/* * Copyright 1990,91 by Thomas Roell, Dinkelscherben, Germany. * * Permission to use, copy, modify, distribute, and sell this software and its * documentation for any purpose is hereby granted without fee, provided that * the above copyright notice appear in all copies and that both that * copyright notice and this permission notice appear in supporting * documentation, and that the name of Thomas Roell not be used in * advertising or publicity pertaining to distribution of the software without * specific, written prior permission. Thomas Roell makes no representations * about the suitability of this software for any purpose. It is provided * "as is" without express or implied warranty. * * THOMAS ROELL DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, * INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO * EVENT SHALL THOMAS ROELL BE LIABLE FOR ANY SPECIAL, INDIRECT OR * CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, * DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER * TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR * PERFORMANCE OF THIS SOFTWARE. * */ /* * Copyright (c) 1994-2003 by The XFree86 Project, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. * * Except as contained in this notice, the name of the copyright holder(s) * and author(s) shall not be used in advertising or otherwise to promote * the sale, use or other dealings in this Software without prior written * authorization from the copyright holder(s) and author(s). */ /* [JCH-96/01/21] Extended std reverse map to four buttons. */ #ifdef HAVE_XORG_CONFIG_H #include #endif #ifdef __UNIXOS2__ #define I_NEED_OS2_H #endif #include #include #include #include "misc.h" #include "compiler.h" #include "xf86.h" #include "xf86Priv.h" #define XF86_OS_PRIVS #include "xf86_OSlib.h" #include "atKeynames.h" #ifdef XFreeXDGA #include "dgaproc.h" #endif #ifdef XINPUT #include #include #else #include "inputstr.h" #endif #include "xf86Xinput.h" #include "mi.h" #include "mipointer.h" #ifdef XF86BIGFONT #define _XF86BIGFONT_SERVER_ #include #endif #ifdef XKB extern Bool noXkbExtension; #endif #ifdef DPMSExtension #define DPMS_SERVER #include #include "dpmsproc.h" #endif #define XE_POINTER 1 #define XE_KEYBOARD 2 #define EqEnqueue(pDev, ev) { \ int __sigstate = xf86BlockSIGIO (); \ mieqEnqueue (pDev, ev); \ xf86UnblockSIGIO(__sigstate); \ } /* * The first of many hacks to get VT switching to work under * Solaris 2.1 for x86. The basic problem is that Solaris is supposed * to be SVR4. It is for the most part, except where the video interface * is concerned. These hacks work around those problems. * See the comments for Linux, and SCO. * * This is a toggling variable: * FALSE = No VT switching keys have been pressed last time around * TRUE = Possible VT switch Pending * (DWH - 12/2/93) * * This has been generalised to work with Linux and *BSD+syscons (DHD) */ #ifdef USE_VT_SYSREQ static Bool VTSysreqToggle = FALSE; #endif /* !USE_VT_SYSREQ */ _X_EXPORT Bool VTSwitchEnabled = TRUE; /* Allows run-time disabling for *BSD and for avoiding VT switches when using the DRI automatic full screen mode.