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Vulkan-Hpp/VulkanHppGenerator.cpp

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// 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 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 );
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 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 );
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() + ";\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
{};
${indexTypeTraits}
)";
auto indexType = m_enums.find( "VkIndexType" );
assert( indexType != m_enums.end() );
std::string indexTypeTraits;
std::set<std::string> seenCppTypes;
for ( auto const & value : indexType->second.values )
{
std::string valueName = generateEnumValueName( indexType->first, value.name, false, m_tags );
std::string cppType;
if ( beginsWith( valueName, "eUint8" ) )
{
cppType = "uint8_t";
}
else if ( beginsWith( valueName, "eUint16" ) )
{
cppType = "uint16_t";
}
else if ( beginsWith( valueName, "eUint32" ) )
{
cppType = "uint32_t";
}
else if ( beginsWith( valueName, "eUint64" ) )
{
cppType = "uint64_t"; // No extension for this currently
}
else
{
assert( beginsWith( valueName, "eNone" ) );
}
if ( !cppType.empty() )
{
if ( seenCppTypes.insert( cppType ).second )
{
// IndexType traits aren't necessarily invertible.
// The Type -> Enum translation will only occur for the first prefixed enum value.
// A hypothetical extension to this enum with a conflicting prefix will use the core spec value.
const std::string typeToEnumTemplate = R"(
template <>
struct IndexTypeValue<${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 )
: vkGetInstanceProcAddr( getProcAddr )
{}
#if defined( VULKAN_HPP_RAII_ENABLE_DEFAULT_CONSTRUCTORS )
InstanceDispatcher() = default;
#endif
void init( VkInstance instance )
{
${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 )
: vkGetDeviceProcAddr( getProcAddr )
{}
#if defined( VULKAN_HPP_RAII_ENABLE_DEFAULT_CONSTRUCTORS )
DeviceDispatcher() = default;
#endif
void init( VkDevice device )
{
${deviceAssignments}
}
public:
${deviceMembers}
};
)";
str += replaceWithMap( deviceDispatcherTemplate,
{ { "deviceAssignments", deviceAssignments }, { "deviceMembers", deviceMembers } } );
return str;
}
std::string VulkanHppGenerator::generateRAIIHandles() const
{
const std::string raiiHandlesTemplate = R"(
//====================
//=== RAII HANDLES ===
//====================
${raiiHandles}
)";
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, { { "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" ) )
{
std::string enter, leave;
std::tie( 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 str =
"\n"
" [[noreturn]] static void throwResultException( Result result, char const * message )\n"
" {\n"
" switch ( result )\n"
" {\n";
for ( auto const & value : enumIt->second.values )
{
if ( beginsWith( value.name, "VK_ERROR" ) )
{
std::string enter, leave;
std::tie( enter, leave ) = generateProtection( value.extension, value.protect );
std::string valueName = generateEnumValueName( enumIt->first, value.name, false, m_tags );
str += enter + " case Result::" + valueName + ": throw " + stripPrefix( valueName, "eError" ) +
"Error( message );\n" + leave;
}
}
str +=
" default: throw SystemError( make_error_code( result ) );\n"
" }\n"
" }\n";
return str;
}
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, m_RAIISpecialFunctions );
}
}
distributeSecondLevelCommands( m_RAIISpecialFunctions );
renameFunctionParameters();
}
//
// 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() )
{
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 );
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() )
{
EnumData flagBitsData( 0 );
flagBitsData.isBitmask = true;
m_enums.insert( std::make_pair( flagBits, flagBitsData ) );
assert( m_types.find( flagBits ) == m_types.end() );
TypeData typeData( TypeCategory::Bitmask );
typeData.referencedIn = referencedIn;
m_types.insert( std::make_pair( flagBits, typeData ) );
}
else
{
assert( m_types.find( flagBits ) != m_types.end() );
}
assert( std::find_if( require.types.begin(),
require.types.end(),
[&flagBits]( std::string const & type )
{ return ( type == flagBits ); } ) == require.types.end() );
newTypes.push_back( flagBits );
}
}
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() )
{
std::string enter, leave;
std::tie( enter, leave ) = std::tie( 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" );
}
}
}
}
}
std::string enter, leave;
std::tie( 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 reach "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;
};
auto singularCommandIt =
std::find_if( constructorIts.begin(), constructorIts.end(), isEquivalentSingularConstructor );
return ( singularCommandIt != 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 to 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 = ( structureIt != m_structures.end() );
if ( found )
{
found = structureIt->second.isUnion;
for ( auto memberIt = structureIt->second.members.begin(); memberIt != structureIt->second.members.end() && !found;
++memberIt )
{
found = memberIt->type.prefix.empty() && memberIt->type.postfix.empty() && 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() );
handleIt = m_handles.find( commandIt->second.params[1].type.type );
assert( handleIt != m_handles.end() );
return 2;
}
else
{
return handleIt->first.empty() ? 0 : 1;
}
}
std::vector<size_t>
VulkanHppGenerator::determineNonConstPointerParamIndices( 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,
std::set<std::string> & specialFunctions ) 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 )
{
specialFunctions.insert( commandIt->first );
// 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::generateArgumentEnhancedConstPointer( ParamData const & param,
bool definition,
bool withAllocators,
#if !defined( NDEBUG )
bool withDispatcher,
#endif
bool & hasDefaultAssignment ) const
{
std::string argument;
std::string name = startLowerCase( stripPrefix( param.name, "p" ) );
if ( param.len.empty() )
{
assert( withDispatcher || !isHandleType( param.type.type ) );
assert( !param.type.prefix.empty() && ( param.type.postfix == "*" ) );
assert( param.arraySizes.empty() );
if ( param.type.type == "void" )
{
assert( !param.optional );
argument = param.type.compose() + " " + param.name;
}
else if ( param.optional )
{
argument = "Optional<const " + stripPrefix( param.type.type, "Vk" ) + "> " + name +
( ( definition || withAllocators ) ? "" : " VULKAN_HPP_DEFAULT_ARGUMENT_NULLPTR_ASSIGNMENT" );
hasDefaultAssignment = true;
}
else
{
argument = param.type.prefix + " " + stripPrefix( param.type.type, "Vk" ) + " & " + name;
}
}
else
{
// a const-pointer with a non-empty len is either null-terminated (aka a string) or represented by an
// ArrayProxy
assert( param.arraySizes.empty() );
if ( param.len == "null-terminated" )
{
assert( param.type.type == "char" );
if ( param.optional )
{
argument = "Optional<const std::string> " + name +
( ( definition || withAllocators ) ? "" : " VULKAN_HPP_DEFAULT_ARGUMENT_NULLPTR_ASSIGNMENT" );
hasDefaultAssignment = true;
}
else
{
argument = "const std::string & " + name;
}
}
else
{
// an ArrayProxy also covers no data, so any optiona flag can be ignored here
assert( endsWith( param.type.postfix, "*" ) );
std::string type = stripPostfix( param.type.compose(), "*" );
size_t pos = type.find( "void" );
if ( pos != std::string::npos )
{
type.replace( pos, 4, "T" );
}
argument = "ArrayProxy<" + type + "> const & " + name;
if ( param.optional && !definition )
{
argument += " VULKAN_HPP_DEFAULT_ARGUMENT_NULLPTR_ASSIGNMENT";
hasDefaultAssignment = true;
}
}
}
return argument;
}
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;
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 ) );
argumentList += "const VULKAN_HPP_NAMESPACE::" + stripPrefix( params[i].type.type, "Vk" ) + " & " +
stripPluralS( startLowerCase( stripPrefix( params[i].name, "p" ) ) );
}
else if ( params[i].type.isConstPointer() )
{
argumentList += generateArgumentEnhancedConstPointer( params[i],
definition,
withAllocators,
#if !defined( NDEBUG )
withDispatcher,
#endif
hasDefaultAssignment );
}
else if ( params[i].type.isNonConstPointer() )
{
assert( withDispatcher || !isHandleType( params[i].type.type ) );
assert( params[i].len.empty() && !params[i].optional );
argumentList += params[i].type.prefix + ( params[i].type.prefix.empty() ? "" : " " ) + params[i].type.type +
" & " + params[i].name;
}
else
{
assert( params[i].type.isValue() );
argumentList += params[i].type.compose() + " " + 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() + " " + 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;
std::tie( allFlags, toStringChecks ) = generateBitmaskValues( bitmaskIt, bitmaskBitsIt );
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::pair<std::string, std::string>
VulkanHppGenerator::generateBitmaskValues( std::map<std::string, BitmaskData>::const_iterator bitmaskIt,
std::map<std::string, EnumData>::const_iterator bitmaskBitsIt ) const
{
assert( !bitmaskBitsIt->second.values.empty() );
std::string allFlags, toStringChecks;
std::string strippedEnumName = stripPrefix( bitmaskBitsIt->first, "Vk" );
bool encounteredFlag = false;
std::string previousEnter, previousLeave;
for ( auto const & value : bitmaskBitsIt->second.values )
{
std::string enter, leave;
std::tie( 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;
}
return std::make_pair( allFlags, toStringChecks );
}
std::string VulkanHppGenerator::generateCallArgumentsEnhanced( std::vector<ParamData> const & params,
size_t initialSkipCount,
bool nonConstPointerAsNullptr,
std::set<size_t> const & singularParams,
bool raiiHandleMemberFunction ) const
{
assert( initialSkipCount <= params.size() );
std::string arguments;
bool encounteredArgument = false;
for ( size_t i = 0; i < initialSkipCount; ++i )
{
if ( encounteredArgument )
{
arguments += ", ";
}
assert( isHandleType( params[i].type.type ) && params[i].type.isValue() );
assert( params[i].arraySizes.empty() && params[i].len.empty() );
std::string argument = "m_" + startLowerCase( stripPrefix( params[i].type.type, "Vk" ) );
if ( raiiHandleMemberFunction )
{
argument = "static_cast<" + params[i].type.type + ">( " + argument + " )";
}
arguments += argument;
encounteredArgument = true;
}
for ( size_t i = initialSkipCount; i < params.size(); ++i )
{
if ( encounteredArgument )
{
arguments += ", ";
}
arguments +=
generateCallArgumentEnhanced( params, i, nonConstPointerAsNullptr, singularParams, raiiHandleMemberFunction );
encounteredArgument = true;
}
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.prefix == "const" );
argument = "reinterpret_cast<const " + param.type.type + "*>( " + argument + " )";
}
else if ( param.type.isValue() )
{
argument = "static_cast<" + param.type.type + ">( " + argument + " )";
}
else
{
assert( !param.type.postfix.empty() );
argument = "reinterpret_cast<" + ( param.type.prefix.empty() ? "" : param.type.prefix ) + " " +
param.type.type + " " + param.type.postfix + ">( " + 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() + ">( " + name + " )";
}
else
{
argument = "&" + name;
}
if ( beginsWith( param.type.type, "Vk" ) )
{
argument = "reinterpret_cast<const " + param.type.type + " *>( " + 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.prefix + " " + param.type.type + " " + param.type.postfix + ">( " +
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.type + " *>( &" + 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.type + " *>( " + 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.type + ">( " + param.name + " )";
}
}
else
{
assert( !param.optional );
assert( param.arraySizes.size() == 1 );
assert( param.type.prefix == "const" );
argument = "reinterpret_cast<const " + param.type.type + " *>( " + 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 = determineNonConstPointerParamIndices( 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 strippedName = startLowerCase( stripPrefix( commandIt->first, "vk" ) );
std::string str = "\n";
str += 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 ) && isupper( searchName[0] ) )
{
searchName[0] = static_cast<char>( tolower( searchName[0] ) );
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 ) && isupper( commandName[0] ) )
{
commandName[0] = static_cast<char>( tolower( commandName[0] ) );
}
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.params, 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} ) );
VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() );
}
} while ( result == Result::eIncomplete );
if ( ( result == Result::eSuccess ) && ( ${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.params, initialSkipCount, true, {}, false ) },
{ "nodiscard", nodiscard },
{ "secondCallArguments",
generateCallArgumentsEnhanced( commandData.params, 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::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" );
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.params, initialSkipCount, true, {}, false ) },
{ "firstVectorName", startLowerCase( stripPrefix( commandData.params[firstVectorParamIt->first].name, "p" ) ) },
{ "nodiscard", nodiscard },
{ "pairConstructor", pairConstructor },
{ "secondCallArguments",
generateCallArgumentsEnhanced( commandData.params, 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}( ${argumentList} ) const;)";
