#define O_BINARY 0
#endif
-
-#define LOG_TAG __FILE__
-#define DLOG(format, args...) ugly_log(UDEBUG, LOG_TAG, format, ## args)
-#define ILOG(format, args...) ugly_log(UINFO, LOG_TAG, format, ## args)
-#define WLOG(format, args...) ugly_log(UWARN, LOG_TAG, format, ## args)
-#define ELOG(format, args...) ugly_log(UERROR, LOG_TAG, format, ## args)
-#define fatal(format, args...) ugly_log(UFATAL, LOG_TAG, format, ## args)
-
/* todo: stm32l15xxx flash memory, pm0062 manual */
/* stm32f FPEC flash controller interface, pm0063 manual */
#define FLASH_L1_FPRG 10
#define FLASH_L1_PROG 3
+//32L4 register base is at FLASH_REGS_ADDR (0x40022000)
+#define STM32L4_FLASH_KEYR (FLASH_REGS_ADDR + 0x08)
+#define STM32L4_FLASH_SR (FLASH_REGS_ADDR + 0x10)
+#define STM32L4_FLASH_CR (FLASH_REGS_ADDR + 0x14)
+#define STM32L4_FLASH_OPTR (FLASH_REGS_ADDR + 0x20)
+
+#define STM32L4_FLASH_SR_BSY 16
+#define STM32L4_FLASH_SR_ERRMASK 0x3f8 /* SR [9:3] */
+
+#define STM32L4_FLASH_CR_LOCK 31 /* Lock control register */
+#define STM32L4_FLASH_CR_PG 0 /* Program */
+#define STM32L4_FLASH_CR_PER 1 /* Page erase */
+#define STM32L4_FLASH_CR_MER1 2 /* Bank 1 erase */
+#define STM32L4_FLASH_CR_MER2 15 /* Bank 2 erase */
+#define STM32L4_FLASH_CR_STRT 16 /* Start command */
+#define STM32L4_FLASH_CR_BKER 11 /* Bank select for page erase */
+#define STM32L4_FLASH_CR_PNB 3 /* Page number (8 bits) */
+// Bits requesting flash operations (useful when we want to clear them)
+#define STM32L4_FLASH_CR_OPBITS \
+ ((1lu<<STM32L4_FLASH_CR_PG) | (1lu<<STM32L4_FLASH_CR_PER) \
+ | (1lu<<STM32L4_FLASH_CR_MER1) | (1lu<<STM32L4_FLASH_CR_MER1))
+// Page is fully specified by BKER and PNB
+#define STM32L4_FLASH_CR_PAGEMASK (0x1fflu << STM32L4_FLASH_CR_PNB)
+
+#define STM32L4_FLASH_OPTR_DUALBANK 21
+
+//STM32L0x flash register base and offsets
+//same as 32L1 above
+// RM0090 - DM00031020.pdf
+#define STM32L0_FLASH_REGS_ADDR ((uint32_t)0x40022000)
+#define FLASH_ACR_OFF ((uint32_t) 0x00)
+#define FLASH_PECR_OFF ((uint32_t) 0x04)
+#define FLASH_PDKEYR_OFF ((uint32_t) 0x08)
+#define FLASH_PEKEYR_OFF ((uint32_t) 0x0c)
+#define FLASH_PRGKEYR_OFF ((uint32_t) 0x10)
+#define FLASH_OPTKEYR_OFF ((uint32_t) 0x14)
+#define FLASH_SR_OFF ((uint32_t) 0x18)
+#define FLASH_OBR_OFF ((uint32_t) 0x1c)
+#define FLASH_WRPR_OFF ((uint32_t) 0x20)
+
+
//STM32F4
#define FLASH_F4_REGS_ADDR ((uint32_t)0x40023c00)
#define FLASH_F4_CR_LOCK 31
#define FLASH_F4_CR_SER 1
#define FLASH_F4_CR_SNB 3
-#define FLASH_F4_CR_SNB_MASK 0x38
+#define FLASH_F4_CR_SNB_MASK 0xf8
#define FLASH_F4_SR_BSY 16
+#define L1_WRITE_BLOCK_SIZE 0x80
+#define L0_WRITE_BLOCK_SIZE 0x40
void write_uint32(unsigned char* buf, uint32_t ui) {
if (!is_bigendian()) { // le -> le (don't swap)
}
static uint32_t __attribute__((unused)) read_flash_rdp(stlink_t *sl) {
- return stlink_read_debug32(sl, FLASH_WRPR) & 0xff;
+ uint32_t rdp;
+ stlink_read_debug32(sl, FLASH_WRPR, &rdp);
+ return rdp & 0xff;
}
static inline uint32_t read_flash_wrpr(stlink_t *sl) {
- return stlink_read_debug32(sl, FLASH_WRPR);
+ uint32_t wrpr;
+ stlink_read_debug32(sl, FLASH_WRPR, &wrpr);
+ return wrpr;
}
static inline uint32_t read_flash_obr(stlink_t *sl) {
- return stlink_read_debug32(sl, FLASH_OBR);
+ uint32_t obr;
+ stlink_read_debug32(sl, FLASH_OBR, &obr);
+ return obr;
}
static inline uint32_t read_flash_cr(stlink_t *sl) {
- uint32_t res;
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP))
- res = stlink_read_debug32(sl, FLASH_F4_CR);
+ uint32_t reg, res;
+
+ if (sl->flash_type == FLASH_TYPE_F4)
+ reg = FLASH_F4_CR;
+ else if (sl->flash_type == FLASH_TYPE_L4)
+ reg = STM32L4_FLASH_CR;
else
- res = stlink_read_debug32(sl, FLASH_CR);
+ reg = FLASH_CR;
+
+ stlink_read_debug32(sl, reg, &res);
+
#if DEBUG_FLASH
fprintf(stdout, "CR:0x%x\n", res);
#endif
static inline unsigned int is_flash_locked(stlink_t *sl) {
/* return non zero for true */
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP))
- return read_flash_cr(sl) & (1 << FLASH_F4_CR_LOCK);
+ uint32_t cr_lock_shift, cr = read_flash_cr(sl);
+
+ if (sl->flash_type == FLASH_TYPE_F4)
+ cr_lock_shift = FLASH_F4_CR_LOCK;
+ else if (sl->flash_type == FLASH_TYPE_L4)
+ cr_lock_shift = STM32L4_FLASH_CR_LOCK;
else
- return read_flash_cr(sl) & (1 << FLASH_CR_LOCK);
+ cr_lock_shift = FLASH_CR_LOCK;
+
+ return cr & (1 << cr_lock_shift);
}
static void unlock_flash(stlink_t *sl) {
+ uint32_t key_reg;
/* the unlock sequence consists of 2 write cycles where
2 key values are written to the FLASH_KEYR register.
an invalid sequence results in a definitive lock of
the FPEC block until next reset.
- */
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP)) {
- stlink_write_debug32(sl, FLASH_F4_KEYR, FLASH_KEY1);
- stlink_write_debug32(sl, FLASH_F4_KEYR, FLASH_KEY2);
- } else {
- stlink_write_debug32(sl, FLASH_KEYR, FLASH_KEY1);
- stlink_write_debug32(sl, FLASH_KEYR, FLASH_KEY2);
- }
+ */
+ if (sl->flash_type == FLASH_TYPE_F4)
+ key_reg = FLASH_F4_KEYR;
+ else if (sl->flash_type == FLASH_TYPE_L4)
+ key_reg = STM32L4_FLASH_KEYR;
+ else
+ key_reg = FLASH_KEYR;
+ stlink_write_debug32(sl, key_reg, FLASH_KEY1);
+ stlink_write_debug32(sl, key_reg, FLASH_KEY2);
}
static int unlock_flash_if(stlink_t *sl) {
}
static void lock_flash(stlink_t *sl) {
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP)) {
- const uint32_t n = read_flash_cr(sl) | (1 << FLASH_F4_CR_LOCK);
- stlink_write_debug32(sl, FLASH_F4_CR, n);
+ uint32_t cr_lock_shift, cr_reg, n;
+
+ if (sl->flash_type == FLASH_TYPE_F4) {
+ cr_reg = FLASH_F4_CR;
+ cr_lock_shift = FLASH_F4_CR_LOCK;
+ } else if (sl->flash_type == FLASH_TYPE_L4) {
+ cr_reg = STM32L4_FLASH_CR;
+ cr_lock_shift = STM32L4_FLASH_CR_LOCK;
} else {
- /* write to 1 only. reset by hw at unlock sequence */
- const uint32_t n = read_flash_cr(sl) | (1 << FLASH_CR_LOCK);
- stlink_write_debug32(sl, FLASH_CR, n);
+ cr_reg = FLASH_CR;
+ cr_lock_shift = FLASH_CR_LOCK;
}
+
+ n = read_flash_cr(sl) | (1 << cr_lock_shift);
+ stlink_write_debug32(sl, cr_reg, n);
}
static void set_flash_cr_pg(stlink_t *sl) {
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP)) {
- uint32_t x = read_flash_cr(sl);
- x |= (1 << FLASH_CR_PG);
- stlink_write_debug32(sl, FLASH_F4_CR, x);
+ uint32_t cr_reg, x;
+
+ x = read_flash_cr(sl);
+
+ if (sl->flash_type == FLASH_TYPE_F4) {
+ cr_reg = FLASH_F4_CR;
+ x |= 1 << FLASH_CR_PG;
+ } else if (sl->flash_type == FLASH_TYPE_L4) {
+ cr_reg = STM32L4_FLASH_CR;
+ x &= ~STM32L4_FLASH_CR_OPBITS;
+ x |= 1 << STM32L4_FLASH_CR_PG;
} else {
- const uint32_t n = 1 << FLASH_CR_PG;
- stlink_write_debug32(sl, FLASH_CR, n);
+ cr_reg = FLASH_CR;
+ x = 1 << FLASH_CR_PG;
}
+
+ stlink_write_debug32(sl, cr_reg, x);
}
static void __attribute__((unused)) clear_flash_cr_pg(stlink_t *sl) {
- const uint32_t n = read_flash_cr(sl) & ~(1 << FLASH_CR_PG);
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP))
- stlink_write_debug32(sl, FLASH_F4_CR, n);
+ uint32_t cr_reg, n;
+
+ if (sl->flash_type == FLASH_TYPE_F4)
+ cr_reg = FLASH_F4_CR;
+ else if (sl->flash_type == FLASH_TYPE_L4)
+ cr_reg = STM32L4_FLASH_CR;
else
- stlink_write_debug32(sl, FLASH_CR, n);
+ cr_reg = FLASH_CR;
+
+ n = read_flash_cr(sl) & ~(1 << FLASH_CR_PG);
+ stlink_write_debug32(sl, cr_reg, n);
}
static void set_flash_cr_per(stlink_t *sl) {
}
static void set_flash_cr_mer(stlink_t *sl) {
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP))
- stlink_write_debug32(sl, FLASH_F4_CR,
- stlink_read_debug32(sl, FLASH_F4_CR) | (1 << FLASH_CR_MER));
- else
- stlink_write_debug32(sl, FLASH_CR,