*/ extern fd_set EnabledDevices; #ifdef XF86PM extern void (*xf86OSPMClose)(void); #endif static void xf86VTSwitch(void); /* * Allow arbitrary drivers or other XFree86 code to register with our main * Wakeup handler. */ typedef struct x_IHRec { int fd; InputHandlerProc ihproc; pointer data; Bool enabled; struct x_IHRec * next; } IHRec, *IHPtr; static IHPtr InputHandlers = NULL; Bool LegalModifier(unsigned int key, DeviceIntPtr pDev) { return TRUE; } /* * TimeSinceLastInputEvent -- * Function used for screensaver purposes by the os module. Returns the * time in milliseconds since there last was any input. */ int TimeSinceLastInputEvent() { if (xf86Info.lastEventTime == 0) { xf86Info.lastEventTime = GetTimeInMillis(); } return GetTimeInMillis() - xf86Info.lastEventTime; } /* * SetTimeSinceLastInputEvent -- * Set the lastEventTime to now. */ _X_EXPORT void SetTimeSinceLastInputEvent() { xf86Info.lastEventTime = GetTimeInMillis(); } /* * ProcessInputEvents -- * Retrieve all waiting input events and pass them to DIX in their * correct chronological order. Only reads from the system pointer * and keyboard. */ void ProcessInputEvents () { int x, y; #ifdef INHERIT_LOCK_STATE static int generation = 0; #endif /* * With INHERIT_LOCK_STATE defined, the initial state of CapsLock, NumLock * and ScrollLock will be set to match that of the VT the server is * running on. */ #ifdef INHERIT_LOCK_STATE if (generation != serverGeneration) { xEvent kevent; DevicePtr pKeyboard = xf86Info.pKeyboard; extern unsigned int xf86InitialCaps, xf86InitialNum, xf86InitialScroll; generation = serverGeneration; kevent.u.keyButtonPointer.time = GetTimeInMillis(); kevent.u.keyButtonPointer.rootX = 0; kevent.u.keyButtonPointer.rootY = 0; kevent.u.u.type = KeyPress; if (xf86InitialCaps) { kevent.u.u.detail = xf86InitialCaps; (* pKeyboard->processInputProc)(&kevent, (DeviceIntPtr)pKeyboard, 1); xf86InitialCaps = 0; } if (xf86InitialNum) { kevent.u.u.detail = xf86InitialNum; (* pKeyboard->processInputProc)(&kevent, (DeviceIntPtr)pKeyboard, 1); xf86InitialNum = 0; } if (xf86InitialScroll) { kevent.u.u.detail = xf86InitialScroll; (* pKeyboard->processInputProc)(&kevent, (DeviceIntPtr)pKeyboard, 1); xf86InitialScroll = 0; } } #endif xf86Info.inputPending = FALSE; mieqProcessInputEvents(); miPointerUpdateSprite(inputInfo.pointer); miPointerGetPosition(inputInfo.pointer, &x, &y); xf86SetViewport(xf86Info.currentScreen, x, y); } void xf86GrabServerCallback(CallbackListPtr *callbacks, pointer data, pointer args) { ServerGrabInfoRec *grab = (ServerGrabInfoRec*)args; xf86Info.grabInfo.server.client = grab->client; xf86Info.grabInfo.server.grabstate = grab->grabstate; } /* * Handle keyboard events that cause some kind of "action" * (i.e., server termination, video mode changes, VT switches, etc.) */ void xf86ProcessActionEvent(ActionEvent action, void *arg) { #ifdef DEBUG ErrorF("ProcessActionEvent(%d,%x)\n", (int) action, arg); #endif switch (action) { case ACTION_TERMINATE: if (!xf86Info.dontZap) { #ifdef XFreeXDGA DGAShutdown(); #endif GiveUp(0); } break; case ACTION_NEXT_MODE: if (!xf86Info.dontZoom) xf86ZoomViewport(xf86Info.currentScreen, 1); break; case ACTION_PREV_MODE: if (!xf86Info.dontZoom) xf86ZoomViewport(xf86Info.currentScreen, -1); break; case