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Diffstat (limited to 'quantum/wear_leveling/wear_leveling.c')
| -rw-r--r-- | quantum/wear_leveling/wear_leveling.c | 768 |
1 files changed, 768 insertions, 0 deletions
diff --git a/quantum/wear_leveling/wear_leveling.c b/quantum/wear_leveling/wear_leveling.c new file mode 100644 index 0000000000..429df45df5 --- /dev/null +++ b/quantum/wear_leveling/wear_leveling.c @@ -0,0 +1,768 @@ +// Copyright 2022 Nick Brassel (@tzarc) +// SPDX-License-Identifier: GPL-2.0-or-later +#include <stdbool.h> +#include "fnv.h" +#include "wear_leveling.h" +#include "wear_leveling_internal.h" + +/* + This wear leveling algorithm is adapted from algorithms from previous + implementations in QMK, namely: + - Artur F. (http://engsta.com/stm32-flash-memory-eeprom-emulator/) + - Yiancar -- QMK's base implementation for STM32F303 + - Ilya Zhuravlev -- initial wear leveling algorithm + - Don Kjer -- increased flash density algorithm + - Nick Brassel (@tzarc) -- decoupled for use on other peripherals + + At this layer, it is assumed that any reads/writes from the backing store + have a "reset state" after erasure of zero. + It is up to the backing store to perform translation of values, such as + taking the complement in order to deal with flash memory's reset value. + + Terminology: + + - Backing store: this is the storage area used by the wear leveling + algorithm. + + - Backing size: this is the amount of storage provided by the backing + store for use by the wear leveling algorithm. + + - Backing write size: this is the minimum number of bytes the backing + store can write in a single operation. + + - Logical data: this is the externally-visible "emulated EEPROM" that + external subsystems "see" when performing reads/writes. + + - Logical size: this is the amount of storage available for use + externally. Effectively, the "size of the EEPROM". + + - Write log: this is a section of the backing store used to keep track + of modifications without overwriting existing data. This log is + "played back" on startup such that any subsequent reads are capable + of returning the latest data. + + - Consolidated data: this is a section of the backing store reserved for + use for the latest copy of logical data. This is only ever written + when the write log is full -- the latest values for the logical data + are written here and the write log is cleared. + + Configurables: + + - BACKING_STORE_WRITE_SIZE: The number of bytes requires for a write + operation. This is defined by the capabilities of the backing store. + + - WEAR_LEVELING_BACKING_SIZE: The number of bytes provided by the + backing store for use by the wear leveling algorithm. This is + defined by the capabilities of the backing store. This value must + also be at least twice the size of the logical size, as well as a + multiple of the logical size. + + - WEAR_LEVELING_LOGICAL_SIZE: The number of bytes externally visible + to other subsystems performing reads/writes. This must be a multiple + of the write size. + + General algorithm: + + During initialization: + * The contents of the consolidated data section are read into cache. + * The contents of the write log are "played back" and update the + cache accordingly. + + During reads: + * Logical data is served from the cache. + + During writes: + * The cache is updated with the new data. + * A new write log entry is appended to the log. + * If the log's full, data is consolidated and the write log cleared. + + Write log structure: + + The first 8 bytes of the write log are a FNV1a_64 hash of the contents + of the consolidated data area, in an attempt to detect and guard against + any data