src/gpu/graphite/ContextUtils.cpp - skia - Git at Google

 /*
  * Copyright 2021 Google LLC
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/gpu/graphite/ContextUtils.h"

 #include <string>
 #include "include/private/SkSLString.h"
 #include "src/core/SkBlenderBase.h"
 #include "src/gpu/graphite/Caps.h"
 #include "src/gpu/graphite/GraphicsPipelineDesc.h"
 #include "src/gpu/graphite/KeyContext.h"
 #include "src/gpu/graphite/PaintParams.h"
 #include "src/gpu/graphite/PipelineData.h"
 #include "src/gpu/graphite/RecorderPriv.h"
 #include "src/gpu/graphite/Renderer.h"
 #include "src/gpu/graphite/ResourceProvider.h"
 #include "src/gpu/graphite/ShaderCodeDictionary.h"
 #include "src/gpu/graphite/UniformManager.h"
 #include "src/gpu/graphite/UniquePaintParamsID.h"

 namespace skgpu::graphite {

 std::tuple<UniquePaintParamsID, const UniformDataBlock*, const TextureDataBlock*>
 ExtractPaintData(Recorder* recorder,
                  PipelineDataGatherer* gatherer,
                  PaintParamsKeyBuilder* builder,
                  const Layout layout,
                  const SkM44& local2Dev,
                  const PaintParams& p,
                  const SkColorInfo& targetColorInfo) {
     SkDEBUGCODE(builder->checkReset());

     gatherer->resetWithNewLayout(layout);

     KeyContext keyContext(recorder, local2Dev, targetColorInfo, p.color());
     p.toKey(keyContext, builder, gatherer);

     auto dict = recorder->priv().shaderCodeDictionary();
     UniformDataCache* uniformDataCache = recorder->priv().uniformDataCache();
     TextureDataCache* textureDataCache = recorder->priv().textureDataCache();

     auto entry = dict->findOrCreate(builder);

     const UniformDataBlock* uniforms =
             gatherer->hasUniforms() ? uniformDataCache->insert(gatherer->finishUniformDataBlock())
                                     : nullptr;
     const TextureDataBlock* textures =
             gatherer->hasTextures() ? textureDataCache->insert(gatherer->textureDataBlock())
                                     : nullptr;

     return { entry->uniqueID(), uniforms, textures };
 }

 std::tuple<const UniformDataBlock*, const TextureDataBlock*> ExtractRenderStepData(
         UniformDataCache* uniformDataCache,
         TextureDataCache* textureDataCache,
         PipelineDataGatherer* gatherer,
         const Layout layout,
         const RenderStep* step,
         const DrawParams& params) {
     gatherer->resetWithNewLayout(layout);
     step->writeUniformsAndTextures(params, gatherer);

     const UniformDataBlock* uniforms =
             gatherer->hasUniforms() ? uniformDataCache->insert(gatherer->finishUniformDataBlock())
                                     : nullptr;
     const TextureDataBlock* textures =
             gatherer->hasTextures() ? textureDataCache->insert(gatherer->textureDataBlock())
                                     : nullptr;

     return { uniforms, textures };
 }

 namespace {
 std::string get_uniform_header(int bufferID, const char* name) {
     std::string result;

     SkSL::String::appendf(&result, "layout (binding=%d) uniform %sUniforms {\n", bufferID, name);

     return result;
 }

 std::string get_uniforms(Layout layout,
                          SkSpan<const Uniform> uniforms,
                          int* offset,
                          int manglingSuffix) {
     std::string result;
     UniformOffsetCalculator offsetter(layout, *offset);

     for (const Uniform& u : uniforms) {
         SkSL::String::appendf(&result,
                               "    layout(offset=%zu) %s %s",
                               offsetter.advanceOffset(u.type(), u.count()),
                               SkSLTypeString(u.type()),
                               u.name());
         if (manglingSuffix >= 0) {
             result.append("_");
             result.append(std::to_string(manglingSuffix));
         }
         if (u.count()) {
             result.append("[");
             result.append(std::to_string(u.count()));
             result.append("]");
         }
         result.append(";\n");
     }

