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c882cb0894
openocd/src/flash/tms470.c
mifi c882cb0894 - added autoprobe functionality 
- corrected blocksize handling from GDB "info mem" command
(thanks to Øyvind and Spen for these patches)

git-svn-id: svn://svn.berlios.de/openocd/trunk@278 b42882b7-edfa-0310-969c-e2dbd0fdcd60
2008-01-27 14:05:59 +00:00

1309 lines
38 KiB
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/***************************************************************************
* (c) Copyright 2007, 2008 by Christopher Kilgour *
* techie |_at_| whiterocker |_dot_| com *
* *
* This program is free software; you can redistribute it and/or modify *
* it under the terms of the GNU General Public License as published by *
* the Free Software Foundation; either version 2 of the License, or *
* (at your option) any later version. *
* *
* This program is distributed in the hope that it will be useful, *
* but WITHOUT ANY WARRANTY; without even the implied warranty of *
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
* GNU General Public License for more details. *
* *
* You should have received a copy of the GNU General Public License *
* along with this program; if not, write to the *
* Free Software Foundation, Inc., *
* 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. *
***************************************************************************/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include "log.h"
#include "tms470.h"
#include <string.h>
#include <unistd.h>
int
tms470_register_commands( struct command_context_s *cmd_ctx );
int
tms470_flash_bank_command( struct command_context_s *cmd_ctx,
char *cmd,
char **args,
int argc,
struct flash_bank_s *bank );
int
tms470_erase( struct flash_bank_s *bank,
int first,
int last );
int
tms470_protect( struct flash_bank_s *bank,
int set,
int first,
int last );
int
tms470_write( struct flash_bank_s *bank,
u8 *buffer,
u32 offset,
u32 count );
int
tms470_probe( struct flash_bank_s *bank );
int
tms470_auto_probe( struct flash_bank_s *bank );
int
tms470_erase_check( struct flash_bank_s *bank );
int
tms470_protect_check( struct flash_bank_s *bank );
int
tms470_info( struct flash_bank_s *bank,
char *buf,
int buf_size );
flash_driver_t tms470_flash =
{
.name = "tms470",
.register_commands = tms470_register_commands,
.flash_bank_command = tms470_flash_bank_command,
.erase = tms470_erase,
.protect = tms470_protect,
.write = tms470_write,
.probe = tms470_probe,
.auto_probe = tms470_auto_probe,
.erase_check = tms470_erase_check,
.protect_check = tms470_protect_check,
.info = tms470_info
};
/* ----------------------------------------------------------------------
Internal Support, Helpers
---------------------------------------------------------------------- */
const flash_sector_t TMS470R1A256_SECTORS[] =
{
{ 0x00000000, 0x00002000, -1, -1 },
{ 0x00002000, 0x00002000, -1, -1 },
{ 0x00004000, 0x00002000, -1, -1 },
{ 0x00006000, 0x00002000, -1, -1 },
{ 0x00008000, 0x00008000, -1, -1 },
{ 0x00010000, 0x00008000, -1, -1 },
{ 0x00018000, 0x00008000, -1, -1 },
{ 0x00020000, 0x00008000, -1, -1 },
{ 0x00028000, 0x00008000, -1, -1 },
{ 0x00030000, 0x00008000, -1, -1 },
{ 0x00038000, 0x00002000, -1, -1 },
{ 0x0003A000, 0x00002000, -1, -1 },
{ 0x0003C000, 0x00002000, -1, -1 },
{ 0x0003E000, 0x00002000, -1, -1 },
};
#define TMS470R1A256_NUM_SECTORS \
(sizeof(TMS470R1A256_SECTORS)/sizeof(TMS470R1A256_SECTORS[0]))
const flash_sector_t TMS470R1A288_BANK0_SECTORS[] =
{
{ 0x00000000, 0x00002000, -1, -1 },
{ 0x00002000, 0x00002000, -1, -1 },
{ 0x00004000, 0x00002000, -1, -1 },
{ 0x00006000, 0x00002000, -1, -1 },
};
#define TMS470R1A288_BANK0_NUM_SECTORS \
(sizeof(TMS470R1A288_BANK0_SECTORS)/sizeof(TMS470R1A288_BANK0_SECTORS[0]))
const flash_sector_t TMS470R1A288_BANK1_SECTORS[] =
{
{ 0x00040000, 0x00010000, -1, -1 },
{ 0x00050000, 0x00010000, -1, -1 },
{ 0x00060000, 0x00010000, -1, -1 },
{ 0x00070000, 0x00010000, -1, -1 },
};
#define TMS470R1A288_BANK1_NUM_SECTORS \
(sizeof(TMS470R1A288_BANK1_SECTORS)/sizeof(TMS470R1A288_BANK1_SECTORS[0]))
/* ---------------------------------------------------------------------- */
int
tms470_read_part_info( struct flash_bank_s *bank )
{
tms470_flash_bank_t *tms470_info = bank->driver_priv;
target_t *target = bank->target;
u32 device_ident_reg;
u32 silicon_version;
u32 technology_family;
u32 rom_flash;
u32 part_number;
char * part_name;
if (target->state != TARGET_HALTED)
{
WARNING( "Cannot communicate... target not halted." );
return ERROR_TARGET_NOT_HALTED;
}
/* read and parse the device identification register */
target_read_u32( target, 0xFFFFFFF0, &device_ident_reg );
INFO( "device_ident_reg=0x%08x", device_ident_reg );
if ((device_ident_reg & 7) == 0)
{
WARNING( "Cannot identify target as a TMS470 family." );
return ERROR_FLASH_OPERATION_FAILED;
}
silicon_version = (device_ident_reg >> 12) & 0xF;
technology_family = (device_ident_reg >> 11) & 1;
rom_flash = (device_ident_reg >> 10) & 1;
part_number = (device_ident_reg >> 3) & 0x7f;
/*
* If the part number is known, determine if the flash bank is valid
* based on the base address being within the known flash bank
* ranges. Then fixup/complete the remaining fields of the flash
* bank structure.
