impeller/renderer/pipeline_builder.h - mirrors/engine - Git at Google

 // Copyright 2013 The Flutter Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef FLUTTER_IMPELLER_RENDERER_PIPELINE_BUILDER_H_
 #define FLUTTER_IMPELLER_RENDERER_PIPELINE_BUILDER_H_

 #include "flutter/fml/logging.h"
 #include "flutter/fml/macros.h"
 #include "impeller/base/strings.h"
 #include "impeller/base/validation.h"
 #include "impeller/core/formats.h"
 #include "impeller/renderer/context.h"
 #include "impeller/renderer/pipeline_descriptor.h"
 #include "impeller/renderer/shader_library.h"
 #include "impeller/renderer/vertex_descriptor.h"

 namespace impeller {

 //------------------------------------------------------------------------------
 /// @brief      An optional (but highly recommended) utility for creating
 ///             pipelines from reflected shader information.
 ///
 /// @tparam     VertexShader_    The reflected vertex shader information. Found
 ///                              in a generated header file called
 ///                              <shader_name>.vert.h.
 /// @tparam     FragmentShader_  The reflected fragment shader information.
 ///                              Found in a generated header file called
 ///                              <shader_name>.frag.h.
 ///
 template <class VertexShader_, class FragmentShader_>
 struct PipelineBuilder {
  public:
   using VertexShader = VertexShader_;
   using FragmentShader = FragmentShader_;

   static constexpr size_t kVertexBufferIndex =
       VertexDescriptor::kReservedVertexBufferIndex;

   //----------------------------------------------------------------------------
   /// @brief      Create a default pipeline descriptor using the combination
   ///             reflected shader information. The descriptor can be configured
   ///             further before a pipeline state object is created using it.
   ///
   /// @param[in]  context  The context
   ///
   /// @return     If the combination of reflected shader information is
   ///             compatible and the requisite functions can be found in the
   ///             context, a pipeline descriptor.
   ///
   static std::optional<PipelineDescriptor> MakeDefaultPipelineDescriptor(
       const Context& context,
       const std::vector<Scalar>& constants = {}) {
     PipelineDescriptor desc;
     desc.SetSpecializationConstants(constants);
     if (InitializePipelineDescriptorDefaults(context, desc)) {
       return {std::move(desc)};
     }
     return std::nullopt;
   }

   [[nodiscard]] static bool InitializePipelineDescriptorDefaults(
       const Context& context,
       PipelineDescriptor& desc) {
     // Setup debug instrumentation.
     desc.SetLabel(SPrintF("%s Pipeline", FragmentShader::kLabel.data()));

     // Resolve pipeline entrypoints.
     {
       auto vertex_function = context.GetShaderLibrary()->GetFunction(
           VertexShader::kEntrypointName, ShaderStage::kVertex);
       auto fragment_function = context.GetShaderLibrary()->GetFunction(
           FragmentShader::kEntrypointName, ShaderStage::kFragment);

       if (!vertex_function || !fragment_function) {
         VALIDATION_LOG << "Could not resolve pipeline entrypoint(s) '"
                        << VertexShader::kEntrypointName << "' and '"
                        << FragmentShader::kEntrypointName
                        << "' for pipeline named '" << VertexShader::kLabel
                        << "'.";
         return false;
       }

       desc.AddStageEntrypoint(std::move(vertex_function));
       desc.AddStageEntrypoint(std::move(fragment_function));
     }

     // Setup the vertex descriptor from reflected information.
     {
       auto vertex_descriptor = std::make_shared<VertexDescriptor>();
       vertex_descriptor->SetStageInputs(VertexShader::kAllShaderStageInputs,
                                         VertexShader::kInterleavedBufferLayout);
       vertex_descriptor->RegisterDescriptorSetLayouts(
           VertexShader::kDescriptorSetLayouts);
       vertex_descriptor->RegisterDescriptorSetLayouts(
           FragmentShader::kDescriptorSetLayouts);
       desc.SetVertexDescriptor(std::move(vertex_descriptor));
     }

     // Setup fragment shader output descriptions.
     {
       // Configure the sole color attachments pixel format. This is by
       // convention.
       ColorAttachmentDescriptor color0;
       color0.format = context.GetCapabilities()->GetDefaultColorFormat();
       color0.blending_enabled = true;
       desc.SetColorAttachmentDescriptor(0u, color0);
     }

     // Setup default depth buffer descriptions.
     {
       DepthAttachmentDescriptor depth0;
       depth0.depth_compare = CompareFunction::kAlways;
       desc.SetDepthStencilAttachmentDescriptor(depth0);
       desc.SetDepthPixelFormat(
           context.GetCapabilities()->GetDefaultDepthStencilFormat());
     }

     // Setup default stencil buffer descriptions.
     {
       StencilAttachmentDescriptor stencil0;
       stencil0.stencil_compare = CompareFunction::kEqual;
       desc.SetStencilAttachmentDescriptors(stencil0);
       desc.SetStencilPixelFormat(
           context.GetCapabilities()->GetDefaultDepthStencilFormat());
     }

     return true;
   }
 };

