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kc3-lang/angle/src/libANGLE/validationES.cpp
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Author :
Geoff Lang
Date : 2016-10-31 14:08:10
Hash : 3b573612
Message : Add enough ES 3.1 enums to support initializing the dEQP ES 3.1 tests. BUG=angleproject:1442 Change-Id: Iece3efb272fdcbe004d4136129ba7bfe74ba5265 Reviewed-on: https://chromium-review.googlesource.com/405530 Reviewed-by: Jamie Madill <jmadill@chromium.org> Reviewed-by: Corentin Wallez <cwallez@chromium.org> Commit-Queue: Geoff Lang <geofflang@chromium.org>
- src/libANGLE/validationES.cpp
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// // Copyright (c) 2013-2014 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. // // validationES.h: Validation functions for generic OpenGL ES entry point parameters #include "libANGLE/validationES.h" #include "libANGLE/validationES2.h" #include "libANGLE/validationES3.h" #include "libANGLE/Context.h" #include "libANGLE/Display.h" #include "libANGLE/Texture.h" #include "libANGLE/Framebuffer.h" #include "libANGLE/FramebufferAttachment.h" #include "libANGLE/formatutils.h" #include "libANGLE/Image.h" #include "libANGLE/Query.h" #include "libANGLE/Program.h" #include "libANGLE/Uniform.h" #include "libANGLE/TransformFeedback.h" #include "libANGLE/VertexArray.h" #include "common/mathutil.h" #include "common/utilities.h" using namespace angle; namespace gl { const char *g_ExceedsMaxElementErrorMessage = "Element value exceeds maximum element index."; namespace { bool ValidateDrawAttribs(ValidationContext *context, GLint primcount, GLint maxVertex) { const gl::State &state = context->getGLState(); const gl::Program *program = state.getProgram(); const VertexArray *vao = state.getVertexArray(); const auto &vertexAttribs = vao->getVertexAttributes(); size_t maxEnabledAttrib = vao->getMaxEnabledAttribute(); for (size_t attributeIndex = 0; attributeIndex < maxEnabledAttrib; ++attributeIndex) { const VertexAttribute &attrib = vertexAttribs[attributeIndex]; if (program->isAttribLocationActive(attributeIndex) && attrib.enabled) { gl::Buffer *buffer = attrib.buffer.get(); if (buffer) { GLint64 attribStride = static_cast<GLint64>(ComputeVertexAttributeStride(attrib)); GLint64 maxVertexElement = 0; if (attrib.divisor > 0) { maxVertexElement = static_cast<GLint64>(primcount) / static_cast<GLint64>(attrib.divisor); } else { maxVertexElement = static_cast<GLint64>(maxVertex); } // If we're drawing zero vertices, we have enough data. if (maxVertexElement > 0) { // Note: Last vertex element does not take the full stride! GLint64 attribSize = static_cast<GLint64>(ComputeVertexAttributeTypeSize(attrib)); GLint64 attribDataSize = (maxVertexElement - 1) * attribStride + attribSize; GLint64 attribOffset = static_cast<GLint64>(attrib.offset); // [OpenGL ES 3.0.2] section 2.9.4 page 40: // We can return INVALID_OPERATION if our vertex attribute does not have // enough backing data. if (attribDataSize + attribOffset > buffer->getSize()) { context->handleError( Error(GL_INVALID_OPERATION, "Vertex buffer is not big enough for the draw call")); return false; } } } else if (attrib.pointer == NULL) { // This is an application error that would normally result in a crash, // but we catch it and return an error context->handleError(Error( GL_INVALID_OPERATION, "An enabled vertex array has no buffer and no pointer.")); return false; } } } return true; } bool ValidReadPixelsFormatType(ValidationContext *context, GLenum framebufferComponentType, GLenum format, GLenum type) { switch (framebufferComponentType) { case GL_UNSIGNED_NORMALIZED: // TODO(geofflang): Don't accept BGRA here. Some chrome internals appear to try to use // ReadPixels with BGRA even if the extension is not present return (format == GL_RGBA && type == GL_UNSIGNED_BYTE) || (context->getExtensions().readFormatBGRA && format == GL_BGRA_EXT && type == GL_UNSIGNED_BYTE); case GL_SIGNED_NORMALIZED: return (format == GL_RGBA && type == GL_UNSIGNED_BYTE); case GL_INT: return (format == GL_RGBA_INTEGER && type == GL_INT); case GL_UNSIGNED_INT: return (format == GL_RGBA_INTEGER && type == GL_UNSIGNED_INT); case GL_FLOAT: return (format == GL_RGBA && type == GL_FLOAT); default: UNREACHABLE(); return false; } } bool ValidCap(const Context *context, GLenum cap, bool queryOnly) { switch (cap) { // EXT_multisample_compatibility case GL_MULTISAMPLE_EXT: case GL_SAMPLE_ALPHA_TO_ONE_EXT: return context->getExtensions().multisampleCompatibility; case GL_CULL_FACE: case GL_POLYGON_OFFSET_FILL: case GL_SAMPLE_ALPHA_TO_COVERAGE: case GL_SAMPLE_COVERAGE: case GL_SCISSOR_TEST: case GL_STENCIL_TEST: case GL_DEPTH_TEST: case GL_BLEND: case GL_DITHER: return true; case GL_PRIMITIVE_RESTART_FIXED_INDEX: case GL_RASTERIZER_DISCARD: return (context->getClientMajorVersion() >= 3); case GL_DEBUG_OUTPUT_SYNCHRONOUS: case GL_DEBUG_OUTPUT: return context->getExtensions().debug; case GL_BIND_GENERATES_RESOURCE_CHROMIUM: return queryOnly && context->getExtensions().bindGeneratesResource; case GL_FRAMEBUFFER_SRGB_EXT: return context->getExtensions().sRGBWriteControl; case GL_SAMPLE_MASK: UNIMPLEMENTED(); return context->getClientVersion() >= Version(3, 1); default: return false; } } bool ValidateReadPixelsBase(ValidationContext *context, GLint x, GLint y, GLsizei width, GLsizei height, GLenum format, GLenum type, GLsizei bufSize, GLsizei *length, GLvoid *pixels) { if (length != nullptr) { *length = 0; } if (width < 0 || height < 0) { context->handleError(Error(GL_INVALID_VALUE, "width and height must be positive")); return false; } auto readFramebuffer = context->getGLState().getReadFramebuffer(); if (readFramebuffer->checkStatus(context->getContextState()) != GL_FRAMEBUFFER_COMPLETE) { context->handleError(Error(GL_INVALID_FRAMEBUFFER_OPERATION)); return false; } if (readFramebuffer->id() != 0 && readFramebuffer->getSamples(context->getContextState()) != 0) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } const Framebuffer *framebuffer = context->getGLState().getReadFramebuffer(); ASSERT(framebuffer); if (framebuffer->getReadBufferState() == GL_NONE) { context->handleError(Error(GL_INVALID_OPERATION, "Read buffer is GL_NONE")); return false; } const FramebufferAttachment *readBuffer = framebuffer->getReadColorbuffer(); if (!readBuffer) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } GLenum currentFormat = framebuffer->getImplementationColorReadFormat(); GLenum currentType = framebuffer->getImplementationColorReadType(); GLenum currentInternalFormat = readBuffer->getFormat().asSized(); const gl::InternalFormat &internalFormatInfo = gl::GetInternalFormatInfo(currentInternalFormat); bool validFormatTypeCombination = ValidReadPixelsFormatType(context, internalFormatInfo.componentType, format, type); if (!(currentFormat == format && currentType == type) && !validFormatTypeCombination) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } // Check for pixel pack buffer related API errors gl::Buffer *pixelPackBuffer = context->getGLState().getTargetBuffer(GL_PIXEL_PACK_BUFFER); if (pixelPackBuffer != nullptr && pixelPackBuffer->isMapped()) { // ...the buffer object's data store is currently mapped. context->handleError(Error(GL_INVALID_OPERATION, "Pixel pack buffer is mapped.")); return false; } // .. the data would be packed to the buffer object such that the memory writes required // would exceed the data store size. GLenum sizedInternalFormat = GetSizedInternalFormat(format, type); const InternalFormat &formatInfo = GetInternalFormatInfo(sizedInternalFormat); const gl::Extents size(width, height, 1); const auto &pack = context->getGLState().getPackState(); auto endByteOrErr = formatInfo.computePackUnpackEndByte(type, size, pack, false); if (endByteOrErr.isError()) { context->handleError(endByteOrErr.getError()); return false; } size_t endByte = endByteOrErr.getResult(); if (bufSize >= 0) { if (static_cast<size_t>(bufSize) < endByte) { context->handleError( Error(GL_INVALID_OPERATION, "bufSize must be at least %u bytes.", endByte)); return false; } } if (pixelPackBuffer != nullptr) { CheckedNumeric<size_t> checkedEndByte(endByte); CheckedNumeric<size_t> checkedOffset(reinterpret_cast<size_t>(pixels)); checkedEndByte += checkedOffset; if (checkedEndByte.ValueOrDie() > static_cast<size_t>(pixelPackBuffer->getSize())) { // Overflow past the end of the buffer context->handleError( Error(GL_INVALID_OPERATION, "Writes would overflow the pixel pack buffer.")); return false; } } if (length != nullptr) { if (endByte > static_cast<size_t>(std::numeric_limits<GLsizei>::max())) { context->handleError( Error(GL_INVALID_OPERATION, "length would overflow GLsizei.", endByte)); return false; } *length = static_cast<GLsizei>(endByte); } return true; } bool ValidateGetRenderbufferParameterivBase(Context *context, GLenum target, GLenum pname, GLsizei *length) { if (length) { *length = 0; } if (target != GL_RENDERBUFFER) { context->handleError(Error(GL_INVALID_ENUM, "Invalid target.")); return false; } Renderbuffer *renderbuffer = context->getGLState().getCurrentRenderbuffer(); if (renderbuffer == nullptr) { context->handleError(Error(GL_INVALID_OPERATION, "No renderbuffer bound.")); return false; } switch (pname) { case GL_RENDERBUFFER_WIDTH: case GL_RENDERBUFFER_HEIGHT: case GL_RENDERBUFFER_INTERNAL_FORMAT: case GL_RENDERBUFFER_RED_SIZE: case GL_RENDERBUFFER_GREEN_SIZE: case GL_RENDERBUFFER_BLUE_SIZE: case GL_RENDERBUFFER_ALPHA_SIZE: case GL_RENDERBUFFER_DEPTH_SIZE: case GL_RENDERBUFFER_STENCIL_SIZE: break; case GL_RENDERBUFFER_SAMPLES_ANGLE: if (!context->getExtensions().framebufferMultisample) { context->handleError( Error(GL_INVALID_ENUM, "GL_ANGLE_framebuffer_multisample is not enabled.")); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown pname.")); return false; } if (length) { *length = 1; } return true; } bool ValidateGetShaderivBase(Context *context, GLuint shader, GLenum pname, GLsizei *length) { if (length) { *length = 0; } if (GetValidShader(context, shader) == nullptr) { return false; } switch (pname) { case GL_SHADER_TYPE: case GL_DELETE_STATUS: case GL_COMPILE_STATUS: case GL_INFO_LOG_LENGTH: case GL_SHADER_SOURCE_LENGTH: break; case GL_TRANSLATED_SHADER_SOURCE_LENGTH_ANGLE: if (!context->getExtensions().translatedShaderSource) { context->handleError( Error(GL_INVALID_ENUM, "GL_ANGLE_translated_shader_source is not enabled.")); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown pname.")); return false; } if (length) { *length = 1; } return true; } bool ValidateGetTexParameterBase(Context *context, GLenum target, GLenum pname, GLsizei *length) { if (length) { *length = 0; } if (!ValidTextureTarget(context, target) && !ValidTextureExternalTarget(context, target)) { context->handleError(Error(GL_INVALID_ENUM, "Invalid texture target")); return false; } if (context->getTargetTexture(target) == nullptr) { // Should only be possible for external textures context->handleError(Error(GL_INVALID_ENUM, "No texture bound.")); return false; } switch (pname) { case GL_TEXTURE_MAG_FILTER: case GL_TEXTURE_MIN_FILTER: case GL_TEXTURE_WRAP_S: case GL_TEXTURE_WRAP_T: break; case GL_TEXTURE_USAGE_ANGLE: if (!context->getExtensions().textureUsage) { context->handleError( Error(GL_INVALID_ENUM, "GL_ANGLE_texture_usage is not enabled.")); return false; } break; case GL_TEXTURE_MAX_ANISOTROPY_EXT: if (!context->getExtensions().textureFilterAnisotropic) { context->handleError( Error(GL_INVALID_ENUM, "GL_EXT_texture_filter_anisotropic is not enabled.")); return false; } break; case GL_TEXTURE_IMMUTABLE_FORMAT: if (context->getClientMajorVersion() < 3 && !context->getExtensions().textureStorage) { context->handleError( Error(GL_INVALID_ENUM, "GL_EXT_texture_storage is not enabled.")); return false; } break; case GL_TEXTURE_WRAP_R: case GL_TEXTURE_IMMUTABLE_LEVELS: case GL_TEXTURE_SWIZZLE_R: case GL_TEXTURE_SWIZZLE_G: case GL_TEXTURE_SWIZZLE_B: case GL_TEXTURE_SWIZZLE_A: case GL_TEXTURE_BASE_LEVEL: case GL_TEXTURE_MAX_LEVEL: case GL_TEXTURE_MIN_LOD: case GL_TEXTURE_MAX_LOD: case GL_TEXTURE_COMPARE_MODE: case GL_TEXTURE_COMPARE_FUNC: if (context->getClientMajorVersion() < 3) { context->handleError(Error(GL_INVALID_ENUM, "pname requires OpenGL ES 3.0.")); return false; } break; case GL_TEXTURE_SRGB_DECODE_EXT: if (!context->getExtensions().textureSRGBDecode) { context->handleError( Error(GL_INVALID_ENUM, "GL_EXT_texture_sRGB_decode is not enabled.")); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown pname.")); return false; } if (length) { *length = 1; } return true; } template <typename ParamType> bool ValidateTextureWrapModeValue(Context *context, ParamType *params, bool isExternalTextureTarget) { switch (ConvertToGLenum(params[0])) { case GL_CLAMP_TO_EDGE: break; case GL_REPEAT: case GL_MIRRORED_REPEAT: if (isExternalTextureTarget) { // OES_EGL_image_external specifies this error. context->handleError(Error( GL_INVALID_ENUM, "external textures only support CLAMP_TO_EDGE wrap mode")); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown param value.")); return false; } return true; } template <typename ParamType> bool ValidateTextureMinFilterValue(Context *context, ParamType *params, bool isExternalTextureTarget) { switch (ConvertToGLenum(params[0])) { case GL_NEAREST: case GL_LINEAR: break; case GL_NEAREST_MIPMAP_NEAREST: case GL_LINEAR_MIPMAP_NEAREST: case GL_NEAREST_MIPMAP_LINEAR: case GL_LINEAR_MIPMAP_LINEAR: if (isExternalTextureTarget) { // OES_EGL_image_external specifies this error. context->handleError( Error(GL_INVALID_ENUM, "external textures only support NEAREST and LINEAR filtering")); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown param value.")); return false; } return true; } template <typename ParamType> bool ValidateTextureMagFilterValue(Context *context, ParamType *params) { switch (ConvertToGLenum(params[0])) { case GL_NEAREST: case GL_LINEAR: break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown param value.")); return false; } return true; } template <typename ParamType> bool ValidateTextureCompareModeValue(Context *context, ParamType *params) { // Acceptable mode parameters from GLES 3.0.2 spec, table 3.17 switch (ConvertToGLenum(params[0])) { case GL_NONE: case GL_COMPARE_REF_TO_TEXTURE: break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown param value.")); return false; } return true; } template <typename ParamType> bool ValidateTextureCompareFuncValue(Context *context, ParamType *params) { // Acceptable function parameters from GLES 3.0.2 spec, table 3.17 switch (ConvertToGLenum(params[0])) { case GL_LEQUAL: case