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view src/render/opengles2/SDL_render_gles2.c @ 5267:b530ef003506
Happy 2011! :)
| author | Sam Lantinga <slouken@libsdl.org> |
|---|---|
| date | Fri, 11 Feb 2011 22:37:15 -0800 |
| parents | 62d2bc792002 |
| children | 8e421890cdb8 |
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/* SDL - Simple DirectMedia Layer Copyright (C) 1997-2011 Sam Lantinga Copyright (C) 2010 itsnotabigtruck. This library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this library; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA Sam Lantinga slouken@libsdl.org */ #include "SDL_config.h" #if SDL_VIDEO_RENDER_OGL_ES2 && !SDL_RENDER_DISABLED #include "SDL_opengles2.h" #include "../SDL_sysrender.h" #include "SDL_shaders_gles2.h" /************************************************************************************************* * Bootstrap data * *************************************************************************************************/ static SDL_Renderer *GLES2_CreateRenderer(SDL_Window *window, Uint32 flags); SDL_RenderDriver GLES2_RenderDriver = { GLES2_CreateRenderer, { "opengles2", (SDL_RENDERER_ACCELERATED | SDL_RENDERER_PRESENTVSYNC), 1, {SDL_PIXELFORMAT_ABGR8888}, 0, 0 } }; /************************************************************************************************* * Context structures * *************************************************************************************************/ typedef struct GLES2_TextureData { GLenum texture; GLenum texture_type; GLenum pixel_format; GLenum pixel_type; void *pixel_data; size_t pitch; } GLES2_TextureData; typedef struct GLES2_ShaderCacheEntry { GLuint id; GLES2_ShaderType type; const GLES2_ShaderInstance *instance; int references; struct GLES2_ShaderCacheEntry *prev; struct GLES2_ShaderCacheEntry *next; } GLES2_ShaderCacheEntry; typedef struct GLES2_ShaderCache { int count; GLES2_ShaderCacheEntry *head; } GLES2_ShaderCache; typedef struct GLES2_ProgramCacheEntry { GLuint id; SDL_BlendMode blend_mode; GLES2_ShaderCacheEntry *vertex_shader; GLES2_ShaderCacheEntry *fragment_shader; GLuint uniform_locations[16]; struct GLES2_ProgramCacheEntry *prev; struct GLES2_ProgramCacheEntry *next; } GLES2_ProgramCacheEntry; typedef struct GLES2_ProgramCache { int count; GLES2_ProgramCacheEntry *head; GLES2_ProgramCacheEntry *tail; } GLES2_ProgramCache; typedef enum { GLES2_ATTRIBUTE_POSITION = 0, GLES2_ATTRIBUTE_TEXCOORD = 1 } GLES2_Attribute; typedef enum { GLES2_UNIFORM_PROJECTION, GLES2_UNIFORM_TEXTURE, GLES2_UNIFORM_MODULATION, GLES2_UNIFORM_COLOR, GLES2_UNIFORM_COLORTABLE } GLES2_Uniform; typedef enum { GLES2_IMAGESOURCE_SOLID, GLES2_IMAGESOURCE_TEXTURE } GLES2_ImageSource; typedef struct GLES2_DriverContext { SDL_GLContext *context; int shader_format_count; GLenum *shader_formats; GLES2_ShaderCache shader_cache; GLES2_ProgramCache program_cache; GLES2_ProgramCacheEntry *current_program; SDL_bool updateSize; } GLES2_DriverContext; #define GLES2_MAX_CACHED_PROGRAMS 8 /************************************************************************************************* * Renderer state APIs * *************************************************************************************************/ static int GLES2_ActivateRenderer(SDL_Renderer *renderer); static void GLES2_WindowEvent(SDL_Renderer * renderer, const SDL_WindowEvent *event); static void GLES2_SetClipRect(SDL_Renderer * renderer, const SDL_Rect * rect); static void GLES2_DestroyRenderer(SDL_Renderer *renderer); static SDL_GLContext SDL_CurrentContext = NULL; static int GLES2_ActivateRenderer(SDL_Renderer * renderer) { GLES2_DriverContext *rdata = (GLES2_DriverContext *)renderer->driverdata; SDL_Window *window = renderer->window; if (SDL_CurrentContext != rdata->context) { /* Null out the current program to ensure we set it again */ rdata->current_program = NULL; if (SDL_GL_MakeCurrent(window, rdata->context) < 0) { return -1; } SDL_CurrentContext = rdata->context; } if (rdata->updateSize) { int