corruption. + + The write log follows the hash: + + Given that the algorithm needs to cater for 2-, 4-, and 8-byte writes, + a variable-length write log entry is used such that the minimal amount + of storage is used based off the backing store write size. + + Firstly, an empty log entry is expected to be all zeros. If the backing + store uses 0xFF for cleared bytes, it should return the complement, such + that this wear-leveling algorithm "receives" zeros. + + For multi-byte writes, up to 8 bytes will be used for each log entry, + depending on the size of backing store writes: + + ╔ Multi-byte Log Entry (2, 4-byte) ═╗ + ║00XXXYYY║YYYYYYYY║YYYYYYYY║AAAAAAAA║ + ║ └┬┘└┬┘║└──┬───┘║└──┬───┘║└──┬───┘║ + ║ LenAdd║ Address║ Address║Value[0]║ + ╚════════╩════════╩════════╩════════╝ + ╔ Multi-byte Log Entry (2-byte) ══════════════════════╗ + ║00XXXYYY║YYYYYYYY║YYYYYYYY║AAAAAAAA║BBBBBBBB║CCCCCCCC║ + ║ └┬┘└┬┘║└──┬───┘║└──┬───┘║└──┬───┘║└──┬───┘║└──┬───┘║ + ║ LenAdd║ Address║ Address║Value[0]║Value[1]║Value[2]║ + ╚════════╩════════╩════════╩════════╩════════╩════════╝ + ╔ Multi-byte Log Entry (2, 4, 8-byte) ══════════════════════════════════╗ + ║00XXXYYY║YYYYYYYY║YYYYYYYY║AAAAAAAA║BBBBBBBB║CCCCCCCC║DDDDDDDD║EEEEEEEE║ + ║ └┬┘└┬┘║└──┬───┘║└──┬───┘║└──┬───┘║└──┬───┘║└──┬───┘║└──┬───┘║└──┬───┘║ + ║ LenAdd║ Address║ Address║Value[0]║Value[1]║Value[2]║Value[3]║Value[4]║ + ╚════════╩════════╩════════╩════════╩════════╩════════╩════════╩════════╝ + + 19 bits are used for the address, which allows for a max logical size of + 512kB. Up to 5 bytes can be included in a single log entry. + + For 2-byte backing store writes, the last two bytes are optional + depending on the length of data to be written. Accordingly, either 3 + or 4 backing store write operations will occur. + For 4-byte backing store writes, either one or two write operations + occur, depending on the length. + For 8-byte backing store writes, one write operation occur. + + 2-byte backing store optimizations: + + For single byte writes, addresses between 0...63 are encoded in a single + backing store write operation. 4- and 8-byte backing stores do not have + this optimization as it does not minimize the number of bytes written. + + ╔ Byte-Entry ════╗ + ║01XXXXXXYYYYYYYY║ + ║ └─┬──┘└──┬───┘║ + ║ Address Value ║ + ╚════════════════╝ + 0 <= Address < 0x40 (64) + + A second optimization takes into account uint16_t writes of 0 or 1, + specifically catering for KC_NO and KC_TRANSPARENT in the dynamic keymap + subsystem. This is valid only for the first 16kB of logical data -- + addresses outside this range will use the multi-byte encoding above. + + ╔ U16-Encoded 0 ═╗ + ║100XXXXXXXXXXXXX║ + ║ │└─────┬─────┘║ + ║ │Address >> 1 ║ + ║ └── Value: 0 ║ + ╚════════════════╝ + 0 <= Address <= 0x3FFE (16382) + + ╔ U16-Encoded 1 ═╗ + ║101XXXXXXXXXXXXX║ + ║ │└─────┬─────┘║ + ║ │Address >> 1 ║ + ║ └── Value: 1 ║ + ╚════════════════╝ + 0 <= Address <= 0x3FFE (16382) */ + +/** + * Storage area for the wear-leveling cache. + */ +static struct __attribute__((__aligned__(BACKING_STORE_WRITE_SIZE))) { + __attribute__((__aligned__(BACKING_STORE_WRITE_SIZE))) uint8_t cache[(WEAR_LEVELING_LOGICAL_SIZE)]; + uint32_t write_address; + bool unlocked; +} wear_leveling; + +/** + * Locking helper: status + */ +typedef enum backing_store_lock_status_t { STATUS_FAILURE = 0, STATUS_SUCCESS, STATUS_UNCHANGED } backing_store_lock_status_t; + +/** + * Locking helper: unlock + */ +static inline backing_store_lock_status_t wear_leveling_unlock(void) { + if (wear_leveling.unlocked) { + return STATUS_UNCHANGED; + } + if (!backing_store_unlock()) { + return STATUS_FAILURE; + } + wear_leveling.unlocked = true; + return