gecko/gfx/gl/GLContext.cpp
Ehsan Akhgari 6220f98ec6 Backed out 9 changesets (bug 943660, bug 936964) because of ASAN use-after-free crashes on browser-chrome and mochitest-other
Backed out changeset 85486c4aa3d8 (bug 936964)
Backed out changeset 25312eb71998 (bug 936964)
Backed out changeset 6dbb8333960c (bug 936964)
Backed out changeset da6465ad476f (bug 936964)
Backed out changeset a87ffc992f38 (bug 936964)
Backed out changeset 4ae3a61182db (bug 936964)
Backed out changeset 34e9c3137804 (bug 936964)
Backed out changeset fd1459e71585 (bug 936964)
Backed out changeset 3e8a701d8bdc (bug 943660)

Landed on a CLOSED TREE

--HG--
rename : content/canvas/src/WebGLMemoryTracker.h => content/canvas/src/WebGLMemoryReporterWrapper.h
2013-11-27 20:05:00 -05:00

3581 lines
126 KiB
C++

/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/* vim: set ts=8 sts=4 et sw=4 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include <algorithm>
#include <stdio.h>
#include <string.h>
#include <ctype.h>
#include "GLContext.h"
#include "gfxCrashReporterUtils.h"
#include "gfxPlatform.h"
#include "gfxUtils.h"
#include "GLContextProvider.h"
#include "GLTextureImage.h"
#include "nsPrintfCString.h"
#include "nsThreadUtils.h"
#include "prenv.h"
#include "prlink.h"
#include "SurfaceStream.h"
#include "GfxTexturesReporter.h"
#include "TextureGarbageBin.h"
#include "gfx2DGlue.h"
#include "mozilla/DebugOnly.h"
#include "mozilla/Preferences.h"
#ifdef XP_MACOSX
#include <CoreServices/CoreServices.h>
#include "gfxColor.h"
#endif
#if defined(MOZ_WIDGET_COCOA)
#include "nsCocoaFeatures.h"
#endif
using namespace mozilla::gfx;
namespace mozilla {
namespace gl {
#ifdef DEBUG
unsigned GLContext::sCurrentGLContextTLS = -1;
#endif
uint32_t GLContext::sDebugMode = 0;
#define MAX_SYMBOL_LENGTH 128
#define MAX_SYMBOL_NAMES 5
// should match the order of GLExtensions, and be null-terminated.
static const char *sExtensionNames[] = {
"GL_EXT_framebuffer_object",
"GL_ARB_framebuffer_object",
"GL_ARB_texture_rectangle",
"GL_EXT_bgra",
"GL_EXT_texture_format_BGRA8888",
"GL_OES_depth24",
"GL_OES_depth32",
"GL_OES_stencil8",
"GL_OES_texture_npot",
"GL_ARB_depth_texture",
"GL_OES_depth_texture",
"GL_OES_packed_depth_stencil",
"GL_IMG_read_format",
"GL_EXT_read_format_bgra",
"GL_APPLE_client_storage",
"GL_ARB_texture_non_power_of_two",
"GL_ARB_pixel_buffer_object",
"GL_ARB_ES2_compatibility",
"GL_ARB_ES3_compatibility",
"GL_OES_texture_float",
"GL_OES_texture_float_linear",
"GL_ARB_texture_float",
"GL_EXT_unpack_subimage",
"GL_OES_standard_derivatives",
"GL_EXT_texture_filter_anisotropic",
"GL_EXT_texture_compression_s3tc",
"GL_EXT_texture_compression_dxt1",
"GL_ANGLE_texture_compression_dxt3",
"GL_ANGLE_texture_compression_dxt5",
"GL_AMD_compressed_ATC_texture",
"GL_IMG_texture_compression_pvrtc",
"GL_EXT_framebuffer_blit",
"GL_ANGLE_framebuffer_blit",
"GL_EXT_framebuffer_multisample",
"GL_ANGLE_framebuffer_multisample",
"GL_OES_rgb8_rgba8",
"GL_ARB_robustness",
"GL_EXT_robustness",
"GL_ARB_sync",
"GL_OES_EGL_image",
"GL_OES_EGL_sync",
"GL_OES_EGL_image_external",
"GL_EXT_packed_depth_stencil",
"GL_OES_element_index_uint",
"GL_OES_vertex_array_object",
"GL_ARB_vertex_array_object",
"GL_APPLE_vertex_array_object",
"GL_ARB_draw_buffers",
"GL_EXT_draw_buffers",
"GL_EXT_gpu_shader4",
"GL_EXT_blend_minmax",
"GL_ARB_draw_instanced",
"GL_EXT_draw_instanced",
"GL_NV_draw_instanced",
"GL_ARB_instanced_arrays",
"GL_NV_instanced_arrays",
"GL_ANGLE_instanced_arrays",
"GL_EXT_occlusion_query_boolean",
"GL_ARB_occlusion_query2",
"GL_EXT_transform_feedback",
"GL_NV_transform_feedback",
"GL_ANGLE_depth_texture",
"GL_EXT_sRGB",
"GL_EXT_texture_sRGB",
"GL_ARB_framebuffer_sRGB",
"GL_EXT_framebuffer_sRGB",
"GL_KHR_debug",
nullptr
};
static bool
ParseGLVersion(GLContext* gl, unsigned int* version)
{
GLenum error = gl->fGetError();
if (error != LOCAL_GL_NO_ERROR) {
MOZ_ASSERT(false, "An OpenGL error has been triggered before.");
return false;
}
/**
* B2G emulator bug work around: The emulator implements OpenGL ES 2.0 on
* OpenGL 3.2. The bug is that GetIntegerv(LOCAL_GL_{MAJOR,MINOR}_VERSION)
* returns OpenGL 3.2 instead of generating an error.
*/
if (!gl->IsGLES())
{
/**
* OpenGL 3.1 and OpenGL ES 3.0 both introduce GL_{MAJOR,MINOR}_VERSION
* with GetIntegerv. So we first try those constants even though we
* might not have an OpenGL context supporting them, has this is a
* better way than parsing GL_VERSION.
*/
GLint majorVersion = 0;
GLint minorVersion = 0;
gl->fGetIntegerv(LOCAL_GL_MAJOR_VERSION, &majorVersion);
gl->fGetIntegerv(LOCAL_GL_MINOR_VERSION, &minorVersion);
// If it's not an OpenGL (ES) 3.0 context, we will have an error
error = gl->fGetError();
if (error == LOCAL_GL_NO_ERROR &&
majorVersion > 0 &&
minorVersion >= 0)
{
*version = majorVersion * 100 + minorVersion * 10;
return true;
}
}
/**
* We were not able to use GL_{MAJOR,MINOR}_VERSION, so we parse
* GL_VERSION.
*
*
* OpenGL 2.x, 3.x, 4.x specifications:
* The VERSION and SHADING_LANGUAGE_VERSION strings are laid out as follows:
*
* <version number><space><vendor-specific information>
*
* The version number is either of the form major_number.minor_number or
* major_number.minor_number.release_number, where the numbers all have
* one or more digits.
*
*
* OpenGL ES 2.0, 3.0 specifications:
* The VERSION string is laid out as follows:
*
* "OpenGL ES N.M vendor-specific information"
*
* The version number is either of the form major_number.minor_number or
* major_number.minor_number.release_number, where the numbers all have
* one or more digits.
*
*
* Note:
* We don't care about release_number.
*/
const char* versionString = (const char*)gl->fGetString(LOCAL_GL_VERSION);
error = gl->fGetError();
if (error != LOCAL_GL_NO_ERROR) {
MOZ_ASSERT(false, "glGetString(GL_VERSION) has generated an error");
return false;
} else if (!versionString) {
MOZ_ASSERT(false, "glGetString(GL_VERSION) has returned 0");
return false;
}
const char kGLESVersionPrefix[] = "OpenGL ES ";
if (strncmp(versionString, kGLESVersionPrefix, strlen(kGLESVersionPrefix)) == 0) {
versionString += strlen(kGLESVersionPrefix);
}
const char* itr = versionString;
char* end = nullptr;
int majorVersion = (int)strtol(itr, &end, 10);
if (!end) {
MOZ_ASSERT(false, "Failed to parse the GL major version number.");
return false;
} else if (*end != '.') {
MOZ_ASSERT(false, "Failed to parse GL's major-minor version number separator.");
return false;
}
// we skip the '.' between the major and the minor version
itr = end + 1;
end = nullptr;
int minorVersion = (int)strtol(itr, &end, 10);
if (!end) {
MOZ_ASSERT(false, "Failed to parse GL's minor version number.");
return false;
}
if (majorVersion <= 0 || majorVersion >= 100) {
MOZ_ASSERT(false, "Invalid major version.");
return false;
} else if (minorVersion < 0 || minorVersion >= 10) {
MOZ_ASSERT(false, "Invalid minor version.");
return false;
}
*version = (unsigned int)(majorVersion * 100 + minorVersion * 10);
return true;
}
GLContext::GLContext(const SurfaceCaps& caps,
GLContext* sharedContext,
bool isOffscreen)
: mInitialized(false),
mIsOffscreen(isOffscreen),
mIsGlobalSharedContext(false),
mContextLost(false),
mVersion(0),
mProfile(ContextProfile::Unknown),
mVendor(-1),
mRenderer(-1),
mHasRobustness(false),
#ifdef DEBUG
mGLError(LOCAL_GL_NO_ERROR),
#endif
mTexBlit_Buffer(0),
mTexBlit_VertShader(0),
mTex2DBlit_FragShader(0),
mTex2DRectBlit_FragShader(0),
mTex2DBlit_Program(0),
mTex2DRectBlit_Program(0),
mTexBlit_UseDrawNotCopy(false),
mSharedContext(sharedContext),
mFlipped(false),
mBlitProgram(0),
mBlitFramebuffer(0),
mCaps(caps),
mScreen(nullptr),
mLockedSurface(nullptr),
mMaxTextureSize(0),
mMaxCubeMapTextureSize(0),
mMaxTextureImageSize(0),
mMaxRenderbufferSize(0),
mNeedsTextureSizeChecks(false),
mWorkAroundDriverBugs(true)
{
mOwningThread = NS_GetCurrentThread();
mTexBlit_UseDrawNotCopy = Preferences::GetBool("gl.blit-draw-not-copy", false);
}
GLContext::~GLContext() {
NS_ASSERTION(IsDestroyed(), "GLContext implementation must call MarkDestroyed in destructor!");
#ifdef DEBUG
if (mSharedContext) {
GLContext *tip = mSharedContext;
while (tip->mSharedContext)
tip = tip->mSharedContext;
tip->SharedContextDestroyed(this);
tip->ReportOutstandingNames();
} else {
ReportOutstandingNames();
}
#endif
}
bool
GLContext::InitWithPrefix(const char *prefix, bool trygl)
{
ScopedGfxFeatureReporter reporter("GL Context");
if (mInitialized) {
reporter.SetSuccessful();
return true;
}
mWorkAroundDriverBugs = gfxPlatform::GetPlatform()->WorkAroundDriverBugs();
SymLoadStruct symbols[] = {
{ (PRFuncPtr*) &mSymbols.fActiveTexture, { "ActiveTexture", "ActiveTextureARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fAttachShader, { "AttachShader", "AttachShaderARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBindAttribLocation, { "BindAttribLocation", "BindAttribLocationARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBindBuffer, { "BindBuffer", "BindBufferARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBindTexture, { "BindTexture", "BindTextureARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBlendColor, { "BlendColor", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBlendEquation, { "BlendEquation", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBlendEquationSeparate, { "BlendEquationSeparate", "BlendEquationSeparateEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBlendFunc, { "BlendFunc", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBlendFuncSeparate, { "BlendFuncSeparate", "BlendFuncSeparateEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBufferData, { "BufferData", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBufferSubData, { "BufferSubData", nullptr } },
{ (PRFuncPtr*) &mSymbols.fClear, { "Clear", nullptr } },
{ (PRFuncPtr*) &mSymbols.fClearColor, { "ClearColor", nullptr } },
{ (PRFuncPtr*) &mSymbols.fClearStencil, { "ClearStencil", nullptr } },
{ (PRFuncPtr*) &mSymbols.fColorMask, { "ColorMask", nullptr } },
{ (PRFuncPtr*) &mSymbols.fCompressedTexImage2D, {"CompressedTexImage2D", nullptr} },
{ (PRFuncPtr*) &mSymbols.fCompressedTexSubImage2D, {"CompressedTexSubImage2D", nullptr} },
{ (PRFuncPtr*) &mSymbols.fCullFace, { "CullFace", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDetachShader, { "DetachShader", "DetachShaderARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDepthFunc, { "DepthFunc", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDepthMask, { "DepthMask", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDisable, { "Disable", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDisableVertexAttribArray, { "DisableVertexAttribArray", "DisableVertexAttribArrayARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDrawArrays, { "DrawArrays", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDrawElements, { "DrawElements", nullptr } },
{ (PRFuncPtr*) &mSymbols.fEnable, { "Enable", nullptr } },
{ (PRFuncPtr*) &mSymbols.fEnableVertexAttribArray, { "EnableVertexAttribArray", "EnableVertexAttribArrayARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fFinish, { "Finish", nullptr } },
{ (PRFuncPtr*) &mSymbols.fFlush, { "Flush", nullptr } },
{ (PRFuncPtr*) &mSymbols.fFrontFace, { "FrontFace", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetActiveAttrib, { "GetActiveAttrib", "GetActiveAttribARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetActiveUniform, { "GetActiveUniform", "GetActiveUniformARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetAttachedShaders, { "GetAttachedShaders", "GetAttachedShadersARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetAttribLocation, { "GetAttribLocation", "GetAttribLocationARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetIntegerv, { "GetIntegerv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetFloatv, { "GetFloatv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetBooleanv, { "GetBooleanv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetBufferParameteriv, { "GetBufferParameteriv", "GetBufferParameterivARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetError, { "GetError", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetProgramiv, { "GetProgramiv", "GetProgramivARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetProgramInfoLog, { "GetProgramInfoLog", "GetProgramInfoLogARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fTexParameteri, { "TexParameteri", nullptr } },
{ (PRFuncPtr*) &mSymbols.fTexParameteriv, { "TexParameteriv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fTexParameterf, { "TexParameterf", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetString, { "GetString", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetTexParameterfv, { "GetTexParameterfv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetTexParameteriv, { "GetTexParameteriv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetUniformfv, { "GetUniformfv", "GetUniformfvARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetUniformiv, { "GetUniformiv", "GetUniformivARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetUniformLocation, { "GetUniformLocation", "GetUniformLocationARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetVertexAttribfv, { "GetVertexAttribfv", "GetVertexAttribfvARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetVertexAttribiv, { "GetVertexAttribiv", "GetVertexAttribivARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetVertexAttribPointerv, { "GetVertexAttribPointerv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fHint, { "Hint", nullptr } },
{ (PRFuncPtr*) &mSymbols.fIsBuffer, { "IsBuffer", "IsBufferARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fIsEnabled, { "IsEnabled", nullptr } },
{ (PRFuncPtr*) &mSymbols.fIsProgram, { "IsProgram", "IsProgramARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fIsShader, { "IsShader", "IsShaderARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fIsTexture, { "IsTexture", "IsTextureARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fLineWidth, { "LineWidth", nullptr } },
{ (PRFuncPtr*) &mSymbols.fLinkProgram, { "LinkProgram", "LinkProgramARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fPixelStorei, { "PixelStorei", nullptr } },
{ (PRFuncPtr*) &mSymbols.fPolygonOffset, { "PolygonOffset", nullptr } },
{ (PRFuncPtr*) &mSymbols.fReadPixels, { "ReadPixels", nullptr } },
{ (PRFuncPtr*) &mSymbols.fSampleCoverage, { "SampleCoverage", nullptr } },
{ (PRFuncPtr*) &mSymbols.fScissor, { "Scissor", nullptr } },
{ (PRFuncPtr*) &mSymbols.fStencilFunc, { "StencilFunc", nullptr } },
{ (PRFuncPtr*) &mSymbols.fStencilFuncSeparate, { "StencilFuncSeparate", "StencilFuncSeparateEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fStencilMask, { "StencilMask", nullptr } },
{ (PRFuncPtr*) &mSymbols.fStencilMaskSeparate, { "StencilMaskSeparate", "StencilMaskSeparateEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fStencilOp, { "StencilOp", nullptr } },
{ (PRFuncPtr*) &mSymbols.fStencilOpSeparate, { "StencilOpSeparate", "StencilOpSeparateEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fTexImage2D, { "TexImage2D", nullptr } },
