/* * Copyright © 1999 Henry Davies * Copyright © 2001 Stefan Gmeiner * Copyright © 2002 S. Lehner * Copyright © 2002 Peter Osterlund * Copyright © 2002 Linuxcare Inc. David Kennedy * Copyright © 2003 Hartwig Felger * Copyright © 2003 Jörg Bösner * Copyright © 2003 Fred Hucht * Copyright © 2004 Alexei Gilchrist * Copyright © 2004 Matthias Ihmig * Copyright © 2006 Stefan Bethge * Copyright © 2006 Christian Thaeter * Copyright © 2007 Joseph P. Skudlarek * Copyright © 2008 Fedor P. Goncharov * Copyright © 2008-2009 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: * Joseph P. Skudlarek * Christian Thaeter * Stefan Bethge * Matthias Ihmig * Alexei Gilchrist * Jörg Bösner * Hartwig Felger * Peter Osterlund * S. Lehner * Stefan Gmeiner * Henry Davies for the * Linuxcare Inc. David Kennedy * Fred Hucht * Fedor P. Goncharov * Simon Thum * * Trademarks are the property of their respective owners. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include "synaptics.h" #include "synapticsstr.h" #include "synaptics-properties.h" typedef enum { NO_EDGE = 0, BOTTOM_EDGE = 1, TOP_EDGE = 2, LEFT_EDGE = 4, RIGHT_EDGE = 8, LEFT_BOTTOM_EDGE = BOTTOM_EDGE | LEFT_EDGE, RIGHT_BOTTOM_EDGE = BOTTOM_EDGE | RIGHT_EDGE, RIGHT_TOP_EDGE = TOP_EDGE | RIGHT_EDGE, LEFT_TOP_EDGE = TOP_EDGE | LEFT_EDGE } edge_type; /* * We expect to be receiving a steady 80 packets/sec (which gives 40 * reports/sec with more than one finger on the pad, as Advanced Gesture Mode * requires two PS/2 packets per report). Instead of a random scattering of * magic 13 and 20ms numbers scattered throughout the driver, introduce * POLL_MS as 14ms, which is slightly less than 80Hz. 13ms is closer to * 80Hz, but if the kernel event reporting was even slightly delayed, * we would produce synthetic motion followed immediately by genuine * motion, so use 14. * * We use this to call back at a constant rate to at least produce the * illusion of smooth motion. It works a lot better than you'd expect. */ #define POLL_MS 14 #define MAX(a, b) (((a)>(b))?(a):(b)) #define MIN(a, b) (((a)<(b))?(a):(b)) #define TIME_DIFF(a, b) ((int)((a)-(b))) #define SQR(x) ((x) * (x)) #ifndef M_PI #define M_PI 3.14159265358979323846 #endif #ifndef M_SQRT1_2 #define M_SQRT1_2 0.70710678118654752440 /* 1/sqrt(2) */ #endif #define INPUT_BUFFER_SIZE 200 /***************************************************************************** * Forward declaration ****************************************************************************/ #if GET_ABI_MAJOR(ABI_XINPUT_VERSION) >= 12 static int SynapticsPreInit(InputDriverPtr drv, InputInfoPtr pInfo, int flags); #else static InputInfoPtr SynapticsPreInit(InputDriverPtr drv, IDevPtr dev, int flags); #endif static void SynapticsUnInit(InputDriverPtr drv, InputInfoPtr pInfo, int flags); static Bool DeviceControl(DeviceIntPtr, int); static void ReadInput(InputInfoPtr); static int HandleState(InputInfoPtr, struct SynapticsHwState*); static int ControlProc(InputInfoPtr, xDeviceCtl*); static int SwitchMode(ClientPtr, DeviceIntPtr, int); static Bool DeviceInit(DeviceIntPtr); static Bool DeviceOn(DeviceIntPtr); static Bool DeviceOff(DeviceIntPtr); static Bool DeviceClose(DeviceIntPtr); static Bool QueryHardware(InputInfoPtr); static void ReadDevDimensions(InputInfoPtr); static void ScaleCoordinates(SynapticsPrivate *priv, struct SynapticsHwState *hw); static void CalculateScalingCoeffs(SynapticsPrivate *priv); static void SanitizeDimensions(InputInfoPtr pInfo); void InitDeviceProperties(InputInfoPtr pInfo); int SetProperty(DeviceIntPtr dev, Atom property, XIPropertyValuePtr prop, BOOL checkonly); const static struct { const char *name; struct SynapticsProtocolOperations *proto_ops; } protocols[] = { #ifdef BUILD_EVENTCOMM {"event", &event_proto_operations}, #endif #ifdef BUILD_PSMCOMM {"psm", &psm_proto_operations}, #endif #ifdef BUILD_PS2COMM {"psaux", &psaux_proto_operations}, {"alps", &alps_proto_operations}, #endif {NULL, NULL} }; InputDriverRec SYNAPTICS = { 1, "synaptics", NULL, SynapticsPreInit, SynapticsUnInit, NULL, }; static XF86ModuleVersionInfo VersionRec = { "synaptics", 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} }; static pointer SetupProc(pointer module, pointer options, int *errmaj, int *errmin) { xf86AddInputDriver(&SYNAPTICS, module, 0); return module; } _X_EXPORT XF86ModuleData synapticsModuleData = { &VersionRec, &SetupProc, NULL }; /***************************************************************************** * Function Definitions ****************************************************************************/ /** * Fill in default dimensions for backends that cannot query the hardware. * Eventually, we want the edges to be 1900/5400 for x, 1900/4000 for y. * These values are based so that calculate_edge_widths() will give us the * right values. * * The default values 1900, etc. come from the dawn of time, when men where * men, or possibly apes. */ static void SanitizeDimensions(InputInfoPtr pInfo) { SynapticsPrivate *priv = (SynapticsPrivate *)pInfo->private; if (priv->minx >= priv->maxx) { priv->minx = 1615; priv->maxx = 5685; priv->resx = 0; xf86IDrvMsg(pInfo, X_PROBED, "invalid x-axis range. defaulting to %d - %d\n", priv->minx, priv->maxx); } if (priv->miny >= priv->maxy) { priv->miny = 1729; priv->maxy = 4171; priv->resy = 0; xf86IDrvMsg(pInfo, X_PROBED, "invalid y-axis range. defaulting to %d - %d\n", priv->miny, priv->maxy); } if (priv->minp >= priv->maxp) { priv->minp = 0; priv->maxp = 256; xf86IDrvMsg(pInfo, X_PROBED, "invalid pressure range. defaulting to %d - %d\n", priv->minp, priv->maxp); } if (priv->minw >= priv->maxw) { priv->minw = 0; priv->maxw = 16; xf86IDrvMsg(pInfo, X_PROBED, "invalid finger width range. defaulting to %d - %d\n", priv->minw, priv->maxw); } } static void SetDeviceAndProtocol(InputInfoPtr pInfo) { SynapticsPrivate *priv = pInfo->private; char *proto, *device; int i; proto = xf86SetStrOption(pInfo->options, "Protocol", NULL); device = xf86SetStrOption(pInfo->options, "Device", NULL); for (i = 0; protocols[i].name; i++) { if ((!device || !proto) && protocols[i].proto_ops->AutoDevProbe && protocols[i].proto_ops->AutoDevProbe(pInfo, device)) break; else if (proto && !strcmp(proto, protocols[i].name)) break; } free(proto); free(device); priv->proto_ops = protocols[i].proto_ops; } /* * Allocate and initialize read-only memory for the SynapticsParameters data to hold * driver settings. * The function will allocate shared memory if priv->shm_config is TRUE. */ static Bool alloc_shm_data(InputInfoPtr pInfo) { int shmid; SynapticsPrivate *priv = pInfo->private; if (priv->synshm) return TRUE; /* Already allocated */ if (priv->shm_config) { if ((shmid = shmget(SHM_SYNAPTICS, 0, 0)) != -1) shmctl(shmid, IPC_RMID, NULL); if ((shmid = shmget(SHM_SYNAPTICS, sizeof(SynapticsSHM), 0774 | IPC_CREAT)) == -1) { xf86IDrvMsg(pInfo, X_ERROR, "error shmget\n"); return FALSE; } if ((priv->synshm = (SynapticsSHM*)shmat(shmid, NULL, 0)) == NULL) { xf86IDrvMsg(pInfo, X_ERROR, "error shmat\n"); return FALSE; } } else { priv->synshm = calloc(1, sizeof(SynapticsSHM)); if (!priv->synshm) return FALSE; } return TRUE; } /* * Free SynapticsParameters data previously allocated by alloc_shm_data(). */ static void free_shm_data(SynapticsPrivate *priv) { int shmid; if (!priv->synshm) return; if (priv->shm_config) { if ((shmid = shmget(SHM_SYNAPTICS, 0, 0)) != -1) shmctl(shmid, IPC_RMID, NULL); } else { free(priv->synshm); } priv->synshm = NULL; } static void calculate_edge_widths(SynapticsPrivate *priv, int *l, int *r, int *t, int *b) { int width, height; int ewidth, eheight; /* edge width/height */ width = abs(priv->maxx - priv->minx); height = abs(priv->maxy - priv->miny); if (priv->model == MODEL_SYNAPTICS) { ewidth = width * .07; eheight = height * .07; } else if (priv->model == MODEL_ALPS) { ewidth = width * .15; eheight = height * .15; } else if (priv->model == MODEL_APPLETOUCH) { ewidth = width * .085; eheight = height * .085; } else { ewidth = width * .04; eheight = height * .054; } *l = priv->minx + ewidth; *r = priv->maxx - ewidth; *t = priv->miny + eheight; *b = priv->maxy - eheight; } /* Area options support both percent values and absolute values. This is * awkward. The xf86Set* calls will print to the log, but they'll * also print an error if we request a percent value but only have an * int. So - check first for percent, then call xf86Set* again to get * the log message. */ static int set_percent_option(pointer options, const char* optname, const int range, const int offset, const int default_value) { int result; #if GET_ABI_MAJOR(ABI_XINPUT_VERSION) >= 11 double percent = xf86CheckPercentOption(options, optname, -1); if (percent >= 0.0) { percent = xf86SetPercentOption(options, optname, -1); result = percent/100.0 * range + offset; } else #endif result = xf86SetIntOption(options, optname, default_value); return result; } static void set_default_parameters(InputInfoPtr pInfo) { SynapticsPrivate *priv = pInfo->private; /* read-only */ pointer opts = pInfo->options; /* read-only */ SynapticsParameters *pars = &priv->synpara; /* modified */ int horizScrollDelta, vertScrollDelta; /* pixels */ int tapMove; /* pixels */ int l, r, t, b; /* left, right, top, bottom */ int edgeMotionMinSpeed, edgeMotionMaxSpeed; /* pixels/second */ double accelFactor; /* 1/pixels */ int fingerLow, fingerHigh, fingerPress; /* pressure */ int emulateTwoFingerMinZ; /* pressure */ int emulateTwoFingerMinW; /* width */ int edgeMotionMinZ, edgeMotionMaxZ; /* pressure */ int pressureMotionMinZ, pressureMotionMaxZ; /* pressure */ int palmMinWidth, palmMinZ; /* pressure */ int tapButton1, tapButton2, tapButton3; int clickFinger1, clickFinger2, clickFinger3; Bool vertEdgeScroll, horizEdgeScroll; Bool vertTwoFingerScroll, horizTwoFingerScroll; int horizResolution = 1; int vertResolution = 1; int width, height, diag, range; int horizHyst, vertHyst; /* read the parameters */ if (priv->synshm) priv->synshm->version = (PACKAGE_VERSION_MAJOR*10000+PACKAGE_VERSION_MINOR*100+PACKAGE_VERSION_PATCHLEVEL); /* The synaptics specs specify typical edge widths of 4% on x, and 5.4% on * y (page 7) [Synaptics TouchPad Interfacing Guide, 510-000080 - A * Second Edition, http://www.synaptics.com/support/dev_support.cfm, 8 Sep * 2008]. We use 7% for both instead for synaptics devices, and 15% for * ALPS models. * http://bugs.freedesktop.org/show_bug.cgi?id=21214 * * If the range was autodetected, apply these edge widths to all four * sides. */ width = abs(priv->maxx - priv->minx); height = abs(priv->maxy - priv->miny); diag = sqrt(width * width + height * height); calculate_edge_widths(priv, &l, &r, &t, &b); /* Again, based on typical x/y range and defaults */ horizScrollDelta = diag * .020; vertScrollDelta = diag * .020; tapMove = diag * .044; edgeMotionMinSpeed = 1; edgeMotionMaxSpeed = diag * .080; accelFactor = 200.0 / diag; /* trial-and-error */ /* hysteresis, assume >= 0 is a detected value (e.g. evdev fuzz) */ horizHyst = pars->hyst_x >= 0 ? pars->hyst_x : diag * 0.005; vertHyst = pars->hyst_y >= 0 ? pars->hyst_y : diag * 0.005; range = priv->maxp - priv->minp; /* scaling based on defaults and a pressure of 256 */ fingerLow = priv->minp + range * (25.0/256); fingerHigh = priv->minp + range * (30.0/256); fingerPress = priv->minp + range * 1.000; emulateTwoFingerMinZ = priv->minp + range * (282.0/256); edgeMotionMinZ = priv->minp + range * (30.0/256); edgeMotionMaxZ = priv->minp + range * (160.0/256); pressureMotionMinZ = priv->minp + range * (30.0/256); pressureMotionMaxZ = priv->minp + range * (160.0/256); palmMinZ = priv->minp + range * (200.0/256); range = priv->maxw - priv->minw; /* scaling based on defaults below and a tool width of 16 */ palmMinWidth = priv->minw + range * (10.0/16); emulateTwoFingerMinW = priv->minw + range * (7.0/16); /* Enable tap if we don't have a phys left button */ tapButton1 = priv->has_left ? 0 : 1; tapButton2 = priv->has_left ? 0 : 3; tapButton3 = priv->has_left ? 0 : 2; /* Enable multifinger-click if only have one physical button, otherwise clickFinger is always button 1. */ clickFinger1 = 1; clickFinger2 = (priv->has_right || priv->has_middle) ? 1 : 3; clickFinger3 = (priv->has_right || priv->has_middle) ? 1 : 2; /* Enable vert edge scroll if we can't detect doubletap */ vertEdgeScroll = priv->has_double ? FALSE : TRUE; horizEdgeScroll = FALSE; /* Enable twofinger scroll if we can detect doubletap */ vertTwoFingerScroll = priv->has_double ? TRUE : FALSE; horizTwoFingerScroll = FALSE; /* Use resolution reported by hardware if available */ if ((priv->resx > 0) && (priv->resy > 0)) { horizResolution = priv->resx; vertResolution = priv->resy; } /* set the parameters */ pars->left_edge = xf86SetIntOption(opts, "LeftEdge", l); pars->right_edge = xf86SetIntOption(opts, "RightEdge", r); pars->top_edge = xf86SetIntOption(opts, "TopEdge", t); pars->bottom_edge = xf86SetIntOption(opts, "BottomEdge", b); pars->area_top_edge = set_percent_option(opts, "AreaTopEdge", height, priv->miny, 0); pars->area_bottom_edge = set_percent_option(opts, "AreaBottomEdge", height, priv->miny, 0); pars->area_left_edge = set_percent_option(opts, "AreaLeftEdge", width, priv->minx, 0); pars->area_right_edge = set_percent_option(opts, "AreaRightEdge", width, priv->minx, 0); pars->hyst_x = set_percent_option(opts, "HorizHysteresis", width, 0, horizHyst); pars->hyst_y = set_percent_option(opts, "VertHysteresis", height, 0, vertHyst); pars->finger_low = xf86SetIntOption(opts, "FingerLow", fingerLow); pars->finger_high = xf86SetIntOption(opts, "FingerHigh", fingerHigh); pars->finger_press = xf86SetIntOption(opts, "FingerPress", fingerPress); pars->tap_time = xf86SetIntOption(opts, "MaxTapTime", 180); pars->tap_move = xf86SetIntOption(opts, "MaxTapMove", tapMove); pars->tap_time_2 = xf86SetIntOption(opts, "MaxDoubleTapTime", 180); pars->click_time = xf86SetIntOption(opts, "ClickTime", 100); pars->fast_taps = xf86SetBoolOption(opts, "FastTaps", FALSE); pars->emulate_mid_button_time = xf86SetIntOption(opts, "EmulateMidButtonTime", 75); pars->emulate_twofinger_z = xf86SetIntOption(opts, "EmulateTwoFingerMinZ", emulateTwoFingerMinZ); pars->emulate_twofinger_w = xf86SetIntOption(opts, "EmulateTwoFingerMinW", emulateTwoFingerMinW); pars->scroll_dist_vert = xf86SetIntOption(opts, "VertScrollDelta", horizScrollDelta); pars->scroll_dist_horiz = xf86SetIntOption(opts, "HorizScrollDelta", vertScrollDelta); pars->scroll_edge_vert = xf86SetBoolOption(opts, "VertEdgeScroll", vertEdgeScroll); pars->scroll_edge_horiz = xf86SetBoolOption(opts, "HorizEdgeScroll", horizEdgeScroll); pars->scroll_edge_corner = xf86SetBoolOption(opts, "CornerCoasting", FALSE); pars->scroll_twofinger_vert = xf86SetBoolOption(opts, "VertTwoFingerScroll", vertTwoFingerScroll); pars->scroll_twofinger_horiz = xf86SetBoolOption(opts, "HorizTwoFingerScroll", horizTwoFingerScroll); pars->edge_motion_min_z = xf86SetIntOption(opts, "EdgeMotionMinZ", edgeMotionMinZ); pars->edge_motion_max_z = xf86SetIntOption(opts, "EdgeMotionMaxZ", edgeMotionMaxZ); pars->edge_motion_min_speed = xf86SetIntOption(opts, "EdgeMotionMinSpeed", edgeMotionMinSpeed); pars->edge_motion_max_speed = xf86SetIntOption(opts, "EdgeMotionMaxSpeed", edgeMotionMaxSpeed); pars->edge_motion_use_always = xf86SetBoolOption(opts, "EdgeMotionUseAlways", FALSE); if (priv->has_scrollbuttons) { pars->updown_button_scrolling = xf86SetBoolOption(opts, "UpDownScrolling", TRUE); pars->leftright_button_scrolling = xf86SetBoolOption(opts, "LeftRightScrolling", TRUE); pars->updown_button_repeat = xf86SetBoolOption(opts, "UpDownScrollRepeat", TRUE); pars->leftright_button_repeat = xf86SetBoolOption(opts, "LeftRightScrollRepeat", TRUE); } pars->scroll_button_repeat = xf86SetIntOption(opts,"ScrollButtonRepeat", 100); pars->touchpad_off = xf86SetIntOption(opts, "TouchpadOff", 0); pars->locked_drags = xf86SetBoolOption(opts, "LockedDrags", FALSE); pars->locked_drag_time = xf86SetIntOption(opts, "LockedDragTimeout", 5000); pars->tap_action[RT_TAP] = xf86SetIntOption(opts, "RTCornerButton", 0); pars->tap_action[RB_TAP] = xf86SetIntOption(opts, "RBCornerButton", 0); pars->tap_action[LT_TAP] = xf86SetIntOption(opts, "LTCornerButton", 0); pars->tap_action[LB_TAP] = xf86SetIntOption(opts, "LBCornerButton", 0); pars->tap_action[F1_TAP] = xf86SetIntOption(opts, "TapButton1", tapButton1); pars->tap_action[F2_TAP] = xf86SetIntOption(opts, "TapButton2", tapButton2); pars->tap_action[F3_TAP] = xf86SetIntOption(opts, "TapButton3", tapButton3); pars->click_action[F1_CLICK1] = xf86SetIntOption(opts, "ClickFinger1", clickFinger1); pars->click_action[F2_CLICK1] = xf86SetIntOption(opts, "ClickFinger2", clickFinger2); pars->click_action[F3_CLICK1] = xf86SetIntOption(opts, "ClickFinger3", clickFinger3); pars->circular_scrolling = xf86SetBoolOption(opts, "CircularScrolling", FALSE); pars->circular_trigger = xf86SetIntOption(opts, "CircScrollTrigger", 0); pars->circular_pad = xf86SetBoolOption(opts, "CircularPad", FALSE); pars->palm_detect = xf86SetBoolOption(opts, "PalmDetect", FALSE); pars->palm_min_width = xf86SetIntOption(opts, "PalmMinWidth", palmMinWidth); pars->palm_min_z = xf86SetIntOption(opts, "PalmMinZ", palmMinZ); pars->single_tap_timeout = xf86SetIntOption(opts, "SingleTapTimeout", 180); pars->press_motion_min_z = xf86SetIntOption(opts, "PressureMotionMinZ", pressureMotionMinZ); pars->press_motion_max_z = xf86SetIntOption(opts, "PressureMotionMaxZ", pressureMotionMaxZ); pars->min_speed = xf86SetRealOption(opts, "MinSpeed", 0.4); pars->max_speed = xf86SetRealOption(opts, "MaxSpeed", 0.7); pars->accl = xf86SetRealOption(opts, "AccelFactor", accelFactor); pars->trackstick_speed = xf86SetRealOption(opts, "TrackstickSpeed", 40); pars->scroll_dist_circ = xf86SetRealOption(opts, "CircScrollDelta", 0.1); pars->coasting_speed = xf86SetRealOption(opts, "CoastingSpeed", 20.0); pars->coasting_friction = xf86SetRealOption(opts, "CoastingFriction", 50); pars->press_motion_min_factor = xf86SetRealOption(opts, "PressureMotionMinFactor", 1.0); pars->press_motion_max_factor = xf86SetRealOption(opts, "PressureMotionMaxFactor", 1.0); pars->grab_event_device = xf86SetBoolOption(opts, "GrabEventDevice", TRUE); pars->tap_and_drag_gesture = xf86SetBoolOption(opts, "TapAndDragGesture", TRUE); pars->resolution_horiz = xf86SetIntOption(opts, "HorizResolution", horizResolution); pars->resolution_vert = xf86SetIntOption(opts, "VertResolution", vertResolution); /* Warn about (and fix) incorrectly configured TopEdge/BottomEdge parameters */ if (pars->top_edge > pars->bottom_edge) { int tmp = pars->top_edge; pars->top_edge = pars->bottom_edge; pars->bottom_edge = tmp; xf86IDrvMsg(pInfo, X_WARNING, "TopEdge is bigger than BottomEdge. Fixing.