/* * Copyright 1990, 1998 The Open Group 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. 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 OPEN GROUP 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 Open Group 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 Open Group. * * Author: Keith Packard, MIT X Consortium */ /* * mieq.c * * Machine independent event queue * */ #if HAVE_DIX_CONFIG_H #include <dix-config.h> #endif # include <X11/X.h> # include <X11/Xmd.h> # include <X11/Xproto.h> # include "misc.h" # include "windowstr.h" # include "pixmapstr.h" # include "inputstr.h" # include "inpututils.h" # include "mi.h" # include "mipointer.h" # include "scrnintstr.h" # include <X11/extensions/XI.h> # include <X11/extensions/XIproto.h> # include <X11/extensions/geproto.h> # include "extinit.h" # include "exglobals.h" # include "eventstr.h" #ifdef DPMSExtension # include "dpmsproc.h" # include <X11/extensions/dpmsconst.h> #endif /* Maximum size should be initial size multiplied by a power of 2 */ #define QUEUE_INITIAL_SIZE 256 #define QUEUE_RESERVED_SIZE 64 #define QUEUE_MAXIMUM_SIZE 4096 #define QUEUE_DROP_BACKTRACE_FREQUENCY 100 #define QUEUE_DROP_BACKTRACE_MAX 10 #define EnqueueScreen(dev) dev->spriteInfo->sprite->pEnqueueScreen #define DequeueScreen(dev) dev->spriteInfo->sprite->pDequeueScreen typedef struct _Event { InternalEvent* events; ScreenPtr pScreen; DeviceIntPtr pDev; /* device this event _originated_ from */ } EventRec, *EventPtr; typedef struct _EventQueue { HWEventQueueType head, tail; /* long for SetInputCheck */ CARD32 lastEventTime; /* to avoid time running backwards */ int lastMotion; /* device ID if last event motion? */ EventRec *events; /* our queue as an array */ size_t nevents; /* the number of buckets in our queue */ size_t dropped; /* counter for number of consecutive dropped events */ mieqHandler handlers[128]; /* custom event handler */ } EventQueueRec, *EventQueuePtr; static EventQueueRec miEventQueue; #ifdef XQUARTZ #include <pthread.h> static pthread_mutex_t miEventQueueMutex = PTHREAD_MUTEX_INITIALIZER; extern BOOL serverRunning; extern pthread_mutex_t serverRunningMutex; extern pthread_cond_t serverRunningCond; static inline void wait_for_server_init(void) { /* If the server hasn't finished initializing, wait for it... */ if(!serverRunning) { pthread_mutex_lock(&serverRunningMutex); while(!serverRunning) pthread_cond_wait(&serverRunningCond, &serverRunningMutex); pthread_mutex_unlock(&serverRunningMutex); } } #endif static size_t mieqNumEnqueued(EventQueuePtr eventQueue) { size_t n_enqueued = 0; if (eventQueue->nevents) { /* % is not well-defined with negative numbers... sigh */ n_enqueued = eventQueue->tail - eventQueue->head + eventQueue->nevents; if (n_enqueued >= eventQueue->nevents) n_enqueued -= eventQueue->nevents; } return n_enqueued; } /* Pre-condition: Called with miEventQueueMutex held */ static Bool mieqGrowQueue(EventQueuePtr eventQueue, size_t new_nevents) { size_t i, n_enqueued, first_hunk; EventRec *new_events; if (!eventQueue) { ErrorF("[mi] mieqGrowQueue called with a NULL eventQueue\n"); return FALSE; } if (new_nevents <= eventQueue->nevents) return FALSE; new_events = calloc(new_nevents, sizeof(EventRec)); if (new_events == NULL) { ErrorF("[mi] mieqGrowQueue memory allocation error.\n"); return FALSE; } n_enqueued = mieqNumEnqueued(eventQueue); /* We block signals, so an mieqEnqueue triggered by SIGIO does not * write to our queue as we are modifying it. */ OsBlockSignals(); /* First copy the existing events */ first_hunk = eventQueue->nevents - eventQueue->head; memcpy(new_events, &eventQueue->events[eventQueue->head], first_hunk * sizeof(EventRec)); memcpy(&new_events[first_hunk], eventQueue->events, eventQueue->head * sizeof(EventRec)); /* Initialize the new portion */ for (i = eventQueue->nevents; i < new_nevents; i++) { InternalEvent* evlist = InitEventList(1); if (!evlist) { size_t j; for (j = 0; j < i; j++) FreeEventList(new_events[j].events, 1); free(new_events); OsReleaseSignals(); return FALSE; } new_events[i].events = evlist; } /* And update our record */ eventQueue->tail = n_enqueued; eventQueue->head = 0; eventQueue->nevents = new_nevents; free(eventQueue->events); eventQueue->events = new_events; OsReleaseSignals(); return TRUE; } Bool mieqInit(void) { memset(&miEventQueue, 0, sizeof(miEventQueue)); miEventQueue.lastEventTime = GetTimeInMillis (); if(!mieqGrowQueue(&miEventQueue, QUEUE_INITIAL_SIZE)) FatalError("Could not allocate event queue.