*/
switch( part_number )
{
case 0x0a:
part_name = "TMS470R1A256";
if (bank->base >= 0x00040000)
{
ERROR( "No %s flash bank contains base address 0x%08x.",
part_name, bank->base );
return ERROR_FLASH_OPERATION_FAILED;
}
tms470_info->ordinal = 0;
bank->base = 0x00000000;
bank->size = 256*1024;
bank->num_sectors = TMS470R1A256_NUM_SECTORS;
bank->sectors = malloc( sizeof( TMS470R1A256_SECTORS ) );
if (!bank->sectors)
{
return ERROR_FLASH_OPERATION_FAILED;
}
(void) memcpy( bank->sectors,
TMS470R1A256_SECTORS,
sizeof( TMS470R1A256_SECTORS ) );
break;
case 0x2b:
part_name = "TMS470R1A288";
if ((bank->base >= 0x00000000) && (bank->base < 0x00008000))
{
tms470_info->ordinal = 0;
bank->base = 0x00000000;
bank->size = 32*1024;
bank->num_sectors = TMS470R1A288_BANK0_NUM_SECTORS;
bank->sectors = malloc( sizeof( TMS470R1A288_BANK0_SECTORS ) );
if (!bank->sectors)
{
return ERROR_FLASH_OPERATION_FAILED;
}
(void) memcpy( bank->sectors,
TMS470R1A288_BANK0_SECTORS,
sizeof( TMS470R1A288_BANK0_SECTORS ) );
}
else if ((bank->base >= 0x00040000) && (bank->base < 0x00080000))
{
tms470_info->ordinal = 1;
bank->base = 0x00040000;
bank->size = 256*1024;
bank->num_sectors = TMS470R1A288_BANK1_NUM_SECTORS;
bank->sectors = malloc( sizeof( TMS470R1A288_BANK1_SECTORS ) );
if (!bank->sectors)
{
return ERROR_FLASH_OPERATION_FAILED;
}
(void) memcpy( bank->sectors,
TMS470R1A288_BANK1_SECTORS,
sizeof( TMS470R1A288_BANK1_SECTORS ) );
}
else
{
ERROR( "No %s flash bank contains base address 0x%08x.",
part_name, bank->base );
return ERROR_FLASH_OPERATION_FAILED;
}
break;
default:
WARNING( "Could not identify part 0x%02x as a member of the TMS470 family.",
part_number );
return ERROR_FLASH_OPERATION_FAILED;
}
/* turn off memory selects */
target_write_u32( target, 0xFFFFFFE4, 0x00000000 );
target_write_u32( target, 0xFFFFFFE0, 0x00000000 );
bank->chip_width = 32;
bank->bus_width = 32;
INFO( "Identified %s, ver=%d, core=%s, nvmem=%s.",
part_name,
silicon_version,
(technology_family ? "1.8v" : "3.3v"),
(rom_flash ? "rom" : "flash") );
tms470_info->device_ident_reg = device_ident_reg;
tms470_info->silicon_version = silicon_version;
tms470_info->technology_family = technology_family;
tms470_info->rom_flash = rom_flash;
tms470_info->part_number = part_number;
tms470_info->part_name = part_name;
/*
* Disable reset on address access violation.
