Vulkan-Hpp/VulkanHppGenerator.cpp
asuessenbach a3807fb92b Use VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL with vk::raii::Context
-> vk::raii::Context constructor now either gets
     no argument as before, loading vkGetInstanceProcAddr via an internal DynamicLoader;
     or a PFN_vkGetInstanceProcAddr, using that to fill the dispatcher
+ changed the sample RAII_Samples/RayTracing to work with VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL defined to be zero
+ fixed the missing destructor call in most of the move assignments of the vk::raii classes
2021-11-16 18:07:19 +01:00

17936 lines
739 KiB
C++

// Copyright(c) 2015-2020, NVIDIA CORPORATION. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "VulkanHppGenerator.hpp"
#include <cassert>
#include <fstream>
#include <regex>
bool beginsWith( std::string const & text, std::string const & prefix );
bool endsWith( std::string const & text, std::string const & postfix );
void check( bool condition, int line, std::string const & message );
void checkAttributes( int line,
std::map<std::string, std::string> const & attributes,
std::map<std::string, std::set<std::string>> const & required,
std::map<std::string, std::set<std::string>> const & optional );
void checkElements( int line,
std::vector<tinyxml2::XMLElement const *> const & elements,
std::map<std::string, bool> const & required,
std::set<std::string> const & optional = {} );
std::set<size_t> determineSingularParams( size_t returnParamIndex,
std::map<size_t, size_t> const & vectorParamIndices );
std::string findTag( std::set<std::string> const & tags, std::string const & name, std::string const & postfix = "" );
std::string generateCArraySizes( std::vector<std::string> const & sizes );
std::pair<std::string, std::string>
generateEnumSuffixes( std::string const & name, bool bitmask, std::set<std::string> const & tags );
std::string generateEnumValueName( std::string const & enumName,
std::string const & valueName,
bool bitmask,
std::set<std::string> const & tags );
std::string generateNamespacedType( std::string const & type );
std::string generateNoDiscard( bool multiSuccessCodes, bool multiErrorCodes );
std::string generateReturnType( std::vector<std::string> const & successCodes, std::string const & baseType );
std::string generateStandardArray( std::string const & type, std::vector<std::string> const & sizes );
std::string generateStandardArrayWrapper( std::string const & type, std::vector<std::string> const & sizes );
std::string generateSuccessCode( std::string const & code, std::set<std::string> const & tags );
std::map<std::string, std::string> getAttributes( tinyxml2::XMLElement const * element );
template <typename ElementContainer>
std::vector<tinyxml2::XMLElement const *> getChildElements( ElementContainer const * element );
std::pair<std::vector<std::string>, std::string> readModifiers( tinyxml2::XMLNode const * node );
void replaceAll( std::string & str, std::string const & from, std::string const & to );
std::string replaceWithMap( std::string const & input, std::map<std::string, std::string> replacements );
std::string startLowerCase( std::string const & input );
std::string startUpperCase( std::string const & input );
std::string stripPostfix( std::string const & value, std::string const & postfix );
std::string stripPluralS( std::string const & name );
std::string stripPrefix( std::string const & value, std::string const & prefix );
std::string toCamelCase( std::string const & value );
std::string toUpperCase( std::string const & name );
std::vector<std::string> tokenize( std::string const & tokenString, std::string const & separator );
template <typename StringContainer>
std::string toString( StringContainer const & strings );
std::string toString( tinyxml2::XMLError error );
std::string trim( std::string const & input );
std::string trimEnd( std::string const & input );
std::string trimStars( std::string const & input );
void warn( bool condition, int line, std::string const & message );
void writeToFile( std::string const & str, std::string const & fileName );
template <class InputIt, class UnaryPredicate>
std::vector<InputIt> findAll( InputIt first, InputIt last, UnaryPredicate p )
{
std::vector<InputIt> result;
while ( first != last )
{
if ( p( *first ) )
{
result.push_back( first );
}
++first;
}
return result;
}
const std::set<std::string> altLens = { "codeSize / 4", "(rasterizationSamples + 31) / 32", "2*VK_UUID_SIZE" };
const std::set<std::string> specialPointerTypes = {
"Display", "IDirectFB", "wl_display", "xcb_connection_t", "_screen_window"
};
//
// VulkanHppGenerator public interface
//
VulkanHppGenerator::VulkanHppGenerator( tinyxml2::XMLDocument const & document )
{
// insert the default "handle" without class (for createInstance, and such)
m_handles.insert( std::make_pair( "", HandleData( {}, "", 0 ) ) );
// read the document and check its correctness
int line = document.GetLineNum();
std::vector<tinyxml2::XMLElement const *> elements = getChildElements( &document );
checkElements( line, elements, { { "registry", true } } );
check( elements.size() == 1,
line,
"encountered " + std::to_string( elements.size() ) + " elements named <registry> but only one is allowed" );
readRegistry( elements[0] );
checkCorrectness();
// some "FlagBits" enums are not specified, but needed for our "Flags" handling -> add them here
for ( auto & feature : m_features )
{
addMissingFlagBits( feature.second.requireData, feature.first );
}
for ( auto & ext : m_extensions )
{
addMissingFlagBits( ext.second.requireData, ext.first );
}
// determine the extensionsByNumber map
for ( auto extensionIt = m_extensions.begin(); extensionIt != m_extensions.end(); ++extensionIt )
{
int number = atoi( extensionIt->second.number.c_str() );
assert( m_extensionsByNumber.find( number ) == m_extensionsByNumber.end() );
m_extensionsByNumber[number] = extensionIt;
}
}
std::string VulkanHppGenerator::generateBaseTypes() const
{
assert( !m_baseTypes.empty() );
const std::string basetypesTemplate = R"(
//==================
//=== BASE TYPEs ===
//==================
${basetypes}
)";
std::string basetypes;
for ( auto const & baseType : m_baseTypes )
{
// filter out VkFlags and VkFlags64, as they are mapped to our own Flags class
if ( ( baseType.first != "VkFlags" ) && ( baseType.first != "VkFlags64" ) )
{
basetypes += " using " + stripPrefix( baseType.first, "Vk" ) + " = " +
baseType.second.typeInfo.compose( "VULKAN_HPP_NAMESPACE" ) + ";\n";
}
}
return replaceWithMap( basetypesTemplate, { { "basetypes", basetypes } } );
}
std::string VulkanHppGenerator::generateBitmasks() const
{
const std::string bitmasksTemplate = R"(
//================
//=== BITMASKs ===
//================
${bitmasks}
)";
std::string bitmasks;
std::set<std::string> listedBitmasks;
for ( auto const & feature : m_features )
{
bitmasks += generateBitmasks( feature.second.requireData, listedBitmasks, feature.first );
}
for ( auto const & extIt : m_extensionsByNumber )
{
bitmasks += generateBitmasks( extIt.second->second.requireData, listedBitmasks, extIt.second->first );
}
return replaceWithMap( bitmasksTemplate, { { "bitmasks", bitmasks } } );
}
std::string VulkanHppGenerator::generateCommandDefinitions() const
{
const std::string commandDefinitionsTemplate = R"(
//===========================
//=== COMMAND Definitions ===
//===========================
${commandDefinitions}
)";
std::string commandDefinitions;
std::set<std::string> listedCommands; // some commands are listed with more than one extension!
for ( auto const & feature : m_features )
{
commandDefinitions += generateCommandDefinitions( feature.second.requireData, listedCommands, feature.first );
}
for ( auto const & extIt : m_extensionsByNumber )
{
commandDefinitions +=
generateCommandDefinitions( extIt.second->second.requireData, listedCommands, extIt.second->first );
}
return replaceWithMap( commandDefinitionsTemplate, { { "commandDefinitions", commandDefinitions } } );
}
std::string VulkanHppGenerator::generateDispatchLoaderDynamic() const
{
const std::string dispatchLoaderDynamicTemplate = R"(
using PFN_dummy = void ( * )();
class DispatchLoaderDynamic : public DispatchLoaderBase
{
public:
${commandMembers}
public:
DispatchLoaderDynamic() VULKAN_HPP_NOEXCEPT = default;
DispatchLoaderDynamic( DispatchLoaderDynamic const & rhs ) VULKAN_HPP_NOEXCEPT = default;
#if !defined( VK_NO_PROTOTYPES )
// This interface is designed to be used for per-device function pointers in combination with a linked vulkan library.
template <typename DynamicLoader>
void init(VULKAN_HPP_NAMESPACE::Instance const & instance, VULKAN_HPP_NAMESPACE::Device const & device, DynamicLoader const & dl) VULKAN_HPP_NOEXCEPT
{
PFN_vkGetInstanceProcAddr getInstanceProcAddr = dl.template getProcAddress<PFN_vkGetInstanceProcAddr>("vkGetInstanceProcAddr");
PFN_vkGetDeviceProcAddr getDeviceProcAddr = dl.template getProcAddress<PFN_vkGetDeviceProcAddr>("vkGetDeviceProcAddr");
init(static_cast<VkInstance>(instance), getInstanceProcAddr, static_cast<VkDevice>(device), device ? getDeviceProcAddr : nullptr);
}
// This interface is designed to be used for per-device function pointers in combination with a linked vulkan library.
template <typename DynamicLoader
#if VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL
= VULKAN_HPP_NAMESPACE::DynamicLoader
#endif
>
void init(VULKAN_HPP_NAMESPACE::Instance const & instance, VULKAN_HPP_NAMESPACE::Device const & device) VULKAN_HPP_NOEXCEPT
{
static DynamicLoader dl;
init(instance, device, dl);
}
#endif // !defined( VK_NO_PROTOTYPES )
DispatchLoaderDynamic(PFN_vkGetInstanceProcAddr getInstanceProcAddr) VULKAN_HPP_NOEXCEPT
{
init(getInstanceProcAddr);
}
void init( PFN_vkGetInstanceProcAddr getInstanceProcAddr ) VULKAN_HPP_NOEXCEPT
{
VULKAN_HPP_ASSERT(getInstanceProcAddr);
vkGetInstanceProcAddr = getInstanceProcAddr;
${initialCommandAssignments}
}
// This interface does not require a linked vulkan library.
DispatchLoaderDynamic( VkInstance instance,
PFN_vkGetInstanceProcAddr getInstanceProcAddr,
VkDevice device = {},
PFN_vkGetDeviceProcAddr getDeviceProcAddr = nullptr ) VULKAN_HPP_NOEXCEPT
{
init( instance, getInstanceProcAddr, device, getDeviceProcAddr );
}
// This interface does not require a linked vulkan library.
void init( VkInstance instance,
PFN_vkGetInstanceProcAddr getInstanceProcAddr,
VkDevice device = {},
PFN_vkGetDeviceProcAddr /*getDeviceProcAddr*/ = nullptr ) VULKAN_HPP_NOEXCEPT
{
VULKAN_HPP_ASSERT(instance && getInstanceProcAddr);
vkGetInstanceProcAddr = getInstanceProcAddr;
init( VULKAN_HPP_NAMESPACE::Instance(instance) );
if (device) {
init( VULKAN_HPP_NAMESPACE::Device(device) );
}
}
void init( VULKAN_HPP_NAMESPACE::Instance instanceCpp ) VULKAN_HPP_NOEXCEPT
{
VkInstance instance = static_cast<VkInstance>(instanceCpp);
${instanceCommandAssignments}
}
void init( VULKAN_HPP_NAMESPACE::Device deviceCpp ) VULKAN_HPP_NOEXCEPT
{
VkDevice device = static_cast<VkDevice>(deviceCpp);
${deviceCommandAssignments}
}
};
)";
std::string commandMembers, deviceCommandAssignments, initialCommandAssignments, instanceCommandAssignments;
std::set<std::string> listedCommands; // some commands are listed with more than one extension!
for ( auto const & feature : m_features )
{
appendDispatchLoaderDynamicCommands( feature.second.requireData,
listedCommands,
feature.first,
commandMembers,
initialCommandAssignments,
instanceCommandAssignments,
deviceCommandAssignments );
}
for ( auto const & extIt : m_extensionsByNumber )
{
appendDispatchLoaderDynamicCommands( extIt.second->second.requireData,
listedCommands,
extIt.second->first,
commandMembers,
initialCommandAssignments,
instanceCommandAssignments,
deviceCommandAssignments );
}
return replaceWithMap( dispatchLoaderDynamicTemplate,
{ { "commandMembers", commandMembers },
{ "deviceCommandAssignments", deviceCommandAssignments },
{ "initialCommandAssignments", initialCommandAssignments },
{ "instanceCommandAssignments", instanceCommandAssignments } } );
}
std::string VulkanHppGenerator::generateDispatchLoaderStatic() const
{
const std::string dispatchLoaderStaticTemplate = R"(
#if !defined( VK_NO_PROTOTYPES )
class DispatchLoaderStatic : public DispatchLoaderBase
{
public:
${commands}
};
#endif
)";
std::string commands;
std::set<std::string> listedCommands;
for ( auto const & feature : m_features )
{
commands += generateDispatchLoaderStaticCommands( feature.second.requireData, listedCommands, feature.first );
}
for ( auto const & extIt : m_extensionsByNumber )
{
commands +=
generateDispatchLoaderStaticCommands( extIt.second->second.requireData, listedCommands, extIt.second->first );
}
return replaceWithMap( dispatchLoaderStaticTemplate, { { "commands", commands } } );
}
std::string VulkanHppGenerator::generateEnums() const
{
// start with toHexString, which is used in all the to_string functions here!
const std::string enumsTemplate = R"(
VULKAN_HPP_INLINE std::string toHexString( uint32_t value )
{
std::stringstream stream;
stream << std::hex << value;
return stream.str();
}
//=============
//=== ENUMs ===
//=============
${enums}
template<ObjectType value>
struct cpp_type
{};
)";
std::string enums;
std::set<std::string> listedEnums;
for ( auto const & feature : m_features )
{
enums += generateEnums( feature.second.requireData, listedEnums, feature.first );
}
for ( auto const & extIt : m_extensionsByNumber )
{
enums += generateEnums( extIt.second->second.requireData, listedEnums, extIt.second->first );
}
return replaceWithMap( enumsTemplate, { { "enums", enums } } );
}
std::string VulkanHppGenerator::generateHandles() const
{
// Note: reordering structs or handles by features and extensions is not possible!
std::string str = R"(
//===============
//=== HANDLEs ===
//===============
)";
std::set<std::string> listedHandles;
for ( auto const & handle : m_handles )
{
if ( listedHandles.find( handle.first ) == listedHandles.end() )
{
str += generateHandle( handle, listedHandles );
}
}
return str;
}
std::string VulkanHppGenerator::generateHashStructures() const
{
const std::string hashesTemplate = R"(
//=======================
//=== HASH structures ===
//=======================
${hashes}
)";
// start with the hash on Flags<BitType>
std::string hashes = R"(
template <typename BitType> struct hash<VULKAN_HPP_NAMESPACE::Flags<BitType>>
{
std::size_t operator()(VULKAN_HPP_NAMESPACE::Flags<BitType> const& flags) const VULKAN_HPP_NOEXCEPT
{
return std::hash<typename std::underlying_type<BitType>::type>{}(static_cast<typename std::underlying_type<BitType>::type>(flags));
}
};
)";
for ( auto const & feature : m_features )
{
hashes += generateHashStructures( feature.second.requireData, feature.first );
}
for ( auto const & extIt : m_extensionsByNumber )
{
hashes += generateHashStructures( extIt.second->second.requireData, extIt.second->first );
}
return replaceWithMap( hashesTemplate, { { "hashes", hashes } } );
}
std::string VulkanHppGenerator::generateIndexTypeTraits() const
{
const std::string indexTypeTraitsTemplate = R"(
template<typename T>
struct IndexTypeValue
{};
${indexTypeTraits}
)";
auto indexType = m_enums.find( "VkIndexType" );
assert( indexType != m_enums.end() );
std::string indexTypeTraits;
std::set<std::string> listedCppTypes;
for ( auto const & value : indexType->second.values )
{
std::string valueName = generateEnumValueName( indexType->first, value.name, false, m_tags );
std::string cppType;
if ( !beginsWith( valueName, "eNone" ) )
{
// get the bit count out of the value Name (8, 16, 32, ... ) and generate the cppType (uint8_t,...)
assert( beginsWith( valueName, "eUint" ) );
auto beginDigit = valueName.begin() + strlen( "eUint" );
assert( isdigit( *beginDigit ) );
auto endDigit =
std::find_if_not( beginDigit, valueName.end(), []( std::string::value_type c ) { return isdigit( c ); } );
cppType = "uint" + valueName.substr( strlen( "eUint" ), endDigit - beginDigit ) + "_t";
}
if ( !cppType.empty() )
{
if ( listedCppTypes.insert( cppType ).second )
{
// IndexType traits aren't necessarily invertible.
// The Type -> Enum translation will only occur for the first prefixed enum value.
// A hypothetical extension to this enum with a conflicting prefix will use the core spec value.
const std::string typeToEnumTemplate = R"(
template <>
struct IndexTypeValue<${cppType}>
{
static VULKAN_HPP_CONST_OR_CONSTEXPR IndexType value = IndexType::${valueName};
};
)";
indexTypeTraits += replaceWithMap( typeToEnumTemplate, { { "cppType", cppType }, { "valueName", valueName } } );
}
// Enum -> Type translations are always able to occur.
const std::string enumToTypeTemplate = R"(
template <>
struct CppType<IndexType, IndexType::${valueName}>
{
using Type = ${cppType};
};
)";
indexTypeTraits += replaceWithMap( enumToTypeTemplate, { { "cppType", cppType }, { "valueName", valueName } } );
}
}
return replaceWithMap( indexTypeTraitsTemplate, { { "indexTypeTraits", indexTypeTraits } } );
}
std::string VulkanHppGenerator::generateRAIICommandDefinitions() const
{
const std::string commandDefinitionsTemplate = R"(
//===========================
//=== COMMAND Definitions ===
//===========================
${commandDefinitions}
)";
std::string commandDefinitions;
std::set<std::string> listedCommands; // some commands are listed with more than one extension!
for ( auto const & feature : m_features )
{
commandDefinitions += generateRAIICommandDefinitions( feature.second.requireData, listedCommands, feature.first );
}
for ( auto const & extIt : m_extensionsByNumber )
{
commandDefinitions +=
generateRAIICommandDefinitions( extIt.second->second.requireData, listedCommands, extIt.second->first );
}
return replaceWithMap( commandDefinitionsTemplate, { { "commandDefinitions", commandDefinitions } } );
}
std::string VulkanHppGenerator::generateRAIIDispatchers() const
{
std::string contextInitializers, contextMembers, deviceAssignments, deviceMembers, instanceAssignments,
instanceMembers;
std::set<std::string> listedCommands;
for ( auto const & feature : m_features )
{
appendRAIIDispatcherCommands( feature.second.requireData,
listedCommands,
feature.first,
contextInitializers,
contextMembers,
deviceAssignments,
deviceMembers,
instanceAssignments,
instanceMembers );
}
for ( auto const & extension : m_extensions )
{
appendRAIIDispatcherCommands( extension.second.requireData,
listedCommands,
extension.first,
contextInitializers,
contextMembers,
deviceAssignments,
deviceMembers,
instanceAssignments,
instanceMembers );
}
std::string contextDispatcherTemplate = R"(
class ContextDispatcher : public DispatchLoaderBase
{
public:
ContextDispatcher( PFN_vkGetInstanceProcAddr getProcAddr )
: vkGetInstanceProcAddr( getProcAddr )${contextInitializers}
{}
public:
PFN_vkGetInstanceProcAddr vkGetInstanceProcAddr = 0;
${contextMembers}
};
)";
std::string str =
replaceWithMap( contextDispatcherTemplate,
{ { "contextInitializers", contextInitializers }, { "contextMembers", contextMembers } } );
std::string instanceDispatcherTemplate = R"(
class InstanceDispatcher : public DispatchLoaderBase
{
public:
InstanceDispatcher( PFN_vkGetInstanceProcAddr getProcAddr, VkInstance instance )
: vkGetInstanceProcAddr( getProcAddr )
{
${instanceAssignments}
vkGetDeviceProcAddr =
PFN_vkGetDeviceProcAddr( vkGetInstanceProcAddr( instance, "vkGetDeviceProcAddr" ) );
}
public:
${instanceMembers}
PFN_vkGetDeviceProcAddr vkGetDeviceProcAddr = 0;
};
)";
str += replaceWithMap( instanceDispatcherTemplate,
{ { "instanceAssignments", instanceAssignments }, { "instanceMembers", instanceMembers } } );
std::string deviceDispatcherTemplate = R"(
class DeviceDispatcher : public DispatchLoaderBase
{
public:
DeviceDispatcher( PFN_vkGetDeviceProcAddr getProcAddr, VkDevice device ) : vkGetDeviceProcAddr( getProcAddr )
{
${deviceAssignments}
}
public:
${deviceMembers}
};
)";
str += replaceWithMap( deviceDispatcherTemplate,
{ { "deviceAssignments", deviceAssignments }, { "deviceMembers", deviceMembers } } );
return str;
}
std::string VulkanHppGenerator::generateRAIIHandles() const
{
const std::string raiiHandlesTemplate = R"(
//========================================
//=== RAII HANDLE forward declarations ===
//========================================
${forwardDeclarations}
//====================
//=== RAII HANDLES ===
//====================
${raiiHandles}
)";
std::string forwardDeclarations;
for ( auto const & feature : m_features )
{
forwardDeclarations += generateRAIIHandleForwardDeclarations( feature.second.requireData, feature.first );
}
for ( auto const & extIt : m_extensionsByNumber )
{
forwardDeclarations +=
generateRAIIHandleForwardDeclarations( extIt.second->second.requireData, extIt.second->first );
}
std::set<std::string> listedHandles;
auto handleIt = m_handles.begin();
assert( handleIt->first.empty() );
std::string raiiHandles = generateRAIIHandleContext( *handleIt, m_RAIISpecialFunctions );
for ( ++handleIt; handleIt != m_handles.end(); ++handleIt )
{
raiiHandles += generateRAIIHandle( *handleIt, listedHandles, m_RAIISpecialFunctions );
}
return replaceWithMap( raiiHandlesTemplate,
{ { "forwardDeclarations", forwardDeclarations }, { "raiiHandles", raiiHandles } } );
}
// Intended only for `enum class Result`!
std::string VulkanHppGenerator::generateResultExceptions() const
{
const std::string templateString = R"(
${enter} class ${className} : public SystemError
{
public:
${className}( std::string const & message )
: SystemError( make_error_code( ${enumName}::${enumMemberName} ), message ) {}
${className}( char const * message )
: SystemError( make_error_code( ${enumName}::${enumMemberName} ), message ) {}
};
${leave})";
std::string str;
auto enumIt = m_enums.find( "VkResult" );
for ( auto const & value : enumIt->second.values )
{
if ( beginsWith( value.name, "VK_ERROR" ) )
{
auto [enter, leave] = generateProtection( value.extension, value.protect );
std::string valueName = generateEnumValueName( enumIt->first, value.name, false, m_tags );
str += replaceWithMap( templateString,
{ { "className", stripPrefix( valueName, "eError" ) + "Error" },
{ "enter", enter },
{ "enumName", stripPrefix( enumIt->first, "Vk" ) },
{ "enumMemberName", valueName },
{ "leave", leave } } );
}
}
return str;
}
std::string VulkanHppGenerator::generateStructExtendsStructs() const
{
const std::string structExtendsTemplate = R"(
//=======================
//=== STRUCTS EXTENDS ===
//=======================
${structExtends}
)";
std::string structExtends;
std::set<std::string> listedStructs;
for ( auto const & feature : m_features )
{
structExtends += generateStructExtendsStructs( feature.second.requireData, listedStructs, feature.first );
}
for ( auto const & extIt : m_extensionsByNumber )
{
structExtends +=
generateStructExtendsStructs( extIt.second->second.requireData, listedStructs, extIt.second->first );
}
return replaceWithMap( structExtendsTemplate, { { "structExtends", structExtends } } );
}
std::string VulkanHppGenerator::generateStructForwardDeclarations() const
{
const std::string fowardDeclarationsTemplate = R"(
//===================================
//=== STRUCT forward declarations ===
//===================================
${forwardDeclarations}
)";
std::string forwardDeclarations;
for ( auto const & feature : m_features )
{
forwardDeclarations += generateStructForwardDeclarations( feature.second.requireData, feature.first );
}
for ( auto const & extIt : m_extensionsByNumber )
{
forwardDeclarations += generateStructForwardDeclarations( extIt.second->second.requireData, extIt.second->first );
}
return replaceWithMap( fowardDeclarationsTemplate, { { "forwardDeclarations", forwardDeclarations } } );
}
std::string VulkanHppGenerator::generateStructs() const
{
const std::string structsTemplate = R"(
//===============
//=== STRUCTS ===
//===============
${structs}
)";
// Note reordering structs or handles by features and extensions is not possible!
std::set<std::string> listedStructs;
std::string structs;
for ( auto const & structure : m_structures )
{
if ( listedStructs.find( structure.first ) == listedStructs.end() )
{
structs += generateStruct( structure, listedStructs );
}
}
return replaceWithMap( structsTemplate, { { "structs", structs } } );
}
std::string VulkanHppGenerator::generateThrowResultException() const
{
auto enumIt = m_enums.find( "VkResult" );
std::string cases;
for ( auto const & value : enumIt->second.values )
{
if ( beginsWith( value.name, "VK_ERROR" ) )
{
auto [enter, leave] = generateProtection( value.extension, value.protect );
std::string valueName = generateEnumValueName( enumIt->first, value.name, false, m_tags );
cases += enter + " case Result::" + valueName + ": throw " + stripPrefix( valueName, "eError" ) +
"Error( message );\n" + leave;
}
}
cases.pop_back(); // remove last newline
const std::string throwTemplate = R"(
namespace
{
[[noreturn]] void throwResultException( Result result, char const * message )
{
switch ( result )
{
${cases}
default: throw SystemError( make_error_code( result ) );
}
}
}
)";
return replaceWithMap( throwTemplate, { { "cases", cases } } );
}
std::string const & VulkanHppGenerator::getTypesafeCheck() const
{
return m_typesafeCheck;
}
std::string const & VulkanHppGenerator::getVersion() const
{
return m_version;
}
std::string const & VulkanHppGenerator::getVulkanLicenseHeader() const
{
return m_vulkanLicenseHeader;
}
void VulkanHppGenerator::prepareRAIIHandles()
{
// filter out functions that are not usefull on this level of abstraction (like vkGetInstanceProcAddr)
// and all the construction and destruction functions, as they are used differently
for ( auto & handle : m_handles )
{
if ( !handle.first.empty() )
{
handle.second.destructorIt = determineRAIIHandleDestructor( handle.first );
if ( handle.second.destructorIt != m_commands.end() )
{
m_RAIISpecialFunctions.insert( handle.second.destructorIt->first );
}
handle.second.constructorIts = determineRAIIHandleConstructors( handle.first, handle.second.destructorIt );
}
}
distributeSecondLevelCommands( m_RAIISpecialFunctions );
// we rename a couple of function parameters to prevent this warning, treated as an error:
// warning C4458: declaration of 'objectType' hides class member
for ( auto & command : m_commands )
{
for ( auto & param : command.second.params )
{
if ( param.name == "objectType" )
{
param.name += "_";
}
}
}
}
//
// VulkanHppGenerator private interface
//
void VulkanHppGenerator::addCommand( std::string const & name, CommandData & commandData )
{
// find the handle this command is going to be associated to
check( !commandData.params.empty(), commandData.xmlLine, "command <" + name + "> with no params" );
std::map<std::string, HandleData>::iterator handleIt = m_handles.find( commandData.params[0].type.type );
if ( handleIt == m_handles.end() )
{
handleIt = m_handles.find( "" );
}
check( handleIt != m_handles.end(), commandData.xmlLine, "could not find a handle to hold command <" + name + ">" );
commandData.handle = handleIt->first;
// add this command to the list of commands
check( m_commands.insert( std::make_pair( name, commandData ) ).second,
commandData.xmlLine,
"already encountered command <" + name + ">" );
// put the command into the handle's list of commands
check( handleIt->second.commands.insert( name ).second,
commandData.xmlLine,
"command list of handle <" + handleIt->first + "> already holds a commnand <" + name + ">" );
}
void VulkanHppGenerator::addMissingFlagBits( std::vector<RequireData> & requireData, std::string const & referencedIn )
{
for ( auto & require : requireData )
{
std::vector<std::string> newTypes;
for ( auto const & type : require.types )
{
auto bitmaskIt = m_bitmasks.find( type );
if ( ( bitmaskIt != m_bitmasks.end() ) && bitmaskIt->second.requirements.empty() )
{
// generate the flagBits enum name out of the bitmask name
size_t pos = bitmaskIt->first.find( "Flags" );
assert( pos != std::string::npos );
std::string flagBits = bitmaskIt->first.substr( 0, pos + 4 ) + "Bit" + bitmaskIt->first.substr( pos + 4 );
// as the bitmask's requirement is still empty, this flagBits should not be listed in the require list!
assert( std::find_if( require.types.begin(),
require.types.end(),
[&flagBits]( std::string const & type )
{ return ( type == flagBits ); } ) == require.types.end() );
bitmaskIt->second.requirements = flagBits;
// some flagsBits are specified but never listed as required for any flags!
// so, even if this bitmask has not enum listed as required, it might still already exist in the enums list
if ( m_enums.find( flagBits ) == m_enums.end() )
{
m_enums.insert( std::make_pair( flagBits, EnumData( 0, true ) ) );
assert( m_types.find( flagBits ) == m_types.end() );
m_types.insert( std::make_pair( flagBits, TypeData( TypeCategory::Bitmask, referencedIn ) ) );
}
else
{
assert( m_types.find( flagBits ) != m_types.end() );
}
newTypes.push_back( flagBits );
}
}
// add all the newly created flagBits types to the require list as if they had been part of the vk.xml!
require.types.insert( require.types.end(), newTypes.begin(), newTypes.end() );
}
}
std::string VulkanHppGenerator::addTitleAndProtection( std::string const & title,
std::string const & strIf,
std::string const & strElse ) const
{
std::string str;
if ( !strIf.empty() )
{
auto [enter, leave] = generateProtection( title, std::string() );
str = "\n" + enter + " //=== " + title + " ===\n" + strIf;
if ( !enter.empty() && !strElse.empty() )
{
str += "#else \n" + strElse;
}
str += leave;
}
return str;
}
void VulkanHppGenerator::appendDispatchLoaderDynamicCommands( std::vector<RequireData> const & requireData,
std::set<std::string> & listedCommands,
std::string const & title,
std::string & commandMembers,
std::string & initialCommandAssignments,
std::string & instanceCommandAssignments,
std::string & deviceCommandAssignments ) const
{
std::string members, initial, instance, device, placeholders;
for ( auto const & require : requireData )
{
for ( auto const & command : require.commands )
{
if ( listedCommands.insert( command ).second )
{
auto commandIt = m_commands.find( command );
assert( commandIt != m_commands.end() );
members += " PFN_" + commandIt->first + " " + commandIt->first + " = 0;\n";
placeholders += " PFN_dummy " + commandIt->first + "_placeholder = 0;\n";
if ( commandIt->second.handle.empty() )
{
initial += generateDispatchLoaderDynamicCommandAssignment( commandIt->first, commandIt->second, "NULL" );
}
else
{
instance += generateDispatchLoaderDynamicCommandAssignment( commandIt->first, commandIt->second, "instance" );
if ( isDeviceCommand( commandIt->second ) )
{
device += generateDispatchLoaderDynamicCommandAssignment( commandIt->first, commandIt->second, "device" );
}
}
}
}
}
auto [enter, leave] = generateProtection( title, std::string() );
std::string header = "\n" + enter + " //=== " + title + " ===\n";
if ( !members.empty() )
{
commandMembers += header + members;
if ( !enter.empty() )
{
commandMembers += "#else\n" + placeholders;
}
commandMembers += leave;
}
if ( !initial.empty() )
{
initialCommandAssignments += header + initial + leave;
}
if ( !instance.empty() )
{
instanceCommandAssignments += header + instance + leave;
}
if ( !device.empty() )
{
deviceCommandAssignments += header + device + leave;
}
}
void VulkanHppGenerator::appendRAIIDispatcherCommands( std::vector<RequireData> const & requireData,
std::set<std::string> & listedCommands,
std::string const & title,
std::string & contextInitializers,
std::string & contextMembers,
std::string & deviceAssignments,
std::string & deviceMembers,
std::string & instanceAssignments,
std::string & instanceMembers ) const
{
std::string ci, cm, da, dm, dmp, ia, im, imp;
for ( auto const & require : requireData )
{
for ( auto const & command : require.commands )
{
if ( listedCommands.insert( command ).second )
{
auto commandIt = m_commands.find( command );
assert( commandIt != m_commands.end() );
if ( commandIt->second.handle.empty() )
{
assert( commandIt->second.alias.empty() );
ci += ", " + commandIt->first + "( PFN_" + commandIt->first + "( getProcAddr( NULL, \"" + commandIt->first +
"\" ) ) )";
cm += " PFN_" + commandIt->first + " " + commandIt->first + " = 0;\n";
}
else if ( ( commandIt->second.handle == "VkDevice" ) ||
hasParentHandle( commandIt->second.handle, "VkDevice" ) )
{
da += " " + commandIt->first + " = PFN_" + commandIt->first + "( vkGetDeviceProcAddr( device, \"" +
commandIt->first + "\" ) );\n";
// if this is an alias'ed function, use it as a fallback for the original one
if ( !commandIt->second.alias.empty() )
{
da += " if ( !" + commandIt->second.alias + " ) " + commandIt->second.alias + " = " +
commandIt->first + ";\n";
}
dm += " PFN_" + commandIt->first + " " + commandIt->first + " = 0;\n";
dmp += " PFN_dummy " + commandIt->first + "_placeholder = 0;\n";
}
else
{
assert( ( commandIt->second.handle == "VkInstance" ) ||
hasParentHandle( commandIt->second.handle, "VkInstance" ) );
ia += " " + commandIt->first + " = PFN_" + commandIt->first + "( vkGetInstanceProcAddr( instance, \"" +
commandIt->first + "\" ) );\n";
// if this is an alias'ed function, use it as a fallback for the original one
if ( !commandIt->second.alias.empty() )
{
ia += " if ( !" + commandIt->second.alias + " ) " + commandIt->second.alias + " = " +
commandIt->first + ";\n";
}
im += +" PFN_" + commandIt->first + " " + commandIt->first + " = 0;\n";
imp += " PFN_dummy " + commandIt->first + "_placeholder = 0;\n";
}
}
}
}
contextInitializers += addTitleAndProtection( title, ci );
contextMembers += addTitleAndProtection( title, cm );
deviceAssignments += addTitleAndProtection( title, da );
deviceMembers += addTitleAndProtection( title, dm, dmp );
instanceAssignments += addTitleAndProtection( title, ia );
instanceMembers += addTitleAndProtection( title, im, imp );
}
void VulkanHppGenerator::checkBitmaskCorrectness() const
{
for ( auto const & bitmask : m_bitmasks )
{
// check that a bitmask is referenced somewhere
// I think, it's not forbidden to not reference a bitmask, but it would probably be not intended?
auto typeIt = m_types.find( bitmask.first );
assert( typeIt != m_types.end() );
check( !typeIt->second.referencedIn.empty(),
bitmask.second.xmlLine,
"bitmask <" + bitmask.first + "> not listed in any feature or extension" );
// check that the requirement is an enum
if ( !bitmask.second.requirements.empty() )
{
check( m_enums.find( bitmask.second.requirements ) != m_enums.end(),
bitmask.second.xmlLine,
"bitmask requires unknown <" + bitmask.second.requirements + ">" );
}
}
}
void VulkanHppGenerator::checkCommandCorrectness() const
{
// prepare command checks by gathering all result codes and aliases into one set of resultCodes
auto resultIt = m_enums.find( "VkResult" );
assert( resultIt != m_enums.end() );
std::set<std::string> resultCodes;
for ( auto rc : resultIt->second.values )
{
resultCodes.insert( rc.name );
}
for ( auto rc : resultIt->second.aliases )
{
resultCodes.insert( rc.first );
}
// command checks
for ( auto const & command : m_commands )
{
// check that a command is referenced somewhere
// I think, it's not forbidden to not reference a function, but it would probably be not intended?
check( !command.second.referencedIn.empty(),
command.second.xmlLine,
"command <" + command.first + "> not listed in any feature or extension" );
// check for unknow error or succes codes
for ( auto const & ec : command.second.errorCodes )
{
check( resultCodes.find( ec ) != resultCodes.end(),
command.second.xmlLine,
"command uses unknown error code <" + ec + ">" );
}
for ( auto const & sc : command.second.successCodes )
{
check( resultCodes.find( sc ) != resultCodes.end(),
command.second.xmlLine,
"command uses unknown success code <" + sc + ">" );
}
// check that functions returning a VkResult specify successcodes
check( ( command.second.returnType != "VkResult" ) || !command.second.successCodes.empty(),
command.second.xmlLine,
"missing successcodes on command <" + command.first + "> returning VkResult!" );
// check that all parameter types as well as the return type are known types
for ( auto const & p : command.second.params )
{
check( m_types.find( p.type.type ) != m_types.end(),
p.xmlLine,
"comand uses parameter of unknown type <" + p.type.type + ">" );
}
check( m_types.find( command.second.returnType ) != m_types.end(),
command.second.xmlLine,
"command uses unknown return type <" + command.second.returnType + ">" );
}
}
void VulkanHppGenerator::checkCorrectness() const
{
check( !m_vulkanLicenseHeader.empty(), -1, "missing license header" );
checkBitmaskCorrectness();
checkCommandCorrectness();
checkEnumCorrectness();
checkExtensionCorrectness();
checkFuncPointerCorrectness();
checkHandleCorrectness();
checkStructCorrectness();
}
void VulkanHppGenerator::checkEnumCorrectness() const
{
for ( auto const & e : m_enums )
{
// check that a bitmask is referenced somewhere
// it's not forbidden to not reference a bitmask, and in fact that happens! So just warn here
auto typeIt = m_types.find( e.first );
assert( typeIt != m_types.end() );
warn( !typeIt->second.referencedIn.empty(),
e.second.xmlLine,
"enum <" + e.first + "> not listed in any feature or extension" );
// check that the aliasNames are known enum values or known aliases
for ( auto const & alias : e.second.aliases )
{
check( ( std::find_if( e.second.values.begin(),
e.second.values.end(),
[&alias]( EnumValueData const & evd )
{ return evd.name == alias.second.name; } ) != e.second.values.end() ) ||
( e.second.aliases.find( alias.second.name ) != e.second.aliases.end() ),
alias.second.xmlLine,
"enum <" + alias.first + "> uses unknown alias <" + alias.second.name + ">" );
}
// check that any protection fits to the corresponding extension
for ( auto const & v : e.second.values )
{
if ( !v.protect.empty() )
{
auto extIt = m_extensions.find( v.extension );
assert( extIt != m_extensions.end() );
auto platformIt = m_platforms.find( extIt->second.platform );
assert( platformIt != m_platforms.end() );
check( v.protect == platformIt->second.protect,
v.xmlLine,
"attribute <protect> of enum value <" + v.name + "> is \"" + v.protect +
"\" but corresponding extension <" + v.extension + "> belongs to platform <" + platformIt->first +
"> with protection \"" + platformIt->second.protect + "\"" );
}
}
}
// enum checks by features and extensions
for ( auto & feature : m_features )
{
checkEnumCorrectness( feature.second.requireData );
}
for ( auto & ext : m_extensions )
{
checkEnumCorrectness( ext.second.requireData );
}
}
void VulkanHppGenerator::checkEnumCorrectness( std::vector<RequireData> const & requireData ) const
{
for ( auto const & require : requireData )
{
for ( auto const & type : require.types )
{
auto typeIt = m_types.find( type );
assert( typeIt != m_types.end() );
switch ( typeIt->second.category )
{
case TypeCategory::Bitmask:
{
// check that each "require" listed for a bitmask is listed for a feature or an extension
auto bitmaskIt = m_bitmasks.find( type );
if ( bitmaskIt != m_bitmasks.end() )
{
// not for every bitmask is a "require" listed
if ( !bitmaskIt->second.requirements.empty() )
{
auto requireTypeIt = m_types.find( bitmaskIt->second.requirements );
assert( requireTypeIt != m_types.end() );
check( !requireTypeIt->second.referencedIn.empty(),
bitmaskIt->second.xmlLine,
"bitmask <" + bitmaskIt->first + "> requires <" + bitmaskIt->second.requirements +
"> which is not listed for any feature or extension!" );
}
}
else
{
// every bitmask not listed in the m_bitmasks, should be an alias of such a thing
assert( std::find_if( m_bitmasks.begin(),
m_bitmasks.end(),
[&type]( std::pair<const std::string, BitmaskData> const & bd )
{ return bd.second.alias == type; } ) != m_bitmasks.end() );
}
}
break;
case TypeCategory::Enum:
{
auto enumIt = m_enums.find( type );
if ( enumIt != m_enums.end() )
{
if ( enumIt->second.isBitmask )
{
// check that any enum of a bitmask is listed as "require" or "bitvalues" for a bitmask
auto bitmaskIt = std::find_if( m_bitmasks.begin(),
m_bitmasks.end(),
[&enumIt]( auto const & bitmask )
{ return bitmask.second.requirements == enumIt->first; } );
check( bitmaskIt != m_bitmasks.end(),
enumIt->second.xmlLine,
"enum <" + enumIt->first +
"> is not listed as an requires or bitvalues for any bitmask in the types section" );
// check that bitwidth of the enum and type of the corresponding bitmask are equal
check( ( enumIt->second.bitwidth != "64" ) || ( bitmaskIt->second.type == "VkFlags64" ),
enumIt->second.xmlLine,
"enum <" + enumIt->first + "> is marked with bitwidth <64> but corresponding bitmask <" +
bitmaskIt->first + "> is not of type <VkFlags64>" );
}
}
else
{
// every enum not listed in the m_enums, should be an alias of such a thing
assert( std::find_if( m_enums.begin(),
m_enums.end(),
[&type]( std::pair<const std::string, EnumData> const & ed )
{ return ed.second.alias == type; } ) != m_enums.end() );
}
}
break;
default: break;
}
}
}
}
bool VulkanHppGenerator::checkEquivalentSingularConstructor(
std::vector<std::map<std::string, CommandData>::const_iterator> const & constructorIts,
std::map<std::string, CommandData>::const_iterator constructorIt,
std::vector<ParamData>::const_iterator lenIt ) const
{
// check, if there is no singular constructor with the very same arguments as this array constructor
// (besides the size, of course)
auto isEquivalentSingularConstructor = [constructorIt, lenIt]( std::map<std::string, CommandData>::const_iterator it )
{
if ( it->second.params.size() + 1 != constructorIt->second.params.size() )
{
return false;
}
size_t lenIdx = std::distance( constructorIt->second.params.begin(), lenIt );
for ( size_t i = 0, j = 0; i < it->second.params.size(); ++i, ++j )
{
assert( j < constructorIt->second.params.size() );
if ( j == lenIdx )
{
++j;
}
if ( it->second.params[i].type.type != constructorIt->second.params[j].type.type )
{
return false;
}
}
return true;
};
return ( std::find_if( constructorIts.begin(), constructorIts.end(), isEquivalentSingularConstructor ) !=
constructorIts.end() );
}
void VulkanHppGenerator::checkExtensionCorrectness() const
{
for ( auto const & extension : m_extensions )
{
// check for existence of any deprecation, obsoletion, or promotion
if ( !extension.second.deprecatedBy.empty() )
{
check( ( m_extensions.find( extension.second.deprecatedBy ) != m_extensions.end() ) ||
( m_features.find( extension.second.deprecatedBy ) != m_features.end() ),
extension.second.xmlLine,
"extension deprecated by unknown extension/version <" + extension.second.promotedTo + ">" );
}
if ( !extension.second.obsoletedBy.empty() )
{
check( ( m_extensions.find( extension.second.obsoletedBy ) != m_extensions.end() ) ||
( m_features.find( extension.second.obsoletedBy ) != m_features.end() ),
extension.second.xmlLine,
"extension obsoleted by unknown extension/version <" + extension.second.promotedTo + ">" );
}
if ( !extension.second.promotedTo.empty() )
{
check( ( m_extensions.find( extension.second.promotedTo ) != m_extensions.end() ) ||
( m_features.find( extension.second.promotedTo ) != m_features.end() ),
extension.second.xmlLine,
"extension promoted to unknown extension/version <" + extension.second.promotedTo + ">" );
}
// check for existence of any requirement
for ( auto const & require : extension.second.requireData )
{
check( require.title.empty() || ( m_features.find( require.title ) != m_features.end() ) ||
( m_extensions.find( require.title ) != m_extensions.end() ),
require.xmlLine,
"extension <" + extension.first + "> lists an unknown require <" + require.title + ">" );
}
}
}
void VulkanHppGenerator::checkFuncPointerCorrectness() const
{
for ( auto const & funcPointer : m_funcPointers )
{
if ( !funcPointer.second.requirements.empty() )
{
check( m_types.find( funcPointer.second.requirements ) != m_types.end(),
funcPointer.second.xmlLine,
"funcpointer requires unknown <" + funcPointer.second.requirements + ">" );
}
for ( auto const & argument : funcPointer.second.arguments )
{
check( m_types.find( argument.type ) != m_types.end(),
argument.xmlLine,
"funcpointer argument of unknown type <" + argument.type + ">" );
}
}
}
void VulkanHppGenerator::checkHandleCorrectness() const
{
// prepare handle checks by getting the VkObjectType enum
auto objectTypeIt = m_enums.find( "VkObjectType" );
assert( objectTypeIt != m_enums.end() );
// handle checks
for ( auto const & handle : m_handles )
{
// check the existence of the parent
check( m_handles.find( handle.second.parent ) != m_handles.end(),
handle.second.xmlLine,
"handle <" + handle.first + "> with unknown parent <" + handle.second.parent + ">" );
// check existence of objTypeEnum used with this handle type
if ( !handle.first.empty() )
{
assert( !handle.second.objTypeEnum.empty() );
check( std::find_if( objectTypeIt->second.values.begin(),
objectTypeIt->second.values.end(),
[&handle]( EnumValueData const & evd )
{ return evd.name == handle.second.objTypeEnum; } ) != objectTypeIt->second.values.end(),
handle.second.xmlLine,
"handle <" + handle.first + "> specifies unknown \"objtypeenum\" <" + handle.second.objTypeEnum + ">" );
}
}
// check that all specified objectType values are used with a handle type
for ( auto const & objectTypeValue : objectTypeIt->second.values )
{
if ( objectTypeValue.name != "VK_OBJECT_TYPE_UNKNOWN" )
{
check( std::find_if( m_handles.begin(),
m_handles.end(),
[&objectTypeValue]( std::pair<std::string, HandleData> const & hd )
{ return hd.second.objTypeEnum == objectTypeValue.name; } ) != m_handles.end(),
objectTypeValue.xmlLine,
"VkObjectType value <" + objectTypeValue.name + "> not specified as \"objtypeenum\" for any handle" );
}
}
}
void VulkanHppGenerator::checkStructCorrectness() const
{
for ( auto const & structAlias : m_structureAliases )
{
auto structIt = m_structures.find( structAlias.second.alias );
check( structIt != m_structures.end(),
structAlias.second.xmlLine,
"unknown struct alias <" + structAlias.second.alias + ">" );
}
for ( auto const & structAliasInverse : m_structureAliasesInverse )
{
auto structIt = m_structures.find( structAliasInverse.first );
if ( structIt == m_structures.end() )
{
assert( !structAliasInverse.second.empty() );
auto aliasIt = m_structureAliases.find( *structAliasInverse.second.begin() );
assert( aliasIt != m_structureAliases.end() );
check( false,
aliasIt->second.xmlLine,
"struct <" + aliasIt->first + "> uses unknown alias <" + aliasIt->second.alias + ">" );
}
}
std::set<std::string> sTypeValues;
for ( auto const & structure : m_structures )
{
// check that a struct is referenced somewhere
// I think, it's not forbidden to not reference a struct, but it would probably be not intended?
auto typeIt = m_types.find( structure.first );
assert( typeIt != m_types.end() );
check( !typeIt->second.referencedIn.empty(),
structure.second.xmlLine,
"structure <" + structure.first + "> not listed in any feature or extension" );
// check for existence of all structs that are extended by this struct
for ( auto const & extend : structure.second.structExtends )
{
check( ( m_structures.find( extend ) != m_structures.end() ) ||
( m_structureAliases.find( extend ) != m_structureAliases.end() ),
structure.second.xmlLine,
"struct <" + structure.first + "> extends unknown <" + extend + ">" );
}
// checks on the members of a struct
checkStructMemberCorrectness( structure.first, structure.second.members, sTypeValues );
}
// enum VkStructureType checks (need to be after structure checks because of sTypeValues gathered there)
auto structureTypeIt = m_enums.find( "VkStructureType" );
assert( structureTypeIt != m_enums.end() );
for ( auto const & enumValue : structureTypeIt->second.values )
{
if ( ( enumValue.name == "VK_STRUCTURE_TYPE_LOADER_INSTANCE_CREATE_INFO" ) ||
( enumValue.name == "VK_STRUCTURE_TYPE_LOADER_DEVICE_CREATE_INFO" ) )
{
check( sTypeValues.find( enumValue.name ) == sTypeValues.end(),
enumValue.xmlLine,
"Reserved VkStructureType enum value <" + enumValue.name + "> is used" );
}
else
{
check( sTypeValues.erase( enumValue.name ) == 1,
enumValue.xmlLine,
"VkStructureType enum value <" + enumValue.name + "> never used" );
}
}
assert( sTypeValues.empty() );
}
void VulkanHppGenerator::checkStructMemberCorrectness( std::string const & structureName,
std::vector<MemberData> const & members,
std::set<std::string> & sTypeValues ) const
{
for ( auto const & member : members )
{
// if a member specifies a selector, that member is a union and the selector is an enum
// check that there's a 1-1 connection between the specified selections and the values of that enum
if ( !member.selector.empty() )
{
std::string const & selector = member.selector;
auto selectorIt = std::find_if(
members.begin(), members.end(), [&selector]( MemberData const & md ) { return md.name == selector; } );
assert( selectorIt != members.end() );
auto selectorEnumIt = m_enums.find( selectorIt->type.type );
assert( selectorEnumIt != m_enums.end() );
auto unionIt = m_structures.find( member.type.type );
assert( ( unionIt != m_structures.end() ) && unionIt->second.isUnion );
for ( auto const & unionMember : unionIt->second.members )
{
// check that each union member has a selection, that is a value of the seleting enum
assert( !unionMember.selection.empty() );
std::string const & selection = unionMember.selection;
check( std::find_if( selectorEnumIt->second.values.begin(),
selectorEnumIt->second.values.end(),
[&selection]( EnumValueData const & evd )
{ return evd.name == selection; } ) != selectorEnumIt->second.values.end(),
unionMember.xmlLine,
"union member <" + unionMember.name + "> uses selection <" + selection +
"> that is not part of the selector type <" + selectorIt->type.type + ">" );
}
}
// check that each member type is known
check( m_types.find( member.type.type ) != m_types.end(),
member.xmlLine,
"struct member uses unknown type <" + member.type.type + ">" );
// check that any used constant is a known constant
if ( !member.usedConstant.empty() )
{
check( m_constants.find( member.usedConstant ) != m_constants.end(),
member.xmlLine,
"struct member array size uses unknown constant <" + member.usedConstant + ">" );
}
// checks if a value is specified
if ( !member.value.empty() )
{
auto enumIt = m_enums.find( member.type.type );
if ( enumIt != m_enums.end() )
{
// check that the value exists in the specified enum
check( std::find_if( enumIt->second.values.begin(),
enumIt->second.values.end(),
[&member]( auto const & evd )
{ return member.value == evd.name; } ) != enumIt->second.values.end(),
member.xmlLine,
"value <" + member.value + "> for member <" + member.name + "> in structure <" + structureName +
"> of enum type <" + member.type.type + "> not listed" );
// special handling for sType: no value should appear more than once
if ( member.name == "sType" )
{
check( sTypeValues.insert( member.value ).second,
member.xmlLine,
"sType value <" + member.value + "> has been used before" );
}
}
else if ( member.type.type == "uint32_t" )
{
// check that a value for a uint32_t is all digits
check( member.value.find_first_not_of( "0123456789" ) == std::string::npos,
member.xmlLine,
"value <" + member.value + "> for member <" + member.name + "> in structure <" + structureName +
"> of type <" + member.type.type + "> is not a number" );
}
else
{
// don't know the type of the value -> error out
check( false,
member.xmlLine,
"member <" + member.name + "> in structure <" + structureName + "> holds value <" + member.value +
"> for an unhandled type <" + member.type.type + ">" );
}
}
}
}
bool VulkanHppGenerator::containsArray( std::string const & type ) const
{
// a simple recursive check if a type is or contains an array
auto structureIt = m_structures.find( type );
bool found = false;
if ( structureIt != m_structures.end() )
{
for ( auto memberIt = structureIt->second.members.begin(); memberIt != structureIt->second.members.end() && !found;
++memberIt )
{
found = !memberIt->arraySizes.empty() || containsArray( memberIt->type.type );
}
}
return found;
}
bool VulkanHppGenerator::containsUnion( std::string const & type ) const
{
// a simple recursive check if a type is or contains a union
auto structureIt = m_structures.find( type );
bool found = false;
if ( structureIt != m_structures.end() )
{
found = structureIt->second.isUnion;
for ( auto memberIt = structureIt->second.members.begin(); memberIt != structureIt->second.members.end() && !found;
++memberIt )
{
found = memberIt->type.isValue() && containsUnion( memberIt->type.type );
}
}
return found;
}
std::vector<size_t> VulkanHppGenerator::determineConstPointerParamIndices( std::vector<ParamData> const & params ) const
{
std::vector<size_t> constPointerParamIndices;
for ( size_t i = 0; i < params.size(); i++ )
{
// very special handling for some types, which come in as non-const pointers, but are meant as const-pointers
if ( params[i].type.isConstPointer() ||
( params[i].type.isNonConstPointer() &&
( specialPointerTypes.find( params[i].type.type ) != specialPointerTypes.end() ) ) )
{
constPointerParamIndices.push_back( i );
}
}
return constPointerParamIndices;
}
size_t VulkanHppGenerator::determineDefaultStartIndex( std::vector<ParamData> const & params,
std::set<size_t> const & skippedParams ) const
{
// determine the index where the arguments start to have defaults
size_t defaultStartIndex = INVALID_INDEX;
for ( int i = static_cast<int>( params.size() ) - 1;
( 0 <= i ) && ( params[i].optional || ( skippedParams.find( i ) != skippedParams.end() ) );
--i )
{
defaultStartIndex = i;
}
return defaultStartIndex;
}
size_t VulkanHppGenerator::determineInitialSkipCount( std::string const & command ) const
{
// determine the number of arguments to skip for a function
// -> 0: the command is not bound to an instance or a device (the corresponding handle has no name)
// -> 1: the command bound to an instance or a device (the corresponding handle has a name)
// -> 2: the command has been moved to a second handle
auto commandIt = m_commands.find( command );
assert( commandIt != m_commands.end() );
auto handleIt = m_handles.find( commandIt->second.handle );
assert( handleIt != m_handles.end() );
if ( handleIt->second.commands.find( command ) == handleIt->second.commands.end() )
{
assert( 1 < commandIt->second.params.size() );
assert( m_handles.find( commandIt->second.params[1].type.type ) != m_handles.end() );
return 2;
}
else
{
return handleIt->first.empty() ? 0 : 1;
}
}
std::vector<size_t> VulkanHppGenerator::determineReturnParamIndices( std::vector<ParamData> const & params ) const
{
std::vector<size_t> nonConstPointerParamIndices;
for ( size_t i = 0; i < params.size(); i++ )
{
// very special handling of parameters of some types, which always come as a non-const pointer but are not meant
// to be a potential return value!
if ( params[i].type.isNonConstPointer() &&
( specialPointerTypes.find( params[i].type.type ) == specialPointerTypes.end() ) )
{
nonConstPointerParamIndices.push_back( i );
}
}
return nonConstPointerParamIndices;
}
std::vector<std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator>
VulkanHppGenerator::determineRAIIHandleConstructors(
std::string const & handleType, std::map<std::string, CommandData>::const_iterator destructorIt ) const
{
std::vector<std::map<std::string, CommandData>::const_iterator> constructorIts;
auto isConstructorCandidate = [&handleType]( std::pair<std::string, CommandData> const & cd )
{
return std::find_if( cd.second.params.begin(),
cd.second.params.end(),
[&handleType]( ParamData const & pd ) {
return ( pd.type.type == handleType ) && pd.type.isNonConstPointer();
} ) != cd.second.params.end();
};
for ( auto commandIt = m_commands.begin(); commandIt != m_commands.end(); )
{
// find the commands that get a non-const pointer to the handleType, that is, return a handle type
commandIt = std::find_if( commandIt, m_commands.end(), isConstructorCandidate );
if ( commandIt != m_commands.end() )
{
// only commands that provide all information needed for the destructor can be considered a constructor!
bool valid = true;
if ( destructorIt != m_commands.end() )
{
// get the destructors parameter to the handleType
auto desctructorHandleParamIt =
std::find_if( destructorIt->second.params.begin(),
destructorIt->second.params.end(),
[&handleType]( ParamData const & pd ) { return pd.type.type == handleType; } );
assert( desctructorHandleParamIt != destructorIt->second.params.end() );
// lambda to check if a destructor parameter is a parameter of the constructor candidate
// (or it's just the len parameter, which is not needed for the constructor)
auto isConstructorCandidateParam =
[&desctructorHandleParamIt, &commandIt, this]( ParamData const & destructorParam )
{
// check if the destructor param type equals this param type, or, if this param type is a struct, is part of
// that struct
auto isDestructorParamType = [&destructorParam, this]( ParamData const & pd )
{
if ( pd.type.type != destructorParam.type.type )
{
// check if the destructor param type equals a structure member type
auto isStructureMemberType = [&destructorParam]( MemberData const & md )
{
return md.type.type == destructorParam.type.type;
};
auto structureIt = m_structures.find( pd.type.type );
return ( structureIt != m_structures.end() ) &&
( std::find_if( structureIt->second.members.begin(),
structureIt->second.members.end(),
isStructureMemberType ) != structureIt->second.members.end() );
}
return true;
};
return ( destructorParam.name == desctructorHandleParamIt->len ) ||
( std::find_if( commandIt->second.params.begin(),
commandIt->second.params.end(),
isDestructorParamType ) != commandIt->second.params.end() );
};
// the constructor candidate is valid, if none of the (relevant) destructor parameters is missing in the
// constructor candidate params
valid = ( std::find_if_not( destructorIt->second.params.begin(),
destructorIt->second.params.end(),
isConstructorCandidateParam ) == destructorIt->second.params.end() );
}
if ( valid )
{
// filter out alias functions
if ( commandIt->second.alias.empty() )
{
constructorIts.push_back( commandIt );
}
}
++commandIt;
}
}
assert( !constructorIts.empty() );
return constructorIts;
}
std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator
VulkanHppGenerator::determineRAIIHandleDestructor( std::string const & handleType ) const
{
std::string type = stripPrefix( handleType, "Vk" );
auto destructorIt = m_commands.find( "vkDestroy" + type );
if ( destructorIt == m_commands.end() )
{
destructorIt = m_commands.find( "vkFree" + type + "s" );
if ( destructorIt == m_commands.end() )
{
destructorIt = m_commands.find( "vkRelease" + type );
if ( destructorIt == m_commands.end() )
{
if ( handleType == "VkDeviceMemory" )
{
// special handling for vkDeviceMemory
destructorIt = m_commands.find( "vkFreeMemory" );
assert( destructorIt != m_commands.end() );
}
else if ( handleType == "VkDisplayKHR" )
{
// special handling for VkDisplayKHR
destructorIt = m_commands.find( "vkReleaseDisplayEXT" );
assert( destructorIt != m_commands.end() );
}
else
{
assert( ( handleType == "VkDisplayModeKHR" ) || ( handleType == "VkPhysicalDevice" ) ||
( handleType == "VkQueue" ) );
}
}
}
}
return destructorIt;
}
std::set<size_t> VulkanHppGenerator::determineSkippedParams( std::vector<ParamData> const & params,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & returnParamIndices,
bool singular ) const
{
// skip the initial skips (get fed by the object)
assert( initialSkipCount <= params.size() );
std::set<size_t> skippedParams;
for ( size_t i = 0; i < initialSkipCount; ++i )
{
skippedParams.insert( i );
}
// skip the size parameters (get derived from an array)
for ( auto const & vpi : vectorParamIndices )
{
assert( !params[vpi.first].len.empty() );
if ( ( ( std::find_if( returnParamIndices.begin(),
returnParamIndices.end(),
[&vpi]( size_t rpi ) { return vpi.first == rpi; } ) == returnParamIndices.end() ) &&
isParam( params[vpi.first].len, params ) ) ||
( singular && params[vpi.second].type.isValue() ) )
{
skippedParams.insert( vpi.second );
}
}
// skip the return parameters (get resolved by local variables to be returned)
skippedParams.insert( returnParamIndices.begin(), returnParamIndices.end() );
return skippedParams;
}
std::string VulkanHppGenerator::determineSubStruct( std::pair<std::string, StructureData> const & structure ) const
{
if ( structure.second.members.front().name != "sType" )
{
// check if sd is a substruct of structure
auto isSubStruct = [&structure]( std::pair<std::string, StructureData> const & sd )
{
// member-by-member comparison of type and name
auto memberIt = structure.second.members.begin();
auto isMember = [&memberIt]( MemberData const & md )
{
if ( ( md.type == memberIt->type ) && ( md.name == memberIt->name ) )
{
++memberIt;
return true;
}
return false;
};
return ( sd.second.members.size() < structure.second.members.size() ) &&
( std::find_if_not( sd.second.members.begin(), sd.second.members.end(), isMember ) ==
sd.second.members.end() );
};
// look for a struct in m_structures that starts identically to structure
auto structIt = std::find_if( m_structures.begin(), m_structures.end(), isSubStruct );
return ( structIt == m_structures.end() ) ? "" : structIt->first;
}
return "";
}
std::map<size_t, size_t> VulkanHppGenerator::determineVectorParamIndices( std::vector<ParamData> const & params ) const
{
std::map<size_t, size_t> vectorParamIndices;
// look for the parameters whose len equals the name of an other parameter
for ( size_t i = 0; i < params.size(); i++ )
{
if ( !params[i].len.empty() )
{
for ( size_t j = 0; j < i; j++ )
{
if ( ( params[j].name == params[i].len ) || isLenByStructMember( params[i].len, params[j] ) )
{
// add this parameter as a vector parameter, using the len-name parameter as the second value
vectorParamIndices.insert( std::make_pair( i, j ) );
}
}
}
}
return vectorParamIndices;
}
void VulkanHppGenerator::distributeSecondLevelCommands( std::set<std::string> const & specialFunctions )
{
// distribute commands from instance/device to second-level handles, like Queue, Event,... for RAII handles
for ( auto & handle : m_handles )
{
if ( !handle.first.empty() )
{
for ( auto command = handle.second.commands.begin(); command != handle.second.commands.end(); )
{
bool foundCommand = false;
if ( specialFunctions.find( *command ) == specialFunctions.end() )
{
auto commandIt = m_commands.find( *command );
assert( commandIt != m_commands.end() );
assert( commandIt->second.params.front().type.type == handle.first );
if ( ( 1 < commandIt->second.params.size() ) && ( isHandleType( commandIt->second.params[1].type.type ) ) &&
!commandIt->second.params[1].optional )
{
auto handleIt = m_handles.find( commandIt->second.params[1].type.type );
assert( handleIt != m_handles.end() );
assert( !handleIt->second.constructorIts.empty() );
if ( ( *handleIt->second.constructorIts.begin() )->second.handle == handle.first )
{
assert( std::find_if( handleIt->second.constructorIts.begin(),
handleIt->second.constructorIts.end(),
[&handle]( auto const & constructorIt ) {
return constructorIt->second.handle != handle.first;
} ) == handleIt->second.constructorIts.end() );
handleIt->second.secondLevelCommands.insert( *command );
command = handle.second.commands.erase( command );
foundCommand = true;
}
}
}
if ( !foundCommand )
{
++command;
}
}
}
}
}
std::string VulkanHppGenerator::findBaseName( std::string aliasName,
std::map<std::string, EnumAliasData> const & aliases ) const
{
std::string baseName = aliasName;
auto aliasIt = aliases.find( baseName );
while ( aliasIt != aliases.end() )
{
baseName = aliasIt->second.name;
aliasIt = aliases.find( baseName );
}
return baseName;
}
std::string VulkanHppGenerator::generateArgumentListEnhanced( std::vector<ParamData> const & params,
std::set<size_t> const & skippedParams,
std::set<size_t> const & singularParams,
bool definition,
bool withAllocators,
bool structureChain,
bool withDispatcher ) const
{
size_t defaultStartIndex = withAllocators ? ~0 : determineDefaultStartIndex( params, skippedParams );
std::string argumentList;
bool encounteredArgument = false;
for ( size_t i = 0; i < params.size(); ++i )
{
if ( skippedParams.find( i ) == skippedParams.end() )
{
if ( encounteredArgument )
{
argumentList += ", ";
}
bool hasDefaultAssignment = false;
std::string composedType = params[i].type.compose( "VULKAN_HPP_NAMESPACE" );
if ( singularParams.find( i ) != singularParams.end() )
{
assert( !params[i].optional );
assert( params[i].type.isConstPointer() && !params[i].len.empty() &&
!isLenByStructMember( params[i].len, params ) && beginsWith( params[i].type.type, "Vk" ) );
assert( !isHandleType( params[i].type.type ) );
assert( endsWith( composedType, " *" ) );
argumentList += stripPostfix( composedType, " *" ) + " & " +
stripPluralS( startLowerCase( stripPrefix( params[i].name, "p" ) ) );
}
else if ( params[i].type.isConstPointer() )
{
assert( endsWith( composedType, " *" ) );
std::string name = startLowerCase( stripPrefix( params[i].name, "p" ) );
if ( params[i].len.empty() )
{
assert( withDispatcher || !isHandleType( params[i].type.type ) );
assert( !params[i].type.prefix.empty() && ( params[i].type.postfix == "*" ) );
assert( params[i].arraySizes.empty() );
if ( params[i].type.type == "void" )
{
assert( !params[i].optional );
argumentList += composedType + " " + params[i].name;
}
else if ( params[i].optional )
{
argumentList +=
"Optional<" + stripPostfix( composedType, " *" ) + "> " + name +
( ( definition || withAllocators ) ? "" : " VULKAN_HPP_DEFAULT_ARGUMENT_NULLPTR_ASSIGNMENT" );
hasDefaultAssignment = true;
}
else
{
argumentList += stripPostfix( composedType, " *" ) + " & " + name;
}
}
else
{
// a const-pointer with a non-empty len is either null-terminated (aka a string) or represented by an
// ArrayProxy
assert( params[i].arraySizes.empty() );
if ( params[i].len == "null-terminated" )
{
assert( params[i].type.type == "char" );
if ( params[i].optional )
{
argumentList +=
"Optional<const std::string> " + name +
( ( definition || withAllocators ) ? "" : " VULKAN_HPP_DEFAULT_ARGUMENT_NULLPTR_ASSIGNMENT" );
hasDefaultAssignment = true;
}
else
{
argumentList += "const std::string & " + name;
}
}
else
{
// an ArrayProxy also covers no data, so any optional flag can be ignored here
std::string type = stripPostfix( composedType, " *" );
size_t pos = type.find( "void" );
if ( pos != std::string::npos )
{
type.replace( pos, 4, "T" );
}
argumentList += "ArrayProxy<" + type + "> const & " + name;
if ( params[i].optional && !definition )
{
argumentList += " VULKAN_HPP_DEFAULT_ARGUMENT_NULLPTR_ASSIGNMENT";
hasDefaultAssignment = true;
}
}
}
}
else if ( params[i].type.isNonConstPointer() )
{
assert( withDispatcher || !isHandleType( params[i].type.type ) );
assert( params[i].len.empty() && !params[i].optional );
assert( endsWith( composedType, " *" ) );
argumentList += stripPostfix( composedType, " *" ) + " & " + params[i].name;
}
else
{
assert( params[i].type.isValue() );
argumentList += composedType + " " + params[i].name + generateCArraySizes( params[i].arraySizes );
}
argumentList += std::string( !definition && ( defaultStartIndex <= i ) && !hasDefaultAssignment
? " VULKAN_HPP_DEFAULT_ARGUMENT_ASSIGNMENT"
: "" );
encounteredArgument = true;
}
}
if ( withAllocators )
{
if ( structureChain )
{
if ( encounteredArgument )
{
argumentList += ", ";
}
argumentList += "StructureChainAllocator & structureChainAllocator";
encounteredArgument = true;
}
else
{
for ( auto sp : skippedParams )
{
if ( !params[sp].len.empty() )
{
if ( encounteredArgument )
{
argumentList += ", ";
}
std::string type = ( params[sp].type.type == "void" )
? "Uint8_t"
: startUpperCase( stripPrefix( params[sp].type.type, "Vk" ) );
argumentList += type + "Allocator & " + startLowerCase( type ) + "Allocator";
encounteredArgument = true;
}
}
}
}
if ( withDispatcher )
{
if ( encounteredArgument )
{
argumentList += ", ";
}
argumentList +=
std::string( "Dispatch const & d" ) + ( definition ? "" : " VULKAN_HPP_DEFAULT_DISPATCHER_ASSIGNMENT" );
}
return argumentList;
}
std::string VulkanHppGenerator::generateArgumentListStandard( std::vector<ParamData> const & params,
std::set<size_t> const & skippedParams ) const
{
std::string argumentList;
for ( size_t i = 0; i < params.size(); ++i )
{
if ( skippedParams.find( i ) == skippedParams.end() )
{
argumentList += params[i].type.compose( "VULKAN_HPP_NAMESPACE" ) + " " + params[i].name +
generateCArraySizes( params[i].arraySizes ) + ", ";
}
}
argumentList += "Dispatch const & d ";
return argumentList;
}
std::string VulkanHppGenerator::generateBitmask( std::map<std::string, BitmaskData>::const_iterator bitmaskIt ) const
{
auto bitmaskBitsIt = m_enums.find( bitmaskIt->second.requirements );
assert( bitmaskBitsIt != m_enums.end() );
std::string strippedBitmaskName = stripPrefix( bitmaskIt->first, "Vk" );
std::string strippedEnumName = stripPrefix( bitmaskBitsIt->first, "Vk" );
// each Flags class is using the class 'Flags' with the corresponding FlagBits enum as the template parameter
std::string str = "\n using " + strippedBitmaskName + " = Flags<" + strippedEnumName + ">;\n";
std::string alias =
bitmaskIt->second.alias.empty()
? ""
: ( "\n using " + stripPrefix( bitmaskIt->second.alias, "Vk" ) + " = " + strippedBitmaskName + ";\n" );
if ( bitmaskBitsIt->second.values.empty() )
{
static std::string bitmaskValuesTemplate = R"(${alias}
VULKAN_HPP_INLINE std::string to_string( ${bitmaskName} )
{
return "{}";
}
)";
str += replaceWithMap( bitmaskValuesTemplate, { { "alias", alias }, { "bitmaskName", strippedBitmaskName } } );
}
else
{
static const std::string bitmaskValuesTemplate = R"(
template <> struct FlagTraits<${enumName}>
{
enum : ${bitmaskType}
{
allFlags = ${allFlags}
};
};
VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR ${bitmaskName} operator|( ${enumName} bit0, ${enumName} bit1 ) VULKAN_HPP_NOEXCEPT
{
return ${bitmaskName}( bit0 ) | bit1;
}
VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR ${bitmaskName} operator&( ${enumName} bit0, ${enumName} bit1 ) VULKAN_HPP_NOEXCEPT
{
return ${bitmaskName}( bit0 ) & bit1;
}
VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR ${bitmaskName} operator^( ${enumName} bit0, ${enumName} bit1 ) VULKAN_HPP_NOEXCEPT
{
return ${bitmaskName}( bit0 ) ^ bit1;
}
VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR ${bitmaskName} operator~( ${enumName} bits ) VULKAN_HPP_NOEXCEPT
{
return ~( ${bitmaskName}( bits ) );
}
${alias}
VULKAN_HPP_INLINE std::string to_string( ${bitmaskName} value )
{
if ( !value )
return "{}";
std::string result;
${toStringChecks}
return "{ " + result.substr( 0, result.size() - 3 ) + " }";
}
)";
std::string allFlags, toStringChecks;
bool encounteredFlag = false;
std::string previousEnter, previousLeave;
for ( auto const & value : bitmaskBitsIt->second.values )
{
auto [enter, leave] = generateProtection( value.extension, value.protect );
std::string valueName = generateEnumValueName( bitmaskBitsIt->first, value.name, true, m_tags );
allFlags += ( ( previousEnter != enter ) ? ( "\n" + previousLeave + enter ) : "\n" ) + " " +
( encounteredFlag ? "| " : " " ) + bitmaskIt->second.type + "( " + strippedEnumName +
"::" + valueName + " )";
if ( value.singleBit )
{
toStringChecks += ( ( previousEnter != enter ) ? ( previousLeave + enter ) : "" ) + " if ( value & " +
strippedEnumName + "::" + valueName + " ) result += \"" + valueName.substr( 1 ) + " | \";\n";
}
encounteredFlag = true;
previousEnter = enter;
previousLeave = leave;
}
if ( !previousLeave.empty() )
{
assert( endsWith( previousLeave, "\n" ) );
toStringChecks += previousLeave;
previousLeave.resize( previousLeave.size() - strlen( "\n" ) );
allFlags += "\n" + previousLeave;
}
str += replaceWithMap( bitmaskValuesTemplate,
{ { "alias", alias },
{ "allFlags", allFlags },
{ "bitmaskName", strippedBitmaskName },
{ "bitmaskType", bitmaskIt->second.type },
{ "enumName", strippedEnumName },
{ "toStringChecks", toStringChecks } } );
}
return str;
}
std::string VulkanHppGenerator::generateBitmasks( std::vector<RequireData> const & requireData,
std::set<std::string> & listedBitmasks,
std::string const & title ) const
{
std::string str;
for ( auto const & require : requireData )
{
for ( auto const & type : require.types )
{
auto bitmaskIt = m_bitmasks.find( type );
if ( ( bitmaskIt != m_bitmasks.end() ) && ( listedBitmasks.find( type ) == listedBitmasks.end() ) )
{
listedBitmasks.insert( type );
str += generateBitmask( bitmaskIt );
}
}
}
return addTitleAndProtection( title, str );
}
std::string VulkanHppGenerator::generateCallArgumentsEnhanced( CommandData const & commandData,
size_t initialSkipCount,
bool nonConstPointerAsNullptr,
std::set<size_t> const & singularParams,
bool raiiHandleMemberFunction ) const
{
assert( initialSkipCount <= commandData.params.size() );
std::string arguments;
bool encounteredArgument = false;
if ( raiiHandleMemberFunction )
{
switch ( initialSkipCount )
{
case 1:
assert( isHandleType( commandData.params[0].type.type ) && commandData.params[0].type.isValue() );
assert( commandData.params[0].arraySizes.empty() && commandData.params[0].len.empty() );
assert( commandData.params[0].type.type == commandData.handle );
arguments = "static_cast<" + commandData.handle + ">( m_" +
startLowerCase( stripPrefix( commandData.handle, "Vk" ) ) + " )";
encounteredArgument = true;
break;
case 2:
{
assert( isHandleType( commandData.params[0].type.type ) && commandData.params[0].type.isValue() );
assert( commandData.params[0].arraySizes.empty() && commandData.params[0].len.empty() );
assert( commandData.params[0].type.type == commandData.handle );
auto handleIt = m_handles.find( commandData.params[1].type.type );
assert( handleIt != m_handles.end() );
arguments = "static_cast<" + commandData.handle + ">( m_" +
startLowerCase( stripPrefix( commandData.handle, "Vk" ) ) + " )";
assert( commandData.params[1].type.isValue() && commandData.params[1].arraySizes.empty() &&
commandData.params[1].len.empty() );
arguments += ", static_cast<" + commandData.params[1].type.type + ">( m_" +
generateRAIIHandleConstructorParamName( handleIt->first, handleIt->second.destructorIt ) + " )";
encounteredArgument = true;
}
break;
}
}
else
{
for ( size_t i = 0; i < initialSkipCount; ++i )
{
if ( encounteredArgument )
{
arguments += ", ";
}
assert( isHandleType( commandData.params[i].type.type ) && commandData.params[i].type.isValue() );
assert( commandData.params[i].arraySizes.empty() && commandData.params[i].len.empty() );
arguments += "m_" + startLowerCase( stripPrefix( commandData.params[i].type.type, "Vk" ) );
encounteredArgument = true;
}
}
for ( size_t i = initialSkipCount; i < commandData.params.size(); ++i )
{
if ( encounteredArgument )
{
arguments += ", ";
}
arguments += generateCallArgumentEnhanced(
commandData.params, i, nonConstPointerAsNullptr, singularParams, raiiHandleMemberFunction );
encounteredArgument = true;
}
return arguments;
}
std::string VulkanHppGenerator::generateCallArgumentsRAIIFactory( std::vector<ParamData> const & params,
size_t initialSkipCount,
std::set<size_t> const & skippedParameters,
std::set<size_t> const & singularParams ) const
{
assert( initialSkipCount <= params.size() );
std::string arguments = "*this";
// skip the last parameter!
