/* * Copyright (c) 2015-2018, ARM Limited and Contributors. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include #include /* * Functions in this file implement Bakery Algorithm for mutual exclusion with the * bakery lock data structures in cacheable and Normal memory. * * ARM architecture offers a family of exclusive access instructions to * efficiently implement mutual exclusion with hardware support. However, as * well as depending on external hardware, these instructions have defined * behavior only on certain memory types (cacheable and Normal memory in * particular; see ARMv8 Architecture Reference Manual section B2.10). Use cases * in trusted firmware are such that mutual exclusion implementation cannot * expect that accesses to the lock have the specific type required by the * architecture for these primitives to function (for example, not all * contenders may have address translation enabled). * * This implementation does not use mutual exclusion primitives. It expects * memory regions where the locks reside to be cacheable and Normal. * * Note that the ARM architecture guarantees single-copy atomicity for aligned * accesses regardless of status of address translation. */ #ifdef PLAT_PERCPU_BAKERY_LOCK_SIZE /* * Verify that the platform defined value for the per-cpu space for bakery locks is * a multiple of the cache line size, to prevent multiple CPUs writing to the same * bakery lock cache line * * Using this value, if provided, rather than the linker generated value results in * more efficient code */ CASSERT((PLAT_PERCPU_BAKERY_LOCK_SIZE & (CACHE_WRITEBACK_GRANULE - 1)) == 0, \ PLAT_PERCPU_BAKERY_LOCK_SIZE_not_cacheline_multiple); #define PERCPU_BAKERY_LOCK_SIZE (PLAT_PERCPU_BAKERY_LOCK_SIZE) #else /* * Use the linker defined symbol which has evaluated the size reqiurement. * This is not as efficient as using a platform defined constant */ IMPORT_SYM(uintptr_t, __PERCPU_BAKERY_LOCK_START__, BAKERY_LOCK_START); IMPORT_SYM(uintptr_t, __PERCPU_BAKERY_LOCK_END__, BAKERY_LOCK_END); #define PERCPU_BAKERY_LOCK_SIZE (BAKERY_LOCK_END - BAKERY_LOCK_START) #endif static inline bakery_lock_t *get_bakery_info(unsigned int cpu_ix, bakery_lock_t *lock) { return (bakery_info_t *)((uintptr_t)lock + cpu_ix * PERCPU_BAKERY_LOCK_SIZE); } static inline void write_cache_op(uintptr_t addr, bool cached) { if (cached) dccvac(addr); else dcivac(addr); dsbish(); } static inline void read_cache_op(uintptr_t addr, bool cached) { if (cached) dccivac(addr); } /* Helper function to check if the lock is acquired */ static inline bool is_lock_acquired(const bakery_info_t *my_bakery_info, int is_cached) { /* * Even though lock data is updated only by the owning cpu and * appropriate cache maintenance operations are performed, * if the previous update was done when the cpu was not participating * in coherency, then there is a chance that cache maintenance * operations were not propagated to all the caches in the system. * Hence do a `read_cache_op()` prior to read. */ read_cache_op((uintptr_t)my_bakery_info, is_cached); return bakery_ticket_number(my_bakery_info->lock_data) != 0U; } static unsigned int bakery_get_ticket(bakery_lock_t *lock, unsigned int me, int is_cached) { unsigned int my_ticket, their_ticket; unsigned int they; bakery_info_t *my_bakery_info, *their_bakery_info; /* * Obtain a reference to the bakery information for this cpu and ensure * it is not NULL. */ my_bakery_info = get_bakery_info(me, lock); assert(my_bakery_info != NULL); /* Prevent recursive acquisition.