/* * Copyright (c) 2006-2021, RT-Thread Development Team * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2012-06-02 Bernard the first version * 2018-08-02 Tanek split run and sleep modes, support custom mode * 2019-04-28 Zero-Free improve PM mode and device ops interface * 2020-11-23 zhangsz update pm mode select * 2020-11-27 zhangsz update pm 2.0 */ #include #include #include #ifdef RT_USING_PM static struct rt_pm _pm; /* default mode : system power on */ static rt_uint8_t _pm_default_sleep = RT_PM_DEFAULT_SLEEP_MODE; /* default deepsleep mode : tick-less mode */ static rt_uint8_t _pm_default_deepsleep = RT_PM_DEFAULT_DEEPSLEEP_MODE; static struct rt_pm_notify _pm_notify; static rt_uint8_t _pm_init_flag = 0; #define RT_PM_TICKLESS_THRESH (2) RT_WEAK rt_uint32_t rt_pm_enter_critical(rt_uint8_t sleep_mode) { return rt_hw_interrupt_disable(); } RT_WEAK void rt_pm_exit_critical(rt_uint32_t ctx, rt_uint8_t sleep_mode) { rt_hw_interrupt_enable(ctx); } /** * This function will suspend all registered devices */ static int _pm_device_suspend(rt_uint8_t mode) { int index, ret = RT_EOK; for (index = 0; index < _pm.device_pm_number; index++) { if (_pm.device_pm[index].ops->suspend != RT_NULL) { ret = _pm.device_pm[index].ops->suspend(_pm.device_pm[index].device, mode); if(ret != RT_EOK) break; } } return ret; } /** * This function will resume all registered devices */ static void _pm_device_resume(rt_uint8_t mode) { int index; for (index = 0; index < _pm.device_pm_number; index++) { if (_pm.device_pm[index].ops->resume != RT_NULL) { _pm.device_pm[index].ops->resume(_pm.device_pm[index].device, mode); } } } /** * This function will update the frequency of all registered devices */ static void _pm_device_frequency_change(rt_uint8_t mode) { rt_uint32_t index; /* make the frequency change */ for (index = 0; index < _pm.device_pm_number; index ++) { if (_pm.device_pm[index].ops->frequency_change != RT_NULL) _pm.device_pm[index].ops->frequency_change(_pm.device_pm[index].device, mode); } } /** * This function will update the system clock frequency when idle */ static void _pm_frequency_scaling(struct rt_pm *pm) { rt_base_t level; if (pm->flags & RT_PM_FREQUENCY_PENDING) { level = rt_hw_interrupt_disable(); /* change system runing mode */ pm->ops->run(pm, pm->run_mode); /* changer device frequency */ _pm_device_frequency_change(pm->run_mode); pm->flags &= ~RT_PM_FREQUENCY_PENDING; rt_hw_interrupt_enable(level); } } /** * This function selects the sleep mode according to the rt_pm_request/rt_pm_release count. */ static rt_uint8_t _pm_select_sleep_mode(struct rt_pm *pm) { int index; rt_uint8_t mode; mode = _pm_default_deepsleep; for (index = PM_SLEEP_MODE_NONE; index < PM_SLEEP_MODE_MAX; index ++) { if (pm->modes[index]) { mode = index; break; } } pm->sleep_mode = mode; return mode; } /** * pm module request delay sleep. */ void rt_pm_module_delay_sleep(rt_uint8_t module_id, rt_tick_t timeout) { rt_base_t level; struct rt_pm *pm; if (_pm_init_flag == 0) return; if (module_id > (PM_MODULE_MAX_ID - 1)) return; level = rt_hw_interrupt_disable(); pm = &_pm; pm->module_status[module_id].busy_flag = RT_TRUE; pm->module_status[module_id].timeout = timeout; pm->module_status[module_id].start_time = rt_tick_get(); rt_hw_interrupt_enable(level); } /** * This function check if all modules in idle status. */ static rt_bool_t _pm_device_check_idle(void) { struct rt_pm *pm; if (_pm_init_flag == 0) return RT_TRUE; pm = &_pm; for (int i = 0; i < PM_MODULE_MAX_ID; i++) { if (pm->module_status[i].busy_flag == RT_TRUE) { if (rt_tick_get() - pm->module_status[i].start_time > pm->module_status[i].timeout) { pm->module_status[i].busy_flag = RT_FALSE; pm->module_status[i].timeout = 0x00; } } if (pm->module_status[i].busy_flag == RT_TRUE) { return RT_FALSE; } } return RT_TRUE; } /** * This function changes the power sleep mode base on the result of selection */ static void _pm_change_sleep_mode(struct rt_pm *pm) { rt_tick_t timeout_tick, delta_tick; rt_base_t level; int ret = RT_EOK; level = rt_pm_enter_critical(pm->sleep_mode); /* module busy request */ if (_pm_device_check_idle() == RT_FALSE) { pm->ops->sleep(pm, PM_SLEEP_MODE_NONE); rt_pm_exit_critical(level, pm->sleep_mode); return; } if (_pm.sleep_mode == PM_SLEEP_MODE_NONE) { pm->ops->sleep(pm, PM_SLEEP_MODE_NONE); rt_pm_exit_critical(level, pm->sleep_mode); } else { /* Notify app will enter sleep mode */ if (_pm_notify.notify) _pm_notify.notify(RT_PM_ENTER_SLEEP, pm->sleep_mode, _pm_notify.data); /* Suspend all peripheral device */ ret = _pm_device_suspend(pm->sleep_mode); if (ret != RT_EOK) { _pm_device_resume(pm->sleep_mode); if (_pm_notify.notify) _pm_notify.notify(RT_PM_EXIT_SLEEP, pm->sleep_mode, _pm_notify.data); rt_pm_exit_critical(level, pm->sleep_mode); return; } /* Tickless*/ if (pm->timer_mask & (0x01 << pm->sleep_mode)) { timeout_tick = rt_timer_next_timeout_tick(); if (timeout_tick == RT_TICK_MAX) { if (pm->ops->timer_start) { pm->ops->timer_start(pm, RT_TICK_MAX); } } else { timeout_tick = timeout_tick - rt_tick_get(); if (timeout_tick < RT_PM_TICKLESS_THRESH) { pm->sleep_mode = PM_SLEEP_MODE_IDLE; } else { pm->ops->timer_start(pm, timeout_tick); } } } /* enter lower power state */ pm->ops->sleep(pm, pm->sleep_mode); /* wake up from lower power state*/ if (pm->timer_mask & (0x01 << pm->sleep_mode)) { delta_tick = pm->ops->timer_get_tick(pm); pm->ops->timer_stop(pm); if (delta_tick) { rt_tick_set(rt_tick_get() + delta_tick); } } /* resume all device */ _pm_device_resume(pm->sleep_mode); if (_pm_notify.notify) _pm_notify.notify(RT_PM_EXIT_SLEEP, pm->sleep_mode, _pm_notify.data); rt_pm_exit_critical(level, pm->sleep_mode); if (pm->timer_mask & (0x01 << pm->sleep_mode)) { if (delta_tick) { rt_timer_check(); } } } } /** * This function will enter corresponding power mode. */ void rt_system_power_manager(void) { if (_pm_init_flag == 0) return; /* CPU frequency scaling according to the runing mode settings */ _pm_frequency_scaling(&_pm); /* Low Power Mode Processing */ _pm_change_sleep_mode(&_pm); } /** * Upper application or device driver requests the system * stall in corresponding power mode. * * @param parameter the parameter of run mode or sleep mode */ void rt_pm_request(rt_uint8_t mode) { rt_base_t level; struct rt_pm *pm; if (_pm_init_flag == 0) return; if (mode > (PM_SLEEP_MODE_MAX - 1)) return; level = rt_hw_interrupt_disable(); pm = &_pm; if (pm->modes[mode] < 255) pm->modes[mode] ++; _pm_select_sleep_mode(pm); rt_hw_interrupt_enable(level); } /** * Upper application or device driver releases the stall * of corresponding power mode. * * @param parameter the parameter of run mode or sleep mode * */ void rt_pm_release(rt_uint8_t mode) { rt_ubase_t level; struct rt_pm *pm; if (_pm_init_flag == 0) return; if (mode > (PM_SLEEP_MODE_MAX - 1)) return; level = rt_hw_interrupt_disable(); pm = &_pm; if (pm->modes[mode] > 0) pm->modes[mode] --; _pm_select_sleep_mode(pm); rt_hw_interrupt_enable(level); } /** * Upper application or device driver releases all the stall * of corresponding power mode. * * @param parameter the parameter of run mode or sleep mode * */ void