     *offset = offsetter.size();
     return result;
 }
 }  // anonymous namespace

 std::string EmitPaintParamsUniforms(int bufferID,
                                     const char* name,
                                     const Layout layout,
                                     const std::vector<PaintParamsKey::BlockReader>& readers) {
     int offset = 0;

     std::string result = get_uniform_header(bufferID, name);
     for (int i = 0; i < (int) readers.size(); ++i) {
         SkSpan<const Uniform> uniforms = readers[i].entry()->fUniforms;

         if (!uniforms.empty()) {
             SkSL::String::appendf(&result, "// %s uniforms\n", readers[i].entry()->fName);
             result += get_uniforms(layout, uniforms, &offset, i);
         }
     }
     result.append("};\n\n");

     return result;
 }

 std::string EmitRenderStepUniforms(int bufferID,
                                    const char* name,
                                    const Layout layout,
                                    SkSpan<const Uniform> uniforms) {
     int offset = 0;

     std::string result = get_uniform_header(bufferID, name);
     result += get_uniforms(layout, uniforms, &offset, -1);
     result.append("};\n\n");

     return result;
 }

 std::string EmitPaintParamsStorageBuffer(
         int bufferID,
         const char* bufferTypePrefix,
         const char* bufferNamePrefix,
         const std::vector<PaintParamsKey::BlockReader>& readers) {

     std::string result;
     SkSL::String::appendf(&result, "struct %sUniformData {\n", bufferTypePrefix);
     for (int i = 0; i < (int)readers.size(); ++i) {
         SkSpan<const Uniform> uniforms = readers[i].entry()->fUniforms;
         if (uniforms.empty()) {
             continue;
         }
         SkSL::String::appendf(&result, "// %s uniforms\n", readers[i].entry()->fName);
         int manglingSuffix = i;
         for (const Uniform& u : uniforms) {
             SkSL::String::appendf(
                     &result, "    %s %s_%d", SkSLTypeString(u.type()), u.name(), manglingSuffix);
             if (u.count()) {
                 SkSL::String::appendf(&result, "[%u]", u.count());
             }
             result.append(";\n");
         }
     }
     result.append("};\n\n");

     SkSL::String::appendf(&result,
                           "layout (binding=%d) buffer %sUniforms {\n"
                           "    %sUniformData %sUniformData[];\n"
                           "};\n",
                           bufferID,
                           bufferTypePrefix,
                           bufferTypePrefix,
                           bufferNamePrefix);
     return result;
 }

 std::string EmitStorageBufferAccess(const char* bufferNamePrefix,
                                     const char* ssboIndex,
                                     const char* uniformName) {
     return SkSL::String::printf("%sUniformData[%s].%s", bufferNamePrefix, ssboIndex, uniformName);
 }

 std::string EmitTexturesAndSamplers(const ResourceBindingRequirements& bindingReqs,
                                     const std::vector<PaintParamsKey::BlockReader>& readers,
                                     int* binding) {
     std::string result;
     for (int i = 0; i < (int) readers.size(); ++i) {
         SkSpan<const TextureAndSampler> samplers = readers[i].entry()->fTexturesAndSamplers;

         if (!samplers.empty()) {
             SkSL::String::appendf(&result, "// %s samplers\n", readers[i].entry()->fName);

             for (const TextureAndSampler& t : samplers) {
                 result += EmitSamplerLayout(bindingReqs, binding);
                 SkSL::String::appendf(&result, " uniform sampler2D %s_%d;\n", t.name(), i);
             }
         }
     }

     return result;
 }

 std::string EmitSamplerLayout(const ResourceBindingRequirements& bindingReqs, int* binding) {
     std::string result;

