/* Copyright 2014 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. */ /* Motion sense module to read from various motion sensors. */ #include "accelgyro.h" #include "atomic.h" #include "chipset.h" #include "common.h" #include "console.h" #include "gesture.h" #include "hooks.h" #include "host_command.h" #include "hwtimer.h" #include "lid_angle.h" #include "lightbar.h" #include "math_util.h" #include "mkbp_event.h" #include "motion_sense.h" #include "motion_sense_fifo.h" #include "motion_lid.h" #include "power.h" #include "queue.h" #include "tablet_mode.h" #include "timer.h" #include "task.h" #include "util.h" /* Console output macros */ #define CPUTS(outstr) cputs(CC_MOTION_SENSE, outstr) #define CPRINTS(format, args...) cprints(CC_MOTION_SENSE, format, ## args) #define CPRINTF(format, args...) cprintf(CC_MOTION_SENSE, format, ## args) #ifdef CONFIG_ORIENTATION_SENSOR /* * Orientation mode vectors, must match sequential ordering of * known orientations from enum motionsensor_orientation */ const intv3_t orientation_modes[] = { [MOTIONSENSE_ORIENTATION_LANDSCAPE] = { 0, -1, 0 }, [MOTIONSENSE_ORIENTATION_PORTRAIT] = { 1, 0, 0 }, [MOTIONSENSE_ORIENTATION_UPSIDE_DOWN_PORTRAIT] = { -1, 0, 0 }, [MOTIONSENSE_ORIENTATION_UPSIDE_DOWN_LANDSCAPE] = { 0, 1, 0 }, }; #endif /* Delay between FIFO interruption. */ static unsigned int ap_event_interval; /* Minimum time in between running motion sense task loop. */ unsigned int motion_min_interval = CONFIG_MOTION_MIN_SENSE_WAIT_TIME * MSEC; #ifdef CONFIG_CMD_ACCEL_INFO static int accel_disp; #endif #define SENSOR_ACTIVE(_sensor) (sensor_active & (_sensor)->active_mask) /* * Adjustment in us to ec rate when calculating interrupt interval: * To be sure the EC will send an interrupt even if it finishes processing * events slightly earlier than the previous period. */ #define MOTION_SENSOR_INT_ADJUSTMENT_US 10 struct mutex g_sensor_mutex; /* * Current power level (S0, S3, S5, ...) */ test_export_static enum chipset_state_mask sensor_active; #ifdef CONFIG_ACCEL_SPOOF_MODE static void print_spoof_mode_status(int id); #endif /* defined(CONFIG_ACCEL_SPOOF_MODE) */ /* Flags to control whether to send an ODR change event for a sensor */ static uint32_t odr_event_required; static inline int motion_sensor_in_forced_mode( const struct motion_sensor_t *sensor) { #ifdef CONFIG_ACCEL_FORCE_MODE_MASK /* Sensor not in force mode, its irq_handler is getting data. */ if (!(CONFIG_ACCEL_FORCE_MODE_MASK & (1 << (sensor - motion_sensors)))) return 0; else return 1; #else return 0; #endif } /* Minimal amount of time since last collection before triggering a new one */ static inline int motion_sensor_time_to_read(const timestamp_t *ts, const struct motion_sensor_t *sensor) { if (sensor->collection_rate == 0) return 0; /* * If the time is within the min motion interval (3 ms) go ahead and * read from the sensor */ return time_after(ts->le.lo, sensor->next_collection - motion_min_interval); } static enum sensor_config motion_sense_get_ec_config(void) { switch (sensor_active) { case SENSOR_ACTIVE_S0: return SENSOR_CONFIG_EC_S0; case SENSOR_ACTIVE_S3: return SENSOR_CONFIG_EC_S3; case SENSOR_ACTIVE_S5: return SENSOR_CONFIG_EC_S5; default: CPRINTS("get_ec_config: Invalid active state: %x", sensor_active); return SENSOR_CONFIG_MAX; } } /* motion_sense_set_data_rate * * Set the sensor data rate. It is altered when the AP change the data * rate or when the power state changes. */ int motion_sense_set_data_rate(struct motion_sensor_t *sensor) { int roundup, ap_odr_mhz = 0, ec_odr_mhz, odr, ret; enum sensor_config config_id; timestamp_t ts = get_time(); /* We assume the sensor is initialized */ /* Check the AP setting first. */ if (sensor_active != SENSOR_ACTIVE_S5) ap_odr_mhz = BASE_ODR(sensor->config[SENSOR_CONFIG_AP].odr); /* check if the EC set the sensor ODR at a higher frequency */ config_id = motion_sense_get_ec_config(); ec_odr_mhz = BASE_ODR(sensor->config[config_id].odr); if (ec_odr_mhz > ap_odr_mhz) { odr = ec_odr_mhz; } else { odr = ap_odr_mhz; config_id = SENSOR_CONFIG_AP; } roundup = !!(sensor->config[config_id].odr & ROUND_UP_FLAG); ret = sensor->drv->set_data_rate(sensor, odr, roundup); if (ret) return ret; #ifdef CONFIG_CONSOLE_VERBOSE CPRINTS("%s ODR: %d - roundup %d from config %d [AP %d]", sensor->name, odr, roundup, config_id, BASE_ODR(sensor->config[SENSOR_CONFIG_AP].odr)); #else CPRINTS("%c%d ODR %d rup %d cfg %d AP %d", sensor->name[0], sensor->type, odr, roundup, config_id, BASE_ODR(sensor->config[SENSOR_CONFIG_AP].odr)); #endif mutex_lock(&g_sensor_mutex); if (ap_odr_mhz) /* * In case the AP want to run the sensors faster than it can, * be sure we don't see the ratio to 0. */ sensor->oversampling_ratio = MAX(1, sensor->drv->get_data_rate(sensor) / ap_odr_mhz); else sensor->oversampling_ratio = 0; /* * Reset last collection: the last collection may be so much in the past * it may appear to be in the future. */ odr = sensor->drv->get_data_rate(sensor); sensor->collection_rate = odr > 0 ? SECOND * 1000 / odr : 0; sensor->next_collection = ts.le.lo + sensor->collection_rate; sensor->oversampling = 0; mutex_unlock(&g_sensor_mutex); return 0; } static int motion_sense_set_ec_rate_from_ap( const struct motion_sensor_t *sensor, unsigned int new_rate_us) { int odr_mhz = sensor->drv->get_data_rate(sensor); if (new_rate_us == 0) return 0; if (motion_sensor_in_forced_mode(sensor)) /* * AP EC sampling rate does not matter: we will collect at the * requested sensor frequency. */ goto end_set_ec_rate_from_ap; if (odr_mhz == 0) goto end_set_ec_rate_from_ap; /* * If the EC collection rate is close to the sensor data rate, * given variation from the EC scheduler, it is possible that a sensor * will not present any measurement for a given time slice, and then 2 * measurement for the next. That will create a large interval between * 2 measurements. * To