/**
* @file
*
* @ingroup RTEMSBSPsPowerPCMPC55XX
*
* @brief MPC55XX flash memory support.
*
* I set my MMU up to map what will finally be in flash into RAM and at the
* same time I map the flash to a different location. When the software
* is tested I can use this to copy the RAM version of the program into
* the flash and when I reboot I'm running out of flash.
*
* I use a flag word located after the boot configuration half-word to
* indicate that the MMU should be left alone, and I don't include the RCHW
* or that flag in my call to this routine.
*
* There are obviously other uses for this.
**/
/*
* Copyright (c) 2009-2011
* HD Associates, Inc.
* 18 Main Street
* Pepperell, MA 01463
* USA
* dufault@hda.com
*
* The license and distribution terms for this file may be
* found in the file LICENSE in this distribution or at
* http://www.rtems.org/license/LICENSE.
*/
#include <errno.h>
#include <sys/types.h>
#include <mpc55xx/regs.h>
#include <mpc55xx/mpc55xx.h>
#include <libcpu/powerpc-utility.h>
#include <rtems/powerpc/registers.h>
#if MPC55XX_CHIP_FAMILY == 555 || MPC55XX_CHIP_FAMILY == 556
/* Set up the memory ranges for the flash on
* the MPC5553, MPC5554, MPC5566 and MPC5567.
* I check if it is an unknown CPU and return an error.
*
* These CPUS have a low, mid, and high space of memory.
*
* Only the low space really needs a table like this, but for simplicity
* I do low, mid, and high the same way.
*/
struct range { /* A memory range. */
uint32_t lower;
uint32_t upper;
};
/* The ranges of the memory banks for the low space. All the
* chips I'm looking at share this low format, identified by LAS=6:
* 2 16K banks,
* 2 48K banks,
* 2 64K banks.
*/
static const struct range lsel_ranges[] = {
{ 0, (1*16 )*1024 - 1},
{(1*16 )*1024, (2*16 )*1024 - 1},
{(2*16 )*1024, (2*16 + 1*48 )*1024 - 1},
{(2*16 + 1*48 )*1024, (2*16 + 2*48 )*1024 - 1},
{(2*16 + 2*48 )*1024, (2*16 + 2*48 + 1*64)*1024 - 1},
{(2*16 + 2*48 + 1*64)*1024, (2*16 + 2*48 + 2*64)*1024 - 1},
};
/* The ranges of the memory blocks for the mid banks, 2 128K banks.
* Again, all the chips share this, identified by MAS=0.
*/
#define MBSTART ((2*16+2*48+2*64)*1024)
static const struct range msel_ranges[] = {
{MBSTART , MBSTART + 1*128*1024 - 1},
{MBSTART + 1*128*1024, MBSTART + 2*128*1024 - 1},
};
/* The ranges of the memory blocks for the high banks.
* There are N 128K banks, where N <= 20,
* and is identified by looking at the SIZE field.
*
* This could benefit from being redone to save a few bytes
* and provide for bigger flash spaces.
*/
#define HBSTART (MBSTART+2*128*1024)
static const struct range hbsel_ranges[] = {
{HBSTART , HBSTART + 1*128*1024 - 1},
{HBSTART + 1*128*1024, HBSTART + 2*128*1024 - 1},
{HBSTART + 2*128*1024, HBSTART + 3*128*1024 - 1},
{HBSTART + 3*128*1024, HBSTART + 4*128*1024 - 1},
{HBSTART + 4*128*1024, HBSTART + 5*128*1024 - 1},
{HBSTART + 5*128*1024, HBSTART + 6*128*1024 - 1},
{HBSTART + 6*128*1024, HBSTART + 7*128*1024 - 1},
{HBSTART + 7*128*1024, HBSTART + 8*128*1024 - 1},
{HBSTART + 8*128*1024, HBSTART + 9*128*1024 - 1},
{HBSTART + 9*128*1024, HBSTART + 10*128*1024 - 1},
{HBSTART + 10*128*1024, HBSTART + 11*128*1024 - 1},
{HBSTART + 11*128*1024, HBSTART + 12*128*1024 - 1},
{HBSTART + 12*128*1024, HBSTART + 13*128*1024 - 1},
{HBSTART + 13*128*1024, HBSTART + 14*128*1024 - 1},
{HBSTART + 14*128*1024, HBSTART + 15*128*1024 - 1},
{HBSTART + 15*128*1024, HBSTART + 16*128*1024 - 1},
{HBSTART + 16*128*1024, HBSTART + 17*128*1024 - 1},
{HBSTART + 17*128*1024, HBSTART + 18*128*1024 - 1},
{HBSTART + 18*128*1024, HBSTART + 19*128*1024 - 1},
{HBSTART + 19*128*1024, HBSTART + 20*128*1024 - 1},
};
/* Set bits in a bitmask to indicate which banks are
* within the range "first" and "last".
