/********************************************************************************* * recordMyDesktop * ********************************************************************************** * * * Copyright (C) 2006 John Varouhakis * * * * * * This program is free software; you can redistribute it and/or modify * * it under the terms of the GNU General Public License as published by * * the Free Software Foundation; either version 2 of the License, or * * (at your option) any later version. * * * * This program 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 General Public License for more details. * * * * You should have received a copy of the GNU General Public License * * along with this program; if not, write to the Free Software * * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA * * * * * * * * For further information contact me at johnvarouhakis@gmail.com * **********************************************************************************/ #ifndef RECORDMYDESKTOP_H #define RECORDMYDESKTOP_H 1 #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include //define whcih way we are reading a pixmap #if __BYTE_ORDER == __LITTLE_ENDIAN #define __ABYTE 3 #define __RBYTE 2 #define __GBYTE 1 #define __BBYTE 0 #elif __BYTE_ORDER == __BIG_ENDIAN #define __ABYTE 0 #define __RBYTE 1 #define __GBYTE 2 #define __BBYTE 3 #else #error Only little-endian and big-endian systems are supported #endif //do not be confused //this is useless and obsolete. //There are no plans for other fotmats enum {UNSPECIFIED,OGG_THEORA_VORBIS}; /**Structs*/ typedef struct _DisplaySpecs{ //this struct holds some basic information int screen; //about the display,needed mostly for uint width; //validity checks at startup uint height; Window root; Visual *visual; GC gc; int depth; unsigned long bpixel; unsigned long wpixel; }DisplaySpecs; typedef struct _WGeometry{ //basic geometry of a window or area int x; int y; int width; int height; }WGeometry; typedef struct _RectArea{ //an area that has been damaged gets stored WGeometry geom; //in a list comprised of structs of this type struct _RectArea *prev,*next; }RectArea; typedef struct _BRWindow{ //'basic recorded window' specs WGeometry geom; //window attributes WGeometry rgeom; //part of window that is recorded int nbytes; //size of zpixmap when screenshoting Window windowid; //id }BRWindow; //defaults in the following comment lines may be out of sync with reality //check DEFAULT_ARGS macro further bellow typedef struct _ProgArgs{ int delay; //start up delay Window windowid; //window to record(default root) char *display; //display to connect(default :0) int x,y; //x,y offset(default 0,0) int width,height; //defaults to window width and height int quietmode; //no messages to stderr,stdout char *filename; //output file(default out.