     // If fDistinctIndexRanges is false, then texture and sampler indices may clash with other
     // resource indices. Graphite assumes that they will be placed in descriptor set (Vulkan) and
     // bind group (Dawn) index 1.
     if (bindingReqs.fSeparateTextureAndSamplerBinding) {
         int samplerIndex = (*binding)++;
         int textureIndex = (*binding)++;
         SkSL::String::appendf(&result,
                               "layout(wgsl, %ssampler=%d, texture=%d)",
                               bindingReqs.fDistinctIndexRanges ? "" : "set=1, ",
                               samplerIndex,
                               textureIndex);
     } else {
         SkSL::String::appendf(&result,
                               "layout(%sbinding=%d)",
                               bindingReqs.fDistinctIndexRanges ? "" : "set=1, ",
                               *binding);
         (*binding)++;
     }
     return result;
 }

 namespace {
 std::string emit_attributes(SkSpan<const Attribute> vertexAttrs,
                             SkSpan<const Attribute> instanceAttrs) {
     std::string result;

     int attr = 0;
     auto add_attrs = [&](SkSpan<const Attribute> attrs) {
         for (auto a : attrs) {
             SkSL::String::appendf(&result, "    layout(location=%d) in ", attr++);
             result.append(SkSLTypeString(a.gpuType()));
             SkSL::String::appendf(&result, " %s;\n", a.name());
         }
     };

     if (!vertexAttrs.empty()) {
         result.append("// vertex attrs\n");
         add_attrs(vertexAttrs);
     }
     if (!instanceAttrs.empty()) {
         result.append("// instance attrs\n");
         add_attrs(instanceAttrs);
     }

     return result;
 }
 }  // anonymous namespace

 std::string EmitVaryings(const RenderStep* step,
                          const char* direction,
                          bool emitShadingSsboIndexVarying,
                          bool emitLocalCoordsVarying) {
     std::string result;
     int location = 0;

     if (emitShadingSsboIndexVarying) {
         SkSL::String::appendf(&result,
                               "    layout(location=%d) %s int shadingSsboIndexVar;\n",
                               location++,
                               direction);
     }

     if (emitLocalCoordsVarying) {
         SkSL::String::appendf(&result, "    layout(location=%d) %s ", location++, direction);
         result.append(SkSLTypeString(SkSLType::kFloat2));
         SkSL::String::appendf(&result, " localCoordsVar;\n");
     }

     for (auto v : step->varyings()) {
         SkSL::String::appendf(&result, "    layout(location=%d) %s ", location++, direction);
         result.append(SkSLTypeString(v.fType));
         SkSL::String::appendf(&result, " %s;\n", v.fName);
     }

     return result;
 }

 std::string GetSkSLVS(const ResourceBindingRequirements& bindingReqs,
                       const RenderStep* step,
                       bool defineShadingSsboIndexVarying,
                       bool defineLocalCoordsVarying) {
     // TODO: To more completely support end-to-end rendering, this will need to be updated so that
     // the RenderStep shader snippet can produce a device coord, a local coord, and depth.
     // If the paint combination doesn't need the local coord it can be ignored, otherwise we need
     // a varying for it. The fragment function's output will need to be updated to have a color and
     // the depth, or when there's no combination, just the depth. Lastly, we also should add the
     // static/intrinsic uniform binding point so that we can handle normalizing the device position
     // produced by the RenderStep automatically.

     // Fixed program header
     std::string sksl =
         "layout (binding=0) uniform intrinsicUniforms {\n"
         "    layout(offset=0) float4 rtAdjust;\n"
         "};\n"
         "\n";

     if (step->numVertexAttributes() > 0 || step->numInstanceAttributes() > 0) {
         sksl += emit_attributes(step->vertexAttributes(), step->instanceAttributes());
     }

     // Uniforms needed by RenderStep
     // The uniforms are mangled by having their index in 'fEntries' as a suffix (i.e., "_%d")
     // TODO: replace hard-coded bufferID with the backend's renderstep uniform-buffer index.
     if (step->numUniforms() > 0) {
         sksl += EmitRenderStepUniforms(
                 1, "Step", bindingReqs.fUniformBufferLayout, step->uniforms());
     }

     // Varyings needed by RenderStep
     sksl += EmitVaryings(step, "out", defineShadingSsboIndexVarying, defineLocalCoordsVarying);