GL_GEQUAL: case GL_LESS: case GL_GREATER: case GL_EQUAL: case GL_NOTEQUAL: case GL_ALWAYS: case GL_NEVER: break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown param value.")); return false; } return true; } template <typename ParamType> bool ValidateTextureSRGBDecodeValue(Context *context, ParamType *params) { if (!context->getExtensions().textureSRGBDecode) { context->handleError(Error(GL_INVALID_ENUM, "GL_EXT_texture_sRGB_decode is not enabled.")); return false; } switch (ConvertToGLenum(params[0])) { case GL_DECODE_EXT: case GL_SKIP_DECODE_EXT: break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown param value.")); return false; } return true; } template <typename ParamType> bool ValidateTexParameterBase(Context *context, GLenum target, GLenum pname, GLsizei bufSize, ParamType *params) { if (!ValidTextureTarget(context, target) && !ValidTextureExternalTarget(context, target)) { context->handleError(Error(GL_INVALID_ENUM, "Invalid texture target")); return false; } if (context->getTargetTexture(target) == nullptr) { // Should only be possible for external textures context->handleError(Error(GL_INVALID_ENUM, "No texture bound.")); return false; } const GLsizei minBufSize = 1; if (bufSize >= 0 && bufSize < minBufSize) { context->handleError( Error(GL_INVALID_OPERATION, "bufSize must be at least %i.", minBufSize)); return false; } switch (pname) { case GL_TEXTURE_WRAP_R: case GL_TEXTURE_SWIZZLE_R: case GL_TEXTURE_SWIZZLE_G: case GL_TEXTURE_SWIZZLE_B: case GL_TEXTURE_SWIZZLE_A: case GL_TEXTURE_BASE_LEVEL: case GL_TEXTURE_MAX_LEVEL: case GL_TEXTURE_COMPARE_MODE: case GL_TEXTURE_COMPARE_FUNC: case GL_TEXTURE_MIN_LOD: case GL_TEXTURE_MAX_LOD: if (context->getClientMajorVersion() < 3) { context->handleError(Error(GL_INVALID_ENUM, "pname requires OpenGL ES 3.0.")); return false; } if (target == GL_TEXTURE_EXTERNAL_OES && !context->getExtensions().eglImageExternalEssl3) { context->handleError(Error(GL_INVALID_ENUM, "ES3 texture parameters are not available without " "GL_OES_EGL_image_external_essl3.")); return false; } break; default: break; } switch (pname) { case GL_TEXTURE_WRAP_S: case GL_TEXTURE_WRAP_T: case GL_TEXTURE_WRAP_R: if (!ValidateTextureWrapModeValue(context, params, target == GL_TEXTURE_EXTERNAL_OES)) { return false; } break; case GL_TEXTURE_MIN_FILTER: if (!ValidateTextureMinFilterValue(context, params, target == GL_TEXTURE_EXTERNAL_OES)) { return false; } break; case GL_TEXTURE_MAG_FILTER: if (!ValidateTextureMagFilterValue(context, params)) { return false; } break; case GL_TEXTURE_USAGE_ANGLE: switch (ConvertToGLenum(params[0])) { case GL_NONE: case GL_FRAMEBUFFER_ATTACHMENT_ANGLE: break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown param value.")); return false; } break; case GL_TEXTURE_MAX_ANISOTROPY_EXT: if (!context->getExtensions().textureFilterAnisotropic) { context->handleError( Error(GL_INVALID_ENUM, "GL_EXT_texture_anisotropic is not enabled.")); return false; } // we assume the parameter passed to this validation method is truncated, not rounded if (params[0] < 1) { context->handleError(Error(GL_INVALID_VALUE, "Max anisotropy must be at least 1.")); return false; } break; case GL_TEXTURE_MIN_LOD: case GL_TEXTURE_MAX_LOD: // any value is permissible break; case GL_TEXTURE_COMPARE_MODE: if (!ValidateTextureCompareModeValue(context, params)) { return false; } break; case GL_TEXTURE_COMPARE_FUNC: if (!ValidateTextureCompareFuncValue(context, params)) { return false; } break; case GL_TEXTURE_SWIZZLE_R: case GL_TEXTURE_SWIZZLE_G: case GL_TEXTURE_SWIZZLE_B: case GL_TEXTURE_SWIZZLE_A: switch (ConvertToGLenum(params[0])) { case GL_RED: case GL_GREEN: case GL_BLUE: case GL_ALPHA: case GL_ZERO: case GL_ONE: break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown param value.")); return false; } break; case GL_TEXTURE_BASE_LEVEL: if (params[0] < 0) { context->handleError(Error(GL_INVALID_VALUE, "Base level must be at least 0.")); return false; } if (target == GL_TEXTURE_EXTERNAL_OES && static_cast<GLuint>(params[0]) != 0) { context->handleError( Error(GL_INVALID_OPERATION, "Base level must be 0 for external textures.")); return false; } break; case GL_TEXTURE_MAX_LEVEL: if (params[0] < 0) { context->handleError(Error(GL_INVALID_VALUE, "Max level must be at least 0.")); return false; } break; case GL_DEPTH_STENCIL_TEXTURE_MODE: if (context->getClientVersion() < Version(3, 1)) { context->handleError(Error(GL_INVALID_ENUM, "pname requires OpenGL ES 3.1.")); return false; } UNIMPLEMENTED(); break; case GL_TEXTURE_SRGB_DECODE_EXT: if (!ValidateTextureSRGBDecodeValue(context, params)) { return false; } break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown pname.")); return false; } return true; } template <typename ParamType> bool ValidateSamplerParameterBase(Context *context, GLuint sampler, GLenum pname, GLsizei bufSize, ParamType *params) { if (context->getClientMajorVersion() < 3) { context->handleError( Error(GL_INVALID_OPERATION, "Context does not support OpenGL ES 3.0.")); return false; } if (!context->isSampler(sampler)) { context->handleError(Error(GL_INVALID_OPERATION, "Sampler is not valid.")); return false; } const GLsizei minBufSize = 1; if (bufSize >= 0 && bufSize < minBufSize) { context->handleError( Error(GL_INVALID_OPERATION, "bufSize must be at least %i.", minBufSize)); return false; } switch (pname) { case GL_TEXTURE_WRAP_S: case GL_TEXTURE_WRAP_T: case GL_TEXTURE_WRAP_R: if (!ValidateTextureWrapModeValue(context, params, false)) { return false; } break; case GL_TEXTURE_MIN_FILTER: if (!ValidateTextureMinFilterValue(context, params, false)) { return false; } break; case GL_TEXTURE_MAG_FILTER: if (!ValidateTextureMagFilterValue(context, params)) { return false; } break; case GL_TEXTURE_MIN_LOD: case GL_TEXTURE_MAX_LOD: // any value is permissible break; case GL_TEXTURE_COMPARE_MODE: if (!ValidateTextureCompareModeValue(context, params)) { return false; } break; case GL_TEXTURE_COMPARE_FUNC: if (!ValidateTextureCompareFuncValue(context, params)) { return false; } break; case GL_TEXTURE_SRGB_DECODE_EXT: if (!ValidateTextureSRGBDecodeValue(context, params)) { return false; } break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown pname.")); return false; } return true; } bool ValidateGetSamplerParameterBase(Context *context, GLuint sampler, GLenum pname, GLsizei *length) { if (length) { *length = 0; } if (context->getClientMajorVersion() < 3) { context->handleError( Error(GL_INVALID_OPERATION, "Context does not support OpenGL ES 3.0.")); return false; } if (!context->isSampler(sampler)) { context->handleError(Error(GL_INVALID_OPERATION, "Sampler is not valid.")); return false; } switch (pname) { case GL_TEXTURE_WRAP_S: case GL_TEXTURE_WRAP_T: case GL_TEXTURE_WRAP_R: case GL_TEXTURE_MIN_FILTER: case GL_TEXTURE_MAG_FILTER: case GL_TEXTURE_MIN_LOD: case GL_TEXTURE_MAX_LOD: case GL_TEXTURE_COMPARE_MODE: case GL_TEXTURE_COMPARE_FUNC: break; case GL_TEXTURE_SRGB_DECODE_EXT: if (!context->getExtensions().textureSRGBDecode) { context->handleError( Error(GL_INVALID_ENUM, "GL_EXT_texture_sRGB_decode is not enabled.")); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown pname.")); return false; } if (length) { *length = 1; } return true; } bool ValidateGetVertexAttribBase(Context *context, GLuint index, GLenum pname, GLsizei *length, bool pointer, bool pureIntegerEntryPoint) { if (length) { *length = 0; } if (pureIntegerEntryPoint && context->getClientMajorVersion() < 3) { context->handleError( Error(GL_INVALID_OPERATION, "Context does not support OpenGL ES 3.0.")); return false; } if (index >= context->getCaps().maxVertexAttributes) { context->handleError(Error( GL_INVALID_VALUE, "index must be less than the value of GL_MAX_VERTEX_ATTRIBUTES.")); return false; } if (pointer) { if (pname != GL_VERTEX_ATTRIB_ARRAY_POINTER) { context->handleError(Error(GL_INVALID_ENUM, "Unknown pname.")); return false; } } else { switch (pname) { case GL_VERTEX_ATTRIB_ARRAY_ENABLED: case GL_VERTEX_ATTRIB_ARRAY_SIZE: case GL_VERTEX_ATTRIB_ARRAY_STRIDE: case GL_VERTEX_ATTRIB_ARRAY_TYPE: case GL_VERTEX_ATTRIB_ARRAY_NORMALIZED: case GL_VERTEX_ATTRIB_ARRAY_BUFFER_BINDING: case GL_CURRENT_VERTEX_ATTRIB: break; case GL_VERTEX_ATTRIB_ARRAY_DIVISOR: static_assert( GL_VERTEX_ATTRIB_ARRAY_DIVISOR == GL_VERTEX_ATTRIB_ARRAY_DIVISOR_ANGLE, "ANGLE extension enums not equal to GL enums."); if (context->getClientMajorVersion() < 3 && !context->getExtensions().instancedArrays) { context->handleError(Error(GL_INVALID_ENUM, "GL_VERTEX_ATTRIB_ARRAY_DIVISOR requires OpenGL ES " "3.0 or GL_ANGLE_instanced_arrays.")); return false; } break; case GL_VERTEX_ATTRIB_ARRAY_INTEGER: if (context->getClientMajorVersion() < 3) { context->handleError(Error(GL_INVALID_ENUM, "pname requires OpenGL ES 3.0.")); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown pname.")); return false; } } if (length) { if (pname == GL_CURRENT_VERTEX_ATTRIB) { *length = 4; } else { *length = 1; } } return true; } bool ValidateGetActiveUniformBlockivBase(Context *context, GLuint program, GLuint uniformBlockIndex, GLenum pname, GLsizei *length) { if (length) { *length = 0; } if (context->getClientMajorVersion() < 3) { context->handleError( Error(GL_INVALID_OPERATION, "Context does not support OpenGL ES 3.0.")); return false; } Program *programObject = GetValidProgram(context, program); if (!programObject) { return false; } if (uniformBlockIndex >= programObject->getActiveUniformBlockCount()) { context->handleError( Error(GL_INVALID_VALUE, "uniformBlockIndex exceeds active uniform block count.")); return false; } switch (pname) { case GL_UNIFORM_BLOCK_BINDING: case GL_UNIFORM_BLOCK_DATA_SIZE: case GL_UNIFORM_BLOCK_NAME_LENGTH: case GL_UNIFORM_BLOCK_ACTIVE_UNIFORMS: case GL_UNIFORM_BLOCK_ACTIVE_UNIFORM_INDICES: case GL_UNIFORM_BLOCK_REFERENCED_BY_VERTEX_SHADER: case GL_UNIFORM_BLOCK_REFERENCED_BY_FRAGMENT_SHADER: break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown pname.")); return false; } if (length) { if (pname == GL_UNIFORM_BLOCK_ACTIVE_UNIFORM_INDICES) { const UniformBlock &uniformBlock = programObject->getUniformBlockByIndex(uniformBlockIndex); *length = static_cast<GLsizei>(uniformBlock.memberUniformIndexes.size()); } else { *length = 1; } } return true; } bool ValidateGetBufferParameterBase(ValidationContext *context, GLenum target, GLenum pname, bool pointerVersion, GLsizei *numParams) { if (numParams) { *numParams = 0; } if (!ValidBufferTarget(context, target)) { context->handleError(Error(GL_INVALID_ENUM, "Invalid buffer target.")); return false; } const Buffer *buffer = context->getGLState().getTargetBuffer(target); if (!buffer) { // A null buffer means that "0" is bound to the requested buffer target context->handleError(Error(GL_INVALID_OPERATION, "No buffer bound.")); return false; } const Extensions &extensions = context->getExtensions(); switch (pname) { case GL_BUFFER_USAGE: case GL_BUFFER_SIZE: break; case GL_BUFFER_ACCESS_OES: if (!extensions.mapBuffer) { context->handleError( Error(GL_INVALID_ENUM, "pname requires OpenGL ES 3.0 or GL_OES_map_buffer.")); return false; } break; case GL_BUFFER_MAPPED: static_assert(GL_BUFFER_MAPPED == GL_BUFFER_MAPPED_OES, "GL enums should be equal."); if (context->getClientMajorVersion() < 3 && !extensions.mapBuffer && !extensions.mapBufferRange) { context->handleError(Error( GL_INVALID_ENUM, "pname requires OpenGL ES 3.0, GL_OES_map_buffer or GL_EXT_map_buffer_range.")); return false; } break; case GL_BUFFER_MAP_POINTER: if (!pointerVersion) { context->handleError( Error(GL_INVALID_ENUM, "GL_BUFFER_MAP_POINTER can only be queried with GetBufferPointerv.")); return false; } break; case GL_BUFFER_ACCESS_FLAGS: case GL_BUFFER_MAP_OFFSET: case GL_BUFFER_MAP_LENGTH: if (context->getClientMajorVersion() < 3 && !extensions.mapBufferRange) { context->handleError(Error( GL_INVALID_ENUM, "pname requires OpenGL ES 3.0 or GL_EXT_map_buffer_range.")); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown pname.")); return false; } // All buffer parameter queries return one value. if (numParams) { *numParams = 1; } return true; } bool ValidateGetInternalFormativBase(Context *context, GLenum target, GLenum internalformat, GLenum pname, GLsizei bufSize, GLsizei *numParams) { if (numParams) { *numParams = 0; } if (context->getClientMajorVersion() < 3) { context->handleError( Error(GL_INVALID_OPERATION, "Context does not support OpenGL ES 3.0.")); return false; } const TextureCaps &formatCaps = context->getTextureCaps().get(internalformat); if (!formatCaps.renderable) { context->handleError(Error(GL_INVALID_ENUM, "Internal format is not renderable.")); return false; } switch (target) { case GL_RENDERBUFFER: break; default: context->handleError(Error(GL_INVALID_ENUM, "Invalid target.")); return false; } if (bufSize < 0) { context->handleError(Error(GL_INVALID_VALUE, "bufSize cannot be negative.")); return false; } GLsizei maxWriteParams = 0; switch (pname) { case GL_NUM_SAMPLE_COUNTS: maxWriteParams = 1; break; case GL_SAMPLES: maxWriteParams = static_cast<GLsizei>(formatCaps.sampleCounts.size()); break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown pname.")); return false; } if (numParams) { // glGetInternalFormativ will not overflow bufSize *numParams = std::min(bufSize, maxWriteParams); } return true; } } // anonymous namespace bool ValidTextureTarget(const ValidationContext *context, GLenum target) { switch (target) { case GL_TEXTURE_2D: case GL_TEXTURE_CUBE_MAP: return true; case GL_TEXTURE_3D: case GL_TEXTURE_2D_ARRAY: return (context->getClientMajorVersion() >= 3); case GL_TEXTURE_2D_MULTISAMPLE: UNIMPLEMENTED(); return (context->getClientVersion() >= Version(3, 1)); default: return false; } } bool ValidTexture2DTarget(const ValidationContext *context, GLenum target) { switch (target) { case GL_TEXTURE_2D: case GL_TEXTURE_CUBE_MAP: return true; default: return false; } } bool ValidTexture3DTarget(const ValidationContext *context, GLenum target) { switch (target) { case GL_TEXTURE_3D: case GL_TEXTURE_2D_ARRAY: return (context->getClientMajorVersion() >= 3); default: return false; } } // Most texture GL calls are not compatible with external textures, so we have a separate validation // function for use in the GL calls that do bool ValidTextureExternalTarget(const ValidationContext *context, GLenum target) { return (target == GL_TEXTURE_EXTERNAL_OES) && (context->getExtensions().eglImageExternal || context->getExtensions().eglStreamConsumerExternal); } // This function differs from ValidTextureTarget in that the target must be // usable as the destination of a 2D operation-- so