/* Copyright (C) 2009 The Android Open Source Project ** ** This software is licensed under the terms of the GNU General Public ** License version 2, as published by the Free Software Foundation, and ** may be copied, distributed, and modified under those terms. ** ** This program is distributed in the hope that it will be useful, ** but WITHOUT ANY WARRANTY; without even the implied warranty of ** MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ** GNU General Public License for more details. */ #include "android/hw-sensors.h" #include "android/utils/debug.h" #include "android/utils/misc.h" #include "android/hw-qemud.h" #include "android/globals.h" #include "qemu-char.h" #include "qemu-timer.h" #define D(...) VERBOSE_PRINT(sensors,__VA_ARGS__) /* define T_ACTIVE to 1 to debug transport communications */ #define T_ACTIVE 0 #if T_ACTIVE #define T(...) VERBOSE_PRINT(sensors,__VA_ARGS__) #else #define T(...) ((void)0) #endif /* this code supports emulated sensor hardware * * Note that currently, only the accelerometer is really emulated, and only * for the purpose of allowing auto-rotating the screen in keyboard-less * configurations. * * */ static const struct { const char* name; int id; } _sSensors[MAX_SENSORS] = { #define SENSOR_(x,y) { y, ANDROID_SENSOR_##x }, SENSORS_LIST #undef SENSOR_ }; static int _sensorIdFromName( const char* name ) { int nn; for (nn = 0; nn < MAX_SENSORS; nn++) if (!strcmp(_sSensors[nn].name,name)) return _sSensors[nn].id; return -1; } typedef struct { float x, y, z; } Acceleration; typedef struct { float x, y, z; } MagneticField; typedef struct { float azimuth; float pitch; float roll; } Orientation; typedef struct { float celsius; } Temperature; typedef struct { char enabled; union { Acceleration acceleration; MagneticField magnetic; Orientation orientation; Temperature temperature; } u; } Sensor; /* * - when the qemu-specific sensors HAL module starts, it sends * "list-sensors" * * - this code replies with a string containing an integer corresponding * to a bitmap of available hardware sensors in the current AVD * configuration (e.g. "1" a.k.a (1 << ANDROID_SENSOR_ACCELERATION)) * * - the HAL module sends "set::" to enable or disable * the report of a given sensor state. must be the name of * a given sensor (e.g. "accelerometer"), and must be either * "1" (to enable) or "0" (to disable). * * - Once at least one sensor is "enabled", this code should periodically * send information about the corresponding enabled sensors. The default * period is 200ms. * * - the HAL module sends "set-delay:", where is an integer * corresponding to a time delay in milli-seconds. This corresponds to * a new interval between sensor events sent by this code to the HAL * module. * * - the HAL module can also send a "wake" command. This code should simply * send the "wake" back to the module. This is used internally to wake a * blocking read that happens in a different thread. This ping-pong makes * the code in the HAL module very simple. * * - each timer tick, this code sends sensor reports in the following * format (each line corresponds to a different line sent to the module): * * acceleration::: * magnetic-field::: * orientation::: * temperature: * sync: * * Where each line before the sync: is optional and will only * appear if the corresponding sensor has been enabled by the HAL module. * * Note that is the VM time in micro-seconds when the report * was "taken" by this code. This is adjusted by the HAL module to * emulated system time (using the first sync: to compute an adjustment * offset). */ #define HEADER_SIZE 4 #define BUFFER_SIZE 512 typedef struct { QemudService* service; int32_t delay_ms; uint32_t enabledMask; QEMUTimer* timer; Sensor sensors[MAX_SENSORS]; } HwSensors; /* forward */ static void