/* Copyright (c) 2013 The Chromium OS Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ /* Keyboard scanner module for Chrome EC */ #include "chipset.h" #include "clock.h" #include "common.h" #include "console.h" #include "hooks.h" #include "host_command.h" #include "keyboard_config.h" #include "keyboard_protocol.h" #include "keyboard_raw.h" #include "keyboard_scan.h" #include "lid_switch.h" #include "switch.h" #include "system.h" #include "task.h" #include "timer.h" #include "util.h" /* Console output macros */ #define CPUTS(outstr) cputs(CC_KEYSCAN, outstr) #define CPRINTF(format, args...) cprintf(CC_KEYSCAN, format, ## args) #define CPRINTS(format, args...) cprints(CC_KEYSCAN, format, ## args) #define SCAN_TIME_COUNT 32 /* Number of last scan times to track */ /* If we're waiting for a scan to happen, we'll give it this long */ #define SCAN_TASK_TIMEOUT_US (100 * MSEC) #ifndef CONFIG_KEYBOARD_POST_SCAN_CLOCKS /* * Default delay in clocks; this was experimentally determined to be long * enough to avoid watchdog warnings or I2C errors on a typical notebook * config on STM32. */ #define CONFIG_KEYBOARD_POST_SCAN_CLOCKS 16000 #endif #ifndef CONFIG_KEYBOARD_BOARD_CONFIG /* Use default keyboard scan config, because board didn't supply one */ struct keyboard_scan_config keyscan_config = { .output_settle_us = 50, .debounce_down_us = 9 * MSEC, .debounce_up_us = 30 * MSEC, .scan_period_us = 3 * MSEC, .min_post_scan_delay_us = 1000, .poll_timeout_us = 100 * MSEC, .actual_key_mask = { 0x14, 0xff, 0xff, 0xff, 0xff, 0xf5, 0xff, 0xa4, 0xff, 0xfe, 0x55, 0xfa, 0xca /* full set */ }, }; #endif /* Boot key list. Must be in same order as enum boot_key. */ struct boot_key_entry { uint8_t mask_index; uint8_t mask_value; }; static const struct boot_key_entry boot_key_list[] = { {0, 0x00}, /* (none) */ {KEYBOARD_COL_ESC, KEYBOARD_MASK_ESC}, /* Esc */ {KEYBOARD_COL_DOWN, KEYBOARD_MASK_DOWN}, /* Down-arrow */ }; static enum boot_key boot_key_value = BOOT_KEY_OTHER; static uint8_t debounced_state[KEYBOARD_COLS]; /* Debounced key matrix */ static uint8_t prev_state[KEYBOARD_COLS]; /* Matrix from previous scan */ static uint8_t debouncing[KEYBOARD_COLS]; /* Mask of keys being debounced */ static uint8_t simulated_key[KEYBOARD_COLS]; /* Keys simulated-pressed */ static uint32_t scan_time[SCAN_TIME_COUNT]; /* Times of last scans */ static int scan_time_index; /* Current scan_time[] index */ /* Index into scan_time[] when each key started debouncing */ static uint8_t scan_edge_index[KEYBOARD_COLS][KEYBOARD_ROWS]; /* Minimum delay between keyboard scans based on current clock frequency */ static uint32_t post_scan_clock_us; /* * Print all keyboard scan state changes? Off by default because it generates * a lot of debug output, which makes the saved EC console data less useful. */ static int print_state_changes; static int disable_scanning_mask; /* Must init to 0 for scanning at boot */ /* Constantly incrementing counter of the number of times we polled */ static volatile int kbd_polls; static int keyboard_scan_is_enabled(void) { return !disable_scanning_mask; } void keyboard_scan_enable(int enable, enum kb_scan_disable_masks mask) { int old_disable_scanning = disable_scanning_mask; disable_scanning_mask = enable ? (disable_scanning_mask & ~mask) : (disable_scanning_mask | mask); if (disable_scanning_mask != old_disable_scanning) CPRINTS("KB disable_scanning_mask changed: 0x%08x", disable_scanning_mask); if (old_disable_scanning && !disable_scanning_mask) { /* * Scanning is being enabled, so wake up the scanning