// // Copyright 2015 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. // #include "test_utils/ANGLETest.h" #include "test_utils/gl_raii.h" using namespace angle; namespace { class GLSLTest : public ANGLETest { protected: GLSLTest() { setWindowWidth(128); setWindowHeight(128); setConfigRedBits(8); setConfigGreenBits(8); setConfigBlueBits(8); setConfigAlphaBits(8); } virtual void SetUp() { ANGLETest::SetUp(); mSimpleVSSource = R"(attribute vec4 inputAttribute; void main() { gl_Position = inputAttribute; })"; } std::string GenerateVaryingType(GLint vectorSize) { char varyingType[10]; if (vectorSize == 1) { sprintf(varyingType, "float"); } else { sprintf(varyingType, "vec%d", vectorSize); } return std::string(varyingType); } std::string GenerateVectorVaryingDeclaration(GLint vectorSize, GLint arraySize, GLint id) { char buff[100]; if (arraySize == 1) { sprintf(buff, "varying %s v%d;\n", GenerateVaryingType(vectorSize).c_str(), id); } else { sprintf(buff, "varying %s v%d[%d];\n", GenerateVaryingType(vectorSize).c_str(), id, arraySize); } return std::string(buff); } std::string GenerateVectorVaryingSettingCode(GLint vectorSize, GLint arraySize, GLint id) { std::string returnString; char buff[100]; if (arraySize == 1) { sprintf(buff, "\t v%d = %s(1.0);\n", id, GenerateVaryingType(vectorSize).c_str()); returnString += buff; } else { for (int i = 0; i < arraySize; i++) { sprintf(buff, "\t v%d[%d] = %s(1.0);\n", id, i, GenerateVaryingType(vectorSize).c_str()); returnString += buff; } } return returnString; } std::string GenerateVectorVaryingUseCode(GLint arraySize, GLint id) { if (arraySize == 1) { char buff[100]; sprintf(buff, "v%d + ", id); return std::string(buff); } else { std::string returnString; for (int i = 0; i < arraySize; i++) { char buff[100]; sprintf(buff, "v%d[%d] + ", id, i); returnString += buff; } return returnString; } } void GenerateGLSLWithVaryings(GLint floatCount, GLint floatArrayCount, GLint vec2Count, GLint vec2ArrayCount, GLint vec3Count, GLint vec3ArrayCount, GLint vec4Count, GLint vec4ArrayCount, bool useFragCoord, bool usePointCoord, bool usePointSize, std::string* fragmentShader, std::string* vertexShader) { // Generate a string declaring the varyings, to share between the fragment shader and the vertex shader. std::string varyingDeclaration; unsigned int varyingCount = 0; for (GLint i = 0; i < floatCount; i++) { varyingDeclaration += GenerateVectorVaryingDeclaration(1, 1, varyingCount); varyingCount += 1; } for (GLint i = 0; i < floatArrayCount; i++) { varyingDeclaration += GenerateVectorVaryingDeclaration(1, 2, varyingCount); varyingCount += 1; } for (GLint i = 0; i < vec2Count; i++) { varyingDeclaration += GenerateVectorVaryingDeclaration(2, 1, varyingCount); varyingCount += 1; } for (GLint i = 0; i < vec2ArrayCount; i++) { varyingDeclaration += GenerateVectorVaryingDeclaration(2, 2, varyingCount); varyingCount += 1; } for (GLint i = 0; i < vec3Count; i++) { varyingDeclaration += GenerateVectorVaryingDeclaration(3, 1, varyingCount); varyingCount += 1; } for (GLint i = 0; i < vec3ArrayCount; i++) { varyingDeclaration += GenerateVectorVaryingDeclaration(3, 2, varyingCount); varyingCount += 1; } for (GLint i = 0; i < vec4Count; i++) { varyingDeclaration += GenerateVectorVaryingDeclaration(4, 1, varyingCount); varyingCount += 1; } for (GLint i = 0; i < vec4ArrayCount; i++) { varyingDeclaration += GenerateVectorVaryingDeclaration(4, 2, varyingCount); varyingCount += 1; } // Generate the vertex shader vertexShader->clear(); vertexShader->append(varyingDeclaration); vertexShader->append("\nvoid main()\n{\n"); unsigned int currentVSVarying = 0; for (GLint i = 0; i < floatCount; i++) { vertexShader->append(GenerateVectorVaryingSettingCode(1, 1, currentVSVarying)); currentVSVarying += 1; } for (GLint i = 0; i < floatArrayCount; i++) { vertexShader->append(GenerateVectorVaryingSettingCode(1, 2, currentVSVarying)); currentVSVarying += 1; } for (GLint i = 0; i < vec2Count; i++) { vertexShader->append(GenerateVectorVaryingSettingCode(2, 1, currentVSVarying)); currentVSVarying += 1; } for (GLint i = 0; i < vec2ArrayCount; i++) { vertexShader->append(GenerateVectorVaryingSettingCode(2, 2, currentVSVarying)); currentVSVarying += 1; } for (GLint i = 0; i < vec3Count; i++) { vertexShader->append(GenerateVectorVaryingSettingCode(3, 1, currentVSVarying)); currentVSVarying += 1; } for (GLint i = 0; i < vec3ArrayCount; i++) { vertexShader->append(GenerateVectorVaryingSettingCode(3, 2, currentVSVarying)); currentVSVarying += 1; } for (GLint i = 0; i < vec4Count; i++) { vertexShader->append(GenerateVectorVaryingSettingCode(4, 1, currentVSVarying)); currentVSVarying += 1; } for (GLint i = 0; i < vec4ArrayCount; i++) { vertexShader->append(GenerateVectorVaryingSettingCode(4, 2, currentVSVarying)); currentVSVarying += 1; } if (usePointSize) { vertexShader->append("gl_PointSize = 1.0;\n"); } vertexShader->append("}\n"); // Generate the fragment shader fragmentShader->clear(); fragmentShader->append("precision highp float;\n"); fragmentShader->append(varyingDeclaration); fragmentShader->append("\nvoid main() \n{ \n\tvec4 retColor = vec4(0,0,0,0);\n"); unsigned int currentFSVarying = 0; // Make use of the float varyings fragmentShader->append("\tretColor += vec4("); for (GLint i = 0; i < floatCount; i++) { fragmentShader->append(GenerateVectorVaryingUseCode(1, currentFSVarying)); currentFSVarying += 1; } for (GLint i = 0; i < floatArrayCount; i++) { fragmentShader->append(GenerateVectorVaryingUseCode(2, currentFSVarying)); currentFSVarying += 1; } fragmentShader->append("0.0, 0.0, 0.0, 0.0);\n"); // Make use of the vec2 varyings fragmentShader->append("\tretColor += vec4("); for (GLint i = 0; i < vec2Count; i++) { fragmentShader->append(GenerateVectorVaryingUseCode(1, currentFSVarying)); currentFSVarying += 1; } for (GLint i = 0; i < vec2ArrayCount; i++) { fragmentShader->append(GenerateVectorVaryingUseCode(2, currentFSVarying)); currentFSVarying += 1; } fragmentShader->append("vec2(0.0, 0.0), 0.0, 0.0);\n"); // Make use of the vec3 varyings fragmentShader->append("\tretColor += vec4("); for (GLint i = 0; i < vec3Count; i++) { fragmentShader->append(GenerateVectorVaryingUseCode(1, currentFSVarying)); currentFSVarying += 1; } for (GLint i = 0; i < vec3ArrayCount; i++) { fragmentShader->append(GenerateVectorVaryingUseCode(2, currentFSVarying)); currentFSVarying += 1; } fragmentShader->append("vec3(0.0, 0.0, 0.0), 0.0);\n"); // Make use of the vec4 varyings fragmentShader->append("\tretColor += "); for (GLint i = 0; i < vec4Count; i++) { fragmentShader->append(GenerateVectorVaryingUseCode(1, currentFSVarying)); currentFSVarying += 1; } for (GLint i = 0; i < vec4ArrayCount; i++) { fragmentShader->append(GenerateVectorVaryingUseCode(2, currentFSVarying)); currentFSVarying += 1; } fragmentShader->append("vec4(0.0, 0.0, 0.0, 0.0);\n"); // Set gl_FragColor, and use special variables if requested fragmentShader->append("\tgl_FragColor = retColor"); if (useFragCoord) { fragmentShader->append(" + gl_FragCoord"); } if (usePointCoord) { fragmentShader->append(" + vec4(gl_PointCoord, 0.0, 0.0)"); } fragmentShader->append(";\n}"); } void VaryingTestBase(GLint floatCount, GLint floatArrayCount, GLint vec2Count, GLint vec2ArrayCount, GLint vec3Count, GLint vec3ArrayCount, GLint vec4Count, GLint vec4ArrayCount, bool useFragCoord, bool usePointCoord, bool usePointSize, bool expectSuccess) { std::string fragmentShaderSource; std::string vertexShaderSource; GenerateGLSLWithVaryings(floatCount, floatArrayCount, vec2Count, vec2ArrayCount, vec3Count, vec3ArrayCount, vec4Count, vec4ArrayCount, useFragCoord, usePointCoord, usePointSize, &fragmentShaderSource, &vertexShaderSource); GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); if (expectSuccess) { EXPECT_NE(0u, program); } else { EXPECT_EQ(0u, program); } } void CompileGLSLWithUniformsAndSamplers(GLint vertexUniformCount, GLint fragmentUniformCount, GLint vertexSamplersCount, GLint fragmentSamplersCount, bool expectSuccess) { std::stringstream vertexShader; std::stringstream fragmentShader; // Generate the vertex shader vertexShader << "precision mediump float;\n"; for (int i = 0; i < vertexUniformCount; i++) { vertexShader << "uniform vec4 v" << i << ";\n"; } for (int i = 0; i < vertexSamplersCount; i++) { vertexShader << "uniform sampler2D s" << i << ";\n"; } vertexShader << "void main()\n{\n"; for (int i = 0; i < vertexUniformCount; i++) { vertexShader << " gl_Position += v" << i << ";\n"; } for (int i = 0; i < vertexSamplersCount; i++) { vertexShader << " gl_Position += texture2D(s" << i << ", vec2(0.0, 0.0));\n"; } if (vertexUniformCount == 0 && vertexSamplersCount == 0) { vertexShader << " gl_Position = vec4(0.0);\n"; } vertexShader << "}\n"; // Generate the fragment shader fragmentShader << "precision mediump float;\n"; for (int i = 0; i < fragmentUniformCount; i++) { fragmentShader << "uniform vec4 v" << i << ";\n"; } for (int i = 0; i < fragmentSamplersCount; i++) { fragmentShader << "uniform sampler2D s" << i << ";\n"; } fragmentShader << "void main()\n{\n"; for (int i = 0; i < fragmentUniformCount; i++) { fragmentShader << " gl_FragColor += v" << i << ";\n"; } for (int i = 0; i < fragmentSamplersCount; i++) { fragmentShader << " gl_FragColor += texture2D(s" << i << ", vec2(0.0, 0.0));\n"; } if (fragmentUniformCount == 0 && fragmentSamplersCount == 0) { fragmentShader << " gl_FragColor = vec4(0.0, 1.0, 0.0, 1.0);\n"; } fragmentShader << "}\n"; GLuint program = CompileProgram(vertexShader.str(), fragmentShader.str()); if (expectSuccess) { EXPECT_NE(0u, program); } else { EXPECT_EQ(0u, program); } } std::string mSimpleVSSource; }; class GLSLTestNoValidation : public GLSLTest { public: GLSLTestNoValidation() { setNoErrorEnabled(true); } }; class GLSLTest_ES3 : public GLSLTest { void SetUp() override { ANGLETest::SetUp(); mSimpleVSSource = R"(#version 300 es in vec4 inputAttribute; void main() { gl_Position = inputAttribute; })"; } }; class GLSLTest_ES31 : public GLSLTest { void SetUp() override { ANGLETest::SetUp(); mSimpleVSSource = R"(#version 310 es in vec4 inputAttribute; void main() { gl_Position = inputAttribute; })"; } }; TEST_P(GLSLTest, NamelessScopedStructs) { const std::string fragmentShaderSource = R"(precision mediump float; void main() { struct { float q; } b; gl_FragColor = vec4(1, 0, 0, 1); gl_FragColor.a += b.q; })"; GLuint program = CompileProgram(mSimpleVSSource, fragmentShaderSource); EXPECT_NE(0u, program); } TEST_P(GLSLTest, ScopedStructsOrderBug) { // TODO(geofflang): Find out why this doesn't compile on Apple OpenGL drivers // (http://anglebug.com/1292) // TODO(geofflang): Find out why this doesn't compile on AMD OpenGL drivers // (http://anglebug.com/1291) if (IsDesktopOpenGL() && (IsOSX() || !IsNVIDIA())) { std::cout << "Test disabled on this OpenGL configuration." << std::endl; return; } const std::string fragmentShaderSource = R"(precision