a cube face is valid, but // GL_TEXTURE_CUBE_MAP is not. // Note: duplicate of IsInternalTextureTarget bool ValidTexture2DDestinationTarget(const ValidationContext *context, GLenum target) { switch (target) { case GL_TEXTURE_2D: case GL_TEXTURE_CUBE_MAP_POSITIVE_X: case GL_TEXTURE_CUBE_MAP_NEGATIVE_X: case GL_TEXTURE_CUBE_MAP_POSITIVE_Y: case GL_TEXTURE_CUBE_MAP_NEGATIVE_Y: case GL_TEXTURE_CUBE_MAP_POSITIVE_Z: case GL_TEXTURE_CUBE_MAP_NEGATIVE_Z: return true; default: return false; } } bool ValidTexture3DDestinationTarget(const ValidationContext *context, GLenum target) { switch (target) { case GL_TEXTURE_3D: case GL_TEXTURE_2D_ARRAY: return true; default: return false; } } bool ValidFramebufferTarget(GLenum target) { static_assert(GL_DRAW_FRAMEBUFFER_ANGLE == GL_DRAW_FRAMEBUFFER && GL_READ_FRAMEBUFFER_ANGLE == GL_READ_FRAMEBUFFER, "ANGLE framebuffer enums must equal the ES3 framebuffer enums."); switch (target) { case GL_FRAMEBUFFER: return true; case GL_READ_FRAMEBUFFER: return true; case GL_DRAW_FRAMEBUFFER: return true; default: return false; } } bool ValidBufferTarget(const ValidationContext *context, GLenum target) { switch (target) { case GL_ARRAY_BUFFER: case GL_ELEMENT_ARRAY_BUFFER: return true; case GL_PIXEL_PACK_BUFFER: case GL_PIXEL_UNPACK_BUFFER: return (context->getExtensions().pixelBufferObject || context->getClientMajorVersion() >= 3); case GL_COPY_READ_BUFFER: case GL_COPY_WRITE_BUFFER: case GL_TRANSFORM_FEEDBACK_BUFFER: case GL_UNIFORM_BUFFER: return (context->getClientMajorVersion() >= 3); case GL_ATOMIC_COUNTER_BUFFER: case GL_SHADER_STORAGE_BUFFER: case GL_DRAW_INDIRECT_BUFFER: case GL_DISPATCH_INDIRECT_BUFFER: UNIMPLEMENTED(); return context->getClientVersion() >= Version(3, 1); default: return false; } } bool ValidMipLevel(const ValidationContext *context, GLenum target, GLint level) { const auto &caps = context->getCaps(); size_t maxDimension = 0; switch (target) { case GL_TEXTURE_2D: maxDimension = caps.max2DTextureSize; break; case GL_TEXTURE_CUBE_MAP: case GL_TEXTURE_CUBE_MAP_POSITIVE_X: case GL_TEXTURE_CUBE_MAP_NEGATIVE_X: case GL_TEXTURE_CUBE_MAP_POSITIVE_Y: case GL_TEXTURE_CUBE_MAP_NEGATIVE_Y: case GL_TEXTURE_CUBE_MAP_POSITIVE_Z: case GL_TEXTURE_CUBE_MAP_NEGATIVE_Z: maxDimension = caps.maxCubeMapTextureSize; break; case GL_TEXTURE_3D: maxDimension = caps.max3DTextureSize; break; case GL_TEXTURE_2D_ARRAY: maxDimension = caps.max2DTextureSize; break; default: UNREACHABLE(); } return level <= gl::log2(static_cast<int>(maxDimension)); } bool ValidImageSizeParameters(const Context *context, GLenum target, GLint level, GLsizei width, GLsizei height, GLsizei depth, bool isSubImage) { if (level < 0 || width < 0 || height < 0 || depth < 0) { return false; } // TexSubImage parameters can be NPOT without textureNPOT extension, // as long as the destination texture is POT. if (!isSubImage && !context->getExtensions().textureNPOT && (level != 0 && (!gl::isPow2(width) || !gl::isPow2(height) || !gl::isPow2(depth)))) { return false; } if (!ValidMipLevel(context, target, level)) { return false; } return true; } bool CompressedTextureFormatRequiresExactSize(GLenum internalFormat) { // List of compressed format that require that the texture size is smaller than or a multiple of // the compressed block size. switch (internalFormat) { case GL_COMPRESSED_RGB_S3TC_DXT1_EXT: case GL_COMPRESSED_RGBA_S3TC_DXT1_EXT: case GL_COMPRESSED_RGBA_S3TC_DXT3_ANGLE: case GL_COMPRESSED_RGBA_S3TC_DXT5_ANGLE: case GL_ETC1_RGB8_LOSSY_DECODE_ANGLE: return true; default: return false; } } bool ValidCompressedImageSize(const ValidationContext *context, GLenum internalFormat, GLsizei width, GLsizei height) { const gl::InternalFormat &formatInfo = gl::GetInternalFormatInfo(internalFormat); if (!formatInfo.compressed) { return false; } if (width < 0 || height < 0) { return false; } if (CompressedTextureFormatRequiresExactSize(internalFormat)) { if ((static_cast<GLuint>(width) > formatInfo.compressedBlockWidth && width % formatInfo.compressedBlockWidth != 0) || (static_cast<GLuint>(height) > formatInfo.compressedBlockHeight && height % formatInfo.compressedBlockHeight != 0)) { return false; } } return true; } bool ValidImageDataSize(ValidationContext *context, GLenum textureTarget, GLsizei width, GLsizei height, GLsizei depth, GLenum internalFormat, GLenum type, const GLvoid *pixels, GLsizei imageSize) { gl::Buffer *pixelUnpackBuffer = context->getGLState().getTargetBuffer(GL_PIXEL_UNPACK_BUFFER); if (pixelUnpackBuffer == nullptr && imageSize < 0) { // Checks are not required return true; } // ...the data would be unpacked from the buffer object such that the memory reads required // would exceed the data store size. GLenum sizedFormat = GetSizedInternalFormat(internalFormat, type); const gl::InternalFormat &formatInfo = gl::GetInternalFormatInfo(sizedFormat); const gl::Extents size(width, height, depth); const auto &unpack = context->getGLState().getUnpackState(); bool targetIs3D = textureTarget == GL_TEXTURE_3D || textureTarget == GL_TEXTURE_2D_ARRAY; auto endByteOrErr = formatInfo.computePackUnpackEndByte(type, size, unpack, targetIs3D); if (endByteOrErr.isError()) { context->handleError(endByteOrErr.getError()); return false; } GLuint endByte = endByteOrErr.getResult(); if (pixelUnpackBuffer) { CheckedNumeric<size_t> checkedEndByte(endByteOrErr.getResult()); CheckedNumeric<size_t> checkedOffset(reinterpret_cast<size_t>(pixels)); checkedEndByte += checkedOffset; if (!checkedEndByte.IsValid() || (checkedEndByte.ValueOrDie() > static_cast<size_t>(pixelUnpackBuffer->getSize()))) { // Overflow past the end of the buffer context->handleError(Error(GL_INVALID_OPERATION)); return false; } } else { ASSERT(imageSize >= 0); if (pixels == nullptr && imageSize != 0) { context->handleError( Error(GL_INVALID_OPERATION, "imageSize must be 0 if no texture data is provided.")); return false; } if (pixels != nullptr && endByte > static_cast<GLuint>(imageSize)) { context->handleError( Error(GL_INVALID_OPERATION, "imageSize must be at least %u.", endByte)); return false; } } return true; } bool ValidQueryType(const Context *context, GLenum queryType) { static_assert(GL_ANY_SAMPLES_PASSED == GL_ANY_SAMPLES_PASSED_EXT, "GL extension enums not equal."); static_assert(GL_ANY_SAMPLES_PASSED_CONSERVATIVE == GL_ANY_SAMPLES_PASSED_CONSERVATIVE_EXT, "GL extension enums not equal."); switch (queryType) { case GL_ANY_SAMPLES_PASSED: case GL_ANY_SAMPLES_PASSED_CONSERVATIVE: return true; case GL_TRANSFORM_FEEDBACK_PRIMITIVES_WRITTEN: return (context->getClientMajorVersion() >= 3); case GL_TIME_ELAPSED_EXT: return context->getExtensions().disjointTimerQuery; case GL_COMMANDS_COMPLETED_CHROMIUM: return context->getExtensions().syncQuery; default: return false; } } Program *GetValidProgram(ValidationContext *context, GLuint id) { // ES3 spec (section 2.11.1) -- "Commands that accept shader or program object names will generate the // error INVALID_VALUE if the provided name is not the name of either a shader or program object and // INVALID_OPERATION if the provided name identifies an object that is not the expected type." Program *validProgram = context->getProgram(id); if (!validProgram) { if (context->getShader(id)) { context->handleError( Error(GL_INVALID_OPERATION, "Expected a program name, but found a shader name")); } else { context->handleError(Error(GL_INVALID_VALUE, "Program name is not valid")); } } return validProgram; } Shader *GetValidShader(ValidationContext *context, GLuint id) { // See ValidProgram for spec details. Shader *validShader = context->getShader(id); if (!validShader) { if (context->getProgram(id)) { context->handleError( Error(GL_INVALID_OPERATION, "Expected a shader name, but found a program name")); } else { context->handleError(Error(GL_INVALID_VALUE, "Shader name is invalid")); } } return validShader; } bool ValidateAttachmentTarget(gl::Context *context, GLenum attachment) { if (attachment >= GL_COLOR_ATTACHMENT0_EXT && attachment <= GL_COLOR_ATTACHMENT15_EXT) { const unsigned int colorAttachment = (attachment - GL_COLOR_ATTACHMENT0_EXT); if (colorAttachment >= context->getCaps().maxColorAttachments) { context->handleError(Error(GL_INVALID_VALUE)); return false; } } else { switch (attachment) { case GL_DEPTH_ATTACHMENT: case GL_STENCIL_ATTACHMENT: break; case GL_DEPTH_STENCIL_ATTACHMENT: if (!context->getExtensions().webglCompatibility && context->getClientMajorVersion() < 3) { context->handleError(Error(GL_INVALID_ENUM)); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM)); return false; } } return true; } bool ValidateRenderbufferStorageParametersBase(gl::Context *context, GLenum target, GLsizei samples, GLenum internalformat, GLsizei width, GLsizei height) { switch (target) { case GL_RENDERBUFFER: break; default: context->handleError(Error(GL_INVALID_ENUM)); return false; } if (width < 0 || height < 0 || samples < 0) { context->handleError(Error(GL_INVALID_VALUE)); return false; } const TextureCaps &formatCaps = context->getTextureCaps().get(internalformat); if (!formatCaps.renderable) { context->handleError(Error(GL_INVALID_ENUM)); return false; } // ANGLE_framebuffer_multisample does not explicitly state that the internal format must be // sized but it does state that the format must be in the ES2.0 spec table 4.5 which contains // only sized internal formats. const gl::InternalFormat &formatInfo = gl::GetInternalFormatInfo(internalformat); if (formatInfo.pixelBytes == 0) { context->handleError(Error(GL_INVALID_ENUM)); return false; } if (static_cast<GLuint>(std::max(width, height)) > context->getCaps().maxRenderbufferSize) { context->handleError(Error(GL_INVALID_VALUE)); return false; } GLuint handle = context->getGLState().getRenderbufferId(); if (handle == 0) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } return true; } bool ValidateRenderbufferStorageParametersANGLE(gl::Context *context, GLenum target, GLsizei samples, GLenum internalformat, GLsizei width, GLsizei height) { ASSERT(samples == 0 || context->getExtensions().framebufferMultisample); // ANGLE_framebuffer_multisample states that the value of samples must be less than or equal // to MAX_SAMPLES_ANGLE (Context::getCaps().maxSamples) otherwise GL_INVALID_VALUE is // generated. if (static_cast<GLuint>(samples) > context->getCaps().maxSamples) { context->handleError(Error(GL_INVALID_VALUE)); return false; } // ANGLE_framebuffer_multisample states GL_OUT_OF_MEMORY is generated on a failure to create // the specified storage. This is different than ES 3.0 in which a sample number higher // than the maximum sample number supported by this format generates a GL_INVALID_VALUE. // The TextureCaps::getMaxSamples method is only guarenteed to be valid when the context is ES3. if (context->getClientMajorVersion() >= 3) { const TextureCaps &formatCaps = context->getTextureCaps().get(internalformat); if (static_cast<GLuint>(samples) > formatCaps.getMaxSamples()) { context->handleError(Error(GL_OUT_OF_MEMORY)); return false; } } return ValidateRenderbufferStorageParametersBase(context, target, samples, internalformat, width, height); } bool ValidateFramebufferRenderbufferParameters(gl::Context *context, GLenum target, GLenum attachment, GLenum renderbuffertarget, GLuint renderbuffer) { if (!ValidFramebufferTarget(target)) { context->handleError(Error(GL_INVALID_ENUM)); return false; } gl::Framebuffer *framebuffer = context->getGLState().getTargetFramebuffer(target); ASSERT(framebuffer); if (framebuffer->id() == 0) { context->handleError( Error(GL_INVALID_OPERATION, "Cannot change default FBO's attachments")); return false; } if (!ValidateAttachmentTarget(context, attachment)) { return false; } // [OpenGL ES 2.0.25] Section 4.4.3 page 112 // [OpenGL ES 3.0.2] Section 4.4.2 page 201 // 'renderbuffer' must be either zero or the name of an existing renderbuffer object of // type 'renderbuffertarget', otherwise an INVALID_OPERATION error is generated. if (renderbuffer != 0) { if (!context->getRenderbuffer(renderbuffer)) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } } return true; } bool ValidateBlitFramebufferParameters(ValidationContext *context, GLint srcX0, GLint srcY0, GLint srcX1, GLint srcY1, GLint dstX0, GLint dstY0, GLint dstX1, GLint dstY1, GLbitfield mask, GLenum filter) { switch (filter) { case GL_NEAREST: break; case GL_LINEAR: break; default: context->handleError(Error(GL_INVALID_ENUM)); return false; } if ((mask & ~(GL_COLOR_BUFFER_BIT | GL_STENCIL_BUFFER_BIT | GL_DEPTH_BUFFER_BIT)) != 0) { context->handleError(Error(GL_INVALID_VALUE)); return false; } if (mask == 0) { // ES3.0 spec, section 4.3.2 specifies that a mask of zero is valid and no // buffers are copied. return false; } // ES3.0 spec, section 4.3.2 states that linear filtering is only available for the // color buffer, leaving only nearest being unfiltered from above if ((mask & ~GL_COLOR_BUFFER_BIT) != 0 && filter != GL_NEAREST) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } const auto &glState = context->getGLState(); gl::Framebuffer *readFramebuffer = glState.getReadFramebuffer(); gl::Framebuffer *drawFramebuffer = glState.getDrawFramebuffer(); if (!readFramebuffer || !drawFramebuffer) { context->handleError(Error(GL_INVALID_FRAMEBUFFER_OPERATION)); return false; } if (readFramebuffer->id() == drawFramebuffer->id()) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (readFramebuffer->checkStatus(context->getContextState()) != GL_FRAMEBUFFER_COMPLETE) { context->handleError(Error(GL_INVALID_FRAMEBUFFER_OPERATION)); return false; } if (drawFramebuffer->checkStatus(context->getContextState()) != GL_FRAMEBUFFER_COMPLETE) { context->handleError(Error(GL_INVALID_FRAMEBUFFER_OPERATION)); return false; } if (drawFramebuffer->getSamples(context->getContextState()) != 0) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } bool sameBounds = srcX0 == dstX0 && srcY0 == dstY0 && srcX1 == dstX1 && srcY1 == dstY1; if (mask & GL_COLOR_BUFFER_BIT) { const gl::FramebufferAttachment *readColorBuffer = readFramebuffer->getReadColorbuffer(); const gl::FramebufferAttachment *drawColorBuffer = drawFramebuffer->getFirstColorbuffer(); const Extensions &extensions = context->getExtensions(); if (readColorBuffer && drawColorBuffer) { const Format &readFormat = readColorBuffer->getFormat(); for (size_t drawbufferIdx = 0; drawbufferIdx < drawFramebuffer->getDrawbufferStateCount(); ++drawbufferIdx) { const FramebufferAttachment *attachment = drawFramebuffer->getDrawBuffer(drawbufferIdx); if (attachment) { const Format &drawFormat = attachment->getFormat(); // The GL ES 3.0.2 spec (pg 193) states that: // 