/* * Copyright © 2006-2009 Simon Thum * Copyright © 2012 Jonas Ådahl * Copyright © 2014-2015 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. */ #include "config.h" #include #include #include #include #include #include #include "filter.h" #include "libinput-util.h" #include "filter-private.h" /* * Default parameters for pointer acceleration profiles. */ #define DEFAULT_THRESHOLD v_ms2us(0.4) /* in units/us */ #define MINIMUM_THRESHOLD v_ms2us(0.2) /* in units/us */ #define DEFAULT_ACCELERATION 2.0 /* unitless factor */ #define DEFAULT_INCLINE 1.1 /* unitless factor */ struct pointer_accelerator { struct motion_filter base; accel_profile_func_t profile; double velocity; /* units/us */ double last_velocity; /* units/us */ struct pointer_trackers trackers; double threshold; /* units/us */ double accel; /* unitless factor */ double incline; /* incline of the function */ int dpi; }; /** * Calculate the acceleration factor for the given delta with the timestamp. * * @param accel The acceleration filter * @param unaccelerated The raw delta in the device's dpi * @param data Caller-specific data * @param time Current time in µs * * @return A unitless acceleration factor, to be applied to the delta */ static inline double calculate_acceleration_factor(struct pointer_accelerator *accel, const struct device_float_coords *unaccelerated, void *data, uint64_t time) { double velocity; /* units/us in device-native dpi*/ double accel_factor; trackers_feed(&accel->trackers, unaccelerated, time); velocity = trackers_velocity(&accel->trackers, time); accel_factor = calculate_acceleration_simpsons(&accel->base, accel->profile, data, velocity, accel->last_velocity, time); accel->last_velocity = velocity; return accel_factor; } /** * Generic filter that calculates the acceleration factor and applies it to * the coordinates. * * @param filter The acceleration filter * @param unaccelerated The raw delta in the device's dpi * @param data Caller-specific data * @param time Current time in µs * * @return An accelerated tuple of coordinates representing accelerated * motion, still in device units. */ static struct device_float_coords accelerator_filter_generic(struct motion_filter *filter, const struct device_float_coords *unaccelerated, void *data, uint64_t time) { struct pointer_accelerator *accel = (struct pointer_accelerator *) filter; double accel_value; /* unitless factor */ struct device_float_coords accelerated; accel_value = calculate_acceleration_factor(accel, unaccelerated, data, time); accelerated.x = accel_value * unaccelerated->x; accelerated.y = accel_value * unaccelerated->y; return accelerated; } static struct normalized_coords accelerator_filter_pre_normalized(struct motion_filter *filter, const struct device_float_coords *unaccelerated, void *data, uint64_t time) { struct pointer_accelerator *accel = (struct pointer_accelerator *) filter; struct normalized_coords normalized; struct device_float_coords converted, accelerated; /* Accelerate for normalized units and return normalized units. API requires device_floats, so we just copy the bits around */ normalized = normalize_for_dpi(unaccelerated, accel->dpi); converted.x = normalized.x; converted.y = normalized.y; accelerated = accelerator_filter_generic(filter, &converted, data, time); normalized.x = accelerated.x; normalized.y = accelerated.y; return normalized; } /** * Generic filter that does nothing beyond converting from the device's * native dpi into normalized coordinates. * * @param filter The acceleration filter * @param unaccelerated The raw delta in the device's dpi * @param data Caller-specific data * @param time Current time in µs * * @return An accelerated tuple of coordinates representing normalized * motion */ static struct normalized_coords accelerator_filter_noop(struct motion_filter *filter, const struct device_float_coords *unaccelerated, void *data, uint64_t time) { struct pointer_accelerator *accel = (struct pointer_accelerator *) filter; return normalize_for_dpi(unaccelerated, accel->dpi); } static void accelerator_restart(struct