- stlink_read_debug32(sl, FLASH_CR) | (1 << FLASH_CR_MER));
+ uint32_t val, cr_reg, cr_mer;
+
+ if (sl->flash_type == FLASH_TYPE_F4) {
+ cr_reg = FLASH_F4_CR;
+ cr_mer = 1 << FLASH_CR_MER;
+ } else if (sl->flash_type == FLASH_TYPE_L4) {
+ cr_reg = STM32L4_FLASH_CR;
+ cr_mer = (1 << STM32L4_FLASH_CR_MER1) | (1 << STM32L4_FLASH_CR_MER2);
+ } else {
+ cr_reg = FLASH_CR;
+ cr_mer = 1 << FLASH_CR_MER;
+ }
+
+ stlink_read_debug32(sl, cr_reg, &val);
+ val |= cr_mer;
+ stlink_write_debug32(sl, cr_reg, val);
}
static void __attribute__((unused)) clear_flash_cr_mer(stlink_t *sl) {
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP))
- stlink_write_debug32(sl, FLASH_F4_CR,
- stlink_read_debug32(sl, FLASH_F4_CR) & ~(1 << FLASH_CR_MER));
- else
- stlink_write_debug32(sl, FLASH_CR,
- stlink_read_debug32(sl, FLASH_CR) & ~(1 << FLASH_CR_MER));
+ uint32_t val, cr_reg, cr_mer;
+
+ if (sl->flash_type == FLASH_TYPE_F4) {
+ cr_reg = FLASH_F4_CR;
+ cr_mer = 1 << FLASH_CR_MER;
+ } else if (sl->flash_type == FLASH_TYPE_L4) {
+ cr_reg = STM32L4_FLASH_CR;
+ cr_mer = (1 << STM32L4_FLASH_CR_MER1) | (1 << STM32L4_FLASH_CR_MER2);
+ } else {
+ cr_reg = FLASH_CR;
+ cr_mer = 1 << FLASH_CR_MER;
+ }
+
+ stlink_read_debug32(sl, cr_reg, &val);
+ val &= ~cr_mer;
+ stlink_write_debug32(sl, cr_reg, val);
}
static void set_flash_cr_strt(stlink_t *sl) {
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP)) {
- uint32_t x = read_flash_cr(sl);
- x |= (1 << FLASH_F4_CR_STRT);
- stlink_write_debug32(sl, FLASH_F4_CR, x);
+ uint32_t val, cr_reg, cr_strt;
+
+ if (sl->flash_type == FLASH_TYPE_F4) {
+ cr_reg = FLASH_F4_CR;
+ cr_strt = 1 << FLASH_F4_CR_STRT;
+ } else if (sl->flash_type == FLASH_TYPE_L4) {
+ cr_reg = STM32L4_FLASH_CR;
+ cr_strt = 1 << STM32L4_FLASH_CR_STRT;
} else {
- stlink_write_debug32(sl, FLASH_CR,
- stlink_read_debug32(sl, FLASH_CR) | (1 << FLASH_CR_STRT) );
+ cr_reg = FLASH_CR;
+ cr_strt = 1 << FLASH_CR_STRT;
}
+
+ stlink_read_debug32(sl, cr_reg, &val);
+ val |= cr_strt;
+ stlink_write_debug32(sl, cr_reg, val);
}
static inline uint32_t read_flash_acr(stlink_t *sl) {
- return stlink_read_debug32(sl, FLASH_ACR);
+ uint32_t acr;
+ stlink_read_debug32(sl, FLASH_ACR, &acr);
+ return acr;
}
static inline uint32_t read_flash_sr(stlink_t *sl) {
- uint32_t res;
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP))
- res = stlink_read_debug32(sl, FLASH_F4_SR);
+ uint32_t res, sr_reg;
+
+ if (sl->flash_type == FLASH_TYPE_F4)
+ sr_reg = FLASH_F4_SR;
+ else if (sl->flash_type == FLASH_TYPE_L4)
+ sr_reg = STM32L4_FLASH_SR;
else
- res = stlink_read_debug32(sl, FLASH_SR);
- //fprintf(stdout, "SR:0x%x\n", *(uint32_t*) sl->q_buf);
+ sr_reg = FLASH_SR;
+
+ stlink_read_debug32(sl, sr_reg, &res);
+
return res;
}
static inline unsigned int is_flash_busy(stlink_t *sl) {
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP))
- return read_flash_sr(sl) & (1 << FLASH_F4_SR_BSY);
+ uint32_t sr_busy_shift;
+
+ if (sl->flash_type == FLASH_TYPE_F4)
+ sr_busy_shift = FLASH_F4_SR_BSY;
+ else if (sl->flash_type == FLASH_TYPE_L4)
+ sr_busy_shift = STM32L4_FLASH_SR_BSY;
else
- return read_flash_sr(sl) & (1 << FLASH_SR_BSY);
+ sr_busy_shift = FLASH_SR_BSY;
+
+ return read_flash_sr(sl) & (1 << sr_busy_shift);
}
static void wait_flash_busy(stlink_t *sl) {
stlink_write_debug32(sl, FLASH_F4_CR, x);
}
-#if 0 /* todo */
-
-static void disable_flash_read_protection(stlink_t *sl) {
- /* erase the option byte area */
- /* rdp = 0x00a5; */
- /* reset */
+static inline void write_flash_cr_bker_pnb(stlink_t *sl, uint32_t n) {
+ stlink_write_debug32(sl, STM32L4_FLASH_SR, 0xFFFFFFFF & ~(1<<STM32L4_FLASH_SR_BSY));
+ uint32_t x = read_flash_cr(sl);
+ x &=~ STM32L4_FLASH_CR_OPBITS;
+ x &=~ STM32L4_FLASH_CR_PAGEMASK;
+ x &= ~(1<<STM32L4_FLASH_CR_MER1);
+ x &= ~(1<<STM32L4_FLASH_CR_MER2);
+ x |= (n << STM32L4_FLASH_CR_PNB);
+ x |= (1lu << STM32L4_FLASH_CR_PER);
+#if DEBUG_FLASH
+ fprintf(stdout, "BKER:PNB:0x%x 0x%x\n", x, n);
+#endif
+ stlink_write_debug32(sl, STM32L4_FLASH_CR, x);
}
-#endif /* todo */
-
// Delegates to the backends...
void stlink_close(stlink_t *sl) {
DLOG("*** stlink_close ***\n");
+ if (!sl)
+ return;
sl->backend->close(sl);
free(sl);
}
-void stlink_exit_debug_mode(stlink_t *sl) {
+int stlink_exit_debug_mode(stlink_t *sl) {
+ int ret;
+
DLOG("*** stlink_exit_debug_mode ***\n");
- stlink_write_debug32(sl, DHCSR, DBGKEY);
- sl->backend->exit_debug_mode(sl);
+ ret = stlink_write_debug32(sl, DHCSR, DBGKEY);
+ if (ret == -1)
+ return ret;
+
+ return sl->backend->exit_debug_mode(sl);
}
-void stlink_enter_swd_mode(stlink_t *sl) {
+int stlink_enter_swd_mode(stlink_t *sl) {
DLOG("*** stlink_enter_swd_mode ***\n");
- sl->backend->enter_swd_mode(sl);
+ return sl->backend->enter_swd_mode(sl);
}
// Force the core into the debug mode -> halted state.
-void stlink_force_debug(stlink_t *sl) {
+int stlink_force_debug(stlink_t *sl) {
DLOG("*** stlink_force_debug_mode ***\n");
- sl->backend->force_debug(sl);
+ return sl->backend->force_debug(sl);
}
-void stlink_exit_dfu_mode(stlink_t *sl) {
+int stlink_exit_dfu_mode(stlink_t *sl) {
DLOG("*** stlink_exit_dfu_mode ***\n");
- sl->backend->exit_dfu_mode(sl);
+ return sl->backend->exit_dfu_mode(sl);
}
-uint32_t stlink_core_id(stlink_t *sl) {
+int stlink_core_id(stlink_t *sl) {
+ int ret;
+
DLOG("*** stlink_core_id ***\n");
- sl->backend->core_id(sl);
+ ret = sl->backend->core_id(sl);
+ if (ret == -1) {
+ ELOG("Failed to read core_id\n");
+ return ret;
+ }
if (sl->verbose > 2)
stlink_print_data(sl);
DLOG("core_id = 0x%08x\n", sl->core_id);
- return sl->core_id;
+ return ret;
}
-uint32_t stlink_chip_id(stlink_t *sl) {
- uint32_t chip_id = stlink_read_debug32(sl, 0xE0042000);
- if (chip_id == 0) chip_id = stlink_read_debug32(sl, 0x40015800); //Try Corex M0 DBGMCU_IDCODE register address
- return chip_id;
+int stlink_chip_id(stlink_t *sl, uint32_t *chip_id) {
+ int ret;
+
+ ret = stlink_read_debug32(sl, 0xE0042000, chip_id);
+ if (ret == -1)
+ return ret;
+
+ if (*chip_id == 0)
+ ret = stlink_read_debug32(sl, 0x40015800, chip_id); //Try Corex M0 DBGMCU_IDCODE register address
+
+ return ret;
}
/**
* @param sl stlink context
* @param cpuid pointer to the result object
*/
-void stlink_cpu_id(stlink_t *sl, cortex_m3_cpuid_t *cpuid) {
- uint32_t raw = stlink_read_debug32(sl, CM3_REG_CPUID);
+int stlink_cpu_id(stlink_t *sl, cortex_m3_cpuid_t *cpuid) {
+ uint32_t raw;
+
+ if (stlink_read_debug32(sl, CM3_REG_CPUID, &raw))
+ return -1;
+
cpuid->implementer_id = (raw >> 24) & 0x7f;
cpuid->variant = (raw >> 20) & 0xf;
cpuid->part = (raw >> 4) & 0xfff;
cpuid->revision = raw & 0xf;
- return;
+ return 0;
}
/**
int stlink_load_device_params(stlink_t *sl) {
ILOG("Loading device parameters....\n");
const chip_params_t *params = NULL;
- sl->core_id = stlink_core_id(sl);
- uint32_t chip_id = stlink_chip_id(sl);
+ stlink_core_id(sl);
+ uint32_t chip_id;
+ uint32_t flash_size;
+ stlink_chip_id(sl, &chip_id);
sl->chip_id = chip_id & 0xfff;
/* Fix chip_id for F4 rev A errata , Read CPU ID, as CoreID is the same for F2/F4*/
if (sl->chip_id == 0x411) {
- uint32_t cpuid = stlink_read_debug32(sl, 0xE000ED00);
+ uint32_t cpuid;
+ stlink_read_debug32(sl, 0xE000ED00, &cpuid);
if ((cpuid & 0xfff0) == 0xc240)
sl->chip_id = 0x413;
}
return -1;
}
+ if (params->flash_type == FLASH_TYPE_UNKNOWN) {
+ WLOG("Invalid flash type, please check device declaration\n");
+ return -1;
+ }
+
+
// These are fixed...
sl->flash_base = STM32_FLASH_BASE;
sl->sram_base = STM32_SRAM_BASE;
-
- // read flash size from hardware, if possible...