for ( size_t i = initialSkipCount; i < params.size() - 1; ++i )
{
if ( skippedParameters.find( i ) == skippedParameters.end() )
{
std::string argument = params[i].name;
if ( !params[i].type.isValue() )
{
argument = startLowerCase( stripPrefix( argument, "p" ) );
if ( singularParams.find( i ) != singularParams.end() )
{
argument = stripPluralS( argument );
}
}
else
{
assert( singularParams.find( i ) == singularParams.end() );
}
arguments += ", " + argument;
}
}
return arguments;
}
std::string VulkanHppGenerator::generateCallArgumentsStandard( std::string const & handle,
std::vector<ParamData> const & params ) const
{
std::string arguments;
bool encounteredArgument = false;
for ( auto const & param : params )
{
if ( encounteredArgument )
{
arguments += ", ";
}
if ( ( param.type.type == handle ) && param.type.isValue() )
{
assert( param.arraySizes.empty() && param.len.empty() );
arguments += "m_" + startLowerCase( stripPrefix( param.type.type, "Vk" ) );
}
else
{
std::string argument = param.name;
if ( beginsWith( param.type.type, "Vk" ) )
{
if ( !param.arraySizes.empty() )
{
assert( param.arraySizes.size() == 1 );
assert( param.type.isValue() );
assert( param.type.postfix.empty() );
argument = "reinterpret_cast<" + param.type.compose( "" ) + " *>( " + argument + " )";
}
else if ( param.type.isValue() )
{
argument = "static_cast<" + param.type.type + ">( " + argument + " )";
}
else
{
assert( !param.type.postfix.empty() );
argument = "reinterpret_cast<" + param.type.compose( "" ) + ">( " + argument + " )";
}
}
arguments += argument;
}
encounteredArgument = true;
}
return arguments;
}
std::string VulkanHppGenerator::generateCallArgumentEnhanced( std::vector<ParamData> const & params,
size_t paramIndex,
bool nonConstPointerAsNullptr,
std::set<size_t> const & singularParams,
bool raiiHandleMemberFunction ) const
{
std::string argument;
ParamData const & param = params[paramIndex];
if ( param.type.isConstPointer() || ( specialPointerTypes.find( param.type.type ) != specialPointerTypes.end() ) )
{
// parameter is a const-pointer or one of the special pointer types that are considered to be const-pointers
argument = generateCallArgumentEnhancedConstPointer( param, paramIndex, singularParams );
}
else if ( param.type.isNonConstPointer() &&
( specialPointerTypes.find( param.type.type ) == specialPointerTypes.end() ) )
{
// parameter is a non-const pointer and none of the special pointer types, that are considered const-pointers
argument = generateCallArgumentEnhancedNonConstPointer(
param, paramIndex, nonConstPointerAsNullptr, singularParams, raiiHandleMemberFunction );
}
else
{
argument = generateCallArgumentEnhancedValue( params, paramIndex, singularParams );
}
assert( !argument.empty() );
return argument;
}
std::string VulkanHppGenerator::generateCallArgumentEnhancedConstPointer(
ParamData const & param, size_t paramIndex, std::set<size_t> const & singularParams ) const
{
std::string argument;
std::string name = startLowerCase( stripPrefix( param.name, "p" ) );
if ( isHandleType( param.type.type ) && param.type.isValue() )
{
assert( !param.optional );
// if at all, this is the first argument, and it's the implicitly provided member handle
assert( paramIndex == 0 );
assert( param.arraySizes.empty() && param.len.empty() );
argument = "m_" + startLowerCase( stripPrefix( param.type.type, "Vk" ) );
}
else if ( param.len.empty() )
{
// this const-pointer parameter has no length, that is it's a const-pointer to a single value
if ( param.type.type == "void" )
{
assert( !param.optional );
// use the original name here, as void-pointer are not mapped to some reference
argument = param.name;
}
else if ( param.optional )
{
argument = "static_cast<" + param.type.compose( "VULKAN_HPP_NAMESPACE" ) + ">( " + name + " )";
}
else
{
argument = "&" + name;
}
if ( beginsWith( param.type.type, "Vk" ) )
{
argument = "reinterpret_cast<" + param.type.compose( "" ) + ">( " + argument + " )";
}
}
else if ( param.len == "null-terminated" )
{
// this const-pointer parameter is "null-terminated", that is it's a string
assert( ( param.type.type == "char" ) && param.arraySizes.empty() );
if ( param.optional )
{
argument = name + " ? " + name + "->c_str() : nullptr";
}
else
{
argument = name + ".c_str()";
}
}
else
{
// this const-pointer parameter has some explicit length
if ( singularParams.find( paramIndex ) != singularParams.end() )
{
assert( !param.optional );
argument = "&" + stripPluralS( name );
}
else
{
// this const-parameter is represented by some array, where data() also works with no data (optional)
argument = name + ".data()";
}
if ( beginsWith( param.type.type, "Vk" ) || ( param.type.type == "void" ) )
{
argument = "reinterpret_cast<" + param.type.compose( "" ) + ">( " + argument + " )";
}
}
return argument;
}
std::string VulkanHppGenerator::generateCallArgumentEnhancedNonConstPointer( ParamData const & param,
size_t paramIndex,
bool nonConstPointerAsNullptr,
std::set<size_t> const & singularParams,
bool raiiHandleMemberFunction ) const
{
std::string argument;
std::string name = startLowerCase( stripPrefix( param.name, "p" ) );
if ( param.len.empty() )
{
assert( param.arraySizes.empty() );
if ( beginsWith( param.type.type, "Vk" ) )
{
argument = "reinterpret_cast<" + param.type.compose( "" ) + ">( &" + name + " )";
}
else
{
assert( !param.optional );
argument = "&" + name;
}
}
else
{
// the non-const pointer has a len -> it will be represented by some array
assert( param.arraySizes.empty() );
if ( nonConstPointerAsNullptr )
{
argument = "nullptr";
}
else
{
if ( singularParams.find( paramIndex ) != singularParams.end() )
{
argument = "&" + stripPluralS( name );
}
else
{
// get the data of the array, which also covers no data -> no need to look at param.optional
argument = name + ".data()";
}
if ( ( beginsWith( param.type.type, "Vk" ) || ( param.type.type == "void" ) ) &&
( !raiiHandleMemberFunction || !isHandleType( param.type.type ) ) )
{
argument = "reinterpret_cast<" + param.type.compose( "" ) + ">( " + argument + " )";
}
}
}
return argument;
}
std::string VulkanHppGenerator::generateCallArgumentEnhancedValue( std::vector<ParamData> const & params,
size_t paramIndex,
std::set<size_t> const & singularParams ) const
{
std::string argument;
ParamData const & param = params[paramIndex];
assert( param.len.empty() );
if ( beginsWith( param.type.type, "Vk" ) )
{
if ( param.arraySizes.empty() )
{
auto pointerIt =
std::find_if( params.begin(), params.end(), [&param]( ParamData const & pd ) { return pd.len == param.name; } );
if ( pointerIt != params.end() )
{
assert( !param.optional );
argument = startLowerCase( stripPrefix( pointerIt->name, "p" ) ) + ".size()";
if ( pointerIt->type.type == "void" )
{
argument += " * sizeof( T )";
}
}
else
{
argument = "static_cast<" + param.type.compose( "" ) + ">( " + param.name + " )";
}
}
else
{
assert( !param.optional );
assert( param.arraySizes.size() == 1 );
assert( param.type.prefix == "const" );
argument = "reinterpret_cast<" + param.type.compose( "" ) + " *>( " + param.name + " )";
}
}
else
{
auto pointerIt =
std::find_if( params.begin(), params.end(), [&param]( ParamData const & pd ) { return pd.len == param.name; } );
if ( pointerIt != params.end() )
{
// this parameter is the len of some other -> replace it with that parameter's size
assert( param.arraySizes.empty() );
assert( ( param.type.type == "size_t" ) || ( param.type.type == "uint32_t" ) );
if ( singularParams.find( paramIndex ) == singularParams.end() )
{
argument = startLowerCase( stripPrefix( pointerIt->name, "p" ) ) + ".size()";
if ( pointerIt->type.type == "void" )
{
argument += " * sizeof( T )";
}
}
else
{
if ( pointerIt->type.type == "void" )
{
argument = "sizeof( T )";
}
else
{
argument = "1";
}
}
}
else
{
assert( !param.optional );
assert( param.arraySizes.size() <= 1 );
argument = param.name;
}
}
return argument;
}
std::string VulkanHppGenerator::generateCommand( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition ) const
{
std::string str;
if ( commandData.returnType == "VkResult" )
{
assert( !commandData.successCodes.empty() );
if ( commandData.successCodes.size() == 1 )
{
if ( commandData.errorCodes.empty() )
{
str = generateCommandResultSingleSuccessNoErrors( name, commandData, initialSkipCount, definition );
}
else
{
str = generateCommandResultSingleSuccessWithErrors( name, commandData, initialSkipCount, definition );
}
}
else
{
if ( commandData.errorCodes.empty() )
{
str = generateCommandResultMultiSuccessNoErrors( name, commandData, initialSkipCount, definition );
}
else
{
str = generateCommandResultMultiSuccessWithErrors( name, commandData, initialSkipCount, definition );
}
}
}
else if ( commandData.returnType == "void" )
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( commandData.params );
switch ( returnParamIndices.size() )
{
case 0: str = generateCommandVoid0Return( name, commandData, initialSkipCount, definition ); break;
case 1:
str = generateCommandVoid1Return( name, commandData, initialSkipCount, definition, returnParamIndices[0] );
break;
case 2:
str = generateCommandVoid2Return( name, commandData, initialSkipCount, definition, returnParamIndices );
break;
}
}
else
{
str = generateCommandValue( name, commandData, initialSkipCount, definition );
}
if ( str.empty() )
{
throw std::runtime_error( "Never encountered a function like <" + name + "> !" );
}
return str;
}
std::string VulkanHppGenerator::generateCommandDefinitions( std::vector<RequireData> const & requireData,
std::set<std::string> & listedCommands,
std::string const & title ) const
{
std::string str;
for ( auto const & require : requireData )
{
for ( auto const & command : require.commands )
{
if ( listedCommands.insert( command ).second )
{
auto commandIt = m_commands.find( command );
assert( commandIt != m_commands.end() );
str += generateCommandDefinitions( command, commandIt->second.handle );
}
}
}
return addTitleAndProtection( title, str );
}
std::string VulkanHppGenerator::generateCommandDefinitions( std::string const & command,
std::string const & handle ) const
{
auto commandIt = m_commands.find( command );
assert( commandIt != m_commands.end() );
std::string str = "\n" + generateCommand( commandIt->first, commandIt->second, handle.empty() ? 0 : 1, true );
// special handling for destroy functions, filter out alias functions
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, 1, m_tags );
if ( commandIt->second.alias.empty() &&
( ( ( commandIt->first.substr( 2, 7 ) == "Destroy" ) && ( commandName != "destroy" ) ) ||
( commandIt->first.substr( 2, 4 ) == "Free" ) ||
( commandIt->first == "vkReleasePerformanceConfigurationINTEL" ) ) )
{
CommandData commandData = commandIt->second;
assert( ( 1 < commandData.params.size() ) && ( commandData.params[0].type.type == handle ) );
commandData.params[1].optional =
false; // make sure, the object to destroy/free/release is not optional in the shortened version!
std::string destroyCommandString = generateCommand( commandIt->first, commandData, handle.empty() ? 0 : 1, true );
std::string shortenedName;
if ( commandIt->first.substr( 2, 7 ) == "Destroy" )
{
shortenedName = "destroy";
}
else if ( commandIt->first.substr( 2, 4 ) == "Free" )
{
shortenedName = "free";
}
else
{
assert( commandIt->first == "vkReleasePerformanceConfigurationINTEL" );
shortenedName = "release";
}
size_t pos = destroyCommandString.find( commandName );
while ( pos != std::string::npos )
{
destroyCommandString.replace( pos, commandName.length(), shortenedName );
pos = destroyCommandString.find( commandName, pos );
}
// we need to remove the default argument for the first argument, to prevent ambiguities!
assert( 1 < commandIt->second.params.size() );
pos = destroyCommandString.find( commandIt->second.params[1].name ); // skip the standard version of the function
assert( pos != std::string::npos );
pos = destroyCommandString.find( commandIt->second.params[1].name,
pos + 1 ); // get the argument to destroy in the advanced version
assert( pos != std::string::npos );
pos = destroyCommandString.find( " VULKAN_HPP_DEFAULT_ARGUMENT_ASSIGNMENT", pos );
if ( pos != std::string::npos )
{
destroyCommandString.erase( pos, strlen( " VULKAN_HPP_DEFAULT_ARGUMENT_ASSIGNMENT" ) );
}
str += "\n" + destroyCommandString;
}
return str;
}
std::string VulkanHppGenerator::generateCommandName( std::string const & vulkanCommandName,
std::vector<ParamData> const & params,
size_t initialSkipCount,
std::set<std::string> const & tags ) const
{
std::string commandName( startLowerCase( stripPrefix( vulkanCommandName, "vk" ) ) );
for ( size_t i = initialSkipCount - 1; i < initialSkipCount; --i ) // count down to zero, then wrap around and stop
{
std::string const & argumentType = params[i].type.type;
std::string searchName = stripPrefix( argumentType, "Vk" );
std::string argumentTag = findTag( tags, argumentType );
if ( !argumentTag.empty() )
{
searchName = stripPostfix( searchName, argumentTag );
}
size_t pos = commandName.find( searchName );
if ( pos == std::string::npos )
{
searchName = startLowerCase( searchName );
pos = commandName.find( searchName );
}
if ( pos != std::string::npos )
{
size_t len = searchName.length();
if ( commandName.find( searchName + "s" ) == pos )
{
// filter out any plural of the searchName as well!
++len;
}
commandName.erase( pos, len );
}
else if ( ( searchName == "commandBuffer" ) && beginsWith( commandName, "cmd" ) )
{
commandName.erase( 0, 3 );
pos = 0;
}
if ( pos == 0 )
{
commandName = startLowerCase( commandName );
}
std::string commandTag = findTag( tags, commandName );
if ( !argumentTag.empty() && ( argumentTag == commandTag ) )
{
commandName = stripPostfix( commandName, argumentTag );
}
}
return commandName;
}
std::string VulkanHppGenerator::generateCommandResult( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices ) const
{
assert( commandData.returnType == "VkResult" );
std::set<size_t> skippedParameters =
determineSkippedParams( commandData.params, initialSkipCount, vectorParamIndices, {}, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParameters, {}, definition, false, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnType = ( 1 < commandData.successCodes.size() ) ? "Result" : "typename ResultValueType<void>::type";
if ( definition )
{
std::string const functionTemplate =
R"( template <typename Dispatch>
${nodiscard}VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
return createResultValue( result, VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}"${successCodeList} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
${nodiscard}${returnType} ${commandName}( ${argumentList} ) const;)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "returnType", returnType } } );
}
}
std::string VulkanHppGenerator::generateCommandResultEnumerate( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::pair<size_t, size_t> const & vectorParamIndices,
bool withAllocator ) const
{
assert( commandData.returnType == "VkResult" );
assert( ( commandData.successCodes.size() == 2 ) && ( commandData.successCodes[0] == "VK_SUCCESS" ) &&
( commandData.successCodes[1] == "VK_INCOMPLETE" ) );
std::set<size_t> skippedParams = determineSkippedParams( commandData.params,
initialSkipCount,
{ vectorParamIndices },
{ vectorParamIndices.second, vectorParamIndices.first },
false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, withAllocator, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string vectorElementType = ( commandData.params[vectorParamIndices.first].type.type == "void" )
? "uint8_t"
: stripPrefix( commandData.params[vectorParamIndices.first].type.type, "Vk" );
std::string allocatorType = startUpperCase( vectorElementType ) + "Allocator";
if ( definition )
{
const std::string functionTemplate =
R"( template <typename ${allocatorType}, typename Dispatch${typenameCheck}>
${nodiscard}VULKAN_HPP_INLINE typename ResultValueType<std::vector<${vectorElementType}, ${allocatorType}>>::type ${className}${classSeparator}${commandName}( ${argumentList} )${const}
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
std::vector<${vectorElementType}, ${allocatorType}> ${vectorName}${vectorAllocator};
${counterType} ${counterName};
Result result;
do
{
result = static_cast<Result>( d.${vkCommand}( ${firstCallArguments} ) );
if ( ( result == Result::eSuccess ) && ${counterName} )
{
${vectorName}.resize( ${counterName} );
result = static_cast<Result>( d.${vkCommand}( ${secondCallArguments} ) );
}
} while ( result == Result::eIncomplete );
if ( result == VULKAN_HPP_NAMESPACE::Result::eSuccess )
{
VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() );
if ( ${counterName} < ${vectorName}.size() )
{
${vectorName}.resize( ${counterName} );
}
}
return createResultValue( result, ${vectorName}, VULKAN_HPP_NAMESPACE_STRING"::${className}${classSeparator}${commandName}" );
})";
std::string typenameCheck = withAllocator
? ( ", typename B, typename std::enable_if<std::is_same<typename B::value_type, " +
vectorElementType + ">::value, int>::type " )
: "";
return replaceWithMap(
functionTemplate,
{ { "allocatorType", allocatorType },
{ "argumentList", argumentList },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "const", commandData.handle.empty() ? "" : " const" },
{ "counterName", startLowerCase( stripPrefix( commandData.params[vectorParamIndices.second].name, "p" ) ) },
{ "counterType", commandData.params[vectorParamIndices.second].type.type },
{ "firstCallArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, true, {}, false ) },
{ "nodiscard", nodiscard },
{ "secondCallArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "typenameCheck", typenameCheck },
{ "vectorAllocator", withAllocator ? ( "( " + startLowerCase( allocatorType ) + " )" ) : "" },
{ "vectorElementType", vectorElementType },
{ "vectorName", startLowerCase( stripPrefix( commandData.params[vectorParamIndices.first].name, "p" ) ) },
{ "vkCommand", name } } );
}
else
{
const std::string functionTemplate =
R"( template <typename ${allocatorType} = std::allocator<${vectorElementType}>, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE${typenameCheck}>
${nodiscard}typename ResultValueType<std::vector<${vectorElementType}, ${allocatorType}>>::type ${commandName}( ${argumentList} )${const};)";
std::string typenameCheck = withAllocator ? ( ", typename B = " + allocatorType +
", typename std::enable_if<std::is_same<typename B::value_type, " +
vectorElementType + ">::value, int>::type = 0" )
: "";
return replaceWithMap( functionTemplate,
{ { "allocatorType", allocatorType },
{ "argumentList", argumentList },
{ "const", commandData.handle.empty() ? "" : " const" },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "typenameCheck", typenameCheck },
{ "vectorElementType", vectorElementType } } );
}
}
std::string
VulkanHppGenerator::generateCommandResultEnumerateChained( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::pair<size_t, size_t> const & vectorParamIndex,
bool withAllocator ) const
{
std::set<size_t> skippedParams = determineSkippedParams( commandData.params,
initialSkipCount,
{ vectorParamIndex },
{ vectorParamIndex.second, vectorParamIndex.first },
false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, withAllocator, true, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string vectorElementType =
stripPostfix( commandData.params[vectorParamIndex.first].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" );
std::string allocatorType = startUpperCase( vectorElementType ) + "Allocator";
if ( definition )
{
const std::string functionTemplate =
R"( template <typename StructureChain, typename StructureChainAllocator, typename Dispatch${typenameCheck}>
${nodiscard}VULKAN_HPP_INLINE std::vector<StructureChain, StructureChainAllocator> ${className}${classSeparator}${commandName}( ${argumentList} )${const}
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
std::vector<StructureChain, StructureChainAllocator> returnVector${structureChainAllocator};
std::vector<${vectorElementType}> ${vectorName};
${counterType} ${counterName};
Result result;
do
{
result = static_cast<Result>( d.${vkCommand}( ${firstCallArguments} ) );
if ( ( result == Result::eSuccess ) && ${counterName} )
{
returnVector.resize( ${counterName} );
${vectorName}.resize( ${counterName} );
for ( ${counterType} i = 0; i < ${counterName}; i++ )
{
${vectorName}[i].pNext = returnVector[i].template get<${vectorElementType}>().pNext;
}
result = static_cast<Result>( d.${vkCommand}( ${secondCallArguments} ) );
}
} while ( result == Result::eIncomplete );
if ( result == VULKAN_HPP_NAMESPACE::Result::eSuccess )
{
VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() );
if ( ${counterName} < ${vectorName}.size() )
{
returnVector.resize( ${counterName} );
}
for ( ${counterType} i = 0; i < ${counterName}; i++ )
{
returnVector[i].template get<${vectorElementType}>() = ${vectorName}[i];
}
}
return createResultValue( result, returnVector, VULKAN_HPP_NAMESPACE_STRING"::${className}${classSeparator}${commandName}" );
})";
std::string typenameCheck = withAllocator
? ( ", typename B, typename std::enable_if<std::is_same<typename B::value_type, " +
vectorElementType + ">::value, int>::type " )
: "";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "const", commandData.handle.empty() ? "" : " const" },
{ "counterName", startLowerCase( stripPrefix( commandData.params[vectorParamIndex.second].name, "p" ) ) },
{ "counterType", commandData.params[vectorParamIndex.second].type.type },
{ "firstCallArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, true, {}, false ) },
{ "nodiscard", nodiscard },
{ "secondCallArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "structureChainAllocator", withAllocator ? ( "( structureChainAllocator )" ) : "" },
{ "typenameCheck", typenameCheck },
{ "vectorElementType", vectorElementType },
{ "vectorName", startLowerCase( stripPrefix( commandData.params[vectorParamIndex.first].name, "p" ) ) },
{ "vkCommand", name } } );
}
else
{
const std::string functionTemplate =
R"( template <typename StructureChain, typename StructureChainAllocator = std::allocator<StructureChain>, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE${typenameCheck}>
${nodiscard}std::vector<StructureChain, StructureChainAllocator> ${commandName}( ${argumentList} )${const};)";
std::string typenameCheck =
withAllocator
? ( ", typename B = StructureChainAllocator, typename std::enable_if<std::is_same<typename B::value_type, " +
vectorElementType + ">::value, int>::type = 0" )
: "";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "const", commandData.handle.empty() ? "" : " const" },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "typenameCheck", typenameCheck } } );
}
}
std::string
VulkanHppGenerator::generateCommandResultEnumerateTwoVectors( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & returnParamIndices,
bool withAllocators ) const
{
assert( !commandData.handle.empty() && ( commandData.returnType == "VkResult" ) );
assert( ( commandData.successCodes.size() == 2 ) && ( commandData.successCodes[0] == "VK_SUCCESS" ) &&
( commandData.successCodes[1] == "VK_INCOMPLETE" ) );
auto firstVectorParamIt = vectorParamIndices.begin();
auto secondVectorParamIt = std::next( firstVectorParamIt );
assert( commandData.params[0].type.type == commandData.handle );
assert( firstVectorParamIt->second == secondVectorParamIt->second );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, withAllocators, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string templateTypeFirst = stripPrefix( commandData.params[firstVectorParamIt->first].type.type, "Vk" );
std::string templateTypeSecond = stripPrefix( commandData.params[secondVectorParamIt->first].type.type, "Vk" );
assert( isupper( templateTypeFirst[0] ) && isupper( templateTypeSecond[0] ) );
if ( definition )
{
const std::string functionTemplate =
R"( template <typename ${templateTypeFirst}Allocator, typename ${templateTypeSecond}Allocator, typename Dispatch${typenameCheck}>
${nodiscard}VULKAN_HPP_INLINE typename ResultValueType<std::pair<std::vector<${templateTypeFirst}, ${templateTypeFirst}Allocator>, std::vector<${templateTypeSecond}, ${templateTypeSecond}Allocator>>>::type ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
std::pair<std::vector<${templateTypeFirst}, ${templateTypeFirst}Allocator>, std::vector<${templateTypeSecond}, ${templateTypeSecond}Allocator>> data${pairConstructor};
std::vector<${templateTypeFirst}, ${templateTypeFirst}Allocator> & ${firstVectorName} = data.first;
std::vector<${templateTypeSecond}, ${templateTypeSecond}Allocator> & ${secondVectorName} = data.second;
${counterType} ${counterName};
Result result;
do
{
result = static_cast<Result>( d.${vkCommand}( ${firstCallArguments} ) );
if ( ( result == Result::eSuccess ) && counterCount )
{
${firstVectorName}.resize( ${counterName} );
${secondVectorName}.resize( ${counterName} );
result = static_cast<Result>( d.${vkCommand}( ${secondCallArguments} ) );
VULKAN_HPP_ASSERT( ${counterName} <= ${firstVectorName}.size() );
}
} while ( result == Result::eIncomplete );
if ( ( result == Result::eSuccess ) && ( ${counterName} < ${firstVectorName}.size() ) )
{
${firstVectorName}.resize( ${counterName} );
${secondVectorName}.resize( ${counterName} );
}
return createResultValue( result, data, VULKAN_HPP_NAMESPACE_STRING"::${className}${classSeparator}${commandName}" );
})";
std::string pairConstructor =
withAllocators
? ( "( std::piecewise_construct, std::forward_as_tuple( " +
startLowerCase( stripPrefix( commandData.params[firstVectorParamIt->first].type.type, "Vk" ) ) +
"Allocator ), std::forward_as_tuple( " +
startLowerCase( stripPrefix( commandData.params[secondVectorParamIt->first].type.type, "Vk" ) ) +
"Allocator ) )" )
: "";
std::string typenameCheck =
withAllocators ? ( ", typename B1, typename B2, typename std::enable_if<std::is_same<typename B1::value_type, " +
templateTypeFirst + ">::value && std::is_same<typename B2::value_type, " + templateTypeSecond +
">::value, int>::type " )
: "";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "counterName",
startLowerCase( stripPrefix( stripPluralS( commandData.params[firstVectorParamIt->second].name ), "p" ) ) },
{ "counterType", commandData.params[firstVectorParamIt->second].type.type },
{ "firstCallArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, true, {}, false ) },
{ "firstVectorName", startLowerCase( stripPrefix( commandData.params[firstVectorParamIt->first].name, "p" ) ) },
{ "nodiscard", nodiscard },
{ "pairConstructor", pairConstructor },
{ "secondCallArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "secondVectorName",
startLowerCase( stripPrefix( commandData.params[secondVectorParamIt->first].name, "p" ) ) },
{ "templateTypeFirst", templateTypeFirst },
{ "templateTypeSecond", templateTypeSecond },
{ "typenameCheck", typenameCheck },
{ "vkCommand", name } } );
}
else
{
const std::string functionTemplate =
R"( template <typename ${templateTypeFirst}Allocator = std::allocator<${templateTypeFirst}>, typename ${templateTypeSecond}Allocator = std::allocator<${templateTypeSecond}>, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE${typenameCheck}>
${nodiscard}typename ResultValueType<std::pair<std::vector<${templateTypeFirst}, ${templateTypeFirst}Allocator>, std::vector<${templateTypeSecond}, ${templateTypeSecond}Allocator>>>::type ${commandName}( ${argumentList} ) const;)";
std::string typenameCheck =
withAllocators
? ( ", typename B1 = " + templateTypeFirst + "Allocator, typename B2 = " + templateTypeSecond +
"Allocator, typename std::enable_if<std::is_same<typename B1::value_type, " + templateTypeFirst +
">::value && std::is_same<typename B2::value_type, " + templateTypeSecond + ">::value, int>::type = 0" )
: "";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "templateTypeFirst", templateTypeFirst },
{ "templateTypeSecond", templateTypeSecond },
{ "typenameCheck", typenameCheck } } );
}
}
std::string VulkanHppGenerator::generateCommandResultGetChain( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
assert( !commandData.handle.empty() && ( commandData.returnType == "VkResult" ) && !commandData.errorCodes.empty() );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, {}, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, false, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnType =
stripPostfix( commandData.params[returnParamIndex].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename X, typename Y, typename... Z, typename Dispatch>
VULKAN_HPP_NODISCARD_WHEN_NO_EXCEPTIONS VULKAN_HPP_INLINE typename ResultValueType<StructureChain<X, Y, Z...>>::type ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
StructureChain<X, Y, Z...> structureChain;
${returnType} & ${returnVariable} = structureChain.template get<${returnType}>();
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
return createResultValue( result, structureChain, VULKAN_HPP_NAMESPACE_STRING"::${className}${classSeparator}${commandName}"${successCodeList} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "returnVariable", startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) ) },
{ "returnType", returnType },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename X, typename Y, typename... Z, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
VULKAN_HPP_NODISCARD_WHEN_NO_EXCEPTIONS typename ResultValueType<StructureChain<X, Y, Z...>>::type ${commandName}( ${argumentList} ) const;)";
return replaceWithMap( functionTemplate, { { "argumentList", argumentList }, { "commandName", commandName } } );
}
}
std::string VulkanHppGenerator::generateCommandResultGetHandleUnique( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
assert( ( commandData.returnType == "VkResult" ) && ( commandData.successCodes.size() == 1 ) );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, {}, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, false, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnBaseType =
stripPostfix( commandData.params[returnParamIndex].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename Dispatch>
${nodiscard}VULKAN_HPP_INLINE typename ResultValueType<UniqueHandle<${returnBaseType}, Dispatch>>::type ${className}${classSeparator}${commandName}Unique( ${argumentList} )${const}
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
${returnBaseType} ${returnValueName};
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
${ObjectDeleter}<${parentName}, Dispatch> deleter( ${this}${allocator}d );
return createResultValue<${returnBaseType}, Dispatch>( result, ${returnValueName}, VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}Unique", deleter );
})";
std::string objectDeleter, allocator;
if ( ( name.find( "Acquire" ) != std::string::npos ) || ( name.find( "Get" ) != std::string::npos ) )
{
if ( ( name == "vkAcquirePerformanceConfigurationINTEL" ) || ( name == "vkGetRandROutputDisplayEXT" ) ||
( name == "vkGetWinrtDisplayNV" ) || ( name == "vkGetDrmDisplayEXT" ) )
{
objectDeleter = "ObjectRelease";
}
else
{
throw std::runtime_error( "Found " + name + " which requires special handling for the object deleter" );
}
}
else if ( name.find( "Allocate" ) != std::string::npos )
{
objectDeleter = "ObjectFree";
allocator = "allocator, ";
}
else
{
assert( ( name.find( "Create" ) != std::string::npos ) || ( name.find( "Register" ) != std::string::npos ) );
objectDeleter = "ObjectDestroy";
allocator = "allocator, ";
}
std::string className =
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "";
std::string parentName = ( className.empty() || ( commandData.params[returnParamIndex].type.type == "VkDevice" ) )
? "NoParent"
: className;
return replaceWithMap(
functionTemplate,
{ { "allocator", allocator },
{ "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "className", className },
{ "classSeparator", className.empty() ? "" : "::" },
{ "commandName", commandName },
{ "const", commandData.handle.empty() ? "" : " const" },
{ "nodiscard", nodiscard },
{ "ObjectDeleter", objectDeleter },
{ "parentName", parentName },
{ "returnBaseType", returnBaseType },
{ "returnValueName", startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) ) },
{ "this", ( parentName == "NoParent" ) ? "" : "*this, " },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
${nodiscard}VULKAN_HPP_INLINE typename ResultValueType<UniqueHandle<${returnBaseType}, Dispatch>>::type ${commandName}Unique( ${argumentList} )${const};)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "const", commandData.handle.empty() ? "" : " const" },
{ "nodiscard", nodiscard },
{ "returnBaseType", returnBaseType } } );
}
}
std::string VulkanHppGenerator::generateCommandResultGetSingularAndValue(
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::vector<size_t> const & returnParamIndices,
std::map<size_t, size_t> const & vectorParamIndices ) const
{
assert( !commandData.handle.empty() && ( commandData.returnType == "VkResult" ) );
assert( ( vectorParamIndices.size() == 2 ) && ( returnParamIndices.size() == 2 ) );
assert( vectorParamIndices.find( returnParamIndices[0] ) != vectorParamIndices.end() );
assert( vectorParamIndices.find( returnParamIndices[1] ) == vectorParamIndices.end() );
assert( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second );
assert( commandData.returnType == "VkResult" );
std::set<size_t> skippedParameters =
determineSkippedParams( commandData.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
std::set<size_t> singularParameters = determineSingularParams( returnParamIndices[0], vectorParamIndices );
std::string argumentList = generateArgumentListEnhanced(
commandData.params, skippedParameters, singularParameters, definition, false, false, true );
std::string commandName = stripPluralS( generateCommandName( name, commandData.params, initialSkipCount, m_tags ) );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string singularElementType =
stripPostfix( commandData.params[returnParamIndices[0]].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" );
std::string valueType =
stripPostfix( commandData.params[returnParamIndices[1]].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename Dispatch>
${nodiscard}VULKAN_HPP_INLINE typename ResultValueType<std::pair<${singularElementType}, ${valueType}>>::type ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
std::pair<${singularElementType},${valueType}> data;
${singularElementType} & ${singularName} = data.first;
${valueType} & ${valueName} = data.second;
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
return createResultValue( result, data, VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}"${successCodeList} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments",
generateCallArgumentsEnhanced( commandData, initialSkipCount, false, singularParameters, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "singularElementType", singularElementType },
{ "singularName",
startLowerCase( stripPluralS( stripPrefix( commandData.params[returnParamIndices[0]].name, "p" ) ) ) },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "valueName", startLowerCase( stripPrefix( commandData.params[returnParamIndices[1]].name, "p" ) ) },
{ "valueType", valueType },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
${nodiscard}typename ResultValueType<std::pair<${singularElementType}, ${valueType}>>::type ${commandName}( ${argumentList} ) const;)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "singularElementType", singularElementType },
{ "valueType", valueType } } );
}
}
std::string
VulkanHppGenerator::generateCommandResultGetTwoVectors( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices ) const
{
assert( commandData.returnType == "VkResult" );
assert( commandData.params[0].type.type == commandData.handle );
#if !defined( NDEBUG )
auto firstVectorParamIt = vectorParamIndices.begin();
auto secondVectorParamIt = std::next( firstVectorParamIt );
assert( firstVectorParamIt->second == secondVectorParamIt->second );
#endif
std::set<size_t> skippedParameters =
determineSkippedParams( commandData.params, initialSkipCount, vectorParamIndices, {}, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParameters, {}, definition, false, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::pair<bool, std::map<size_t, std::vector<size_t>>> vectorSizeCheck = needsVectorSizeCheck( vectorParamIndices );
std::string noexceptString = vectorSizeCheck.first ? "VULKAN_HPP_NOEXCEPT_WHEN_NO_EXCEPTIONS" : "VULKAN_HPP_NOEXCEPT";
if ( definition )
{
const std::string functionTemplate =
R"( template <typename Dispatch>
VULKAN_HPP_INLINE Result ${className}${classSeparator}${commandName}( ${argumentList} ) const ${noexcept}
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );${vectorSizeCheck}
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
return createResultValue( result, VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}"${successCodeList} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "noexcept", noexceptString },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "vectorSizeCheck",
vectorSizeCheck.first
? generateVectorSizeCheck( name, commandData, initialSkipCount, vectorSizeCheck.second, skippedParameters )
: "" },
{ "vkCommand", name } } );
}
else
{
const std::string functionTemplate =
R"( template <typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
Result ${commandName}( ${argumentList} ) const ${noexcept};)";
return replaceWithMap( functionTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
{ "noexcept", noexceptString },
} );
}
}
std::string VulkanHppGenerator::generateCommandResultGetValue( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
assert( commandData.returnType == "VkResult" );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, {}, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, false, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnBaseType =
trimEnd( stripPostfix( commandData.params[returnParamIndex].type.compose( "VULKAN_HPP_NAMESPACE" ), "*" ) );
std::string typenameT;
if ( returnBaseType == "void" )
{
returnBaseType = "T";
typenameT = "typename T, ";
}
std::string returnType = generateReturnType( commandData.successCodes, returnBaseType );
if ( definition )
{
std::string const functionTemplate =
R"( template <${typenameT}typename Dispatch>
${nodiscard}VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}( ${argumentList} )${const}
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
${returnBaseType} ${returnValueName};
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
return createResultValue( result, ${returnValueName}, VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}"${successCodeList} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "const", commandData.handle.empty() ? "" : " const" },
{ "commandName", commandName },
{ "returnBaseType", returnBaseType },
{ "returnValueName", startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) ) },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "typenameT", typenameT },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <${typenameT}typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
${nodiscard}${returnType} ${commandName}( ${argumentList} )${const};)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "const", commandData.handle.empty() ? "" : " const" },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "typenameT", typenameT } } );
}
}
std::string
VulkanHppGenerator::generateCommandResultGetValueDeprecated( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex ) const
{
assert( commandData.returnType == "VkResult" );
assert( ( vectorParamIndices.find( returnParamIndex ) == vectorParamIndices.end() ) );
std::string argumentList = generateFunctionHeaderArgumentsEnhanced(
commandData, returnParamIndex, INVALID_INDEX, initialSkipCount, vectorParamIndices, !definition, false );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnType =
stripPostfix( commandData.params[returnParamIndex].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename Dispatch>
VULKAN_HPP_DEPRECATED( "This function is deprecated. Use one of the other flavours of it.")
${nodiscard}VULKAN_HPP_INLINE typename ResultValueType<${returnType}>::type ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
${functionBody}
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "functionBody",
generateFunctionBodyEnhanced( name,
commandData,
initialSkipCount,
returnParamIndex,
INVALID_INDEX,
vectorParamIndices,
false,
returnType,
false ) },
{ "nodiscard", nodiscard },
{ "returnType", returnType } } );
}
else
{
std::string const functionTemplate =
R"( template <typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
${nodiscard}typename ResultValueType<${returnType}>::type ${commandName}( ${argumentList} ) const;)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "returnType", returnType } } );
}
}
std::string VulkanHppGenerator::generateCommandResultGetVector( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex ) const
{
assert( commandData.returnType == "VkResult" );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, false, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnType = generateReturnType( commandData.successCodes, "std::vector<T,Allocator>" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename T, typename Allocator, typename Dispatch>
${nodiscard}VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
VULKAN_HPP_ASSERT( ${dataSize} % sizeof( T ) == 0 );
std::vector<T,Allocator> ${dataName}( ${dataSize} / sizeof( T ) );
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
return createResultValue( result, ${dataName}, VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}"${successCodeList} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "dataName", startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) ) },
{ "dataSize", commandData.params[returnParamIndex].len },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename T, typename Allocator = std::allocator<T>, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
${nodiscard}${returnType} ${commandName}( ${argumentList} ) const;)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "returnType", returnType } } );
}
}
std::string
VulkanHppGenerator::generateCommandResultGetVectorAndValue( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & returnParamIndices,
bool withAllocator ) const
{
assert( !commandData.handle.empty() && ( commandData.returnType == "VkResult" ) );
assert( ( vectorParamIndices.size() == 2 ) && ( returnParamIndices.size() == 2 ) );
assert( vectorParamIndices.find( returnParamIndices[0] ) != vectorParamIndices.end() );
assert( vectorParamIndices.find( returnParamIndices[1] ) == vectorParamIndices.end() );
assert( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second );
assert( commandData.returnType == "VkResult" );
std::set<size_t> skippedParameters =
determineSkippedParams( commandData.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParameters, {}, definition, withAllocator, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnType = generateReturnType( commandData.successCodes, "std::vector<T,Allocator>" );
std::string vectorElementType =
stripPostfix( commandData.params[returnParamIndices[0]].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" );
std::string allocatorType = startUpperCase( vectorElementType ) + "Allocator";
std::string valueType =
stripPostfix( commandData.params[returnParamIndices[1]].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename ${allocatorType}, typename Dispatch${typenameCheck}>
${nodiscard}VULKAN_HPP_INLINE typename ResultValueType<std::pair<std::vector<${vectorElementType}, ${allocatorType}>, ${valueType}>>::type ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
std::pair<std::vector<${vectorElementType}, ${allocatorType}>,${valueType}> data( std::piecewise_construct, std::forward_as_tuple( ${vectorSize}${allocateInitializer} ), std::forward_as_tuple( 0 ) );
std::vector<${vectorElementType}, ${allocatorType}> & ${vectorName} = data.first;
${valueType} & ${valueName} = data.second;
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
return createResultValue( result, data, VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}"${successCodeList} );
})";
std::string typenameCheck = withAllocator
? ( ", typename B, typename std::enable_if<std::is_same<typename B::value_type, " +
vectorElementType + ">::value, int>::type " )
: "";
return replaceWithMap(
functionTemplate,
{ { "allocateInitializer", withAllocator ? ( ", " + startLowerCase( allocatorType ) ) : "" },
{ "allocatorType", allocatorType },
{ "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "typenameCheck", typenameCheck },
{ "valueName", startLowerCase( stripPrefix( commandData.params[returnParamIndices[1]].name, "p" ) ) },
{ "valueType", valueType },
{ "vectorElementType", vectorElementType },
{ "vectorName", startLowerCase( stripPrefix( commandData.params[returnParamIndices[0]].name, "p" ) ) },
{ "vectorSize",
startLowerCase( stripPrefix( commandData.params[vectorParamIndices.begin()->first].name, "p" ) ) +
".size()" },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename ${allocatorType} = std::allocator<${vectorElementType}>, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE${typenameCheck}>
${nodiscard}typename ResultValueType<std::pair<std::vector<${vectorElementType}, ${allocatorType}>, ${valueType}>>::type ${commandName}( ${argumentList} ) const;)";
std::string typenameCheck = withAllocator ? ( ", typename B = " + allocatorType +
", typename std::enable_if<std::is_same<typename B::value_type, " +
vectorElementType + ">::value, int>::type = 0" )
: "";
return replaceWithMap( functionTemplate,
{ { "allocatorType", allocatorType },
{ "argumentList", argumentList },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "typenameCheck", typenameCheck },
{ "valueType", valueType },
{ "vectorElementType", vectorElementType } } );
}
}
std::string
VulkanHppGenerator::generateCommandResultGetVectorDeprecated( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex ) const
{
assert( commandData.returnType == "VkResult" );
std::string argumentList = generateFunctionHeaderArgumentsEnhanced(
commandData, INVALID_INDEX, returnParamIndex, initialSkipCount, vectorParamIndices, !definition, false );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnType = generateReturnType( commandData.successCodes, "void" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename T, typename Dispatch>
VULKAN_HPP_DEPRECATED( "This function is deprecated. Use one of the other flavours of it.")
${nodiscard}VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
${functionBody}
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "functionBody",
generateFunctionBodyEnhanced( name,
commandData,
initialSkipCount,
INVALID_INDEX,
returnParamIndex,
vectorParamIndices,
false,
"void",
false ) },
{ "nodiscard", nodiscard },
{ "returnType", returnType } } );
}
else
{
std::string const functionTemplate =
R"( template <typename T, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
${nodiscard}${returnType} ${commandName}( ${argumentList} ) const;)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "returnType", returnType } } );
}
}
std::string VulkanHppGenerator::generateCommandResultGetVectorOfHandlesOrValues(
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex,
bool withAllocator ) const
{
assert( commandData.returnType == "VkResult" );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, withAllocator, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
assert( beginsWith( commandData.params[returnParamIndex].type.type, "Vk" ) );
std::string elementType = stripPrefix( commandData.params[returnParamIndex].type.type, "Vk" );
std::string returnType = generateReturnType(
commandData.successCodes, "std::vector<VULKAN_HPP_NAMESPACE::" + elementType + ", " + elementType + "Allocator>" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename ${elementType}Allocator, typename Dispatch${typenameCheck}>
${nodiscard}VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
std::vector<VULKAN_HPP_NAMESPACE::${elementType}, ${elementType}Allocator> ${vectorName}( ${vectorSize}${vectorAllocator} );
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
return createResultValue( result, ${vectorName}, VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}"${successCodeList} );
})";
std::string typenameCheck = withAllocator
? ( ", typename B, typename std::enable_if<std::is_same<typename B::value_type, " +
elementType + ">::value, int>::type " )
: "";
std::string vectorName = startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) );
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "elementType", elementType },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "typenameCheck", typenameCheck },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "vectorAllocator", withAllocator ? ( ", " + startLowerCase( elementType ) + "Allocator" ) : "" },
{ "vectorName", vectorName },
{ "vectorSize", getVectorSize( commandData.params, vectorParamIndices, returnParamIndex ) },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename ${elementType}Allocator = std::allocator<${elementType}>, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE${typenameCheck}>
${nodiscard}${returnType} ${commandName}( ${argumentList} ) const;)";
std::string typenameCheck = withAllocator
? ( ", typename B = " + elementType +
"Allocator, typename std::enable_if<std::is_same<typename B::value_type, " +
elementType + ">::value, int>::type = 0" )
: "";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "elementType", elementType },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "typenameCheck", typenameCheck } } );
}
}
std::string VulkanHppGenerator::generateCommandResultGetVectorOfHandlesOrValuesSingular(
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex ) const
{
assert( ( vectorParamIndices.size() == 2 ) &&
( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second ) );
assert( commandData.params[vectorParamIndices.begin()->second].type.isValue() );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, true );
std::set<size_t> singularParams = determineSingularParams( returnParamIndex, vectorParamIndices );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, singularParams, definition, false, false, true );
std::string commandName = stripPluralS( generateCommandName( name, commandData.params, initialSkipCount, m_tags ) );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
assert( beginsWith( commandData.params[returnParamIndex].type.type, "Vk" ) );
std::string dataType =
stripPostfix( commandData.params[returnParamIndex].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" );
std::string returnType = generateReturnType( commandData.successCodes, dataType );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename Dispatch>
${nodiscard}VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
${dataType} ${dataName};
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
return createResultValue( result, ${dataName}, VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}"${successCodeList} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments",
generateCallArgumentsEnhanced( commandData, initialSkipCount, false, singularParams, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "dataName", stripPluralS( startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) ) ) },
{ "dataType", dataType },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
${nodiscard}${returnType} ${commandName}( ${argumentList} ) const;)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "returnType", returnType } } );
}
}
std::string VulkanHppGenerator::generateCommandResultGetVectorOfHandlesUnique(
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex,
bool withAllocator ) const
{
assert( commandData.returnType == "VkResult" );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, withAllocator, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string handleType = stripPrefix( commandData.params[returnParamIndex].type.type, "Vk" );
std::string returnType = generateReturnType(
commandData.successCodes, "std::vector<UniqueHandle<" + handleType + ", Dispatch>, " + handleType + "Allocator>" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename Dispatch, typename ${handleType}Allocator${typenameCheck}>
${nodiscard}VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}Unique( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
std::vector<UniqueHandle<${handleType}, Dispatch>, ${handleType}Allocator> ${uniqueVectorName}${vectorAllocator};
std::vector<${handleType}> ${vectorName}( ${vectorSize} );
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
if ( ${successCheck} )
{
${uniqueVectorName}.reserve( ${vectorSize} );
${deleterDefinition};
for ( size_t i=0; i < ${vectorSize}; i++ )
{
${uniqueVectorName}.push_back( UniqueHandle<${handleType}, Dispatch>( ${vectorName}[i], deleter ) );
}
}
return createResultValue( result, std::move( ${uniqueVectorName} ), VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}Unique"${successCodeList} );
})";
std::string className =
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "";
std::string deleterDefinition;
std::vector<std::string> lenParts = tokenize( commandData.params[returnParamIndex].len, "->" );
switch ( lenParts.size() )
{
case 1: deleterDefinition = "ObjectDestroy<" + className + ", Dispatch> deleter( *this, allocator, d )"; break;
case 2:
{
auto vpiIt = vectorParamIndices.find( returnParamIndex );
assert( vpiIt != vectorParamIndices.end() );
std::string poolType, poolName;
std::tie( poolType, poolName ) = getPoolTypeAndName( commandData.params[vpiIt->second].type.type );
assert( !poolType.empty() );
poolType = stripPrefix( poolType, "Vk" );
poolName = startLowerCase( stripPrefix( lenParts[0], "p" ) ) + "." + poolName;
deleterDefinition =
"PoolFree<" + className + ", " + poolType + ", Dispatch> deleter( *this, " + poolName + ", d )";
}
break;
}
std::string typenameCheck =
withAllocator ? ( ", typename B, typename std::enable_if<std::is_same<typename B::value_type, UniqueHandle<" +
handleType + ", Dispatch>>::value, int>::type " )
: "";
std::string vectorName = startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) );
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "className", className },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "deleterDefinition", deleterDefinition },
{ "handleType", handleType },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "successCheck", generateSuccessCheck( commandData.successCodes ) },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "typenameCheck", typenameCheck },
{ "uniqueVectorName", "unique" + stripPrefix( commandData.params[returnParamIndex].name, "p" ) },
{ "vectorAllocator", withAllocator ? ( "( " + startLowerCase( handleType ) + "Allocator )" ) : "" },
{ "vectorName", vectorName },
{ "vectorSize", getVectorSize( commandData.params, vectorParamIndices, returnParamIndex ) },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE, typename ${handleType}Allocator = std::allocator<UniqueHandle<${handleType}, Dispatch>>${typenameCheck}>
${nodiscard}${returnType} ${commandName}Unique( ${argumentList} ) const;)";
std::string typenameCheck =
withAllocator ? ( ", typename B = " + handleType +
"Allocator, typename std::enable_if<std::is_same<typename B::value_type, UniqueHandle<" +
handleType + ", Dispatch>>::value, int>::type = 0" )
: "";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "handleType", handleType },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "typenameCheck", typenameCheck } } );
}
}
std::string VulkanHppGenerator::generateCommandResultGetVectorOfHandlesUniqueSingular(
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex ) const
{
assert( ( vectorParamIndices.size() == 2 ) &&
( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second ) );
assert( commandData.params[vectorParamIndices.begin()->second].type.isValue() );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, true );
std::set<size_t> singularParams = determineSingularParams( returnParamIndex, vectorParamIndices );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, singularParams, definition, false, false, true );
std::string commandName = stripPluralS( generateCommandName( name, commandData.params, initialSkipCount, m_tags ) );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string handleType = stripPrefix( commandData.params[returnParamIndex].type.type, "Vk" );
std::string returnType = generateReturnType( commandData.successCodes, "UniqueHandle<" + handleType + ", Dispatch>" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename Dispatch>
${nodiscard}VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}Unique( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
${handleType} ${handleName};
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
ObjectDestroy<${className}, Dispatch> deleter( *this, allocator, d );
return createResultValue<${handleType}, Dispatch>( result, ${handleName}, VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}Unique"${successCodeList}, deleter );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments",
generateCallArgumentsEnhanced( commandData, initialSkipCount, false, singularParams, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "handleName",
stripPluralS( startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) ) ) },
{ "handleType", handleType },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
${nodiscard}${returnType} ${commandName}Unique( ${argumentList} ) const;)";
return replaceWithMap( functionTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
} );
}
}
std::string
VulkanHppGenerator::generateCommandResultGetVectorOfVoidSingular( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex ) const
{
assert( commandData.returnType == "VkResult" );
assert( commandData.params[returnParamIndex].type.type == "void" );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, true );
std::set<size_t> singularParams = determineSingularParams( returnParamIndex, vectorParamIndices );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, false, false, true );
std::string commandName = stripPluralS( generateCommandName( name, commandData.params, initialSkipCount, m_tags ) );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnType = generateReturnType( commandData.successCodes, "T" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename T, typename Dispatch>
${nodiscard}VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
T ${dataName};
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
return createResultValue( result, ${dataName}, VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}"${successCodeList} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments",
generateCallArgumentsEnhanced( commandData, initialSkipCount, false, singularParams, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "dataName", startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) ) },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename T, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
${nodiscard}${returnType} ${commandName}( ${argumentList} ) const;)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "returnType", returnType } } );
}
}
std::string VulkanHppGenerator::generateCommandResultMultiSuccessNoErrors( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition ) const
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( commandData.params );
if ( returnParamIndices.empty() )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.empty() )
{
std::vector<size_t> constPointerParamIndices = determineConstPointerParamIndices( commandData.params );
if ( constPointerParamIndices.empty() )
{
return generateCommandSetStandardOrEnhanced(
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResult( name, commandData, initialSkipCount, definition, {} ) );
}
}
}
return "";
}
std::string VulkanHppGenerator::generateCommandResultMultiSuccessWithErrors( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition ) const
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( commandData.params );
switch ( returnParamIndices.size() )
{
case 0:
return generateCommandResultMultiSuccessWithErrors0Return( name, commandData, initialSkipCount, definition );
break;
case 1:
return generateCommandResultMultiSuccessWithErrors1Return(
name, commandData, initialSkipCount, definition, returnParamIndices[0] );
break;
case 2:
return generateCommandResultMultiSuccessWithErrors2Return(
name, commandData, initialSkipCount, definition, returnParamIndices );
break;
case 3:
return generateCommandResultMultiSuccessWithErrors3Return(
name, commandData, initialSkipCount, definition, returnParamIndices );
break;
}
return "";
}
std::string VulkanHppGenerator::generateCommandResultMultiSuccessWithErrors0Return( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition ) const
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
switch ( vectorParamIndices.size() )
{
case 0:
{
std::vector<size_t> constPointerParamIndices = determineConstPointerParamIndices( commandData.params );
switch ( constPointerParamIndices.size() )
{
case 0:
return generateCommandSetStandardOrEnhanced(
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResult( name, commandData, initialSkipCount, definition, {} ) );
break;
case 1:
if ( commandData.params[constPointerParamIndices[0]].type.type != "void" )
{
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResult( name, commandData, initialSkipCount, definition, {} ) );
}
break;
}
}
break;
case 1:
if ( commandData.params[vectorParamIndices.begin()->second].type.isValue() )
{
if ( isHandleType( commandData.params[vectorParamIndices.begin()->first].type.type ) )
{
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResult( name, commandData, initialSkipCount, definition, vectorParamIndices ) );
}
}
break;
case 2:
if ( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second )
{
if ( commandData.params[vectorParamIndices.begin()->second].type.type == "uint32_t" )
{
if ( ( commandData.params[vectorParamIndices.begin()->first].type.type != "void" ) &&
!isHandleType( commandData.params[vectorParamIndices.begin()->first].type.type ) &&
!isStructureChainAnchor( commandData.params[vectorParamIndices.begin()->first].type.type ) )
{
if ( ( commandData.params[std::next( vectorParamIndices.begin() )->first].type.type != "void" ) &&
!isHandleType( commandData.params[std::next( vectorParamIndices.begin() )->first].type.type ) &&
!isStructureChainAnchor(
commandData.params[std::next( vectorParamIndices.begin() )->first].type.type ) )
{
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetTwoVectors(
name, commandData, initialSkipCount, definition, vectorParamIndices ) );
}
}
}
}
break;
}
return "";
}
std::string VulkanHppGenerator::generateCommandResultMultiSuccessWithErrors1Return( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
if ( commandData.params[returnParamIndex].type.type == "void" )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.size() == 1 )
{
if ( returnParamIndex == vectorParamIndices.begin()->first )
{
if ( commandData.params[vectorParamIndices.begin()->second].type.isValue() )
{
return generateCommandSetStandardEnhancedSingularDeprecated(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetVectorDeprecated(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ),
generateCommandResultGetVector(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ),
generateCommandResultGetVectorOfVoidSingular(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ) );
}
}
}
}
else if ( isHandleType( commandData.params[returnParamIndex].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.size() == 2 )
{
if ( returnParamIndex == std::next( vectorParamIndices.begin() )->first )
{
if ( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second )
{
if ( commandData.params[vectorParamIndices.begin()->second].type.type == "uint32_t" )
{
if ( isStructureChainAnchor( commandData.params[vectorParamIndices.begin()->first].type.type ) )
{
return generateCommandSetStandardEnhancedWithAllocatorSingularUnique(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetVectorOfHandlesOrValues(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, false ),
generateCommandResultGetVectorOfHandlesOrValues(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, true ),
generateCommandResultGetVectorOfHandlesOrValuesSingular(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ),
generateCommandResultGetVectorOfHandlesUnique(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, false ),
generateCommandResultGetVectorOfHandlesUnique(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, true ),
generateCommandResultGetVectorOfHandlesUniqueSingular(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ) );
}
}
}
}
}
}
else if ( !isStructureChainAnchor( commandData.params[returnParamIndex].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.empty() )
{
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetValue( name, commandData, initialSkipCount, definition, returnParamIndex ) );
}
}
return "";
}
std::string VulkanHppGenerator::generateCommandResultMultiSuccessWithErrors2Return(
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::vector<size_t> const & returnParamIndices ) const
{
if ( ( commandData.successCodes.size() == 2 ) && ( commandData.successCodes[0] == "VK_SUCCESS" ) &&
( commandData.successCodes[1] == "VK_INCOMPLETE" ) )
{
if ( ( commandData.params[returnParamIndices[0]].type.type == "size_t" ) ||
( commandData.params[returnParamIndices[0]].type.type == "uint32_t" ) )
{
if ( isStructureChainAnchor( commandData.params[returnParamIndices[1]].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.size() == 1 )
{
if ( returnParamIndices[0] == vectorParamIndices.begin()->second )
{
if ( returnParamIndices[1] == vectorParamIndices.begin()->first )
{
return generateCommandSetStandardEnhancedWithAllocatorChained(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultEnumerate(
name, commandData, initialSkipCount, definition, *vectorParamIndices.begin(), false ),
generateCommandResultEnumerate(
name, commandData, initialSkipCount, definition, *vectorParamIndices.begin(), true ),
generateCommandResultEnumerateChained(
name, commandData, initialSkipCount, definition, *vectorParamIndices.begin(), false ),
generateCommandResultEnumerateChained(
name, commandData, initialSkipCount, definition, *vectorParamIndices.begin(), true ) );
}
}
}
}
else
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.size() == 1 )
{
if ( returnParamIndices[0] == vectorParamIndices.begin()->second )
{
if ( returnParamIndices[1] == vectorParamIndices.begin()->first )
{
return generateCommandSetStandardEnhancedWithAllocator(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultEnumerate(
name, commandData, initialSkipCount, definition, *vectorParamIndices.begin(), false ),
generateCommandResultEnumerate(
name, commandData, initialSkipCount, definition, *vectorParamIndices.begin(), true ) );
}
}
}
}
}
}
return "";
}
std::string VulkanHppGenerator::generateCommandResultMultiSuccessWithErrors3Return(
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::vector<size_t> const & returnParamIndices ) const
{
if ( commandData.params[returnParamIndices[0]].type.type == "uint32_t" )
{
if ( ( commandData.params[returnParamIndices[1]].type.type != "void" ) &&
!isHandleType( commandData.params[returnParamIndices[1]].type.type ) &&
!isStructureChainAnchor( commandData.params[returnParamIndices[1]].type.type ) )
{
if ( ( commandData.params[returnParamIndices[2]].type.type != "void" ) &&
!isHandleType( commandData.params[returnParamIndices[2]].type.type ) &&
!isStructureChainAnchor( commandData.params[returnParamIndices[2]].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.size() == 2 )
{
if ( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second )
{
if ( returnParamIndices[0] == vectorParamIndices.begin()->second )
{
if ( returnParamIndices[1] == vectorParamIndices.begin()->first )
{
if ( returnParamIndices[2] == std::next( vectorParamIndices.begin() )->first )
{
return generateCommandSetStandardEnhancedWithAllocator(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultEnumerateTwoVectors(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndices, false ),
generateCommandResultEnumerateTwoVectors(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndices, true ) );
}
}
}
}
}
}
}
}
return "";
}
std::string VulkanHppGenerator::generateCommandResultSingleSuccessNoErrors( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition ) const
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( commandData.params );
if ( returnParamIndices.empty() )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.empty() )
{
std::vector<size_t> constPointerParamIndices = determineConstPointerParamIndices( commandData.params );
if ( constPointerParamIndices.empty() )
{
return generateCommandSetStandardOrEnhanced(
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResult( name, commandData, initialSkipCount, definition, {} ) );
}
}
else if ( vectorParamIndices.size() == 1 )
{
if ( commandData.params[vectorParamIndices.begin()->second].type.isValue() )
{
if ( isHandleType( commandData.params[vectorParamIndices.begin()->first].type.type ) )
{
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResult( name, commandData, initialSkipCount, definition, vectorParamIndices ) );
}
}
}
}
return "";
}
std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition ) const
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( commandData.params );
switch ( returnParamIndices.size() )
{
case 0:
return generateCommandResultSingleSuccessWithErrors0Return( name, commandData, initialSkipCount, definition );
break;
case 1:
return generateCommandResultSingleSuccessWithErrors1Return(
name, commandData, initialSkipCount, definition, returnParamIndices[0] );
break;
case 2:
return generateCommandResultSingleSuccessWithErrors2Return(
name, commandData, initialSkipCount, definition, returnParamIndices );
break;
}
return "";
}
std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors0Return( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition ) const
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
switch ( vectorParamIndices.size() )
{
case 0:
{
std::vector<size_t> constPointerParamIndices = determineConstPointerParamIndices( commandData.params );
switch ( constPointerParamIndices.size() )
{
case 0:
return generateCommandSetStandardOrEnhanced(
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResult( name, commandData, initialSkipCount, definition, {} ) );
break;
case 1:
if ( commandData.params[constPointerParamIndices[0]].type.type != "void" )
{
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResult( name, commandData, initialSkipCount, definition, {} ) );
}
break;
}
}
break;
case 1:
if ( commandData.params[vectorParamIndices.begin()->second].type.isValue() )
{
if ( commandData.params[vectorParamIndices.begin()->first].type.type != "void" )
{
// NOTE: no matter if it's a Handle, a StructureChainAnchor, or any other Data...