mediump float; struct T { float f; }; void main() { T a; struct T { float q; }; T b; gl_FragColor = vec4(1, 0, 0, 1); gl_FragColor.a += a.f; gl_FragColor.a += b.q; })"; GLuint program = CompileProgram(mSimpleVSSource, fragmentShaderSource); EXPECT_NE(0u, program); } TEST_P(GLSLTest, ScopedStructsBug) { const std::string fragmentShaderSource = R"(precision mediump float; struct T_0 { float f; }; void main() { gl_FragColor = vec4(1, 0, 0, 1); struct T { vec2 v; }; T_0 a; T b; gl_FragColor.a += a.f; gl_FragColor.a += b.v.x; })"; GLuint program = CompileProgram(mSimpleVSSource, fragmentShaderSource); EXPECT_NE(0u, program); } TEST_P(GLSLTest, DxPositionBug) { const std::string &vertexShaderSource = R"(attribute vec4 inputAttribute; varying float dx_Position; void main() { gl_Position = vec4(inputAttribute); dx_Position = 0.0; })"; const std::string &fragmentShaderSource = R"(precision mediump float; varying float dx_Position; void main() { gl_FragColor = vec4(dx_Position, 0, 0, 1); })"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } TEST_P(GLSLTest, ElseIfRewriting) { const std::string &vertexShaderSource = "attribute vec4 a_position;\n" "varying float v;\n" "void main() {\n" " gl_Position = a_position;\n" " v = 1.0;\n" " if (a_position.x <= 0.5) {\n" " v = 0.0;\n" " } else if (a_position.x >= 0.5) {\n" " v = 2.0;\n" " }\n" "}\n"; const std::string &fragmentShaderSource = "precision highp float;\n" "varying float v;\n" "void main() {\n" " vec4 color = vec4(1.0, 0.0, 0.0, 1.0);\n" " if (v >= 1.0) color = vec4(0.0, 1.0, 0.0, 1.0);\n" " if (v >= 2.0) color = vec4(0.0, 0.0, 1.0, 1.0);\n" " gl_FragColor = color;\n" "}\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); ASSERT_NE(0u, program); drawQuad(program, "a_position", 0.5f); EXPECT_PIXEL_EQ(0, 0, 255, 0, 0, 255); EXPECT_PIXEL_EQ(getWindowWidth()-1, 0, 0, 255, 0, 255); } TEST_P(GLSLTest, TwoElseIfRewriting) { const std::string &vertexShaderSource = "attribute vec4 a_position;\n" "varying float v;\n" "void main() {\n" " gl_Position = a_position;\n" " if (a_position.x == 0.0) {\n" " v = 1.0;\n" " } else if (a_position.x > 0.5) {\n" " v = 0.0;\n" " } else if (a_position.x > 0.75) {\n" " v = 0.5;\n" " }\n" "}\n"; const std::string &fragmentShaderSource = "precision highp float;\n" "varying float v;\n" "void main() {\n" " gl_FragColor = vec4(v, 0.0, 0.0, 1.0);\n" "}\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } TEST_P(GLSLTest, FrontFacingAndVarying) { EGLPlatformParameters platform = GetParam().eglParameters; const std::string vertexShaderSource = R"(attribute vec4 a_position; varying float v_varying; void main() { v_varying = a_position.x; gl_Position = a_position; })"; const std::string fragmentShaderSource = R"(precision mediump float; varying float v_varying; void main() { vec4 c; if (gl_FrontFacing) { c = vec4(v_varying, 0, 0, 1.0); } else { c = vec4(0, v_varying, 0, 1.0); } gl_FragColor = c; })"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); // Compilation should fail on D3D11 feature level 9_3, since gl_FrontFacing isn't supported. if (platform.renderer == EGL_PLATFORM_ANGLE_TYPE_D3D11_ANGLE) { if (platform.majorVersion == 9 && platform.minorVersion == 3) { EXPECT_EQ(0u, program); return; } } // Otherwise, compilation should succeed EXPECT_NE(0u, program); } // Test that we can release the shader compiler and still compile things properly. TEST_P(GLSLTest, ReleaseCompilerThenCompile) { const std::string &simpleVS = "attribute vec4 position; void main() { gl_Position = position; }"; const std::string &simpleFS = "void main() { gl_FragColor = vec4(1, 0, 0, 1); }"; // Draw with the first program. ANGLE_GL_PROGRAM(program1, simpleVS, simpleFS); drawQuad(program1, "position", 0.5f); ASSERT_GL_NO_ERROR(); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::red); // Clear and release shader compiler. glClearColor(0.0f, 1.0f, 0.0f, 1.0f); glClear(GL_COLOR_BUFFER_BIT); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); glReleaseShaderCompiler(); ASSERT_GL_NO_ERROR(); // Draw with a second program. ANGLE_GL_PROGRAM(program2, simpleVS, simpleFS); drawQuad(program2, "position", 0.5f); ASSERT_GL_NO_ERROR(); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::red); } // Verify that linking shaders declaring different shading language versions fails. TEST_P(GLSLTest_ES3, VersionMismatch) { const std::string fragmentShaderSource100 = "precision mediump float;\n" "varying float v_varying;\n" "void main() { gl_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource100 = "attribute vec4 a_position;\n" "varying float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; const std::string fragmentShaderSource300 = "#version 300 es\n" "precision mediump float;\n" "in float v_varying;\n" "out vec4 my_FragColor;\n" "void main() { my_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource300 = "#version 300 es\n" "in vec4 a_position;\n" "out float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource300, fragmentShaderSource100); EXPECT_EQ(0u, program); program = CompileProgram(vertexShaderSource100, fragmentShaderSource300); EXPECT_EQ(0u, program); } // Verify that declaring varying as invariant only in vertex shader fails in ESSL 1.00. TEST_P(GLSLTest, InvariantVaryingOut) { const std::string fragmentShaderSource = "precision mediump float;\n" "varying float v_varying;\n" "void main() { gl_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "attribute vec4 a_position;\n" "invariant varying float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_EQ(0u, program); } // Verify that declaring varying as invariant only in vertex shader succeeds in ESSL 3.00. TEST_P(GLSLTest_ES3, InvariantVaryingOut) { // TODO: ESSL 3.00 -> GLSL 1.20 translation should add "invariant" in fragment shader // for varyings which are invariant in vertex shader (http://anglebug.com/1293) if (IsDesktopOpenGL()) { std::cout << "Test disabled on OpenGL." << std::endl; return; } const std::string fragmentShaderSource = "#version 300 es\n" "precision mediump float;\n" "in float v_varying;\n" "out vec4 my_FragColor;\n" "void main() { my_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "#version 300 es\n" "in vec4 a_position;\n" "invariant out float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that declaring varying as invariant only in fragment shader fails in ESSL 1.00. TEST_P(GLSLTest, InvariantVaryingIn) { const std::string fragmentShaderSource = "precision mediump float;\n" "invariant varying float v_varying;\n" "void main() { gl_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "attribute vec4 a_position;\n" "varying float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_EQ(0u, program); } // Verify that declaring varying as invariant only in fragment shader fails in ESSL 3.00. TEST_P(GLSLTest_ES3, InvariantVaryingIn) { const std::string fragmentShaderSource = "#version 300 es\n" "precision mediump float;\n" "invariant in float v_varying;\n" "out vec4 my_FragColor;\n" "void main() { my_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "#version 300 es\n" "in vec4 a_position;\n" "out float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_EQ(0u, program); } // Verify that declaring varying as invariant in both shaders succeeds in ESSL 1.00. TEST_P(GLSLTest, InvariantVaryingBoth) { const std::string fragmentShaderSource = "precision mediump float;\n" "invariant varying float v_varying;\n" "void main() { gl_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "attribute vec4 a_position;\n" "invariant varying float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that declaring varying as invariant in both shaders fails in ESSL 3.00. TEST_P(GLSLTest_ES3, InvariantVaryingBoth) { const std::string fragmentShaderSource = "#version 300 es\n" "precision mediump float;\n" "invariant in float v_varying;\n" "out vec4 my_FragColor;\n" "void main() { my_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "#version 300 es\n" "in vec4 a_position;\n" "invariant out float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_EQ(0u, program); } // Verify that declaring gl_Position as invariant succeeds in ESSL 1.00. TEST_P(GLSLTest, InvariantGLPosition) { const std::string fragmentShaderSource = "precision mediump float;\n" "varying float v_varying;\n" "void main() { gl_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "attribute vec4 a_position;\n" "invariant gl_Position;\n" "varying float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that declaring gl_Position as invariant succeeds in ESSL 3.00. TEST_P(GLSLTest_ES3, InvariantGLPosition) { const std::string fragmentShaderSource = "#version 300 es\n" "precision mediump float;\n" "in float v_varying;\n" "out vec4 my_FragColor;\n" "void main() { my_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "#version 300 es\n" "in vec4 a_position;\n" "invariant gl_Position;\n" "out float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that using invariant(all) in both shaders succeeds in ESSL 1.00. TEST_P(GLSLTest, InvariantAllBoth) { // TODO: ESSL 1.00 -> GLSL 1.20 translation should add "invariant" in fragment shader // for varyings which are invariant in vertex shader individually, // and remove invariant(all) from fragment shader (http://anglebug.com/1293) if (IsDesktopOpenGL()) { std::cout << "Test disabled on OpenGL." << std::endl; return; } const std::string fragmentShaderSource = "#pragma STDGL invariant(all)\n" "precision mediump float;\n" "varying float v_varying;\n" "void main() { gl_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "#pragma STDGL invariant(all)\n" "attribute vec4 a_position;\n" "varying float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that functions without return statements still compile TEST_P(GLSLTest, MissingReturnFloat) { const std::string vertexShaderSource = "varying float v_varying;\n" "float f() { if (v_varying > 0.0) return 1.0; }\n" "void main() { gl_Position = vec4(f(), 0, 0, 1); }\n"; const std::string fragmentShaderSource = "precision mediump float;\n" "void main() { gl_FragColor = vec4(0, 0, 0, 1); }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that functions without return statements still compile TEST_P(GLSLTest, MissingReturnVec2) { const std::string vertexShaderSource = "varying float v_varying;\n" "vec2 f() { if (v_varying > 0.0) return vec2(1.0, 1.0); }\n" "void main() { gl_Position = vec4(f().x, 0, 0, 1); }\n"; const std::string fragmentShaderSource = "precision mediump float;\n" "void main() { gl_FragColor = vec4(0, 0, 0, 1); }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that functions without return statements still compile TEST_P(GLSLTest, MissingReturnVec3) { const std::string vertexShaderSource = "varying float v_varying;\n" "vec3 f() { if (v_varying > 0.0) return vec3(1.0, 1.0, 1.0); }\n" "void main() { gl_Position = vec4(f().x, 0, 0, 1); }\n"; const std::string fragmentShaderSource = "precision mediump float;\n" "void