Daiki Kato
mbed-os for GR-LYCHEE
Dependents: mbed-os-example-blinky-gr-lychee GR-Boads_Camera_sample GR-Boards_Audio_Recoder GR-Boads_Camera_DisplayApp ... more
platform/mbed_critical.c@0:f782d9c66c49, 2018-02-02 (annotated)
- Committer:
- dkato
- Date:
- Fri Feb 02 05:42:23 2018 +0000
- Revision:
- 0:f782d9c66c49
mbed-os for GR-LYCHEE
Who changed what in which revision?
| User | Revision | Line number | New contents of line |
|---|---|---|---|
| dkato | 0:f782d9c66c49 | 1 | /* |
| dkato | 0:f782d9c66c49 | 2 | * Copyright (c) 2015-2016, ARM Limited, All Rights Reserved |
| dkato | 0:f782d9c66c49 | 3 | * SPDX-License-Identifier: Apache-2.0 |
| dkato | 0:f782d9c66c49 | 4 | * |
| dkato | 0:f782d9c66c49 | 5 | * Licensed under the Apache License, Version 2.0 (the "License"); you may |
| dkato | 0:f782d9c66c49 | 6 | * not use this file except in compliance with the License. |
| dkato | 0:f782d9c66c49 | 7 | * You may obtain a copy of the License at |
| dkato | 0:f782d9c66c49 | 8 | * |
| dkato | 0:f782d9c66c49 | 9 | * http://www.apache.org/licenses/LICENSE-2.0 |
| dkato | 0:f782d9c66c49 | 10 | * |
| dkato | 0:f782d9c66c49 | 11 | * Unless required by applicable law or agreed to in writing, software |
| dkato | 0:f782d9c66c49 | 12 | * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT |
| dkato | 0:f782d9c66c49 | 13 | * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
| dkato | 0:f782d9c66c49 | 14 | * See the License for the specific language governing permissions and |
| dkato | 0:f782d9c66c49 | 15 | * limitations under the License. |
| dkato | 0:f782d9c66c49 | 16 | */ |
| dkato | 0:f782d9c66c49 | 17 | |
| dkato | 0:f782d9c66c49 | 18 | /* Declare __STDC_LIMIT_MACROS so stdint.h defines UINT32_MAX when using C++ */ |
| dkato | 0:f782d9c66c49 | 19 | #define __STDC_LIMIT_MACROS |
| dkato | 0:f782d9c66c49 | 20 | #include "platform/mbed_critical.h" |
| dkato | 0:f782d9c66c49 | 21 | |
| dkato | 0:f782d9c66c49 | 22 | #include "cmsis.h" |
| dkato | 0:f782d9c66c49 | 23 | #include "platform/mbed_assert.h" |
| dkato | 0:f782d9c66c49 | 24 | #include "platform/mbed_toolchain.h" |
| dkato | 0:f782d9c66c49 | 25 | |
| dkato | 0:f782d9c66c49 | 26 | #define EXCLUSIVE_ACCESS (!defined (__CORTEX_M0) && !defined (__CORTEX_M0PLUS)) |
| dkato | 0:f782d9c66c49 | 27 | |
| dkato | 0:f782d9c66c49 | 28 | static volatile uint32_t interrupt_enable_counter = 0; |
| dkato | 0:f782d9c66c49 | 29 | static volatile bool critical_interrupts_disabled = false; |
| dkato | 0:f782d9c66c49 | 30 | |
| dkato | 0:f782d9c66c49 | 31 | bool core_util_are_interrupts_enabled(void) |
| dkato | 0:f782d9c66c49 | 32 | { |
| dkato | 0:f782d9c66c49 | 33 | #if defined(__CORTEX_A9) |
| dkato | 0:f782d9c66c49 | 34 | return ((__get_CPSR() & 0x80) == 0); |
| dkato | 0:f782d9c66c49 | 35 | #else |
| dkato | 0:f782d9c66c49 | 36 | return ((__get_PRIMASK() & 0x1) == 0); |