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResult( name, commandData, initialSkipCount, definition, vectorParamIndices ) );
}
}
break;
}
return "";
}
std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors1Return( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
if ( commandData.params[returnParamIndex].type.type == "void" )
{
return generateCommandResultSingleSuccessWithErrors1ReturnVoid(
name, commandData, initialSkipCount, definition, returnParamIndex );
}
else if ( isHandleType( commandData.params[returnParamIndex].type.type ) )
{
return generateCommandResultSingleSuccessWithErrors1ReturnHandle(
name, commandData, initialSkipCount, definition, returnParamIndex );
}
else if ( isStructureChainAnchor( commandData.params[returnParamIndex].type.type ) )
{
return generateCommandResultSingleSuccessWithErrors1ReturnChain(
name, commandData, initialSkipCount, definition, returnParamIndex );
}
else
{
return generateCommandResultSingleSuccessWithErrors1ReturnValue(
name, commandData, initialSkipCount, definition, returnParamIndex );
}
}
std::string
VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors1ReturnChain( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.empty() )
{
return generateCommandSetStandardEnhancedChained(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetValue( name, commandData, initialSkipCount, definition, returnParamIndex ),
generateCommandResultGetChain( name, commandData, initialSkipCount, definition, returnParamIndex ) );
}
return "";
}
std::string
VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors1ReturnHandle( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
switch ( vectorParamIndices.size() )
{
case 0:
return generateCommandSetStandardEnhancedUnique(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetValue( name, commandData, initialSkipCount, definition, returnParamIndex ),
generateCommandResultGetHandleUnique( name, commandData, initialSkipCount, definition, returnParamIndex ) );
break;
case 1:
return generateCommandResultSingleSuccessWithErrors1ReturnHandle1Vector(
name, commandData, initialSkipCount, definition, returnParamIndex, *vectorParamIndices.begin() );
break;
case 2:
return generateCommandResultSingleSuccessWithErrors1ReturnHandle2Vector(
name, commandData, initialSkipCount, definition, returnParamIndex, vectorParamIndices );
break;
}
return "";
}
std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors1ReturnHandle1Vector(
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex,
std::pair<size_t, size_t> const & vectorParamIndex ) const
{
if ( returnParamIndex == vectorParamIndex.first )
{
if ( isLenByStructMember( commandData.params[vectorParamIndex.first].len,
commandData.params[vectorParamIndex.second] ) )
{
return generateCommandSetStandardEnhancedWithAllocatorUnique(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetVectorOfHandlesOrValues(
name, commandData, initialSkipCount, definition, { vectorParamIndex }, returnParamIndex, false ),
generateCommandResultGetVectorOfHandlesOrValues(
name, commandData, initialSkipCount, definition, { vectorParamIndex }, returnParamIndex, true ),
generateCommandResultGetVectorOfHandlesUnique(
name, commandData, initialSkipCount, definition, { vectorParamIndex }, returnParamIndex, false ),
generateCommandResultGetVectorOfHandlesUnique(
name, commandData, initialSkipCount, definition, { vectorParamIndex }, returnParamIndex, true ) );
}
}
return "";
}
std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors1ReturnHandle2Vector(
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex,
std::map<size_t, size_t> const & vectorParamIndices ) const
{
if ( returnParamIndex == std::next( vectorParamIndices.begin() )->first )
{
if ( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second )
{
if ( commandData.params[vectorParamIndices.begin()->second].type.isValue() )
{
if ( isStructureChainAnchor( commandData.params[vectorParamIndices.begin()->first].type.type ) )
{
return generateCommandSetStandardEnhancedWithAllocatorSingularUnique(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetVectorOfHandlesOrValues(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, false ),
generateCommandResultGetVectorOfHandlesOrValues(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, true ),
generateCommandResultGetVectorOfHandlesOrValuesSingular(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ),
generateCommandResultGetVectorOfHandlesUnique(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, false ),
generateCommandResultGetVectorOfHandlesUnique(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, true ),
generateCommandResultGetVectorOfHandlesUniqueSingular(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ) );
}
}
}
}
return "";
}
std::string
VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors1ReturnValue( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
switch ( vectorParamIndices.size() )
{
case 0:
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetValue( name, commandData, initialSkipCount, definition, returnParamIndex ) );
case 2:
return generateCommandResultSingleSuccessWithErrors1ReturnValue2Vectors(
name, commandData, initialSkipCount, definition, returnParamIndex, vectorParamIndices );
break;
}
return "";
}
std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors1ReturnValue2Vectors(
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex,
std::map<size_t, size_t> const & vectorParamIndices ) const
{
if ( returnParamIndex == std::next( vectorParamIndices.begin() )->first )
{
if ( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second )
{
if ( commandData.params[vectorParamIndices.begin()->second].type.type == "uint32_t" )
{
if ( ( commandData.params[vectorParamIndices.begin()->first].type.type != "void" ) &&
!isHandleType( commandData.params[vectorParamIndices.begin()->first].type.type ) &&
!isStructureChainAnchor( commandData.params[vectorParamIndices.begin()->first].type.type ) )
{
return generateCommandSetStandardEnhancedWithAllocatorSingular(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetVectorOfHandlesOrValues(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, false ),
generateCommandResultGetVectorOfHandlesOrValues(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, true ),
generateCommandResultGetVectorOfHandlesOrValuesSingular(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ) );
}
}
}
}
return "";
}
std::string
VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors1ReturnVoid( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
switch ( vectorParamIndices.size() )
{
case 0:
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetValue( name, commandData, initialSkipCount, definition, returnParamIndex ) );
break;
case 1:
if ( returnParamIndex == vectorParamIndices.begin()->first )
{
if ( commandData.params[vectorParamIndices.begin()->second].type.isValue() )
{
return generateCommandSetStandardEnhancedSingularDeprecated(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetVectorDeprecated(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ),
generateCommandResultGetVector(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ),
generateCommandResultGetVectorOfVoidSingular(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ) );
}
}
break;
case 2:
if ( returnParamIndex == std::next( vectorParamIndices.begin() )->first )
{
if ( vectorParamIndices.begin()->second != std::next( vectorParamIndices.begin() )->second )
{
if ( commandData.params[vectorParamIndices.begin()->second].type.isValue() )
{
if ( isHandleType( commandData.params[vectorParamIndices.begin()->first].type.type ) )
{
if ( commandData.params[std::next( vectorParamIndices.begin() )->second].type.isValue() )
{
return generateCommandSetStandardEnhancedSingularDeprecated(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetVectorDeprecated(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ),
generateCommandResultGetVector(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ),
generateCommandResultGetVectorOfVoidSingular(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ) );
}
}
}
}
}
break;
}
return "";
}
std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors2Return(
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::vector<size_t> const & returnParamIndices ) const
{
if ( ( commandData.params[returnParamIndices[0]].type.type != "void" ) &&
!isHandleType( commandData.params[returnParamIndices[0]].type.type ) &&
!isStructureChainAnchor( commandData.params[returnParamIndices[0]].type.type ) )
{
if ( ( commandData.params[returnParamIndices[1]].type.type != "void" ) &&
!isHandleType( commandData.params[returnParamIndices[1]].type.type ) &&
!isStructureChainAnchor( commandData.params[returnParamIndices[1]].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.size() == 2 )
{
if ( returnParamIndices[0] == std::next( vectorParamIndices.begin() )->first )
{
if ( vectorParamIndices.find( returnParamIndices[1] ) == vectorParamIndices.end() )
{
assert( ( returnParamIndices[1] != vectorParamIndices.begin()->second ) &&
( returnParamIndices[1] != std::next( vectorParamIndices.begin() )->second ) );
if ( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second )
{
if ( commandData.params[vectorParamIndices.begin()->second].type.isValue() )
{
if ( ( commandData.params[vectorParamIndices.begin()->first].type.type != "void" ) &&
!isHandleType( commandData.params[vectorParamIndices.begin()->first].type.type ) &&
!isStructureChainAnchor( commandData.params[vectorParamIndices.begin()->first].type.type ) )
{
return generateCommandSetStandardEnhancedWithAllocatorSingularDeprecated(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetValueDeprecated(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndices[1] ),
generateCommandResultGetVectorAndValue(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndices, false ),
generateCommandResultGetVectorAndValue(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndices, true ),
generateCommandResultGetSingularAndValue(
name, commandData, initialSkipCount, definition, returnParamIndices, vectorParamIndices ) );
}
}
}
}
}
}
}
}
return "";
}
std::string VulkanHppGenerator::generateCommandSetStandard( std::string const & standard ) const
{
const std::string commandTemplate = R"(
${commandStandard}
)";
return replaceWithMap( commandTemplate, std::map<std::string, std::string>( { { "commandStandard", standard } } ) );
}
std::string VulkanHppGenerator::generateCommandSetStandardEnhanced( bool definition,
std::string const & standard,
std::string const & enhanced ) const
{
const std::string commandTemplate = R"(
${commandStandard}${newlineOnDefinition}
#ifndef VULKAN_HPP_DISABLE_ENHANCED_MODE
${commandEnhanced}
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap( commandTemplate,
std::map<std::string, std::string>( { { "commandEnhanced", enhanced },
{ "commandStandard", standard },
{ "newlineOnDefinition", definition ? "\n" : "" } } ) );
}
std::string VulkanHppGenerator::generateCommandSetStandardEnhancedChained( bool definition,
std::string const & standard,
std::string const & enhanced,
std::string const & enhancedChained ) const
{
std::string const commandTemplate = R"(
${commandStandard}${newlineOnDefinition}
#ifndef VULKAN_HPP_DISABLE_ENHANCED_MODE
${commandEnhanced}${newlineOnDefinition}
${commandEnhancedChained}
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap( commandTemplate,
std::map<std::string, std::string>( { { "commandEnhanced", enhanced },
{ "commandEnhancedChained", enhancedChained },
{ "commandStandard", standard },
{ "newlineOnDefinition", definition ? "\n" : "" } } ) );
}
std::string
VulkanHppGenerator::generateCommandSetStandardEnhancedSingularDeprecated( bool definition,
std::string const & standard,
std::string const & enhancedDeprecated,
std::string const & enhanced,
std::string const & enhancedSingular ) const
{
std::string const commandTemplate = R"(
${commandStandard}${newlineOnDefinition}
#ifndef VULKAN_HPP_DISABLE_ENHANCED_MODE
${commandEnhancedDeprecated}${newlineOnDefinition}
${commandEnhanced}${newlineOnDefinition}
${commandEnhancedSingular}
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap( commandTemplate,
std::map<std::string, std::string>( { { "commandEnhanced", enhanced },
{ "commandEnhancedDeprecated", enhancedDeprecated },
{ "commandEnhancedSingular", enhancedSingular },
{ "commandStandard", standard },
{ "newlineOnDefinition", definition ? "\n" : "" } } ) );
}
std::string VulkanHppGenerator::generateCommandSetStandardEnhancedUnique( bool definition,
std::string const & standard,
std::string const & enhanced,
std::string const & enhancedUnique ) const
{
std::string const commandTemplate = R"(
${commandStandard}${newlineOnDefinition}
#ifndef VULKAN_HPP_DISABLE_ENHANCED_MODE
${commandEnhanced}${newlineOnDefinition}
# ifndef VULKAN_HPP_NO_SMART_HANDLE
${commandEnhancedUnique}
# endif /*VULKAN_HPP_NO_SMART_HANDLE*/
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap( commandTemplate,
std::map<std::string, std::string>( { { "commandEnhanced", enhanced },
{ "commandEnhancedUnique", enhancedUnique },
{ "commandStandard", standard },
{ "newlineOnDefinition", definition ? "\n" : "" } } ) );
}
std::string
VulkanHppGenerator::generateCommandSetStandardEnhancedWithAllocator( bool definition,
std::string const & standard,
std::string const & enhanced,
std::string const & enhancedWithAllocator ) const
{
const std::string commandTemplate = R"(
${commandStandard}${newlineOnDefinition}
#ifndef VULKAN_HPP_DISABLE_ENHANCED_MODE
${commandEnhanced}${newlineOnDefinition}
${commandEnhancedWithAllocator}
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap(
commandTemplate,
std::map<std::string, std::string>( { { "commandEnhanced", enhanced },
{ "commandEnhancedWithAllocator", enhancedWithAllocator },
{ "commandStandard", standard },
{ "newlineOnDefinition", definition ? "\n" : "" } } ) );
}
std::string VulkanHppGenerator::generateCommandSetStandardEnhancedWithAllocatorChained(
bool definition,
std::string const & standard,
std::string const & enhanced,
std::string const & enhancedWithAllocator,
std::string const & enhancedChained,
std::string const & enhancedChainedWithAllocator ) const
{
std::string const commandTemplate = R"(
${commandStandard}${newlineOnDefinition}
#ifndef VULKAN_HPP_DISABLE_ENHANCED_MODE
${commandEnhanced}${newlineOnDefinition}
${commandEnhancedWithAllocator}${newlineOnDefinition}
${commandEnhancedChained}${newlineOnDefinition}
${commandEnhancedChainedWithAllocator}
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap(
commandTemplate,
std::map<std::string, std::string>( { { "commandEnhanced", enhanced },
{ "commandEnhancedChained", enhancedChained },
{ "commandEnhancedChainedWithAllocator", enhancedChainedWithAllocator },
{ "commandEnhancedWithAllocator", enhancedWithAllocator },
{ "commandStandard", standard },
{ "newlineOnDefinition", definition ? "\n" : "" } } ) );
}
std::string VulkanHppGenerator::generateCommandSetStandardEnhancedWithAllocatorSingularDeprecated(
bool definition,
std::string const & standard,
std::string const & enhancedDeprecated,
std::string const & enhanced,
std::string const & enhancedWithAllocator,
std::string const & enhancedSingular ) const
{
const std::string commandTemplate = R"(
${commandStandard}${newlineOnDefinition}
#ifndef VULKAN_HPP_DISABLE_ENHANCED_MODE
${commandEnhancedDeprecated}${newlineOnDefinition}
${commandEnhanced}${newlineOnDefinition}
${commandEnhancedWithAllocator}
${commandEnhancedSingular}
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap(
commandTemplate,
std::map<std::string, std::string>( { { "commandEnhanced", enhanced },
{ "commandEnhancedDeprecated", enhancedDeprecated },
{ "commandEnhancedSingular", enhancedSingular },
{ "commandEnhancedWithAllocator", enhancedWithAllocator },
{ "commandStandard", standard },
{ "newlineOnDefinition", definition ? "\n" : "" } } ) );
}
std::string VulkanHppGenerator::generateCommandSetStandardEnhancedWithAllocatorSingular(
bool definition,
std::string const & standard,
std::string const & enhanced,
std::string const & enhancedWithAllocator,
std::string const & enhancedSingular ) const
{
std::string const commandTemplate = R"(
${commandStandard}${newlineOnDefinition}
#ifndef VULKAN_HPP_DISABLE_ENHANCED_MODE
${commandEnhanced}${newlineOnDefinition}
${commandEnhancedWithAllocator}${newlineOnDefinition}
${commandEnhancedSingular}${newlineOnDefinition}
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap(
commandTemplate,
std::map<std::string, std::string>( { { "commandEnhanced", enhanced },
{ "commandEnhancedSingular", enhancedSingular },
{ "commandEnhancedWithAllocator", enhancedWithAllocator },
{ "commandStandard", standard },
{ "newlineOnDefinition", definition ? "\n" : "" } } ) );
}
std::string VulkanHppGenerator::generateCommandSetStandardEnhancedWithAllocatorSingularUnique(
bool definition,
std::string const & standard,
std::string const & enhanced,
std::string const & enhancedWithAllocator,
std::string const & enhancedSingular,
std::string const & enhancedUnique,
std::string const & enhancedUniqueWithAllocator,
std::string const & enhancedUniqueSingular ) const
{
std::string const commandTemplate = R"(
${commandStandard}${newlineOnDefinition}
#ifndef VULKAN_HPP_DISABLE_ENHANCED_MODE
${commandEnhanced}${newlineOnDefinition}
${commandEnhancedWithAllocator}${newlineOnDefinition}
${commandEnhancedSingular}${newlineOnDefinition}
# ifndef VULKAN_HPP_NO_SMART_HANDLE
${commandEnhancedUnique}${newlineOnDefinition}
${commandEnhancedUniqueWithAllocator}${newlineOnDefinition}
${commandEnhancedUniqueSingular}
# endif /*VULKAN_HPP_NO_SMART_HANDLE*/
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap(
commandTemplate,
std::map<std::string, std::string>( { { "commandEnhanced", enhanced },
{ "commandEnhancedSingular", enhancedSingular },
{ "commandEnhancedUnique", enhancedUnique },
{ "commandEnhancedUniqueSingular", enhancedUniqueSingular },
{ "commandEnhancedUniqueWithAllocator", enhancedUniqueWithAllocator },
{ "commandEnhancedWithAllocator", enhancedWithAllocator },
{ "commandStandard", standard },
{ "newlineOnDefinition", definition ? "\n" : "" } } ) );
}
std::string VulkanHppGenerator::generateCommandSetStandardEnhancedWithAllocatorUnique(
bool definition,
std::string const & standard,
std::string const & enhanced,
std::string const & enhancedWithAllocator,
std::string const & enhancedUnique,
std::string const & enhancedUniqueWithAllocator ) const
{
std::string const commandTemplate = R"(
${commandStandard}${newlineOnDefinition}
#ifndef VULKAN_HPP_DISABLE_ENHANCED_MODE
${commandEnhanced}${newlineOnDefinition}
${commandEnhancedWithAllocator}${newlineOnDefinition}
# ifndef VULKAN_HPP_NO_SMART_HANDLE
${commandEnhancedUnique}${newlineOnDefinition}
${commandEnhancedUniqueWithAllocator}
# endif /*VULKAN_HPP_NO_SMART_HANDLE*/
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap(
commandTemplate,
std::map<std::string, std::string>( { { "commandEnhanced", enhanced },
{ "commandEnhancedUnique", enhancedUnique },
{ "commandEnhancedUniqueWithAllocator", enhancedUniqueWithAllocator },
{ "commandEnhancedWithAllocator", enhancedWithAllocator },
{ "commandStandard", standard },
{ "newlineOnDefinition", definition ? "\n" : "" } } ) );
}
std::string VulkanHppGenerator::generateCommandSetStandardOrEnhanced( std::string const & standard,
std::string const & enhanced ) const
{
const std::string commandTemplate = R"(
#ifdef VULKAN_HPP_DISABLE_ENHANCED_MODE
${commandStandard}
#else
${commandEnhanced}
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap(
commandTemplate,
std::map<std::string, std::string>( { { "commandEnhanced", enhanced }, { "commandStandard", standard } } ) );
}
std::string VulkanHppGenerator::generateCommandStandard( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition ) const
{
std::set<size_t> skippedParams = determineSkippedParams( commandData.params, initialSkipCount, {}, {}, false );
std::string argumentList = generateArgumentListStandard( commandData.params, skippedParams );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard =
( 1 < commandData.successCodes.size() + commandData.errorCodes.size() ) ? "VULKAN_HPP_NODISCARD " : "";
std::string returnType = stripPrefix( commandData.returnType, "Vk" );
if ( definition )
{
std::string functionBody =
"d." + name + "( " + generateCallArgumentsStandard( commandData.handle, commandData.params ) + " )";
if ( beginsWith( commandData.returnType, "Vk" ) )
{
functionBody = "return static_cast<" + returnType + ">( " + functionBody + " )";
}
else if ( commandData.returnType != "void" )
{
functionBody = "return " + functionBody;
}
std::string const functionTemplate =
R"( template <typename Dispatch>
${nodiscard}VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}( ${argumentList} )${const} VULKAN_HPP_NOEXCEPT
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
${functionBody};
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "const", commandData.handle.empty() ? "" : " const" },
{ "functionBody", functionBody },
{ "nodiscard", nodiscard },
{ "returnType", returnType } } );
}
else
{
std::string const functionTemplate =
R"( template <typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
${nodiscard}${returnType} ${commandName}( ${argumentList} VULKAN_HPP_DEFAULT_DISPATCHER_ASSIGNMENT )${const} VULKAN_HPP_NOEXCEPT;)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "const", commandData.handle.empty() ? "" : " const" },
{ "nodiscard", nodiscard },
{ "returnType", returnType } } );
}
}
std::string VulkanHppGenerator::generateCommandType( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition ) const
{
assert( ( commandData.returnType != "VkResult" ) && ( commandData.returnType != "void" ) &&
commandData.successCodes.empty() && commandData.errorCodes.empty() );
std::set<size_t> skippedParameters = determineSkippedParams( commandData.params, initialSkipCount, {}, {}, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParameters, {}, definition, false, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnType = stripPrefix( commandData.returnType, "Vk" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename Dispatch>
${nodiscard}VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
return d.${vkCommand}( ${callArguments} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
${nodiscard}${returnType} ${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT;)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "returnType", returnType } } );
}
}
std::string VulkanHppGenerator::generateCommandValue( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition ) const
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( commandData.params );
if ( returnParamIndices.empty() )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.empty() )
{
std::vector<size_t> constPointerParamIndices = determineConstPointerParamIndices( commandData.params );
switch ( constPointerParamIndices.size() )
{
case 0:
return generateCommandSetStandard(
generateCommandStandard( name, commandData, initialSkipCount, definition ) );
break;
case 1:
if ( commandData.params[constPointerParamIndices[0]].type.type != "void" )
{
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandType( name, commandData, initialSkipCount, definition ) );
}
break;
}
}
}
return "";
}
std::string VulkanHppGenerator::generateCommandVoid( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices ) const
{
assert( ( commandData.returnType == "void" ) && commandData.successCodes.empty() && commandData.errorCodes.empty() );
std::set<size_t> skippedParameters =
determineSkippedParams( commandData.params, initialSkipCount, vectorParamIndices, {}, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParameters, {}, definition, false, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string typenameT = ( ( vectorParamIndices.size() == 1 ) &&
( commandData.params[vectorParamIndices.begin()->first].type.type == "void" ) )
? "typename T, "
: "";
std::pair<bool, std::map<size_t, std::vector<size_t>>> vectorSizeCheck = needsVectorSizeCheck( vectorParamIndices );
std::string noexceptString = vectorSizeCheck.first ? "VULKAN_HPP_NOEXCEPT_WHEN_NO_EXCEPTIONS" : "VULKAN_HPP_NOEXCEPT";
if ( definition )
{
std::string const functionTemplate =
R"( template <${typenameT}typename Dispatch>
VULKAN_HPP_INLINE void ${className}${classSeparator}${commandName}( ${argumentList} ) const ${noexcept}
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );${vectorSizeCheck}
d.${vkCommand}( ${callArguments} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "noexcept", noexceptString },
{ "typenameT", typenameT },
{ "vectorSizeCheck",
vectorSizeCheck.first
? generateVectorSizeCheck( name, commandData, initialSkipCount, vectorSizeCheck.second, skippedParameters )
: "" },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <${typenameT}typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
void ${commandName}( ${argumentList} ) const ${noexcept};)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "noexcept", noexceptString },
{ "typenameT", typenameT } } );
}
}
std::string VulkanHppGenerator::generateCommandVoid0Return( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition ) const
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
switch ( vectorParamIndices.size() )
{
case 0:
{
std::vector<size_t> constPointerParamIndices = determineConstPointerParamIndices( commandData.params );
if ( std::find_if( constPointerParamIndices.begin(),
constPointerParamIndices.end(),
[&commandData]( size_t idx )
{ return commandData.params[idx].type.type != "void"; } ) == constPointerParamIndices.end() )
{
return generateCommandSetStandard(
generateCommandStandard( name, commandData, initialSkipCount, definition ) );
}
else
{
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandVoid( name, commandData, initialSkipCount, definition, {} ) );
}
}
break;
case 1:
if ( commandData.params[vectorParamIndices.begin()->second].type.isValue() )
{
if ( ( commandData.params[vectorParamIndices.begin()->second].type.type == "uint32_t" ) ||
( commandData.params[vectorParamIndices.begin()->second].type.type == "VkDeviceSize" ) )
{
// Note: no need to care about commandData.params[vectorParamIndices.begin()->first].type.type !
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandVoid( name, commandData, initialSkipCount, definition, vectorParamIndices ) );
}
}
break;
default:
if ( std::find_if( vectorParamIndices.begin(),
vectorParamIndices.end(),
[&commandData]( std::pair<size_t, size_t> const & vpi )
{
return !commandData.params[vpi.second].type.isValue() ||
( commandData.params[vpi.second].type.type != "uint32_t" ) ||
( commandData.params[vpi.first].type.type == "void" );
} ) == vectorParamIndices.end() )
{
// None of the vectorParamIndices has a counter not by value, has a counter different from uint32_t,
// or has a data type void
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandVoid( name, commandData, initialSkipCount, definition, vectorParamIndices ) );
}
break;
}
return "";
}
std::string VulkanHppGenerator::generateCommandVoid1Return( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
if ( isHandleType( commandData.params[returnParamIndex].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.empty() )
{
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandVoidGetValue( name, commandData, initialSkipCount, definition, {}, returnParamIndex ) );
}
}
else if ( isStructureChainAnchor( commandData.params[returnParamIndex].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.empty() )
{
return generateCommandSetStandardEnhancedChained(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandVoidGetValue( name, commandData, initialSkipCount, definition, {}, returnParamIndex ),
generateCommandVoidGetChain( name, commandData, initialSkipCount, definition, returnParamIndex ) );
}
}
else if ( commandData.params[returnParamIndex].type.type != "void" )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
switch ( vectorParamIndices.size() )
{
case 0:
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandVoidGetValue( name, commandData, initialSkipCount, definition, {}, returnParamIndex ) );
break;
case 1:
if ( returnParamIndex != vectorParamIndices.begin()->first )
{
if ( !isHandleType( commandData.params[vectorParamIndices.begin()->first].type.type ) &&
!isStructureChainAnchor( commandData.params[vectorParamIndices.begin()->first].type.type ) &&
( commandData.params[vectorParamIndices.begin()->first].type.type != "void" ) )
{
if ( isLenByStructMember( commandData.params[vectorParamIndices.begin()->first].len,
commandData.params[vectorParamIndices.begin()->second] ) )
{
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandVoidGetValue(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex ) );
}
}
}
break;
}
}
return "";
}
std::string VulkanHppGenerator::generateCommandVoid2Return( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::vector<size_t> const & returnParamIndices ) const
{
if ( commandData.params[returnParamIndices[0]].type.type == "uint32_t" )
{
if ( isStructureChainAnchor( commandData.params[returnParamIndices[1]].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.size() == 1 )
{
if ( returnParamIndices[0] == vectorParamIndices.begin()->second )
{
if ( returnParamIndices[1] == vectorParamIndices.begin()->first )
{
return generateCommandSetStandardEnhancedWithAllocatorChained(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandVoidEnumerate( name,
commandData,
initialSkipCount,
definition,
*vectorParamIndices.begin(),
returnParamIndices,
false ),
generateCommandVoidEnumerate( name,
commandData,
initialSkipCount,
definition,
*vectorParamIndices.begin(),
returnParamIndices,
true ),
generateCommandVoidEnumerateChained( name,
commandData,
initialSkipCount,
definition,
*vectorParamIndices.begin(),
returnParamIndices,
false ),
generateCommandVoidEnumerateChained( name,
commandData,
initialSkipCount,
definition,
*vectorParamIndices.begin(),
returnParamIndices,
true ) );
}
}
}
}
else if ( ( commandData.params[returnParamIndices[1]].type.type != "void" ) &&
!isHandleType( commandData.params[returnParamIndices[1]].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandData.params );
if ( vectorParamIndices.size() == 1 )
{
if ( returnParamIndices[0] == vectorParamIndices.begin()->second )
{
if ( returnParamIndices[1] == vectorParamIndices.begin()->first )
{
return generateCommandSetStandardEnhancedWithAllocator(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandVoidEnumerate( name,
commandData,
initialSkipCount,
definition,
*vectorParamIndices.begin(),
returnParamIndices,
false ),
generateCommandVoidEnumerate( name,
commandData,
initialSkipCount,
definition,
*vectorParamIndices.begin(),
returnParamIndices,
true ) );
}
}
}
}
}
return "";
}
std::string VulkanHppGenerator::generateCommandVoidEnumerate( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::pair<size_t, size_t> const & vectorParamIndex,
std::vector<size_t> const & returnParamIndices,
bool withAllocators ) const
{
assert( commandData.params[0].type.type == commandData.handle && ( commandData.returnType == "void" ) &&
commandData.successCodes.empty() && commandData.errorCodes.empty() );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, { vectorParamIndex }, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, withAllocators, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string vectorElementType = stripPrefix( commandData.params[vectorParamIndex.first].type.type, "Vk" );
if ( definition )
{
const std::string functionTemplate =
R"( template <typename ${vectorElementType}Allocator, typename Dispatch${typenameCheck}>
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::vector<${vectorElementType}, ${vectorElementType}Allocator> ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
std::vector<${vectorElementType}, ${vectorElementType}Allocator> ${vectorName}${vectorAllocator};
${counterType} ${counterName};
d.${vkCommand}( ${firstCallArguments} );
${vectorName}.resize( ${counterName} );
d.${vkCommand}( ${secondCallArguments} );
VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() );
return ${vectorName};
})";
std::string vectorName = startLowerCase( stripPrefix( commandData.params[vectorParamIndex.first].name, "p" ) );
std::string typenameCheck = withAllocators
? ( ", typename B, typename std::enable_if<std::is_same<typename B::value_type, " +
vectorElementType + ">::value, int>::type " )
: "";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "counterName", startLowerCase( stripPrefix( commandData.params[vectorParamIndex.second].name, "p" ) ) },
{ "counterType", commandData.params[vectorParamIndex.second].type.type },
{ "firstCallArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, true, {}, false ) },
{ "secondCallArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "typenameCheck", typenameCheck },
{ "vectorAllocator",
withAllocators
? ( "( " + startLowerCase( stripPrefix( commandData.params[vectorParamIndex.first].type.type, "Vk" ) ) +
"Allocator )" )
: "" },
{ "vectorElementType", vectorElementType },
{ "vectorName", vectorName },
{ "vkCommand", name } } );
}
else
{
const std::string functionTemplate =
R"( template <typename ${vectorElementType}Allocator = std::allocator<${vectorElementType}>, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE${typenameCheck}>
VULKAN_HPP_NODISCARD std::vector<${vectorElementType}, ${vectorElementType}Allocator> ${commandName}( ${argumentList} ) const;)";
std::string typenameCheck = withAllocators
? ( ", typename B = " + vectorElementType +
"Allocator, typename std::enable_if<std::is_same<typename B::value_type, " +
vectorElementType + ">::value, int>::type = 0" )
: "";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "typenameCheck", typenameCheck },
{ "vectorElementType", vectorElementType } } );
}
}
std::string VulkanHppGenerator::generateCommandVoidEnumerateChained( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::pair<size_t, size_t> const & vectorParamIndex,
std::vector<size_t> const & returnParamIndices,
bool withAllocators ) const
{
assert( ( commandData.params[0].type.type == commandData.handle ) && ( commandData.returnType == "void" ) &&
commandData.successCodes.empty() && commandData.errorCodes.empty() );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, { vectorParamIndex }, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, withAllocators, true, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string vectorElementType =
stripPostfix( commandData.params[vectorParamIndex.first].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" );
if ( definition )
{
const std::string functionTemplate =
R"( template <typename StructureChain, typename StructureChainAllocator, typename Dispatch${typenameCheck}>
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::vector<StructureChain, StructureChainAllocator> ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
${counterType} ${counterName};
d.${vkCommand}( ${firstCallArguments} );
std::vector<StructureChain, StructureChainAllocator> returnVector( ${counterName}${structureChainAllocator} );
std::vector<${vectorElementType}> ${vectorName}( ${counterName} );
for ( ${counterType} i = 0; i < ${counterName}; i++ )
{
${vectorName}[i].pNext =
returnVector[i].template get<${vectorElementType}>().pNext;
}
d.${vkCommand}( ${secondCallArguments} );
VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() );
for ( ${counterType} i = 0; i < ${counterName}; i++ )
{
returnVector[i].template get<${vectorElementType}>() = ${vectorName}[i];
}
return returnVector;
})";
std::string vectorName = startLowerCase( stripPrefix( commandData.params[vectorParamIndex.first].name, "p" ) );
std::string typenameCheck =
withAllocators
? ( ", typename B, typename std::enable_if<std::is_same<typename B::value_type, StructureChain>::value, int>::type" )
: "";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "counterName", startLowerCase( stripPrefix( commandData.params[vectorParamIndex.second].name, "p" ) ) },
{ "counterType", commandData.params[vectorParamIndex.second].type.type },
{ "firstCallArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, true, {}, false ) },
{ "secondCallArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "structureChainAllocator", withAllocators ? ( ", structureChainAllocator" ) : "" },
{ "typenameCheck", typenameCheck },
{ "vectorElementType", vectorElementType },
{ "vectorName", vectorName },
{ "vkCommand", name } } );
}
else
{
const std::string functionTemplate =
R"( template <typename StructureChain, typename StructureChainAllocator = std::allocator<StructureChain>, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE${typenameCheck}>
VULKAN_HPP_NODISCARD std::vector<StructureChain, StructureChainAllocator> ${commandName}( ${argumentList} ) const;)";
std::string typenameCheck =
withAllocators
? ( ", typename B = StructureChainAllocator, typename std::enable_if<std::is_same<typename B::value_type, StructureChain>::value, int>::type = 0" )
: "";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList }, { "commandName", commandName }, { "typenameCheck", typenameCheck } } );
}
}
std::string VulkanHppGenerator::generateCommandVoidGetChain( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
assert( ( commandData.returnType == "void" ) && commandData.successCodes.empty() && commandData.errorCodes.empty() );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, {}, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, false, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnType =
stripPostfix( commandData.params[returnParamIndex].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename X, typename Y, typename... Z, typename Dispatch>
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE StructureChain<X, Y, Z...> ${className}${classSeparator}${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
StructureChain<X, Y, Z...> structureChain;
${returnType} & ${returnVariable} = structureChain.template get<${returnType}>();
d.${vkCommand}( ${callArguments} );
return structureChain;
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "returnVariable", startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) ) },
{ "returnType", returnType },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename X, typename Y, typename... Z, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
VULKAN_HPP_NODISCARD StructureChain<X, Y, Z...> ${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT;)";
return replaceWithMap( functionTemplate, { { "argumentList", argumentList }, { "commandName", commandName } } );
}
}
std::string VulkanHppGenerator::generateCommandVoidGetValue( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex ) const
{
assert( ( commandData.returnType == "void" ) && commandData.successCodes.empty() && commandData.errorCodes.empty() );
assert( vectorParamIndices.size() <= 1 );
assert( vectorParamIndices.empty() || ( vectorParamIndices.find( returnParamIndex ) == vectorParamIndices.end() ) );
assert( vectorParamIndices.empty() || ( vectorParamIndices.begin()->second != INVALID_INDEX ) );
std::set<size_t> skippedParameters =
determineSkippedParams( commandData.params, initialSkipCount, {}, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParameters, {}, definition, false, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnType =
stripPostfix( commandData.params[returnParamIndex].type.compose( "VULKAN_HPP_NAMESPACE" ), "*" );
bool needsVectorSizeCheck =
!vectorParamIndices.empty() && isLenByStructMember( commandData.params[vectorParamIndices.begin()->first].len,
commandData.params[vectorParamIndices.begin()->second] );
std::string noexceptString = needsVectorSizeCheck ? "VULKAN_HPP_NOEXCEPT_WHEN_NO_EXCEPTIONS" : "VULKAN_HPP_NOEXCEPT";
if ( definition )
{
std::string className =
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "";
std::string classSeparator = commandData.handle.empty() ? "" : "::";
std::string vectorSizeCheck;
if ( needsVectorSizeCheck )
{
std::string const sizeCheckTemplate =
R"(
#ifdef VULKAN_HPP_NO_EXCEPTIONS
VULKAN_HPP_ASSERT( ${vectorName}.size() == ${sizeValue} );
#else
if ( ${vectorName}.size() != ${sizeValue} )
{
throw LogicError( VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}: ${vectorName}.size() != ${sizeValue}" );
}
#endif /*VULKAN_HPP_NO_EXCEPTIONS*/)";
std::vector<std::string> lenParts = tokenize( commandData.params[vectorParamIndices.begin()->first].len, "->" );
assert( lenParts.size() == 2 );
vectorSizeCheck = replaceWithMap(
sizeCheckTemplate,
{ { "className", className },
{ "classSeparator", classSeparator },
{ "commandName", commandName },
{ "sizeValue", startLowerCase( stripPrefix( lenParts[0], "p" ) ) + "." + lenParts[1] },
{ "vectorName",
startLowerCase( stripPrefix( commandData.params[vectorParamIndices.begin()->first].name, "p" ) ) } } );
}
std::string const functionTemplate =
R"( template <typename Dispatch>
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}( ${argumentList} ) const ${noexcept}
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );${vectorSizeCheck}
${returnType} ${returnVariable};
d.${vkCommand}( ${callArguments} );
return ${returnVariable};
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, false ) },
{ "className", className },
{ "classSeparator", classSeparator },
{ "commandName", commandName },
{ "noexcept", noexceptString },
{ "returnType", returnType },
{ "returnVariable", startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) ) },
{ "vectorSizeCheck", vectorSizeCheck },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
VULKAN_HPP_NODISCARD ${returnType} ${commandName}( ${argumentList} ) const ${noexcept};)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "noexcept", noexceptString },
{ "returnType", returnType } } );
}
}
std::string VulkanHppGenerator::generateConstexprString( std::string const & structName ) const
{
// structs with a VkBaseInStructure and VkBaseOutStructure can't be a constexpr!
bool isConstExpression = ( structName != "VkBaseInStructure" ) && ( structName != "VkBaseOutStructure" );
return isConstExpression ? ( std::string( "VULKAN_HPP_CONSTEXPR" ) +
( ( containsUnion( structName ) || containsArray( structName ) ) ? "_14 " : " " ) )
: "";
}
std::string VulkanHppGenerator::generateDestroyCommand( std::string const & name,
CommandData const & commandData ) const
{
// special handling for destroy functions, filter out alias functions
std::string commandName = generateCommandName( name, commandData.params, 1, m_tags );
if ( commandData.alias.empty() &&
( ( ( name.substr( 2, 7 ) == "Destroy" ) && ( commandName != "destroy" ) ) ||
( name.substr( 2, 4 ) == "Free" ) || ( name == "vkReleasePerformanceConfigurationINTEL" ) ) )
{
assert( 1 < commandData.params.size() );
// make sure, the object to destroy/free/release is not optional in the shortened version!
CommandData localCommandData = commandData;
localCommandData.params[1].optional = false;
std::string destroyCommandString = generateCommand( name, localCommandData, 1, false );
std::string shortenedName;
if ( name.substr( 2, 7 ) == "Destroy" )
{
shortenedName = "destroy";
}
else if ( name.substr( 2, 4 ) == "Free" )
{
shortenedName = "free";
}
else
{
assert( name == "vkReleasePerformanceConfigurationINTEL" );
shortenedName = "release";
}
size_t pos = destroyCommandString.find( commandName );
while ( pos != std::string::npos )
{
destroyCommandString.replace( pos, commandName.length(), shortenedName );
pos = destroyCommandString.find( commandName, pos );
}
// we need to remove the default argument for the first argument, to prevent ambiguities!
assert( 1 < localCommandData.params.size() );
pos = destroyCommandString.find( localCommandData.params[1].name ); // skip the standard version of the function
assert( pos != std::string::npos );
pos = destroyCommandString.find( localCommandData.params[1].name,
pos + 1 ); // get the argument to destroy in the advanced version
assert( pos != std::string::npos );
pos = destroyCommandString.find( " VULKAN_HPP_DEFAULT_ARGUMENT_ASSIGNMENT", pos );
if ( pos != std::string::npos )
{
destroyCommandString.erase( pos, strlen( " VULKAN_HPP_DEFAULT_ARGUMENT_ASSIGNMENT" ) );
}
return "\n" + destroyCommandString;
}
return "";
}
std::string VulkanHppGenerator::generateDispatchLoaderDynamicCommandAssignment( std::string const & commandName,
CommandData const & commandData,
std::string const & firstArg ) const
{
if ( commandName == "vkGetInstanceProcAddr" )
{
// Don't overwite vkGetInstanceProcAddr with NULL.
return "";
}
std::string str = " " + commandName + " = PFN_" + commandName + "( vkGet" +
( ( firstArg == "device" ) ? "Device" : "Instance" ) + "ProcAddr( " + firstArg + ", \"" +
commandName + "\" ) );\n";
// if this is an alias'ed function, use it as a fallback for the original one
if ( !commandData.alias.empty() )
{
str += " if ( !" + commandData.alias + " ) " + commandData.alias + " = " + commandName + ";\n";
}
return str;
}
std::string VulkanHppGenerator::generateDispatchLoaderStaticCommands( std::vector<RequireData> const & requireData,
std::set<std::string> & listedCommands,
std::string const & title ) const
{
std::string str;
for ( auto const & require : requireData )
{
for ( auto const & command : require.commands )
{
// some commands are listed for multiple extensions !
if ( listedCommands.insert( command ).second )
{
auto commandIt = m_commands.find( command );
assert( commandIt != m_commands.end() );
str += "\n";
std::string parameterList, parameters;
assert( !commandIt->second.params.empty() );
for ( auto param : commandIt->second.params )
{
parameterList += param.type.compose( "" ) + " " + param.name + generateCArraySizes( param.arraySizes ) + ", ";
parameters += param.name + ", ";
}
assert( endsWith( parameterList, ", " ) && endsWith( parameters, ", " ) );
parameterList.resize( parameterList.size() - 2 );
parameters.resize( parameters.size() - 2 );
const std::string commandTemplate = R"(
${returnType} ${commandName}( ${parameterList} ) const VULKAN_HPP_NOEXCEPT
{
return ::${commandName}( ${parameters} );
}
)";
str += replaceWithMap( commandTemplate,
{ { "commandName", commandIt->first },
{ "parameterList", parameterList },
{ "parameters", parameters },
{ "returnType", commandIt->second.returnType } } );
}
}
}
return addTitleAndProtection( title, str );
}
std::string VulkanHppGenerator::generateEnhancedReturnType( CommandData const & commandData,
size_t returnParamIndex,
bool isStructureChain ) const
{
assert( ( returnParamIndex == INVALID_INDEX ) || ( returnParamIndex < commandData.params.size() ) );
std::string enhancedReturnType;
assert( returnParamIndex != INVALID_INDEX );
// if there is a return parameter, we think returnType is always "void" or "VkResult"
// -> we can return that parameter
assert( ( commandData.returnType == "void" ) || ( commandData.returnType == "VkResult" ) );
assert( commandData.successCodes.empty() || ( commandData.successCodes[0] == "VK_SUCCESS" ) );
return ( commandData.params[returnParamIndex].type.type == "void" )
? "std::vector<uint8_t,Allocator>" // the return parameter is a vector-type parameter
: isStructureChain ? "std::vector<StructureChain,Allocator>" // for structureChain returns, it's just
// a vector of StrutureChains
: "std::vector<" + stripPrefix( commandData.params[returnParamIndex].type.type, "Vk" ) +
",Allocator>"; // for the other parameters, we use a vector of the pure type
}
std::string VulkanHppGenerator::generateEnum( std::pair<std::string, EnumData> const & enumData ) const
{
std::string bitmask;
if ( enumData.second.isBitmask )
{
auto bitmaskIt =
std::find_if( m_bitmasks.begin(),
m_bitmasks.end(),
[&enumData]( auto const & bitmask ) { return bitmask.second.requirements == enumData.first; } );
assert( bitmaskIt != m_bitmasks.end() );
bitmask = " : " + bitmaskIt->first;
}
std::string enumValues, previousEnter, previousLeave;
std::map<std::string, std::string> valueToNameMap;
for ( auto const & value : enumData.second.values )
{
auto [enter, leave] = generateProtection( value.extension, value.protect );
if ( previousEnter != enter )
{
enumValues += previousLeave + enter;
}
std::string valueName = generateEnumValueName( enumData.first, value.name, enumData.second.isBitmask, m_tags );
enumValues += " " + valueName + " = " + value.name + ",\n";
assert( valueToNameMap.find( valueName ) == valueToNameMap.end() );
valueToNameMap[valueName] = value.name;
previousEnter = enter;
previousLeave = leave;
}
enumValues += previousLeave;
for ( auto const & alias : enumData.second.aliases )
{
std::string aliasName =
generateEnumValueName( enumData.second.alias.empty() ? enumData.first : enumData.second.alias,
alias.first,
enumData.second.isBitmask,
m_tags );
// make sure to only list alias values that differ from all previous values
auto valueToNameIt = valueToNameMap.find( aliasName );
if ( valueToNameIt == valueToNameMap.end() )
{
#if !defined( NDEBUG )
auto enumIt = std::find_if( enumData.second.values.begin(),
enumData.second.values.end(),
[&alias]( EnumValueData const & evd ) { return alias.second.name == evd.name; } );
if ( enumIt == enumData.second.values.end() )
{
auto aliasIt = enumData.second.aliases.find( alias.second.name );
assert( aliasIt != enumData.second.aliases.end() );
auto nextAliasIt = enumData.second.aliases.find( aliasIt->second.name );
while ( nextAliasIt != enumData.second.aliases.end() )
{
aliasIt = nextAliasIt;
nextAliasIt = enumData.second.aliases.find( aliasIt->second.name );
}
enumIt = std::find_if( enumData.second.values.begin(),
enumData.second.values.end(),
[&aliasIt]( EnumValueData const & evd ) { return aliasIt->second.name == evd.name; } );
}
assert( enumIt != enumData.second.values.end() );
assert( enumIt->extension.empty() || generateProtection( enumIt->extension, enumIt->protect ).first.empty() );
#endif
enumValues += " " + aliasName + " = " + alias.first + ",\n";
// map the aliasName to the name of the base
std::string baseName = findBaseName( alias.second.name, enumData.second.aliases );
assert( std::find_if( enumData.second.values.begin(),
enumData.second.values.end(),
[&baseName]( EnumValueData const & evd )
{ return evd.name == baseName; } ) != enumData.second.values.end() );
valueToNameMap[aliasName] = baseName;
}
#if !defined( NDEBUG )
else
{
// verify, that the identical value represents the identical name
std::string baseName = findBaseName( alias.second.name, enumData.second.aliases );
assert( std::find_if( enumData.second.values.begin(),
enumData.second.values.end(),
[&baseName]( EnumValueData const & evd )
{ return evd.name == baseName; } ) != enumData.second.values.end() );
assert( baseName == valueToNameIt->second );
}
#endif
}
if ( !enumValues.empty() )
{
size_t pos = enumValues.rfind( ',' );
assert( pos != std::string::npos );
enumValues.erase( pos, 1 );
enumValues = "\n" + enumValues + " ";
}
std::string enumUsing;
if ( !enumData.second.alias.empty() )
{
enumUsing +=
" using " + stripPrefix( enumData.second.alias, "Vk" ) + " = " + stripPrefix( enumData.first, "Vk" ) + ";\n";
}
const std::string enumTemplate = R"( enum class ${enumName}${bitmask}
{${enumValues}};
${enumUsing})";
return replaceWithMap( enumTemplate,
{ { "bitmask", bitmask },
{ "enumName", stripPrefix( enumData.first, "Vk" ) },
{ "enumUsing", enumUsing },
{ "enumValues", enumValues } } );
}
std::string VulkanHppGenerator::generateEnums( std::vector<RequireData> const & requireData,
std::set<std::string> & listedEnums,
std::string const & title ) const
{
std::string str;
for ( auto const & require : requireData )
{
for ( auto const & type : require.types )
{
auto enumIt = m_enums.find( type );
if ( ( enumIt != m_enums.end() ) && ( listedEnums.find( type ) == listedEnums.end() ) )
{
listedEnums.insert( type );
str += "\n";
str += generateEnum( *enumIt );
str += generateEnumToString( *enumIt );
}
}
}
return addTitleAndProtection( title, str );
}
std::string VulkanHppGenerator::generateEnumInitializer( TypeInfo const & type,
std::vector<std::string> const & arraySizes,
std::vector<EnumValueData> const & values,
bool bitmask ) const
{
// enum arguments might need special initialization
assert( type.prefix.empty() && !values.empty() );
std::string valueName = generateEnumValueName( type.type, values.front().name, bitmask, m_tags );
std::string value = "VULKAN_HPP_NAMESPACE::" + stripPrefix( type.type, "Vk" ) + "::" + valueName;
std::string str;
if ( arraySizes.empty() )
{
str += value;
}
else
{
assert( arraySizes.size() == 1 );
auto constIt = m_constants.find( arraySizes[0] );
int count = std::stoi( ( constIt == m_constants.end() ) ? arraySizes[0] : constIt->second );
assert( 1 < count );
str += "{ { " + value;
for ( int i = 1; i < count; i++ )
{
str += ", " + value;
}
str += " } }";
}
return str;
}
std::string VulkanHppGenerator::generateEnumToString( std::pair<std::string, EnumData> const & enumData ) const
{
std::string enumName = stripPrefix( enumData.first, "Vk" );
std::string functionBody;
if ( enumData.second.values.empty() )
{
functionBody = R"x( return "(void)";)x";
}
else
{
std::string cases, previousEnter, previousLeave;
for ( auto const & value : enumData.second.values )
{
auto [enter, leave] = generateProtection( value.extension, value.protect );
if ( previousEnter != enter )
{
cases += previousLeave + enter;
}
const std::string caseTemplate = R"( case ${enumName}::e${valueName} : return "${valueName}";
)";
cases += replaceWithMap(
caseTemplate,
{ { "enumName", enumName },
{ "valueName",
generateEnumValueName( enumData.first, value.name, enumData.second.isBitmask, m_tags ).substr( 1 ) } } );
previousEnter = enter;
previousLeave = leave;
}
cases += previousLeave;
const std::string functionBodyTemplate =
R"x( switch ( value )
{
${cases} default: return "invalid ( " + VULKAN_HPP_NAMESPACE::toHexString( static_cast<uint32_t>( value ) ) + " )";
}
)x";
functionBody = replaceWithMap( functionBodyTemplate, { { "cases", cases } } );
}
const std::string enumToStringTemplate = R"(
VULKAN_HPP_INLINE std::string to_string( ${enumName}${argument} )
{
${functionBody}
}
)";
return replaceWithMap( enumToStringTemplate,
{ { "argument", enumData.second.values.empty() ? "" : " value" },
{ "enumName", enumName },
{ "functionBody", functionBody } } );
}
std::string VulkanHppGenerator::generateFailureCheck( std::vector<std::string> const & successCodes ) const
{
assert( !successCodes.empty() );
std::string failureCheck = "result != " + generateSuccessCode( successCodes[0], m_tags );
if ( 1 < successCodes.size() )
{
failureCheck = "( " + failureCheck + " )";
for ( size_t i = 1; i < successCodes.size(); ++i )
{
failureCheck += "&& ( result != " + generateSuccessCode( successCodes[i], m_tags ) + " )";
}
}
return failureCheck;
}
std::string VulkanHppGenerator::generateFunctionBodyEnhanced( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
size_t returnParamIndex,
size_t templateParamIndex,
std::map<size_t, size_t> const & vectorParamIndices,
bool twoStep,
std::string const & enhancedReturnType,
bool withAllocator ) const
{
std::string str;
if ( 1 < vectorParamIndices.size() )
{
str += generateFunctionBodyEnhancedMultiVectorSizeCheck(
name, commandData, initialSkipCount, returnParamIndex, vectorParamIndices );
}
std::string returnName;
if ( returnParamIndex != INVALID_INDEX )
{
str += generateFunctionBodyEnhancedLocalReturnVariable(
commandData, returnParamIndex, enhancedReturnType, withAllocator );
returnName = startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) );
}
if ( twoStep )
{
str += generateFunctionBodyEnhancedTwoStep(
name, commandData, returnParamIndex, templateParamIndex, vectorParamIndices, returnName );
}
else
{
str += generateFunctionBodyEnhancedSingleStep(
name, commandData, returnParamIndex, templateParamIndex, vectorParamIndices );
}
if ( ( commandData.returnType == "VkResult" ) || !commandData.successCodes.empty() )
{
str += generateFunctionBodyEnhancedReturnResultValue(
returnName, name, commandData, initialSkipCount, returnParamIndex, twoStep );
}
return str;
}
std::string VulkanHppGenerator::generateFunctionBodyEnhancedLocalReturnVariable( CommandData const & commandData,
size_t returnParamIndex,
std::string const & enhancedReturnType,
bool withAllocator ) const
{
std::string pureReturnType = stripPrefix( commandData.params[returnParamIndex].type.type, "Vk" );
std::string returnName = startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) );
// there is a returned parameter -> we need a local variable to hold that value
assert( stripPrefix( commandData.returnType, "Vk" ) != enhancedReturnType );
// the returned parameter is somehow enhanced by us
// in non-singular case, use the enhanced type for the return variable (like vector<...>)
std::string str = " " + enhancedReturnType + " " + returnName;
if ( withAllocator )
{
str += "( vectorAllocator )";
}
str += ";\n";
return str;
}
std::string VulkanHppGenerator::generateFunctionBodyEnhancedMultiVectorSizeCheck(
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
size_t returnParamIndex,
std::map<size_t, size_t> const & vectorParamIndices ) const
{
std::string const sizeCheckTemplate =
R"#(#ifdef VULKAN_HPP_NO_EXCEPTIONS
VULKAN_HPP_ASSERT( ${firstVectorName}.size() == ${secondVectorName}.size() );
#else
if ( ${firstVectorName}.size() != ${secondVectorName}.size() )
{
throw LogicError( VULKAN_HPP_NAMESPACE_STRING "::${className}::${commandName}: ${firstVectorName}.size() != ${secondVectorName}.size()" );
}
#endif /*VULKAN_HPP_NO_EXCEPTIONS*/
)#";
// add some error checks if multiple vectors need to have the same size
std::string str;
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
for ( std::map<size_t, size_t>::const_iterator it0 = vectorParamIndices.begin(); it0 != vectorParamIndices.end();
++it0 )
{
if ( it0->first != returnParamIndex )
{
for ( std::map<size_t, size_t>::const_iterator it1 = std::next( it0 ); it1 != vectorParamIndices.end(); ++it1 )
{
if ( ( it1->first != returnParamIndex ) && ( it0->second == it1->second ) )
{
str += replaceWithMap(
sizeCheckTemplate,
std::map<std::string, std::string>(
{ { "firstVectorName", startLowerCase( stripPrefix( commandData.params[it0->first].name, "p" ) ) },
{ "secondVectorName", startLowerCase( stripPrefix( commandData.params[it1->first].name, "p" ) ) },
{ "className", commandData.params[initialSkipCount - 1].type.type },
{ "commandName", commandName } } ) );
}
}
}
}
return str;
}
std::string VulkanHppGenerator::generateFunctionBodyEnhancedReturnResultValue( std::string const & returnName,
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
size_t returnParamIndex,
bool twoStep ) const
{
std::string successCodes;
if ( !twoStep && ( 1 < commandData.successCodes.size() ) )
{
// and for the single-step algorithms with more than one success code list them all
successCodes += ", { " + generateSuccessCode( commandData.successCodes[0], m_tags );
for ( size_t i = 1; i < commandData.successCodes.size(); i++ )
{
successCodes += ", " + generateSuccessCode( commandData.successCodes[i], m_tags );
}
successCodes += " }";
}
const std::string createResultValueTemplate =
R"( return createResultValue( result, ${returnName}VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}"${successCodes} );
)";
return replaceWithMap( createResultValueTemplate,
{ { "className", stripPrefix( commandData.handle, "Vk" ) },
{ "commandName", generateCommandName( name, commandData.params, initialSkipCount, m_tags ) },
{ "returnName", ( returnParamIndex != INVALID_INDEX ) ? ( returnName + ", " ) : "" },
{ "successCodes", successCodes } } );
}
std::string VulkanHppGenerator::generateFunctionBodyEnhancedSingleStep(
std::string const & name,
CommandData const & commandData,
size_t returnParamIndex,
size_t templateParamIndex,
std::map<size_t, size_t> const & vectorParamIndices ) const
{
std::string str = " ";
if ( commandData.returnType == "VkResult" )
{
str += "Result result = static_cast<Result>( ";
}
str +=
generateFunctionCall( name, commandData, returnParamIndex, templateParamIndex, vectorParamIndices, false, true );
if ( commandData.returnType == "VkResult" )
{
str += " )";
}
str += ";\n";
return str;
}
std::string
VulkanHppGenerator::generateFunctionBodyEnhancedTwoStep( std::string const & name,
CommandData const & commandData,
size_t returnParamIndex,
size_t templateParamIndex,
std::map<size_t, size_t> const & vectorParamIndices,
std::string const & returnName ) const
{
assert( ( commandData.returnType == "VkResult" ) || ( commandData.returnType == "void" ) );
assert( returnParamIndex != INVALID_INDEX );
// local count variable to hold the size of the vector to fill
std::map<size_t, size_t>::const_iterator returnit = vectorParamIndices.find( returnParamIndex );
assert( returnit != vectorParamIndices.end() && ( returnit->second != INVALID_INDEX ) );
// take the pure type of the size parameter; strip the leading 'p' from its name for its local name
std::string sizeName = startLowerCase( stripPrefix( commandData.params[returnit->second].name, "p" ) );
std::string str =
" " + stripPrefix( commandData.params[returnit->second].type.type, "Vk" ) + " " + sizeName + ";\n";
std::string const multiSuccessTemplate =
R"( Result result;
do
{
result = static_cast<Result>( ${call1} );
if ( ( result == Result::eSuccess ) && ${sizeName} )
{
${returnName}.resize( ${sizeName} );
result = static_cast<Result>( ${call2} );
}
} while ( result == Result::eIncomplete );
if ( result == Result::eSuccess )
{
VULKAN_HPP_ASSERT( ${sizeName} <= ${returnName}.size() );
${returnName}.resize( ${sizeName} );
}
)";
std::string const singleSuccessTemplate =
R"( Result result = static_cast<Result>( ${call1} );
if ( ( result == Result::eSuccess ) && ${sizeName} )
{
${returnName}.resize( ${sizeName} );
result = static_cast<Result>( ${call2} );
}
)";
std::string const voidMultiCallTemplate =
R"( ${call1};
${returnName}.resize( ${sizeName} );
${call2};
)";
std::string const & selectedTemplate =
( commandData.returnType == "VkResult" )
? ( ( 1 < commandData.successCodes.size() ) ? multiSuccessTemplate : singleSuccessTemplate )
: voidMultiCallTemplate;
std::string call1 =
generateFunctionCall( name, commandData, returnParamIndex, templateParamIndex, vectorParamIndices, true, true );
std::string call2 =
generateFunctionCall( name, commandData, returnParamIndex, templateParamIndex, vectorParamIndices, true, false );
str += replaceWithMap(
selectedTemplate,
{ { "sizeName", sizeName }, { "returnName", returnName }, { "call1", call1 }, { "call2", call2 } } );
return str;
}
std::string
VulkanHppGenerator::generateFunctionHeaderArgumentsEnhanced( CommandData const & commandData,
size_t returnParamIndex,
size_t templateParamIndex,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
bool withDefaults,
bool withAllocator ) const
{
std::string str;
// check if there's at least one argument left to put in here
std::vector<size_t> returnParamIndices;
if ( returnParamIndex != INVALID_INDEX )
{
returnParamIndices.push_back( returnParamIndex );
}
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
if ( skippedParams.size() < commandData.params.size() )
{
str += " ";
bool argEncountered = false;
for ( size_t i = 0; i < commandData.params.size(); i++ )
{
std::string arg = generateFunctionHeaderArgumentEnhanced( commandData.params[i],
i,
vectorParamIndices,
skippedParams.find( i ) != skippedParams.end(),
( templateParamIndex == i ) );
if ( !arg.empty() )
{
str += ( argEncountered ? ", " : "" ) + arg;
argEncountered = true;
}
}
if ( argEncountered )
{
str += ", ";
}
}
if ( withAllocator )
{
str += "Allocator const & vectorAllocator, ";
}
str += "Dispatch const &d";
if ( withDefaults )
{
str += " VULKAN_HPP_DEFAULT_DISPATCHER_ASSIGNMENT";
}
str += " ";
return str;
}
std::string VulkanHppGenerator::generateFunctionCall( std::string const & name,
CommandData const & commandData,
size_t returnParamIndex,
size_t templateParamIndex,
std::map<size_t, size_t> const & vectorParamIndices,
bool twoStep,
bool firstCall ) const
{
// the original function call
std::string str = "d." + name + "( ";
bool encounteredArgument = false;
if ( !commandData.handle.empty() )
{
auto handleIt = m_handles.find( commandData.handle );
assert( handleIt != m_handles.end() );
// if it's member of a class -> the first argument is the member variable, starting with "m_"
assert( handleIt->first == commandData.params[0].type.type );
str += "m_" + startLowerCase( stripPrefix( handleIt->first, "Vk" ) );
encounteredArgument = true;
}
// generate the command arguments
size_t firstArgument = commandData.handle.empty() ? 0 : 1;
assert( firstArgument <= commandData.params.size() );
for ( size_t i = firstArgument; i < commandData.params.size(); i++ )
{
if ( encounteredArgument )
{
str += ", ";
}
auto it = vectorParamIndices.find( i );
if ( it != vectorParamIndices.end() )
{
// this parameter is a vector parameter
assert( commandData.params[it->first].type.postfix.back() == '*' );
if ( ( returnParamIndex == it->first ) && twoStep && firstCall )
{
// this parameter is the return parameter, and it's the first call of a two-step algorithm -> just just nullptr
str += "nullptr";
}
else
{
std::string parameterName = startLowerCase( stripPrefix( commandData.params[it->first].name, "p" ) );
if ( beginsWith( commandData.params[it->first].type.type, "Vk" ) || ( it->first == templateParamIndex ) )
{
// CHECK for !commandData.params[it->first].optional
// this parameter is a vulkan type or a templated type -> need to reinterpret cast
str += "reinterpret_cast<";
if ( commandData.params[it->first].type.prefix.find( "const" ) == 0 )
{
str += "const ";
}
str += commandData.params[it->first].type.type + "*>( " + parameterName + ".data() )";
}
else
{
// this parameter is just a vetor -> get the pointer to its data
str += parameterName + ".data()";
}
}
}
else
{
it = find_if( vectorParamIndices.begin(),
vectorParamIndices.end(),
[i]( std::pair<size_t, size_t> const & vpi ) { return vpi.second == i; } );
if ( it != vectorParamIndices.end() )
{
// this parameter is a count parameter for a vector parameter
// the corresponding vector parameter is not the return parameter, or it's not a two-step algorithm
// for the non-singular version, the count is the size of the vector parameter
// -> use the vector parameter name without leading 'p' to get the size (in number of elements, not in bytes)
assert( commandData.params[it->first].name[0] == 'p' );
str += startLowerCase( stripPrefix( commandData.params[it->first].name, "p" ) ) + ".size() ";
if ( it->first == templateParamIndex )
{
// if the vector parameter is templatized -> multiply by the size of that type to get the size in bytes
str += "* sizeof( T ) ";
}
}
else if ( beginsWith( commandData.params[i].type.type, "Vk" ) )
{
str += "static_cast<" + commandData.params[i].type.type + ">( " + commandData.params[i].name + " )";
}
else
{
// this parameter is just a plain type
if ( !commandData.params[i].type.postfix.empty() )
{
assert( commandData.params[i].type.postfix.back() == '*' );
// it's a pointer
std::string parameterName = startLowerCase( stripPrefix( commandData.params[i].name, "p" ) );
// it's a non-const pointer, and char is the only type that occurs -> use the address of the parameter
assert( commandData.params[i].type.type.find( "char" ) == std::string::npos );
str += "&" + parameterName;
}
else
{
// it's a plain parameter -> just use its name
str += commandData.params[i].name;
}
}
}
encounteredArgument = true;
}
str += " )";
return str;
}
std::string
VulkanHppGenerator::generateFunctionHeaderArgumentEnhanced( ParamData const & param,
size_t paramIndex,
std::map<size_t, size_t> const & vectorParamIndices,
bool skip,
bool isTemplateParam ) const
{
std::string str;
if ( !skip )
{
std::string strippedParameterName = startLowerCase( stripPrefix( param.name, "p" ) );
std::map<size_t, size_t>::const_iterator it = vectorParamIndices.find( paramIndex );
if ( it == vectorParamIndices.end() )
{
// the argument ist not a vector
assert( param.type.postfix.empty() );
// and its not a pointer -> just use its type and name here
str += param.type.compose( "VULKAN_HPP_NAMESPACE" ) + " " + param.name + generateCArraySizes( param.arraySizes );
}
else
{
// the argument is a vector
str += generateFunctionHeaderArgumentEnhancedVector(
param, strippedParameterName, it->second != INVALID_INDEX, isTemplateParam );
}
}
return str;
}
std::string VulkanHppGenerator::generateFunctionHeaderArgumentEnhancedVector( ParamData const & param,
std::string const & strippedParameterName,
bool hasSizeParam,
bool isTemplateParam ) const
{
assert( param.type.postfix.back() == '*' );
// it's optional, if it's marked as optional and there's no size specified
bool optional = param.optional && !hasSizeParam;
// use our ArrayProxy
bool isConst = ( param.type.prefix.find( "const" ) != std::string::npos );
return std::string( optional ? "Optional<" : "" ) + "ArrayProxy<" +
( isTemplateParam ? ( isConst ? "const T" : "T" )
: stripPostfix( param.type.compose( "VULKAN_HPP_NAMESPACE" ), "*" ) ) +
"> const &" + ( optional ? "> " : "" ) + strippedParameterName;
}
std::string VulkanHppGenerator::generateFunctionPointerCheck( std::string const & function,
std::string const & referencedIn ) const
{
std::string functionPointerCheck;
if ( m_extensions.find( referencedIn ) != m_extensions.end() )
{
std::string message = "Function <" + function + "> needs extension <" + referencedIn + "> enabled!";
functionPointerCheck = "\n VULKAN_HPP_ASSERT( getDispatcher()->" + function + " && \"" + message + "\" );\n";
}
return functionPointerCheck;
}
std::string VulkanHppGenerator::generateHandle( std::pair<std::string, HandleData> const & handleData,
std::set<std::string> & listedHandles ) const
{
assert( listedHandles.find( handleData.first ) == listedHandles.end() );
// first check for any handle that needs to be listed before this one
std::string str = generateHandleDependencies( handleData, listedHandles );
// list the commands of this handle
if ( handleData.first.empty() )
{
// the free functions, not bound to any handle
str += generateHandleEmpty( handleData.second );
}
else
{
// append any forward declaration of Deleters used by this handle
if ( !handleData.second.childrenHandles.empty() )
{
str += generateUniqueTypes( handleData.first, handleData.second.childrenHandles );
}
else if ( handleData.first == "VkPhysicalDevice" )
{
// special handling for class Device, as it's created from PhysicalDevice, but destroys itself
str += generateUniqueTypes( "", { "VkDevice" } );
}
// list all the commands that are mapped to members of this class
std::string commands = generateHandleCommandDeclarations( handleData.second.commands );
// create CPPType template specialization and the debugReportObjectType
std::string valueName = handleData.second.objTypeEnum;
valueName = valueName.replace( 3, 0, "DEBUG_REPORT_" ) + "_EXT";
auto enumIt = m_enums.find( "VkDebugReportObjectTypeEXT" );
assert( enumIt != m_enums.end() );
auto valueIt = std::find_if( enumIt->second.values.begin(),
enumIt->second.values.end(),
[&valueName]( EnumValueData const & evd ) { return valueName == evd.name; } );
std::string className = stripPrefix( handleData.first, "Vk" );
std::string cppType, debugReportObjectType;
if ( valueIt == enumIt->second.values.end() )
{
debugReportObjectType = "eUnknown";
}
else
{
static const std::string cppTypeFromDebugReportObjectTypeEXTTemplate = R"(
template <>
struct CppType<VULKAN_HPP_NAMESPACE::DebugReportObjectTypeEXT, VULKAN_HPP_NAMESPACE::DebugReportObjectTypeEXT::e${className}>
{
using Type = VULKAN_HPP_NAMESPACE::${className};
};
)";
cppType = replaceWithMap( cppTypeFromDebugReportObjectTypeEXTTemplate, { { "className", className } } );
debugReportObjectType = generateEnumValueName( enumIt->first, valueIt->name, false, m_tags );
}
auto [enter, leave] = generateProtection( handleData.first, !handleData.second.alias.empty() );
assert( !handleData.second.objTypeEnum.empty() );
enumIt = m_enums.find( "VkObjectType" );
assert( enumIt != m_enums.end() );
valueIt =
std::find_if( enumIt->second.values.begin(),
enumIt->second.values.end(),
[&handleData]( EnumValueData const & evd ) { return evd.name == handleData.second.objTypeEnum; } );
assert( valueIt != enumIt->second.values.end() );
std::string usingAlias;
if ( !handleData.second.alias.empty() )
{
usingAlias += " using " + stripPrefix( handleData.second.alias, "Vk" ) + " = " +
stripPrefix( handleData.first, "Vk" ) + ";\n";
}
static const std::string templateString = R"(
${enter} class ${className}
{
public:
using CType = Vk${className};
using NativeType = Vk${className};
static VULKAN_HPP_CONST_OR_CONSTEXPR VULKAN_HPP_NAMESPACE::ObjectType objectType = VULKAN_HPP_NAMESPACE::ObjectType::${objTypeEnum};
static VULKAN_HPP_CONST_OR_CONSTEXPR VULKAN_HPP_NAMESPACE::DebugReportObjectTypeEXT debugReportObjectType = VULKAN_HPP_NAMESPACE::DebugReportObjectTypeEXT::${debugReportObjectType};
public:
VULKAN_HPP_CONSTEXPR ${className}() = default;
VULKAN_HPP_CONSTEXPR ${className}( std::nullptr_t ) VULKAN_HPP_NOEXCEPT
{}
VULKAN_HPP_TYPESAFE_EXPLICIT ${className}( Vk${className} ${memberName} ) VULKAN_HPP_NOEXCEPT
: m_${memberName}( ${memberName} )
{}
#if defined(VULKAN_HPP_TYPESAFE_CONVERSION)
${className} & operator=(Vk${className} ${memberName}) VULKAN_HPP_NOEXCEPT
{
m_${memberName} = ${memberName};
return *this;
}
#endif
${className} & operator=( std::nullptr_t ) VULKAN_HPP_NOEXCEPT
{
m_${memberName} = {};
return *this;
}
#if defined(VULKAN_HPP_HAS_SPACESHIP_OPERATOR)
auto operator<=>( ${className} const & ) const = default;
#else
bool operator==( ${className} const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return m_${memberName} == rhs.m_${memberName};
}
bool operator!=(${className} const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return m_${memberName} != rhs.m_${memberName};
}
bool operator<(${className} const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return m_${memberName} < rhs.m_${memberName};
}
#endif
${commands}
VULKAN_HPP_TYPESAFE_EXPLICIT operator Vk${className}() const VULKAN_HPP_NOEXCEPT
{
return m_${memberName};
}
explicit operator bool() const VULKAN_HPP_NOEXCEPT
{
return m_${memberName} != VK_NULL_HANDLE;
}
bool operator!() const VULKAN_HPP_NOEXCEPT
{
return m_${memberName} == VK_NULL_HANDLE;
}
private:
Vk${className} m_${memberName} = {};
};
VULKAN_HPP_STATIC_ASSERT( sizeof( VULKAN_HPP_NAMESPACE::${className} ) == sizeof( Vk${className} ), "handle and wrapper have different size!" );
VULKAN_HPP_STATIC_ASSERT( std::is_nothrow_move_constructible<VULKAN_HPP_NAMESPACE::${className}>::value, "${className} is not nothrow_move_constructible!" );
template <>
struct VULKAN_HPP_DEPRECATED("vk::cpp_type is deprecated. Use vk::CppType instead.") cpp_type<ObjectType::${objTypeEnum}>
{
using type = VULKAN_HPP_NAMESPACE::${className};
};
template <>
struct CppType<VULKAN_HPP_NAMESPACE::ObjectType, VULKAN_HPP_NAMESPACE::ObjectType::${objTypeEnum}>
{
using Type = VULKAN_HPP_NAMESPACE::${className};
};
${CppType}
template <>
struct isVulkanHandleType<VULKAN_HPP_NAMESPACE::${className}>
{
static VULKAN_HPP_CONST_OR_CONSTEXPR bool value = true;
};
${usingAlias}${leave})";
str += replaceWithMap( templateString,
{ { "className", className },
{ "commands", commands },
{ "CppType", cppType },
{ "debugReportObjectType", debugReportObjectType },
{ "enter", enter },
{ "leave", leave },
{ "memberName", startLowerCase( stripPrefix( handleData.first, "Vk" ) ) },
{ "objTypeEnum", generateEnumValueName( enumIt->first, valueIt->name, false, m_tags ) },
{ "usingAlias", usingAlias } } );
}
listedHandles.insert( handleData.first );
return str;
}
std::string VulkanHppGenerator::generateHandleCommandDeclarations( std::set<std::string> const & commands ) const
{
std::string str;
std::set<std::string> listedCommands; // some commands are listed with more than one extension!