main() { gl_FragColor = vec4(0, 0, 0, 1); }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that functions without return statements still compile TEST_P(GLSLTest, MissingReturnVec4) { const std::string vertexShaderSource = "varying float v_varying;\n" "vec4 f() { if (v_varying > 0.0) return vec4(1.0, 1.0, 1.0, 1.0); }\n" "void main() { gl_Position = vec4(f().x, 0, 0, 1); }\n"; const std::string fragmentShaderSource = "precision mediump float;\n" "void main() { gl_FragColor = vec4(0, 0, 0, 1); }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that functions without return statements still compile TEST_P(GLSLTest, MissingReturnIVec4) { const std::string vertexShaderSource = "varying float v_varying;\n" "ivec4 f() { if (v_varying > 0.0) return ivec4(1, 1, 1, 1); }\n" "void main() { gl_Position = vec4(f().x, 0, 0, 1); }\n"; const std::string fragmentShaderSource = "precision mediump float;\n" "void main() { gl_FragColor = vec4(0, 0, 0, 1); }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that functions without return statements still compile TEST_P(GLSLTest, MissingReturnMat4) { const std::string vertexShaderSource = "varying float v_varying;\n" "mat4 f() { if (v_varying > 0.0) return mat4(1.0); }\n" "void main() { gl_Position = vec4(f()[0][0], 0, 0, 1); }\n"; const std::string fragmentShaderSource = "precision mediump float;\n" "void main() { gl_FragColor = vec4(0, 0, 0, 1); }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that functions without return statements still compile TEST_P(GLSLTest, MissingReturnStruct) { const std::string vertexShaderSource = "varying float v_varying;\n" "struct s { float a; int b; vec2 c; };\n" "s f() { if (v_varying > 0.0) return s(1.0, 1, vec2(1.0, 1.0)); }\n" "void main() { gl_Position = vec4(f().a, 0, 0, 1); }\n"; const std::string fragmentShaderSource = "precision mediump float;\n" "void main() { gl_FragColor = vec4(0, 0, 0, 1); }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that functions without return statements still compile TEST_P(GLSLTest_ES3, MissingReturnArray) { const std::string vertexShaderSource = "#version 300 es\n" "in float v_varying;\n" "vec2[2] f() { if (v_varying > 0.0) { return vec2[2](vec2(1.0, 1.0), vec2(1.0, 1.0)); } }\n" "void main() { gl_Position = vec4(f()[0].x, 0, 0, 1); }\n"; const std::string fragmentShaderSource = "#version 300 es\n" "precision mediump float;\n" "out vec4 my_FragColor;\n" "void main() { my_FragColor = vec4(0, 0, 0, 1); }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that functions without return statements still compile TEST_P(GLSLTest_ES3, MissingReturnArrayOfStructs) { const std::string vertexShaderSource = "#version 300 es\n" "in float v_varying;\n" "struct s { float a; int b; vec2 c; };\n" "s[2] f() { if (v_varying > 0.0) { return s[2](s(1.0, 1, vec2(1.0, 1.0)), s(1.0, 1, " "vec2(1.0, 1.0))); } }\n" "void main() { gl_Position = vec4(f()[0].a, 0, 0, 1); }\n"; const std::string fragmentShaderSource = "#version 300 es\n" "precision mediump float;\n" "out vec4 my_FragColor;\n" "void main() { my_FragColor = vec4(0, 0, 0, 1); }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that functions without return statements still compile TEST_P(GLSLTest_ES3, MissingReturnStructOfArrays) { // TODO(cwallez) remove the suppression once NVIDIA drivers are updated across trybots, drivers // since late 2016 should have the fix. Last check on 2017-05-30 revealed that the Windows // Server 2008 bots still had the old, failing drivers. if (IsNVIDIA() && IsOpenGLES()) { std::cout << "Test skipped on NVIDIA OpenGL ES because it disallows returning " "structure of arrays" << std::endl; return; } const std::string vertexShaderSource = "#version 300 es\n" "in float v_varying;\n" "struct s { float a[2]; int b[2]; vec2 c[2]; };\n" "s f() { if (v_varying > 0.0) { return s(float[2](1.0, 1.0), int[2](1, 1)," "vec2[2](vec2(1.0, 1.0), vec2(1.0, 1.0))); } }\n" "void main() { gl_Position = vec4(f().a[0], 0, 0, 1); }\n"; const std::string fragmentShaderSource = "#version 300 es\n" "precision mediump float;\n" "out vec4 my_FragColor;\n" "void main() { my_FragColor = vec4(0, 0, 0, 1); }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Verify that using invariant(all) in both shaders fails in ESSL 3.00. TEST_P(GLSLTest_ES3, InvariantAllBoth) { const std::string fragmentShaderSource = "#version 300 es\n" "#pragma STDGL invariant(all)\n" "precision mediump float;\n" "in float v_varying;\n" "out vec4 my_FragColor;\n" "void main() { my_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "#version 300 es\n" "#pragma STDGL invariant(all)\n" "in vec4 a_position;\n" "out float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_EQ(0u, program); } // Verify that using invariant(all) only in fragment shader fails in ESSL 1.00. TEST_P(GLSLTest, InvariantAllIn) { const std::string fragmentShaderSource = "#pragma STDGL invariant(all)\n" "precision mediump float;\n" "varying float v_varying;\n" "void main() { gl_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "attribute vec4 a_position;\n" "varying float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_EQ(0u, program); } // Verify that using invariant(all) only in fragment shader fails in ESSL 3.00. TEST_P(GLSLTest_ES3, InvariantAllIn) { const std::string fragmentShaderSource = "#version 300 es\n" "#pragma STDGL invariant(all)\n" "precision mediump float;\n" "in float v_varying;\n" "out vec4 my_FragColor;\n" "void main() { my_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "#version 300 es\n" "in vec4 a_position;\n" "out float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_EQ(0u, program); } // Verify that using invariant(all) only in vertex shader fails in ESSL 1.00. TEST_P(GLSLTest, InvariantAllOut) { const std::string fragmentShaderSource = "precision mediump float;\n" "varying float v_varying;\n" "void main() { gl_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "#pragma STDGL invariant(all)\n" "attribute vec4 a_position;\n" "varying float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_EQ(0u, program); } // Verify that using invariant(all) only in vertex shader succeeds in ESSL 3.00. TEST_P(GLSLTest_ES3, InvariantAllOut) { // TODO: ESSL 3.00 -> GLSL 1.20 translation should add "invariant" in fragment shader // for varyings which are invariant in vertex shader, // because of invariant(all) being used in vertex shader (http://anglebug.com/1293) if (IsDesktopOpenGL()) { std::cout << "Test disabled on OpenGL." << std::endl; return; } const std::string fragmentShaderSource = "#version 300 es\n" "precision mediump float;\n" "in float v_varying;\n" "out vec4 my_FragColor;\n" "void main() { my_FragColor = vec4(v_varying, 0, 0, 1.0); }\n"; const std::string vertexShaderSource = "#version 300 es\n" "#pragma STDGL invariant(all)\n" "in vec4 a_position;\n" "out float v_varying;\n" "void main() { v_varying = a_position.x; gl_Position = a_position; }\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } TEST_P(GLSLTest, MaxVaryingVec4) { #if defined(__APPLE__) // TODO(geofflang): Find out why this doesn't compile on Apple AND OpenGL drivers // (http://anglebug.com/1291) if (IsAMD() && getPlatformRenderer() == EGL_PLATFORM_ANGLE_TYPE_OPENGL_ANGLE) { std::cout << "Test disabled on Apple AMD OpenGL." << std::endl; return; } #endif GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); VaryingTestBase(0, 0, 0, 0, 0, 0, maxVaryings, 0, false, false, false, true); } TEST_P(GLSLTest, MaxMinusTwoVaryingVec4PlusTwoSpecialVariables) { GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); // Generate shader code that uses gl_FragCoord and gl_PointCoord, two special fragment shader variables. VaryingTestBase(0, 0, 0, 0, 0, 0, maxVaryings - 2, 0, true, true, false, true); } TEST_P(GLSLTest, MaxMinusTwoVaryingVec4PlusThreeSpecialVariables) { // TODO(geofflang): Figure out why this fails on OpenGL AMD (http://anglebug.com/1291) if (IsAMD() && getPlatformRenderer() == EGL_PLATFORM_ANGLE_TYPE_OPENGL_ANGLE) { std::cout << "Test disabled on OpenGL." << std::endl; return; } GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); // Generate shader code that uses gl_FragCoord, gl_PointCoord and gl_PointSize. VaryingTestBase(0, 0, 0, 0, 0, 0, maxVaryings - 2, 0, true, true, true, true); } TEST_P(GLSLTest, MaxVaryingVec3) { GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); VaryingTestBase(0, 0, 0, 0, maxVaryings, 0, 0, 0, false, false, false, true); } TEST_P(GLSLTest, MaxVaryingVec3Array) { GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); VaryingTestBase(0, 0, 0, 0, 0, maxVaryings / 2, 0, 0, false, false, false, true); } // Disabled because of a failure in D3D9 TEST_P(GLSLTest, MaxVaryingVec3AndOneFloat) { if (IsD3D9()) { std::cout << "Test disabled on D3D9." << std::endl; return; } GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); VaryingTestBase(1, 0, 0, 0, maxVaryings, 0, 0, 0, false, false, false, true); } // Disabled because of a failure in D3D9 TEST_P(GLSLTest, MaxVaryingVec3ArrayAndOneFloatArray) { if (IsD3D9()) { std::cout << "Test disabled on D3D9." << std::endl; return; } GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); VaryingTestBase(0, 1, 0, 0, 0, maxVaryings / 2, 0, 0, false, false, false, true); } // Disabled because of a failure in D3D9 TEST_P(GLSLTest, TwiceMaxVaryingVec2) { if (IsD3D9()) { std::cout << "Test disabled on D3D9." << std::endl; return; } if (getPlatformRenderer() == EGL_PLATFORM_ANGLE_TYPE_OPENGLES_ANGLE) { // TODO(geofflang): Figure out why this fails on NVIDIA's GLES driver std::cout << "Test disabled on OpenGL ES." << std::endl; return; } #if defined(__APPLE__) // TODO(geofflang): Find out why this doesn't compile on Apple AND OpenGL drivers // (http://anglebug.com/1291) if (IsAMD() && getPlatformRenderer() == EGL_PLATFORM_ANGLE_TYPE_OPENGL_ANGLE) { std::cout << "Test disabled on Apple AMD OpenGL." << std::endl; return; } #endif GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); VaryingTestBase(0, 0, 2 * maxVaryings, 0, 0, 0, 0, 0, false, false, false, true); } // Disabled because of a failure in D3D9 TEST_P(GLSLTest, MaxVaryingVec2Arrays) { if (IsD3DSM3()) { std::cout << "Test disabled on SM3." << std::endl; return; } if (getPlatformRenderer() == EGL_PLATFORM_ANGLE_TYPE_OPENGLES_ANGLE) { // TODO(geofflang): Figure out why this fails on NVIDIA's GLES driver std::cout << "Test disabled on OpenGL ES." << std::endl; return; } #if defined(__APPLE__) // TODO(geofflang): Find out why this doesn't compile on Apple AND OpenGL drivers // (http://anglebug.com/1291) if (IsAMD() && getPlatformRenderer() == EGL_PLATFORM_ANGLE_TYPE_OPENGL_ANGLE) { std::cout << "Test disabled on Apple AMD OpenGL." << std::endl; return; } #endif GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); // Special case: because arrays of mat2 are packed as small grids of two rows by two columns, // we should be aware that when we're packing into an odd number of varying registers the // last row will be empty and can not fit the final vec2 arrary. GLint maxVec2Arrays = (maxVaryings >> 1) << 1; VaryingTestBase(0, 0, 0, maxVec2Arrays, 0, 0, 0, 0, false, false, false, true); } // Verify shader source with a fixed length that is less than the null-terminated length will compile. TEST_P(GLSLTest, FixedShaderLength) { GLuint shader = glCreateShader(GL_FRAGMENT_SHADER); const std::string appendGarbage = "abcasdfasdfasdfasdfasdf"; const std::string source = "void main() { gl_FragColor = vec4(0, 0, 0, 0); }" + appendGarbage; const char *sourceArray[1] = { source.c_str() }; GLint lengths[1] = { static_cast(source.length() - appendGarbage.length()) }; glShaderSource(shader, static_cast(ArraySize(sourceArray)), sourceArray, lengths); glCompileShader(shader); GLint compileResult; glGetShaderiv(shader, GL_COMPILE_STATUS, &compileResult); EXPECT_NE(compileResult, 0); } // Verify that a negative shader source length is treated as a null-terminated length. TEST_P(GLSLTest, NegativeShaderLength) { GLuint shader = glCreateShader(GL_FRAGMENT_SHADER); const char *sourceArray[1] = { "void main() { gl_FragColor = vec4(0, 0, 0, 0); }" }; GLint lengths[1] = { -10 }; glShaderSource(shader, static_cast(ArraySize(sourceArray)), sourceArray, lengths); glCompileShader(shader); GLint compileResult; glGetShaderiv(shader, GL_COMPILE_STATUS, &compileResult); EXPECT_NE(compileResult, 0); } // Check that having an invalid char after the "." doesn't cause an assert. TEST_P(GLSLTest, InvalidFieldFirstChar) { GLuint shader = glCreateShader(GL_VERTEX_SHADER); const char *source = "void main() {vec4 x; x.