Mercurial > sdl-ios-xcode
view test/testdraw2.c @ 3335:b8d313de8a65
Adam Strzelecki to SDL
Since current DirectFB implementation is incomplete for YUV surfaces (actually causes segmentation faults when trying Lock and use YUV planar textures) I decided to fix it a bit.
Here's a patch that should make DirectFB properly support YUV both packed and planar (3 planes).
(1) Removed SDL_BYTESPERPIXEL at all in favor of DFB_BYTES_PER_PIXEL(SDLToDFBPixelFormat(fmt)) which does return always proper BPP for YUVs too, coz SDL_BYTESPERPIXEL returns incorrect values for FOURCCs
(2) Fixed data->pixels allocation for planar YUVs in CreateTexture, it should allocate 150% more space
(3) Copy other planes for planar YUVs in UpdateTexture
(4) Moved checking if format is supported at all with DirectFB on CreateTexture at the beginning of the code
Waiting for comments,
--
Adam Strzelecki | nanoant.com
| author | Sam Lantinga <slouken@libsdl.org> |
|---|---|
| date | Sun, 04 Oct 2009 04:03:37 +0000 |
| parents | 83c3a4b0e421 |
| children | 438ba87e9578 |
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/* Simple program: draw as many random objects on the screen as possible */ #include <stdlib.h> #include <stdio.h> #include <time.h> #include "common.h" #define NUM_OBJECTS 100 static CommonState *state; static int num_objects; static SDL_bool cycle_color; static SDL_bool cycle_alpha; static int cycle_direction = 1; static int current_alpha = 255; static int current_color = 255; static SDL_BlendMode blendMode = SDL_BLENDMODE_NONE; void DrawPoints(SDL_WindowID window) { int i; int x, y; int window_w, window_h; /* Query the sizes */ SDL_GetWindowSize(window, &window_w, &window_h); SDL_SetRenderDrawBlendMode(blendMode); for (i = 0; i < num_objects * 4; ++i) { /* Cycle the color and alpha, if desired */ if (cycle_color) { current_color += cycle_direction; if (current_color < 0) { current_color = 0; cycle_direction = -cycle_direction; } if (current_color > 255) { current_color = 255; cycle_direction = -cycle_direction; } } if (cycle_alpha) { current_alpha += cycle_direction; if (current_alpha < 0) { current_alpha = 0; cycle_direction = -cycle_direction; } if (current_alpha > 255) { current_alpha = 255; cycle_direction = -cycle_direction; } } SDL_SetRenderDrawColor(255, (Uint8) current_color, (Uint8) current_color, (Uint8) current_alpha); x = rand() % window_w; y = rand() % window_h; SDL_RenderPoint(x, y); } SDL_SetRenderDrawBlendMode(SDL_BLENDMODE_NONE); } void DrawLines(SDL_WindowID window) { int i; int x1, y1, x2, y2; int window_w, window_h; /* Query the sizes */ SDL_GetWindowSize(window, &window_w, &window_h); SDL_SetRenderDrawBlendMode(blendMode); for (i = 0; i < num_objects; ++i) { /* Cycle the color and alpha, if desired */ if (cycle_color) { current_color += cycle_direction; if (current_color < 0) { current_color = 0; cycle_direction = -cycle_direction; } if (current_color > 255) { current_color = 255; cycle_direction = -cycle_direction; } } if (cycle_alpha) { current_alpha += cycle_direction; if (current_alpha < 0) { current_alpha = 0; cycle_direction = -cycle_direction; } if (current_alpha > 255) { current_alpha = 255; cycle_direction = -cycle_direction; } } SDL_SetRenderDrawColor(255, (Uint8) current_color, (Uint8) current_color, (Uint8) current_alpha); if (i == 0) { SDL_RenderLine(0, 0, window_w - 1, window_h - 1); SDL_RenderLine(0, window_h - 1, window_w - 1, 0); SDL_RenderLine(0, window_h / 2, window_w - 1, window_h / 2); SDL_RenderLine(window_w / 2, 0, window_w / 2, window_h - 1); } else { x1 = rand() % window_w; x2 = rand() % window_w; y1 = rand() % window_h; y2 = rand() % window_h; SDL_RenderLine(x1, y1, x2, y2); } } SDL_SetRenderDrawBlendMode(SDL_BLENDMODE_NONE); } void