- if (sl->chip_id == STM32_CHIPID_F2) {
- sl->flash_size = 0x100000; /* Use maximum, User must care!*/
- } else if (sl->chip_id == STM32_CHIPID_F4 ||
- sl->chip_id == STM32_CHIPID_F4_LP) {
- sl->flash_size = 0x100000; //todo: RM0090 error; size register same address as unique ID
- } else if (sl->chip_id == STM32_CHIPID_L1_MEDIUM || sl->chip_id == STM32_CHIPID_L1_MEDIUM_PLUS) {
- // if the flash size is zero, we assume it is 128k, if not we calculate the real value
- uint32_t flash_size = stlink_read_debug32(sl,params->flash_size_reg) & 0xffff;
- if ( flash_size == 0 ) {
- sl->flash_size = 128 * 1024;
- } else {
- sl->flash_size = flash_size * 1024;
- }
+ stlink_read_debug32(sl,(params->flash_size_reg) & ~3, &flash_size);
+ if (params->flash_size_reg & 2)
+ flash_size = flash_size >>16;
+ flash_size = flash_size & 0xffff;
+
+ if ((sl->chip_id == STM32_CHIPID_L1_MEDIUM || sl->chip_id == STM32_CHIPID_L1_MEDIUM_PLUS) && ( flash_size == 0 )) {
+ sl->flash_size = 128 * 1024;
+ } else if (sl->chip_id == STM32_CHIPID_L1_CAT2) {
+ sl->flash_size = (flash_size & 0xff) * 1024;
} else if ((sl->chip_id & 0xFFF) == STM32_CHIPID_L1_HIGH) {
- uint32_t flash_size = stlink_read_debug32(sl, params->flash_size_reg) & 0x1;
// 0 is 384k and 1 is 256k
if ( flash_size == 0 ) {
sl->flash_size = 384 * 1024;
sl->flash_size = 256 * 1024;
}
} else {
- uint32_t flash_size = stlink_read_debug32(sl, params->flash_size_reg) & 0xffff;
sl->flash_size = flash_size * 1024;
}
+ sl->flash_type = params->flash_type;
sl->flash_pgsz = params->flash_pagesize;
sl->sram_size = params->sram_size;
sl->sys_base = params->bootrom_base;
sl->sys_size = params->bootrom_size;
+ //medium and low devices have the same chipid. ram size depends on flash size.
+ //STM32F100xx datasheet Doc ID 16455 Table 2
+ if(sl->chip_id == STM32_CHIPID_F1_VL_MEDIUM_LOW && sl->flash_size < 64 * 1024){
+ sl->sram_size = 0x1000;
+ }
+
ILOG("Device connected is: %s, id %#x\n", params->description, chip_id);
// TODO make note of variable page size here.....
ILOG("SRAM size: %#x bytes (%d KiB), Flash: %#x bytes (%d KiB) in pages of %zd bytes\n",
- sl->sram_size, sl->sram_size / 1024, sl->flash_size, sl->flash_size / 1024,
- sl->flash_pgsz);
+ sl->sram_size, sl->sram_size / 1024, sl->flash_size, sl->flash_size / 1024,
+ sl->flash_pgsz);
return 0;
}
-void stlink_reset(stlink_t *sl) {
+int stlink_reset(stlink_t *sl) {
DLOG("*** stlink_reset ***\n");
- sl->backend->reset(sl);
+ return sl->backend->reset(sl);
}
-void stlink_jtag_reset(stlink_t *sl, int value) {
+int stlink_jtag_reset(stlink_t *sl, int value) {
DLOG("*** stlink_jtag_reset ***\n");
- sl->backend->jtag_reset(sl, value);
+ return sl->backend->jtag_reset(sl, value);
}
-void stlink_run(stlink_t *sl) {
+int stlink_run(stlink_t *sl) {
DLOG("*** stlink_run ***\n");
- sl->backend->run(sl);
+ return sl->backend->run(sl);
}
-void stlink_status(stlink_t *sl) {
+int stlink_status(stlink_t *sl) {
+ int ret;
+
DLOG("*** stlink_status ***\n");
- sl->backend->status(sl);
+ ret = sl->backend->status(sl);
stlink_core_stat(sl);
+
+ return ret;
}
/**
return;
}
-void stlink_version(stlink_t *sl) {
+int stlink_version(stlink_t *sl) {
DLOG("*** looking up stlink version\n");
- sl->backend->version(sl);
+ if (sl->backend->version(sl))
+ return -1;
+
_parse_version(sl, &sl->version);
DLOG("st vid = 0x%04x (expect 0x%04x)\n", sl->version.st_vid, USB_ST_VID);
if (sl->version.swim_v == 0) {
DLOG(" notice: the firmware doesn't support a swim interface\n");
}
+
+ return 0;
}
int stlink_target_voltage(stlink_t *sl) {
DLOG("*** reading target voltage\n");
if (sl->backend->target_voltage != NULL) {
voltage = sl->backend->target_voltage(sl);
- if (voltage != -1) {
+ if (voltage != -1) {
DLOG("target voltage = %ldmV\n", voltage);
- } else {
+ } else {
DLOG("error reading target voltage\n");
- }
+ }
} else {
DLOG("reading voltage not supported by backend\n");
}
return voltage;
}
-uint32_t stlink_read_debug32(stlink_t *sl, uint32_t addr) {
- uint32_t data = sl->backend->read_debug32(sl, addr);
- DLOG("*** stlink_read_debug32 %x is %#x\n", data, addr);
- return data;
+int stlink_read_debug32(stlink_t *sl, uint32_t addr, uint32_t *data) {
+ int ret;
+
+ ret = sl->backend->read_debug32(sl, addr, data);
+ if (!ret)
+ DLOG("*** stlink_read_debug32 %x is %#x\n", *data, addr);
+
+ return ret;
}
-void stlink_write_debug32(stlink_t *sl, uint32_t addr, uint32_t data) {
+int stlink_write_debug32(stlink_t *sl, uint32_t addr, uint32_t data) {
DLOG("*** stlink_write_debug32 %x to %#x\n", data, addr);
- sl->backend->write_debug32(sl, addr, data);
+ return sl->backend->write_debug32(sl, addr, data);
}
-void stlink_write_mem32(stlink_t *sl, uint32_t addr, uint16_t len) {
+int stlink_write_mem32(stlink_t *sl, uint32_t addr, uint16_t len) {
DLOG("*** stlink_write_mem32 %u bytes to %#x\n", len, addr);
if (len % 4 != 0) {
fprintf(stderr, "Error: Data length doesn't have a 32 bit alignment: +%d byte.\n", len % 4);
abort();
}
- sl->backend->write_mem32(sl, addr, len);
+ return sl->backend->write_mem32(sl, addr, len);
}
-void stlink_read_mem32(stlink_t *sl, uint32_t addr, uint16_t len) {
+int stlink_read_mem32(stlink_t *sl, uint32_t addr, uint16_t len) {
DLOG("*** stlink_read_mem32 ***\n");
if (len % 4 != 0) { // !!! never ever: fw gives just wrong values
fprintf(stderr, "Error: Data length doesn't have a 32 bit alignment: +%d byte.\n",
len % 4);
abort();
}
- sl->backend->read_mem32(sl, addr, len);
+ return sl->backend->read_mem32(sl, addr, len);
}
-void stlink_write_mem8(stlink_t *sl, uint32_t addr, uint16_t len) {
+int stlink_write_mem8(stlink_t *sl, uint32_t addr, uint16_t len) {
DLOG("*** stlink_write_mem8 ***\n");
if (len > 0x40 ) { // !!! never ever: Writing more then 0x40 bytes gives unexpected behaviour
fprintf(stderr, "Error: Data length > 64: +%d byte.\n",
len);
abort();
}
- sl->backend->write_mem8(sl, addr, len);
+ return sl->backend->write_mem8(sl, addr, len);
}
-void stlink_read_all_regs(stlink_t *sl, reg *regp) {
+int stlink_read_all_regs(stlink_t *sl, reg *regp) {
DLOG("*** stlink_read_all_regs ***\n");
- sl->backend->read_all_regs(sl, regp);
+ return sl->backend->read_all_regs(sl, regp);
}
-void stlink_read_all_unsupported_regs(stlink_t *sl, reg *regp) {
+int stlink_read_all_unsupported_regs(stlink_t *sl, reg *regp) {
DLOG("*** stlink_read_all_unsupported_regs ***\n");
- sl->backend->read_all_unsupported_regs(sl, regp);
+ return sl->backend->read_all_unsupported_regs(sl, regp);
}
-void stlink_write_reg(stlink_t *sl, uint32_t reg, int idx) {
+int stlink_write_reg(stlink_t *sl, uint32_t reg, int idx) {
DLOG("*** stlink_write_reg\n");
- sl->backend->write_reg(sl, reg, idx);
+ return sl->backend->write_reg(sl, reg, idx);
}
-void stlink_read_reg(stlink_t *sl, int r_idx, reg *regp) {
+int stlink_read_reg(stlink_t *sl, int r_idx, reg *regp) {
DLOG("*** stlink_read_reg\n");
DLOG(" (%d) ***\n", r_idx);
if (r_idx > 20 || r_idx < 0) {
fprintf(stderr, "Error: register index must be in [0..20]\n");
- return;
+ return -1;
}
- sl->backend->read_reg(sl, r_idx, regp);
+ return sl->backend->read_reg(sl, r_idx, regp);
}
-void stlink_read_unsupported_reg(stlink_t *sl, int r_idx, reg *regp) {
+int stlink_read_unsupported_reg(stlink_t *sl, int r_idx, reg *regp) {
int r_convert;
DLOG("*** stlink_read_unsupported_reg\n");
r_convert = 0x40 + (r_idx - 0x20);
} else {
fprintf(stderr, "Error: register address must be in [0x1C..0x40]\n");
- return;