}"; glShaderSource(shader, 1, &source, 0); glCompileShader(shader); GLint compileResult; glGetShaderiv(shader, GL_COMPILE_STATUS, &compileResult); EXPECT_EQ(0, compileResult); } // Verify that a length array with mixed positive and negative values compiles. TEST_P(GLSLTest, MixedShaderLengths) { GLuint shader = glCreateShader(GL_FRAGMENT_SHADER); const char *sourceArray[] = { "void main()", "{", " gl_FragColor = vec4(0, 0, 0, 0);", "}", }; GLint lengths[] = { -10, 1, static_cast(strlen(sourceArray[2])), -1, }; ASSERT_EQ(ArraySize(sourceArray), ArraySize(lengths)); glShaderSource(shader, static_cast(ArraySize(sourceArray)), sourceArray, lengths); glCompileShader(shader); GLint compileResult; glGetShaderiv(shader, GL_COMPILE_STATUS, &compileResult); EXPECT_NE(compileResult, 0); } // Verify that zero-length shader source does not affect shader compilation. TEST_P(GLSLTest, ZeroShaderLength) { GLuint shader = glCreateShader(GL_FRAGMENT_SHADER); const char *sourceArray[] = { "adfasdf", "34534", "void main() { gl_FragColor = vec4(0, 0, 0, 0); }", "", "asdfasdfsdsdf", }; GLint lengths[] = { 0, 0, -1, 0, 0, }; ASSERT_EQ(ArraySize(sourceArray), ArraySize(lengths)); glShaderSource(shader, static_cast(ArraySize(sourceArray)), sourceArray, lengths); glCompileShader(shader); GLint compileResult; glGetShaderiv(shader, GL_COMPILE_STATUS, &compileResult); EXPECT_NE(compileResult, 0); } // Tests that bad index expressions don't crash ANGLE's translator. // https://code.google.com/p/angleproject/issues/detail?id=857 TEST_P(GLSLTest, BadIndexBug) { const std::string &fragmentShaderSourceVec = "precision mediump float;\n" "uniform vec4 uniformVec;\n" "void main()\n" "{\n" " gl_FragColor = vec4(uniformVec[int()]);\n" "}"; GLuint shader = CompileShader(GL_FRAGMENT_SHADER, fragmentShaderSourceVec); EXPECT_EQ(0u, shader); if (shader != 0) { glDeleteShader(shader); } const std::string &fragmentShaderSourceMat = "precision mediump float;\n" "uniform mat4 uniformMat;\n" "void main()\n" "{\n" " gl_FragColor = vec4(uniformMat[int()]);\n" "}"; shader = CompileShader(GL_FRAGMENT_SHADER, fragmentShaderSourceMat); EXPECT_EQ(0u, shader); if (shader != 0) { glDeleteShader(shader); } const std::string &fragmentShaderSourceArray = "precision mediump float;\n" "uniform vec4 uniformArray;\n" "void main()\n" "{\n" " gl_FragColor = vec4(uniformArray[int()]);\n" "}"; shader = CompileShader(GL_FRAGMENT_SHADER, fragmentShaderSourceArray); EXPECT_EQ(0u, shader); if (shader != 0) { glDeleteShader(shader); } } // Test that structs defined in uniforms are translated correctly. TEST_P(GLSLTest, StructSpecifiersUniforms) { const std::string fragmentShaderSource = R"(precision mediump float; uniform struct S { float field;} s; void main() { gl_FragColor = vec4(1, 0, 0, 1); gl_FragColor.a += s.field; })"; GLuint program = CompileProgram(mSimpleVSSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Test that gl_DepthRange is not stored as a uniform location. Since uniforms // beginning with "gl_" are filtered out by our validation logic, we must // bypass the validation to test the behaviour of the implementation. // (note this test is still Impl-independent) TEST_P(GLSLTestNoValidation, DepthRangeUniforms) { const std::string fragmentShaderSource = R"(precision mediump float; void main() { gl_FragColor = vec4(gl_DepthRange.near, gl_DepthRange.far, gl_DepthRange.diff, 1); })"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShaderSource); // We need to bypass validation for this call. GLint nearIndex = glGetUniformLocation(program.get(), "gl_DepthRange.near"); EXPECT_EQ(-1, nearIndex); // Test drawing does not throw an exception. drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_GL_NO_ERROR(); } std::string GenerateSmallPowShader(double base, double exponent) { std::stringstream stream; stream.precision(8); double result = pow(base, exponent); stream << "precision highp float;\n" << "float fun(float arg)\n" << "{\n" << " return pow(arg, " << std::fixed << exponent << ");\n" << "}\n" << "\n" << "void main()\n" << "{\n" << " const float a = " << std::scientific << base << ";\n" << " float b = fun(a);\n" << " if (abs(" << result << " - b) < " << std::abs(result * 0.001) << ")\n" << " {\n" << " gl_FragColor = vec4(0.0, 1.0, 0.0, 1.0);\n" << " }\n" << " else\n" << " {\n" << " gl_FragColor = vec4(1.0, 0.0, 0.0, 1.0);\n" << " }\n" << "}\n"; return stream.str(); } // Covers the WebGL test 'glsl/bugs/pow-of-small-constant-in-user-defined-function' // See http://anglebug.com/851 TEST_P(GLSLTest, PowOfSmallConstant) { std::vector bads; for (int eps = -1; eps <= 1; ++eps) { for (int i = -4; i <= 5; ++i) { if (i >= -1 && i <= 1) continue; const double epsilon = 1.0e-8; double bad = static_cast(i) + static_cast(eps) * epsilon; bads.push_back(bad); } } for (double bad : bads) { const std::string &fragmentShaderSource = GenerateSmallPowShader(1.0e-6, bad); ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShaderSource); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); EXPECT_GL_NO_ERROR(); } } // Test that fragment shaders which contain non-constant loop indexers and compiled for FL9_3 and // below // fail with a specific error message. // Additionally test that the same fragment shader compiles successfully with feature levels greater // than FL9_3. TEST_P(GLSLTest, LoopIndexingValidation) { const std::string fragmentShaderSource = R"(precision mediump float; uniform float loopMax; void main() { gl_FragColor = vec4(1, 0, 0, 1); for (float l = 0.0; l < loopMax; l++) { if (loopMax > 3.0) { gl_FragColor.a += 0.1; } } })"; GLuint shader = glCreateShader(GL_FRAGMENT_SHADER); const char *sourceArray[1] = {fragmentShaderSource.c_str()}; glShaderSource(shader, 1, sourceArray, nullptr); glCompileShader(shader); GLint compileResult; glGetShaderiv(shader, GL_COMPILE_STATUS, &compileResult); // If the test is configured to run limited to Feature Level 9_3, then it is // assumed that shader compilation will fail with an expected error message containing // "Loop index cannot be compared with non-constant expression" if ((GetParam() == ES2_D3D11_FL9_3() || GetParam() == ES2_D3D9())) { if (compileResult != 0) { FAIL() << "Shader compilation succeeded, expected failure"; } else { GLint infoLogLength; glGetShaderiv(shader, GL_INFO_LOG_LENGTH, &infoLogLength); std::string infoLog; infoLog.resize(infoLogLength); glGetShaderInfoLog(shader, static_cast(infoLog.size()), nullptr, &infoLog[0]); if (infoLog.find("Loop index cannot be compared with non-constant expression") == std::string::npos) { FAIL() << "Shader compilation failed with unexpected error message"; } } } else { EXPECT_NE(0, compileResult); } if (shader != 0) { glDeleteShader(shader); } } // Tests that the maximum uniforms count returned from querying GL_MAX_VERTEX_UNIFORM_VECTORS // can actually be used. TEST_P(GLSLTest, VerifyMaxVertexUniformVectors) { if (IsLinux() && IsIntel()) { std::cout << "Test timed out on Linux Intel. See crbug.com/680631." << std::endl; return; } int maxUniforms = 10000; glGetIntegerv(GL_MAX_VERTEX_UNIFORM_VECTORS, &maxUniforms); EXPECT_GL_NO_ERROR(); std::cout << "Validating GL_MAX_VERTEX_UNIFORM_VECTORS = " << maxUniforms << std::endl; CompileGLSLWithUniformsAndSamplers(maxUniforms, 0, 0, 0, true); } // Tests that the maximum uniforms count returned from querying GL_MAX_VERTEX_UNIFORM_VECTORS // can actually be used along with the maximum number of texture samplers. TEST_P(GLSLTest, VerifyMaxVertexUniformVectorsWithSamplers) { if (GetParam().eglParameters.renderer == EGL_PLATFORM_ANGLE_TYPE_OPENGL_ANGLE || GetParam().eglParameters.renderer == EGL_PLATFORM_ANGLE_TYPE_OPENGLES_ANGLE) { std::cout << "Test disabled on OpenGL." << std::endl; return; } int maxUniforms = 10000; glGetIntegerv(GL_MAX_VERTEX_UNIFORM_VECTORS, &maxUniforms); EXPECT_GL_NO_ERROR(); std::cout << "Validating GL_MAX_VERTEX_UNIFORM_VECTORS = " << maxUniforms << std::endl; int maxTextureImageUnits = 0; glGetIntegerv(GL_MAX_VERTEX_TEXTURE_IMAGE_UNITS, &maxTextureImageUnits); CompileGLSLWithUniformsAndSamplers(maxUniforms, 0, maxTextureImageUnits, 0, true); } // Tests that the maximum uniforms count + 1 from querying GL_MAX_VERTEX_UNIFORM_VECTORS // fails shader compilation. TEST_P(GLSLTest, VerifyMaxVertexUniformVectorsExceeded) { int maxUniforms = 10000; glGetIntegerv(GL_MAX_VERTEX_UNIFORM_VECTORS, &maxUniforms); EXPECT_GL_NO_ERROR(); std::cout << "Validating GL_MAX_VERTEX_UNIFORM_VECTORS + 1 = " << maxUniforms + 1 << std::endl; CompileGLSLWithUniformsAndSamplers(maxUniforms + 1, 0, 0, 0, false); } // Tests that the maximum uniforms count returned from querying GL_MAX_FRAGMENT_UNIFORM_VECTORS // can actually be used. TEST_P(GLSLTest, VerifyMaxFragmentUniformVectors) { if (IsLinux() && IsIntel()) { std::cout << "Test timed out on Linux Intel. See crbug.com/680631." << std::endl; return; } int maxUniforms = 10000; glGetIntegerv(GL_MAX_FRAGMENT_UNIFORM_VECTORS, &maxUniforms); EXPECT_GL_NO_ERROR(); std::cout << "Validating GL_MAX_FRAGMENT_UNIFORM_VECTORS = " << maxUniforms << std::endl; CompileGLSLWithUniformsAndSamplers(0, maxUniforms, 0, 0, true); } // Tests that the maximum uniforms count returned from querying GL_MAX_FRAGMENT_UNIFORM_VECTORS // can actually be used along with the maximum number of texture