*/
static void
range_set(
uint32_t first,
uint32_t last,
int *p_bits,
const struct range *pr,
int n_range
)
{
int i;
int bits = 0;
for (i = 0; i < n_range; i++) {
/* If the upper limit is less than "first" or the lower limit
* is greater than "last" then the block is not in range.
*/
if ( !(pr[i].upper < first || pr[i].lower > last)) {
bits |= (1 << i); /* This block is in the range, set the bit. */
}
}
*p_bits = bits;
}
/** Return the size of the on-chip flash
* verifying that this is a device that we know about.
* @return 0 for OK, non-zero for error:
* - MPC55XX_FLASH_VERIFY_ERR for LAS not 6 or MAS not 0.
* @note This is overriding what verify means!
* - MPC55XX_FLASH_SIZE_ERR Not a chip I've checked against the manual,
* athat is, SIZE not 5, 7, or 11.
*/
int
mpc55xx_flash_size(
uint32_t *p_size /**< The size is returned here. */
)
{
/* On the MPC5553, MPC5554, MPC5566, and MP5567 the
* low address space LAS field is 0x6 and all have
* six blocks sized 2*16k, 2*48k, and 2*64k.
*
* All the mid and high address spaces have 128K blocks.
*
* The mid address space MAS size field is 0 for the above machines,
* and they all have 2 128K blocks.
*
* For the high address space we look at the
* size field to figure out the size. The SIZE field is:
*
* 5 for 1.5MB (MPC5553)
* 7 for 2MB (MPC5554, MPC5567)
* 11 for 3MB (MPC5566)
*/
int hblocks; /* The number of blocks in the high address space. */
/* Verify the configuration matches one of the chips that I've checked out.
*/
if (FLASH.MCR.B.LAS != 6 || FLASH.MCR.B.MAS != 0) {
return MPC55XX_FLASH_VERIFY_ERR;
}
switch(FLASH.MCR.B.SIZE) {
case 5:
hblocks = 8;
break;
case 7:
hblocks = 12;
break;
case 11:
hblocks = 20;
break;
default:
return MPC55XX_FLASH_SIZE_ERR;
}
/* The first two banks are 256K.
* The high block has "hblocks" 128K blocks.
*/
*p_size = 256*1024 + 256*1024 + hblocks * 128*1024;
return 0;
}
/* Unlock the flash blocks if "p_locked" points to something that is 0.
* If it is a NULL pointer then we aren't allowed to do the unlock.
*/
static int
unlock_once(int lsel, int msel, int hbsel, int *p_locked)
{
union LMLR_tag lmlr;
union SLMLR_tag slmlr;
union HLR_tag hlr;
/* If we're already locked return.
*/
if (p_locked && (*p_locked == 1)) {
return 0;
}
/* Do we have to lock something in the low or mid block?
*/
lmlr = FLASH.LMLR;
if ((lsel || msel) && (lmlr.B.LME == 0)) {
union LMLR_tag lmlr_unlock;
lmlr_unlock.B.LLOCK=~lsel;
lmlr_unlock.B.MLOCK=~msel;
lmlr_unlock.B.SLOCK=1;
if (lmlr.B.LLOCK != lmlr_unlock.B.LLOCK ||
lmlr.B.MLOCK != lmlr_unlock.B.MLOCK) {
if (p_locked == 0) {
return MPC55XX_FLASH_LOCK_ERR;
} else {
*p_locked = 1;
}
FLASH.LMLR.R = 0xA1A11111; /* Unlock. */
FLASH.LMLR = lmlr_unlock;
}
}
slmlr = FLASH.SLMLR;
if ((lsel || msel) && (slmlr.B.SLE == 0)) {
union SLMLR_tag slmlr_unlock;
slmlr_unlock.B.SLLOCK=~lsel;
slmlr_unlock.B.SMLOCK=~msel;
slmlr_unlock.B.SSLOCK=1;
if (slmlr.B.SLLOCK != slmlr_unlock.B.SLLOCK ||
slmlr.B.SMLOCK != slmlr_unlock.B.SMLOCK) {
if (p_locked == 0) {
return MPC55XX_FLASH_LOCK_ERR;
} else {
*p_locked = 1;
}
FLASH.SLMLR.R = 0xC3C33333; /* Unlock. */
FLASH.SLMLR = slmlr_unlock;
}
}
/* Do we have to unlock something in the high block?