     // Vertex shader function declaration
     sksl += "void main() {";
     // Create stepLocalCoords which render steps can write to.
     sksl += "float2 stepLocalCoords = float2(0);";
     // Vertex shader body
     sksl += step->vertexSkSL();
     sksl += "sk_Position = float4(devPosition.xy * rtAdjust.xy + devPosition.ww * rtAdjust.zw,"
             "devPosition.zw);";

     if (defineShadingSsboIndexVarying) {
         // Assign SSBO index value to the SSBO index varying
         SkSL::String::appendf(&sksl, "shadingSsboIndexVar = %s;", step->ssboIndex());
     }

     if (defineLocalCoordsVarying) {
         // Assign Render Step's stepLocalCoords to the localCoordsVar varying.
         sksl += "localCoordsVar = stepLocalCoords;";
     }
     sksl += "}";

     return sksl;
 }

 FragSkSLInfo GetSkSLFS(const ResourceBindingRequirements& bindingReqs,
                       const ShaderCodeDictionary* dict,
                       const RuntimeEffectDictionary* rteDict,
                       const RenderStep* step,
                       UniquePaintParamsID paintID,
                       bool useStorageBuffers) {
     if (!paintID.isValid()) {
         // TODO: we should return the error shader code here
         return {};
     }

     FragSkSLInfo result;

     const char* shadingSsboIndexVar = useStorageBuffers ? "shadingSsboIndexVar" : nullptr;
     ShaderInfo shaderInfo(rteDict, shadingSsboIndexVar);

     dict->getShaderInfo(paintID, &shaderInfo);
     result.fBlendInfo = shaderInfo.blendInfo();
     result.fRequiresLocalCoords = shaderInfo.needsLocalCoords();

     // Extra RenderStep uniforms are always backed by a UBO. Uniforms for the PaintParams are either
     // UBO or SSBO backed based on `useStorageBuffers`.
     result.fSkSL =
             shaderInfo.toSkSL(bindingReqs,
                               step,
                               useStorageBuffers,
                               /*defineLocalCoordsVarying=*/result.fRequiresLocalCoords,
                               /*numTexturesAndSamplersUsed=*/&result.fNumTexturesAndSamplers);

     return result;
 }

 } // namespace skgpu::graphite
	/*
	* Copyright 2021 Google LLC
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/gpu/graphite/ContextUtils.h"

	#include <string>
	#include "include/private/SkSLString.h"
	#include "src/core/SkBlenderBase.h"
	#include "src/gpu/graphite/Caps.h"
	#include "src/gpu/graphite/GraphicsPipelineDesc.h"
	#include "src/gpu/graphite/KeyContext.h"
	#include "src/gpu/graphite/PaintParams.h"
	#include "src/gpu/graphite/PipelineData.h"
	#include "src/gpu/graphite/RecorderPriv.h"
	#include "src/gpu/graphite/Renderer.h"
	#include "src/gpu/graphite/ResourceProvider.h"
	#include "src/gpu/graphite/ShaderCodeDictionary.h"
	#include "src/gpu/graphite/UniformManager.h"
	#include "src/gpu/graphite/UniquePaintParamsID.h"

	namespace skgpu::graphite {

	std::tuple<UniquePaintParamsID, const UniformDataBlock, const TextureDataBlock>
	ExtractPaintData(Recorder* recorder,
	PipelineDataGatherer* gatherer,
	PaintParamsKeyBuilder* builder,
	const Layout layout,
	const SkM44& local2Dev,
	const PaintParams& p,
	const SkColorInfo& targetColorInfo) {
	SkDEBUGCODE(builder->checkReset());

	gatherer->resetWithNewLayout(layout);