[ogg|*]) int encoding; //encoding(default OGG_THEORA_VORBIS) int cursor_color; //black or white=>1 or 0 int have_dummy_cursor;//disable/enable drawing of the dummy cursor int xfixes_cursor; //disable/enable drawing of a cursor obtained //through the xfixes extension float fps; //desired framerate(default 15) unsigned int frequency; //desired frequency (default 22050) unsigned int channels; //no of channels(default 2) char *device; //default sound device(default according to alsa or oss) int nosound; //do not record sound(default 0) int noshared; //do not use shared memory extension(default 1) int nocondshared; //de not use shared memory on large image aquititions int shared_thres; //threshold to use shared memory int full_shots; //do not poll damage, take full screenshots int no_quick_subsample;//average pixels in chroma planes int v_bitrate,v_quality,s_quality;//video bitrate,video-sound quality int dropframes; //option for theora encoder int encOnTheFly; //encode while recording, no caching(default 0) char *workdir; //directory to be used for cache files(default $HOME) }ProgArgs; //this struct holds anything related to encoding AND //writting out to file. typedef struct _EncData{ ogg_stream_state m_ogg_ts;//theora ogg_stream_state m_ogg_vs;//vorbis ogg_page m_ogg_pg;//this could be avoided since // it is used only while initializing ogg_packet m_ogg_pckt1;//theora stream ogg_packet m_ogg_pckt2;//vorbis stream //theora data theora_state m_th_st; theora_info m_th_inf; theora_comment m_th_cmmnt; yuv_buffer yuv; //vorbis data vorbis_info m_vo_inf; vorbis_comment m_vo_cmmnt; vorbis_dsp_state m_vo_dsp; vorbis_block m_vo_block; //these should be 0, since area is quantized //before input int x_offset, y_offset; //our file FILE *fp; }EncData; //this struct will hold a few basic //information, needed for caching the frames. typedef struct _CacheData{ char *workdir, //The directory were the project will be stored, while recording. //Since this will take a lot of space, the user must be //able to change the location. *projname, //This is the name of the folder that will hold the project. //It is rMD-session-%d where %d is the pid of the current proccess. //This way, running two instances will not create problems //and also, a frontend can identify leftovers from a possible crash //and delete them *imgdata, //workdir+projname+img.out.gz *audiodata; //workdir+projname+audio.pcm gzFile *ifp; //image data file pointer FILE *afp; //audio data file pointer }CacheData; //sound buffer //sound keeps coming so we que it in this list //which we then traverse typedef struct _SndBuffer{ signed char *data; struct _SndBuffer *next; }SndBuffer; //this structure holds any data related to the program //It's usage is mostly to be given as an argument to the //threads,so they will have access to the program data, avoiding //at the same time usage of any globals. typedef struct _ProgData{ ProgArgs args;//the program arguments DisplaySpecs specs;//Display specific information BRWindow brwin;//recording window Display *dpy;//curtrent display XImage *image;//the image that holds the current full screenshot XImage *shimage;//the image that holds the current full screenshot(shared memory) unsigned char *dummy_pointer;//a dummy pointer to be drawn in every frame //data is casted to unsigned for later use in YUV buffer int dummy_p_size;//initially 16x16,always square unsigned char npxl;//this is the no pixel convention when drawing the dummy pointer char *datamain,//the data of image *datash,//the data of shimage *datatemp;//buffer for the temporary image,which will be //preallocated in case shared memory is not used. RectArea *rect_root[2];//the interchanging list roots for storing the changed regions int list_selector,//selector for the above damage_event,//damage event base code damage_error,//damage error base code running; SndBuffer *sound_buffer; EncData *enc_data; CacheData *cache_data; int hard_pause;//if sound device doesn't support pause //we have to close and reopen int avd;//syncronization among audio and video unsigned int periodtime, frametime; pthread_mutex_t list_mutex[2],//mutexes for concurrency protection of the lists sound_buffer_mutex, libogg_mutex,//libogg is not thread safe yuv_mutex;//this might not be needed since we only have //one read-only and one write-only thread //also on previous versions, y component was looped separately //and then u and v so this was needed to avoid wrong coloring to render //Currently this mutex only prevents the cursor from flickering pthread_cond_t time_cond,//this gets a broadcast by the handler whenever it's time to get a screenshot pause_cond,//this is blocks execution, when program is paused sound_buffer_ready,//sound encoding finished sound_data_read,//a buffer is ready for proccessing image_buffer_ready;//image encoding finished snd_pcm_t *sound_handle; snd_pcm_uframes_t periodsize; }ProgData; //This is the header of every frame. //Reconstruction will be correct only if made on //the same platform. //We need the total number of blocks //for each plane. //The number of the frame compared to the //number of time expirations at the time of //caching, will enable us to make up for lost frames. //default 4+4+2+2+2=14!bad! //me add pad, make god of 2 happy! typedef struct _FrameHeader{ char frame_prefix[4];//always FRAM u_int32_t frameno,//number of frame(cached frames) current_total;//number of frames that should have been //taken at time of caching this one u_int16_t Ynum,//number of changed blocks in the Y plane Unum,//number of changed blocks in the U plane Vnum;//number of changed blocks in the V plane u_int16_t pad;//always zero }FrameHeader; //The frame after retrieval. //Based on the Header information //we can read the correct amount of bytes. typedef struct _CachedFrame{ FrameHeader *header; unsigned char *YBlocks;//identifying number on the grid, starting at top left unsigned char *UBlocks;// >> >> unsigned char *VBlocks;// >> >> unsigned char *YData;//pointer to data for the blocks that have changed, unsigned char *UData;//which have to be remapped on the buffer