*/
hlr = FLASH.HLR;
if (hbsel && (hlr.B.HBE == 0)) {
union HLR_tag hlr_unlock;
hlr_unlock.B.HBLOCK = ~hbsel;
if (hlr.B.HBLOCK != hlr_unlock.B.HBLOCK) {
if (p_locked == 0) {
return MPC55XX_FLASH_LOCK_ERR;
} else {
*p_locked = 1;
}
FLASH.HLR.R = 0xB2B22222; /* Unlock. */
FLASH.HLR = hlr_unlock;
}
}
return 0;
}
static inline uint32_t
tsize(int i)
{
return 1 << (10 + 2 * i);
}
static int
addr_map(
int to_phys, /* If 1 lookup physical else lookup mapped. */
const void *addr, /* The address to look up. */
uint32_t *p_result /* Result is here. */
)
{
uint32_t u_addr = (uint32_t)addr;
uint32_t mas0, mas1, mas2, mas3;
uint32_t start, end;
rtems_interrupt_level level;
int i;
for (i = 0; i < 32; i++) {
mas0 = 0x10000000 | (i << 16);
rtems_interrupt_disable(level);
PPC_SET_SPECIAL_PURPOSE_REGISTER(FSL_EIS_MAS0, mas0);
asm volatile("tlbre");
mas1 = PPC_SPECIAL_PURPOSE_REGISTER(FSL_EIS_MAS1);
mas2 = PPC_SPECIAL_PURPOSE_REGISTER(FSL_EIS_MAS2);
mas3 = PPC_SPECIAL_PURPOSE_REGISTER(FSL_EIS_MAS3);
rtems_interrupt_enable(level);
if (mas1 & 0x80000000) {
/* Valid. */
start = (to_phys ? mas2 : mas3) & 0xFFFFF000;
end = start + tsize((mas1 >> 8) & 0x0000000F);
/* Are we within range?
*/
if (start <= u_addr && end >= u_addr) {
uint32_t offset = (to_phys ? mas3 : mas2) & 0xFFFFF000;
*p_result = u_addr - offset;
return 0;
}
}
}
/* Not found in a TLB.
*/
return ESRCH;
}
/** Return the physical address corresponding to a mapped address.
@return 0 if OK, ESRCH if not found in TLB1.
**/
int
mpc55xx_physical_address(
const void *addr, /**< Mapped address. */
uint32_t *p_result /**< Result returned here. */
)
{
return addr_map(1, addr, p_result);
}
/** Return the mapped address corresponding to a mapped address.
@return 0 if OK, ESRCH if not found in TLB1.
**/
int
mpc55xx_mapped_address(
const void *addr, /**< Mapped address. */
uint32_t *p_result /**< Result returned here. */
)
{
return addr_map(0, addr, p_result);
}
/**
* Copy memory from an address into the flash when flash is relocated
* If programming fails the address that it failed at can be returned.
@note At end of operation the flash may be left writable.
* Use mpc55xx_flash_read_only() to set read-only.
@return Zero for OK, non-zero for error:
* - ESRCH Can't lookup where something lives.
* - EPERM Attempt to write to non-writable flash.
* - ETXTBSY Attempt to flash overlapping regions.
* - MPC55XX_FLASH_CONFIG_ERR for LAS not 6 or MAS not 0.
* - MPC55XX_FLASH_SIZE_ERR for SIZE not 5, 7, or 11.
* - MPC55XX_FLASH_RANGE_ERR for illegal access:
* - first or first+last outside of flash;
* - first not on a mod(8) boundary;
* - nbytes not multiple of 8.