for ( auto const & feature : m_features )
{
std::vector<std::string> commandNames =
selectCommandsByHandle( feature.second.requireData, commands, listedCommands );
if ( !commandNames.empty() )
{
str += "\n //=== " + feature.first + " ===\n";
for ( auto const & command : commandNames )
{
auto commandIt = m_commands.find( command );
assert( commandIt != m_commands.end() );
str += "\n";
str += generateCommand( commandIt->first, commandIt->second, 1, false );
str += generateDestroyCommand( commandIt->first, commandIt->second );
}
}
}
for ( auto const & extIt : m_extensionsByNumber )
{
std::vector<std::string> commandNames =
selectCommandsByHandle( extIt.second->second.requireData, commands, listedCommands );
if ( !commandNames.empty() )
{
auto [enter, leave] = generateProtection( extIt.second->first, std::string() );
str += "\n" + enter + " //=== " + extIt.second->first + " ===\n";
for ( auto const & command : commandNames )
{
auto commandIt = m_commands.find( command );
assert( commandIt != m_commands.end() );
std::string commandString;
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, 1, m_tags );
str += "\n";
str += generateCommand( commandIt->first, commandIt->second, 1, false );
str += generateDestroyCommand( commandIt->first, commandIt->second );
}
str += leave;
}
}
return str;
}
std::string VulkanHppGenerator::generateHandleDependencies( std::pair<std::string, HandleData> const & handleData,
std::set<std::string> & listedHandles ) const
{
std::string str;
for ( auto const & command : handleData.second.commands )
{
auto commandIt = m_commands.find( command );
assert( commandIt != m_commands.end() );
for ( auto const & parameter : commandIt->second.params )
{
auto handleIt = m_handles.find( parameter.type.type );
if ( ( handleIt != m_handles.end() ) && ( parameter.type.type != handleData.first ) &&
( listedHandles.find( parameter.type.type ) == listedHandles.end() ) )
{
str += generateHandle( *handleIt, listedHandles );
}
}
}
return str;
}
std::string VulkanHppGenerator::generateHandleEmpty( HandleData const & handleData ) const
{
std::string str;
std::set<std::string> listedCommands; // some commands are listed with more than one extension !
for ( auto const & feature : m_features )
{
std::vector<std::string> commands =
selectCommandsByHandle( feature.second.requireData, handleData.commands, listedCommands );
if ( !commands.empty() )
{
str += "\n //=== " + feature.first + " ===\n";
for ( auto const & command : commands )
{
auto commandIt = m_commands.find( command );
assert( commandIt != m_commands.end() );
if ( commandIt->first == "vkCreateInstance" )
{
// special handling for createInstance, as we need to explicitly place the forward declarations and the
// deleter classes here
#if !defined( NDEBUG )
auto handleIt = m_handles.find( "" );
assert( ( handleIt != m_handles.end() ) && ( handleIt->second.childrenHandles.size() == 2 ) );
assert( handleIt->second.childrenHandles.find( "VkInstance" ) != handleIt->second.childrenHandles.end() );
#endif
str += generateUniqueTypes( "", { "VkInstance" } );
}
str += "\n";
str += generateCommand( commandIt->first, commandIt->second, 0, false );
}
}
}
#if !defined( NDEBUG )
for ( auto const & extIt : m_extensionsByNumber )
{
assert( selectCommandsByHandle( extIt.second->second.requireData, handleData.commands, listedCommands ).empty() );
}
#endif
return str;
}
std::string VulkanHppGenerator::generateHashStructures( std::vector<RequireData> const & requireData,
std::string const & title ) const
{
const std::string hashTemplate = R"(
template <> struct hash<VULKAN_HPP_NAMESPACE::${type}>
{
std::size_t operator()(VULKAN_HPP_NAMESPACE::${type} const & ${name}) const VULKAN_HPP_NOEXCEPT
{
return std::hash<Vk${type}>{}(static_cast<Vk${type}>(${name}));
}
};
)";
std::string str;
for ( auto const & require : requireData )
{
for ( auto const & type : require.types )
{
auto handleIt = m_handles.find( type );
if ( handleIt != m_handles.end() )
{
std::string handleType = stripPrefix( handleIt->first, "Vk" );
std::string handleName = startLowerCase( handleType );
str += replaceWithMap( hashTemplate, { { "name", handleName }, { "type", handleType } } );
}
}
}
return addTitleAndProtection( title, str );
}
std::string VulkanHppGenerator::generateLenInitializer(
std::vector<MemberData>::const_iterator mit,
std::map<std::vector<MemberData>::const_iterator,
std::vector<std::vector<MemberData>::const_iterator>>::const_iterator litit,
bool mutualExclusiveLens ) const
{
std::string initializer;
if ( mutualExclusiveLens )
{
// there are multiple mutually exclusive arrays related to this len
for ( size_t i = 0; i + 1 < litit->second.size(); i++ )
{
auto arrayIt = litit->second[i];
std::string argumentName = startLowerCase( stripPrefix( arrayIt->name, "p" ) ) + "_";
initializer += "!" + argumentName + ".empty() ? " + argumentName + ".size() : ";
}
auto arrayIt = litit->second.back();
std::string argumentName = startLowerCase( stripPrefix( arrayIt->name, "p" ) ) + "_";
initializer += argumentName + ".size()";
}
else
{
auto arrayIt = litit->second.front();
assert( ( arrayIt->len.front() == litit->first->name ) ||
( ( arrayIt->len.front() == "codeSize / 4" ) && ( litit->first->name == "codeSize" ) ) );
assert( beginsWith( arrayIt->name, "p" ) );
std::string argumentName = startLowerCase( stripPrefix( arrayIt->name, "p" ) ) + "_";
assert( mit->type.prefix.empty() && mit->type.postfix.empty() );
initializer = argumentName + ".size()";
if ( arrayIt->len.front() == "codeSize / 4" )
{
initializer += " * 4";
}
if ( ( arrayIt->type.type == "void" ) &&
( std::count_if(
arrayIt->type.postfix.begin(), arrayIt->type.postfix.end(), []( char c ) { return c == '*'; } ) < 2 ) )
{
initializer += " * sizeof(T)";
}
}
if ( mit->type.type != "size_t" )
{
initializer = "static_cast<" + mit->type.type + ">( " + initializer + " )";
}
return initializer;
}
std::string VulkanHppGenerator::generateName( TypeInfo const & typeInfo ) const
{
std::string name = stripPrefix( typeInfo.type, "Vk" );
assert( typeInfo.prefix.find( '*' ) == std::string::npos );
if ( typeInfo.postfix.find( '*' ) != std::string::npos )
{
assert( typeInfo.postfix.find_first_of( '*' ) == typeInfo.postfix.find_last_of( '*' ) );
name = "p" + name;
}
else
{
name = startLowerCase( name );
}
return name;
}
std::pair<std::string, std::string> VulkanHppGenerator::generateProtection( std::string const & referencedIn,
std::string const & protect ) const
{
if ( !referencedIn.empty() )
{
if ( m_features.find( referencedIn ) == m_features.end() )
{
auto extensionIt = m_extensions.find( referencedIn );
assert( extensionIt != m_extensions.end() );
if ( !extensionIt->second.platform.empty() )
{
auto platformIt = m_platforms.find( extensionIt->second.platform );
assert( platformIt != m_platforms.end() );
if ( !platformIt->second.protect.empty() )
{
return std::make_pair( "#if defined( " + platformIt->second.protect + " )\n",
"#endif /*" + platformIt->second.protect + "*/\n" );
}
}
}
}
else if ( !protect.empty() )
{
return std::make_pair( "#if defined( " + protect + " )\n", "#endif /*" + protect + "*/\n" );
}
return std::make_pair( "", "" );
}
std::pair<std::string, std::string> VulkanHppGenerator::generateProtection( std::string const & type,
bool isAliased ) const
{
if ( isAliased )
{
return std::make_pair( "", "" );
}
else
{
auto typeIt = m_types.find( type );
assert( typeIt != m_types.end() );
return generateProtection( typeIt->second.referencedIn, std::string() );
}
}
std::string VulkanHppGenerator::generateRAIICommandDefinitions( std::vector<RequireData> const & requireData,
std::set<std::string> & listedCommands,
std::string const & title ) const
{
std::string str;
for ( auto const & require : requireData )
{
for ( auto const & command : require.commands )
{
if ( listedCommands.insert( command ).second )
{
str += generateRAIIHandleCommand( command, determineInitialSkipCount( command ), true );
}
}
}
return addTitleAndProtection( title, str );
}
std::string VulkanHppGenerator::generateRAIIHandle( std::pair<std::string, HandleData> const & handle,
std::set<std::string> & listedHandles,
std::set<std::string> const & specialFunctions ) const
{
std::string str;
if ( listedHandles.find( handle.first ) == listedHandles.end() )
{
rescheduleRAIIHandle( str, handle, listedHandles, specialFunctions );
auto [enter, leave] = generateProtection( handle.first, !handle.second.alias.empty() );
std::string handleType = stripPrefix( handle.first, "Vk" );
std::string handleName = generateRAIIHandleConstructorParamName( handle.first, handle.second.destructorIt );
auto [singularConstructors, arrayConstructors] = generateRAIIHandleConstructors( handle );
auto [destructor, destructorCall] =
( handle.second.destructorIt == m_commands.end() )
? std::make_pair( "", "" )
: generateRAIIHandleDestructor( handle.first, handle.second.destructorIt, enter );
auto [getConstructorSuccessCode, memberVariables, moveConstructorInitializerList, moveAssignmentInstructions] =
generateRAIIHandleDetails( handle, destructorCall );
std::string declarations = generateRAIIHandleCommandDeclarations( handle, specialFunctions );
assert( !handle.second.objTypeEnum.empty() );
auto enumIt = m_enums.find( "VkObjectType" );
assert( enumIt != m_enums.end() );
auto valueIt =
std::find_if( enumIt->second.values.begin(),
enumIt->second.values.end(),
[&handle]( EnumValueData const & evd ) { return evd.name == handle.second.objTypeEnum; } );
assert( valueIt != enumIt->second.values.end() );
std::string objTypeEnum = generateEnumValueName( enumIt->first, valueIt->name, false, m_tags );
enumIt = m_enums.find( "VkDebugReportObjectTypeEXT" );
assert( enumIt != m_enums.end() );
std::string valueName = handle.second.objTypeEnum;
valueName = valueName.replace( 3, 0, "DEBUG_REPORT_" ) + "_EXT";
valueIt = std::find_if( enumIt->second.values.begin(),
enumIt->second.values.end(),
[&valueName]( EnumValueData const & evd ) { return valueName == evd.name; } );
std::string debugReportObjectType = ( valueIt != enumIt->second.values.end() )
? generateEnumValueName( enumIt->first, valueIt->name, false, m_tags )
: "eUnknown";
std::string dispatcherType =
( ( handle.first == "VkDevice" ) ||
( handle.second.constructorIts.front()->second.params.front().type.type == "VkDevice" ) )
? "VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::DeviceDispatcher"
: "VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::InstanceDispatcher";
std::string getParent;
if ( ( handle.first != "VkInstance" ) && ( handle.first != "VkDevice" ) &&
( handle.second.destructorIt != m_commands.end() ) )
{
assert( !handle.second.destructorIt->second.params.empty() );
std::string parentType = stripPrefix( handle.second.destructorIt->second.params.front().type.type, "Vk" );
getParent = " VULKAN_HPP_NAMESPACE::" + parentType + " get" + parentType + "() const\n";
getParent += " {\n";
getParent += " return m_" + handle.second.destructorIt->second.params.front().name + ";\n";
getParent += " }\n";
}
const std::string handleTemplate = R"(
${enter} class ${handleType}
{
public:
using CType = Vk${handleType};
static VULKAN_HPP_CONST_OR_CONSTEXPR VULKAN_HPP_NAMESPACE::ObjectType objectType = VULKAN_HPP_NAMESPACE::ObjectType::${objTypeEnum};
static VULKAN_HPP_CONST_OR_CONSTEXPR VULKAN_HPP_NAMESPACE::DebugReportObjectTypeEXT debugReportObjectType = VULKAN_HPP_NAMESPACE::DebugReportObjectTypeEXT::${debugReportObjectType};
public:
${singularConstructors}
${handleType}( std::nullptr_t ) {}
${destructor}
${handleType}() = delete;
${handleType}( ${handleType} const & ) = delete;
${handleType}( ${handleType} && rhs ) VULKAN_HPP_NOEXCEPT
: ${moveConstructorInitializerList}
{}
${handleType} & operator=( ${handleType} const & ) = delete;
${handleType} & operator=( ${handleType} && rhs ) VULKAN_HPP_NOEXCEPT
{
if ( this != &rhs )
{
${moveAssignmentInstructions}
}
return *this;
}
VULKAN_HPP_NAMESPACE::${handleType} const & operator*() const VULKAN_HPP_NOEXCEPT
{
return m_${handleName};
}
${getConstructorSuccessCode}
${getParent}
${dispatcherType} const * getDispatcher() const
{
VULKAN_HPP_ASSERT( m_dispatcher->getVkHeaderVersion() == VK_HEADER_VERSION );
return ${getDispatcherReturn}m_dispatcher;
}
${memberFunctionsDeclarations}
private:
${memberVariables}
};
${leave})";
str += replaceWithMap(
handleTemplate,
{ { "debugReportObjectType", debugReportObjectType },
{ "destructor", destructor },
{ "dispatcherType", dispatcherType },
{ "enter", enter },
{ "getConstructorSuccessCode", getConstructorSuccessCode },
{ "getDispatcherReturn", ( handleType == "Device" ) || ( handleType == "Instance" ) ? "&*" : "" },
{ "getParent", getParent },
{ "handleName", handleName },
{ "handleType", handleType },
{ "leave", leave },
{ "memberFunctionsDeclarations", declarations },
{ "memberVariables", memberVariables },
{ "moveAssignmentInstructions", moveAssignmentInstructions },
{ "moveConstructorInitializerList", moveConstructorInitializerList },
{ "objTypeEnum", objTypeEnum },
{ "singularConstructors", singularConstructors } } );
if ( !arrayConstructors.empty() )
{
// it's a handle class with a friendly handles class
const std::string handlesTemplate = R"(
${enter} class ${handleType}s : public std::vector<VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::${handleType}>
{
public:
${arrayConstructors}
${handleType}s() = delete;
${handleType}s( ${handleType}s const & ) = delete;
${handleType}s( ${handleType}s && rhs ) = default;
${handleType}s & operator=( ${handleType}s const & ) = delete;
${handleType}s & operator=( ${handleType}s && rhs ) = default;
};
${leave}
)";
str += replaceWithMap( handlesTemplate,
{ { "arrayConstructors", arrayConstructors },
{ "enter", enter },
{ "handleType", handleType },
{ "leave", leave } } );
}
}
return str;
}
std::string VulkanHppGenerator::generateRAIIHandleCommand( std::string const & command,
size_t initialSkipCount,
bool definition ) const
{
std::string str;
if ( m_RAIISpecialFunctions.find( command ) == m_RAIISpecialFunctions.end() )
{
auto commandIt = m_commands.find( command );
assert( commandIt != m_commands.end() );
if ( commandIt->second.returnType == "VkResult" )
{
str = generateRAIIHandleCommandResult( commandIt, initialSkipCount, definition );
}
else if ( commandIt->second.returnType == "void" )
{
str = generateRAIIHandleCommandVoid( commandIt, initialSkipCount, definition );
}
else
{
str = generateRAIIHandleCommandValue( commandIt, initialSkipCount, definition );
}
if ( str.empty() )
{
throw std::runtime_error( "Never encountered a command like <" + commandIt->first + "> !" );
}
}
return str;
}
std::string
VulkanHppGenerator::generateRAIIHandleCommandDeclarations( std::pair<std::string, HandleData> const & handle,
std::set<std::string> const & specialFunctions ) const
{
std::string functionDeclarations;
std::set<std::string> listedCommands; // some commands are listed with more than one extension !
for ( auto const & feature : m_features )
{
std::vector<std::string> firstLevelCommands, secondLevelCommands;
for ( auto const & require : feature.second.requireData )
{
for ( auto const & command : require.commands )
{
if ( specialFunctions.find( command ) == specialFunctions.end() )
{
if ( handle.second.commands.find( command ) != handle.second.commands.end() )
{
assert( listedCommands.find( command ) == listedCommands.end() );
listedCommands.insert( command );
firstLevelCommands.push_back( command );
}
else if ( handle.second.secondLevelCommands.find( command ) != handle.second.secondLevelCommands.end() )
{
assert( listedCommands.find( command ) == listedCommands.end() );
listedCommands.insert( command );
assert( !handle.first.empty() );
secondLevelCommands.push_back( command );
}
}
}
}
if ( !firstLevelCommands.empty() || !secondLevelCommands.empty() )
{
functionDeclarations += "\n //=== " + feature.first + " ===\n";
for ( auto const & command : firstLevelCommands )
{
functionDeclarations += generateRAIIHandleCommand( command, handle.first.empty() ? 0 : 1, false );
}
for ( auto const & command : secondLevelCommands )
{
assert( !handle.first.empty() );
functionDeclarations += generateRAIIHandleCommand( command, 2, false );
}
}
}
for ( auto const & extIt : m_extensionsByNumber )
{
std::vector<std::string> firstLevelCommands, secondLevelCommands;
for ( auto & req : extIt.second->second.requireData )
{
for ( auto const & command : req.commands )
{
if ( ( specialFunctions.find( command ) == specialFunctions.end() ) &&
( listedCommands.find( command ) == listedCommands.end() ) )
{
if ( handle.second.commands.find( command ) != handle.second.commands.end() )
{
listedCommands.insert( command );
firstLevelCommands.push_back( command );
}
else if ( handle.second.secondLevelCommands.find( command ) != handle.second.secondLevelCommands.end() )
{
listedCommands.insert( command );
secondLevelCommands.push_back( command );
}
}
}
}
if ( !firstLevelCommands.empty() || !secondLevelCommands.empty() )
{
std::string enter, leave;
if ( extIt.second->first != m_types.find( handle.first )->second.referencedIn )
{
std::tie( enter, leave ) = generateProtection( extIt.second->first, std::string() );
}
functionDeclarations += "\n" + enter + " //=== " + extIt.second->first + " ===\n";
for ( auto const & command : firstLevelCommands )
{
functionDeclarations += generateRAIIHandleCommand( command, handle.first.empty() ? 0 : 1, false );
}
for ( auto const & command : secondLevelCommands )
{
assert( !handle.first.empty() );
functionDeclarations += generateRAIIHandleCommand( command, 2, false );
}
functionDeclarations += leave;
}
}
return functionDeclarations;
}
std::string
VulkanHppGenerator::generateRAIIHandleCommandFactory( std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
size_t returnParamIndex,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, {}, { returnParamIndex }, false );
std::string argumentList =
generateRAIIHandleCommandFactoryArgumentList( commandIt->second.params, skippedParameters, definition, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string handleType =
stripPostfix( commandIt->second.params[returnParamIndex].type.compose( "VULKAN_HPP_RAII_NAMESPACE" ), " *" );
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE ${handleType} ${className}::${commandName}( ${argumentList} ) const
{
return ${handleType}( ${callArguments} );
}
)";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments",
generateCallArgumentsRAIIFactory( commandIt->second.params, initialSkipCount, skippedParameters, {} ) },
{ "className",
initialSkipCount ? stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" )
: "Context" },
{ "commandName", commandName },
{ "handleType", handleType } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD ${handleType} ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap(
declarationTemplate,
{ { "argumentList", argumentList }, { "commandName", commandName }, { "handleType", handleType } } );
}
}
std::string
VulkanHppGenerator::generateRAIIHandleCommandFactoryArgumentList( std::vector<ParamData> const & params,
std::set<size_t> const & skippedParameters,
bool definition,
bool singular ) const
{
std::string arguments;
bool encounteredArgument = false;
for ( size_t i = 0; i < params.size(); ++i )
{
if ( skippedParameters.find( i ) == skippedParameters.end() )
{
if ( encounteredArgument )
{
arguments += ", ";
}
arguments += generateRAIIHandleConstructorArgument( params[i], definition, singular, false );
encounteredArgument = true;
}
}
return arguments;
}
std::string VulkanHppGenerator::generateRAIIHandleCommandFactorySingular(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::vector<size_t> const & returnParamIndices,
std::map<size_t, size_t> const & vectorParamIndices,
bool definition ) const
{
assert( isHandleType( commandIt->second.params[returnParamIndices.back()].type.type ) );
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, returnParamIndices, true );
std::set<size_t> singularParams = determineSingularParams( returnParamIndices.back(), vectorParamIndices );
std::string argumentList =
generateRAIIHandleCommandFactoryArgumentList( commandIt->second.params, skippedParameters, definition, true );
std::string commandName =
stripPluralS( generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags ) );
std::string handleType = stripPostfix(
commandIt->second.params[returnParamIndices.back()].type.compose( "VULKAN_HPP_RAII_NAMESPACE" ), " *" );
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE ${handleType} ${className}::${commandName}( ${argumentList} ) const
{
return ${handleType}( ${callArguments} );
}
)";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments",
generateCallArgumentsRAIIFactory(
commandIt->second.params, initialSkipCount, skippedParameters, singularParams ) },
{ "className",
initialSkipCount ? stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" )
: "Context" },
{ "commandName", commandName },
{ "handleType", handleType } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD ${handleType} ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap(
declarationTemplate,
{ { "argumentList", argumentList }, { "commandName", commandName }, { "handleType", handleType } } );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandFactoryVector(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::vector<size_t> const & returnParamIndices,
std::map<size_t, size_t> const & vectorParamIndices,
bool definition ) const
{
assert( isHandleType( commandIt->second.params[returnParamIndices.back()].type.type ) );
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
std::string argumentList =
generateRAIIHandleCommandFactoryArgumentList( commandIt->second.params, skippedParameters, definition, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string handleType = stripPostfix(
commandIt->second.params[returnParamIndices.back()].type.compose( "VULKAN_HPP_RAII_NAMESPACE" ), " *" );
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::vector<${handleType}> ${className}::${commandName}( ${argumentList} ) const
{
return ${handleType}s( ${callArguments} );
}
)";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments",
generateCallArgumentsRAIIFactory( commandIt->second.params, initialSkipCount, skippedParameters, {} ) },
{ "className",
initialSkipCount ? stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" )
: "Context" },
{ "commandName", commandName },
{ "handleType", handleType } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::vector<${handleType}> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap(
declarationTemplate,
{ { "argumentList", argumentList }, { "commandName", commandName }, { "handleType", handleType } } );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResult(
std::map<std::string, CommandData>::const_iterator commandIt, size_t initialSkipCount, bool definition ) const
{
assert( !commandIt->second.successCodes.empty() );
if ( commandIt->second.successCodes.size() == 1 )
{
if ( commandIt->second.errorCodes.empty() )
{
return generateRAIIHandleCommandResultSingleSuccessNoErrors( commandIt, initialSkipCount, definition );
}
else
{
return generateRAIIHandleCommandResultSingleSuccessWithErrors( commandIt, initialSkipCount, definition );
}
}
else
{
if ( commandIt->second.errorCodes.empty() )
{
return generateRAIIHandleCommandResultMultiSuccessNoErrors( commandIt, initialSkipCount, definition );
}
else
{
return generateRAIIHandleCommandResultMultiSuccessWithErrors( commandIt, initialSkipCount, definition );
}
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessNoErrors(
std::map<std::string, CommandData>::const_iterator commandIt, size_t initialSkipCount, bool definition ) const
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( commandIt->second.params );
if ( returnParamIndices.empty() )
{
return generateRAIIHandleCommandResultMultiSuccessNoErrors0Return(
commandIt, initialSkipCount, determineVectorParamIndices( commandIt->second.params ), definition );
}
return "";
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessNoErrors0Return(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, {}, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE VULKAN_HPP_NAMESPACE::Result ${className}::${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT
{${functionPointerCheck}${vectorSizeCheck}
return static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::pair<bool, std::map<size_t, std::vector<size_t>>> vectorSizeCheck = needsVectorSizeCheck( vectorParamIndices );
std::string vectorSizeCheckString =
vectorSizeCheck.first
? generateRAIIHandleVectorSizeCheck(
commandIt->first, commandIt->second, initialSkipCount, vectorSizeCheck.second, skippedParameters )
: "";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "vectorSizeCheck", vectorSizeCheckString },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_NAMESPACE::Result ${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessWithErrors(
std::map<std::string, CommandData>::const_iterator commandIt, size_t initialSkipCount, bool definition ) const
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( commandIt->second.params );
switch ( returnParamIndices.size() )
{
case 0:
return generateRAIIHandleCommandResultMultiSuccessWithErrors0Return(
commandIt, initialSkipCount, determineVectorParamIndices( commandIt->second.params ), definition );
break;
case 1:
return generateRAIIHandleCommandResultMultiSuccessWithErrors1Return(
commandIt, initialSkipCount, definition, returnParamIndices[0] );
break;
case 2:
return generateRAIIHandleCommandResultMultiSuccessWithErrors2Return(
commandIt, initialSkipCount, definition, returnParamIndices );
break;
case 3:
return generateRAIIHandleCommandResultMultiSuccessWithErrors3Return(
commandIt, initialSkipCount, definition, returnParamIndices );
break;
}
return "";
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessWithErrors0Return(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, {}, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE VULKAN_HPP_NAMESPACE::Result ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}${vectorSizeCheck}
VULKAN_HPP_NAMESPACE::Result result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return result;
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::pair<bool, std::map<size_t, std::vector<size_t>>> vectorSizeCheck = needsVectorSizeCheck( vectorParamIndices );
std::string vectorSizeCheckString =
vectorSizeCheck.first
? generateRAIIHandleVectorSizeCheck(
commandIt->first, commandIt->second, initialSkipCount, vectorSizeCheck.second, skippedParameters )
: "";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "vectorSizeCheck", vectorSizeCheckString },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_NAMESPACE::Result ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessWithErrors1Return(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
std::string str;
if ( commandIt->second.params[returnParamIndex].type.type == "void" )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
if ( vectorParamIndices.size() == 1 )
{
if ( returnParamIndex == vectorParamIndices.begin()->first )
{
if ( commandIt->second.params[vectorParamIndices.begin()->second].type.type == "size_t" )
{
str = generateRAIIHandleCommandResultMultiSuccessWithErrors1ReturnVoidVector(
commandIt, initialSkipCount, vectorParamIndices, { returnParamIndex }, definition );
str += generateRAIIHandleCommandResultMultiSuccessWithErrors1ReturnVoidSingular(
commandIt, initialSkipCount, vectorParamIndices, { returnParamIndex }, definition );
}
}
}
}
else if ( isHandleType( commandIt->second.params[returnParamIndex].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
if ( vectorParamIndices.size() == 2 )
{
if ( returnParamIndex == std::next( vectorParamIndices.begin() )->first )
{
if ( commandIt->second.params[vectorParamIndices.begin()->second].type.type == "uint32_t" )
{
if ( isStructureChainAnchor( commandIt->second.params[vectorParamIndices.begin()->first].type.type ) )
{
str = generateRAIIHandleCommandFactoryVector(
commandIt, initialSkipCount, { returnParamIndex }, vectorParamIndices, definition );
str += generateRAIIHandleCommandFactorySingular(
commandIt, initialSkipCount, { returnParamIndex }, vectorParamIndices, definition );
}
}
}
}
}
else if ( !isStructureChainAnchor( commandIt->second.params[returnParamIndex].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
if ( vectorParamIndices.empty() )
{
str = generateRAIIHandleCommandResultMultiSuccessWithErrors1ReturnValue(
commandIt, initialSkipCount, vectorParamIndices, { returnParamIndex }, definition );
}
}
return str;
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessWithErrors1ReturnValue(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & returnParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string returnType =
stripPostfix( commandIt->second.params[returnParamIndices[0]].type.compose( "VULKAN_HPP_NAMESPACE" ), "*" );
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::pair<VULKAN_HPP_NAMESPACE::Result, ${returnType}> ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
${returnType} ${valueName};
VULKAN_HPP_NAMESPACE::Result result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return std::make_pair( result, ${valueName} );
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::string valueName = startLowerCase( stripPrefix( commandIt->second.params[returnParamIndices[0]].name, "p" ) );
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "valueName", valueName },
{ "returnType", returnType },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::pair<VULKAN_HPP_NAMESPACE::Result, ${returnType}> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
{ "returnType", returnType },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessWithErrors1ReturnVoidSingular(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & returnParamIndices,
bool definition ) const
{
assert( returnParamIndices.size() == 1 );
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, returnParamIndices, true );
std::set<size_t> singularParams = determineSingularParams( returnParamIndices[0], vectorParamIndices );
std::string argumentList = generateArgumentListEnhanced(
commandIt->second.params, skippedParameters, singularParams, definition, false, false, false );
std::string commandName =
stripPluralS( generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags ) );
if ( definition )
{
std::string const singularDefinitionTemplate =
R"(
template <typename T>
VULKAN_HPP_NODISCARD std::pair<VULKAN_HPP_NAMESPACE::Result, T> ${className}::${commandName}( ${argumentList} ) const
{
T ${dataName};
Result result = static_cast<Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return std::make_pair( result, ${dataName} );
}
)";
std::string callArguments =
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, singularParams, true );
std::string dataName = startLowerCase( stripPrefix( commandIt->second.params[returnParamIndices[0]].name, "p" ) );
return replaceWithMap(
singularDefinitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "dataName", dataName },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const singularDeclarationTemplate =
R"(
template <typename T>
VULKAN_HPP_NODISCARD std::pair<VULKAN_HPP_NAMESPACE::Result, T> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( singularDeclarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessWithErrors1ReturnVoidVector(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & returnParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
if ( definition )
{
std::string const definitionTemplate =
R"(
template <typename T>
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::pair<VULKAN_HPP_NAMESPACE::Result, std::vector<T>> ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
VULKAN_HPP_ASSERT( ${dataSize} % sizeof( T ) == 0 );
std::vector<T> ${dataName}( ${dataSize} / sizeof( T ) );
Result result = static_cast<Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return std::make_pair( result, ${dataName} );
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::string dataName = startLowerCase( stripPrefix( commandIt->second.params[returnParamIndices[0]].name, "p" ) );
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "dataName", dataName },
{ "dataSize", commandIt->second.params[returnParamIndices[0]].len },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
template <typename T>
VULKAN_HPP_NODISCARD std::pair<VULKAN_HPP_NAMESPACE::Result, std::vector<T>> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessWithErrors2Return(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
bool definition,
std::vector<size_t> const & returnParamIndices ) const
{
if ( ( commandIt->second.params[returnParamIndices[0]].type.type == "uint32_t" ) ||
( commandIt->second.params[returnParamIndices[0]].type.type == "size_t" ) )
{
// needs some very special handling of "vkGetSwapchainImagesKHR" !!
if ( isHandleType( commandIt->second.params[returnParamIndices[1]].type.type ) &&
( commandIt->first != "vkGetSwapchainImagesKHR" ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
if ( vectorParamIndices.size() == 1 )
{
if ( returnParamIndices[0] == vectorParamIndices.begin()->second )
{
if ( returnParamIndices[1] == vectorParamIndices.begin()->first )
{
if ( ( commandIt->second.successCodes.size() == 2 ) &&
( commandIt->second.successCodes[0] == "VK_SUCCESS" ) &&
( commandIt->second.successCodes[1] == "VK_INCOMPLETE" ) )
{
return generateRAIIHandleCommandFactoryVector(
commandIt, initialSkipCount, returnParamIndices, vectorParamIndices, definition );
}
}
}
}
}
else
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
if ( vectorParamIndices.size() == 1 )
{
if ( returnParamIndices[0] == vectorParamIndices.begin()->second )
{
if ( returnParamIndices[1] == vectorParamIndices.begin()->first )
{
if ( ( commandIt->second.successCodes.size() == 2 ) &&
( commandIt->second.successCodes[0] == "VK_SUCCESS" ) &&
( commandIt->second.successCodes[1] == "VK_INCOMPLETE" ) )
{
std::string str = generateRAIIHandleCommandResultMultiSuccessWithErrors2Return1VectorEnumerate(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndices, definition );
if ( isStructureChainAnchor( commandIt->second.params[returnParamIndices[1]].type.type ) )
{
str += generateRAIIHandleCommandResultMultiSuccessWithErrors2Return1VectorEnumerateChain(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndices, definition );
}
return str;
}
}
}
}
}
}
return "";
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessWithErrors2Return1VectorEnumerate(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & returnParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string vectorElementType = commandIt->second.params[vectorParamIndices.begin()->first].type.type;
if ( !isHandleType( vectorElementType ) )
{
assert( commandIt->second.params[vectorParamIndices.begin()->first].type.isNonConstPointer() );
vectorElementType =
( vectorElementType == "void" )
? "uint8_t"
: stripPostfix(
commandIt->second.params[vectorParamIndices.begin()->first].type.compose( "VULKAN_HPP_NAMESPACE" ), "*" );
}
if ( definition )
{
const std::string definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::vector<${vectorElementType}> ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
std::vector<${vectorElementType}> ${vectorName};
${counterType} ${counterName};
VULKAN_HPP_NAMESPACE::Result result;
do
{
result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${firstCallArguments} ) );
if ( ( result == VULKAN_HPP_NAMESPACE::Result::eSuccess ) && ${counterName} )
{
${vectorName}.resize( ${counterName} );
result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${secondCallArguments} ) );
}
} while ( result == VULKAN_HPP_NAMESPACE::Result::eIncomplete );
if ( result != VULKAN_HPP_NAMESPACE::Result::eSuccess )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
if ( result == VULKAN_HPP_NAMESPACE::Result::eSuccess )
{
VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() );
if ( ${counterName} < ${vectorName}.size() )
{
${vectorName}.resize( ${counterName} );
}
}
return ${vectorName};
}
)";
std::string counterName =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->second].name, "p" ) );
std::string firstCallArguments =
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, true, {}, true );
std::string secondCallArguments =
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::string vectorName =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->first].name, "p" ) );
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "className",
initialSkipCount ? stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" )
: "Context" },
{ "commandName", commandName },
{ "counterName", counterName },
{ "counterType", commandIt->second.params[vectorParamIndices.begin()->second].type.type },
{ "firstCallArguments", firstCallArguments },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "secondCallArguments", secondCallArguments },
{ "vectorElementType", vectorElementType },
{ "vectorName", vectorName },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::vector<${vectorElementType}> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
{ "vectorElementType", vectorElementType },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessWithErrors2Return1VectorEnumerateChain(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & returnParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, true, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string vectorElementType = commandIt->second.params[vectorParamIndices.begin()->first].type.type;
if ( !isHandleType( vectorElementType ) )
{
assert( commandIt->second.params[vectorParamIndices.begin()->first].type.isNonConstPointer() );
vectorElementType =
( vectorElementType == "void" )
? "uint8_t"
: stripPostfix(
commandIt->second.params[vectorParamIndices.begin()->first].type.compose( "VULKAN_HPP_NAMESPACE" ), "*" );
}
if ( definition )
{
const std::string definitionTemplate =
R"(
template <typename X, typename Y, typename... Z>
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::vector<StructureChain<X, Y, Z...>> ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
std::vector<StructureChain<X, Y, Z...>> returnVector;
std::vector<${vectorElementType}> ${vectorName};
${counterType} ${counterName};
VULKAN_HPP_NAMESPACE::Result result;
do
{
result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${firstCallArguments} ) );
if ( ( result == VULKAN_HPP_NAMESPACE::Result::eSuccess ) && ${counterName} )
{
returnVector.resize( ${counterName} );
${vectorName}.resize( ${counterName} );
for ( ${counterType} i = 0; i < ${counterName}; i++ )
{
${vectorName}[i].pNext = returnVector[i].template get<${vectorElementType}>().pNext;
}
result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${secondCallArguments} ) );
}
} while ( result == VULKAN_HPP_NAMESPACE::Result::eIncomplete );
if ( result != VULKAN_HPP_NAMESPACE::Result::eSuccess )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() );
if ( ${counterName} < ${vectorName}.size() )
{
returnVector.resize( ${counterName} );
}
for ( ${counterType} i = 0; i < ${counterName}; i++ )
{
returnVector[i].template get<${vectorElementType}>() = ${vectorName}[i];
}
return ${vectorName};
}
)";
std::string counterName =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->second].name, "p" ) );
std::string firstCallArguments =
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, true, {}, true );
std::string secondCallArguments =
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::string vectorName =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->first].name, "p" ) );
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "className",
initialSkipCount ? stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" )
: "Context" },
{ "commandName", commandName },
{ "counterName", counterName },
{ "counterType", commandIt->second.params[vectorParamIndices.begin()->second].type.type },
{ "firstCallArguments", firstCallArguments },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "secondCallArguments", secondCallArguments },
{ "vectorElementType", vectorElementType },
{ "vectorName", vectorName },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
template <typename X, typename Y, typename... Z>
VULKAN_HPP_NODISCARD std::vector<StructureChain<X, Y, Z...>> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate, { { "argumentList", argumentList }, { "commandName", commandName } } );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessWithErrors3Return(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
bool definition,
std::vector<size_t> const & returnParamIndices ) const
{
if ( commandIt->second.params[returnParamIndices[0]].type.type == "uint32_t" )
{
if ( ( commandIt->second.params[returnParamIndices[1]].type.type != "void" ) &&
!isHandleType( commandIt->second.params[returnParamIndices[1]].type.type ) &&
!isStructureChainAnchor( commandIt->second.params[returnParamIndices[1]].type.type ) )
{
if ( ( commandIt->second.params[returnParamIndices[2]].type.type != "void" ) &&
!isHandleType( commandIt->second.params[returnParamIndices[2]].type.type ) &&
!isStructureChainAnchor( commandIt->second.params[returnParamIndices[2]].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
if ( vectorParamIndices.size() == 2 )
{
if ( returnParamIndices[0] == vectorParamIndices.begin()->second )
{
if ( returnParamIndices[1] == vectorParamIndices.begin()->first )
{
if ( returnParamIndices[2] == std::next( vectorParamIndices.begin() )->first )
{
if ( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second )
{
if ( ( commandIt->second.successCodes.size() == 2 ) &&
( commandIt->second.successCodes[0] == "VK_SUCCESS" ) &&
( commandIt->second.successCodes[1] == "VK_INCOMPLETE" ) )
{
return generateRAIIHandleCommandResultMultiSuccessWithErrors3Return2VectorEnumerate(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndices, definition );
}
}
}
}
}
}
}
}
}
return "";
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessWithErrors3Return2VectorEnumerate(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & returnParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
auto firstVectorParamIt = vectorParamIndices.begin();
auto secondVectorParamIt = std::next( firstVectorParamIt );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string counterName =
startLowerCase( stripPrefix( stripPluralS( commandIt->second.params[firstVectorParamIt->second].name ), "p" ) );
std::string firstType = stripPrefix( commandIt->second.params[firstVectorParamIt->first].type.type, "Vk" );
std::string secondType = stripPrefix( commandIt->second.params[secondVectorParamIt->first].type.type, "Vk" );
if ( definition )
{
const std::string definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::pair<std::vector<${firstType}>, std::vector<${secondType}>> ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
std::pair<std::vector<${firstType}>, std::vector<${secondType}>> data;
std::vector<${firstType}> & ${firstVectorName} = data.first;
std::vector<${secondType}> & ${secondVectorName} = data.second;
${counterType} ${counterName};
VULKAN_HPP_NAMESPACE::Result result;
do
{
result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${firstCallArguments} ) );
if ( ( result == VULKAN_HPP_NAMESPACE::Result::eSuccess ) && counterCount )
{
${firstVectorName}.resize( ${counterName} );
${secondVectorName}.resize( ${counterName} );
result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${secondCallArguments} ) );
VULKAN_HPP_ASSERT( ${counterName} <= ${firstVectorName}.size() );
}
} while ( result == VULKAN_HPP_NAMESPACE::Result::eIncomplete );
if ( ( result == VULKAN_HPP_NAMESPACE::Result::eSuccess ) && ( ${counterName} < ${firstVectorName}.size() ) )
{
${firstVectorName}.resize( ${counterName} );
${secondVectorName}.resize( ${counterName} );
}
if ( result != VULKAN_HPP_NAMESPACE::Result::eSuccess )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return data;
}
)";
std::string firstCallArguments =
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, true, {}, true );
std::string firstVectorName =
startLowerCase( stripPrefix( commandIt->second.params[firstVectorParamIt->first].name, "p" ) );
std::string secondCallArguments =
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::string secondVectorName =
startLowerCase( stripPrefix( commandIt->second.params[secondVectorParamIt->first].name, "p" ) );
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "counterName", counterName },
{ "counterType", commandIt->second.params[firstVectorParamIt->second].type.type },
{ "firstCallArguments", firstCallArguments },
{ "firstType", firstType },
{ "firstVectorName", firstVectorName },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "secondCallArguments", secondCallArguments },
{ "secondType", secondType },
{ "secondVectorName", secondVectorName },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::pair<std::vector<${firstType}>, std::vector<${secondType}>> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "firstType", firstType },
{ "secondType", secondType } } );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessNoErrors(
std::map<std::string, CommandData>::const_iterator commandIt, size_t initialSkipCount, bool definition ) const
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( commandIt->second.params );
if ( returnParamIndices.empty() )
{
return generateRAIIHandleCommandResultSingleSuccessNoErrors0Return(
commandIt, initialSkipCount, determineVectorParamIndices( commandIt->second.params ), definition );
}
return "";
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessNoErrors0Return(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, {}, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_INLINE void ${className}::${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT
{${functionPointerCheck}${vectorSizeCheck}
getDispatcher()->${vkCommand}( ${callArguments} );
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::pair<bool, std::map<size_t, std::vector<size_t>>> vectorSizeCheck = needsVectorSizeCheck( vectorParamIndices );
std::string vectorSizeCheckString =
vectorSizeCheck.first
? generateRAIIHandleVectorSizeCheck(
commandIt->first, commandIt->second, initialSkipCount, vectorSizeCheck.second, skippedParameters )
: "";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "vectorSizeCheck", vectorSizeCheckString },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
void ${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessWithErrors(
std::map<std::string, CommandData>::const_iterator commandIt, size_t initialSkipCount, bool definition ) const
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( commandIt->second.params );
switch ( returnParamIndices.size() )
{
case 0:
return generateRAIIHandleCommandResultSingleSuccessWithErrors0Return(
commandIt, initialSkipCount, determineVectorParamIndices( commandIt->second.params ), definition );
break;
case 1:
return generateRAIIHandleCommandResultSingleSuccessWithErrors1Return(
commandIt, initialSkipCount, definition, returnParamIndices[0] );
break;
case 2:
return generateRAIIHandleCommandResultSingleSuccessWithErrors2Return(
commandIt, initialSkipCount, definition, returnParamIndices );
break;
}
return "";
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessWithErrors0Return(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, {}, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_INLINE void ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}${vectorSizeCheck}
VULKAN_HPP_NAMESPACE::Result result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::pair<bool, std::map<size_t, std::vector<size_t>>> vectorSizeCheck = needsVectorSizeCheck( vectorParamIndices );
std::string vectorSizeCheckString =
vectorSizeCheck.first
? generateRAIIHandleVectorSizeCheck(
commandIt->first, commandIt->second, initialSkipCount, vectorSizeCheck.second, skippedParameters )
: "";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "vectorSizeCheck", vectorSizeCheckString },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
void ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnChain(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & returnParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
if ( definition )
{
std::string const functionTemplate =
R"(
template <typename X, typename Y, typename... Z>
VULKAN_HPP_NODISCARD StructureChain<X, Y, Z...> ${className}::${commandName}( ${argumentList} ) const
{
StructureChain<X, Y, Z...> structureChain;
${returnType} & ${returnVariable} = structureChain.template get<${returnType}>();
VULKAN_HPP_NAMESPACE::Result result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return structureChain;
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::string returnType =
stripPostfix( commandIt->second.params[returnParamIndices[0]].type.compose( "VULKAN_HPP_NAMESPACE" ), "*" );
std::string returnVariable =
startLowerCase( stripPrefix( commandIt->second.params[returnParamIndices[0]].name, "p" ) );
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "returnVariable", returnVariable },
{ "returnType", returnType },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
template <typename X, typename Y, typename... Z>
VULKAN_HPP_NODISCARD StructureChain<X, Y, Z...> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessWithErrors1Return(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
std::string str;
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
if ( commandIt->second.params[returnParamIndex].type.type == "void" )
{
switch ( vectorParamIndices.size() )
{
case 0:
str = generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnValue(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndex, definition );
break;
case 1:
if ( returnParamIndex == vectorParamIndices.begin()->first )
{
if ( commandIt->second.params[vectorParamIndices.begin()->second].type.type == "size_t" )
{
str = generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnVoidVector(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndex, definition );
str += generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnVoidSingular(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndex, definition );
}
}
break;
case 2:
if ( returnParamIndex == std::next( vectorParamIndices.begin() )->first )
{
if ( commandIt->second.params[vectorParamIndices.begin()->second].type.type == "uint32_t" )
{
if ( isHandleType( commandIt->second.params[vectorParamIndices.begin()->first].type.type ) )
{
if ( commandIt->second.params[std::next( vectorParamIndices.begin() )->second].type.type == "size_t" )
{
str = generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnVoidVector(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndex, definition );
str += generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnVoidSingular(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndex, definition );
}
}
}
}
break;
}
}
else if ( isHandleType( commandIt->second.params[returnParamIndex].type.type ) )
{
switch ( vectorParamIndices.size() )
{
case 0:
str = generateRAIIHandleCommandFactory( commandIt, initialSkipCount, returnParamIndex, definition );
break;
case 1:
if ( returnParamIndex == vectorParamIndices.begin()->first )
{
if ( m_structures.find( commandIt->second.params[vectorParamIndices.begin()->second].type.type ) !=
m_structures.end() )
{
str = generateRAIIHandleCommandFactoryVector(
commandIt, initialSkipCount, { returnParamIndex }, vectorParamIndices, definition );
}
}
break;
case 2:
if ( returnParamIndex == std::next( vectorParamIndices.begin() )->first )
{
if ( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second )
{
if ( commandIt->second.params[vectorParamIndices.begin()->second].type.type == "uint32_t" )
{
if ( isStructureChainAnchor( commandIt->second.params[vectorParamIndices.begin()->first].type.type ) )
{
str = generateRAIIHandleCommandFactoryVector(
commandIt, initialSkipCount, { returnParamIndex }, vectorParamIndices, definition );
str += generateRAIIHandleCommandFactorySingular(
commandIt, initialSkipCount, { returnParamIndex }, vectorParamIndices, definition );
}
}
}
}
break;
}
}
else if ( isStructureChainAnchor( commandIt->second.params[returnParamIndex].type.type ) )
{
if ( vectorParamIndices.empty() )
{
str = generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnValue(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndex, definition );
str += generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnChain(
commandIt, initialSkipCount, vectorParamIndices, { returnParamIndex }, definition );
}
}
else
{
switch ( vectorParamIndices.size() )
{
case 0:
str = generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnValue(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndex, definition );
break;
case 2:
if ( returnParamIndex == std::next( vectorParamIndices.begin() )->first )
{
if ( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second )
{
if ( commandIt->second.params[vectorParamIndices.begin()->second].type.type == "uint32_t" )
{
if ( ( commandIt->second.params[vectorParamIndices.begin()->first].type.type != "void" ) &&
!isHandleType( commandIt->second.params[vectorParamIndices.begin()->first].type.type ) &&
!isStructureChainAnchor( commandIt->second.params[vectorParamIndices.begin()->first].type.type ) )
{
str = generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnValueVector(
commandIt, initialSkipCount, returnParamIndex, vectorParamIndices, definition );
str += generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnValueSingular(
commandIt, initialSkipCount, returnParamIndex, vectorParamIndices, definition );
}
}
}
}
break;
}
}
return str;
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnValue(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string returnType =
stripPostfix( commandIt->second.params[returnParamIndex].type.compose( "VULKAN_HPP_NAMESPACE" ), "*" );
std::string typenameT;
if ( returnType == "void" )
{
returnType = "T";
typenameT = "template <typename T> ";
}
if ( definition )
{
std::string const definitionTemplate =
R"(
${typenameT}VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE ${returnType} ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
${returnType} ${valueName};
VULKAN_HPP_NAMESPACE::Result result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return ${valueName};
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::string valueName = startLowerCase( stripPrefix( commandIt->second.params[returnParamIndex].name, "p" ) );
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className",
initialSkipCount ? stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" )
: "Context" },
{ "commandName", commandName },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "valueName", valueName },
{ "returnType", returnType },
{ "typenameT", typenameT },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
${typenameT}VULKAN_HPP_NODISCARD ${returnType} ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "returnType", returnType },
{ "typenameT", typenameT } } );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnValueSingular(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
size_t returnParamIndex,
std::map<size_t, size_t> const & vectorParamIndices,
bool definition ) const
{
assert( vectorParamIndices.size() == 2 );
assert( returnParamIndex == std::next( vectorParamIndices.begin() )->first );
assert( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second );
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, true );
std::set<size_t> singularParams = determineSingularParams( returnParamIndex, vectorParamIndices );
std::string argumentList = generateArgumentListEnhanced(
commandIt->second.params, skippedParameters, singularParams, definition, false, false, false );
std::string commandName =
stripPluralS( generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags ) );
std::string dataType =
stripPostfix( commandIt->second.params[returnParamIndex].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" );
if ( definition )
{
std::string const singularDefinitionTemplate =
R"(
VULKAN_HPP_NODISCARD ${dataType} ${className}::${commandName}( ${argumentList} ) const
{
${dataType} ${dataName};
Result result = static_cast<Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return ${dataName};
}
)";
return replaceWithMap(
singularDefinitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments",
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, singularParams, true ) },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "dataName",
stripPluralS( startLowerCase( stripPrefix( commandIt->second.params[returnParamIndex].name, "p" ) ) ) },
{ "dataType", dataType },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const singularDeclarationTemplate =
R"(
VULKAN_HPP_NODISCARD ${dataType} ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap(
singularDeclarationTemplate,
{ { "argumentList", argumentList }, { "commandName", commandName }, { "dataType", dataType } } );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnValueVector(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
size_t returnParamIndex,
std::map<size_t, size_t> const & vectorParamIndices,
bool definition ) const
{
assert( vectorParamIndices.size() == 2 );
assert( returnParamIndex == std::next( vectorParamIndices.begin() )->first );
assert( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second );
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string elementType =
stripPostfix( commandIt->second.params[returnParamIndex].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" );
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::vector<${elementType}> ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
std::vector<${elementType}> ${vectorName}( ${vectorSize} );
Result result = static_cast<Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return ${vectorName};
}
)";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true ) },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "elementType", elementType },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "vectorName", startLowerCase( stripPrefix( commandIt->second.params[returnParamIndex].name, "p" ) ) },
{ "vectorSize",
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->first].name, "p" ) ) +
".size()" },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::vector<${elementType}> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap(
declarationTemplate,
{ { "argumentList", argumentList }, { "commandName", commandName }, { "elementType", elementType } } );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnVoidSingular(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, true );
std::set<size_t> singularParams = determineSingularParams( returnParamIndex, vectorParamIndices );
std::string argumentList = generateArgumentListEnhanced(
commandIt->second.params, skippedParameters, singularParams, definition, false, false, false );
std::string commandName =
stripPluralS( generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags ) );
if ( definition )
{
std::string const singularDefinitionTemplate =
R"(
template <typename T>
VULKAN_HPP_NODISCARD T ${className}::${commandName}( ${argumentList} ) const
{
T ${dataName};
Result result = static_cast<Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return ${dataName};
}
)";
std::string callArguments =
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, singularParams, true );
std::string dataName = startLowerCase( stripPrefix( commandIt->second.params[returnParamIndex].name, "p" ) );
return replaceWithMap(
singularDefinitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "dataName", dataName },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const singularDeclarationTemplate =
R"(
template <typename T>
VULKAN_HPP_NODISCARD T ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( singularDeclarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnVoidVector(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
if ( definition )
{
std::string const definitionTemplate =
R"(
template <typename T>
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::vector<T> ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
VULKAN_HPP_ASSERT( ${dataSize} % sizeof( T ) == 0 );
std::vector<T> ${dataName}( ${dataSize} / sizeof( T ) );
Result result = static_cast<Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return ${dataName};
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::string dataName = startLowerCase( stripPrefix( commandIt->second.params[returnParamIndex].name, "p" ) );
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "dataName", dataName },
{ "dataSize", commandIt->second.params[returnParamIndex].len },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
template <typename T>
VULKAN_HPP_NODISCARD std::vector<T> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessWithErrors2Return(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
bool definition,
std::vector<size_t> const & returnParamIndices ) const
{
std::string str;
if ( commandIt->second.params[returnParamIndices[0]].type.type == "uint64_t" )
{
if ( commandIt->second.params[returnParamIndices[1]].type.type == "uint64_t" )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
if ( vectorParamIndices.size() == 2 )
{
if ( returnParamIndices[0] == std::next( vectorParamIndices.begin() )->first )
{
assert( returnParamIndices[1] != std::next( vectorParamIndices.begin() )->second );
if ( returnParamIndices[1] != vectorParamIndices.begin()->first )
{
assert( returnParamIndices[1] != vectorParamIndices.begin()->second );
if ( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second )
{
if ( commandIt->second.params[vectorParamIndices.begin()->second].type.type == "uint32_t" )
{
if ( ( commandIt->second.params[vectorParamIndices.begin()->first].type.type != "void" ) &&
!isHandleType( commandIt->second.params[vectorParamIndices.begin()->first].type.type ) &&
!isStructureChainAnchor( commandIt->second.params[vectorParamIndices.begin()->first].type.type ) )
{
// two returns and two vectors! But one input vector, one output vector of the same size,
// and one output value
str = generateRAIIHandleCommandResultSingleSuccessWithErrors2ReturnValueVectorValue(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndices, definition );
str += generateRAIIHandleCommandResultSingleSuccessWithErrors2ReturnValueSingularValue(
commandIt, initialSkipCount, definition, returnParamIndices, vectorParamIndices );
}
}
}
}
}
}
}
}
return str;
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessWithErrors2ReturnValueSingularValue(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
bool definition,
std::vector<size_t> const & returnParamIndices,
std::map<size_t, size_t> const & vectorParamIndices ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
assert( std::next( vectorParamIndices.begin() )->first == returnParamIndices[0] );
assert( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second );
std::set<size_t> singularParams = determineSingularParams( returnParamIndices[0], vectorParamIndices );
std::string argumentList = generateArgumentListEnhanced(
commandIt->second.params, skippedParameters, singularParams, definition, false, false, false );
std::string commandName =
stripPluralS( generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags ) );
std::string singularElementType = commandIt->second.params[returnParamIndices[0]].type.type;
std::string valueType = commandIt->second.params[returnParamIndices[1]].type.type;
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::pair<${singularElementType}, ${valueType}> ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
std::pair<${singularElementType}, ${valueType}> data;
${singularElementType} & ${singularName} = data.first;
${valueType} & ${valueName} = data.second;
VULKAN_HPP_NAMESPACE::Result result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return data;
}
)";
std::string callArguments =
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, singularParams, true );
std::string valueName = startLowerCase( stripPrefix( commandIt->second.params[returnParamIndices[1]].name, "p" ) );
std::string singularName =
startLowerCase( stripPluralS( stripPrefix( commandIt->second.params[returnParamIndices[0]].name, "p" ) ) );
std::string vectorSize =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->first].name, "p" ) ) +
".size()";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "singularElementType", singularElementType },
{ "valueName", valueName },
{ "singularName", singularName },
{ "valueType", valueType },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::pair<${singularElementType}, ${valueType}> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "singularElementType", singularElementType },
{ "valueType", valueType } } );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessWithErrors2ReturnValueVectorValue(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & returnParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string valueType = commandIt->second.params[returnParamIndices[1]].type.type;
std::string vectorElementType = commandIt->second.params[returnParamIndices[0]].type.type;
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::pair<std::vector<${vectorElementType}>, ${valueType}> ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
std::pair<std::vector<${vectorElementType}>, ${valueType}> data( std::piecewise_construct, std::forward_as_tuple( ${vectorSize} ), std::forward_as_tuple( 0 ) );
std::vector<${vectorElementType}> & ${vectorName} = data.first;
${valueType} & ${valueName} = data.second;
VULKAN_HPP_NAMESPACE::Result result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return data;
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::string valueName = startLowerCase( stripPrefix( commandIt->second.params[returnParamIndices[1]].name, "p" ) );
std::string vectorName = startLowerCase( stripPrefix( commandIt->second.params[returnParamIndices[0]].name, "p" ) );
std::string vectorSize =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->first].name, "p" ) ) +
".size()";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "valueName", valueName },
{ "valueType", valueType },
{ "vectorElementType", vectorElementType },
{ "vectorName", vectorName },
{ "vectorSize", vectorSize },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::pair<std::vector<${vectorElementType}>, ${valueType}> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
{ "valueType", valueType },
{ "vectorElementType", vectorElementType },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandValue(
std::map<std::string, CommandData>::const_iterator commandIt, size_t initialSkipCount, bool definition ) const
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( commandIt->second.params );
if ( returnParamIndices.empty() )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
if ( vectorParamIndices.empty() )
{
if ( beginsWith( commandIt->second.returnType, "Vk" ) )
{
return generateRAIIHandleCommandValue0Return0VectorVkType(
commandIt, initialSkipCount, vectorParamIndices, definition );
}
else
{
return generateRAIIHandleCommandValue0Return0VectorType(
commandIt, initialSkipCount, vectorParamIndices, definition );
}
}
}
return "";
}
std::string VulkanHppGenerator::generateRAIIHandleCommandValue0Return0VectorType(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, {}, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string returnType = generateNamespacedType( commandIt->second.returnType );
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE ${returnType} ${className}::${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT
{${functionPointerCheck}${vectorSizeCheck}
return getDispatcher()->${vkCommand}( ${callArguments} );
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::pair<bool, std::map<size_t, std::vector<size_t>>> vectorSizeCheck = needsVectorSizeCheck( vectorParamIndices );
std::string vectorSizeCheckString =
vectorSizeCheck.first
? generateVectorSizeCheck(
commandIt->first, commandIt->second, initialSkipCount, vectorSizeCheck.second, skippedParameters )
: "";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "returnType", returnType },
{ "vectorSizeCheck", vectorSizeCheckString },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD ${returnType} ${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
{ "returnType", returnType },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandValue0Return0VectorVkType(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, {}, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string returnType = generateNamespacedType( commandIt->second.returnType );
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE ${returnType} ${className}::${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT
{${functionPointerCheck}${vectorSizeCheck}
return static_cast<${returnType}>( getDispatcher()->${vkCommand}( ${callArguments} ) );
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::pair<bool, std::map<size_t, std::vector<size_t>>> vectorSizeCheck = needsVectorSizeCheck( vectorParamIndices );
std::string vectorSizeCheckString =
vectorSizeCheck.first
? generateRAIIHandleVectorSizeCheck(
commandIt->first, commandIt->second, initialSkipCount, vectorSizeCheck.second, skippedParameters )
: "";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "returnType", returnType },
{ "vectorSizeCheck", vectorSizeCheckString },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD ${returnType} ${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
{ "returnType", returnType },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandVoid(
std::map<std::string, CommandData>::const_iterator commandIt, size_t initialSkipCount, bool definition ) const
{
std::string str;
std::vector<size_t> returnParamIndices = determineReturnParamIndices( commandIt->second.params );
switch ( returnParamIndices.size() )
{
case 0: str = generateRAIIHandleCommandVoid0Return( commandIt, initialSkipCount, definition ); break;
case 1:
if ( isHandleType( commandIt->second.params[returnParamIndices[0]].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
if ( vectorParamIndices.empty() )
{
str = generateRAIIHandleCommandFactory( commandIt, initialSkipCount, returnParamIndices[0], definition );
}
}
else if ( commandIt->second.params[returnParamIndices[0]].type.type != "void" )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
auto returnVectorParamIt = vectorParamIndices.find( returnParamIndices[0] );
if ( returnVectorParamIt == vectorParamIndices.end() )
{
str = generateRAIIHandleCommandVoid1ReturnValue(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndices[0], definition );
if ( isStructureChainAnchor( commandIt->second.params[returnParamIndices[0]].type.type ) )
{
str += generateRAIIHandleCommandVoid1ReturnChain(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndices[0], definition );
}
}
}
break;
case 2:
if ( commandIt->second.params[returnParamIndices[0]].type.type == "uint32_t" )
{
if ( ( commandIt->second.params[returnParamIndices[1]].type.type != "void" ) &&
!isHandleType( commandIt->second.params[returnParamIndices[1]].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
if ( vectorParamIndices.size() == 1 )
{
if ( returnParamIndices[0] == vectorParamIndices.begin()->second )
{
if ( returnParamIndices[1] == vectorParamIndices.begin()->first )
{
str = generateRAIIHandleCommandVoid2ReturnEnumerateValue(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndices, definition );
if ( isStructureChainAnchor( commandIt->second.params[returnParamIndices[1]].type.type ) )
{
str += generateRAIIHandleCommandVoid2ReturnEnumerateChain(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndices, definition );
}
}
}
}
}
}
break;
}
return str;
}
std::string VulkanHppGenerator::generateRAIIHandleCommandVoid0Return(
std::map<std::string, CommandData>::const_iterator commandIt, size_t initialSkipCount, bool definition ) const
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, {}, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::pair<bool, std::map<size_t, std::vector<size_t>>> vectorSizeCheck = needsVectorSizeCheck( vectorParamIndices );
std::string noexceptString = vectorSizeCheck.first ? "VULKAN_HPP_NOEXCEPT_WHEN_NO_EXCEPTIONS" : "VULKAN_HPP_NOEXCEPT";
std::string templateString = ( ( vectorParamIndices.size() == 1 ) &&
( commandIt->second.params[vectorParamIndices.begin()->first].type.type == "void" ) )
? "template <typename T>\n"
: "";
if ( definition )
{
std::string const definitionTemplate =
R"(
${template}VULKAN_HPP_INLINE void ${className}::${commandName}( ${argumentList} ) const ${noexcept}
{${functionPointerCheck}${vectorSizeCheck}
getDispatcher()->${vkCommand}( ${callArguments} );
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::string vectorSizeCheckString =
vectorSizeCheck.first
? generateVectorSizeCheck(
commandIt->first, commandIt->second, initialSkipCount, vectorSizeCheck.second, skippedParameters )
: "";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "noexcept", noexceptString },
{ "template", templateString },
{ "vectorSizeCheck", vectorSizeCheckString },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
${template}void ${commandName}( ${argumentList} ) const ${noexcept};
)";
return replaceWithMap( declarationTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "noexcept", noexceptString },
{ "template", templateString } } );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandVoid1ReturnChain(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
if ( definition )
{
std::string const definitionTemplate =
R"(
template <typename X, typename Y, typename... Z>
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE StructureChain<X, Y, Z...> ${className}::${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT
{${functionPointerCheck}
StructureChain<X, Y, Z...> structureChain;
${returnType} & ${returnVariable} = structureChain.template get<${returnType}>();
getDispatcher()->${vkCommand}( ${callArguments} );
return structureChain;
}
)";
std::string callArguments = generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::string returnType =
stripPostfix( commandIt->second.params[returnParamIndex].type.compose( "VULKAN_HPP_NAMESPACE" ), "*" );
std::string returnVariable = startLowerCase( stripPrefix( commandIt->second.params[returnParamIndex].name, "p" ) );
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "returnVariable", returnVariable },
{ "returnType", returnType },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
template <typename X, typename Y, typename... Z>
VULKAN_HPP_NODISCARD StructureChain<X, Y, Z...> ${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandVoid1ReturnValue(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string returnType =
stripPostfix( commandIt->second.params[returnParamIndex].type.compose( "VULKAN_HPP_NAMESPACE" ), "*" );
std::pair<bool, std::map<size_t, std::vector<size_t>>> vectorSizeCheck = needsVectorSizeCheck( vectorParamIndices );
std::string noexceptString = vectorSizeCheck.first ? "VULKAN_HPP_NOEXCEPT_WHEN_NO_EXCEPTIONS" : "VULKAN_HPP_NOEXCEPT";
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE ${returnType} ${className}::${commandName}( ${argumentList} ) const ${noexcept}
{${functionPointerCheck}${vectorSizeCheck}
${returnType} ${returnVariable};
getDispatcher()->${vkCommand}( ${callArguments} );
return ${returnVariable};
}
)";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true ) },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "noexcept", noexceptString },
{ "vectorSizeCheck",
vectorSizeCheck.first
? generateVectorSizeCheck(
commandIt->first, commandIt->second, initialSkipCount, vectorSizeCheck.second, skippedParameters )
: "" },
{ "returnType", returnType },
{ "returnVariable", startLowerCase( stripPrefix( commandIt->second.params[returnParamIndex].name, "p" ) ) },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD ${returnType} ${commandName}( ${argumentList} ) const ${noexcept};
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
{ "noexcept", noexceptString },
{ "returnType", returnType },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandVoid2ReturnEnumerateChain(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & returnParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string counterName =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->second].name, "p" ) );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
if ( definition )
{
const std::string definitionTemplate =
R"(
template <typename StructureChain>
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::vector<StructureChain> ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
${counterType} ${counterName};
getDispatcher()->${vkCommand}( ${firstCallArguments} );
std::vector<StructureChain> returnVector( ${counterName} );
std::vector<${vectorElementType}> ${vectorName}( ${counterName} );
for ( ${counterType} i = 0; i < ${counterName}; i++ )
{
${vectorName}[i].pNext = returnVector[i].template get<${vectorElementType}>().pNext;
}
getDispatcher()->${vkCommand}( ${secondCallArguments} );
VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() );
for ( ${counterType} i = 0; i < ${counterName}; i++ )
{
returnVector[i].template get<${vectorElementType}>() = ${vectorName}[i];
}
return returnVector;
}
)";
std::string firstCallArguments =
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, true, {}, true );
std::string secondCallArguments =
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::string vectorElementType = stripPostfix(
commandIt->second.params[vectorParamIndices.begin()->first].type.compose( "VULKAN_HPP_NAMESPACE" ), "*" );
std::string vectorName =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->first].name, "p" ) );
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "counterName", counterName },
{ "counterType", commandIt->second.params[vectorParamIndices.begin()->second].type.type },
{ "firstCallArguments", firstCallArguments },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "secondCallArguments", secondCallArguments },
{ "vectorElementType", vectorElementType },
{ "vectorName", vectorName },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
template <typename StructureChain>
VULKAN_HPP_NODISCARD std::vector<StructureChain> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandVoid2ReturnEnumerateValue(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & returnParamIndices,
bool definition ) const
{
assert( returnParamIndices.size() == 2 );
assert( vectorParamIndices.size() == 1 );
std::set<size_t> skippedParameters =
determineSkippedParams( commandIt->second.params, initialSkipCount, vectorParamIndices, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string vectorElementType = stripPostfix(
commandIt->second.params[vectorParamIndices.begin()->first].type.compose( "VULKAN_HPP_NAMESPACE" ), "*" );
if ( definition )
{
const std::string definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::vector<${vectorElementType}> ${className}::${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT
{${functionPointerCheck}
${counterType} ${counterName};
getDispatcher()->${vkCommand}( ${firstCallArguments} );
std::vector<${vectorElementType}> ${vectorName}( ${counterName} );
getDispatcher()->${vkCommand}( ${secondCallArguments} );
VULKAN_HPP_ASSERT( ${counterName} == ${vectorName}.size() );
return ${vectorName};
}
)";
std::string counterName =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->second].name, "p" ) );
std::string firstCallArguments =
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, true, {}, true );
std::string secondCallArguments =
generateCallArgumentsEnhanced( commandIt->second, initialSkipCount, false, {}, true );
std::string vectorName =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->first].name, "p" ) );
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "counterName", counterName },
{ "counterType", commandIt->second.params[vectorParamIndices.begin()->second].type.type },
{ "firstCallArguments", firstCallArguments },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "secondCallArguments", secondCallArguments },
{ "vectorElementType", vectorElementType },
{ "vectorName", vectorName },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::vector<${vectorElementType}> ${commandName}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT;
)";
return replaceWithMap( declarationTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "vectorElementType", vectorElementType } } );
}
}
std::pair<std::string, std::string> VulkanHppGenerator::generateRAIIHandleConstructor(
std::pair<std::string, HandleData> const & handle,
std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator constructorIt,
std::string const & enter,
std::string const & leave ) const
{
std::string singularConstructor, arrayConstructor;
if ( constructorIt->second.returnType == "VkResult" )
{
std::tie( singularConstructor, arrayConstructor ) =
generateRAIIHandleConstructorResult( handle, constructorIt, enter, leave );
}
else if ( constructorIt->second.returnType == "void" )
{
std::tie( singularConstructor, arrayConstructor ) =
generateRAIIHandleConstructorVoid( handle, constructorIt, enter, leave );
}
if ( singularConstructor.empty() && arrayConstructor.empty() )
{
throw std::runtime_error( "Never encountered a function like <" + constructorIt->first + "> !" );
}
return std::make_pair( singularConstructor, arrayConstructor );
}
std::pair<std::string, std::string> VulkanHppGenerator::generateRAIIHandleConstructor1Return2Vector(
std::pair<std::string, HandleData> const & handle,
std::map<std::string, CommandData>::const_iterator constructorIt,
std::string const & enter,
std::string const & leave,
size_t returnParamIndex,
std::map<size_t, size_t> const & vectorParamIndices ) const
{
if ( returnParamIndex == std::next( vectorParamIndices.begin() )->first )
{
if ( vectorParamIndices.begin()->second == std::next( vectorParamIndices.begin() )->second )
{
if ( constructorIt->second.params[vectorParamIndices.begin()->second].type.type == "uint32_t" )
{
if ( isStructureChainAnchor( constructorIt->second.params[vectorParamIndices.begin()->first].type.type ) )
{
std::string singularConstructor;
auto lenParamIt = constructorIt->second.params.begin() + vectorParamIndices.begin()->second;
auto handleParamIt = constructorIt->second.params.begin() + std::next( vectorParamIndices.begin() )->first;
if ( !checkEquivalentSingularConstructor( handle.second.constructorIts, constructorIt, lenParamIt ) )
{
singularConstructor =
generateRAIIHandleConstructorVectorSingular( handle, constructorIt, handleParamIt, enter, leave );
}
return std::make_pair(
singularConstructor,
generateRAIIHandleConstructorVector( handle, constructorIt, handleParamIt, enter, leave ) );
}
}
}
}
return std::make_pair( "", "" );
}
std::pair<std::string, std::string>
VulkanHppGenerator::generateRAIIHandleConstructors( std::pair<std::string, HandleData> const & handle ) const
{
auto [enter, leave] = generateProtection( handle.first, !handle.second.alias.empty() );
std::string singularConstructors, arrayConstructors;
for ( auto constructorIt : handle.second.constructorIts )
{
// there is a non-const parameter with handle type : the to-be-constructed handle
// check for additional enter/leave guards for the constructors
auto [constructorEnter, constructorLeave] = generateProtection( constructorIt->second.referencedIn, std::string() );
if ( constructorEnter == enter )
{
constructorEnter.clear();
constructorLeave.clear();
}
auto [singularConstructor, arrayConstructor] =
generateRAIIHandleConstructor( handle, constructorIt, constructorEnter, constructorLeave );
arrayConstructors += arrayConstructor;
singularConstructors += singularConstructor;
}
singularConstructors += generateRAIIHandleConstructorTakeOwnership( handle );
return std::make_pair( singularConstructors, arrayConstructors );
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorArgument( ParamData const & param,
bool definition,
bool singular,
bool takesOwnership ) const
{
std::string argument;
if ( param.type.isConstPointer() )
{
assert( beginsWith( param.type.type, "Vk" ) );
assert( beginsWith( param.name, "p" ) );
std::string argumentName = startLowerCase( stripPrefix( param.name, "p" ) );
std::string argumentType = "VULKAN_HPP_NAMESPACE::" + stripPrefix( param.type.type, "Vk" );
if ( param.optional )
{
assert( param.len.empty() );
argument = "VULKAN_HPP_NAMESPACE::Optional<const " + argumentType + "> " + argumentName +
( definition ? "" : " = nullptr" );
}
else if ( param.len.empty() )
{
argument = argumentType + " const & " + argumentName;
}
else if ( singular )
{
argument = argumentType + " const & " + stripPluralS( argumentName );
}
else
{
argument = "VULKAN_HPP_NAMESPACE::ArrayProxy<" + argumentType + "> const & " + argumentName;
}
}
else if ( specialPointerTypes.find( param.type.type ) != specialPointerTypes.end() )
{
assert( !param.optional );
assert( param.type.isNonConstPointer() );
argument = param.type.type + " & " + param.name;
}
else if ( ( param.type.isValue() ) && isHandleType( param.type.type ) )
{
if ( takesOwnership )
{
assert( !param.optional );
argument = param.type.type + " " + param.name;
}
else
{
argument = "VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::" + stripPrefix( param.type.type, "Vk" );
if ( param.optional )
{
argument = "VULKAN_HPP_NAMESPACE::Optional<const " + argument + ">";
}
argument += " const & " + param.name;
}
}
else
{
assert( !param.optional );
argument = param.type.compose( "VULKAN_HPP_NAMESPACE" ) + " " + param.name;
}
return argument;
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorArguments(
std::pair<std::string, HandleData> const & handle,
std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator constructorIt,
bool singular,
bool takesOwnership ) const
{
auto [parentType, parentName] = getParentTypeAndName( handle );
std::string arguments = "VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::" + parentType + " const & " + parentName;
if ( takesOwnership )
{
arguments +=
", " + handle.first + " " + generateRAIIHandleConstructorParamName( handle.first, handle.second.destructorIt );
}
if ( constructorIt != m_commands.end() )
{
parentType = "Vk" + parentType;
bool skip = skipLeadingGrandParent( handle );
for ( size_t i = skip ? 1 : 0; i < constructorIt->second.params.size(); i++ )
{
ParamData const & param = constructorIt->second.params[i];
// filter parent and handle type
if ( ( param.type.type != parentType ) && ( param.type.type != handle.first ) )
{
// the specialPointerTypes are considered const-pointers!
