diff options
Diffstat (limited to 'xorg-server/dix')
-rw-r--r-- | xorg-server/dix/devices.c | 6 | ||||
-rw-r--r-- | xorg-server/dix/ptrveloc.c | 2372 |
2 files changed, 1202 insertions, 1176 deletions
diff --git a/xorg-server/dix/devices.c b/xorg-server/dix/devices.c index 6329d2810..92b95ed69 100644 --- a/xorg-server/dix/devices.c +++ b/xorg-server/dix/devices.c @@ -842,6 +842,9 @@ CloseDevice(DeviceIntPtr dev) if(dev->valuator && dev->valuator->accelScheme.AccelCleanupProc) dev->valuator->accelScheme.AccelCleanupProc(dev); + while (dev->xkb_interest) + XkbRemoveResourceClient((DevicePtr)dev,dev->xkb_interest->resource); + xfree(dev->name); classes = (ClassesPtr)&dev->key; @@ -853,9 +856,6 @@ CloseDevice(DeviceIntPtr dev) FreeAllDeviceClasses(classes); } - while (dev->xkb_interest) - XkbRemoveResourceClient((DevicePtr)dev,dev->xkb_interest->resource); - if (DevHasCursor(dev) && dev->spriteInfo->sprite) { xfree(dev->spriteInfo->sprite->spriteTrace); xfree(dev->spriteInfo->sprite); diff --git a/xorg-server/dix/ptrveloc.c b/xorg-server/dix/ptrveloc.c index 1aa0849aa..b9ece2159 100644 --- a/xorg-server/dix/ptrveloc.c +++ b/xorg-server/dix/ptrveloc.c @@ -1,1173 +1,1199 @@ -/* - * - * Copyright © 2006-2009 Simon Thum simon dot thum at gmx dot de - * - * 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. - */ - -#ifdef HAVE_DIX_CONFIG_H -#include <dix-config.h> -#endif - -#ifdef _MSC_VER -#define _USE_MATH_DEFINES -#endif - -#include <math.h> -#include <ptrveloc.h> -#include <exevents.h> -#include <X11/Xatom.h> - -#include <xserver-properties.h> - -/***************************************************************************** - * Predictable pointer acceleration - * - * 2006-2009 by Simon Thum (simon [dot] thum [at] gmx de) - * - * Serves 3 complementary functions: - * 1) provide a sophisticated ballistic velocity estimate to improve - * the relation between velocity (of the device) and acceleration - * 2) make arbitrary acceleration profiles possible - * 3) decelerate by two means (constant and adaptive) if enabled - * - * Important concepts are the - * - * - Scheme - * which selects the basic algorithm - * (see devices.c/InitPointerAccelerationScheme) - * - Profile - * which returns an acceleration - * for a given velocity - * - * The profile can be selected by the user at runtime. - * The classic profile is intended to cleanly perform old-style - * function selection (threshold =/!= 0) - * - ****************************************************************************/ - -#ifdef _MSC_VER -#define inline __inline -#define lrintf(val) ((int)val) -#endif - -/* fwds */ -int -SetAccelerationProfile(DeviceVelocityPtr vel, int profile_num); -static float -SimpleSmoothProfile(DeviceIntPtr dev, DeviceVelocityPtr vel, float velocity, - float threshold, float acc); -static PointerAccelerationProfileFunc -GetAccelerationProfile(DeviceVelocityPtr vel, int profile_num); - -/*#define PTRACCEL_DEBUGGING*/ - -#ifdef PTRACCEL_DEBUGGING -#define DebugAccelF ErrorF -#else -#define DebugAccelF(...) /* */ -#endif - -/******************************** - * Init/Uninit - *******************************/ - -/* some int which is not a profile number */ -#define PROFILE_UNINITIALIZE (-100) - -/* number of properties for predictable acceleration */ -#define NPROPS_PREDICTABLE_ACCEL 4 - -/** - * Init struct so it should match the average case - */ -void -InitVelocityData(DeviceVelocityPtr vel) -{ - memset(vel, 0, sizeof(DeviceVelocityRec)); - - vel->corr_mul = 10.0; /* dots per 10 milisecond should be usable */ - vel->const_acceleration = 1.0; /* no acceleration/deceleration */ - vel->reset_time = 300; - vel->use_softening = 1; - vel->min_acceleration = 1.0; /* don't decelerate */ - vel->max_rel_diff = 0.2; - vel->max_diff = 1.0; - vel->initial_range = 2; - vel->average_accel = TRUE; - SetAccelerationProfile(vel, AccelProfileClassic); - InitTrackers(vel, 16); -} - - -/** - * Clean up - */ -void -FreeVelocityData(DeviceVelocityPtr vel){ - xfree(vel->tracker); - SetAccelerationProfile(vel, PROFILE_UNINITIALIZE); -} - - -/* - * dix uninit helper, called through scheme - */ -void -AccelerationDefaultCleanup(DeviceIntPtr dev) -{ - /*sanity check*/ - if( dev->valuator->accelScheme.AccelSchemeProc == acceleratePointerPredictable - && dev->valuator->accelScheme.accelData != NULL){ - dev->valuator->accelScheme.AccelSchemeProc = NULL; - FreeVelocityData(dev->valuator->accelScheme.accelData); - xfree(dev->valuator->accelScheme.accelData); - dev->valuator->accelScheme.accelData = NULL; - DeletePredictableAccelerationProperties(dev); - } -} - - -/************************* - * Input property support - ************************/ - -/** - * choose profile - */ -static int -AccelSetProfileProperty(DeviceIntPtr dev, Atom atom, - XIPropertyValuePtr val, BOOL checkOnly) -{ - DeviceVelocityPtr vel; - int profile, *ptr = &profile; - int rc; - int nelem = 1; - - if (atom != XIGetKnownProperty(ACCEL_PROP_PROFILE_NUMBER)) - return Success; - - vel = GetDevicePredictableAccelData(dev); - if (!vel) - return BadValue; - rc = XIPropToInt(val, &nelem, &ptr); - - if(checkOnly) - { - if (rc) - return rc; - - if (GetAccelerationProfile(vel, profile) == NULL) - return BadValue; - } else - SetAccelerationProfile(vel, profile); - - return Success; -} - -static long -AccelInitProfileProperty(DeviceIntPtr dev, DeviceVelocityPtr vel) -{ - int profile = vel->statistics.profile_number; - Atom prop_profile_number = XIGetKnownProperty(ACCEL_PROP_PROFILE_NUMBER); - - XIChangeDeviceProperty(dev, prop_profile_number, XA_INTEGER, 32, - PropModeReplace, 1, &profile, FALSE); - XISetDevicePropertyDeletable(dev, prop_profile_number, FALSE); - return XIRegisterPropertyHandler(dev, AccelSetProfileProperty, NULL, NULL); -} - -/** - * constant deceleration - */ -static int -AccelSetDecelProperty(DeviceIntPtr dev, Atom atom, - XIPropertyValuePtr val, BOOL checkOnly) -{ - DeviceVelocityPtr vel; - float v, *ptr = &v; - int rc; - int nelem = 1; - - if (atom != XIGetKnownProperty(ACCEL_PROP_CONSTANT_DECELERATION)) - return Success; - - vel = GetDevicePredictableAccelData(dev); - if (!vel) - return BadValue; - rc = XIPropToFloat(val, &nelem, &ptr); - - if(checkOnly) - { - if (rc) - return rc; - return (v >= 1.0f) ? Success : BadValue; - } - - if(v >= 1.0f) - vel->const_acceleration = 1/v; - - return Success; -} - -static long -AccelInitDecelProperty(DeviceIntPtr dev, DeviceVelocityPtr vel) -{ - float fval = 1.0/vel->const_acceleration; - Atom prop_const_decel = XIGetKnownProperty(ACCEL_PROP_CONSTANT_DECELERATION); - XIChangeDeviceProperty(dev, prop_const_decel, - XIGetKnownProperty(XATOM_FLOAT), 32, - PropModeReplace, 1, &fval, FALSE); - XISetDevicePropertyDeletable(dev, prop_const_decel, FALSE); - return XIRegisterPropertyHandler(dev, AccelSetDecelProperty, NULL, NULL); -} - - -/** - * adaptive deceleration - */ -static int -AccelSetAdaptDecelProperty(DeviceIntPtr dev, Atom atom, - XIPropertyValuePtr val, BOOL checkOnly) -{ - DeviceVelocityPtr veloc; - float v, *ptr = &v; - int rc; - int nelem = 1; - - if (atom != XIGetKnownProperty(ACCEL_PROP_ADAPTIVE_DECELERATION)) - return Success; - - veloc = GetDevicePredictableAccelData(dev); - if (!veloc) - return BadValue; - rc = XIPropToFloat(val, &nelem, &ptr); - - if(checkOnly) - { - if (rc) - return rc; - return (v >= 1.0f) ? Success : BadValue; - } - - if(v >= 1.0f) - veloc->min_acceleration = 1/v; - - return Success; -} - -static long -AccelInitAdaptDecelProperty(DeviceIntPtr dev, DeviceVelocityPtr vel) -{ - float fval = 1.0/vel->min_acceleration; - Atom prop_adapt_decel = XIGetKnownProperty(ACCEL_PROP_ADAPTIVE_DECELERATION); - - XIChangeDeviceProperty(dev, prop_adapt_decel, XIGetKnownProperty(XATOM_FLOAT), 32, - PropModeReplace, 1, &fval, FALSE); - XISetDevicePropertyDeletable(dev, prop_adapt_decel, FALSE); - return