ACTION_DISABLEGRAB: if (!xf86Info.grabInfo.disabled && xf86Info.grabInfo.allowDeactivate) { if (inputInfo.pointer && inputInfo.pointer->grab != NULL && inputInfo.pointer->DeactivateGrab) inputInfo.pointer->DeactivateGrab(inputInfo.pointer); if (inputInfo.keyboard && inputInfo.keyboard->grab != NULL && inputInfo.keyboard->DeactivateGrab) inputInfo.keyboard->DeactivateGrab(inputInfo.keyboard); } break; case ACTION_CLOSECLIENT: if (!xf86Info.grabInfo.disabled && xf86Info.grabInfo.allowClosedown) { ClientPtr pointer, keyboard, server; pointer = keyboard = server = NULL; if (inputInfo.pointer && inputInfo.pointer->grab != NULL) pointer = clients[CLIENT_ID(inputInfo.pointer->grab->resource)]; if (inputInfo.keyboard && inputInfo.keyboard->grab != NULL) { keyboard = clients[CLIENT_ID(inputInfo.keyboard->grab->resource)]; if (keyboard == pointer) keyboard = NULL; } if ((xf86Info.grabInfo.server.grabstate == SERVER_GRABBED) && (((server = xf86Info.grabInfo.server.client) == pointer) || (server == keyboard))) server = NULL; if (pointer) CloseDownClient(pointer); if (keyboard) CloseDownClient(keyboard); if (server) CloseDownClient(server); } break; #if !defined(__SOL8__) && !defined(__UNIXOS2__) && !defined(sgi) && \ (!defined(sun) || defined(i386)) && defined(VT_ACTIVATE) case ACTION_SWITCHSCREEN: if (VTSwitchEnabled && !xf86Info.dontVTSwitch && arg) { int vtno = *((int *) arg); #if defined(__SCO__) || defined(__UNIXWARE__) vtno--; #endif #if defined(QNX4) xf86Info.vtRequestsPending = vtno; #else if (ioctl(xf86Info.consoleFd, VT_ACTIVATE, vtno) < 0) ErrorF("Failed to switch consoles (%s)\n", strerror(errno)); #endif } break; case ACTION_SWITCHSCREEN_NEXT: if (VTSwitchEnabled && !xf86Info.dontVTSwitch) { /* Shouldn't this be true for (sun) && (i386) && (SVR4) ? */ #if defined(__SCO__) || defined(__UNIXWARE__) if (ioctl(xf86Info.consoleFd, VT_ACTIVATE, xf86Info.vtno) < 0) #else if (ioctl(xf86Info.consoleFd, VT_ACTIVATE, xf86Info.vtno + 1) < 0) #endif #if defined (__SCO__) || (defined(sun) && defined (i386) && defined (SVR4)) || defined(__UNIXWARE__) if (ioctl(xf86Info.consoleFd, VT_ACTIVATE, 0) < 0) #else if (ioctl(xf86Info.consoleFd, VT_ACTIVATE, 1) < 0) #endif ErrorF("Failed to switch consoles (%s)\n", strerror(errno)); } break; case ACTION_SWITCHSCREEN_PREV: if (VTSwitchEnabled && !xf86Info.dontVTSwitch && xf86Info.vtno > 0) { if (ioctl(xf86Info.consoleFd, VT_ACTIVATE, xf86Info.vtno - 1) < 0) ErrorF("Failed to switch consoles (%s)\n", strerror(errno)); } break; #endif case ACTION_MESSAGE: { char *retstr, *message = (char *) arg; ScrnInfoPtr pScr = XF86SCRNINFO(xf86Info.currentScreen); #ifdef DEBUG ErrorF("ActionMessage: '%s'\n", message); #endif /* Okay the message made it to the ddx. The common layer */ /* can check for relevant messages here and react to any */ /* that have a global effect. For example: */ /* */ /* if (!strcmp(message, "foo") { */ /* do_foo(); break */ /* } */ /* */ /* otherwise fallback to sending a key event message to */ /* the current screen's driver: */ if (*pScr->HandleMessage != NULL) { (void) (*pScr->HandleMessage)(pScr->scrnIndex, "KeyEventMessage", message, &retstr); } } break; default: break; } } #define ModifierIsSet(k) ((modifiers & (k)) == (k)) _X_EXPORT Bool xf86CommonSpecialKey(int key, Bool down, int modifiers) { if ((!ModifierIsSet(ShiftMask)) && (((ModifierIsSet(ControlMask | AltMask)) || (ModifierIsSet(ControlMask | AltLangMask))))) { switch (key) { case KEY_BackSpace: xf86ProcessActionEvent(ACTION_TERMINATE, NULL); break; /* * Check grabs */ case KEY_KP_Divide: xf86ProcessActionEvent(ACTION_DISABLEGRAB, NULL); break; case KEY_KP_Multiply: xf86ProcessActionEvent(ACTION_CLOSECLIENT, NULL); break; /* * The idea here is to pass the scancode down to a list of * registered routines. There should be some standard conventions * for processing certain keys. */ case KEY_KP_Minus: /* Keypad - */ if (down) xf86ProcessActionEvent(ACTION_PREV_MODE, NULL); if (!xf86Info.dontZoom) return TRUE; break; case KEY_KP_Plus: /* Keypad + */ if (down) xf86ProcessActionEvent(ACTION_NEXT_MODE, NULL); if (!xf86Info.dontZoom) return TRUE; break; } } return FALSE; } /* * xf86Wakeup -- * Os wakeup handler. */ /* ARGSUSED */ void xf86Wakeup(pointer blockData, int err, pointer pReadmask) { #if !defined(__UNIXOS2__) && !defined(__QNX__) fd_set* LastSelectMask = (fd_set*)pReadmask; fd_set devicesWithInput; InputInfoPtr pInfo; if (err >= 0) { XFD_ANDSET(&devicesWithInput, LastSelectMask, &EnabledDevices); if (XFD_ANYSET(&devicesWithInput)) { pInfo = xf86InputDevs; while (pInfo) { if (pInfo->read_input && pInfo->fd >= 0 && (FD_ISSET(pInfo->fd, &devicesWithInput) != 0)) { int sigstate = xf86BlockSIGIO(); pInfo->read_input(pInfo); xf86UnblockSIGIO(sigstate); /* * Remove the descriptior from the set because more than one * device may share the same file descriptor. */ FD_CLR(pInfo->fd, &devicesWithInput); } pInfo = pInfo->next; } } } #else /* __UNIXOS2__ and __QNX__ */ InputInfoPtr pInfo; pInfo = xf86InputDevs; while (pInfo) { if (pInfo->read_input && pInfo->fd >= 0) { int sigstate = xf86BlockSIGIO(); pInfo->read_input(pInfo); xf86UnblockSIGIO(sigstate); /* * Must break here because more than one device may share * the same file descriptor. */ break; } pInfo = pInfo->next; } #endif /* __UNIXOS2__ and __QNX__ */ if (err >= 0) { /* we don't want the handlers called if select() */ IHPtr ih; /* returned with an error condition, do we? */ for (ih = InputHandlers; ih; ih = ih->next) { if (ih->enabled && ih->fd >= 0 && ih->ihproc && (FD_ISSET(ih->fd, ((fd_set *)pReadmask)) != 0)) { ih->ihproc(ih->fd, ih->data); } } } if (xf86VTSwitchPending()) xf86VTSwitch(); if (xf86Info.inputPending) ProcessInputEvents(); } /* * xf86SigioReadInput -- * signal handler for the SIGIO signal. */ static void xf86SigioReadInput(int fd, void *closure) { int sigstate = xf86BlockSIGIO(); InputInfoPtr pInfo = (InputInfoPtr) closure; pInfo->read_input(pInfo); xf86UnblockSIGIO(sigstate); } /* * xf86AddEnabledDevice -- * */ _X_EXPORT void xf86AddEnabledDevice(InputInfoPtr pInfo) { if (!xf86InstallSIGIOHandler (pInfo->fd, xf86SigioReadInput, pInfo)) { AddEnabledDevice(pInfo->fd); } } /* * xf86RemoveEnabledDevice -- * */ _X_EXPORT void xf86RemoveEnabledDevice(InputInfoPtr pInfo) { if (!xf86RemoveSIGIOHandler (pInfo->fd)) { RemoveEnabledDevice(pInfo->fd); } } static int *xf86SignalIntercept = NULL; _X_EXPORT void xf86InterceptSignals(int *signo) { if ((xf86SignalIntercept = signo)) *signo = -1; } static void (*xf86SigIllHandler)(void) = NULL; _X_EXPORT void xf86InterceptSigIll(void (*sigillhandler)(void)) { xf86SigIllHandler = sigillhandler; } #ifdef HAVE_BACKTRACE #include static __inline__ void xorg_backtrace(void) { void *array[32]; /* deeper nesting than this means something's wrong */ size_t size, i; char **strings; ErrorF("\nBacktrace:\n"); size = backtrace(array, 32); strings = backtrace_symbols(array, size); for (i = 0; i < size; i++) ErrorF("%d: %s\n", i, strings[i]); free(strings); } #else /* not glibc or glibc < 2.1 */ # if defined(sun) && defined(__SVR4) # define HAVE_PSTACK # endif # if defined(HAVE_WALKCONTEXT) /* Solaris 9 & later */ # include # include # include # include #ifdef _LP64 # define ElfSym Elf64_Sym #else # define ElfSym Elf32_Sym #endif /* Called for each frame on the stack to print it's contents */ static int xorg_backtrace_frame(uintptr_t pc, int signo, void *arg) { Dl_info dlinfo; ElfSym *dlsym; char header[32]; int depth = *((int *) arg); if (signo) { char signame[SIG2STR_MAX]; if (sig2str(signo, signame) != 0) { strcpy(signame, "unknown"); } ErrorF("** Signal %d (%s)\n", signo, signame); } snprintf(header, sizeof(header), "%d: 0x%lx", depth, pc); *((int *) arg) = depth + 1; /* Ask system dynamic loader for info on the address */ if (dladdr1((void *) pc, &dlinfo, (void **) &dlsym, RTLD_DL_SYMENT)) { unsigned long offset = pc - (uintptr_t) dlinfo.dli_saddr; const char *symname; if (offset < dlsym->st_size) { /* inside a function */ symname = dlinfo.dli_sname; } else { /* found which file it was in, but not which function */ symname = "
"; offset = pc - (uintptr_t)dlinfo.dli_fbase; } ErrorF("%s: %s:%s+0x%lx\n", header, dlinfo.dli_fname, symname, offset); } else { /* Couldn't find symbol info from system dynamic loader, should * probably poke elfloader here, but haven't written that code yet, * so we just print the pc. */ ErrorF("%s\n", header); } return 0; } # endif /* HAVE_WALKCONTEXT */ # ifdef HAVE_PSTACK static int xorg_backtrace_pstack(void) { pid_t kidpid; int pipefd[2]; if (pipe(pipefd) != 0) { return -1; } kidpid = fork1(); if (kidpid == -1) { /* ERROR */ return -1; } else if (kidpid == 0) { /* CHILD */ char parent[16]; seteuid(0); close(STDIN_FILENO); close(STDOUT_FILENO); dup2(pipefd[1],STDOUT_FILENO); closefrom(STDERR_FILENO); snprintf(parent, sizeof(parent), "%d", getppid()); execle("/usr/bin/pstack", "pstack", parent, NULL); exit(1); } else { /* PARENT */ char btline[256]; int kidstat; int bytesread; int done = 0; close(pipefd[1]); while (!done) { bytesread = read(pipefd[0], btline, sizeof(btline) - 1); if (bytesread > 0) { btline[bytesread] = 0; ErrorF("%s", btline); } else if ((bytesread < 0) || ((errno != EINTR) && (errno != EAGAIN))) done = 1; } close(pipefd[0]); waitpid(kidpid, &kidstat, 0); if (kidstat != 0) return -1; } return 0; } # endif /* HAVE_PSTACK */ # if defined(HAVE_PSTACK) || defined(HAVE_WALKCONTEXT) static __inline__ void xorg_backtrace(void) { ErrorF("\nBacktrace:\n"); # ifdef HAVE_PSTACK /* First try fork/exec of pstack - otherwise