/* * Copyright (C) 2011 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "GL2Encoder.h" #include #include #include #ifndef MIN #define MIN(a, b) ((a) < (b) ? (a) : (b)) #endif static GLubyte *gVendorString= (GLubyte *) "Android"; static GLubyte *gRendererString= (GLubyte *) "Android HW-GLES 2.0"; static GLubyte *gVersionString= (GLubyte *) "OpenGL ES 2.0"; static GLubyte *gExtensionsString= (GLubyte *) "GL_OES_EGL_image_external "; #define SET_ERROR_IF(condition,err) if((condition)) { \ ALOGE("%s:%s:%d GL error 0x%x\n", __FILE__, __FUNCTION__, __LINE__, err); \ ctx->setError(err); \ return; \ } #define RET_AND_SET_ERROR_IF(condition,err,ret) if((condition)) { \ ALOGE("%s:%s:%d GL error 0x%x\n", __FILE__, __FUNCTION__, __LINE__, err); \ ctx->setError(err); \ return ret; \ } GL2Encoder::GL2Encoder(IOStream *stream, ChecksumCalculator *protocol) : gl2_encoder_context_t(stream, protocol) { m_initialized = false; m_state = NULL; m_error = GL_NO_ERROR; m_num_compressedTextureFormats = 0; m_max_cubeMapTextureSize = 0; m_max_renderBufferSize = 0; m_max_textureSize = 0; m_compressedTextureFormats = NULL; //overrides #define OVERRIDE(name) m_##name##_enc = this-> name ; this-> name = &s_##name OVERRIDE(glFlush); OVERRIDE(glPixelStorei); OVERRIDE(glGetString); OVERRIDE(glBindBuffer); OVERRIDE(glBufferData); OVERRIDE(glBufferSubData); OVERRIDE(glDeleteBuffers); OVERRIDE(glDrawArrays); OVERRIDE(glDrawElements); OVERRIDE(glGetIntegerv); OVERRIDE(glGetFloatv); OVERRIDE(glGetBooleanv); OVERRIDE(glVertexAttribPointer); OVERRIDE(glEnableVertexAttribArray); OVERRIDE(glDisableVertexAttribArray); OVERRIDE(glGetVertexAttribiv); OVERRIDE(glGetVertexAttribfv); OVERRIDE(glGetVertexAttribPointerv); this->glShaderBinary = &s_glShaderBinary; this->glShaderSource = &s_glShaderSource; this->glFinish = &s_glFinish; OVERRIDE(glGetError); OVERRIDE(glLinkProgram); OVERRIDE(glDeleteProgram); OVERRIDE(glGetUniformiv); OVERRIDE(glGetUniformfv); OVERRIDE(glCreateProgram); OVERRIDE(glCreateShader); OVERRIDE(glDeleteShader); OVERRIDE(glAttachShader); OVERRIDE(glDetachShader); OVERRIDE(glGetAttachedShaders); OVERRIDE(glGetShaderSource); OVERRIDE(glGetShaderInfoLog); OVERRIDE(glGetProgramInfoLog); OVERRIDE(glGetUniformLocation); OVERRIDE(glUseProgram); OVERRIDE(glUniform1f); OVERRIDE(glUniform1fv); OVERRIDE(glUniform1i); OVERRIDE(glUniform1iv); OVERRIDE(glUniform2f); OVERRIDE(glUniform2fv); OVERRIDE(glUniform2i); OVERRIDE(glUniform2iv); OVERRIDE(glUniform3f); OVERRIDE(glUniform3fv); OVERRIDE(glUniform3i); OVERRIDE(glUniform3iv); OVERRIDE(glUniform4f); OVERRIDE(glUniform4fv); OVERRIDE(glUniform4i); OVERRIDE(glUniform4iv); OVERRIDE(glUniformMatrix2fv); OVERRIDE(glUniformMatrix3fv); OVERRIDE(glUniformMatrix4fv); OVERRIDE(glActiveTexture); OVERRIDE(glBindTexture); OVERRIDE(glDeleteTextures); OVERRIDE(glGetTexParameterfv); OVERRIDE(glGetTexParameteriv); OVERRIDE(glTexParameterf); OVERRIDE(glTexParameterfv); OVERRIDE(glTexParameteri); OVERRIDE(glTexParameteriv); OVERRIDE(glTexImage2D); OVERRIDE(glTexSubImage2D); } GL2Encoder::~GL2Encoder() { delete m_compressedTextureFormats; } GLenum GL2Encoder::s_glGetError(void * self) { GL2Encoder *ctx = (GL2Encoder *)self; GLenum err = ctx->getError(); if(err != GL_NO_ERROR) { ctx->setError(GL_NO_ERROR); return err; } return ctx->m_glGetError_enc(self); } void GL2Encoder::s_glFlush(void *self) { GL2Encoder *ctx = (GL2Encoder *) self; ctx->m_glFlush_enc(self); ctx->m_stream->flush(); } const GLubyte *GL2Encoder::s_glGetString(void *self, GLenum name) { (void)self; GLubyte *retval = (GLubyte *) ""; switch(name) { case GL_VENDOR: retval = gVendorString; break; case GL_RENDERER: retval = gRendererString; break; case GL_VERSION: retval = gVersionString; break; case GL_EXTENSIONS: retval = gExtensionsString; break; } return retval; } void GL2Encoder::s_glPixelStorei(void *self, GLenum param, GLint value) { GL2Encoder *ctx = (GL2Encoder *)self; ctx->m_glPixelStorei_enc(ctx, param, value); assert(ctx->m_state != NULL); ctx->m_state->setPixelStore(param, value); } void GL2Encoder::s_glBindBuffer(void *self, GLenum target, GLuint id) { GL2Encoder *ctx = (GL2Encoder *) self; assert(ctx->m_state != NULL); ctx->m_state->bindBuffer(target, id); // TODO set error state if needed; ctx->m_glBindBuffer_enc(self, target, id); } void GL2Encoder::s_glBufferData(void * self, GLenum target, GLsizeiptr size, const GLvoid * data, GLenum usage) { GL2Encoder *ctx = (GL2Encoder *) self; SET_ERROR_IF(!(target == GL_ARRAY_BUFFER || target == GL_ELEMENT_ARRAY_BUFFER), GL_INVALID_ENUM); GLuint bufferId = ctx->m_state->getBuffer(target); SET_ERROR_IF(bufferId==0, GL_INVALID_OPERATION); SET_ERROR_IF(size<0, GL_INVALID_VALUE); ctx->m_shared->updateBufferData(bufferId, size, (void*)data); ctx->m_glBufferData_enc(self, target, size, data, usage); } void GL2Encoder::s_glBufferSubData(void * self, GLenum target, GLintptr offset, GLsizeiptr size, const GLvoid * data) { GL2Encoder *ctx = (GL2Encoder *) self; SET_ERROR_IF(!