// 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 "XMLHelper.hpp" #include #include #include #include #include #include struct MacroData { std::string deprecatedComment = {}; std::string calleeMacro = {}; std::vector params = {}; std::string definition = {}; }; void checkAttributes( int line, std::map const & attributes, std::map> const & required, std::map> const & optional ); void checkForError( bool condition, int line, std::string const & message ); void checkForWarning( bool condition, int line, std::string const & message ); std::vector> filterNumbers( std::vector const & names ); std::string generateCArraySizes( std::vector const & sizes ); std::string generateNamespacedType( std::string const & type ); std::string generateNoDiscard( bool returnsSomething, bool multiSuccessCodes, bool multiErrorCodes ); std::string generateStandardArray( std::string const & type, std::vector const & sizes ); std::string generateStandardArrayWrapper( std::string const & type, std::vector const & sizes ); std::map getAttributes( tinyxml2::XMLElement const * element ); template std::vector getChildElements( ElementContainer const * element ); bool isNumber( std::string const & name ); std::pair, std::string> readModifiers( tinyxml2::XMLNode const * node ); std::string readSnippet( std::string const & snippetFile ); std::string replaceWithMap( std::string const & input, std::map 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 stripPrefix( std::string const & value, std::string const & prefix ); std::string toUpperCase( std::string const & name ); std::vector tokenize( std::string const & tokenString, std::string const & separator ); std::vector tokenizeAny( std::string const & tokenString, std::string const & separators ); std::string toString( tinyxml2::XMLError error ); std::string trim( std::string const & input ); std::string trimEnd( std::string const & input ); std::string trimStars( std::string const & input ); MacroData parseMacro( std::vector const & completeMacro ); void writeToFile( std::string const & str, std::string const & fileName ); const std::set specialPointerTypes = { "Display", "IDirectFB", "wl_display", "xcb_connection_t", "_screen_window" }; // // VulkanHppGenerator public interface // VulkanHppGenerator::VulkanHppGenerator( tinyxml2::XMLDocument const & document, std::string const & api ) : m_api( api ) { // insert the default "handle" without class (for createInstance, and such) m_handles.insert( std::make_pair( "", HandleData() ) ); // read the document and check its correctness int line = document.GetLineNum(); std::vector elements = getChildElements( &document ); checkElements( line, elements, { { "registry", true } } ); checkForError( elements.size() == 1, line, "encountered " + std::to_string( elements.size() ) + " elements named but only one is allowed" ); readRegistry( elements[0] ); filterLenMembers(); checkCorrectness(); handleRemovals(); // add the commands to the respective handles // some "FlagBits" enums are not specified, but needed for our "Flags" handling -> add them here for ( auto & feature : m_features ) { addCommandsToHandle( feature.requireData ); addMissingFlagBits( feature.requireData, feature.name ); } for ( auto & extension : m_extensions ) { addCommandsToHandle( extension.requireData ); addMissingFlagBits( extension.requireData, extension.name ); } m_definesPartition = partitionDefines( m_defines ); } void VulkanHppGenerator::generateEnumsHppFile() const { std::string const vulkan_enums_hpp = std::string( BASE_PATH ) + "/vulkan/" + m_api + "_enums.hpp"; std::cout << "VulkanHppGenerator: Generating " << vulkan_enums_hpp << " ..." << std::endl; std::string const vulkanEnumsHppTemplate = R"(${licenseHeader} #ifndef VULKAN_ENUMS_HPP # define VULKAN_ENUMS_HPP namespace VULKAN_HPP_NAMESPACE { template struct CppType {}; ${enums} ${indexTypeTraits} } // namespace VULKAN_HPP_NAMESPACE #endif )"; std::string str = replaceWithMap( vulkanEnumsHppTemplate, { { "enums", generateEnums() }, { "indexTypeTraits", generateIndexTypeTraits() }, { "licenseHeader", m_vulkanLicenseHeader } } ); writeToFile( str, vulkan_enums_hpp ); } void VulkanHppGenerator::generateExtensionInspectionFile() const { std::string const vulkan_extension_inspection_hpp = std::string( BASE_PATH ) + "/vulkan/" + m_api + "_extension_inspection.hpp"; std::cout << "VulkanHppGenerator: Generating " << vulkan_extension_inspection_hpp << " ..." << std::endl; std::string const vulkanExtensionInspectionHppTemplate = R"(${licenseHeader} #ifndef VULKAN_EXTENSION_INSPECTION_HPP # define VULKAN_EXTENSION_INSPECTION_HPP #include #include #include namespace VULKAN_HPP_NAMESPACE { //====================================== //=== Extension inspection functions === //====================================== std::set const & getDeviceExtensions(); std::set const & getInstanceExtensions(); std::map const & getDeprecatedExtensions(); std::map>> const & getExtensionDepends( std::string const & extension ); ${getExtensionDependsByVersionDeclaration} std::map const & getObsoletedExtensions(); std::map const & getPromotedExtensions(); VULKAN_HPP_CONSTEXPR_20 std::string getExtensionDeprecatedBy( std::string const & extension ); VULKAN_HPP_CONSTEXPR_20 std::string getExtensionObsoletedBy( std::string const & extension ); VULKAN_HPP_CONSTEXPR_20 std::string getExtensionPromotedTo( std::string const & extension ); VULKAN_HPP_CONSTEXPR_20 bool isDeprecatedExtension( std::string const & extension ); VULKAN_HPP_CONSTEXPR_20 bool isDeviceExtension( std::string const & extension ); VULKAN_HPP_CONSTEXPR_20 bool isInstanceExtension( std::string const & extension ); VULKAN_HPP_CONSTEXPR_20 bool isObsoletedExtension( std::string const & extension ); VULKAN_HPP_CONSTEXPR_20 bool isPromotedExtension( std::string const & extension ); //===================================================== //=== Extension inspection function implementations === //===================================================== VULKAN_HPP_INLINE std::map const & getDeprecatedExtensions() { static std::map deprecatedExtensions = { ${deprecatedExtensions} }; return deprecatedExtensions; } VULKAN_HPP_INLINE std::set const & getDeviceExtensions() { static std::set deviceExtensions = { ${deviceExtensions} }; return deviceExtensions; } VULKAN_HPP_INLINE std::set const & getInstanceExtensions() { static std::set instanceExtensions = { ${instanceExtensions} }; return instanceExtensions; } VULKAN_HPP_INLINE std::map>> const & getExtensionDepends( std::string const & extension ) { static std::map>> noDependencies; static std::map>>> dependencies = { ${extensionDependencies} }; auto depIt = dependencies.find( extension ); return ( depIt != dependencies.end() ) ? depIt->second : noDependencies; } ${getExtensionDependsByVersionDefinition} VULKAN_HPP_INLINE std::map const & getObsoletedExtensions() { static std::map obsoletedExtensions = { ${obsoletedExtensions} }; return obsoletedExtensions; } VULKAN_HPP_INLINE std::map const & getPromotedExtensions() { static std::map promotedExtensions = { ${promotedExtensions} }; return promotedExtensions; } VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_20 std::string getExtensionDeprecatedBy( std::string const & extension ) { ${voidExtension} ${deprecatedBy} } VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_20 std::string getExtensionObsoletedBy( std::string const & extension ) { ${voidExtension} ${obsoletedBy} } VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_20 std::string getExtensionPromotedTo( std::string const & extension ) { ${promotedTo} } VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_20 bool isDeprecatedExtension( std::string const & extension ) { ${voidExtension} return ${deprecatedTest}; } VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_20 bool isDeviceExtension( std::string const & extension ) { return ${deviceTest}; } VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_20 bool isInstanceExtension( std::string const & extension ) { return ${instanceTest}; } VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_20 bool isObsoletedExtension( std::string const & extension ) { ${voidExtension} return ${obsoletedTest}; } VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_20 bool isPromotedExtension( std::string const & extension ) { return ${promotedTest}; } } // namespace VULKAN_HPP_NAMESPACE #endif )"; std::string str = replaceWithMap( vulkanExtensionInspectionHppTemplate, { { "api", m_api }, { "deprecatedExtensions", generateReplacedExtensionsList( []( ExtensionData const & extension ) { return extension.isDeprecated; }, []( ExtensionData const & extension ) { return extension.deprecatedBy; } ) }, { "deviceExtensions", generateExtensionsList( "device" ) }, { "deviceTest", generateExtensionTypeTest( "device" ) }, { "deprecatedBy", generateExtensionReplacedBy( []( ExtensionData const & extension ) { return extension.isDeprecated; }, []( ExtensionData const & extension ) { return extension.deprecatedBy; } ) }, { "deprecatedTest", generateExtensionReplacedTest( []( ExtensionData const & extension ) { return extension.isDeprecated; } ) }, { "extensionDependencies", generateExtensionDependencies() }, { "getExtensionDependsByVersionDeclaration", generateExtensionDependsByVersion( false ) }, { "getExtensionDependsByVersionDefinition", generateExtensionDependsByVersion( true ) }, { "instanceExtensions", generateExtensionsList( "instance" ) }, { "instanceTest", generateExtensionTypeTest( "instance" ) }, { "licenseHeader", m_vulkanLicenseHeader }, { "obsoletedBy", generateExtensionReplacedBy( []( ExtensionData const & extension ) { return !extension.obsoletedBy.empty(); }, []( ExtensionData const & extension ) { return extension.obsoletedBy; } ) }, { "obsoletedExtensions", generateReplacedExtensionsList( []( ExtensionData const & extension ) { return !extension.obsoletedBy.empty(); }, []( ExtensionData const & extension ) { return extension.obsoletedBy; } ) }, { "obsoletedTest", generateExtensionReplacedTest( []( ExtensionData const & extension ) { return !extension.obsoletedBy.empty(); } ) }, { "promotedExtensions", generateReplacedExtensionsList( []( ExtensionData const & extension ) { return !extension.promotedTo.empty(); }, []( ExtensionData const & extension ) { return extension.promotedTo; } ) }, { "promotedTest", generateExtensionReplacedTest( []( ExtensionData const & extension ) { return !extension.promotedTo.empty(); } ) }, { "promotedTo", generateExtensionReplacedBy( []( ExtensionData const & extension ) { return !extension.promotedTo.empty(); }, []( ExtensionData const & extension ) { return extension.promotedTo; } ) }, { "voidExtension", ( m_api == "vulkan" ) ? "" : "(void)extension;" } } ); writeToFile( str, vulkan_extension_inspection_hpp ); } void VulkanHppGenerator::generateFormatTraitsHppFile() const { std::string const vulkan_format_traits_hpp = std::string( BASE_PATH ) + "/vulkan/" + m_api + "_format_traits.hpp"; std::cout << "VulkanHppGenerator: Generating " << vulkan_format_traits_hpp << " ..." << std::endl; std::string const vulkanFormatTraitsHppTemplate = R"(${licenseHeader} #ifndef VULKAN_FORMAT_TRAITS_HPP # define VULKAN_FORMAT_TRAITS_HPP #include namespace VULKAN_HPP_NAMESPACE { ${formatTraits} } // namespace VULKAN_HPP_NAMESPACE #endif )"; std::string str = replaceWithMap( vulkanFormatTraitsHppTemplate, { { "formatTraits", generateFormatTraits() }, { "licenseHeader", m_vulkanLicenseHeader } } ); writeToFile( str, vulkan_format_traits_hpp ); } void VulkanHppGenerator::generateFuncsHppFile() const { std::string const vulkan_funcs_hpp = std::string( BASE_PATH ) + "/vulkan/" + m_api + "_funcs.hpp"; std::cout << "VulkanHppGenerator: Generating " << vulkan_funcs_hpp << " ..." << std::endl; std::string const vulkanFuncsHppTemplate = R"(${licenseHeader} #ifndef VULKAN_FUNCS_HPP # define VULKAN_FUNCS_HPP namespace VULKAN_HPP_NAMESPACE { ${commandDefinitions} } // namespace VULKAN_HPP_NAMESPACE #endif )"; std::string str = replaceWithMap( vulkanFuncsHppTemplate, { { "commandDefinitions", generateCommandDefinitions() }, { "licenseHeader", m_vulkanLicenseHeader } } ); writeToFile( str, vulkan_funcs_hpp ); } void VulkanHppGenerator::generateHandlesHppFile() const { std::string const vulkan_handles_hpp = std::string( BASE_PATH ) + "/vulkan/" + m_api + "_handles.hpp"; std::cout << "VulkanHppGenerator: Generating " << vulkan_handles_hpp << " ..." << std::endl; std::string const vulkanHandlesHppTemplate = R"(${licenseHeader} #ifndef VULKAN_HANDLES_HPP # define VULKAN_HANDLES_HPP namespace VULKAN_HPP_NAMESPACE { ${structForwardDeclarations} ${handleForwardDeclarations} ${uniqueHandles} ${handles} } // namespace VULKAN_HPP_NAMESPACE // operators to compare vk::-handles with nullptr template typename std::enable_if::value, bool>::type operator==( const T & v, std::nullptr_t ) { return !v; } template typename std::enable_if::value, bool>::type operator==( std::nullptr_t, const T & v ) { return !v; } template typename std::enable_if::value, bool>::type operator!=( const T & v, std::nullptr_t ) { return v; } template typename std::enable_if::value, bool>::type operator!=( std::nullptr_t, const T & v ) { return v; } #endif )"; std::string str = replaceWithMap( vulkanHandlesHppTemplate, { { "handles", generateHandles() }, { "handleForwardDeclarations", generateHandleForwardDeclarations() }, { "licenseHeader", m_vulkanLicenseHeader }, { "structForwardDeclarations", generateStructForwardDeclarations() }, { "uniqueHandles", generateUniqueHandles() } } ); writeToFile( str, vulkan_handles_hpp ); } void VulkanHppGenerator::generateHashHppFile() const { std::string const vulkan_hash_hpp = std::string( BASE_PATH ) + "/vulkan/" + m_api + "_hash.hpp"; std::cout << "VulkanHppGenerator: Generating " << vulkan_hash_hpp << " ..." << std::endl; std::string const vulkanHandlesHppTemplate = R"(${licenseHeader} #ifndef VULKAN_HASH_HPP # define VULKAN_HASH_HPP #include namespace std { //======================================= //=== HASH structures for Flags types === //======================================= template struct hash> { std::size_t operator()( VULKAN_HPP_NAMESPACE::Flags const & flags ) const VULKAN_HPP_NOEXCEPT { return std::hash::type>{}( static_cast::type>( flags ) ); } }; ${handleHashStructures} ${structHashStructures} } // namespace std #endif )"; std::string str = replaceWithMap( vulkanHandlesHppTemplate, { { "handleHashStructures", generateHandleHashStructures() }, { "licenseHeader", m_vulkanLicenseHeader }, { "structHashStructures", generateStructHashStructures() } } ); writeToFile( str, vulkan_hash_hpp ); } void VulkanHppGenerator::generateHppFile() const { std::string const vulkan_hpp = std::string( BASE_PATH ) + "/vulkan/" + m_api + ".hpp"; std::cout << "VulkanHppGenerator: Generating " << vulkan_hpp << " ... " << std::endl; std::string const vulkanHppTemplate = R"(${licenseHeader} ${includes} static_assert( VK_HEADER_VERSION == ${headerVersion}, "Wrong VK_HEADER_VERSION!" ); // 32-bit vulkan is not typesafe for non-dispatchable handles, so don't allow copy constructors on this platform by default. // To enable this feature on 32-bit platforms please define VULKAN_HPP_TYPESAFE_CONVERSION ${typesafeCheck} # if !defined( VULKAN_HPP_TYPESAFE_CONVERSION ) # define VULKAN_HPP_TYPESAFE_CONVERSION # endif #endif ${defines} namespace VULKAN_HPP_NAMESPACE { ${ArrayWrapper1D} ${ArrayWrapper2D} ${Flags} #if !defined( VULKAN_HPP_DISABLE_ENHANCED_MODE ) ${ArrayProxy} ${ArrayProxyNoTemporaries} ${StridedArrayProxy} ${Optional} ${StructureChain} ${UniqueHandle} #endif // VULKAN_HPP_DISABLE_ENHANCED_MODE ${DispatchLoaderBase} ${DispatchLoaderStatic} ${DispatchLoaderDefault} #if !defined( VULKAN_HPP_NO_SMART_HANDLE ) ${ObjectDestroy} ${ObjectFree} ${ObjectRelease} ${PoolFree} #endif // !VULKAN_HPP_NO_SMART_HANDLE ${baseTypes} } // namespace VULKAN_HPP_NAMESPACE #include #if !defined( VULKAN_HPP_NO_TO_STRING ) #include #endif #ifndef VULKAN_HPP_NO_EXCEPTIONS namespace std { template <> struct is_error_code_enum : public true_type {}; } // namespace std #endif namespace VULKAN_HPP_NAMESPACE { #ifndef VULKAN_HPP_NO_EXCEPTIONS ${Exceptions} ${resultExceptions} ${throwResultException} #endif ${ResultValue} ${resultChecks} ${constexprDefines} } // namespace VULKAN_HPP_NAMESPACE // clang-format off #include #include #include // clang-format on namespace VULKAN_HPP_NAMESPACE { #if !defined( VULKAN_HPP_DISABLE_ENHANCED_MODE ) ${structExtendsStructs} #endif // VULKAN_HPP_DISABLE_ENHANCED_MODE ${DynamicLoader} ${DispatchLoaderDynamic} } // namespace VULKAN_HPP_NAMESPACE #endif )"; std::string str = replaceWithMap( vulkanHppTemplate, { { "ArrayProxy", readSnippet( "ArrayProxy.hpp" ) }, { "ArrayProxyNoTemporaries", readSnippet( "ArrayProxyNoTemporaries.hpp" ) }, { "ArrayWrapper1D", readSnippet( "ArrayWrapper1D.hpp" ) }, { "ArrayWrapper2D", readSnippet( "ArrayWrapper2D.hpp" ) }, { "baseTypes", generateBaseTypes() }, { "constexprDefines", generateConstexprDefines() }, { "defines", readSnippet( "defines.hpp" ) }, { "DispatchLoaderBase", readSnippet( "DispatchLoaderBase.hpp" ) }, { "DispatchLoaderDefault", readSnippet( "DispatchLoaderDefault.hpp" ) }, { "DispatchLoaderDynamic", generateDispatchLoaderDynamic() }, { "DispatchLoaderStatic", generateDispatchLoaderStatic() }, { "DynamicLoader", readSnippet( "DynamicLoader.hpp" ) }, { "Exceptions", readSnippet( "Exceptions.hpp" ) }, { "Flags", readSnippet( "Flags.hpp" ) }, { "headerVersion", m_version }, { "includes", replaceWithMap( readSnippet( "includes.hpp" ), { { "vulkan_h", ( m_api == "vulkan" ) ? "vulkan.h" : "vulkan_sc_core.h" }, { "vulkan_hpp", m_api + ".hpp" } } ) }, { "licenseHeader", m_vulkanLicenseHeader }, { "ObjectDestroy", readSnippet( "ObjectDestroy.hpp" ) }, { "ObjectFree", readSnippet( "ObjectFree.hpp" ) }, { "ObjectRelease", readSnippet( "ObjectRelease.hpp" ) }, { "Optional", readSnippet( "Optional.hpp" ) }, { "PoolFree", readSnippet( "PoolFree.hpp" ) }, { "resultChecks", readSnippet( "resultChecks.hpp" ) }, { "resultExceptions", generateResultExceptions() }, { "structExtendsStructs", generateStructExtendsStructs() }, { "ResultValue", readSnippet( "ResultValue.hpp" ) }, { "StridedArrayProxy", readSnippet( "StridedArrayProxy.hpp" ) }, { "StructureChain", readSnippet( "StructureChain.hpp" ) }, { "throwResultException", generateThrowResultException() }, { "typesafeCheck", m_typesafeCheck }, { "UniqueHandle", readSnippet( "UniqueHandle.hpp" ) } } ); writeToFile( str, vulkan_hpp ); } void VulkanHppGenerator::generateRAIIHppFile() const { std::string const vulkan_raii_hpp = std::string( BASE_PATH ) + "/vulkan/" + m_api + "_raii.hpp"; std::cout << "VulkanHppGenerator: Generating " << vulkan_raii_hpp << " ..." << std::endl; std::string const vulkanHandlesHppTemplate = R"(${licenseHeader} #ifndef VULKAN_RAII_HPP #define VULKAN_RAII_HPP #include #include // std::exchange, std::forward #include #if !defined( VULKAN_HPP_RAII_NAMESPACE ) # define VULKAN_HPP_RAII_NAMESPACE raii #endif #if !defined( VULKAN_HPP_DISABLE_ENHANCED_MODE ) && !defined(VULKAN_HPP_NO_EXCEPTIONS) namespace VULKAN_HPP_NAMESPACE { namespace VULKAN_HPP_RAII_NAMESPACE { template VULKAN_HPP_CONSTEXPR_14 VULKAN_HPP_INLINE T exchange( T & obj, U && newValue ) { # if ( 14 <= VULKAN_HPP_CPP_VERSION ) return std::exchange( obj, std::forward( newValue ) ); # else T oldValue = std::move( obj ); obj = std::forward( newValue ); return oldValue; # endif } ${RAIIDispatchers} ${RAIIHandles} ${RAIICommandDefinitions} } // namespace VULKAN_HPP_RAII_NAMESPACE } // namespace VULKAN_HPP_NAMESPACE #endif #endif )"; std::string str = replaceWithMap( vulkanHandlesHppTemplate, { { "licenseHeader", m_vulkanLicenseHeader }, { "RAIICommandDefinitions", generateRAIICommandDefinitions() }, { "RAIIDispatchers", generateRAIIDispatchers() }, { "RAIIHandles", generateRAIIHandles() } } ); writeToFile( str, vulkan_raii_hpp ); } void VulkanHppGenerator::generateStaticAssertionsHppFile() const { std::string const static_assertions_hpp = std::string( BASE_PATH ) + "/vulkan/" + m_api + "_static_assertions.hpp"; std::cout << "VulkanHppGenerator: Generating " << static_assertions_hpp << " ..." << std::endl; std::string const vulkanHandlesHppTemplate = R"(${licenseHeader} #ifndef VULKAN_STATIC_ASSERTIONS_HPP # define VULKAN_STATIC_ASSERTIONS_HPP #include //========================= //=== static_assertions === //========================= ${staticAssertions} #endif )"; std::string str = replaceWithMap( vulkanHandlesHppTemplate, { { "licenseHeader", m_vulkanLicenseHeader }, { "staticAssertions", generateStaticAssertions() } } ); writeToFile( str, static_assertions_hpp ); } void VulkanHppGenerator::generateStructsHppFile() const { std::string const vulkan_structs_hpp = std::string( BASE_PATH ) + "/vulkan/" + m_api + "_structs.hpp"; std::cout << "VulkanHppGenerator: Generating " << vulkan_structs_hpp << " ..." << std::endl; std::string const vulkanHandlesHppTemplate = R"(${licenseHeader} #ifndef VULKAN_STRUCTS_HPP # define VULKAN_STRUCTS_HPP #include // strcmp namespace VULKAN_HPP_NAMESPACE { ${structs} } // namespace VULKAN_HPP_NAMESPACE #endif )"; std::string str = replaceWithMap( vulkanHandlesHppTemplate, { { "licenseHeader", m_vulkanLicenseHeader }, { "structs", generateStructs() } } ); writeToFile( str, vulkan_structs_hpp ); } void VulkanHppGenerator::generateToStringHppFile() const { std::string const vulkan_to_string_hpp = std::string( BASE_PATH ) + "/vulkan/" + m_api + "_to_string.hpp"; std::cout << "VulkanHppGenerator: Generating " << vulkan_to_string_hpp << "..." << std::endl; std::string const vulkanHandlesHppTemplate = R"(${licenseHeader} #ifndef VULKAN_TO_STRING_HPP # define VULKAN_TO_STRING_HPP #include #if __cpp_lib_format # include // std::format #else # include // std::stringstream #endif namespace VULKAN_HPP_NAMESPACE { ${bitmasksToString} ${enumsToString} } // namespace VULKAN_HPP_NAMESPACE #endif )"; std::string str = replaceWithMap( vulkanHandlesHppTemplate, { { "bitmasksToString", generateBitmasksToString() }, { "enumsToString", generateEnumsToString() }, { "licenseHeader", m_vulkanLicenseHeader } } ); writeToFile( str, vulkan_to_string_hpp ); } void VulkanHppGenerator::generateCppModuleFile() const { std::string const vulkan_cppm = std::string( BASE_PATH ) + "/vulkan/" + m_api + ".cppm"; std::cout << "VulkanHppGenerator: Generating " << vulkan_cppm << "..." << std::endl; std::string const vulkanCppmTemplate = R"(${licenseHeader} module; #include #include #include #include #include export module ${api}; VULKAN_HPP_DEFAULT_DISPATCH_LOADER_DYNAMIC_STORAGE export namespace VULKAN_HPP_NAMESPACE { ${usings} namespace VULKAN_HPP_RAII_NAMESPACE { ${raiiUsings} } // namespace VULKAN_HPP_RAII_NAMESPACE } // namespace VULKAN_HPP_NAMESPACE )"; auto const str = replaceWithMap( vulkanCppmTemplate, { { "licenseHeader", m_vulkanLicenseHeader }, { "api", m_api }, { "usings", generateCppModuleUsings() }, { "raiiUsings", generateCppModuleRaiiUsings() } } ); writeToFile( str, vulkan_cppm ); } void VulkanHppGenerator::prepareRAIIHandles() { // filter out functions that are not usefull on this level of abstraction (like vkGetInstanceProcAddr) // and all the destruction functions, as they are used differently assert( m_handles.begin()->first.empty() ); for ( auto handleIt = std::next( m_handles.begin() ); handleIt != m_handles.end(); ++handleIt ) { handleIt->second.destructorIt = determineRAIIHandleDestructor( handleIt->first ); if ( handleIt->second.destructorIt != m_commands.end() ) { m_RAIISpecialFunctions.insert( handleIt->second.destructorIt->first ); } handleIt->second.constructorIts = determineRAIIHandleConstructors( handleIt->first, handleIt->second.destructorIt ); } distributeSecondLevelCommands( m_RAIISpecialFunctions ); } void VulkanHppGenerator::prepareVulkanFuncs() { // rename a couple of function parameters to prevent this warning, treated as an error: // warning C4458: declaration of 'objectType' hides class member for ( auto & command : m_commands ) { for ( auto & param : command.second.params ) { if ( param.name == "objectType" ) { param.name += "_"; } } } } // // VulkanHppGenerator private interface // void VulkanHppGenerator::addCommand( std::string const & name, CommandData & commandData ) { // find the handle this command is going to be associated to checkForError( !commandData.params.empty(), commandData.xmlLine, "command <" + name + "> with no params" ); auto handleIt = m_handles.find( commandData.params[0].type.type ); if ( handleIt == m_handles.end() ) { handleIt = m_handles.begin(); assert( handleIt->first == "" ); } commandData.handle = handleIt->first; // add this command to the list of commands checkForError( m_commands.insert( std::make_pair( name, commandData ) ).second, commandData.xmlLine, "already encountered command <" + name + ">" ); } void VulkanHppGenerator::addCommandsToHandle( std::vector const & requireData ) { for ( auto const & require : requireData ) { for ( auto const & command : require.commands ) { auto const & commandData = getCommandData( command ); auto handleIt = m_handles.find( commandData.handle ); assert( handleIt != m_handles.end() ); if ( !handleIt->second.commands.contains( command ) ) { handleIt->second.commands.insert( command ); registerDeleter( command, commandData ); } } } } void VulkanHppGenerator::addMissingFlagBits( std::vector & requireData, std::string const & requiredBy ) { for ( auto & require : requireData ) { std::vector newTypes; for ( auto const & type : require.types ) { auto bitmaskIt = m_bitmasks.find( type ); if ( ( bitmaskIt != m_bitmasks.end() ) && bitmaskIt->second.require.empty() ) { // generate the flagBits enum name out of the bitmask name: VkFooFlagsXXX -> VkFooFlagBitsXXX size_t pos = bitmaskIt->first.find( "Flags" ); assert( pos != std::string::npos ); std::string flagBits = bitmaskIt->first.substr( 0, pos + 4 ) + "Bit" + bitmaskIt->first.substr( pos + 4 ); // as the bitmask's requirement is still empty, this flagBits should not be listed in the require list! assert( std::none_of( require.types.begin(), require.types.end(), [&flagBits]( std::string const & type ) { return ( type == flagBits ); } ) ); bitmaskIt->second.require = flagBits; // some flagsBits are specified but never listed as required for any flags! // so, even if this bitmask has no enum listed as required, it might still already exist in the enums list auto enumIt = m_enums.find( flagBits ); if ( enumIt == m_enums.end() ) { m_enums.insert( std::make_pair( flagBits, EnumData{ .isBitmask = true, .xmlLine = 0 } ) ); assert( !m_types.contains( flagBits ) ); m_types.insert( std::make_pair( flagBits, TypeData{ TypeCategory::Bitmask, { requiredBy }, 0 } ) ); } else { assert( m_types.contains( flagBits ) ); enumIt->second.isBitmask = true; } newTypes.push_back( flagBits ); } } // add all the newly created flagBits types to the require list as if they had been part of the vk.xml! require.types.insert( require.types.end(), newTypes.begin(), newTypes.end() ); } } std::string VulkanHppGenerator::addTitleAndProtection( std::string const & title, std::string const & strIf, std::string const & strElse ) const { std::string str; if ( !strIf.empty() ) { auto [enter, leave] = generateProtection( getProtectFromTitle( title ) ); str = "\n" + enter + " //=== " + title + " ===\n" + strIf; if ( !enter.empty() && !strElse.empty() ) { str += "#else \n" + strElse; } str += leave; } return str; } bool VulkanHppGenerator::allVectorSizesSupported( std::vector const & params, std::map const & vectorParams ) const { // check if all vector sizes are by value and their type is one of "uint32_t", "VkDeviceSize", or "VkSampleCountFlagBits" return std::all_of( vectorParams.begin(), vectorParams.end(), [¶ms]( auto const & vpi ) { return params[vpi.second.lenParam].type.isValue() && ( ( params[vpi.second.lenParam].type.type == "uint32_t" ) || ( params[vpi.second.lenParam].type.type == "VkDeviceSize" ) || ( params[vpi.second.lenParam].type.type == "VkSampleCountFlagBits" ) ); } ); } void VulkanHppGenerator::appendDispatchLoaderDynamicCommands( std::vector const & requireData, std::set & 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 const & commandData = getCommandData( command ); members += " PFN_" + command + " " + command + " = 0;\n"; placeholders += " PFN_dummy " + command + "_placeholder = 0;\n"; if ( commandData.handle.empty() ) { initial += generateDispatchLoaderDynamicCommandAssignment( command, "NULL" ); } else { instance += generateDispatchLoaderDynamicCommandAssignment( command, "instance" ); if ( isDeviceCommand( commandData ) ) { device += generateDispatchLoaderDynamicCommandAssignment( command, "device" ); } } } } } auto [enter, leave] = generateProtection( getProtectFromTitle( title ) ); 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 const & requireData, std::set & 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 const & commandData = getCommandData( command ); if ( commandData.handle.empty() ) { assert( findAlias( command, m_commandAliases ) == m_commandAliases.end() ); ci += ", " + command + "( PFN_" + command + "( getProcAddr( NULL, \"" + command + "\" ) ) )"; cm += " PFN_" + command + " " + command + " = 0;\n"; } else if ( ( commandData.handle == "VkDevice" ) || hasParentHandle( commandData.handle, "VkDevice" ) ) { da += " " + command + " = PFN_" + command + "( vkGetDeviceProcAddr( device, \"" + command + "\" ) );\n"; // if this is an alias'ed function, use it as a fallback for the original one auto aliasIt = m_commandAliases.find( command ); if ( aliasIt != m_commandAliases.end() ) { da += " if ( !" + aliasIt->second.name + " ) " + aliasIt->second.name + " = " + command + ";\n"; } dm += " PFN_" + command + " " + command + " = 0;\n"; dmp += " PFN_dummy " + command + "_placeholder = 0;\n"; } else { assert( ( commandData.handle == "VkInstance" ) || hasParentHandle( commandData.handle, "VkInstance" ) ); // filter out vkGetInstanceProcAddr, as starting with Vulkan 1.2 it can resolve itself only (!) with an // instance nullptr ! if ( command != "vkGetInstanceProcAddr" ) { ia += " " + command + " = PFN_" + command + "( vkGetInstanceProcAddr( instance, \"" + command + "\" ) );\n"; // if this is an alias'ed function, use it as a fallback for the original one auto aliasIt = m_commandAliases.find( command ); if ( aliasIt != m_commandAliases.end() ) { ia += " if ( !" + aliasIt->second.name + " ) " + aliasIt->second.name + " = " + command + ";\n"; } } im += +" PFN_" + command + " " + command + " = 0;\n"; imp += " PFN_dummy " + command + "_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 required 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() ); checkForError( !typeIt->second.requiredBy.empty(), bitmask.second.xmlLine, "bitmask <" + bitmask.first + "> not required in any feature or extension" ); // check that the requirement is an enum if ( !bitmask.second.require.empty() ) { checkForError( m_enums.contains( bitmask.second.require ), bitmask.second.xmlLine, "bitmask <" + bitmask.first + "> requires unknown enum <" + bitmask.second.require + ">" ); } } } void VulkanHppGenerator::checkCommandCorrectness() const { // prepare command checks by gathering all result codes (including aliases and not supported ones!) into one set of resultCodes auto resultIt = m_enums.find( "VkResult" ); assert( resultIt != m_enums.end() ); std::set resultCodes; for ( auto rc : resultIt->second.values ) { resultCodes.insert( rc.name ); } for ( auto rc : resultIt->second.unsupportedValues ) { resultCodes.insert( rc.name ); } // 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? checkForError( !command.second.requiredBy.empty(), command.second.xmlLine, "command <" + command.first + "> not required in any feature or extension" ); // check for unknown error or succes codes for ( auto const & ec : command.second.errorCodes ) { checkForError( resultCodes.contains( ec ), command.second.xmlLine, "command uses unknown error code <" + ec + ">" ); } for ( auto const & sc : command.second.successCodes ) { checkForError( resultCodes.contains( sc ), command.second.xmlLine, "command uses unknown success code <" + sc + ">" ); } // check that functions returning a VkResult specify successcodes if ( ( command.second.returnType == "VkResult" ) && command.second.successCodes.empty() ) { // emit an error if this function is required in at least one supported feature or extension // disabled or not supported features/extensions are still listed in requiredBy, but not in m_features/m_extensions bool functionUsed = false; for ( auto const & require : command.second.requiredBy ) { functionUsed |= isSupportedFeature( require ) || isSupportedExtension( require ); } if ( functionUsed ) { checkForError( false, 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 ) { checkForError( m_types.contains( p.type.type ), p.xmlLine, "comand uses parameter of unknown type <" + p.type.type + ">" ); } checkForError( m_types.contains( command.second.returnType ), command.second.xmlLine, "command uses unknown return type <" + command.second.returnType + ">" ); } } void VulkanHppGenerator::checkCorrectness() const { checkForError( !m_vulkanLicenseHeader.empty(), -1, "missing license header" ); checkBitmaskCorrectness(); checkCommandCorrectness(); checkDefineCorrectness(); checkEnumCorrectness(); checkExtensionCorrectness(); checkFuncPointerCorrectness(); checkHandleCorrectness(); checkStructCorrectness(); } void VulkanHppGenerator::checkDefineCorrectness() const { // check that any requirements of a define is known for ( auto const & d : m_defines ) { checkForError( d.second.require.empty() || m_types.contains( d.second.require ), d.second.xmlLine, "define <" + d.first + "> uses unknown require <" + d.second.require + ">" ); } } void VulkanHppGenerator::checkEnumCorrectness() const { for ( auto const & e : m_enums ) { // check that a bitmask is required somewhere // some bitmasks are never required, so make this a warning only auto typeIt = m_types.find( e.first ); assert( typeIt != m_types.end() ); checkForWarning( !typeIt->second.requiredBy.empty(), e.second.xmlLine, "enum <" + e.first + "> not required in any feature or extension" ); // check that the alias names are known enum values for ( auto const & value : e.second.values ) { checkForError( value.alias.empty() || std::any_of( e.second.values.begin(), e.second.values.end(), [&value]( auto const & evd ) { return evd.name == value.alias; } ) || std::any_of( e.second.unsupportedValues.begin(), e.second.unsupportedValues.end(), [&value]( auto const & evd ) { return evd.name == value.alias; } ), value.xmlLine, "enum <" + value.name + "> uses unknown alias <" + value.alias + ">" ); } } // enum checks by features and extensions for ( auto & feature : m_features ) { checkEnumCorrectness( feature.requireData ); } for ( auto & ext : m_extensions ) { checkEnumCorrectness( ext.requireData ); } // enum alias checks for ( auto const & alias : m_enumAliases ) { checkForError( m_enums.contains( alias.second.name ), alias.second.xmlLine, "enum <" + alias.first + "> uses unknown alias <" + alias.second.name + ">" ); } // special check for VkFormat if ( !m_formats.empty() ) { auto enumIt = m_enums.find( "VkFormat" ); assert( enumIt != m_enums.end() ); assert( enumIt->second.values.front().name == "VK_FORMAT_UNDEFINED" ); for ( auto enumValueIt = std::next( enumIt->second.values.begin() ); enumValueIt != enumIt->second.values.end(); ++enumValueIt ) { // check for non-alias formats only checkForError( !enumValueIt->alias.empty() || m_formats.contains( enumValueIt->name ), enumValueIt->xmlLine, "missing format specification for <" + enumValueIt->name + ">" ); } } } void VulkanHppGenerator::checkEnumCorrectness( std::vector const & requireData ) const { for ( auto const & require : requireData ) { for ( auto const & type : require.types ) { auto typeIt = m_types.find( type ); assert( typeIt != m_types.end() ); switch ( typeIt->second.category ) { case TypeCategory::Bitmask: { // check that each "require" listed for a bitmask is listed for a feature or an extension auto bitmaskIt = m_bitmasks.find( type ); if ( bitmaskIt != m_bitmasks.end() ) { // not for every bitmask is a "require" listed if ( !bitmaskIt->second.require.empty() ) { auto requireTypeIt = m_types.find( bitmaskIt->second.require ); assert( requireTypeIt != m_types.end() ); checkForError( !requireTypeIt->second.requiredBy.empty(), bitmaskIt->second.xmlLine, "bitmask <" + bitmaskIt->first + "> requires <" + bitmaskIt->second.require + "> which is not required by any feature or extension!" ); } } else { // every bitmask not listed in the m_bitmasks, should be an alias of such a thing checkForError( m_bitmaskAliases.contains( type ), typeIt->second.xmlLine, "bitmask type <" + type + "> is not listed as a bitmask" ); } } 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.require == enumIt->first; } ); checkForError( 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 checkForError( ( 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 " ); } } else { // every enum not listed in the m_enums, should be an alias of such a thing checkForError( m_enumAliases.contains( type ), typeIt->second.xmlLine, "enum type <" + type + "> is not listed as an enum" ); } } break; default: break; } } } } bool VulkanHppGenerator::checkEquivalentSingularConstructor( std::vector::const_iterator> const & constructorIts, std::map::const_iterator constructorIt, std::vector::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::const_iterator it ) { if ( it->second.params.size() + 1 != constructorIt->second.params.size() ) { return false; } size_t lenIdx = std::distance( constructorIt->second.params.begin(), lenIt ); for ( size_t i = 0, j = 0; i < it->second.params.size(); ++i, ++j ) { assert( j < constructorIt->second.params.size() ); if ( j == lenIdx ) { ++j; } if ( it->second.params[i].type.type != constructorIt->second.params[j].type.type ) { return false; } } return true; }; return ( std::any_of( constructorIts.begin(), constructorIts.end(), isEquivalentSingularConstructor ) ); } void VulkanHppGenerator::checkExtensionCorrectness() const { for ( auto const & extension : m_extensions ) { // check for existence of any depends, deprecation, obsoletion, or promotion for ( auto const & dependsByVersion : extension.depends ) { checkForError( isFeature( dependsByVersion.first ), extension.xmlLine, "extension <" + extension.name + "> lists an unknown feature <" + dependsByVersion.first + ">" ); for ( auto const & dependsSet : dependsByVersion.second ) { for ( auto const & depends : dependsSet ) { checkForError( isExtension( depends ), extension.xmlLine, "extension <" + extension.name + "> lists an unknown depends <" + depends + ">" ); } } } if ( !extension.deprecatedBy.empty() ) { checkForError( isFeature( extension.deprecatedBy ) || isExtension( extension.deprecatedBy ), extension.xmlLine, "extension <" + extension.name + "> is deprecated by unknown extension/version <" + extension.promotedTo + ">" ); } if ( !extension.obsoletedBy.empty() ) { checkForError( isFeature( extension.obsoletedBy ) || isExtension( extension.obsoletedBy ), extension.xmlLine, "extension <" + extension.name + "> is obsoleted by unknown extension/version <" + extension.promotedTo + ">" ); } if ( !extension.promotedTo.empty() ) { checkForError( isFeature( extension.promotedTo ) || isExtension( extension.promotedTo ), extension.xmlLine, "extension <" + extension.name + "> is promoted to unknown extension/version <" + extension.promotedTo + ">" ); } // check for existence of any requirement for ( auto const & require : extension.requireData ) { if ( !require.depends.empty() ) { std::vector depends = tokenizeAny( require.depends, ",+()" ); for ( auto const & depend : depends ) { checkForError( isFeature( depend ) || isExtension( depend ), require.xmlLine, "extension <" + extension.name + "> lists an unknown depends <" + depend + ">" ); } } } } } void VulkanHppGenerator::checkFuncPointerCorrectness() const { for ( auto const & funcPointer : m_funcPointers ) { if ( !funcPointer.second.require.empty() ) { checkForError( m_types.contains( funcPointer.second.require ), funcPointer.second.xmlLine, "funcpointer requires unknown <" + funcPointer.second.require + ">" ); } for ( auto const & argument : funcPointer.second.arguments ) { checkForError( m_types.contains( argument.type ), 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 checkForError( m_handles.contains( handle.second.parent ), 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() ); // only check with used handles! checkForError( !isTypeUsed( handle.first ) || std::any_of( objectTypeIt->second.values.begin(), objectTypeIt->second.values.end(), [&handle]( EnumValueData const & evd ) { return evd.name == handle.second.objTypeEnum; } ), 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 for non-alias objectTypes only checkForError( !objectTypeValue.alias.empty() || std::any_of( m_handles.begin(), m_handles.end(), [&objectTypeValue]( std::pair const & hd ) { return hd.second.objTypeEnum == objectTypeValue.name; } ), objectTypeValue.xmlLine, "VkObjectType value <" + objectTypeValue.name + "> not specified as \"objtypeenum\" for any handle" ); } } } void VulkanHppGenerator::checkStructCorrectness() const { for ( auto const & structAlias : m_structAliases ) { checkForError( m_structs.contains( structAlias.second.name ), structAlias.second.xmlLine, "unknown struct alias <" + structAlias.second.name + ">" ); } std::set sTypeValues; for ( auto const & structure : m_structs ) { // 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() ); checkForError( !typeIt->second.requiredBy.empty(), structure.second.xmlLine, "structure <" + structure.first + "> not required by any feature or extension" ); // check for existence of all structs that are extended by this struct for ( auto const & extend : structure.second.structExtends ) { checkForError( m_structs.contains( extend ) || m_structAliases.contains( extend ), 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() ); static std::set reservedValues = { "VK_STRUCTURE_TYPE_LOADER_INSTANCE_CREATE_INFO", "VK_STRUCTURE_TYPE_LOADER_DEVICE_CREATE_INFO", "VK_STRUCTURE_TYPE_PRIVATE_VENDOR_INFO_RESERVED_OFFSET_0_NV" }; for ( auto const & enumValue : structureTypeIt->second.values ) { if ( reservedValues.contains( enumValue.name ) ) { checkForError( !sTypeValues.contains( enumValue.name ), enumValue.xmlLine, "Reserved VkStructureType enum value <" + enumValue.name + "> is used" ); } else { // check for non-alias structureTypes only checkForError( !enumValue.alias.empty() || ( 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 const & members, std::set & sTypeValues ) const { // determine if this struct is requird/used bool structUsed = isTypeUsed( structureName ); for ( auto const & member : members ) { // check that all member types are required in some feature or extension if ( member.type.type.starts_with( "Vk" ) ) { auto memberTypeIt = m_types.find( member.type.type ); assert( memberTypeIt != m_types.end() ); checkForError( !memberTypeIt->second.requiredBy.empty(), member.xmlLine, "struct member type <" + member.type.type + "> used in struct <" + structureName + "> is never required for any feature or extension" ); } // 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() ) { auto selectorIt = findStructMemberIt( member.selector, members ); assert( selectorIt != members.end() ); auto selectorEnumIt = m_enums.find( selectorIt->type.type ); assert( selectorEnumIt != m_enums.end() ); auto unionIt = m_structs.find( member.type.type ); assert( ( unionIt != m_structs.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() ); for ( auto const & selection : unionMember.selection ) { checkForError( std::any_of( selectorEnumIt->second.values.begin(), selectorEnumIt->second.values.end(), [&selection]( EnumValueData const & evd ) { return evd.name == selection; } ) || std::any_of( selectorEnumIt->second.unsupportedValues.begin(), selectorEnumIt->second.unsupportedValues.end(), [&selection]( EnumValueData const & evd ) { return evd.name == selection; } ), 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 checkForError( m_types.contains( member.type.type ), member.xmlLine, "struct member uses unknown type <" + member.type.type + ">" ); // check that any used constant is a known constant for ( auto const & arraySize : member.arraySizes ) { checkForError( ( arraySize.find_first_not_of( "0123456789" ) == std::string::npos ) || m_constants.contains( arraySize ), member.xmlLine, "struct member array size uses unknown constant <" + arraySize + ">" ); } // 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 (if the struct is used at all) if ( structUsed ) { checkForError( std::any_of( enumIt->second.values.begin(), enumIt->second.values.end(), [&member]( auto const & evd ) { return member.value == evd.name; } ), 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" ) { checkForError( 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 checkForError( 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 checkForError( false, member.xmlLine, "member <" + member.name + "> in structure <" + structureName + "> holds value <" + member.value + "> for an unhandled type <" + member.type.type + ">" ); } } } } std::string VulkanHppGenerator::combineDataTypes( std::map const & vectorParams, std::vector const & returnParams, bool enumerating, std::vector const & dataTypes, CommandFlavourFlags flavourFlags, bool raii ) const { assert( dataTypes.size() == returnParams.size() ); std::vector modifiedDataTypes( dataTypes.size() ); for ( size_t i = 0; i < returnParams.size(); ++i ) { auto vectorParamIt = vectorParams.find( returnParams[i] ); modifiedDataTypes[i] = ( vectorParamIt == vectorParams.end() || ( flavourFlags & CommandFlavourFlagBits::singular ) ) ? dataTypes[i] : ( "std::vector<" + dataTypes[i] + ( raii || ( flavourFlags & CommandFlavourFlagBits::unique ) ? ">" : ( ", " + startUpperCase( stripPrefix( dataTypes[i], "VULKAN_HPP_NAMESPACE::" ) ) + "Allocator>" ) ) ); } std::string combinedType; switch ( modifiedDataTypes.size() ) { case 0: combinedType = "void"; break; case 1: combinedType = modifiedDataTypes[0]; break; case 2: assert( !enumerating || ( vectorParams.contains( returnParams[1] ) && ( vectorParams.find( returnParams[1] )->second.lenParam == returnParams[0] ) ) ); combinedType = enumerating ? modifiedDataTypes[1] : ( "std::pair<" + modifiedDataTypes[0] + ", " + modifiedDataTypes[1] + ">" ); break; case 3: assert( enumerating ); switch ( vectorParams.size() ) { case 1: assert( ( vectorParams.begin()->first == returnParams[2] ) && ( vectorParams.begin()->second.lenParam == returnParams[1] ) ); combinedType = "std::pair<" + modifiedDataTypes[0] + ", " + modifiedDataTypes[2] + ">"; break; case 2: assert( ( vectorParams.begin()->first == returnParams[1] ) && ( vectorParams.begin()->second.lenParam == returnParams[0] ) && ( std::next( vectorParams.begin() )->first == returnParams[2] ) && ( std::next( vectorParams.begin() )->second.lenParam == returnParams[0] ) ); combinedType = "std::pair<" + modifiedDataTypes[1] + ", " + modifiedDataTypes[2] + ">"; break; default: assert( false ); break; } break; default: assert( false ); break; } return combinedType; } bool VulkanHppGenerator::containsArray( std::string const & type ) const { // a simple recursive check if a type is or contains an array auto structureIt = m_structs.find( type ); bool found = false; if ( structureIt != m_structs.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::containsFuncPointer( std::string const & type ) const { // a simple recursive check if a type contains a funcpointer auto structureIt = m_structs.find( type ); bool found = false; if ( structureIt != m_structs.end() ) { for ( auto memberIt = structureIt->second.members.begin(); memberIt != structureIt->second.members.end() && !found; ++memberIt ) { found = m_funcPointers.contains( memberIt->type.type ) || ( ( memberIt->type.type != type ) && containsFuncPointer( memberIt->type.type ) ); } } return found; } bool VulkanHppGenerator::containsFloatingPoints( std::vector const & members ) const { for ( auto const & m : members ) { if ( ( ( m.type.type == "float" ) || ( m.type.type == "double" ) ) && m.type.isValue() ) { return true; } } return false; } bool VulkanHppGenerator::containsUnion( std::string const & type ) const { // a simple recursive check if a type is or contains a union auto structureIt = m_structs.find( type ); bool found = false; if ( structureIt != m_structs.end() ) { found = structureIt->second.isUnion; for ( auto memberIt = structureIt->second.members.begin(); memberIt != structureIt->second.members.end() && !found; ++memberIt ) { found = memberIt->type.isValue() && containsUnion( memberIt->type.type ); } } return found; } std::vector VulkanHppGenerator::determineChainedReturnParams( std::vector const & params, std::vector const & returnParams ) const { std::vector chainedParams; for ( auto rp : returnParams ) { if ( isStructureChainAnchor( params[rp].type.type ) ) { chainedParams.push_back( rp ); } } return chainedParams; } std::vector VulkanHppGenerator::determineConstPointerParams( std::vector const & params ) const { std::vector constPointerParams; 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.contains( params[i].type.type ) ) ) { constPointerParams.push_back( i ); } } return constPointerParams; } std::vector VulkanHppGenerator::determineDataTypes( std::vector const & params, std::map const & vectorParams, std::vector const & returnParams, std::set const & templatedParams ) const { std::vector dataTypes; for ( auto rp : returnParams ) { if ( templatedParams.contains( rp ) ) { auto vectorParamIt = vectorParams.find( rp ); if ( ( vectorParamIt != vectorParams.end() ) && std::any_of( returnParams.begin(), returnParams.end(), [&vectorParamIt]( size_t rp ) { return rp == vectorParamIt->first; } ) && std::any_of( returnParams.begin(), returnParams.end(), [&vectorParamIt]( size_t rp ) { return rp == vectorParamIt->second.lenParam; } ) ) { dataTypes.push_back( "uint8_t" ); } else { dataTypes.push_back( ( stripPrefix( params[rp].name, "p" ) + "Type" ) ); } } else { dataTypes.push_back( trimEnd( stripPostfix( params[rp].type.compose( "VULKAN_HPP_NAMESPACE" ), "*" ) ) ); } } return dataTypes; } size_t VulkanHppGenerator::determineDefaultStartIndex( std::vector const & params, std::set const & skippedParams ) const { // determine the index where the arguments start to have defaults size_t defaultStartIndex = INVALID_INDEX; for ( int i = static_cast( params.size() ) - 1; ( 0 <= i ) && ( params[i].optional || skippedParams.contains( i ) ); --i ) { defaultStartIndex = i; } return defaultStartIndex; } bool VulkanHppGenerator::determineEnumeration( std::map const & vectorParams, std::vector const & returnParams ) const { // a command is considered to be enumerating some data, if for at least one vectorParam both, the data and the counter, are returnParams return std::any_of( vectorParams.begin(), vectorParams.end(), [&returnParams]( auto const & vp ) { return std::any_of( returnParams.begin(), returnParams.end(), [&vp]( size_t rp ) { return rp == vp.first; } ) && std::any_of( returnParams.begin(), returnParams.end(), [&vp]( size_t rp ) { return rp == vp.second.lenParam; } ); } ); } 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 ); if ( commandIt == m_commands.end() ) { auto aliasIt = m_commandAliases.find( command ); assert( aliasIt != m_commandAliases.end() ); commandIt = m_commands.find( aliasIt->second.name ); assert( commandIt != m_commands.end() ); } auto handleIt = m_handles.find( commandIt->second.handle ); assert( handleIt != m_handles.end() ); if ( !handleIt->second.commands.contains( commandIt->first ) ) { assert( 1 < commandIt->second.params.size() ); assert( m_handles.contains( commandIt->second.params[1].type.type ) ); return 2; } else { return handleIt->first.empty() ? 