std::string typenameCheck =
withAllocators
? ( ", typename B1 = " + templateTypeFirst + "Allocator, typename B2 = " + templateTypeSecond +
"Allocator, typename std::enable_if<std::is_same<typename B1::value_type, " + templateTypeFirst +
">::value && std::is_same<typename B2::value_type, " + templateTypeSecond + ">::value, int>::type = 0" )
: "";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "templateTypeFirst", templateTypeFirst },
{ "templateTypeSecond", templateTypeSecond },
{ "typenameCheck", typenameCheck } } );
}
}
std::string VulkanHppGenerator::generateCommandResultEnumerateTwoVectorsDeprecated(
std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::map<size_t, size_t> const & vectorParamIndices,
bool withAllocators ) const
{
std::vector<size_t> rpis = determineNonConstPointerParamIndices( commandData.params );
assert( !rpis.empty() && ( rpis.back() + 1 == commandData.params.size() ) );
size_t returnParamIndex = rpis.back();
std::string argumentList = generateFunctionHeaderArgumentsEnhanced( commandData,
returnParamIndex,
returnParamIndex,
initialSkipCount,
vectorParamIndices,
!definition,
withAllocators );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnType = generateEnhancedReturnType( commandData, returnParamIndex, false );
std::string templateType = stripPrefix( commandData.params[returnParamIndex].type.type, "Vk" );
if ( definition )
{
const std::string functionTemplate =
R"( template <typename Allocator, typename Dispatch${typeCheck}>
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 );
${functionBody}
})";
std::string typeCheck = withAllocators
? ", typename B, typename std::enable_if<std::is_same<typename B::value_type, " +
templateType + ">::value, int>::type"
: "";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "functionBody",
generateFunctionBodyEnhanced( name,
commandData,
initialSkipCount,
returnParamIndex,
returnParamIndex,
vectorParamIndices,
true,
returnType,
withAllocators ) },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "typeCheck", typeCheck } } );
}
else
{
const std::string functionTemplate =
R"( template <typename Allocator = std::allocator<${templateType}>, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE${typeCheck}>
${nodiscard}typename ResultValueType<${returnType}>::type ${commandName}( ${argumentList} ) const;)";
std::string typeCheck =
withAllocators ? ", typename B = Allocator, typename std::enable_if<std::is_same<typename B::value_type, " +
templateType + ">::value, int>::type = 0"
: "";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "templateType", templateType },
{ "typeCheck", typeCheck } } );
}
}
std::string VulkanHppGenerator::generateCommandResultGetChain( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t nonConstPointerIndex ) const
{
assert( !commandData.handle.empty() && ( commandData.returnType == "VkResult" ) && !commandData.errorCodes.empty() );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, {}, { nonConstPointerIndex }, 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() );
assert( beginsWith( commandData.params[nonConstPointerIndex].type.type, "Vk" ) );
std::string returnType =
"VULKAN_HPP_NAMESPACE::" + stripPrefix( commandData.params[nonConstPointerIndex].type.type, "Vk" );
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.params, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "returnVariable", startLowerCase( stripPrefix( commandData.params[nonConstPointerIndex].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 nonConstPointerIndex ) const
{
assert( ( commandData.returnType == "VkResult" ) && ( commandData.successCodes.size() == 1 ) );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, {}, { nonConstPointerIndex }, 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 = commandData.params[nonConstPointerIndex].type.compose();
assert( endsWith( returnBaseType, "*" ) );
returnBaseType.pop_back();
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 ) );
assert( ( name.find( "Create" ) != std::string::npos ) || ( name == "vkRegisterDeviceEventEXT" ) ||
( name == "vkRegisterDisplayEventEXT" ) );
objectDeleter = "ObjectDestroy";
allocator = "allocator, ";
}
std::string className =
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "";
std::string parentName =
( className.empty() || ( commandData.params[nonConstPointerIndex].type.type == "VkDevice" ) ) ? "NoParent"
: className;
return replaceWithMap(
functionTemplate,
{ { "allocator", allocator },
{ "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData.params, 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[nonConstPointerIndex].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() );
assert( !beginsWith( commandData.params[returnParamIndices[0]].type.type, "Vk" ) );
std::string singularElementType = commandData.params[returnParamIndices[0]].type.type;
assert( !beginsWith( commandData.params[returnParamIndices[1]].type.type, "Vk" ) );
std::string valueType = commandData.params[returnParamIndices[1]].type.type;
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.params, 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::generateCommandResultGetTwoValues( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::vector<size_t> returnParamIndices ) const
{
assert( returnParamIndices.size() == 2 );
assert( commandData.params[returnParamIndices[0]].type.type != "void" );
assert( commandData.params[returnParamIndices[1]].type.type != "void" );
assert( 1 < commandData.successCodes.size() );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, {}, returnParamIndices, 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 firstReturnType = commandData.params[returnParamIndices[0]].type.compose();
assert( endsWith( firstReturnType, "*" ) );
firstReturnType.pop_back();
std::string secondReturnType = commandData.params[returnParamIndices[1]].type.compose();
assert( endsWith( secondReturnType, "*" ) );
secondReturnType.pop_back();
if ( definition )
{
std::string const functionTemplate =
R"( template <typename Dispatch>
${nodiscard}VULKAN_HPP_INLINE ResultValue<std::pair<${firstReturnType}, ${secondReturnType}>> ${className}${classSeparator}${commandName}( ${argumentList} )${const}
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
std::pair<${firstReturnType}, ${secondReturnType}> returnValue;
${firstReturnType} & ${firstReturnName} = returnValue.first;
${secondReturnType} & ${secondReturnName} = returnValue.second;
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
return createResultValue( result, returnValue, VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}"${successCodeList} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData.params, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "const", commandData.handle.empty() ? "" : " const" },
{ "commandName", commandName },
{ "firstReturnName", startLowerCase( stripPrefix( commandData.params[returnParamIndices[0]].name, "p" ) ) },
{ "firstReturnType", firstReturnType },
{ "secondReturnName", startLowerCase( stripPrefix( commandData.params[returnParamIndices[1]].name, "p" ) ) },
{ "secondReturnType", secondReturnType },
{ "nodiscard", nodiscard },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>
${nodiscard}ResultValue<std::pair<${firstReturnType}, ${secondReturnType}>> ${commandName}( ${argumentList} )${const};)";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "const", commandData.handle.empty() ? "" : " const" },
{ "firstReturnType", firstReturnType },
{ "nodiscard", nodiscard },
{ "secondReturnType", secondReturnType } } );
}
}
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.params, 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 ${noexcept};)";
return replaceWithMap( functionTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
{ "noexcept", noexceptString },
} );
}
}
std::string VulkanHppGenerator::generateCommandResultGetValue( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
assert( commandData.returnType == "VkResult" );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, {}, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, false, false, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
std::string nodiscard = generateNoDiscard( 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() );
std::string returnBaseType = commandData.params[returnParamIndex].type.compose();
assert( endsWith( returnBaseType, "*" ) );
returnBaseType.pop_back();
std::string typenameT;
if ( returnBaseType == "void" )
{
returnBaseType = "T";
typenameT = "typename T, ";
}
std::string returnType = generateReturnType( commandData, returnBaseType );
if ( definition )
{
std::string const functionTemplate =
R"( template <${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}"${successCodeList} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData.params, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "const", commandData.handle.empty() ? "" : " const" },
{ "commandName", commandName },
{ "returnBaseType", returnBaseType },
{ "returnValueName", startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) ) },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "typenameT", typenameT },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <${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() );
assert( !beginsWith( commandData.params[returnParamIndex].type.type, "Vk" ) );
std::string returnType = commandData.params[returnParamIndex].type.type;
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, "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.params, 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, "std::vector<T,Allocator>" );
assert( !beginsWith( commandData.params[returnParamIndices[0]].type.type, "Vk" ) );
std::string vectorElementType = commandData.params[returnParamIndices[0]].type.type;
std::string allocatorType = startUpperCase( vectorElementType ) + "Allocator";
assert( !beginsWith( commandData.params[returnParamIndices[1]].type.type, "Vk" ) );
std::string valueType = commandData.params[returnParamIndices[1]].type.type;
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.params, 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, "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::generateCommandResultGetVectorOfHandles( 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 =
( commandData.successCodes.size() == 1 )
? ( "typename ResultValueType<std::vector<" + handleType + ", " + handleType + "Allocator>>::type" )
: ( "ResultValue<std::vector<" + handleType + ", " + handleType + "Allocator>>" );
if ( definition )
{
std::string const functionTemplate =
R"( template <typename ${handleType}Allocator, typename Dispatch${typenameCheck}>
${nodiscard}VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}( ${argumentList} ) const
{
VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION );
std::vector<${handleType}, ${handleType}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, " +
handleType + ">::value, int>::type " )
: "";
std::string vectorName = startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) );
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData.params, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "handleType", handleType },
{ "returnType", returnType },
{ "typenameCheck", typenameCheck },
{ "successCodeList", generateSuccessCodeList( commandData.successCodes ) },
{ "vectorAllocator", withAllocator ? ( ", " + startLowerCase( handleType ) + "Allocator" ) : "" },
{ "vectorName", vectorName },
{ "vectorSize", getVectorSize( commandData.params, vectorParamIndices, returnParamIndex ) },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <typename ${handleType}Allocator = std::allocator<${handleType}>, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE${typenameCheck}>
${nodiscard}${returnType} ${commandName}( ${argumentList} ) const;)";
std::string typenameCheck = withAllocator
? ( ", typename B = " + handleType +
"Allocator, typename std::enable_if<std::is_same<typename B::value_type, " +
handleType + ">::value, int>::type = 0" )
: "";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "handleType", handleType },
{ "nodiscard", nodiscard },
{ "returnType", returnType },
{ "typenameCheck", typenameCheck } } );
}
}
std::string VulkanHppGenerator::generateCommandResultGetVectorOfHandlesSingular(
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 = ( commandData.successCodes.size() == 1 )
? ( "typename ResultValueType<" + handleType + ">::type" )
: ( "ResultValue<" + handleType + ">" );
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 );
${handleType} ${handleName};
Result result = static_cast<Result>( d.${vkCommand}( ${callArguments} ) );
return createResultValue( result, ${handleName}, VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}"${successCodeList} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments",
generateCallArgumentsEnhanced( commandData.params, initialSkipCount, false, singularParams, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "nodiscard", nodiscard },
{ "handleName",
stripPluralS( startLowerCase( stripPrefix( commandData.params[returnParamIndex].name, "p" ) ) ) },
{ "handleType", handleType },
{ "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 =
( commandData.successCodes.size() == 1 )
? ( "typename ResultValueType<std::vector<UniqueHandle<" + handleType + ", Dispatch>, " + handleType +