| dkato | 0:f782d9c66c49 | 37 | #endif |
| dkato | 0:f782d9c66c49 | 38 | } |
| dkato | 0:f782d9c66c49 | 39 | |
| dkato | 0:f782d9c66c49 | 40 | MBED_WEAK void core_util_critical_section_enter(void) |
| dkato | 0:f782d9c66c49 | 41 | { |
| dkato | 0:f782d9c66c49 | 42 | bool interrupts_disabled = !core_util_are_interrupts_enabled(); |
| dkato | 0:f782d9c66c49 | 43 | __disable_irq(); |
| dkato | 0:f782d9c66c49 | 44 | |
| dkato | 0:f782d9c66c49 | 45 | /* Save the interrupt disabled state as it was prior to any nested critical section lock use */ |
| dkato | 0:f782d9c66c49 | 46 | if (!interrupt_enable_counter) { |
| dkato | 0:f782d9c66c49 | 47 | critical_interrupts_disabled = interrupts_disabled; |
| dkato | 0:f782d9c66c49 | 48 | } |
| dkato | 0:f782d9c66c49 | 49 | |
| dkato | 0:f782d9c66c49 | 50 | /* If the interrupt_enable_counter overflows or we are in a nested critical section and interrupts |
| dkato | 0:f782d9c66c49 | 51 | are enabled, then something has gone badly wrong thus assert an error. |
| dkato | 0:f782d9c66c49 | 52 | */ |
| dkato | 0:f782d9c66c49 | 53 | MBED_ASSERT(interrupt_enable_counter < UINT32_MAX); |
| dkato | 0:f782d9c66c49 | 54 | // FIXME |
| dkato | 0:f782d9c66c49 | 55 | #ifndef FEATURE_UVISOR |
| dkato | 0:f782d9c66c49 | 56 | if (interrupt_enable_counter > 0) { |
| dkato | 0:f782d9c66c49 | 57 | MBED_ASSERT(interrupts_disabled); |
| dkato | 0:f782d9c66c49 | 58 | } |
| dkato | 0:f782d9c66c49 | 59 | #else |
| dkato | 0:f782d9c66c49 | 60 | #warning "core_util_critical_section_enter needs fixing to work from unprivileged code" |
| dkato | 0:f782d9c66c49 | 61 | #endif /* FEATURE_UVISOR */ |
| dkato | 0:f782d9c66c49 | 62 | interrupt_enable_counter++; |
| dkato | 0:f782d9c66c49 | 63 | } |
| dkato | 0:f782d9c66c49 | 64 | |
| dkato | 0:f782d9c66c49 | 65 | MBED_WEAK void core_util_critical_section_exit(void) |
| dkato | 0:f782d9c66c49 | 66 | { |
| dkato | 0:f782d9c66c49 | 67 | /* If critical_section_enter has not previously been called, do nothing */ |
| dkato | 0:f782d9c66c49 | 68 | if (interrupt_enable_counter) { |
| dkato | 0:f782d9c66c49 | 69 | |
| dkato | 0:f782d9c66c49 | 70 | // FIXME |
| dkato | 0:f782d9c66c49 | 71 | #ifndef FEATURE_UVISOR |
| dkato | 0:f782d9c66c49 | 72 | bool interrupts_disabled = !core_util_are_interrupts_enabled(); /* get the current interrupt disabled state */ |
| dkato | 0:f782d9c66c49 | 73 | |
| dkato | 0:f782d9c66c49 | 74 | MBED_ASSERT(interrupts_disabled); /* Interrupts must be disabled on invoking an exit from a critical section */ |
| dkato | 0:f782d9c66c49 | 75 | #else |
| dkato | 0:f782d9c66c49 | 76 | #warning "core_util_critical_section_exit needs fixing to work from unprivileged code" |
| dkato | 0:f782d9c66c49 | 77 | #endif /* FEATURE_UVISOR */ |
| dkato | 0:f782d9c66c49 | 78 | |
| dkato | 0:f782d9c66c49 | 79 | interrupt_enable_counter--; |
| dkato | 0:f782d9c66c49 | 80 | |