1) If the read buffer is fixed point format, the draw buffer must be as well // 2) If the read buffer is an unsigned integer format, the draw buffer must be as well // 3) If the read buffer is a signed integer format, the draw buffer must be as well // Changes with EXT_color_buffer_float: // Case 1) is changed to fixed point OR floating point GLenum readComponentType = readFormat.info->componentType; GLenum drawComponentType = drawFormat.info->componentType; bool readFixedPoint = (readComponentType == GL_UNSIGNED_NORMALIZED || readComponentType == GL_SIGNED_NORMALIZED); bool drawFixedPoint = (drawComponentType == GL_UNSIGNED_NORMALIZED || drawComponentType == GL_SIGNED_NORMALIZED); if (extensions.colorBufferFloat) { bool readFixedOrFloat = (readFixedPoint || readComponentType == GL_FLOAT); bool drawFixedOrFloat = (drawFixedPoint || drawComponentType == GL_FLOAT); if (readFixedOrFloat != drawFixedOrFloat) { context->handleError(Error(GL_INVALID_OPERATION, "If the read buffer contains fixed-point or " "floating-point values, the draw buffer " "must as well.")); return false; } } else if (readFixedPoint != drawFixedPoint) { context->handleError(Error(GL_INVALID_OPERATION, "If the read buffer contains fixed-point " "values, the draw buffer must as well.")); return false; } if (readComponentType == GL_UNSIGNED_INT && drawComponentType != GL_UNSIGNED_INT) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (readComponentType == GL_INT && drawComponentType != GL_INT) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (readColorBuffer->getSamples() > 0 && (!Format::SameSized(readFormat, drawFormat) || !sameBounds)) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } } } if ((readFormat.info->componentType == GL_INT || readFormat.info->componentType == GL_UNSIGNED_INT) && filter == GL_LINEAR) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } } } GLenum masks[] = {GL_DEPTH_BUFFER_BIT, GL_STENCIL_BUFFER_BIT}; GLenum attachments[] = {GL_DEPTH_ATTACHMENT, GL_STENCIL_ATTACHMENT}; for (size_t i = 0; i < 2; i++) { if (mask & masks[i]) { const gl::FramebufferAttachment *readBuffer = readFramebuffer->getAttachment(attachments[i]); const gl::FramebufferAttachment *drawBuffer = drawFramebuffer->getAttachment(attachments[i]); if (readBuffer && drawBuffer) { if (!Format::SameSized(readBuffer->getFormat(), drawBuffer->getFormat())) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (readBuffer->getSamples() > 0 && !sameBounds) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } } } } return true; } bool ValidateReadPixels(ValidationContext *context, GLint x, GLint y, GLsizei width, GLsizei height, GLenum format, GLenum type, GLvoid *pixels) { return ValidateReadPixelsBase(context, x, y, width, height, format, type, -1, nullptr, pixels); } bool ValidateReadPixelsRobustANGLE(ValidationContext *context, GLint x, GLint y, GLsizei width, GLsizei height, GLenum format, GLenum type, GLsizei bufSize, GLsizei *length, GLvoid *pixels) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateReadPixelsBase(context, x, y, width, height, format, type, bufSize, length, pixels)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateReadnPixelsEXT(Context *context, GLint x, GLint y, GLsizei width, GLsizei height, GLenum format, GLenum type, GLsizei bufSize, GLvoid *pixels) { if (bufSize < 0) { context->handleError(Error(GL_INVALID_VALUE, "bufSize must be a positive number")); return false; } return ValidateReadPixelsBase(context, x, y, width, height, format, type, bufSize, nullptr, pixels); } bool ValidateReadnPixelsRobustANGLE(ValidationContext *context, GLint x, GLint y, GLsizei width, GLsizei height, GLenum format, GLenum type, GLsizei bufSize, GLsizei *length, GLvoid *data) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateReadPixelsBase(context, x, y, width, height, format, type, bufSize, length, data)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGenQueriesEXT(gl::Context *context, GLsizei n) { if (!context->getExtensions().occlusionQueryBoolean && !context->getExtensions().disjointTimerQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Query extension not enabled")); return false; } return ValidateGenOrDelete(context, n); } bool ValidateDeleteQueriesEXT(gl::Context *context, GLsizei n) { if (!context->getExtensions().occlusionQueryBoolean && !context->getExtensions().disjointTimerQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Query extension not enabled")); return false; } return ValidateGenOrDelete(context, n); } bool ValidateBeginQueryBase(gl::Context *context, GLenum target, GLuint id) { if (!ValidQueryType(context, target)) { context->handleError(Error(GL_INVALID_ENUM, "Invalid query target")); return false; } if (id == 0) { context->handleError(Error(GL_INVALID_OPERATION, "Query id is 0")); return false; } // From EXT_occlusion_query_boolean: If BeginQueryEXT is called with an <id> // of zero, if the active query object name for <target> is non-zero (for the // targets ANY_SAMPLES_PASSED_EXT and ANY_SAMPLES_PASSED_CONSERVATIVE_EXT, if // the active query for either target is non-zero), if <id> is the name of an // existing query object whose type does not match <target>, or if <id> is the // active query object name for any query type, the error INVALID_OPERATION is // generated. // Ensure no other queries are active // NOTE: If other queries than occlusion are supported, we will need to check // separately that: // a) The query ID passed is not the current active query for any target/type // b) There are no active queries for the requested target (and in the case // of GL_ANY_SAMPLES_PASSED_EXT and GL_ANY_SAMPLES_PASSED_CONSERVATIVE_EXT, // no query may be active for either if glBeginQuery targets either. if (context->getGLState().isQueryActive(target)) { context->handleError(Error(GL_INVALID_OPERATION, "Other query is active")); return false; } Query *queryObject = context->getQuery(id, true, target); // check that name was obtained with glGenQueries if (!queryObject) { context->handleError(Error(GL_INVALID_OPERATION, "Invalid query id")); return false; } // check for type mismatch if (queryObject->getType() != target) { context->handleError(Error(GL_INVALID_OPERATION, "Query type does not match target")); return false; } return true; } bool ValidateBeginQueryEXT(gl::Context *context, GLenum target, GLuint id) { if (!context->getExtensions().occlusionQueryBoolean && !context->getExtensions().disjointTimerQuery && !context->getExtensions().syncQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Query extension not enabled")); return false; } return ValidateBeginQueryBase(context, target, id); } bool ValidateEndQueryBase(gl::Context *context, GLenum target) { if (!ValidQueryType(context, target)) { context->handleError(Error(GL_INVALID_ENUM, "Invalid query target")); return false; } const Query *queryObject = context->getGLState().getActiveQuery(target); if (queryObject == nullptr) { context->handleError(Error(GL_INVALID_OPERATION, "Query target not active")); return false; } return true; } bool ValidateEndQueryEXT(gl::Context *context, GLenum target) { if (!context->getExtensions().occlusionQueryBoolean && !context->getExtensions().disjointTimerQuery && !context->getExtensions().syncQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Query extension not enabled")); return false; } return ValidateEndQueryBase(context, target); } bool ValidateQueryCounterEXT(Context *context, GLuint id, GLenum target) { if (!context->getExtensions().disjointTimerQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Disjoint timer query not enabled")); return false; } if (target != GL_TIMESTAMP_EXT) { context->handleError(Error(GL_INVALID_ENUM, "Invalid query target")); return false; } Query *queryObject = context->getQuery(id, true, target); if (queryObject == nullptr) { context->handleError(Error(GL_INVALID_OPERATION, "Invalid query id")); return false; } if (context->getGLState().isQueryActive(queryObject)) { context->handleError(Error(GL_INVALID_OPERATION, "Query is active")); return false; } return true; } bool ValidateGetQueryivBase(Context *context, GLenum target, GLenum pname, GLsizei *numParams) { if (numParams) { *numParams = 0; } if (!ValidQueryType(context, target) && target != GL_TIMESTAMP_EXT) { context->handleError(Error(GL_INVALID_ENUM, "Invalid query type")); return false; } switch (pname) { case GL_CURRENT_QUERY_EXT: if (target == GL_TIMESTAMP_EXT) { context->handleError( Error(GL_INVALID_ENUM, "Cannot use current query for timestamp")); return false; } break; case GL_QUERY_COUNTER_BITS_EXT: if (!context->getExtensions().disjointTimerQuery || (target != GL_TIMESTAMP_EXT && target != GL_TIME_ELAPSED_EXT)) { context->handleError(Error(GL_INVALID_ENUM, "Invalid pname")); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM, "Invalid pname")); return false; } if (numParams) { // All queries return only one value *numParams = 1; } return true; } bool ValidateGetQueryivEXT(Context *context, GLenum target, GLenum pname, GLint *params) { if (!context->getExtensions().occlusionQueryBoolean && !context->getExtensions().disjointTimerQuery && !context->getExtensions().syncQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Query extension not enabled")); return false; } return ValidateGetQueryivBase(context, target, pname, nullptr); } bool ValidateGetQueryivRobustANGLE(Context *context, GLenum target, GLenum pname, GLsizei bufSize, GLsizei *length, GLint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetQueryivBase(context, target, pname, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetQueryObjectValueBase(Context *context, GLuint id, GLenum pname, GLsizei *numParams) { if (numParams) { *numParams = 0; } Query *queryObject = context->getQuery(id, false, GL_NONE); if (!queryObject) { context->handleError(Error(GL_INVALID_OPERATION, "Query does not exist")); return false; } if (context->getGLState().isQueryActive(queryObject)) { context->handleError(Error(GL_INVALID_OPERATION, "Query currently active")); return false; } switch (pname) { case GL_QUERY_RESULT_EXT: case GL_QUERY_RESULT_AVAILABLE_EXT: break; default: context->handleError(Error(GL_INVALID_ENUM, "Invalid pname enum")); return false; } if (numParams) { *numParams = 1; } return true; } bool ValidateGetQueryObjectivEXT(Context *context, GLuint id, GLenum pname, GLint *params) { if (!context->getExtensions().disjointTimerQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Timer query extension not enabled")); return false; } return ValidateGetQueryObjectValueBase(context, id, pname, nullptr); } bool ValidateGetQueryObjectivRobustANGLE(Context *context, GLuint id, GLenum pname, GLsizei bufSize, GLsizei *length, GLint *params) { if (!context->getExtensions().disjointTimerQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Timer query extension not enabled")); return false; } if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetQueryObjectValueBase(context, id, pname, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetQueryObjectuivEXT(Context *context, GLuint id, GLenum pname, GLuint *params) { if (!context->getExtensions().disjointTimerQuery && !context->getExtensions().occlusionQueryBoolean && !context->getExtensions().syncQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Query extension not enabled")); return false; } return ValidateGetQueryObjectValueBase(context, id, pname, nullptr); } bool ValidateGetQueryObjectuivRobustANGLE(Context *context, GLuint id, GLenum pname, GLsizei bufSize, GLsizei *length, GLuint *params) { if (!context->getExtensions().disjointTimerQuery && !context->getExtensions().occlusionQueryBoolean && !context->getExtensions().syncQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Query extension not enabled")); return false; } if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetQueryObjectValueBase(context, id, pname, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetQueryObjecti64vEXT(Context *context, GLuint id, GLenum pname, GLint64 *params) { if (!context->getExtensions().disjointTimerQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Timer query extension not enabled")); return false; } return ValidateGetQueryObjectValueBase(context, id, pname, nullptr); } bool ValidateGetQueryObjecti64vRobustANGLE(Context *context, GLuint id, GLenum pname, GLsizei bufSize, GLsizei *length, GLint64 *params) { if (!context->getExtensions().disjointTimerQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Timer query extension not enabled")); return false; } if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetQueryObjectValueBase(context, id, pname, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetQueryObjectui64vEXT(Context *context, GLuint id, GLenum pname, GLuint64 *params) { if (!context->getExtensions().disjointTimerQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Timer query extension not enabled")); return false; } return ValidateGetQueryObjectValueBase(context, id, pname, nullptr); } bool ValidateGetQueryObjectui64vRobustANGLE(Context *context, GLuint id, GLenum pname, GLsizei bufSize, GLsizei *length, GLuint64 *params) { if (!context->getExtensions().disjointTimerQuery) { context->handleError(Error(GL_INVALID_OPERATION, "Timer query extension not enabled")); return false; } if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetQueryObjectValueBase(context, id, pname, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } static bool ValidateUniformCommonBase(gl::Context *context, GLenum targetUniformType, GLint location, GLsizei count, const LinkedUniform **uniformOut) { if (count < 0) { context->handleError(Error(GL_INVALID_VALUE)); return false; } gl::Program *program = context->getGLState().getProgram(); if (!program) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (program->isIgnoredUniformLocation(location)) { // Silently ignore the uniform command return false; } if (!program->isValidUniformLocation(location)) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } const LinkedUniform &uniform = program->getUniformByLocation(location); // attempting to write an array to a non-array uniform is an INVALID_OPERATION if (!uniform.isArray() && count > 1) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } *uniformOut = &uniform; return true; } bool ValidateUniform(gl::Context *context, GLenum uniformType, GLint location, GLsizei count) { // Check for ES3 uniform entry points if (VariableComponentType(uniformType) == GL_UNSIGNED_INT && context->getClientMajorVersion() < 3) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } const LinkedUniform *uniform = nullptr; if (!ValidateUniformCommonBase(context, uniformType, location, count, &uniform)) { return false; } GLenum targetBoolType = VariableBoolVectorType(uniformType); bool samplerUniformCheck = (IsSamplerType(uniform->type) && uniformType == GL_INT); if (!samplerUniformCheck && uniformType != uniform->type && targetBoolType != uniform->type) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } return true; } bool ValidateUniformMatrix(gl::Context *context, GLenum matrixType, GLint location, GLsizei count, GLboolean transpose) { // Check for ES3 uniform entry points int rows = VariableRowCount(matrixType); int cols = VariableColumnCount(matrixType); if (rows != cols && context->getClientMajorVersion() < 3) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (transpose != GL_FALSE && context->getClientMajorVersion() < 3) { context->handleError(Error(GL_INVALID_VALUE)); return false; } const LinkedUniform *uniform = nullptr; if (!ValidateUniformCommonBase(context, matrixType, location, count, &uniform)) { return false; } if (uniform->type != matrixType) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } return true; } bool ValidateStateQuery(ValidationContext *context, GLenum pname, GLenum *nativeType, unsigned int *numParams) { if (!context->getQueryParameterInfo(pname, nativeType, numParams)) { context->handleError(Error(GL_INVALID_ENUM)); return false; } const Caps &caps = context->getCaps(); if (pname >= GL_DRAW_BUFFER0 && pname <= GL_DRAW_BUFFER15) { unsigned int colorAttachment = (pname - GL_DRAW_BUFFER0); if (colorAttachment >= caps.maxDrawBuffers) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } } switch (pname) { case GL_TEXTURE_BINDING_2D: case GL_TEXTURE_BINDING_CUBE_MAP: case GL_TEXTURE_BINDING_3D: case GL_TEXTURE_BINDING_2D_ARRAY: break; case GL_TEXTURE_BINDING_EXTERNAL_OES: if (!context->getExtensions().eglStreamConsumerExternal && !context->getExtensions().eglImageExternal) { context->handleError(Error(GL_INVALID_ENUM, "Neither NV_EGL_stream_consumer_external nor " "GL_OES_EGL_image_external extensions enabled")); return false; } break; case GL_IMPLEMENTATION_COLOR_READ_TYPE: case GL_IMPLEMENTATION_COLOR_READ_FORMAT: { if (context->getGLState().getReadFramebuffer()->checkStatus( context->getContextState()) != GL_FRAMEBUFFER_COMPLETE) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } const Framebuffer *framebuffer = context->getGLState().getReadFramebuffer(); ASSERT(framebuffer); if (framebuffer->getReadBufferState() == GL_NONE) { context->handleError(Error(GL_INVALID_OPERATION, "Read buffer is GL_NONE")); return false; } const FramebufferAttachment *attachment = framebuffer->getReadColorbuffer(); if (!attachment) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } } break; default: break; } // pname is valid, but there are no parameters to return if (*numParams == 0) { return false; } return true; } bool ValidateRobustStateQuery(ValidationContext *context, GLenum pname, GLsizei bufSize, GLenum *nativeType, unsigned int *numParams) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateStateQuery(context, pname, nativeType, numParams)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *numParams)) { return false; } return true; } bool ValidateCopyTexImageParametersBase(ValidationContext *context, GLenum target, GLint level, GLenum internalformat, bool isSubImage, GLint xoffset, GLint yoffset, GLint zoffset, GLint x, GLint y, GLsizei width, GLsizei height, GLint border, Format *textureFormatOut) { if (level < 0 || xoffset < 0 || yoffset < 0 || zoffset < 0 || width < 0 || height < 0) { context->handleError(Error(GL_INVALID_VALUE)); return false; } if (std::numeric_limits<GLsizei>::max() - xoffset < width || std::numeric_limits<GLsizei>::max() - yoffset < height) { context->handleError(Error(GL_INVALID_VALUE)); return false; } if (border != 0) { context->handleError(Error(GL_INVALID_VALUE)); return false; } if (!ValidMipLevel(context, target, level)) { context->handleError(Error(GL_INVALID_VALUE)); return false; } const auto &state = context->getGLState(); auto readFramebuffer = state.getReadFramebuffer(); if (readFramebuffer->checkStatus(context->getContextState()) != GL_FRAMEBUFFER_COMPLETE) { context->handleError(Error(GL_INVALID_FRAMEBUFFER_OPERATION)); return false; } if (readFramebuffer->id() != 0 && readFramebuffer->getSamples(context->getContextState()) != 0) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (readFramebuffer->getReadBufferState() == GL_NONE) { context->handleError(Error(GL_INVALID_OPERATION, "Read buffer is GL_NONE")); return false; } const gl::Caps &caps = context->getCaps(); GLuint maxDimension = 0; switch (target) { case GL_TEXTURE_2D: maxDimension = caps.max2DTextureSize; break; case GL_TEXTURE_CUBE_MAP_POSITIVE_X: case GL_TEXTURE_CUBE_MAP_NEGATIVE_X: case GL_TEXTURE_CUBE_MAP_POSITIVE_Y: case GL_TEXTURE_CUBE_MAP_NEGATIVE_Y: case GL_TEXTURE_CUBE_MAP_POSITIVE_Z: case GL_TEXTURE_CUBE_MAP_NEGATIVE_Z: maxDimension = caps.maxCubeMapTextureSize; break; case GL_TEXTURE_2D_ARRAY: maxDimension = caps.max2DTextureSize; break; case GL_TEXTURE_3D: maxDimension = caps.max3DTextureSize; break; default: context->handleError(Error(GL_INVALID_ENUM)); return false; } gl::Texture *texture = state.getTargetTexture(IsCubeMapTextureTarget(target) ? GL_TEXTURE_CUBE_MAP : target); if (!texture) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (texture->getImmutableFormat() && !isSubImage) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } const gl::InternalFormat &formatInfo = gl::GetInternalFormatInfo(internalformat); if (formatInfo.depthBits > 0) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (formatInfo.compressed && !ValidCompressedImageSize(context, internalformat, width, height)) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (isSubImage) { if (static_cast<size_t>(xoffset + width) > texture->getWidth(target, level) || static_cast<size_t>(yoffset + height) > texture->getHeight(target, level) || static_cast<size_t>(zoffset) >= texture->getDepth(target, level)) { context->handleError(Error(GL_INVALID_VALUE)); return false; } } else { if (IsCubeMapTextureTarget(target) && width != height) { context->handleError(Error(GL_INVALID_VALUE)); return false; } if (!formatInfo.textureSupport(context->getClientVersion(), context->getExtensions())) { context->handleError(Error(GL_INVALID_ENUM)); return false; } int maxLevelDimension = (maxDimension >> level); if (static_cast<int>(width) > maxLevelDimension || static_cast<int>(height) > maxLevelDimension) { context->handleError(Error(GL_INVALID_VALUE)); return false; } } if (textureFormatOut) { *textureFormatOut = texture->getFormat(target, level); } return true; } static bool ValidateDrawBase(ValidationContext *context, GLenum mode, GLsizei count, GLsizei primcount) { switch (mode) { case GL_POINTS: case GL_LINES: case GL_LINE_LOOP: case GL_LINE_STRIP: case GL_TRIANGLES: case GL_TRIANGLE_STRIP: case GL_TRIANGLE_FAN: break; default: context->handleError(Error(GL_INVALID_ENUM)); return false; } if (count < 0) { context->handleError(Error(GL_INVALID_VALUE)); return false; } const State &state = context->getGLState(); // Check for mapped buffers if (state.hasMappedBuffer(GL_ARRAY_BUFFER)) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } Framebuffer *framebuffer = state.getDrawFramebuffer(); if (context->getLimitations().noSeparateStencilRefsAndMasks) { const FramebufferAttachment *stencilBuffer = framebuffer->getStencilbuffer(); GLuint stencilBits = stencilBuffer ? stencilBuffer->getStencilSize() : 0; GLuint minimumRequiredStencilMask = (1 << stencilBits) - 1; const DepthStencilState &depthStencilState = state.getDepthStencilState(); if ((depthStencilState.stencilWritemask & minimumRequiredStencilMask) != (depthStencilState.stencilBackWritemask & minimumRequiredStencilMask) || state.getStencilRef() != state.getStencilBackRef() || (depthStencilState.stencilMask & minimumRequiredStencilMask) != (depthStencilState.stencilBackMask & minimumRequiredStencilMask)) { // Note: these separate values are not supported in WebGL, due to D3D's limitations. See // Section 6.10 of the WebGL 1.0 spec ERR( "This ANGLE implementation does not support separate front/back stencil " "writemasks, reference values, or stencil mask values."); context->handleError(Error(GL_INVALID_OPERATION)); return false; } } if (framebuffer->checkStatus(context->getContextState()) != GL_FRAMEBUFFER_COMPLETE) { context->handleError(Error(GL_INVALID_FRAMEBUFFER_OPERATION)); return false; } gl::Program *program = state.getProgram(); if (!program) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (!program->validateSamplers(NULL, context->getCaps())) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } // Uniform buffer validation for (unsigned int uniformBlockIndex = 0; uniformBlockIndex < program->getActiveUniformBlockCount(); uniformBlockIndex++) { const gl::UniformBlock &uniformBlock = program->getUniformBlockByIndex(uniformBlockIndex); GLuint blockBinding = program->getUniformBlockBinding(uniformBlockIndex); const OffsetBindingPointer<Buffer> &uniformBuffer = state.getIndexedUniformBuffer(blockBinding); if (uniformBuffer.get() == nullptr) { // undefined behaviour context->handleError( Error(GL_INVALID_OPERATION, "It is undefined behaviour to have a used but unbound uniform buffer.")); return false; } size_t uniformBufferSize = uniformBuffer.getSize(); if (uniformBufferSize == 0) { // Bind the whole buffer. uniformBufferSize = static_cast<size_t>(uniformBuffer->getSize()); } if (uniformBufferSize < uniformBlock.dataSize) { // undefined behaviour context->handleError( Error(GL_INVALID_OPERATION, "It is undefined behaviour to use a uniform buffer that is too small.")); return false; } } // No-op if zero count return (count > 0); } bool ValidateDrawArrays(ValidationContext *context, GLenum mode, GLint first, GLsizei count, GLsizei primcount) { if (first < 0) { context->handleError(Error(GL_INVALID_VALUE)); return false; } const State &state = context->getGLState(); gl::TransformFeedback *curTransformFeedback = state.getCurrentTransformFeedback(); if (curTransformFeedback && curTransformFeedback->isActive() && !curTransformFeedback->isPaused() && curTransformFeedback->getPrimitiveMode() != mode) { // It is an invalid operation to call DrawArrays or DrawArraysInstanced with a draw mode // that does not match the current transform feedback object's draw mode (if transform feedback // is active), (3.0.2, section 2.14, pg 86) context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (!ValidateDrawBase(context, mode, count, primcount)) { return false; } if (!ValidateDrawAttribs(context, primcount, count)) { return false; } return true; } bool ValidateDrawArraysInstanced(Context *context, GLenum mode, GLint first, GLsizei count, GLsizei primcount) { if (primcount < 0) { context->handleError(Error(GL_INVALID_VALUE)); return false; } if (!ValidateDrawArrays(context, mode, first, count, primcount)) { return false; } // No-op if zero primitive count return (primcount > 0); } static bool ValidateDrawInstancedANGLE(Context *context) { // Verify there is at least one active attribute with a divisor of zero const gl::State &state = context->getGLState(); gl::Program *program = state.getProgram(); const VertexArray *vao = state.getVertexArray(); for (size_t attributeIndex = 0; attributeIndex < MAX_VERTEX_ATTRIBS; attributeIndex++) { const VertexAttribute &attrib = vao->getVertexAttribute(attributeIndex); if (program->isAttribLocationActive(attributeIndex) && attrib.divisor == 0) { return true; } } context->handleError(Error(GL_INVALID_OPERATION, "ANGLE_instanced_arrays requires that at least one active attribute" "has a divisor of zero.")); return false; } bool ValidateDrawArraysInstancedANGLE(Context *context, GLenum mode, GLint first, GLsizei count, GLsizei primcount) { if (!ValidateDrawInstancedANGLE(context)) { return false; } return ValidateDrawArraysInstanced(context, mode, first, count, primcount); } bool ValidateDrawElements(ValidationContext *context, GLenum mode, GLsizei count, GLenum type, const GLvoid *indices, GLsizei primcount, IndexRange *indexRangeOut) { switch (type) { case GL_UNSIGNED_BYTE: case GL_UNSIGNED_SHORT: break; case GL_UNSIGNED_INT: if (context->getClientMajorVersion() < 3 && !context->getExtensions().elementIndexUint) { context->handleError(Error(GL_INVALID_ENUM)); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM)); return false; } const State &state = context->getGLState(); gl::TransformFeedback *curTransformFeedback = state.getCurrentTransformFeedback(); if (curTransformFeedback && curTransformFeedback->isActive() && !curTransformFeedback->isPaused()) { // It is an invalid operation to call DrawElements, DrawRangeElements or DrawElementsInstanced // while transform feedback is active, (3.0.2, section 2.14, pg 86) context->handleError(Error(GL_INVALID_OPERATION)); return false; } // Check for mapped buffers if (state.hasMappedBuffer(GL_ELEMENT_ARRAY_BUFFER)) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } const gl::VertexArray *vao = state.getVertexArray(); gl::Buffer *elementArrayBuffer = vao->getElementArrayBuffer().get(); if (!indices && !elementArrayBuffer) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (elementArrayBuffer) { const gl::Type &typeInfo = gl::GetTypeInfo(type); GLint64 offset = reinterpret_cast<GLint64>(indices); GLint64 byteCount = static_cast<GLint64>(typeInfo.bytes) * static_cast<GLint64>(count)+offset; // check for integer overflows if (static_cast<GLuint>(count) > (std::numeric_limits<GLuint>::max() / typeInfo.bytes) || byteCount > static_cast<GLint64>(std::numeric_limits<GLuint>::max())) { context->handleError(Error(GL_OUT_OF_MEMORY)); return false; } // Check for reading past the end of the bound buffer object if (byteCount > elementArrayBuffer->getSize()) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } } else if (!indices) { // Catch this programming error here context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (!ValidateDrawBase(context, mode, count, primcount)) { return false; } // Use max index to validate if our vertex buffers are large enough for the pull. // TODO: offer fast path, with disabled index validation. // TODO: also disable index checking on back-ends that are robust to out-of-range accesses. if (elementArrayBuffer) { uintptr_t offset = reinterpret_cast<uintptr_t>(indices); Error error = elementArrayBuffer->getIndexRange(type, static_cast<size_t>(offset), count, state.isPrimitiveRestartEnabled(), indexRangeOut); if (error.isError()) { context->handleError(error); return false; } } else { *indexRangeOut = ComputeIndexRange(type, indices, count, state.isPrimitiveRestartEnabled()); } // If we use an index greater than our maximum supported index range, return an error. // The ES3 spec does not specify behaviour here, it is undefined, but ANGLE should always // return an error if possible here. if (static_cast<GLuint64>(indexRangeOut->end) >= context->getCaps().maxElementIndex) { context->handleError(Error(GL_INVALID_OPERATION, g_ExceedsMaxElementErrorMessage)); return false; } if (!ValidateDrawAttribs(context, primcount, static_cast<GLint>(indexRangeOut->vertexCount()))) { return false; } // No op if there are no real indices in the index data (all are primitive restart). return (indexRangeOut->vertexIndexCount > 0); } bool ValidateDrawElementsInstanced(Context *context, GLenum mode, GLsizei count, GLenum type, const GLvoid *indices, GLsizei primcount, IndexRange *indexRangeOut) { if (primcount < 0) { context->handleError(Error(GL_INVALID_VALUE)); return false; } if (!ValidateDrawElements(context, mode, count, type, indices, primcount, indexRangeOut)) { return false; } // No-op zero primitive count return (primcount > 0); } bool ValidateDrawElementsInstancedANGLE(Context *context, GLenum mode, GLsizei count, GLenum type, const GLvoid *indices, GLsizei primcount, IndexRange *indexRangeOut) { if (!ValidateDrawInstancedANGLE(context)) { return false; } return ValidateDrawElementsInstanced(context, mode, count, type, indices, primcount, indexRangeOut); } bool ValidateFramebufferTextureBase(Context *context, GLenum target, GLenum attachment, GLuint texture, GLint level) { if (!ValidFramebufferTarget(target)) { context->handleError(Error(GL_INVALID_ENUM)); return false; } if (!ValidateAttachmentTarget(context, attachment)) { return false; } if (texture != 0) { gl::Texture *tex = context->getTexture(texture); if (tex == NULL) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (level < 0) { context->handleError(Error(GL_INVALID_VALUE)); return false; } } const gl::Framebuffer *framebuffer = context->getGLState().getTargetFramebuffer(target); ASSERT(framebuffer); if (framebuffer->id() == 0) { context->handleError( Error(GL_INVALID_OPERATION, "Cannot change default FBO's attachments")); return false; } return true; } bool ValidateFramebufferTexture2D(Context *context, GLenum target, GLenum attachment, GLenum textarget, GLuint texture, GLint level) { // Attachments are required to be bound to level 0 without ES3 or the GL_OES_fbo_render_mipmap extension if (context->getClientMajorVersion() < 3 && !context->getExtensions().fboRenderMipmap && level != 0) { context->handleError(Error(GL_INVALID_VALUE)); return false; } if (!ValidateFramebufferTextureBase(context, target, attachment, texture, level)) { return false; } if (texture != 0) { gl::Texture *tex = context->getTexture(texture); ASSERT(tex); const gl::Caps &caps = context->getCaps(); switch (textarget) { case GL_TEXTURE_2D: { if (level > gl::log2(caps.max2DTextureSize)) { context->handleError(Error(GL_INVALID_VALUE)); return false; } if (tex->getTarget() != GL_TEXTURE_2D) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } } break; case GL_TEXTURE_CUBE_MAP_POSITIVE_X: case GL_TEXTURE_CUBE_MAP_NEGATIVE_X: case GL_TEXTURE_CUBE_MAP_POSITIVE_Y: case GL_TEXTURE_CUBE_MAP_NEGATIVE_Y: case GL_TEXTURE_CUBE_MAP_POSITIVE_Z: case GL_TEXTURE_CUBE_MAP_NEGATIVE_Z: { if (level > gl::log2(caps.maxCubeMapTextureSize)) { context->handleError(Error(GL_INVALID_VALUE)); return false; } if (tex->getTarget() != GL_TEXTURE_CUBE_MAP) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } } break; default: context->handleError(Error(GL_INVALID_ENUM)); return false; } const Format &format = tex->getFormat(textarget, level); if (format.info->compressed) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } } return true; } bool ValidateGetUniformBase(Context *context, GLuint program, GLint location) { if (program == 0) { context->handleError(Error(GL_INVALID_VALUE)); return false; } gl::Program *programObject = GetValidProgram(context, program); if (!programObject) { return false; } if (!programObject || !programObject->isLinked()) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } if (!programObject->isValidUniformLocation(location)) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } return true; } bool ValidateGetUniformfv(Context *context, GLuint program, GLint location, GLfloat* params) { return ValidateGetUniformBase(context, program, location); } bool ValidateGetUniformiv(Context *context, GLuint program, GLint location, GLint* params) { return ValidateGetUniformBase(context, program, location); } static bool ValidateSizedGetUniform(Context *context, GLuint program, GLint location, GLsizei bufSize, GLsizei *length) { if (length) { *length = 0; } if (!ValidateGetUniformBase(context, program, location)) { return false; } if (bufSize < 0) { context->handleError(Error(GL_INVALID_VALUE, "bufSize cannot be negative.")); return false; } gl::Program *programObject = context->getProgram(program); ASSERT(programObject); // sized queries -- ensure the provided buffer is large enough const LinkedUniform &uniform = programObject->getUniformByLocation(location); size_t requiredBytes = VariableExternalSize(uniform.type); if (static_cast<size_t>(bufSize) < requiredBytes) { context->handleError( Error(GL_INVALID_OPERATION, "bufSize of at least %u is required.", requiredBytes)); return false; } if (length) { *length = VariableComponentCount(uniform.type); } return true; } bool ValidateGetnUniformfvEXT(Context *context, GLuint program, GLint location, GLsizei bufSize, GLfloat* params) { return ValidateSizedGetUniform(context, program, location, bufSize, nullptr); } bool ValidateGetnUniformivEXT(Context *context, GLuint program, GLint location, GLsizei bufSize, GLint* params) { return ValidateSizedGetUniform(context, program, location, bufSize, nullptr); } bool ValidateGetUniformfvRobustANGLE(Context *context, GLuint program, GLint location, GLsizei bufSize, GLsizei *length, GLfloat *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } // bufSize is validated in ValidateSizedGetUniform return ValidateSizedGetUniform(context, program, location, bufSize, length); } bool ValidateGetUniformivRobustANGLE(Context *context, GLuint program, GLint location, GLsizei bufSize, GLsizei *length, GLint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } // bufSize is validated in ValidateSizedGetUniform return ValidateSizedGetUniform(context, program, location, bufSize, length); } bool ValidateGetUniformuivRobustANGLE(Context *context, GLuint program, GLint location, GLsizei bufSize, GLsizei *length, GLuint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (context->getClientMajorVersion() < 3) { context->handleError( Error(GL_INVALID_OPERATION, "Entry point requires at least OpenGL ES 3.0.")); return false; } // bufSize is validated in ValidateSizedGetUniform return ValidateSizedGetUniform(context, program, location, bufSize, length); } bool ValidateDiscardFramebufferBase(Context *context, GLenum target, GLsizei numAttachments, const GLenum *attachments, bool defaultFramebuffer) { if (numAttachments < 0) { context->handleError(Error(GL_INVALID_VALUE, "numAttachments must not be less than zero")); return false; } for (GLsizei i = 0; i < numAttachments; ++i) { if (attachments[i] >= GL_COLOR_ATTACHMENT0 && attachments[i] <= GL_COLOR_ATTACHMENT31) { if (defaultFramebuffer) { context->handleError(Error( GL_INVALID_ENUM, "Invalid attachment when the default framebuffer is bound")); return false; } if (attachments[i] >= GL_COLOR_ATTACHMENT0 + context->getCaps().maxColorAttachments) { context->handleError(Error(GL_INVALID_OPERATION, "Requested color attachment is greater than the maximum " "supported color attachments")); return false; } } else { switch (attachments[i]) { case GL_DEPTH_ATTACHMENT: case GL_STENCIL_ATTACHMENT: case GL_DEPTH_STENCIL_ATTACHMENT: if (defaultFramebuffer) { context->handleError( Error(GL_INVALID_ENUM, "Invalid attachment when the default framebuffer is bound")); return false; } break; case GL_COLOR: case GL_DEPTH: case GL_STENCIL: if (!defaultFramebuffer) { context->handleError( Error(GL_INVALID_ENUM, "Invalid attachment when the default framebuffer is not bound")); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM, "Invalid attachment")); return false; } } } return true; } bool ValidateInsertEventMarkerEXT(Context *context, GLsizei length, const char *marker) { // Note that debug marker calls must not set error state if (length < 0) { return false; } if (marker == nullptr) { return false; } return true; } bool ValidatePushGroupMarkerEXT(Context *context, GLsizei length, const char *marker) { // Note that debug marker calls must not set error state if (length < 0) { return false; } if (length > 0 && marker == nullptr) { return false; } return true; } bool ValidateEGLImageTargetTexture2DOES(Context *context, egl::Display *display, GLenum target, egl::Image *image) { if (!context->getExtensions().eglImage && !context->getExtensions().eglImageExternal) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } switch (target) { case GL_TEXTURE_2D: if (!context->getExtensions().eglImage) { context->handleError(Error( GL_INVALID_ENUM, "GL_TEXTURE_2D texture target requires GL_OES_EGL_image.")); } break; case GL_TEXTURE_EXTERNAL_OES: if (!context->getExtensions().eglImageExternal) { context->handleError(Error( GL_INVALID_ENUM, "GL_TEXTURE_EXTERNAL_OES texture target requires GL_OES_EGL_image_external.")); } break; default: context->handleError(Error(GL_INVALID_ENUM, "invalid texture target.")); return false; } if (!display->isValidImage(image)) { context->handleError(Error(GL_INVALID_VALUE, "EGL image is not valid.")); return false; } if (image->getSamples() > 0) { context->handleError(Error(GL_INVALID_OPERATION, "cannot create a 2D texture from a multisampled EGL image.")); return false; } const TextureCaps &textureCaps = context->getTextureCaps().get(image->getFormat().asSized()); if (!textureCaps.texturable) { context->handleError(Error(GL_INVALID_OPERATION, "EGL image internal format is not supported as a texture.")); return false; } return true; } bool ValidateEGLImageTargetRenderbufferStorageOES(Context *context, egl::Display *display, GLenum target, egl::Image *image) { if (!context->getExtensions().eglImage) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } switch (target) { case GL_RENDERBUFFER: break; default: context->handleError(Error(GL_INVALID_ENUM, "invalid renderbuffer target.")); return false; } if (!display->isValidImage(image)) { context->handleError(Error(GL_INVALID_VALUE, "EGL image is not valid.")); return false; } const TextureCaps &textureCaps = context->getTextureCaps().get(image->getFormat().asSized()); if (!textureCaps.renderable) { context->handleError(Error( GL_INVALID_OPERATION, "EGL image internal format is not supported as a renderbuffer.")); return false; } return true; } bool ValidateBindVertexArrayBase(Context *context, GLuint array) { if (!context->isVertexArrayGenerated(array)) { // The default VAO should always exist ASSERT(array != 0); context->handleError(Error(GL_INVALID_OPERATION)); return false; } return true; } bool ValidateLinkProgram(Context *context, GLuint program) { if (context->hasActiveTransformFeedback(program)) { // ES 3.0.4 section 2.15 page 91 context->handleError(Error(GL_INVALID_OPERATION, "Cannot link program while program is associated with an active " "transform feedback object.")); return false; } return true; } bool ValidateProgramBinaryBase(Context *context, GLuint program, GLenum binaryFormat, const void *binary, GLint length) { Program *programObject = GetValidProgram(context, program); if (programObject == nullptr) { return false; } const std::vector<GLenum> &programBinaryFormats = context->getCaps().programBinaryFormats; if (std::find(programBinaryFormats.begin(), programBinaryFormats.end(), binaryFormat) == programBinaryFormats.end()) { context->handleError(Error(GL_INVALID_ENUM, "Program binary format is not valid.")); return false; } if (context->hasActiveTransformFeedback(program)) { // ES 3.0.4 section 2.15 page 91 context->handleError(Error(GL_INVALID_OPERATION, "Cannot change program binary while program is associated with " "an active transform feedback object.")); return false; } return true; } bool ValidateGetProgramBinaryBase(Context *context, GLuint program, GLsizei bufSize, GLsizei *length, GLenum *binaryFormat, void *binary) { Program *programObject = GetValidProgram(context, program); if (programObject == nullptr) { return false; } if (!programObject->isLinked()) { context->handleError(Error(GL_INVALID_OPERATION, "Program is not linked.")); return false; } return true; } bool ValidateUseProgram(Context *context, GLuint program) { if (program != 0) { Program *programObject = context->getProgram(program); if (!programObject) { // ES 3.1.0 section 7.3 page 72 if (context->getShader(program)) { context->handleError( Error(GL_INVALID_OPERATION, "Attempted to use a single shader instead of a shader program.")); return false; } else { context->handleError(Error(GL_INVALID_VALUE, "Program invalid.")); return false; } } if (!programObject->isLinked()) { context->handleError(Error(GL_INVALID_OPERATION, "Program not linked.")); return false; } } if (context->getGLState().isTransformFeedbackActiveUnpaused()) { // ES 3.0.4 section 2.15 page 91 context->handleError( Error(GL_INVALID_OPERATION, "Cannot change active program while transform feedback is unpaused.")); return false; } return true; } bool ValidateCopyTexImage2D(ValidationContext *context, GLenum target, GLint level, GLenum internalformat, GLint x, GLint y, GLsizei width, GLsizei height, GLint border) { if (context->getClientMajorVersion() < 3) { return ValidateES2CopyTexImageParameters(context, target, level, internalformat, false, 0, 0, x, y, width, height, border); } ASSERT(context->getClientMajorVersion() == 3); return ValidateES3CopyTexImage2DParameters(context, target, level, internalformat, false, 0, 0, 0, x, y, width, height, border); } bool ValidateFramebufferRenderbuffer(Context *context, GLenum target, GLenum attachment, GLenum renderbuffertarget, GLuint renderbuffer) { if (!ValidFramebufferTarget(target) || (renderbuffertarget != GL_RENDERBUFFER && renderbuffer != 0)) { context->handleError(Error(GL_INVALID_ENUM)); return false; } return ValidateFramebufferRenderbufferParameters(context, target, attachment, renderbuffertarget, renderbuffer); } bool ValidateDrawBuffersBase(ValidationContext *context, GLsizei n, const GLenum *bufs) { // INVALID_VALUE is generated if n