Mercurial > sdl-ios-xcode
view test/testoverlay2.c @ 4139:568c9b3c0167 SDL-1.2
* Added configure option --enable-screensaver, to allow enabling the screensaver by default.
* Use XResetScreenSaver() instead of disabling screensaver entirely.
Full discussion summary from Erik on the SDL mailing list:
Current behaviour
=================
SDL changes the user's display power management settings without
permission from the user and without telling the user.
The interface that it uses to do so is DPMSDisable/DPMSEnable, which
should only ever be used by configuration utilities like KControl, never
by normal application programs, let alone by the libraries that they
use. Using an interface that is not at all intended for what SDL tries
to achieve means that it will not work as it should. Firstly, the power
management is completely disabled during the whole lifetime of the SDL
program, not only when it should be. Secondly, it makes SDL
non-reentrant, meaning that things will break when multiple SDL programs
are clients of the same X server simultaneously. Thirdly, no cleanup
mechanism ensures that the setting is restored if the client does not do
that (for example if it crashes).
In addition to that, this interface is broken on xorg,
[http://bugs.freedesktop.org/show_bug.cgi?id=13962], so what SDL tries
to do does not work at all on that implementation of the X Window
System. (The reason that the DPMSEnable works in KControl is that it
calls DPMSSetTimeout immediately after,
[http://websvn.kde.org/tags/KDE/3.5.9/kdebase/kcontrol/energy/energy.cpp?annotate=774532#l343]).
The problems that the current behaviour causes
==============================================
1. Information leak. When the user is away, someone might see what the
user has on the display when the user counts on the screensaver
preventing this. This does not even require physical access to the
workstation, it is enough to see it from a distance.
2. Draining battery. An SDL program that runs on a laptop will quickly
drain the battery while the user is away. The system will soon shut down
and require recharging before being usable again, while it should in
fact have consumed very little energy if the user's settings would have
been obeyed.
3. Wasting energy. Even if battery issues are not considered, energy as
such is wasted.
4. Display wear. The display may be worn out.
The problems that the current behaviour tries to solve
======================================================
1. Preventing screensaver while playing movies.
Many SDL applications are media players. They have reasons to prevent
screensavers from being activated while a movie is being played. When a
user clicks on the play button it can be interpreted as saying "play
this movie, but do not turn off the display while playing it, because I
will watch it even though I do not interact with the system".
2. Preventing screensaver when some input bypasses X.
Sometimes SDL uses input from another source than the X server, so
that the X server is bypassed. This obviously breaks the screensaver
handling. SDL tries to work around that.
3. Preventing screensaver when all input bypasses X.
There is something called Direct Graphics Access mode, where a
program takes control of both the display and the input devices from the
X server. This obviously means that the X server can not handle the
screensaver alone, since screensaver handling depends on input handling.
SDL does not do what it should to help the X server to handle the
screensaver. Nor does SDL take care of screeensaver handling itself. SDL
simply disables the screensaver completely.
How the problems should be solved
=================================
The correct way for an application program to prevent the screensaver
under X is to call XResetScreenSaver. This was recently discovered and
implemented by the mplayer developers,
[http://svn.mplayerhq.hu/mplayer?view=rev&revision=25637]. SDL needs to
wrap this in an API call (SDL_ResetScreenSaver) and implement it for the
other video targets (if they do not have a corresponding call, SDL
should do what it takes on that particular target, for example sending
fake key events).
1. When a movie is played, the player should reset the screensaver when
the animation is advanced to a new frame. The same applies to anything
similar, like slideshows.
2. When the X server is handling input, it must handle all input
(keyboards, mice, gamepads, ...). This is necessary, not only to be able
to handle the screensaver, but also so that it can send the events to
the correct (the currently active) client. If there is an input device
that the X server can not handle for some reason (such as lack of Plug
and Play capability), the program that handles the device as a
workaround must simulate what would happen if the X server would have
handled the device, by calling XResetScreenSaver when input is received
from the device.