| dkato | 0:f782d9c66c49 | 81 | /* Only re-enable interrupts if we are exiting the last of the nested critical sections and |
| dkato | 0:f782d9c66c49 | 82 | interrupts were enabled on entry to the first critical section. |
| dkato | 0:f782d9c66c49 | 83 | */ |
| dkato | 0:f782d9c66c49 | 84 | if (!interrupt_enable_counter && !critical_interrupts_disabled) { |
| dkato | 0:f782d9c66c49 | 85 | __enable_irq(); |
| dkato | 0:f782d9c66c49 | 86 | } |
| dkato | 0:f782d9c66c49 | 87 | } |
| dkato | 0:f782d9c66c49 | 88 | } |
| dkato | 0:f782d9c66c49 | 89 | |
| dkato | 0:f782d9c66c49 | 90 | #if EXCLUSIVE_ACCESS |
| dkato | 0:f782d9c66c49 | 91 | |
| dkato | 0:f782d9c66c49 | 92 | /* Supress __ldrex and __strex deprecated warnings - "#3731-D: intrinsic is deprecated" */ |
| dkato | 0:f782d9c66c49 | 93 | #if defined (__CC_ARM) |
| dkato | 0:f782d9c66c49 | 94 | #pragma diag_suppress 3731 |
| dkato | 0:f782d9c66c49 | 95 | #endif |
| dkato | 0:f782d9c66c49 | 96 | |
| dkato | 0:f782d9c66c49 | 97 | bool core_util_atomic_cas_u8(uint8_t *ptr, uint8_t *expectedCurrentValue, uint8_t desiredValue) |
| dkato | 0:f782d9c66c49 | 98 | { |
| dkato | 0:f782d9c66c49 | 99 | uint8_t currentValue = __LDREXB((volatile uint8_t*)ptr); |
| dkato | 0:f782d9c66c49 | 100 | if (currentValue != *expectedCurrentValue) { |
| dkato | 0:f782d9c66c49 | 101 | *expectedCurrentValue = currentValue; |
| dkato | 0:f782d9c66c49 | 102 | __CLREX(); |
| dkato | 0:f782d9c66c49 | 103 | return false; |
| dkato | 0:f782d9c66c49 | 104 | } |
| dkato | 0:f782d9c66c49 | 105 | |
| dkato | 0:f782d9c66c49 | 106 | return !__STREXB(desiredValue, (volatile uint8_t*)ptr); |
| dkato | 0:f782d9c66c49 | 107 | } |
| dkato | 0:f782d9c66c49 | 108 | |
| dkato | 0:f782d9c66c49 | 109 | bool core_util_atomic_cas_u16(uint16_t *ptr, uint16_t *expectedCurrentValue, uint16_t desiredValue) |
| dkato | 0:f782d9c66c49 | 110 | { |
| dkato | 0:f782d9c66c49 | 111 | uint16_t currentValue = __LDREXH((volatile uint16_t*)ptr); |
| dkato | 0:f782d9c66c49 | 112 | if (currentValue != *expectedCurrentValue) { |
| dkato | 0:f782d9c66c49 | 113 | *expectedCurrentValue = currentValue; |
| dkato | 0:f782d9c66c49 | 114 | __CLREX(); |
| dkato | 0:f782d9c66c49 | 115 | return false; |
| dkato | 0:f782d9c66c49 | 116 | } |
| dkato | 0:f782d9c66c49 | 117 | |
| dkato | 0:f782d9c66c49 | 118 | return !__STREXH(desiredValue, (volatile uint16_t*)ptr); |
| dkato | 0:f782d9c66c49 | 119 | } |
| dkato | 0:f782d9c66c49 | 120 | |
| dkato | 0:f782d9c66c49 | 121 | |
| dkato | 0:f782d9c66c49 | 122 | bool core_util_atomic_cas_u32(uint32_t *ptr, uint32_t *expectedCurrentValue, uint32_t desiredValue) |
| dkato | 0:f782d9c66c49 | 123 | { |
| dkato | 0:f782d9c66c49 | 124 | uint32_t currentValue = __LDREXW((volatile uint32_t*)ptr); |
| dkato | 0:f782d9c66c49 | 125 | if (currentValue != *expectedCurrentValue) { |
| dkato | 0:f782d9c66c49 | 126 | *expectedCurrentValue = currentValue; |
