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[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [packages/] [services/] [gfx/] [mw/] [v2_0/] [src/] [nanox/] [client.c] - Rev 174
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/* * Copyright (c) 1999, 2000 Greg Haerr <greg@censoft.com> * Copyright (c) 1999, 2000 Alex Holden <alex@linuxhacker.org> * Copyright (c) 1991 David I. Bell * Copyright (c) 2000 Vidar Hokstad * Copyright (c) 2000 Morten Rolland <mortenro@screenmedia.no> * * Permission is granted to use, distribute, or modify this source, * provided that this copyright notice remains intact. * * Client routines to do graphics with windows and graphics contexts. * * Rewritten heavily for speed by Greg Haerr * * Whenever you add a new API entry point, please comment it in the same way * as the rest of the functions in this file. Also add your functions to the * appropriate section(s) in doc/nano-X/nano-X-sections.txt and regenerate the * documentation by running make in the doc/nano-X/ directory. If you do not * have the necessary tools (gtk-doc and the docbook-tools) to rebuild the * documentation, just skip that step and we will do it for you. */ #include <stdio.h> #include <stdlib.h> #include <unistd.h> #include <string.h> #include <stddef.h> #include <signal.h> #include <errno.h> #include <time.h> #if HAVE_SHAREDMEM_SUPPORT #include <sys/types.h> #include <sys/ipc.h> #include <sys/shm.h> #endif #include <sys/time.h> #include <sys/socket.h> #if ELKS #include <linuxmt/na.h> #include <linuxmt/time.h> #elif __ECOS #include <netinet/in.h> #include <sys/select.h> #include <cyg/kernel/kapi.h> #define _NO_SVR_MAPPING #define getpid() ((int)cyg_thread_self()) #else #include <sys/un.h> #if hpux #include <sys/time.h> #else #ifdef __GLIBC__ #include <sys/select.h> #endif #endif #endif #include "nano-X.h" #include "serv.h" #include "nxproto.h" #define GR_CLOSE_FIX 1 /* dirty hack attempts to fix GrClose hang bug*/ #define SHM_BLOCK_SIZE 4096 #ifndef __ECOS /* exported global data */ int nxSocket = -1; /* The network socket descriptor */ #if HAVE_SHAREDMEM_SUPPORT char * nxSharedMem = 0; /* Address of shared memory segment*/ static int nxSharedMemSize; /* Size in bytes of shared mem segment*/ #endif static int regfdmax = -1; /* GrRegisterInput globals*/ static fd_set regfdset; /* readable error strings*/ char *nxErrorStrings[] = { GR_ERROR_STRINGS }; static EVENT_LIST * evlist; /* * The following is the user defined function for handling errors. * If this is not set, then the default action is to close the connection * to the server, describe the error, and then exit. This error function * will only be called when the client asks for events. */ static GR_FNCALLBACKEVENT ErrorFunc = GrDefaultErrorHandler; #else /* __ECOS*/ /* * eCos uses a thread data pointer to store all statics in... */ int ecos_nanox_client_data_index = CYGNUM_KERNEL_THREADS_DATA_MAX; /* readable error strings*/ char *nxErrorStrings[] = { GR_ERROR_STRINGS }; #endif /* * Queue an event in FIFO for later retrieval. */ static void QueueEvent(GR_EVENT *ep) { EVENT_LIST * elp; EVENT_LIST * prevelp; ACCESS_PER_THREAD_DATA() elp = malloc(sizeof(EVENT_LIST)); if (elp) { elp->event = *ep; elp->next = NULL; /* add as last entry on list*/ if (!evlist) { evlist = elp; return; } prevelp = evlist; while (prevelp->next) prevelp = prevelp->next; prevelp->next = elp; } } /* * Retrieve first event in FIFO event queue. */ static void GetNextQueuedEvent(GR_EVENT *ep) { ACCESS_PER_THREAD_DATA() *ep = evlist->event; evlist = evlist->next; } /* * Read n bytes of data from the server into block *b. Make sure the data * you are about to read are actually of the correct type - e.g. make a * check for the first block of data you read as a response to a command * with the Typed version of this function. Returns 0 on success or -1 on * failure. */ static int GrReadBlock(void *b, int n) { int i = 0; char *v; ACCESS_PER_THREAD_DATA() v = (char *) b; nxFlushReq(0L,0); while(v < ((char *) b + n)) { i = read(nxSocket, v, ((char *) b + n - v)); if ( i <= 0 ) { if ( i == 0 ) { /* We should maybe produce an event here, * if possible. */ EPRINTF("nxclient: lost connection to Nano-X " "server\n"); exit(1); } if ( errno == EINTR || errno == EAGAIN ) continue; EPRINTF("nxclient: bad readblock %d\n", i); return -1; } v += i; } return 0; } /* * Read a byte of data from the server. */ static int GrReadByte() { unsigned char c; if(GrReadBlock(&c, 1) == -1) return -1; else return (int) c; } /* * Check if this is a CLIENT_DATA event, in which case we need to read the * data for the event into a buffer and set the event data pointer to the * address of it (or NULL if the malloc() fails). We also don't try to read * any data if datalen is 0. */ static void GrCheckForClientData(GR_EVENT *evp) { GR_EVENT_CLIENT_DATA *event; if(evp->type == GR_EVENT_TYPE_CLIENT_DATA) { event = (GR_EVENT_CLIENT_DATA *)evp; if(!event->datalen) { event->data = NULL; return; } if(!(event->data = malloc(event->datalen))) return; GrReadBlock(event->data, event->datalen); } } /* * Check if the data we are about to read is of the correct type. This * must be done in order to avoid reading an event as part of the response * from the server to a command that requires a reply. */ static int GrCheckBlockType(short packettype) { short b; GR_EVENT event; while (GrReadBlock(&b,sizeof(b)) != -1) { if (b == packettype) return b; if (b == GrNumGetNextEvent) { /*EPRINTF("nxclient %d: Storing event (expected %d)\n", getpid(), packettype);*/ #if 0 /* We only need to handle one event, since the next * event won't arrive until the next GrPrepareSelect() * has been called, and by then we have already * handled this event in GrServiceSelect(). If * GrPrepareSelect() is never called, then we should * never get here either, so that is cool too. */ GrReadBlock(&storedevent_data, sizeof(storedevent_data)); GrCheckForClientData(&storedevent_data); storedevent = 1; #endif /* read event and queue it for later processing*/ GrReadBlock(&event, sizeof(event)); QueueEvent(&event); } else { EPRINTF("nxclient %d: Wrong packet type %d " "(expected %d)\n", getpid(),b, packettype); } } EPRINTF("nxclient %d: Corrupted packet\n", getpid()); return -1; } /* * Actually read a response from the server, much like the GrReadBlock but * make sure the response is of the right kind, e.g. store the event that * may have sneaked into the stream. */ static int GrTypedReadBlock(void *b, int n, int type) { int r; r = GrCheckBlockType(type); if (r != type) return -1; return GrReadBlock(b,n); } /* * Check if the passed event is an error event, and call the error handler if * there is one. After calling the handler (if it returns), the event type is * set to a non-event so that we don't return an error event through the * GetEvent() mechanism. This solution is simpler than creating a client-side * event queue. */ static void CheckErrorEvent(GR_EVENT *ep) { ACCESS_PER_THREAD_DATA() if (ep->type == GR_EVENT_TYPE_ERROR) { if (ErrorFunc) { /* call error handler*/ ErrorFunc(ep); /* then convert to null event*/ ep->type = GR_EVENT_TYPE_NONE; } } } /** * GrFlush: * * Flush the message buffer of any messages it may contain. */ void GrFlush(void) { nxFlushReq(0L,1); } /** * GrOpen: * @Returns: the fd of the connection to the server or -1 on failure * * Open a connection to the graphics server. */ int GrOpen(void) { size_t size; nxOpenReq req; int tries; int ret = 0; #if ELKS struct sockaddr_na name; #define ADDR_FAM AF_NANO #elif defined(__ECOS) struct sockaddr_in name; #define ADDR_FAM AF_INET #else struct sockaddr_un name; #define ADDR_FAM AF_UNIX #endif ACCESS_PER_THREAD_DATA() if (nxSocket == -1) { if((nxSocket = socket(ADDR_FAM, SOCK_STREAM, 0)) == -1) { nxSocket = -1; return -1; } } else { return nxSocket; } #if ELKS name.sun_family = AF_NANO; name.sun_no = GR_NUMB_SOCKET; size = sizeof(struct sockaddr_na); #elif defined(__ECOS) name.sin_family = AF_INET; name.sin_port = htons(6600); /* Nano-X server port*/ name.sin_addr.s_addr = inet_addr("127.0.0.1"); /* Loopback address*/ size = sizeof(struct sockaddr_in); #else name.sun_family = AF_UNIX; strcpy(name.sun_path, GR_NAMED_SOCKET); size = (offsetof(struct sockaddr_un, sun_path) + strlen(name.sun_path) + 1); #endif /* * Try to open the connection for up to a second, * waiting 1/10 second between attempts. */ for (tries=1; tries<=10; ++tries) { struct timespec req; ret = connect(nxSocket, (struct sockaddr *) &name, size); if (ret >= 0) break; req.tv_sec = 0; req.tv_nsec = 100000000L; nanosleep(&req, NULL); EPRINTF("nxclient: retry connect attempt %d\n", tries); } if (ret == -1) { close(nxSocket); nxSocket = -1; return -1; } /* * By Performing the 'GrOpen' without allocating a buffer, just * shuffeling the struct over the wire, we can postpone the * allocation of the client size command buffer, which will never be * allocated if the first command after GrOpen() is * GrReqShmCmds() which allocates a replacement shared memory * segment. * So: Calling GrReqShmCmds() right after GrOpen will prevent the * traditional command queue buffer from being allocated from * the process heap - and only the shared memory segment is * allocated. */ req.reqType = GrNumOpen; req.hilength = 0; req.length = sizeof(req); /* associate the process ID with the client*/ req.pid = getpid(); nxWriteSocket((char *)&req,sizeof(req)); return nxSocket; } #if GR_CLOSE_FIX static void mySignalhandler(int sig) { if (sig == SIGALRM) { printf("Oops! nxFlushReq() timed out, cowardly chickening " "out!