{ (PRFuncPtr*) &mSymbols.fTexSubImage2D, { "TexSubImage2D", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform1f, { "Uniform1f", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform1fv, { "Uniform1fv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform1i, { "Uniform1i", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform1iv, { "Uniform1iv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform2f, { "Uniform2f", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform2fv, { "Uniform2fv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform2i, { "Uniform2i", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform2iv, { "Uniform2iv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform3f, { "Uniform3f", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform3fv, { "Uniform3fv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform3i, { "Uniform3i", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform3iv, { "Uniform3iv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform4f, { "Uniform4f", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform4fv, { "Uniform4fv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform4i, { "Uniform4i", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniform4iv, { "Uniform4iv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniformMatrix2fv, { "UniformMatrix2fv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniformMatrix3fv, { "UniformMatrix3fv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUniformMatrix4fv, { "UniformMatrix4fv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUseProgram, { "UseProgram", nullptr } },
{ (PRFuncPtr*) &mSymbols.fValidateProgram, { "ValidateProgram", nullptr } },
{ (PRFuncPtr*) &mSymbols.fVertexAttribPointer, { "VertexAttribPointer", nullptr } },
{ (PRFuncPtr*) &mSymbols.fVertexAttrib1f, { "VertexAttrib1f", nullptr } },
{ (PRFuncPtr*) &mSymbols.fVertexAttrib2f, { "VertexAttrib2f", nullptr } },
{ (PRFuncPtr*) &mSymbols.fVertexAttrib3f, { "VertexAttrib3f", nullptr } },
{ (PRFuncPtr*) &mSymbols.fVertexAttrib4f, { "VertexAttrib4f", nullptr } },
{ (PRFuncPtr*) &mSymbols.fVertexAttrib1fv, { "VertexAttrib1fv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fVertexAttrib2fv, { "VertexAttrib2fv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fVertexAttrib3fv, { "VertexAttrib3fv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fVertexAttrib4fv, { "VertexAttrib4fv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fViewport, { "Viewport", nullptr } },
{ (PRFuncPtr*) &mSymbols.fCompileShader, { "CompileShader", nullptr } },
{ (PRFuncPtr*) &mSymbols.fCopyTexImage2D, { "CopyTexImage2D", nullptr } },
{ (PRFuncPtr*) &mSymbols.fCopyTexSubImage2D, { "CopyTexSubImage2D", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetShaderiv, { "GetShaderiv", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetShaderInfoLog, { "GetShaderInfoLog", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetShaderSource, { "GetShaderSource", nullptr } },
{ (PRFuncPtr*) &mSymbols.fShaderSource, { "ShaderSource", nullptr } },
{ (PRFuncPtr*) &mSymbols.fVertexAttribPointer, { "VertexAttribPointer", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBindFramebuffer, { "BindFramebuffer", "BindFramebufferEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBindRenderbuffer, { "BindRenderbuffer", "BindRenderbufferEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fCheckFramebufferStatus, { "CheckFramebufferStatus", "CheckFramebufferStatusEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fFramebufferRenderbuffer, { "FramebufferRenderbuffer", "FramebufferRenderbufferEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fFramebufferTexture2D, { "FramebufferTexture2D", "FramebufferTexture2DEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGenerateMipmap, { "GenerateMipmap", "GenerateMipmapEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetFramebufferAttachmentParameteriv, { "GetFramebufferAttachmentParameteriv", "GetFramebufferAttachmentParameterivEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetRenderbufferParameteriv, { "GetRenderbufferParameteriv", "GetRenderbufferParameterivEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fIsFramebuffer, { "IsFramebuffer", "IsFramebufferEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fIsRenderbuffer, { "IsRenderbuffer", "IsRenderbufferEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fRenderbufferStorage, { "RenderbufferStorage", "RenderbufferStorageEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGenBuffers, { "GenBuffers", "GenBuffersARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGenTextures, { "GenTextures", nullptr } },
{ (PRFuncPtr*) &mSymbols.fCreateProgram, { "CreateProgram", "CreateProgramARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fCreateShader, { "CreateShader", "CreateShaderARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGenFramebuffers, { "GenFramebuffers", "GenFramebuffersEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGenRenderbuffers, { "GenRenderbuffers", "GenRenderbuffersEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDeleteBuffers, { "DeleteBuffers", "DeleteBuffersARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDeleteTextures, { "DeleteTextures", "DeleteTexturesARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDeleteProgram, { "DeleteProgram", "DeleteProgramARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDeleteShader, { "DeleteShader", "DeleteShaderARB", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDeleteFramebuffers, { "DeleteFramebuffers", "DeleteFramebuffersEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDeleteRenderbuffers, { "DeleteRenderbuffers", "DeleteRenderbuffersEXT", nullptr } },
{ nullptr, { nullptr } },
};
mInitialized = LoadSymbols(&symbols[0], trygl, prefix);
if (mInitialized) {
unsigned int version = 0;
bool parseSuccess = ParseGLVersion(this, &version);
if (version >= mVersion) {
mVersion = version;
} else if (parseSuccess) {
NS_WARNING("Parsed version less than expected.");
mInitialized = false;
}
}
// Load OpenGL ES 2.0 symbols, or desktop if we aren't using ES 2.
if (mInitialized) {
if (IsGLES2()) {
SymLoadStruct symbols_ES2[] = {
{ (PRFuncPtr*) &mSymbols.fGetShaderPrecisionFormat, { "GetShaderPrecisionFormat", nullptr } },
{ (PRFuncPtr*) &mSymbols.fClearDepthf, { "ClearDepthf", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDepthRangef, { "DepthRangef", nullptr } },
{ nullptr, { nullptr } },
};
if (!LoadSymbols(&symbols_ES2[0], trygl, prefix)) {
NS_ERROR("OpenGL ES 2.0 supported, but symbols could not be loaded.");
mInitialized = false;
}
} else {
SymLoadStruct symbols_desktop[] = {
{ (PRFuncPtr*) &mSymbols.fClearDepth, { "ClearDepth", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDepthRange, { "DepthRange", nullptr } },
{ (PRFuncPtr*) &mSymbols.fReadBuffer, { "ReadBuffer", nullptr } },
{ (PRFuncPtr*) &mSymbols.fMapBuffer, { "MapBuffer", nullptr } },
{ (PRFuncPtr*) &mSymbols.fUnmapBuffer, { "UnmapBuffer", nullptr } },
{ (PRFuncPtr*) &mSymbols.fPointParameterf, { "PointParameterf", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDrawBuffer, { "DrawBuffer", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDrawBuffers, { "DrawBuffers", nullptr } },
{ nullptr, { nullptr } },
};
if (!LoadSymbols(&symbols_desktop[0], trygl, prefix)) {
NS_ERROR("Desktop symbols failed to load.");
mInitialized = false;
}
}
}
const char *glVendorString = nullptr;
const char *glRendererString = nullptr;
if (mInitialized) {
// The order of these strings must match up with the order of the enum
// defined in GLContext.h for vendor IDs
glVendorString = (const char *)fGetString(LOCAL_GL_VENDOR);
if (!glVendorString)
mInitialized = false;
const char *vendorMatchStrings[VendorOther] = {
"Intel",
"NVIDIA",
"ATI",
"Qualcomm",
"Imagination",
"nouveau"
};
mVendor = VendorOther;
for (int i = 0; i < VendorOther; ++i) {
if (DoesStringMatch(glVendorString, vendorMatchStrings[i])) {
mVendor = i;
break;
}
}
// The order of these strings must match up with the order of the enum
// defined in GLContext.h for renderer IDs
glRendererString = (const char *)fGetString(LOCAL_GL_RENDERER);
if (!glRendererString)
mInitialized = false;
const char *rendererMatchStrings[RendererOther] = {
"Adreno 200",
"Adreno 205",
"Adreno (TM) 205",
"Adreno (TM) 320",
"PowerVR SGX 530",
"PowerVR SGX 540",
"NVIDIA Tegra",
"Android Emulator"
};
mRenderer = RendererOther;
for (int i = 0; i < RendererOther; ++i) {
if (DoesStringMatch(glRendererString, rendererMatchStrings[i])) {
mRenderer = i;
break;
}
}
}
#ifdef DEBUG
if (PR_GetEnv("MOZ_GL_DEBUG"))
sDebugMode |= DebugEnabled;
// enables extra verbose output, informing of the start and finish of every GL call.
// useful e.g. to record information to investigate graphics system crashes/lockups
if (PR_GetEnv("MOZ_GL_DEBUG_VERBOSE"))
sDebugMode |= DebugTrace;
// aborts on GL error. Can be useful to debug quicker code that is known not to generate any GL error in principle.
if (PR_GetEnv("MOZ_GL_DEBUG_ABORT_ON_ERROR"))
sDebugMode |= DebugAbortOnError;
#endif
if (mInitialized) {
#ifdef DEBUG
static bool firstRun = true;
if (firstRun && DebugMode()) {
const char *vendors[VendorOther] = {
"Intel",
"NVIDIA",
"ATI",
"Qualcomm"
};
MOZ_ASSERT(glVendorString);
if (mVendor < VendorOther) {
printf_stderr("OpenGL vendor ('%s') recognized as: %s\n",
glVendorString, vendors[mVendor]);
} else {
printf_stderr("OpenGL vendor ('%s') unrecognized\n", glVendorString);
}
}
firstRun = false;
#endif
InitExtensions();
InitFeatures();
// Disable extensions with partial or incorrect support.
if (WorkAroundDriverBugs()) {
if (Renderer() == RendererAdrenoTM320) {
MarkUnsupported(GLFeature::standard_derivatives);
}
#ifdef XP_MACOSX
// The Mac Nvidia driver, for versions up to and including 10.8, don't seem
// to properly support this. See 814839
// this has been fixed in Mac OS X 10.9. See 907946
if (Vendor() == gl::GLContext::VendorNVIDIA &&
!nsCocoaFeatures::OnMavericksOrLater())
{
MarkUnsupported(GLFeature::depth_texture);
}
#endif
// ANGLE's divisor support is busted. (see bug 916816)
if (IsANGLE()) {
MarkUnsupported(GLFeature::instanced_arrays);
}
}
NS_ASSERTION(!IsExtensionSupported(GLContext::ARB_pixel_buffer_object) ||
(mSymbols.fMapBuffer && mSymbols.fUnmapBuffer),
"ARB_pixel_buffer_object supported without glMapBuffer/UnmapBuffer being available!");
if (SupportsRobustness()) {
mHasRobustness = false;
if (IsExtensionSupported(ARB_robustness)) {
SymLoadStruct robustnessSymbols[] = {
{ (PRFuncPtr*) &mSymbols.fGetGraphicsResetStatus, { "GetGraphicsResetStatusARB", nullptr } },
{ nullptr, { nullptr } },
};
if (!LoadSymbols(&robustnessSymbols[0], trygl, prefix)) {
NS_ERROR("GL supports ARB_robustness without supplying GetGraphicsResetStatusARB.");
mSymbols.fGetGraphicsResetStatus = nullptr;
} else {
mHasRobustness = true;
}
}
if (!IsExtensionSupported(ARB_robustness) &&
IsExtensionSupported(EXT_robustness)) {
SymLoadStruct robustnessSymbols[] = {
{ (PRFuncPtr*) &mSymbols.fGetGraphicsResetStatus, { "GetGraphicsResetStatusEXT", nullptr } },
{ nullptr, { nullptr } },
};
if (!LoadSymbols(&robustnessSymbols[0], trygl, prefix)) {
NS_ERROR("GL supports EXT_robustness without supplying GetGraphicsResetStatusEXT.");
mSymbols.fGetGraphicsResetStatus = nullptr;
} else {
mHasRobustness = true;
}
}
if (!mHasRobustness) {
MarkUnsupported(GLFeature::robustness);
}
}
// Check for aux symbols based on extensions
if (IsSupported(GLFeature::framebuffer_blit))
{
SymLoadStruct auxSymbols[] = {
{
(PRFuncPtr*) &mSymbols.fBlitFramebuffer,
{
"BlitFramebuffer",
"BlitFramebufferEXT",
"BlitFramebufferANGLE",
nullptr
}
},
{ nullptr, { nullptr } },
};
if (!LoadSymbols(&auxSymbols[0], trygl, prefix)) {
NS_ERROR("GL supports framebuffer_blit without supplying glBlitFramebuffer");
MarkUnsupported(GLFeature::framebuffer_blit);
mSymbols.fBlitFramebuffer = nullptr;
}
}
if (IsSupported(GLFeature::framebuffer_multisample))
{
SymLoadStruct auxSymbols[] = {
{
(PRFuncPtr*) &mSymbols.fRenderbufferStorageMultisample,
{
"RenderbufferStorageMultisample",
"RenderbufferStorageMultisampleEXT",
"RenderbufferStorageMultisampleANGLE",
nullptr
}
},
{ nullptr, { nullptr } },
};
if (!LoadSymbols(&auxSymbols[0], trygl, prefix)) {
NS_ERROR("GL supports framebuffer_multisample without supplying glRenderbufferStorageMultisample");
MarkUnsupported(GLFeature::framebuffer_multisample);
mSymbols.fRenderbufferStorageMultisample = nullptr;
}
}
if (IsExtensionSupported(ARB_sync)) {
SymLoadStruct syncSymbols[] = {
{ (PRFuncPtr*) &mSymbols.fFenceSync, { "FenceSync", nullptr } },
{ (PRFuncPtr*) &mSymbols.fIsSync, { "IsSync", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDeleteSync, { "DeleteSync", nullptr } },
{ (PRFuncPtr*) &mSymbols.fClientWaitSync, { "ClientWaitSync", nullptr } },
{ (PRFuncPtr*) &mSymbols.fWaitSync, { "WaitSync", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetInteger64v, { "GetInteger64v", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetSynciv, { "GetSynciv", nullptr } },
{ nullptr, { nullptr } },
};
if (!LoadSymbols(&syncSymbols[0], trygl, prefix)) {
NS_ERROR("GL supports ARB_sync without supplying its functions.");
MarkExtensionUnsupported(ARB_sync);
mSymbols.fFenceSync = nullptr;
mSymbols.fIsSync = nullptr;
mSymbols.fDeleteSync = nullptr;
mSymbols.fClientWaitSync = nullptr;
mSymbols.fWaitSync = nullptr;
mSymbols.fGetInteger64v = nullptr;
mSymbols.fGetSynciv = nullptr;
}
}
if (IsExtensionSupported(OES_EGL_image)) {
SymLoadStruct imageSymbols[] = {
{ (PRFuncPtr*) &mSymbols.fEGLImageTargetTexture2D, { "EGLImageTargetTexture2DOES", nullptr } },
{ (PRFuncPtr*) &mSymbols.fEGLImageTargetRenderbufferStorage, { "EGLImageTargetRenderbufferStorageOES", nullptr } },
{ nullptr, { nullptr } },
};
if (!LoadSymbols(&imageSymbols[0], trygl, prefix)) {
NS_ERROR("GL supports OES_EGL_image without supplying its functions.");
MarkExtensionUnsupported(OES_EGL_image);
mSymbols.fEGLImageTargetTexture2D = nullptr;
mSymbols.fEGLImageTargetRenderbufferStorage = nullptr;
}
}
if (IsExtensionSupported(ARB_vertex_array_object) ||
IsExtensionSupported(OES_vertex_array_object)) {
SymLoadStruct vaoSymbols[] = {
{ (PRFuncPtr*) &mSymbols.fIsVertexArray, { "IsVertexArray", "IsVertexArrayOES", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGenVertexArrays, { "GenVertexArrays", "GenVertexArraysOES", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBindVertexArray, { "BindVertexArray", "BindVertexArrayOES", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDeleteVertexArrays, { "DeleteVertexArrays", "DeleteVertexArraysOES", nullptr } },
{ nullptr, { nullptr } },
};
if (!LoadSymbols(&vaoSymbols[0], trygl, prefix)) {
NS_ERROR("GL supports Vertex Array Object without supplying its functions.");
MarkUnsupported(GLFeature::vertex_array_object);
mSymbols.fIsVertexArray = nullptr;
mSymbols.fGenVertexArrays = nullptr;
mSymbols.fBindVertexArray = nullptr;
mSymbols.fDeleteVertexArrays = nullptr;
}
}
else if (IsExtensionSupported(APPLE_vertex_array_object)) {
/*
* separate call to LoadSymbols with APPLE_vertex_array_object to work around
* a driver bug : the IsVertexArray symbol (without suffix) can be present but unusable.