when reading unsigned char *VData; }CachedFrame; /**Globals*/ //I've read somewhere that I'll go to hell for using globals... int Paused,*Running,Aborted; pthread_cond_t *time_cond,*pause_cond; unsigned char Yr[256],Yg[256],Yb[256], Ur[256],Ug[256],Ub[256], Vr[256],Vg[256],Vb[256]; //the following values are of no effect //but they might be usefull later for profiling unsigned int inserts,//total insertions in the lists frames_total,//frames calculated by total time expirations frames_lost;//the value of shame //used to determine frame drop which can //happen on failure to receive a signal over a condition variable int capture_busy, encoder_busy; /**Macros*/ #define CLIP_EVENT_AREA(e,brwin,wgeom){\ if(((e)->area.x<=(brwin)->rgeom.x)&&((e)->area.y<=(brwin)->rgeom.y)&&\ ((e)->area.width>=(brwin)->rgeom.width)&&((e)->area.height<(brwin)->rgeom.height)){\ (wgeom)->x=(brwin)->rgeom.x;\ (wgeom)->y=(brwin)->rgeom.y;\ (wgeom)->width=(brwin)->rgeom.width;\ (wgeom)->height=(brwin)->rgeom.height;\ }\ else{\ (wgeom)->x=((((e)->area.x+(e)->area.width>=(brwin)->rgeom.x)&&\ ((e)->area.x<=(brwin)->rgeom.x+(brwin)->rgeom.width))?\ (((e)->area.x<=(brwin)->rgeom.x)?(brwin)->rgeom.x:(e)->area.x):-1);\ \ (wgeom)->y=((((e)->area.y+(e)->area.height>=(brwin)->rgeom.y)&&\ ((e)->area.y<=(brwin)->rgeom.y+(brwin)->rgeom.height))?\ (((e)->area.y<=(brwin)->rgeom.y)?(brwin)->rgeom.y:(e)->area.y):-1);\ \ (wgeom)->width=((e)->area.x<=(brwin)->rgeom.x)?\ (e)->area.width-((brwin)->rgeom.x-(e)->area.x):\ ((e)->area.x<=(brwin)->rgeom.x+(brwin)->rgeom.width)?\ (((brwin)->rgeom.width-(e)->area.x+(brwin)->rgeom.x<(e)->area.width)?\ (brwin)->rgeom.width-(e)->area.x+(brwin)->rgeom.x:e->area.width):-1;\ \ (wgeom)->height=((e)->area.y<=(brwin)->rgeom.y)?\ (e)->area.height-((brwin)->rgeom.y-(e)->area.y):\ ((e)->area.y<=(brwin)->rgeom.y+(brwin)->rgeom.height)?\ (((brwin)->rgeom.height-(e)->area.y+(brwin)->rgeom.y<(e)->area.height)?\ (brwin)->rgeom.height-(e)->area.y+(brwin)->rgeom.y:(e)->area.height):-1;\ \ if((wgeom)->width>(brwin)->rgeom.width)(wgeom)->width=(brwin)->rgeom.width;\ if((wgeom)->height>(brwin)->rgeom.height)(wgeom)->height=(brwin)->rgeom.height;\ }\ } #define CLIP_DUMMY_POINTER_AREA(dummy_p_area,brwin,wgeom){\ (wgeom)->x=((((dummy_p_area).x+(dummy_p_area).width>=(brwin)->rgeom.x)&&\ ((dummy_p_area).x<=(brwin)->rgeom.x+(brwin)->rgeom.width))?\ (((dummy_p_area).x<=(brwin)->rgeom.x)?(brwin)->rgeom.x:(dummy_p_area).x):-1);\ (wgeom)->y=((((dummy_p_area).y+(dummy_p_area).height>=(brwin)->rgeom.y)&&\ ((dummy_p_area).y<=(brwin)->rgeom.y+(brwin)->rgeom.height))?\ (((dummy_p_area).y<=(brwin)->rgeom.y)?(brwin)->rgeom.y:(dummy_p_area).y):-1);\ (wgeom)->width=((dummy_p_area).x<=(brwin)->rgeom.x)?\ (dummy_p_area).width-((brwin)->rgeom.x-(dummy_p_area).x):\ ((dummy_p_area).x<=(brwin)->rgeom.x+(brwin)->rgeom.width)?\ ((brwin)->rgeom.width-(dummy_p_area).x+(brwin)->rgeom.x<(dummy_p_area).width)?