/* * Copyright (C) 2007 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../common.h" #include "minui.h" //#define _EVENT_LOGGING #define MAX_DEVICES 32 #define VIBRATOR_TIMEOUT_FILE "/sys/class/timed_output/vibrator/enable" #define VIBRATOR_TIME_MS 50 #define LEDS_HAPTICS_DURATION_FILE "/sys/class/leds/vibrator/duration" #define LEDS_HAPTICS_ACTIVATE_FILE "/sys/class/leds/vibrator/activate" #ifndef SYN_REPORT #define SYN_REPORT 0x00 #endif #ifndef SYN_CONFIG #define SYN_CONFIG 0x01 #endif #ifndef SYN_MT_REPORT #define SYN_MT_REPORT 0x02 #endif #define ABS_MT_POSITION 0x2a /* Group a set of X and Y */ #define ABS_MT_AMPLITUDE 0x2b /* Group a set of Z and W */ #define ABS_MT_SLOT 0x2f #define ABS_MT_TOUCH_MAJOR 0x30 #define ABS_MT_TOUCH_MINOR 0x31 #define ABS_MT_WIDTH_MAJOR 0x32 #define ABS_MT_WIDTH_MINOR 0x33 #define ABS_MT_ORIENTATION 0x34 #define ABS_MT_POSITION_X 0x35 #define ABS_MT_POSITION_Y 0x36 #define ABS_MT_TOOL_TYPE 0x37 #define ABS_MT_BLOB_ID 0x38 #define ABS_MT_TRACKING_ID 0x39 #define ABS_MT_PRESSURE 0x3a #define ABS_MT_DISTANCE 0x3b enum { DOWN_NOT, DOWN_SENT, DOWN_RELEASED, }; struct virtualkey { int scancode; int centerx, centery; int width, height; }; struct position { int x, y; int synced; struct input_absinfo xi, yi; }; struct ev { struct pollfd *fd; struct virtualkey *vks; int vk_count; char deviceName[64]; int ignored; struct position p, mt_p; int down; }; static struct pollfd ev_fds[MAX_DEVICES]; static struct ev evs[MAX_DEVICES]; static unsigned ev_count = 0; static struct timeval lastInputStat; static time_t lastInputMTime; static int has_mouse = 0; static inline int ABS(int x) { return x<0?-x:x; } int write_to_file(const std::string& fn, const std::string& line) { FILE *file; file = fopen(fn.c_str(), "w"); if (file != NULL) { fwrite(line.c_str(), line.size(), 1, file); fclose(file); return 0; } LOGI("Cannot find file %s\n", fn.c_str()); return -1; } #ifndef TW_NO_HAPTICS int vibrate(int timeout_ms) { if (timeout_ms > 10000) timeout_ms = 1000; char tout[6]; sprintf(tout, "%i", timeout_ms); if (std::ifstream(LEDS_HAPTICS_ACTIVATE_FILE).good()) { write_to_file(LEDS_HAPTICS_DURATION_FILE, tout); write_to_file(LEDS_HAPTICS_ACTIVATE_FILE, "1"); } else write_to_file(VIBRATOR_TIMEOUT_FILE, tout); return 0; } #endif /* Returns empty tokens */ static char *vk_strtok_r(char *str, const char *delim, char **save_str) { if(!str) { if(!*save_str) return NULL; str = (*save_str) + 1; } *save_str = strpbrk(str, delim); if (*save_str) **save_str = '\0'; return str; } static int vk_init(struct ev *e) { char vk_path[PATH_MAX] = "/sys/board_properties/virtualkeys."; char vks[2048], *ts = NULL; ssize_t len; int vk_fd; int i; e->vk_count = 0; len = strlen(vk_path); len = ioctl(e->fd->fd, EVIOCGNAME(sizeof(e->deviceName)), e->deviceName); if (len <= 0) { LOGE("Unable to query event object.\n"); return -1; } #ifdef _EVENT_LOGGING printf("Event object: %s\n", e->deviceName); #endif #ifdef WHITELIST_INPUT if (strcmp(e->deviceName, EXPAND(WHITELIST_INPUT)) != 0) { e->ignored = 1; } #else #ifndef TW_INPUT_BLACKLIST // Blacklist these "input" devices, use TW_INPUT_BLACKLIST := "accelerometer\x0atest1\x0atest2" using the \x0a as a separator between input devices if (strcmp(e->deviceName, "bma250") == 0 || strcmp(e->deviceName, "bma150") == 0) { LOGI("Blacklisting input device: %s\n", e->deviceName); e->ignored = 1; } #else char* bl = strdup(EXPAND(TW_INPUT_BLACKLIST)); char* blacklist = strtok(bl, "\n"); while (blacklist != NULL) { if (strcmp(e->deviceName, blacklist) == 0) { LOGI("Blacklisting input device: %s\n", blacklist); e->ignored = 1; } blacklist = strtok(NULL, "\n"); } free(bl); #endif #endif strcat(vk_path, e->deviceName); // Some devices split the keys from the touchscreen e->vk_count = 0; vk_fd = open(vk_path, O_RDONLY); if (vk_fd >= 0) { len = read(vk_fd, vks, sizeof(vks)-1); close(vk_fd); if (len <= 0) return -1; vks[len] = '\0'; /* Parse a line like: keytype:keycode:centerx:centery:width:height:keytype2:keycode2:centerx2:... */ for (ts = vks, e->vk_count = 1; *ts; ++ts) { if (*ts == ':') ++e->vk_count; } if (e->vk_count % 6) { LOGI("minui: %s is %d %% 6\n", vk_path, e->vk_count % 6); } e->vk_count /= 6; if (e->vk_count <= 0) return -1; e->down = DOWN_NOT; } ioctl(e->fd->fd, EVIOCGABS(ABS_X), &e->p.xi); ioctl(e->fd->fd, EVIOCGABS(ABS_Y), &e->p.yi); e->p.synced = 0; #ifdef _EVENT_LOGGING printf("EV: ST minX: %d maxX: %d minY: %d maxY: %d\n", e->p.xi.minimum, e->p.xi.maximum, e->p.yi.minimum, e->p.yi.maximum); #endif ioctl(e->fd->fd, EVIOCGABS(ABS_MT_POSITION_X), &e->mt_p.xi); ioctl(e->fd->fd, EVIOCGABS(ABS_MT_POSITION_Y), &e->mt_p.yi); e->mt_p.synced = 0; #ifdef _EVENT_LOGGING printf("EV: MT minX: %d maxX: %d minY: %d maxY: %d\n", e->mt_p.xi.minimum, e->mt_p.xi.maximum, e->mt_p.yi.minimum, e->mt_p.yi.maximum); #endif e->vks = (virtualkey *)malloc(sizeof(*e->vks) * e->vk_count); for (i = 0; i < e->vk_count; ++i) { char *token[6]; int j; for (j = 0; j < 6; ++j) { token[j] = vk_strtok_r((i||j)?NULL:vks, ":", &ts); } if (strcmp(token[0], "0x01") != 0) { /* Java does string compare, so we do too. */ LOGI("minui: %s: ignoring unknown virtual key type %s\n", vk_path, token[0]); continue; } e->vks[i].scancode = strtol(token[1], NULL, 0); e->vks[i].centerx = strtol(token[2], NULL, 0); e->vks[i].centery = strtol(token[3], NULL, 0); e->vks[i].width = strtol(token[4], NULL, 0); e->vks[i].height = strtol(token[5], NULL, 0); } return 0; } #define BITS_PER_LONG (sizeof(long) * 8) #define NBITS(x) ((((x)-1)/BITS_PER_LONG)+1) #define OFF(x) ((x)%BITS_PER_LONG) #define LONG(x) ((x)/BITS_PER_LONG) #define test_bit(bit, array) ((array[LONG(bit)] >> OFF(bit)) & 1) // Check for EV_REL (REL_X and REL_Y) and, because touchscreens can have those too, // check also for EV_KEY (BTN_LEFT and BTN_RIGHT) static void check_mouse(int fd, const char* deviceName) { if(has_mouse) return; unsigned long bit[EV_MAX][NBITS(KEY_MAX)]; memset(bit, 0, sizeof(bit)); ioctl(fd, EVIOCGBIT(0, EV_MAX), bit[0]); if(!test_bit(EV_REL, bit[0]) || !test_bit(EV_KEY, bit[0])) return; ioctl(fd, EVIOCGBIT(EV_REL, KEY_MAX), bit[EV_REL]); if(!test_bit(REL_X, bit[EV_REL]) || !test_bit(REL_Y, bit[EV_REL])) return; ioctl(fd, EVIOCGBIT(EV_KEY, KEY_MAX), bit[EV_KEY]); if(!test_bit(BTN_LEFT, bit[EV_KEY]) || !test_bit(BTN_RIGHT, bit[EV_KEY])) return; LOGI("Found mouse '%s'\n", deviceName); has_mouse = 1; } int ev_has_mouse(void) { return has_mouse; } int ev_init(void) { DIR *dir; struct dirent *de; int fd; has_mouse = 0; dir = opendir("/dev/input"); if(dir != 0) { while((de = readdir(dir))) { #ifdef _EVENT_LOGGING fprintf(stderr,"/dev/input/%s\n", de->d_name); #endif if(strncmp(de->d_name,"event",5)) continue; fd = openat(dirfd(dir), de->d_name, O_RDONLY); if(fd < 0) continue; ev_fds[ev_count].fd = fd; ev_fds[ev_count].events = POLLIN; evs[ev_count].fd = &ev_fds[ev_count]; /* Load virtualkeys