kc3-lang/angle/src/libANGLE/GLES1Renderer.cpp

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• Hash : 9c4c0926
  Author :
  Date : 2018-06-13T09:29:00
  

  Reland "GLES1: Point rasterization (partial implementation)"
  
  This is a reland of 4004ae0e033a0169de3cb53c0a036833ad47178a
  
  Fix: Put the missing early-out in ValidatePointParameterCommon
  
  Original change's description:
  > GLES1: Point rasterization (partial implementation)
  >
  > - Not included: Smooth points
  >
  > - GL_OES_point_sprite
  > - Update test expectations. Note: due to different random sampling,
  > edge cases were hit in UserClip. Disabling that test for now.
  >
  > BUG=angleproject:2306
  >
  > Change-Id: If8367bc3321804b3299d3bc381d6a8e236754baa
  > Reviewed-on: https://chromium-review.googlesource.com/1101910
  > Reviewed-by: Corentin Wallez <cwallez@chromium.org>
  > Commit-Queue: Lingfeng Yang <lfy@google.com>
  
  Bug: angleproject:2306
  Change-Id: Id8e71352a77ff0ce71cb604965effbfb8aca613e
  Reviewed-on: https://chromium-review.googlesource.com/1108458
  Reviewed-by: Corentin Wallez <cwallez@chromium.org>
  Commit-Queue: Lingfeng Yang <lfy@google.com>
  

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• src/libANGLE/GLES1Renderer.cpp

• //
  // Copyright 2018 The ANGLE Project Authors. All rights reserved.
  // Use of this source code is governed by a BSD-style license that can be
  // found in the LICENSE file.
  //
  
  // GLES1Renderer.cpp: Implements the GLES1Renderer renderer.
  
  #include "libANGLE/GLES1Renderer.h"
  
  #include <string.h>
  #include <iterator>
  #include <sstream>
  #include <vector>
  
  #include "libANGLE/Context.h"
  #include "libANGLE/Program.h"
  #include "libANGLE/ResourceManager.h"
  #include "libANGLE/Shader.h"
  #include "libANGLE/State.h"
  #include "libANGLE/renderer/ContextImpl.h"
  
  namespace
  {
  #include "libANGLE/GLES1Shaders.inc"
  }  // anonymous namespace
  
  namespace gl
  {
  
  GLES1Renderer::GLES1Renderer() : mRendererProgramInitialized(false)
  {
  }
  
  void GLES1Renderer::onDestroy(Context *context, State *state)
  {
      if (mRendererProgramInitialized)
      {
          state->setProgram(context, 0);
  
          mShaderPrograms->deleteProgram(context, mProgramState.program);
          mShaderPrograms->release(context);
          mShaderPrograms             = nullptr;
          mRendererProgramInitialized = false;
      }
  }
  
  GLES1Renderer::~GLES1Renderer() = default;
  
  Error GLES1Renderer::prepareForDraw(PrimitiveMode mode, Context *context, State *glState)
  {
      ANGLE_TRY(initializeRendererProgram(context, glState));
  
      const GLES1State &gles1State = glState->gles1();
  
      Program *programObject = getProgram(mProgramState.program);
  
      GLES1UniformBuffers &uniformBuffers = mUniformBuffers;
  
      if (!gles1State.isClientStateEnabled(ClientVertexArrayType::Normal))
      {
          const angle::Vector3 normal = gles1State.getCurrentNormal();
          context->vertexAttrib3f(kNormalAttribIndex, normal.x(), normal.y(), normal.z());
      }
  
      if (!gles1State.isClientStateEnabled(ClientVertexArrayType::Color))
      {
          const ColorF color = gles1State.getCurrentColor();
          context->vertexAttrib4f(kColorAttribIndex, color.red, color.green, color.blue, color.alpha);
      }
  
      if (!gles1State.isClientStateEnabled(ClientVertexArrayType::PointSize))
      {
          GLfloat pointSize = gles1State.mPointParameters.pointSize;
          context->vertexAttrib1f(kPointSizeAttribIndex, pointSize);
      }
  
      for (int i = 0; i < kTexUnitCount; i++)
      {
          if (!gles1State.mTexCoordArrayEnabled[i])
          {
              const TextureCoordF texcoord = gles1State.getCurrentTextureCoords(i);
              context->vertexAttrib4f(kTextureCoordAttribIndexBase + i, texcoord.s, texcoord.t,
                                      texcoord.r, texcoord.q);
          }
      }
  