rt_pm_release_all(rt_uint8_t mode) { rt_ubase_t level; struct rt_pm *pm; if (_pm_init_flag == 0) return; if (mode > (PM_SLEEP_MODE_MAX - 1)) return; level = rt_hw_interrupt_disable(); pm = &_pm; pm->modes[mode] = 0; _pm_select_sleep_mode(pm); rt_hw_interrupt_enable(level); } /** * Upper application or device driver requests the system * stall in corresponding power mode. * * @param module_id the application or device module id * @param mode the system power sleep mode */ void rt_pm_module_request(uint8_t module_id, rt_uint8_t mode) { rt_base_t level; struct rt_pm *pm; if (_pm_init_flag == 0) return; if (mode > (PM_SLEEP_MODE_MAX - 1)) return; if (module_id > (PM_MODULE_MAX_ID - 1)) return; level = rt_hw_interrupt_disable(); pm = &_pm; pm->module_status[module_id].req_status = 0x01; if (pm->modes[mode] < 255) pm->modes[mode] ++; _pm_select_sleep_mode(pm); rt_hw_interrupt_enable(level); } /** * Upper application or device driver releases the stall * of corresponding power mode. * * @param module_id the application or device module id * @param mode the system power sleep mode * */ void rt_pm_module_release(uint8_t module_id, rt_uint8_t mode) { rt_ubase_t level; struct rt_pm *pm; if (_pm_init_flag == 0) return; if (mode > (PM_SLEEP_MODE_MAX - 1)) return; if (module_id > (PM_MODULE_MAX_ID - 1)) return; level = rt_hw_interrupt_disable(); pm = &_pm; if (pm->modes[mode] > 0) pm->modes[mode] --; if (pm->modes[mode] == 0) pm->module_status[module_id].req_status = 0x00; _pm_select_sleep_mode(pm); rt_hw_interrupt_enable(level); } /** * Upper application or device driver releases all the stall * of corresponding power mode. * * @param module_id the application or device module id * @param mode the system power sleep mode * */ void rt_pm_module_release_all(uint8_t module_id, rt_uint8_t mode) { rt_ubase_t level; struct rt_pm *pm; if (_pm_init_flag == 0) return; if (mode > (PM_SLEEP_MODE_MAX - 1)) return; level = rt_hw_interrupt_disable(); pm = &_pm; pm->modes[mode] = 0; pm->module_status[module_id].req_status = 0x00; _pm_select_sleep_mode(pm); rt_hw_interrupt_enable(level); } /** * Register a device with PM feature * * @param device the device with PM feature * @param ops the PM ops for device */ void rt_pm_device_register(struct rt_device *device, const struct rt_device_pm_ops *ops) { rt_base_t level; struct rt_device_pm *device_pm; RT_DEBUG_NOT_IN_INTERRUPT; level = rt_hw_interrupt_disable(); device_pm = (struct rt_device_pm *)RT_KERNEL_REALLOC(_pm.device_pm, (_pm.device_pm_number + 1) * sizeof(struct rt_device_pm)); if (device_pm != RT_NULL) { _pm.device_pm = device_pm; _pm.device_pm[_pm.device_pm_number].device = device; _pm.device_pm[_pm.device_pm_number].ops = ops; _pm.device_pm_number += 1; } rt_hw_interrupt_enable(level); } /** * Unregister device from PM manager. * * @param device the device with PM feature */ void rt_pm_device_unregister(struct rt_device *device) { rt_ubase_t level; rt_uint32_t index; RT_DEBUG_NOT_IN_INTERRUPT; level = rt_hw_interrupt_disable(); for (index = 0; index < _pm.device_pm_number; index ++) { if (_pm.device_pm[index].device == device) { /* remove current entry */ for (; index < _pm.device_pm_number - 1; index ++) { _pm.device_pm[index] = _pm.device_pm[index + 1]; } _pm.device_pm[_pm.device_pm_number - 1].device = RT_NULL; _pm.device_pm[_pm.device_pm_number - 1].ops = RT_NULL; _pm.device_pm_number -= 1; /* break out and not touch memory */ break; } } rt_hw_interrupt_enable(level); } /** * This function set notification callback for application */ void rt_pm_notify_set(void (*notify)(rt_uint8_t