+ return -1;
}
- sl->backend->read_unsupported_reg(sl, r_convert, regp);
+ return sl->backend->read_unsupported_reg(sl, r_convert, regp);
}
-void stlink_write_unsupported_reg(stlink_t *sl, uint32_t val, int r_idx, reg *regp) {
+int stlink_write_unsupported_reg(stlink_t *sl, uint32_t val, int r_idx, reg *regp) {
int r_convert;
DLOG("*** stlink_write_unsupported_reg\n");
r_convert = 0x40 + (r_idx - 0x20);
} else {
fprintf(stderr, "Error: register address must be in [0x1C..0x40]\n");
- return;
+ return -1;
}
- sl->backend->write_unsupported_reg(sl, val, r_convert, regp);
+ return sl->backend->write_unsupported_reg(sl, val, r_convert, regp);
}
unsigned int is_core_halted(stlink_t *sl) {
return sl->q_buf[0] == STLINK_CORE_HALTED;
}
-void stlink_step(stlink_t *sl) {
+int stlink_step(stlink_t *sl) {
DLOG("*** stlink_step ***\n");
- sl->backend->step(sl);
+ return sl->backend->step(sl);
}
int stlink_current_mode(stlink_t *sl) {
int mode = sl->backend->current_mode(sl);
switch (mode) {
- case STLINK_DEV_DFU_MODE:
- DLOG("stlink current mode: dfu\n");
- return mode;
- case STLINK_DEV_DEBUG_MODE:
- DLOG("stlink current mode: debug (jtag or swd)\n");
- return mode;
- case STLINK_DEV_MASS_MODE:
- DLOG("stlink current mode: mass\n");
- return mode;
+ case STLINK_DEV_DFU_MODE:
+ DLOG("stlink current mode: dfu\n");
+ return mode;
+ case STLINK_DEV_DEBUG_MODE:
+ DLOG("stlink current mode: debug (jtag or swd)\n");
+ return mode;
+ case STLINK_DEV_MASS_MODE:
+ DLOG("stlink current mode: mass\n");
+ return mode;
}
DLOG("stlink mode: unknown!\n");
return STLINK_DEV_UNKNOWN_MODE;
return;
switch (sl->q_buf[0]) {
- case STLINK_CORE_RUNNING:
- sl->core_stat = STLINK_CORE_RUNNING;
- DLOG(" core status: running\n");
- return;
- case STLINK_CORE_HALTED:
- sl->core_stat = STLINK_CORE_HALTED;
- DLOG(" core status: halted\n");
- return;
- default:
- sl->core_stat = STLINK_CORE_STAT_UNKNOWN;
- fprintf(stderr, " core status: unknown\n");
+ case STLINK_CORE_RUNNING:
+ sl->core_stat = STLINK_CORE_RUNNING;
+ DLOG(" core status: running\n");
+ return;
+ case STLINK_CORE_HALTED:
+ sl->core_stat = STLINK_CORE_HALTED;
+ DLOG(" core status: halted\n");
+ return;
+ default:
+ sl->core_stat = STLINK_CORE_STAT_UNKNOWN;
+ fprintf(stderr, " core status: unknown\n");
}
}
for (int i = 0; i < sl->q_len; i++) {
if (i % 16 == 0) {
/*
- if (sl->q_data_dir == Q_DATA_OUT)
- fprintf(stdout, "\n<- 0x%08x ", sl->q_addr + i);
- else
- fprintf(stdout, "\n-> 0x%08x ", sl->q_addr + i);
- */
+ if (sl->q_data_dir == Q_DATA_OUT)
+ fprintf(stdout, "\n<- 0x%08x ", sl->q_addr + i);
+ else
+ fprintf(stdout, "\n-> 0x%08x ", sl->q_addr + i);
+ */
}
fprintf(stdout, " %02x", (unsigned int) sl->q_buf[i]);
}
int error = -1;
size_t off;
+ size_t len;
mapped_file_t mf = MAPPED_FILE_INITIALIZER;
+ uint32_t val;
if (map_file(&mf, path) == -1) {
} else if ((addr + mf.len) > (sl->sram_base + sl->sram_size)) {
fprintf(stderr, "addr too high\n");
goto on_error;
- } else if ((addr & 3) || (mf.len & 3)) {
+ } else if (addr & 3) {
/* todo */
- fprintf(stderr, "unaligned addr or size\n");
+ fprintf(stderr, "unaligned addr\n");
goto on_error;
}
+
+ len = mf.len;
+
+ if(len & 3) {
+ len -= len & 3;
+ }
+
/* do the copy by 1k blocks */
- for (off = 0; off < mf.len; off += 1024) {
+ for (off = 0; off < len; off += 1024) {
size_t size = 1024;
- if ((off + size) > mf.len)
- size = mf.len - off;
+ if ((off + size) > len)
+ size = len - off;
memcpy(sl->q_buf, mf.base + off, size);
stlink_write_mem32(sl, addr + off, size);
}
+ if(mf.len > len) {
+ memcpy(sl->q_buf, mf.base + len, mf.len - len);
+ stlink_write_mem8(sl, addr + len, mf.len - len);
+ }
+
/* check the file ha been written */
if (check_file(sl, &mf, addr) == -1) {
fprintf(stderr, "check_file() == -1\n");
/* success */
error = 0;
/* set stack*/
- stlink_write_reg(sl, stlink_read_debug32(sl, addr ),13);
+ stlink_read_debug32(sl, addr, &val);
+ stlink_write_reg(sl, val, 13);
/* Set PC to the reset routine*/
- stlink_write_reg(sl, stlink_read_debug32(sl, addr + 4),15);
+ stlink_read_debug32(sl, addr + 4, &val);
+ stlink_write_reg(sl, val, 15);
stlink_run(sl);
on_error:
int error = -1;
size_t off;
- int num_empty = 0;
- unsigned char erased_pattern = (sl->chip_id == STM32_CHIPID_L1_MEDIUM || sl->chip_id == STM32_CHIPID_L1_MEDIUM_PLUS
- || sl->chip_id == STM32_CHIPID_L1_HIGH) ? 0:0xff;
const int fd = open(path, O_RDWR | O_TRUNC | O_CREAT, 00700);
if (fd == -1) {
}
if (size <1)
- size = sl->flash_size;
+ size = sl->flash_size;
if (size > sl->flash_size)
- size = sl->flash_size;
+ size = sl->flash_size;
- /* do the copy by 1k blocks */
- for (off = 0; off < size; off += 1024) {
- size_t read_size = 1024;
- size_t rounded_size;
- size_t index;
- if ((off + read_size) > size)
- read_size = size - off;
+ size_t cmp_size = (sl->flash_pgsz > 0x1800)? 0x1800:sl->flash_pgsz;
+ for (off = 0; off < size; off += cmp_size) {
+ size_t aligned_size;
- /* round size if needed */
- rounded_size = read_size;
- if (rounded_size & 3)
- rounded_size = (rounded_size + 4) & ~(3);
-
- stlink_read_mem32(sl, addr + off, rounded_size);
-
- for(index = 0; index < read_size; index ++) {
- if (sl->q_buf[index] == erased_pattern)
- num_empty ++;
- else
- num_empty = 0;
- }
- if (write(fd, sl->q_buf, read_size) != (ssize_t) read_size) {
- fprintf(stderr, "write() != read_size\n");
+ /* adjust last page size */
+ if ((off + cmp_size) > size)
+ cmp_size = size - off;
+
+ aligned_size = cmp_size;
+ if (aligned_size & (4 - 1))
+ aligned_size = (cmp_size + 4) & ~(4 - 1);
+
+ stlink_read_mem32(sl, addr + off, aligned_size);
+
+ if (write(fd, sl->q_buf, sl->q_len) != (ssize_t) aligned_size) {
+ fprintf(stderr, "write() != aligned_size\n");
goto on_error;
}
}
- /* Ignore NULL Bytes at end of file */
- if (!ftruncate(fd, size - num_empty)) {
- error = -1;
- }
-
/* success */
error = 0;
}
uint32_t calculate_F4_sectornum(uint32_t flashaddr){
+ uint32_t offset = 0;
flashaddr &= ~STM32_FLASH_BASE; //Page now holding the actual flash address
- if (flashaddr<0x4000) return (0);
- else if(flashaddr<0x8000) return(1);
- else if(flashaddr<0xc000) return(2);
- else if(flashaddr<0x10000) return(3);
- else if(flashaddr<0x20000) return(4);
- else return(flashaddr/0x20000)+4;
+ if (flashaddr >= 0x100000) {
+ offset = 12;
+ flashaddr -= 0x100000;
+ }
+ if (flashaddr<0x4000) return (offset + 0);
+ else if(flashaddr<0x8000) return(offset + 1);
+ else if(flashaddr<0xc000) return(offset + 2);
+ else if(flashaddr<0x10000) return(offset + 3);
+ else if(flashaddr<0x20000) return(offset + 4);
+ else return offset + (flashaddr/0x20000) +4;
+
+}
+uint32_t calculate_F7_sectornum(uint32_t flashaddr){
+ flashaddr &= ~STM32_FLASH_BASE; //Page now holding the actual flash address
+ if(flashaddr<0x20000) return(flashaddr/0x8000);
+ else if(flashaddr<0x40000) return(4);
+ else return(flashaddr/0x40000) +4;
+
+}
+
+// Returns BKER:PNB for the given page address
+uint32_t calculate_L4_page(stlink_t *sl, uint32_t flashaddr) {
+ uint32_t bker = 0;
+ uint32_t flashopt;
+ stlink_read_debug32(sl, STM32L4_FLASH_OPTR, &flashopt);
+ flashaddr -= STM32_FLASH_BASE;
+ if (flashopt & (1lu << STM32L4_FLASH_OPTR_DUALBANK)) {
+ uint32_t banksize = sl->flash_size / 2;
+ if (flashaddr >= banksize) {
+ flashaddr -= banksize;
+ bker = 0x100;
+ }
+ }
+ // For 1MB chips without the dual-bank option set, the page address will
+ // overflow into the BKER bit, which gives us the correct bank:page value.