is negative or greater than value of MAX_DRAW_BUFFERS if (n < 0 || static_cast<GLuint>(n) > context->getCaps().maxDrawBuffers) { context->handleError( Error(GL_INVALID_VALUE, "n must be non-negative and no greater than MAX_DRAW_BUFFERS")); return false; } ASSERT(context->getGLState().getDrawFramebuffer()); GLuint frameBufferId = context->getGLState().getDrawFramebuffer()->id(); GLuint maxColorAttachment = GL_COLOR_ATTACHMENT0_EXT + context->getCaps().maxColorAttachments; // This should come first before the check for the default frame buffer // because when we switch to ES3.1+, invalid enums will return INVALID_ENUM // rather than INVALID_OPERATION for (int colorAttachment = 0; colorAttachment < n; colorAttachment++) { const GLenum attachment = GL_COLOR_ATTACHMENT0_EXT + colorAttachment; if (bufs[colorAttachment] != GL_NONE && bufs[colorAttachment] != GL_BACK && (bufs[colorAttachment] < GL_COLOR_ATTACHMENT0 || bufs[colorAttachment] > GL_COLOR_ATTACHMENT31)) { // Value in bufs is not NONE, BACK, or GL_COLOR_ATTACHMENTi // The 3.0.4 spec says to generate GL_INVALID_OPERATION here, but this // was changed to GL_INVALID_ENUM in 3.1, which dEQP also expects. // 3.1 is still a bit ambiguous about the error, but future specs are // expected to clarify that GL_INVALID_ENUM is the correct error. context->handleError(Error(GL_INVALID_ENUM, "Invalid buffer value")); return false; } else if (bufs[colorAttachment] >= maxColorAttachment) { context->handleError( Error(GL_INVALID_OPERATION, "Buffer value is greater than MAX_DRAW_BUFFERS")); return false; } else if (bufs[colorAttachment] != GL_NONE && bufs[colorAttachment] != attachment && frameBufferId != 0) { // INVALID_OPERATION-GL is bound to buffer and ith argument // is not COLOR_ATTACHMENTi or NONE context->handleError( Error(GL_INVALID_OPERATION, "Ith value does not match COLOR_ATTACHMENTi or NONE")); return false; } } // INVALID_OPERATION is generated if GL is bound to the default framebuffer // and n is not 1 or bufs is bound to value other than BACK and NONE if (frameBufferId == 0) { if (n != 1) { context->handleError(Error(GL_INVALID_OPERATION, "n must be 1 when GL is bound to the default framebuffer")); return false; } if (bufs[0] != GL_NONE && bufs[0] != GL_BACK) { context->handleError(Error( GL_INVALID_OPERATION, "Only NONE or BACK are valid values when drawing to the default framebuffer")); return false; } } return true; } bool ValidateCopyTexSubImage2D(Context *context, GLenum target, GLint level, GLint xoffset, GLint yoffset, GLint x, GLint y, GLsizei width, GLsizei height) { if (context->getClientMajorVersion() < 3) { return ValidateES2CopyTexImageParameters(context, target, level, GL_NONE, true, xoffset, yoffset, x, y, width, height, 0); } return ValidateES3CopyTexImage2DParameters(context, target, level, GL_NONE, true, xoffset, yoffset, 0, x, y, width, height, 0); } bool ValidateGetBufferPointervBase(Context *context, GLenum target, GLenum pname, GLsizei *length, void **params) { if (length) { *length = 0; } if (context->getClientMajorVersion() < 3 && !context->getExtensions().mapBuffer) { context->handleError( Error(GL_INVALID_OPERATION, "Context does not support OpenGL ES 3.0 or GL_OES_map_buffer is not enabled.")); return false; } if (!ValidBufferTarget(context, target)) { context->handleError(Error(GL_INVALID_ENUM, "Buffer target not valid: 0x%X", target)); return false; } switch (pname) { case GL_BUFFER_MAP_POINTER: break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown pname.")); return false; } // GLES 3.0 section 2.10.1: "Attempts to attempts to modify or query buffer object state for a // target bound to zero generate an INVALID_OPERATION error." // GLES 3.1 section 6.6 explicitly specifies this error. if (context->getGLState().getTargetBuffer(target) == nullptr) { context->handleError( Error(GL_INVALID_OPERATION, "Can not get pointer for reserved buffer name zero.")); return false; } if (length) { *length = 1; } return true; } bool ValidateUnmapBufferBase(Context *context, GLenum target) { if (!ValidBufferTarget(context, target)) { context->handleError(Error(GL_INVALID_ENUM, "Invalid buffer target.")); return false; } Buffer *buffer = context->getGLState().getTargetBuffer(target); if (buffer == nullptr || !buffer->isMapped()) { context->handleError(Error(GL_INVALID_OPERATION, "Buffer not mapped.")); return false; } return true; } bool ValidateMapBufferRangeBase(Context *context, GLenum target, GLintptr offset, GLsizeiptr length, GLbitfield access) { if (!ValidBufferTarget(context, target)) { context->handleError(Error(GL_INVALID_ENUM, "Invalid buffer target.")); return false; } if (offset < 0 || length < 0) { context->handleError(Error(GL_INVALID_VALUE, "Invalid offset or length.")); return false; } Buffer *buffer = context->getGLState().getTargetBuffer(target); if (!buffer) { context->handleError(Error(GL_INVALID_OPERATION, "Attempted to map buffer object zero.")); return false; } // Check for buffer overflow CheckedNumeric<size_t> checkedOffset(offset); auto checkedSize = checkedOffset + length; if (!checkedSize.IsValid() || checkedSize.ValueOrDie() > static_cast<size_t>(buffer->getSize())) { context->handleError( Error(GL_INVALID_VALUE, "Mapped range does not fit into buffer dimensions.")); return false; } // Check for invalid bits in the mask GLbitfield allAccessBits = GL_MAP_READ_BIT | GL_MAP_WRITE_BIT | GL_MAP_INVALIDATE_RANGE_BIT | GL_MAP_INVALIDATE_BUFFER_BIT | GL_MAP_FLUSH_EXPLICIT_BIT | GL_MAP_UNSYNCHRONIZED_BIT; if (access & ~(allAccessBits)) { context->handleError(Error(GL_INVALID_VALUE, "Invalid access bits: 0x%X.", access)); return false; } if (length == 0) { context->handleError(Error(GL_INVALID_OPERATION, "Buffer mapping length is zero.")); return false; } if (buffer->isMapped()) { context->handleError(Error(GL_INVALID_OPERATION, "Buffer is already mapped.")); return false; } // Check for invalid bit combinations if ((access & (GL_MAP_READ_BIT | GL_MAP_WRITE_BIT)) == 0) { context->handleError( Error(GL_INVALID_OPERATION, "Need to map buffer for either reading or writing.")); return false; } GLbitfield writeOnlyBits = GL_MAP_INVALIDATE_RANGE_BIT | GL_MAP_INVALIDATE_BUFFER_BIT | GL_MAP_UNSYNCHRONIZED_BIT; if ((access & GL_MAP_READ_BIT) != 0 && (access & writeOnlyBits) != 0) { context->handleError(Error(GL_INVALID_OPERATION, "Invalid access bits when mapping buffer for reading: 0x%X.", access)); return false; } if ((access & GL_MAP_WRITE_BIT) == 0 && (access & GL_MAP_FLUSH_EXPLICIT_BIT) != 0) { context->handleError(Error( GL_INVALID_OPERATION, "The explicit flushing bit may only be set if the buffer is mapped for writing.")); return false; } return true; } bool ValidateFlushMappedBufferRangeBase(Context *context, GLenum target, GLintptr offset, GLsizeiptr length) { if (offset < 0 || length < 0) { context->handleError(Error(GL_INVALID_VALUE, "Invalid offset/length parameters.")); return false; } if (!ValidBufferTarget(context, target)) { context->handleError(Error(GL_INVALID_ENUM, "Invalid buffer target.")); return false; } Buffer *buffer = context->getGLState().getTargetBuffer(target); if (buffer == nullptr) { context->handleError(Error(GL_INVALID_OPERATION, "Attempted to flush buffer object zero.")); return false; } if (!buffer->isMapped() || (buffer->getAccessFlags() & GL_MAP_FLUSH_EXPLICIT_BIT) == 0) { context->handleError(Error( GL_INVALID_OPERATION, "Attempted to flush a buffer not mapped for explicit flushing.")); return false; } // Check for buffer overflow CheckedNumeric<size_t> checkedOffset(offset); auto checkedSize = checkedOffset + length; if (!checkedSize.IsValid() || checkedSize.ValueOrDie() > static_cast<size_t>(buffer->getMapLength())) { context->handleError( Error(GL_INVALID_VALUE, "Flushed range does not fit into buffer mapping dimensions.")); return false; } return true; } bool ValidateGenerateMipmap(Context *context, GLenum target) { if (!ValidTextureTarget(context, target)) { context->handleError(Error(GL_INVALID_ENUM)); return false; } Texture *texture = context->getTargetTexture(target); if (texture == nullptr) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } const GLuint effectiveBaseLevel = texture->getTextureState().getEffectiveBaseLevel(); // This error isn't spelled out in the spec in a very explicit way, but we interpret the spec so // that out-of-range base level has a non-color-renderable / non-texture-filterable format. if (effectiveBaseLevel >= gl::IMPLEMENTATION_MAX_TEXTURE_LEVELS) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } GLenum baseTarget = (target == GL_TEXTURE_CUBE_MAP) ? GL_TEXTURE_CUBE_MAP_POSITIVE_X : target; const auto &format = texture->getFormat(baseTarget, effectiveBaseLevel); const TextureCaps &formatCaps = context->getTextureCaps().get(format.asSized()); // GenerateMipmap should not generate an INVALID_OPERATION for textures created with // unsized formats or that are color renderable and filterable. Since we do not track if // the texture was created with sized or unsized format (only sized formats are stored), // it is not possible to make sure the the LUMA formats can generate mipmaps (they should // be able to) because they aren't color renderable. Simply do a special case for LUMA // textures since they're the only texture format that can be created with unsized formats // that is not color renderable. New unsized formats are unlikely to be added, since ES2 // was the last version to use add them. if (format.info->depthBits > 0 || format.info->stencilBits > 0 || !formatCaps.filterable || (!formatCaps.renderable && !format.info->isLUMA()) || format.info->compressed) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } // GL_EXT_sRGB does not support mipmap generation on sRGB textures if (context->getClientMajorVersion() == 2 && format.info->colorEncoding == GL_SRGB) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } // Non-power of 2 ES2 check if (context->getClientVersion() < Version(3, 0) && !context->getExtensions().textureNPOT && (!isPow2(static_cast<int>(texture->getWidth(baseTarget, 0))) || !isPow2(static_cast<int>(texture->getHeight(baseTarget, 0))))) { ASSERT(target == GL_TEXTURE_2D || target == GL_TEXTURE_CUBE_MAP); context->handleError(Error(GL_INVALID_OPERATION)); return false; } // Cube completeness check if (target == GL_TEXTURE_CUBE_MAP && !texture->getTextureState().isCubeComplete()) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } return true; } bool ValidateGenBuffers(Context *context, GLint n, GLuint *) { return ValidateGenOrDelete(context, n); } bool ValidateDeleteBuffers(Context *context, GLint n, const GLuint *) { return ValidateGenOrDelete(context, n); } bool ValidateGenFramebuffers(Context *context, GLint n, GLuint *) { return ValidateGenOrDelete(context, n); } bool ValidateDeleteFramebuffers(Context *context, GLint n, const GLuint *) { return ValidateGenOrDelete(context, n); } bool ValidateGenRenderbuffers(Context *context, GLint n, GLuint *) { return ValidateGenOrDelete(context, n); } bool ValidateDeleteRenderbuffers(Context *context, GLint n, const GLuint *) { return ValidateGenOrDelete(context, n); } bool ValidateGenTextures(Context *context, GLint n, GLuint *) { return ValidateGenOrDelete(context, n); } bool ValidateDeleteTextures(Context *context, GLint n, const GLuint *) { return ValidateGenOrDelete(context, n); } bool ValidateGenOrDelete(Context *context, GLint n) { if (n < 0) { context->handleError(Error(GL_INVALID_VALUE, "n < 0")); return false; } return true; } bool ValidateEnable(Context *context, GLenum cap) { if (!ValidCap(context, cap, false)) { context->handleError(Error(GL_INVALID_ENUM, "Invalid cap.")); return false; } if (context->getLimitations().noSampleAlphaToCoverageSupport && cap == GL_SAMPLE_ALPHA_TO_COVERAGE) { const char *errorMessage = "Current renderer doesn't support alpha-to-coverage"; context->handleError(Error(GL_INVALID_OPERATION, errorMessage)); // We also output an error message to the debugger window if tracing is active, so that // developers can see the error message. ERR("%s", errorMessage); return false; } return true; } bool ValidateDisable(Context *context, GLenum cap) { if (!ValidCap(context, cap, false)) { context->handleError(Error(GL_INVALID_ENUM, "Invalid cap.")); return false; } return true; } bool ValidateIsEnabled(Context *context, GLenum cap) { if (!ValidCap(context, cap, true)) { context->handleError(Error(GL_INVALID_ENUM, "Invalid cap.")); return false; } return true; } bool ValidateRobustEntryPoint(ValidationContext *context, GLsizei bufSize) { if (!context->getExtensions().robustClientMemory) { context->handleError( Error(GL_INVALID_OPERATION, "GL_ANGLE_robust_client_memory is not available.")); return false; } if (bufSize < 0) { context->handleError(Error(GL_INVALID_VALUE, "bufSize cannot be negative.")); return false; } return true; } bool ValidateRobustBufferSize(ValidationContext *context, GLsizei bufSize, GLsizei numParams) { if (bufSize < numParams) { context->handleError(Error(GL_INVALID_OPERATION, "%u parameters are required but %i were provided.", numParams, bufSize)); return false; } return true; } bool ValidateGetFramebufferAttachmentParameteriv(ValidationContext *context, GLenum target, GLenum attachment, GLenum pname, GLsizei *numParams) { // Only one parameter is returned from glGetFramebufferAttachmentParameteriv *numParams = 1; if (!ValidFramebufferTarget(target)) { context->handleError(Error(GL_INVALID_ENUM)); return false; } int clientVersion = context->getClientMajorVersion(); switch (pname) { case GL_FRAMEBUFFER_ATTACHMENT_OBJECT_TYPE: case GL_FRAMEBUFFER_ATTACHMENT_OBJECT_NAME: case GL_FRAMEBUFFER_ATTACHMENT_TEXTURE_LEVEL: case GL_FRAMEBUFFER_ATTACHMENT_TEXTURE_CUBE_MAP_FACE: break; case GL_FRAMEBUFFER_ATTACHMENT_COLOR_ENCODING: if (clientVersion < 3 && !context->getExtensions().sRGB) { context->handleError(Error(GL_INVALID_ENUM)); return false; } break; case GL_FRAMEBUFFER_ATTACHMENT_RED_SIZE: case GL_FRAMEBUFFER_ATTACHMENT_GREEN_SIZE: case GL_FRAMEBUFFER_ATTACHMENT_BLUE_SIZE: case GL_FRAMEBUFFER_ATTACHMENT_ALPHA_SIZE: case GL_FRAMEBUFFER_ATTACHMENT_DEPTH_SIZE: case GL_FRAMEBUFFER_ATTACHMENT_STENCIL_SIZE: case GL_FRAMEBUFFER_ATTACHMENT_COMPONENT_TYPE: case GL_FRAMEBUFFER_ATTACHMENT_TEXTURE_LAYER: if (clientVersion < 3) { context->handleError(Error(GL_INVALID_ENUM)); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM)); return false; } // Determine if the attachment is a valid enum switch (attachment) { case GL_BACK: case GL_FRONT: case GL_DEPTH: case GL_STENCIL: case GL_DEPTH_STENCIL_ATTACHMENT: if (clientVersion < 3) { context->handleError(Error(GL_INVALID_ENUM)); return