0 : 1; } } std::vector VulkanHppGenerator::determineReturnParams( std::vector const & params ) const { std::vector 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.contains( params[i].type.type ) ) { nonConstPointerParamIndices.push_back( i ); } } return nonConstPointerParamIndices; } std::vector::const_iterator> VulkanHppGenerator::determineRAIIHandleConstructors( std::string const & handleType, std::map::const_iterator destructorIt ) const { std::vector::const_iterator> constructorIts; auto isConstructorCandidate = [this, &handleType]( std::pair const & cd ) { return isSupported( cd.second.requiredBy ) && std::any_of( cd.second.params.begin(), cd.second.params.end(), [&handleType]( ParamData const & pd ) { return ( pd.type.type == handleType ) && pd.type.isNonConstPointer(); } ); }; 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 structureIt = m_structs.find( pd.type.type ); return ( structureIt != m_structs.end() ) && ( findStructMemberItByType( destructorParam.type.type, structureIt->second.members ) != structureIt->second.members.end() ); } return true; }; return ( destructorParam.name == desctructorHandleParamIt->lenExpression ) || std::any_of( commandIt->second.params.begin(), commandIt->second.params.end(), isDestructorParamType ); }; // the constructor candidate is valid, if none of the (relevant) destructor parameters is missing in the // constructor candidate params valid = std::all_of( destructorIt->second.params.begin(), destructorIt->second.params.end(), isConstructorCandidateParam ); } if ( valid ) { constructorIts.push_back( commandIt ); } ++commandIt; } } return constructorIts; } std::map::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 VulkanHppGenerator::determineSingularParams( size_t returnParam, std::map const & vectorParams ) const { auto returnVectorIt = vectorParams.find( returnParam ); assert( returnVectorIt != vectorParams.end() ); std::set singularParams; singularParams.insert( returnVectorIt->second.lenParam ); for ( auto const & vpi : vectorParams ) { if ( vpi.second.lenParam == returnVectorIt->second.lenParam ) { singularParams.insert( vpi.first ); } } return singularParams; } std::set VulkanHppGenerator::determineSkippedParams( std::vector const & params, size_t initialSkipCount, std::map const & vectorParams, std::vector const & returnParams, bool singular ) const { // skip the initial skips (get fed by the object) assert( initialSkipCount <= params.size() ); std::set skippedParams; for ( size_t i = 0; i < initialSkipCount; ++i ) { skippedParams.insert( i ); } // skip the size parameters (get derived from an array), and a stride parameter for ( auto const & vpi : vectorParams ) { assert( !params[vpi.first].lenExpression.empty() ); if ( ( std::none_of( returnParams.begin(), returnParams.end(), [&vpi]( size_t rpi ) { return vpi.first == rpi; } ) && isParam( params[vpi.first].lenExpression, params ) ) || ( singular && params[vpi.second.lenParam].type.isValue() ) ) { skippedParams.insert( vpi.second.lenParam ); } if ( vpi.second.strideParam != INVALID_INDEX ) { skippedParams.insert( vpi.second.strideParam ); } } // skip the return parameters (get resolved by local variables to be returned) skippedParams.insert( returnParams.begin(), returnParams.end() ); return skippedParams; } std::string VulkanHppGenerator::determineSubStruct( std::pair const & structure ) const { if ( structure.second.members.front().name != "sType" ) { // check if sd is a substruct of structure auto isSubStruct = [&structure]( std::pair 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::all_of( sd.second.members.begin(), sd.second.members.end(), isMember ); }; // look for a struct in m_structs that starts identically to structure auto structIt = std::find_if( m_structs.begin(), m_structs.end(), isSubStruct ); return ( structIt == m_structs.end() ) ? "" : structIt->first; } return ""; } std::map VulkanHppGenerator::determineVectorParams( std::vector const & params ) const { std::map vectorParams; // 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].lenExpression.empty() && ( params[i].lenExpression != "null-terminated" ) ) { VectorParamData & vpd = vectorParams[i]; if ( params[i].lenParams.empty() ) { std::string const & lenExpression = params[i].lenExpression; assert( std::none_of( params.begin(), params.end(), [&lenExpression]( auto const & pd ) { return ( lenExpression == pd.name ); } ) ); auto lenIt = std::find_if( params.begin(), params.end(), [this, &lenExpression]( auto const & pd ) { return isLenByStructMember( lenExpression, pd ); } ); assert( lenIt != params.end() ); vpd.lenParam = std::distance( params.begin(), lenIt ); } else { assert( params[i].lenParams.size() == 1 ); vpd.lenParam = params[i].lenParams[0].second; } if ( !params[i].strideParam.first.empty() ) { vpd.strideParam = params[i].strideParam.second; } } } return vectorParams; } std::set VulkanHppGenerator::determineVoidPointerParams( std::vector const & params ) const { std::set voidPointerParams; for ( size_t i = 0; i < params.size(); i++ ) { if ( !params[i].type.isValue() && ( params[i].type.type == "void" ) && ( params[i].type.postfix != "**" ) ) { voidPointerParams.insert( i ); } } return voidPointerParams; } void VulkanHppGenerator::distributeSecondLevelCommands( std::set 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.contains( *command ) ) { auto const & commandData = getCommandData( *command ); assert( commandData.params.front().type.type == handle.first ); if ( ( 1 < commandData.params.size() ) && ( isHandleType( commandData.params[1].type.type ) ) && !commandData.params[1].optional ) { auto handleIt = m_handles.find( commandData.params[1].type.type ); assert( handleIt != m_handles.end() ); // filter out functions seem to fit due to taking handles as first and second argument, but the first argument is not the // type to create the second one, and so it's unknown to the raii handle! assert( !handleIt->second.constructorIts.empty() ); if ( ( *handleIt->second.constructorIts.begin() )->second.handle == handle.first ) { assert( std::none_of( handleIt->second.constructorIts.begin(), handleIt->second.constructorIts.end(), [&handle]( auto const & constructorIt ) { return constructorIt->second.handle != handle.first; } ) ); handleIt->second.secondLevelCommands.insert( *command ); command = handle.second.commands.erase( command ); foundCommand = true; } } } if ( !foundCommand ) { ++command; } } } } } void VulkanHppGenerator::filterLenMembers() { for ( auto & sd : m_structs ) { for ( auto & member : sd.second.members ) { std::erase_if( member.lenMembers, [this]( std::pair const & nameIndex ) { return m_constants.contains( nameIndex.first ); } ); for ( auto & lenMember : member.lenMembers ) { if ( lenMember.second == size_t( ~0 ) ) { auto lenMemberIt = findStructMemberIt( lenMember.first, sd.second.members ); checkForError( lenMemberIt != sd.second.members.end(), member.xmlLine, "struct member <" + member.name + "> uses unknown len member <" + lenMember.first + "> in its \"altlen\" attribute <" + member.lenExpressions[0] + ">" ); lenMember.second = std::distance( sd.second.members.cbegin(), lenMemberIt ); } } } } } std::map::const_iterator VulkanHppGenerator::findAlias( std::string const & name, std::map const & aliases ) const { auto lambda = [&name]( std::pair const & ad ) { return ad.second.name == name; }; auto it = std::find_if( aliases.begin(), aliases.end(), lambda ); assert( ( it == aliases.end() ) || std::none_of( std::next( it ), aliases.end(), lambda ) ); return it; } std::string VulkanHppGenerator::findBaseName( std::string aliasName, std::map 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; } VulkanHppGenerator::EnumValueData const * VulkanHppGenerator::findEnumValueData( std::map::const_iterator enumIt, std::string const & name ) const { EnumValueData const * evdPtr = nullptr; auto evdIt = std::find_if( enumIt->second.values.begin(), enumIt->second.values.end(), [&name]( EnumValueData const & evd ) { return evd.name == name; } ); if ( evdIt == enumIt->second.values.end() ) { evdIt = std::find_if( enumIt->second.unsupportedValues.begin(), enumIt->second.unsupportedValues.end(), [&name]( EnumValueData const & evd ) { return evd.name == name; } ); if ( evdIt != enumIt->second.unsupportedValues.end() ) { evdPtr = &*evdIt; } } else { evdPtr = &*evdIt; } return evdPtr; } std::vector::const_iterator VulkanHppGenerator::findFeature( std::string const & name ) const { return std::find_if( m_features.begin(), m_features.end(), [&name]( FeatureData const & fd ) { return fd.name == name; } ); } std::vector::const_iterator VulkanHppGenerator::findParamIt( std::string const & name, std::vector const & paramData ) const { return std::find_if( paramData.begin(), paramData.end(), [&name]( ParamData const & pd ) { return pd.name == name; } ); } std::vector::const_iterator VulkanHppGenerator::findStructMemberIt( std::string const & name, std::vector const & memberData ) const { return std::find_if( memberData.begin(), memberData.end(), [&name]( MemberData const & md ) { return md.name == name; } ); } std::vector::const_iterator VulkanHppGenerator::findStructMemberItByType( std::string const & type, std::vector const & memberData ) const { return std::find_if( memberData.begin(), memberData.end(), [&type]( MemberData const & md ) { return md.type.type == type; } ); } std::vector::const_iterator VulkanHppGenerator::findSupportedExtension( std::string const & name ) const { return std::find_if( m_extensions.begin(), m_extensions.end(), [&name]( ExtensionData const & ed ) { return ed.name == name; } ); } std::string VulkanHppGenerator::findTag( std::string const & name, std::string const & postfix ) const { auto tagIt = std::find_if( m_tags.begin(), m_tags.end(), [&name, &postfix]( std::pair const & t ) { return name.ends_with( t.first + postfix ); } ); return ( tagIt != m_tags.end() ) ? tagIt->first : ""; } std::pair VulkanHppGenerator::generateAllocatorTemplates( std::vector const & returnParams, std::vector const & returnDataTypes, std::map const & vectorParams, std::vector const & chainedReturnParams, CommandFlavourFlags flavourFlags, bool definition ) const { assert( chainedReturnParams.size() <= 1 ); bool chained = flavourFlags & CommandFlavourFlagBits::chained; bool singular = flavourFlags & CommandFlavourFlagBits::singular; bool unique = flavourFlags & CommandFlavourFlagBits::unique; assert( returnParams.size() == returnDataTypes.size() ); std::string allocatorTemplates; if ( !singular ) { for ( size_t i = 0; i < returnParams.size(); i++ ) { if ( vectorParams.contains( returnParams[i] ) ) { if ( chained && !chainedReturnParams.empty() && ( chainedReturnParams[0] == returnParams[i] ) ) { allocatorTemplates += "typename StructureChainAllocator"; if ( !definition ) { allocatorTemplates += " = std::allocator"; } } else { allocatorTemplates += "typename " + startUpperCase( stripPrefix( returnDataTypes[i], "VULKAN_HPP_NAMESPACE::" ) ) + "Allocator"; if ( !definition ) { allocatorTemplates += " = std::allocator<" + ( unique ? ( "UniqueHandle<" + returnDataTypes[i] + ", Dispatch>" ) : returnDataTypes[i] ) + ">"; } } allocatorTemplates += ", "; } } } std::string uniqueHandleAllocatorTemplates; if ( unique && !allocatorTemplates.empty() ) { uniqueHandleAllocatorTemplates = ", " + stripPostfix( allocatorTemplates, ", " ); allocatorTemplates.clear(); } return std::make_pair( allocatorTemplates, uniqueHandleAllocatorTemplates ); } std::string VulkanHppGenerator::generateArgumentListEnhanced( std::vector const & params, std::vector const & returnParams, std::map const & vectorParams, std::set const & skippedParams, std::set const & singularParams, std::set const & templatedParams, std::vector const & chainedReturnParams, bool definition, CommandFlavourFlags flavourFlags, bool withDispatcher ) const { bool withAllocators = flavourFlags & CommandFlavourFlagBits::withAllocator; 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.contains( i ) ) { if ( encounteredArgument ) { argumentList += ", "; } bool hasDefaultAssignment = false; std::string composedType = params[i].type.compose( "VULKAN_HPP_NAMESPACE" ); if ( singularParams.contains( i ) ) { assert( !params[i].optional ); assert( params[i].type.isConstPointer() && !params[i].lenExpression.empty() && !isLenByStructMember( params[i].lenExpression, params ) && params[i].type.type.starts_with( "Vk" ) ); assert( !isHandleType( params[i].type.type ) ); assert( composedType.ends_with( " *" ) ); argumentList += stripPostfix( composedType, " *" ) + " & " + stripPluralS( startLowerCase( stripPrefix( params[i].name, "p" ) ) ); } else if ( params[i].type.isConstPointer() ) { assert( composedType.ends_with( " *" ) ); std::string name = startLowerCase( stripPrefix( params[i].name, "p" ) ); if ( params[i].lenExpression.empty() ) { assert( withDispatcher || !isHandleType( params[i].type.type ) ); assert( !params[i].type.prefix.empty() && ( params[i].type.postfix == "*" ) ); assert( params[i].arraySizes.empty() ); if ( params[i].type.type == "void" ) { argumentList += templatedParams.contains( i ) ? ( stripPrefix( params[i].name, "p" ) + "Type const & " + name ) : ( composedType + " " + params[i].name ); } else if ( params[i].optional ) { argumentList += "Optional<" + stripPostfix( composedType, " *" ) + "> " + name + ( ( definition || withAllocators ) ? "" : " VULKAN_HPP_DEFAULT_ARGUMENT_NULLPTR_ASSIGNMENT" ); hasDefaultAssignment = true; } else { argumentList += stripPostfix( composedType, " *" ) + " & " + name; } } else { // a const-pointer with a non-empty len is either null-terminated (aka a string) or represented by an // ArrayProxy assert( params[i].arraySizes.empty() ); if ( params[i].lenExpression == "null-terminated" ) { assert( params[i].type.type == "char" ); if ( params[i].optional ) { argumentList += "Optional " + name + ( ( definition || withAllocators ) ? "" : " VULKAN_HPP_DEFAULT_ARGUMENT_NULLPTR_ASSIGNMENT" ); hasDefaultAssignment = true; } else { argumentList += "const std::string & " + name; } } else { // an ArrayProxy also covers no data, so any optional flag can be ignored here std::string type = stripPostfix( composedType, " *" ); size_t pos = type.find( "void" ); if ( pos != std::string::npos ) { type.replace( pos, 4, stripPrefix( params[i].name, "p" ) + "Type" ); } argumentList += std::string( "VULKAN_HPP_NAMESPACE::" ) + ( params[i].strideParam.first.empty() ? "" : "Strided" ) + "ArrayProxy<" + type + "> const & " + name; if ( params[i].optional && !definition ) { assert( params[i].strideParam.first.empty() ); argumentList += " VULKAN_HPP_DEFAULT_ARGUMENT_NULLPTR_ASSIGNMENT"; hasDefaultAssignment = true; } } } } else if ( params[i].type.isNonConstPointer() ) { assert( withDispatcher || !isHandleType( params[i].type.type ) ); assert( params[i].lenExpression.empty() && !params[i].optional ); assert( composedType.ends_with( " *" ) ); argumentList += stripPostfix( composedType, " *" ) + " & " + params[i].name; } else { assert( params[i].type.isValue() ); argumentList += composedType + " " + params[i].name + generateCArraySizes( params[i].arraySizes ); } argumentList += std::string( !definition && ( defaultStartIndex <= i ) && !hasDefaultAssignment ? " VULKAN_HPP_DEFAULT_ARGUMENT_ASSIGNMENT" : "" ); encounteredArgument = true; } } if ( withAllocators ) { if ( ( flavourFlags & CommandFlavourFlagBits::chained ) && needsStructureChainResize( vectorParams, chainedReturnParams ) ) { if ( encounteredArgument ) { argumentList += ", "; } argumentList += "StructureChainAllocator & structureChainAllocator"; encounteredArgument = true; } else { for ( auto sp : skippedParams ) { if ( !params[sp].lenExpression.empty() ) { if ( encounteredArgument ) { argumentList += ", "; } std::string type; if ( templatedParams.contains( sp ) ) { auto vectorParamIt = vectorParams.find( sp ); if ( ( vectorParamIt != vectorParams.end() ) && std::any_of( returnParams.begin(), returnParams.end(), [&vectorParamIt]( size_t rp ) { return rp == vectorParamIt->first; } ) && std::any_of( returnParams.begin(), returnParams.end(), [&vectorParamIt]( size_t rp ) { return rp == vectorParamIt->second.lenParam; } ) ) { type = "Uint8_t"; } else { type = stripPrefix( params[sp].name, "p" ) + "Type"; } } else { 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 const & params, std::set const & skippedParams ) const { std::string argumentList; for ( size_t i = 0; i < params.size(); ++i ) { if ( !skippedParams.contains( i ) ) { argumentList += params[i].type.compose( "VULKAN_HPP_NAMESPACE" ) + " " + params[i].name + generateCArraySizes( params[i].arraySizes ) + ", "; } } argumentList += "Dispatch const & d "; return argumentList; } std::string VulkanHppGenerator::generateArgumentTemplates( std::vector const & params, std::vector const & returnParams, std::map const & vectorParams, std::set const & templatedParams, std::vector const & chainedReturnParams, bool raii ) const { std::string argumentTemplates; if ( !chainedReturnParams.empty() ) { assert( chainedReturnParams.size() == 1 ); argumentTemplates = vectorParams.contains( chainedReturnParams[0] ) ? "typename StructureChain, " : "typename X, typename Y, typename... Z, "; } if ( !templatedParams.empty() ) { for ( auto t : templatedParams ) { assert( params[t].name.starts_with( "p" ) ); auto vectorParamIt = vectorParams.find( t ); if ( ( vectorParamIt == vectorParams.end() ) || std::none_of( returnParams.begin(), returnParams.end(), [&vectorParamIt]( size_t rp ) { return rp == vectorParamIt->first; } ) || std::none_of( returnParams.begin(), returnParams.end(), [&vectorParamIt]( size_t rp ) { return rp == vectorParamIt->second.lenParam; } ) ) { assert( chainedReturnParams.empty() ); // only templated parameters that are not part of an enumeration are really templated argumentTemplates += "typename " + stripPrefix( params[t].name, "p" ) + "Type, "; } } } if ( !argumentTemplates.empty() && raii ) { argumentTemplates = "template <" + stripPostfix( argumentTemplates, ", " ) + ">"; } return argumentTemplates; } 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, and basetypes without any type information if ( ( baseType.first != "VkFlags" ) && ( baseType.first != "VkFlags64" ) && !baseType.second.typeInfo.type.empty() ) { basetypes += " using " + stripPrefix( baseType.first, "Vk" ) + " = " + baseType.second.typeInfo.compose( "VULKAN_HPP_NAMESPACE" ) + ";\n"; } } return replaceWithMap( basetypesTemplate, { { "basetypes", basetypes } } ); } std::string VulkanHppGenerator::generateBitmask( std::map::const_iterator bitmaskIt, std::string const & surroundingProtect ) const { auto bitmaskBitsIt = m_enums.find( bitmaskIt->second.require ); assert( bitmaskBitsIt != m_enums.end() ); std::string bitmaskName = stripPrefix( bitmaskIt->first, "Vk" ); std::string enumName = stripPrefix( bitmaskBitsIt->first, "Vk" ); auto aliasBitmaskIt = findAlias( bitmaskIt->first, m_bitmaskAliases ); std::string alias = ( aliasBitmaskIt == m_bitmaskAliases.end() ) ? "" : ( " using " + stripPrefix( aliasBitmaskIt->first, "Vk" ) + " = " + bitmaskName + ";\n" ); std::string allFlags; if ( bitmaskBitsIt->second.values.empty() ) { allFlags = " {};"; } else { bool encounteredFlag = false; std::string previousEnter, previousLeave; for ( auto const & value : bitmaskBitsIt->second.values ) { // only list non-alias values in the allFlags trait if ( value.alias.empty() ) { // if the value's protect differs from the surrounding protect, generate protection code std::string enter, leave; if ( !value.protect.empty() && ( value.protect != surroundingProtect ) ) { tie( enter, leave ) = generateProtection( value.protect ); } std::string valueName = generateEnumValueName( bitmaskBitsIt->first, value.name, true ); allFlags += ( ( previousEnter != enter ) ? ( "\n" + previousLeave + enter ) : "\n" ) + " " + ( encounteredFlag ? "| " : " " ) + enumName + "::" + valueName; encounteredFlag = true; previousEnter = enter; previousLeave = leave; } } if ( !previousLeave.empty() ) { allFlags += "\n" + previousLeave; } allFlags += ";"; } static const std::string bitmaskTemplate = R"( using ${bitmaskName} = Flags<${enumName}>; ${alias} template <> struct FlagTraits<${enumName}> { static VULKAN_HPP_CONST_OR_CONSTEXPR bool isBitmask = true; static VULKAN_HPP_CONST_OR_CONSTEXPR ${bitmaskName} allFlags = ${allFlags} }; )"; return replaceWithMap( bitmaskTemplate, { { "alias", alias }, { "allFlags", allFlags }, { "bitmaskName", bitmaskName }, { "enumName", enumName } } ); } std::string VulkanHppGenerator::generateBitmasksToString() const { const std::string bitmasksToStringTemplate = R"( //========================== //=== BITMASKs to_string === //========================== ${bitmasksToString} )"; std::string bitmasksToString; std::set listedBitmasks; for ( auto const & feature : m_features ) { bitmasksToString += generateBitmasksToString( feature.requireData, listedBitmasks, feature.name ); } for ( auto const & extension : m_extensions ) { bitmasksToString += generateBitmasksToString( extension.requireData, listedBitmasks, extension.name ); } return replaceWithMap( bitmasksToStringTemplate, { { "bitmasksToString", bitmasksToString } } ); } std::string VulkanHppGenerator::generateBitmasksToString( std::vector const & requireData, std::set & 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.contains( type ) ) { listedBitmasks.insert( type ); str += generateBitmaskToString( bitmaskIt ); } } } return addTitleAndProtection( title, str ); } std::string VulkanHppGenerator::generateBitmaskToString( std::map::const_iterator bitmaskIt ) const { auto bitmaskBitsIt = m_enums.find( bitmaskIt->second.require ); assert( bitmaskBitsIt != m_enums.end() ); std::string bitmaskName = stripPrefix( bitmaskIt->first, "Vk" ); std::string enumName = stripPrefix( bitmaskBitsIt->first, "Vk" ); std::string str; if ( bitmaskBitsIt->second.values.empty() ) { static std::string bitmaskToStringTemplate = R"( VULKAN_HPP_INLINE std::string to_string( ${bitmaskName} ) { return "{}"; } )"; str += replaceWithMap( bitmaskToStringTemplate, { { "bitmaskName", bitmaskName } } ); } else { static const std::string bitmaskToStringTemplate = R"( VULKAN_HPP_INLINE std::string to_string( ${bitmaskName} value ) { if ( !value ) return "${emptyValue}"; std::string result; ${toStringChecks} return "{ " + result.substr( 0, result.size() - 3 ) + " }"; } )"; std::string emptyValue = "{}"; std::string toStringChecks; std::string previousEnter, previousLeave; for ( auto const & value : bitmaskBitsIt->second.values ) { std::string valueName = generateEnumValueName( bitmaskBitsIt->first, value.name, true ); if ( value.value == "0" ) { assert( emptyValue == "{}" ); emptyValue = valueName.substr( 1 ); } else if ( !value.bitpos.empty() ) { assert( value.alias.empty() ); auto [enter, leave] = generateProtection( value.protect ); toStringChecks += ( ( previousEnter != enter ) ? ( previousLeave + enter ) : "" ) + " if ( value & " + enumName + "::" + valueName + " ) result += \"" + valueName.substr( 1 ) + " | \";\n"; previousEnter = enter; previousLeave = leave; } } if ( !previousLeave.empty() ) { assert( previousLeave.ends_with( "\n" ) ); toStringChecks += previousLeave; previousLeave.resize( previousLeave.size() - strlen( "\n" ) ); } str += replaceWithMap( bitmaskToStringTemplate, { { "bitmaskName", bitmaskName }, { "emptyValue", emptyValue }, { "toStringChecks", toStringChecks } } ); } return str; } std::string VulkanHppGenerator::generateCallArgumentsEnhanced( CommandData const & commandData, size_t initialSkipCount, bool nonConstPointerAsNullptr, std::set const & singularParams, std::set const & templatedParams, bool raiiHandleMemberFunction ) const { assert( initialSkipCount <= commandData.params.size() ); std::string arguments; bool encounteredArgument = false; if ( raiiHandleMemberFunction ) { switch ( initialSkipCount ) { case 1: assert( isHandleType( commandData.params[0].type.type ) && commandData.params[0].type.isValue() ); assert( commandData.params[0].arraySizes.empty() && commandData.params[0].lenExpression.empty() ); assert( commandData.params[0].type.type == commandData.handle ); arguments = "static_cast<" + commandData.handle + ">( m_" + startLowerCase( stripPrefix( commandData.handle, "Vk" ) ) + " )"; encounteredArgument = true; break; case 2: { assert( isHandleType( commandData.params[0].type.type ) && commandData.params[0].type.isValue() ); assert( commandData.params[0].arraySizes.empty() && commandData.params[0].lenExpression.empty() ); assert( commandData.params[0].type.type == commandData.handle ); auto handleIt = m_handles.find( commandData.params[1].type.type ); assert( handleIt != m_handles.end() ); arguments = "static_cast<" + commandData.handle + ">( m_" + startLowerCase( stripPrefix( commandData.handle, "Vk" ) ) + " )"; assert( commandData.params[1].type.isValue() && commandData.params[1].arraySizes.empty() && commandData.params[1].lenExpression.empty() ); arguments += ", static_cast<" + commandData.params[1].type.type + ">( m_" + generateRAIIHandleConstructorParamName( handleIt->first, handleIt->second.destructorIt ) + " )"; encounteredArgument = true; } break; } } else { for ( size_t i = 0; i < initialSkipCount; ++i ) { if ( encounteredArgument ) { arguments += ", "; } assert( isHandleType( commandData.params[i].type.type ) && commandData.params[i].type.isValue() ); assert( commandData.params[i].arraySizes.empty() && commandData.params[i].lenExpression.empty() ); arguments += "m_" + startLowerCase( stripPrefix( commandData.params[i].type.type, "Vk" ) ); encounteredArgument = true; } } for ( size_t i = initialSkipCount; i < commandData.params.size(); ++i ) { if ( encounteredArgument ) { arguments += ", "; } arguments += generateCallArgumentEnhanced( commandData.params, i, nonConstPointerAsNullptr, singularParams, templatedParams ); encounteredArgument = true; } return arguments; } std::string VulkanHppGenerator::generateCallArgumentsRAIIFactory( std::vector const & params, size_t initialSkipCount, std::set const & skippedParams, std::set const & singularParams ) const { assert( initialSkipCount <= params.size() ); std::string arguments = "*this"; // skip the last parameter! for ( size_t i = initialSkipCount; i < params.size() - 1; ++i ) { if ( !skippedParams.contains( i ) ) { std::string argument = params[i].name; if ( !params[i].type.isValue() ) { argument = startLowerCase( stripPrefix( argument, "p" ) ); if ( singularParams.contains( i ) ) { argument = stripPluralS( argument ); } } else { assert( !singularParams.contains( i ) ); } arguments += ", " + argument; } } return arguments; } std::string VulkanHppGenerator::generateCallArgumentsStandard( std::string const & handle, std::vector 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.lenExpression.empty() ); arguments += "m_" + startLowerCase( stripPrefix( param.type.type, "Vk" ) ); } else { std::string argument = param.name; if ( param.type.type.starts_with( "Vk" ) ) { if ( !param.arraySizes.empty() ) { assert( param.arraySizes.size() == 1 ); assert( param.type.isValue() ); assert( param.type.postfix.empty() ); argument = "reinterpret_cast<" + param.type.compose( "" ) + " *>( " + argument + " )"; } else if ( param.type.isValue() ) { argument = "static_cast<" + param.type.type + ">( " + argument + " )"; } else { assert( !param.type.postfix.empty() ); argument = "reinterpret_cast<" + param.type.compose( "" ) + ">( " + argument + " )"; } } arguments += argument; } encounteredArgument = true; } return arguments; } std::string VulkanHppGenerator::generateCallArgumentEnhanced( std::vector const & params, size_t paramIndex, bool nonConstPointerAsNullptr, std::set const & singularParams, std::set const & templatedParams ) const { std::string argument; ParamData const & param = params[paramIndex]; if ( param.type.isConstPointer() || specialPointerTypes.contains( param.type.type ) ) { // parameter is a const-pointer or one of the special pointer types that are considered to be const-pointers argument = generateCallArgumentEnhancedConstPointer( param, paramIndex, singularParams, templatedParams ); } else if ( param.type.isNonConstPointer() && !specialPointerTypes.contains( param.type.type ) ) { // parameter is a non-const pointer and none of the special pointer types, that are considered const-pointers argument = generateCallArgumentEnhancedNonConstPointer( param, paramIndex, nonConstPointerAsNullptr, singularParams ); } else { argument = generateCallArgumentEnhancedValue( params, paramIndex, singularParams ); } assert( !argument.empty() ); return argument; } std::string VulkanHppGenerator::generateCallArgumentEnhancedConstPointer( ParamData const & param, size_t paramIndex, std::set const & singularParams, std::set const & templatedParams ) 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.lenExpression.empty() ); argument = "m_" + startLowerCase( stripPrefix( param.type.type, "Vk" ) ); } else if ( param.lenExpression.empty() ) { // this const-pointer parameter has no length, that is it's a const-pointer to a single value if ( param.type.type == "void" ) { argument = templatedParams.contains( paramIndex ) ? "reinterpret_cast<" + param.type.compose( "VULKAN_HPP_NAMESPACE" ) + ">( &" + name + " )" : param.name; } else if ( param.optional ) { argument = "static_cast<" + param.type.compose( "VULKAN_HPP_NAMESPACE" ) + ">( " + name + " )"; } else { argument = "&" + name; } if ( param.type.type.starts_with( "Vk" ) ) { argument = "reinterpret_cast<" + param.type.compose( "" ) + ">( " + argument + " )"; } } else if ( param.lenExpression == "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.contains( paramIndex ) ) { 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 ( param.type.type.starts_with( "Vk" ) || ( param.type.type == "void" ) ) { argument = "reinterpret_cast<" + param.type.compose( "" ) + ">( " + argument + " )"; } } return argument; } std::string VulkanHppGenerator::generateCallArgumentEnhancedNonConstPointer( ParamData const & param, size_t paramIndex, bool nonConstPointerAsNullptr, std::set const & singularParams ) const { std::string argument; std::string name = startLowerCase( stripPrefix( param.name, "p" ) ); if ( param.lenExpression.empty() ) { assert( param.arraySizes.empty() ); if ( param.type.type.starts_with( "Vk" ) ) { argument = "reinterpret_cast<" + param.type.compose( "" ) + ">( &" + name + " )"; } else { assert( !param.optional ); argument = "&" + name; } } else { // the non-const pointer has a lenExpression -> it will be represented by some array assert( param.arraySizes.empty() ); if ( nonConstPointerAsNullptr ) { argument = "nullptr"; } else { if ( singularParams.contains( paramIndex ) ) { 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 ( param.type.type.starts_with( "Vk" ) || ( param.type.type == "void" ) ) { argument = "reinterpret_cast<" + param.type.compose( "" ) + ">( " + argument + " )"; } } } return argument; } std::string VulkanHppGenerator::generateCallArgumentEnhancedValue( std::vector const & params, size_t paramIndex, std::set const & singularParams ) const { std::string argument; ParamData const & param = params[paramIndex]; assert( param.lenExpression.empty() ); if ( param.type.type.starts_with( "Vk" ) ) { if ( param.arraySizes.empty() ) { // check if this param is used as the len of an other param auto pointerIt = std::find_if( params.begin(), params.end(), [¶m]( ParamData const & pd ) { return pd.lenExpression == param.name; } ); if ( pointerIt != params.end() ) { assert( !param.optional ); argument = startLowerCase( stripPrefix( pointerIt->name, "p" ) ) + ".size()"; if ( pointerIt->type.type == "void" ) { argument += " * sizeof( " + stripPrefix( pointerIt->name, "p" ) + "Type )"; } } else { argument = "static_cast<" + param.type.compose( "" ) + ">( " + param.name + " )"; } // check if this param is used as the stride of an other param assert( std::none_of( params.begin(), params.end(), [paramIndex]( ParamData const & pd ) { return pd.strideParam.second == paramIndex; } ) ); } else { assert( !param.optional ); assert( param.arraySizes.size() == 1 ); assert( param.type.prefix == "const" ); argument = "reinterpret_cast<" + param.type.compose( "" ) + " *>( " + param.name + " )"; } } else { auto pointerIt = std::find_if( params.begin(), params.end(), [¶m]( ParamData const & pd ) { return pd.lenExpression == 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.contains( paramIndex ) ) { if ( pointerIt->type.type == "void" ) { argument = "sizeof( " + stripPrefix( pointerIt->name, "p" ) + "Type )"; } else { argument = "1"; } } else { argument = startLowerCase( stripPrefix( pointerIt->name, "p" ) ) + ".size()"; if ( pointerIt->type.type == "void" ) { argument += " * sizeof( " + stripPrefix( pointerIt->name, "p" ) + "Type )"; } } } else { assert( !param.optional ); assert( param.arraySizes.size() <= 1 ); pointerIt = std::find_if( params.begin(), params.end(), [paramIndex]( ParamData const & pd ) { return pd.strideParam.second == paramIndex; } ); if ( pointerIt != params.end() ) { // this parameter is the stride of some other -> replace it with that parameter's stride assert( param.arraySizes.empty() ); assert( param.type.type == "uint32_t" ); assert( pointerIt->strideParam.first == param.name ); argument = startLowerCase( stripPrefix( pointerIt->name, "p" ) ) + ".stride()"; } else { argument = param.name; } } } return argument; } std::string VulkanHppGenerator::generateCallSequence( std::string const & name, CommandData const & commandData, std::vector const & returnParams, std::map const & vectorParams, size_t initialSkipCount, std::set const & singularParams, std::set const & templatedParams, std::vector const & chainedReturnParams, CommandFlavourFlags flavourFlags, bool raii ) const { std::string dispatcher = raii ? "getDispatcher()->" : "d."; // if at least one returnParam is a size value of a vector param (and no singular params), we need two calls if ( singularParams.empty() && std::any_of( returnParams.begin(), returnParams.end(), [&vectorParams]( size_t rp ) { return std::any_of( vectorParams.begin(), vectorParams.end(), [rp]( auto const & vp ) { return vp.second.lenParam == rp; } ); } ) ) { auto vectorParamIt = vectorParams.begin(); assert( std::any_of( returnParams.begin(), returnParams.end(), [&vectorParamIt]( size_t rp ) { return rp == vectorParamIt->first; } ) ); assert( std::any_of( returnParams.begin(), returnParams.end(), [&vectorParamIt]( size_t rp ) { return rp == vectorParamIt->second.lenParam; } ) ); std::string firstCallArguments = generateCallArgumentsEnhanced( commandData, initialSkipCount, true, {}, templatedParams, raii ); std::string secondCallArguments = generateCallArgumentsEnhanced( commandData, initialSkipCount, false, {}, templatedParams, raii ); std::string vectorName = startLowerCase( stripPrefix( commandData.params[vectorParamIt->first].name, "p" ) ); std::string vectorSize = startLowerCase( stripPrefix( commandData.params[vectorParamIt->second.lenParam].name, "p" ) ); if ( ( flavourFlags & CommandFlavourFlagBits::chained ) && needsStructureChainResize( vectorParams, chainedReturnParams ) ) { assert( vectorParams.size() == 1 ); // chained data needs some more handling!! std::string vectorElementType = stripPostfix( commandData.params[vectorParamIt->first].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" ); if ( commandData.returnType == "VkResult" ) { const std::string callSequenceTemplate = R"(VkResult result; do { result = ${dispatcher}${vkCommand}( ${firstCallArguments} ); if ( ( result == VK_SUCCESS ) && ${counterName} ) { structureChains.resize( ${counterName} ); ${vectorName}.resize( ${counterName} ); for ( ${counterType} i = 0; i < ${counterName}; i++ ) { ${vectorName}[i].pNext = structureChains[i].template get<${vectorElementType}>().pNext; } result = ${dispatcher}${vkCommand}( ${secondCallArguments} ); } } while ( result == VK_INCOMPLETE );)"; return replaceWithMap( callSequenceTemplate, { { "counterName", startLowerCase( stripPrefix( commandData.params[vectorParamIt->second.lenParam].name, "p" ) ) }, { "counterType", commandData.params[vectorParamIt->second.lenParam].type.type }, { "dispatcher", dispatcher }, { "firstCallArguments", firstCallArguments }, { "secondCallArguments", secondCallArguments }, { "vectorElementType", vectorElementType }, { "vectorName", vectorName }, { "vkCommand", name } } ); } else { const std::string callSequenceTemplate = R"(${dispatcher}${vkCommand}( ${firstCallArguments} ); structureChains.resize( ${counterName} ); ${vectorName}.resize( ${counterName} ); for ( ${counterType} i = 0; i < ${counterName}; i++ ) { ${vectorName}[i].pNext = structureChains[i].template get<${vectorElementType}>().pNext; } ${dispatcher}${vkCommand}( ${secondCallArguments} );)"; return replaceWithMap( callSequenceTemplate, { { "counterName", startLowerCase( stripPrefix( commandData.params[vectorParamIt->second.lenParam].name, "p" ) ) }, { "counterType", commandData.params[vectorParamIt->second.lenParam].type.type }, { "dispatcher", dispatcher }, { "firstCallArguments", firstCallArguments }, { "secondCallArguments", secondCallArguments }, { "vectorElementType", vectorElementType }, { "vectorName", vectorName }, { "vkCommand", name } } ); } } else if ( commandData.returnType == "VkResult" ) { std::string resizes; for ( auto const & vp : vectorParams ) { assert( std::any_of( returnParams.begin(), returnParams.end(), [&vp]( size_t rp ) { return rp == vp.first; } ) && std::any_of( returnParams.begin(), returnParams.end(), [&vp]( size_t rp ) { return rp == vp.second.lenParam; } ) ); resizes += startLowerCase( stripPrefix( commandData.params[vp.first].name, "p" ) ) + ".resize( " + startLowerCase( stripPrefix( commandData.params[vp.second.lenParam].name, "p" ) ) + " );\n"; } resizes.pop_back(); switch ( commandData.successCodes.size() ) { case 1: { assert( commandData.successCodes[0] == "VK_SUCCESS" ); std::string const callSequenceTemplate = R"(${dispatcher}${vkCommand}( ${firstCallArguments} ); ${resizes} ${dispatcher}${vkCommand}( ${secondCallArguments} ); )"; return replaceWithMap( callSequenceTemplate, { { "dispatcher", dispatcher }, { "firstCallArguments", firstCallArguments }, { "secondCallArguments", secondCallArguments }, { "resizes", resizes }, { "vkCommand", name } } ); } case 2: { assert( ( commandData.successCodes[0] == "VK_SUCCESS" ) && ( commandData.successCodes[1] == "VK_INCOMPLETE" ) ); std::string const callSequenceTemplate = R"(VkResult result; do { result = ${dispatcher}${vkCommand}( ${firstCallArguments} ); if ( ( result == VK_SUCCESS ) && ${counterName} ) { ${resizes} result = ${dispatcher}${vkCommand}( ${secondCallArguments} ); } } while ( result == VK_INCOMPLETE );)"; return replaceWithMap( callSequenceTemplate, { { "counterName", startLowerCase( stripPrefix( commandData.params[vectorParamIt->second.lenParam].name, "p" ) ) }, { "dispatcher", dispatcher }, { "firstCallArguments", firstCallArguments }, { "secondCallArguments", secondCallArguments }, { "resizes", resizes }, { "vkCommand", name } } ); } default: assert( false ); return ""; } } else { // no need to enumerate here, just two calls assert( commandData.returnType == "void" ); std::string const callSequenceTemplate = R"(${dispatcher}${vkCommand}( ${firstCallArguments} ); ${vectorName}.resize( ${vectorSize} ); ${dispatcher}${vkCommand}( ${secondCallArguments} );)"; return replaceWithMap( callSequenceTemplate, { { "dispatcher", dispatcher }, { "firstCallArguments", firstCallArguments }, { "secondCallArguments", secondCallArguments }, { "vectorName", vectorName }, { "vectorSize", vectorSize }, { "vkCommand", name } } ); } } else { std::string const callSequenceTemplate = R"(${resultAssignment}${dispatcher}${vkCommand}( ${callArguments} );)"; std::string callArguments = generateCallArgumentsEnhanced( commandData, initialSkipCount, false, singularParams, templatedParams, raii ); std::string resultAssignment = generateResultAssignment( commandData ); return replaceWithMap( callSequenceTemplate, { { "callArguments", callArguments }, { "dispatcher", dispatcher }, { "resultAssignment", resultAssignment }, { "vkCommand", name } } ); } } std::string VulkanHppGenerator::generateCommand( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, bool raii ) const { std::string cmd; if ( commandData.returnType == "VkResult" ) { cmd = generateCommandResult( name, commandData, initialSkipCount, definition, raii ); } else if ( commandData.returnType == "void" ) { cmd = generateCommandVoid( name, commandData, initialSkipCount, definition, raii ); } else { cmd = generateCommandValue( name, commandData, initialSkipCount, definition, raii ); } if ( cmd.empty() ) { throw std::runtime_error( "Never encountered a function like <" + name + "> !" ); } return cmd; } std::string VulkanHppGenerator::generateCommandDefinitions() const { const std::string commandDefinitionsTemplate = R"( //=========================== //=== COMMAND Definitions === //=========================== ${commandDefinitions} )"; std::string commandDefinitions; std::set listedCommands; // some commands are listed with more than one extension! for ( auto const & feature : m_features ) { commandDefinitions += generateCommandDefinitions( feature.requireData, listedCommands, feature.name ); } for ( auto const & extension : m_extensions ) { commandDefinitions += generateCommandDefinitions( extension.requireData, listedCommands, extension.name ); } return replaceWithMap( commandDefinitionsTemplate, { { "commandDefinitions", commandDefinitions } } ); } std::string VulkanHppGenerator::generateCommandDefinitions( std::vector const & requireData, std::set & 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 += generateCommandDefinitions( command, getCommandData( command ).handle ); } } } return addTitleAndProtection( title, str ); } std::string VulkanHppGenerator::generateCommandDefinitions( std::string const & command, std::string const & handle ) const { auto const & commandData = getCommandData( command ); std::string str = "\n" + generateCommand( command, commandData, handle.empty() ? 0 : 1, true, false ); // special handling for destroy functions, filter out alias functions std::string commandName = generateCommandName( command, commandData.params, 1 ); if ( !m_commandAliases.contains( command ) && ( ( ( command.substr( 2, 7 ) == "Destroy" ) && ( commandName != "destroy" ) ) || ( command.substr( 2, 4 ) == "Free" ) || ( command == "vkReleasePerformanceConfigurationINTEL" ) ) ) { CommandData specialCommandData = commandData; assert( ( 1 < specialCommandData.params.size() ) && ( specialCommandData.params[0].type.type == handle ) ); specialCommandData.params[1].optional = false; // make sure, the object to destroy/free/release is not optional in the shortened version! std::string destroyCommandString = generateCommand( command, specialCommandData, handle.empty() ? 0 : 1, true, false ); std::string shortenedName; if ( command.substr( 2, 7 ) == "Destroy" ) { shortenedName = "destroy"; } else if ( command.substr( 2, 4 ) == "Free" ) { shortenedName = "free"; } else { assert( command == "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 ); } // special handling for "free", to prevent interfering with MSVC debug free! if ( shortenedName == "free" ) { std::string toEncloseString = stripPrefix( handle, "Vk" ) + "::free"; std::string enclosedString = "( " + toEncloseString + " )"; pos = destroyCommandString.find( toEncloseString ); while ( pos != std::string::npos ) { destroyCommandString.replace( pos, toEncloseString.length(), enclosedString ); pos = destroyCommandString.find( toEncloseString, pos + enclosedString.length() ); } } // we need to remove the default argument for the first argument, to prevent ambiguities! assert( 1 < commandData.params.size() ); pos = destroyCommandString.find( commandData.params[1].name ); // skip the standard version of the function assert( pos != std::string::npos ); pos = destroyCommandString.find( commandData.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::generateCommandEnhanced( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, std::map const & vectorParams, std::vector const & returnParams, CommandFlavourFlags flavourFlags ) const { bool chained = flavourFlags & CommandFlavourFlagBits::chained; bool singular = flavourFlags & CommandFlavourFlagBits::singular; assert( vectorParams.empty() || ( vectorParams.begin()->second.lenParam != INVALID_INDEX ) ); assert( !singular || !returnParams.empty() ); // if singular is true, then there is at least one returnParam ! std::set skippedParams = determineSkippedParams( commandData.params, initialSkipCount, vectorParams, returnParams, singular ); // special handling for vkGetMemoryHostPointerPropertiesEXT: here, we really need to stick with the const void * parameter ! std::set templatedParams = ( name == "vkGetMemoryHostPointerPropertiesEXT" ) ? std::set() : determineVoidPointerParams( commandData.params ); std::vector chainedReturnParams; if ( chained ) { chainedReturnParams = determineChainedReturnParams( commandData.params, returnParams ); assert( chainedReturnParams.size() == 1 ); } std::set singularParams = singular ? determineSingularParams( returnParams[0], vectorParams ) : std::set(); std::pair>> vectorSizeCheck = needsVectorSizeCheck( commandData.params, vectorParams, returnParams, singularParams, skippedParams ); bool enumerating = determineEnumeration( vectorParams, returnParams ); std::vector dataTypes = determineDataTypes( commandData.params, vectorParams, returnParams, templatedParams ); std::string dataType = combineDataTypes( vectorParams, returnParams, enumerating, dataTypes, flavourFlags, false ); std::string argumentTemplates = generateArgumentTemplates( commandData.params, returnParams, vectorParams, templatedParams, chainedReturnParams, false ); auto [allocatorTemplates, uniqueHandleAllocatorTemplates] = generateAllocatorTemplates( returnParams, dataTypes, vectorParams, chainedReturnParams, flavourFlags, definition ); std::string typenameCheck = generateTypenameCheck( returnParams, vectorParams, chainedReturnParams, definition, dataTypes, flavourFlags ); std::string nodiscard = generateNoDiscard( !returnParams.empty(), 1 < commandData.successCodes.size(), 1 < commandData.errorCodes.size() ); std::string returnType = generateReturnType( commandData, returnParams, vectorParams, flavourFlags, false, dataTypes ); std::string className = initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : ""; std::string classSeparator = commandData.handle.empty() ? "" : "::"; std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, flavourFlags ); std::string argumentList = generateArgumentListEnhanced( commandData.params, returnParams, vectorParams, skippedParams, singularParams, templatedParams, chainedReturnParams, definition, flavourFlags, true ); std::string constString = commandData.handle.empty() ? "" : " const"; std::string noexceptString = generateNoExcept( commandData.errorCodes, returnParams, vectorParams, flavourFlags, vectorSizeCheck.first, false ); if ( definition ) { std::string vectorSizeCheckString = vectorSizeCheck.first ? generateVectorSizeCheck( name, commandData, initialSkipCount, vectorSizeCheck.second, skippedParams, false ) : ""; std::string returnVariable = generateReturnVariable( commandData, returnParams, vectorParams, flavourFlags ); std::string dataDeclarations = generateDataDeclarations( commandData, returnParams, vectorParams, templatedParams, flavourFlags, false, dataTypes, dataType, returnType, returnVariable ); std::string dataPreparation = generateDataPreparation( commandData, initialSkipCount, returnParams, vectorParams, templatedParams, flavourFlags, enumerating ); std::string dataSizeChecks = generateDataSizeChecks( commandData, returnParams, dataTypes, vectorParams, templatedParams, singular ); std::string callSequence = generateCallSequence( name, commandData, returnParams, vectorParams, initialSkipCount, singularParams, templatedParams, chainedReturnParams, flavourFlags, false ); std::string resultCheck = generateResultCheck( commandData, className, classSeparator, commandName, enumerating ); std::string returnStatement = generateReturnStatement( name, commandData, returnVariable, returnType, dataType, initialSkipCount, returnParams.empty() ? INVALID_INDEX : returnParams[0], flavourFlags, enumerating, false ); std::string const functionTemplate = R"( template <${argumentTemplates}${allocatorTemplates}typename Dispatch${uniqueHandleAllocatorTemplates}${typenameCheck}> ${nodiscard}VULKAN_HPP_INLINE ${returnType} ${className}${classSeparator}${commandName}( ${argumentList} )${const}${noexcept} { VULKAN_HPP_ASSERT( d.getVkHeaderVersion() == VK_HEADER_VERSION ); ${vectorSizeCheck} ${dataSizeChecks} ${dataDeclarations} ${callSequence} ${resultCheck} ${dataPreparation} ${returnStatement} })"; return replaceWithMap( functionTemplate, { { "allocatorTemplates", allocatorTemplates }, { "argumentList", argumentList }, { "argumentTemplates", argumentTemplates }, { "callSequence", callSequence }, { "className", className }, { "classSeparator", classSeparator }, { "commandName", commandName }, { "const", constString }, { "dataDeclarations", dataDeclarations }, { "dataPreparation", dataPreparation }, { "dataSizeChecks", dataSizeChecks }, { "nodiscard", nodiscard }, { "noexcept", noexceptString }, { "resultCheck", resultCheck }, { "returnStatement", returnStatement }, { "returnType", returnType }, { "typenameCheck", typenameCheck }, { "uniqueHandleAllocatorTemplates", uniqueHandleAllocatorTemplates }, { "vectorSizeCheck", vectorSizeCheckString } } ); } else { std::string const functionTemplate = R"( template <${argumentTemplates}${allocatorTemplates}typename Dispatch = VULKAN_HPP_DEFAULT_DISPATCHER_TYPE${uniqueHandleAllocatorTemplates}${typenameCheck}> ${nodiscard}${returnType} ${commandName}( ${argumentList} )${const}${noexcept};)"; return replaceWithMap( functionTemplate, { { "allocatorTemplates", allocatorTemplates }, { "argumentList", argumentList }, { "argumentTemplates", argumentTemplates }, { "commandName", commandName }, { "const", commandData.handle.empty() ? "" : " const" }, { "nodiscard", nodiscard }, { "noexcept", noexceptString }, { "returnType", returnType }, { "typenameCheck", typenameCheck }, { "uniqueHandleAllocatorTemplates", uniqueHandleAllocatorTemplates } } ); } } std::string VulkanHppGenerator::generateCommandName( std::string const & vulkanCommandName, std::vector const & params, size_t initialSkipCount, CommandFlavourFlags flavourFlags ) 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( argumentType ); if ( !argumentTag.empty() ) { searchName = stripPostfix( searchName, argumentTag ); } size_t pos = commandName.find( searchName ); if ( pos == std::string::npos ) { searchName = startLowerCase( searchName ); pos = commandName.find( searchName ); } if ( pos != std::string::npos ) { size_t len = searchName.length(); if ( commandName.find( searchName + "s" ) == pos ) { // filter out any plural of the searchName as well! ++len; } commandName.erase( pos, len ); } else if ( ( searchName == "commandBuffer" ) && commandName.starts_with( "cmd" ) ) { commandName.erase( 0, 3 ); pos = 0; } if ( pos == 0 ) { commandName = startLowerCase( commandName ); } std::string commandTag = findTag( commandName ); if ( !argumentTag.empty() && ( argumentTag == commandTag ) ) { commandName = stripPostfix( commandName, argumentTag ); } } if ( flavourFlags & CommandFlavourFlagBits::singular ) { commandName = stripPluralS( commandName ); } if ( flavourFlags & CommandFlavourFlagBits::unique ) { commandName += "Unique"; } return commandName; } std::string VulkanHppGenerator::generateCommandResult( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, bool raii ) const { assert( !commandData.successCodes.empty() ); if ( commandData.successCodes.size() == 1 ) { return generateCommandResultSingleSuccess( name, commandData, initialSkipCount, definition, raii ); } else if ( commandData.errorCodes.empty() ) { return generateCommandResultMultiSuccessNoErrors( name, commandData, initialSkipCount, definition, raii ); } else { return generateCommandResultMultiSuccessWithErrors( name, commandData, initialSkipCount, definition, raii ); } } std::string VulkanHppGenerator::generateCommandResultMultiSuccessNoErrors( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, bool raii ) const { std::vector returnParams = determineReturnParams( commandData.params ); switch ( returnParams.size() ) { case 0: { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.empty() ) { std::vector constPointerParams = determineConstPointerParams( commandData.params ); if ( constPointerParams.empty() ) { return generateCommandSetExclusive( name, commandData, initialSkipCount, definition, raii ); } } } break; case 2: if ( ( commandData.successCodes.size() == 2 ) && ( commandData.successCodes[0] == "VK_SUCCESS" ) && ( commandData.successCodes[1] == "VK_INCOMPLETE" ) ) { if ( ( commandData.params[returnParams[0]].type.type == "size_t" ) || ( commandData.params[returnParams[0]].type.type == "uint32_t" ) ) { if ( ( commandData.params[returnParams[1]].type.type != "void" ) && !isHandleType( commandData.params[returnParams[1]].type.type ) && !isStructureChainAnchor( commandData.params[returnParams[1]].type.type ) ) { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.size() == 1 ) { if ( returnParams[0] == vectorParams.begin()->second.lenParam ) { if ( returnParams[1] == vectorParams.begin()->first ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, returnParams, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator }, raii, false, { CommandFlavourFlagBits::enhanced } ); } } } } } } break; } return ""; } std::string VulkanHppGenerator::generateCommandResultMultiSuccessWithErrors( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, bool raii ) const { std::vector returnParams = determineReturnParams( commandData.params ); switch ( returnParams.size() ) { case 0: return generateCommandResultWithErrors0Return( name, commandData, initialSkipCount, definition, raii ); case 1: return generateCommandResultMultiSuccessWithErrors1Return( name, commandData, initialSkipCount, definition, returnParams[0], raii ); case 2: return generateCommandResultMultiSuccessWithErrors2Return( name, commandData, initialSkipCount, definition, returnParams, raii ); case 3: return generateCommandResultMultiSuccessWithErrors3Return( name, commandData, initialSkipCount, definition, returnParams, raii ); } return ""; } std::string VulkanHppGenerator::generateCommandResultMultiSuccessWithErrors1Return( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, size_t returnParam, bool raii ) const { if ( commandData.params[returnParam].type.type == "void" ) { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.size() == 1 ) { if ( returnParam == vectorParams.begin()->first ) { if ( commandData.params[vectorParams.begin()->second.lenParam].type.isValue() ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::singular }, raii, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::singular } ); } } } } else if ( isHandleType( commandData.params[returnParam].type.type ) ) { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.size() == 2 ) { if ( returnParam == std::next( vectorParams.begin() )->first ) { if ( vectorParams.begin()->second.lenParam == std::next( vectorParams.begin() )->second.lenParam ) { if ( commandData.params[vectorParams.begin()->second.lenParam].type.type == "uint32_t" ) { if ( isStructureChainAnchor( commandData.params[vectorParams.begin()->first].type.type ) ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, true, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator, CommandFlavourFlagBits::singular }, raii, true, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::singular } ); } } } } } } else if ( isStructureChainAnchor( commandData.params[returnParam].type.type ) ) { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.empty() ) { #if 0 // needs to be verified ... return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::chained }, raii, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::chained } ); #endif return ""; } } else { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.empty() ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced }, raii, false, { CommandFlavourFlagBits::enhanced } ); } } return ""; } std::string VulkanHppGenerator::generateCommandResultMultiSuccessWithErrors2Return( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, std::vector const & returnParams, bool raii ) const { if ( ( commandData.successCodes.size() == 2 ) && ( commandData.successCodes[0] == "VK_SUCCESS" ) && ( commandData.successCodes[1] == "VK_INCOMPLETE" ) ) { if ( ( commandData.params[returnParams[0]].type.type == "size_t" ) || ( commandData.params[returnParams[0]].type.type == "uint32_t" ) ) { // needs some very special handling of "vkGetSwapchainImagesKHR" !! if ( isHandleType( commandData.params[returnParams[1]].type.type ) && ( name != "vkGetSwapchainImagesKHR" ) ) { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.size() == 1 ) { if ( returnParams[0] == vectorParams.begin()->second.lenParam ) { if ( returnParams[1] == vectorParams.begin()->first ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, returnParams, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator }, raii, true, { CommandFlavourFlagBits::enhanced } ); } } } } else if ( isStructureChainAnchor( commandData.params[returnParams[1]].type.type ) ) { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.size() == 1 ) { if ( returnParams[0] == vectorParams.begin()->second.lenParam ) { if ( returnParams[1] == vectorParams.begin()->first ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, returnParams, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator, CommandFlavourFlagBits::chained, CommandFlavourFlagBits::chained | CommandFlavourFlagBits::withAllocator }, raii, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::chained } ); } } } } else { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.size() == 1 ) { if ( returnParams[0] == vectorParams.begin()->second.lenParam ) { if ( returnParams[1] == vectorParams.begin()->first ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, returnParams, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator }, raii, false, { CommandFlavourFlagBits::enhanced } ); } } } } } else if ( ( commandData.params[returnParams[0]].type.type != "void" ) && !isHandleType( commandData.params[returnParams[0]].type.type ) && !isStructureChainAnchor( commandData.params[returnParams[0]].type.type ) ) { if ( ( commandData.params[returnParams[1]].type.type != "void" ) && !isHandleType( commandData.params[returnParams[1]].type.type ) && !isStructureChainAnchor( commandData.params[returnParams[1]].type.type ) ) { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.empty() ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, returnParams, vectorParams, false, { CommandFlavourFlagBits::enhanced }, raii, false, { CommandFlavourFlagBits::enhanced } ); } } } } return ""; } std::string VulkanHppGenerator::generateCommandResultMultiSuccessWithErrors3Return( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, std::vector const & returnParams, bool raii ) const { std::map vectorParams = determineVectorParams( commandData.params ); switch ( vectorParams.size() ) { case 1: if ( ( commandData.params[returnParams[0]].type.type != "void" ) && !isHandleType( commandData.params[returnParams[0]].type.type ) ) { if ( ( commandData.params[returnParams[1]].type.type == "size_t" ) || ( commandData.params[returnParams[1]].type.type == "uint32_t" ) ) { if ( ( commandData.params[returnParams[2]].type.type == "void" ) || ( !isHandleType( commandData.params[returnParams[2]].type.type ) && !isStructureChainAnchor( commandData.params[returnParams[2]].type.type ) ) ) { if ( returnParams[1] == vectorParams.begin()->second.lenParam ) { if ( returnParams[2] == vectorParams.begin()->first ) { std::vector flags = { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator }; std::vector raiiFlags = { CommandFlavourFlagBits::enhanced }; if ( isStructureChainAnchor( commandData.params[returnParams[0]].type.type ) ) { flags.push_back( CommandFlavourFlagBits::chained ); flags.push_back( CommandFlavourFlagBits::chained | CommandFlavourFlagBits::withAllocator ); raiiFlags.push_back( CommandFlavourFlagBits::chained ); } return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, returnParams, vectorParams, false, flags, raii, false, raiiFlags ); } } } } } break; case 2: if ( commandData.params[returnParams[0]].type.type == "uint32_t" ) { if ( ( commandData.params[returnParams[1]].type.type != "void" ) && !isHandleType( commandData.params[returnParams[1]].type.type ) && !isStructureChainAnchor( commandData.params[returnParams[1]].type.type ) ) { if ( ( commandData.params[returnParams[2]].type.type != "void" ) && !isHandleType( commandData.params[returnParams[2]].type.type ) && !isStructureChainAnchor( commandData.params[returnParams[2]].type.type ) ) { if ( vectorParams.begin()->second.lenParam == std::next( vectorParams.begin() )->second.lenParam ) { if ( returnParams[0] == vectorParams.begin()->second.lenParam ) { if ( returnParams[1] == vectorParams.begin()->first ) { if ( returnParams[2] == std::next( vectorParams.begin() )->first ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, returnParams, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator }, raii, false, { CommandFlavourFlagBits::enhanced } ); } } } } } } } break; default: assert( false ); break; } return ""; } std::string VulkanHppGenerator::generateCommandResultSingleSuccess( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, bool raii ) const { if ( commandData.errorCodes.empty() ) { return generateCommandResultSingleSuccessNoErrors( name, commandData, initialSkipCount, definition, raii ); } else { return generateCommandResultSingleSuccessWithErrors( name, commandData, initialSkipCount, definition, raii ); } } std::string VulkanHppGenerator::generateCommandResultSingleSuccessNoErrors( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, bool raii ) const { std::vector returnParams = determineReturnParams( commandData.params ); switch ( returnParams.size() ) { case 0: { std::map vectorParams = determineVectorParams( commandData.params ); switch ( vectorParams.size() ) { case 0: if ( determineConstPointerParams( commandData.params ).empty() ) { return generateCommandSetExclusive( name, commandData, initialSkipCount, definition, raii ); } else { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, returnParams, vectorParams, false, { CommandFlavourFlagBits::enhanced }, raii, false, { CommandFlavourFlagBits::enhanced } ); } break; case 1: if ( !raii ) { if ( commandData.params[vectorParams.begin()->second.lenParam].type.isValue() ) { if ( isHandleType( commandData.params[vectorParams.begin()->first].type.type ) ) { return generateCommandSet( definition, generateCommandStandard( name, commandData, initialSkipCount, definition ), { generateCommandEnhanced( name, commandData, initialSkipCount, definition, vectorParams, {} ) } ); } } } break; } } break; case 1: { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.empty() ) { if ( ( commandData.params[returnParams[0]].type.type != "void" ) && !isHandleType( commandData.params[returnParams[0]].type.type ) && !isStructureChainAnchor( commandData.params[returnParams[0]].type.type ) ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, returnParams, vectorParams, false, { CommandFlavourFlagBits::enhanced }, raii, false, { CommandFlavourFlagBits::enhanced } ); } } } break; case 2: if ( ( commandData.params[returnParams[0]].type.type == "size_t" ) || ( commandData.params[returnParams[0]].type.type == "uint32_t" ) ) { if ( ( commandData.params[returnParams[1]].type.type != "void" ) && !isHandleType( commandData.params[returnParams[1]].type.type ) && !isStructureChainAnchor( commandData.params[returnParams[1]].type.type ) ) { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.size() == 1 ) { if ( returnParams[0] == vectorParams.begin()->second.lenParam ) { if ( returnParams[1] == vectorParams.begin()->first ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, returnParams, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator }, raii, false, { CommandFlavourFlagBits::enhanced } ); } } } } } break; } return ""; } std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, bool raii ) const { std::vector returnParams = determineReturnParams( commandData.params ); switch ( returnParams.size() ) { case 0: return generateCommandResultWithErrors0Return( name, commandData, initialSkipCount, definition, raii ); case 1: return generateCommandResultSingleSuccessWithErrors1Return( name, commandData, initialSkipCount, definition, returnParams[0], raii ); case 2: return generateCommandResultSingleSuccessWithErrors2Return( name, commandData, initialSkipCount, definition, returnParams, raii ); } return ""; } std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors1Return( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, size_t returnParam, bool raii ) const { if ( commandData.params[returnParam].type.type == "void" ) { return generateCommandResultSingleSuccessWithErrors1ReturnVoid( name, commandData, initialSkipCount, definition, returnParam, raii ); } else if ( isHandleType( commandData.params[returnParam].type.type ) ) { return generateCommandResultSingleSuccessWithErrors1ReturnHandle( name, commandData, initialSkipCount, definition, returnParam, raii ); } else if ( isStructureChainAnchor( commandData.params[returnParam].type.type ) ) { return generateCommandResultSingleSuccessWithErrors1ReturnChain( name, commandData, initialSkipCount, definition, returnParam, raii ); } else { return generateCommandResultSingleSuccessWithErrors1ReturnValue( name, commandData, initialSkipCount, definition, returnParam, raii ); } } std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors1ReturnChain( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, size_t returnParam, bool raii ) const { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.empty() ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::chained }, raii, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::chained } ); } return ""; } std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors1ReturnHandle( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, size_t returnParam, bool raii ) const { std::map vectorParams = determineVectorParams( commandData.params ); switch ( vectorParams.size() ) { case 0: return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, true, { CommandFlavourFlagBits::enhanced }, raii, true, { CommandFlavourFlagBits::enhanced } ); case 1: if ( returnParam == vectorParams.begin()->first ) { if ( isLenByStructMember( commandData.params[vectorParams.begin()->first].lenExpression, commandData.params[vectorParams.begin()->second.lenParam] ) ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, true, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator }, raii, true, { CommandFlavourFlagBits::enhanced } ); } } break; case 2: if ( returnParam == std::next( vectorParams.begin() )->first ) { if ( vectorParams.begin()->second.lenParam == std::next( vectorParams.begin() )->second.lenParam ) { if ( commandData.params[vectorParams.begin()->second.lenParam].type.isValue() ) { if ( ( commandData.params[vectorParams.begin()->first].type.type != "void" ) && !isHandleType( commandData.params[vectorParams.begin()->first].type.type ) ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, true, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator, CommandFlavourFlagBits::singular }, raii, true, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::singular } ); } } } } break; } return ""; } std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors1ReturnValue( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, size_t returnParam, bool raii ) const { std::map vectorParams = determineVectorParams( commandData.params ); switch ( vectorParams.size() ) { case 0: return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced }, raii, false, { CommandFlavourFlagBits::enhanced } ); case 2: if ( returnParam == std::next( vectorParams.begin() )->first ) { if ( vectorParams.begin()->second.lenParam == std::next( vectorParams.begin() )->second.lenParam ) { if ( commandData.params[vectorParams.begin()->second.lenParam].type.type == "uint32_t" ) { if ( ( commandData.params[vectorParams.begin()->first].type.type != "void" ) && !isHandleType( commandData.params[vectorParams.begin()->first].type.type ) && !isStructureChainAnchor( commandData.params[vectorParams.begin()->first].type.type ) ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator, CommandFlavourFlagBits::singular }, raii, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::singular } ); } } } } break; } return ""; } std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors1ReturnVoid( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, size_t returnParam, bool raii ) const { std::map vectorParams = determineVectorParams( commandData.params ); switch ( vectorParams.size() ) { case 0: return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced }, raii, false, { CommandFlavourFlagBits::enhanced } ); case 1: if ( returnParam == vectorParams.begin()->first ) { if ( commandData.params[vectorParams.begin()->second.lenParam].type.isValue() ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::singular }, raii, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::singular } ); } } break; case 2: if ( returnParam == std::next( vectorParams.begin() )->first ) { if ( vectorParams.begin()->second.lenParam != std::next( vectorParams.begin() )->second.lenParam ) { if ( commandData.params[vectorParams.begin()->second.lenParam].type.isValue() ) { if ( isHandleType( commandData.params[vectorParams.begin()->first].type.type ) ) { if ( commandData.params[std::next( vectorParams.begin() )->second.lenParam].type.isValue() ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::singular }, raii, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::singular } ); } } } } } break; } return ""; } std::string VulkanHppGenerator::generateCommandResultSingleSuccessWithErrors2Return( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, std::vector const & returnParams, bool raii ) const { if ( ( commandData.params[returnParams[0]].type.type != "void" ) && !isHandleType( commandData.params[returnParams[0]].type.type ) && !isStructureChainAnchor( commandData.params[returnParams[0]].type.type ) ) { if ( ( commandData.params[returnParams[1]].type.type != "void" ) && !isHandleType( commandData.params[returnParams[1]].type.type ) && !isStructureChainAnchor( commandData.params[returnParams[1]].type.type ) ) { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.size() == 2 ) { if ( returnParams[0] == std::next( vectorParams.begin() )->first ) { if ( !vectorParams.contains( returnParams[1] ) ) { assert( ( returnParams[1] != vectorParams.begin()->second.lenParam ) && ( returnParams[1] != std::next( vectorParams.begin() )->second.lenParam ) ); if ( vectorParams.begin()->second.lenParam == std::next( vectorParams.begin() )->second.lenParam ) { if ( commandData.params[vectorParams.begin()->second.lenParam].type.isValue() ) { if ( ( commandData.params[vectorParams.begin()->first].type.type != "void" ) && !isHandleType( commandData.params[vectorParams.begin()->first].type.type ) && !isStructureChainAnchor( commandData.params[vectorParams.begin()->first].type.type ) ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, returnParams, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator, CommandFlavourFlagBits::singular }, raii, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::singular } ); } } } } } } } } return ""; } std::string VulkanHppGenerator::generateCommandResultWithErrors0Return( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, bool raii ) const { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.empty() && determineConstPointerParams( commandData.params ).empty() ) { return generateCommandSetExclusive( name, commandData, initialSkipCount, definition, raii ); } else if ( allVectorSizesSupported( commandData.params, vectorParams ) ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, {}, vectorParams, false, { CommandFlavourFlagBits::enhanced }, raii, false, { CommandFlavourFlagBits::enhanced } ); } return ""; } std::string VulkanHppGenerator::generateCommandSet( bool definition, std::string const & standard, std::vector const & enhanced, std::vector const & unique ) const { assert( unique.empty() || ( enhanced.size() == unique.size() ) ); std::string commandSet = "\n" + standard; if ( !enhanced.empty() ) { std::string separator = definition ? "\n" : ""; commandSet += separator + "\n#ifndef VULKAN_HPP_DISABLE_ENHANCED_MODE\n"; bool firstEnhanced = true; for ( auto const & e : enhanced ) { if ( !firstEnhanced ) { commandSet += separator + "\n"; } firstEnhanced = false; commandSet += e; } if ( !unique.empty() ) { commandSet += separator + "\n# ifndef VULKAN_HPP_NO_SMART_HANDLE\n"; bool firstUnique = true; for ( auto const & u : unique ) { if ( !firstUnique ) { commandSet += separator + "\n"; } firstUnique = false; commandSet += u; } commandSet += "\n# endif /* VULKAN_HPP_NO_SMART_HANDLE */"; } commandSet += "\n#endif /* VULKAN_HPP_DISABLE_ENHANCED_MODE */"; } commandSet += "\n"; return commandSet; } std::string VulkanHppGenerator::generateCommandSet( 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( { { "commandEnhanced", enhanced }, { "commandStandard", standard } } ) ); } std::string VulkanHppGenerator::generateCommandSetExclusive( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, bool raii ) const { if ( raii ) { return generateRAIIHandleCommandEnhanced( name, commandData, initialSkipCount, {}, {}, definition ); } else { return generateCommandSet( generateCommandStandard( name, commandData, initialSkipCount, definition ), generateCommandEnhanced( name, commandData, initialSkipCount, definition, {}, {} ) ); } } std::string VulkanHppGenerator::generateCommandSetInclusive( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, std::vector returnParams, std::map vectorParams, bool unique, std::vector const & flags, bool raii, bool raiiFactory, std::vector const & raiiFlags ) const { if ( raii ) { std::string raiiCommands; for ( auto flag : raiiFlags ) { raiiCommands += raiiFactory ? generateRAIIHandleCommandFactory( name, commandData, initialSkipCount, returnParams, vectorParams, definition, flag ) : generateRAIIHandleCommandEnhanced( name, commandData, initialSkipCount, returnParams, vectorParams, definition, flag ); } return raiiCommands; } else { std::vector enhancedCommands, uniqueCommands; for ( auto flag : flags ) { enhancedCommands.push_back( generateCommandEnhanced( name, commandData, initialSkipCount, definition, vectorParams, returnParams, flag ) ); if ( unique ) { uniqueCommands.push_back( generateCommandEnhanced( name, commandData, initialSkipCount, definition, vectorParams, returnParams, flag | CommandFlavourFlagBits::unique ) ); } } return generateCommandSet( definition, generateCommandStandard( name, commandData, initialSkipCount, definition ), enhancedCommands, uniqueCommands ); } } std::string VulkanHppGenerator::generateCommandStandard( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition ) const { std::set skippedParams = determineSkippedParams( commandData.params, initialSkipCount, {}, {}, false ); std::string argumentList = generateArgumentListStandard( commandData.params, skippedParams ); std::string commandName = generateCommandName( name, commandData.params, initialSkipCount ); 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 ( commandData.returnType.starts_with( "Vk" ) ) { functionBody = "return static_cast<" + returnType + ">( " + functionBody + " )"; } else if ( commandData.returnType != "void" ) { functionBody = "return " + functionBody; } std::string const functionTemplate = R"( template ${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 ${nodiscard}${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::generateCommandVoid( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, bool raii ) const { std::vector returnParams = determineReturnParams( commandData.params ); switch ( returnParams.size() ) { case 0: return generateCommandVoid0Return( name, commandData, initialSkipCount, definition, raii ); case 1: return generateCommandVoid1Return( name, commandData, initialSkipCount, definition, returnParams[0], raii ); case 2: return generateCommandVoid2Return( name, commandData, initialSkipCount, definition, returnParams, raii ); } return ""; } std::string VulkanHppGenerator::generateCommandValue( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, bool raii ) const { std::vector returnParams = determineReturnParams( commandData.params ); if ( returnParams.empty() ) { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.empty() ) { if ( determineConstPointerParams( commandData.params ).empty() ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, {}, vectorParams, false, {}, raii, false, { CommandFlavourFlagBits::enhanced } ); } else { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, {}, vectorParams, false, { CommandFlavourFlagBits::enhanced }, raii, false, { CommandFlavourFlagBits::enhanced } ); } } else if ( vectorParams.size() <= 1 ) { if ( !raii ) { return generateCommandSet( definition, generateCommandStandard( name, commandData, initialSkipCount, definition ), { generateCommandEnhanced( name, commandData, initialSkipCount, definition, vectorParams, returnParams ) } ); } } } return ""; } std::string VulkanHppGenerator::generateCommandVoid0Return( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, bool raii ) const { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.empty() && determineConstPointerParams( commandData.params ).empty() ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, {}, vectorParams, false, {}, raii, false, { CommandFlavourFlagBits::enhanced } ); } else if ( allVectorSizesSupported( commandData.params, vectorParams ) ) { // All the vectorParams have a counter by value, of type "uint32_t", "VkDeviceSize", or "VkSampleCountFlagBits" (!) return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, {}, vectorParams, false, { CommandFlavourFlagBits::enhanced }, raii, false, { CommandFlavourFlagBits::enhanced } ); } return ""; } std::string VulkanHppGenerator::generateCommandVoid1Return( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, size_t returnParam, bool raii ) const { std::map vectorParams = determineVectorParams( commandData.params ); if ( ( commandData.params[returnParam].type.type == "void" ) ) { switch ( vectorParams.size() ) { case 0: return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced }, raii, false, { CommandFlavourFlagBits::enhanced } ); case 1: if ( returnParam == vectorParams.begin()->first ) { if ( name == stripPluralS( name ) ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::singular }, raii, false, { CommandFlavourFlagBits::singular } ); } } break; } } else if ( isHandleType( commandData.params[returnParam].type.type ) ) { if ( vectorParams.empty() ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced }, raii, true, { CommandFlavourFlagBits::enhanced } ); } } else if ( isStructureChainAnchor( commandData.params[returnParam].type.type ) ) { if ( vectorParams.empty() ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::chained }, raii, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::chained } ); } } else { switch ( vectorParams.size() ) { case 0: return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced }, raii, false, { CommandFlavourFlagBits::enhanced } ); case 1: if ( returnParam == vectorParams.begin()->first ) { if ( !raii ) { // you get a vector of stuff, with the size being one of the parameters return generateCommandSet( definition, generateCommandStandard( name, commandData, initialSkipCount, definition ), { generateCommandEnhanced( name, commandData, initialSkipCount, definition, vectorParams, { returnParam } ), generateCommandEnhanced( name, commandData, initialSkipCount, definition, vectorParams, { returnParam }, CommandFlavourFlagBits::withAllocator ) } ); } } else { if ( !isHandleType( commandData.params[vectorParams.begin()->first].type.type ) && !isStructureChainAnchor( commandData.params[vectorParams.begin()->first].type.type ) && ( commandData.params[vectorParams.begin()->first].type.type != "void" ) ) { if ( isLenByStructMember( commandData.params[vectorParams.begin()->first].lenExpression, commandData.params[vectorParams.begin()->second.lenParam] ) ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, { returnParam }, vectorParams, false, { CommandFlavourFlagBits::enhanced }, raii, false, { CommandFlavourFlagBits::enhanced } ); } } } break; } } return ""; } std::string VulkanHppGenerator::generateCommandVoid2Return( std::string const & name, CommandData const & commandData, size_t initialSkipCount, bool definition, std::vector const & returnParams, bool raii ) const { if ( commandData.params[returnParams[0]].type.type == "uint32_t" ) { std::map vectorParams = determineVectorParams( commandData.params ); if ( vectorParams.size() == 1 ) { if ( returnParams[0] == vectorParams.begin()->second.lenParam ) { if ( returnParams[1] == vectorParams.begin()->first ) { if ( isStructureChainAnchor( commandData.params[returnParams[1]].type.type ) ) { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, returnParams, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator, CommandFlavourFlagBits::chained, CommandFlavourFlagBits::chained | CommandFlavourFlagBits::withAllocator }, raii, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::chained } ); } else { return generateCommandSetInclusive( name, commandData, initialSkipCount, definition, returnParams, vectorParams, false, { CommandFlavourFlagBits::enhanced, CommandFlavourFlagBits::withAllocator }, raii, false, { CommandFlavourFlagBits::enhanced } ); } } } } } return ""; } std::string VulkanHppGenerator::generateConstexprString( std::string const & structName ) const { // structs with a VkBaseInStructure and VkBaseOutStructure can't be a constexpr! bool isConstExpression = ( structName != "VkBaseInStructure" ) && ( structName != "VkBaseOutStructure" ); return isConstExpression ? ( std::string( "VULKAN_HPP_CONSTEXPR" ) + ( ( containsUnion( structName ) || containsArray( structName ) ) ? "_14 " : " " ) ) : ""; } std::string VulkanHppGenerator::generateConstexprDefines() const { auto const constexprFunctionTemplate = std::string{ R"( template ::value>::type> ${deprecated}VULKAN_HPP_CONSTEXPR uint32_t ${constName}( ${arguments} ) { return ${implementation}; } )" }; auto const constexprCallTemplate = std::string{ R"( ${deprecated}VULKAN_HPP_CONSTEXPR_INLINE auto ${constName} = ${callee}( ${arguments} ); )" }; auto const constexprValueTemplate = std::string{ R"( ${deprecated}VULKAN_HPP_CONSTEXPR_INLINE ${type} ${constName} = ${value}; )" }; auto const deprecatedAttribute = std::string{ R"(VULKAN_HPP_DEPRECATED("${reason}") )" }; // handle the value and callee macros first so they are visible for use in functions below. auto constexprDefines = std::string{ R"( //=========================== //=== CONSTEXPR CONSTANTs === //=========================== )" }; { auto const generateConstantsAndProtection = [&constexprValueTemplate, this]( std::vector const & requireData, std::string const & title, std::set & listedConstants ) { auto constants = std::string{}; for ( auto const & require : requireData ) { for ( auto const & constant : require.constants ) { if ( !listedConstants.contains( constant ) ) { auto constIt = m_constants.find( constant ); if ( constIt == m_constants.end() ) { auto aliasIt = m_constantAliases.find( constant ); assert( aliasIt != m_constantAliases.end() ); constIt = m_constants.find( aliasIt->second.name ); assert( constIt != m_constants.end() ); } constants += replaceWithMap( constexprValueTemplate, { { "type", constIt->second.type }, { "constName", stripPrefix( toCamelCase( constant ), "Vk" ) }, { "deprecated", "" }, { "value", constant } } ); listedConstants.insert( constant ); } } } return addTitleAndProtection( title, constants ); }; std::set listedConstants; for ( auto const & feature : m_features ) { constexprDefines += generateConstantsAndProtection( feature.requireData, feature.name, listedConstants ); } for ( auto const & extension : m_extensions ) { constexprDefines += generateConstantsAndProtection( extension.requireData, extension.name, listedConstants ); } } // values constexprDefines += R"( //======================== //=== CONSTEXPR VALUEs === //======================== )"; for ( auto const & [macro, data] : m_definesPartition.values ) { auto const deprecated = data.deprecated ? replaceWithMap( deprecatedAttribute, { { "reason", data.deprecationReason } } ) : ""; // make `macro` PascalCase and strip the `Vk` prefix auto const constName = stripPrefix( toCamelCase( macro ), "Vk" ); auto const valueString = replaceWithMap( constexprValueTemplate, { { "type", "uint32_t" }, { "constName", constName }, { "deprecated", deprecated }, { "value", macro } } ); constexprDefines += valueString; } // functions constexprDefines += R"( //========================= //=== CONSTEXPR CALLEEs === //========================= )"; for ( auto const & [macro, data] : m_definesPartition.callees ) { auto const deprecated = data.deprecated ? replaceWithMap( deprecatedAttribute, { { "reason", data.deprecationReason } } ) : ""; // make `macro` camelCase and strip the `Vk` prefix auto const constName = startLowerCase( stripPrefix( toCamelCase( macro ), "Vk" ) ); // for every parameter, need to use auto const and append a comma if needed (i.e. has more than one parameter, and not for the last one) auto parametersString = std::string{}; for ( auto const & paramString : data.params ) { parametersString += "T const " + paramString + ", "; } // trim the last two characters (i.e. the last comma and the space) parametersString.resize( parametersString.size() - 2 ); auto const functionString = replaceWithMap( constexprFunctionTemplate, { { "arguments", parametersString }, { "constName", constName }, { "deprecated", deprecated }, { "implementation", data.possibleDefinition } } ); constexprDefines += functionString; } // callers constexprDefines += R"( //========================= //=== CONSTEXPR CALLERs === //========================= )"; for ( auto const & [macro, data] : m_definesPartition.callers ) { auto const deprecated = data.deprecated ? replaceWithMap( deprecatedAttribute, { { "reason", data.deprecationReason } } ) : ""; // make `macro` PascalCase and strip the `Vk` prefix auto const constName = stripPrefix( toCamelCase( macro ), "Vk" ); auto argumentsString = std::string{}; // for every argument, append a comma if needed (i.e. has more than one parameter, and not for the last one) for ( auto const & argString : data.params ) { argumentsString += argString + ", "; } // trim the last two characters (i.e. the last comma and the space) argumentsString.resize( argumentsString.size() - 2 ); auto const callerString = replaceWithMap( constexprCallTemplate, { { "arguments", argumentsString }, { "callee", startLowerCase( data.possibleCallee ) }, { "constName", constName }, { "deprecated", deprecated } } ); constexprDefines += callerString; } return constexprDefines; } std::string VulkanHppGenerator::generateConstexprUsings() const { auto constexprUsings = std::string{ R"( //=========================== //=== CONSTEXPR CONSTANTs === //=========================== )" }; auto const constexprUsingTemplate = std::string{ R"( using VULKAN_HPP_NAMESPACE::${constName}; )" }; auto const pascalCasePrefixStrip = []( std::string const & macro ) { return stripPrefix( toCamelCase( macro ), "Vk" ); }; auto const camelCasePrefixStrip = []( std::string const & macro ) { return startLowerCase( stripPrefix( toCamelCase( macro ), "Vk" ) ); }; // constants { auto const generateConstantsAndProtection = [&constexprUsingTemplate, this]( std::vector const & requireData, std::string const & title, std::set & listedConstants ) { auto constants = std::string{}; for ( auto const & require : requireData ) { for ( auto const & constant : require.constants ) { if ( !listedConstants.contains( constant ) ) { auto constIt = m_constants.find( constant ); if ( constIt == m_constants.end() ) { auto aliasIt = m_constantAliases.find( constant ); assert( aliasIt != m_constantAliases.end() ); constIt = m_constants.find( aliasIt->second.name ); assert( constIt != m_constants.end() ); } constants += replaceWithMap( constexprUsingTemplate, { { "constName", stripPrefix( toCamelCase( constant ), "Vk" ) } } ); listedConstants.insert( constant ); } } } return addTitleAndProtection( title, constants ); }; std::set listedConstants; for ( auto const & feature : m_features ) { constexprUsings += generateConstantsAndProtection( feature.requireData, feature.name, listedConstants ); } for ( auto const & extension : m_extensions ) { constexprUsings += generateConstantsAndProtection( extension.requireData, extension.name, listedConstants ); } } // values constexprUsings += R"( //======================== //=== CONSTEXPR VALUEs === //======================== )"; for ( auto const & macro : m_definesPartition.values ) { // make `macro` PascalCase and strip the `Vk` prefix auto const constName = pascalCasePrefixStrip( macro.first ); constexprUsings += replaceWithMap( constexprUsingTemplate, { { "constName", constName } } ); } // callees constexprUsings += R"( //========================= //=== CONSTEXPR CALLEEs === //========================= )"; for ( auto const & macro : m_definesPartition.callees ) { // make `macro` camelCase and strip the `Vk` prefix auto const constName = camelCasePrefixStrip( macro.first ); constexprUsings += replaceWithMap( constexprUsingTemplate, { { "constName", constName } } ); } // callers constexprUsings += R"( //========================== //=== CONSTEXPR CALLERSs === //========================== )"; for ( auto const & macro : m_definesPartition.callers ) { // make `macro` PascalCase and strip the `Vk` prefix auto const constName = pascalCasePrefixStrip( macro.first ); constexprUsings += replaceWithMap( constexprUsingTemplate, { { "constName", constName } } ); } return constexprUsings; } std::string VulkanHppGenerator::generateCppModuleHandleUsings() const { auto const usingTemplate = std::string{ R"( using VULKAN_HPP_NAMESPACE::${className}; )" }; auto handleUsings = std::string{ R"( //=============== //=== HANDLEs === //=============== using VULKAN_HPP_NAMESPACE::isVulkanHandleType; )" }; auto const generateUsingsAndProtection = [&usingTemplate, this]( std::vector const & requireData, std::string const & title ) { auto usings = std::string{}; for ( auto const & require : requireData ) { for ( auto const & type : require.types ) { if ( auto const & handleIt = m_handles.find( type ); handleIt != m_handles.end() ) { usings += replaceWithMap( usingTemplate, { { "className", stripPrefix( handleIt->first, "Vk" ) } } ); } } } return addTitleAndProtection( title, usings ); }; for ( auto const & feature : m_features ) { handleUsings += generateUsingsAndProtection( feature.requireData, feature.name ); } for ( auto const & extension : m_extensions ) { handleUsings += generateUsingsAndProtection( extension.requireData, extension.name ); } return handleUsings; } std::string VulkanHppGenerator::generateCppModuleStructUsings() const { auto const usingTemplate = std::string{ R"( using VULKAN_HPP_NAMESPACE::${structName}; )" }; auto structUsings = std::string{ R"( //=============== //=== STRUCTs === //=============== )" }; auto listedStructs = std::set{}; auto const generateUsingsAndProtection = [&listedStructs, &usingTemplate, this]( std::vector const & requireData, std::string const & title ) { auto localUsings = std::string{}; for ( auto const & require : requireData ) { for ( auto const & type : require.types ) { if ( auto const & structIt = m_structs.find( type ); structIt != m_structs.end() && listedStructs.insert( type ).second ) { auto const structureType = stripPrefix( structIt->first, "Vk" ); localUsings += replaceWithMap( usingTemplate, { { "structName", structureType } } ); // replace the findAlias call with the contents, because it includes an assert that breaks in Debug mode, which shouldn't break. There are multiple // aliases for a given struct, and that's ok. Maybe we should refactor for ( auto const & [alias, aliasData] : m_structAliases ) { if ( aliasData.name == structIt->first ) { auto const aliasName = stripPrefix( alias, "Vk" ); localUsings += replaceWithMap( usingTemplate, { { "structName", aliasName } } ); } } } } } return addTitleAndProtection( title, localUsings ); }; for ( auto const & feature : m_features ) { structUsings += generateUsingsAndProtection( feature.requireData, feature.name ); } for ( auto const & extension : m_extensions ) { structUsings += generateUsingsAndProtection( extension.requireData, extension.name ); } return structUsings; } std::string VulkanHppGenerator::generateCppModuleUniqueHandleUsings() const { auto const usingTemplate = std::string{ R"( using VULKAN_HPP_NAMESPACE::Unique${handleName}; )" }; auto uniqueHandleUsings = std::string{ R"( //====================== //=== UNIQUE HANDLEs === //====================== )" }; auto const [smartHandleEnter, smartHandleLeave] = generateProtection( "VULKAN_HPP_NO_SMART_HANDLE", false ); uniqueHandleUsings += "\n" + smartHandleEnter; auto const generateUsingsAndProtection = [&usingTemplate, this]( std::vector const & requireData, std::string const & title ) { auto usings = std::string{}; for ( auto const & require : requireData ) { for ( auto const & type : require.types ) { if ( auto const & handleIt = m_handles.find( type ); handleIt != m_handles.end() && !handleIt->second.deleteCommand.empty() ) { usings += replaceWithMap( usingTemplate, { { "handleName", stripPrefix( handleIt->first, "Vk" ) } } ); } } } return addTitleAndProtection( title, usings ); }; for ( auto const & feature : m_features ) { uniqueHandleUsings += generateUsingsAndProtection( feature.requireData, feature.name ); } for ( auto const & extension : m_extensions ) { uniqueHandleUsings += generateUsingsAndProtection( extension.requireData, extension.name ); } uniqueHandleUsings += R"( using VULKAN_HPP_NAMESPACE::UniqueHandleTraits; )"; uniqueHandleUsings += smartHandleLeave + "\n"; return uniqueHandleUsings; } std::string VulkanHppGenerator::generateCppModuleFuncsUsings() const { auto const usingTemplate = std::string{ R"( using VULKAN_HPP_NAMESPACE::${funcName}; )" }; auto funcUsings = std::string{ R"( //=========================== //=== COMMAND Definitions === //=========================== )" }; for ( auto const & func : m_handles.at( "" ).commands ) { funcUsings += replaceWithMap( usingTemplate, { { "funcName", startLowerCase( stripPrefix( func, "vk" ) ) } } ); } auto const [enter, leave] = generateProtection( "VULKAN_HPP_NO_SMART_HANDLE", false ); funcUsings += "\n" + enter + replaceWithMap( usingTemplate, { { "funcName", "createInstanceUnique" } } ) + leave + "\n"; return funcUsings; } std::string VulkanHppGenerator::generateCppModuleEnumUsings() const { auto const usingTemplate = std::string{ R"( using VULKAN_HPP_NAMESPACE::${enumName}; )" }; auto enumUsings = std::string{ R"( //============= //=== ENUMs === //============= )" }; auto listedEnums = std::set{}; // insert CppType first enumUsings += replaceWithMap( usingTemplate, { { "enumName", "CppType" } } ); auto const generateUsingsAndProtection = [&listedEnums, &usingTemplate, this]( std::vector const & requireData, std::string const & title ) { auto localUsings = std::string{}; for ( auto const & require : requireData ) { for ( auto const & type : require.types ) { if ( auto const & enumIt = m_enums.find( type ); enumIt != m_enums.end() && listedEnums.insert( type ).second ) { auto const enumName = stripPrefix( enumIt->first, "Vk" ); localUsings += replaceWithMap( usingTemplate, { { "enumName", enumName } } ); if ( auto const aliasIt = findAlias( enumIt->first, m_enumAliases ); aliasIt != m_enumAliases.end() ) { localUsings += replaceWithMap( usingTemplate, { { "enumName", stripPrefix( aliasIt->first, "Vk" ) } } ); } if ( auto const bitmaskIt = std::find_if( m_bitmasks.begin(), m_bitmasks.end(), [&enumIt]( std::pair const & bitmask ) { return bitmask.second.require == enumIt->first; } ); bitmaskIt != m_bitmasks.end() ) { localUsings += replaceWithMap( usingTemplate, { { "enumName", stripPrefix( bitmaskIt->first, "Vk" ) } } ); } } } } return addTitleAndProtection( title, localUsings ); }; for ( auto const & feature : m_features ) { enumUsings += generateUsingsAndProtection( feature.requireData, feature.name ); } for ( auto const & extension : m_extensions ) { enumUsings += generateUsingsAndProtection( extension.requireData, extension.name ); } // finally insert IndexTypeValue auto const indexTypeComment = R"( //========================= //=== Index Type Traits === //========================= )"; enumUsings += indexTypeComment + replaceWithMap( usingTemplate, { { "enumName", "IndexTypeValue" } } ); return enumUsings; } std::string VulkanHppGenerator::generateCppModuleFormatTraitsUsings() const { // everything is hardcoded, so things are very easy... auto formatTraitsUsings = std::string{ R"( //===================== //=== Format Traits === //===================== )" }; auto const usingTemplate = std::string{ R"( using VULKAN_HPP_NAMESPACE::${function}; )" }; auto const formatTraitFunctions = std::array{ "blockExtent", "blockSize", "compatibilityClass", "componentBits", "componentCount", "componentName", "componentNumericFormat", "componentPlaneIndex", "componentsAreCompressed", "compressionScheme", "isCompressed", "packed", "planeCompatibleFormat", "planeCount", "planeHeightDivisor", "planeWidthDivisor", "texelsPerBlock" }; for ( auto const & func : formatTraitFunctions ) { formatTraitsUsings += replaceWithMap( usingTemplate, { { "function", func } } ); } return formatTraitsUsings; } std::string VulkanHppGenerator::generateCppModuleExtensionInspectionUsings() const { auto const usingTemplate = std::string{ R"( using VULKAN_HPP_NAMESPACE::${function}; )" }; auto extensionInspectionsUsings = std::string{ R"( //====================================== //=== Extension inspection functions === //====================================== )" }; auto const extensionInspectionFunctions = std::array{ "getDeviceExtensions", "getInstanceExtensions", "getDeprecatedExtensions", "getExtensionDepends", "getExtensionDepends", "getObsoletedExtensions", "getPromotedExtensions", "getExtensionDeprecatedBy", "getExtensionObsoletedBy", "getExtensionPromotedTo", "isDeprecatedExtension", "isDeviceExtension", "isInstanceExtension", "isObsoletedExtension", "isPromotedExtension" }; for ( auto const & func : extensionInspectionFunctions ) { extensionInspectionsUsings += replaceWithMap( usingTemplate, { { "function", func } } ); } return extensionInspectionsUsings; } std::string VulkanHppGenerator::generateCppModuleUsings() const { auto const usingTemplate = std::string{ R"( using VULKAN_HPP_NAMESPACE::${className}; )" }; auto const hardCodedTypes = std::array{ "ArrayWrapper1D", "ArrayWrapper2D", "FlagTraits", "Flags", "DispatchLoaderBase" }; auto const hardCodedEnhancedModeTypes = std::array{ "ArrayProxy", "ArrayProxyNoTemporaries", "StridedArrayProxy", "Optional", "StructureChain", "UniqueHandle" }; auto const hardCodedSmartHandleTypes = std::array{ "ObjectDestroy", "ObjectFree", "ObjectRelease", "PoolFree" }; auto usings = std::string{ R"( //===================================== //=== HARDCODED TYPEs AND FUNCTIONs === //===================================== )" }; for ( auto const & className : hardCodedTypes ) { usings += replaceWithMap( usingTemplate, { { "className", className } } ); } auto const & [noPrototypesEnter, noPrototypesLeave] = generateProtection( "VK_NO_PROTOTYPES", false ); usings += "\n" + noPrototypesEnter + replaceWithMap( usingTemplate, { { "className", "DispatchLoaderStatic" } } ) + noPrototypesLeave + "\n"; // insert the Flags bitwise operators auto const flagsBitWiseOperatorsUsings = std::array{ "operator&", "operator|", "operator^", "operator~" }; for ( auto const & operatorName : flagsBitWiseOperatorsUsings ) { usings += replaceWithMap( usingTemplate, { { "className", operatorName } } ); } // delete the namespace declaration for the default dispatcher macro using statement usings += R"(using VULKAN_HPP_DEFAULT_DISPATCHER_TYPE; )"; auto enhancedModeUsings = std::string{}; for ( auto const & className : hardCodedEnhancedModeTypes ) { enhancedModeUsings += replaceWithMap( usingTemplate, { { "className", std::string{ className } } } ); } // protect the enhanced-mode usings with a macro auto [enterEnhancedMode, leaveEnhancedMode] = generateProtection( "VULKAN_HPP_DISABLE_ENHANCED_MODE", false ); usings += "\n" + enterEnhancedMode + enhancedModeUsings + leaveEnhancedMode + "\n"; auto noSmartHandleUsings = std::string{}; for ( auto const & className : hardCodedSmartHandleTypes ) { noSmartHandleUsings += replaceWithMap( usingTemplate, { { "className", std::string{ className } } } ); } // likewise for the smart-handle usings auto [enterNoSmartHandle, leaveNoSmartHandle] = generateProtection( "VULKAN_HPP_NO_SMART_HANDLE", false ); usings += "\n" + enterNoSmartHandle + noSmartHandleUsings + leaveNoSmartHandle + "\n"; // now generate baseTypes auto baseTypes = std::string{ R"( //================== //=== BASE TYPEs === //================== )" }; for ( auto const & baseType : m_baseTypes ) { if ( baseType.first != "VkFlags" && baseType.first != "VkFlags64" && !baseType.second.typeInfo.type.empty() ) { baseTypes += replaceWithMap( usingTemplate, { { "className", stripPrefix( baseType.first, "Vk" ) } } ); } } usings += baseTypes; // generate Enums usings += generateCppModuleEnumUsings(); // to_string, toHexString auto const toString = std::array{ "to_string", "toHexString" }; auto const [toStringEnter, toStringLeave] = generateProtection( "VULKAN_HPP_NO_TO_STRING", false ); usings += R"( //====================== //=== ENUM to_string === //====================== )" + toStringEnter; for ( auto const & name : toString ) { usings += replaceWithMap( usingTemplate, { { "className", name } } ); } usings += toStringLeave + "\n"; // hardcoded exceptions and functions auto const hardCodedExceptionTypesAndFunctions = std::array{ "ErrorCategoryImpl", "Error", "LogicError", "SystemError", "errorCategory", "make_error_code", "make_error_condition" }; auto [exceptionsEnter, exceptionsLeave] = generateProtection( "VULKAN_HPP_NO_EXCEPTIONS", false ); auto exceptionsUsings = std::string{ R"( //============================= //=== EXCEPTIONs AND ERRORs === //============================= )" } + exceptionsEnter; for ( auto const & name : hardCodedExceptionTypesAndFunctions ) { exceptionsUsings += replaceWithMap( usingTemplate, { { "className", name } } ); } usings += exceptionsUsings; // result Exceptions auto resultExceptionsUsings = std::string{}; auto const & [name, data] = *m_enums.find( "VkResult" ); for ( auto const & [alias, bitpos, enumName, protect, value, xmlLine] : data.values ) { if ( alias.empty() && enumName.starts_with( "VK_ERROR" ) ) { auto [enter, leave] = generateProtection( protect ); enter = enter.empty() ? enter : "\n" + enter; leave = leave.empty() ? leave : leave + "\n"; auto const valueName = generateEnumValueName( name, enumName, false ); auto const className = stripPrefix( valueName, "eError" ) + "Error"; resultExceptionsUsings += enter + replaceWithMap( usingTemplate, { { "className", className } } ) + leave; } } usings += resultExceptionsUsings; usings += exceptionsLeave + "\n"; // ResultValue auto const hardCodedResultValueTypes = std::array{ "ignore", "ResultValue", "ResultValueType", "createResultValueType" }; for ( auto const & className : hardCodedResultValueTypes ) { usings += replaceWithMap( usingTemplate, { { "className", className } } ); } // resultCheck usings += replaceWithMap( usingTemplate, { { "className", "resultCheck" } } ) + "\n"; usings += generateConstexprUsings() + "\n"; // structs, handles, UniqueHandles, etc usings += generateCppModuleStructUsings(); usings += generateCppModuleHandleUsings(); usings += generateCppModuleUniqueHandleUsings(); usings += generateCppModuleFuncsUsings(); auto const [enterDisableEnhanced, leaveDisableEnhanced] = generateProtection( "VULKAN_HPP_DISABLE_ENHANCED_MODE", false ); usings += "\n" + enterDisableEnhanced + replaceWithMap( usingTemplate, { { "className", "StructExtends" } } ) + leaveDisableEnhanced + "\n"; auto const [enterDynamicLoader, leaveDynamicLoader] = generateProtection( "VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL" ); usings += "\n" + enterDynamicLoader + replaceWithMap( usingTemplate, { { "className", "DynamicLoader" } } ) + leaveDynamicLoader + "\n"; usings += replaceWithMap( usingTemplate, { { "className", "DispatchLoaderDynamic" } } ) + "\n"; usings += generateCppModuleFormatTraitsUsings(); usings += generateCppModuleExtensionInspectionUsings(); return usings; } std::string VulkanHppGenerator::generateCppModuleRaiiUsings() const { auto const raiiUsingTemplate = std::string{ R"( using VULKAN_HPP_RAII_NAMESPACE::${className}; )" }; auto usings = std::string{ R"( //====================== //=== RAII HARDCODED === //====================== using VULKAN_HPP_RAII_NAMESPACE::exchange; using VULKAN_HPP_RAII_NAMESPACE::Context; using VULKAN_HPP_RAII_NAMESPACE::ContextDispatcher; using VULKAN_HPP_RAII_NAMESPACE::InstanceDispatcher; using VULKAN_HPP_RAII_NAMESPACE::DeviceDispatcher; //==================== //=== RAII HANDLEs === //==================== )" }; auto const generateUsingsAndProtection = [&raiiUsingTemplate, this]( std::vector const & requireData, std::string const & title ) { auto usings = std::string{}; for ( auto const & require : requireData ) { for ( auto const & type : require.types ) { if ( auto const & handleIt = m_handles.find( type ); handleIt != m_handles.end() ) { usings += replaceWithMap( raiiUsingTemplate, { { "className", stripPrefix( handleIt->first, "Vk" ) } } ); // if there is an array constructor, generate the plural type also if ( !generateRAIIHandleConstructors( *handleIt ).second.empty() ) { usings += replaceWithMap( raiiUsingTemplate, { { "className", stripPrefix( type, "Vk" ) + "s" } } ); } } } } return addTitleAndProtection( title, usings ); }; // now, insert features and extensions with protection, and strip Vk prefix for ( auto const & feature : m_features ) { usings += generateUsingsAndProtection( feature.requireData, feature.name ); } for ( auto const & extension : m_extensions ) { usings += generateUsingsAndProtection( extension.requireData, extension.name ); } return usings; } std::string VulkanHppGenerator::generateDataDeclarations( CommandData const & commandData, std::vector const & returnParams, std::map const & vectorParams, std::set const & templatedParams, CommandFlavourFlags flavourFlags, bool raii, std::vector const & dataTypes, std::string const & dataType, std::string const & returnType, std::string const & returnVariable ) const { assert( dataTypes.size() == returnParams.size() ); switch ( returnParams.size() ) { case 0: return ""; // no returnParams -> no data declarations case 1: return generateDataDeclarations1Return( commandData, returnParams, vectorParams, templatedParams, flavourFlags, dataTypes, dataType, returnType, returnVariable ); case 2: assert( !( flavourFlags & CommandFlavourFlagBits::unique ) ); return generateDataDeclarations2Returns( commandData, returnParams, vectorParams, flavourFlags, raii, dataTypes, dataType, returnVariable ); case 3: assert( !( flavourFlags & ( CommandFlavourFlagBits::singular | CommandFlavourFlagBits::unique ) ) ); return generateDataDeclarations3Returns( commandData, returnParams, vectorParams, flavourFlags, raii, dataTypes ); default: assert( false ); return ""; } } std::string VulkanHppGenerator::generateDataDeclarations1Return( CommandData const & commandData, std::vector const & returnParams, std::map const & vectorParams, std::set const & templatedParams, CommandFlavourFlags flavourFlags, std::vector const & dataTypes, std::string const & dataType, std::string const & returnType, std::string const & returnVariable ) const { auto vectorParamIt = vectorParams.find( returnParams[0] ); if ( !( flavourFlags & CommandFlavourFlagBits::chained ) ) { if ( ( vectorParamIt == vectorParams.end() ) || ( flavourFlags & CommandFlavourFlagBits::singular ) ) { std::string const dataDeclarationsTemplate = R"(${returnType} ${returnVariable};)"; return replaceWithMap( dataDeclarationsTemplate, { { "returnType", dataType }, { "returnVariable", returnVariable } } ); } else { std::string allocator = stripPrefix( dataTypes[0], "VULKAN_HPP_NAMESPACE::" ) + "Allocator"; std::string vectorAllocator = ( ( flavourFlags & CommandFlavourFlagBits::withAllocator ) && !( flavourFlags & CommandFlavourFlagBits::unique ) ) ? ( ", " + startLowerCase( allocator ) ) : ""; std::string vectorSize = getVectorSize( commandData.params, vectorParams, returnParams[0], dataTypes[0], templatedParams ); std::string const dataDeclarationsTemplate = R"(${dataType} ${returnVariable}( ${vectorSize}${vectorAllocator} );)"; return replaceWithMap( dataDeclarationsTemplate, { { "dataType", dataType }, { "returnVariable", returnVariable }, { "vectorAllocator", vectorAllocator }, { "vectorSize", vectorSize } } ); } } else { assert( ( vectorParamIt == vectorParams.end() ) || ( flavourFlags & CommandFlavourFlagBits::singular ) ); std::string dataVariable = startLowerCase( stripPrefix( commandData.params[returnParams[0]].name, "p" ) ); std::string const dataDeclarationsTemplate = R"(${returnType} ${returnVariable}; ${dataType} & ${dataVariable} = ${returnVariable}.template get<${dataType}>();)"; return replaceWithMap( dataDeclarationsTemplate, { { "dataType", dataTypes[0] }, { "dataVariable", dataVariable }, { "returnType", ( commandData.returnType == "void" ) ? returnType : "StructureChain" }, { "returnVariable", returnVariable } } ); } } std::string VulkanHppGenerator::generateDataDeclarations2Returns( CommandData const & commandData, std::vector const & returnParams, std::map const & vectorParams, CommandFlavourFlags flavourFlags, bool raii, std::vector const & dataTypes, std::string const & dataType, std::string const & returnVariable ) const { bool chained = flavourFlags & CommandFlavourFlagBits::chained; bool singular = flavourFlags & CommandFlavourFlagBits::singular; bool withAllocator = flavourFlags & CommandFlavourFlagBits::withAllocator; switch ( vectorParams.size() ) { case 0: assert( !singular && !chained ); { std::string firstDataVariable = startLowerCase( stripPrefix( commandData.params[returnParams[0]].name, "p" ) ); std::string secondDataVariable = startLowerCase( stripPrefix( commandData.params[returnParams[1]].name, "p" ) ); std::string const dataDeclarationTemplate = R"(std::pair<${firstDataType},${secondDataType}> data_; ${firstDataType} & ${firstDataVariable} = data_.first; ${secondDataType} & ${secondDataVariable} = data_.second;)"; return replaceWithMap( dataDeclarationTemplate, { { "firstDataType", dataTypes[0] }, { "firstDataVariable", firstDataVariable }, { "secondDataType", dataTypes[1] }, { "secondDataVariable", secondDataVariable } } ); } case 1: assert( ( returnParams[0] == vectorParams.begin()->second.lenParam ) && ( returnParams[1] == vectorParams.begin()->first ) && !singular ); { std::string counterVariable = startLowerCase( stripPrefix( commandData.params[returnParams[0]].name, "p" ) ); if ( !chained ) { std::string vectorAllocator = withAllocator ? ( "( " + startLowerCase( stripPrefix( dataTypes[1], "VULKAN_HPP_NAMESPACE::" ) ) + "Allocator )" ) : ""; std::string const dataDeclarationTemplate = R"(${returnType} ${returnVariable}${vectorAllocator}; ${counterType} ${counterVariable};)"; return replaceWithMap( dataDeclarationTemplate, { { "counterType", dataTypes[0] }, { "counterVariable", counterVariable }, { "returnType", dataType }, { "returnVariable", returnVariable }, { "vectorAllocator", vectorAllocator } } ); } else { std::string structureChainAllocator = raii ? "" : ", StructureChainAllocator"; std::string structureChainInitializer = withAllocator ? ( "( structureChainAllocator )" ) : ""; std::string vectorVariable = startLowerCase( stripPrefix( commandData.params[returnParams[1]].name, "p" ) ); std::string const dataDeclarationTemplate = R"(std::vector structureChains${structureChainInitializer}; std::vector<${vectorElementType}> ${vectorVariable}; ${counterType} ${counterVariable};)"; return replaceWithMap( dataDeclarationTemplate, { { "counterType", dataTypes[0] }, { "counterVariable", counterVariable }, { "structureChainAllocator", structureChainAllocator }, { "structureChainInitializer", structureChainInitializer }, { "vectorElementType", dataTypes[1] }, { "vectorVariable", vectorVariable }, } ); } } break; case 2: assert( ( returnParams[0] == std::next( vectorParams.begin() )->first ) && !vectorParams.contains( returnParams[1] ) && !chained ); { std::string firstDataVariable = startLowerCase( stripPrefix( commandData.params[returnParams[0]].name, "p" ) ); std::string secondDataVariable = startLowerCase( stripPrefix( commandData.params[returnParams[1]].name, "p" ) ); if ( singular ) { firstDataVariable = stripPluralS( firstDataVariable ); std::string const dataDeclarationTemplate = R"(std::pair<${firstDataType},${secondDataType}> data_; ${firstDataType} & ${firstDataVariable} = data_.first; ${secondDataType} & ${secondDataVariable} = data_.second;)"; return replaceWithMap( dataDeclarationTemplate, { { "firstDataType", dataTypes[0] }, { "firstDataVariable", firstDataVariable }, { "secondDataType", dataTypes[1] }, { "secondDataVariable", secondDataVariable } } ); } else { std::string allocatorType = raii ? "" : ( startUpperCase( stripPrefix( dataTypes[0], "VULKAN_HPP_NAMESPACE::" ) ) + "Allocator" ); std::string allocateInitializer = withAllocator ? ( ", " + startLowerCase( allocatorType ) ) : ""; if ( !raii ) { allocatorType = ", " + allocatorType; } std::string vectorSize = startLowerCase( stripPrefix( commandData.params[vectorParams.begin()->first].name, "p" ) ) + ".size()"; std::string const dataDeclarationTemplate = R"(std::pair,${secondDataType}> data_( std::piecewise_construct, std::forward_as_tuple( ${vectorSize}${allocateInitializer} ), std::forward_as_tuple( 0 ) ); std::vector<${firstDataType}${allocatorType}> & ${firstDataVariable} = data_.first; ${secondDataType} & ${secondDataVariable} = data_.second;)"; return replaceWithMap( dataDeclarationTemplate, { { "allocateInitializer", allocateInitializer }, { "allocatorType", allocatorType }, { "firstDataType", dataTypes[0] }, { "firstDataVariable", firstDataVariable }, { "secondDataType", dataTypes[1] }, { "secondDataVariable", secondDataVariable }, { "vectorSize", vectorSize } } ); } } break; default: assert( false ); return ""; } } std::string VulkanHppGenerator::generateDataDeclarations3Returns( CommandData const & commandData, std::vector const & returnParams, std::map const & vectorParams, CommandFlavourFlags flavourFlags, bool raii, std::vector const & dataTypes ) const { switch ( vectorParams.size() ) { case 1: { assert( ( returnParams[1] == vectorParams.begin()->second.lenParam ) && ( returnParams[2] == vectorParams.begin()->first ) ); std::string valueVariable = startLowerCase( stripPrefix( commandData.params[returnParams[0]].name, "p" ) ); std::string counterVariable = startLowerCase( stripPrefix( commandData.params[returnParams[1]].name, "p" ) ); std::string vectorVariable = startLowerCase( stripPrefix( commandData.params[returnParams[2]].name, "p" ) ); std::string vectorAllocatorType, pairConstructor; if ( !raii ) { vectorAllocatorType = startUpperCase( stripPrefix( dataTypes[2], "VULKAN_HPP_NAMESPACE::" ) ) + "Allocator"; pairConstructor = ( flavourFlags & CommandFlavourFlagBits::withAllocator ) ? ( "( std::piecewise_construct, std::forward_as_tuple(), std::forward_as_tuple( " + startLowerCase( vectorAllocatorType ) + " ) )" ) : ""; vectorAllocatorType = ", " + vectorAllocatorType; } std::string const chainedDataDeclarationsTemplate = R"(std::pair,std::vector<${vectorElementType}${vectorAllocatorType}>> data_${pairConstructor}; ${valueType} & ${valueVariable} = data_.first.template get<${valueType}>(); std::vector<${vectorElementType}${vectorAllocatorType}> & ${vectorVariable} = data_.second; ${counterType} ${counterVariable};)"; std::string const dataDeclarationsTemplate = R"(std::pair<${valueType},std::vector<${vectorElementType}${vectorAllocatorType}>> data_${pairConstructor}; ${valueType} & ${valueVariable} = data_.first; std::vector<${vectorElementType}${vectorAllocatorType}> & ${vectorVariable} = data_.second; ${counterType} ${counterVariable};)"; return replaceWithMap( ( flavourFlags & CommandFlavourFlagBits::chained ) ? chainedDataDeclarationsTemplate : dataDeclarationsTemplate, { { "counterType", dataTypes[1] }, { "counterVariable", counterVariable }, { "vectorAllocatorType", vectorAllocatorType }, { "vectorElementType", dataTypes[2] }, { "vectorVariable", vectorVariable }, { "pairConstructor", pairConstructor }, { "valueType", dataTypes[0] }, { "valueVariable", valueVariable } } ); } break; case 2: { assert( !