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401 lines
15 KiB
C
401 lines
15 KiB
C
/*
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* SPDX-FileCopyrightText: 2015-2022 Espressif Systems (Shanghai) CO LTD
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*
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* SPDX-License-Identifier: Apache-2.0
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*/
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#include <sys/lock.h>
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#include <stdlib.h>
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#include <sys/reent.h>
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#include "esp_attr.h"
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#include "freertos/FreeRTOS.h"
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#include "freertos/semphr.h"
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#include "freertos/task.h"
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#include "freertos/portable.h"
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#include "esp_rom_caps.h"
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/* Notes on our newlib lock implementation:
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*
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* - Use FreeRTOS mutex semaphores as locks.
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* - lock_t is int, but we store an SemaphoreHandle_t there.
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* - Locks are no-ops until the FreeRTOS scheduler is running.
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* - Due to this, locks need to be lazily initialised the first time
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* they are acquired. Initialisation/deinitialisation of locks is
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* protected by lock_init_spinlock.
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* - Race conditions around lazy initialisation (via lock_acquire) are
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* protected against.
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* - Anyone calling lock_close is reponsible for ensuring noone else
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* is holding the lock at this time.
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* - Race conditions between lock_close & lock_init (for the same lock)
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* are the responsibility of the caller.
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*/
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static portMUX_TYPE lock_init_spinlock = portMUX_INITIALIZER_UNLOCKED;
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/* Initialize the given lock by allocating a new mutex semaphore
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as the _lock_t value.
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Called by _lock_init*, also called by _lock_acquire* to lazily initialize locks that might have
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been initialised (to zero only) before the RTOS scheduler started.
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*/
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static void IRAM_ATTR lock_init_generic(_lock_t *lock, uint8_t mutex_type) {
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portENTER_CRITICAL(&lock_init_spinlock);
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if (*lock) {
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/* Lock already initialised (either we didn't check earlier,
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or it got initialised while we were waiting for the
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spinlock.) */
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}
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else
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{
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/* Create a new semaphore
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this is a bit of an API violation, as we're calling the
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private function xQueueCreateMutex(x) directly instead of
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the xSemaphoreCreateMutex / xSemaphoreCreateRecursiveMutex
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wrapper functions...
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The better alternative would be to pass pointers to one of
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the two xSemaphoreCreate___Mutex functions, but as FreeRTOS
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implements these as macros instead of inline functions
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(*party like it's 1998!*) it's not possible to do this
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without writing wrappers. Doing it this way seems much less
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spaghetti-like.
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*/
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SemaphoreHandle_t new_sem = xQueueCreateMutex(mutex_type);
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if (!new_sem) {
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abort(); /* No more semaphores available or OOM */
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}
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*lock = (_lock_t)new_sem;
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}
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portEXIT_CRITICAL(&lock_init_spinlock);
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}
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void IRAM_ATTR _lock_init(_lock_t *lock) {
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*lock = 0; // In case lock's memory is uninitialized
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lock_init_generic(lock, queueQUEUE_TYPE_MUTEX);
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}
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void IRAM_ATTR _lock_init_recursive(_lock_t *lock) {
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*lock = 0; // In case lock's memory is uninitialized
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lock_init_generic(lock, queueQUEUE_TYPE_RECURSIVE_MUTEX);
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}
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/* Free the mutex semaphore pointed to by *lock, and zero it out.
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Note that FreeRTOS doesn't account for deleting mutexes while they
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are held, and neither do we... so take care not to delete newlib
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locks while they may be held by other tasks!
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Also, deleting a lock in this way will cause it to be lazily
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re-initialised if it is used again. Caller has to avoid doing
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this!
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*/
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void IRAM_ATTR _lock_close(_lock_t *lock) {
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portENTER_CRITICAL(&lock_init_spinlock);
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if (*lock) {
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SemaphoreHandle_t h = (SemaphoreHandle_t)(*lock);
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#if (INCLUDE_xSemaphoreGetMutexHolder == 1)
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configASSERT(xSemaphoreGetMutexHolder(h) == NULL); /* mutex should not be held */
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#endif
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vSemaphoreDelete(h);
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*lock = 0;
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}
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portEXIT_CRITICAL(&lock_init_spinlock);
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}
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void _lock_close_recursive(_lock_t *lock) __attribute__((alias("_lock_close")));
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/* Acquire the mutex semaphore for lock. wait up to delay ticks.