*/
SymLoadStruct vaoSymbols[] = {
{ (PRFuncPtr*) &mSymbols.fIsVertexArray, { "IsVertexArrayAPPLE", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGenVertexArrays, { "GenVertexArraysAPPLE", nullptr } },
{ (PRFuncPtr*) &mSymbols.fBindVertexArray, { "BindVertexArrayAPPLE", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDeleteVertexArrays, { "DeleteVertexArraysAPPLE", nullptr } },
{ nullptr, { nullptr } },
};
if (!LoadSymbols(&vaoSymbols[0], trygl, prefix)) {
NS_ERROR("GL supports Vertex Array Object without supplying its functions.");
MarkUnsupported(GLFeature::vertex_array_object);
mSymbols.fIsVertexArray = nullptr;
mSymbols.fGenVertexArrays = nullptr;
mSymbols.fBindVertexArray = nullptr;
mSymbols.fDeleteVertexArrays = nullptr;
}
}
if (IsSupported(GLFeature::draw_instanced)) {
SymLoadStruct drawInstancedSymbols[] = {
{ (PRFuncPtr*) &mSymbols.fDrawArraysInstanced,
{ "DrawArraysInstanced",
"DrawArraysInstancedARB",
"DrawArraysInstancedEXT",
"DrawArraysInstancedNV",
"DrawArraysInstancedANGLE",
nullptr
}
},
{ (PRFuncPtr*) &mSymbols.fDrawElementsInstanced,
{ "DrawElementsInstanced",
"DrawElementsInstancedARB",
"DrawElementsInstancedEXT",
"DrawElementsInstancedNV",
"DrawElementsInstancedANGLE",
nullptr
}
},
{ nullptr, { nullptr } },
};
if (!LoadSymbols(drawInstancedSymbols, trygl, prefix)) {
NS_ERROR("GL supports instanced draws without supplying its functions.");
MarkUnsupported(GLFeature::draw_instanced);
mSymbols.fDrawArraysInstanced = nullptr;
mSymbols.fDrawElementsInstanced = nullptr;
}
}
if (IsSupported(GLFeature::instanced_arrays)) {
SymLoadStruct instancedArraySymbols[] = {
{ (PRFuncPtr*) &mSymbols.fVertexAttribDivisor,
{ "VertexAttribDivisor",
"VertexAttribDivisorARB",
"VertexAttribDivisorNV",
"VertexAttribDivisorANGLE",
nullptr
}
},
{ nullptr, { nullptr } },
};
if (!LoadSymbols(instancedArraySymbols, trygl, prefix)) {
NS_ERROR("GL supports array instanced without supplying it function.");
MarkUnsupported(GLFeature::instanced_arrays);
mSymbols.fVertexAttribDivisor = nullptr;
}
}
if (IsSupported(GLFeature::transform_feedback)) {
SymLoadStruct transformFeedbackSymbols[] = {
{ (PRFuncPtr*) &mSymbols.fBindBufferBase,
{ "BindBufferBase",
"BindBufferBaseEXT",
"BindBufferBaseNV",
nullptr
}
},
{ (PRFuncPtr*) &mSymbols.fBindBufferRange,
{ "BindBufferRange",
"BindBufferRangeEXT",
"BindBufferRangeNV",
nullptr
}
},
{ (PRFuncPtr*) &mSymbols.fBeginTransformFeedback,
{ "BeginTransformFeedback",
"BeginTransformFeedbackEXT",
"BeginTransformFeedbackNV",
nullptr
}
},
{ (PRFuncPtr*) &mSymbols.fEndTransformFeedback,
{ "EndTransformFeedback",
"EndTransformFeedbackEXT",
"EndTransformFeedbackNV",
nullptr
}
},
{ (PRFuncPtr*) &mSymbols.fTransformFeedbackVaryings,
{ "TransformFeedbackVaryings",
"TransformFeedbackVaryingsEXT",
"TransformFeedbackVaryingsNV",
nullptr
}
},
{ (PRFuncPtr*) &mSymbols.fGetTransformFeedbackVarying,
{ "GetTransformFeedbackVarying",
"GetTransformFeedbackVaryingEXT",
"GetTransformFeedbackVaryingNV",
nullptr
}
},
{ (PRFuncPtr*) &mSymbols.fGetIntegeri_v,
{ "GetIntegeri_v",
"GetIntegerIndexedvEXT",
"GetIntegerIndexedvNV",
nullptr
}
},
{ nullptr, { nullptr } },
};
if (!LoadSymbols(transformFeedbackSymbols, trygl, prefix)) {
NS_ERROR("GL supports transform feedback without supplying its functions.");
MarkUnsupported(GLFeature::transform_feedback);
MarkUnsupported(GLFeature::bind_buffer_offset);
mSymbols.fBindBufferBase = nullptr;
mSymbols.fBindBufferRange = nullptr;
mSymbols.fBeginTransformFeedback = nullptr;
mSymbols.fEndTransformFeedback = nullptr;
mSymbols.fTransformFeedbackVaryings = nullptr;
mSymbols.fGetTransformFeedbackVarying = nullptr;
mSymbols.fGetIntegeri_v = nullptr;
}
}
if (IsSupported(GLFeature::bind_buffer_offset)) {
SymLoadStruct bindBufferOffsetSymbols[] = {
{ (PRFuncPtr*) &mSymbols.fBindBufferOffset,
{ "BindBufferOffset",
"BindBufferOffsetEXT",
"BindBufferOffsetNV",
nullptr
}
},
{ nullptr, { nullptr } },
};
if (!LoadSymbols(bindBufferOffsetSymbols, trygl, prefix)) {
NS_ERROR("GL supports BindBufferOffset without supplying its function.");
MarkUnsupported(GLFeature::bind_buffer_offset);
mSymbols.fBindBufferOffset = nullptr;
}
}
if (IsSupported(GLFeature::query_objects)) {
SymLoadStruct queryObjectsSymbols[] = {
{ (PRFuncPtr*) &mSymbols.fBeginQuery, { "BeginQuery", "BeginQueryEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGenQueries, { "GenQueries", "GenQueriesEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDeleteQueries, { "DeleteQueries", "DeleteQueriesEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fEndQuery, { "EndQuery", "EndQueryEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetQueryiv, { "GetQueryiv", "GetQueryivEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetQueryObjectuiv, { "GetQueryObjectuiv", "GetQueryObjectuivEXT", nullptr } },
{ (PRFuncPtr*) &mSymbols.fIsQuery, { "IsQuery", "IsQueryEXT", nullptr } },
{ nullptr, { nullptr } },
};
if (!LoadSymbols(queryObjectsSymbols, trygl, prefix)) {
NS_ERROR("GL supports query objects without supplying its functions.");
MarkUnsupported(GLFeature::query_objects);
MarkUnsupported(GLFeature::get_query_object_iv);
MarkUnsupported(GLFeature::occlusion_query);
MarkUnsupported(GLFeature::occlusion_query_boolean);
MarkUnsupported(GLFeature::occlusion_query2);
mSymbols.fBeginQuery = nullptr;
mSymbols.fGenQueries = nullptr;
mSymbols.fDeleteQueries = nullptr;
mSymbols.fEndQuery = nullptr;
mSymbols.fGetQueryiv = nullptr;
mSymbols.fGetQueryObjectuiv = nullptr;
mSymbols.fIsQuery = nullptr;
}
}
if (IsSupported(GLFeature::get_query_object_iv)) {
SymLoadStruct queryObjectsSymbols[] = {
{ (PRFuncPtr*) &mSymbols.fGetQueryObjectiv, { "GetQueryObjectiv", "GetQueryObjectivEXT", nullptr } },
{ nullptr, { nullptr } },
};
if (!LoadSymbols(queryObjectsSymbols, trygl, prefix)) {
NS_ERROR("GL supports query objects iv getter without supplying its function.");
MarkUnsupported(GLFeature::get_query_object_iv);
mSymbols.fGetQueryObjectiv = nullptr;
}
}
if (IsExtensionSupported(KHR_debug)) {
SymLoadStruct extSymbols[] = {
{ (PRFuncPtr*) &mSymbols.fDebugMessageControl, { "DebugMessageControl", "DebugMessageControlKHR", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDebugMessageInsert, { "DebugMessageInsert", "DebugMessageInsertKHR", nullptr } },
{ (PRFuncPtr*) &mSymbols.fDebugMessageCallback, { "DebugMessageCallback", "DebugMessageCallbackKHR", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetDebugMessageLog, { "GetDebugMessageLog", "GetDebugMessageLogKHR", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetPointerv, { "GetPointerv", "GetPointervKHR", nullptr } },
{ (PRFuncPtr*) &mSymbols.fPushDebugGroup, { "PushDebugGroup", "PushDebugGroupKHR", nullptr } },
{ (PRFuncPtr*) &mSymbols.fPopDebugGroup, { "PopDebugGroup", "PopDebugGroupKHR", nullptr } },
{ (PRFuncPtr*) &mSymbols.fObjectLabel, { "ObjectLabel", "ObjectLabelKHR", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetObjectLabel, { "GetObjectLabel", "GetObjectLabelKHR", nullptr } },
{ (PRFuncPtr*) &mSymbols.fObjectPtrLabel, { "ObjectPtrLabel", "ObjectPtrLabelKHR", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetObjectPtrLabel, { "GetObjectPtrLabel", "GetObjectPtrLabelKHR", nullptr } },
{ nullptr, { nullptr } },
};
if (!LoadSymbols(&extSymbols[0], trygl, prefix)) {
NS_ERROR("GL supports KHR_debug without supplying its functions.");
MarkExtensionUnsupported(KHR_debug);
mSymbols.fDebugMessageControl = nullptr;
mSymbols.fDebugMessageInsert = nullptr;
mSymbols.fDebugMessageCallback = nullptr;
mSymbols.fGetDebugMessageLog = nullptr;
mSymbols.fGetPointerv = nullptr;
mSymbols.fPushDebugGroup = nullptr;
mSymbols.fPopDebugGroup = nullptr;
mSymbols.fObjectLabel = nullptr;
mSymbols.fGetObjectLabel = nullptr;
mSymbols.fObjectPtrLabel = nullptr;
mSymbols.fGetObjectPtrLabel = nullptr;
}
}
// Load developer symbols, don't fail if we can't find them.
SymLoadStruct auxSymbols[] = {
{ (PRFuncPtr*) &mSymbols.fGetTexImage, { "GetTexImage", nullptr } },
{ (PRFuncPtr*) &mSymbols.fGetTexLevelParameteriv, { "GetTexLevelParameteriv", nullptr } },
{ nullptr, { nullptr } },
};
bool warnOnFailures = DebugMode();
LoadSymbols(&auxSymbols[0], trygl, prefix, warnOnFailures);
}
if (mInitialized) {
GLint v[4];
fGetIntegerv(LOCAL_GL_SCISSOR_BOX, v);
mScissorStack.AppendElement(nsIntRect(v[0], v[1], v[2], v[3]));
fGetIntegerv(LOCAL_GL_VIEWPORT, v);
mViewportStack.AppendElement(nsIntRect(v[0], v[1], v[2], v[3]));
raw_fGetIntegerv(LOCAL_GL_MAX_TEXTURE_SIZE, &mMaxTextureSize);
raw_fGetIntegerv(LOCAL_GL_MAX_CUBE_MAP_TEXTURE_SIZE, &mMaxCubeMapTextureSize);
raw_fGetIntegerv(LOCAL_GL_MAX_RENDERBUFFER_SIZE, &mMaxRenderbufferSize);
#ifdef XP_MACOSX
if (mWorkAroundDriverBugs) {
if (mVendor == VendorIntel) {
// see bug 737182 for 2D textures, bug 684882 for cube map textures.
mMaxTextureSize = std::min(mMaxTextureSize, 4096);
mMaxCubeMapTextureSize = std::min(mMaxCubeMapTextureSize, 512);
// for good measure, we align renderbuffers on what we do for 2D textures
mMaxRenderbufferSize = std::min(mMaxRenderbufferSize, 4096);
mNeedsTextureSizeChecks = true;
} else if (mVendor == VendorNVIDIA) {
SInt32 major, minor;
OSErr err1 = ::Gestalt(gestaltSystemVersionMajor, &major);
OSErr err2 = ::Gestalt(gestaltSystemVersionMinor, &minor);
if (err1 != noErr || err2 != noErr ||
major < 10 || (major == 10 && minor < 8)) {
// See bug 877949.
mMaxTextureSize = std::min(mMaxTextureSize, 4096);
mMaxRenderbufferSize = std::min(mMaxRenderbufferSize, 4096);
}
else {
// See bug 879656. 8192 fails, 8191 works.
mMaxTextureSize = std::min(mMaxTextureSize, 8191);
mMaxRenderbufferSize = std::min(mMaxRenderbufferSize, 8191);
}
// Part of the bug 879656, but it also doesn't hurt the 877949
mNeedsTextureSizeChecks = true;
}
}
#endif
#ifdef MOZ_X11
if (mWorkAroundDriverBugs &&
mVendor == VendorNouveau) {
// see bug 814716. Clamp MaxCubeMapTextureSize at 2K for Nouveau.
mMaxCubeMapTextureSize = std::min(mMaxCubeMapTextureSize, 2048);
mNeedsTextureSizeChecks = true;
}
#endif
mMaxTextureImageSize = mMaxTextureSize;
mMaxSamples = 0;
if (IsSupported(GLFeature::framebuffer_multisample)) {
fGetIntegerv(LOCAL_GL_MAX_SAMPLES, (GLint*)&mMaxSamples);
}
// We're ready for final setup.
fBindFramebuffer(LOCAL_GL_FRAMEBUFFER, 0);
if (mCaps.any)
DetermineCaps();
UpdatePixelFormat();
UpdateGLFormats(mCaps);
mTexGarbageBin = new TextureGarbageBin(this);
MOZ_ASSERT(IsCurrent());
}
if (mInitialized)
reporter.SetSuccessful();
else {
// if initialization fails, ensure all symbols are zero, to avoid hard-to-understand bugs
mSymbols.Zero();
NS_WARNING("InitWithPrefix failed!");
}
mVersionString = nsPrintfCString("%u.%u.%u", mVersion / 100, (mVersion / 10) % 10, mVersion % 10);
return mInitialized;
}
void
GLContext::InitExtensions()
{
MakeCurrent();
const char* extensions = (const char*)fGetString(LOCAL_GL_EXTENSIONS);
if (!extensions)
return;
#ifdef DEBUG
static bool firstRun = true;
#else
// Non-DEBUG, so never spew.
const bool firstRun = false;
#endif
InitializeExtensionsBitSet(mAvailableExtensions, extensions, sExtensionNames, firstRun && DebugMode());
if (WorkAroundDriverBugs() &&
Vendor() == VendorQualcomm) {
// Some Adreno drivers do not report GL_OES_EGL_sync, but they really do support it.
MarkExtensionSupported(OES_EGL_sync);
}
if (WorkAroundDriverBugs() &&
Renderer() == RendererAndroidEmulator) {
// the Android emulator, which we use to run B2G reftests on,
// doesn't expose the OES_rgb8_rgba8 extension, but it seems to
// support it (tautologically, as it only runs on desktop GL).