*/
target_write_u32( target, 0xFFFFFFE0, 0x00004007 );
return ERROR_OK;
}
/* ---------------------------------------------------------------------- */
u32 keysSet = 0;
u32 flashKeys[4];
int
tms470_handle_flash_keyset_command( struct command_context_s * cmd_ctx,
char * cmd,
char ** args,
int argc )
{
if (argc > 4)
{
command_print( cmd_ctx, "tms470 flash_keyset <key0> <key1> <key2> <key3>" );
return ERROR_INVALID_ARGUMENTS;
}
else if (argc == 4)
{
int i;
for( i=0; i<4; i++ )
{
int start = (0 == strncmp( args[i], "0x", 2 )) ? 2 : 0;
if (1 != sscanf( &args[i][start], "%x", &flashKeys[i] ))
{
command_print( cmd_ctx, "could not process flash key %s", args[i] );
ERROR( "could not process flash key %s", args[i] );
return ERROR_INVALID_ARGUMENTS;
}
}
keysSet = 1;
}
else if (argc != 0)
{
command_print( cmd_ctx, "tms470 flash_keyset <key0> <key1> <key2> <key3>" );
return ERROR_INVALID_ARGUMENTS;
}
if (keysSet)
{
command_print( cmd_ctx, "using flash keys 0x%08x, 0x%08x, 0x%08x, 0x%08x",
flashKeys[0], flashKeys[1], flashKeys[2], flashKeys[3] );
}
else
{
command_print( cmd_ctx, "flash keys not set" );
}
return ERROR_OK;
}
const u32 FLASH_KEYS_ALL_ONES[] = { 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, };
const u32 FLASH_KEYS_ALL_ZEROS[] = { 0x00000000, 0x00000000,
0x00000000, 0x00000000, };
const u32 FLASH_KEYS_MIX1[] = { 0xf0fff0ff, 0xf0fff0ff,
0xf0fff0ff, 0xf0fff0ff };
const u32 FLASH_KEYS_MIX2[] = { 0x0000ffff, 0x0000ffff,
0x0000ffff, 0x0000ffff };
/* ---------------------------------------------------------------------- */
int oscMHz = 12;
int
tms470_handle_osc_megahertz_command( struct command_context_s * cmd_ctx,
char * cmd,
char ** args,
int argc )
{
if (argc > 1)
{
command_print( cmd_ctx, "tms470 osc_megahertz <MHz>" );
return ERROR_INVALID_ARGUMENTS;
}
else if (argc == 1)
{
sscanf( args[0], "%d", &oscMHz );
}
if (oscMHz <= 0)
{
ERROR( "osc_megahertz must be positive and non-zero!" );
command_print( cmd_ctx, "osc_megahertz must be positive and non-zero!" );
oscMHz = 12;
return ERROR_INVALID_ARGUMENTS;
}
command_print( cmd_ctx, "osc_megahertz=%d", oscMHz );
return ERROR_OK;
}
/* ---------------------------------------------------------------------- */
int plldis = 0;
int
tms470_handle_plldis_command( struct command_context_s * cmd_ctx,
char * cmd,
char ** args,
int argc )
{
if (argc > 1)
{
command_print( cmd_ctx, "tms470 plldis <0|1>" );
return ERROR_INVALID_ARGUMENTS;
}
else if (argc == 1)
{
sscanf( args[0], "%d", &plldis );
plldis = plldis ? 1 : 0;
}
command_print( cmd_ctx, "plldis=%d", plldis );
return ERROR_OK;
}
/* ---------------------------------------------------------------------- */
int
tms470_check_flash_unlocked( target_t * target )
{
u32 fmbbusy;
target_read_u32( target, 0xFFE89C08, &fmbbusy );
INFO( "tms470 fmbbusy=0x%08x -> %s",
fmbbusy,
fmbbusy & 0x8000 ? "unlocked" : "LOCKED" );
return fmbbusy & 0x8000 ? ERROR_OK : ERROR_FLASH_OPERATION_FAILED;
}
/* ---------------------------------------------------------------------- */
int
tms470_try_flash_keys( target_t * target,
const u32 * key_set )
{
u32 glbctrl, fmmstat;
int retval = ERROR_FLASH_OPERATION_FAILED;
/* set GLBCTRL.4 */
target_read_u32( target, 0xFFFFFFDC, &glbctrl );
target_write_u32( target, 0xFFFFFFDC, glbctrl | 0x10 );
/* only perform the key match when 3VSTAT is clear */
target_read_u32( target, 0xFFE8BC0C, &fmmstat );
if (!(fmmstat & 0x08))
{
unsigned i;
u32 fmmac2, fmbptr, fmbac2, fmbbusy, orig_fmregopt;
target_write_u32( target, 0xFFE8BC04, fmmstat & ~0x07 );
/* wait for pump ready */
do
{
target_read_u32( target, 0xFFE8A814, &fmbptr );
usleep( 1000 );
}
while( !(fmbptr & 0x0200) );
/* force max wait states */
target_read_u32( target, 0xFFE88004, &fmbac2 );
target_write_u32( target, 0xFFE88004, fmbac2 | 0xff );
/* save current access mode, force normal read mode */
target_read_u32( target, 0xFFE89C00, &orig_fmregopt );
target_write_u32( target, 0xFFE89C00, 0x00 );
for( i=0; i<4; i++ )
{
u32 tmp;
/* There is no point displaying the value of tmp, it is
* filtered by the chip. The purpose of this read is to
* prime the unlocking logic rather than read out the value.
*/
target_read_u32( target, 0x00001FF0+4*i, &tmp );
INFO( "tms470 writing fmpkey=0x%08x", key_set[i] );
target_write_u32( target, 0xFFE89C0C, key_set[i] );
}
if (ERROR_OK == tms470_check_flash_unlocked( target ))
{
/*
* There seems to be a side-effect of reading the FMPKEY
* register in that it re-enables the protection. So we
* re-enable it.