+ return bker | flashaddr/sl->flash_pgsz;
}
uint32_t stlink_calculate_pagesize(stlink_t *sl, uint32_t flashaddr){
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP)) {
- uint32_t sector=calculate_F4_sectornum(flashaddr);
- if (sector<4) sl->flash_pgsz=0x4000;
- else if(sector<5) sl->flash_pgsz=0x10000;
- else sl->flash_pgsz=0x20000;
- }
- return (sl->flash_pgsz);
+ if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) || (sl->chip_id == STM32_CHIPID_F4_DE) ||
+ (sl->chip_id == STM32_CHIPID_F4_LP) || (sl->chip_id == STM32_CHIPID_F4_HD) || (sl->chip_id == STM32_CHIPID_F411RE) ||
+ (sl->chip_id == STM32_CHIPID_F446) || (sl->chip_id == STM32_CHIPID_F4_DSI)) {
+ uint32_t sector=calculate_F4_sectornum(flashaddr);
+ if (sector>= 12) {
+ sector -= 12;
+ }
+ if (sector<4) sl->flash_pgsz=0x4000;
+ else if(sector<5) sl->flash_pgsz=0x10000;
+ else sl->flash_pgsz=0x20000;
+ }
+ else if (sl->chip_id == STM32_CHIPID_F7) {
+ uint32_t sector=calculate_F7_sectornum(flashaddr);
+ if (sector<4) sl->flash_pgsz=0x8000;
+ else if(sector<5) sl->flash_pgsz=0x20000;
+ else sl->flash_pgsz=0x40000;
+ }
+ return (sl->flash_pgsz);
}
/**
*/
int stlink_erase_flash_page(stlink_t *sl, stm32_addr_t flashaddr)
{
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP)) {
- /* wait for ongoing op to finish */
- wait_flash_busy(sl);
-
- /* unlock if locked */
- unlock_flash_if(sl);
+ if (sl->flash_type == FLASH_TYPE_F4 || sl->flash_type == FLASH_TYPE_L4) {
+ /* wait for ongoing op to finish */
+ wait_flash_busy(sl);
- /* select the page to erase */
- // calculate the actual page from the address
- uint32_t sector=calculate_F4_sectornum(flashaddr);
+ /* unlock if locked */
+ unlock_flash_if(sl);
- fprintf(stderr, "EraseFlash - Sector:0x%x Size:0x%x\n", sector, stlink_calculate_pagesize(sl, flashaddr));
- write_flash_cr_snb(sl, sector);
+ /* select the page to erase */
+ if (sl->chip_id == STM32_CHIPID_L4) {
+ // calculate the actual bank+page from the address
+ uint32_t page = calculate_L4_page(sl, flashaddr);
- /* start erase operation */
- set_flash_cr_strt(sl);
+ fprintf(stderr, "EraseFlash - Page:0x%x Size:0x%x ", page, stlink_calculate_pagesize(sl, flashaddr));
- /* wait for completion */
- wait_flash_busy(sl);
+ write_flash_cr_bker_pnb(sl, page);
+ } else if (sl->chip_id == STM32_CHIPID_F7) {
+ // calculate the actual page from the address
+ uint32_t sector=calculate_F7_sectornum(flashaddr);
- /* relock the flash */
- //todo: fails to program if this is in
- lock_flash(sl);
-#if DEBUG_FLASH
- fprintf(stdout, "Erase Final CR:0x%x\n", read_flash_cr(sl));
-#endif
- } else if (sl->chip_id == STM32_CHIPID_L1_MEDIUM || sl->chip_id == STM32_CHIPID_L1_MEDIUM_PLUS
- || sl->chip_id == STM32_CHIPID_L1_HIGH) {
+ fprintf(stderr, "EraseFlash - Sector:0x%x Size:0x%x ", sector, stlink_calculate_pagesize(sl, flashaddr));
- uint32_t val;
+ write_flash_cr_snb(sl, sector);
+ } else {
+ // calculate the actual page from the address
+ uint32_t sector=calculate_F4_sectornum(flashaddr);
- /* check if the locks are set */
- val = stlink_read_debug32(sl, STM32L_FLASH_PECR);
- if((val & (1<<0))||(val & (1<<1))) {
- /* disable pecr protection */
- stlink_write_debug32(sl, STM32L_FLASH_PEKEYR, 0x89abcdef);
- stlink_write_debug32(sl, STM32L_FLASH_PEKEYR, 0x02030405);
+ fprintf(stderr, "EraseFlash - Sector:0x%x Size:0x%x ", sector, stlink_calculate_pagesize(sl, flashaddr));
+
+ //the SNB values for flash sectors in the second bank do not directly follow the values for the first bank on 2mb devices...
+ if (sector >= 12) sector += 4;
- /* check pecr.pelock is cleared */
- val = stlink_read_debug32(sl, STM32L_FLASH_PECR);
- if (val & (1 << 0)) {
- WLOG("pecr.pelock not clear (%#x)\n", val);
- return -1;
+ write_flash_cr_snb(sl, sector);
}
- /* unlock program memory */
- stlink_write_debug32(sl, STM32L_FLASH_PRGKEYR, 0x8c9daebf);
- stlink_write_debug32(sl, STM32L_FLASH_PRGKEYR, 0x13141516);
+ /* start erase operation */
+ set_flash_cr_strt(sl);
- /* check pecr.prglock is cleared */
- val = stlink_read_debug32(sl, STM32L_FLASH_PECR);
- if (val & (1 << 1)) {
- WLOG("pecr.prglock not clear (%#x)\n", val);
- return -1;
+ /* wait for completion */
+ wait_flash_busy(sl);
+
+ /* relock the flash */
+ //todo: fails to program if this is in
+ lock_flash(sl);
+#if DEBUG_FLASH
+ fprintf(stdout, "Erase Final CR:0x%x\n", read_flash_cr(sl));
+#endif
+ } else if (sl->flash_type == FLASH_TYPE_L0) {
+
+ uint32_t val;
+ uint32_t flash_regs_base;
+ if (sl->chip_id == STM32_CHIPID_L0) {
+ flash_regs_base = STM32L0_FLASH_REGS_ADDR;
+ } else {
+ flash_regs_base = STM32L_FLASH_REGS_ADDR;
}
- }
- /* unused: unlock the option byte block */
-#if 0
- stlink_write_debug32(sl, STM32L_FLASH_OPTKEYR, 0xfbead9c8);
- stlink_write_debug32(sl, STM32L_FLASH_OPTKEYR, 0x24252627);
+ /* check if the locks are set */
+ stlink_read_debug32(sl, flash_regs_base + FLASH_PECR_OFF, &val);
+ if((val & (1<<0))||(val & (1<<1))) {
+ /* disable pecr protection */
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PEKEYR_OFF, 0x89abcdef);
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PEKEYR_OFF, 0x02030405);
+
+ /* check pecr.pelock is cleared */
+ stlink_read_debug32(sl, flash_regs_base + FLASH_PECR_OFF, &val);
+ if (val & (1 << 0)) {
+ WLOG("pecr.pelock not clear (%#x)\n", val);
+ return -1;
+ }
- /* check pecr.optlock is cleared */
- val = stlink_read_debug32(sl, STM32L_FLASH_PECR);
- if (val & (1 << 2)) {
- fprintf(stderr, "pecr.prglock not clear\n");
- return -1;
- }
-#endif
+ /* unlock program memory */
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PRGKEYR_OFF, 0x8c9daebf);
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PRGKEYR_OFF, 0x13141516);
- /* set pecr.{erase,prog} */
- val |= (1 << 9) | (1 << 3);
- stlink_write_debug32(sl, STM32L_FLASH_PECR, val);
+ /* check pecr.prglock is cleared */
+ stlink_read_debug32(sl, flash_regs_base + FLASH_PECR_OFF, &val);
+ if (val & (1 << 1)) {
+ WLOG("pecr.prglock not clear (%#x)\n", val);
+ return -1;
+ }
+ }
+ /* set pecr.{erase,prog} */
+ val |= (1 << 9) | (1 << 3);
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PECR_OFF, val);
#if 0 /* fix_to_be_confirmed */
- /* wait for sr.busy to be cleared
- MP: Test shows that busy bit is not set here. Perhaps, PM0062 is
- wrong and we do not need to wait here for clearing the busy bit.
- TEXANE: ok, if experience says so and it works for you, we comment
- it. If someone has a problem, please drop an email.
- */
- while ((stlink_read_debug32(sl, STM32L_FLASH_SR) & (1 << 0)) != 0)
- ;
+ /* wait for sr.busy to be cleared
+ * MP: Test shows that busy bit is not set here. Perhaps, PM0062 is
+ * wrong and we do not need to wait here for clearing the busy bit.
+ * TEXANE: ok, if experience says so and it works for you, we comment
+ * it. If someone has a problem, please drop an email.
+ */
+ do {
+ stlink_read_debug32(sl, STM32L_FLASH_SR, &val)
+ } while((val & (1 << 0)) != 0);
#endif /* fix_to_be_confirmed */
- /* write 0 to the first word of the page to be erased */
- stlink_write_debug32(sl, flashaddr, 0);
-
- /* MP: It is better to wait for clearing the busy bit after issuing
- page erase command, even though PM0062 recommends to wait before it.
- Test shows that a few iterations is performed in the following loop
- before busy bit is cleared.*/
- while ((stlink_read_debug32(sl, STM32L_FLASH_SR) & (1 << 0)) != 0)
- ;
-
- /* reset lock bits */
- val = stlink_read_debug32(sl, STM32L_FLASH_PECR)
- | (1 << 0) | (1 << 1) | (1 << 2);
- stlink_write_debug32(sl, STM32L_FLASH_PECR, val);
- } else if (sl->core_id == STM32VL_CORE_ID
- || sl->core_id == STM32F0_CORE_ID
- || sl->chip_id == STM32_CHIPID_F3
- || sl->chip_id == STM32_CHIPID_F37x) {
- /* wait for ongoing op to finish */
- wait_flash_busy(sl);
+ /* write 0 to the first word of the page to be erased */
+ stlink_write_debug32(sl, flashaddr, 0);
+
+ /* MP: It is better to wait for clearing the busy bit after issuing
+ page erase command, even though PM0062 recommends to wait before it.