( flavourFlags & CommandFlavourFlagBits::chained ) ); assert( ( returnParams[0] == vectorParams.begin()->second.lenParam ) && ( returnParams[1] == vectorParams.begin()->first ) && ( returnParams[2] == std::next( vectorParams.begin() )->first ) && ( returnParams[0] == std::next( vectorParams.begin() )->second.lenParam ) ); std::string counterVariable = startLowerCase( stripPrefix( commandData.params[returnParams[0]].name, "p" ) ); std::string firstVectorVariable = startLowerCase( stripPrefix( commandData.params[returnParams[1]].name, "p" ) ); std::string secondVectorVariable = startLowerCase( stripPrefix( commandData.params[returnParams[2]].name, "p" ) ); std::string firstVectorAllocatorType, secondVectorAllocatorType, pairConstructor; if ( !raii ) { firstVectorAllocatorType = startUpperCase( stripPrefix( dataTypes[1], "VULKAN_HPP_NAMESPACE::" ) ) + "Allocator"; secondVectorAllocatorType = startUpperCase( stripPrefix( dataTypes[2], "VULKAN_HPP_NAMESPACE::" ) ) + "Allocator"; pairConstructor = ( flavourFlags & CommandFlavourFlagBits::withAllocator ) ? ( "( std::piecewise_construct, std::forward_as_tuple( " + startLowerCase( firstVectorAllocatorType ) + " ), std::forward_as_tuple( " + startLowerCase( secondVectorAllocatorType ) + " ) )" ) : ""; firstVectorAllocatorType = ", " + firstVectorAllocatorType; secondVectorAllocatorType = ", " + secondVectorAllocatorType; } std::string const dataDeclarationsTemplate = R"(std::pair, std::vector<${secondVectorElementType}${secondVectorAllocatorType}>> data_${pairConstructor}; std::vector<${firstVectorElementType}${firstVectorAllocatorType}> & ${firstVectorVariable} = data_.first; std::vector<${secondVectorElementType}${secondVectorAllocatorType}> & ${secondVectorVariable} = data_.second; ${counterType} ${counterVariable};)"; return replaceWithMap( dataDeclarationsTemplate, { { "counterType", dataTypes[0] }, { "counterVariable", counterVariable }, { "firstVectorAllocatorType", firstVectorAllocatorType }, { "firstVectorElementType", dataTypes[1] }, { "firstVectorVariable", firstVectorVariable }, { "pairConstructor", pairConstructor }, { "secondVectorAllocatorType", secondVectorAllocatorType }, { "secondVectorElementType", dataTypes[2] }, { "secondVectorVariable", secondVectorVariable } } ); } default: assert( false ); return ""; } } std::string VulkanHppGenerator::generateDataPreparation( CommandData const & commandData, size_t initialSkipCount, std::vector const & returnParams, std::map const & vectorParams, std::set const & templatedParams, CommandFlavourFlags flavourFlags, bool enumerating ) const { bool chained = flavourFlags & CommandFlavourFlagBits::chained; bool singular = flavourFlags & CommandFlavourFlagBits::singular; bool unique = flavourFlags & CommandFlavourFlagBits::unique; auto vectorParamIt = ( 1 < returnParams.size() ) ? vectorParams.find( returnParams[1] ) : vectorParams.end(); if ( vectorParamIt != vectorParams.end() ) { assert( !unique ); std::string vectorName = startLowerCase( stripPrefix( commandData.params[vectorParamIt->first].name, "p" ) ); if ( chained ) { assert( !singular ); assert( templatedParams.empty() ); assert( returnParams.size() == 2 ); assert( !vectorParams.contains( returnParams[0] ) ); assert( ( vectorParamIt != vectorParams.end() ) && ( vectorParamIt->second.lenParam == returnParams[0] ) ); std::string vectorElementType = stripPostfix( commandData.params[vectorParamIt->first].type.compose( "VULKAN_HPP_NAMESPACE" ), " *" ); if ( enumerating ) { std::string const dataPreparationTemplate = R"(VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() ); if ( ${counterName} < ${vectorName}.size() ) { structureChains.resize( ${counterName} ); } for ( ${counterType} i = 0; i < ${counterName}; i++ ) { structureChains[i].template get<${vectorElementType}>() = ${vectorName}[i]; })"; return replaceWithMap( dataPreparationTemplate, { { "counterName", startLowerCase( stripPrefix( commandData.params[vectorParamIt->second.lenParam].name, "p" ) ) }, { "counterType", commandData.params[vectorParamIt->second.lenParam].type.type }, { "vectorElementType", vectorElementType }, { "vectorName", vectorName } } ); } else { std::string const dataPreparationTemplate = R"(for ( ${counterType} i = 0; i < ${counterName}; i++ ) { structureChains[i].template get<${vectorElementType}>() = ${vectorName}[i]; })"; return replaceWithMap( dataPreparationTemplate, { { "counterName", startLowerCase( stripPrefix( commandData.params[vectorParamIt->second.lenParam].name, "p" ) ) }, { "counterType", commandData.params[vectorParamIt->second.lenParam].type.type }, { "vectorElementType", vectorElementType }, { "vectorName", vectorName } } ); } } else if ( enumerating ) { assert( !singular ); assert( ( vectorParams.size() != 2 ) || ( ( vectorParams.begin()->first == returnParams[1] ) && ( vectorParams.begin()->second.lenParam == returnParams[0] ) && ( std::next( vectorParams.begin() )->first == returnParams[2] ) && ( std::next( vectorParams.begin() )->second.lenParam == returnParams[0] ) ) ); std::string resizes; for ( auto const & vp : vectorParams ) { assert( std::any_of( returnParams.begin(), returnParams.end(), [&vp]( size_t rp ) { return rp == vp.first; } ) && std::any_of( returnParams.begin(), returnParams.end(), [&vp]( size_t rp ) { return rp == vp.second.lenParam; } ) ); resizes += startLowerCase( stripPrefix( commandData.params[vp.first].name, "p" ) ) + ".resize( " + startLowerCase( stripPrefix( commandData.params[vp.second.lenParam].name, "p" ) ) + " );\n"; } resizes.pop_back(); std::string const dataPreparationTemplate = R"(VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() ); if ( ${counterName} < ${vectorName}.size() ) { ${resizes} })"; return replaceWithMap( dataPreparationTemplate, { { "counterName", startLowerCase( stripPrefix( commandData.params[vectorParamIt->second.lenParam].name, "p" ) ) }, { "resizes", resizes }, { "vectorName", vectorName } } ); } } else if ( unique && !singular && ( returnParams.size() == 1 ) && vectorParams.contains( returnParams[0] ) ) { assert( !enumerating ); std::string className = initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : ""; std::string deleterDefinition; std::vector lenParts = tokenize( commandData.params[returnParams[0]].lenExpression, "->" ); switch ( lenParts.size() ) { case 1: deleterDefinition = "ObjectDestroy<" + className + ", Dispatch> deleter( *this, allocator, d )"; break; case 2: { auto vpiIt = vectorParams.find( returnParams[0] ); assert( vpiIt != vectorParams.end() ); std::string poolType, poolName; std::tie( poolType, poolName ) = getPoolTypeAndName( commandData.params[vpiIt->second.lenParam].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 handleType = stripPrefix( commandData.params[returnParams[0]].type.type, "Vk" ); std::string uniqueVectorName = "unique" + stripPrefix( commandData.params[returnParams[0]].name, "p" ); std::string vectorAllocator = ( flavourFlags & CommandFlavourFlagBits::withAllocator ) ? ( "( " + startLowerCase( handleType ) + "Allocator )" ) : ""; std::string vectorName = startLowerCase( stripPrefix( commandData.params[returnParams[0]].name, "p" ) ); std::string elementName = stripPluralS( vectorName ); std::string vectorSize = getVectorSize( commandData.params, vectorParams, returnParams[0], commandData.params[returnParams[0]].type.type, templatedParams ); std::string const dataPreparationTemplate = R"(std::vector, ${handleType}Allocator> ${uniqueVectorName}${vectorAllocator}; ${uniqueVectorName}.reserve( ${vectorSize} ); ${deleterDefinition}; for ( auto const & ${elementName} : ${vectorName} ) { ${uniqueVectorName}.push_back( UniqueHandle<${handleType}, Dispatch>( ${elementName}, deleter ) ); })"; return replaceWithMap( dataPreparationTemplate, { { "elementName", elementName }, { "deleterDefinition", deleterDefinition }, { "handleType", handleType }, { "uniqueVectorName", uniqueVectorName }, { "vectorAllocator", vectorAllocator }, { "vectorName", vectorName }, { "vectorSize", vectorSize } } ); } return ""; } std::string VulkanHppGenerator::generateDataSizeChecks( CommandData const & commandData, std::vector const & returnParams, std::vector const & returnParamTypes, std::map const & vectorParams, std::set const & templatedParams, bool singular ) const { assert( returnParams.size() == returnParamTypes.size() ); std::string dataSizeChecks; if ( !singular ) { const std::string dataSizeCheckTemplate = R"( VULKAN_HPP_ASSERT( ${dataSize} % sizeof( ${dataType} ) == 0 );)"; for ( size_t i = 0; i < returnParams.size(); i++ ) { auto vectorParamIt = vectorParams.find( returnParams[i] ); if ( ( vectorParamIt != vectorParams.end() ) && templatedParams.contains( returnParams[i] ) && std::none_of( returnParams.begin(), returnParams.end(), [&vectorParamIt]( size_t rp ) { return rp == vectorParamIt->second.lenParam; } ) ) { dataSizeChecks += replaceWithMap( dataSizeCheckTemplate, { { "dataSize", commandData.params[vectorParamIt->second.lenParam].name }, { "dataType", returnParamTypes[i] } } ); } } } return dataSizeChecks; } 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; 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(instanceCpp); ${instanceCommandAssignments} } void init( VULKAN_HPP_NAMESPACE::Device deviceCpp ) VULKAN_HPP_NOEXCEPT { VkDevice device = static_cast(deviceCpp); ${deviceCommandAssignments} } template 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("vkGetInstanceProcAddr"); PFN_vkGetDeviceProcAddr getDeviceProcAddr = dl.template getProcAddress("vkGetDeviceProcAddr"); init(static_cast(instance), getInstanceProcAddr, static_cast(device), device ? getDeviceProcAddr : nullptr); } template void init(VULKAN_HPP_NAMESPACE::Instance const & instance, VULKAN_HPP_NAMESPACE::Device const & device) VULKAN_HPP_NOEXCEPT { static DynamicLoader dl; init(instance, device, dl); } };)"; std::string commandMembers, deviceCommandAssignments, initialCommandAssignments, instanceCommandAssignments; std::set listedCommands; // some commands are listed with more than one extension! for ( auto const & feature : m_features ) { appendDispatchLoaderDynamicCommands( feature.requireData, listedCommands, feature.name, commandMembers, initialCommandAssignments, instanceCommandAssignments, deviceCommandAssignments ); } for ( auto const & extension : m_extensions ) { appendDispatchLoaderDynamicCommands( extension.requireData, listedCommands, extension.name, 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 listedCommands; for ( auto const & feature : m_features ) { commands += generateDispatchLoaderStaticCommands( feature.requireData, listedCommands, feature.name ); } for ( auto const & extension : m_extensions ) { commands += generateDispatchLoaderStaticCommands( extension.requireData, listedCommands, extension.name ); } return replaceWithMap( dispatchLoaderStaticTemplate, { { "commands", commands } } ); } 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 ); if ( !m_commandAliases.contains( name ) && ( ( ( 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, false ); std::string shortenedName; if ( name.substr( 2, 7 ) == "Destroy" ) { shortenedName = "destroy"; } else if ( name.substr( 2, 4 ) == "Free" ) { // enclose "free" in parenthesis to prevent interference with MSVC debug 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, std::string const & firstArg ) const { if ( commandName == "vkGetInstanceProcAddr" ) { // Don't overwite vkGetInstanceProcAddr with NULL. return ""; } std::string str = " " + commandName + " = PFN_" + commandName + "( vkGet" + ( ( firstArg == "device" ) ? "Device" : "Instance" ) + "ProcAddr( " + firstArg + ", \"" + commandName + "\" ) );\n"; // if this is an alias'ed function, use it as a fallback for the original one auto aliasIt = m_commandAliases.find( commandName ); if ( aliasIt != m_commandAliases.end() ) { str += " if ( !" + aliasIt->second.name + " ) " + aliasIt->second.name + " = " + commandName + ";\n"; } return str; } std::string VulkanHppGenerator::generateDispatchLoaderStaticCommands( std::vector const & requireData, std::set & 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 const & commandData = getCommandData( command ); str += "\n"; std::string parameterList, parameters; assert( !commandData.params.empty() ); for ( auto param : commandData.params ) { parameterList += param.type.compose( "" ) + " " + param.name + generateCArraySizes( param.arraySizes ) + ", "; parameters += param.name + ", "; } assert( parameterList.ends_with( ", " ) && parameters.ends_with( ", " ) ); 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", command }, { "parameterList", parameterList }, { "parameters", parameters }, { "returnType", commandData.returnType } } ); } } } return addTitleAndProtection( title, str ); } std::string VulkanHppGenerator::generateEnum( std::pair const & enumData, std::string const & surroundingProtect ) const { std::string baseType, bitmask; if ( enumData.second.isBitmask ) { auto bitmaskIt = std::find_if( m_bitmasks.begin(), m_bitmasks.end(), [&enumData]( auto const & bitmask ) { return bitmask.second.require == enumData.first; } ); assert( bitmaskIt != m_bitmasks.end() ); baseType = " : " + bitmaskIt->first; bitmask = generateBitmask( bitmaskIt, surroundingProtect ); } auto aliasEnumIt = findAlias( enumData.first, m_enumAliases ); std::string enumValues, previousEnter, previousLeave; #if !defined( NDEBUG ) std::map valueToNameMap; #else std::set valueSet; #endif for ( auto const & value : enumData.second.values ) { std::string valueName = generateEnumValueName( value.alias.empty() || ( aliasEnumIt == m_enumAliases.end() ) ? enumData.first : aliasEnumIt->first, value.name, enumData.second.isBitmask ); #if !defined( NDEBUG ) auto valueToNameIt = valueToNameMap.find( valueName ); if ( valueToNameIt == valueToNameMap.end() ) #else if ( !valueSet.contains( valueName ) ) #endif { // if the value's protect differs from the surrounding protect, generate protection code std::string enter, leave; if ( !value.protect.empty() && ( value.protect != surroundingProtect ) ) { tie( enter, leave ) = generateProtection( value.protect ); } if ( previousEnter != enter ) { enumValues += previousLeave + enter; } enumValues += " " + valueName + " = " + value.name + ",\n"; #if !defined( NDEBUG ) if ( value.alias.empty() ) { valueToNameMap[valueName] = value.name; } else { // map the aliasName to the name of the base std::string baseName = value.name; auto valueIt = std::find_if( enumData.second.values.begin(), enumData.second.values.end(), [&baseName]( EnumValueData const & evd ) { return evd.name == baseName; } ); assert( valueIt != enumData.second.values.end() ); while ( !valueIt->alias.empty() ) { baseName = valueIt->alias; valueIt = std::find_if( enumData.second.values.begin(), enumData.second.values.end(), [&baseName]( EnumValueData const & evd ) { return evd.name == baseName; } ); if ( valueIt == enumData.second.values.end() ) { valueIt = std::find_if( enumData.second.unsupportedValues.begin(), enumData.second.unsupportedValues.end(), [&baseName]( EnumValueData const & evd ) { return evd.name == baseName; } ); assert( valueIt != enumData.second.unsupportedValues.end() ); } } valueToNameMap[valueName] = baseName; } #else valueSet.insert( valueName ); #endif previousEnter = enter; previousLeave = leave; } #if !defined( NDEBUG ) else { // verify, that the identical value represents the identical name auto valueIt = std::find_if( enumData.second.values.begin(), enumData.second.values.end(), [&value]( EnumValueData const & evd ) { return evd.name == value.name; } ); std::string baseName = valueIt->name; while ( !valueIt->alias.empty() ) { baseName = valueIt->alias; valueIt = std::find_if( enumData.second.values.begin(), enumData.second.values.end(), [&baseName]( EnumValueData const & evd ) { return evd.name == baseName; } ); } assert( baseName == valueToNameIt->second ); } #endif } enumValues += previousLeave; if ( !enumValues.empty() ) { size_t pos = enumValues.rfind( ',' ); assert( pos != std::string::npos ); enumValues.erase( pos, 1 ); enumValues = "\n" + enumValues + " "; } std::string enumUsing; if ( aliasEnumIt != m_enumAliases.end() ) { enumUsing += " using " + stripPrefix( aliasEnumIt->first, "Vk" ) + " = " + stripPrefix( enumData.first, "Vk" ) + ";\n"; } const std::string enumTemplate = R"( enum class ${enumName}${baseType} {${enumValues}}; ${enumUsing}${bitmask})"; return replaceWithMap( enumTemplate, { { "baseType", baseType }, { "bitmask", bitmask }, { "enumName", stripPrefix( enumData.first, "Vk" ) }, { "enumUsing", enumUsing }, { "enumValues", enumValues } } ); } std::string VulkanHppGenerator::generateEnums() const { const std::string enumsTemplate = R"( //============= //=== ENUMs === //============= ${enums} )"; std::string enums; std::set listedEnums; for ( auto const & feature : m_features ) { enums += generateEnums( feature.requireData, listedEnums, feature.name ); } for ( auto const & extension : m_extensions ) { enums += generateEnums( extension.requireData, listedEnums, extension.name ); } return replaceWithMap( enumsTemplate, { { "enums", enums } } ); } std::string VulkanHppGenerator::generateEnums( std::vector const & requireData, std::set & listedEnums, std::string const & title ) const { std::string surroundingProtect = getProtectFromTitle( title ); 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.contains( type ) ) { listedEnums.insert( type ); str += "\n"; str += generateEnum( *enumIt, surroundingProtect ); } } } return addTitleAndProtection( title, str ); } std::string VulkanHppGenerator::generateEnumsToString() const { // start with toHexString, which is used in all the to_string functions here! const std::string enumsToStringTemplate = R"( //======================= //=== ENUMs to_string === //======================= VULKAN_HPP_INLINE std::string toHexString( uint32_t value ) { #if __cpp_lib_format return std::format( "{:x}", value ); #else std::stringstream stream; stream << std::hex << value; return stream.str(); #endif } ${enumsToString} )"; std::string enumsToString; std::set listedEnums; for ( auto const & feature : m_features ) { enumsToString += generateEnumsToString( feature.requireData, listedEnums, feature.name ); } for ( auto const & extension : m_extensions ) { enumsToString += generateEnumsToString( extension.requireData, listedEnums, extension.name ); } return replaceWithMap( enumsToStringTemplate, { { "enumsToString", enumsToString } } ); } std::string VulkanHppGenerator::generateEnumsToString( std::vector const & requireData, std::set & 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.contains( type ) ) { listedEnums.insert( type ); str += "\n"; str += generateEnumToString( *enumIt ); } } } return addTitleAndProtection( title, str ); } std::string VulkanHppGenerator::generateEnumInitializer( TypeInfo const & type, std::vector const & arraySizes, std::vector 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 ); std::string value = generateNamespacedType( type.type ) + "::" + 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.value ); assert( 1 < count ); str += "{ { " + value; for ( int i = 1; i < count; i++ ) { str += ", " + value; } str += " } }"; } return str; } std::string VulkanHppGenerator::generateEnumToString( std::pair 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 ) { // generate cases for non-alias enum values only if ( value.alias.empty() ) { auto [enter, leave] = generateProtection( 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 ).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( 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::pair VulkanHppGenerator::generateEnumSuffixes( std::string const & name, bool bitmask ) const { 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( 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 : m_tags ) { if ( prefix.ends_with( tag.first + "_" ) ) { prefix.erase( prefix.length() - tag.first.length() - 1 ); postfix = "_" + tag.first; break; } else if ( name.ends_with( tag.first ) ) { postfix = "_" + tag.first; break; } } } return std::make_pair( prefix, postfix ); } std::string VulkanHppGenerator::generateEnumValueName( std::string const & enumName, std::string const & valueName, bool bitmask ) const { std::string prefix, postfix; std::tie( prefix, postfix ) = generateEnumSuffixes( enumName, bitmask ); std::string tag = findTag( valueName, "" ); if ( postfix == "_" + tag ) { tag = findTag( 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 VulkanHppGenerator::generateExtensionDependencies() const { std::string extensionDependencies, previousEnter, previousLeave; for ( auto const & extension : m_extensions ) { if ( !extension.depends.empty() ) { std::string dependsPerExtension = "{ \"" + extension.name + "\", { "; for ( auto const & dependsByVersion : extension.depends ) { dependsPerExtension += "{ \"" + dependsByVersion.first + "\", { "; if ( !dependsByVersion.second.empty() ) { dependsPerExtension += " { "; for ( auto const & dependsSet : dependsByVersion.second ) { for ( auto const & depends : dependsSet ) { dependsPerExtension += "\"" + depends + "\", "; } } dependsPerExtension += " }, "; assert( dependsPerExtension.ends_with( ", " ) ); dependsPerExtension = dependsPerExtension.substr( 0, dependsPerExtension.length() - 2 ); } dependsPerExtension += " } }, "; } assert( dependsPerExtension.ends_with( ", " ) ); dependsPerExtension = dependsPerExtension.substr( 0, dependsPerExtension.length() - 2 ); dependsPerExtension += " } }, "; auto [enter, leave] = generateProtection( getProtectFromTitle( extension.name ) ); extensionDependencies += ( ( previousEnter != enter ) ? ( "\n" + previousLeave + enter ) : "\n" ) + dependsPerExtension; previousEnter = enter; previousLeave = leave; } } assert( extensionDependencies.ends_with( ", " ) ); extensionDependencies = extensionDependencies.substr( 0, extensionDependencies.length() - 2 ); if ( !previousLeave.empty() ) { extensionDependencies += "\n" + previousLeave; } return extensionDependencies; } std::string VulkanHppGenerator::generateExtensionDependsByVersion( bool definition ) const { if ( m_api != "vulkan" ) { return ""; } if ( definition ) { const std::string generateExtensionDependsTemplate = R"( VULKAN_HPP_INLINE std::pair> const &> getExtensionDepends( std::string const & version, std::string const & extension ) { #if !defined( NDEBUG ) static std::set versions = { ${versions} }; assert( versions.find( version ) != versions.end() ); #endif static std::vector> noDependencies; std::map>> const & dependencies = getExtensionDepends( extension ); if ( dependencies.empty() ) { return { true, noDependencies }; } auto depIt = dependencies.lower_bound( version ); if ( ( depIt == dependencies.end() ) || ( depIt->first != version ) ) { depIt = std::prev( depIt ); } if ( depIt == dependencies.end() ) { return { false, noDependencies }; } else { return { true, depIt->second }; } } )"; std::string versions; for ( auto const & feature : m_features ) { versions += "\"" + feature.name + "\", "; } assert( versions.ends_with( ", " ) ); versions = versions.substr( 0, versions.length() - 2 ); return replaceWithMap( generateExtensionDependsTemplate, { { "versions", versions } } ); } else { return "std::pair> const &> getExtensionDepends( std::string const & version, std::string const & extension );"; } } template std::string VulkanHppGenerator::generateExtensionReplacedBy( Predicate p, Extraction e ) const { std::string replacedBy, previousEnter, previousLeave; for ( auto const & extension : m_extensions ) { if ( p( extension ) ) { auto [enter, leave] = generateProtection( getProtectFromTitle( extension.name ) ); replacedBy += ( ( previousEnter != enter ) ? ( "\n" + previousLeave + enter ) : "\n" ) + " if ( extension == \"" + extension.name + "\" ) { return \"" + e( extension ) + "\"; }"; previousEnter = enter; previousLeave = leave; } } if ( !previousLeave.empty() ) { replacedBy += "\n" + previousLeave; } replacedBy += "\n return \"\";"; return replacedBy; } template std::string VulkanHppGenerator::generateExtensionReplacedTest( Predicate p ) const { std::string replacedTest, previousEnter, previousLeave; bool unprotectedEntry = false; for ( auto const & extension : m_extensions ) { if ( p( extension ) ) { auto [enter, leave] = generateProtection( getProtectFromTitle( extension.name ) ); unprotectedEntry |= enter.empty(); replacedTest += ( ( previousEnter != enter ) ? ( "\n" + previousLeave + enter ) : "\n" ) + "( extension == \"" + extension.name + "\" ) || "; previousEnter = enter; previousLeave = leave; } } if ( unprotectedEntry ) { assert( replacedTest.ends_with( " || " ) ); replacedTest = replacedTest.substr( 0, replacedTest.length() - 4 ); } if ( !previousLeave.empty() ) { replacedTest += "\n" + previousLeave; } if ( !unprotectedEntry ) { replacedTest += "false"; // there might be no replacements at all, so add a "false" at the end... } return replacedTest; } std::string VulkanHppGenerator::generateExtensionsList( std::string const & type ) const { std::string extensionsList, previousEnter, previousLeave; for ( auto const & extension : m_extensions ) { if ( extension.type == type ) { auto [enter, leave] = generateProtection( getProtectFromTitle( extension.name ) ); extensionsList += ( ( previousEnter != enter ) ? ( "\n" + previousLeave + enter ) : "\n" ) + "\"" + extension.name + "\", "; previousEnter = enter; previousLeave = leave; } } assert( extensionsList.ends_with( ", " ) ); extensionsList = extensionsList.substr( 0, extensionsList.length() - 2 ); if ( !previousLeave.empty() ) { extensionsList += "\n" + previousLeave; } return extensionsList; } std::string VulkanHppGenerator::generateExtensionTypeTest( std::string const & type ) const { std::string typeTest, previousEnter, previousLeave; bool first = true; for ( auto const & extension : m_extensions ) { if ( extension.type == type ) { auto [enter, leave] = generateProtection( getProtectFromTitle( extension.name ) ); typeTest += ( ( previousEnter != enter ) ? ( "\n" + previousLeave + enter ) : "\n" ) + ( first ? "" : " || " ) + "( extension == \"" + extension.name + "\" )"; previousEnter = enter; previousLeave = leave; first = false; } } if ( !previousLeave.empty() ) { typeTest += "\n" + previousLeave; } return typeTest; } std::string VulkanHppGenerator::generateFailureCheck( std::vector const & successCodes ) const { assert( !successCodes.empty() ); std::string failureCheck = "result != " + generateSuccessCode( successCodes[0] ); if ( 1 < successCodes.size() ) { failureCheck = "( " + failureCheck + " )"; for ( size_t i = 1; i < successCodes.size(); ++i ) { failureCheck += "&& ( result != " + generateSuccessCode( successCodes[i] ) + " )"; } } return failureCheck; } std::string VulkanHppGenerator::generateFormatTraits() const { if ( m_formats.empty() ) { return ""; } const std::string formatTraitsTemplate = R"( //===================== //=== Format Traits === //===================== // The three-dimensional extent of a texel block. VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 std::array blockExtent( VULKAN_HPP_NAMESPACE::Format format ) { switch( format ) { ${blockExtentCases} default: return {{1, 1, 1 }}; } } // The texel block size in bytes. VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 uint8_t blockSize( VULKAN_HPP_NAMESPACE::Format format ) { switch( format ) { ${blockSizeCases} default : VULKAN_HPP_ASSERT( false ); return 0; } } // The class of the format (can't be just named "class"!) VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 char const * compatibilityClass( VULKAN_HPP_NAMESPACE::Format format ) { switch( format ) { ${classCases} default : VULKAN_HPP_ASSERT( false ); return ""; } } // The number of bits in this component, if not compressed, otherwise 0. VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 uint8_t componentBits( VULKAN_HPP_NAMESPACE::Format format, uint8_t component ) { switch( format ) { ${componentBitsCases} default: return 0; } } // The number of components of this format. VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 uint8_t componentCount( VULKAN_HPP_NAMESPACE::Format format ) { switch( format ) { ${componentCountCases} default: return 0; } } // The name of the component VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 char const * componentName( VULKAN_HPP_NAMESPACE::Format format, uint8_t component ) { switch( format ) { ${componentNameCases} default: return ""; } } // The numeric format of the component VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 char const * componentNumericFormat( VULKAN_HPP_NAMESPACE::Format format, uint8_t component ) { switch( format ) { ${componentNumericFormatCases} default: return ""; } } // The plane this component lies in. VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 uint8_t componentPlaneIndex( VULKAN_HPP_NAMESPACE::Format format, uint8_t component ) { switch( format ) { ${componentPlaneIndexCases} default: return 0; } } // True, if the components of this format are compressed, otherwise false. VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 bool componentsAreCompressed( VULKAN_HPP_NAMESPACE::Format format ) { switch( format ) { ${componentsAreCompressedCases} return true; default: return false; } } // A textual description of the compression scheme, or an empty string if it is not compressed VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 char const * compressionScheme( VULKAN_HPP_NAMESPACE::Format format ) { switch( format ) { ${compressionSchemeCases} default: return ""; } } // True, if this format is a compressed one. VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 bool isCompressed( VULKAN_HPP_NAMESPACE::Format format ) { return ( *VULKAN_HPP_NAMESPACE::compressionScheme( format ) != 0 ); } // The number of bits into which the format is packed. A single image element in this format // can be stored in the same space as a scalar type of this bit width. VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 uint8_t packed( VULKAN_HPP_NAMESPACE::Format format ) { switch( format ) { ${packedCases} default: return 0; } } // The single-plane format that this plane is compatible with. VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 VULKAN_HPP_NAMESPACE::Format planeCompatibleFormat( VULKAN_HPP_NAMESPACE::Format format, uint8_t plane ) { switch( format ) { ${planeCompatibleCases} default: VULKAN_HPP_ASSERT( plane == 0 ); return format; } } // The number of image planes of this format. VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 uint8_t planeCount( VULKAN_HPP_NAMESPACE::Format format ) { switch( format ) { ${planeCountCases} default: return 1; } } // The relative height of this plane. A value of k means that this plane is 1/k the height of the overall format. VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 uint8_t planeHeightDivisor( VULKAN_HPP_NAMESPACE::Format format, uint8_t plane ) { switch( format ) { ${planeHeightDivisorCases} default: VULKAN_HPP_ASSERT( plane == 0 ); return 1; } } // The relative width of this plane. A value of k means that this plane is 1/k the width of the overall format. VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 uint8_t planeWidthDivisor( VULKAN_HPP_NAMESPACE::Format format, uint8_t plane ) { switch( format ) { ${planeWidthDivisorCases} default: VULKAN_HPP_ASSERT( plane == 0 ); return 1; } } // The number of texels in a texel block. VULKAN_HPP_INLINE VULKAN_HPP_CONSTEXPR_14 uint8_t texelsPerBlock( VULKAN_HPP_NAMESPACE::Format format ) { switch( format ) { ${texelsPerBlockCases} default: VULKAN_HPP_ASSERT( false ); return 0; } } )"; auto formatIt = m_enums.find( "VkFormat" ); assert( formatIt != m_enums.end() ); assert( formatIt->second.values.front().name == "VK_FORMAT_UNDEFINED" ); std::string blockSizeCases, blockExtentCases, classCases, componentBitsCases, componentCountCases, componentNameCases, componentNumericFormatCases, componentPlaneIndexCases, componentsAreCompressedCases, compressionSchemeCases, packedCases, planeCompatibleCases, planeCountCases, planeHeightDivisorCases, planeWidthDivisorCases, texelsPerBlockCases; for ( auto formatValuesIt = std::next( formatIt->second.values.begin() ); formatValuesIt != formatIt->second.values.end(); ++formatValuesIt ) { // only generate a trait for non-alias formats if ( formatValuesIt->alias.empty() ) { auto traitIt = m_formats.find( formatValuesIt->name ); assert( traitIt != m_formats.end() ); std::string caseString = " case VULKAN_HPP_NAMESPACE::Format::" + generateEnumValueName( "VkFormat", traitIt->first, false ) + ":"; blockSizeCases += caseString + " return " + traitIt->second.blockSize + ";\n"; if ( !traitIt->second.blockExtent.empty() ) { std::vector blockExtent = tokenize( traitIt->second.blockExtent, "," ); assert( blockExtent.size() == 3 ); blockExtentCases += caseString + " return {{ " + blockExtent[0] + ", " + blockExtent[1] + ", " + blockExtent[2] + " }};\n"; } classCases += caseString + " return \"" + traitIt->second.classAttribute + "\";\n"; if ( traitIt->second.components.front().bits != "compressed" ) { const std::string componentBitsCaseTemplate = R"(${caseString} switch( component ) { ${componentCases} default: VULKAN_HPP_ASSERT( false ); return 0; } )"; std::string componentCases; for ( size_t i = 0; i < traitIt->second.components.size(); ++i ) { componentCases += " case " + std::to_string( i ) + ": return " + traitIt->second.components[i].bits + ";\n"; } componentCases.pop_back(); componentBitsCases += replaceWithMap( componentBitsCaseTemplate, { { "caseString", caseString }, { "componentCases", componentCases } } ); } componentCountCases += caseString + " return " + std::to_string( traitIt->second.components.size() ) + ";\n"; { const std::string componentNameCaseTemplate = R"(${caseString} switch( component ) { ${componentCases} default: VULKAN_HPP_ASSERT( false ); return ""; } )"; std::string componentCases; for ( size_t i = 0; i < traitIt->second.components.size(); ++i ) { componentCases += " case " + std::to_string( i ) + ": return \"" + traitIt->second.components[i].name + "\";\n"; } componentCases.pop_back(); componentNameCases += replaceWithMap( componentNameCaseTemplate, { { "caseString", caseString }, { "componentCases", componentCases } } ); } { const std::string componentNumericFormatCaseTemplate = R"(${caseString} switch( component ) { ${componentCases} default: VULKAN_HPP_ASSERT( false ); return ""; } )"; std::string componentCases; for ( size_t i = 0; i < traitIt->second.components.size(); ++i ) { componentCases += " case " + std::to_string( i ) + ": return \"" + traitIt->second.components[i].numericFormat + "\";\n"; } componentCases.pop_back(); componentNumericFormatCases += replaceWithMap( componentNumericFormatCaseTemplate, { { "caseString", caseString }, { "componentCases", componentCases } } ); } if ( !traitIt->second.components.front().planeIndex.empty() ) { const std::string componentPlaneIndexCaseTemplate = R"(${caseString} switch( component ) { ${componentCases} default: VULKAN_HPP_ASSERT( false ); return 0; } )"; std::string componentCases; for ( size_t i = 0; i < traitIt->second.components.size(); ++i ) { componentCases += " case " + std::to_string( i ) + ": return " + traitIt->second.components[i].planeIndex + ";\n"; } componentCases.pop_back(); componentPlaneIndexCases += replaceWithMap( componentPlaneIndexCaseTemplate, { { "caseString", caseString }, { "componentCases", componentCases } } ); } if ( traitIt->second.components.front().bits == "compressed" ) { componentsAreCompressedCases += caseString + "\n"; } if ( !traitIt->second.compressed.empty() ) { compressionSchemeCases += caseString + " return \"" + traitIt->second.compressed + "\";\n"; } if ( !traitIt->second.packed.empty() ) { packedCases += caseString + " return " + traitIt->second.packed + ";\n"; } if ( !traitIt->second.planes.empty() ) { const std::string planeCompatibleCaseTemplate = R"(${caseString} switch( plane ) { ${compatibleCases} default: VULKAN_HPP_ASSERT( false ); return VULKAN_HPP_NAMESPACE::Format::eUndefined; } )"; const std::string planeHeightDivisorCaseTemplate = R"(${caseString} switch( plane ) { ${heightDivisorCases} default: VULKAN_HPP_ASSERT( false ); return 1; } )"; const std::string planeWidthDivisorCaseTemplate = R"(${caseString} switch( plane ) { ${widthDivisorCases} default: VULKAN_HPP_ASSERT( false ); return 1; } )"; std::string compatibleCases, heightDivisorCases, widthDivisorCases; for ( size_t i = 0; i < traitIt->second.planes.size(); ++i ) { compatibleCases += " case " + std::to_string( i ) + ": return VULKAN_HPP_NAMESPACE::Format::" + generateEnumValueName( "VkFormat", traitIt->second.planes[i].compatible, false ) + ";\n"; heightDivisorCases += " case " + std::to_string( i ) + ": return " + traitIt->second.planes[i].heightDivisor + ";\n"; widthDivisorCases += " case " + std::to_string( i ) + ": return " + traitIt->second.planes[i].widthDivisor + ";\n"; } compatibleCases.pop_back(); heightDivisorCases.pop_back(); widthDivisorCases.pop_back(); planeCompatibleCases += replaceWithMap( planeCompatibleCaseTemplate, { { "caseString", caseString }, { "compatibleCases", compatibleCases } } ); planeCountCases += caseString + " return " + std::to_string( traitIt->second.planes.size() ) + ";\n"; planeHeightDivisorCases += replaceWithMap( planeHeightDivisorCaseTemplate, { { "caseString", caseString }, { "heightDivisorCases", heightDivisorCases } } ); planeWidthDivisorCases += replaceWithMap( planeWidthDivisorCaseTemplate, { { "caseString", caseString }, { "widthDivisorCases", widthDivisorCases } } ); } texelsPerBlockCases += caseString + " return " + traitIt->second.texelsPerBlock + ";\n"; } } return replaceWithMap( formatTraitsTemplate, { { "blockExtentCases", blockExtentCases }, { "blockSizeCases", blockSizeCases }, { "classCases", classCases }, { "componentBitsCases", componentBitsCases }, { "componentCountCases", componentCountCases }, { "componentNameCases", componentNameCases }, { "componentNumericFormatCases", componentNumericFormatCases }, { "componentPlaneIndexCases", componentPlaneIndexCases }, { "componentsAreCompressedCases", componentsAreCompressedCases }, { "compressionSchemeCases", compressionSchemeCases }, { "packedCases", packedCases }, { "planeCompatibleCases", planeCompatibleCases }, { "planeCountCases", planeCountCases }, { "planeHeightDivisorCases", planeHeightDivisorCases }, { "planeWidthDivisorCases", planeWidthDivisorCases }, { "texelsPerBlockCases", texelsPerBlockCases } } ); } std::string VulkanHppGenerator::generateFunctionPointerCheck( std::string const & function, std::set const & requiredBy ) const { std::string functionPointerCheck; if ( !requiredBy.empty() ) { std::string message = "Function <" + function + "> requires <" + *requiredBy.begin() + ">"; for ( auto it = std::next( requiredBy.begin() ); it != requiredBy.end(); ++it ) { message += " or <" + *it + ">"; } functionPointerCheck = "VULKAN_HPP_ASSERT( getDispatcher()->" + function + " && \"" + message + "\" );"; } return functionPointerCheck; } std::string VulkanHppGenerator::generateHandle( std::pair const & handleData, std::set & listedHandles ) const { assert( !listedHandles.contains( handleData.first ) ); // 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 { // 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 { using Type = VULKAN_HPP_NAMESPACE::${className}; }; )"; cppType = replaceWithMap( cppTypeFromDebugReportObjectTypeEXTTemplate, { { "className", className } } ); debugReportObjectType = generateEnumValueName( enumIt->first, valueIt->name, false ); } auto [enter, leave] = generateProtection( getProtectFromType( handleData.first ) ); 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; auto aliasIt = findAlias( handleData.first, m_handleAliases ); if ( aliasIt != m_handleAliases.end() ) { usingAlias += " using " + stripPrefix( aliasIt->first, "Vk" ) + " = " + stripPrefix( handleData.first, "Vk" ) + ";\n"; } const std::string typesafeExplicitKeyword = handleData.second.isDispatchable ? "" : "VULKAN_HPP_TYPESAFE_EXPLICIT "; const std::string typesafeConversionConditional = handleData.second.isDispatchable ? "" : "#if defined(VULKAN_HPP_TYPESAFE_CONVERSION)\n"; const std::string typesafeConversionConditionalEnd = handleData.second.isDispatchable ? "" : "#endif\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 {} ${typesafeExplicitKeyword}${className}( Vk${className} ${memberName} ) VULKAN_HPP_NOEXCEPT : m_${memberName}( ${memberName} ) {} ${typesafeConversionConditional} ${className} & operator=(Vk${className} ${memberName}) VULKAN_HPP_NOEXCEPT { m_${memberName} = ${memberName}; return *this; } ${typesafeConversionConditionalEnd} ${className} & operator=( std::nullptr_t ) VULKAN_HPP_NOEXCEPT { m_${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} ${typesafeExplicitKeyword}operator Vk${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_${memberName} = {}; }; template <> struct CppType { using Type = VULKAN_HPP_NAMESPACE::${className}; }; ${CppType} template <> struct isVulkanHandleType { 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 ) }, { "usingAlias", usingAlias }, { "typesafeExplicitKeyword", typesafeExplicitKeyword }, { "typesafeConversionConditional", typesafeConversionConditional }, { "typesafeConversionConditionalEnd", typesafeConversionConditionalEnd } } ); } listedHandles.insert( handleData.first ); return str; } std::string VulkanHppGenerator::generateHandleCommandDeclarations( std::set const & commands ) const { std::string str; std::set listedCommands; // some commands are listed with more than one extension! for ( auto const & feature : m_features ) { std::vector commandNames = selectCommandsByHandle( feature.requireData, commands, listedCommands ); if ( !commandNames.empty() ) { str += "\n //=== " + feature.name + " ===\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, false ); str += generateDestroyCommand( commandIt->first, commandIt->second ); } } } for ( auto const & extension : m_extensions ) { std::vector commandNames = selectCommandsByHandle( extension.requireData, commands, listedCommands ); if ( !commandNames.empty() ) { auto [enter, leave] = generateProtection( getProtectFromTitle( extension.name ) ); str += "\n" + enter + " //=== " + extension.name + " ===\n"; for ( auto const & command : commandNames ) { auto const & commandData = getCommandData( command ); std::string commandString; std::string commandName = generateCommandName( command, commandData.params, 1 ); str += "\n"; str += generateCommand( command, commandData, 1, false, false ); str += generateDestroyCommand( command, commandData ); } str += leave; } } return str; } std::string VulkanHppGenerator::generateHandleDependencies( std::pair const & handleData, std::set & listedHandles ) const { std::string str; for ( auto const & command : handleData.second.commands ) { auto const & commandData = getCommandData( command ); for ( auto const & parameter : commandData.params ) { auto handleIt = m_handles.find( parameter.type.type ); if ( ( handleIt != m_handles.end() ) && ( parameter.type.type != handleData.first ) && !listedHandles.contains( parameter.type.type ) ) { str += generateHandle( *handleIt, listedHandles ); } } } return str; } std::string VulkanHppGenerator::generateHandleEmpty( HandleData const & handleData ) const { std::string str; std::set listedCommands; // some commands are listed with more than one extension ! for ( auto const & feature : m_features ) { std::vector commands = selectCommandsByHandle( feature.requireData, handleData.commands, listedCommands ); if ( !commands.empty() ) { str += "\n //=== " + feature.name + " ===\n"; for ( auto const & command : commands ) { auto commandIt = m_commands.find( command ); assert( commandIt != m_commands.end() ); str += "\n" + generateCommand( commandIt->first, commandIt->second, 0, false, false ); } } } #if !defined( NDEBUG ) for ( auto const & extension : m_extensions ) { assert( selectCommandsByHandle( extension.requireData, handleData.commands, listedCommands ).empty() ); } #endif return str; } std::string VulkanHppGenerator::generateHandleForwardDeclarations() const { const std::string fowardDeclarationsTemplate = R"( //=================================== //=== HANDLE forward declarations === //=================================== ${forwardDeclarations} )"; std::string forwardDeclarations; for ( auto const & feature : m_features ) { forwardDeclarations += generateHandleForwardDeclarations( feature.requireData, feature.name ); } for ( auto const & extension : m_extensions ) { forwardDeclarations += generateHandleForwardDeclarations( extension.requireData, extension.name ); } return replaceWithMap( fowardDeclarationsTemplate, { { "forwardDeclarations", forwardDeclarations } } ); } std::string VulkanHppGenerator::generateHandleForwardDeclarations( std::vector const & requireData, std::string const & title ) const { std::string str; for ( auto const & require : requireData ) { for ( auto const & type : require.types ) { auto handleIt = m_handles.find( type ); if ( handleIt != m_handles.end() ) { str += "class " + stripPrefix( handleIt->first, "Vk" ) + ";\n"; } } } return addTitleAndProtection( title, str ); } std::string VulkanHppGenerator::generateHandleHashStructures( std::vector const & requireData, std::string const & title ) const { const std::string hashTemplate = R"( template <> struct hash { std::size_t operator()(VULKAN_HPP_NAMESPACE::${type} const & ${name}) const VULKAN_HPP_NOEXCEPT { return std::hash{}(static_cast(${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::generateHandleHashStructures() const { const std::string hashesTemplate = R"( //=================================== //=== HASH structures for handles === //=================================== ${hashes} )"; std::string hashes; for ( auto const & feature : m_features ) { hashes += generateHandleHashStructures( feature.requireData, feature.name ); } for ( auto const & extension : m_extensions ) { hashes += generateHandleHashStructures( extension.requireData, extension.name ); } return replaceWithMap( hashesTemplate, { { "hashes", hashes } } ); } std::string VulkanHppGenerator::generateHandles() const { // Note: reordering structs or handles by features and extensions is not possible! std::string str = R"( //=============== //=== HANDLEs === //=============== template struct isVulkanHandleType { static VULKAN_HPP_CONST_OR_CONSTEXPR bool value = false; }; )"; std::set listedHandles; str += generateHandle( *m_handles.begin(), listedHandles ); // artificial handle without a name! for ( auto handleIt = std::next( m_handles.begin() ); handleIt != m_handles.end(); ++handleIt ) { if ( !listedHandles.contains( handleIt->first ) && isTypeUsed( handleIt->first ) ) { str += generateHandle( *handleIt, listedHandles ); } } return str; } std::string VulkanHppGenerator::generateIndexTypeTraits() const { const std::string indexTypeTraitsTemplate = R"( //========================= //=== Index Type Traits === //========================= template struct IndexTypeValue {}; ${indexTypeTraits} )"; auto indexType = m_enums.find( "VkIndexType" ); assert( indexType != m_enums.end() ); std::string indexTypeTraits; for ( auto const & value : indexType->second.values ) { assert( value.name.starts_with( "VK_INDEX_TYPE_UINT" ) || value.name.starts_with( "VK_INDEX_TYPE_NONE" ) ); if ( value.alias.empty() && value.name.starts_with( "VK_INDEX_TYPE_UINT" ) ) { std::string valueName = generateEnumValueName( indexType->first, value.name, false ); assert( valueName.starts_with( "eUint" ) ); auto beginDigit = valueName.begin() + strlen( "eUint" ); assert( isdigit( *beginDigit ) ); auto endDigit = std::find_if( beginDigit, valueName.end(), []( std::string::value_type c ) { return !isdigit( c ); } ); std::string cppType = "uint" + valueName.substr( strlen( "eUint" ), endDigit - beginDigit ) + "_t"; // from type to enum value const std::string typeToEnumTemplate = R"( template <> struct IndexTypeValue<${cppType}> { static VULKAN_HPP_CONST_OR_CONSTEXPR IndexType value = IndexType::${valueName}; }; )"; indexTypeTraits += replaceWithMap( typeToEnumTemplate, { { "cppType", cppType }, { "valueName", valueName } } ); // from enum value to type const std::string enumToTypeTemplate = R"( template <> struct CppType { using Type = ${cppType}; }; )"; indexTypeTraits += replaceWithMap( enumToTypeTemplate, { { "cppType", cppType }, { "valueName", valueName } } ); } } return replaceWithMap( indexTypeTraitsTemplate, { { "indexTypeTraits", indexTypeTraits } } ); } std::string VulkanHppGenerator::generateLenInitializer( std::vector::const_iterator mit, std::map::const_iterator, std::vector::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->lenExpressions.front() == litit->first->name ) || ( ( arrayIt->lenExpressions.front() == "codeSize / 4" ) && ( litit->first->name == "codeSize" ) ) ); assert( arrayIt->name.starts_with( "p" ) ); std::string argumentName = startLowerCase( stripPrefix( arrayIt->name, "p" ) ) + "_"; assert( mit->type.prefix.empty() && mit->type.postfix.empty() ); initializer = argumentName + ".size()"; if ( arrayIt->lenExpressions.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::string VulkanHppGenerator::generateNoExcept( std::vector const & errorCodes, std::vector const & returnParams, std::map const & vectorParams, CommandFlavourFlags flavourFlags, bool vectorSizeCheck, bool raii ) const { // noexcept is only possible with no error codes, and the return param (if any) is not a vector param (unless it's the singular version) return ( errorCodes.empty() && ( ( flavourFlags & CommandFlavourFlagBits::singular ) || returnParams.empty() || std::none_of( returnParams.begin(), returnParams.end(), [&vectorParams]( size_t rp ) { return vectorParams.contains( rp ); } ) ) ) ? ( vectorSizeCheck ? ( raii ? "" : " VULKAN_HPP_NOEXCEPT_WHEN_NO_EXCEPTIONS" ) : " VULKAN_HPP_NOEXCEPT" ) : ""; } std::string VulkanHppGenerator::generateObjectDeleter( std::string const & commandName, CommandData const & commandData, size_t initialSkipCount, size_t returnParam ) const { std::string objectDeleter, allocator; if ( ( commandName.find( "Acquire" ) != std::string::npos ) || ( commandName.find( "Get" ) != std::string::npos ) ) { if ( ( commandName == "vkAcquirePerformanceConfigurationINTEL" ) || ( commandName == "vkGetRandROutputDisplayEXT" ) || ( commandName == "vkGetWinrtDisplayNV" ) || ( commandName == "vkGetDrmDisplayEXT" ) ) { objectDeleter = "ObjectRelease"; } else { throw std::runtime_error( "Found " + commandName + " which requires special handling for the object deleter" ); } } else if ( commandName.find( "Allocate" ) != std::string::npos ) { objectDeleter = "ObjectFree"; allocator = "allocator, "; } else { assert( ( commandName.find( "Create" ) != std::string::npos ) || ( commandName.find( "Register" ) != std::string::npos ) ); objectDeleter = "ObjectDestroy"; allocator = "allocator, "; } std::string className = initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : ""; std::string parentName = ( className.empty() || ( commandData.params[returnParam].type.type == "VkDevice" ) ) ? "NoParent" : className; return objectDeleter + "<" + parentName + ", Dispatch>( " + ( ( parentName == "NoParent" ) ? "" : "*this, " ) + allocator + "d )"; } std::pair VulkanHppGenerator::generateProtection( std::string const & protect, bool defined ) const { auto const openProtect = defined ? "#if defined( " : "#if !defined( "; return protect.empty() ? std::make_pair( "", "" ) : std::make_pair( openProtect + protect + " )\n", "#endif /*" + protect + "*/\n" ); } std::string VulkanHppGenerator::generateRAIICommandDefinitions() const { const std::string commandDefinitionsTemplate = R"( //=========================== //=== COMMAND Definitions === //=========================== ${commandDefinitions} )"; std::string commandDefinitions; std::set listedCommands; // some commands are listed with more than one extension! for ( auto const & feature : m_features ) { commandDefinitions += generateRAIICommandDefinitions( feature.requireData, listedCommands, feature.name ); } for ( auto const & extension : m_extensions ) { commandDefinitions += generateRAIICommandDefinitions( extension.requireData, listedCommands, extension.name ); } return replaceWithMap( commandDefinitionsTemplate, { { "commandDefinitions", commandDefinitions } } ); } std::string VulkanHppGenerator::generateRAIICommandDefinitions( std::vector const & requireData, std::set & listedCommands, std::string const & title ) const { std::string str; for ( auto const & require : requireData ) { for ( auto const & command : require.commands ) { if ( listedCommands.insert( command ).second ) { str += generateRAIIHandleCommand( command, determineInitialSkipCount( command ), true ); } } } return addTitleAndProtection( title, str ); } std::string VulkanHppGenerator::generateRAIIDispatchers() const { std::string contextInitializers, contextMembers, deviceAssignments, deviceMembers, instanceAssignments, instanceMembers; std::set listedCommands; for ( auto const & feature : m_features ) { appendRAIIDispatcherCommands( feature.requireData, listedCommands, feature.name, contextInitializers, contextMembers, deviceAssignments, deviceMembers, instanceAssignments, instanceMembers ); } for ( auto const & extension : m_extensions ) { appendRAIIDispatcherCommands( extension.requireData, listedCommands, extension.name, contextInitializers, contextMembers, deviceAssignments, deviceMembers, instanceAssignments, instanceMembers ); } std::string contextDispatcherTemplate = R"( class ContextDispatcher : public DispatchLoaderBase { public: ContextDispatcher( PFN_vkGetInstanceProcAddr getProcAddr ) : vkGetInstanceProcAddr( getProcAddr )${contextInitializers} {} public: PFN_vkGetInstanceProcAddr vkGetInstanceProcAddr = 0; ${contextMembers} }; )"; std::string str = replaceWithMap( contextDispatcherTemplate, { { "contextInitializers", contextInitializers }, { "contextMembers", contextMembers } } ); std::string instanceDispatcherTemplate = R"( class InstanceDispatcher : public DispatchLoaderBase { public: InstanceDispatcher( PFN_vkGetInstanceProcAddr getProcAddr, VkInstance instance ) : vkGetInstanceProcAddr( getProcAddr ) { ${instanceAssignments} vkGetDeviceProcAddr = PFN_vkGetDeviceProcAddr( vkGetInstanceProcAddr( instance, "vkGetDeviceProcAddr" ) ); } public: ${instanceMembers} PFN_vkGetDeviceProcAddr vkGetDeviceProcAddr = 0; }; )"; str += replaceWithMap( instanceDispatcherTemplate, { { "instanceAssignments", instanceAssignments }, { "instanceMembers", instanceMembers } } ); std::string deviceDispatcherTemplate = R"( class DeviceDispatcher : public DispatchLoaderBase { public: DeviceDispatcher( PFN_vkGetDeviceProcAddr getProcAddr, VkDevice device ) : vkGetDeviceProcAddr( getProcAddr ) { ${deviceAssignments} } public: ${deviceMembers} }; )"; str += replaceWithMap( deviceDispatcherTemplate, { { "deviceAssignments", deviceAssignments }, { "deviceMembers", deviceMembers } } ); return str; } std::string VulkanHppGenerator::generateRAIIHandle( std::pair const & handle, std::set & listedHandles, std::set const & specialFunctions ) const { std::string str; if ( !listedHandles.contains( handle.first ) ) { rescheduleRAIIHandle( str, handle, listedHandles, specialFunctions ); auto [enter, leave] = generateProtection( getProtectFromType( handle.first ) ); std::string handleType = stripPrefix( handle.first, "Vk" ); std::string handleName = generateRAIIHandleConstructorParamName( handle.first, handle.second.destructorIt ); auto [singularConstructors, arrayConstructors] = generateRAIIHandleConstructors( handle ); auto [clearMembers, getConstructorSuccessCode, memberVariables, moveConstructorInitializerList, moveAssignmentInstructions, swapMembers, releaseMembers] = generateRAIIHandleDetails( handle ); std::string declarations = generateRAIIHandleCommandDeclarations( handle, specialFunctions ); assert( !handle.second.objTypeEnum.empty() ); auto enumIt = m_enums.find( "VkObjectType" ); assert( enumIt != m_enums.end() ); auto valueIt = std::find_if( enumIt->second.values.begin(), enumIt->second.values.end(), [&handle]( EnumValueData const & evd ) { return evd.name == handle.second.objTypeEnum; } ); assert( valueIt != enumIt->second.values.end() ); std::string objTypeEnum = generateEnumValueName( enumIt->first, valueIt->name, false ); 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 ) : "eUnknown"; std::string dispatcherType = ( ( handle.first == "VkDevice" ) || ( handle.second.constructorIts.front()->second.params.front().type.type == "VkDevice" ) ) ? "VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::DeviceDispatcher" : "VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::InstanceDispatcher"; std::string getParent; if ( ( handle.first != "VkInstance" ) && ( handle.first != "VkDevice" ) && ( handle.second.destructorIt != m_commands.end() ) ) { assert( !handle.second.destructorIt->second.params.empty() ); std::string parentType = stripPrefix( handle.second.destructorIt->second.params.front().type.type, "Vk" ); getParent = " VULKAN_HPP_NAMESPACE::" + parentType + " get" + parentType + "() const\n"; getParent += " {\n"; getParent += " return m_" + handle.second.destructorIt->second.params.front().name + ";\n"; getParent += " }\n"; } std::string assignmentOperator, copyConstructor; if ( handle.second.destructorIt == m_commands.end() ) { // allow copy constructor and assignment operator for classes without destructor std::string const copyConstructorTemplate = R"( ${handleType}( ${handleType} const & rhs ) : m_${handleName}( rhs.m_${handleName} ), m_dispatcher( rhs.m_dispatcher ) {})"; copyConstructor += replaceWithMap( copyConstructorTemplate, { { "handleName", handleName }, { "handleType", handleType } } ); std::string assignmentOperatorTemplate = R"( ${handleType} & operator=( ${handleType} const & rhs ) { m_${handleName} = rhs.m_${handleName}; m_dispatcher = rhs.m_dispatcher; return *this; })"; assignmentOperator += replaceWithMap( assignmentOperatorTemplate, { { "handleName", handleName }, { "handleType", handleType } } ); } else { std::string const copyConstructorTemplate = R"( ${handleType}( ${handleType} const & ) = delete;)"; copyConstructor += replaceWithMap( copyConstructorTemplate, { { "handleType", handleType } } ); std::string const assignmentOperatorTemplate = R"( ${handleType} & operator=( ${handleType} const & ) = delete;)"; assignmentOperator += replaceWithMap( assignmentOperatorTemplate, { { "handleType", handleType } } ); } const std::string handleTemplate = R"( ${enter} class ${handleType} { public: using CType = Vk${handleType}; static VULKAN_HPP_CONST_OR_CONSTEXPR VULKAN_HPP_NAMESPACE::ObjectType objectType = VULKAN_HPP_NAMESPACE::ObjectType::${objTypeEnum}; static VULKAN_HPP_CONST_OR_CONSTEXPR VULKAN_HPP_NAMESPACE::DebugReportObjectTypeEXT debugReportObjectType = VULKAN_HPP_NAMESPACE::DebugReportObjectTypeEXT::${debugReportObjectType}; public: ${singularConstructors} ${handleType}( std::nullptr_t ) {} ~${handleType}() { clear(); } ${handleType}() = delete; ${copyConstructor} ${handleType}( ${handleType} && rhs ) VULKAN_HPP_NOEXCEPT : ${moveConstructorInitializerList} {} ${assignmentOperator} ${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}; } void clear() VULKAN_HPP_NOEXCEPT { ${clearMembers} } VULKAN_HPP_NAMESPACE::${handleType} release() { ${releaseMembers} } ${getConstructorSuccessCode} ${getParent} ${dispatcherType} const * getDispatcher() const { VULKAN_HPP_ASSERT( m_dispatcher->getVkHeaderVersion() == VK_HEADER_VERSION ); return ${getDispatcherReturn}m_dispatcher; } void swap( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::${handleType} & rhs ) VULKAN_HPP_NOEXCEPT { ${swapMembers} } ${memberFunctionsDeclarations} private: ${memberVariables} }; ${leave})"; str += replaceWithMap( handleTemplate, { { "assignmentOperator", assignmentOperator }, { "clearMembers", clearMembers }, { "copyConstructor", copyConstructor }, { "debugReportObjectType", debugReportObjectType }, { "dispatcherType", dispatcherType }, { "enter", enter }, { "getConstructorSuccessCode", getConstructorSuccessCode }, { "getDispatcherReturn", ( handleType == "Device" ) || ( handleType == "Instance" ) ? "&*" : "" }, { "getParent", getParent }, { "handleName", handleName }, { "handleType", handleType }, { "leave", leave }, { "memberFunctionsDeclarations", declarations }, { "memberVariables", memberVariables }, { "moveAssignmentInstructions", moveAssignmentInstructions }, { "moveConstructorInitializerList", moveConstructorInitializerList }, { "objTypeEnum", objTypeEnum }, { "releaseMembers", releaseMembers }, { "singularConstructors", singularConstructors }, { "swapMembers", swapMembers } } ); 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 { public: ${arrayConstructors} ${handleType}s( std::nullptr_t ) {} ${handleType}s() = delete; ${handleType}s( ${handleType}s const & ) = delete; ${handleType}s( ${handleType}s && rhs ) = default; ${handleType}s & operator=( ${handleType}s const & ) = delete; ${handleType}s & operator=( ${handleType}s && rhs ) = default; }; ${leave} )"; str += replaceWithMap( handlesTemplate, { { "arrayConstructors", arrayConstructors }, { "enter", enter }, { "handleType", handleType }, { "leave", leave } } ); } } return str; } std::string VulkanHppGenerator::generateRAIIHandleCommand( std::string const & command, size_t initialSkipCount, bool definition ) const { std::string str; if ( !m_RAIISpecialFunctions.contains( command ) ) { str = generateCommand( command, getCommandData( command ), initialSkipCount, definition, true ); } return str; } std::string VulkanHppGenerator::generateRAIIHandleCommandDeclarations( std::pair const & handle, std::set const & specialFunctions ) const { std::string functionDeclarations; std::set listedCommands; // some commands are listed with more than one extension ! for ( auto const & feature : m_features ) { std::vector firstLevelCommands, secondLevelCommands; for ( auto const & require : feature.requireData ) { for ( auto const & command : require.commands ) { if ( !specialFunctions.contains( command ) ) { if ( handle.second.commands.contains( command ) ) { assert( !listedCommands.contains( command ) ); listedCommands.insert( command ); firstLevelCommands.push_back( command ); } else if ( handle.second.secondLevelCommands.contains( command ) ) { assert( !listedCommands.contains( command ) ); listedCommands.insert( command ); assert( !handle.first.empty() ); secondLevelCommands.push_back( command ); } } } } if ( !firstLevelCommands.empty() || !secondLevelCommands.empty() ) { functionDeclarations += "\n //=== " + feature.name + " ===\n"; for ( auto const & command : firstLevelCommands ) { functionDeclarations += generateRAIIHandleCommand( command, handle.first.empty() ? 