*/
for( i=0; i<4; i++ )
{
u32 tmp;
target_read_u32( target, 0x00001FF0+4*i, &tmp );
target_write_u32( target, 0xFFE89C0C, key_set[i] );
}
retval = ERROR_OK;
}
/* restore settings */
target_write_u32( target, 0xFFE89C00, orig_fmregopt );
target_write_u32( target, 0xFFE88004, fmbac2 );
}
/* clear config bit */
target_write_u32( target, 0xFFFFFFDC, glbctrl );
return retval;
}
/* ---------------------------------------------------------------------- */
int
tms470_unlock_flash( struct flash_bank_s * bank )
{
tms470_flash_bank_t * tms470_info = bank->driver_priv;
target_t * target = bank->target;
const u32 * p_key_sets[5];
unsigned i, key_set_count;
if (keysSet)
{
p_key_sets[0] = flashKeys;
p_key_sets[1] = FLASH_KEYS_ALL_ONES;
p_key_sets[2] = FLASH_KEYS_ALL_ZEROS;
p_key_sets[3] = FLASH_KEYS_MIX1;
p_key_sets[4] = FLASH_KEYS_MIX2;
}
else
{
key_set_count = 4;
p_key_sets[0] = FLASH_KEYS_ALL_ONES;
p_key_sets[1] = FLASH_KEYS_ALL_ZEROS;
p_key_sets[2] = FLASH_KEYS_MIX1;
p_key_sets[3] = FLASH_KEYS_MIX2;
}
for( i=0; i<key_set_count; i++ )
{
if (tms470_try_flash_keys( target, p_key_sets[i] ) == ERROR_OK)
{
INFO( "tms470 flash is unlocked" );
return ERROR_OK;
}
}
WARNING( "tms470 could not unlock flash memory protection level 2" );
return ERROR_FLASH_OPERATION_FAILED;
}
/* ---------------------------------------------------------------------- */
int
tms470_flash_initialize_internal_state_machine( struct flash_bank_s * bank )
{
u32 fmmac2, fmmac1, fmmaxep, k, delay, glbctrl, sysclk;
target_t *target = bank->target;
tms470_flash_bank_t * tms470_info = bank->driver_priv;
int result = ERROR_OK;
/*
* Select the desired bank to be programmed by writing BANK[2:0] of
* FMMAC2.
*/
target_read_u32( target, 0xFFE8BC04, &fmmac2 );
fmmac2 &= ~0x0007;
fmmac2 |= (tms470_info->ordinal & 7);
target_write_u32( target, 0xFFE8BC04, fmmac2 );
DEBUG( "set fmmac2=0x%04x", fmmac2 );
/*
* Disable level 1 sector protection by setting bit 15 of FMMAC1.
*/
target_read_u32( target, 0xFFE8BC00, &fmmac1 );
fmmac1 |= 0x8000;
target_write_u32( target, 0xFFE8BC00, fmmac1 );
DEBUG( "set fmmac1=0x%04x", fmmac1 );
/*
* FMTCREG=0x2fc0;
*/
target_write_u32( target, 0xFFE8BC10, 0x2fc0 );
DEBUG( "set fmtcreg=0x2fc0" );
/*
* MAXPP=50
*/
target_write_u32( target, 0xFFE8A07C, 50 );
DEBUG( "set fmmaxpp=50" );
/*
* MAXCP=0xf000+2000
*/
target_write_u32( target, 0xFFE8A084, 0xf000+2000 );
DEBUG( "set fmmaxcp=0x%04x", 0xf000+2000 );
/*
* configure VHV
*/
target_read_u32( target, 0xFFE8A080, &fmmaxep );
if (fmmaxep == 0xf000)
{
fmmaxep = 0xf000+4095;
target_write_u32( target, 0xFFE8A80C, 0x9964 );
DEBUG( "set fmptr3=0x9964" );
}
else
{
fmmaxep = 0xa000+4095;
target_write_u32( target, 0xFFE8A80C, 0x9b64 );
DEBUG( "set fmptr3=0x9b64" );
}
target_write_u32( target, 0xFFE8A080, fmmaxep );
DEBUG( "set fmmaxep=0x%04x", fmmaxep );
/*
* FMPTR4=0xa000
*/
target_write_u32( target, 0xFFE8A810, 0xa000 );
DEBUG( "set fmptr4=0xa000" );
/*
* FMPESETUP, delay parameter selected based on clock frequency.
*
* According to the TI App Note SPNU257 and flashing code, delay is
* int((sysclk(MHz) + 1) / 2), with a minimum of 5. The system
* clock is usually derived from the ZPLL module, and selected by
* the plldis global.
*/
target_read_u32( target, 0xFFFFFFDC, &glbctrl );
sysclk = (plldis ? 1 : (glbctrl & 0x08) ? 4 : 8 ) * oscMHz / (1 + (glbctrl & 7));
delay = (sysclk > 10) ? (sysclk + 1) / 2 : 5;
target_write_u32( target, 0xFFE8A018, (delay<<4)|(delay<<8) );
DEBUG( "set fmpsetup=0x%04x", (delay<<4)|(delay<<8) );
/*
* FMPVEVACCESS, based on delay.