	KeyContext keyContext(recorder, local2Dev, targetColorInfo, p.color());
	p.toKey(keyContext, builder, gatherer);

	auto dict = recorder->priv().shaderCodeDictionary();
	UniformDataCache* uniformDataCache = recorder->priv().uniformDataCache();
	TextureDataCache* textureDataCache = recorder->priv().textureDataCache();

	auto entry = dict->findOrCreate(builder);

	const UniformDataBlock* uniforms =
	gatherer->hasUniforms() ? uniformDataCache->insert(gatherer->finishUniformDataBlock())
	: nullptr;
	const TextureDataBlock* textures =
	gatherer->hasTextures() ? textureDataCache->insert(gatherer->textureDataBlock())
	: nullptr;

	return { entry->uniqueID(), uniforms, textures };
	}

	std::tuple<const UniformDataBlock, const TextureDataBlock> ExtractRenderStepData(
	UniformDataCache* uniformDataCache,
	TextureDataCache* textureDataCache,
	PipelineDataGatherer* gatherer,
	const Layout layout,
	const RenderStep* step,
	const DrawParams& params) {
	gatherer->resetWithNewLayout(layout);
	step->writeUniformsAndTextures(params, gatherer);

	const UniformDataBlock* uniforms =
	gatherer->hasUniforms() ? uniformDataCache->insert(gatherer->finishUniformDataBlock())
	: nullptr;
	const TextureDataBlock* textures =
	gatherer->hasTextures() ? textureDataCache->insert(gatherer->textureDataBlock())
	: nullptr;

	return { uniforms, textures };
	}

	namespace {
	std::string get_uniform_header(int bufferID, const char* name) {
	std::string result;

	SkSL::String::appendf(&result, "layout (binding=%d) uniform %sUniforms {\n", bufferID, name);

	return result;
	}

	std::string get_uniforms(Layout layout,
	SkSpan<const Uniform> uniforms,
	int* offset,
	int manglingSuffix) {
	std::string result;
	UniformOffsetCalculator offsetter(layout, *offset);

	for (const Uniform& u : uniforms) {
	SkSL::String::appendf(&result,
	" layout(offset=%zu) %s %s",
	offsetter.advanceOffset(u.type(), u.count()),
	SkSLTypeString(u.type()),
	u.name());
	if (manglingSuffix >= 0) {
	result.append("_");
	result.append(std::to_string(manglingSuffix));
	}
	if (u.count()) {
	result.append("[");
	result.append(std::to_string(u.count()));
	result.append("]");
	}
	result.append(";\n");
	}

	*offset = offsetter.size();
	return result;
	}
	} // anonymous namespace

	std::string EmitPaintParamsUniforms(int bufferID,
	const char* name,
	const Layout layout,
	const std::vector<PaintParamsKey::BlockReader>& readers) {
	int offset = 0;

	std::string result = get_uniform_header(bufferID, name);
	for (int i = 0; i < (int) readers.size(); ++i) {
	SkSpan<const Uniform> uniforms = readers[i].entry()->fUniforms;

	if (!uniforms.empty()) {
	SkSL::String::appendf(&result, "// %s uniforms\n", readers[i].entry()->fName);
	result += get_uniforms(layout, uniforms, &offset, i);
	}
	}
	result.append("};\n\n");

	return result;
	}

	std::string EmitRenderStepUniforms(int bufferID,
	const char* name,
	const Layout layout,
	SkSpan<const Uniform> uniforms) {
	int offset = 0;

	std::string result = get_uniform_header(bufferID, name);
	result += get_uniforms(layout, uniforms, &offset, -1);
	result.append("};\n\n");

	return result;
	}

	std::string EmitPaintParamsStorageBuffer(
	int bufferID,
	const char* bufferTypePrefix,
	const char* bufferNamePrefix,
	const std::vector<PaintParamsKey::BlockReader>& readers) {

	std::string result;
	SkSL::String::appendf(&result, "struct %sUniformData {\n", bufferTypePrefix);
	for (int i = 0; i < (int)readers.size(); ++i) {
	SkSpan<const Uniform> uniforms = readers[i].entry()->fUniforms;
	if (uniforms.empty()) {
	continue;
	}
	SkSL::String::appendf(&result, "// %s uniforms\n", readers[i].entry()->fName);
	int manglingSuffix = i;
	for (const Uniform& u : uniforms) {
	SkSL::String::appendf(
	&result, " %s %s_%d", SkSLTypeString(u.type()), u.name(), manglingSuffix);
	if (u.count()) {
	SkSL::String::appendf(&result, "[%u]", u.count());
	}
	result.append(";\n");
	}
	}
	result.append("};\n\n");

