Merge commit 'ac9fa8a82eb313351a64a0de3afaf28e2b0ed422' as 'deps/SPIRV-Cross'

This commit is contained in:
Hans-Kristian Arntzen 2019-06-24 13:42:34 +02:00
commit 90fd5657b5
2199 changed files with 135813 additions and 0 deletions

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deps/SPIRV-Cross/.clang-format vendored Executable file
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# The style used for all options not specifically set in the configuration.
BasedOnStyle: LLVM
# The extra indent or outdent of access modifiers, e.g. public:.
AccessModifierOffset: -4
# If true, aligns escaped newlines as far left as possible. Otherwise puts them into the right-most column.
AlignEscapedNewlinesLeft: true
# If true, aligns trailing comments.
AlignTrailingComments: false
# Allow putting all parameters of a function declaration onto the next line even if BinPackParameters is false.
AllowAllParametersOfDeclarationOnNextLine: false
# Allows contracting simple braced statements to a single line.
AllowShortBlocksOnASingleLine: false
# If true, short case labels will be contracted to a single line.
AllowShortCaseLabelsOnASingleLine: false
# Dependent on the value, int f() { return 0; } can be put on a single line. Possible values: None, Inline, All.
AllowShortFunctionsOnASingleLine: None
# If true, if (a) return; can be put on a single line.
AllowShortIfStatementsOnASingleLine: false
# If true, while (true) continue; can be put on a single line.
AllowShortLoopsOnASingleLine: false
# If true, always break after function definition return types.
AlwaysBreakAfterDefinitionReturnType: false
# If true, always break before multiline string literals.
AlwaysBreakBeforeMultilineStrings: false
# If true, always break after the template<...> of a template declaration.
AlwaysBreakTemplateDeclarations: true
# If false, a function call's arguments will either be all on the same line or will have one line each.
BinPackArguments: true
# If false, a function declaration's or function definition's parameters will either all be on the same line
# or will have one line each.
BinPackParameters: true
# The way to wrap binary operators. Possible values: None, NonAssignment, All.
BreakBeforeBinaryOperators: None
# The brace breaking style to use. Possible values: Attach, Linux, Stroustrup, Allman, GNU.
BreakBeforeBraces: Allman
# If true, ternary operators will be placed after line breaks.
BreakBeforeTernaryOperators: false
# Always break constructor initializers before commas and align the commas with the colon.
BreakConstructorInitializersBeforeComma: true
# The column limit. A column limit of 0 means that there is no column limit.
ColumnLimit: 120
# A regular expression that describes comments with special meaning, which should not be split into lines or otherwise changed.
CommentPragmas: '^ *'
# If the constructor initializers don't fit on a line, put each initializer on its own line.
ConstructorInitializerAllOnOneLineOrOnePerLine: false
# The number of characters to use for indentation of constructor initializer lists.
ConstructorInitializerIndentWidth: 4
# Indent width for line continuations.
ContinuationIndentWidth: 4
# If true, format braced lists as best suited for C++11 braced lists.
Cpp11BracedListStyle: false
# Disables formatting at all.
DisableFormat: false
# A vector of macros that should be interpreted as foreach loops instead of as function calls.
#ForEachMacros: ''
# Indent case labels one level from the switch statement.
# When false, use the same indentation level as for the switch statement.
# Switch statement body is always indented one level more than case labels.
IndentCaseLabels: false
# The number of columns to use for indentation.
IndentWidth: 4
# Indent if a function definition or declaration is wrapped after the type.
IndentWrappedFunctionNames: false
# If true, empty lines at the start of blocks are kept.
KeepEmptyLinesAtTheStartOfBlocks: true
# Language, this format style is targeted at. Possible values: None, Cpp, Java, JavaScript, Proto.
Language: Cpp
# The maximum number of consecutive empty lines to keep.
MaxEmptyLinesToKeep: 1
# The indentation used for namespaces. Possible values: None, Inner, All.
NamespaceIndentation: None
# The penalty for breaking a function call after "call(".
PenaltyBreakBeforeFirstCallParameter: 19
# The penalty for each line break introduced inside a comment.
PenaltyBreakComment: 300
# The penalty for breaking before the first <<.
PenaltyBreakFirstLessLess: 120
# The penalty for each line break introduced inside a string literal.
PenaltyBreakString: 1000
# The penalty for each character outside of the column limit.
PenaltyExcessCharacter: 1000000
# Penalty for putting the return type of a function onto its own line.
PenaltyReturnTypeOnItsOwnLine: 1000000000
# Pointer and reference alignment style. Possible values: Left, Right, Middle.
PointerAlignment: Right
# If true, a space may be inserted after C style casts.
SpaceAfterCStyleCast: false
# If false, spaces will be removed before assignment operators.
SpaceBeforeAssignmentOperators: true
# Defines in which cases to put a space before opening parentheses. Possible values: Never, ControlStatements, Always.
SpaceBeforeParens: ControlStatements
# If true, spaces may be inserted into '()'.
SpaceInEmptyParentheses: false
# The number of spaces before trailing line comments (// - comments).
SpacesBeforeTrailingComments: 1
# If true, spaces will be inserted after '<' and before '>' in template argument lists.
SpacesInAngles: false
# If true, spaces may be inserted into C style casts.
SpacesInCStyleCastParentheses: false
# If true, spaces are inserted inside container literals (e.g. ObjC and Javascript array and dict literals).
SpacesInContainerLiterals: false
# If true, spaces will be inserted after '(' and before ')'.
SpacesInParentheses: false
# If true, spaces will be inserted after '[' and befor']'.
SpacesInSquareBrackets: false
# Format compatible with this standard, e.g. use A<A<int> > instead of A<A<int>> for LS_Cpp03. Possible values: Cpp03, Cpp11, Auto.
Standard: Cpp11
# The number of columns used for tab stops.
TabWidth: 4
# The way to use tab characters in the resulting file. Possible values: Never, ForIndentation, Always.
UseTab: ForIndentation
# Do not reflow comments
ReflowComments: false

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deps/SPIRV-Cross/.gitignore vendored Normal file
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*.o
*.d
*.txt
/test
/spirv-cross
/obj
/msvc/x64
/msvc/Debug
/msvc/Release
*.suo
*.sdf
*.opensdf
*.shader
*.a
*.bc
/external
.vs/
*.vcxproj.user
!CMakeLists.txt

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deps/SPIRV-Cross/.travis.yml vendored Normal file
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language:
- cpp
- python
python: 3.7
matrix:
include:
- os: linux
dist: trusty
compiler: gcc
env:
- GENERATOR="Unix Makefiles"
- ARTIFACT=gcc-trusty-64bit
- os: linux
dist: trusty
compiler: clang
env:
- GENERATOR="Unix Makefiles"
- ARTIFACT=clang-trusty-64bit
- os: osx
compiler: clang
osx_image: xcode10
env:
- GENERATOR="Unix Makefiles"
- ARTIFACT=clang-macos-64bit
- os: windows
before_install:
- choco install python3
- export PATH="/c/Python37:/c/Python37/Scripts:$PATH"
env:
- GENERATOR="Visual Studio 15 2017"
- ARTIFACT=vs2017-32bit
- os: windows
before_install:
- choco install python3
- export PATH="/c/Python37:/c/Python37/Scripts:$PATH"
env:
- GENERATOR="Visual Studio 15 2017 Win64"
- ARTIFACT=vs2017-64bit
before_script:
- "./checkout_glslang_spirv_tools.sh"
script:
- if [[ "$TRAVIS_OS_NAME" == "windows" ]]; then PYTHON3=$(which python); fi
- if [[ "$TRAVIS_OS_NAME" != "windows" ]]; then PYTHON3=$(which python3); fi
- "./build_glslang_spirv_tools.sh Release"
- mkdir build
- cd build
- cmake .. -DSPIRV_CROSS_SHARED=ON -DCMAKE_INSTALL_PREFIX=output -DCMAKE_BUILD_TYPE=Release -G "${GENERATOR}" -DPYTHON_EXECUTABLE:FILEPATH="${PYTHON3}" -DSPIRV_CROSS_ENABLE_TESTS=ON
- cmake --build . --config Release
- cmake --build . --config Release --target install
- ctest --verbose -C Release
- cd ..
before_deploy:
- REV=${ARTIFACT}-$(git rev-parse --short=10 HEAD)
- cd build/output
- tar cf spirv-cross-${REV}.tar *
- gzip spirv-cross-${REV}.tar
- cd ../..
- export FILE_TO_UPLOAD=build/output/spirv-cross-${REV}.tar.gz
deploy:
provider: releases
api_key:
secure: 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
file: "${FILE_TO_UPLOAD}"
skip_cleanup: true
on:
tags: true