| dkato | 0:f782d9c66c49 | 127 | __CLREX(); |
| dkato | 0:f782d9c66c49 | 128 | return false; |
| dkato | 0:f782d9c66c49 | 129 | } |
| dkato | 0:f782d9c66c49 | 130 | |
| dkato | 0:f782d9c66c49 | 131 | return !__STREXW(desiredValue, (volatile uint32_t*)ptr); |
| dkato | 0:f782d9c66c49 | 132 | } |
| dkato | 0:f782d9c66c49 | 133 | |
| dkato | 0:f782d9c66c49 | 134 | uint8_t core_util_atomic_incr_u8(uint8_t *valuePtr, uint8_t delta) |
| dkato | 0:f782d9c66c49 | 135 | { |
| dkato | 0:f782d9c66c49 | 136 | uint8_t newValue; |
| dkato | 0:f782d9c66c49 | 137 | do { |
| dkato | 0:f782d9c66c49 | 138 | newValue = __LDREXB((volatile uint8_t*)valuePtr) + delta; |
| dkato | 0:f782d9c66c49 | 139 | } while (__STREXB(newValue, (volatile uint8_t*)valuePtr)); |
| dkato | 0:f782d9c66c49 | 140 | return newValue; |
| dkato | 0:f782d9c66c49 | 141 | } |
| dkato | 0:f782d9c66c49 | 142 | |
| dkato | 0:f782d9c66c49 | 143 | uint16_t core_util_atomic_incr_u16(uint16_t *valuePtr, uint16_t delta) |
| dkato | 0:f782d9c66c49 | 144 | { |
| dkato | 0:f782d9c66c49 | 145 | uint16_t newValue; |
| dkato | 0:f782d9c66c49 | 146 | do { |
| dkato | 0:f782d9c66c49 | 147 | newValue = __LDREXH((volatile uint16_t*)valuePtr) + delta; |
| dkato | 0:f782d9c66c49 | 148 | } while (__STREXH(newValue, (volatile uint16_t*)valuePtr)); |
| dkato | 0:f782d9c66c49 | 149 | return newValue; |
| dkato | 0:f782d9c66c49 | 150 | } |
| dkato | 0:f782d9c66c49 | 151 | |
| dkato | 0:f782d9c66c49 | 152 | uint32_t core_util_atomic_incr_u32(uint32_t *valuePtr, uint32_t delta) |
| dkato | 0:f782d9c66c49 | 153 | { |
| dkato | 0:f782d9c66c49 | 154 | uint32_t newValue; |
| dkato | 0:f782d9c66c49 | 155 | do { |
| dkato | 0:f782d9c66c49 | 156 | newValue = __LDREXW((volatile uint32_t*)valuePtr) + delta; |
| dkato | 0:f782d9c66c49 | 157 | } while (__STREXW(newValue, (volatile uint32_t*)valuePtr)); |
| dkato | 0:f782d9c66c49 | 158 | return newValue; |
| dkato | 0:f782d9c66c49 | 159 | } |
| dkato | 0:f782d9c66c49 | 160 | |
| dkato | 0:f782d9c66c49 | 161 | |
| dkato | 0:f782d9c66c49 | 162 | uint8_t core_util_atomic_decr_u8(uint8_t *valuePtr, uint8_t delta) |
| dkato | 0:f782d9c66c49 | 163 | { |
| dkato | 0:f782d9c66c49 | 164 | uint8_t newValue; |
| dkato | 0:f782d9c66c49 | 165 | do { |
| dkato | 0:f782d9c66c49 | 166 | newValue = __LDREXB((volatile uint8_t*)valuePtr) - delta; |
| dkato | 0:f782d9c66c49 | 167 | } while (__STREXB(newValue, (volatile uint8_t*)valuePtr)); |
| dkato | 0:f782d9c66c49 | 168 | return newValue; |
| dkato | 0:f782d9c66c49 | 169 | } |
| dkato | 0:f782d9c66c49 | 170 | |
| dkato | 0:f782d9c66c49 | 171 | uint16_t core_util_atomic_decr_u16(uint16_t *valuePtr, uint16_t delta) |
| dkato | 0:f782d9c66c49 | 172 | { |
| dkato | 0:f782d9c66c49 | 173 | uint16_t newValue; |
| dkato | 0:f782d9c66c49 | 174 | do { |
| dkato | 0:f782d9c66c49 | 175 | newValue = __LDREXH((volatile uint16_t*)valuePtr) - delta; |