event, rt_uint8_t mode, void *data), void *data) { _pm_notify.notify = notify; _pm_notify.data = data; } /** * This function set default sleep mode when no pm_request */ void rt_pm_default_set(rt_uint8_t sleep_mode) { _pm_default_sleep = sleep_mode; } /** * RT-Thread device interface for PM device */ static rt_size_t _rt_pm_device_read(rt_device_t dev, rt_off_t pos, void *buffer, rt_size_t size) { struct rt_pm *pm; rt_size_t length; length = 0; pm = (struct rt_pm *)dev; RT_ASSERT(pm != RT_NULL); if (pos < PM_SLEEP_MODE_MAX) { int mode; mode = pm->modes[pos]; length = rt_snprintf(buffer, size, "%d", mode); } return length; } static rt_size_t _rt_pm_device_write(rt_device_t dev, rt_off_t pos, const void *buffer, rt_size_t size) { unsigned char request; if (size) { /* get request */ request = *(unsigned char *)buffer; if (request == 0x01) { rt_pm_request(pos); } else if (request == 0x00) { rt_pm_release(pos); } } return 1; } static rt_err_t _rt_pm_device_control(rt_device_t dev, int cmd, void *args) { rt_uint32_t mode; switch (cmd) { case RT_PM_DEVICE_CTRL_REQUEST: mode = (rt_uint32_t)args; rt_pm_request(mode); break; case RT_PM_DEVICE_CTRL_RELEASE: mode = (rt_uint32_t)args; rt_pm_release(mode); break; } return RT_EOK; } int rt_pm_run_enter(rt_uint8_t mode) { rt_base_t level; struct rt_pm *pm; if (_pm_init_flag == 0) return -RT_EIO; if (mode > PM_RUN_MODE_MAX) return -RT_EINVAL; level = rt_hw_interrupt_disable(); pm = &_pm; if (mode < pm->run_mode) { /* change system runing mode */ pm->ops->run(pm, mode); /* changer device frequency */ _pm_device_frequency_change(mode); } else { pm->flags |= RT_PM_FREQUENCY_PENDING; } pm->run_mode = mode; rt_hw_interrupt_enable(level); return RT_EOK; } #ifdef RT_USING_DEVICE_OPS const static struct rt_device_ops pm_ops = { RT_NULL, RT_NULL, RT_NULL, _rt_pm_device_read, _rt_pm_device_write, _rt_pm_device_control, }; #endif /** * This function will initialize power management. * * @param ops the PM operations. * @param timer_mask indicates which mode has timer feature. * @param user_data user data */ void rt_system_pm_init(const struct rt_pm_ops *ops, rt_uint8_t timer_mask, void *user_data) { struct rt_device *device; struct rt_pm *pm; pm = &_pm; device = &(_pm.parent); device->type = RT_Device_Class_PM; device->rx_indicate = RT_NULL; device->tx_complete = RT_NULL; #ifdef RT_USING_DEVICE_OPS device->ops = &pm_ops; #else device->init = RT_NULL; device->open = RT_NULL; device->close = RT_NULL; device->read = _rt_pm_device_read; device->write = _rt_pm_device_write; device->control = _rt_pm_device_control; #endif device->user_data = user_data; /* register PM device to the system */ rt_device_register(device, "pm", RT_DEVICE_FLAG_RDWR); rt_memset(pm->modes, 0, sizeof(pm->modes)); pm->sleep_mode = _pm_default_sleep; /* when system power on, set default sleep modes */ pm->modes[pm->sleep_mode] = 1; pm->module_status[PM_POWER_ID].req_status = 1; pm->run_mode = RT_PM_DEFAULT_RUN_MODE; pm->timer_mask = timer_mask; pm->ops = ops; pm->device_pm = RT_NULL; pm->device_pm_number = 0; #if IDLE_THREAD_STACK_SIZE <= 256 #error "[pm.c ERR] IDLE Stack Size Too Small!" #endif _pm_init_flag = 1; } #ifdef RT_USING_FINSH #include static const char *_pm_sleep_str[] = PM_SLEEP_MODE_NAMES; static const char *_pm_run_str[] = PM_RUN_MODE_NAMES; static void rt_pm_release_mode(int argc, char **argv) { int mode = 0; if (argc >= 2) { mode = atoi(argv[1]); } rt_pm_release(mode); } MSH_CMD_EXPORT_ALIAS(rt_pm_release_mode, pm_release, release power management mode); static void rt_pm_release_mode_all(int