/* mbed Microcontroller Library ******************************************************************************* * Copyright (c) 2014, Realtek Semiconductor Corp. * All rights reserved. * * This module is a confidential and proprietary property of RealTek and * possession or use of this module requires written permission of RealTek. ******************************************************************************* */ #include "objects.h" #include #include "us_ticker_api.h" #include "PeripheralNames.h" #define TICK_READ_FROM_CPU 0 // 1: read tick from CPU, 0: read tick from G-Timer #define SYS_TIM_ID 1 // the G-Timer ID for System #define APP_TIM_ID 6 // the G-Timer ID for Application static int us_ticker_inited = 0; static TIMER_ADAPTER TimerAdapter; extern HAL_TIMER_OP HalTimerOp; VOID _us_ticker_irq_handler(IN VOID *Data) { us_ticker_irq_handler(); } void us_ticker_init(void) { if (us_ticker_inited) return; us_ticker_inited = 1; // Initial a G-Timer TimerAdapter.IrqDis = 1; // Disable Irq TimerAdapter.IrqHandle.IrqFun = (IRQ_FUN) _us_ticker_irq_handler; TimerAdapter.IrqHandle.IrqNum = TIMER2_7_IRQ; TimerAdapter.IrqHandle.Priority = 10; TimerAdapter.IrqHandle.Data = (u32)NULL; TimerAdapter.TimerId = APP_TIM_ID; TimerAdapter.TimerIrqPriority = 0; TimerAdapter.TimerLoadValueUs = 1; TimerAdapter.TimerMode = FREE_RUN_MODE; // Countdown Free Run HalTimerOp.HalTimerInit((VOID*) &TimerAdapter); DBG_TIMER_INFO("%s: Timer_Id=%d\n", __FUNCTION__, APP_TIM_ID); } #if (!TICK_READ_FROM_CPU) || !defined(PLATFORM_FREERTOS) uint32_t us_ticker_read() { uint32_t tick_cnt; uint32_t ticks_125ms; uint32_t ticks_remain; uint64_t us_tick; //1 Our G-timer resolution is ~31 us (1/32K), and is a countdown timer // if (!us_ticker_inited) { // us_ticker_init(); // } tick_cnt = HalTimerOp.HalTimerReadCount(SYS_TIM_ID); tick_cnt = 0xffffffff - tick_cnt; // it's a down counter ticks_125ms = tick_cnt/(GTIMER_CLK_HZ/8); ticks_remain = tick_cnt - (ticks_125ms*(GTIMER_CLK_HZ/8)); us_tick = ticks_125ms * 125000; us_tick += (ticks_remain * 1000000)/GTIMER_CLK_HZ; return ((uint32_t)us_tick); } #else // if the system tick didn't be initialed, call delay function may got system hang #define OS_CLOCK (200000000UL/6*5) // CPU clock = 166.66 MHz #define OS_TICK 1000 // OS ticks 1000/sec #define OS_TRV ((uint32_t)(((double)OS_CLOCK*(double)OS_TICK)/1E6)-1) #define NVIC_ST_CTRL (*((volatile uint32_t *)0xE000E010)) #define NVIC_ST_RELOAD (*((volatile uint32_t *)0xE000E014)) #define NVIC_ST_CURRENT (*((volatile uint32_t *)0xE000E018)) extern uint32_t xTaskGetTickCount( void ); uint32_t us_ticker_read() { uint32_t tick_cnt; uint32_t us_tick, ms; static uint32_t last_us_tick=0; ms = xTaskGetTickCount(); us_tick = (uint32_t)(ms*1000); tick_cnt = OS_TRV - NVIC_ST_CURRENT; us_tick += (uint32_t)((tick_cnt*1000)/(OS_TRV+1) ); if ( (last_us_tick > us_tick) && (last_us_tick < 0xFFFFFC00) ) { us_tick += 1000; } last_us_tick = us_tick; return us_tick; } #endif void us_ticker_set_interrupt(timestamp_t timestamp) { uint32_t cur_time_us; uint32_t time_def; cur_time_us = us_ticker_read(); if ((uint32_t)timestamp >= cur_time_us) { time_def = (uint32_t)timestamp - cur_time_us; } else { time_def = 0xffffffff - cur_time_us + (uint32_t)timestamp; } if (time_def < TIMER_TICK_US) { time_def = TIMER_TICK_US; // at least 1 tick } TimerAdapter.IrqDis = 0; // Enable Irq TimerAdapter.TimerLoadValueUs = time_def; TimerAdapter.TimerMode = USER_DEFINED; // Countdown Free Run HalTimerOp.HalTimerInit((VOID*) &TimerAdapter); } void us_ticker_disable_interrupt(void) { HalTimerOp.HalTimerDis((u32)TimerAdapter.TimerId); } void us_ticker_clear_interrupt(void) { HalTimerOp.HalTimerIrqClear((u32)TimerAdapter.TimerId); }