* - MPC55XX_FLASH_ERASE_ERR Erase requested but failed.
* - MPC55XX_FLASH_PROGRAM_ERR Program requested but failed.
* - MPC55XX_FLASH_NOT_BLANK_ERR Blank check requested but not blank.
* - MPC55XX_FLASH_VERIFY_ERR Verify requested but failed.
* - MPC55XX_FLASH_LOCK_ERR Unlock requested but failed.
**/
int
mpc55xx_flash_copy_op(
void *dest, /**< An address in the flash to copy to. */
const void *src, /**< An address in memory to copy from. */
size_t nbytes, /**< The number of bytes to copy. */
uint32_t opmask, /**< Bitmask of operations to perform.
* - MPC55XX_FLASH_UNLOCK: Unlock the blocks.
* - MPC55XX_FLASH_ERASE: Erase the blocks.
* - MPC55XX_FLASH_BLANK_CHECK: Verify the blocks are blank.
* - MPC55XX_FLASH_PROGRAM: Program the FLASH.
* - MPC55XX_FLASH_VERIFY: Verify the regions match.
**/
uint32_t *p_fail /**< If not NULL then the address where the operation
* failed is returned here.
**/
)
{
uint32_t udest, usrc, flash_size;
int r;
int peg; /* Program or Erase Good - Did it work? */
int lsel; /* Low block select bits. */
int msel; /* Mid block select bits. */
int hbsel; /* High block select bits. */
int s_lsel; /* Source Low block select bits. */
int s_msel; /* Source Mid block select bits. */
int s_hbsel; /* Source High block select bits. */
int unlocked = 0;
int *p_unlocked;
int i;
int nwords; /* The number of 32 bit words to write. */
volatile uint32_t *flash; /* Where the flash is mapped in. */
volatile uint32_t *memory; /* What to copy into flash. */
const void *flashing_from; /* Where we are flahsing from.
* "const" is to match invalidate cache function signature. */
uint32_t offset; /* Where the FLASH is mapped into memory. */
if ( (r = mpc55xx_flash_size(&flash_size))) {
return r;
}
/* Get where the flash is mapped in.
*/
offset = mpc55xx_flash_address();
udest = ((uint32_t)dest) - offset;
if ( (r = mpc55xx_physical_address(src, &usrc)) ) {
return r;
}
/* Verify that the address being programmed is in flash and that it is
* a multiple of 64 bits.
* Someone else can remove the 64-bit restriction.
*/
if (udest > flash_size ||
udest + nbytes > flash_size ||
(udest & 0x7) != 0 ||
(nbytes & 0x7) != 0) {
return MPC55XX_FLASH_RANGE_ERR;
}
if (opmask == 0) {
return 0;
}
/* If we're going to do a write-style operation the flash must be writable.
*/
if ((opmask &
(MPC55XX_FLASH_UNLOCK | MPC55XX_FLASH_ERASE | MPC55XX_FLASH_PROGRAM)) &&
!mpc55xx_flash_writable()
) {
return EPERM;
}
/* If we aren't allowed to unlock then set the pointer to zero.
* That is how "unlock_once" decides we can't unlock.
*/
p_unlocked = (opmask & MPC55XX_FLASH_UNLOCK) ? &unlocked : 0;
/* Set up the bit masks for the blocks to program or erase.
*/
range_set(udest, udest + nbytes, &lsel, lsel_ranges, RTEMS_ARRAY_SIZE( lsel_ranges));
range_set(udest, udest + nbytes, &msel, msel_ranges, RTEMS_ARRAY_SIZE( msel_ranges));
range_set(udest, udest + nbytes, &hbsel, hbsel_ranges, RTEMS_ARRAY_SIZE(hbsel_ranges));
range_set(usrc, usrc + nbytes, &s_lsel, lsel_ranges, RTEMS_ARRAY_SIZE( lsel_ranges));
range_set(usrc, usrc + nbytes, &s_msel, msel_ranges, RTEMS_ARRAY_SIZE( msel_ranges));
range_set(usrc, usrc + nbytes, &s_hbsel, hbsel_ranges, RTEMS_ARRAY_SIZE(hbsel_ranges));
/* Are we attempting overlapping flash?