3. When the X server is not handling the input, it depends on the
program that does to call XResetScreenSaver whenever an input event
occurs. Alternatively the program must handle the screensaver countdown
internally and call XActivateScreenSaver.
| author | Sam Lantinga <slouken@libsdl.org> |
|---|---|
| date | Fri, 29 Feb 2008 13:55:44 +0000 |
| parents | f1211a4b7380 |
| children | 782fd950bd46 c121d94672cb |
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/******************************************************************************** * * * Test of the overlay used for moved pictures, test more closed to real life. * * Running trojan moose :) Coded by Mike Gorchak. * * * ********************************************************************************/ #include <stdlib.h> #include <stdio.h> #include <string.h> #include "SDL.h" #define MOOSEPIC_W 64 #define MOOSEPIC_H 88 #define MOOSEFRAME_SIZE (MOOSEPIC_W * MOOSEPIC_H) #define MOOSEFRAMES_COUNT 10 SDL_Color MooseColors[84]={ { 49, 49, 49}, { 66, 24, 0}, { 66, 33, 0}, { 66, 66, 66}, { 66, 115, 49}, { 74, 33, 0}, { 74, 41, 16}, { 82, 33, 8}, { 82, 41, 8}, { 82, 49, 16}, { 82, 82, 82}, { 90, 41, 8}, { 90, 41, 16}, { 90, 57, 24}, { 99, 49, 16}, { 99, 66, 24}, { 99, 66, 33}, { 99, 74, 33}, {107, 57, 24}, {107, 82, 41}, {115, 57, 33}, {115, 66, 33}, {115, 66, 41}, {115, 74, 0}, {115, 90, 49}, {115, 115, 115}, {123, 82, 0}, {123, 99, 57}, {132, 66, 41}, {132, 74, 41}, {132, 90, 8}, {132, 99, 33}, {132, 99, 66}, {132, 107, 66}, {140, 74, 49}, {140, 99, 16}, {140, 107, 74}, {140, 115, 74}, {148, 107, 24}, {148, 115, 82}, {148, 123, 74}, {148, 123, 90}, {156, 115, 33}, {156, 115, 90}, {156, 123, 82}, {156, 132, 82}, {156, 132, 99}, {156, 156, 156}, {165, 123, 49}, {165, 123, 90}, {165, 132, 82}, {165, 132, 90}, {165, 132, 99}, {165, 140, 90}, {173, 132, 57}, {173, 132, 99}, {173, 140, 107}, {173, 140, 115}, {173, 148, 99}, {173, 173, 173}, {181, 140, 74}, {181, 148, 115}, {181, 148, 123}, {181, 156, 107}, {189, 148, 123}, {189, 156, 82}, {189, 156, 123}, {189, 156, 132}, {189, 189, 189}, {198, 156, 123}, {198, 165, 132}, {206, 165, 99}, {206, 165, 132}, {206, 173, 140}, {206, 206, 206}, {214, 173, 115}, {214, 173, 140}, {222, 181, 148}, {222, 189, 132}, {222, 189, 156}, {222, 222, 222}, {231, 198, 165}, {231, 231, 231}, {239, 206, 173} }; /* Call this instead of exit(), so we can clean up SDL: atexit() is evil. */ static void quit(int rc) { SDL_Quit(); exit(rc); } /* All RGB2YUV conversion code and some other parts of code has been taken from testoverlay.c */ /* NOTE: These RGB conversion functions are not intended for speed, only as examples. */ void RGBtoYUV(Uint8 *rgb, int *yuv, int monochrome, int luminance) { if (monochrome) { #if 1 /* these are the two formulas that I found on the FourCC site... */ yuv[0] = 0.299*rgb[0] + 0.587*rgb[1] + 0.114*rgb[2]; yuv[1] = 128; yuv[2] = 128; #else yuv[0] = (0.257 * rgb[0]) + (0.504 * rgb[1]) + (0.098 * rgb[2]) + 16; yuv[1] = 128; yuv[2] = 128; #endif } else { #if 1 /* these are the two formulas that I found on the FourCC site... */ yuv[0] = 0.299*rgb[0] + 0.587*rgb[1] + 0.114*rgb[2]; yuv[1] = (rgb[2]-yuv[0])*0.565 + 128; yuv[2] = (rgb[0]-yuv[0])*0.713 + 128; #else yuv[0] = (0.257 * rgb[0]) + (0.504 * rgb[1]) + (0.098 * rgb[2]) + 16; yuv[1] = 128 - (0.148 * rgb[0]) - (0.291 * rgb[1]) + (0.439 * rgb[2]); yuv[2] = 128 + (0.439 * rgb[0]) - (0.368 * rgb[1]) - (0.071 * rgb[2]); #endif } if (luminance!