\n"); SetInputCheck(&miEventQueue.head, &miEventQueue.tail); return TRUE; } void mieqFini(void) { int i; for (i = 0; i < miEventQueue.nevents; i++) { if (miEventQueue.events[i].events != NULL) { FreeEventList(miEventQueue.events[i].events, 1); miEventQueue.events[i].events = NULL; } } free(miEventQueue.events); } /* This function will determine if the given event is allowed to used the reserved * queue space. */ static Bool mieqReservedCandidate(InternalEvent *e) { switch(e->any.type) { case ET_KeyRelease: case ET_ButtonRelease: #if XFreeXDGA case ET_DGAEvent: #endif case ET_RawKeyRelease: case ET_RawButtonRelease: case ET_XQuartz: return TRUE; default: return FALSE; } } /* * Must be reentrant with ProcessInputEvents. Assumption: mieqEnqueue * will never be interrupted. If this is called from both signal * handlers and regular code, make sure the signal is suspended when * called from regular code. */ void mieqEnqueue(DeviceIntPtr pDev, InternalEvent *e) { unsigned int oldtail = miEventQueue.tail; InternalEvent* evt; int isMotion = 0; int evlen; Time time; size_t n_enqueued; #ifdef XQUARTZ wait_for_server_init(); pthread_mutex_lock(&miEventQueueMutex); #endif verify_internal_event(e); n_enqueued = mieqNumEnqueued(&miEventQueue); /* avoid merging events from different devices */ if (e->any.type == ET_Motion) isMotion = pDev->id; if (isMotion && isMotion == miEventQueue.lastMotion && oldtail != miEventQueue.head) { oldtail = (oldtail - 1) % miEventQueue.nevents; } else if ((n_enqueued + 1 == miEventQueue.nevents) || ((n_enqueued + 1 >= miEventQueue.nevents - QUEUE_RESERVED_SIZE) && !mieqReservedCandidate(e))) { /* Toss events which come in late. Usually this means your server's * stuck in an infinite loop somewhere, but SIGIO is still getting * handled. */ miEventQueue.dropped++; if (miEventQueue.dropped == 1) { ErrorF("[mi] EQ overflowing. Additional events will be discarded until existing events are processed.\n"); xorg_backtrace(); ErrorF("[mi] These backtraces from mieqEnqueue may point to a culprit higher up the stack.\n"); ErrorF("[mi] mieq is *NOT* the cause. It is a victim.\n"); } else if (miEventQueue.dropped % QUEUE_DROP_BACKTRACE_FREQUENCY == 0 && miEventQueue.dropped / QUEUE_DROP_BACKTRACE_FREQUENCY <= QUEUE_DROP_BACKTRACE_MAX) { ErrorF("[mi] EQ overflow continuing. %lu events have been dropped.\n", miEventQueue.dropped); if (miEventQueue.dropped / QUEUE_DROP_BACKTRACE_FREQUENCY == QUEUE_DROP_BACKTRACE_MAX) { ErrorF("[mi] No further overflow reports will be reported until the clog is cleared.\n"); } xorg_backtrace(); } #ifdef XQUARTZ pthread_mutex_unlock(&miEventQueueMutex); #endif return; } evlen = e->any.length; evt = miEventQueue.events[oldtail].events; memcpy(evt, e, evlen); time = e->any.time; /* Make sure that event times don't go backwards - this * is "unnecessary", but very useful. */ if (time < miEventQueue.lastEventTime && miEventQueue.lastEventTime - time < 10000) e->any.time = miEventQueue.lastEventTime; miEventQueue.lastEventTime = evt->any.time; miEventQueue.events[oldtail].pScreen = pDev ? EnqueueScreen(pDev) : NULL; miEventQueue.events[oldtail].pDev = pDev; miEventQueue.lastMotion = isMotion; miEventQueue.tail = (oldtail + 1) % miEventQueue.nevents; #ifdef XQUARTZ pthread_mutex_unlock(&miEventQueueMutex); #endif } /** * Changes the screen reference events are