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# Copyright 2016 Google Inc.
#
# 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.
cmake_minimum_required(VERSION 2.8)
set(CMAKE_CXX_STANDARD 11)
project(SPIRV-Cross LANGUAGES CXX C)
enable_testing()
option(SPIRV_CROSS_EXCEPTIONS_TO_ASSERTIONS "Instead of throwing exceptions assert" OFF)
option(SPIRV_CROSS_SHARED "Build the C API as a single shared library." OFF)
option(SPIRV_CROSS_STATIC "Build the C and C++ API as static libraries." ON)
option(SPIRV_CROSS_CLI "Build the CLI binary. Requires SPIRV_CROSS_STATIC." ON)
option(SPIRV_CROSS_ENABLE_TESTS "Enable SPIRV-Cross tests." ON)
option(SPIRV_CROSS_ENABLE_GLSL "Enable GLSL support." ON)
option(SPIRV_CROSS_ENABLE_HLSL "Enable HLSL target support." ON)
option(SPIRV_CROSS_ENABLE_MSL "Enable MSL target support." ON)
option(SPIRV_CROSS_ENABLE_CPP "Enable C++ target support." ON)
option(SPIRV_CROSS_ENABLE_REFLECT "Enable JSON reflection target support." ON)
option(SPIRV_CROSS_ENABLE_C_API "Enable C API wrapper support in static library." ON)
option(SPIRV_CROSS_ENABLE_UTIL "Enable util module support." ON)
option(SPIRV_CROSS_SANITIZE_ADDRESS "Sanitize address" OFF)
option(SPIRV_CROSS_SANITIZE_MEMORY "Sanitize memory" OFF)
option(SPIRV_CROSS_SANITIZE_THREADS "Sanitize threads" OFF)
option(SPIRV_CROSS_SANITIZE_UNDEFINED "Sanitize undefined" OFF)
option(SPIRV_CROSS_NAMESPACE_OVERRIDE "" "Override the namespace used in the C++ API.")
option(SPIRV_CROSS_FORCE_STL_TYPES "Force use of STL types instead of STL replacements in certain places. Might reduce performance." OFF)
if(${CMAKE_GENERATOR} MATCHES "Makefile")
if(${CMAKE_CURRENT_SOURCE_DIR} STREQUAL ${CMAKE_CURRENT_BINARY_DIR})
message(FATAL_ERROR "Build out of tree to avoid overwriting Makefile")
endif()
endif()
set(spirv-compiler-options "")
set(spirv-compiler-defines "")
set(spirv-cross-link-flags "")
message(STATUS "Finding Git version for SPIRV-Cross.")
set(spirv-cross-build-version "unknown")
find_package(Git)
if (GIT_FOUND)
execute_process(
COMMAND ${GIT_EXECUTABLE} rev-parse --short HEAD
WORKING_DIRECTORY ${CMAKE_CURRENT_SOURCE_DIR}
OUTPUT_VARIABLE spirv-cross-build-version
ERROR_QUIET
OUTPUT_STRIP_TRAILING_WHITESPACE
)
message(STATUS "Git hash: ${spirv-cross-build-version}")
else()
message(STATUS "Git not found, using unknown build version.")
endif()
string(TIMESTAMP spirv-cross-timestamp)
configure_file(${CMAKE_CURRENT_SOURCE_DIR}/cmake/gitversion.in.h ${CMAKE_CURRENT_BINARY_DIR}/gitversion.h @ONLY)
if(SPIRV_CROSS_EXCEPTIONS_TO_ASSERTIONS)
set(spirv-compiler-defines ${spirv-compiler-defines} SPIRV_CROSS_EXCEPTIONS_TO_ASSERTIONS)
endif()
if(SPIRV_CROSS_FORCE_STL_TYPES)
set(spirv-compiler-defines ${spirv-compiler-defines} SPIRV_CROSS_FORCE_STL_TYPES)
endif()
if (CMAKE_COMPILER_IS_GNUCXX OR (${CMAKE_CXX_COMPILER_ID} MATCHES "Clang"))
set(spirv-compiler-options ${spirv-compiler-options} -Wall -Wextra -Werror -Wshadow)
if (SPIRV_CROSS_EXCEPTIONS_TO_ASSERTIONS)
set(spirv-compiler-options ${spirv-compiler-options} -fno-exceptions)
endif()
if (SPIRV_CROSS_SANITIZE_ADDRESS)
set(spirv-compiler-options ${spirv-compiler-options} -fsanitize=address)
set(spirv-cross-link-flags "${spirv-cross-link-flags} -fsanitize=address")
endif()
if (SPIRV_CROSS_SANITIZE_UNDEFINED)
set(spirv-compiler-options ${spirv-compiler-options} -fsanitize=undefined)
set(spirv-cross-link-flags "${spirv-cross-link-flags} -fsanitize=undefined")
endif()
if (SPIRV_CROSS_SANITIZE_MEMORY)
set(spirv-compiler-options ${spirv-compiler-options} -fsanitize=memory)
set(spirv-cross-link-flags "${spirv-cross-link-flags} -fsanitize=memory")
endif()
if (SPIRV_CROSS_SANITIZE_THREADS)
set(spirv-compiler-options ${spirv-compiler-options} -fsanitize=thread)
set(spirv-cross-link-flags "${spirv-cross-link-flags} -fsanitize=thread")
endif()
elseif (MSVC)
set(spirv-compiler-options ${spirv-compiler-options} /wd4267)
endif()
macro(extract_headers out_abs file_list)
set(${out_abs}) # absolute paths
foreach(_a ${file_list})
# get_filename_component only returns the longest extension, so use a regex
string(REGEX REPLACE ".*\\.(h|hpp)" "\\1" ext ${_a})
# For shared library, we are only interested in the C header.
if (SPIRV_CROSS_STATIC)
if(("${ext}" STREQUAL "h") OR ("${ext}" STREQUAL "hpp"))
list(APPEND ${out_abs} "${_a}")
endif()
else()
if("${ext}" STREQUAL "h")
list(APPEND ${out_abs} "${_a}")
endif()
endif()
endforeach()
endmacro()
macro(spirv_cross_add_library name config_name library_type)
add_library(${name} ${library_type} ${ARGN})
extract_headers(hdrs "${ARGN}")
target_include_directories(${name} PUBLIC
$<BUILD_INTERFACE:${CMAKE_CURRENT_SOURCE_DIR}>
$<INSTALL_INTERFACE:include/spirv_cross>)
set_target_properties(${name} PROPERTIES
PUBLIC_HEADERS "${hdrs}")
target_compile_options(${name} PRIVATE ${spirv-compiler-options})
target_compile_definitions(${name} PRIVATE ${spirv-compiler-defines})
if (SPIRV_CROSS_NAMESPACE_OVERRIDE)
if (${library_type} MATCHES "STATIC")
target_compile_definitions(${name} PUBLIC SPIRV_CROSS_NAMESPACE_OVERRIDE=${SPIRV_CROSS_NAMESPACE_OVERRIDE})
else()
target_compile_definitions(${name} PRIVATE SPIRV_CROSS_NAMESPACE_OVERRIDE=${SPIRV_CROSS_NAMESPACE_OVERRIDE})
endif()
endif()
install(TARGETS ${name}
EXPORT ${config_name}Config
RUNTIME DESTINATION bin
LIBRARY DESTINATION lib
ARCHIVE DESTINATION lib
PUBLIC_HEADER DESTINATION include/spirv_cross)
install(FILES ${hdrs} DESTINATION include/spirv_cross)
install(EXPORT ${config_name}Config DESTINATION share/${config_name}/cmake)
export(TARGETS ${name} FILE ${config_name}Config.cmake)
endmacro()
set(spirv-cross-core-sources
${CMAKE_CURRENT_SOURCE_DIR}/GLSL.std.450.h
${CMAKE_CURRENT_SOURCE_DIR}/spirv_common.hpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cross_containers.hpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cross_error_handling.hpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv.hpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cross.hpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cross.cpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_parser.hpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_parser.cpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cross_parsed_ir.hpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cross_parsed_ir.cpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cfg.hpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cfg.cpp)
set(spirv-cross-c-sources
spirv.h
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cross_c.cpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cross_c.h)
set(spirv-cross-glsl-sources
${CMAKE_CURRENT_SOURCE_DIR}/spirv_glsl.cpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_glsl.hpp)
set(spirv-cross-cpp-sources
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cpp.cpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cpp.hpp)
set(spirv-cross-msl-sources
${CMAKE_CURRENT_SOURCE_DIR}/spirv_msl.cpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_msl.hpp)
set(spirv-cross-hlsl-sources
${CMAKE_CURRENT_SOURCE_DIR}/spirv_hlsl.cpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_hlsl.hpp)
set(spirv-cross-reflect-sources
${CMAKE_CURRENT_SOURCE_DIR}/spirv_reflect.cpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_reflect.hpp)
set(spirv-cross-util-sources
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cross_util.cpp
${CMAKE_CURRENT_SOURCE_DIR}/spirv_cross_util.hpp)
if (SPIRV_CROSS_STATIC)
spirv_cross_add_library(spirv-cross-core spirv_cross_core STATIC
${spirv-cross-core-sources})
if (SPIRV_CROSS_ENABLE_GLSL)
spirv_cross_add_library(spirv-cross-glsl spirv_cross_glsl STATIC
${spirv-cross-glsl-sources})
target_link_libraries(spirv-cross-glsl PRIVATE spirv-cross-core)
endif()
if (SPIRV_CROSS_ENABLE_CPP)
spirv_cross_add_library(spirv-cross-cpp spirv_cross_cpp STATIC
${spirv-cross-cpp-sources})
if (SPIRV_CROSS_ENABLE_GLSL)
target_link_libraries(spirv-cross-cpp PRIVATE spirv-cross-glsl)
else()
message(FATAL_ERROR "Must enable GLSL support to enable C++ support.")
endif()
endif()
if (SPIRV_CROSS_ENABLE_REFLECT)
if (SPIRV_CROSS_ENABLE_GLSL)
spirv_cross_add_library(spirv-cross-reflect spirv_cross_reflect STATIC
${spirv-cross-reflect-sources})
else()
message(FATAL_ERROR "Must enable GLSL support to enable JSON reflection support.")
endif()
endif()
if (SPIRV_CROSS_ENABLE_MSL)
spirv_cross_add_library(spirv-cross-msl spirv_cross_msl STATIC
${spirv-cross-msl-sources})
if (SPIRV_CROSS_ENABLE_GLSL)
target_link_libraries(spirv-cross-msl PRIVATE spirv-cross-glsl)
else()
message(FATAL_ERROR "Must enable GLSL support to enable MSL support.")
endif()
endif()
if (SPIRV_CROSS_ENABLE_HLSL)
spirv_cross_add_library(spirv-cross-hlsl spirv_cross_hlsl STATIC
${spirv-cross-hlsl-sources})
if (SPIRV_CROSS_ENABLE_GLSL)
target_link_libraries(spirv-cross-hlsl PRIVATE spirv-cross-glsl)
else()
message(FATAL_ERROR "Must enable GLSL support to enable HLSL support.")
endif()
endif()
if (SPIRV_CROSS_ENABLE_UTIL)
spirv_cross_add_library(spirv-cross-util spirv_cross_util STATIC
${spirv-cross-util-sources})
target_link_libraries(spirv-cross-util PRIVATE spirv-cross-core)
endif()
if (SPIRV_CROSS_ENABLE_C_API)
spirv_cross_add_library(spirv-cross-c spirv_cross_c STATIC
${spirv-cross-c-sources})
target_include_directories(spirv-cross-c PRIVATE ${CMAKE_CURRENT_BINARY_DIR})
target_compile_definitions(spirv-cross-c PRIVATE HAVE_SPIRV_CROSS_GIT_VERSION)
if (SPIRV_CROSS_ENABLE_GLSL)
target_link_libraries(spirv-cross-c PRIVATE spirv-cross-glsl)
target_compile_definitions(spirv-cross-c PRIVATE SPIRV_CROSS_C_API_GLSL=1)
endif()
if (SPIRV_CROSS_ENABLE_HLSL)
target_link_libraries(spirv-cross-c PRIVATE spirv-cross-hlsl)
target_compile_definitions(spirv-cross-c PRIVATE SPIRV_CROSS_C_API_HLSL=1)
endif()
if (SPIRV_CROSS_ENABLE_MSL)
target_link_libraries(spirv-cross-c PRIVATE spirv-cross-msl)
target_compile_definitions(spirv-cross-c PRIVATE SPIRV_CROSS_C_API_MSL=1)
endif()
if (SPIRV_CROSS_ENABLE_CPP)
target_link_libraries(spirv-cross-c PRIVATE spirv-cross-cpp)
target_compile_definitions(spirv-cross-c PRIVATE SPIRV_CROSS_C_API_CPP=1)
endif()
if (SPIRV_CROSS_ENABLE_REFLECT)
target_link_libraries(spirv-cross-c PRIVATE spirv-cross-reflect)
target_compile_definitions(spirv-cross-c PRIVATE SPIRV_CROSS_C_API_REFLECT=1)
endif()
endif()
endif()
set(spirv-cross-abi-major 0)
set(spirv-cross-abi-minor 14)
set(spirv-cross-abi-patch 0)
if (SPIRV_CROSS_SHARED)
set(SPIRV_CROSS_VERSION ${spirv-cross-abi-major}.${spirv-cross-abi-minor}.${spirv-cross-abi-patch})
set(SPIRV_CROSS_INSTALL_LIB_DIR ${CMAKE_INSTALL_PREFIX}/lib)
set(SPIRV_CROSS_INSTALL_INC_DIR ${CMAKE_INSTALL_PREFIX}/include/spirv_cross)
configure_file(
${CMAKE_CURRENT_SOURCE_DIR}/pkg-config/spirv-cross-c-shared.pc.in
${CMAKE_CURRENT_BINARY_DIR}/spirv-cross-c-shared.pc @ONLY)
install(FILES ${CMAKE_CURRENT_BINARY_DIR}/spirv-cross-c-shared.pc DESTINATION ${CMAKE_INSTALL_PREFIX}/share/pkgconfig)
spirv_cross_add_library(spirv-cross-c-shared spirv_cross_c_shared SHARED
${spirv-cross-core-sources}
${spirv-cross-c-sources})
target_include_directories(spirv-cross-c-shared PRIVATE ${CMAKE_CURRENT_BINARY_DIR})
target_compile_definitions(spirv-cross-c-shared PRIVATE HAVE_SPIRV_CROSS_GIT_VERSION)
if (SPIRV_CROSS_ENABLE_GLSL)
target_sources(spirv-cross-c-shared PRIVATE ${spirv-cross-glsl-sources})
target_compile_definitions(spirv-cross-c-shared PRIVATE SPIRV_CROSS_C_API_GLSL=1)
endif()
if (SPIRV_CROSS_ENABLE_HLSL)
if (SPIRV_CROSS_ENABLE_GLSL)
target_sources(spirv-cross-c-shared PRIVATE ${spirv-cross-hlsl-sources})
else()
message(FATAL_ERROR "Must enable GLSL support to enable HLSL support.")
endif()
target_compile_definitions(spirv-cross-c-shared PRIVATE SPIRV_CROSS_C_API_HLSL=1)
endif()
if (SPIRV_CROSS_ENABLE_MSL)
if (SPIRV_CROSS_ENABLE_GLSL)
target_sources(spirv-cross-c-shared PRIVATE ${spirv-cross-msl-sources})
else()
message(FATAL_ERROR "Must enable GLSL support to enable MSL support.")
endif()
target_compile_definitions(spirv-cross-c-shared PRIVATE SPIRV_CROSS_C_API_MSL=1)
endif()
if (SPIRV_CROSS_ENABLE_CPP)
if (SPIRV_CROSS_ENABLE_GLSL)
target_sources(spirv-cross-c-shared PRIVATE ${spirv-cross-cpp-sources})
else()
message(FATAL_ERROR "Must enable GLSL support to enable C++ support.")
endif()
target_compile_definitions(spirv-cross-c-shared PRIVATE SPIRV_CROSS_C_API_CPP=1)
endif()
if (SPIRV_CROSS_ENABLE_REFLECT)
if (SPIRV_CROSS_ENABLE_GLSL)
target_sources(spirv-cross-c-shared PRIVATE ${spirv-cross-reflect-sources})
else()
message(FATAL_ERROR "Must enable GLSL support to enable JSON reflection support.")
endif()
target_compile_definitions(spirv-cross-c-shared PRIVATE SPIRV_CROSS_C_API_REFLECT=1)
endif()
if (CMAKE_COMPILER_IS_GNUCXX OR (${CMAKE_CXX_COMPILER_ID} MATCHES "Clang"))
# Only export the C API.
target_compile_options(spirv-cross-c-shared PRIVATE -fvisibility=hidden)
if (NOT APPLE)
set_target_properties(spirv-cross-c-shared PROPERTIES LINK_FLAGS "${spirv-cross-link-flags}")
endif()
endif()
target_compile_definitions(spirv-cross-c-shared PRIVATE SPVC_EXPORT_SYMBOLS)
set_target_properties(spirv-cross-c-shared PROPERTIES
VERSION ${SPIRV_CROSS_VERSION}
SOVERSION ${spirv-cross-abi-major})
endif()
if (SPIRV_CROSS_CLI)
if (NOT SPIRV_CROSS_ENABLE_GLSL)
message(FATAL_ERROR "Must enable GLSL if building CLI.")
endif()
if (NOT SPIRV_CROSS_ENABLE_HLSL)
message(FATAL_ERROR "Must enable HLSL if building CLI.")
endif()
if (NOT SPIRV_CROSS_ENABLE_MSL)
message(FATAL_ERROR "Must enable MSL if building CLI.")
endif()
if (NOT SPIRV_CROSS_ENABLE_CPP)
message(FATAL_ERROR "Must enable C++ if building CLI.")
endif()
if (NOT SPIRV_CROSS_ENABLE_REFLECT)
message(FATAL_ERROR "Must enable reflection if building CLI.")
endif()
if (NOT SPIRV_CROSS_ENABLE_UTIL)
message(FATAL_ERROR "Must enable utils if building CLI.")
endif()
if (NOT SPIRV_CROSS_STATIC)
message(FATAL_ERROR "Must build static libraries if building CLI.")
endif()
add_executable(spirv-cross main.cpp)
target_compile_options(spirv-cross PRIVATE ${spirv-compiler-options})
target_include_directories(spirv-cross PRIVATE ${CMAKE_CURRENT_BINARY_DIR})
target_compile_definitions(spirv-cross PRIVATE ${spirv-compiler-defines} HAVE_SPIRV_CROSS_GIT_VERSION)
set_target_properties(spirv-cross PROPERTIES LINK_FLAGS "${spirv-cross-link-flags}")
install(TARGETS spirv-cross RUNTIME DESTINATION bin)
target_link_libraries(spirv-cross PRIVATE
spirv-cross-glsl
spirv-cross-hlsl
spirv-cross-cpp
spirv-cross-reflect
spirv-cross-msl
spirv-cross-util
spirv-cross-core)
if (SPIRV_CROSS_ENABLE_TESTS)
# Set up tests, using only the simplest modes of the test_shaders
# script. You have to invoke the script manually to:
# - Update the reference files
# - Get cycle counts from malisc
# - Keep failing outputs
find_package(PythonInterp)
find_program(spirv-cross-glslang NAMES glslangValidator
PATHS ${CMAKE_CURRENT_SOURCE_DIR}/external/glslang-build/output/bin
NO_DEFAULT_PATH)
find_program(spirv-cross-spirv-as NAMES spirv-as
PATHS ${CMAKE_CURRENT_SOURCE_DIR}/external/spirv-tools-build/output/bin
NO_DEFAULT_PATH)
find_program(spirv-cross-spirv-val NAMES spirv-val
PATHS ${CMAKE_CURRENT_SOURCE_DIR}/external/spirv-tools-build/output/bin
NO_DEFAULT_PATH)
find_program(spirv-cross-spirv-opt NAMES spirv-opt
PATHS ${CMAKE_CURRENT_SOURCE_DIR}/external/spirv-tools-build/output/bin
NO_DEFAULT_PATH)
if ((${spirv-cross-glslang} MATCHES "NOTFOUND") OR (${spirv-cross-spirv-as} MATCHES "NOTFOUND") OR (${spirv-cross-spirv-val} MATCHES "NOTFOUND") OR (${spirv-cross-spirv-opt} MATCHES "NOTFOUND"))
set(SPIRV_CROSS_ENABLE_TESTS OFF)
message("Could not find glslang or SPIRV-Tools build under external/. Run ./checkout_glslang_spirv_tools.sh and ./build_glslang_spirv_tools.sh. Testing will be disabled.")
else()
set(SPIRV_CROSS_ENABLE_TESTS ON)
message("Found glslang and SPIRV-Tools. Enabling test suite.")
message("Found glslangValidator in: ${spirv-cross-glslang}.")
message("Found spirv-as in: ${spirv-cross-spirv-as}.")
message("Found spirv-val in: ${spirv-cross-spirv-val}.")
message("Found spirv-opt in: ${spirv-cross-spirv-opt}.")
endif()
set(spirv-cross-externals
--glslang "${spirv-cross-glslang}"
--spirv-as "${spirv-cross-spirv-as}"
--spirv-opt "${spirv-cross-spirv-opt}"
--spirv-val "${spirv-cross-spirv-val}")
if (${PYTHONINTERP_FOUND} AND SPIRV_CROSS_ENABLE_TESTS)
if (${PYTHON_VERSION_MAJOR} GREATER 2)
add_executable(spirv-cross-c-api-test tests-other/c_api_test.c)
target_link_libraries(spirv-cross-c-api-test spirv-cross-c)
set_target_properties(spirv-cross-c-api-test PROPERTIES LINK_FLAGS "${spirv-cross-link-flags}")
add_executable(spirv-cross-small-vector-test tests-other/small_vector.cpp)
target_link_libraries(spirv-cross-small-vector-test spirv-cross-core)
set_target_properties(spirv-cross-small-vector-test PROPERTIES LINK_FLAGS "${spirv-cross-link-flags}")
add_executable(spirv-cross-msl-constexpr-test tests-other/msl_constexpr_test.cpp)
target_link_libraries(spirv-cross-msl-constexpr-test spirv-cross-c)
set_target_properties(spirv-cross-msl-constexpr-test PROPERTIES LINK_FLAGS "${spirv-cross-link-flags}")
if (CMAKE_COMPILER_IS_GNUCXX OR (${CMAKE_CXX_COMPILER_ID} MATCHES "Clang"))
target_compile_options(spirv-cross-c-api-test PRIVATE -std=c89 -Wall -Wextra)
endif()
add_test(NAME spirv-cross-c-api-test
COMMAND $<TARGET_FILE:spirv-cross-c-api-test> ${CMAKE_CURRENT_SOURCE_DIR}/tests-other/c_api_test.spv
${spirv-cross-abi-major}
${spirv-cross-abi-minor}
${spirv-cross-abi-patch})
add_test(NAME spirv-cross-small-vector-test
COMMAND $<TARGET_FILE:spirv-cross-small-vector-test>)
add_test(NAME spirv-cross-msl-constexpr-test
COMMAND $<TARGET_FILE:spirv-cross-msl-constexpr-test> ${CMAKE_CURRENT_SOURCE_DIR}/tests-other/msl_constexpr_test.spv)
add_test(NAME spirv-cross-test
COMMAND ${PYTHON_EXECUTABLE} ${CMAKE_CURRENT_SOURCE_DIR}/test_shaders.py --parallel
${spirv-cross-externals}
${CMAKE_CURRENT_SOURCE_DIR}/shaders
WORKING_DIRECTORY $<TARGET_FILE_DIR:spirv-cross>)
add_test(NAME spirv-cross-test-no-opt
COMMAND ${PYTHON_EXECUTABLE} ${CMAKE_CURRENT_SOURCE_DIR}/test_shaders.py --parallel
${spirv-cross-externals}
${CMAKE_CURRENT_SOURCE_DIR}/shaders-no-opt
WORKING_DIRECTORY $<TARGET_FILE_DIR:spirv-cross>)
add_test(NAME spirv-cross-test-metal
COMMAND ${PYTHON_EXECUTABLE} ${CMAKE_CURRENT_SOURCE_DIR}/test_shaders.py --metal --parallel
${spirv-cross-externals}
${CMAKE_CURRENT_SOURCE_DIR}/shaders-msl
WORKING_DIRECTORY $<TARGET_FILE_DIR:spirv-cross>)
add_test(NAME spirv-cross-test-metal-no-opt
COMMAND ${PYTHON_EXECUTABLE} ${CMAKE_CURRENT_SOURCE_DIR}/test_shaders.py --metal --parallel
${spirv-cross-externals}
${CMAKE_CURRENT_SOURCE_DIR}/shaders-msl-no-opt
WORKING_DIRECTORY $<TARGET_FILE_DIR:spirv-cross>)
add_test(NAME spirv-cross-test-hlsl
COMMAND ${PYTHON_EXECUTABLE} ${CMAKE_CURRENT_SOURCE_DIR}/test_shaders.py --hlsl --parallel
${spirv-cross-externals}
${CMAKE_CURRENT_SOURCE_DIR}/shaders-hlsl
WORKING_DIRECTORY $<TARGET_FILE_DIR:spirv-cross>)
add_test(NAME spirv-cross-test-hlsl-no-opt
COMMAND ${PYTHON_EXECUTABLE} ${CMAKE_CURRENT_SOURCE_DIR}/test_shaders.py --hlsl --parallel
${spirv-cross-externals}
${CMAKE_CURRENT_SOURCE_DIR}/shaders-hlsl-no-opt
WORKING_DIRECTORY $<TARGET_FILE_DIR:spirv-cross>)
add_test(NAME spirv-cross-test-opt
COMMAND ${PYTHON_EXECUTABLE} ${CMAKE_CURRENT_SOURCE_DIR}/test_shaders.py --opt --parallel
${spirv-cross-externals}
${CMAKE_CURRENT_SOURCE_DIR}/shaders
WORKING_DIRECTORY $<TARGET_FILE_DIR:spirv-cross>)
add_test(NAME spirv-cross-test-metal-opt
COMMAND ${PYTHON_EXECUTABLE} ${CMAKE_CURRENT_SOURCE_DIR}/test_shaders.py --metal --opt --parallel
${spirv-cross-externals}
${CMAKE_CURRENT_SOURCE_DIR}/shaders-msl
WORKING_DIRECTORY $<TARGET_FILE_DIR:spirv-cross>)
add_test(NAME spirv-cross-test-hlsl-opt
COMMAND ${PYTHON_EXECUTABLE} ${CMAKE_CURRENT_SOURCE_DIR}/test_shaders.py --hlsl --opt --parallel
${spirv-cross-externals}
${CMAKE_CURRENT_SOURCE_DIR}/shaders-hlsl
WORKING_DIRECTORY $<TARGET_FILE_DIR:spirv-cross>)
add_test(NAME spirv-cross-test-reflection
COMMAND ${PYTHON_EXECUTABLE} ${CMAKE_CURRENT_SOURCE_DIR}/test_shaders.py --reflect --parallel
${spirv-cross-externals}
${CMAKE_CURRENT_SOURCE_DIR}/shaders-reflection
WORKING_DIRECTORY $<TARGET_FILE_DIR:spirv-cross>)
endif()
elseif(NOT ${PYTHONINTERP_FOUND})
message(WARNING "Testing disabled. Could not find python3. If you have python3 installed try running "
"cmake with -DPYTHON_EXECUTABLE:FILEPATH=/path/to/python3 to help it find the executable")
endif()
endif()
endif()

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A reminder that this issue tracker is managed by the Khronos Group. Interactions here should follow the Khronos Code of Conduct (https://www.khronos.org/developers/code-of-conduct), which prohibits aggressive or derogatory language. Please keep the discussion friendly and civil.

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/*
** Copyright (c) 2014-2016 The Khronos Group Inc.
**
** Permission is hereby granted, free of charge, to any person obtaining a copy
** of this software and/or associated documentation files (the "Materials"),
** to deal in the Materials without restriction, including without limitation
** the rights to use, copy, modify, merge, publish, distribute, sublicense,
** and/or sell copies of the Materials, and to permit persons to whom the
** Materials are furnished to do so, subject to the following conditions:
**
** The above copyright notice and this permission notice shall be included in
** all copies or substantial portions of the Materials.
**
** MODIFICATIONS TO THIS FILE MAY MEAN IT NO LONGER ACCURATELY REFLECTS KHRONOS
** STANDARDS. THE UNMODIFIED, NORMATIVE VERSIONS OF KHRONOS SPECIFICATIONS AND
** HEADER INFORMATION ARE LOCATED AT https://www.khronos.org/registry/
**
** THE MATERIALS ARE PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
** OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
** FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
** THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
** LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
** FROM,OUT OF OR IN CONNECTION WITH THE MATERIALS OR THE USE OR OTHER DEALINGS
** IN THE MATERIALS.
*/
#ifndef GLSLstd450_H
#define GLSLstd450_H
static const int GLSLstd450Version = 100;
static const int GLSLstd450Revision = 3;
enum GLSLstd450 {
GLSLstd450Bad = 0, // Don't use
GLSLstd450Round = 1,
GLSLstd450RoundEven = 2,
GLSLstd450Trunc = 3,
GLSLstd450FAbs = 4,
GLSLstd450SAbs = 5,
GLSLstd450FSign = 6,
GLSLstd450SSign = 7,
GLSLstd450Floor = 8,
GLSLstd450Ceil = 9,
GLSLstd450Fract = 10,
GLSLstd450Radians = 11,
GLSLstd450Degrees = 12,
GLSLstd450Sin = 13,
GLSLstd450Cos = 14,
GLSLstd450Tan = 15,
GLSLstd450Asin = 16,
GLSLstd450Acos = 17,
GLSLstd450Atan = 18,
GLSLstd450Sinh = 19,
GLSLstd450Cosh = 20,
GLSLstd450Tanh = 21,
GLSLstd450Asinh = 22,
GLSLstd450Acosh = 23,
GLSLstd450Atanh = 24,
GLSLstd450Atan2 = 25,
GLSLstd450Pow = 26,
GLSLstd450Exp = 27,
GLSLstd450Log = 28,
GLSLstd450Exp2 = 29,
GLSLstd450Log2 = 30,
GLSLstd450Sqrt = 31,
GLSLstd450InverseSqrt = 32,
GLSLstd450Determinant = 33,
GLSLstd450MatrixInverse = 34,
GLSLstd450Modf = 35, // second operand needs an OpVariable to write to
GLSLstd450ModfStruct = 36, // no OpVariable operand
GLSLstd450FMin = 37,
GLSLstd450UMin = 38,
GLSLstd450SMin = 39,
GLSLstd450FMax = 40,
GLSLstd450UMax = 41,
GLSLstd450SMax = 42,
GLSLstd450FClamp = 43,
GLSLstd450UClamp = 44,
GLSLstd450SClamp = 45,
GLSLstd450FMix = 46,
GLSLstd450IMix = 47, // Reserved
GLSLstd450Step = 48,
GLSLstd450SmoothStep = 49,
GLSLstd450Fma = 50,
GLSLstd450Frexp = 51, // second operand needs an OpVariable to write to
GLSLstd450FrexpStruct = 52, // no OpVariable operand
GLSLstd450Ldexp = 53,
GLSLstd450PackSnorm4x8 = 54,
GLSLstd450PackUnorm4x8 = 55,
GLSLstd450PackSnorm2x16 = 56,
GLSLstd450PackUnorm2x16 = 57,
GLSLstd450PackHalf2x16 = 58,
GLSLstd450PackDouble2x32 = 59,
GLSLstd450UnpackSnorm2x16 = 60,
GLSLstd450UnpackUnorm2x16 = 61,
GLSLstd450UnpackHalf2x16 = 62,
GLSLstd450UnpackSnorm4x8 = 63,
GLSLstd450UnpackUnorm4x8 = 64,
GLSLstd450UnpackDouble2x32 = 65,
GLSLstd450Length = 66,
GLSLstd450Distance = 67,
GLSLstd450Cross = 68,
GLSLstd450Normalize = 69,
GLSLstd450FaceForward = 70,
GLSLstd450Reflect = 71,
GLSLstd450Refract = 72,
GLSLstd450FindILsb = 73,
GLSLstd450FindSMsb = 74,
GLSLstd450FindUMsb = 75,
GLSLstd450InterpolateAtCentroid = 76,
GLSLstd450InterpolateAtSample = 77,
GLSLstd450InterpolateAtOffset = 78,
GLSLstd450NMin = 79,
GLSLstd450NMax = 80,
GLSLstd450NClamp = 81,
GLSLstd450Count
};
#endif // #ifndef GLSLstd450_H

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Apache License
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TARGET := spirv-cross
SOURCES := $(wildcard spirv_*.cpp)
CLI_SOURCES := main.cpp
OBJECTS := $(SOURCES:.cpp=.o)
CLI_OBJECTS := $(CLI_SOURCES:.cpp=.o)
STATIC_LIB := lib$(TARGET).a
DEPS := $(OBJECTS:.o=.d) $(CLI_OBJECTS:.o=.d)
CXXFLAGS += -std=c++11 -Wall -Wextra -Wshadow
ifeq ($(DEBUG), 1)
CXXFLAGS += -O0 -g
else
CXXFLAGS += -O2 -DNDEBUG
endif
ifeq ($(SPIRV_CROSS_EXCEPTIONS_TO_ASSERTIONS), 1)
CXXFLAGS += -DSPIRV_CROSS_EXCEPTIONS_TO_ASSERTIONS -fno-exceptions
endif
all: $(TARGET)
-include $(DEPS)
$(TARGET): $(CLI_OBJECTS) $(STATIC_LIB)
$(CXX) -o $@ $(CLI_OBJECTS) $(STATIC_LIB) $(LDFLAGS)
$(STATIC_LIB): $(OBJECTS)
$(AR) rcs $@ $(OBJECTS)
%.o: %.cpp
$(CXX) -c -o $@ $< $(CXXFLAGS) -MMD
clean:
rm -f $(TARGET) $(OBJECTS) $(CLI_OBJECTS) $(STATIC_LIB) $(DEPS)
.PHONY: clean