prevent that, increase the EC period by 5% to be sure to get at * least one measurement at every collection time. * We will apply that correction only if the ec rate is within 10% of * the data rate. */ if (SECOND * 1100 / odr_mhz > new_rate_us) new_rate_us = new_rate_us / 100 * 105; end_set_ec_rate_from_ap: return MAX(new_rate_us, motion_min_interval); } /* * motion_sense_select_ec_rate * * Calculate the ec_rate for a given sensor. * - sensor: sensor to use * - config_id: determine the requester (AP or EC). * - interrupt: * If interrupt is set: return the sampling rate requested by AP or EC. * If interrupt is not set and the sensor is in forced mode, * we return the rate needed to probe the sensor at the right ODR. * otherwise return the sampling rate requested by AP or EC. * * return rate in us. */ static int motion_sense_select_ec_rate( const struct motion_sensor_t *sensor, enum sensor_config config_id, int interrupt) { if (interrupt == 0 && motion_sensor_in_forced_mode(sensor)) { int rate_mhz = BASE_ODR(sensor->config[config_id].odr); /* we have to run ec at the sensor frequency rate.*/ if (rate_mhz > 0) return SECOND * 1000 / rate_mhz; else return 0; } else { return sensor->config[config_id].ec_rate; } } /* motion_sense_ec_rate * * Calculate the sensor ec rate. It will be use to set the motion task polling * rate. * * Return the EC rate, in us. */ static int motion_sense_ec_rate(struct motion_sensor_t *sensor) { int ec_rate = 0, ec_rate_from_cfg; /* Check the AP setting first. */ if (sensor_active != SENSOR_ACTIVE_S5) ec_rate = motion_sense_select_ec_rate( sensor, SENSOR_CONFIG_AP, 0); ec_rate_from_cfg = motion_sense_select_ec_rate( sensor, motion_sense_get_ec_config(), 0); if (ec_rate_from_cfg != 0) if (ec_rate == 0 || ec_rate_from_cfg < ec_rate) ec_rate = ec_rate_from_cfg; return ec_rate; } /* * motion_sense_set_motion_intervals * * Set the wake up interval for the motion sense thread. * It is set to the highest frequency one of the sensors need to be polled at. * * Note: Not static to be tested. */ static void motion_sense_set_motion_intervals(void) { int i, sensor_ec_rate, ec_int_rate = 0; struct motion_sensor_t *sensor; for (i = 0; i < motion_sensor_count; ++i) { sensor = &motion_sensors[i]; /* * If the sensor is sleeping, no need to check it periodically. */ if ((sensor->state != SENSOR_INITIALIZED) || (sensor->drv->get_data_rate(sensor) == 0)) continue; sensor_ec_rate = motion_sense_select_ec_rate( sensor, SENSOR_CONFIG_AP, 1); if (ec_int_rate == 0 || (sensor_ec_rate && sensor_ec_rate < ec_int_rate)) ec_int_rate = sensor_ec_rate; } ap_event_interval = MAX(0, ec_int_rate - MOTION_SENSOR_INT_ADJUSTMENT_US); /* * Wake up the motion sense task: we want to sensor task to take * in account the new period right away. */ task_wake(TASK_ID_MOTIONSENSE); } static inline int motion_sense_init(struct motion_sensor_t *sensor) { int ret, cnt = 3; /* Initialize accelerometers. */ do { ret = sensor->drv->init(sensor); } while ((ret != EC_SUCCESS) && (--cnt > 0)); if (ret != EC_SUCCESS) { sensor->state = SENSOR_INIT_ERROR; } else { sensor->state = SENSOR_INITIALIZED; motion_sense_set_data_rate(sensor); } return ret; } /* * sensor_init_done * * Called by init routine of each sensors when successful. */ int sensor_init_done(const struct motion_sensor_t *s) { int ret; ret = s->drv->set_range(s, BASE_RANGE(s->default_range), !!(s->default_range & ROUND_UP_FLAG)); if (ret == EC_RES_SUCCESS) { #ifdef CONFIG_CONSOLE_VERBOSE CPRINTS("%s: MS Done Init type:0x%X range:%d", s->name, s->type, s->drv->get_range(s)); #else CPRINTS("%c%d InitDone r:%d", s->name[0], s->type, s->drv->get_range(s)); #endif } return ret; } /* * motion_sense_switch_sensor_rate * * Suspend all sensors that are not needed. * Mark them as uninitialized, they will lose power and * need to be initialized again. */ static void motion_sense_switch_sensor_rate(void) { int i, ret; struct motion_sensor_t *sensor; for (i = 0; i < motion_sensor_count; ++i) { sensor = &motion_sensors[i]; if (SENSOR_ACTIVE(sensor)) { /* Initialize or just back the odr previously set. */ if (sensor->state == SENSOR_INITIALIZED) { motion_sense_set_data_rate(sensor); } else { ret = motion_sense_init(sensor); if (ret != EC_SUCCESS) { CPRINTS("%s: %d: init failed: %d", sensor->name, i, ret); #if defined(CONFIG_TABLET_MODE) && defined(CONFIG_LID_ANGLE) /* * No tablet mode allowed if an accel * is not working. */ if (i == CONFIG_LID_ANGLE_SENSOR_BASE || i == CONFIG_LID_ANGLE_SENSOR_LID) { tablet_set_mode(0); } #endif } } } else { /* The sensors are being powered off */ if (sensor->state == SENSOR_INITIALIZED) sensor->state = SENSOR_NOT_INITIALIZED; } } motion_sense_set_motion_intervals(); } DECLARE_DEFERRED(motion_sense_switch_sensor_rate); static void motion_sense_shutdown(void) { int i; struct motion_sensor_t *sensor; #ifdef CONFIG_GESTURE_DETECTION_MASK uint32_t enabled = 0, disabled, mask; #endif sensor_active = SENSOR_ACTIVE_S5; for (i = 0; i < motion_sensor_count; i++) { sensor = &motion_sensors[i]; /* Forget about changes made by the AP */ sensor->config[SENSOR_CONFIG_AP].odr = 0; sensor->config[SENSOR_CONFIG_AP].ec_rate = 0; } motion_sense_switch_sensor_rate(); /* Forget activities set by the AP */ #ifdef CONFIG_GESTURE_DETECTION_MASK mask = CONFIG_GESTURE_DETECTION_MASK; while (mask) { i = get_next_bit(&mask); sensor = &motion_sensors[i]; if (sensor->state != SENSOR_INITIALIZED) continue; sensor->drv->list_activities(sensor, &enabled, &disabled); /* exclude double tap, it is used internally. */ enabled &= ~BIT(MOTIONSENSE_ACTIVITY_DOUBLE_TAP); while (enabled) { int activity = get_next_bit(&enabled); sensor->drv->manage_activity(sensor, activity, 0, NULL); } /* Re-enable double tap in case AP disabled it */ sensor->drv->manage_activity(sensor, MOTIONSENSE_ACTIVITY_DOUBLE_TAP, 1, NULL); } #endif } DECLARE_HOOK(HOOK_CHIPSET_SHUTDOWN, motion_sense_shutdown, MOTION_SENSE_HOOK_PRIO); static void motion_sense_suspend(void) { /* * If we are coming from S5, don't enter suspend: * We will go in SO almost immediately. */ if (sensor_active == SENSOR_ACTIVE_S5) return; sensor_active = SENSOR_ACTIVE_S3; /* * During shutdown sequence sensor rails can be powered down * asynchronously to the EC hence EC cannot interlock the sensor * states with the power down states. To avoid this issue, defer * switching the sensors rate with a configurable delay if in S3. * By the time deferred function is serviced, if the chipset is * in S5 we can back out from switching the sensor rate. * * TODO: This does not fix the issue completely. It is mitigating * some of the accesses when we're going from S0->S5 with a very * brief stop in S3. */ hook_call_deferred(&motion_sense_switch_sensor_rate_data, CONFIG_MOTION_SENSE_SUSPEND_DELAY_US); } DECLARE_HOOK(HOOK_CHIPSET_SUSPEND, motion_sense_suspend, MOTION_SENSE_HOOK_PRIO); static void motion_sense_resume(void) { sensor_active = SENSOR_ACTIVE_S0; hook_call_deferred(&motion_sense_switch_sensor_rate_data, CONFIG_MOTION_SENSE_RESUME_DELAY_US); } DECLARE_HOOK(HOOK_CHIPSET_RESUME, motion_sense_resume, MOTION_SENSE_HOOK_PRIO); static void motion_sense_startup(void) { /* * If the AP is already in S0, call the resume hook now. * We may initialize the sensor 2 times (once in RO, another time in * RW), but it may be necessary if the init sequence has changed. */ if (chipset_in_state(SENSOR_ACTIVE_S0_S3_S5)) motion_sense_shutdown(); if (chipset_in_state(SENSOR_ACTIVE_S0_S3)) motion_sense_suspend(); if (chipset_in_state(SENSOR_ACTIVE_S0)) motion_sense_resume(); } DECLARE_HOOK(HOOK_INIT, motion_sense_startup, MOTION_SENSE_HOOK_PRIO); /* Write to LPC status byte to represent that accelerometers are present. */ static inline void set_present(uint8_t *lpc_status) { *lpc_status |= EC_MEMMAP_ACC_STATUS_PRESENCE_BIT; } #ifdef CONFIG_MOTION_FILL_LPC_SENSE_DATA /* Update/Write LPC data */ static inline void update_sense_data(uint8_t *lpc_status, int *psample_id) { int s, d, i; uint16_t *lpc_data = (uint16_t *)host_get_memmap(EC_MEMMAP_ACC_DATA); #if (!defined HAS_TASK_ALS) && (defined CONFIG_ALS) uint16_t *lpc_als = (uint16_t *)host_get_memmap(EC_MEMMAP_ALS); #endif struct motion_sensor_t *sensor; /* * Set the busy bit before writing the sensor data. Increment * the counter and clear the busy bit after writing the sensor * data. On the host side, the host needs to make sure the busy * bit is not set and that the counter remains the same before * and after reading the data. */ *lpc_status |= EC_MEMMAP_ACC_STATUS_BUSY_BIT; /* * Copy sensor data to shared memory. Note that this code * assumes little endian, which is what the host expects. Also, * note that we share the lid angle calculation with host only * for debugging purposes. The EC lid angle is an approximation * with uncalibrated accelerometers. The AP calculates a separate, * more accurate lid angle. */ #ifdef CONFIG_LID_ANGLE lpc_data[0] = motion_lid_get_angle(); #else lpc_data[0] = LID_ANGLE_UNRELIABLE; #endif /* * The first 2 entries must be accelerometers, then gyroscope. * If there is only one accel and one gyro, the entry for the second * accel is skipped. */ for (s = 0, d = 0; d < 3 && s < motion_sensor_count; s++, d++) { sensor = &motion_sensors[s]; if (sensor->type > MOTIONSENSE_TYPE_GYRO) break; else if (sensor->type == MOTIONSENSE_TYPE_GYRO) d = 2; for (i = X; i <= Z; i++) lpc_data[1 + i + 3 * d] = sensor->xyz[i]; } #if (!defined HAS_TASK_ALS) && (defined CONFIG_ALS) for (i = 0; i < EC_ALS_ENTRIES && i < ALS_COUNT; i++) lpc_als[i] = motion_als_sensors[i]->xyz[X]; #endif /* * Increment sample id and clear busy bit to signal we finished * updating data. */ *psample_id = (*psample_id + 1) & EC_MEMMAP_ACC_STATUS_SAMPLE_ID_MASK; *lpc_status = EC_MEMMAP_ACC_STATUS_PRESENCE_BIT | *psample_id; } #endif static int motion_sense_read(struct motion_sensor_t *sensor) { if (sensor->state != SENSOR_INITIALIZED) return EC_ERROR_UNKNOWN; if (sensor->drv->get_data_rate(sensor) == 0) return EC_ERROR_NOT_POWERED; #ifdef CONFIG_ACCEL_SPOOF_MODE /* * If the sensor is in spoof mode, the readings are already present in * spoof_xyz. */ if (sensor->flags & MOTIONSENSE_FLAG_IN_SPOOF_MODE) return EC_SUCCESS; #endif /* defined(CONFIG_ACCEL_SPOOF_MODE) */ /* Otherwise, read all raw X,Y,Z accelerations. */ return sensor->drv->read(sensor, sensor->raw_xyz); } static inline void increment_sensor_collection(struct motion_sensor_t *sensor, const timestamp_t *ts) { sensor->next_collection += sensor->collection_rate; if (time_after(ts->le.lo, sensor->next_collection)) { /* * If we get here it means that we completely missed a sensor * collection time and we attempt to recover by scheduling as * soon as possible. This should not happen and if it does it * means that the ec cannot handle the requested data rate. */ int missed_events = time_until(sensor->next_collection, ts->le.lo) / sensor->collection_rate; CPRINTS("%s Missed %d data collections at %u - rate: %d", sensor->name, missed_events, sensor->next_collection, sensor->collection_rate); sensor->next_collection = ts->le.lo + motion_min_interval; } } static int motion_sense_process(struct motion_sensor_t *sensor, uint32_t *event, const timestamp_t *ts) { int ret = EC_SUCCESS; int is_odr_pending = 0; if (*event & TASK_EVENT_MOTION_ODR_CHANGE) { const int sensor_bit = 1 << (sensor - motion_sensors); int odr_pending = atomic_read_clear(&odr_event_required); is_odr_pending = odr_pending & sensor_bit; odr_pending &= ~sensor_bit; atomic_or(&odr_event_required, odr_pending); } #ifdef CONFIG_ACCEL_INTERRUPTS if ((*event & TASK_EVENT_MOTION_INTERRUPT_MASK || is_odr_pending) && (sensor->drv->irq_handler != NULL)) { ret = sensor->drv->irq_handler(sensor, event); } #endif if (IS_ENABLED(CONFIG_ACCEL_FIFO)) { if (motion_sensor_in_forced_mode(sensor)) { if (motion_sensor_time_to_read(ts, sensor)) { struct ec_response_motion_sensor_data vector; int *v = sensor->raw_xyz; ret = motion_sense_read(sensor); if (ret == EC_SUCCESS) { vector.flags = 0; vector.sensor_num = sensor - motion_sensors; if (IS_ENABLED(CONFIG_ACCEL_SPOOF_MODE) && sensor->flags & MOTIONSENSE_FLAG_IN_SPOOF_MODE) v = sensor->spoof_xyz; vector.data[X] = v[X]; vector.data[Y] = v[Y]; vector.data[Z] = v[Z]; motion_sense_fifo_stage_data( &vector, sensor, 3, __hw_clock_source_read()); motion_sense_fifo_commit_data(); } increment_sensor_collection(sensor, ts); } else { ret = EC_ERROR_BUSY; } } if (*event & TASK_EVENT_MOTION_FLUSH_PENDING) { int flush_pending = atomic_read_clear( &sensor->flush_pending); for (; flush_pending > 0; flush_pending--) { motion_sense_insert_async_event(sensor, ASYNC_EVENT_FLUSH); } } } else { if (motion_sensor_in_forced_mode(sensor)) { if (motion_sensor_time_to_read(ts, sensor)) { /* Get latest data for local calculation */ ret = motion_sense_read(sensor); increment_sensor_collection(sensor, ts); } else { ret = EC_ERROR_BUSY; } if (ret == EC_SUCCESS) { mutex_lock(&g_sensor_mutex); memcpy(sensor->xyz, sensor->raw_xyz, sizeof(sensor->xyz)); mutex_unlock(&g_sensor_mutex); } } } /* ODR change was requested. */ if (is_odr_pending) { motion_sense_set_data_rate(sensor); motion_sense_set_motion_intervals(); if (IS_ENABLED(CONFIG_ACCEL_FIFO)) motion_sense_insert_async_event( sensor, ASYNC_EVENT_ODR); } return ret; } #ifdef CONFIG_ORIENTATION_SENSOR enum motionsensor_orientation motion_sense_remap_orientation( const struct motion_sensor_t *s, enum motionsensor_orientation orientation) { enum motionsensor_orientation rotated_orientation; const intv3_t *orientation_v; intv3_t rotated_orientation_v; if (orientation == MOTIONSENSE_ORIENTATION_UNKNOWN) return MOTIONSENSE_ORIENTATION_UNKNOWN; orientation_v = &orientation_modes[orientation]; rotate(*orientation_v, *s->rot_standard_ref, rotated_orientation_v); rotated_orientation = ((2 * rotated_orientation_v[1] + rotated_orientation_v[0] + 4) % 5); return rotated_orientation; } #endif #ifdef CONFIG_GESTURE_DETECTION static void check_and_queue_gestures(uint32_t *event) { #ifdef CONFIG_ORIENTATION_SENSOR const struct motion_sensor_t *sensor; #endif #ifdef CONFIG_GESTURE_SW_DETECTION /* Run gesture recognition engine */ gesture_calc(event); #endif #ifdef CONFIG_GESTURE_SENSOR_BATTERY_TAP if (*event & TASK_EVENT_MOTION_ACTIVITY_INTERRUPT( MOTIONSENSE_ACTIVITY_DOUBLE_TAP)) { #ifdef CONFIG_GESTURE_HOST_DETECTION struct ec_response_motion_sensor_data vector; /* * Send events to the FIFO * AP is ignoring double tap event, do no wake up and no * automatic disable. */ vector.flags = 0; vector.activity = MOTIONSENSE_ACTIVITY_DOUBLE_TAP; vector.state = 1; /* triggered */ vector.sensor_num = MOTION_SENSE_ACTIVITY_SENSOR_ID; motion_sense_fifo_stage_data(&vector, NULL, 0, __hw_clock_source_read()); motion_sense_fifo_commit_data(); #endif /* Call board specific function to process tap */ sensor_board_proc_double_tap(); } #endif #ifdef CONFIG_GESTURE_SIGMO if (*event & TASK_EVENT_MOTION_ACTIVITY_INTERRUPT( MOTIONSENSE_ACTIVITY_SIG_MOTION)) { struct motion_sensor_t *activity_sensor; #ifdef CONFIG_GESTURE_HOST_DETECTION struct ec_response_motion_sensor_data vector; /* Send events to the FIFO */ vector.flags = MOTIONSENSE_SENSOR_FLAG_WAKEUP; vector.activity = MOTIONSENSE_ACTIVITY_SIG_MOTION; vector.state = 1; /* triggered */ vector.sensor_num = MOTION_SENSE_ACTIVITY_SENSOR_ID; motion_sense_fifo_stage_data(&vector, NULL, 0, __hw_clock_source_read()); motion_sense_fifo_commit_data(); #endif /* Disable further detection */ activity_sensor = &motion_sensors[CONFIG_GESTURE_SIGMO]; activity_sensor->drv->manage_activity( activity_sensor, MOTIONSENSE_ACTIVITY_SIG_MOTION, 0, NULL); } #endif #ifdef CONFIG_ORIENTATION_SENSOR sensor = &motion_sensors[LID_ACCEL]; if (SENSOR_ACTIVE(sensor) && (sensor->state == SENSOR_INITIALIZED)) { struct ec_response_motion_sensor_data vector = { .flags = 0, .activity = MOTIONSENSE_ACTIVITY_ORIENTATION, .sensor_num = MOTION_SENSE_ACTIVITY_SENSOR_ID, }; mutex_lock(sensor->mutex); if (ORIENTATION_CHANGED(sensor) && (GET_ORIENTATION(sensor) != MOTIONSENSE_ORIENTATION_UNKNOWN)) { SET_ORIENTATION_UPDATED(sensor); vector.state = GET_ORIENTATION(sensor); motion_sense_fifo_add_data(&vector, NULL, 0, __hw_clock_source_read()); #ifdef CONFIG_DEBUG_ORIENTATION { static const char * const mode_strs[] = { "Landscape", "Portrait", "Inv_Portrait", "Inv_Landscape", "Unknown" }; CPRINTS(mode_strs[GET_ORIENTATION(sensor)]); } #endif } mutex_unlock(sensor->mutex); } #endif } #endif /* * Motion Sense Task * Requirement: motion_sensors[] are defined in board.c file. * Two (minimum) Accelerometers: * 1 in the A/B(lid, display) and 1 in the C/D(base, keyboard) * Gyro Sensor (optional) */ void motion_sense_task(void *u) { int i, ret, wait_us; timestamp_t ts_begin_task, ts_end_task; int32_t time_diff; uint32_t event = 0; uint16_t ready_status; struct motion_sensor_t *sensor; #ifdef CONFIG_LID_ANGLE const uint16_t lid_angle_sensors = (BIT(CONFIG_LID_ANGLE_SENSOR_BASE)| BIT(CONFIG_LID_ANGLE_SENSOR_LID)); #endif timestamp_t ts_last_int; #ifdef CONFIG_MOTION_FILL_LPC_SENSE_DATA int sample_id = 0; uint8_t *lpc_status; lpc_status = host_get_memmap(EC_MEMMAP_ACC_STATUS); set_present(lpc_status); #endif if (IS_ENABLED(CONFIG_ACCEL_FIFO)) ts_last_int = get_time(); while (1) { ts_begin_task = get_time(); ready_status = 0; for (i = 0; i < motion_sensor_count; ++i) { sensor = &motion_sensors[i]; /* if the sensor is active in the current power state */ if (SENSOR_ACTIVE(sensor)) { if (sensor->state != SENSOR_INITIALIZED) { continue; } ret = motion_sense_process(sensor, &event, &ts_begin_task); if (ret != EC_SUCCESS) continue; ready_status |= BIT(i); } } #ifdef CONFIG_GESTURE_DETECTION check_and_queue_gestures(&event); #endif #ifdef CONFIG_LID_ANGLE /* * Check to see that the sensors required for lid angle * calculation are ready. */ ready_status &= lid_angle_sensors; if (ready_status == lid_angle_sensors) motion_lid_calc(); #endif #ifdef CONFIG_CMD_ACCEL_INFO if (accel_disp) { CPRINTF("[%T event 0x%08x ", event); for (i = 0; i < motion_sensor_count; ++i) { sensor = &motion_sensors[i]; CPRINTF("%s=%-5d, %-5d, %-5d ", sensor->name, sensor->xyz[X], sensor->xyz[Y], sensor->xyz[Z]); } #ifdef CONFIG_LID_ANGLE CPRINTF("a=%-4d", motion_lid_get_angle()); #endif CPRINTF("]\n"); } #endif #ifdef CONFIG_MOTION_FILL_LPC_SENSE_DATA update_sense_data(lpc_status, &sample_id); #endif /* * Ask the host to flush the queue if * - a flush event has been queued. * - the queue is almost full, * - we haven't done it for a while. */ if (IS_ENABLED(CONFIG_ACCEL_FIFO) && (motion_sense_fifo_is_wake_up_needed() || event & (TASK_EVENT_MOTION_ODR_CHANGE | TASK_EVENT_MOTION_FLUSH_PENDING) || (ap_event_interval > 0 && time_after(ts_begin_task.le.lo, ts_last_int.le.lo + ap_event_interval)))) { if ((event & TASK_EVENT_MOTION_FLUSH_PENDING) == 0) { motion_sense_fifo_stage_timestamp( __hw_clock_source_read()); motion_sense_fifo_commit_data(); } ts_last_int = ts_begin_task; /* * Count the number of event the AP is allowed to * collect. */ mutex_lock(&g_sensor_mutex); fifo_queue_count = queue_count(&motion_sense_fifo); mutex_unlock(&g_sensor_mutex); #ifdef CONFIG_MKBP_EVENT /* * Send an event if we know we are in S0 and the kernel * driver is listening, or the AP needs to be waken up. * In the latter case, the driver pulls the event and * will resume listening until it is suspended again. */ if ((fifo_int_enabled && sensor_active == SENSOR_ACTIVE_S0) || wake_up_needed) { mkbp_send_event(EC_MKBP_EVENT_SENSOR_FIFO); wake_up_needed = 0; } #endif /* CONFIG_MKBP_EVENT */ } ts_end_task = get_time(); wait_us = -1; for (i = 0; i < motion_sensor_count; i++) { struct motion_sensor_t *sensor = &motion_sensors[i]; if (!motion_sensor_in_forced_mode(sensor) || sensor->collection_rate == 0) continue; time_diff = time_until(ts_end_task.le.lo, sensor->next_collection); /* We missed our collection time so wake soon */ if (time_diff <= 0) { wait_us = 0; break; } if (wait_us == -1 || wait_us > time_diff) wait_us = time_diff; } if (wait_us >= 0 && wait_us < motion_min_interval) { /* * Guarantee some minimum delay to allow other lower * priority tasks to run. */ wait_us = motion_min_interval; } event = task_wait_event(wait_us); } } /*****************************************************************************/ /* Host commands */ /* Function to map host sensor IDs to motion sensor. */ static struct motion_sensor_t *host_sensor_id_to_real_sensor(int host_id) { struct motion_sensor_t *sensor; if (host_id >= motion_sensor_count) return NULL; sensor = &motion_sensors[host_id]; /* if sensor is powered and initialized, return match */ if (SENSOR_ACTIVE(sensor) && (sensor->state == SENSOR_INITIALIZED)) return sensor; /* If no match then the EC currently doesn't support ID received. */ return NULL; } static struct motion_sensor_t *host_sensor_id_to_motion_sensor(int host_id) { #ifdef CONFIG_GESTURE_HOST_DETECTION if (host_id == MOTION_SENSE_ACTIVITY_SENSOR_ID) /* * Return the info for the first sensor that * support some gestures. */ return host_sensor_id_to_real_sensor( __builtin_ctz(CONFIG_GESTURE_DETECTION_MASK)); #endif return host_sensor_id_to_real_sensor(host_id); } static enum ec_status host_cmd_motion_sense(struct host_cmd_handler_args *args) { const struct ec_params_motion_sense *in = args->params; struct ec_response_motion_sense *out = args->response; struct motion_sensor_t *sensor; int i, ret = EC_RES_INVALID_PARAM, reported; switch (in->cmd) { case MOTIONSENSE_CMD_DUMP: out->dump.module_flags = (*(host_get_memmap(EC_MEMMAP_ACC_STATUS)) & EC_MEMMAP_ACC_STATUS_PRESENCE_BIT) ? MOTIONSENSE_MODULE_FLAG_ACTIVE : 0; out->dump.sensor_count = ALL_MOTION_SENSORS; args->response_size = sizeof(out->dump); reported = MIN(ALL_MOTION_SENSORS, in->dump.max_sensor_count); mutex_lock(&g_sensor_mutex); for (i = 0; i < reported; i++) { out->dump.sensor[i].flags = MOTIONSENSE_SENSOR_FLAG_PRESENT; if (i < motion_sensor_count) { sensor = &motion_sensors[i]; /* casting from int to s16 */ out->dump.sensor[i].data[X] = sensor->xyz[X]; out->dump.sensor[i].data[Y] = sensor->xyz[Y]; out->dump.sensor[i].data[Z] = sensor->xyz[Z]; } else { memset(out->dump.sensor[i].data, 0, 3 * sizeof(int16_t)); } } mutex_unlock(&g_sensor_mutex); args->response_size += reported * sizeof(struct ec_response_motion_sensor_data); break; case MOTIONSENSE_CMD_DATA: sensor = host_sensor_id_to_real_sensor( in->sensor_odr.sensor_num); if (sensor == NULL) return EC_RES_INVALID_PARAM; out->data.flags = 0; mutex_lock(&g_sensor_mutex); out->data.data[X] = sensor->xyz[X]; out->data.data[Y] = sensor->xyz[Y]; out->data.data[Z] = sensor->xyz[Z]; mutex_unlock(&g_sensor_mutex); args->response_size = sizeof(out->data); break; case MOTIONSENSE_CMD_INFO: sensor = host_sensor_id_to_motion_sensor( in->sensor_odr.sensor_num); if (sensor == NULL) return EC_RES_INVALID_PARAM; #ifdef CONFIG_GESTURE_HOST_DETECTION if (in->sensor_odr.sensor_num == MOTION_SENSE_ACTIVITY_SENSOR_ID) out->info.type = MOTIONSENSE_TYPE_ACTIVITY; else #endif out->info.type = sensor->type; out->info.location = sensor->location; out->info.chip = sensor->chip; if (args->version >= 3) { out->info_3.min_frequency = sensor->min_frequency; out->info_3.max_frequency = sensor->max_frequency; out->info_3.fifo_max_event_count = MAX_FIFO_EVENT_COUNT; args->response_size = sizeof(out->info_3); } else { args->response_size = sizeof(out->info); } break; case MOTIONSENSE_CMD_EC_RATE: sensor = host_sensor_id_to_real_sensor( in->sensor_odr.sensor_num); if (sensor == NULL) return EC_RES_INVALID_PARAM; /* * Set new sensor sampling rate when