*/
k = delay|(delay<<8);
target_write_u32( target, 0xFFE8A05C, k );
DEBUG( "set fmpvevaccess=0x%04x", k );
/*
* FMPCHOLD, FMPVEVHOLD, FMPVEVSETUP, based on delay.
*/
k <<= 1;
target_write_u32( target, 0xFFE8A034, k );
DEBUG( "set fmpchold=0x%04x", k );
target_write_u32( target, 0xFFE8A040, k );
DEBUG( "set fmpvevhold=0x%04x", k );
target_write_u32( target, 0xFFE8A024, k );
DEBUG( "set fmpvevsetup=0x%04x", k );
/*
* FMCVACCESS, based on delay.
*/
k = delay*16;
target_write_u32( target, 0xFFE8A060, k );
DEBUG( "set fmcvaccess=0x%04x", k );
/*
* FMCSETUP, based on delay.
*/
k = 0x3000 | delay*20;
target_write_u32( target, 0xFFE8A020, k );
DEBUG( "set fmcsetup=0x%04x", k );
/*
* FMEHOLD, based on delay.
*/
k = (delay*20) << 2;
target_write_u32( target, 0xFFE8A038, k );
DEBUG( "set fmehold=0x%04x", k );
/*
* PWIDTH, CWIDTH, EWIDTH, based on delay.
*/
target_write_u32( target, 0xFFE8A050, delay*8 );
DEBUG( "set fmpwidth=0x%04x", delay*8 );
target_write_u32( target, 0xFFE8A058, delay*1000 );
DEBUG( "set fmcwidth=0x%04x", delay*1000 );
target_write_u32( target, 0xFFE8A054, delay*5400 );
DEBUG( "set fmewidth=0x%04x", delay*5400 );
return result;
}
/* ---------------------------------------------------------------------- */
int
tms470_flash_status( struct flash_bank_s * bank )
{
target_t *target = bank->target;
int result = ERROR_OK;
u32 fmmstat;
target_read_u32( target, 0xFFE8BC0C, &fmmstat );
DEBUG( "set fmmstat=0x%04x", fmmstat );
if (fmmstat & 0x0080)
{
WARNING( "tms470 flash command: erase still active after busy clear." );
result = ERROR_FLASH_OPERATION_FAILED;
}
if (fmmstat & 0x0040)
{
WARNING( "tms470 flash command: program still active after busy clear." );
result = ERROR_FLASH_OPERATION_FAILED;
}
if (fmmstat & 0x0020)
{
WARNING( "tms470 flash command: invalid data command." );
result = ERROR_FLASH_OPERATION_FAILED;
}
if (fmmstat & 0x0010)
{
WARNING( "tms470 flash command: program, erase or validate sector failed." );
result = ERROR_FLASH_OPERATION_FAILED;
}
if (fmmstat & 0x0008)
{
WARNING( "tms470 flash command: voltage instability detected." );
result = ERROR_FLASH_OPERATION_FAILED;
}
if (fmmstat & 0x0006)
{
WARNING( "tms470 flash command: command suspend detected." );
result = ERROR_FLASH_OPERATION_FAILED;
}
if (fmmstat & 0x0001)
{
WARNING( "tms470 flash command: sector was locked." );
result = ERROR_FLASH_OPERATION_FAILED;
}
return result;
}
/* ---------------------------------------------------------------------- */
int
tms470_erase_sector( struct flash_bank_s * bank,
int sector )
{
u32 glbctrl, orig_fmregopt, fmbsea, fmbseb, fmmstat;
target_t *target = bank->target;
u32 flashAddr = bank->base + bank->sectors[sector].offset;
int result = ERROR_OK;
/*
* Set the bit GLBCTRL4 of the GLBCTRL register (in the System
* module) to enable writing to the flash registers }.
*/
target_read_u32( target, 0xFFFFFFDC, &glbctrl );
target_write_u32( target, 0xFFFFFFDC, glbctrl | 0x10 );
DEBUG( "set glbctrl=0x%08x", glbctrl | 0x10 );
/* Force normal read mode. */
target_read_u32( target, 0xFFE89C00, &orig_fmregopt );
target_write_u32( target, 0xFFE89C00, 0 );
DEBUG( "set fmregopt=0x%08x", 0 );
(void) tms470_flash_initialize_internal_state_machine( bank );
/*
* Select one or more bits in FMBSEA or FMBSEB to disable Level 1
* protection for the particular sector to be erased/written.