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mutex_type is queueQUEUE_TYPE_RECURSIVE_MUTEX or queueQUEUE_TYPE_MUTEX
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*/
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static int IRAM_ATTR lock_acquire_generic(_lock_t *lock, uint32_t delay, uint8_t mutex_type) {
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SemaphoreHandle_t h = (SemaphoreHandle_t)(*lock);
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if (!h) {
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if (xTaskGetSchedulerState() == taskSCHEDULER_NOT_STARTED) {
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return 0; /* locking is a no-op before scheduler is up, so this "succeeds" */
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}
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/* lazy initialise lock - might have had a static initializer (that we don't use) */
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lock_init_generic(lock, mutex_type);
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h = (SemaphoreHandle_t)(*lock);
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configASSERT(h != NULL);
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}
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if (xTaskGetSchedulerState() == taskSCHEDULER_NOT_STARTED) {
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return 0; /* locking is a no-op before scheduler is up, so this "succeeds" */
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}
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BaseType_t success;
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if (!xPortCanYield()) {
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/* In ISR Context */
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if (mutex_type == queueQUEUE_TYPE_RECURSIVE_MUTEX) {
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abort(); /* recursive mutexes make no sense in ISR context */
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}
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BaseType_t higher_task_woken = false;
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success = xSemaphoreTakeFromISR(h, &higher_task_woken);
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if (!success && delay > 0) {
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abort(); /* Tried to block on mutex from ISR, couldn't... rewrite your program to avoid libc interactions in ISRs! */
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}
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if (higher_task_woken) {
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portYIELD_FROM_ISR();
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}
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}
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else {
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/* In task context */
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if (mutex_type == queueQUEUE_TYPE_RECURSIVE_MUTEX) {
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success = xSemaphoreTakeRecursive(h, delay);
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} else {
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success = xSemaphoreTake(h, delay);
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}
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}
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return (success == pdTRUE) ? 0 : -1;
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}
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void IRAM_ATTR _lock_acquire(_lock_t *lock) {
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lock_acquire_generic(lock, portMAX_DELAY, queueQUEUE_TYPE_MUTEX);
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}
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void IRAM_ATTR _lock_acquire_recursive(_lock_t *lock) {
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lock_acquire_generic(lock, portMAX_DELAY, queueQUEUE_TYPE_RECURSIVE_MUTEX);
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}
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int IRAM_ATTR _lock_try_acquire(_lock_t *lock) {
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return lock_acquire_generic(lock, 0, queueQUEUE_TYPE_MUTEX);
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}
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int IRAM_ATTR _lock_try_acquire_recursive(_lock_t *lock) {
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return lock_acquire_generic(lock, 0, queueQUEUE_TYPE_RECURSIVE_MUTEX);
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}
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/* Release the mutex semaphore for lock.
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mutex_type is queueQUEUE_TYPE_RECURSIVE_MUTEX or queueQUEUE_TYPE_MUTEX
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*/
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static void IRAM_ATTR lock_release_generic(_lock_t *lock, uint8_t mutex_type) {
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if (xTaskGetSchedulerState() == taskSCHEDULER_NOT_STARTED) {
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return; /* locking is a no-op before scheduler is up */
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}
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SemaphoreHandle_t h = (SemaphoreHandle_t)(*lock);
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assert(h);
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if (!xPortCanYield()) {
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if (mutex_type == queueQUEUE_TYPE_RECURSIVE_MUTEX) {
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abort(); /* indicates logic bug, it shouldn't be possible to lock recursively in ISR */
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}
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BaseType_t higher_task_woken = false;
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xSemaphoreGiveFromISR(h, &higher_task_woken);
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if (higher_task_woken) {
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portYIELD_FROM_ISR();
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}
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} else {
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if (mutex_type == queueQUEUE_TYPE_RECURSIVE_MUTEX) {
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xSemaphoreGiveRecursive(h);
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} else {
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xSemaphoreGive(h);
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}
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}
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}
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void IRAM_ATTR _lock_release(_lock_t *lock) {
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lock_release_generic(lock, queueQUEUE_TYPE_MUTEX);
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}
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void IRAM_ATTR _lock_release_recursive(_lock_t *lock) {
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lock_release_generic(lock, queueQUEUE_TYPE_RECURSIVE_MUTEX);
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}
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/* To ease the transition to newlib 3.3.0, this part is kept under an ifdef.
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* After the toolchain with newlib 3.3.0 is released and merged, the ifdefs
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* can be removed.
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*
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* Also the retargetable locking functions still rely on the previous
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* implementation. Once support for !_RETARGETABLE_LOCKING is removed,
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* the code can be simplified, removing support for lazy initialization of
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* locks. At the same time, IDF code which relies on _lock_acquire/_lock_release
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* will have to be updated to not depend on lazy initialization.