"Allocator>>::type" )
: ( "ResultValue<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.params, 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 = ( commandData.successCodes.size() == 1 )
? ( "typename ResultValueType<UniqueHandle<" + handleType + ", Dispatch>>::type" )
: ( "ResultValue<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.params, 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, "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.params, 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 = determineNonConstPointerParamIndices( 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 = determineNonConstPointerParamIndices( 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 ),
generateCommandResultGetVectorOfHandles(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, false ),
generateCommandResultGetVectorOfHandles(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, true ),
generateCommandResultGetVectorOfHandlesSingular(
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.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 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 generateCommandSetStandardEnhancedWithAllocatorDeprecated2(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultEnumerateTwoVectorsDeprecated(
name, commandData, initialSkipCount, definition, vectorParamIndices, false ),
generateCommandResultEnumerateTwoVectorsDeprecated(
name, commandData, initialSkipCount, definition, vectorParamIndices, true ),
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 = determineNonConstPointerParamIndices( 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 = determineNonConstPointerParamIndices( 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 ( 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 if ( commandData.params[returnParamIndex].type.type == "void" )
{
return generateCommandResultSingleSuccessWithErrors1ReturnVoid(
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 generateCommandResultSingleSuccessWithErrors1ReturnHandle0Vector(
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::generateCommandResultSingleSuccessWithErrors1ReturnHandle0Vector( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
size_t returnParamIndex ) const
{
return generateCommandSetStandardEnhancedUnique(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetValue( name, commandData, initialSkipCount, definition, returnParamIndex ),
generateCommandResultGetHandleUnique( name, commandData, initialSkipCount, definition, returnParamIndex ) );
}
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 ),
generateCommandResultGetVectorOfHandles(
name, commandData, initialSkipCount, definition, { vectorParamIndex }, returnParamIndex, false ),
generateCommandResultGetVectorOfHandles(
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 ),
generateCommandResultGetVectorOfHandles(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, false ),
generateCommandResultGetVectorOfHandles(
name, commandData, initialSkipCount, definition, vectorParamIndices, returnParamIndex, true ),
generateCommandResultGetVectorOfHandlesSingular(
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 );
if ( vectorParamIndices.empty() )
{
return generateCommandSetStandardEnhanced(
definition,
generateCommandStandard( name, commandData, initialSkipCount, definition ),
generateCommandResultGetValue( name, commandData, initialSkipCount, definition, 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::generateCommandSetStandardEnhancedWithAllocatorDeprecated2(
bool definition,
std::string const & standard,
std::string const & enhancedDeprecated,
std::string const & enhancedWithAllocatorDeprecated,
std::string const & enhanced,
std::string const & enhancedWithAllocator ) const
{
const std::string commandTemplate = R"(
${commandStandard}${newlineOnDefinition}
#ifndef VULKAN_HPP_DISABLE_ENHANCED_MODE
${commandEnhancedDeprecated}${newlineOnDefinition}
${commandEnhancedWithAllocatorDeprecated}${newlineOnDefinition}
${commandEnhanced}${newlineOnDefinition}
${commandEnhancedWithAllocator}
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap(
commandTemplate,
std::map<std::string, std::string>( { { "commandEnhanced", enhanced },
{ "commandEnhancedDeprecated", enhancedDeprecated },
{ "commandEnhancedWithAllocator", enhancedWithAllocator },
{ "commandEnhancedWithAllocatorDeprecated", enhancedWithAllocatorDeprecated },
{ "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.params, 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 = determineNonConstPointerParamIndices( 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}( ${callArguments} );
})";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", generateCallArgumentsEnhanced( commandData.params, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "noexcept", noexceptString },
{ "typenameT", typenameT },
{ "vectorSizeCheck",
vectorSizeCheck.first
? generateVectorSizeCheck( name, commandData, initialSkipCount, vectorSizeCheck.second, skippedParameters )
: "" },
{ "vkCommand", name } } );
}
else
{
std::string const functionTemplate =
R"( template <${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.params, initialSkipCount, true, {}, false ) },
{ "secondCallArguments",
generateCallArgumentsEnhanced( commandData.params, 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}( ${argumentList} ) const;)";
std::string typenameCheck = withAllocators
? ( ", typename B = " + vectorElementType +
"Allocator, typename std::enable_if<std::is_same<typename B::value_type, " +
vectorElementType + ">::value, int>::type = 0" )
: "";
return replaceWithMap( functionTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "typenameCheck", typenameCheck },
{ "vectorElementType", vectorElementType } } );
}
}
std::string VulkanHppGenerator::generateCommandVoidEnumerateChained( std::string const & name,
CommandData const & commandData,
size_t initialSkipCount,
bool definition,
std::pair<size_t, size_t> const & vectorParamIndex,
std::vector<size_t> const & returnParamIndices,
bool withAllocators ) const
{
assert( ( commandData.params[0].type.type == commandData.handle ) && ( commandData.returnType == "void" ) &&
commandData.successCodes.empty() && commandData.errorCodes.empty() );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, { vectorParamIndex }, returnParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandData.params, skippedParams, {}, definition, withAllocators, true, true );
std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, m_tags );
assert( beginsWith( commandData.params[vectorParamIndex.first].type.type, "Vk" ) );
std::string vectorElementType =
"VULKAN_HPP_NAMESPACE::" + stripPrefix( commandData.params[vectorParamIndex.first].type.type, "Vk" );
if ( definition )
{
const std::string functionTemplate =
R"( template <typename StructureChain, typename StructureChainAllocator, typename Dispatch${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}>() = ${vectorName}[i];
}
return returnVector;
})";
std::string vectorName = startLowerCase( stripPrefix( commandData.params[vectorParamIndex.first].name, "p" ) );
std::string typenameCheck =
withAllocators
? ( ", typename B, typename std::enable_if<std::is_same<typename B::value_type, StructureChain>::value, int>::type" )
: "";
return replaceWithMap(
functionTemplate,
{ { "argumentList", argumentList },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "counterName", startLowerCase( stripPrefix( commandData.params[vectorParamIndex.second].name, "p" ) ) },
{ "counterType", commandData.params[vectorParamIndex.second].type.type },
{ "firstCallArguments",
generateCallArgumentsEnhanced( commandData.params, initialSkipCount, true, {}, false ) },
{ "secondCallArguments",
generateCallArgumentsEnhanced( commandData.params, initialSkipCount, false, {}, false ) },
{ "structureChainAllocator", withAllocators ? ( ", structureChainAllocator" ) : "" },
{ "typenameCheck", typenameCheck },
{ "vectorElementType", vectorElementType },
{ "vectorName", vectorName },
{ "vkCommand", name } } );
}
else
{
const std::string functionTemplate =
R"( template <typename StructureChain, typename StructureChainAllocator = std::allocator<StructureChain>, typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE${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 nonConstPointerIndex ) const
{
assert( ( commandData.returnType == "void" ) && commandData.successCodes.empty() && commandData.errorCodes.empty() );
std::set<size_t> skippedParams =
determineSkippedParams( commandData.params, initialSkipCount, {}, { nonConstPointerIndex }, 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() );
assert( beginsWith( commandData.params[nonConstPointerIndex].type.type, "Vk" ) );
std::string returnType =
"VULKAN_HPP_NAMESPACE::" + stripPrefix( commandData.params[nonConstPointerIndex].type.type, "Vk" );
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.params, initialSkipCount, false, {}, false ) },
{ "className",
initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "" },
{ "classSeparator", commandData.handle.empty() ? "" : "::" },
{ "commandName", commandName },
{ "returnVariable", startLowerCase( stripPrefix( commandData.params[nonConstPointerIndex].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(), "*" );
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.params, 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::pair<std::string, StructureData> const & structData,
bool assignmentOperator ) const
{
// structs with a union (and VkBaseInStructure and VkBaseOutStructure) can't be a constexpr!
bool isConstExpression = !containsUnion( structData.first ) && ( structData.first != "VkBaseInStructure" ) &&
( structData.first != "VkBaseOutStructure" );
return isConstExpression ? ( std::string( "VULKAN_HPP_CONSTEXPR" ) +
( ( containsArray( structData.first ) || assignmentOperator ) ? "_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
{
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.prefix + ( param.type.prefix.empty() ? "" : " " ) + param.type.type +
param.type.postfix + " " + 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 )
{
std::string enter, leave;
std::tie( 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 )
{
std::string enter, leave;
std::tie( 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::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(), "*" ) ) + "> 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 );
}
std::string enter, leave;
std::tie( 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() )
{
std::string enter, leave;
std::tie( 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 ), m_RAIISpecialFunctions, 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 );
std::string enter, leave;
std::tie( enter, leave ) = generateProtection( handle.first, !handle.second.alias.empty() );
std::string handleType = stripPrefix( handle.first, "Vk" );
std::string handleName = startLowerCase( handleType );
std::string singularConstructors, arrayConstructors;
std::tie( singularConstructors, arrayConstructors ) = generateRAIIHandleConstructors( handle );
std::string upgradeConstructor = arrayConstructors.empty() ? "" : generateRAIIHandleUpgradeConstructor( handle );
std::string destructor, destructorCall;
std::tie( destructor, destructorCall ) =
( handle.second.destructorIt == m_commands.end() )
? std::make_pair( "", "" )
: generateRAIIHandleDestructor( handle.first, handle.second.destructorIt, enter );
std::string getConstructorSuccessCode, memberVariables, moveConstructorInitializerList, moveAssignmentInstructions;
std::tie( getConstructorSuccessCode, memberVariables, moveConstructorInitializerList, moveAssignmentInstructions ) =
generateRAIIHandleDetails( handle, destructorCall );
std::string declarations = generateRAIIHandleMemberFunctionDeclarations( 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";
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}
${upgradeConstructor}
${destructor}
#if defined( VULKAN_HPP_RAII_ENABLE_DEFAULT_CONSTRUCTORS )
${handleType}() = default;
#else
${handleType}() = delete;
#endif
${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}
${dispatcherType} const * getDispatcher() const
{
VULKAN_HPP_ASSERT( m_dispatcher${dispatcherAccess}getVkHeaderVersion() == VK_HEADER_VERSION );
return ${getDispatcherReturn}m_dispatcher;
}
#if defined( VULKAN_HPP_RAII_ENABLE_DEFAULT_CONSTRUCTORS )
explicit operator bool() const VULKAN_HPP_NOEXCEPT
{
return m_${handleName}.operator bool();
}
bool operator!() const VULKAN_HPP_NOEXCEPT
{
return m_${handleName}.operator!();
}
#endif
${memberFunctionsDeclarations}
private:
${memberVariables}
};
${leave})";
str += replaceWithMap(
handleTemplate,
{ { "debugReportObjectType", debugReportObjectType },
{ "destructor", destructor },
{ "dispatcherAccess", ( handleType == "Device" ) || ( handleType == "Instance" ) ? "." : "->" },
{ "dispatcherType", dispatcherType },
{ "enter", enter },
{ "getConstructorSuccessCode", getConstructorSuccessCode },
{ "getDispatcherReturn", ( handleType == "Device" ) || ( handleType == "Instance" ) ? "&" : "" },
{ "handleName", handleName },
{ "handleType", handleType },
{ "leave", leave },
{ "memberFunctionsDeclarations", declarations },
{ "memberVariables", memberVariables },
{ "moveAssignmentInstructions", moveAssignmentInstructions },