being enqueued from. * Input events are enqueued with a screen reference and dequeued and * processed with a (potentially different) screen reference. * This function is called whenever a new event has changed screen but is * still logically on the previous screen as seen by the client. * This usually happens whenever the visible cursor moves across screen * boundaries during event generation, before the same event is processed * and sent down the wire. * * @param pDev The device that triggered a screen change. * @param pScreen The new screen events are being enqueued for. * @param set_dequeue_screen If TRUE, pScreen is set as both enqueue screen * and dequeue screen. */ void mieqSwitchScreen(DeviceIntPtr pDev, ScreenPtr pScreen, Bool set_dequeue_screen) { #ifdef XQUARTZ pthread_mutex_lock(&miEventQueueMutex); #endif EnqueueScreen(pDev) = pScreen; if (set_dequeue_screen) DequeueScreen(pDev) = pScreen; #ifdef XQUARTZ pthread_mutex_unlock(&miEventQueueMutex); #endif } void mieqSetHandler(int event, mieqHandler handler) { #ifdef XQUARTZ pthread_mutex_lock(&miEventQueueMutex); #endif if (handler && miEventQueue.handlers[event]) ErrorF("[mi] mieq: warning: overriding existing handler %p with %p for " "event %d\n", miEventQueue.handlers[event], handler, event); miEventQueue.handlers[event] = handler; #ifdef XQUARTZ pthread_mutex_unlock(&miEventQueueMutex); #endif } /** * Change the device id of the given event to the given device's id. */ static void ChangeDeviceID(DeviceIntPtr dev, InternalEvent* event) { switch(event->any.type) { case ET_Motion: case ET_KeyPress: case ET_KeyRelease: case ET_ButtonPress: case ET_ButtonRelease: case ET_ProximityIn: case ET_ProximityOut: case ET_Hierarchy: case ET_DeviceChanged: case ET_TouchBegin: case ET_TouchUpdate: case ET_TouchEnd: event->device_event.deviceid = dev->id; break; case ET_TouchOwnership: event->touch_ownership_event.deviceid = dev->id; break; #if XFreeXDGA case ET_DGAEvent: break; #endif case ET_RawKeyPress: case ET_RawKeyRelease: case ET_RawButtonPress: case ET_RawButtonRelease: case ET_RawMotion: case ET_RawTouchBegin: case ET_RawTouchEnd: case ET_RawTouchUpdate: event->raw_event.deviceid = dev->id; break; default: ErrorF("[mi] Unknown event type (%d), cannot change id.\n", event->any.type); } } static void FixUpEventForMaster(DeviceIntPtr mdev, DeviceIntPtr sdev, InternalEvent* original, InternalEvent *master) { verify_internal_event(original); verify_internal_event(master); /* Ensure chained button mappings, i.e. that the detail field is the * value of the mapped button on the SD, not the physical button */ if (original->any.type == ET_ButtonPress || original->any.type == ET_ButtonRelease) { int btn = original->device_event.detail.button; if (!sdev->button) return; /* Should never happen */ master->device_event.detail.button = sdev->button->map[btn]; } } /** * Copy the given event into master. * @param sdev The slave device the original event comes from * @param original The event as it came from the EQ * @param copy The event after being copied * @return The master device or NULL if the device is a floating slave. */ DeviceIntPtr CopyGetMasterEvent(DeviceIntPtr sdev, InternalEvent* original, InternalEvent *copy) { DeviceIntPtr mdev; int len = original->any.length; int type = original->any.type; int mtype; /* which master type? */ verify_internal_event(original); /* ET_XQuartz has sdev == NULL */ if (!sdev || IsMaster(sdev) || IsFloating(sdev)) return NULL; #if XFreeXDGA if (type == ET_DGAEvent) type = original->dga_event.subtype; #endif switch(type) { case ET_KeyPress: case ET_KeyRelease: mtype = MASTER_KEYBOARD; break; case ET_ButtonPress: case ET_ButtonRelease: case ET_Motion: case ET_ProximityIn: case ET_ProximityOut: mtype = MASTER_POINTER; break; default: mtype = MASTER_ATTACHED; break; } mdev = GetMaster(sdev, mtype); memcpy(copy, original, len); ChangeDeviceID(mdev, copy); FixUpEventForMaster(mdev, sdev, original, copy); return