xenocara/xserver/dix/eventconvert.c
2010-12-21 20:10:44 +00:00

729 lines
22 KiB
C

/*
* Copyright © 2009 Red Hat, Inc.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice (including the next
* paragraph) 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 AUTHORS OR COPYRIGHT HOLDERS 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.
*
*/
/**
* @file eventconvert.c
* This file contains event conversion routines from InternalEvent to the
* matching protocol events.
*/
#ifdef HAVE_DIX_CONFIG_H
#include <dix-config.h>
#endif
#include <stdint.h>
#include <X11/X.h>
#include <X11/extensions/XIproto.h>
#include <X11/extensions/XI2proto.h>
#include <X11/extensions/XI.h>
#include <X11/extensions/XI2.h>
#include "dix.h"
#include "inputstr.h"
#include "misc.h"
#include "eventstr.h"
#include "exglobals.h"
#include "eventconvert.h"
#include "xiquerydevice.h"
#include "xkbsrv.h"
static int countValuators(DeviceEvent *ev, int *first);
static int getValuatorEvents(DeviceEvent *ev, deviceValuator *xv);
static int eventToKeyButtonPointer(DeviceEvent *ev, xEvent **xi, int *count);
static int eventToDeviceChanged(DeviceChangedEvent *ev, xEvent **dcce);
static int eventToDeviceEvent(DeviceEvent *ev, xEvent **xi);
static int eventToRawEvent(RawDeviceEvent *ev, xEvent **xi);
/* Do not use, read comments below */
BOOL EventIsKeyRepeat(xEvent *event);
/**
* Hack to allow detectable autorepeat for core and XI1 events.
* The sequence number is unused until we send to the client and can be
* misused to store data. More or less, anyway.
*
* Do not use this. It may change any time without warning, eat your babies
* and piss on your cat.
*/
static void
EventSetKeyRepeatFlag(xEvent *event, BOOL on)
{
event->u.u.sequenceNumber = on;
}
/**
* Check if the event was marked as a repeat event before.
* NOTE: This is a nasty hack and should NOT be used by anyone else but
* TryClientEvents.
*/
BOOL
EventIsKeyRepeat(xEvent *event)
{
return !!event->u.u.sequenceNumber;
}
/**
* Convert the given event to the respective core event.
*
* Return values:
* Success ... core contains the matching core event.
* BadValue .. One or more values in the internal event are invalid.
* BadMatch .. The event has no core equivalent.
*
* @param[in] event The event to convert into a core event.
* @param[in] core The memory location to store the core event at.
* @return Success or the matching error code.
*/
int
EventToCore(InternalEvent *event, xEvent *core)
{
switch(event->any.type)
{
case ET_Motion:
{
DeviceEvent *e = &event->device_event;
/* Don't create core motion event if neither x nor y are
* present */
if (!BitIsOn(e->valuators.mask, 0) &&
!BitIsOn(e->valuators.mask, 1))
return BadMatch;
}
/* fallthrough */
case ET_ButtonPress:
case ET_ButtonRelease:
case ET_KeyPress:
case ET_KeyRelease:
{
DeviceEvent *e = &event->device_event;
if (e->detail.key > 0xFF)
return BadMatch;
memset(core, 0, sizeof(xEvent));
core->u.u.type = e->type - ET_KeyPress + KeyPress;
core->u.u.detail = e->detail.key & 0xFF;
core->u.keyButtonPointer.time = e->time;
core->u.keyButtonPointer.rootX = e->root_x;
core->u.keyButtonPointer.rootY = e->root_y;
core->u.keyButtonPointer.state = e->corestate;
core->u.keyButtonPointer.root = e->root;
EventSetKeyRepeatFlag(core, (e->type == ET_KeyPress && e->key_repeat));
}
break;
case ET_ProximityIn:
case ET_ProximityOut:
case ET_RawKeyPress:
case ET_RawKeyRelease:
case ET_RawButtonPress:
case ET_RawButtonRelease:
case ET_RawMotion:
return BadMatch;
default:
/* XXX: */
ErrorF("[dix] EventToCore: Not implemented yet \n");
return BadImplementation;
}
return Success;
}
/**
* Convert the given event to the respective XI 1.x event and store it in
* xi. xi is allocated on demand and must be freed by the caller.
* count returns the number of events in xi. If count is 1, and the type of
* xi is GenericEvent, then xi may be larger than 32 bytes.
*
* Return values:
* Success ... core contains the matching core event.
* BadValue .. One or more values in the internal event are invalid.