XIRegisterPropertyHandler(dev, AccelSetAdaptDecelProperty, NULL, NULL); -} - - -/** - * velocity scaling - */ -static int -AccelSetScaleProperty(DeviceIntPtr dev, Atom atom, - XIPropertyValuePtr val, BOOL checkOnly) -{ - DeviceVelocityPtr vel; - float v, *ptr = &v; - int rc; - int nelem = 1; - - if (atom != XIGetKnownProperty(ACCEL_PROP_VELOCITY_SCALING)) - return Success; - - vel = GetDevicePredictableAccelData(dev); - if (!vel) - return BadValue; - rc = XIPropToFloat(val, &nelem, &ptr); - - if (checkOnly) - { - if (rc) - return rc; - - return (v > 0) ? Success : BadValue; - } - - if(v > 0) - vel->corr_mul = v; - - return Success; -} - -static long -AccelInitScaleProperty(DeviceIntPtr dev, DeviceVelocityPtr vel) -{ - float fval = vel->corr_mul; - Atom prop_velo_scale = XIGetKnownProperty(ACCEL_PROP_VELOCITY_SCALING); - - XIChangeDeviceProperty(dev, prop_velo_scale, XIGetKnownProperty(XATOM_FLOAT), 32, - PropModeReplace, 1, &fval, FALSE); - XISetDevicePropertyDeletable(dev, prop_velo_scale, FALSE); - return XIRegisterPropertyHandler(dev, AccelSetScaleProperty, NULL, NULL); -} - -static int AccelPropHandlerPrivateKeyIndex; -DevPrivateKey AccelPropHandlerPrivateKey = &AccelPropHandlerPrivateKeyIndex; - -BOOL -InitializePredictableAccelerationProperties(DeviceIntPtr dev) -{ - DeviceVelocityPtr vel = GetDevicePredictableAccelData(dev); - long *prop_handlers; - - if(!vel) - return FALSE; - prop_handlers = xalloc(NPROPS_PREDICTABLE_ACCEL * sizeof(long)); - - prop_handlers[0] = AccelInitProfileProperty(dev, vel); - prop_handlers[1] = AccelInitDecelProperty(dev, vel); - prop_handlers[2] = AccelInitAdaptDecelProperty(dev, vel); - prop_handlers[3] = AccelInitScaleProperty(dev, vel); - - dixSetPrivate(&dev->devPrivates, AccelPropHandlerPrivateKey, - prop_handlers); - - return TRUE; -} - -BOOL -DeletePredictableAccelerationProperties(DeviceIntPtr dev) -{ - Atom prop; - long *prop_handlers; - int i; - - prop = XIGetKnownProperty(ACCEL_PROP_VELOCITY_SCALING); - XIDeleteDeviceProperty(dev, prop, FALSE); - prop = XIGetKnownProperty(ACCEL_PROP_ADAPTIVE_DECELERATION); - XIDeleteDeviceProperty(dev, prop, FALSE); - prop = XIGetKnownProperty(ACCEL_PROP_CONSTANT_DECELERATION); - XIDeleteDeviceProperty(dev, prop, FALSE); - prop = XIGetKnownProperty(ACCEL_PROP_PROFILE_NUMBER); - XIDeleteDeviceProperty(dev, prop, FALSE); - - prop_handlers = dixLookupPrivate(&dev->devPrivates, - AccelPropHandlerPrivateKey); - dixSetPrivate(&dev->devPrivates, AccelPropHandlerPrivateKey, NULL); - - for (i = 0; prop_handlers && i < NPROPS_PREDICTABLE_ACCEL; i++) - XIUnregisterPropertyHandler(dev, prop_handlers[i]); - xfree(prop_handlers); - - return TRUE; -} - -/********************* - * Tracking logic - ********************/ - -void -InitTrackers(DeviceVelocityPtr vel, int ntracker) -{ - if(ntracker < 1){ - ErrorF("(dix ptracc) invalid number of trackers\n"); - return; - } - xfree(vel->tracker); - vel->tracker = (MotionTrackerPtr)xalloc(ntracker * sizeof(MotionTracker)); - memset(vel->tracker, 0, ntracker * sizeof(MotionTracker)); - vel->num_tracker = ntracker; -} - -/** - * return a bit field of possible directions. - * 0 = N, 2 = E, 4 = S, 6 = W, in-between is as you guess. - * There's no reason against widening to more precise directions (<45 degrees), - * should it not perform well. All this is needed for is sort out non-linear - * motion, so precision isn't paramount. However, one should not flag direction - * too narrow, since it would then cut the linear segment to zero size way too - * often. - */ -static int -DoGetDirection(int dx, int dy){ - float r; - int i1, i2; - /* on insignificant mickeys, flag 135 degrees */ - if(abs(dx) < 2 && abs(dy < 2)){ - /* first check diagonal cases */ - if(dx > 0 && dy > 0) - return 4+8+16; - if(dx > 0 && dy < 0) - return 1+2+4; - if(dx < 0 && dy < 0) - return 1+128+64; - if(dx < 0 && dy > 0) - return 16+32+64; - /* check axis-aligned directions */ - if(dx > 0) - return 2+4+8; /*E*/ - if(dx < 0) - return 128+64+32; /*W*/ - if(dy > 0) - return 32+16+8; /*S*/ - if(dy < 0) - return 128+1+2; /*N*/ - return 255; /* shouldn't happen */ - } - /* else, compute angle and set appropriate flags */ -#ifdef _ISOC99_SOURCE - r = atan2f(dy, dx); -#else - r = atan2(dy, dx); -#endif - /* find direction. We avoid r to become negative, - * since C has no well-defined modulo for such cases. */ - r = (r+(M_PI*2.5))/(M_PI/4); - /* this intends to flag 2 directions (90 degrees), - * except on very well-aligned mickeys. */ - i1 = (int)(r+0.1) % 8; - i2 = (int)(r+0.9) % 8; - if(i1 < 0 || i1 > 7 || i2 < 0 || i2 > 7) - return 255; /* shouldn't happen */ - return 1 << i1 | 1 << i2; -} - -#define DIRECTION_CACHE_RANGE 5 -#define DIRECTION_CACHE_SIZE (DIRECTION_CACHE_RANGE*2+1) - -/* cache DoGetDirection(). */ -static int -GetDirection(int dx, int dy){ - static int cache[DIRECTION_CACHE_SIZE][DIRECTION_CACHE_SIZE]; - int i; - if (abs(dx) <= DIRECTION_CACHE_RANGE && - abs(dy) <= DIRECTION_CACHE_RANGE) { - /* cacheable */ - i = cache[DIRECTION_CACHE_RANGE+dx][DIRECTION_CACHE_RANGE+dy]; - if(i != 0){ - return i; - }else{ - i = DoGetDirection(dx, dy); - cache[DIRECTION_CACHE_RANGE+dx][DIRECTION_CACHE_RANGE+dy] = i; - return i; - } - }else{ - /* non-cacheable */ - return DoGetDirection(dx, dy); - } -} - -#undef DIRECTION_CACHE_RANGE -#undef DIRECTION_CACHE_SIZE - - -/* convert offset (age) to array index */ -#define TRACKER_INDEX(s, d) (((s)->num_tracker + (s)->cur_tracker - (d)) % (s)->num_tracker) - -static inline void -FeedTrackers(DeviceVelocityPtr vel, int dx, int dy, int cur_t) -{ - int n; - for(n = 0; n < vel->num_tracker; n++){ - vel->tracker[n].dx += dx; - vel->tracker[n].dy += dy; - } - n = (vel->cur_tracker + 1) % vel->num_tracker; - vel->tracker[n].dx = 0; - vel->tracker[n].dy = 0; - vel->tracker[n].time = cur_t; - vel->tracker[n].dir = GetDirection(dx, dy); - DebugAccelF("(dix prtacc) motion [dx: %i dy: %i dir:%i diff: %i]\n", - dx, dy, vel->tracker[n].dir, - cur_t - vel->tracker[vel->cur_tracker].time); - vel->cur_tracker = n; -} - -/** - * calc velocity for given tracker, with - * velocity scaling. - * This assumes linear motion. - */ -static float -CalcTracker(DeviceVelocityPtr vel, int offset, int cur_t){ - int index = TRACKER_INDEX(vel, offset); - float dist = sqrt( vel->tracker[index].dx * vel->tracker[index].dx - + vel->tracker[index].dy * vel->tracker[index].dy); - int dtime = cur_t - vel->tracker[index].time; - if(dtime > 0) - return (dist / dtime); - else - return 0;/* synonymous for NaN, since we're not C99 */ -} - -/* find the most plausible velocity. That is, the most distant - * (in time) tracker which isn't too old, beyond a linear partition, - * or simply too much off initial velocity. - * - * May return 0. - */ -static float -QueryTrackers(DeviceVelocityPtr vel, int cur_t){ - int n, offset, dir = 255, i = -1, age_ms; - /* initial velocity: a low-offset, valid velocity */ - float iveloc = 0, res = 0, tmp, vdiff; - float vfac = vel->corr_mul * vel->const_acceleration; /* premultiply */ - /* loop from current to older data */ - for(offset = 1; offset < vel->num_tracker; offset++){ - n = TRACKER_INDEX(vel, offset); - - age_ms = cur_t - vel->tracker[n].time; - - /* bail out if data is too old and protect from overrun */ - if (age_ms >= vel->reset_time || age_ms < 0) { - DebugAccelF("(dix prtacc) query: tracker too old\n"); - break; - } - - /* - * this heuristic avoids using the linear-motion velocity formula - * in CalcTracker() on motion that isn't exactly linear. So to get - * even more precision we could subdivide as a final step, so possible - * non-linearities are accounted for. - */ - dir &= vel->tracker[n].dir; - if(dir == 0){ - DebugAccelF("(dix prtacc) query: no longer linear\n"); - /* instead of breaking it we might also inspect the partition after, - * but actual improvement with this is probably rare. */ - break; - } - - tmp = CalcTracker(vel, offset, cur_t) * vfac; - - if ((iveloc == 0 || offset <= vel->initial_range) && tmp != 0) { - /* set initial velocity and result */ - res = iveloc = tmp; - i = offset; - } else if (iveloc != 0 && tmp != 0) { - vdiff = fabs(iveloc - tmp); - if (vdiff <= vel->max_diff || - vdiff/(iveloc + tmp) < vel->max_rel_diff) { - /* we're in range with the initial velocity, - * so this result is likely better - * (it contains more information). */ - res = tmp; - i = offset; - }else{ - /* we're not in range, quit - it won't get better. */ - DebugAccelF("(dix prtacc) query: tracker too different:" - " old %2.2f initial %2.2f diff: %2.2f\n", - tmp, iveloc, vdiff); - break; - } - } - } - if(offset == vel->num_tracker){ - DebugAccelF("(dix prtacc) query: last tracker in effect\n"); - i = vel->num_tracker-1; - } - if(i>=0){ - n = TRACKER_INDEX(vel, i); - DebugAccelF("(dix prtacc) result: offset %i [dx: %i dy: %i diff: %i]\n", - i, - vel->tracker[n].dx, - vel->tracker[n].dy, - cur_t - vel->tracker[n].time); - } - return res; -} - -#undef TRACKER_INDEX - -/** - * Perform velocity approximation based on 2D 'mickeys' (mouse motion delta). - * return true if non-visible state reset is suggested - */ -short -ProcessVelocityData2D( - DeviceVelocityPtr vel, - int dx, - int dy, - int time) -{ - float velocity; - - vel->last_velocity = vel->velocity; - - FeedTrackers(vel, dx, dy, time); - - velocity = QueryTrackers(vel, time); - - vel->velocity = velocity; - return velocity == 0; -} - -/** - * this flattens significant ( > 1) mickeys a little bit for more steady - * constant-velocity response - */ -static inline float -ApplySimpleSoftening(int od, int d) -{ - float res = d; - if (d <= 1 && d >= -1) - return res; - if (d > od) - res -= 0.5; - else if (d < od) - res += 0.5; - return res; -} - - -static void -ApplySofteningAndConstantDeceleration( - DeviceVelocityPtr vel, - int dx, - int dy, - float* fdx, - float* fdy, - short do_soften) -{ - if (do_soften && vel->use_softening) { - *fdx = ApplySimpleSoftening(vel->last_dx, dx); - *fdy = ApplySimpleSoftening(vel->last_dy, dy); - } else { - *fdx = dx; - *fdy = dy; - } - - *fdx *= vel->const_acceleration; - *fdy *= vel->const_acceleration; -} - -/* - * compute the acceleration for given velocity and enforce min_acceleartion - */ -float -BasicComputeAcceleration( - DeviceIntPtr dev, - DeviceVelocityPtr vel, - float velocity, - float threshold, - float acc){ - - float result; - result = vel->Profile(dev, vel, velocity, threshold, acc); - - /* enforce min_acceleration */ - if (result < vel->min_acceleration) - result = vel->min_acceleration; - return result; -} - -/** - * Compute acceleration. Takes into account averaging, nv-reset, etc. - */ -static float -ComputeAcceleration( - DeviceIntPtr dev, - DeviceVelocityPtr vel, - float threshold, - float acc){ - float res; - - if(vel->velocity <= 0){ - DebugAccelF("(dix ptracc) profile skipped\n"); - /* - * If we have no idea about device velocity, don't pretend it. - */ - return 1; - } - - if(vel->average_accel && vel->velocity != vel->last_velocity){ - /* use simpson's rule to average acceleration between - * current and previous velocity. - * Though being the more natural choice, it causes a minor delay - * in comparison, so it can be disabled. */ - res = BasicComputeAcceleration( - dev, vel, vel->velocity, threshold, acc); - res += BasicComputeAcceleration( - dev, vel, vel->last_velocity, threshold, acc); - res += 4.0f * BasicComputeAcceleration(dev, vel, - (vel->last_velocity + vel->velocity) / 2, - threshold, acc); - res /= 6.0f; - DebugAccelF("(dix ptracc) profile average [%.2f ... %.2f] is %.3f\n", - vel->velocity, vel->last_velocity, res); - return res; - }else{ - res = BasicComputeAcceleration(dev, vel, - vel->velocity, threshold, acc); - DebugAccelF("(dix ptracc) profile sample [%.2f] is %.3f\n", - vel->velocity, res); - return res; - } -} - - -/***************************************** - * Acceleration functions and profiles - ****************************************/ - -/** - * Polynomial function similar previous one, but with f(1) = 1 - */ -static float -PolynomialAccelerationProfile( - DeviceIntPtr dev, - DeviceVelocityPtr vel, - float velocity, - float ignored, - float acc) -{ - return pow(velocity, (acc - 1.0) * 0.5); -} - - -/** - * returns acceleration for velocity. - * This profile selects the two functions like the old scheme did - */ -static float -ClassicProfile( - DeviceIntPtr dev, - DeviceVelocityPtr vel, - float velocity, - float threshold, - float acc) -{ - if (threshold > 0) { - return SimpleSmoothProfile (dev, - vel, - velocity, - threshold, - acc); - } else { - return PolynomialAccelerationProfile (dev, - vel, - velocity, - 0, - acc); - } -} - - -/** - * Power profile - * This has a completely smooth transition curve, i.e. no jumps in the - * derivatives. - * - * This has the expense of overall response dependency on min-acceleration. - * In effect, min_acceleration mimics const_acceleration in this profile. - */ -static float -PowerProfile( - DeviceIntPtr dev, - DeviceVelocityPtr vel, - float velocity, - float threshold, - float acc) -{ - float vel_dist; - - acc = (acc-1.0) * 0.1f + 1.0; /* without this, acc of 2 is unuseable */ - - if (velocity <= threshold) - return vel->min_acceleration; - vel_dist = velocity - threshold; - return (pow(acc, vel_dist)) * vel->min_acceleration; -} - - -/** - * just a smooth function in [0..1] -> [0..1] - * - point symmetry at 0.5 - * - f'(0) = f'(1) = 0 - * - starts faster than a sinoid - * - smoothness C1 (Cinf if you dare to ignore endpoints) - */ -static inline float -CalcPenumbralGradient(float x){ - x *= 2.0f; - x -= 1.0f; - return 0.5f + (x * sqrt(1.0f - x*x) + asin(x))/M_PI; -} - - -/** - * acceleration function similar to classic accelerated/unaccelerated, - * but with smooth transition in between (and towards zero for adaptive dec.). - */ -static float -SimpleSmoothProfile( - DeviceIntPtr dev, - DeviceVelocityPtr vel, - float velocity, - float threshold, - float acc) -{ - if(velocity < 1.0f) - return CalcPenumbralGradient(0.5 + velocity*0.5) * 2.0f - 1.0f; - if(threshold < 1.0f) - threshold = 1.0f; - if (velocity <= threshold) - return 1; - velocity /= threshold; - if (velocity >= acc) - return acc; - else - return 1.0f + (CalcPenumbralGradient(velocity/acc) * (acc - 1.0f)); -} - - -/** - * This profile uses the first half of the penumbral gradient as a start - * and then scales linearly. - */ -static float -SmoothLinearProfile( - DeviceIntPtr dev, - DeviceVelocityPtr vel, - float velocity, - float threshold, - float acc) -{ - float res, nv; - - if(acc > 1.0f) - acc -= 1.0f; /*this is so acc = 1 is no acceleration */ - else - return 1.0f; - - nv = (velocity - threshold) * acc * 0.5f; - - if(nv < 0){ - res = 0; - }else if(nv < 2){ - res = CalcPenumbralGradient(nv*0.25f)*2.0f; - }else{ - nv -= 2.0f; - res = nv * 2.0f / M_PI /* steepness of gradient at 0.5 */ - + 1.0f; /* gradient crosses 2|1 */ - } - res += vel->min_acceleration; - return res; -} - - -static float -LinearProfile( - DeviceIntPtr dev, - DeviceVelocityPtr vel, - float velocity, - float threshold, - float acc) -{ - return acc * velocity; -} - - -static float -NoProfile( - DeviceIntPtr dev, - DeviceVelocityPtr vel, - float velocity, - float threshold, - float acc) -{ - return 1.0f; -} - -static PointerAccelerationProfileFunc -GetAccelerationProfile( - DeviceVelocityPtr vel, - int profile_num) -{ - switch(profile_num){ - case AccelProfileClassic: - return ClassicProfile; - case AccelProfileDeviceSpecific: - return vel->deviceSpecificProfile; - case AccelProfilePolynomial: - return PolynomialAccelerationProfile; - case AccelProfileSmoothLinear: - return SmoothLinearProfile; - case AccelProfileSimple: - return SimpleSmoothProfile; - case AccelProfilePower: - return PowerProfile; - case AccelProfileLinear: - return LinearProfile; - case AccelProfileNone: - return NoProfile; - default: - return NULL; - } -} - -/** - * Set the profile by number. - * Intended to make profiles exchangeable at runtime. - * If you created a profile, give it a number here and in the header to - * make it selectable. In case some profile-specific init is needed, here - * would be a good place, since FreeVelocityData() also calls this with - * PROFILE_UNINITIALIZE. - * - * returns FALSE if profile number is unavailable, TRUE otherwise. - */ -int -SetAccelerationProfile( - DeviceVelocityPtr vel, - int profile_num) -{ - PointerAccelerationProfileFunc profile; - profile = GetAccelerationProfile(vel, profile_num); - - if(profile == NULL && profile_num != PROFILE_UNINITIALIZE) - return FALSE; - - if(vel->profile_private != NULL){ - /* Here one could free old profile-private data */ - xfree(vel->profile_private); - vel->profile_private = NULL; - } - /* Here one could init profile-private data */ - vel->Profile = profile; - vel->statistics.profile_number = profile_num; - return TRUE; -} - -/********************************************** - * driver interaction - **********************************************/ - - -/** - * device-specific profile - * - * The device-specific profile is intended as a hook for a driver - * which may want to provide an own acceleration profile. - * It should not rely on profile-private data, instead - * it should do init/uninit in the driver (ie. with DEVICE_INIT and friends). - * Users may override or choose it. - */ -void -SetDeviceSpecificAccelerationProfile( - DeviceVelocityPtr vel, - PointerAccelerationProfileFunc profile) -{ - if(vel) - vel->deviceSpecificProfile = profile; -} - -/** - * Use this function to obtain a DeviceVelocityPtr for a device. Will return NULL if - * the predictable acceleration scheme is not in effect. - */ -DeviceVelocityPtr -GetDevicePredictableAccelData( - DeviceIntPtr dev) -{ - /*sanity check*/ - if(!dev){ - ErrorF("[dix] accel: DeviceIntPtr was NULL"); - return NULL; - } - if( dev->valuator && - dev->valuator->accelScheme.AccelSchemeProc == - acceleratePointerPredictable && - dev->valuator->accelScheme.accelData != NULL){ - - return (DeviceVelocityPtr)dev->valuator->accelScheme.accelData; - } - return NULL; -} - -/******************************** - * acceleration schemes - *******************************/ - -/** - * Modifies valuators in-place. - * This version employs a velocity approximation algorithm to - * enable fine-grained predictable acceleration profiles. - */ -void -acceleratePointerPredictable( - DeviceIntPtr dev, - int first_valuator, - int num_valuators, - int *valuators, - int evtime) -{ - float mult = 0.0; - int dx = 0, dy = 0; - int *px = NULL, *py = NULL; - DeviceVelocityPtr velocitydata = - (DeviceVelocityPtr) dev->valuator->accelScheme.accelData; - float fdx, fdy, tmp; /* no need to init */ - Bool soften = TRUE; - - if (!num_valuators || !valuators || !velocitydata) - return; - - if (velocitydata->statistics.profile_number == AccelProfileNone && - velocitydata->const_acceleration == 1.0f) { - return; /*we're inactive anyway, so skip the whole thing.*/ - } - - if (first_valuator == 0) { - dx = valuators[0]; - px = &valuators[0]; - } - if (first_valuator <= 1 && num_valuators >= (2 - first_valuator)) { - dy = valuators[1 - first_valuator]; - py = &valuators[1 - first_valuator]; - } - - if (dx || dy){ - /* reset non-visible state? */ - if (ProcessVelocityData2D(velocitydata, dx , dy, evtime)) { - soften = FALSE; - } - - if (dev->ptrfeed && dev->ptrfeed->ctrl.num) { - /* invoke acceleration profile to determine acceleration */ - mult = ComputeAcceleration (dev, velocitydata, - dev->ptrfeed->ctrl.threshold, - (float)dev->ptrfeed->ctrl.num / - (float)dev->ptrfeed->ctrl.den); - - if(mult != 1.0 || velocitydata->const_acceleration != 1.0) { - ApplySofteningAndConstantDeceleration( velocitydata, - dx, dy, - &fdx, &fdy, - (mult > 1.0) && soften); - - if (dx) { - tmp = mult * fdx + dev->last.remainder[0]; - /* Since it may not be apparent: lrintf() does not offer - * strong statements about rounding; however because we - * process each axis conditionally, there's no danger - * of a toggling remainder. Its lack of guarantees likely - * makes it faster on the average target. */ - *px = lrintf(tmp); - dev->last.remainder[0] = tmp - (float)*px; - } - if (dy) { - tmp = mult * fdy + dev->last.remainder[1]; - *py = lrintf(tmp); - dev->last.remainder[1] = tmp - (float)*py; - } - DebugAccelF("pos (%i | %i) remainders x: %.3f y: %.3f delta x:%.3f y:%.3f\n", - *px, *py, dev->last.remainder[0], dev->last.remainder[1], fdx, fdy); - } - } - } - /* remember last motion delta (for softening/slow movement treatment) */ - velocitydata->last_dx = dx; - velocitydata->last_dy = dy; -} - - - -/** - * Originally a part of xf86PostMotionEvent; modifies valuators - * in-place. Retained mostly for embedded scenarios. - */ -void -acceleratePointerLightweight( - DeviceIntPtr dev, - int first_valuator, - int num_valuators, - int *valuators, - int ignored) -{ - float mult = 0.0; - int dx = 0, dy = 0; - int *px = NULL, *py = NULL; - - if (!num_valuators || !valuators) - return; - - if (first_valuator == 0) { - dx = valuators[0]; - px = &valuators[0]; - } - if (first_valuator <= 1 && num_valuators >= (2 - first_valuator)) { - dy = valuators[1 - first_valuator]; - py = &valuators[1 - first_valuator]; - } - - if (!dx && !dy) - return; - - if (dev->ptrfeed && dev->ptrfeed->ctrl.num) { - /* modeled from xf86Events.c */ - if (dev->ptrfeed->ctrl.threshold) { - if ((abs(dx) + abs(dy)) >= dev->ptrfeed->ctrl.threshold) { - dev->last.remainder[0] = ((float)dx * - (float)(dev->ptrfeed->ctrl.num)) / - (float)(dev->ptrfeed->ctrl.den) + - dev->last.remainder[0]; - if (px) { - *px = (int)dev->last.remainder[0]; - dev->last.remainder[0] = dev->last.remainder[0] - - (float)(*px); - } - - dev->last.remainder[1] = ((float)dy * - (float)(dev->ptrfeed->ctrl.num)) / - (float)(dev->ptrfeed->ctrl.den) + - dev->last.remainder[1]; - if (py) { - *py = (int)dev->last.remainder[1]; - dev->last.remainder[1] = dev->last.remainder[1] - - (float)(*py); - } - } - } - else { - mult = pow((float)dx * (float)dx + (float)dy * (float)dy, - ((float)(dev->ptrfeed->ctrl.num) / - (float)(dev->ptrfeed->ctrl.den) - 1.0) / - 2.0) / 2.0; - if (dx) { - dev->last.remainder[0] = mult * (float)dx + - dev->last.remainder[0]; - *px = (int)dev->last.remainder[0]; - dev->last.remainder[0] = dev->last.remainder[0] - - (float)(*px); - } - if (dy) { - dev->last.remainder[1] = mult * (float)dy + - dev->last.remainder[1]; - *py = (int)dev->last.remainder[1]; - dev->last.remainder[1] = dev->last.remainder[1] - - (float)(*py); - } - } - } -} +/*
+ *
+ * Copyright © 2006-2009 Simon Thum simon dot thum at gmx dot de
+ *
+ * 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.
+ */
+
+#ifdef HAVE_DIX_CONFIG_H
+#include <dix-config.h>
+#endif
+
+#ifdef _MSC_VER
+#define _USE_MATH_DEFINES
+#endif
+
+#include <math.h>
+#include <ptrveloc.h>
+#include <exevents.h>
+#include <X11/Xatom.h>
+
+#include <xserver-properties.h>
+
+/*****************************************************************************
+ * Predictable pointer acceleration
+ *
+ * 2006-2009 by Simon Thum (simon [dot] thum [at] gmx de)
+ *
+ * Serves 3 complementary functions:
+ * 1) provide a sophisticated ballistic velocity estimate to improve
+ * the relation between velocity (of the device) and acceleration
+ * 2) make arbitrary acceleration profiles possible
+ * 3) decelerate by two means (constant and adaptive) if enabled
+ *
+ * Important concepts are the
+ *
+ * - Scheme
+ * which selects the basic algorithm
+ * (see devices.c/InitPointerAccelerationScheme)
+ * - Profile
+ * which returns an acceleration
+ * for a given velocity
+ *
+ * The profile can be selected by the user at runtime.
