esp-idf/components/newlib/stdatomic.c

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// Copyright 2015-2021 Espressif Systems (Shanghai) PTE LTD
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//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//replacement for gcc built-in functions
#include "sdkconfig.h"
#include <stdbool.h>
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#include <stdint.h>
#include "soc/soc_caps.h"
#include "freertos/FreeRTOS.h"
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#ifdef __XTENSA__
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#include "xtensa/config/core-isa.h"
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#ifndef XCHAL_HAVE_S32C1I
#error "XCHAL_HAVE_S32C1I not defined, include correct header!"
#endif
#define HAS_ATOMICS_32 (XCHAL_HAVE_S32C1I == 1)
// no 64-bit atomics on Xtensa
#define HAS_ATOMICS_64 0
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#else // RISCV
// GCC toolchain will define this pre-processor if "A" extension is supported
#ifndef __riscv_atomic
#define __riscv_atomic 0
#endif
#define HAS_ATOMICS_32 (__riscv_atomic == 1)
#define HAS_ATOMICS_64 ((__riscv_atomic == 1) && (__riscv_xlen == 64))
#endif // (__XTENSA__, __riscv)
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#if SOC_CPU_CORES_NUM == 1
// Single core SoC: atomics can be implemented using portENTER_CRITICAL_NESTED
// and portEXIT_CRITICAL_NESTED, which disable and enable interrupts.
#define _ATOMIC_ENTER_CRITICAL() ({ \
unsigned state = portENTER_CRITICAL_NESTED(); \
state; \
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})
#define _ATOMIC_EXIT_CRITICAL(state) do { \
portEXIT_CRITICAL_NESTED(state); \
} while (0)
#else // SOC_CPU_CORES_NUM
_Static_assert(HAS_ATOMICS_32, "32-bit atomics should be supported if SOC_CPU_CORES_NUM > 1");
// Only need to implement 64-bit atomics here. Use a single global portMUX_TYPE spinlock
// to emulate the atomics.
static portMUX_TYPE s_atomic_lock = portMUX_INITIALIZER_UNLOCKED;
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// Return value is not used but kept for compatibility with the single-core version above.
#define _ATOMIC_ENTER_CRITICAL() ({ \
portENTER_CRITICAL_SAFE(&s_atomic_lock); \
0; \
})
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#define _ATOMIC_EXIT_CRITICAL(state) do { \
(void) (state); \
portEXIT_CRITICAL_SAFE(&s_atomic_lock); \
} while(0)
#endif // SOC_CPU_CORES_NUM
#define ATOMIC_LOAD(n, type) type __atomic_load_ ## n (const type* mem, int memorder) \
{ \
unsigned state = _ATOMIC_ENTER_CRITICAL(); \
type ret = *mem; \
_ATOMIC_EXIT_CRITICAL(state); \
return ret; \
}
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#define ATOMIC_STORE(n, type) void __atomic_store_ ## n (type* mem, type val, int memorder) \
{ \
unsigned state = _ATOMIC_ENTER_CRITICAL(); \
*mem = val; \
_ATOMIC_EXIT_CRITICAL(state); \
}
#define ATOMIC_EXCHANGE(n, type) type __atomic_exchange_ ## n (type* mem, type val, int memorder) \
{ \
unsigned state = _ATOMIC_ENTER_CRITICAL(); \
type ret = *mem; \
*mem = val; \
_ATOMIC_EXIT_CRITICAL(state); \
return ret; \
}
#define CMP_EXCHANGE(n, type) bool __atomic_compare_exchange_ ## n (type* mem, type* expect, type desired, bool weak, int success, int failure) \
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{ \
bool ret = false; \
unsigned state = _ATOMIC_ENTER_CRITICAL(); \
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if (*mem == *expect) { \
ret = true; \
*mem = desired; \
} else { \
*expect = *mem; \
} \
_ATOMIC_EXIT_CRITICAL(state); \
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return ret; \
}