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# SPIRV-Cross
SPIRV-Cross is a tool designed for parsing and converting SPIR-V to other shader languages.
[![Build Status](https://travis-ci.org/KhronosGroup/SPIRV-Cross.svg?branch=master)](https://travis-ci.org/KhronosGroup/SPIRV-Cross)
[![Build Status](https://ci.appveyor.com/api/projects/status/github/KhronosGroup/SPIRV-Cross?svg=true&branch=master)](https://ci.appveyor.com/project/HansKristian-Work/SPIRV-Cross)
## Features
- Convert SPIR-V to readable, usable and efficient GLSL
- Convert SPIR-V to readable, usable and efficient Metal Shading Language (MSL)
- Convert SPIR-V to readable, usable and efficient HLSL
- Convert SPIR-V to debuggable C++ [DEPRECATED]
- Convert SPIR-V to a JSON reflection format [EXPERIMENTAL]
- Reflection API to simplify the creation of Vulkan pipeline layouts
- Reflection API to modify and tweak OpDecorations
- Supports "all" of vertex, fragment, tessellation, geometry and compute shaders.
SPIRV-Cross tries hard to emit readable and clean output from the SPIR-V.
The goal is to emit GLSL or MSL that looks like it was written by a human and not awkward IR/assembly-like code.
NOTE: Individual features are expected to be mostly complete, but it is possible that certain obscure GLSL features are not yet supported.
However, most missing features are expected to be "trivial" improvements at this stage.
## Building
SPIRV-Cross has been tested on Linux, iOS/OSX, Windows and Android. CMake is the main build system.
### Linux and macOS
Building with CMake is recommended, as it is the only build system which is tested in continuous integration.
It is also the only build system which has install commands and other useful build system features.
However, you can just run `make` on the command line as a fallback if you only care about the CLI tool.
A non-ancient GCC (4.8+) or Clang (3.x+) compiler is required as SPIRV-Cross uses C++11 extensively.
### Windows
Building with CMake is recommended, which is the only way to target MSVC.
MinGW-w64 based compilation works with `make` as a fallback.
### Android
SPIRV-Cross is only useful as a library here. Use the CMake build to link SPIRV-Cross to your project.
### C++ exceptions
The make and CMake build flavors offer the option to treat exceptions as assertions. To disable exceptions for make just append `SPIRV_CROSS_EXCEPTIONS_TO_ASSERTIONS=1` to the command line. For CMake append `-DSPIRV_CROSS_EXCEPTIONS_TO_ASSERTIONS=ON`. By default exceptions are enabled.
### Static, shared and CLI
You can use `-DSPIRV_CROSS_STATIC=ON/OFF` `-DSPIRV_CROSS_SHARED=ON/OFF` `-DSPIRV_CROSS_CLI=ON/OFF` to control which modules are built (and installed).
## Usage
### Using the C++ API
The C++ API is the main API for SPIRV-Cross. For more in-depth documentation than what's provided in this README,
please have a look at the [Wiki](https://github.com/KhronosGroup/SPIRV-Cross/wiki).
**NOTE**: This API is not guaranteed to be ABI-stable, and it is highly recommended to link against this API statically.
The API is generally quite stable, but it can change over time, see the C API for more stability.
To perform reflection and convert to other shader languages you can use the SPIRV-Cross API.
For example:
```c++
#include "spirv_glsl.hpp"
#include <vector>
#include <utility>
extern std::vector<uint32_t> load_spirv_file();
int main()
{
// Read SPIR-V from disk or similar.
std::vector<uint32_t> spirv_binary = load_spirv_file();
spirv_cross::CompilerGLSL glsl(std::move(spirv_binary));
// The SPIR-V is now parsed, and we can perform reflection on it.
spirv_cross::ShaderResources resources = glsl.get_shader_resources();
// Get all sampled images in the shader.
for (auto &resource : resources.sampled_images)
{
unsigned set = glsl.get_decoration(resource.id, spv::DecorationDescriptorSet);
unsigned binding = glsl.get_decoration(resource.id, spv::DecorationBinding);
printf("Image %s at set = %u, binding = %u\n", resource.name.c_str(), set, binding);
// Modify the decoration to prepare it for GLSL.
glsl.unset_decoration(resource.id, spv::DecorationDescriptorSet);
// Some arbitrary remapping if we want.
glsl.set_decoration(resource.id, spv::DecorationBinding, set * 16 + binding);
}
// Set some options.
spirv_cross::CompilerGLSL::Options options;
options.version = 310;
options.es = true;
glsl.set_options(options);
// Compile to GLSL, ready to give to GL driver.
std::string source = glsl.compile();
}
```
### Using the C API wrapper
To facilitate C compatibility and compatibility with foreign programming languages, a C89-compatible API wrapper is provided. Unlike the C++ API,
the goal of this wrapper is to be fully stable, both API and ABI-wise.
This is the only interface which is supported when building SPIRV-Cross as a shared library.
An important point of the wrapper is that all memory allocations are contained in the `spvc_context`.
This simplifies the use of the API greatly. However, you should destroy the context as soon as reasonable,
or use `spvc_context_release_allocations()` if you intend to reuse the `spvc_context` object again soon.
Most functions return a `spvc_result`, where `SPVC_SUCCESS` is the only success code.
For brevity, the code below does not do any error checking.
```c
#include <spirv_cross_c.h>
const SpvId *spirv = get_spirv_data();
size_t word_count = get_spirv_word_count();
spvc_context context = NULL;
spvc_parsed_ir ir = NULL;
spvc_compiler compiler_glsl = NULL;
spvc_compiler_options options = NULL;
spvc_resources resources = NULL;
const spvc_reflected_resource *list = NULL;
const char *result = NULL;
size_t count;
size_t i;
// Create context.
spvc_context_create(&context);
// Set debug callback.
spvc_context_set_error_callback(context, error_callback, userdata);
// Parse the SPIR-V.
spvc_context_parse_spirv(context, spirv, word_count, &ir);
// Hand it off to a compiler instance and give it ownership of the IR.
spvc_context_create_compiler(context, SPVC_BACKEND_GLSL, ir, SPVC_CAPTURE_MODE_TAKE_OWNERSHIP, &compiler_glsl);
// Do some basic reflection.
spvc_compiler_create_shader_resources(compiler_glsl, &resources);
spvc_resources_get_resource_list_for_type(resources, SPVC_RESOURCE_TYPE_UNIFORM_BUFFER, &list, &count);
for (i = 0; i < count; i++)
{
printf("ID: %u, BaseTypeID: %u, TypeID: %u, Name: %s\n", list[i].id, list[i].base_type_id, list[i].type_id,
list[i].name);
printf(" Set: %u, Binding: %u\n",
spvc_compiler_get_decoration(compiler_glsl, list[i].id, SpvDecorationDescriptorSet),
spvc_compiler_get_decoration(compiler_glsl, list[i].id, SpvDecorationBinding));
}
// Modify options.
spvc_compiler_create_compiler_options(context, &options);
spvc_compiler_options_set_uint(options, SPVC_COMPILER_OPTION_GLSL_VERSION, 330);
spvc_compiler_options_set_bool(options, SPVC_COMPILER_OPTION_GLSL_ES, SPVC_FALSE);
spvc_compiler_install_compiler_options(compiler_glsl, options);
spvc_compiler_compile(compiler, &result);
printf("Cross-compiled source: %s\n", result);
// Frees all memory we allocated so far.
spvc_context_destroy(context);
```
### Linking
#### CMake add_subdirectory()
This is the recommended way if you are using CMake and want to link against SPIRV-Cross statically.
#### Integrating SPIRV-Cross in a custom build system
To add SPIRV-Cross to your own codebase, just copy the source and header files from root directory
and build the relevant .cpp files you need. Make sure to build with C++11 support, e.g. `-std=c++11` in GCC and Clang.
Alternatively, the Makefile generates a libspirv-cross.a static library during build that can be linked in.
#### Linking against SPIRV-Cross as a system library
It is possible to link against SPIRV-Cross when it is installed as a system library,
which would be mostly relevant for Unix-like platforms.
##### pkg-config
For Unix-based systems, a pkg-config is installed for the C API, e.g.:
```
$ pkg-config spirv-cross-c-shared --libs --cflags
-I/usr/local/include/spirv_cross -L/usr/local/lib -lspirv-cross-c-shared
```
##### CMake
If the project is installed, it can be found with `find_package()`, e.g.:
```
cmake_minimum_required(VERSION 3.5)
set(CMAKE_C_STANDARD 99)
project(Test LANGUAGES C)
find_package(spirv_cross_c_shared)
if (spirv_cross_c_shared_FOUND)
message(STATUS "Found SPIRV-Cross C API! :)")
else()
message(STATUS "Could not find SPIRV-Cross C API! :(")
endif()
add_executable(test test.c)
target_link_libraries(test spirv-cross-c-shared)
```
test.c:
```c
#include <spirv_cross_c.h>
int main(void)
{
spvc_context context;
spvc_context_create(&context);
spvc_context_destroy(context);
}
```
### CLI
The CLI is suitable for basic cross-compilation tasks, but it cannot support the full flexibility that the API can.
Some examples below.
#### Creating a SPIR-V file from GLSL with glslang
```
glslangValidator -H -V -o test.spv test.frag
```
#### Converting a SPIR-V file to GLSL ES
```
glslangValidator -H -V -o test.spv shaders/comp/basic.comp
./spirv-cross --version 310 --es test.spv
```
#### Converting to desktop GLSL
```
glslangValidator -H -V -o test.spv shaders/comp/basic.comp
./spirv-cross --version 330 --no-es test.spv --output test.comp
```
#### Disable prettifying optimizations
```
glslangValidator -H -V -o test.spv shaders/comp/basic.comp
./spirv-cross --version 310 --es test.spv --output test.comp --force-temporary
```
### Using shaders generated from C++ backend
Please see `samples/cpp` where some GLSL shaders are compiled to SPIR-V, decompiled to C++ and run with test data.
Reading through the samples should explain how to use the C++ interface.
A simple Makefile is included to build all shaders in the directory.
### Implementation notes
When using SPIR-V and SPIRV-Cross as an intermediate step for cross-compiling between high level languages there are some considerations to take into account,
as not all features used by one high-level language are necessarily supported natively by the target shader language.
SPIRV-Cross aims to provide the tools needed to handle these scenarios in a clean and robust way, but some manual action is required to maintain compatibility.
#### HLSL source to GLSL
##### HLSL entry points
When using SPIR-V shaders compiled from HLSL, there are some extra things you need to take care of.
First make sure that the entry point is used correctly.
If you forget to set the entry point correctly in glslangValidator (-e MyFancyEntryPoint),
you will likely encounter this error message:
```
Cannot end a function before ending the current block.
Likely cause: If this SPIR-V was created from glslang HLSL, make sure the entry point is valid.
```
##### Vertex/Fragment interface linking
HLSL relies on semantics in order to effectively link together shader stages. In the SPIR-V generated by glslang, the transformation from HLSL to GLSL ends up looking like
```c++
struct VSOutput {
// SV_Position is rerouted to gl_Position
float4 position : SV_Position;
float4 coord : TEXCOORD0;
};
VSOutput main(...) {}
```
```c++
struct VSOutput {
float4 coord;
}
layout(location = 0) out VSOutput _magicNameGeneratedByGlslang;
```
While this works, be aware of the type of the struct which is used in the vertex stage and the fragment stage.
There may be issues if the structure type name differs in vertex stage and fragment stage.
You can make use of the reflection interface to force the name of the struct type.
```
// Something like this for both vertex outputs and fragment inputs.
compiler.set_name(varying_resource.base_type_id, "VertexFragmentLinkage");
```
Some platform may require identical variable name for both vertex outputs and fragment inputs. (for example MacOSX)
to rename varaible base on location, please add
```
--rename-interface-variable <in|out> <location> <new_variable_name>
```
#### HLSL source to legacy GLSL/ESSL
HLSL tends to emit varying struct types to pass data between vertex and fragment.
This is not supported in legacy GL/GLES targets, so to support this, varying structs are flattened.
This is done automatically, but the API user might need to be aware that this is happening in order to support all cases.
Modern GLES code like this:
```c++
struct Output {
vec4 a;
vec2 b;
};
out Output vout;
```
Is transformed into:
```c++
struct Output {
vec4 a;
vec2 b;
};
varying vec4 Output_a;
varying vec2 Output_b;
```
Note that now, both the struct name and the member names will participate in the linking interface between vertex and fragment, so
API users might want to ensure that both the struct names and member names match so that vertex outputs and fragment inputs can link properly.
#### Separate image samplers (HLSL/Vulkan) for backends which do not support it (GLSL)
Another thing you need to remember is when using samplers and textures in HLSL these are separable, and not directly compatible with GLSL. If you need to use this with desktop GL/GLES, you need to call `Compiler::build_combined_image_samplers` first before calling `Compiler::compile`, or you will get an exception.
```c++
// From main.cpp
// Builds a mapping for all combinations of images and samplers.
compiler->build_combined_image_samplers();
// Give the remapped combined samplers new names.
// Here you can also set up decorations if you want (binding = #N).
for (auto &remap : compiler->get_combined_image_samplers())
{
compiler->set_name(remap.combined_id, join("SPIRV_Cross_Combined", compiler->get_name(remap.image_id),
compiler->get_name(remap.sampler_id)));
}
```
If your target is Vulkan GLSL, `--vulkan-semantics` will emit separate image samplers as you'd expect.
The command line client calls `Compiler::build_combined_image_samplers` automatically, but if you're calling the library, you'll need to do this yourself.
#### Descriptor sets (Vulkan GLSL) for backends which do not support them (HLSL/GLSL/Metal)
Descriptor sets are unique to Vulkan, so make sure that descriptor set + binding is remapped to a flat binding scheme (set always 0), so that other APIs can make sense of the bindings.
This can be done with `Compiler::set_decoration(id, spv::DecorationDescriptorSet)`.
#### Linking by name for targets which do not support explicit locations (legacy GLSL/ESSL)
Modern GLSL and HLSL sources (and SPIR-V) relies on explicit layout(location) qualifiers to guide the linking process between shader stages,
but older GLSL relies on symbol names to perform the linking. When emitting shaders with older versions, these layout statements will be removed,
so it is important that the API user ensures that the names of I/O variables are sanitized so that linking will work properly.
The reflection API can rename variables, struct types and struct members to deal with these scenarios using `Compiler::set_name` and friends.
#### Clip-space conventions
SPIRV-Cross can perform some common clip space conversions on gl_Position/SV_Position by enabling `CompilerGLSL::Options.vertex.fixup_clipspace`.
While this can be convenient, it is recommended to modify the projection matrices instead as that can achieve the same result.
For GLSL targets, enabling this will convert a shader which assumes `[0, w]` depth range (Vulkan / D3D / Metal) into `[-w, w]` range.
For MSL and HLSL targets, enabling this will convert a shader in `[-w, w]` depth range (OpenGL) to `[0, w]` depth range.
By default, the CLI will not enable `fixup_clipspace`, but in the API you might want to set an explicit value using `CompilerGLSL::set_options()`.
Y-flipping of gl_Position and similar is also supported.
The use of this is discouraged, because relying on vertex shader Y-flipping tends to get quite messy.
To enable this, set `CompilerGLSL::Options.vertex.flip_vert_y` or `--flip-vert-y` in CLI.
## Contributing
Contributions to SPIRV-Cross are welcome. See Testing and Licensing sections for details.
### Testing
SPIRV-Cross maintains a test suite of shaders with reference output of how the output looks after going through a roundtrip through
glslangValidator/spirv-as then back through SPIRV-Cross again.
The reference files are stored inside the repository in order to be able to track regressions.
All pull requests should ensure that test output does not change unexpectedly. This can be tested with:
```
./checkout_glslang_spirv_tools.sh # Checks out glslang and SPIRV-Tools at a fixed revision which matches the reference output.
# NOTE: Some users have reported problems cloning from git:// paths. To use https:// instead pass in
# $ PROTOCOL=https ./checkout_glslang_spirv_tools.sh
# instead.
./build_glslang_spirv_tools.sh # Builds glslang and SPIRV-Tools.
./test_shaders.sh # Runs over all changes and makes sure that there are no deltas compared to reference files.
```
`./test_shaders.sh` currently requires a Makefile setup with GCC/Clang to be set up.
However, on Windows, this can be rather inconvenient if a MinGW environment is not set up.
To use a spirv-cross binary you built with CMake (or otherwise), you can pass in an environment variable as such:
```
SPIRV_CROSS_PATH=path/to/custom/spirv-cross ./test_shaders.sh
```
However, when improving SPIRV-Cross there are of course legitimate cases where reference output should change.
In these cases, run:
```
./update_test_shaders.sh # SPIRV_CROSS_PATH also works here.
```
to update the reference files and include these changes as part of the pull request.
Always make sure you are running the correct version of glslangValidator as well as SPIRV-Tools when updating reference files.
See `checkout_glslang_spirv_tools.sh` which revisions are currently expected. The revisions change regularly.
In short, the master branch should always be able to run `./test_shaders.py shaders` and friends without failure.
SPIRV-Cross uses Travis CI to test all pull requests, so it is not strictly needed to perform testing yourself if you have problems running it locally.
A pull request which does not pass testing on Travis will not be accepted however.
When adding support for new features to SPIRV-Cross, a new shader and reference file should be added which covers usage of the new shader features in question.
Travis CI runs the test suite with the CMake, by running `ctest`. This is a more straight-forward alternative to `./test_shaders.sh`.
### Licensing
Contributors of new files should add a copyright header at the top of every new source code file with their copyright
along with the Apache 2.0 licensing stub.
### Formatting
SPIRV-Cross uses `clang-format` to automatically format code.
Please use `clang-format` with the style sheet found in `.clang-format` to automatically format code before submitting a pull request.
To make things easy, the `format_all.sh` script can be used to format all
source files in the library. In this directory, run the following from the
command line:
./format_all.sh
## Regression testing
In shaders/ a collection of shaders are maintained for purposes of regression testing.
The current reference output is contained in reference/.
`./test_shaders.py shaders` can be run to perform regression testing.
See `./test_shaders.py --help` for more.
### Metal backend
To test the roundtrip path GLSL -> SPIR-V -> MSL, `--msl` can be added, e.g. `./test_shaders.py --msl shaders-msl`.
### HLSL backend
To test the roundtrip path GLSL -> SPIR-V -> HLSL, `--hlsl` can be added, e.g. `./test_shaders.py --hlsl shaders-hlsl`.
### Updating regression tests
When legitimate changes are found, use `--update` flag to update regression files.
Otherwise, `./test_shaders.py` will fail with error code.
### Mali Offline Compiler cycle counts
To obtain a CSV of static shader cycle counts before and after going through spirv-cross, add
`--malisc` flag to `./test_shaders`. This requires the Mali Offline Compiler to be installed in PATH.

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environment:
matrix:
- GENERATOR: "Visual Studio 12 2013 Win64"
CONFIG: Debug
- GENERATOR: "Visual Studio 12 2013 Win64"
CONFIG: Release
- GENERATOR: "Visual Studio 14 2015 Win64"
CONFIG: Debug
- GENERATOR: "Visual Studio 14 2015 Win64"
CONFIG: Release
- GENERATOR: "Visual Studio 12 2013"
CONFIG: Debug
- GENERATOR: "Visual Studio 12 2013"
CONFIG: Release
- GENERATOR: "Visual Studio 14 2015"
CONFIG: Debug
- GENERATOR: "Visual Studio 14 2015"
CONFIG: Release
build_script:
- git submodule update --init
- cmake "-G%GENERATOR%" -H. -B_builds
- cmake --build _builds --config "%CONFIG%"

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#!/bin/bash
PROFILE=Release
if [ ! -z $1 ]; then
PROFILE=$1
fi
if [ ! -z $2 ]; then
NPROC="--parallel $2"
fi
echo "Building glslang."
mkdir -p external/glslang-build
cd external/glslang-build
cmake ../glslang -DCMAKE_BUILD_TYPE=$PROFILE -DCMAKE_INSTALL_PREFIX=output
cmake --build . --config $PROFILE --target install ${NPROC}
cd ../..
echo "Building SPIRV-Tools."
mkdir -p external/spirv-tools-build
cd external/spirv-tools-build
cmake ../spirv-tools -DCMAKE_BUILD_TYPE=$PROFILE -DSPIRV_WERROR=OFF -DCMAKE_INSTALL_PREFIX=output
cmake --build . --config $PROFILE --target install ${NPROC}
cd ../..

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#!/bin/bash
GLSLANG_REV=e291f7a09f6733f6634fe077a228056fabee881e
SPIRV_TOOLS_REV=89fe836fe22c3e5c2a062ebeade012e2c2f0839b
SPIRV_HEADERS_REV=c4f8f65792d4bf2657ca751904c511bbcf2ac77b
if [ -z $PROTOCOL ]; then
PROTOCOL=git
fi
echo "Using protocol \"$PROTOCOL\" for checking out repositories. If this is problematic, try PROTOCOL=https $0."
if [ -d external/glslang ]; then
echo "Updating glslang to revision $GLSLANG_REV."
cd external/glslang
git fetch origin
git checkout $GLSLANG_REV
else
echo "Cloning glslang revision $GLSLANG_REV."
mkdir -p external
cd external
git clone $PROTOCOL://github.com/KhronosGroup/glslang.git
cd glslang
git checkout $GLSLANG_REV
fi
cd ../..
if [ -d external/spirv-tools ]; then
echo "Updating SPIRV-Tools to revision $SPIRV_TOOLS_REV."
cd external/spirv-tools
git fetch origin
git checkout $SPIRV_TOOLS_REV
else
echo "Cloning SPIRV-Tools revision $SPIRV_TOOLS_REV."
mkdir -p external
cd external
git clone $PROTOCOL://github.com/KhronosGroup/SPIRV-Tools.git spirv-tools
cd spirv-tools
git checkout $SPIRV_TOOLS_REV
fi
if [ -d external/spirv-headers ]; then
cd external/spirv-headers
git pull origin master
git checkout $SPIRV_HEADERS_REV
cd ../..
else
git clone $PROTOCOL://github.com/KhronosGroup/SPIRV-Headers.git external/spirv-headers
cd external/spirv-headers
git checkout $SPIRV_HEADERS_REV
cd ../..
fi
cd ../..