if there are any */ vk_init(&evs[ev_count]); if (!evs[ev_count].ignored) check_mouse(fd, evs[ev_count].deviceName); ev_count++; if(ev_count == MAX_DEVICES) break; } closedir(dir); } struct stat st; if(stat("/dev/input", &st) >= 0) lastInputMTime = st.st_mtime; gettimeofday(&lastInputStat, NULL); return 0; } void ev_exit(void) { while (ev_count-- > 0) { if (evs[ev_count].vk_count) { free(evs[ev_count].vks); evs[ev_count].vk_count = 0; } close(ev_fds[ev_count].fd); } ev_count = 0; } /*static int vk_inside_display(__s32 value, struct input_absinfo *info, int screen_size) { int screen_pos; if (info->minimum == info->maximum) return 0; screen_pos = (value - info->minimum) * (screen_size - 1) / (info->maximum - info->minimum); return (screen_pos >= 0 && screen_pos < screen_size); }*/ static int vk_tp_to_screen(struct position *p, int *x, int *y) { if (p->xi.minimum == p->xi.maximum || p->yi.minimum == p->yi.maximum) { // In this case, we assume the screen dimensions are the same. *x = p->x; *y = p->y; return 0; } #ifdef _EVENT_LOGGING printf("EV: p->x=%d x-range=%d,%d fb-width=%d\n", p->x, p->xi.minimum, p->xi.maximum, gr_fb_width()); #endif #ifndef RECOVERY_TOUCHSCREEN_SWAP_XY int fb_width = gr_fb_width(); int fb_height = gr_fb_height(); #else // We need to swap the scaling sizes, too int fb_width = gr_fb_height(); int fb_height = gr_fb_width(); #endif *x = (p->x - p->xi.minimum) * (fb_width - 1) / (p->xi.maximum - p->xi.minimum); *y = (p->y - p->yi.minimum) * (fb_height - 1) / (p->yi.maximum - p->yi.minimum); if (*x >= 0 && *x < fb_width && *y >= 0 && *y < fb_height) { return 0; } return 1; } /* Translate a virtual key in to a real key event, if needed */ /* Returns non-zero when the event should be consumed */ static int vk_modify(struct ev *e, struct input_event *ev) { static int downX = -1, downY = -1; static int discard = 0; static int last_virt_key = 0; static int lastWasSynReport = 0; static int touchReleaseOnNextSynReport = 0; static int use_tracking_id_negative_as_touch_release = 0; // On some devices, type: 3 code: 39 value: -1, aka EV_ABS ABS_MT_TRACKING_ID -1 indicates a true touch release int i; int x, y; // This is used to ditch useless event handlers, like an accelerometer if (e->ignored) return 1; if (ev->type == EV_REL && ev->code == REL_Z) { // This appears to be an accelerometer or another strange input device. It's not the touchscreen. #ifdef _EVENT_LOGGING printf("EV: Device disabled due to non-touchscreen messages.\n"); #endif e->ignored = 1; return 1; } #ifdef _EVENT_LOGGING printf("EV: %s => type: %x code: %x value: %d\n", e->deviceName, ev->type, ev->code, ev->value); #endif // Handle keyboard events, value of 1 indicates key down, 0 indicates key up if (ev->type == EV_KEY) { return 0; } if (ev->type == EV_ABS) { switch (ev->code) { case ABS_X: //00 e->p.synced |= 0x01; e->p.x = ev->value; #ifdef _EVENT_LOGGING printf("EV: %s => EV_ABS ABS_X %d\n", e->deviceName, ev->value); #endif break; case ABS_Y: //01 e->p.synced |= 0x02; e->p.y = ev->value; #ifdef _EVENT_LOGGING printf("EV: %s => EV_ABS ABS_Y %d\n", e->deviceName, ev->value); #endif break; case ABS_MT_POSITION: //2a e->mt_p.synced = 0x03; if (ev->value == (1 << 31)) { #ifndef TW_IGNORE_MT_POSITION_0 e->mt_p.x = 0; e->mt_p.y = 0; lastWasSynReport = 1; #endif #ifdef _EVENT_LOGGING #ifndef TW_IGNORE_MT_POSITION_0 printf("EV: %s => EV_ABS ABS_MT_POSITION %d, set x and y to 0 and lastWasSynReport