\ (brwin)->rgeom.width-(dummy_p_area).x+(brwin)->rgeom.x:(dummy_p_area).width:-1;\ (wgeom)->height=((dummy_p_area).y<=(brwin)->rgeom.y)?\ (dummy_p_area).height-((brwin)->rgeom.y-(dummy_p_area).y):\ ((dummy_p_area).y<=(brwin)->rgeom.y+(brwin)->rgeom.height)?\ ((brwin)->rgeom.height-(dummy_p_area).y+(brwin)->rgeom.y<(dummy_p_area).height)?\ (brwin)->rgeom.height-(dummy_p_area).y+(brwin)->rgeom.y:(dummy_p_area).height:-1;\ if((wgeom)->width>(brwin)->rgeom.width)(wgeom)->width=(brwin)->rgeom.width;\ if((wgeom)->height>(brwin)->rgeom.height)(wgeom)->height=(brwin)->rgeom.height;\ } #define DEFAULT_ARGS(args){\ (args)->delay=0;\ if(getenv("DISPLAY")!=NULL){\ (args)->display=(char *)malloc(strlen(getenv("DISPLAY"))+1);\ strcpy((args)->display,getenv("DISPLAY"));\ }\ else\ (args)->display=NULL;\ (args)->windowid=(args)->x=(args)->y\ =(args)->width=(args)->height=(args)->quietmode\ =(args)->nosound=(args)->full_shots=(args)->encOnTheFly=0;\ (args)->noshared=1;\ (args)->dropframes=(args)->nocondshared=0;\ (args)->no_quick_subsample=1;\ (args)->filename=(char *)malloc(8);\ strcpy((args)->filename,"out.ogg");\ (args)->encoding=OGG_THEORA_VORBIS;\ (args)->cursor_color=1;\ (args)->shared_thres=75;\ (args)->have_dummy_cursor=0;\ (args)->xfixes_cursor=1;\ (args)->device=(char *)malloc(8);\ strcpy((args)->device,"hw:0,0");\ (args)->fps=15;\ (args)->channels=1;\ (args)->frequency=22050;\ (args)->v_bitrate=45000;\ (args)->v_quality=63;\ (args)->s_quality=10;\ (args)->workdir=(char *)malloc(strlen(getenv("HOME"))+1);\ strcpy((args)->workdir,getenv("HOME"));\ } #define QUERY_DISPLAY_SPECS(display,specstruct){\ (specstruct)->screen=DefaultScreen(display);\ (specstruct)->width=DisplayWidth(display,(specstruct)->screen);\ (specstruct)->height=DisplayHeight(display,(specstruct)->screen);\ (specstruct)->root=RootWindow(display,(specstruct)->screen);\ (specstruct)->visual=DefaultVisual(display,(specstruct)->screen);\ (specstruct)->gc=DefaultGC(display,(specstruct)->screen);\ (specstruct)->depth=DefaultDepth(display,(specstruct)->screen);\ (specstruct)->bpixel=XBlackPixel(display,(specstruct)->screen);\ (specstruct)->wpixel=XWhitePixel(display,(specstruct)->screen);\ } #define AVG_4_PIXELS(data_array,width_img,k_tm,i_tm,offset)\ ((data_array[(k_tm*width_img+i_tm)*4+offset]+data_array[((k_tm-1)*width_img+i_tm)*4+offset]\ +data_array[(k_tm*width_img+i_tm-1)*4+offset]+data_array[((k_tm-1)*width_img+i_tm-1)*4+offset])/4) #define UPDATE_YUV_BUFFER_SH(yuv,data,x_tm,y_tm,width_tm,height_tm){\ int i,k;\ for(k=y_tm;ky[i+k*yuv->y_width]=Yr[data[(i+k*yuv->y_width)*4+__RBYTE]] + Yg[data[(i+k*yuv->y_width)*4+__GBYTE]] + Yb[data[(i+k*yuv->y_width)*4+__BBYTE]];\ if((k%2)&&(i%2)){\ yuv->u[i/2+k/2*yuv->uv_width]=Ur[data[(i+k*yuv->y_width)*4+__RBYTE]] + Ug[data[(i+k*yuv->y_width)*4+__GBYTE]] + Ub[data[(i+k*yuv->y_width)*4+__BBYTE]] ;\ yuv->v[i/2+k/2*yuv->uv_width]=Vr[data[(i+k*yuv->y_width)*4+__RBYTE]] + Vg[data[(i+k*yuv->y_width)*4+__GBYTE]] + Vb[data[(i+k*yuv->y_width)*4+__BBYTE]] ;\ }\ }\ }\ } #define