+ * The classic profile is intended to cleanly perform old-style
+ * function selection (threshold =/!= 0)
+ *
+ ****************************************************************************/
+
+#ifdef _MSC_VER
+#define inline __inline
+#define lrintf(val) ((int)val)
+#endif
+
+/* fwds */
+int
+SetAccelerationProfile(DeviceVelocityPtr vel, int profile_num);
+static float
+SimpleSmoothProfile(DeviceIntPtr dev, DeviceVelocityPtr vel, float velocity,
+ float threshold, float acc);
+static PointerAccelerationProfileFunc
+GetAccelerationProfile(DeviceVelocityPtr vel, int profile_num);
+
+/*#define PTRACCEL_DEBUGGING*/
+
+#ifdef PTRACCEL_DEBUGGING
+#define DebugAccelF ErrorF
+#else
+#define DebugAccelF(...) /* */
+#endif
+
+/********************************
+ * Init/Uninit
+ *******************************/
+
+/* some int which is not a profile number */
+#define PROFILE_UNINITIALIZE (-100)
+
+/* number of properties for predictable acceleration */
+#define NPROPS_PREDICTABLE_ACCEL 4
+
+/**
+ * Init struct so it should match the average case
+ */
+void
+InitVelocityData(DeviceVelocityPtr vel)
+{
+ memset(vel, 0, sizeof(DeviceVelocityRec));
+
+ vel->corr_mul = 10.0; /* dots per 10 milisecond should be usable */
+ vel->const_acceleration = 1.0; /* no acceleration/deceleration */
+ vel->reset_time = 300;
+ vel->use_softening = 1;
+ vel->min_acceleration = 1.0; /* don't decelerate */
+ vel->max_rel_diff = 0.2;
+ vel->max_diff = 1.0;
+ vel->initial_range = 2;
+ vel->average_accel = TRUE;
+ SetAccelerationProfile(vel, AccelProfileClassic);
+ InitTrackers(vel, 16);
+}
+
+
+/**
+ * Clean up
+ */
+void
+FreeVelocityData(DeviceVelocityPtr vel){
+ xfree(vel->tracker);
+ SetAccelerationProfile(vel, PROFILE_UNINITIALIZE);
+}
+
+
+/*
+ * dix uninit helper, called through scheme
+ */
+void
+AccelerationDefaultCleanup(DeviceIntPtr dev)
+{
+ /*sanity check*/
+ if( dev->valuator->accelScheme.AccelSchemeProc == acceleratePointerPredictable
+ && dev->valuator->accelScheme.accelData != NULL){
+ dev->valuator->accelScheme.AccelSchemeProc = NULL;
+ FreeVelocityData(dev->valuator->accelScheme.accelData);
+ xfree(dev->valuator->accelScheme.accelData);
+ dev->valuator->accelScheme.accelData = NULL;
+ DeletePredictableAccelerationProperties(dev);
+ }
+}
+
+
+/*************************
+ * Input property support
+ ************************/
+
+/**
+ * choose profile
+ */
+static int
+AccelSetProfileProperty(DeviceIntPtr dev, Atom atom,
+ XIPropertyValuePtr val, BOOL checkOnly)
+{
+ DeviceVelocityPtr vel;
+ int profile, *ptr = &profile;
+ int rc;
+ int nelem = 1;
+
+ if (atom != XIGetKnownProperty(ACCEL_PROP_PROFILE_NUMBER))
+ return Success;
+
+ vel = GetDevicePredictableAccelData(dev);
+ if (!vel)
+ return BadValue;
+ rc = XIPropToInt(val, &nelem, &ptr);
+
+ if(checkOnly)
+ {
+ if (rc)
+ return rc;
+
+ if (GetAccelerationProfile(vel, profile) == NULL)
+ return BadValue;
+ } else
+ SetAccelerationProfile(vel, profile);
+
+ return Success;
+}
+
+static long
+AccelInitProfileProperty(DeviceIntPtr dev, DeviceVelocityPtr vel)
+{
+ int profile = vel->statistics.profile_number;
+ Atom prop_profile_number = XIGetKnownProperty(ACCEL_PROP_PROFILE_NUMBER);
+
+ XIChangeDeviceProperty(dev, prop_profile_number, XA_INTEGER, 32,
+ PropModeReplace, 1, &profile, FALSE);
+ XISetDevicePropertyDeletable(dev, prop_profile_number, FALSE);
+ return XIRegisterPropertyHandler(dev, AccelSetProfileProperty, NULL, NULL);
+}
+
+/**
+ * constant deceleration
+ */
+static int
+AccelSetDecelProperty(DeviceIntPtr dev, Atom atom,
+ XIPropertyValuePtr val, BOOL checkOnly)
+{
+ DeviceVelocityPtr vel;
+ float v, *ptr = &v;
+ int rc;
+ int nelem = 1;
+
+ if (atom != XIGetKnownProperty(ACCEL_PROP_CONSTANT_DECELERATION))
+ return Success;
+
+ vel = GetDevicePredictableAccelData(dev);
+ if (!vel)
+ return BadValue;
+ rc = XIPropToFloat(val, &nelem, &ptr);
+
+ if(checkOnly)
+ {
+ if (rc)
+ return rc;
+ return (v >= 1.0f) ? Success : BadValue;
+ }
+
+ if(v >= 1.0f)
+ vel->const_acceleration = 1/v;
+
+ return Success;
+}
+
+static long
+AccelInitDecelProperty(DeviceIntPtr dev, DeviceVelocityPtr vel)
+{
+ float fval = 1.0/vel->const_acceleration;
+ Atom prop_const_decel = XIGetKnownProperty(ACCEL_PROP_CONSTANT_DECELERATION);
+ XIChangeDeviceProperty(dev, prop_const_decel,
+ XIGetKnownProperty(XATOM_FLOAT), 32,
+ PropModeReplace, 1, &fval, FALSE);
+ XISetDevicePropertyDeletable(dev, prop_const_decel, FALSE);
+ return XIRegisterPropertyHandler(dev, AccelSetDecelProperty, NULL, NULL);
+}
+
+
+/**
+ * adaptive deceleration
+ */
+static int
+AccelSetAdaptDecelProperty(DeviceIntPtr dev, Atom atom,
+ XIPropertyValuePtr val, BOOL checkOnly)
+{
+ DeviceVelocityPtr veloc;
+ float v, *ptr = &v;
+ int rc;
+ int nelem = 1;
+
+ if (atom != XIGetKnownProperty(ACCEL_PROP_ADAPTIVE_DECELERATION))
+ return Success;
+
+ veloc = GetDevicePredictableAccelData(dev);
+ if (!veloc)
+ return BadValue;
+ rc = XIPropToFloat(val, &nelem, &ptr);
+
+ if(checkOnly)
+ {
+ if (rc)
+ return rc;
+ return (v >= 1.0f) ? Success : BadValue;
+ }
+
+ if(v >= 1.0f)
+ veloc->min_acceleration = 1/v;
+
+ return Success;
+}
+
+static long
+AccelInitAdaptDecelProperty(DeviceIntPtr dev, DeviceVelocityPtr vel)
+{
+ float fval = 1.0/vel->min_acceleration;
+ Atom prop_adapt_decel = XIGetKnownProperty(ACCEL_PROP_ADAPTIVE_DECELERATION);
+
+ XIChangeDeviceProperty(dev, prop_adapt_decel, XIGetKnownProperty(XATOM_FLOAT), 32,
+ PropModeReplace, 1, &fval, FALSE);
+ XISetDevicePropertyDeletable(dev, prop_adapt_decel, FALSE);
+ return XIRegisterPropertyHandler(dev, AccelSetAdaptDecelProperty, NULL, NULL);
+}
+
+
+/**
+ * velocity scaling
+ */
+static int
+AccelSetScaleProperty(DeviceIntPtr dev, Atom atom,
+ XIPropertyValuePtr val, BOOL checkOnly)
+{
+ DeviceVelocityPtr vel;
+ float v, *ptr = &v;
+ int rc;
+ int nelem = 1;
+
+ if (atom != XIGetKnownProperty(ACCEL_PROP_VELOCITY_SCALING))
+ return Success;
+
+ vel = GetDevicePredictableAccelData(dev);
+ if (!vel)
+ return BadValue;
+ rc = XIPropToFloat(val, &nelem, &ptr);
+
+ if (checkOnly)
+ {
+ if (rc)
+ return rc;
+
+ return (v > 0) ? Success : BadValue;
+ }
+
+ if(v > 0)
+ vel->corr_mul = v;
+
+ return Success;
+}
+
+static long
+AccelInitScaleProperty(DeviceIntPtr dev, DeviceVelocityPtr vel)
+{
+ float fval = vel->corr_mul;
+ Atom prop_velo_scale = XIGetKnownProperty(ACCEL_PROP_VELOCITY_SCALING);
+
+ XIChangeDeviceProperty(dev, prop_velo_scale, XIGetKnownProperty(XATOM_FLOAT), 32,
+ PropModeReplace, 1, &fval, FALSE);
+ XISetDevicePropertyDeletable(dev, prop_velo_scale, FALSE);
+ return XIRegisterPropertyHandler(dev, AccelSetScaleProperty, NULL, NULL);
+}
+
+static int AccelPropHandlerPrivateKeyIndex;
+DevPrivateKey AccelPropHandlerPrivateKey = &AccelPropHandlerPrivateKeyIndex;
+
+BOOL
+InitializePredictableAccelerationProperties(DeviceIntPtr dev)
+{
+ DeviceVelocityPtr vel = GetDevicePredictableAccelData(dev);
+ long *prop_handlers;
+
+ if(!vel)
+ return FALSE;
+ prop_handlers = xalloc(NPROPS_PREDICTABLE_ACCEL * sizeof(long));
+
+ prop_handlers[0] = AccelInitProfileProperty(dev, vel);
+ prop_handlers[1] = AccelInitDecelProperty(dev, vel);
+ prop_handlers[2] = AccelInitAdaptDecelProperty(dev, vel);
+ prop_handlers[3] = AccelInitScaleProperty(dev, vel);
+
+ dixSetPrivate(&dev->devPrivates, AccelPropHandlerPrivateKey,
+ prop_handlers);
+
+ return TRUE;
+}
+
+BOOL
+DeletePredictableAccelerationProperties(DeviceIntPtr dev)
+{
+ Atom prop;
+ long *prop_handlers;
+ int i;
+
+ prop = XIGetKnownProperty(ACCEL_PROP_VELOCITY_SCALING);
+ XIDeleteDeviceProperty(dev, prop, FALSE);
+ prop = XIGetKnownProperty(ACCEL_PROP_ADAPTIVE_DECELERATION);
+ XIDeleteDeviceProperty(dev, prop, FALSE);
+ prop = XIGetKnownProperty(ACCEL_PROP_CONSTANT_DECELERATION);
+ XIDeleteDeviceProperty(dev, prop, FALSE);
+ prop = XIGetKnownProperty(ACCEL_PROP_PROFILE_NUMBER);
+ XIDeleteDeviceProperty(dev, prop, FALSE);
+
+ prop_handlers = dixLookupPrivate(&dev->devPrivates,
+ AccelPropHandlerPrivateKey);
+ dixSetPrivate(&dev->devPrivates, AccelPropHandlerPrivateKey, NULL);
+
+ for (i = 0; prop_handlers && i < NPROPS_PREDICTABLE_ACCEL; i++)
+ XIUnregisterPropertyHandler(dev, prop_handlers[i]);
+ xfree(prop_handlers);
+
+ return TRUE;
+}
+
+/*********************
+ * Tracking logic
+ ********************/
+
+void
+InitTrackers(DeviceVelocityPtr vel, int ntracker)
+{
+ if(ntracker < 1){
+ ErrorF("(dix ptracc) invalid number of trackers\n");
+ return;
+ }
+ xfree(vel->tracker);
+ vel->tracker = (MotionTrackerPtr)xalloc(ntracker * sizeof(MotionTracker));
+ memset(vel->tracker, 0, ntracker * sizeof(MotionTracker));
+ vel->num_tracker = ntracker;
+}
+
+/**
+ * return a bit field of possible directions.
