* 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., *
- * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. *
+ * along with this program. If not, see <http://www.gnu.org/licenses/>. *
***************************************************************************/
#ifdef HAVE_CONFIG_H
#endif
#include "imp.h"
+#include "helper/binarybuffer.h"
+
+#include <target/cortex_m.h>
#define SAMD_NUM_SECTORS 16
+#define SAMD_PAGE_SIZE_MAX 1024
#define SAMD_FLASH ((uint32_t)0x00000000) /* physical Flash memory */
+#define SAMD_USER_ROW ((uint32_t)0x00804000) /* User Row of Flash */
+#define SAMD_PAC1 0x41000000 /* Peripheral Access Control 1 */
#define SAMD_DSU 0x41002000 /* Device Service Unit */
#define SAMD_NVMCTRL 0x41004000 /* Non-volatile memory controller */
+#define SAMD_DSU_STATUSA 1 /* DSU status register */
#define SAMD_DSU_DID 0x18 /* Device ID register */
#define SAMD_NVMCTRL_CTRLA 0x00 /* NVM control A register */
#define SAMD_NVM_CMD_SSB 0x45 /* Set Security Bit */
#define SAMD_NVM_CMD_INVALL 0x46 /* Invalidate all caches */
+/* NVMCTRL bits */
+#define SAMD_NVM_CTRLB_MANW 0x80
+
/* Known identifiers */
#define SAMD_PROCESSOR_M0 0x01
#define SAMD_FAMILY_D 0x00
+#define SAMD_FAMILY_L 0x01
+#define SAMD_FAMILY_C 0x02
#define SAMD_SERIES_20 0x00
#define SAMD_SERIES_21 0x01
+#define SAMD_SERIES_22 0x02
+#define SAMD_SERIES_10 0x02
+#define SAMD_SERIES_11 0x03
+#define SAMD_SERIES_09 0x04
+
+/* Device ID macros */
+#define SAMD_GET_PROCESSOR(id) (id >> 28)
+#define SAMD_GET_FAMILY(id) (((id >> 23) & 0x1F))
+#define SAMD_GET_SERIES(id) (((id >> 16) & 0x3F))
+#define SAMD_GET_DEVSEL(id) (id & 0xFF)
struct samd_part {
uint8_t id;
uint32_t ram_kb;
};
+/* Known SAMD09 parts. DID reset values missing in RM, see
+ * https://github.com/avrxml/asf/blob/master/sam0/utils/cmsis/samd09/include/ */
+static const struct samd_part samd09_parts[] = {
+ { 0x0, "SAMD09D14A", 16, 4 },
+ { 0x7, "SAMD09C13A", 8, 4 },
+};
+
+/* Known SAMD10 parts */
+static const struct samd_part samd10_parts[] = {
+ { 0x0, "SAMD10D14AMU", 16, 4 },
+ { 0x1, "SAMD10D13AMU", 8, 4 },
+ { 0x2, "SAMD10D12AMU", 4, 4 },
+ { 0x3, "SAMD10D14ASU", 16, 4 },
+ { 0x4, "SAMD10D13ASU", 8, 4 },
+ { 0x5, "SAMD10D12ASU", 4, 4 },
+ { 0x6, "SAMD10C14A", 16, 4 },
+ { 0x7, "SAMD10C13A", 8, 4 },
+ { 0x8, "SAMD10C12A", 4, 4 },
+};
+
+/* Known SAMD11 parts */
+static const struct samd_part samd11_parts[] = {
+ { 0x0, "SAMD11D14AMU", 16, 4 },