MarkExtensionSupported(OES_rgb8_rgba8);
}
#ifdef DEBUG
firstRun = false;
#endif
}
// Take texture data in a given buffer and copy it into a larger buffer,
// padding out the edge pixels for filtering if necessary
static void
CopyAndPadTextureData(const GLvoid* srcBuffer,
GLvoid* dstBuffer,
GLsizei srcWidth, GLsizei srcHeight,
GLsizei dstWidth, GLsizei dstHeight,
GLsizei stride, GLint pixelsize)
{
unsigned char *rowDest = static_cast<unsigned char*>(dstBuffer);
const unsigned char *source = static_cast<const unsigned char*>(srcBuffer);
for (GLsizei h = 0; h < srcHeight; ++h) {
memcpy(rowDest, source, srcWidth * pixelsize);
rowDest += dstWidth * pixelsize;
source += stride;
}
GLsizei padHeight = srcHeight;
// Pad out an extra row of pixels so that edge filtering doesn't use garbage data
if (dstHeight > srcHeight) {
memcpy(rowDest, source - stride, srcWidth * pixelsize);
padHeight++;
}
// Pad out an extra column of pixels
if (dstWidth > srcWidth) {
rowDest = static_cast<unsigned char*>(dstBuffer) + srcWidth * pixelsize;
for (GLsizei h = 0; h < padHeight; ++h) {
memcpy(rowDest, rowDest - pixelsize, pixelsize);
rowDest += dstWidth * pixelsize;
}
}
}
// In both of these cases (for the Adreno at least) it is impossible
// to determine good or bad driver versions for POT texture uploads,
// so blacklist them all. Newer drivers use a different rendering
// string in the form "Adreno (TM) 200" and the drivers we've seen so
// far work fine with NPOT textures, so don't blacklist those until we
// have evidence of any problems with them.
bool
GLContext::CanUploadSubTextures()
{
if (!mWorkAroundDriverBugs)
return true;
// There are certain GPUs that we don't want to use glTexSubImage2D on
// because that function can be very slow and/or buggy
if (Renderer() == RendererAdreno200 || Renderer() == RendererAdreno205)
return false;
// On PowerVR glTexSubImage does a readback, so it will be slower
// than just doing a glTexImage2D() directly. i.e. 26ms vs 10ms
if (Renderer() == RendererSGX540 || Renderer() == RendererSGX530)
return false;
return true;
}
bool
GLContext::CanReadSRGBFromFBOTexture()
{
if (!mWorkAroundDriverBugs)
return true;
#ifdef XP_MACOSX
// Bug 843668:
// MacOSX 10.6 reports to support EXT_framebuffer_sRGB and
// EXT_texture_sRGB but fails to convert from sRGB to linear
// when writing to an sRGB texture attached to an FBO.
SInt32 major, minor;
::Gestalt(gestaltSystemVersionMajor, &major);
::Gestalt(gestaltSystemVersionMinor, &minor);
if (major == 10 && minor <= 6) {
return false;
}
#endif // XP_MACOSX
return true;
}
bool GLContext::sPowerOfTwoForced = false;
bool GLContext::sPowerOfTwoPrefCached = false;
void
GLContext::PlatformStartup()
{
CacheCanUploadNPOT();
NS_RegisterMemoryReporter(new GfxTexturesReporter());
}
void
GLContext::CacheCanUploadNPOT()
{
MOZ_ASSERT(NS_IsMainThread(), "Can't cache prefs off the main thread.");
MOZ_ASSERT(!sPowerOfTwoPrefCached, "Must only call this function once!");
sPowerOfTwoPrefCached = true;
mozilla::Preferences::AddBoolVarCache(&sPowerOfTwoForced,
"gfx.textures.poweroftwo.force-enabled");
}
bool
GLContext::CanUploadNonPowerOfTwo()
{
MOZ_ASSERT(sPowerOfTwoPrefCached);
if (!mWorkAroundDriverBugs)
return true;
// Some GPUs driver crash when uploading non power of two 565 textures.
return sPowerOfTwoForced ? false : (Renderer() != RendererAdreno200 &&
Renderer() != RendererAdreno205);
}
bool
GLContext::WantsSmallTiles()
{
// We must use small tiles for good performance if we can't use
// glTexSubImage2D() for some reason.
if (!CanUploadSubTextures())
return true;
// We can't use small tiles on the SGX 540, because of races in texture upload.
if (mWorkAroundDriverBugs &&
Renderer() == RendererSGX540)
return false;
// Don't use small tiles otherwise. (If we implement incremental texture upload,
// then we will want to revisit this.)
return false;
}
// Common code for checking for both GL extensions and GLX extensions.
bool
GLContext::ListHasExtension(const GLubyte *extensions, const char *extension)
{
// fix bug 612572 - we were crashing as we were calling this function with extensions==null
if (extensions == nullptr || extension == nullptr)
return false;
const GLubyte *start;
GLubyte *where, *terminator;
/* Extension names should not have spaces. */
where = (GLubyte *) strchr(extension, ' ');
if (where || *extension == '\0')
return false;
/*
* It takes a bit of care to be fool-proof about parsing the
* OpenGL extensions string. Don't be fooled by sub-strings,
* etc.
*/
start = extensions;
for (;;) {
where = (GLubyte *) strstr((const char *) start, extension);
if (!where) {
break;
}
terminator = where + strlen(extension);
if (where == start || *(where - 1) == ' ') {
if (*terminator == ' ' || *terminator == '\0') {
return true;
}
}
start = terminator;
}
return false;
}
already_AddRefed<TextureImage>
GLContext::CreateTextureImage(const nsIntSize& aSize,
TextureImage::ContentType aContentType,
GLenum aWrapMode,
TextureImage::Flags aFlags,
TextureImage::ImageFormat aImageFormat)
{
return CreateBasicTextureImage(this, aSize, aContentType, aWrapMode,
aFlags, aImageFormat);
}
void GLContext::ApplyFilterToBoundTexture(GraphicsFilter aFilter)
{
ApplyFilterToBoundTexture(LOCAL_GL_TEXTURE_2D, aFilter);
}
void GLContext::ApplyFilterToBoundTexture(GLuint aTarget,
GraphicsFilter aFilter)
{
if (aFilter == GraphicsFilter::FILTER_NEAREST) {
fTexParameteri(aTarget, LOCAL_GL_TEXTURE_MIN_FILTER, LOCAL_GL_NEAREST);
fTexParameteri(aTarget, LOCAL_GL_TEXTURE_MAG_FILTER, LOCAL_GL_NEAREST);
} else {
fTexParameteri(aTarget, LOCAL_GL_TEXTURE_MIN_FILTER, LOCAL_GL_LINEAR);
fTexParameteri(aTarget, LOCAL_GL_TEXTURE_MAG_FILTER, LOCAL_GL_LINEAR);
}
}
void
GLContext::DetermineCaps()
{
PixelBufferFormat format = QueryPixelFormat();
SurfaceCaps caps;
caps.color = !!format.red && !!format.green && !!format.blue;
caps.bpp16 = caps.color && format.ColorBits() == 16;
caps.alpha = !!format.alpha;
caps.depth = !!format.depth;
caps.stencil = !!format.stencil;
caps.antialias = format.samples > 1;
caps.preserve = true;
mCaps = caps;
}
PixelBufferFormat
GLContext::QueryPixelFormat()
{
PixelBufferFormat format;
ScopedBindFramebuffer autoFB(this, 0);
fGetIntegerv(LOCAL_GL_RED_BITS , &format.red );
fGetIntegerv(LOCAL_GL_GREEN_BITS, &format.green);
fGetIntegerv(LOCAL_GL_BLUE_BITS , &format.blue );
fGetIntegerv(LOCAL_GL_ALPHA_BITS, &format.alpha);
fGetIntegerv(LOCAL_GL_DEPTH_BITS, &format.depth);
fGetIntegerv(LOCAL_GL_STENCIL_BITS, &format.stencil);
fGetIntegerv(LOCAL_GL_SAMPLES, &format.samples);
return format;
}
void
GLContext::UpdatePixelFormat()
{
PixelBufferFormat format = QueryPixelFormat();
#ifdef DEBUG
const SurfaceCaps& caps = Caps();
MOZ_ASSERT(!caps.any, "Did you forget to DetermineCaps()?");
MOZ_ASSERT(caps.color == !!format.red);
MOZ_ASSERT(caps.color == !!format.green);
MOZ_ASSERT(caps.color == !!format.blue);
MOZ_ASSERT(caps.alpha == !!format.alpha);
// These we either must have if they're requested, or
// we can have if they're not.
MOZ_ASSERT(caps.depth == !!format.depth || !caps.depth);
MOZ_ASSERT(caps.stencil == !!format.stencil || !caps.stencil);
MOZ_ASSERT(caps.antialias == (format.samples > 1));
#endif
mPixelFormat = new PixelBufferFormat(format);
}
GLFormats
GLContext::ChooseGLFormats(const SurfaceCaps& caps) const
{
GLFormats formats;
// If we're on ES2 hardware and we have an explicit request for 16 bits of color or less
// OR we don't support full 8-bit color, return a 4444 or 565 format.
bool bpp16 = caps.bpp16;
if (IsGLES2()) {
if (!IsExtensionSupported(OES_rgb8_rgba8))
bpp16 = true;
} else {
// RGB565 is uncommon on desktop, requiring ARB_ES2_compatibility.
// Since it's also vanishingly useless there, let's not support it.
bpp16 = false;
}
if (bpp16) {
MOZ_ASSERT(IsGLES2());
if (caps.alpha) {
formats.color_texInternalFormat = LOCAL_GL_RGBA;
formats.color_texFormat = LOCAL_GL_RGBA;
formats.color_texType = LOCAL_GL_UNSIGNED_SHORT_4_4_4_4;
formats.color_rbFormat = LOCAL_GL_RGBA4;
} else {
formats.color_texInternalFormat = LOCAL_GL_RGB;
formats.color_texFormat = LOCAL_GL_RGB;
formats.color_texType = LOCAL_GL_UNSIGNED_SHORT_5_6_5;
formats.color_rbFormat = LOCAL_GL_RGB565;
}
} else {
formats.color_texType = LOCAL_GL_UNSIGNED_BYTE;
if (caps.alpha) {
formats.color_texInternalFormat = IsGLES2() ? LOCAL_GL_RGBA : LOCAL_GL_RGBA8;
formats.color_texFormat = LOCAL_GL_RGBA;
formats.color_rbFormat = LOCAL_GL_RGBA8;
} else {
formats.color_texInternalFormat = IsGLES2() ? LOCAL_GL_RGB : LOCAL_GL_RGB8;
formats.color_texFormat = LOCAL_GL_RGB;
formats.color_rbFormat = LOCAL_GL_RGB8;
}
}
uint32_t msaaLevel = Preferences::GetUint("gl.msaa-level", 2);
GLsizei samples = msaaLevel * msaaLevel;
samples = std::min(samples, mMaxSamples);
// Bug 778765.
if (WorkAroundDriverBugs() && samples == 1) {
samples = 0;
}
formats.samples = samples;
// Be clear that these are 0 if unavailable.
formats.depthStencil = 0;
if (!IsGLES2() || IsExtensionSupported(OES_packed_depth_stencil)) {
formats.depthStencil = LOCAL_GL_DEPTH24_STENCIL8;
}
formats.depth = 0;
if (IsGLES2()) {
if (IsExtensionSupported(OES_depth24)) {
formats.depth = LOCAL_GL_DEPTH_COMPONENT24;
} else {
formats.depth = LOCAL_GL_DEPTH_COMPONENT16;
}
} else {
formats.depth = LOCAL_GL_DEPTH_COMPONENT24;
}
formats.stencil = LOCAL_GL_STENCIL_INDEX8;
return formats;
}
GLuint
GLContext::CreateTextureForOffscreen(const GLFormats& formats, const gfxIntSize& size)
{
MOZ_ASSERT(formats.color_texInternalFormat);
MOZ_ASSERT(formats.color_texFormat);
MOZ_ASSERT(formats.color_texType);
return CreateTexture(formats.color_texInternalFormat,
formats.color_texFormat,
formats.color_texType,
size);
}
GLuint
GLContext::CreateTexture(GLenum internalFormat, GLenum format, GLenum type, const gfxIntSize& size)
{
GLuint tex = 0;
fGenTextures(1, &tex);
ScopedBindTexture autoTex(this, tex);
fTexParameteri(LOCAL_GL_TEXTURE_2D, LOCAL_GL_TEXTURE_MIN_FILTER, LOCAL_GL_LINEAR);
fTexParameteri(LOCAL_GL_TEXTURE_2D, LOCAL_GL_TEXTURE_MAG_FILTER, LOCAL_GL_LINEAR);
fTexParameteri(LOCAL_GL_TEXTURE_2D, LOCAL_GL_TEXTURE_WRAP_S, LOCAL_GL_CLAMP_TO_EDGE);
fTexParameteri(LOCAL_GL_TEXTURE_2D, LOCAL_GL_TEXTURE_WRAP_T, LOCAL_GL_CLAMP_TO_EDGE);
fTexImage2D(LOCAL_GL_TEXTURE_2D,
0,
internalFormat,
size.width, size.height,
0,
format,
type,
nullptr);
return tex;
}
static inline void
RenderbufferStorageBySamples(GLContext* gl, GLsizei samples, GLenum internalFormat, const gfxIntSize& size)
{
if (samples) {
gl->fRenderbufferStorageMultisample(LOCAL_GL_RENDERBUFFER,
samples,
internalFormat,
size.width, size.height);
} else {
gl->fRenderbufferStorage(LOCAL_GL_RENDERBUFFER,
internalFormat,
size.width, size.height);
}
}
GLuint
GLContext::CreateRenderbuffer(GLenum format, GLsizei samples, const gfxIntSize& size)
{
GLuint rb = 0;
fGenRenderbuffers(1, &rb);
ScopedBindRenderbuffer autoRB(this, rb);
RenderbufferStorageBySamples(this, samples, format, size);
return rb;
}
void
GLContext::CreateRenderbuffersForOffscreen(const GLFormats& formats, const gfxIntSize& size,
bool multisample,
GLuint* colorMSRB, GLuint* depthRB, GLuint* stencilRB)
{
GLsizei samples = multisample ? formats.samples : 0;
if (colorMSRB) {
MOZ_ASSERT(formats.samples > 0);
MOZ_ASSERT(formats.color_rbFormat);
*colorMSRB = CreateRenderbuffer(formats.color_rbFormat, samples, size);
}
if (depthRB &&
stencilRB &&
formats.depthStencil)
{
*depthRB = CreateRenderbuffer(formats.depthStencil, samples, size);
*stencilRB = *depthRB;
} else {
if (depthRB) {
MOZ_ASSERT(formats.depth);
*depthRB = CreateRenderbuffer(formats.depth, samples, size);
}
if (stencilRB) {
MOZ_ASSERT(formats.stencil);
*stencilRB = CreateRenderbuffer(formats.stencil, samples, size);
}
}
}
bool
GLContext::IsFramebufferComplete(GLuint fb, GLenum* pStatus)
{
MOZ_ASSERT(fb);
ScopedBindFramebuffer autoFB(this, fb);
MOZ_ASSERT(fIsFramebuffer(fb));
GLenum status = fCheckFramebufferStatus(LOCAL_GL_FRAMEBUFFER);
if (pStatus)
*pStatus = status;
return status == LOCAL_GL_FRAMEBUFFER_COMPLETE;
}
void
GLContext::AttachBuffersToFB(GLuint colorTex, GLuint colorRB,
GLuint depthRB, GLuint stencilRB,
GLuint fb, GLenum target)
{
MOZ_ASSERT(fb);
MOZ_ASSERT( !(colorTex && colorRB) );
ScopedBindFramebuffer autoFB(this, fb);
MOZ_ASSERT(fIsFramebuffer(fb)); // It only counts after being bound.
if (colorTex) {
MOZ_ASSERT(fIsTexture(colorTex));
MOZ_ASSERT(target == LOCAL_GL_TEXTURE_2D ||
target == LOCAL_GL_TEXTURE_RECTANGLE_ARB);
fFramebufferTexture2D(LOCAL_GL_FRAMEBUFFER,
LOCAL_GL_COLOR_ATTACHMENT0,
target,
colorTex,
0);
} else if (colorRB) {
MOZ_ASSERT(fIsRenderbuffer(colorRB));
fFramebufferRenderbuffer(LOCAL_GL_FRAMEBUFFER,
LOCAL_GL_COLOR_ATTACHMENT0,
LOCAL_GL_RENDERBUFFER,
colorRB);
}
if (depthRB) {
MOZ_ASSERT(fIsRenderbuffer(depthRB));
fFramebufferRenderbuffer(LOCAL_GL_FRAMEBUFFER,
LOCAL_GL_DEPTH_ATTACHMENT,
LOCAL_GL_RENDERBUFFER,
depthRB);
}
if (stencilRB) {
MOZ_ASSERT(fIsRenderbuffer(stencilRB));
fFramebufferRenderbuffer(LOCAL_GL_FRAMEBUFFER,
LOCAL_GL_STENCIL_ATTACHMENT,
LOCAL_GL_RENDERBUFFER,
stencilRB);
}
}
bool
GLContext::AssembleOffscreenFBs(const GLuint colorMSRB,
const GLuint depthRB,
const GLuint stencilRB,
const GLuint texture,
GLuint* drawFB_out,
GLuint* readFB_out)
{
if (!colorMSRB && !texture) {
MOZ_ASSERT(!depthRB && !stencilRB);
if (drawFB_out)
*drawFB_out = 0;
if (readFB_out)
*readFB_out = 0;
return true;
}
ScopedBindFramebuffer autoFB(this);
GLuint drawFB = 0;
GLuint readFB = 0;
if (texture) {
readFB = 0;
fGenFramebuffers(1, &readFB);
BindFB(readFB);
fFramebufferTexture2D(LOCAL_GL_FRAMEBUFFER,
LOCAL_GL_COLOR_ATTACHMENT0,
LOCAL_GL_TEXTURE_2D,
texture,
0);
}
if (colorMSRB) {
drawFB = 0;
fGenFramebuffers(1, &drawFB);
BindFB(drawFB);
fFramebufferRenderbuffer(LOCAL_GL_FRAMEBUFFER,
LOCAL_GL_COLOR_ATTACHMENT0,
LOCAL_GL_RENDERBUFFER,
colorMSRB);
} else {
drawFB = readFB;
}
MOZ_ASSERT(GetFB() == drawFB);
if (depthRB) {
fFramebufferRenderbuffer(LOCAL_GL_FRAMEBUFFER,
LOCAL_GL_DEPTH_ATTACHMENT,
LOCAL_GL_RENDERBUFFER,
depthRB);
}
if (stencilRB) {
fFramebufferRenderbuffer(LOCAL_GL_FRAMEBUFFER,
LOCAL_GL_STENCIL_ATTACHMENT,
LOCAL_GL_RENDERBUFFER,
stencilRB);
}
// We should be all resized. Check for framebuffer completeness.