\n"); } } static float SynapticsAccelerationProfile(DeviceIntPtr dev, DeviceVelocityPtr vel, float velocity, float thr, float acc) { InputInfoPtr pInfo = dev->public.devicePrivate; SynapticsPrivate *priv = (SynapticsPrivate *) (pInfo->private); SynapticsParameters* para = &priv->synpara; double accelfct; /* * synaptics accel was originally base on device coordinate based * velocity, which we recover this way so para->accl retains its scale. */ velocity /= vel->const_acceleration; /* speed up linear with finger velocity */ accelfct = velocity * para->accl; /* clip acceleration factor */ if (accelfct > para->max_speed * acc) accelfct = para->max_speed * acc; else if (accelfct < para->min_speed) accelfct = para->min_speed; /* modify speed according to pressure */ if (priv->moving_state == MS_TOUCHPAD_RELATIVE) { int minZ = para->press_motion_min_z; int maxZ = para->press_motion_max_z; double minFctr = para->press_motion_min_factor; double maxFctr = para->press_motion_max_factor; if (priv->hwState.z <= minZ) { accelfct *= minFctr; } else if (priv->hwState.z >= maxZ) { accelfct *= maxFctr; } else { accelfct *= minFctr + (priv->hwState.z - minZ) * (maxFctr - minFctr) / (maxZ - minZ); } } return accelfct; } #if GET_ABI_MAJOR(ABI_XINPUT_VERSION) < 12 static int NewSynapticsPreInit(InputDriverPtr drv, InputInfoPtr pInfo, int flags); /* * called by the module loader for initialization */ static InputInfoPtr SynapticsPreInit(InputDriverPtr drv, IDevPtr dev, int flags) { InputInfoPtr pInfo; /* Allocate a new InputInfoRec and add it to the head xf86InputDevs. */ pInfo = xf86AllocateInput(drv, 0); if (!pInfo) { return NULL; } /* initialize the InputInfoRec */ pInfo->name = dev->identifier; pInfo->reverse_conversion_proc = NULL; pInfo->dev = NULL; pInfo->private_flags = 0; pInfo->flags = XI86_SEND_DRAG_EVENTS; pInfo->conf_idev = dev; pInfo->always_core_feedback = 0; xf86CollectInputOptions(pInfo, NULL, NULL); if (NewSynapticsPreInit(drv, pInfo, flags) != Success) return NULL; pInfo->flags |= XI86_CONFIGURED; return pInfo; } static int NewSynapticsPreInit(InputDriverPtr drv, InputInfoPtr pInfo, int flags) #else static int SynapticsPreInit(InputDriverPtr drv, InputInfoPtr pInfo, int flags) #endif { SynapticsPrivate *priv; /* allocate memory for SynapticsPrivateRec */ priv = calloc(1, sizeof(SynapticsPrivate)); if (!priv) return BadAlloc; pInfo->type_name = XI_TOUCHPAD; pInfo->device_control = DeviceControl; pInfo->read_input = ReadInput; pInfo->control_proc = ControlProc; pInfo->switch_mode = SwitchMode; pInfo->private = priv; /* allocate now so we don't allocate in the signal handler */ priv->timer = TimerSet(NULL, 0, 0, NULL, NULL); if (!priv->timer) { free(priv); return BadAlloc; } /* may change pInfo->options */ SetDeviceAndProtocol(pInfo); if (priv->proto_ops == NULL) { xf86IDrvMsg(pInfo, X_ERROR, "Synaptics driver unable to detect protocol\n"); goto SetupProc_fail; } priv->device = xf86FindOptionValue(pInfo->options, "Device"); /* open the touchpad device */ pInfo->fd = xf86OpenSerial(pInfo->options); if (pInfo->fd == -1) { xf86IDrvMsg(pInfo, X_ERROR, "Synaptics driver unable to open device\n"); goto SetupProc_fail; } xf86ErrorFVerb(6, "port opened successfully\n"); /* initialize variables */ priv->repeatButtons = 0; priv->nextRepeat = 0; priv->count_packet_finger = 0; priv->tap_state = TS_START; priv->tap_button = 0; priv->tap_button_state = TBS_BUTTON_UP; priv->touch_on.millis = 0; priv->synpara.hyst_x = -1; priv->synpara.hyst_y = -1; /* read hardware dimensions */ ReadDevDimensions(pInfo); /* install shared memory or normal memory for parameters */ priv->shm_config = xf86SetBoolOption(pInfo->options, "SHMConfig", FALSE); set_default_parameters(pInfo); CalculateScalingCoeffs(priv); if (!alloc_shm_data(pInfo)) goto SetupProc_fail; priv->comm.buffer = XisbNew(pInfo->fd, INPUT_BUFFER_SIZE); if (!QueryHardware(pInfo)) { xf86IDrvMsg(pInfo, X_ERROR, "Unable to query/initialize Synaptics hardware.\n"); goto SetupProc_fail; } xf86ProcessCommonOptions(pInfo, pInfo->options); if (pInfo->fd != -1) { if (priv->comm.buffer) { XisbFree(priv->comm.buffer); priv->comm.buffer = NULL; } xf86CloseSerial(pInfo->fd); } pInfo->fd = -1; return Success; SetupProc_fail: if (pInfo->fd >= 0) { xf86CloseSerial(pInfo->fd); pInfo->fd = -1; } if (priv->comm.buffer) XisbFree(priv->comm.buffer); free_shm_data(priv); free(priv->proto_data); free(priv->timer); free(priv); pInfo->private = NULL; return BadAlloc; } /* * Uninitialize the device. */ static void SynapticsUnInit(InputDriverPtr drv, InputInfoPtr pInfo, int flags) { SynapticsPrivate *priv = ((SynapticsPrivate *)pInfo->private); if (priv && priv->timer) free(priv->timer); if (priv && priv->proto_data) free(priv->proto_data); free(pInfo->private); pInfo->private = NULL; xf86DeleteInput(pInfo, 0); } /* * Alter the control parameters for the mouse. Note that all special * protocol values are handled by dix. */ static void SynapticsCtrl(DeviceIntPtr device, PtrCtrl *ctrl) { } static Bool DeviceControl(DeviceIntPtr dev, int mode) { Bool RetValue; switch (mode) { case DEVICE_INIT: RetValue = DeviceInit(dev); break; case DEVICE_ON: RetValue = DeviceOn(dev); break; case DEVICE_OFF: RetValue = DeviceOff(dev); break; case DEVICE_CLOSE: RetValue = DeviceClose(dev); break; default: RetValue = BadValue; } return RetValue; } static Bool DeviceOn(DeviceIntPtr dev) { InputInfoPtr pInfo = dev->public.devicePrivate; SynapticsPrivate *priv = (SynapticsPrivate *) (pInfo->private); DBG(3, "Synaptics DeviceOn called\n"); pInfo->fd = xf86OpenSerial(pInfo->options); if (pInfo->fd == -1) { xf86IDrvMsg(pInfo, X_WARNING, "cannot open input device\n"); return !Success; } if (priv->proto_ops->DeviceOnHook) priv->proto_ops->DeviceOnHook(pInfo, &priv->synpara); priv->comm.buffer = XisbNew(pInfo->fd, INPUT_BUFFER_SIZE); if (!priv->comm.buffer) { xf86CloseSerial(pInfo->fd); pInfo->fd = -1; return !Success; } xf86FlushInput(pInfo->fd); /* reinit the pad */ if (!QueryHardware(pInfo)) { XisbFree(priv->comm.buffer); priv->comm.buffer = NULL; xf86CloseSerial(pInfo->fd); pInfo->fd = -1; return !Success; } xf86AddEnabledDevice(pInfo); dev->public.on = TRUE; return Success; } static Bool DeviceOff(DeviceIntPtr dev) { InputInfoPtr pInfo = dev->public.devicePrivate; SynapticsPrivate *priv = (SynapticsPrivate *) (pInfo->private); DBG(3, "Synaptics DeviceOff called\n"); if (pInfo->fd != -1) { TimerCancel(priv->timer); xf86RemoveEnabledDevice(pInfo); if (priv->proto_ops->DeviceOffHook) priv->proto_ops->DeviceOffHook(pInfo); if (priv->comm.buffer) { XisbFree(priv->comm.buffer); priv->comm.buffer = NULL; } xf86CloseSerial(pInfo->fd); pInfo->fd = -1; } dev->public.on = FALSE; return Success; } static Bool DeviceClose(DeviceIntPtr dev) { Bool RetValue; InputInfoPtr pInfo = dev->public.devicePrivate; SynapticsPrivate *priv = (SynapticsPrivate *) pInfo->private; RetValue = DeviceOff(dev); TimerFree(priv->timer); priv->timer = NULL; free_shm_data(priv); return RetValue; } static void InitAxesLabels(Atom *labels, int nlabels) { memset(labels, 0, nlabels * sizeof(Atom)); switch(nlabels) { default: case 2: labels[1] = XIGetKnownProperty(AXIS_LABEL_PROP_REL_Y); case 1: labels[0] = XIGetKnownProperty(AXIS_LABEL_PROP_REL_X); break; } } static void InitButtonLabels(Atom *labels, int nlabels) { memset(labels, 0, nlabels * sizeof(Atom)); switch(nlabels) { default: case 7: labels[6] = XIGetKnownProperty(BTN_LABEL_PROP_BTN_HWHEEL_RIGHT); case 6: labels[5] = XIGetKnownProperty(BTN_LABEL_PROP_BTN_HWHEEL_LEFT); case 5: labels[4] = XIGetKnownProperty(BTN_LABEL_PROP_BTN_WHEEL_DOWN); case 4: labels[3] = XIGetKnownProperty(BTN_LABEL_PROP_BTN_WHEEL_UP); case 3: labels[2] = XIGetKnownProperty(BTN_LABEL_PROP_BTN_RIGHT); case 2: labels[1] = XIGetKnownProperty(BTN_LABEL_PROP_BTN_MIDDLE); case 1: labels[0] = XIGetKnownProperty(BTN_LABEL_PROP_BTN_LEFT); break; } } static Bool DeviceInit(DeviceIntPtr dev) { InputInfoPtr pInfo = dev->public.devicePrivate; SynapticsPrivate *priv = (SynapticsPrivate *) (pInfo->private); Atom float_type, prop; float tmpf; unsigned char map[SYN_MAX_BUTTONS + 1]; int i; int min, max; Atom btn_labels[SYN_MAX_BUTTONS] = { 0 }; Atom axes_labels[2] = { 0 }; DeviceVelocityPtr pVel; InitAxesLabels(axes_labels, 2); InitButtonLabels(btn_labels, SYN_MAX_BUTTONS); DBG(3, "Synaptics DeviceInit called\n"); for (i = 0; i <= SYN_MAX_BUTTONS; i++) map[i] = i; dev->public.on = FALSE; InitPointerDeviceStruct((DevicePtr)dev, map, SYN_MAX_BUTTONS, btn_labels, SynapticsCtrl, GetMotionHistorySize(), 2, axes_labels); /* * setup dix acceleration to match legacy synaptics settings, and * etablish a device-specific profile to do stuff like pressure-related * acceleration. */ if (NULL != (pVel = GetDevicePredictableAccelData(dev))) { SetDeviceSpecificAccelerationProfile(pVel, SynapticsAccelerationProfile); /* float property type */ float_type = XIGetKnownProperty(XATOM_FLOAT); /* translate MinAcc to constant deceleration. * May be overridden in xf86InitValuatorDefaults */ tmpf = 1.0 / priv->synpara.min_speed; xf86IDrvMsg(pInfo, X_CONFIG, "(accel) MinSpeed is now constant deceleration " "%.1f\n", tmpf); prop = XIGetKnownProperty(ACCEL_PROP_CONSTANT_DECELERATION); XIChangeDeviceProperty(dev, prop, float_type, 32, PropModeReplace, 1, &tmpf, FALSE); /* adjust accordingly */ priv->synpara.max_speed /= priv->synpara.min_speed; priv->synpara.min_speed = 1.0; /* synaptics seems to report 80 packet/s, but dix scales for * 100 packet/s by default. */ pVel->corr_mul = 12.5f; /*1000[ms]/80[/s] = 12.5 */ xf86IDrvMsg(pInfo, X_CONFIG, "MaxSpeed is now %.2f\n", priv->synpara.max_speed); xf86IDrvMsg(pInfo, X_CONFIG, "AccelFactor is now %.3f\n", priv->synpara.accl); prop = XIGetKnownProperty(ACCEL_PROP_PROFILE_NUMBER); i = AccelProfileDeviceSpecific; XIChangeDeviceProperty(dev, prop, XA_INTEGER, 32, PropModeReplace, 1, &i, FALSE); } /* X valuator */ if (priv->minx < priv->maxx) { min = priv->minx; max = priv->maxx; } else { min = 0; max = -1; } xf86InitValuatorAxisStruct(dev, 0, axes_labels[0], min, max, priv->resx * 1000, 0, priv->resx * 1000 #if GET_ABI_MAJOR(ABI_XINPUT_VERSION) >= 12 , Relative #endif ); xf86InitValuatorDefaults(dev, 0); /* Y valuator */ if (priv->miny < priv->maxy) { min = priv->miny; max = priv->maxy; } else { min = 0; max = -1; } xf86InitValuatorAxisStruct(dev, 1, axes_labels[1], min, max, priv->resy * 1000, 0, priv->resy * 1000 #if GET_ABI_MAJOR(ABI_XINPUT_VERSION) >= 12 , Relative #endif ); xf86InitValuatorDefaults(dev, 1); if (!alloc_shm_data(pInfo)) return !Success; InitDeviceProperties(pInfo); XIRegisterPropertyHandler(pInfo->dev, SetProperty, NULL, NULL); return Success; } /* * Convert from absolute X/Y coordinates to a coordinate system where * -1 corresponds to the left/upper edge and +1 corresponds to the * right/lower edge. */ static void relative_coords(SynapticsPrivate *priv, int x, int y, double *relX, double *relY) { int minX = priv->synpara.left_edge; int maxX = priv->synpara.right_edge; int minY = priv->synpara.top_edge; int maxY = priv->synpara.bottom_edge; double xCenter = (minX + maxX) / 2.0; double yCenter = (minY + maxY) / 2.0; if ((maxX - xCenter > 0) && (maxY - yCenter > 0)) { *relX = (x - xCenter) / (maxX - xCenter); *relY = (y - yCenter) / (maxY - yCenter); } else { *relX = 0; *relY = 0; } } /* return angle of point relative to center */ static double angle(SynapticsPrivate *priv, int x, int y) { double xCenter = (priv->synpara.left_edge + priv->synpara.right_edge) / 2.0; double yCenter = (priv->synpara.top_edge + priv->synpara.bottom_edge) / 2.0; return atan2(-(y - yCenter), x - xCenter); } /* return angle difference */ static double diffa(double a1, double a2) { double da = fmod(a2 - a1, 2 * M_PI); if (da < 0) da += 2 * M_PI; if (da > M_PI) da -= 2 * M_PI; return da; } static edge_type circular_edge_detection(SynapticsPrivate *priv, int x, int y) { edge_type edge = 0; double relX, relY, relR; relative_coords(priv, x, y, &relX, &relY); relR = SQR(relX) + SQR(relY); if (relR > 1) { /* we are outside the ellipse enclosed by the edge parameters */ if (relX > M_SQRT1_2) edge |= RIGHT_EDGE; else if (relX < -M_SQRT1_2) edge |= LEFT_EDGE; if (relY < -M_SQRT1_2) edge |= TOP_EDGE; else if (relY > M_SQRT1_2) edge |= BOTTOM_EDGE; } return edge; } static edge_type edge_detection(SynapticsPrivate *priv, int x, int y) { edge_type edge = NO_EDGE; if (priv->synpara.circular_pad) return circular_edge_detection(priv, x, y); if (x > priv->synpara.right_edge) edge |= RIGHT_EDGE; else if (x < priv->synpara.left_edge) edge |= LEFT_EDGE; if (y < priv->synpara.top_edge) edge |= TOP_EDGE; else if (y > priv->synpara.bottom_edge) edge |= BOTTOM_EDGE; return edge; } /* Checks whether coordinates are in the Synaptics Area * or not. If no Synaptics Area is defined (i.e. if * priv->synpara.area_{left|right|top|bottom}_edge are * all set to zero), the function returns TRUE. */ static Bool is_inside_active_area(SynapticsPrivate *priv, int x, int y) { Bool inside_area = TRUE; if ((priv->synpara.area_left_edge != 0) && (x < priv->synpara.area_left_edge)) inside_area = FALSE; else if ((priv->synpara.area_right_edge != 0) && (x > priv->synpara.area_right_edge)) inside_area = FALSE; if ((priv->synpara.area_top_edge != 0) && (y < priv->synpara.area_top_edge)) inside_area = FALSE; else if ((priv->synpara.area_bottom_edge != 0) && (y > priv->synpara.area_bottom_edge)) inside_area = FALSE; return inside_area; } static CARD32 timerFunc(OsTimerPtr timer, CARD32 now, pointer arg) { InputInfoPtr pInfo = arg; SynapticsPrivate *priv = (SynapticsPrivate *) (pInfo->private); struct SynapticsHwState hw; int delay; int sigstate; CARD32 wakeUpTime; sigstate = xf86BlockSIGIO(); hw = priv->hwState; hw.millis = now; delay = HandleState(pInfo, &hw); /* * Workaround for wraparound bug in the TimerSet function. This bug is already * fixed in CVS, but this driver needs to work with XFree86 versions 4.2.x and * 4.3.x too. */ wakeUpTime = now + delay; if (wakeUpTime <= now) wakeUpTime = 0xffffffffL; priv->timer = TimerSet(priv->timer, TimerAbsolute, wakeUpTime, timerFunc, pInfo); xf86UnblockSIGIO(sigstate); return 0; } static int clamp(int val, int min, int max) { if (val < min) return min; else if (val < max) return val; else return max; } static Bool SynapticsGetHwState(InputInfoPtr pInfo, SynapticsPrivate *priv, struct SynapticsHwState *hw) { return priv->proto_ops->ReadHwState(pInfo, &priv->comm, hw); } /* * called for each full received packet from the touchpad */ static void ReadInput(InputInfoPtr pInfo) { SynapticsPrivate *priv = (SynapticsPrivate *) (pInfo->private); struct SynapticsHwState hw; int delay = 0; Bool newDelay = FALSE; while (SynapticsGetHwState(pInfo, priv, &hw)) { hw.millis = GetTimeInMillis(); priv->hwState = hw; delay = HandleState(pInfo, &hw); newDelay = TRUE; } if (newDelay) priv->timer = TimerSet(priv->timer, 0, delay, timerFunc, pInfo); } static int HandleMidButtonEmulation(SynapticsPrivate *priv, struct SynapticsHwState *hw, int *delay) { SynapticsParameters *para = &priv->synpara; Bool done = FALSE; int timeleft; int mid = 0; while (!done) { switch (priv->mid_emu_state) { case MBE_LEFT_CLICK: case MBE_RIGHT_CLICK: case MBE_OFF: priv->button_delay_millis = hw->millis; if (hw->left) { priv->mid_emu_state = MBE_LEFT; } else if (hw->right) { priv->mid_emu_state = MBE_RIGHT; } else { done = TRUE; } break; case MBE_LEFT: timeleft = TIME_DIFF(priv->button_delay_millis + para->emulate_mid_button_time, hw->millis); if (timeleft > 0) *delay = MIN(*delay, timeleft); /* timeout, but within the same ReadInput cycle! */ if ((timeleft <= 0) && !hw->left) { priv->mid_emu_state = MBE_LEFT_CLICK; done = TRUE; } else if ((!hw->left) || (timeleft <= 0)) { hw->left = TRUE; priv->mid_emu_state = MBE_TIMEOUT; done = TRUE; } else if (hw->right) { priv->mid_emu_state = MBE_MID; } else { hw->left = FALSE; done = TRUE; } break; case MBE_RIGHT: timeleft = TIME_DIFF(priv->button_delay_millis + para->emulate_mid_button_time, hw->millis); if (timeleft > 0) *delay = MIN(*delay, timeleft); /* timeout, but within the same ReadInput cycle! */ if ((timeleft <= 0) && !hw->right) { priv->mid_emu_state = MBE_RIGHT_CLICK; done = TRUE; } else if (!hw->right || (timeleft <= 0)) { hw->right = TRUE; priv->mid_emu_state = MBE_TIMEOUT; done = TRUE; } else if (hw->left) { priv->mid_emu_state = MBE_MID; } else { hw->right = FALSE; done = TRUE; } break; case MBE_MID: if (!hw->left && !hw->right) { priv->mid_emu_state = MBE_OFF; } else { mid = TRUE; hw->left = hw->right = FALSE; done = TRUE; } break; case MBE_TIMEOUT: if (!hw->left && !hw->right) { priv->mid_emu_state = MBE_OFF; } else { done = TRUE; } } } return mid; } static enum FingerState SynapticsDetectFinger(SynapticsPrivate *priv, struct SynapticsHwState *hw) { SynapticsParameters *para = &priv->synpara; enum FingerState finger; /* finger detection thru pressure and threshold */ if (hw->z > para->finger_press && priv->finger_state < FS_PRESSED) finger = FS_PRESSED; else if (hw->z > para->finger_high && priv->finger_state < FS_TOUCHED) finger = FS_TOUCHED; else if (hw->z < para->finger_low && priv->finger_state > FS_UNTOUCHED) finger = FS_UNTOUCHED; else finger = priv->finger_state; if (!para->palm_detect) return finger; /* palm detection */ if (finger) { if ((hw->z > para->palm_min_z) && (hw->fingerWidth > para->palm_min_width)) priv->palm = TRUE; } else { priv->palm = FALSE; } if (hw->x == 0) priv->avg_width = 0; else priv->avg_width += (hw->fingerWidth - priv->avg_width + 1) / 2; if (finger && !priv->finger_state) { int safe_width = MAX(hw->fingerWidth, priv->avg_width); if (hw->numFingers > 1 || /* more than one finger -> not a palm */ ((safe_width < 6) && (priv->prev_z < para->finger_high)) || /* thin finger, distinct touch -> not a palm */ ((safe_width < 7) && (priv->prev_z < para->finger_high / 2)))/* thin finger, distinct touch -> not a palm */ { /* leave finger value as is */ } else if (hw->z > priv->prev_z + 1) /* z not stable, may be a palm */ finger = FS_UNTOUCHED; else if (hw->z < priv->prev_z - 5) /* z not stable, may be a palm */ finger = FS_UNTOUCHED; else if (hw->fingerWidth > para->palm_min_width) /* finger width too large -> probably palm */ finger = FS_UNTOUCHED; } priv->prev_z = hw->z; if (priv->palm) finger = FS_UNTOUCHED; return finger; } static void SelectTapButton(SynapticsPrivate *priv, edge_type edge) { TapEvent tap; if (priv->synpara.touchpad_off == 2) { priv->tap_button = 0; return; } switch (priv->tap_max_fingers) { case 1: default: switch (edge) { case RIGHT_TOP_EDGE: DBG(7, "right top edge\n"); tap = RT_TAP; break; case RIGHT_BOTTOM_EDGE: DBG(7, "right bottom edge\n"); tap = RB_TAP; break; case LEFT_TOP_EDGE: DBG(7, "left top edge\n"); tap = LT_TAP; break; case LEFT_BOTTOM_EDGE: DBG(7, "left bottom edge\n"); tap = LB_TAP; break; default: DBG(7, "no edge\n"); tap = F1_TAP; break; } break; case 2: DBG(7, "two finger tap\n"); tap = F2_TAP; break; case 3: DBG(7, "three finger tap\n"); tap = F3_TAP; break; } priv->tap_button = priv->synpara.tap_action[tap]; priv->tap_button = clamp(priv->tap_button, 0, SYN_MAX_BUTTONS); } static void SetTapState(SynapticsPrivate *priv, enum TapState tap_state, int millis) { SynapticsParameters *para = &priv->synpara; DBG(7, "SetTapState - %d -> %d (millis:%d)\n", priv->tap_state, tap_state, millis); switch (tap_state) { case TS_START: priv->tap_button_state = TBS_BUTTON_UP; priv->tap_max_fingers = 0; break; case TS_1: priv->tap_button_state = TBS_BUTTON_UP; break; case TS_2A: if (para->fast_taps) priv->tap_button_state = TBS_BUTTON_DOWN; else priv->tap_button_state = TBS_BUTTON_UP; break; case TS_2B: priv->tap_button_state = TBS_BUTTON_UP; break; case TS_3: if (para->tap_and_drag_gesture) priv->tap_button_state = TBS_BUTTON_DOWN; else priv->tap_button_state = TBS_BUTTON_UP; break; case TS_SINGLETAP: if (para->fast_taps) priv->tap_button_state = TBS_BUTTON_UP; else priv->tap_button_state = TBS_BUTTON_DOWN; priv->touch_on.millis = millis; break; default: break; } priv->tap_state = tap_state; } static void SetMovingState(SynapticsPrivate *priv, enum MovingState moving_state, int millis) { DBG(7, "SetMovingState - %d -> %d center at %d/%d (millis:%d)\n", priv->moving_state, moving_state,priv->hwState.x, priv->hwState.y, millis); if (moving_state == MS_TRACKSTICK) { priv->trackstick_neutral_x = priv->hwState.x; priv->trackstick_neutral_y = priv->hwState.y; } priv->moving_state = moving_state; } static int GetTimeOut(SynapticsPrivate *priv) { SynapticsParameters *para = &priv->synpara; switch (priv->tap_state) { case TS_1: case TS_3: case TS_5: return para->tap_time; case TS_SINGLETAP: return para->click_time; case TS_2A: return para->single_tap_timeout; case TS_2B: return para->tap_time_2; case TS_4: return para->locked_drag_time; default: return -1; /* No timeout */ } } static int HandleTapProcessing(SynapticsPrivate *priv, struct SynapticsHwState *hw, enum FingerState finger, Bool inside_active_area) { SynapticsParameters *para = &priv->synpara; Bool touch, release, is_timeout, move; int timeleft, timeout; edge_type edge; int delay = 1000000000; if (priv->palm) return delay; touch = finger && !priv->finger_state; release = !finger && priv->finger_state; move = (finger && (priv->tap_max_fingers <= ((priv->horiz_scroll_twofinger_on || priv->vert_scroll_twofinger_on)? 2 : 1)) && ((abs(hw->x - priv->touch_on.x) >= para->tap_move) || (abs(hw->y - priv->touch_on.y) >= para->tap_move))); if (touch) { priv->touch_on.x = hw->x; priv->touch_on.y = hw->y; priv->touch_on.millis = hw->millis; } else if (release) { priv->touch_on.millis = hw->millis; } if (hw->z > para->finger_high) if (priv->tap_max_fingers < hw->numFingers) priv->tap_max_fingers = hw->numFingers; timeout = GetTimeOut(priv); timeleft = TIME_DIFF(priv->touch_on.millis + timeout, hw->millis); is_timeout = timeleft <= 0; restart: switch (priv->tap_state) { case TS_START: if (touch) SetTapState(priv, TS_1, hw->millis); break; case TS_1: if (move) { SetMovingState(priv, MS_TOUCHPAD_RELATIVE, hw->millis); SetTapState(priv, TS_MOVE, hw->millis); goto restart; } else if (is_timeout) { if (finger == FS_TOUCHED) { SetMovingState(priv, MS_TOUCHPAD_RELATIVE, hw->millis); } else if (finger == FS_PRESSED) { SetMovingState(priv, MS_TRACKSTICK, hw->millis); } SetTapState(priv, TS_MOVE, hw->millis); goto restart; } else if (release) { edge = edge_detection(priv, priv->touch_on.x, priv->touch_on.y); SelectTapButton(priv, edge); /* Disable taps outside of the active area */ if (!inside_active_area) { priv->tap_button = 0; } SetTapState(priv, TS_2A, hw->millis); } break; case TS_MOVE: if (move && priv->moving_state == MS_TRACKSTICK) { SetMovingState(priv, MS_TOUCHPAD_RELATIVE, hw->millis); } if (release) { SetMovingState(priv, MS_FALSE, hw->millis); SetTapState(priv, TS_START, hw->millis); } break; case TS_2A: if (touch) SetTapState(priv, TS_3, hw->millis); else if (is_timeout) SetTapState(priv, TS_SINGLETAP, hw->millis); break; case TS_2B: if (touch) { SetTapState(priv, TS_3, hw->millis); } else if (is_timeout) { SetTapState(priv, TS_START, hw->millis); priv->tap_button_state = TBS_BUTTON_DOWN_UP; } break; case TS_SINGLETAP: if (touch) SetTapState(priv, TS_1, hw->millis); else if (is_timeout) SetTapState(priv, TS_START, hw->millis); break; case TS_3: if (move) { if (para->tap_and_drag_gesture) { SetMovingState(priv, MS_TOUCHPAD_RELATIVE, hw->millis); SetTapState(priv, TS_DRAG, hw->millis); } else { SetTapState(priv, TS_1, hw->millis); } goto restart; } else if (is_timeout) { if (para->tap_and_drag_gesture) { if (finger == FS_TOUCHED) { SetMovingState(priv, MS_TOUCHPAD_RELATIVE, hw->millis); } else if (finger == FS_PRESSED) { SetMovingState(priv, MS_TRACKSTICK, hw->millis); } SetTapState(priv, TS_DRAG, hw->millis); } else { SetTapState(priv, TS_1, hw->millis); } goto restart; } else if (release) { SetTapState(priv, TS_2B, hw->millis); } break; case TS_DRAG: if (move) SetMovingState(priv, MS_TOUCHPAD_RELATIVE, hw->millis); if (release) { SetMovingState(priv, MS_FALSE, hw->millis); if (para->locked_drags) { SetTapState(priv, TS_4, hw->millis); } else { SetTapState(priv, TS_START, hw->millis); } } break; case TS_4: if (is_timeout) { SetTapState(priv, TS_START, hw->millis); goto restart; } if (touch) SetTapState(priv, TS_5, hw->millis); break; case TS_5: if (is_timeout || move) { SetTapState(priv, TS_DRAG, hw->millis); goto restart; } else if (release) { SetMovingState(priv, MS_FALSE, hw->millis); SetTapState(priv, TS_START, hw->millis); } break; } timeout = GetTimeOut(priv); if (timeout >= 0) { timeleft = TIME_DIFF(priv->touch_on.millis + timeout, hw->millis); delay = clamp(timeleft, 1, delay); } return delay; } #define HIST(a) (priv->move_hist[((priv->hist_index - (a) + SYNAPTICS_MOVE_HISTORY) % SYNAPTICS_MOVE_HISTORY)]) #define HIST_DELTA(a, b, e) ((HIST((a)).e) - (HIST((b)).e)) static void store_history(SynapticsPrivate *priv, int x, int y, unsigned int millis) { int idx = (priv->hist_index + 1) % SYNAPTICS_MOVE_HISTORY; priv->move_hist[idx].x = x; priv->move_hist[idx].y = y; priv->move_hist[idx].millis = millis; priv->hist_index = idx; } /* * Estimate the slope for the data sequence [x3, x2, x1, x0] by using * linear regression to fit a line to the data and use the slope of the * line. */ static double