mdev; } static void mieqMoveToNewScreen(DeviceIntPtr dev, ScreenPtr screen, DeviceEvent *event) { if (dev && screen && screen != DequeueScreen(dev)) { int x = 0, y = 0; DequeueScreen(dev) = screen; x = event->root_x; y = event->root_y; NewCurrentScreen (dev, DequeueScreen(dev), x, y); } } /** * Post the given @event through the device hierarchy, as appropriate. * Use this function if an event must be posted for a given device during the * usual event processing cycle. */ void mieqProcessDeviceEvent(DeviceIntPtr dev, InternalEvent *event, ScreenPtr screen) { mieqHandler handler; DeviceIntPtr master; InternalEvent mevent; /* master event */ verify_internal_event(event); /* Custom event handler */ handler = miEventQueue.handlers[event->any.type]; switch (event->any.type) { /* Catch events that include valuator information and check if they * are changing the screen */ case ET_Motion: case ET_KeyPress: case ET_KeyRelease: case ET_ButtonPress: case ET_ButtonRelease: if (!handler) mieqMoveToNewScreen(dev, screen, &event->device_event); break; case ET_TouchBegin: case ET_TouchUpdate: case ET_TouchEnd: if (!handler && (event->device_event.flags & TOUCH_POINTER_EMULATED)) mieqMoveToNewScreen(dev, screen, &event->device_event); break; default: break; } master = CopyGetMasterEvent(dev, event, &mevent); if (master) master->lastSlave = dev; /* If someone's registered a custom event handler, let them * steal it. */ if (handler) { int screenNum = dev && DequeueScreen(dev) ? DequeueScreen(dev)->myNum : (screen ? screen->myNum : 0); handler(screenNum, event, dev); /* Check for the SD's master in case the device got detached * during event processing */ if (master && !IsFloating(dev)) handler(screenNum, &mevent, master); } else { /* process slave first, then master */ dev->public.processInputProc(event, dev); /* Check for the SD's master in case the device got detached * during event processing */ if (master && !IsFloating(dev)) master->public.processInputProc(&mevent, master); } } /* Call this from ProcessInputEvents(). */ void mieqProcessInputEvents(void) { EventRec *e = NULL; ScreenPtr screen; static InternalEvent event; DeviceIntPtr dev = NULL, master = NULL; size_t n_enqueued; #ifdef XQUARTZ pthread_mutex_lock(&miEventQueueMutex); #endif /* Grow our queue if we are reaching capacity: < 2 * QUEUE_RESERVED_SIZE remaining */ n_enqueued = mieqNumEnqueued(&miEventQueue); if (n_enqueued >= (miEventQueue.nevents - (2 * QUEUE_RESERVED_SIZE)) && miEventQueue.nevents < QUEUE_MAXIMUM_SIZE) { ErrorF("[mi] Increasing EQ size to %lu to prevent dropped events.\n", miEventQueue.nevents << 1); if (!mieqGrowQueue(&miEventQueue, miEventQueue.nevents << 1)) { ErrorF("[mi] Increasing the size of EQ failed.\n"); } } if (miEventQueue.dropped) { ErrorF("[mi] EQ processing has resumed after %lu dropped events.\n", miEventQueue.dropped); ErrorF("[mi] This may be caused my a misbehaving driver monopolizing the server's resources.\n"); miEventQueue.dropped = 0; } while (miEventQueue.head != miEventQueue.tail) { e = &miEventQueue.events[miEventQueue.head]; event = *e->events; dev = e->pDev; screen = e->pScreen; miEventQueue.head = (miEventQueue.head + 1) % miEventQueue.nevents; #ifdef XQUARTZ pthread_mutex_unlock(&miEventQueueMutex); #endif master = (dev) ? GetMaster(dev, MASTER_ATTACHED) : NULL; if (screenIsSaved == SCREEN_SAVER_ON) dixSaveScreens (serverClient, SCREEN_SAVER_OFF, ScreenSaverReset); #ifdef DPMSExtension else if (DPMSPowerLevel != DPMSModeOn) SetScreenSaverTimer(); if (DPMSPowerLevel != DPMSModeOn) DPMSSet(serverClient, DPMSModeOn); #endif mieqProcessDeviceEvent(dev, &event, screen); /* Update the sprite now. Next event may be from different device. */ if (event.any.type == ET_Motion && master) miPointerUpdateSprite(dev); #ifdef XQUARTZ pthread_mutex_lock(&miEventQueueMutex); #endif } #ifdef XQUARTZ pthread_mutex_unlock(&miEventQueueMutex); #endif }