/* * Copyright (c) 2020 Raspberry Pi (Trading) Ltd. * * SPDX-License-Identifier: BSD-3-Clause */ #include "hardware/timer.h" #include "hardware/irq.h" #include "hardware/sync.h" #include "hardware/claim.h" check_hw_layout(timer_hw_t, ints, TIMER_INTS_OFFSET); static hardware_alarm_callback_t alarm_callbacks[NUM_TIMERS]; static uint32_t target_hi[NUM_TIMERS]; static uint8_t timer_callbacks_pending; static_assert(NUM_TIMERS <= 4, ""); static uint8_t claimed; void hardware_alarm_claim(uint alarm_num) { check_hardware_alarm_num_param(alarm_num); hw_claim_or_assert(&claimed, alarm_num, "Hardware alarm %d already claimed"); } void hardware_alarm_unclaim(uint alarm_num) { check_hardware_alarm_num_param(alarm_num); hw_claim_clear(&claimed, alarm_num); } bool hardware_alarm_is_claimed(uint alarm_num) { check_hardware_alarm_num_param(alarm_num); return hw_is_claimed(&claimed, alarm_num); } int hardware_alarm_claim_unused(bool required) { return hw_claim_unused_from_range(&claimed, required, 0, NUM_TIMERS - 1, "No timers available"); } /// tag::time_us_64[] uint64_t time_us_64() { // Need to make sure that the upper 32 bits of the timer // don't change, so read that first uint32_t hi = timer_hw->timerawh; uint32_t lo; do { // Read the lower 32 bits lo = timer_hw->timerawl; // Now read the upper 32 bits again and // check that it hasn't incremented. If it has loop around // and read the lower 32 bits again to get an accurate value uint32_t next_hi = timer_hw->timerawh; if (hi == next_hi) break; hi = next_hi; } while (true); return ((uint64_t) hi << 32u) | lo; } /// end::time_us_64[] /// \tag::busy_wait[] void busy_wait_us_32(uint32_t delay_us) { if (0 <= (int32_t)delay_us) { // we only allow 31 bits, otherwise we could have a race in the loop below with // values very close to 2^32 uint32_t start = timer_hw->timerawl; while (timer_hw->timerawl - start < delay_us) { tight_loop_contents(); } } else { busy_wait_us(delay_us); } } void busy_wait_us(uint64_t delay_us) { uint64_t base = time_us_64(); uint64_t target = base + delay_us; if (target < base) { target = (uint64_t)-1; } absolute_time_t t; update_us_since_boot(&t, target); busy_wait_until(t); } void busy_wait_ms(uint32_t delay_ms) { if (delay_ms <= 0x7fffffffu / 1000) { busy_wait_us_32(delay_ms * 1000); } else { busy_wait_us(delay_ms * 1000ull); } } void busy_wait_until(absolute_time_t t) { uint64_t target = to_us_since_boot(t); uint32_t hi_target = (uint32_t)(target >> 32u); uint32_t hi = timer_hw->timerawh; while (hi < hi_target) { hi = timer_hw->timerawh; tight_loop_contents(); } while (hi == hi_target && timer_hw->timerawl < (uint32_t) target) { hi = timer_hw->timerawh; tight_loop_contents(); } } /// \end::busy_wait[] static inline uint harware_alarm_irq_number(uint alarm_num) { return TIMER_IRQ_0 + alarm_num; } static void hardware_alarm_irq_handler(void) { // Determine which timer this IRQ is for uint alarm_num = __get_current_exception() - VTABLE_FIRST_IRQ - TIMER_IRQ_0; check_hardware_alarm_num_param(alarm_num); hardware_alarm_callback_t callback = NULL; spin_lock_t *lock = spin_lock_instance(PICO_SPINLOCK_ID_TIMER); uint32_t save = spin_lock_blocking(lock); // Clear the timer IRQ (inside lock, because we check whether we have handled the IRQ yet in alarm_set by looking at the interrupt status timer_hw->intr = 1u << alarm_num; // Clear any forced IRQ hw_clear_bits(&timer_hw->intf, 1u << alarm_num); // make sure the IRQ is still valid if (timer_callbacks_pending & (1u << alarm_num)) { // Now check whether we have a timer event to handle that isn't already obsolete (this could happen if we // were already in the IRQ handler before someone else changed the timer setup if (timer_hw->timerawh >= target_hi[alarm_num]) { // we have reached the right high word as well as low word value callback = alarm_callbacks[alarm_num]; timer_callbacks_pending &= (uint8_t)~(1u << alarm_num); } else { // try again in 2^32 us timer_hw->alarm[alarm_num] = timer_hw->alarm[alarm_num]; // re-arm the timer } } spin_unlock(lock, save); if (callback) { callback(alarm_num); } } void hardware_alarm_set_callback(uint alarm_num, hardware_alarm_callback_t callback) { // todo check current core owner // note this should probably be subsumed by irq_set_exclusive_handler anyway, since that // should disallow IRQ handlers on both cores check_hardware_alarm_num_param(alarm_num); uint irq_num = harware_alarm_irq_number(alarm_num); spin_lock_t *lock = spin_lock_instance(PICO_SPINLOCK_ID_TIMER); uint32_t save = spin_lock_blocking(lock); if (callback) { if (hardware_alarm_irq_handler != irq_get_vtable_handler(irq_num)) { // note that set_exclusive will silently allow you to set the handler to the same thing // since it is idempotent, which means we don't need to worry about locking ourselves irq_set_exclusive_handler(irq_num, hardware_alarm_irq_handler); irq_set_enabled(irq_num, true); // Enable interrupt in block and at processor hw_set_bits(&timer_hw->inte, 1u << alarm_num); } alarm_callbacks[alarm_num] = callback; } else { alarm_callbacks[alarm_num] = NULL; timer_callbacks_pending &= (uint8_t)~(1u << alarm_num); irq_remove_handler(irq_num, hardware_alarm_irq_handler); irq_set_enabled(irq_num, false); } spin_unlock(lock, save); } bool hardware_alarm_set_target(uint alarm_num, absolute_time_t target) { bool missed; uint64_t now = time_us_64(); uint64_t t = to_us_since_boot(target); if (now >= t) { missed = true; } else { missed = false; // 1) actually set the hardware timer spin_lock_t *lock = spin_lock_instance(PICO_SPINLOCK_ID_TIMER); uint32_t save = spin_lock_blocking(lock); uint8_t old_timer_callbacks_pending = timer_callbacks_pending; timer_callbacks_pending |= (uint8_t)(1u << alarm_num); timer_hw->intr = 1u << alarm_num; // clear any IRQ timer_hw->alarm[alarm_num] = (uint32_t) t; // Set the alarm. Writing time should arm it target_hi[alarm_num] = (uint32_t)(t >> 32u); // 2) check for races if (!(timer_hw->armed & 1u << alarm_num)) { // not armed, so has already fired .. IRQ must be pending (we are still under lock) assert(timer_hw->ints & 1u << alarm_num); } else { if (time_us_64() >= t) { // we are already at or past the right time; there is no point in us racing against the IRQ // we are about to generate. note however that, if there was already a timer pending before, // then we still let the IRQ fire, as whatever it was, is not handled by our setting missed=true here missed = true; if (timer_callbacks_pending != old_timer_callbacks_pending) { // disarm the timer timer_hw->armed = 1u << alarm_num; // clear the IRQ... timer_hw->intr = 1u << alarm_num; // ... including anything pending on the processor - perhaps unnecessary, but // our timer flag says we aren't expecting anything. irq_clear(harware_alarm_irq_number(alarm_num)); // and clear our flag so that if the IRQ handler is already active (because it is on // the other core) it will also skip doing anything timer_callbacks_pending = old_timer_callbacks_pending; } } } spin_unlock(lock, save); // note at this point any pending timer IRQ can likely run } return missed; } void hardware_alarm_cancel(uint alarm_num) { check_hardware_alarm_num_param(alarm_num); spin_lock_t *lock = spin_lock_instance(PICO_SPINLOCK_ID_TIMER); uint32_t save = spin_lock_blocking(lock); timer_hw->armed = 1u << alarm_num; timer_callbacks_pending &= (uint8_t)~(1u << alarm_num); spin_unlock(lock, save); } void hardware_alarm_force_irq(uint alarm_num) { check_hardware_alarm_num_param(alarm_num); spin_lock_t *lock = spin_lock_instance(PICO_SPINLOCK_ID_TIMER); uint32_t save = spin_lock_blocking(lock); timer_callbacks_pending |= (uint8_t)(1u << alarm_num); spin_unlock(lock, save); hw_set_bits(&timer_hw->intf, 1u << alarm_num); }