if ( param.type.isNonConstPointer() &&
( specialPointerTypes.find( param.type.type ) == specialPointerTypes.end() ) )
{
// this is supposed to be the returned size on an enumeration function!
#if !defined( NDEBUG )
assert( param.type.type == "uint32_t" );
auto typeIt = std::find_if( constructorIt->second.params.begin(),
constructorIt->second.params.end(),
[&handle]( ParamData const & pd ) { return pd.type.type == handle.first; } );
assert( typeIt != constructorIt->second.params.end() );
assert( typeIt->len == param.name );
#endif
continue;
}
else if ( std::find_if( constructorIt->second.params.begin(),
constructorIt->second.params.end(),
[&param]( ParamData const & pd )
{ return pd.len == param.name; } ) != constructorIt->second.params.end() )
{
// this is the len of an other parameter, which will be mapped to an ArrayProxy
assert( param.type.isValue() && ( param.type.type == "uint32_t" ) );
assert( param.arraySizes.empty() && param.len.empty() && !param.optional );
continue;
}
arguments += ", " + generateRAIIHandleConstructorArgument( param, false, singular, takesOwnership );
}
}
}
return arguments;
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorCallArguments(
std::pair<std::string, HandleData> const & handle,
std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator constructorIt,
bool nonConstPointerAsNullptr,
std::set<size_t> const & singularParams,
bool allocatorIsMemberVariable ) const
{
std::string arguments;
bool encounteredArgument = false;
size_t i = 0;
if ( skipLeadingGrandParent( handle ) )
{
assert( ( 1 < constructorIt->second.params.size() ) &&
( m_handles.find( constructorIt->second.params[0].type.type ) != m_handles.end() ) &&
( m_handles.find( constructorIt->second.params[1].type.type ) != m_handles.end() ) );
arguments += "static_cast<" + constructorIt->second.params[0].type.type + ">( " +
constructorIt->second.params[1].name + ".get" +
stripPrefix( constructorIt->second.params[0].type.type, "Vk" ) + "() )";
encounteredArgument = true;
i = 1;
}
for ( ; i < constructorIt->second.params.size(); ++i )
{
ParamData const & param = constructorIt->second.params[i];
if ( encounteredArgument )
{
arguments += ", ";
}
if ( param.type.type == handle.first )
{
assert( param.type.isNonConstPointer() && param.arraySizes.empty() );
if ( param.len.empty() || !singularParams.empty() )
{
assert( !param.optional );
assert( singularParams.empty() || ( param.len == constructorIt->second.params[*singularParams.begin()].name ) );
std::string paramName = generateRAIIHandleConstructorParamName( handle.first, handle.second.destructorIt );
arguments += "reinterpret_cast<" + handle.first + "*>( &m_" + paramName + " )";
}
else if ( nonConstPointerAsNullptr )
{
arguments += "nullptr";
}
else
{
arguments += startLowerCase( stripPrefix( param.name, "p" ) ) + ".data()";
}
}
else if ( param.type.type == "VkAllocationCallbacks" )
{
assert( param.optional );
if ( allocatorIsMemberVariable )
{
arguments += "reinterpret_cast<const VkAllocationCallbacks *>( m_allocator )";
}
else
{
arguments +=
"reinterpret_cast<const VkAllocationCallbacks *>(static_cast<const VULKAN_HPP_NAMESPACE::AllocationCallbacks *>( allocator ) )";
}
}
else if ( m_handles.find( param.type.type ) != m_handles.end() )
{
assert( param.type.isValue() && param.arraySizes.empty() && param.len.empty() );
if ( param.optional )
{
arguments += param.name + " ? static_cast<" + param.type.type + ">( **" + param.name + " ) : 0";
}
else
{
arguments += "static_cast<" + param.type.type + ">( *" + param.name + " )";
}
}
else
{
assert( !param.optional );
arguments +=
generateCallArgumentEnhanced( constructorIt->second.params, i, nonConstPointerAsNullptr, singularParams, true );
}
encounteredArgument = true;
}
return arguments;
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorEnumerate(
std::pair<std::string, HandleData> const & handle,
std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator constructorIt,
std::vector<ParamData>::const_iterator handleParamIt,
std::vector<ParamData>::const_iterator lenParamIt,
std::string const & enter,
std::string const & leave ) const
{
std::string handleConstructorArguments = generateRAIIHandleSingularConstructorArguments( handle, constructorIt );
std::string handleType = stripPrefix( handle.first, "Vk" );
std::string dispatcherType = hasParentHandle( handle.first, "VkDevice" )
? "VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::DeviceDispatcher"
: "VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::InstanceDispatcher";
const std::string constructorTemplate =
R"(
${enter} ${handleType}s( ${constructorArguments} )
{
${dispatcherType} const * dispatcher = ${parentName}.getDispatcher();
std::vector<${vectorElementType}> ${vectorName};
${counterType} ${counterName};
VULKAN_HPP_NAMESPACE::Result result;
do
{
result = static_cast<VULKAN_HPP_NAMESPACE::Result>( dispatcher->${constructorCall}( ${firstCallArguments} ) );
if ( ( result == VULKAN_HPP_NAMESPACE::Result::eSuccess ) && ${counterName} )
{
${vectorName}.resize( ${counterName} );
result = static_cast<VULKAN_HPP_NAMESPACE::Result>( dispatcher->${constructorCall}( ${secondCallArguments} ) );
}
} while ( result == VULKAN_HPP_NAMESPACE::Result::eIncomplete );
if ( result == VULKAN_HPP_NAMESPACE::Result::eSuccess )
{
VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() );
this->reserve( ${counterName} );
for ( auto const & ${handleName} : ${vectorName} )
{
this->emplace_back( ${parentName}, ${handleConstructorArguments} );
}
}
else
{
throwResultException( result, "${constructorCall}" );
}
}
${leave})";
return replaceWithMap(
constructorTemplate,
{ { "constructorArguments", generateRAIIHandleConstructorArguments( handle, constructorIt, false, false ) },
{ "constructorCall", constructorIt->first },
{ "counterName", startLowerCase( stripPrefix( lenParamIt->name, "p" ) ) },
{ "counterType", lenParamIt->type.type },
{ "dispatcherType", dispatcherType },
{ "enter", enter },
{ "firstCallArguments", generateRAIIHandleConstructorCallArguments( handle, constructorIt, true, {}, true ) },
{ "handleConstructorArguments", handleConstructorArguments },
{ "handleName", startLowerCase( handleType ) },
{ "handleType", handleType },
{ "leave", leave },
{ "parentName", constructorIt->second.params.front().name },
{ "secondCallArguments", generateRAIIHandleConstructorCallArguments( handle, constructorIt, false, {}, true ) },
{ "vectorElementType", handleParamIt->type.type },
{ "vectorName", startLowerCase( stripPrefix( handleParamIt->name, "p" ) ) } } );
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorInitializationList(
std::pair<std::string, HandleData> const & handle,
std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator constructorIt,
std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator destructorIt,
bool takesOwnership ) const
{
auto [parentType, parentName] = getParentTypeAndName( handle );
std::string handleName = generateRAIIHandleConstructorParamName( handle.first, destructorIt );
std::string initializationList;
if ( destructorIt != m_commands.end() )
{
for ( auto destructorParam : destructorIt->second.params )
{
if ( destructorParam.type.type == "Vk" + parentType )
{
initializationList += "m_" + parentName + "( *" + parentName + " ), ";
}
else if ( destructorParam.type.type == handle.first )
{
if ( takesOwnership )
{
initializationList += "m_" + handleName + "( " + handleName + " ), ";
}
}
else if ( destructorParam.type.type == "VkAllocationCallbacks" )
{
assert( destructorParam.type.isConstPointer() && destructorParam.arraySizes.empty() &&
destructorParam.len.empty() && destructorParam.optional );
initializationList +=
"m_allocator( static_cast<const VULKAN_HPP_NAMESPACE::AllocationCallbacks *>( allocator ) ), ";
}
else if ( isHandleType( destructorParam.type.type ) )
{
assert( destructorParam.type.isValue() && destructorParam.arraySizes.empty() && destructorParam.len.empty() &&
!destructorParam.optional );
initializationList += "m_" + destructorParam.name + "( ";
auto constructorParamIt = std::find_if( constructorIt->second.params.begin(),
constructorIt->second.params.end(),
[&destructorParam]( ParamData const & pd )
{ return pd.type.type == destructorParam.type.type; } );
if ( constructorParamIt != constructorIt->second.params.end() )
{
assert( constructorParamIt->type.isValue() && constructorParamIt->arraySizes.empty() &&
constructorParamIt->len.empty() && !constructorParamIt->optional );
if ( constructorParamIt->type.type == "Vk" + parentType )
{
initializationList += "*";
}
initializationList += constructorParamIt->name;
}
else
{
#if !defined( NDEBUG )
bool found = false;
#endif
for ( auto constructorParam : constructorIt->second.params )
{
auto structureIt = m_structures.find( constructorParam.type.type );
if ( structureIt != m_structures.end() )
{
auto structureMemberIt = std::find_if( structureIt->second.members.begin(),
structureIt->second.members.end(),
[&destructorParam]( MemberData const & md )
{ return md.type.type == destructorParam.type.type; } );
if ( structureMemberIt != structureIt->second.members.end() )
{
assert( constructorParam.type.isConstPointer() && constructorParam.arraySizes.empty() &&
constructorParam.len.empty() && !constructorParam.optional );
initializationList +=
startLowerCase( stripPrefix( constructorParam.name, "p" ) ) + "." + structureMemberIt->name;
#if !defined( NDEBUG )
found = true;
#endif
break;
}
}
}
assert( found );
}
initializationList += " ), ";
}
else
{
// we can ignore all other parameters here !
}
}
}
else
{
if ( !handle.second.secondLevelCommands.empty() )
{
assert( !handle.second.constructorIts.empty() );
auto constructorCommandIt = m_commands.find( handle.second.constructorIts.front()->first );
assert( ( constructorCommandIt != m_commands.end() ) && ( 1 < constructorCommandIt->second.params.size() ) );
assert( std::next( constructorCommandIt->second.params.begin() )->type.type == "Vk" + parentType );
auto commandIt = m_commands.find( *handle.second.secondLevelCommands.begin() );
assert( ( commandIt != m_commands.end() ) && ( 1 < commandIt->second.params.size() ) );
assert( commandIt->second.params.front().type.type == constructorCommandIt->second.params.front().type.type );
assert( std::next( commandIt->second.params.begin() )->type.type == handle.first );
std::string grandParentType = stripPrefix( commandIt->second.params.front().type.type, "Vk" );
initializationList +=
"m_" + startLowerCase( grandParentType ) + "( " + parentName + ".get" + grandParentType + "() ), ";
}
if ( takesOwnership )
{
initializationList += "m_" + handleName + "( " + handleName + " ), ";
}
}
return initializationList.empty() ? initializationList
: initializationList.substr( 0, initializationList.size() - 2 );
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorParamName(
std::string const & type, std::map<std::string, CommandData>::const_iterator destructorIt ) const
{
if ( destructorIt != m_commands.end() )
{
auto destructorParamIt =
std::find_if( destructorIt->second.params.begin(),
destructorIt->second.params.end(),
[&type]( ParamData const & destructorParam ) { return destructorParam.type.type == type; } );
if ( destructorParamIt != destructorIt->second.params.end() )
{
assert( std::find_if( std::next( destructorParamIt ),
destructorIt->second.params.end(),
[&type]( ParamData const & destructorParam )
{ return destructorParam.type.type == type; } ) == destructorIt->second.params.end() );
if ( !destructorParamIt->type.isValue() )
{
return startLowerCase( stripPrefix( stripPluralS( destructorParamIt->name ), "p" ) );
}
else
{
return destructorParamIt->name;
}
}
}
return startLowerCase( stripPrefix( type, "Vk" ) );
}
std::pair<std::string, std::string> VulkanHppGenerator::generateRAIIHandleConstructorResult(
std::pair<std::string, HandleData> const & handle,
std::map<std::string, CommandData>::const_iterator constructorIt,
std::string const & enter,
std::string const & leave ) const
{
assert( !constructorIt->second.successCodes.empty() );
assert( constructorIt->second.successCodes[0] == "VK_SUCCESS" );
switch ( constructorIt->second.successCodes.size() )
{
case 1:
if ( !constructorIt->second.errorCodes.empty() )
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( constructorIt->second.params );
if ( returnParamIndices.size() == 1 )
{
assert( isHandleType( constructorIt->second.params[returnParamIndices[0]].type.type ) );
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( constructorIt->second.params );
switch ( vectorParamIndices.size() )
{
case 0:
return std::make_pair( generateRAIIHandleConstructorResultSingleSuccessWithErrors1Return0Vector(
handle, constructorIt, enter, leave ),
"" );
case 1:
if ( returnParamIndices[0] == vectorParamIndices.begin()->first )
{
if ( isLenByStructMember( constructorIt->second.params[vectorParamIndices.begin()->first].len,
constructorIt->second.params[vectorParamIndices.begin()->second] ) )
{
auto handleParamIt = constructorIt->second.params.begin() + returnParamIndices[0];
return std::make_pair(
"", generateRAIIHandleConstructorVector( handle, constructorIt, handleParamIt, enter, leave ) );
}
}
break;
case 2:
return generateRAIIHandleConstructor1Return2Vector(
handle, constructorIt, enter, leave, returnParamIndices[0], vectorParamIndices );
}
}
}
break;
case 2:
if ( !constructorIt->second.errorCodes.empty() )
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( constructorIt->second.params );
switch ( returnParamIndices.size() )
{
case 1:
assert( isHandleType( constructorIt->second.params[returnParamIndices[0]].type.type ) );
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( constructorIt->second.params );
if ( vectorParamIndices.size() == 2 )
{
return generateRAIIHandleConstructor1Return2Vector(
handle, constructorIt, enter, leave, returnParamIndices[0], vectorParamIndices );
}
}
break;
case 2:
if ( constructorIt->second.params[returnParamIndices[0]].type.type == "uint32_t" )
{
assert( isHandleType( constructorIt->second.params[returnParamIndices[1]].type.type ) );
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( constructorIt->second.params );
if ( vectorParamIndices.size() == 1 )
{
if ( returnParamIndices[0] == vectorParamIndices.begin()->second )
{
assert( returnParamIndices[1] == vectorParamIndices.begin()->first );
assert( constructorIt->second.successCodes[1] == "VK_INCOMPLETE" );
auto lenParamIt = constructorIt->second.params.begin() + returnParamIndices[0];
auto handleParamIt = constructorIt->second.params.begin() + returnParamIndices[1];
return std::make_pair( "",
generateRAIIHandleConstructorEnumerate(
handle, constructorIt, handleParamIt, lenParamIt, enter, leave ) );
}
}
}
break;
}
}
break;
case 4:
if ( !constructorIt->second.errorCodes.empty() )
{
std::vector<size_t> returnParamIndices = determineReturnParamIndices( constructorIt->second.params );
if ( returnParamIndices.size() == 1 )
{
assert( isHandleType( constructorIt->second.params[returnParamIndices[0]].type.type ) );
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( constructorIt->second.params );
if ( vectorParamIndices.size() == 2 )
{
return generateRAIIHandleConstructor1Return2Vector(
handle, constructorIt, enter, leave, returnParamIndices[0], vectorParamIndices );
}
}
}
break;
}
return std::make_pair( "", "" );
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorResultSingleSuccessWithErrors1Return0Vector(
std::pair<std::string, HandleData> const & handle,
std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator constructorIt,
std::string const & enter,
std::string const & leave ) const
{
auto [parentType, parentName] = getParentTypeAndName( handle );
std::string getDispatcher = parentName + ".getDispatcher()";
std::string dispatcherInitializer, dispatcherInit;
if ( ( handle.first != "VkInstance" ) && ( handle.first != "VkDevice" ) )
{
dispatcherInitializer = "m_dispatcher( " + getDispatcher + " )";
}
else
{
std::string handleType = stripPrefix( handle.first, "Vk" );
dispatcherInit =
"\n m_dispatcher.reset( new VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::" + handleType +
"Dispatcher( " + parentName + ".getDispatcher()->vkGet" + handleType + "ProcAddr, static_cast<" + handle.first +
">( m_" + startLowerCase( handleType ) + " ) ) );";
}
std::string constructorArguments = generateRAIIHandleConstructorArguments( handle, constructorIt, false, false );
std::string callArguments = generateRAIIHandleConstructorCallArguments(
handle, constructorIt, false, {}, handle.second.destructorIt != m_commands.end() );
std::string initializationList =
generateRAIIHandleConstructorInitializationList( handle, constructorIt, handle.second.destructorIt, false );
if ( !initializationList.empty() && !dispatcherInitializer.empty() )
{
initializationList += ", ";
}
const std::string constructorTemplate =
R"(
${enter} ${handleType}( ${constructorArguments} )
: ${initializationList}${dispatcherInitializer}
{
VULKAN_HPP_NAMESPACE::Result result = static_cast<VULKAN_HPP_NAMESPACE::Result>( ${getDispatcher}->${constructorCall}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, "${constructorCall}" );
}${dispatcherInit}
}
${leave})";
return replaceWithMap( constructorTemplate,
{ { "callArguments", callArguments },
{ "constructorArguments", constructorArguments },
{ "constructorCall", constructorIt->first },
{ "dispatcherInitializer", dispatcherInitializer },
{ "dispatcherInit", dispatcherInit },
{ "enter", enter },
{ "failureCheck", generateFailureCheck( constructorIt->second.successCodes ) },
{ "getDispatcher", getDispatcher },
{ "leave", leave },
{ "handleType", stripPrefix( handle.first, "Vk" ) },
{ "initializationList", initializationList } } );
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorTakeOwnership(
std::pair<std::string, HandleData> const & handle ) const
{
std::string handleType = stripPrefix( handle.first, "Vk" );
std::string handleName = startLowerCase( handleType );
auto [parentType, parentName] = getParentTypeAndName( handle );
std::string constructorArguments =
generateRAIIHandleConstructorArguments( handle, handle.second.destructorIt, false, true );
std::string initializationList = generateRAIIHandleConstructorInitializationList(
handle, handle.second.destructorIt, handle.second.destructorIt, true );
assert( !handle.second.constructorIts.empty() );
if ( 1 < handle.second.constructorIts[0]->second.successCodes.size() &&
( handle.second.constructorIts[0]->second.successCodes[1] != "VK_INCOMPLETE" ) )
{
#if !defined( NDEBUG )
for ( size_t i = 1; i < handle.second.constructorIts.size(); ++i )
{
assert( 1 < handle.second.constructorIts[i]->second.successCodes.size() );
}
#endif
constructorArguments += ", VULKAN_HPP_NAMESPACE::Result successCode = VULKAN_HPP_NAMESPACE::Result::eSuccess";
initializationList += ", m_constructorSuccessCode( successCode )";
}
std::string dispatcherInitializer;
if ( ( handle.first != "VkInstance" ) && ( handle.first != "VkDevice" ) )
{
dispatcherInitializer = "m_dispatcher( " + parentName + ".getDispatcher() )";
}
if ( !initializationList.empty() && !dispatcherInitializer.empty() )
{
initializationList += ", ";
}
std::string dispatcherInit;
if ( ( handle.first == "VkDevice" ) || ( handle.first == "VkInstance" ) )
{
dispatcherInit =
"\n m_dispatcher.reset( new VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::" + handleType +
"Dispatcher( " + parentName + ".getDispatcher()->vkGet" + handleType + "ProcAddr, static_cast<" + handle.first +
">( m_" + startLowerCase( handleType ) + " ) ) );";
}
const std::string constructorTemplate =
R"(
${handleType}( ${constructorArguments} )
: ${initializationList}${dispatcherInitializer}
{${dispatcherInit}}
)";
return replaceWithMap( constructorTemplate,
{ { "constructorArguments", constructorArguments },
{ "dispatcherInitializer", dispatcherInitializer },
{ "dispatcherInit", dispatcherInit },
{ "handleType", handleType },
{ "initializationList", initializationList } } );
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorVector(
std::pair<std::string, HandleData> const & handle,
std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator constructorIt,
std::vector<ParamData>::const_iterator handleParamIt,
std::string const & enter,
std::string const & leave ) const
{
std::string vectorSize;
auto lenIt = std::find_if( constructorIt->second.params.begin(),
constructorIt->second.params.end(),
[&handleParamIt]( ParamData const & pd ) { return pd.name == handleParamIt->len; } );
if ( lenIt == constructorIt->second.params.end() )
{
std::vector<std::string> lenParts = tokenize( handleParamIt->len, "->" );
assert( lenParts.size() == 2 );
lenIt = std::find_if( constructorIt->second.params.begin(),
constructorIt->second.params.end(),
[&lenParts]( ParamData const & pd ) { return pd.name == lenParts[0]; } );
#if !defined( NDEBUG )
assert( lenIt != constructorIt->second.params.end() );
auto structureIt = m_structures.find( lenIt->type.type );
assert( structureIt != m_structures.end() );
assert( std::find_if( structureIt->second.members.begin(),
structureIt->second.members.end(),
[&lenParts]( MemberData const & md )
{ return md.name == lenParts[1]; } ) != structureIt->second.members.end() );
assert( constructorIt->second.successCodes.size() == 1 );
#endif
vectorSize = startLowerCase( stripPrefix( lenParts[0], "p" ) ) + "." + lenParts[1];
}
else
{
auto arrayIt = std::find_if( constructorIt->second.params.begin(),
constructorIt->second.params.end(),
[&lenIt, &handleParamIt]( ParamData const & pd )
{ return ( pd.len == lenIt->name ) && ( pd.name != handleParamIt->name ); } );
assert( arrayIt != constructorIt->second.params.end() );
vectorSize = startLowerCase( stripPrefix( arrayIt->name, "p" ) ) + ".size()";
}
std::string handleConstructorArguments = generateRAIIHandleSingularConstructorArguments( handle, constructorIt );
std::string handleType = stripPrefix( handle.first, "Vk" );
std::string successCodePassToElement = ( 1 < constructorIt->second.successCodes.size() ) ? ", result" : "";
const std::string constructorTemplate =
R"(
${enter} ${handleType}s( ${constructorArguments} )
{
VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::DeviceDispatcher const * dispatcher = ${parentName}.getDispatcher();
std::vector<${vectorElementType}> ${vectorName}( ${vectorSize} );
VULKAN_HPP_NAMESPACE::Result result = static_cast<VULKAN_HPP_NAMESPACE::Result>( dispatcher->${constructorCall}( ${callArguments} ) );
if ( ${successCheck} )
{
this->reserve( ${vectorSize} );
for ( auto const & ${handleName} : ${vectorName} )
{
this->emplace_back( ${parentName}, ${handleConstructorArguments}${successCodePassToElement} );
}
}
else
{
throwResultException( result, "${constructorCall}" );
}
}
${leave})";
return replaceWithMap(
constructorTemplate,
{ { "callArguments", generateRAIIHandleConstructorCallArguments( handle, constructorIt, false, {}, false ) },
{ "constructorArguments", generateRAIIHandleConstructorArguments( handle, constructorIt, false, false ) },
{ "constructorCall", constructorIt->first },
{ "enter", enter },
{ "handleConstructorArguments", handleConstructorArguments },
{ "handleName", startLowerCase( handleType ) },
{ "handleType", handleType },
{ "leave", leave },
{ "parentName", constructorIt->second.params.front().name },
{ "successCheck", generateSuccessCheck( constructorIt->second.successCodes ) },
{ "successCodePassToElement", successCodePassToElement },
{ "vectorElementType", handleParamIt->type.type },
{ "vectorName", startLowerCase( stripPrefix( handleParamIt->name, "p" ) ) },
{ "vectorSize", vectorSize } } );
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorVectorSingular(
std::pair<std::string, HandleData> const & handle,
std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator constructorIt,
std::vector<ParamData>::const_iterator handleParamIt,
std::string const & enter,
std::string const & leave ) const
{
size_t returnParamIndex = static_cast<size_t>( std::distance( constructorIt->second.params.begin(), handleParamIt ) );
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( constructorIt->second.params );
std::set<size_t> singularParams = determineSingularParams( returnParamIndex, vectorParamIndices );
std::string callArguments =
generateRAIIHandleConstructorCallArguments( handle, constructorIt, false, singularParams, true );
std::string initializationList =
generateRAIIHandleConstructorInitializationList( handle, constructorIt, handle.second.destructorIt, false );
assert( !initializationList.empty() );
std::string failureCheck = generateFailureCheck( constructorIt->second.successCodes );
replaceAll( failureCheck, "result", "m_constructorSuccessCode" );
const std::string singularConstructorTemplate =
R"(
${enter} ${handleType}( ${constructorArguments} )
: ${initializationList}, m_dispatcher( ${firstArgument}.getDispatcher() )
{
m_constructorSuccessCode = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${constructorCall}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( m_constructorSuccessCode, "${constructorCall}" );
}
}
${leave})";
return replaceWithMap(
singularConstructorTemplate,
{ { "initializationList", initializationList },
{ "callArguments", callArguments },
{ "constructorArguments", generateRAIIHandleConstructorArguments( handle, constructorIt, true, false ) },
{ "constructorCall", constructorIt->first },
{ "enter", enter },
{ "firstArgument", constructorIt->second.params[0].name },
{ "failureCheck", failureCheck },
{ "leave", leave },
{ "handleType", stripPrefix( handle.first, "Vk" ) } } );
}
std::pair<std::string, std::string> VulkanHppGenerator::generateRAIIHandleConstructorVoid(
std::pair<std::string, HandleData> const & handle,
std::map<std::string, CommandData>::const_iterator constructorIt,
std::string const & enter,
std::string const & leave ) const
{
assert( constructorIt->second.successCodes.empty() && constructorIt->second.errorCodes.empty() );
std::vector<size_t> returnParamIndices = determineReturnParamIndices( constructorIt->second.params );
if ( returnParamIndices.size() == 1 )
{
assert( isHandleType( constructorIt->second.params[returnParamIndices[0]].type.type ) );
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( constructorIt->second.params );
if ( vectorParamIndices.empty() )
{
return std::make_pair( generateRAIIHandleConstructorVoid1Return0Vector( handle, constructorIt, enter, leave ),
"" );
}
}
return std::make_pair( "", "" );
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorVoid1Return0Vector(
std::pair<std::string, HandleData> const & handle,
std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator constructorIt,
std::string const & enter,
std::string const & leave ) const
{
std::string callArguments = generateRAIIHandleConstructorCallArguments( handle, constructorIt, false, {}, true );
std::string constructorArguments = generateRAIIHandleConstructorArguments( handle, constructorIt, false, false );
std::string initializationList =
generateRAIIHandleConstructorInitializationList( handle, constructorIt, handle.second.destructorIt, false );
if ( !initializationList.empty() )
{
initializationList += ", ";
}
const std::string constructorTemplate =
R"(
${enter} ${handleType}( ${constructorArguments} )
: ${initializationList}m_dispatcher( ${firstArgument}.getDispatcher() )
{
getDispatcher()->${constructorCall}( ${callArguments} );
}
${leave})";
return replaceWithMap( constructorTemplate,
{ { "callArguments", callArguments },
{ "constructorArguments", constructorArguments },
{ "constructorCall", constructorIt->first },
{ "enter", enter },
{ "firstArgument", constructorIt->second.params[0].name },
{ "leave", leave },
{ "handleType", stripPrefix( handle.first, "Vk" ) },
{ "initializationList", initializationList } } );
}
std::string VulkanHppGenerator::generateRAIIHandleContext( std::pair<std::string, HandleData> const & handle,
std::set<std::string> const & specialFunctions ) const
{
const std::string contextTemplate = R"(
class Context
{
public:
#if VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL
Context()
: m_dispatcher( new VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::ContextDispatcher(
m_dynamicLoader.getProcAddress<PFN_vkGetInstanceProcAddr>( "vkGetInstanceProcAddr" ) ) )
#else
Context( PFN_vkGetInstanceProcAddr getInstanceProcAddr )
: m_dispatcher( new VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::ContextDispatcher( getInstanceProcAddr ) )
#endif
{}
~Context() = default;
Context( Context const & ) = delete;
Context( Context && rhs ) VULKAN_HPP_NOEXCEPT
#if VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL
: m_dynamicLoader( std::move( rhs.m_dynamicLoader ) )
, m_dispatcher( rhs.m_dispatcher.release() )
#else
: m_dispatcher( rhs.m_dispatcher.release() )
#endif
{}
Context & operator=( Context const & ) = delete;
Context & operator=( Context && rhs ) VULKAN_HPP_NOEXCEPT
{
if ( this != &rhs )
{
#if VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL
m_dynamicLoader = std::move( rhs.m_dynamicLoader );
#endif
m_dispatcher.reset( rhs.m_dispatcher.release() );
}
return *this;
}
${memberFunctionDeclarations}
VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::ContextDispatcher const * getDispatcher() const
{
VULKAN_HPP_ASSERT( m_dispatcher->getVkHeaderVersion() == VK_HEADER_VERSION );
return &*m_dispatcher;
}
private:
#if VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL
VULKAN_HPP_NAMESPACE::DynamicLoader m_dynamicLoader;
#endif
std::unique_ptr<VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::ContextDispatcher> m_dispatcher;
};
)";
return replaceWithMap(
contextTemplate,
{ { "memberFunctionDeclarations", generateRAIIHandleCommandDeclarations( handle, specialFunctions ) } } );
}
std::pair<std::string, std::string>
VulkanHppGenerator::generateRAIIHandleDestructor( std::string const & handleType,
std::map<std::string, CommandData>::const_iterator destructorIt,
std::string const & enter ) const
{
auto [destructorEnter, destructorLeave] = generateProtection( destructorIt->second.referencedIn, std::string() );
bool doProtect = !destructorEnter.empty() && ( destructorEnter != enter );
if ( !doProtect )
{
destructorEnter.clear();
destructorLeave.clear();
}
std::string destructorCall =
destructorIt->first + "( " + generateRAIIHandleDestructorCallArguments( handleType, destructorIt ) + " )";
const std::string destructorTemplate = R"(
${enter}~${handleType}()
{
if ( m_${handleName} )
{
getDispatcher()->${destructorCall};
}
}
${leave})";
std::string destructor =
replaceWithMap( destructorTemplate,
{ { "destructorCall", destructorCall },
{ "enter", destructorEnter },
{ "handleName", generateRAIIHandleConstructorParamName( handleType, destructorIt ) },
{ "handleType", stripPrefix( handleType, "Vk" ) },
{ "leave", destructorLeave } } );
return std::make_pair( destructor, destructorCall );
}
std::string VulkanHppGenerator::generateRAIIHandleDestructorCallArguments(
std::string const & handleType, std::map<std::string, CommandData>::const_iterator destructorIt ) const
{
std::string arguments;
bool encounteredArgument = false;
for ( auto param : destructorIt->second.params )
{
if ( encounteredArgument )
{
arguments += ", ";
}
if ( param.type.type == handleType )
{
std::string handleName = param.name;
if ( param.type.isValue() )
{
arguments += "static_cast<" + handleType + ">( m_" + handleName + " )";
}
else
{
arguments += "reinterpret_cast<" + handleType + " const *>( &m_" +
stripPluralS( startLowerCase( stripPrefix( handleName, "p" ) ) ) + " )";
}
}
else if ( param.type.type == "VkAllocationCallbacks" )
{
// vk::AllocationCallbacks is stored as a member of the handle class
arguments += "reinterpret_cast<const VkAllocationCallbacks *>( m_allocator )";
}
else if ( isHandleType( param.type.type ) )
{
assert( param.arraySizes.empty() );
std::string argument = "m_" + param.name;
if ( param.type.isValue() )
{
arguments += "static_cast<" + param.type.type + ">( " + argument + " )";
}
else
{
assert( param.type.isConstPointer() );
assert( !param.len.empty() && ( std::find_if( destructorIt->second.params.begin(),
destructorIt->second.params.end(),
[&param]( ParamData const & pd ) {
return pd.name == param.len;
} ) != destructorIt->second.params.end() ) );
arguments += "reinterpret_cast<" + param.type.type + " const *>( &" + argument + " )";
}
}
else
{
assert( ( param.type.type == "uint32_t" ) && param.type.isValue() && param.arraySizes.empty() &&
param.len.empty() && !param.optional );
assert( std::find_if( destructorIt->second.params.begin(),
destructorIt->second.params.end(),
[&param]( ParamData const & pd )
{ return pd.len == param.name; } ) != destructorIt->second.params.end() );
arguments += "1";
}
encounteredArgument = true;
}
return arguments;
}
std::tuple<std::string, std::string, std::string, std::string>
VulkanHppGenerator::generateRAIIHandleDetails( std::pair<std::string, HandleData> const & handle,
std::string const & destructorCall ) const
{
std::string getConstructorSuccessCode;
bool multiSuccessCodeContructor = isMultiSuccessCodeConstructor( handle.second.constructorIts );
if ( multiSuccessCodeContructor )
{
getConstructorSuccessCode = R"(
VULKAN_HPP_NAMESPACE::Result getConstructorSuccessCode() const
{
return m_constructorSuccessCode;
}
)";
}
auto [parentType, parentName] = getParentTypeAndName( handle );
std::string handleType = stripPrefix( handle.first, "Vk" );
std::string handleName = generateRAIIHandleConstructorParamName( handle.first, handle.second.destructorIt );
std::string moveConstructorInitializerList, moveAssignmentInstructions, memberVariables;
if ( handle.second.destructorIt != m_commands.end() )
{
moveAssignmentInstructions = " if ( m_" + handleName +
" )\n"
" {\n"
" getDispatcher()->" +
destructorCall +
";\n"
" }";
for ( auto const & destructorParam : handle.second.destructorIt->second.params )
{
if ( destructorParam.type.type == "Vk" + parentType )
{
moveConstructorInitializerList = "m_" + parentName +
"( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" +
parentName + ", {} ) ), ";
moveAssignmentInstructions += "\n m_" + parentName +
" = VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" +
parentName + ", {} );";
memberVariables = "\n VULKAN_HPP_NAMESPACE::" + parentType + " m_" + parentName + " = {};";
}
else if ( destructorParam.type.type == handle.first )
{
moveConstructorInitializerList += "m_" + handleName +
"( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" +
handleName + ", {} ) ), ";
moveAssignmentInstructions += "\n m_" + handleName +
" = VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" +
handleName + ", {} );";
memberVariables += "\n VULKAN_HPP_NAMESPACE::" + handleType + " m_" + handleName + " = {};";
}
else if ( std::find_if( handle.second.destructorIt->second.params.begin(),
handle.second.destructorIt->second.params.end(),
[&destructorParam]( ParamData const & pd ) { return pd.len == destructorParam.name; } ) ==
handle.second.destructorIt->second.params.end() )
{
std::string name = destructorParam.name;
if ( !destructorParam.type.isValue() )
{
name = startLowerCase( stripPrefix( name, "p" ) );
}
memberVariables += "\n " + destructorParam.type.compose( "VULKAN_HPP_NAMESPACE" ) + " m_" + name + " = " +
( destructorParam.type.postfix.empty() ? "{}" : "nullptr" ) + ";";
moveConstructorInitializerList +=
"m_" + name + "( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" + name + ", {} ) ), ";
moveAssignmentInstructions += "\n m_" + name +
" = VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" + name +
", {} );";
}
}
}
else
{
if ( !handle.second.secondLevelCommands.empty() )
{
assert( !handle.second.constructorIts.empty() );
assert( !handle.second.constructorIts.front()->second.params.empty() );
auto const & frontType = handle.second.constructorIts.front()->second.params.front().type.type;
assert( isHandleType( frontType ) );
auto handleIt = m_handles.find( "Vk" + parentType );
assert( handleIt != m_handles.end() );
assert( handleIt->second.parent == frontType );
std::string frontName = handle.second.constructorIts.front()->second.params.front().name;
moveConstructorInitializerList = "m_" + frontName +
"( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" +
frontName + ", {} ) ), ";
moveAssignmentInstructions = "\n m_" + frontName +
" = VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" + frontName +
", {} );";
memberVariables = "\n VULKAN_HPP_NAMESPACE::" + stripPrefix( frontType, "Vk" ) + " m_" + frontName + " = {};";
}
moveConstructorInitializerList += "m_" + handleName +
"( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" +
handleName + ", {} ) ), ";
moveAssignmentInstructions += "\n m_" + handleName +
" = VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" + handleName +
", {} );";
memberVariables += "\n VULKAN_HPP_NAMESPACE::" + handleType + " m_" + handleName + " = {};";
}
if ( multiSuccessCodeContructor )
{
memberVariables += "\n VULKAN_HPP_NAMESPACE::Result m_constructorSuccessCode;";
}
if ( handle.first == "VkInstance" )
{
memberVariables +=
"\n std::unique_ptr<VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::InstanceDispatcher> m_dispatcher;";
}
else if ( handle.first == "VkDevice" )
{
memberVariables +=
"\n std::unique_ptr<VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::DeviceDispatcher> m_dispatcher;";
}
else if ( handle.second.constructorIts.front()->second.params.front().type.type == "VkDevice" )
{
memberVariables +=
"\n VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::DeviceDispatcher const * m_dispatcher = nullptr;";
}
else
{
memberVariables +=
"\n VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::InstanceDispatcher const * m_dispatcher = nullptr;";
}
if ( ( handle.first == "VkInstance" ) || ( handle.first == "VkDevice" ) )
{
moveConstructorInitializerList += "m_dispatcher( rhs.m_dispatcher.release() )";
moveAssignmentInstructions += "\n m_dispatcher.reset( rhs.m_dispatcher.release() );";
}
else
{
moveConstructorInitializerList +=
"m_dispatcher( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_dispatcher, nullptr ) )";
moveAssignmentInstructions +=
"\n m_dispatcher = VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_dispatcher, nullptr );";
}
return std::make_tuple(
getConstructorSuccessCode, memberVariables, moveConstructorInitializerList, moveAssignmentInstructions );
}
std::string VulkanHppGenerator::generateRAIIHandleForwardDeclarations( std::vector<RequireData> const & requireData,
std::string const & title ) const
{
std::string str;
for ( auto const & require : requireData )
{
for ( auto const & type : require.types )
{
auto handleIt = m_handles.find( type );
if ( handleIt != m_handles.end() )
{
str += " class " + stripPrefix( handleIt->first, "Vk" ) + ";\n";
}
}
}
return addTitleAndProtection( title, str );
}
std::string VulkanHppGenerator::generateRAIIHandleSingularConstructorArguments(
std::pair<std::string, HandleData> const & handle,
std::map<std::string, CommandData>::const_iterator constructorIt ) const
{
std::string arguments = startLowerCase( stripPrefix( handle.first, "Vk" ) );
if ( handle.second.destructorIt != m_commands.end() )
{
auto [parentType, parentName] = getParentTypeAndName( handle );
parentType = "Vk" + parentType;
for ( auto const & destructorParam : handle.second.destructorIt->second.params )
{
if ( ( destructorParam.type.type != parentType ) && ( destructorParam.type.type != handle.first ) &&
( std::find_if( handle.second.destructorIt->second.params.begin(),
handle.second.destructorIt->second.params.end(),
[&destructorParam]( ParamData const & pd ) { return pd.len == destructorParam.name; } ) ==
handle.second.destructorIt->second.params.end() ) )
{
if ( std::find_if( constructorIt->second.params.begin(),
constructorIt->second.params.end(),
[&destructorParam]( ParamData const & pd ) {
return pd.type.type == destructorParam.type.type;
} ) != constructorIt->second.params.end() )
{
if ( isHandleType( destructorParam.type.type ) )
{
assert( destructorParam.type.isValue() );
arguments += ", static_cast<" + destructorParam.type.type + ">( *" + destructorParam.name + " )";
}
else
{
assert( destructorParam.type.type == "VkAllocationCallbacks" );
arguments += ", allocator";
}
}
else
{
#if !defined( NDEBUG )
bool found = false;
#endif
for ( auto const & constructorParam : constructorIt->second.params )
{
auto structureIt = m_structures.find( constructorParam.type.type );
if ( structureIt != m_structures.end() )
{
auto memberIt = std::find_if( structureIt->second.members.begin(),
structureIt->second.members.end(),
[&destructorParam]( MemberData const & md )
{ return md.type.type == destructorParam.type.type; } );
if ( memberIt != structureIt->second.members.end() )
{
#if !defined( NDEBUG )
found = true;
#endif
assert( !constructorParam.type.isValue() );
std::string argument =
startLowerCase( stripPrefix( constructorParam.name, "p" ) ) + "." + memberIt->name;
if ( isHandleType( memberIt->type.type ) )
{
argument = "static_cast<" + memberIt->type.type + ">( " + argument + " )";
}
arguments += ", " + argument;
break;
}
}
}
assert( found );
}
}
}
}
return arguments;
}
std::string
VulkanHppGenerator::generateRAIIHandleVectorSizeCheck( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
std::map<size_t, std::vector<size_t>> const & countToVectorMap,
std::set<size_t> const & skippedParams ) const
{
std::string const throwTemplate =
R"#( if ( ${zeroSizeCheck}${firstVectorName}.size() != ${secondVectorName}.size() )
{
throw LogicError( VULKAN_HPP_NAMESPACE_STRING "::${className}::${commandName}: ${firstVectorName}.size() != ${secondVectorName}.size()" );
})#";
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string sizeChecks;
for ( auto const & cvm : countToVectorMap )
{
assert( !commandData.params[cvm.second[0]].optional );
size_t defaultStartIndex = determineDefaultStartIndex( commandData.params, skippedParams );
std::string firstVectorName = startLowerCase( stripPrefix( commandData.params[cvm.second[0]].name, "p" ) );
for ( size_t i = 1; i < cvm.second.size(); i++ )
{
std::string secondVectorName = startLowerCase( stripPrefix( commandData.params[cvm.second[i]].name, "p" ) );
bool withZeroSizeCheck = commandData.params[cvm.second[i]].optional && ( defaultStartIndex <= cvm.second[i] );
sizeChecks +=
replaceWithMap( throwTemplate,
{ { "firstVectorName", firstVectorName },
{ "className", stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "secondVectorName", secondVectorName },
{ "zeroSizeCheck", withZeroSizeCheck ? ( "!" + secondVectorName + ".empty() && " ) : "" } } );
if ( i + 1 < cvm.second.size() )
{
sizeChecks += "\n";
}
}
}
if ( !sizeChecks.empty() )
{
sizeChecks += "\n";
}
return sizeChecks;
}
std::string
VulkanHppGenerator::generateSizeCheck( std::vector<std::vector<MemberData>::const_iterator> const & arrayIts,
std::string const & structName,
bool mutualExclusiveLens ) const
{
std::string sizeCheck;
if ( 1 < arrayIts.size() )
{
static const std::string throwTextTemplate = R"( if ( ${throwCheck} )
{
throw LogicError( VULKAN_HPP_NAMESPACE_STRING"::${structName}::${structName}: ${throwCheck}" );
}
)";
std::string assertionText, throwText;
if ( mutualExclusiveLens )
{
// exactly one of the arrays has to be non-empty
std::string sum;
for ( auto it : arrayIts )
{
sum += "!" + startLowerCase( stripPrefix( it->name, "p" ) ) + "_.empty() + ";
}
sum.resize( sum.size() - 3 );
assertionText += " VULKAN_HPP_ASSERT( ( " + sum + " ) <= 1);\n";
throwText +=
replaceWithMap( throwTextTemplate, { { "structName", structName }, { "throwCheck", "1 < ( " + sum + " )" } } );
}
else
{
for ( size_t first = 0; first + 1 < arrayIts.size(); ++first )
{
assert( beginsWith( arrayIts[first]->name, "p" ) );
std::string firstName = startLowerCase( stripPrefix( arrayIts[first]->name, "p" ) ) + "_";
for ( auto second = first + 1; second < arrayIts.size(); ++second )
{
assert( beginsWith( arrayIts[second]->name, "p" ) );
std::string secondName = startLowerCase( stripPrefix( arrayIts[second]->name, "p" ) ) + "_";
std::string assertionCheck = firstName + ".size() == " + secondName + ".size()";
std::string throwCheck = firstName + ".size() != " + secondName + ".size()";
if ( ( !arrayIts[first]->optional.empty() && arrayIts[first]->optional.front() ) ||
( !arrayIts[second]->optional.empty() && arrayIts[second]->optional.front() ) )
{
assertionCheck = "( " + assertionCheck + " )";
throwCheck = "( " + throwCheck + " )";
if ( !arrayIts[second]->optional.empty() && arrayIts[second]->optional.front() )
{
assertionCheck = secondName + ".empty() || " + assertionCheck;
throwCheck = "!" + secondName + ".empty() && " + throwCheck;
}
if ( !arrayIts[first]->optional.empty() && arrayIts[first]->optional.front() )
{
assertionCheck = firstName + ".empty() || " + assertionCheck;
throwCheck = "!" + firstName + ".empty() && " + throwCheck;
}
}
assertionText += " VULKAN_HPP_ASSERT( " + assertionCheck + " );\n";
throwText +=
replaceWithMap( throwTextTemplate, { { "structName", structName }, { "throwCheck", throwCheck } } );
}
}
}
sizeCheck += "\n#ifdef VULKAN_HPP_NO_EXCEPTIONS\n" + assertionText + "#else\n" + throwText +
"#endif /*VULKAN_HPP_NO_EXCEPTIONS*/\n" + " ";
}
return sizeCheck;
}
std::string VulkanHppGenerator::generateStruct( std::pair<std::string, StructureData> const & structure,
std::set<std::string> & listedStructs ) const
{
assert( listedStructs.find( structure.first ) == listedStructs.end() );
std::string str;
for ( auto const & member : structure.second.members )
{
auto structIt = m_structures.find( member.type.type );
if ( ( structIt != m_structures.end() ) && ( structure.first != member.type.type ) &&
( listedStructs.find( member.type.type ) == listedStructs.end() ) )
{
str += generateStruct( *structIt, listedStructs );
}
}
if ( !structure.second.subStruct.empty() )
{
auto structureIt = m_structures.find( structure.second.subStruct );
if ( ( structureIt != m_structures.end() ) && ( listedStructs.find( structureIt->first ) == listedStructs.end() ) )
{
str += generateStruct( *structureIt, listedStructs );
}
}
if ( structure.second.isUnion )
{
str += generateUnion( structure );
}
else
{
str += generateStructure( structure );
}
listedStructs.insert( structure.first );
return str;
}
std::string VulkanHppGenerator::generateStructAssignmentOperators(
std::pair<std::string, StructureData> const & structData ) const
{
static const std::string assignmentFromVulkanType = R"(
${structName} & operator=( ${structName} const & rhs ) VULKAN_HPP_NOEXCEPT = default;
${structName} & operator=( Vk${structName} const & rhs ) VULKAN_HPP_NOEXCEPT
{
*this = *reinterpret_cast<VULKAN_HPP_NAMESPACE::${structName} const *>( &rhs );
return *this;
}
)";
return replaceWithMap( assignmentFromVulkanType, { { "structName", stripPrefix( structData.first, "Vk" ) } } );
}
std::string
VulkanHppGenerator::generateStructCompareOperators( std::pair<std::string, StructureData> const & structData ) const
{
static const std::set<std::string> simpleTypes = { "char", "double", "DWORD", "float", "HANDLE",
"HINSTANCE", "HMONITOR", "HWND", "int", "int8_t",
"int16_t", "int32_t", "int64_t", "LPCWSTR", "size_t",
"uint8_t", "uint16_t", "uint32_t", "uint64_t" };
// two structs are compared by comparing each of the elements
std::string compareMembers;
std::string intro = "";
for ( size_t i = 0; i < structData.second.members.size(); i++ )
{
MemberData const & member = structData.second.members[i];
auto typeIt = m_types.find( member.type.type );
assert( typeIt != m_types.end() );
if ( ( typeIt->second.category == TypeCategory::Requires ) && member.type.postfix.empty() &&
( simpleTypes.find( member.type.type ) == simpleTypes.end() ) )
{
// this type might support operator==()... that is, use memcmp
compareMembers +=
intro + "( memcmp( &" + member.name + ", &rhs." + member.name + ", sizeof( " + member.type.type + " ) ) == 0 )";
}
else
{
// for all others, we use the operator== of that type
compareMembers += intro + "( " + member.name + " == rhs." + member.name + " )";
}
intro = "\n && ";
}
static const std::string compareTemplate = R"(
#if defined(VULKAN_HPP_HAS_SPACESHIP_OPERATOR)
auto operator<=>( ${name} const & ) const = default;
#else
bool operator==( ${name} const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return ${compareMembers};
}
bool operator!=( ${name} const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return !operator==( rhs );
}
#endif
)";
return replaceWithMap( compareTemplate,
{ { "name", stripPrefix( structData.first, "Vk" ) }, { "compareMembers", compareMembers } } );
}
std::string
VulkanHppGenerator::generateStructConstructors( std::pair<std::string, StructureData> const & structData ) const
{
// the constructor with all the elements as arguments, with defaults
// and the simple copy constructor from the corresponding vulkan structure
static const std::string constructors = R"(
${constexpr}${structName}(${arguments}) VULKAN_HPP_NOEXCEPT
${initializers}
{}
${constexpr}${structName}( ${structName} const & rhs ) VULKAN_HPP_NOEXCEPT = default;
${structName}( Vk${structName} const & rhs ) VULKAN_HPP_NOEXCEPT
: ${structName}( *reinterpret_cast<${structName} const *>( &rhs ) )
{}
)";
std::string arguments, initializers;
bool listedArgument = false;
bool firstArgument = true;
for ( auto const & member : structData.second.members )
{
// gather the arguments
std::string argument = generateStructConstructorArgument( listedArgument, member, true );
if ( !argument.empty() )
{
listedArgument = true;
arguments += argument;
}
// gather the initializers; skip member 'pNext' and members with exactly one legal value
if ( ( member.name != "pNext" ) && member.value.empty() )
{
initializers += ( firstArgument ? ":" : "," ) + std::string( " " ) + member.name + "( " + member.name + "_ )";
firstArgument = false;
}
}
std::string str = replaceWithMap( constructors,
{ { "arguments", arguments },
{ "constexpr", generateConstexprString( structData.first ) },
{ "initializers", initializers },
{ "structName", stripPrefix( structData.first, "Vk" ) } } );
str += generateStructConstructorsEnhanced( structData );
return str;
}
std::string VulkanHppGenerator::generateStructConstructorsEnhanced(
std::pair<std::string, StructureData> const & structData ) const
{
auto memberIts =
findAll( structData.second.members.begin(),
structData.second.members.end(),
[]( MemberData const & md )
{
return !md.len.empty() && !( md.len[0] == "null-terminated" ) &&
( ( altLens.find( md.len[0] ) == altLens.end() ) || ( md.len[0] == "codeSize / 4" ) );
} );
if ( !memberIts.empty() )
{
// map from len-members to all the array members using that len
std::map<std::vector<MemberData>::const_iterator, std::vector<std::vector<MemberData>::const_iterator>> lenIts;
for ( auto const & mit : memberIts )
{
std::string lenName = ( mit->len.front() == "codeSize / 4" ) ? "codeSize" : mit->len.front();
auto lenIt = std::find_if(
structData.second.members.begin(), mit, [&lenName]( MemberData const & md ) { return md.name == lenName; } );
assert( lenIt != mit );
lenIts[lenIt].push_back( mit );
}
std::string arguments, initializers;
bool listedArgument = false;
bool firstArgument = true;
bool arrayListed = false;
std::string templateHeader, sizeChecks;
for ( auto mit = structData.second.members.begin(); mit != structData.second.members.end(); ++mit )
{
// gather the initializers; skip member 'pNext' and constant members
if ( ( mit->name != "pNext" ) && mit->value.empty() )
{
auto litit = lenIts.find( mit );
if ( litit != lenIts.end() )
{
// len arguments just have an initalizer, from the ArrayProxyNoTemporaries size
initializers += ( firstArgument ? ": " : ", " ) + mit->name + "( " +
generateLenInitializer( mit, litit, structData.second.mutualExclusiveLens ) + " )";
sizeChecks += generateSizeCheck(
litit->second, stripPrefix( structData.first, "Vk" ), structData.second.mutualExclusiveLens );
}
else if ( std::find( memberIts.begin(), memberIts.end(), mit ) != memberIts.end() )
{
assert( beginsWith( mit->name, "p" ) );
std::string argumentName = startLowerCase( stripPrefix( mit->name, "p" ) ) + "_";
assert( endsWith( mit->type.postfix, "*" ) );
std::string argumentType = trimEnd( stripPostfix( mit->type.compose( "VULKAN_HPP_NAMESPACE" ), "*" ) );
if ( ( mit->type.type == "void" ) && ( argumentType.find( '*' ) == std::string::npos ) )
{
// the argument after stripping one pointer is just void
assert( templateHeader.empty() );
templateHeader = " template <typename T>\n";
size_t pos = argumentType.find( "void" );
assert( pos != std::string::npos );
argumentType.replace( pos, strlen( "void" ), "T" );
}
arguments += listedArgument ? ", " : "";
arguments += "VULKAN_HPP_NAMESPACE::ArrayProxyNoTemporaries<" + argumentType + "> const & " + argumentName;
if ( arrayListed )
{
arguments += " = {}";
}
listedArgument = true;
arrayListed = true;
initializers += ( firstArgument ? ": " : ", " ) + mit->name + "( " + argumentName + ".data() )";
}
else
{
std::string argument = generateStructConstructorArgument( listedArgument, *mit, arrayListed );
if ( !argument.empty() )
{
listedArgument = true;
arguments += argument;
}
initializers += ( firstArgument ? ": " : ", " ) + mit->name + "( " + mit->name + "_ )";
}
firstArgument = false;
}
}
static const std::string constructorTemplate = R"(
#if !defined( VULKAN_HPP_DISABLE_ENHANCED_MODE )
${templateHeader} ${structName}( ${arguments} )
${initializers}
{${sizeChecks}}
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap( constructorTemplate,
{ { "arguments", arguments },
{ "initializers", initializers },
{ "sizeChecks", sizeChecks },
{ "structName", stripPrefix( structData.first, "Vk" ) },
{ "templateHeader", templateHeader } } );
}
return "";
}
std::string VulkanHppGenerator::generateStructConstructorArgument( bool listedArgument,
MemberData const & memberData,
bool withDefault ) const
{
// skip members 'pNext' and members with a specified value, as they are never explicitly set
std::string str;
if ( ( memberData.name != "pNext" ) && memberData.value.empty() )
{
str += ( listedArgument ? ( ", " ) : "" );
if ( memberData.arraySizes.empty() )
{
str += memberData.type.compose( "VULKAN_HPP_NAMESPACE" ) + " ";
}
else
{
str +=
generateStandardArray( memberData.type.compose( "VULKAN_HPP_NAMESPACE" ), memberData.arraySizes ) + " const & ";
}
str += memberData.name + "_";
if ( withDefault )
{
str += " = ";
auto enumIt = m_enums.find( memberData.type.type );
if ( enumIt != m_enums.end() && memberData.type.postfix.empty() )
{
str += generateEnumInitializer(
memberData.type, memberData.arraySizes, enumIt->second.values, enumIt->second.isBitmask );
}
else
{
assert( memberData.value.empty() );
// all the rest can be initialized with just {}
str += "{}";
}
}
}
return str;
}
std::string VulkanHppGenerator::generateStructure( std::pair<std::string, StructureData> const & structure ) const
{
auto [enter, leave] = generateProtection(
structure.first, m_structureAliasesInverse.find( structure.first ) != m_structureAliasesInverse.end() );
std::string str = "\n" + enter;
std::string constructorAndSetters;
constructorAndSetters += "#if !defined( VULKAN_HPP_NO_STRUCT_CONSTRUCTORS )";
constructorAndSetters += generateStructConstructors( structure );
constructorAndSetters += generateStructSubConstructor( structure );
constructorAndSetters += "#endif /*VULKAN_HPP_NO_STRUCT_CONSTRUCTORS*/\n";
constructorAndSetters += generateStructAssignmentOperators( structure );
if ( !structure.second.returnedOnly )
{
// only structs that are not returnedOnly get setters!