      // Matrices
      {
          angle::Mat4 proj = gles1State.mProjectionMatrices.back();
          setUniformMatrix4fv(programObject, mProgramState.projMatrixLoc, 1, GL_FALSE, proj.data());
  
          angle::Mat4 modelview = gles1State.mModelviewMatrices.back();
          setUniformMatrix4fv(programObject, mProgramState.modelviewMatrixLoc, 1, GL_FALSE,
                              modelview.data());
  
          angle::Mat4 modelviewInvTr = modelview.transpose().inverse();
          setUniformMatrix4fv(programObject, mProgramState.modelviewInvTrLoc, 1, GL_FALSE,
                              modelviewInvTr.data());
  
          Mat4Uniform *textureMatrixBuffer = uniformBuffers.textureMatrices.data();
  
          for (int i = 0; i < kTexUnitCount; i++)
          {
              angle::Mat4 textureMatrix = gles1State.mTextureMatrices[i].back();
              memcpy(textureMatrixBuffer + i, textureMatrix.data(), sizeof(Mat4Uniform));
          }
  
          setUniformMatrix4fv(programObject, mProgramState.textureMatrixLoc, kTexUnitCount, GL_FALSE,
                              reinterpret_cast<float *>(uniformBuffers.textureMatrices.data()));
      }
  
      // Texturing
      {
          std::array<GLint, kTexUnitCount> &tex2DEnables   = uniformBuffers.tex2DEnables;
          std::array<GLint, kTexUnitCount> &texCubeEnables = uniformBuffers.texCubeEnables;
  
          std::vector<int> tex2DFormats = {GL_RGBA, GL_RGBA, GL_RGBA, GL_RGBA};
  
          for (int i = 0; i < kTexUnitCount; i++)
          {
              // GL_OES_cube_map allows only one of TEXTURE_2D / TEXTURE_CUBE_MAP
              // to be enabled per unit, thankfully. From the extension text:
              //
              //  --  Section 3.8.10 "Texture Application"
              //
              //      Replace the beginning sentences of the first paragraph (page 138)
              //      with:
              //
              //      "Texturing is enabled or disabled using the generic Enable
              //      and Disable commands, respectively, with the symbolic constants
              //      TEXTURE_2D or TEXTURE_CUBE_MAP_OES to enable the two-dimensional or cube
              //      map texturing respectively.  If the cube map texture and the two-
              //      dimensional texture are enabled, then cube map texturing is used.  If
              //      texturing is disabled, a rasterized fragment is passed on unaltered to the
              //      next stage of the GL (although its texture coordinates may be discarded).
              //      Otherwise, a texture value is found according to the parameter values of
              //      the currently bound texture image of the appropriate dimensionality.
  
              texCubeEnables[i] = gles1State.isTextureTargetEnabled(i, TextureType::CubeMap);
              tex2DEnables[i] =
                  !texCubeEnables[i] && (gles1State.isTextureTargetEnabled(i, TextureType::_2D));
  
              Texture *curr2DTexture = glState->getSamplerTexture(i, TextureType::_2D);
              if (curr2DTexture)
              {
                  tex2DFormats[i] = gl::GetUnsizedFormat(
                      curr2DTexture->getFormat(TextureTarget::_2D, 0).info->internalFormat);
              }
          }
  
          setUniform1iv(programObject, mProgramState.enableTexture2DLoc, kTexUnitCount,
                        tex2DEnables.data());
          setUniform1iv(programObject, mProgramState.enableTextureCubeMapLoc, kTexUnitCount,
                        texCubeEnables.data());
  
          setUniform1iv(programObject, mProgramState.textureFormatLoc, kTexUnitCount,
                        tex2DFormats.data());
  
          for (int i = 0; i < kTexUnitCount; i++)
          {
              const auto &env = gles1State.textureEnvironment(i);
  
              uniformBuffers.texEnvModes[i]      = ToGLenum(env.mode);
              uniformBuffers.texCombineRgbs[i]   = ToGLenum(env.combineRgb);
              uniformBuffers.texCombineAlphas[i] = ToGLenum(env.combineAlpha);
  
              uniformBuffers.texCombineSrc0Rgbs[i]   = ToGLenum(env.src0Rgb);
              uniformBuffers.texCombineSrc0Alphas[i] = ToGLenum(env.src0Alpha);
              uniformBuffers.texCombineSrc1Rgbs[i]   = ToGLenum(env.src1Rgb);
              uniformBuffers.texCombineSrc1Alphas[i] = ToGLenum(env.src1Alpha);
              uniformBuffers.texCombineSrc2Rgbs[i]   = ToGLenum(env.src2Rgb);
              uniformBuffers.texCombineSrc2Alphas[i] = ToGLenum(env.src2Alpha);
  