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#ifndef SPIRV_CROSS_GIT_VERSION_H_
#define SPIRV_CROSS_GIT_VERSION_H_
#define SPIRV_CROSS_GIT_REVISION "Git commit: @spirv-cross-build-version@ Timestamp: @spirv-cross-timestamp@"
#endif

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#!/bin/bash
#for file in spirv_*.{cpp,hpp} include/spirv_cross/*.{hpp,h} samples/cpp/*.cpp main.cpp
for file in spirv_*.{cpp,hpp} main.cpp
do
echo "Formatting file: $file ..."
clang-format -style=file -i $file
done

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/*
* Copyright 2015-2017 ARM Limited
*
* 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.
*/
#ifndef SPIRV_CROSS_BARRIER_HPP
#define SPIRV_CROSS_BARRIER_HPP
#include <atomic>
#include <thread>
namespace spirv_cross
{
class Barrier
{
public:
Barrier()
{
count.store(0);
iteration.store(0);
}
void set_release_divisor(unsigned divisor)
{
this->divisor = divisor;
}
static inline void memoryBarrier()
{
std::atomic_thread_fence(std::memory_order_seq_cst);
}
void reset_counter()
{
count.store(0);
iteration.store(0);
}
void wait()
{
unsigned target_iteration = iteration.load(std::memory_order_relaxed) + 1;
// Overflows cleanly.
unsigned target_count = divisor * target_iteration;
// Barriers don't enforce memory ordering.
// Be as relaxed about the barrier as we possibly can!
unsigned c = count.fetch_add(1u, std::memory_order_relaxed);
if (c + 1 == target_count)
{
iteration.store(target_iteration, std::memory_order_relaxed);
}
else
{
// If we have more threads than the CPU, don't hog the CPU for very long periods of time.
while (iteration.load(std::memory_order_relaxed) != target_iteration)
std::this_thread::yield();
}
}
private:
unsigned divisor = 1;
std::atomic<unsigned> count;
std::atomic<unsigned> iteration;
};
}
#endif

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/*
* Copyright 2015-2017 ARM Limited
*
* 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.
*/
#ifndef SPIRV_CROSS_EXTERNAL_INTERFACE_H
#define SPIRV_CROSS_EXTERNAL_INTERFACE_H
#ifdef __cplusplus
extern "C" {
#endif
#include <stddef.h>
typedef struct spirv_cross_shader spirv_cross_shader_t;
struct spirv_cross_interface
{
spirv_cross_shader_t *(*construct)(void);
void (*destruct)(spirv_cross_shader_t *thiz);
void (*invoke)(spirv_cross_shader_t *thiz);
};
void spirv_cross_set_stage_input(spirv_cross_shader_t *thiz, unsigned location, void *data, size_t size);
void spirv_cross_set_stage_output(spirv_cross_shader_t *thiz, unsigned location, void *data, size_t size);
void spirv_cross_set_push_constant(spirv_cross_shader_t *thiz, void *data, size_t size);
void spirv_cross_set_uniform_constant(spirv_cross_shader_t *thiz, unsigned location, void *data, size_t size);
void spirv_cross_set_resource(spirv_cross_shader_t *thiz, unsigned set, unsigned binding, void **data, size_t size);
const struct spirv_cross_interface *spirv_cross_get_interface(void);
typedef enum spirv_cross_builtin {
SPIRV_CROSS_BUILTIN_POSITION = 0,
SPIRV_CROSS_BUILTIN_FRAG_COORD = 1,
SPIRV_CROSS_BUILTIN_WORK_GROUP_ID = 2,
SPIRV_CROSS_BUILTIN_NUM_WORK_GROUPS = 3,
SPIRV_CROSS_NUM_BUILTINS
} spirv_cross_builtin;
void spirv_cross_set_builtin(spirv_cross_shader_t *thiz, spirv_cross_builtin builtin, void *data, size_t size);
#define SPIRV_CROSS_NUM_DESCRIPTOR_SETS 4
#define SPIRV_CROSS_NUM_DESCRIPTOR_BINDINGS 16
#define SPIRV_CROSS_NUM_STAGE_INPUTS 16
#define SPIRV_CROSS_NUM_STAGE_OUTPUTS 16
#define SPIRV_CROSS_NUM_UNIFORM_CONSTANTS 32
enum spirv_cross_format
{
SPIRV_CROSS_FORMAT_R8_UNORM = 0,
SPIRV_CROSS_FORMAT_R8G8_UNORM = 1,
SPIRV_CROSS_FORMAT_R8G8B8_UNORM = 2,
SPIRV_CROSS_FORMAT_R8G8B8A8_UNORM = 3,
SPIRV_CROSS_NUM_FORMATS
};
enum spirv_cross_wrap
{
SPIRV_CROSS_WRAP_CLAMP_TO_EDGE = 0,
SPIRV_CROSS_WRAP_REPEAT = 1,
SPIRV_CROSS_NUM_WRAP
};
enum spirv_cross_filter
{
SPIRV_CROSS_FILTER_NEAREST = 0,
SPIRV_CROSS_FILTER_LINEAR = 1,
SPIRV_CROSS_NUM_FILTER
};
enum spirv_cross_mipfilter
{
SPIRV_CROSS_MIPFILTER_BASE = 0,
SPIRV_CROSS_MIPFILTER_NEAREST = 1,
SPIRV_CROSS_MIPFILTER_LINEAR = 2,
SPIRV_CROSS_NUM_MIPFILTER
};
struct spirv_cross_miplevel
{
const void *data;
unsigned width, height;
size_t stride;
};
struct spirv_cross_sampler_info
{
const struct spirv_cross_miplevel *mipmaps;
unsigned num_mipmaps;
enum spirv_cross_format format;
enum spirv_cross_wrap wrap_s;
enum spirv_cross_wrap wrap_t;
enum spirv_cross_filter min_filter;
enum spirv_cross_filter mag_filter;
enum spirv_cross_mipfilter mip_filter;
};
typedef struct spirv_cross_sampler_2d spirv_cross_sampler_2d_t;
spirv_cross_sampler_2d_t *spirv_cross_create_sampler_2d(const struct spirv_cross_sampler_info *info);
void spirv_cross_destroy_sampler_2d(spirv_cross_sampler_2d_t *samp);
#ifdef __cplusplus
}
#endif
#endif

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/*
* Copyright 2015-2017 ARM Limited
*
* 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.
*/
#ifndef SPIRV_CROSS_IMAGE_HPP
#define SPIRV_CROSS_IMAGE_HPP
#ifndef GLM_SWIZZLE
#define GLM_SWIZZLE
#endif
#ifndef GLM_FORCE_RADIANS
#define GLM_FORCE_RADIANS
#endif
#include <glm/glm.hpp>
namespace spirv_cross
{
template <typename T>
struct image2DBase
{
virtual ~image2DBase() = default;
inline virtual T load(glm::ivec2 coord) const
{
return T(0, 0, 0, 1);
}
inline virtual void store(glm::ivec2 coord, const T &v)
{
}
};
typedef image2DBase<glm::vec4> image2D;
typedef image2DBase<glm::ivec4> iimage2D;
typedef image2DBase<glm::uvec4> uimage2D;
template <typename T>
inline T imageLoad(const image2DBase<T> &image, glm::ivec2 coord)
{
return image.load(coord);
}
template <typename T>
void imageStore(image2DBase<T> &image, glm::ivec2 coord, const T &value)
{
image.store(coord, value);
}
}
#endif

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/*
* Copyright 2015-2017 ARM Limited
*
* 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.
*/
#ifndef SPIRV_CROSS_INTERNAL_INTERFACE_HPP
#define SPIRV_CROSS_INTERNAL_INTERFACE_HPP
// This file must only be included by the shader generated by spirv-cross!
#ifndef GLM_FORCE_SWIZZLE
#define GLM_FORCE_SWIZZLE
#endif
#ifndef GLM_FORCE_RADIANS
#define GLM_FORCE_RADIANS
#endif
#include <glm/glm.hpp>
#include "barrier.hpp"
#include "external_interface.h"
#include "image.hpp"
#include "sampler.hpp"
#include "thread_group.hpp"
#include <assert.h>
#include <stdint.h>
namespace internal
{
// Adaptor helpers to adapt GLSL access chain syntax to C++.
// Don't bother with arrays of arrays on uniforms ...
// Would likely need horribly complex variadic template munging.
template <typename T>
struct Interface
{
enum
{
ArraySize = 1,
Size = sizeof(T)
};
Interface()
: ptr(0)
{
}
T &get()
{
assert(ptr);
return *ptr;
}
T *ptr;
};
// For array types, return a pointer instead.
template <typename T, unsigned U>
struct Interface<T[U]>
{
enum
{
ArraySize = U,
Size = U * sizeof(T)
};
Interface()
: ptr(0)
{
}
T *get()
{
assert(ptr);
return ptr;
}
T *ptr;
};
// For case when array size is 1, avoid double dereference.
template <typename T>
struct PointerInterface
{
enum
{
ArraySize = 1,
Size = sizeof(T *)
};
enum
{
PreDereference = true
};
PointerInterface()
: ptr(0)
{
}
T &get()
{
assert(ptr);
return *ptr;
}
T *ptr;
};
// Automatically converts a pointer down to reference to match GLSL syntax.
template <typename T>
struct DereferenceAdaptor
{
DereferenceAdaptor(T **ptr)
: ptr(ptr)
{
}
T &operator[](unsigned index) const
{
return *(ptr[index]);
}
T **ptr;
};
// We can't have a linear array of T* since T* can be an abstract type in case of samplers.
// We also need a list of pointers since we can have run-time length SSBOs.
template <typename T, unsigned U>
struct PointerInterface<T[U]>
{
enum
{
ArraySize = U,
Size = sizeof(T *) * U
};
enum
{
PreDereference = false
};
PointerInterface()
: ptr(0)
{
}
DereferenceAdaptor<T> get()
{
assert(ptr);
return DereferenceAdaptor<T>(ptr);
}
T **ptr;
};
// Resources can be more abstract and be unsized,
// so we need to have an array of pointers for those cases.
template <typename T>
struct Resource : PointerInterface<T>
{
};
// POD with no unknown sizes, so we can express these as flat arrays.
template <typename T>
struct UniformConstant : Interface<T>
{
};
template <typename T>
struct StageInput : Interface<T>
{
};
template <typename T>
struct StageOutput : Interface<T>
{
};
template <typename T>
struct PushConstant : Interface<T>
{
};
}
struct spirv_cross_shader
{
struct PPSize
{
PPSize()
: ptr(0)
, size(0)
{
}
void **ptr;
size_t size;
};
struct PPSizeResource
{
PPSizeResource()
: ptr(0)
, size(0)
, pre_dereference(false)
{
}
void **ptr;
size_t size;
bool pre_dereference;
};
PPSizeResource resources[SPIRV_CROSS_NUM_DESCRIPTOR_SETS][SPIRV_CROSS_NUM_DESCRIPTOR_BINDINGS];
PPSize stage_inputs[SPIRV_CROSS_NUM_STAGE_INPUTS];
PPSize stage_outputs[SPIRV_CROSS_NUM_STAGE_OUTPUTS];
PPSize uniform_constants[SPIRV_CROSS_NUM_UNIFORM_CONSTANTS];
PPSize push_constant;
PPSize builtins[SPIRV_CROSS_NUM_BUILTINS];
template <typename U>
void register_builtin(spirv_cross_builtin builtin, const U &value)
{
assert(!builtins[builtin].ptr);
builtins[builtin].ptr = (void **)&value.ptr;
builtins[builtin].size = sizeof(*value.ptr) * U::ArraySize;
}
void set_builtin(spirv_cross_builtin builtin, void *data, size_t size)
{
assert(builtins[builtin].ptr);
assert(size >= builtins[builtin].size);
*builtins[builtin].ptr = data;
}
template <typename U>
void register_resource(const internal::Resource<U> &value, unsigned set, unsigned binding)
{
assert(set < SPIRV_CROSS_NUM_DESCRIPTOR_SETS);
assert(binding < SPIRV_CROSS_NUM_DESCRIPTOR_BINDINGS);
assert(!resources[set][binding].ptr);
resources[set][binding].ptr = (void **)&value.ptr;
resources[set][binding].size = internal::Resource<U>::Size;
resources[set][binding].pre_dereference = internal::Resource<U>::PreDereference;
}
template <typename U>
void register_stage_input(const internal::StageInput<U> &value, unsigned location)
{
assert(location < SPIRV_CROSS_NUM_STAGE_INPUTS);
assert(!stage_inputs[location].ptr);
stage_inputs[location].ptr = (void **)&value.ptr;
stage_inputs[location].size = internal::StageInput<U>::Size;
}
template <typename U>
void register_stage_output(const internal::StageOutput<U> &value, unsigned location)
{
assert(location < SPIRV_CROSS_NUM_STAGE_OUTPUTS);
assert(!stage_outputs[location].ptr);
stage_outputs[location].ptr = (void **)&value.ptr;
stage_outputs[location].size = internal::StageOutput<U>::Size;
}
template <typename U>
void register_uniform_constant(const internal::UniformConstant<U> &value, unsigned location)
{
assert(location < SPIRV_CROSS_NUM_UNIFORM_CONSTANTS);
assert(!uniform_constants[location].ptr);
uniform_constants[location].ptr = (void **)&value.ptr;
uniform_constants[location].size = internal::UniformConstant<U>::Size;
}
template <typename U>
void register_push_constant(const internal::PushConstant<U> &value)
{
assert(!push_constant.ptr);
push_constant.ptr = (void **)&value.ptr;
push_constant.size = internal::PushConstant<U>::Size;
}
void set_stage_input(unsigned location, void *data, size_t size)
{
assert(location < SPIRV_CROSS_NUM_STAGE_INPUTS);
assert(stage_inputs[location].ptr);
assert(size >= stage_inputs[location].size);
*stage_inputs[location].ptr = data;
}
void set_stage_output(unsigned location, void *data, size_t size)
{
assert(location < SPIRV_CROSS_NUM_STAGE_OUTPUTS);
assert(stage_outputs[location].ptr);
assert(size >= stage_outputs[location].size);
*stage_outputs[location].ptr = data;
}
void set_uniform_constant(unsigned location, void *data, size_t size)
{
assert(location < SPIRV_CROSS_NUM_UNIFORM_CONSTANTS);
assert(uniform_constants[location].ptr);
assert(size >= uniform_constants[location].size);
*uniform_constants[location].ptr = data;
}
void set_push_constant(void *data, size_t size)
{
assert(push_constant.ptr);
assert(size >= push_constant.size);
*push_constant.ptr = data;
}
void set_resource(unsigned set, unsigned binding, void **data, size_t size)
{
assert(set < SPIRV_CROSS_NUM_DESCRIPTOR_SETS);
assert(binding < SPIRV_CROSS_NUM_DESCRIPTOR_BINDINGS);
assert(resources[set][binding].ptr);
assert(size >= resources[set][binding].size);
// We're using the regular PointerInterface, dereference ahead of time.
if (resources[set][binding].pre_dereference)
*resources[set][binding].ptr = *data;
else
*resources[set][binding].ptr = data;
}
};
namespace spirv_cross
{
template <typename T>
struct BaseShader : spirv_cross_shader
{
void invoke()
{
static_cast<T *>(this)->main();
}
};
struct FragmentResources
{
internal::StageOutput<glm::vec4> gl_FragCoord;
void init(spirv_cross_shader &s)
{
s.register_builtin(SPIRV_CROSS_BUILTIN_FRAG_COORD, gl_FragCoord);
}
#define gl_FragCoord __res->gl_FragCoord.get()
};
template <typename T, typename Res>
struct FragmentShader : BaseShader<FragmentShader<T, Res>>
{
inline void main()
{
impl.main();
}
FragmentShader()
{
resources.init(*this);
impl.__res = &resources;
}
T impl;
Res resources;
};
struct VertexResources
{
internal::StageOutput<glm::vec4> gl_Position;
void init(spirv_cross_shader &s)
{
s.register_builtin(SPIRV_CROSS_BUILTIN_POSITION, gl_Position);
}
#define gl_Position __res->gl_Position.get()
};
template <typename T, typename Res>
struct VertexShader : BaseShader<VertexShader<T, Res>>
{
inline void main()
{
impl.main();
}
VertexShader()
{
resources.init(*this);
impl.__res = &resources;
}
T impl;
Res resources;
};
struct TessEvaluationResources
{
inline void init(spirv_cross_shader &)
{
}
};
template <typename T, typename Res>
struct TessEvaluationShader : BaseShader<TessEvaluationShader<T, Res>>
{
inline void main()
{
impl.main();
}
TessEvaluationShader()
{
resources.init(*this);
impl.__res = &resources;
}
T impl;
Res resources;
};
struct TessControlResources
{
inline void init(spirv_cross_shader &)
{
}
};
template <typename T, typename Res>
struct TessControlShader : BaseShader<TessControlShader<T, Res>>
{
inline void main()
{
impl.main();
}
TessControlShader()
{
resources.init(*this);
impl.__res = &resources;
}
T impl;
Res resources;
};
struct GeometryResources
{
inline void init(spirv_cross_shader &)
{
}
};
template <typename T, typename Res>
struct GeometryShader : BaseShader<GeometryShader<T, Res>>
{
inline void main()
{
impl.main();
}
GeometryShader()
{
resources.init(*this);
impl.__res = &resources;
}
T impl;
Res resources;
};
struct ComputeResources
{
internal::StageInput<glm::uvec3> gl_WorkGroupID__;
internal::StageInput<glm::uvec3> gl_NumWorkGroups__;
void init(spirv_cross_shader &s)
{
s.register_builtin(SPIRV_CROSS_BUILTIN_WORK_GROUP_ID, gl_WorkGroupID__);
s.register_builtin(SPIRV_CROSS_BUILTIN_NUM_WORK_GROUPS, gl_NumWorkGroups__);
}
#define gl_WorkGroupID __res->gl_WorkGroupID__.get()
#define gl_NumWorkGroups __res->gl_NumWorkGroups__.get()
Barrier barrier__;
#define barrier() __res->barrier__.wait()
};
struct ComputePrivateResources
{
uint32_t gl_LocalInvocationIndex__;
#define gl_LocalInvocationIndex __priv_res.gl_LocalInvocationIndex__
glm::uvec3 gl_LocalInvocationID__;
#define gl_LocalInvocationID __priv_res.gl_LocalInvocationID__
glm::uvec3 gl_GlobalInvocationID__;
#define gl_GlobalInvocationID __priv_res.gl_GlobalInvocationID__
};
template <typename T, typename Res, unsigned WorkGroupX, unsigned WorkGroupY, unsigned WorkGroupZ>
struct ComputeShader : BaseShader<ComputeShader<T, Res, WorkGroupX, WorkGroupY, WorkGroupZ>>
{
inline void main()
{
resources.barrier__.reset_counter();
for (unsigned z = 0; z < WorkGroupZ; z++)
for (unsigned y = 0; y < WorkGroupY; y++)
for (unsigned x = 0; x < WorkGroupX; x++)
impl[z][y][x].__priv_res.gl_GlobalInvocationID__ =
glm::uvec3(WorkGroupX, WorkGroupY, WorkGroupZ) * resources.gl_WorkGroupID__.get() +
glm::uvec3(x, y, z);
group.run();
group.wait();
}
ComputeShader()
: group(&impl[0][0][0])
{
resources.init(*this);
resources.barrier__.set_release_divisor(WorkGroupX * WorkGroupY * WorkGroupZ);
unsigned i = 0;
for (unsigned z = 0; z < WorkGroupZ; z++)
{
for (unsigned y = 0; y < WorkGroupY; y++)
{
for (unsigned x = 0; x < WorkGroupX; x++)
{
impl[z][y][x].__priv_res.gl_LocalInvocationID__ = glm::uvec3(x, y, z);
impl[z][y][x].__priv_res.gl_LocalInvocationIndex__ = i++;
impl[z][y][x].__res = &resources;
}
}
}
}
T impl[WorkGroupZ][WorkGroupY][WorkGroupX];
ThreadGroup<T, WorkGroupX * WorkGroupY * WorkGroupZ> group;
Res resources;
};
inline void memoryBarrierShared()
{
Barrier::memoryBarrier();
}
inline void memoryBarrier()
{
Barrier::memoryBarrier();
}
// TODO: Rest of the barriers.
// Atomics
template <typename T>
inline T atomicAdd(T &v, T a)
{
static_assert(sizeof(std::atomic<T>) == sizeof(T), "Cannot cast properly to std::atomic<T>.");
// We need explicit memory barriers in GLSL to enfore any ordering.
// FIXME: Can we really cast this? There is no other way I think ...
return std::atomic_fetch_add_explicit(reinterpret_cast<std::atomic<T> *>(&v), a, std::memory_order_relaxed);
}
}
void spirv_cross_set_stage_input(spirv_cross_shader_t *shader, unsigned location, void *data, size_t size)
{
shader->set_stage_input(location, data, size);
}
void spirv_cross_set_stage_output(spirv_cross_shader_t *shader, unsigned location, void *data, size_t size)
{
shader->set_stage_output(location, data, size);
}
void spirv_cross_set_uniform_constant(spirv_cross_shader_t *shader, unsigned location, void *data, size_t size)
{
shader->set_uniform_constant(location, data, size);
}
void spirv_cross_set_resource(spirv_cross_shader_t *shader, unsigned set, unsigned binding, void **data, size_t size)
{
shader->set_resource(set, binding, data, size);
}
void spirv_cross_set_push_constant(spirv_cross_shader_t *shader, void *data, size_t size)
{
shader->set_push_constant(data, size);
}
void spirv_cross_set_builtin(spirv_cross_shader_t *shader, spirv_cross_builtin builtin, void *data, size_t size)
{
shader->set_builtin(builtin, data, size);
}
#endif