samplers. TEST_P(GLSLTest, VerifyMaxFragmentUniformVectorsWithSamplers) { if (GetParam().eglParameters.renderer == EGL_PLATFORM_ANGLE_TYPE_OPENGL_ANGLE || GetParam().eglParameters.renderer == EGL_PLATFORM_ANGLE_TYPE_OPENGLES_ANGLE) { std::cout << "Test disabled on OpenGL." << std::endl; return; } int maxUniforms = 10000; glGetIntegerv(GL_MAX_FRAGMENT_UNIFORM_VECTORS, &maxUniforms); EXPECT_GL_NO_ERROR(); int maxTextureImageUnits = 0; glGetIntegerv(GL_MAX_TEXTURE_IMAGE_UNITS, &maxTextureImageUnits); CompileGLSLWithUniformsAndSamplers(0, maxUniforms, 0, maxTextureImageUnits, true); } // Tests that the maximum uniforms count + 1 from querying GL_MAX_FRAGMENT_UNIFORM_VECTORS // fails shader compilation. TEST_P(GLSLTest, VerifyMaxFragmentUniformVectorsExceeded) { int maxUniforms = 10000; glGetIntegerv(GL_MAX_FRAGMENT_UNIFORM_VECTORS, &maxUniforms); EXPECT_GL_NO_ERROR(); std::cout << "Validating GL_MAX_FRAGMENT_UNIFORM_VECTORS + 1 = " << maxUniforms + 1 << std::endl; CompileGLSLWithUniformsAndSamplers(0, maxUniforms + 1, 0, 0, false); } // Test compiling shaders using the GL_EXT_shader_texture_lod extension TEST_P(GLSLTest, TextureLOD) { if (!extensionEnabled("GL_EXT_shader_texture_lod")) { std::cout << "Test skipped due to missing GL_EXT_shader_texture_lod." << std::endl; return; } const std::string source = "#extension GL_EXT_shader_texture_lod : require\n" "uniform sampler2D u_texture;\n" "void main() {\n" " gl_FragColor = texture2DGradEXT(u_texture, vec2(0.0, 0.0), vec2(0.0, 0.0), vec2(0.0, " "0.0));\n" "}\n"; GLuint shader = CompileShader(GL_FRAGMENT_SHADER, source); ASSERT_NE(0u, shader); glDeleteShader(shader); } // Test that two constructors which have vec4 and mat2 parameters get disambiguated (issue in // HLSL). TEST_P(GLSLTest_ES3, AmbiguousConstructorCall2x2) { const std::string fragmentShaderSource = "#version 300 es\n" "precision highp float;\n" "out vec4 my_FragColor;\n" "void main()\n" "{\n" " my_FragColor = vec4(0.0);\n" "}"; const std::string vertexShaderSource = "#version 300 es\n" "precision highp float;\n" "in vec4 a_vec;\n" "in mat2 a_mat;\n" "void main()\n" "{\n" " gl_Position = vec4(a_vec) + vec4(a_mat);\n" "}"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Test that two constructors which have mat2x3 and mat3x2 parameters get disambiguated. // This was suspected to be an issue in HLSL, but HLSL seems to be able to natively choose between // the function signatures in this case. TEST_P(GLSLTest_ES3, AmbiguousConstructorCall2x3) { const std::string fragmentShaderSource = "#version 300 es\n" "precision highp float;\n" "out vec4 my_FragColor;\n" "void main()\n" "{\n" " my_FragColor = vec4(0.0);\n" "}"; const std::string vertexShaderSource = "#version 300 es\n" "precision highp float;\n" "in mat3x2 a_matA;\n" "in mat2x3 a_matB;\n" "void main()\n" "{\n" " gl_Position = vec4(a_matA) + vec4(a_matB);\n" "}"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Test that two functions which have vec4 and mat2 parameters get disambiguated (issue in HLSL). TEST_P(GLSLTest_ES3, AmbiguousFunctionCall2x2) { const std::string fragmentShaderSource = "#version 300 es\n" "precision highp float;\n" "out vec4 my_FragColor;\n" "void main()\n" "{\n" " my_FragColor = vec4(0.0);\n" "}"; const std::string vertexShaderSource = "#version 300 es\n" "precision highp float;\n" "in vec4 a_vec;\n" "in mat2 a_mat;\n" "vec4 foo(vec4 a)\n" "{\n" " return a;\n" "}\n" "vec4 foo(mat2 a)\n" "{\n" " return vec4(a[0][0]);\n" "}\n" "void main()\n" "{\n" " gl_Position = foo(a_vec) + foo(a_mat);\n" "}"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Test that an user-defined function with a large number of float4 parameters doesn't fail due to // the function name being too long. TEST_P(GLSLTest_ES3, LargeNumberOfFloat4Parameters) { const std::string fragmentShaderSource = "#version 300 es\n" "precision highp float;\n" "out vec4 my_FragColor;\n" "void main()\n" "{\n" " my_FragColor = vec4(0.0);\n" "}"; std::stringstream vertexShaderStream; const unsigned int paramCount = 1024u; vertexShaderStream << "#version 300 es\n" "precision highp float;\n" "in vec4 a_vec;\n" "vec4 lotsOfVec4Parameters("; for (unsigned int i = 0; i < paramCount; ++i) { vertexShaderStream << "vec4 a" << i << ", "; } vertexShaderStream << "vec4 aLast)\n" "{\n" " return "; for (unsigned int i = 0; i < paramCount; ++i) { vertexShaderStream << "a" << i << " + "; } vertexShaderStream << "aLast;\n" "}\n" "void main()\n" "{\n" " gl_Position = lotsOfVec4Parameters("; for (unsigned int i = 0; i < paramCount; ++i) { vertexShaderStream << "a_vec, "; } vertexShaderStream << "a_vec);\n" "}"; GLuint program = CompileProgram(vertexShaderStream.str(), fragmentShaderSource); EXPECT_NE(0u, program); } // This test was written specifically to stress DeferGlobalInitializers AST transformation. // Test a shader where a global constant array is initialized with an expression containing array // indexing. This initializer is tricky to constant fold, so if it's not constant folded it needs to // be handled in a way that doesn't generate statements in the global scope in HLSL output. // Also includes multiple array initializers in one declaration, where only the second one has // array indexing. This makes sure that the qualifier for the declaration is set correctly if // transformations are applied to the declaration also in the case of ESSL output. TEST_P(GLSLTest_ES3, InitGlobalArrayWithArrayIndexing) { // TODO(ynovikov): re-enable once root cause of http://anglebug.com/1428 is fixed if (IsAndroid() && IsAdreno() && IsOpenGLES()) { std::cout << "Test skipped on Adreno OpenGLES on Android." << std::endl; return; } const std::string vertexShaderSource = "#version 300 es\n" "precision highp float;\n" "in vec4 a_vec;\n" "void main()\n" "{\n" " gl_Position = vec4(a_vec);\n" "}"; const std::string fragmentShaderSource = "#version 300 es\n" "precision highp float;\n" "out vec4 my_FragColor;\n" "const highp float f[2] = float[2](0.1, 0.2);\n" "const highp float[2] g = float[2](0.3, 0.4), h = float[2](0.5, f[1]);\n" "void main()\n" "{\n" " my_FragColor = vec4(h[1]);\n" "}"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Test that index-constant sampler array indexing is supported. TEST_P(GLSLTest, IndexConstantSamplerArrayIndexing) { if (IsD3D11_FL93()) { std::cout << "Test skipped on D3D11 FL 9.3." << std::endl; return; } const std::string vertexShaderSource = "attribute vec4 vPosition;\n" "void main()\n" "{\n" " gl_Position = vPosition;\n" "}"; const std::string fragmentShaderSource = "precision mediump float;\n" "uniform sampler2D uni[2];\n" "\n" "float zero(int x)\n" "{\n" " return float(x) - float(x);\n" "}\n" "\n" "void main()\n" "{\n" " vec4 c = vec4(0,0,0,0);\n" " for (int ii = 1; ii < 3; ++ii) {\n" " if (c.x > 255.0) {\n" " c.x = 255.0 + zero(ii);\n" " break;\n" " }\n" // Index the sampler array with a predictable loop index (index-constant) as opposed to // a true constant. This is valid in OpenGL ES but isn't in many Desktop OpenGL versions, // without an extension. " c += texture2D(uni[ii - 1], vec2(0.5, 0.5));\n" " }\n" " gl_FragColor = c;\n" "}"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Test that the #pragma directive is supported and doesn't trigger a compilation failure on the // native driver. The only pragma that gets passed to the OpenGL driver is "invariant" but we don't // want to test its behavior, so don't use any varyings. TEST_P(GLSLTest, PragmaDirective) { const std::string vertexShaderSource = "#pragma STDGL invariant(all)\n" "void main()\n" "{\n" " gl_Position = vec4(1.0, 0.0, 0.0, 1.0);\n" "}\n"; const std::string fragmentShaderSource = "precision mediump float;\n" "void main()\n" "{\n" " gl_FragColor = vec4(1.0);\n" "}\n"; GLuint program = CompileProgram(vertexShaderSource, fragmentShaderSource); EXPECT_NE(0u, program); } // Sequence operator evaluates operands from left to right (ESSL 3.00 section 5.9). // The function call that returns the array needs to be evaluated after ++j for the expression to // return the correct value (true). TEST_P(GLSLTest_ES3, SequenceOperatorEvaluationOrderArray) { const std::string &fragmentShaderSource = "#version 300 es\n" "precision mediump float;\n" "out vec4 my_FragColor; \n" "int[2] func(int param) {\n" " return int[2](param, param);\n" "}\n" "void main() {\n" " int a[2]; \n" " for (int i = 0; i < 2; ++i) {\n" " a[i] = 1;\n" " }\n" " int j = 0; \n" " bool result = ((++j), (a == func(j)));\n" " my_FragColor = vec4(0.0, (result ? 1.0 : 0.0), 0.0, 1.0);\n" "}\n"; GLuint program = CompileProgram(mSimpleVSSource, fragmentShaderSource); ASSERT_NE(0u, program); drawQuad(program, "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Sequence operator evaluates operands from left to right (ESSL 3.00 section 5.9). // The short-circuiting expression needs to be evaluated after ++j for the expression to return the // correct value (true). TEST_P(GLSLTest_ES3, SequenceOperatorEvaluationOrderShortCircuit) { const std::string &fragmentShaderSource = "#version 300 es\n" "precision mediump float;\n" "out vec4 my_FragColor; \n" "void main() {\n" " int j = 0; \n" " bool result = ((++j), (j == 1 ? true : (++j == 3)));\n" " my_FragColor = vec4(0.0, ((result && j == 1) ? 1.0 : 0.0), 0.0, 1.0);\n" "}\n"; GLuint program = CompileProgram(mSimpleVSSource, fragmentShaderSource); ASSERT_NE(0u, program); drawQuad(program, "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Sequence operator evaluates operands from left to right (ESSL 3.00 section 5.9). // Indexing the vector needs to be evaluated after func() for the right result. TEST_P(GLSLTest_ES3, SequenceOperatorEvaluationOrderDynamicVectorIndexingInLValue) { const std::string &fragmentShaderSource = "#version 300 es\n" "precision mediump float;\n" "out vec4 my_FragColor;\n" "uniform int u_zero;\n" "int sideEffectCount = 0;\n" "float func() {\n" " ++sideEffectCount;\n" " return -1.0;\n" "}\n" "void main() {\n" " vec4 v = vec4(0.0, 2.0, 4.0, 6.0); \n" " float f = (func(), (++v[u_zero + sideEffectCount]));\n" " bool green = abs(f - 3.0) < 0.01 && abs(v[1] - 3.0) < 0.01 && sideEffectCount == 1;\n" " my_FragColor = vec4(0.0, (green ? 