(target == GL_ARRAY_BUFFER || target == GL_ELEMENT_ARRAY_BUFFER), GL_INVALID_ENUM); GLuint bufferId = ctx->m_state->getBuffer(target); SET_ERROR_IF(bufferId==0, GL_INVALID_OPERATION); GLenum res = ctx->m_shared->subUpdateBufferData(bufferId, offset, size, (void*)data); SET_ERROR_IF(res, res); ctx->m_glBufferSubData_enc(self, target, offset, size, data); } void GL2Encoder::s_glDeleteBuffers(void * self, GLsizei n, const GLuint * buffers) { GL2Encoder *ctx = (GL2Encoder *) self; SET_ERROR_IF(n<0, GL_INVALID_VALUE); for (int i=0; im_shared->deleteBufferData(buffers[i]); ctx->m_state->unBindBuffer(buffers[i]); ctx->m_glDeleteBuffers_enc(self,1,&buffers[i]); } } void GL2Encoder::s_glVertexAttribPointer(void *self, GLuint indx, GLint size, GLenum type, GLboolean normalized, GLsizei stride, const GLvoid * ptr) { GL2Encoder *ctx = (GL2Encoder *)self; assert(ctx->m_state != NULL); ctx->m_state->setState(indx, size, type, normalized, stride, ptr); } void GL2Encoder::s_glGetIntegerv(void *self, GLenum param, GLint *ptr) { GL2Encoder *ctx = (GL2Encoder *) self; assert(ctx->m_state != NULL); GLClientState* state = ctx->m_state; switch (param) { case GL_NUM_SHADER_BINARY_FORMATS: *ptr = 0; break; case GL_SHADER_BINARY_FORMATS: // do nothing break; case GL_COMPRESSED_TEXTURE_FORMATS: { GLint *compressedTextureFormats = ctx->getCompressedTextureFormats(); if (ctx->m_num_compressedTextureFormats > 0 && compressedTextureFormats != NULL) { memcpy(ptr, compressedTextureFormats, ctx->m_num_compressedTextureFormats * sizeof(GLint)); } break; } case GL_MAX_COMBINED_TEXTURE_IMAGE_UNITS: case GL_MAX_VERTEX_TEXTURE_IMAGE_UNITS: case GL_MAX_TEXTURE_IMAGE_UNITS: ctx->m_glGetIntegerv_enc(self, param, ptr); *ptr = MIN(*ptr, GLClientState::MAX_TEXTURE_UNITS); break; case GL_TEXTURE_BINDING_2D: *ptr = state->getBoundTexture(GL_TEXTURE_2D); break; case GL_TEXTURE_BINDING_EXTERNAL_OES: *ptr = state->getBoundTexture(GL_TEXTURE_EXTERNAL_OES); break; case GL_MAX_CUBE_MAP_TEXTURE_SIZE: if (ctx->m_max_cubeMapTextureSize != 0) { *ptr = ctx->m_max_cubeMapTextureSize; } else { ctx->m_glGetIntegerv_enc(self, param, ptr); ctx->m_max_cubeMapTextureSize = *ptr; } break; case GL_MAX_RENDERBUFFER_SIZE: if (ctx->m_max_renderBufferSize != 0) { *ptr = ctx->m_max_renderBufferSize; } else { ctx->m_glGetIntegerv_enc(self, param, ptr); ctx->m_max_renderBufferSize = *ptr; } break; case GL_MAX_TEXTURE_SIZE: if (ctx->m_max_textureSize != 0) { *ptr = ctx->m_max_textureSize; } else { ctx->m_glGetIntegerv_enc(self, param, ptr); ctx->m_max_textureSize = *ptr; } break; case GL_MAX_VERTEX_ATTRIBS: if (!ctx->m_state->getClientStateParameter(param, ptr)) { ctx->m_glGetIntegerv_enc(self, param, ptr); ctx->m_state->setMaxVertexAttribs(*ptr); } break; default: if (!ctx->m_state->getClientStateParameter(param, ptr)) { ctx->m_glGetIntegerv_enc(self, param, ptr); } break; } } void GL2Encoder::s_glGetFloatv(void *self, GLenum param, GLfloat *ptr) { GL2Encoder *ctx = (GL2Encoder *)self; assert(ctx->m_state != NULL); GLClientState* state = ctx->m_state; switch (param) { case GL_NUM_SHADER_BINARY_FORMATS: *ptr = 0; break; case GL_SHADER_BINARY_FORMATS: // do nothing break; case GL_COMPRESSED_TEXTURE_FORMATS: { GLint *compressedTextureFormats = ctx->getCompressedTextureFormats(); if (ctx->m_num_compressedTextureFormats > 0 && compressedTextureFormats != NULL) { for (int i = 0; i < ctx->m_num_compressedTextureFormats; i++) { ptr[i] = (GLfloat) compressedTextureFormats[i]; } } break; } case GL_MAX_COMBINED_TEXTURE_IMAGE_UNITS: case GL_MAX_VERTEX_TEXTURE_IMAGE_UNITS: case GL_MAX_TEXTURE_IMAGE_UNITS: ctx->m_glGetFloatv_enc(self, param, ptr); *ptr = MIN(*ptr, (GLfloat)GLClientState::MAX_TEXTURE_UNITS); break; case GL_TEXTURE_BINDING_2D: *ptr = (GLfloat)state->getBoundTexture(GL_TEXTURE_2D); break; case GL_TEXTURE_BINDING_EXTERNAL_OES: *ptr = (GLfloat)state->getBoundTexture(GL_TEXTURE_EXTERNAL_OES); break; default: if (!ctx->m_state->getClientStateParameter(param, ptr)) { ctx->m_glGetFloatv_enc(self, param, ptr); } break; } } void GL2Encoder::s_glGetBooleanv(void *self, GLenum param, GLboolean *ptr) { GL2Encoder *ctx = (GL2Encoder *)self; assert(ctx->m_state != NULL); GLClientState* state = ctx->m_state; switch (param) { case GL_NUM_SHADER_BINARY_FORMATS: *ptr = GL_FALSE; break; case GL_SHADER_BINARY_FORMATS: // do nothing break; case GL_COMPRESSED_TEXTURE_FORMATS: { GLint *compressedTextureFormats = ctx->getCompressedTextureFormats(); if (ctx->m_num_compressedTextureFormats > 0 && compressedTextureFormats != NULL) { for (int i = 0; i < ctx->m_num_compressedTextureFormats; i++) { ptr[i] = compressedTextureFormats[i] != 0 ? GL_TRUE : GL_FALSE; } } break; } case GL_TEXTURE_BINDING_2D: *ptr = state->getBoundTexture(GL_TEXTURE_2D) != 0 ? GL_TRUE : GL_FALSE; break; case GL_TEXTURE_BINDING_EXTERNAL_OES: *ptr = state->getBoundTexture(GL_TEXTURE_EXTERNAL_OES) != 0 ? GL_TRUE : GL_FALSE; break; default: if (!ctx->m_state->getClientStateParameter(param, ptr)) { ctx->m_glGetBooleanv_enc(self, param, ptr); } *ptr = (*ptr != 0) ? GL_TRUE : GL_FALSE; break; } } void GL2Encoder::s_glEnableVertexAttribArray(void *self, GLuint index) { GL2Encoder *ctx = (GL2Encoder *)self; assert(ctx->m_state); GLint maxIndex; ctx->glGetIntegerv(self, GL_MAX_VERTEX_ATTRIBS, &maxIndex); SET_ERROR_IF(!(index < maxIndex), GL_INVALID_VALUE); ctx->m_state->enable(index, 1); } void GL2Encoder::s_glDisableVertexAttribArray(void *self, GLuint index) { GL2Encoder *ctx = (GL2Encoder *)self; assert(ctx->m_state); GLint maxIndex; ctx->glGetIntegerv(self, GL_MAX_VERTEX_ATTRIBS, &maxIndex); SET_ERROR_IF(!