argc, char **argv) { int mode = 0; if (argc >= 2) { mode = atoi(argv[1]); } rt_pm_release_all(mode); } MSH_CMD_EXPORT_ALIAS(rt_pm_release_mode_all, pm_release_all, release power management mode count); static void rt_pm_request_mode(int argc, char **argv) { int mode = 0; if (argc >= 2) { mode = atoi(argv[1]); } rt_pm_request(mode); } MSH_CMD_EXPORT_ALIAS(rt_pm_request_mode, pm_request, request power management mode); static void rt_module_release_mode(int argc, char **argv) { int module = 0; int mode = 0; if (argc >= 3) { module = atoi(argv[1]); mode = atoi(argv[2]); } rt_pm_module_release(module, mode); } MSH_CMD_EXPORT_ALIAS(rt_module_release_mode, pm_module_release, release module power mode); static void rt_module_release_mode_all(int argc, char **argv) { int module = 0; int mode = 0; if (argc >= 3) { module = atoi(argv[1]); mode = atoi(argv[2]); } rt_pm_module_release_all(module, mode); } MSH_CMD_EXPORT_ALIAS(rt_module_release_mode_all, pm_module_release_all, release power management mode count); static void rt_module_request_mode(int argc, char **argv) { int module = 0; int mode = 0; if (argc >= 3) { module = atoi(argv[1]); mode = atoi(argv[2]); } rt_pm_module_request(module, mode); } MSH_CMD_EXPORT_ALIAS(rt_module_request_mode, pm_module_request, request power management mode); static void rt_module_delay_sleep(int argc, char **argv) { int module = 0; unsigned int timeout = 0; if (argc >= 3) { module = atoi(argv[1]); timeout = atoi(argv[2]); } rt_pm_module_delay_sleep(module, timeout); } MSH_CMD_EXPORT_ALIAS(rt_module_delay_sleep, pm_module_delay, module request delay sleep); static void rt_pm_run_mode_switch(int argc, char **argv) { int mode = 0; if (argc >= 2) { mode = atoi(argv[1]); } rt_pm_run_enter(mode); } MSH_CMD_EXPORT_ALIAS(rt_pm_run_mode_switch, pm_run, switch power management run mode); rt_uint32_t rt_pm_module_get_status(void) { rt_uint8_t index = 0; struct rt_pm *pm; rt_uint32_t req_status = 0x00; pm = &_pm; for (index = 0; index < 32; index ++) { if (pm->module_status[index].req_status == 0x01) req_status |= 1<= PM_MODULE_MAX_ID) break; } return req_status; } rt_uint8_t rt_pm_get_sleep_mode(void) { struct rt_pm *pm; pm = &_pm; return pm->sleep_mode; } static void rt_pm_dump_status(void) { rt_uint32_t index; struct rt_pm *pm; pm = &_pm; rt_kprintf("| Power Management Mode | Counter | Timer |\n"); rt_kprintf("+-----------------------+---------+-------+\n"); for (index = 0; index < PM_SLEEP_MODE_MAX; index ++) { int has_timer = 0; if (pm->timer_mask & (1 << index)) has_timer = 1; rt_kprintf("| %021s | %7d | %5d |\n", _pm_sleep_str[index], pm->modes[index], has_timer); } rt_kprintf("+-----------------------+---------+-------+\n"); rt_kprintf("pm current sleep mode: %s\n", _pm_sleep_str[pm->sleep_mode]); rt_kprintf("pm current run mode: %s\n", _pm_run_str[pm->run_mode]); rt_kprintf("\n"); rt_kprintf("| module | busy | start time | timeout |\n"); rt_kprintf("+--------+------+------------+-----------+\n"); for (index = 0; index < PM_MODULE_MAX_ID; index ++) { if ((pm->module_status[index].busy_flag == RT_TRUE) || (pm->module_status[index].req_status != 0x00)) { rt_kprintf("| %04d | %d | 0x%08x | 0x%08x |\n", index, pm->module_status[index].busy_flag, pm->module_status[index].start_time, pm->module_status[index].timeout); } } rt_kprintf("+--------+------+------------+-----------+\n"); } FINSH_FUNCTION_EXPORT_ALIAS(rt_pm_dump_status, pm_dump, dump power management status); MSH_CMD_EXPORT_ALIAS(rt_pm_dump_status, pm_dump, dump power management status); #endif #endif /* RT_USING_PM */