/* * Copyright © 2004-2008 Red Hat, Inc. * * 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 Red Hat * not be used in advertising or publicity pertaining to distribution * of the software without specific, written prior permission. Red * Hat makes no representations about the suitability of this software * for any purpose. It is provided "as is" without express or implied * warranty. * * THE AUTHORS DISCLAIM ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, * INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN * NO EVENT SHALL THE AUTHORS 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. * * Authors: * Kristian Høgsberg (krh@redhat.com) * Adam Jackson (ajax@redhat.com) * Peter Hutterer (peter.hutterer@redhat.com) * Oliver McFadden (oliver.mcfadden@nokia.com) */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "evdev.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* removed from server, purge when dropping support for server 1.10 */ #define XI86_SEND_DRAG_EVENTS 0x08 #ifndef MAXDEVICES #include /* for MAX_DEVICES */ #define MAXDEVICES MAX_DEVICES #endif #define ArrayLength(a) (sizeof(a) / (sizeof((a)[0]))) #define MIN_KEYCODE 8 #define GLYPHS_PER_KEY 2 #define AltMask Mod1Mask #define NumLockMask Mod2Mask #define AltLangMask Mod3Mask #define KanaMask Mod4Mask #define ScrollLockMask Mod5Mask #define CAPSFLAG 1 #define NUMFLAG 2 #define SCROLLFLAG 4 #define MODEFLAG 8 #define COMPOSEFLAG 16 static char *evdevDefaults[] = { "XkbRules", "evdev", "XkbModel", "evdev", "XkbLayout", "us", NULL }; /* Any of those triggers a proximity event */ static int proximity_bits[] = { BTN_TOOL_PEN, BTN_TOOL_RUBBER, BTN_TOOL_BRUSH, BTN_TOOL_PENCIL, BTN_TOOL_AIRBRUSH, BTN_TOOL_FINGER, BTN_TOOL_MOUSE, BTN_TOOL_LENS, }; static int EvdevOn(DeviceIntPtr); static int EvdevCache(InputInfoPtr pInfo); static void EvdevKbdCtrl(DeviceIntPtr device, KeybdCtrl *ctrl); static int EvdevSwitchMode(ClientPtr client, DeviceIntPtr device, int mode); static BOOL EvdevGrabDevice(InputInfoPtr pInfo, int grab, int ungrab); static void EvdevSetCalibration(InputInfoPtr pInfo, int num_calibration, int calibration[4]); static int EvdevOpenDevice(InputInfoPtr pInfo); static void EvdevInitAxesLabels(EvdevPtr pEvdev, int natoms, Atom *atoms); static void EvdevInitButtonLabels(EvdevPtr pEvdev, int natoms, Atom *atoms); static void EvdevInitProperty(DeviceIntPtr dev); static int EvdevSetProperty(DeviceIntPtr dev, Atom atom, XIPropertyValuePtr val, BOOL checkonly); static Atom prop_invert; static Atom prop_calibration; static Atom prop_swap; static Atom prop_axis_label; static Atom prop_btn_label; /* All devices the evdev driver has allocated and knows about. * MAXDEVICES is safe as null-terminated array, as two devices (VCP and VCK) * cannot be used by evdev, leaving us with a space of 2 at the end. */ static EvdevPtr evdev_devices[MAXDEVICES] = {NULL}; static int EvdevSwitchMode(ClientPtr client, DeviceIntPtr device, int mode) { InputInfoPtr pInfo; EvdevPtr pEvdev; pInfo = device->public.devicePrivate; pEvdev = pInfo->private; if (pEvdev->flags & EVDEV_RELATIVE_EVENTS) { if (mode == Relative) return Success; else return XI_BadMode; } switch (mode) { case Absolute: pEvdev->flags &= ~EVDEV_RELATIVE_MODE; break; case Relative: pEvdev->flags |= EVDEV_RELATIVE_MODE; break; default: return XI_BadMode; } return Success; } static size_t EvdevCountBits(unsigned long *array, size_t nlongs) { unsigned int i; size_t count = 0; for (i = 0; i < nlongs; i++) { unsigned long x = array[i]; while (x > 0) { count += (x & 0x1); x >>= 1; } } return count; } static int EvdevGetMajorMinor(InputInfoPtr pInfo) { struct stat st; if (fstat(pInfo->fd, &st) == -1) { xf86IDrvMsg(pInfo, X_ERROR, "stat failed (%s). cannot check for duplicates.\n", strerror(errno)); return 0; } return st.st_rdev; } /** * Return TRUE if one of the devices we know about has the same min/maj * number. */ static BOOL EvdevIsDuplicate(InputInfoPtr pInfo) { EvdevPtr pEvdev = pInfo->private; EvdevPtr* dev = evdev_devices; if (pEvdev->min_maj) { while(*dev) { if ((*dev) != pEvdev && (*dev)->min_maj && (*dev)->min_maj == pEvdev->min_maj) return TRUE; dev++; } } return FALSE; } /** * Add to internal device list. */ static void EvdevAddDevice(InputInfoPtr pInfo) { EvdevPtr pEvdev = pInfo->private; EvdevPtr* dev = evdev_devices; while(*dev) dev++; *dev = pEvdev; } /** * Remove from internal device list. */ static void EvdevRemoveDevice(InputInfoPtr pInfo) { EvdevPtr pEvdev = pInfo->private; EvdevPtr *dev = evdev_devices; int count = 0; while(*dev) { count++; if (*dev == pEvdev) { memmove(dev, dev + 1, sizeof(evdev_devices) - (count * sizeof(EvdevPtr))); break; } dev++; } } static void SetXkbOption(InputInfoPtr pInfo, char *name, char **option) { char *s; if ((s = xf86SetStrOption(pInfo->options, name, NULL))) { if (!s[0]) { free(s); *option = NULL; } else { *option = s; } } } static int wheel_up_button = 4; static int wheel_down_button = 5; static int wheel_left_button = 6; static int wheel_right_button = 7; static EventQueuePtr EvdevNextInQueue(InputInfoPtr pInfo) { EvdevPtr pEvdev = pInfo->private; if (pEvdev->num_queue >= EVDEV_MAXQUEUE) { xf86IDrvMsg(pInfo, X_NONE, "dropping event due to full queue!\n"); return NULL; } pEvdev->num_queue++; return &pEvdev->queue[pEvdev->num_queue - 1]; } void EvdevQueueKbdEvent(InputInfoPtr pInfo, struct input_event *ev, int value) { int code = ev->code + MIN_KEYCODE; EventQueuePtr pQueue; /* Filter all repeated events from device. We'll do softrepeat in the server, but only since 1.6 */ if (value == 2) return; if ((pQueue = EvdevNextInQueue(pInfo))) { pQueue->type = EV_QUEUE_KEY; pQueue->key = code; pQueue->val = value; } } void EvdevQueueButtonEvent(InputInfoPtr pInfo, int button, int value) { EventQueuePtr pQueue; if ((pQueue = EvdevNextInQueue(pInfo))) { pQueue->type = EV_QUEUE_BTN; pQueue->key = button; pQueue->val = value; } } void EvdevQueueProximityEvent(InputInfoPtr pInfo, int value) { EventQueuePtr pQueue; if ((pQueue = EvdevNextInQueue(pInfo))) { pQueue->type = EV_QUEUE_PROXIMITY; pQueue->key = 0; pQueue->val = value; } } /** * Post button event right here, right now. * Interface for MB emulation since these need to post immediately. */ void EvdevPostButtonEvent(InputInfoPtr pInfo, int button, int value) { xf86PostButtonEvent(pInfo->dev, Relative, button, value, 0, 0); } void EvdevQueueButtonClicks(InputInfoPtr pInfo, int button, int count) { int i; for (i = 0; i < count; i++) { EvdevQueueButtonEvent(pInfo, button, 1); EvdevQueueButtonEvent(pInfo, button, 0); } } /** * Take the valuators and process them accordingly. */ static void EvdevProcessValuators(InputInfoPtr pInfo) { int tmp; EvdevPtr pEvdev = pInfo->private; int *delta = pEvdev->delta; /* convert to relative motion for touchpads */ if (pEvdev->abs_queued && (pEvdev->flags & EVDEV_RELATIVE_MODE)) { if (pEvdev->in_proximity) { if (valuator_mask_isset(pEvdev->vals, 0)) { if (valuator_mask_isset(pEvdev->old_vals, 0)) delta[REL_X] = valuator_mask_get(pEvdev->vals, 0) - valuator_mask_get(pEvdev->old_vals, 0); valuator_mask_set(pEvdev->old_vals, 0, valuator_mask_get(pEvdev->vals, 0)); } if (valuator_mask_isset(pEvdev->vals, 1)) { if (valuator_mask_isset(pEvdev->old_vals, 1)) delta[REL_Y] = valuator_mask_get(pEvdev->vals, 1) - valuator_mask_get(pEvdev->old_vals, 1); valuator_mask_set(pEvdev->old_vals, 1, valuator_mask_get(pEvdev->vals, 1)); } } else { valuator_mask_zero(pEvdev->old_vals); } valuator_mask_zero(pEvdev->vals); pEvdev->abs_queued = 0; pEvdev->rel_queued = 1; } if (pEvdev->rel_queued) { int i; if (pEvdev->swap_axes) { tmp = pEvdev->delta[REL_X]; pEvdev->delta[REL_X] = pEvdev->delta[REL_Y]; pEvdev->delta[REL_Y] = tmp; } if (pEvdev->invert_x) pEvdev->delta[REL_X] *= -1; if (pEvdev->invert_y) pEvdev->delta[REL_Y] *= -1; Evdev3BEmuProcessRelMotion(pInfo, pEvdev->delta[REL_X], pEvdev->delta[REL_Y]); for (i = 0; i < REL_CNT; i++) { int map = pEvdev->axis_map[i]; if (pEvdev->delta[i] && map != -1) valuator_mask_set(pEvdev->vals, map, pEvdev->delta[i]); } } /* * Some devices only generate valid abs coords when BTN_TOOL_PEN is * pressed. On wacom tablets, this means that the pen is in * proximity of the tablet. After the pen is removed, BTN_TOOL_PEN is * released, and a (0, 0) absolute event is generated. Checking * pEvdev->in_proximity here lets us ignore that event. pEvdev is * initialized to 1 so devices that don't use this scheme still * just works. */ else if (pEvdev->abs_queued && pEvdev->in_proximity) { int unswapped_x = valuator_mask_get(pEvdev->vals, 0); int unswapped_y = valuator_mask_get(pEvdev->vals, 1); int i; for (i = 0; i <= 1; i++) { int val; int calib_min; int calib_max; if (!valuator_mask_isset(pEvdev->vals, i)) continue; val = valuator_mask_get(pEvdev->vals, i); if (i == 0) { calib_min = pEvdev->calibration.min_x; calib_max = pEvdev->calibration.max_x; } else { calib_min = pEvdev->calibration.min_y; calib_max = pEvdev->calibration.max_y; } if (pEvdev->swap_axes) val = xf86ScaleAxis((i == 0 ? unswapped_y : unswapped_x), pEvdev->absinfo[i].maximum, pEvdev->absinfo[i].minimum, pEvdev->absinfo[1 - i].maximum, pEvdev->absinfo[1 - i].minimum); if (pEvdev->flags & EVDEV_CALIBRATED) val = xf86ScaleAxis(val, pEvdev->absinfo[i].maximum, pEvdev->absinfo[i].minimum, calib_max, calib_min); if ((i == 0 && pEvdev->invert_x) || (i == 1 && pEvdev->invert_y)) val = (pEvdev->absinfo[i].maximum - val + pEvdev->absinfo[i].minimum); valuator_mask_set(pEvdev->vals, i, val); } Evdev3BEmuProcessAbsMotion(pInfo, pEvdev->vals); } } static void EvdevProcessProximityEvent(InputInfoPtr pInfo, struct input_event *ev) { EvdevPtr pEvdev = pInfo->private; if (!pEvdev->use_proximity) return; pEvdev->prox_queued = 1; EvdevQueueProximityEvent(pInfo, ev->value); } /** * Proximity handling is rather weird because of tablet-specific issues. * Some tablets, notably Wacoms, send a 0/0 coordinate in the same EV_SYN as * the out-of-proximity notify. We need to ignore those, hence we only * actually post valuator events when we're in proximity. * * Other tablets send the x/y coordinates, then EV_SYN, then the proximity * event. For those, we need to remember x/y to post it when the proximity * comes. * * If we're not in proximity and we get valuator events, remember that, they * won't be posted though. If we move into proximity without valuators, use * the last ones we got and let the rest of the code post them. */ static int EvdevProcessProximityState(InputInfoPtr pInfo) { EvdevPtr pEvdev = pInfo->private; int prox_state = 0; int i; /* Does this device have any proximity axes? */ if (!pEvdev->prox) return 0; /* no proximity change in the queue */ if (!pEvdev->prox_queued) { if (pEvdev->abs_queued && !pEvdev->in_proximity) for (i = 0; i < valuator_mask_size(pEvdev->vals); i++) if (valuator_mask_isset(pEvdev->vals, i)) valuator_mask_set(pEvdev->prox, i, valuator_mask_get(pEvdev->vals, i)); return 0; } for (i = 0; i < pEvdev->num_queue; i++) { if (pEvdev->queue[i].type == EV_QUEUE_PROXIMITY) { prox_state = pEvdev->queue[i].val; break; } } if ((prox_state && !pEvdev->in_proximity) || (!prox_state && pEvdev->in_proximity)) { /* We're about to go into/out of proximity but have no abs events * within the EV_SYN. Use the last coordinates we have. */ if (!pEvdev->abs_queued && valuator_mask_num_valuators(pEvdev->prox) > 0) { valuator_mask_copy(pEvdev->vals, pEvdev->prox); valuator_mask_zero(pEvdev->prox); pEvdev->abs_queued = 1; } } pEvdev->in_proximity = prox_state; return 1; } /** * Take a button input event and process it accordingly. */ static void EvdevProcessButtonEvent(InputInfoPtr pInfo, struct input_event *ev) { unsigned int button; int value; EvdevPtr pEvdev = pInfo->private; button = EvdevUtilButtonEventToButtonNumber(pEvdev, ev->code); /* Get the signed value, earlier kernels had this as unsigned */ value = ev->value; /* Handle drag lock */ if (EvdevDragLockFilterEvent(pInfo, button, value)) return; if (EvdevWheelEmuFilterButton(pInfo, button, value)) return; if (EvdevMBEmuFilterEvent(pInfo, button, value)) return; if (button) EvdevQueueButtonEvent(pInfo, button, value); else EvdevQueueKbdEvent(pInfo, ev, value); } /** * Take the relative motion input event and process it accordingly. */ static void EvdevProcessRelativeMotionEvent(InputInfoPtr pInfo, struct input_event *ev) { int value; EvdevPtr pEvdev = pInfo->private; int map; /* Get the signed value, earlier kernels had this as unsigned */ value = ev->value; switch (ev->code) { case REL_WHEEL: if (value > 0) EvdevQueueButtonClicks(pInfo, wheel_up_button, value); else if (value < 0) EvdevQueueButtonClicks(pInfo, wheel_down_button, -value); break; case REL_DIAL: case REL_HWHEEL: if (value > 0) EvdevQueueButtonClicks(pInfo, wheel_right_button, value); else if (value < 0) EvdevQueueButtonClicks(pInfo, wheel_left_button, -value); break; /* We don't post wheel events as axis motion. */ default: /* Ignore EV_REL events if we never set up for them. */ if (!(pEvdev->flags & EVDEV_RELATIVE_EVENTS)) return; /* Handle mouse wheel emulation */ if (EvdevWheelEmuFilterMotion(pInfo, ev)) return; pEvdev->rel_queued = 1; pEvdev->delta[ev->code] += value; map = pEvdev->axis_map[ev->code]; valuator_mask_set(pEvdev->vals, map, value); break; } } /** * Take the absolute motion input event and process it accordingly. */ static void EvdevProcessAbsoluteMotionEvent(InputInfoPtr pInfo, struct input_event *ev) { int value; EvdevPtr pEvdev = pInfo->private; int map; /* Get the signed value, earlier kernels had this as unsigned */ value = ev->value; /* Ignore EV_ABS events if we never set up for them. */ if (!