task to * unlock the task_wait_event() loop after enable_interrupt(). */ task_wake(TASK_ID_KEYSCAN); } else if (disable_scanning_mask && !old_disable_scanning) { keyboard_raw_drive_column(KEYBOARD_COLUMN_NONE); keyboard_clear_buffer(); } } /** * Print the keyboard state. * * @param state State array to print * @param msg Description of state */ static void print_state(const uint8_t *state, const char *msg) { int c; CPRINTF("[%T KB %s:", msg); for (c = 0; c < KEYBOARD_COLS; c++) { if (state[c]) CPRINTF(" %02x", state[c]); else CPUTS(" --"); } CPUTS("]\n"); } /** * Ensure that the keyboard has been scanned. * * Makes sure that we've fully gone through the keyboard scanning loop at * least once. */ static void ensure_keyboard_scanned(int old_polls) { uint64_t start_time; start_time = get_time().val; /* * Ensure we see the poll task run. * * Note that the poll task is higher priority than ours so we know that * while we're running it's not partway through a poll. That means that * if kbd_polls changes we've gone through a whole cycle. */ while ((kbd_polls == old_polls) && (get_time().val - start_time < SCAN_TASK_TIMEOUT_US)) usleep(keyscan_config.scan_period_us); } /** * Simulate a keypress. * * @param row Row of key * @param col Column of key * @param pressed Non-zero if pressed, zero if released */ static void simulate_key(int row, int col, int pressed) { int old_polls; if ((simulated_key[col] & (1 << row)) == ((pressed ? 1 : 0) << row)) return; /* No change */ simulated_key[col] ^= (1 << row); /* Keep track of polls now that we've got keys simulated */ old_polls = kbd_polls; print_state(simulated_key, "simulated "); /* Wake the task to handle changes in simulated keys */ task_wake(TASK_ID_KEYSCAN); /* * Make sure that the keyboard task sees the key for long enough. * That means it needs to have run and for enough time. */ ensure_keyboard_scanned(old_polls); usleep(pressed ? keyscan_config.debounce_down_us : keyscan_config.debounce_up_us); ensure_keyboard_scanned(kbd_polls); } /** * Read the raw keyboard matrix state. * * Used in pre-init, so must not make task-switching-dependent calls; udelay() * is ok because it's a spin-loop. * * @param state Destination for new state (must be KEYBOARD_COLS long). * * @return 1 if at least one key is pressed, else zero. */ static int read_matrix(uint8_t *state) { int c; uint8_t r; int pressed = 0; for (c = 0; c < KEYBOARD_COLS; c++) { /* * Stop if scanning becomes disabled. Note, scanning is enabled * on boot by default. */ if (!keyboard_scan_is_enabled()) break; /* Select column, then wait a bit for it to settle */ keyboard_raw_drive_column(c); udelay(keyscan_config.output_settle_us); /* Read the row state */ r = keyboard_raw_read_rows(); /* Add in simulated keypresses */ r |= simulated_key[c]; /* * Keep track of what keys appear to be pressed. Even if they * don't exist in the matrix, they'll keep triggering * interrupts, so we can't leave scanning mode. */ pressed |= r; /* Mask off keys that don't exist on the actual keyboard */ r &= keyscan_config.actual_key_mask[c]; #ifdef CONFIG_KEYBOARD_TEST /* Use simulated keyscan sequence instead if testing active */ r = keyscan_seq_get_scan(c, r); #endif /* Store the masked state */ state[c] = r; } keyboard_raw_drive_column(KEYBOARD_COLUMN_NONE); return pressed ? 