estimate_delta(double x0, double x1, double x2, double x3) { return x0 * 0.3 + x1 * 0.1 - x2 * 0.1 - x3 * 0.3; } /** * Applies hysteresis. center is shifted such that it is in range with * in by the margin again. The new center is returned. * @param in the current value * @param center the current center * @param margin the margin to center in which no change is applied * @return the new center (which might coincide with the previous) */ static int hysteresis(int in, int center, int margin) { int diff = in - center; if (abs(diff) <= margin) { diff = 0; } else if (diff > margin) { diff -= margin; } else if (diff < -margin) { diff += margin; } return center + diff; } static void get_delta_for_trackstick(SynapticsPrivate *priv, const struct SynapticsHwState *hw, double *dx, double *dy) { SynapticsParameters *para = &priv->synpara; double dtime = (hw->millis - HIST(0).millis) / 1000.0; *dx = (hw->x - priv->trackstick_neutral_x); *dy = (hw->y - priv->trackstick_neutral_y); *dx = *dx * dtime * para->trackstick_speed; *dy = *dy * dtime * para->trackstick_speed; } static void get_edge_speed(SynapticsPrivate *priv, const struct SynapticsHwState *hw, edge_type edge, int *x_edge_speed, int *y_edge_speed) { SynapticsParameters *para = &priv->synpara; int minZ = para->edge_motion_min_z; int maxZ = para->edge_motion_max_z; int minSpd = para->edge_motion_min_speed; int maxSpd = para->edge_motion_max_speed; int edge_speed; if (hw->z <= minZ) { edge_speed = minSpd; } else if (hw->z >= maxZ) { edge_speed = maxSpd; } else { edge_speed = minSpd + (hw->z - minZ) * (maxSpd - minSpd) / (maxZ - minZ); } if (!priv->synpara.circular_pad) { /* on rectangular pad */ if (edge & RIGHT_EDGE) { *x_edge_speed = edge_speed; } else if (edge & LEFT_EDGE) { *x_edge_speed = -edge_speed; } if (edge & TOP_EDGE) { *y_edge_speed = -edge_speed; } else if (edge & BOTTOM_EDGE) { *y_edge_speed = edge_speed; } } else if (edge) { /* at edge of circular pad */ double relX, relY; relative_coords(priv, hw->x, hw->y, &relX, &relY); *x_edge_speed = (int)(edge_speed * relX); *y_edge_speed = (int)(edge_speed * relY); } } static void get_delta(SynapticsPrivate *priv, const struct SynapticsHwState *hw, edge_type edge, double *dx, double *dy) { SynapticsParameters *para = &priv->synpara; double dtime = (hw->millis - HIST(0).millis) / 1000.0; double integral; double tmpf; int x_edge_speed = 0; int y_edge_speed = 0; /* HIST is full enough: priv->count_packet_finger > 3 */ *dx = estimate_delta(hw->x, HIST(0).x, HIST(1).x, HIST(2).x); *dy = estimate_delta(hw->y, HIST(0).y, HIST(1).y, HIST(2).y); if ((priv->tap_state == TS_DRAG) || para->edge_motion_use_always) get_edge_speed(priv, hw, edge, &x_edge_speed, &y_edge_speed); /* report edge speed as synthetic motion. Of course, it would be * cooler to report floats than to buffer, but anyway. */ tmpf = *dx + x_edge_speed * dtime + priv->frac_x; priv->frac_x = modf(tmpf, &integral); *dx = integral; tmpf = *dy + y_edge_speed * dtime + priv->frac_y; priv->frac_y = modf(tmpf, &integral); *dy = integral; } /** * Compute relative motion ('deltas') including edge motion xor trackstick. */ static int ComputeDeltas(SynapticsPrivate *priv, const struct SynapticsHwState *hw, edge_type edge, int *dxP, int *dyP, Bool inside_area) { enum MovingState moving_state; double dx, dy; int delay = 1000000000; dx = dy = 0; moving_state = priv->moving_state; if (moving_state == MS_FALSE) { switch (priv->tap_state) { case TS_MOVE: case TS_DRAG: moving_state = MS_TOUCHPAD_RELATIVE; break; case TS_1: case TS_3: case TS_5: if (hw->numFingers == 1) moving_state = MS_TOUCHPAD_RELATIVE; break; default: break; } } if (!inside_area || !moving_state || priv->palm || priv->vert_scroll_edge_on || priv->horiz_scroll_edge_on || priv->vert_scroll_twofinger_on || priv->horiz_scroll_twofinger_on || priv->circ_scroll_on || priv->prevFingers != hw->numFingers) { /* reset packet counter. */ priv->count_packet_finger = 0; goto out; } /* To create the illusion of fluid motion, call back at roughly the report * rate, even in the absence of new hardware events; see comment above * POLL_MS declaration. */ delay = MIN(delay, POLL_MS); if (priv->count_packet_finger <= 3) /* min. 3 packets, see get_delta() */ goto skip; /* skip the lot */ if (priv->moving_state == MS_TRACKSTICK) get_delta_for_trackstick(priv, hw, &dx, &dy); else if (moving_state == MS_TOUCHPAD_RELATIVE) get_delta(priv, hw, edge, &dx, &dy); skip: priv->count_packet_finger++; out: priv->prevFingers = hw->numFingers; *dxP = dx; *dyP = dy; return delay; } struct ScrollData { int left, right, up, down; }; static double estimate_delta_circ(SynapticsPrivate *priv) { double a1 = angle(priv, HIST(3).x, HIST(3).y); double a2 = angle(priv, HIST(2).x, HIST(2).y); double a3 = angle(priv, HIST(1).x, HIST(1).y); double a4 = angle(priv, HIST(0).x, HIST(0).y); double d1 = diffa(a2, a1); double d2 = d1 + diffa(a3, a2); double d3 = d2 + diffa(a4, a3); return estimate_delta(d3, d2, d1, 0); } /* vert and horiz are to know which direction to start coasting * circ is true if the user had been circular scrolling. */ static void start_coasting(SynapticsPrivate *priv, struct SynapticsHwState *hw, Bool vert, Bool horiz, Bool circ) { SynapticsParameters *para = &priv->synpara; priv->autoscroll_y = 0.0; priv->autoscroll_x = 0.0; if ((priv->scroll_packet_count > 3) && (para->coasting_speed > 0.0)) { double pkt_time = HIST_DELTA(0, 3, millis) / 1000.0; if (vert && !circ) { double dy = estimate_delta(HIST(0).y, HIST(1).y, HIST(2).y, HIST(3).y); int sdelta = para->scroll_dist_vert; if (pkt_time > 0 && sdelta > 0) { double scrolls_per_sec = dy / pkt_time / sdelta; if (fabs(scrolls_per_sec) >= para->coasting_speed) { priv->autoscroll_yspd = scrolls_per_sec; priv->autoscroll_y = (hw->y - priv->scroll_y) / (double)sdelta; } } } if (horiz && !circ){ double dx = estimate_delta(HIST(0).x, HIST(1).x, HIST(2).x, HIST(3).x); int sdelta = para->scroll_dist_horiz; if (pkt_time > 0 && sdelta > 0) { double scrolls_per_sec = dx / pkt_time / sdelta; if (fabs(scrolls_per_sec) >= para->coasting_speed) { priv->autoscroll_xspd = scrolls_per_sec; priv->autoscroll_x = (hw->x - priv->scroll_x) / (double)sdelta; } } } if (circ) { double da = estimate_delta_circ(priv); double sdelta = para->scroll_dist_circ; if (pkt_time > 0 && sdelta > 0) { double scrolls_per_sec = da / pkt_time / sdelta; if (fabs(scrolls_per_sec) >= para->coasting_speed) { if (vert) { priv->autoscroll_yspd = scrolls_per_sec; priv->autoscroll_y = diffa(priv->scroll_a, angle(priv, hw->x, hw->y)) / sdelta; } else if (horiz) { priv->autoscroll_xspd = scrolls_per_sec; priv->autoscroll_x = diffa(priv->scroll_a, angle(priv, hw->x, hw->y)) / sdelta; } } } } } priv->scroll_packet_count = 0; } static void stop_coasting(SynapticsPrivate *priv) { priv->autoscroll_xspd = 0; priv->autoscroll_yspd = 0; priv->scroll_packet_count = 0; } static int HandleScrolling(SynapticsPrivate *priv, struct SynapticsHwState *hw, edge_type edge, Bool finger, struct ScrollData *sd) { SynapticsParameters *para = &priv->synpara; int delay = 1000000000; sd->left = sd->right = sd->up = sd->down = 0; if (priv->synpara.touchpad_off == 2) { stop_coasting(priv); priv->circ_scroll_on = FALSE; priv->vert_scroll_edge_on = FALSE; priv->horiz_scroll_edge_on = FALSE; priv->vert_scroll_twofinger_on = FALSE; priv->horiz_scroll_twofinger_on = FALSE; return delay; } /* scroll detection */ if (finger && !priv->finger_state) { stop_coasting(priv); if (para->circular_scrolling) { if ((para->circular_trigger == 0 && edge) || (para->circular_trigger == 1 && edge & TOP_EDGE) || (para->circular_trigger == 2 && edge & TOP_EDGE && edge & RIGHT_EDGE) || (para->circular_trigger == 3 && edge & RIGHT_EDGE) || (para->circular_trigger == 4 && edge & RIGHT_EDGE && edge & BOTTOM_EDGE) || (para->circular_trigger == 5 && edge & BOTTOM_EDGE) || (para->circular_trigger == 6 && edge & BOTTOM_EDGE && edge & LEFT_EDGE) || (para->circular_trigger == 7 && edge & LEFT_EDGE) || (para->circular_trigger == 8 && edge & LEFT_EDGE && edge & TOP_EDGE)) { priv->circ_scroll_on = TRUE; priv->circ_scroll_vert = TRUE; priv->scroll_a = angle(priv, hw->x, hw->y); DBG(7, "circular scroll detected on edge\n"); } } } if (!priv->circ_scroll_on) { if (finger) { if (hw->numFingers == 2) { if (!priv->vert_scroll_twofinger_on && (para->scroll_twofinger_vert) && (para->scroll_dist_vert != 0)) { priv->vert_scroll_twofinger_on = TRUE; priv->vert_scroll_edge_on = FALSE; priv->scroll_y = hw->y; DBG(7, "vert two-finger scroll detected\n"); } if (!priv->horiz_scroll_twofinger_on && (para->scroll_twofinger_horiz) && (para->scroll_dist_horiz != 0)) { priv->horiz_scroll_twofinger_on = TRUE; priv->horiz_scroll_edge_on = FALSE; priv->scroll_x = hw->x; DBG(7, "horiz two-finger scroll detected\n"); } } } if (finger && !priv->finger_state) { if (!priv->vert_scroll_twofinger_on && !priv->horiz_scroll_twofinger_on) { if ((para->scroll_edge_vert) && (para->scroll_dist_vert != 0) && (edge & RIGHT_EDGE)) { priv->vert_scroll_edge_on = TRUE; priv->scroll_y = hw->y; DBG(7, "vert edge scroll detected on right edge\n"); } if ((para->scroll_edge_horiz) && (para->scroll_dist_horiz != 0) && (edge & BOTTOM_EDGE)) { priv->horiz_scroll_edge_on = TRUE; priv->scroll_x = hw->x; DBG(7, "horiz edge scroll detected on bottom edge\n"); } } } } { Bool oldv = priv->vert_scroll_twofinger_on || priv->vert_scroll_edge_on || (priv->circ_scroll_on && priv->circ_scroll_vert); Bool oldh = priv->horiz_scroll_twofinger_on || priv->horiz_scroll_edge_on || (priv->circ_scroll_on && !priv->circ_scroll_vert); Bool oldc = priv->circ_scroll_on; if (priv->circ_scroll_on && !finger) { /* circular scroll locks in until finger is raised */ DBG(7, "cicular scroll off\n"); priv->circ_scroll_on = FALSE; } if (!finger || hw->numFingers != 2) { if (priv->vert_scroll_twofinger_on) { DBG(7, "vert two-finger scroll off\n"); priv->vert_scroll_twofinger_on = FALSE; } if (priv->horiz_scroll_twofinger_on) { DBG(7, "horiz two-finger scroll off\n"); priv->horiz_scroll_twofinger_on = FALSE; } } if (priv->vert_scroll_edge_on && (!