BA
/
BaBoRo_test2
Backup 1
mbed-os/platform/mbed_critical.c
- Committer:
- borlanic
- Date:
- 2018-04-24
- Revision:
- 0:02dd72d1d465
File content as of revision 0:02dd72d1d465:
/* * Copyright (c) 2015-2016, ARM Limited, All Rights Reserved * SPDX-License-Identifier: Apache-2.0 * * 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. */ /* Declare __STDC_LIMIT_MACROS so stdint.h defines UINT32_MAX when using C++ */ #define __STDC_LIMIT_MACROS #include "hal/critical_section_api.h" #include "cmsis.h" #include "platform/mbed_assert.h" #include "platform/mbed_critical.h" #include "platform/mbed_toolchain.h" // if __EXCLUSIVE_ACCESS rtx macro not defined, we need to get this via own-set architecture macros #ifndef MBED_EXCLUSIVE_ACCESS #ifndef __EXCLUSIVE_ACCESS #if ((__ARM_ARCH_7M__ == 1U) || \ (__ARM_ARCH_7EM__ == 1U) || \ (__ARM_ARCH_8M_BASE__ == 1U) || \ (__ARM_ARCH_8M_MAIN__ == 1U)) || \ (__ARM_ARCH_7A__ == 1U) #define MBED_EXCLUSIVE_ACCESS 1U #elif (__ARM_ARCH_6M__ == 1U) #define MBED_EXCLUSIVE_ACCESS 0U #else #error "Unknown architecture for exclusive access" #endif #else #define MBED_EXCLUSIVE_ACCESS __EXCLUSIVE_ACCESS #endif #endif static volatile uint32_t critical_section_reentrancy_counter = 0; bool core_util_are_interrupts_enabled(void) { #if defined(__CORTEX_A9) return ((__get_CPSR() & 0x80) == 0); #else return ((__get_PRIMASK() & 0x1) == 0); #endif } bool core_util_is_isr_active(void) { #if defined(__CORTEX_A9) switch(__get_CPSR() & 0x1FU) { case CPSR_M_USR: case CPSR_M_SYS: return false; case CPSR_M_SVC: default: return true; } #else return (__get_IPSR() != 0U); #endif } bool core_util_in_critical_section(void) { return hal_in_critical_section(); } void core_util_critical_section_enter(void) { // FIXME #ifdef FEATURE_UVISOR #warning "core_util_critical_section_enter needs fixing to work from unprivileged code" #else // If the reentrancy counter overflows something has gone badly wrong. MBED_ASSERT(critical_section_reentrancy_counter < UINT32_MAX); #endif /* FEATURE_UVISOR */ hal_critical_section_enter(); ++critical_section_reentrancy_counter; } void core_util_critical_section_exit(void) { // FIXME #ifdef FEATURE_UVISOR #warning "core_util_critical_section_exit needs fixing to work from unprivileged code" #endif /* FEATURE_UVISOR */ // If critical_section_enter has not previously been called, do nothing if (critical_section_reentrancy_counter == 0) { return; } --critical_section_reentrancy_counter; if (critical_section_reentrancy_counter == 0) { hal_critical_section_exit(); } } #if MBED_EXCLUSIVE_ACCESS /* Supress __ldrex and __strex deprecated warnings - "#3731-D: intrinsic is deprecated" */ #if defined (__CC_ARM) #pragma diag_suppress 3731 #endif bool core_util_atomic_cas_u8(volatile uint8_t *ptr, uint8_t *expectedCurrentValue, uint8_t desiredValue) { do { uint8_t currentValue = __LDREXB(ptr); if (currentValue != *expectedCurrentValue) { *expectedCurrentValue = currentValue; __CLREX(); return false; } } while (__STREXB(desiredValue, ptr)); return true; } bool core_util_atomic_cas_u16(volatile uint16_t *ptr, uint16_t *expectedCurrentValue, uint16_t desiredValue) { do { uint16_t currentValue = __LDREXH(ptr); if (currentValue != *expectedCurrentValue) { *expectedCurrentValue = currentValue; __CLREX(); return false; } } while (__STREXH(desiredValue, ptr)); return true; } bool core_util_atomic_cas_u32(volatile uint32_t *ptr, uint32_t *expectedCurrentValue, uint32_t desiredValue) { do { uint32_t currentValue = __LDREXW(ptr); if (currentValue != *expectedCurrentValue) { *expectedCurrentValue = currentValue; __CLREX(); return false; } } while (__STREXW(desiredValue, ptr)); return true; } uint8_t core_util_atomic_incr_u8(volatile uint8_t *valuePtr, uint8_t delta) { uint8_t newValue; do { newValue = __LDREXB(valuePtr) + delta; } while (__STREXB(newValue, valuePtr)); return newValue; } uint16_t core_util_atomic_incr_u16(volatile uint16_t *valuePtr, uint16_t delta) { uint16_t newValue; do { newValue = __LDREXH(valuePtr) + delta; } while (__STREXH(newValue, valuePtr)); return