\n"); exit(127); } } #endif /** * GrClose: * * Close the graphics device, flushing any waiting messages. */ /* Vladimir Cotfas: hang in GrFlush() --> nxFlushReq(0L,1); */ void GrClose(void) { ACCESS_PER_THREAD_DATA() #if GR_CLOSE_FIX /* allow 1 second to flush*/ void * oldSignalHandler = signal(SIGALRM, mySignalhandler); alarm(1); #endif AllocReq(Close); GrFlush(); #if GR_CLOSE_FIX alarm(0); signal(SIGALRM, oldSignalHandler); #endif close(nxSocket); nxSocket = -1; } /** * GrDefaultErrorHandler: * @ep: the error event structure * * The default error handler which is called when the server reports an error * event and the client hasn't set up a handler of it's own. * * Generates a human readable error message on stderr describing what error * occurred and what function it occured in, then exits. */ void GrDefaultErrorHandler(GR_EVENT *ep) { if (ep->type == GR_EVENT_TYPE_ERROR) { EPRINTF("nxclient %d: Error (%s) ", getpid(), ep->error.name); EPRINTF(nxErrorStrings[ep->error.code], ep->error.id); GrClose(); exit(1); } } /** * GrSetErrorHandler: * @fncb: the function to call to handle error events * @Returns: the address of the previous error handler * * Sets an error handling routine that will be called on any errors from * the server (assuming the client has asked to receive them). If zero is * used as the argument, errors will be returned as regular events instead. */ GR_FNCALLBACKEVENT GrSetErrorHandler(GR_FNCALLBACKEVENT fncb) { ACCESS_PER_THREAD_DATA() GR_FNCALLBACKEVENT orig = ErrorFunc; ErrorFunc = fncb; return orig; } /** * GrDelay: * @msecs: number of milliseconds to delay * * This function suspends execution of the program for the specified * number of milliseconds. */ void GrDelay(GR_TIMEOUT msecs) { struct timeval timeval; timeval.tv_sec = msecs / 1000; timeval.tv_usec = msecs % 1000; select(0, NULL, NULL, NULL, &timeval); } /** * GrGetScreenInfo: * @sip: pointer to a GR_SCREEN_INFO structure * * Fills in the specified GR_SCREEN_INFO structure. */ void GrGetScreenInfo(GR_SCREEN_INFO *sip) { AllocReq(GetScreenInfo); GrTypedReadBlock(sip, sizeof(GR_SCREEN_INFO),GrNumGetScreenInfo); } /** * GrGetSysColor: * @index: an index into the server's colour look up table * @Returns: the colour found at the specified index * * Returns the colour at the specified index into the server's colour look * up table. The colours in the table are those with names like * "GR_COLOR_DESKTOP", "GR_COLOR_ACTIVECAPTION", "GR_COLOR_APPWINDOW", etc. * as listed in nano-X.h */ GR_COLOR GrGetSysColor(int index) { nxGetSysColorReq *req; GR_COLOR color; req = AllocReq(GetSysColor); req->index = index; if(GrTypedReadBlock(&color, sizeof(color),GrNumGetSysColor) == -1) return 0; return color; } /** * GrGetFontInfo: * @fontno: the font ID number * @fip: pointer to a GR_FONT_INFO structure * * Fills in the specified GR_FONT_INFO structure with information regarding * the specified font. */ void GrGetFontInfo(GR_FONT_ID fontno, GR_FONT_INFO *fip) { nxGetFontInfoReq *req; req = AllocReq(GetFontInfo); req->fontid = fontno; GrTypedReadBlock(fip, sizeof(GR_FONT_INFO),GrNumGetFontInfo); } /** * GrGetGCInfo: * @gc: a graphics context * @gcip: pointer to a GR_GC_INFO structure * * Fills in the specified GR_GC_INFO structure with information regarding the * specified graphics context. */ void GrGetGCInfo(GR_GC_ID gc, GR_GC_INFO *gcip) { nxGetGCInfoReq *req; req = AllocReq(GetGCInfo); req->gcid = gc; GrTypedReadBlock(gcip, sizeof(GR_GC_INFO),GrNumGetGCInfo); } /** * GrGetGCTextSize: * @gc: the graphics context * @str: pointer to a text string * @count: the length of the string * @flags: text rendering flags (GR_TF*) * @retwidth: pointer to the variable the width will be returned in * @retheight: pointer to the variable the height will be returned in * @retbase: pointer to the variable the baseline height will be returned in * * Calculates the dimensions of the specified text string using the current font * and flags in the specified graphics context. The count argument can be -1 * if the string is null terminated. */ void GrGetGCTextSize(GR_GC_ID gc, void *str, int count, int flags, GR_SIZE *retwidth, GR_SIZE *retheight, GR_SIZE *retbase) { nxGetGCTextSizeReq *req; int size; if(count == -1 && (flags&MWTF_PACKMASK) == MWTF_ASCII) count = strlen((char *)str); size = nxCalcStringBytes(str, count, flags); req = AllocReqExtra(GetGCTextSize, size); req->gcid = gc; req->flags = flags; memcpy(GetReqData(req), str, size); GrTypedReadBlock(retwidth, sizeof(*retwidth),GrNumGetGCTextSize); GrReadBlock(retheight, sizeof(*retheight)); GrReadBlock(retbase, sizeof(*retbase)); } /** * GrRegisterInput: * @fd: the file descriptor to monitor * * Register an extra file descriptor to monitor in the main select() call. * An event will be returned when the fd has data waiting to be read if that * event has been selected for. */ void GrRegisterInput(int fd) { ACCESS_PER_THREAD_DATA() if (fd < 0) return; FD_SET(fd, ®fdset); if (fd > regfdmax) regfdmax = fd + 1; } /** * GrUnregisterInput: * @fd: the file descriptor to stop monitoring * * Stop monitoring a file descriptor (previously registered with * GrRegisterInput()) in the main select() call. */ void GrUnregisterInput(int fd) { int i, max; ACCESS_PER_THREAD_DATA() /* unregister all inputs if fd is -1 */ if (fd == -1) { FD_ZERO(®fdset); regfdmax = -1; return; } FD_CLR(fd, ®fdset); /* recalculate the max file descriptor */ for (i = 0, max = regfdmax, regfdmax = -1; i < max; i++) if (FD_ISSET(i, ®fdset)) regfdmax = i + 1; } /** * GrPrepareSelect: * @maxfd: pointer to a variable which the highest in use fd will be written to * @rfdset: pointer to the file descriptor set structure to use * * Prepare for a GrServiceSelect function by asking the server to send the next * event but not waiting around for it to arrive and initialising the * specified fd_set structure with the client/server socket descriptor and any * previously registered external file descriptors. Also compares the current * contents of maxfd, the client/server socket descriptor, and the previously * registered external file descriptors, and returns the highest of them in * maxfd. */ void GrPrepareSelect(int *maxfd,void *rfdset) { fd_set *rfds = rfdset; int fd; ACCESS_PER_THREAD_DATA() AllocReq(GetNextEvent); GrFlush(); FD_SET(nxSocket, rfds); if(nxSocket > *maxfd) *maxfd = nxSocket; /* handle registered input file descriptors*/ for (fd = 0; fd < regfdmax; fd++) { if (FD_ISSET(fd, ®fdset)) { FD_SET(fd, rfds); if (fd > *maxfd) *maxfd = fd; } } } /** * GrServiceSelect: * @rfdset: pointer to the file descriptor set to monitor * @fncb: pointer to the function to call when an event needs handling * * Used by GrMainLoop() to call the specified callback function when an * event arrives or there is data waiting on an external fd specified by * GrRegisterInput(). */ void GrServiceSelect(void *rfdset, GR_FNCALLBACKEVENT fncb) { fd_set * rfds = rfdset; int fd; GR_EVENT ev; ACCESS_PER_THREAD_DATA() /* Clean out any event that might have arrived while waiting * for other data, for instance by doing Nano-X requests * between GrPrepareSelect() and GrServiceSelect(), or when * an event is generated in Nano-X at the same time as the * client wakes up for some reason and calls Nano-X functions. */ if (evlist) { /*DPRINTF("nxclient: Handling queued event\n");*/ GetNextQueuedEvent(&ev); CheckErrorEvent(&ev); fncb(&ev); } else { if(FD_ISSET(nxSocket, rfds)) { GrTypedReadBlock(&ev, sizeof(ev),GrNumGetNextEvent); GrCheckForClientData(&ev); CheckErrorEvent(&ev); fncb(&ev); } } /* check for input on registered file descriptors */ for (fd = 0; fd < regfdmax; fd++) { if (FD_ISSET(fd, ®fdset) && FD_ISSET(fd, rfds)) { ev.type = GR_EVENT_TYPE_FDINPUT; ev.fdinput.fd = fd; fncb(&ev); } } } /** * GrMainLoop: * @fncb: * * A convenience function which calls the specified callback function whenever * an event arrives or there is data to be read on a file descriptor previously * specified by GrRegisterInput(). Currently never returns. */ void GrMainLoop(GR_FNCALLBACKEVENT fncb) { fd_set rfds; int setsize = 0; for(;;) { FD_ZERO(&rfds); GrPrepareSelect(&setsize, &rfds); if(select(setsize+1, &rfds, NULL, NULL, NULL) > 0) GrServiceSelect(&rfds, fncb); } } /** * GrGetNextEvent: * @ep: pointer to the GR_EVENT structure to return the event in * * Gets the next event from the event queue and places it in the specified * GR_EVENT structure. If the queue is currently empty, we sleep until the * next event arrives from the server or input is read on a file descriptor * previously specified by GrRegisterInput(). */ void GrGetNextEvent(GR_EVENT *ep) { GrGetNextEventTimeout(ep, 0L); } /** * GrGetNextEventTimeout: * @ep: pointer to the GR_EVENT structure to return the event in * @timeout: the number of milliseconds to wait before timing out * * Gets the next event from the event queue and places it in the specified * GR_EVENT structure. If the queue is currently empty, we sleep until the * next event arrives from the server, input is read on a file descriptor * previously specified by GrRegisterInput(), or a timeout occurs. Note * that a value of 0 for the timeout parameter doesn't mean "timeout after 0 * milliseconds" but is in fact a magic number meaning "never time out". */ void GrGetNextEventTimeout(GR_EVENT *ep, GR_TIMEOUT timeout) { fd_set rfds; int setsize = 0; int e; struct timeval to; ACCESS_PER_THREAD_DATA() if (evlist) { /*DPRINTF("nxclient %d: Returning queued event\n",getpid());*/ GetNextQueuedEvent(ep); CheckErrorEvent(ep); return; } FD_ZERO(&rfds); /* * This will cause a GrGetNextEvent to be sent down the wire. * If we timeout before the server responds, and then * call this procedure again, and the server has more than * one event waiting for this process, then more than one * event will be written on the socket by the server. At * that point, a single stored event won't work, and the * client needs an event queue. */ GrPrepareSelect(&setsize, &rfds); if (timeout) { to.tv_sec = timeout / 1000; to.tv_usec = (timeout % 1000) * 1000; } if((e = select(setsize+1, &rfds, NULL, NULL, timeout ? &to : NULL))>0) { int fd; if(FD_ISSET(nxSocket, &rfds)) { /* * This will never be GR_EVENT_NONE with the current * implementation. */ GrTypedReadBlock(ep, sizeof(*ep),GrNumGetNextEvent); GrCheckForClientData(ep); CheckErrorEvent(ep); return; } /* check for input on registered file descriptors */ for (fd = 0; fd < regfdmax; fd++) { if (FD_ISSET(fd, ®fdset) && FD_ISSET(fd, &rfds)) { ep->type = GR_EVENT_TYPE_FDINPUT; ep->fdinput.fd = fd; break; } } } else if (e == 0) { /* * Timeout has occured. We currently return a timeout event * regardless of whether the client has selected for it. */ ep->type = GR_EVENT_TYPE_TIMEOUT; } else { if(errno == EINTR) { ep->type = GR_EVENT_TYPE_NONE; } else { EPRINTF("nxclient: select failed\n"); GrClose(); exit(1); } } } /** * GrCheckNextEvent: * @ep: pointer to the GR_EVENT structure to return the event in * * Gets the next event from the event queue if there is one, or returns * immediately with an event type of GR_EVENT_TYPE_NONE if it is empty. */ void GrCheckNextEvent(GR_EVENT *ep) { ACCESS_PER_THREAD_DATA() if (evlist) { /*DPRINTF("nxclient %d: Returning queued event\n",getpid());*/ GetNextQueuedEvent(ep); CheckErrorEvent(ep); return; } AllocReq(CheckNextEvent); GrTypedReadBlock(ep, sizeof(*ep),GrNumGetNextEvent); GrCheckForClientData(ep); CheckErrorEvent(ep); } /** * GrPeekEvent: * @ep: pointer to the GR_EVENT structure to return the event in * @Returns: 1 if an event was returned, or 0 if the queue was empty * * Fills in the specified event structure with a copy of the next event on the * queue, without actually removing it from the queue. An event type of * GR_EVENT_TYPE_NONE is given if the queue is empty. */ int GrPeekEvent(GR_EVENT *ep) { int ret; ACCESS_PER_THREAD_DATA() if (evlist) { *ep = evlist->event; CheckErrorEvent(ep); return 1; } AllocReq(PeekEvent); GrTypedReadBlock(ep, sizeof(*ep),GrNumPeekEvent); GrCheckForClientData(ep); ret = GrReadByte(); CheckErrorEvent(ep); return ret; } /** * GrPeekWaitEvent: * @ep: pointer to the GR_EVENT structure to return the event in * * Wait until an event is available for a client, and then peek at it. */ void GrPeekWaitEvent(GR_EVENT *ep) { EVENT_LIST * elp; ACCESS_PER_THREAD_DATA() if (evlist) { *ep = evlist->event; CheckErrorEvent(ep); return; } /* no events, wait for next event*/ GrGetNextEvent(ep); /* add event back on head of list*/ elp = malloc(sizeof(EVENT_LIST)); if (elp) { elp->event = *ep; elp->next = evlist; } /* peek at it*/ GrPeekEvent(ep); } /** * GrSelectEvents: * @wid: the ID of the window to set the event mask of * @eventmask: a bit field specifying the desired event mask * * Select the event types which should be returned for the specified window. */ void GrSelectEvents(GR_WINDOW_ID wid, GR_EVENT_MASK