0 : 1, false ); } for ( auto const & command : secondLevelCommands ) { assert( !handle.first.empty() ); functionDeclarations += generateRAIIHandleCommand( command, 2, false ); } } } for ( auto const & extension : m_extensions ) { std::vector firstLevelCommands, secondLevelCommands; for ( auto & req : extension.requireData ) { for ( auto const & command : req.commands ) { if ( !specialFunctions.contains( command ) && !listedCommands.contains( command ) ) { if ( handle.second.commands.contains( command ) ) { listedCommands.insert( command ); firstLevelCommands.push_back( command ); } else if ( handle.second.secondLevelCommands.contains( command ) ) { listedCommands.insert( command ); secondLevelCommands.push_back( command ); } } } } if ( !firstLevelCommands.empty() || !secondLevelCommands.empty() ) { std::string handleProtect = getProtectFromType( handle.first ); std::string titleProtect = getProtectFromTitle( extension.name ); std::string enter, leave; if ( !titleProtect.empty() && ( titleProtect != handleProtect ) ) { std::tie( enter, leave ) = generateProtection( titleProtect ); } functionDeclarations += "\n" + enter + " //=== " + extension.name + " ===\n"; for ( auto const & command : firstLevelCommands ) { functionDeclarations += generateRAIIHandleCommand( command, handle.first.empty() ? 0 : 1, false ); } for ( auto const & command : secondLevelCommands ) { assert( !handle.first.empty() ); functionDeclarations += generateRAIIHandleCommand( command, 2, false ); } functionDeclarations += leave; } } return functionDeclarations; } std::string VulkanHppGenerator::generateRAIIHandleCommandEnhanced( std::string const & name, CommandData const & commandData, size_t initialSkipCount, std::vector const & returnParams, std::map const & vectorParams, bool definition, CommandFlavourFlags flavourFlags ) const { bool singular = flavourFlags & CommandFlavourFlagBits::singular; std::set skippedParams = determineSkippedParams( commandData.params, initialSkipCount, vectorParams, returnParams, singular ); std::set singularParams = singular ? determineSingularParams( returnParams[0], vectorParams ) : std::set(); // special handling for vkGetMemoryHostPointerPropertiesEXT: here, we really need to stick with the const void * parameter ! std::set templatedParams = ( name == "vkGetMemoryHostPointerPropertiesEXT" ) ? std::set() : determineVoidPointerParams( commandData.params ); std::vector chainedReturnParams = ( flavourFlags & CommandFlavourFlagBits::chained ) ? determineChainedReturnParams( commandData.params, returnParams ) : std::vector(); assert( chainedReturnParams.size() <= 1 ); bool enumerating = determineEnumeration( vectorParams, returnParams ); std::vector dataTypes = determineDataTypes( commandData.params, vectorParams, returnParams, templatedParams ); std::string dataType = combineDataTypes( vectorParams, returnParams, enumerating, dataTypes, flavourFlags, true ); std::string argumentTemplates = generateArgumentTemplates( commandData.params, returnParams, vectorParams, templatedParams, chainedReturnParams, true ); std::string argumentList = generateArgumentListEnhanced( commandData.params, returnParams, vectorParams, skippedParams, singularParams, templatedParams, chainedReturnParams, definition, flavourFlags, false ); std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, flavourFlags ); std::string nodiscard = generateNoDiscard( !returnParams.empty() || ( ( commandData.returnType != "VkResult" ) && ( commandData.returnType != "void" ) ), 1 < commandData.successCodes.size(), false ); std::pair>> vectorSizeCheck = needsVectorSizeCheck( commandData.params, vectorParams, returnParams, singularParams, skippedParams ); std::string noexceptString = generateNoExcept( commandData.errorCodes, returnParams, vectorParams, flavourFlags, vectorSizeCheck.first, true ); std::string returnType = generateReturnType( commandData, returnParams, vectorParams, flavourFlags, true, dataTypes ); if ( definition ) { std::string const definitionTemplate = R"( ${argumentTemplates} ${nodiscard} VULKAN_HPP_INLINE ${returnType} ${className}::${commandName}( ${argumentList} ) const ${noexcept} { ${functionPointerCheck} ${vectorSizeCheck} ${dataSizeChecks} ${dataDeclarations} ${callSequence} ${resultCheck} ${dataPreparation} ${returnStatement} } )"; std::string callSequence = generateCallSequence( name, commandData, returnParams, vectorParams, initialSkipCount, singularParams, templatedParams, chainedReturnParams, flavourFlags, true ); std::string className = initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "Context"; std::string returnVariable = generateReturnVariable( commandData, returnParams, vectorParams, flavourFlags ); std::string dataDeclarations = generateDataDeclarations( commandData, returnParams, vectorParams, templatedParams, flavourFlags, true, dataTypes, dataType, returnType, returnVariable ); std::string dataPreparation = generateDataPreparation( commandData, initialSkipCount, returnParams, vectorParams, templatedParams, flavourFlags, enumerating ); std::string dataSizeChecks = generateDataSizeChecks( commandData, returnParams, dataTypes, vectorParams, templatedParams, singular ); std::string resultCheck = generateResultCheck( commandData, className, "::", commandName, enumerating ); std::string returnStatement = generateReturnStatement( name, commandData, returnVariable, returnType, dataType, initialSkipCount, returnParams.empty() ? INVALID_INDEX : returnParams[0], flavourFlags, enumerating, true ); std::string vectorSizeCheckString = vectorSizeCheck.first ? generateRAIIHandleVectorSizeCheck( name, commandData, initialSkipCount, vectorSizeCheck.second, skippedParams ) : ""; return replaceWithMap( definitionTemplate, { { "argumentList", argumentList }, { "argumentTemplates", argumentTemplates }, { "callSequence", callSequence }, { "className", className }, { "commandName", commandName }, { "dataDeclarations", dataDeclarations }, { "dataPreparation", dataPreparation }, { "dataSizeChecks", dataSizeChecks }, { "functionPointerCheck", generateFunctionPointerCheck( name, commandData.requiredBy ) }, { "nodiscard", nodiscard }, { "noexcept", noexceptString }, { "resultCheck", resultCheck }, { "returnStatement", returnStatement }, { "returnType", returnType }, { "vectorSizeCheck", vectorSizeCheckString } } ); } else { std::string const declarationTemplate = R"( ${argumentTemplates} ${nodiscard} ${returnType} ${commandName}( ${argumentList} ) const ${noexcept}; )"; return replaceWithMap( declarationTemplate, { { "argumentList", argumentList }, { "argumentTemplates", argumentTemplates }, { "commandName", commandName }, { "nodiscard", nodiscard }, { "noexcept", noexceptString }, { "returnType", returnType } } ); } } std::string VulkanHppGenerator::generateRAIIHandleCommandFactory( std::string const & name, CommandData const & commandData, size_t initialSkipCount, std::vector const & returnParams, std::map const & vectorParams, bool definition, CommandFlavourFlags flavourFlags ) const { bool singular = flavourFlags & CommandFlavourFlagBits::singular; assert( isHandleType( commandData.params[returnParams.back()].type.type ) ); assert( ( returnParams.size() == 1 ) || ( ( returnParams.size() == 2 ) && ( vectorParams.size() == 1 ) && ( returnParams[0] == vectorParams.begin()->second.lenParam ) && ( returnParams[1] == vectorParams.begin()->first ) ) ); std::set skippedParams = determineSkippedParams( commandData.params, initialSkipCount, vectorParams, returnParams, singular ); std::set singularParams = singular ? determineSingularParams( returnParams.back(), vectorParams ) : std::set(); std::string argumentList = generateRAIIHandleCommandFactoryArgumentList( commandData.params, skippedParams, definition, singular ); std::string commandName = generateCommandName( name, commandData.params, initialSkipCount, flavourFlags ); std::string handleType = stripPostfix( commandData.params[returnParams.back()].type.compose( "VULKAN_HPP_RAII_NAMESPACE" ), " *" ); std::string returnType = handleType; if ( vectorParams.contains( returnParams.back() ) && !singular ) { returnType = "std::vector<" + handleType + ">"; handleType += "s"; } if ( definition ) { std::string callArguments = generateCallArgumentsRAIIFactory( commandData.params, initialSkipCount, skippedParams, singularParams ); std::string className = initialSkipCount ? stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ) : "Context"; std::string const definitionTemplate = R"( VULKAN_HPP_NODISCARD VULKAN_HPP_INLINE ${returnType} ${className}::${commandName}( ${argumentList} ) const { return ${handleType}( ${callArguments} ); } )"; return replaceWithMap( definitionTemplate, { { "argumentList", argumentList }, { "callArguments", callArguments }, { "className", className }, { "commandName", commandName }, { "handleType", handleType }, { "returnType", returnType } } ); } else { std::string const declarationTemplate = R"( VULKAN_HPP_NODISCARD ${returnType} ${commandName}( ${argumentList} ) const; )"; return replaceWithMap( declarationTemplate, { { "argumentList", argumentList }, { "commandName", commandName }, { "returnType", returnType } } ); } } std::string VulkanHppGenerator::generateRAIIHandleCommandFactoryArgumentList( std::vector const & params, std::set const & skippedParams, bool definition, bool singular ) const { std::string arguments; bool encounteredArgument = false; for ( size_t i = 0; i < params.size(); ++i ) { if ( !skippedParams.contains( i ) ) { if ( encounteredArgument ) { arguments += ", "; } arguments += generateRAIIHandleConstructorArgument( params[i], definition, singular, false ); encounteredArgument = true; } } return arguments; } std::pair VulkanHppGenerator::generateRAIIHandleConstructor( std::pair const & handle, std::map::const_iterator constructorIt, std::string const & enter, std::string const & leave ) const { std::string singularConstructor, arrayConstructor; if ( constructorIt->second.returnType == "VkResult" ) { std::tie( singularConstructor, arrayConstructor ) = generateRAIIHandleConstructorResult( handle, constructorIt, enter, leave ); } else if ( constructorIt->second.returnType == "void" ) { std::tie( singularConstructor, arrayConstructor ) = generateRAIIHandleConstructorVoid( handle, constructorIt, enter, leave ); } if ( singularConstructor.empty() && arrayConstructor.empty() ) { throw std::runtime_error( "Never encountered a function like <" + constructorIt->first + "> !" ); } return std::make_pair( singularConstructor, arrayConstructor ); } std::pair VulkanHppGenerator::generateRAIIHandleConstructor1Return2Vector( std::pair const & handle, std::map::const_iterator constructorIt, std::string const & enter, std::string const & leave, size_t returnParam, std::map const & vectorParams ) const { if ( returnParam == std::next( vectorParams.begin() )->first ) { if ( vectorParams.begin()->second.lenParam == std::next( vectorParams.begin() )->second.lenParam ) { if ( constructorIt->second.params[vectorParams.begin()->second.lenParam].type.type == "uint32_t" ) { if ( ( constructorIt->second.params[vectorParams.begin()->first].type.type != "void" ) && !isHandleType( constructorIt->second.params[vectorParams.begin()->first].type.type ) ) { std::string singularConstructor; auto lenParamIt = constructorIt->second.params.begin() + vectorParams.begin()->second.lenParam; auto handleParamIt = constructorIt->second.params.begin() + std::next( vectorParams.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 VulkanHppGenerator::generateRAIIHandleConstructors( std::pair const & handle ) const { auto [enter, leave] = generateProtection( getProtectFromType( handle.first ) ); std::string singularConstructors, arrayConstructors; for ( auto constructorIt : handle.second.constructorIts ) { // there is a non-const parameter with handle type : the to-be-constructed handle // check for additional enter/leave guards for the constructors auto [constructorEnter, constructorLeave] = generateProtection( getProtectFromTitles( constructorIt->second.requiredBy ) ); if ( constructorEnter == enter ) { constructorEnter.clear(); constructorLeave.clear(); } auto [singularConstructor, arrayConstructor] = generateRAIIHandleConstructor( handle, constructorIt, constructorEnter, constructorLeave ); arrayConstructors += arrayConstructor; singularConstructors += singularConstructor; } singularConstructors += generateRAIIHandleConstructorTakeOwnership( handle ); return std::make_pair( singularConstructors, arrayConstructors ); } std::string VulkanHppGenerator::generateRAIIHandleConstructorArgument( ParamData const & param, bool definition, bool singular, bool takesOwnership ) const { std::string argument; if ( param.type.isConstPointer() ) { assert( param.type.type.starts_with( "Vk" ) ); assert( param.name.starts_with( "p" ) ); std::string argumentName = startLowerCase( stripPrefix( param.name, "p" ) ); std::string argumentType = generateNamespacedType( param.type.type ); if ( param.optional ) { assert( param.lenExpression.empty() ); argument = "VULKAN_HPP_NAMESPACE::Optional " + argumentName + ( definition ? "" : " = nullptr" ); } else if ( param.lenExpression.empty() ) { argument = argumentType + " const & " + argumentName; } else if ( singular ) { argument = argumentType + " const & " + stripPluralS( argumentName ); } else { argument = "VULKAN_HPP_NAMESPACE::ArrayProxy<" + argumentType + "> const & " + argumentName; } } else if ( specialPointerTypes.contains( param.type.type ) ) { assert( !param.optional ); assert( param.type.isNonConstPointer() ); argument = param.type.type + " & " + param.name; } else if ( ( param.type.isValue() ) && isHandleType( param.type.type ) ) { if ( takesOwnership ) { assert( !param.optional ); argument = param.type.type + " " + param.name; } else { argument = "VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::" + stripPrefix( param.type.type, "Vk" ); if ( param.optional ) { argument = "VULKAN_HPP_NAMESPACE::Optional"; } argument += " const & " + param.name; } } else { assert( !param.optional ); if ( param.arraySizes.empty() ) { argument = param.type.compose( "VULKAN_HPP_NAMESPACE" ) + " "; } else { argument = generateStandardArray( param.type.compose( "VULKAN_HPP_NAMESPACE" ), param.arraySizes ) + " const & "; } argument += param.name; } return argument; } std::string VulkanHppGenerator::generateRAIIHandleConstructorArguments( std::pair const & handle, std::map::const_iterator constructorIt, bool singular, bool takesOwnership ) const { auto [parentType, parentName] = getParentTypeAndName( handle ); std::string arguments = "VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::" + parentType + " const & " + parentName; if ( takesOwnership ) { arguments += ", " + handle.first + " " + generateRAIIHandleConstructorParamName( handle.first, handle.second.destructorIt ); } if ( constructorIt != m_commands.end() ) { parentType = "Vk" + parentType; bool skip = skipLeadingGrandParent( handle ); for ( size_t i = skip ? 1 : 0; i < constructorIt->second.params.size(); i++ ) { ParamData const & param = constructorIt->second.params[i]; // filter parent and handle type if ( ( param.type.type != parentType ) && ( param.type.type != handle.first ) ) { // the specialPointerTypes are considered const-pointers! if ( param.type.isNonConstPointer() && !specialPointerTypes.contains( param.type.type ) ) { // this is supposed to be the returned size on an enumeration function! #if !defined( NDEBUG ) assert( param.type.type == "uint32_t" ); auto typeIt = std::find_if( constructorIt->second.params.begin(), constructorIt->second.params.end(), [&handle]( ParamData const & pd ) { return pd.type.type == handle.first; } ); assert( typeIt != constructorIt->second.params.end() ); assert( typeIt->lenExpression == param.name ); #endif continue; } else if ( std::any_of( constructorIt->second.params.begin(), constructorIt->second.params.end(), [¶m]( ParamData const & pd ) { return pd.lenExpression == param.name; } ) ) { // 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.lenExpression.empty() && !param.optional ); continue; } arguments += ", " + generateRAIIHandleConstructorArgument( param, false, singular, takesOwnership ); } } } return arguments; } std::string VulkanHppGenerator::generateRAIIHandleConstructorCallArguments( std::pair const & handle, std::map::const_iterator constructorIt, bool nonConstPointerAsNullptr, std::set const & singularParams, bool allocatorIsMemberVariable ) const { std::string arguments; bool encounteredArgument = false; size_t i = 0; if ( skipLeadingGrandParent( handle ) ) { assert( ( 1 < constructorIt->second.params.size() ) && m_handles.contains( constructorIt->second.params[0].type.type ) && m_handles.contains( constructorIt->second.params[1].type.type ) ); arguments += "static_cast<" + constructorIt->second.params[0].type.type + ">( " + constructorIt->second.params[1].name + ".get" + stripPrefix( constructorIt->second.params[0].type.type, "Vk" ) + "() )"; encounteredArgument = true; i = 1; } for ( ; i < constructorIt->second.params.size(); ++i ) { ParamData const & param = constructorIt->second.params[i]; if ( encounteredArgument ) { arguments += ", "; } if ( param.type.type == handle.first ) { assert( param.type.isNonConstPointer() && param.arraySizes.empty() ); if ( param.lenExpression.empty() || !singularParams.empty() ) { assert( !param.optional ); assert( singularParams.empty() || ( param.lenExpression == constructorIt->second.params[*singularParams.begin()].name ) ); std::string paramName = generateRAIIHandleConstructorParamName( handle.first, handle.second.destructorIt ); arguments += "reinterpret_cast<" + handle.first + "*>( &m_" + paramName + " )"; } else if ( nonConstPointerAsNullptr ) { arguments += "nullptr"; } else { arguments += startLowerCase( stripPrefix( param.name, "p" ) ) + ".data()"; } } else if ( param.type.type == "VkAllocationCallbacks" ) { assert( param.optional ); if ( allocatorIsMemberVariable ) { arguments += "reinterpret_cast( m_allocator )"; } else { arguments += "reinterpret_cast(static_cast( allocator ) )"; } } else if ( m_handles.contains( param.type.type ) ) { assert( param.type.isValue() && param.arraySizes.empty() && param.lenExpression.empty() ); if ( param.optional ) { arguments += param.name + " ? static_cast<" + param.type.type + ">( **" + param.name + " ) : 0"; } else { arguments += "static_cast<" + param.type.type + ">( *" + param.name + " )"; } } else { assert( !param.optional ); arguments += generateCallArgumentEnhanced( constructorIt->second.params, i, nonConstPointerAsNullptr, singularParams, {} ); } encounteredArgument = true; } return arguments; } std::string VulkanHppGenerator::generateRAIIHandleConstructorEnumerate( std::pair const & handle, std::map::const_iterator constructorIt, std::vector::const_iterator handleParamIt, std::vector::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} ${counterName}; VULKAN_HPP_NAMESPACE::Result result; do { result = static_cast( dispatcher->${constructorCall}( ${firstCallArguments} ) ); if ( ( result == VULKAN_HPP_NAMESPACE::Result::eSuccess ) && ${counterName} ) { ${vectorName}.resize( ${counterName} ); result = static_cast( dispatcher->${constructorCall}( ${secondCallArguments} ) ); } } while ( result == VULKAN_HPP_NAMESPACE::Result::eIncomplete ); if ( result == VULKAN_HPP_NAMESPACE::Result::eSuccess ) { VULKAN_HPP_ASSERT( ${counterName} <= ${vectorName}.size() ); this->reserve( ${counterName} ); for ( auto const & ${handleName} : ${vectorName} ) { this->emplace_back( ${parentName}, ${handleConstructorArguments} ); } } else { detail::throwResultException( result, "${constructorCall}" ); } } ${leave})"; return replaceWithMap( constructorTemplate, { { "constructorArguments", generateRAIIHandleConstructorArguments( handle, constructorIt, false, false ) }, { "constructorCall", constructorIt->first }, { "counterName", startLowerCase( stripPrefix( lenParamIt->name, "p" ) ) }, { "counterType", lenParamIt->type.type }, { "dispatcherType", dispatcherType }, { "enter", enter }, { "firstCallArguments", generateRAIIHandleConstructorCallArguments( handle, constructorIt, true, {}, true ) }, { "handleConstructorArguments", handleConstructorArguments }, { "handleName", startLowerCase( handleType ) }, { "handleType", handleType }, { "leave", leave }, { "parentName", constructorIt->second.params.front().name }, { "secondCallArguments", generateRAIIHandleConstructorCallArguments( handle, constructorIt, false, {}, true ) }, { "vectorElementType", handleParamIt->type.type }, { "vectorName", startLowerCase( stripPrefix( handleParamIt->name, "p" ) ) } } ); } std::string VulkanHppGenerator::generateRAIIHandleConstructorInitializationList( std::pair const & handle, std::map::const_iterator constructorIt, std::map::const_iterator destructorIt, bool takesOwnership ) const { auto [parentType, parentName] = getParentTypeAndName( handle ); std::string handleName = generateRAIIHandleConstructorParamName( handle.first, destructorIt ); std::string initializationList; if ( destructorIt != m_commands.end() ) { for ( auto destructorParam : destructorIt->second.params ) { if ( destructorParam.type.type == "Vk" + parentType ) { initializationList += "m_" + parentName + "( *" + parentName + " ), "; } else if ( destructorParam.type.type == handle.first ) { if ( takesOwnership ) { initializationList += "m_" + handleName + "( " + handleName + " ), "; } } else if ( destructorParam.type.type == "VkAllocationCallbacks" ) { assert( destructorParam.type.isConstPointer() && destructorParam.arraySizes.empty() && destructorParam.lenExpression.empty() && destructorParam.optional ); initializationList += "m_allocator( static_cast( allocator ) ), "; } else if ( isHandleType( destructorParam.type.type ) ) { assert( destructorParam.type.isValue() && destructorParam.arraySizes.empty() && destructorParam.lenExpression.empty() && !destructorParam.optional ); initializationList += "m_" + destructorParam.name + "( "; auto constructorParamIt = std::find_if( constructorIt->second.params.begin(), constructorIt->second.params.end(), [&destructorParam]( ParamData const & pd ) { return pd.type.type == destructorParam.type.type; } ); if ( constructorParamIt != constructorIt->second.params.end() ) { assert( constructorParamIt->type.isValue() && constructorParamIt->arraySizes.empty() && constructorParamIt->lenExpression.empty() && !constructorParamIt->optional ); if ( constructorParamIt->type.type == "Vk" + parentType ) { initializationList += "*"; } initializationList += constructorParamIt->name; } else { #if !defined( NDEBUG ) bool found = false; #endif for ( auto constructorParam : constructorIt->second.params ) { auto structureIt = m_structs.find( constructorParam.type.type ); if ( structureIt != m_structs.end() ) { auto structureMemberIt = findStructMemberItByType( destructorParam.type.type, structureIt->second.members ); if ( structureMemberIt != structureIt->second.members.end() ) { assert( constructorParam.type.isConstPointer() && constructorParam.arraySizes.empty() && constructorParam.lenExpression.empty() && !constructorParam.optional ); initializationList += startLowerCase( stripPrefix( constructorParam.name, "p" ) ) + "." + structureMemberIt->name; #if !defined( NDEBUG ) found = true; #endif break; } } } assert( found ); } initializationList += " ), "; } else { // we can ignore all other parameters here ! } } } else { if ( !handle.second.secondLevelCommands.empty() ) { assert( !handle.second.constructorIts.empty() ); #if !defined( NDEBUG ) auto constructorCommandIt = m_commands.find( handle.second.constructorIts.front()->first ); #endif assert( ( constructorCommandIt != m_commands.end() ) && ( 1 < constructorCommandIt->second.params.size() ) ); assert( std::next( constructorCommandIt->second.params.begin() )->type.type == "Vk" + parentType ); auto commandIt = m_commands.find( *handle.second.secondLevelCommands.begin() ); assert( ( commandIt != m_commands.end() ) && ( 1 < commandIt->second.params.size() ) ); assert( commandIt->second.params.front().type.type == constructorCommandIt->second.params.front().type.type ); assert( std::next( commandIt->second.params.begin() )->type.type == handle.first ); std::string grandParentType = stripPrefix( commandIt->second.params.front().type.type, "Vk" ); initializationList += "m_" + startLowerCase( grandParentType ) + "( " + parentName + ".get" + grandParentType + "() ), "; } if ( takesOwnership ) { initializationList += "m_" + handleName + "( " + handleName + " ), "; } } return initializationList.empty() ? initializationList : initializationList.substr( 0, initializationList.size() - 2 ); } std::string VulkanHppGenerator::generateRAIIHandleConstructorParamName( std::string const & type, std::map::const_iterator destructorIt ) const { if ( destructorIt != m_commands.end() ) { auto destructorParamIt = std::find_if( destructorIt->second.params.begin(), destructorIt->second.params.end(), [&type]( ParamData const & destructorParam ) { return destructorParam.type.type == type; } ); if ( destructorParamIt != destructorIt->second.params.end() ) { assert( std::none_of( std::next( destructorParamIt ), destructorIt->second.params.end(), [&type]( ParamData const & destructorParam ) { return destructorParam.type.type == type; } ) ); if ( !destructorParamIt->type.isValue() ) { return startLowerCase( stripPrefix( stripPluralS( destructorParamIt->name ), "p" ) ); } else { return destructorParamIt->name; } } } return startLowerCase( stripPrefix( type, "Vk" ) ); } std::pair VulkanHppGenerator::generateRAIIHandleConstructorResult( std::pair const & handle, std::map::const_iterator constructorIt, std::string const & enter, std::string const & leave ) const { assert( !constructorIt->second.successCodes.empty() ); assert( constructorIt->second.successCodes[0] == "VK_SUCCESS" ); switch ( constructorIt->second.successCodes.size() ) { case 1: if ( !constructorIt->second.errorCodes.empty() ) { std::vector returnParams = determineReturnParams( constructorIt->second.params ); if ( returnParams.size() == 1 ) { assert( isHandleType( constructorIt->second.params[returnParams[0]].type.type ) ); std::map vectorParams = determineVectorParams( constructorIt->second.params ); switch ( vectorParams.size() ) { case 0: return std::make_pair( generateRAIIHandleConstructorResultSingleSuccessWithErrors1Return0Vector( handle, constructorIt, enter, leave ), "" ); case 1: if ( returnParams[0] == vectorParams.begin()->first ) { if ( isLenByStructMember( constructorIt->second.params[vectorParams.begin()->first].lenExpression, constructorIt->second.params[vectorParams.begin()->second.lenParam] ) ) { auto handleParamIt = constructorIt->second.params.begin() + returnParams[0]; return std::make_pair( "", generateRAIIHandleConstructorVector( handle, constructorIt, handleParamIt, enter, leave ) ); } } break; case 2: return generateRAIIHandleConstructor1Return2Vector( handle, constructorIt, enter, leave, returnParams[0], vectorParams ); } } } break; case 2: if ( !constructorIt->second.errorCodes.empty() ) { std::vector returnParams = determineReturnParams( constructorIt->second.params ); switch ( returnParams.size() ) { case 1: assert( isHandleType( constructorIt->second.params[returnParams[0]].type.type ) ); { std::map vectorParams = determineVectorParams( constructorIt->second.params ); if ( vectorParams.size() == 2 ) { return generateRAIIHandleConstructor1Return2Vector( handle, constructorIt, enter, leave, returnParams[0], vectorParams ); } } break; case 2: if ( constructorIt->second.params[returnParams[0]].type.type == "uint32_t" ) { assert( isHandleType( constructorIt->second.params[returnParams[1]].type.type ) ); std::map vectorParams = determineVectorParams( constructorIt->second.params ); if ( vectorParams.size() == 1 ) { if ( returnParams[0] == vectorParams.begin()->second.lenParam ) { assert( returnParams[1] == vectorParams.begin()->first ); assert( constructorIt->second.successCodes[1] == "VK_INCOMPLETE" ); auto lenParamIt = constructorIt->second.params.begin() + returnParams[0]; auto handleParamIt = constructorIt->second.params.begin() + returnParams[1]; return std::make_pair( "", generateRAIIHandleConstructorEnumerate( handle, constructorIt, handleParamIt, lenParamIt, enter, leave ) ); } } } break; } } break; case 4: if ( !constructorIt->second.errorCodes.empty() ) { std::vector returnParams = determineReturnParams( constructorIt->second.params ); if ( returnParams.size() == 1 ) { assert( isHandleType( constructorIt->second.params[returnParams[0]].type.type ) ); std::map vectorParams = determineVectorParams( constructorIt->second.params ); if ( vectorParams.size() == 2 ) { return generateRAIIHandleConstructor1Return2Vector( handle, constructorIt, enter, leave, returnParams[0], vectorParams ); } } } break; } return std::make_pair( "", "" ); } std::string VulkanHppGenerator::generateRAIIHandleConstructorResultSingleSuccessWithErrors1Return0Vector( std::pair const & handle, std::map::const_iterator constructorIt, std::string const & enter, std::string const & leave ) const { auto [parentType, parentName] = getParentTypeAndName( handle ); std::string getDispatcher = parentName + ".getDispatcher()"; std::string dispatcherInitializer, dispatcherInit; if ( ( handle.first != "VkInstance" ) && ( handle.first != "VkDevice" ) ) { dispatcherInitializer = "m_dispatcher( " + getDispatcher + " )"; } else { std::string handleType = stripPrefix( handle.first, "Vk" ); dispatcherInit = "\n m_dispatcher.reset( new VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::" + handleType + "Dispatcher( " + parentName + ".getDispatcher()->vkGet" + handleType + "ProcAddr, static_cast<" + handle.first + ">( m_" + startLowerCase( handleType ) + " ) ) );"; } std::string constructorArguments = generateRAIIHandleConstructorArguments( handle, constructorIt, false, false ); std::string callArguments = generateRAIIHandleConstructorCallArguments( handle, constructorIt, false, {}, handle.second.destructorIt != m_commands.end() ); std::string initializationList = generateRAIIHandleConstructorInitializationList( handle, constructorIt, handle.second.destructorIt, false ); if ( !initializationList.empty() && !dispatcherInitializer.empty() ) { initializationList += ", "; } const std::string constructorTemplate = R"( ${enter} ${handleType}( ${constructorArguments} ) : ${initializationList}${dispatcherInitializer} { VULKAN_HPP_NAMESPACE::Result result = static_cast( ${getDispatcher}->${constructorCall}( ${callArguments} ) ); if ( ${failureCheck} ) { detail::throwResultException( result, "${constructorCall}" ); }${dispatcherInit} } ${leave})"; return replaceWithMap( constructorTemplate, { { "callArguments", callArguments }, { "constructorArguments", constructorArguments }, { "constructorCall", constructorIt->first }, { "dispatcherInitializer", dispatcherInitializer }, { "dispatcherInit", dispatcherInit }, { "enter", enter }, { "failureCheck", generateFailureCheck( constructorIt->second.successCodes ) }, { "getDispatcher", getDispatcher }, { "leave", leave }, { "handleType", stripPrefix( handle.first, "Vk" ) }, { "initializationList", initializationList } } ); } std::string VulkanHppGenerator::generateRAIIHandleConstructorTakeOwnership( std::pair const & handle ) const { std::string handleType = stripPrefix( handle.first, "Vk" ); std::string handleName = startLowerCase( handleType ); auto [parentType, parentName] = getParentTypeAndName( handle ); std::string constructorArguments = generateRAIIHandleConstructorArguments( handle, handle.second.destructorIt, false, true ); std::string initializationList = generateRAIIHandleConstructorInitializationList( handle, handle.second.destructorIt, handle.second.destructorIt, true ); assert( !handle.second.constructorIts.empty() ); if ( 1 < handle.second.constructorIts[0]->second.successCodes.size() && ( handle.second.constructorIts[0]->second.successCodes[1] != "VK_INCOMPLETE" ) ) { #if !defined( NDEBUG ) for ( size_t i = 1; i < handle.second.constructorIts.size(); ++i ) { assert( 1 < handle.second.constructorIts[i]->second.successCodes.size() ); } #endif constructorArguments += ", VULKAN_HPP_NAMESPACE::Result successCode = VULKAN_HPP_NAMESPACE::Result::eSuccess"; if ( isMultiSuccessCodeConstructor( handle.second.constructorIts ) ) { initializationList += ", m_constructorSuccessCode( successCode )"; } } std::string dispatcherInitializer; if ( ( handle.first != "VkInstance" ) && ( handle.first != "VkDevice" ) ) { dispatcherInitializer = "m_dispatcher( " + parentName + ".getDispatcher() )"; } if ( !initializationList.empty() && !dispatcherInitializer.empty() ) { initializationList += ", "; } std::string dispatcherInit; if ( ( handle.first == "VkDevice" ) || ( handle.first == "VkInstance" ) ) { dispatcherInit = "\n m_dispatcher.reset( new VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::" + handleType + "Dispatcher( " + parentName + ".getDispatcher()->vkGet" + handleType + "ProcAddr, static_cast<" + handle.first + ">( m_" + startLowerCase( handleType ) + " ) ) );"; } const std::string constructorTemplate = R"( ${handleType}( ${constructorArguments} ) : ${initializationList}${dispatcherInitializer} {${dispatcherInit}} )"; return replaceWithMap( constructorTemplate, { { "constructorArguments", constructorArguments }, { "dispatcherInitializer", dispatcherInitializer }, { "dispatcherInit", dispatcherInit }, { "handleType", handleType }, { "initializationList", initializationList } } ); } std::string VulkanHppGenerator::generateRAIIHandleConstructorVector( std::pair const & handle, std::map::const_iterator constructorIt, std::vector::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->lenExpression; } ); if ( lenIt == constructorIt->second.params.end() ) { std::vector lenParts = tokenize( handleParamIt->lenExpression, "->" ); 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_structs.find( lenIt->type.type ); assert( structureIt != m_structs.end() ); assert( isStructMember( lenParts[1], structureIt->second.members ) ); 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.lenExpression == 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}( ${vectorSize} ); VULKAN_HPP_NAMESPACE::Result result = static_cast( dispatcher->${constructorCall}( ${callArguments} ) ); if ( ${successCheck} ) { this->reserve( ${vectorSize} ); for ( auto const & ${handleName} : ${vectorName} ) { this->emplace_back( ${parentName}, ${handleConstructorArguments}${successCodePassToElement} ); } } else { detail::throwResultException( result, "${constructorCall}" ); } } ${leave})"; return replaceWithMap( constructorTemplate, { { "callArguments", generateRAIIHandleConstructorCallArguments( handle, constructorIt, false, {}, false ) }, { "constructorArguments", generateRAIIHandleConstructorArguments( handle, constructorIt, false, false ) }, { "constructorCall", constructorIt->first }, { "enter", enter }, { "handleConstructorArguments", handleConstructorArguments }, { "handleName", startLowerCase( handleType ) }, { "handleType", handleType }, { "leave", leave }, { "parentName", constructorIt->second.params.front().name }, { "successCheck", generateSuccessCheck( constructorIt->second.successCodes ) }, { "successCodePassToElement", successCodePassToElement }, { "vectorElementType", handleParamIt->type.type }, { "vectorName", startLowerCase( stripPrefix( handleParamIt->name, "p" ) ) }, { "vectorSize", vectorSize } } ); } std::string VulkanHppGenerator::generateRAIIHandleConstructorVectorSingular( std::pair const & handle, std::map::const_iterator constructorIt, std::vector::const_iterator handleParamIt, std::string const & enter, std::string const & leave ) const { size_t returnParam = static_cast( std::distance( constructorIt->second.params.begin(), handleParamIt ) ); std::map vectorParams = determineVectorParams( constructorIt->second.params ); std::set singularParams = determineSingularParams( returnParam, vectorParams ); std::string callArguments = generateRAIIHandleConstructorCallArguments( handle, constructorIt, false, singularParams, true ); std::string initializationList = generateRAIIHandleConstructorInitializationList( handle, constructorIt, handle.second.destructorIt, false ); assert( !initializationList.empty() ); std::string resultVariable = "VULKAN_HPP_NAMESPACE::Result result"; std::string failureCheck = generateFailureCheck( constructorIt->second.successCodes ); std::string result = "result"; if ( isMultiSuccessCodeConstructor( handle.second.constructorIts ) ) { resultVariable = "m_constructorSuccessCode"; failureCheck = std::regex_replace( failureCheck, std::regex( "result" ), "m_constructorSuccessCode" ); result = "m_constructorSuccessCode"; } const std::string singularConstructorTemplate = R"( ${enter} ${handleType}( ${constructorArguments} ) : ${initializationList}, m_dispatcher( ${firstArgument}.getDispatcher() ) { ${resultVariable} = static_cast( getDispatcher()->${constructorCall}( ${callArguments} ) ); if ( ${failureCheck} ) { detail::throwResultException( ${result}, "${constructorCall}" ); } } ${leave})"; return replaceWithMap( singularConstructorTemplate, { { "initializationList", initializationList }, { "callArguments", callArguments }, { "constructorArguments", generateRAIIHandleConstructorArguments( handle, constructorIt, true, false ) }, { "constructorCall", constructorIt->first }, { "enter", enter }, { "firstArgument", constructorIt->second.params[0].name }, { "failureCheck", failureCheck }, { "leave", leave }, { "handleType", stripPrefix( handle.first, "Vk" ) }, { "result", result }, { "resultVariable", resultVariable } } ); } std::pair VulkanHppGenerator::generateRAIIHandleConstructorVoid( std::pair const & handle, std::map::const_iterator constructorIt, std::string const & enter, std::string const & leave ) const { assert( constructorIt->second.successCodes.empty() && constructorIt->second.errorCodes.empty() ); std::vector returnParams = determineReturnParams( constructorIt->second.params ); if ( returnParams.size() == 1 ) { assert( isHandleType( constructorIt->second.params[returnParams[0]].type.type ) ); std::map vectorParams = determineVectorParams( constructorIt->second.params ); if ( vectorParams.empty() ) { return std::make_pair( generateRAIIHandleConstructorVoid1Return0Vector( handle, constructorIt, enter, leave ), "" ); } } return std::make_pair( "", "" ); } std::string VulkanHppGenerator::generateRAIIHandleConstructorVoid1Return0Vector( std::pair const & handle, std::map::const_iterator constructorIt, std::string const & enter, std::string const & leave ) const { std::string callArguments = generateRAIIHandleConstructorCallArguments( handle, constructorIt, false, {}, true ); std::string constructorArguments = generateRAIIHandleConstructorArguments( handle, constructorIt, false, false ); std::string initializationList = generateRAIIHandleConstructorInitializationList( handle, constructorIt, handle.second.destructorIt, false ); if ( !initializationList.empty() ) { initializationList += ", "; } const std::string constructorTemplate = R"( ${enter} ${handleType}( ${constructorArguments} ) : ${initializationList}m_dispatcher( ${firstArgument}.getDispatcher() ) { getDispatcher()->${constructorCall}( ${callArguments} ); } ${leave})"; return replaceWithMap( constructorTemplate, { { "callArguments", callArguments }, { "constructorArguments", constructorArguments }, { "constructorCall", constructorIt->first }, { "enter", enter }, { "firstArgument", constructorIt->second.params[0].name }, { "leave", leave }, { "handleType", stripPrefix( handle.first, "Vk" ) }, { "initializationList", initializationList } } ); } std::string VulkanHppGenerator::generateRAIIHandleContext( std::pair const & handle, std::set const & specialFunctions ) const { const std::string contextTemplate = R"( class Context { public: #if VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL Context() : m_dispatcher( new VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::ContextDispatcher( m_dynamicLoader.getProcAddress( "vkGetInstanceProcAddr" ) ) ) #else Context( PFN_vkGetInstanceProcAddr getInstanceProcAddr ) : m_dispatcher( new VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::ContextDispatcher( getInstanceProcAddr ) ) #endif {} ~Context() = default; Context( Context const & ) = delete; Context( Context && rhs ) VULKAN_HPP_NOEXCEPT #if VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL : m_dynamicLoader( std::move( rhs.m_dynamicLoader ) ) , m_dispatcher( rhs.m_dispatcher.release() ) #else : m_dispatcher( rhs.m_dispatcher.release() ) #endif {} Context & operator=( Context const & ) = delete; Context & operator=( Context && rhs ) VULKAN_HPP_NOEXCEPT { if ( this != &rhs ) { #if VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL m_dynamicLoader = std::move( rhs.m_dynamicLoader ); #endif m_dispatcher.reset( rhs.m_dispatcher.release() ); } return *this; } VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::ContextDispatcher const * getDispatcher() const { VULKAN_HPP_ASSERT( m_dispatcher->getVkHeaderVersion() == VK_HEADER_VERSION ); return &*m_dispatcher; } void swap( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::Context & rhs ) { #if VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL std::swap( m_dynamicLoader, rhs.m_dynamicLoader ); #endif m_dispatcher.swap( rhs.m_dispatcher ); } ${memberFunctionDeclarations} private: #if VULKAN_HPP_ENABLE_DYNAMIC_LOADER_TOOL VULKAN_HPP_NAMESPACE::DynamicLoader m_dynamicLoader; #endif std::unique_ptr m_dispatcher; }; )"; return replaceWithMap( contextTemplate, { { "memberFunctionDeclarations", generateRAIIHandleCommandDeclarations( handle, specialFunctions ) } } ); } std::string VulkanHppGenerator::generateRAIIHandleDestructorCallArguments( std::string const & handleType, std::map::const_iterator destructorIt ) const { std::string arguments; bool encounteredArgument = false; for ( auto param : destructorIt->second.params ) { if ( encounteredArgument ) { arguments += ", "; } if ( param.type.type == handleType ) { std::string handleName = param.name; if ( param.type.isValue() ) { arguments += "static_cast<" + handleType + ">( m_" + handleName + " )"; } else { arguments += "reinterpret_cast<" + handleType + " const *>( &m_" + stripPluralS( startLowerCase( stripPrefix( handleName, "p" ) ) ) + " )"; } } else if ( param.type.type == "VkAllocationCallbacks" ) { // vk::AllocationCallbacks is stored as a member of the handle class arguments += "reinterpret_cast( m_allocator )"; } else if ( isHandleType( param.type.type ) ) { assert( param.arraySizes.empty() ); std::string argument = "m_" + param.name; if ( param.type.isValue() ) { arguments += "static_cast<" + param.type.type + ">( " + argument + " )"; } else { assert( param.type.isConstPointer() ); assert( !param.lenExpression.empty() && std::any_of( destructorIt->second.params.begin(), destructorIt->second.params.end(), [¶m]( ParamData const & pd ) { return pd.name == param.lenExpression; } ) ); arguments += "reinterpret_cast<" + param.type.type + " const *>( &" + argument + " )"; } } else { assert( ( param.type.type == "uint32_t" ) && param.type.isValue() && param.arraySizes.empty() && param.lenExpression.empty() && !param.optional ); assert( std::any_of( destructorIt->second.params.begin(), destructorIt->second.params.end(), [¶m]( ParamData const & pd ) { return pd.lenExpression == param.name; } ) ); arguments += "1"; } encounteredArgument = true; } return arguments; } std::tuple VulkanHppGenerator::generateRAIIHandleDetails( std::pair const & handle ) const { std::string getConstructorSuccessCode; bool multiSuccessCodeContructor = isMultiSuccessCodeConstructor( handle.second.constructorIts ); if ( multiSuccessCodeContructor ) { getConstructorSuccessCode = R"( VULKAN_HPP_NAMESPACE::Result getConstructorSuccessCode() const { return m_constructorSuccessCode; } )"; } auto [parentType, parentName] = getParentTypeAndName( handle ); std::string handleName = generateRAIIHandleConstructorParamName( handle.first, handle.second.destructorIt ); std::string clearMembers, moveConstructorInitializerList, moveAssignmentInstructions, memberVariables, swapMembers, releaseMembers; if ( handle.second.destructorIt != m_commands.end() ) { clearMembers = " if ( m_" + handleName + " )\n"; clearMembers += " {\n"; clearMembers += " getDispatcher()->" + handle.second.destructorIt->first + "( " + generateRAIIHandleDestructorCallArguments( handle.first, handle.second.destructorIt ) + " );\n"; clearMembers += " }"; for ( auto const & destructorParam : handle.second.destructorIt->second.params ) { std::string memberName, memberType; if ( destructorParam.type.type == "Vk" + parentType ) { memberName = parentName; memberType = "VULKAN_HPP_NAMESPACE::" + parentType; } else if ( destructorParam.type.type == handle.first ) { memberName = handleName; memberType = generateNamespacedType( handle.first ); } else if ( std::none_of( handle.second.destructorIt->second.params.begin(), handle.second.destructorIt->second.params.end(), [&destructorParam]( ParamData const & pd ) { return pd.lenExpression == destructorParam.name; } ) ) { std::string name = destructorParam.name; if ( !destructorParam.type.isValue() ) { name = startLowerCase( stripPrefix( name, "p" ) ); } memberName = name; memberType = destructorParam.type.compose( "VULKAN_HPP_NAMESPACE" ); } if ( !memberName.empty() ) { clearMembers += "\n m_" + memberName + " = nullptr;"; moveConstructorInitializerList += "m_" + memberName + "( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" + memberName + ", {} ) ), "; moveAssignmentInstructions += "\n std::swap( m_" + memberName + ", rhs.m_" + memberName + " );"; memberVariables += "\n " + memberType + " m_" + memberName + " = {};"; swapMembers += "\n std::swap( m_" + memberName + ", rhs.m_" + memberName + " );"; if ( destructorParam.type.type != handle.first ) { releaseMembers += "\n m_" + memberName + " = nullptr;"; } } } } else { if ( !handle.second.secondLevelCommands.empty() ) { assert( !handle.second.constructorIts.empty() ); assert( !handle.second.constructorIts.front()->second.params.empty() ); auto const & frontType = handle.second.constructorIts.front()->second.params.front().type.type; assert( isHandleType( frontType ) ); #if !defined( NDEBUG ) auto handleIt = m_handles.find( "Vk" + parentType ); #endif assert( handleIt != m_handles.end() ); assert( handleIt->second.parent == frontType ); std::string frontName = handle.second.constructorIts.front()->second.params.front().name; clearMembers += "\n m_" + frontName + " = nullptr;"; moveConstructorInitializerList = "m_" + frontName + "( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" + frontName + ", {} ) ), "; moveAssignmentInstructions = "\n std::swap( m_" + frontName + ", rhs.m_" + frontName + " );"; memberVariables = "\n VULKAN_HPP_NAMESPACE::" + stripPrefix( frontType, "Vk" ) + " m_" + frontName + " = {};"; swapMembers = "\n std::swap( m_" + frontName + ", rhs.m_" + frontName + " );"; releaseMembers += "\n m_" + frontName + " = nullptr;"; } clearMembers += "\n m_" + handleName + " = nullptr;"; moveConstructorInitializerList += "m_" + handleName + "( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_" + handleName + ", {} ) ), "; moveAssignmentInstructions += "\n std::swap( m_" + handleName + ", rhs.m_" + handleName + " );"; memberVariables += "\n " + generateNamespacedType( handle.first ) + " m_" + handleName + " = {};"; swapMembers += "\n std::swap( m_" + handleName + ", rhs.m_" + handleName + " );"; } if ( multiSuccessCodeContructor ) { clearMembers += "\n m_constructorSuccessCode = VULKAN_HPP_NAMESPACE::Result::eErrorUnknown;"; memberVariables += "\n VULKAN_HPP_NAMESPACE::Result m_constructorSuccessCode = VULKAN_HPP_NAMESPACE::Result::eErrorUnknown;"; swapMembers += "\n std::swap( m_constructorSuccessCode, rhs.m_constructorSuccessCode );"; moveConstructorInitializerList += "m_constructorSuccessCode( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_constructorSuccessCode, {} ) ), "; moveAssignmentInstructions += "\n std::swap( m_constructorSuccessCode, rhs.m_constructorSuccessCode );"; releaseMembers += "\n m_constructorSuccessCode = VULKAN_HPP_NAMESPACE::Result::eErrorUnknown;"; } if ( handle.first == "VkInstance" ) { memberVariables += "\n std::unique_ptr m_dispatcher;"; } else if ( handle.first == "VkDevice" ) { memberVariables += "\n std::unique_ptr m_dispatcher;"; } else if ( handle.second.constructorIts.front()->second.params.front().type.type == "VkDevice" ) { memberVariables += "\n VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::DeviceDispatcher const * m_dispatcher = nullptr;"; } else { memberVariables += "\n VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::InstanceDispatcher const * m_dispatcher = nullptr;"; } clearMembers += "\n m_dispatcher = nullptr;"; swapMembers += "\n std::swap( m_dispatcher, rhs.m_dispatcher );"; releaseMembers += "\n m_dispatcher = nullptr;"; releaseMembers += "\n return VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( m_" + handleName + ", nullptr );"; if ( ( handle.first == "VkInstance" ) || ( handle.first == "VkDevice" ) ) { moveConstructorInitializerList += "m_dispatcher( rhs.m_dispatcher.release() )"; } else { moveConstructorInitializerList += "m_dispatcher( VULKAN_HPP_NAMESPACE::VULKAN_HPP_RAII_NAMESPACE::exchange( rhs.m_dispatcher, nullptr ) )"; } moveAssignmentInstructions += "\n std::swap( m_dispatcher, rhs.m_dispatcher );"; return std::make_tuple( clearMembers, getConstructorSuccessCode, memberVariables, moveConstructorInitializerList, moveAssignmentInstructions, swapMembers, releaseMembers ); } std::string VulkanHppGenerator::generateRAIIHandleForwardDeclarations( std::vector const & requireData, std::string const & title ) const { std::string str; for ( auto const & require : requireData ) { for ( auto const & type : require.types ) { auto handleIt = m_handles.find( type ); if ( handleIt != m_handles.end() ) { str += " class " + stripPrefix( handleIt->first, "Vk" ) + ";\n"; } } } return addTitleAndProtection( title, str ); } std::string VulkanHppGenerator::generateRAIIHandles() const { const std::string raiiHandlesTemplate = R"( //======================================== //=== RAII HANDLE forward declarations === //======================================== ${forwardDeclarations} //==================== //=== RAII HANDLES === //==================== ${raiiHandles} )"; std::string forwardDeclarations; for ( auto const & feature : m_features ) { forwardDeclarations += generateRAIIHandleForwardDeclarations( feature.requireData, feature.name ); } for ( auto const & extension : m_extensions ) { forwardDeclarations += generateRAIIHandleForwardDeclarations( extension.requireData, extension.name ); } std::set listedHandles; auto handleIt = m_handles.begin(); assert( handleIt->first.empty() ); std::string raiiHandles = generateRAIIHandleContext( *handleIt, m_RAIISpecialFunctions ); for ( ++handleIt; handleIt != m_handles.end(); ++handleIt ) { if ( isTypeUsed( handleIt->first ) ) { raiiHandles += generateRAIIHandle( *handleIt, listedHandles, m_RAIISpecialFunctions ); } } return replaceWithMap( raiiHandlesTemplate, { { "forwardDeclarations", forwardDeclarations }, { "raiiHandles", raiiHandles } } ); } std::string VulkanHppGenerator::generateRAIIHandleSingularConstructorArguments( std::pair const & handle, std::map::const_iterator constructorIt ) const { std::string arguments = startLowerCase( stripPrefix( handle.first, "Vk" ) ); if ( handle.second.destructorIt != m_commands.end() ) { auto [parentType, parentName] = getParentTypeAndName( handle ); parentType = "Vk" + parentType; for ( auto const & destructorParam : handle.second.destructorIt->second.params ) { if ( ( destructorParam.type.type != parentType ) && ( destructorParam.type.type != handle.first ) && std::none_of( handle.second.destructorIt->second.params.begin(), handle.second.destructorIt->second.params.end(), [&destructorParam]( ParamData const & pd ) { return pd.lenExpression == destructorParam.name; } ) ) { if ( std::any_of( constructorIt->second.params.begin(), constructorIt->second.params.end(), [&destructorParam]( ParamData const & pd ) { return pd.type.type == destructorParam.type.type; } ) ) { if ( isHandleType( destructorParam.type.type ) ) { assert( destructorParam.type.isValue() ); arguments += ", static_cast<" + destructorParam.type.type + ">( *" + destructorParam.name + " )"; } else { assert( destructorParam.type.type == "VkAllocationCallbacks" ); arguments += ", allocator"; } } else { #if !defined( NDEBUG ) bool found = false; #endif for ( auto const & constructorParam : constructorIt->second.params ) { auto structureIt = m_structs.find( constructorParam.type.type ); if ( structureIt != m_structs.end() ) { auto memberIt = findStructMemberItByType( destructorParam.type.type, structureIt->second.members ); if ( memberIt != structureIt->second.members.end() ) { #if !defined( NDEBUG ) found = true; #endif assert( !constructorParam.type.isValue() ); std::string argument = startLowerCase( stripPrefix( constructorParam.name, "p" ) ) + "." + memberIt->name; if ( isHandleType( memberIt->type.type ) ) { argument = "static_cast<" + memberIt->type.type + ">( " + argument + " )"; } arguments += ", " + argument; break; } } } assert( found ); } } } } return arguments; } std::string VulkanHppGenerator::generateRAIIHandleVectorSizeCheck( std::string const & name, CommandData const & commandData, size_t initialSkipCount, std::map> const & countToVectorMap, std::set 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 const throwTemplateVoid = R"#( if ( ${zeroSizeCheck}${firstVectorName}.size() * sizeof( ${firstDataType} ) != ${secondVectorName}.size() * sizeof( ${secondDataType} ) ) { throw LogicError( VULKAN_HPP_NAMESPACE_STRING "::${className}::${commandName}: ${firstVectorName}.size() * sizeof( ${firstDataType} ) != ${secondVectorName}.size() * sizeof( ${secondDataType} )" ); })#"; std::string const throwTemplateSingle = R"#( if ( ${vectorName}.size() != ${sizeValue} ) { throw LogicError( VULKAN_HPP_NAMESPACE_STRING "::${className}::${commandName}: ${vectorName}.size() != ${sizeValue}" ); })#"; std::string className = stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ); std::string commandName = generateCommandName( name, commandData.params, initialSkipCount ); std::string sizeChecks; for ( auto const & cvm : countToVectorMap ) { size_t defaultStartIndex = determineDefaultStartIndex( commandData.params, skippedParams ); std::string firstVectorName = startLowerCase( stripPrefix( commandData.params[cvm.second[0]].name, "p" ) ); if ( cvm.second.size() == 1 ) { std::string sizeValue; if ( isLenByStructMember( commandData.params[cvm.second[0]].lenExpression, commandData.params[cvm.first] ) ) { std::vector lenParts = tokenize( commandData.params[cvm.second[0]].lenExpression, "->" ); assert( lenParts.size() == 2 ); sizeValue = startLowerCase( stripPrefix( lenParts[0], "p" ) ) + "." + lenParts[1]; } else { assert( !commandData.params[cvm.second[0]].lenParams.empty() ); if ( commandData.params[cvm.first].type.type == "VkSampleCountFlagBits" ) { assert( commandData.params[cvm.second[0]].lenExpression == "(" + commandData.params[cvm.second[0]].lenParams[0].first + " + 31) / 32" ); sizeValue = "( static_cast( " + commandData.params[cvm.second[0]].lenParams[0].first + " ) + 31 ) / 32"; } else { sizeValue = commandData.params[cvm.second[0]].lenExpression; } } sizeChecks += replaceWithMap( throwTemplateSingle, { { "className", className }, { "commandName", commandName }, { "sizeValue", sizeValue }, { "vectorName", firstVectorName } } ); } else { 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] ); if ( commandData.params[cvm.second[0]].type.type == "void" ) { assert( commandData.params[cvm.second[i]].type.type == "void" ); std::string firstDataType = stripPrefix( commandData.params[cvm.second[0]].name, "p" ) + "Type"; std::string secondDataType = stripPrefix( commandData.params[cvm.second[i]].name, "p" ) + "Type"; sizeChecks += replaceWithMap( throwTemplateVoid, { { "firstDataType", firstDataType }, { "firstVectorName", firstVectorName }, { "className", className }, { "commandName", commandName }, { "secondDataType", secondDataType }, { "secondVectorName", secondVectorName }, { "zeroSizeCheck", withZeroSizeCheck ? ( "!" + secondVectorName + ".empty() && " ) : "" } } ); } else { sizeChecks += replaceWithMap( throwTemplate, { { "firstVectorName", firstVectorName }, { "className", className }, { "commandName", commandName }, { "secondVectorName", secondVectorName }, { "zeroSizeCheck", withZeroSizeCheck ? ( "!" + secondVectorName + ".empty() && " ) : "" } } ); } if ( i + 1 < cvm.second.size() ) { sizeChecks += "\n"; } } } } if ( !sizeChecks.empty() ) { sizeChecks += "\n"; } return sizeChecks; } template std::string VulkanHppGenerator::generateReplacedExtensionsList( Predicate p, Extraction e ) const { std::string extensionsList, previousEnter, previousLeave; for ( auto const & extension : m_extensions ) { if ( p( extension ) ) { auto [enter, leave] = generateProtection( getProtectFromTitle( extension.name ) ); extensionsList += ( ( previousEnter != enter ) ? ( "\n" + previousLeave + enter ) : "\n" ) + "{ \"" + extension.name + "\", \"" + e( extension ) + "\"}, "; previousEnter = enter; previousLeave = leave; } } if ( !extensionsList.empty() ) { assert( extensionsList.ends_with( ", " ) ); extensionsList = extensionsList.substr( 0, extensionsList.length() - 2 ); if ( !previousLeave.empty() ) { extensionsList += "\n" + previousLeave; } } return extensionsList; } std::string VulkanHppGenerator::generateResultAssignment( CommandData const & commandData ) const { std::string resultAssignment; if ( ( commandData.returnType != "void" ) && !