/* * Copyright (c) 2023 Renesas Electronics Corporation * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include #include #include #include #include #include #define COUNTER_SPAN BIT(24) #define CYC_PER_TICK k_ticks_to_cyc_ceil32(1) #define TICK_TO_CYC(tick) k_ticks_to_cyc_ceil32(tick) #define CYC_TO_TICK(cyc) k_cyc_to_ticks_ceil32(cyc) #define MAX_TICKS (((COUNTER_SPAN / 2) - CYC_PER_TICK) / (CYC_PER_TICK)) #define SMARTBOND_CLOCK_CONTROLLER DEVICE_DT_GET(DT_NODELABEL(osc)) /* Margin values are based on DA1469x characterization data */ #define RC32K_FREQ_POSITIVE_MARGIN_DUE_TO_VOLTAGE (675) #define RC32K_FREQ_MARGIN_DUE_TO_TEMPERATURE (450) static uint32_t last_timer_val_reg; static uint32_t timer_val_31_24; static uint32_t last_isr_val; static uint32_t last_isr_val_rounded; static uint32_t announced_ticks; static uint32_t get_rc32k_max_frequency(void) { /* According to DA1469x datasheet */ uint32_t r32k_frequency = 37000; clock_control_get_rate(SMARTBOND_CLOCK_CONTROLLER, (clock_control_subsys_t)SMARTBOND_CLK_RC32K, &r32k_frequency); r32k_frequency += RC32K_FREQ_POSITIVE_MARGIN_DUE_TO_VOLTAGE + RC32K_FREQ_MARGIN_DUE_TO_TEMPERATURE; return r32k_frequency; } static void set_reload(uint32_t val) { TIMER2->TIMER2_RELOAD_REG = val & TIMER2_TIMER2_RELOAD_REG_TIM_RELOAD_Msk; } static uint32_t timer_val_32(void) { uint32_t timer_val_reg; uint32_t val; timer_val_reg = TIMER2->TIMER2_TIMER_VAL_REG & TIMER2_TIMER2_TIMER_VAL_REG_TIM_TIMER_VALUE_Msk; if (timer_val_reg < last_timer_val_reg) { timer_val_31_24 += COUNTER_SPAN; } last_timer_val_reg = timer_val_reg; val = timer_val_31_24 + timer_val_reg; return val; } static uint32_t timer_val_32_noupdate(void) { uint32_t timer_val_reg; uint32_t val; timer_val_reg = TIMER2->TIMER2_TIMER_VAL_REG & TIMER2_TIMER2_TIMER_VAL_REG_TIM_TIMER_VALUE_Msk; val = timer_val_31_24 + timer_val_reg; if (timer_val_reg < last_timer_val_reg) { val += COUNTER_SPAN; } return val; } void sys_clock_set_timeout(int32_t ticks, bool idle) { uint32_t target_val; uint32_t timer_val; if (!IS_ENABLED(CONFIG_TICKLESS_KERNEL)) { return; } if (ticks == K_TICKS_FOREVER) { /* FIXME we could disable timer here */ } /* * When Watchdog is NOT enabled but power management is, system * starts watchdog before PD_SYS is powered off. * Watchdog default reload value is 0x1FFF (~82s for RC32K and 172s for RCX). * After this time watchdog will reset system if not woken up before. * When Watchdog is not configured power management freezes watchdog * as soon as system is awaken. Following code makes sure that * system never goes to sleep for longer time that watchdog reload value. */ if (!IS_ENABLED(CONFIG_WDT_SMARTBOND) && IS_ENABLED(CONFIG_PM)) { uint32_t watchdog_expire_ticks; if (CRG_TOP->CLK_RCX_REG & CRG_TOP_CLK_RCX_REG_RCX_ENABLE_Msk) { /* * When LP clock is RCX, the watchdog is clocked by RCX clock * divided by 320. */ watchdog_expire_ticks = SYS_WDOG->WATCHDOG_REG * 320; } else { /* * When LP clock is not RCX, the watchdog is clocked by RC32K * divided by 320. In this case watchdog value to LP clock * ticks must be calculated according to XTAL32K frequency and * RC32K maximum frequency. */ watchdog_expire_ticks = SYS_WDOG->WATCHDOG_REG * CONFIG_SYS_CLOCK_TICKS_PER_SEC / (get_rc32k_max_frequency() / 320); } if (watchdog_expire_ticks - 2 < ticks) { ticks = watchdog_expire_ticks - 2; } } ticks = (ticks == K_TICKS_FOREVER) ? MAX_TICKS : ticks; ticks = CLAMP(ticks - 1, 0, (int32_t)MAX_TICKS); timer_val = timer_val_32_noupdate(); /* Calculate target timer value and align to full tick */ target_val = timer_val + TICK_TO_CYC(ticks); target_val = ((target_val + CYC_PER_TICK - 1) / CYC_PER_TICK) * CYC_PER_TICK; set_reload(target_val); /* * If time was so small that it already fired or should fire * just now, mark interrupt as pending to avoid losing timer event. * Condition is true when target_val (point in time that should be * used for wakeup) is behind timer value or is equal to it. * In that case we don't know if reload value was set in time or * not but time expired anyway so make sure that interrupt is pending. */ if ((int32_t)(target_val - timer_val_32_noupdate() - 1) < 0) { NVIC_SetPendingIRQ(TIMER2_IRQn); } } uint32_t sys_clock_elapsed(void) { if (!IS_ENABLED(CONFIG_TICKLESS_KERNEL)) { return 0; } return CYC_TO_TICK(timer_val_32_noupdate() - last_isr_val); } uint32_t sys_clock_cycle_get_32(void) { return timer_val_32_noupdate(); } void sys_clock_idle_exit(void) { TIMER2->TIMER2_CTRL_REG |= TIMER2_TIMER2_CTRL_REG_TIM_EN_Msk; } void sys_clock_disable(void) { TIMER2->TIMER2_CTRL_REG &= ~TIMER2_TIMER2_CTRL_REG_TIM_EN_Msk; } static void timer2_isr(const void *arg) { uint32_t val; int32_t delta; int32_t dticks; ARG_UNUSED(arg); TIMER2->TIMER2_CLEAR_IRQ_REG = 1; val = timer_val_32(); delta = (int32_t)(val - last_isr_val_rounded); last_isr_val = val; dticks = CYC_TO_TICK(delta); last_isr_val_rounded += TICK_TO_CYC(dticks); announced_ticks += dticks; sys_clock_announce(dticks); } static int sys_clock_driver_init(void) { #if CONFIG_PM uint8_t pdc_idx; uint8_t en_xtal; en_xtal = DT_NODE_HAS_STATUS_OKAY(DT_NODELABEL(xtal32m)) ? MCU_PDC_EN_XTAL : 0; /* Enable wakeup by TIMER2 */ pdc_idx = da1469x_pdc_add(MCU_PDC_TRIGGER_TIMER2, MCU_PDC_MASTER_M33, en_xtal); __ASSERT_NO_MSG(pdc_idx >= 0); da1469x_pdc_set(pdc_idx); da1469x_pdc_ack(pdc_idx); #endif TIMER2->TIMER2_CTRL_REG = 0; TIMER2->TIMER2_PRESCALER_REG = 0; TIMER2->TIMER2_CTRL_REG |= TIMER2_TIMER2_CTRL_REG_TIM_CLK_EN_Msk; TIMER2->TIMER2_CTRL_REG |= TIMER2_TIMER2_CTRL_REG_TIM_FREE_RUN_MODE_EN_Msk | TIMER2_TIMER2_CTRL_REG_TIM_IRQ_EN_Msk | TIMER2_TIMER2_CTRL_REG_TIM_EN_Msk; IRQ_CONNECT(TIMER2_IRQn, _IRQ_PRIO_OFFSET, timer2_isr, 0, 0); irq_enable(TIMER2_IRQn); return 0; } SYS_INIT(sys_clock_driver_init, PRE_KERNEL_2, CONFIG_SYSTEM_CLOCK_INIT_PRIORITY);