GLenum status;
bool isComplete = true;
if (!IsFramebufferComplete(drawFB, &status)) {
NS_WARNING("DrawFBO: Incomplete");
#ifdef DEBUG
if (DebugMode()) {
printf_stderr("Framebuffer status: %X\n", status);
}
#endif
isComplete = false;
}
if (!IsFramebufferComplete(readFB, &status)) {
NS_WARNING("ReadFBO: Incomplete");
#ifdef DEBUG
if (DebugMode()) {
printf_stderr("Framebuffer status: %X\n", status);
}
#endif
isComplete = false;
}
if (drawFB_out) {
*drawFB_out = drawFB;
} else if (drawFB) {
NS_RUNTIMEABORT("drawFB created when not requested!");
}
if (readFB_out) {
*readFB_out = readFB;
} else if (readFB) {
NS_RUNTIMEABORT("readFB created when not requested!");
}
return isComplete;
}
bool
GLContext::PublishFrame()
{
MOZ_ASSERT(mScreen);
if (!mScreen->PublishFrame(OffscreenSize()))
return false;
return true;
}
SharedSurface*
GLContext::RequestFrame()
{
MOZ_ASSERT(mScreen);
return mScreen->Stream()->SwapConsumer();
}
void
GLContext::ClearSafely()
{
// bug 659349 --- we must be very careful here: clearing a GL framebuffer is nontrivial, relies on a lot of state,
// and in the case of the backbuffer of a WebGL context, state is exposed to scripts.
//
// The code here is taken from WebGLContext::ForceClearFramebufferWithDefaultValues, but I didn't find a good way of
// sharing code with it. WebGL's code is somewhat performance-critical as it is typically called on every frame, so
// WebGL keeps track of GL state to avoid having to query it everytime, and also tries to only do work for actually
// present buffers (e.g. stencil buffer). Doing that here seems like premature optimization,
// as ClearSafely() is called only when e.g. a canvas is resized, not on every animation frame.
realGLboolean scissorTestEnabled;
realGLboolean ditherEnabled;
realGLboolean colorWriteMask[4];
realGLboolean depthWriteMask;
GLint stencilWriteMaskFront, stencilWriteMaskBack;
GLfloat colorClearValue[4];
GLfloat depthClearValue;
GLint stencilClearValue;
// save current GL state
fGetBooleanv(LOCAL_GL_SCISSOR_TEST, &scissorTestEnabled);
fGetBooleanv(LOCAL_GL_DITHER, &ditherEnabled);
fGetBooleanv(LOCAL_GL_COLOR_WRITEMASK, colorWriteMask);
fGetBooleanv(LOCAL_GL_DEPTH_WRITEMASK, &depthWriteMask);
fGetIntegerv(LOCAL_GL_STENCIL_WRITEMASK, &stencilWriteMaskFront);
fGetIntegerv(LOCAL_GL_STENCIL_BACK_WRITEMASK, &stencilWriteMaskBack);
fGetFloatv(LOCAL_GL_COLOR_CLEAR_VALUE, colorClearValue);
fGetFloatv(LOCAL_GL_DEPTH_CLEAR_VALUE, &depthClearValue);
fGetIntegerv(LOCAL_GL_STENCIL_CLEAR_VALUE, &stencilClearValue);
// prepare GL state for clearing
fDisable(LOCAL_GL_SCISSOR_TEST);
fDisable(LOCAL_GL_DITHER);
PushViewportRect(nsIntRect(0, 0, OffscreenSize().width, OffscreenSize().height));
fColorMask(1, 1, 1, 1);
fClearColor(0.f, 0.f, 0.f, 0.f);
fDepthMask(1);
fClearDepth(1.0f);
fStencilMask(0xffffffff);
fClearStencil(0);
// do clear
fClear(LOCAL_GL_COLOR_BUFFER_BIT |
LOCAL_GL_DEPTH_BUFFER_BIT |
LOCAL_GL_STENCIL_BUFFER_BIT);
// restore GL state after clearing
fColorMask(colorWriteMask[0],
colorWriteMask[1],
colorWriteMask[2],
colorWriteMask[3]);
fClearColor(colorClearValue[0],
colorClearValue[1],
colorClearValue[2],
colorClearValue[3]);
fDepthMask(depthWriteMask);
fClearDepth(depthClearValue);
fStencilMaskSeparate(LOCAL_GL_FRONT, stencilWriteMaskFront);
fStencilMaskSeparate(LOCAL_GL_BACK, stencilWriteMaskBack);
fClearStencil(stencilClearValue);
PopViewportRect();
if (ditherEnabled)
fEnable(LOCAL_GL_DITHER);
else
fDisable(LOCAL_GL_DITHER);
if (scissorTestEnabled)
fEnable(LOCAL_GL_SCISSOR_TEST);
else
fDisable(LOCAL_GL_SCISSOR_TEST);
}
void
GLContext::MarkDestroyed()
{
if (IsDestroyed())
return;
if (MakeCurrent()) {
DestroyScreenBuffer();
// This is for Blit{Tex,FB}To{TexFB}.
DeleteTexBlitProgram();
// Likely used by OGL Layers.
fDeleteProgram(mBlitProgram);
mBlitProgram = 0;
fDeleteFramebuffers(1, &mBlitFramebuffer);
mBlitFramebuffer = 0;
mTexGarbageBin->GLContextTeardown();
} else {
NS_WARNING("MakeCurrent() failed during MarkDestroyed! Skipping GL object teardown.");
}
mSymbols.Zero();
}
static void SwapRAndBComponents(gfxImageSurface* surf)
{
uint8_t *row = surf->Data();
size_t rowBytes = surf->Width()*4;
size_t rowHole = surf->Stride() - rowBytes;
size_t rows = surf->Height();
while (rows) {
const uint8_t *rowEnd = row + rowBytes;
while (row != rowEnd) {
row[0] ^= row[2];
row[2] ^= row[0];
row[0] ^= row[2];
row += 4;
}
row += rowHole;
--rows;
}
}
static already_AddRefed<gfxImageSurface> YInvertImageSurface(gfxImageSurface* aSurf)
{
gfxIntSize size = aSurf->GetSize();
nsRefPtr<gfxImageSurface> temp = new gfxImageSurface(size, aSurf->Format());
nsRefPtr<gfxContext> ctx = new gfxContext(temp);
ctx->SetOperator(gfxContext::OPERATOR_SOURCE);
ctx->Scale(1.0, -1.0);
ctx->Translate(-gfxPoint(0.0, size.height));
ctx->SetSource(aSurf);
ctx->Paint();
return temp.forget();
}
already_AddRefed<gfxImageSurface>
GLContext::GetTexImage(GLuint aTexture, bool aYInvert, SurfaceFormat aFormat)
{
MakeCurrent();
GuaranteeResolve();
fActiveTexture(LOCAL_GL_TEXTURE0);
fBindTexture(LOCAL_GL_TEXTURE_2D, aTexture);
gfxIntSize size;
fGetTexLevelParameteriv(LOCAL_GL_TEXTURE_2D, 0, LOCAL_GL_TEXTURE_WIDTH, &size.width);
fGetTexLevelParameteriv(LOCAL_GL_TEXTURE_2D, 0, LOCAL_GL_TEXTURE_HEIGHT, &size.height);
nsRefPtr<gfxImageSurface> surf = new gfxImageSurface(size, gfxImageFormatARGB32);
if (!surf || surf->CairoStatus()) {
return nullptr;
}
uint32_t currentPackAlignment = 0;
fGetIntegerv(LOCAL_GL_PACK_ALIGNMENT, (GLint*)&currentPackAlignment);
if (currentPackAlignment != 4) {
fPixelStorei(LOCAL_GL_PACK_ALIGNMENT, 4);
}
fGetTexImage(LOCAL_GL_TEXTURE_2D, 0, LOCAL_GL_RGBA, LOCAL_GL_UNSIGNED_BYTE, surf->Data());
if (currentPackAlignment != 4) {
fPixelStorei(LOCAL_GL_PACK_ALIGNMENT, currentPackAlignment);
}
if (aFormat == FORMAT_R8G8B8A8 || aFormat == FORMAT_R8G8B8X8) {
SwapRAndBComponents(surf);
}
if (aYInvert) {
surf = YInvertImageSurface(surf);
}
return surf.forget();
}
already_AddRefed<gfxImageSurface>
GLContext::ReadTextureImage(GLuint aTexture,
const gfxIntSize& aSize,
GLenum aTextureFormat,
bool aYInvert)
{
MakeCurrent();
nsRefPtr<gfxImageSurface> isurf;
GLint oldrb, oldfb, oldprog, oldPackAlignment;
GLint success;
GLuint rb = 0, fb = 0;
GLuint vs = 0, fs = 0, prog = 0;
const char *vShader =
"attribute vec4 aVertex;\n"
"attribute vec2 aTexCoord;\n"
"varying vec2 vTexCoord;\n"
"void main() { gl_Position = aVertex; vTexCoord = aTexCoord; }";
const char *fShader =
"#ifdef GL_ES\n"
"precision mediump float;\n"
"#endif\n"
"varying vec2 vTexCoord;\n"
"uniform sampler2D uTexture;\n"
"void main() { gl_FragColor = texture2D(uTexture, vTexCoord); }";
float verts[4*4] = {
-1.0f, -1.0f, 0.0f, 1.0f,
1.0f, -1.0f, 0.0f, 1.0f,
-1.0f, 1.0f, 0.0f, 1.0f,
1.0f, 1.0f, 0.0f, 1.0f
};
float texcoords[2*4] = {
0.0f, 0.0f, 1.0f, 0.0f, 0.0f, 1.0f, 1.0f, 1.0f
};
fGetIntegerv(LOCAL_GL_RENDERBUFFER_BINDING, &oldrb);
fGetIntegerv(LOCAL_GL_FRAMEBUFFER_BINDING, &oldfb);
fGetIntegerv(LOCAL_GL_CURRENT_PROGRAM, &oldprog);
fGetIntegerv(LOCAL_GL_PACK_ALIGNMENT, &oldPackAlignment);
PushViewportRect(nsIntRect(0, 0, aSize.width, aSize.height));
fGenRenderbuffers(1, &rb);
fBindRenderbuffer(LOCAL_GL_RENDERBUFFER, rb);
fRenderbufferStorage(LOCAL_GL_RENDERBUFFER, LOCAL_GL_RGBA,
aSize.width, aSize.height);
fGenFramebuffers(1, &fb);
fBindFramebuffer(LOCAL_GL_FRAMEBUFFER, fb);
fFramebufferRenderbuffer(LOCAL_GL_FRAMEBUFFER, LOCAL_GL_COLOR_ATTACHMENT0,
LOCAL_GL_RENDERBUFFER, rb);
if (fCheckFramebufferStatus(LOCAL_GL_FRAMEBUFFER) !=
LOCAL_GL_FRAMEBUFFER_COMPLETE)
{
goto cleanup;
}
vs = fCreateShader(LOCAL_GL_VERTEX_SHADER);
fs = fCreateShader(LOCAL_GL_FRAGMENT_SHADER);
fShaderSource(vs, 1, (const GLchar**) &vShader, nullptr);
fShaderSource(fs, 1, (const GLchar**) &fShader, nullptr);
fCompileShader(vs);
fCompileShader(fs);
prog = fCreateProgram();
fAttachShader(prog, vs);
fAttachShader(prog, fs);
fBindAttribLocation(prog, 0, "aVertex");
fBindAttribLocation(prog, 1, "aTexCoord");
fLinkProgram(prog);
fGetProgramiv(prog, LOCAL_GL_LINK_STATUS, &success);
if (!success) {
goto cleanup;
}
fUseProgram(prog);
fEnableVertexAttribArray(0);
fEnableVertexAttribArray(1);
fVertexAttribPointer(0, 4, LOCAL_GL_FLOAT, LOCAL_GL_FALSE, 0, verts);
fVertexAttribPointer(1, 2, LOCAL_GL_FLOAT, LOCAL_GL_FALSE, 0, texcoords);
fActiveTexture(LOCAL_GL_TEXTURE0);
fBindTexture(LOCAL_GL_TEXTURE_2D, aTexture);
fUniform1i(fGetUniformLocation(prog, "uTexture"), 0);
fDrawArrays(LOCAL_GL_TRIANGLE_STRIP, 0, 4);
fDisableVertexAttribArray(1);
fDisableVertexAttribArray(0);
isurf = new gfxImageSurface(aSize, gfxImageFormatARGB32);
if (!isurf || isurf->CairoStatus()) {
isurf = nullptr;
goto cleanup;
}
if (oldPackAlignment != 4)
fPixelStorei(LOCAL_GL_PACK_ALIGNMENT, 4);
fReadPixels(0, 0, aSize.width, aSize.height,
LOCAL_GL_RGBA, LOCAL_GL_UNSIGNED_BYTE,
isurf->Data());
SwapRAndBComponents(isurf);
if (oldPackAlignment != 4)
fPixelStorei(LOCAL_GL_PACK_ALIGNMENT, oldPackAlignment);
if (aYInvert) {
isurf = YInvertImageSurface(isurf);
}
cleanup:
// note that deleting 0 has no effect in any of these calls
fDeleteRenderbuffers(1, &rb);
fDeleteFramebuffers(1, &fb);
fDeleteShader(vs);
fDeleteShader(fs);
fDeleteProgram(prog);
fBindRenderbuffer(LOCAL_GL_RENDERBUFFER, oldrb);
fBindFramebuffer(LOCAL_GL_FRAMEBUFFER, oldfb);
fUseProgram(oldprog);
PopViewportRect();
return isurf.forget();
}
static bool
GetActualReadFormats(GLContext* gl, GLenum destFormat, GLenum destType,
GLenum& readFormat, GLenum& readType)
{
if (destFormat == LOCAL_GL_RGBA &&
destType == LOCAL_GL_UNSIGNED_BYTE)
{
readFormat = destFormat;
readType = destType;
return true;
}
bool fallback = true;
if (gl->IsGLES2()) {
GLenum auxFormat = 0;
GLenum auxType = 0;
gl->fGetIntegerv(LOCAL_GL_IMPLEMENTATION_COLOR_READ_FORMAT, (GLint*)&auxFormat);
gl->fGetIntegerv(LOCAL_GL_IMPLEMENTATION_COLOR_READ_TYPE, (GLint*)&auxType);
if (destFormat == auxFormat &&
destType == auxType)
{
fallback = false;
}
} else {
switch (destFormat) {
case LOCAL_GL_RGB: {
if (destType == LOCAL_GL_UNSIGNED_SHORT_5_6_5_REV)
fallback = false;
break;
}
case LOCAL_GL_BGRA: {
if (destType == LOCAL_GL_UNSIGNED_INT_8_8_8_8_REV)
fallback = false;
break;
}
}
}
if (fallback) {
readFormat = LOCAL_GL_RGBA;
readType = LOCAL_GL_UNSIGNED_BYTE;
return false;
} else {
readFormat = destFormat;
readType = destType;
return true;
}
}
void
GLContext::ReadScreenIntoImageSurface(gfxImageSurface* dest)
{
ScopedBindFramebuffer autoFB(this, 0);
ReadPixelsIntoImageSurface(dest);
}
TemporaryRef<SourceSurface>
GLContext::ReadPixelsToSourceSurface(const gfx::IntSize &aSize)
{
// XXX we should do this properly one day without using the gfxImageSurface
RefPtr<DataSourceSurface> dataSourceSurface =
Factory::CreateDataSourceSurface(aSize, gfx::FORMAT_B8G8R8A8);
nsRefPtr<gfxImageSurface> surf =
new gfxImageSurface(dataSourceSurface->GetData(),
gfxIntSize(aSize.width, aSize.height),
dataSourceSurface->Stride(),
gfxImageFormatARGB32);
ReadPixelsIntoImageSurface(surf);
dataSourceSurface->MarkDirty();
return dataSourceSurface;
}
void
GLContext::ReadPixelsIntoImageSurface(gfxImageSurface* dest)
{
MakeCurrent();
MOZ_ASSERT(dest->GetSize() != gfxIntSize(0, 0));
/* gfxImageFormatARGB32:
* RGBA+UByte: be[RGBA], le[ABGR]
* RGBA+UInt: le[RGBA]
* BGRA+UInt: le[BGRA]
* BGRA+UIntRev: le[ARGB]
*
* gfxImageFormatRGB16_565:
* RGB+UShort: le[rrrrrggg,gggbbbbb]
*/
bool hasAlpha = dest->Format() == gfxImageFormatARGB32;
int destPixelSize;
GLenum destFormat;
GLenum destType;
switch (dest->Format()) {
case gfxImageFormatRGB24: // XRGB
case gfxImageFormatARGB32:
destPixelSize = 4;
// Needs host (little) endian ARGB.