constructorAndSetters += "\n#if !defined( VULKAN_HPP_NO_STRUCT_SETTERS )";
for ( size_t i = 0; i < structure.second.members.size(); i++ )
{
constructorAndSetters +=
generateStructSetter( stripPrefix( structure.first, "Vk" ), structure.second.members, i );
}
constructorAndSetters += "#endif /*VULKAN_HPP_NO_STRUCT_SETTERS*/\n";
}
// operator==() and operator!=()
// only structs without a union as a member can have a meaningfull == and != operation; we filter them out
std::string compareOperators;
if ( !containsUnion( structure.first ) )
{
compareOperators += generateStructCompareOperators( structure );
}
// the member variables
std::string members, sTypeValue;
std::tie( members, sTypeValue ) = generateStructMembers( structure, " " );
static const std::string structureTemplate = R"( struct ${structureName}
{
using NativeType = Vk${structureName};
${allowDuplicate}
${structureType}
${constructorAndSetters}
operator ${vkName} const &() const VULKAN_HPP_NOEXCEPT
{
return *reinterpret_cast<const ${vkName}*>( this );
}
operator ${vkName} &() VULKAN_HPP_NOEXCEPT
{
return *reinterpret_cast<${vkName}*>( this );
}
${compareOperators}
public:
${members}
};
VULKAN_HPP_STATIC_ASSERT( sizeof( VULKAN_HPP_NAMESPACE::${structureName} ) == sizeof( ${vkName} ), "struct and wrapper have different size!" );
VULKAN_HPP_STATIC_ASSERT( std::is_standard_layout<VULKAN_HPP_NAMESPACE::${structureName}>::value, "struct wrapper is not a standard layout!" );
VULKAN_HPP_STATIC_ASSERT( std::is_nothrow_move_constructible<VULKAN_HPP_NAMESPACE::${structureName}>::value, "${structureName} is not nothrow_move_constructible!" );
)";
std::string structureName = stripPrefix( structure.first, "Vk" );
std::string allowDuplicate, structureType;
if ( !sTypeValue.empty() )
{
allowDuplicate = std::string( " static const bool allowDuplicate = " ) +
( structure.second.allowDuplicate ? "true;" : "false;" );
structureType =
" static VULKAN_HPP_CONST_OR_CONSTEXPR StructureType structureType = StructureType::" + sTypeValue + ";\n";
}
str += replaceWithMap( structureTemplate,
{ { "allowDuplicate", allowDuplicate },
{ "structureName", structureName },
{ "structureType", structureType },
{ "constructorAndSetters", constructorAndSetters },
{ "vkName", structure.first },
{ "compareOperators", compareOperators },
{ "members", members } } );
if ( !sTypeValue.empty() )
{
std::string cppTypeTemplate = R"(
template <>
struct CppType<StructureType, StructureType::${sTypeValue}>
{
using Type = ${structureName};
};
)";
str += replaceWithMap( cppTypeTemplate, { { "sTypeValue", sTypeValue }, { "structureName", structureName } } );
}
auto aliasIt = m_structureAliasesInverse.find( structure.first );
if ( aliasIt != m_structureAliasesInverse.end() )
{
for ( std::string const & alias : aliasIt->second )
{
str += " using " + stripPrefix( alias, "Vk" ) + " = " + structureName + ";\n";
}
}
str += leave;
return str;
}
std::string VulkanHppGenerator::generateStructExtendsStructs( std::vector<RequireData> const & requireData,
std::set<std::string> & listedStructs,
std::string const & title ) const
{
std::string str;
for ( auto const & require : requireData )
{
for ( auto const & type : require.types )
{
auto structIt = m_structures.find( type );
if ( structIt != m_structures.end() )
{
assert( listedStructs.find( type ) == listedStructs.end() );
listedStructs.insert( type );
auto [enter, leave] = generateProtection( title, std::string() );
// append all allowed structure chains
for ( auto extendName : structIt->second.structExtends )
{
std::map<std::string, StructureData>::const_iterator itExtend = m_structures.find( extendName );
if ( itExtend == m_structures.end() )
{
// look if the extendName acutally is an alias of some other structure
auto aliasIt = m_structureAliases.find( extendName );
if ( aliasIt != m_structureAliases.end() )
{
itExtend = m_structures.find( aliasIt->second.alias );
assert( itExtend != m_structures.end() );
}
}
auto [subEnter, subLeave] = generateProtection(
itExtend->first, m_structureAliasesInverse.find( itExtend->first ) != m_structureAliasesInverse.end() );
if ( enter != subEnter )
{
str += subEnter;
}
str += " template <> struct StructExtends<" + stripPrefix( structIt->first, "Vk" ) + ", " +
stripPrefix( extendName, "Vk" ) + ">{ enum { value = true }; };\n";
if ( leave != subLeave )
{
str += subLeave;
}
}
}
}
}
return addTitleAndProtection( title, str );
}
std::string VulkanHppGenerator::generateStructForwardDeclarations( std::vector<RequireData> const & requireData,
std::string const & title ) const
{
std::string str;
for ( auto const & require : requireData )
{
for ( auto const & type : require.types )
{
auto structIt = m_structures.find( type );
if ( structIt != m_structures.end() )
{
std::string structureType = stripPrefix( structIt->first, "Vk" );
str += ( structIt->second.isUnion ? " union " : " struct " ) + structureType + ";\n";
auto inverseIt = m_structureAliasesInverse.find( type );
if ( inverseIt != m_structureAliasesInverse.end() )
{
for ( auto alias : inverseIt->second )
{
str += " using " + stripPrefix( alias, "Vk" ) + " = " + structureType + ";\n";
}
}
}
}
}
return addTitleAndProtection( title, str );
}
std::pair<std::string, std::string>
VulkanHppGenerator::generateStructMembers( std::pair<std::string, StructureData> const & structData,
std::string const & prefix ) const
{
std::string str, sTypeValue;
for ( auto const & member : structData.second.members )
{
str += prefix;
if ( !member.bitCount.empty() && beginsWith( member.type.type, "Vk" ) )
{
assert( member.type.prefix.empty() && member.type.postfix.empty() ); // never encounterd a different case
str += member.type.type;
}
else if ( member.arraySizes.empty() )
{
str += member.type.compose( "VULKAN_HPP_NAMESPACE" );
}
else
{
assert( member.type.prefix.empty() && member.type.postfix.empty() );
str += generateStandardArrayWrapper( member.type.compose( "VULKAN_HPP_NAMESPACE" ), member.arraySizes );
}
str += " " + member.name;
if ( !member.value.empty() )
{
// special handling for members with legal value: use it as the default
str += " = ";
if ( member.type.type == "uint32_t" )
{
str += member.value;
}
else
{
auto enumIt = m_enums.find( member.type.type );
assert( enumIt != m_enums.end() );
std::string enumValue = member.value;
auto valueIt = std::find_if( enumIt->second.values.begin(),
enumIt->second.values.end(),
[&enumValue]( EnumValueData const & evd ) { return enumValue == evd.name; } );
assert( valueIt != enumIt->second.values.end() );
std::string valueName = generateEnumValueName( enumIt->first, valueIt->name, enumIt->second.isBitmask, m_tags );
str += stripPrefix( member.type.type, "Vk" ) + "::" + valueName;
if ( member.name == "sType" )
{
sTypeValue = valueName;
}
}
}
else
{
// as we don't have any meaningful default initialization values, everything can be initialized by just '{}' !
assert( member.arraySizes.empty() || member.bitCount.empty() );
if ( !member.bitCount.empty() )
{
str += " : " + member.bitCount; // except for bitfield members, where no default member initializatin is
// supported (up to C++20)
}
else
{
str += " = ";
auto enumIt = m_enums.find( member.type.type );
if ( member.arraySizes.empty() && ( enumIt != m_enums.end() ) && member.type.postfix.empty() )
{
str +=
generateEnumInitializer( member.type, member.arraySizes, enumIt->second.values, enumIt->second.isBitmask );
}
else
{
str += "{}";
}
}
}
str += ";\n";
}
return std::make_pair( str, sTypeValue );
}
std::string VulkanHppGenerator::generateStructSetter( std::string const & structureName,
std::vector<MemberData> const & memberData,
size_t index ) const
{
std::string str;
MemberData const & member = memberData[index];
if ( member.type.type != "VkStructureType" ) // filter out StructureType, which is supposed to be immutable !
{
static const std::string templateString = R"(
${constexpr}${structureName} & set${MemberName}( ${memberType} ${reference}${memberName}_ ) VULKAN_HPP_NOEXCEPT
{
${assignment};
return *this;
}
)";
std::string memberType =
member.arraySizes.empty()
? member.type.compose( "VULKAN_HPP_NAMESPACE" )
: generateStandardArray( member.type.compose( "VULKAN_HPP_NAMESPACE" ), member.arraySizes );
bool isReinterpretation = !member.bitCount.empty() && beginsWith( member.type.type, "Vk" );
std::string assignment;
if ( isReinterpretation )
{
assignment = member.name + " = " + "*reinterpret_cast<" + member.type.type + "*>(&" + member.name + "_)";
}
else
{
assignment = member.name + " = " + member.name + "_";
}
str += replaceWithMap(
templateString,
{ { "assignment", assignment },
{ "constexpr", isReinterpretation ? "" : "VULKAN_HPP_CONSTEXPR_14 " },
{ "memberName", member.name },
{ "MemberName", startUpperCase( member.name ) },
{ "memberType", memberType },
{ "reference",
( member.type.postfix.empty() && ( m_structures.find( member.type.type ) != m_structures.end() ) )
? "const & "
: "" },
{ "structureName", structureName } } );
if ( !member.len.empty() && ( member.len[0] != "null-terminated" ) &&
( ( altLens.find( member.len[0] ) == altLens.end() ) || ( member.len[0] == "codeSize / 4" ) ) )
{
assert( member.name.front() == 'p' );
std::string arrayName = startLowerCase( stripPrefix( member.name, "p" ) );
std::string lenName, lenValue;
if ( member.len[0] == "codeSize / 4" )
{
lenName = "codeSize";
lenValue = arrayName + "_.size() * 4";
}
else
{
lenName = member.len[0];
lenValue = arrayName + "_.size()";
}
assert( memberType.back() == '*' );
memberType = trimEnd( stripPostfix( memberType, "*" ) );
std::string templateHeader;
if ( ( member.type.type == "void" ) && ( memberType.find( '*' ) == std::string::npos ) )
{
assert( templateHeader.empty() );
templateHeader = "template <typename T>\n ";
size_t pos = memberType.find( "void" );
assert( pos != std::string::npos );
memberType.replace( pos, strlen( "void" ), "T" );
lenValue += " * sizeof(T)";
}
auto lenMember = std::find_if(
memberData.begin(), memberData.end(), [&lenName]( MemberData const & md ) { return md.name == lenName; } );
assert( lenMember != memberData.end() && lenMember->type.prefix.empty() && lenMember->type.postfix.empty() );
if ( lenMember->type.type != "size_t" )
{
lenValue = "static_cast<" + lenMember->type.type + ">( " + lenValue + " )";
}
static const std::string setArrayTemplate = R"(
#if !defined( VULKAN_HPP_DISABLE_ENHANCED_MODE )
${templateHeader}${structureName} & set${ArrayName}( VULKAN_HPP_NAMESPACE::ArrayProxyNoTemporaries<${memberType}> const & ${arrayName}_ ) VULKAN_HPP_NOEXCEPT
{
${lenName} = ${lenValue};
${memberName} = ${arrayName}_.data();
return *this;
}
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
str += replaceWithMap( setArrayTemplate,
{ { "arrayName", arrayName },
{ "ArrayName", startUpperCase( arrayName ) },
{ "lenName", lenName },
{ "lenValue", lenValue },
{ "memberName", member.name },
{ "memberType", memberType },
{ "structureName", structureName },
{ "templateHeader", templateHeader } } );
}
}
return str;
}
std::string
VulkanHppGenerator::generateStructSubConstructor( std::pair<std::string, StructureData> const & structData ) const
{
if ( !structData.second.subStruct.empty() )
{
auto const & subStruct = m_structures.find( structData.second.subStruct );
assert( subStruct != m_structures.end() );
std::string subStructArgumentName = startLowerCase( stripPrefix( subStruct->first, "Vk" ) );
std::string subCopies;
bool firstArgument = true;
for ( size_t i = 0; i < subStruct->second.members.size(); i++ )
{
assert( structData.second.members[i].arraySizes.empty() );
static const std::string subCopiesTemplate =
R"( ${separator} ${structMemberName}( ${subStructArgumentName}.${subStructMemberName} )
)";
subCopies += replaceWithMap( subCopiesTemplate,
{ { "separator", firstArgument ? ":" : "," },
{ "structMemberName", structData.second.members[i].name },
{ "subStructMemberName", subStruct->second.members[i].name },
{ "subStructArgumentName", subStructArgumentName } } );
firstArgument = false;
}
std::string subArguments;
bool listedArgument = true;
for ( size_t i = subStruct->second.members.size(); i < structData.second.members.size(); i++ )
{
std::string argument = generateStructConstructorArgument( listedArgument, structData.second.members[i], true );
if ( !argument.empty() )
{
listedArgument = true;
subArguments += argument;
}
assert( structData.second.members[i].arraySizes.empty() );
static const std::string subCopiesTemplate = R"( , ${memberName}( ${memberName}_ )
)";
subCopies += replaceWithMap( subCopiesTemplate, { { "memberName", structData.second.members[i].name } } );
}
static const std::string subStructConstructorTemplate = R"(
explicit ${structName}( ${subStructName} const & ${subStructArgumentName}${subArguments} )
${subCopies} {}
)";
return replaceWithMap( subStructConstructorTemplate,
{ { "structName", stripPrefix( structData.first, "Vk" ) },
{ "subArguments", subArguments },
{ "subCopies", subCopies },
{ "subStructArgumentName", subStructArgumentName },
{ "subStructName", stripPrefix( subStruct->first, "Vk" ) } } );
}
return "";
}
std::string VulkanHppGenerator::generateSuccessCheck( std::vector<std::string> const & successCodes ) const
{
assert( !successCodes.empty() );
std::string successCheck = "result == " + generateSuccessCode( successCodes[0], m_tags );
if ( 1 < successCodes.size() )
{
successCheck = "( " + successCheck + " )";
for ( size_t i = 1; i < successCodes.size(); ++i )
{
successCheck += "|| ( result == " + generateSuccessCode( successCodes[i], m_tags ) + " )";
}
}
return successCheck;
}
std::string VulkanHppGenerator::generateSuccessCodeList( std::vector<std::string> const & successCodes ) const
{
std::string successCodeList;
if ( 1 < successCodes.size() )
{
successCodeList = ", { " + generateSuccessCode( successCodes[0], m_tags );
for ( size_t i = 1; i < successCodes.size(); ++i )
{
successCodeList += ", " + generateSuccessCode( successCodes[i], m_tags );
}
successCodeList += " }";
}
return successCodeList;
}
std::string VulkanHppGenerator::generateUnion( std::pair<std::string, StructureData> const & structure ) const
{
auto [enter, leave] = generateProtection(
structure.first, m_structureAliasesInverse.find( structure.first ) != m_structureAliasesInverse.end() );
std::string unionName = stripPrefix( structure.first, "Vk" );
bool firstMember = true;
std::set<TypeInfo> listedTypes; // create just one constructor per different type !
std::string constructors;
for ( auto memberIt = structure.second.members.begin(); memberIt != structure.second.members.end(); ++memberIt )
{
if ( listedTypes.insert( memberIt->type ).second )
{
// VkBool32 is aliased to uint32_t. Don't create a VkBool32 constructor if the union also contains a uint32_t
// constructor.
if ( memberIt->type.type == "VkBool32" )
{
if ( std::find_if( structure.second.members.begin(),
structure.second.members.end(),
[]( MemberData const & member ) {
return member.type.type == std::string( "uint32_t" );
} ) != structure.second.members.end() )
{
continue;
}
}
bool multipleType = ( std::find_if( std::next( memberIt ),
structure.second.members.end(),
[memberIt]( MemberData const & member ) {
return member.type == memberIt->type;
} ) != structure.second.members.end() );
std::string memberType =
( memberIt->arraySizes.empty() )
? memberIt->type.compose( "VULKAN_HPP_NAMESPACE" )
: ( "const " +
generateStandardArray( memberIt->type.compose( "VULKAN_HPP_NAMESPACE" ), memberIt->arraySizes ) + "&" );
// In a majority of cases this can be constexpr in C++11 as well, however, determining when exactly
// that is the case is a lot more involved and probably not worth it.
static const std::string constructorTemplate = R"(
VULKAN_HPP_CONSTEXPR_14 ${unionName}( ${memberType} ${argumentName}_${defaultAssignment} )
: ${memberName}( ${argumentName}_ )
{})";
constructors +=
( firstMember ? "" : "\n" ) +
replaceWithMap( constructorTemplate,
{ { "argumentName", multipleType ? generateName( memberIt->type ) : memberIt->name },
{ "defaultAssignment", firstMember ? " = {}" : "" },
{ "memberName", memberIt->name },
{ "memberType", memberType },
{ "unionName", stripPrefix( structure.first, "Vk" ) } } );
firstMember = false;
}
}
// one setter per union element
std::string setters;
for ( size_t i = 0; i < structure.second.members.size(); i++ )
{
setters += generateStructSetter( stripPrefix( structure.first, "Vk" ), structure.second.members, i );
}
// filter out leading and trailing newline
setters = setters.substr( 1, setters.length() - 2 );
// the union member variables
std::string members;
// if there's at least one Vk... type in this union, check for unrestricted unions support
bool needsUnrestrictedUnions = ( std::find_if( structure.second.members.begin(),
structure.second.members.end(),
[]( MemberData const & member ) {
return beginsWith( member.type.type, "Vk" );
} ) != structure.second.members.end() );
if ( needsUnrestrictedUnions )
{
members += "#ifdef VULKAN_HPP_HAS_UNRESTRICTED_UNIONS\n";
}
for ( auto const & member : structure.second.members )
{
static const std::string memberTemplate = R"( ${memberType} ${memberName};
)";
members += replaceWithMap(
memberTemplate,
{ { "memberName", member.name },
{ "memberType",
member.arraySizes.empty()
? member.type.compose( "VULKAN_HPP_NAMESPACE" )
: generateStandardArrayWrapper( member.type.compose( "VULKAN_HPP_NAMESPACE" ), member.arraySizes ) } } );
}
if ( needsUnrestrictedUnions )
{
members += "#else\n";
for ( auto const & member : structure.second.members )
{
static const std::string memberTemplate = R"( ${memberType} ${memberName}${arraySizes};
)";
members += replaceWithMap( memberTemplate,
{ { "arraySizes", generateCArraySizes( member.arraySizes ) },
{ "memberName", member.name },
{ "memberType", member.type.compose( "" ) } } );
}
members += "#endif /*VULKAN_HPP_HAS_UNRESTRICTED_UNIONS*/\n";
}
static const std::string unionTemplate = R"(
${enter} union ${unionName}
{
using NativeType = Vk${unionName};
#if !defined( VULKAN_HPP_NO_UNION_CONSTRUCTORS )
${constructors}
#endif /*VULKAN_HPP_NO_UNION_CONSTRUCTORS*/
#if !defined( VULKAN_HPP_NO_UNION_SETTERS )
${setters}
#endif /*VULKAN_HPP_NO_UNION_SETTERS*/
operator Vk${unionName} const &() const
{
return *reinterpret_cast<const Vk${unionName}*>( this );
}
operator Vk${unionName} &()
{
return *reinterpret_cast<Vk${unionName}*>( this );
}
${members}
};
${leave})";
return replaceWithMap( unionTemplate,
{ { "constructors", constructors },
{ "enter", enter },
{ "leave", leave },
{ "members", members },
{ "setters", setters },
{ "unionName", unionName } } );
}
std::string VulkanHppGenerator::generateUniqueTypes( std::string const & parentType,
std::set<std::string> const & childrenTypes ) const
{
std::string childrenTraits;
for ( auto const & childType : childrenTypes )
{
auto handleIt = m_handles.find( childType );
assert( handleIt != m_handles.end() );
std::string type = stripPrefix( childType, "Vk" );
auto [enter, leave] = generateProtection( handleIt->first, !handleIt->second.alias.empty() );
std::string aliasHandle;
if ( !handleIt->second.alias.empty() )
{
static const std::string aliasHandleTemplate =
R"( using Unique${aliasType} = UniqueHandle<${type}, VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>;
)";
aliasHandle += replaceWithMap(
aliasHandleTemplate, { { "aliasType", stripPrefix( handleIt->second.alias, "Vk" ) }, { "type", type } } );
}
static const std::string traitsTemplate = R"(${enter} template <typename Dispatch>
class UniqueHandleTraits<${type}, Dispatch>
{
public:
using deleter = ${deleterType}${deleterAction}<${deleterParent}${deleterPool}, Dispatch>;
};
using Unique${type} = UniqueHandle<${type}, VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>;
${aliasHandle}${leave})";
childrenTraits += replaceWithMap(
traitsTemplate,
{ { "aliasHandle", aliasHandle },
{ "deleterAction", ( handleIt->second.deleteCommand.substr( 2, 4 ) == "Free" ) ? "Free" : "Destroy" },
{ "deleterParent", parentType.empty() ? "NoParent" : stripPrefix( parentType, "Vk" ) },
{ "deleterPool",
handleIt->second.deletePool.empty() ? "" : ", " + stripPrefix( handleIt->second.deletePool, "Vk" ) },
{ "deleterType", handleIt->second.deletePool.empty() ? "Object" : "Pool" },
{ "enter", enter },
{ "leave", leave },
{ "type", type } } );
}
static const std::string uniqueTypeTemplate = R"(
#ifndef VULKAN_HPP_NO_SMART_HANDLE
${parentClass}${childrenTraits}#endif /*VULKAN_HPP_NO_SMART_HANDLE*/
)";
return replaceWithMap(
uniqueTypeTemplate,
{ { "childrenTraits", childrenTraits },
{ "parentClass", parentType.empty() ? "" : ( " class " + stripPrefix( parentType, "Vk" ) + ";\n" ) } } );
}
std::string VulkanHppGenerator::generateVectorSizeCheck( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
std::map<size_t, std::vector<size_t>> const & countToVectorMap,
std::set<size_t> const & skippedParams ) const
{
std::string str;
std::string const assertTemplate =
" VULKAN_HPP_ASSERT( ${zeroSizeCheck}${firstVectorName}.size() == ${secondVectorName}.size() );";
std::string const throwTemplate =
R"#( if ( ${zeroSizeCheck}${firstVectorName}.size() != ${secondVectorName}.size() )
{
throw LogicError( VULKAN_HPP_NAMESPACE_STRING "::${className}::${commandName}: ${firstVectorName}.size() != ${secondVectorName}.size()" );
})#";
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string assertions, throws;
for ( auto const & cvm : countToVectorMap )
{
assert( !commandData.params[cvm.second[0]].optional );
size_t defaultStartIndex = determineDefaultStartIndex( commandData.params, skippedParams );
std::string firstVectorName = startLowerCase( stripPrefix( commandData.params[cvm.second[0]].name, "p" ) );
for ( size_t i = 1; i < cvm.second.size(); i++ )
{
std::string secondVectorName = startLowerCase( stripPrefix( commandData.params[cvm.second[i]].name, "p" ) );
bool withZeroSizeCheck = commandData.params[cvm.second[i]].optional && ( defaultStartIndex <= cvm.second[i] );
assertions +=
replaceWithMap( assertTemplate,
{ { "firstVectorName", firstVectorName },
{ "secondVectorName", secondVectorName },
{ "zeroSizeCheck", withZeroSizeCheck ? ( secondVectorName + ".empty() || " ) : "" } } );
throws +=
replaceWithMap( throwTemplate,
{ { "firstVectorName", firstVectorName },
{ "className", stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "secondVectorName", secondVectorName },
{ "zeroSizeCheck", withZeroSizeCheck ? ( "!" + secondVectorName + ".empty() && " ) : "" } } );
if ( i + 1 < cvm.second.size() )
{
assertions += "\n";
throws += "\n";
}
}
}
std::string const sizeCheckTemplate =
R"#(
#ifdef VULKAN_HPP_NO_EXCEPTIONS
${assertions}
#else
${throws}
#endif /*VULKAN_HPP_NO_EXCEPTIONS*/
)#";
str = replaceWithMap( sizeCheckTemplate, { { "assertions", assertions }, { "throws", throws } } );
return str;
}
std::pair<std::string, std::string>
VulkanHppGenerator::getParentTypeAndName( std::pair<std::string, HandleData> const & handle ) const
{
std::string parentType, parentName;
if ( handle.first == "VkInstance" )
{
parentType = "Context";
parentName = "context";
}
else
{
bool skip = skipLeadingGrandParent( handle );
assert( !handle.second.constructorIts.empty() &&
( ( skip ? 1u : 0u ) < handle.second.constructorIts.front()->second.params.size() ) );
auto const & param = handle.second.constructorIts.front()->second.params[skip ? 1 : 0];
assert( isHandleType( param.type.type ) && param.type.isValue() );
parentType = stripPrefix( param.type.type, "Vk" );
parentName = param.name;
}
return std::make_pair( parentType, parentName );
}
std::string VulkanHppGenerator::getPlatform( std::string const & title ) const
{
if ( m_features.find( title ) == m_features.end() )
{
auto extensionIt = m_extensions.find( title );
assert( extensionIt != m_extensions.end() );
return extensionIt->second.platform;
}
return "";
}
std::pair<std::string, std::string> VulkanHppGenerator::getPoolTypeAndName( std::string const & type ) const
{
auto structIt = m_structures.find( type );
assert( structIt != m_structures.end() );
auto memberIt = std::find_if( structIt->second.members.begin(),
structIt->second.members.end(),
[]( MemberData const & md ) { return md.name.find( "Pool" ) != std::string::npos; } );
assert( memberIt != structIt->second.members.end() );
assert( std::find_if( std::next( memberIt ),
structIt->second.members.end(),
[]( MemberData const & md )
{ return md.name.find( "Pool" ) != std::string::npos; } ) == structIt->second.members.end() );
return std::make_pair( memberIt->type.type, memberIt->name );
}
std::string VulkanHppGenerator::getVectorSize( std::vector<ParamData> const & params,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex ) const
{
std::vector<std::string> lenParts = tokenize( params[returnParamIndex].len, "->" );
switch ( lenParts.size() )
{
case 1:
{
std::string const & len = lenParts[0];
size_t lenIdx = std::distance(
params.begin(),
std::find_if( params.begin(), params.end(), [&len]( ParamData const & pd ) { return pd.name == len; } ) );
assert( lenIdx < params.size() );
auto lenVectorParamIt =
std::find_if( vectorParamIndices.begin(),
vectorParamIndices.end(),
[&lenIdx]( std::pair<size_t, size_t> const & vpi ) { return vpi.second == lenIdx; } );
return ( lenVectorParamIt == vectorParamIndices.end() )
? lenParts[0]
: ( startLowerCase( stripPrefix( params[lenVectorParamIt->first].name, "p" ) ) + ".size()" );
}
break;
case 2: return startLowerCase( stripPrefix( lenParts[0], "p" ) ) + "." + lenParts[1]; break;
default: assert( false ); return "";
}
}
bool VulkanHppGenerator::hasParentHandle( std::string const & handle, std::string const & parent ) const
{
std::string candidate = handle;
while ( !candidate.empty() )
{
auto const & handleIt = m_handles.find( candidate );
assert( handleIt != m_handles.end() );
if ( handleIt->second.parent == parent )
{
return true;
}
else
{
candidate = handleIt->second.parent;
}
}
return false;
}
bool VulkanHppGenerator::isDeviceCommand( CommandData const & commandData ) const
{
return !commandData.handle.empty() && !commandData.params.empty() &&
( m_handles.find( commandData.params[0].type.type ) != m_handles.end() ) &&
( commandData.params[0].type.type != "VkInstance" ) &&
( commandData.params[0].type.type != "VkPhysicalDevice" );
}
bool VulkanHppGenerator::isHandleType( std::string const & type ) const
{
if ( beginsWith( type, "Vk" ) )
{
auto it = m_handles.find( type );
if ( it == m_handles.end() )
{
it = std::find_if( m_handles.begin(),
m_handles.end(),
[&type]( std::pair<std::string, HandleData> const & hd ) { return hd.second.alias == type; } );
}
return ( it != m_handles.end() );
}
return false;
}
bool VulkanHppGenerator::isLenByStructMember( std::string const & name, std::vector<ParamData> const & params ) const
{
// check if name specifies a member of a struct
std::vector<std::string> nameParts = tokenize( name, "->" );
if ( nameParts.size() == 1 )
{
// older versions of vk.xml used the notation parameter::member
nameParts = tokenize( name, "::" );
}
if ( nameParts.size() == 2 )
{
auto paramIt = std::find_if(
params.begin(), params.end(), [&n = nameParts[0]]( ParamData const & pd ) { return pd.name == n; } );
if ( paramIt != params.end() )
{
#if !defined( NDEBUG )
auto structureIt = m_structures.find( paramIt->type.type );
assert( structureIt != m_structures.end() );
assert( std::find_if( structureIt->second.members.begin(),
structureIt->second.members.end(),
[&n = nameParts[1]]( MemberData const & md )
{ return md.name == n; } ) != structureIt->second.members.end() );
#endif
return true;
}
}
return false;
}
bool VulkanHppGenerator::isLenByStructMember( std::string const & name, ParamData const & param ) const
{
// check if name specifies a member of a struct
std::vector<std::string> nameParts = tokenize( name, "->" );
if ( nameParts.size() == 1 )
{
// older versions of vk.xml used the notation parameter::member
nameParts = tokenize( name, "::" );
}
if ( ( nameParts.size() == 2 ) && ( nameParts[0] == param.name ) )
{
#if !defined( NDEBUG )
auto structureIt = m_structures.find( param.type.type );
assert( structureIt != m_structures.end() );
assert( std::find_if( structureIt->second.members.begin(),
structureIt->second.members.end(),
[&n = nameParts[1]]( MemberData const & md )
{ return md.name == n; } ) != structureIt->second.members.end() );
#endif
return true;
}
return false;
}
bool VulkanHppGenerator::isMultiSuccessCodeConstructor(
std::vector<std::map<std::string, CommandData>::const_iterator> const & constructorIts ) const
{
bool ok = !constructorIts.empty();
if ( ok )
{
auto constructorIt = constructorIts.begin();
ok = ( 2 < ( *constructorIt )->second.successCodes.size() ) ||
( ( ( *constructorIt )->second.successCodes.size() == 2 ) &&
( ( *constructorIt )->second.successCodes[1] != "VK_INCOMPLETE" ) );
#if !defined( NDEBUG )
for ( constructorIt = std::next( constructorIt ); constructorIt != constructorIts.end(); ++constructorIt )
{
assert( ok == ( 2 < ( *constructorIt )->second.successCodes.size() ) ||
( ( ( *constructorIt )->second.successCodes.size() == 2 ) &&
( ( *constructorIt )->second.successCodes[1] != "VK_INCOMPLETE" ) ) );
}
#endif
}
return ok;
}
bool VulkanHppGenerator::isParam( std::string const & name, std::vector<ParamData> const & params ) const
{
return std::find_if( params.begin(), params.end(), [&name]( ParamData const & pd ) { return pd.name == name; } ) !=
params.end();
}
bool VulkanHppGenerator::isStructureChainAnchor( std::string const & type ) const
{
if ( beginsWith( type, "Vk" ) )
{
auto it = m_structures.find( type );
if ( it == m_structures.end() )
{
auto aliasIt = m_structureAliases.find( type );
if ( aliasIt != m_structureAliases.end() )
{
it = m_structures.find( aliasIt->second.alias );
}
}
if ( it != m_structures.end() )
{
return m_extendedStructs.find( it->first ) != m_extendedStructs.end();
}
}
return false;
}
std::pair<bool, std::map<size_t, std::vector<size_t>>>
VulkanHppGenerator::needsVectorSizeCheck( std::map<size_t, size_t> const & vectorParamIndices ) const
{
std::map<size_t, std::vector<size_t>> countToVectorMap;
for ( auto const & vpi : vectorParamIndices )
{
if ( vpi.second != INVALID_INDEX )
{
countToVectorMap[vpi.second].push_back( vpi.first );
}
}
return std::make_pair( std::find_if( countToVectorMap.begin(),
countToVectorMap.end(),
[]( auto const & cvm )
{ return 1 < cvm.second.size(); } ) != countToVectorMap.end(),
countToVectorMap );
}
void VulkanHppGenerator::readCommands( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), {}, { { "comment", {} } } );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, { { "command", false } } );
for ( auto child : children )
{
assert( child->Value() == std::string( "command" ) );
readCommandsCommand( child );
}
}
void VulkanHppGenerator::readCommandsCommand( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
if ( attributes.find( "alias" ) != attributes.end() )
{
// for command aliases, create a copy of the aliased command
checkAttributes( line,
attributes,
{},
{
{ "alias", {} },
{ "name", {} },
} );
checkElements( line, getChildElements( element ), {} );
std::string alias, name;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "alias" )
{
alias = attribute.second;
}
else if ( attribute.first == "name" )
{
name = attribute.second;
check( beginsWith( name, "vk" ), line, "name <" + name + "> should begin with <vk>" );
}
}
auto commandIt = m_commands.find( alias );
check( commandIt != m_commands.end(), line, "missing command <" + alias + ">" );
CommandData commandData = commandIt->second;
commandData.alias = alias;
commandData.xmlLine = line;
addCommand( name, commandData );
}
else
{
checkAttributes( line,
attributes,
{},
{ { "cmdbufferlevel", { "primary", "secondary" } },
{ "comment", {} },
{ "errorcodes", {} },
{ "queues", { "compute", "decode", "encode", "graphics", "sparse_binding", "transfer" } },
{ "renderpass", { "both", "inside", "outside" } },
{ "successcodes", {} } } );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, { { "param", false }, { "proto", true } }, { "implicitexternsyncparams" } );
CommandData commandData( line );
for ( auto const & attribute : attributes )
{
if ( attribute.first == "errorcodes" )
{
commandData.errorCodes = tokenize( attribute.second, "," );
// errorCodes are checked in checkCorrectness after complete reading
}
else if ( attribute.first == "successcodes" )
{
commandData.successCodes = tokenize( attribute.second, "," );
// successCodes are checked in checkCorrectness after complete reading
}
}
std::string name;
for ( auto child : children )
{
std::string value = child->Value();
if ( value == "param" )
{
commandData.params.push_back( readCommandsCommandParam( child, commandData.params ) );
}
else if ( value == "proto" )
{
std::tie( name, commandData.returnType ) = readCommandsCommandProto( child );
}
}
assert( !name.empty() );
check( ( commandData.returnType == "VkResult" ) || commandData.errorCodes.empty(),
line,
"command <" + name + "> does not return a VkResult but specifies errorcodes" );
check( ( commandData.returnType == "VkResult" ) || commandData.successCodes.empty(),
line,
"command <" + name + "> does not return a VkResult but specifies successcodes" );
registerDeleter( name, std::make_pair( name, commandData ) );
addCommand( name, commandData );
}
}
VulkanHppGenerator::ParamData VulkanHppGenerator::readCommandsCommandParam( tinyxml2::XMLElement const * element,
std::vector<ParamData> const & params )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line,
attributes,
{},
{ { "externsync", {} },
{ "len", {} },
{ "noautovalidity", { "true" } },
{ "objecttype", { "objectType" } },
{ "optional", { "false", "true" } } } );
ParamData paramData( line );
for ( auto attribute : attributes )
{
if ( attribute.first == "len" )
{
paramData.len = attribute.second;
check( ( paramData.len == "null-terminated" ) || isParam( paramData.len, params ) ||
isLenByStructMember( paramData.len, params ),
line,
"command param len <" + paramData.len + "> is not recognized as a valid len value" );
}
else if ( attribute.first == "optional" )
{
paramData.optional = ( attribute.second == "true" );
}
}
NameData nameData;
std::tie( nameData, paramData.type ) = readNameAndType( element );
check( m_types.find( paramData.type.type ) != m_types.end(), line, "unknown type <" + paramData.type.type + ">" );
check( paramData.type.prefix.empty() || ( paramData.type.prefix == "const" ) ||
( paramData.type.prefix == "const struct" ) || ( paramData.type.prefix == "struct" ),
line,
"unexpected type prefix <" + paramData.type.prefix + ">" );
check( paramData.type.postfix.empty() || ( paramData.type.postfix == "*" ) || ( paramData.type.postfix == "**" ) ||
( paramData.type.postfix == "* const *" ),
line,
"unexpected type postfix <" + paramData.type.postfix + ">" );
check( std::find_if( params.begin(),
params.end(),
[&name = nameData.name]( ParamData const & pd ) { return pd.name == name; } ) == params.end(),
line,
"command param <" + nameData.name + "> already used" );
paramData.name = nameData.name;
paramData.arraySizes = nameData.arraySizes;
return paramData;
}
std::pair<std::string, std::string> VulkanHppGenerator::readCommandsCommandProto( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), {}, {} );
auto [nameData, typeInfo] = readNameAndType( element );
check( beginsWith( nameData.name, "vk" ), line, "name <" + nameData.name + "> does not begin with <vk>" );
check( nameData.arraySizes.empty(), line, "name <" + nameData.name + "> with unsupported arraySizes" );
check( m_types.find( typeInfo.type ) != m_types.end(), line, "unknown type <" + typeInfo.type + ">" );
check( typeInfo.prefix.empty(), line, "unexpected type prefix <" + typeInfo.prefix + ">" );
check( typeInfo.postfix.empty(), line, "unexpected type postfix <" + typeInfo.postfix + ">" );
check(
m_commands.find( nameData.name ) == m_commands.end(), line, "command <" + nameData.name + "> already specified" );
return std::make_pair( nameData.name, typeInfo.type );
}
void VulkanHppGenerator::readEnums( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line,
attributes,
{ { "name", {} } },
{ { "bitwidth", { "64" } }, { "comment", {} }, { "type", { "bitmask", "enum" } } } );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
std::string bitwidth, name, type;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "bitwidth" )
{
bitwidth = attribute.second;
}
else if ( attribute.first == "name" )
{
name = attribute.second;
}
else if ( attribute.first == "type" )
{
type = attribute.second;
}
}
assert( !name.empty() );
if ( name == "API Constants" )
{
checkElements( line, children, { { "enum", false } }, {} );
for ( auto const & child : children )
{
readEnumsConstant( child );
}
}
else
{
checkElements( line, children, {}, { "comment", "enum", "unused" } );
check( !type.empty(), line, "enum without type" );
// get the EnumData entry in enum map
std::map<std::string, EnumData>::iterator enumIt = m_enums.find( name );
if ( enumIt == m_enums.end() )
{
enumIt = std::find_if( m_enums.begin(),
m_enums.end(),
[&name]( std::pair<std::string, EnumData> const & enumData )
{ return enumData.second.alias == name; } );
}
check( enumIt != m_enums.end(), line, "enum <" + name + "> is not listed as enum in the types section" );
check( enumIt->second.values.empty(), line, "enum <" + name + "> already holds values" );
// mark it as a bitmask, if it is one
bool bitmask = ( type == "bitmask" );
if ( bitmask )
{
check( name.find( "FlagBits" ) != std::string::npos, line, "bitmask <" + name + "> does not contain <FlagBits>" );
}
enumIt->second.isBitmask = bitmask;
enumIt->second.bitwidth = bitwidth;
// read the names of the enum values
for ( auto child : children )
{
std::string value = child->Value();
if ( value == "comment" )
{
readComment( child );
}
else if ( value == "enum" )
{
readEnumsEnum( child, enumIt );
}
}
}
}
void VulkanHppGenerator::readEnumsConstant( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes(
line, attributes, { { "name", {} } }, { { "alias", {} }, { "comment", {} }, { "type", {} }, { "value", {} } } );
checkElements( line, getChildElements( element ), {} );
std::string alias, name, value;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "alias" )
{
check( m_constants.find( attribute.second ) != m_constants.end(),
line,
"unknown enum constant alias <" + attribute.second + ">" );
alias = attribute.second;
}
else if ( attribute.first == "name" )
{
check( m_constants.find( attribute.second ) == m_constants.end(),
line,
"already specified enum constant <" + attribute.second + ">" );
name = attribute.second;
}
else if ( attribute.first == "value" )
{
check( !attribute.second.empty(), line, "value of enum constant is empty" );
value = attribute.second;
}
}
check( alias.empty() != value.empty(), line, "for enum <" + name + "> either alias or value need to be specified" );
m_constants[name] = alias.empty() ? value : m_constants[alias];
}
void VulkanHppGenerator::readEnumsEnum( tinyxml2::XMLElement const * element,
std::map<std::string, EnumData>::iterator enumIt )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
if ( attributes.find( "alias" ) != attributes.end() )
{
checkAttributes( line, attributes, { { "alias", {} }, { "name", {} } }, { { "comment", {} } } );
checkElements( line, getChildElements( element ), {} );
std::string alias, bitpos, name, value;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "alias" )
{
alias = attribute.second;
}
else if ( attribute.first == "name" )
{
name = attribute.second;
}
}
assert( !name.empty() );
enumIt->second.addEnumAlias( line, name, alias );
}
else
{
checkAttributes(
line,
attributes,
{ { "name", {} } },
{ { "bitpos", {} }, { "comment", {} }, { "protect", { "VK_ENABLE_BETA_EXTENSIONS" } }, { "value", {} } } );
checkElements( line, getChildElements( element ), {} );
std::string alias, bitpos, name, protect, value;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "bitpos" )
{
bitpos = attribute.second;
}
else if ( attribute.first == "name" )
{
name = attribute.second;
}
else if ( attribute.first == "protect" )
{
protect = attribute.second;
}
else if ( attribute.first == "value" )
{
value = attribute.second;
}
}
std::string prefix = generateEnumSuffixes( enumIt->first, enumIt->second.isBitmask, m_tags ).first;
check( beginsWith( name, prefix ),
line,
"encountered enum value <" + name + "> that does not begin with expected prefix <" + prefix + ">" );
check( bitpos.empty() ^ value.empty(), line, "invalid set of attributes for enum <" + name + ">" );
enumIt->second.addEnumValue( line, name, protect, !bitpos.empty(), "" );
}
}
std::string VulkanHppGenerator::readComment( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), {}, {} );
checkElements( line, getChildElements( element ), {} );
return element->GetText();
}
void VulkanHppGenerator::readExtensions( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), { { "comment", {} } }, {} );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, { { "extension", false } } );
for ( auto child : children )
{
assert( child->Value() == std::string( "extension" ) );
readExtensionsExtension( child );
}
}
void VulkanHppGenerator::readExtensionsExtension( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
auto it = attributes.find( "supported" );
check( it != attributes.end(), line, "Missing attribute <supported> for extension!" );
if ( it->second == "disabled" )
{
checkElements( line, children, {}, { "require" } );
// kick out all the disabled stuff we've read before !!
for ( auto const & child : children )
{
assert( child->Value() == std::string( "require" ) );
readExtensionsExtensionDisabledRequire( child );
}
}
else
{
checkAttributes( line,
attributes,
{ { "name", {} }, { "number", {} }, { "supported", { "disabled", "enabled", "vulkan" } } },
{ { "author", {} },
{ "comment", {} },
{ "contact", {} },
{ "deprecatedby", {} },
{ "obsoletedby", {} },
{ "platform", {} },
{ "promotedto", {} },
{ "provisional", { "true" } },
{ "requires", {} },
{ "requiresCore", {} },
{ "sortorder", { "1" } },
{ "specialuse", { "cadsupport", "d3demulation", "debugging", "devtools", "glemulation" } },
{ "type", { "device", "instance" } } } );
checkElements( line, children, { { "require", false } } );
std::string deprecatedBy, name, number, obsoletedBy, platform, promotedTo, supported;
std::vector<std::string> requirements;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "deprecatedby" )
{
deprecatedBy = attribute.second;
}
else if ( attribute.first == "name" )
{
name = attribute.second;
}
else if ( attribute.first == "number" )
{
number = attribute.second;
}
else if ( attribute.first == "obsoletedby" )
{
obsoletedBy = attribute.second;
}
else if ( attribute.first == "platform" )
{
platform = attribute.second;
check( m_platforms.find( platform ) != m_platforms.end(), line, "unknown platform <" + platform + ">" );
}
else if ( attribute.first == "promotedto" )
{
promotedTo = attribute.second;
}
else if ( attribute.first == "provisional" )
{
if ( platform.empty() )
{
// for now, having the attribute provisional="true" implies attribute platform="provisional" to get stuff
// protected by VK_ENABLE_BETA_EXTENSIONS
platform = "provisional";
}
check(
platform == "provisional",
line,
"while attribute <provisional> is set to \"true\", attribute <platform> is not set to \"provisional\" but to \"" +
platform + "\"" );
}
else if ( attribute.first == "requires" )
{
requirements = tokenize( attribute.second, "," );
}
else if ( attribute.first == "requiresCore" )
{
std::string const & requiresCore = attribute.second;
check( std::find_if( m_features.begin(),
m_features.end(),
[&requiresCore]( std::pair<std::string, FeatureData> const & feature )
{ return feature.second.number == requiresCore; } ) != m_features.end(),
line,
"unknown feature number <" + attribute.second + ">" );
}
else if ( attribute.first == "supported" )
{
supported = attribute.second;
assert( supported != "disabled" );
}
}
auto pitb = m_extensions.insert(
std::make_pair( name, ExtensionData( line, deprecatedBy, number, obsoletedBy, platform, promotedTo ) ) );
check( pitb.second, line, "already encountered extension <" + name + ">" );
for ( auto const & r : requirements )
{
check( pitb.first->second.requiresAttribute.insert( r ).second,
line,
"required extension <" + r + "> already listed" );
}
// extract the tag from the name, which is supposed to look like VK_<tag>_<other>
size_t tagStart = name.find( '_' );
check( tagStart != std::string::npos, line, "name <" + name + "> is missing an underscore '_'" );
size_t tagEnd = name.find( '_', tagStart + 1 );
check( tagEnd != std::string::npos, line, "name <" + name + "> is missing an underscore '_'" );
std::string tag = name.substr( tagStart + 1, tagEnd - tagStart - 1 );
check( m_tags.find( tag ) != m_tags.end(), line, "name <" + name + "> is using an unknown tag <" + tag + ">" );
for ( auto child : children )
{
assert( child->Value() == std::string( "require" ) );
readExtensionsExtensionRequire( child, pitb.first );
}
}
}
void VulkanHppGenerator::readExtensionsExtensionDisabledRequire( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), {}, {} );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, { { "enum", false } }, { "command", "comment", "type" } );
for ( auto child : children )
{
std::string value = child->Value();
if ( value == "command" )
{
readExtensionsExtensionDisabledRequireCommand( child );
}
else if ( value == "comment" )
{
readComment( child );
}
else if ( value == "enum" )
{
// just skip enums of disabled extensions
}
else
{
assert( value == "type" );
readExtensionsExtensionDisabledRequireType( child );
}
}
}
void VulkanHppGenerator::readExtensionsExtensionDisabledRequireCommand( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, { { "name", {} } }, {} );
checkElements( line, getChildElements( element ), {} );
std::string name = attributes.find( "name" )->second;
// first unlink the command from its class
auto commandIt = m_commands.find( name );
if ( commandIt != m_commands.end() )
{
auto handleIt = m_handles.find( commandIt->second.handle );
check( handleIt != m_handles.end(), line, "cannot find handle corresponding to command <" + name + ">" );
handleIt->second.commands.erase( commandIt->first );
// then erase the command from the command list
m_commands.erase( commandIt );
}
}
void VulkanHppGenerator::readExtensionsExtensionDisabledRequireType( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, { { "name", {} } }, {} );
checkElements( line, getChildElements( element ), {} );
std::string name = attributes.find( "name" )->second;
auto typeIt = m_types.find( name );
if ( typeIt != m_types.end() )
{
switch ( typeIt->second.category )
{
case TypeCategory::Bitmask:
{
auto bitmasksIt = m_bitmasks.find( name );
check( bitmasksIt != m_bitmasks.end(), line, "trying to remove unknown bitmask <" + name + ">" );
check( bitmasksIt->second.alias.empty(),
line,
"trying to remove disabled bitmask <" + name + "> which has alias <" + bitmasksIt->second.alias +
">" );
m_bitmasks.erase( bitmasksIt );
}
break;
case TypeCategory::Enum:
{
auto enumIt = m_enums.find( name );
check( enumIt != m_enums.end(), line, "trying to remove unknown enum <" + name + ">" );
check( enumIt->second.alias.empty(),
line,
"trying to remove disabled enum <" + name + "> which has alias <" + enumIt->second.alias + ">" );
m_enums.erase( enumIt );
}
break;
case TypeCategory::Struct:
{
auto structIt = m_structures.find( name );
check( structIt != m_structures.end(), line, "trying to remove unknown struct <" + name + ">" );
auto inverseAliasIt = m_structureAliasesInverse.find( name );
if ( inverseAliasIt != m_structureAliasesInverse.end() )
{
check( false,
line,
"trying to remove disabled structure <" + name + "> which has " +
std::to_string( inverseAliasIt->second.size() ) + "aliases" );
}
m_structures.erase( structIt );
}
break;
default:
check( false,
line,
"trying to remove <" + name + "> of unhandled type <" + toString( typeIt->second.category ) + ">" );
break;
}
}
}
void VulkanHppGenerator::readExtensionsExtensionRequire( tinyxml2::XMLElement const * element,
std::map<std::string, ExtensionData>::iterator extensionIt )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, {}, { { "extension", {} }, { "feature", {} } } );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, {}, { "command", "comment", "enum", "type" } );
std::string requireTitle;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "extension" )
{
assert( requireTitle.empty() );
requireTitle = attribute.second;
check( std::find_if( extensionIt->second.requireData.begin(),
extensionIt->second.requireData.end(),
[&requireTitle]( RequireData const & rd )
{ return rd.title == requireTitle; } ) == extensionIt->second.requireData.end(),
line,
"required extension <" + requireTitle + "> already listed" );
}
else
{
assert( attribute.first == "feature" );
check(
m_features.find( attribute.second ) != m_features.end(), line, "unknown feature <" + attribute.second + ">" );
assert( requireTitle.empty() );
requireTitle = attribute.second;
}
}
RequireData requireData( line, requireTitle );
bool requireDataEmpty = true;
for ( auto child : children )
{
std::string value = child->Value();
if ( value == "command" )
{
readExtensionsExtensionRequireCommand( child, extensionIt->first, requireData );
requireDataEmpty = false;
}
else if ( value == "comment" )
{
readComment( child );
}
else if ( value == "enum" )
{
readRequireEnum( child, extensionIt->first );
}
else if ( value == "type" )
{
readExtensionsExtensionRequireType( child, extensionIt->first, requireData );
requireDataEmpty = false;
}
}
if ( !requireDataEmpty )
{
extensionIt->second.requireData.push_back( requireData );
}
}
void VulkanHppGenerator::readExtensionsExtensionRequireCommand( tinyxml2::XMLElement const * element,
std::string const & extensionName,
RequireData & requireData )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, { { "name", {} } }, {} );
checkElements( line, getChildElements( element ), {} );
std::string name;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "name" )
{
name = attribute.second;
}
}
assert( !name.empty() );
// mark this command be part of this extension
auto commandIt = m_commands.find( name );
check( commandIt != m_commands.end(),
line,
"command <" + name + "> marked as required in extension <" + extensionName +
"> was not listed before as a command!" );
if ( commandIt->second.referencedIn.empty() )
{
commandIt->second.referencedIn = extensionName;
}
else
{
check( getPlatform( commandIt->second.referencedIn ) == getPlatform( extensionName ),
line,
"command <" + name + "> is referenced in extensions <" + commandIt->second.referencedIn + "> and <" +
extensionName + "> and thus protected by different platforms <" +
getPlatform( commandIt->second.referencedIn ) + "> and <" + getPlatform( extensionName ) + ">!" );
}
assert( std::find( requireData.commands.begin(), requireData.commands.end(), name ) == requireData.commands.end() );
requireData.commands.push_back( name );
}
void VulkanHppGenerator::readExtensionsExtensionRequireType( tinyxml2::XMLElement const * element,
std::string const & extensionName,
RequireData & requireData )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, { { "name", {} } }, { { "comment", {} } } );
checkElements( line, getChildElements( element ), {} );
std::string name;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "name" )
{
name = attribute.second;
}
}
assert( !name.empty() );
auto typeIt = m_types.find( name );
check( typeIt != m_types.end(), line, "failed to find required type <" + name + ">" );
if ( typeIt->second.referencedIn.empty() )
{
typeIt->second.referencedIn = extensionName;
assert( std::find( requireData.types.begin(), requireData.types.end(), name ) == requireData.types.end() );
requireData.types.push_back( name );
}
else
{
check( getPlatform( typeIt->second.referencedIn ) == getPlatform( extensionName ),
line,
"type <" + name + "> is referenced in extensions <" + typeIt->second.referencedIn + "> and <" +
extensionName + "> and thus protected by different platforms <" +
getPlatform( typeIt->second.referencedIn ) + "> and <" + getPlatform( extensionName ) + ">!" );
}
}
void VulkanHppGenerator::readFeature( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes(
line, attributes, { { "api", { "vulkan" } }, { "comment", {} }, { "name", {} }, { "number", {} } }, {} );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, { { "require", false } } );
std::string name, number, modifiedNumber;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "name" )
{
name = attribute.second;
}
else if ( attribute.first == "number" )
{
number = attribute.second;
modifiedNumber = number;
std::replace( modifiedNumber.begin(), modifiedNumber.end(), '.', '_' );
}
}
assert( !name.empty() && !number.empty() );
check( name == "VK_VERSION_" + modifiedNumber, line, "unexpected formatting of name <" + name + ">" );
check( m_features.find( name ) == m_features.end(), line, "already specified feature <" + name + ">" );
auto featureIt = m_features.insert( std::make_pair( name, number ) ).first;
for ( auto child : children )
{
assert( child->Value() == std::string( "require" ) );
readFeatureRequire( child, featureIt );
}
}
void VulkanHppGenerator::readFeatureRequire( tinyxml2::XMLElement const * element,
std::map<std::string, FeatureData>::iterator featureIt )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), {}, { { "comment", {} } } );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, {}, { "command", "comment", "enum", "type" } );
RequireData requireData( line, "" );
bool requireDataEmpty = true;
for ( auto child : children )
{
std::string value = child->Value();
if ( value == "command" )
{
readFeatureRequireCommand( child, featureIt, requireData );
requireDataEmpty = false;
}
else if ( value == "comment" )
{
readComment( child );
}
else if ( value == "enum" )
{
readRequireEnum( child, "" );
}
else if ( value == "type" )
{
readFeatureRequireType( child, featureIt, requireData );
requireDataEmpty = false;
}
}
if ( !requireDataEmpty )
{
featureIt->second.requireData.push_back( requireData );
}
}
void VulkanHppGenerator::readFeatureRequireCommand( tinyxml2::XMLElement const * element,
std::map<std::string, FeatureData>::iterator featureIt,
RequireData & requireData )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, {}, { { "name", {} } } );
std::string name = attributes.find( "name" )->second;
auto commandIt = m_commands.find( name );
check( commandIt != m_commands.end(), line, "feature requires unknown command <" + name + ">" );
check( commandIt->second.referencedIn.empty(),
line,
"command <" + name + "> already listed with feature <" + commandIt->second.referencedIn + ">" );
commandIt->second.referencedIn = featureIt->first;
assert( std::find( requireData.commands.begin(), requireData.commands.end(), name ) == requireData.commands.end() );
requireData.commands.push_back( name );
}
void VulkanHppGenerator::readFeatureRequireType( tinyxml2::XMLElement const * element,
std::map<std::string, FeatureData>::iterator featureIt,
RequireData & requireData )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, {}, { { "comment", {} }, { "name", {} } } );
checkElements( line, getChildElements( element ), {} );
std::string name = attributes.find( "name" )->second;
auto requireTypeIt = std::find_if(
requireData.types.begin(), requireData.types.end(), [&name]( std::string const & type ) { return type == name; } );
check( requireTypeIt == requireData.types.end(), line, "type <" + name + "> already listed for this feature!" );
// some types are in fact includes (like vk_platform) or defines (like VK_API_VERSION)
if ( ( m_defines.find( name ) == m_defines.end() ) && ( m_includes.find( name ) == m_includes.end() ) )
{
auto typeIt = m_types.find( name );
check( typeIt != m_types.end(), line, "feature requires unknown type <" + name + ">" );
check( typeIt->second.referencedIn.empty() || ( typeIt->second.referencedIn == featureIt->first ),
line,
"type <" + name + "> already listed on feature <" + typeIt->second.referencedIn + ">" );
typeIt->second.referencedIn = featureIt->first;
requireData.types.push_back( name );
}
}
std::pair<VulkanHppGenerator::NameData, VulkanHppGenerator::TypeInfo>
VulkanHppGenerator::readNameAndType( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, { { "name", true } }, { { "type" } } );
NameData nameData;
TypeInfo typeInfo;
for ( auto child : children )
{
line = child->GetLineNum();
checkAttributes( line, getAttributes( child ), {}, {} );
checkElements( line, getChildElements( child ), {} );
std::string value = child->Value();
if ( value == "name" )
{
nameData.name = child->GetText();
std::string bitCount;
std::tie( nameData.arraySizes, bitCount ) = readModifiers( child->NextSibling() );
check( bitCount.empty(), line, "name <" + nameData.name + "> with unsupported bitCount <" + bitCount + ">" );
}
else if ( value == "type" )
{
typeInfo = readTypeInfo( child );
}
}
return std::make_pair( nameData, typeInfo );
}
void VulkanHppGenerator::readPlatforms( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), { { "comment", {} } }, {} );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, { { "platform", false } } );
for ( auto child : children )
{
readPlatformsPlatform( child );
}
}
void VulkanHppGenerator::readPlatformsPlatform( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, { { "comment", {} }, { "name", {} }, { "protect", {} } }, {} );
checkElements( line, getChildElements( element ), {} );
std::string name, protect;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "name" )
{
name = attribute.second;
check( !name.empty(), line, "attribute <name> is empty" );
}
else if ( attribute.first == "protect" )
{
protect = attribute.second;
check( !protect.empty(), line, "attribute <protect> is empty" );
}
}
assert( !name.empty() && !protect.empty() );
check( std::find_if( m_platforms.begin(),
m_platforms.end(),
[&protect]( std::pair<std::string, PlatformData> const & p )
{ return p.second.protect == protect; } ) == m_platforms.end(),
line,
"platform protect <" + protect + "> already specified" );
check( m_platforms.insert( std::make_pair( name, PlatformData( protect ) ) ).second,
line,
"platform name <" + name + "> already specified" );
}
void VulkanHppGenerator::readRegistry( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), {}, {} );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line,
children,
{ { "commands", true },
{ "comment", false },
{ "enums", false },
{ "extensions", true },
{ "feature", false },
{ "platforms", true },
{ "spirvcapabilities", true },
{ "spirvextensions", true },
{ "tags", true },
{ "types", true } } );
for ( auto child : children )
{
const std::string value = child->Value();
if ( value == "commands" )
{
readCommands( child );
}
else if ( value == "comment" )
{
std::string comment = readComment( child );
if ( comment.find( "\nCopyright" ) == 0 )
{
setVulkanLicenseHeader( child->GetLineNum(), comment );
}
}
else if ( value == "enums" )
{
readEnums( child );
}
else if ( value == "extensions" )
{
readExtensions( child );
}
else if ( value == "feature" )
{
readFeature( child );
}
else if ( value == "platforms" )
{
readPlatforms( child );
}
else if ( value == "spirvcapabilities" )
{
readSPIRVCapabilities( child );
}
else if ( value == "spirvextensions" )
{
readSPIRVExtensions( child );
}
else if ( value == "tags" )
{
readTags( child );
}
else if ( value == "types" )
{
readTypes( child );
}
}
}
void VulkanHppGenerator::readRequireEnum( tinyxml2::XMLElement const * element, std::string const & extensionName )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
if ( attributes.find( "alias" ) != attributes.end() )
{
checkAttributes( line, attributes, { { "alias", {} }, { "name", {} } }, { { "comment", {} }, { "extends", {} } } );
checkElements( line, getChildElements( element ), {} );
std::string alias, bitpos, name, extends, extnumber, offset, value;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "alias" )
{
alias = attribute.second;
}
else if ( attribute.first == "extends" )
{
extends = attribute.second;
}
else if ( attribute.first == "name" )
{
name = attribute.second;
}
}
if ( !extends.empty() )
{
auto enumIt = m_enums.find( extends );
check( enumIt != m_enums.end(), line, "feature extends unknown enum <" + extends + ">" );
// add this enum name to the list of aliases
enumIt->second.addEnumAlias( line, name, alias );
}
}
else
{
checkAttributes( line,
attributes,
{ { "name", {} } },
{ { "bitpos", {} },
{ "comment", {} },
{ "extends", {} },
{ "dir", { "-" } },
{ "extnumber", {} },
{ "offset", {} },
{ "protect", { "VK_ENABLE_BETA_EXTENSIONS" } },
{ "value", {} } } );
checkElements( line, getChildElements( element ), {} );
std::string bitpos, name, extends, extnumber, offset, protect, value;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "bitpos" )
{
bitpos = attribute.second;
}
else if ( attribute.first == "extends" )
{
extends = attribute.second;
}
else if ( attribute.first == "name" )
{
name = attribute.second;
}
else if ( attribute.first == "offset" )
{
offset = attribute.second;
}
else if ( attribute.first == "protect" )
{
protect = attribute.second;
}
else if ( attribute.first == "value" )
{
value = attribute.second;
}
}
if ( !extends.empty() )
{
auto enumIt = m_enums.find( extends );
check( enumIt != m_enums.end(), line, "feature extends unknown enum <" + extends + ">" );
// add this enum name to the list of values
check( bitpos.empty() + offset.empty() + value.empty() == 2,
line,
"exactly one out of bitpos = <" + bitpos + ">, offset = <" + offset + ">, and value = <" + value +
"> are supposed to be empty" );
enumIt->second.addEnumValue( element->GetLineNum(), name, protect, !bitpos.empty(), extensionName );
}
else if ( value.empty() )
{
check( m_constants.find( name ) != m_constants.end(), line, "unknown required enum <" + name + ">" );
}
}
}
void VulkanHppGenerator::readSPIRVCapabilities( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, { { "comment", {} } }, {} );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, {}, { "spirvcapability" } );
for ( auto child : children )
{
assert( child->Value() == std::string( "spirvcapability" ) );
readSPIRVCapabilitiesSPIRVCapability( child );
}
}
void VulkanHppGenerator::readSPIRVCapabilitiesSPIRVCapability( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, { { "name", {} } }, {} );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, {}, { "enable" } );
for ( auto child : children )
{
assert( child->Value() == std::string( "enable" ) );
readSPIRVCapabilitiesSPIRVCapabilityEnable( child );
}
}
void VulkanHppGenerator::readSPIRVCapabilitiesSPIRVCapabilityEnable( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkElements( line, getChildElements( element ), {}, {} );
if ( attributes.find( "extension" ) != attributes.end() )
{
readSPIRVCapabilitiesSPIRVCapabilityEnableExtension( line, attributes );
}
else if ( attributes.find( "property" ) != attributes.end() )
{
readSPIRVCapabilitiesSPIRVCapabilityEnableProperty( line, attributes );
}
else if ( attributes.find( "struct" ) != attributes.end() )
{
readSPIRVCapabilitiesSPIRVCapabilityEnableStruct( line, attributes );
}
else if ( attributes.find( "version" ) != attributes.end() )
{
readSPIRVCapabilitiesSPIRVCapabilityEnableVersion( line, attributes );
}
else
{
check( false, line, "unknown set of attributes specified for SPIR-V capability" );
}
}
void VulkanHppGenerator::readSPIRVCapabilitiesSPIRVCapabilityEnableExtension(
int xmlLine, std::map<std::string, std::string> const & attributes )
{
checkAttributes( xmlLine, attributes, { { "extension", {} } }, {} );
check( attributes.size() == 1,
xmlLine,
"unexpected attributes in addition to <extension> specified for SPIR-V capability" );
for ( auto const & attribute : attributes )
{
assert( attribute.first == "extension" );
check( m_extensions.find( attribute.second ) != m_extensions.end(),
xmlLine,
"unknown extension <" + attribute.second + "> specified for SPIR-V capability" );
}
}
void VulkanHppGenerator::readSPIRVCapabilitiesSPIRVCapabilityEnableProperty(
int xmlLine, std::map<std::string, std::string> const & attributes )
{
checkAttributes(
xmlLine, attributes, { { "member", {} }, { "property", {} }, { "requires", {} }, { "value", {} } }, {} );
std::string member, property, value;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "member" )
{
member = attribute.second;
}
else if ( attribute.first == "property" )
{
property = attribute.second;
}
if ( attribute.first == "requires" )
{
std::vector<std::string>
requires = tokenize( attribute.second, "," );
for ( auto const & r : requires )
{
check( ( m_features.find( r ) != m_features.end() ) || ( m_extensions.find( r ) != m_extensions.end() ),
xmlLine,
"unknown requires <" + r + "> specified for SPIR-V capability" );
}
}
else if ( attribute.first == "value" )
{
value = attribute.second;
}
}
assert( !member.empty() && !property.empty() && !value.empty() );
auto propertyIt = m_structures.find( property );
check(
propertyIt != m_structures.end(), xmlLine, "unknown property <" + property + "> specified for SPIR-V capability" );
auto memberIt = std::find_if( propertyIt->second.members.begin(),
propertyIt->second.members.end(),
[&member]( MemberData const & md ) { return md.name == member; } );
check( memberIt != propertyIt->second.members.end(),
xmlLine,
"unknown member <" + member + "> specified for SPIR-V capability" );
if ( memberIt->type.type == "VkBool32" )
{
check( ( value == "VK_FALSE" ) || ( value == "VK_TRUE" ),
xmlLine,
"unknown value <" + value + "> for boolean member <" + member + "> specified for SPIR-V capability" );
}
else
{
auto bitmaskIt = m_bitmasks.find( memberIt->type.type );
check( bitmaskIt != m_bitmasks.end(),
xmlLine,
"attribute member = <" + member + "> specified for SPIR-V capability is not a bitmask" );
assert( !bitmaskIt->second.requirements.empty() );
auto enumIt = m_enums.find( bitmaskIt->second.requirements );
check( enumIt != m_enums.end(),
xmlLine,
"attribute member = <" + member + "> specified for SPIR-V capability requires an unknown enum <" +
bitmaskIt->second.requirements + ">" );
auto valueIt = std::find_if( enumIt->second.values.begin(),
enumIt->second.values.end(),
[&value]( EnumValueData const & evd ) { return evd.name == value; } );
check( valueIt != enumIt->second.values.end(),
xmlLine,
"unknown attribute value = <" + value + "> specified for SPIR-V capability" );
}
}
void VulkanHppGenerator::readSPIRVCapabilitiesSPIRVCapabilityEnableStruct(
int xmlLine, std::map<std::string, std::string> const & attributes )
{
checkAttributes(
xmlLine, attributes, { { "feature", {} }, { "struct", {} } }, { { "alias", {} }, { "requires", {} } } );
for ( auto const & attribute : attributes )
{
if ( attribute.first == "requires" )
{
std::vector<std::string>
requires = tokenize( attribute.second, "," );
for ( auto const & r : requires )
{
check( ( m_features.find( r ) != m_features.end() ) || ( m_extensions.find( r ) != m_extensions.end() ),
xmlLine,
"unknown requires <" + r + "> specified for SPIR-V capability" );
}
}
else if ( attribute.first == "struct" )
{
check( ( m_structures.find( attribute.second ) != m_structures.end() ) ||
( m_structureAliases.find( attribute.second ) != m_structureAliases.end() ),
xmlLine,
"unknown structure <" + attribute.second + "> specified for SPIR-V capability" );
check( attributes.find( "feature" ) != attributes.end(),
xmlLine,
"missing feature attribute for SPIR-V capability specified with struct <" + attribute.second + ">" );
}
else
{
assert( ( attribute.first == "alias" ) || ( attribute.first == "feature" ) );
}
}
}
void VulkanHppGenerator::readSPIRVCapabilitiesSPIRVCapabilityEnableVersion(
int xmlLine, std::map<std::string, std::string> const & attributes )
{
checkAttributes( xmlLine, attributes, { { "version", {} } }, {} );
check(
attributes.size() == 1, xmlLine, "unexpected attributes in addition to <version> specified for SPIR-V capability" );
for ( auto const & attribute : attributes )
{
assert( attribute.first == "version" );
std::string feature = attribute.second;
if ( beginsWith( feature, "VK_API_" ) )
{
feature.erase( 3, 4 ); // remove "API_" from the version -> VK_VERSION_x_y
}
check( beginsWith( feature, "VK_VERSION_" ),
xmlLine,
"unknown version <" + attribute.second + "> specified for SPIR-V capability" );
check( m_features.find( feature ) != m_features.end(),
xmlLine,
"unknown version <" + attribute.second + "> specified for SPIR-V capability" );
}
}
void VulkanHppGenerator::readSPIRVExtensions( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, { { "comment", {} } }, {} );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, {}, { "spirvextension" } );
for ( auto child : children )
{
assert( child->Value() == std::string( "spirvextension" ) );
readSPIRVExtensionsExtension( child );
}
}
void VulkanHppGenerator::readSPIRVExtensionsExtension( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, { { "name", {} } }, {} );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, {}, { "enable" } );
for ( auto child : children )
{
assert( child->Value() == std::string( "enable" ) );
readSPIRVExtensionsExtensionEnable( child );
}
}
void VulkanHppGenerator::readSPIRVExtensionsExtensionEnable( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, {}, { { "extension", {} }, { "version", {} } } );
checkElements( line, getChildElements( element ), {}, {} );
check( !attributes.empty(), line, "no version or extension specified for SPIR-V extension" );
for ( auto const & attribute : attributes )
{
if ( attribute.first == "extension" )
{
check( m_extensions.find( attribute.second ) != m_extensions.end(),
line,
"unknown extension <" + attribute.second + "> specified for SPIR-V extension" );
}
else
{
assert( attribute.first == "version" );
std::string feature = attribute.second;
if ( beginsWith( feature, "VK_API_" ) )
{
feature.erase( 3, 4 ); // remove "API_" from the version -> VK_VERSION_x_y
}
check( beginsWith( feature, "VK_VERSION_" ),
line,
"unknown version <" + attribute.second + "> specified for SPIR-V extension" );
check( m_features.find( feature ) != m_features.end(),
line,
"unknown version <" + attribute.second + "> specified for SPIR-V extension" );
}
}
}
void VulkanHppGenerator::readTags( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), { { "comment", {} } }, {} );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, { { "tag", false } } );
for ( auto child : children )
{
readTagsTag( child );
}
}
void VulkanHppGenerator::readTagsTag( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line, attributes, { { "author", {} }, { "contact", {} }, { "name", {} } }, {} );
checkElements( line, getChildElements( element ), {} );
for ( auto const & attribute : attributes )
{
if ( attribute.first == "name" )
{
check( m_tags.find( attribute.second ) == m_tags.end(),
line,
"tag named <" + attribute.second + "> has already been specified" );
m_tags.insert( attribute.second );
}
else
{
check( ( attribute.first == "author" ) || ( attribute.first == "contact" ),
line,
"unknown attribute <" + attribute.first + ">" );
}
}
}
void VulkanHppGenerator::readTypes( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), { { "comment", {} } }, {} );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, { { "comment", false }, { "type", false } } );
for ( auto child : children )
{
std::string value = child->Value();
if ( value == "comment" )
{
readComment( child );
}
else
{
assert( value == "type" );
readTypesType( child );
}
}
}
void VulkanHppGenerator::readTypesType( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
auto categoryIt = attributes.find( "category" );
if ( categoryIt != attributes.end() )
{
if ( categoryIt->second == "basetype" )
{
readTypesTypeBasetype( element, attributes );
}
else if ( categoryIt->second == "bitmask" )
{
readTypesTypeBitmask( element, attributes );
}
else if ( categoryIt->second == "define" )
{
readTypesTypeDefine( element, attributes );
}
else if ( categoryIt->second == "enum" )
{
readTypesTypeEnum( element, attributes );
}
else if ( categoryIt->second == "funcpointer" )
{
readTypesTypeFuncpointer( element, attributes );
}
else if ( categoryIt->second == "handle" )
{
readTypesTypeHandle( element, attributes );
}
else if ( categoryIt->second == "include" )
{
readTypesTypeInclude( element, attributes );
}
else if ( categoryIt->second == "struct" )
{
readTypesTypeStruct( element, false, attributes );
}
else
{
check(
categoryIt->second == "union", element->GetLineNum(), "unknown type category <" + categoryIt->second + ">" );
readTypesTypeStruct( element, true, attributes );
}
}
else
{
auto requiresIt = attributes.find( "requires" );
if ( requiresIt != attributes.end() )
{
readTypesTypeRequires( element, attributes );
}
else
{
check( ( attributes.size() == 1 ) && ( attributes.begin()->first == "name" ) &&
( attributes.begin()->second == "int" ),
line,
"unknown type" );
check( m_types.insert( std::make_pair( attributes.begin()->second, TypeCategory::Unknown ) ).second,
line,
"type <" + attributes.begin()->second + "> already specified" );
}
}
}
void VulkanHppGenerator::readTypesTypeBasetype( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
checkAttributes( line, attributes, { { "category", { "basetype" } } }, {} );
NameData nameData;
TypeInfo typeInfo;
std::tie( nameData, typeInfo ) = readNameAndType( element );
if ( typeInfo.prefix == "typedef" )
{
// remove redundant typeInfo.prefix "typedef"
typeInfo.prefix.clear();
}
check( nameData.arraySizes.empty(), line, "name <" + nameData.name + "> with unsupported arraySizes" );
check( typeInfo.prefix.empty(), line, "unexpected type prefix <" + typeInfo.prefix + ">" );
check( typeInfo.postfix.empty() || ( typeInfo.postfix == "*" ),
line,
"unexpected type postfix <" + typeInfo.postfix + ">" );
if ( !typeInfo.type.empty() )
{
check( m_baseTypes.insert( std::make_pair( nameData.name, BaseTypeData( typeInfo, line ) ) ).second,
line,
"basetype <" + nameData.name + "> already specified" );
}
check( m_types.insert( std::make_pair( nameData.name, TypeCategory::BaseType ) ).second,
line,
"basetype <" + nameData.name + "> already specified as a type" );
}
void VulkanHppGenerator::readTypesTypeBitmask( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
auto aliasIt = attributes.find( "alias" );
if ( aliasIt != attributes.end() )
{
checkAttributes( line, attributes, { { "alias", {} }, { "category", { "bitmask" } }, { "name", {} } }, {} );
checkElements( line, getChildElements( element ), {} );
std::string alias, name;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "alias" )
{
alias = attribute.second;
}
else if ( attribute.first == "name" )
{
name = attribute.second;
}
}
auto bitmasksIt = m_bitmasks.find( alias );
check( bitmasksIt != m_bitmasks.end(), line, "missing alias <" + alias + ">." );
check( bitmasksIt->second.alias.empty(),
line,
"alias for bitmask <" + bitmasksIt->first + "> already specified as <" + bitmasksIt->second.alias + ">" );
bitmasksIt->second.alias = name;
check( m_types.insert( std::make_pair( name, TypeCategory::Bitmask ) ).second,
line,
"aliased bitmask <" + name + "> already specified as a type" );
}
else
{
checkAttributes( line, attributes, { { "category", { "bitmask" } } }, { { "bitvalues", {} }, { "requires", {} } } );
std::string bitvalues, requirements;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "bitvalues" )
{
bitvalues = attribute.second;
}
else if ( attribute.first == "requires" )
{
requirements = attribute.second;
}
}
NameData nameData;
TypeInfo typeInfo;
std::tie( nameData, typeInfo ) = readNameAndType( element );
check( beginsWith( nameData.name, "Vk" ), line, "name <" + nameData.name + "> does not begin with <Vk>" );
check( nameData.arraySizes.empty(), line, "name <" + nameData.name + "> with unsupported arraySizes" );
warn( ( typeInfo.type == "VkFlags" ) || ( typeInfo.type == "VkFlags64" ),
line,
"unexpected bitmask type <" + typeInfo.type + ">" );
check( typeInfo.prefix == "typedef", line, "unexpected type prefix <" + typeInfo.prefix + ">" );
check( typeInfo.postfix.empty(), line, "unexpected type postfix <" + typeInfo.postfix + ">" );
check(
bitvalues.empty() || requirements.empty(), line, "attributes <bitvalues> and <requires> are both specified" );
check( ( typeInfo.type != "VkFlags64" ) || !bitvalues.empty(),
line,
"bitmask of type <VkFlags64> needs attribute bitvalues to be set" );
if ( !bitvalues.empty() )
{
requirements = bitvalues;
}
m_bitmasks.insert( std::make_pair( nameData.name, BitmaskData( requirements, typeInfo.type, line ) ) );
check( m_types.insert( std::make_pair( nameData.name, TypeCategory::Bitmask ) ).second,
line,
"bitmask <" + nameData.name + "> already specified as a type" );
}
}
void VulkanHppGenerator::readTypesTypeDefine( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
checkAttributes( line, attributes, { { "category", { "define" } } }, { { "name", {} }, { "requires", {} } } );
std::string name;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "name" )
{
name = attribute.second;
}
else if ( attribute.first == "requires" )
{
check( m_defines.find( attribute.second ) != m_defines.end(),
line,
"using undefined requires <" + attribute.second + ">" );
}
}
if ( !name.empty() )
{
check( !element->FirstChildElement(), line, "unknown formatting of type category=define name <" + name + ">" );
check( element->LastChild() && element->LastChild()->ToText() && element->LastChild()->ToText()->Value(),
line,
"unknown formatting of type category=define named <" + name + ">" );
// filter out the check for the different types of VK_DEFINE_NON_DISPATCHABLE_HANDLE
if ( name == "VK_USE_64_BIT_PTR_DEFINES" )
{
m_typesafeCheck = "#if ( VK_USE_64_BIT_PTR_DEFINES == 1 )";
}
else if ( ( name == "VK_DEFINE_NON_DISPATCHABLE_HANDLE" ) && ( m_typesafeCheck.empty() ) )
{
std::string text = element->LastChild()->ToText()->Value();
size_t start = text.find( "#if defined(__LP64__)" );
check( start != std::string::npos, line, "unexpected text in type category=define named <" + name + ">" );
size_t end = text.find_first_of( "\r\n", start + 1 );
check( end != std::string::npos, line, "unexpected text in type category=define named <" + name + ">" );
m_typesafeCheck = text.substr( start, end - start );
}
}
else if ( element->GetText() )
{
std::string text = element->GetText();
if ( ( text.find( "class" ) != std::string::npos ) || ( text.find( "struct" ) != std::string::npos ) )
{
// here are a couple of structs as defines, which really are types!