w, h; SDL_GetWindowSize(window, &w, &h); glViewport(0, 0, w, h); rdata->updateSize = SDL_FALSE; } return 0; } static void GLES2_WindowEvent(SDL_Renderer * renderer, const SDL_WindowEvent *event) { GLES2_DriverContext *rdata = (GLES2_DriverContext *)renderer->driverdata; if (event->event == SDL_WINDOWEVENT_RESIZED) { /* Rebind the context to the window area */ SDL_CurrentContext = NULL; rdata->updateSize = SDL_TRUE; } } static void GLES2_SetClipRect(SDL_Renderer * renderer, const SDL_Rect * rect) { GLES2_ActivateRenderer(renderer); if (rect) { int w, h; SDL_GetWindowSize(renderer->window, &w, &h); glScissor(rect->x, (h-(rect->y+rect->h)), rect->w, rect->h); glEnable(GL_SCISSOR_TEST); } else { glDisable(GL_SCISSOR_TEST); } } static void GLES2_DestroyRenderer(SDL_Renderer *renderer) { GLES2_DriverContext *rdata = (GLES2_DriverContext *)renderer->driverdata; GLES2_ProgramCacheEntry *entry; GLES2_ProgramCacheEntry *next; /* Deallocate everything */ if (rdata) { GLES2_ActivateRenderer(renderer); entry = rdata->program_cache.head; while (entry) { glDeleteShader(entry->vertex_shader->id); glDeleteShader(entry->fragment_shader->id); SDL_free(entry->vertex_shader); SDL_free(entry->fragment_shader); glDeleteProgram(entry->id); next = entry->next; SDL_free(entry); entry = next; } if (rdata->context) { SDL_GL_DeleteContext(rdata->context); } if (rdata->shader_formats) { SDL_free(rdata->shader_formats); } SDL_free(rdata); } SDL_free(renderer); } /************************************************************************************************* * Texture APIs * *************************************************************************************************/ static int GLES2_CreateTexture(SDL_Renderer *renderer, SDL_Texture *texture); static void GLES2_DestroyTexture(SDL_Renderer *renderer, SDL_Texture *texture); static int GLES2_LockTexture(SDL_Renderer *renderer, SDL_Texture *texture, const SDL_Rect *rect, void **pixels, int *pitch); static void GLES2_UnlockTexture(SDL_Renderer *renderer, SDL_Texture *texture); static int GLES2_UpdateTexture(SDL_Renderer *renderer, SDL_Texture *texture, const SDL_Rect *rect, const void *pixels, int pitch); static int GLES2_CreateTexture(SDL_Renderer *renderer, SDL_Texture *texture) { GLES2_DriverContext *rdata = (GLES2_DriverContext *)renderer->driverdata; GLES2_TextureData *tdata; GLenum format; GLenum type; GLES2_ActivateRenderer(renderer); /* Determine the corresponding GLES texture format params */ switch (texture->format) { case SDL_PIXELFORMAT_ABGR8888: format = GL_RGBA; type = GL_UNSIGNED_BYTE; break; default: SDL_SetError("Texture format not supported"); return -1; } /* Allocate a texture struct */ tdata = (GLES2_TextureData *)SDL_calloc(1, sizeof(GLES2_TextureData)); if (!tdata) { SDL_OutOfMemory(); return -1; } tdata->texture = 0; tdata->texture_type = GL_TEXTURE_2D; tdata->pixel_format = format; tdata->pixel_type = type; /* Allocate a blob for image data */ if (texture->access == SDL_TEXTUREACCESS_STREAMING) { tdata->pitch = texture->w * SDL_BYTESPERPIXEL(texture->format); tdata->pixel_data = SDL_malloc(tdata->pitch * texture->h); if (!tdata->pixel_data) { SDL_OutOfMemory(); SDL_free(tdata); return -1; } } /* Allocate the texture */ glGetError(); glGenTextures(1, &tdata->texture); glActiveTexture(GL_TEXTURE0); glBindTexture(tdata->texture_type, tdata->texture); glTexParameteri(tdata->texture_type, GL_TEXTURE_MIN_FILTER, GL_LINEAR); glTexParameteri(tdata->texture_type, GL_TEXTURE_MAG_FILTER, GL_LINEAR); glTexParameteri(tdata->texture_type, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE); glTexParameteri(tdata->texture_type, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE); glTexImage2D(tdata->texture_type, 0, format, texture->w, texture->h, 0, format, type, NULL); if (glGetError() != GL_NO_ERROR) { SDL_SetError("Texture creation failed"); glDeleteTextures(1, &tdata->texture); SDL_free(tdata); return -1; } texture->driverdata = tdata; return 0; } static void GLES2_DestroyTexture(SDL_Renderer *renderer, SDL_Texture *texture) { GLES2_TextureData *tdata = (GLES2_TextureData *)texture->driverdata; GLES2_ActivateRenderer(renderer); /* Destroy the texture */ if (tdata) { glDeleteTextures(1, &tdata->texture); SDL_free(tdata->pixel_data); SDL_free(tdata); texture->driverdata = NULL; } } static int GLES2_LockTexture(SDL_Renderer *renderer, SDL_Texture *texture, const SDL_Rect *rect, void **pixels, int *pitch) { GLES2_TextureData *tdata = (GLES2_TextureData *)texture->driverdata; /* Retrieve the buffer/pitch for the specified region */ *pixels = (Uint8 *)tdata->pixel_data + (tdata->pitch * rect->y) + (rect->x * SDL_BYTESPERPIXEL(texture->format)); *pitch = tdata->pitch; return 0; } static void GLES2_UnlockTexture(SDL_Renderer *renderer, SDL_Texture *texture) { GLES2_TextureData *tdata = (GLES2_TextureData *)texture->driverdata; SDL_Rect rect; /* We do whole texture updates, at least for now */ rect.x = 0; rect.y = 0; rect.w = texture->w; rect.h = texture->h; GLES2_UpdateTexture(renderer, texture, &rect, tdata->pixel_data, tdata->pitch); } static int GLES2_UpdateTexture(SDL_Renderer *renderer, SDL_Texture *texture, const SDL_Rect *rect, const void *pixels, int pitch) { GLES2_TextureData *tdata = (GLES2_TextureData *)texture->driverdata; Uint8 *blob = NULL; Uint8 *src; int srcPitch; int y; GLES2_ActivateRenderer(renderer); /* Bail out if we're supposed to update an empty rectangle */ if (rect->w <= 0 || rect->h <= 0) return 0; /* Reformat the texture data into a tightly packed array */ srcPitch = rect->w * SDL_BYTESPERPIXEL(texture->format); src = (Uint8 *)pixels; if (pitch != srcPitch) { blob = (Uint8 *)SDL_malloc(srcPitch * rect->h); if (!blob) { SDL_OutOfMemory(); return -1; } src = blob; for (y = 0; y < rect->h; ++y) { SDL_memcpy(src, pixels, srcPitch); src += srcPitch; pixels = (Uint8 *)pixels + pitch; } src = blob; } /* Create a texture subimage with the supplied data */ glGetError(); glActiveTexture(GL_TEXTURE0); glBindTexture(tdata->texture_type, tdata->texture); glPixelStorei(GL_UNPACK_ALIGNMENT, 1); glTexSubImage2D(tdata->texture_type, 0, rect->x, rect->y, rect->w, rect->h, tdata->pixel_format, tdata->pixel_type, src); if (blob) { SDL_free(blob); } if (glGetError() != GL_NO_ERROR) { SDL_SetError("Failed to update texture"); return -1; } return 0; } /************************************************************************************************* * Shader management functions * *************************************************************************************************/ static GLES2_ShaderCacheEntry *GLES2_CacheShader(SDL_Renderer *renderer, GLES2_ShaderType type, SDL_BlendMode blendMode); static void GLES2_EvictShader(SDL_Renderer *renderer, GLES2_ShaderCacheEntry *entry); static GLES2_ProgramCacheEntry *GLES2_CacheProgram(SDL_Renderer *renderer, GLES2_ShaderCacheEntry *vertex, GLES2_ShaderCacheEntry *fragment, SDL_BlendMode blendMode); static int GLES2_SelectProgram(SDL_Renderer *renderer, GLES2_ImageSource source, SDL_BlendMode blendMode); static int GLES2_SetOrthographicProjection(SDL_Renderer *renderer); static GLES2_ProgramCacheEntry * GLES2_CacheProgram(SDL_Renderer *renderer, GLES2_ShaderCacheEntry *vertex, GLES2_ShaderCacheEntry *fragment, SDL_BlendMode blendMode) { GLES2_DriverContext *rdata = (GLES2_DriverContext *)renderer->driverdata; GLES2_ProgramCacheEntry *entry; GLES2_ShaderCacheEntry *shaderEntry; GLint linkSuccessful; /* Check if we've already cached this program */ entry = rdata->program_cache.head; while (entry) { if (entry->vertex_shader == vertex && entry->fragment_shader == fragment) break; entry = entry->next; } if (entry) { if (rdata->program_cache.count > 1) { if (entry->next) entry->next->prev = entry->prev; if (entry->prev) entry->prev->next = entry->next; entry->prev = NULL; entry->next = rdata->program_cache.head; rdata->program_cache.head->prev = entry; rdata->program_cache.head = entry; } return entry; } /* Create a program cache entry */ entry = (GLES2_ProgramCacheEntry *)SDL_calloc(1, sizeof(GLES2_ProgramCacheEntry)); if (!entry) { SDL_OutOfMemory(); return NULL; } entry->vertex_shader = vertex; entry->fragment_shader = fragment; entry->blend_mode = blendMode; /* Create the program and link it */ glGetError(); entry->id = glCreateProgram(); glAttachShader(entry->id, vertex->id); glAttachShader(entry->id, fragment->id); glBindAttribLocation(entry->id, GLES2_ATTRIBUTE_POSITION, "a_position"); glBindAttribLocation(entry->id, GLES2_ATTRIBUTE_TEXCOORD, "a_texCoord"); glLinkProgram(entry->id); glGetProgramiv(entry->id, GL_LINK_STATUS, &linkSuccessful); if (glGetError() != GL_NO_ERROR || !linkSuccessful) { SDL_SetError("Failed to link shader program"); glDeleteProgram(entry->id); SDL_free(entry); return NULL; } /* Predetermine locations of uniform variables */ entry->uniform_locations[GLES2_UNIFORM_PROJECTION] = glGetUniformLocation(entry->id, "u_projection"); entry->uniform_locations[GLES2_UNIFORM_TEXTURE] = glGetUniformLocation(entry->id, "u_texture"); entry->uniform_locations[GLES2_UNIFORM_MODULATION] = glGetUniformLocation(entry->id, "u_modulation"); entry->uniform_locations[GLES2_UNIFORM_COLOR] = glGetUniformLocation(entry->id, "u_color"); entry->uniform_locations[GLES2_UNIFORM_COLORTABLE] = glGetUniformLocation(entry->id, "u_colorTable"); /* Cache the linked program */ if (rdata->program_cache.head) { entry->next = rdata->program_cache.head; rdata->program_cache.head->prev = entry; } else { rdata->program_cache.tail = entry; } rdata->program_cache.head = entry; ++rdata->program_cache.count; /* Increment the refcount of the shaders we're using */ ++vertex->references; ++fragment->references; /* Evict the last entry from the cache if we exceed the limit */ if (rdata->program_cache.count > GLES2_MAX_CACHED_PROGRAMS) { shaderEntry = rdata->program_cache.tail->vertex_shader; if (--shaderEntry->references <= 0) GLES2_EvictShader(renderer, shaderEntry); shaderEntry = rdata->program_cache.tail->fragment_shader; if (--shaderEntry->references <= 0) GLES2_EvictShader(renderer, shaderEntry); glDeleteProgram(rdata->program_cache.tail->id); rdata->program_cache.tail = rdata->program_cache.tail->prev; SDL_free(rdata->program_cache.tail->next); rdata->program_cache.tail->next = NULL; --rdata->program_cache.count; } return entry; } static GLES2_ShaderCacheEntry * GLES2_CacheShader(SDL_Renderer *renderer, GLES2_ShaderType type, SDL_BlendMode blendMode) { GLES2_DriverContext *rdata = (GLES2_DriverContext *)renderer->driverdata; const GLES2_Shader *shader; const GLES2_ShaderInstance *instance = NULL; GLES2_ShaderCacheEntry *entry = NULL; GLint compileSuccessful = GL_FALSE; int i, j; /* Find the corresponding shader */ shader = GLES2_GetShader(type, blendMode); if (!shader) { SDL_SetError("No shader matching the requested characteristics was found"); return NULL; } /* Find a matching shader instance that's supported on this hardware */ for (i = 0; i < shader->instance_count && !instance; ++i) { for (j = 0; j < rdata->shader_format_count && !instance; ++j) { if (!shader->instances) continue; if (!shader->instances[i]) continue; if (shader->instances[i]->format != rdata->shader_formats[j]) continue; instance = shader->instances[i]; } } if (!instance) { SDL_SetError("The specified shader cannot be loaded on the current platform"); return NULL; } /* Check if we've already cached this shader */ entry = rdata->shader_cache.head; while (entry) { if (entry->instance == instance) break; entry = entry->next; } if (entry) return entry; /* Create a shader cache entry */ entry = (GLES2_ShaderCacheEntry *)SDL_calloc(1, sizeof(GLES2_ShaderCacheEntry)); if (!entry) { SDL_OutOfMemory(); return NULL; } entry->type = type; entry->instance = instance; /* Compile or load the selected shader instance */ glGetError(); entry->id = glCreateShader(instance->type); if (instance->format == (GLenum)-1) { glShaderSource(entry->id, 1, (const char **)&instance->data, NULL); glCompileShader(entry->id); glGetShaderiv(entry->id, GL_COMPILE_STATUS, &compileSuccessful); } else { glShaderBinary(1, &entry->id, instance->format, instance->data, instance->length); compileSuccessful = GL_TRUE; } if (glGetError() != GL_NO_ERROR || !compileSuccessful) { char *info = NULL; int length; glGetShaderiv(entry->id, GL_INFO_LOG_LENGTH, &length); if (length > 0) { info = SDL_stack_alloc(char, length); if (info) { glGetShaderInfoLog(entry->id, length, &length, info); } } if (info) { SDL_SetError("Failed to load the shader: %s", info); SDL_stack_free(info); } else { SDL_SetError("Failed to load the shader"); } glDeleteShader(entry->id); SDL_free(entry); return NULL; } /* Link the shader entry in at the front of the cache */ if (rdata->shader_cache.head) { entry->next = rdata->shader_cache.head; rdata->shader_cache.head->prev = entry; } rdata->shader_cache.head = entry; ++rdata->shader_cache.count; return entry; } static void GLES2_EvictShader(SDL_Renderer *renderer, GLES2_ShaderCacheEntry *entry) { GLES2_DriverContext *rdata = (GLES2_DriverContext *)renderer->driverdata; /* Unlink the shader from the cache */ if (entry->next) entry->next->prev = entry->prev; if (entry->prev) entry->prev->next = entry->next; if (rdata->shader_cache.head == entry) rdata->shader_cache.head = entry->next; --rdata->shader_cache.count; /* Deallocate the shader */ glDeleteShader(entry->id); SDL_free(entry); } static int GLES2_SelectProgram(SDL_Renderer *renderer, GLES2_ImageSource source, SDL_BlendMode blendMode) { GLES2_DriverContext *rdata = (GLES2_DriverContext *)renderer->driverdata; GLES2_ShaderCacheEntry *vertex = NULL; GLES2_ShaderCacheEntry *fragment = NULL; GLES2_ShaderType vtype, ftype; GLES2_ProgramCacheEntry *program; /* Select an appropriate shader pair for the specified modes */ vtype = GLES2_SHADER_VERTEX_DEFAULT; switch (source) { case GLES2_IMAGESOURCE_SOLID: ftype = GLES2_SHADER_FRAGMENT_SOLID_SRC; break; case GLES2_IMAGESOURCE_TEXTURE: ftype = GLES2_SHADER_FRAGMENT_TEXTURE_SRC; break; } /* Load the requested shaders */ vertex = GLES2_CacheShader(renderer, vtype, blendMode); if (!vertex) goto fault; fragment = GLES2_CacheShader(renderer, ftype, blendMode); if (!fragment) goto fault; /* Check if we need to change programs at all */ if (rdata->current_program && rdata->current_program->vertex_shader == vertex && rdata->current_program->fragment_shader == fragment) return 0; /* Generate a matching program */ program = GLES2_CacheProgram(renderer, vertex, fragment, blendMode); if (!program) goto fault; /* Select that program in OpenGL */ glGetError(); glUseProgram(program->id); if (glGetError() != GL_NO_ERROR) { SDL_SetError("Failed to select program"); goto fault; } /* Set the current program */ rdata->current_program = program; /* Activate an orthographic projection */ if (GLES2_SetOrthographicProjection(renderer) < 0) goto fault; /* Clean up and return */ return 0; fault: if (vertex && vertex->references <= 0) GLES2_EvictShader(renderer, vertex); if (fragment && fragment->references <= 0) GLES2_EvictShader(renderer, fragment); rdata->current_program = NULL; return -1; } static int GLES2_SetOrthographicProjection(SDL_Renderer *renderer) { GLES2_DriverContext *rdata = (GLES2_DriverContext *)renderer->driverdata; SDL_Window *window = renderer->window; int w, h; GLfloat projection[4][4]; GLuint locProjection; /* Get the window width and height */ SDL_GetWindowSize(window, &w, &h); /* Prepare an orthographic projection */ projection[0][0] = 2.0f / w; projection[0][1] = 0.0f; projection[0][2] = 0.0f; projection[0][3] = 0.0f; projection[1][0] = 0.0f; projection[1][1] = -2.0f / h; projection[1][2] = 0.0f; projection[1][3] = 0.0f; projection[2][0] = 0.0f; projection[2][1] = 0.0f; projection[2][2] = 1.0f; projection[2][3] = 0.0f; projection[3][0] = -1.0f; projection[3][1] = 1.0f; projection[3][2] = 0.0f; projection[3][3] = 1.0f; /* Set the projection matrix */ locProjection = rdata->current_program->uniform_locations[GLES2_UNIFORM_PROJECTION]; glGetError(); glUniformMatrix4fv(locProjection, 1, GL_FALSE, (GLfloat *)projection); if (glGetError() != GL_NO_ERROR) { SDL_SetError("Failed to set orthographic