AP is on, if the data arg * has a value. */ if (in->ec_rate.data != EC_MOTION_SENSE_NO_VALUE) { sensor->config[SENSOR_CONFIG_AP].ec_rate = motion_sense_set_ec_rate_from_ap( sensor, in->ec_rate.data * MSEC); /* Bound the new sampling rate. */ motion_sense_set_motion_intervals(); /* Force a collection to purge old events. */ task_set_event(TASK_ID_MOTIONSENSE, TASK_EVENT_MOTION_ODR_CHANGE, 0); } out->ec_rate.ret = motion_sense_ec_rate(sensor) / MSEC; args->response_size = sizeof(out->ec_rate); break; case MOTIONSENSE_CMD_SENSOR_ODR: /* Verify sensor number is valid. */ sensor = host_sensor_id_to_real_sensor( in->sensor_odr.sensor_num); if (sensor == NULL) return EC_RES_INVALID_PARAM; /* Set new data rate if the data arg has a value. */ if (in->sensor_odr.data != EC_MOTION_SENSE_NO_VALUE) { sensor->config[SENSOR_CONFIG_AP].odr = in->sensor_odr.data | (in->sensor_odr.roundup ? ROUND_UP_FLAG : 0); /* * The new ODR may suspend sensor, leaving samples * in the FIFO. Flush it explicitly. */ atomic_or(&odr_event_required, 1 << (sensor - motion_sensors)); task_set_event(TASK_ID_MOTIONSENSE, TASK_EVENT_MOTION_ODR_CHANGE, 0); } out->sensor_odr.ret = sensor->drv->get_data_rate(sensor); args->response_size = sizeof(out->sensor_odr); break; case MOTIONSENSE_CMD_SENSOR_RANGE: /* Verify sensor number is valid. */ sensor = host_sensor_id_to_real_sensor( in->sensor_range.sensor_num); if (sensor == NULL) return EC_RES_INVALID_PARAM; /* Set new range if the data arg has a value. */ if (in->sensor_range.data != EC_MOTION_SENSE_NO_VALUE) { if (!sensor->drv->set_range) return EC_RES_INVALID_COMMAND; if (sensor->drv->set_range(sensor, in->sensor_range.data, in->sensor_range.roundup) != EC_SUCCESS) { return EC_RES_INVALID_PARAM; } } if (!sensor->drv->get_range) return EC_RES_INVALID_COMMAND; out->sensor_range.ret = sensor->drv->get_range(sensor); args->response_size = sizeof(out->sensor_range); break; case MOTIONSENSE_CMD_SENSOR_OFFSET: /* Verify sensor number is valid. */ sensor = host_sensor_id_to_real_sensor( in->sensor_offset.sensor_num); if (sensor == NULL) return EC_RES_INVALID_PARAM; /* Set new range if the data arg has a value. */ if (in->sensor_offset.flags & MOTION_SENSE_SET_OFFSET) { if (!sensor->drv->set_offset) return EC_RES_INVALID_COMMAND; ret = sensor->drv->set_offset(sensor, in->sensor_offset.offset, in->sensor_offset.temp); if (ret != EC_SUCCESS) return ret; } if (!sensor->drv->get_offset) return EC_RES_INVALID_COMMAND; ret = sensor->drv->get_offset(sensor, out->sensor_offset.offset, &out->sensor_offset.temp); if (ret != EC_SUCCESS) return ret; args->response_size = sizeof(out->sensor_offset); break; case MOTIONSENSE_CMD_SENSOR_SCALE: /* Verify sensor number is valid. */ sensor = host_sensor_id_to_real_sensor( in->sensor_scale.sensor_num); if (sensor == NULL) return EC_RES_INVALID_PARAM; /* Set new range if the data arg has a value. */ if (in->sensor_scale.flags & MOTION_SENSE_SET_OFFSET) { if (!sensor->drv->set_scale) return EC_RES_INVALID_COMMAND; ret = sensor->drv->set_scale(sensor, in->sensor_scale.scale, in->sensor_scale.temp); if (ret != EC_SUCCESS) return ret; } if (!sensor->drv->get_scale) return EC_RES_INVALID_COMMAND; ret = sensor->drv->get_scale(sensor, out->sensor_scale.scale, &out->sensor_scale.temp); if (ret != EC_SUCCESS) return ret; args->response_size = sizeof(out->sensor_scale); break; case MOTIONSENSE_CMD_PERFORM_CALIB: /* Verify sensor number is valid. */ sensor = host_sensor_id_to_real_sensor( in->perform_calib.sensor_num); if (sensor == NULL) return EC_RES_INVALID_PARAM; if (!sensor->drv->perform_calib) return EC_RES_INVALID_COMMAND; ret = sensor->drv->perform_calib( sensor, in->perform_calib.enable); if (ret != EC_SUCCESS) return ret; ret = sensor->drv->get_offset(sensor, out->perform_calib.offset, &out->perform_calib.temp); if (ret != EC_SUCCESS) return ret; args->response_size = sizeof(out->perform_calib); break; case MOTIONSENSE_CMD_FIFO_FLUSH: if (!IS_ENABLED(CONFIG_ACCEL_FIFO)) return EC_RES_INVALID_PARAM; sensor = host_sensor_id_to_real_sensor( in->sensor_odr.sensor_num); if (sensor == NULL) return EC_RES_INVALID_PARAM; atomic_add(&sensor->flush_pending, 1); task_set_event(TASK_ID_MOTIONSENSE, TASK_EVENT_MOTION_FLUSH_PENDING, 0); /* pass-through */ case MOTIONSENSE_CMD_FIFO_INFO: if (!IS_ENABLED(CONFIG_ACCEL_FIFO)) { /* * Only support the INFO command, to tell there is no * FIFO. */ memset(&out->fifo_info, 0, sizeof(out->fifo_info)); args->response_size = sizeof(out->fifo_info); break; } motion_sense_get_fifo_info(&out->fifo_info); for (i = 0; i < motion_sensor_count; i++) { out->fifo_info.lost[i] = motion_sensors[i].lost; motion_sensors[i].lost = 0; } motion_sense_fifo_lost = 0; args->response_size = sizeof(out->fifo_info) + sizeof(uint16_t) * motion_sensor_count; break; case MOTIONSENSE_CMD_FIFO_READ: if (!IS_ENABLED(CONFIG_ACCEL_FIFO)) return EC_RES_INVALID_PARAM; mutex_lock(&g_sensor_mutex); reported = MIN((args->response_max - sizeof(out->fifo_read)) / motion_sense_fifo.unit_bytes, MIN(queue_count(&motion_sense_fifo), in->fifo_read.max_data_vector)); reported = queue_remove_units(&motion_sense_fifo, out->fifo_read.data, reported); mutex_unlock(&g_sensor_mutex); out->fifo_read.number_data = reported; args->response_size = sizeof(out->fifo_read) + reported * motion_sense_fifo.unit_bytes; break; case MOTIONSENSE_CMD_FIFO_INT_ENABLE: if (!IS_ENABLED(CONFIG_ACCEL_FIFO)) return EC_RES_INVALID_PARAM; switch (in->fifo_int_enable.enable) { case 0: case 1: fifo_int_enabled = in->fifo_int_enable.enable; /* fallthrough */ case EC_MOTION_SENSE_NO_VALUE: out->fifo_int_enable.ret = fifo_int_enabled; args->response_size = sizeof(out->fifo_int_enable); break; default: return EC_RES_INVALID_PARAM; } break; #ifdef CONFIG_GESTURE_HOST_DETECTION case MOTIONSENSE_CMD_LIST_ACTIVITIES: { uint32_t enabled, disabled, mask, i; out->list_activities.enabled = 