* BadMatch .. The event has no XI equivalent.
*
* @param[in] ev The event to convert into an XI 1 event.
* @param[out] xi Future memory location for the XI event.
* @param[out] count Number of elements in xi.
*
* @return Success or the error code.
*/
int
EventToXI(InternalEvent *ev, xEvent **xi, int *count)
{
switch (ev->any.type)
{
case ET_Motion:
case ET_ButtonPress:
case ET_ButtonRelease:
case ET_KeyPress:
case ET_KeyRelease:
case ET_ProximityIn:
case ET_ProximityOut:
return eventToKeyButtonPointer(&ev->device_event, xi, count);
case ET_DeviceChanged:
case ET_RawKeyPress:
case ET_RawKeyRelease:
case ET_RawButtonPress:
case ET_RawButtonRelease:
case ET_RawMotion:
*count = 0;
*xi = NULL;
return BadMatch;
default:
break;
}
ErrorF("[dix] EventToXI: Not implemented for %d \n", ev->any.type);
return BadImplementation;
}
/**
* Convert the given event to the respective XI 2.x event and store it in xi.
* xi is allocated on demand and must be freed by the caller.
*
* Return values:
* Success ... core contains the matching core event.
* BadValue .. One or more values in the internal event are invalid.
* BadMatch .. The event has no XI2 equivalent.
*
* @param[in] ev The event to convert into an XI2 event
* @param[out] xi Future memory location for the XI2 event.
*
* @return Success or the error code.
*/
int
EventToXI2(InternalEvent *ev, xEvent **xi)
{
switch (ev->any.type)
{
/* Enter/FocusIn are for grabs. We don't need an actual event, since
* the real events delivered are triggered elsewhere */
case ET_Enter:
case ET_FocusIn:
*xi = NULL;
return Success;
case ET_Motion:
case ET_ButtonPress:
case ET_ButtonRelease:
case ET_KeyPress:
case ET_KeyRelease:
return eventToDeviceEvent(&ev->device_event, xi);
case ET_ProximityIn:
case ET_ProximityOut:
*xi = NULL;
return BadMatch;
case ET_DeviceChanged:
return eventToDeviceChanged(&ev->changed_event, xi);
case ET_RawKeyPress:
case ET_RawKeyRelease:
case ET_RawButtonPress:
case ET_RawButtonRelease:
case ET_RawMotion:
return eventToRawEvent(&ev->raw_event, xi);
default:
break;
}
ErrorF("[dix] EventToXI2: Not implemented for %d \n", ev->any.type);
return BadImplementation;
}
static int
eventToKeyButtonPointer(DeviceEvent *ev, xEvent **xi, int *count)
{
int num_events;
int first; /* dummy */
deviceKeyButtonPointer *kbp;
/* Sorry, XI 1.x protocol restrictions. */
if (ev->detail.button > 0xFF || ev->deviceid >= 0x80)
{
*count = 0;
return Success;
}
num_events = (countValuators(ev, &first) + 5)/6; /* valuator ev */
num_events++; /* the actual event event */
*xi = calloc(num_events, sizeof(xEvent));
if (!(*xi))
{
return BadAlloc;
}
kbp = (deviceKeyButtonPointer*)(*xi);
kbp->detail = ev->detail.button;
kbp->time = ev->time;
kbp->root = ev->root;
kbp->root_x = ev->root_x;
kbp->root_y = ev->root_y;
kbp->deviceid = ev->deviceid;
kbp->state = ev->corestate;
EventSetKeyRepeatFlag((xEvent*)kbp,
(ev->type == ET_KeyPress && ev->key_repeat));
if (num_events > 1)
kbp->deviceid |= MORE_EVENTS;
switch(ev->type)
{
case ET_Motion: kbp->type = DeviceMotionNotify; break;
case ET_ButtonPress: kbp->type = DeviceButtonPress; break;
case ET_ButtonRelease: kbp->type = DeviceButtonRelease; break;
case ET_KeyPress: kbp->type = DeviceKeyPress; break;
case ET_KeyRelease: kbp->type = DeviceKeyRelease; break;
case ET_ProximityIn: kbp->type = ProximityIn; break;
case ET_ProximityOut: kbp->type = ProximityOut; break;
default:
break;
}
if (num_events > 1)
{
getValuatorEvents(ev, (deviceValuator*)(kbp + 1));
}
*count = num_events;
return Success;
}
/**
* Set first to the first valuator in the event ev and return the number of
* valuators from first to the last set valuator.