*/
if (sector < 16)
{
target_read_u32( target, 0xFFE88008, &fmbsea );
target_write_u32( target, 0xFFE88008, fmbsea | (1<<sector) );
DEBUG( "set fmbsea=0x%04x", fmbsea | (1<<sector) );
}
else
{
target_read_u32( target, 0xFFE8800C, &fmbseb );
target_write_u32( target, 0xFFE8800C, fmbseb | (1<<(sector-16)) );
DEBUG( "set fmbseb=0x%04x", fmbseb | (1<<(sector-16)) );
}
bank->sectors[sector].is_protected = 0;
/*
* clear status regiser, sent erase command, kickoff erase
*/
target_write_u16( target, flashAddr, 0x0040 );
DEBUG( "write *(u16 *)0x%08x=0x0040", flashAddr );
target_write_u16( target, flashAddr, 0x0020 );
DEBUG( "write *(u16 *)0x%08x=0x0020", flashAddr );
target_write_u16( target, flashAddr, 0xffff );
DEBUG( "write *(u16 *)0x%08x=0xffff", flashAddr );
/*
* Monitor FMMSTAT, busy until clear, then check and other flags for
* ultimate result of the operation.
*/
do
{
target_read_u32( target, 0xFFE8BC0C, &fmmstat );
if (fmmstat & 0x0100)
{
usleep( 1000 );
}
}
while( fmmstat & 0x0100 );
result = tms470_flash_status( bank );
if (sector < 16)
{
target_write_u32( target, 0xFFE88008, fmbsea );
DEBUG( "set fmbsea=0x%04x", fmbsea );
bank->sectors[sector].is_protected =
fmbsea & (1<<sector) ? 0 : 1;
}
else
{
target_write_u32( target, 0xFFE8800C, fmbseb );
DEBUG( "set fmbseb=0x%04x", fmbseb );
bank->sectors[sector].is_protected =
fmbseb & (1<<(sector-16)) ? 0 : 1;
}
target_write_u32( target, 0xFFE89C00, orig_fmregopt );
DEBUG( "set fmregopt=0x%08x", orig_fmregopt );
target_write_u32( target, 0xFFFFFFDC, glbctrl );
DEBUG( "set glbctrl=0x%08x", glbctrl );
if (result == ERROR_OK)
{
bank->sectors[sector].is_erased = 1;
}
return result;
}
/* ----------------------------------------------------------------------
Implementation of Flash Driver Interfaces
---------------------------------------------------------------------- */
int
tms470_register_commands( struct command_context_s *cmd_ctx )
{
command_t *tms470_cmd = register_command( cmd_ctx,
NULL,
"tms470",
NULL,
COMMAND_ANY,
"applies to TI tms470 family" );
register_command( cmd_ctx,
tms470_cmd,
"flash_keyset",
tms470_handle_flash_keyset_command,
COMMAND_ANY,
"tms470 flash_keyset <key0> <key1> <key2> <key3>" );
register_command( cmd_ctx,
tms470_cmd,
"osc_megahertz",
tms470_handle_osc_megahertz_command,
COMMAND_ANY,
"tms470 osc_megahertz <MHz>" );
register_command( cmd_ctx,
tms470_cmd,
"plldis",
tms470_handle_plldis_command,
COMMAND_ANY,
"tms470 plldis <0/1>" );
return ERROR_OK;
}
/* ---------------------------------------------------------------------- */
int
tms470_erase( struct flash_bank_s * bank,
int first,
int last )
{
tms470_flash_bank_t *tms470_info = bank->driver_priv;
target_t *target = bank->target;
int sector, result = ERROR_OK;
if (!tms470_info->device_ident_reg)
{
tms470_read_part_info( bank );
}
if ((first < 0) ||
(first >= bank->num_sectors) ||
(last < 0) ||
(last >= bank->num_sectors) ||
(first > last))
{
ERROR( "Sector range %d to %d invalid.", first, last );
return ERROR_FLASH_SECTOR_INVALID;
}
result = tms470_unlock_flash( bank );
if (result != ERROR_OK)
{
return result;
}
for( sector=first; sector<=last; sector++ )
{
INFO( "Erasing tms470 bank %d sector %d...",
tms470_info->ordinal, sector );
result = tms470_erase_sector( bank, sector );
if (result != ERROR_OK)
{
ERROR( "tms470 could not erase flash sector." );
break;
}
else
{
INFO( "sector erased successfully." );
}
}
return result;
}
/* ---------------------------------------------------------------------- */
int
tms470_protect( struct flash_bank_s * bank,
int set,
int first,
int last )
{
tms470_flash_bank_t *tms470_info = bank->driver_priv;
target_t *target = bank->target;
u32 fmmac2, fmbsea, fmbseb;
int sector;
if (!tms470_info->device_ident_reg)
{
tms470_read_part_info( bank );
}
if ((first < 0) ||
(first >= bank->num_sectors) ||
(last < 0) ||
(last >= bank->num_sectors) ||
(first > last))
{
ERROR( "Sector range %d to %d invalid.", first, last );
return ERROR_FLASH_SECTOR_INVALID;
}
/* enable the appropriate bank */
target_read_u32( target, 0xFFE8BC04, &fmmac2 );
target_write_u32( target, 0xFFE8BC04,
(fmmac2 & ~7) | tms470_info->ordinal );
/* get the original sector proection flags for this bank */
target_read_u32( target, 0xFFE88008, &fmbsea );
target_read_u32( target, 0xFFE8800C, &fmbseb );
for( sector=0; sector<bank->num_sectors; sector++ )
{
if (sector < 16)
{
fmbsea = set ? fmbsea & ~(1<<sector) :
fmbsea | (1<<sector);
bank->sectors[sector].is_protected = set ? 1 : 0;
}
else
{