              uniformBuffers.texCombineOp0Rgbs[i]   = ToGLenum(env.op0Rgb);
              uniformBuffers.texCombineOp0Alphas[i] = ToGLenum(env.op0Alpha);
              uniformBuffers.texCombineOp1Rgbs[i]   = ToGLenum(env.op1Rgb);
              uniformBuffers.texCombineOp1Alphas[i] = ToGLenum(env.op1Alpha);
              uniformBuffers.texCombineOp2Rgbs[i]   = ToGLenum(env.op2Rgb);
              uniformBuffers.texCombineOp2Alphas[i] = ToGLenum(env.op2Alpha);
  
              uniformBuffers.texEnvColors[i][0] = env.color.red;
              uniformBuffers.texEnvColors[i][1] = env.color.green;
              uniformBuffers.texEnvColors[i][2] = env.color.blue;
              uniformBuffers.texEnvColors[i][3] = env.color.alpha;
  
              uniformBuffers.texEnvRgbScales[i]   = env.rgbScale;
              uniformBuffers.texEnvAlphaScales[i] = env.alphaScale;
  
              uniformBuffers.pointSpriteCoordReplaces[i] = env.pointSpriteCoordReplace;
          }
  
          setUniform1iv(programObject, mProgramState.textureEnvModeLoc, kTexUnitCount,
                        uniformBuffers.texEnvModes.data());
          setUniform1iv(programObject, mProgramState.combineRgbLoc, kTexUnitCount,
                        uniformBuffers.texCombineRgbs.data());
          setUniform1iv(programObject, mProgramState.combineAlphaLoc, kTexUnitCount,
                        uniformBuffers.texCombineAlphas.data());
  
          setUniform1iv(programObject, mProgramState.src0rgbLoc, kTexUnitCount,
                        uniformBuffers.texCombineSrc0Rgbs.data());
          setUniform1iv(programObject, mProgramState.src0alphaLoc, kTexUnitCount,
                        uniformBuffers.texCombineSrc0Alphas.data());
          setUniform1iv(programObject, mProgramState.src1rgbLoc, kTexUnitCount,
                        uniformBuffers.texCombineSrc1Rgbs.data());
          setUniform1iv(programObject, mProgramState.src1alphaLoc, kTexUnitCount,
                        uniformBuffers.texCombineSrc1Alphas.data());
          setUniform1iv(programObject, mProgramState.src2rgbLoc, kTexUnitCount,
                        uniformBuffers.texCombineSrc2Rgbs.data());
          setUniform1iv(programObject, mProgramState.src2alphaLoc, kTexUnitCount,
                        uniformBuffers.texCombineSrc2Alphas.data());
  
          setUniform1iv(programObject, mProgramState.op0rgbLoc, kTexUnitCount,
                        uniformBuffers.texCombineOp0Rgbs.data());
          setUniform1iv(programObject, mProgramState.op0alphaLoc, kTexUnitCount,
                        uniformBuffers.texCombineOp0Alphas.data());
          setUniform1iv(programObject, mProgramState.op1rgbLoc, kTexUnitCount,
                        uniformBuffers.texCombineOp1Rgbs.data());
          setUniform1iv(programObject, mProgramState.op1alphaLoc, kTexUnitCount,
                        uniformBuffers.texCombineOp1Alphas.data());
          setUniform1iv(programObject, mProgramState.op2rgbLoc, kTexUnitCount,
                        uniformBuffers.texCombineOp2Rgbs.data());
          setUniform1iv(programObject, mProgramState.op2alphaLoc, kTexUnitCount,
                        uniformBuffers.texCombineOp2Alphas.data());
  
          setUniform4fv(programObject, mProgramState.textureEnvColorLoc, kTexUnitCount,
                        reinterpret_cast<float *>(uniformBuffers.texEnvColors.data()));
          setUniform1fv(programObject, mProgramState.rgbScaleLoc, kTexUnitCount,
                        uniformBuffers.texEnvRgbScales.data());
          setUniform1fv(programObject, mProgramState.alphaScaleLoc, kTexUnitCount,
                        uniformBuffers.texEnvAlphaScales.data());
  
          setUniform1iv(programObject, mProgramState.pointSpriteCoordReplaceLoc, kTexUnitCount,
                        uniformBuffers.pointSpriteCoordReplaces.data());
      }
  
      // Alpha test
      {
          setUniform1i(programObject, mProgramState.enableAlphaTestLoc,
                       glState->getEnableFeature(GL_ALPHA_TEST));
          setUniform1i(programObject, mProgramState.alphaFuncLoc,
                       ToGLenum(gles1State.mAlphaTestFunc));
          setUniform1f(programObject, mProgramState.alphaTestRefLoc, gles1State.mAlphaTestRef);
      }
  