#define FETCH_ADD(n, type) type __atomic_fetch_add_ ## n (type* ptr, type value, int memorder) \
{ \
unsigned state = _ATOMIC_ENTER_CRITICAL(); \
type ret = *ptr; \
*ptr = *ptr + value; \
_ATOMIC_EXIT_CRITICAL(state); \
return ret; \
}
#define FETCH_SUB(n, type) type __atomic_fetch_sub_ ## n (type* ptr, type value, int memorder) \
{ \
unsigned state = _ATOMIC_ENTER_CRITICAL(); \
type ret = *ptr; \
*ptr = *ptr - value; \
_ATOMIC_EXIT_CRITICAL(state); \
return ret; \
}
#define FETCH_AND(n, type) type __atomic_fetch_and_ ## n (type* ptr, type value, int memorder) \
{ \
unsigned state = _ATOMIC_ENTER_CRITICAL(); \
type ret = *ptr; \
*ptr = *ptr & value; \
_ATOMIC_EXIT_CRITICAL(state); \
return ret; \
}
#define FETCH_OR(n, type) type __atomic_fetch_or_ ## n (type* ptr, type value, int memorder) \
{ \
unsigned state = _ATOMIC_ENTER_CRITICAL(); \
type ret = *ptr; \
*ptr = *ptr | value; \
_ATOMIC_EXIT_CRITICAL(state); \
return ret; \
}
#define FETCH_XOR(n, type) type __atomic_fetch_xor_ ## n (type* ptr, type value, int memorder) \
{ \
unsigned state = _ATOMIC_ENTER_CRITICAL(); \
type ret = *ptr; \
*ptr = *ptr ^ value; \
_ATOMIC_EXIT_CRITICAL(state); \
return ret; \
}
#define SYNC_FETCH_OP(op, n, type) type __sync_fetch_and_ ## op ##_ ## n (type* ptr, type value) \
{ \
return __atomic_fetch_ ## op ##_ ## n (ptr, value, __ATOMIC_SEQ_CST); \
}
#define SYNC_BOOL_CMP_EXCHANGE(n, type) bool __sync_bool_compare_and_swap_ ## n (type *ptr, type oldval, type newval) \
{ \
bool ret = false; \
unsigned state = _ATOMIC_ENTER_CRITICAL(); \
if (*ptr == oldval) { \
*ptr = newval; \
ret = true; \
} \
_ATOMIC_EXIT_CRITICAL(state); \
return ret; \
}
#define SYNC_VAL_CMP_EXCHANGE(n, type) type __sync_val_compare_and_swap_ ## n (type *ptr, type oldval, type newval) \
{ \
unsigned state = _ATOMIC_ENTER_CRITICAL(); \
type ret = *ptr; \
if (*ptr == oldval) { \
*ptr = newval; \
} \
_ATOMIC_EXIT_CRITICAL(state); \
return ret; \
}
#if !HAS_ATOMICS_32
ATOMIC_EXCHANGE(1, uint8_t)
ATOMIC_EXCHANGE(2, uint16_t)
ATOMIC_EXCHANGE(4, uint32_t)
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CMP_EXCHANGE(1, uint8_t)
CMP_EXCHANGE(2, uint16_t)
CMP_EXCHANGE(4, uint32_t)
FETCH_ADD(1, uint8_t)
FETCH_ADD(2, uint16_t)
FETCH_ADD(4, uint32_t)
FETCH_SUB(1, uint8_t)
FETCH_SUB(2, uint16_t)
FETCH_SUB(4, uint32_t)
FETCH_AND(1, uint8_t)
FETCH_AND(2, uint16_t)
FETCH_AND(4, uint32_t)
FETCH_OR(1, uint8_t)
FETCH_OR(2, uint16_t)
FETCH_OR(4, uint32_t)
FETCH_XOR(1, uint8_t)
FETCH_XOR(2, uint16_t)
FETCH_XOR(4, uint32_t)
SYNC_FETCH_OP(add, 1, uint8_t)
SYNC_FETCH_OP(add, 2, uint16_t)
SYNC_FETCH_OP(add, 4, uint32_t)
SYNC_FETCH_OP(sub, 1, uint8_t)
SYNC_FETCH_OP(sub, 2, uint16_t)
SYNC_FETCH_OP(sub, 4, uint32_t)
SYNC_FETCH_OP(and, 1, uint8_t)
SYNC_FETCH_OP(and, 2, uint16_t)
SYNC_FETCH_OP(and, 4, uint32_t)
SYNC_FETCH_OP(or, 1, uint8_t)
SYNC_FETCH_OP(or, 2, uint16_t)
SYNC_FETCH_OP(or, 4, uint32_t)
SYNC_FETCH_OP(xor, 1, uint8_t)
SYNC_FETCH_OP(xor, 2, uint16_t)
SYNC_FETCH_OP(xor, 4, uint32_t)
SYNC_BOOL_CMP_EXCHANGE(1, uint8_t)
SYNC_BOOL_CMP_EXCHANGE(2, uint16_t)
SYNC_BOOL_CMP_EXCHANGE(4, uint32_t)
SYNC_VAL_CMP_EXCHANGE(1, uint8_t)
SYNC_VAL_CMP_EXCHANGE(2, uint16_t)
SYNC_VAL_CMP_EXCHANGE(4, uint32_t)
#endif // !HAS_ATOMICS_32
#if !HAS_ATOMICS_64
ATOMIC_LOAD(8, uint64_t)
ATOMIC_STORE(8, uint64_t)
ATOMIC_EXCHANGE(8, uint64_t)
CMP_EXCHANGE(8, uint64_t)
FETCH_ADD(8, uint64_t)
FETCH_SUB(8, uint64_t)
FETCH_AND(8, uint64_t)
FETCH_OR(8, uint64_t)
FETCH_XOR(8, uint64_t)
SYNC_FETCH_OP(add, 8, uint64_t)
SYNC_FETCH_OP(sub, 8, uint64_t)
SYNC_FETCH_OP(and, 8, uint64_t)
SYNC_FETCH_OP(or, 8, uint64_t)
SYNC_FETCH_OP(xor, 8, uint64_t)
SYNC_BOOL_CMP_EXCHANGE(8, uint64_t)
SYNC_VAL_CMP_EXCHANGE(8, uint64_t)
#endif // !HAS_ATOMICS_64