1 : 0; } /** * Check special runtime key combinations. * * @param state Keyboard state to use when checking keys. * * @return 1 if a special key was pressed, 0 if not */ static int check_runtime_keys(const uint8_t *state) { int num_press = 0; int c; /* * All runtime key combos are (right or left ) alt + volume up + (some * key NOT on the same col as alt or volume up ) */ if (state[KEYBOARD_COL_VOL_UP] != KEYBOARD_MASK_VOL_UP) return 0; if (state[KEYBOARD_COL_RIGHT_ALT] != KEYBOARD_MASK_RIGHT_ALT && state[KEYBOARD_COL_LEFT_ALT] != KEYBOARD_MASK_LEFT_ALT) return 0; /* * Count number of columns with keys pressed. We know two columns are * pressed for volume up and alt, so if only one more key is pressed * there will be exactly 3 non-zero columns. */ for (c = 0; c < KEYBOARD_COLS; c++) { if (state[c]) num_press++; } if (num_press != 3) return 0; /* Check individual keys */ if (state[KEYBOARD_COL_KEY_R] == KEYBOARD_MASK_KEY_R) { /* R = reboot */ CPRINTS("KB warm reboot"); keyboard_clear_buffer(); chipset_reset(0); return 1; } else if (state[KEYBOARD_COL_KEY_H] == KEYBOARD_MASK_KEY_H) { /* H = hibernate */ CPRINTS("KB hibernate"); system_hibernate(0, 0); return 1; } return 0; } /** * Check for ghosting in the keyboard state. * * Assumes that the state has already been masked with the actual key mask, so * that coords which don't correspond with actual keys don't trigger ghosting * detection. * * @param state Keyboard state to check. * * @return 1 if ghosting detected, else 0. */ static int has_ghosting(const uint8_t *state) { int c, c2; for (c = 0; c < KEYBOARD_COLS; c++) { if (!state[c]) continue; for (c2 = c + 1; c2 < KEYBOARD_COLS; c2++) { /* * A little bit of cleverness here. Ghosting happens * if 2 columns share at least 2 keys. So we OR the * columns together and then see if more than one bit * is set. x&(x-1) is non-zero only if x has more than * one bit set. */ uint8_t common = state[c] & state[c2]; if (common & (common - 1)) return 1; } } return 0; } /** * Update keyboard state using low-level interface to read keyboard. * * @param state Keyboard state to update. * * @return 1 if any key is still pressed, 0 if no key is pressed. */ static int check_keys_changed(uint8_t *state) { int any_pressed = 0; int c, i; int any_change = 0; static uint8_t new_state[KEYBOARD_COLS]; uint32_t tnow = get_time().le.lo; /* Save the current scan time */ if (++scan_time_index >= SCAN_TIME_COUNT) scan_time_index = 0; scan_time[scan_time_index] = tnow; /* Read the raw key state */ any_pressed = read_matrix(new_state); /* Ignore if so many keys are pressed that we're ghosting. */ if (has_ghosting(new_state)) return any_pressed; /* Check for changes between previous scan and this one */ for (c = 0; c < KEYBOARD_COLS; c++) { int diff = new_state[c] ^ prev_state[c]; if (!diff) continue; for (i = 0; i < KEYBOARD_ROWS; i++) { if (diff & (1 << i)) scan_edge_index[c][i] = scan_time_index; } debouncing[c] |= diff; prev_state[c] = new_state[c]; } /* Check for keys which are done debouncing */ for (c = 0; c < KEYBOARD_COLS; c++) { int debc = debouncing[c]; if (!debc) continue; for (i = 0; i < KEYBOARD_ROWS; i++) { int mask = 1 << i; int new_mask = new_state[c] & mask; /* Are we done debouncing this key? */ if (!(debc & mask)) continue; /* Not debouncing this key */ if (tnow - scan_time[scan_edge_index[c][i]] < (new_mask ? keyscan_config.debounce_down_us : keyscan_config.debounce_up_us)) continue; /* Not done debouncing */ debouncing[c] &= ~mask; /* Did the key change from its previous state? */ if ((state[c] & mask) == new_mask) continue; /* No */ state[c] ^= mask; any_change = 1; #ifdef CONFIG_KEYBOARD_PROTOCOL_8042 /* Inform keyboard module if scanning is enabled */ if (keyboard_scan_is_enabled()) keyboard_state_changed(i, c, new_mask ? 