motion_filter *filter, void *data, uint64_t time) { struct pointer_accelerator *accel = (struct pointer_accelerator *) filter; trackers_reset(&accel->trackers, time); } static void accelerator_destroy(struct motion_filter *filter) { struct pointer_accelerator *accel = (struct pointer_accelerator *) filter; trackers_free(&accel->trackers); free(accel); } static bool accelerator_set_speed(struct motion_filter *filter, double speed_adjustment) { struct pointer_accelerator *accel_filter = (struct pointer_accelerator *)filter; assert(speed_adjustment >= -1.0 && speed_adjustment <= 1.0); /* Note: the numbers below are nothing but trial-and-error magic, don't read more into them other than "they mostly worked ok" */ /* delay when accel kicks in */ accel_filter->threshold = DEFAULT_THRESHOLD - v_ms2us(0.25) * speed_adjustment; if (accel_filter->threshold < MINIMUM_THRESHOLD) accel_filter->threshold = MINIMUM_THRESHOLD; /* adjust max accel factor */ accel_filter->accel = DEFAULT_ACCELERATION + speed_adjustment * 1.5; /* higher speed -> faster to reach max */ accel_filter->incline = DEFAULT_INCLINE + speed_adjustment * 0.75; filter->speed_adjustment = speed_adjustment; return true; } double pointer_accel_profile_linear(struct motion_filter *filter, void *data, double speed_in, /* in device units (units/µs) */ uint64_t time) { struct pointer_accelerator *accel_filter = (struct pointer_accelerator *)filter; const double max_accel = accel_filter->accel; /* unitless factor */ const double threshold = accel_filter->threshold; /* units/us */ const double incline = accel_filter->incline; double factor; /* unitless */ /* Normalize to 1000dpi, because the rest below relies on that */ speed_in = speed_in * DEFAULT_MOUSE_DPI/accel_filter->dpi; /* Our acceleration function calculates a factor to accelerate input deltas with. The function is a double incline with a plateau, with a rough shape like this: accel factor ^ | / | _____/ | / |/ +-------------> speed in The two inclines are linear functions in the form y = ax + b where y is speed_out x is speed_in a is the incline of acceleration b is minimum acceleration factor for speeds up to 0.07 u/ms, we decelerate, down to 30% of input speed. hence 1 = a * 0.07 + 0.3 0.7 = a * 0.07 => a := 10 deceleration function is thus: y = 10x + 0.3 Note: * 0.07u/ms as threshold is a result of trial-and-error and has no other intrinsic meaning. * 0.3 is chosen simply because it is above the Nyquist frequency for subpixel motion within a pixel. */ if (v_us2ms(speed_in) < 0.07) { factor = 10 * v_us2ms(speed_in) + 0.3; /* up to the threshold, we keep factor 1, i.e. 1:1 movement */ } else if (speed_in < threshold) { factor = 1; } else { /* Acceleration function above the threshold: y = ax' + b where T is threshold x is speed_in x' is speed and y(T) == 1 hence 1 = ax' + 1 => x' := (x - T) */ factor = incline * v_us2ms(speed_in - threshold) + 1; } /* Cap at the maximum acceleration factor */ factor = min(max_accel, factor); return factor; } struct motion_filter_interface accelerator_interface = { .type = LIBINPUT_CONFIG_ACCEL_PROFILE_ADAPTIVE, .filter = accelerator_filter_pre_normalized, .filter_constant = accelerator_filter_noop, .restart = accelerator_restart, .destroy = accelerator_destroy, .set_speed = accelerator_set_speed, }; static struct pointer_accelerator * create_default_filter(int dpi, bool use_velocity_averaging) { struct pointer_accelerator *filter; filter = zalloc(sizeof *filter); filter->last_velocity = 0.0; trackers_init(&filter->trackers, use_velocity_averaging ? 16 : 2); filter->threshold = DEFAULT_THRESHOLD; filter->accel = DEFAULT_ACCELERATION; filter->incline = DEFAULT_INCLINE; filter->dpi = dpi; return filter; } struct motion_filter * create_pointer_accelerator_filter_linear(int dpi, bool use_velocity_averaging) { struct pointer_accelerator *filter; filter = create_default_filter(dpi, use_velocity_averaging); if (!filter) return NULL; filter->base.interface = &accelerator_interface; filter->profile = pointer_accel_profile_linear; return &filter->base; }