/************************************************************ Copyright 1989, 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. Copyright 1989 by Hewlett-Packard Company, Palo Alto, California. All Rights Reserved Permission to use, copy, modify, and distribute this software and its documentation for any purpose and without fee is hereby granted, 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 Hewlett-Packard not be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission. HEWLETT-PACKARD DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL HEWLETT-PACKARD 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. ********************************************************/ /*********************************************************************** * * Input Extension library internal functions. * */ #if HAVE_CONFIG_H #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include "XIint.h" #define ENQUEUE_EVENT True #define DONT_ENQUEUE False #define FP1616toDBL(x) ((x) * 1.0 / (1 << 16)) int copy_classes(XIDeviceInfo *to, xXIAnyInfo* from, int *nclasses); int size_classes(xXIAnyInfo* from, int nclasses); static XExtensionInfo *xinput_info; static const char *xinput_extension_name = INAME; static int XInputClose( Display * /* dpy */, XExtCodes * /* codes */ ); static char *XInputError( Display * /* dpy */, int /* code */, XExtCodes * /* codes */, char * /* buf */, int /* n */ ); static Bool XInputWireToEvent( Display * /* dpy */, XEvent * /* re */, xEvent * /* event */ ); static Bool XInputWireToCookie( Display* /* display */, XGenericEventCookie* /* re */, xEvent* /* event */ ); static Bool XInputCopyCookie( Display* /* display */, XGenericEventCookie* /* in */, XGenericEventCookie* /* out */ ); static int wireToDeviceEvent(xXIDeviceEvent *in, XGenericEventCookie* out); static int wireToDeviceChangedEvent(xXIDeviceChangedEvent *in, XGenericEventCookie *cookie); static int wireToHierarchyChangedEvent(xXIHierarchyEvent *in, XGenericEventCookie *cookie); static int wireToRawEvent(XExtDisplayInfo *info, xXIRawEvent *in, XGenericEventCookie *cookie); static int wireToEnterLeave(xXIEnterEvent *in, XGenericEventCookie *cookie); static int wireToPropertyEvent(xXIPropertyEvent *in, XGenericEventCookie *cookie); static int wireToTouchOwnershipEvent(xXITouchOwnershipEvent *in, XGenericEventCookie *cookie); static int wireToBarrierEvent(xXIBarrierEvent *in, XGenericEventCookie *cookie); static /* const */ XEvent emptyevent; typedef Status (*core_event_to_wire)(Display*, XEvent*, xEvent*); static /* const */ XExtensionHooks xinput_extension_hooks = { NULL, /* create_gc */ NULL, /* copy_gc */ NULL, /* flush_gc */ NULL, /* free_gc */ NULL, /* create_font */ NULL, /* free_font */ XInputClose, /* close_display */ XInputWireToEvent, /* wire_to_event */ (core_event_to_wire)_XiEventToWire, /* event_to_wire */ NULL, /* error */ XInputError, /* error_string */ }; static const char *XInputErrorList[] = { "BadDevice, invalid or uninitialized input device", /* BadDevice */ "BadEvent, invalid event type", /* BadEvent */ "BadMode, invalid mode parameter", /* BadMode */ "DeviceBusy, device is busy", /* DeviceBusy */ "BadClass, invalid event class", /* BadClass */ }; /* Get the version supported by the server to know which number of * events are support. Otherwise, a wrong number of events may smash * the Xlib-internal event processing vector. * * Since the extension hasn't been initialized yet, we need to * manually get the opcode, then the version. */ static int _XiFindEventsSupported(Display *dpy) { XExtCodes codes; XExtensionVersion *extversion = NULL; int nevents = 0; if (!XQueryExtension(dpy, INAME, &codes.major_opcode, &codes.first_event, &codes.first_error)) goto out; LockDisplay(dpy); extversion = _XiGetExtensionVersionRequest(dpy, INAME, codes.major_opcode); UnlockDisplay(dpy); SyncHandle(); if (!extversion || !extversion->present) goto out; if (extversion->major_version >= 2) nevents = IEVENTS; /* number is fixed, XI2 adds GenericEvents only */ else if (extversion->major_version <= 0) { printf("XInput_find_display: invalid extension version %d.%d\n", extversion->major_version, extversion->minor_version); goto out; } else { switch(extversion->minor_version) { case XI_Add_DeviceProperties_Minor: nevents = XI_DevicePropertyNotify + 1; break; case XI_Add_DevicePresenceNotify_Minor: nevents = XI_DevicePresenceNotify + 1; break; default: nevents = XI_DeviceButtonstateNotify + 1; break; } } out: if (extversion) XFree(extversion); return nevents; } _X_HIDDEN XExtDisplayInfo *XInput_find_display (Display *dpy) { XExtDisplayInfo *dpyinfo; if (!xinput_info) { if (!(xinput_info = XextCreateExtension())) return NULL; } if (!(dpyinfo = XextFindDisplay (xinput_info, dpy))) { int nevents = _XiFindEventsSupported(dpy); dpyinfo = XextAddDisplay (xinput_info, dpy, xinput_extension_name, &xinput_extension_hooks, nevents, NULL); if (dpyinfo->codes) /* NULL if XI doesn't exist on the server */ { XESetWireToEventCookie(dpy, dpyinfo->codes->major_opcode, XInputWireToCookie); XESetCopyEventCookie(dpy, dpyinfo->codes->major_opcode, XInputCopyCookie); } } return dpyinfo; } static XEXT_GENERATE_ERROR_STRING(XInputError, xinput_extension_name, IERRORS, XInputErrorList) /******************************************************************* * * Input extension versions. * */ static XExtensionVersion versions[] = { {XI_Absent, 0, 0}, {XI_Present, XI_Initial_Release_Major, XI_Initial_Release_Minor}, {XI_Present, XI_Add_XDeviceBell_Major, XI_Add_XDeviceBell_Minor}, {XI_Present, XI_Add_XSetDeviceValuators_Major, XI_Add_XSetDeviceValuators_Minor}, {XI_Present, XI_Add_XChangeDeviceControl_Major, XI_Add_XChangeDeviceControl_Minor}, {XI_Present, XI_Add_DevicePresenceNotify_Major, XI_Add_DevicePresenceNotify_Minor}, {XI_Present, XI_Add_DeviceProperties_Major, XI_Add_DeviceProperties_Minor}, {XI_Present, 2, 0}, {XI_Present, 2, 1}, {XI_Present, 2, 