{ "moveConstructorInitializerList", moveConstructorInitializerList },
{ "objTypeEnum", objTypeEnum },
{ "singularConstructors", singularConstructors },
{ "upgradeConstructor", upgradeConstructor } } );
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}
#if defined( VULKAN_HPP_RAII_ENABLE_DEFAULT_CONSTRUCTORS )
${handleType}s() = default;
#else
${handleType}s() = delete;
#endif
${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,
std::set<std::string> const & specialFunctions,
bool definition ) const
{
std::string str;
if ( specialFunctions.find( command ) == specialFunctions.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 str like <" + commandIt->first + "> !" );
}
}
return str;
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultMultiSuccessWithErrors(
std::map<std::string, CommandData>::const_iterator commandIt, size_t initialSkipCount, bool definition ) const
{
std::vector<size_t> returnParamIndices = determineNonConstPointerParamIndices( 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.params, 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;
assert( !isHandleType( commandIt->second.params[returnParamIndex].type.type ) );
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 ( !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 & nonConstPointerParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, 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[nonConstPointerParamIndices[0]].type.compose(), "*" );
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.params, initialSkipCount, false, {}, true );
std::string valueName =
startLowerCase( stripPrefix( commandIt->second.params[nonConstPointerParamIndices[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 & nonConstPointerParamIndices,
bool definition ) const
{
assert( nonConstPointerParamIndices.size() == 1 );
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, true );
std::set<size_t> singularParams = determineSingularParams( nonConstPointerParamIndices[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.params, initialSkipCount, false, singularParams, true );
std::string dataName =
startLowerCase( stripPrefix( commandIt->second.params[nonConstPointerParamIndices[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 & nonConstPointerParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, 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.params, initialSkipCount, false, {}, true );
std::string dataName =
startLowerCase( stripPrefix( commandIt->second.params[nonConstPointerParamIndices[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[nonConstPointerParamIndices[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" ) )
{
if ( !isStructureChainAnchor( 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 )
{
if ( ( commandIt->second.successCodes.size() == 2 ) &&
( commandIt->second.successCodes[0] == "VK_SUCCESS" ) &&
( commandIt->second.successCodes[1] == "VK_INCOMPLETE" ) )
{
return generateRAIIHandleCommandResultMultiSuccessWithErrors2Return1VectorEnumerate(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndices, definition );
}
}
}
}
}
}
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 & nonConstPointerParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, 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(), "*" );
}
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} ) );
VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() );
}
} while ( result == VULKAN_HPP_NAMESPACE::Result::eIncomplete );
if ( ( result == VULKAN_HPP_NAMESPACE::Result::eSuccess ) && ( ${counterName} < ${vectorName}.size() ) )
{
${vectorName}.resize( ${counterName} );
}
if ( result != VULKAN_HPP_NAMESPACE::Result::eSuccess )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return ${vectorName};
}
)";
std::string counterName =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->second].name, "p" ) );
std::string firstCallArguments =
generateCallArgumentsEnhanced( commandIt->second.params, initialSkipCount, true, {}, true );
std::string secondCallArguments =
generateCallArgumentsEnhanced( commandIt->second.params, initialSkipCount, false, {}, true );
std::string vectorName =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->first].name, "p" ) );
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "className",
initialSkipCount ? stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" )
: "Context" },
{ "commandName", commandName },
{ "counterName", counterName },
{ "counterType", commandIt->second.params[vectorParamIndices.begin()->second].type.type },
{ "firstCallArguments", firstCallArguments },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "secondCallArguments", secondCallArguments },
{ "vectorElementType", vectorElementType },
{ "vectorName", vectorName },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::vector<${vectorElementType}> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
{ "vectorElementType", vectorElementType },
} );
}
}
std::string VulkanHppGenerator::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 & nonConstPointerParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, 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}::${commandName}" );
}
return data;
}
)";
std::string firstCallArguments =
generateCallArgumentsEnhanced( commandIt->second.params, initialSkipCount, true, {}, true );
std::string firstVectorName =
startLowerCase( stripPrefix( commandIt->second.params[firstVectorParamIt->first].name, "p" ) );
std::string secondCallArguments =
generateCallArgumentsEnhanced( commandIt->second.params, initialSkipCount, false, {}, true );
std::string secondVectorName =
startLowerCase( stripPrefix( commandIt->second.params[secondVectorParamIt->first].name, "p" ) );
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "counterName", counterName },
{ "counterType", commandIt->second.params[firstVectorParamIt->second].type.type },
{ "firstCallArguments", firstCallArguments },
{ "firstType", firstType },
{ "firstVectorName", firstVectorName },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "secondCallArguments", secondCallArguments },
{ "secondType", secondType },
{ "secondVectorName", secondVectorName },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::pair<std::vector<${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 = determineNonConstPointerParamIndices( 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.params, 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 = determineNonConstPointerParamIndices( 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.params, 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 & nonConstPointerParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, 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.params, initialSkipCount, false, {}, true );
std::string returnType =
stripPostfix( commandIt->second.params[nonConstPointerParamIndices[0]].type.compose(), "*" );
std::string returnVariable =
startLowerCase( stripPrefix( commandIt->second.params[nonConstPointerParamIndices[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;
assert( !isHandleType( commandIt->second.params[returnParamIndex].type.type ) );
if ( isStructureChainAnchor( commandIt->second.params[returnParamIndex].type.type ) )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
if ( vectorParamIndices.empty() )
{
str = generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnValue(
commandIt, initialSkipCount, vectorParamIndices, { returnParamIndex }, definition );
str += generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnChain(
commandIt, initialSkipCount, vectorParamIndices, { returnParamIndex }, definition );
}
}
else if ( commandIt->second.params[returnParamIndex].type.type != "void" )
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
if ( vectorParamIndices.empty() )
{
str = generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnValue(
commandIt, initialSkipCount, vectorParamIndices, { returnParamIndex }, definition );
}
}
else
{
std::map<size_t, size_t> vectorParamIndices = determineVectorParamIndices( commandIt->second.params );
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;
}
}
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,
std::vector<size_t> const & nonConstPointerParamIndices,
bool definition ) const
{
assert( nonConstPointerParamIndices.size() == 1 );
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, 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[nonConstPointerParamIndices[0]].type.compose(), "*" );
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.params, initialSkipCount, false, {}, true );
std::string valueName =
startLowerCase( stripPrefix( commandIt->second.params[nonConstPointerParamIndices[0]].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::generateRAIIHandleCommandResultSingleSuccessWithErrors1ReturnVoidSingular(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & nonConstPointerParamIndices,
bool definition ) const
{
assert( nonConstPointerParamIndices.size() == 1 );
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, true );
std::set<size_t> singularParams = determineSingularParams( nonConstPointerParamIndices[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 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.params, initialSkipCount, false, singularParams, true );
std::string dataName =
startLowerCase( stripPrefix( commandIt->second.params[nonConstPointerParamIndices[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 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,
std::vector<size_t> const & nonConstPointerParamIndices,
bool definition ) const
{
assert( nonConstPointerParamIndices.size() == 1 );
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, 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.params, initialSkipCount, false, {}, true );
std::string dataName =
startLowerCase( stripPrefix( commandIt->second.params[nonConstPointerParamIndices[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[nonConstPointerParamIndices[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::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}::${commandName}" );
}
return data;
}
)";
std::string callArguments =
generateCallArgumentsEnhanced( commandIt->second.params, initialSkipCount, false, singularParams, true );
std::string valueName = startLowerCase( stripPrefix( commandIt->second.params[returnParamIndices[1]].name, "p" ) );
std::string singularName =
startLowerCase( stripPluralS( stripPrefix( commandIt->second.params[returnParamIndices[0]].name, "p" ) ) );
std::string vectorSize =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->first].name, "p" ) ) +
".size()";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "singularElementType", singularElementType },
{ "valueName", valueName },
{ "singularName", singularName },
{ "valueType", valueType },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::pair<${singularElementType}, ${valueType}> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "singularElementType", singularElementType },
{ "valueType", valueType } } );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandResultSingleSuccessWithErrors2ReturnValueVectorValue(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & nonConstPointerParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string valueType = commandIt->second.params[nonConstPointerParamIndices[1]].type.type;
std::string vectorElementType = commandIt->second.params[nonConstPointerParamIndices[0]].type.type;
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::pair<std::vector<${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}::${commandName}" );
}
return data;
}
)";
std::string callArguments =
generateCallArgumentsEnhanced( commandIt->second.params, initialSkipCount, false, {}, true );
std::string valueName =
startLowerCase( stripPrefix( commandIt->second.params[nonConstPointerParamIndices[1]].name, "p" ) );
std::string vectorName =
startLowerCase( stripPrefix( commandIt->second.params[nonConstPointerParamIndices[0]].name, "p" ) );
std::string vectorSize =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->first].name, "p" ) ) +
".size()";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "valueName", valueName },
{ "valueType", valueType },
{ "vectorElementType", vectorElementType },
{ "vectorName", vectorName },
{ "vectorSize", vectorSize },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::pair<std::vector<${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 = determineNonConstPointerParamIndices( 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.params, 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.params, 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 = determineNonConstPointerParamIndices( commandIt->second.params );
switch ( returnParamIndices.size() )
{
case 0: str = generateRAIIHandleCommandVoid0Return( commandIt, initialSkipCount, definition ); break;
case 1:
assert( !isHandleType( commandIt->second.params[returnParamIndices[0]].type.type ) );
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, definition );
if ( isStructureChainAnchor( commandIt->second.params[returnParamIndices[0]].type.type ) )
{
str += generateRAIIHandleCommandVoid1ReturnChain(
commandIt, initialSkipCount, vectorParamIndices, returnParamIndices, 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.params, 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,