tinyxml2::XMLElement const * child = element->FirstChildElement();
check( child && ( strcmp( child->Value(), "name" ) == 0 ) && child->GetText(),
line,
"unexpected formatting of type category=define" );
name = child->GetText();
check( m_types.insert( std::make_pair( name, TypeCategory::Define ) ).second,
line,
"type <" + name + "> has already been speficied" );
}
else
{
tinyxml2::XMLElement const * child = element->FirstChildElement();
check( child && !child->FirstAttribute() && ( strcmp( child->Value(), "name" ) == 0 ) && child->GetText(),
line,
"unknown formatting of type category define" );
name = trim( child->GetText() );
if ( name == "VK_HEADER_VERSION" )
{
m_version = trimEnd( element->LastChild()->ToText()->Value() );
}
// ignore all the other defines
warn( !child->NextSiblingElement() ||
( child->NextSiblingElement() && !child->NextSiblingElement()->FirstAttribute() &&
( strcmp( child->NextSiblingElement()->Value(), "type" ) == 0 ) &&
!child->NextSiblingElement()->NextSiblingElement() ),
line,
"unknown formatting of type category define" );
}
}
assert( !name.empty() );
check( m_defines.insert( name ).second, line, "define <" + name + "> has already been specified" );
}
void VulkanHppGenerator::readTypesTypeEnum( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
checkAttributes( line, attributes, { { "category", { "enum" } }, { "name", {} } }, { { "alias", {} } } );
checkElements( line, getChildElements( element ), {} );
std::string alias, name;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "alias" )
{
alias = attribute.second;
check( !alias.empty(), line, "enum with empty alias" );
}
else if ( attribute.first == "name" )
{
name = attribute.second;
check( !name.empty(), line, "enum with empty name" );
check( m_enums.find( name ) == m_enums.end(), line, "enum <" + name + "> already specified" );
}
}
assert( !name.empty() );
if ( alias.empty() )
{
check( m_enums.insert( std::make_pair( name, EnumData( line ) ) ).second,
line,
"enum <" + name + "> already specified" );
}
else
{
auto enumIt = m_enums.find( alias );
check( enumIt != m_enums.end(), line, "enum with unknown alias <" + alias + ">" );
check( enumIt->second.alias.empty(),
line,
"enum <" + enumIt->first + "> already has an alias <" + enumIt->second.alias + ">" );
enumIt->second.alias = name;
}
check( m_types.insert( std::make_pair( name, TypeCategory::Enum ) ).second,
line,
"enum <" + name + "> already specified as a type" );
}
void VulkanHppGenerator::readTypesTypeFuncpointer( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
checkAttributes( line, attributes, { { "category", { "funcpointer" } } }, { { "requires", {} } } );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, { { "name", true } }, { "type" } );
std::string requirements;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "requires" )
{
requirements = attribute.second;
}
}
auto funcPointerIt = m_funcPointers.end();
std::set<std::string> argumentNames;
for ( auto const & child : children )
{
std::string value = child->Value();
int childLine = child->GetLineNum();
if ( value == "name" )
{
std::string name = child->GetText();
check( !name.empty(), childLine, "funcpointer with empty name" );
check( m_funcPointers.find( name ) == m_funcPointers.end(),
childLine,
"funcpointer <" + name + "> already specified" );
funcPointerIt = m_funcPointers.insert( std::make_pair( name, FuncPointerData( requirements, line ) ) ).first;
check( m_types.insert( std::make_pair( name, TypeCategory::FuncPointer ) ).second,
childLine,
"funcpointer <" + name + "> already specified as a type" );
}
else if ( value == "type" )
{
assert( funcPointerIt != m_funcPointers.end() );
std::string type = child->GetText();
funcPointerIt->second.arguments.push_back( { type, childLine } );
auto sibling = child->NextSibling();
char const * siblingValue = sibling->Value();
assert( siblingValue != nullptr );
std::string argumentName = siblingValue;
argumentName = argumentName.substr( argumentName.find_first_not_of( "* " ) );
argumentName = argumentName.substr( 0, argumentName.find_first_of( ",)" ) );
check( argumentNames.insert( argumentName ).second,
childLine,
"funcpointer <" + funcPointerIt->first + "> already has an argument named <" + argumentName + ">" );
}
}
}
void VulkanHppGenerator::readTypesTypeHandle( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
auto aliasIt = attributes.find( "alias" );
if ( aliasIt != attributes.end() )
{
checkAttributes( line, attributes, { { "alias", {} }, { "category", { "handle" } }, { "name", {} } }, {} );
checkElements( line, getChildElements( element ), {} );
auto handlesIt = m_handles.find( aliasIt->second );
check( handlesIt != m_handles.end(), line, "using unspecified alias <" + aliasIt->second + ">." );
check( handlesIt->second.alias.empty(),
line,
"handle <" + handlesIt->first + "> already has an alias <" + handlesIt->second.alias + ">" );
handlesIt->second.alias = attributes.find( "name" )->second;
check( m_types.insert( std::make_pair( handlesIt->second.alias, TypeCategory::Handle ) ).second,
line,
"handle alias <" + handlesIt->second.alias + "> already specified as a type" );
}
else
{
checkAttributes( line, attributes, { { "category", { "handle" } } }, { { "objtypeenum", {} }, { "parent", {} } } );
std::string objTypeEnum, parent;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "objtypeenum" )
{
objTypeEnum = attribute.second;
}
else if ( attribute.first == "parent" )
{
parent = attribute.second;
}
}
NameData nameData;
TypeInfo typeInfo;
std::tie( nameData, typeInfo ) = readNameAndType( element );
check( beginsWith( nameData.name, "Vk" ), line, "name <" + nameData.name + "> does not begin with <Vk>" );
check( nameData.arraySizes.empty(), line, "name <" + nameData.name + "> with unsupported arraySizes" );
check( ( typeInfo.type == "VK_DEFINE_HANDLE" ) || ( typeInfo.type == "VK_DEFINE_NON_DISPATCHABLE_HANDLE" ),
line,
"handle with invalid type <" + typeInfo.type + ">" );
check( typeInfo.prefix.empty(), line, "unexpected type prefix <" + typeInfo.prefix + ">" );
check( typeInfo.postfix == "(", line, "unexpected type postfix <" + typeInfo.postfix + ">" );
check( !objTypeEnum.empty(), line, "handle <" + nameData.name + "> does not specify attribute \"objtypeenum\"" );
check(
parent.find( ',' ) == std::string::npos, line, "mulitple parents specified for handle <" + nameData.name + ">" );
check( m_handles.insert( std::make_pair( nameData.name, HandleData( parent, objTypeEnum, line ) ) ).second,
line,
"handle <" + nameData.name + "> already specified" );
check( m_types.insert( std::make_pair( nameData.name, TypeCategory::Handle ) ).second,
line,
"handle <" + nameData.name + "> already specified as a type" );
}
}
void VulkanHppGenerator::readTypesTypeInclude( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
checkAttributes( line, attributes, { { "category", { "include" } }, { "name", {} } }, {} );
checkElements( line, getChildElements( element ), {} );
std::string name = attributes.find( "name" )->second;
check( m_includes.insert( name ).second, element->GetLineNum(), "include named <" + name + "> already specified" );
}
void VulkanHppGenerator::readTypesTypeRequires( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
checkAttributes( line, attributes, { { "name", {} }, { "requires", {} } }, {} );
checkElements( line, getChildElements( element ), {} );
for ( auto attribute : attributes )
{
if ( attribute.first == "name" )
{
check( m_types.insert( std::make_pair( attribute.second, TypeCategory::Requires ) ).second,
line,
"type named <" + attribute.second + "> already specified" );
}
else
{
assert( attribute.first == "requires" );
check( m_includes.find( attribute.second ) != m_includes.end(),
line,
"type requires unknown include <" + attribute.second + ">" );
}
}
}
void VulkanHppGenerator::readTypesTypeStruct( tinyxml2::XMLElement const * element,
bool isUnion,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
if ( attributes.find( "alias" ) != attributes.end() )
{
checkAttributes( line, attributes, { { "alias", {} }, { "category", { "struct" } }, { "name", {} } }, {} );
checkElements( line, getChildElements( element ), {}, {} );
std::string alias, name;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "alias" )
{
alias = attribute.second;
}
else if ( attribute.first == "name" )
{
name = attribute.second;
}
}
check( m_structureAliases.insert( std::make_pair( name, StructureAliasData( alias, line ) ) ).second,
line,
"structure alias <" + name + "> already used" );
check( m_structureAliasesInverse[alias].insert( name ).second,
line,
"structure alias <" + name + "> already used with structure <" + alias + ">" );
check( m_types.insert( std::make_pair( name, TypeCategory::Struct ) ).second,
line,
"struct <" + name + "> already specified as a type" );
}
else
{
checkAttributes( line,
attributes,
{ { "category", { isUnion ? "union" : "struct" } }, { "name", {} } },
{ { "allowduplicate", { "true" } },
{ "comment", {} },
{ "returnedonly", { "true" } },
{ "structextends", {} } } );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, {}, { "member", "comment" } );
std::string category, name;
std::vector<std::string> structExtends;
bool allowDuplicate = false;
bool returnedOnly = false;
for ( auto const & attribute : attributes )
{
if ( attribute.first == "allowduplicate" )
{
assert( attribute.second == "true" );
allowDuplicate = true;
}
else if ( attribute.first == "category" )
{
category = attribute.second;
}
else if ( attribute.first == "name" )
{
name = attribute.second;
}
else if ( attribute.first == "returnedonly" )
{
check(
attribute.second == "true", line, "unknown value for attribute returnedonly: <" + attribute.second + ">" );
returnedOnly = true;
}
else if ( attribute.first == "structextends" )
{
structExtends = tokenize( attribute.second, "," );
}
}
assert( !name.empty() );
// make this warn a check, as soon as vk.xml has been fixed on attribute "allowduplicate" !
warn( !allowDuplicate || !structExtends.empty(),
line,
"attribute <allowduplicate> is true, but no structures are listed in <structextends>" );
check( m_structures.find( name ) == m_structures.end(), line, "struct <" + name + "> already specfied" );
std::map<std::string, StructureData>::iterator it =
m_structures.insert( std::make_pair( name, StructureData( structExtends, line ) ) ).first;
it->second.allowDuplicate = allowDuplicate;
it->second.isUnion = isUnion;
it->second.returnedOnly = returnedOnly;
for ( auto child : children )
{
std::string value = child->Value();
if ( value == "comment" )
{
readComment( child );
}
else if ( value == "member" )
{
readTypesTypeStructMember( child, it->second.members, isUnion );
}
}
it->second.subStruct = determineSubStruct( *it );
// check if multiple structure members use the very same (not empty) len attribute
// Note: even though the arrays are not marked as optional, they still might be mutually exclusive (like in
// VkWriteDescriptorSet)! That is, there's not enough information available in vk.xml to decide on that, so we
// need this external knowledge!
static std::set<std::string> mutualExclusiveStructs = { "VkAccelerationStructureBuildGeometryInfoKHR",
"VkWriteDescriptorSet" };
static std::set<std::string> multipleLenStructs = { "VkImageConstraintsInfoFUCHSIA",
"VkIndirectCommandsLayoutTokenNV",
"VkPresentInfoKHR",
"VkSemaphoreWaitInfo",
"VkSubmitInfo",
"VkSubpassDescription",
"VkSubpassDescription2",
"VkWin32KeyedMutexAcquireReleaseInfoKHR",
"VkWin32KeyedMutexAcquireReleaseInfoNV" };
bool warned = false;
for ( auto m0It = it->second.members.begin(); !warned && ( m0It != it->second.members.end() ); ++m0It )
{
if ( !m0It->len.empty() && ( m0It->len.front() != "null-terminated" ) )
{
for ( auto m1It = std::next( m0It ); !warned && ( m1It != it->second.members.end() ); ++m1It )
{
if ( !m1It->len.empty() && ( m0It->len.front() == m1It->len.front() ) )
{
if ( mutualExclusiveStructs.find( it->first ) != mutualExclusiveStructs.end() )
{
it->second.mutualExclusiveLens = true;
}
else
{
warn(
multipleLenStructs.find( it->first ) != multipleLenStructs.end(),
line,
"Encountered structure <" + it->first +
"> with multiple members referencing the same member for len. Need to be checked if they are supposed to be mutually exclusive." );
warned = true;
}
}
}
}
}
m_extendedStructs.insert( structExtends.begin(), structExtends.end() );
check(
m_types.insert( std::make_pair( name, ( category == "struct" ) ? TypeCategory::Struct : TypeCategory::Union ) )
.second,
line,
"struct <" + name + "> already specified as a type" ); // log type and alias in m_types
}
}
void VulkanHppGenerator::readTypesTypeStructMember( tinyxml2::XMLElement const * element,
std::vector<MemberData> & members,
bool isUnion )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
checkAttributes( line,
attributes,
{},
{ { "altlen", {} },
{ "externsync", { "true" } },
{ "len", {} },
{ "limittype", { "bitmask", "max", "min", "noauto", "range", "struct" } },
{ "noautovalidity", { "true" } },
{ "objecttype", { "objectType" } },
{ "optional", { "false", "true" } },
{ "selection", {} },
{ "selector", {} },
{ "values", {} } } );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, { { "name", true }, { "type", true } }, { "comment", "enum" } );
MemberData memberData( line );
for ( auto child : children )
{
std::string value = child->Value();
if ( value == "enum" )
{
readTypesTypeStructMemberEnum( child, memberData );
}
else if ( value == "name" )
{
readTypesTypeStructMemberName( child, memberData, members );
}
else if ( value == "type" )
{
readTypesTypeStructMemberType( child, memberData );
}
}
for ( auto const & attribute : attributes )
{
if ( attribute.first == "altlen" )
{
assert( memberData.len.empty() );
memberData.len = tokenize( attribute.second, "," );
check( memberData.len.size() == 1,
line,
"member attribute <altlen> holds unknown number of data: " + std::to_string( memberData.len.size() ) );
check( altLens.find( memberData.len[0] ) != altLens.end(),
line,
"member attribute <altlen> holds unknown value <" + memberData.len[0] + ">" );
}
if ( attribute.first == "len" )
{
if ( memberData.len.empty() )
{
memberData.len = tokenize( attribute.second, "," );
check( !memberData.len.empty() && ( memberData.len.size() <= 2 ),
line,
"member attribute <len> holds unknown number of data: " + std::to_string( memberData.len.size() ) );
auto lenMember =
std::find_if( members.begin(),
members.end(),
[&memberData]( MemberData const & md ) { return ( md.name == memberData.len[0] ); } );
check( lenMember != members.end() || ( memberData.len[0] == "null-terminated" ),
line,
"member attribute <len> holds unknown value <" + memberData.len[0] + ">" );
if ( lenMember != members.end() )
{
check( lenMember->type.prefix.empty() && lenMember->type.postfix.empty(),
line,
"member attribute <len> references a member of unexpected type <" +
lenMember->type.compose( "VULKAN_HPP_NAMESPACE" ) + ">" );
}
if ( 1 < memberData.len.size() )
{
check( ( memberData.len[1] == "1" ) || ( memberData.len[1] == "null-terminated" ),
line,
"member attribute <len> holds unknown second value <" + memberData.len[1] + ">" );
}
}
}
else if ( attribute.first == "noautovalidity" )
{
memberData.noAutoValidity = ( attribute.second == "true" );
}
else if ( attribute.first == "optional" )
{
std::vector<std::string> optional = tokenize( attribute.second, "," );
memberData.optional.reserve( optional.size() );
for ( auto const & o : optional )
{
memberData.optional.push_back( o == "true" );
}
}
else if ( attribute.first == "selection" )
{
check( isUnion, line, "attribute <selection> is used with a non-union structure." );
memberData.selection = attribute.second;
}
else if ( attribute.first == "selector" )
{
memberData.selector = attribute.second;
std::string const & selector = memberData.selector;
auto selectorIt = std::find_if(
members.begin(), members.end(), [selector]( MemberData const & md ) { return md.name == selector; } );
check( selectorIt != members.end(), line, "member attribute <selector> holds unknown value <" + selector + ">" );
check( m_enums.find( selectorIt->type.type ) != m_enums.end(),
line,
"member attribute <selector> references unknown enum type <" + selectorIt->type.type + ">" );
}
else if ( attribute.first == "values" )
{
std::vector<std::string> values = tokenize( attribute.second, "," );
check( values.size() == 1,
line,
"attribute \"values\" holds multiple values <" + attribute.first +
">, but it's expected to hold just one" );
memberData.value = values[0];
}
}
members.push_back( memberData );
}
void VulkanHppGenerator::readTypesTypeStructMemberEnum( tinyxml2::XMLElement const * element, MemberData & memberData )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), {}, {} );
checkElements( line, getChildElements( element ), {}, {} );
std::string enumString = element->GetText();
check( element->PreviousSibling() && ( strcmp( element->PreviousSibling()->Value(), "[" ) == 0 ) &&
element->NextSibling() && ( strcmp( element->NextSibling()->Value(), "]" ) == 0 ),
line,
std::string( "structure member array specifiation is ill-formatted: <" ) + enumString + ">" );
memberData.arraySizes.push_back( enumString );
check( memberData.usedConstant.empty(), line, "struct already holds a constant <" + memberData.usedConstant + ">" );
memberData.usedConstant = enumString;
}
void VulkanHppGenerator::readTypesTypeStructMemberName( tinyxml2::XMLElement const * element,
MemberData & memberData,
std::vector<MemberData> const & members )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), {}, {} );
checkElements( line, getChildElements( element ), {}, {} );
std::string name = element->GetText();
check( std::find_if( members.begin(), members.end(), [&name]( MemberData const & md ) { return md.name == name; } ) ==
members.end(),
line,
"structure member name <" + name + "> already used" );
memberData.name = name;
std::tie( memberData.arraySizes, memberData.bitCount ) = readModifiers( element->NextSibling() );
}
void VulkanHppGenerator::readTypesTypeStructMemberType( tinyxml2::XMLElement const * element, MemberData & memberData )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), {}, {} );
checkElements( line, getChildElements( element ), {}, {} );
memberData.type = readTypeInfo( element );
}
VulkanHppGenerator::TypeInfo VulkanHppGenerator::readTypeInfo( tinyxml2::XMLElement const * element ) const
{
TypeInfo typeInfo;
tinyxml2::XMLNode const * previousSibling = element->PreviousSibling();
if ( previousSibling && previousSibling->ToText() )
{
typeInfo.prefix = trim( previousSibling->Value() );
}
typeInfo.type = element->GetText();
tinyxml2::XMLNode const * nextSibling = element->NextSibling();
if ( nextSibling && nextSibling->ToText() )
{
typeInfo.postfix = trimStars( trimEnd( nextSibling->Value() ) );
}
return typeInfo;
}
void VulkanHppGenerator::registerDeleter( std::string const & name,
std::pair<std::string, CommandData> const & commandData )
{
if ( ( commandData.first.substr( 2, 7 ) == "Destroy" ) || ( commandData.first.substr( 2, 4 ) == "Free" ) )
{
std::string key;
size_t valueIndex;
switch ( commandData.second.params.size() )
{
case 2:
case 3:
assert( commandData.second.params.back().type.type == "VkAllocationCallbacks" );
key = ( commandData.second.params.size() == 2 ) ? "" : commandData.second.params[0].type.type;
valueIndex = commandData.second.params.size() - 2;
break;
case 4:
key = commandData.second.params[0].type.type;
valueIndex = 3;
assert( m_handles.find( commandData.second.params[valueIndex].type.type ) != m_handles.end() );
m_handles.find( commandData.second.params[valueIndex].type.type )->second.deletePool =
commandData.second.params[1].type.type;
break;
default: assert( false ); valueIndex = 0;
}
auto keyHandleIt = m_handles.find( key );
assert( ( keyHandleIt != m_handles.end() ) &&
( keyHandleIt->second.childrenHandles.find( commandData.second.params[valueIndex].type.type ) ==
keyHandleIt->second.childrenHandles.end() ) );
keyHandleIt->second.childrenHandles.insert( commandData.second.params[valueIndex].type.type );
auto handleIt = m_handles.find( commandData.second.params[valueIndex].type.type );
assert( handleIt != m_handles.end() );
handleIt->second.deleteCommand = name;
}
}
void VulkanHppGenerator::rescheduleRAIIHandle( std::string & str,
std::pair<std::string, HandleData> const & handle,
std::set<std::string> & listedHandles,
std::set<std::string> const & specialFunctions ) const
{
listedHandles.insert( handle.first );
if ( !handle.second.parent.empty() && ( listedHandles.find( handle.second.parent ) == listedHandles.end() ) )
{
auto parentIt = m_handles.find( handle.second.parent );
assert( parentIt != m_handles.end() );
str += generateRAIIHandle( *parentIt, listedHandles, specialFunctions );
}
for ( auto constructorIt : handle.second.constructorIts )
{
for ( auto const & param : constructorIt->second.params )
{
auto handleIt = m_handles.find( param.type.type );
if ( handleIt != m_handles.end() && ( listedHandles.find( param.type.type ) == listedHandles.end() ) )
{
str += generateRAIIHandle( *handleIt, listedHandles, specialFunctions );
}
}
}
}
std::vector<std::string> VulkanHppGenerator::selectCommandsByHandle( std::vector<RequireData> const & requireData,
std::set<std::string> const & handleCommands,
std::set<std::string> & listedCommands ) const
{
std::vector<std::string> selectedCommands;
for ( auto const & require : requireData )
{
for ( auto const & command : require.commands )
{
if ( ( handleCommands.find( command ) != handleCommands.end() ) && listedCommands.insert( command ).second )
{
selectedCommands.push_back( command );
}
}
}
return selectedCommands;
}
void VulkanHppGenerator::setVulkanLicenseHeader( int line, std::string const & comment )
{
check( m_vulkanLicenseHeader.empty(), line, "second encounter of a Copyright comment" );
m_vulkanLicenseHeader = comment;
// replace any '\n' with "\n// "
for ( size_t pos = m_vulkanLicenseHeader.find( '\n' ); pos != std::string::npos;
pos = m_vulkanLicenseHeader.find( '\n', pos + 1 ) )
{
m_vulkanLicenseHeader.replace( pos, 1, "\n// " );
}
// replace any " \n" with "\n"
for ( size_t pos = m_vulkanLicenseHeader.find( " \n" ); pos != std::string::npos;
pos = m_vulkanLicenseHeader.find( " \n", pos ) )
{
m_vulkanLicenseHeader.replace( pos, 2, "\n" );
}
// remove any trailing spaces
m_vulkanLicenseHeader = trimEnd( m_vulkanLicenseHeader );
// and add a little message on our own
m_vulkanLicenseHeader += "\n\n// This header is generated from the Khronos Vulkan XML API Registry.";
m_vulkanLicenseHeader = trim( m_vulkanLicenseHeader ) + "\n";
}
bool VulkanHppGenerator::skipLeadingGrandParent( std::pair<std::string, HandleData> const & handle ) const
{
bool skip = false;
assert( !handle.second.constructorIts.empty() );
auto constructorIt = handle.second.constructorIts.begin();
if ( ( 1 < ( *constructorIt )->second.params.size() ) &&
isHandleType( ( *constructorIt )->second.params[0].type.type ) &&
( ( *constructorIt )->second.params[1].type.type == handle.second.parent ) )
{
auto parentIt = m_handles.find( handle.second.parent );
assert( parentIt != m_handles.end() );
skip = ( ( *constructorIt )->second.params[0].type.type == parentIt->second.parent );
#if !defined( NDEBUG )
for ( auto it = std::next( constructorIt ); it != handle.second.constructorIts.end(); ++it )
{
assert( ( *it )->second.params[0].type.type == ( *constructorIt )->second.params[0].type.type );
assert( !skip || ( ( *it )->second.params[1].type.type == ( *constructorIt )->second.params[1].type.type ) );
}
#endif
}
return skip;
}
std::string VulkanHppGenerator::toString( TypeCategory category )
{
switch ( category )
{
case TypeCategory::Bitmask: return "bitmask";
case TypeCategory::BaseType: return "basetype";
case TypeCategory::Define: return "define";
case TypeCategory::Enum: return "enum";
case TypeCategory::FuncPointer: return "funcpointer";
case TypeCategory::Handle: return "handle";
case TypeCategory::Requires: return "requires";
case TypeCategory::Struct: return "struct";
case TypeCategory::Union: return "union";
case TypeCategory::Unknown: return "unkown";
default: assert( false ); return "";
}
}
void VulkanHppGenerator::EnumData::addEnumAlias( int line, std::string const & name, std::string const & aliasName )
{
auto aliasIt = aliases.find( name );
check( ( aliasIt == aliases.end() ) || ( aliasIt->second.name == aliasName ),
line,
"enum alias <" + name + "> already listed for a different enum value" );
aliases.insert( std::make_pair( name, EnumAliasData( aliasName, line ) ) );
}
void VulkanHppGenerator::EnumData::addEnumValue(
int line, std::string const & valueName, std::string const & protect, bool bitpos, std::string const & extension )
{
auto valueIt = std::find_if(
values.begin(), values.end(), [&valueName]( EnumValueData const & evd ) { return evd.name == valueName; } );
if ( valueIt == values.end() )
{
values.emplace_back( line, valueName, protect, extension, bitpos );
}
}
std::string VulkanHppGenerator::TypeInfo::compose( std::string const & nameSpace ) const
{
return prefix + ( prefix.empty() ? "" : " " ) +
( nameSpace.empty()
? type
: ( ( ( type.substr( 0, 2 ) == "Vk" ) ? ( nameSpace + "::" ) : "" ) + stripPrefix( type, "Vk" ) ) ) +
( postfix.empty() ? "" : " " ) + postfix;
}
//
// VulkanHppGenerator local functions
//
bool beginsWith( std::string const & text, std::string const & prefix )
{
return prefix.empty() || text.substr( 0, prefix.length() ) == prefix;
}
bool endsWith( std::string const & text, std::string const & postfix )
{
return postfix.empty() ||
( ( postfix.length() <= text.length() ) && ( text.substr( text.length() - postfix.length() ) == postfix ) );
}
void check( bool condition, int line, std::string const & message )
{
if ( !condition )
{
throw std::runtime_error( "VulkanHppGenerator: Spec error on line " + std::to_string( line ) + ": " + message );
}
}
// check the validity of an attributes map
// line : the line in the xml file where the attributes are listed
// attributes : the map of name/value pairs of the encountered attributes
// required : the required attributes, with a set of allowed values per attribute
// optional : the optional attributes, with a set of allowed values per attribute
void checkAttributes( int line,
std::map<std::string, std::string> const & attributes,
std::map<std::string, std::set<std::string>> const & required,
std::map<std::string, std::set<std::string>> const & optional )
{
// check if all required attributes are included and if there is a set of allowed values, check if the actual value
// is part of that set
for ( auto const & r : required )
{
auto attributesIt = attributes.find( r.first );
check( attributesIt != attributes.end(), line, "missing attribute <" + r.first + ">" );
check( r.second.empty() || ( r.second.find( attributesIt->second ) != r.second.end() ),
line,
"unexpected attribute value <" + attributesIt->second + "> in attribute <" + r.first + ">" );
}
// check if all not required attributes or optional, and if there is a set of allowed values, check if the actual
// value is part of that set
for ( auto const & a : attributes )
{
if ( required.find( a.first ) == required.end() )
{
auto optionalIt = optional.find( a.first );
if ( optionalIt == optional.end() )
{
warn( false, line, "unknown attribute <" + a.first + ">" );
continue;
}
if ( !optionalIt->second.empty() )
{
std::vector<std::string> values = tokenize( a.second, "," );
for ( auto const & v : values )
{
warn( optionalIt->second.find( v ) != optionalIt->second.end(),
line,
"unexpected attribute value <" + v + "> in attribute <" + a.first + ">" );
}
}
}
}
}
void checkElements( int line,
std::vector<tinyxml2::XMLElement const *> const & elements,
std::map<std::string, bool> const & required,
std::set<std::string> const & optional )
{
std::map<std::string, size_t> encountered;
for ( auto const & e : elements )
{
std::string value = e->Value();
encountered[value]++;
warn( ( required.find( value ) != required.end() ) || ( optional.find( value ) != optional.end() ),
e->GetLineNum(),
"unknown element <" + value + ">" );
}
for ( auto const & r : required )
{
auto encounteredIt = encountered.find( r.first );
check( encounteredIt != encountered.end(), line, "missing required element <" + r.first + ">" );
// check: r.second (means: required excactly once) => (encouteredIt->second == 1)
check( !r.second || ( encounteredIt->second == 1 ),
line,
"required element <" + r.first + "> is supposed to be listed exactly once, but is listed " +
std::to_string( encounteredIt->second ) );
}
}
std::set<size_t> determineSingularParams( size_t returnParamIndex, std::map<size_t, size_t> const & vectorParamIndices )
{
auto returnVectorIt = vectorParamIndices.find( returnParamIndex );
assert( returnVectorIt != vectorParamIndices.end() );
std::set<size_t> singularParams;
singularParams.insert( returnVectorIt->second );
for ( auto const & vpi : vectorParamIndices )
{
if ( vpi.second == returnVectorIt->second )
{
singularParams.insert( vpi.first );
}
}
return singularParams;
}
std::string findTag( std::set<std::string> const & tags, std::string const & name, std::string const & postfix )
{
auto tagIt = std::find_if(
tags.begin(), tags.end(), [&name, &postfix]( std::string const & t ) { return endsWith( name, t + postfix ); } );
return ( tagIt != tags.end() ) ? *tagIt : "";
}
std::string generateCArraySizes( std::vector<std::string> const & sizes )
{
std::string arraySizes;
for ( auto const & s : sizes )
{
arraySizes += "[" + s + "]";
}
return arraySizes;
}
std::pair<std::string, std::string>
generateEnumSuffixes( std::string const & name, bool bitmask, std::set<std::string> const & tags )
{
std::string prefix, postfix;
if ( name == "VkResult" )
{
prefix = "VK_";
}
else
{
if ( bitmask )
{
// for a bitmask enum, start with "VK", cut off the trailing "FlagBits", and convert that name to upper case
// end that with "Bit"
size_t pos = name.find( "FlagBits" );
assert( pos != std::string::npos );
std::string shortenedName = name;
shortenedName.erase( pos, strlen( "FlagBits" ) );
std::string tag = findTag( tags, shortenedName );
prefix = toUpperCase( stripPostfix( shortenedName, tag ) ) + "_";
}
else
{
// for a non-bitmask enum, convert the name to upper case
prefix = toUpperCase( name ) + "_";
}
// if the enum name contains a tag move it from the prefix to the postfix to generate correct enum value names.
for ( auto const & tag : tags )
{
if ( endsWith( prefix, tag + "_" ) )
{
prefix.erase( prefix.length() - tag.length() - 1 );
postfix = "_" + tag;
break;
}
else if ( endsWith( name, tag ) )
{
postfix = "_" + tag;
break;
}
}
}
return std::make_pair( prefix, postfix );
}
std::string generateEnumValueName( std::string const & enumName,
std::string const & valueName,
bool bitmask,
std::set<std::string> const & tags )
{
std::string prefix, postfix;
std::tie( prefix, postfix ) = generateEnumSuffixes( enumName, bitmask, tags );
std::string tag = findTag( tags, valueName, "" );
if ( postfix == "_" + tag )
{
tag = findTag( tags, valueName, postfix );
}
std::string result = "e" + toCamelCase( stripPostfix( stripPrefix( valueName, prefix ), postfix ) );
if ( bitmask )
{
size_t pos = result.find( "Bit" );
if ( pos != std::string::npos )
{
result.erase( pos, 3 );
}
}
if ( !tag.empty() && ( result.substr( result.length() - tag.length() ) == toCamelCase( tag ) ) )
{
result = result.substr( 0, result.length() - tag.length() ) + tag;
}
return result;
}
std::string generateNamespacedType( std::string const & type )
{
return beginsWith( type, "Vk" ) ? ( "VULKAN_HPP_NAMESPACE::" + stripPrefix( type, "Vk" ) ) : type;
}
std::string generateNoDiscard( bool multiSuccessCodes, bool multiErrorCodes )
{
return ( multiSuccessCodes ) ? "VULKAN_HPP_NODISCARD "
: ( multiErrorCodes ? "VULKAN_HPP_NODISCARD_WHEN_NO_EXCEPTIONS " : "" );
}
std::string generateReturnType( std::vector<std::string> const & successCodes, std::string const & baseType )
{
return ( 1 < successCodes.size() ) ? ( ( baseType == "void" ) ? "Result" : ( "ResultValue<" + baseType + ">" ) )
: ( "typename ResultValueType<" + baseType + ">::type" );
}
std::string generateStandardArray( std::string const & type, std::vector<std::string> const & sizes )
{
std::string arrayString = "std::array<" + type + "," + sizes.back() + ">";
for ( size_t i = sizes.size() - 2; i < sizes.size(); i-- )
{
arrayString = "std::array<" + arrayString + "," + sizes[i] + ">";
}
return arrayString;
}
std::string generateStandardArrayWrapper( std::string const & type, std::vector<std::string> const & sizes )
{
std::string arrayString = "VULKAN_HPP_NAMESPACE::ArrayWrapper" + std::to_string( sizes.size() ) + "D<" + type;
for ( auto const & size : sizes )
{
arrayString += ", " + size;
}
arrayString += ">";
return arrayString;
}
std::string generateSuccessCode( std::string const & code, std::set<std::string> const & tags )
{
std::string tag = findTag( tags, code );
// on each success code: prepend 'VULKAN_HPP_NAMESPACE::Result::e', strip "VK_" and a tag, convert it to camel case,
// and add the tag again
return "VULKAN_HPP_NAMESPACE::Result::e" + toCamelCase( stripPostfix( stripPrefix( code, "VK_" ), tag ) ) + tag;
}
std::map<std::string, std::string> getAttributes( tinyxml2::XMLElement const * element )
{
std::map<std::string, std::string> attributes;
for ( auto attribute = element->FirstAttribute(); attribute; attribute = attribute->Next() )
{
assert( attributes.find( attribute->Name() ) == attributes.end() );
attributes[attribute->Name()] = attribute->Value();
}
return attributes;
}
template <typename ElementContainer>
std::vector<tinyxml2::XMLElement const *> getChildElements( ElementContainer const * element )
{
std::vector<tinyxml2::XMLElement const *> childElements;
for ( tinyxml2::XMLElement const * childElement = element->FirstChildElement(); childElement;
childElement = childElement->NextSiblingElement() )
{
childElements.push_back( childElement );
}
return childElements;
}
std::pair<std::vector<std::string>, std::string> readModifiers( tinyxml2::XMLNode const * node )
{
std::vector<std::string> arraySizes;
std::string bitCount;
if ( node && node->ToText() )
{
// following the name there might be some array size
std::string value = node->Value();
assert( !value.empty() );
if ( value[0] == '[' )
{
std::string::size_type endPos = 0;
while ( endPos + 1 != value.length() )
{
std::string::size_type startPos = value.find( '[', endPos );
check( startPos != std::string::npos, node->GetLineNum(), "could not find '[' in <" + value + ">" );
endPos = value.find( ']', startPos );
check( endPos != std::string::npos, node->GetLineNum(), "could not find ']' in <" + value + ">" );
check( startPos + 2 <= endPos, node->GetLineNum(), "missing content between '[' and ']' in <" + value + ">" );
arraySizes.push_back( value.substr( startPos + 1, endPos - startPos - 1 ) );
}
}
else if ( value[0] == ':' )
{
bitCount = value.substr( 1 );
}
else
{
check( ( value[0] == ';' ) || ( value[0] == ')' ), node->GetLineNum(), "unknown modifier <" + value + ">" );
}
}
return std::make_pair( arraySizes, bitCount );
}
void replaceAll( std::string & str, std::string const & from, std::string const & to )
{
size_t pos = 0;
while ( ( pos = str.find( from, pos ) ) != std::string::npos )
{
str.replace( pos, from.length(), to );
pos += to.length(); // Handles case where 'to' is a substring of 'from'
}
}
std::string replaceWithMap( std::string const & input, std::map<std::string, std::string> replacements )
{
// This will match ${someVariable} and contain someVariable in match group 1
std::regex re( R"(\$\{([^\}]+)\})" );
auto it = std::sregex_iterator( input.begin(), input.end(), re );
auto end = std::sregex_iterator();
// No match, just return the original string
if ( it == end )
{
assert( replacements.empty() );
return input;
}
#if !defined( NDEBUG )
std::set<std::string> matchedReplacements;
#endif
std::string result = "";
while ( it != end )
{
std::smatch match = *it;
auto itReplacement = replacements.find( match[1].str() );
assert( itReplacement != replacements.end() );
#if !defined( NDEBUG )
matchedReplacements.insert( match[1].str() );
#endif
result +=
match.prefix().str() + ( ( itReplacement != replacements.end() ) ? itReplacement->second : match[0].str() );
++it;
// we've passed the last match. Append the rest of the orignal string
if ( it == end )
{
result += match.suffix().str();
}
}
#if !defined( NDEBUG )
std::set<std::string> missedReplacements;
for ( auto r : replacements )
{
if ( matchedReplacements.find( r.first ) == matchedReplacements.end() )
{
missedReplacements.insert( r.first );
}
}
assert( missedReplacements.empty() );
#endif
return result;
}
std::string startLowerCase( std::string const & input )
{
return input.empty() ? "" : static_cast<char>( tolower( input[0] ) ) + input.substr( 1 );
}
std::string startUpperCase( std::string const & input )
{
return input.empty() ? "" : static_cast<char>( toupper( input[0] ) ) + input.substr( 1 );
}
std::string stripPostfix( std::string const & value, std::string const & postfix )
{
std::string strippedValue = value;
if ( endsWith( strippedValue, postfix ) )
{
strippedValue.erase( strippedValue.length() - postfix.length() );
}
return strippedValue;
}
std::string stripPluralS( std::string const & name )
{
std::string strippedName( name );
size_t pos = strippedName.rfind( 's' );
if ( pos != std::string::npos )
{
if ( ( 2 <= pos ) && ( strippedName.substr( pos - 2, 3 ) == "ies" ) )
{
strippedName.replace( pos - 2, 3, "y" );
}
else
{
strippedName.erase( pos, 1 );
}
}
return strippedName;
}
std::string stripPrefix( std::string const & value, std::string const & prefix )
{
std::string strippedValue = value;
if ( beginsWith( strippedValue, prefix ) )
{
strippedValue.erase( 0, prefix.length() );
}
return strippedValue;
}
std::string toCamelCase( std::string const & value )
{
assert( !value.empty() && ( isupper( value[0] ) || isdigit( value[0] ) ) );
std::string result;
result.reserve( value.size() );
bool keepUpper = true;
for ( auto c : value )
{
if ( c == '_' )
{
keepUpper = true;
}
else if ( isdigit( c ) )
{
keepUpper = true;
result.push_back( c );
}
else if ( keepUpper )
{
result.push_back( c );
keepUpper = false;
}
else
{
result.push_back( static_cast<char>( tolower( c ) ) );
}
}
return result;
}
std::string toUpperCase( std::string const & name )
{
std::string convertedName;
bool previousIsLowerCase = false;
bool previousIsDigit = false;
for ( auto c : name )
{
if ( ( isupper( c ) && ( previousIsLowerCase || previousIsDigit ) ) || ( isdigit( c ) && previousIsLowerCase ) )
{
convertedName.push_back( '_' );
}
convertedName.push_back( static_cast<char>( toupper( c ) ) );
previousIsLowerCase = !!islower( c );
previousIsDigit = !!isdigit( c );
}
return convertedName;
}
std::vector<std::string> tokenize( std::string const & tokenString, std::string const & separator )
{
std::vector<std::string> tokens;
if ( !tokenString.empty() )
{
size_t start = 0, end;
do
{
end = tokenString.find( separator, start );
if ( start != end )
{
tokens.push_back( trim( tokenString.substr( start, end - start ) ) );
}
start = end + separator.length();
} while ( end != std::string::npos );
}
return tokens;
}
template <typename StringContainer>
std::string toString( StringContainer const & strings )
{
std::string str;
bool encounteredMember = false;
for ( auto s : strings )
{
if ( encounteredMember )
{
str += ", ";
}
str += s;
encounteredMember = true;
}
return str;
}
std::string trim( std::string const & input )
{
std::string result = input;
result.erase( result.begin(),
std::find_if( result.begin(), result.end(), []( char c ) { return !std::isspace( c ); } ) );
result.erase( std::find_if( result.rbegin(), result.rend(), []( char c ) { return !std::isspace( c ); } ).base(),
result.end() );
return result;
}
std::string trimEnd( std::string const & input )
{
std::string result = input;
result.erase( std::find_if( result.rbegin(), result.rend(), []( char c ) { return !std::isspace( c ); } ).base(),
result.end() );
return result;
}
std::string trimStars( std::string const & input )
{
std::string result = input;
size_t pos = result.find( '*' );
while ( pos != std::string::npos )
{
if ( ( 0 < pos ) && ( result[pos - 1] != ' ' ) && ( result[pos - 1] != '*' ) )
{
result.insert( pos, 1, ' ' );
++pos;
}
else if ( ( pos < result.length() - 1 ) && ( result[pos + 1] != ' ' ) && ( result[pos + 1] != '*' ) )
{
result.insert( pos + 1, 1, ' ' );
}
pos = result.find( '*', pos + 1 );
}
return result;
}
void warn( bool condition, int line, std::string const & message )
{
if ( !condition )
{
std::cerr << "VulkanHppGenerator: Spec warning on line " << std::to_string( line ) << ": " << message << "!"
