nodemcu-firmware/components/platform/platform_flash.c

249 lines
7.7 KiB
C

#include "platform.h"
#include "flash_api.h"
#include <stddef.h>
#include <stdlib.h>
#include <string.h>
// ****************************************************************************
// Internal flash support functions
/* This symbol must be exported by the linker command file and contain the
* size of all the sections packed into the irom0_flash.bin file, in order
* for us to find the end of used flash.
*/
extern char _irom0_bin_min_sz[];
// Helper function: find the flash sector in which an address resides
// Return the sector number, as well as the start and end address of the sector
static uint32_t flashh_find_sector( uint32_t address, uint32_t *pstart, uint32_t *pend )
{
#ifdef INTERNAL_FLASH_SECTOR_SIZE
// All the sectors in the flash have the same size, so just align the address
uint32_t sect_id = address / INTERNAL_FLASH_SECTOR_SIZE;
if( pstart )
*pstart = sect_id * INTERNAL_FLASH_SECTOR_SIZE ;
if( pend )
*pend = ( sect_id + 1 ) * INTERNAL_FLASH_SECTOR_SIZE - 1;
return sect_id;
#else // #ifdef INTERNAL_FLASH_SECTOR_SIZE
// The flash has blocks of different size
// Their size is decribed in the INTERNAL_FLASH_SECTOR_ARRAY macro
const uint32_t flash_sect_size[] = INTERNAL_FLASH_SECTOR_ARRAY;
uint32_t total = 0, i = 0;
while( ( total <= address ) && ( i < sizeof( flash_sect_size ) / sizeof( uint32_t ) ) )
total += flash_sect_size[ i ++ ];
if( pstart )
*pstart = ( total - flash_sect_size[ i - 1 ] );
if( pend )
*pend = total - 1;
return i - 1;
#endif // #ifdef INTERNAL_FLASH_SECTOR_SIZE
}
uint32_t platform_flash_get_sector_of_address( uint32_t addr )
{
return flashh_find_sector( addr, NULL, NULL );
}
uint32_t platform_flash_get_num_sectors(void)
{
#ifdef INTERNAL_FLASH_SECTOR_SIZE
return INTERNAL_FLASH_SIZE / INTERNAL_FLASH_SECTOR_SIZE;
#else // #ifdef INTERNAL_FLASH_SECTOR_SIZE
const uint32_t flash_sect_size[] = INTERNAL_FLASH_SECTOR_ARRAY;
return sizeof( flash_sect_size ) / sizeof( uint32_t );
#endif // #ifdef INTERNAL_FLASH_SECTOR_SIZE
}
uint32_t platform_flash_get_first_free_block_address( uint32_t *psect )
{
uint32_t flash_offs = IROM0_START_FLASH_ADDR + (uint32_t)_irom0_bin_min_sz;
uint32_t sect =
(flash_offs + INTERNAL_FLASH_SECTOR_SIZE-1)/INTERNAL_FLASH_SECTOR_SIZE;
++sect; /* compensate for various headers not counted in _irom0_bin_min_sz */
if (psect)
*psect = sect;
return sect * INTERNAL_FLASH_SECTOR_SIZE;
}
uint32_t platform_flash_write( const void *from, uint32_t toaddr, uint32_t size )
{
#ifndef INTERNAL_FLASH_WRITE_UNIT_SIZE
return platform_s_flash_write( from, toaddr, size );
#else // #ifindef INTERNAL_FLASH_WRITE_UNIT_SIZE
uint32_t temp, rest, ssize = size;
unsigned i;
char tmpdata[ INTERNAL_FLASH_WRITE_UNIT_SIZE ];
const uint8_t *pfrom = ( const uint8_t* )from;
const uint32_t blksize = INTERNAL_FLASH_WRITE_UNIT_SIZE;
const uint32_t blkmask = INTERNAL_FLASH_WRITE_UNIT_SIZE - 1;
// Align the start
if( toaddr & blkmask )
{
rest = toaddr & blkmask;
temp = toaddr & ~blkmask; // this is the actual aligned address
// memcpy( tmpdata, ( const void* )temp, blksize );
platform_s_flash_read( tmpdata, temp, blksize );
for( i = rest; size && ( i < blksize ); i ++, size --, pfrom ++ )
tmpdata[ i ] = *pfrom;
platform_s_flash_write( tmpdata, temp, blksize );
if( size == 0 )
return ssize;
toaddr = temp + blksize;
}
// The start address is now a multiple of blksize
// Compute how many bytes we can write as multiples of blksize
rest = size & blkmask;
temp = size & ~blkmask;
// Program the blocks now
if( temp )
{
platform_s_flash_write( pfrom, toaddr, temp );
toaddr += temp;
pfrom += temp;
}
// And the final part of a block if needed
if( rest )
{
// memcpy( tmpdata, ( const void* )toaddr, blksize );