std::vector<size_t> const & nonConstPointerParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, 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.params, initialSkipCount, false, {}, true );
std::string returnType =
stripPostfix( commandIt->second.params[nonConstPointerParamIndices[0]].type.compose(), "*" );
std::string returnVariable =
startLowerCase( stripPrefix( commandIt->second.params[nonConstPointerParamIndices[0]].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,
std::vector<size_t> const & nonConstPointerParamIndices,
bool definition ) const
{
assert( nonConstPointerParamIndices.size() == 1 );
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, 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[nonConstPointerParamIndices[0]].type.compose(), "*" );
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.params, 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[nonConstPointerParamIndices[0]].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 & nonConstPointerParamIndices,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, 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.params, initialSkipCount, true, {}, true );
std::string secondCallArguments =
generateCallArgumentsEnhanced( commandIt->second.params, initialSkipCount, false, {}, true );
std::string vectorElementType =
stripPostfix( commandIt->second.params[vectorParamIndices.begin()->first].type.compose(), "*" );
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}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleCommandVoid2ReturnEnumerateValue(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & nonConstPointerParamIndices,
bool definition ) const
{
assert( nonConstPointerParamIndices.size() == 2 );
assert( vectorParamIndices.size() == 1 );
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string vectorElementType =
stripPostfix( commandIt->second.params[vectorParamIndices.begin()->first].type.compose(), "*" );
if ( definition )
{
const std::string definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::vector<${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 ${vectorName};
}
)";
std::string counterName =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->second].name, "p" ) );
std::string firstCallArguments =
generateCallArgumentsEnhanced( commandIt->second.params, initialSkipCount, true, {}, true );
std::string secondCallArguments =
generateCallArgumentsEnhanced( commandIt->second.params, initialSkipCount, false, {}, true );
std::string vectorName =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->first].name, "p" ) );
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "counterName", counterName },
{ "counterType", commandIt->second.params[vectorParamIndices.begin()->second].type.type },
{ "firstCallArguments", firstCallArguments },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "secondCallArguments", secondCallArguments },
{ "vectorElementType", vectorElementType },
{ "vectorName", vectorName },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::vector<${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" )
{
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 = determineNonConstPointerParamIndices( 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:
singularConstructor = generateRAIIHandleConstructorResult( handle, constructorIt, enter, leave );
break;
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];
arrayConstructor =
generateRAIIHandleConstructorVector( handle, constructorIt, handleParamIt, enter, leave );
}
}
break;
case 2:
std::tie( singularConstructor, arrayConstructor ) = generateRAIIHandleConstructor1Return2Vector(
handle, constructorIt, enter, leave, returnParamIndices[0], vectorParamIndices );
break;
}
}
}
break;
case 2:
if ( !constructorIt->second.errorCodes.empty() )
{
std::vector<size_t> returnParamIndices = determineNonConstPointerParamIndices( 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 )
{
std::tie( singularConstructor, arrayConstructor ) = 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];
arrayConstructor = generateRAIIHandleConstructorEnumerate(
handle, constructorIt, handleParamIt, lenParamIt, enter, leave );
}
}
}
break;
}
}
break;
case 4:
if ( !constructorIt->second.errorCodes.empty() )
{
std::vector<size_t> returnParamIndices = determineNonConstPointerParamIndices( 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 )
{
std::tie( singularConstructor, arrayConstructor ) = generateRAIIHandleConstructor1Return2Vector(
handle, constructorIt, enter, leave, returnParamIndices[0], vectorParamIndices );
}
}
}
break;
}
}
else if ( constructorIt->second.returnType == "void" )
{
assert( constructorIt->second.successCodes.empty() && constructorIt->second.errorCodes.empty() );
std::vector<size_t> returnParamIndices = determineNonConstPointerParamIndices( 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() )
{
singularConstructor = 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
{
std::string enter, leave;
std::tie( 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
std::string constructorEnter, constructorLeave;
std::tie( constructorEnter, constructorLeave ) =
generateProtection( constructorIt->second.referencedIn, std::string() );
if ( constructorEnter == enter )
{
constructorEnter.clear();
constructorLeave.clear();
}
std::string arrayConstructor, singularConstructor;
std::tie( singularConstructor, arrayConstructor ) =
generateRAIIHandleConstructor( handle, constructorIt, constructorEnter, constructorLeave );
arrayConstructors += arrayConstructor;
singularConstructors += singularConstructor;
}
singularConstructors += generateRAIIHandleConstructorTakeOwnership( handle );
return std::make_pair( singularConstructors, arrayConstructors );
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorArguments( std::string const & handleType,
std::vector<ParamData> const & params,
bool singular,
bool encounteredArgument ) const
{
std::string arguments;
for ( auto param : params )
{
if ( param.type.type != handleType ) // filter out the constructed type
{
// 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(
params.begin(), params.end(), [&handleType]( ParamData const & pd ) { return pd.type.type == handleType; } );
assert( typeIt != params.end() );
assert( typeIt->len == param.name );
#endif
continue;
}
else if ( std::find_if( params.begin(),
params.end(),
[&param]( ParamData const & pd ) { return pd.len == param.name; } ) != 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;
}
if ( encounteredArgument )
{
arguments += ", ";
}
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() );
arguments += "VULKAN_HPP_NAMESPACE::Optional<const " + argumentType + "> " + argumentName + " = nullptr";
}
else if ( param.len.empty() )
{
arguments += argumentType + " const & " + argumentName;
}
else
{
assert( std::find_if( params.begin(),
params.end(),
[&param]( ParamData const & pd ) { return pd.name == param.len; } ) != params.end() );
if ( singular )
{
arguments += argumentType + " const & " + stripPluralS( argumentName );
}
else
{
arguments += "VULKAN_HPP_NAMESPACE::ArrayProxy<" + argumentType + "> const & " + argumentName;
}
}
}
else if ( specialPointerTypes.find( param.type.type ) != specialPointerTypes.end() )
{
assert( !param.optional );
assert( param.type.isNonConstPointer() );
arguments += param.type.type + " & " + param.name;
}
else if ( ( param.type.isValue() ) && isHandleType( param.type.type ) )
{
std::string argument =
"VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::" + stripPrefix( param.type.type, "Vk" );
if ( param.optional )
{
argument = "VULKAN_HPP_NAMESPACE::Optional<const " + argument + ">";
}
arguments += argument + " const & " + param.name;
}
else
{
assert( !param.optional );
arguments += param.type.compose() + " " + param.name;
}
encounteredArgument = true;
}
}
return arguments;
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorCallArguments( std::string const & handleType,
std::vector<ParamData> const & params,
bool nonConstPointerAsNullptr,
std::set<size_t> const & singularParams,
bool allocatorIsMemberVariable ) const
{
std::string arguments;
bool encounteredArgument = false;
for ( size_t i = 0; i < params.size(); ++i )
{
ParamData const & param = params[i];
if ( encounteredArgument )
{
arguments += ", ";
}
if ( param.type.type == handleType )
{
assert( param.type.isNonConstPointer() && param.arraySizes.empty() );
if ( param.len.empty() || !singularParams.empty() )
{
assert( !param.optional );
assert( singularParams.empty() || ( param.len == params[*singularParams.begin()].name ) );
arguments +=
"reinterpret_cast<" + handleType + "*>( &m_" + startLowerCase( stripPrefix( handleType, "Vk" ) ) + " )";
}
else if ( nonConstPointerAsNullptr )
{
arguments += "nullptr";
}
else
{
arguments += startLowerCase( stripPrefix( param.name, "p" ) ) + ".data()";
}
}
else if ( param.type.type == "VkAllocationCallbacks" )
{
assert( param.optional );
if ( allocatorIsMemberVariable )
{
// VkAllocationCallbacks is stored as a member of the handle class !
arguments += "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( 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} ) );
VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() );
}
} while ( result == VULKAN_HPP_NAMESPACE::Result::eIncomplete );
if ( result == VULKAN_HPP_NAMESPACE::Result::eSuccess )
{
this->reserve( ${counterName} );
for ( auto const & ${handleName} : ${vectorName} )
{
this->emplace_back( ${handleConstructorArguments}, dispatcher );
}
}
else
{
throwResultException( result, "${constructorCall}" );
}
}
${leave})";
return replaceWithMap(
constructorTemplate,
{ { "constructorArguments",
generateRAIIHandleConstructorArguments( handle.first, constructorIt->second.params, false, false ) },
{ "constructorCall", constructorIt->first },
{ "counterName", startLowerCase( stripPrefix( lenParamIt->name, "p" ) ) },
{ "counterType", lenParamIt->type.type },
{ "dispatcherType", dispatcherType },
{ "enter", enter },
{ "firstCallArguments",
generateRAIIHandleConstructorCallArguments( handle.first, constructorIt->second.params, true, {}, true ) },
{ "handleConstructorArguments", handleConstructorArguments },
{ "handleName", startLowerCase( handleType ) },
{ "handleType", handleType },
{ "leave", leave },
{ "parentName", constructorIt->second.params.front().name },
{ "secondCallArguments",
generateRAIIHandleConstructorCallArguments( handle.first, constructorIt->second.params, false, {}, true ) },
{ "vectorElementType", handleParamIt->type.type },
{ "vectorName", startLowerCase( stripPrefix( handleParamIt->name, "p" ) ) } } );
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorInitializationList(
std::string const & handleType,
std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator constructorIt,
std::map<std::string, VulkanHppGenerator::CommandData>::const_iterator destructorIt,
bool hasSecondLevelCommands ) const
{
std::string initializationList;
if ( destructorIt != m_commands.end() )
{
for ( auto destructorParam : destructorIt->second.params )
{
if ( destructorParam.type.type != handleType )
{
if ( isHandleType( destructorParam.type.type ) )
{
assert( destructorParam.type.isValue() && destructorParam.arraySizes.empty() && destructorParam.len.empty() &&
!destructorParam.optional );
initializationList += "m_" + startLowerCase( stripPrefix( destructorParam.type.type, "Vk" ) ) + "( ";
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 );
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 if ( destructorParam.type.type == "VkAllocationCallbacks" )
{
assert( destructorParam.type.isConstPointer() && destructorParam.arraySizes.empty() &&
destructorParam.len.empty() && destructorParam.optional );
initializationList +=
"m_allocator( reinterpret_cast<const VkAllocationCallbacks *>( static_cast<const VULKAN_HPP_NAMESPACE::AllocationCallbacks *>( allocator ) ) ), ";
}
else
{
// we can ignore all other parameters here !
}
}
}
}
else if ( hasSecondLevelCommands )
{
auto const & param = constructorIt->second.params.front();
initializationList = "m_" + startLowerCase( stripPrefix( param.type.type, "Vk" ) ) + "( *" + param.name + " ), ";
}
return initializationList;
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorResult(
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.first, constructorIt->second.params, false, {}, handle.second.destructorIt != m_commands.end() );
std::string constructorArguments, dispatcherArgument, dispatcherInit, getDispatcher;
if ( handle.first == "VkInstance" )
{
constructorArguments = "VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::Context const & context";
dispatcherArgument = "context.getDispatcher()->vkGetInstanceProcAddr";
getDispatcher = "context.getDispatcher()";
}
else
{
dispatcherArgument = constructorIt->second.params[0].name + ".getDispatcher()";
if ( handle.first == "VkDevice" )
{
dispatcherArgument = dispatcherArgument + "->vkGetDeviceProcAddr";
getDispatcher = "physicalDevice.getDispatcher()";
}
else
{
getDispatcher = "getDispatcher()";
}
}
constructorArguments += generateRAIIHandleConstructorArguments(
handle.first, constructorIt->second.params, false, handle.first == "VkInstance" );
if ( ( handle.first == "VkDevice" ) || ( handle.first == "VkInstance" ) )
{
dispatcherInit = "\n m_dispatcher.init( static_cast<" + handle.first + ">( m_" +