| dkato | 0:f782d9c66c49 | 176 | } while (__STREXH(newValue, (volatile uint16_t*)valuePtr)); |
| dkato | 0:f782d9c66c49 | 177 | return newValue; |
| dkato | 0:f782d9c66c49 | 178 | } |
| dkato | 0:f782d9c66c49 | 179 | |
| dkato | 0:f782d9c66c49 | 180 | uint32_t core_util_atomic_decr_u32(uint32_t *valuePtr, uint32_t delta) |
| dkato | 0:f782d9c66c49 | 181 | { |
| dkato | 0:f782d9c66c49 | 182 | uint32_t newValue; |
| dkato | 0:f782d9c66c49 | 183 | do { |
| dkato | 0:f782d9c66c49 | 184 | newValue = __LDREXW((volatile uint32_t*)valuePtr) - delta; |
| dkato | 0:f782d9c66c49 | 185 | } while (__STREXW(newValue, (volatile uint32_t*)valuePtr)); |
| dkato | 0:f782d9c66c49 | 186 | return newValue; |
| dkato | 0:f782d9c66c49 | 187 | } |
| dkato | 0:f782d9c66c49 | 188 | |
| dkato | 0:f782d9c66c49 | 189 | #else |
| dkato | 0:f782d9c66c49 | 190 | |
| dkato | 0:f782d9c66c49 | 191 | bool core_util_atomic_cas_u8(uint8_t *ptr, uint8_t *expectedCurrentValue, uint8_t desiredValue) |
| dkato | 0:f782d9c66c49 | 192 | { |
| dkato | 0:f782d9c66c49 | 193 | bool success; |
| dkato | 0:f782d9c66c49 | 194 | uint8_t currentValue; |
| dkato | 0:f782d9c66c49 | 195 | core_util_critical_section_enter(); |
| dkato | 0:f782d9c66c49 | 196 | currentValue = *ptr; |
| dkato | 0:f782d9c66c49 | 197 | if (currentValue == *expectedCurrentValue) { |
| dkato | 0:f782d9c66c49 | 198 | *ptr = desiredValue; |
| dkato | 0:f782d9c66c49 | 199 | success = true; |
| dkato | 0:f782d9c66c49 | 200 | } else { |
| dkato | 0:f782d9c66c49 | 201 | *expectedCurrentValue = currentValue; |
| dkato | 0:f782d9c66c49 | 202 | success = false; |
| dkato | 0:f782d9c66c49 | 203 | } |
| dkato | 0:f782d9c66c49 | 204 | core_util_critical_section_exit(); |
| dkato | 0:f782d9c66c49 | 205 | return success; |
| dkato | 0:f782d9c66c49 | 206 | } |
| dkato | 0:f782d9c66c49 | 207 | |
| dkato | 0:f782d9c66c49 | 208 | bool core_util_atomic_cas_u16(uint16_t *ptr, uint16_t *expectedCurrentValue, uint16_t desiredValue) |
| dkato | 0:f782d9c66c49 | 209 | { |
| dkato | 0:f782d9c66c49 | 210 | bool success; |
| dkato | 0:f782d9c66c49 | 211 | uint16_t currentValue; |
| dkato | 0:f782d9c66c49 | 212 | core_util_critical_section_enter(); |
| dkato | 0:f782d9c66c49 | 213 | currentValue = *ptr; |
| dkato | 0:f782d9c66c49 | 214 | if (currentValue == *expectedCurrentValue) { |
| dkato | 0:f782d9c66c49 | 215 | *ptr = desiredValue; |
| dkato | 0:f782d9c66c49 | 216 | success = true; |
| dkato | 0:f782d9c66c49 | 217 | } else { |
| dkato | 0:f782d9c66c49 | 218 | *expectedCurrentValue = currentValue; |
| dkato | 0:f782d9c66c49 | 219 | success = false; |
| dkato | 0:f782d9c66c49 | 220 | } |
| dkato | 0:f782d9c66c49 | 221 | core_util_critical_section_exit(); |
| dkato | 0:f782d9c66c49 | 222 | return success; |
| dkato | 0:f782d9c66c49 | 223 | } |
| dkato | 0:f782d9c66c49 | 224 | |