fmbseb = set ? fmbseb & ~(1<<(sector-16)) :
fmbseb | (1<<(sector-16));
bank->sectors[sector].is_protected = set ? 1 : 0;
}
}
/* update the protection bits */
target_write_u32( target, 0xFFE88008, fmbsea );
target_write_u32( target, 0xFFE8800C, fmbseb );
return ERROR_OK;
}
/* ---------------------------------------------------------------------- */
int
tms470_write( struct flash_bank_s * bank,
u8 * buffer,
u32 offset,
u32 count )
{
target_t *target = bank->target;
tms470_flash_bank_t *tms470_info = bank->driver_priv;
u32 glbctrl, fmbac2, orig_fmregopt, fmbsea, fmbseb, fmmaxpp, fmmstat;
int i, result = ERROR_OK;
if (!tms470_info->device_ident_reg)
{
tms470_read_part_info( bank );
}
INFO( "Writing %d bytes starting at 0x%08x",
count, bank->base + offset );
/* set GLBCTRL.4 */
target_read_u32( target, 0xFFFFFFDC, &glbctrl );
target_write_u32( target, 0xFFFFFFDC, glbctrl | 0x10 );
(void) tms470_flash_initialize_internal_state_machine( bank );
/* force max wait states */
target_read_u32( target, 0xFFE88004, &fmbac2 );
target_write_u32( target, 0xFFE88004, fmbac2 | 0xff );
/* save current access mode, force normal read mode */
target_read_u32( target, 0xFFE89C00, &orig_fmregopt );
target_write_u32( target, 0xFFE89C00, 0x00 );
/*
* Disable Level 1 protection for all sectors to be erased/written.
*/
target_read_u32( target, 0xFFE88008, &fmbsea );
target_write_u32( target, 0xFFE88008, 0xffff );
target_read_u32( target, 0xFFE8800C, &fmbseb );
target_write_u32( target, 0xFFE8800C, 0xffff );
/* read MAXPP */
target_read_u32( target, 0xFFE8A07C, &fmmaxpp );
for( i=0; i<count; i+=2 )
{
u32 addr = bank->base + offset + i;
u16 word = (((u16) buffer[i]) << 8) | (u16) buffer[i+1];
if (word != 0xffff)
{
INFO( "writing 0x%04x at 0x%08x", word, addr );
/* clear status register */
target_write_u16( target, addr, 0x0040 );
/* program flash command */
target_write_u16( target, addr, 0x0010 );
/* burn the 16-bit word (big-endian) */
target_write_u16( target, addr, word );
/*
* Monitor FMMSTAT, busy until clear, then check and other flags
* for ultimate result of the operation.
*/
do
{
target_read_u32( target, 0xFFE8BC0C, &fmmstat );
if (fmmstat & 0x0100)
{
usleep( 1000 );
}
}
while( fmmstat & 0x0100 );
if (fmmstat & 0x3ff)
{
ERROR( "fmstat=0x%04x", fmmstat );
ERROR( "Could not program word 0x%04x at address 0x%08x.",
word, addr );
result = ERROR_FLASH_OPERATION_FAILED;
break;
}
}
else
{
INFO( "skipping 0xffff at 0x%08x", addr );
}
}
/* restore */
target_write_u32( target, 0xFFE88008, fmbsea );
target_write_u32( target, 0xFFE8800C, fmbseb );
target_write_u32( target, 0xFFE88004, fmbac2 );
target_write_u32( target, 0xFFE89C00, orig_fmregopt );
target_write_u32( target, 0xFFFFFFDC, glbctrl );
return result;
}
/* ---------------------------------------------------------------------- */
int
tms470_probe( struct flash_bank_s * bank )
{
tms470_flash_bank_t * tms470_info = bank->driver_priv;
tms470_info->probed = 0;
if (!tms470_info->device_ident_reg)
{
tms470_read_part_info( bank );
}
tms470_info->probed = 1;
return ERROR_OK;
}
int
tms470_auto_probe( struct flash_bank_s * bank )
{
tms470_flash_bank_t * tms470_info = bank->driver_priv;
if (tms470_info->probed)
return ERROR_OK;
return tms470_probe(bank);
}
/* ---------------------------------------------------------------------- */
int
tms470_erase_check( struct flash_bank_s * bank )
{
target_t *target = bank->target;
tms470_flash_bank_t * tms470_info = bank->driver_priv;
int sector, result = ERROR_OK;
u32 fmmac2, fmbac2, glbctrl, orig_fmregopt;
static u8 buffer[64*1024];
if (!tms470_info->device_ident_reg)
{
tms470_read_part_info( bank );
}
/* set GLBCTRL.4 */
target_read_u32( target, 0xFFFFFFDC, &glbctrl );
target_write_u32( target, 0xFFFFFFDC, glbctrl | 0x10 );
/* save current access mode, force normal read mode */
target_read_u32( target, 0xFFE89C00, &orig_fmregopt );
target_write_u32( target, 0xFFE89C00, 0x00 );
/* enable the appropriate bank */
target_read_u32( target, 0xFFE8BC04, &fmmac2 );
target_write_u32( target, 0xFFE8BC04,
(fmmac2 & ~7) | tms470_info->ordinal );
/* TCR=0 */
target_write_u32( target, 0xFFE8BC10, 0x2fc0 );
/* clear TEZ in fmbrdy */
target_write_u32( target, 0xFFE88010, 0x0b );
/* save current wait states, force max */
target_read_u32( target, 0xFFE88004, &fmbac2 );
target_write_u32( target, 0xFFE88004, fmbac2 | 0xff );
/*
* The TI primitives inspect the flash memory by reading one 32-bit
* word at a time. Here we read an entire sector and inspect it in
* an attempt to reduce the JTAG overhead.