(pEvdev->flags & EVDEV_ABSOLUTE_EVENTS)) return; if (ev->code > ABS_MAX) return; if (EvdevWheelEmuFilterMotion(pInfo, ev)) return; map = pEvdev->axis_map[ev->code]; valuator_mask_set(pEvdev->vals, map, value); pEvdev->abs_queued = 1; } /** * Take the key press/release input event and process it accordingly. */ static void EvdevProcessKeyEvent(InputInfoPtr pInfo, struct input_event *ev) { int value, i; EvdevPtr pEvdev = pInfo->private; /* Get the signed value, earlier kernels had this as unsigned */ value = ev->value; /* don't repeat mouse buttons */ if (ev->code >= BTN_MOUSE && ev->code < KEY_OK) if (value == 2) return; for (i = 0; i < ArrayLength(proximity_bits); i++) { if (ev->code == proximity_bits[i]) { EvdevProcessProximityEvent(pInfo, ev); return; } } switch (ev->code) { case BTN_TOUCH: /* For devices that have but don't use proximity, use * BTN_TOUCH as the proximity notifier */ if (!pEvdev->use_proximity) pEvdev->in_proximity = value ? ev->code : 0; if (!(pEvdev->flags & (EVDEV_TOUCHSCREEN | EVDEV_TABLET))) break; /* Treat BTN_TOUCH from devices that only have BTN_TOUCH as * BTN_LEFT. */ ev->code = BTN_LEFT; /* Intentional fallthrough! */ default: EvdevProcessButtonEvent(pInfo, ev); break; } } /** * Post the relative motion events. */ void EvdevPostRelativeMotionEvents(InputInfoPtr pInfo, int num_v, int first_v, int v[MAX_VALUATORS]) { EvdevPtr pEvdev = pInfo->private; if (pEvdev->rel_queued) { xf86PostMotionEventM(pInfo->dev, Relative, pEvdev->vals); } } /** * Post the absolute motion events. */ void EvdevPostAbsoluteMotionEvents(InputInfoPtr pInfo, int num_v, int first_v, int v[MAX_VALUATORS]) { EvdevPtr pEvdev = pInfo->private; /* * Some devices only generate valid abs coords when BTN_TOOL_PEN is * pressed. On wacom tablets, this means that the pen is in * proximity of the tablet. After the pen is removed, BTN_TOOL_PEN is * released, and a (0, 0) absolute event is generated. Checking * pEvdev->in_proximity here lets us ignore that event. * pEvdev->in_proximity is initialized to 1 so devices that don't use * this scheme still just work. */ if (pEvdev->abs_queued && pEvdev->in_proximity) { xf86PostMotionEventM(pInfo->dev, Absolute, pEvdev->vals); } } static void EvdevPostProximityEvents(InputInfoPtr pInfo, int which, int num_v, int first_v, int v[MAX_VALUATORS]) { int i; EvdevPtr pEvdev = pInfo->private; for (i = 0; pEvdev->prox_queued && i < pEvdev->num_queue; i++) { switch (pEvdev->queue[i].type) { case EV_QUEUE_KEY: case EV_QUEUE_BTN: break; case EV_QUEUE_PROXIMITY: if (pEvdev->queue[i].val == which) xf86PostProximityEventP(pInfo->dev, which, first_v, num_v, v + first_v); break; } } } /** * Post the queued key/button events. */ static void EvdevPostQueuedEvents(InputInfoPtr pInfo, int num_v, int first_v, int v[MAX_VALUATORS]) { int i; EvdevPtr pEvdev = pInfo->private; for (i = 0; i < pEvdev->num_queue; i++) { switch (pEvdev->queue[i].type) { case EV_QUEUE_KEY: xf86PostKeyboardEvent(pInfo->dev, pEvdev->queue[i].key, pEvdev->queue[i].val); break; case EV_QUEUE_BTN: if (Evdev3BEmuFilterEvent(pInfo, pEvdev->queue[i].key, pEvdev->queue[i].val)) break; if (pEvdev->abs_queued && pEvdev->in_proximity) { xf86PostButtonEventP(pInfo->dev, Absolute, pEvdev->queue[i].key, pEvdev->queue[i].val, first_v, num_v, v + first_v); } else xf86PostButtonEvent(pInfo->dev, Relative, pEvdev->queue[i].key, pEvdev->queue[i].val, 0, 0); break; case EV_QUEUE_PROXIMITY: break; } } } /** * Take the synchronization input event and process it accordingly; the motion * notify events are sent first, then any button/key press/release events. */ static void EvdevProcessSyncEvent(InputInfoPtr pInfo, struct input_event *ev) { int num_v = 0, first_v = 0; int v[MAX_VALUATORS] = {}; EvdevPtr pEvdev = pInfo->private; EvdevProcessProximityState(pInfo); EvdevProcessValuators(pInfo); EvdevPostProximityEvents(pInfo, TRUE, num_v, first_v, v); EvdevPostRelativeMotionEvents(pInfo, num_v, first_v, v); EvdevPostAbsoluteMotionEvents(pInfo, num_v, first_v, v); EvdevPostQueuedEvents(pInfo, num_v, first_v, v); EvdevPostProximityEvents(pInfo, FALSE, num_v, first_v, v); memset(pEvdev->delta, 0, sizeof(pEvdev->delta)); memset(pEvdev->queue, 0, sizeof(pEvdev->queue)); if (pEvdev->vals) valuator_mask_zero(pEvdev->vals); pEvdev->num_queue = 0; pEvdev->abs_queued = 0; pEvdev->rel_queued = 0; pEvdev->prox_queued = 0; } /** * Process the events from the device; nothing is actually posted to the server * until an EV_SYN event is received. */ static void EvdevProcessEvent(InputInfoPtr pInfo, struct input_event *ev) { switch (ev->type) { case EV_REL: EvdevProcessRelativeMotionEvent(pInfo, ev); break; case EV_ABS: EvdevProcessAbsoluteMotionEvent(pInfo, ev); break; case EV_KEY: EvdevProcessKeyEvent(pInfo, ev); break; case EV_SYN: EvdevProcessSyncEvent(pInfo, ev); break; } } #undef ABS_X_VALUE #undef ABS_Y_VALUE #undef ABS_VALUE /* just a magic number to reduce the number of reads */ #define NUM_EVENTS 16 static void EvdevReadInput(InputInfoPtr pInfo) { struct input_event ev[NUM_EVENTS]; int i, len = sizeof(ev); while (len == sizeof(ev)) { len = read(pInfo->fd, &ev, sizeof(ev)); if (len <= 0) { if (errno == ENODEV) /* May happen after resume */ { EvdevMBEmuFinalize(pInfo); Evdev3BEmuFinalize(pInfo); xf86RemoveEnabledDevice(pInfo); close(pInfo->fd); pInfo->fd = -1; } else if (errno != EAGAIN) { /* We use X_NONE here because it doesn't alloc */ xf86MsgVerb(X_NONE, 0, "%s: Read error: %s\n", pInfo->name, strerror(errno)); } break; } /* The kernel promises that we always only read a complete * event, so len != sizeof ev is an error. */ if (len % sizeof(ev[0])) { /* We use X_NONE here because it doesn't alloc */ xf86MsgVerb(X_NONE, 0, "%s: Read error: %s\n", pInfo->name, strerror(errno)); break; } for (i = 0; i < len/sizeof(ev[0]); i++) EvdevProcessEvent(pInfo, &ev[i]); } } #define TestBit(bit, array) ((array[(bit) / LONG_BITS]) & (1L << ((bit) % LONG_BITS))) static void EvdevPtrCtrlProc(DeviceIntPtr device, PtrCtrl *ctrl) { /* Nothing to do, dix handles all settings */ } static void EvdevKbdCtrl(DeviceIntPtr device, KeybdCtrl *ctrl) { static struct { int xbit, code; } bits[] = { { CAPSFLAG, LED_CAPSL }, { NUMFLAG, LED_NUML }, { SCROLLFLAG, LED_SCROLLL }, { MODEFLAG, LED_KANA }, { COMPOSEFLAG, LED_COMPOSE } }; InputInfoPtr pInfo; struct input_event ev[ArrayLength(bits)]; int i; memset(ev, 0, sizeof(ev)); pInfo = device->public.devicePrivate; for (i = 0; i < ArrayLength(bits); i++) { ev[i].type = EV_LED; ev[i].code = bits[i].code; ev[i].value = (ctrl->leds & bits[i].xbit) > 0; } write(pInfo->fd, ev, sizeof ev); } static int EvdevAddKeyClass(DeviceIntPtr device) { InputInfoPtr pInfo; EvdevPtr pEvdev; pInfo = device->public.devicePrivate; pEvdev = pInfo->private; /* sorry, no rules change allowed for you */ xf86ReplaceStrOption(pInfo->options, "xkb_rules", "evdev"); SetXkbOption(pInfo, "xkb_rules", &pEvdev->rmlvo.rules); SetXkbOption(pInfo, "xkb_model", &pEvdev->rmlvo.model); if (!pEvdev->rmlvo.model) SetXkbOption(pInfo, "XkbModel", &pEvdev->rmlvo.model); SetXkbOption(pInfo, "xkb_layout", &pEvdev->rmlvo.layout); if (!pEvdev->rmlvo.layout) SetXkbOption(pInfo, "XkbLayout", &pEvdev->rmlvo.layout); SetXkbOption(pInfo, "xkb_variant", &pEvdev->rmlvo.variant); if (!pEvdev->rmlvo.variant) SetXkbOption(pInfo, "XkbVariant", &pEvdev->rmlvo.variant); SetXkbOption(pInfo, "xkb_options", &pEvdev->rmlvo.options); if (!pEvdev->rmlvo.options) SetXkbOption(pInfo, "XkbOptions", &pEvdev->rmlvo.options); if (!InitKeyboardDeviceStruct(device, &pEvdev->rmlvo, NULL, EvdevKbdCtrl)) return !Success; return Success; } static int EvdevAddAbsValuatorClass(DeviceIntPtr device) { InputInfoPtr pInfo; EvdevPtr pEvdev; int num_axes, axis, i = 0; Atom *atoms; pInfo = device->public.devicePrivate; pEvdev = pInfo->private; if (!TestBit(EV_ABS, pEvdev->bitmask)) goto out; num_axes = EvdevCountBits(pEvdev->abs_bitmask, NLONGS(ABS_MAX)); if (num_axes < 1) goto out; if (num_axes > MAX_VALUATORS) { xf86IDrvMsg(pInfo, X_WARNING, "found %d axes, limiting to %d.