| dkato | 0:f782d9c66c49 | 225 | |
| dkato | 0:f782d9c66c49 | 226 | bool core_util_atomic_cas_u32(uint32_t *ptr, uint32_t *expectedCurrentValue, uint32_t desiredValue) |
| dkato | 0:f782d9c66c49 | 227 | { |
| dkato | 0:f782d9c66c49 | 228 | bool success; |
| dkato | 0:f782d9c66c49 | 229 | uint32_t currentValue; |
| dkato | 0:f782d9c66c49 | 230 | core_util_critical_section_enter(); |
| dkato | 0:f782d9c66c49 | 231 | currentValue = *ptr; |
| dkato | 0:f782d9c66c49 | 232 | if (currentValue == *expectedCurrentValue) { |
| dkato | 0:f782d9c66c49 | 233 | *ptr = desiredValue; |
| dkato | 0:f782d9c66c49 | 234 | success = true; |
| dkato | 0:f782d9c66c49 | 235 | } else { |
| dkato | 0:f782d9c66c49 | 236 | *expectedCurrentValue = currentValue; |
| dkato | 0:f782d9c66c49 | 237 | success = false; |
| dkato | 0:f782d9c66c49 | 238 | } |
| dkato | 0:f782d9c66c49 | 239 | core_util_critical_section_exit(); |
| dkato | 0:f782d9c66c49 | 240 | return success; |
| dkato | 0:f782d9c66c49 | 241 | } |
| dkato | 0:f782d9c66c49 | 242 | |
| dkato | 0:f782d9c66c49 | 243 | |
| dkato | 0:f782d9c66c49 | 244 | uint8_t core_util_atomic_incr_u8(uint8_t *valuePtr, uint8_t delta) |
| dkato | 0:f782d9c66c49 | 245 | { |
| dkato | 0:f782d9c66c49 | 246 | uint8_t newValue; |
| dkato | 0:f782d9c66c49 | 247 | core_util_critical_section_enter(); |
| dkato | 0:f782d9c66c49 | 248 | newValue = *valuePtr + delta; |
| dkato | 0:f782d9c66c49 | 249 | *valuePtr = newValue; |
| dkato | 0:f782d9c66c49 | 250 | core_util_critical_section_exit(); |
| dkato | 0:f782d9c66c49 | 251 | return newValue; |
| dkato | 0:f782d9c66c49 | 252 | } |
| dkato | 0:f782d9c66c49 | 253 | |
| dkato | 0:f782d9c66c49 | 254 | uint16_t core_util_atomic_incr_u16(uint16_t *valuePtr, uint16_t delta) |
| dkato | 0:f782d9c66c49 | 255 | { |
| dkato | 0:f782d9c66c49 | 256 | uint16_t newValue; |
| dkato | 0:f782d9c66c49 | 257 | core_util_critical_section_enter(); |
| dkato | 0:f782d9c66c49 | 258 | newValue = *valuePtr + delta; |
| dkato | 0:f782d9c66c49 | 259 | *valuePtr = newValue; |
| dkato | 0:f782d9c66c49 | 260 | core_util_critical_section_exit(); |
| dkato | 0:f782d9c66c49 | 261 | return newValue; |
| dkato | 0:f782d9c66c49 | 262 | } |
| dkato | 0:f782d9c66c49 | 263 | |
| dkato | 0:f782d9c66c49 | 264 | uint32_t core_util_atomic_incr_u32(uint32_t *valuePtr, uint32_t delta) |
| dkato | 0:f782d9c66c49 | 265 | { |
| dkato | 0:f782d9c66c49 | 266 | uint32_t newValue; |
| dkato | 0:f782d9c66c49 | 267 | core_util_critical_section_enter(); |
| dkato | 0:f782d9c66c49 | 268 | newValue = *valuePtr + delta; |
| dkato | 0:f782d9c66c49 | 269 | *valuePtr = newValue; |
| dkato | 0:f782d9c66c49 | 270 | core_util_critical_section_exit(); |
| dkato | 0:f782d9c66c49 | 271 | return newValue; |
| dkato | 0:f782d9c66c49 | 272 | } |
| dkato | 0:f782d9c66c49 | 273 | |
| dkato | 0:f782d9c66c49 | 274 | |