<< std::endl;
}
}
void writeToFile( std::string const & str, std::string const & fileName )
{
std::ofstream ofs( fileName );
assert( !ofs.fail() );
ofs << str;
ofs.close();
#if defined( CLANG_FORMAT_EXECUTABLE )
std::cout << "VulkanHppGenerator: Formatting " << fileName << " ..." << std::endl;
std::string commandString = "\"" CLANG_FORMAT_EXECUTABLE "\" -i --style=file " + fileName;
int ret = std::system( commandString.c_str() );
if ( ret != 0 )
{
std::cout << "VulkanHppGenerator: failed to format file " << fileName << " with error <" << ret << ">\n";
}
#endif
}
std::string toString( tinyxml2::XMLError error )
{
switch ( error )
{
case tinyxml2::XML_SUCCESS: return "XML_SUCCESS";
case tinyxml2::XML_NO_ATTRIBUTE: return "XML_NO_ATTRIBUTE";
case tinyxml2::XML_WRONG_ATTRIBUTE_TYPE: return "XML_WRONG_ATTRIBUTE_TYPE";
case tinyxml2::XML_ERROR_FILE_NOT_FOUND: return "XML_ERROR_FILE_NOT_FOUND";
case tinyxml2::XML_ERROR_FILE_COULD_NOT_BE_OPENED: return "XML_ERROR_FILE_COULD_NOT_BE_OPENED";
case tinyxml2::XML_ERROR_FILE_READ_ERROR: return "XML_ERROR_FILE_READ_ERROR";
case tinyxml2::XML_ERROR_PARSING_ELEMENT: return "XML_ERROR_PARSING_ELEMENT";
case tinyxml2::XML_ERROR_PARSING_ATTRIBUTE: return "XML_ERROR_PARSING_ATTRIBUTE";
case tinyxml2::XML_ERROR_PARSING_TEXT: return "XML_ERROR_PARSING_TEXT";
case tinyxml2::XML_ERROR_PARSING_CDATA: return "XML_ERROR_PARSING_CDATA";
case tinyxml2::XML_ERROR_PARSING_COMMENT: return "XML_ERROR_PARSING_COMMENT";
case tinyxml2::XML_ERROR_PARSING_DECLARATION: return "XML_ERROR_PARSING_DECLARATION";
case tinyxml2::XML_ERROR_PARSING_UNKNOWN: return "XML_ERROR_PARSING_UNKNOWN";
case tinyxml2::XML_ERROR_EMPTY_DOCUMENT: return "XML_ERROR_EMPTY_DOCUMENT";
case tinyxml2::XML_ERROR_MISMATCHED_ELEMENT: return "XML_ERROR_MISMATCHED_ELEMENT";
case tinyxml2::XML_ERROR_PARSING: return "XML_ERROR_PARSING";
case tinyxml2::XML_CAN_NOT_CONVERT_TEXT: return "XML_CAN_NOT_CONVERT_TEXT";
case tinyxml2::XML_NO_TEXT_NODE: return "XML_NO_TEXT_NODE";
default: return "unknown error code <" + std::to_string( error ) + ">";
}
}
int main( int argc, char ** argv )
{
static const std::string classArrayProxy = R"(
#if !defined( VULKAN_HPP_DISABLE_ENHANCED_MODE )
template <typename T>
class ArrayProxy
{
public:
VULKAN_HPP_CONSTEXPR ArrayProxy() VULKAN_HPP_NOEXCEPT
: m_count( 0 )
, m_ptr( nullptr )
{}
VULKAN_HPP_CONSTEXPR ArrayProxy( std::nullptr_t ) VULKAN_HPP_NOEXCEPT
: m_count( 0 )
, m_ptr( nullptr )
{}
ArrayProxy( T & value ) VULKAN_HPP_NOEXCEPT
: m_count( 1 )
, m_ptr( &value )
{}
template <typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxy( typename std::remove_const<T>::type & value ) VULKAN_HPP_NOEXCEPT
: m_count( 1 )
, m_ptr( &value )
{}
ArrayProxy( uint32_t count, T * ptr ) VULKAN_HPP_NOEXCEPT
: m_count( count )
, m_ptr( ptr )
{}
template <typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxy( uint32_t count, typename std::remove_const<T>::type * ptr ) VULKAN_HPP_NOEXCEPT
: m_count( count )
, m_ptr( ptr )
{}
# if __GNUC__ >= 9
# pragma GCC diagnostic push
# pragma GCC diagnostic ignored "-Winit-list-lifetime"
# endif
ArrayProxy( std::initializer_list<T> const & list ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( list.size() ) )
, m_ptr( list.begin() )
{}
template <typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxy( std::initializer_list<typename std::remove_const<T>::type> const & list ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( list.size() ) )
, m_ptr( list.begin() )
{}
ArrayProxy( std::initializer_list<T> & list ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( list.size() ) )
, m_ptr( list.begin() )
{}
template <typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxy( std::initializer_list<typename std::remove_const<T>::type> & list ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( list.size() ) )
, m_ptr( list.begin() )
{}
# if __GNUC__ >= 9
# pragma GCC diagnostic pop
# endif
template <size_t N>
ArrayProxy( std::array<T, N> const & data ) VULKAN_HPP_NOEXCEPT
: m_count( N )
, m_ptr( data.data() )
{}
template <size_t N, typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxy( std::array<typename std::remove_const<T>::type, N> const & data ) VULKAN_HPP_NOEXCEPT
: m_count( N )
, m_ptr( data.data() )
{}
template <size_t N>
ArrayProxy( std::array<T, N> & data ) VULKAN_HPP_NOEXCEPT
: m_count( N )
, m_ptr( data.data() )
{}
template <size_t N, typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxy( std::array<typename std::remove_const<T>::type, N> & data ) VULKAN_HPP_NOEXCEPT
: m_count( N )
, m_ptr( data.data() )
{}
template <class Allocator = std::allocator<typename std::remove_const<T>::type>>
ArrayProxy( std::vector<T, Allocator> const & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
template <class Allocator = std::allocator<typename std::remove_const<T>::type>,
typename B = T,
typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxy( std::vector<typename std::remove_const<T>::type, Allocator> const & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
template <class Allocator = std::allocator<typename std::remove_const<T>::type>>
ArrayProxy( std::vector<T, Allocator> & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
template <class Allocator = std::allocator<typename std::remove_const<T>::type>,
typename B = T,
typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxy( std::vector<typename std::remove_const<T>::type, Allocator> & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
#if defined( VULKAN_HPP_SUPPORT_SPAN )
template <size_t N = std::dynamic_extent>
ArrayProxy( std::span<T, N> const & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
template <size_t N = std::dynamic_extent, typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxy( std::span<typename std::remove_const<T>::type, N> const & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
template <size_t N = std::dynamic_extent>
ArrayProxy( std::span<T, N> & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
template <size_t N = std::dynamic_extent, typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxy( std::span<typename std::remove_const<T>::type, N> & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
#endif
const T * begin() const VULKAN_HPP_NOEXCEPT
{
return m_ptr;
}
const T * end() const VULKAN_HPP_NOEXCEPT
{
return m_ptr + m_count;
}
const T & front() const VULKAN_HPP_NOEXCEPT
{
VULKAN_HPP_ASSERT( m_count && m_ptr );
return *m_ptr;
}
const T & back() const VULKAN_HPP_NOEXCEPT
{
VULKAN_HPP_ASSERT( m_count && m_ptr );
return *( m_ptr + m_count - 1 );
}
bool empty() const VULKAN_HPP_NOEXCEPT
{
return ( m_count == 0 );
}
uint32_t size() const VULKAN_HPP_NOEXCEPT
{
return m_count;
}
T * data() const VULKAN_HPP_NOEXCEPT
{
return m_ptr;
}
private:
uint32_t m_count;
T * m_ptr;
};
template <typename T>
class ArrayProxyNoTemporaries
{
public:
VULKAN_HPP_CONSTEXPR ArrayProxyNoTemporaries() VULKAN_HPP_NOEXCEPT
: m_count( 0 )
, m_ptr( nullptr )
{}
VULKAN_HPP_CONSTEXPR ArrayProxyNoTemporaries( std::nullptr_t ) VULKAN_HPP_NOEXCEPT
: m_count( 0 )
, m_ptr( nullptr )
{}
ArrayProxyNoTemporaries( T & value ) VULKAN_HPP_NOEXCEPT
: m_count( 1 )
, m_ptr( &value )
{}
ArrayProxyNoTemporaries( T && value ) = delete;
template <typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( typename std::remove_const<T>::type & value ) VULKAN_HPP_NOEXCEPT
: m_count( 1 )
, m_ptr( &value )
{}
template <typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( typename std::remove_const<T>::type && value ) = delete;
ArrayProxyNoTemporaries( uint32_t count, T * ptr ) VULKAN_HPP_NOEXCEPT
: m_count( count )
, m_ptr( ptr )
{}
template <typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( uint32_t count, typename std::remove_const<T>::type * ptr ) VULKAN_HPP_NOEXCEPT
: m_count( count )
, m_ptr( ptr )
{}
ArrayProxyNoTemporaries( std::initializer_list<T> const & list ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( list.size() ) )
, m_ptr( list.begin() )
{}
ArrayProxyNoTemporaries( std::initializer_list<T> const && list ) = delete;
template <typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::initializer_list<typename std::remove_const<T>::type> const & list )
VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( list.size() ) )
, m_ptr( list.begin() )
{}
template <typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::initializer_list<typename std::remove_const<T>::type> const && list ) = delete;
ArrayProxyNoTemporaries( std::initializer_list<T> & list ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( list.size() ) )
, m_ptr( list.begin() )
{}
ArrayProxyNoTemporaries( std::initializer_list<T> && list ) = delete;
template <typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::initializer_list<typename std::remove_const<T>::type> & list ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( list.size() ) )
, m_ptr( list.begin() )
{}
template <typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::initializer_list<typename std::remove_const<T>::type> && list ) = delete;
template <size_t N>
ArrayProxyNoTemporaries( std::array<T, N> const & data ) VULKAN_HPP_NOEXCEPT
: m_count( N )
, m_ptr( data.data() )
{}
template <size_t N>
ArrayProxyNoTemporaries( std::array<T, N> const && data ) = delete;
template <size_t N, typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::array<typename std::remove_const<T>::type, N> const & data ) VULKAN_HPP_NOEXCEPT
: m_count( N )
, m_ptr( data.data() )
{}
template <size_t N, typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::array<typename std::remove_const<T>::type, N> const && data ) = delete;
template <size_t N>
ArrayProxyNoTemporaries( std::array<T, N> & data ) VULKAN_HPP_NOEXCEPT
: m_count( N )
, m_ptr( data.data() )
{}
template <size_t N>
ArrayProxyNoTemporaries( std::array<T, N> && data ) = delete;
template <size_t N, typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::array<typename std::remove_const<T>::type, N> & data ) VULKAN_HPP_NOEXCEPT
: m_count( N )
, m_ptr( data.data() )
{}
template <size_t N, typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::array<typename std::remove_const<T>::type, N> && data ) = delete;
template <class Allocator = std::allocator<typename std::remove_const<T>::type>>
ArrayProxyNoTemporaries( std::vector<T, Allocator> const & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
template <class Allocator = std::allocator<typename std::remove_const<T>::type>>
ArrayProxyNoTemporaries( std::vector<T, Allocator> const && data ) = delete;
template <class Allocator = std::allocator<typename std::remove_const<T>::type>,
typename B = T,
typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::vector<typename std::remove_const<T>::type, Allocator> const & data )
VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
template <class Allocator = std::allocator<typename std::remove_const<T>::type>,
typename B = T,
typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::vector<typename std::remove_const<T>::type, Allocator> const && data ) = delete;
template <class Allocator = std::allocator<typename std::remove_const<T>::type>>
ArrayProxyNoTemporaries( std::vector<T, Allocator> & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
template <class Allocator = std::allocator<typename std::remove_const<T>::type>>
ArrayProxyNoTemporaries( std::vector<T, Allocator> && data ) = delete;
template <class Allocator = std::allocator<typename std::remove_const<T>::type>,
typename B = T,
typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::vector<typename std::remove_const<T>::type, Allocator> & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
template <class Allocator = std::allocator<typename std::remove_const<T>::type>,
typename B = T,
typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::vector<typename std::remove_const<T>::type, Allocator> && data ) = delete;
#if defined( VULKAN_HPP_SUPPORT_SPAN )
template <size_t N = std::dynamic_extent>
ArrayProxyNoTemporaries( std::span<T, N> const & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
template <size_t N = std::dynamic_extent, typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::span<typename std::remove_const<T>::type, N> const & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
template <size_t N = std::dynamic_extent>
ArrayProxyNoTemporaries( std::span<T, N> & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
template <size_t N = std::dynamic_extent, typename B = T, typename std::enable_if<std::is_const<B>::value, int>::type = 0>
ArrayProxyNoTemporaries( std::span<typename std::remove_const<T>::type, N> & data ) VULKAN_HPP_NOEXCEPT
: m_count( static_cast<uint32_t>( data.size() ) )
, m_ptr( data.data() )
{}
#endif
const T * begin() const VULKAN_HPP_NOEXCEPT
{
return m_ptr;
}
const T * end() const VULKAN_HPP_NOEXCEPT
{
return m_ptr + m_count;
}
const T & front() const VULKAN_HPP_NOEXCEPT
{
VULKAN_HPP_ASSERT( m_count && m_ptr );
return *m_ptr;
}
const T & back() const VULKAN_HPP_NOEXCEPT
{
VULKAN_HPP_ASSERT( m_count && m_ptr );
return *( m_ptr + m_count - 1 );
}
bool empty() const VULKAN_HPP_NOEXCEPT
{
return ( m_count == 0 );
}
uint32_t size() const VULKAN_HPP_NOEXCEPT
{
return m_count;
}
T * data() const VULKAN_HPP_NOEXCEPT
{
return m_ptr;
}
private:
uint32_t m_count;
T * m_ptr;
};
#endif
)";
static const std::string classArrayWrapper = R"(
template <typename T, size_t N>
class ArrayWrapper1D : public std::array<T, N>
{
public:
VULKAN_HPP_CONSTEXPR ArrayWrapper1D() VULKAN_HPP_NOEXCEPT
: std::array<T, N>()
{}
VULKAN_HPP_CONSTEXPR ArrayWrapper1D( std::array<T, N> const & data ) VULKAN_HPP_NOEXCEPT
: std::array<T, N>( data )
{}
#if ( VK_USE_64_BIT_PTR_DEFINES == 0 )
// on 32 bit compiles, needs overloads on index type int to resolve ambiguities
VULKAN_HPP_CONSTEXPR T const & operator[]( int index ) const VULKAN_HPP_NOEXCEPT
{
return std::array<T, N>::operator[]( index );
}
T & operator[]( int index ) VULKAN_HPP_NOEXCEPT
{
return std::array<T, N>::operator[]( index );
}
#endif
operator T const * () const VULKAN_HPP_NOEXCEPT
{
return this->data();
}
operator T * () VULKAN_HPP_NOEXCEPT
{
return this->data();
}
template <typename B = T, typename std::enable_if<std::is_same<B, char>::value, int>::type = 0>
operator std::string() const
{
return std::string( this->data() );
}
#if 17 <= VULKAN_HPP_CPP_VERSION
template <typename B = T, typename std::enable_if<std::is_same<B, char>::value, int>::type = 0>
operator std::string_view() const
{
return std::string_view( this->data() );
}
#endif
template <typename B = T, typename std::enable_if<std::is_same<B, char>::value, int>::type = 0>
bool operator<( ArrayWrapper1D<char, N> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return *static_cast<std::array<char, N> const *>( this ) < *static_cast<std::array<char, N> const *>( &rhs );
}
template <typename B = T, typename std::enable_if<std::is_same<B, char>::value, int>::type = 0>
bool operator<=( ArrayWrapper1D<char, N> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return *static_cast<std::array<char, N> const *>( this ) <= *static_cast<std::array<char, N> const *>( &rhs );
}
template <typename B = T, typename std::enable_if<std::is_same<B, char>::value, int>::type = 0>
bool operator>( ArrayWrapper1D<char, N> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return *static_cast<std::array<char, N> const *>( this ) > *static_cast<std::array<char, N> const *>( &rhs );
}
template <typename B = T, typename std::enable_if<std::is_same<B, char>::value, int>::type = 0>
bool operator>=( ArrayWrapper1D<char, N> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return *static_cast<std::array<char, N> const *>( this ) >= *static_cast<std::array<char, N> const *>( &rhs );
}
template <typename B = T, typename std::enable_if<std::is_same<B, char>::value, int>::type = 0>
bool operator==( ArrayWrapper1D<char, N> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return *static_cast<std::array<char, N> const *>( this ) == *static_cast<std::array<char, N> const *>( &rhs );
}
template <typename B = T, typename std::enable_if<std::is_same<B, char>::value, int>::type = 0>
bool operator!=( ArrayWrapper1D<char, N> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return *static_cast<std::array<char, N> const *>( this ) != *static_cast<std::array<char, N> const *>( &rhs );
}
};
// specialization of relational operators between std::string and arrays of chars
template <size_t N>
bool operator<( std::string const & lhs, ArrayWrapper1D<char, N> const & rhs ) VULKAN_HPP_NOEXCEPT
{
return lhs < rhs.data();
}
template <size_t N>
bool operator<=( std::string const & lhs, ArrayWrapper1D<char, N> const & rhs ) VULKAN_HPP_NOEXCEPT
{
return lhs <= rhs.data();
}
template <size_t N>
bool operator>( std::string const & lhs, ArrayWrapper1D<char, N> const & rhs ) VULKAN_HPP_NOEXCEPT
{
return lhs > rhs.data();
}
template <size_t N>
bool operator>=( std::string const & lhs, ArrayWrapper1D<char, N> const & rhs ) VULKAN_HPP_NOEXCEPT
{
return lhs >= rhs.data();
}
template <size_t N>
bool operator==( std::string const & lhs, ArrayWrapper1D<char, N> const & rhs ) VULKAN_HPP_NOEXCEPT
{
return lhs == rhs.data();
}
template <size_t N>
bool operator!=( std::string const & lhs, ArrayWrapper1D<char, N> const & rhs ) VULKAN_HPP_NOEXCEPT
{
return lhs != rhs.data();
}
template <typename T, size_t N, size_t M>
class ArrayWrapper2D : public std::array<ArrayWrapper1D<T, M>, N>
{
public:
VULKAN_HPP_CONSTEXPR ArrayWrapper2D() VULKAN_HPP_NOEXCEPT
: std::array<ArrayWrapper1D<T, M>, N>()
{}
VULKAN_HPP_CONSTEXPR ArrayWrapper2D( std::array<std::array<T, M>, N> const & data ) VULKAN_HPP_NOEXCEPT
: std::array<ArrayWrapper1D<T, M>, N>( *reinterpret_cast<std::array<ArrayWrapper1D<T, M>, N> const *>( &data ) )
{}
};
)";
static const std::string classFlags = R"(
template <typename FlagBitsType>
struct FlagTraits
{
enum
{
allFlags = 0
};
};
template <typename BitType>
class Flags
{
public:
using MaskType = typename std::underlying_type<BitType>::type;
// constructors
VULKAN_HPP_CONSTEXPR Flags() VULKAN_HPP_NOEXCEPT
: m_mask( 0 )
{}
VULKAN_HPP_CONSTEXPR Flags( BitType bit ) VULKAN_HPP_NOEXCEPT
: m_mask( static_cast<MaskType>( bit ) )
{}
VULKAN_HPP_CONSTEXPR Flags( Flags<BitType> const & rhs ) VULKAN_HPP_NOEXCEPT = default;
VULKAN_HPP_CONSTEXPR explicit Flags( MaskType flags ) VULKAN_HPP_NOEXCEPT
: m_mask( flags )
{}
// relational operators
#if defined( VULKAN_HPP_HAS_SPACESHIP_OPERATOR )
auto operator<=>( Flags<BitType> const & ) const = default;
#else
VULKAN_HPP_CONSTEXPR bool operator<( Flags<BitType> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return m_mask < rhs.m_mask;
}
VULKAN_HPP_CONSTEXPR bool operator<=( Flags<BitType> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return m_mask <= rhs.m_mask;
}
VULKAN_HPP_CONSTEXPR bool operator>( Flags<BitType> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return m_mask > rhs.m_mask;
}
VULKAN_HPP_CONSTEXPR bool operator>=( Flags<BitType> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return m_mask >= rhs.m_mask;
}
VULKAN_HPP_CONSTEXPR bool operator==( Flags<BitType> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return m_mask == rhs.m_mask;
}
VULKAN_HPP_CONSTEXPR bool operator!=( Flags<BitType> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return m_mask != rhs.m_mask;
}
#endif
// logical operator
VULKAN_HPP_CONSTEXPR bool operator!() const VULKAN_HPP_NOEXCEPT
{
return !m_mask;
}
// bitwise operators
VULKAN_HPP_CONSTEXPR Flags<BitType> operator&( Flags<BitType> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return Flags<BitType>( m_mask & rhs.m_mask );
}
VULKAN_HPP_CONSTEXPR Flags<BitType> operator|( Flags<BitType> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return Flags<BitType>( m_mask | rhs.m_mask );
}
VULKAN_HPP_CONSTEXPR Flags<BitType> operator^( Flags<BitType> const & rhs ) const VULKAN_HPP_NOEXCEPT
{
return Flags<BitType>( m_mask ^ rhs.m_mask );
}
VULKAN_HPP_CONSTEXPR Flags<BitType> operator~() const VULKAN_HPP_NOEXCEPT
{
return Flags<BitType>( m_mask ^ FlagTraits<BitType>::allFlags );
}
// assignment operators
VULKAN_HPP_CONSTEXPR_14 Flags<BitType> & operator=( Flags<BitType> const & rhs ) VULKAN_HPP_NOEXCEPT = default;
VULKAN_HPP_CONSTEXPR_14 Flags<BitType> & operator|=( Flags<BitType> const & rhs ) VULKAN_HPP_NOEXCEPT
{
m_mask |= rhs.m_mask;
return *this;
}
VULKAN_HPP_CONSTEXPR_14 Flags<BitType> & operator&=( Flags<BitType> const & rhs ) VULKAN_HPP_NOEXCEPT
{
m_mask &= rhs.m_mask;
return *this;
}
VULKAN_HPP_CONSTEXPR_14 Flags<BitType> & operator^=( Flags<BitType> const & rhs ) VULKAN_HPP_NOEXCEPT
{
m_mask ^= rhs.m_mask;
return *this;
}
// cast operators
explicit VULKAN_HPP_CONSTEXPR operator bool() const VULKAN_HPP_NOEXCEPT
{
return !!m_mask;
}
explicit VULKAN_HPP_CONSTEXPR operator MaskType() const VULKAN_HPP_NOEXCEPT
{
return m_mask;
}
#if defined( VULKAN_HPP_FLAGS_MASK_TYPE_AS_PUBLIC )
public:
#else
private:
#endif
MaskType m_mask;
};
#if !defined( VULKAN_HPP_HAS_SPACESHIP_OPERATOR )
// relational operators only needed for pre C++20
template <typename BitType>
VULKAN_HPP_CONSTEXPR bool operator<( BitType bit, Flags<BitType> const & flags ) VULKAN_HPP_NOEXCEPT
{
return flags.operator>( bit );
}
template <typename BitType>
VULKAN_HPP_CONSTEXPR bool operator<=( BitType bit, Flags<BitType> const & flags ) VULKAN_HPP_NOEXCEPT
{
return flags.operator>=( bit );
}
template <typename BitType>
VULKAN_HPP_CONSTEXPR bool operator>( BitType bit, Flags<BitType> const & flags ) VULKAN_HPP_NOEXCEPT
{
return flags.operator<( bit );
}
template <typename BitType>
VULKAN_HPP_CONSTEXPR bool operator>=( BitType bit, Flags<BitType> const & flags ) VULKAN_HPP_NOEXCEPT
{
return flags.operator<=( bit );
}
template <typename BitType>
VULKAN_HPP_CONSTEXPR bool operator==( BitType bit, Flags<BitType> const & flags ) VULKAN_HPP_NOEXCEPT
{
return flags.operator==( bit );
}
template <typename BitType>
VULKAN_HPP_CONSTEXPR bool operator!=( BitType bit, Flags<BitType> const & flags ) VULKAN_HPP_NOEXCEPT
{
return flags.operator!=( bit );
}
#endif
// bitwise operators
template <typename BitType>
VULKAN_HPP_CONSTEXPR Flags<BitType> operator&( BitType bit, Flags<BitType> const & flags ) VULKAN_HPP_NOEXCEPT
{
return flags.operator&( bit );
}
template <typename BitType>
VULKAN_HPP_CONSTEXPR Flags<BitType> operator|( BitType bit, Flags<BitType> const & flags ) VULKAN_HPP_NOEXCEPT
{
return flags.operator|( bit );
}
template <typename BitType>
VULKAN_HPP_CONSTEXPR Flags<BitType> operator^( BitType bit, Flags<BitType> const & flags ) VULKAN_HPP_NOEXCEPT
{
return flags.operator^( bit );
}
)";
static const std::string classObjectDestroy = R"(
struct AllocationCallbacks;
template <typename OwnerType, typename Dispatch>
class ObjectDestroy
{
public:
ObjectDestroy() = default;
ObjectDestroy( OwnerType owner,
Optional<const AllocationCallbacks> allocationCallbacks
VULKAN_HPP_DEFAULT_ARGUMENT_NULLPTR_ASSIGNMENT,
Dispatch const & dispatch VULKAN_HPP_DEFAULT_DISPATCHER_ASSIGNMENT ) VULKAN_HPP_NOEXCEPT
: m_owner( owner )
, m_allocationCallbacks( allocationCallbacks )
, m_dispatch( &dispatch )
{}
OwnerType getOwner() const VULKAN_HPP_NOEXCEPT { return m_owner; }
Optional<const AllocationCallbacks> getAllocator() const VULKAN_HPP_NOEXCEPT { return m_allocationCallbacks; }
protected:
template <typename T>
void destroy(T t) VULKAN_HPP_NOEXCEPT
{
VULKAN_HPP_ASSERT( m_owner && m_dispatch );
m_owner.destroy( t, m_allocationCallbacks, *m_dispatch );
}
private:
OwnerType m_owner = {};
Optional<const AllocationCallbacks> m_allocationCallbacks = nullptr;
Dispatch const * m_dispatch = nullptr;
};
class NoParent;
template <typename Dispatch>
class ObjectDestroy<NoParent, Dispatch>
{
public:
ObjectDestroy() = default;
ObjectDestroy( Optional<const AllocationCallbacks> allocationCallbacks,
Dispatch const & dispatch VULKAN_HPP_DEFAULT_DISPATCHER_ASSIGNMENT ) VULKAN_HPP_NOEXCEPT
: m_allocationCallbacks( allocationCallbacks )
, m_dispatch( &dispatch )
{}
Optional<const AllocationCallbacks> getAllocator() const VULKAN_HPP_NOEXCEPT { return m_allocationCallbacks; }
protected:
template <typename T>
void destroy(T t) VULKAN_HPP_NOEXCEPT
{
VULKAN_HPP_ASSERT( m_dispatch );
t.destroy( m_allocationCallbacks, *m_dispatch );
}
private:
Optional<const AllocationCallbacks> m_allocationCallbacks = nullptr;
Dispatch const * m_dispatch = nullptr;
};
)";
static const std::string classObjectFree = R"(
template <typename OwnerType, typename Dispatch>
class ObjectFree
{
public:
ObjectFree() = default;
ObjectFree( OwnerType owner,
Optional<const AllocationCallbacks> allocationCallbacks VULKAN_HPP_DEFAULT_ARGUMENT_NULLPTR_ASSIGNMENT,
Dispatch const & dispatch VULKAN_HPP_DEFAULT_DISPATCHER_ASSIGNMENT ) VULKAN_HPP_NOEXCEPT
: m_owner( owner )
, m_allocationCallbacks( allocationCallbacks )
, m_dispatch( &dispatch )
{}
OwnerType getOwner() const VULKAN_HPP_NOEXCEPT
{
return m_owner;
}
Optional<const AllocationCallbacks> getAllocator() const VULKAN_HPP_NOEXCEPT
{
return m_allocationCallbacks;
}
protected:
template <typename T>
void destroy( T t ) VULKAN_HPP_NOEXCEPT
{
VULKAN_HPP_ASSERT( m_owner && m_dispatch );
m_owner.free( t, m_allocationCallbacks, *m_dispatch );
}
private:
OwnerType m_owner = {};
Optional<const AllocationCallbacks> m_allocationCallbacks = nullptr;
Dispatch const * m_dispatch = nullptr;
};
)";
static const std::string classObjectRelease = R"(
template <typename OwnerType, typename Dispatch>
class ObjectRelease
{
public:
ObjectRelease() = default;
ObjectRelease( OwnerType owner,
Dispatch const & dispatch VULKAN_HPP_DEFAULT_DISPATCHER_ASSIGNMENT ) VULKAN_HPP_NOEXCEPT
: m_owner( owner )
, m_dispatch( &dispatch )
{}
OwnerType getOwner() const VULKAN_HPP_NOEXCEPT
{
return m_owner;
}
protected:
template <typename T>
void destroy( T t ) VULKAN_HPP_NOEXCEPT
{
VULKAN_HPP_ASSERT( m_owner && m_dispatch );
m_owner.release( t, *m_dispatch );
}
private:
OwnerType m_owner = {};
Dispatch const * m_dispatch = nullptr;
};
)";
static const std::string classOptional = R"(
template <typename RefType>
class Optional
{
public:
Optional( RefType & reference ) VULKAN_HPP_NOEXCEPT
{
m_ptr = &reference;
}
Optional( RefType * ptr ) VULKAN_HPP_NOEXCEPT
{
m_ptr = ptr;
}
Optional( std::nullptr_t ) VULKAN_HPP_NOEXCEPT
{
m_ptr = nullptr;
}
operator RefType *() const VULKAN_HPP_NOEXCEPT
{
return m_ptr;
}
RefType const * operator->() const VULKAN_HPP_NOEXCEPT
{
return m_ptr;
}
explicit operator bool() const VULKAN_HPP_NOEXCEPT
{
return !!m_ptr;
}
private:
RefType * m_ptr;
};
)";
static const std::string classPoolFree = R"(
template <typename OwnerType, typename PoolType, typename Dispatch>
class PoolFree
{
public:
PoolFree() = default;
PoolFree( OwnerType owner,
PoolType pool,
Dispatch const & dispatch VULKAN_HPP_DEFAULT_DISPATCHER_ASSIGNMENT ) VULKAN_HPP_NOEXCEPT
: m_owner( owner )
, m_pool( pool )
, m_dispatch( &dispatch )
{}
OwnerType getOwner() const VULKAN_HPP_NOEXCEPT { return m_owner; }
PoolType getPool() const VULKAN_HPP_NOEXCEPT { return m_pool; }
protected:
template <typename T>
void destroy(T t) VULKAN_HPP_NOEXCEPT
{
m_owner.free( m_pool, t, *m_dispatch );
}
private:
OwnerType m_owner = OwnerType();
PoolType m_pool = PoolType();
Dispatch const * m_dispatch = nullptr;
};
)";
static const std::string classStructureChain = R"(
template <typename X, typename Y>
struct StructExtends
{
enum
{
value = false
};
};
template <typename Type, class...>
struct IsPartOfStructureChain
{
static const bool valid = false;
};
template <typename Type, typename Head, typename... Tail>
struct IsPartOfStructureChain<Type, Head, Tail...>
{
static const bool valid = std::is_same<Type, Head>::value || IsPartOfStructureChain<Type, Tail...>::valid;
};
template <size_t Index, typename T, typename... ChainElements>
struct StructureChainContains
{
static const bool value =
std::is_same<T, typename std::tuple_element<Index, std::tuple<ChainElements...>>::type>::value ||
StructureChainContains<Index - 1, T, ChainElements...>::value;
};
template <typename T, typename... ChainElements>
struct StructureChainContains<0, T, ChainElements...>
{
static const bool value =
std::is_same<T, typename std::tuple_element<0, std::tuple<ChainElements...>>::type>::value;
};
template <size_t Index, typename... ChainElements>
struct StructureChainValidation
{
using TestType = typename std::tuple_element<Index, std::tuple<ChainElements...>>::type;
static const bool valid =
StructExtends<TestType, typename std::tuple_element<0, std::tuple<ChainElements...>>::type>::value &&
( TestType::allowDuplicate || !StructureChainContains<Index - 1, TestType, ChainElements...>::value ) &&
StructureChainValidation<Index - 1, ChainElements...>::valid;
};
template <typename... ChainElements>
struct StructureChainValidation<0, ChainElements...>
{
static const bool valid = true;
};
template <typename... ChainElements>
class StructureChain : public std::tuple<ChainElements...>
{
public:
StructureChain() VULKAN_HPP_NOEXCEPT
{
static_assert( StructureChainValidation<sizeof...( ChainElements ) - 1, ChainElements...>::valid,
"The structure chain is not valid!" );
link<sizeof...( ChainElements ) - 1>();
}
StructureChain( StructureChain const & rhs ) VULKAN_HPP_NOEXCEPT : std::tuple<ChainElements...>( rhs )
{
static_assert( StructureChainValidation<sizeof...( ChainElements ) - 1, ChainElements...>::valid,
"The structure chain is not valid!" );
link( &std::get<0>( *this ),
&std::get<0>( rhs ),
reinterpret_cast<VkBaseOutStructure *>( &std::get<0>( *this ) ),
reinterpret_cast<VkBaseInStructure const *>( &std::get<0>( rhs ) ) );
}
StructureChain( StructureChain && rhs ) VULKAN_HPP_NOEXCEPT
: std::tuple<ChainElements...>( std::forward<std::tuple<ChainElements...>>( rhs ) )
{
static_assert( StructureChainValidation<sizeof...( ChainElements ) - 1, ChainElements...>::valid,
"The structure chain is not valid!" );
link( &std::get<0>( *this ),
&std::get<0>( rhs ),
reinterpret_cast<VkBaseOutStructure *>( &std::get<0>( *this ) ),
reinterpret_cast<VkBaseInStructure const *>( &std::get<0>( rhs ) ) );
}
StructureChain( ChainElements const &... elems ) VULKAN_HPP_NOEXCEPT : std::tuple<ChainElements...>( elems... )
{
static_assert( StructureChainValidation<sizeof...( ChainElements ) - 1, ChainElements...>::valid,
"The structure chain is not valid!" );
link<sizeof...( ChainElements ) - 1>();
}
StructureChain & operator=( StructureChain const & rhs ) VULKAN_HPP_NOEXCEPT
{
std::tuple<ChainElements...>::operator=( rhs );
link( &std::get<0>( *this ),
&std::get<0>( rhs ),
reinterpret_cast<VkBaseOutStructure *>( &std::get<0>( *this ) ),
reinterpret_cast<VkBaseInStructure const *>( &std::get<0>( rhs ) ) );
return *this;
}
StructureChain & operator=( StructureChain && rhs ) = delete;
template <typename T = typename std::tuple_element<0, std::tuple<ChainElements...>>::type, size_t Which = 0>
T & get() VULKAN_HPP_NOEXCEPT
{
return std::get<ChainElementIndex<0, T, Which, void, ChainElements...>::value>(
static_cast<std::tuple<ChainElements...> &>( *this ) );
}
template <typename T = typename std::tuple_element<0, std::tuple<ChainElements...>>::type, size_t Which = 0>
T const & get() const VULKAN_HPP_NOEXCEPT
{
return std::get<ChainElementIndex<0, T, Which, void, ChainElements...>::value>(
static_cast<std::tuple<ChainElements...> const &>( *this ) );
}
template <typename T0, typename T1, typename... Ts>
std::tuple<T0 &, T1 &, Ts &...> get() VULKAN_HPP_NOEXCEPT
{
return std::tie( get<T0>(), get<T1>(), get<Ts>()... );
}
template <typename T0, typename T1, typename... Ts>
std::tuple<T0 const &, T1 const &, Ts const &...> get() const VULKAN_HPP_NOEXCEPT
{
return std::tie( get<T0>(), get<T1>(), get<Ts>()... );
}
template <typename ClassType, size_t Which = 0>
typename std::enable_if<
std::is_same<ClassType, typename std::tuple_element<0, std::tuple<ChainElements...>>::type>::value &&
( Which == 0 ),
bool>::type
isLinked() const VULKAN_HPP_NOEXCEPT
{
return true;
}
template <typename ClassType, size_t Which = 0>
typename std::enable_if<
!std::is_same<ClassType, typename std::tuple_element<0, std::tuple<ChainElements...>>::type>::value ||
( Which != 0 ),
bool>::type
isLinked() const VULKAN_HPP_NOEXCEPT
{
static_assert( IsPartOfStructureChain<ClassType, ChainElements...>::valid,
"Can't unlink Structure that's not part of this StructureChain!" );
return isLinked( reinterpret_cast<VkBaseInStructure const *>( &get<ClassType, Which>() ) );
}
template <typename ClassType, size_t Which = 0>
typename std::enable_if<
!std::is_same<ClassType, typename std::tuple_element<0, std::tuple<ChainElements...>>::type>::value ||
( Which != 0 ),
void>::type relink() VULKAN_HPP_NOEXCEPT
{
static_assert( IsPartOfStructureChain<ClassType, ChainElements...>::valid,
"Can't relink Structure that's not part of this StructureChain!" );
auto pNext = reinterpret_cast<VkBaseInStructure *>( &get<ClassType, Which>() );
VULKAN_HPP_ASSERT( !isLinked( pNext ) );
auto & headElement = std::get<0>( static_cast<std::tuple<ChainElements...> &>( *this ) );
pNext->pNext = reinterpret_cast<VkBaseInStructure const *>( headElement.pNext );
headElement.pNext = pNext;
}
template <typename ClassType, size_t Which = 0>
typename std::enable_if<
!std::is_same<ClassType, typename std::tuple_element<0, std::tuple<ChainElements...>>::type>::value ||
( Which != 0 ),
void>::type unlink() VULKAN_HPP_NOEXCEPT
{
static_assert( IsPartOfStructureChain<ClassType, ChainElements...>::valid,
"Can't unlink Structure that's not part of this StructureChain!" );
unlink( reinterpret_cast<VkBaseOutStructure const *>( &get<ClassType, Which>() ) );
}
private:
template <int Index, typename T, int Which, typename, class First, class... Types>
struct ChainElementIndex : ChainElementIndex<Index + 1, T, Which, void, Types...>
{};
template <int Index, typename T, int Which, class First, class... Types>
struct ChainElementIndex<Index,
T,
Which,
typename std::enable_if<!std::is_same<T, First>::value, void>::type,
First,
Types...> : ChainElementIndex<Index + 1, T, Which, void, Types...>
{};
template <int Index, typename T, int Which, class First, class... Types>
struct ChainElementIndex<Index,
T,
Which,
typename std::enable_if<std::is_same<T, First>::value, void>::type,
First,
Types...> : ChainElementIndex<Index + 1, T, Which - 1, void, Types...>
{};
template <int Index, typename T, class First, class... Types>
struct ChainElementIndex<Index,
T,
0,
typename std::enable_if<std::is_same<T, First>::value, void>::type,
First,
Types...> : std::integral_constant<int, Index>
{};
bool isLinked( VkBaseInStructure const * pNext ) const VULKAN_HPP_NOEXCEPT
{
VkBaseInStructure const * elementPtr = reinterpret_cast<VkBaseInStructure const *>(
&std::get<0>( static_cast<std::tuple<ChainElements...> const &>( *this ) ) );
while ( elementPtr )
{
if ( elementPtr->pNext == pNext )
{
return true;
}
elementPtr = elementPtr->pNext;
}
return false;
}
template <size_t Index>
typename std::enable_if<Index != 0, void>::type link() VULKAN_HPP_NOEXCEPT
{
auto & x = std::get<Index - 1>( static_cast<std::tuple<ChainElements...> &>( *this ) );
x.pNext = &std::get<Index>( static_cast<std::tuple<ChainElements...> &>( *this ) );
link<Index - 1>();
}
template <size_t Index>
typename std::enable_if<Index == 0, void>::type link() VULKAN_HPP_NOEXCEPT
{}
void link( void * dstBase, void const * srcBase, VkBaseOutStructure * dst, VkBaseInStructure const * src )
{
while ( src->pNext )
{
std::ptrdiff_t offset =
reinterpret_cast<char const *>( src->pNext ) - reinterpret_cast<char const *>( srcBase );
dst->pNext = reinterpret_cast<VkBaseOutStructure *>( reinterpret_cast<char *>( dstBase ) + offset );
dst = dst->pNext;
src = src->pNext;
}
dst->pNext = nullptr;
}
void unlink( VkBaseOutStructure const * pNext ) VULKAN_HPP_NOEXCEPT
{
VkBaseOutStructure * elementPtr =
reinterpret_cast<VkBaseOutStructure *>( &std::get<0>( static_cast<std::tuple<ChainElements...> &>( *this ) ) );
while ( elementPtr && ( elementPtr->pNext != pNext ) )
{
elementPtr = elementPtr->pNext;
}
if ( elementPtr )
{
elementPtr->pNext = pNext->pNext;
}
else
{
VULKAN_HPP_ASSERT( false ); // fires, if the ClassType member has already been unlinked !
}
}
};
)";
static const std::string classUniqueHandle = R"(
#if !defined( VULKAN_HPP_NO_SMART_HANDLE )
template <typename Type, typename Dispatch>
class UniqueHandleTraits;
template <typename Type, typename Dispatch>
class UniqueHandle : public UniqueHandleTraits<Type, Dispatch>::deleter
{
private:
using Deleter = typename UniqueHandleTraits<Type, Dispatch>::deleter;
public:
using element_type = Type;
UniqueHandle()
: Deleter()
, m_value()
{}
explicit UniqueHandle( Type const & value, Deleter const & deleter = Deleter() ) VULKAN_HPP_NOEXCEPT
: Deleter( deleter )
, m_value( value )
{}
UniqueHandle( UniqueHandle const & ) = delete;
UniqueHandle( UniqueHandle && other ) VULKAN_HPP_NOEXCEPT
: Deleter( std::move( static_cast<Deleter &>( other ) ) )
, m_value( other.release() )
{}
~UniqueHandle() VULKAN_HPP_NOEXCEPT
{
if ( m_value )
{
this->destroy( m_value );
}
}
UniqueHandle & operator=( UniqueHandle const & ) = delete;
UniqueHandle & operator=( UniqueHandle && other ) VULKAN_HPP_NOEXCEPT
{
reset( other.release() );
*static_cast<Deleter *>( this ) = std::move( static_cast<Deleter &>( other ) );
return *this;
}
explicit operator bool() const VULKAN_HPP_NOEXCEPT
{
return m_value.operator bool();
}
Type const * operator->() const VULKAN_HPP_NOEXCEPT
{
return &m_value;
}
Type * operator->() VULKAN_HPP_NOEXCEPT
{
return &m_value;
}
Type const & operator*() const VULKAN_HPP_NOEXCEPT
{
return m_value;
}
Type & operator*() VULKAN_HPP_NOEXCEPT
{
return m_value;
}
const Type & get() const VULKAN_HPP_NOEXCEPT
{
return m_value;
}
Type & get() VULKAN_HPP_NOEXCEPT
{
return m_value;
}
void reset( Type const & value = Type() ) VULKAN_HPP_NOEXCEPT
{
if ( m_value != value )
{
if ( m_value )
{
this->destroy( m_value );
}
m_value = value;
}
}
Type release() VULKAN_HPP_NOEXCEPT
{
Type value = m_value;
m_value = nullptr;
return value;
}
void swap( UniqueHandle<Type, Dispatch> & rhs ) VULKAN_HPP_NOEXCEPT
{
std::swap( m_value, rhs.m_value );
std::swap( static_cast<Deleter &>( *this ), static_cast<Deleter &>( rhs ) );
}
private:
Type m_value;
};
template <typename UniqueType>
VULKAN_HPP_INLINE std::vector<typename UniqueType::element_type>
uniqueToRaw( std::vector<UniqueType> const & handles )
{
std::vector<typename UniqueType::element_type> newBuffer( handles.size() );
std::transform(
handles.begin(), handles.end(), newBuffer.begin(), []( UniqueType const & handle ) { return handle.get(); } );
return newBuffer;
}
template <typename Type, typename Dispatch>
VULKAN_HPP_INLINE void swap( UniqueHandle<Type, Dispatch> & lhs,
UniqueHandle<Type, Dispatch> & rhs ) VULKAN_HPP_NOEXCEPT
{
lhs.swap( rhs );
}
#endif
)";
static const std::string defines = R"(
// <tuple> includes <sys/sysmacros.h> through some other header
// this results in major(x) being resolved to gnu_dev_major(x)
// which is an expression in a constructor initializer list.
#if defined( major )
# undef major
#endif
#if defined( minor )
# undef minor
#endif
// Windows defines MemoryBarrier which is deprecated and collides
// with the VULKAN_HPP_NAMESPACE::MemoryBarrier struct.
#if defined( MemoryBarrier )
# undef MemoryBarrier
#endif
#if !defined( VULKAN_HPP_HAS_UNRESTRICTED_UNIONS )
# if defined( __clang__ )
# if __has_feature( cxx_unrestricted_unions )
# define VULKAN_HPP_HAS_UNRESTRICTED_UNIONS
# endif
# elif defined( __GNUC__ )
# define GCC_VERSION ( __GNUC__ * 10000 + __GNUC_MINOR__ * 100 + __GNUC_PATCHLEVEL__ )
# if 40600 <= GCC_VERSION
# define VULKAN_HPP_HAS_UNRESTRICTED_UNIONS
# endif
# elif defined( _MSC_VER )
# if 1900 <= _MSC_VER
# define VULKAN_HPP_HAS_UNRESTRICTED_UNIONS
# endif
# endif
#endif
#if !defined( VULKAN_HPP_INLINE )
# if defined( __clang__ )
# if __has_attribute( always_inline )
# define VULKAN_HPP_INLINE __attribute__( ( always_inline ) ) __inline__
# else
# define VULKAN_HPP_INLINE inline
# endif
# elif defined( __GNUC__ )
# define VULKAN_HPP_INLINE __attribute__( ( always_inline ) ) __inline__
# elif defined( _MSC_VER )
# define VULKAN_HPP_INLINE inline
# else
# define VULKAN_HPP_INLINE inline
# endif
#endif
#if defined( VULKAN_HPP_TYPESAFE_CONVERSION )
# define VULKAN_HPP_TYPESAFE_EXPLICIT
#else
# define VULKAN_HPP_TYPESAFE_EXPLICIT explicit
#endif
#if defined( __cpp_constexpr )
# define VULKAN_HPP_CONSTEXPR constexpr
# if __cpp_constexpr >= 201304
# define VULKAN_HPP_CONSTEXPR_14 constexpr
# else
# define VULKAN_HPP_CONSTEXPR_14
# endif
# define VULKAN_HPP_CONST_OR_CONSTEXPR constexpr
#else
# define VULKAN_HPP_CONSTEXPR
# define VULKAN_HPP_CONSTEXPR_14
# define VULKAN_HPP_CONST_OR_CONSTEXPR const
#endif
#if !defined( VULKAN_HPP_NOEXCEPT )
# if defined( _MSC_VER ) && ( _MSC_VER <= 1800 )
# define VULKAN_HPP_NOEXCEPT
# else
# define VULKAN_HPP_NOEXCEPT noexcept
# define VULKAN_HPP_HAS_NOEXCEPT 1
# if defined( VULKAN_HPP_NO_EXCEPTIONS )
# define VULKAN_HPP_NOEXCEPT_WHEN_NO_EXCEPTIONS noexcept
# else
# define VULKAN_HPP_NOEXCEPT_WHEN_NO_EXCEPTIONS
# endif
# endif
#endif
#if 14 <= VULKAN_HPP_CPP_VERSION
# define VULKAN_HPP_DEPRECATED( msg ) [[deprecated( msg )]]
#else
# define VULKAN_HPP_DEPRECATED( msg )
#endif
#if ( 17 <= VULKAN_HPP_CPP_VERSION ) && !defined( VULKAN_HPP_NO_NODISCARD_WARNINGS )
# define VULKAN_HPP_NODISCARD [[nodiscard]]
# if defined( VULKAN_HPP_NO_EXCEPTIONS )
# define VULKAN_HPP_NODISCARD_WHEN_NO_EXCEPTIONS [[nodiscard]]
# else
# define VULKAN_HPP_NODISCARD_WHEN_NO_EXCEPTIONS
# endif
#else
# define VULKAN_HPP_NODISCARD
# define VULKAN_HPP_NODISCARD_WHEN_NO_EXCEPTIONS
#endif
#if !defined( VULKAN_HPP_NAMESPACE )
# define VULKAN_HPP_NAMESPACE vk
#endif
#define VULKAN_HPP_STRINGIFY2( text ) #text
#define VULKAN_HPP_STRINGIFY( text ) VULKAN_HPP_STRINGIFY2( text )
#define VULKAN_HPP_NAMESPACE_STRING VULKAN_HPP_STRINGIFY( VULKAN_HPP_NAMESPACE )
)";
static const std::string dispatchLoaderBase = R"(
class DispatchLoaderBase
{
public:
DispatchLoaderBase() = default;
DispatchLoaderBase( std::nullptr_t )
#if !defined( NDEBUG )
: m_valid( false )
#endif
{}
#if !defined( NDEBUG )
size_t getVkHeaderVersion() const
{
VULKAN_HPP_ASSERT( m_valid );
return vkHeaderVersion;
}
private:
size_t vkHeaderVersion = VK_HEADER_VERSION;
bool m_valid = true;
#endif
};
)";
static const std::string dispatchLoaderDefault = R"(
class DispatchLoaderDynamic;
#if !defined(VULKAN_HPP_DISPATCH_LOADER_DYNAMIC)
# if defined( VK_NO_PROTOTYPES )
# define VULKAN_HPP_DISPATCH_LOADER_DYNAMIC 1
# else
# define VULKAN_HPP_DISPATCH_LOADER_DYNAMIC 0
# endif
#endif
#if !defined( VULKAN_HPP_STORAGE_API )
# if defined( VULKAN_HPP_STORAGE_SHARED )
# if defined( _MSC_VER )
# if defined( VULKAN_HPP_STORAGE_SHARED_EXPORT )
# define VULKAN_HPP_STORAGE_API __declspec( dllexport )
# else
# define VULKAN_HPP_STORAGE_API __declspec( dllimport )
# endif
# elif defined( __clang__ ) || defined( __GNUC__ )
# if defined( VULKAN_HPP_STORAGE_SHARED_EXPORT )
# define VULKAN_HPP_STORAGE_API __attribute__( ( visibility( "default" ) ) )
# else
# define VULKAN_HPP_STORAGE_API
# endif
# else
# define VULKAN_HPP_STORAGE_API
# pragma warning Unknown import / export semantics
# endif
# else
# define VULKAN_HPP_STORAGE_API
# endif
#endif
#if !defined( VULKAN_HPP_DEFAULT_DISPATCHER )
# if VULKAN_HPP_DISPATCH_LOADER_DYNAMIC == 1
# define VULKAN_HPP_DEFAULT_DISPATCHER ::VULKAN_HPP_NAMESPACE::defaultDispatchLoaderDynamic
# define VULKAN_HPP_DEFAULT_DISPATCH_LOADER_DYNAMIC_STORAGE \
namespace VULKAN_HPP_NAMESPACE \
{ \
VULKAN_HPP_STORAGE_API DispatchLoaderDynamic defaultDispatchLoaderDynamic; \
}
extern VULKAN_HPP_STORAGE_API DispatchLoaderDynamic defaultDispatchLoaderDynamic;
# else
static inline ::VULKAN_HPP_NAMESPACE::DispatchLoaderStatic & getDispatchLoaderStatic()
{
static ::VULKAN_HPP_NAMESPACE::DispatchLoaderStatic dls;
return dls;
}
# define VULKAN_HPP_DEFAULT_DISPATCHER ::VULKAN_HPP_NAMESPACE::getDispatchLoaderStatic()
# define VULKAN_HPP_DEFAULT_DISPATCH_LOADER_DYNAMIC_STORAGE
# endif
#endif
#if !defined( VULKAN_HPP_DEFAULT_DISPATCHER_TYPE )
# if VULKAN_HPP_DISPATCH_LOADER_DYNAMIC == 1
# define VULKAN_HPP_DEFAULT_DISPATCHER_TYPE ::VULKAN_HPP_NAMESPACE::DispatchLoaderDynamic
# else
# define VULKAN_HPP_DEFAULT_DISPATCHER_TYPE ::VULKAN_HPP_NAMESPACE::DispatchLoaderStatic
# endif
#endif
#if defined( VULKAN_HPP_NO_DEFAULT_DISPATCHER )
# define VULKAN_HPP_DEFAULT_ARGUMENT_ASSIGNMENT
# define VULKAN_HPP_DEFAULT_ARGUMENT_NULLPTR_ASSIGNMENT
# define VULKAN_HPP_DEFAULT_DISPATCHER_ASSIGNMENT
#else
# define VULKAN_HPP_DEFAULT_ARGUMENT_ASSIGNMENT = {}
# define VULKAN_HPP_DEFAULT_ARGUMENT_NULLPTR_ASSIGNMENT = nullptr
# define VULKAN_HPP_DEFAULT_DISPATCHER_ASSIGNMENT = VULKAN_HPP_DEFAULT_DISPATCHER
#endif
)";
static const std::string dynamicLoader = R"(
#if VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL
class DynamicLoader
{
public:
# ifdef VULKAN_HPP_NO_EXCEPTIONS
DynamicLoader( std::string const & vulkanLibraryName = {} ) VULKAN_HPP_NOEXCEPT
# else
DynamicLoader( std::string const & vulkanLibraryName = {} )
# endif
{
if ( !vulkanLibraryName.empty() )
{
# if defined( __unix__ ) || defined( __APPLE__ ) || defined( __QNXNTO__ ) || defined(__Fuchsia__)
m_library = dlopen( vulkanLibraryName.c_str(), RTLD_NOW | RTLD_LOCAL );
# elif defined( _WIN32 )
m_library = ::LoadLibraryA( vulkanLibraryName.c_str() );
# else
# error unsupported platform
# endif
}
else
{
# if defined( __unix__ ) || defined( __QNXNTO__ ) || defined(__Fuchsia__)
m_library = dlopen( "libvulkan.so", RTLD_NOW | RTLD_LOCAL );
if ( m_library == nullptr )
{
m_library = dlopen( "libvulkan.so.1", RTLD_NOW | RTLD_LOCAL );
}
# elif defined( __APPLE__ )
m_library = dlopen( "libvulkan.dylib", RTLD_NOW | RTLD_LOCAL );
# elif defined( _WIN32 )
m_library = ::LoadLibraryA( "vulkan-1.dll" );
# else
# error unsupported platform
# endif
}
#ifndef VULKAN_HPP_NO_EXCEPTIONS
if ( m_library == nullptr )
{
// NOTE there should be an InitializationFailedError, but msvc insists on the symbol does not exist within the scope of this function.
throw std::runtime_error( "Failed to load vulkan library!" );
}
#endif
}
DynamicLoader( DynamicLoader const & ) = delete;
DynamicLoader( DynamicLoader && other ) VULKAN_HPP_NOEXCEPT : m_library(other.m_library)
{
other.m_library = nullptr;
}
DynamicLoader &operator=( DynamicLoader const & ) = delete;
DynamicLoader &operator=( DynamicLoader && other ) VULKAN_HPP_NOEXCEPT
{
std::swap(m_library, other.m_library);
return *this;
}
~DynamicLoader() VULKAN_HPP_NOEXCEPT
{
if ( m_library )
{
# if defined( __unix__ ) || defined( __APPLE__ ) || defined( __QNXNTO__ ) || defined(__Fuchsia__)
dlclose( m_library );
# elif defined( _WIN32 )
::FreeLibrary( m_library );
# else
# error unsupported platform
# endif
}
}
template <typename T>
T getProcAddress( const char* function ) const VULKAN_HPP_NOEXCEPT
{
# if defined( __unix__ ) || defined( __APPLE__ ) || defined( __QNXNTO__ ) || defined(__Fuchsia__)
return (T)dlsym( m_library, function );
# elif defined( _WIN32 )
return (T)::GetProcAddress( m_library, function );
# else
# error unsupported platform
# endif
}
bool success() const VULKAN_HPP_NOEXCEPT { return m_library != nullptr; }
private:
# if defined( __unix__ ) || defined( __APPLE__ ) || defined( __QNXNTO__ ) || defined(__Fuchsia__)
void * m_library;
# elif defined( _WIN32 )
::HINSTANCE m_library;
# else
# error unsupported platform
# endif
};
#endif
)";
static const std::string exceptions = R"(
class ErrorCategoryImpl : public std::error_category
{
public:
virtual const char* name() const VULKAN_HPP_NOEXCEPT override { return VULKAN_HPP_NAMESPACE_STRING"::Result"; }
virtual std::string message(int ev) const override { return to_string(static_cast<Result>(ev)); }
};
class Error
{
public:
Error() VULKAN_HPP_NOEXCEPT = default;
Error(const Error&) VULKAN_HPP_NOEXCEPT = default;
virtual ~Error() VULKAN_HPP_NOEXCEPT = default;
virtual const char* what() const VULKAN_HPP_NOEXCEPT = 0;
};
class LogicError : public Error, public std::logic_error
{
public:
explicit LogicError( const std::string& what )
: Error(), std::logic_error(what) {}
explicit LogicError( char const * what )
: Error(), std::logic_error(what) {}
virtual const char* what() const VULKAN_HPP_NOEXCEPT { return std::logic_error::what(); }
};
class SystemError : public Error, public std::system_error
{
public:
SystemError( std::error_code ec )
: Error(), std::system_error(ec) {}
SystemError( std::error_code ec, std::string const & what )
: Error(), std::system_error(ec, what) {}
SystemError( std::error_code ec, char const * what )
: Error(), std::system_error(ec, what) {}
SystemError( int ev, std::error_category const & ecat )
: Error(), std::system_error(ev, ecat) {}
SystemError( int ev, std::error_category const & ecat, std::string const & what)
: Error(), std::system_error(ev, ecat, what) {}
SystemError( int ev, std::error_category const & ecat, char const * what)
: Error(), std::system_error(ev, ecat, what) {}
virtual const char* what() const VULKAN_HPP_NOEXCEPT { return std::system_error::what(); }
};
VULKAN_HPP_INLINE const std::error_category& errorCategory() VULKAN_HPP_NOEXCEPT
{
static ErrorCategoryImpl instance;
return instance;
}
VULKAN_HPP_INLINE std::error_code make_error_code(Result e) VULKAN_HPP_NOEXCEPT
{
return std::error_code(static_cast<int>(e), errorCategory());
}
VULKAN_HPP_INLINE std::error_condition make_error_condition(Result e) VULKAN_HPP_NOEXCEPT
{
return std::error_condition(static_cast<int>(e), errorCategory());
}
)";
static const std::string includes = R"(
#ifndef VULKAN_HPP
#define VULKAN_HPP
#if defined( _MSVC_LANG )
# define VULKAN_HPP_CPLUSPLUS _MSVC_LANG
#else
# define VULKAN_HPP_CPLUSPLUS __cplusplus
#endif
#if 201703L < VULKAN_HPP_CPLUSPLUS
# define VULKAN_HPP_CPP_VERSION 20
#elif 201402L < VULKAN_HPP_CPLUSPLUS
# define VULKAN_HPP_CPP_VERSION 17
#elif 201103L < VULKAN_HPP_CPLUSPLUS
# define VULKAN_HPP_CPP_VERSION 14
#elif 199711L < VULKAN_HPP_CPLUSPLUS
# define VULKAN_HPP_CPP_VERSION 11
#else
# error "vulkan.hpp needs at least c++ standard version 11"
#endif
#include <algorithm>
#include <array>
#include <cstddef>
#include <cstdint>
#include <cstring>
#include <functional>
#include <initializer_list>
#include <sstream>
#include <string>
#include <system_error>
#include <tuple>
#include <type_traits>
#include <vulkan/vulkan.h>
#if 17 <= VULKAN_HPP_CPP_VERSION
# include <string_view>
#endif
#if defined( VULKAN_HPP_DISABLE_ENHANCED_MODE )
# if !defined( VULKAN_HPP_NO_SMART_HANDLE )
# define VULKAN_HPP_NO_SMART_HANDLE
# endif
#else
# include <memory>
# include <vector>
#endif
#if defined( VULKAN_HPP_NO_CONSTRUCTORS )
# if !defined( VULKAN_HPP_NO_STRUCT_CONSTRUCTORS )
# define VULKAN_HPP_NO_STRUCT_CONSTRUCTORS
# endif
# if !defined( VULKAN_HPP_NO_UNION_CONSTRUCTORS )
# define VULKAN_HPP_NO_UNION_CONSTRUCTORS
# endif
#endif
#if defined( VULKAN_HPP_NO_SETTERS )
# if !defined( VULKAN_HPP_NO_STRUCT_SETTERS )
# define VULKAN_HPP_NO_STRUCT_SETTERS
# endif
# if !defined( VULKAN_HPP_NO_UNION_SETTERS )
# define VULKAN_HPP_NO_UNION_SETTERS
# endif
#endif
#if !defined( VULKAN_HPP_ASSERT )
# include <cassert>
# define VULKAN_HPP_ASSERT assert
#endif
#if !defined( VULKAN_HPP_ASSERT_ON_RESULT )
# define VULKAN_HPP_ASSERT_ON_RESULT VULKAN_HPP_ASSERT
#endif
#if !defined( VULKAN_HPP_STATIC_ASSERT )
# define VULKAN_HPP_STATIC_ASSERT static_assert
#endif
#if !defined( VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL )
# define VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL 1
#endif
#if VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL == 1
# if defined( __unix__ ) || defined( __APPLE__ ) || defined( __QNXNTO__ ) || defined(__Fuchsia__)
# include <dlfcn.h>
# elif defined( _WIN32 )
typedef struct HINSTANCE__ * HINSTANCE;
# if defined( _WIN64 )
typedef int64_t( __stdcall * FARPROC )();
# else
typedef int( __stdcall * FARPROC )();
# endif
extern "C" __declspec( dllimport ) HINSTANCE __stdcall LoadLibraryA( char const * lpLibFileName );
extern "C" __declspec( dllimport ) int __stdcall FreeLibrary( HINSTANCE hLibModule );
extern "C" __declspec( dllimport ) FARPROC __stdcall GetProcAddress( HINSTANCE hModule, const char * lpProcName );
# endif
#endif
#if !defined( __has_include )
# define __has_include( x ) false
#endif
#if ( 201711 <= __cpp_impl_three_way_comparison ) && __has_include( <compare> ) && !defined( VULKAN_HPP_NO_SPACESHIP_OPERATOR )
# define VULKAN_HPP_HAS_SPACESHIP_OPERATOR
#endif
#if defined( VULKAN_HPP_HAS_SPACESHIP_OPERATOR )
# include <compare>
#endif
#if ( 201803 <= __cpp_lib_span )
# define VULKAN_HPP_SUPPORT_SPAN
# include <span>
#endif
)";
static const std::string structResultValue = R"(
template <typename T> void ignore(T const &) VULKAN_HPP_NOEXCEPT {}
template <typename T>
struct ResultValue
{
#ifdef VULKAN_HPP_HAS_NOEXCEPT
ResultValue( Result r, T & v ) VULKAN_HPP_NOEXCEPT(VULKAN_HPP_NOEXCEPT(T(v)))
#else
ResultValue( Result r, T & v )
#endif
: result( r )
, value( v )
{}
#ifdef VULKAN_HPP_HAS_NOEXCEPT
ResultValue( Result r, T && v ) VULKAN_HPP_NOEXCEPT(VULKAN_HPP_NOEXCEPT(T(std::move(v))))
#else
ResultValue( Result r, T && v )
#endif
: result( r )
, value( std::move( v ) )
{}
Result result;
T value;
operator std::tuple<Result&, T&>() VULKAN_HPP_NOEXCEPT { return std::tuple<Result&, T&>(result, value); }
#if !defined(VULKAN_HPP_DISABLE_IMPLICIT_RESULT_VALUE_CAST)
VULKAN_HPP_DEPRECATED("Implicit-cast operators on vk::ResultValue are deprecated. Explicitly access the value as member of ResultValue.")
operator T const & () const & VULKAN_HPP_NOEXCEPT
{
return value;
}
VULKAN_HPP_DEPRECATED("Implicit-cast operators on vk::ResultValue are deprecated. Explicitly access the value as member of ResultValue.")
operator T& () & VULKAN_HPP_NOEXCEPT
{
return value;
}
VULKAN_HPP_DEPRECATED("Implicit-cast operators on vk::ResultValue are deprecated. Explicitly access the value as member of ResultValue.")
operator T const && () const && VULKAN_HPP_NOEXCEPT
{
return std::move( value );
}
VULKAN_HPP_DEPRECATED("Implicit-cast operators on vk::ResultValue are deprecated. Explicitly access the value as member of ResultValue.")
operator T&& () && VULKAN_HPP_NOEXCEPT
{
return std::move( value );
}
#endif
};
#if !defined( VULKAN_HPP_NO_SMART_HANDLE )
template <typename Type, typename Dispatch>
struct ResultValue<UniqueHandle<Type, Dispatch>>
{
#ifdef VULKAN_HPP_HAS_NOEXCEPT
ResultValue(Result r, UniqueHandle<Type, Dispatch> && v) VULKAN_HPP_NOEXCEPT
#else
ResultValue(Result r, UniqueHandle<Type, Dispatch> && v)
#endif
: result(r)
, value(std::move(v))
{}
std::tuple<Result, UniqueHandle<Type, Dispatch>> asTuple()
{
return std::make_tuple( result, std::move( value ) );
}
# if !defined(VULKAN_HPP_DISABLE_IMPLICIT_RESULT_VALUE_CAST)
VULKAN_HPP_DEPRECATED("Implicit-cast operators on vk::ResultValue are deprecated. Explicitly access the value as member of ResultValue.")
operator UniqueHandle<Type, Dispatch>& () & VULKAN_HPP_NOEXCEPT
{
return value;
}
VULKAN_HPP_DEPRECATED("Implicit-cast operators on vk::ResultValue are deprecated. Explicitly access the value as member of ResultValue.")
operator UniqueHandle<Type, Dispatch>() VULKAN_HPP_NOEXCEPT
{
return std::move(value);
}
# endif
Result result;
UniqueHandle<Type, Dispatch> value;
};
template <typename Type, typename Dispatch>
struct ResultValue<std::vector<UniqueHandle<Type, Dispatch>>>
{
# ifdef VULKAN_HPP_HAS_NOEXCEPT
ResultValue( Result r, std::vector<UniqueHandle<Type, Dispatch>> && v ) VULKAN_HPP_NOEXCEPT
# else
ResultValue( Result r, std::vector<UniqueHandle<Type, Dispatch>> && v )
# endif
: result( r )
, value( std::move( v ) )
{}
std::tuple<Result, std::vector<UniqueHandle<Type, Dispatch>>> asTuple()
{
return std::make_tuple( result, std::move( value ) );
}
Result result;
std::vector<UniqueHandle<Type, Dispatch>> value;
# if !defined(VULKAN_HPP_DISABLE_IMPLICIT_RESULT_VALUE_CAST)
VULKAN_HPP_DEPRECATED(
"Implicit-cast operators on vk::ResultValue are deprecated. Explicitly access the value as member of ResultValue." )
operator std::tuple<Result &, std::vector<UniqueHandle<Type, Dispatch>> &>() VULKAN_HPP_NOEXCEPT
{
return std::tuple<Result &, std::vector<UniqueHandle<Type, Dispatch>> &>( result, value );
}
# endif
};
#endif
template <typename T>
struct ResultValueType
{
#ifdef VULKAN_HPP_NO_EXCEPTIONS
typedef ResultValue<T> type;
#else
typedef T type;
#endif
};
template <>
struct ResultValueType<void>
{
#ifdef VULKAN_HPP_NO_EXCEPTIONS
typedef Result type;
#else
typedef void type;
#endif
};
VULKAN_HPP_INLINE ResultValueType<void>::type createResultValue( Result result, char const * message )
{
#ifdef VULKAN_HPP_NO_EXCEPTIONS
ignore(message);
VULKAN_HPP_ASSERT_ON_RESULT( result == Result::eSuccess );
return result;
#else
if ( result != Result::eSuccess )
{
throwResultException( result, message );
}
#endif
}
template <typename T>
VULKAN_HPP_INLINE typename ResultValueType<T>::type createResultValue( Result result, T & data, char const * message )
{
#ifdef VULKAN_HPP_NO_EXCEPTIONS
ignore(message);
VULKAN_HPP_ASSERT_ON_RESULT( result == Result::eSuccess );
return ResultValue<T>( result, std::move( data ) );
#else
if ( result != Result::eSuccess )
{
throwResultException( result, message );
}
return std::move( data );
#endif
}
VULKAN_HPP_INLINE Result createResultValue( Result result, char const * message, std::initializer_list<Result> successCodes )
{
#ifdef VULKAN_HPP_NO_EXCEPTIONS
ignore(message);
ignore(successCodes); // just in case VULKAN_HPP_ASSERT_ON_RESULT is empty
VULKAN_HPP_ASSERT_ON_RESULT( std::find( successCodes.begin(), successCodes.end(), result ) != successCodes.end() );
#else
if ( std::find( successCodes.begin(), successCodes.end(), result ) == successCodes.end() )
{
throwResultException( result, message );
}
#endif
return result;
}
template <typename T>
VULKAN_HPP_INLINE ResultValue<T> createResultValue( Result result, T & data, char const * message, std::initializer_list<Result> successCodes )
{
#ifdef VULKAN_HPP_NO_EXCEPTIONS
ignore(message);
ignore(successCodes); // just in case VULKAN_HPP_ASSERT_ON_RESULT is empty
VULKAN_HPP_ASSERT_ON_RESULT( std::find( successCodes.begin(), successCodes.end(), result ) != successCodes.end() );
#else
if ( std::find( successCodes.begin(), successCodes.end(), result ) == successCodes.end() )
{
throwResultException( result, message );
}
#endif
return ResultValue<T>( result, std::move( data ) );
}
#ifndef VULKAN_HPP_NO_SMART_HANDLE
template <typename T, typename D>
VULKAN_HPP_INLINE typename ResultValueType<UniqueHandle<T,D>>::type createResultValue( Result result, T & data, char const * message, typename UniqueHandleTraits<T,D>::deleter const & deleter )
{
#ifdef VULKAN_HPP_NO_EXCEPTIONS
ignore(message);
VULKAN_HPP_ASSERT_ON_RESULT( result == Result::eSuccess );
return ResultValue<UniqueHandle<T,D>>( result, UniqueHandle<T,D>(data, deleter ) );
#else
if ( result != Result::eSuccess )
{
throwResultException( result, message );
}
return UniqueHandle<T,D>(data, deleter );
#endif
}
template <typename T, typename D>
VULKAN_HPP_INLINE ResultValue<UniqueHandle<T, D>>
createResultValue( Result result,
T & data,
char const * message,
std::initializer_list<Result> successCodes,
typename UniqueHandleTraits<T, D>::deleter const & deleter )
{
# ifdef VULKAN_HPP_NO_EXCEPTIONS
ignore( message );
ignore(successCodes); // just in case VULKAN_HPP_ASSERT_ON_RESULT is empty
VULKAN_HPP_ASSERT_ON_RESULT( std::find( successCodes.begin(), successCodes.end(), result ) != successCodes.end() );
# else
if ( std::find( successCodes.begin(), successCodes.end(), result ) == successCodes.end() )
{
throwResultException( result, message );
}
# endif
return ResultValue<UniqueHandle<T, D>>( result, UniqueHandle<T, D>( data, deleter ) );
}
template <typename T, typename D>
VULKAN_HPP_INLINE typename ResultValueType<std::vector<UniqueHandle<T, D>>>::type
createResultValue( Result result, std::vector<UniqueHandle<T, D>> && data, char const * message )
{
# ifdef VULKAN_HPP_NO_EXCEPTIONS
ignore( message );
VULKAN_HPP_ASSERT_ON_RESULT( result == Result::eSuccess );
return ResultValue<std::vector<UniqueHandle<T, D>>>( result, std::move( data ) );
# else
if ( result != Result::eSuccess )
{
throwResultException( result, message );
}
return std::move( data );
# endif
}
template <typename T, typename D>
VULKAN_HPP_INLINE ResultValue<std::vector<UniqueHandle<T, D>>>
createResultValue( Result result,
std::vector<UniqueHandle<T, D>> && data,
char const * message,
std::initializer_list<Result> successCodes )
{
# ifdef VULKAN_HPP_NO_EXCEPTIONS
ignore( message );
ignore(successCodes); // just in case VULKAN_HPP_ASSERT_ON_RESULT is empty
VULKAN_HPP_ASSERT_ON_RESULT( std::find( successCodes.begin(), successCodes.end(), result ) != successCodes.end() );
# else
if ( std::find( successCodes.begin(), successCodes.end(), result ) == successCodes.end() )
{
throwResultException( result, message );
}
# endif
return ResultValue<std::vector<UniqueHandle<T, D>>>( result, std::move( data ) );
}
#endif
)";
static const std::string typeTraits = R"(
template <typename EnumType, EnumType value>
struct CppType
{};
template <typename Type>
struct isVulkanHandleType
{
static VULKAN_HPP_CONST_OR_CONSTEXPR bool value = false;
};
)";
try
{
tinyxml2::XMLDocument doc;
std::string filename = ( argc == 1 ) ? VK_SPEC : argv[1];
std::cout << "VulkanHppGenerator: Loading " << filename << std::endl;
tinyxml2::XMLError error = doc.LoadFile( filename.c_str() );
if ( error != tinyxml2::XML_SUCCESS )
{
std::cout << "VulkanHppGenerator: failed to load file " << filename << " with error <" << toString( error ) << ">"
<< std::endl;
return -1;
}
std::cout << "VulkanHppGenerator: Parsing " << filename << std::endl;
VulkanHppGenerator generator( doc );
std::cout << "VulkanHppGenerator: Generating " << VULKAN_ENUMS_HPP_FILE << " ..." << std::endl;
std::string str;
str = generator.getVulkanLicenseHeader();
str += +R"(
#ifndef VULKAN_ENUMS_HPP
# define VULKAN_ENUMS_HPP
namespace VULKAN_HPP_NAMESPACE
{
)";
str += typeTraits;
str += generator.generateEnums();
str += generator.generateIndexTypeTraits();
str += generator.generateBitmasks();
str += R"(
} // namespace VULKAN_HPP_NAMESPACE
#endif
)";
writeToFile( str, VULKAN_ENUMS_HPP_FILE );
std::cout << "VulkanHppGenerator: Generating " << VULKAN_HANDLES_HPP_FILE << " ..." << std::endl;
str.clear();
str = generator.getVulkanLicenseHeader();
str += +R"(
#ifndef VULKAN_HANDLES_HPP
# define VULKAN_HANDLES_HPP
namespace VULKAN_HPP_NAMESPACE
{
)";
str += generator.generateStructForwardDeclarations();
str += generator.generateHandles();
str += R"(
} // namespace VULKAN_HPP_NAMESPACE
#endif
)";
writeToFile( str, VULKAN_HANDLES_HPP_FILE );
std::cout << "VulkanHppGenerator: Generating " << VULKAN_STRUCTS_HPP_FILE << " ..." << std::endl;
str.clear();
str = generator.getVulkanLicenseHeader();
str += +R"(
#ifndef VULKAN_STRUCTS_HPP
# define VULKAN_STRUCTS_HPP
namespace VULKAN_HPP_NAMESPACE
{
)";
str += generator.generateStructs();
str += R"(
} // namespace VULKAN_HPP_NAMESPACE
#endif
)";
writeToFile( str, VULKAN_STRUCTS_HPP_FILE );
std::cout << "VulkanHppGenerator: Generating " << VULKAN_FUNCS_HPP_FILE << " ..." << std::endl;
str.clear();
str = generator.getVulkanLicenseHeader();
str += +R"(
#ifndef VULKAN_FUNCS_HPP
# define VULKAN_FUNCS_HPP
namespace VULKAN_HPP_NAMESPACE
{
)";
str += generator.generateCommandDefinitions();
str += R"(
} // namespace VULKAN_HPP_NAMESPACE
#endif
)";
writeToFile( str, VULKAN_FUNCS_HPP_FILE );
std::cout << "VulkanHppGenerator: Generating " << VULKAN_HPP_FILE << " ..." << std::endl;
str.clear();
str += generator.getVulkanLicenseHeader() + includes + "\n";
str += "static_assert( VK_HEADER_VERSION == " + generator.getVersion() +
" , \"Wrong VK_HEADER_VERSION!\" );\n"
"\n";
str +=
"// 32-bit vulkan is not typesafe for handles, so don't allow copy constructors on this platform by default.\n"
"// To enable this feature on 32-bit platforms please define VULKAN_HPP_TYPESAFE_CONVERSION\n" +
generator.getTypesafeCheck() +
"\n"
"# if !defined( VULKAN_HPP_TYPESAFE_CONVERSION )\n"
"# define VULKAN_HPP_TYPESAFE_CONVERSION\n"
"# endif\n"
"#endif\n";
str += defines + "\n" + "namespace VULKAN_HPP_NAMESPACE\n" + "{" + classArrayProxy + classArrayWrapper +
classFlags + classOptional + classStructureChain + classUniqueHandle;
str += dispatchLoaderBase;
str += generator.generateDispatchLoaderStatic();
str += dispatchLoaderDefault;
str += classObjectDestroy + classObjectFree + classObjectRelease + classPoolFree + "\n";
str += generator.generateBaseTypes();
str += R"(} // namespace VULKAN_HPP_NAMESPACE
#include <vulkan/vulkan_enums.hpp>
#ifndef VULKAN_HPP_NO_EXCEPTIONS
namespace std
{
template <>
struct is_error_code_enum<VULKAN_HPP_NAMESPACE::Result> : public true_type
{};
}
#endif
namespace VULKAN_HPP_NAMESPACE
{
#ifndef VULKAN_HPP_NO_EXCEPTIONS
)";
str += exceptions;
str += generator.generateResultExceptions();
str += generator.generateThrowResultException();
str += "#endif\n" + structResultValue;
str += R"(} // namespace VULKAN_HPP_NAMESPACE
// clang-format off
#include <vulkan/vulkan_handles.hpp>
#include <vulkan/vulkan_structs.hpp>
#include <vulkan/vulkan_funcs.hpp>
// clang-format on
namespace VULKAN_HPP_NAMESPACE
{
)";
str += generator.generateStructExtendsStructs();
str += dynamicLoader;
str += generator.generateDispatchLoaderDynamic();
str +=
"} // namespace VULKAN_HPP_NAMESPACE\n"
"\n"
"namespace std\n"
"{\n";
str += generator.generateHashStructures();
str +=
"} // namespace std\n"
"#endif\n";
writeToFile( str, VULKAN_HPP_FILE );
std::cout << "VulkanHppGenerator: Generating " << VULKAN_RAII_HPP_FILE << " ..." << std::endl;
str.clear();
str = generator.getVulkanLicenseHeader() + R"(
#ifndef VULKAN_RAII_HPP
# define VULKAN_RAII_HPP
#include <vulkan/vulkan.hpp>
#if !defined( VULKAN_HPP_RAII_NAMESPACE )
# define VULKAN_HPP_RAII_NAMESPACE raii
#endif
namespace VULKAN_HPP_NAMESPACE
{
namespace VULKAN_HPP_RAII_NAMESPACE
{
#if !defined( VULKAN_HPP_DISABLE_ENHANCED_MODE ) && !defined(VULKAN_HPP_NO_EXCEPTIONS)
template <class T, class U = T>
VULKAN_HPP_CONSTEXPR_14 VULKAN_HPP_INLINE T exchange( T & obj, U && newValue )
{
# if ( 14 <= VULKAN_HPP_CPP_VERSION )
return std::exchange<T>( obj, std::forward<U>( newValue ) );
# else
T oldValue = std::move( obj );
obj = std::forward<U>( newValue );
return oldValue;
# endif
}
)";
generator.prepareRAIIHandles();
str += generator.generateRAIIDispatchers();
str += generator.generateRAIIHandles();
str += generator.generateRAIICommandDefinitions();
str += R"(
#endif
} // namespace VULKAN_HPP_RAII_NAMESPACE
} // namespace VULKAN_HPP_NAMESPACE
#endif
)";
writeToFile( str, VULKAN_RAII_HPP_FILE );
#if !defined( CLANG_FORMAT_EXECUTABLE )
std::cout
<< "VulkanHppGenerator: could not find clang-format. The generated files will not be formatted accordingly.\n";
#endif
}
catch ( std::exception const & e )
{
std::cout << "caught exception: " << e.what() << std::endl;
return -1;
}
catch ( ... )
{
std::cout << "caught unknown exception" << std::endl;
return -1;
}
}