hw_sensors_receive( HwSensors* h, uint8_t* query, int querylen ); static void hw_sensors_timer_tick(void* opaque); /* Qemud service management */ static void _hw_sensors_qemud_client_recv( void* opaque, uint8_t* msg, int msglen ) { hw_sensors_receive(opaque, msg, msglen); } static QemudClient* _hw_sensors_service_connect( void* opaque, QemudService* service, int channel ) { HwSensors* sensors = opaque; QemudClient* client = qemud_client_new(service, channel, sensors, _hw_sensors_qemud_client_recv, NULL); qemud_client_set_framing(client, 1); return client; } /* change the value of the emulated acceleration vector */ static void hw_sensors_set_acceleration( HwSensors* h, float x, float y, float z ) { Sensor* s = &h->sensors[ANDROID_SENSOR_ACCELERATION]; s->u.acceleration.x = x; s->u.acceleration.y = y; s->u.acceleration.z = z; } #if 0 /* not used yet */ /* change the value of the emulated magnetic vector */ static void hw_sensors_set_magnetic_field( HwSensors* h, float x, float y, float z ) { Sensor* s = &h->sensors[ANDROID_SENSOR_MAGNETIC_FIELD]; s->u.magnetic.x = x; s->u.magnetic.y = y; s->u.magnetic.z = z; } /* change the values of the emulated orientation */ static void hw_sensors_set_orientation( HwSensors* h, float azimuth, float pitch, float roll ) { Sensor* s = &h->sensors[ANDROID_SENSOR_MAGNETIC_FIELD]; s->u.orientation.azimuth = azimuth; s->u.orientation.pitch = pitch; s->u.orientation.roll = roll; } /* change the emulated temperature */ static void hw_sensors_set_temperature( HwSensors* h, float celsius ) { Sensor* s = &h->sensors[ANDROID_SENSOR_MAGNETIC_FIELD]; s->u.temperature.celsius = celsius; } #endif /* change the coarse orientation (landscape/portrait) of the emulated device */ static void hw_sensors_set_coarse_orientation( HwSensors* h, AndroidCoarseOrientation orient ) { /* The Android framework computes the orientation by looking at * the accelerometer sensor (*not* the orientation sensor !) * * That's because the gravity is a constant 9.81 vector that * can be determined quite easily. * * Also, for some reason, the framework code considers that the phone should * be inclined by 30 degrees along the phone's X axis to be considered * in its ideal "vertical" position * * If the phone is completely vertical, rotating it will not do anything ! */ const double g = 9.81; const double cos_30 = 0.866025403784; const double sin_30 = 0.5; switch (orient) { case ANDROID_COARSE_PORTRAIT: hw_sensors_set_acceleration( h, 0., g*cos_30, g*sin_30 ); break; case ANDROID_COARSE_LANDSCAPE: hw_sensors_set_acceleration( h, g*cos_30, 0., g*sin_30 ); break; default: ; } } /* initialize the sensors state */ static void hw_sensors_init( HwSensors* h ) { h->service = qemud_service_register("sensors", 1, h, _hw_sensors_service_connect ); h->enabledMask = 0; h->delay_ms = 1000; h->timer = qemu_new_timer(vm_clock, hw_sensors_timer_tick, h); hw_sensors_set_coarse_orientation(h, ANDROID_COARSE_PORTRAIT); } /* send a one-line message to the HAL module through a qemud channel */ static void hw_sensors_send( HwSensors* hw, const uint8_t* msg, int msglen ) { D("%s: '%s'", __FUNCTION__, quote_bytes((const void*)msg, msglen)); qemud_service_broadcast(hw->service, msg, msglen); } /* this function is called periodically to send sensor reports * to the HAL module, and re-arm the timer if necessary */ static void hw_sensors_timer_tick( void* opaque ) { HwSensors* h = opaque; int64_t delay = h->delay_ms; int64_t now_ns; uint32_t mask = h->enabledMask; Sensor* sensor; char buffer[128]; sensor = &h->sensors[ANDROID_SENSOR_ACCELERATION]; if (sensor->enabled) { snprintf(buffer, sizeof buffer, "acceleration:%g:%g:%g", sensor->u.acceleration.x, sensor->u.acceleration.y, sensor->u.acceleration.z); hw_sensors_send(h, (uint8_t*)buffer, strlen(buffer)); } sensor = &h->sensors[ANDROID_SENSOR_MAGNETIC_FIELD]; if (sensor->enabled) { snprintf(buffer, sizeof buffer, "magnetic-field:%g:%g:%g", sensor->u.magnetic.x, sensor->u.magnetic.y, sensor->u.magnetic.z); hw_sensors_send(h, (uint8_t*)buffer, strlen(buffer)); } sensor = &h->sensors[ANDROID_SENSOR_ORIENTATION]; if (sensor->enabled) { snprintf(buffer, sizeof buffer, "orientation:%g:%g:%g", sensor->u.orientation.azimuth, sensor->u.orientation.pitch, sensor->u.orientation.roll); hw_sensors_send(h, (uint8_t*)buffer, strlen(buffer)); } sensor = &h->sensors[ANDROID_SENSOR_TEMPERATURE]; if (sensor->enabled) { snprintf(buffer, sizeof buffer, "temperature:%g", sensor->u.temperature.celsius); hw_sensors_send(h, (uint8_t*)buffer, strlen(buffer)); } now_ns = qemu_get_clock(vm_clock); snprintf(buffer, sizeof buffer, "sync:%lld", now_ns/1000); hw_sensors_send(h, (uint8_t*)buffer, strlen(buffer)); /* rearm timer, use a minimum delay of 20 ms, just to * be safe. */ if (mask == 0) return; if (delay < 20) delay = 20; delay *= 1000000LL; /* convert to nanoseconds */ qemu_mod_timer(h->timer, now_ns + delay); } /* handle incoming messages from the HAL module */ static void hw_sensors_receive( HwSensors* hw, uint8_t* msg, int msglen ) { D("%s: '%.*s'", __FUNCTION__, msglen, msg); /* "list-sensors" is used to get an integer bit map of * available emulated sensors. We compute the mask from the * current hardware configuration. */ if (msglen == 12 && !memcmp(msg, "list-sensors", 12)) { char buff[12]; int mask = 0; if (android_hw->hw_accelerometer) mask |= (1 << ANDROID_SENSOR_ACCELERATION); /* XXX: TODO: Add other tests when we add the corresponding * properties to hardware-properties.ini et al. */ snprintf(buff, sizeof buff, "%d", mask); hw_sensors_send(hw, (const uint8_t*)buff, strlen(buff)); return; } /* "wake" is a special message that must be sent back through * the channel. It is used to exit a blocking read. */ if (msglen == 4 && !memcmp(msg, "wake", 4)) { hw_sensors_send(hw, (const uint8_t*)"wake", 4); return; } /* "set-delay:" is used to set the delay in milliseconds * between sensor events */ if (msglen > 10 && !memcmp(msg, "set-delay:", 10)) { hw->delay_ms = atoi((const char*)msg+10); if (hw->enabledMask != 0) hw_sensors_timer_tick(hw); return; } /* "set::" is used to enable/disable a given * sensor. must be 0 or 1 */ if (msglen > 4 && !memcmp(msg, "set:", 4)) { char* q; int id, enabled, oldEnabledMask = hw->enabledMask; msg += 4; q = strchr((char*)msg, ':'); if (q == NULL) { /* should not happen */ D("%s: ignore bad 'set' command", __FUNCTION__); return; } *q++ = 0; id = _sensorIdFromName((const char*)msg); if (id < 0) { D("%s: ignore unknown sensor name '%s'", __FUNCTION__, msg); return; } enabled = (q[0] == '1'); hw->sensors[id].enabled = (char) enabled; if (enabled) hw->enabledMask |= (1 << id); else hw->enabledMask &= ~(1 << id); D("%s: %s %s sensor", __FUNCTION__, hw->sensors[id].enabled ? "enabling" : "disabling", msg); if (oldEnabledMask == 0 && enabled) { /* we enabled our first sensor, start event reporting */ D("%s: starting event reporting (mask=%04x)", __FUNCTION__, hw->enabledMask); } else if (hw->enabledMask == 0 && !enabled) { /* we disabled our last sensor, stop event reporting */ D("%s: stopping event reporting", __FUNCTION__); } hw_sensors_timer_tick(hw); return; } D("%s: ignoring unknown query", __FUNCTION__); } static HwSensors _sensorsState[1]; void android_hw_sensors_init( void ) { HwSensors* hw = _sensorsState; if (hw->service == NULL) { hw_sensors_init(hw); D("%s: sensors qemud service initialized", __FUNCTION__); } } /* change the coarse orientation value */ extern void android_sensors_set_coarse_orientation( AndroidCoarseOrientation orient ) { android_hw_sensors_init(); hw_sensors_set_coarse_orientation(_sensorsState, orient); }