+ Test shows that a few iterations is performed in the following loop
+ before busy bit is cleared.*/
+ do {
+ stlink_read_debug32(sl, flash_regs_base + FLASH_SR_OFF, &val);
+ } while ((val & (1 << 0)) != 0);
+
+ /* reset lock bits */
+ stlink_read_debug32(sl, flash_regs_base + FLASH_PECR_OFF, &val);
+ val |= (1 << 0) | (1 << 1) | (1 << 2);
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PECR_OFF, val);
+ } else if (sl->flash_type == FLASH_TYPE_F0) {
+ /* wait for ongoing op to finish */
+ wait_flash_busy(sl);
- /* unlock if locked */
- unlock_flash_if(sl);
+ /* unlock if locked */
+ unlock_flash_if(sl);
- /* set the page erase bit */
- set_flash_cr_per(sl);
+ /* set the page erase bit */
+ set_flash_cr_per(sl);
- /* select the page to erase */
- write_flash_ar(sl, flashaddr);
+ /* select the page to erase */
+ write_flash_ar(sl, flashaddr);
- /* start erase operation, reset by hw with bsy bit */
- set_flash_cr_strt(sl);
+ /* start erase operation, reset by hw with bsy bit */
+ set_flash_cr_strt(sl);
- /* wait for completion */
- wait_flash_busy(sl);
+ /* wait for completion */
+ wait_flash_busy(sl);
- /* relock the flash */
- lock_flash(sl);
- } else {
- WLOG("unknown coreid %x, page erase failed\n", sl->core_id);
- return -1;
- }
+ /* relock the flash */
+ lock_flash(sl);
+ } else {
+ WLOG("unknown coreid %x, page erase failed\n", sl->core_id);
+ return -1;
+ }
- /* todo: verify the erased page */
+ /* todo: verify the erased page */
- return 0;
+ return 0;
}
int stlink_erase_flash_mass(stlink_t *sl) {
- if (sl->chip_id == STM32_CHIPID_L1_MEDIUM || sl->chip_id == STM32_CHIPID_L1_MEDIUM_PLUS
- || sl->chip_id == STM32_CHIPID_L1_HIGH) {
+ if (sl->flash_type == FLASH_TYPE_L0) {
/* erase each page */
int i = 0, num_pages = sl->flash_size/sl->flash_pgsz;
for (i = 0; i < num_pages; i++) {
WLOG("Failed to erase_flash_page(%#zx) == -1\n", addr);
return -1;
}
- fprintf(stdout,"\rFlash page at %5d/%5d erased", i, num_pages);
+ fprintf(stdout,"-> Flash page at %5d/%5d erased\n", i, num_pages);
fflush(stdout);
}
fprintf(stdout, "\n");
0x0A, 0x4C, // ldr r4, STM32_FLASH_BASE
0x01, 0x25, // mov r5, #1 /* FLASH_CR_PG, FLASH_SR_BUSY */
0x04, 0x26, // mov r6, #4 /* PGERR */
- // write_half_word:
+ // write_half_word:
0x23, 0x69, // ldr r3, [r4, #16] /* FLASH->CR */
0x2B, 0x43, // orr r3, r5
0x23, 0x61, // str r3, [r4, #16] /* FLASH->CR |= FLASH_CR_PG */
0x03, 0x88, // ldrh r3, [r0] /* r3 = *sram */
0x0B, 0x80, // strh r3, [r1] /* *flash = r3 */
- // busy:
+ // busy:
0xE3, 0x68, // ldr r3, [r4, #12] /* FLASH->SR */
0x2B, 0x42, // tst r3, r5 /* FLASH_SR_BUSY */
0xFC, 0xD0, // beq busy
0x01, 0x3A, // sub r2, r2, #0x01 /* count-- */
0x00, 0x2A, // cmp r2, #0
0xF0, 0xD1, // bne write_half_word
- // exit:
+ // exit:
0x23, 0x69, // ldr r3, [r4, #16] /* FLASH->CR */
0xAB, 0x43, // bic r3, r5
0x23, 0x61, // str r3, [r4, #16] /* FLASH->CR &= ~FLASH_CR_PG */
static const uint8_t loader_code_stm32l[] = {
/* openocd.git/contrib/loaders/flash/stm32lx.S
- r0, input, dest addr
- r1, input, source addr
+ r0, input, source addr
+ r1, input, dest addr
r2, input, word count
- r3, output, word count
- */
+ r2, output, remaining word count
+ */
- 0x00, 0x23,
0x04, 0xe0,
- 0x51, 0xf8, 0x04, 0xcb,
- 0x40, 0xf8, 0x04, 0xcb,
- 0x01, 0x33,
+ 0x50, 0xf8, 0x04, 0xcb,
+ 0x41, 0xf8, 0x04, 0xcb,
+ 0x01, 0x3a,
- 0x93, 0x42,
+ 0x00, 0x2a,
0xf8, 0xd3,
- 0x00, 0xbe
+ 0x00, 0xbe,
+ };
+
+ static const uint8_t loader_code_stm32l0[] = {
+
+ /*
+ r0, input, source addr
+ r1, input, dest addr
+ r2, input, word count
+ r2, output, remaining word count
+ */
+
+ 0x04, 0xe0,
+
+ 0x04, 0x68,
+ 0x0c, 0x60,
+ 0x01, 0x3a,
+ 0x04, 0x31,
+ 0x04, 0x30,
+
+ 0x00, 0x2a,
+ 0xf8, 0xd3,
+ 0x00, 0xbe,
};
static const uint8_t loader_code_stm32f4[] = {
0x00, 0x3c, 0x02, 0x40,
};
+ static const uint8_t loader_code_stm32f4_lv[] = {
+ // flashloaders/stm32f4lv.s
+ 0x92, 0x00,
+
+ 0x08, 0x4b,
+ 0x62, 0xb1,
+ 0x04, 0x78,
+ 0x0c, 0x70,
+
+ 0xdc, 0x89,
+ 0x14, 0xf0, 0x01, 0x0f,
+ 0xfb, 0xd1,
+ 0x00, 0xf1, 0x01, 0x00,
+ 0x01, 0xf1, 0x01, 0x01,
+ 0xa2, 0xf1, 0x01, 0x02,
+ 0xf1, 0xe7,
+
+ 0x00, 0xbe,
+ 0x00, 0xbf,
+
+ 0x00, 0x3c, 0x02, 0x40,
+ };
+
+ static const uint8_t loader_code_stm32l4[] = {
+ // flashloaders/stm32l4.s
+ 0x08, 0x4b, // start: ldr r3, [pc, #32] ; <flash_base>
+ 0x72, 0xb1, // next: cbz r2, <done>
+ 0x04, 0x68, // ldr r4, [r0, #0]
+ 0x45, 0x68, // ldr r5, [r0, #4]
+ 0x0c, 0x60, // str r4, [r1, #0]
+ 0x4d, 0x60, // str r5, [r1, #4]
+ 0x5c, 0x8a, // wait: ldrh r4, [r3, #18]
+ 0x14, 0xf0, 0x01, 0x0f, // tst.w r4, #1
+ 0xfb, 0xd1, // bne.n <wait>
+ 0x00, 0xf1, 0x08, 0x00, // add.w r0, r0, #8
+ 0x01, 0xf1, 0x08, 0x01, // add.w r1, r1, #8
+ 0xa2, 0xf1, 0x01, 0x02, // sub.w r2, r2, #1
+ 0xef, 0xe7, // b.n <next>
+ 0x00, 0xbe, // done: bkpt 0x0000
+ 0x00, 0x20, 0x02, 0x40 // flash_base: .word 0x40022000
+ };
+
+ static const uint8_t loader_code_stm32f7[] = {
+ 0x08, 0x4b,
+ 0x72, 0xb1,
+ 0x04, 0x68,
+ 0x0c, 0x60,
+ 0xbf, 0xf3, 0x4f, 0x8f, // DSB Memory barrier for in order flash write
+ 0xdc, 0x89,
+ 0x14, 0xf0, 0x01, 0x0f,
+ 0xfb, 0xd1,
+ 0x00, 0xf1, 0x04, 0x00,
+ 0x01, 0xf1, 0x04, 0x01,
+ 0xa2, 0xf1, 0x01, 0x02,
+ 0xef, 0xe7,
+ 0x00, 0xbe, // bkpt #0x00
+ 0x00, 0x3c, 0x02, 0x40,
+ };
+
const uint8_t* loader_code;
size_t loader_size;
- if (sl->chip_id == STM32_CHIPID_L1_MEDIUM || sl->chip_id == STM32_CHIPID_L1_MEDIUM_PLUS
- || sl->chip_id == STM32_CHIPID_L1_HIGH ) { /* stm32l */
+ if (sl->chip_id == STM32_CHIPID_L1_MEDIUM || sl->chip_id == STM32_CHIPID_L1_CAT2
+ || sl->chip_id == STM32_CHIPID_L1_MEDIUM_PLUS || sl->chip_id == STM32_CHIPID_L1_HIGH
+ || sl->chip_id == STM32_CHIPID_L152_RE) { /* stm32l */
loader_code = loader_code_stm32l;
loader_size = sizeof(loader_code_stm32l);
- } else if (sl->core_id == STM32VL_CORE_ID || sl->chip_id == STM32_CHIPID_F3 || sl->chip_id == STM32_CHIPID_F37x) {
+ } else if (sl->core_id == STM32VL_CORE_ID
+ || sl->chip_id == STM32_CHIPID_F3
+ || sl->chip_id == STM32_CHIPID_F3_SMALL
+ || sl->chip_id == STM32_CHIPID_F303_HIGH
+ || sl->chip_id == STM32_CHIPID_F37x
+ || sl->chip_id == STM32_CHIPID_F334) {
loader_code = loader_code_stm32vl;
loader_size = sizeof(loader_code_stm32vl);
- } else if (sl->chip_id == STM32_CHIPID_F2 ||
- sl->chip_id == STM32_CHIPID_F4 || sl->chip_id == STM32_CHIPID_F4_LP) {
- loader_code = loader_code_stm32f4;
- loader_size = sizeof(loader_code_stm32f4);
- } else if (sl->chip_id == STM32_CHIPID_F0 || sl->chip_id == STM32_CHIPID_F0_SMALL) {
+ } else if (sl->chip_id == STM32_CHIPID_F2 || sl->chip_id == STM32_CHIPID_F4 || (sl->chip_id == STM32_CHIPID_F4_DE) ||
+ sl->chip_id == STM32_CHIPID_F4_LP || sl->chip_id == STM32_CHIPID_F4_HD || (sl->chip_id == STM32_CHIPID_F411RE) ||
+ (sl->chip_id == STM32_CHIPID_F446) || (sl->chip_id == STM32_CHIPID_F4_DSI)){
+ int voltage = stlink_target_voltage(sl);
+ if (voltage == -1) {
+ printf("Failed to read Target voltage\n");
+ return voltage;
+ } else if (voltage > 2700) {
+ loader_code = loader_code_stm32f4;
+ loader_size = sizeof(loader_code_stm32f4);
+ } else {
+ loader_code = loader_code_stm32f4_lv;
+ loader_size = sizeof(loader_code_stm32f4_lv);
+ }
+ } else if (sl->chip_id == STM32_CHIPID_F7){
+ loader_code = loader_code_stm32f7;
+ loader_size = sizeof(loader_code_stm32f7);
+ } else if (sl->chip_id == STM32_CHIPID_F0 || sl->chip_id == STM32_CHIPID_F04 || sl->chip_id == STM32_CHIPID_F0_CAN || sl->chip_id == STM32_CHIPID_F0_SMALL || sl->chip_id == STM32_CHIPID_F09X) {
loader_code = loader_code_stm32f0;
loader_size = sizeof(loader_code_stm32f0);
+ } else if (sl->chip_id == STM32_CHIPID_L0) {
+ loader_code = loader_code_stm32l0;
+ loader_size = sizeof(loader_code_stm32l0);
+ } else if (sl->chip_id == STM32_CHIPID_L4) {
+ loader_code = loader_code_stm32l4;
+ loader_size = sizeof(loader_code_stm32l4);
} else {
ELOG("unknown coreid, not sure what flash loader to use, aborting!: %x\n", sl->core_id);
return -1;
}
memcpy(sl->q_buf, loader_code, loader_size);
+
+ /* pad to 32-bits */
+ loader_size = (loader_size + 3) & ~3;
+
stlink_write_mem32(sl, sl->sram_base, loader_size);
*addr = sl->sram_base;
}
-int stm32l1_write_half_pages(stlink_t *sl, stm32_addr_t addr, uint8_t* base, unsigned num_half_pages)
+int stm32l1_write_half_pages(stlink_t *sl, stm32_addr_t addr, uint8_t* base, uint32_t len, uint32_t pagesize)
{
unsigned int count;
+ unsigned int num_half_pages = len / pagesize;
uint32_t val;
+ uint32_t flash_regs_base;
flash_loader_t fl;