(index < maxIndex), GL_INVALID_VALUE); ctx->m_state->enable(index, 0); } void GL2Encoder::s_glGetVertexAttribiv(void *self, GLuint index, GLenum pname, GLint *params) { GL2Encoder *ctx = (GL2Encoder *)self; assert(ctx->m_state); GLint maxIndex; ctx->glGetIntegerv(self, GL_MAX_VERTEX_ATTRIBS, &maxIndex); SET_ERROR_IF(!(index < maxIndex), GL_INVALID_VALUE); if (!ctx->m_state->getVertexAttribParameter(index, pname, params)) { ctx->m_glGetVertexAttribiv_enc(self, index, pname, params); } } void GL2Encoder::s_glGetVertexAttribfv(void *self, GLuint index, GLenum pname, GLfloat *params) { GL2Encoder *ctx = (GL2Encoder *)self; assert(ctx->m_state); GLint maxIndex; ctx->glGetIntegerv(self, GL_MAX_VERTEX_ATTRIBS, &maxIndex); SET_ERROR_IF(!(index < maxIndex), GL_INVALID_VALUE); if (!ctx->m_state->getVertexAttribParameter(index, pname, params)) { ctx->m_glGetVertexAttribfv_enc(self, index, pname, params); } } void GL2Encoder::s_glGetVertexAttribPointerv(void *self, GLuint index, GLenum pname, GLvoid **pointer) { GL2Encoder *ctx = (GL2Encoder *)self; if (ctx->m_state == NULL) return; GLint maxIndex; ctx->glGetIntegerv(self, GL_MAX_VERTEX_ATTRIBS, &maxIndex); SET_ERROR_IF(!(index < maxIndex), GL_INVALID_VALUE); SET_ERROR_IF(pname != GL_VERTEX_ATTRIB_ARRAY_POINTER, GL_INVALID_ENUM); (void)pname; const GLClientState::VertexAttribState *va_state = ctx->m_state->getState(index); if (va_state != NULL) { *pointer = va_state->data; } } void GL2Encoder::sendVertexAttributes(GLint first, GLsizei count) { assert(m_state); for (int i = 0; i < m_state->nLocations(); i++) { bool enableDirty; const GLClientState::VertexAttribState *state = m_state->getStateAndEnableDirty(i, &enableDirty); if (!state) { continue; } if (!enableDirty && !state->enabled) { continue; } if (state->enabled) { m_glEnableVertexAttribArray_enc(this, i); unsigned int datalen = state->elementSize * count; int stride = state->stride == 0 ? state->elementSize : state->stride; int firstIndex = stride * first; this->m_glBindBuffer_enc(this, GL_ARRAY_BUFFER, state->bufferObject); if (state->bufferObject == 0) { this->glVertexAttribPointerData(this, i, state->size, state->type, state->normalized, state->stride, (unsigned char *)state->data + firstIndex, datalen); } else { this->glVertexAttribPointerOffset(this, i, state->size, state->type, state->normalized, state->stride, (uintptr_t) state->data + firstIndex); } this->m_glBindBuffer_enc(this, GL_ARRAY_BUFFER, m_state->currentArrayVbo()); } else { this->m_glDisableVertexAttribArray_enc(this, i); } } } static bool isValidDrawMode(GLenum mode) { switch(mode) { case GL_POINTS: case GL_LINE_STRIP: case GL_LINE_LOOP: case GL_LINES: case GL_TRIANGLE_STRIP: case GL_TRIANGLE_FAN: case GL_TRIANGLES: return true; } return false; } static bool isValidDrawType(GLenum mode) { return mode == GL_UNSIGNED_BYTE || mode == GL_UNSIGNED_SHORT || mode == GL_UNSIGNED_INT; } void GL2Encoder::s_glDrawArrays(void *self, GLenum mode, GLint first, GLsizei count) { GL2Encoder *ctx = (GL2Encoder *)self; SET_ERROR_IF(!isValidDrawMode(mode), GL_INVALID_ENUM); SET_ERROR_IF(count<0, GL_INVALID_VALUE); bool has_arrays = false; int nLocations = ctx->m_state->nLocations(); for (int i = 0; i < nLocations; i++) { const GLClientState::VertexAttribState *state = ctx->m_state->getState(i); if (state->enabled) { if (state->bufferObject || state->data) { has_arrays = true; } else { ALOGE("glDrawArrays: a vertex attribute array is enabled with no data bound\n"); ctx->setError(GL_INVALID_OPERATION); return; } } } if (!has_arrays) { ALOGE("glDrawArrays: no data bound to the command - ignoring\n"); return; } ctx->sendVertexAttributes(first, count); ctx->m_glDrawArrays_enc(ctx, mode, 0, count); } void GL2Encoder::s_glDrawElements(void *self, GLenum mode, GLsizei count, GLenum type, const void *indices) { GL2Encoder *ctx = (GL2Encoder *)self; assert(ctx->m_state != NULL); SET_ERROR_IF(!(isValidDrawMode(mode) && isValidDrawType(type)),GL_INVALID_ENUM); SET_ERROR_IF(count<0, GL_INVALID_VALUE); bool has_immediate_arrays = false; bool has_indirect_arrays = false; int nLocations = ctx->m_state->nLocations(); for (int i = 0; i < nLocations; i++) { const GLClientState::VertexAttribState *state = ctx->m_state->getState(i); if (state->enabled) { if (state->bufferObject != 0) { has_indirect_arrays = true; } else if (state->data) { has_immediate_arrays = true; } else { ALOGW("glDrawElements: a vertex attribute array is enabled with no data bound\n"); ctx->setError(GL_INVALID_OPERATION); return; } } } if (!has_immediate_arrays && !has_indirect_arrays) { ALOGE("glDrawElements: no data bound to the command - ignoring\n"); return; } bool adjustIndices = true; if (ctx->m_state->currentIndexVbo() != 0) { if (!has_immediate_arrays) { ctx->sendVertexAttributes(0, count); ctx->m_glBindBuffer_enc(self, GL_ELEMENT_ARRAY_BUFFER, ctx->m_state->currentIndexVbo()); ctx->glDrawElementsOffset(ctx, mode, count, type, (uintptr_t)indices); adjustIndices = false; } else { BufferData * buf = ctx->m_shared->getBufferData(ctx->m_state->currentIndexVbo()); ctx->m_glBindBuffer_enc(self, GL_ELEMENT_ARRAY_BUFFER, 