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/*
* Copyright 2015-2017 ARM Limited
*
* 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.
*/
#ifndef SPIRV_CROSS_SAMPLER_HPP
#define SPIRV_CROSS_SAMPLER_HPP
#include <vector>
namespace spirv_cross
{
struct spirv_cross_sampler_2d
{
inline virtual ~spirv_cross_sampler_2d()
{
}
};
template <typename T>
struct sampler2DBase : spirv_cross_sampler_2d
{
sampler2DBase(const spirv_cross_sampler_info *info)
{
mips.insert(mips.end(), info->mipmaps, info->mipmaps + info->num_mipmaps);
format = info->format;
wrap_s = info->wrap_s;
wrap_t = info->wrap_t;
min_filter = info->min_filter;
mag_filter = info->mag_filter;
mip_filter = info->mip_filter;
}
inline virtual T sample(glm::vec2 uv, float bias)
{
return sampleLod(uv, bias);
}
inline virtual T sampleLod(glm::vec2 uv, float lod)
{
if (mag_filter == SPIRV_CROSS_FILTER_NEAREST)
{
uv.x = wrap(uv.x, wrap_s, mips[0].width);
uv.y = wrap(uv.y, wrap_t, mips[0].height);
glm::vec2 uv_full = uv * glm::vec2(mips[0].width, mips[0].height);
int x = int(uv_full.x);
int y = int(uv_full.y);
return sample(x, y, 0);
}
else
{
return T(0, 0, 0, 1);
}
}
inline float wrap(float v, spirv_cross_wrap wrap, unsigned size)
{
switch (wrap)
{
case SPIRV_CROSS_WRAP_REPEAT:
return v - glm::floor(v);
case SPIRV_CROSS_WRAP_CLAMP_TO_EDGE:
{
float half = 0.5f / size;
return glm::clamp(v, half, 1.0f - half);
}
default:
return 0.0f;
}
}
std::vector<spirv_cross_miplevel> mips;
spirv_cross_format format;
spirv_cross_wrap wrap_s;
spirv_cross_format wrap_t;
spirv_cross_filter min_filter;
spirv_cross_filter mag_filter;
spirv_cross_mipfilter mip_filter;
};
typedef sampler2DBase<glm::vec4> sampler2D;
typedef sampler2DBase<glm::ivec4> isampler2D;
typedef sampler2DBase<glm::uvec4> usampler2D;
template <typename T>
inline T texture(const sampler2DBase<T> &samp, const glm::vec2 &uv, float bias = 0.0f)
{
return samp.sample(uv, bias);
}
}
#endif

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/*
* Copyright 2015-2017 ARM Limited
*
* 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.
*/
#ifndef SPIRV_CROSS_THREAD_GROUP_HPP
#define SPIRV_CROSS_THREAD_GROUP_HPP
#include <condition_variable>
#include <mutex>
#include <thread>
namespace spirv_cross
{
template <typename T, unsigned Size>
class ThreadGroup
{
public:
ThreadGroup(T *impl)
{
for (unsigned i = 0; i < Size; i++)
workers[i].start(&impl[i]);
}
void run()
{
for (auto &worker : workers)
worker.run();
}
void wait()
{
for (auto &worker : workers)
worker.wait();
}
private:
struct Thread
{
enum State
{
Idle,
Running,
Dying
};
State state = Idle;
void start(T *impl)
{
worker = std::thread([impl, this] {
for (;;)
{
{
std::unique_lock<std::mutex> l{ lock };
cond.wait(l, [this] { return state != Idle; });
if (state == Dying)
break;
}
impl->main();
std::lock_guard<std::mutex> l{ lock };
state = Idle;
cond.notify_one();
}
});
}
void wait()
{
std::unique_lock<std::mutex> l{ lock };
cond.wait(l, [this] { return state == Idle; });
}
void run()
{
std::lock_guard<std::mutex> l{ lock };
state = Running;
cond.notify_one();
}
~Thread()
{
if (worker.joinable())
{
{
std::lock_guard<std::mutex> l{ lock };
state = Dying;
cond.notify_one();
}
worker.join();
}
}
std::thread worker;
std::condition_variable cond;
std::mutex lock;
};
Thread workers[Size];
};
}
#endif

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deps/SPIRV-Cross/main.cpp vendored Normal file

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prefix=@CMAKE_INSTALL_PREFIX@
exec_prefix=@CMAKE_INSTALL_PREFIX@
libdir=@SPIRV_CROSS_INSTALL_LIB_DIR@
sharedlibdir=@SPIRV_CROSS_INSTALL_LIB_DIR@
includedir=@SPIRV_CROSS_INSTALL_INC_DIR@
Name: spirv-cross-c-shared
Description: C API for SPIRV-Cross
Version: @SPIRV_CROSS_VERSION@
Requires:
Libs: -L${libdir} -L${sharedlibdir} -lspirv-cross-c-shared
Cflags: -I${includedir}

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RWByteAddressBuffer _4 : register(u0);
void comp_main()
{
uint _21 = _4.Load(_4.Load(0) * 4 + 4);
for (uint _23 = 0u; _23 < 64u; )
{
_4.Store(_23 * 4 + 4, 0u);
_23++;
continue;
}
_4.Store(_4.Load(0) * 4 + 4, _21);
}
[numthreads(1, 1, 1)]
void main()
{
comp_main();
}

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RWByteAddressBuffer u0_counter : register(u1);
RWBuffer<uint> u0 : register(u0);
static uint3 gl_GlobalInvocationID;
struct SPIRV_Cross_Input
{
uint3 gl_GlobalInvocationID : SV_DispatchThreadID;
};
void comp_main()
{
uint _29;
u0_counter.InterlockedAdd(0, -1, _29);
u0[asint(asfloat(_29))] = uint(int(gl_GlobalInvocationID.x)).x;
}
[numthreads(4, 1, 1)]
void main(SPIRV_Cross_Input stage_input)
{
gl_GlobalInvocationID = stage_input.gl_GlobalInvocationID;
comp_main();
}

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RWByteAddressBuffer u0_counter : register(u1);
RWBuffer<uint> u0 : register(u0);
static uint3 gl_GlobalInvocationID;
struct SPIRV_Cross_Input
{
uint3 gl_GlobalInvocationID : SV_DispatchThreadID;
};
void comp_main()
{
uint _29;
u0_counter.InterlockedAdd(0, 1, _29);
u0[asint(asfloat(_29))] = uint(int(gl_GlobalInvocationID.x)).x;
}
[numthreads(4, 1, 1)]
void main(SPIRV_Cross_Input stage_input)
{
gl_GlobalInvocationID = stage_input.gl_GlobalInvocationID;
comp_main();
}

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struct A
{
int a;
int b;
};
struct A_1
{
int a;
int b;
};
RWByteAddressBuffer C1 : register(u1);
cbuffer C2 : register(b2)
{
A_1 C2_1_Data[1024] : packoffset(c0);
};
RWByteAddressBuffer C3 : register(u0);
cbuffer B : register(b3)
{
A_1 C4_Data[1024] : packoffset(c0);
};
static uint3 gl_GlobalInvocationID;
struct SPIRV_Cross_Input
{
uint3 gl_GlobalInvocationID : SV_DispatchThreadID;
};
void comp_main()
{
C1.Store(gl_GlobalInvocationID.x * 8 + 0, uint(C2_1_Data[gl_GlobalInvocationID.x].a));
C1.Store(gl_GlobalInvocationID.x * 8 + 4, uint(C2_1_Data[gl_GlobalInvocationID.x].b));
C3.Store(gl_GlobalInvocationID.x * 8 + 0, uint(C4_Data[gl_GlobalInvocationID.x].a));
C3.Store(gl_GlobalInvocationID.x * 8 + 4, uint(C4_Data[gl_GlobalInvocationID.x].b));
}
[numthreads(1, 1, 1)]
void main(SPIRV_Cross_Input stage_input)
{
gl_GlobalInvocationID = stage_input.gl_GlobalInvocationID;
comp_main();
}

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RWByteAddressBuffer bar : register(u0);
RWByteAddressBuffer foo : register(u1);
void comp_main()
{
[unroll]
for (int _135 = 0; _135 < 16; )
{
bar.Store4(_135 * 16 + 0, asuint(asfloat(foo.Load4(_135 * 16 + 0))));
_135++;
continue;
}
[loop]
for (int _136 = 0; _136 < 16; )
{
bar.Store4((15 - _136) * 16 + 0, asuint(asfloat(foo.Load4(_136 * 16 + 0))));
_136++;
continue;
}
[branch]
if (asfloat(bar.Load(160)) > 10.0f)
{
foo.Store4(320, asuint(5.0f.xxxx));
}
foo.Store4(320, asuint(20.0f.xxxx));
}
[numthreads(1, 1, 1)]
void main()
{
comp_main();
}

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void comp_main()
{
}
[numthreads(1, 1, 1)]
void main()
{
comp_main();
}

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RWByteAddressBuffer _4 : register(u0);
void comp_main()
{
_4.Store(0, asuint(isnan(asfloat(_4.Load(96))) ? asfloat(_4.Load(48)) : (isnan(asfloat(_4.Load(48))) ? asfloat(_4.Load(96)) : min(asfloat(_4.Load(48)), asfloat(_4.Load(96))))));
bool2 _146 = isnan(asfloat(_4.Load2(56)));
bool2 _147 = isnan(asfloat(_4.Load2(104)));
float2 _148 = min(asfloat(_4.Load2(56)), asfloat(_4.Load2(104)));
float2 _149 = float2(_146.x ? asfloat(_4.Load2(104)).x : _148.x, _146.y ? asfloat(_4.Load2(104)).y : _148.y);
_4.Store2(8, asuint(float2(_147.x ? asfloat(_4.Load2(56)).x : _149.x, _147.y ? asfloat(_4.Load2(56)).y : _149.y)));
bool3 _151 = isnan(asfloat(_4.Load3(64)));
bool3 _152 = isnan(asfloat(_4.Load3(112)));
float3 _153 = min(asfloat(_4.Load3(64)), asfloat(_4.Load3(112)));
float3 _154 = float3(_151.x ? asfloat(_4.Load3(112)).x : _153.x, _151.y ? asfloat(_4.Load3(112)).y : _153.y, _151.z ? asfloat(_4.Load3(112)).z : _153.z);
_4.Store3(16, asuint(float3(_152.x ? asfloat(_4.Load3(64)).x : _154.x, _152.y ? asfloat(_4.Load3(64)).y : _154.y, _152.z ? asfloat(_4.Load3(64)).z : _154.z)));
bool4 _156 = isnan(asfloat(_4.Load4(80)));
bool4 _157 = isnan(asfloat(_4.Load4(128)));
float4 _158 = min(asfloat(_4.Load4(80)), asfloat(_4.Load4(128)));
float4 _159 = float4(_156.x ? asfloat(_4.Load4(128)).x : _158.x, _156.y ? asfloat(_4.Load4(128)).y : _158.y, _156.z ? asfloat(_4.Load4(128)).z : _158.z, _156.w ? asfloat(_4.Load4(128)).w : _158.w);
_4.Store4(32, asuint(float4(_157.x ? asfloat(_4.Load4(80)).x : _159.x, _157.y ? asfloat(_4.Load4(80)).y : _159.y, _157.z ? asfloat(_4.Load4(80)).z : _159.z, _157.w ? asfloat(_4.Load4(80)).w : _159.w)));
_4.Store(0, asuint(isnan(asfloat(_4.Load(96))) ? asfloat(_4.Load(48)) : (isnan(asfloat(_4.Load(48))) ? asfloat(_4.Load(96)) : max(asfloat(_4.Load(48)), asfloat(_4.Load(96))))));
bool2 _166 = isnan(asfloat(_4.Load2(56)));
bool2 _167 = isnan(asfloat(_4.Load2(104)));
float2 _168 = max(asfloat(_4.Load2(56)), asfloat(_4.Load2(104)));
float2 _169 = float2(_166.x ? asfloat(_4.Load2(104)).x : _168.x, _166.y ? asfloat(_4.Load2(104)).y : _168.y);
_4.Store2(8, asuint(float2(_167.x ? asfloat(_4.Load2(56)).x : _169.x, _167.y ? asfloat(_4.Load2(56)).y : _169.y)));
bool3 _171 = isnan(asfloat(_4.Load3(64)));
bool3 _172 = isnan(asfloat(_4.Load3(112)));
float3 _173 = max(asfloat(_4.Load3(64)), asfloat(_4.Load3(112)));
float3 _174 = float3(_171.x ? asfloat(_4.Load3(112)).x : _173.x, _171.y ? asfloat(_4.Load3(112)).y : _173.y, _171.z ? asfloat(_4.Load3(112)).z : _173.z);
_4.Store3(16, asuint(float3(_172.x ? asfloat(_4.Load3(64)).x : _174.x, _172.y ? asfloat(_4.Load3(64)).y : _174.y, _172.z ? asfloat(_4.Load3(64)).z : _174.z)));
bool4 _176 = isnan(asfloat(_4.Load4(80)));
bool4 _177 = isnan(asfloat(_4.Load4(128)));
float4 _178 = max(asfloat(_4.Load4(80)), asfloat(_4.Load4(128)));
float4 _179 = float4(_176.x ? asfloat(_4.Load4(128)).x : _178.x, _176.y ? asfloat(_4.Load4(128)).y : _178.y, _176.z ? asfloat(_4.Load4(128)).z : _178.z, _176.w ? asfloat(_4.Load4(128)).w : _178.w);
_4.Store4(32, asuint(float4(_177.x ? asfloat(_4.Load4(80)).x : _179.x, _177.y ? asfloat(_4.Load4(80)).y : _179.y, _177.z ? asfloat(_4.Load4(80)).z : _179.z, _177.w ? asfloat(_4.Load4(80)).w : _179.w)));
float _180 = isnan(asfloat(_4.Load(48))) ? asfloat(_4.Load(0)) : (isnan(asfloat(_4.Load(0))) ? asfloat(_4.Load(48)) : max(asfloat(_4.Load(0)), asfloat(_4.Load(48))));
_4.Store(0, asuint(isnan(asfloat(_4.Load(96))) ? _180 : (isnan(_180) ? asfloat(_4.Load(96)) : min(_180, asfloat(_4.Load(96))))));
bool2 _193 = isnan(asfloat(_4.Load2(8)));
bool2 _194 = isnan(asfloat(_4.Load2(56)));
float2 _195 = max(asfloat(_4.Load2(8)), asfloat(_4.Load2(56)));
float2 _196 = float2(_193.x ? asfloat(_4.Load2(56)).x : _195.x, _193.y ? asfloat(_4.Load2(56)).y : _195.y);
float2 _191 = float2(_194.x ? asfloat(_4.Load2(8)).x : _196.x, _194.y ? asfloat(_4.Load2(8)).y : _196.y);
bool2 _198 = isnan(_191);
bool2 _199 = isnan(asfloat(_4.Load2(104)));
float2 _200 = min(_191, asfloat(_4.Load2(104)));
float2 _201 = float2(_198.x ? asfloat(_4.Load2(104)).x : _200.x, _198.y ? asfloat(_4.Load2(104)).y : _200.y);
_4.Store2(8, asuint(float2(_199.x ? _191.x : _201.x, _199.y ? _191.y : _201.y)));
bool3 _204 = isnan(asfloat(_4.Load3(16)));
bool3 _205 = isnan(asfloat(_4.Load3(64)));
float3 _206 = max(asfloat(_4.Load3(16)), asfloat(_4.Load3(64)));
float3 _207 = float3(_204.x ? asfloat(_4.Load3(64)).x : _206.x, _204.y ? asfloat(_4.Load3(64)).y : _206.y, _204.z ? asfloat(_4.Load3(64)).z : _206.z);
float3 _202 = float3(_205.x ? asfloat(_4.Load3(16)).x : _207.x, _205.y ? asfloat(_4.Load3(16)).y : _207.y, _205.z ? asfloat(_4.Load3(16)).z : _207.z);
bool3 _209 = isnan(_202);
bool3 _210 = isnan(asfloat(_4.Load3(112)));
float3 _211 = min(_202, asfloat(_4.Load3(112)));
float3 _212 = float3(_209.x ? asfloat(_4.Load3(112)).x : _211.x, _209.y ? asfloat(_4.Load3(112)).y : _211.y, _209.z ? asfloat(_4.Load3(112)).z : _211.z);
_4.Store3(16, asuint(float3(_210.x ? _202.x : _212.x, _210.y ? _202.y : _212.y, _210.z ? _202.z : _212.z)));
bool4 _215 = isnan(asfloat(_4.Load4(32)));
bool4 _216 = isnan(asfloat(_4.Load4(80)));
float4 _217 = max(asfloat(_4.Load4(32)), asfloat(_4.Load4(80)));
float4 _218 = float4(_215.x ? asfloat(_4.Load4(80)).x : _217.x, _215.y ? asfloat(_4.Load4(80)).y : _217.y, _215.z ? asfloat(_4.Load4(80)).z : _217.z, _215.w ? asfloat(_4.Load4(80)).w : _217.w);
float4 _213 = float4(_216.x ? asfloat(_4.Load4(32)).x : _218.x, _216.y ? asfloat(_4.Load4(32)).y : _218.y, _216.z ? asfloat(_4.Load4(32)).z : _218.z, _216.w ? asfloat(_4.Load4(32)).w : _218.w);
bool4 _220 = isnan(_213);
bool4 _221 = isnan(asfloat(_4.Load4(128)));
float4 _222 = min(_213, asfloat(_4.Load4(128)));
float4 _223 = float4(_220.x ? asfloat(_4.Load4(128)).x : _222.x, _220.y ? asfloat(_4.Load4(128)).y : _222.y, _220.z ? asfloat(_4.Load4(128)).z : _222.z, _220.w ? asfloat(_4.Load4(128)).w : _222.w);
_4.Store4(32, asuint(float4(_221.x ? _213.x : _223.x, _221.y ? _213.y : _223.y, _221.z ? _213.z : _223.z, _221.w ? _213.w : _223.w)));
for (int _139 = 0; _139 < 2; )
{
bool2 _225 = isnan(asfloat(_4.Load2(56)));
bool2 _226 = isnan(asfloat(_4.Load2(104)));
float2 _227 = min(asfloat(_4.Load2(56)), asfloat(_4.Load2(104)));
float2 _228 = float2(_225.x ? asfloat(_4.Load2(104)).x : _227.x, _225.y ? asfloat(_4.Load2(104)).y : _227.y);
_4.Store2(8, asuint(float2(_226.x ? asfloat(_4.Load2(56)).x : _228.x, _226.y ? asfloat(_4.Load2(56)).y : _228.y)));
float _229 = isnan(asfloat(_4.Load(56))) ? asfloat(_4.Load(0)) : (isnan(asfloat(_4.Load(0))) ? asfloat(_4.Load(56)) : max(asfloat(_4.Load(0)), asfloat(_4.Load(56))));
_4.Store(0, asuint(isnan(asfloat(_4.Load(60))) ? _229 : (isnan(_229) ? asfloat(_4.Load(60)) : min(_229, asfloat(_4.Load(60))))));
_139++;
continue;
}
}
[numthreads(1, 1, 1)]
void main()
{
comp_main();
}

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#ifndef SPIRV_CROSS_CONSTANT_ID_0
#define SPIRV_CROSS_CONSTANT_ID_0 1u
#endif
static const uint _3 = SPIRV_CROSS_CONSTANT_ID_0;
#ifndef SPIRV_CROSS_CONSTANT_ID_2
#define SPIRV_CROSS_CONSTANT_ID_2 3u
#endif
static const uint _4 = SPIRV_CROSS_CONSTANT_ID_2;
static const uint3 gl_WorkGroupSize = uint3(_3, 2u, _4);
RWByteAddressBuffer _8 : register(u0);
RWByteAddressBuffer _9 : register(u1);
static uint3 gl_WorkGroupID;
struct SPIRV_Cross_Input
{
uint3 gl_WorkGroupID : SV_GroupID;
};
static uint3 _22 = gl_WorkGroupSize;
void comp_main()
{
_8.Store(gl_WorkGroupID.x * 4 + 0, asuint(asfloat(_9.Load(gl_WorkGroupID.x * 4 + 0)) + asfloat(_8.Load(gl_WorkGroupID.x * 4 + 0))));
}
[numthreads(SPIRV_CROSS_CONSTANT_ID_0, 2, SPIRV_CROSS_CONSTANT_ID_2)]
void main(SPIRV_Cross_Input stage_input)
{
gl_WorkGroupID = stage_input.gl_WorkGroupID;
comp_main();
}

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cbuffer _4_5 : register(b0)
{
column_major float2x4 _5_m0 : packoffset(c0);
float4 _5_m1 : packoffset(c4);
};
static float2 _3;
struct SPIRV_Cross_Output
{
float2 _3 : SV_Target0;
};
void frag_main()
{
_3 = mul(_5_m0, _5_m1);
}
SPIRV_Cross_Output main()
{
frag_main();
SPIRV_Cross_Output stage_output;
stage_output._3 = _3;
return stage_output;
}

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Texture2D<float4> uTex : register(t1);
SamplerState uSampler : register(s0);
static float4 FragColor;
static float2 vUV;
struct SPIRV_Cross_Input
{
float2 vUV : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = uTex.Sample(uSampler, vUV);
FragColor += uTex.Sample(uSampler, vUV, int2(1, 1));
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
vUV = stage_input.vUV;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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void frag_main()
{
}
void main()
{
frag_main();
}