=100) { yuv[0]=yuv[0]*luminance/100; if (yuv[0]>255) yuv[0]=255; } } void ConvertRGBtoYV12(SDL_Surface *s, SDL_Overlay *o, int monochrome, int luminance) { int x,y; int yuv[3]; Uint8 *p,*op[3]; SDL_LockSurface(s); SDL_LockYUVOverlay(o); /* Convert */ for(y=0; y<s->h && y<o->h; y++) { p=((Uint8 *) s->pixels)+s->pitch*y; op[0]=o->pixels[0]+o->pitches[0]*y; op[1]=o->pixels[1]+o->pitches[1]*(y/2); op[2]=o->pixels[2]+o->pitches[2]*(y/2); for(x=0; x<s->w && x<o->w; x++) { RGBtoYUV(p, yuv, monochrome, luminance); *(op[0]++)=yuv[0]; if(x%2==0 && y%2==0) { *(op[1]++)=yuv[2]; *(op[2]++)=yuv[1]; } p+=s->format->BytesPerPixel; } } SDL_UnlockYUVOverlay(o); SDL_UnlockSurface(s); } void ConvertRGBtoIYUV(SDL_Surface *s, SDL_Overlay *o, int monochrome, int luminance) { int x,y; int yuv[3]; Uint8 *p,*op[3]; SDL_LockSurface(s); SDL_LockYUVOverlay(o); /* Convert */ for(y=0; y<s->h && y<o->h; y++) { p=((Uint8 *) s->pixels)+s->pitch*y; op[0]=o->pixels[0]+o->pitches[0]*y; op[1]=o->pixels[1]+o->pitches[1]*(y/2); op[2]=o->pixels[2]+o->pitches[2]*(y/2); for(x=0; x<s->w && x<o->w; x++) { RGBtoYUV(p,yuv, monochrome, luminance); *(op[0]++)=yuv[0]; if(x%2==0 && y%2==0) { *(op[1]++)=yuv[1]; *(op[2]++)=yuv[2]; } p+=s->format->BytesPerPixel; } } SDL_UnlockYUVOverlay(o); SDL_UnlockSurface(s); } void ConvertRGBtoUYVY(SDL_Surface *s, SDL_Overlay *o, int monochrome, int luminance) { int x,y; int yuv[3]; Uint8 *p,*op; SDL_LockSurface(s); SDL_LockYUVOverlay(o); for(y=0; y<s->h && y<o->h; y++) { p=((Uint8 *) s->pixels)+s->pitch*y; op=o->pixels[0]+o->pitches[0]*y; for(x=0; x<s->w && x<o->w; x++) { RGBtoYUV(p, yuv, monochrome, luminance); if(x%2==0) { *(op++)=yuv[1]; *(op++)=yuv[0]; *(op++)=yuv[2]; } else *(op++)=yuv[0]; p+=s->format->BytesPerPixel; } } SDL_UnlockYUVOverlay(o); SDL_UnlockSurface(s); } void ConvertRGBtoYVYU(SDL_Surface *s, SDL_Overlay *o, int monochrome, int luminance) { int x,y; int yuv[3]; Uint8 *p,*op; SDL_LockSurface(s); SDL_LockYUVOverlay(o); for(y=0; y<s->h && y<o->h; y++) { p=((Uint8 *) s->pixels)+s->pitch*y; op=o->pixels[0]+o->pitches[0]*y; for(x=0; x<s->w && x<o->w; x++) { RGBtoYUV(p,yuv, monochrome, luminance); if(x%2==0) { *(op++)=yuv[0]; *(op++)=yuv[2]; op[1]=yuv[1]; } else { *op=yuv[0]; op+=2; } p+=s->format->BytesPerPixel; } } SDL_UnlockYUVOverlay(o); SDL_UnlockSurface(s); } void ConvertRGBtoYUY2(SDL_Surface *s, SDL_Overlay *o, int monochrome, int luminance) { int x,y; int yuv[3]; Uint8 *p,*op; SDL_LockSurface(s); SDL_LockYUVOverlay(o); for(y=0; y<s->h && y<o->h; y++) { p=((Uint8 *) s->pixels)+s->pitch*y; op=o->pixels[0]+o->pitches[0]*y; for(x=0; x<s->w && x<o->w; x++) { RGBtoYUV(p,yuv, monochrome, luminance); if(x%2==0) { *(op++)=yuv[0]; *(op++)=yuv[1]; op[1]=yuv[2]; } else { *op=yuv[0]; op+=2; } p+=s->format->BytesPerPixel; } } SDL_UnlockYUVOverlay(o); SDL_UnlockSurface(s); } static void PrintUsage(char *argv0) { fprintf(stderr, "Usage: %s [arg] [arg] [arg] ...\n", argv0); fprintf(stderr, "\n"); fprintf(stderr, "Where 'arg' is any of the following options:\n"); fprintf(stderr, "\n"); fprintf(stderr, " -fps <frames per second>\n"); fprintf(stderr, " -format <fmt> (one of the: YV12, IYUV, YUY2, UYVY, YVYU)\n"); fprintf(stderr, " -scale <scale factor> (initial scale of the overlay)\n"); fprintf(stderr, " -help (shows this help)\n"); fprintf(stderr, "\n"); fprintf(stderr, "Press ESC to exit, or SPACE to freeze the movie while application running.