DrawRects(SDL_WindowID window) { int i; SDL_Rect rect; int window_w, window_h; /* Query the sizes */ SDL_GetWindowSize(window, &window_w, &window_h); SDL_SetRenderDrawBlendMode(blendMode); for (i = 0; i < num_objects / 4; ++i) { /* Cycle the color and alpha, if desired */ if (cycle_color) { current_color += cycle_direction; if (current_color < 0) { current_color = 0; cycle_direction = -cycle_direction; } if (current_color > 255) { current_color = 255; cycle_direction = -cycle_direction; } } if (cycle_alpha) { current_alpha += cycle_direction; if (current_alpha < 0) { current_alpha = 0; cycle_direction = -cycle_direction; } if (current_alpha > 255) { current_alpha = 255; cycle_direction = -cycle_direction; } } SDL_SetRenderDrawColor(255, (Uint8) current_color, (Uint8) current_color, (Uint8) current_alpha); rect.w = rand() % (window_h / 2); rect.h = rand() % (window_h / 2); rect.x = (rand() % window_w) - (rect.w / 2); rect.y = (rand() % window_w) - (rect.h / 2); SDL_RenderFill(&rect); } SDL_SetRenderDrawBlendMode(SDL_BLENDMODE_NONE); } int main(int argc, char *argv[]) { int i, done; SDL_Event event; Uint32 then, now, frames; /* Initialize parameters */ num_objects = NUM_OBJECTS; /* Initialize test framework */ state = CommonCreateState(argv, SDL_INIT_VIDEO); if (!state) { return 1; } for (i = 1; i < argc;) { int consumed; consumed = CommonArg(state, i); if (consumed == 0) { consumed = -1; if (SDL_strcasecmp(argv[i], "--blend") == 0) { if (argv[i + 1]) { if (SDL_strcasecmp(argv[i + 1], "none") == 0) { blendMode = SDL_BLENDMODE_NONE; consumed = 2; } else if (SDL_strcasecmp(argv[i + 1], "mask") == 0) { blendMode = SDL_BLENDMODE_MASK; consumed = 2; } else if (SDL_strcasecmp(argv[i + 1], "blend") == 0) { blendMode = SDL_BLENDMODE_BLEND; consumed = 2; } else if (SDL_strcasecmp(argv[i + 1], "add") == 0) { blendMode = SDL_BLENDMODE_ADD; consumed = 2; } else if (SDL_strcasecmp(argv[i + 1], "mod") == 0) { blendMode = SDL_BLENDMODE_MOD; consumed = 2; } } } else if (SDL_strcasecmp(argv[i], "--cyclecolor") == 0) { cycle_color = SDL_TRUE; consumed = 1; } else if (SDL_strcasecmp(argv[i], "--cyclealpha") == 0) { cycle_alpha = SDL_TRUE; consumed = 1; } else if (SDL_isdigit(*argv[i])) { num_objects = SDL_atoi(argv[i]); consumed = 1; } } if (consumed < 0) { fprintf(stderr, "Usage: %s %s [--blend none|mask|blend|add|mod] [--cyclecolor] [--cyclealpha]\n", argv[0], CommonUsage(state)); return 1; } i += consumed; } if (!CommonInit(state)) { return 2; } /* Create the windows and initialize the renderers */ for (i = 0; i < state->num_windows; ++i) { SDL_SelectRenderer(state->windows[i]); SDL_SetRenderDrawColor(0xA0, 0xA0, 0xA0, 0xFF); SDL_RenderFill(NULL); } srand(time(NULL)); /* Main render loop */ frames = 0; then = SDL_GetTicks(); done = 0; while (!done) { /* Check for events */ ++frames; while (SDL_PollEvent(&event)) { CommonEvent(state, &event, &done); switch (event.type) { case SDL_WINDOWEVENT: switch (event.window.event) { case SDL_WINDOWEVENT_EXPOSED: SDL_SelectRenderer(event.window.windowID); SDL_SetRenderDrawColor(0xA0, 0xA0, 0xA0, 0xFF); SDL_RenderFill(NULL); break; } break; default: break; } } for (i = 0; i < state->num_windows; ++i) { SDL_SelectRenderer(state->windows[i]); SDL_SetRenderDrawColor(0xA0, 0xA0, 0xA0, 0xFF); SDL_RenderFill(NULL); DrawRects(state->windows[i]); DrawLines(state->windows[i]); DrawPoints(state->windows[i]); SDL_RenderPresent(); } } /* Print out some timing information */ now = SDL_GetTicks(); if (now > then) { double fps = ((double) frames * 1000) / (now - then); printf("%2.2f frames per second\n", fps); } return 0; } /* vi: set ts=4 sw=4 expandtab: */