\n", num_axes, MAX_VALUATORS); num_axes = MAX_VALUATORS; } pEvdev->num_vals = num_axes; if (num_axes > 0) { pEvdev->vals = valuator_mask_new(num_axes); pEvdev->old_vals = valuator_mask_new(num_axes); if (!pEvdev->vals || !pEvdev->old_vals) { xf86IDrvMsg(pInfo, X_ERROR, "failed to allocate valuator masks.\n"); goto out; } } atoms = malloc(pEvdev->num_vals * sizeof(Atom)); for (axis = ABS_X; i < MAX_VALUATORS && axis <= ABS_MAX; axis++) { pEvdev->axis_map[axis] = -1; if (!TestBit(axis, pEvdev->abs_bitmask)) continue; pEvdev->axis_map[axis] = i; i++; } EvdevInitAxesLabels(pEvdev, pEvdev->num_vals, atoms); if (!InitValuatorClassDeviceStruct(device, num_axes, atoms, GetMotionHistorySize(), Absolute)) { xf86IDrvMsg(pInfo, X_ERROR, "failed to initialize valuator class device.\n"); goto out; } for (axis = ABS_X; axis <= ABS_MAX; axis++) { int axnum = pEvdev->axis_map[axis]; int resolution = 10000; if (axnum == -1) continue; #if LINUX_VERSION_CODE > KERNEL_VERSION(2, 6, 30) /* Kernel provides units/mm, X wants units/m */ if (pEvdev->absinfo[axis].resolution) resolution = pEvdev->absinfo[axis].resolution * 1000; #endif xf86InitValuatorAxisStruct(device, axnum, atoms[axnum], pEvdev->absinfo[axis].minimum, pEvdev->absinfo[axis].maximum, resolution, 0, resolution, Absolute); xf86InitValuatorDefaults(device, axnum); } free(atoms); for (i = 0; i < ArrayLength(proximity_bits); i++) { if (!pEvdev->use_proximity) break; if (TestBit(proximity_bits[i], pEvdev->key_bitmask)) { InitProximityClassDeviceStruct(device); pEvdev->prox = valuator_mask_new(num_axes); if (!pEvdev->prox) { xf86IDrvMsg(pInfo, X_ERROR, "failed to allocate proximity valuator " "mask.\n"); goto out; } break; } } if (!InitPtrFeedbackClassDeviceStruct(device, EvdevPtrCtrlProc)) { xf86IDrvMsg(pInfo, X_ERROR, "failed to initialize pointer feedback class device.\n"); goto out; } if (pEvdev->flags & EVDEV_TOUCHPAD) pEvdev->flags |= EVDEV_RELATIVE_MODE; else pEvdev->flags &= ~EVDEV_RELATIVE_MODE; if (xf86FindOption(pInfo->options, "Mode")) { char *mode; mode = xf86SetStrOption(pInfo->options, "Mode", NULL); if (!strcasecmp("absolute", mode)) pEvdev->flags &= ~EVDEV_RELATIVE_MODE; else if (!strcasecmp("relative", mode)) pEvdev->flags |= EVDEV_RELATIVE_MODE; else xf86IDrvMsg(pInfo, X_INFO, "unknown mode, use default\n"); free(mode); } return Success; out: valuator_mask_free(&pEvdev->vals); valuator_mask_free(&pEvdev->old_vals); valuator_mask_free(&pEvdev->prox); return !Success; } static int EvdevAddRelValuatorClass(DeviceIntPtr device) { InputInfoPtr pInfo; EvdevPtr pEvdev; int num_axes, axis, i = 0; Atom *atoms; pInfo = device->public.devicePrivate; pEvdev = pInfo->private; if (!TestBit(EV_REL, pEvdev->bitmask)) goto out; num_axes = EvdevCountBits(pEvdev->rel_bitmask, NLONGS(REL_MAX)); if (num_axes < 1) goto out; /* Wheels are special, we post them as button events. So let's ignore them * in the axes list too */ if (TestBit(REL_WHEEL, pEvdev->rel_bitmask)) num_axes--; if (TestBit(REL_HWHEEL, pEvdev->rel_bitmask)) num_axes--; if (TestBit(REL_DIAL, pEvdev->rel_bitmask)) num_axes--; if (num_axes <= 0) goto out; if (num_axes > MAX_VALUATORS) { xf86IDrvMsg(pInfo, X_WARNING, "found %d axes, limiting to %d.\n", num_axes, MAX_VALUATORS); num_axes = MAX_VALUATORS; } pEvdev->num_vals = num_axes; if (num_axes > 0) { pEvdev->vals = valuator_mask_new(num_axes); if (!pEvdev->vals) goto out; } atoms = malloc(pEvdev->num_vals * sizeof(Atom)); for (axis = REL_X; i < MAX_VALUATORS && axis <= REL_MAX; axis++) { pEvdev->axis_map[axis] = -1; /* We don't post wheel events, so ignore them here too */ if (axis == REL_WHEEL || axis == REL_HWHEEL || axis == REL_DIAL) continue; if (!TestBit(axis, pEvdev->rel_bitmask)) continue; pEvdev->axis_map[axis] = i; i++; } EvdevInitAxesLabels(pEvdev, pEvdev->num_vals, atoms); if (!InitValuatorClassDeviceStruct(device, num_axes, atoms, GetMotionHistorySize(), Relative)) { xf86IDrvMsg(pInfo, X_ERROR, "failed to initialize valuator class device.\n"); goto out; } if (!InitPtrFeedbackClassDeviceStruct(device, EvdevPtrCtrlProc)) { xf86IDrvMsg(pInfo, X_ERROR, "failed to initialize pointer feedback class " "device.\n"); goto out; } for (axis = REL_X; axis <= REL_MAX; axis++) { int axnum = pEvdev->axis_map[axis]; if (axnum == -1) continue; xf86InitValuatorAxisStruct(device, axnum, atoms[axnum], -1, -1, 1, 0, 1, Relative); xf86InitValuatorDefaults(device, axnum); } free(atoms); return Success; out: valuator_mask_free(&pEvdev->vals); return !Success; } static int EvdevAddButtonClass(DeviceIntPtr device) { InputInfoPtr pInfo; EvdevPtr pEvdev; Atom *labels; pInfo = device->public.devicePrivate; pEvdev = pInfo->private; labels = malloc(pEvdev->num_buttons * sizeof(Atom)); EvdevInitButtonLabels(pEvdev, pEvdev->num_buttons, labels); if (!InitButtonClassDeviceStruct(device, pEvdev->num_buttons, labels, pEvdev->btnmap)) return !Success; free(labels); return Success; } /** * Init the button mapping for the device. By default, this is a 1:1 mapping, * i.e. Button 1 maps to Button 1, Button 2 to 2, etc. * * If a mapping has been specified, the mapping is the default, with the * user-defined ones overwriting the defaults. * i.e. a user-defined mapping of "3 2 1" results in a mapping of 3 2 1 4 5 6 ... * * Invalid button mappings revert to the default. * * Note that index 0 is unused, button 0 does not exist. * This mapping is initialised for all devices, but only applied if the device * has buttons (in EvdevAddButtonClass). */ static void EvdevInitButtonMapping(InputInfoPtr pInfo) { int i, nbuttons = 1; char *mapping = NULL; EvdevPtr pEvdev = pInfo->private; /* Check for user-defined button mapping */ if ((mapping = xf86CheckStrOption(pInfo->options, "ButtonMapping", NULL))) { char *map, *s = " "; int btn = 0; xf86IDrvMsg(pInfo, X_CONFIG, "ButtonMapping '%s'\n", mapping); map = mapping; while (s && *s != '\0' && nbuttons < EVDEV_MAXBUTTONS) { btn = strtol(map, &s, 10); if (s == map || btn < 0 || btn > EVDEV_MAXBUTTONS) { xf86IDrvMsg(pInfo, X_ERROR, "... Invalid button mapping. Using defaults\n"); nbuttons = 1; /* ensure defaults start at 1 */ break; } pEvdev->btnmap[nbuttons++] = btn; map = s; } free(mapping); } for (i = nbuttons; i < ArrayLength(pEvdev->btnmap); i++) pEvdev->btnmap[i] = i; } static void EvdevInitAnyValuators(DeviceIntPtr device, EvdevPtr pEvdev) { InputInfoPtr pInfo = device->public.devicePrivate; if (pEvdev->flags & EVDEV_RELATIVE_EVENTS && EvdevAddRelValuatorClass(device) == Success) xf86IDrvMsg(pInfo, X_INFO, "initialized for relative axes.