      // Shading, materials, and lighting
      {
          setUniform1i(programObject, mProgramState.shadeModelFlatLoc,
                       gles1State.mShadeModel == ShadingModel::Flat);
          setUniform1i(programObject, mProgramState.enableLightingLoc,
                       glState->getEnableFeature(GL_LIGHTING));
          setUniform1i(programObject, mProgramState.enableRescaleNormalLoc,
                       glState->getEnableFeature(GL_RESCALE_NORMAL));
          setUniform1i(programObject, mProgramState.enableNormalizeLoc,
                       glState->getEnableFeature(GL_NORMALIZE));
          setUniform1i(programObject, mProgramState.enableColorMaterialLoc,
                       glState->getEnableFeature(GL_COLOR_MATERIAL));
  
          const auto &material = gles1State.mMaterial;
  
          setUniform4fv(programObject, mProgramState.materialAmbientLoc, 1, material.ambient.data());
          setUniform4fv(programObject, mProgramState.materialDiffuseLoc, 1, material.diffuse.data());
          setUniform4fv(programObject, mProgramState.materialSpecularLoc, 1,
                        material.specular.data());
          setUniform4fv(programObject, mProgramState.materialEmissiveLoc, 1,
                        material.emissive.data());
          setUniform1f(programObject, mProgramState.materialSpecularExponentLoc,
                       material.specularExponent);
  
          const auto &lightModel = gles1State.mLightModel;
  
          setUniform4fv(programObject, mProgramState.lightModelSceneAmbientLoc, 1,
                        lightModel.color.data());
  
          // TODO (lfy@google.com): Implement two-sided lighting model
          // gl->uniform1i(mProgramState.lightModelTwoSidedLoc, lightModel.twoSided);
  
          for (int i = 0; i < kLightCount; i++)
          {
              const auto &light              = gles1State.mLights[i];
              uniformBuffers.lightEnables[i] = light.enabled;
              memcpy(uniformBuffers.lightAmbients.data() + i, light.ambient.data(),
                     sizeof(Vec4Uniform));
              memcpy(uniformBuffers.lightDiffuses.data() + i, light.diffuse.data(),
                     sizeof(Vec4Uniform));
              memcpy(uniformBuffers.lightSpeculars.data() + i, light.specular.data(),
                     sizeof(Vec4Uniform));
              memcpy(uniformBuffers.lightPositions.data() + i, light.position.data(),
                     sizeof(Vec4Uniform));
              memcpy(uniformBuffers.lightDirections.data() + i, light.direction.data(),
                     sizeof(Vec3Uniform));
              uniformBuffers.spotlightExponents[i]    = light.spotlightExponent;
              uniformBuffers.spotlightCutoffAngles[i] = light.spotlightCutoffAngle;
              uniformBuffers.attenuationConsts[i]     = light.attenuationConst;
              uniformBuffers.attenuationLinears[i]    = light.attenuationLinear;
              uniformBuffers.attenuationQuadratics[i] = light.attenuationQuadratic;
          }
  
          setUniform1iv(programObject, mProgramState.lightEnablesLoc, kLightCount,
                        uniformBuffers.lightEnables.data());
          setUniform4fv(programObject, mProgramState.lightAmbientsLoc, kLightCount,
                        reinterpret_cast<float *>(uniformBuffers.lightAmbients.data()));
          setUniform4fv(programObject, mProgramState.lightDiffusesLoc, kLightCount,
                        reinterpret_cast<float *>(uniformBuffers.lightDiffuses.data()));
          setUniform4fv(programObject, mProgramState.lightSpecularsLoc, kLightCount,
                        reinterpret_cast<float *>(uniformBuffers.lightSpeculars.data()));
          setUniform4fv(programObject, mProgramState.lightPositionsLoc, kLightCount,
                        reinterpret_cast<float *>(uniformBuffers.lightPositions.data()));
          setUniform3fv(programObject, mProgramState.lightDirectionsLoc, kLightCount,
                        reinterpret_cast<float *>(uniformBuffers.lightDirections.data()));
          setUniform1fv(programObject, mProgramState.lightSpotlightExponentsLoc, kLightCount,
                        reinterpret_cast<float *>(uniformBuffers.spotlightExponents.data()));
          setUniform1fv(programObject, mProgramState.lightSpotlightCutoffAnglesLoc, kLightCount,
                        reinterpret_cast<float *>(uniformBuffers.spotlightCutoffAngles.data()));
          setUniform1fv(programObject, mProgramState.lightAttenuationConstsLoc, kLightCount,
                        reinterpret_cast<float *>(uniformBuffers.attenuationConsts.data()));
          setUniform1fv(programObject, mProgramState.lightAttenuationLinearsLoc, kLightCount,
                        reinterpret_cast<float *>(uniformBuffers.attenuationLinears.data()));
          setUniform1fv(programObject, mProgramState.lightAttenuationQuadraticsLoc, kLightCount,
                        reinterpret_cast<float *>(uniformBuffers.attenuationQuadratics.data()));
      }
  
