/* * Copyright (c) 2015 Wind River Systems, Inc. * Copyright (c) 2022 Carlo Caione * * SPDX-License-Identifier: Apache-2.0 */ #ifndef ZEPHYR_INCLUDE_CACHE_H_ #define ZEPHYR_INCLUDE_CACHE_H_ /** * @file * @brief cache API interface */ #include #include #include #ifdef __cplusplus extern "C" { #endif #if defined(CONFIG_EXTERNAL_CACHE) #include #elif defined(CONFIG_ARCH_CACHE) #include #endif /** * @defgroup cache_interface Cache Interface * @ingroup os_services * @{ */ /** * @cond INTERNAL_HIDDEN * */ #define _CPU DT_PATH(cpus, cpu_0) /** @endcond */ /** * @brief Enable the d-cache * * Enable the data cache * */ static ALWAYS_INLINE void sys_cache_data_enable(void) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_DCACHE) cache_data_enable(); #endif } /** * @brief Disable the d-cache * * Disable the data cache * */ static ALWAYS_INLINE void sys_cache_data_disable(void) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_DCACHE) cache_data_disable(); #endif } /** * @brief Enable the i-cache * * Enable the instruction cache * */ static ALWAYS_INLINE void sys_cache_instr_enable(void) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_ICACHE) cache_instr_enable(); #endif } /** * @brief Disable the i-cache * * Disable the instruction cache * */ static ALWAYS_INLINE void sys_cache_instr_disable(void) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_ICACHE) cache_instr_disable(); #endif } /** * @brief Flush the d-cache * * Flush the whole data cache. * * @retval 0 If succeeded. * @retval -ENOTSUP If not supported. * @retval -errno Negative errno for other failures. */ static ALWAYS_INLINE int sys_cache_data_flush_all(void) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_DCACHE) return cache_data_flush_all(); #endif return -ENOTSUP; } /** * @brief Flush the i-cache * * Flush the whole instruction cache. * * @retval 0 If succeeded. * @retval -ENOTSUP If not supported. * @retval -errno Negative errno for other failures. */ static ALWAYS_INLINE int sys_cache_instr_flush_all(void) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_ICACHE) return cache_instr_flush_all(); #endif return -ENOTSUP; } /** * @brief Invalidate the d-cache * * Invalidate the whole data cache. * * @retval 0 If succeeded. * @retval -ENOTSUP If not supported. * @retval -errno Negative errno for other failures. */ static ALWAYS_INLINE int sys_cache_data_invd_all(void) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_DCACHE) return cache_data_invd_all(); #endif return -ENOTSUP; } /** * @brief Invalidate the i-cache * * Invalidate the whole instruction cache. * * @retval 0 If succeeded. * @retval -ENOTSUP If not supported. * @retval -errno Negative errno for other failures. */ static ALWAYS_INLINE int sys_cache_instr_invd_all(void) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_ICACHE) return cache_instr_invd_all(); #endif return -ENOTSUP; } /** * @brief Flush and Invalidate the d-cache * * Flush and Invalidate the whole data cache. * * @retval 0 If succeeded. * @retval -ENOTSUP If not supported. * @retval -errno Negative errno for other failures. */ static ALWAYS_INLINE int sys_cache_data_flush_and_invd_all(void) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_DCACHE) return cache_data_flush_and_invd_all(); #endif return -ENOTSUP; } /** * @brief Flush and Invalidate the i-cache * * Flush and Invalidate the whole instruction cache. * * @retval 0 If succeeded. * @retval -ENOTSUP If not supported. * @retval -errno Negative errno for other failures. */ static ALWAYS_INLINE int sys_cache_instr_flush_and_invd_all(void) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_ICACHE) return cache_instr_flush_and_invd_all(); #endif return -ENOTSUP; } /** * @brief Flush an address range in the d-cache * * Flush the specified address range of the data cache. * * @note the cache operations act on cache line. When multiple data structures * share the same cache line being flushed, all the portions of the * data structures sharing the same line will be flushed. This is usually * not a problem because writing back is a non-destructive process that * could be triggered by hardware at any time, so having an aligned * @p addr or a padded @p size is not strictly necessary. * * @param addr Starting address to flush. * @param size Range size. * * @retval 0 If succeeded. * @retval -ENOTSUP If not supported. * @retval -errno Negative errno for other failures. */ __syscall_always_inline int sys_cache_data_flush_range(void *addr, size_t size); static ALWAYS_INLINE int z_impl_sys_cache_data_flush_range(void *addr, size_t size) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_DCACHE) return cache_data_flush_range(addr, size); #endif ARG_UNUSED(addr); ARG_UNUSED(size); return -ENOTSUP; } /** * @brief Flush an address range in the i-cache * * Flush the specified address range of the instruction cache. * * @note the cache operations act on