+ { 0x1, "SAMD11D13AMU", 8, 4 },
+ { 0x2, "SAMD11D12AMU", 4, 4 },
+ { 0x3, "SAMD11D14ASU", 16, 4 },
+ { 0x4, "SAMD11D13ASU", 8, 4 },
+ { 0x5, "SAMD11D12ASU", 4, 4 },
+ { 0x6, "SAMD11C14A", 16, 4 },
+ { 0x7, "SAMD11C13A", 8, 4 },
+ { 0x8, "SAMD11C12A", 4, 4 },
+};
+
/* Known SAMD20 parts. See Table 12-8 in 42129F–SAM–10/2013 */
static const struct samd_part samd20_parts[] = {
{ 0x0, "SAMD20J18A", 256, 32 },
{ 0x7, "SAMD20G16A", 64, 8 },
{ 0x8, "SAMD20G15A", 32, 4 },
{ 0x9, "SAMD20G14A", 16, 2 },
+ { 0xA, "SAMD20E18A", 256, 32 },
{ 0xB, "SAMD20E17A", 128, 16 },
{ 0xC, "SAMD20E16A", 64, 8 },
{ 0xD, "SAMD20E15A", 32, 4 },
{ 0xC, "SAMD21E16A", 64, 8 },
{ 0xD, "SAMD21E15A", 32, 4 },
{ 0xE, "SAMD21E14A", 16, 2 },
+ /* Below are B Variants (Table 3-7 from rev I of datasheet) */
+ { 0x20, "SAMD21J16B", 64, 8 },
+ { 0x21, "SAMD21J15B", 32, 4 },
+ { 0x23, "SAMD21G16B", 64, 8 },
+ { 0x24, "SAMD21G15B", 32, 4 },
+ { 0x26, "SAMD21E16B", 64, 8 },
+ { 0x27, "SAMD21E15B", 32, 4 },
+};
+
+/* Known SAMR21 parts. */
+static const struct samd_part samr21_parts[] = {
+ { 0x19, "SAMR21G18A", 256, 32 },
+ { 0x1A, "SAMR21G17A", 128, 32 },
+ { 0x1B, "SAMR21G16A", 64, 32 },
+ { 0x1C, "SAMR21E18A", 256, 32 },
+ { 0x1D, "SAMR21E17A", 128, 32 },
+ { 0x1E, "SAMR21E16A", 64, 32 },
+};
+
+/* Known SAML21 parts. */
+static const struct samd_part saml21_parts[] = {
+ { 0x00, "SAML21J18A", 256, 32 },
+ { 0x01, "SAML21J17A", 128, 16 },
+ { 0x02, "SAML21J16A", 64, 8 },
+ { 0x05, "SAML21G18A", 256, 32 },
+ { 0x06, "SAML21G17A", 128, 16 },
+ { 0x07, "SAML21G16A", 64, 8 },
+ { 0x0A, "SAML21E18A", 256, 32 },
+ { 0x0B, "SAML21E17A", 128, 16 },
+ { 0x0C, "SAML21E16A", 64, 8 },
+ { 0x0D, "SAML21E15A", 32, 4 },
+ { 0x0F, "SAML21J18B", 256, 32 },
+ { 0x10, "SAML21J17B", 128, 16 },
+ { 0x11, "SAML21J16B", 64, 8 },
+ { 0x14, "SAML21G18B", 256, 32 },
+ { 0x15, "SAML21G17B", 128, 16 },
+ { 0x16, "SAML21G16B", 64, 8 },
+ { 0x19, "SAML21E18B", 256, 32 },
+ { 0x1A, "SAML21E17B", 128, 16 },
+ { 0x1B, "SAML21E16B", 64, 8 },
+ { 0x1C, "SAML21E15B", 32, 4 },
+};
+
+/* Known SAML22 parts. */
+static const struct samd_part saml22_parts[] = {
+ { 0x00, "SAML22N18A", 256, 32 },
+ { 0x01, "SAML22N17A", 128, 16 },
+ { 0x02, "SAML22N16A", 64, 8 },
+ { 0x05, "SAML22J18A", 256, 32 },
+ { 0x06, "SAML22J17A", 128, 16 },
+ { 0x07, "SAML22J16A", 64, 8 },
+ { 0x0A, "SAML22G18A", 256, 32 },
+ { 0x0B, "SAML22G17A", 128, 16 },
+ { 0x0C, "SAML22G16A", 64, 8 },
+};
+
+/* Known SAMC20 parts. */
