Loading docs/html/ndk/guides/graphics/shader-compilers.jd 0 → 100644 +194 −0 Original line number Diff line number Diff line page.title=Vulkan Shader Compilers on Android @jd:body <div id="qv-wrapper"> <div id="qv"> <h2>On this page</h2> <ol> <li><a href="#aot">AOT Compilation</a></li> <li><a href="#runtime">Runtime Compilation</a></li> <li><a href="#integrating">Integrating Into your Project</a></li> </ol> </div> </div> <p> A Vulkan app must manage shaders differently from the way an OpenGL ES app does so: In OpenGL ES, you provide a shader as a set of strings forming the source text of a GLSL shader program. By contrast, the Vulkan API requires you to provide a shader in the form of an entry point in a <a href=”https://www.khronos.org/spir”>SPIR-V</a> module. </p> <p> The NDK includes a runtime library for compiling GLSL into SPIR-V. The runtime library is the same as the one in the <a href="https://github.com/google/shaderc">Shaderc</a> open source project, and use the same <a href="https://github.com/KhronosGroup/glslang">Glslang GLSL</a> reference compiler as a back end. By default, the Shaderc version of the compiler assumes you are compiling for Vulkan. After checking whether your code is valid for Vulkan, the compiler automatically enables the {@code KHR_vulkan_glsl} extension. The Shaderc version of the compiler also generates Vulkan-compliant SPIR-V code. </p> <p> You can choose to compile SPIR-V modules into your Vulkan app during development, a practice called <em>ahead-of-time</em>, or <em>AOT</em>, compiling. Alternatively, you can have your app compile them from shipped or procedurally generated shader source when needed during runtime. This practice is called <em>runtime compiling</em>. </p> <p> The rest of this page provides more detail about each practice, and then explains how to integrate shader compilation into your Vulkan app. </p> <h2 id=”aot”>AOT Compilation</h2> <p> For AOT compilation, we recommend the <em>glslc</em> command-line compiler from GLSL to SPIR-V. This compiler is available from the <a href="https://github.com/google/shaderc">Shaderc</a> project.</a>Many of its command-line options are similar to those of GCC and Clang, allowing you to integrate glslc into build systems easily. </p> <p> The glslc tool compiles a single-source file to a SPIR-V module with a single shader entry point. By default, the output file has the same name as that of the source file, but with the {@code .spv} extension appended. </p> <p> You use filename extensions to tell the glslc tool which graphics shader stage to compile, or whether a compute shader is being compiled. For information on how to use these filename extensions, and options you can use with the tool, see <a href="https://github.com/google/shaderc/tree/master/glslc#user-content-shader-stage-specification"> Shader stage specification</a> in the <a href="https://github.com/google/shaderc/tree/master/glslc"> glslc</a> manual. </p> <h2 id="runtime">Runtime Compilation</h2> <p> For JIT compilation of shaders during runtime, the NDK provides the libshaderc library, which has both C and C++ APIs. </p> <p> C++ applications should use the C++ API. We recommend that apps in other languages use the C API, because the C ABI is lower level, and likely to provide better stability. </p> <p> The following example shows how to use the C++ API: </p> <pre> #include <iostream> #include <string> #include <vector> #include <shaderc/shaderc.hpp> std::vector<uint32_t> compile_file(const std::string& name, shaderc_shader_kind kind, const std::string& data) { shaderc::Compiler compiler; shaderc::CompileOptions options; // Like -DMY_DEFINE=1 options.AddMacroDefinition("MY_DEFINE", "1"); shaderc::SpvCompilationResult module = compiler.CompileGlslToSpv( data.c_str(), data.size(), kind, name.c_str(), options); if (module.GetCompilationStatus() != shaderc_compilation_status_success) { std::cerr << module.GetErrorMessage(); } std::vector<uint32_t> result(module.cbegin(), module.cend()); return result; } </pre> <h2 id=”integrating”>Integrating into Your Projects</h2> <p> You can integrate the Vulkan shader compiler into your app using either the project's {@code Android.mk} file or Gradle. </p> <h3 id=”androidmk”>Android.mk</h3> <p> Perform the following steps to use your project's {@code Android.mk} file to integrate the shader compiler. </p> <ol> <li> Include the following lines in your Android.mk file: <pre class="no-pretty-print"> include $(CLEAR_VARS) ... LOCAL_STATIC_LIBRARIES := shaderc ... include $(BUILD_SHARED_LIBRARY) $(call import-module, third_party/shaderc) </pre> </li> <li> Set APP_STL to one of {@code c++_static}, {@code c++_shared}, {@code gnustl_static}, or {@code gnustl_shared}. </li> </ol> <h3 id=”gradle”>Gradle</h3> <ol> <li> In a terminal window, navigate to {@code <ndk_root>/sources/third_party/shaderc/}. </li> <li> Run the following command: <pre class="no-pretty-print"> $ ../../../ndk-build NDK_PROJECT_PATH=. APP_BUILD_SCRIPT=Android.mk \ APP_STL:=<stl_version> APP_ABI=all libshaderc_combined </pre> <p> This command places two folders in <ndk_root>/sources/third_party/shaderc/. The directory structure is as follows: </p> <pre class="no-pretty-print"> include/ shaderc/ shaderc.h shaderc.hpp libs/ <stl_version>/ {all of the abis} libshaderc.a </pre> </li> <li> Add includes and link lines as you normally would for external libraries. </li> <p> The STL that you use to build your program must match the {@code stl} specified in {@code stl_version}. Only {@code c++_static}, {@code c++_shared}, {@code gnustl_static}, and {@code gnustl_shared} are supported. </p> Loading