\n"); fprintf(stderr, "\n"); } int main(int argc, char **argv) { Uint8* RawMooseData; SDL_RWops* handle; SDL_Surface* screen; SDL_Surface* MooseFrame[MOOSEFRAMES_COUNT]; SDL_Overlay* overlay; SDL_Rect overlayrect; SDL_Event event; Uint32 lastftick; int paused=0; int resized=0; int i; int fps=12; int fpsdelay; int overlay_format=SDL_YUY2_OVERLAY; int scale=5; if (SDL_Init(SDL_INIT_VIDEO | SDL_INIT_NOPARACHUTE) < 0) { fprintf(stderr, "Couldn't initialize SDL: %s\n", SDL_GetError()); return 3; } while ( argc > 1 ) { if (strcmp(argv[1], "-fps")== 0) { if (argv[2]) { fps = atoi(argv[2]); if (fps==0) { fprintf(stderr, "The -fps option requires an argument [from 1 to 1000], default is 12.\n"); quit(10); } if ((fps<0) || (fps>1000)) { fprintf(stderr, "The -fps option must be in range from 1 to 1000, default is 12.\n"); quit(10); } argv += 2; argc -= 2; } else { fprintf(stderr, "The -fps option requires an argument [from 1 to 1000], default is 12.\n"); quit(10); } } else if (strcmp(argv[1], "-format") == 0) { if (argv[2]) { if (!strcmp(argv[2],"YV12")) overlay_format = SDL_YV12_OVERLAY; else if(!strcmp(argv[2],"IYUV")) overlay_format = SDL_IYUV_OVERLAY; else if(!strcmp(argv[2],"YUY2")) overlay_format = SDL_YUY2_OVERLAY; else if(!strcmp(argv[2],"UYVY")) overlay_format = SDL_UYVY_OVERLAY; else if(!strcmp(argv[2],"YVYU")) overlay_format = SDL_YVYU_OVERLAY; else { fprintf(stderr, "The -format option %s is not recognized, see help for info.\n", argv[2]); quit(10); } argv += 2; argc -= 2; } else { fprintf(stderr, "The -format option requires an argument, default is YUY2.\n"); quit(10); } } else if (strcmp(argv[1], "-scale") == 0) { if (argv[2]) { scale = atoi(argv[2]); if (scale==0) { fprintf(stderr, "The -scale option requires an argument [from 1 to 50], default is 5.\n"); quit(10); } if ((scale<0) || (scale>50)) { fprintf(stderr, "The -scale option must be in range from 1 to 50, default is 5.\n"); quit(10); } argv += 2; argc -= 2; } else { fprintf(stderr, "The -fps option requires an argument [from 1 to 1000], default is 12.\n"); quit(10); } } else if ((strcmp(argv[1], "-help") == 0 ) || (strcmp(argv[1], "-h") == 0)) { PrintUsage(argv[0]); quit(0); } else { fprintf(stderr, "Unrecognized option: %s.\n", argv[1]); quit(10); } break; } RawMooseData=(Uint8*)malloc(MOOSEFRAME_SIZE * MOOSEFRAMES_COUNT); if (RawMooseData==NULL) { fprintf(stderr, "Can't allocate memory for movie !\n"); free(RawMooseData); quit(1); } /* load the trojan moose images */ handle=SDL_RWFromFile("moose.dat", "rb"); if (handle==NULL) { fprintf(stderr, "Can't find the file moose.dat !\n"); free(RawMooseData); quit(2); } SDL_RWread(handle, RawMooseData, MOOSEFRAME_SIZE, MOOSEFRAMES_COUNT); SDL_RWclose(handle); /* Set video mode */ if ( (screen=SDL_SetVideoMode(MOOSEPIC_W*scale, MOOSEPIC_H*scale, 0, SDL_RESIZABLE | SDL_SWSURFACE)) == NULL ) { fprintf(stderr, "Couldn't set video mode: %s\n", SDL_GetError()); free(RawMooseData); quit(4); } /* Set the window manager title bar */ SDL_WM_SetCaption("SDL test overlay: running moose", "testoverlay2"); for (i=0; i<MOOSEFRAMES_COUNT; i++) { MooseFrame[i]=SDL_CreateRGBSurfaceFrom(RawMooseData+i*MOOSEFRAME_SIZE, MOOSEPIC_W, MOOSEPIC_H, 