+static const struct samd_part samc20_parts[] = {
+ { 0x00, "SAMC20J18A", 256, 32 },
+ { 0x01, "SAMC20J17A", 128, 16 },
+ { 0x02, "SAMC20J16A", 64, 8 },
+ { 0x03, "SAMC20J15A", 32, 4 },
+ { 0x05, "SAMC20G18A", 256, 32 },
+ { 0x06, "SAMC20G17A", 128, 16 },
+ { 0x07, "SAMC20G16A", 64, 8 },
+ { 0x08, "SAMC20G15A", 32, 4 },
+ { 0x0A, "SAMC20E18A", 256, 32 },
+ { 0x0B, "SAMC20E17A", 128, 16 },
+ { 0x0C, "SAMC20E16A", 64, 8 },
+ { 0x0D, "SAMC20E15A", 32, 4 },
+};
+
+/* Known SAMC21 parts. */
+static const struct samd_part samc21_parts[] = {
+ { 0x00, "SAMC21J18A", 256, 32 },
+ { 0x01, "SAMC21J17A", 128, 16 },
+ { 0x02, "SAMC21J16A", 64, 8 },
+ { 0x03, "SAMC21J15A", 32, 4 },
+ { 0x05, "SAMC21G18A", 256, 32 },
+ { 0x06, "SAMC21G17A", 128, 16 },
+ { 0x07, "SAMC21G16A", 64, 8 },
+ { 0x08, "SAMC21G15A", 32, 4 },
+ { 0x0A, "SAMC21E18A", 256, 32 },
+ { 0x0B, "SAMC21E17A", 128, 16 },
+ { 0x0C, "SAMC21E16A", 64, 8 },
+ { 0x0D, "SAMC21E15A", 32, 4 },
};
/* Each family of parts contains a parts table in the DEVSEL field of DID. The
samd20_parts, ARRAY_SIZE(samd20_parts) },
{ SAMD_PROCESSOR_M0, SAMD_FAMILY_D, SAMD_SERIES_21,
samd21_parts, ARRAY_SIZE(samd21_parts) },
+ { SAMD_PROCESSOR_M0, SAMD_FAMILY_D, SAMD_SERIES_21,
+ samr21_parts, ARRAY_SIZE(samr21_parts) },
+ { SAMD_PROCESSOR_M0, SAMD_FAMILY_D, SAMD_SERIES_09,
+ samd09_parts, ARRAY_SIZE(samd09_parts) },
+ { SAMD_PROCESSOR_M0, SAMD_FAMILY_D, SAMD_SERIES_10,
+ samd10_parts, ARRAY_SIZE(samd10_parts) },
+ { SAMD_PROCESSOR_M0, SAMD_FAMILY_D, SAMD_SERIES_11,
+ samd11_parts, ARRAY_SIZE(samd11_parts) },
+ { SAMD_PROCESSOR_M0, SAMD_FAMILY_L, SAMD_SERIES_21,
+ saml21_parts, ARRAY_SIZE(saml21_parts) },
+ { SAMD_PROCESSOR_M0, SAMD_FAMILY_L, SAMD_SERIES_22,
+ saml22_parts, ARRAY_SIZE(saml22_parts) },
+ { SAMD_PROCESSOR_M0, SAMD_FAMILY_C, SAMD_SERIES_20,
+ samc20_parts, ARRAY_SIZE(samc20_parts) },
+ { SAMD_PROCESSOR_M0, SAMD_FAMILY_C, SAMD_SERIES_21,
+ samc21_parts, ARRAY_SIZE(samc21_parts) },
};
struct samd_info {
static struct samd_info *samd_chips;
+
+
static const struct samd_part *samd_find_part(uint32_t id)
{
- uint8_t processor = (id >> 28);
- uint8_t family = (id >> 24) & 0x0F;
- uint8_t series = (id >> 16) & 0xFF;
- uint8_t devsel = id & 0xFF;
+ uint8_t processor = SAMD_GET_PROCESSOR(id);
+ uint8_t family = SAMD_GET_FAMILY(id);
+ uint8_t series = SAMD_GET_SERIES(id);
+ uint8_t devsel = SAMD_GET_DEVSEL(id);
for (unsigned i = 0; i < ARRAY_SIZE(samd_families); i++) {