fall back to walkcontext pstack is preferred since it can print names of non-exported functions */ if (xorg_backtrace_pstack() < 0) # endif { # ifdef HAVE_WALKCONTEXT ucontext_t u; int depth = 1; if (getcontext(&u) == 0) walkcontext(&u, xorg_backtrace_frame, &depth); else # endif Error("Failed to get backtrace info"); } ErrorF("\n"); } # else /* Default fallback if we can't find any way to get a backtrace */ static __inline__ void xorg_backtrace(void) { return; } # endif #endif /* * xf86SigHandler -- * Catch unexpected signals and exit or continue cleanly. */ void xf86SigHandler(int signo) { if ((signo == SIGILL) && xf86SigIllHandler) { (*xf86SigIllHandler)(); /* Re-arm handler just in case we unexpectedly return here */ (void) signal(signo, xf86SigHandler); return; } if (xf86SignalIntercept && (*xf86SignalIntercept < 0)) { *xf86SignalIntercept = signo; /* Re-arm handler just in case */ (void) signal(signo, xf86SigHandler); return; } signal(signo,SIG_IGN); xf86Info.caughtSignal = TRUE; #ifdef XF86BIGFONT XF86BigfontCleanup(); #endif xorg_backtrace(); FatalError("Caught signal %d. Server aborting\n", signo); } #ifdef MEMDEBUG void xf86SigMemDebug(int signo) { CheckMemory(); (void) signal(signo, xf86SigMemDebug); return; } #endif static void xf86ReleaseKeys(DeviceIntPtr pDev) { KeyClassPtr keyc = NULL; KeySym *map = NULL; xEvent ke; int i = 0, j = 0, nevents = 0; if (!pDev || !pDev->key) return; keyc = pDev->key; map = keyc->curKeySyms.map; /* * Hmm... here is the biggest hack of every time ! * It may be possible that a switch-vt procedure has finished BEFORE * you released all keys neccessary to do this. That peculiar behavior * can fool the X-server pretty much, cause it assumes that some keys * were not released. TWM may stuck alsmost completly.... * OK, what we are doing here is after returning from the vt-switch * exeplicitely unrelease all keyboard keys before the input-devices * are reenabled. */ for (i = keyc->curKeySyms.minKeyCode, map = keyc->curKeySyms.map; i < keyc->curKeySyms.maxKeyCode; i++, map += keyc->curKeySyms.mapWidth) { if (KeyPressed(i)) { switch (*map) { /* Don't release the lock keys */ case XK_Caps_Lock: case XK_Shift_Lock: case XK_Num_Lock: case XK_Scroll_Lock: case XK_Kana_Lock: break; default: if (pDev == inputInfo.keyboard) { ke.u.keyButtonPointer.time = GetTimeInMillis(); ke.u.keyButtonPointer.rootX = 0; ke.u.keyButtonPointer.rootY = 0; ke.u.u.type = KeyRelease; ke.u.u.detail = i; (*pDev->public.processInputProc) (&ke, pDev, 1); } else { nevents = GetKeyboardEvents(xf86Events, pDev, KeyRelease, i); for (j = 0; j < nevents; j++) EqEnqueue(pDev, xf86Events + i); } break; } } } } /* * xf86VTSwitch -- * Handle requests for switching the vt. */ static void xf86VTSwitch() { int i, prevSIGIO; InputInfoPtr pInfo; IHPtr ih; #ifdef DEBUG ErrorF("xf86VTSwitch()\n"); #endif #ifdef XFreeXDGA if(!DGAVTSwitch()) return; #endif /* * Since all screens are currently all in the same state it is sufficient * check the first. This might change in future. */ if (xf86Screens[0]->vtSema) { #ifdef DEBUG ErrorF("xf86VTSwitch: Leaving, xf86Exiting is %s\n", BOOLTOSTRING((dispatchException & DE_TERMINATE) ? TRUE : FALSE)); #endif #ifdef DPMSExtension if (DPMSPowerLevel != DPMSModeOn) DPMSSet(DPMSModeOn); #endif for (i = 0; i < xf86NumScreens; i++) { if (!