destFormat = LOCAL_GL_BGRA;
destType = LOCAL_GL_UNSIGNED_INT_8_8_8_8_REV;
break;
case gfxImageFormatRGB16_565:
destPixelSize = 2;
destFormat = LOCAL_GL_RGB;
destType = LOCAL_GL_UNSIGNED_SHORT_5_6_5_REV;
break;
default:
MOZ_CRASH("Bad format.");
}
MOZ_ASSERT(dest->Stride() == dest->Width() * destPixelSize);
GLenum readFormat = destFormat;
GLenum readType = destType;
bool needsTempSurf = !GetActualReadFormats(this,
destFormat, destType,
readFormat, readType);
nsAutoPtr<gfxImageSurface> tempSurf;
gfxImageSurface* readSurf = nullptr;
int readPixelSize = 0;
if (needsTempSurf) {
if (DebugMode()) {
NS_WARNING("Needing intermediary surface for ReadPixels. This will be slow!");
}
ImageFormat readFormatGFX;
switch (readFormat) {
case LOCAL_GL_RGBA:
case LOCAL_GL_BGRA: {
readFormatGFX = hasAlpha ? gfxImageFormatARGB32
: gfxImageFormatRGB24;
break;
}
case LOCAL_GL_RGB: {
MOZ_ASSERT(readPixelSize == 2);
MOZ_ASSERT(readType == LOCAL_GL_UNSIGNED_SHORT_5_6_5_REV);
readFormatGFX = gfxImageFormatRGB16_565;
break;
}
default: {
MOZ_CRASH("Bad read format.");
}
}
switch (readType) {
case LOCAL_GL_UNSIGNED_BYTE: {
MOZ_ASSERT(readFormat == LOCAL_GL_RGBA);
readPixelSize = 4;
break;
}
case LOCAL_GL_UNSIGNED_INT_8_8_8_8_REV: {
MOZ_ASSERT(readFormat == LOCAL_GL_BGRA);
readPixelSize = 4;
break;
}
case LOCAL_GL_UNSIGNED_SHORT_5_6_5_REV: {
MOZ_ASSERT(readFormat == LOCAL_GL_RGB);
readPixelSize = 2;
break;
}
default: {
MOZ_CRASH("Bad read type.");
}
}
tempSurf = new gfxImageSurface(dest->GetSize(), readFormatGFX, false);
readSurf = tempSurf;
} else {
readPixelSize = destPixelSize;
readSurf = dest;
}
MOZ_ASSERT(readPixelSize);
GLint currentPackAlignment = 0;
fGetIntegerv(LOCAL_GL_PACK_ALIGNMENT, &currentPackAlignment);
if (currentPackAlignment != readPixelSize)
fPixelStorei(LOCAL_GL_PACK_ALIGNMENT, readPixelSize);
GLsizei width = dest->Width();
GLsizei height = dest->Height();
readSurf->Flush();
fReadPixels(0, 0,
width, height,
readFormat, readType,
readSurf->Data());
readSurf->MarkDirty();
if (currentPackAlignment != readPixelSize)
fPixelStorei(LOCAL_GL_PACK_ALIGNMENT, currentPackAlignment);
if (readSurf != dest) {
MOZ_ASSERT(readFormat == LOCAL_GL_RGBA);
MOZ_ASSERT(readType == LOCAL_GL_UNSIGNED_BYTE);
// So we just copied in RGBA in big endian, or le: 0xAABBGGRR.
// We want 0xAARRGGBB, so swap R and B:
dest->Flush();
SwapRAndBComponents(readSurf);
dest->MarkDirty();
gfxContext ctx(dest);
ctx.SetOperator(gfxContext::OPERATOR_SOURCE);
ctx.SetSource(readSurf);
ctx.Paint();
}
// Check if GL is giving back 1.0 alpha for
// RGBA reads to RGBA images from no-alpha buffers.
#ifdef XP_MACOSX
if (WorkAroundDriverBugs() &&
mVendor == VendorNVIDIA &&
dest->Format() == gfxImageFormatARGB32 &&
width && height)
{
GLint alphaBits = 0;
fGetIntegerv(LOCAL_GL_ALPHA_BITS, &alphaBits);
if (!alphaBits) {
const uint32_t alphaMask = gfxPackedPixelNoPreMultiply(0xff,0,0,0);
dest->Flush();
uint32_t* itr = (uint32_t*)dest->Data();
uint32_t testPixel = *itr;
if ((testPixel & alphaMask) != alphaMask) {
// We need to set the alpha channel to 1.0 manually.
uint32_t* itrEnd = itr + width*height; // Stride is guaranteed to be width*4.
for (; itr != itrEnd; itr++) {
*itr |= alphaMask;
}
}
dest->MarkDirty();
}
}
#endif
}
void
GLContext::BlitTextureImage(TextureImage *aSrc, const nsIntRect& aSrcRect,
TextureImage *aDst, const nsIntRect& aDstRect)
{
NS_ASSERTION(!aSrc->InUpdate(), "Source texture is in update!");
NS_ASSERTION(!aDst->InUpdate(), "Destination texture is in update!");
if (aSrcRect.IsEmpty() || aDstRect.IsEmpty())
return;
int savedFb = 0;
fGetIntegerv(LOCAL_GL_FRAMEBUFFER_BINDING, &savedFb);
fDisable(LOCAL_GL_SCISSOR_TEST);
fDisable(LOCAL_GL_BLEND);
// 2.0 means scale up by two
float blitScaleX = float(aDstRect.width) / float(aSrcRect.width);
float blitScaleY = float(aDstRect.height) / float(aSrcRect.height);
// We start iterating over all destination tiles
aDst->BeginTileIteration();
do {
// calculate portion of the tile that is going to be painted to
nsIntRect dstSubRect;
nsIntRect dstTextureRect = ThebesIntRect(aDst->GetTileRect());
dstSubRect.IntersectRect(aDstRect, dstTextureRect);
// this tile is not part of the destination rectangle aDstRect
if (dstSubRect.IsEmpty())
continue;
// (*) transform the rect of this tile into the rectangle defined by aSrcRect...
nsIntRect dstInSrcRect(dstSubRect);
dstInSrcRect.MoveBy(-aDstRect.TopLeft());
// ...which might be of different size, hence scale accordingly
dstInSrcRect.ScaleRoundOut(1.0f / blitScaleX, 1.0f / blitScaleY);
dstInSrcRect.MoveBy(aSrcRect.TopLeft());
SetBlitFramebufferForDestTexture(aDst->GetTextureID());
UseBlitProgram();
aSrc->BeginTileIteration();
// now iterate over all tiles in the source Image...
do {
// calculate portion of the source tile that is in the source rect
nsIntRect srcSubRect;
nsIntRect srcTextureRect = ThebesIntRect(aSrc->GetTileRect());
srcSubRect.IntersectRect(aSrcRect, srcTextureRect);
// this tile is not part of the source rect
if (srcSubRect.IsEmpty()) {
continue;
}
// calculate intersection of source rect with destination rect
srcSubRect.IntersectRect(srcSubRect, dstInSrcRect);
// this tile does not overlap the current destination tile
if (srcSubRect.IsEmpty()) {
continue;
}
// We now have the intersection of
// the current source tile
// and the desired source rectangle
// and the destination tile
// and the desired destination rectange
// in destination space.
// We need to transform this back into destination space, inverting the transform from (*)
nsIntRect srcSubInDstRect(srcSubRect);
srcSubInDstRect.MoveBy(-aSrcRect.TopLeft());
srcSubInDstRect.ScaleRoundOut(blitScaleX, blitScaleY);
srcSubInDstRect.MoveBy(aDstRect.TopLeft());
// we transform these rectangles to be relative to the current src and dst tiles, respectively
nsIntSize srcSize = srcTextureRect.Size();
nsIntSize dstSize = dstTextureRect.Size();
srcSubRect.MoveBy(-srcTextureRect.x, -srcTextureRect.y);
srcSubInDstRect.MoveBy(-dstTextureRect.x, -dstTextureRect.y);
float dx0 = 2.0f * float(srcSubInDstRect.x) / float(dstSize.width) - 1.0f;
float dy0 = 2.0f * float(srcSubInDstRect.y) / float(dstSize.height) - 1.0f;
float dx1 = 2.0f * float(srcSubInDstRect.x + srcSubInDstRect.width) / float(dstSize.width) - 1.0f;
float dy1 = 2.0f * float(srcSubInDstRect.y + srcSubInDstRect.height) / float(dstSize.height) - 1.0f;
PushViewportRect(nsIntRect(0, 0, dstSize.width, dstSize.height));
RectTriangles rects;
nsIntSize realTexSize = srcSize;
if (!CanUploadNonPowerOfTwo()) {
realTexSize = nsIntSize(NextPowerOfTwo(srcSize.width),
NextPowerOfTwo(srcSize.height));
}
if (aSrc->GetWrapMode() == LOCAL_GL_REPEAT) {
rects.addRect(/* dest rectangle */
dx0, dy0, dx1, dy1,
/* tex coords */
srcSubRect.x / float(realTexSize.width),
srcSubRect.y / float(realTexSize.height),
srcSubRect.XMost() / float(realTexSize.width),
srcSubRect.YMost() / float(realTexSize.height));
} else {
DecomposeIntoNoRepeatTriangles(srcSubRect, realTexSize, rects);
// now put the coords into the d[xy]0 .. d[xy]1 coordinate space
// from the 0..1 that it comes out of decompose
RectTriangles::vert_coord* v = (RectTriangles::vert_coord*)rects.vertexPointer();
for (unsigned int i = 0; i < rects.elements(); ++i) {
v[i].x = (v[i].x * (dx1 - dx0)) + dx0;
v[i].y = (v[i].y * (dy1 - dy0)) + dy0;
}
}
TextureImage::ScopedBindTexture texBind(aSrc, LOCAL_GL_TEXTURE0);
fBindBuffer(LOCAL_GL_ARRAY_BUFFER, 0);
fVertexAttribPointer(0, 2, LOCAL_GL_FLOAT, LOCAL_GL_FALSE, 0, rects.vertexPointer());
fVertexAttribPointer(1, 2, LOCAL_GL_FLOAT, LOCAL_GL_FALSE, 0, rects.texCoordPointer());
fEnableVertexAttribArray(0);
fEnableVertexAttribArray(1);
fDrawArrays(LOCAL_GL_TRIANGLES, 0, rects.elements());
fDisableVertexAttribArray(0);
fDisableVertexAttribArray(1);
PopViewportRect();
} while (aSrc->NextTile());
} while (aDst->NextTile());
fVertexAttribPointer(0, 2, LOCAL_GL_FLOAT, LOCAL_GL_FALSE, 0, nullptr);
fVertexAttribPointer(1, 2, LOCAL_GL_FLOAT, LOCAL_GL_FALSE, 0, nullptr);
// unbind the previous texture from the framebuffer
SetBlitFramebufferForDestTexture(0);
fBindFramebuffer(LOCAL_GL_FRAMEBUFFER, savedFb);
fEnable(LOCAL_GL_SCISSOR_TEST);
fEnable(LOCAL_GL_BLEND);
}
static unsigned int
DataOffset(const nsIntPoint &aPoint, int32_t aStride, gfxImageFormat aFormat)
{
unsigned int data = aPoint.y * aStride;
data += aPoint.x * gfxASurface::BytePerPixelFromFormat(aFormat);
return data;
}
GLContext::SurfaceFormat
GLContext::UploadImageDataToTexture(unsigned char* aData,
int32_t aStride,
gfxImageFormat aFormat,
const nsIntRegion& aDstRegion,
GLuint& aTexture,
bool aOverwrite,
bool aPixelBuffer,
GLenum aTextureUnit,
GLenum aTextureTarget)
{
bool textureInited = aOverwrite ? false : true;
MakeCurrent();
fActiveTexture(aTextureUnit);
if (!aTexture) {
fGenTextures(1, &aTexture);
fBindTexture(aTextureTarget, aTexture);
fTexParameteri(aTextureTarget,
LOCAL_GL_TEXTURE_MIN_FILTER,
LOCAL_GL_LINEAR);
fTexParameteri(aTextureTarget,
LOCAL_GL_TEXTURE_MAG_FILTER,
LOCAL_GL_LINEAR);
fTexParameteri(aTextureTarget,
LOCAL_GL_TEXTURE_WRAP_S,
LOCAL_GL_CLAMP_TO_EDGE);
fTexParameteri(aTextureTarget,
LOCAL_GL_TEXTURE_WRAP_T,
LOCAL_GL_CLAMP_TO_EDGE);
textureInited = false;
} else {
fBindTexture(aTextureTarget, aTexture);
}
nsIntRegion paintRegion;
if (!textureInited) {
paintRegion = nsIntRegion(aDstRegion.GetBounds());
} else {
paintRegion = aDstRegion;
}
GLenum format;
GLenum internalFormat;
GLenum type;
int32_t pixelSize = gfxASurface::BytePerPixelFromFormat(aFormat);
SurfaceFormat surfaceFormat;
MOZ_ASSERT(GetPreferredARGB32Format() == LOCAL_GL_BGRA ||
GetPreferredARGB32Format() == LOCAL_GL_RGBA);
switch (aFormat) {
case gfxImageFormatARGB32:
if (GetPreferredARGB32Format() == LOCAL_GL_BGRA) {
format = LOCAL_GL_BGRA;
surfaceFormat = FORMAT_R8G8B8A8;
type = LOCAL_GL_UNSIGNED_INT_8_8_8_8_REV;
} else {
format = LOCAL_GL_RGBA;
surfaceFormat = FORMAT_B8G8R8A8;
type = LOCAL_GL_UNSIGNED_BYTE;
}
internalFormat = LOCAL_GL_RGBA;
break;
case gfxImageFormatRGB24:
// Treat RGB24 surfaces as RGBA32 except for the surface
// format used.