1.0 : 0.0), 0.0, 1.0);\n" "}\n"; GLuint program = CompileProgram(mSimpleVSSource, fragmentShaderSource); ASSERT_NE(0u, program); drawQuad(program, "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test that using gl_PointCoord with GL_TRIANGLES doesn't produce a link error. // From WebGL test conformance/rendering/point-specific-shader-variables.html // See http://anglebug.com/1380 TEST_P(GLSLTest, RenderTrisWithPointCoord) { const std::string &vert = "attribute vec2 aPosition;\n" "void main()\n" "{\n" " gl_Position = vec4(aPosition, 0, 1);\n" " gl_PointSize = 1.0;\n" "}"; const std::string &frag = "void main()\n" "{\n" " gl_FragColor = vec4(gl_PointCoord.xy, 0, 1);\n" " gl_FragColor = vec4(0, 1, 0, 1);\n" "}"; ANGLE_GL_PROGRAM(prog, vert, frag); drawQuad(prog.get(), "aPosition", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Convers a bug with the integer pow statement workaround. TEST_P(GLSLTest, NestedPowStatements) { const std::string &vert = "attribute vec2 position;\n" "void main()\n" "{\n" " gl_Position = vec4(position, 0, 1);\n" "}"; const std::string &frag = "precision mediump float;\n" "float func(float v)\n" "{\n" " float f1 = pow(v, 2.0);\n" " return pow(f1 + v, 2.0);\n" "}\n" "void main()\n" "{\n" " float v = func(2.0);\n" " gl_FragColor = abs(v - 36.0) < 0.001 ? vec4(0, 1, 0, 1) : vec4(1, 0, 0, 1);\n" "}"; ANGLE_GL_PROGRAM(prog, vert, frag); drawQuad(prog.get(), "position", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test that -float calculation is correct. TEST_P(GLSLTest_ES3, UnaryMinusOperatorFloat) { const std::string &vert = "#version 300 es\n" "in highp vec4 position;\n" "void main() {\n" " gl_Position = position;\n" "}\n"; const std::string &frag = "#version 300 es\n" "out highp vec4 o_color;\n" "void main() {\n" " highp float f = -1.0;\n" " // atan(tan(0.5), -f) should be 0.5.\n" " highp float v = atan(tan(0.5), -f);\n" " o_color = abs(v - 0.5) < 0.001 ? vec4(0, 1, 0, 1) : vec4(1, 0, 0, 1);\n" "}\n"; ANGLE_GL_PROGRAM(prog, vert, frag); drawQuad(prog.get(), "position", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test that atan(vec2, vec2) calculation is correct. TEST_P(GLSLTest_ES3, AtanVec2) { const std::string &vert = "#version 300 es\n" "in highp vec4 position;\n" "void main() {\n" " gl_Position = position;\n" "}\n"; const std::string &frag = "#version 300 es\n" "out highp vec4 o_color;\n" "void main() {\n" " highp float f = 1.0;\n" " // atan(tan(0.5), f) should be 0.5.\n" " highp vec2 v = atan(vec2(tan(0.5)), vec2(f));\n" " o_color = (abs(v[0] - 0.5) < 0.001 && abs(v[1] - 0.5) < 0.001) ? vec4(0, 1, 0, 1) : " "vec4(1, 0, 0, 1);\n" "}\n"; ANGLE_GL_PROGRAM(prog, vert, frag); drawQuad(prog.get(), "position", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Convers a bug with the unary minus operator on signed integer workaround. TEST_P(GLSLTest_ES3, UnaryMinusOperatorSignedInt) { const std::string &vert = "#version 300 es\n" "in highp vec4 position;\n" "out mediump vec4 v_color;\n" "uniform int ui_one;\n" "uniform int ui_two;\n" "uniform int ui_three;\n" "void main() {\n" " int s[3];\n" " s[0] = ui_one;\n" " s[1] = -(-(-ui_two + 1) + 1);\n" // s[1] = -ui_two " s[2] = ui_three;\n" " int result = 0;\n" " for (int i = 0; i < ui_three; i++) {\n" " result += s[i];\n" " }\n" " v_color = (result == 2) ? vec4(0, 1, 0, 1) : vec4(1, 0, 0, 1);\n" " gl_Position = position;\n" "}\n"; const std::string &frag = "#version 300 es\n" "in mediump vec4 v_color;\n" "layout(location=0) out mediump vec4 o_color;\n" "void main() {\n" " o_color = v_color;\n" "}\n"; ANGLE_GL_PROGRAM(prog, vert, frag); GLint oneIndex = glGetUniformLocation(prog.get(), "ui_one"); ASSERT_NE(-1, oneIndex); GLint twoIndex = glGetUniformLocation(prog.get(), "ui_two"); ASSERT_NE(-1, twoIndex); GLint threeIndex = glGetUniformLocation(prog.get(), "ui_three"); ASSERT_NE(-1, threeIndex); glUseProgram(prog.get()); glUniform1i(oneIndex, 1); glUniform1i(twoIndex, 2); glUniform1i(threeIndex, 3); drawQuad(prog.get(), "position", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Convers a bug with the unary minus operator on unsigned integer workaround. TEST_P(GLSLTest_ES3, UnaryMinusOperatorUnsignedInt) { const std::string &vert = "#version 300 es\n" "in highp vec4 position;\n" "out mediump vec4 v_color;\n" "uniform uint ui_one;\n" "uniform uint ui_two;\n" "uniform uint ui_three;\n" "void main() {\n" " uint s[3];\n" " s[0] = ui_one;\n" " s[1] = -(-(-ui_two + 1u) + 1u);\n" // s[1] = -ui_two " s[2] = ui_three;\n" " uint result = 0u;\n" " for (uint i = 0u; i < ui_three; i++) {\n" " result += s[i];\n" " }\n" " v_color = (result == 2u) ? vec4(0, 1, 0, 1) : vec4(1, 0, 0, 1);\n" " gl_Position = position;\n" "}\n"; const std::string &frag = "#version 300 es\n" "in mediump vec4 v_color;\n" "layout(location=0) out mediump vec4 o_color;\n" "void main() {\n" " o_color = v_color;\n" "}\n"; ANGLE_GL_PROGRAM(prog, vert, frag); GLint oneIndex = glGetUniformLocation(prog.get(), "ui_one"); ASSERT_NE(-1, oneIndex); GLint twoIndex = glGetUniformLocation(prog.get(), "ui_two"); ASSERT_NE(-1, twoIndex); GLint threeIndex = glGetUniformLocation(prog.get(), "ui_three"); ASSERT_NE(-1, threeIndex); glUseProgram(prog.get()); glUniform1ui(oneIndex, 1u); glUniform1ui(twoIndex, 2u); glUniform1ui(threeIndex, 3u); drawQuad(prog.get(), "position", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test a nested sequence operator with a ternary operator inside. The ternary operator is // intended to be such that it gets converted to an if statement on the HLSL backend. TEST_P(GLSLTest, NestedSequenceOperatorWithTernaryInside) { const std::string &vert = "attribute vec2 position;\n" "void main()\n" "{\n" " gl_Position = vec4(position, 0, 1);\n" "}"; // Note that the uniform keep_flop_positive doesn't need to be set - the test expects it to have // its default value false. const std::string &frag = "precision mediump float;\n" "uniform bool keep_flop_positive;\n" "float flop;\n" "void main() {\n" " flop = -1.0,\n" " (flop *= -1.0,\n" " keep_flop_positive ? 0.0 : flop *= -1.0),\n" " gl_FragColor = vec4(0, -flop, 0, 1);\n" "}"; ANGLE_GL_PROGRAM(prog, vert, frag); drawQuad(prog.get(), "position", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test that using a sampler2D and samplerExternalOES in the same shader works (anglebug.com/1534) TEST_P(GLSLTest, ExternalAnd2DSampler) { if (!extensionEnabled("GL_OES_EGL_image_external")) { std::cout << "Test skipped because GL_OES_EGL_image_external is not available." << std::endl; return; } const std::string fragmentShader = "precision mediump float;\n" "uniform samplerExternalOES tex0;\n" "uniform sampler2D tex1;\n" "void main(void)\n" "{\n" " vec2 uv = vec2(0.0, 0.0);" " gl_FragColor = texture2D(tex0, uv) + texture2D(tex1, uv);\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); } // Test that literal infinity can be written out from the shader translator. // A similar test can't be made for NaNs, since ESSL 3.00.6 requirements for NaNs are very loose. TEST_P(GLSLTest_ES3, LiteralInfinityOutput) { const std::string &fragmentShader = "#version 300 es\n" "precision highp float;\n" "out vec4 out_color;\n" "uniform float u;\n" "void main()\n" "{\n" " float infVar = 1.0e40 - u;\n" " bool correct = isinf(infVar) && infVar > 0.0;\n" " out_color = correct ? vec4(0.0, 1.0, 0.0, 1.0) : vec4(1.0, 0.0, 0.0, 1.0);\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test that literal negative infinity can be written out from the shader translator. // A similar test can't be made for NaNs, since ESSL 3.00.6 requirements for NaNs are very loose. TEST_P(GLSLTest_ES3, LiteralNegativeInfinityOutput) { const std::string &fragmentShader = "#version 300 es\n" "precision highp float;\n" "out vec4 out_color;\n" "uniform float u;\n" "void main()\n" "{\n" " float infVar = -1.0e40 + u;\n" " bool correct = isinf(infVar) && infVar < 0.0;\n" " out_color = correct ? vec4(0.0, 1.0, 0.0, 1.0) : vec4(1.0, 0.0, 0.0, 1.0);\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // The following MultipleDeclaration* tests are testing TranslatorHLSL specific simplification // passes. Because the interaction of multiple passes must be tested, it is difficult to write // a unittest for them. Instead we add the tests as end2end so will in particular test // TranslatorHLSL when run on Windows. // Test that passes splitting multiple declarations and comma operators are correctly ordered. TEST_P(GLSLTest_ES3, MultipleDeclarationWithCommaOperator) { const std::string &fragmentShader = "#version 300 es\n" "precision mediump float;\n" "out vec4 color;\n" "void main(void)\n" "{\n" " float a = 0.0, b = ((gl_FragCoord.x < 0.5 ? a : 0.0), 1.0);\n" " color = vec4(b);\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); } // Test that passes splitting multiple declarations and comma operators and for loops are // correctly ordered. TEST_P(GLSLTest_ES3, MultipleDeclarationWithCommaOperatorInForLoop) { const std::string &fragmentShader = "#version 300 es\n" "precision mediump float;\n" "out vec4 color;\n" "void main(void)\n" "{\n" " for(float a = 0.0, b = ((gl_FragCoord.x < 0.5 ? a : 0.0), 1.0); a < 10.0; a++)\n" " {\n" " b += 1.0;\n" " color = vec4(b);\n" " }\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); } // Test that splitting multiple declaration in for loops works with no loop condition TEST_P(GLSLTest_ES3, MultipleDeclarationInForLoopEmptyCondition) { const std::string &fragmentShader = "#version 300 es\n" "precision mediump float;\n" "out vec4 color;\n" "void main(void)\n" "{\n" " for(float a = 0.0, b = 1.0;; a++)\n" " {\n" " b += 1.0;\n" " if (a > 10.0) {break;}\n" " color = vec4(b);\n" " }\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); } // Test that splitting multiple declaration in for loops works with no loop expression TEST_P(GLSLTest_ES3, MultipleDeclarationInForLoopEmptyExpression) { const std::string &fragmentShader = "#version 300 es\n" "precision mediump float;\n" "out vec4 color;\n" "void main(void)\n" "{\n" " for(float a = 0.0, b = 1.0; a < 10.0;)\n" " {\n" " b += 1.0;\n" " a += 1.0;\n" " color = vec4(b);\n" " }\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); } // Test that dynamic indexing of a matrix inside a dynamic indexing of a vector in an l-value works // correctly. TEST_P(GLSLTest_ES3, NestedDynamicIndexingInLValue) { const std::string &fragmentShader = "#version 300 es\n" "precision mediump float;\n" "out vec4 my_FragColor;\n" "uniform int u_zero;\n" "void main() {\n" " mat2 m = mat2(0.0, 0.0, 0.0, 0.0);\n" " m[u_zero + 1][u_zero + 1] = float(u_zero + 1);\n" " float f = m[1][1];\n" " my_FragColor = vec4(1.0 - f, f, 0.0, 1.0);\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } class WebGLGLSLTest : public GLSLTest { protected: WebGLGLSLTest() { setWebGLCompatibilityEnabled(true); } }; TEST_P(WebGLGLSLTest, MaxVaryingVec4PlusFragCoord) { GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); // Generate shader code that uses gl_FragCoord, a special fragment shader variables. // This test should fail, since we are really using (maxVaryings + 1) varyings. VaryingTestBase(0, 0, 0, 0, 0, 0, maxVaryings, 0, true, false, false, false); } TEST_P(WebGLGLSLTest, MaxVaryingVec4PlusPointCoord) { GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); // Generate shader code that uses gl_FragCoord, a special fragment shader variables. // This test should fail, since we are really using (maxVaryings + 1) varyings. VaryingTestBase(0, 0, 0, 0, 0, 0, maxVaryings, 0, false, true, false, false); } TEST_P(WebGLGLSLTest, MaxPlusOneVaryingVec3) { GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); VaryingTestBase(0, 0, 0, 0, maxVaryings + 1, 0, 0, 