2} }; /*********************************************************************** * * Return errors reported by this extension. * */ void _xibaddevice( Display *dpy, int *error) { XExtDisplayInfo *info = XInput_find_display(dpy); *error = info->codes->first_error + XI_BadDevice; } void _xibadclass( Display *dpy, int *error) { XExtDisplayInfo *info = XInput_find_display(dpy); *error = info->codes->first_error + XI_BadClass; } void _xibadevent( Display *dpy, int *error) { XExtDisplayInfo *info = XInput_find_display(dpy); *error = info->codes->first_error + XI_BadEvent; } void _xibadmode( Display *dpy, int *error) { XExtDisplayInfo *info = XInput_find_display(dpy); *error = info->codes->first_error + XI_BadMode; } void _xidevicebusy( Display *dpy, int *error) { XExtDisplayInfo *info = XInput_find_display(dpy); *error = info->codes->first_error + XI_DeviceBusy; } static int XInputCheckExtension(Display *dpy, XExtDisplayInfo *info) { XextCheckExtension (dpy, info, xinput_extension_name, 0); return 1; } /***************************************************************** * Compare version numbers between info and the built-in version table. * Returns * -1 if info's version is less than version_index's version, * 0 if equal (or DontCheck), * 1 if info's version is greater than version_index's version. * Returns -2 on initialization errors which shouldn't happen if you call it * correctly. */ _X_HIDDEN int _XiCheckVersion(XExtDisplayInfo *info, int version_index) { XExtensionVersion *ext; if (versions[version_index].major_version == Dont_Check) return 0; if (!info->data) return -2; ext = ((XInputData *) info->data)->vers; if (!ext) return -2; if (ext->major_version == versions[version_index].major_version && ext->minor_version == versions[version_index].minor_version) return 0; if (ext->major_version < versions[version_index].major_version || (ext->major_version == versions[version_index].major_version && ext->minor_version < versions[version_index].minor_version)) return -1; else return 1; } /*********************************************************************** * * Check to see if the input extension is installed in the server. * Also check to see if the version is >= the requested version. * */ _X_HIDDEN int _XiCheckExtInit( register Display *dpy, register int version_index, XExtDisplayInfo *info) { if (!XInputCheckExtension(dpy, info)) { UnlockDisplay(dpy); return (-1); } if (info->data == NULL) { info->data = (XPointer) Xmalloc(sizeof(XInputData)); if (!info->data) { UnlockDisplay(dpy); return (-1); } ((XInputData *) info->data)->vers = _XiGetExtensionVersionRequest(dpy, "XInputExtension", info->codes->major_opcode); } if (_XiCheckVersion(info, version_index) < 0) { UnlockDisplay(dpy); return -1; } return (0); } /*********************************************************************** * * Close display routine. * */ static int XInputClose( Display *dpy, XExtCodes *codes) { XExtDisplayInfo *info = XInput_find_display(dpy); if (info->data != NULL) { XFree((char *)((XInputData *) info->data)->vers); XFree((char *)info->data); } if (!XextRemoveDisplay(xinput_info, dpy)) return 0; if (xinput_info->ndisplays == 0) { XextDestroyExtension(xinput_info); xinput_info = NULL; } return 1; } static int Ones(Mask mask) { register Mask y; y = (mask >> 1) & 033333333333; y = mask - y - ((y >> 1) & 033333333333); return (((y + (y >> 3)) & 030707070707) % 077); } static int count_bits(unsigned char* ptr, int len) { int bits = 0; unsigned int i; unsigned char x; for (i = 0; i < len; i++) { x = ptr[i]; while(x > 0) { bits += (x & 0x1); x >>= 1; } } return bits; } int _XiGetDevicePresenceNotifyEvent(Display * dpy) { XExtDisplayInfo *info = XInput_find_display(dpy); return info->codes->first_event + XI_DevicePresenceNotify; } /*********************************************************************** * * Handle Input extension events. * Reformat a wire event into an XEvent structure of the right type. * */ static Bool XInputWireToEvent( Display *dpy, XEvent *re, xEvent *event) { unsigned int type, reltype; XExtDisplayInfo *info = XInput_find_display(dpy); XEvent *save = (XEvent *) info->data; type = event->u.u.type & 0x7f; reltype = (type - info->codes->first_event); if (type == GenericEvent || (reltype != XI_DeviceValuator && reltype != XI_DeviceKeystateNotify && reltype != XI_DeviceButtonstateNotify)) { *save = emptyevent; save->type = type; ((XAnyEvent *) save)->serial = _XSetLastRequestRead(dpy, (xGenericReply *) event); ((XAnyEvent *) save)->send_event = ((event->u.u.type & 0x80) != 0); ((XAnyEvent *) save)->display = dpy; } /* Process traditional events */ if (type != GenericEvent) { switch (reltype) { case XI_DeviceMotionNotify: { register XDeviceMotionEvent *ev = (XDeviceMotionEvent *) save; deviceKeyButtonPointer *ev2 = (deviceKeyButtonPointer *) event; ev->root = ev2->root; ev->window = ev2->event; ev->subwindow = ev2->child; ev->time = ev2->time; ev->x_root = ev2->root_x; ev->y_root = ev2->root_y; ev->x = ev2->event_x; ev->y = ev2->event_y; ev->state = ev2->state; ev->same_screen = ev2->same_screen; ev->is_hint = ev2->detail; ev->deviceid = ev2->deviceid & DEVICE_BITS; return (DONT_ENQUEUE); } break; case XI_DeviceKeyPress: case XI_DeviceKeyRelease: { register XDeviceKeyEvent *ev = (XDeviceKeyEvent *) save; deviceKeyButtonPointer *ev2 = (deviceKeyButtonPointer *) event; ev->root = ev2->root; ev->window = ev2->event; ev->subwindow = ev2->child; ev->time = ev2->time; ev->x_root = ev2->root_x; ev->y_root = ev2->root_y; ev->x = ev2->event_x; ev->y = ev2->event_y; ev->state = ev2->state; ev->same_screen = ev2->same_screen; ev->keycode = ev2->detail; ev->deviceid = ev2->deviceid & DEVICE_BITS; if (ev2->deviceid & MORE_EVENTS) return (DONT_ENQUEUE); else { *re = *save; return (ENQUEUE_EVENT); } } break; case XI_DeviceButtonPress: case XI_DeviceButtonRelease: { register XDeviceButtonEvent *ev = (XDeviceButtonEvent *) save; deviceKeyButtonPointer *ev2 = (deviceKeyButtonPointer *) event; ev->root = ev2->root; ev->window = ev2->event; ev->subwindow = ev2->child; ev->time = ev2->time; ev->x_root = ev2->root_x; ev->y_root = ev2->root_y; ev->x = ev2->event_x; ev->y = ev2->event_y; ev->state = ev2->state; ev->same_screen = ev2->same_screen; ev->button = ev2->detail; ev->deviceid = ev2->deviceid & DEVICE_BITS; if (ev2->deviceid & MORE_EVENTS) return (DONT_ENQUEUE); else { *re = *save; return (ENQUEUE_EVENT); } } break; case XI_ProximityIn: case XI_ProximityOut: { register XProximityNotifyEvent *ev = (XProximityNotifyEvent *) save; deviceKeyButtonPointer *ev2 = (deviceKeyButtonPointer *) event; ev->root = ev2->root; ev->window = ev2->event; ev->subwindow = ev2->child; ev->time = ev2->time; ev->x_root = ev2->root_x; ev->y_root = ev2->root_y; ev->x = ev2->event_x; ev->y = ev2->event_y; ev->state = ev2->state; ev->same_screen = ev2->same_screen; ev->deviceid = ev2->deviceid & DEVICE_BITS; if (ev2->deviceid & MORE_EVENTS) return (DONT_ENQUEUE); else { *re = *save; return (ENQUEUE_EVENT); } } break; case XI_DeviceValuator: { deviceValuator *xev = (deviceValuator *) event; int save_type = save->type - info->codes->first_event; int i; if (save_type == XI_DeviceKeyPress || save_type == XI_DeviceKeyRelease) { XDeviceKeyEvent *kev = (XDeviceKeyEvent *) save; kev->device_state = xev->device_state; kev->axes_count = xev->num_valuators; kev->first_axis = xev->first_valuator; i = xev->num_valuators; if (i > 6) i = 6; switch (i) { case 6: kev->axis_data[5] = xev->valuator5; case 5: kev->axis_data[4] = xev->valuator4; case 4: kev->axis_data[3] = xev->valuator3; case 3: kev->axis_data[2] = xev->valuator2; case 2: kev->axis_data[1] = xev->valuator1; case 1: kev->axis_data[0] = xev->valuator0; } } else if (save_type == XI_DeviceButtonPress || save_type == XI_DeviceButtonRelease) { XDeviceButtonEvent *bev = (XDeviceButtonEvent *) save; bev->device_state = xev->device_state; bev->axes_count = xev->num_valuators; bev->first_axis = xev->first_valuator; i = xev->num_valuators; if (i > 6) i = 6; switch (i) { case 6: bev->axis_data[5] = xev->valuator5; case 5: bev->axis_data[4] = xev->valuator4; case 4: bev->axis_data[3] = xev->valuator3; case 3: bev->axis_data[2] = xev->valuator2; case 2: bev->axis_data[1] = xev->valuator1; case 1: bev->axis_data[0] = xev->valuator0; } } else if (save_type == XI_DeviceMotionNotify) { XDeviceMotionEvent *mev = (XDeviceMotionEvent *) save; mev->device_state = xev->device_state; mev->axes_count = xev->num_valuators; mev->first_axis = xev->first_valuator; i = xev->num_valuators; if (i > 6) i = 6; switch (i) { case 6: mev->axis_data[5] = xev->valuator5; case 5: mev->axis_data[4] = xev->valuator4; case 4: mev->axis_data[3] = xev->valuator3; case 3: mev->axis_data[2] = xev->valuator2; case 2: mev->axis_data[1] = xev->valuator1; case 1: mev->axis_data[0] = xev->valuator0; } } else if (save_type == XI_ProximityIn || save_type == XI_ProximityOut) { XProximityNotifyEvent *pev = (XProximityNotifyEvent *) save; pev->device_state = xev->device_state; pev->axes_count = xev->num_valuators; pev->first_axis = xev->first_valuator; i = xev->num_valuators; if (i > 6) i = 6; switch (i) { case 6: pev->axis_data[5] = xev->valuator5; case 5: pev->axis_data[4] = xev->valuator4; case 4: pev->axis_data[3] = xev->valuator3; case 3: pev->axis_data[2] = xev->valuator2; case 2: pev->axis_data[1] = xev->valuator1; case 1: pev->axis_data[0] = xev->valuator0; } } else if (save_type == XI_DeviceStateNotify) { int j; XDeviceStateNotifyEvent *sev = (XDeviceStateNotifyEvent *) save; XInputClass *any = (XInputClass *) & sev->data[0]; XValuatorStatus *v; for (i = 0; i < sev->num_classes; i++) if (any->class != ValuatorClass) any = (XInputClass *) ((char *)any + any->length); v = (XValuatorStatus *) any; i = v->num_valuators; j = xev->num_valuators; if (j > 3) j = 3; switch (j) { case 3: v->valuators[i + 2] = xev->valuator2; case 2: v->valuators[i + 1] = xev->valuator1; case 1: v->valuators[i + 0] = xev->valuator0; } v->num_valuators += j; } *re = *save; return (ENQUEUE_EVENT); } break; case XI_DeviceFocusIn: case XI_DeviceFocusOut: { register XDeviceFocusChangeEvent *ev = (XDeviceFocusChangeEvent *) re; deviceFocus *fev = (deviceFocus *) event; *ev = *((XDeviceFocusChangeEvent *) save); ev->window = fev->window; ev->time = fev->time; ev->mode = fev->mode; ev->detail = fev->detail; ev->deviceid = fev->deviceid & DEVICE_BITS; return (ENQUEUE_EVENT); } break; case XI_DeviceStateNotify: { int j; XDeviceStateNotifyEvent *stev = (XDeviceStateNotifyEvent *) save; deviceStateNotify *sev = (deviceStateNotify *) event; char *data; stev->window = None; stev->deviceid = sev->deviceid & DEVICE_BITS; stev->time = sev->time; stev->num_classes = Ones((Mask) sev->classes_reported & InputClassBits); data = (char *)&stev->data[0]; if (sev->classes_reported & (1 << KeyClass)) { register XKeyStatus *kstev = (XKeyStatus *) data; kstev->class = KeyClass; kstev->length = sizeof(XKeyStatus); kstev->num_keys = sev->num_keys; memcpy((char *)&kstev->keys[0], (char *)&sev->keys[0], 4); data += sizeof(XKeyStatus); } if (sev->classes_reported & (1 << ButtonClass)) { register XButtonStatus *bev = (XButtonStatus *) data; bev->class = ButtonClass; bev->length = sizeof(XButtonStatus); bev->num_buttons = sev->num_buttons; memcpy((char *)bev->buttons, (char *)sev->buttons, 4); data += sizeof(XButtonStatus); } if (sev->classes_reported & (1 << ValuatorClass)) { register XValuatorStatus *vev = (XValuatorStatus *) data; vev->class = ValuatorClass; vev->length = sizeof(XValuatorStatus); vev->num_valuators = sev->num_valuators; vev->mode = sev->classes_reported >> ModeBitsShift; j = sev->num_valuators; if (j > 3) j = 3; switch (j) { case 3: vev->valuators[2] = sev->valuator2; case 2: vev->valuators[1] = sev->valuator1; case 1: vev->valuators[0] = sev->valuator0; } data += sizeof(XValuatorStatus); } if (sev->deviceid & MORE_EVENTS) return (DONT_ENQUEUE); else { *re = *save; return (ENQUEUE_EVENT); } } break; case XI_DeviceKeystateNotify: { int i; XInputClass *anyclass; register XKeyStatus *kv; deviceKeyStateNotify *ksev = (deviceKeyStateNotify *) event; XDeviceStateNotifyEvent *kstev = (XDeviceStateNotifyEvent *) save; anyclass = (XInputClass *) & kstev->data[0]; for (i = 0; i < kstev->num_classes; i++) if (anyclass->class == KeyClass) break; else anyclass = (XInputClass *) ((char *)anyclass + anyclass->length); kv = (XKeyStatus *) anyclass; kv->num_keys = 256; memcpy((char *)&kv->keys[4], (char *)ksev->keys, 28); if (ksev->deviceid & MORE_EVENTS) return (DONT_ENQUEUE); else { *re = *save; return (ENQUEUE_EVENT); } } break; case XI_DeviceButtonstateNotify: { int i; XInputClass *anyclass; register XButtonStatus *bv; deviceButtonStateNotify *bsev = (deviceButtonStateNotify *) event; XDeviceStateNotifyEvent *bstev = (XDeviceStateNotifyEvent *) save; anyclass = (XInputClass *) & bstev->data[0]; for (i = 0; i < bstev->num_classes; i++) if (anyclass->class == ButtonClass) break; else anyclass = (XInputClass *) ((char *)anyclass + anyclass->length); bv = (XButtonStatus *) anyclass; bv->num_buttons = 256; memcpy((char *)&bv->buttons[4], (char *)bsev->buttons, 28); if (bsev->deviceid & MORE_EVENTS) return (DONT_ENQUEUE); else { *re = *save; return (ENQUEUE_EVENT); } } break; case XI_DeviceMappingNotify: { register XDeviceMappingEvent *ev = (XDeviceMappingEvent *) re; deviceMappingNotify *ev2 = (deviceMappingNotify *) event; *ev = *((XDeviceMappingEvent *) save); ev->window = 0; ev->first_keycode = ev2->firstKeyCode; ev->request = ev2->request; ev->count = ev2->count; ev->time = ev2->time; ev->deviceid = ev2->deviceid & DEVICE_BITS; return (ENQUEUE_EVENT); } break; case XI_ChangeDeviceNotify: { register XChangeDeviceNotifyEvent *ev = (XChangeDeviceNotifyEvent *) re; changeDeviceNotify *ev2 = (changeDeviceNotify *) event; *ev = *((XChangeDeviceNotifyEvent *) save); ev->window = 0; ev->request = ev2->request; ev->time = ev2->time; ev->deviceid = ev2->deviceid & DEVICE_BITS; return (ENQUEUE_EVENT); } break; case XI_DevicePresenceNotify: { XDevicePresenceNotifyEvent *ev = (XDevicePresenceNotifyEvent *) re; devicePresenceNotify *ev2 = (devicePresenceNotify *) event; *ev = *(XDevicePresenceNotifyEvent *) save; ev->window = 0; ev->time = ev2->time; ev->devchange = ev2->devchange; ev->deviceid = ev2->deviceid; ev->control = ev2->control; return (ENQUEUE_EVENT); } break; case XI_DevicePropertyNotify: { XDevicePropertyNotifyEvent* ev = (XDevicePropertyNotifyEvent*)re; devicePropertyNotify *ev2 = (devicePropertyNotify*)event; *ev = *(XDevicePropertyNotifyEvent*)save; ev->time = ev2->time; ev->deviceid = ev2->deviceid; ev->atom = ev2->atom; ev->state = ev2->state; return ENQUEUE_EVENT; } break; default: printf("XInputWireToEvent: UNKNOWN WIRE EVENT! type=%d\n", type); break; } } return (DONT_ENQUEUE); } static void xge_copy_to_cookie(xGenericEvent* ev, XGenericEventCookie *cookie) { cookie->type = ev->type; cookie->evtype = ev->evtype; cookie->extension = ev->extension; } static Bool XInputWireToCookie( Display *dpy, XGenericEventCookie *cookie, xEvent *event) { XExtDisplayInfo *info = XInput_find_display(dpy); XEvent *save = (XEvent *) info->data; xGenericEvent* ge = (xGenericEvent*)event; if (ge->extension != info->codes->major_opcode) { printf("XInputWireToCookie: wrong extension opcode %d\n", ge->extension); return DONT_ENQUEUE; } *save = emptyevent; save->type = event->u.u.type; ((XAnyEvent*)save)->serial = _XSetLastRequestRead(dpy, (xGenericReply *) event); ((XAnyEvent*)save)->send_event = ((event->u.u.type & 0x80) != 0); ((XAnyEvent*)save)->display = dpy; xge_copy_to_cookie((xGenericEvent*)event, (XGenericEventCookie*)save); switch(ge->evtype) { case XI_Motion: case XI_ButtonPress: case XI_ButtonRelease: case XI_KeyPress: case XI_KeyRelease: case XI_TouchBegin: case XI_TouchUpdate: case XI_TouchEnd: *cookie = *(XGenericEventCookie*)save; if (!wireToDeviceEvent((xXIDeviceEvent*)event, cookie)) { printf("XInputWireToCookie: CONVERSION FAILURE! evtype=%d\n", ge->evtype); break; } return ENQUEUE_EVENT; case XI_DeviceChanged: *cookie = *(XGenericEventCookie*)save; if (!wireToDeviceChangedEvent((xXIDeviceChangedEvent*)event, cookie)) { printf("XInputWireToCookie: CONVERSION FAILURE! evtype=%d\n", ge->evtype); break; } return ENQUEUE_EVENT; case XI_HierarchyChanged: *cookie = *(XGenericEventCookie*)save; if (!wireToHierarchyChangedEvent((xXIHierarchyEvent*)event, cookie)) { printf("XInputWireToCookie: CONVERSION FAILURE! evtype=%d\n", ge->evtype); break; } return ENQUEUE_EVENT; case XI_TouchOwnership: *cookie = *(XGenericEventCookie*)save; if (!wireToTouchOwnershipEvent((xXITouchOwnershipEvent*)event, cookie)) { printf("XInputWireToCookie: CONVERSION FAILURE! evtype=%d\n", ge->evtype); break; } return ENQUEUE_EVENT; case XI_RawKeyPress: case XI_RawKeyRelease: case XI_RawButtonPress: case XI_RawButtonRelease: case XI_RawMotion: case XI_RawTouchBegin: case XI_RawTouchUpdate: case XI_RawTouchEnd: *cookie = *(XGenericEventCookie*)save; if (!wireToRawEvent(info, (xXIRawEvent*)event, cookie)) { printf("XInputWireToCookie: CONVERSION FAILURE! evtype=%d\n", ge->evtype); break; } return ENQUEUE_EVENT; case XI_Enter: case XI_Leave: case XI_FocusIn: case XI_FocusOut: *cookie = *(XGenericEventCookie*)save; if (!wireToEnterLeave((xXIEnterEvent*)event, cookie)) { printf("XInputWireToCookie: CONVERSION FAILURE! evtype=%d\n", ge->evtype); break; } return ENQUEUE_EVENT; case XI_PropertyEvent: *cookie = *(XGenericEventCookie*)save; if (!wireToPropertyEvent((xXIPropertyEvent*)event, cookie)) { printf("XInputWireToCookie: CONVERSION FAILURE! evtype=%d\n", ge->evtype); break; } return ENQUEUE_EVENT; case XI_BarrierHit: case XI_BarrierLeave: *cookie = *(XGenericEventCookie*)save; if (!wireToBarrierEvent((xXIBarrierEvent*)event, cookie)) { printf("XInputWireToCookie: CONVERSION FAILURE! evtype=%d\n", ge->evtype); break; } return ENQUEUE_EVENT; default: printf("XInputWireToCookie: Unknown generic event. type %d\n", ge->evtype); } return DONT_ENQUEUE; } /** * Calculate length in bytes needed for the device event with the given * button mask length, valuator mask length + valuator mask. All parameters * in bytes. */ static inline int sizeDeviceEvent(int buttons_len, int valuators_len, unsigned char *valuators_mask) { int len; len = sizeof(XIDeviceEvent); len += sizeof(XIButtonState) + buttons_len; len += sizeof(XIValuatorState) + valuators_len; len += count_bits(valuators_mask, valuators_len) * sizeof(double); len += sizeof(XIModifierState) + sizeof(XIGroupState); return len; } /* Return the size with added padding so next element would be double-aligned unless the architecture is known to allow unaligned data accesses. Not doing this can cause a bus error on MIPS N32. */ static int pad_to_double(int size) { #if !defined(__i386__) && !defined(__sh__) if (size % sizeof(double) != 0) size += sizeof(double) - size % sizeof(double); #endif return size; } /** * Set structure and atoms to size in bytes of XIButtonClassInfo, its * button state mask and labels array. */ static void sizeXIButtonClassType(int num_buttons, int* structure, int* state, int* atoms) { int size; int labels; *structure = pad_to_double(sizeof(XIButtonClassInfo)); size = ((((num_buttons + 7)/8) + 3)/4); /* Force mask alignment with longs to avoid unaligned * access when accessing the atoms. */ *state = pad_to_double(size * 4); labels = num_buttons * sizeof(Atom); /* Force mask alignment with longs to avoid * unaligned access when accessing the atoms. */ labels += ((((num_buttons + 7)/8) + 3)/4) * sizeof(Atom); *atoms = pad_to_double(labels); } /** * Set structure and keycodes to size in bytes of XIKeyClassInfo and * its keycodes array. */ static void sizeXIKeyClassType(int num_keycodes, int* structure, int* keycodes) { *structure = pad_to_double(sizeof(XIKeyClassInfo)); *keycodes = pad_to_double(num_keycodes * sizeof(int)); } /** * Return the size in bytes required to store the matching class type * num_elements is num_buttons for XIButtonClass or num_keycodes for * XIKeyClass. * * Also used from copy_classes in XIQueryDevice.c */ static int sizeDeviceClassType(int type, int num_elements) { int l = 0; int extra1 = 0; int extra2 = 0; switch(type) { case XIButtonClass: sizeXIButtonClassType(num_elements, &l, &extra1, &extra2); l += extra1 + extra2; break; case XIKeyClass: sizeXIKeyClassType(num_elements, &l, &extra1); l += extra1; break; case XIValuatorClass: l = pad_to_double(sizeof(XIValuatorClassInfo)); break; case XIScrollClass: l = pad_to_double(sizeof(XIScrollClassInfo)); break; case XITouchClass: l = pad_to_double(sizeof(XITouchClassInfo)); break; default: printf("sizeDeviceClassType: unknown type %d\n", type); break; } return l; } static Bool copyHierarchyEvent(XGenericEventCookie *cookie_in, XGenericEventCookie *cookie_out) { XIHierarchyEvent *in, *out; void *ptr; in = cookie_in->data; ptr = cookie_out->data = malloc(sizeof(XIHierarchyEvent) + in->num_info * sizeof(XIHierarchyInfo)); if (!ptr) return False; out = next_block(&ptr, sizeof(XIHierarchyEvent)); *out = *in; out->info = next_block(&ptr, in->num_info * sizeof(XIHierarchyInfo)); memcpy(out->info, in->info, in->num_info * sizeof(XIHierarchyInfo)); return True; } static Bool copyDeviceChangedEvent(XGenericEventCookie *in_cookie, XGenericEventCookie *out_cookie) { int len, i; XIDeviceChangedEvent *in, *out; XIAnyClassInfo *any; void *ptr; in = in_cookie->data; len = sizeof(XIDeviceChangedEvent); len += in->num_classes * sizeof(XIAnyClassInfo*); for (i = 0; i < in->num_classes; i++) { any = in->classes[i]; switch(any->type) { case XIButtonClass: len += sizeDeviceClassType(XIButtonClass, ((XIButtonClassInfo*)any)->num_buttons); break; case XIKeyClass: len += sizeDeviceClassType(XIKeyClass, ((XIKeyClassInfo*)any)->num_keycodes); break; case XIValuatorClass: len += sizeDeviceClassType(XIValuatorClass, 0); break; case XIScrollClass: len += sizeDeviceClassType(XIScrollClass, 0); break; default: printf("copyDeviceChangedEvent: unknown type %d\n", any->type); break; } } ptr = out_cookie->data = malloc(len); if (!ptr) return False; out = next_block(&ptr, sizeof(XIDeviceChangedEvent)); *out = *in; out->classes = next_block(&ptr, out->num_classes * sizeof(XIAnyClassInfo*)); for (i = 0; i < in->num_classes; i++) { any = in->classes[i]; switch(any->type) { case XIButtonClass: { int struct_size; int state_size; int labels_size; XIButtonClassInfo *bin, *bout; bin = (XIButtonClassInfo*)any; sizeXIButtonClassType(bin->num_buttons, &struct_size, &state_size, &labels_size); bout = next_block(&ptr, struct_size); *bout = *bin; bout->state.mask = next_block(&ptr, state_size); memcpy(bout->state.mask, bin->state.mask, bout->state.mask_len); bout->labels = next_block(&ptr, labels_size); memcpy(bout->labels, bin->labels, bout->num_buttons * sizeof(Atom)); out->classes[i] = (XIAnyClassInfo*)bout; break; } case XIKeyClass: { XIKeyClassInfo *kin, *kout; int struct_size; int keycodes_size; kin = (XIKeyClassInfo*)any; sizeXIKeyClassType(kin->num_keycodes, &struct_size, &keycodes_size); kout = next_block(&ptr, struct_size); *kout = *kin; kout->keycodes = next_block(&ptr, keycodes_size); memcpy(kout->keycodes, kin->keycodes, kout->num_keycodes * sizeof(int)); out->classes[i] = (XIAnyClassInfo*)kout; break; } case XIValuatorClass: { XIValuatorClassInfo *vin, *vout; vin = (XIValuatorClassInfo*)any; vout = next_block(&ptr, sizeDeviceClassType(XIValuatorClass, 0)); *vout = *vin; out->classes[i] = (XIAnyClassInfo*)vout; break; } case XIScrollClass: { XIScrollClassInfo *sin, *sout; sin = (XIScrollClassInfo*)any; sout = next_block(&ptr, sizeDeviceClassType(XIScrollClass, 0)); *sout = *sin; out->classes[i] = (XIAnyClassInfo*)sout; break; } } } return