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static float4 FragColor;
static float4 vA;
static float4 vB;
struct SPIRV_Cross_Input
{
float4 vA : TEXCOORD0;
float4 vB : TEXCOORD1;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = fmod(vA, vB);
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
vA = stage_input.vA;
vB = stage_input.vB;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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static float4 FragColor;
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = 10.0f.xxxx;
}
SPIRV_Cross_Output main()
{
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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Texture2D<float4> uTexture : register(t0);
SamplerState _uTexture_sampler : register(s0);
static int2 Size;
struct SPIRV_Cross_Output
{
int2 Size : SV_Target0;
};
uint2 SPIRV_Cross_textureSize(Texture2D<float4> Tex, uint Level, out uint Param)
{
uint2 ret;
Tex.GetDimensions(Level, ret.x, ret.y, Param);
return ret;
}
void frag_main()
{
uint _19_dummy_parameter;
uint _20_dummy_parameter;
Size = int2(SPIRV_Cross_textureSize(uTexture, uint(0), _19_dummy_parameter)) + int2(SPIRV_Cross_textureSize(uTexture, uint(1), _20_dummy_parameter));
}
SPIRV_Cross_Output main()
{
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.Size = Size;
return stage_output;
}

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Texture2D<float4> uImage : register(t0);
SamplerState _uImage_sampler : register(s0);
static float4 v0;
static float4 FragColor;
struct SPIRV_Cross_Input
{
float4 v0 : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
float phi;
float4 _36;
int _51;
_51 = 0;
phi = 1.0f;
_36 = float4(1.0f, 2.0f, 1.0f, 2.0f);
for (;;)
{
FragColor = _36;
if (_51 < 4)
{
if (v0[_51] > 0.0f)
{
float2 _48 = phi.xx;
_51++;
phi += 2.0f;
_36 = uImage.SampleLevel(_uImage_sampler, _48, 0.0f);
continue;
}
else
{
break;
}
}
else
{
break;
}
}
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
v0 = stage_input.v0;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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static float3 FragColor;
struct SPIRV_Cross_Output
{
float3 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = float3(asfloat(0x7f800000u), asfloat(0xff800000u), asfloat(0x7fc00000u));
}
SPIRV_Cross_Output main()
{
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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static float FragColor;
static float vColor;
struct SPIRV_Cross_Input
{
float vColor : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float FragColor : SV_Target0;
};
#line 8 "test.frag"
void frag_main()
{
float _80;
#line 8 "test.frag"
FragColor = 1.0f;
#line 9 "test.frag"
FragColor = 2.0f;
#line 10 "test.frag"
_80 = vColor;
if (_80 < 0.0f)
{
#line 12 "test.frag"
FragColor = 3.0f;
}
else
{
#line 16 "test.frag"
FragColor = 4.0f;
}
for (int _126 = 0; float(_126) < (40.0f + _80); )
{
#line 21 "test.frag"
FragColor += 0.20000000298023223876953125f;
#line 22 "test.frag"
FragColor += 0.300000011920928955078125f;
_126 += (int(_80) + 5);
continue;
}
switch (int(_80))
{
case 0:
{
#line 28 "test.frag"
FragColor += 0.20000000298023223876953125f;
#line 29 "test.frag"
break;
}
case 1:
{
#line 32 "test.frag"
FragColor += 0.4000000059604644775390625f;
#line 33 "test.frag"
break;
}
default:
{
#line 36 "test.frag"
FragColor += 0.800000011920928955078125f;
#line 37 "test.frag"
break;
}
}
for (;;)
{
FragColor += (10.0f + _80);
#line 43 "test.frag"
if (FragColor < 100.0f)
{
}
else
{
break;
}
}
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
vColor = stage_input.vColor;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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static const float _46[16] = { 1.0f, 2.0f, 3.0f, 4.0f, 1.0f, 2.0f, 3.0f, 4.0f, 1.0f, 2.0f, 3.0f, 4.0f, 1.0f, 2.0f, 3.0f, 4.0f };
static const float4 _76[4] = { 0.0f.xxxx, 1.0f.xxxx, 8.0f.xxxx, 5.0f.xxxx };
static const float4 _90[4] = { 20.0f.xxxx, 30.0f.xxxx, 50.0f.xxxx, 60.0f.xxxx };
static float FragColor;
static int index;
struct SPIRV_Cross_Input
{
nointerpolation int index : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float FragColor : SV_Target0;
};
void frag_main()
{
float4 foobar[4] = _76;
float4 baz[4] = _76;
FragColor = _46[index];
if (index < 10)
{
FragColor += _46[index ^ 1];
}
else
{
FragColor += _46[index & 1];
}
bool _99 = index > 30;
if (_99)
{
FragColor += _76[index & 3].y;
}
else
{
FragColor += _76[index & 1].x;
}
if (_99)
{
foobar[1].z = 20.0f;
}
int _37 = index & 3;
FragColor += foobar[_37].z;
baz = _90;
FragColor += baz[_37].z;
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
index = stage_input.index;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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cbuffer Registers
{
float registers_foo : packoffset(c0);
};
static float FragColor;
struct SPIRV_Cross_Output
{
float FragColor : SV_Target0;
};
void frag_main()
{
FragColor = 10.0f + registers_foo;
}
SPIRV_Cross_Output main()
{
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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Texture2D<float4> g_Texture : register(t0);
SamplerState g_Sampler : register(s0);
SamplerComparisonState g_CompareSampler : register(s1);
static float2 in_var_TEXCOORD0;
static float out_var_SV_Target;
struct SPIRV_Cross_Input
{
float2 in_var_TEXCOORD0 : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float out_var_SV_Target : SV_Target0;
};
void frag_main()
{
out_var_SV_Target = g_Texture.Sample(g_Sampler, in_var_TEXCOORD0).x + g_Texture.SampleCmpLevelZero(g_CompareSampler, in_var_TEXCOORD0, 0.5f);
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
in_var_TEXCOORD0 = stage_input.in_var_TEXCOORD0;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.out_var_SV_Target = out_var_SV_Target;
return stage_output;
}

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struct myType
{
float data;
};
static const myType _18 = { 0.0f };
static const myType _20 = { 1.0f };
static const myType _21[5] = { { 0.0f }, { 1.0f }, { 0.0f }, { 1.0f }, { 0.0f } };
static float4 gl_FragCoord;
static float4 o_color;
struct SPIRV_Cross_Input
{
float4 gl_FragCoord : SV_Position;
};
struct SPIRV_Cross_Output
{
float4 o_color : SV_Target0;
};
float mod(float x, float y)
{
return x - y * floor(x / y);
}
float2 mod(float2 x, float2 y)
{
return x - y * floor(x / y);
}
float3 mod(float3 x, float3 y)
{
return x - y * floor(x / y);
}
float4 mod(float4 x, float4 y)
{
return x - y * floor(x / y);
}
void frag_main()
{
if (_21[int(mod(gl_FragCoord.x, 4.0f))].data > 0.0f)
{
o_color = float4(0.0f, 1.0f, 0.0f, 1.0f);
}
else
{
o_color = float4(1.0f, 0.0f, 0.0f, 1.0f);
}
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
gl_FragCoord = stage_input.gl_FragCoord;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.o_color = o_color;
return stage_output;
}

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static float4 FragColor;
static int4 vA;
static int4 vB;
struct SPIRV_Cross_Input
{
nointerpolation int4 vA : TEXCOORD0;
nointerpolation int4 vB : TEXCOORD1;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = float4(vA - vB * (vA / vB));
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
vA = stage_input.vA;
vB = stage_input.vB;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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static const float4 _20[2] = { float4(1.0f, 2.0f, 3.0f, 4.0f), 10.0f.xxxx };
static float4 FragColors[2] = _20;
static float4 FragColor = 5.0f.xxxx;
struct SPIRV_Cross_Output
{
float4 FragColors[2] : SV_Target0;
float4 FragColor : SV_Target2;
};
void frag_main()
{
}
SPIRV_Cross_Output main()
{
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColors = FragColors;
stage_output.FragColor = FragColor;
return stage_output;
}

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Texture2D<float4> uTexture : register(t0);
SamplerState _uTexture_sampler : register(s0);
static float4 gl_FragCoord;
static float4 FragColor;
struct SPIRV_Cross_Input
{
float4 gl_FragCoord : SV_Position;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = uTexture.Load(int3(int2(gl_FragCoord.xy), 0));
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
gl_FragCoord = stage_input.gl_FragCoord;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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Texture2D<float4> uShadow : register(t0);
SamplerComparisonState _uShadow_sampler : register(s0);
Texture2D<float4> uTexture : register(t1);
SamplerComparisonState uSampler : register(s2);
static float3 vUV;
static float FragColor;
struct SPIRV_Cross_Input
{
float3 vUV : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float FragColor : SV_Target0;
};
void frag_main()
{
FragColor = uShadow.SampleCmp(_uShadow_sampler, vUV.xy, vUV.z) + uTexture.SampleCmp(uSampler, vUV.xy, vUV.z);
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
vUV = stage_input.vUV;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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static int counter;
static float4 FragColor;
struct SPIRV_Cross_Input
{
nointerpolation int counter : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
float4 _33;
for (;;)
{
if (counter == 10)
{
_33 = 10.0f.xxxx;
break;
}
else
{
_33 = 30.0f.xxxx;
break;
}
}
FragColor = _33;
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
counter = stage_input.counter;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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struct InstanceData
{
column_major float4x4 MATRIX_MVP;
float4 Color;
};
cbuffer gInstanceData : register(b0)
{
InstanceData gInstanceData_1_data[32] : packoffset(c0);
};
static float4 gl_Position;
static int gl_InstanceIndex;
static float3 PosL;
static float4 _entryPointOutput_Color;
struct SPIRV_Cross_Input
{
float3 PosL : TEXCOORD0;
uint gl_InstanceIndex : SV_InstanceID;
};
struct SPIRV_Cross_Output
{
float4 _entryPointOutput_Color : TEXCOORD0;
float4 gl_Position : SV_Position;
};
void vert_main()
{
gl_Position = mul(float4(PosL, 1.0f), gInstanceData_1_data[uint(gl_InstanceIndex)].MATRIX_MVP);
_entryPointOutput_Color = gInstanceData_1_data[uint(gl_InstanceIndex)].Color;
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
gl_InstanceIndex = int(stage_input.gl_InstanceIndex);
PosL = stage_input.PosL;
vert_main();
SPIRV_Cross_Output stage_output;
stage_output.gl_Position = gl_Position;
stage_output._entryPointOutput_Color = _entryPointOutput_Color;
return stage_output;
}

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#ifndef SPIRV_CROSS_CONSTANT_ID_201
#define SPIRV_CROSS_CONSTANT_ID_201 -10
#endif
static const int _7 = SPIRV_CROSS_CONSTANT_ID_201;
static const int _20 = (_7 + 2);
#ifndef SPIRV_CROSS_CONSTANT_ID_202
#define SPIRV_CROSS_CONSTANT_ID_202 100u
#endif
static const uint _8 = SPIRV_CROSS_CONSTANT_ID_202;
static const uint _25 = (_8 % 5u);
#ifndef SPIRV_CROSS_CONSTANT_ID_0
#define SPIRV_CROSS_CONSTANT_ID_0 int4(20, 30, _20, _20)
#endif
static const int4 _30 = SPIRV_CROSS_CONSTANT_ID_0;
static const int2 _32 = int2(_30.y, _30.x);
static const int _33 = _30.y;
static float4 gl_Position;
static int _4;
struct SPIRV_Cross_Output
{
nointerpolation int _4 : TEXCOORD0;
float4 gl_Position : SV_Position;
};
void vert_main()
{
float4 _63 = 0.0f.xxxx;
_63.y = float(_20);
float4 _66 = _63;
_66.z = float(_25);
float4 _52 = _66 + float4(_30);
float2 _56 = _52.xy + float2(_32);
gl_Position = float4(_56.x, _56.y, _52.z, _52.w);
_4 = _33;
}
SPIRV_Cross_Output main()
{
vert_main();
SPIRV_Cross_Output stage_output;
stage_output.gl_Position = gl_Position;
stage_output._4 = _4;
return stage_output;
}

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static float4 gl_Position;
static int gl_VertexIndex;
static int gl_InstanceIndex;
struct SPIRV_Cross_Input
{
uint gl_VertexIndex : SV_VertexID;
uint gl_InstanceIndex : SV_InstanceID;
};
struct SPIRV_Cross_Output
{
float4 gl_Position : SV_Position;
};
void vert_main()
{
gl_Position = float(uint(gl_VertexIndex) + uint(gl_InstanceIndex)).xxxx;
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
gl_VertexIndex = int(stage_input.gl_VertexIndex);
gl_InstanceIndex = int(stage_input.gl_InstanceIndex);
vert_main();
SPIRV_Cross_Output stage_output;
stage_output.gl_Position = gl_Position;
return stage_output;
}

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static float4 gl_Position;
static int gl_VertexIndex;
static int gl_InstanceIndex;
struct SPIRV_Cross_Input
{
uint gl_VertexIndex : SV_VertexID;
uint gl_InstanceIndex : SV_InstanceID;
};
struct SPIRV_Cross_Output
{
float4 gl_Position : SV_Position;
};
void vert_main()
{
gl_Position = float(gl_VertexIndex + gl_InstanceIndex).xxxx;
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
gl_VertexIndex = int(stage_input.gl_VertexIndex);
gl_InstanceIndex = int(stage_input.gl_InstanceIndex);
vert_main();
SPIRV_Cross_Output stage_output;
stage_output.gl_Position = gl_Position;
return stage_output;
}

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RWByteAddressBuffer wo : register(u1);
ByteAddressBuffer ro : register(t0);
static uint3 gl_GlobalInvocationID;
struct SPIRV_Cross_Input
{
uint3 gl_GlobalInvocationID : SV_DispatchThreadID;
};
void comp_main()
{
wo.Store4(gl_GlobalInvocationID.x * 64 + 272, asuint(asfloat(ro.Load4(gl_GlobalInvocationID.x * 64 + 160))));
wo.Store4(gl_GlobalInvocationID.x * 16 + 480, asuint(asfloat(ro.Load4(gl_GlobalInvocationID.x * 16 + 480))));
}
[numthreads(1, 1, 1)]
void main(SPIRV_Cross_Input stage_input)
{
gl_GlobalInvocationID = stage_input.gl_GlobalInvocationID;
comp_main();
}

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RWByteAddressBuffer WriteOnly : register(u2);
ByteAddressBuffer ReadOnly : register(t0);
RWByteAddressBuffer ReadWrite : register(u1);
void comp_main()
{
WriteOnly.Store4(0, asuint(asfloat(ReadOnly.Load4(0))));
ReadWrite.Store4(0, asuint(asfloat(ReadWrite.Load4(0)) + 10.0f.xxxx));
}
[numthreads(1, 1, 1)]
void main()
{
comp_main();
}

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RWByteAddressBuffer u0_counter : register(u1);
RWBuffer<uint> u0 : register(u0);
static uint3 gl_GlobalInvocationID;
struct SPIRV_Cross_Input
{
uint3 gl_GlobalInvocationID : SV_DispatchThreadID;
};
void comp_main()
{
uint _29;
u0_counter.InterlockedAdd(0, -1, _29);
u0[uint(asint(asfloat(_29))) + 0u] = uint(int(gl_GlobalInvocationID.x)).x;
}
[numthreads(4, 1, 1)]
void main(SPIRV_Cross_Input stage_input)
{
gl_GlobalInvocationID = stage_input.gl_GlobalInvocationID;
comp_main();
}

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RWByteAddressBuffer u0_counter : register(u1);
RWBuffer<uint> u0 : register(u0);
static uint3 gl_GlobalInvocationID;
struct SPIRV_Cross_Input
{
uint3 gl_GlobalInvocationID : SV_DispatchThreadID;
};
void comp_main()
{
uint _29;
u0_counter.InterlockedAdd(0, 1, _29);
u0[uint(asint(asfloat(_29))) + 0u] = uint(int(gl_GlobalInvocationID.x)).x;
}
[numthreads(4, 1, 1)]
void main(SPIRV_Cross_Input stage_input)
{
gl_GlobalInvocationID = stage_input.gl_GlobalInvocationID;
comp_main();
}

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RWByteAddressBuffer ssbo : register(u2);
RWTexture2D<uint> uImage : register(u0);
RWTexture2D<int> iImage : register(u1);
groupshared int int_atomic;
groupshared uint uint_atomic;
groupshared int int_atomic_array[1];
groupshared uint uint_atomic_array[1];
void comp_main()
{
uint _19;
InterlockedAdd(uImage[int2(1, 5)], 1u, _19);
uint _27;
InterlockedAdd(uImage[int2(1, 5)], 1u, _27);
iImage[int2(1, 6)] = int(_27).x;
uint _32;
InterlockedOr(uImage[int2(1, 5)], 1u, _32);
uint _34;
InterlockedXor(uImage[int2(1, 5)], 1u, _34);
uint _36;
InterlockedAnd(uImage[int2(1, 5)], 1u, _36);
uint _38;
InterlockedMin(uImage[int2(1, 5)], 1u, _38);
uint _40;
InterlockedMax(uImage[int2(1, 5)], 1u, _40);
uint _44;
InterlockedCompareExchange(uImage[int2(1, 5)], 10u, 2u, _44);
int _47;
InterlockedAdd(iImage[int2(1, 6)], 1, _47);
int _49;
InterlockedOr(iImage[int2(1, 6)], 1, _49);
int _51;
InterlockedXor(iImage[int2(1, 6)], 1, _51);
int _53;
InterlockedAnd(iImage[int2(1, 6)], 1, _53);
int _55;
InterlockedMin(iImage[int2(1, 6)], 1, _55);
int _57;
InterlockedMax(iImage[int2(1, 6)], 1, _57);
int _61;
InterlockedCompareExchange(iImage[int2(1, 5)], 10, 2, _61);
uint _68;
ssbo.InterlockedAdd(0, 1u, _68);
uint _70;
ssbo.InterlockedOr(0, 1u, _70);
uint _72;
ssbo.InterlockedXor(0, 1u, _72);
uint _74;
ssbo.InterlockedAnd(0, 1u, _74);
uint _76;
ssbo.InterlockedMin(0, 1u, _76);
uint _78;
ssbo.InterlockedMax(0, 1u, _78);
uint _80;
ssbo.InterlockedExchange(0, 1u, _80);
uint _82;
ssbo.InterlockedCompareExchange(0, 10u, 2u, _82);
int _85;
ssbo.InterlockedAdd(4, 1, _85);
int _87;
ssbo.InterlockedOr(4, 1, _87);
int _89;
ssbo.InterlockedXor(4, 1, _89);
int _91;
ssbo.InterlockedAnd(4, 1, _91);
int _93;
ssbo.InterlockedMin(4, 1, _93);
int _95;
ssbo.InterlockedMax(4, 1, _95);
int _97;
ssbo.InterlockedExchange(4, 1, _97);
int _99;
ssbo.InterlockedCompareExchange(4, 10, 2, _99);
int _102;
InterlockedAdd(int_atomic, 10, _102);
uint _105;
InterlockedAdd(uint_atomic, 10u, _105);
int _110;
InterlockedAdd(int_atomic_array[0], 10, _110);
uint _115;
InterlockedAdd(uint_atomic_array[0], 10u, _115);
}
[numthreads(1, 1, 1)]
void main()
{
comp_main();
}

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static const uint3 gl_WorkGroupSize = uint3(4u, 1u, 1u);
void comp_main()
{
GroupMemoryBarrier();
AllMemoryBarrier();
DeviceMemoryBarrier();
DeviceMemoryBarrier();
AllMemoryBarrier();
GroupMemoryBarrierWithGroupSync();
AllMemoryBarrier();
GroupMemoryBarrierWithGroupSync();
DeviceMemoryBarrier();
GroupMemoryBarrierWithGroupSync();
DeviceMemoryBarrier();
GroupMemoryBarrierWithGroupSync();
AllMemoryBarrier();
GroupMemoryBarrierWithGroupSync();
GroupMemoryBarrierWithGroupSync();
}
[numthreads(4, 1, 1)]
void main()
{
comp_main();
}

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static const uint3 gl_WorkGroupSize = uint3(8u, 4u, 2u);
void comp_main()
{
}
[numthreads(8, 4, 2)]
void main()
{
comp_main();
}

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struct Data
{
float a;
float b;
};
#ifndef SPIRV_CROSS_CONSTANT_ID_0
#define SPIRV_CROSS_CONSTANT_ID_0 4.0f
#endif
static const float X = SPIRV_CROSS_CONSTANT_ID_0;
static const uint3 gl_WorkGroupSize = uint3(2u, 1u, 1u);
static const Data _21 = { 1.0f, 2.0f };
static const Data _24 = { 3.0f, 4.0f };
static const Data _25[2] = { { 1.0f, 2.0f }, { 3.0f, 4.0f } };
static const Data _30 = { 3.0f, 5.0f };
RWByteAddressBuffer _61 : register(u0);
static uint3 gl_WorkGroupID;
static uint3 gl_LocalInvocationID;
static uint gl_LocalInvocationIndex;
struct SPIRV_Cross_Input
{
uint3 gl_WorkGroupID : SV_GroupID;
uint3 gl_LocalInvocationID : SV_GroupThreadID;
uint gl_LocalInvocationIndex : SV_GroupIndex;
};
void comp_main()
{
Data _28 = { X, 2.0f };
Data _31[2] = { _28, _30 };
Data data2[2] = _31;
if (gl_LocalInvocationIndex == 0u)
{
_61.Store(gl_WorkGroupID.x * 8 + 0, asuint(_25[gl_LocalInvocationID.x].a + data2[gl_LocalInvocationID.x].a));
_61.Store(gl_WorkGroupID.x * 8 + 4, asuint(_25[gl_LocalInvocationID.x].b + data2[gl_LocalInvocationID.x].b));
}
}
[numthreads(2, 1, 1)]
void main(SPIRV_Cross_Input stage_input)
{
gl_WorkGroupID = stage_input.gl_WorkGroupID;
gl_LocalInvocationID = stage_input.gl_LocalInvocationID;
gl_LocalInvocationIndex = stage_input.gl_LocalInvocationIndex;
comp_main();
}