	SkSL::String::appendf(&result,
	"layout (binding=%d) buffer %sUniforms {\n"
	" %sUniformData %sUniformData[];\n"
	"};\n",
	bufferID,
	bufferTypePrefix,
	bufferTypePrefix,
	bufferNamePrefix);
	return result;
	}

	std::string EmitStorageBufferAccess(const char* bufferNamePrefix,
	const char* ssboIndex,
	const char* uniformName) {
	return SkSL::String::printf("%sUniformData[%s].%s", bufferNamePrefix, ssboIndex, uniformName);
	}

	std::string EmitTexturesAndSamplers(const ResourceBindingRequirements& bindingReqs,
	const std::vector<PaintParamsKey::BlockReader>& readers,
	int* binding) {
	std::string result;
	for (int i = 0; i < (int) readers.size(); ++i) {
	SkSpan<const TextureAndSampler> samplers = readers[i].entry()->fTexturesAndSamplers;

	if (!samplers.empty()) {
	SkSL::String::appendf(&result, "// %s samplers\n", readers[i].entry()->fName);

	for (const TextureAndSampler& t : samplers) {
	result += EmitSamplerLayout(bindingReqs, binding);
	SkSL::String::appendf(&result, " uniform sampler2D %s_%d;\n", t.name(), i);
	}
	}
	}

	return result;
	}

	std::string EmitSamplerLayout(const ResourceBindingRequirements& bindingReqs, int* binding) {
	std::string result;

	// If fDistinctIndexRanges is false, then texture and sampler indices may clash with other
	// resource indices. Graphite assumes that they will be placed in descriptor set (Vulkan) and
	// bind group (Dawn) index 1.
	if (bindingReqs.fSeparateTextureAndSamplerBinding) {
	int samplerIndex = (*binding)++;
	int textureIndex = (*binding)++;
	SkSL::String::appendf(&result,
	"layout(wgsl, %ssampler=%d, texture=%d)",
	bindingReqs.fDistinctIndexRanges ? "" : "set=1, ",
	samplerIndex,
	textureIndex);
	} else {
	SkSL::String::appendf(&result,
	"layout(%sbinding=%d)",
	bindingReqs.fDistinctIndexRanges ? "" : "set=1, ",
	*binding);
	(*binding)++;
	}
	return result;
	}

	namespace {
	std::string emit_attributes(SkSpan<const Attribute> vertexAttrs,
	SkSpan<const Attribute> instanceAttrs) {
	std::string result;

	int attr = 0;
	auto add_attrs = [&](SkSpan<const Attribute> attrs) {
	for (auto a : attrs) {
	SkSL::String::appendf(&result, " layout(location=%d) in ", attr++);
	result.append(SkSLTypeString(a.gpuType()));
	SkSL::String::appendf(&result, " %s;\n", a.name());
	}
	};

	if (!vertexAttrs.empty()) {
	result.append("// vertex attrs\n");
	add_attrs(vertexAttrs);
	}
	if (!instanceAttrs.empty()) {
	result.append("// instance attrs\n");
	add_attrs(instanceAttrs);
	}

	return result;
	}
	} // anonymous namespace

	std::string EmitVaryings(const RenderStep* step,
	const char* direction,
	bool emitShadingSsboIndexVarying,
	bool emitLocalCoordsVarying) {
	std::string result;
	int location = 0;

	if (emitShadingSsboIndexVarying) {
	SkSL::String::appendf(&result,
	" layout(location=%d) %s int shadingSsboIndexVar;\n",
	location++,
	direction);
	}

	if (emitLocalCoordsVarying) {
	SkSL::String::appendf(&result, " layout(location=%d) %s ", location++, direction);
	result.append(SkSLTypeString(SkSLType::kFloat2));
	SkSL::String::appendf(&result, " localCoordsVar;\n");
	}