      // Fog
      {
          const FogParameters &fog = gles1State.fogParameters();
          setUniform1i(programObject, mProgramState.fogEnableLoc, glState->getEnableFeature(GL_FOG));
          setUniform1i(programObject, mProgramState.fogModeLoc, ToGLenum(fog.mode));
          setUniform1f(programObject, mProgramState.fogDensityLoc, fog.density);
          setUniform1f(programObject, mProgramState.fogStartLoc, fog.start);
          setUniform1f(programObject, mProgramState.fogEndLoc, fog.end);
          setUniform4fv(programObject, mProgramState.fogColorLoc, 1, fog.color.data());
      }
  
      // Clip planes
      {
          bool enableClipPlanes = false;
          for (int i = 0; i < kClipPlaneCount; i++)
          {
              uniformBuffers.clipPlaneEnables[i] = glState->getEnableFeature(GL_CLIP_PLANE0 + i);
              enableClipPlanes = enableClipPlanes || uniformBuffers.clipPlaneEnables[i];
              gles1State.getClipPlane(
                  i, reinterpret_cast<float *>(uniformBuffers.clipPlanes.data() + i));
          }
  
          setUniform1i(programObject, mProgramState.enableClipPlanesLoc, enableClipPlanes);
          setUniform1iv(programObject, mProgramState.clipPlaneEnablesLoc, kClipPlaneCount,
                        uniformBuffers.clipPlaneEnables.data());
          setUniform4fv(programObject, mProgramState.clipPlanesLoc, kClipPlaneCount,
                        reinterpret_cast<float *>(uniformBuffers.clipPlanes.data()));
      }
  
      // Point rasterization
      {
          const PointParameters &pointParams = gles1State.mPointParameters;
  
          setUniform1i(programObject, mProgramState.pointRasterizationLoc,
                       mode == PrimitiveMode::Points);
          setUniform1i(programObject, mProgramState.pointSpriteEnabledLoc,
                       glState->getEnableFeature(GL_POINT_SPRITE_OES));
          setUniform1f(programObject, mProgramState.pointSizeMinLoc, pointParams.pointSizeMin);
          setUniform1f(programObject, mProgramState.pointSizeMaxLoc, pointParams.pointSizeMax);
          setUniform3fv(programObject, mProgramState.pointDistanceAttenuationLoc, 1,
                        pointParams.pointDistanceAttenuation.data());
      }
  
      // None of those are changes in sampler, so there is no need to set the GL_PROGRAM dirty.
      // Otherwise, put the dirtying here.
  
      return NoError();
  }
  
  int GLES1Renderer::vertexArrayIndex(ClientVertexArrayType type, const State *glState) const
  {
      switch (type)
      {
          case ClientVertexArrayType::Vertex:
              return kVertexAttribIndex;
          case ClientVertexArrayType::Normal:
              return kNormalAttribIndex;
          case ClientVertexArrayType::Color:
              return kColorAttribIndex;
          case ClientVertexArrayType::PointSize:
              return kPointSizeAttribIndex;
          case ClientVertexArrayType::TextureCoord:
              return kTextureCoordAttribIndexBase + glState->gles1().getClientTextureUnit();
          default:
              UNREACHABLE();
              return 0;
      }
  }
  
  // static
  int GLES1Renderer::TexCoordArrayIndex(unsigned int unit)
  {
      return kTextureCoordAttribIndexBase + unit;
  }
  
  AttributesMask GLES1Renderer::getVertexArraysAttributeMask(const State *glState) const
  {
      AttributesMask res;
      const GLES1State &gles1 = glState->gles1();
  
      ClientVertexArrayType nonTexcoordArrays[] = {
          ClientVertexArrayType::Vertex, ClientVertexArrayType::Normal, ClientVertexArrayType::Color,
          ClientVertexArrayType::PointSize,
      };
  
      for (const ClientVertexArrayType attrib : nonTexcoordArrays)
      {
          res.set(vertexArrayIndex(attrib, glState), gles1.isClientStateEnabled(attrib));
      }
  
      for (unsigned int i = 0; i < kTexUnitCount; i++)
      {
          res.set(TexCoordArrayIndex(i), gles1.isTexCoordArrayEnabled(i));
      }
  
      return res;
  }
  
  Shader *GLES1Renderer::getShader(GLuint handle) const
  {
      return mShaderPrograms->getShader(handle);
  }
  