+ if (sl->chip_id == STM32_CHIPID_L0) {
+ flash_regs_base = STM32L0_FLASH_REGS_ADDR;
+ } else {
+ flash_regs_base = STM32L_FLASH_REGS_ADDR;
+ }
+
ILOG("Starting Half page flash write for STM32L core id\n");
/* flash loader initialization */
if (init_flash_loader(sl, &fl) == -1) {
return -1;
}
/* Unlock already done */
- val = stlink_read_debug32(sl, STM32L_FLASH_PECR);
+ stlink_read_debug32(sl, flash_regs_base + FLASH_PECR_OFF, &val);
val |= (1 << FLASH_L1_FPRG);
- stlink_write_debug32(sl, STM32L_FLASH_PECR, val);
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PECR_OFF, val);
val |= (1 << FLASH_L1_PROG);
- stlink_write_debug32(sl, STM32L_FLASH_PECR, val);
- while ((stlink_read_debug32(sl, STM32L_FLASH_SR) & (1 << 0)) != 0) {}
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PECR_OFF, val);
+ do {
+ stlink_read_debug32(sl, flash_regs_base + FLASH_SR_OFF, &val);
+ } while ((val & (1 << 0)) != 0);
-#define L1_WRITE_BLOCK_SIZE 0x80
for (count = 0; count < num_half_pages; count ++) {
- if (run_flash_loader(sl, &fl, addr + count * L1_WRITE_BLOCK_SIZE, base + count * L1_WRITE_BLOCK_SIZE, L1_WRITE_BLOCK_SIZE) == -1) {
- WLOG("l1_run_flash_loader(%#zx) failed! == -1\n", addr + count * L1_WRITE_BLOCK_SIZE);
- val = stlink_read_debug32(sl, STM32L_FLASH_PECR);
+ if (run_flash_loader(sl, &fl, addr + count * pagesize, base + count * pagesize, pagesize) == -1) {
+ WLOG("l1_run_flash_loader(%#zx) failed! == -1\n", addr + count * pagesize);
+ stlink_read_debug32(sl, flash_regs_base + FLASH_PECR_OFF, &val);
val &= ~((1 << FLASH_L1_FPRG) |(1 << FLASH_L1_PROG));
- stlink_write_debug32(sl, STM32L_FLASH_PECR, val);
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PECR_OFF, val);
return -1;
}
/* wait for sr.busy to be cleared */
fprintf(stdout, "\r%3u/%u halfpages written", count + 1, num_half_pages);
fflush(stdout);
}
- while ((stlink_read_debug32(sl, STM32L_FLASH_SR) & (1 << 0)) != 0) {
- }
+ do {
+ stlink_read_debug32(sl, flash_regs_base + FLASH_SR_OFF, &val);
+ } while ((val & (1 << 0)) != 0);
}
- val = stlink_read_debug32(sl, STM32L_FLASH_PECR);
+ stlink_read_debug32(sl, flash_regs_base + FLASH_PECR_OFF, &val);
val &= ~(1 << FLASH_L1_PROG);
- stlink_write_debug32(sl, STM32L_FLASH_PECR, val);
- val = stlink_read_debug32(sl, STM32L_FLASH_PECR);
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PECR_OFF, val);
+ stlink_read_debug32(sl, flash_regs_base + FLASH_PECR_OFF, &val);
val &= ~(1 << FLASH_L1_FPRG);
- stlink_write_debug32(sl, STM32L_FLASH_PECR, val);
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PECR_OFF, val);
return 0;
}
-int stlink_write_flash(stlink_t *sl, stm32_addr_t addr, uint8_t* base, uint32_t len) {
+int stlink_write_flash(stlink_t *sl, stm32_addr_t addr, uint8_t* base, uint32_t len, uint8_t eraseonly) {
size_t off;
flash_loader_t fl;
ILOG("Attempting to write %d (%#x) bytes to stm32 address: %u (%#x)\n",
- len, len, addr, addr);
+ len, len, addr, addr);
/* check addr range is inside the flash */
stlink_calculate_pagesize(sl, addr);
if (addr < sl->flash_base) {
return -1;
}
fprintf(stdout,"\rFlash page at addr: 0x%08lx erased",
- (unsigned long)addr + off);
+ (unsigned long)addr + off);
fflush(stdout);
page_count++;
}
fprintf(stdout,"\n");
ILOG("Finished erasing %d pages of %d (%#x) bytes\n",
- page_count, sl->flash_pgsz, sl->flash_pgsz);
+ page_count, sl->flash_pgsz, sl->flash_pgsz);
- if ((sl->chip_id == STM32_CHIPID_F2) || (sl->chip_id == STM32_CHIPID_F4) ||
- (sl->chip_id == STM32_CHIPID_F4_LP)) {
- /* todo: check write operation */
+ if (eraseonly)
+ return 0;
- ILOG("Starting Flash write for F2/F4\n");
+ if ((sl->flash_type == FLASH_TYPE_F4) || (sl->flash_type == FLASH_TYPE_L4)) {
+ /* todo: check write operation */
+
+ ILOG("Starting Flash write for F2/F4/L4\n");
/* flash loader initialization */
if (init_flash_loader(sl, &fl) == -1) {
ELOG("init_flash_loader() == -1\n");
return -1;
}
- /* First unlock the cr */
- unlock_flash_if(sl);
+ /* First unlock the cr */
+ unlock_flash_if(sl);
- /* TODO: Check that Voltage range is 2.7 - 3.6 V */
- /* set parallelisim to 32 bit*/
- write_flash_cr_psiz(sl, 2);
+ /* TODO: Check that Voltage range is 2.7 - 3.6 V */
+ if (sl->chip_id != STM32_CHIPID_L4) {
+ /* set parallelisim to 32 bit*/
+ int voltage = stlink_target_voltage(sl);
+ if (voltage == -1) {
+ printf("Failed to read Target voltage\n");
+ return voltage;
+ } else if (voltage > 2700) {
+ printf("enabling 32-bit flash writes\n");
+ write_flash_cr_psiz(sl, 2);
+ } else {
+ printf("Target voltage (%d mV) too low for 32-bit flash, using 8-bit flash writes\n", voltage);
+ write_flash_cr_psiz(sl, 0);
+ }
+ } else {
+ /* L4 does not have a byte-write mode */
+ int voltage = stlink_target_voltage(sl);
+ if (voltage == -1) {
+ printf("Failed to read Target voltage\n");
+ return voltage;
+ } else if (voltage < 1710) {
+ printf("Target voltage (%d mV) too low for flash writes!\n", voltage);
+ return -1;
+ }
+ }
- /* set programming mode */
- set_flash_cr_pg(sl);
+ /* set programming mode */
+ set_flash_cr_pg(sl);
for(off = 0; off < len;) {
size_t size = len - off > 0x8000 ? 0x8000 : len - off;
off += size;
}
-#if 0
-#define PROGRESS_CHUNK_SIZE 0x1000
- /* write a word in program memory */
- for (off = 0; off < len; off += sizeof(uint32_t)) {
- uint32_t data;
- if (sl->verbose >= 1) {
- if ((off & (PROGRESS_CHUNK_SIZE - 1)) == 0) {
- /* show progress. writing procedure is slow
- and previous errors are misleading */
- const uint32_t pgnum = (off / PROGRESS_CHUNK_SIZE)+1;
- const uint32_t pgcount = len / PROGRESS_CHUNK_SIZE +1;
- fprintf(stdout, "Writing %ukB chunk %u out of %u\n",
- PROGRESS_CHUNK_SIZE/1024, pgnum, pgcount);
- }
- }
-
- write_uint32((unsigned char*) &data, *(uint32_t*) (base + off));
- stlink_write_debug32(sl, addr + off, data);
-
- /* wait for sr.busy to be cleared */
- wait_flash_busy(sl);
-
- }
-#endif
- /* Relock flash */
- lock_flash(sl);
-
-#if 0 /* todo: debug mode */
- fprintf(stdout, "Final CR:0x%x\n", read_flash_cr(sl));
-#endif
+ /* Relock flash */
+ lock_flash(sl);
} //STM32F4END
- else if (sl->chip_id == STM32_CHIPID_L1_MEDIUM || sl->chip_id == STM32_CHIPID_L1_MEDIUM_PLUS
- || sl->chip_id == STM32_CHIPID_L1_HIGH ) {
- /* use fast word write. todo: half page. */
- uint32_t val;
-
-#if 0 /* todo: check write operation */
+ else if (sl->flash_type == FLASH_TYPE_L0) {
+ /* use fast word write. todo: half page. */
+ uint32_t val;
+ uint32_t flash_regs_base;
+ uint32_t pagesize;
- uint32_t nwrites = sl->flash_pgsz;
-
- redo_write:
+ if (sl->chip_id == STM32_CHIPID_L0) {
+ flash_regs_base = STM32L0_FLASH_REGS_ADDR;
+ pagesize = L0_WRITE_BLOCK_SIZE;
+ } else {
+ flash_regs_base = STM32L_FLASH_REGS_ADDR;
+ pagesize = L1_WRITE_BLOCK_SIZE;
+ }
-#endif /* todo: check write operation */
+ /* todo: check write operation */
- /* disable pecr protection */
- stlink_write_debug32(sl, STM32L_FLASH_PEKEYR, 0x89abcdef);
- stlink_write_debug32(sl, STM32L_FLASH_PEKEYR, 0x02030405);
+ /* disable pecr protection */
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PEKEYR_OFF, 0x89abcdef);
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PEKEYR_OFF, 0x02030405);
- /* check pecr.pelock is cleared */
- val = stlink_read_debug32(sl, STM32L_FLASH_PECR);
- if (val & (1 << 0)) {
- fprintf(stderr, "pecr.pelock not clear\n");
- return -1;
- }
+ /* check pecr.pelock is cleared */
+ stlink_read_debug32(sl, flash_regs_base + FLASH_PECR_OFF, &val);
+ if (val & (1 << 0)) {
+ fprintf(stderr, "pecr.pelock not clear\n");
+ return -1;
+ }
- /* unlock program memory */
- stlink_write_debug32(sl, STM32L_FLASH_PRGKEYR, 0x8c9daebf);
- stlink_write_debug32(sl, STM32L_FLASH_PRGKEYR, 0x13141516);
+ /* unlock program memory */
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PRGKEYR_OFF, 0x8c9daebf);
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PRGKEYR_OFF, 0x13141516);
- /* check pecr.prglock is cleared */
- val = stlink_read_debug32(sl, STM32L_FLASH_PECR);
- if (val & (1 << 1)) {
- fprintf(stderr, "pecr.prglock not clear\n");
- return -1;
- }
- off = 0;
- if (len > L1_WRITE_BLOCK_SIZE) {
- if (stm32l1_write_half_pages(sl, addr, base, len/L1_WRITE_BLOCK_SIZE) == -1) {
- /* This may happen on a blank device! */
+ /* check pecr.prglock is cleared */
+ stlink_read_debug32(sl, flash_regs_base + FLASH_PECR_OFF, &val);
+ if (val & (1 << 1)) {
+ fprintf(stderr, "pecr.prglock not clear\n");
+ return -1;
+ }
+ off = 0;