8, MOOSEPIC_W, 0, 0, 0, 0); if (MooseFrame[i]==NULL) { fprintf(stderr, "Couldn't create SDL_Surfaces:%s\n", SDL_GetError()); free(RawMooseData); quit(5); } SDL_SetColors(MooseFrame[i], MooseColors, 0, 84); { SDL_Surface *newsurf; SDL_PixelFormat format; format.palette=NULL; format.BitsPerPixel=32; format.BytesPerPixel=4; #if SDL_BYTEORDER == SDL_LIL_ENDIAN format.Rshift=0; format.Gshift=8; format.Bshift=16; #else format.Rshift=24; format.Gshift=16; format.Bshift=8; #endif format.Ashift=0; format.Rmask=0xff<<format.Rshift; format.Gmask=0xff<<format.Gshift; format.Bmask=0xff<<format.Bshift; format.Amask=0; format.Rloss=0; format.Gloss=0; format.Bloss=0; format.Aloss=8; format.colorkey=0; format.alpha=0; newsurf=SDL_ConvertSurface(MooseFrame[i], &format, SDL_SWSURFACE); if(!newsurf) { fprintf(stderr, "Couldn't convert picture to 32bits RGB: %s\n", SDL_GetError()); quit(6); } SDL_FreeSurface(MooseFrame[i]); MooseFrame[i]=newsurf; } } free(RawMooseData); overlay=SDL_CreateYUVOverlay(MOOSEPIC_W, MOOSEPIC_H, overlay_format, screen); if (!overlay) { fprintf(stderr, "Couldn't create overlay: %s\n", SDL_GetError()); quit(7); } printf("Created %dx%dx%d %s %s overlay\n",overlay->w,overlay->h,overlay->planes, overlay->hw_overlay?"hardware":"software", overlay->format==SDL_YV12_OVERLAY?"YV12": overlay->format==SDL_IYUV_OVERLAY?"IYUV": overlay->format==SDL_YUY2_OVERLAY?"YUY2": overlay->format==SDL_UYVY_OVERLAY?"UYVY": overlay->format==SDL_YVYU_OVERLAY?"YVYU": "Unknown"); for(i=0; i<overlay->planes; i++) { printf(" plane %d: pitch=%d\n", i, overlay->pitches[i]); } overlayrect.x=0; overlayrect.y=0; overlayrect.w=MOOSEPIC_W*scale; overlayrect.h=MOOSEPIC_H*scale; /* set the start frame */ i=0; fpsdelay=1000/fps; /* Ignore key up events, they don't even get filtered */ SDL_EventState(SDL_KEYUP, SDL_IGNORE); lastftick=SDL_GetTicks(); /* Loop, waiting for QUIT or RESIZE */ while (1) { if (SDL_PollEvent(&event)) { switch (event.type) { case SDL_VIDEORESIZE: screen=SDL_SetVideoMode(event.resize.w, event.resize.h, 0, SDL_RESIZABLE | SDL_SWSURFACE); overlayrect.w=event.resize.w; overlayrect.h=event.resize.h; if (paused) { resized=1; } break; case SDL_MOUSEBUTTONDOWN: overlayrect.x = event.button.x - overlayrect.w/2; overlayrect.y = event.button.y - overlayrect.h/2; break; case SDL_KEYDOWN: if (event.key.keysym.sym == SDLK_SPACE) { paused=!paused; break; } if (event.key.keysym.sym != SDLK_ESCAPE) { break; } case SDL_QUIT: SDL_FreeYUVOverlay(overlay); for (i=0; i<MOOSEFRAMES_COUNT; i++) { SDL_FreeSurface(MooseFrame[i]); } quit(0); } } if ((!paused)||(resized)) { if (((SDL_GetTicks()-lastftick)>fpsdelay)||(resized)) { lastftick=SDL_GetTicks(); switch (overlay_format) { case SDL_YUY2_OVERLAY: ConvertRGBtoYUY2(MooseFrame[i], overlay, 0, 100); break; case SDL_YV12_OVERLAY: ConvertRGBtoYV12(MooseFrame[i], overlay, 0, 100); break; case SDL_UYVY_OVERLAY: ConvertRGBtoUYVY(MooseFrame[i], overlay, 0, 100); break; case SDL_YVYU_OVERLAY: ConvertRGBtoYVYU(MooseFrame[i], overlay, 0, 100); break; case SDL_IYUV_OVERLAY: ConvertRGBtoIYUV(MooseFrame[i], overlay, 0, 100); break; } SDL_DisplayYUVOverlay(overlay, &overlayrect); if (!resized) { i++; if (i==10) { i=0; } } else { resized=0; } } } /* kind of timeslice to OS */ SDL_Delay(1); } SDL_Quit(); return 0; }