0, false, false, false, false); } TEST_P(WebGLGLSLTest, MaxPlusOneVaryingVec3Array) { GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); VaryingTestBase(0, 0, 0, 0, 0, maxVaryings / 2 + 1, 0, 0, false, false, false, false); } TEST_P(WebGLGLSLTest, MaxVaryingVec3AndOneVec2) { GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); VaryingTestBase(0, 0, 1, 0, maxVaryings, 0, 0, 0, false, false, false, false); } TEST_P(WebGLGLSLTest, MaxPlusOneVaryingVec2) { GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); VaryingTestBase(0, 0, 2 * maxVaryings + 1, 0, 0, 0, 0, 0, false, false, false, false); } TEST_P(WebGLGLSLTest, MaxVaryingVec3ArrayAndMaxPlusOneFloatArray) { GLint maxVaryings = 0; glGetIntegerv(GL_MAX_VARYING_VECTORS, &maxVaryings); VaryingTestBase(0, maxVaryings / 2 + 1, 0, 0, 0, 0, 0, maxVaryings / 2, false, false, false, false); } } // anonymous namespace // Test that FindLSB and FindMSB return correct values in their corner cases. TEST_P(GLSLTest_ES31, FindMSBAndFindLSBCornerCases) { // Suspecting AMD driver bug - failure seen on bots running on AMD R5 230. if (IsAMD() && IsOpenGL() && IsLinux()) { std::cout << "Test skipped on AMD OpenGL Linux" << std::endl; return; } const std::string &fragmentShader = "#version 310 es\n" "precision mediump float;\n" "out vec4 my_FragColor;\n" "uniform int u_zero;\n" "void main() {\n" " if (findLSB(u_zero) == -1 && findMSB(u_zero) == -1 && findMSB(u_zero - 1) == -1)\n" " {\n" " my_FragColor = vec4(0.0, 1.0, 0.0, 1.0);\n" " }\n" " else\n" " {\n" " my_FragColor = vec4(1.0, 0.0, 0.0, 1.0);\n" " }\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test that writing into a swizzled vector that is dynamically indexed succeeds. TEST_P(GLSLTest_ES3, WriteIntoDynamicIndexingOfSwizzledVector) { if (IsOpenGL()) { // http://anglebug.com/1924 std::cout << "Test skipped on all OpenGL configurations because it has incorrect results" << std::endl; return; } // The shader first assigns v.x to v.z (1.0) // Then v.y to v.y (2.0) // Then v.z to v.x (1.0) const std::string &fragmentShader = "#version 300 es\n" "precision highp float;\n" "out vec4 my_FragColor;\n" "void main() {\n" " vec3 v = vec3(1.0, 2.0, 3.0);\n" " for (int i = 0; i < 3; i++) {\n" " v.zyx[i] = v[i];\n" " }\n" " my_FragColor = distance(v, vec3(1.0, 2.0, 1.0)) < 0.01 ? vec4(0, 1, 0, 1) : vec4(1, " "0, 0, 1);\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // This test covers a bug (and associated workaround) with nested sampling operations in the HLSL // compiler DLL. TEST_P(GLSLTest_ES3, NestedSamplingOperation) { // This seems to be bugged on some version of Android. Might not affect the newest versions. // TODO(jmadill): Lift suppression when Chromium bots are upgraded. if (IsAndroid() && IsOpenGLES()) { std::cout << "Test skipped on Android because of bug with Nexus 5X." << std::endl; return; } const std::string &vertexShader = "#version 300 es\n" "out vec2 texCoord;\n" "in vec2 position;\n" "void main()\n" "{\n" " gl_Position = vec4(position, 0, 1);\n" " texCoord = position * 0.5 + vec2(0.5);\n" "}\n"; const std::string &simpleFragmentShader = "#version 300 es\n" "in mediump vec2 texCoord;\n" "out mediump vec4 fragColor;\n" "void main()\n" "{\n" " fragColor = vec4(texCoord, 0, 1);\n" "}\n"; const std::string &nestedFragmentShader = "#version 300 es\n" "uniform mediump sampler2D samplerA;\n" "uniform mediump sampler2D samplerB;\n" "in mediump vec2 texCoord;\n" "out mediump vec4 fragColor;\n" "void main ()\n" "{\n" " fragColor = texture(samplerB, texture(samplerA, texCoord).xy);\n" "}\n"; ANGLE_GL_PROGRAM(initProg, vertexShader, simpleFragmentShader); ANGLE_GL_PROGRAM(nestedProg, vertexShader, nestedFragmentShader); // Initialize a first texture with default texCoord data. GLTexture texA; glActiveTexture(GL_TEXTURE0); glBindTexture(GL_TEXTURE_2D, texA); glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, getWindowWidth(), getWindowHeight(), 0, GL_RGBA, GL_UNSIGNED_BYTE, nullptr); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST); GLFramebuffer fbo; glBindFramebuffer(GL_FRAMEBUFFER, fbo); glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, texA, 0); drawQuad(initProg, "position", 0.5f); ASSERT_GL_NO_ERROR(); // Initialize a second texture with a simple color pattern. GLTexture texB; glActiveTexture(GL_TEXTURE1); glBindTexture(GL_TEXTURE_2D, texB); std::array simpleColors = { {GLColor::red, GLColor::green, GLColor::blue, GLColor::yellow}}; glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, 2, 2, 0, GL_RGBA, GL_UNSIGNED_BYTE, simpleColors.data()); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST); // Draw with the nested program, using the first texture to index the second. glBindFramebuffer(GL_FRAMEBUFFER, 0); glUseProgram(nestedProg); GLint samplerALoc = glGetUniformLocation(nestedProg, "samplerA"); ASSERT_NE(-1, samplerALoc); glUniform1i(samplerALoc, 0); GLint samplerBLoc = glGetUniformLocation(nestedProg, "samplerB"); ASSERT_NE(-1, samplerBLoc); glUniform1i(samplerBLoc, 1); drawQuad(nestedProg, "position", 0.5f); ASSERT_GL_NO_ERROR(); // Compute four texel centers. Vector2 windowSize(getWindowWidth(), getWindowHeight()); Vector2 quarterWindowSize = windowSize / 4; Vector2 ul = quarterWindowSize; Vector2 ur(windowSize.x() - quarterWindowSize.x(), quarterWindowSize.y()); Vector2 ll(quarterWindowSize.x(), windowSize.y() - quarterWindowSize.y()); Vector2 lr = windowSize - quarterWindowSize; EXPECT_PIXEL_COLOR_EQ_VEC2(ul, simpleColors[0]); EXPECT_PIXEL_COLOR_EQ_VEC2(ur, simpleColors[1]); EXPECT_PIXEL_COLOR_EQ_VEC2(ll, simpleColors[2]); EXPECT_PIXEL_COLOR_EQ_VEC2(lr, simpleColors[3]); } // Tests that using a constant declaration as the only statement in a for loop without curly braces // doesn't crash. TEST_P(GLSLTest, ConstantStatementInForLoop) { const std::string &vertexShader = "void main()\n" "{\n" " for (int i = 0; i < 10; ++i)\n" " const int b = 0;\n" "}\n"; GLuint shader = CompileShader(GL_VERTEX_SHADER, vertexShader); EXPECT_NE(0u, shader); glDeleteShader(shader); } // Tests that using a constant declaration as a loop init expression doesn't crash. Note that this // test doesn't work on D3D9 due to looping limitations, so it is only run on ES3. TEST_P(GLSLTest_ES3, ConstantStatementAsLoopInit) { const std::string &vertexShader = "void main()\n" "{\n" " for (const int i = 0; i < 0;) {}\n" "}\n"; GLuint shader = CompileShader(GL_VERTEX_SHADER, vertexShader); EXPECT_NE(0u, shader); glDeleteShader(shader); } // Test that uninitialized local variables are initialized to 0. TEST_P(GLSLTest_ES3, InitUninitializedLocals) { if (IsAndroid() && IsOpenGLES()) { // http://anglebug.com/2046 std::cout << "Test skipped on Android GLES because local variable initialization is disabled." << std::endl; return; } if (IsOSX() && IsOpenGL()) { // http://anglebug.com/2041 std::cout << "Test skipped on Mac OpenGL because local variable initialization is disabled." << std::endl; return; } const std::string &fragmentShader = "#version 300 es\n" "precision mediump float;\n" "out vec4 my_FragColor;\n" "int result = 0;\n" "void main()\n" "{\n" " int u;\n" " result += u;\n" " int k = 0;\n" " for (int i[2], j = i[0] + 1; k < 2; ++k)\n" " {\n" " result += j;\n" " }\n" " if (result == 2)\n" " {\n" " my_FragColor = vec4(0, 1, 0, 1);\n" " }\n" " else\n" " {\n" " my_FragColor = vec4(1, 0, 0, 1);\n" " }\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test that uninitialized structs containing arrays of structs are initialized to 0. This // specifically tests with two different struct variables declared in the same block. TEST_P(GLSLTest, InitUninitializedStructContainingArrays) { if (IsAndroid() && IsOpenGLES()) { // http://anglebug.com/2046 std::cout << "Test skipped on Android GLES because local variable initialization is disabled." << std::endl; return; } if (IsOSX() && IsOpenGL()) { // http://anglebug.com/2041 std::cout << "Test skipped on Mac OpenGL because local variable initialization is disabled." << std::endl; return; } const std::string &fragmentShader = "precision mediump float;\n" "struct T\n" "{\n" " int a[2];\n" "};\n" "struct S\n" "{\n" " T t[2];\n" "};\n" "void main()\n" "{\n" " S s;\n" " S s2;\n" " if (s.t[1].a[1] == 0 && s2.t[1].a[1] == 0)\n" " {\n" " gl_FragColor = vec4(0, 1, 0, 1);\n" " }\n" " else\n" " {\n" " gl_FragColor = vec4(1, 0, 0, 1);\n" " }\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Verify that two shaders with the same uniform name and members but different structure names will // not link. TEST_P(GLSLTest, StructureNameMatchingTest) { const char *vsSource = "// Structures must have the same name, sequence of type names, and\n" "// type definitions, and field names to be considered the same type.\n" "// GLSL 1.017 4.2.4\n" "precision mediump float;\n" "struct info {\n" " vec4 pos;\n" " vec4 color;\n" "};\n" "\n" "uniform info uni;\n" "void main()\n" "{\n" " gl_Position = uni.pos;\n" "}\n"; GLuint vs = CompileShader(GL_VERTEX_SHADER, vsSource); ASSERT_NE(0u, vs); glDeleteShader(vs); const char *fsSource = "// Structures must have the same name, sequence of type names, and\n" "// type definitions, and field names to be considered the same type.\n" "// GLSL 1.017 4.2.4\n" "precision mediump float;\n" "struct info1 {\n" " vec4 pos;\n" " vec4 color;\n" "};\n" "\n" "uniform info1 uni;\n" "void main()\n" "{\n" " gl_FragColor = uni.color;\n" "}\n"; GLuint fs = CompileShader(GL_FRAGMENT_SHADER, fsSource); ASSERT_NE(0u, fs); glDeleteShader(fs); GLuint program = CompileProgram(vsSource, fsSource); EXPECT_EQ(0u, program); } // Test that an uninitialized nameless struct inside a for loop init statement works. TEST_P(GLSLTest_ES3, UninitializedNamelessStructInForInitStatement) { if (IsAndroid() && IsOpenGLES()) { // http://anglebug.com/2046 std::cout << "Test skipped on Android GLES because local variable initialization is disabled." << std::endl; return; } if (IsOSX() && IsOpenGL()) { // http://anglebug.com/2041 std::cout << "Test skipped on Mac OpenGL because local variable initialization is disabled." << std::endl; return; } const std::string &fragmentShader = "#version 300 es\n" "precision highp float;\n" "out vec4 my_FragColor;\n" "void main()\n" "{\n" " my_FragColor = vec4(1, 0, 0, 1);\n" " for (struct { float q; } b; b.q < 2.0; b.q++) {\n" " my_FragColor = vec4(0, 1, 0, 1);\n" " }\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test that uninitialized global variables are initialized to 0. TEST_P(WebGLGLSLTest, InitUninitializedGlobals) { const std::string &fragmentShader = "precision mediump float;\n" "int result;\n" "int i[2], j = i[0] + 1;\n" "void main()\n" "{\n" " result += j;\n" " if (result == 1)\n" " {\n" " gl_FragColor = vec4(0, 1, 0, 1);\n" " }\n" " else\n" " {\n" " gl_FragColor = vec4(1, 0, 0, 1);\n" " }\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f, 1.0f, true); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test that an uninitialized nameless struct in the global