\n"); if (pEvdev->flags & EVDEV_ABSOLUTE_EVENTS && EvdevAddAbsValuatorClass(device) == Success) xf86IDrvMsg(pInfo, X_INFO, "initialized for absolute axes.\n"); } static void EvdevInitAbsValuators(DeviceIntPtr device, EvdevPtr pEvdev) { InputInfoPtr pInfo = device->public.devicePrivate; if (EvdevAddAbsValuatorClass(device) == Success) { xf86IDrvMsg(pInfo, X_INFO,"initialized for absolute axes.\n"); } else { xf86IDrvMsg(pInfo, X_ERROR,"failed to initialize for absolute axes.\n"); pEvdev->flags &= ~EVDEV_ABSOLUTE_EVENTS; } } static void EvdevInitRelValuators(DeviceIntPtr device, EvdevPtr pEvdev) { InputInfoPtr pInfo = device->public.devicePrivate; int has_abs_axes = pEvdev->flags & EVDEV_ABSOLUTE_EVENTS; if (EvdevAddRelValuatorClass(device) == Success) { xf86IDrvMsg(pInfo, X_INFO,"initialized for relative axes.\n"); if (has_abs_axes) { xf86IDrvMsg(pInfo, X_WARNING,"ignoring absolute axes.\n"); pEvdev->flags &= ~EVDEV_ABSOLUTE_EVENTS; } } else { xf86IDrvMsg(pInfo, X_ERROR,"failed to initialize for relative axes.\n"); pEvdev->flags &= ~EVDEV_RELATIVE_EVENTS; if (has_abs_axes) EvdevInitAbsValuators(device, pEvdev); } } static void EvdevInitTouchDevice(DeviceIntPtr device, EvdevPtr pEvdev) { InputInfoPtr pInfo = device->public.devicePrivate; if (pEvdev->flags & EVDEV_RELATIVE_EVENTS) { xf86IDrvMsg(pInfo, X_WARNING, "touchpads, tablets and touchscreens " "ignore relative axes.\n"); pEvdev->flags &= ~EVDEV_RELATIVE_EVENTS; } EvdevInitAbsValuators(device, pEvdev); } static int EvdevInit(DeviceIntPtr device) { int i; InputInfoPtr pInfo; EvdevPtr pEvdev; pInfo = device->public.devicePrivate; pEvdev = pInfo->private; /* clear all axis_map entries */ for(i = 0; i < max(ABS_CNT,REL_CNT); i++) pEvdev->axis_map[i]=-1; if (pEvdev->flags & EVDEV_KEYBOARD_EVENTS) EvdevAddKeyClass(device); if (pEvdev->flags & EVDEV_BUTTON_EVENTS) EvdevAddButtonClass(device); /* We don't allow relative and absolute axes on the same device. The * reason is that some devices (MS Optical Desktop 2000) register both * rel and abs axes for x/y. * * The abs axes register min/max; this min/max then also applies to the * relative device (the mouse) and caps it at 0..255 for both axes. * So, unless you have a small screen, you won't be enjoying it much; * consequently, absolute axes are generally ignored. * * However, currenly only a device with absolute axes can be registered * as a touch{pad,screen}. Thus, given such a device, absolute axes are * used and relative axes are ignored. */ if (pEvdev->flags & (EVDEV_UNIGNORE_RELATIVE | EVDEV_UNIGNORE_ABSOLUTE)) EvdevInitAnyValuators(device, pEvdev); else if (pEvdev->flags & (EVDEV_TOUCHPAD | EVDEV_TOUCHSCREEN | EVDEV_TABLET)) EvdevInitTouchDevice(device, pEvdev); else if (pEvdev->flags & EVDEV_RELATIVE_EVENTS) EvdevInitRelValuators(device, pEvdev); else if (pEvdev->flags & EVDEV_ABSOLUTE_EVENTS) EvdevInitAbsValuators(device, pEvdev); /* We drop the return value, the only time we ever want the handlers to * unregister is when the device dies. In which case we don't have to * unregister anyway */ EvdevInitProperty(device); XIRegisterPropertyHandler(device, EvdevSetProperty, NULL, NULL); EvdevMBEmuInitProperty(device); Evdev3BEmuInitProperty(device); EvdevWheelEmuInitProperty(device); EvdevDragLockInitProperty(device); return Success; } /** * Init all extras (wheel emulation, etc.) and grab the device. */ static int EvdevOn(DeviceIntPtr device) { InputInfoPtr pInfo; EvdevPtr pEvdev; int rc = Success; pInfo = device->public.devicePrivate; pEvdev = pInfo->private; /* after PreInit fd is still open */ rc = EvdevOpenDevice(pInfo); if (rc != Success) return rc; EvdevGrabDevice(pInfo, 1, 0); xf86FlushInput(pInfo->fd); xf86AddEnabledDevice(pInfo); EvdevMBEmuOn(pInfo); Evdev3BEmuOn(pInfo); pEvdev->flags |= EVDEV_INITIALIZED; device->public.on = TRUE; return Success; } static int EvdevProc(DeviceIntPtr device, int what) { InputInfoPtr pInfo; EvdevPtr pEvdev; pInfo = device->public.devicePrivate; pEvdev = pInfo->private; switch (what) { case DEVICE_INIT: return EvdevInit(device); case DEVICE_ON: return EvdevOn(device); case DEVICE_OFF: if (pEvdev->flags & EVDEV_INITIALIZED) { EvdevMBEmuFinalize(pInfo); Evdev3BEmuFinalize(pInfo); } if (pInfo->fd != -1) { EvdevGrabDevice(pInfo, 0, 1); xf86RemoveEnabledDevice(pInfo); close(pInfo->fd); pInfo->fd = -1; } pEvdev->min_maj = 0; pEvdev->flags &= ~EVDEV_INITIALIZED; device->public.on = FALSE; break; case DEVICE_CLOSE: xf86IDrvMsg(pInfo, X_INFO, "Close\n"); if (pInfo->fd != -1) { close(pInfo->fd); pInfo->fd = -1; } valuator_mask_free(&pEvdev->vals); valuator_mask_free(&pEvdev->old_vals); valuator_mask_free(&pEvdev->prox); EvdevRemoveDevice(pInfo); pEvdev->min_maj = 0; break; } return Success; } /** * Get as much information as we can from the fd and cache it. * * @return Success if the information was cached, or !Success otherwise. */ static int EvdevCache(InputInfoPtr pInfo) { EvdevPtr pEvdev = pInfo->private; int i, len; char name[1024] = {0}; unsigned long bitmask[NLONGS(EV_CNT)] = {0}; unsigned long key_bitmask[NLONGS(KEY_CNT)] = {0}; unsigned long rel_bitmask[NLONGS(REL_CNT)] = {0}; unsigned long abs_bitmask[NLONGS(ABS_CNT)] = {0}; unsigned long led_bitmask[NLONGS(LED_CNT)] = {0}; if (ioctl(pInfo->fd, EVIOCGNAME(sizeof(name) - 1), name) < 0) { xf86IDrvMsg(pInfo, X_ERROR, "ioctl EVIOCGNAME failed: %s\n", strerror(errno)); goto error; } strcpy(pEvdev->name, name); len = ioctl(pInfo->fd, EVIOCGBIT(0, sizeof(bitmask)), bitmask); if (len < 0) { xf86IDrvMsg(pInfo, X_ERROR, "ioctl EVIOCGBIT failed: %s\n", strerror(errno)); goto error; } memcpy(pEvdev->bitmask, bitmask, len); len = ioctl(pInfo->fd, EVIOCGBIT(EV_REL, sizeof(rel_bitmask)), rel_bitmask); if (len < 0) { xf86IDrvMsg(pInfo, X_ERROR, "ioctl EVIOCGBIT failed: %s\n", strerror(errno)); goto error; } memcpy(pEvdev->rel_bitmask, rel_bitmask, len); len = ioctl(pInfo->fd, EVIOCGBIT(EV_ABS, sizeof(abs_bitmask)), abs_bitmask); if (len < 0) { xf86IDrvMsg(pInfo, X_ERROR, "ioctl EVIOCGBIT failed: %s\n", strerror(errno)); goto error; } memcpy(pEvdev->abs_bitmask, abs_bitmask, len); len = ioctl(pInfo->fd, EVIOCGBIT(EV_LED, sizeof(led_bitmask)), led_bitmask); if (len < 0) { xf86IDrvMsg(pInfo, X_ERROR, "ioctl EVIOCGBIT failed: %s\n", strerror(errno)); goto error; } memcpy(pEvdev->led_bitmask, led_bitmask, len); /* * Do not try to validate absinfo data since it is not expected * to be static, always refresh it in evdev structure. */ for (i = ABS_X; i <= ABS_MAX; i++) { if (TestBit(i, abs_bitmask)) { len = ioctl(pInfo->fd, EVIOCGABS(i), &pEvdev->absinfo[i]); if (len < 0) { xf86IDrvMsg(pInfo, X_ERROR, "ioctl EVIOCGABSi(%d) failed: %s\n", i, strerror(errno)); goto error; } } } len = ioctl(pInfo->fd, EVIOCGBIT(EV_KEY, sizeof(key_bitmask)), key_bitmask); if (len < 0) { xf86IDrvMsg(pInfo, X_ERROR, "ioctl EVIOCGBIT failed: %s\n", strerror(errno)); goto error; } /* Copy the data so we have reasonably up-to-date info */ memcpy(pEvdev->key_bitmask, key_bitmask, len); return Success; error: return !Success; } /** * Issue an EVIOCGRAB on the device file, either as a grab or to ungrab, or * both. Return TRUE on success, otherwise FALSE. Failing the release is a * still considered a success, because it's not as if you could do anything * about it. */ static BOOL EvdevGrabDevice(InputInfoPtr pInfo, int grab, int ungrab) { EvdevPtr pEvdev = pInfo->private; if (pEvdev->grabDevice) { if (grab && ioctl(pInfo->fd, EVIOCGRAB, (void *)1)) { xf86IDrvMsg(pInfo, X_WARNING, "Grab failed (%s)\n", strerror(errno)); return FALSE; } else if (ungrab && ioctl(pInfo->fd, EVIOCGRAB, (void *)0)) xf86IDrvMsg(pInfo, X_WARNING, "Release failed (%s)\n", strerror(errno)); } return TRUE; } static int EvdevProbe(InputInfoPtr pInfo) { int i, has_rel_axes, has_abs_axes, has_keys, num_buttons, has_scroll; int has_lmr; /* left middle right */ int ignore_abs = 0, ignore_rel = 0; EvdevPtr pEvdev = pInfo->private; int rc = 1; /* Trinary state for ignoring axes: - unset: do the normal thing. - TRUE: explicitly ignore them. - FALSE: unignore axes, use them at all cost if they're present. */ if (xf86FindOption(pInfo->options, "IgnoreRelativeAxes")) { if (xf86SetBoolOption(pInfo->options, "IgnoreRelativeAxes", FALSE)) ignore_rel = TRUE; else pEvdev->flags |= EVDEV_UNIGNORE_RELATIVE; } if (xf86FindOption(pInfo->options, "IgnoreAbsoluteAxes")) { if (xf86SetBoolOption(pInfo->options, "IgnoreAbsoluteAxes", FALSE)) ignore_abs = TRUE; else pEvdev->flags |= EVDEV_UNIGNORE_ABSOLUTE; } has_rel_axes = FALSE; has_abs_axes = FALSE; has_keys = FALSE; has_scroll = FALSE; has_lmr = FALSE; num_buttons = 0; /* count all buttons */ for (i = BTN_MISC; i < BTN_JOYSTICK; i++) { int mapping = 0; if (TestBit(i, pEvdev->key_bitmask)) { mapping = EvdevUtilButtonEventToButtonNumber(pEvdev, i); if (mapping > num_buttons) num_buttons = mapping; } } has_lmr = TestBit(BTN_LEFT, pEvdev->key_bitmask) || TestBit(BTN_MIDDLE, pEvdev->key_bitmask) || TestBit(BTN_RIGHT, pEvdev->key_bitmask); if (num_buttons) { pEvdev->flags |= EVDEV_BUTTON_EVENTS; pEvdev->num_buttons = num_buttons; xf86IDrvMsg(pInfo, X_PROBED, "Found %d mouse buttons\n", num_buttons); } for (i = 0; i < REL_MAX; i++) { if (TestBit(i, pEvdev->rel_bitmask)) { has_rel_axes = TRUE; break; } } if (has_rel_axes) { if (TestBit(REL_WHEEL, pEvdev->rel_bitmask) || TestBit(REL_HWHEEL, pEvdev->rel_bitmask) || TestBit(REL_DIAL, pEvdev->rel_bitmask)) { xf86IDrvMsg(pInfo, X_PROBED, "Found scroll wheel(s)\n"); has_scroll = TRUE; if (!num_buttons) xf86IDrvMsg(pInfo, X_INFO, "Forcing buttons for scroll wheel(s)\n"); num_buttons = (num_buttons < 3) ? 7 : num_buttons + 4; pEvdev->num_buttons = num_buttons; } if (!ignore_rel) { xf86IDrvMsg(pInfo, X_PROBED, "Found relative axes\n"); pEvdev->flags |= EVDEV_RELATIVE_EVENTS; if (TestBit(REL_X, pEvdev->rel_bitmask) && TestBit(REL_Y, pEvdev->rel_bitmask)) { xf86IDrvMsg(pInfo, X_PROBED, "Found x and y relative axes\n"); } } else { xf86IDrvMsg(pInfo, X_INFO, "Relative axes present but ignored.\n"); has_rel_axes = FALSE; } } for (i = 0; i < ABS_MAX; i++) { if (TestBit(i, pEvdev->abs_bitmask)) { has_abs_axes = TRUE; break; } } if (ignore_abs && has_abs_axes) { xf86IDrvMsg(pInfo, X_INFO, "Absolute axes present but ignored.\n"); has_abs_axes = FALSE; } else if (has_abs_axes) { xf86IDrvMsg(pInfo, X_PROBED, "Found absolute axes\n"); pEvdev->flags |= EVDEV_ABSOLUTE_EVENTS; if ((TestBit(ABS_X, pEvdev->abs_bitmask) && TestBit(ABS_Y, pEvdev->abs_bitmask))) { xf86IDrvMsg(pInfo, X_PROBED, "Found x and y absolute axes\n"); if (TestBit(BTN_TOOL_PEN, pEvdev->key_bitmask) || TestBit(BTN_STYLUS, pEvdev->key_bitmask) || TestBit(BTN_STYLUS2, pEvdev->key_bitmask)) { xf86IDrvMsg(pInfo, X_PROBED, "Found absolute tablet.\n"); pEvdev->flags |= EVDEV_TABLET; if (!pEvdev->num_buttons) { pEvdev->num_buttons = 7; /* LMR + scroll wheels */ pEvdev->flags |= EVDEV_BUTTON_EVENTS; } } else if (TestBit(ABS_PRESSURE, pEvdev->abs_bitmask) || TestBit(BTN_TOUCH, pEvdev->key_bitmask)) { if (has_lmr || TestBit(BTN_TOOL_FINGER, pEvdev->key_bitmask)) { xf86IDrvMsg(pInfo, X_PROBED, "Found absolute touchpad.\n"); pEvdev->flags |= EVDEV_TOUCHPAD; } else { xf86IDrvMsg(pInfo, X_PROBED, "Found absolute touchscreen\n"); pEvdev->flags |= EVDEV_TOUCHSCREEN; pEvdev->flags |= EVDEV_BUTTON_EVENTS; } } } } for (i = 0; i < BTN_MISC; i++) { if (TestBit(i, pEvdev->key_bitmask)) { xf86IDrvMsg(pInfo, X_PROBED, "Found keys\n"); pEvdev->flags |= EVDEV_KEYBOARD_EVENTS; has_keys = TRUE; break; } } if (has_rel_axes || has_abs_axes) { char *str; int num_calibration = 0, calibration[4] = { 0, 0, 0, 0 }; pEvdev->invert_x = xf86SetBoolOption(pInfo->options, "InvertX", FALSE); pEvdev->invert_y = xf86SetBoolOption(pInfo->options, "InvertY", FALSE); pEvdev->swap_axes = xf86SetBoolOption(pInfo->options, "SwapAxes", FALSE); str = xf86CheckStrOption(pInfo->options, "Calibration", NULL); if (str) { num_calibration = sscanf(str, "%d %d %d %d", &calibration[0], &calibration[1], &calibration[2], &calibration[3]); free(str); if (num_calibration == 4) EvdevSetCalibration(pInfo, num_calibration, calibration); else xf86IDrvMsg(pInfo, X_ERROR, "Insufficient calibration factors (%d). Ignoring calibration\n", num_calibration); } } if (has_rel_axes || has_abs_axes || num_buttons) { pInfo->flags |= XI86_SEND_DRAG_EVENTS; if (pEvdev->flags & EVDEV_TOUCHPAD) { xf86IDrvMsg(pInfo, X_INFO, "Configuring as touchpad\n"); pInfo->type_name = XI_TOUCHPAD; pEvdev->use_proximity = 0; } else if (pEvdev->flags & EVDEV_TABLET) { xf86IDrvMsg(pInfo, X_INFO, "Configuring as tablet\n"); pInfo->type_name = XI_TABLET; } else if (pEvdev->flags & EVDEV_TOUCHSCREEN) { xf86IDrvMsg(pInfo, X_INFO, "Configuring as touchscreen\n"); pInfo->type_name = XI_TOUCHSCREEN; } else { xf86IDrvMsg(pInfo, X_INFO, "Configuring as mouse\n"); pInfo->type_name = XI_MOUSE; } rc = 0; } if (has_keys) { xf86IDrvMsg(pInfo, X_INFO, "Configuring as keyboard\n"); pInfo->type_name = XI_KEYBOARD; rc = 0; } if (has_scroll && (has_rel_axes || has_abs_axes || num_buttons || has_keys)) { xf86IDrvMsg(pInfo, X_INFO, "Adding scrollwheel support\n"); pEvdev->flags |= EVDEV_BUTTON_EVENTS; pEvdev->flags |= EVDEV_RELATIVE_EVENTS; } if (rc) xf86IDrvMsg(pInfo, X_WARNING, "Don't know how to use device\n"); return rc; } static void EvdevSetCalibration(InputInfoPtr pInfo, int num_calibration, int calibration[4]) { EvdevPtr pEvdev = pInfo->private; if (num_calibration == 0) { pEvdev->flags &= ~EVDEV_CALIBRATED; pEvdev->calibration.min_x = 0; pEvdev->calibration.max_x = 0; pEvdev->calibration.min_y = 0; pEvdev->calibration.max_y = 0; } else if (num_calibration == 4) { pEvdev->flags |= EVDEV_CALIBRATED; pEvdev->calibration.min_x = calibration[0]; pEvdev->calibration.max_x = calibration[1]; pEvdev->calibration.min_y = calibration[2]; pEvdev->calibration.max_y = calibration[3]; } } static int EvdevOpenDevice(InputInfoPtr pInfo) { EvdevPtr pEvdev = pInfo->private; char *device = pEvdev->device; if (!device) { device = xf86CheckStrOption(pInfo->options, "Device", NULL); if (!device) { xf86IDrvMsg(pInfo, X_ERROR, "No device specified.