	for (auto v : step->varyings()) {
	SkSL::String::appendf(&result, " layout(location=%d) %s ", location++, direction);
	result.append(SkSLTypeString(v.fType));
	SkSL::String::appendf(&result, " %s;\n", v.fName);
	}

	return result;
	}

	std::string GetSkSLVS(const ResourceBindingRequirements& bindingReqs,
	const RenderStep* step,
	bool defineShadingSsboIndexVarying,
	bool defineLocalCoordsVarying) {
	// TODO: To more completely support end-to-end rendering, this will need to be updated so that
	// the RenderStep shader snippet can produce a device coord, a local coord, and depth.
	// If the paint combination doesn't need the local coord it can be ignored, otherwise we need
	// a varying for it. The fragment function's output will need to be updated to have a color and
	// the depth, or when there's no combination, just the depth. Lastly, we also should add the
	// static/intrinsic uniform binding point so that we can handle normalizing the device position
	// produced by the RenderStep automatically.

	// Fixed program header
	std::string sksl =
	"layout (binding=0) uniform intrinsicUniforms {\n"
	" layout(offset=0) float4 rtAdjust;\n"
	"};\n"
	"\n";

	if (step->numVertexAttributes() > 0 \|\| step->numInstanceAttributes() > 0) {
	sksl += emit_attributes(step->vertexAttributes(), step->instanceAttributes());
	}

	// Uniforms needed by RenderStep
	// The uniforms are mangled by having their index in 'fEntries' as a suffix (i.e., "_%d")
	// TODO: replace hard-coded bufferID with the backend's renderstep uniform-buffer index.
	if (step->numUniforms() > 0) {
	sksl += EmitRenderStepUniforms(
	1, "Step", bindingReqs.fUniformBufferLayout, step->uniforms());
	}

	// Varyings needed by RenderStep
	sksl += EmitVaryings(step, "out", defineShadingSsboIndexVarying, defineLocalCoordsVarying);

	// Vertex shader function declaration
	sksl += "void main() {";
	// Create stepLocalCoords which render steps can write to.
	sksl += "float2 stepLocalCoords = float2(0);";
	// Vertex shader body
	sksl += step->vertexSkSL();
	sksl += "sk_Position = float4(devPosition.xy * rtAdjust.xy + devPosition.ww * rtAdjust.zw,"
	"devPosition.zw);";

	if (defineShadingSsboIndexVarying) {
	// Assign SSBO index value to the SSBO index varying
	SkSL::String::appendf(&sksl, "shadingSsboIndexVar = %s;", step->ssboIndex());
	}

	if (defineLocalCoordsVarying) {
	// Assign Render Step's stepLocalCoords to the localCoordsVar varying.
	sksl += "localCoordsVar = stepLocalCoords;";
	}
	sksl += "}";

	return sksl;
	}

	FragSkSLInfo GetSkSLFS(const ResourceBindingRequirements& bindingReqs,
	const ShaderCodeDictionary* dict,
	const RuntimeEffectDictionary* rteDict,
	const RenderStep* step,
	UniquePaintParamsID paintID,
	bool useStorageBuffers) {
	if (!paintID.isValid()) {
	// TODO: we should return the error shader code here
	return {};
	}

	FragSkSLInfo result;

	const char* shadingSsboIndexVar = useStorageBuffers ? "shadingSsboIndexVar" : nullptr;
	ShaderInfo shaderInfo(rteDict, shadingSsboIndexVar);

	dict->getShaderInfo(paintID, &shaderInfo);
	result.fBlendInfo = shaderInfo.blendInfo();
	result.fRequiresLocalCoords = shaderInfo.needsLocalCoords();

	// Extra RenderStep uniforms are always backed by a UBO. Uniforms for the PaintParams are either
	// UBO or SSBO backed based on `useStorageBuffers`.
	result.fSkSL =
	shaderInfo.toSkSL(bindingReqs,
	step,
	useStorageBuffers,
	/defineLocalCoordsVarying=/result.fRequiresLocalCoords,
	/numTexturesAndSamplersUsed=/&result.fNumTexturesAndSamplers);

	return result;
	}

	} // namespace skgpu::graphite