+ if (len > pagesize) {
+ if (stm32l1_write_half_pages(sl, addr, base, len, pagesize) == -1) {
+ /* This may happen on a blank device! */
WLOG("\nwrite_half_pages failed == -1\n");
- } else {
- off = (len /L1_WRITE_BLOCK_SIZE)*L1_WRITE_BLOCK_SIZE;
- }
- }
+ } else {
+ off = (len / pagesize)*pagesize;
+ }
+ }
- /* write remainingword in program memory */
- for ( ; off < len; off += sizeof(uint32_t)) {
+ /* write remainingword in program memory */
+ for ( ; off < len; off += sizeof(uint32_t)) {
uint32_t data;
if (off > 254)
fprintf(stdout, "\r");
stlink_write_debug32(sl, addr + off, data);
/* wait for sr.busy to be cleared */
- while ((stlink_read_debug32(sl, STM32L_FLASH_SR) & (1 << 0)) != 0)
- ;
-
-#if 0 /* todo: check redo write operation */
-
- /* check written bytes. todo: should be on a per page basis. */
- data = stlink_read_debug32(sl, addr + off);
- if (data == *(uint32_t*)(base + off)) {
- /* re erase the page and redo the write operation */
- uint32_t page;
- uint32_t val;
-
- /* fail if successive write count too low */
- if (nwrites < sl->flash_pgsz) {
- fprintf(stderr, "writes operation failure count too high, aborting\n");
- return -1;
- }
-
- nwrites = 0;
-
- /* assume addr aligned */
- if (off % sl->flash_pgsz) off &= ~(sl->flash_pgsz - 1);
- page = addr + off;
-
- fprintf(stderr, "invalid write @0x%x(0x%x): 0x%x != 0x%x. retrying.\n",
- page, addr + off, read_uint32(base + off, 0), read_uint32(sl->q_buf, 0));
-
- /* reset lock bits */
- val = stlink_read_debug32(sl, STM32L_FLASH_PECR)
- | (1 << 0) | (1 << 1) | (1 << 2);
- stlink_write_debug32(sl, STM32L_FLASH_PECR, val);
+ do {
+ stlink_read_debug32(sl, flash_regs_base + FLASH_SR_OFF, &val);
+ } while ((val & (1 << 0)) != 0);
- stlink_erase_flash_page(sl, page);
+ /* todo: check redo write operation */
- goto redo_write;
- }
-
- /* increment successive writes counter */
- ++nwrites;
-
-#endif /* todo: check redo write operation */
- }
+ }
fprintf(stdout, "\n");
- /* reset lock bits */
- val = stlink_read_debug32(sl, STM32L_FLASH_PECR)
- | (1 << 0) | (1 << 1) | (1 << 2);
- stlink_write_debug32(sl, STM32L_FLASH_PECR, val);
- } else if (sl->core_id == STM32VL_CORE_ID || sl->core_id == STM32F0_CORE_ID || sl->chip_id == STM32_CHIPID_F3 || sl->chip_id == STM32_CHIPID_F37x) {
- ILOG("Starting Flash write for VL/F0 core id\n");
+ /* reset lock bits */
+ stlink_read_debug32(sl, flash_regs_base + FLASH_PECR_OFF, &val);
+ val |= (1 << 0) | (1 << 1) | (1 << 2);
+ stlink_write_debug32(sl, flash_regs_base + FLASH_PECR_OFF, val);
+ } else if (sl->flash_type == FLASH_TYPE_F0) {
+ ILOG("Starting Flash write for VL/F0/F3 core id\n");
/* flash loader initialization */
if (init_flash_loader(sl, &fl) == -1) {
ELOG("init_flash_loader() == -1\n");
if (sl->verbose >= 1) {
/* show progress. writing procedure is slow
and previous errors are misleading */
- fprintf(stdout, "\r%3u/%lu pages written", write_block_count++, (unsigned long)len/sl->flash_pgsz);
+ fprintf(stdout, "\r%3u/%lu pages written", write_block_count++, (unsigned long)len/sl->flash_pgsz);
fflush(stdout);
}
}
int stlink_fwrite_flash(stlink_t *sl, const char* path, stm32_addr_t addr) {
/* write the file in flash at addr */
int err;
- unsigned int num_empty = 0, index;
- unsigned char erased_pattern =(sl->chip_id == STM32_CHIPID_L1_MEDIUM || sl->chip_id == STM32_CHIPID_L1_MEDIUM_PLUS
- || sl->chip_id == STM32_CHIPID_L1_HIGH )?0:0xff;
+ unsigned int num_empty, index, val;
+ unsigned char erased_pattern;
mapped_file_t mf = MAPPED_FILE_INITIALIZER;
+
if (map_file(&mf, path) == -1) {
ELOG("map_file() == -1\n");
return -1;
}
- for(index = 0; index < mf.len; index ++) {
- if (mf.base[index] == erased_pattern)
- num_empty ++;
- else
- num_empty = 0;
+
+ if (sl->flash_type == FLASH_TYPE_L0)
+ erased_pattern = 0x00;
+ else
+ erased_pattern = 0xff;
+
+ index = mf.len;
+ for(num_empty = 0; num_empty != mf.len; ++num_empty) {
+ if (mf.base[--index] != erased_pattern) {
+ break;
+ }
}
+ /* Round down to words */
+ num_empty -= (num_empty & 3);
if(num_empty != 0) {
- ILOG("Ignoring %d bytes of Zeros at end of file\n",num_empty);
- mf.len -= num_empty;
+ ILOG("Ignoring %d bytes of 0x%02x at end of file\n", num_empty, erased_pattern);
}
- err = stlink_write_flash(sl, addr, mf.base, mf.len);
+ err = stlink_write_flash(sl, addr, mf.base, num_empty == mf.len? mf.len : mf.len - num_empty, num_empty == mf.len);
/* set stack*/
- stlink_write_reg(sl, stlink_read_debug32(sl, addr ),13);
+ stlink_read_debug32(sl, addr, &val);
+ stlink_write_reg(sl, val, 13);
/* Set PC to the reset routine*/
- stlink_write_reg(sl, stlink_read_debug32(sl, addr + 4),15);
+ stlink_read_debug32(sl, addr + 4, &val);
+ stlink_write_reg(sl, val, 15);
stlink_run(sl);
unmap_file(&mf);
return err;
reg rr;
int i = 0;
+ size_t count = 0;
+
DLOG("Running flash loader, write address:%#x, size: %zd\n", target, size);
// FIXME This can never return -1
if (write_buffer_to_sram(sl, fl, buf, size) == -1) {
return -1;
}
- if (sl->chip_id == STM32_CHIPID_L1_MEDIUM || sl->chip_id == STM32_CHIPID_L1_MEDIUM_PLUS
- || sl->chip_id == STM32_CHIPID_L1_HIGH ) {
-
- size_t count = size / sizeof(uint32_t);
- if (size % sizeof(uint32_t)) ++count;
-
- /* setup core */
- stlink_write_reg(sl, target, 0); /* target */
- stlink_write_reg(sl, fl->buf_addr, 1); /* source */
- stlink_write_reg(sl, count, 2); /* count (32 bits words) */
- stlink_write_reg(sl, fl->loader_addr, 15); /* pc register */
-
- } else if (sl->core_id == STM32VL_CORE_ID || sl->core_id == STM32F0_CORE_ID || sl->chip_id == STM32_CHIPID_F3 || sl->chip_id == STM32_CHIPID_F37x) {
-
- size_t count = size / sizeof(uint16_t);
- if (size % sizeof(uint16_t)) ++count;
-
- /* setup core */
- stlink_write_reg(sl, fl->buf_addr, 0); /* source */
- stlink_write_reg(sl, target, 1); /* target */
- stlink_write_reg(sl, count, 2); /* count (16 bits half words) */
- stlink_write_reg(sl, 0, 3); /* flash bank 0 (input) */
- stlink_write_reg(sl, fl->loader_addr, 15); /* pc register */
-
- } else if (sl->chip_id == STM32_CHIPID_F2 ||
- sl->chip_id == STM32_CHIPID_F4 || sl->chip_id == STM32_CHIPID_F4_LP) {
-
- size_t count = size / sizeof(uint32_t);
- if (size % sizeof(uint32_t)) ++count;
-
- /* setup core */
- stlink_write_reg(sl, fl->buf_addr, 0); /* source */
- stlink_write_reg(sl, target, 1); /* target */
- stlink_write_reg(sl, count, 2); /* count (32 bits words) */
- stlink_write_reg(sl, fl->loader_addr, 15); /* pc register */
-
- } else {
- fprintf(stderr, "unknown coreid 0x%x, don't know what flash loader to use\n", sl->core_id);
- return -1;
+ if (sl->flash_type == FLASH_TYPE_F0) {
+ count = size / sizeof(uint16_t);
+ if (size % sizeof(uint16_t))
+ ++count;
+ } else if (sl->flash_type == FLASH_TYPE_F4 || sl->flash_type == FLASH_TYPE_L0) {
+ count = size / sizeof(uint32_t);
+ if (size % sizeof(uint32_t))
+ ++count;
+ } else if (sl->flash_type == FLASH_TYPE_L4) {
+ count = size / sizeof(uint64_t);
+ if (size % sizeof(uint64_t))
+ ++count;
}
+ /* setup core */
+ stlink_write_reg(sl, fl->buf_addr, 0); /* source */
+ stlink_write_reg(sl, target, 1); /* target */
+ stlink_write_reg(sl, count, 2); /* count */
+ stlink_write_reg(sl, 0, 3); /* flash bank 0 (input), only used on F0, but armless fopr others */
+ stlink_write_reg(sl, fl->loader_addr, 15); /* pc register */
+
/* run loader */
stlink_run(sl);
}
/* check written byte count */
- if (sl->chip_id == STM32_CHIPID_L1_MEDIUM || sl->chip_id == STM32_CHIPID_L1_MEDIUM_PLUS
- || sl->chip_id == STM32_CHIPID_L1_HIGH ) {
-
- size_t count = size / sizeof(uint32_t);
- if (size % sizeof(uint32_t)) ++count;
-
- stlink_read_reg(sl, 3, &rr);
- if (rr.r[3] != count) {
- fprintf(stderr, "write error, count == %u\n", rr.r[3]);
- return -1;
- }
-
- } else if (sl->core_id == STM32VL_CORE_ID || sl->core_id == STM32F0_CORE_ID || sl->chip_id == STM32_CHIPID_F3 || sl->chip_id == STM32_CHIPID_F37x) {
-
- stlink_read_reg(sl, 2, &rr);
- if (rr.r[2] != 0) {
+ stlink_read_reg(sl, 2, &rr);
+ if (rr.r[2] != 0) {
fprintf(stderr, "write error, count == %u\n", rr.r[2]);
return -1;
- }
-
- } else if (sl->chip_id == STM32_CHIPID_F2 ||
- sl->chip_id == STM32_CHIPID_F4 || sl->chip_id == STM32_CHIPID_F4_LP) {
-
- stlink_read_reg(sl, 2, &rr);
- if (rr.r[2] != 0) {
- fprintf(stderr, "write error, count == %u\n", rr.r[2]);
- return -1;
- }
-
- } else {
-
- fprintf(stderr, "unknown coreid 0x%x, can't check written byte count\n", sl->core_id);
- return -1;
-
}
return 0;