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*
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* Explanation of the different lock types:
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*
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* Newlib 2.2.0 and 3.0.0:
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* _lock_t is defined as int, stores SemaphoreHandle_t.
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*
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* Newlib 3.3.0:
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* struct __lock is (or contains) StaticSemaphore_t
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* _LOCK_T is a pointer to struct __lock, equivalent to SemaphoreHandle_t.
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* It has the same meaning as _lock_t in the previous implementation.
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*
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*/
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/* This ensures the platform-specific definition in lock.h is correct.
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* We use "greater or equal" since the size of StaticSemaphore_t may
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* vary by 2 words, depending on whether configUSE_TRACE_FACILITY is enabled.
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*/
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_Static_assert(sizeof(struct __lock) >= sizeof(StaticSemaphore_t),
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"Incorrect size of struct __lock");
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/* FreeRTOS configuration check */
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_Static_assert(configSUPPORT_STATIC_ALLOCATION,
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"FreeRTOS should be configured with static allocation support");
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/* These 2 locks are used instead of 9 distinct newlib static locks,
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* as most of the locks are required for lesser-used features, so
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* the chance of performance degradation due to lock contention is low.
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*/
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static StaticSemaphore_t s_common_mutex;
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static StaticSemaphore_t s_common_recursive_mutex;
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#if ESP_ROM_HAS_RETARGETABLE_LOCKING
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/* C3 and S3 ROMs are built without Newlib static lock symbols exported, and
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* with an extra level of _LOCK_T indirection in mind.
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* The following is a workaround for this:
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* - on startup, we call esp_rom_newlib_init_common_mutexes to set
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* the two mutex pointers to magic values.
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* - if in __retarget_lock_acquire*, we check if the argument dereferences
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* to the magic value. If yes, we lock the correct mutex defined in the app,
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* instead.
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* Casts from &StaticSemaphore_t to _LOCK_T are okay because _LOCK_T
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* (which is SemaphoreHandle_t) is a pointer to the corresponding
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* StaticSemaphore_t structure. This is ensured by asserts below.
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*/
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#define ROM_NEEDS_MUTEX_OVERRIDE
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#endif // ESP_ROM_HAS_RETARGETABLE_LOCKING
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#ifdef ROM_NEEDS_MUTEX_OVERRIDE
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#define ROM_MUTEX_MAGIC 0xbb10c433
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/* This is a macro, since we are overwriting the argument */
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#define MAYBE_OVERRIDE_LOCK(_lock, _lock_to_use_instead) \
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if (*(int*)_lock == ROM_MUTEX_MAGIC) { \
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(_lock) = (_LOCK_T) (_lock_to_use_instead); \
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}
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#else // ROM_NEEDS_MUTEX_OVERRIDE
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#define MAYBE_OVERRIDE_LOCK(_lock, _lock_to_use_instead)
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#endif // ROM_NEEDS_MUTEX_OVERRIDE
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void IRAM_ATTR __retarget_lock_init(_LOCK_T *lock)
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{
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*lock = NULL; /* In case lock's memory is uninitialized */
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lock_init_generic(lock, queueQUEUE_TYPE_MUTEX);
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}
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void IRAM_ATTR __retarget_lock_init_recursive(_LOCK_T *lock)
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{
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*lock = NULL; /* In case lock's memory is uninitialized */
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lock_init_generic(lock, queueQUEUE_TYPE_RECURSIVE_MUTEX);
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}
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void IRAM_ATTR __retarget_lock_close(_LOCK_T lock)
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{
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_lock_close(&lock);
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}
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void IRAM_ATTR __retarget_lock_close_recursive(_LOCK_T lock)
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{
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_lock_close_recursive(&lock);
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}
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/* Separate function, to prevent generating multiple assert strings */
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static void IRAM_ATTR check_lock_nonzero(_LOCK_T lock)
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{
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assert(lock != NULL && "Uninitialized lock used");
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}
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void IRAM_ATTR __retarget_lock_acquire(_LOCK_T lock)
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{
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check_lock_nonzero(lock);
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MAYBE_OVERRIDE_LOCK(lock, &s_common_mutex);
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_lock_acquire(&lock);
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}
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void IRAM_ATTR __retarget_lock_acquire_recursive(_LOCK_T lock)
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{
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check_lock_nonzero(lock);
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MAYBE_OVERRIDE_LOCK(lock, &s_common_recursive_mutex);