( ( commandData.returnType == "VkResult" ) && ( commandData.successCodes.size() == 1 ) && commandData.errorCodes.empty() ) ) { resultAssignment = commandData.returnType + " result = "; } return resultAssignment; } std::string VulkanHppGenerator::generateResultCheck( CommandData const & commandData, std::string const & className, std::string const & classSeparator, std::string commandName, bool enumerating ) const { std::string resultCheck; if ( !commandData.errorCodes.empty() ) { std::string successCodeList = generateSuccessCodeList( commandData.successCodes, enumerating ); std::string const resultCheckTemplate = R"(resultCheck( static_cast( result ), VULKAN_HPP_NAMESPACE_STRING "::${className}${classSeparator}${commandName}"${successCodeList} );)"; resultCheck = replaceWithMap( resultCheckTemplate, { { "className", className }, { "classSeparator", classSeparator }, { "commandName", commandName }, { "successCodeList", successCodeList } } ); } return resultCheck; } // 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 ) { // Only generate exception class for non-alias results codes if ( value.alias.empty() && value.name.starts_with( "VK_ERROR" ) ) { auto [enter, leave] = generateProtection( value.protect ); std::string valueName = generateEnumValueName( enumIt->first, value.name, false ); str += replaceWithMap( templateString, { { "className", stripPrefix( valueName, "eError" ) + "Error" }, { "enter", enter }, { "enumName", stripPrefix( enumIt->first, "Vk" ) }, { "enumMemberName", valueName }, { "leave", leave } } ); } } return str; } std::string VulkanHppGenerator::generateReturnStatement( std::string const & commandName, CommandData const & commandData, std::string const & returnVariable, std::string const & returnType, std::string const & dataType, size_t initialSkipCount, size_t returnParam, CommandFlavourFlags flavourFlags, bool enumerating, bool raii ) const { bool unique = flavourFlags & CommandFlavourFlagBits::unique; std::string returnStatement; if ( commandData.returnType.starts_with( "Vk" ) ) { if ( ( commandData.successCodes.size() == 1 ) || enumerating ) { assert( commandData.successCodes[0] == "VK_SUCCESS" ); if ( raii || commandData.errorCodes.empty() ) { if ( !returnVariable.empty() ) { returnStatement = "return " + returnVariable + ";"; } } else { if ( returnVariable.empty() ) { assert( !unique ); returnStatement = "return createResultValueType( static_cast( result ) );"; } else if ( unique ) { assert( returnParam != INVALID_INDEX ); returnStatement = "return createResultValueType( static_cast( result ), "; if ( dataType.starts_with( "std::" ) ) { returnStatement += "std::move( unique" + startUpperCase( returnVariable ) + " )"; } else { returnStatement += "UniqueHandle<" + dataType + ", Dispatch>( " + returnVariable + ", " + generateObjectDeleter( commandName, commandData, initialSkipCount, returnParam ) + " )"; } returnStatement += " );"; } else { returnStatement = "return createResultValueType( static_cast( result ), " + returnVariable + " );"; } } } else { if ( returnVariable.empty() ) { assert( !unique ); returnStatement = "return static_cast( result );"; } else if ( unique ) { assert( returnParam != INVALID_INDEX ); assert( returnType.starts_with( "ResultValue<" ) && returnType.ends_with( ">" ) ); returnStatement = "return " + returnType + "( static_cast( result ), "; if ( dataType.starts_with( "std::" ) ) { returnStatement += "std::move( unique" + startUpperCase( returnVariable ) + " )"; } else { returnStatement += "UniqueHandle<" + dataType + ", Dispatch>( " + returnVariable + ", " + generateObjectDeleter( commandName, commandData, initialSkipCount, returnParam ) + " )"; } returnStatement += " );"; } else { assert( returnType.starts_with( raii ? "std::pair" ) ); returnStatement = "return " + ( raii ? "std::make_pair" : returnType ) + "( static_cast( result ), " + returnVariable + " );"; } } } else { assert( !unique ); if ( returnVariable.empty() ) { if ( commandData.returnType != "void" ) { returnStatement = "return result;"; } } else { returnStatement = "return " + returnVariable + ";"; } } return returnStatement; } std::string VulkanHppGenerator::generateReturnType( CommandData const & commandData, std::vector const & returnParams, std::map const & vectorParams, CommandFlavourFlags flavourFlags, bool raii, std::vector const & dataTypes ) const { assert( returnParams.size() == dataTypes.size() ); bool chained = flavourFlags & CommandFlavourFlagBits::chained; bool singular = flavourFlags & CommandFlavourFlagBits::singular; bool unique = flavourFlags & CommandFlavourFlagBits::unique; assert( !( chained && unique ) ); std::string dataType; switch ( returnParams.size() ) { case 0: dataType = "void"; break; case 1: if ( chained ) { assert( vectorParams.empty() ); assert( isStructureChainAnchor( commandData.params[returnParams[0]].type.type ) ); dataType = "VULKAN_HPP_NAMESPACE::StructureChain"; } else if ( unique ) { assert( isHandleType( commandData.params[returnParams[0]].type.type ) ); if ( vectorParams.contains( returnParams[0] ) && !singular ) { dataType = "std::vector, " + stripPrefix( dataTypes[0], "VULKAN_HPP_NAMESPACE::" ) + "Allocator>"; } else { dataType = "UniqueHandle<" + dataTypes[0] + ", Dispatch>"; } } else { if ( vectorParams.contains( returnParams[0] ) && !singular ) { dataType = "std::vector<" + dataTypes[0] + ( raii ? "" : ( ", " + stripPrefix( dataTypes[0], "VULKAN_HPP_NAMESPACE::" ) + "Allocator" ) ) + ">"; } else { dataType = dataTypes[0]; } } break; case 2: assert( !unique ); if ( chained ) { #if !defined( NDEBUG ) auto vectorIt = vectorParams.find( returnParams[1] ); #endif assert( ( vectorIt != vectorParams.end() ) && ( vectorIt->second.lenParam == returnParams[0] ) ); assert( isStructureChainAnchor( commandData.params[returnParams[1]].type.type ) ); dataType = std::string( "std::vector"; } else { if ( vectorParams.contains( returnParams[0] ) ) { if ( singular ) { dataType = "std::pair<" + dataTypes[0] + ", " + dataTypes[1] + ">"; } else { dataType = "std::pair, " + dataTypes[1] + ">"; } } else if ( vectorParams.contains( returnParams[1] ) ) { assert( vectorParams.find( returnParams[1] )->second.lenParam == returnParams[0] ); dataType = "std::vector<" + dataTypes[1] + ( raii ? "" : ( ", " + startUpperCase( stripPrefix( dataTypes[1], "VULKAN_HPP_NAMESPACE::" ) ) + "Allocator" ) ) + ">"; } else { dataType = "std::pair<" + dataTypes[0] + ", " + dataTypes[1] + ">"; } } break; case 3: assert( !unique ); if ( chained ) { assert( dataTypes[2] == "uint8_t" ); #if !defined( NDEBUG ) auto vectorIt = vectorParams.find( returnParams[2] ); assert( ( vectorIt != vectorParams.end() ) && ( vectorIt->second.lenParam == returnParams[1] ) ); assert( !vectorParams.contains( returnParams[0] ) ); #endif dataType = "std::pair, std::vector<" + dataTypes[2] + ( raii ? "" : ( ", " + startUpperCase( dataTypes[2] ) + "Allocator" ) ) + ">>"; } else { if ( vectorParams.contains( returnParams[1] ) ) { #if !defined( NDEBUG ) auto vectorIt = vectorParams.find( returnParams[1] ); assert( ( vectorIt != vectorParams.end() ) && ( vectorIt->second.lenParam == returnParams[0] ) ); vectorIt = vectorParams.find( returnParams[2] ); assert( ( vectorIt != vectorParams.end() ) && ( vectorIt->second.lenParam == returnParams[0] ) ); #endif dataType = "std::pair, std::vector<" + dataTypes[2] + ( raii ? "" : ( ", " + stripPrefix( dataTypes[2], "VULKAN_HPP_NAMESPACE::" ) + "Allocator" ) ) + ">>"; } else { #if !defined( NDEBUG ) auto vectorIt = vectorParams.find( returnParams[2] ); assert( ( vectorIt != vectorParams.end() ) && ( vectorIt->second.lenParam == returnParams[1] ) ); assert( !vectorParams.contains( returnParams[0] ) ); #endif dataType = "std::pair<" + dataTypes[0] + ", std::vector<" + dataTypes[2] + ( raii ? "" : ( ", " + startUpperCase( stripPrefix( dataTypes[2], "VULKAN_HPP_NAMESPACE::" ) ) + "Allocator" ) ) + ">>"; } } break; default: assert( false ); } std::string returnType; if ( ( 1 < commandData.successCodes.size() ) && returnParams.empty() && !chained ) { assert( ( commandData.returnType == "VkResult" ) && !unique ); returnType = "VULKAN_HPP_NAMESPACE::Result"; } else if ( ( commandData.returnType != "VkResult" ) && ( commandData.returnType != "void" ) ) { assert( returnParams.empty() && !chained && !unique ); if ( commandData.returnType.starts_with( "Vk" ) ) { returnType = generateNamespacedType( commandData.returnType ); } else { returnType = commandData.returnType; } } else if ( ( commandData.returnType == "void" ) || ( ( commandData.returnType == "VkResult" ) && ( commandData.successCodes.size() == 1 ) && ( commandData.errorCodes.empty() || raii ) ) ) { assert( !unique ); assert( ( commandData.returnType != "void" ) || ( returnParams.size() <= 2 ) ); returnType = dataType; } else { assert( commandData.returnType == "VkResult" ); assert( !commandData.successCodes.empty() && ( commandData.successCodes[0] == "VK_SUCCESS" ) ); if ( ( 1 < commandData.successCodes.size() ) && ( ( returnParams.size() == 1 ) || ( ( returnParams.size() == 2 ) && vectorParams.empty() ) ) ) { assert( !commandData.errorCodes.empty() ); returnType = ( raii ? "std::pair"; } else { assert( ( ( commandData.successCodes.size() == 1 ) || ( ( commandData.successCodes.size() == 2 ) && ( commandData.successCodes[1] == "VK_INCOMPLETE" ) ) ) && ( returnParams.size() <= 3 ) ); returnType = raii ? dataType : ( "typename ResultValueType<" + dataType + ">::type" ); } } return returnType; } std::string VulkanHppGenerator::generateReturnVariable( CommandData const & commandData, std::vector const & returnParams, std::map const & vectorParams, CommandFlavourFlags flavourFlags ) const { bool chained = flavourFlags & CommandFlavourFlagBits::chained; bool singular = flavourFlags & CommandFlavourFlagBits::singular; std::string returnVariable; switch ( returnParams.size() ) { case 0: break; // no return variable case 1: if ( chained ) { returnVariable = "structureChain"; } else { returnVariable = startLowerCase( stripPrefix( commandData.params[returnParams[0]].name, "p" ) ); if ( singular ) { returnVariable = stripPluralS( returnVariable ); } } break; case 2: if ( chained ) { returnVariable = "structureChains"; } else { auto vectorParamIt = vectorParams.find( returnParams[1] ); if ( vectorParamIt == vectorParams.end() ) { // the return variable is simply named "data_", and holds the multi-return value stuff returnVariable = "data_"; } else { assert( vectorParamIt->second.lenParam == returnParams[0] ); assert( !singular ); returnVariable = startLowerCase( stripPrefix( commandData.params[returnParams[1]].name, "p" ) ); } } break; case 3: assert( !singular ); assert( ( ( vectorParams.size() == 1 ) && ( vectorParams.begin()->first == returnParams[2] ) && ( vectorParams.begin()->second.lenParam == returnParams[1] ) ) || ( ( vectorParams.size() == 2 ) && ( vectorParams.begin()->first == returnParams[1] ) && ( vectorParams.begin()->second.lenParam == returnParams[0] ) && ( std::next( vectorParams.begin() )->first == returnParams[2] ) && ( std::next( vectorParams.begin() )->second.lenParam == returnParams[0] ) ) ); returnVariable = "data_"; break; } return returnVariable; } std::string VulkanHppGenerator::generateSizeCheck( std::vector::const_iterator> const & arrayIts, std::string const & structName, bool mutualExclusiveLens ) const { std::string sizeCheck; if ( 1 < arrayIts.size() ) { static const std::string throwTextTemplate = R"( if ( ${throwCheck} ) { throw LogicError( VULKAN_HPP_NAMESPACE_STRING"::${structName}::${structName}: ${throwCheck}" ); } )"; std::string assertionText, throwText; if ( mutualExclusiveLens ) { // exactly one of the arrays has to be non-empty std::string sum; for ( auto it : arrayIts ) { sum += "!" + startLowerCase( stripPrefix( it->name, "p" ) ) + "_.empty() + "; } sum.resize( sum.size() - 3 ); assertionText += " VULKAN_HPP_ASSERT( ( " + sum + " ) <= 1);\n"; throwText += replaceWithMap( throwTextTemplate, { { "structName", structName }, { "throwCheck", "1 < ( " + sum + " )" } } ); } else { for ( size_t first = 0; first + 1 < arrayIts.size(); ++first ) { assert( arrayIts[first]->name.starts_with( "p" ) ); std::string firstName = startLowerCase( stripPrefix( arrayIts[first]->name, "p" ) ) + "_"; for ( auto second = first + 1; second < arrayIts.size(); ++second ) { assert( arrayIts[second]->name.starts_with( "p" ) ); std::string secondName = startLowerCase( stripPrefix( arrayIts[second]->name, "p" ) ) + "_"; std::string assertionCheck = firstName + ".size() == " + secondName + ".size()"; std::string throwCheck = firstName + ".size() != " + secondName + ".size()"; if ( ( !arrayIts[first]->optional.empty() && arrayIts[first]->optional.front() ) || ( !arrayIts[second]->optional.empty() && arrayIts[second]->optional.front() ) ) { assertionCheck = "( " + assertionCheck + " )"; throwCheck = "( " + throwCheck + " )"; if ( !arrayIts[second]->optional.empty() && arrayIts[second]->optional.front() ) { assertionCheck = secondName + ".empty() || " + assertionCheck; throwCheck = "!" + secondName + ".empty() && " + throwCheck; } if ( !arrayIts[first]->optional.empty() && arrayIts[first]->optional.front() ) { assertionCheck = firstName + ".empty() || " + assertionCheck; throwCheck = "!" + firstName + ".empty() && " + throwCheck; } } assertionText += " VULKAN_HPP_ASSERT( " + assertionCheck + " );\n"; throwText += replaceWithMap( throwTextTemplate, { { "structName", structName }, { "throwCheck", throwCheck } } ); } } } sizeCheck += "\n#ifdef VULKAN_HPP_NO_EXCEPTIONS\n" + assertionText + "#else\n" + throwText + "#endif /*VULKAN_HPP_NO_EXCEPTIONS*/\n" + " "; } return sizeCheck; } std::string VulkanHppGenerator::generateStaticAssertions() const { std::string staticAssertions; std::set listedStructs; for ( auto const & feature : m_features ) { staticAssertions += generateStaticAssertions( feature.requireData, feature.name, listedStructs ); } for ( auto const & extension : m_extensions ) { staticAssertions += generateStaticAssertions( extension.requireData, extension.name, listedStructs ); } return staticAssertions; } std::string VulkanHppGenerator::generateStaticAssertions( std::vector const & requireData, std::string const & title, std::set & listedStructs ) const { std::string str; for ( auto const & require : requireData ) { for ( auto const & type : require.types ) { auto handleIt = m_handles.find( type ); if ( handleIt != m_handles.end() ) { std::string const assertionTemplate = R"( VULKAN_HPP_STATIC_ASSERT( sizeof( VULKAN_HPP_NAMESPACE::${className} ) == sizeof( Vk${className} ), "handle and wrapper have different size!" ); VULKAN_HPP_STATIC_ASSERT( std::is_nothrow_move_constructible::value, "${className} is not nothrow_move_constructible!" ); )"; str += replaceWithMap( assertionTemplate, { { "className", stripPrefix( handleIt->first, "Vk" ) } } ); } else { auto structIt = m_structs.find( type ); if ( ( structIt != m_structs.end() ) && listedStructs.insert( type ).second ) { std::string const assertionTemplate = R"( VULKAN_HPP_STATIC_ASSERT( sizeof( VULKAN_HPP_NAMESPACE::${structureType} ) == sizeof( Vk${structureType} ), "struct and wrapper have different size!" ); VULKAN_HPP_STATIC_ASSERT( std::is_standard_layout::value, "struct wrapper is not a standard layout!" ); VULKAN_HPP_STATIC_ASSERT( std::is_nothrow_move_constructible::value, "${structureType} is not nothrow_move_constructible!" ); )"; str += replaceWithMap( assertionTemplate, { { "structureType", stripPrefix( structIt->first, "Vk" ) } } ); } } } } return addTitleAndProtection( title, str ); } std::string VulkanHppGenerator::generateStruct( std::pair const & structure, std::set & listedStructs ) const { assert( !listedStructs.contains( structure.first ) ); std::string str; for ( auto const & member : structure.second.members ) { auto structIt = m_structs.find( member.type.type ); if ( ( structIt != m_structs.end() ) && ( structure.first != member.type.type ) && !listedStructs.contains( member.type.type ) ) { str += generateStruct( *structIt, listedStructs ); } } if ( !structure.second.subStruct.empty() ) { auto structureIt = m_structs.find( structure.second.subStruct ); if ( ( structureIt != m_structs.end() ) && !listedStructs.contains( structureIt->first ) ) { str += generateStruct( *structureIt, listedStructs ); } } if ( structure.second.isUnion ) { str += generateUnion( structure ); } else { str += generateStructure( structure ); } listedStructs.insert( structure.first ); return str; } std::string VulkanHppGenerator::generateStructCompareOperators( std::pair const & structData ) const { static const std::set 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, spaceshipMembers; std::string intro = ""; bool nonDefaultCompare = false; std::string spaceshipOrdering = containsFloatingPoints( structData.second.members ) ? "std::partial_ordering" : "std::strong_ordering"; 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::ExternalType ) && member.type.postfix.empty() && !simpleTypes.contains( member.type.type ) ) { nonDefaultCompare = true; // this type might support operator==() or operator<=>()... that is, use memcmp compareMembers += intro + "( memcmp( &" + member.name + ", &rhs." + member.name + ", sizeof( " + member.type.type + " ) ) == 0 )"; static const std::string spaceshipMemberTemplate = R"( if ( auto cmp = memcmp( &${name}, &rhs.${name}, sizeof( ${type} ) ); cmp != 0 ) return ( cmp < 0 ) ? ${ordering}::less : ${ordering}::greater; )"; spaceshipMembers += replaceWithMap( spaceshipMemberTemplate, { { "name", member.name }, { "ordering", spaceshipOrdering }, { "type", member.type.type } } ); } else if ( member.type.type == "char" && !member.lenExpressions.empty() ) { // compare null-terminated strings nonDefaultCompare = true; assert( member.lenExpressions.size() < 3 ); if ( member.lenExpressions.size() == 1 ) { assert( member.lenExpressions[0] == "null-terminated" ); compareMembers += intro + "( ( " + member.name + " == rhs." + member.name + " ) || ( strcmp( " + member.name + ", rhs." + member.name + " ) == 0 ) )"; static const std::string spaceshipMemberTemplate = R"( if ( ${name} != rhs.${name} ) if ( auto cmp = strcmp( ${name}, rhs.${name} ); cmp != 0 ) return ( cmp < 0 ) ? ${ordering}::less : ${ordering}::greater; )"; spaceshipMembers += replaceWithMap( spaceshipMemberTemplate, { { "name", member.name }, { "ordering", spaceshipOrdering } } ); } else { assert( member.lenExpressions[1] == "null-terminated" ); assert( ( member.type.prefix == "const" ) && ( member.type.postfix == "* const *" ) ); static const std::string compareMemberTemplate = R"(std::equal( ${name}, ${name} + ${count}, rhs.${name}, []( char const * left, char const * right ) { return ( left == right ) || ( strcmp( left, right ) == 0 ); } ))"; compareMembers += intro + replaceWithMap( compareMemberTemplate, { { "count", member.lenExpressions[0] }, { "name", member.name } } ); static const std::string spaceshipMemberTemplate = R"( for ( size_t i = 0; i < ${count}; ++i ) { if ( ${name}[i] != rhs.${name}[i] ) if ( auto cmp = strcmp( ${name}[i], rhs.${name}[i] ); cmp != 0 ) return cmp < 0 ? ${ordering}::less : ${ordering}::greater; } )"; spaceshipMembers += replaceWithMap( spaceshipMemberTemplate, { { "count", member.lenExpressions[0] }, { "name", member.name }, { "ordering", spaceshipOrdering } } ); } } else { // for all others, we use the operator== of that type compareMembers += intro + "( " + member.name + " == rhs." + member.name + " )"; spaceshipMembers += " if ( auto cmp = " + member.name + " <=> rhs." + member.name + "; cmp != 0 ) return cmp;\n"; } intro = "\n && "; } std::string structName = stripPrefix( structData.first, "Vk" ); std::string compareBody, spaceshipOperator, spaceshipOperatorIf, spaceshipOperatorElse, spaceshipOperatorEndif; if ( nonDefaultCompare ) { compareBody = " return " + compareMembers + ";"; if ( !containsFuncPointer( structData.first ) ) { static const std::string spaceshipOperatorTemplate = R"( ${ordering} operator<=>( ${name} const & rhs ) const VULKAN_HPP_NOEXCEPT { ${spaceshipMembers} return ${ordering}::equivalent; })"; spaceshipOperatorIf = "#if defined(VULKAN_HPP_HAS_SPACESHIP_OPERATOR)"; spaceshipOperator = replaceWithMap( spaceshipOperatorTemplate, { { "name", structName }, { "ordering", spaceshipOrdering }, { "spaceshipMembers", spaceshipMembers } } ); spaceshipOperatorElse = "#endif\n"; spaceshipOperatorEndif = ""; } } else { // use reflection only if VULKAN_HPP_USE_REFLECT is defined static const std::string compareBodyTemplate = R"(#if defined( VULKAN_HPP_USE_REFLECT ) return this->reflect() == rhs.reflect(); #else return ${compareMembers}; #endif)"; compareBody = replaceWithMap( compareBodyTemplate, { { "compareMembers", compareMembers } } ); if ( !containsFuncPointer( structData.first ) ) { spaceshipOperatorIf = "#if defined(VULKAN_HPP_HAS_SPACESHIP_OPERATOR)"; spaceshipOperator = "auto operator<=>( " + structName + " const & ) const = default;"; spaceshipOperatorElse = "#else"; spaceshipOperatorEndif = "#endif\n"; } } static const std::string compareTemplate = R"( ${spaceshipOperatorIf} ${spaceshipOperator} ${spaceshipOperatorElse} bool operator==( ${name} const & rhs ) const VULKAN_HPP_NOEXCEPT { ${compareBody} } bool operator!=( ${name} const & rhs ) const VULKAN_HPP_NOEXCEPT { return !operator==( rhs ); } ${spaceshipOperatorEndif})"; return replaceWithMap( compareTemplate, { { "name", structName }, { "compareBody", compareBody }, { "spaceshipOperator", spaceshipOperator }, { "spaceshipOperatorElse", spaceshipOperatorElse }, { "spaceshipOperatorEndif", spaceshipOperatorEndif }, { "spaceshipOperatorIf", spaceshipOperatorIf } } ); } std::string VulkanHppGenerator::generateStructConstructors( std::pair const & structData ) const { // the constructor with all the elements as arguments, with defaults // and the simple copy constructor from the corresponding vulkan structure static const std::string constructors = R"(${constexpr}${structName}(${arguments}) VULKAN_HPP_NOEXCEPT ${initializers} {} ${constexpr}${structName}( ${structName} const & rhs ) VULKAN_HPP_NOEXCEPT = default; ${structName}( Vk${structName} const & rhs ) VULKAN_HPP_NOEXCEPT : ${structName}( *reinterpret_cast<${structName} const *>( &rhs ) ) {} )"; std::string arguments, initializers; bool listedArgument = false; bool firstArgument = true; for ( auto const & member : structData.second.members ) { // gather the arguments std::string argument = generateStructConstructorArgument( listedArgument, member, true ); if ( !argument.empty() ) { listedArgument = true; arguments += argument; } // gather the initializers; skip members with exactly one legal value if ( member.value.empty() ) { initializers += std::string( firstArgument ? ": " : ", " ) + member.name + "( " + member.name + "_ )"; firstArgument = false; } } auto pNextIt = std::find_if( structData.second.members.begin(), structData.second.members.end(), []( MemberData const & md ) { return md.name == "pNext"; } ); if ( pNextIt != structData.second.members.end() ) { // add pNext as a last optional argument to the constructor arguments += std::string( listedArgument ? ", " : "" ) + pNextIt->type.compose( "VULKAN_HPP_NAMESPACE" ) + " pNext_ = nullptr"; } std::string str = replaceWithMap( constructors, { { "arguments", arguments }, { "constexpr", generateConstexprString( structData.first ) }, { "initializers", initializers }, { "structName", stripPrefix( structData.first, "Vk" ) } } ); str += generateStructConstructorsEnhanced( structData ); return str; } std::string VulkanHppGenerator::generateStructConstructorsEnhanced( std::pair const & structData ) const { if ( std::any_of( structData.second.members.begin(), structData.second.members.end(), [this]( MemberData const & md ) { return hasLen( md ); } ) ) { // map from len-members to all the array members using that len std::map::const_iterator, std::vector::const_iterator>> lenIts; for ( auto mit = structData.second.members.begin(); mit != structData.second.members.end(); ++mit ) { if ( hasLen( *mit ) ) { std::string lenName = ( mit->lenExpressions.front() == "codeSize / 4" ) ? "codeSize" : mit->lenExpressions.front(); auto lenIt = findStructMemberIt( lenName, structData.second.members ); 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 if ( mit->name == "pNext" ) // for pNext, we just get the initializer... the argument is added at the end { initializers += std::string( firstArgument ? ":" : "," ) + " pNext( pNext_ )"; firstArgument = false; } else if ( mit->value.empty() ) // skip constant members { auto litit = lenIts.find( mit ); if ( litit != lenIts.end() ) { // len arguments just have an initalizer, from the ArrayProxyNoTemporaries size initializers += ( firstArgument ? ": " : ", " ) + mit->name + "( " + generateLenInitializer( mit, litit, structData.second.mutualExclusiveLens ) + " )"; sizeChecks += generateSizeCheck( litit->second, stripPrefix( structData.first, "Vk" ), structData.second.mutualExclusiveLens ); } else if ( hasLen( *mit ) ) { assert( mit->name.starts_with( "p" ) ); std::string argumentName = startLowerCase( stripPrefix( mit->name, "p" ) ) + "_"; assert( mit->type.postfix.ends_with( "*" ) ); std::string argumentType = trimEnd( stripPostfix( mit->type.compose( "VULKAN_HPP_NAMESPACE" ), "*" ) ); if ( ( mit->type.type == "void" ) && ( argumentType.find( '*' ) == std::string::npos ) ) { // the argument after stripping one pointer is just void assert( templateHeader.empty() ); templateHeader = " template \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; } } auto pNextIt = std::find_if( structData.second.members.begin(), structData.second.members.end(), []( MemberData const & md ) { return md.name == "pNext"; } ); if ( pNextIt != structData.second.members.end() ) { // add pNext as a last optional argument to the constructor arguments += std::string( listedArgument ? ", " : "" ) + pNextIt->type.compose( "VULKAN_HPP_NAMESPACE" ) + " pNext_ = nullptr"; } static const std::string constructorTemplate = R"( #if !defined( VULKAN_HPP_DISABLE_ENHANCED_MODE ) ${templateHeader} ${structName}( ${arguments} ) ${initializers} {${sizeChecks}} #endif /*VULKAN_HPP_DISABLE_ENHANCED_MODE*/ )"; return replaceWithMap( constructorTemplate, { { "arguments", arguments }, { "initializers", initializers }, { "sizeChecks", sizeChecks }, { "structName", stripPrefix( structData.first, "Vk" ) }, { "templateHeader", templateHeader } } ); } return ""; } std::string VulkanHppGenerator::generateStructConstructorArgument( bool listedArgument, MemberData const & memberData, bool withDefault ) const { // skip members 'pNext' and members with a specified value, as they are never explicitly set std::string str; if ( ( memberData.name != "pNext" ) && memberData.value.empty() ) { str += ( listedArgument ? ( ", " ) : "" ); if ( memberData.arraySizes.empty() ) { str += memberData.type.compose( "VULKAN_HPP_NAMESPACE" ) + " "; } else { str += generateStandardArray( memberData.type.compose( "VULKAN_HPP_NAMESPACE" ), memberData.arraySizes ) + " const & "; } str += memberData.name + "_"; if ( withDefault ) { str += " = "; auto enumIt = m_enums.find( memberData.type.type ); if ( enumIt != m_enums.end() && memberData.type.postfix.empty() ) { str += generateEnumInitializer( memberData.type, memberData.arraySizes, enumIt->second.values, enumIt->second.isBitmask ); } else { assert( memberData.value.empty() ); // all the rest can be initialized with just {} str += "{}"; } } } return str; } std::string VulkanHppGenerator::generateStructHashStructure( std::pair const & structure, std::set & listedStructs ) const { assert( !listedStructs.contains( structure.first ) ); std::string str; for ( auto const & member : structure.second.members ) { auto structIt = m_structs.find( member.type.type ); if ( ( structIt != m_structs.end() ) && ( structure.first != member.type.type ) && !listedStructs.contains( member.type.type ) ) { str += generateStructHashStructure( *structIt, listedStructs ); } } if ( !containsUnion( structure.first ) ) { static const std::string hashTemplate = R"( ${enter}template <> struct hash { std::size_t operator()(VULKAN_HPP_NAMESPACE::${structureType} const & ${structureName}) const VULKAN_HPP_NOEXCEPT { std::size_t seed = 0; ${hashSum} return seed; } }; ${leave})"; auto [enter, leave] = generateProtection( getProtectFromType( structure.first ) ); std::string structureType = stripPrefix( structure.first, "Vk" ); std::string structureName = startLowerCase( structureType ); str += replaceWithMap( hashTemplate, { { "enter", enter }, { "hashSum", generateStructHashSum( structureName, structure.second.members ) }, { "leave", leave }, { "structureName", structureName }, { "structureType", structureType } } ); } listedStructs.insert( structure.first ); return str; } std::string VulkanHppGenerator::generateStructHashStructures() const { const std::string hashesTemplate = R"( #if 14 <= VULKAN_HPP_CPP_VERSION //====================================== //=== HASH structures for structures === //====================================== # if !defined( VULKAN_HPP_HASH_COMBINE ) # define VULKAN_HPP_HASH_COMBINE( seed, value ) \ seed ^= std::hash::type>{}( value ) + 0x9e3779b9 + ( seed << 6 ) + ( seed >> 2 ) # endif ${hashes} #endif // 14 <= VULKAN_HPP_CPP_VERSION )"; // Note reordering structs or handles by features and extensions is not possible! std::set listedStructs; std::string hashes; for ( auto const & structure : m_structs ) { if ( !listedStructs.contains( structure.first ) && isTypeUsed( structure.first ) ) { hashes += generateStructHashStructure( structure, listedStructs ); } } return replaceWithMap( hashesTemplate, { { "hashes", hashes } } ); } std::string VulkanHppGenerator::generateStructHashSum( std::string const & structName, std::vector const & members ) const { std::string hashSum; for ( auto const & member : members ) { if ( !member.arraySizes.empty() ) { assert( member.arraySizes.size() < 3 ); hashSum += " for ( size_t i = 0; i < " + member.arraySizes[0] + "; ++i )\n"; hashSum += " {\n"; if ( member.arraySizes.size() == 1 ) { hashSum += " VULKAN_HPP_HASH_COMBINE( seed, " + structName + "." + member.name + "[i] );\n"; } else { hashSum += " for ( size_t j=0; j < " + member.arraySizes[1] + "; ++j )\n"; hashSum += " {\n"; hashSum += " VULKAN_HPP_HASH_COMBINE( seed, " + structName + "." + member.name + "[i][j] );\n"; hashSum += " }\n"; } hashSum += " }\n"; } else if ( member.type.type == "char" && !member.lenExpressions.empty() ) { assert( member.lenExpressions.size() < 3 ); if ( member.lenExpressions.size() == 1 ) { assert( member.lenExpressions[0] == "null-terminated" ); hashSum += " for ( const char* p = " + structName + "." + member.name + "; *p != '\\0'; ++p )\n"; hashSum += " {\n"; hashSum += " VULKAN_HPP_HASH_COMBINE( seed, *p );\n"; hashSum += " }\n"; } else { assert( member.lenExpressions[1] == "null-terminated" ); hashSum += " for ( size_t i = 0; i < " + structName + "." + member.lenExpressions[0] + "; ++i )\n"; hashSum += " {\n"; hashSum += " for ( const char* p = " + structName + "." + member.name + "[i]; *p != '\\0'; ++p )\n"; hashSum += " {\n"; hashSum += " VULKAN_HPP_HASH_COMBINE( seed, *p );\n"; hashSum += " }\n"; hashSum += " }\n"; } } else { hashSum += " VULKAN_HPP_HASH_COMBINE( seed, " + structName + "." + member.name + " );\n"; } } assert( !hashSum.empty() ); return hashSum.substr( 0, hashSum.size() - 1 ); } 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 listedStructs; std::string structs; for ( auto const & structure : m_structs ) { if ( !listedStructs.contains( structure.first ) && isTypeUsed( structure.first ) ) { structs += generateStruct( structure, listedStructs ); } } return replaceWithMap( structsTemplate, { { "structs", structs } } ); } std::string VulkanHppGenerator::generateStructure( std::pair const & structure ) const { auto [enter, leave] = generateProtection( getProtectFromType( structure.first ) ); std::string str = "\n" + enter; static const std::string constructorsTemplate = R"( #if !defined( VULKAN_HPP_NO_STRUCT_CONSTRUCTORS ) ${constructors} ${subConstructors} ${structName} & operator=( ${structName} const & rhs ) VULKAN_HPP_NOEXCEPT = default; #endif /*VULKAN_HPP_NO_STRUCT_CONSTRUCTORS*/ ${structName} & operator=( Vk${structName} const & rhs ) VULKAN_HPP_NOEXCEPT { *this = *reinterpret_cast( &rhs ); return *this; } )"; std::string constructorsAndSetters = replaceWithMap( constructorsTemplate, { { "constructors", generateStructConstructors( structure ) }, { "structName", stripPrefix( structure.first, "Vk" ) }, { "subConstructors", generateStructSubConstructor( structure ) } } ); if ( !structure.second.returnedOnly ) { // only structs that are not returnedOnly get setters! constructorsAndSetters += "\n#if !defined( VULKAN_HPP_NO_STRUCT_SETTERS )"; for ( size_t i = 0; i < structure.second.members.size(); i++ ) { constructorsAndSetters += generateStructSetter( stripPrefix( structure.first, "Vk" ), structure.second.members, i ); } constructorsAndSetters += "#endif /*VULKAN_HPP_NO_STRUCT_SETTERS*/\n"; } std::string structureType = stripPrefix( structure.first, "Vk" ); // the member variables std::string members, memberNames, memberTypes, sTypeValue; std::tie( members, memberNames, memberTypes, sTypeValue ) = generateStructMembers( structure ); // reflect is meaningfull for structs only, filter out unions std::string reflect; if ( !structure.second.isUnion ) { // use reflection only if VULKAN_HPP_USE_REFLECT is defined static const std::string reflectTemplate = R"( #if defined( VULKAN_HPP_USE_REFLECT ) #if 14 <= VULKAN_HPP_CPP_VERSION auto #else std::tuple<${memberTypes}> #endif reflect() const VULKAN_HPP_NOEXCEPT { return std::tie( ${memberNames} ); } #endif )"; reflect = replaceWithMap( reflectTemplate, { { "memberNames", memberNames }, { "memberTypes", memberTypes } } ); } // 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 ); } static const std::string structureTemplate = R"( struct ${structureType} { using NativeType = Vk${structureType}; ${allowDuplicate} ${typeValue} ${constructorsAndSetters} operator Vk${structureType} const &() const VULKAN_HPP_NOEXCEPT { return *reinterpret_cast( this ); } operator Vk${structureType} &() VULKAN_HPP_NOEXCEPT { return *reinterpret_cast( this ); } ${reflect} ${compareOperators} public: ${members} }; )"; std::string allowDuplicate, typeValue; if ( !sTypeValue.empty() ) { allowDuplicate = std::string( " static const bool allowDuplicate = " ) + ( structure.second.allowDuplicate ? "true;" : "false;" ); typeValue = " static VULKAN_HPP_CONST_OR_CONSTEXPR StructureType structureType = StructureType::" + sTypeValue + ";\n"; } str += replaceWithMap( structureTemplate, { { "allowDuplicate", allowDuplicate }, { "constructorsAndSetters", constructorsAndSetters }, { "compareOperators", compareOperators }, { "members", members }, { "reflect", reflect }, { "structureType", structureType }, { "typeValue", typeValue } } ); if ( !sTypeValue.empty() ) { std::string cppTypeTemplate = R"( template <> struct CppType { using Type = ${structureType}; }; )"; str += replaceWithMap( cppTypeTemplate, { { "sTypeValue", sTypeValue }, { "structureType", structureType } } ); } for ( auto const & alias : m_structAliases ) { if ( alias.second.name == structure.first ) { str += " using " + stripPrefix( alias.first, "Vk" ) + " = " + structureType + ";\n"; } } str += leave; return str; } std::string VulkanHppGenerator::generateStructExtendsStructs() const { const std::string structExtendsTemplate = R"( //======================= //=== STRUCTS EXTENDS === //======================= ${structExtends})"; std::string structExtends; std::set listedStructs; for ( auto const & feature : m_features ) { structExtends += generateStructExtendsStructs( feature.requireData, listedStructs, feature.name ); } for ( auto const & extension : m_extensions ) { structExtends += generateStructExtendsStructs( extension.requireData, listedStructs, extension.name ); } return replaceWithMap( structExtendsTemplate, { { "structExtends", structExtends } } ); } std::string VulkanHppGenerator::generateStructExtendsStructs( std::vector const & requireData, std::set & listedStructs, std::string const & title ) const { std::string str; for ( auto const & require : requireData ) { for ( auto const & type : require.types ) { auto structIt = m_structs.find( type ); if ( ( structIt != m_structs.end() ) && listedStructs.insert( type ).second ) { auto [enter, leave] = generateProtection( getProtectFromTitle( title ) ); // append all allowed structure chains for ( auto extendName : structIt->second.structExtends ) { std::map::const_iterator itExtend = m_structs.find( extendName ); if ( itExtend == m_structs.end() ) { // look if the extendName acutally is an alias of some other structure auto aliasIt = m_structAliases.find( extendName ); if ( aliasIt != m_structAliases.end() ) { itExtend = m_structs.find( aliasIt->second.name ); assert( itExtend != m_structs.end() ); } } auto [subEnter, subLeave] = generateProtection( getProtectFromType( itExtend->first ) ); if ( enter != subEnter ) { str += subEnter; } str += " template <> struct StructExtends<" + stripPrefix( structIt->first, "Vk" ) + ", " + stripPrefix( extendName, "Vk" ) + ">{ enum { value = true }; };\n"; if ( leave != subLeave ) { str += subLeave; } } } } } return addTitleAndProtection( title, str ); } std::string VulkanHppGenerator::generateStructForwardDeclarations() const { const std::string fowardDeclarationsTemplate = R"( //=================================== //=== STRUCT forward declarations === //=================================== ${forwardDeclarations} )"; std::string forwardDeclarations; std::set listedStructs; for ( auto const & feature : m_features ) { forwardDeclarations += generateStructForwardDeclarations( feature.requireData, feature.name, listedStructs ); } for ( auto const & extension : m_extensions ) { forwardDeclarations += generateStructForwardDeclarations( extension.requireData, extension.name, listedStructs ); } return replaceWithMap( fowardDeclarationsTemplate, { { "forwardDeclarations", forwardDeclarations } } ); } std::string VulkanHppGenerator::generateStructForwardDeclarations( std::vector const & requireData, std::string const & title, std::set & listedStructs ) const { std::string str; for ( auto const & require : requireData ) { for ( auto const & type : require.types ) { auto structIt = m_structs.find( type ); if ( ( structIt != m_structs.end() ) && listedStructs.insert( type ).second ) { std::string structureType = stripPrefix( structIt->first, "Vk" ); str += ( structIt->second.isUnion ? " union " : " struct " ) + structureType + ";\n"; for ( auto const & alias : m_structAliases ) { if ( alias.second.name == type ) { str += " using " + stripPrefix( alias.first, "Vk" ) + " = " + structureType + ";\n"; } } } } } return addTitleAndProtection( title, str ); } std::tuple VulkanHppGenerator::generateStructMembers( std::pair const & structData ) const { std::string members, memberNames, memberTypes, sTypeValue; for ( auto const & member : structData.second.members ) { members += " "; std::string type; if ( !member.bitCount.empty() && member.type.type.starts_with( "Vk" ) ) { assert( member.type.prefix.empty() && member.type.postfix.empty() ); // never encounterd a different case type = member.type.type; } else if ( member.arraySizes.empty() ) { type = member.type.compose( "VULKAN_HPP_NAMESPACE" ); } else { assert( member.type.prefix.empty() && member.type.postfix.empty() ); type = generateStandardArrayWrapper( member.type.compose( "VULKAN_HPP_NAMESPACE" ), member.arraySizes ); } members += type + " " + member.name; if ( !member.value.empty() ) { // special handling for members with legal value: use it as the default members += " = "; if ( member.type.type == "uint32_t" ) { members += 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 ); members += 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() ) { members += " : " + member.bitCount; // except for bitfield members, where no default member initializatin // is supported (up to C++20) } else { members += " = "; auto enumIt = m_enums.find( member.type.type ); if ( member.arraySizes.empty() && ( enumIt != m_enums.end() ) && member.type.postfix.empty() ) { members += generateEnumInitializer( member.type, member.arraySizes, enumIt->second.values, enumIt->second.isBitmask ); } else { members += "{}"; } } } members += ";\n"; memberNames += member.name + ", "; memberTypes += type + " const &, "; } return std::make_tuple( members, stripPostfix( memberNames, ", " ), stripPostfix( memberTypes, ", " ), sTypeValue ); } std::string VulkanHppGenerator::generateStructSetter( std::string const & structureName, std::vector const & memberData, size_t index ) const { std::string str; MemberData const & member = memberData[index]; if ( member.type.type != "VkStructureType" ) // filter out StructureType, which is supposed to be immutable ! { static const std::string templateString = R"( ${constexpr}${structureName} & set${MemberName}( ${memberType} ${reference}${memberName}_ ) VULKAN_HPP_NOEXCEPT { ${assignment}; return *this; } )"; std::string memberType = member.arraySizes.empty() ? member.type.compose( "VULKAN_HPP_NAMESPACE" ) : generateStandardArray( member.type.compose( "VULKAN_HPP_NAMESPACE" ), member.arraySizes ); bool isReinterpretation = !member.bitCount.empty() && member.type.type.starts_with( "Vk" ); std::string assignment; if ( isReinterpretation ) { assignment = member.name + " = " + "*reinterpret_cast<" + member.type.type + "*>(&" + member.name + "_)"; } else { assignment = member.name + " = " + member.name + "_"; } str += replaceWithMap( templateString, { { "assignment", assignment }, { "constexpr", isReinterpretation ? "" : "VULKAN_HPP_CONSTEXPR_14 " }, { "memberName", member.name }, { "MemberName", startUpperCase( member.name ) }, { "memberType", memberType }, { "reference", ( member.type.postfix.empty() && m_structs.contains( member.type.type ) ) ? "const & " : "" }, { "structureName", structureName } } ); if ( hasLen( member ) ) { assert( member.name.front() == 'p' ); std::string arrayName = startLowerCase( stripPrefix( member.name, "p" ) ); std::string lenName, lenValue; if ( member.lenExpressions[0] == "codeSize / 4" ) { lenName = "codeSize"; lenValue = arrayName + "_.size() * 4"; } else { lenName = member.lenExpressions[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 \n "; size_t pos = memberType.find( "void" ); assert( pos != std::string::npos ); memberType.replace( pos, strlen( "void" ), "T" ); lenValue += " * sizeof(T)"; } auto lenMember = findStructMemberIt( lenName, memberData ); 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 const & structData ) const { if ( !structData.second.subStruct.empty() ) { auto const & subStruct = m_structs.find( structData.second.subStruct ); assert( subStruct != m_structs.end() ); std::string subStructArgumentName = startLowerCase( stripPrefix( subStruct->first, "Vk" ) ); std::string subCopies; bool firstArgument = true; for ( size_t i = 0; i < subStruct->second.members.size(); i++ ) { assert( structData.second.members[i].arraySizes.empty() ); static const std::string subCopiesTemplate = R"( ${separator} ${structMemberName}( ${subStructArgumentName}.${subStructMemberName} ) )"; subCopies += replaceWithMap( subCopiesTemplate, { { "separator", firstArgument ? ":" : "," }, { "structMemberName", structData.second.members[i].name }, { "subStructMemberName", subStruct->second.members[i].name }, { "subStructArgumentName", subStructArgumentName } } ); firstArgument = false; } std::string subArguments; bool listedArgument = true; for ( size_t i = subStruct->second.members.size(); i < structData.second.members.size(); i++ ) { std::string argument = generateStructConstructorArgument( listedArgument, structData.second.members[i], true ); if ( !argument.empty() ) { listedArgument = true; subArguments += argument; } assert( structData.second.members[i].arraySizes.empty() ); static const std::string subCopiesTemplate = R"( , ${memberName}( ${memberName}_ ) )"; subCopies += replaceWithMap( subCopiesTemplate, { { "memberName", structData.second.members[i].name } } ); } static const std::string subStructConstructorTemplate = R"( explicit ${structName}( ${subStructName} const & ${subStructArgumentName}${subArguments} ) ${subCopies} {} )"; return replaceWithMap( subStructConstructorTemplate, { { "structName", stripPrefix( structData.first, "Vk" ) }, { "subArguments", subArguments }, { "subCopies", subCopies }, { "subStructArgumentName", subStructArgumentName }, { "subStructName", stripPrefix( subStruct->first, "Vk" ) } } ); } return ""; } std::string VulkanHppGenerator::generateSuccessCheck( std::vector const & successCodes ) const { assert( !successCodes.empty() ); std::string successCheck = "result == " + generateSuccessCode( successCodes[0] ); if ( 1 < successCodes.size() ) { successCheck = "( " + successCheck + " )"; for ( size_t i = 1; i < successCodes.size(); ++i ) { successCheck += "|| ( result == " + generateSuccessCode( successCodes[i] ) + " )"; } } return successCheck; } std::string VulkanHppGenerator::generateSuccessCode( std::string const & code ) const { std::string tag = findTag( 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::string VulkanHppGenerator::generateSuccessCodeList( std::vector const & successCodes, bool enumerating ) const { std::string successCodeList; if ( ( 1 < successCodes.size() ) && !enumerating ) { successCodeList = ", { " + generateSuccessCode( successCodes[0] ); for ( size_t i = 1; i < successCodes.size(); ++i ) { successCodeList += ", " + generateSuccessCode( successCodes[i] ); } successCodeList += " }"; } return successCodeList; } std::string VulkanHppGenerator::generateThrowResultException() const { auto enumIt = m_enums.find( "VkResult" ); std::string cases; for ( auto const & value : enumIt->second.values ) { // only generate throw-functions for non-alias error codes if ( value.alias.empty() && value.name.starts_with( "VK_ERROR" ) ) { auto [enter, leave] = generateProtection( value.protect ); std::string valueName = generateEnumValueName( enumIt->first, value.name, false ); cases += enter + " case Result::" + valueName + ": throw " + stripPrefix( valueName, "eError" ) + "Error( message );\n" + leave; } } cases.pop_back(); // remove last newline const std::string throwTemplate = R"( namespace detail { [[noreturn]] VULKAN_HPP_INLINE void throwResultException( Result result, char const * message ) { switch ( result ) { ${cases} default: throw SystemError( make_error_code( result ), message ); } } })"; return replaceWithMap( throwTemplate, { { "cases", cases } } ); } std::string VulkanHppGenerator::generateTypenameCheck( std::vector const & returnParams, std::map const & vectorParams, std::vector const & chainedReturnParams, bool definition, std::vector const & dataTypes, CommandFlavourFlags flavourFlags ) const { std::string typenameCheck, enableIf; if ( !