if (samd_families[i].processor == processor &&
return ERROR_OK;
}
+static int samd_get_flash_page_info(struct target *target,
+ uint32_t *sizep, int *nump)
+{
+ int res;
+ uint32_t param;
+
+ res = target_read_u32(target, SAMD_NVMCTRL + SAMD_NVMCTRL_PARAM, ¶m);
+ if (res == ERROR_OK) {
+ /* The PSZ field (bits 18:16) indicate the page size bytes as 2^(3+n)
+ * so 0 is 8KB and 7 is 1024KB. */
+ if (sizep)
+ *sizep = (8 << ((param >> 16) & 0x7));
+ /* The NVMP field (bits 15:0) indicates the total number of pages */
+ if (nump)
+ *nump = param & 0xFFFF;
+ } else {
+ LOG_ERROR("Couldn't read NVM Parameters register");
+ }
+
+ return res;
+}
+
static int samd_probe(struct flash_bank *bank)
{
- uint32_t id, param;
+ uint32_t id;
int res;
struct samd_info *chip = (struct samd_info *)bank->driver_priv;
const struct samd_part *part;
part = samd_find_part(id);
if (part == NULL) {
- LOG_ERROR("Couldn't find part correspoding to DID %08" PRIx32, id);
+ LOG_ERROR("Couldn't find part corresponding to DID %08" PRIx32, id);
return ERROR_FAIL;
}
- res = target_read_u32(bank->target,
- SAMD_NVMCTRL + SAMD_NVMCTRL_PARAM, ¶m);
- if (res != ERROR_OK) {
- LOG_ERROR("Couldn't read NVM Parameters register");
- return res;
- }
-
bank->size = part->flash_kb * 1024;
chip->sector_size = bank->size / SAMD_NUM_SECTORS;
- /* The PSZ field (bits 18:16) indicate the page size bytes as 2^(3+n) so
- * 0 is 8KB and 7 is 1024KB. */
- chip->page_size = (8 << ((param >> 16) & 0x7));
- /* The NVMP field (bits 15:0) indicates the total number of pages */
- chip->num_pages = param & 0xFFFF;
+ res = samd_get_flash_page_info(bank->target, &chip->page_size,
+ &chip->num_pages);
+ if (res != ERROR_OK) {
+ LOG_ERROR("Couldn't determine Flash page size");
+ return res;
+ }
/* Sanity check: the total flash size in the DSU should match the page size
* multiplied by the number of pages. */
return ERROR_OK;
}
-static int samd_protect(struct flash_bank *bank, int set, int first, int last)
-{
- int res;
- struct samd_info *chip = (struct samd_info *)bank->driver_priv;
-
- res = ERROR_OK;
-
- for (int s = first; s <= last; s++) {
- if (set != bank->sectors[s].is_protected) {
- /* Load an address that is within this sector (we use offset 0) */
- res = target_write_u32(bank->target, SAMD_NVMCTRL + SAMD_NVMCTRL_ADDR,
- s * chip->sector_size);
- if (res != ERROR_OK)
- goto exit;
-
- /* Tell the controller to lock that sector */
-
- uint16_t cmd = (set) ?