0); indices = (void*)((GLintptr)buf->m_fixedBuffer.ptr() + (GLintptr)indices); } } if (adjustIndices) { void *adjustedIndices = (void*)indices; int minIndex = 0, maxIndex = 0; switch(type) { case GL_BYTE: case GL_UNSIGNED_BYTE: GLUtils::minmax((unsigned char *)indices, count, &minIndex, &maxIndex); if (minIndex != 0) { adjustedIndices = ctx->m_fixedBuffer.alloc(glSizeof(type) * count); GLUtils::shiftIndices((unsigned char *)indices, (unsigned char *)adjustedIndices, count, -minIndex); } break; case GL_SHORT: case GL_UNSIGNED_SHORT: GLUtils::minmax((unsigned short *)indices, count, &minIndex, &maxIndex); if (minIndex != 0) { adjustedIndices = ctx->m_fixedBuffer.alloc(glSizeof(type) * count); GLUtils::shiftIndices((unsigned short *)indices, (unsigned short *)adjustedIndices, count, -minIndex); } break; case GL_INT: case GL_UNSIGNED_INT: GLUtils::minmax((unsigned int *)indices, count, &minIndex, &maxIndex); if (minIndex != 0) { adjustedIndices = ctx->m_fixedBuffer.alloc(glSizeof(type) * count); GLUtils::shiftIndices((unsigned int *)indices, (unsigned int *)adjustedIndices, count, -minIndex); } break; default: ALOGE("unsupported index buffer type %d\n", type); } if (has_indirect_arrays || 1) { ctx->sendVertexAttributes(minIndex, maxIndex - minIndex + 1); ctx->glDrawElementsData(ctx, mode, count, type, adjustedIndices, count * glSizeof(type)); // XXX - OPTIMIZATION (see the other else branch) should be implemented if(!has_indirect_arrays) { //ALOGD("unoptimized drawelements !!!\n"); } } else { // we are all direct arrays and immidate mode index array - // rebuild the arrays and the index array; ALOGE("glDrawElements: direct index & direct buffer data - will be implemented in later versions;\n"); } } } GLint * GL2Encoder::getCompressedTextureFormats() { if (m_compressedTextureFormats == NULL) { this->glGetIntegerv(this, GL_NUM_COMPRESSED_TEXTURE_FORMATS, &m_num_compressedTextureFormats); if (m_num_compressedTextureFormats > 0) { // get number of texture formats; m_compressedTextureFormats = new GLint[m_num_compressedTextureFormats]; this->glGetCompressedTextureFormats(this, m_num_compressedTextureFormats, m_compressedTextureFormats); } } return m_compressedTextureFormats; } // Replace uses of samplerExternalOES with sampler2D, recording the names of // modified shaders in data. Also remove // #extension GL_OES_EGL_image_external : require // statements. // // This implementation assumes the input has already been pre-processed. If not, // a few cases will be mishandled: // // 1. "mySampler" will be incorrectly recorded as being a samplerExternalOES in // the following code: // #if 1 // uniform sampler2D mySampler; // #else // uniform samplerExternalOES mySampler; // #endif // // 2. Comments that look like sampler declarations will be incorrectly modified // and recorded: // // samplerExternalOES hahaFooledYou // // 3. However, GLSL ES does not have a concatentation operator, so things like // this (valid in C) are invalid and not a problem: // #define SAMPLER(TYPE, NAME) uniform sampler#TYPE NAME // SAMPLER(ExternalOES, mySampler); // static bool replaceSamplerExternalWith2D(char* const str, ShaderData* const data) { static const char STR_HASH_EXTENSION[] = "#extension"; static const char STR_GL_OES_EGL_IMAGE_EXTERNAL[] = "GL_OES_EGL_image_external"; static const char STR_SAMPLER_EXTERNAL_OES[] = "samplerExternalOES"; static const char STR_SAMPLER2D_SPACE[] = "sampler2D "; // -- overwrite all "#extension GL_OES_EGL_image_external : xxx" statements char* c = str; while ((c = strstr(c, STR_HASH_EXTENSION))) { char* start = c; c += sizeof(STR_HASH_EXTENSION)-1; while (isspace(*c) && *c != '\0') { c++; } if (strncmp(c, STR_GL_OES_EGL_IMAGE_EXTERNAL, sizeof(STR_GL_OES_EGL_IMAGE_EXTERNAL)-1) == 0) { // #extension statements are terminated by end of line c = start; while (*c != '\0' && *c != '\r' && *c != '\n') { *c++ = ' '; } } } // -- replace "samplerExternalOES" with "sampler2D" and record name c = str; while ((c = strstr(c, STR_SAMPLER_EXTERNAL_OES))) { // Make sure "samplerExternalOES" isn't a substring of a larger token if (c == str || !isspace(*(c-1))) { c++; continue; } char* sampler_start = c; c += sizeof(STR_SAMPLER_EXTERNAL_OES)-1; if (!isspace(*c) && *c != '\0') { continue; } // capture sampler name while (isspace(*c) && *c != '\0') { c++; } if (!isalpha(*c) && *c != '_') { // not an identifier return false; } char* name_start = c; do { c++; } while (isalnum(*c) || *c == '_'); data->samplerExternalNames.push_back( android::String8(name_start, c - name_start)); // memcpy instead of strcpy since we don't want the NUL terminator memcpy(sampler_start, STR_SAMPLER2D_SPACE, sizeof(STR_SAMPLER2D_SPACE)-1); } return true; } void GL2Encoder::s_glShaderBinary(void *self, GLsizei n, const GLuint *shaders, GLenum binaryformat, const void* binary, GLsizei length) { GL2Encoder* ctx = (GL2Encoder*)self; // Although it is not supported, need to set proper error code. SET_ERROR_IF(1, GL_INVALID_ENUM); } void GL2Encoder::s_glShaderSource(void *self, GLuint shader, GLsizei count, const GLchar * const *string, const GLint *length) { GL2Encoder* ctx = (GL2Encoder*)self; ShaderData* shaderData = ctx->m_shared->getShaderData(shader); SET_ERROR_IF(!ctx->m_shared->isObject(shader), GL_INVALID_VALUE); SET_ERROR_IF(!shaderData, GL_INVALID_OPERATION); SET_ERROR_IF((count<0), GL_INVALID_VALUE); int len = glUtilsCalcShaderSourceLen((char**)string, (GLint*)length, count); char *str = new char[len + 1]; glUtilsPackStrings(str, (char**)string, (GLint*)length, count); // TODO: pre-process str before calling replaceSamplerExternalWith2D(). // Perhaps we can borrow Mesa's pre-processor? if (!replaceSamplerExternalWith2D(str, shaderData)) { delete str; ctx->setError(GL_OUT_OF_MEMORY); return; } ctx->glShaderString(ctx, shader, str, len + 1); delete str; } void GL2Encoder::s_glFinish(void *self) { GL2Encoder *ctx = (GL2Encoder *)self; ctx->glFinishRoundTrip(self); } void GL2Encoder::s_glLinkProgram(void * self, GLuint program) { GL2Encoder *ctx = (GL2Encoder *)self; ctx->m_glLinkProgram_enc(self, program); GLint linkStatus = 0; ctx->glGetProgramiv(self,program,GL_LINK_STATUS,&linkStatus); if (!linkStatus) return; //get number of active uniforms in the program GLint numUniforms=0; ctx->glGetProgramiv(self, program, GL_ACTIVE_UNIFORMS, &numUniforms); ctx->m_shared->initProgramData(program,numUniforms); //get the length of the longest uniform name GLint maxLength=0; ctx->glGetProgramiv(self, program, GL_ACTIVE_UNIFORM_MAX_LENGTH, &maxLength); GLint size; GLenum type; GLchar *name = new GLchar[maxLength+1]; GLint location; //for each active uniform, get its size and starting location. for (GLint i=0 ; iglGetActiveUniform(self, program, i, maxLength, NULL, &size, &type, name); location = ctx->m_glGetUniformLocation_enc(self, program, name); ctx->m_shared->setProgramIndexInfo(program, i, location, size, type, name); } ctx->m_shared->setupLocationShiftWAR(program); delete[] name; } void GL2Encoder::s_glDeleteProgram(void *self, GLuint program) { GL2Encoder *ctx = (GL2Encoder*)self; ctx->m_glDeleteProgram_enc(self, program); ctx->m_shared->deleteProgramData(program); } void GL2Encoder::s_glGetUniformiv(void *self, GLuint program, GLint location, GLint* params) { GL2Encoder *ctx = (GL2Encoder*)self; SET_ERROR_IF(!ctx->m_shared->isObject(program), GL_INVALID_VALUE); SET_ERROR_IF(!ctx->m_shared->isProgram(program), GL_INVALID_OPERATION); SET_ERROR_IF(!ctx->m_shared->isProgramInitialized(program), GL_INVALID_OPERATION); GLint hostLoc = ctx->m_shared->locationWARAppToHost(program, location); SET_ERROR_IF(ctx->m_shared->getProgramUniformType(program,hostLoc)==0, GL_INVALID_OPERATION); ctx->m_glGetUniformiv_enc(self, program, hostLoc, params); } void GL2Encoder::s_glGetUniformfv(void *self, GLuint program, GLint location, GLfloat* params) { GL2Encoder *ctx = (GL2Encoder*)self; SET_ERROR_IF(!ctx->m_shared->isObject(program), GL_INVALID_VALUE); SET_ERROR_IF(!ctx->m_shared->isProgram(program), GL_INVALID_OPERATION); SET_ERROR_IF(!ctx->m_shared->isProgramInitialized(program), GL_INVALID_OPERATION); GLint hostLoc = ctx->m_shared->locationWARAppToHost(program,location); SET_ERROR_IF(ctx->m_shared->getProgramUniformType(program,hostLoc)==0, GL_INVALID_OPERATION); ctx->m_glGetUniformfv_enc(self, program, hostLoc, params); } GLuint GL2Encoder::s_glCreateProgram(void * self) { GL2Encoder *ctx = (GL2Encoder*)self; GLuint program = ctx->m_glCreateProgram_enc(self); if (program!=0) ctx->m_shared->addProgramData(program); return program; } GLuint GL2Encoder::s_glCreateShader(void *self, GLenum shaderType) { GL2Encoder *ctx = (GL2Encoder*)self; RET_AND_SET_ERROR_IF(((shaderType != GL_VERTEX_SHADER) && (shaderType != GL_FRAGMENT_SHADER)), GL_INVALID_ENUM, 0); GLuint shader = ctx->m_glCreateShader_enc(self, shaderType); if (shader != 0) { if (!ctx->m_shared->addShaderData(shader)) { ctx->m_glDeleteShader_enc(self, shader); return 0; } } return shader; } void GL2Encoder::s_glGetAttachedShaders(void *self, GLuint program, GLsizei maxCount, GLsizei* count, GLuint* shaders) { GL2Encoder *ctx = (GL2Encoder*)self; SET_ERROR_IF(maxCount < 0, GL_INVALID_VALUE); ctx->m_glGetAttachedShaders_enc(self, program, maxCount, count, shaders); } void GL2Encoder::s_glGetShaderSource(void *self, GLuint shader, GLsizei bufsize, GLsizei* length, GLchar* source) { GL2Encoder *ctx = (GL2Encoder*)self; SET_ERROR_IF(bufsize < 0, GL_INVALID_VALUE); ctx->m_glGetShaderSource_enc(self, shader, bufsize, length, source); } void GL2Encoder::s_glGetShaderInfoLog(void *self, GLuint shader, GLsizei bufsize, GLsizei* length, GLchar* infolog) { GL2Encoder *ctx = (GL2Encoder*)self; SET_ERROR_IF(bufsize < 0, GL_INVALID_VALUE); ctx->m_glGetShaderInfoLog_enc(self, shader, bufsize, length, infolog); } void GL2Encoder::s_glGetProgramInfoLog(void *self, GLuint program, GLsizei bufsize, GLsizei* length, GLchar* infolog) { GL2Encoder *ctx = (GL2Encoder*)self; SET_ERROR_IF(bufsize < 0, GL_INVALID_VALUE); ctx->m_glGetProgramInfoLog_enc(self, program, bufsize, length, infolog); } void GL2Encoder::s_glDeleteShader(void *self, GLenum shader) { GL2Encoder *ctx = (GL2Encoder*)self; ctx->m_glDeleteShader_enc(self,shader); ctx->m_shared->unrefShaderData(shader); } void GL2Encoder::s_glAttachShader(void *self, GLuint program, GLuint shader) { GL2Encoder *ctx = (GL2Encoder*)self; ctx->m_glAttachShader_enc(self, program, shader); ctx->m_shared->attachShader(program, shader); } void GL2Encoder::s_glDetachShader(void *self, GLuint program, GLuint shader) { GL2Encoder *ctx = (GL2Encoder*)self; ctx->m_glDetachShader_enc(self, program, shader); ctx->m_shared->detachShader(program, shader); } int GL2Encoder::s_glGetUniformLocation(void *self, GLuint program, const GLchar *name) { if (!name) return -1; GL2Encoder *ctx = (GL2Encoder*)self; // if we need the uniform location WAR // parse array index from the end of the name string int arrIndex = 0; bool needLocationWAR = ctx->m_shared->needUniformLocationWAR(program); if (needLocationWAR) { int namelen = strlen(name); if (name[namelen-1] == ']') { char *brace = strrchr(name,'['); if (!brace || sscanf(brace+1,"%d",&arrIndex) != 1) { return -1; } } } int hostLoc = ctx->m_glGetUniformLocation_enc(self, program, name); if (hostLoc >= 0 && needLocationWAR) { return ctx->m_shared->locationWARHostToApp(program, hostLoc, arrIndex); } return hostLoc; } bool GL2Encoder::updateHostTexture2DBinding(GLenum texUnit, GLenum newTarget) { if (newTarget != GL_TEXTURE_2D && newTarget != GL_TEXTURE_EXTERNAL_OES) return false; m_state->setActiveTextureUnit(texUnit); GLenum oldTarget = m_state->getPriorityEnabledTarget(GL_TEXTURE_2D); if (newTarget != oldTarget) { if (newTarget == GL_TEXTURE_EXTERNAL_OES) { m_state->disableTextureTarget(GL_TEXTURE_2D); m_state->enableTextureTarget(GL_TEXTURE_EXTERNAL_OES); } else { m_state->disableTextureTarget(GL_TEXTURE_EXTERNAL_OES); m_state->enableTextureTarget(GL_TEXTURE_2D); } m_glActiveTexture_enc(this, texUnit); m_glBindTexture_enc(this, GL_TEXTURE_2D, m_state->getBoundTexture(newTarget)); return true; } return false; } void GL2Encoder::s_glUseProgram(void *self, GLuint program) { GL2Encoder *ctx = (GL2Encoder*)self; GLClientState* state = ctx->m_state; GLSharedGroupPtr shared = ctx->m_shared; ctx->m_glUseProgram_enc(self, program); ctx->m_state->setCurrentProgram(program); GLenum origActiveTexture = state->getActiveTextureUnit(); GLenum hostActiveTexture = origActiveTexture; GLint samplerIdx = -1; GLint samplerVal; GLenum samplerTarget; while ((samplerIdx = shared->getNextSamplerUniform(program, samplerIdx, &samplerVal, &samplerTarget)) != -1) { if (samplerVal < 0 || samplerVal >= GLClientState::MAX_TEXTURE_UNITS) continue; if (ctx->updateHostTexture2DBinding(GL_TEXTURE0 + samplerVal, samplerTarget)) { hostActiveTexture = GL_TEXTURE0 + samplerVal; } } state->setActiveTextureUnit(origActiveTexture); if (hostActiveTexture != origActiveTexture) { ctx->m_glActiveTexture_enc(self, origActiveTexture); } } void GL2Encoder::checkValidUniformParam(void *self, GLsizei count, GLboolean transpose) { GL2Encoder *ctx = (GL2Encoder*)self; GLuint program = ctx->m_state->currentProgram(); SET_ERROR_IF(!ctx->m_shared->isProgram(program), GL_INVALID_OPERATION); SET_ERROR_IF((count < 0 || transpose == GL_TRUE), GL_INVALID_VALUE); } void GL2Encoder::getHostLocation(void *self, GLint location, GLint *hostLoc) { GL2Encoder *ctx = (GL2Encoder*)self; GLuint program = ctx->m_state->currentProgram(); if (location == -1) { *hostLoc = location; return; } SET_ERROR_IF((location < 0), GL_INVALID_OPERATION); GLint curHostLoc = ctx->m_shared->locationWARAppToHost(program,location); SET_ERROR_IF((ctx->m_shared->getProgramUniformType(program,curHostLoc) == 0 && curHostLoc!=-1), GL_INVALID_OPERATION); *hostLoc = curHostLoc; } void GL2Encoder::s_glUniform1f(void *self , GLint location, GLfloat x) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, 0, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform1f_enc(self, hostLoc, x); } void GL2Encoder::s_glUniform1fv(void *self , GLint location, GLsizei count, const GLfloat* v) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, count, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform1fv_enc(self, hostLoc, count, v); } void GL2Encoder::s_glUniform1i(void *self , GLint location, GLint x) { GL2Encoder *ctx = (GL2Encoder*)self; GLClientState* state = ctx->m_state; GLSharedGroupPtr shared = ctx->m_shared; GLint hostLoc; ctx->checkValidUniformParam(self, 0, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform1i_enc(self, hostLoc, x); GLenum target; if (shared->setSamplerUniform(state->currentProgram(), location, x, &target)) { GLenum origActiveTexture = state->getActiveTextureUnit(); if (ctx->updateHostTexture2DBinding(GL_TEXTURE0 + x, target)) { ctx->m_glActiveTexture_enc(self, origActiveTexture); } state->setActiveTextureUnit(origActiveTexture); } } void GL2Encoder::s_glUniform1iv(void *self , GLint location, GLsizei count, const GLint* v) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, count, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform1iv_enc(self, hostLoc, count, v); } void GL2Encoder::s_glUniform2f(void *self , GLint location, GLfloat x, GLfloat y) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, 0, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform2f_enc(self, hostLoc, x, y); } void GL2Encoder::s_glUniform2fv(void *self , GLint location, GLsizei count, const GLfloat* v) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, count, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform2fv_enc(self, hostLoc, count, v); } void