1 : 0); #endif } } if (any_change) { #ifdef CONFIG_KEYBOARD_SUPPRESS_NOISE /* Suppress keyboard noise */ keyboard_suppress_noise(); #endif if (print_state_changes) print_state(state, "state"); #ifdef PRINT_SCAN_TIMES /* Print delta times from now back to each previous scan */ CPRINTF("[%T kb deltaT"); for (i = 0; i < SCAN_TIME_COUNT; i++) { int tnew = scan_time[ (SCAN_TIME_COUNT + scan_time_index - i) % SCAN_TIME_COUNT]; CPRINTF(" %d", tnow - tnew); } CPRINTF("]\n"); #endif /* Swallow special keys */ if (check_runtime_keys(state)) return 0; #ifdef CONFIG_KEYBOARD_PROTOCOL_MKBP keyboard_fifo_add(state); #endif } kbd_polls++; return any_pressed; } /* * Return non-zero if the specified key is pressed, with at most the keys used * for keyboard-controlled reset also pressed. */ static int check_key(const uint8_t *state, int index, int mask) { uint8_t allowed_mask[KEYBOARD_COLS] = {0}; int c; /* Check for the key */ if (mask && !(state[index] & mask)) return 0; /* Check for other allowed keys */ allowed_mask[index] |= mask; allowed_mask[KEYBOARD_COL_REFRESH] |= KEYBOARD_MASK_REFRESH; for (c = 0; c < KEYBOARD_COLS; c++) { if (state[c] & ~allowed_mask[c]) return 0; /* Disallowed key pressed */ } return 1; } /** * Check what boot key is down, if any. * * @param state Keyboard state at boot. * * @return the key which is down, or BOOT_KEY_OTHER if an unrecognized * key combination is down or this isn't the right type of boot to look at * boot keys. */ static enum boot_key check_boot_key(const uint8_t *state) { const struct boot_key_entry *k = boot_key_list; int i; /* * If we jumped to this image, ignore boot keys. This prevents * re-triggering events in RW firmware that were already processed by * RO firmware. */ if (system_jumped_to_this_image()) return BOOT_KEY_OTHER; /* If reset was not caused by reset pin, refresh must be held down */ if (!(system_get_reset_flags() & RESET_FLAG_RESET_PIN) && !(state[KEYBOARD_COL_REFRESH] & KEYBOARD_MASK_REFRESH)) return BOOT_KEY_OTHER; /* Check what single key is down */ for (i = 0; i < ARRAY_SIZE(boot_key_list); i++, k++) { if (check_key(state, k->mask_index, k->mask_value)) { CPRINTS("KB boot key %d", i); return i; } } return BOOT_KEY_OTHER; } static void keyboard_freq_change(void) { post_scan_clock_us = (CONFIG_KEYBOARD_POST_SCAN_CLOCKS * 1000) / (clock_get_freq() / 1000); } DECLARE_HOOK(HOOK_FREQ_CHANGE, keyboard_freq_change, HOOK_PRIO_DEFAULT); /*****************************************************************************/ /* Interface */ struct keyboard_scan_config *keyboard_scan_get_config(void) { return &keyscan_config; } enum boot_key keyboard_scan_get_boot_key(void) { return boot_key_value; } const uint8_t *keyboard_scan_get_state(void) { return debounced_state; } void keyboard_scan_init(void) { /* Configure GPIO */ keyboard_raw_init(); /* Tri-state the columns */ keyboard_raw_drive_column(KEYBOARD_COLUMN_NONE); /* Initialize raw state */ read_matrix(debounced_state); memcpy(prev_state, debounced_state, sizeof(prev_state)); /* Check for keys held down at boot */ boot_key_value = check_boot_key(debounced_state); /* Trigger event if recovery key was pressed */ if (boot_key_value == BOOT_KEY_ESC) host_set_single_event(EC_HOST_EVENT_KEYBOARD_RECOVERY); } void keyboard_scan_task(void) { timestamp_t poll_deadline, start; int wait_time; print_state(debounced_state, "init state"); keyboard_raw_task_start(); /* Set initial clock frequency-based minimum delay between scans */ keyboard_freq_change(); while (1) { /* Enable all outputs */ CPRINTS("KB wait"); if (keyboard_scan_is_enabled()) keyboard_raw_drive_column(KEYBOARD_COLUMN_ALL); keyboard_raw_enable_interrupt(1); /* Wait for scanning enabled and key pressed. */ do { /* * Don't wait if scanning is enabled and a key is * already pressed. This prevents a race between the * user pressing a key and enable_interrupt() * starting to pay attention to edges. */ if (!keyboard_raw_read_rows() || !keyboard_scan_is_enabled()) task_wait_event(-1); } while (!keyboard_scan_is_enabled()); /* Enter polling mode */ CPRINTS("KB poll"); keyboard_raw_enable_interrupt(0); keyboard_raw_drive_column(KEYBOARD_COLUMN_NONE); /* Busy polling keyboard state. */ while (keyboard_scan_is_enabled()) { start = get_time(); /* Check for keys down */ if (check_keys_changed(debounced_state)) { poll_deadline.val = start.val + keyscan_config.poll_timeout_us; } else if (timestamp_expired(poll_deadline, &start)) { break; } /* Delay between scans */ wait_time = keyscan_config.scan_period_us - (get_time().val - start.val); if (wait_time < keyscan_config.min_post_scan_delay_us) wait_time = keyscan_config.min_post_scan_delay_us; if (wait_time < post_scan_clock_us) wait_time = post_scan_clock_us; usleep(wait_time); } } } #ifdef CONFIG_LID_SWITCH static void keyboard_lid_change(void) { if (lid_is_open()) keyboard_scan_enable(1, KB_SCAN_DISABLE_LID_CLOSED); else keyboard_scan_enable(0, KB_SCAN_DISABLE_LID_CLOSED); } DECLARE_HOOK(HOOK_LID_CHANGE, keyboard_lid_change, HOOK_PRIO_DEFAULT); #endif /*****************************************************************************/ /* Host commands */ static int mkbp_command_simulate_key(struct host_cmd_handler_args *args) { const struct ec_params_mkbp_simulate_key *p = args->params; /* Only available on unlocked systems */ if (system_is_locked()) return EC_RES_ACCESS_DENIED; if (p->col >= KEYBOARD_COLS || p->row >= KEYBOARD_ROWS) return EC_RES_INVALID_PARAM; simulate_key(p->row, p->col, p->pressed); return EC_RES_SUCCESS; } DECLARE_HOST_COMMAND(EC_CMD_MKBP_SIMULATE_KEY, mkbp_command_simulate_key, EC_VER_MASK(0)); /*****************************************************************************/ /* Console commands */ static int command_ksstate(int argc, char **argv) { if (argc > 1 && !parse_bool(argv[1], &print_state_changes)) return EC_ERROR_PARAM1; print_state(debounced_state, "debounced "); print_state(prev_state, "prev "); print_state(debouncing, "debouncing"); ccprintf("Keyboard scan disable mask: 0x%08x\n", disable_scanning_mask); ccprintf("Keyboard scan state printing %s\n", print_state_changes ? "on" : "off"); return EC_SUCCESS; } DECLARE_CONSOLE_COMMAND(ksstate, command_ksstate, "ksstate [on | off]", "Show or toggle printing keyboard scan state", NULL); static int command_keyboard_press(int argc, char **argv) { if (argc == 1) { int i, j; ccputs("Simulated keys:\n"); for (i = 0; i < KEYBOARD_COLS; ++i) { if (simulated_key[i] == 0) continue; for (j = 0; j < KEYBOARD_ROWS; ++j) if (simulated_key[i] & (1 << j)) ccprintf("\t%d %d\n", i, j); } } else if (argc == 3 || argc == 4) { int r, c, p; char *e; c = strtoi(argv[1], &e, 0); if (*e || c < 0 || c >= KEYBOARD_COLS) return EC_ERROR_PARAM1; r = strtoi(argv[2], &e, 0); if (*e || r < 0 || r >= KEYBOARD_ROWS) return EC_ERROR_PARAM2; if (argc == 3) { /* Simulate a press and release */ simulate_key(r, c, 1); simulate_key(r, c, 0); } else { p = strtoi(argv[3], &e, 0); if (*e || p < 0 || p > 1) return EC_ERROR_PARAM3; simulate_key(r, c, p); } } return EC_SUCCESS; } DECLARE_CONSOLE_COMMAND(kbpress, command_keyboard_press, "[col row [0 | 1]]", "Simulate keypress", NULL);