 }  // namespace impeller

 #endif  // FLUTTER_IMPELLER_RENDERER_PIPELINE_BUILDER_H_
	// Copyright 2013 The Flutter Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef FLUTTER_IMPELLER_RENDERER_PIPELINE_BUILDER_H_
	#define FLUTTER_IMPELLER_RENDERER_PIPELINE_BUILDER_H_

	#include "flutter/fml/logging.h"
	#include "flutter/fml/macros.h"
	#include "impeller/base/strings.h"
	#include "impeller/base/validation.h"
	#include "impeller/core/formats.h"
	#include "impeller/renderer/context.h"
	#include "impeller/renderer/pipeline_descriptor.h"
	#include "impeller/renderer/shader_library.h"
	#include "impeller/renderer/vertex_descriptor.h"

	namespace impeller {

	//------------------------------------------------------------------------------
	/// @brief An optional (but highly recommended) utility for creating
	/// pipelines from reflected shader information.
	///
	/// @tparam VertexShader_ The reflected vertex shader information. Found
	/// in a generated header file called
	/// <shader_name>.vert.h.
	/// @tparam FragmentShader_ The reflected fragment shader information.
	/// Found in a generated header file called
	/// <shader_name>.frag.h.
	///
	template <class VertexShader_, class FragmentShader_>
	struct PipelineBuilder {
	public:
	using VertexShader = VertexShader_;
	using FragmentShader = FragmentShader_;

	static constexpr size_t kVertexBufferIndex =
	VertexDescriptor::kReservedVertexBufferIndex;

	//----------------------------------------------------------------------------
	/// @brief Create a default pipeline descriptor using the combination
	/// reflected shader information. The descriptor can be configured
	/// further before a pipeline state object is created using it.
	///
	/// @param[in] context The context
	///
	/// @return If the combination of reflected shader information is
	/// compatible and the requisite functions can be found in the
	/// context, a pipeline descriptor.
	///
	static std::optional<PipelineDescriptor> MakeDefaultPipelineDescriptor(
	const Context& context,
	const std::vector<Scalar>& constants = {}) {
	PipelineDescriptor desc;
	desc.SetSpecializationConstants(constants);
	if (InitializePipelineDescriptorDefaults(context, desc)) {
	return {std::move(desc)};
	}
	return std::nullopt;
	}

	[[nodiscard]] static bool InitializePipelineDescriptorDefaults(
	const Context& context,
	PipelineDescriptor& desc) {
	// Setup debug instrumentation.
	desc.SetLabel(SPrintF("%s Pipeline", FragmentShader::kLabel.data()));

	// Resolve pipeline entrypoints.
	{
	auto vertex_function = context.GetShaderLibrary()->GetFunction(
	VertexShader::kEntrypointName, ShaderStage::kVertex);
	auto fragment_function = context.GetShaderLibrary()->GetFunction(
	FragmentShader::kEntrypointName, ShaderStage::kFragment);

	if (!vertex_function \|\| !fragment_function) {
	VALIDATION_LOG << "Could not resolve pipeline entrypoint(s) '"
	<< VertexShader::kEntrypointName << "' and '"
	<< FragmentShader::kEntrypointName
	<< "' for pipeline named '" << VertexShader::kLabel
	<< "'.";
	return false;
	}

	desc.AddStageEntrypoint(std::move(vertex_function));
	desc.AddStageEntrypoint(std::move(fragment_function));
	}

	// Setup the vertex descriptor from reflected information.
	{
	auto vertex_descriptor = std::make_shared<VertexDescriptor>();
	vertex_descriptor->SetStageInputs(VertexShader::kAllShaderStageInputs,
	VertexShader::kInterleavedBufferLayout);
	vertex_descriptor->RegisterDescriptorSetLayouts(
	VertexShader::kDescriptorSetLayouts);
	vertex_descriptor->RegisterDescriptorSetLayouts(
	FragmentShader::kDescriptorSetLayouts);
	desc.SetVertexDescriptor(std::move(vertex_descriptor));
	}

	// Setup fragment shader output descriptions.
	{
	// Configure the sole color attachments pixel format. This is by
	// convention.
	ColorAttachmentDescriptor color0;
	color0.format = context.GetCapabilities()->GetDefaultColorFormat();
	color0.blending_enabled = true;
	desc.SetColorAttachmentDescriptor(0u, color0);
	}

	// Setup default depth buffer descriptions.
	{
	DepthAttachmentDescriptor depth0;
	depth0.depth_compare = CompareFunction::kAlways;
	desc.SetDepthStencilAttachmentDescriptor(depth0);
	desc.SetDepthPixelFormat(
	context.GetCapabilities()->GetDefaultDepthStencilFormat());
	}

	// Setup default stencil buffer descriptions.
	{
	StencilAttachmentDescriptor stencil0;
	stencil0.stencil_compare = CompareFunction::kEqual;
	desc.SetStencilAttachmentDescriptors(stencil0);
	desc.SetStencilPixelFormat(
	context.GetCapabilities()->GetDefaultDepthStencilFormat());
	}

	return true;
	}
	};

	} // namespace impeller

	#endif // FLUTTER_IMPELLER_RENDERER_PIPELINE_BUILDER_H_