( flavourFlags & CommandFlavourFlagBits::singular ) && ( flavourFlags & CommandFlavourFlagBits::withAllocator ) ) { for ( size_t i = 0; i < returnParams.size(); ++i ) { if ( vectorParams.contains( returnParams[i] ) ) { std::string elementType = ( ( flavourFlags & CommandFlavourFlagBits::chained ) && std::any_of( chainedReturnParams.begin(), chainedReturnParams.end(), [&returnParams, i]( size_t crp ) { return crp == returnParams[i]; } ) ) ? "StructureChain" : stripPrefix( dataTypes[i], "VULKAN_HPP_NAMESPACE::" ); std::string extendedElementType = elementType; if ( flavourFlags & CommandFlavourFlagBits::unique ) { extendedElementType = "UniqueHandle<" + elementType + ", Dispatch>"; } std::string index = std::to_string( i ); if ( definition ) { typenameCheck += ", typename B" + index; } else { typenameCheck += ", typename B" + index + " = " + startUpperCase( elementType ) + "Allocator"; } enableIf += enableIf.empty() ? ", typename std::enable_if<" : " && "; enableIf += "std::is_same::value"; } } assert( !typenameCheck.empty() ); if ( !typenameCheck.empty() ) { typenameCheck += enableIf + ", int>::type"; if ( !definition ) { typenameCheck += " = 0"; } } } return typenameCheck; } std::string VulkanHppGenerator::generateUnion( std::pair const & structure ) const { auto [enter, leave] = generateProtection( getProtectFromType( structure.first ) ); std::string unionName = stripPrefix( structure.first, "Vk" ); bool firstMember = true; std::set listedTypes; // create just one constructor per different type ! std::string constructors; for ( auto memberIt = structure.second.members.begin(); memberIt != structure.second.members.end(); ++memberIt ) { if ( listedTypes.insert( memberIt->type ).second ) { // VkBool32 is aliased to uint32_t. Don't create a VkBool32 constructor if the union also contains a // uint32_t constructor. if ( memberIt->type.type == "VkBool32" ) { if ( findStructMemberItByType( "uint32_t", structure.second.members ) != structure.second.members.end() ) { continue; } } bool multipleType = std::any_of( std::next( memberIt ), structure.second.members.end(), [memberIt]( MemberData const & member ) { return member.type == memberIt->type; } ); std::string memberType = ( memberIt->arraySizes.empty() ) ? memberIt->type.compose( "VULKAN_HPP_NAMESPACE" ) : ( "const " + generateStandardArray( memberIt->type.compose( "VULKAN_HPP_NAMESPACE" ), memberIt->arraySizes ) + "&" ); // In a majority of cases this can be constexpr in C++11 as well, however, determining when exactly // that is the case is a lot more involved and probably not worth it. static const std::string constructorTemplate = R"( VULKAN_HPP_CONSTEXPR_14 ${unionName}( ${memberType} ${argumentName}_${defaultAssignment} ) : ${memberName}( ${argumentName}_ ) {})"; constructors += ( firstMember ? "" : "\n" ) + replaceWithMap( constructorTemplate, { { "argumentName", multipleType ? generateName( memberIt->type ) : memberIt->name }, { "defaultAssignment", firstMember ? " = {}" : "" }, { "memberName", memberIt->name }, { "memberType", memberType }, { "unionName", stripPrefix( structure.first, "Vk" ) } } ); firstMember = false; if ( !memberIt->arraySizes.empty() ) { assert( !multipleType ); assert( memberIt->arraySizes.size() == 1 ); int size = std::stoi( memberIt->arraySizes[0] ); assert( std::to_string( size ) == memberIt->arraySizes[0] ); std::string arguments, callArguments; bool firstArgument = true; for ( int i = 0; i < size; i++ ) { if ( !firstArgument ) { arguments += ", "; callArguments += ", "; } std::string argumentIndex = std::to_string( i ); arguments += memberIt->type.type + " " + memberIt->name + "_" + argumentIndex; callArguments += memberIt->name + "_" + argumentIndex; firstArgument = false; } static const std::string constructorBySequenceTemplate = R"( VULKAN_HPP_CONSTEXPR ${unionName}( ${arguments} ) : ${memberName}{ { { ${callArguments} } } } {})"; constructors += "\n" + replaceWithMap( constructorBySequenceTemplate, { { "arguments", arguments }, { "callArguments", callArguments }, { "memberName", memberIt->name }, { "unionName", stripPrefix( structure.first, "Vk" ) } } ); } } } // one setter per union element std::string setters; for ( size_t i = 0; i < structure.second.members.size(); i++ ) { setters += generateStructSetter( stripPrefix( structure.first, "Vk" ), structure.second.members, i ); } // filter out leading and trailing newline setters = setters.substr( 1, setters.length() - 2 ); // the union member variables std::string members; // if there's at least one Vk... type in this union, check for unrestricted unions support bool needsUnrestrictedUnions = std::any_of( structure.second.members.begin(), structure.second.members.end(), []( MemberData const & member ) { return member.type.type.starts_with( "Vk" ); } ); if ( needsUnrestrictedUnions ) { members += "#ifdef VULKAN_HPP_HAS_UNRESTRICTED_UNIONS\n"; } for ( auto const & member : structure.second.members ) { static const std::string memberTemplate = R"( ${memberType} ${memberName}; )"; members += replaceWithMap( memberTemplate, { { "memberName", member.name }, { "memberType", member.arraySizes.empty() ? member.type.compose( "VULKAN_HPP_NAMESPACE" ) : generateStandardArrayWrapper( member.type.compose( "VULKAN_HPP_NAMESPACE" ), member.arraySizes ) } } ); } if ( needsUnrestrictedUnions ) { members += "#else\n"; for ( auto const & member : structure.second.members ) { static const std::string memberTemplate = R"( ${memberType} ${memberName}${arraySizes}; )"; members += replaceWithMap( memberTemplate, { { "arraySizes", generateCArraySizes( member.arraySizes ) }, { "memberName", member.name }, { "memberType", member.type.compose( "" ) } } ); } members += "#endif /*VULKAN_HPP_HAS_UNRESTRICTED_UNIONS*/\n"; } static const std::string unionTemplate = R"( ${enter} union ${unionName} { using NativeType = Vk${unionName}; #if !defined( VULKAN_HPP_NO_UNION_CONSTRUCTORS ) ${constructors} #endif /*VULKAN_HPP_NO_UNION_CONSTRUCTORS*/ #if !defined( VULKAN_HPP_NO_UNION_SETTERS ) ${setters} #endif /*VULKAN_HPP_NO_UNION_SETTERS*/ operator Vk${unionName} const &() const { return *reinterpret_cast( this ); } operator Vk${unionName} &() { return *reinterpret_cast( this ); } ${members} }; ${leave})"; return replaceWithMap( unionTemplate, { { "constructors", constructors }, { "enter", enter }, { "leave", leave }, { "members", members }, { "setters", setters }, { "unionName", unionName } } ); } std::string VulkanHppGenerator::generateUniqueHandle( std::pair const & handleData ) const { if ( !handleData.second.deleteCommand.empty() ) { std::string type = stripPrefix( handleData.first, "Vk" ); std::string aliasHandle; auto aliasIt = findAlias( handleData.first, m_handleAliases ); if ( aliasIt != m_handleAliases.end() ) { static const std::string aliasHandleTemplate = R"( using Unique${aliasType} = UniqueHandle<${type}, VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>;)"; aliasHandle += replaceWithMap( aliasHandleTemplate, { { "aliasType", stripPrefix( aliasIt->first, "Vk" ) }, { "type", type } } ); } static const std::string uniqueHandleTemplate = R"( template class UniqueHandleTraits<${type}, Dispatch> { public: using deleter = ${deleterType}${deleterAction}<${deleterParent}${deleterPool}, Dispatch>; }; using Unique${type} = UniqueHandle<${type}, VULKAN_HPP_DEFAULT_DISPATCHER_TYPE>; ${aliasHandle})"; return replaceWithMap( uniqueHandleTemplate, { { "aliasHandle", aliasHandle }, { "deleterAction", ( handleData.second.deleteCommand.substr( 2, 4 ) == "Free" ) ? "Free" : "Destroy" }, { "deleterParent", handleData.second.deleteParent.empty() ? "NoParent" : stripPrefix( handleData.second.deleteParent, "Vk" ) }, { "deleterPool", handleData.second.deletePool.empty() ? "" : ", " + stripPrefix( handleData.second.deletePool, "Vk" ) }, { "deleterType", handleData.second.deletePool.empty() ? "Object" : "Pool" }, { "type", type } } ); } return ""; } std::string VulkanHppGenerator::generateUniqueHandle( std::vector const & requireData, std::string const & title ) const { std::string str; for ( auto const & require : requireData ) { for ( auto const & type : require.types ) { auto handleIt = m_handles.find( type ); if ( handleIt != m_handles.end() ) { str += generateUniqueHandle( *handleIt ); } } } return addTitleAndProtection( title, str ); } std::string VulkanHppGenerator::generateUniqueHandles() const { std::string uniqueHandlesTemplate = R"( #ifndef VULKAN_HPP_NO_SMART_HANDLE //====================== //=== UNIQUE HANDLEs === //====================== ${uniqueHandles} #endif /*VULKAN_HPP_NO_SMART_HANDLE*/ )"; std::string uniqueHandles; for ( auto const & feature : m_features ) { uniqueHandles += generateUniqueHandle( feature.requireData, feature.name ); } for ( auto const & extension : m_extensions ) { uniqueHandles += generateUniqueHandle( extension.requireData, extension.name ); } assert( uniqueHandles.back() == '\n' ); uniqueHandles.pop_back(); return replaceWithMap( uniqueHandlesTemplate, { { "uniqueHandles", uniqueHandles } } ); } std::string VulkanHppGenerator::generateVectorSizeCheck( std::string const & name, CommandData const & commandData, size_t initialSkipCount, std::map> const & countToVectorMap, std::set const & skippedParams, bool onlyThrows ) const { std::string const assertTemplate = " VULKAN_HPP_ASSERT( ${zeroSizeCheck}${firstVectorName}.size() == ${secondVectorName}.size() );"; std::string const assertTemplateVoid = " VULKAN_HPP_ASSERT( ${zeroSizeCheck}${firstVectorName}.size() * sizeof( ${firstDataType} ) == ${secondVectorName}.size() * sizeof( ${secondDataType} ) );"; std::string const assertTemplateSingle = " VULKAN_HPP_ASSERT( ${vectorName}.size() == ${sizeValue} );"; 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 const throwTemplateVoid = R"#( if ( ${zeroSizeCheck}${firstVectorName}.size() * sizeof( ${firstDataType} ) != ${secondVectorName}.size() * sizeof( ${secondDataType} ) ) { throw LogicError( VULKAN_HPP_NAMESPACE_STRING "::${className}::${commandName}: ${firstVectorName}.size() * sizeof( ${firstDataType} ) != ${secondVectorName}.size() * sizeof( ${secondDataType} )" ); })#"; std::string const throwTemplateSingle = R"#( if ( ${vectorName}.size() != ${sizeValue} ) { throw LogicError( VULKAN_HPP_NAMESPACE_STRING "::${className}::${commandName}: ${vectorName}.size() != ${sizeValue}" ); })#"; std::string className = stripPrefix( commandData.params[initialSkipCount - 1].type.type, "Vk" ); std::string commandName = generateCommandName( name, commandData.params, initialSkipCount ); std::string assertions, throws; for ( auto const & cvm : countToVectorMap ) { size_t defaultStartIndex = determineDefaultStartIndex( commandData.params, skippedParams ); std::string firstVectorName = startLowerCase( stripPrefix( commandData.params[cvm.second[0]].name, "p" ) ); if ( cvm.second.size() == 1 ) { std::string sizeValue; if ( isLenByStructMember( commandData.params[cvm.second[0]].lenExpression, commandData.params[cvm.first] ) ) { std::vector lenParts = tokenize( commandData.params[cvm.second[0]].lenExpression, "->" ); assert( lenParts.size() == 2 ); sizeValue = startLowerCase( stripPrefix( lenParts[0], "p" ) ) + "." + lenParts[1]; } else { assert( !commandData.params[cvm.second[0]].lenParams.empty() ); if ( commandData.params[cvm.first].type.type == "VkSampleCountFlagBits" ) { assert( commandData.params[cvm.second[0]].lenExpression == "(" + commandData.params[cvm.second[0]].lenParams[0].first + " + 31) / 32" ); sizeValue = "( static_cast( " + commandData.params[cvm.second[0]].lenParams[0].first + " ) + 31 ) / 32"; } else { sizeValue = commandData.params[cvm.second[0]].lenExpression; } } assertions += replaceWithMap( assertTemplateSingle, { { "sizeValue", sizeValue }, { "vectorName", firstVectorName } } ); throws += replaceWithMap( throwTemplateSingle, { { "className", className }, { "commandName", commandName }, { "sizeValue", sizeValue }, { "vectorName", firstVectorName } } ); } else { 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] ); if ( commandData.params[cvm.second[0]].type.type == "void" ) { assert( commandData.params[cvm.second[i]].type.type == "void" ); std::string firstDataType = stripPrefix( commandData.params[cvm.second[0]].name, "p" ) + "Type"; std::string secondDataType = stripPrefix( commandData.params[cvm.second[i]].name, "p" ) + "Type"; assertions += replaceWithMap( assertTemplateVoid, { { "firstDataType", firstDataType }, { "firstVectorName", firstVectorName }, { "secondDataType", secondDataType }, { "secondVectorName", secondVectorName }, { "zeroSizeCheck", withZeroSizeCheck ? ( secondVectorName + ".empty() || " ) : "" } } ); throws += replaceWithMap( throwTemplateVoid, { { "firstDataType", firstDataType }, { "firstVectorName", firstVectorName }, { "className", className }, { "commandName", commandName }, { "secondDataType", secondDataType }, { "secondVectorName", secondVectorName }, { "zeroSizeCheck", withZeroSizeCheck ? ( "!" + secondVectorName + ".empty() && " ) : "" } } ); } else { assertions += replaceWithMap( assertTemplate, { { "firstVectorName", firstVectorName }, { "secondVectorName", secondVectorName }, { "zeroSizeCheck", withZeroSizeCheck ? ( secondVectorName + ".empty() || " ) : "" } } ); throws += replaceWithMap( throwTemplate, { { "firstVectorName", firstVectorName }, { "className", className }, { "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*/)"; return onlyThrows ? throws : replaceWithMap( sizeCheckTemplate, { { "assertions", assertions }, { "throws", throws } } ); } VulkanHppGenerator::CommandData const & VulkanHppGenerator::getCommandData( std::string const & command ) const { auto commandIt = m_commands.find( command ); if ( commandIt == m_commands.end() ) { auto aliasIt = m_commandAliases.find( command ); assert( aliasIt != m_commandAliases.end() ); commandIt = m_commands.find( aliasIt->second.name ); assert( commandIt != m_commands.end() ); } return commandIt->second; } std::pair VulkanHppGenerator::getParentTypeAndName( std::pair const & handle ) const { std::string parentType, parentName; if ( handle.first == "VkInstance" ) { parentType = "Context"; parentName = "context"; } else { bool skip = skipLeadingGrandParent( handle ); assert( !handle.second.constructorIts.empty() && ( ( skip ? 1u : 0u ) < handle.second.constructorIts.front()->second.params.size() ) ); auto const & param = handle.second.constructorIts.front()->second.params[skip ? 1 : 0]; assert( isHandleType( param.type.type ) && param.type.isValue() ); parentType = stripPrefix( param.type.type, "Vk" ); parentName = param.name; } return std::make_pair( parentType, parentName ); } std::string VulkanHppGenerator::getPlatform( std::string const & title ) const { if ( !isSupportedFeature( title ) ) { auto extensionIt = findSupportedExtension( title ); assert( extensionIt != m_extensions.end() ); return extensionIt->platform; } return ""; } std::pair VulkanHppGenerator::getPoolTypeAndName( std::string const & type ) const { auto structIt = m_structs.find( type ); assert( structIt != m_structs.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::none_of( std::next( memberIt ), structIt->second.members.end(), []( MemberData const & md ) { return md.name.find( "Pool" ) != std::string::npos; } ) ); return std::make_pair( memberIt->type.type, memberIt->name ); } std::string VulkanHppGenerator::getProtectFromPlatform( std::string const & platform ) const { auto platformIt = m_platforms.find( platform ); return ( platformIt != m_platforms.end() ) ? platformIt->second.protect : ""; } std::string VulkanHppGenerator::getProtectFromTitle( std::string const & title ) const { if ( !isSupportedFeature( title ) ) { auto extensionIt = findSupportedExtension( title ); return ( extensionIt != m_extensions.end() ) ? getProtectFromPlatform( extensionIt->platform ) : ""; } return ""; } std::string VulkanHppGenerator::getProtectFromTitles( std::set const & titles ) const { for ( auto titleIt = titles.begin(); titleIt != titles.end(); ++titleIt ) { std::string protect = getProtectFromTitle( *titleIt ); if ( !protect.empty() ) { #if !defined( NDEBUG ) for ( titleIt = std::next( titleIt ); titleIt != titles.end(); ++titleIt ) { std::string p = getProtectFromTitle( *titleIt ); assert( p.empty() || ( p == protect ) ); } #endif return protect; } } return ""; } std::string VulkanHppGenerator::getProtectFromType( std::string const & type ) const { auto typeIt = m_types.find( type ); assert( typeIt != m_types.end() ); return getProtectFromTitles( typeIt->second.requiredBy ); } std::string VulkanHppGenerator::getVectorSize( std::vector const & params, std::map const & vectorParams, size_t returnParam, std::string const & returnParamType, std::set const & templatedParams ) const { std::string vectorSize; std::vector lenParts = tokenize( params[returnParam].lenExpression, "->" ); 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() ); // look for the len, not being the len of the return param, but of an other vector param auto lenVectorParamIt = std::find_if( vectorParams.begin(), vectorParams.end(), [&lenIdx, &returnParam]( auto const & vpi ) { return ( vpi.first != returnParam ) && ( vpi.second.lenParam == lenIdx ); } ); if ( lenVectorParamIt == vectorParams.end() ) { vectorSize = lenParts[0]; if ( templatedParams.contains( returnParam ) ) { vectorSize += " / sizeof( " + returnParamType + " )"; } } else { assert( !templatedParams.contains( returnParam ) ); vectorSize = startLowerCase( stripPrefix( params[lenVectorParamIt->first].name, "p" ) ) + ".size()"; } } break; case 2: assert( vectorParams.contains( returnParam ) ); vectorSize = startLowerCase( stripPrefix( lenParts[0], "p" ) ) + "." + lenParts[1]; break; default: assert( false ); break; } assert( !vectorSize.empty() ); return vectorSize; } void VulkanHppGenerator::handleRemoval( RemoveData const & removeData ) { for ( auto const & command : removeData.commands ) { bool removed = false; auto commandIt = m_commands.find( command ); if ( commandIt == m_commands.end() ) { auto aliasIt = m_commandAliases.find( command ); assert( aliasIt != m_commandAliases.end() ); commandIt = m_commands.find( aliasIt->second.name ); assert( commandIt != m_commands.end() ); } for ( auto const & requiredBy : commandIt->second.requiredBy ) { auto featureIt = std::find_if( m_features.begin(), m_features.end(), [&requiredBy]( FeatureData const & fd ) { return fd.name == requiredBy; } ); if ( featureIt != m_features.end() ) { removed |= handleRemovalCommand( command, featureIt->requireData ); } else { auto extensionIt = std::find_if( m_extensions.begin(), m_extensions.end(), [&requiredBy]( ExtensionData const & ed ) { return ed.name == requiredBy; } ); if ( extensionIt != m_extensions.end() ) { removed |= handleRemovalCommand( command, extensionIt->requireData ); } else { assert( m_unsupportedExtensions.contains( requiredBy ) ); removed = true; } } } checkForError( removed, commandIt->second.xmlLine, "to be removed command <" + commandIt->first + "> could not be removed" ); } for ( auto const & e : removeData.enums ) { bool removed = false; for ( auto enumIt = m_enums.begin(); !removed && enumIt != m_enums.end(); ++enumIt ) { auto valueIt = std::find_if( enumIt->second.values.begin(), enumIt->second.values.end(), [&e]( EnumValueData const evd ) { return evd.name == e; } ); if ( valueIt != enumIt->second.values.end() ) { enumIt->second.values.erase( valueIt ); removed = true; } } checkForError( removed, 0, "to be removed enum value <" + e + "> could not be removed" ); } for ( auto const & type : removeData.types ) { auto typeIt = m_types.find( type ); assert( typeIt != m_types.end() ); bool removed = typeIt->second.requiredBy.empty(); for ( auto const & requiredBy : typeIt->second.requiredBy ) { auto featureIt = std::find_if( m_features.begin(), m_features.end(), [&requiredBy]( FeatureData const & fd ) { return fd.name == requiredBy; } ); if ( featureIt != m_features.end() ) { removed |= handleRemovalType( type, featureIt->requireData ); } else { auto extensionIt = std::find_if( m_extensions.begin(), m_extensions.end(), [&requiredBy]( ExtensionData const & ed ) { return ed.name == requiredBy; } ); if ( extensionIt != m_extensions.end() ) { removed |= handleRemovalType( type, extensionIt->requireData ); } else { assert( m_unsupportedExtensions.contains( requiredBy ) ); removed = true; } } } checkForError( removed, typeIt->second.xmlLine, "to be removed type <" + typeIt->first + "> could not be removed" ); } } bool VulkanHppGenerator::handleRemovalCommand( std::string const & command, std::vector & requireData ) { bool removed = false; for ( auto requireDataIt = requireData.begin(); !removed && ( requireDataIt != requireData.end() ); ++requireDataIt ) { auto requireCommandIt = std::find( requireDataIt->commands.begin(), requireDataIt->commands.end(), command ); if ( requireCommandIt != requireDataIt->commands.end() ) { assert( std::none_of( std::next( requireCommandIt ), requireDataIt->commands.end(), [&command]( std::string const & requireCommand ) { return requireCommand == command; } ) ); requireDataIt->commands.erase( requireCommandIt ); assert( !requireDataIt->commands.empty() || !requireDataIt->types.empty() ); removed = true; #if !defined( NDEBUG ) for ( auto it = std::next( requireDataIt ); it != requireData.end(); ++it ) { assert( std::none_of( it->commands.begin(), it->commands.end(), [&command]( std::string const & requireCommand ) { return requireCommand == command; } ) ); } #endif } } return removed; } void VulkanHppGenerator::handleRemovals() { for ( auto const & feature : m_features ) { for ( auto const & removeData : feature.removeData ) { handleRemoval( removeData ); } } } bool VulkanHppGenerator::handleRemovalType( std::string const & type, std::vector & requireData ) { bool removed = false; for ( auto requireDataIt = requireData.begin(); !removed && ( requireDataIt != requireData.end() ); ) { auto requireTypeIt = std::find( requireDataIt->types.begin(), requireDataIt->types.end(), type ); if ( requireTypeIt != requireDataIt->types.end() ) { assert( std::none_of( std::next( requireTypeIt ), requireDataIt->types.end(), [&type]( std::string const & requireType ) { return requireType == type; } ) ); requireDataIt->types.erase( requireTypeIt ); requireDataIt = ( requireDataIt->commands.empty() && requireDataIt->types.empty() ) ? requireData.erase( requireDataIt ) : std::next( requireDataIt ); removed = true; #if !defined( NDEBUG ) for ( auto it = std::next( requireDataIt ); it != requireData.end(); ++it ) { assert( std::none_of( it->types.begin(), it->types.end(), [&type]( std::string const & requireType ) { return requireType == type; } ) ); } #endif } else { requireDataIt = std::next( requireDataIt ); } } return removed; } bool VulkanHppGenerator::hasLen( MemberData const & memberData ) const { assert( memberData.lenMembers.size() <= memberData.lenExpressions.size() ); return !memberData.lenMembers.empty() && ( ( memberData.lenExpressions[0] == memberData.lenMembers[0].first ) || ( memberData.lenExpressions[0] == ( memberData.lenMembers[0].first + " / 4" ) ) ); } bool VulkanHppGenerator::hasParentHandle( std::string const & handle, std::string const & parent ) const { std::string candidate = handle; while ( !candidate.empty() ) { auto const & handleIt = m_handles.find( candidate ); assert( handleIt != m_handles.end() ); if ( handleIt->second.parent == parent ) { return true; } else { candidate = handleIt->second.parent; } } return false; } bool VulkanHppGenerator::isDeviceCommand( CommandData const & commandData ) const { return !commandData.handle.empty() && !commandData.params.empty() && m_handles.contains( commandData.params[0].type.type ) && ( commandData.params[0].type.type != "VkInstance" ) && ( commandData.params[0].type.type != "VkPhysicalDevice" ); } bool VulkanHppGenerator::isExtension( std::string const & name ) const { return isSupportedExtension( name ) || m_unsupportedExtensions.contains( name ); } bool VulkanHppGenerator::isFeature( std::string const & name ) const { return isSupportedFeature( name ) || m_unsupportedFeatures.contains( name ); } bool VulkanHppGenerator::isHandleType( std::string const & type ) const { if ( type.starts_with( "Vk" ) ) { auto it = m_handles.find( type ); if ( it == m_handles.end() ) { auto aliasIt = m_handleAliases.find( type ); if ( aliasIt != m_handleAliases.end() ) { it = m_handles.find( aliasIt->second.name ); assert( it != m_handles.end() ); } } return ( it != m_handles.end() ); } return false; } bool VulkanHppGenerator::isLenByStructMember( std::string const & name, std::vector const & params ) const { // check if name specifies a member of a struct std::vector 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_structs.find( paramIt->type.type ); assert( structureIt != m_structs.end() ); assert( isStructMember( nameParts[1], structureIt->second.members ) ); #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 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_structs.find( param.type.type ); assert( structureIt != m_structs.end() ); assert( isStructMember( nameParts[1], structureIt->second.members ) ); #endif return true; } return false; } bool VulkanHppGenerator::isMultiSuccessCodeConstructor( std::vector::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 const & params ) const { return findParamIt( name, params ) != params.end(); } bool VulkanHppGenerator::isStructMember( std::string const & name, std::vector const & memberData ) const { return findStructMemberIt( name, memberData ) != memberData.end(); } bool VulkanHppGenerator::isStructureChainAnchor( std::string const & type ) const { if ( type.starts_with( "Vk" ) ) { auto it = m_structs.find( type ); if ( it == m_structs.end() ) { auto aliasIt = m_structAliases.find( type ); if ( aliasIt != m_structAliases.end() ) { it = m_structs.find( aliasIt->second.name ); } } if ( it != m_structs.end() ) { return m_extendedStructs.contains( it->first ); } } return false; } bool VulkanHppGenerator::isSupported( std::set const & requiredBy ) const { for ( auto const & r : requiredBy ) { if ( isSupportedFeature( r ) || isSupportedExtension( r ) ) { return true; } else { assert( m_unsupportedFeatures.contains( r ) || m_unsupportedExtensions.contains( r ) ); } } return false; } bool VulkanHppGenerator::isSupportedExtension( std::string const & name ) const { return std::any_of( m_extensions.begin(), m_extensions.end(), [&name]( ExtensionData const & ed ) { return ed.name == name; } ); } bool VulkanHppGenerator::isSupportedFeature( std::string const & name ) const { return std::any_of( m_features.begin(), m_features.end(), [&name]( FeatureData const & fd ) { return fd.name == name; } ); } bool VulkanHppGenerator::isTypeRequired( std::string const & type ) const { auto typeIt = m_types.find( type ); assert( typeIt != m_types.end() ); return !typeIt->second.requiredBy.empty(); } bool VulkanHppGenerator::isTypeUsed( std::string const & type ) const { auto typeIt = m_types.find( type ); assert( typeIt != m_types.end() ); for ( auto const & require : typeIt->second.requiredBy ) { auto featureIt = findFeature( require ); if ( featureIt != m_features.end() ) { for ( auto const & r : featureIt->requireData ) { if ( std::any_of( r.types.begin(), r.types.end(), [&type]( std::string const & requireType ) { return requireType == type; } ) ) { return true; } } } else { auto extensionIt = findSupportedExtension( require ); if ( extensionIt != m_extensions.end() ) { for ( auto const & r : extensionIt->requireData ) { if ( std::any_of( r.types.begin(), r.types.end(), [&type]( std::string const & requireType ) { return requireType == type; } ) ) { return true; } } } } } return false; } bool VulkanHppGenerator::needsStructureChainResize( std::map const & vectorParams, std::vector const & chainedReturnParams ) const { auto it = std::find_if( chainedReturnParams.begin(), chainedReturnParams.end(), [&vectorParams]( size_t crp ) { return vectorParams.contains( crp ); } ); // assert that there's no other chained vector param ! assert( ( it == chainedReturnParams.end() ) || std::none_of( std::next( it ), chainedReturnParams.end(), [&vectorParams]( size_t crp ) { return vectorParams.contains( crp ); } ) ); return ( it != chainedReturnParams.end() ); } std::pair>> VulkanHppGenerator::needsVectorSizeCheck( std::vector const & params, std::map const & vectorParams, std::vector const & returnParams, std::set const & singularParams, std::set const & skippedParams ) const { std::map> countToVectorMap; for ( auto const & vpi : vectorParams ) { if ( ( vpi.second.lenParam != INVALID_INDEX ) && std::none_of( returnParams.begin(), returnParams.end(), [&vpi]( size_t rp ) { return rp == vpi.first; } ) && ( !singularParams.contains( vpi.second.lenParam ) || isLenByStructMember( params[vpi.first].lenExpression, params[vpi.second.lenParam] ) ) ) { countToVectorMap[vpi.second.lenParam].push_back( vpi.first ); } } return std::make_pair( std::any_of( countToVectorMap.begin(), countToVectorMap.end(), [this, ¶ms, &skippedParams]( auto const & cvm ) { return ( 1 < cvm.second.size() ) || isLenByStructMember( params[cvm.second[0]].lenExpression, params[cvm.first] ) || std::none_of( params[cvm.second[0]].lenParams.begin(), params[cvm.second[0]].lenParams.end(), [&skippedParams]( std::pair const & lenParam ) { return skippedParams.contains( lenParam.second ); } ); } ), countToVectorMap ); } void VulkanHppGenerator::readCommand( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); auto aliasIt = attributes.find( "alias" ); if ( aliasIt != attributes.end() ) { checkAttributes( line, attributes, { { "alias", {} }, { "name", {} } }, {} ); std::string alias = aliasIt->second; std::string name = attributes.find( "name" )->second; checkForError( name.starts_with( "vk" ), line, "name <" + name + "> should begin with \"vk\"" ); checkForError( m_commands.contains( alias ), line, "command <" + name + "> is aliased to unknown command <" + alias + ">" ); checkForError( m_commandAliases.insert( { name, { alias, line } } ).second, line, "command <" + name + "> already specified as alias" ); } else { checkAttributes( line, attributes, {}, { { "api", { "vulkan", "vulkansc" } }, { "cmdbufferlevel", { "primary", "secondary" } }, { "comment", {} }, { "errorcodes", {} }, { "queues", { "compute", "decode", "encode", "graphics", "opticalflow", "sparse_binding", "transfer" } }, { "renderpass", { "both", "inside", "outside" } }, { "successcodes", {} }, { "tasks", { "action", "indirection", "state", "synchronization" } }, { "videocoding", { "both", "inside", "outside" } } } ); std::vector children = getChildElements( element ); checkElements( line, children, { { "param", false }, { "proto", true } }, { "implicitexternsyncparams" } ); CommandData commandData; commandData.xmlLine = line; std::string api; for ( auto const & attribute : attributes ) { if ( attribute.first == "api" ) { api = attribute.second; } else 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" ) { std::pair result = readCommandParam( child, commandData.params ); if ( result.first ) { commandData.params.push_back( result.second ); } } else if ( value == "proto" ) { std::tie( name, commandData.returnType ) = readCommandProto( child ); } } for ( auto & param : commandData.params ) { for ( auto & lenParam : param.lenParams ) { auto paramIt = findParamIt( lenParam.first, commandData.params ); checkForError( paramIt != commandData.params.end(), param.xmlLine, "param <" + param.name + "> uses unknown len parameter <" + lenParam.first + "> in its \"altlen\" attribute <" + param.lenExpression + ">" ); lenParam.second = std::distance( commandData.params.cbegin(), paramIt ); } if ( !param.strideParam.first.empty() ) { auto paramIt = findParamIt( param.strideParam.first, commandData.params ); checkForError( paramIt != commandData.params.end(), param.xmlLine, "param <" + param.name + "> uses unknown stride parameter <" + param.strideParam.first + ">" ); param.strideParam.second = std::distance( commandData.params.cbegin(), paramIt ); } } assert( !name.empty() ); checkForError( ( commandData.returnType == "VkResult" ) || commandData.errorCodes.empty(), line, "command <" + name + "> does not return a VkResult but specifies errorcodes" ); checkForError( ( commandData.returnType == "VkResult" ) || commandData.successCodes.empty(), line, "command <" + name + "> does not return a VkResult but specifies successcodes" ); if ( api.empty() || ( api == m_api ) ) { checkForError( !m_commands.contains( name ), line, "command <" + name + "> already specified" ); addCommand( name, commandData ); } } } std::pair VulkanHppGenerator::readCommandParam( tinyxml2::XMLElement const * element, std::vector const & params ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, {}, { { "altlen", {} }, { "api", { "vulkan", "vulkansc" } }, { "externsync", {} }, { "len", {} }, { "noautovalidity", { "true" } }, { "objecttype", { "objectType" } }, { "optional", { "false", "true" } }, { "stride", {} }, { "validstructs", {} } } ); ParamData paramData; paramData.xmlLine = line; std::string api; for ( auto attribute : attributes ) { if ( attribute.first == "altlen" ) { assert( paramData.lenExpression.empty() ); paramData.lenExpression = attribute.second; paramData.lenParams = filterNumbers( tokenizeAny( attribute.second, " /()+" ) ); } else if ( attribute.first == "api" ) { api = attribute.second; } else if ( attribute.first == "len" ) { if ( paramData.lenExpression.empty() ) { paramData.lenExpression = attribute.second; auto paramIt = findParamIt( attribute.second, params ); if ( paramIt != params.end() ) { paramData.lenParams.push_back( { attribute.second, std::distance( params.cbegin(), paramIt ) } ); } else { checkForError( ( attribute.second == "null-terminated" ) || isLenByStructMember( attribute.second, params ), line, "attribute holds an unknown value <" + attribute.second + ">" ); } } } else if ( attribute.first == "stride" ) { paramData.strideParam.first = attribute.second; } else if ( attribute.first == "optional" ) { paramData.optional = ( attribute.second == "true" ); } else if ( attribute.first == "validstructs" ) { std::vector validStructs = tokenize( attribute.second, "," ); for ( auto const & vs : validStructs ) { checkForError( m_structs.contains( vs ), line, "unknown struct <" + vs + "> listed in attribute " ); } } } NameData nameData; std::tie( nameData, paramData.type ) = readNameAndType( element ); checkForError( m_types.contains( paramData.type.type ), line, "unknown type <" + paramData.type.type + ">" ); checkForError( paramData.type.prefix.empty() || ( paramData.type.prefix == "const" ) || ( paramData.type.prefix == "const struct" ) || ( paramData.type.prefix == "struct" ), line, "unexpected type prefix <" + paramData.type.prefix + ">" ); checkForError( paramData.type.postfix.empty() || ( paramData.type.postfix == "*" ) || ( paramData.type.postfix == "**" ) || ( paramData.type.postfix == "* const *" ), line, "unexpected type postfix <" + paramData.type.postfix + ">" ); paramData.name = nameData.name; paramData.arraySizes = nameData.arraySizes; if ( api.empty() || ( api == m_api ) ) { checkForError( std::none_of( params.begin(), params.end(), [&name = nameData.name]( ParamData const & pd ) { return pd.name == name; } ), line, "command param <" + nameData.name + "> already used" ); } return std::make_pair( api.empty() || ( api == m_api ), paramData ); } std::pair VulkanHppGenerator::readCommandProto( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); checkAttributes( line, getAttributes( element ), {}, {} ); auto [nameData, typeInfo] = readNameAndType( element ); checkForError( nameData.name.starts_with( "vk" ), line, "name <" + nameData.name + "> does not begin with " ); checkForError( nameData.arraySizes.empty(), line, "name <" + nameData.name + "> with unsupported arraySizes" ); checkForError( m_types.contains( typeInfo.type ), line, "unknown type <" + typeInfo.type + ">" ); checkForError( typeInfo.prefix.empty(), line, "unexpected type prefix <" + typeInfo.prefix + ">" ); checkForError( typeInfo.postfix.empty(), line, "unexpected type postfix <" + typeInfo.postfix + ">" ); 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 children = getChildElements( element ); checkElements( line, children, { { "command", false } } ); for ( auto child : children ) { readCommand( child ); } } void VulkanHppGenerator::readEnums( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "name", {} } }, { { "bitwidth", { "64" } }, { "comment", {} }, { "type", { "bitmask", "enum" } } } ); std::vector 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 ) { readEnumsConstants( child ); } } else { checkElements( line, children, {}, { "comment", "enum", "unused" } ); checkForError( !type.empty(), line, "enum without type" ); // get the EnumData entry in enum map auto enumIt = m_enums.find( name ); if ( enumIt == m_enums.end() ) { auto aliasIt = m_enumAliases.find( name ); if ( aliasIt != m_enumAliases.end() ) { enumIt = m_enums.find( aliasIt->second.name ); } } checkForError( enumIt != m_enums.end(), line, "enum <" + name + "> is not listed as enum in the types section" ); checkForError( 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 ) { checkForError( 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 == "enum" ) { readEnumsEnum( child, enumIt ); } } } } void VulkanHppGenerator::readEnumsConstants( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkElements( line, getChildElements( element ), {} ); auto aliasIt = attributes.find( "alias" ); if ( aliasIt != attributes.end() ) { checkAttributes( line, attributes, { { "alias", {} }, { "name", {} } }, {} ); std::string alias = aliasIt->second; std::string name = attributes.find( "name" )->second; checkForError( m_constants.contains( alias ), line, "enum <" + name + "> is an alias of an unknown enum <" + alias + ">." ); checkForError( m_types.insert( { name, TypeData{ TypeCategory::Constant, {}, line } } ).second, line, "enum <" + name + "> already specified" ); assert( !m_constantAliases.contains( name ) ); m_constantAliases[name] = { alias, line }; } else { checkAttributes( line, attributes, { { "name", {} }, { "type", {} }, { "value", {} } }, { { "comment", {} } } ); std::string alias, name, type, value; for ( auto const & attribute : attributes ) { if ( attribute.first == "name" ) { name = attribute.second; checkForError( !m_constants.contains( name ), line, "already specified enum constant <" + name + ">" ); } else if ( attribute.first == "type" ) { type = attribute.second; } else if ( attribute.first == "value" ) { value = attribute.second; } } checkForError( m_types.insert( { name, TypeData{ TypeCategory::Constant, {}, line } } ).second, line, "enum <" + name + "> already specified" ); assert( !m_constants.contains( name ) ); m_constants[name] = { type, value, line }; } } void VulkanHppGenerator::readEnumsEnum( tinyxml2::XMLElement const * element, std::map::iterator enumIt ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); if ( attributes.contains( "alias" ) ) { checkAttributes( line, attributes, { { "alias", {} }, { "name", {} } }, { { "api", { "vulkan", "vulkansc" } }, { "comment", {} }, { "deprecated", { "aliased" } } } ); checkElements( line, getChildElements( element ), {} ); std::string alias, api, bitpos, name, value; for ( auto const & attribute : attributes ) { if ( attribute.first == "alias" ) { alias = attribute.second; } else if ( attribute.first == "api" ) { api = attribute.second; } else if ( attribute.first == "deprecated" ) { // the enum value is marked as deprecated/aliased but still exisits -> no modifications needed here } else if ( attribute.first == "name" ) { name = attribute.second; } } assert( !name.empty() ); if ( api.empty() || ( api == m_api ) ) { enumIt->second.addEnumAlias( line, name, alias, "", true ); } } else { checkAttributes( line, attributes, { { "name", {} } }, { { "bitpos", {} }, { "comment", {} }, { "value", {} } } ); checkElements( line, getChildElements( element ), {} ); std::string alias, bitpos, name, 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 == "value" ) { value = attribute.second; } } std::string prefix = generateEnumSuffixes( enumIt->first, enumIt->second.isBitmask ).first; checkForError( name.starts_with( prefix ), line, "encountered enum value <" + name + "> that does not begin with expected prefix <" + prefix + ">" ); checkForError( bitpos.empty() ^ value.empty(), line, "both or none of \"bitpos\" and \"value\" are set for enum <" + name + "> which is invalid" ); enumIt->second.addEnumValue( line, name, "", bitpos, value, true ); } } void VulkanHppGenerator::readExtensionRequire( tinyxml2::XMLElement const * element, ExtensionData & extensionData, bool extensionSupported ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, {}, { { "api", { "vulkansc" } }, { "comment", {} }, { "depends", {} } } ); std::vector children = getChildElements( element ); checkElements( line, children, {}, { "command", "comment", "enum", "type" } ); RequireData requireData{ .xmlLine = line }; std::string api; for ( auto const & attribute : attributes ) { if ( attribute.first == "api" ) { api = attribute.second; } else if ( attribute.first == "depends" ) { assert( requireData.depends.empty() ); requireData.depends = attribute.second; checkForError( std::none_of( extensionData.requireData.begin(), extensionData.requireData.end(), [&requireData]( RequireData const & rd ) { return rd.depends == requireData.depends; } ), line, "required extension <" + requireData.depends + "> already listed" ); } } bool requireSupported = api.empty() || ( api == m_api ); for ( auto child : children ) { std::string value = child->Value(); if ( value == "command" ) { requireData.commands.push_back( readRequireCommand( child, extensionData.name ) ); } else if ( value == "enum" ) { readRequireEnum( child, extensionData.name, extensionData.platform, extensionSupported && requireSupported, requireData ); } else if ( value == "type" ) { requireData.types.push_back( readRequireType( child, extensionData.name ) ); } } if ( requireSupported && ( !requireData.commands.empty() || !requireData.types.empty() ) ) { extensionData.requireData.push_back( requireData ); } } void VulkanHppGenerator::readExtensions( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); checkAttributes( line, getAttributes( element ), { { "comment", {} } }, {} ); std::vector children = getChildElements( element ); checkElements( line, children, { { "extension", false } } ); for ( auto child : children ) { readExtension( child ); } } void VulkanHppGenerator::readExtension( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); std::vector children = getChildElements( element ); checkAttributes( line, attributes, { { "name", {} }, { "number", {} }, { "supported", { "disabled", "vulkan", "vulkansc" } } }, { { "author", {} }, { "comment", {} }, { "contact", {} }, { "depends", {} }, { "deprecatedby", {} }, { "obsoletedby", {} }, { "platform", {} }, { "promotedto", {} }, { "provisional", { "true" } }, { "ratified", { "vulkan", "vulkansc" } }, { "sortorder", { "1" } }, { "specialuse", { "cadsupport", "d3demulation", "debugging", "devtools", "glemulation" } }, { "type", { "device", "instance" } } } ); checkElements( line, children, { { "require", false } } ); ExtensionData extensionData{ .xmlLine = line }; std::vector ratified, supported; for ( auto const & attribute : attributes ) { if ( attribute.first == "depends" ) { // currently, we map the few complex depends attributes to a canonical format! const std::map complexToCanonicalDepends = { { "(VK_EXT_filter_cubic)+(VK_VERSION_1_2,VK_EXT_sampler_filter_minmax)", "VK_EXT_filter_cubic+VK_EXT_sampler_filter_minmax,VK_VERSION_1_2+VK_EXT_filter_cubic" }, { "VK_KHR_swapchain+VK_KHR_get_surface_capabilities2+(VK_KHR_get_physical_device_properties2,VK_VERSION_1_1)", "VK_KHR_swapchain+VK_KHR_get_surface_capabilities2+VK_KHR_get_physical_device_properties2,VK_VERSION_1_1+VK_KHR_swapchain+VK_KHR_get_surface_capabilities2" }, { "((VK_KHR_bind_memory2+VK_KHR_get_physical_device_properties2+VK_KHR_sampler_ycbcr_conversion),VK_VERSION_1_1)+(VK_KHR_image_format_list,VK_VERSION_1_2)", "VK_KHR_bind_memory2+VK_KHR_get_physical_device_properties2+VK_KHR_sampler_ycbcr_conversion+VK_KHR_image_format_list,VK_VERSION_1_1+VK_KHR_image_format_list,VK_VERSION_1_2" }, { "VK_KHR_swapchain+(VK_KHR_maintenance2,VK_VERSION_1_1)+(VK_KHR_image_format_list,VK_VERSION_1_2)", "VK_KHR_swapchain+VK_KHR_maintenance2+VK_KHR_image_format_list,VK_VERSION_1_1+VK_KHR_swapchain+VK_KHR_image_format_list,VK_VERSION_1_2+VK_KHR_swapchain" }, { "(VK_KHR_create_renderpass2,VK_VERSION_1_2)+(VK_KHR_get_physical_device_properties2,VK_VERSION_1_1)", "VK_KHR_create_renderpass2+VK_KHR_get_physical_device_properties2,VK_VERSION_1_1+VK_KHR_create_renderpass2,VK_VERSION_1_2" }, { "(VK_KHR_get_physical_device_properties2+VK_KHR_device_group),VK_VERSION_1_1", "VK_KHR_get_physical_device_properties2+VK_KHR_device_group,VK_VERSION_1_1" }, { "(VK_KHR_get_physical_device_properties2,VK_VERSION_1_1)+(VK_KHR_dynamic_rendering,VK_VERSION_1_3)", "VK_KHR_get_physical_device_properties2+VK_KHR_dynamic_rendering,VK_VERSION_1_1+VK_KHR_dynamic_rendering,VK_VERSION_1_3" } }; auto canonicalIt = complexToCanonicalDepends.find( attribute.second ); std::string depends; if ( canonicalIt == complexToCanonicalDepends.end() ) { depends = attribute.second; std::erase_if( depends, []( char c ) { return ( c == '(' ) || ( c == ')' ); } ); } else { depends = canonicalIt->second; } // first tokenize by ',', giving a vector of dependencies for different vulkan versions std::vector allDependencies = tokenize( depends, "," ); for ( auto dep : allDependencies ) { // for ease of handling, prepend the (optional) VK_VERSION_1_0 if ( !dep.starts_with( "VK_VERSION" ) ) { assert( dep.find( "VK_VERSION" ) == std::string::npos ); dep = "VK_VERSION_1_0+" + dep; } // then tokenize by '+', giving a vector of dependendies for the vulkan version listed as the first element here std::vector dependsByVersion = tokenize( dep, "+" ); extensionData.depends[dependsByVersion[0]].push_back( { std::next( dependsByVersion.begin() ), dependsByVersion.end() } ); } } else if ( attribute.first == "deprecatedby" ) { extensionData.deprecatedBy = attribute.second; extensionData.isDeprecated = true; } else if ( attribute.first == "name" ) { extensionData.name = attribute.second; checkForError( !isExtension( extensionData.name ), line, "already encountered extension <" + extensionData.name + ">" ); } else if ( attribute.first == "number" ) { extensionData.number = attribute.second; } else if ( attribute.first == "obsoletedby" ) { extensionData.obsoletedBy = attribute.second; } else if ( attribute.first == "platform" ) { extensionData.platform = attribute.second; checkForError( m_platforms.contains( extensionData.platform ), line, "unknown platform <" + extensionData.platform + ">" ); } else if ( attribute.first == "promotedto" ) { extensionData.promotedTo = attribute.second; } else if ( attribute.first == "provisional" ) { if ( extensionData.platform.empty() ) { // for now, having the attribute provisional="true" implies attribute platform="provisional" to get // stuff protected by VK_ENABLE_BETA_EXTENSIONS extensionData.platform = "provisional"; } checkForError( extensionData.platform == "provisional", line, "while attribute is set to \"true\", attribute is not set to \"provisional\" but to \"" + extensionData.platform + "\"" ); } else if ( attribute.first == "ratified" ) { ratified = tokenize( attribute.second, "," ); } else if ( attribute.first == "supported" ) { supported = tokenize( attribute.second, "," ); } else if ( attribute.first == "type" ) { extensionData.type = attribute.second; } } checkForWarning( std::any_of( supported.begin(), supported.end(), []( std::string const & s ) { return s == "disabled"; } ) || extensionData.isDeprecated || ratified.empty() || ( supported == ratified ), line, "attribute \"ratified\" differs from attribute \"supported\"" ); bool extensionSupported = supported.empty() || std::any_of( supported.begin(), supported.end(), [this]( std::string const & s ) { return s == m_api; } ); checkForError( !extensionSupported || !extensionData.type.empty(), line, "missing attribute \"type\" for supported extension <" + extensionData.name + ">" ); for ( auto child : children ) { readExtensionRequire( child, extensionData, extensionSupported ); } if ( std::none_of( supported.begin(), supported.end(), []( std::string const & s ) { return s == "disabled"; } ) ) { // extract the tag from the name, which is supposed to look like VK__ size_t tagStart = extensionData.name.find( '_' ); checkForError( tagStart != std::string::npos, line, "name <" + extensionData.name + "> is missing an underscore '_'" ); size_t tagEnd = extensionData.name.find( '_', tagStart + 1 ); checkForError( tagEnd != std::string::npos, line, "name <" + extensionData.name + "> is missing an underscore '_'" ); std::string tag = extensionData.name.substr( tagStart + 1, tagEnd - tagStart - 1 ); checkForError( ( m_tags.find( tag ) != m_tags.end() ), line, "name <" + extensionData.name + "> is using an unknown tag <" + tag + ">" ); } if ( extensionSupported ) { m_extensions.push_back( extensionData ); } else { checkForError( m_unsupportedExtensions.insert( extensionData.name ).second, line, "unsupported extension <" + extensionData.name + "> already specified" ); } } void VulkanHppGenerator::readFeature( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "api", { "vulkan", "vulkansc" } }, { "comment", {} }, { "name", {} }, { "number", {} } }, {} ); std::vector children = getChildElements( element ); checkElements( line, children, { { "require", false } }, { "remove" } ); FeatureData featureData; featureData.xmlLine = line; std::vector api; std::string modifiedNumber; for ( auto const & attribute : attributes ) { if ( attribute.first == "api" ) { api = tokenize( attribute.second, "," ); } else if ( attribute.first == "name" ) { featureData.name = attribute.second; } else if ( attribute.first == "number" ) { featureData.number = attribute.second; modifiedNumber = featureData.number; std::replace( modifiedNumber.begin(), modifiedNumber.end(), '.', '_' ); } } bool featureSupported = std::any_of( api.begin(), api.end(), [this]( std::string const & a ) { return a == m_api; } ); for ( auto child : children ) { std::string value = child->Value(); if ( value == "remove" ) { featureData.removeData.push_back( readFeatureRemove( child ) ); } else if ( value == "require" ) { featureData.requireData.push_back( readFeatureRequire( child, featureData.name, featureSupported ) ); } } checkForError( featureData.name == ( std::any_of( api.begin(), api.end(), []( std::string const & a ) { return a == "vulkan"; } ) ? "VK_VERSION_" : "VKSC_VERSION_" ) + modifiedNumber, line, "unexpected formatting of name <" + featureData.name + ">" ); checkForError( !isFeature( featureData.name ), line, "feature <" + featureData.name + "> already specified" ); if ( featureSupported ) { m_features.push_back( featureData ); } else { m_unsupportedFeatures.insert( featureData.name ); } } VulkanHppGenerator::RemoveData VulkanHppGenerator::readFeatureRemove( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); checkAttributes( line, getAttributes( element ), {}, { { "comment", {} } } ); std::vector children = getChildElements( element ); checkElements( line, children, {}, { "command", "enum", "type" } ); RemoveData removeData; removeData.xmlLine = line; for ( auto child : children ) { std::string value = child->Value(); if ( value == "command" ) { removeData.commands.push_back( readName( child ) ); } else if ( value == "enum" ) { removeData.enums.push_back( readName( child ) ); } else if ( value == "type" ) { removeData.types.push_back( readName( child ) ); } } return removeData; } VulkanHppGenerator::RequireData VulkanHppGenerator::readFeatureRequire( tinyxml2::XMLElement const * element, std::string const & featureName, bool featureSupported ) { int line = element->GetLineNum(); checkAttributes( line, getAttributes( element ), {}, { { "comment", {} } } ); std::vector children = getChildElements( element ); checkElements( line, children, {}, { "command", "comment", "enum", "type" } ); RequireData requireData{ .xmlLine = line }; for ( auto child : children ) { std::string value = child->Value(); if ( value == "command" ) { requireData.commands.push_back( readRequireCommand( child, featureName ) ); } else if ( value == "enum" ) { readRequireEnum( child, featureName, "", featureSupported, requireData ); } else if ( value == "type" ) { requireData.types.push_back( readRequireType( child, featureName ) ); } } return requireData; } void VulkanHppGenerator::readFormat( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "blockSize", { "1", "2", "3", "4", "5", "6", "8", "12", "16", "24", "32" } }, { "class", {} }, { "name", {} }, { "texelsPerBlock", { "1", "16", "20", "25", "30", "36", "40", "48", "50", "60", "64", "80", "100", "120", "144" } } }, { { "blockExtent", { "1", "2", "4", "5", "6", "8", "10", "12" } }, { "chroma", { "420", "422", "444" } }, { "compressed", { "ASTC HDR", "ASTC LDR", "BC", "EAC", "ETC", "ETC2", "PVRTC" } }, { "packed", { "8", "16", "32" } } } ); std::vector children = getChildElements( element ); checkElements( line, children, { { "component", false } }, { "plane", "spirvimageformat" } ); FormatData format; format.xmlLine = line; std::string name; for ( auto const & attribute : attributes ) { if ( attribute.first == "blockExtent" ) { checkForError( tokenize( attribute.second, "," ).size() == 3, line, "unexpected number of elements in attribute " ); format.blockExtent = attribute.second; } if ( attribute.first == "blockSize" ) { format.blockSize = attribute.second; } else if ( attribute.first == "chroma" ) { format.chroma = attribute.second; } else if ( attribute.first == "class" ) { format.classAttribute = attribute.second; } else if ( attribute.first == "compressed" ) { format.compressed = attribute.second; } else if ( attribute.first == "name" ) { name = attribute.second; } else if ( attribute.first == "packed" ) { format.packed = attribute.second; } else if ( attribute.first == "texelsPerBlock" ) { format.texelsPerBlock = attribute.second; } } for ( auto child : children ) { std::string value = child->Value(); if ( value == "component" ) { readFormatComponent( child, format ); } else if ( value == "plane" ) { readFormatPlane( child, format ); } else if ( value == "spirvimageformat" ) { readFormatSPIRVImageFormat( child, format ); } } if ( format.components.front().bits == "compressed" ) { for ( auto componentIt = std::next( format.components.begin() ); componentIt != format.components.end(); ++componentIt ) { checkForError( componentIt->bits == "compressed", line, "component is expected to be marked as compressed in attribute " ); } } if ( !format.components.front().planeIndex.empty() ) { for ( auto componentIt = std::next( format.components.begin() ); componentIt != format.components.end(); ++componentIt ) { checkForError( !componentIt->planeIndex.empty(), line, "component is expected to have a planeIndex" ); } size_t planeCount = 1 + std::stoi( format.components.back().planeIndex ); checkForError( format.planes.size() == planeCount, line, "number of planes does not fit to largest planeIndex of the components" ); } auto formatIt = m_enums.find( "VkFormat" ); assert( formatIt != m_enums.end() ); auto valueIt = std::find_if( formatIt->second.values.begin(), formatIt->second.values.end(), [&name]( EnumValueData const & evd ) { return evd.name == name; } ); if ( valueIt != formatIt->second.values.end() ) { checkForError( m_formats.insert( { name, format } ).second, line, "format <" + name + "> already specified" ); } else { checkForError( std::any_of( formatIt->second.unsupportedValues.begin(), formatIt->second.unsupportedValues.end(), [&name]( EnumValueData const & evd ) { return evd.name == name; } ), line, "unknown format <" + name + ">" ); } } void VulkanHppGenerator::readFormatComponent( tinyxml2::XMLElement const * element, FormatData & formatData ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "bits", { "1", "2", "4", "5", "6", "8", "9", "10", "11", "12", "16", "24", "32", "64", "compressed" } }, { "name", {} }, { "numericFormat", { "SFLOAT", "SINT", "SNORM", "SRGB", "SSCALED", "UFLOAT", "UINT", "UNORM", "USCALED" } } }, { { "planeIndex", { "0", "1", "2" } } } ); checkElements( line, getChildElements( element ), {} ); formatData.components.emplace_back(); ComponentData & component = formatData.components.back(); component.xmlLine = line; for ( auto const & attribute : attributes ) { if ( attribute.first == "bits" ) { checkForError( ( attribute.second != "compressed" ) || !formatData.compressed.empty(), line, "component of a not compressed format is marked as compressed" ); component.bits = attribute.second; } else if ( attribute.first == "name" ) { component.name = attribute.second; } else if ( attribute.first == "numericFormat" ) { component.numericFormat = attribute.second; } else if ( attribute.first == "planeIndex" ) { component.planeIndex = attribute.second; } } } void VulkanHppGenerator::readFormatPlane( tinyxml2::XMLElement const * element, FormatData & formatData ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "compatible", {} }, { "index", { "0", "1", "2" } }, { "heightDivisor", { "1", "2" } }, { "widthDivisor", { "1", "2" } } }, {} ); checkElements( line, getChildElements( element ), {} ); formatData.planes.emplace_back(); PlaneData & plane = formatData.planes.back(); plane.xmlLine = line; for ( auto const & attribute : attributes ) { if ( attribute.first == "compatible" ) { plane.compatible = attribute.second; auto formatIt = m_enums.find( "VkFormat" ); assert( formatIt != m_enums.end() ); checkForError( std::any_of( formatIt->second.values.begin(), formatIt->second.values.end(), [&plane]( EnumValueData const & evd ) { return evd.name == plane.compatible; } ), line, "encountered unknown format <" + plane.compatible + ">" ); } else if ( attribute.first == "index" ) { size_t index = std::stoi( attribute.second ); checkForError( index + 1 == formatData.planes.size(), line, "unexpected index <" + attribute.second + ">" ); } else if ( attribute.first == "heightDivisor" ) { plane.heightDivisor = attribute.second; } else if ( attribute.first == "widthDivisor" ) { plane.widthDivisor = attribute.second; } } } void VulkanHppGenerator::readFormats( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); checkAttributes( line, getAttributes( element ), {}, {} ); std::vector children = getChildElements( element ); checkElements( line, children, { { "format", false } } ); for ( auto child : children ) { readFormat( child ); } } void VulkanHppGenerator::readFormatSPIRVImageFormat( tinyxml2::XMLElement const * element, FormatData & formatData ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "name", {} } }, {} ); checkElements( line, getChildElements( element ), {} ); std::string name = attributes.find( "name" )->second; checkForError( formatData.spirvImageFormat.empty(), line, "spirvimageformat <" + name + "> already specified" ); formatData.spirvImageFormat = name; } std::string VulkanHppGenerator::readName( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "name", {} } }, {} ); checkElements( line, getChildElements( element ), {} ); return attributes.find( "name" )->second; } std::pair VulkanHppGenerator::readNameAndType( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::vector children = getChildElements( element ); checkElements( line, children, { { "name", true } }, { { "enum" }, { "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 == "enum" ) { nameData.arraySizes.push_back( child->GetText() ); checkForError( child->PreviousSibling() && ( strcmp( child->PreviousSibling()->Value(), "[" ) == 0 ) && child->NextSibling() && ( strcmp( child->NextSibling()->Value(), "]" ) == 0 ), line, std::string( "array specifiation is ill-formatted: <" ) + nameData.arraySizes.back() + ">" ); checkForError( m_constants.contains( nameData.arraySizes.back() ), line, "using unknown enum value <" + nameData.arraySizes.back() + ">" ); } else if ( value == "name" ) { nameData.name = child->GetText(); std::string bitCount; std::tie( nameData.arraySizes, bitCount ) = readModifiers( child->NextSibling() ); checkForError( 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 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; } else if ( attribute.first == "protect" ) { protect = attribute.second; } } checkForError( std::none_of( m_platforms.begin(), m_platforms.end(), [&protect]( std::pair const & p ) { return p.second.protect == protect; } ), line, "protect <" + protect + "> of platform <" + name + "> is already used with some other platform" ); checkForError( m_platforms.insert( { name, { protect, line } } ).second, line, "platform <" + name + "> is already specified" ); } void VulkanHppGenerator::readPlatforms( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); checkAttributes( line, getAttributes( element ), { { "comment", {} } }, {} ); std::vector 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 children = getChildElements( element ); checkElements( line, children, { { "commands", true }, { "comment", false }, { "enums", false }, { "extensions", true }, { "feature", false }, { "formats", true }, { "platforms", true }, { "spirvcapabilities", true }, { "spirvextensions", true }, { "sync", 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 ) { m_vulkanLicenseHeader = generateCopyrightMessage( comment ); } } else if ( value == "enums" ) { readEnums( child ); } else if ( value == "extensions" ) { readExtensions( child ); } else if ( value == "feature" ) { readFeature( child ); } else if ( value == "formats" ) { readFormats( child ); } else if ( value == "platforms" ) { readPlatforms( child ); } else if ( value == "spirvcapabilities" ) { readSPIRVCapabilities( child ); } else if ( value == "spirvextensions" ) { readSPIRVExtensions( child ); } else if ( value == "sync" ) { readSync( child ); } else if ( value == "tags" ) { readTags( child ); } else if ( value == "types" ) { readTypes( child ); } } } std::string VulkanHppGenerator::readRequireCommand( tinyxml2::XMLElement const * element, std::string const & requiredBy ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "name", {} } }, { { "comment", {} } } ); checkElements( line, getChildElements( element ), {} ); std::string name = attributes.find( "name" )->second; auto commandIt = m_commands.find( name ); if ( commandIt == m_commands.end() ) { auto aliasIt = m_commandAliases.find( name ); checkForError( aliasIt != m_commandAliases.end(), line, "unknown required command <" + name + ">" ); commandIt = m_commands.find( aliasIt->second.name ); assert( commandIt != m_commands.end() ); } commandIt->second.requiredBy.insert( requiredBy ); return name; } void VulkanHppGenerator::readRequireEnum( tinyxml2::XMLElement const * element, std::string const & requiredBy, std::string const & platform, bool supported, RequireData & requireData ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkElements( line, getChildElements( element ), {} ); if ( attributes.contains( "alias" ) ) { checkAttributes( line, attributes, { { "alias", {} }, { "name", {} } }, { { "api", { "vulkan", "vulkansc" } }, { "comment", {} }, { "deprecated", { "aliased" } }, { "extends", {} } } ); std::string alias, api, extends, name; for ( auto const & attribute : attributes ) { if ( attribute.first == "alias" ) { alias = attribute.second; } else if ( attribute.first == "api" ) { api = attribute.second; } else if ( attribute.first == "extends" ) { extends = attribute.second; } else if ( attribute.first == "name" ) { name = attribute.second; } } if ( extends.empty() ) { checkForError( m_types.insert( { name, TypeData{ TypeCategory::Constant, { requiredBy }, line } } ).second, line, "required enum <" + name + "> already specified" ); assert( !m_constantAliases.contains( name ) ); m_constantAliases[name] = { alias, line }; } else { auto typeIt = m_types.find( extends ); checkForError( typeIt != m_types.end(), line, "enum value <" + name + "> extends unknown type <" + extends + ">" ); checkForError( typeIt->second.category == TypeCategory::Enum, line, "enum value <" + name + "> extends non-enum type <" + extends + ">" ); typeIt->second.requiredBy.insert( requiredBy ); auto enumIt = m_enums.find( extends ); assert( enumIt != m_enums.end() ); enumIt->second.addEnumAlias( line, name, alias, getProtectFromPlatform( platform ), ( api.empty() || ( api == m_api ) ) && supported ); } } else { checkAttributes( line, attributes, { { "name", {} } }, { { "api", { "vulkan", "vulkansc" } }, { "bitpos", {} }, { "comment", {} }, { "dir", { "-" } }, { "extends", {} }, { "extnumber", {} }, { "offset", {} }, { "protect", { "VK_ENABLE_BETA_EXTENSIONS" } }, { "value", {} } } ); std::string api, bitpos, extends, name, offset, protect, value; for ( auto const & attribute : attributes ) { if ( attribute.first == "api" ) { api = attribute.second; } else if ( attribute.first == "bitpos" ) { bitpos = attribute.second; } 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() ) { if ( value.empty() ) { auto typeIt = m_types.find( name ); checkForError( typeIt != m_types.end(), line, "unknown required enum <" + name + ">" ); typeIt->second.requiredBy.insert( requiredBy ); requireData.constants.push_back( name ); } else { if ( api.empty() || ( api == m_api ) ) { checkForError( m_types.insert( { name, TypeData{ TypeCategory::Constant, { requiredBy }, line } } ).second, line, "required enum <" + name + "> specified by value <" + value + "> is already specified" ); } } } else { checkForError( bitpos.empty() + offset.empty() + value.empty() == 2, line, "exactly one out of bitpos = <" + bitpos + ">, offset = <" + offset + ">, and value = <" + value + "> are supposed to be empty" ); auto typeIt = m_types.find( extends ); checkForError( typeIt != m_types.end(), line, "enum value <" + name + "> extends unknown type <" + extends + ">" ); checkForError( typeIt->second.category == TypeCategory::Enum, line, "enum value <" + name + "> extends non-enum type <" + extends + ">" ); typeIt->second.requiredBy.insert( requiredBy ); auto enumIt = m_enums.find( extends ); assert( enumIt != m_enums.end() ); enumIt->second.addEnumValue( line, name, protect.empty() ? getProtectFromPlatform( platform ) : protect, bitpos + offset, value, ( api.empty() || ( api == m_api ) ) && supported ); } } } std::string VulkanHppGenerator::readRequireType( tinyxml2::XMLElement const * element, std::string const & requiredBy ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "name", {} } }, { { "comment", {} } } ); checkElements( line, getChildElements( element ), {} ); std::string name = attributes.find( "name" )->second; auto typeIt = m_types.find( name ); checkForError( typeIt != m_types.end(), line, "unknown required type <" + name + ">" ); typeIt->second.requiredBy.insert( requiredBy ); return name; } void VulkanHppGenerator::readSPIRVCapability( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "name", {} } }, {} ); std::vector children = getChildElements( element ); checkElements( line, children, {}, { "enable" } ); for ( auto child : children ) { readSPIRVCapabilityEnable( child ); } } void VulkanHppGenerator::readSPIRVCapabilityEnable( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkElements( line, getChildElements( element ), {}, {} ); if ( attributes.contains( "extension" ) ) { checkAttributes( line, attributes, { { "extension", {} } }, {} ); std::string const & extension = attributes.find( "extension" )->second; checkForError( isExtension( extension ), line, "unknown extension <" + extension + "> specified for SPIR-V capability" ); } else if ( attributes.contains( "property" ) ) { checkAttributes( line, 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 require = tokenize( attribute.second, "," ); for ( auto const & r : require ) { checkForError( isFeature( r ) || isExtension( r ), line, "unknown requires <" + r + "> specified for SPIR-V capability" ); } } else if ( attribute.first == "value" ) { value = attribute.second; } } auto propertyIt = m_structs.find( property ); checkForError( propertyIt != m_structs.end(), line, "unknown property <" + property + "> specified for SPIR-V capability" ); auto memberIt = findStructMemberIt( member, propertyIt->second.members ); checkForError( memberIt != propertyIt->second.members.end(), line, "unknown member <" + member + "> specified for SPIR-V capability" ); if ( memberIt->type.type == "VkBool32" ) { checkForError( ( value == "VK_FALSE" ) || ( value == "VK_TRUE" ), line, "unknown value <" + value + "> for boolean member <" + member + "> specified for SPIR-V capability" ); } else { auto bitmaskIt = m_bitmasks.find( memberIt->type.type ); checkForError( bitmaskIt != m_bitmasks.end(), line, "member <" + member + "> specified for SPIR-V capability is not a bitmask" ); checkForError( !bitmaskIt->second.require.empty(), line, "member <" + member + "> specified for SPIR-V capability has no required enum" ); auto enumIt = m_enums.find( bitmaskIt->second.require ); checkForError( enumIt != m_enums.end(), line, "member <" + member + "> specified for SPIR-V capability requires an unknown enum <" + bitmaskIt->second.require + ">" ); checkForError( std::any_of( enumIt->second.values.begin(), enumIt->second.values.end(), [&value]( EnumValueData const & evd ) { return evd.name == value; } ) || std::any_of( enumIt->second.unsupportedValues.begin(), enumIt->second.unsupportedValues.end(), [&value]( EnumValueData const & evd ) { return evd.name == value; } ), line, "unknown attribute value <" + value + "> specified for SPIR-V capability" ); } } else if ( attributes.contains( "struct" ) ) { checkAttributes( line, attributes, { { "feature", {} }, { "struct", {} } }, { { "alias", {} }, { "requires", {} } } ); for ( auto const & attribute : attributes ) { if ( attribute.first == "requires" ) { std::vector require = tokenize( attribute.second, "," ); for ( auto const & r : require ) { checkForError( isFeature( r ) || isExtension( r ), line, "unknown requires <" + r + "> specified for SPIR-V capability" ); } } else if ( attribute.first == "struct" ) { checkForError( m_structs.contains( attribute.second ) || m_structAliases.contains( attribute.second ), line, "unknown structure <" + attribute.second + "> specified for SPIR-V capability" ); } } } else if ( attributes.contains( "version" ) ) { checkAttributes( line, attributes, { { "version", {} } }, {} ); std::string version = attributes.find( "version" )->second; if ( version.starts_with( "VK_API_" ) ) { version.erase( 3, 4 ); // remove "API_" from the version -> VK_VERSION_x_y } checkForError( isFeature( version ), line, "unknown version <" + version + "> specified for SPIR-V capability" ); } } void VulkanHppGenerator::readSPIRVCapabilities( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "comment", {} } }, {} ); std::vector children = getChildElements( element ); checkElements( line, children, {}, { "spirvcapability" } ); for ( auto child : children ) { readSPIRVCapability( child ); } } void VulkanHppGenerator::readSPIRVExtension( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "name", {} } }, {} ); std::vector children = getChildElements( element ); checkElements( line, children, {}, { "enable" } ); for ( auto child : children ) { readSPIRVExtensionEnable( child ); } } void VulkanHppGenerator::readSPIRVExtensionEnable( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, {}, { { "extension", {} }, { "version", {} } } ); checkElements( line, getChildElements( element ), {}, {} ); for ( auto const & attribute : attributes ) { if ( attribute.first == "extension" ) { checkForError( isExtension( attribute.second ), line, "unknown extension <" + attribute.second + "> specified for SPIR-V extension" ); } else { assert( attribute.first == "version" ); std::string feature = attribute.second; if ( feature.starts_with( "VK_API_" ) ) { feature.erase( 3, 4 ); // remove "API_" from the version -> VK_VERSION_x_y } checkForError( isFeature( feature ), line, "unknown version <" + attribute.second + "> specified for SPIR-V extension" ); } } } void VulkanHppGenerator::readSPIRVExtensions( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "comment", {} } }, {} ); std::vector children = getChildElements( element ); checkElements( line, children, {}, { "spirvextension" } ); for ( auto child : children ) { readSPIRVExtension( child ); } } void VulkanHppGenerator::readStructMember( tinyxml2::XMLElement const * element, std::vector & members, bool isUnion ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, {}, { { "altlen", {} }, { "api", { "vulkan", "vulkansc" } }, { "deprecated", { "ignored" } }, { "externsync", { "true" } }, { "len", {} }, { "limittype", { "bitmask", "bits", "exact", "max", "min", "mul", "noauto", "pot", "range", "struct" } }, { "noautovalidity", { "true" } }, { "objecttype", { "objectType" } }, { "optional", { "false", "true" } }, { "selection", {} }, { "selector", {} }, { "values", {} } } ); std::vector children = getChildElements( element ); checkElements( line, children, { { "name", true }, { "type", true } }, { "comment", "enum" } ); MemberData memberData; memberData.xmlLine = line; std::string api; for ( auto const & attribute : attributes ) { if ( attribute.first == "api" ) { api = attribute.second; } else if ( attribute.first == "altlen" ) { assert( memberData.lenExpressions.empty() ); memberData.lenExpressions = tokenize( attribute.second, "," ); checkForError( memberData.lenExpressions.size() == 1, line, "member attribute holds unknown number of data: " + std::to_string( memberData.lenExpressions.size() ) ); memberData.lenMembers = filterNumbers( tokenizeAny( attribute.second, " /()+*" ) ); } else if ( attribute.second == "deprecated" ) { assert( false ); // the struct member is marked as deprecated/ignored, but still exisits -> no modifications needed here } else if ( attribute.first == "len" ) { if ( memberData.lenExpressions.empty() ) { memberData.lenExpressions = tokenize( attribute.second, "," ); checkForError( !memberData.lenExpressions.empty() && ( memberData.lenExpressions.size() <= 2 ), line, "member attribute holds unknown number of data: " + std::to_string( memberData.lenExpressions.size() ) ); if ( memberData.lenExpressions[0] != "null-terminated" ) { auto lenMemberIt = findStructMemberIt( memberData.lenExpressions[0], members ); checkForError( lenMemberIt != members.end(), line, "member attribute holds unknown value <" + memberData.lenExpressions[0] + ">" ); checkForError( lenMemberIt->type.prefix.empty(), line, "member attribute references a member of unexpected type <" + lenMemberIt->type.compose( "VULKAN_HPP_NAMESPACE" ) + ">" ); memberData.lenMembers.push_back( { memberData.lenExpressions[0], std::distance( members.cbegin(), lenMemberIt ) } ); } if ( 1 < memberData.lenExpressions.size() ) { checkForError( ( memberData.lenExpressions[1] == "1" ) || ( memberData.lenExpressions[1] == "null-terminated" ), line, "member attribute holds unknown second value <" + memberData.lenExpressions[1] + ">" ); } } } else if ( attribute.first == "noautovalidity" ) { memberData.noAutoValidity = ( attribute.second == "true" ); } else if ( attribute.first == "optional" ) { std::vector 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" ) { checkForError( isUnion, line, "attribute is used with a non-union structure." ); memberData.selection = tokenize( attribute.second, "," ); } else if ( attribute.first == "selector" ) { memberData.selector = attribute.second; auto selectorIt = findStructMemberIt( memberData.selector, members ); checkForError( selectorIt != members.end(), line, "member attribute holds unknown value <" + memberData.selector + ">" ); checkForError( m_enums.contains( selectorIt->type.type ), line, "member attribute references unknown enum type <" + selectorIt->type.type + ">" ); } else if ( attribute.first == "values" ) { std::vector values = tokenize( attribute.second, "," ); checkForError( values.size() == 1, line, "attribute \"values\" holds multiple values <" + attribute.first + ">, but it's expected to hold just one" ); memberData.value = values[0]; } } std::string name; for ( auto child : children ) { int childLine = child->GetLineNum(); checkAttributes( childLine, getAttributes( child ), {}, {} ); checkElements( childLine, getChildElements( child ), {}, {} ); std::string value = child->Value(); if ( value == "enum" ) { std::string enumString = child->GetText(); checkForError( child->PreviousSibling() && ( strcmp( child->PreviousSibling()->Value(), "[" ) == 0 ) && child->NextSibling() && ( strcmp( child->NextSibling()->Value(), "]" ) == 0 ), line, std::string( "struct member array specifiation is ill-formatted: <" ) + enumString + ">" ); memberData.arraySizes.push_back( enumString ); } else if ( value == "name" ) { name = child->GetText(); std::tie( memberData.arraySizes, memberData.bitCount ) = readModifiers( child->NextSibling() ); } else if ( value == "type" ) { memberData.type = readTypeInfo( child ); } } assert( !name.empty() ); if ( api.empty() || ( api == m_api ) ) { checkForError( std::none_of( members.begin(), members.end(), [&name]( MemberData const & md ) { return md.name == name; } ), line, "struct member name <" + name + "> already used" ); memberData.name = name; members.push_back( memberData ); } } void VulkanHppGenerator::readSync( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); checkAttributes( line, getAttributes( element ), { { "comment", {} } }, {} ); std::vector children = getChildElements( element ); checkElements( line, children, { { "syncaccess", false }, { "syncpipeline", false }, { "syncstage", false } }, {} ); auto accessFlagBitsIt = m_enums.find( "VkAccessFlagBits" ); assert( accessFlagBitsIt != m_enums.end() ); auto accessFlagBits2It = m_enums.find( "VkAccessFlagBits2" ); assert( accessFlagBits2It != m_enums.end() ); auto stageFlagBitsIt = m_enums.find( "VkPipelineStageFlagBits" ); assert( stageFlagBitsIt != m_enums.end() ); auto stageFlagBits2It = m_enums.find( "VkPipelineStageFlagBits2" ); assert( stageFlagBits2It != m_enums.end() ); for ( auto child : children ) { std::string value = child->Value(); if ( value == "syncaccess" ) { readSyncAccess( child, accessFlagBitsIt, accessFlagBits2It, stageFlagBits2It ); } else if ( value == "syncpipeline" ) { readSyncPipeline( child ); } else { assert( value == "syncstage" ); readSyncStage( child, stageFlagBitsIt, stageFlagBits2It ); } } } void VulkanHppGenerator::readSyncAccess( tinyxml2::XMLElement const * element, std::map::const_iterator accessFlagBitsIt, std::map::const_iterator accessFlagBits2It, std::map::const_iterator stageFlagBits2It ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "name", {} } }, { { "alias", {} } } ); std::vector children = getChildElements( element ); checkElements( line, children, {}, { "comment", "syncequivalent", "syncsupport" } ); EnumValueData const * aliasPtr = nullptr; for ( auto const & attribute : attributes ) { if ( attribute.first == "alias" ) { aliasPtr = findEnumValueData( accessFlagBitsIt, attribute.second ); checkForError( aliasPtr != nullptr, line, "syncaccess alias <" + attribute.second + "> not specified as a VkAccessFlagBits value!" ); } else { assert( attribute.first == "name" ); auto namePtr = findEnumValueData( accessFlagBits2It, attribute.second ); checkForError( namePtr != nullptr, line, "syncaccess name <" + attribute.second + "> not specified as a VkAccessFlagBits value!" ); if ( aliasPtr != nullptr ) { checkForError( ( aliasPtr->value == namePtr->value ) && ( aliasPtr->bitpos == namePtr->bitpos ), line, "syncaccess name <" + attribute.second + "> has an alias <" + aliasPtr->name + "> with a different value or bitpos!" ); } } } for ( auto child : children ) { std::string value = child->Value(); if ( value == "syncequivalent" ) { readSyncAccessEquivalent( child, accessFlagBits2It ); } else if ( value == "syncsupport" ) { readSyncAccessSupport( child, stageFlagBits2It ); } } } void VulkanHppGenerator::readSyncAccessEquivalent( tinyxml2::XMLElement const * element, std::map::const_iterator accessFlagBits2It ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "access", {} } }, {} ); checkElements( line, getChildElements( element ), {}, {} ); for ( auto const & attribute : attributes ) { assert( attribute.first == "access" ); std::vector access = tokenize( attribute.second, "," ); for ( auto const & a : access ) { checkForError( findEnumValueData( accessFlagBits2It, a ) != nullptr, line, "syncequivalent access uses unknown value <" + a + ">!" ); } } } void VulkanHppGenerator::readSyncAccessSupport( tinyxml2::XMLElement const * element, std::map::const_iterator stageFlagBits2It ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "stage", {} } }, {} ); checkElements( line, getChildElements( element ), {}, {} ); for ( auto const & attribute : attributes ) { if ( attribute.first == "stage" ) { std::vector stage = tokenize( attribute.second, "," ); for ( auto const & s : stage ) { checkForError( findEnumValueData( stageFlagBits2It, s ) != nullptr, line, "syncsupport stage uses unknown value <" + s + ">!" ); } } } } void VulkanHppGenerator::readSyncPipeline( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "name", {} } }, { { "depends", {} } } ); std::vector children = getChildElements( element ); checkElements( line, children, { { "syncpipelinestage", false } }, {} ); for ( auto const & attribute : attributes ) { if ( attribute.first == "depends" ) { std::vector depends = tokenize( attribute.second, "," ); for ( auto const & d : depends ) { checkForError( std::any_of( m_extensions.begin(), m_extensions.end(), [&d]( ExtensionData const & ed ) { return ed.name == d; } ) || m_unsupportedExtensions.contains( d ), line, "syncpipeline depends on unknown extension <" + d + ">" ); } } } } void VulkanHppGenerator::readSyncStage( tinyxml2::XMLElement const * element, std::map::const_iterator stageFlagBitsIt, std::map::const_iterator stageFlagBits2It ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "name", {} } }, { { "alias", {} } } ); std::vector children = getChildElements( element ); checkElements( line, children, {}, { "syncequivalent", "syncsupport" } ); EnumValueData const * aliasPtr = nullptr; for ( auto const & attribute : attributes ) { if ( attribute.first == "alias" ) { aliasPtr = findEnumValueData( stageFlagBitsIt, attribute.second ); checkForError( aliasPtr != nullptr, line, "syncstage alias <" + attribute.second + "> not specified as a VkPipelineStageFlagBits value!" ); } else { assert( attribute.first == "name" ); auto namePtr = findEnumValueData( stageFlagBits2It, attribute.second ); checkForError( namePtr != nullptr, line, "syncstage name <" + attribute.second + "> not specified as a VkPipelineStageFlagBits2 value!" ); if ( aliasPtr != nullptr ) { checkForError( ( aliasPtr->value == namePtr->value ) && ( aliasPtr->bitpos == namePtr->bitpos ), line, "syncstate name <" + attribute.second + "> has an alias <" + aliasPtr->name + "> with a different value or bitpos!" ); } } } for ( auto child : children ) { std::string value = child->Value(); if ( value == "syncequivalent" ) { readSyncStageEquivalent( child, stageFlagBits2It ); } else { assert( value == "syncsupport" ); readSyncStageSupport( child ); } } } void VulkanHppGenerator::readSyncStageEquivalent( tinyxml2::XMLElement const * element, std::map::const_iterator stageFlagBits2It ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "stage", {} } }, {} ); checkElements( line, getChildElements( element ), {}, {} ); for ( auto const & attribute : attributes ) { assert( attribute.first == "stage" ); std::vector stage = tokenize( attribute.second, "," ); for ( auto const & s : stage ) { checkForError( findEnumValueData( stageFlagBits2It, s ) != nullptr, line, "syncequivalent stage uses unknown value <" + s + ">!" ); } } } void VulkanHppGenerator::readSyncStageSupport( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); checkAttributes( line, getAttributes( element ), { { "queues", { "compute", "decode", "encode", "graphics", "opticalflow", "transfer" } } }, {} ); checkElements( line, getChildElements( element ), {}, {} ); } void VulkanHppGenerator::readTag( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); checkAttributes( line, attributes, { { "author", {} }, { "contact", {} }, { "name", {} } }, {} ); checkElements( line, getChildElements( element ), {} ); std::string name = attributes.find( "name" )->second; checkForError( m_tags.insert( { name, { line } } ).second, line, "tag <" + name + "> already specified" ); } void VulkanHppGenerator::readTags( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); checkAttributes( line, getAttributes( element ), { { "comment", {} } }, {} ); std::vector children = getChildElements( element ); checkElements( line, children, { { "tag", false } } ); for ( auto child : children ) { readTag( child ); } } void VulkanHppGenerator::readTypeBasetype( tinyxml2::XMLElement const * element, std::map 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(); } checkForError( nameData.arraySizes.empty(), line, "name <" + nameData.name + "> with unsupported arraySizes" ); checkForError( typeInfo.prefix.empty(), line, "unexpected type prefix <" + typeInfo.prefix + ">" ); checkForError( typeInfo.postfix.empty() || ( typeInfo.postfix == "*" ), line, "unexpected type postfix <" + typeInfo.postfix + ">" ); checkForError( m_types.insert( { nameData.name, TypeData{ TypeCategory::BaseType, {}, line } } ).second, line, "basetype <" + nameData.name + "> already specified" ); assert( !m_baseTypes.contains( nameData.name ) ); m_baseTypes[nameData.name] = { typeInfo, line }; } void VulkanHppGenerator::readTypeBitmask( tinyxml2::XMLElement const * element, std::map const & attributes ) { int line = element->GetLineNum(); auto aliasIt = attributes.find( "alias" ); if ( aliasIt != attributes.end() ) { checkAttributes( line, attributes, { { "alias", {} }, { "category", { "bitmask" } }, { "name", {} } }, {} ); checkElements( line, getChildElements( element ), {} ); std::string alias = aliasIt->second; std::string name = attributes.find( "name" )->second; checkForError( m_bitmasks.contains( alias ), line, "bitmask <" + name + "> is an alias of an unknown bitmask <" + alias + ">." ); checkForError( m_types.insert( { name, TypeData{ TypeCategory::Bitmask, {}, line } } ).second, line, "bitmask <" + name + "> already specified" ); assert( !m_bitmaskAliases.contains( name ) ); m_bitmaskAliases[name] = { alias, line }; } else { checkAttributes( line, attributes, { { "category", { "bitmask" } } }, { { "api", { "vulkan", "vulkansc" } }, { "bitvalues", {} }, { "requires", {} } } ); std::string api, bitvalues, require; for ( auto const & attribute : attributes ) { if ( attribute.first == "api" ) { api = attribute.second; } else if ( attribute.first == "bitvalues" ) { bitvalues = attribute.second; } else if ( attribute.first == "requires" ) { require = attribute.second; } } NameData nameData; TypeInfo typeInfo; std::tie( nameData, typeInfo ) = readNameAndType( element ); checkForError( nameData.name.starts_with( "Vk" ), line, "name <" + nameData.name + "> does not begin with " ); checkForError( nameData.arraySizes.empty(), line, "name <" + nameData.name + "> with unsupported arraySizes" ); checkForWarning( ( typeInfo.type == "VkFlags" ) || ( typeInfo.type == "VkFlags64" ), line, "unexpected bitmask type <" + typeInfo.type + ">" ); checkForError( typeInfo.prefix == "typedef", line, "unexpected type prefix <" + typeInfo.prefix + ">" ); checkForError( typeInfo.postfix.empty(), line, "unexpected type postfix <" + typeInfo.postfix + ">" ); checkForError( bitvalues.empty() || require.empty(), line, "attributes and are both specified" ); checkForError( ( typeInfo.type != "VkFlags64" ) || !bitvalues.empty(), line, "bitmask of type needs attribute bitvalues to be set" ); if ( !bitvalues.empty() ) { require = bitvalues; } if ( api.empty() || ( api == m_api ) ) { checkForError( m_types.insert( { nameData.name, TypeData{ TypeCategory::Bitmask, {}, line } } ).second, line, "bitmask <" + nameData.name + "> already specified" ); assert( !m_bitmasks.contains( nameData.name ) ); m_bitmasks[nameData.name] = { require, typeInfo.type, line }; } } } VulkanHppGenerator::DefinesPartition VulkanHppGenerator::partitionDefines( std::map const & defines ) { DefinesPartition partition{}; for ( auto const & define : defines ) { // VK_DEFINE_HANDLE is macro magic that cannot be constexpr-ed // Also filter out the VKSC_ macros, as although they are in the spec, they are not defined in any header. if ( define.first.starts_with( "VK_" ) && ( define.first != "VK_DEFINE_HANDLE" ) ) { if ( define.second.possibleCallee.empty() ) { if ( define.second.possibleDefinition.empty() ) { #if !defined( NDEBUG ) const std::set ignoredDefines{ "VK_DEFINE_NON_DISPATCHABLE_HANDLE", "VK_NULL_HANDLE", "VK_USE_64_BIT_PTR_DEFINES" }; #endif assert( ignoredDefines.contains( define.first ) ); } else { if ( define.second.params.empty() ) { partition.values.insert( define ); } else { partition.callees.insert( define ); } } } else { assert( !define.second.params.empty() && define.second.possibleDefinition.empty() ); partition.callers.insert( define ); } } } return partition; } void VulkanHppGenerator::readTypeDefine( tinyxml2::XMLElement const * element, std::map const & attributes ) { int line = element->GetLineNum(); checkAttributes( line, attributes, { { "category", { "define" } } }, { { "api", { "vulkan", "vulkansc" } }, { "comment", {} }, { "deprecated", { "true" } }, { "name", {} }, { "requires", {} } } ); std::string api, name, require; bool deprecated = false; for ( auto const & attribute : attributes ) { if ( attribute.first == "api" ) { api = attribute.second; } else if ( attribute.first == "deprecated" ) { assert( attribute.second == "true" ); deprecated = true; } else if ( attribute.first == "name" ) { name = attribute.second; } else if ( attribute.first == "requires" ) { require = attribute.second; } } if ( !name.empty() ) { checkForError( !element->FirstChildElement(), line, "unknown formatting of type category=define name <" + name + ">" ); checkForError( 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() ) ) { assert( false ); std::string text = element->LastChild()->ToText()->Value(); size_t start = text.find( "#if defined(__LP64__)" ); checkForError( start != std::string::npos, line, "unexpected text in type category=define named <" + name + ">" ); size_t end = text.find_first_of( "\r\n", start + 1 ); checkForError( 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! assert( false ); tinyxml2::XMLElement const * child = element->FirstChildElement(); checkForError( child && ( strcmp( child->Value(), "name" ) == 0 ) && child->GetText(), line, "unexpected formatting of type category=define" ); name = child->GetText(); checkForError( m_types.insert( std::make_pair( name, TypeData{ .category = TypeCategory::Define } ) ).second, line, "type <" + name + "> has already been speficied" ); } else { tinyxml2::XMLElement const * child = element->FirstChildElement(); checkForError( 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" ) && ( api.empty() || ( api == m_api ) ) ) { m_version = trimEnd( element->LastChild()->ToText()->Value() ); } // ignore all the other defines checkForWarning( !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() ); if ( api.empty() || ( api == m_api ) ) { MacroVisitor definesVisitor{}; element->Accept( &definesVisitor ); auto const & [deprecatedReason, possibleCallee, params, possibleDefinition] = parseMacro( definesVisitor.macro ); checkForError( m_types.insert( { name, TypeData{ TypeCategory::Define, {}, line } } ).second, line, "define <" + name + "> already specified" ); assert( !m_defines.contains( name ) ); m_defines[name] = { deprecated, require, line, deprecatedReason, possibleCallee, params, possibleDefinition }; } } void VulkanHppGenerator::readTypeEnum( tinyxml2::XMLElement const * element, std::map 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; } else if ( attribute.first == "name" ) { name = attribute.second; } } checkForError( m_types.insert( { name, TypeData{ TypeCategory::Enum, {}, line } } ).second, line, "enum <" + name + "> already specified" ); if ( alias.empty() ) { assert( !m_enums.contains( name ) ); m_enums[name] = EnumData{ .xmlLine = line }; } else { checkForError( m_enumAliases.insert( { name, { alias, line } } ).second, line, "enum <" + name + "> already specified as some alias" ); } } void VulkanHppGenerator::readTypeFuncpointer( tinyxml2::XMLElement const * element, std::map const & attributes ) { int line = element->GetLineNum(); checkAttributes( line, attributes, { { "category", { "funcpointer" } } }, { { "requires", {} } } ); std::vector children = getChildElements( element ); checkElements( line, children, { { "name", true } }, { "type" } ); std::string require; for ( auto const & attribute : attributes ) { if ( attribute.first == "requires" ) { require = attribute.second; } } std::string name; std::vector arguments; for ( auto const & child : children ) { std::string value = child->Value(); if ( value == "name" ) { name = child->GetText(); } else if ( value == "type" ) { int argumentLine = child->GetLineNum(); std::string type = child->GetText(); 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( ",)" ) ); checkForError( std::none_of( arguments.begin(), arguments.end(), [&argumentName]( FuncPointerArgumentData const & argument ) { return argument.name == argumentName; } ), line, "argument <" + argumentName + "> already listed in funcpointer <" + name + ">" ); arguments.push_back( { argumentName, type, argumentLine } ); } } assert( !name.empty() ); std::set argumentNames; checkForError( m_types.insert( { name, TypeData{ TypeCategory::FuncPointer, {}, line } } ).second, line, "funcpointer <" + name + "> already specified" ); assert( !m_funcPointers.contains( name ) ); m_funcPointers[name] = { arguments, require, line }; } void VulkanHppGenerator::readTypeHandle( tinyxml2::XMLElement const * element, std::map 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 ), {} ); std::string alias = aliasIt->second; std::string name = attributes.find( "name" )->second; checkForError( m_handles.contains( alias ), line, "handle <" + name + "> uses unknown alias <" + alias + ">." ); checkForError( m_types.insert( { name, TypeData{ TypeCategory::Handle, {}, line } } ).second, line, "handle <" + name + "> already specified" ); assert( !m_handleAliases.contains( name ) ); m_handleAliases[name] = { alias, line }; } else { checkAttributes( line, attributes, { { "category", { "handle" } }, { "objtypeenum", {} } }, { { "parent", {} } } ); HandleData handleData; handleData.xmlLine = line; for ( auto const & attribute : attributes ) { if ( attribute.first == "objtypeenum" ) { handleData.objTypeEnum = attribute.second; } else if ( attribute.first == "parent" ) { handleData.parent = attribute.second; } } NameData nameData; TypeInfo typeInfo; std::tie( nameData, typeInfo ) = readNameAndType( element ); handleData.isDispatchable = typeInfo.type == "VK_DEFINE_HANDLE"; checkForError( nameData.name.starts_with( "Vk" ), line, "name <" + nameData.name + "> does not begin with " ); checkForError( nameData.arraySizes.empty(), line, "name <" + nameData.name + "> with unsupported arraySizes" ); checkForError( ( typeInfo.type == "VK_DEFINE_HANDLE" ) || ( typeInfo.type == "VK_DEFINE_NON_DISPATCHABLE_HANDLE" ), line, "handle with invalid type <" + typeInfo.type + ">" ); checkForError( typeInfo.prefix.empty(), line, "unexpected type prefix <" + typeInfo.prefix + ">" ); checkForError( typeInfo.postfix == "(", line, "unexpected type postfix <" + typeInfo.postfix + ">" ); checkForError( !handleData.objTypeEnum.empty(), line, "handle <" + nameData.name + "> does not specify attribute \"objtypeenum\"" ); checkForError( m_types.insert( { nameData.name, TypeData{ TypeCategory::Handle, {}, line } } ).second, line, "handle <" + nameData.name + "> already specified" ); assert( !m_handles.contains( nameData.name ) ); m_handles.insert( { nameData.name, handleData } ); } } void VulkanHppGenerator::readTypeInclude( tinyxml2::XMLElement const * element, std::map const & attributes ) { int line = element->GetLineNum(); checkAttributes( line, attributes, { { "category", { "include" } }, { "name", {} } }, {} ); checkElements( line, getChildElements( element ), {} ); std::string name = attributes.find( "name" )->second; checkForError( m_types.insert( { name, TypeData{ TypeCategory::Include, {}, line } } ).second, line, "type <" + name + "> already specified" ); assert( !m_includes.contains( name ) ); m_includes[name] = { line }; } void VulkanHppGenerator::readTypeRequires( tinyxml2::XMLElement const * element, std::map const & attributes ) { int line = element->GetLineNum(); checkAttributes( line, attributes, { { "name", {} }, { "requires", {} } }, {} ); checkElements( line, getChildElements( element ), {} ); std::string name, require; for ( auto attribute : attributes ) { if ( attribute.first == "name" ) { name = attribute.second; } else { assert( attribute.first == "requires" ); require = attribute.second; } } checkForError( m_includes.contains( require ), line, "type <" + name + "> requires unknown <" + require + ">" ); checkForError( m_types.insert( { name, TypeData{ TypeCategory::ExternalType, {}, line } } ).second, line, "type <" + name + "> already specified" ); assert( !m_externalTypes.contains( name ) ); m_externalTypes[name] = { require, line }; } void VulkanHppGenerator::readTypeStruct( tinyxml2::XMLElement const * element, bool isUnion, std::map const & attributes ) { int line = element->GetLineNum(); auto aliasIt = attributes.find( "alias" ); if ( aliasIt != attributes.end() ) { checkAttributes( line, attributes, { { "alias", {} }, { "category", { "struct" } }, { "name", {} } }, {} ); checkElements( line, getChildElements( element ), {}, {} ); std::string alias = aliasIt->second; std::string name = attributes.find( "name" )->second; checkForError( m_types.insert( { name, TypeData{ TypeCategory::Struct, {}, line } } ).second, line, "struct <" + name + "> already specified" ); assert( !m_structAliases.contains( name ) ); m_structAliases[name] = { alias, line }; } else { checkAttributes( line, attributes, { { "category", { isUnion ? "union" : "struct" } }, { "name", {} } }, { { "allowduplicate", { "false", "true" } }, { "comment", {} }, { "returnedonly", { "true" } }, { "structextends", {} } } ); std::vector children = getChildElements( element ); checkElements( line, children, {}, { "member", "comment" } ); StructureData structureData; structureData.xmlLine = line; structureData.isUnion = isUnion; std::string name; for ( auto const & attribute : attributes ) { if ( attribute.first == "allowduplicate" ) { structureData.allowDuplicate = ( attribute.second == "true" ); } else if ( attribute.first == "category" ) { assert( isUnion ? ( attribute.second == "union" ) : ( attribute.second == "struct" ) ); } else if ( attribute.first == "name" ) { name = attribute.second; } else if ( attribute.first == "returnedonly" ) { assert( attribute.second == "true" ); structureData.returnedOnly = true; } else if ( attribute.first == "structextends" ) { structureData.structExtends = tokenize( attribute.second, "," ); } } assert( !name.empty() ); checkForError( !structureData.allowDuplicate || !structureData.structExtends.empty(), line, "attribute is true, but no structures are listed in " ); checkForError( m_types.insert( { name, TypeData{ isUnion ? TypeCategory::Union : TypeCategory::Struct, {}, line } } ).second, line, "struct <" + name + "> already specified" ); assert( !m_structs.contains( name ) ); std::map::iterator it = m_structs.insert( std::make_pair( name, structureData ) ).first; for ( auto child : children ) { std::string value = child->Value(); 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 mutualExclusiveStructs = { "VkAccelerationStructureBuildGeometryInfoKHR", "VkAccelerationStructureTrianglesOpacityMicromapEXT", "VkMicromapBuildInfoEXT", "VkWriteDescriptorSet" }; static std::set multipleLenStructs = { "VkAccelerationStructureTrianglesDisplacementMicromapNV", "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->lenExpressions.empty() && ( m0It->lenExpressions.front() != "null-terminated" ) ) { for ( auto m1It = std::next( m0It ); !warned && ( m1It != it->second.members.end() ); ++m1It ) { if ( !m1It->lenExpressions.empty() && ( m0It->lenExpressions.front() == m1It->lenExpressions.front() ) ) { if ( mutualExclusiveStructs.contains( it->first ) ) { it->second.mutualExclusiveLens = true; } else { checkForWarning( multipleLenStructs.contains( it->first ), 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( structureData.structExtends.begin(), structureData.structExtends.end() ); } } void VulkanHppGenerator::readTypes( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); checkAttributes( line, getAttributes( element ), { { "comment", {} } }, {} ); std::vector children = getChildElements( element ); checkElements( line, children, { { "comment", false }, { "type", false } } ); for ( auto child : children ) { std::string value = child->Value(); if ( value == "type" ) { readTypesType( child ); } } } void VulkanHppGenerator::readTypesType( tinyxml2::XMLElement const * element ) { int line = element->GetLineNum(); std::map attributes = getAttributes( element ); auto categoryIt = attributes.find( "category" ); if ( categoryIt != attributes.end() ) { if ( categoryIt->second == "basetype" ) { readTypeBasetype( element, attributes ); } else if ( categoryIt->second == "bitmask" ) { readTypeBitmask( element, attributes ); } else if ( categoryIt->second == "define" ) { readTypeDefine( element, attributes ); } else if ( categoryIt->second == "enum" ) { readTypeEnum( element, attributes ); } else if ( categoryIt->second == "funcpointer" ) { readTypeFuncpointer( element, attributes ); } else if ( categoryIt->second == "handle" ) { readTypeHandle( element, attributes ); } else if ( categoryIt->second == "include" ) { readTypeInclude( element, attributes ); } else if ( ( categoryIt->second == "struct" ) || ( categoryIt->second == "union" ) ) { readTypeStruct( element, ( categoryIt->second == "union" ), attributes ); } else { checkForError( false, line, "unknown category <" + categoryIt->second + "> encountered" ); } } else { auto requiresIt = attributes.find( "requires" ); if ( requiresIt != attributes.end() ) { readTypeRequires( element, attributes ); } else { checkForError( ( attributes.size() == 1 ) && ( attributes.begin()->first == "name" ) && ( attributes.begin()->second == "int" ), line, "unknown type" ); checkForError( m_types.insert( { "int", TypeData{ TypeCategory::Unknown, {}, line } } ).second, line, "type already specified" ); } } } TypeInfo VulkanHppGenerator::readTypeInfo( tinyxml2::XMLElement const * element ) const { TypeInfo typeInfo; tinyxml2::XMLNode const * previousSibling = element->PreviousSibling(); if ( previousSibling && previousSibling->ToText() ) { typeInfo.prefix = trim( previousSibling->Value() ); } typeInfo.type = element->GetText(); tinyxml2::XMLNode const * nextSibling = element->NextSibling(); if ( nextSibling && nextSibling->ToText() ) { typeInfo.postfix = trimStars( trimEnd( nextSibling->Value() ) ); } return typeInfo; } void VulkanHppGenerator::registerDeleter( std::string const & commandName, CommandData const & commandData ) { if ( ( commandName.substr( 2, 7 ) == "Destroy" ) || ( commandName.substr( 2, 4 ) == "Free" ) ) { std::string key; size_t valueIndex; switch ( commandData.params.size() ) { case 2: case 3: assert( commandData.params.back().type.type == "VkAllocationCallbacks" ); key = ( commandData.params.size() == 2 ) ? "" : commandData.params[0].type.type; valueIndex = commandData.params.size() - 2; break; case 4: key = commandData.params[0].type.type; valueIndex = 3; assert( m_handles.contains( commandData.params[valueIndex].type.type ) ); m_handles.find( commandData.params[valueIndex].type.type )->second.deletePool = commandData.params[1].type.type; break; default: assert( false ); valueIndex = 0; } auto keyHandleIt = m_handles.find( key ); assert( keyHandleIt != m_handles.end() ); keyHandleIt->second.childrenHandles.insert( commandData.params[valueIndex].type.type ); auto handleIt = m_handles.find( commandData.params[valueIndex].type.type ); assert( handleIt != m_handles.end() ); handleIt->second.deleteCommand = commandName; handleIt->second.deleteParent = key; } } void VulkanHppGenerator::rescheduleRAIIHandle( std::string & str, std::pair const & handle, std::set & listedHandles, std::set const & specialFunctions ) const { listedHandles.insert( handle.first ); if ( !handle.second.parent.empty() && !listedHandles.contains( handle.second.parent ) ) { 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.contains( param.type.type ) ) { str += generateRAIIHandle( *handleIt, listedHandles, specialFunctions ); } } } } std::vector VulkanHppGenerator::selectCommandsByHandle( std::vector const & requireData, std::set const & handleCommands, std::set & listedCommands ) const { std::vector selectedCommands; for ( auto const & require : requireData ) { for ( auto const & command : require.commands ) { if ( handleCommands.contains( command ) && listedCommands.insert( command ).second ) { selectedCommands.push_back( command ); } } } return selectedCommands; } bool VulkanHppGenerator::skipLeadingGrandParent( std::pair const & handle ) const { bool skip = false; assert( !handle.second.constructorIts.empty() ); auto constructorIt = handle.second.constructorIts.begin(); if ( ( 1 < ( *constructorIt )->second.params.size() ) && isHandleType( ( *constructorIt )->second.params[0].type.type ) && ( ( *constructorIt )->second.params[1].type.type == handle.second.parent ) ) { auto parentIt = m_handles.find( handle.second.parent ); assert( parentIt != m_handles.end() ); skip = ( ( *constructorIt )->second.params[0].type.type == parentIt->second.parent ); #if !defined( NDEBUG ) for ( auto it = std::next( constructorIt ); it != handle.second.constructorIts.end(); ++it ) { assert( ( *it )->second.params[0].type.type == ( *constructorIt )->second.params[0].type.type ); assert( !skip || ( ( *it )->second.params[1].type.type == ( *constructorIt )->second.params[1].type.type ) ); } #endif } return skip; } std::string VulkanHppGenerator::stripPluralS( std::string const & name ) const { std::string strippedName = name; std::string tag = findTag( name ); if ( strippedName.ends_with( "s" + tag ) ) { size_t pos = strippedName.rfind( 's' ); if ( ( 2 <= pos ) && ( strippedName.substr( pos - 2, 3 ) == "ies" ) ) { strippedName.replace( pos - 2, 3, "y" ); } else { strippedName.erase( pos, 1 ); } } return strippedName; } 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::ExternalType: return "ExternalType"; case TypeCategory::FuncPointer: return "funcpointer"; case TypeCategory::Handle: return "handle"; case TypeCategory::Struct: return "struct"; case TypeCategory::Union: return "union"; case TypeCategory::Unknown: return "unkown"; default: assert( false ); return ""; } } void VulkanHppGenerator::EnumData::addEnumAlias( int line, std::string const & name, std::string const & alias, std::string const & protect, bool supported ) { auto & valuesRef = supported ? values : unsupportedValues; auto valueIt = std::find_if( valuesRef.begin(), valuesRef.end(), [&name]( EnumValueData const & evd ) { return evd.name == name; } ); if ( valueIt != valuesRef.end() ) { if ( supported ) { checkForError( ( valueIt->alias == alias ) && ( valueIt->protect == protect ) && valueIt->bitpos.empty() && valueIt->value.empty(), line, "enum alias <" + name + "> already specified with different attributes" ); } else { checkForWarning( ( valueIt->alias == alias ) && ( valueIt->protect == protect ) && valueIt->bitpos.empty() && valueIt->value.empty(), line, "enum alias <" + name + "> already specified with different attributes" ); } } else { valuesRef.push_back( { alias, "", name, protect, "", line } ); } } void VulkanHppGenerator::EnumData::addEnumValue( int line, std::string const & name, std::string const & protect, std::string const & bitpos, std::string const & value, bool supported ) { auto & valuesRef = supported ? values : unsupportedValues; auto valueIt = std::find_if( valuesRef.begin(), valuesRef.end(), [&name]( EnumValueData const & evd ) { return evd.name == name; } ); if ( valueIt != valuesRef.end() ) { checkForError( valueIt->alias.empty() && ( valueIt->protect == protect ) && ( valueIt->bitpos == bitpos ) && ( valueIt->value == value ), line, "enum value <" + name + "> already specified with different attributes" ); } else { valuesRef.push_back( { "", bitpos, name, protect, value, line } ); } } // // VulkanHppGenerator local functions // std::vector> filterNumbers( std::vector const & names ) { std::vector> filteredNames; for ( auto const & name : names ) { if ( !isNumber( name ) ) { filteredNames.push_back( { name, ~0 } ); } } return filteredNames; } std::string generateCArraySizes( std::vector const & sizes ) { std::string arraySizes; for ( auto const & s : sizes ) { arraySizes += "[" + s + "]"; } return arraySizes; } std::string generateNamespacedType( std::string const & type ) { return type.starts_with( "Vk" ) ? ( "VULKAN_HPP_NAMESPACE::" + stripPrefix( type, "Vk" ) ) : type; } std::string generateNoDiscard( bool returnsSomething, bool multiSuccessCodes, bool multiErrorCodes ) { return ( returnsSomething || multiSuccessCodes ) ? "VULKAN_HPP_NODISCARD " : ( multiErrorCodes ? "VULKAN_HPP_NODISCARD_WHEN_NO_EXCEPTIONS " : "" ); } std::string generateStandardArray( std::string const & type, std::vector 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; } bool isNumber( std::string const & name ) { return name.find_first_not_of( "0123456789" ) == std::string::npos; } std::string readSnippet( std::string const & snippetFile ) { std::ifstream ifs( std::string( BASE_PATH ) + "/snippets/" + snippetFile ); assert( !ifs.fail() ); std::ostringstream oss; oss << ifs.rdbuf(); return oss.str(); } std::string startLowerCase( std::string const & input ) { assert( !input.empty() ); return static_cast( tolower( input[0] ) ) + input.substr( 1 ); } std::string startUpperCase( std::string const & input ) { assert( !input.empty() ); return static_cast( toupper( input[0] ) ) + input.substr( 1 ); } std::vector tokenizeAny( std::string const & tokenString, std::string const & separators ) { size_t len = tokenString.length(); std::vector tokens; if ( !tokenString.empty() ) { size_t start = 0, end; do { end = tokenString.find_first_of( separators, start ); if ( ( start != end ) && ( start < len ) ) { tokens.push_back( trim( tokenString.substr( start, end - start ) ) ); } start = end + 1; } while ( end != std::string::npos ); } return tokens; } // function to take three or four-vector of strings containing a macro definition, and return // a tuple with possibly the deprecation reason, possibly the called macro, the macro parameters, and possibly the definition MacroData parseMacro( std::vector const & completeMacro ) { // #define macro definition // #define macro( params ) definition // #define macro1 macro2( params ) auto const paramsRegex = std::regex{ R"((\(.*?\)))" }; auto const commentRegex = std::regex{ R"(\s*//.*)" }; auto rawComment = completeMacro[0]; std::erase( rawComment, '/' ); auto const strippedComment = trim( stripPostfix( stripPrefix( rawComment, " DEPRECATED:" ), "#define " ) ); // macro with parameters and implementation if ( completeMacro.size() == 3 ) { auto const & paramsAndDefinitionAndTrailingComment = completeMacro[2]; if ( paramsAndDefinitionAndTrailingComment.find( '(' ) == std::string::npos ) { // no opening parenthesis found => no parameters return { strippedComment, {}, {}, std::regex_replace( paramsAndDefinitionAndTrailingComment, commentRegex, "" ) }; } // match the first set of parentheses only auto paramsMatch = std::smatch{}; std::regex_search( paramsAndDefinitionAndTrailingComment, paramsMatch, paramsRegex ); // remove the leading and trailing parentheses and tokenise the remaining string auto params = tokenize( stripPrefix( stripPostfix( paramsMatch[1].str(), ")" ), "(" ), "," ); // replace the parameters with empty string, leaving behind the implementation and (possibly) a trailing comment auto implementation = std::regex_replace( paramsAndDefinitionAndTrailingComment, paramsRegex, "", std::regex_constants::format_first_only ); implementation = implementation.substr( 0, implementation.find( "//" ) ); std::erase( implementation, '\\' ); implementation = trim( implementation ); return { strippedComment, {}, params, implementation }; } if ( completeMacro.size() == 4 ) { auto const & calledMacro = toCamelCase( stripPrefix( completeMacro[2], "VK_" ) ); auto const & argsAndTrailingComment = completeMacro[3]; auto argsMatch = std::smatch{}; std::regex_search( argsAndTrailingComment, argsMatch, paramsRegex ); auto args = tokenize( stripPrefix( stripPostfix( argsMatch[1].str(), ")" ), "(" ), "," ); return { strippedComment, calledMacro, args, {} }; } return {}; } int main( int argc, char ** argv ) { if ( ( argc % 2 ) == 0 ) { std::cout << "VulkanHppGenerator usage: VulkanHppGenerator [-f filename][-api [vulkan|vulkansc]]" << std::endl; std::cout << "\tdefault for filename is <" << VK_SPEC << ">" << std::endl; std::cout << "\tdefault for api " << std::endl; std::cout << "\tsupported values for api are and " << std::endl; return -1; } std::string api = "vulkan"; std::string filename = VK_SPEC; for ( int i = 1; i < argc; i += 2 ) { if ( strcmp( argv[i], "-api" ) == 0 ) { api = argv[i + 1]; } else if ( strcmp( argv[i], "-f" ) == 0 ) { filename = argv[i + 1]; } else { std::cout << "unsupported argument <" << argv[i] << ">" << std::endl; return -1; } } if ( ( api != "vulkan" ) && ( api != "vulkansc" ) ) { std::cout << "unsupported api <" << api << ">" << std::endl; return -1; } #if defined( CLANG_FORMAT_EXECUTABLE ) std::cout << "VulkanHppGenerator: Found "; std::string commandString = "\"" CLANG_FORMAT_EXECUTABLE "\" --version "; int ret = std::system( commandString.c_str() ); if ( ret != 0 ) { std::cout << "VulkanHppGenerator: failed to determine clang_format version with error <" << ret << ">\n"; } #endif tinyxml2::XMLDocument doc; std::cout << "VulkanHppGenerator: Loading " << filename << std::endl; tinyxml2::XMLError error = doc.LoadFile( filename.c_str() ); if ( error != tinyxml2::XML_SUCCESS ) { std::cout << "VulkanHppGenerator: failed to load file " << filename << " with error <" << toString( error ) << ">" << std::endl; return -1; } try { std::cout << "VulkanHppGenerator: Parsing " << filename << std::endl; VulkanHppGenerator generator( doc, api ); generator.generateHppFile(); generator.generateEnumsHppFile(); generator.generateExtensionInspectionFile(); generator.generateFormatTraitsHppFile(); generator.prepareVulkanFuncs(); generator.generateFuncsHppFile(); generator.generateHandlesHppFile(); generator.generateHashHppFile(); generator.prepareRAIIHandles(); generator.generateRAIIHppFile(); generator.generateStaticAssertionsHppFile(); generator.generateStructsHppFile(); generator.generateToStringHppFile(); generator.generateCppModuleFile(); #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; } }