eventmask) { nxSelectEventsReq *req; req = AllocReq(SelectEvents); req->windowid = wid; req->eventmask = eventmask; } /** * GrNewWindow: * @parent: the ID of the parent window * @x: the X coordinate of the new window relative to the parent window * @y: the Y coordinate of the new window relative to the parent window * @width: the width of the new window * @height: the height of the new window * @bordersize: the width of the window border * @background: the colour of the window background * @bordercolor: the colour of the window border * @Returns: the ID of the newly created window * * Create a new window with the specified parent and window attributes. */ GR_WINDOW_ID GrNewWindow(GR_WINDOW_ID parent, GR_COORD x, GR_COORD y, GR_SIZE width, GR_SIZE height, GR_SIZE bordersize, GR_COLOR background, GR_COLOR bordercolor) { nxNewWindowReq *req; GR_WINDOW_ID wid; req = AllocReq(NewWindow); req->parentid = parent; req->x = x; req->y = y; req->width = width; req->height = height; req->backgroundcolor = background; req->bordercolor = bordercolor; req->bordersize = bordersize; if(GrTypedReadBlock(&wid, sizeof(wid),GrNumNewWindow) == -1) return 0; return wid; } /** * GrNewPixmap: * @width: the width of the pixmap * @height: the height of the pixmap * @addr: currently unused in client/server mode * @Returns: the ID of the newly created pixmap * * Create a new server side pixmap (an offscreen drawing area which can be * copied into a window using a GrCopyArea call) of the specified width and * height. */ /* FIXME: Add support for shared memory... */ GR_WINDOW_ID GrNewPixmap(GR_SIZE width, GR_SIZE height, void *addr) { nxNewPixmapReq *req; GR_WINDOW_ID wid; req = AllocReq(NewPixmap); req->width = width; req->height = height; if(GrTypedReadBlock(&wid, sizeof(wid), GrNumNewPixmap) == -1) return 0; return wid; } /** * GrNewInputWindow: * @parent: the ID of the window to use as the parent of the new window * @x: the X coordinate of the new window relative to the parent window * @y: the Y coordinate of the new window relative to the parent window * @width: the width of the new window * @height: the height of the new window * @Returns: the ID of the newly created window * * Create a new input-only window with the specified dimensions which is a * child of the specified parent window. */ GR_WINDOW_ID GrNewInputWindow(GR_WINDOW_ID parent, GR_COORD x, GR_COORD y, GR_SIZE width, GR_SIZE height) { nxNewInputWindowReq *req; GR_WINDOW_ID wid; req = AllocReq(NewInputWindow); req->parentid = parent; req->x = x; req->y = y; req->width = width; req->height = height; if(GrTypedReadBlock(&wid, sizeof(wid), GrNumNewInputWindow) == -1) return 0; return wid; } /** * GrDestroyWindow: * @wid: the ID of the window to destroy * * Recursively unmaps and frees the data structures associated with the * specified window and all of its children. */ void GrDestroyWindow(GR_WINDOW_ID wid) { nxDestroyWindowReq *req; req = AllocReq(DestroyWindow); req->windowid = wid; } /** * GrGetWindowInfo: * @wid: the ID of the window to retrieve information about * @infoptr: pointer to a GR_WINDOW_INFO structure to return the information in * * Fills in a GR_WINDOW_INFO structure with information regarding the window * with the specified window ID. */ void GrGetWindowInfo(GR_WINDOW_ID wid, GR_WINDOW_INFO *infoptr) { nxGetWindowInfoReq *req; req = AllocReq(GetWindowInfo); req->windowid = wid; GrTypedReadBlock(infoptr, sizeof(GR_WINDOW_INFO), GrNumGetWindowInfo); } /** * GrNewGC: * @Returns: the ID of the newly created graphics context or 0 on error * * Creates a new graphics context structure and returns the ID used to refer * to it. The structure is initialised with a set of default parameters. */ GR_GC_ID GrNewGC(void) { GR_GC_ID gc; AllocReq(NewGC); if(GrTypedReadBlock(&gc, sizeof(gc),GrNumNewGC) == -1) return 0; return gc; } /** * GrCopyGC: * @gc: the already existing graphics context to copy the parameters from * @Returns: the ID of the newly created graphics context or 0 on error * * Creates a new graphics context structure and fills it in with the values * from the specified already existing graphics context. */ GR_GC_ID GrCopyGC(GR_GC_ID gc) { nxCopyGCReq *req; GR_GC_ID newgc; req = AllocReq(CopyGC); req->gcid = gc; if(GrTypedReadBlock(&newgc, sizeof(newgc),GrNumCopyGC) == -1) return 0; return newgc; } /** * GrDestroyGC: * @gc: the ID of the graphics context structure to destroy * * Destroys the graphics context structure with the specified ID. */ void GrDestroyGC(GR_GC_ID gc) { nxDestroyGCReq *req; req = AllocReq(DestroyGC); req->gcid = gc; } /** * GrNewRegion: * @Returns: the ID of the newly created region * * Creates a new region structure and returns the ID used to refer to it. * The structure is initialised with a set of default parameters. */ GR_REGION_ID GrNewRegion(void) { GR_REGION_ID region; AllocReq(NewRegion); if(GrTypedReadBlock(®ion, sizeof(region),GrNumNewRegion) == -1) return 0; return region; } /** * GrDestroyRegion: * @region: the ID of the region structure to destroy * * Destroys the region structure with the specified ID. */ void GrDestroyRegion(GR_REGION_ID region) { nxDestroyRegionReq *req; req = AllocReq(DestroyRegion); req->regionid = region; } /** * GrUnionRectWithRegion: * @region: the ID of the region to modify * @rect: a pointer to the rectangle to add to the region * * Makes a union of the specified region and the specified rectangle and * places the result back in the source region. */ void GrUnionRectWithRegion(GR_REGION_ID region, GR_RECT *rect) { nxUnionRectWithRegionReq *req; req = AllocReq(UnionRectWithRegion); if(rect) memcpy(&req->rect, rect, sizeof(*rect)); req->regionid = region; } /** * GrUnionRegion: * @dst_rgn: the ID of the destination region * @src_rgn1: the ID of the first source region * @src_rgn2: the ID of the second source region * * Makes a union of the specified source regions and places the result in the * specified destination region. */ void GrUnionRegion(GR_REGION_ID dst_rgn, GR_REGION_ID src_rgn1, GR_REGION_ID src_rgn2) { nxUnionRegionReq *req; req = AllocReq(UnionRegion); req->regionid = dst_rgn; req->srcregionid1 = src_rgn1; req->srcregionid2 = src_rgn2; } /** * GrSubtractRegion: * @dst_rgn: the ID of the destination region * @src_rgn1: the ID of the first source region * @src_rgn2: the ID of the second source region * * Subtracts the second source region from the first source region and places * the result in the specified destination region. */ void GrSubtractRegion(GR_REGION_ID dst_rgn, GR_REGION_ID src_rgn1, GR_REGION_ID src_rgn2) { nxSubtractRegionReq *req; req = AllocReq(SubtractRegion); req->regionid = dst_rgn; req->srcregionid1 = src_rgn1; req->srcregionid2 = src_rgn2; } /** * GrXorRegion: * @dst_rgn: the ID of the destination region * @src_rgn1: the ID of the first source region * @src_rgn2: the ID of the second source region * * Performs a logical exclusive OR operation on the specified source regions * and places the result in the destination region. The destination region * will contain only the parts of the source regions which do not overlap. */ void GrXorRegion(GR_REGION_ID dst_rgn, GR_REGION_ID src_rgn1, GR_REGION_ID src_rgn2) { nxXorRegionReq *req; req = AllocReq(XorRegion); req->regionid = dst_rgn; req->srcregionid1 = src_rgn1; req->srcregionid2 = src_rgn2; } /** * GrIntersectRegion: * @dst_rgn: the ID of the destination region * @src_rgn1: the ID of the first source region * @src_rgn2: the ID of the second source region * * Calculates the intersection of the two specified source regions and places * the result in the specified destination region. The destination region * will contain only the parts of the source regions which overlap each other. */ void GrIntersectRegion(GR_REGION_ID dst_rgn, GR_REGION_ID src_rgn1, GR_REGION_ID src_rgn2) { nxIntersectRegionReq *req; req = AllocReq(IntersectRegion); req->regionid = dst_rgn; req->srcregionid1 = src_rgn1; req->srcregionid2 = src_rgn2; } /** * GrSetGCRegion: * @gc: the ID of the graphics context to set the clip mask of * @region: the ID of the region to use as the clip mask * * Sets the clip mask of the specified graphics context to the specified * region. Subsequent drawing operations using this graphics context will not * draw outside the specified region. The region ID can be set to 0 to remove * the clipping region from the specified graphics context. */ void GrSetGCRegion(GR_GC_ID gc, GR_REGION_ID region) { nxSetGCRegionReq *req; req = AllocReq(SetGCRegion); req->gcid = gc; req->regionid = region; } /** * GrSetGCClipOrigin: * @gc: the ID of the graphics context with user clip region * @xoff: new X offset of user clip region * @xoff: new Y offset of user clip region * * Sets the X,Y origin of the user clip region in the specified * graphics context. */ void GrSetGCClipOrigin(GR_GC_ID gc, int x, int y) { nxSetGCClipOriginReq *req; req = AllocReq(SetGCClipOrigin); req->gcid = gc; req->xoff = x; req->yoff = y; } /** * GrPointInRegion: * @region: the ID of the region to examine * @x: the X coordinate of the point to test for * @y: the Y coordinate of the point to test for * @Returns: True if the point is within the region, or False otherwise * * Tests whether the specified point is within the specified region, and * then returns either True or False depending on the result. */ GR_BOOL GrPointInRegion(GR_REGION_ID region, GR_COORD x, GR_COORD y) { nxPointInRegionReq *req; GR_BOOL ret_value; req = AllocReq(PointInRegion); req->regionid = region; req->x = x; req->y = y; if(GrTypedReadBlock(&ret_value, sizeof(ret_value), GrNumPointInRegion) == -1) return GR_FALSE; return ret_value; } /** * GrRectInRegion: * @region: the ID of the region to examine * @x: the X coordinates of the rectangle to test * @y: the Y coordinates of the rectangle to test * @w: the width of the rectangle to test * @h: the height of the rectangle to test * @Returns: GR_RECT_PARTIN, GR_RECT_ALLIN, or GR_RECT_OUT * * Tests whether the specified rectangle is contained within the specified * region. Returns GR_RECT_OUT if it is not inside it at all, GR_RECT_ALLIN * if it is completely contained within the region, or GR_RECT_PARTIN if * it is partially contained within the region. */ int GrRectInRegion(GR_REGION_ID region, GR_COORD x, GR_COORD y, GR_COORD w, GR_COORD h) { nxRectInRegionReq *req; unsigned short ret_value; req = AllocReq(RectInRegion); req->regionid = region; req->x = x; req->y = y; req->w = w; req->h = h; if(GrTypedReadBlock(&ret_value, sizeof(ret_value), GrNumRectInRegion) == -1) return 0; return (int)ret_value; } /** * GrEmptyRegion: * @region: the ID of the region to examine * @Returns: GR_TRUE if the region is empty, or GR_FALSE if it is not * * Determines whether the specified region is empty, and returns GR_TRUE * if it is, or GR_FALSE otherwise. */ GR_BOOL GrEmptyRegion(GR_REGION_ID region) { nxEmptyRegionReq *req; GR_BOOL ret_value; req = AllocReq(EmptyRegion); req->regionid = region; if(GrTypedReadBlock(&ret_value, sizeof(ret_value), GrNumEmptyRegion) == -1) return GR_FALSE; return ret_value; } /** * GrEqualRegion: * @rgn1: the ID of the first region to examine * @rgn2: the ID of the second region to examine * @Returns: GR_TRUE if the