if (GetPreferredARGB32Format() == LOCAL_GL_BGRA) {
format = LOCAL_GL_BGRA;
surfaceFormat = FORMAT_R8G8B8X8;
type = LOCAL_GL_UNSIGNED_INT_8_8_8_8_REV;
} else {
format = LOCAL_GL_RGBA;
surfaceFormat = FORMAT_B8G8R8X8;
type = LOCAL_GL_UNSIGNED_BYTE;
}
internalFormat = LOCAL_GL_RGBA;
break;
case gfxImageFormatRGB16_565:
internalFormat = format = LOCAL_GL_RGB;
type = LOCAL_GL_UNSIGNED_SHORT_5_6_5;
surfaceFormat = FORMAT_R5G6B5;
break;
case gfxImageFormatA8:
internalFormat = format = LOCAL_GL_LUMINANCE;
type = LOCAL_GL_UNSIGNED_BYTE;
// We don't have a specific luminance shader
surfaceFormat = FORMAT_A8;
break;
default:
NS_ASSERTION(false, "Unhandled image surface format!");
format = 0;
type = 0;
surfaceFormat = FORMAT_UNKNOWN;
}
nsIntRegionRectIterator iter(paintRegion);
const nsIntRect *iterRect;
// Top left point of the region's bounding rectangle.
nsIntPoint topLeft = paintRegion.GetBounds().TopLeft();
while ((iterRect = iter.Next())) {
// The inital data pointer is at the top left point of the region's
// bounding rectangle. We need to find the offset of this rect
// within the region and adjust the data pointer accordingly.
unsigned char *rectData =
aData + DataOffset(iterRect->TopLeft() - topLeft, aStride, aFormat);
NS_ASSERTION(textureInited || (iterRect->x == 0 && iterRect->y == 0),
"Must be uploading to the origin when we don't have an existing texture");
if (textureInited && CanUploadSubTextures()) {
TexSubImage2D(aTextureTarget,
0,
iterRect->x,
iterRect->y,
iterRect->width,
iterRect->height,
aStride,
pixelSize,
format,
type,
rectData);
} else {
TexImage2D(aTextureTarget,
0,
internalFormat,
iterRect->width,
iterRect->height,
aStride,
pixelSize,
0,
format,
type,
rectData);
}
}
return surfaceFormat;
}
GLContext::SurfaceFormat
GLContext::UploadSurfaceToTexture(gfxASurface *aSurface,
const nsIntRegion& aDstRegion,
GLuint& aTexture,
bool aOverwrite,
const nsIntPoint& aSrcPoint,
bool aPixelBuffer,
GLenum aTextureUnit,
GLenum aTextureTarget)
{
nsRefPtr<gfxImageSurface> imageSurface = aSurface->GetAsImageSurface();
unsigned char* data = nullptr;
if (!imageSurface ||
(imageSurface->Format() != gfxImageFormatARGB32 &&
imageSurface->Format() != gfxImageFormatRGB24 &&
imageSurface->Format() != gfxImageFormatRGB16_565 &&
imageSurface->Format() != gfxImageFormatA8)) {
// We can't get suitable pixel data for the surface, make a copy
nsIntRect bounds = aDstRegion.GetBounds();
imageSurface =
new gfxImageSurface(gfxIntSize(bounds.width, bounds.height),
gfxImageFormatARGB32);
nsRefPtr<gfxContext> context = new gfxContext(imageSurface);
context->Translate(-gfxPoint(aSrcPoint.x, aSrcPoint.y));
context->SetSource(aSurface);
context->Paint();
data = imageSurface->Data();
NS_ASSERTION(!aPixelBuffer,
"Must be using an image compatible surface with pixel buffers!");
} else {
// If a pixel buffer is bound the data pointer parameter is relative
// to the start of the data block.
if (!aPixelBuffer) {
data = imageSurface->Data();
}
data += DataOffset(aSrcPoint, imageSurface->Stride(),
imageSurface->Format());
}
MOZ_ASSERT(imageSurface);
imageSurface->Flush();
return UploadImageDataToTexture(data,
imageSurface->Stride(),
imageSurface->Format(),
aDstRegion, aTexture, aOverwrite,
aPixelBuffer, aTextureUnit, aTextureTarget);
}
static gfxImageFormat
ImageFormatForSurfaceFormat(gfx::SurfaceFormat aFormat)
{
switch (aFormat) {
case gfx::FORMAT_B8G8R8A8:
return gfxImageFormatARGB32;
case gfx::FORMAT_B8G8R8X8:
return gfxImageFormatRGB24;
case gfx::FORMAT_R5G6B5:
return gfxImageFormatRGB16_565;
case gfx::FORMAT_A8:
return gfxImageFormatA8;
default:
return gfxImageFormatUnknown;
}
}
GLContext::SurfaceFormat
GLContext::UploadSurfaceToTexture(gfx::DataSourceSurface *aSurface,
const nsIntRegion& aDstRegion,
GLuint& aTexture,
bool aOverwrite,
const nsIntPoint& aSrcPoint,
bool aPixelBuffer,
GLenum aTextureUnit,
GLenum aTextureTarget)
{
unsigned char* data = aPixelBuffer ? nullptr : aSurface->GetData();
int32_t stride = aSurface->Stride();
gfxImageFormat format =
ImageFormatForSurfaceFormat(aSurface->GetFormat());
data += DataOffset(aSrcPoint, stride, format);
return UploadImageDataToTexture(data, stride, format,
aDstRegion, aTexture, aOverwrite,
aPixelBuffer, aTextureUnit,
aTextureTarget);
}
static GLint GetAddressAlignment(ptrdiff_t aAddress)
{
if (!(aAddress & 0x7)) {
return 8;
} else if (!(aAddress & 0x3)) {
return 4;
} else if (!(aAddress & 0x1)) {
return 2;
} else {
return 1;
}
}
void
GLContext::TexImage2D(GLenum target, GLint level, GLint internalformat,
GLsizei width, GLsizei height, GLsizei stride,
GLint pixelsize, GLint border, GLenum format,
GLenum type, const GLvoid *pixels)
{
if (IsGLES2()) {
NS_ASSERTION(format == (GLenum)internalformat,
"format and internalformat not the same for glTexImage2D on GLES2");
if (!CanUploadNonPowerOfTwo()
&& (stride != width * pixelsize
|| !IsPowerOfTwo(width)
|| !IsPowerOfTwo(height))) {
// Pad out texture width and height to the next power of two
// as we don't support/want non power of two texture uploads
GLsizei paddedWidth = NextPowerOfTwo(width);
GLsizei paddedHeight = NextPowerOfTwo(height);
GLvoid* paddedPixels = new unsigned char[paddedWidth * paddedHeight * pixelsize];
// Pad out texture data to be in a POT sized buffer for uploading to
// a POT sized texture
CopyAndPadTextureData(pixels, paddedPixels, width, height,
paddedWidth, paddedHeight, stride, pixelsize);
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT,
std::min(GetAddressAlignment((ptrdiff_t)paddedPixels),
GetAddressAlignment((ptrdiff_t)paddedWidth * pixelsize)));
fTexImage2D(target,
border,
internalformat,
paddedWidth,
paddedHeight,
border,
format,
type,
paddedPixels);
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT, 4);
delete[] static_cast<unsigned char*>(paddedPixels);
return;
}
if (stride == width * pixelsize) {
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT,
std::min(GetAddressAlignment((ptrdiff_t)pixels),
GetAddressAlignment((ptrdiff_t)stride)));
fTexImage2D(target,
border,
internalformat,
width,
height,
border,
format,
type,
pixels);
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT, 4);
} else {
// Use GLES-specific workarounds for GL_UNPACK_ROW_LENGTH; these are
// implemented in TexSubImage2D.
fTexImage2D(target,
border,
internalformat,
width,
height,
border,
format,
type,
nullptr);
TexSubImage2D(target,
level,
0,
0,
width,
height,
stride,
pixelsize,
format,
type,
pixels);
}
} else {
// desktop GL (non-ES) path
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT,
std::min(GetAddressAlignment((ptrdiff_t)pixels),
GetAddressAlignment((ptrdiff_t)stride)));
int rowLength = stride/pixelsize;
fPixelStorei(LOCAL_GL_UNPACK_ROW_LENGTH, rowLength);
fTexImage2D(target,
level,
internalformat,
width,
height,
border,
format,
type,
pixels);
fPixelStorei(LOCAL_GL_UNPACK_ROW_LENGTH, 0);
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT, 4);
}
}
void
GLContext::TexSubImage2D(GLenum target, GLint level,
GLint xoffset, GLint yoffset,
GLsizei width, GLsizei height, GLsizei stride,
GLint pixelsize, GLenum format,
GLenum type, const GLvoid* pixels)
{
if (IsGLES2()) {
if (stride == width * pixelsize) {
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT,
std::min(GetAddressAlignment((ptrdiff_t)pixels),
GetAddressAlignment((ptrdiff_t)stride)));
fTexSubImage2D(target,
level,
xoffset,
yoffset,
width,
height,
format,
type,
pixels);
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT, 4);
} else if (IsExtensionSupported(EXT_unpack_subimage)) {
TexSubImage2DWithUnpackSubimageGLES(target, level, xoffset, yoffset,
width, height, stride,
pixelsize, format, type, pixels);
} else {
TexSubImage2DWithoutUnpackSubimage(target, level, xoffset, yoffset,
width, height, stride,
pixelsize, format, type, pixels);
}
} else {
// desktop GL (non-ES) path
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT,
std::min(GetAddressAlignment((ptrdiff_t)pixels),
GetAddressAlignment((ptrdiff_t)stride)));
int rowLength = stride/pixelsize;
fPixelStorei(LOCAL_GL_UNPACK_ROW_LENGTH, rowLength);
fTexSubImage2D(target,
level,
xoffset,
yoffset,
width,
height,
format,
type,
pixels);
fPixelStorei(LOCAL_GL_UNPACK_ROW_LENGTH, 0);
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT, 4);
}
}
void
GLContext::TexSubImage2DWithUnpackSubimageGLES(GLenum target, GLint level,
GLint xoffset, GLint yoffset,
GLsizei width, GLsizei height,
GLsizei stride, GLint pixelsize,
GLenum format, GLenum type,
const GLvoid* pixels)
{
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT,
std::min(GetAddressAlignment((ptrdiff_t)pixels),
GetAddressAlignment((ptrdiff_t)stride)));
// When using GL_UNPACK_ROW_LENGTH, we need to work around a Tegra
// driver crash where the driver apparently tries to read
// (stride - width * pixelsize) bytes past the end of the last input
// row. We only upload the first height-1 rows using GL_UNPACK_ROW_LENGTH,
// and then we upload the final row separately. See bug 697990.
int rowLength = stride/pixelsize;
fPixelStorei(LOCAL_GL_UNPACK_ROW_LENGTH, rowLength);
fTexSubImage2D(target,
level,
xoffset,
yoffset,
width,
height-1,
format,
type,
pixels);
fPixelStorei(LOCAL_GL_UNPACK_ROW_LENGTH, 0);
fTexSubImage2D(target,
level,
xoffset,
yoffset+height-1,
width,
1,
format,
type,
(const unsigned char *)pixels+(height-1)*stride);
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT, 4);
}
void
GLContext::TexSubImage2DWithoutUnpackSubimage(GLenum target, GLint level,
GLint xoffset, GLint yoffset,
GLsizei width, GLsizei height,
GLsizei stride, GLint pixelsize,
GLenum format, GLenum type,
const GLvoid* pixels)
{
// Not using the whole row of texture data and GL_UNPACK_ROW_LENGTH
// isn't supported. We make a copy of the texture data we're using,
// such that we're using the whole row of data in the copy. This turns
// out to be more efficient than uploading row-by-row; see bug 698197.
unsigned char *newPixels = new unsigned char[width*height*pixelsize];
unsigned char *rowDest = newPixels;
const unsigned char *rowSource = (const unsigned char *)pixels;
for (int h = 0; h < height; h++) {
memcpy(rowDest, rowSource, width*pixelsize);
rowDest += width*pixelsize;
rowSource += stride;
}
stride = width*pixelsize;
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT,
std::min(GetAddressAlignment((ptrdiff_t)newPixels),
GetAddressAlignment((ptrdiff_t)stride)));
fTexSubImage2D(target,
level,
xoffset,
yoffset,
width,
height,
format,
type,
newPixels);
delete [] newPixels;
fPixelStorei(LOCAL_GL_UNPACK_ALIGNMENT, 4);
}
void
GLContext::RectTriangles::addRect(GLfloat x0, GLfloat y0, GLfloat x1, GLfloat y1,
GLfloat tx0, GLfloat ty0, GLfloat tx1, GLfloat ty1,
bool flip_y /* = false */)
{
vert_coord v;
v.x = x0; v.y = y0;
vertexCoords.AppendElement(v);
v.x = x1; v.y = y0;
vertexCoords.AppendElement(v);
v.x = x0; v.y = y1;
vertexCoords.AppendElement(v);
v.x = x0; v.y = y1;
vertexCoords.AppendElement(v);
v.x = x1; v.y = y0;
vertexCoords.AppendElement(v);
v.x = x1; v.y = y1;
vertexCoords.AppendElement(v);
if (flip_y) {
tex_coord t;
t.u = tx0; t.v = ty1;
texCoords.AppendElement(t);
t.u = tx1; t.v = ty1;
texCoords.AppendElement(t);
t.u = tx0; t.v = ty0;
texCoords.AppendElement(t);
t.u = tx0; t.v = ty0;
texCoords.AppendElement(t);
t.u = tx1; t.v = ty1;
texCoords.AppendElement(t);
t.u = tx1; t.v = ty0;
texCoords.AppendElement(t);
} else {
tex_coord t;
t.u = tx0; t.v = ty0;
texCoords.AppendElement(t);
t.u = tx1; t.v = ty0;
texCoords.AppendElement(t);
t.u = tx0; t.v = ty1;
texCoords.AppendElement(t);
t.u = tx0; t.v = ty1;
texCoords.AppendElement(t);
t.u = tx1; t.v = ty0;
texCoords.AppendElement(t);
t.u = tx1; t.v = ty1;
texCoords.AppendElement(t);
}
}
static GLfloat
WrapTexCoord(GLfloat v)
{
// fmodf gives negative results for negative numbers;
// that is, fmodf(0.75, 1.0) == 0.75, but
// fmodf(-0.75, 1.0) == -0.75. For the negative case,
// the result we need is 0.25, so we add 1.0f.
if (v < 0.0f) {
return 1.0f + fmodf(v, 1.0f);
}
return fmodf(v, 1.0f);
}
void
GLContext::DecomposeIntoNoRepeatTriangles(const nsIntRect& aTexCoordRect,
const nsIntSize& aTexSize,
RectTriangles& aRects,
bool aFlipY /* = false */)
{
// normalize this
nsIntRect tcr(aTexCoordRect);
while (tcr.x >= aTexSize.width)
tcr.x -= aTexSize.width;
while (tcr.y >= aTexSize.height)
tcr.y -= aTexSize.height;
// Compute top left and bottom right tex coordinates
GLfloat tl[2] =
{ GLfloat(tcr.x) / GLfloat(aTexSize.width),
GLfloat(tcr.y) / GLfloat(aTexSize.height) };
GLfloat br[2] =
{ GLfloat(tcr.XMost()) / GLfloat(aTexSize.width),
GLfloat(tcr.YMost()) / GLfloat(aTexSize.height) };
// then check if we wrap in either the x or y axis; if we do,
// then also use fmod to figure out the "true" non-wrapping
// texture coordinates.
bool xwrap = false, ywrap = false;
if (tcr.x < 0 || tcr.x > aTexSize.width ||
tcr.XMost() < 0 || tcr.XMost() > aTexSize.width)
{
xwrap = true;
tl[0] = WrapTexCoord(tl[0]);
br[0] = WrapTexCoord(br[0]);
}
if (tcr.y < 0 || tcr.y > aTexSize.height ||
tcr.YMost() < 0 || tcr.YMost() > aTexSize.height)
{
ywrap = true;
tl[1] = WrapTexCoord(tl[1]);
br[1] = WrapTexCoord(br[1]);
}
NS_ASSERTION(tl[0] >= 0.0f && tl[0] <= 1.0f &&
tl[1] >= 0.0f && tl[1] <= 1.0f &&
br[0] >= 0.0f && br[0] <= 1.0f &&
br[1] >= 0.0f && br[1] <= 1.0f,
"Somehow generated invalid texture coordinates");
// If xwrap is false, the texture will be sampled from tl[0]
// .. br[0]. If xwrap is true, then it will be split into tl[0]
// .. 1.0, and 0.0 .. br[0]. Same for the Y axis. The
// destination rectangle is also split appropriately, according
// to the calculated xmid/ymid values.