to 1\n", e->deviceName, ev->value); #else printf("Ignoring ABS_MT_POSITION 0\n", e->deviceName, ev->value); #endif #endif } else { lastWasSynReport = 0; e->mt_p.x = (ev->value & 0x7FFF0000) >> 16; e->mt_p.y = (ev->value & 0xFFFF); #ifdef _EVENT_LOGGING printf("EV: %s => EV_ABS ABS_MT_POSITION %d, set x: %d and y: %d and lastWasSynReport to 0\n", e->deviceName, ev->value, (ev->value & 0x7FFF0000) >> 16, (ev->value & 0xFFFF)); #endif } break; case ABS_MT_TOUCH_MAJOR: //30 if (ev->value == 0) { #ifndef TW_IGNORE_MAJOR_AXIS_0 // We're in a touch release, although some devices will still send positions as well e->mt_p.x = 0; e->mt_p.y = 0; touchReleaseOnNextSynReport = 1; #endif } #ifdef _EVENT_LOGGING printf("EV: %s => EV_ABS ABS_MT_TOUCH_MAJOR %d\n", e->deviceName, ev->value); #endif break; case ABS_MT_PRESSURE: //3a if (ev->value == 0) { // We're in a touch release, although some devices will still send positions as well e->mt_p.x = 0; e->mt_p.y = 0; touchReleaseOnNextSynReport = 1; } #ifdef _EVENT_LOGGING printf("EV: %s => EV_ABS ABS_MT_PRESSURE %d\n", e->deviceName, ev->value); #endif break; case ABS_MT_POSITION_X: //35 e->mt_p.synced |= 0x01; e->mt_p.x = ev->value; #ifdef _EVENT_LOGGING printf("EV: %s => EV_ABS ABS_MT_POSITION_X %d\n", e->deviceName, ev->value); #endif break; case ABS_MT_POSITION_Y: //36 e->mt_p.synced |= 0x02; e->mt_p.y = ev->value; #ifdef _EVENT_LOGGING printf("EV: %s => EV_ABS ABS_MT_POSITION_Y %d\n", e->deviceName, ev->value); #endif break; case ABS_MT_TOUCH_MINOR: //31 #ifdef _EVENT_LOGGING printf("EV: %s => EV_ABS ABS_MT_TOUCH_MINOR %d\n", e->deviceName, ev->value); #endif break; case ABS_MT_WIDTH_MAJOR: //32 #ifdef _EVENT_LOGGING printf("EV: %s => EV_ABS ABS_MT_WIDTH_MAJOR %d\n", e->deviceName, ev->value); #endif break; case ABS_MT_WIDTH_MINOR: //33 #ifdef _EVENT_LOGGING printf("EV: %s => EV_ABS ABS_MT_WIDTH_MINOR %d\n", e->deviceName, ev->value); #endif break; case ABS_MT_TRACKING_ID: //39 #ifdef TW_IGNORE_ABS_MT_TRACKING_ID #ifdef _EVENT_LOGGING printf("EV: %s => EV_ABS ABS_MT_TRACKING_ID %d ignored\n", e->deviceName, ev->value); #endif return 1; #endif if (ev->value < 0) { e->mt_p.x = 0; e->mt_p.y = 0; touchReleaseOnNextSynReport = 2; use_tracking_id_negative_as_touch_release = 1; #ifdef _EVENT_LOGGING if (use_tracking_id_negative_as_touch_release) printf("using ABS_MT_TRACKING_ID value -1 to indicate touch releases\n"); #endif } #ifdef _EVENT_LOGGING printf("EV: %s => EV_ABS ABS_MT_TRACKING_ID %d\n", e->deviceName, ev->value); #endif break; #ifdef _EVENT_LOGGING // These are for touch logging purposes only case ABS_MT_ORIENTATION: //34 printf("EV: %s => EV_ABS ABS_MT_ORIENTATION %d\n", e->deviceName, ev->value); return 1; break; case ABS_MT_TOOL_TYPE: //37 LOGI("EV: %s => EV_ABS ABS_MT_TOOL_TYPE %d\n", e->deviceName, ev->value); return 1; break; case ABS_MT_BLOB_ID: //38 printf("EV: %s => EV_ABS ABS_MT_BLOB_ID %d\n", e->deviceName, ev->value); return 1; break; case ABS_MT_DISTANCE: //3b printf("EV: %s => EV_ABS ABS_MT_DISTANCE %d\n", e->deviceName, ev->value); return 1; break; case ABS_MT_SLOT: printf("EV: %s => ABS_MT_SLOT %d\n", e->deviceName, ev->value); return 1; break; #endif default: // This is an unhandled message, just skip it return 1; } if (ev->code != ABS_MT_POSITION) { lastWasSynReport = 0; return 1; } } // Check if we should ignore the message if (ev->code != ABS_MT_POSITION && (ev->type != EV_SYN || (ev->code != SYN_REPORT && ev->code != SYN_MT_REPORT))) { lastWasSynReport = 0; return 0; } #ifdef _EVENT_LOGGING if (ev->type == EV_SYN && ev->code == SYN_REPORT) printf("EV: %s => EV_SYN SYN_REPORT\n", e->deviceName); if (ev->type == EV_SYN && ev->code == SYN_MT_REPORT) printf("EV: %s => EV_SYN SYN_MT_REPORT\n", e->deviceName); #endif // Discard the MT versions if (ev->code == SYN_MT_REPORT) return 0; if (((lastWasSynReport == 1 || touchReleaseOnNextSynReport == 1) && !use_tracking_id_negative_as_touch_release) || (use_tracking_id_negative_as_touch_release && touchReleaseOnNextSynReport == 2)) { // Reset the value touchReleaseOnNextSynReport = 0; // We are a finger-up state if (!discard) { // Report the key up ev->type = EV_ABS; ev->code = 0; ev->value = (downX << 16) | downY; } downX = -1; downY = -1; if (discard) { discard = 0; // Send the keyUp event ev->type = EV_KEY; ev->code = last_virt_key; ev->value = 0; } return 0; } lastWasSynReport = 1; // Retrieve where the x,y position is if (e->p.synced & 0x03) { vk_tp_to_screen(&e->p, &x, &y); } else if (e->mt_p.synced & 0x03) { vk_tp_to_screen(&e->mt_p, &x, &y); } else { // We don't have useful information to convey return 1; } #ifdef RECOVERY_TOUCHSCREEN_SWAP_XY x ^= y; y ^= x; x ^= y; #endif #ifdef RECOVERY_TOUCHSCREEN_FLIP_X x = gr_fb_width() - x; #endif #ifdef RECOVERY_TOUCHSCREEN_FLIP_Y y = gr_fb_height() - y; #endif #ifdef _EVENT_LOGGING printf("EV: x: %d y: %d\n", x, y); #endif // Clear the current sync states e->p.synced = e->mt_p.synced = 0; // If we have nothing useful to report, skip it if (x == -1 || y == -1) return 1; // Special case, we'll ignore touches on 0,0 because it usually means // that we received extra data after our last sync and x and y were // reset to 0. We should not be using 0,0 anyway. if (x == 0 && y == 0) return 1; // On first touch, see if we're at a virtual key if (downX == -1) { // Attempt mapping to virtual key for (i = 0; i < e->vk_count; ++i) { int xd = ABS(e->vks[i].centerx - x); int yd = ABS(e->vks[i].centery - y); if (xd < e->vks[i].width/2 && yd < e->vks[i].height/2) { ev->type = EV_KEY; ev->code = e->vks[i].scancode; ev->value = 1; last_virt_key = e->vks[i].scancode; #ifndef TW_NO_HAPTICS vibrate(VIBRATOR_TIME_MS); #endif // Mark that all further movement until lift is discard, // and make sure we don't come back into this area discard = 1; downX = 0; return 0; } } } // If we were originally a button press, discard this event if (discard) { return 1; } // Record where we started the touch for deciding if this is a key or a scroll downX = x; downY = y; ev->type = EV_ABS; ev->code = 1; ev->value = (x << 16) | y; return 0; } int ev_get(struct input_event *ev, int timeout_ms) { int r; unsigned n; struct timeval curr; gettimeofday(&curr, NULL); if(curr.tv_sec - lastInputStat.tv_sec >= 2) { struct stat st; stat("/dev/input", &st); if (st.st_mtime > lastInputMTime) { LOGI("Reloading input devices\n"); ev_exit(); ev_init(); lastInputMTime = st.st_mtime; } lastInputStat = curr; } r = poll(ev_fds, ev_count, timeout_ms); if(r > 0) { for(n = 0; n < ev_count; n++) { if(ev_fds[n].revents & POLLIN) { r = read(ev_fds[n].fd, ev, sizeof(*ev)); if(r == sizeof(*ev)) { if (!vk_modify(&evs[n], ev)) return 0; } } } return -1; } return -2; } int ev_wait(int timeout __unused) { return -1; } void ev_dispatch(void) { return; } int ev_get_input(int fd __unused, short revents __unused, struct input_event *ev __unused) { return -1; }