True; } static Bool copyDeviceEvent(XGenericEventCookie *cookie_in, XGenericEventCookie *cookie_out) { int len; XIDeviceEvent *in, *out; int bits; /* valuator bits */ void *ptr; in = cookie_in->data; bits = count_bits(in->valuators.mask, in->valuators.mask_len); len = sizeDeviceEvent(in->buttons.mask_len, in->valuators.mask_len, in->valuators.mask); ptr = cookie_out->data = malloc(len); if (!ptr) return False; out = next_block(&ptr, sizeof(XIDeviceEvent)); *out = *in; out->buttons.mask = next_block(&ptr, in->buttons.mask_len); memcpy(out->buttons.mask, in->buttons.mask, out->buttons.mask_len); out->valuators.mask = next_block(&ptr, in->valuators.mask_len); memcpy(out->valuators.mask, in->valuators.mask, out->valuators.mask_len); out->valuators.values = next_block(&ptr, bits * sizeof(double)); memcpy(out->valuators.values, in->valuators.values, bits * sizeof(double)); return True; } static Bool copyEnterEvent(XGenericEventCookie *cookie_in, XGenericEventCookie *cookie_out) { int len; XIEnterEvent *in, *out; void *ptr; in = cookie_in->data; len = sizeof(XIEnterEvent) + in->buttons.mask_len; ptr = cookie_out->data = malloc(len); if (!ptr) return False; out = next_block(&ptr, sizeof(XIEnterEvent)); *out = *in; out->buttons.mask = next_block(&ptr, in->buttons.mask_len); memcpy(out->buttons.mask, in->buttons.mask, out->buttons.mask_len); return True; } static Bool copyPropertyEvent(XGenericEventCookie *cookie_in, XGenericEventCookie *cookie_out) { XIPropertyEvent *in, *out; in = cookie_in->data; out = cookie_out->data = malloc(sizeof(XIPropertyEvent)); if (!out) return False; *out = *in; return True; } static Bool copyTouchOwnershipEvent(XGenericEventCookie *cookie_in, XGenericEventCookie *cookie_out) { XITouchOwnershipEvent *in, *out; in = cookie_in->data; out = cookie_out->data = malloc(sizeof(XITouchOwnershipEvent)); if (!out) return False; *out = *in; return True; } static Bool copyRawEvent(XGenericEventCookie *cookie_in, XGenericEventCookie *cookie_out) { XIRawEvent *in, *out; void *ptr; int len; int bits; in = cookie_in->data; bits = count_bits(in->valuators.mask, in->valuators.mask_len); len = sizeof(XIRawEvent) + in->valuators.mask_len; len += bits * sizeof(double) * 2; ptr = cookie_out->data = malloc(len); if (!ptr) return False; out = next_block(&ptr, sizeof(XIRawEvent)); *out = *in; out->valuators.mask = next_block(&ptr, out->valuators.mask_len); memcpy(out->valuators.mask, in->valuators.mask, out->valuators.mask_len); out->valuators.values = next_block(&ptr, bits * sizeof(double)); memcpy(out->valuators.values, in->valuators.values, bits * sizeof(double)); out->raw_values = next_block(&ptr, bits * sizeof(double)); memcpy(out->raw_values, in->raw_values, bits * sizeof(double)); return True; } static Bool copyBarrierEvent(XGenericEventCookie *in_cookie, XGenericEventCookie *out_cookie) { XIBarrierEvent *in, *out; in = in_cookie->data; out = out_cookie->data = calloc(1, sizeof(XIBarrierEvent)); if (!out) return False; *out = *in; return True; } static Bool XInputCopyCookie(Display *dpy, XGenericEventCookie *in, XGenericEventCookie *out) { int ret = True; XExtDisplayInfo *info = XInput_find_display(dpy); if (in->extension != info->codes->major_opcode) { printf("XInputCopyCookie: wrong extension opcode %d\n", in->extension); return False; } *out = *in; out->data = NULL; out->cookie = 0; switch(in->evtype) { case XI_Motion: case XI_ButtonPress: case XI_ButtonRelease: case XI_KeyPress: case XI_KeyRelease: case XI_TouchBegin: case XI_TouchUpdate: case XI_TouchEnd: ret = copyDeviceEvent(in, out); break; case XI_DeviceChanged: ret = copyDeviceChangedEvent(in, out); break; case XI_HierarchyChanged: ret = copyHierarchyEvent(in, out); break; case XI_Enter: case XI_Leave: case XI_FocusIn: case XI_FocusOut: ret = copyEnterEvent(in, out); break; case XI_PropertyEvent: ret = copyPropertyEvent(in, out); break; case XI_TouchOwnership: ret = copyTouchOwnershipEvent(in, out); break; case XI_RawKeyPress: case XI_RawKeyRelease: case XI_RawButtonPress: case XI_RawButtonRelease: case XI_RawMotion: case XI_RawTouchBegin: case XI_RawTouchUpdate: case XI_RawTouchEnd: ret = copyRawEvent(in, out); break; case XI_BarrierHit: case XI_BarrierLeave: ret = copyBarrierEvent(in, out); break; default: printf("XInputCopyCookie: unknown evtype %d\n", in->evtype); ret = False; } if (!ret) printf("XInputCopyCookie: Failed to copy evtype %d", in->evtype); return ret; } static int wireToDeviceEvent(xXIDeviceEvent *in, XGenericEventCookie* cookie) { int len, i; unsigned char *ptr; void *ptr_lib; FP3232 *values; XIDeviceEvent *out; ptr = (unsigned char*)&in[1] + in->buttons_len * 4; len = sizeDeviceEvent(in->buttons_len * 4, in->valuators_len * 4, ptr); cookie->data = ptr_lib = malloc(len); out = next_block(&ptr_lib, sizeof(XIDeviceEvent)); out->display = cookie->display; out->type = in->type; out->serial = cookie->serial; out->extension = in->extension; out->evtype = in->evtype; out->send_event = ((in->type & 0x80) != 0); out->time = in->time; out->deviceid = in->deviceid; out->sourceid = in->sourceid; out->detail = in->detail; out->root = in->root; out->event = in->event; out->child = in->child; out->root_x = FP1616toDBL(in->root_x); out->root_y = FP1616toDBL(in->root_y); out->event_x = FP1616toDBL(in->event_x); out->event_y = FP1616toDBL(in->event_y); out->flags = in->flags; out->mods.base = in->mods.base_mods; out->mods.locked = in->mods.locked_mods; out->mods.latched = in->mods.latched_mods; out->mods.effective = in->mods.effective_mods; out->group.base = in->group.base_group; out->group.locked = in->group.locked_group; out->group.latched = in->group.latched_group; out->group.effective = in->group.effective_group; out->buttons.mask_len = in->buttons_len * 4; out->valuators.mask_len = in->valuators_len * 4; out->buttons.mask = next_block(&ptr_lib, out->buttons.mask_len); /* buttons */ ptr = (unsigned