cache line. When multiple data structures * share the same cache line being flushed, all the portions of the * data structures sharing the same line will be flushed. This is usually * not a problem because writing back is a non-destructive process that * could be triggered by hardware at any time, so having an aligned * @p addr or a padded @p size is not strictly necessary. * * @param addr Starting address to flush. * @param size Range size. * * @retval 0 If succeeded. * @retval -ENOTSUP If not supported. * @retval -errno Negative errno for other failures. */ static ALWAYS_INLINE int sys_cache_instr_flush_range(void *addr, size_t size) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_ICACHE) return cache_instr_flush_range(addr, size); #endif ARG_UNUSED(addr); ARG_UNUSED(size); return -ENOTSUP; } /** * @brief Invalidate an address range in the d-cache * * Invalidate the specified address range of the data cache. * * @note the cache operations act on cache line. When multiple data structures * share the same cache line being invalidated, all the portions of the * non-read-only data structures sharing the same line will be * invalidated as well. This is a destructive process that could lead to * data loss and/or corruption. When @p addr is not aligned to the cache * line and/or @p size is not a multiple of the cache line size the * behaviour is undefined. * * @param addr Starting address to invalidate. * @param size Range size. * * @retval 0 If succeeded. * @retval -ENOTSUP If not supported. * @retval -errno Negative errno for other failures. */ __syscall_always_inline int sys_cache_data_invd_range(void *addr, size_t size); static ALWAYS_INLINE int z_impl_sys_cache_data_invd_range(void *addr, size_t size) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_DCACHE) return cache_data_invd_range(addr, size); #endif ARG_UNUSED(addr); ARG_UNUSED(size); return -ENOTSUP; } /** * @brief Invalidate an address range in the i-cache * * Invalidate the specified address range of the instruction cache. * * @note the cache operations act on cache line. When multiple data structures * share the same cache line being invalidated, all the portions of the * non-read-only data structures sharing the same line will be * invalidated as well. This is a destructive process that could lead to * data loss and/or corruption. When @p addr is not aligned to the cache * line and/or @p size is not a multiple of the cache line size the * behaviour is undefined. * * @param addr Starting address to invalidate. * @param size Range size. * * @retval 0 If succeeded. * @retval -ENOTSUP If not supported. * @retval -errno Negative errno for other failures. */ static ALWAYS_INLINE int sys_cache_instr_invd_range(void *addr, size_t size) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_ICACHE) return cache_instr_invd_range(addr, size); #endif ARG_UNUSED(addr); ARG_UNUSED(size); return -ENOTSUP; } /** * @brief Flush and Invalidate an address range in the d-cache * * Flush and Invalidate the specified address range of the data cache. * * @note the cache operations act on cache line. When multiple data structures * share the same cache line being flushed, all the portions of the * data structures sharing the same line will be flushed before being * invalidated. This is usually not a problem because writing back is a * non-destructive process that could be triggered by hardware at any * time, so having an aligned @p addr or a padded @p size is not strictly * necessary. * * @param addr Starting address to flush and invalidate. * @param size Range size. * * @retval 0 If succeeded. * @retval -ENOTSUP If not supported. * @retval -errno Negative errno for other failures. */ __syscall_always_inline int sys_cache_data_flush_and_invd_range(void *addr, size_t size); static ALWAYS_INLINE int z_impl_sys_cache_data_flush_and_invd_range(void *addr, size_t size) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_DCACHE) return cache_data_flush_and_invd_range(addr, size); #endif ARG_UNUSED(addr); ARG_UNUSED(size); return -ENOTSUP; } /** * @brief Flush and Invalidate an address range in the i-cache * * Flush and Invalidate the specified address range of the instruction cache. * * @note the cache operations act on cache line. When multiple data structures * share the same cache line being flushed, all the portions of the * data structures sharing the same line will be flushed before being * invalidated. This is usually not a problem because writing back is a * non-destructive process that could be triggered by hardware at any * time, so having an aligned @p addr or a padded @p size is not strictly * necessary. * * @param addr Starting address to flush and invalidate. * @param size Range size. * * @retval 0 If succeeded. * @retval -ENOTSUP If not supported. * @retval -errno Negative errno for other failures. */ static ALWAYS_INLINE int