*/
static int
countValuators(DeviceEvent *ev, int *first)
{
int first_valuator = -1, last_valuator = -1, num_valuators = 0;
int i;
for (i = 0; i < sizeof(ev->valuators.mask) * 8; i++)
{
if (BitIsOn(ev->valuators.mask, i))
{
if (first_valuator == -1)
first_valuator = i;
last_valuator = i;
}
}
if (first_valuator != -1)
{
num_valuators = last_valuator - first_valuator + 1;
*first = first_valuator;
}
return num_valuators;
}
static int
getValuatorEvents(DeviceEvent *ev, deviceValuator *xv)
{
int i;
int state = 0;
int first_valuator, num_valuators;
num_valuators = countValuators(ev, &first_valuator);
if (num_valuators > 0)
{
DeviceIntPtr dev = NULL;
dixLookupDevice(&dev, ev->deviceid, serverClient, DixUseAccess);
/* State needs to be assembled BEFORE the device is updated. */
state = (dev && dev->key) ? XkbStateFieldFromRec(&dev->key->xkbInfo->state) : 0;
state |= (dev && dev->button) ? (dev->button->state) : 0;
}
/* FIXME: non-continuous valuator data in internal events*/
for (i = 0; i < num_valuators; i += 6, xv++) {
xv->type = DeviceValuator;
xv->first_valuator = first_valuator + i;
xv->num_valuators = ((num_valuators - i) > 6) ? 6 : (num_valuators - i);
xv->deviceid = ev->deviceid;
xv->device_state = state;
switch (xv->num_valuators) {
case 6:
xv->valuator5 = ev->valuators.data[xv->first_valuator + 5];
case 5:
xv->valuator4 = ev->valuators.data[xv->first_valuator + 4];
case 4:
xv->valuator3 = ev->valuators.data[xv->first_valuator + 3];
case 3:
xv->valuator2 = ev->valuators.data[xv->first_valuator + 2];
case 2:
xv->valuator1 = ev->valuators.data[xv->first_valuator + 1];
case 1:
xv->valuator0 = ev->valuators.data[xv->first_valuator + 0];
}
if (i + 6 < num_valuators)
xv->deviceid |= MORE_EVENTS;
}
return (num_valuators + 5) / 6;
}
static int
appendKeyInfo(DeviceChangedEvent *dce, xXIKeyInfo* info)
{
uint32_t *kc;
int i;
info->type = XIKeyClass;
info->num_keycodes = dce->keys.max_keycode - dce->keys.min_keycode + 1;
info->length = sizeof(xXIKeyInfo)/4 + info->num_keycodes;
info->sourceid = dce->sourceid;
kc = (uint32_t*)&info[1];
for (i = 0; i < info->num_keycodes; i++)
*kc++ = i + dce->keys.min_keycode;
return info->length * 4;
}
static int
appendButtonInfo(DeviceChangedEvent *dce, xXIButtonInfo *info)
{
unsigned char *bits;
int mask_len;
mask_len = bytes_to_int32(bits_to_bytes(dce->buttons.num_buttons));
info->type = XIButtonClass;
info->num_buttons = dce->buttons.num_buttons;
info->length = bytes_to_int32(sizeof(xXIButtonInfo)) +
info->num_buttons + mask_len;
info->sourceid = dce->sourceid;
bits = (unsigned char*)&info[1];
memset(bits, 0, mask_len * 4);
/* FIXME: is_down? */
bits += mask_len * 4;
memcpy(bits, dce->buttons.names, dce->buttons.num_buttons * sizeof(Atom));
return info->length * 4;
}
static int
appendValuatorInfo(DeviceChangedEvent *dce, xXIValuatorInfo *info, int axisnumber)
{
info->type = XIValuatorClass;
info->length = sizeof(xXIValuatorInfo)/4;
info->label = dce->valuators[axisnumber].name;
info->min.integral = dce->valuators[axisnumber].min;
info->min.frac = 0;
info->max.integral = dce->valuators[axisnumber].max;
info->max.frac = 0;
/* FIXME: value */
info->value.integral = 0;
info->value.frac = 0;
info->resolution = dce->valuators[axisnumber].resolution;
info->number = axisnumber;
info->mode = dce->valuators[axisnumber].mode; /* Server doesn't have per-axis mode yet */
info->sourceid = dce->sourceid;
return info->length * 4;
}
static int
eventToDeviceChanged(DeviceChangedEvent *dce, xEvent **xi)
{
xXIDeviceChangedEvent *dcce;
int len = sizeof(xXIDeviceChangedEvent);
int nkeys;
char *ptr;
if (dce->buttons.num_buttons)
{
len += sizeof(xXIButtonInfo);
len += dce->buttons.num_buttons * sizeof(Atom); /* button names */
len += pad_to_int32(bits_to_bytes(dce->buttons.num_buttons));
}
if (dce->num_valuators)
len += sizeof(xXIValuatorInfo) * dce->num_valuators;
nkeys = (dce->keys.max_keycode > 0) ?