(dispatchException & DE_TERMINATE)) if (xf86Screens[i]->EnableDisableFBAccess) (*xf86Screens[i]->EnableDisableFBAccess) (i, FALSE); } #if !defined(__UNIXOS2__) /* * Keep the order: Disable Device > LeaveVT * EnterVT > EnableDevice */ pInfo = xf86InputDevs; while (pInfo) { if (pInfo->dev) DisableDevice(pInfo->dev); pInfo = pInfo->next; } #endif /* !__UNIXOS2__ */ xf86EnterServerState(SETUP); for (i = 0; i < xf86NumScreens; i++) xf86Screens[i]->LeaveVT(i, 0); for (ih = InputHandlers; ih; ih = ih->next) xf86DisableInputHandler(ih); xf86AccessLeave(); /* We need this here, otherwise */ xf86AccessLeaveState(); /* console won't be restored */ if (!xf86VTSwitchAway()) { /* * switch failed */ #ifdef DEBUG ErrorF("xf86VTSwitch: Leave failed\n"); #endif prevSIGIO = xf86BlockSIGIO(); xf86AccessEnter(); xf86EnterServerState(SETUP); for (i = 0; i < xf86NumScreens; i++) { if (!xf86Screens[i]->EnterVT(i, 0)) FatalError("EnterVT failed for screen %d\n", i); } xf86EnterServerState(OPERATING); if (!(dispatchException & DE_TERMINATE)) { for (i = 0; i < xf86NumScreens; i++) { if (xf86Screens[i]->EnableDisableFBAccess) (*xf86Screens[i]->EnableDisableFBAccess) (i, TRUE); } } SaveScreens(SCREEN_SAVER_FORCER, ScreenSaverReset); #if !defined(__UNIXOS2__) pInfo = xf86InputDevs; while (pInfo) { if (pInfo->dev) { xf86ReleaseKeys(pInfo->dev); EnableDevice(pInfo->dev); } pInfo = pInfo->next; } /* XXX HACK */ xf86ReleaseKeys(inputInfo.keyboard); #endif /* !__UNIXOS2__ */ for (ih = InputHandlers; ih; ih = ih->next) xf86EnableInputHandler(ih); xf86UnblockSIGIO(prevSIGIO); } else { #ifdef XF86PM if (xf86OSPMClose) xf86OSPMClose(); xf86OSPMClose = NULL; #endif for (i = 0; i < xf86NumScreens; i++) { /* * zero all access functions to * trap calls when switched away. */ xf86Screens[i]->vtSema = FALSE; xf86Screens[i]->access = NULL; xf86Screens[i]->busAccess = NULL; } if (xorgHWAccess) xf86DisableIO(); } } else { #ifdef DEBUG ErrorF("xf86VTSwitch: Entering\n"); #endif if (!xf86VTSwitchTo()) return; prevSIGIO = xf86BlockSIGIO(); #ifdef XF86PM xf86OSPMClose = xf86OSPMOpen(); #endif if (xorgHWAccess) xf86EnableIO(); xf86AccessEnter(); xf86EnterServerState(SETUP); for (i = 0; i < xf86NumScreens; i++) { xf86Screens[i]->vtSema = TRUE; if (!xf86Screens[i]->EnterVT(i, 0)) FatalError("EnterVT failed for screen %d\n", i); } xf86EnterServerState(OPERATING); for (i = 0; i < xf86NumScreens; i++) { if (xf86Screens[i]->EnableDisableFBAccess) (*xf86Screens[i]->EnableDisableFBAccess)(i, TRUE); } /* Turn screen saver off when switching back */ SaveScreens(SCREEN_SAVER_FORCER,ScreenSaverReset); #if !defined(__UNIXOS2__) pInfo = xf86InputDevs; while (pInfo) { if (pInfo->dev) { xf86ReleaseKeys(pInfo->dev); EnableDevice(pInfo->dev); } pInfo = pInfo->next; } /* XXX HACK */ xf86ReleaseKeys(inputInfo.keyboard); #endif /* !