  Program *GLES1Renderer::getProgram(GLuint handle) const
  {
      return mShaderPrograms->getProgram(handle);
  }
  
  Error GLES1Renderer::compileShader(Context *context,
                                     ShaderType shaderType,
                                     const char *src,
                                     GLuint *shaderOut)
  {
      rx::ContextImpl *implementation = context->getImplementation();
      const Limitations &limitations  = implementation->getNativeLimitations();
  
      GLuint shader = mShaderPrograms->createShader(implementation, limitations, shaderType);
  
      Shader *shaderObject = getShader(shader);
  
      if (!shaderObject)
          return InternalError();
  
      shaderObject->setSource(1, &src, nullptr);
      shaderObject->compile(context);
  
      *shaderOut = shader;
  
      if (!shaderObject->isCompiled(context))
      {
          GLint infoLogLength = shaderObject->getInfoLogLength(context);
          std::vector<char> infoLog(infoLogLength, 0);
          shaderObject->getInfoLog(context, infoLogLength - 1, nullptr, infoLog.data());
          fprintf(stderr, "GLES1Renderer::%s: Info log: %s\n", __func__, infoLog.data());
          return InternalError() << "GLES1Renderer shader compile failed. Source: " << src
                                 << " Info log: " << infoLog.data();
      }
  
      return NoError();
  }
  
  Error GLES1Renderer::linkProgram(Context *context,
                                   State *glState,
                                   GLuint vertexShader,
                                   GLuint fragmentShader,
                                   const std::unordered_map<GLint, std::string> &attribLocs,
                                   GLuint *programOut)
  {
      GLuint program = mShaderPrograms->createProgram(context->getImplementation());
  
      Program *programObject = getProgram(program);
  
      if (!programObject)
      {
          return InternalError();
      }
  
      *programOut = program;
  
      programObject->attachShader(getShader(vertexShader));
      programObject->attachShader(getShader(fragmentShader));
  
      for (auto it : attribLocs)
      {
          GLint index             = it.first;
          const std::string &name = it.second;
          programObject->bindAttributeLocation(index, name.c_str());
      }
  
      ANGLE_TRY(programObject->link(context));
  
      glState->onProgramExecutableChange(programObject);
  
      if (!programObject->isLinked())
      {
          GLint infoLogLength = programObject->getInfoLogLength();
          std::vector<char> infoLog(infoLogLength, 0);
          programObject->getInfoLog(infoLogLength - 1, nullptr, infoLog.data());
          return InternalError() << "GLES1Renderer program link failed. Info log: " << infoLog.data();
      }
  
      programObject->detachShader(context, getShader(vertexShader));
      programObject->detachShader(context, getShader(fragmentShader));
  
      return NoError();
  }
  
  Error GLES1Renderer::initializeRendererProgram(Context *context, State *glState)
  {
      if (mRendererProgramInitialized)
      {
          return NoError();
      }
  
      mShaderPrograms = new ShaderProgramManager();
  
      GLuint vertexShader;
      GLuint fragmentShader;
  
      ANGLE_TRY(compileShader(context, ShaderType::Vertex, kGLES1DrawVShader, &vertexShader));
  
      std::stringstream fragmentStream;
      fragmentStream << kGLES1DrawFShaderHeader;
      fragmentStream << kGLES1DrawFShaderUniformDefs;
      fragmentStream << kGLES1DrawFShaderFunctions;
      fragmentStream << kGLES1DrawFShaderMultitexturing;
      fragmentStream << kGLES1DrawFShaderMain;
  
      ANGLE_TRY(compileShader(context, ShaderType::Fragment, fragmentStream.str().c_str(),
                              &fragmentShader));
  
      std::unordered_map<GLint, std::string> attribLocs;
  
      attribLocs[(GLint)kVertexAttribIndex]    = "pos";
      attribLocs[(GLint)kNormalAttribIndex]    = "normal";
      attribLocs[(GLint)kColorAttribIndex]     = "color";
      attribLocs[(GLint)kPointSizeAttribIndex] = "pointsize";
  
      for (int i = 0; i < kTexUnitCount; i++)
      {
          std::stringstream ss;
          ss << "texcoord" << i;
          attribLocs[kTextureCoordAttribIndexBase + i] = ss.str();
      }
  
      ANGLE_TRY(linkProgram(context, glState, vertexShader, fragmentShader, attribLocs,
                            &mProgramState.program));
  
      mShaderPrograms->deleteShader(context, vertexShader);
      mShaderPrograms->deleteShader(context, fragmentShader);
  