regions are equal, or GR_FALSE otherwise * * Determines whether the specified regions are identical, and returns GR_TRUE * if it is, or GR_FALSE otherwise. */ GR_BOOL GrEqualRegion(GR_REGION_ID rgn1, GR_REGION_ID rgn2) { nxEqualRegionReq *req; GR_BOOL ret_value; req = AllocReq(EqualRegion); req->region1 = rgn1; req->region2 = rgn2; if(GrTypedReadBlock(&ret_value, sizeof(ret_value), GrNumEqualRegion) == -1) return GR_FALSE; return ret_value; } /** * GrOffsetRegion: * @region: the ID of the region to offset * @dx: the distance to offset the region by in the X axis * @dy: the distance to offset the region by in the Y axis * * Offsets the specified region by the specified distance. */ void GrOffsetRegion(GR_REGION_ID region, GR_SIZE dx, GR_SIZE dy) { nxOffsetRegionReq *req; req = AllocReq(OffsetRegion); req->region = region; req->dx = dx; req->dy = dy; } /** * GrGetRegionBox: * @region: the ID of the region to get the bounding box of * @rect: pointer to a rectangle structure * @Returns: the region type * * Fills in the specified rectangle structure with a bounding box that would * completely enclose the specified region, and also returns the type of the * specified region. */ int GrGetRegionBox(GR_REGION_ID region, GR_RECT *rect) { nxGetRegionBoxReq *req; unsigned short ret_value; if (!rect) return GR_FALSE; req = AllocReq(GetRegionBox); req->regionid = region; if(GrTypedReadBlock(rect, sizeof(*rect), GrNumGetRegionBox) == -1) return GR_FALSE; if(GrTypedReadBlock(&ret_value, sizeof(ret_value), GrNumGetRegionBox) == -1) return GR_FALSE; return ret_value; } /** * GrNewPolygonRegion: * @mode: the polygon mode to use (GR_POLY_EVENODD or GR_POLY_WINDING) * @count: the number of points in the polygon * @points: pointer to an array of point structures describing the polygon * @Returns: the ID of the newly allocated region structure, or 0 on error * * Creates a new region structure, fills it with the region described by the * specified polygon, and returns the ID used to refer to it. */ GR_REGION_ID GrNewPolygonRegion(int mode, GR_COUNT count, GR_POINT *points) { nxNewPolygonRegionReq *req; long size; GR_REGION_ID region; if(count == 0) return GrNewRegion(); if(points == NULL) return 0; size = (long)count * sizeof(GR_POINT); req = AllocReqExtra(NewPolygonRegion, size); req->mode = mode; /* FIXME: unportable method, depends on sizeof(int) in GR_POINT*/ memcpy(GetReqData(req), points, size); if(GrTypedReadBlock(®ion, sizeof(region), GrNumNewPolygonRegion) == -1) return 0; return region; } /** * GrMapWindow: * @wid: the ID of the window to map * * Recursively maps (makes visible) the specified window and all of the * child windows which have a sufficient map count. The border and background * of the window are painted, and an exposure event is generated for the * window and every child which becomes visible. */ void GrMapWindow(GR_WINDOW_ID wid) { nxMapWindowReq *req; req = AllocReq(MapWindow); req->windowid = wid; } /** * GrUnmapWindow: * @wid: the ID of the window to unmap * * Recursively unmaps (makes invisible) the specified window and all of the * child windows. */ void GrUnmapWindow(GR_WINDOW_ID wid) { nxUnmapWindowReq *req; req = AllocReq(UnmapWindow); req->windowid = wid; } /** * GrRaiseWindow: * @wid: the ID of the window to raise * * Places the specified window at the top of its parents drawing stack, above * all of its sibling windows. */ void GrRaiseWindow(GR_WINDOW_ID wid) { nxRaiseWindowReq *req; req = AllocReq(RaiseWindow); req->windowid = wid; } /** * GrLowerWindow: * @wid: the ID of the window to lower * * Places the specified window at the bottom of its parents drawing stack, * below all of its sibling windows. */ void GrLowerWindow(GR_WINDOW_ID wid) { nxLowerWindowReq *req; req = AllocReq(LowerWindow); req->windowid = wid; } /** * GrMoveWindow: * @wid: the ID of the window to move * @x: the X coordinate to move the window to relative to its parent. * @y: the Y coordinate to move the window to relative to its parent. * * Moves the specified window to the specified position relative to its * parent window. */ void GrMoveWindow(GR_WINDOW_ID wid, GR_COORD x, GR_COORD y) { nxMoveWindowReq *req; req = AllocReq(MoveWindow); req->windowid = wid; req->x = x; req->y = y; } /** * GrResizeWindow: * @wid: the ID of the window to resize * @width: the width to resize the window to * @height: the height to resize the window to * * Resizes the specified window to be the specified width and height. */ void GrResizeWindow(GR_WINDOW_ID wid, GR_SIZE width, GR_SIZE height) { nxResizeWindowReq *req; req = AllocReq(ResizeWindow); req->windowid = wid; req->width = width; req->height = height; } /** * GrReparentWindow: * @wid: the ID of the window to reparent * @pwid: the ID of the new parent window * @x: the X coordinate to place the window at relative to the new parent * @y: the Y coordinate to place the window at relative to the new parent * * Changes the parent window of the specified window to the specified parent * window and places it at the specified coordinates relative to the new * parent. */ void GrReparentWindow(GR_WINDOW_ID wid, GR_WINDOW_ID pwid, GR_COORD x, GR_COORD y) { nxReparentWindowReq *req; req = AllocReq(ReparentWindow); req->windowid = wid; req->parentid = pwid; req->x = x; req->y = y; } /** * GrClearArea: * @wid: window ID * @exposeflag: a flag indicating whether to also generate an exposure event * * Clears the specified window by to its background color or pixmap. * If exposeflag is non zero, an exposure event is generated for * the window after it has been cleared. */ void GrClearArea(GR_WINDOW_ID wid, GR_COORD x, GR_COORD y, GR_SIZE width, GR_SIZE height, GR_BOOL exposeflag) { nxClearAreaReq *req; req = AllocReq(ClearArea); req->windowid = wid; req->x = x; req->y = y; req->width = width; req->height = height; req->exposeflag = exposeflag; } /** * GrGetFocus: * @Returns: the ID of the window which currently has the keyboard focus * * Returns the ID of the window which currently has the keyboard focus. */ GR_WINDOW_ID GrGetFocus(void) { GR_WINDOW_ID wid; AllocReq(GetFocus); if(GrTypedReadBlock(&wid, sizeof(wid), GrNumGetFocus) == -1) return 0; return wid; } /** * GrSetFocus: * @wid: the ID of the window to set the focus to * * Sets the keyboard focus to the specified window. */ void GrSetFocus(GR_WINDOW_ID wid) { nxSetFocusReq *req; req = AllocReq(SetFocus); req->windowid = wid; } /** * GrSetWindowCursor: * @wid: the ID of the window to set the cursor for * @cid: the cursor ID * * Specify a cursor for a window. * This cursor will only be used within that window, and by default * for its new children. If the cursor is currently within this * window, it will be changed to the new one immediately. * If the new cursor ID is 0, revert to the root window cursor. */ void GrSetWindowCursor(GR_WINDOW_ID wid, GR_CURSOR_ID cid) { nxSetWindowCursorReq *req; req = AllocReq(SetWindowCursor); req->windowid = wid; req->cursorid = cid; } /** * GrNewCursor: * @width: the width of the pointer bitmap * @height: the height of the pointer bitmap * @hotx: the X coordinate within the bitmap used as the target of the pointer * @hoty: the Y coordinate within the bitmap used as the target of the pointer * @foreground: the colour to use for the foreground of the pointer * @background: the colour to use for the background of the pointer * @fgbitmap: pointer to bitmap data specifying the foreground of the pointer * @bgbitmap: pointer to bitmap data specifying the background of the pointer * * Creates a server-based cursor (mouse graphic) resource. */ GR_CURSOR_ID GrNewCursor(GR_SIZE width, GR_SIZE height, GR_COORD hotx, GR_COORD hoty, GR_COLOR foreground, GR_COLOR background, GR_BITMAP *fgbitmap, GR_BITMAP *bgbitmap) { nxNewCursorReq *req; int bitmapsize; char * data; GR_CURSOR_ID cursorid; bitmapsize = GR_BITMAP_SIZE(width, height) * sizeof(GR_BITMAP); req = AllocReqExtra(NewCursor, bitmapsize*2); req->width = width; req->height = height; req->hotx = hotx; req->hoty = hoty; req->fgcolor = foreground; req->bgcolor = background; data = GetReqData(req); memcpy(data, fgbitmap, bitmapsize); memcpy(data+bitmapsize, bgbitmap, bitmapsize); if(GrTypedReadBlock(&cursorid, sizeof(cursorid), GrNumNewCursor) == -1) return 0; return cursorid; } /** * GrMoveCursor: * @x: the X coordinate to move the pointer to * @y: the Y coordinate to move the pointer to * * Moves the cursor (mouse pointer) to the specified coordinates. * The coordinates are relative to the root window, where (0,0) is the upper * left hand corner of the screen. The reference point used for the pointer * is that of the "hot spot". After moving the pointer, the graphic used for * the pointer will change to the graphic defined for use in the window which * it is over. */ void GrMoveCursor(GR_COORD x, GR_COORD y) { nxMoveCursorReq *req; req = AllocReq(MoveCursor); req->x = x; req->y = y; } /** * GrSetGCForeground: * @gc: the ID of the graphics context to set the foreground colour of * @foreground: the colour to use as the new foreground colour * * Changes the foreground colour of the specified graphics context to the * specified colour. */ void GrSetGCForeground(GR_GC_ID gc, GR_COLOR foreground) { nxSetGCForegroundReq *req; req = AllocReq(SetGCForeground); req->gcid = gc; req->color = foreground; } /** * GrSetGCBackground: * @gc: the ID of the graphics context to set the background colour of * @background: the colour to use as the new background colour * * Changes the background colour of the specified graphics context to the * specified colour. */ void GrSetGCBackground(GR_GC_ID gc, GR_COLOR background) { nxSetGCBackgroundReq *req; req = AllocReq(SetGCBackground); req->gcid = gc; req->color = background; } /** * GrSetGCMode: * @gc: the ID of the graphics context to set the drawing mode of * @mode: the new drawing mode * * Changes the drawing mode (SET, XOR, OR, AND, etc.) of the specified * graphics context to the specified mode. */ void GrSetGCMode(GR_GC_ID gc, int mode) { nxSetGCModeReq *req; req = AllocReq(SetGCMode); req->gcid = gc; req->mode = mode; } /** * GrSetGCUseBackground: * @gc: the ID of the graphics context to change the "use background" flag of * @flag: flag specifying whether to use the background colour or not * * Sets the flag which chooses whether or not the background colour is used * when drawing bitmaps and text using the specified graphics context to the * specified value. */ void GrSetGCUseBackground(GR_GC_ID gc, GR_BOOL flag) { nxSetGCUseBackgroundReq *req; req = AllocReq(SetGCUseBackground); req->gcid = gc; req->flag = flag; } /** * GrCreateFont: * @name: string containing the name of a built in font to look for * @height: the desired height of the font * @plogfont: pointer to a LOGFONT structure * @Returns: a font ID number which can be used to refer to the font * * Attempts to locate a font with the desired attributes and returns a font * ID number which can be used to refer to it. If the plogfont argument is * not NULL, the values in that structure will be used to choose a font. * Otherwise, if the height is non zero, the built in font with the closest * height to that specified will be used. If the height is zero, the built * in font with the specified name will be used. If the desired font is not * found, the first built in font will be returned as a last resort. */ GR_FONT_ID GrCreateFont(GR_CHAR *name, GR_COORD height, GR_LOGFONT *plogfont) { nxCreateFontReq *req; GR_FONT_ID fontid; req = AllocReq(CreateFont); if (plogfont) { memcpy(&req->lf, plogfont, sizeof(*plogfont)); req->height = 0; req->lf_used = 1; } else { if (name) strcpy(req->lf.lfFaceName, name); else req->lf.lfFaceName[0] = '\0'; req->height = height; req->lf_used = 0; } if(GrTypedReadBlock(&fontid, sizeof(fontid),GrNumCreateFont) == -1) return 0; return fontid; } /** * GrGetFontList: * @fonts: pointer used to return an array of font names. * @numfonts: pointer used to return the number of names found. * * Returns an array of strings containing the names of available fonts and an * integer that specifies the number of strings returned. */ void GrGetFontList(GR_FONTLIST ***fonts, int *numfonts) { nxGetFontListReq *req; char *tmpstr; GR_FONTLIST **flist; int num, len, i; req = AllocReq(GetFontList); GrTypedReadBlock(&num, sizeof(int), GrNumGetFontList); *numfonts = num; if(num == -1) return; flist = (GR_FONTLIST**)malloc(num * sizeof(GR_FONTLIST*)); for(i = 0; i < num; i++) flist[i] = (GR_FONTLIST*)malloc(sizeof(GR_FONTLIST*)); for(i = 0; i < num; i++) { GrReadBlock(&len, sizeof(int)); tmpstr = (char*)malloc(len * sizeof(char)); GrReadBlock(tmpstr, len * sizeof(char)); flist[i]->ttname = tmpstr; GrReadBlock(&len, sizeof(int)); tmpstr = (char*)malloc(len * sizeof(char)); GrReadBlock(tmpstr, len * sizeof(char)); flist[i]->mwname = tmpstr; } *fonts = flist; } /** * GrFreeFontList: * @fonts: pointer to array returned by GrGetFontList * @numfonts: the number of font names in the array * * free's the specified array. */ void GrFreeFontList(GR_FONTLIST ***fonts, int n) { int i; MWFONTLIST *g, **list = *fonts; for (i = 0; i < n; i++) { g = list[i]; if(g) { if(g->mwname) free(g->mwname); if(g->ttname) free(g->ttname); free(g); } } free(list); *fonts = 0; } /** * GrSetFontSize: * @fontid: the ID number of the font to change the size of * @fontsize: the size to change the font to * * Changes the size of the specified font to the specified size. */ void GrSetFontSize(GR_FONT_ID fontid, GR_COORD fontsize) { nxSetFontSizeReq *req; req = AllocReq(SetFontSize); req->fontid = fontid; req->fontsize = fontsize; } /** * GrSetFontRotation: * @fontid: the ID number of the font to rotate * @tenthdegrees: the angle to set the rotation to in tenths of a degree * * Changes the rotation of the specified font to the specified angle. */ void GrSetFontRotation(GR_FONT_ID fontid, int tenthdegrees) { nxSetFontRotationReq *req; req = AllocReq(SetFontRotation); req->fontid = fontid; req->tenthdegrees = tenthdegrees; } /** * GrSetFontAttr: * @fontid: the ID of the font to set the attributes of * @setflags: mask specifying attribute flags to set * @clrflags: mask specifying attribute flags to clear * * Changes the attributes (GR_TFKERNING, GR_TFANTIALIAS, GR_TFUNDERLINE, etc.) * of the specified font according to the set and clear mask arguments. */ void GrSetFontAttr(GR_FONT_ID fontid, int setflags, int clrflags) { nxSetFontAttrReq *req; req = AllocReq(SetFontAttr); req->fontid = fontid; req->setflags = setflags; req->clrflags = clrflags; } /** * GrDestroyFont: * @fontid: the ID of the font to destroy * * Frees all resources associated with the specified font ID, and if the font * is a non built in type and this is the last ID referring to it, unloads the * font from memory. */ void GrDestroyFont(GR_FONT_ID fontid) { nxDestroyFontReq *req; req = AllocReq(DestroyFont); req->fontid = fontid; } /** * GrSetGCFont: * @gc: the ID of the graphics context to set the font of * @font: the ID of the font * * Sets the font to be used for text drawing in the specified graphics * context to the specified font ID. */ void GrSetGCFont(GR_GC_ID gc, GR_FONT_ID font) { nxSetGCFontReq *req; req = AllocReq(SetGCFont); req->gcid = gc; req->fontid = font; } /** * GrLine: * @id: the ID of the drawable to draw the line on * @gc: the ID of the graphics context to use when drawing the line * @x1: the X coordinate of the start of the line relative to the drawable * @y1: the Y coordinate of the start of the line relative to the drawable * @x2: the X coordinate of the end of the line relative to the drawable * @y2: the Y coordinate of the end of the line relative to the drawable * * Draws a line using the specified graphics context on the specified drawable * from (x1, y1) to (x2, y2), with coordinates given relative to the drawable. */ void GrLine(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x1, GR_COORD y1, GR_COORD x2, GR_COORD y2) { nxLineReq *req; req = AllocReq(Line); req->drawid = id; req->gcid = gc; req->x1 = x1; req->y1 = y1; req->x2 = x2; req->y2 = y2; } /** * GrRect: * @id: the ID of the drawable to draw the rectangle on * @gc: the ID of the graphics context to use when drawing the rectangle * @x: the X coordinate of the rectangle relative to the drawable * @y: the Y coordinate of the rectangle relative to the drawable * @width: the width of the rectangle * @height: the height of the rectangle * * Draw the boundary of a rectangle of the specified dimensions and position * on the specified drawable using the specified graphics context. */ void GrRect(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, GR_SIZE width, GR_SIZE height) { nxRectReq *req; req = AllocReq(Rect); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; req->width = width; req->height = height; } /** * GrFillRect: * @id: the ID of the drawable to draw the rectangle on * @gc: the ID of the graphics context to use when drawing the rectangle * @x: the X coordinate of the rectangle relative to the drawable * @y: the Y coordinate of the rectangle relative to the drawable * @width: the width of the rectangle * @height: the height of the rectangle * * Draw a filled rectangle of the specified dimensions and position on the * specified drawable using the specified graphics context. */ void GrFillRect(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, GR_SIZE width, GR_SIZE height) { nxFillRectReq *req; req = AllocReq(FillRect); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; req->width = width; req->height = height; } /** * GrEllipse: * @id: the ID of the drawable to draw the ellipse on * @gc: the ID of the graphics context to use when drawing the ellipse * @x: the X coordinate to draw the ellipse at relative to the drawable * @y: the Y coordinate to draw the ellipse at relative to the drawable * @rx: the radius of the ellipse on the X axis * @ry: the radius of the ellipse on the Y axis * * Draws the boundary of ellipse at the specified position using the specified * dimensions and graphics context on the specified drawable. */ void GrEllipse(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, GR_SIZE rx, GR_SIZE ry) { nxEllipseReq *req; req = AllocReq(Ellipse); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; req->rx = rx; req->ry = ry; } /** * GrFillEllipse: * @id: the ID of the drawable to draw the filled ellipse on * @gc: the ID of the graphics context to use when drawing the ellipse * @x: the X coordinate to draw the ellipse at relative to the drawable * @y: the Y coordinate to draw the ellipse at relative to the drawable * @rx: the radius of the ellipse on the X axis * @ry: the radius of the ellipse on the Y axis * * Draws a filled ellipse at the specified position using the specified * dimensions and graphics context on the specified drawable. */ void GrFillEllipse(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, GR_SIZE rx, GR_SIZE ry) { nxFillEllipseReq *req; req = AllocReq(FillEllipse); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; req->rx = rx; req->ry = ry; } /** * GrArc: * @id: the ID of the drawable to draw the arc on * @gc: the graphics context to use when drawing the arc * @x: the X coordinate to draw the arc at relative to the drawable * @y: the Y coordinate to draw the arc at relative to the drawable * @rx: the radius of the arc on the X axis * @ry: the radius of the arc on the Y axis * @ax: the X coordinate of the start of the arc relative to the drawable * @ay: the Y coordinate of the start of the arc relative to the drawable * @bx: the X coordinate of the end of the arc relative to the drawable * @by: the Y coordinate of the end of the arc relative to the drawable * @type: the fill style to use when drawing the arc * * Draws an arc with the specified dimensions at the specified position * on the specified drawable using the specified graphics context. * The type specifies the fill type. Possible values include GR_ARC and * GR_PIE. */ void GrArc(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, GR_SIZE rx, GR_SIZE ry, GR_COORD ax, GR_COORD ay, GR_COORD bx, GR_COORD by, int type) { nxArcReq *req; req = AllocReq(Arc); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; req->rx = rx; req->ry = ry; req->ax = ax; req->ay = ay; req->bx = bx; req->by = by; req->type = type; } /** * GrArcAngle: * @id: the ID of the drawable to draw the arc on * @gc: the graphics context to use when drawing the arc * @x: the X coordinate to draw the arc at relative to the drawable * @y: the Y coordinate to draw the arc at relative to the drawable * @rx: the radius of the arc on the X axis * @ry: the radius of the arc on the Y axis * @angle1: the angle of the start of the arc * @angle2: the angle of the end of the arc * @type: the fill style to use when drawing the arc * * Draws an arc with the specified dimensions at the specified position * on the specified drawable using the specified graphics context. * The type specifies the fill type. Possible values include GR_ARC and * GR_PIE. This function requires floating point support, and is slightly * slower than the GrArc() function which does not require floating point. */ void GrArcAngle(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, GR_SIZE rx, GR_SIZE ry, GR_COORD angle1, GR_COORD angle2, int type) { nxArcAngleReq *req; req = AllocReq(ArcAngle); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; req->rx = rx; req->ry = ry; req->angle1 = angle1; req->angle2 = angle2; req->type = type; } /** * GrBitmap: * @id: the ID of the drawable to draw the bitmap onto * @gc: the ID of the graphics context to use when drawing the bitmap * @x: the X coordinate to draw the bitmap at relative to the drawable * @y: the Y coordinate to draw the bitmap at relative to the drawable * @width: the width of the bitmap * @height: the height of the bitmap * @bitmaptable: pointer to the bitmap data * * Draws the monochrome bitmap data provided in the bitmaptable argument * at the specified position on the specified drawable using the specified * graphics context. Note that the bitmap data should be an array of aligned * 16 bit words. The usebackground flag in the graphics context specifies * whether to draw the background colour wherever a bit value is zero. */ void GrBitmap(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, GR_SIZE width, GR_SIZE height, GR_BITMAP *bitmaptable) { nxBitmapReq *req; long bitmapsize; bitmapsize = (long)GR_BITMAP_SIZE(width, height) * sizeof(GR_BITMAP); req = AllocReqExtra(Bitmap, bitmapsize); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; req->width = width; req->height = height; memcpy(GetReqData(req), bitmaptable, bitmapsize); } /** * GrDrawImageBits: * @id: the ID of the drawable to draw the image onto * @gc: the ID of the graphics context to use when drawing the image * @x: the X coordinate to draw the image at relative to the drawable * @y: the Y coordinate to draw the image at relative to the drawable * @pimage: pointer to the image structure * * Draws the image contained in the specified image structure onto the * specified drawable at the specified coordinates using the specified * graphics context. */ void GrDrawImageBits(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, GR_IMAGE_HDR *pimage) { nxDrawImageBitsReq *req; int imagesize; int palsize; char *addr; imagesize = pimage->pitch * pimage->height; palsize = pimage->palsize * sizeof(MWPALENTRY); req = AllocReqExtra(DrawImageBits, imagesize + palsize); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; /* fill MWIMAGEHDR items passed externally*/ req->width = pimage->width; req->height = pimage->height; req->planes = pimage->planes; req->bpp = pimage->bpp; req->pitch = pimage->pitch; req->bytesperpixel = pimage->bytesperpixel; req->compression = pimage->compression; req->palsize = pimage->palsize; req->transcolor = pimage->transcolor; addr = GetReqData(req); memcpy(addr, pimage->imagebits, imagesize); memcpy(addr+imagesize, pimage->palette, palsize); } /** * GrDrawImageFromFile: * @id: the ID of the drawable to draw the image onto * @gc: the ID of the graphics context to use when drawing the image * @x: the X coordinate to draw the image at relative to the drawable * @y: the Y coordinate to draw the image at relative to the drawable * @width: the maximum image width * @height: the maximum image height * @path: string containing the filename of the image to load * @flags: flags specific to the particular image loader * * Loads the specified image file and draws it at the specified position * on the specified drawable using the specified graphics context. The * width and height values specify the size of the image to draw- if the * actual image is a different size, it will be scaled to fit. The image type * is automatically detected using the magic numbers in the image header (ie. * the filename extension is irrelevant). The currently supported image types * include GIF, JPEG, Windows BMP, PNG, XPM, and both ascii and binary * variants of PBM, PGM, and PPM. However the image types supported by a * particular server depend on which image types were enabled in the server * configuration at build time. */ void GrDrawImageFromFile(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, GR_SIZE width, GR_SIZE height, char* path, int flags) { nxDrawImageFromFileReq *req; req = AllocReqExtra(DrawImageFromFile, strlen(path)+1); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; req->width = width; req->height = height; req->flags = flags; memcpy(GetReqData(req), path, strlen(path)+1); } /** * GrLoadImageFromFile: * @path: string containing the filename of the image to load * @flags: flags specific to the particular image loader * @Returns: ID of the image buffer the image was loaded into * * Loads the specified image file into a newly created server image buffer * and returns the ID of the buffer. The image type is automatically detected * using the magic numbers in the image header (ie. the filename extension is * irrelevant). The currently supported image types include GIF, JPEG, Windows * BMP, PNG, XPM, and both ascii and binary variants of PBM, PGM, and PPM. * However the image types supported by a particular server depend on which * image types were enabled in the server configuration at build time. */ GR_IMAGE_ID GrLoadImageFromFile(char *path, int flags) { nxLoadImageFromFileReq *req; GR_IMAGE_ID imageid; req = AllocReqExtra(LoadImageFromFile, strlen(path)+1); req->flags = flags; memcpy(GetReqData(req), path, strlen(path)+1); if(GrTypedReadBlock(&imageid, sizeof(imageid), GrNumLoadImageFromFile) == -1) return 0; return imageid; } /** * GrDrawImageToFit: * @id: the ID of the drawable to draw the image onto * @gc: the ID of the graphics context to use when drawing the image * @x: the X coordinate to draw the image at relative to the drawable * @y: the Y coordinate to draw the image at relative to the drawable * @width: the maximum image width * @height: the maximum image height * @imageid: the ID of the image buffer containing the image to display * * Draws the image from the specified image buffer at the specified position * on the specified drawable using the specified graphics context. The * width and height values specify the size of the image to draw- if the * actual image is a different size, it will be scaled to fit. */ void GrDrawImageToFit(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, GR_SIZE width, GR_SIZE height, GR_IMAGE_ID imageid) { nxDrawImageToFitReq *req; req = AllocReq(DrawImageToFit); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; req->width = width; req->height = height; req->imageid = imageid; } /** * GrFreeImage: * @id: ID of the image buffer to free * * Destroys the specified image buffer and reclaims the memory used by it. */ void GrFreeImage(GR_IMAGE_ID id) { nxFreeImageReq *req; req = AllocReq(FreeImage); req->id = id; } /** * GrGetImageInfo: * @id: ID of an image buffer * @iip: pointer to a GR_IMAGE_INFO structure * * Fills in the specified image information structure with the details of the * specified image buffer. */ void GrGetImageInfo(GR_IMAGE_ID id, GR_IMAGE_INFO *iip) { nxGetImageInfoReq *req; req = AllocReq(GetImageInfo); req->id = id; GrTypedReadBlock(iip, sizeof(GR_IMAGE_INFO), GrNumGetImageInfo); } static int sendImageBuffer(void *buffer, int size) { int bufid; int bufsize = size; void *bufptr = buffer; nxImageBufferAllocReq *alloc; nxImageBufferSendReq *send; /* Step 1 - Allocate a buffer on the other side */ alloc = AllocReq(ImageBufferAlloc); alloc->size = size; GrTypedReadBlock(&bufid, sizeof(bufid), GrNumImageBufferAlloc); if (bufid < 0) return(0); /* step 2 - Send the buffer across */ while(bufsize > 0) { int chunk = (MAXREQUESTSZ - sizeof(nxImageBufferSendReq)); if (chunk > bufsize) chunk=bufsize; send = AllocReqExtra(ImageBufferSend, chunk); send->buffer_id = bufid; send->size = chunk; memcpy(GetReqData(send), bufptr, chunk); bufptr += chunk; bufsize -= chunk; } return(bufid); } GR_IMAGE_ID GrLoadImageFromBuffer(void *buffer, int size, int flags) { int bufid; nxLoadImageFromBufferReq *req; GR_IMAGE_ID imageid; /* Step 1 - Send the buffer to the other side */ bufid = sendImageBuffer(buffer, size); if (!bufid) return(0); /* Step 2 - Send the command to load the image */ /* Note - This will free the buffer automagically */ req = AllocReq(LoadImageFromBuffer); req->flags = flags; req->buffer = bufid; if(GrTypedReadBlock(&imageid, sizeof(imageid), GrNumLoadImageFromBuffer) == -1) return(0); else return(imageid); } void GrDrawImageFromBuffer(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, GR_SIZE width, GR_SIZE height, void *buffer, int size, int flags) { int bufid; nxDrawImageFromBufferReq *req; /* Step 1 - Send the buffer to the other side */ bufid = sendImageBuffer(buffer, size); if (!bufid) return; /* Step 2 - Send the command to load/draw the image */ /* Note - This will free the buffer automagically */ req = AllocReq(DrawImageFromBuffer); req->flags = flags; req->drawid = id; req->gcid = gc; req->x = x; req->y = y; req->width = width; req->height = height; req->flags = flags; req->buffer = bufid; } /* * Draw a rectangular area in the specified drawable using the specified * graphics context. This differs from rectangle drawing in that the * color values for each pixel in the rectangle are specified. * The color table is indexed * row by row. Values whose color matches the background color are only * written if the usebackground flag is set in the GC. * * The pixels are packed according to pixtype: * * pixtype array of * MWPF_RGB MWCOLORVAL (unsigned long) * MWPF_PIXELVAL MWPIXELVAL (compile-time dependent) * MWPF_PALETTE unsigned char * MWPF_TRUECOLOR0888 unsigned long * MWPF_TRUECOLOR888 packed struct {char r,char g,char b} (24 bits) * MWPF_TRUECOLOR565 unsigned short * MWPF_TRUECOLOR555 unsigned short * MWPF_TRUECOLOR332 unsigned char */ /** * GrArea: * @id: the ID of the drawable to draw the area onto * @gc: the ID of the graphics context to use when drawing the area * @x: the X coordinate to draw the area at relative to the drawable * @y: the Y coordinate to draw the area at relative to the drawable * @width: the width of the area * @height: the height of the area * @pixels: pointer to an array containing the pixel data * @pixtype: the format of the pixel data * * Draws the specified pixel array of the specified size and format onto the * specified drawable using the specified graphics context at the specified * position. Note that colour conversion is currently only performed when using * the GR_PF_RGB format, which is an unsigned long containing RGBX data. */ void GrArea(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, GR_SIZE width, GR_SIZE height, void *pixels, int pixtype) { nxAreaReq *req; long size; long chunk_y; int pixsize; /* Calculate size of packed pixels*/ switch(pixtype) { case MWPF_RGB: pixsize = sizeof(MWCOLORVAL); break; case MWPF_PIXELVAL: pixsize = sizeof(MWPIXELVAL); break; case MWPF_PALETTE: case MWPF_TRUECOLOR332: pixsize = sizeof(unsigned char); break; case MWPF_TRUECOLOR0888: pixsize = sizeof(unsigned long); break; case MWPF_TRUECOLOR888: pixsize = 3; break; case MWPF_TRUECOLOR565: case MWPF_TRUECOLOR555: pixsize = sizeof(unsigned short); break; default: return; } /* Break request into MAXREQUESTSZ size packets*/ while(height > 0) { chunk_y = (MAXREQUESTSZ - sizeof(nxAreaReq)) / ((long)width * pixsize); if(chunk_y > height) chunk_y = height; size = chunk_y * ((long)width * pixsize); req = AllocReqExtra(Area, size); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; req->width = width; req->height = chunk_y; req->pixtype = pixtype; memcpy(GetReqData(req), pixels, size); pixels = (void *)(((char *)pixels) + size); y += chunk_y; height -= chunk_y; } } /** * GrCopyArea: * @id: the ID of the drawable to copy the area to * @gc: the ID of the graphics context to use when copying the area * @x: the X coordinate to copy the area to within the destination drawable * @y: the Y coordinate to copy the area to within the destination drawable * @width: the width of the area to copy * @height: the height of the area to copy * @srcid: the ID of the drawable to copy the area from * @srcx: the X coordinate to copy the area from within the source drawable * @srcy: the Y coordinate to copy the area from within the source drawable * @op: the ROP codes to pass to the blitter when performing the copy * * Copies the specified area of the specified size between the specified * drawables at the specified positions using the specified graphics context * and ROP codes. 