0; out->list_activities.disabled = 0; ret = EC_RES_SUCCESS; mask = CONFIG_GESTURE_DETECTION_MASK; while (mask && ret == EC_RES_SUCCESS) { i = get_next_bit(&mask); sensor = &motion_sensors[i]; ret = sensor->drv->list_activities(sensor, &enabled, &disabled); if (ret == EC_RES_SUCCESS) { out->list_activities.enabled |= enabled; out->list_activities.disabled |= disabled; } } if (ret != EC_RES_SUCCESS) return ret; args->response_size = sizeof(out->list_activities); break; } case MOTIONSENSE_CMD_SET_ACTIVITY: { uint32_t enabled, disabled, mask, i; mask = CONFIG_GESTURE_DETECTION_MASK; ret = EC_RES_SUCCESS; while (mask && ret == EC_RES_SUCCESS) { i = get_next_bit(&mask); sensor = &motion_sensors[i]; sensor->drv->list_activities(sensor, &enabled, &disabled); if ((1 << in->set_activity.activity) & (enabled | disabled)) ret = sensor->drv->manage_activity(sensor, in->set_activity.activity, in->set_activity.enable, &in->set_activity); } if (ret != EC_RES_SUCCESS) return ret; args->response_size = 0; break; } #endif /* defined(CONFIG_GESTURE_HOST_DETECTION) */ #ifdef CONFIG_ACCEL_SPOOF_MODE case MOTIONSENSE_CMD_SPOOF: { sensor = host_sensor_id_to_real_sensor(in->spoof.sensor_id); if (sensor == NULL) return EC_RES_INVALID_PARAM; switch (in->spoof.spoof_enable) { case MOTIONSENSE_SPOOF_MODE_DISABLE: /* Disable spoof mode. */ sensor->flags &= ~MOTIONSENSE_FLAG_IN_SPOOF_MODE; break; case MOTIONSENSE_SPOOF_MODE_CUSTOM: /* * Enable spoofing, but use provided component values. */ sensor->spoof_xyz[X] = (int)in->spoof.components[X]; sensor->spoof_xyz[Y] = (int)in->spoof.components[Y]; sensor->spoof_xyz[Z] = (int)in->spoof.components[Z]; sensor->flags |= MOTIONSENSE_FLAG_IN_SPOOF_MODE; break; case MOTIONSENSE_SPOOF_MODE_LOCK_CURRENT: /* * Enable spoofing, but lock to current sensor * values. raw_xyz already has the values we want. */ sensor->spoof_xyz[X] = sensor->raw_xyz[X]; sensor->spoof_xyz[Y] = sensor->raw_xyz[Y]; sensor->spoof_xyz[Z] = sensor->raw_xyz[Z]; sensor->flags |= MOTIONSENSE_FLAG_IN_SPOOF_MODE; break; case MOTIONSENSE_SPOOF_MODE_QUERY: /* Querying the spoof status of the sensor. */ out->spoof.ret = !!(sensor->flags & MOTIONSENSE_FLAG_IN_SPOOF_MODE); args->response_size = sizeof(out->spoof); break; default: return EC_RES_INVALID_PARAM; } /* * Only print the status when spoofing is enabled or disabled. */ if (in->spoof.spoof_enable != MOTIONSENSE_SPOOF_MODE_QUERY) print_spoof_mode_status((int)(sensor - motion_sensors)); break; } #endif /* defined(CONFIG_ACCEL_SPOOF_MODE) */ default: /* Call other users of the motion task */ #ifdef CONFIG_LID_ANGLE if (ret == EC_RES_INVALID_PARAM) ret = host_cmd_motion_lid(args); #endif return ret; } return EC_RES_SUCCESS; } DECLARE_HOST_COMMAND(EC_CMD_MOTION_SENSE_CMD, host_cmd_motion_sense, EC_VER_MASK(1) | EC_VER_MASK(2) | EC_VER_MASK(3)); /*****************************************************************************/ /* Console commands */ #ifdef CONFIG_CMD_ACCELS static int command_accelrange(int argc, char **argv) { char *e; int id, data, round = 1; struct motion_sensor_t *sensor; if (argc < 2 || argc > 4) return EC_ERROR_PARAM_COUNT; /* First argument is sensor id. */ id = strtoi(argv[1], &e, 0); if (*e || id < 0 || id >= motion_sensor_count) return EC_ERROR_PARAM1; sensor = &motion_sensors[id]; if (argc >= 3) { /* Second argument is data to write. */ data = strtoi(argv[2], &e, 0); if (*e) return EC_ERROR_PARAM2; if (argc == 4) { /* Third argument is rounding flag. */ round = strtoi(argv[3], &e, 0); if (*e) return EC_ERROR_PARAM3; } /* * Write new range, if it returns invalid arg, then return * a parameter error. */ if (sensor->drv->set_range(sensor, data, round) == EC_ERROR_INVAL) return EC_ERROR_PARAM2; } else { ccprintf("Range for sensor %d: %d\n", id, sensor->drv->get_range(sensor)); } return EC_SUCCESS; } DECLARE_CONSOLE_COMMAND(accelrange, command_accelrange, "id [data [roundup]]", "Read or write accelerometer range"); static int command_accelresolution(int argc, char **argv) { char *e; int id, data, round = 1; struct motion_sensor_t *sensor; if (argc < 2 || argc > 4) return EC_ERROR_PARAM_COUNT; /* First argument is sensor id. */ id = strtoi(argv[1], &e, 0); if (*e || id < 0 || id >= motion_sensor_count) return EC_ERROR_PARAM1; sensor = &motion_sensors[id]; if (argc >= 3) { /* Second argument is data to write. */ data = strtoi(argv[2], &e, 0); if (*e) return EC_ERROR_PARAM2; if (argc == 4) { /* Third argument is rounding flag. */ round = strtoi(argv[3], &e, 0); if (*e) return EC_ERROR_PARAM3; } /* * Write new resolution, if it returns invalid arg, then * return a parameter error. */ if (sensor->drv->set_resolution && sensor->drv->set_resolution(sensor, data, round) == EC_ERROR_INVAL) return EC_ERROR_PARAM2; } else { ccprintf("Resolution for sensor %d: %d\n", id, sensor->drv->get_resolution(sensor)); } return EC_SUCCESS; } DECLARE_CONSOLE_COMMAND(accelres, command_accelresolution, "id [data [roundup]]", "Read or write accelerometer resolution"); static int command_accel_data_rate(int argc, char **argv) { char *e; int id, data, round = 1; struct motion_sensor_t *sensor; enum sensor_config config_id; if (argc < 2 || argc > 4) return EC_ERROR_PARAM_COUNT; /* First argument is sensor id. */ id = strtoi(argv[1], &e, 0); if (*e || id < 0 || id >= motion_sensor_count) return EC_ERROR_PARAM1; sensor = &motion_sensors[id]; if (argc >= 3) { /* Second argument is data to write. */ data = strtoi(argv[2], &e, 0); if (*e) return EC_ERROR_PARAM2; if (argc == 4) { /* Third argument is rounding flag. */ round = strtoi(argv[3], &e, 0); if (*e) return EC_ERROR_PARAM3; } /* * Take ownership of the sensor and * Write new data rate, if it returns invalid arg, then * return a parameter error. */ config_id = motion_sense_get_ec_config(); sensor->config[SENSOR_CONFIG_AP].odr = 0; sensor->config[config_id].odr = data | (round ? ROUND_UP_FLAG : 