startLowerCase( stripPrefix( handle.first, "Vk" ) ) + " ) );";
}
std::string initializationList = generateRAIIHandleConstructorInitializationList(
handle.first, constructorIt, handle.second.destructorIt, !handle.second.secondLevelCommands.empty() );
const std::string constructorTemplate =
R"(
${enter} ${handleType}( ${constructorArguments} )
: ${initializationList}m_dispatcher( ${dispatcherArgument} )
{
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 },
{ "dispatcherArgument", dispatcherArgument },
{ "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 paramType;
std::string constructorArguments, dispatcherArgument, initializationList;
if ( handle.first == "VkInstance" )
{
constructorArguments = "VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::Context const & context";
dispatcherArgument = "context.getDispatcher()->vkGetInstanceProcAddr";
}
else
{
assert( !handle.second.constructorIts.empty() && !handle.second.constructorIts.front()->second.params.empty() );
auto param = handle.second.constructorIts.front()->second.params.begin();
assert( isHandleType( param->type.type ) && param->type.isValue() );
paramType = stripPrefix( param->type.type, "Vk" );
constructorArguments =
"VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::" + paramType + " const & " + startLowerCase( paramType );
dispatcherArgument = startLowerCase( paramType ) + ".getDispatcher()";
if ( handle.first == "VkDevice" )
{
dispatcherArgument = dispatcherArgument + "->vkGetDeviceProcAddr";
}
}
std::string handleName = startLowerCase( handleType );
constructorArguments += ", " + handle.first + " " + handleName;
initializationList += "m_" + handleName + "( " + handleName + " ), ";
if ( handle.second.destructorIt != m_commands.end() )
{
std::vector<ParamData> params = handle.second.destructorIt->second.params;
auto paramIt = std::find_if(
params.begin(), params.end(), [&paramType]( ParamData const & pd ) { return pd.type.type == "Vk" + paramType; } );
if ( paramIt != params.end() )
{
params.erase( paramIt );
}
constructorArguments += generateRAIIHandleConstructorArguments( handle.first, params, false, true );
initializationList += generateRAIIHandleConstructorInitializationList( handle.first,
handle.second.destructorIt,
handle.second.destructorIt,
!handle.second.secondLevelCommands.empty() );
}
else if ( !handle.second.secondLevelCommands.empty() )
{
initializationList += "m_" + startLowerCase( paramType ) + "( *" + startLowerCase( paramType ) + " ), ";
}
std::string dispatcherInit;
if ( ( handle.first == "VkDevice" ) || ( handle.first == "VkInstance" ) )
{
dispatcherInit = "\n m_dispatcher.init( static_cast<" + handle.first + ">( m_" +
startLowerCase( stripPrefix( handle.first, "Vk" ) ) + " ) );\n ";
}
const std::string constructorTemplate =
R"(
${handleType}( ${constructorArguments} )
: ${initializationList}m_dispatcher( ${dispatcherArgument} )
{${dispatcherInit}}
)";
return replaceWithMap( constructorTemplate,
{ { "constructorArguments", constructorArguments },
{ "dispatcherArgument", dispatcherArgument },
{ "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( ${handleConstructorArguments}, ${successCodePassToElement} dispatcher );
}
}
else
{
throwResultException( result, "${constructorCall}" );
}
}
${leave})";
return replaceWithMap(
constructorTemplate,
{ { "callArguments",
generateRAIIHandleConstructorCallArguments( handle.first, constructorIt->second.params, false, {}, false ) },
{ "constructorArguments",
generateRAIIHandleConstructorArguments( handle.first, constructorIt->second.params, 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.first, constructorIt->second.params, false, singularParams, true );
std::string initializationList = generateRAIIHandleConstructorInitializationList(
handle.first, constructorIt, handle.second.destructorIt, !handle.second.secondLevelCommands.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.first, constructorIt->second.params, true, false ) },
{ "constructorCall", constructorIt->first },
{ "enter", enter },
{ "firstArgument", constructorIt->second.params[0].name },
{ "failureCheck", failureCheck },
{ "leave", leave },
{ "handleType", stripPrefix( handle.first, "Vk" ) } } );
}
std::string VulkanHppGenerator::generateRAIIHandleConstructorVoid(
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.first, constructorIt->second.params, false, {}, true );
std::string constructorArguments =
generateRAIIHandleConstructorArguments( handle.first, constructorIt->second.params, false, false );
std::string initializationList = generateRAIIHandleConstructorInitializationList(
handle.first, constructorIt, handle.second.destructorIt, !handle.second.secondLevelCommands.empty() );
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:
Context()
: m_dispatcher( m_dynamicLoader.getProcAddress<PFN_vkGetInstanceProcAddr>( "vkGetInstanceProcAddr" ) )
{}
~Context() = default;
Context( Context const & ) = delete;
Context( Context && rhs ) VULKAN_HPP_NOEXCEPT
: m_dynamicLoader( std::move( rhs.m_dynamicLoader ) )
, m_dispatcher( std::move( rhs.m_dispatcher ) )
{}
Context & operator=( Context const & ) = delete;
Context & operator=( Context && rhs ) VULKAN_HPP_NOEXCEPT
{
if ( this != &rhs )
{
m_dynamicLoader = std::move( rhs.m_dynamicLoader );
m_dispatcher = std::move( rhs.m_dispatcher );
}
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:
VULKAN_HPP_NAMESPACE::DynamicLoader m_dynamicLoader;
VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::ContextDispatcher m_dispatcher;
};
)";
return replaceWithMap(
contextTemplate,
{ { "memberFunctionDeclarations", generateRAIIHandleMemberFunctionDeclarations( 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
{
std::string destructorEnter, destructorLeave;
std::tie( 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->second.params ) +
" )";
const std::string destructorTemplate = R"(
${enter}~${handleType}()
{
if ( m_${handleName} )
{
getDispatcher()->${destructorCall};
}
}
${leave})";
std::string destructor = replaceWithMap( destructorTemplate,
{ { "destructorCall", destructorCall },
{ "enter", destructorEnter },
{ "handleName", startLowerCase( stripPrefix( handleType, "Vk" ) ) },
{ "handleType", stripPrefix( handleType, "Vk" ) },
{ "leave", destructorLeave } } );
return std::make_pair( destructor, destructorCall );
}
std::string VulkanHppGenerator::generateRAIIHandleDestructorCallArguments( std::string const & handleType,
std::vector<ParamData> const & params ) const
{
std::string arguments;
bool encounteredArgument = false;
for ( auto param : params )
{
if ( encounteredArgument )
{
arguments += ", ";
}
if ( param.type.type == "VkAllocationCallbacks" )
{
// VkAllocationCallbacks is stored as a member of the handle class
arguments += "m_allocator";
}
else if ( isHandleType( param.type.type ) )
{
assert( param.arraySizes.empty() );
std::string argument = "m_" + startLowerCase( stripPrefix( param.type.type, "Vk" ) );
if ( param.type.isValue() )
{
if ( param.type.type == handleType )
{
argument = "static_cast<" + param.type.type + ">( " + argument + " )";
}
arguments += argument;
}
else
{
assert( param.type.isConstPointer() );
assert( !param.len.empty() &&
( std::find_if( params.begin(),
params.end(),
[&param]( ParamData const & pd ) { return pd.name == param.len; } ) != 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( params.begin(),
params.end(),
[&param]( ParamData const & pd ) { return pd.len == param.name; } ) != 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, memberVariables, moveConstructorInitializerList, moveAssignmentInstructions;
bool multiSuccessCodeContructor = isMultiSuccessCodeConstructor( handle.second.constructorIts );
if ( multiSuccessCodeContructor )
{
getConstructorSuccessCode = R"(
VULKAN_HPP_NAMESPACE::Result getConstructorSuccessCode() const
{
return m_constructorSuccessCode;
}
)";
}
std::string handleType = stripPrefix( handle.first, "Vk" );
std::string handleName = startLowerCase( handleType );
memberVariables = " VULKAN_HPP_NAMESPACE::" + handleType + " m_" + handleName + ";";
moveConstructorInitializerList =
"m_" + handleName + "( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" + handleName + ", {} ) )";
moveAssignmentInstructions = " m_" + handleName +
" = VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" + handleName +
", {} );";
if ( handle.second.destructorIt != m_commands.end() )
{
moveAssignmentInstructions = " if ( m_" + handleName +
" )\n"
" {\n"
" getDispatcher()->" +
destructorCall +
";\n"
" }\n"
" " +
moveAssignmentInstructions;
for ( auto const & destructorParam : handle.second.destructorIt->second.params )
{
if ( ( 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() ) )
{
std::string name = destructorParam.name;
if ( !destructorParam.type.isValue() )
{
name = startLowerCase( stripPrefix( name, "p" ) );
}
memberVariables += "\n " + destructorParam.type.prefix + " " + destructorParam.type.type + " " +
destructorParam.type.postfix + " m_" + name + ";";
moveConstructorInitializerList += ", m_" + name + "( rhs.m_" + name + " )";
moveAssignmentInstructions += "\n m_" + name + " = rhs.m_" + name + ";";
}
}
}
else if ( !handle.second.secondLevelCommands.empty() )
{
assert( !handle.second.constructorIts.empty() );
assert( !handle.second.constructorIts.front()->second.params.empty() );
auto const & parentType = handle.second.constructorIts.front()->second.params.front().type;
assert( isHandleType( parentType.type ) );
memberVariables += "\n VULKAN_HPP_NAMESPACE::" + stripPrefix( parentType.type, "Vk" ) + " m_" +
startLowerCase( stripPrefix( parentType.type, "Vk" ) ) + ";";
}
if ( multiSuccessCodeContructor )
{
memberVariables += "\n VULKAN_HPP_NAMESPACE::Result m_constructorSuccessCode;";
}
if ( handle.first == "VkInstance" )
{
memberVariables += "\n VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::InstanceDispatcher m_dispatcher;";
}
else if ( handle.first == "VkDevice" )
{
memberVariables += "\n 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;";
}
else
{
memberVariables +=
"\n VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::InstanceDispatcher const * m_dispatcher;";
}
moveConstructorInitializerList += ", m_dispatcher( rhs.m_dispatcher )";
moveAssignmentInstructions += "\n m_dispatcher = rhs.m_dispatcher;";
return std::make_tuple(
getConstructorSuccessCode, memberVariables, moveConstructorInitializerList, moveAssignmentInstructions );
}
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 );
}
//
// 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 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
}
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;
}
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::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() + " " + 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::generateRAIIHandleMemberFunctionDeclarations(
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, specialFunctions, false );
}
for ( auto const & command : secondLevelCommands )
{
assert( !handle.first.empty() );
functionDeclarations += generateRAIIHandleCommand( command, 2, specialFunctions, 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, specialFunctions, false );
}
for ( auto const & command : secondLevelCommands )
{
assert( !handle.first.empty() );
functionDeclarations += generateRAIIHandleCommand( command, 2, specialFunctions, false );
}
functionDeclarations += leave;
}
}
return functionDeclarations;
}
std::string VulkanHppGenerator::generateRAIIHandleMemberFunctionResultMultiGetTwoValues(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
std::vector<size_t> const & nonConstPointerParamIndices,
bool definition ) const
{
assert( nonConstPointerParamIndices.size() == 2 );
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, nonConstPointerParamIndices, 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 returnType0 =
stripPostfix( commandIt->second.params[nonConstPointerParamIndices[0]].type.compose(), "*" );
std::string returnType1 =
stripPostfix( commandIt->second.params[nonConstPointerParamIndices[1]].type.compose(), "*" );
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::tuple<VULKAN_HPP_NAMESPACE::Result, ${returnType0}, ${returnType1}> ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
${returnType0} ${valueName0};
${returnType1} ${valueName1};
VULKAN_HPP_NAMESPACE::Result result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return std::make_tuple( result, ${valueName0}, ${valueName1} );
}
)";
std::string callArguments =
generateCallArgumentsEnhanced( commandIt->second.params, initialSkipCount, false, {}, true );
std::string valueName0 =
startLowerCase( stripPrefix( commandIt->second.params[nonConstPointerParamIndices[0]].name, "p" ) );
std::string valueName1 =
startLowerCase( stripPrefix( commandIt->second.params[nonConstPointerParamIndices[1]].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 ) },
{ "returnType0", returnType0 },
{ "returnType1", returnType1 },
{ "valueName0", valueName0 },
{ "valueName1", valueName1 },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::tuple<VULKAN_HPP_NAMESPACE::Result, ${returnType0}, ${returnType1}> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{ { "argumentList", argumentList },
{ "commandName", commandName },
{ "returnType0", returnType0 },
{ "returnType1", returnType1 } } );
}
}