__UNIXOS2__ */ for (ih = InputHandlers; ih; ih = ih->next) xf86EnableInputHandler(ih); xf86UnblockSIGIO(prevSIGIO); } } /* Input handler registration */ static pointer addInputHandler(int fd, InputHandlerProc proc, pointer data) { IHPtr ih; if (fd < 0 || !proc) return NULL; ih = xcalloc(sizeof(*ih), 1); if (!ih) return NULL; ih->fd = fd; ih->ihproc = proc; ih->data = data; ih->enabled = TRUE; ih->next = InputHandlers; InputHandlers = ih; return ih; } _X_EXPORT pointer xf86AddInputHandler(int fd, InputHandlerProc proc, pointer data) { IHPtr ih = addInputHandler(fd, proc, data); if (ih) AddEnabledDevice(fd); return ih; } _X_EXPORT pointer xf86AddGeneralHandler(int fd, InputHandlerProc proc, pointer data) { IHPtr ih = addInputHandler(fd, proc, data); if (ih) AddGeneralSocket(fd); return ih; } static void removeInputHandler(IHPtr ih) { IHPtr p; if (ih == InputHandlers) InputHandlers = ih->next; else { p = InputHandlers; while (p && p->next != ih) p = p->next; if (ih) p->next = ih->next; } xfree(ih); } _X_EXPORT int xf86RemoveInputHandler(pointer handler) { IHPtr ih; int fd; if (!handler) return -1; ih = handler; fd = ih->fd; if (ih->fd >= 0) RemoveEnabledDevice(ih->fd); removeInputHandler(ih); return fd; } _X_EXPORT int xf86RemoveGeneralHandler(pointer handler) { IHPtr ih; int fd; if (!handler) return -1; ih = handler; fd = ih->fd; if (ih->fd >= 0) RemoveGeneralSocket(ih->fd); removeInputHandler(ih); return fd; } _X_EXPORT void xf86DisableInputHandler(pointer handler) { IHPtr ih; if (!handler) return; ih = handler; ih->enabled = FALSE; if (ih->fd >= 0) RemoveEnabledDevice(ih->fd); } _X_EXPORT void xf86DisableGeneralHandler(pointer handler) { IHPtr ih; if (!handler) return; ih = handler; ih->enabled = FALSE; if (ih->fd >= 0) RemoveGeneralSocket(ih->fd); } _X_EXPORT void xf86EnableInputHandler(pointer handler) { IHPtr ih; if (!handler) return; ih = handler; ih->enabled = TRUE; if (ih->fd >= 0) AddEnabledDevice(ih->fd); } _X_EXPORT void xf86EnableGeneralHandler(pointer handler) { IHPtr ih; if (!handler) return; ih = handler; ih->enabled = TRUE; if (ih->fd >= 0) AddGeneralSocket(ih->fd); } /* * As used currently by the DRI, the return value is ignored. */ _X_EXPORT Bool xf86EnableVTSwitch(Bool new) { static Bool def = TRUE; Bool old; old = VTSwitchEnabled; if (!new) { /* Disable VT switching */ def = VTSwitchEnabled; VTSwitchEnabled = FALSE; } else { /* Restore VT switching to default */ VTSwitchEnabled = def; } return old; } void xf86ReloadInputDevs(int sig) { InputInfoPtr pInfo; signal(sig, (void(*)(int))xf86ReloadInputDevs); pInfo = xf86InputDevs; while (pInfo) { DisableDevice(pInfo->dev); EnableDevice(pInfo->dev); pInfo = pInfo->next; } return; } _X_EXPORT void DDXRingBell(int volume, int pitch, int duration) { xf86OSRingBell(volume, pitch, duration); } #ifdef WSCONS_SUPPORT /* XXX Currently XKB is mandatory. */ extern int WSKbdToKeycode(int); void xf86PostWSKbdEvent(struct wscons_event *event) { int type = event->type; int value = event->value; unsigned int keycode; int blocked; if (type == WSCONS_EVENT_KEY_UP || type == WSCONS_EVENT_KEY_DOWN) { Bool down = (type == WSCONS_EVENT_KEY_DOWN ? TRUE : FALSE); /* map the scancodes to standard XFree86 scancode */ keycode = WSKbdToKeycode(value); if (!down) keycode |= 0x80; /* It seems better to block SIGIO there */ blocked = xf86BlockSIGIO(); xf86PostKbdEvent(keycode); xf86UnblockSIGIO(blocked); } } #endif /* WSCONS_SUPPORT */