0); task_set_event(TASK_ID_MOTIONSENSE, TASK_EVENT_MOTION_ODR_CHANGE, 0); } else { ccprintf("Data rate for sensor %d: %d\n", id, sensor->drv->get_data_rate(sensor)); ccprintf("EC rate for sensor %d: %d\n", id, motion_sense_ec_rate(sensor)); ccprintf("Current Interrupt rate: %d\n", ap_event_interval); } return EC_SUCCESS; } DECLARE_CONSOLE_COMMAND(accelrate, command_accel_data_rate, "id [data [roundup]]", "Read or write accelerometer ODR"); static int command_accel_read_xyz(int argc, char **argv) { char *e; int id, n = 1, ret; struct motion_sensor_t *sensor; intv3_t v; if (argc < 2) return EC_ERROR_PARAM_COUNT; /* First argument is sensor id. */ id = strtoi(argv[1], &e, 0); if (*e || id < 0 || id >= motion_sensor_count) return EC_ERROR_PARAM1; if (argc >= 3) n = strtoi(argv[2], &e, 0); sensor = &motion_sensors[id]; while ((n == -1) || (n-- > 0)) { ret = sensor->drv->read(sensor, v); if (ret == 0) ccprintf("Current data %d: %-5d %-5d %-5d\n", id, v[X], v[Y], v[Z]); else ccprintf("vector not ready\n"); ccprintf("Last calib. data %d: %-5d %-5d %-5d\n", id, sensor->xyz[X], sensor->xyz[Y], sensor->xyz[Z]); task_wait_event(motion_min_interval); } return EC_SUCCESS; } DECLARE_CONSOLE_COMMAND(accelread, command_accel_read_xyz, "id [n]", "Read sensor x/y/z"); static int command_accel_init(int argc, char **argv) { char *e; int id, ret; struct motion_sensor_t *sensor; if (argc < 2) return EC_ERROR_PARAM_COUNT; /* First argument is sensor id. */ id = strtoi(argv[1], &e, 0); if (*e || id < 0 || id >= motion_sensor_count) return EC_ERROR_PARAM1; sensor = &motion_sensors[id]; ret = motion_sense_init(sensor); ccprintf("%s: state %d - %d\n", sensor->name, sensor->state, ret); return EC_SUCCESS; } DECLARE_CONSOLE_COMMAND(accelinit, command_accel_init, "id", "Init sensor"); #ifdef CONFIG_CMD_ACCEL_INFO static int command_display_accel_info(int argc, char **argv) { int val, i, j; if (argc > 3) return EC_ERROR_PARAM_COUNT; ccprintf("Motion sensors count = %d\n", motion_sensor_count); /* Print motion sensor info. */ for (i = 0; i < motion_sensor_count; i++) { ccprintf("\nsensor %d name: %s\n", i, motion_sensors[i].name); ccprintf("active mask: %d\n", motion_sensors[i].active_mask); ccprintf("chip: %d\n", motion_sensors[i].chip); ccprintf("type: %d\n", motion_sensors[i].type); ccprintf("location: %d\n", motion_sensors[i].location); ccprintf("port: %d\n", motion_sensors[i].port); ccprintf("addr: %d\n", I2C_GET_ADDR(motion_sensors[i] .i2c_spi_addr_flags)); ccprintf("range: %d\n", motion_sensors[i].default_range); ccprintf("min_freq: %d\n", motion_sensors[i].min_frequency); ccprintf("max_freq: %d\n", motion_sensors[i].max_frequency); ccprintf("config:\n"); for (j = 0; j < SENSOR_CONFIG_MAX; j++) { ccprintf("%d - odr: %umHz, ec_rate: %uus\n", j, motion_sensors[i].config[j].odr & ~ROUND_UP_FLAG, motion_sensors[i].config[j].ec_rate); } } /* First argument is on/off whether to display accel data. */ if (argc > 1) { if (!parse_bool(argv[1], &val)) return EC_ERROR_PARAM1; accel_disp = val; } return EC_SUCCESS; } DECLARE_CONSOLE_COMMAND(accelinfo, command_display_accel_info, "on/off [interval]", "Print motion sensor info, lid angle calculations" " and set calculation frequency."); #endif /* CONFIG_CMD_ACCEL_INFO */ #ifdef CONFIG_CMD_ACCEL_FIFO static int motion_sense_read_fifo(int argc, char **argv) { int count, i; struct ec_response_motion_sensor_data v; if (argc < 1) return EC_ERROR_PARAM_COUNT; /* Limit the amount of data to avoid saturating the UART buffer */ count = MIN(queue_count(&motion_sense_fifo), 16); for (i = 0; i < count; i++) { queue_peek_units(&motion_sense_fifo, &v, i, 1); if (v.flags & (MOTIONSENSE_SENSOR_FLAG_TIMESTAMP | MOTIONSENSE_SENSOR_FLAG_FLUSH)) { uint64_t timestamp; memcpy(×tamp, v.data, sizeof(v.data)); ccprintf("Timestamp: 0x%016lx%s\n", timestamp, (v.flags & MOTIONSENSE_SENSOR_FLAG_FLUSH ? " - Flush" : "")); } else { ccprintf("%d %d: %-5d %-5d %-5d\n", i, v.sensor_num, v.data[X], v.data[Y], v.data[Z]); } } return EC_SUCCESS; } DECLARE_CONSOLE_COMMAND(fiforead, motion_sense_read_fifo, "id", "Read Fifo sensor"); #endif /* defined(CONFIG_CMD_ACCEL_FIFO) */ #endif /* CONFIG_CMD_ACCELS */ #ifdef CONFIG_ACCEL_SPOOF_MODE static void print_spoof_mode_status(int id) { CPRINTS("Sensor %d spoof mode is %s. <%d, %d, %d>", id, (motion_sensors[id].flags & MOTIONSENSE_FLAG_IN_SPOOF_MODE) ? "enabled" : "disabled", motion_sensors[id].spoof_xyz[X], motion_sensors[id].spoof_xyz[Y], motion_sensors[id].spoof_xyz[Z]); } #ifdef CONFIG_CMD_ACCELSPOOF static int command_accelspoof(int argc, char **argv) { char *e; int id, enable, i; struct motion_sensor_t *s; /* There must be at least 1 parameter, the sensor id. */ if (argc < 2) return EC_ERROR_PARAM_COUNT; /* First argument is sensor id. */ id = strtoi(argv[1], &e, 0); if (id >= motion_sensor_count || id < 0) return EC_ERROR_PARAM1; s = &motion_sensors[id]; /* Print the sensor's current spoof status. */ if (argc == 2) print_spoof_mode_status(id); /* Enable/Disable spoof mode. */ if (argc >= 3) { if (!parse_bool(argv[2], &enable)) return EC_ERROR_PARAM2; if (enable) { /* * If no components are provided, we'll just use the * current values as the spoofed values. But if the * components are provided, use the provided ones as the * spoofed ones. */ if (argc == 6) { for (i = 0; i < 3; i++) s->spoof_xyz[i] = strtoi(argv[3 + i], &e, 0); } else if (argc == 3) { for (i = X; i <= Z; i++) s->spoof_xyz[i] = s->raw_xyz[i]; } else { /* It's either all or nothing. */ return EC_ERROR_PARAM_COUNT; } } if (enable) s->flags |= MOTIONSENSE_FLAG_IN_SPOOF_MODE; else s->flags &= ~MOTIONSENSE_FLAG_IN_SPOOF_MODE; print_spoof_mode_status(id); } return EC_SUCCESS; } DECLARE_CONSOLE_COMMAND(accelspoof, command_accelspoof, "id [on/off] [X] [Y] [Z]", "Enable/Disable spoofing of sensor readings."); #endif /* defined(CONIFG_CMD_ACCELSPOOF) */ #endif /* defined(CONFIG_ACCEL_SPOOF_MODE) */