projection"); return -1; } return 0; } /************************************************************************************************* * Rendering functions * *************************************************************************************************/ static const float inv255f = 1.0f / 255.0f; static int GLES2_RenderClear(SDL_Renderer *renderer); static int GLES2_RenderDrawPoints(SDL_Renderer *renderer, const SDL_Point *points, int count); static int GLES2_RenderDrawLines(SDL_Renderer *renderer, const SDL_Point *points, int count); static int GLES2_RenderFillRects(SDL_Renderer *renderer, const SDL_Rect **rects, int count); static int GLES2_RenderCopy(SDL_Renderer *renderer, SDL_Texture *texture, const SDL_Rect *srcrect, const SDL_Rect *dstrect); static void GLES2_RenderPresent(SDL_Renderer *renderer); static int GLES2_RenderClear(SDL_Renderer *renderer) { float r = (float)renderer->r * inv255f; float g = (float)renderer->g * inv255f; float b = (float)renderer->b * inv255f; float a = (float)renderer->a * inv255f; GLES2_ActivateRenderer(renderer); /* Clear the backbuffer with the selected color */ glClearColor(r, g, b, a); glClear(GL_COLOR_BUFFER_BIT); return 0; } static void GLES2_SetBlendMode(int blendMode) { switch (blendMode) { case SDL_BLENDMODE_NONE: default: glDisable(GL_BLEND); break; case SDL_BLENDMODE_BLEND: glEnable(GL_BLEND); glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); break; case SDL_BLENDMODE_ADD: glEnable(GL_BLEND); glBlendFunc(GL_SRC_ALPHA, GL_ONE); break; case SDL_BLENDMODE_MOD: glEnable(GL_BLEND); glBlendFunc(GL_ZERO, GL_SRC_COLOR); break; } } static int GLES2_RenderDrawPoints(SDL_Renderer *renderer, const SDL_Point *points, int count) { GLES2_DriverContext *rdata = (GLES2_DriverContext *)renderer->driverdata; GLfloat *vertices; SDL_BlendMode blendMode; int alpha; GLuint locColor; int idx; GLES2_ActivateRenderer(renderer); blendMode = renderer->blendMode; alpha = renderer->a; /* Activate an appropriate shader and set the projection matrix */ if (GLES2_SelectProgram(renderer, GLES2_IMAGESOURCE_SOLID, blendMode) < 0) return -1; /* Select the color to draw with */ locColor = rdata->current_program->uniform_locations[GLES2_UNIFORM_COLOR]; glGetError(); glUniform4f(locColor, renderer->r * inv255f, renderer->g * inv255f, renderer->b * inv255f, alpha * inv255f); /* Configure the correct blend mode */ GLES2_SetBlendMode(blendMode); /* Emit the specified vertices as points */ vertices = SDL_stack_alloc(GLfloat, count * 2); for (idx = 0; idx < count; ++idx) { GLfloat x = (GLfloat)points[idx].x + 0.5f; GLfloat y = (GLfloat)points[idx].y + 0.5f; vertices[idx * 2] = x; vertices[(idx * 2) + 1] = y; } glEnableVertexAttribArray(GLES2_ATTRIBUTE_POSITION); glVertexAttribPointer(GLES2_ATTRIBUTE_POSITION, 2, GL_FLOAT, GL_FALSE, 0, vertices); glDrawArrays(GL_POINTS, 0, count); glDisableVertexAttribArray(GLES2_ATTRIBUTE_POSITION); SDL_stack_free(vertices); if (glGetError() != GL_NO_ERROR) { SDL_SetError("Failed to render lines"); return -1; } return 0; } static int GLES2_RenderDrawLines(SDL_Renderer *renderer, const SDL_Point *points, int count) { GLES2_DriverContext *rdata = (GLES2_DriverContext *)renderer->driverdata; GLfloat *vertices; SDL_BlendMode blendMode; int alpha; GLuint locColor; int idx; GLES2_ActivateRenderer(renderer); blendMode = renderer->blendMode; alpha = renderer->a; /* Activate an appropriate shader and set the projection matrix */ if (GLES2_SelectProgram(renderer, GLES2_IMAGESOURCE_SOLID, blendMode) < 0) return -1; /* Select the color to draw with */ locColor = rdata->current_program->uniform_locations[GLES2_UNIFORM_COLOR]; glGetError(); glUniform4f(locColor, renderer->r * inv255f, renderer->g * inv255f, renderer->b * inv255f, alpha * inv255f); /* Configure the correct blend mode */ GLES2_SetBlendMode(blendMode); /* Emit a line strip including the specified vertices */ vertices = SDL_stack_alloc(GLfloat, count * 2); for (idx = 0; idx < count; ++idx) { GLfloat x = (GLfloat)points[idx].x + 0.5f; GLfloat y = (GLfloat)points[idx].y + 0.5f; vertices[idx * 2] = x; vertices[(idx * 2) + 1] = y; } glEnableVertexAttribArray(GLES2_ATTRIBUTE_POSITION); glVertexAttribPointer(GLES2_ATTRIBUTE_POSITION, 2, GL_FLOAT, GL_FALSE, 0, vertices); glDrawArrays(GL_LINE_STRIP, 0, count); glDisableVertexAttribArray(GLES2_ATTRIBUTE_POSITION); SDL_stack_free(vertices); if (glGetError() != GL_NO_ERROR) { SDL_SetError("Failed to render lines"); return -1; } return 0; } static int GLES2_RenderFillRects(SDL_Renderer *renderer, const SDL_Rect **rects, int count) { GLES2_DriverContext *rdata = (GLES2_DriverContext *)renderer->driverdata; GLfloat vertices[8]; SDL_BlendMode blendMode; int alpha; GLuint locColor; int idx; GLES2_ActivateRenderer(renderer); blendMode = renderer->blendMode; alpha = renderer->a; /* Activate an appropriate shader and set the projection matrix */ if (GLES2_SelectProgram(renderer, GLES2_IMAGESOURCE_SOLID, blendMode) < 0) return -1; /* Select the color to draw with */ locColor = rdata->current_program->uniform_locations[GLES2_UNIFORM_COLOR]; glGetError(); glUniform4f(locColor, renderer->r * inv255f, renderer->g * inv255f, renderer->b * inv255f, alpha * inv255f); /* Configure the correct blend mode */ GLES2_SetBlendMode(blendMode); /* Emit a line loop for each rectangle */ glEnableVertexAttribArray(GLES2_ATTRIBUTE_POSITION); for (idx = 0; idx < count; ++idx) { GLfloat xMin = (GLfloat)rects[idx]->x; GLfloat xMax = (GLfloat)(rects[idx]->x + rects[idx]->w); GLfloat yMin = (GLfloat)rects[idx]->y; GLfloat yMax = (GLfloat)(rects[idx]->y + rects[idx]->h); vertices[0] = xMin; vertices[1] = yMin; vertices[2] = xMax; vertices[3] = yMin; vertices[4] = xMin; vertices[5] = yMax; vertices[6] = xMax; vertices[7] = yMax; glVertexAttribPointer(GLES2_ATTRIBUTE_POSITION, 2, GL_FLOAT, GL_FALSE, 0, vertices); glDrawArrays(GL_TRIANGLE_STRIP, 0, 4); } glDisableVertexAttribArray(GLES2_ATTRIBUTE_POSITION); if (glGetError() != GL_NO_ERROR) { SDL_SetError("Failed to render lines"); return -1; } return 0; } static int GLES2_RenderCopy(SDL_Renderer *renderer, SDL_Texture *texture, const SDL_Rect *srcrect, const SDL_Rect *dstrect) { GLES2_DriverContext *rdata = (GLES2_DriverContext *)renderer->driverdata; GLES2_TextureData *tdata = (GLES2_TextureData *)texture->driverdata; GLES2_ImageSource sourceType; SDL_BlendMode blendMode; int alpha; GLfloat vertices[8]; GLfloat texCoords[8]; GLuint locTexture; GLuint locModulation; GLuint locColorTable; GLES2_ActivateRenderer(renderer); /* Activate an appropriate shader and set the projection matrix */ blendMode = texture->blendMode; alpha = texture->a; sourceType = GLES2_IMAGESOURCE_TEXTURE; if (GLES2_SelectProgram(renderer, sourceType, blendMode) < 0) return -1; /* Select the target texture */ locTexture = rdata->current_program->uniform_locations[GLES2_UNIFORM_TEXTURE]; glGetError(); glActiveTexture(GL_TEXTURE0); glBindTexture(tdata->texture_type, tdata->texture); glUniform1i(locTexture, 0); /* Configure texture blending */ GLES2_SetBlendMode(blendMode); /* Configure color modulation */ locModulation = rdata->current_program->uniform_locations[GLES2_UNIFORM_MODULATION]; glUniform4f(locModulation, texture->r * inv255f, texture->g * inv255f, texture->b * inv255f, alpha * inv255f); /* Emit the textured quad */ glEnableVertexAttribArray(GLES2_ATTRIBUTE_TEXCOORD); glEnableVertexAttribArray(GLES2_ATTRIBUTE_POSITION); vertices[0] = (GLfloat)dstrect->x; vertices[1] = (GLfloat)dstrect->y; vertices[2] = (GLfloat)(dstrect->x + dstrect->w); vertices[3] = (GLfloat)dstrect->y; vertices[4] = (GLfloat)dstrect->x; vertices[5] = (GLfloat)(dstrect->y + dstrect->h); vertices[6] = (GLfloat)(dstrect->x + dstrect->w); vertices[7] = (GLfloat)(dstrect->y + dstrect->h); glVertexAttribPointer(GLES2_ATTRIBUTE_POSITION, 2, GL_FLOAT, GL_FALSE, 0, vertices); texCoords[0] = srcrect->x / (GLfloat)texture->w; texCoords[1] = srcrect->y / (GLfloat)texture->h; texCoords[2] = (srcrect->x + srcrect->w) / (GLfloat)texture->w; texCoords[3] = srcrect->y / (GLfloat)texture->h; texCoords[4] = srcrect->x / (GLfloat)texture->w; texCoords[5] = (srcrect->y + srcrect->h) / (GLfloat)texture->h; texCoords[6] = (srcrect->x + srcrect->w) / (GLfloat)texture->w; texCoords[7] = (srcrect->y + srcrect->h) / (GLfloat)texture->h; glVertexAttribPointer(GLES2_ATTRIBUTE_TEXCOORD, 2, GL_FLOAT, GL_FALSE, 0, texCoords); glDrawArrays(GL_TRIANGLE_STRIP, 0, 4); glDisableVertexAttribArray(GLES2_ATTRIBUTE_POSITION); glDisableVertexAttribArray(GLES2_ATTRIBUTE_TEXCOORD); if (glGetError() != GL_NO_ERROR) { SDL_SetError("Failed to render texture"); return -1; } return 0; } static void GLES2_RenderPresent(SDL_Renderer *renderer) { GLES2_ActivateRenderer(renderer); /* Tell the video driver to swap buffers */ SDL_GL_SwapWindow(renderer->window); } /************************************************************************************************* * Renderer instantiation * *************************************************************************************************/ #define GL_NVIDIA_PLATFORM_BINARY_NV 0x890B static SDL_Renderer * GLES2_CreateRenderer(SDL_Window *window, Uint32 flags) { SDL_Renderer *renderer; GLES2_DriverContext *rdata; GLint nFormats; #ifndef ZUNE_HD GLboolean hasCompiler; #endif /* Create the renderer struct */ renderer = (SDL_Renderer *)SDL_calloc(1, sizeof(SDL_Renderer)); if (!renderer) { SDL_OutOfMemory(); return NULL; } rdata = (GLES2_DriverContext *)SDL_calloc(1, sizeof(GLES2_DriverContext)); if (!rdata) { GLES2_DestroyRenderer(renderer); SDL_OutOfMemory(); return NULL; } renderer->info = GLES2_RenderDriver.info; renderer->window = window; renderer->driverdata = rdata; renderer->info.flags = SDL_RENDERER_ACCELERATED; /* Create an OpenGL ES 2.0 context */ SDL_GL_SetAttribute(SDL_GL_CONTEXT_MAJOR_VERSION, 2); SDL_GL_SetAttribute(SDL_GL_CONTEXT_MINOR_VERSION, 0); rdata->context = SDL_GL_CreateContext(window); if (!rdata->context) { GLES2_DestroyRenderer(renderer); return NULL; } if (SDL_GL_MakeCurrent(window, rdata->context) < 0) { GLES2_DestroyRenderer(renderer); return NULL; } if (flags & SDL_RENDERER_PRESENTVSYNC) { SDL_GL_SetSwapInterval(1); } else { SDL_GL_SetSwapInterval(0); } if (SDL_GL_GetSwapInterval() > 0) { renderer->info.flags |= SDL_RENDERER_PRESENTVSYNC; } /* Determine supported shader formats */ /* HACK: glGetInteger is broken on the Zune HD's compositor, so we just hardcode this */ glGetError(); #ifdef ZUNE_HD nFormats = 1; #else /* !ZUNE_HD */ glGetIntegerv(GL_NUM_SHADER_BINARY_FORMATS, &nFormats); glGetBooleanv(GL_SHADER_COMPILER, &hasCompiler); if (hasCompiler) ++nFormats; #endif /* ZUNE_HD */ rdata->shader_formats = (GLenum *)SDL_calloc(nFormats, sizeof(GLenum)); if (!rdata->shader_formats) { GLES2_DestroyRenderer(renderer); SDL_OutOfMemory(); return NULL; } rdata->shader_format_count = nFormats; #ifdef ZUNE_HD rdata->shader_formats[0] = GL_NVIDIA_PLATFORM_BINARY_NV; #else /* !ZUNE_HD */ glGetIntegerv(GL_SHADER_BINARY_FORMATS, (GLint *)rdata->shader_formats); if (glGetError() != GL_NO_ERROR) { GLES2_DestroyRenderer(renderer); SDL_SetError("Failed to query supported shader formats"); return NULL; } if (hasCompiler) rdata->shader_formats[nFormats - 1] = (GLenum)-1; #endif /* ZUNE_HD */ rdata->updateSize = SDL_TRUE; /* Populate the function pointers for the module */ renderer->WindowEvent = &GLES2_WindowEvent; renderer->CreateTexture = &GLES2_CreateTexture; renderer->UpdateTexture = &GLES2_UpdateTexture; renderer->LockTexture = &GLES2_LockTexture; renderer->UnlockTexture = &GLES2_UnlockTexture; renderer->SetClipRect = &GLES2_SetClipRect; renderer->RenderClear = &GLES2_RenderClear; renderer->RenderDrawPoints = &GLES2_RenderDrawPoints; renderer->RenderDrawLines = &GLES2_RenderDrawLines; renderer->RenderFillRects = &GLES2_RenderFillRects; renderer->RenderCopy = &GLES2_RenderCopy; renderer->RenderPresent = &GLES2_RenderPresent; renderer->DestroyTexture = &GLES2_DestroyTexture; renderer->DestroyRenderer = &GLES2_DestroyRenderer; return renderer; } #endif /* SDL_VIDEO_RENDER_OGL_ES2 && !SDL_RENDER_DISABLED */ /* vi: set ts=4 sw=4 expandtab: */