/* * SPDX-FileCopyrightText: 2015-2021 Espressif Systems (Shanghai) CO LTD * * SPDX-License-Identifier: Apache-2.0 */ #pragma once #include #include #include "sdkconfig.h" #include "soc/cpu.h" #include "hal/cpu_hal.h" #include "soc/compare_set.h" #if __XTENSA__ #include "xtensa/xtruntime.h" #endif #ifdef __cplusplus extern "C" { #endif #ifdef CONFIG_SPIRAM_WORKAROUND_NEED_VOLATILE_SPINLOCK #define NEED_VOLATILE_MUX volatile #else #define NEED_VOLATILE_MUX #endif #define SPINLOCK_FREE 0xB33FFFFF #define SPINLOCK_WAIT_FOREVER (-1) #define SPINLOCK_NO_WAIT 0 #define SPINLOCK_INITIALIZER {.owner = SPINLOCK_FREE,.count = 0} #define CORE_ID_REGVAL_XOR_SWAP (0xCDCD ^ 0xABAB) typedef struct { NEED_VOLATILE_MUX uint32_t owner; NEED_VOLATILE_MUX uint32_t count; }spinlock_t; /** * @brief Initialize a lock to its default state - unlocked * @param lock - spinlock object to initialize */ static inline void __attribute__((always_inline)) spinlock_initialize(spinlock_t *lock) { assert(lock); #if !CONFIG_FREERTOS_UNICORE lock->owner = SPINLOCK_FREE; lock->count = 0; #endif } /** * @brief Top level spinlock acquire function, spins until get the lock * * This function will: * - Save current interrupt state, then disable interrupts * - Spin until lock is acquired or until timeout occurs * - Restore interrupt state * * @note Spinlocks alone do no constitute true critical sections (as this * function reenables interrupts once the spinlock is acquired). For critical * sections, use the interface provided by the operating system. * @param lock - target spinlock object * @param timeout - cycles to wait, passing SPINLOCK_WAIT_FOREVER blocs indefinitely */ static inline bool __attribute__((always_inline)) spinlock_acquire(spinlock_t *lock, int32_t timeout) { #if !CONFIG_FREERTOS_UNICORE && !BOOTLOADER_BUILD uint32_t result; uint32_t irq_status; uint32_t ccount_start; uint32_t core_id, other_core_id; assert(lock); irq_status = XTOS_SET_INTLEVEL(XCHAL_EXCM_LEVEL); if(timeout != SPINLOCK_WAIT_FOREVER){ RSR(CCOUNT, ccount_start); } /*spin until we own a core */ RSR(PRID, core_id); /* Note: coreID is the full 32 bit core ID (CORE_ID_REGVAL_PRO/CORE_ID_REGVAL_APP) */ other_core_id = CORE_ID_REGVAL_XOR_SWAP ^ core_id; do { /* lock->owner should be one of SPINLOCK_FREE, CORE_ID_REGVAL_PRO, * CORE_ID_REGVAL_APP: * - If SPINLOCK_FREE, we want to atomically set to 'core_id'. * - If "our" core_id, we can drop through immediately. * - If "other_core_id", we spin here. */ result = core_id; #if (CONFIG_ESP32_SPIRAM_SUPPORT || CONFIG_ESP32S3_SPIRAM_SUPPORT) if (esp_ptr_external_ram(lock)) { compare_and_set_extram(&lock->owner, SPINLOCK_FREE, &result); } else { #endif compare_and_set_native(&lock->owner, SPINLOCK_FREE, &result); #if (CONFIG_ESP32_SPIRAM_SUPPORT || CONFIG_ESP32S3_SPIRAM_SUPPORT) } #endif if(result != other_core_id) { break; } if (timeout != SPINLOCK_WAIT_FOREVER) { uint32_t ccount_now; ccount_now = cpu_hal_get_cycle_count(); if (ccount_now - ccount_start > (unsigned)timeout) { XTOS_RESTORE_INTLEVEL(irq_status); return false; } } }while(1); /* any other value implies memory corruption or uninitialized mux */ assert(result == core_id || result == SPINLOCK_FREE); assert((result == SPINLOCK_FREE) == (lock->count == 0)); /* we're first to lock iff count is zero */ assert(lock->count < 0xFF); /* Bad count value implies memory corruption */ lock->count++; XTOS_RESTORE_INTLEVEL(irq_status); return true; #else // !CONFIG_FREERTOS_UNICORE return true; #endif } /** * @brief Top level spinlock unlock function, unlocks a previously locked spinlock * * This function will: * - Save current interrupt state, then disable interrupts * - Release the spinlock * - Restore interrupt state * * @note Spinlocks alone do no constitute true critical sections (as this * function reenables interrupts once the spinlock is acquired). For critical * sections, use the interface provided by the operating system. * @param lock - target, locked before, spinlock object */ static inline void __attribute__((always_inline)) spinlock_release(spinlock_t *lock) { #if !CONFIG_FREERTOS_UNICORE && !BOOTLOADER_BUILD uint32_t irq_status; uint32_t core_id; assert(lock); irq_status = XTOS_SET_INTLEVEL(XCHAL_EXCM_LEVEL); RSR(PRID, core_id); assert(core_id == lock->owner); // This is a mutex we didn't lock, or it's corrupt lock->count--; if(!lock->count) { lock->owner = SPINLOCK_FREE; } else { assert(lock->count < 0x100); // Indicates memory corruption } XTOS_RESTORE_INTLEVEL(irq_status); #endif } #ifdef __cplusplus } #endif