// There isn't a 1:1 mapping between tex coords and destination coords;
// when computing midpoints, we have to take that into account. We
// need to map the texture coords, which are (in the wrap case):
// |tl->1| and |0->br| to the |0->1| range of the vertex coords. So
// we have the length (1-tl)+(br) that needs to map into 0->1.
// These are only valid if there is wrap involved, they won't be used
// otherwise.
GLfloat xlen = (1.0f - tl[0]) + br[0];
GLfloat ylen = (1.0f - tl[1]) + br[1];
NS_ASSERTION(!xwrap || xlen > 0.0f, "xlen isn't > 0, what's going on?");
NS_ASSERTION(!ywrap || ylen > 0.0f, "ylen isn't > 0, what's going on?");
NS_ASSERTION(aTexCoordRect.width <= aTexSize.width &&
aTexCoordRect.height <= aTexSize.height, "tex coord rect would cause tiling!");
if (!xwrap && !ywrap) {
aRects.addRect(0.0f, 0.0f,
1.0f, 1.0f,
tl[0], tl[1],
br[0], br[1],
aFlipY);
} else if (!xwrap && ywrap) {
GLfloat ymid = (1.0f - tl[1]) / ylen;
aRects.addRect(0.0f, 0.0f,
1.0f, ymid,
tl[0], tl[1],
br[0], 1.0f,
aFlipY);
aRects.addRect(0.0f, ymid,
1.0f, 1.0f,
tl[0], 0.0f,
br[0], br[1],
aFlipY);
} else if (xwrap && !ywrap) {
GLfloat xmid = (1.0f - tl[0]) / xlen;
aRects.addRect(0.0f, 0.0f,
xmid, 1.0f,
tl[0], tl[1],
1.0f, br[1],
aFlipY);
aRects.addRect(xmid, 0.0f,
1.0f, 1.0f,
0.0f, tl[1],
br[0], br[1],
aFlipY);
} else {
GLfloat xmid = (1.0f - tl[0]) / xlen;
GLfloat ymid = (1.0f - tl[1]) / ylen;
aRects.addRect(0.0f, 0.0f,
xmid, ymid,
tl[0], tl[1],
1.0f, 1.0f,
aFlipY);
aRects.addRect(xmid, 0.0f,
1.0f, ymid,
0.0f, tl[1],
br[0], 1.0f,
aFlipY);
aRects.addRect(0.0f, ymid,
xmid, 1.0f,
tl[0], 0.0f,
1.0f, br[1],
aFlipY);
aRects.addRect(xmid, ymid,
1.0f, 1.0f,
0.0f, 0.0f,
br[0], br[1],
aFlipY);
}
}
void
GLContext::UseBlitProgram()
{
if (mBlitProgram) {
fUseProgram(mBlitProgram);
return;
}
mBlitProgram = fCreateProgram();
GLuint shaders[2];
shaders[0] = fCreateShader(LOCAL_GL_VERTEX_SHADER);
shaders[1] = fCreateShader(LOCAL_GL_FRAGMENT_SHADER);
const char *blitVSSrc =
"attribute vec2 aVertex;"
"attribute vec2 aTexCoord;"
"varying vec2 vTexCoord;"
"void main() {"
" vTexCoord = aTexCoord;"
" gl_Position = vec4(aVertex, 0.0, 1.0);"
"}";
const char *blitFSSrc = "#ifdef GL_ES\nprecision mediump float;\n#endif\n"
"uniform sampler2D uSrcTexture;"
"varying vec2 vTexCoord;"
"void main() {"
" gl_FragColor = texture2D(uSrcTexture, vTexCoord);"
"}";
fShaderSource(shaders[0], 1, (const GLchar**) &blitVSSrc, nullptr);
fShaderSource(shaders[1], 1, (const GLchar**) &blitFSSrc, nullptr);
for (int i = 0; i < 2; ++i) {
GLint success, len = 0;
fCompileShader(shaders[i]);
fGetShaderiv(shaders[i], LOCAL_GL_COMPILE_STATUS, &success);
NS_ASSERTION(success, "Shader compilation failed!");
if (!success) {
nsAutoCString log;
fGetShaderiv(shaders[i], LOCAL_GL_INFO_LOG_LENGTH, (GLint*) &len);
log.SetCapacity(len);
fGetShaderInfoLog(shaders[i], len, (GLint*) &len, (char*) log.BeginWriting());
log.SetLength(len);
printf_stderr("Shader %d compilation failed:\n%s\n", log.get());
return;
}
fAttachShader(mBlitProgram, shaders[i]);
fDeleteShader(shaders[i]);
}
fBindAttribLocation(mBlitProgram, 0, "aVertex");
fBindAttribLocation(mBlitProgram, 1, "aTexCoord");
fLinkProgram(mBlitProgram);
GLint success, len = 0;
fGetProgramiv(mBlitProgram, LOCAL_GL_LINK_STATUS, &success);
NS_ASSERTION(success, "Shader linking failed!");
if (!success) {
nsAutoCString log;
fGetProgramiv(mBlitProgram, LOCAL_GL_INFO_LOG_LENGTH, (GLint*) &len);
log.SetCapacity(len);
fGetProgramInfoLog(mBlitProgram, len, (GLint*) &len, (char*) log.BeginWriting());
log.SetLength(len);
printf_stderr("Program linking failed:\n%s\n", log.get());
return;
}
fUseProgram(mBlitProgram);
fUniform1i(fGetUniformLocation(mBlitProgram, "uSrcTexture"), 0);
}
void
GLContext::SetBlitFramebufferForDestTexture(GLuint aTexture)
{
if (!mBlitFramebuffer) {
fGenFramebuffers(1, &mBlitFramebuffer);
}
fBindFramebuffer(LOCAL_GL_FRAMEBUFFER, mBlitFramebuffer);
fFramebufferTexture2D(LOCAL_GL_FRAMEBUFFER,
LOCAL_GL_COLOR_ATTACHMENT0,
LOCAL_GL_TEXTURE_2D,
aTexture,
0);
GLenum result = fCheckFramebufferStatus(LOCAL_GL_FRAMEBUFFER);
if (aTexture && (result != LOCAL_GL_FRAMEBUFFER_COMPLETE)) {
nsAutoCString msg;
msg.Append("Framebuffer not complete -- error 0x");
msg.AppendInt(result, 16);
// Note: if you are hitting this, it is likely that
// your texture is not texture complete -- that is, you
// allocated a texture name, but didn't actually define its
// size via a call to TexImage2D.
NS_RUNTIMEABORT(msg.get());
}
}
#ifdef DEBUG
void
GLContext::CreatedProgram(GLContext *aOrigin, GLuint aName)
{
mTrackedPrograms.AppendElement(NamedResource(aOrigin, aName));
}
void
GLContext::CreatedShader(GLContext *aOrigin, GLuint aName)
{
mTrackedShaders.AppendElement(NamedResource(aOrigin, aName));
}
void
GLContext::CreatedBuffers(GLContext *aOrigin, GLsizei aCount, GLuint *aNames)
{
for (GLsizei i = 0; i < aCount; ++i) {
mTrackedBuffers.AppendElement(NamedResource(aOrigin, aNames[i]));
}
}
void
GLContext::CreatedQueries(GLContext *aOrigin, GLsizei aCount, GLuint *aNames)
{
for (GLsizei i = 0; i < aCount; ++i) {
mTrackedQueries.AppendElement(NamedResource(aOrigin, aNames[i]));
}
}
void
GLContext::CreatedTextures(GLContext *aOrigin, GLsizei aCount, GLuint *aNames)
{
for (GLsizei i = 0; i < aCount; ++i) {
mTrackedTextures.AppendElement(NamedResource(aOrigin, aNames[i]));
}
}
void
GLContext::CreatedFramebuffers(GLContext *aOrigin, GLsizei aCount, GLuint *aNames)
{
for (GLsizei i = 0; i < aCount; ++i) {
mTrackedFramebuffers.AppendElement(NamedResource(aOrigin, aNames[i]));
}
}
void
GLContext::CreatedRenderbuffers(GLContext *aOrigin, GLsizei aCount, GLuint *aNames)
{
for (GLsizei i = 0; i < aCount; ++i) {
mTrackedRenderbuffers.AppendElement(NamedResource(aOrigin, aNames[i]));
}
}
static void
RemoveNamesFromArray(GLContext *aOrigin, GLsizei aCount, const GLuint *aNames, nsTArray<GLContext::NamedResource>& aArray)
{
for (GLsizei j = 0; j < aCount; ++j) {
GLuint name = aNames[j];
// name 0 can be ignored
if (name == 0)
continue;
for (uint32_t i = 0; i < aArray.Length(); ++i) {
if (aArray[i].name == name) {
aArray.RemoveElementAt(i);
break;
}
}
}
}
void
GLContext::DeletedProgram(GLContext *aOrigin, GLuint aName)
{
RemoveNamesFromArray(aOrigin, 1, &aName, mTrackedPrograms);
}
void
GLContext::DeletedShader(GLContext *aOrigin, GLuint aName)
{
RemoveNamesFromArray(aOrigin, 1, &aName, mTrackedShaders);
}
void
GLContext::DeletedBuffers(GLContext *aOrigin, GLsizei aCount, GLuint *aNames)
{
RemoveNamesFromArray(aOrigin, aCount, aNames, mTrackedBuffers);
}
void
GLContext::DeletedQueries(GLContext *aOrigin, GLsizei aCount, const GLuint *aNames)
{
RemoveNamesFromArray(aOrigin, aCount, aNames, mTrackedQueries);
}
void
GLContext::DeletedTextures(GLContext *aOrigin, GLsizei aCount, GLuint *aNames)
{
RemoveNamesFromArray(aOrigin, aCount, aNames, mTrackedTextures);
}
void
GLContext::DeletedFramebuffers(GLContext *aOrigin, GLsizei aCount, GLuint *aNames)
{
RemoveNamesFromArray(aOrigin, aCount, aNames, mTrackedFramebuffers);
}
void
GLContext::DeletedRenderbuffers(GLContext *aOrigin, GLsizei aCount, GLuint *aNames)
{
RemoveNamesFromArray(aOrigin, aCount, aNames, mTrackedRenderbuffers);
}
static void
MarkContextDestroyedInArray(GLContext *aContext, nsTArray<GLContext::NamedResource>& aArray)
{
for (uint32_t i = 0; i < aArray.Length(); ++i) {
if (aArray[i].origin == aContext)
aArray[i].originDeleted = true;
}
}
void
GLContext::SharedContextDestroyed(GLContext *aChild)
{
MarkContextDestroyedInArray(aChild, mTrackedPrograms);
MarkContextDestroyedInArray(aChild, mTrackedShaders);
MarkContextDestroyedInArray(aChild, mTrackedTextures);
MarkContextDestroyedInArray(aChild, mTrackedFramebuffers);
MarkContextDestroyedInArray(aChild, mTrackedRenderbuffers);
MarkContextDestroyedInArray(aChild, mTrackedBuffers);
MarkContextDestroyedInArray(aChild, mTrackedQueries);
}
static void
ReportArrayContents(const char *title, const nsTArray<GLContext::NamedResource>& aArray)
{
if (aArray.Length() == 0)
return;
printf_stderr("%s:\n", title);
nsTArray<GLContext::NamedResource> copy(aArray);
copy.Sort();
GLContext *lastContext = nullptr;
for (uint32_t i = 0; i < copy.Length(); ++i) {
if (lastContext != copy[i].origin) {
if (lastContext)
printf_stderr("\n");
printf_stderr(" [%p - %s] ", copy[i].origin, copy[i].originDeleted ? "deleted" : "live");
lastContext = copy[i].origin;
}
printf_stderr("%d ", copy[i].name);
}
printf_stderr("\n");
}
void
GLContext::ReportOutstandingNames()
{
if (!DebugMode())
return;
printf_stderr("== GLContext %p Outstanding ==\n", this);
ReportArrayContents("Outstanding Textures", mTrackedTextures);
ReportArrayContents("Outstanding Buffers", mTrackedBuffers);
ReportArrayContents("Outstanding Queries", mTrackedQueries);
ReportArrayContents("Outstanding Programs", mTrackedPrograms);
ReportArrayContents("Outstanding Shaders", mTrackedShaders);
ReportArrayContents("Outstanding Framebuffers", mTrackedFramebuffers);
ReportArrayContents("Outstanding Renderbuffers", mTrackedRenderbuffers);
}
#endif /* DEBUG */
void
GLContext::GuaranteeResolve()
{
if (mScreen) {
mScreen->AssureBlitted();
}
fFinish();
}
const gfxIntSize&
GLContext::OffscreenSize() const
{
MOZ_ASSERT(IsOffscreen());
return mScreen->Size();
}
bool
GLContext::CreateScreenBufferImpl(const gfxIntSize& size, const SurfaceCaps& caps)
{
GLScreenBuffer* newScreen = GLScreenBuffer::Create(this, size, caps);
if (!newScreen)
return false;
if (!newScreen->Resize(size)) {
delete newScreen;
return false;
}
DestroyScreenBuffer();
// This will rebind to 0 (Screen) if needed when
// it falls out of scope.
ScopedBindFramebuffer autoFB(this);
mScreen = newScreen;
return true;
}
bool
GLContext::ResizeScreenBuffer(const gfxIntSize& size)
{
if (!IsOffscreenSizeAllowed(size))
return false;
return mScreen->Resize(size);
}
void
GLContext::DestroyScreenBuffer()
{
delete mScreen;
mScreen = nullptr;
}
void
GLContext::ForceDirtyScreen()
{
ScopedBindFramebuffer autoFB(0);
BeforeGLDrawCall();
// no-op; just pretend we did something
AfterGLDrawCall();
}
void
GLContext::CleanDirtyScreen()
{
ScopedBindFramebuffer autoFB(0);
BeforeGLReadCall();
// no-op; we just want to make sure the Read FBO is updated if it needs to be
AfterGLReadCall();
}
void
GLContext::EmptyTexGarbageBin()
{
TexGarbageBin()->EmptyGarbage();
}
bool
GLContext::IsOffscreenSizeAllowed(const gfxIntSize& aSize) const {
int32_t biggerDimension = std::max(aSize.width, aSize.height);
int32_t maxAllowed = std::min(mMaxRenderbufferSize, mMaxTextureSize);
return biggerDimension <= maxAllowed;
}
bool
GLContext::IsOwningThreadCurrent()
{
return NS_GetCurrentThread() == mOwningThread;
}
void
GLContext::DispatchToOwningThread(nsIRunnable *event)
{
// Before dispatching, we need to ensure we're not in the middle of
// shutting down. Dispatching runnables in the middle of shutdown
// (that is, when the main thread is no longer get-able) can cause them
// to leak. See Bug 741319, and Bug 744115.
nsCOMPtr<nsIThread> mainThread;
if (NS_SUCCEEDED(NS_GetMainThread(getter_AddRefs(mainThread)))) {
mOwningThread->Dispatch(event, NS_DISPATCH_NORMAL);
}
}
bool
DoesStringMatch(const char* aString, const char *aWantedString)
{
if (!aString || !aWantedString)
return false;
const char *occurrence = strstr(aString, aWantedString);
// aWanted not found
if (!occurrence)
return false;
// aWantedString preceded by alpha character
if (occurrence != aString && isalpha(*(occurrence-1)))
return false;
// aWantedVendor followed by alpha character
const char *afterOccurrence = occurrence + strlen(aWantedString);
if (isalpha(*afterOccurrence))
return false;
return true;
}
} /* namespace gl */
} /* namespace mozilla */