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globallycoherent RWByteAddressBuffer _29 : register(u3);
ByteAddressBuffer _33 : register(t2);
RWTexture2D<float> uImageIn : register(u0);
globallycoherent RWTexture2D<float> uImageOut : register(u1);
void comp_main()
{
uImageOut[int2(9, 7)] = uImageIn[int2(9, 7)].x;
_29.Store(0, asuint(asfloat(_33.Load(0))));
}
[numthreads(1, 1, 1)]
void main()
{
comp_main();
}

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RWTexture2D<float> uImageInF : register(u0);
RWTexture2D<float> uImageOutF : register(u1);
RWTexture2D<int> uImageInI : register(u2);
RWTexture2D<int> uImageOutI : register(u3);
RWTexture2D<uint> uImageInU : register(u4);
RWTexture2D<uint> uImageOutU : register(u5);
RWBuffer<float> uImageInBuffer : register(u6);
RWBuffer<float> uImageOutBuffer : register(u7);
RWTexture2D<float2> uImageInF2 : register(u8);
RWTexture2D<float2> uImageOutF2 : register(u9);
RWTexture2D<int2> uImageInI2 : register(u10);
RWTexture2D<int2> uImageOutI2 : register(u11);
RWTexture2D<uint2> uImageInU2 : register(u12);
RWTexture2D<uint2> uImageOutU2 : register(u13);
RWBuffer<float2> uImageInBuffer2 : register(u14);
RWBuffer<float2> uImageOutBuffer2 : register(u15);
RWTexture2D<float4> uImageInF4 : register(u16);
RWTexture2D<float4> uImageOutF4 : register(u17);
RWTexture2D<int4> uImageInI4 : register(u18);
RWTexture2D<int4> uImageOutI4 : register(u19);
RWTexture2D<uint4> uImageInU4 : register(u20);
RWTexture2D<uint4> uImageOutU4 : register(u21);
RWBuffer<float4> uImageInBuffer4 : register(u22);
RWBuffer<float4> uImageOutBuffer4 : register(u23);
RWTexture2D<float4> uImageNoFmtF : register(u24);
RWTexture2D<uint4> uImageNoFmtU : register(u25);
RWTexture2D<int4> uImageNoFmtI : register(u26);
static uint3 gl_GlobalInvocationID;
struct SPIRV_Cross_Input
{
uint3 gl_GlobalInvocationID : SV_DispatchThreadID;
};
void comp_main()
{
int2 _23 = int2(gl_GlobalInvocationID.xy);
uImageOutF[_23] = uImageInF[_23].x;
uImageOutI[_23] = uImageInI[_23].x;
uImageOutU[_23] = uImageInU[_23].x;
int _74 = int(gl_GlobalInvocationID.x);
uImageOutBuffer[_74] = uImageInBuffer[_74].x;
uImageOutF2[_23] = uImageInF2[_23].xy;
uImageOutI2[_23] = uImageInI2[_23].xy;
uImageOutU2[_23] = uImageInU2[_23].xy;
float4 _135 = uImageInBuffer2[_74].xyyy;
uImageOutBuffer2[_74] = _135.xy;
uImageOutF4[_23] = uImageInF4[_23];
int4 _165 = uImageInI4[_23];
uImageOutI4[_23] = _165;
uint4 _180 = uImageInU4[_23];
uImageOutU4[_23] = _180;
uImageOutBuffer4[_74] = uImageInBuffer4[_74];
uImageNoFmtF[_23] = _135;
uImageNoFmtU[_23] = _180;
uImageNoFmtI[_23] = _165;
}
[numthreads(1, 1, 1)]
void main(SPIRV_Cross_Input stage_input)
{
gl_GlobalInvocationID = stage_input.gl_GlobalInvocationID;
comp_main();
}

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RWByteAddressBuffer _15 : register(u0);
ByteAddressBuffer _20 : register(t1);
// Returns the inverse of a matrix, by using the algorithm of calculating the classical
// adjoint and dividing by the determinant. The contents of the matrix are changed.
float2x2 SPIRV_Cross_Inverse(float2x2 m)
{
float2x2 adj; // The adjoint matrix (inverse after dividing by determinant)
// Create the transpose of the cofactors, as the classical adjoint of the matrix.
adj[0][0] = m[1][1];
adj[0][1] = -m[0][1];
adj[1][0] = -m[1][0];
adj[1][1] = m[0][0];
// Calculate the determinant as a combination of the cofactors of the first row.
float det = (adj[0][0] * m[0][0]) + (adj[0][1] * m[1][0]);
// Divide the classical adjoint matrix by the determinant.
// If determinant is zero, matrix is not invertable, so leave it unchanged.
return (det != 0.0f) ? (adj * (1.0f / det)) : m;
}
// Returns the determinant of a 2x2 matrix.
float SPIRV_Cross_Det2x2(float a1, float a2, float b1, float b2)
{
return a1 * b2 - b1 * a2;
}
// Returns the inverse of a matrix, by using the algorithm of calculating the classical
// adjoint and dividing by the determinant. The contents of the matrix are changed.
float3x3 SPIRV_Cross_Inverse(float3x3 m)
{
float3x3 adj; // The adjoint matrix (inverse after dividing by determinant)
// Create the transpose of the cofactors, as the classical adjoint of the matrix.
adj[0][0] = SPIRV_Cross_Det2x2(m[1][1], m[1][2], m[2][1], m[2][2]);
adj[0][1] = -SPIRV_Cross_Det2x2(m[0][1], m[0][2], m[2][1], m[2][2]);
adj[0][2] = SPIRV_Cross_Det2x2(m[0][1], m[0][2], m[1][1], m[1][2]);
adj[1][0] = -SPIRV_Cross_Det2x2(m[1][0], m[1][2], m[2][0], m[2][2]);
adj[1][1] = SPIRV_Cross_Det2x2(m[0][0], m[0][2], m[2][0], m[2][2]);
adj[1][2] = -SPIRV_Cross_Det2x2(m[0][0], m[0][2], m[1][0], m[1][2]);
adj[2][0] = SPIRV_Cross_Det2x2(m[1][0], m[1][1], m[2][0], m[2][1]);
adj[2][1] = -SPIRV_Cross_Det2x2(m[0][0], m[0][1], m[2][0], m[2][1]);
adj[2][2] = SPIRV_Cross_Det2x2(m[0][0], m[0][1], m[1][0], m[1][1]);
// Calculate the determinant as a combination of the cofactors of the first row.
float det = (adj[0][0] * m[0][0]) + (adj[0][1] * m[1][0]) + (adj[0][2] * m[2][0]);
// Divide the classical adjoint matrix by the determinant.
// If determinant is zero, matrix is not invertable, so leave it unchanged.
return (det != 0.0f) ? (adj * (1.0f / det)) : m;
}
// Returns the determinant of a 3x3 matrix.
float SPIRV_Cross_Det3x3(float a1, float a2, float a3, float b1, float b2, float b3, float c1, float c2, float c3)
{
return a1 * SPIRV_Cross_Det2x2(b2, b3, c2, c3) - b1 * SPIRV_Cross_Det2x2(a2, a3, c2, c3) + c1 * SPIRV_Cross_Det2x2(a2, a3, b2, b3);
}
// Returns the inverse of a matrix, by using the algorithm of calculating the classical
// adjoint and dividing by the determinant. The contents of the matrix are changed.
float4x4 SPIRV_Cross_Inverse(float4x4 m)
{
float4x4 adj; // The adjoint matrix (inverse after dividing by determinant)
// Create the transpose of the cofactors, as the classical adjoint of the matrix.
adj[0][0] = SPIRV_Cross_Det3x3(m[1][1], m[1][2], m[1][3], m[2][1], m[2][2], m[2][3], m[3][1], m[3][2], m[3][3]);
adj[0][1] = -SPIRV_Cross_Det3x3(m[0][1], m[0][2], m[0][3], m[2][1], m[2][2], m[2][3], m[3][1], m[3][2], m[3][3]);
adj[0][2] = SPIRV_Cross_Det3x3(m[0][1], m[0][2], m[0][3], m[1][1], m[1][2], m[1][3], m[3][1], m[3][2], m[3][3]);
adj[0][3] = -SPIRV_Cross_Det3x3(m[0][1], m[0][2], m[0][3], m[1][1], m[1][2], m[1][3], m[2][1], m[2][2], m[2][3]);
adj[1][0] = -SPIRV_Cross_Det3x3(m[1][0], m[1][2], m[1][3], m[2][0], m[2][2], m[2][3], m[3][0], m[3][2], m[3][3]);
adj[1][1] = SPIRV_Cross_Det3x3(m[0][0], m[0][2], m[0][3], m[2][0], m[2][2], m[2][3], m[3][0], m[3][2], m[3][3]);
adj[1][2] = -SPIRV_Cross_Det3x3(m[0][0], m[0][2], m[0][3], m[1][0], m[1][2], m[1][3], m[3][0], m[3][2], m[3][3]);
adj[1][3] = SPIRV_Cross_Det3x3(m[0][0], m[0][2], m[0][3], m[1][0], m[1][2], m[1][3], m[2][0], m[2][2], m[2][3]);
adj[2][0] = SPIRV_Cross_Det3x3(m[1][0], m[1][1], m[1][3], m[2][0], m[2][1], m[2][3], m[3][0], m[3][1], m[3][3]);
adj[2][1] = -SPIRV_Cross_Det3x3(m[0][0], m[0][1], m[0][3], m[2][0], m[2][1], m[2][3], m[3][0], m[3][1], m[3][3]);
adj[2][2] = SPIRV_Cross_Det3x3(m[0][0], m[0][1], m[0][3], m[1][0], m[1][1], m[1][3], m[3][0], m[3][1], m[3][3]);
adj[2][3] = -SPIRV_Cross_Det3x3(m[0][0], m[0][1], m[0][3], m[1][0], m[1][1], m[1][3], m[2][0], m[2][1], m[2][3]);
adj[3][0] = -SPIRV_Cross_Det3x3(m[1][0], m[1][1], m[1][2], m[2][0], m[2][1], m[2][2], m[3][0], m[3][1], m[3][2]);
adj[3][1] = SPIRV_Cross_Det3x3(m[0][0], m[0][1], m[0][2], m[2][0], m[2][1], m[2][2], m[3][0], m[3][1], m[3][2]);
adj[3][2] = -SPIRV_Cross_Det3x3(m[0][0], m[0][1], m[0][2], m[1][0], m[1][1], m[1][2], m[3][0], m[3][1], m[3][2]);
adj[3][3] = SPIRV_Cross_Det3x3(m[0][0], m[0][1], m[0][2], m[1][0], m[1][1], m[1][2], m[2][0], m[2][1], m[2][2]);
// Calculate the determinant as a combination of the cofactors of the first row.
float det = (adj[0][0] * m[0][0]) + (adj[0][1] * m[1][0]) + (adj[0][2] * m[2][0]) + (adj[0][3] * m[3][0]);
// Divide the classical adjoint matrix by the determinant.
// If determinant is zero, matrix is not invertable, so leave it unchanged.
return (det != 0.0f) ? (adj * (1.0f / det)) : m;
}
void comp_main()
{
float2x2 _23 = asfloat(uint2x2(_20.Load2(0), _20.Load2(8)));
float2x2 _24 = SPIRV_Cross_Inverse(_23);
_15.Store2(0, asuint(_24[0]));
_15.Store2(8, asuint(_24[1]));
float3x3 _29 = asfloat(uint3x3(_20.Load3(16), _20.Load3(32), _20.Load3(48)));
float3x3 _30 = SPIRV_Cross_Inverse(_29);
_15.Store3(16, asuint(_30[0]));
_15.Store3(32, asuint(_30[1]));
_15.Store3(48, asuint(_30[2]));
float4x4 _35 = asfloat(uint4x4(_20.Load4(64), _20.Load4(80), _20.Load4(96), _20.Load4(112)));
float4x4 _36 = SPIRV_Cross_Inverse(_35);
_15.Store4(64, asuint(_36[0]));
_15.Store4(80, asuint(_36[1]));
_15.Store4(96, asuint(_36[2]));
_15.Store4(112, asuint(_36[3]));
}
[numthreads(1, 1, 1)]
void main()
{
comp_main();
}

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RWByteAddressBuffer _10 : register(u0);
cbuffer SPIRV_Cross_NumWorkgroups : register(b0)
{
uint3 SPIRV_Cross_NumWorkgroups_1_count : packoffset(c0);
};
void comp_main()
{
_10.Store3(0, SPIRV_Cross_NumWorkgroups_1_count);
}
[numthreads(1, 1, 1)]
void main()
{
comp_main();
}

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RWByteAddressBuffer _10 : register(u0);
cbuffer SPIRV_Cross_NumWorkgroups : register(b0)
{
uint3 SPIRV_Cross_NumWorkgroups_1_count : packoffset(c0);
};
static uint3 gl_WorkGroupID;
struct SPIRV_Cross_Input
{
uint3 gl_WorkGroupID : SV_GroupID;
};
void comp_main()
{
_10.Store3(0, SPIRV_Cross_NumWorkgroups_1_count + gl_WorkGroupID);
}
[numthreads(1, 1, 1)]
void main(SPIRV_Cross_Input stage_input)
{
gl_WorkGroupID = stage_input.gl_WorkGroupID;
comp_main();
}

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RWByteAddressBuffer _11 : register(u0);
void comp_main()
{
_11.Store(0, asuint(asfloat(_11.Load(0)) * asfloat(_11.Load(96))));
_11.Store4(16, asuint(asfloat(_11.Load4(16)) * asfloat(_11.Load4(112))));
float4x4 _35 = asfloat(uint4x4(_11.Load4(128), _11.Load4(144), _11.Load4(160), _11.Load4(176)));
float4x4 _37 = asfloat(uint4x4(_11.Load4(32), _11.Load4(48), _11.Load4(64), _11.Load4(80)));
float4x4 _38 = mul(_35, _37);
_11.Store4(32, asuint(_38[0]));
_11.Store4(48, asuint(_38[1]));
_11.Store4(64, asuint(_38[2]));
_11.Store4(80, asuint(_38[3]));
}
[numthreads(1, 1, 1)]
void main()
{
comp_main();
}

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RWByteAddressBuffer _28 : register(u0);
cbuffer UBO : register(b1)
{
int _68_index0 : packoffset(c0);
int _68_index1 : packoffset(c0.y);
};
void comp_main()
{
float4x4 _253 = asfloat(uint4x4(_28.Load(64), _28.Load(80), _28.Load(96), _28.Load(112), _28.Load(68), _28.Load(84), _28.Load(100), _28.Load(116), _28.Load(72), _28.Load(88), _28.Load(104), _28.Load(120), _28.Load(76), _28.Load(92), _28.Load(108), _28.Load(124)));
_28.Store4(0, asuint(_253[0]));
_28.Store4(16, asuint(_253[1]));
_28.Store4(32, asuint(_253[2]));
_28.Store4(48, asuint(_253[3]));
float2x2 _256 = asfloat(uint2x2(_28.Load(144), _28.Load(152), _28.Load(148), _28.Load(156)));
_28.Store2(128, asuint(_256[0]));
_28.Store2(136, asuint(_256[1]));
float2x3 _259 = asfloat(uint2x3(_28.Load(192), _28.Load(200), _28.Load(208), _28.Load(196), _28.Load(204), _28.Load(212)));
_28.Store3(160, asuint(_259[0]));
_28.Store3(176, asuint(_259[1]));
float3x2 _262 = asfloat(uint3x2(_28.Load(240), _28.Load(256), _28.Load(244), _28.Load(260), _28.Load(248), _28.Load(264)));
_28.Store2(216, asuint(_262[0]));
_28.Store2(224, asuint(_262[1]));
_28.Store2(232, asuint(_262[2]));
float4x4 _265 = asfloat(uint4x4(_28.Load4(0), _28.Load4(16), _28.Load4(32), _28.Load4(48)));
_28.Store(64, asuint(_265[0].x));
_28.Store(68, asuint(_265[1].x));
_28.Store(72, asuint(_265[2].x));
_28.Store(76, asuint(_265[3].x));
_28.Store(80, asuint(_265[0].y));
_28.Store(84, asuint(_265[1].y));
_28.Store(88, asuint(_265[2].y));
_28.Store(92, asuint(_265[3].y));
_28.Store(96, asuint(_265[0].z));
_28.Store(100, asuint(_265[1].z));
_28.Store(104, asuint(_265[2].z));
_28.Store(108, asuint(_265[3].z));
_28.Store(112, asuint(_265[0].w));
_28.Store(116, asuint(_265[1].w));
_28.Store(120, asuint(_265[2].w));
_28.Store(124, asuint(_265[3].w));
float2x2 _268 = asfloat(uint2x2(_28.Load2(128), _28.Load2(136)));
_28.Store(144, asuint(_268[0].x));
_28.Store(148, asuint(_268[1].x));
_28.Store(152, asuint(_268[0].y));
_28.Store(156, asuint(_268[1].y));
float2x3 _271 = asfloat(uint2x3(_28.Load3(160), _28.Load3(176)));
_28.Store(192, asuint(_271[0].x));
_28.Store(196, asuint(_271[1].x));
_28.Store(200, asuint(_271[0].y));
_28.Store(204, asuint(_271[1].y));
_28.Store(208, asuint(_271[0].z));
_28.Store(212, asuint(_271[1].z));
float3x2 _274 = asfloat(uint3x2(_28.Load2(216), _28.Load2(224), _28.Load2(232)));
_28.Store(240, asuint(_274[0].x));
_28.Store(244, asuint(_274[1].x));
_28.Store(248, asuint(_274[2].x));
_28.Store(256, asuint(_274[0].y));
_28.Store(260, asuint(_274[1].y));
_28.Store(264, asuint(_274[2].y));
_28.Store(_68_index0 * 4 + _68_index1 * 16 + 64, asuint(1.0f));
_28.Store(_68_index0 * 4 + _68_index1 * 8 + 144, asuint(2.0f));
_28.Store(_68_index0 * 4 + _68_index1 * 8 + 192, asuint(3.0f));
_28.Store(_68_index0 * 4 + _68_index1 * 16 + 240, asuint(4.0f));
_28.Store(_68_index0 * 4 + 64, asuint(1.0f.x));
_28.Store(_68_index0 * 4 + 80, asuint(1.0f.xxxx.y));
_28.Store(_68_index0 * 4 + 96, asuint(1.0f.xxxx.z));
_28.Store(_68_index0 * 4 + 112, asuint(1.0f.xxxx.w));
_28.Store(_68_index0 * 4 + 144, asuint(2.0f.x));
_28.Store(_68_index0 * 4 + 152, asuint(2.0f.xx.y));
_28.Store(_68_index0 * 4 + 192, asuint(3.0f.x));
_28.Store(_68_index0 * 4 + 200, asuint(3.0f.xxx.y));
_28.Store(_68_index0 * 4 + 208, asuint(3.0f.xxx.z));
_28.Store(_68_index0 * 4 + 240, asuint(4.0f.x));
_28.Store(_68_index0 * 4 + 256, asuint(4.0f.xx.y));
_28.Store(_68_index0 * 16 + _68_index1 * 4 + 0, asuint(1.0f));
_28.Store(_68_index0 * 8 + _68_index1 * 4 + 128, asuint(2.0f));
_28.Store(_68_index0 * 16 + _68_index1 * 4 + 160, asuint(3.0f));
_28.Store(_68_index0 * 8 + _68_index1 * 4 + 216, asuint(4.0f));
_28.Store4(_68_index0 * 16 + 0, asuint(1.0f.xxxx));
_28.Store2(_68_index0 * 8 + 128, asuint(2.0f.xx));
_28.Store3(_68_index0 * 16 + 160, asuint(3.0f.xxx));
_28.Store2(_68_index0 * 8 + 216, asuint(4.0f.xx));
}
[numthreads(1, 1, 1)]
void main()
{
comp_main();
}

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static const uint3 gl_WorkGroupSize = uint3(4u, 1u, 1u);
ByteAddressBuffer _22 : register(t0);
RWByteAddressBuffer _44 : register(u1);
static uint3 gl_GlobalInvocationID;
static uint gl_LocalInvocationIndex;
struct SPIRV_Cross_Input
{
uint3 gl_GlobalInvocationID : SV_DispatchThreadID;
uint gl_LocalInvocationIndex : SV_GroupIndex;
};
groupshared float sShared[4];
void comp_main()
{
sShared[gl_LocalInvocationIndex] = asfloat(_22.Load(gl_GlobalInvocationID.x * 4 + 0));
GroupMemoryBarrierWithGroupSync();
_44.Store(gl_GlobalInvocationID.x * 4 + 0, asuint(sShared[3u - gl_LocalInvocationIndex]));
}
[numthreads(4, 1, 1)]
void main(SPIRV_Cross_Input stage_input)
{
gl_GlobalInvocationID = stage_input.gl_GlobalInvocationID;
gl_LocalInvocationIndex = stage_input.gl_LocalInvocationIndex;
comp_main();
}

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#ifndef SPIRV_CROSS_CONSTANT_ID_0
#define SPIRV_CROSS_CONSTANT_ID_0 100
#endif
static const int a = SPIRV_CROSS_CONSTANT_ID_0;
#ifndef SPIRV_CROSS_CONSTANT_ID_1
#define SPIRV_CROSS_CONSTANT_ID_1 200
#endif
static const int b = SPIRV_CROSS_CONSTANT_ID_1;
struct A
{
int member0[a];
int member1[b];
};
struct B
{
int member0[b];
int member1[a];
};
#ifndef SPIRV_CROSS_CONSTANT_ID_2
#define SPIRV_CROSS_CONSTANT_ID_2 300
#endif
static const int c = SPIRV_CROSS_CONSTANT_ID_2;
static const int d = (c + 50);
#ifndef SPIRV_CROSS_CONSTANT_ID_3
#define SPIRV_CROSS_CONSTANT_ID_3 400
#endif
static const int e = SPIRV_CROSS_CONSTANT_ID_3;
RWByteAddressBuffer _22 : register(u0);
static uint3 gl_GlobalInvocationID;
struct SPIRV_Cross_Input
{
uint3 gl_GlobalInvocationID : SV_DispatchThreadID;
};
void comp_main()
{
_22.Store(gl_GlobalInvocationID.x * 4 + 2800, uint(int(_22.Load(gl_GlobalInvocationID.x * 4 + 2800)) + (int(_22.Load(gl_GlobalInvocationID.x * 4 + 2400)) + e)));
}
[numthreads(1, 1, 1)]
void main(SPIRV_Cross_Input stage_input)
{
gl_GlobalInvocationID = stage_input.gl_GlobalInvocationID;
comp_main();
}