*/
for( sector=0; sector<bank->num_sectors; sector++ )
{
if (bank->sectors[sector].is_erased != 1)
{
u32 i, addr = bank->base + bank->sectors[sector].offset;
INFO( "checking flash bank %d sector %d",
tms470_info->ordinal,
sector );
target_read_buffer( target,
addr,
bank->sectors[sector].size,
buffer );
bank->sectors[sector].is_erased = 1;
for( i=0; i<bank->sectors[sector].size; i++ )
{
if (buffer[i] != 0xff)
{
WARNING( "tms470 bank %d, sector %d, not erased.",
tms470_info->ordinal,
sector );
WARNING( "at location 0x%08x: flash data is 0x%02x.",
addr+i,
buffer[i] );
bank->sectors[sector].is_erased = 0;
break;
}
}
}
if (bank->sectors[sector].is_erased != 1)
{
result = ERROR_FLASH_SECTOR_NOT_ERASED;
break;
}
else
{
INFO( "sector erased" );
}
}
/* reset TEZ, wait states, read mode, GLBCTRL.4 */
target_write_u32( target, 0xFFE88010, 0x0f );
target_write_u32( target, 0xFFE88004, fmbac2 );
target_write_u32( target, 0xFFE89C00, orig_fmregopt );
target_write_u32( target, 0xFFFFFFDC, glbctrl );
return result;
}
/* ---------------------------------------------------------------------- */
int
tms470_protect_check( struct flash_bank_s * bank )
{
target_t *target = bank->target;
tms470_flash_bank_t * tms470_info = bank->driver_priv;
int sector, result = ERROR_OK;
u32 fmmac2, fmbsea, fmbseb;
if (!tms470_info->device_ident_reg)
{
tms470_read_part_info( bank );
}
/* enable the appropriate bank */
target_read_u32( target, 0xFFE8BC04, &fmmac2 );
target_write_u32( target, 0xFFE8BC04,
(fmmac2 & ~7) | tms470_info->ordinal );
target_read_u32( target, 0xFFE88008, &fmbsea );
target_read_u32( target, 0xFFE8800C, &fmbseb );
for( sector=0; sector<bank->num_sectors; sector++ )
{
int protected;
if (sector < 16)
{
protected = fmbsea & (1<<sector) ? 0 : 1;
bank->sectors[sector].is_protected = protected;
}
else
{
protected = fmbseb & (1<<(sector-16)) ? 0 : 1;
bank->sectors[sector].is_protected = protected;
}
DEBUG( "bank %d sector %d is %s",
tms470_info->ordinal,
sector,
protected ? "protected" : "not protected" );
}
return result;
}
/* ---------------------------------------------------------------------- */
int
tms470_info( struct flash_bank_s * bank,
char * buf,
int buf_size )
{
int used = 0;
tms470_flash_bank_t * tms470_info = bank->driver_priv;
if (!tms470_info->device_ident_reg)
{
tms470_read_part_info( bank );
}
if (!tms470_info->device_ident_reg)
{
(void) snprintf(buf, buf_size, "Cannot identify target as a TMS470\n");
return ERROR_FLASH_OPERATION_FAILED;
}
used += snprintf( buf, buf_size,
"\ntms470 information: Chip is %s\n",
tms470_info->part_name );
buf += used;
buf_size -= used;
used += snprintf( buf, buf_size,
"Flash protection level 2 is %s\n",
tms470_check_flash_unlocked( bank->target ) == ERROR_OK ? "disabled" : "enabled" );
buf += used;
buf_size -= used;
return ERROR_OK;
}
/* ---------------------------------------------------------------------- */
/*
* flash bank tms470 <base> <size> <chip_width> <bus_width> <target>
* [options...]
*/
int
tms470_flash_bank_command( struct command_context_s *cmd_ctx,
char *cmd,
char **args,
int argc,
struct flash_bank_s *bank )
{
bank->driver_priv = malloc( sizeof( tms470_flash_bank_t ) );
if (!bank->driver_priv)
{
return ERROR_FLASH_OPERATION_FAILED;
}
(void) memset( bank->driver_priv, 0, sizeof( tms470_flash_bank_t ) );
return ERROR_OK;
}
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