false; } break; case GL_DEPTH_ATTACHMENT: case GL_STENCIL_ATTACHMENT: break; default: if (attachment < GL_COLOR_ATTACHMENT0_EXT || (attachment - GL_COLOR_ATTACHMENT0_EXT) >= context->getCaps().maxColorAttachments) { context->handleError(Error(GL_INVALID_ENUM)); return false; } break; } const Framebuffer *framebuffer = context->getGLState().getTargetFramebuffer(target); ASSERT(framebuffer); if (framebuffer->id() == 0) { if (clientVersion < 3) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } switch (attachment) { case GL_BACK: case GL_DEPTH: case GL_STENCIL: break; default: context->handleError(Error(GL_INVALID_OPERATION)); return false; } } else { if (attachment >= GL_COLOR_ATTACHMENT0_EXT && attachment <= GL_COLOR_ATTACHMENT15_EXT) { // Valid attachment query } else { switch (attachment) { case GL_DEPTH_ATTACHMENT: case GL_STENCIL_ATTACHMENT: break; case GL_DEPTH_STENCIL_ATTACHMENT: if (!framebuffer->hasValidDepthStencil()) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } break; default: context->handleError(Error(GL_INVALID_OPERATION)); return false; } } } const FramebufferAttachment *attachmentObject = framebuffer->getAttachment(attachment); if (attachmentObject) { ASSERT(attachmentObject->type() == GL_RENDERBUFFER || attachmentObject->type() == GL_TEXTURE || attachmentObject->type() == GL_FRAMEBUFFER_DEFAULT); switch (pname) { case GL_FRAMEBUFFER_ATTACHMENT_OBJECT_NAME: if (attachmentObject->type() != GL_RENDERBUFFER && attachmentObject->type() != GL_TEXTURE) { context->handleError(Error(GL_INVALID_ENUM)); return false; } break; case GL_FRAMEBUFFER_ATTACHMENT_TEXTURE_LEVEL: if (attachmentObject->type() != GL_TEXTURE) { context->handleError(Error(GL_INVALID_ENUM)); return false; } break; case GL_FRAMEBUFFER_ATTACHMENT_TEXTURE_CUBE_MAP_FACE: if (attachmentObject->type() != GL_TEXTURE) { context->handleError(Error(GL_INVALID_ENUM)); return false; } break; case GL_FRAMEBUFFER_ATTACHMENT_COMPONENT_TYPE: if (attachment == GL_DEPTH_STENCIL_ATTACHMENT) { context->handleError(Error(GL_INVALID_OPERATION)); return false; } break; case GL_FRAMEBUFFER_ATTACHMENT_TEXTURE_LAYER: if (attachmentObject->type() != GL_TEXTURE) { context->handleError(Error(GL_INVALID_ENUM)); return false; } break; default: break; } } else { // ES 2.0.25 spec pg 127 states that if the value of FRAMEBUFFER_ATTACHMENT_OBJECT_TYPE // is NONE, then querying any other pname will generate INVALID_ENUM. // ES 3.0.2 spec pg 235 states that if the attachment type is none, // GL_FRAMEBUFFER_ATTACHMENT_OBJECT_NAME will return zero and be an // INVALID_OPERATION for all other pnames switch (pname) { case GL_FRAMEBUFFER_ATTACHMENT_OBJECT_TYPE: break; case GL_FRAMEBUFFER_ATTACHMENT_OBJECT_NAME: if (clientVersion < 3) { context->handleError(Error(GL_INVALID_ENUM)); return false; } break; default: if (clientVersion < 3) { context->handleError(Error(GL_INVALID_ENUM)); return false; } else { context->handleError(Error(GL_INVALID_OPERATION)); return false; } } } return true; } bool ValidateGetFramebufferAttachmentParameterivRobustANGLE(ValidationContext *context, GLenum target, GLenum attachment, GLenum pname, GLsizei bufSize, GLsizei *numParams) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetFramebufferAttachmentParameteriv(context, target, attachment, pname, numParams)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *numParams)) { return false; } return true; } bool ValidateGetBufferParameteriv(ValidationContext *context, GLenum target, GLenum pname, GLint *params) { return ValidateGetBufferParameterBase(context, target, pname, false, nullptr); } bool ValidateGetBufferParameterivRobustANGLE(ValidationContext *context, GLenum target, GLenum pname, GLsizei bufSize, GLsizei *length, GLint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetBufferParameterBase(context, target, pname, false, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetBufferParameteri64v(ValidationContext *context, GLenum target, GLenum pname, GLint64 *params) { return ValidateGetBufferParameterBase(context, target, pname, false, nullptr); } bool ValidateGetBufferParameteri64vRobustANGLE(ValidationContext *context, GLenum target, GLenum pname, GLsizei bufSize, GLsizei *length, GLint64 *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetBufferParameterBase(context, target, pname, false, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetProgramiv(Context *context, GLuint program, GLenum pname, GLsizei *numParams) { // Currently, all GetProgramiv queries return 1 parameter *numParams = 1; Program *programObject = GetValidProgram(context, program); if (!programObject) { return false; } switch (pname) { case GL_DELETE_STATUS: case GL_LINK_STATUS: case GL_VALIDATE_STATUS: case GL_INFO_LOG_LENGTH: case GL_ATTACHED_SHADERS: case GL_ACTIVE_ATTRIBUTES: case GL_ACTIVE_ATTRIBUTE_MAX_LENGTH: case GL_ACTIVE_UNIFORMS: case GL_ACTIVE_UNIFORM_MAX_LENGTH: break; case GL_PROGRAM_BINARY_LENGTH: if (context->getClientMajorVersion() < 3 && !context->getExtensions().getProgramBinary) { context->handleError(Error(GL_INVALID_ENUM, "Querying GL_PROGRAM_BINARY_LENGTH requires " "GL_OES_get_program_binary or ES 3.0.")); return false; } break; case GL_ACTIVE_UNIFORM_BLOCKS: case GL_ACTIVE_UNIFORM_BLOCK_MAX_NAME_LENGTH: case GL_TRANSFORM_FEEDBACK_BUFFER_MODE: case GL_TRANSFORM_FEEDBACK_VARYINGS: case GL_TRANSFORM_FEEDBACK_VARYING_MAX_LENGTH: case GL_PROGRAM_BINARY_RETRIEVABLE_HINT: if (context->getClientMajorVersion() < 3) { context->handleError(Error(GL_INVALID_ENUM, "Querying requires at least ES 3.0.")); return false; } break; default: context->handleError(Error(GL_INVALID_ENUM, "Unknown parameter name.")); return false; } return true; } bool ValidateGetProgramivRobustANGLE(Context *context, GLuint program, GLenum pname, GLsizei bufSize, GLsizei *numParams) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetProgramiv(context, program, pname, numParams)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *numParams)) { return false; } return true; } bool ValidateGetRenderbufferParameteriv(Context *context, GLenum target, GLenum pname, GLint *params) { return ValidateGetRenderbufferParameterivBase(context, target, pname, nullptr); } bool ValidateGetRenderbufferParameterivRobustANGLE(Context *context, GLenum target, GLenum pname, GLsizei bufSize, GLsizei *length, GLint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetRenderbufferParameterivBase(context, target, pname, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetShaderiv(Context *context, GLuint shader, GLenum pname, GLint *params) { return ValidateGetShaderivBase(context, shader, pname, nullptr); } bool ValidateGetShaderivRobustANGLE(Context *context, GLuint shader, GLenum pname, GLsizei bufSize, GLsizei *length, GLint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetShaderivBase(context, shader, pname, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetTexParameterfv(Context *context, GLenum target, GLenum pname, GLfloat *params) { return ValidateGetTexParameterBase(context, target, pname, nullptr); } bool ValidateGetTexParameterfvRobustANGLE(Context *context, GLenum target, GLenum pname, GLsizei bufSize, GLsizei *length, GLfloat *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetTexParameterBase(context, target, pname, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetTexParameteriv(Context *context, GLenum target, GLenum pname, GLint *params) { return ValidateGetTexParameterBase(context, target, pname, nullptr); } bool ValidateGetTexParameterivRobustANGLE(Context *context, GLenum target, GLenum pname, GLsizei bufSize, GLsizei *length, GLint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetTexParameterBase(context, target, pname, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateTexParameterf(Context *context, GLenum target, GLenum pname, GLfloat param) { return ValidateTexParameterBase(context, target, pname, -1, ¶m); } bool ValidateTexParameterfv(Context *context, GLenum target, GLenum pname, const GLfloat *params) { return ValidateTexParameterBase(context, target, pname, -1, params); } bool ValidateTexParameterfvRobustANGLE(Context *context, GLenum target, GLenum pname, GLsizei bufSize, const GLfloat *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } return ValidateTexParameterBase(context, target, pname, bufSize, params); } bool ValidateTexParameteri(Context *context, GLenum target, GLenum pname, GLint param) { return ValidateTexParameterBase(context, target, pname, -1, ¶m); } bool ValidateTexParameteriv(Context *context, GLenum target, GLenum pname, const GLint *params) { return ValidateTexParameterBase(context, target, pname, -1, params); } bool ValidateTexParameterivRobustANGLE(Context *context, GLenum target, GLenum pname, GLsizei bufSize, const GLint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } return ValidateTexParameterBase(context, target, pname, bufSize, params); } bool ValidateGetSamplerParameterfv(Context *context, GLuint sampler, GLenum pname, GLfloat *params) { return ValidateGetSamplerParameterBase(context, sampler, pname, nullptr); } bool ValidateGetSamplerParameterfvRobustANGLE(Context *context, GLuint sampler, GLenum pname, GLuint bufSize, GLsizei *length, GLfloat *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetSamplerParameterBase(context, sampler, pname, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetSamplerParameteriv(Context *context, GLuint sampler, GLenum pname, GLint *params) { return ValidateGetSamplerParameterBase(context, sampler, pname, nullptr); } bool ValidateGetSamplerParameterivRobustANGLE(Context *context, GLuint sampler, GLenum pname, GLuint bufSize, GLsizei *length, GLint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetSamplerParameterBase(context, sampler, pname, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateSamplerParameterf(Context *context, GLuint sampler, GLenum pname, GLfloat param) { return ValidateSamplerParameterBase(context, sampler, pname, -1, ¶m); } bool ValidateSamplerParameterfv(Context *context, GLuint sampler, GLenum pname, const GLfloat *params) { return ValidateSamplerParameterBase(context, sampler, pname, -1, params); } bool ValidateSamplerParameterfvRobustANGLE(Context *context, GLuint sampler, GLenum pname, GLsizei bufSize, const GLfloat *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } return ValidateSamplerParameterBase(context, sampler, pname, bufSize, params); } bool ValidateSamplerParameteri(Context *context, GLuint sampler, GLenum pname, GLint param) { return ValidateSamplerParameterBase(context, sampler, pname, -1, ¶m); } bool ValidateSamplerParameteriv(Context *context, GLuint sampler, GLenum pname, const GLint *params) { return ValidateSamplerParameterBase(context, sampler, pname, -1, params); } bool ValidateSamplerParameterivRobustANGLE(Context *context, GLuint sampler, GLenum pname, GLsizei bufSize, const GLint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } return ValidateSamplerParameterBase(context, sampler, pname, bufSize, params); } bool ValidateGetVertexAttribfv(Context *context, GLuint index, GLenum pname, GLfloat *params) { return ValidateGetVertexAttribBase(context, index, pname, nullptr, false, false); } bool ValidateGetVertexAttribfvRobustANGLE(Context *context, GLuint index, GLenum pname, GLsizei bufSize, GLsizei *length, GLfloat *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetVertexAttribBase(context, index, pname, length, false, false)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetVertexAttribiv(Context *context, GLuint index, GLenum pname, GLint *params) { return ValidateGetVertexAttribBase(context, index, pname, nullptr, false, false); } bool ValidateGetVertexAttribivRobustANGLE(Context *context, GLuint index, GLenum pname, GLsizei bufSize, GLsizei *length, GLint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetVertexAttribBase(context, index, pname, length, false, false)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetVertexAttribPointerv(Context *context, GLuint index, GLenum pname, void **pointer) { return ValidateGetVertexAttribBase(context, index, pname, nullptr, true, false); } bool ValidateGetVertexAttribPointervRobustANGLE(Context *context, GLuint index, GLenum pname, GLsizei bufSize, GLsizei *length, void **pointer) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetVertexAttribBase(context, index, pname, length, true, false)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetVertexAttribIiv(Context *context, GLuint index, GLenum pname, GLint *params) { return ValidateGetVertexAttribBase(context, index, pname, nullptr, false, true); } bool ValidateGetVertexAttribIivRobustANGLE(Context *context, GLuint index, GLenum pname, GLsizei bufSize, GLsizei *length, GLint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetVertexAttribBase(context, index, pname, length, false, true)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetVertexAttribIuiv(Context *context, GLuint index, GLenum pname, GLuint *params) { return ValidateGetVertexAttribBase(context, index, pname, nullptr, false, true); } bool ValidateGetVertexAttribIuivRobustANGLE(Context *context, GLuint index, GLenum pname, GLsizei bufSize, GLsizei *length, GLuint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetVertexAttribBase(context, index, pname, length, false, true)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetActiveUniformBlockiv(Context *context, GLuint program, GLuint uniformBlockIndex, GLenum pname, GLint *params) { return ValidateGetActiveUniformBlockivBase(context, program, uniformBlockIndex, pname, nullptr); } bool ValidateGetActiveUniformBlockivRobustANGLE(Context *context, GLuint program, GLuint uniformBlockIndex, GLenum pname, GLsizei bufSize, GLsizei *length, GLint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetActiveUniformBlockivBase(context, program, uniformBlockIndex, pname, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } bool ValidateGetInternalFormativ(Context *context, GLenum target, GLenum internalformat, GLenum pname, GLsizei bufSize, GLint *params) { return ValidateGetInternalFormativBase(context, target, internalformat, pname, bufSize, nullptr); } bool ValidateGetInternalFormativRobustANGLE(Context *context, GLenum target, GLenum internalformat, GLenum pname, GLsizei bufSize, GLsizei *length, GLint *params) { if (!ValidateRobustEntryPoint(context, bufSize)) { return false; } if (!ValidateGetInternalFormativBase(context, target, internalformat, pname, bufSize, length)) { return false; } if (!ValidateRobustBufferSize(context, bufSize, *length)) { return false; } return true; } } // namespace gl