dce->keys.max_keycode - dce->keys.min_keycode + 1 : 0;
if (nkeys > 0)
{
len += sizeof(xXIKeyInfo);
len += sizeof(CARD32) * nkeys; /* keycodes */
}
dcce = calloc(1, len);
if (!dcce)
{
ErrorF("[Xi] BadAlloc in SendDeviceChangedEvent.\n");
return BadAlloc;
}
dcce->type = GenericEvent;
dcce->extension = IReqCode;
dcce->evtype = XI_DeviceChanged;
dcce->time = dce->time;
dcce->deviceid = dce->deviceid;
dcce->sourceid = dce->sourceid;
dcce->reason = (dce->flags & DEVCHANGE_DEVICE_CHANGE) ? XIDeviceChange : XISlaveSwitch;
dcce->num_classes = 0;
dcce->length = bytes_to_int32(len - sizeof(xEvent));
ptr = (char*)&dcce[1];
if (dce->buttons.num_buttons)
{
dcce->num_classes++;
ptr += appendButtonInfo(dce, (xXIButtonInfo*)ptr);
}
if (nkeys)
{
dcce->num_classes++;
ptr += appendKeyInfo(dce, (xXIKeyInfo*)ptr);
}
if (dce->num_valuators)
{
int i;
dcce->num_classes += dce->num_valuators;
for (i = 0; i < dce->num_valuators; i++)
ptr += appendValuatorInfo(dce, (xXIValuatorInfo*)ptr, i);
}
*xi = (xEvent*)dcce;
return Success;
}
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;
}
static int
eventToDeviceEvent(DeviceEvent *ev, xEvent **xi)
{
int len = sizeof(xXIDeviceEvent);
xXIDeviceEvent *xde;
int i, btlen, vallen;
char *ptr;
FP3232 *axisval;
/* FIXME: this should just send the buttons we have, not MAX_BUTTONs. Same
* with MAX_VALUATORS below */
/* btlen is in 4 byte units */
btlen = bytes_to_int32(bits_to_bytes(MAX_BUTTONS));
len += btlen * 4; /* buttonmask len */
vallen = count_bits(ev->valuators.mask, sizeof(ev->valuators.mask)/sizeof(ev->valuators.mask[0]));
len += vallen * 2 * sizeof(uint32_t); /* axisvalues */
vallen = bytes_to_int32(bits_to_bytes(MAX_VALUATORS));
len += vallen * 4; /* valuators mask */
*xi = calloc(1, len);
xde = (xXIDeviceEvent*)*xi;
xde->type = GenericEvent;
xde->extension = IReqCode;
xde->evtype = GetXI2Type((InternalEvent*)ev);
xde->time = ev->time;
xde->length = bytes_to_int32(len - sizeof(xEvent));
xde->detail = ev->detail.button;
xde->root = ev->root;
xde->buttons_len = btlen;
xde->valuators_len = vallen;
xde->deviceid = ev->deviceid;
xde->sourceid = ev->sourceid;
xde->root_x = FP1616(ev->root_x, ev->root_x_frac);
xde->root_y = FP1616(ev->root_y, ev->root_y_frac);
if (ev->key_repeat)
xde->flags |= XIKeyRepeat;
xde->mods.base_mods = ev->mods.base;
xde->mods.latched_mods = ev->mods.latched;
xde->mods.locked_mods = ev->mods.locked;
xde->mods.effective_mods = ev->mods.effective;
xde->group.base_group = ev->group.base;
xde->group.latched_group = ev->group.latched;
xde->group.locked_group = ev->group.locked;
xde->group.effective_group = ev->group.effective;
ptr = (char*)&xde[1];
for (i = 0; i < sizeof(ev->buttons) * 8; i++)
{
if (BitIsOn(ev->buttons, i))
SetBit(ptr, i);
}
ptr += xde->buttons_len * 4;
axisval = (FP3232*)(ptr + xde->valuators_len * 4);
for (i = 0; i < sizeof(ev->valuators.mask) * 8; i++)
{
if (BitIsOn(ev->valuators.mask, i))
{
SetBit(ptr, i);
axisval->integral = ev->valuators.data[i];
axisval->frac = ev->valuators.data_frac[i];
axisval++;
}
}
return Success;
}
static int
eventToRawEvent(RawDeviceEvent *ev, xEvent **xi)
{
xXIRawEvent* raw;
int vallen, nvals;