- SAMD_NVM_CMD(SAMD_NVM_CMD_LR) :
- SAMD_NVM_CMD(SAMD_NVM_CMD_UR);
-
- res = target_write_u16(bank->target,
- SAMD_NVMCTRL + SAMD_NVMCTRL_CTRLA,
- cmd);
- if (res != ERROR_OK)
- goto exit;
- }
- }
-exit:
- samd_protect_check(bank);
-
- return res;
-}
-
-static bool samd_check_error(struct flash_bank *bank)
+static bool samd_check_error(struct target *target)
{
int ret;
bool error;
uint16_t status;
- ret = target_read_u16(bank->target,
+ ret = target_read_u16(target,
SAMD_NVMCTRL + SAMD_NVMCTRL_STATUS, &status);
if (ret != ERROR_OK) {
LOG_ERROR("Can't read NVM status");
}
/* Clear the error conditions by writing a one to them */
- ret = target_write_u16(bank->target,
+ ret = target_write_u16(target,
SAMD_NVMCTRL + SAMD_NVMCTRL_STATUS, status);
if (ret != ERROR_OK)
LOG_ERROR("Can't clear NVM error conditions");
return error;
}
-static int samd_erase_row(struct flash_bank *bank, uint32_t address)
+static int samd_issue_nvmctrl_command(struct target *target, uint16_t cmd)
+{
+ int res;
+
+ if (target->state != TARGET_HALTED) {
+ LOG_ERROR("Target not halted");
+ return ERROR_TARGET_NOT_HALTED;
+ }
+
+ /* Issue the NVM command */
+ res = target_write_u16(target,
+ SAMD_NVMCTRL + SAMD_NVMCTRL_CTRLA, SAMD_NVM_CMD(cmd));
+ if (res != ERROR_OK)
+ return res;
+
+ /* Check to see if the NVM command resulted in an error condition. */
+ if (samd_check_error(target))
+ return ERROR_FAIL;
+
+ return ERROR_OK;
+}
+
+static int samd_erase_row(struct target *target, uint32_t address)
{
int res;
- bool error = false;
/* Set an address contained in the row to be erased */
- res = target_write_u32(bank->target,
+ res = target_write_u32(target,
SAMD_NVMCTRL + SAMD_NVMCTRL_ADDR, address >> 1);
- if (res == ERROR_OK) {
- /* Issue the Erase Row command to erase that row */
- res = target_write_u16(bank->target,
- SAMD_NVMCTRL + SAMD_NVMCTRL_CTRLA,
- SAMD_NVM_CMD(SAMD_NVM_CMD_ER));
- /* Check (and clear) error conditions */
- error = samd_check_error(bank);
- }
+ /* Issue the Erase Row command to erase that row. */
+ if (res == ERROR_OK)
+ res = samd_issue_nvmctrl_command(target,
+ address == SAMD_USER_ROW ? SAMD_NVM_CMD_EAR : SAMD_NVM_CMD_ER);
- if (res != ERROR_OK || error) {
+ if (res != ERROR_OK) {
LOG_ERROR("Failed to erase row containing %08" PRIx32, address);
return ERROR_FAIL;
}
return ERROR_OK;
}
-static int samd_erase(struct flash_bank *bank, int first, int last)
+static bool is_user_row_reserved_bit(uint8_t bit)
{
- int res;
- int rows_in_sector;
- struct samd_info *chip = (struct samd_info *)bank->driver_priv;
+ /* See Table 9-3 in the SAMD20 datasheet for more information. */
+ switch (bit) {
+ /* Reserved bits */
+ case 3:
+ case 7:
+ /* Voltage regulator internal configuration with default value of 0x70,
+ * may not be changed. */
+ case 17 ... 24:
+ /* 41 is voltage regulator internal configuration and must not be
+ * changed. 42 through 47 are reserved. */
+ case 41 ... 47:
+ return true;
+ default:
+ break;
+ }
- if (bank->target->state != TARGET_HALTED) {
- LOG_ERROR("Target not halted");
+ return false;
+}
- return ERROR_TARGET_NOT_HALTED;
+/* Modify the contents of the User Row in Flash. These are described in Table
+ * 9-3 of the SAMD20 datasheet. The User Row itself has a size of one page
+ * and contains a combination of "fuses" and calibration data in bits 24:17.