platform_s_flash_read( tmpdata, toaddr, blksize );
for( i = 0; size && ( i < rest ); i ++, size --, pfrom ++ )
tmpdata[ i ] = *pfrom;
platform_s_flash_write( tmpdata, toaddr, blksize );
}
return ssize;
#endif // #ifndef INTERNAL_FLASH_WRITE_UNIT_SIZE
}
uint32_t platform_flash_read( void *to, uint32_t fromaddr, uint32_t size )
{
#ifndef INTERNAL_FLASH_READ_UNIT_SIZE
return platform_s_flash_read( to, fromaddr, size );
#else // #ifindef INTERNAL_FLASH_READ_UNIT_SIZE
uint32_t temp, rest, ssize = size;
unsigned i;
char tmpdata[ INTERNAL_FLASH_READ_UNIT_SIZE ] __attribute__ ((aligned(INTERNAL_FLASH_READ_UNIT_SIZE)));
uint8_t *pto = ( uint8_t* )to;
const uint32_t blksize = INTERNAL_FLASH_READ_UNIT_SIZE;
const uint32_t blkmask = INTERNAL_FLASH_READ_UNIT_SIZE - 1;
// Align the start
if( fromaddr & blkmask )
{
rest = fromaddr & blkmask;
temp = fromaddr & ~blkmask; // this is the actual aligned address
platform_s_flash_read( tmpdata, temp, blksize );
for( i = rest; size && ( i < blksize ); i ++, size --, pto ++ )
*pto = tmpdata[ i ];
if( size == 0 )
return ssize;
fromaddr = temp + blksize;
}
// The start address is now a multiple of blksize
// Compute how many bytes we can read as multiples of blksize
rest = size & blkmask;
temp = size & ~blkmask;
// Program the blocks now
if( temp )
{
platform_s_flash_read( pto, fromaddr, temp );
fromaddr += temp;
pto += temp;
}
// And the final part of a block if needed
if( rest )
{
platform_s_flash_read( tmpdata, fromaddr, blksize );
for( i = 0; size && ( i < rest ); i ++, size --, pto ++ )
*pto = tmpdata[ i ];
}
return ssize;
#endif // #ifndef INTERNAL_FLASH_READ_UNIT_SIZE
}
/*
* Assumptions:
* > toaddr is INTERNAL_FLASH_WRITE_UNIT_SIZE aligned
* > size is a multiple of INTERNAL_FLASH_WRITE_UNIT_SIZE
*/
uint32_t platform_s_flash_write( const void *from, uint32_t toaddr, uint32_t size )
{
SpiFlashOpResult r;
const uint32_t blkmask = INTERNAL_FLASH_WRITE_UNIT_SIZE - 1;
uint32_t *apbuf = NULL;
uint32_t fromaddr = (uint32_t)from;
if( (fromaddr & blkmask ) || (fromaddr >= INTERNAL_FLASH_MAPPED_ADDRESS)) {
apbuf = (uint32_t *)malloc(size);
if(!apbuf)
return 0;
memcpy(apbuf, from, size);
}
r = flash_write(toaddr, apbuf?(uint32 *)apbuf:(uint32 *)from, size);
if(apbuf)
free(apbuf);
if(SPI_FLASH_RESULT_OK == r)
return size;
else{
NODE_ERR( "ERROR in flash_write: r=%d at %08X\n", ( int )r, ( unsigned )toaddr);
return 0;
}
}
/*
* Assumptions:
* > fromaddr is INTERNAL_FLASH_READ_UNIT_SIZE aligned
* > size is a multiple of INTERNAL_FLASH_READ_UNIT_SIZE
*/
uint32_t platform_s_flash_read( void *to, uint32_t fromaddr, uint32_t size )
{
if (size==0)
return 0;
SpiFlashOpResult r;
const uint32_t blkmask = (INTERNAL_FLASH_READ_UNIT_SIZE - 1);
if( ((uint32_t)to) & blkmask )
{
uint32_t size2=size-INTERNAL_FLASH_READ_UNIT_SIZE;
uint32* to2=(uint32*)((((uint32_t)to)&(~blkmask))+INTERNAL_FLASH_READ_UNIT_SIZE);
r = flash_read(fromaddr, to2, size2);
if(SPI_FLASH_RESULT_OK == r)
{
memmove(to,to2,size2);
char back[ INTERNAL_FLASH_READ_UNIT_SIZE ] __attribute__ ((aligned(INTERNAL_FLASH_READ_UNIT_SIZE)));
r=flash_read(fromaddr+size2,(uint32*)back,INTERNAL_FLASH_READ_UNIT_SIZE);
memcpy((uint8_t*)to+size2,back,INTERNAL_FLASH_READ_UNIT_SIZE);
}
}
else
r = flash_read(fromaddr, (uint32 *)to, size);
if(SPI_FLASH_RESULT_OK == r)
return size;
else{
NODE_ERR( "ERROR in flash_read: r=%d at %08X\n", ( int )r, ( unsigned )fromaddr);
return 0;
}
}
int platform_flash_erase_sector( uint32_t sector_id )
{
return flash_erase( sector_id ) == SPI_FLASH_RESULT_OK ? PLATFORM_OK : PLATFORM_ERR;
}
uint32_t platform_flash_mapped2phys (uint32_t mapped_addr)
{
// FIXME: need to take actual memory maps into account!
return mapped_addr - IROM0_START_MAPPED_ADDR + IROM0_START_FLASH_ADDR;
}