UPDATE_YUV_BUFFER_SH_AVG(yuv,data,x_tm,y_tm,width_tm,height_tm){\ int i,k;\ unsigned char avg0,avg1,avg2;\ for(k=y_tm;ky[i+k*yuv->y_width]=Yr[data[(i+k*yuv->y_width)*4+__RBYTE]] + Yg[data[(i+k*yuv->y_width)*4+__GBYTE]] + Yb[data[(i+k*yuv->y_width)*4+__BBYTE]];\ if((k%2)&&(i%2)){\ avg2=AVG_4_PIXELS(data,(yuv->y_width),k,i,__RBYTE);\ avg1=AVG_4_PIXELS(data,(yuv->y_width),k,i,__GBYTE);\ avg0=AVG_4_PIXELS(data,(yuv->y_width),k,i,__BBYTE);\ yuv->u[i/2+k/2*yuv->uv_width]=Ur[avg2] +\ Ug[avg1] +\ Ub[avg0] ;\ yuv->v[i/2+k/2*yuv->uv_width]=Vr[avg2] +\ Vg[avg1] +\ Vb[avg0] ;\ }\ }\ }\ } #define UPDATE_YUV_BUFFER_IM(yuv,data,x_tm,y_tm,width_tm,height_tm){\ int i,k,j=0;\ int x_2=x_tm/2,y_2=y_tm/2;\ for(k=0;ky[x_tm+i+(k+y_tm)*yuv->y_width]=Yr[data[(j*4)+__RBYTE]] + Yg[data[(j*4)+__GBYTE]] + Yb[data[(j*4)+__BBYTE]] ;\ if((k%2)&&(i%2)){\ yuv->u[x_2+i/2+(k/2+y_2)*yuv->uv_width]=\ Ur[data[(k*width_tm+i)*4+__RBYTE]] + Ug[data[(k*width_tm+i)*4+__GBYTE]] + Ub[data[(k*width_tm+i)*4+__BBYTE]];\ yuv->v[x_2+i/2+(k/2+y_2)*yuv->uv_width]=\ Vr[data[(k*width_tm+i)*4+__RBYTE]] + Vg[data[(k*width_tm+i)*4+__GBYTE]] + Vb[data[(k*width_tm+i)*4+__BBYTE]];\ }\ \ j++;\ }\ }\ } #define UPDATE_YUV_BUFFER_IM_AVG(yuv,data,x_tm,y_tm,width_tm,height_tm){\ int i,k,j=0;\ unsigned char avg0,avg1,avg2;\ int x_2=x_tm/2,y_2=y_tm/2;\ for(k=0;ky[x_tm+i+(k+y_tm)*yuv->y_width]=Yr[data[(j*4)+__RBYTE]] + Yg[data[(j*4)+__GBYTE]] + Yb[data[(j*4)+__BBYTE]] ;\ if((k%2)&&(i%2)){\ avg2=AVG_4_PIXELS(data,width_tm,k,i,__RBYTE);\ avg1=AVG_4_PIXELS(data,width_tm,k,i,__GBYTE);\ avg0=AVG_4_PIXELS(data,width_tm,k,i,__BBYTE);\ yuv->u[x_2+i/2+(k/2+y_2)*yuv->uv_width]=\ Ur[avg2] + Ug[avg1] +\ Ub[avg0];\ yuv->v[x_2+i/2+(k/2+y_2)*yuv->uv_width]=\ Vr[avg2] + Vg[avg1] +\ Vb[avg0];\ }\ \ j++;\ }\ }\ } #define XFIXES_POINTER_TO_YUV(yuv,data,x_tm,y_tm,width_tm,height_tm,column_discard_stride){\ int i,k,j=0;\ unsigned char avg0,avg1,avg2,avg3;\ int x_2=x_tm/2,y_2=y_tm/2;\ for(k=0;ky[x_tm+i+(k+y_tm)*yuv->y_width]=\ (yuv->y[x_tm+i+(k+y_tm)*yuv->y_width]*(UCHAR_MAX-data[(j*4)+__ABYTE])+\ (Yr[data[(j*4)+__RBYTE]] + Yg[data[(j*4)+__GBYTE]] + Yb[data[(j*4)+__BBYTE]])*data[(j*4)+__ABYTE])/UCHAR_MAX ;\ if((k%2)&&(i%2)){\ avg3=AVG_4_PIXELS(data,(width_tm+column_discard_stride),k,i,__ABYTE);\ avg2=AVG_4_PIXELS(data,(width_tm+column_discard_stride),k,i,__RBYTE);\ avg1=AVG_4_PIXELS(data,(width_tm+column_discard_stride),k,i,__GBYTE);\ avg0=AVG_4_PIXELS(data,(width_tm+column_discard_stride),k,i,__BBYTE);\ yuv->u[x_2+i/2+(k/2+y_2)*yuv->uv_width]=\ (yuv->u[x_2+i/2+(k/2+y_2)*yuv->uv_width]*(UCHAR_MAX-avg3)+\ (Ur[avg2] + Ug[avg1] +Ub[avg0])*avg3)/UCHAR_MAX;\ yuv->v[x_2+i/2+(k/2+y_2)*yuv->uv_width]=\ (yuv->v[x_2+i/2+(k/2+y_2)*yuv->uv_width]*(UCHAR_MAX-avg3)+\ (Vr[avg2] + Vg[avg1] +Vb[avg0])*avg3)/UCHAR_MAX;\ }\ j++;\ }\ j+=column_discard_stride;\ }\ } #define DUMMY_POINTER_TO_YUV(yuv,data_tm,x_tm,y_tm,width_tm,height_tm,no_pixel){\ int i,k,j=0;\ int x_2=x_tm/2,y_2=y_tm/2,y_width_2=(yuv)->y_width/2;\ for(k=0;ky[x_tm+i+(k+y_tm)*(yuv)->y_width]=Yr[data_tm[(j*4)+__RBYTE]] + Yg[data_tm[(j*4)+__GBYTE]] + Yb[data_tm[(j*4)+__BBYTE]];\ if((k%2)&&(i%2)){\ yuv->u[x_2+i/2+(k/2+y_2)*y_width_2]=Ur[data_tm[(k*width_tm+i)*4+__RBYTE]] + Ug[data_tm[(k*width_tm+i)*4+__GBYTE]] + Ub[data_tm[(k*width_tm+i)*4+__BBYTE]];\ yuv->v[x_2+i/2+(k/2+y_2)*y_width_2]=Vr[data_tm[(k*width_tm+i)*4+__RBYTE]] + Vg[data_tm[(k*width_tm+i)*4+__GBYTE]] + Vb[data_tm[(k*width_tm+i)*4+__BBYTE]] ;\ }\ }\ j++;\ }\ j+=16-width_tm;\ }\ } #define I16TOA(number,buffer){\ int t_num=(number),k=0,i=0;\ char *t_buf=malloc(8);\ t_num=t_num&((2<<15)-1);\ while(t_num>0){\ int digit=t_num%10;\ t_buf[k]=digit+48;\ t_num-=digit;\ t_num/=10;\ k++;\ }\ while(k>0)\ (buffer)[i++]=t_buf[--k];\ (buffer)[i]='\0';\ free(t_buf);\ };\ #define INIT_FRAME(frame_t,fheader_t,yuv_t){\ (frame_t)->header=(fheader_t);\ (frame_t)->YBlocks=malloc(256);\ (frame_t)->UBlocks=malloc(64);\ (frame_t)->VBlocks=malloc(64);\ (frame_t)->YData=malloc((yuv_t)->y_width*(yuv_t)->y_height);\ (frame_t)->UData=malloc((yuv_t)->uv_width*(yuv_t)->uv_height);\ (frame_t)->VData=malloc((yuv_t)->uv_width*(yuv_t)->uv_height);\ }; #define CLEAR_FRAME(frame_t){\ free((frame_t)->YBlocks);\ free((frame_t)->UBlocks);\ free((frame_t)->VBlocks);\ free((frame_t)->YData);\ free((frame_t)->UData);\ free((frame_t)->VData);\ }; /**Function prototypes*/ void *PollDamage(void *pdata); void *GetFrame(void *pdata); void *EncodeImageBuffer(void *pdata); void *FlushToOgg(void *pdata); void UpdateYUVBuffer(yuv_buffer *yuv,unsigned char *data,int x,int y,int width,int height); void ClearList(RectArea **root); int RectInsert(RectArea **root,WGeometry *wgeom); int CollideRects(WGeometry *wgeom1,WGeometry *wgeom2,WGeometry **wgeom_return,int *ngeoms); void SetExpired(int signum); void RegisterCallbacks(ProgArgs *args); void UpdateImage(Display * dpy,yuv_buffer *yuv,pthread_mutex_t *yuv_mutex,DisplaySpecs *specs,RectArea **root,BRWindow *brwin,EncData *enc,char *datatemp,int noshmem,int no_quick_subsample); int GetZPixmap(Display *dpy,Window root,char *data,int x,int y,int width,int height); int ParseArgs(int argc,char **argv,ProgArgs *arg_return); void QueryExtensions(Display *dpy,ProgArgs *args,int *damage_event,int *damage_error); int SetBRWindow(Display *dpy,BRWindow *brwin,DisplaySpecs *specs,ProgArgs *args); unsigned char *MakeDummyPointer(DisplaySpecs *specs,int size,int color,int type,unsigned char *npxl); void *CaptureSound(void *pdata); void *EncodeSoundBuffer(void *pdata); snd_pcm_t *OpenDev(const char *pcm_dev,unsigned int *channels,unsigned int *frequency,snd_pcm_uframes_t *periodsize,unsigned int *periodtime,int *hardpause); void InitEncoder(ProgData *pdata,EncData *enc_data_t,int buffer_ready); void MakeMatrices(); void SizePack2_8_16(int *start,int *size,int limit); void *CacheImageBuffer(void *pdata); void InitCacheData(ProgData *pdata,EncData *enc_data_t,CacheData *cache_data_t); void *CacheSoundBuffer(void *pdata); void *LoadCache(void *pdata); #endif