docs/html/ndk/guides/graphics/shader-compilers.jd - platform/frameworks/base - Gitiles

 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 &lt;iostream&gt;
 #include &lt;string&gt;
 #include &lt;vector&gt;
 #include &lt;shaderc/shaderc.hpp&gt;

 std::vector&lt;uint32_t&gt; 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&lt;uint32_t&gt; 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 &lt;ndk_root&gt;/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:=&lt;stl_version&gt; APP_ABI=all libshaderc_combined
 </pre>

 <p>
 This command places two folders in &lt;ndk_root&gt;/sources/third_party/shaderc/. The directory
 structure is as follows:
 </p>

 <pre class="no-pretty-print">
 include/
   shaderc/
     shaderc.h
     shaderc.hpp
 libs/
   &lt;stl_version&gt;/
     {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>
	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>