      Program *programObject = getProgram(mProgramState.program);
  
      mProgramState.projMatrixLoc      = programObject->getUniformLocation("projection");
      mProgramState.modelviewMatrixLoc = programObject->getUniformLocation("modelview");
      mProgramState.textureMatrixLoc   = programObject->getUniformLocation("texture_matrix");
      mProgramState.modelviewInvTrLoc  = programObject->getUniformLocation("modelview_invtr");
  
      for (int i = 0; i < kTexUnitCount; i++)
      {
          std::stringstream ss2d;
          std::stringstream sscube;
  
          ss2d << "tex_sampler" << i;
          sscube << "tex_cube_sampler" << i;
  
          mProgramState.tex2DSamplerLocs[i] = programObject->getUniformLocation(ss2d.str().c_str());
          mProgramState.texCubeSamplerLocs[i] =
              programObject->getUniformLocation(sscube.str().c_str());
      }
  
      mProgramState.enableTexture2DLoc = programObject->getUniformLocation("enable_texture_2d");
      mProgramState.enableTextureCubeMapLoc =
          programObject->getUniformLocation("enable_texture_cube_map");
  
      mProgramState.textureFormatLoc   = programObject->getUniformLocation("texture_format");
      mProgramState.textureEnvModeLoc  = programObject->getUniformLocation("texture_env_mode");
      mProgramState.combineRgbLoc      = programObject->getUniformLocation("combine_rgb");
      mProgramState.combineAlphaLoc    = programObject->getUniformLocation("combine_alpha");
      mProgramState.src0rgbLoc         = programObject->getUniformLocation("src0_rgb");
      mProgramState.src0alphaLoc       = programObject->getUniformLocation("src0_alpha");
      mProgramState.src1rgbLoc         = programObject->getUniformLocation("src1_rgb");
      mProgramState.src1alphaLoc       = programObject->getUniformLocation("src1_alpha");
      mProgramState.src2rgbLoc         = programObject->getUniformLocation("src2_rgb");
      mProgramState.src2alphaLoc       = programObject->getUniformLocation("src2_alpha");
      mProgramState.op0rgbLoc          = programObject->getUniformLocation("op0_rgb");
      mProgramState.op0alphaLoc        = programObject->getUniformLocation("op0_alpha");
      mProgramState.op1rgbLoc          = programObject->getUniformLocation("op1_rgb");
      mProgramState.op1alphaLoc        = programObject->getUniformLocation("op1_alpha");
      mProgramState.op2rgbLoc          = programObject->getUniformLocation("op2_rgb");
      mProgramState.op2alphaLoc        = programObject->getUniformLocation("op2_alpha");
      mProgramState.textureEnvColorLoc = programObject->getUniformLocation("texture_env_color");
      mProgramState.rgbScaleLoc        = programObject->getUniformLocation("texture_env_rgb_scale");
      mProgramState.alphaScaleLoc      = programObject->getUniformLocation("texture_env_alpha_scale");
      mProgramState.pointSpriteCoordReplaceLoc =
          programObject->getUniformLocation("point_sprite_coord_replace");
  
      mProgramState.enableAlphaTestLoc = programObject->getUniformLocation("enable_alpha_test");
      mProgramState.alphaFuncLoc       = programObject->getUniformLocation("alpha_func");
      mProgramState.alphaTestRefLoc    = programObject->getUniformLocation("alpha_test_ref");
  
      mProgramState.shadeModelFlatLoc = programObject->getUniformLocation("shade_model_flat");
      mProgramState.enableLightingLoc = programObject->getUniformLocation("enable_lighting");
      mProgramState.enableRescaleNormalLoc =
          programObject->getUniformLocation("enable_rescale_normal");
      mProgramState.enableNormalizeLoc = programObject->getUniformLocation("enable_normalize");
      mProgramState.enableColorMaterialLoc =
          programObject->getUniformLocation("enable_color_material");
  
      mProgramState.materialAmbientLoc  = programObject->getUniformLocation("material_ambient");
      mProgramState.materialDiffuseLoc  = programObject->getUniformLocation("material_diffuse");
      mProgramState.materialSpecularLoc = programObject->getUniformLocation("material_specular");
      mProgramState.materialEmissiveLoc = programObject->getUniformLocation("material_emissive");
      mProgramState.materialSpecularExponentLoc =
          programObject->getUniformLocation("material_specular_exponent");
  
      mProgramState.lightModelSceneAmbientLoc =
          programObject->getUniformLocation("light_model_scene_ambient");
      mProgramState.lightModelTwoSidedLoc =
          programObject->getUniformLocation("light_model_two_sided");
  