char*)&in[1]; memcpy(out->buttons.mask, ptr, out->buttons.mask_len); ptr += in->buttons_len * 4; /* valuators */ out->valuators.mask = next_block(&ptr_lib, out->valuators.mask_len); memcpy(out->valuators.mask, ptr, out->valuators.mask_len); ptr += in->valuators_len * 4; len = count_bits(out->valuators.mask, out->valuators.mask_len); out->valuators.values = next_block(&ptr_lib, len * sizeof(double)); values = (FP3232*)ptr; for (i = 0; i < len; i++, values++) { out->valuators.values[i] = values->integral; out->valuators.values[i] += ((double)values->frac / (1 << 16) / (1 << 16)); } return 1; } _X_HIDDEN int size_classes(xXIAnyInfo* from, int nclasses) { int len, i; xXIAnyInfo *any_wire; char *ptr_wire; /* len for to->classes */ len = pad_to_double(nclasses * sizeof(XIAnyClassInfo*)); ptr_wire = (char*)from; for (i = 0; i < nclasses; i++) { int l = 0; any_wire = (xXIAnyInfo*)ptr_wire; switch(any_wire->type) { case XIButtonClass: l = sizeDeviceClassType(XIButtonClass, ((xXIButtonInfo*)any_wire)->num_buttons); break; case XIKeyClass: l = sizeDeviceClassType(XIKeyClass, ((xXIKeyInfo*)any_wire)->num_keycodes); break; case XIValuatorClass: l = sizeDeviceClassType(XIValuatorClass, 0); break; case XIScrollClass: l = sizeDeviceClassType(XIScrollClass, 0); break; case XITouchClass: l = sizeDeviceClassType(XITouchClass, 0); break; } len += l; ptr_wire += any_wire->length * 4; } return len; } /* Copy classes from any into to->classes and return the number of bytes * copied. Memory layout of to->classes is * [clsptr][clsptr][clsptr][classinfo][classinfo]... * |________|___________^ * |______________________^ */ _X_HIDDEN int copy_classes(XIDeviceInfo* to, xXIAnyInfo* from, int *nclasses) { XIAnyClassInfo *any_lib; xXIAnyInfo *any_wire; void *ptr_lib; char *ptr_wire; int i, len; int cls_idx = 0; if (!to->classes) return -1; ptr_wire = (char*)from; ptr_lib = to->classes; to->classes = next_block(&ptr_lib, pad_to_double((*nclasses) * sizeof(XIAnyClassInfo*))); memset(to->classes, 0, (*nclasses) * sizeof(XIAnyClassInfo*)); len = 0; /* count wire length */ for (i = 0; i < *nclasses; i++) { any_lib = (XIAnyClassInfo*)ptr_lib; any_wire = (xXIAnyInfo*)ptr_wire; switch(any_wire->type) { case XIButtonClass: { XIButtonClassInfo *cls_lib; xXIButtonInfo *cls_wire; uint32_t *atoms; int j; int struct_size; int state_size; int labels_size; int wire_mask_size; cls_wire = (xXIButtonInfo*)any_wire; sizeXIButtonClassType(cls_wire->num_buttons, &struct_size, &state_size, &labels_size); cls_lib = next_block(&ptr_lib, struct_size); wire_mask_size = ((cls_wire->num_buttons + 7)/8 + 3)/4 * 4; cls_lib->type = cls_wire->type; cls_lib->sourceid = cls_wire->sourceid; cls_lib->num_buttons = cls_wire->num_buttons; cls_lib->state.mask_len = state_size; cls_lib->state.mask = next_block(&ptr_lib, state_size); memcpy(cls_lib->state.mask, &cls_wire[1], wire_mask_size); if (state_size != wire_mask_size) memset(&cls_lib->state.mask[wire_mask_size], 0, state_size - wire_mask_size); cls_lib->labels = next_block(&ptr_lib, labels_size); atoms =(uint32_t*)((char*)&cls_wire[1] + wire_mask_size); for (j = 0; j < cls_lib->num_buttons; j++) cls_lib->labels[j] = *atoms++; to->classes[cls_idx++] = any_lib; break; } case XIKeyClass: { XIKeyClassInfo *cls_lib; xXIKeyInfo *cls_wire; int struct_size; int keycodes_size; cls_wire = (xXIKeyInfo*)any_wire; sizeXIKeyClassType(cls_wire->num_keycodes, &struct_size, &keycodes_size); cls_lib = next_block(&ptr_lib, struct_size); cls_lib->type = cls_wire->type; cls_lib->sourceid = cls_wire->sourceid; cls_lib->num_keycodes = cls_wire->num_keycodes; cls_lib->keycodes = next_block(&ptr_lib, keycodes_size); memcpy(cls_lib->keycodes, &cls_wire[1], cls_lib->num_keycodes); to->classes[cls_idx++] = any_lib; break; } case XIValuatorClass: { XIValuatorClassInfo *cls_lib; xXIValuatorInfo *cls_wire; cls_lib = next_block(&ptr_lib, sizeDeviceClassType(XIValuatorClass, 0)); cls_wire = (xXIValuatorInfo*)any_wire; cls_lib->type = cls_wire->type; cls_lib->sourceid = cls_wire->sourceid; cls_lib->number = cls_wire->number; cls_lib->label = cls_wire->label; cls_lib->resolution = cls_wire->resolution; cls_lib->min = cls_wire->min.integral; cls_lib->max = cls_wire->max.integral; cls_lib->value = cls_wire->value.integral; /* FIXME: fractional parts */ cls_lib->mode = cls_wire->mode; to->classes[cls_idx++] = any_lib; } break; case XIScrollClass: { XIScrollClassInfo *cls_lib; xXIScrollInfo *cls_wire; cls_lib = next_block(&ptr_lib, sizeDeviceClassType(XIScrollClass, 0)); cls_wire = (xXIScrollInfo*)any_wire; cls_lib->type = cls_wire->type; cls_lib->sourceid = cls_wire->sourceid; cls_lib->number = cls_wire->number; cls_lib->scroll_type= cls_wire->scroll_type; cls_lib->flags = cls_wire->flags; cls_lib->increment = cls_wire->increment.integral; cls_lib->increment += (unsigned int)cls_wire->increment.frac/(double)(1ULL << 32); to->classes[cls_idx++] = any_lib; } break; case XITouchClass: { XITouchClassInfo *cls_lib; xXITouchInfo *cls_wire; cls_wire = (xXITouchInfo*)any_wire; cls_lib = next_block(&ptr_lib, sizeof(XITouchClassInfo)); cls_lib->type = cls_wire->type; cls_lib->sourceid = cls_wire->sourceid; cls_lib->mode = cls_wire->mode; cls_lib->num_touches = cls_wire->num_touches; to->classes[cls_idx++] = any_lib; } break; } len += any_wire->length * 4; ptr_wire += any_wire->length * 4; } /* we may have skipped unknown classes, reset nclasses */ *nclasses = cls_idx; return len; } static int wireToDeviceChangedEvent(xXIDeviceChangedEvent *in, XGenericEventCookie *cookie) { XIDeviceChangedEvent *out; XIDeviceInfo info; int len; int nclasses = in->num_classes; len = size_classes((xXIAnyInfo*)&in[1], in->num_classes); cookie->data = out = malloc(sizeof(XIDeviceChangedEvent) + len); out->type = in->type; out->serial = cookie->serial; out->display = cookie->display; out->extension = in->extension; out->evtype = in->evtype; out->send_event = ((in->type & 0x80) != 0); out->time = in->time; out->deviceid = in->deviceid; out->sourceid = in->sourceid; out->reason = in->reason; out->classes = (XIAnyClassInfo**)&out[1]; info.classes = out->classes; copy_classes(&info, (xXIAnyInfo*)&in[1], &nclasses); out->num_classes = nclasses; return 1; } static int wireToHierarchyChangedEvent(xXIHierarchyEvent *in, XGenericEventCookie *cookie) { int i; XIHierarchyInfo *info_out; xXIHierarchyInfo *info_in; XIHierarchyEvent *out; cookie->data = out = malloc(sizeof(XIHierarchyEvent) + in->num_info * sizeof(XIHierarchyInfo));; out->info = (XIHierarchyInfo*)&out[1]; out->display = cookie->display; out->type = in->type; out->serial = cookie->serial; out->extension = in->extension; out->evtype = in->evtype; out->send_event = ((in->type & 0x80) != 0); out->time = in->time; out->flags = in->flags; out->num_info = in->num_info; info_out = out->info; info_in = (xXIHierarchyInfo*)&in[1]; for (i = 0; i < out->num_info; i++, info_out++, info_in++) { info_out->deviceid = info_in->deviceid; info_out->attachment = info_in->attachment; info_out->use = info_in->use; info_out->enabled = info_in->enabled; info_out->flags = info_in->flags; } return 1; } static int wireToRawEvent(XExtDisplayInfo *info, xXIRawEvent *in, XGenericEventCookie *cookie) { int len, i, bits; FP3232 *values; XIRawEvent *out; void *ptr; len = sizeof(XIRawEvent) + in->valuators_len * 4; bits = count_bits((unsigned char*)&in[1], in->valuators_len * 4); len += bits * sizeof(double) * 2; /* raw + normal */ cookie->data = ptr = calloc(1, len); if (!ptr) return 0; out = next_block(&ptr, sizeof(XIRawEvent)); out->type = in->type; out->serial = cookie->serial; out->display = cookie->display; out->extension = in->extension; out->evtype = in->evtype; out->send_event = ((in->type & 0x80) != 0); out->time = in->time; out->detail = in->detail; out->deviceid = in->deviceid; out->flags = in->flags; /* https://bugs.freedesktop.org/show_bug.cgi?id=34240 */ if (_XiCheckVersion(info, XInput_2_2) >= 0) out->sourceid = in->sourceid; else out->sourceid = 0; out->valuators.mask_len = in->valuators_len * 4; out->valuators.mask = next_block(&ptr, out->valuators.mask_len); memcpy(out->valuators.mask, &in[1], out->valuators.mask_len); out->valuators.values = next_block(&ptr, bits * sizeof(double)); out->raw_values = next_block(&ptr, bits * sizeof(double)); values = (FP3232*)(((char*)&in[1]) + in->valuators_len * 4); for (i = 0; i < bits; i++) { out->valuators.values[i] = values->integral; out->valuators.values[i] += ((double)values->frac / (1 << 16) / (1 << 16)); out->raw_values[i] = (values + bits)->integral; out->raw_values[i] += ((double)(values + bits)->frac / (1 << 16) / (1 << 16)); values++; } return 1; } /* Memory layout of XIEnterEvents: [event][modifiers][group][button] */ static int wireToEnterLeave(xXIEnterEvent *in, XGenericEventCookie *cookie) { int len; XIEnterEvent *out; len = sizeof(XIEnterEvent) + in->buttons_len * 4; cookie->data = out = malloc(len); out->buttons.mask = (unsigned char*)&out[1]; out->type = in->type; out->serial = cookie->serial; out->display = cookie->display; out->extension = in->extension; out->evtype = in->evtype; out->send_event = ((in->type & 0x80) != 0); out->time = in->time; out->detail = in->detail; out->deviceid = in->deviceid; out->root = in->root; out->event = in->event; out->child = in->child; out->sourceid = in->sourceid; out->root_x = FP1616toDBL(in->root_x); out->root_y = FP1616toDBL(in->root_y); out->event_x = FP1616toDBL(in->event_x); out->event_y = FP1616toDBL(in->event_y); out->mode = in->mode; out->focus = in->focus; out->same_screen = in->same_screen; out->mods.base = in->mods.base_mods; out->mods.locked = in->mods.locked_mods; out->mods.latched = in->mods.latched_mods; out->mods.effective = in->mods.effective_mods; out->group.base = in->group.base_group; out->group.locked = in->group.locked_group; out->group.latched = in->group.latched_group; out->group.effective = in->group.effective_group; out->buttons.mask_len = in->buttons_len * 4; memcpy(out->buttons.mask, &in[1], out->buttons.mask_len); return 1; } static int wireToPropertyEvent(xXIPropertyEvent *in, XGenericEventCookie *cookie) { XIPropertyEvent *out = malloc(sizeof(XIPropertyEvent)); cookie->data = out; out->type = in->type; out->serial = cookie->serial; out->extension = in->extension; out->evtype = in->evtype; out->send_event = ((in->type & 0x80) != 0); out->time = in->time; out->property = in->property; out->what = in->what; out->deviceid = in->deviceid; return 1; } static int wireToTouchOwnershipEvent(xXITouchOwnershipEvent *in, XGenericEventCookie *cookie) { XITouchOwnershipEvent *out = malloc(sizeof(XITouchOwnershipEvent)); cookie->data = out; out->type = in->type; out->serial = cookie->serial; out->display = cookie->display; out->extension = in->extension; out->evtype = in->evtype; out->send_event = ((in->type & 0x80) != 0); out->time = in->time; out->deviceid = in->deviceid; out->sourceid = in->sourceid; out->touchid = in->touchid; out->root = in->root; out->event = in->event; out->child = in->child; out->flags = in->flags; return 1; } #define FP3232_TO_DOUBLE(x) ((double) (x).integral + (x).frac / (1ULL << 32)) static int wireToBarrierEvent(xXIBarrierEvent *in, XGenericEventCookie *cookie) { XIBarrierEvent *out = malloc(sizeof(XIBarrierEvent)); cookie->data = out; out->display = cookie->display; out->type = in->type; out->serial = cookie->serial; out->extension = in->extension; out->evtype = in->evtype; out->send_event = ((in->type & 0x80) != 0); out->time = in->time; out->deviceid = in->deviceid; out->sourceid = in->sourceid; out->event = in->event; out->root = in->root; out->root_x = FP1616toDBL(in->root_x); out->root_y = FP1616toDBL(in->root_y); out->dx = FP3232_TO_DOUBLE (in->dx); out->dy = FP3232_TO_DOUBLE (in->dy); out->dtime = in->dtime; out->flags = in->flags; out->barrier = in->barrier; out->eventid = in->eventid; return 1; }