newValue; } uint32_t core_util_atomic_incr_u32(volatile uint32_t *valuePtr, uint32_t delta) { uint32_t newValue; do { newValue = __LDREXW(valuePtr) + delta; } while (__STREXW(newValue, valuePtr)); return newValue; } uint8_t core_util_atomic_decr_u8(volatile uint8_t *valuePtr, uint8_t delta) { uint8_t newValue; do { newValue = __LDREXB(valuePtr) - delta; } while (__STREXB(newValue, valuePtr)); return newValue; } uint16_t core_util_atomic_decr_u16(volatile uint16_t *valuePtr, uint16_t delta) { uint16_t newValue; do { newValue = __LDREXH(valuePtr) - delta; } while (__STREXH(newValue, valuePtr)); return newValue; } uint32_t core_util_atomic_decr_u32(volatile uint32_t *valuePtr, uint32_t delta) { uint32_t newValue; do { newValue = __LDREXW(valuePtr) - delta; } while (__STREXW(newValue, valuePtr)); return newValue; } #else bool core_util_atomic_cas_u8(volatile uint8_t *ptr, uint8_t *expectedCurrentValue, uint8_t desiredValue) { bool success; uint8_t currentValue; core_util_critical_section_enter(); currentValue = *ptr; if (currentValue == *expectedCurrentValue) { *ptr = desiredValue; success = true; } else { *expectedCurrentValue = currentValue; success = false; } core_util_critical_section_exit(); return success; } bool core_util_atomic_cas_u16(volatile uint16_t *ptr, uint16_t *expectedCurrentValue, uint16_t desiredValue) { bool success; uint16_t currentValue; core_util_critical_section_enter(); currentValue = *ptr; if (currentValue == *expectedCurrentValue) { *ptr = desiredValue; success = true; } else { *expectedCurrentValue = currentValue; success = false; } core_util_critical_section_exit(); return success; } bool core_util_atomic_cas_u32(volatile uint32_t *ptr, uint32_t *expectedCurrentValue, uint32_t desiredValue) { bool success; uint32_t currentValue; core_util_critical_section_enter(); currentValue = *ptr; if (currentValue == *expectedCurrentValue) { *ptr = desiredValue; success = true; } else { *expectedCurrentValue = currentValue; success = false; } core_util_critical_section_exit(); return success; } uint8_t core_util_atomic_incr_u8(volatile uint8_t *valuePtr, uint8_t delta) { uint8_t newValue; core_util_critical_section_enter(); newValue = *valuePtr + delta; *valuePtr = newValue; core_util_critical_section_exit(); return newValue; } uint16_t core_util_atomic_incr_u16(volatile uint16_t *valuePtr, uint16_t delta) { uint16_t newValue; core_util_critical_section_enter(); newValue = *valuePtr + delta; *valuePtr = newValue; core_util_critical_section_exit(); return newValue; } uint32_t core_util_atomic_incr_u32(volatile uint32_t *valuePtr, uint32_t delta) { uint32_t newValue; core_util_critical_section_enter(); newValue = *valuePtr + delta; *valuePtr = newValue; core_util_critical_section_exit(); return newValue; } uint8_t core_util_atomic_decr_u8(volatile uint8_t *valuePtr, uint8_t delta) { uint8_t newValue; core_util_critical_section_enter(); newValue = *valuePtr - delta; *valuePtr = newValue; core_util_critical_section_exit(); return newValue; } uint16_t core_util_atomic_decr_u16(volatile uint16_t *valuePtr, uint16_t delta) { uint16_t newValue; core_util_critical_section_enter(); newValue = *valuePtr - delta; *valuePtr = newValue; core_util_critical_section_exit(); return newValue; } uint32_t core_util_atomic_decr_u32(volatile uint32_t *valuePtr, uint32_t delta) { uint32_t newValue; core_util_critical_section_enter(); newValue = *valuePtr - delta; *valuePtr = newValue; core_util_critical_section_exit(); return newValue; } #endif bool core_util_atomic_cas_ptr(void * volatile *ptr, void **expectedCurrentValue, void *desiredValue) { return core_util_atomic_cas_u32( (volatile uint32_t *)ptr, (uint32_t *)expectedCurrentValue, (uint32_t)desiredValue); } void *core_util_atomic_incr_ptr(void * volatile *valuePtr, ptrdiff_t delta) { return (void *)core_util_atomic_incr_u32((volatile uint32_t *)valuePtr, (uint32_t)delta); } void *core_util_atomic_decr_ptr(void * volatile *valuePtr, ptrdiff_t delta) { return (void *)core_util_atomic_decr_u32((volatile uint32_t *)valuePtr, (uint32_t)delta); }