docs/html/ndk/guides/graphics/shader-compilers.jd 0 → 100644 +194 −0 Original line number Diff line number Diff line page.title=Vulkan Shader Compilers on Android @jd:body <div id="qv-wrapper"> <div id="qv"> <h2>On this page</h2> <ol> <li><a href="#aot">AOT Compilation</a></li> <li><a href="#runtime">Runtime Compilation</a></li> <li><a href="#integrating">Integrating Into your Project</a></li> </ol> </div> </div> <p> A Vulkan app must manage shaders differently from the way an OpenGL ES app does so: In OpenGL ES, you provide a shader as a set of strings forming the source text of a GLSL shader program. By contrast, the Vulkan API requires you to provide a shader in the form of an entry point in a <a href=”https://www.khronos.org/spir”>SPIR-V</a> module. </p> <p> The NDK includes a runtime library for compiling GLSL into SPIR-V. The runtime library is the same as the one in the <a href="https://github.com/google/shaderc">Shaderc</a> open source project, and use the same <a href="https://github.com/KhronosGroup/glslang">Glslang GLSL</a> reference compiler as a back end. By default, the Shaderc version of the compiler assumes you are compiling for Vulkan. After checking whether your code is valid for Vulkan, the compiler automatically enables the {@code KHR_vulkan_glsl} extension. The Shaderc version of the compiler also generates Vulkan-compliant SPIR-V code. </p> <p> You can choose to compile SPIR-V modules into your Vulkan app during development, a practice called <em>ahead-of-time</em>, or <em>AOT</em>, compiling. Alternatively, you can have your app compile them from shipped or procedurally generated shader source when needed during runtime. This practice is called <em>runtime compiling</em>. </p> <p> The rest of this page provides more detail about each practice, and then explains how to integrate shader compilation into your Vulkan app. </p> <h2 id=”aot”>AOT Compilation</h2> <p> For AOT compilation, we recommend the <em>glslc</em> command-line compiler from GLSL to SPIR-V. This compiler is available from the <a href="https://github.com/google/shaderc">Shaderc</a> project.</a>Many of its command-line options are similar to those of GCC and Clang, allowing you to integrate glslc into build systems easily. </p> <p> The glslc tool compiles a single-source file to a SPIR-V module with a single shader entry point. By default, the output file has the same name as that of the source file, but with the {@code .spv} extension appended. </p> <p> You use filename extensions to tell the glslc tool which graphics shader stage to compile, or whether a compute shader is being compiled. For information on how to use these filename extensions, and options you can use with the tool, see <a href="https://github.com/google/shaderc/tree/master/glslc#user-content-shader-stage-specification"> Shader stage specification</a> in the <a href="https://github.com/google/shaderc/tree/master/glslc"> glslc</a> manual. </p> <h2 id="runtime">Runtime Compilation</h2> <p> For JIT compilation of shaders during runtime, the NDK provides the libshaderc library, which has both C and C++ APIs. </p> <p> C++ applications should use the C++ API. We recommend that apps in other languages use the C API, because the C ABI is lower level, and likely to provide better stability. </p> <p> The following example shows how to use the C++ API: </p> <pre> #include <iostream> #include <string> #include <vector> #include <shaderc/shaderc.hpp> std::vector<uint32_t> compile_file(const std::string& name, shaderc_shader_kind kind, const std::string& data) { shaderc::Compiler compiler; shaderc::CompileOptions options; // Like -DMY_DEFINE=1 options.AddMacroDefinition("MY_DEFINE", "1"); shaderc::SpvCompilationResult module = compiler.CompileGlslToSpv( data.c_str(), data.size(), kind, name.c_str(), options); if (module.GetCompilationStatus() != shaderc_compilation_status_success) { std::cerr << module.GetErrorMessage(); } std::vector<uint32_t> result(module.cbegin(), module.cend()); return result; } </pre> <h2 id=”integrating”>Integrating into Your Projects</h2> <p> You can integrate the Vulkan shader compiler into your app using either the project's {@code Android.mk} file or Gradle. </p> <h3 id=”androidmk”>Android.mk</h3> <p> Perform the following steps to use your project's {@code Android.mk} file to integrate the shader compiler. </p> <ol> <li> Include the following lines in your Android.mk file: <pre class="no-pretty-print"> include $(CLEAR_VARS) ... LOCAL_STATIC_LIBRARIES := shaderc ... include $(BUILD_SHARED_LIBRARY) $(call import-module, third_party/shaderc) </pre> </li> <li> Set APP_STL to one of {@code c++_static}, {@code c++_shared}, {@code gnustl_static}, or {@code gnustl_shared}. </li> </ol> <h3 id=”gradle”>Gradle</h3> <ol> <li> In a terminal window, navigate to {@code <ndk_root>/sources/third_party/shaderc/}. </li> <li> Run the following command: <pre class="no-pretty-print"> $ ../../../ndk-build NDK_PROJECT_PATH=. APP_BUILD_SCRIPT=Android.mk \ APP_STL:=<stl_version> APP_ABI=all libshaderc_combined </pre> <p> This command places two folders in <ndk_root>/sources/third_party/shaderc/. The directory structure is as follows: </p> <pre class="no-pretty-print"> include/ shaderc/ shaderc.h shaderc.hpp libs/ <stl_version>/ {all of the abis} libshaderc.a </pre> </li> <li> Add includes and link lines as you normally would for external libraries. </li> <p> The STL that you use to build your program must match the {@code stl} specified in {@code stl_version}. Only {@code c++_static}, {@code c++_shared}, {@code gnustl_static}, and {@code gnustl_shared} are supported. </p>