0 is a sensible default ROP code in most cases. */ void GrCopyArea(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, GR_SIZE width, GR_SIZE height, GR_DRAW_ID srcid, GR_COORD srcx, GR_COORD srcy, int op) { nxCopyAreaReq *req; req = AllocReq(CopyArea); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; req->width = width; req->height = height; req->srcid = srcid; req->srcx = srcx; req->srcy = srcy; req->op = op; } /** * GrReadArea: * @id: the ID of the drawable to read an area from * @x: the X coordinate to read the area from relative to the drawable * @y: the Y coordinate to read the area from relative to the drawable * @width: the width of the area to read * @height: the height of the area to read * @pixels: pointer to an area of memory to place the pixel data in * * Reads the pixel data of the specified size from the specified position on * the specified drawable into the specified pixel array. If the drawable is * a window, the data returned will be the pixel values from the relevant * position on the screen regardless of whether the window is obscured by other * windows. If the window is unmapped, or partially or fully outside a window * boundary, black pixel values will be returned. */ void GrReadArea(GR_DRAW_ID id,GR_COORD x,GR_COORD y,GR_SIZE width, GR_SIZE height, GR_PIXELVAL *pixels) { nxReadAreaReq *req; long size; req = AllocReq(ReadArea); req->drawid = id; req->x = x; req->y = y; req->width = width; req->height = height; size = (long)width * height * sizeof(MWPIXELVAL); GrTypedReadBlock(pixels, size, GrNumReadArea); } /** * GrPoint: * @id: the ID of the drawable to draw a point on * @gc: the ID of the graphics context to use when drawing the point * @x: the X coordinate to draw the point at relative to the drawable * @y: the Y coordinate to draw the point at relative to the drawable * * Draws a point using the specified graphics context at the specified position * on the specified drawable. */ void GrPoint(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y) { nxPointReq *req; req = AllocReq(Point); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; } /** * GrPoints: * @id: the ID of the drawable to draw a point on * @gc: the ID of the graphics context to use when drawing the point * @count: the number of points in the point table * @pointtable: pointer to a GR_POINT array which lists the points to draw * * Draws a set of points using the specified graphics context at the positions * specified by the point table on the specified drawable. */ void GrPoints(GR_DRAW_ID id, GR_GC_ID gc, GR_COUNT count, GR_POINT *pointtable) { nxPointsReq *req; long size; size = (long)count * sizeof(GR_POINT); req = AllocReqExtra(Points, size); req->drawid = id; req->gcid = gc; memcpy(GetReqData(req), pointtable, size); } /** * GrPoly: * @id: the ID of the drawable to draw the polygon onto * @gc: the ID of the graphics context to use when drawing the polygon * @count: the number of points in the point array * @pointtable: pointer to an array of points describing the polygon * * Draws an unfilled polygon on the specified drawable using the specified * graphics context. The polygon is specified by an array of point structures. * The polygon is not automatically closed- if a closed polygon is desired, * the last point must be the same as the first. */ void GrPoly(GR_DRAW_ID id, GR_GC_ID gc, GR_COUNT count, GR_POINT *pointtable) { nxPolyReq *req; long size; size = (long)count * sizeof(GR_POINT); req = AllocReqExtra(Poly, size); req->drawid = id; req->gcid = gc; memcpy(GetReqData(req), pointtable, size); } /** * GrFillPoly: * @id: the ID of the drawable to draw the polygon onto * @gc: the ID of the graphics context to use when drawing the polygon * @count: the number of points in the point array * @pointtable: pointer to an array of points describing the polygon * * Draws a filled polygon on the specified drawable using the specified * graphics context. The polygon is specified by an array of point structures. * The polygon is automatically closed- the last point need not be the same as * the first in order for the polygon to be closed. */ void GrFillPoly(GR_DRAW_ID id, GR_GC_ID gc, GR_COUNT count,GR_POINT *pointtable) { nxFillPolyReq *req; long size; size = (long)count * sizeof(GR_POINT); req = AllocReqExtra(FillPoly, size); req->drawid = id; req->gcid = gc; memcpy(GetReqData(req), pointtable, size); } /** * GrText: * @id: the ID of the drawable to draw the text string onto * @gc: the ID of the graphics context to use when drawing the text string * @x: the X coordinate to draw the string at relative to the drawable * @y: the Y coordinate to draw the string at relative to the drawable * @str: the text string to draw * @count: the number of characters (not bytes) in the string * @flags: flags specifying text encoding, alignment, etc. * * Draws the specified text string at the specified position on the specified * drawable using the specified graphics context and flags. The default flags * specify ASCII encoding and baseline alignment. */ void GrText(GR_DRAW_ID id, GR_GC_ID gc, GR_COORD x, GR_COORD y, void *str, GR_COUNT count, int flags) { nxTextReq *req; int size; if(count == -1 && (flags&MWTF_PACKMASK) == MWTF_ASCII) count = strlen((char *)str); size = nxCalcStringBytes(str, count, flags); req = AllocReqExtra(Text, size); req->drawid = id; req->gcid = gc; req->x = x; req->y = y; req->count = count; req->flags = flags; memcpy(GetReqData(req), str, size); } /** * GrGetSystemPalette: * @pal: pointer to a palette structure to fill in with the system palette * * Retrieves the system palette and places it in the specified palette * structure. */ void GrGetSystemPalette(GR_PALETTE *pal) { AllocReq(GetSystemPalette); GrTypedReadBlock(pal, sizeof(*pal), GrNumGetSystemPalette); } /** * GrSetSystemPalette: * @first: the first palette value to set * @pal: pointer to a palette structure containing the new values * * Sets the system palette to the values stored in the specified palette * structure. The values before the specified first value are not set. */ void GrSetSystemPalette(GR_COUNT first, GR_PALETTE *pal) { nxSetSystemPaletteReq *req; req = AllocReq(SetSystemPalette); req->first = first; req->count = pal->count; memcpy(req->palette, pal->palette, sizeof(GR_PALENTRY) * pal->count); } /** * GrFindColor: * @c: the colour value to find * @retpixel: pointer to the returned pixel value * * Calculates the pixel value to use to display the specified colour value. * The colour value is specified as a GR_COLOR, which is a 32 bit truecolour * value stored as RGBX. The pixel value size depends on the architecture. */ void GrFindColor(GR_COLOR c, GR_PIXELVAL *retpixel) { nxFindColorReq *req; req = AllocReq(FindColor); req->color = c; GrTypedReadBlock(retpixel, sizeof(*retpixel), GrNumFindColor); } /** * GrReqShmCmds: * @shmsize: the size of the shared memory area to allocate * * Requests a shared memory area of the specified size to use for transferring * command arguments. This is faster but less portable than the standard BSD * sockets method of communication (and of course will only work if the client * and server are on the same machine). Apart from the initial allocation of * the area using this call, the use of shared memory is completely * transparent. Additionally, if the allocation fails we silently and * automatically fall back on socket communication. It is safe to call this * function even if shared memory support is not compiled in; it will simply * do nothing. * * FIXME: how does the user decide what size of shared memory area to allocate? */ void GrReqShmCmds(long shmsize) { #if HAVE_SHAREDMEM_SUPPORT nxReqShmCmdsReq req; int key, shmid; if ( nxSharedMem != 0 ) return; GrFlush(); shmsize = (shmsize+SHM_BLOCK_SIZE-1) & ~(SHM_BLOCK_SIZE-1); req.reqType = GrNumReqShmCmds; req.hilength = 0; req.length = sizeof(req); req.size = shmsize; nxWriteSocket((char *)&req,sizeof(req)); GrReadBlock(&key,sizeof(key)); if ( !key ) { EPRINTF("nxclient: no shared memory support on server\n"); return; } shmid = shmget(key,shmsize,0); if ( shmid == -1 ) { EPRINTF("nxclient: Can't shmget key %d: %m\n", key); return; } nxSharedMem = shmat(shmid,0,0); shmctl(shmid,IPC_RMID,0); /* Prevent other from attaching */ if ( nxSharedMem == (char *)-1 ) return; nxSharedMemSize = shmsize; nxAssignReqbuffer(nxSharedMem, shmsize); #endif /* HAVE_SHAREDMEM_SUPPORT*/ } /** * GrInjectPointerEvent: * @x: the X coordinate of the pointer event relevant to the root window * @y: the Y coordinate of the pointer event relevant to the root window * @button: the pointer button status * @visible: whether to display the pointer after the event * * Sets the pointer invisible if the visible parameter is GR_FALSE, or visible * if it is GR_TRUE, then moves the pointer to the specified position and * generates a mouse event with the specified button status. Also performs * a GrFlush() so that the event takes effect immediately. */ void GrInjectPointerEvent(GR_COORD x, GR_COORD y, int button, int visible) { nxInjectEventReq *req; req = AllocReq(InjectEvent); req->event_type = GR_INJECT_EVENT_POINTER; req->event.pointer.visible = visible; req->event.pointer.x = x; req->event.pointer.y = y; req->event.pointer.button = button; GrFlush(); } /** * GrInjectKeyboardEvent: * @wid: ID of the window to send the event to, or 0 * @uch: 32 bit Unicode keystroke value to inject * @ch: 8 bit ascii keystroke value to inject * @modifier: modifiers (shift, ctrl, alt, etc.) to inject * @special: special keys to inject * @content: mask specifying which arguments are valid * * Sends a keyboard event to the specified window, or to the window with the * current keyboard focus if 0 is used as the ID. The other arguments * correspond directly to the fields of the same names in the keyboard event * structure. */ void GrInjectKeyboardEvent(GR_WINDOW_ID wid, GR_KEY keyvalue, GR_KEYMOD modifier, GR_SCANCODE scancode, GR_BOOL pressed) { nxInjectEventReq *req; req = AllocReq(InjectEvent); req->event_type = GR_INJECT_EVENT_KEYBOARD; req->event.keyboard.wid = wid; req->event.keyboard.keyvalue = keyvalue; req->event.keyboard.modifier = modifier; req->event.keyboard.scancode = scancode; req->event.keyboard.pressed = pressed; GrFlush(); } /** * GrSetWMProperties: * @wid: the ID of the window to set the WM properties of * @props: pointer to a GR_WM_PROPERTIES structure * * Copies the provided GR_WM_PROPERTIES structure into the the GR_WM_PROPERTIES * structure of the specified window id. */ void GrSetWMProperties(GR_WINDOW_ID wid, GR_WM_PROPERTIES *props) { nxSetWMPropertiesReq *req; char *addr; int s; if ((props->flags & GR_WM_FLAGS_TITLE) && props->title) s = strlen(props->title) + 1; else s = 0; req = AllocReqExtra(SetWMProperties, s + sizeof(GR_WM_PROPERTIES)); req->windowid = wid; addr = GetReqData(req); memcpy(addr, props, sizeof(GR_WM_PROPERTIES)); if (s) memcpy(addr + sizeof(GR_WM_PROPERTIES), props->title, s); } /** * GrGetWMProperties: * @wid: the ID of the window to retreive the WM properties of * @props: pointer to a GR_WM_PROPERTIES structure to fill in * * Reads the GR_WM_PROPERTIES structure for the window with the specified * id and fills in the provided structure with the information. * It is the callers responsibility to free the title member as it is allocated * dynamically. The title field will be set to NULL if the window has no title. */ void GrGetWMProperties(GR_WINDOW_ID wid, GR_WM_PROPERTIES *props) { nxGetWMPropertiesReq *req; UINT16 textlen; GR_CHAR c; req = AllocReq(GetWMProperties); req->windowid = wid; GrTypedReadBlock(props, sizeof(GR_WM_PROPERTIES), GrNumGetWMProperties); GrReadBlock(&textlen, sizeof(textlen)); if(!textlen) { props->title = NULL; return; } if(!