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_lock_acquire_recursive(&lock);
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}
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int IRAM_ATTR __retarget_lock_try_acquire(_LOCK_T lock)
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{
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check_lock_nonzero(lock);
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MAYBE_OVERRIDE_LOCK(lock, &s_common_mutex);
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return _lock_try_acquire(&lock);
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}
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int IRAM_ATTR __retarget_lock_try_acquire_recursive(_LOCK_T lock)
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{
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check_lock_nonzero(lock);
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MAYBE_OVERRIDE_LOCK(lock, &s_common_recursive_mutex);
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return _lock_try_acquire_recursive(&lock);
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}
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void IRAM_ATTR __retarget_lock_release(_LOCK_T lock)
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{
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check_lock_nonzero(lock);
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_lock_release(&lock);
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}
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void IRAM_ATTR __retarget_lock_release_recursive(_LOCK_T lock)
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{
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check_lock_nonzero(lock);
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_lock_release_recursive(&lock);
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}
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/* When _RETARGETABLE_LOCKING is enabled, newlib expects the following locks to be provided: */
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extern StaticSemaphore_t __attribute__((alias("s_common_recursive_mutex"))) __lock___sinit_recursive_mutex;
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extern StaticSemaphore_t __attribute__((alias("s_common_recursive_mutex"))) __lock___malloc_recursive_mutex;
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extern StaticSemaphore_t __attribute__((alias("s_common_recursive_mutex"))) __lock___env_recursive_mutex;
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extern StaticSemaphore_t __attribute__((alias("s_common_recursive_mutex"))) __lock___sfp_recursive_mutex;
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extern StaticSemaphore_t __attribute__((alias("s_common_recursive_mutex"))) __lock___atexit_recursive_mutex;
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extern StaticSemaphore_t __attribute__((alias("s_common_mutex"))) __lock___at_quick_exit_mutex;
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extern StaticSemaphore_t __attribute__((alias("s_common_mutex"))) __lock___tz_mutex;
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extern StaticSemaphore_t __attribute__((alias("s_common_mutex"))) __lock___dd_hash_mutex;
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extern StaticSemaphore_t __attribute__((alias("s_common_mutex"))) __lock___arc4random_mutex;
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void esp_newlib_locks_init(void)
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{
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/* Initialize the two mutexes used for the locks above.
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* Asserts below check our assumption that SemaphoreHandle_t will always
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* point to the corresponding StaticSemaphore_t structure.
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*/
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SemaphoreHandle_t handle;
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handle = xSemaphoreCreateMutexStatic(&s_common_mutex);
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assert(handle == (SemaphoreHandle_t) &s_common_mutex);
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handle = xSemaphoreCreateRecursiveMutexStatic(&s_common_recursive_mutex);
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assert(handle == (SemaphoreHandle_t) &s_common_recursive_mutex);
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(void) handle;
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/* Chip ROMs are built with older versions of newlib, and rely on different lock variables.
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* Initialize these locks to the same values.
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*/
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#ifdef CONFIG_IDF_TARGET_ESP32
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/* Newlib 2.2.0 is used in ROM, the following lock symbols are defined: */
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extern _lock_t __sfp_lock;
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__sfp_lock = (_lock_t) &s_common_recursive_mutex;
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extern _lock_t __sinit_lock;
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__sinit_lock = (_lock_t) &s_common_recursive_mutex;
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extern _lock_t __env_lock_object;
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__env_lock_object = (_lock_t) &s_common_recursive_mutex;
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extern _lock_t __tz_lock_object;
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__tz_lock_object = (_lock_t) &s_common_mutex;
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#elif defined(CONFIG_IDF_TARGET_ESP32S2)
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/* Newlib 3.0.0 is used in ROM, the following lock symbols are defined: */
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extern _lock_t __sinit_recursive_mutex;
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__sinit_recursive_mutex = (_lock_t) &s_common_recursive_mutex;
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extern _lock_t __sfp_recursive_mutex;
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__sfp_recursive_mutex = (_lock_t) &s_common_recursive_mutex;
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#elif ESP_ROM_HAS_RETARGETABLE_LOCKING
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/* Newlib 3.3.0 is used in ROM, built with _RETARGETABLE_LOCKING.
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* No access to lock variables for the purpose of ECO forward compatibility,
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* however we have an API to initialize lock variables used in the ROM.
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*/
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extern void esp_rom_newlib_init_common_mutexes(_LOCK_T, _LOCK_T);
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/* See notes about ROM_NEEDS_MUTEX_OVERRIDE above */
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int magic_val = ROM_MUTEX_MAGIC;
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_LOCK_T magic_mutex = (_LOCK_T) &magic_val;
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esp_rom_newlib_init_common_mutexes(magic_mutex, magic_mutex);
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#else // other target
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#error Unsupported target
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#endif
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}
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