*/
if ((lsel & s_lsel) | (msel & s_msel) | (hbsel & s_hbsel)) {
return ETXTBSY;
}
nwords = nbytes / 4;
flash = (volatile uint32_t *)dest;
memory = (volatile uint32_t *)src;
/* In the following sections any "Step N" notes refer to
* the steps in "13.4.2.3 Flash Programming" in the reference manual.
*/
if (opmask & MPC55XX_FLASH_ERASE) { /* Erase. */
uint32_t flash_biucr_r;
if ( (r = unlock_once(lsel, msel, hbsel, p_unlocked)) ) {
return r;
}
/* Per errata "e989: FLASH: Disable Prefetch during programming and erase" */
flash_biucr_r = FLASH.BIUCR.R;
FLASH.BIUCR.B.PFLIM = 0;
FLASH.MCR.B.ESUS = 0; /* Be sure ESUS is clear. */
FLASH.MCR.B.ERS = 1; /* Step 1: Select erase. */
FLASH.LMSR.B.LSEL = lsel; /* Step 2: Select blocks to be erased. */
FLASH.LMSR.B.MSEL = msel;
FLASH.HSR.B.HBSEL = hbsel;
flash[0] = 0xffffffff; /* Step 3: Write to any address in the flash
* (the "erase interlock write)".
*/
rtems_cache_flush_multiple_data_lines(
RTEMS_DEVOLATILE(void *,flash),
sizeof(flash[0])
);
FLASH.MCR.B.EHV = 1; /* Step 4: Enable high V to start erase. */
while (FLASH.MCR.B.DONE == 0) { /* Step 5: Wait until done. */
}
peg = FLASH.MCR.B.PEG; /* Save result. */
FLASH.MCR.B.EHV = 0; /* Disable high voltage. */
FLASH.MCR.B.ERS = 0; /* De-select erase. */
FLASH.BIUCR.R = flash_biucr_r;
if (peg == 0) {
return MPC55XX_FLASH_ERASE_ERR; /* Flash erase failed. */
}
}
if (opmask & MPC55XX_FLASH_BLANK_CHECK) { /* Verify blank. */
for (i = 0; i < nwords; i++) {
if (flash[i] != 0xffffffff) {
if (p_fail) {
*p_fail = (uint32_t)(flash + i);
}
return MPC55XX_FLASH_NOT_BLANK_ERR; /* Not blank. */
}
}
}
/* Program.
*/
if (opmask & MPC55XX_FLASH_PROGRAM) {
int chunk = 0; /* Used to collect programming into 256 bit chunks. */
if ( (r = unlock_once(lsel, msel, hbsel, p_unlocked)) ) {
return r;
}
FLASH.MCR.B.PGM = 1; /* Step 1 */
for (flashing_from = (const void *)flash, i = 0; i < nwords; i += 2) {
flash[i] = memory[i]; /* Step 2 */
flash[i + 1] = memory[i + 1]; /* Always program in min 64 bits. */
/* Step 3 is "write additional words" */
/* Try to program in chunks of 256 bits.
* Collect the 64 bit writes into 256 bit ones:
*/
chunk++;
if (chunk == 4) {
/* Collected 4 64-bits for a 256 bit chunk. */
rtems_cache_flush_multiple_data_lines(flashing_from, 32); /* Flush cache. */
FLASH.MCR.B.EHV = 1; /* Step 4: Enable high V. */
while (FLASH.MCR.B.DONE == 0) { /* Step 5: Wait until done. */
}
peg = FLASH.MCR.B.PEG; /* Step 6: Save result. */
FLASH.MCR.B.EHV = 0; /* Step 7: Disable high V. */
if (peg == 0) {
FLASH.MCR.B.PGM = 0;
if (p_fail) {
*p_fail = (uint32_t)(flash + i);
}
return MPC55XX_FLASH_PROGRAM_ERR; /* Programming failed. */
}
chunk = 0; /* Reset chunk counter. */
flashing_from = (const void *)(flash + i);
}
/* Step 8: Back to step 2. */
}
if (!chunk) {
FLASH.MCR.B.PGM = 0;
} else {
/* If there is anything left in that last chunk flush it out:
*/
rtems_cache_flush_multiple_data_lines(flashing_from, chunk * 8);
FLASH.MCR.B.EHV = 1;
while (FLASH.MCR.B.DONE == 0) { /* Wait until done. */
}
peg = FLASH.MCR.B.PEG; /* Save result. */
FLASH.MCR.B.EHV = 0; /* Disable high voltage. */
FLASH.MCR.B.PGM = 0;
if (peg == 0) {
if (p_fail) {
*p_fail = (uint32_t)(flash + i);
}
return MPC55XX_FLASH_PROGRAM_ERR; /* Programming failed. */
}
}
}
if (opmask & MPC55XX_FLASH_VERIFY) { /* Verify memory matches. */
for (i = 0; i < nwords; i++) {
if (flash[i] != memory[i]) {
if (p_fail) { /* Return the failed address. */
*p_fail = (uint32_t)(flash + i);
}
return MPC55XX_FLASH_VERIFY_ERR; /* Verification failed. */
}
}
}
return 0;
}
/** Simple flash copy with a signature that matches memcpy.