\n"); return BadValue; } pEvdev->device = device; xf86IDrvMsg(pInfo, X_CONFIG, "Device: \"%s\"\n", device); } if (pInfo->fd < 0) { do { pInfo->fd = open(device, O_RDWR | O_NONBLOCK, 0); } while (pInfo->fd < 0 && errno == EINTR); if (pInfo->fd < 0) { xf86IDrvMsg(pInfo, X_ERROR, "Unable to open evdev device \"%s\".\n", device); return BadValue; } } /* Check major/minor of device node to avoid adding duplicate devices. */ pEvdev->min_maj = EvdevGetMajorMinor(pInfo); if (EvdevIsDuplicate(pInfo)) { xf86IDrvMsg(pInfo, X_WARNING, "device file is duplicate. Ignoring.\n"); close(pInfo->fd); return BadMatch; } return Success; } static void EvdevUnInit(InputDriverPtr drv, InputInfoPtr pInfo, int flags) { EvdevPtr pEvdev = pInfo ? pInfo->private : NULL; if (pEvdev) { /* Release strings allocated in EvdevAddKeyClass. */ XkbFreeRMLVOSet(&pEvdev->rmlvo, FALSE); /* Release string allocated in EvdevOpenDevice. */ free(pEvdev->device); pEvdev->device = NULL; } xf86DeleteInput(pInfo, flags); } static int EvdevPreInit(InputDriverPtr drv, InputInfoPtr pInfo, int flags) { EvdevPtr pEvdev; int rc = BadAlloc; if (!(pEvdev = calloc(sizeof(EvdevRec), 1))) goto error; pInfo->private = pEvdev; pInfo->type_name = "UNKNOWN"; pInfo->device_control = EvdevProc; pInfo->read_input = EvdevReadInput; pInfo->switch_mode = EvdevSwitchMode; rc = EvdevOpenDevice(pInfo); if (rc != Success) goto error; /* * We initialize pEvdev->in_proximity to 1 so that device that doesn't use * proximity will still report events. */ pEvdev->in_proximity = 1; pEvdev->use_proximity = 1; /* Grabbing the event device stops in-kernel event forwarding. In other words, it disables rfkill and the "Macintosh mouse button emulation". Note that this needs a server that sets the console to RAW mode. */ pEvdev->grabDevice = xf86CheckBoolOption(pInfo->options, "GrabDevice", 0); /* If grabDevice is set, ungrab immediately since we only want to grab * between DEVICE_ON and DEVICE_OFF. If we never get DEVICE_ON, don't * hold a grab. */ if (!EvdevGrabDevice(pInfo, 1, 1)) { xf86IDrvMsg(pInfo, X_WARNING, "Device may already be configured.\n"); rc = BadMatch; goto error; } EvdevInitButtonMapping(pInfo); if (EvdevCache(pInfo) || EvdevProbe(pInfo)) { rc = BadMatch; goto error; } EvdevAddDevice(pInfo); if (pEvdev->flags & EVDEV_BUTTON_EVENTS) { EvdevMBEmuPreInit(pInfo); Evdev3BEmuPreInit(pInfo); EvdevWheelEmuPreInit(pInfo); EvdevDragLockPreInit(pInfo); } return Success; error: if (pInfo->fd >= 0) close(pInfo->fd); return rc; } _X_EXPORT InputDriverRec EVDEV = { 1, "evdev", NULL, EvdevPreInit, EvdevUnInit, NULL, evdevDefaults }; static void EvdevUnplug(pointer p) { } static pointer EvdevPlug(pointer module, pointer options, int *errmaj, int *errmin) { xf86AddInputDriver(&EVDEV, module, 0); return module; } static XF86ModuleVersionInfo EvdevVersionRec = { "evdev", MODULEVENDORSTRING, MODINFOSTRING1, MODINFOSTRING2, XORG_VERSION_CURRENT, PACKAGE_VERSION_MAJOR, PACKAGE_VERSION_MINOR, PACKAGE_VERSION_PATCHLEVEL, ABI_CLASS_XINPUT, ABI_XINPUT_VERSION, MOD_CLASS_XINPUT, {0, 0, 0, 0} }; _X_EXPORT XF86ModuleData evdevModuleData = { &EvdevVersionRec, EvdevPlug, EvdevUnplug }; /* Return an index value for a given button event code * returns 0 on non-button event. */ unsigned int EvdevUtilButtonEventToButtonNumber(EvdevPtr pEvdev, int code) { switch (code) { /* Mouse buttons */ case BTN_LEFT: return 1; case BTN_MIDDLE: return 2; case BTN_RIGHT: return 3; case BTN_SIDE ... BTN_JOYSTICK - 1: return 8 + code - BTN_SIDE; /* Generic buttons */ case BTN_0 ... BTN_2: return 1 + code - BTN_0; case BTN_3 ... BTN_MOUSE - 1: return 8 + code - BTN_3; /* Tablet stylus buttons */ case BTN_TOUCH ... BTN_STYLUS2: return 1 + code - BTN_TOUCH; /* The rest */ default: /* Ignore */ return 0; } } /* Aligned with linux/input.h. Note that there are holes in the ABS_ range, these are simply replaced with MISC here */ static char* abs_labels[] = { AXIS_LABEL_PROP_ABS_X, /* 0x00 */ AXIS_LABEL_PROP_ABS_Y, /* 0x01 */ AXIS_LABEL_PROP_ABS_Z, /* 0x02 */ AXIS_LABEL_PROP_ABS_RX, /* 0x03 */ AXIS_LABEL_PROP_ABS_RY, /* 0x04 */ AXIS_LABEL_PROP_ABS_RZ, /* 0x05 */ AXIS_LABEL_PROP_ABS_THROTTLE, /* 0x06 */ AXIS_LABEL_PROP_ABS_RUDDER, /* 0x07 */ AXIS_LABEL_PROP_ABS_WHEEL, /* 0x08 */ AXIS_LABEL_PROP_ABS_GAS, /* 0x09 */ AXIS_LABEL_PROP_ABS_BRAKE, /* 0x0a */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_HAT0X, /* 0x10 */ AXIS_LABEL_PROP_ABS_HAT0Y, /* 0x11 */ AXIS_LABEL_PROP_ABS_HAT1X, /* 0x12 */ AXIS_LABEL_PROP_ABS_HAT1Y, /* 0x13 */ AXIS_LABEL_PROP_ABS_HAT2X, /* 0x14 */ AXIS_LABEL_PROP_ABS_HAT2Y, /* 0x15 */ AXIS_LABEL_PROP_ABS_HAT3X, /* 0x16 */ AXIS_LABEL_PROP_ABS_HAT3Y, /* 0x17 */ AXIS_LABEL_PROP_ABS_PRESSURE, /* 0x18 */ AXIS_LABEL_PROP_ABS_DISTANCE, /* 0x19 */ AXIS_LABEL_PROP_ABS_TILT_X, /* 0x1a */ AXIS_LABEL_PROP_ABS_TILT_Y, /* 0x1b */ AXIS_LABEL_PROP_ABS_TOOL_WIDTH, /* 0x1c */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_VOLUME /* 0x20 */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MISC, /* undefined */ AXIS_LABEL_PROP_ABS_MT_TOUCH_MAJOR, /* 0x30 */ AXIS_LABEL_PROP_ABS_MT_TOUCH_MINOR, /* 0x31 */ AXIS_LABEL_PROP_ABS_MT_WIDTH_MAJOR, /* 0x32 */ AXIS_LABEL_PROP_ABS_MT_WIDTH_MINOR, /* 0x33 */ AXIS_LABEL_PROP_ABS_MT_ORIENTATION, /* 0x34 */ AXIS_LABEL_PROP_ABS_MT_POSITION_X, /* 0x35 */ AXIS_LABEL_PROP_ABS_MT_POSITION_Y, /* 0x36 */ AXIS_LABEL_PROP_ABS_MT_TOOL_TYPE, /* 0x37 */ AXIS_LABEL_PROP_ABS_MT_BLOB_ID, /* 0x38 */ AXIS_LABEL_PROP_ABS_MT_TRACKING_ID, /* 0x39 */ AXIS_LABEL_PROP_ABS_MT_PRESSURE, /* 0x3a */ }; static char* rel_labels[] = { AXIS_LABEL_PROP_REL_X, AXIS_LABEL_PROP_REL_Y, AXIS_LABEL_PROP_REL_Z, AXIS_LABEL_PROP_REL_RX, AXIS_LABEL_PROP_REL_RY, AXIS_LABEL_PROP_REL_RZ, AXIS_LABEL_PROP_REL_HWHEEL, AXIS_LABEL_PROP_REL_DIAL, AXIS_LABEL_PROP_REL_WHEEL, AXIS_LABEL_PROP_REL_MISC }; static char* btn_labels[][16] = { { /* BTN_MISC group offset 0x100*/ BTN_LABEL_PROP_BTN_0, /* 0x00 */ BTN_LABEL_PROP_BTN_1, /* 0x01 */ BTN_LABEL_PROP_BTN_2, /* 0x02 */ BTN_LABEL_PROP_BTN_3, /* 0x03 */ BTN_LABEL_PROP_BTN_4, /* 0x04 */ BTN_LABEL_PROP_BTN_5, /* 0x05 */ BTN_LABEL_PROP_BTN_6, /* 0x06 */ BTN_LABEL_PROP_BTN_7, /* 0x07 */ BTN_LABEL_PROP_BTN_8, /* 0x08 */ BTN_LABEL_PROP_BTN_9 /* 0x09 */ }, { /* BTN_MOUSE group offset 0x110 */ BTN_LABEL_PROP_BTN_LEFT, /* 0x00 */ BTN_LABEL_PROP_BTN_RIGHT, /* 0x01 */ BTN_LABEL_PROP_BTN_MIDDLE, /* 0x02 */ BTN_LABEL_PROP_BTN_SIDE, /* 0x03 */ BTN_LABEL_PROP_BTN_EXTRA, /* 0x04 */ BTN_LABEL_PROP_BTN_FORWARD, /* 0x05 */ BTN_LABEL_PROP_BTN_BACK, /* 0x06 */ BTN_LABEL_PROP_BTN_TASK /* 0x07 */ }, { /* BTN_JOYSTICK group offset 0x120 */ BTN_LABEL_PROP_BTN_TRIGGER, /* 0x00 */ BTN_LABEL_PROP_BTN_THUMB, /* 0x01 */ BTN_LABEL_PROP_BTN_THUMB2, /* 0x02 */ BTN_LABEL_PROP_BTN_TOP, /* 0x03 */ BTN_LABEL_PROP_BTN_TOP2, /* 0x04 */ BTN_LABEL_PROP_BTN_PINKIE, /* 0x05 */ BTN_LABEL_PROP_BTN_BASE, /* 0x06 */ BTN_LABEL_PROP_BTN_BASE2, /* 0x07 */ BTN_LABEL_PROP_BTN_BASE3, /* 0x08 */ BTN_LABEL_PROP_BTN_BASE4, /* 0x09 */ BTN_LABEL_PROP_BTN_BASE5, /* 0x0a */ BTN_LABEL_PROP_BTN_BASE6, /* 0x0b */ NULL, NULL, NULL, BTN_LABEL_PROP_BTN_DEAD /* 0x0f */ }, { /* BTN_GAMEPAD group offset 0x130 */ BTN_LABEL_PROP_BTN_A, /* 0x00 */ BTN_LABEL_PROP_BTN_B, /* 0x01 */ BTN_LABEL_PROP_BTN_C, /* 0x02 */ BTN_LABEL_PROP_BTN_X, /* 0x03 */ BTN_LABEL_PROP_BTN_Y, /* 0x04 */ BTN_LABEL_PROP_BTN_Z, /* 0x05 */ BTN_LABEL_PROP_BTN_TL, /* 0x06 */ BTN_LABEL_PROP_BTN_TR, /* 0x07 */ BTN_LABEL_PROP_BTN_TL2, /* 0x08 */ BTN_LABEL_PROP_BTN_TR2, /* 0x09 */ BTN_LABEL_PROP_BTN_SELECT, /* 0x0a */ BTN_LABEL_PROP_BTN_START, /* 0x0b */ BTN_LABEL_PROP_BTN_MODE, /* 0x0c */ BTN_LABEL_PROP_BTN_THUMBL, /* 0x0d */ BTN_LABEL_PROP_BTN_THUMBR /* 0x0e */ }, { /* BTN_DIGI group offset 0x140 */ BTN_LABEL_PROP_BTN_TOOL_PEN, /* 0x00 */ BTN_LABEL_PROP_BTN_TOOL_RUBBER, /* 0x01 */ BTN_LABEL_PROP_BTN_TOOL_BRUSH, /* 0x02 */ BTN_LABEL_PROP_BTN_TOOL_PENCIL, /* 0x03 */ BTN_LABEL_PROP_BTN_TOOL_AIRBRUSH, /* 0x04 */ BTN_LABEL_PROP_BTN_TOOL_FINGER, /* 0x05 */ BTN_LABEL_PROP_BTN_TOOL_MOUSE, /* 0x06 */ BTN_LABEL_PROP_BTN_TOOL_LENS, /* 0x07 */ NULL, NULL, BTN_LABEL_PROP_BTN_TOUCH, /* 0x0a */ BTN_LABEL_PROP_BTN_STYLUS, /* 0x0b */ BTN_LABEL_PROP_BTN_STYLUS2, /* 0x0c */ BTN_LABEL_PROP_BTN_TOOL_DOUBLETAP, /* 0x0d */ BTN_LABEL_PROP_BTN_TOOL_TRIPLETAP /* 0x0e */ }, { /* BTN_WHEEL group offset 0x150 */ BTN_LABEL_PROP_BTN_GEAR_DOWN, /* 0x00 */ BTN_LABEL_PROP_BTN_GEAR_UP /* 0x01 */ } }; static void EvdevInitAxesLabels(EvdevPtr pEvdev, int natoms, Atom *atoms) { Atom atom; int axis; char **labels; int labels_len = 0; char *misc_label; if (pEvdev->flags & EVDEV_ABSOLUTE_EVENTS) { labels = abs_labels; labels_len = ArrayLength(abs_labels); misc_label = AXIS_LABEL_PROP_ABS_MISC; } else if ((pEvdev->flags & EVDEV_RELATIVE_EVENTS)) { labels = rel_labels; labels_len = ArrayLength(rel_labels); misc_label = AXIS_LABEL_PROP_REL_MISC; } memset(atoms, 0, natoms * sizeof(Atom)); /* Now fill the ones we know */ for (axis = 0; axis < labels_len; axis++) { if (pEvdev->axis_map[axis] == -1) continue; atom = XIGetKnownProperty(labels[axis]); if (!atom) /* Should not happen */ continue; atoms[pEvdev->axis_map[axis]] = atom; } } static void EvdevInitButtonLabels(EvdevPtr pEvdev, int natoms, Atom *atoms) { Atom atom; int button, bmap; /* First, make sure all atoms are initialized */ atom = XIGetKnownProperty(BTN_LABEL_PROP_BTN_UNKNOWN); for (button = 0; button < natoms; button++) atoms[button] = atom; for (button = BTN_MISC; button < BTN_JOYSTICK; button++) { if (TestBit(button, pEvdev->key_bitmask)) { int group = (button % 0x100)/16; int idx = button - ((button/16) * 16); if (!btn_labels[group][idx]) continue; atom = XIGetKnownProperty(btn_labels[group][idx]); if (!atom) continue; /* Props are 0-indexed, button numbers start with 1 */ bmap = EvdevUtilButtonEventToButtonNumber(pEvdev, button) - 1; atoms[bmap] = atom; } } /* wheel buttons, hardcoded anyway */ if (natoms > 3) atoms[3] = XIGetKnownProperty(BTN_LABEL_PROP_BTN_WHEEL_UP); if (natoms > 4) atoms[4] = XIGetKnownProperty(BTN_LABEL_PROP_BTN_WHEEL_DOWN); if (natoms > 5) atoms[5] = XIGetKnownProperty(BTN_LABEL_PROP_BTN_HWHEEL_LEFT); if (natoms > 6) atoms[6] = XIGetKnownProperty(BTN_LABEL_PROP_BTN_HWHEEL_RIGHT); } static void EvdevInitProperty(DeviceIntPtr dev) { InputInfoPtr pInfo = dev->public.devicePrivate; EvdevPtr pEvdev = pInfo->private; int rc; BOOL invert[2]; if (pEvdev->flags & (EVDEV_RELATIVE_EVENTS | EVDEV_ABSOLUTE_EVENTS)) { invert[0] = pEvdev->invert_x; invert[1] = pEvdev->invert_y; prop_invert = MakeAtom(EVDEV_PROP_INVERT_AXES, strlen(EVDEV_PROP_INVERT_AXES), TRUE); rc = XIChangeDeviceProperty(dev, prop_invert, XA_INTEGER, 8, PropModeReplace, 2, invert, FALSE); if (rc != Success) return; XISetDevicePropertyDeletable(dev, prop_invert, FALSE); prop_calibration = MakeAtom(EVDEV_PROP_CALIBRATION, strlen(EVDEV_PROP_CALIBRATION), TRUE); if (pEvdev->flags & EVDEV_CALIBRATED) { int calibration[4]; calibration[0] = pEvdev->calibration.min_x; calibration[1] = pEvdev->calibration.max_x; calibration[2] = pEvdev->calibration.min_y; calibration[3] = pEvdev->calibration.max_y; rc = XIChangeDeviceProperty(dev, prop_calibration, XA_INTEGER, 32, PropModeReplace, 4, calibration, FALSE); } else if (pEvdev->flags & EVDEV_ABSOLUTE_EVENTS) { rc = XIChangeDeviceProperty(dev, prop_calibration, XA_INTEGER, 32, PropModeReplace, 0, NULL, FALSE); } if (rc != Success) return; XISetDevicePropertyDeletable(dev, prop_calibration, FALSE); prop_swap = MakeAtom(EVDEV_PROP_SWAP_AXES, strlen(EVDEV_PROP_SWAP_AXES), TRUE); rc = XIChangeDeviceProperty(dev, prop_swap, XA_INTEGER, 8, PropModeReplace, 1, &pEvdev->swap_axes, FALSE); if (rc != Success) return; XISetDevicePropertyDeletable(dev, prop_swap, FALSE); /* Axis labelling */ if ((pEvdev->num_vals > 0) && (prop_axis_label = XIGetKnownProperty(AXIS_LABEL_PROP))) { Atom atoms[pEvdev->num_vals]; EvdevInitAxesLabels(pEvdev, pEvdev->num_vals, atoms); XIChangeDeviceProperty(dev, prop_axis_label, XA_ATOM, 32, PropModeReplace, pEvdev->num_vals, atoms, FALSE); XISetDevicePropertyDeletable(dev, prop_axis_label, FALSE); } /* Button labelling */ if ((pEvdev->num_buttons > 0) && (prop_btn_label = XIGetKnownProperty(BTN_LABEL_PROP))) { Atom atoms[EVDEV_MAXBUTTONS]; EvdevInitButtonLabels(pEvdev, EVDEV_MAXBUTTONS, atoms); XIChangeDeviceProperty(dev, prop_btn_label, XA_ATOM, 32, PropModeReplace, pEvdev->num_buttons, atoms, FALSE); XISetDevicePropertyDeletable(dev, prop_btn_label, FALSE); } } } static int EvdevSetProperty(DeviceIntPtr dev, Atom atom, XIPropertyValuePtr val, BOOL checkonly) { InputInfoPtr pInfo = dev->public.devicePrivate; EvdevPtr pEvdev = pInfo->private; if (atom == prop_invert) { BOOL* data; if (val->format != 8 || val->size != 2 || val->type != XA_INTEGER) return BadMatch; if (!checkonly) { data = (BOOL*)val->data; pEvdev->invert_x = data[0]; pEvdev->invert_y = data[1]; } } else if (atom == prop_calibration) { if (val->format != 32 || val->type != XA_INTEGER) return BadMatch; if (val->size != 4 && val->size != 0) return BadMatch; if (!checkonly) EvdevSetCalibration(pInfo, val->size, val->data); } else if (atom == prop_swap) { if (val->format != 8 || val->type != XA_INTEGER || val->size != 1) return BadMatch; if (!checkonly) pEvdev->swap_axes = *((BOOL*)val->data); } else if (atom == prop_axis_label || atom == prop_btn_label) return BadAccess; /* Axis/Button labels can't be changed */ return Success; }