STATUS_SUCCESS; +} + +/** + * Locking helper: lock + */ +static inline backing_store_lock_status_t wear_leveling_lock(void) { + if (!wear_leveling.unlocked) { + return STATUS_UNCHANGED; + } + if (!backing_store_lock()) { + return STATUS_FAILURE; + } + wear_leveling.unlocked = false; + return STATUS_SUCCESS; +} + +/** + * Resets the cache, ensuring the write address is correctly initialised. + */ +static void wear_leveling_clear_cache(void) { + memset(wear_leveling.cache, 0, (WEAR_LEVELING_LOGICAL_SIZE)); + wear_leveling.write_address = (WEAR_LEVELING_LOGICAL_SIZE) + 8; // +8 is due to the FNV1a_64 of the consolidated buffer +} + +/** + * Reads the consolidated data from the backing store into the cache. + * Does not consider the write log. + */ +static wear_leveling_status_t wear_leveling_read_consolidated(void) { + wl_dprintf("Reading consolidated data\n"); + + wear_leveling_status_t status = WEAR_LEVELING_SUCCESS; + if (!backing_store_read_bulk(0, (backing_store_int_t *)wear_leveling.cache, sizeof(wear_leveling.cache) / sizeof(backing_store_int_t))) { + wl_dprintf("Failed to read from backing store\n"); + status = WEAR_LEVELING_FAILED; + } + + // Verify the FNV1a_64 result + if (status != WEAR_LEVELING_FAILED) { + uint64_t expected = fnv_64a_buf(wear_leveling.cache, (WEAR_LEVELING_LOGICAL_SIZE), FNV1A_64_INIT); + write_log_entry_t entry; + wl_dprintf("Reading checksum\n"); +#if BACKING_STORE_WRITE_SIZE == 2 + backing_store_read_bulk((WEAR_LEVELING_LOGICAL_SIZE), entry.raw16, 4); +#elif BACKING_STORE_WRITE_SIZE == 4 + backing_store_read_bulk((WEAR_LEVELING_LOGICAL_SIZE), entry.raw32, 2); +#elif BACKING_STORE_WRITE_SIZE == 8 + backing_store_read((WEAR_LEVELING_LOGICAL_SIZE) + 0, &entry.raw64); +#endif + // If we have a mismatch, clear the cache but do not flag a failure, + // which will cater for the completely clean MCU case. + if (entry.raw64 == expected) { + wl_dprintf("Checksum matches, consolidated data is correct\n"); + } else { + wl_dprintf("Checksum mismatch, clearing cache\n"); + wear_leveling_clear_cache(); + } + } + + // If we failed for any reason, then clear the cache + if (status == WEAR_LEVELING_FAILED) { + wear_leveling_clear_cache(); + } + + return status; +} + +/** + * Writes the current cache to consolidated data at the beginning of the backing store. + * Does not clear the write log. + * Pre-condition: this is just after an erase, so we can write directly without reading. + */ +static wear_leveling_status_t wear_leveling_write_consolidated(void) { + wl_dprintf("Writing consolidated data\n"); + + backing_store_lock_status_t lock_status = wear_leveling_unlock(); + wear_leveling_status_t status = WEAR_LEVELING_CONSOLIDATED; + if (!backing_store_write_bulk(0, (backing_store_int_t *)wear_leveling.cache, sizeof(wear_leveling.cache) / sizeof(backing_store_int_t))) { + wl_dprintf("Failed to write to backing store\n"); + status = WEAR_LEVELING_FAILED; + } + + if (status != WEAR_LEVELING_FAILED) { + // Write out the FNV1a_64 result of the consolidated data + write_log_entry_t entry; + entry.raw64 = fnv_64a_buf(wear_leveling.cache, (WEAR_LEVELING_LOGICAL_SIZE), FNV1A_64_INIT); + wl_dprintf("Writing checksum\n"); + do { +#if BACKING_STORE_WRITE_SIZE == 2 + if (!backing_store_write_bulk((WEAR_LEVELING_LOGICAL_SIZE), entry.raw16, 4)) { + status = WEAR_LEVELING_FAILED; + break; + } +#elif BACKING_STORE_WRITE_SIZE == 4 + if (!backing_store_write_bulk((WEAR_LEVELING_LOGICAL_SIZE), entry.raw32, 2)) { + status = WEAR_LEVELING_FAILED; + break; + } +#elif BACKING_STORE_WRITE_SIZE == 8 + if (!backing_store_write((WEAR_LEVELING_LOGICAL_SIZE), entry.raw64)) { + status = WEAR_LEVELING_FAILED; + break; + } +#endif + } while (0); + } + + if (lock_status == STATUS_SUCCESS) { + wear_leveling_lock(); + } + return status; +} + +/** + * Forces a write of the current cache. + * Erases the backing store, including the write log. + * During this operation, there is the potential for data loss if a power loss occurs. + */ +static wear_leveling_status_t wear_leveling_consolidate_force(void) { + wl_dprintf("Erasing backing store\n"); + + // Erase the backing store. Expectation is that any un-written values that are read back after this call come back as zero. + bool ok = backing_store_erase(); + if (!ok) { + wl_dprintf("Failed to erase backing store\n"); + return WEAR_LEVELING_FAILED; + } + + // Write the cache to the first section of the backing store. + wear_leveling_status_t status = wear_leveling_write_consolidated(); + if (status == WEAR_LEVELING_FAILED) { + wl_dprintf("Failed to write consolidated data\n"); + } + + // Next write of the log occurs after the consolidated values at the start of the backing store. + wear_leveling.write_address = (WEAR_LEVELING_LOGICAL_SIZE) + 8; // +8 due to the FNV1a_64 of the consolidated area + + return status; +} + +/** + * Potential write of the current cache to the backing store. + * Skipped if the current write log position is not at the end of the backing store. + * During this operation, there is the potential for data loss if a power loss occurs. + * + * @return true if consolidation occurred + */ +static wear_leveling_status_t wear_leveling_consolidate_if_needed(void) { + if (wear_leveling.write_address >= (WEAR_LEVELING_BACKING_SIZE)) { + return wear_leveling_consolidate_force(); + } + + return WEAR_LEVELING_SUCCESS; +} + +/** + * Appends the supplied fixed-width entry to the write log, optionally consolidating if the log is full. + * + * @return true if consolidation occurred + */ +static wear_leveling_status_t wear_leveling_append_raw(backing_store_int_t value) { + bool ok = backing_store_write(wear_leveling.write_address, value); + if (!ok) { + wl_dprintf("Failed to write to backing store\n"); + return WEAR_LEVELING_FAILED; + } + wear_leveling.write_address += (BACKING_STORE_WRITE_SIZE); + return wear_leveling_consolidate_if_needed(); +} + +/** + * Handles writing multi_byte-encoded data to the backing store. + * + * @return true if consolidation occurred + */ +static wear_leveling_status_t wear_leveling_write_raw_multibyte(uint32_t address, const void *value, size_t length) { + const uint8_t * p = value; + write_log_entry_t log = LOG_ENTRY_MAKE_MULTIBYTE(address, length); + for (size_t i = 0; i < length; ++i) { + log.raw8[3 + i] = p[i]; + } + + // Write to the backing store. See the multi-byte log format in the documentation header at the top of the file. + wear_leveling_status_t status; +#if BACKING_STORE_WRITE_SIZE == 2 + status = wear_leveling_append_raw(log.raw16[0]); + if (status != WEAR_LEVELING_SUCCESS) { + return status; + } + + status = wear_leveling_append_raw(log.raw16[1]); + if (status != WEAR_LEVELING_SUCCESS) { + return status; + } + + if (length > 1) { + status = wear_leveling_append_raw(log.raw16[2]); + if (status != WEAR_LEVELING_SUCCESS) { + return status; + } + } + + if (length > 3) { + status = wear_leveling_append_raw(log.raw16[3]); + if (status != WEAR_LEVELING_SUCCESS) { + return status; + } + } +#elif BACKING_STORE_WRITE_SIZE == 4 + status = wear_leveling_append_raw(log.raw32[0]); + if (status != WEAR_LEVELING_SUCCESS) { + return status; + } + + if (length > 1) { + status = wear_leveling_append_raw(log.raw32[1]); + if (status != WEAR_LEVELING_SUCCESS) { + return status; + } + } +#elif BACKING_STORE_WRITE_SIZE == 8 + status = wear_leveling_append_raw(log.raw64); + if (status != WEAR_LEVELING_SUCCESS) { + return status; + } +#endif + return status; +} + +/** + * Handles the actual writing of logical data into the write log section of the backing store. + */ +static wear_leveling_status_t wear_leveling_write_raw(uint32_t address, const void *value, size_t length) { + const uint8_t * p = value; + size_t remaining = length; + wear_leveling_status_t status = WEAR_LEVELING_SUCCESS; + while (remaining > 0) { +#if BACKING_STORE_WRITE_SIZE == 2 + // Small-write optimizations - uint16_t, 0 or 1, address is even, address <16384: + if (remaining >= 2 && address % 2 == 0 && address < 16384) { + const uint16_t v = ((uint16_t)p[1]) << 8 | p[0]; // don't just dereference a uint16_t here -- if unaligned it generates faults on some MCUs + if (v == 0 || v == 1) { + const write_log_entry_t log = LOG_ENTRY_MAKE_WORD_01(address, v); + status = wear_leveling_append_raw(log.raw16[0]); + if (status != WEAR_LEVELING_SUCCESS) { + // If consolidation occurred, then the cache has already been written to the consolidated area. No need to continue. + // If a failure occurred, pass it on. + return status; + } + + remaining -= 2; + address += 2; + p += 2; + continue; + } + } + + // Small-write optimizations - address<64: + if (address < 64) { + const write_log_entry_t log = LOG_ENTRY_MAKE_OPTIMIZED_64(address, *p); + status = wear_leveling_append_raw(log.raw16[0]); + if (status != WEAR_LEVELING_SUCCESS) { + // If consolidation occurred, then the cache has already been written to the consolidated area. No need to continue. + // If a failure occurred, pass it on. + return status; + } + + remaining--; + address++; + p++; + continue; + } +#endif // BACKING_STORE_WRITE_SIZE == 2 + const size_t this_length = remaining >= LOG_ENTRY_MULTIBYTE_MAX_BYTES ? LOG_ENTRY_MULTIBYTE_MAX_BYTES : remaining; + status = wear_leveling_write_raw_multibyte(address, p, this_length); + if (status != WEAR_LEVELING_SUCCESS) { + // If consolidation occurred, then the cache has already been written to the consolidated area. No need to continue. + // If a failure occurred, pass it on. + return status; + } + remaining -= this_length; + address += (uint32_t)this_length; + p += this_length; + } + + return status; +} + +/** + * "Replays" the write log from the backing store, updating the local cache with updated values. + */ +static wear_leveling_status_t wear_leveling_playback_log(void) { + wl_dprintf("Playback write log\n"); + + wear_leveling_status_t status = WEAR_LEVELING_SUCCESS; + bool cancel_playback = false; + uint32_t address = (WEAR_LEVELING_LOGICAL_SIZE) + 8; // +8 due to the FNV1a_64 of the consolidated area + while (!cancel_playback && address < (WEAR_LEVELING_BACKING_SIZE)) { + backing_store_int_t value; + bool ok = backing_store_read(address, &value); + if (!ok) { + wl_dprintf("Failed to load from backing store, skipping playback of write log\n"); + cancel_playback = true; + status = WEAR_LEVELING_FAILED; + break; + } + if (value == 0) { + wl_dprintf("Found empty slot, no more log entries\n"); + cancel_playback = true; + break; + } + + // If we got a nonzero value, then we need to increment the address to ensure next write occurs at next location + address += (BACKING_STORE_WRITE_SIZE); + + // Read from the write log + write_log_entry_t log; +#if BACKING_STORE_WRITE_SIZE == 2 + log.raw16[0] = value; +#elif BACKING_STORE_WRITE_SIZE == 4 + log.raw32[0] = value; +#elif BACKING_STORE_WRITE_SIZE == 8 + log.raw64 = value; +#endif + + switch (LOG_ENTRY_GET_TYPE(log)) { + case LOG_ENTRY_TYPE_MULTIBYTE: { +#if BACKING_STORE_WRITE_SIZE == 2 + ok = backing_store_read(address, &log.raw16[1]); + if (!ok) { + wl_dprintf("Failed to load from backing