+ * 0 = N, 2 = E, 4 = S, 6 = W, in-between is as you guess.
+ * There's no reason against widening to more precise directions (<45 degrees),
+ * should it not perform well. All this is needed for is sort out non-linear
+ * motion, so precision isn't paramount. However, one should not flag direction
+ * too narrow, since it would then cut the linear segment to zero size way too
+ * often.
+ */
+static int
+DoGetDirection(int dx, int dy){
+ float r;
+ int i1, i2;
+ /* on insignificant mickeys, flag 135 degrees */
+ if(abs(dx) < 2 && abs(dy < 2)){
+ /* first check diagonal cases */
+ if(dx > 0 && dy > 0)
+ return 4+8+16;
+ if(dx > 0 && dy < 0)
+ return 1+2+4;
+ if(dx < 0 && dy < 0)
+ return 1+128+64;
+ if(dx < 0 && dy > 0)
+ return 16+32+64;
+ /* check axis-aligned directions */
+ if(dx > 0)
+ return 2+4+8; /*E*/
+ if(dx < 0)
+ return 128+64+32; /*W*/
+ if(dy > 0)
+ return 32+16+8; /*S*/
+ if(dy < 0)
+ return 128+1+2; /*N*/
+ return 255; /* shouldn't happen */
+ }
+ /* else, compute angle and set appropriate flags */
+#ifdef _ISOC99_SOURCE
+ r = atan2f(dy, dx);
+#else
+ r = atan2(dy, dx);
+#endif
+ /* find direction. We avoid r to become negative,
+ * since C has no well-defined modulo for such cases. */
+ r = (r+(M_PI*2.5))/(M_PI/4);
+ /* this intends to flag 2 directions (90 degrees),
+ * except on very well-aligned mickeys. */
+ i1 = (int)(r+0.1) % 8;
+ i2 = (int)(r+0.9) % 8;
+ if(i1 < 0 || i1 > 7 || i2 < 0 || i2 > 7)
+ return 255; /* shouldn't happen */
+ return 1 << i1 | 1 << i2;
+}
+
+#define DIRECTION_CACHE_RANGE 5
+#define DIRECTION_CACHE_SIZE (DIRECTION_CACHE_RANGE*2+1)
+
+/* cache DoGetDirection(). */
+static int
+GetDirection(int dx, int dy){
+ static int cache[DIRECTION_CACHE_SIZE][DIRECTION_CACHE_SIZE];
+ int i;
+ if (abs(dx) <= DIRECTION_CACHE_RANGE &&
+ abs(dy) <= DIRECTION_CACHE_RANGE) {
+ /* cacheable */
+ i = cache[DIRECTION_CACHE_RANGE+dx][DIRECTION_CACHE_RANGE+dy];
+ if(i != 0){
+ return i;
+ }else{
+ i = DoGetDirection(dx, dy);
+ cache[DIRECTION_CACHE_RANGE+dx][DIRECTION_CACHE_RANGE+dy] = i;
+ return i;
+ }
+ }else{
+ /* non-cacheable */
+ return DoGetDirection(dx, dy);
+ }
+}
+
+#undef DIRECTION_CACHE_RANGE
+#undef DIRECTION_CACHE_SIZE
+
+
+/* convert offset (age) to array index */
+#define TRACKER_INDEX(s, d) (((s)->num_tracker + (s)->cur_tracker - (d)) % (s)->num_tracker)
+
+static inline void
+FeedTrackers(DeviceVelocityPtr vel, int dx, int dy, int cur_t)
+{
+ int n;
+ for(n = 0; n < vel->num_tracker; n++){
+ vel->tracker[n].dx += dx;
+ vel->tracker[n].dy += dy;
+ }
+ n = (vel->cur_tracker + 1) % vel->num_tracker;
+ vel->tracker[n].dx = 0;
+ vel->tracker[n].dy = 0;
+ vel->tracker[n].time = cur_t;
+ vel->tracker[n].dir = GetDirection(dx, dy);
+ DebugAccelF("(dix prtacc) motion [dx: %i dy: %i dir:%i diff: %i]\n",
+ dx, dy, vel->tracker[n].dir,
+ cur_t - vel->tracker[vel->cur_tracker].time);
+ vel->cur_tracker = n;
+}
+
+/**
+ * calc velocity for given tracker, with
+ * velocity scaling.
+ * This assumes linear motion.
+ */
+static float
+CalcTracker(DeviceVelocityPtr vel, int offset, int cur_t){
+ int index = TRACKER_INDEX(vel, offset);
+ float dist = sqrt( vel->tracker[index].dx * vel->tracker[index].dx
+ + vel->tracker[index].dy * vel->tracker[index].dy);
+ int dtime = cur_t - vel->tracker[index].time;
+ if(dtime > 0)
+ return (dist / dtime);
+ else
+ return 0;/* synonymous for NaN, since we're not C99 */
+}
+
+/* find the most plausible velocity. That is, the most distant
+ * (in time) tracker which isn't too old, beyond a linear partition,
+ * or simply too much off initial velocity.
+ *
+ * May return 0.
+ */
+static float
+QueryTrackers(DeviceVelocityPtr vel, int cur_t){
+ int n, offset, dir = 255, i = -1, age_ms;
+ /* initial velocity: a low-offset, valid velocity */
+ float iveloc = 0, res = 0, tmp, vdiff;
+ float vfac = vel->corr_mul * vel->const_acceleration; /* premultiply */
+ /* loop from current to older data */
+ for(offset = 1; offset < vel->num_tracker; offset++){
+ n = TRACKER_INDEX(vel, offset);
+
+ age_ms = cur_t - vel->tracker[n].time;
+
+ /* bail out if data is too old and protect from overrun */
+ if (age_ms >= vel->reset_time || age_ms < 0) {
+ DebugAccelF("(dix prtacc) query: tracker too old\n");
+ break;
+ }
+
+ /*
+ * this heuristic avoids using the linear-motion velocity formula
+ * in CalcTracker() on motion that isn't exactly linear. So to get
+ * even more precision we could subdivide as a final step, so possible
+ * non-linearities are accounted for.
+ */
+ dir &= vel->tracker[n].dir;
+ if(dir == 0){
+ DebugAccelF("(dix prtacc) query: no longer linear\n");
+ /* instead of breaking it we might also inspect the partition after,
+ * but actual improvement with this is probably rare. */
+ break;
+ }
+
+ tmp = CalcTracker(vel, offset, cur_t) * vfac;
+
+ if ((iveloc == 0 || offset <= vel->initial_range) && tmp != 0) {
+ /* set initial velocity and result */
+ res = iveloc = tmp;
+ i = offset;
+ } else if (iveloc != 0 && tmp != 0) {
+ vdiff = fabs(iveloc - tmp);
+ if (vdiff <= vel->max_diff ||
+ vdiff/(iveloc + tmp) < vel->max_rel_diff) {
+ /* we're in range with the initial velocity,
+ * so this result is likely better
+ * (it contains more information). */
+ res = tmp;
+ i = offset;
+ }else{
+ /* we're not in range, quit - it won't get better. */
+ DebugAccelF("(dix prtacc) query: tracker too different:"
+ " old %2.2f initial %2.2f diff: %2.2f\n",
+ tmp, iveloc, vdiff);
+ break;
+ }
+ }
+ }
+ if(offset == vel->num_tracker){
+ DebugAccelF("(dix prtacc) query: last tracker in effect\n");
+ i = vel->num_tracker-1;
+ }
+ if(i>=0){
+ n = TRACKER_INDEX(vel, i);
+ DebugAccelF("(dix prtacc) result: offset %i [dx: %i dy: %i diff: %i]\n",
+ i,
+ vel->tracker[n].dx,
+ vel->tracker[n].dy,
+ cur_t - vel->tracker[n].time);
+ }
+ return res;
+}
+
+#undef TRACKER_INDEX
+
+/**
+ * Perform velocity approximation based on 2D 'mickeys' (mouse motion delta).