GL2Encoder::s_glUniform2i(void *self , GLint location, GLint x, GLint y) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, 0, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform2i_enc(self, hostLoc, x, y); } void GL2Encoder::s_glUniform2iv(void *self , GLint location, GLsizei count, const GLint* v) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, count, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform2iv_enc(self, hostLoc, count, v); } void GL2Encoder::s_glUniform3f(void *self , GLint location, GLfloat x, GLfloat y, GLfloat z) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, 0, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform3f_enc(self, hostLoc, x, y, z); } void GL2Encoder::s_glUniform3fv(void *self , GLint location, GLsizei count, const GLfloat* v) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, count, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform3fv_enc(self, hostLoc, count, v); } void GL2Encoder::s_glUniform3i(void *self , GLint location, GLint x, GLint y, GLint z) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, 0, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform3i_enc(self, hostLoc, x, y, z); } void GL2Encoder::s_glUniform3iv(void *self , GLint location, GLsizei count, const GLint* v) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, count, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform3iv_enc(self, hostLoc, count, v); } void GL2Encoder::s_glUniform4f(void *self , GLint location, GLfloat x, GLfloat y, GLfloat z, GLfloat w) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, 0, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform4f_enc(self, hostLoc, x, y, z, w); } void GL2Encoder::s_glUniform4fv(void *self , GLint location, GLsizei count, const GLfloat* v) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, count, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform4fv_enc(self, hostLoc, count, v); } void GL2Encoder::s_glUniform4i(void *self , GLint location, GLint x, GLint y, GLint z, GLint w) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, 0, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform4i_enc(self, hostLoc, x, y, z, w); } void GL2Encoder::s_glUniform4iv(void *self , GLint location, GLsizei count, const GLint* v) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, count, GL_FALSE); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniform4iv_enc(self, hostLoc, count, v); } void GL2Encoder::s_glUniformMatrix2fv(void *self , GLint location, GLsizei count, GLboolean transpose, const GLfloat* value) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, count, transpose); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniformMatrix2fv_enc(self, hostLoc, count, transpose, value); } void GL2Encoder::s_glUniformMatrix3fv(void *self , GLint location, GLsizei count, GLboolean transpose, const GLfloat* value) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, count, transpose); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniformMatrix3fv_enc(self, hostLoc, count, transpose, value); } void GL2Encoder::s_glUniformMatrix4fv(void *self , GLint location, GLsizei count, GLboolean transpose, const GLfloat* value) { GL2Encoder *ctx = (GL2Encoder*)self; GLint hostLoc; ctx->checkValidUniformParam(self, count, transpose); ctx->getHostLocation(self, location, &hostLoc); ctx->m_glUniformMatrix4fv_enc(self, hostLoc, count, transpose, value); } void GL2Encoder::s_glActiveTexture(void* self, GLenum texture) { GL2Encoder* ctx = (GL2Encoder*)self; GLClientState* state = ctx->m_state; GLenum err; SET_ERROR_IF((err = state->setActiveTextureUnit(texture)) != GL_NO_ERROR, err); ctx->m_glActiveTexture_enc(ctx, texture); } void GL2Encoder::s_glBindTexture(void* self, GLenum target, GLuint texture) { GL2Encoder* ctx = (GL2Encoder*)self; GLClientState* state = ctx->m_state; GLenum err; GLboolean firstUse; SET_ERROR_IF((err = state->bindTexture(target, texture, &firstUse)) != GL_NO_ERROR, err); if (target != GL_TEXTURE_2D && target != GL_TEXTURE_EXTERNAL_OES) { ctx->m_glBindTexture_enc(ctx, target, texture); return; } GLenum priorityTarget = state->getPriorityEnabledTarget(GL_TEXTURE_2D); if (target == GL_TEXTURE_EXTERNAL_OES && firstUse) { ctx->m_glBindTexture_enc(ctx, GL_TEXTURE_2D, texture); ctx->m_glTexParameteri_enc(ctx, GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR); ctx->m_glTexParameteri_enc(ctx, GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE); ctx->m_glTexParameteri_enc(ctx, GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE); if (target != priorityTarget) { ctx->m_glBindTexture_enc(ctx, GL_TEXTURE_2D, state->getBoundTexture(GL_TEXTURE_2D)); } } if (target == priorityTarget) { ctx->m_glBindTexture_enc(ctx, GL_TEXTURE_2D, texture); } } void GL2Encoder::s_glDeleteTextures(void* self, GLsizei n, const GLuint* textures) { GL2Encoder* ctx = (GL2Encoder*)self; GLClientState* state = ctx->m_state; state->deleteTextures(n, textures); ctx->m_glDeleteTextures_enc(ctx, n, textures); } void GL2Encoder::s_glGetTexParameterfv(void* self, GLenum target, GLenum pname, GLfloat* params) { GL2Encoder* ctx = (GL2Encoder*)self; const GLClientState* state = ctx->m_state; if (target == GL_TEXTURE_2D || target == GL_TEXTURE_EXTERNAL_OES) { ctx->override2DTextureTarget(target); ctx->m_glGetTexParameterfv_enc(ctx, GL_TEXTURE_2D, pname, params); ctx->restore2DTextureTarget(); } else { ctx->m_glGetTexParameterfv_enc(ctx, target, pname, params); } } void GL2Encoder::s_glGetTexParameteriv(void* self, GLenum target, GLenum pname, GLint* params) { GL2Encoder* ctx = (GL2Encoder*)self; const GLClientState* state = ctx->m_state; switch (pname) { case GL_REQUIRED_TEXTURE_IMAGE_UNITS_OES: *params = 1; break; default: if (target == GL_TEXTURE_2D || target == GL_TEXTURE_EXTERNAL_OES) { ctx->override2DTextureTarget(target); ctx->m_glGetTexParameteriv_enc(ctx, GL_TEXTURE_2D, pname, params); ctx->restore2DTextureTarget(); } else { ctx->m_glGetTexParameteriv_enc(ctx, target, pname, params); } break; } } static bool isValidTextureExternalParam(GLenum pname, GLenum param) { switch (pname) { case GL_TEXTURE_MIN_FILTER: case GL_TEXTURE_MAG_FILTER: return param == GL_NEAREST || param == GL_LINEAR; case GL_TEXTURE_WRAP_S: case GL_TEXTURE_WRAP_T: return param == GL_CLAMP_TO_EDGE; default: return true; } } void GL2Encoder::s_glTexParameterf(void* self, GLenum target, GLenum pname, GLfloat param) { GL2Encoder* ctx = (GL2Encoder*)self; const GLClientState* state = ctx->m_state; SET_ERROR_IF((target == GL_TEXTURE_EXTERNAL_OES && !isValidTextureExternalParam(pname, (GLenum)param)), GL_INVALID_ENUM); if (target == GL_TEXTURE_2D || target == GL_TEXTURE_EXTERNAL_OES) { ctx->override2DTextureTarget(target); ctx->m_glTexParameterf_enc(ctx, GL_TEXTURE_2D, pname, param); ctx->restore2DTextureTarget(); } else { ctx->m_glTexParameterf_enc(ctx, target, pname, param); } } void GL2Encoder::s_glTexParameterfv(void* self, GLenum target, GLenum pname, const GLfloat* params) { GL2Encoder* ctx = (GL2Encoder*)self; const GLClientState* state = ctx->m_state; SET_ERROR_IF((target == GL_TEXTURE_EXTERNAL_OES && !isValidTextureExternalParam(pname, (GLenum)params[0])), GL_INVALID_ENUM); if (target == GL_TEXTURE_2D || target == GL_TEXTURE_EXTERNAL_OES) { ctx->override2DTextureTarget(target); ctx->m_glTexParameterfv_enc(ctx, GL_TEXTURE_2D, pname, params); ctx->restore2DTextureTarget(); } else { ctx->m_glTexParameterfv_enc(ctx, target, pname, params); } } void GL2Encoder::s_glTexParameteri(void* self, GLenum target, GLenum pname, GLint param) { GL2Encoder* ctx = (GL2Encoder*)self; const GLClientState* state = ctx->m_state; SET_ERROR_IF((target == GL_TEXTURE_EXTERNAL_OES && !isValidTextureExternalParam(pname, (GLenum)param)), GL_INVALID_ENUM); if (target == GL_TEXTURE_2D || target == GL_TEXTURE_EXTERNAL_OES) { ctx->override2DTextureTarget(target); ctx->m_glTexParameteri_enc(ctx, GL_TEXTURE_2D, pname, param); ctx->restore2DTextureTarget(); } else { ctx->m_glTexParameteri_enc(ctx, target, pname, param); } } void GL2Encoder::s_glTexImage2D(void* self, GLenum target, GLint level, GLint internalformat, GLsizei width, GLsizei height, GLint border, GLenum format, GLenum type, const GLvoid* pixels) { GL2Encoder* ctx = (GL2Encoder*)self; if (target == GL_TEXTURE_2D || target == GL_TEXTURE_EXTERNAL_OES) { ctx->override2DTextureTarget(target); ctx->m_glTexImage2D_enc(ctx, target, level, internalformat, width, height, border, format, type, pixels); ctx->restore2DTextureTarget(); } else { ctx->m_glTexImage2D_enc(ctx, target, level, internalformat, width, height, border, format, type, pixels); } } void GL2Encoder::s_glTexSubImage2D(void* self, GLenum target, GLint level, GLint xoffset, GLint yoffset, GLsizei width, GLsizei height, GLenum format, GLenum type, const GLvoid* pixels) { GL2Encoder* ctx = (GL2Encoder*)self; GLint maxTextureSize; ctx->glGetIntegerv(self, GL_MAX_TEXTURE_SIZE, &maxTextureSize); SET_ERROR_IF((level < 0 || level > log2(maxTextureSize)), GL_INVALID_VALUE); if (target == GL_TEXTURE_2D || target == GL_TEXTURE_EXTERNAL_OES) { ctx->override2DTextureTarget(target); ctx->m_glTexSubImage2D_enc(ctx, target, level, xoffset, yoffset, width, height, format, type, pixels); ctx->restore2DTextureTarget(); } else { ctx->m_glTexSubImage2D_enc(ctx, target, level, xoffset, yoffset, width, height, format, type, pixels); } } void GL2Encoder::s_glTexParameteriv(void* self, GLenum target, GLenum pname, const GLint* params) { GL2Encoder* ctx = (GL2Encoder*)self; const GLClientState* state = ctx->m_state; SET_ERROR_IF((target == GL_TEXTURE_EXTERNAL_OES && !isValidTextureExternalParam(pname, (GLenum)params[0])), GL_INVALID_ENUM); if (target == GL_TEXTURE_2D || target == GL_TEXTURE_EXTERNAL_OES) { ctx->override2DTextureTarget(target); ctx->m_glTexParameteriv_enc(ctx, GL_TEXTURE_2D, pname, params); ctx->restore2DTextureTarget(); } else { ctx->m_glTexParameteriv_enc(ctx, target, pname, params); } } void GL2Encoder::override2DTextureTarget(GLenum target) { if ((target == GL_TEXTURE_2D || target == GL_TEXTURE_EXTERNAL_OES) && target != m_state->getPriorityEnabledTarget(GL_TEXTURE_2D)) { m_glBindTexture_enc(this, GL_TEXTURE_2D, m_state->getBoundTexture(target)); } } void GL2Encoder::restore2DTextureTarget() { GLenum priorityTarget = m_state->getPriorityEnabledTarget(GL_TEXTURE_2D); m_glBindTexture_enc(this, GL_TEXTURE_2D, m_state->getBoundTexture(priorityTarget)); }