store, skipping playback of write log\n"); + cancel_playback = true; + status = WEAR_LEVELING_FAILED; + break; + } + address += (BACKING_STORE_WRITE_SIZE); +#endif // BACKING_STORE_WRITE_SIZE == 2 + const uint32_t a = LOG_ENTRY_MULTIBYTE_GET_ADDRESS(log); + const uint8_t l = LOG_ENTRY_MULTIBYTE_GET_LENGTH(log); + + if (a + l > (WEAR_LEVELING_LOGICAL_SIZE)) { + cancel_playback = true; + status = WEAR_LEVELING_FAILED; + break; + } + +#if BACKING_STORE_WRITE_SIZE == 2 + if (l > 1) { + ok = backing_store_read(address, &log.raw16[2]); + if (!ok) { + wl_dprintf("Failed to load from backing store, skipping playback of write log\n"); + cancel_playback = true; + status = WEAR_LEVELING_FAILED; + break; + } + address += (BACKING_STORE_WRITE_SIZE); + } + if (l > 3) { + ok = backing_store_read(address, &log.raw16[3]); + if (!ok) { + wl_dprintf("Failed to load from backing store, skipping playback of write log\n"); + cancel_playback = true; + status = WEAR_LEVELING_FAILED; + break; + } + address += (BACKING_STORE_WRITE_SIZE); + } +#elif BACKING_STORE_WRITE_SIZE == 4 + if (l > 1) { + ok = backing_store_read(address, &log.raw32[1]); + if (!ok) { + wl_dprintf("Failed to load from backing store, skipping playback of write log\n"); + cancel_playback = true; + status = WEAR_LEVELING_FAILED; + break; + } + address += (BACKING_STORE_WRITE_SIZE); + } +#endif + + memcpy(&wear_leveling.cache[a], &log.raw8[3], l); + } break; +#if BACKING_STORE_WRITE_SIZE == 2 + case LOG_ENTRY_TYPE_OPTIMIZED_64: { + const uint32_t a = LOG_ENTRY_OPTIMIZED_64_GET_ADDRESS(log); + const uint8_t v = LOG_ENTRY_OPTIMIZED_64_GET_VALUE(log); + + if (a >= (WEAR_LEVELING_LOGICAL_SIZE)) { + cancel_playback = true; + status = WEAR_LEVELING_FAILED; + break; + } + + wear_leveling.cache[a] = v; + } break; + case LOG_ENTRY_TYPE_WORD_01: { + const uint32_t a = LOG_ENTRY_WORD_01_GET_ADDRESS(log); + const uint8_t v = LOG_ENTRY_WORD_01_GET_VALUE(log); + + if (a + 1 >= (WEAR_LEVELING_LOGICAL_SIZE)) { + cancel_playback = true; + status = WEAR_LEVELING_FAILED; + break; + } + + wear_leveling.cache[a + 0] = v; + wear_leveling.cache[a + 1] = 0; + } break; +#endif // BACKING_STORE_WRITE_SIZE == 2 + default: { + cancel_playback = true; + status = WEAR_LEVELING_FAILED; + } break; + } + } + + // We've reached the end of the log, so we're at the new write location + wear_leveling.write_address = address; + + if (status == WEAR_LEVELING_FAILED) { + // If we had a failure during readback, assume we're corrupted -- force a consolidation with the data we already have + status = wear_leveling_consolidate_force(); + } else { + // Consolidate the cache + write log if required + status = wear_leveling_consolidate_if_needed(); + } + + return status; +} + +/** + * Wear-leveling initialization + */ +wear_leveling_status_t wear_leveling_init(void) { + wl_dprintf("Init\n"); + + // Reset the cache + wear_leveling_clear_cache(); + + // Initialise the backing store + if (!backing_store_init()) { + // If it failed, clear the cache and return with failure + wear_leveling_clear_cache(); + return WEAR_LEVELING_FAILED; + } + + // Read the previous consolidated values, then replay the existing write log so that the cache has the "live" values + wear_leveling_status_t status = wear_leveling_read_consolidated(); + if (status == WEAR_LEVELING_FAILED) { + // If it failed, clear the cache and return with failure + wear_leveling_clear_cache(); + return status; + } + + status = wear_leveling_playback_log(); + if (status == WEAR_LEVELING_FAILED) { + // If it failed, clear the cache and return with failure + wear_leveling_clear_cache(); + return status; + } + + return status; +} + +/** + * Wear-leveling erase. + * Post-condition: any reads from the backing store directly after an erase operation must come back as zero. + */ +wear_leveling_status_t wear_leveling_erase(void) { + wl_dprintf("Erase\n"); + + // Unlock the backing store + backing_store_lock_status_t lock_status = wear_leveling_unlock(); + if (lock_status == STATUS_FAILURE) { + wear_leveling_lock(); + return WEAR_LEVELING_FAILED; + } + + // Perform the erase + bool ret = backing_store_erase(); + wear_leveling_clear_cache(); + + // Lock the backing store if we acquired the lock successfully + if (lock_status == STATUS_SUCCESS) { + ret &= (wear_leveling_lock() != STATUS_FAILURE); + } + + return ret ? WEAR_LEVELING_SUCCESS : WEAR_LEVELING_FAILED; +} + +/** + * Writes logical data into the backing store. Skips writes if there are no changes to values. + */ +wear_leveling_status_t wear_leveling_write(const uint32_t address, const void *value, size_t length) { + wl_assert(address + length <= (WEAR_LEVELING_LOGICAL_SIZE)); + if (address + length > (WEAR_LEVELING_LOGICAL_SIZE)) { + return WEAR_LEVELING_FAILED; + } + + wl_dprintf("Write "); + wl_dump(address, value, length); + + // Skip write if there's no change compared to the current cached value + if (memcmp(value, &wear_leveling.cache[address], length) == 0) { + return true; + } + + // Update the cache before writing to the backing store -- if we hit the end of the backing store during writes to the log then we'll force a consolidation in-line + memcpy(&wear_leveling.cache[address], value, length); + + // Unlock the backing store + backing_store_lock_status_t lock_status = wear_leveling_unlock(); + if (lock_status == STATUS_FAILURE) { + wear_leveling_lock(); + return WEAR_LEVELING_FAILED; + } + + // Perform the actual write + wear_leveling_status_t status = wear_leveling_write_raw(address, value, length); + switch (status) { + case WEAR_LEVELING_CONSOLIDATED: + case WEAR_LEVELING_FAILED: + // If the write triggered consolidation, or the write failed, then nothing else needs to occur. + break; + + case WEAR_LEVELING_SUCCESS: + // Consolidate the cache + write log if required + status = wear_leveling_consolidate_if_needed(); + break; + + default: + // Unsure how we'd get here... + status = WEAR_LEVELING_FAILED; + break; + } + + if (lock_status == STATUS_SUCCESS) { + if (wear_leveling_lock() == STATUS_FAILURE) { + status = WEAR_LEVELING_FAILED; + } + } + + return status; +} + +/** + * Reads logical data from the cache. + */ +wear_leveling_status_t wear_leveling_read(const uint32_t address, void *value, size_t length) { + wl_assert(address + length <= (WEAR_LEVELING_LOGICAL_SIZE)); + if (address + length > (WEAR_LEVELING_LOGICAL_SIZE)) { + return WEAR_LEVELING_FAILED; + } + + // Only need to copy from the cache + memcpy(value, &wear_leveling.cache[address], length); + + wl_dprintf("Read "); + wl_dump(address, value, length); + return WEAR_LEVELING_SUCCESS; +} + +/** + * Weak implementation of bulk read, drivers can implement more optimised implementations. + */ +__attribute__((weak)) bool backing_store_read_bulk(uint32_t address, backing_store_int_t *values, size_t item_count) { + for (size_t i = 0; i < item_count; ++i) { + if (!backing_store_read(address + (i * BACKING_STORE_WRITE_SIZE), &values[i])) { + return false; + } + } + return true; +} + +/** + * Weak implementation of bulk write, drivers can implement more optimised implementations. + */ +__attribute__((weak)) bool backing_store_write_bulk(uint32_t address, backing_store_int_t *values, size_t item_count) { + for (size_t i = 0; i < item_count; ++i) { + if (!backing_store_write(address + (i * BACKING_STORE_WRITE_SIZE), values[i])) { + return false; + } + } + return true; +} |