int i, len = sizeof(xXIRawEvent);
char *ptr;
FP3232 *axisval;
nvals = count_bits(ev->valuators.mask, sizeof(ev->valuators.mask));
len += nvals * sizeof(FP3232) * 2; /* 8 byte per valuator, once
raw, once processed */
vallen = bytes_to_int32(bits_to_bytes(MAX_VALUATORS));
len += vallen * 4; /* valuators mask */
*xi = calloc(1, len);
raw = (xXIRawEvent*)*xi;
raw->type = GenericEvent;
raw->extension = IReqCode;
raw->evtype = GetXI2Type((InternalEvent*)ev);
raw->time = ev->time;
raw->length = bytes_to_int32(len - sizeof(xEvent));
raw->detail = ev->detail.button;
raw->deviceid = ev->deviceid;
raw->valuators_len = vallen;
ptr = (char*)&raw[1];
axisval = (FP3232*)(ptr + raw->valuators_len * 4);
for (i = 0; i < sizeof(ev->valuators.mask) * 8; i++)
{
if (BitIsOn(ev->valuators.mask, i))
{
SetBit(ptr, i);
axisval->integral = ev->valuators.data[i];
axisval->frac = ev->valuators.data_frac[i];
(axisval + nvals)->integral = ev->valuators.data_raw[i];
(axisval + nvals)->frac = ev->valuators.data_raw_frac[i];
axisval++;
}
}
return Success;
}
/**
* Return the corresponding core type for the given event or 0 if no core
* equivalent exists.
*/
int
GetCoreType(InternalEvent *event)
{
int coretype = 0;
switch(event->any.type)
{
case ET_Motion: coretype = MotionNotify; break;
case ET_ButtonPress: coretype = ButtonPress; break;
case ET_ButtonRelease: coretype = ButtonRelease; break;
case ET_KeyPress: coretype = KeyPress; break;
case ET_KeyRelease: coretype = KeyRelease; break;
default:
break;
}
return coretype;
}
/**
* Return the corresponding XI 1.x type for the given event or 0 if no
* equivalent exists.
*/
int
GetXIType(InternalEvent *event)
{
int xitype = 0;
switch(event->any.type)
{
case ET_Motion: xitype = DeviceMotionNotify; break;
case ET_ButtonPress: xitype = DeviceButtonPress; break;
case ET_ButtonRelease: xitype = DeviceButtonRelease; break;
case ET_KeyPress: xitype = DeviceKeyPress; break;
case ET_KeyRelease: xitype = DeviceKeyRelease; break;
case ET_ProximityIn: xitype = ProximityIn; break;
case ET_ProximityOut: xitype = ProximityOut; break;
default:
break;
}
return xitype;
}
/**
* Return the corresponding XI 2.x type for the given event or 0 if no
* equivalent exists.
*/
int
GetXI2Type(InternalEvent *event)
{
int xi2type = 0;
switch(event->any.type)
{
case ET_Motion: xi2type = XI_Motion; break;
case ET_ButtonPress: xi2type = XI_ButtonPress; break;
case ET_ButtonRelease: xi2type = XI_ButtonRelease; break;
case ET_KeyPress: xi2type = XI_KeyPress; break;
case ET_KeyRelease: xi2type = XI_KeyRelease; break;
case ET_Enter: xi2type = XI_Enter; break;
case ET_Leave: xi2type = XI_Leave; break;
case ET_Hierarchy: xi2type = XI_HierarchyChanged; break;
case ET_DeviceChanged: xi2type = XI_DeviceChanged; break;
case ET_RawKeyPress: xi2type = XI_RawKeyPress; break;
case ET_RawKeyRelease: xi2type = XI_RawKeyRelease; break;
case ET_RawButtonPress: xi2type = XI_RawButtonPress; break;
case ET_RawButtonRelease: xi2type = XI_RawButtonRelease; break;
case ET_RawMotion: xi2type = XI_RawMotion; break;
case ET_FocusIn: xi2type = XI_FocusIn; break;
case ET_FocusOut: xi2type = XI_FocusOut; break;
default:
break;
}
return xi2type;
}