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 = determineNonConstPointerParamIndices( 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.params, 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}( ${argumentList} ) const VULKAN_HPP_NOEXCEPT;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleMemberFunctionResultSingleGetVector(
std::map<std::string, CommandData>::const_iterator commandIt,
size_t initialSkipCount,
std::map<size_t, size_t> const & vectorParamIndices,
size_t returnParamIndex,
bool definition ) const
{
std::set<size_t> skippedParameters = determineSkippedParams(
commandIt->second.params, initialSkipCount, vectorParamIndices, { returnParamIndex }, false );
std::string argumentList =
generateArgumentListEnhanced( commandIt->second.params, skippedParameters, {}, definition, false, false, false );
std::string commandName = generateCommandName( commandIt->first, commandIt->second.params, initialSkipCount, m_tags );
std::string vectorElementType = commandIt->second.params[returnParamIndex].type.type;
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE std::vector<${vectorElementType}> ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
std::vector<${vectorElementType}> ${vectorName}( ${vectorSize} );
VULKAN_HPP_NAMESPACE::Result result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return ${vectorName};
}
)";
std::string callArguments =
generateCallArgumentsEnhanced( commandIt->second.params, initialSkipCount, false, {}, true );
std::string vectorName = startLowerCase( stripPrefix( commandIt->second.params[returnParamIndex].name, "p" ) );
std::string vectorSize =
startLowerCase( stripPrefix( commandIt->second.params[vectorParamIndices.begin()->first].name, "p" ) ) +
".size()";
return replaceWithMap(
definitionTemplate,
{ { "argumentList", argumentList },
{ "callArguments", callArguments },
{ "className", stripPrefix( commandIt->second.params[initialSkipCount - 1].type.type, "Vk" ) },
{ "commandName", commandName },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "vectorElementType", vectorElementType },
{ "vectorName", vectorName },
{ "vectorSize", vectorSize },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD std::vector<${vectorElementType}> ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
{ "vectorElementType", vectorElementType },
} );
}
}
std::string VulkanHppGenerator::generateRAIIHandleMemberFunctionResultSingleGetVectorSingular(
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 ) );
std::string vectorElementType = commandIt->second.params[returnParamIndex].type.type;
if ( definition )
{
std::string const definitionTemplate =
R"(
VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE ${vectorElementType} ${className}::${commandName}( ${argumentList} ) const
{${functionPointerCheck}
${vectorElementType} ${vectorElementName};
VULKAN_HPP_NAMESPACE::Result result = static_cast<VULKAN_HPP_NAMESPACE::Result>( getDispatcher()->${vkCommand}( ${callArguments} ) );
if ( ${failureCheck} )
{
throwResultException( result, VULKAN_HPP_NAMESPACE_STRING"::${className}::${commandName}" );
}
return ${vectorElementName};
}
)";
std::string callArguments =
generateCallArgumentsEnhanced( commandIt->second.params, initialSkipCount, false, singularParams, true );
std::string vectorElementName =
stripPluralS( 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 },
{ "failureCheck", generateFailureCheck( commandIt->second.successCodes ) },
{ "functionPointerCheck", generateFunctionPointerCheck( commandIt->first, commandIt->second.referencedIn ) },
{ "vectorElementName", vectorElementName },
{ "vectorElementType", vectorElementType },
{ "vkCommand", commandIt->first } } );
}
else
{
std::string const declarationTemplate =
R"(
VULKAN_HPP_NODISCARD ${vectorElementType} ${commandName}( ${argumentList} ) const;
)";
return replaceWithMap( declarationTemplate,
{
{ "argumentList", argumentList },
{ "commandName", commandName },
{ "vectorElementType", vectorElementType },
} );
}
}
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() )
{
for ( auto const & destructorParam : handle.second.destructorIt->second.params )
{
if ( ( 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 +=
", reinterpret_cast<const VkAllocationCallbacks *>( static_cast<const VULKAN_HPP_NAMESPACE::AllocationCallbacks *>( 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::generateRAIIHandleUpgradeConstructor( std::pair<std::string, HandleData> const & handle ) const
{
std::string typeName = startLowerCase( stripPrefix( handle.first, "Vk" ) );
std::string constructorArguments = handle.first + " " + typeName;
std::string constructorInitializationList = "m_" + typeName + "( " + typeName + " )";
if ( handle.second.destructorIt != m_commands.end() )
{
for ( auto const & destructorParam : handle.second.destructorIt->second.params )
{
if ( ( 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 ( isHandleType( destructorParam.type.type ) )
{
assert( destructorParam.type.isValue() );
std::string name = destructorParam.name;
constructorArguments += ", " + destructorParam.type.type + " " + name;
constructorInitializationList += ", m_" + name + "( " + name + " )";
}
else
{
assert( destructorParam.type.type == "VkAllocationCallbacks" );
constructorArguments += ", VkAllocationCallbacks const * allocator";
constructorInitializationList += ", m_allocator( allocator )";
}
}
}
}
if ( isMultiSuccessCodeConstructor( handle.second.constructorIts ) )
{
constructorArguments += ", VULKAN_HPP_NAMESPACE::Result successCode";
constructorInitializationList += ", m_constructorSuccessCode( successCode )";
}
std::string dispatcherType = ( 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";
const std::string protectedConstructorTemplate = R"(
${handleType}( ${arguments}, ${dispatcherType} const * dispatcher )
: ${initializationList}, m_dispatcher( dispatcher )
{})";
return replaceWithMap( protectedConstructorTemplate,
{ { "arguments", constructorArguments },
{ "dispatcherType", dispatcherType },
{ "handleType", stripPrefix( handle.first, "Vk" ) },
{ "initializationList", constructorInitializationList } } );
}
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::generateReturnType( CommandData const & commandData,
std::string const & baseType ) const
{
return ( 1 < commandData.successCodes.size() )
? ( ( baseType == "void" ) ? "Result" : ( "ResultValue<" + baseType + ">" ) )
: ( "typename ResultValueType<" + baseType + ">::type" );
}
std::string
VulkanHppGenerator::generateSizeCheck( std::vector<std::vector<MemberData>::const_iterator> const & arrayIts,
std::string const & structName,
std::string const & prefix,
bool mutualExclusiveLens ) const
{
std::string sizeCheck;
if ( 1 < arrayIts.size() )
{
std::string assertionText, throwText;
if ( mutualExclusiveLens )
{
// exactly one of the arrays has to be non-empty
std::string sum;
for ( size_t first = 0; first + 1 < arrayIts.size(); ++first )
{
sum += "!" + startLowerCase( stripPrefix( arrayIts[first]->name, "p" ) ) + "_.empty() + ";
}
sum += "!" + startLowerCase( stripPrefix( arrayIts.back()->name, "p" ) ) + "_.empty()";
assertionText += prefix + " VULKAN_HPP_ASSERT( ( " + sum + " ) <= 1);\n";
throwText += prefix + " if ( 1 < ( " + sum + " ) )\n";
throwText += prefix + " {\n";
throwText += prefix + " throw LogicError( VULKAN_HPP_NAMESPACE_STRING \"::" + structName + "::" + structName +
": 1 < ( " + sum + " )\" );\n";
throwText += prefix + " }\n";
}
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 += prefix + " VULKAN_HPP_ASSERT( " + assertionCheck + " );\n";
throwText += prefix + " if ( " + throwCheck + " )\n";
throwText += prefix + " {\n";
throwText += prefix + " throw LogicError( VULKAN_HPP_NAMESPACE_STRING \"::" + structName +
"::" + structName + ": " + throwCheck + "\" );\n";
throwText += prefix + " }\n";
}
}
}
sizeCheck += "\n#ifdef VULKAN_HPP_NO_EXCEPTIONS\n" + assertionText + "#else\n" + throwText +
"#endif /*VULKAN_HPP_NO_EXCEPTIONS*/\n" + prefix;
}
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,
std::string const & prefix ) const
{
static const std::string assignmentFromVulkanType = R"(
${prefix}${structName} & operator=( ${structName} const & rhs ) VULKAN_HPP_NOEXCEPT = default;
${prefix}${structName} & operator=( Vk${structName} const & rhs ) VULKAN_HPP_NOEXCEPT
${prefix}{
${prefix} *this = *reinterpret_cast<VULKAN_HPP_NAMESPACE::${structName} const *>( &rhs );
${prefix} return *this;
${prefix}}
)";
return replaceWithMap( assignmentFromVulkanType,
{ { "prefix", prefix }, { "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::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() + " ";
}
else
{
str += generateStandardArray( memberData.type.compose(), 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::generateStructConstructors( std::pair<std::string, StructureData> const & structData,
std::string const & prefix ) 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"(
${prefix}${constexpr}${structName}(${arguments}) VULKAN_HPP_NOEXCEPT
${prefix}${initializers}
${prefix}{}
${prefix}${constexpr}${structName}( ${structName} const & rhs ) VULKAN_HPP_NOEXCEPT = default;
${prefix}${structName}( Vk${structName} const & rhs ) VULKAN_HPP_NOEXCEPT
${prefix} : ${structName}( *reinterpret_cast<${structName} const *>( &rhs ) )
${prefix}{}
)";
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, false ) },
{ "initializers", initializers },
{ "prefix", prefix },
{ "structName", stripPrefix( structData.first, "Vk" ) } } );
str += generateStructConstructorsEnhanced( structData, prefix );
return str;
}
std::string
VulkanHppGenerator::generateStructConstructorsEnhanced( std::pair<std::string, StructureData> const & structData,
std::string const & prefix ) 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" ), prefix, 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(), "*" ) );
if ( ( mit->type.type == "void" ) && ( argumentType.find( '*' ) == std::string::npos ) )
{
// the argument after stripping one pointer is just void
assert( templateHeader.empty() );
templateHeader = prefix + "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 )
${templateHeader}${prefix}${structName}( ${arguments} )
${prefix}${initializers}
${prefix}{${sizeChecks}}
#endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/
)";
return replaceWithMap( constructorTemplate,
{ { "arguments", arguments },
{ "initializers", initializers },
{ "prefix", prefix },
{ "sizeChecks", sizeChecks },
{ "structName", stripPrefix( structData.first, "Vk" ) },
{ "templateHeader", templateHeader } } );
}
return "";
}
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 );
std::string enter, leave;
std::tie( 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() );
}
}
std::string subEnter, subLeave;
std::tie( 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::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();
}
else
{
assert( member.type.prefix.empty() && member.type.postfix.empty() );
str += generateStandardArrayWrapper( member.type.compose(), 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"(
${structureName} & set${MemberName}( ${memberType} ${reference}${memberName}_ ) VULKAN_HPP_NOEXCEPT
{
${assignment};
return *this;
}
)";
std::string memberType = member.arraySizes.empty()
? member.type.compose()
: generateStandardArray( member.type.compose(), member.arraySizes );
std::string assignment;
if ( !member.bitCount.empty() && beginsWith( member.type.type, "Vk" ) )
{
assignment = member.name + " = " + "*reinterpret_cast<" + member.type.type + "*>(&" + member.name + "_)";
}
else
{
assignment = member.name + " = " + member.name + "_";
}
str += replaceWithMap(
templateString,
{ { "assignment", assignment },
{ "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,
std::string const & prefix ) 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() );
subCopies += prefix + " " + ( firstArgument ? ":" : "," ) + " " + structData.second.members[i].name + "( " +
subStructArgumentName + "." + subStruct->second.members[i].name + " )\n";
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() );
subCopies +=
prefix + " , " + structData.second.members[i].name + "( " + structData.second.members[i].name + "_ )\n";
}
return "\n"
" explicit " +
stripPrefix( structData.first, "Vk" ) + "( " + stripPrefix( subStruct->first, "Vk" ) + " const & " +
subStructArgumentName + subArguments + " )\n" + subCopies + " {}\n";
}
return "";
}
std::string VulkanHppGenerator::generateStructure( std::pair<std::string, StructureData> const & structure ) const
{
std::string enter, leave;
std::tie( 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::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
{
std::string enter, leave;
std::tie( enter, leave ) = generateProtection(
structure.first, m_structureAliasesInverse.find( structure.first ) != m_structureAliasesInverse.end() );
std::string str = "\n" + enter;
std::string unionName = stripPrefix( structure.first, "Vk" );
str += " union " + unionName +
"\n"
" {\n"
" using NativeType = " +
structure.first +
";\n"
"#if !defined( VULKAN_HPP_NO_UNION_CONSTRUCTORS )\n"
" " +
unionName + "( VULKAN_HPP_NAMESPACE::" + unionName +
" const & rhs ) VULKAN_HPP_NOEXCEPT\n"
" {\n"
" memcpy( static_cast<void*>( this ), &rhs, sizeof( VULKAN_HPP_NAMESPACE::" +
unionName +
" ) );\n"
" }\n";
bool firstMember = true;
std::set<TypeInfo> listedTypes; // create just one constructor per different type !