+ * return true if non-visible state reset is suggested
+ */
+short
+ProcessVelocityData2D(
+ DeviceVelocityPtr vel,
+ int dx,
+ int dy,
+ int time)
+{
+ float velocity;
+
+ vel->last_velocity = vel->velocity;
+
+ FeedTrackers(vel, dx, dy, time);
+
+ velocity = QueryTrackers(vel, time);
+
+ vel->velocity = velocity;
+ return velocity == 0;
+}
+
+/**
+ * this flattens significant ( > 1) mickeys a little bit for more steady
+ * constant-velocity response
+ */
+static inline float
+ApplySimpleSoftening(int od, int d)
+{
+ float res = d;
+ if (d <= 1 && d >= -1)
+ return res;
+ if (d > od)
+ res -= 0.5;
+ else if (d < od)
+ res += 0.5;
+ return res;
+}
+
+
+static void
+ApplySofteningAndConstantDeceleration(
+ DeviceVelocityPtr vel,
+ int dx,
+ int dy,
+ float* fdx,
+ float* fdy,
+ short do_soften)
+{
+ if (do_soften && vel->use_softening) {
+ *fdx = ApplySimpleSoftening(vel->last_dx, dx);
+ *fdy = ApplySimpleSoftening(vel->last_dy, dy);
+ } else {
+ *fdx = dx;
+ *fdy = dy;
+ }
+
+ *fdx *= vel->const_acceleration;
+ *fdy *= vel->const_acceleration;
+}
+
+/*
+ * compute the acceleration for given velocity and enforce min_acceleartion
+ */
+float
+BasicComputeAcceleration(
+ DeviceIntPtr dev,
+ DeviceVelocityPtr vel,
+ float velocity,
+ float threshold,
+ float acc){
+
+ float result;
+ result = vel->Profile(dev, vel, velocity, threshold, acc);
+
+ /* enforce min_acceleration */
+ if (result < vel->min_acceleration)
+ result = vel->min_acceleration;
+ return result;
+}
+
+/**
+ * Compute acceleration. Takes into account averaging, nv-reset, etc.
+ */
+static float
+ComputeAcceleration(
+ DeviceIntPtr dev,
+ DeviceVelocityPtr vel,
+ float threshold,
+ float acc){
+ float res;
+
+ if(vel->velocity <= 0){
+ DebugAccelF("(dix ptracc) profile skipped\n");
+ /*
+ * If we have no idea about device velocity, don't pretend it.
+ */
+ return 1;
+ }
+
+ if(vel->average_accel && vel->velocity != vel->last_velocity){
+ /* use simpson's rule to average acceleration between
+ * current and previous velocity.
+ * Though being the more natural choice, it causes a minor delay
+ * in comparison, so it can be disabled. */
+ res = BasicComputeAcceleration(
+ dev, vel, vel->velocity, threshold, acc);
+ res += BasicComputeAcceleration(
+ dev, vel, vel->last_velocity, threshold, acc);
+ res += 4.0f * BasicComputeAcceleration(dev, vel,
+ (vel->last_velocity + vel->velocity) / 2,
+ threshold, acc);
+ res /= 6.0f;
+ DebugAccelF("(dix ptracc) profile average [%.2f ... %.2f] is %.3f\n",
+ vel->velocity, vel->last_velocity, res);
+ return res;
+ }else{
+ res = BasicComputeAcceleration(dev, vel,
+ vel->velocity, threshold, acc);
+ DebugAccelF("(dix ptracc) profile sample [%.2f] is %.3f\n",
+ vel->velocity, res);
+ return res;
+ }
+}
+
+
+/*****************************************
+ * Acceleration functions and profiles
+ ****************************************/
+
+/**
+ * Polynomial function similar previous one, but with f(1) = 1
+ */
+static float
+PolynomialAccelerationProfile(
+ DeviceIntPtr dev,
+ DeviceVelocityPtr vel,
+ float velocity,
+ float ignored,
+ float acc)
+{
+ return pow(velocity, (acc - 1.0) * 0.5);
+}
+
+
+/**
+ * returns acceleration for velocity.
+ * This profile selects the two functions like the old scheme did
+ */
+static float
+ClassicProfile(
+ DeviceIntPtr dev,
+ DeviceVelocityPtr vel,
+ float velocity,
+ float threshold,
+ float acc)
+{
+ if (threshold > 0) {
+ return SimpleSmoothProfile (dev,
+ vel,
+ velocity,
+ threshold,
+ acc);
+ } else {
+ return PolynomialAccelerationProfile (dev,
+ vel,
+ velocity,
+ 0,
+ acc);
+ }
+}
+
+
+/**
+ * Power profile
+ * This has a completely smooth transition curve, i.e. no jumps in the
+ * derivatives.
+ *
+ * This has the expense of overall response dependency on min-acceleration.
+ * In effect, min_acceleration mimics const_acceleration in this profile.
+ */
+static float
+PowerProfile(
+ DeviceIntPtr dev,
+ DeviceVelocityPtr vel,
+ float velocity,
+ float threshold,
+ float acc)
+{
+ float vel_dist;
+
+ acc = (acc-1.0) * 0.1f + 1.0; /* without this, acc of 2 is unuseable */
+
+ if (velocity <= threshold)
+ return vel->min_acceleration;
+ vel_dist = velocity - threshold;
+ return (pow(acc, vel_dist)) * vel->min_acceleration;
+}
+
+
+/**
+ * just a smooth function in [0..1] -> [0..1]
+ * - point symmetry at 0.5
+ * - f'(0) = f'(1) = 0
+ * - starts faster than a sinoid
+ * - smoothness C1 (Cinf if you dare to ignore endpoints)
+ */
+static inline float
+CalcPenumbralGradient(float x){
+ x *= 2.0f;
+ x -= 1.0f;
+ return 0.5f + (x * sqrt(1.0f - x*x) + asin(x))/M_PI;
+}
+
+
+/**
+ * acceleration function similar to classic accelerated/unaccelerated,
+ * but with smooth transition in between (and towards zero for adaptive dec.).
+ */
+static float
+SimpleSmoothProfile(
+ DeviceIntPtr dev,
+ DeviceVelocityPtr vel,
+ float velocity,
+ float threshold,
+ float acc)
+{
+ if(velocity < 1.0f)
+ return CalcPenumbralGradient(0.5 + velocity*0.5) * 2.0f - 1.0f;
+ if(threshold < 1.0f)
+ threshold = 1.0f;
+ if (velocity <= threshold)
+ return 1;
+ velocity /= threshold;
+ if (velocity >= acc)
+ return acc;
+ else
+ return 1.0f + (CalcPenumbralGradient(velocity/acc) * (acc - 1.0f));
+}
+
+
+/**
+ * This profile uses the first half of the penumbral gradient as a start
+ * and then scales linearly.
+ */
+static float
+SmoothLinearProfile(
+ DeviceIntPtr dev,
+ DeviceVelocityPtr vel,
+ float velocity,
+ float threshold,
+ float acc)
+{
+ float res, nv;
+
+ if(acc > 1.0f)
+ acc -= 1.0f; /*this is so acc = 1 is no acceleration */
+ else
+ return 1.0f;
+
+ nv = (velocity - threshold) * acc * 0.5f;
+
+ if(nv < 0){
+ res = 0;
+ }else if(nv < 2){
+ res = CalcPenumbralGradient(nv*0.25f)*2.0f;
+ }else{
+ nv -= 2.0f;
+ res = nv * 2.0f / M_PI /* steepness of gradient at 0.5 */
+ + 1.0f; /* gradient crosses 2|1 */
+ }
+ res += vel->min_acceleration;
+ return res;
+}
+
+
+/**
+ * From 0 to threshold, the response graduates smoothly from min_accel to
+ * acceleration. Beyond threshold it is exactly the specified acceleration.