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#ifndef SPIRV_CROSS_CONSTANT_ID_1
#define SPIRV_CROSS_CONSTANT_ID_1 2
#endif
static const int b = SPIRV_CROSS_CONSTANT_ID_1;
#ifndef SPIRV_CROSS_CONSTANT_ID_0
#define SPIRV_CROSS_CONSTANT_ID_0 1
#endif
static const int a = SPIRV_CROSS_CONSTANT_ID_0;
static const uint _26 = (uint(a) + 0u);
#ifndef SPIRV_CROSS_CONSTANT_ID_10
#define SPIRV_CROSS_CONSTANT_ID_10 1u
#endif
static const uint _27 = SPIRV_CROSS_CONSTANT_ID_10;
static const uint3 gl_WorkGroupSize = uint3(_27, 20u, 1u);
static const uint _32 = gl_WorkGroupSize.x;
static const uint _33 = (_26 + _32);
static const uint _34 = gl_WorkGroupSize.y;
static const uint _35 = (_33 + _34);
static const int _42 = (1 - a);
RWByteAddressBuffer _23 : register(u0);
static uint3 gl_GlobalInvocationID;
struct SPIRV_Cross_Input
{
uint3 gl_GlobalInvocationID : SV_DispatchThreadID;
};
void comp_main()
{
int spec_const_array_size[b];
spec_const_array_size[0] = 10;
spec_const_array_size[1] = 40;
spec_const_array_size[a] = a;
_23.Store((_35 + gl_GlobalInvocationID.x) * 4 + 0, uint(b + spec_const_array_size[_42]));
}
[numthreads(SPIRV_CROSS_CONSTANT_ID_10, 20, 1)]
void main(SPIRV_Cross_Input stage_input)
{
gl_GlobalInvocationID = stage_input.gl_GlobalInvocationID;
comp_main();
}

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RWByteAddressBuffer _11 : register(u1);
void comp_main()
{
uint _14;
_11.GetDimensions(_14);
_14 = (_14 - 16) / 16;
_11.Store(0, uint(int(_14)));
}
[numthreads(1, 1, 1)]
void main()
{
comp_main();
}

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void comp_main()
{
}
[numthreads(1, 1, 1)]
void main()
{
comp_main();
}

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RWByteAddressBuffer _9 : register(u0, space0);
static uint4 gl_SubgroupEqMask;
static uint4 gl_SubgroupGeMask;
static uint4 gl_SubgroupGtMask;
static uint4 gl_SubgroupLeMask;
static uint4 gl_SubgroupLtMask;
void comp_main()
{
_9.Store(0, asuint(float(WaveGetLaneCount())));
_9.Store(0, asuint(float(WaveGetLaneIndex())));
_9.Store(0, asuint(float4(gl_SubgroupEqMask).x));
_9.Store(0, asuint(float4(gl_SubgroupGeMask).x));
_9.Store(0, asuint(float4(gl_SubgroupGtMask).x));
_9.Store(0, asuint(float4(gl_SubgroupLeMask).x));
_9.Store(0, asuint(float4(gl_SubgroupLtMask).x));
uint4 _75 = WaveActiveBallot(true);
float4 _88 = WaveActiveSum(20.0f.xxxx);
int4 _94 = WaveActiveSum(int4(20, 20, 20, 20));
float4 _96 = WaveActiveProduct(20.0f.xxxx);
int4 _98 = WaveActiveProduct(int4(20, 20, 20, 20));
float4 _127 = WavePrefixProduct(_96) * _96;
int4 _129 = WavePrefixProduct(_98) * _98;
}
[numthreads(1, 1, 1)]
void main()
{
gl_SubgroupEqMask = 1u << (WaveGetLaneIndex() - uint4(0, 32, 64, 96));
if (WaveGetLaneIndex() >= 32) gl_SubgroupEqMask.x = 0;
if (WaveGetLaneIndex() >= 64 || WaveGetLaneIndex() < 32) gl_SubgroupEqMask.y = 0;
if (WaveGetLaneIndex() >= 96 || WaveGetLaneIndex() < 64) gl_SubgroupEqMask.z = 0;
if (WaveGetLaneIndex() < 96) gl_SubgroupEqMask.w = 0;
gl_SubgroupGeMask = ~((1u << (WaveGetLaneIndex() - uint4(0, 32, 64, 96))) - 1u);
if (WaveGetLaneIndex() >= 32) gl_SubgroupGeMask.x = 0u;
if (WaveGetLaneIndex() >= 64) gl_SubgroupGeMask.y = 0u;
if (WaveGetLaneIndex() >= 96) gl_SubgroupGeMask.z = 0u;
if (WaveGetLaneIndex() < 32) gl_SubgroupGeMask.y = ~0u;
if (WaveGetLaneIndex() < 64) gl_SubgroupGeMask.z = ~0u;
if (WaveGetLaneIndex() < 96) gl_SubgroupGeMask.w = ~0u;
uint gt_lane_index = WaveGetLaneIndex() + 1;
gl_SubgroupGtMask = ~((1u << (gt_lane_index - uint4(0, 32, 64, 96))) - 1u);
if (gt_lane_index >= 32) gl_SubgroupGtMask.x = 0u;
if (gt_lane_index >= 64) gl_SubgroupGtMask.y = 0u;
if (gt_lane_index >= 96) gl_SubgroupGtMask.z = 0u;
if (gt_lane_index >= 128) gl_SubgroupGtMask.w = 0u;
if (gt_lane_index < 32) gl_SubgroupGtMask.y = ~0u;
if (gt_lane_index < 64) gl_SubgroupGtMask.z = ~0u;
if (gt_lane_index < 96) gl_SubgroupGtMask.w = ~0u;
uint le_lane_index = WaveGetLaneIndex() + 1;
gl_SubgroupLeMask = (1u << (le_lane_index - uint4(0, 32, 64, 96))) - 1u;
if (le_lane_index >= 32) gl_SubgroupLeMask.x = ~0u;
if (le_lane_index >= 64) gl_SubgroupLeMask.y = ~0u;
if (le_lane_index >= 96) gl_SubgroupLeMask.z = ~0u;
if (le_lane_index >= 128) gl_SubgroupLeMask.w = ~0u;
if (le_lane_index < 32) gl_SubgroupLeMask.y = 0u;
if (le_lane_index < 64) gl_SubgroupLeMask.z = 0u;
if (le_lane_index < 96) gl_SubgroupLeMask.w = 0u;
gl_SubgroupLtMask = (1u << (WaveGetLaneIndex() - uint4(0, 32, 64, 96))) - 1u;
if (WaveGetLaneIndex() >= 32) gl_SubgroupLtMask.x = ~0u;
if (WaveGetLaneIndex() >= 64) gl_SubgroupLtMask.y = ~0u;
if (WaveGetLaneIndex() >= 96) gl_SubgroupLtMask.z = ~0u;
if (WaveGetLaneIndex() < 32) gl_SubgroupLtMask.y = 0u;
if (WaveGetLaneIndex() < 64) gl_SubgroupLtMask.z = 0u;
if (WaveGetLaneIndex() < 96) gl_SubgroupLtMask.w = 0u;
comp_main();
}

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static const float _17[5] = { 1.0f, 2.0f, 3.0f, 4.0f, 5.0f };
static float4 FragColor;
static float4 v0;
struct SPIRV_Cross_Input
{
float4 v0 : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
for (int _46 = 0; _46 < 4; )
{
int _33 = _46 + 1;
FragColor += _17[_33].xxxx;
_46 = _33;
continue;
}
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
v0 = stage_input.v0;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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static float3 FragColor;
static float4 vColor;
struct SPIRV_Cross_Input
{
float4 vColor : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float4 FragColor : COLOR0;
};
void frag_main()
{
FragColor = vColor.xyz;
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
vColor = stage_input.vColor;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = float4(FragColor, 0.0);
return stage_output;
}

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static float3 FragColor;
static float4 vColor;
struct SPIRV_Cross_Input
{
float4 vColor : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float3 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = vColor.xyz;
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
vColor = stage_input.vColor;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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Texture2D<float4> uTex : register(t0);
SamplerState _uTex_sampler : register(s0);
static float4 FragColor;
static float4 vColor;
static float2 vTex;
struct SPIRV_Cross_Input
{
float4 vColor : TEXCOORD0;
float2 vTex : TEXCOORD1;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = vColor * uTex.Sample(_uTex_sampler, vTex);
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
vColor = stage_input.vColor;
vTex = stage_input.vTex;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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static float2 value;
static float4 FragColor;
struct SPIRV_Cross_Input
{
float2 value : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = float4(1.0f, 0.0f, asfloat(asint(value.x)), 1.0f);
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
value = stage_input.value;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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static float2 FragColor;
static float2 x0;
struct SPIRV_Cross_Input
{
float2 x0 : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float2 FragColor : SV_Target0;
};
void frag_main()
{
bool2 _27 = (x0.x > x0.y).xx;
FragColor = float2(_27.x ? float2(1.0f, 0.0f).x : float2(0.0f, 1.0f).x, _27.y ? float2(1.0f, 0.0f).y : float2(0.0f, 1.0f).y);
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
x0 = stage_input.x0;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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static float4 gl_FragCoord;
static float gl_FragDepth;
static float4 FragColor;
static float4 vColor;
struct SPIRV_Cross_Input
{
float4 vColor : TEXCOORD0;
float4 gl_FragCoord : SV_Position;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
float gl_FragDepth : SV_Depth;
};
void frag_main()
{
FragColor = gl_FragCoord + vColor;
gl_FragDepth = 0.5f;
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
gl_FragCoord = stage_input.gl_FragCoord;
vColor = stage_input.vColor;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.gl_FragDepth = gl_FragDepth;
stage_output.FragColor = FragColor;
return stage_output;
}

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static float2 value;
static float4 FragColor;
struct SPIRV_Cross_Input
{
float2 value : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
bool _47;
void frag_main()
{
bool2 _25 = bool2(value.x == 0.0f, _47);
FragColor = float4(1.0f, 0.0f, float(bool2(!_25.x, !_25.y).x), float(bool2(value.x <= float2(1.5f, 0.5f).x, value.y <= float2(1.5f, 0.5f).y).x));
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
value = stage_input.value;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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static float gl_ClipDistance[2];
static float gl_CullDistance[1];
static float FragColor;
struct SPIRV_Cross_Input
{
float2 gl_ClipDistance0 : SV_ClipDistance0;
float gl_CullDistance0 : SV_CullDistance0;
};
struct SPIRV_Cross_Output
{
float FragColor : SV_Target0;
};
void frag_main()
{
FragColor = (gl_ClipDistance[0] + gl_CullDistance[0]) + gl_ClipDistance[1];
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
gl_ClipDistance[0] = stage_input.gl_ClipDistance0.x;
gl_ClipDistance[1] = stage_input.gl_ClipDistance0.y;
gl_CullDistance[0] = stage_input.gl_CullDistance0.x;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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Texture2D<float4> uSampler : register(t0);
SamplerState _uSampler_sampler : register(s0);
Texture2D<float4> uSamplerShadow : register(t1);
SamplerComparisonState _uSamplerShadow_sampler : register(s1);
static float FragColor;
struct SPIRV_Cross_Output
{
float FragColor : SV_Target0;
};
void frag_main()
{
FragColor = (uSampler.Sample(_uSampler_sampler, 1.0f.xx) + uSampler.Load(int3(int2(10, 10), 0))).x + uSamplerShadow.SampleCmp(_uSamplerShadow_sampler, 1.0f.xxx.xy, 1.0f);
}
SPIRV_Cross_Output main()
{
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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Texture2D<float4> uDepth : register(t2);
SamplerComparisonState uSampler : register(s0);
SamplerState uSampler1 : register(s1);
static float FragColor;
struct SPIRV_Cross_Output
{
float FragColor : SV_Target0;
};
void frag_main()
{
FragColor = uDepth.SampleCmp(uSampler, 1.0f.xxx.xy, 1.0f) + uDepth.Sample(uSampler1, 1.0f.xx).x;
}
SPIRV_Cross_Output main()
{
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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RWByteAddressBuffer _34 : register(u0);
Texture2D<int4> Buf : register(t1);
SamplerState _Buf_sampler : register(s1);
static float4 gl_FragCoord;
static int vIn;
static int vIn2;
static float4 FragColor;
struct SPIRV_Cross_Input
{
nointerpolation int vIn : TEXCOORD0;
nointerpolation int vIn2 : TEXCOORD1;
float4 gl_FragCoord : SV_Position;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
int _40 = Buf.Load(int3(int2(gl_FragCoord.xy), 0)).x % 16;
FragColor = (asfloat(_34.Load4(_40 * 16 + 0)) + asfloat(_34.Load4(_40 * 16 + 0))) + asfloat(_34.Load4(((vIn * vIn) + (vIn2 * vIn2)) * 16 + 0));
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
gl_FragCoord = stage_input.gl_FragCoord;
vIn = stage_input.vIn;
vIn2 = stage_input.vIn2;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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struct CBO_1
{
float4 a;
float4 b;
float4 c;
float4 d;
};
ConstantBuffer<CBO_1> cbo[2][4] : register(b4, space0);
cbuffer PushMe
{
float4 push_a : packoffset(c0);
float4 push_b : packoffset(c1);
float4 push_c : packoffset(c2);
float4 push_d : packoffset(c3);
};
static float4 FragColor;
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = cbo[1][2].a;
FragColor += cbo[1][2].b;
FragColor += cbo[1][2].c;
FragColor += cbo[1][2].d;
FragColor += push_a;
FragColor += push_b;
FragColor += push_c;
FragColor += push_d;
}
SPIRV_Cross_Output main()
{
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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struct Foo
{
float a;
float b;
};
static const float _16[4] = { 1.0f, 4.0f, 3.0f, 2.0f };
static const Foo _24 = { 10.0f, 20.0f };
static const Foo _27 = { 30.0f, 40.0f };
static const Foo _28[2] = { { 10.0f, 20.0f }, { 30.0f, 40.0f } };
static float4 FragColor;
static int _line;
struct SPIRV_Cross_Input
{
nointerpolation int _line : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = _16[_line].xxxx;
FragColor += (_28[_line].a * _28[1 - _line].a).xxxx;
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
_line = stage_input._line;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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Texture2D<float4> uSampler : register(t0);
SamplerState _uSampler_sampler : register(s0);
static float4 FragColor;
static float4 vInput;
struct SPIRV_Cross_Input
{
float4 vInput : TEXCOORD0;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = vInput;
float4 _23 = uSampler.Sample(_uSampler_sampler, vInput.xy);
float4 _26 = ddx(vInput);
float4 _29 = ddy(vInput);
float4 _32 = fwidth(vInput);
float4 _35 = ddx_coarse(vInput);
float4 _38 = ddy_coarse(vInput);
float4 _41 = fwidth(vInput);
float4 _44 = ddx_fine(vInput);
float4 _47 = ddy_fine(vInput);
float4 _50 = fwidth(vInput);
float _56_tmp = uSampler.CalculateLevelOfDetail(_uSampler_sampler, vInput.zw);
if (vInput.y > 10.0f)
{
FragColor += _23;
FragColor += _26;
FragColor += _29;
FragColor += _32;
FragColor += _35;
FragColor += _38;
FragColor += _41;
FragColor += _44;
FragColor += _47;
FragColor += _50;
FragColor += float2(_56_tmp, _56_tmp).xyxy;
}
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
vInput = stage_input.vInput;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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static float gl_FragDepth;
struct SPIRV_Cross_Output
{
float gl_FragDepth : SV_DepthGreaterEqual;
};
void frag_main()
{
gl_FragDepth = 0.5f;
}
[earlydepthstencil]
SPIRV_Cross_Output main()
{
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.gl_FragDepth = gl_FragDepth;
return stage_output;
}

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static float gl_FragDepth;
struct SPIRV_Cross_Output
{
float gl_FragDepth : SV_DepthLessEqual;
};
void frag_main()
{
gl_FragDepth = 0.5f;
}
[earlydepthstencil]
SPIRV_Cross_Output main()
{
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.gl_FragDepth = gl_FragDepth;
return stage_output;
}

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static float4 FragColor0;
static float4 FragColor1;
struct SPIRV_Cross_Output
{
float4 FragColor0 : SV_Target0;
float4 FragColor1 : SV_Target1;
};
void frag_main()
{
FragColor0 = 1.0f.xxxx;
FragColor1 = 2.0f.xxxx;
}
SPIRV_Cross_Output main()
{
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor0 = FragColor0;
stage_output.FragColor1 = FragColor1;
return stage_output;
}

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void frag_main()
{
}
[earlydepthstencil]
void main()
{
frag_main();
}

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static float2 FP32Out;
static uint FP16;
static uint FP16Out;
static float2 FP32;
struct SPIRV_Cross_Input
{
nointerpolation uint FP16 : TEXCOORD0;
nointerpolation float2 FP32 : TEXCOORD1;
};
struct SPIRV_Cross_Output
{
float2 FP32Out : SV_Target0;
uint FP16Out : SV_Target1;
};
uint SPIRV_Cross_packHalf2x16(float2 value)
{
uint2 Packed = f32tof16(value);
return Packed.x | (Packed.y << 16);
}
float2 SPIRV_Cross_unpackHalf2x16(uint value)
{
return f16tof32(uint2(value & 0xffff, value >> 16));
}
void frag_main()
{
FP32Out = SPIRV_Cross_unpackHalf2x16(FP16);
FP16Out = SPIRV_Cross_packHalf2x16(FP32);
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
FP16 = stage_input.FP16;
FP32 = stage_input.FP32;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FP32Out = FP32Out;
stage_output.FP16Out = FP16Out;
return stage_output;
}

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static min16float4 v4;
static min16float3 v3;
static min16float v1;
static min16float2 v2;
static float o1;
static float2 o2;
static float3 o3;
static float4 o4;
struct SPIRV_Cross_Input
{
min16float v1 : TEXCOORD0;
min16float2 v2 : TEXCOORD1;
min16float3 v3 : TEXCOORD2;
min16float4 v4 : TEXCOORD3;
};
struct SPIRV_Cross_Output
{
float o1 : SV_Target0;
float2 o2 : SV_Target1;
float3 o3 : SV_Target2;
float4 o4 : SV_Target3;
};
void frag_main()
{
min16float4 _324;
min16float4 _387 = modf(v4, _324);
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
v4 = stage_input.v4;
v3 = stage_input.v3;
v1 = stage_input.v1;
v2 = stage_input.v2;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.o1 = o1;
stage_output.o2 = o2;
stage_output.o3 = o3;
stage_output.o4 = o4;
return stage_output;
}

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static bool gl_FrontFacing;
static float4 FragColor;
static float4 vA;
static float4 vB;
struct SPIRV_Cross_Input
{
float4 vA : TEXCOORD0;
float4 vB : TEXCOORD1;
bool gl_FrontFacing : SV_IsFrontFace;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
if (gl_FrontFacing)
{
FragColor = vA;
}
else
{
FragColor = vB;
}
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
gl_FrontFacing = stage_input.gl_FrontFacing;
vA = stage_input.vA;
vB = stage_input.vB;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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void frag_main()
{
}
void main()
{
frag_main();
}

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@ -0,0 +1,8 @@
void frag_main()
{
}
void main()
{
frag_main();
}

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Texture2DMS<float4> uSubpass0 : register(t0);
Texture2DMS<float4> uSubpass1 : register(t1);
static float4 gl_FragCoord;
static int gl_SampleID;
static float4 FragColor;
struct SPIRV_Cross_Input
{
float4 gl_FragCoord : SV_Position;
uint gl_SampleID : SV_SampleIndex;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = (uSubpass0.Load(int2(gl_FragCoord.xy), 1) + uSubpass1.Load(int2(gl_FragCoord.xy), 2)) + uSubpass0.Load(int2(gl_FragCoord.xy), gl_SampleID);
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
gl_FragCoord = stage_input.gl_FragCoord;
gl_SampleID = stage_input.gl_SampleID;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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Texture2D<float4> uSubpass0 : register(t0);
Texture2D<float4> uSubpass1 : register(t1);
static float4 gl_FragCoord;
static float4 FragColor;
struct SPIRV_Cross_Input
{
float4 gl_FragCoord : SV_Position;
};
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = uSubpass0.Load(int3(int2(gl_FragCoord.xy), 0)) + uSubpass1.Load(int3(int2(gl_FragCoord.xy), 0));
}
SPIRV_Cross_Output main(SPIRV_Cross_Input stage_input)
{
gl_FragCoord = stage_input.gl_FragCoord;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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static float4 FragColor;
struct VertexOut
{
float4 a : TEXCOORD1;
float4 b : TEXCOORD2;
};
static VertexOut _12;
struct SPIRV_Cross_Output
{
float4 FragColor : SV_Target0;
};
void frag_main()
{
FragColor = _12.a + _12.b;
}
SPIRV_Cross_Output main(in VertexOut stage_input_12)
{
_12 = stage_input_12;
frag_main();
SPIRV_Cross_Output stage_output;
stage_output.FragColor = FragColor;
return stage_output;
}

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