sys_cache_instr_flush_and_invd_range(void *addr, size_t size) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_ICACHE) return cache_instr_flush_and_invd_range(addr, size); #endif ARG_UNUSED(addr); ARG_UNUSED(size); return -ENOTSUP; } /** * * @brief Get the d-cache line size. * * The API is provided to get the data cache line. * * The cache line size is calculated (in order of priority): * * - At run-time when @kconfig{CONFIG_DCACHE_LINE_SIZE_DETECT} is set. * - At compile time using the value set in @kconfig{CONFIG_DCACHE_LINE_SIZE}. * - At compile time using the `d-cache-line-size` CPU0 property of the DT. * - 0 otherwise * * @retval size Size of the d-cache line. * @retval 0 If the d-cache is not enabled. */ static ALWAYS_INLINE size_t sys_cache_data_line_size_get(void) { #ifdef CONFIG_DCACHE_LINE_SIZE_DETECT return cache_data_line_size_get(); #elif (CONFIG_DCACHE_LINE_SIZE != 0) return CONFIG_DCACHE_LINE_SIZE; #else return DT_PROP_OR(_CPU, d_cache_line_size, 0); #endif } /** * * @brief Get the i-cache line size. * * The API is provided to get the instruction cache line. * * The cache line size is calculated (in order of priority): * * - At run-time when @kconfig{CONFIG_ICACHE_LINE_SIZE_DETECT} is set. * - At compile time using the value set in @kconfig{CONFIG_ICACHE_LINE_SIZE}. * - At compile time using the `i-cache-line-size` CPU0 property of the DT. * - 0 otherwise * * @retval size Size of the d-cache line. * @retval 0 If the d-cache is not enabled. */ static ALWAYS_INLINE size_t sys_cache_instr_line_size_get(void) { #ifdef CONFIG_ICACHE_LINE_SIZE_DETECT return cache_instr_line_size_get(); #elif (CONFIG_ICACHE_LINE_SIZE != 0) return CONFIG_ICACHE_LINE_SIZE; #else return DT_PROP_OR(_CPU, i_cache_line_size, 0); #endif } /** * @brief Test if a pointer is in cached region. * * Some hardware may map the same physical memory twice * so that it can be seen in both (incoherent) cached mappings * and a coherent "shared" area. This tests if a particular * pointer is within the cached, coherent area. * * @param ptr Pointer * * @retval True if pointer is in cached region. * @retval False if pointer is not in cached region. */ static ALWAYS_INLINE bool sys_cache_is_ptr_cached(void *ptr) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_CACHE_DOUBLEMAP) return cache_is_ptr_cached(ptr); #else ARG_UNUSED(ptr); return false; #endif } /** * @brief Test if a pointer is in un-cached region. * * Some hardware may map the same physical memory twice * so that it can be seen in both (incoherent) cached mappings * and a coherent "shared" area. This tests if a particular * pointer is within the un-cached, incoherent area. * * @param ptr Pointer * * @retval True if pointer is not in cached region. * @retval False if pointer is in cached region. */ static ALWAYS_INLINE bool sys_cache_is_ptr_uncached(void *ptr) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_CACHE_DOUBLEMAP) return cache_is_ptr_uncached(ptr); #else ARG_UNUSED(ptr); return false; #endif } /** * @brief Return cached pointer to a RAM address * * This function takes a pointer to any addressable object (either in * cacheable memory or not) and returns a pointer that can be used to * refer to the same memory through the L1 data cache. Data read * through the resulting pointer will reflect locally cached values on * the current CPU if they exist, and writes will go first into the * cache and be written back later. * * @note This API returns the same pointer if CONFIG_CACHE_DOUBLEMAP is not * enabled. * * @see arch_uncached_ptr() * * @param ptr A pointer to a valid C object * @return A pointer to the same object via the L1 dcache */ static ALWAYS_INLINE void __sparse_cache *sys_cache_cached_ptr_get(void *ptr) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_CACHE_DOUBLEMAP) return cache_cached_ptr(ptr); #else return (__sparse_force void __sparse_cache *)ptr; #endif } /** * @brief Return uncached pointer to a RAM address * * This function takes a pointer to any addressable object (either in * cacheable memory or not) and returns a pointer that can be used to * refer to the same memory while bypassing the L1 data cache. Data * in the L1 cache will not be inspected nor modified by the access. * * @note This API returns the same pointer if CONFIG_CACHE_DOUBLEMAP is not * enabled. * * @see arch_cached_ptr() * * @param ptr A pointer to a valid C object * @return A pointer to the same object bypassing the L1 dcache */ static ALWAYS_INLINE void *sys_cache_uncached_ptr_get(void __sparse_cache *ptr) { #if defined(CONFIG_CACHE_MANAGEMENT) && defined(CONFIG_CACHE_DOUBLEMAP) return cache_uncached_ptr(ptr); #else return (__sparse_force void *)ptr; #endif } #ifdef CONFIG_LIBMETAL static ALWAYS_INLINE void sys_cache_flush(void *addr, size_t size) { sys_cache_data_flush_range(addr, size); } #endif #include #ifdef __cplusplus } #endif /** * @} */ #endif /* ZEPHYR_INCLUDE_CACHE_H_ */