| dkato | 0:f782d9c66c49 | 275 | uint8_t core_util_atomic_decr_u8(uint8_t *valuePtr, uint8_t delta) |
| dkato | 0:f782d9c66c49 | 276 | { |
| dkato | 0:f782d9c66c49 | 277 | uint8_t newValue; |
| dkato | 0:f782d9c66c49 | 278 | core_util_critical_section_enter(); |
| dkato | 0:f782d9c66c49 | 279 | newValue = *valuePtr - delta; |
| dkato | 0:f782d9c66c49 | 280 | *valuePtr = newValue; |
| dkato | 0:f782d9c66c49 | 281 | core_util_critical_section_exit(); |
| dkato | 0:f782d9c66c49 | 282 | return newValue; |
| dkato | 0:f782d9c66c49 | 283 | } |
| dkato | 0:f782d9c66c49 | 284 | |
| dkato | 0:f782d9c66c49 | 285 | uint16_t core_util_atomic_decr_u16(uint16_t *valuePtr, uint16_t delta) |
| dkato | 0:f782d9c66c49 | 286 | { |
| dkato | 0:f782d9c66c49 | 287 | uint16_t newValue; |
| dkato | 0:f782d9c66c49 | 288 | core_util_critical_section_enter(); |
| dkato | 0:f782d9c66c49 | 289 | newValue = *valuePtr - delta; |
| dkato | 0:f782d9c66c49 | 290 | *valuePtr = newValue; |
| dkato | 0:f782d9c66c49 | 291 | core_util_critical_section_exit(); |
| dkato | 0:f782d9c66c49 | 292 | return newValue; |
| dkato | 0:f782d9c66c49 | 293 | } |
| dkato | 0:f782d9c66c49 | 294 | |
| dkato | 0:f782d9c66c49 | 295 | uint32_t core_util_atomic_decr_u32(uint32_t *valuePtr, uint32_t delta) |
| dkato | 0:f782d9c66c49 | 296 | { |
| dkato | 0:f782d9c66c49 | 297 | uint32_t newValue; |
| dkato | 0:f782d9c66c49 | 298 | core_util_critical_section_enter(); |
| dkato | 0:f782d9c66c49 | 299 | newValue = *valuePtr - delta; |
| dkato | 0:f782d9c66c49 | 300 | *valuePtr = newValue; |
| dkato | 0:f782d9c66c49 | 301 | core_util_critical_section_exit(); |
| dkato | 0:f782d9c66c49 | 302 | return newValue; |
| dkato | 0:f782d9c66c49 | 303 | } |
| dkato | 0:f782d9c66c49 | 304 | |
| dkato | 0:f782d9c66c49 | 305 | #endif |
| dkato | 0:f782d9c66c49 | 306 | |
| dkato | 0:f782d9c66c49 | 307 | |
| dkato | 0:f782d9c66c49 | 308 | bool core_util_atomic_cas_ptr(void **ptr, void **expectedCurrentValue, void *desiredValue) { |
| dkato | 0:f782d9c66c49 | 309 | return core_util_atomic_cas_u32( |
| dkato | 0:f782d9c66c49 | 310 | (uint32_t *)ptr, |
| dkato | 0:f782d9c66c49 | 311 | (uint32_t *)expectedCurrentValue, |
| dkato | 0:f782d9c66c49 | 312 | (uint32_t)desiredValue); |
| dkato | 0:f782d9c66c49 | 313 | } |
| dkato | 0:f782d9c66c49 | 314 | |
| dkato | 0:f782d9c66c49 | 315 | void *core_util_atomic_incr_ptr(void **valuePtr, ptrdiff_t delta) { |
| dkato | 0:f782d9c66c49 | 316 | return (void *)core_util_atomic_incr_u32((uint32_t *)valuePtr, (uint32_t)delta); |
| dkato | 0:f782d9c66c49 | 317 | } |
| dkato | 0:f782d9c66c49 | 318 | |
| dkato | 0:f782d9c66c49 | 319 | void *core_util_atomic_decr_ptr(void **valuePtr, ptrdiff_t delta) { |
| dkato | 0:f782d9c66c49 | 320 | return (void *)core_util_atomic_decr_u32((uint32_t *)valuePtr, (uint32_t)delta); |
| dkato | 0:f782d9c66c49 | 321 | } |
| dkato | 0:f782d9c66c49 | 322 |