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// 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 ) ═ ╗
║ 00 XXXYYY ║ YYYYYYYY ║ YYYYYYYY ║ AAAAAAAA ║
║ └ ┬ ┘ └ ┬ ┘ ║ └ ─ ─ ┬ ─ ─ ─ ┘ ║ └ ─ ─ ┬ ─ ─ ─ ┘ ║ └ ─ ─ ┬ ─ ─ ─ ┘ ║
║ LenAdd ║ Address ║ Address ║ Value [ 0 ] ║
╚ ═ ═ ═ ═ ═ ═ ═ ═ ╩ ═ ═ ═ ═ ═ ═ ═ ═ ╩ ═ ═ ═ ═ ═ ═ ═ ═ ╩ ═ ═ ═ ═ ═ ═ ═ ═ ╝
╔ Multi - byte Log Entry ( 2 - byte ) ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ╗
║ 00 XXXYYY ║ YYYYYYYY ║ YYYYYYYY ║ AAAAAAAA ║ BBBBBBBB ║ CCCCCCCC ║
║ └ ┬ ┘ └ ┬ ┘ ║ └ ─ ─ ┬ ─ ─ ─ ┘ ║ └ ─ ─ ┬ ─ ─ ─ ┘ ║ └ ─ ─ ┬ ─ ─ ─ ┘ ║ └ ─ ─ ┬ ─ ─ ─ ┘ ║ └ ─ ─ ┬ ─ ─ ─ ┘ ║
║ LenAdd ║ Address ║ Address ║ Value [ 0 ] ║ Value [ 1 ] ║ Value [ 2 ] ║
╚ ═ ═ ═ ═ ═ ═ ═ ═ ╩ ═ ═ ═ ═ ═ ═ ═ ═ ╩ ═ ═ ═ ═ ═ ═ ═ ═ ╩ ═ ═ ═ ═ ═ ═ ═ ═ ╩ ═ ═ ═ ═ ═ ═ ═ ═ ╩ ═ ═ ═ ═ ═ ═ ═ ═ ╝
╔ Multi - byte Log Entry ( 2 , 4 , 8 - byte ) ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ╗
║ 00 XXXYYY ║ 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
512 kB . 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 ═ ═ ═ ═ ╗
║ 01 XXXXXXYYYYYYYY ║
║ └ ─ ┬ ─ ─ ┘ └ ─ ─ ┬ ─ ─ ─ ┘ ║
║ 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 16 kB of logical data - -
addresses outside this range will use the multi - byte encoding above .
╔ U16 - Encoded 0 ═ ╗
║ 100 XXXXXXXXXXXXX ║
║ │ └ ─ ─ ─ ─ ─ ┬ ─ ─ ─ ─ ─ ┘ ║
║ │ Address > > 1 ║
║ └ ─ ─ Value : 0 ║
╚ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ═ ╝
0 < = Address < = 0x3FFE ( 16382 )
╔ U16 - Encoded 1 ═ ╗
║ 101 XXXXXXXXXXXXX ║
║ │ └ ─ ─ ─ ─ ─ ┬ ─ ─ ─ ─ ─ ┘ ║
║ │ 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 ;
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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 ;
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}
// 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 ;
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wl_dprintf ( " Reading checksum \n " ) ;
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# if BACKING_STORE_WRITE_SIZE == 2
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backing_store_read_bulk ( ( WEAR_LEVELING_LOGICAL_SIZE ) , entry . raw16 , 4 ) ;
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# elif BACKING_STORE_WRITE_SIZE == 4
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backing_store_read_bulk ( ( WEAR_LEVELING_LOGICAL_SIZE ) , entry . raw32 , 2 ) ;
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# 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.
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if ( entry . raw64 = = expected ) {
wl_dprintf ( " Checksum matches, consolidated data is correct \n " ) ;
} else {
wl_dprintf ( " Checksum mismatch, clearing cache \n " ) ;
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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 .
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* Pre - condition : this is just after an erase , so we can write directly without reading .
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*/
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 ( ) ;
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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 ;
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}
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 ) ;
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wl_dprintf ( " Writing checksum \n " ) ;
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do {
# if BACKING_STORE_WRITE_SIZE == 2
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if ( ! backing_store_write_bulk ( ( WEAR_LEVELING_LOGICAL_SIZE ) , entry . raw16 , 4 ) ) {
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status = WEAR_LEVELING_FAILED ;
break ;
}
# elif BACKING_STORE_WRITE_SIZE == 4
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if ( ! backing_store_write_bulk ( ( WEAR_LEVELING_LOGICAL_SIZE ) , entry . raw32 , 2 ) ) {
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status = WEAR_LEVELING_FAILED ;
break ;
}
# elif BACKING_STORE_WRITE_SIZE == 8
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if ( ! backing_store_write ( ( WEAR_LEVELING_LOGICAL_SIZE ) , entry . raw64 ) ) {
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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 = * ( const uint16_t * ) p ;
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 ;
}
2022-06-29 21:42:23 +00:00
/**
* 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 ;
}