scope works. TEST_P(WebGLGLSLTest, UninitializedNamelessStructInGlobalScope) { const std::string &fragmentShader = "precision mediump float;\n" "struct { float q; } b;\n" "void main()\n" "{\n" " gl_FragColor = vec4(1, 0, 0, 1);\n" " if (b.q == 0.0)\n" " {\n" " gl_FragColor = vec4(0, 1, 0, 1);\n" " }\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f, 1.0f, true); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test that a loop condition that has an initializer declares a variable. TEST_P(GLSLTest_ES3, ConditionInitializerDeclaresVariable) { const std::string &fragmentShader = "#version 300 es\n" "precision highp float;\n" "out vec4 my_FragColor;\n" "void main()\n" "{\n" " float i = 0.0;\n" " while (bool foo = (i < 1.5))\n" " {\n" " if (!foo)\n" " {\n" " ++i;\n" " }\n" " if (i > 3.5)\n" " {\n" " break;\n" " }\n" " ++i;\n" " }\n" " my_FragColor = vec4(i * 0.5 - 1.0, i * 0.5, 0.0, 1.0);\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test that a variable hides a user-defined function with the same name after its initializer. // GLSL ES 1.00.17 section 4.2.2: "A variable declaration is visible immediately following the // initializer if present, otherwise immediately following the identifier" TEST_P(GLSLTest, VariableHidesUserDefinedFunctionAfterInitializer) { const std::string &fragmentShader = "precision mediump float;\n" "uniform vec4 u;\n" "vec4 foo()\n" "{\n" " return u;\n" "}\n" "void main()\n" "{\n" " vec4 foo = foo();\n" " gl_FragColor = foo + vec4(0, 1, 0, 1);\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test that structs with identical members are not ambiguous as function arguments. TEST_P(GLSLTest, StructsWithSameMembersDisambiguatedByName) { const std::string &fragmentShader = "precision mediump float;\n" "uniform float u_zero;\n" "struct S { float foo; };\n" "struct S2 { float foo; };\n" "float get(S s) { return s.foo + u_zero; }\n" "float get(S2 s2) { return 0.25 + s2.foo + u_zero; }\n" "void main()\n" "{\n" " S s;\n" " s.foo = 0.5;\n" " S2 s2;\n" " s2.foo = 0.25;\n" " gl_FragColor = vec4(0.0, get(s) + get(s2), 0.0, 1.0);\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test that a varying struct that's not statically used in the fragment shader works. // GLSL ES 3.00.6 section 4.3.10. TEST_P(GLSLTest_ES3, VaryingStructNotStaticallyUsedInFragmentShader) { const std::string &vertexShader = "#version 300 es\n" "struct S {\n" " vec4 field;\n" "};\n" "out S varStruct;\n" "void main()\n" "{\n" " gl_Position = vec4(1.0);\n" " varStruct.field = vec4(0.0, 0.5, 0.0, 0.0);\n" "}\n"; const std::string &fragmentShader = "#version 300 es\n" "precision mediump float;\n" "struct S {\n" " vec4 field;\n" "};\n" "in S varStruct;\n" "out vec4 col;\n" "void main()\n" "{\n" " col = vec4(1.0);\n" "}\n"; ANGLE_GL_PROGRAM(program, vertexShader, fragmentShader); } // Test that a varying struct that's not declared in the fragment shader links successfully. // GLSL ES 3.00.6 section 4.3.10. TEST_P(GLSLTest_ES3, VaryingStructNotDeclaredInFragmentShader) { const std::string &vertexShader = "#version 300 es\n" "struct S {\n" " vec4 field;\n" "};\n" "out S varStruct;\n" "void main()\n" "{\n" " gl_Position = vec4(1.0);\n" " varStruct.field = vec4(0.0, 0.5, 0.0, 0.0);\n" "}\n"; const std::string &fragmentShader = "#version 300 es\n" "precision mediump float;\n" "out vec4 col;\n" "void main()\n" "{\n" " col = vec4(1.0);\n" "}\n"; ANGLE_GL_PROGRAM(program, vertexShader, fragmentShader); } // Test that a varying struct that gets used in the fragment shader works. TEST_P(GLSLTest_ES3, VaryingStructUsedInFragmentShader) { const std::string &vertexShader = "#version 300 es\n" "in vec4 inputAttribute;\n" "struct S {\n" " vec4 field;\n" "};\n" "out S varStruct;\n" "void main()\n" "{\n" " gl_Position = inputAttribute;\n" " varStruct.field = vec4(0.0, 1.0, 0.0, 1.0);\n" "}\n"; const std::string &fragmentShader = "#version 300 es\n" "precision mediump float;\n" "out vec4 col;\n" "struct S {\n" " vec4 field;\n" "};\n" "in S varStruct;\n" "void main()\n" "{\n" " col = varStruct.field;\n" "}\n"; ANGLE_GL_PROGRAM(program, vertexShader, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // This test covers passing an array of structs containing samplers as a function argument. TEST_P(GLSLTest, ArrayOfStructsWithSamplersAsFunctionArg) { if (IsAndroid() && IsAdreno() && IsOpenGLES()) { // Shader failed to compile on Android. http://anglebug.com/2114 std::cout << "Test skipped on Adreno OpenGLES on Android." << std::endl; return; } const std::string &vertexShader = "attribute vec2 position;\n" "void main()\n" "{\n" " gl_Position = vec4(position, 0, 1);\n" "}\n"; const std::string &fragmentShader = "precision mediump float;\n" "struct S\n" "{\n" " sampler2D samplerMember; \n" "};\n" "uniform S uStructs[2];\n" "uniform vec2 uTexCoord;\n" "\n" "vec4 foo(S[2] structs)\n" "{\n" " return texture2D(structs[0].samplerMember, uTexCoord);\n" "}\n" "void main()\n" "{\n" " gl_FragColor = foo(uStructs);\n" "}\n"; ANGLE_GL_PROGRAM(program, vertexShader, fragmentShader); // Initialize the texture with green. GLTexture tex; glActiveTexture(GL_TEXTURE0); glBindTexture(GL_TEXTURE_2D, tex); GLubyte texData[] = {0u, 255u, 0u, 255u}; glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, 1, 1, 0, GL_RGBA, GL_UNSIGNED_BYTE, texData); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST); ASSERT_GL_NO_ERROR(); // Draw glUseProgram(program); GLint samplerMemberLoc = glGetUniformLocation(program, "uStructs[0].samplerMember"); ASSERT_NE(-1, samplerMemberLoc); glUniform1i(samplerMemberLoc, 0); GLint texCoordLoc = glGetUniformLocation(program, "uTexCoord"); ASSERT_NE(-1, texCoordLoc); glUniform2f(texCoordLoc, 0.5f, 0.5f); drawQuad(program, "position", 0.5f); ASSERT_GL_NO_ERROR(); EXPECT_PIXEL_COLOR_EQ(1, 1, GLColor::green); } // This test covers passing a struct containing an array of samplers as a function argument. TEST_P(GLSLTest, StructWithSamplerArrayAsFunctionArg) { if (IsAndroid() && IsAdreno() && IsOpenGLES()) { // Shader failed to compile on Android. http://anglebug.com/2114 std::cout << "Test skipped on Adreno OpenGLES on Android." << std::endl; return; } const std::string &vertexShader = "attribute vec2 position;\n" "void main()\n" "{\n" " gl_Position = vec4(position, 0, 1);\n" "}\n"; const std::string &fragmentShader = "precision mediump float;\n" "struct S\n" "{\n" " sampler2D samplerMembers[2];\n" "};\n" "uniform S uStruct;\n" "uniform vec2 uTexCoord;\n" "\n" "vec4 foo(S str)\n" "{\n" " return texture2D(str.samplerMembers[0], uTexCoord);\n" "}\n" "void main()\n" "{\n" " gl_FragColor = foo(uStruct);\n" "}\n"; ANGLE_GL_PROGRAM(program, vertexShader, fragmentShader); // Initialize the texture with green. GLTexture tex; glActiveTexture(GL_TEXTURE0); glBindTexture(GL_TEXTURE_2D, tex); GLubyte texData[] = {0u, 255u, 0u, 255u}; glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, 1, 1, 0, GL_RGBA, GL_UNSIGNED_BYTE, texData); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST); ASSERT_GL_NO_ERROR(); // Draw glUseProgram(program); GLint samplerMemberLoc = glGetUniformLocation(program, "uStruct.samplerMembers[0]"); ASSERT_NE(-1, samplerMemberLoc); glUniform1i(samplerMemberLoc, 0); GLint texCoordLoc = glGetUniformLocation(program, "uTexCoord"); ASSERT_NE(-1, texCoordLoc); glUniform2f(texCoordLoc, 0.5f, 0.5f); drawQuad(program, "position", 0.5f); ASSERT_GL_NO_ERROR(); EXPECT_PIXEL_COLOR_EQ(1, 1, GLColor::green); } // Test that a global variable declared after main() works. This is a regression test for an issue // in global variable initialization. TEST_P(WebGLGLSLTest, GlobalVariableDeclaredAfterMain) { const std::string &fragmentShader = "precision mediump float;\n" "int getFoo();\n" "uniform int u_zero;\n" "void main()\n" "{\n" " gl_FragColor = vec4(1, 0, 0, 1);\n" " if (getFoo() == 0)\n" " {\n" " gl_FragColor = vec4(0, 1, 0, 1);\n" " }\n" "}\n" "int foo;\n" "int getFoo()\n" "{\n" " foo = u_zero;\n" " return foo;\n" "}\n"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f, 1.0f, true); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test calling array length() with a "this" expression having side effects inside a loop condition. // The spec says that sequence operator operands need to run in sequence. TEST_P(GLSLTest_ES3, ArrayLengthOnExpressionWithSideEffectsInLoopCondition) { // "a" gets doubled three times in the below program. const std::string &fragmentShader = R"(#version 300 es precision highp float; out vec4 my_FragColor; uniform int u_zero; int a; int[2] doubleA() { a *= 2; return int[2](a, a); } void main() { a = u_zero + 1; for (int i = 0; i < doubleA().length(); ++i) {} if (a == 8) { my_FragColor = vec4(0, 1, 0, 1); } else { my_FragColor = vec4(1, 0, 0, 1); } })"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test calling array length() with a "this" expression having side effects that interact with side // effects of another operand of the same sequence operator. The spec says that sequence operator // operands need to run in order from left to right (ESSL 3.00.6 section 5.9). TEST_P(GLSLTest_ES3, ArrayLengthOnExpressionWithSideEffectsInSequence) { const std::string &fragmentShader = R"(#version 300 es precision highp float; out vec4 my_FragColor; uniform int u_zero; int a; int[3] doubleA() { a *= 2; return int[3](a, a, a); } void main() { a = u_zero; int b = (a++, doubleA().length()); if (b == 3 && a == 2) { my_FragColor = vec4(0, 1, 0, 1); } else { my_FragColor = vec4(1, 0, 0, 1); } })"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Test calling array length() with a "this" expression that also contains a call of array length(). // Both "this" expressions also have side effects. TEST_P(GLSLTest_ES3, NestedArrayLengthMethodsWithSideEffects) { const std::string &fragmentShader = R"(#version 300 es precision highp float; out vec4 my_FragColor; uniform int u_zero; int a; int[3] multiplyA(int multiplier) { a *= multiplier; return int[3](a, a, a); } void main() { a = u_zero + 1; int b = multiplyA(multiplyA(2).length()).length(); if (b == 3 && a == 6) { my_FragColor = vec4(0, 1, 0, 1); } else { my_FragColor = vec4(1, 0, 0, 1); } })"; ANGLE_GL_PROGRAM(program, mSimpleVSSource, fragmentShader); drawQuad(program.get(), "inputAttribute", 0.5f); EXPECT_PIXEL_COLOR_EQ(0, 0, GLColor::green); } // Use this to select which configurations (e.g. which renderer, which GLES major version) these tests should be run against. ANGLE_INSTANTIATE_TEST(GLSLTest, ES2_D3D9(), ES2_D3D11(), ES2_D3D11_FL9_3(), ES2_OPENGL(), ES3_OPENGL(), ES2_OPENGLES(), ES3_OPENGLES()); // Use this to select which configurations (e.g. which renderer, which GLES major version) these tests should be run against. ANGLE_INSTANTIATE_TEST(GLSLTest_ES3, ES3_D3D11(), ES3_OPENGL(), ES3_OPENGLES()); ANGLE_INSTANTIATE_TEST(WebGLGLSLTest, ES2_D3D11(), ES2_OPENGL(), ES2_OPENGLES()); ANGLE_INSTANTIATE_TEST(GLSLTest_ES31, ES31_D3D11(), ES31_OPENGL(), ES31_OPENGLES());