*/ assert(!is_lock_acquired(my_bakery_info, is_cached)); /* * Tell other contenders that we are through the bakery doorway i.e. * going to allocate a ticket for this cpu. */ my_ticket = 0U; my_bakery_info->lock_data = make_bakery_data(CHOOSING_TICKET, my_ticket); write_cache_op((uintptr_t)my_bakery_info, is_cached); /* * Iterate through the bakery information of each contender to allocate * the highest ticket number for this cpu. */ for (they = 0U; they < BAKERY_LOCK_MAX_CPUS; they++) { if (me == they) continue; /* * Get a reference to the other contender's bakery info and * ensure that a stale copy is not read. */ their_bakery_info = get_bakery_info(they, lock); assert(their_bakery_info != NULL); read_cache_op((uintptr_t)their_bakery_info, is_cached); /* * Update this cpu's ticket number if a higher ticket number is * seen */ their_ticket = bakery_ticket_number(their_bakery_info->lock_data); if (their_ticket > my_ticket) my_ticket = their_ticket; } /* * Compute ticket; then signal to other contenders waiting for us to * finish calculating our ticket value that we're done */ ++my_ticket; my_bakery_info->lock_data = make_bakery_data(CHOSEN_TICKET, my_ticket); write_cache_op((uintptr_t)my_bakery_info, is_cached); return my_ticket; } void bakery_lock_get(bakery_lock_t *lock) { unsigned int they, me, is_cached; unsigned int my_ticket, my_prio, their_ticket; bakery_info_t *their_bakery_info; unsigned int their_bakery_data; me = plat_my_core_pos(); #ifdef __aarch64__ is_cached = read_sctlr_el3() & SCTLR_C_BIT; #else is_cached = read_sctlr() & SCTLR_C_BIT; #endif /* Get a ticket */ my_ticket = bakery_get_ticket(lock, me, is_cached); /* * Now that we got our ticket, compute our priority value, then compare * with that of others, and proceed to acquire the lock */ my_prio = bakery_get_priority(my_ticket, me); for (they = 0U; they < BAKERY_LOCK_MAX_CPUS; they++) { if (me == they) continue; /* * Get a reference to the other contender's bakery info and * ensure that a stale copy is not read. */ their_bakery_info = get_bakery_info(they, lock); assert(their_bakery_info != NULL); /* Wait for the contender to get their ticket */ do { read_cache_op((uintptr_t)their_bakery_info, is_cached); their_bakery_data = their_bakery_info->lock_data; } while (bakery_is_choosing(their_bakery_data)); /* * If the other party is a contender, they'll have non-zero * (valid) ticket value. If they do, compare priorities */ their_ticket = bakery_ticket_number(their_bakery_data); if (their_ticket && (bakery_get_priority(their_ticket, they) < my_prio)) { /* * They have higher priority (lower value). Wait for * their ticket value to change (either release the lock * to have it dropped to 0; or drop and probably content * again for the same lock to have an even higher value) */ do { wfe(); read_cache_op((uintptr_t)their_bakery_info, is_cached); } while (their_ticket == bakery_ticket_number(their_bakery_info->lock_data)); } } /* * Lock acquired. Ensure that any reads and writes from a shared * resource in the critical section read/write values after the lock is * acquired. */ dmbish(); } void bakery_lock_release(bakery_lock_t *lock) { bakery_info_t *my_bakery_info; #ifdef __aarch64__ unsigned int is_cached = read_sctlr_el3() & SCTLR_C_BIT; #else unsigned int is_cached = read_sctlr() & SCTLR_C_BIT; #endif my_bakery_info = get_bakery_info(plat_my_core_pos(), lock); assert(is_lock_acquired(my_bakery_info, is_cached)); /* * Ensure that other observers see any stores in the critical section * before releasing the lock. Also ensure all loads in the critical * section are complete before releasing the lock. Release the lock by * resetting ticket. Then signal other waiting contenders. */ dmbish(); my_bakery_info->lock_data = 0U; write_cache_op((uintptr_t)my_bakery_info, is_cached); /* This sev is ordered by the dsbish in write_cahce_op */ sev(); }