(edge & RIGHT_EDGE) || !finger)) { DBG(7, "vert edge scroll off\n"); priv->vert_scroll_edge_on = FALSE; } if (priv->horiz_scroll_edge_on && (!(edge & BOTTOM_EDGE) || !finger)) { DBG(7, "horiz edge scroll off\n"); priv->horiz_scroll_edge_on = FALSE; } /* If we were corner edge scrolling (coasting), * but no longer in corner or raised a finger, then stop coasting. */ if (para->scroll_edge_corner && (priv->autoscroll_xspd || priv->autoscroll_yspd)) { Bool is_in_corner = ((edge & RIGHT_EDGE) && (edge & (TOP_EDGE | BOTTOM_EDGE))) || ((edge & BOTTOM_EDGE) && (edge & (LEFT_EDGE | RIGHT_EDGE))) ; if (!is_in_corner || !finger) { DBG(7, "corner edge scroll off\n"); stop_coasting(priv); } } /* if we were scrolling, but couldn't corner edge scroll, * and are no longer scrolling, then start coasting */ oldv = oldv && !(priv->vert_scroll_twofinger_on || priv->vert_scroll_edge_on || (priv->circ_scroll_on && priv->circ_scroll_vert)); oldh = oldh && !(priv->horiz_scroll_twofinger_on || priv->horiz_scroll_edge_on || (priv->circ_scroll_on && !priv->circ_scroll_vert)); oldc = oldc && !priv->circ_scroll_on; if ((oldv || oldh) && !para->scroll_edge_corner) { start_coasting(priv, hw, oldv, oldh, oldc); } } /* if hitting a corner (top right or bottom right) while vertical * scrolling is active, consider starting corner edge scrolling or * switching over to circular scrolling smoothly */ if (priv->vert_scroll_edge_on && !priv->horiz_scroll_edge_on && (edge & RIGHT_EDGE) && (edge & (TOP_EDGE | BOTTOM_EDGE))) { if (para->scroll_edge_corner) { if (priv->autoscroll_yspd == 0) { /* FYI: We can generate multiple start_coasting requests if * we're in the corner, but we were moving so slowly when we * got here that we didn't actually start coasting. */ DBG(7, "corner edge scroll on\n"); start_coasting(priv, hw, TRUE, FALSE, FALSE); } } else if (para->circular_scrolling) { priv->vert_scroll_edge_on = FALSE; priv->circ_scroll_on = TRUE; priv->circ_scroll_vert = TRUE; priv->scroll_a = angle(priv, hw->x, hw->y); DBG(7, "switching to circular scrolling\n"); } } /* Same treatment for horizontal scrolling */ if (priv->horiz_scroll_edge_on && !priv->vert_scroll_edge_on && (edge & BOTTOM_EDGE) && (edge & (LEFT_EDGE | RIGHT_EDGE))) { if (para->scroll_edge_corner) { if (priv->autoscroll_xspd == 0) { /* FYI: We can generate multiple start_coasting requests if * we're in the corner, but we were moving so slowly when we * got here that we didn't actually start coasting. */ DBG(7, "corner edge scroll on\n"); start_coasting(priv, hw, FALSE, TRUE, FALSE); } } else if (para->circular_scrolling) { priv->horiz_scroll_edge_on = FALSE; priv->circ_scroll_on = TRUE; priv->circ_scroll_vert = FALSE; priv->scroll_a = angle(priv, hw->x, hw->y); DBG(7, "switching to circular scrolling\n"); } } if (priv->vert_scroll_edge_on || priv->horiz_scroll_edge_on || priv->vert_scroll_twofinger_on || priv->horiz_scroll_twofinger_on || priv->circ_scroll_on) { priv->scroll_packet_count++; } if (priv->vert_scroll_edge_on || priv->vert_scroll_twofinger_on) { /* + = down, - = up */ int delta = para->scroll_dist_vert; if (delta > 0) { while (hw->y - priv->scroll_y > delta) { sd->down++; priv->scroll_y += delta; } while (hw->y - priv->scroll_y < -delta) { sd->up++; priv->scroll_y -= delta; } } } if (priv->horiz_scroll_edge_on || priv->horiz_scroll_twofinger_on) { /* + = right, - = left */ int delta = para->scroll_dist_horiz; if (delta > 0) { while (hw->x - priv->scroll_x > delta) { sd->right++; priv->scroll_x += delta; } while (hw->x - priv->scroll_x < -delta) { sd->left++; priv->scroll_x -= delta; } } } if (priv->circ_scroll_on) { /* + = counter clockwise, - = clockwise */ double delta = para->scroll_dist_circ; if (delta >= 0.005) { while (diffa(priv->scroll_a, angle(priv, hw->x, hw->y)) > delta) { if (priv->circ_scroll_vert) sd->up++; else sd->right++; priv->scroll_a += delta; if (priv->scroll_a > M_PI) priv->scroll_a -= 2 * M_PI; } while (diffa(priv->scroll_a, angle(priv, hw->x, hw->y)) < -delta) { if (priv->circ_scroll_vert) sd->down++; else sd->left++; priv->scroll_a -= delta; if (priv->scroll_a < -M_PI) priv->scroll_a += 2 * M_PI; } } } if (priv->autoscroll_yspd) { double dtime = (hw->millis - HIST(0).millis) / 1000.0; double ddy = para->coasting_friction * dtime; priv->autoscroll_y += priv->autoscroll_yspd * dtime; delay = MIN(delay, POLL_MS); while (priv->autoscroll_y > 1.0) { sd->down++; priv->autoscroll_y -= 1.0; } while (priv->autoscroll_y < -1.0) { sd->up++; priv->autoscroll_y += 1.0; } if (abs(priv->autoscroll_yspd) < ddy) { priv->autoscroll_yspd = 0; priv->scroll_packet_count = 0; } else { priv->autoscroll_yspd += (priv->autoscroll_yspd < 0 ? ddy : -1*ddy); } } if (priv->autoscroll_xspd) { double dtime = (hw->millis - HIST(0).millis) / 1000.0; double ddx = para->coasting_friction * dtime; priv->autoscroll_x += priv->autoscroll_xspd * dtime; delay = MIN(delay, POLL_MS); while (priv->autoscroll_x > 1.0) { sd->right++; priv->autoscroll_x -= 1.0; } while (priv->autoscroll_x < -1.0) { sd->left++; priv->autoscroll_x += 1.0; } if (abs(priv->autoscroll_xspd) < ddx) { priv->autoscroll_xspd = 0; priv->scroll_packet_count = 0; } else { priv->autoscroll_xspd += (priv->autoscroll_xspd < 0 ? ddx : -1*ddx); } } return delay; } static void handle_clickfinger(SynapticsParameters *para, struct SynapticsHwState *hw) { int action = 0; switch(hw->numFingers){ case 1: action = para->click_action[F1_CLICK1]; break; case 2: action = para->click_action[F2_CLICK1]; break; case 3: action = para->click_action[F3_CLICK1]; break; } switch(action){ case 1: hw->left = 1; break; case 2: hw->left = 0; hw->middle = 1; break; case 3: hw->left = 0; hw->right = 1; break; } } /* Update the hardware state in shared memory. This is read-only these days, * nothing in the driver reads back from SHM. SHM configuration is a thing of the past. */ static void update_shm(const InputInfoPtr pInfo, const struct SynapticsHwState *hw) { int i; SynapticsPrivate *priv = (SynapticsPrivate *) (pInfo->private); SynapticsSHM *shm = priv->synshm; if (!shm) return; shm->x = hw->x; shm->y = hw->y; shm->z = hw->z; shm->numFingers = hw->numFingers; shm->fingerWidth = hw->fingerWidth; shm->left = hw->left; shm->right = hw->right; shm->up = hw->up; shm->down = hw->down; for (i = 0; i < 8; i++) shm->multi[i] = hw->multi[i]; shm->middle = hw->middle; } /* Adjust the hardware state according to the extra buttons (if the touchpad * has any and not many touchpads do these days). These buttons are up/down * tilt buttons and/or left/right buttons that then map into a specific * function (or scrolling into). */ static Bool adjust_state_from_scrollbuttons(const InputInfoPtr pInfo, struct SynapticsHwState *hw) { SynapticsPrivate *priv = (SynapticsPrivate *) (pInfo->private); SynapticsParameters *para = &priv->synpara; Bool double_click = FALSE; if (!para->updown_button_scrolling) { if (hw->down) { /* map down button to middle button */ hw->middle = TRUE; } if (hw->up) { /* up button generates double click */ if (!priv->prev_up) double_click = TRUE; } priv->prev_up = hw->up; /* reset up/down button events */ hw->up = hw->down = FALSE; } /* Left/right button scrolling, or middle clicks */ if (!para->leftright_button_scrolling) { if (hw->multi[2] || hw->multi[3]) hw->middle = TRUE; /* reset left/right button events */ hw->multi[2] = hw->multi[3] = FALSE; } return double_click; } static void update_hw_button_state(const InputInfoPtr pInfo, struct SynapticsHwState *hw, int *delay) { SynapticsPrivate *priv = (SynapticsPrivate *) (pInfo->private); SynapticsParameters *para = &priv->synpara; /* Treat the first two multi buttons as up/down for now. */ hw->up |= hw->multi[0]; hw->down |= hw->multi[1]; /* 3rd button emulation */ hw->middle |= HandleMidButtonEmulation(priv, hw, delay); /* Fingers emulate other buttons */ if(hw->left && hw->numFingers >= 1){ handle_clickfinger(para, hw); } /* Two finger emulation */ if (hw->numFingers == 1 && hw->z >= para->emulate_twofinger_z && hw->fingerWidth >= para->emulate_twofinger_w) { hw->numFingers = 2; } } static void post_button_click(const InputInfoPtr pInfo, const int button) { xf86PostButtonEvent(pInfo->dev, FALSE, button, TRUE, 0, 0); xf86PostButtonEvent(pInfo->dev, FALSE, button, FALSE, 0, 0); } static void post_scroll_events(const InputInfoPtr pInfo, struct ScrollData scroll) { while (scroll.up-- > 0) post_button_click(pInfo, 4); while (scroll.down-- > 0) post_button_click(pInfo, 5); while (scroll.left-- > 0) post_button_click(pInfo, 6); while (scroll.right-- > 0) post_button_click(pInfo, 7); } static inline int repeat_scrollbuttons(const InputInfoPtr pInfo, const struct SynapticsHwState *hw, int buttons, int delay) { SynapticsPrivate *priv = (SynapticsPrivate *) (pInfo->private); SynapticsParameters *para = &priv->synpara; int repeat_delay, timeleft; int rep_buttons = ((para->updown_button_repeat ? 0x18 : 0) | (para->leftright_button_repeat ? 0x60 : 0)); /* Handle auto repeat buttons */ repeat_delay = clamp(para->scroll_button_repeat, SBR_MIN, SBR_MAX); if (((hw->up || hw->down) && para->updown_button_repeat && para->updown_button_scrolling) || ((hw->multi[2] || hw->multi[3]) && para->leftright_button_repeat && para->leftright_button_scrolling)) { priv->repeatButtons = buttons & rep_buttons; if (!priv->nextRepeat) { priv->nextRepeat = hw->millis + repeat_delay * 2; } } else { priv->repeatButtons = 0; priv->nextRepeat = 0; } if (priv->repeatButtons) { timeleft = TIME_DIFF(priv->nextRepeat, hw->millis); if (timeleft > 0) delay = MIN(delay, timeleft); if (timeleft <= 0) { int change, id; change = priv->repeatButtons; while (change) { id = ffs(change); change &= ~(1 << (id - 1)); xf86PostButtonEvent(pInfo->dev, FALSE, id, FALSE, 0, 0); xf86PostButtonEvent(pInfo->dev, FALSE, id, TRUE, 0, 0); } priv->nextRepeat = hw->millis + repeat_delay; delay = MIN(delay, repeat_delay); } } return delay; } /* * React on changes in the hardware state. This function is called every time * the hardware state changes. The return value is used to specify how many * milliseconds to wait before calling the function again if no state change * occurs. */ static int HandleState(InputInfoPtr pInfo, struct SynapticsHwState *hw) { SynapticsPrivate *priv = (SynapticsPrivate *) (pInfo->private); SynapticsParameters *para = &priv->synpara; int finger; int dx, dy, buttons, id; edge_type edge = NO_EDGE; int change; struct ScrollData scroll; int double_click = FALSE; int delay = 1000000000; int timeleft; Bool inside_active_area; update_shm(pInfo, hw); /* If touchpad is switched off, we skip the whole thing and return delay */ if (para->touchpad_off == 1) return delay; /* apply hysteresis before doing anything serious. This cancels * out a lot of noise which might surface in strange phenomena * like flicker in scrolling or noise motion. */ priv->hyst_center_x = hysteresis(hw->x, priv->hyst_center_x, para->hyst_x); priv->hyst_center_y = hysteresis(hw->y, priv->hyst_center_y, para->hyst_y); hw->x = priv->hyst_center_x; hw->y = priv->hyst_center_y; inside_active_area = is_inside_active_area(priv, hw->x, hw->y); /* now we know that these _coordinates_ aren't in the area. invalid are: x, y, z, numFingers, fingerWidth valid are: millis, left/right/middle/up/down/etc. */ if (!inside_active_area) { hw->x = 0; hw->y = 0; hw->z = 0; hw->numFingers = 0; hw->fingerWidth = 0; /* FIXME: if finger accidentally moves into the area and doesn't * really release, the finger should remain down. */ finger = FS_UNTOUCHED; edge = NO_EDGE; dx = dy = 0; } /* these two just update hw->left, right, etc. */ update_hw_button_state(pInfo, hw, &delay); if (priv->has_scrollbuttons) double_click = adjust_state_from_scrollbuttons(pInfo, hw); /* no edge or finger detection outside of area */ if (inside_active_area) { edge = edge_detection(priv, hw->x, hw->y); finger = SynapticsDetectFinger(priv, hw); } /* tap and drag detection. Needs to be performed even if the finger is in * the dead area to reset the state. */ timeleft = HandleTapProcessing(priv, hw, finger, inside_active_area); if (timeleft > 0) delay = MIN(delay, timeleft); if (inside_active_area) { /* Don't bother about scrolling in the dead area of the touchpad. */ timeleft = HandleScrolling(priv, hw, edge, finger, &scroll); if (timeleft > 0) delay = MIN(delay, timeleft); /* * Compensate for unequal x/y resolution. This needs to be done after * calculations that require unadjusted coordinates, for example edge * detection. */ ScaleCoordinates(priv, hw); } dx = dy = 0; if (!priv->absolute_events) { timeleft = ComputeDeltas(priv, hw, edge, &dx, &dy, inside_active_area); delay = MIN(delay, timeleft); } buttons = ((hw->left ? 0x01 : 0) | (hw->middle ? 0x02 : 0) | (hw->right ? 0x04 : 0) | (hw->up ? 0x08 : 0) | (hw->down ? 0x10 : 0) | (hw->multi[2] ? 0x20 : 0) | (hw->multi[3] ? 0x40 : 0)); if (priv->tap_button > 0) { int tap_mask = 1 << (priv->tap_button - 1); if (priv->tap_button_state == TBS_BUTTON_DOWN_UP) { if (tap_mask != (priv->lastButtons & tap_mask)) { xf86PostButtonEvent(pInfo->dev, FALSE, priv->tap_button, TRUE, 0, 0); priv->lastButtons |= tap_mask; } priv->tap_button_state = TBS_BUTTON_UP; } if (priv->tap_button_state == TBS_BUTTON_DOWN) buttons |= tap_mask; } /* Post events */ if (finger >= FS_TOUCHED) { if (priv->absolute_events && inside_active_area) { xf86PostMotionEvent(pInfo->dev, 1, 0, 2, hw->x, hw->y); } else if (dx || dy) { xf86PostMotionEvent(pInfo->dev, 0, 0, 2, dx, dy); } } if (priv->mid_emu_state == MBE_LEFT_CLICK) { post_button_click(pInfo, 1); priv->mid_emu_state = MBE_OFF; } else if (priv->mid_emu_state == MBE_RIGHT_CLICK) { post_button_click(pInfo, 3); priv->mid_emu_state = MBE_OFF; } change = buttons ^ priv->lastButtons; while (change) { id = ffs(change); /* number of first set bit 1..32 is returned */ change &= ~(1 << (id - 1)); xf86PostButtonEvent(pInfo->dev, FALSE, id, (buttons & (1 << (id - 1))), 0, 0); } /* Process scroll events only if coordinates are * in the Synaptics Area */ if (inside_active_area) post_scroll_events(pInfo, scroll); if (double_click) { post_button_click(pInfo, 1); post_button_click(pInfo, 1); } if (priv->has_scrollbuttons) delay = repeat_scrollbuttons(pInfo, hw, buttons, delay); /* Save old values of some state variables */ priv->finger_state = finger; priv->lastButtons = buttons; /* generate a history of the absolute positions */ if (inside_active_area) store_history(priv, hw->x, hw->y, hw->millis); return delay; } static int ControlProc(InputInfoPtr pInfo, xDeviceCtl * control) { DBG(3, "Control Proc called\n"); return Success; } static int SwitchMode(ClientPtr client, DeviceIntPtr dev, int mode) { InputInfoPtr pInfo = (InputInfoPtr) dev->public.devicePrivate; SynapticsPrivate *priv = (SynapticsPrivate *) (pInfo->private); DBG(3, "SwitchMode called\n"); switch (mode) { case Absolute: priv->absolute_events = TRUE; break; case Relative: priv->absolute_events = FALSE; break; default: return XI_BadMode; } return Success; } static void ReadDevDimensions(InputInfoPtr pInfo) { SynapticsPrivate *priv = (SynapticsPrivate *) pInfo->private; if (priv->proto_ops->ReadDevDimensions) priv->proto_ops->ReadDevDimensions(pInfo); SanitizeDimensions(pInfo); } static Bool QueryHardware(InputInfoPtr pInfo) { SynapticsPrivate *priv = (SynapticsPrivate *) pInfo->private; priv->comm.protoBufTail = 0; if (!priv->proto_ops->QueryHardware(pInfo)) { xf86IDrvMsg(pInfo, X_PROBED, "no supported touchpad found\n"); if (priv->proto_ops->DeviceOffHook) priv->proto_ops->DeviceOffHook(pInfo); return FALSE; } return TRUE; } static void ScaleCoordinates(SynapticsPrivate *priv, struct SynapticsHwState *hw) { int xCenter = (priv->synpara.left_edge + priv->synpara.right_edge) / 2; int yCenter = (priv->synpara.top_edge + priv->synpara.bottom_edge) / 2; hw->x = (hw->x - xCenter) * priv->horiz_coeff + xCenter; hw->y = (hw->y - yCenter) * priv->vert_coeff + yCenter; } void CalculateScalingCoeffs(SynapticsPrivate *priv) { int vertRes = priv->synpara.resolution_vert; int horizRes = priv->synpara.resolution_horiz; if ((horizRes > vertRes) && (horizRes > 0)) { priv->horiz_coeff = vertRes / (double)horizRes; priv->vert_coeff = 1; } else if ((horizRes < vertRes) && (vertRes > 0)) { priv->horiz_coeff = 1; priv->vert_coeff = horizRes / (double)vertRes; } else { priv->horiz_coeff = 1; priv->vert_coeff = 1; } }