+ */
+static float
+SmoothLimitedProfile(
+ DeviceIntPtr dev,
+ DeviceVelocityPtr vel,
+ float velocity,
+ float threshold,
+ float acc)
+{
+ float res;
+
+ if(velocity >= threshold || threshold == 0.0f)
+ return acc;
+
+ velocity /= threshold; /* should be [0..1[ now */
+
+ res = CalcPenumbralGradient(velocity) * (acc - vel->min_acceleration);
+
+ return vel->min_acceleration + res;
+}
+
+
+static float
+LinearProfile(
+ DeviceIntPtr dev,
+ DeviceVelocityPtr vel,
+ float velocity,
+ float threshold,
+ float acc)
+{
+ return acc * velocity;
+}
+
+static float
+NoProfile(
+ DeviceIntPtr dev,
+ DeviceVelocityPtr vel,
+ float velocity,
+ float threshold,
+ float acc)
+{
+ return 1.0f;
+}
+
+static PointerAccelerationProfileFunc
+GetAccelerationProfile(
+ DeviceVelocityPtr vel,
+ int profile_num)
+{
+ switch(profile_num){
+ case AccelProfileClassic:
+ return ClassicProfile;
+ case AccelProfileDeviceSpecific:
+ return vel->deviceSpecificProfile;
+ case AccelProfilePolynomial:
+ return PolynomialAccelerationProfile;
+ case AccelProfileSmoothLinear:
+ return SmoothLinearProfile;
+ case AccelProfileSimple:
+ return SimpleSmoothProfile;
+ case AccelProfilePower:
+ return PowerProfile;
+ case AccelProfileLinear:
+ return LinearProfile;
+ case AccelProfileSmoothLimited:
+ return SmoothLimitedProfile;
+ case AccelProfileNone:
+ return NoProfile;
+ default:
+ return NULL;
+ }
+}
+
+/**
+ * Set the profile by number.
+ * Intended to make profiles exchangeable at runtime.
+ * If you created a profile, give it a number here and in the header to
+ * make it selectable. In case some profile-specific init is needed, here
+ * would be a good place, since FreeVelocityData() also calls this with
+ * PROFILE_UNINITIALIZE.
+ *
+ * returns FALSE if profile number is unavailable, TRUE otherwise.
+ */
+int
+SetAccelerationProfile(
+ DeviceVelocityPtr vel,
+ int profile_num)
+{
+ PointerAccelerationProfileFunc profile;
+ profile = GetAccelerationProfile(vel, profile_num);
+
+ if(profile == NULL && profile_num != PROFILE_UNINITIALIZE)
+ return FALSE;
+
+ if(vel->profile_private != NULL){
+ /* Here one could free old profile-private data */
+ xfree(vel->profile_private);
+ vel->profile_private = NULL;
+ }
+ /* Here one could init profile-private data */
+ vel->Profile = profile;
+ vel->statistics.profile_number = profile_num;
+ return TRUE;
+}
+
+/**********************************************
+ * driver interaction
+ **********************************************/
+
+
+/**
+ * device-specific profile
+ *
+ * The device-specific profile is intended as a hook for a driver
+ * which may want to provide an own acceleration profile.
+ * It should not rely on profile-private data, instead
+ * it should do init/uninit in the driver (ie. with DEVICE_INIT and friends).
+ * Users may override or choose it.
+ */
+void
+SetDeviceSpecificAccelerationProfile(
+ DeviceVelocityPtr vel,
+ PointerAccelerationProfileFunc profile)
+{
+ if(vel)
+ vel->deviceSpecificProfile = profile;
+}
+
+/**
+ * Use this function to obtain a DeviceVelocityPtr for a device. Will return NULL if
+ * the predictable acceleration scheme is not in effect.
+ */
+DeviceVelocityPtr
+GetDevicePredictableAccelData(
+ DeviceIntPtr dev)
+{
+ /*sanity check*/
+ if(!dev){
+ ErrorF("[dix] accel: DeviceIntPtr was NULL");
+ return NULL;
+ }
+ if( dev->valuator &&
+ dev->valuator->accelScheme.AccelSchemeProc ==
+ acceleratePointerPredictable &&
+ dev->valuator->accelScheme.accelData != NULL){
+
+ return (DeviceVelocityPtr)dev->valuator->accelScheme.accelData;
+ }
+ return NULL;
+}
+
+/********************************
+ * acceleration schemes
+ *******************************/
+
+/**
+ * Modifies valuators in-place.
+ * This version employs a velocity approximation algorithm to
+ * enable fine-grained predictable acceleration profiles.
+ */
+void
+acceleratePointerPredictable(
+ DeviceIntPtr dev,
+ int first_valuator,
+ int num_valuators,
+ int *valuators,
+ int evtime)
+{
+ float mult = 0.0;
+ int dx = 0, dy = 0;
+ int *px = NULL, *py = NULL;
+ DeviceVelocityPtr velocitydata =
+ (DeviceVelocityPtr) dev->valuator->accelScheme.accelData;
+ float fdx, fdy, tmp; /* no need to init */
+ Bool soften = TRUE;
+
+ if (!num_valuators || !valuators || !velocitydata)
+ return;
+
+ if (velocitydata->statistics.profile_number == AccelProfileNone &&
+ velocitydata->const_acceleration == 1.0f) {
+ return; /*we're inactive anyway, so skip the whole thing.*/
+ }
+
+ if (first_valuator == 0) {
+ dx = valuators[0];
+ px = &valuators[0];
+ }
+ if (first_valuator <= 1 && num_valuators >= (2 - first_valuator)) {
+ dy = valuators[1 - first_valuator];
+ py = &valuators[1 - first_valuator];
+ }
+
+ if (dx || dy){
+ /* reset non-visible state? */
+ if (ProcessVelocityData2D(velocitydata, dx , dy, evtime)) {
+ soften = FALSE;
+ }
+
+ if (dev->ptrfeed && dev->ptrfeed->ctrl.num) {
+ /* invoke acceleration profile to determine acceleration */
+ mult = ComputeAcceleration (dev, velocitydata,
+ dev->ptrfeed->ctrl.threshold,
+ (float)dev->ptrfeed->ctrl.num /
+ (float)dev->ptrfeed->ctrl.den);
+
+ if(mult != 1.0 || velocitydata->const_acceleration != 1.0) {
+ ApplySofteningAndConstantDeceleration( velocitydata,
+ dx, dy,
+ &fdx, &fdy,
+ (mult > 1.0) && soften);
+
+ if (dx) {
+ tmp = mult * fdx + dev->last.remainder[0];
+ /* Since it may not be apparent: lrintf() does not offer
+ * strong statements about rounding; however because we
+ * process each axis conditionally, there's no danger
+ * of a toggling remainder. Its lack of guarantees likely
+ * makes it faster on the average target. */
+ *px = lrintf(tmp);
+ dev->last.remainder[0] = tmp - (float)*px;
+ }
+ if (dy) {
+ tmp = mult * fdy + dev->last.remainder[1];
+ *py = lrintf(tmp);
+ dev->last.remainder[1] = tmp - (float)*py;
+ }
+ DebugAccelF("pos (%i | %i) remainders x: %.3f y: %.3f delta x:%.3f y:%.3f\n",
+ *px, *py, dev->last.remainder[0], dev->last.remainder[1], fdx, fdy);
+ }
+ }
+ }
+ /* remember last motion delta (for softening/slow movement treatment) */
+ velocitydata->last_dx = dx;
+ velocitydata->last_dy = dy;
+}
+
+
+
+/**
+ * Originally a part of xf86PostMotionEvent; modifies valuators
+ * in-place. Retained mostly for embedded scenarios.
+ */
+void
+acceleratePointerLightweight(
+ DeviceIntPtr dev,
+ int first_valuator,
+ int num_valuators,
+ int *valuators,
+ int ignored)
+{
+ float mult = 0.0;
+ int dx = 0, dy = 0;
+ int *px = NULL, *py = NULL;
+
+ if (!num_valuators || !valuators)
+ return;
+
+ if (first_valuator == 0) {
+ dx = valuators[0];
+ px = &valuators[0];
+ }
+ if (first_valuator <= 1 && num_valuators >= (2 - first_valuator)) {
+ dy = valuators[1 - first_valuator];
+ py = &valuators[1 - first_valuator];
+ }
+
+ if (!dx && !dy)
+ return;
+
+ if (dev->ptrfeed && dev->ptrfeed->ctrl.num) {
+ /* modeled from xf86Events.c */
+ if (dev->ptrfeed->ctrl.threshold) {
+ if ((abs(dx) + abs(dy)) >= dev->ptrfeed->ctrl.threshold) {
+ dev->last.remainder[0] = ((float)dx *
+ (float)(dev->ptrfeed->ctrl.num)) /
+ (float)(dev->ptrfeed->ctrl.den) +
+ dev->last.remainder[0];
+ if (px) {
+ *px = (int)dev->last.remainder[0];
+ dev->last.remainder[0] = dev->last.remainder[0] -
+ (float)(*px);
+ }
+
+ dev->last.remainder[1] = ((float)dy *
+ (float)(dev->ptrfeed->ctrl.num)) /
+ (float)(dev->ptrfeed->ctrl.den) +
+ dev->last.remainder[1];
+ if (py) {
+ *py = (int)dev->last.remainder[1];
+ dev->last.remainder[1] = dev->last.remainder[1] -
+ (float)(*py);
+ }
+ }
+ }
+ else {
+ mult = pow((float)dx * (float)dx + (float)dy * (float)dy,
+ ((float)(dev->ptrfeed->ctrl.num) /
+ (float)(dev->ptrfeed->ctrl.den) - 1.0) /
+ 2.0) / 2.0;
+ if (dx) {
+ dev->last.remainder[0] = mult * (float)dx +
+ dev->last.remainder[0];
+ *px = (int)dev->last.remainder[0];
+ dev->last.remainder[0] = dev->last.remainder[0] -
+ (float)(*px);
+ }
+ if (dy) {
+ dev->last.remainder[1] = mult * (float)dy +
+ dev->last.remainder[1];
+ *py = (int)dev->last.remainder[1];
+ dev->last.remainder[1] = dev->last.remainder[1] -
+ (float)(*py);
+ }
+ }
+ }
+}
|