@note At end of operation the flash may be left writable.
* Use mpc55xx_flash_read_only() to set read-only.
@return Zero for OK, non-zero for error.
* see flash_copy_op() for possible errors.
**/
int
mpc55xx_flash_copy(
void *dest, /**< An address in the flash to copy to. */
const void *src, /**< An address in the flash copy from. */
size_t nbytes /**< The number of bytes to copy. */
)
{
return mpc55xx_flash_copy_op(dest, src, nbytes,
(MPC55XX_FLASH_UNLOCK |
MPC55XX_FLASH_ERASE |
MPC55XX_FLASH_BLANK_CHECK |
MPC55XX_FLASH_PROGRAM |
MPC55XX_FLASH_VERIFY ), 0);
}
/** Make the flash read-write.
@note This assumes the flash is mapped by TLB1 entry 1.
*/
void
mpc55xx_flash_set_read_write(void)
{
rtems_interrupt_level level;
rtems_interrupt_disable(level);
PPC_SET_SPECIAL_PURPOSE_REGISTER( FSL_EIS_MAS0, 0x10010000);
asm volatile("tlbre");
PPC_SET_SPECIAL_PURPOSE_REGISTER_BITS(FSL_EIS_MAS3, 0x0000000C);
asm volatile("tlbwe");
rtems_interrupt_enable(level);
}
/** Make the flash read-only.
@note This assumes the flash is mapped by TLB1 entry 1.
*/
void
mpc55xx_flash_set_read_only(void)
{
rtems_interrupt_level level;
rtems_interrupt_disable(level);
PPC_SET_SPECIAL_PURPOSE_REGISTER( FSL_EIS_MAS0, 0x10010000);
asm volatile("tlbre");
PPC_CLEAR_SPECIAL_PURPOSE_REGISTER_BITS(FSL_EIS_MAS3, 0x0000000C);
asm volatile("tlbwe");
rtems_interrupt_enable(level);
}
/** See if the flash is writable.
* @note This assumes the flash is mapped by TLB1 entry 1.
* @note It needs to be writable by both user and supervisor.
*/
int
mpc55xx_flash_writable(void)
{
uint32_t mas3;
rtems_interrupt_level level;
rtems_interrupt_disable(level);
PPC_SET_SPECIAL_PURPOSE_REGISTER( FSL_EIS_MAS0, 0x10010000);
asm volatile("tlbre");
mas3 = PPC_SPECIAL_PURPOSE_REGISTER(FSL_EIS_MAS3);
rtems_interrupt_enable(level);
return ((mas3 & 0x0000000C) == 0x0000000C) ? 1 : 0;
}
/** Return the address where the flash is mapped in.
@note This assumes the flash is mapped by TLB1 entry 1.
**/
uint32_t
mpc55xx_flash_address(void)
{
uint32_t mas2;
rtems_interrupt_level level;
rtems_interrupt_disable(level);
PPC_SET_SPECIAL_PURPOSE_REGISTER( FSL_EIS_MAS0, 0x10010000);
asm volatile("tlbre");
mas2 = PPC_SPECIAL_PURPOSE_REGISTER(FSL_EIS_MAS2);
rtems_interrupt_enable(level);
return mas2 & 0xFFFFF000;
}
#endif /* MPC55XX_CHIP_FAMILY == 555 || MPC55XX_CHIP_FAMILY == 556 */