(props->title = malloc(textlen))) { /* Oh dear, we're out of memory but still have to purge the requested data (and throw it away) */ while(textlen--) GrReadBlock(&c, 1); } else { GrReadBlock(props->title, textlen); } } /** * GrCloseWindow: * @wid: the ID of the window to send the CLOSE_REQ event to * * Sends a CLOSE_REQ event to the specified window if the client has selected * to receive CLOSE_REQ events on this window. Used to request an application * to shut down but not force it to do so immediately, so the application can * ask whether to save changed files before shutting down cleanly. */ void GrCloseWindow(GR_WINDOW_ID wid) { nxCloseWindowReq *req; req = AllocReq(CloseWindow); req->windowid = wid; } /** * GrKillWindow: * @wid: the ID of the window to kill * * Forcibly disconnects the client which owns this window with the specified * ID number. Used to kill an application which has locked up and is not * responding to CLOSE_REQ events. */ void GrKillWindow(GR_WINDOW_ID wid) { nxKillWindowReq *req; req = AllocReq(KillWindow); req->windowid = wid; } /** * GrSetScreenSaverTimeout: * @timeout: the number of seconds of inactivity before screen saver activates * * Sets the number of seconds of inactivity before a screen saver activate * event is sent to the root window ID. A value of 0 activates the * screen saver immediately, and a value of -1 disables the screen saver * function. */ void GrSetScreenSaverTimeout(GR_TIMEOUT timeout) { nxSetScreenSaverTimeoutReq *req; req = AllocReq(SetScreenSaverTimeout); req->timeout = timeout; } /** * GrSetSelectionOwner: * @wid: the ID of the window to set the selection owner to * @typelist: list of mime types selection data can be supplied as * * Sets the current selection (otherwise known as the clipboard) ownership * to the specified window. Specifying an owner of 0 disowns the selection. * The typelist argument is a list of mime types (seperated by space * characters) which the window is able to supply the data as. At least one * type must be specified unless you are disowning the selection (typically * text/plain for plain ASCII text or text/uri-list for a filename). * * The window which owns the current selection must be prepared to handle * SELECTION_LOST events (received when another window takes ownership of the * selection) and CLIENT_DATA_REQ events (received when a client wishes to * retreive the selection data). */ void GrSetSelectionOwner(GR_WINDOW_ID wid, GR_CHAR *typelist) { nxSetSelectionOwnerReq *req; char *p; int len; if(wid) { len = strlen(typelist) + 1; req = AllocReqExtra(SetSelectionOwner, len); p = GetReqData(req); memcpy(p, typelist, len); } else { req = AllocReq(SetSelectionOwner); } req->wid = wid; } /** * GrGetSelectionOwner: * @typelist: pointer used to return the list of available mime types * @Returns: the ID of the window which currently owns the selection, or 0 * * Finds the window which currently owns the selection and returns its ID, * or 0 if no window currently owns the selection. A pointer to the list of * mime types the selection owner is capable of supplying is placed in the * pointer specified by the typelist argument. The typelist is null terminated, * and the fields are seperated by space characters. It is the callers * responsibility to free the typelist string, as it is allocated dynamically. * If the allocation fails, it will be set to a NULL pointer, so remember to * check the value of it before using it. */ GR_WINDOW_ID GrGetSelectionOwner(GR_CHAR **typelist) { nxGetSelectionOwnerReq *req; UINT16 textlen; GR_CHAR c; GR_WINDOW_ID wid; req = AllocReq(GetSelectionOwner); GrTypedReadBlock(&wid, sizeof(wid), GrNumGetSelectionOwner); if(wid) { GrReadBlock(&textlen, sizeof(textlen)); if(!(*typelist = malloc(textlen))) { /* Oh dear, we're out of memory but still have to purge the requested data (and throw it away) */ while(textlen--) GrReadBlock(&c, 1); } else { GrReadBlock(*typelist, textlen); } } return wid; } /** * GrRequestClientData: * @wid: the ID of the window requesting the data * @rid: the ID of the window to request the data from * @serial: the serial number of the request * @mimetype: the number of the desired mime type to request * * Sends a CLIENT_DATA_REQ event to the specified window. Used for requesting * both selection and "drag and drop" data. The mimetype argument specifies * the format of the data you would like to receive, as an index into the list * returned by GrGetSelectionOwner (the first type in the list is index 0). * The server makes no guarantees as to when, or even if, the client will * reply to the request. If the client does reply, the reply will take the * form of one or more CLIENT_DATA events. The request serial number is * typically a unique ID which the client can assign to a request in order for * it to be able to keep track of transfers (CLIENT_DATA events contain the * same number in the sid field). Remember to free the data field of the * CLIENT_DATA events as they are dynamically allocated. Also note that if * the allocation fails the data field will be set to NULL, so you should * check the value before using it. */ void GrRequestClientData(GR_WINDOW_ID wid, GR_WINDOW_ID rid, GR_SERIALNO serial, GR_MIMETYPE mimetype) { nxRequestClientDataReq *req; req = AllocReq(RequestClientData); req->wid = wid; req->rid = rid; req->serial = serial; req->mimetype = mimetype; } /** * GrSendClientData: * @wid: the ID of the window sending the data * @did: the ID of the destination window * @sid: the serial number of the request * @len: the number of bytes of data to transfer * @thislen: the number of bytes in this packet * @data: pointer to the data to transfer * * Used as the response to a CLIENT_DATA_REQ event. Sends the specified data * of the specified length to the specified window using the specified source * window ID and transfer serial number. Any fragmentation of the data into * multiple CLIENT_DATA events which is required is handled automatically. * The serial number should always be set to the value supplied by the * CLIENT_DATA_REQ event. The thislen parameter is used internally to split * the data up into packets. It should be set to the same value as the len * parameter. * */ void GrSendClientData(GR_WINDOW_ID wid, GR_WINDOW_ID did, GR_SERIALNO serial, GR_LENGTH len, GR_LENGTH thislen, void *data) { nxSendClientDataReq *req; char *p; GR_LENGTH l, pos = 0; while(pos < len) { l = MAXREQUESTSZ - sizeof(nxSendClientDataReq); if(l > (len - pos)) l = len - pos; req = AllocReqExtra(SendClientData, l); req->wid = wid; req->did = did; req->serial = serial; req->len = len; p = GetReqData(req); memcpy(p, data + pos, l); pos += l; } } /** * GrBell: * * Asks the server to ring the console bell on behalf of the client (intended * for terminal apps to be able to ring the bell on the server even if they * are running remotely). */ void GrBell(void) { AllocReq(Bell); } /** * GrSetBackgroundPixmap: * @wid: ID of the window to set the background of * @pixmap: ID of the pixmap to use as the background * @flags: flags specifying how to draw the pixmap onto the window * * Sets the background of the specified window to the specified pixmap. * The flags which specify how to draw the pixmap (in the top left of the * window, in the centre of the window, tiled, etc.) are those which start with * GR_BACKGROUND_ in nano-X.h. If the pixmap value is 0, the server will * disable the background pixmap and return to using a solid colour fill. */ void GrSetBackgroundPixmap(GR_WINDOW_ID wid, GR_WINDOW_ID pixmap, int flags) { nxSetBackgroundPixmapReq *req; req = AllocReq(SetBackgroundPixmap); req->wid = wid; req->pixmap = pixmap; req->flags = flags; } /** * GrDestroyCursor: * @id: ID of the cursor to destory * * Destroys the specified server-based cursor and * reclaims the memory used by it. */ void GrDestroyCursor(GR_CURSOR_ID cid) { nxDestroyCursorReq *req; req = AllocReq(DestroyCursor); req->cursorid = cid; } /** * GrQueryTree: * @wid: window ID for query * @parentid: returned parent ID * @children: returned children ID list * @nchildren: returned children count * * Return window parent and list of children. * Caller must free() children list after use. */ void GrQueryTree(GR_WINDOW_ID wid, GR_WINDOW_ID *parentid, GR_WINDOW_ID **children, GR_COUNT *nchildren) { nxQueryTreeReq *req; GR_COUNT count; GR_WINDOW_ID dummy; req = AllocReq(QueryTree); req->windowid = wid; GrTypedReadBlock(parentid, sizeof(*parentid), GrNumQueryTree); GrReadBlock(nchildren, sizeof(*nchildren)); if (!*nchildren) { *children = NULL; return; } count = *nchildren; if(!(*children = malloc(count * sizeof(GR_WINDOW_ID)))) { /* We're out of memory but still have to purge the requested data (and throw it away) */ while(count--) GrReadBlock(&dummy, sizeof(GR_WINDOW_ID)); } else { GrReadBlock(*children, count * sizeof(GR_WINDOW_ID)); } } #if YOU_WANT_TO_IMPLEMENT_DRAG_AND_DROP /** * GrRegisterDragAndDropWindow: * @wid: the ID of the window to use as the drag and drop source window * @iid: the ID of the pixmap to use as the drag and drop icon * @typelist: list of mime types the drag and drop data can be supplied as * * Enables the specified window to be used as a drag and drop source. The * specified pixmap will be used as the icon shown whilst dragging, and the * null terminated, newline seperated list of mime types which the data can * be supplied as is specified by the typelist argument. At least one type * (typically text/plain for plain ASCII or text/uri-list for a filename or * list of filenames) must be specified. When the icon is dropped, * the window which it is dropped on will receive a DROP event (providing it * has selected for DROP events), and if the client wishes to accept the data * and is able to handle one of the mime types in the type list, it should use * GrRequestClientData() to retrieve the data from the drag and drop source * window. Remember to free the typelist field of the DROP event as it is * dynamically allocated. It is possible for a client to select for DROP events * on the Root window if it is desired to allow dropping icons on the desktop. */ void GrRegisterDragAndDropWindow(GR_WINDOW_ID wid, GR_WINDOW_ID iid, GR_CHAR *typelist) { } #endif GR_TIMER_ID GrCreateTimer (GR_WINDOW_ID wid, GR_TIMEOUT period) { nxCreateTimerReq *req; GR_TIMER_ID timerid; req = AllocReq(CreateTimer); req->wid = wid; req->period = period; if (GrTypedReadBlock(&timerid, sizeof (timerid), GrNumCreateTimer) == -1) return 0; return timerid; } void GrDestroyTimer (GR_TIMER_ID tid) { nxDestroyTimerReq *req; req = AllocReq(DestroyTimer); req->timerid = tid; } void GrSetPortraitMode(int portraitmode) { nxSetPortraitModeReq *req; req = AllocReq(SetPortraitMode); req->portraitmode = portraitmode; }