/* * This file is part of the MicroPython project, http://micropython.org/ * * The MIT License (MIT) * * Copyright (c) 2019 Damien P. George * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ #include #include "py/gc.h" #include "py/mphal.h" #include "py/runtime.h" #include "softtimer.h" #ifdef MICROPY_SOFT_TIMER_TICKS_MS extern __IO uint32_t MICROPY_SOFT_TIMER_TICKS_MS; volatile uint32_t soft_timer_next; static inline uint32_t soft_timer_get_ms(void) { return MICROPY_SOFT_TIMER_TICKS_MS; } static void soft_timer_schedule_at_ms(uint32_t ticks_ms) { uint32_t atomic_state = MICROPY_BEGIN_ATOMIC_SECTION(); uint32_t uw_tick = MICROPY_SOFT_TIMER_TICKS_MS; if (soft_timer_ticks_diff(ticks_ms, uw_tick) <= 0) { soft_timer_next = uw_tick + 1; } else { soft_timer_next = ticks_ms; } MICROPY_END_ATOMIC_SECTION(atomic_state); } #endif // Pointer to the pairheap of soft timer objects. // This may contain bss/data pointers as well as GC-heap pointers, // and is explicitly GC traced by soft_timer_gc_mark_all(). static soft_timer_entry_t *soft_timer_heap; static int soft_timer_lt(mp_pairheap_t *n1, mp_pairheap_t *n2) { soft_timer_entry_t *e1 = (soft_timer_entry_t *)n1; soft_timer_entry_t *e2 = (soft_timer_entry_t *)n2; return soft_timer_ticks_diff(e1->expiry_ms, e2->expiry_ms) < 0; } void soft_timer_deinit(void) { // Pop off all the nodes which are allocated on the GC-heap. MICROPY_PY_PENDSV_ENTER; soft_timer_entry_t *heap_from = soft_timer_heap; soft_timer_entry_t *heap_to = (soft_timer_entry_t *)mp_pairheap_new(soft_timer_lt); while (heap_from != NULL) { soft_timer_entry_t *entry = (soft_timer_entry_t *)mp_pairheap_peek(soft_timer_lt, &heap_from->pairheap); heap_from = (soft_timer_entry_t *)mp_pairheap_pop(soft_timer_lt, &heap_from->pairheap); if (!(entry->flags & SOFT_TIMER_FLAG_GC_ALLOCATED)) { heap_to = (soft_timer_entry_t *)mp_pairheap_push(soft_timer_lt, &heap_to->pairheap, &entry->pairheap); } } soft_timer_heap = heap_to; MICROPY_PY_PENDSV_EXIT; } // Must be executed at IRQ_PRI_PENDSV void soft_timer_handler(void) { uint32_t ticks_ms = soft_timer_get_ms(); soft_timer_entry_t *heap = soft_timer_heap; while (heap != NULL && soft_timer_ticks_diff(heap->expiry_ms, ticks_ms) <= 0) { soft_timer_entry_t *entry = heap; heap = (soft_timer_entry_t *)mp_pairheap_pop(soft_timer_lt, &heap->pairheap); if (entry->flags & SOFT_TIMER_FLAG_PY_CALLBACK) { mp_sched_schedule(entry->py_callback, MP_OBJ_FROM_PTR(entry)); } else if (entry->c_callback) { entry->c_callback(entry); } if (entry->mode == SOFT_TIMER_MODE_PERIODIC) { entry->expiry_ms += entry->delta_ms; heap = (soft_timer_entry_t *)mp_pairheap_push(soft_timer_lt, &heap->pairheap, &entry->pairheap); } } soft_timer_heap = heap; // Schedule the port's timer to call us back at the correct time. if (heap != NULL) { soft_timer_schedule_at_ms(heap->expiry_ms); } } void soft_timer_gc_mark_all(void) { // Mark all soft timer nodes that are allocated on the GC-heap. // To avoid deep C recursion, pop and recreate the pairheap as nodes are marked. MICROPY_PY_PENDSV_ENTER; soft_timer_entry_t *heap_from = soft_timer_heap; soft_timer_entry_t *heap_to = (soft_timer_entry_t *)mp_pairheap_new(soft_timer_lt); while (heap_from != NULL) { soft_timer_entry_t *entry = (soft_timer_entry_t *)mp_pairheap_peek(soft_timer_lt, &heap_from->pairheap); heap_from = (soft_timer_entry_t *)mp_pairheap_pop(soft_timer_lt, &heap_from->pairheap); if (entry->flags & SOFT_TIMER_FLAG_GC_ALLOCATED) { gc_collect_root((void **)&entry, 1); } heap_to = (soft_timer_entry_t *)mp_pairheap_push(soft_timer_lt, &heap_to->pairheap, &entry->pairheap); } soft_timer_heap = heap_to; MICROPY_PY_PENDSV_EXIT; } void soft_timer_static_init(soft_timer_entry_t *entry, uint16_t mode, uint32_t delta_ms, void (*cb)(soft_timer_entry_t *)) { mp_pairheap_init_node(soft_timer_lt, &entry->pairheap); entry->flags = 0; entry->mode = mode; entry->delta_ms = delta_ms; entry->c_callback = cb; } void soft_timer_insert(soft_timer_entry_t *entry, uint32_t initial_delta_ms) { mp_pairheap_init_node(soft_timer_lt, &entry->pairheap); entry->expiry_ms = soft_timer_get_ms() + initial_delta_ms; MICROPY_PY_PENDSV_ENTER; soft_timer_heap = (soft_timer_entry_t *)mp_pairheap_push(soft_timer_lt, &soft_timer_heap->pairheap, &entry->pairheap); if (entry == soft_timer_heap) { // This new timer became the earliest one so schedule a callback. soft_timer_schedule_at_ms(entry->expiry_ms); } MICROPY_PY_PENDSV_EXIT; } void soft_timer_remove(soft_timer_entry_t *entry) { MICROPY_PY_PENDSV_ENTER; soft_timer_heap = (soft_timer_entry_t *)mp_pairheap_delete(soft_timer_lt, &soft_timer_heap->pairheap, &entry->pairheap); MICROPY_PY_PENDSV_EXIT; }