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() );
static const std::string constructorTemplate = R"(
${unionName}( ${memberType} ${argumentName}_${defaultAssignment} )
: ${memberName}( ${argumentName}_ )
{}
)";
std::string memberType =
( memberIt->arraySizes.empty() )
? memberIt->type.compose()
: ( "const " + generateStandardArray( memberIt->type.compose(), memberIt->arraySizes ) + "&" );
str += replaceWithMap( constructorTemplate,
{ { "argumentName", multipleType ? generateName( memberIt->type ) : memberIt->name },
{ "defaultAssignment", firstMember ? " = {}" : "" },
{ "memberName", memberIt->name },
{ "memberType", memberType },
{ "unionName", stripPrefix( structure.first, "Vk" ) } } );
firstMember = false;
}
}
str += "#endif /*VULKAN_HPP_NO_UNION_CONSTRUCTORS*/\n";
str += "\n#if !defined( VULKAN_HPP_NO_UNION_SETTERS )";
// one setter per union element
for ( size_t i = 0; i < structure.second.members.size(); i++ )
{
str += generateStructSetter( stripPrefix( structure.first, "Vk" ), structure.second.members, i );
}
str += "#endif /*VULKAN_HPP_NO_UNION_SETTERS*/\n";
// assignment operator
static const std::string operatorsTemplate = R"(
VULKAN_HPP_NAMESPACE::${unionName} & operator=( VULKAN_HPP_NAMESPACE::${unionName} const & rhs ) VULKAN_HPP_NOEXCEPT
{
memcpy( static_cast<void*>( this ), &rhs, sizeof( VULKAN_HPP_NAMESPACE::${unionName} ) );
return *this;
}
operator Vk${unionName} const &() const
{
return *reinterpret_cast<const Vk${unionName}*>( this );
}
operator Vk${unionName} &()
{
return *reinterpret_cast<Vk${unionName}*>( this );
}
)";
str += replaceWithMap( operatorsTemplate, { { "unionName", stripPrefix( structure.first, "Vk" ) } } );
// the union member variables
// 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 )
{
str += "#ifdef VULKAN_HPP_HAS_UNRESTRICTED_UNIONS\n";
}
for ( auto const & member : structure.second.members )
{
str += " " +
( member.arraySizes.empty() ? member.type.compose()
: generateStandardArrayWrapper( member.type.compose(), member.arraySizes ) ) +
" " + member.name + ";\n";
}
if ( needsUnrestrictedUnions )
{
str += "#else\n";
for ( auto const & member : structure.second.members )
{
str += " " + member.type.prefix + ( member.type.prefix.empty() ? "" : " " ) + member.type.type +
member.type.postfix + " " + member.name + generateCArraySizes( member.arraySizes ) + ";\n";
}
str += "#endif /*VULKAN_HPP_HAS_UNRESTRICTED_UNIONS*/\n";
}
str += " };\n" + leave;
return str;
}
std::string VulkanHppGenerator::generateUniqueTypes( std::string const & parentType,
std::set<std::string> const & childrenTypes ) const
{
std::string str =
"\n"
"#ifndef VULKAN_HPP_NO_SMART_HANDLE\n";
if ( !parentType.empty() )
{
str += " class " + stripPrefix( parentType, "Vk" ) + ";\n";
}
for ( auto const & childType : childrenTypes )
{
auto handleIt = m_handles.find( childType );
assert( handleIt != m_handles.end() );
std::string type = stripPrefix( childType, "Vk" );
std::string deleterType = handleIt->second.deletePool.empty() ? "Object" : "Pool";
std::string deleterAction = ( handleIt->second.deleteCommand.substr( 2, 4 ) == "Free" ) ? "Free" : "Destroy";
std::string deleterParent = parentType.empty() ? "NoParent" : stripPrefix( parentType, "Vk" );
std::string deleterPool =
handleIt->second.deletePool.empty() ? "" : ", " + stripPrefix( handleIt->second.deletePool, "Vk" );
std::string enter, leave;
std::tie( enter, leave ) = generateProtection( handleIt->first, !handleIt->second.alias.empty() );
str += enter + " template <typename Dispatch> class UniqueHandleTraits<" + type +
", Dispatch> { public: using deleter = " + deleterType + deleterAction + "<" + deleterParent + deleterPool +
", Dispatch>; };\n"
" using Unique" +
type + " = UniqueHandle<" + type + ", VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>;\n";
if ( !handleIt->second.alias.empty() )
{
str += " using Unique" + stripPrefix( handleIt->second.alias, "Vk" ) + " = UniqueHandle<" + type +
", VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>;\n";
}
str += leave;
}
str += "#endif /*VULKAN_HPP_NO_SMART_HANDLE*/\n";
return str;
}
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::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::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::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::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::readBaseType( 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::readBitmask( 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() )
{
readBitmaskAlias( element, attributes );
}
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::readBitmaskAlias( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
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" );
}
void VulkanHppGenerator::readCommand( tinyxml2::XMLElement const * element )
{
std::map<std::string, std::string> attributes = getAttributes( element );
auto aliasIt = attributes.find( "alias" );
if ( aliasIt != attributes.end() )
{
readCommandAlias( element, attributes );
}
else
{
readCommand( element, attributes );
}
}
void VulkanHppGenerator::readCommand( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
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( readCommandParam( child, commandData.params ) );
}
else if ( value == "proto" )
{
std::tie( name, commandData.returnType ) = readCommandProto( 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 );
}
void VulkanHppGenerator::readCommandAlias( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes )
{
// for command aliases, create a copy of the aliased command
int line = element->GetLineNum();
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 );
}
VulkanHppGenerator::ParamData VulkanHppGenerator::readCommandParam( 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::readCommandProto( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), {}, {} );
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( 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::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 )
{
readCommand( child );
}
}
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::readDefine( 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::readEnum( tinyxml2::XMLElement const * element,
std::map<std::string, EnumData>::iterator enumIt )
{
std::map<std::string, std::string> attributes = getAttributes( element );
auto aliasIt = attributes.find( "alias" );
if ( aliasIt != attributes.end() )
{
readEnumAlias( element, attributes, enumIt->second );
}
else
{
readEnum( element, attributes, enumIt );
}
}
void VulkanHppGenerator::readEnum( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes,
std::map<std::string, EnumData>::iterator enumIt )
{
int line = element->GetLineNum();
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(), "" );
}
void VulkanHppGenerator::readEnumAlias( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes,
EnumData & enumData )
{
int line = element->GetLineNum();
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;
check( !alias.empty(), line, "enum with empty alias" );
}
else if ( attribute.first == "name" )
{
name = attribute.second;
check( !name.empty(), line, "enum with empty name" );
}
}
assert( !name.empty() );
enumData.addEnumAlias( line, name, alias );
}
void VulkanHppGenerator::readEnumConstant( 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::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 )
{
readEnumConstant( 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 );
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" )
{
readEnum( child, enumIt );
}
}
}
}
void VulkanHppGenerator::readExtension( tinyxml2::XMLElement const * element )
{
int line = element->GetLineNum();
std::map<std::string, std::string> attributes = getAttributes( element );
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" } } } );
std::vector<tinyxml2::XMLElement const *> children = getChildElements( element );
checkElements( line, children, {}, { "require" } );
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;
}
}
if ( supported == "disabled" )
{
// kick out all the disabled stuff we've read before !!
for ( auto const & child : children )
{
readExtensionDisabledRequire( child );
}
}
else
{
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 )
{
readExtensionRequire( child, pitb.first );
}
}
}
void VulkanHppGenerator::readExtensionDisabledCommand( 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::readExtensionDisabledRequire( 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" )
{
readExtensionDisabledCommand( child );
}
else if ( value == "comment" )
{
readComment( child );
}
else if ( value == "enum" )
{
// just skip enums of disabled extensions
}
else
{
assert( value == "type" );
readExtensionDisabledType( child );
}
}
}
void VulkanHppGenerator::readExtensionDisabledType( 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::readExtensionRequire( 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" )
{
readExtensionRequireCommand( child, extensionIt->first, requireData );
requireDataEmpty = false;
}
else if ( value == "comment" )
{
readComment( child );
}
else if ( value == "enum" )
{
readRequireEnum( child, extensionIt->first );
}
else if ( value == "type" )
{
readExtensionRequireType( child, extensionIt->first, requireData );
requireDataEmpty = false;
}
}
if ( !requireDataEmpty )
{
extensionIt->second.requireData.push_back( requireData );
}
}
void VulkanHppGenerator::readExtensionRequireCommand( 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::readExtensionRequireType( 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::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 )
{
readExtension( child );
}
}
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 )
{
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 );
}
}
void VulkanHppGenerator::readFuncpointer( 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::readHandle( 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" );
}
}
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::readPlatform( 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::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 )
{
readPlatform( child );
}
}
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 )
{
std::map<std::string, std::string> attributes = getAttributes( element );
if ( attributes.find( "alias" ) != attributes.end() )
{
readRequireEnumAlias( element, attributes );
}
else
{
readRequireEnum( element, attributes, extensionName );
}
}
void VulkanHppGenerator::readRequireEnum( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes,
std::string const & extensionName )
{
int line = element->GetLineNum();
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::readRequireEnumAlias( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
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 );
}
}
void VulkanHppGenerator::readRequires( 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::readSPIRVCapability( 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 )
{
std::string value = child->Value();
assert( value == "enable" );
readSPIRVCapabilityEnable( child );
}
}
void VulkanHppGenerator::readSPIRVCapabilityEnable( 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() )
{
readSPIRVCapabilityEnableExtension( line, attributes );
}
else if ( attributes.find( "property" ) != attributes.end() )
{
readSPIRVCapabilityEnableProperty( line, attributes );
}
else if ( attributes.find( "struct" ) != attributes.end() )
{
readSPIRVCapabilityEnableStruct( line, attributes );
}
else if ( attributes.find( "version" ) != attributes.end() )
{
readSPIRVCapabilityEnableVersion( line, attributes );
}
else
{
check( false, line, "unknown set of attributes specified for SPIR-V capability" );
}
}
void VulkanHppGenerator::readSPIRVCapabilityEnableExtension( 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::readSPIRVCapabilityEnableProperty( 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::readSPIRVCapabilityEnableStruct( 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::readSPIRVCapabilityEnableVersion( 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" );
check( beginsWith( attribute.second, "VK_API_VERSION_" ),
xmlLine,
"unknown version <" + attribute.second + "> specified for SPIR-V capability" );
std::string feature = attribute.second;
feature.erase( 3, 4 ); // remove "API_" from the version -> VK_VERSION_x_y
check( m_features.find( feature ) != m_features.end(),
xmlLine,
"unknown version <" + attribute.second + "> specified for SPIR-V capability" );
}
}
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 )
{
std::string value = child->Value();
assert( value == "spirvcapability" );
readSPIRVCapability( child );
}
}
void VulkanHppGenerator::readSPIRVExtension( 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 )
{
std::string value = child->Value();
assert( value == "enable" );
readSPIRVExtensionEnable( child );
}
}
void VulkanHppGenerator::readSPIRVExtensionEnable( 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" );
check( beginsWith( attribute.second, "VK_API_VERSION_" ),
line,
"unknown version <" + attribute.second + "> specified for SPIR-V extension" );
std::string feature = attribute.second;
feature.erase( 3, 4 ); // remove "API_" from the version -> VK_VERSION_x_y
check( m_features.find( feature ) != m_features.end(),
line,
"unknown version <" + attribute.second + "> specified for SPIR-V extension" );
}
}
}
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 )
{
std::string value = child->Value();
assert( value == "spirvextension" );
readSPIRVExtension( child );
}
}
void VulkanHppGenerator::readStruct( tinyxml2::XMLElement const * element,
bool isUnion,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
if ( attributes.find( "alias" ) != attributes.end() )
{
readStructAlias( element, attributes );
}
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" )
{
readStructMember( 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::readStructAlias( tinyxml2::XMLElement const * element,
std::map<std::string, std::string> const & attributes )
{
int line = element->GetLineNum();
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" );
}
void VulkanHppGenerator::readStructMember( 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" )
{
readStructMemberEnum( child, memberData );
}
else if ( value == "name" )
{
readStructMemberName( child, memberData, members );
}
else if ( value == "type" )
{
readStructMemberType( 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() + ">" );
}
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::readStructMemberEnum( 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::readStructMemberName( 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::readStructMemberType( tinyxml2::XMLElement const * element, MemberData & memberData )
{
int line = element->GetLineNum();
checkAttributes( line, getAttributes( element ), {}, {} );
checkElements( line, getChildElements( element ), {}, {} );
memberData.type = readTypeInfo( element );
}
void VulkanHppGenerator::readTag( 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::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 )
{
readTag( child );
}
}
void VulkanHppGenerator::readType( 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" )
{
readBaseType( element, attributes );
}
else if ( categoryIt->second == "bitmask" )
{
readBitmask( element, attributes );
}
else if ( categoryIt->second == "define" )
{
readDefine( element, attributes );
}
else if ( categoryIt->second == "enum" )
{
readTypeEnum( element, attributes );
}
else if ( categoryIt->second == "funcpointer" )
{
readFuncpointer( element, attributes );
}
else if ( categoryIt->second == "handle" )
{
readHandle( element, attributes );
}
else if ( categoryIt->second == "include" )
{
readTypeInclude( element, attributes );
}
else if ( categoryIt->second == "struct" )
{
readStruct( element, false, attributes );
}
else
{
check(
categoryIt->second == "union", element->GetLineNum(), "unknown type category <" + categoryIt->second + ">" );
readStruct( element, true, attributes );
}
}
else
{
auto requiresIt = attributes.find( "requires" );
if ( requiresIt != attributes.end() )
{
readRequires( 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::readTypeEnum( 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::readTypeInclude( 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" );
}
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::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" );
readType( child );
}
}
}
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::renameFunctionParameters()
{
// 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 += "_";
}
}
}
}
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";
}
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 "";
}
}
std::string VulkanHppGenerator::TypeInfo::compose( bool inNamespace ) const
{
return prefix + ( prefix.empty() ? "" : " " ) +
( inNamespace
? ( ( ( type.substr( 0, 2 ) == "Vk" ) ? "VULKAN_HPP_NAMESPACE::" : "" ) + stripPrefix( type, "Vk" ) )
: type ) +
postfix;
}
std::string to_string( 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 defined( _WIN32 ) && !defined( _WIN64 )
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<sizeof...( ChainElements ) - 1>();
}
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<sizeof...( ChainElements ) - 1>();
}
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<sizeof...( ChainElements ) - 1>();
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 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
{
#if !defined(NDEBUG)
public:
size_t getVkHeaderVersion() const
{
return vkHeaderVersion;
}
private:
size_t vkHeaderVersion = VK_HEADER_VERSION;
#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 ::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 <" << to_string( 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;
}
}
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