      mProgramState.lightEnablesLoc    = programObject->getUniformLocation("light_enables");
      mProgramState.lightAmbientsLoc   = programObject->getUniformLocation("light_ambients");
      mProgramState.lightDiffusesLoc   = programObject->getUniformLocation("light_diffuses");
      mProgramState.lightSpecularsLoc  = programObject->getUniformLocation("light_speculars");
      mProgramState.lightPositionsLoc  = programObject->getUniformLocation("light_positions");
      mProgramState.lightDirectionsLoc = programObject->getUniformLocation("light_directions");
      mProgramState.lightSpotlightExponentsLoc =
          programObject->getUniformLocation("light_spotlight_exponents");
      mProgramState.lightSpotlightCutoffAnglesLoc =
          programObject->getUniformLocation("light_spotlight_cutoff_angles");
      mProgramState.lightAttenuationConstsLoc =
          programObject->getUniformLocation("light_attenuation_consts");
      mProgramState.lightAttenuationLinearsLoc =
          programObject->getUniformLocation("light_attenuation_linears");
      mProgramState.lightAttenuationQuadraticsLoc =
          programObject->getUniformLocation("light_attenuation_quadratics");
  
      mProgramState.fogEnableLoc  = programObject->getUniformLocation("enable_fog");
      mProgramState.fogModeLoc    = programObject->getUniformLocation("fog_mode");
      mProgramState.fogDensityLoc = programObject->getUniformLocation("fog_density");
      mProgramState.fogStartLoc   = programObject->getUniformLocation("fog_start");
      mProgramState.fogEndLoc     = programObject->getUniformLocation("fog_end");
      mProgramState.fogColorLoc   = programObject->getUniformLocation("fog_color");
  
      mProgramState.enableClipPlanesLoc = programObject->getUniformLocation("enable_clip_planes");
      mProgramState.clipPlaneEnablesLoc = programObject->getUniformLocation("clip_plane_enables");
      mProgramState.clipPlanesLoc       = programObject->getUniformLocation("clip_planes");
  
      mProgramState.pointRasterizationLoc = programObject->getUniformLocation("point_rasterization");
      mProgramState.pointSizeMinLoc       = programObject->getUniformLocation("point_size_min");
      mProgramState.pointSizeMaxLoc       = programObject->getUniformLocation("point_size_max");
      mProgramState.pointDistanceAttenuationLoc =
          programObject->getUniformLocation("point_distance_attenuation");
      mProgramState.pointSpriteEnabledLoc = programObject->getUniformLocation("point_sprite_enabled");
  
      glState->setProgram(context, programObject);
  
      for (int i = 0; i < kTexUnitCount; i++)
      {
          setUniform1i(programObject, mProgramState.tex2DSamplerLocs[i], i);
          setUniform1i(programObject, mProgramState.texCubeSamplerLocs[i], i + kTexUnitCount);
      }
  
      glState->setObjectDirty(GL_PROGRAM);
  
      mRendererProgramInitialized = true;
      return NoError();
  }
  
  void GLES1Renderer::setUniform1i(Program *programObject, GLint loc, GLint value)
  {
      if (loc == -1)
          return;
      programObject->setUniform1iv(loc, 1, &value);
  }
  
  void GLES1Renderer::setUniform1iv(Program *programObject,
                                    GLint loc,
                                    GLint count,
                                    const GLint *value)
  {
      if (loc == -1)
          return;
      programObject->setUniform1iv(loc, count, value);
  }
  
  void GLES1Renderer::setUniformMatrix4fv(Program *programObject,
                                          GLint loc,
                                          GLint count,
                                          GLboolean transpose,
                                          const GLfloat *value)
  {
      if (loc == -1)
          return;
      programObject->setUniformMatrix4fv(loc, count, transpose, value);
  }
  
  void GLES1Renderer::setUniform4fv(Program *programObject,
                                    GLint loc,
                                    GLint count,
                                    const GLfloat *value)
  {
      if (loc == -1)
          return;
      programObject->setUniform4fv(loc, count, value);
  }
  
  void GLES1Renderer::setUniform3fv(Program *programObject,
                                    GLint loc,
                                    GLint count,
                                    const GLfloat *value)
  {
      if (loc == -1)
          return;
      programObject->setUniform3fv(loc, count, value);
  }
  
  void GLES1Renderer::setUniform1f(Program *programObject, GLint loc, GLfloat value)
  {
      if (loc == -1)
          return;
      programObject->setUniform1fv(loc, 1, &value);
  }
  
  void GLES1Renderer::setUniform1fv(Program *programObject,
                                    GLint loc,
                                    GLint count,
                                    const GLfloat *value)
  {
      if (loc == -1)
          return;
      programObject->setUniform1fv(loc, count, value);
  }
  
  }  // namespace gl
  

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