+ * We therefore try not to erase the row's contents unless we absolutely have
+ * to and we don't permit modifying reserved bits. */
+static int samd_modify_user_row(struct target *target, uint32_t value,
+ uint8_t startb, uint8_t endb)
+{
+ int res;
+
+ if (is_user_row_reserved_bit(startb) || is_user_row_reserved_bit(endb)) {
+ LOG_ERROR("Can't modify bits in the requested range");
+ return ERROR_FAIL;
}
- if (!chip->probed) {
- if (samd_probe(bank) != ERROR_OK)
- return ERROR_FLASH_BANK_NOT_PROBED;
+ /* Retrieve the MCU's page size, in bytes. This is also the size of the
+ * entire User Row. */
+ uint32_t page_size;
+ res = samd_get_flash_page_info(target, &page_size, NULL);
+ if (res != ERROR_OK) {
+ LOG_ERROR("Couldn't determine Flash page size");
+ return res;
}
- /* The SAMD NVM has row erase granularity. There are four pages in a row
- * and the number of rows in a sector depends on the sector size, which in
- * turn depends on the Flash capacity as there is a fixed number of
- * sectors. */
- rows_in_sector = chip->sector_size / (chip->page_size * 4);
+ /* Make sure the size is sane before we allocate. */
+ assert(page_size > 0 && page_size <= SAMD_PAGE_SIZE_MAX);
- /* For each sector to be erased */
- for (int s = first; s <= last; s++) {
- if (bank->sectors[s].is_protected) {
- LOG_ERROR("SAMD: failed to erase sector %d. That sector is write-protected", s);
- return ERROR_FLASH_OPERATION_FAILED;
- }
+ /* Make sure we're within the single page that comprises the User Row. */
+ if (startb >= (page_size * 8) || endb >= (page_size * 8)) {
+ LOG_ERROR("Can't modify bits outside the User Row page range");
+ return ERROR_FAIL;
+ }
- if (!bank->sectors[s].is_erased) {
- /* For each row in that sector */
- for (int r = s * rows_in_sector; r < (s + 1) * rows_in_sector; r++) {
- res = samd_erase_row(bank, r * chip->page_size * 4);
- if (res != ERROR_OK) {
- LOG_ERROR("SAMD: failed to erase sector %d", s);
- return res;
- }
- }
+ uint8_t *buf = malloc(page_size);
+ if (!buf)
+ return ERROR_FAIL;
- bank->sectors[s].is_erased = 1;
+ /* Read the user row (comprising one page) by half-words. */
+ res = target_read_memory(target, SAMD_USER_ROW, 2, page_size / 2, buf);
+ if (res != ERROR_OK)
+ goto out_user_row;
+
+ /* We will need to erase before writing if the new value needs a '1' in any
+ * position for which the current value had a '0'. Otherwise we can avoid
+ * erasing. */
+ uint32_t cur = buf_get_u32(buf, startb, endb - startb + 1);
+ if ((~cur) & value) {
+ res = samd_erase_row(target, SAMD_USER_ROW);
+ if (res != ERROR_OK) {
+ LOG_ERROR("Couldn't erase user row");
+ goto out_user_row;
}
}
- return ERROR_OK;
-}
+ /* Modify */
+ buf_set_u32(buf, startb, endb - startb + 1, value);
-static struct flash_sector *samd_find_sector_by_address(struct flash_bank *bank, uint32_t address)
-{
- struct samd_info *chip = (struct samd_info *)bank->driver_priv;
+ /* Write the page buffer back out to the target. A Flash write will be
+ * triggered automatically. */
+ res = target_write_memory(target, SAMD_USER_ROW, 4, page_size / 4, buf);
+ if (res != ERROR_OK)
+ goto out_user_row;
- for (int i = 0; i < bank->num_sectors; i++) {
- if (bank->sectors[i].offset <= address &&
- address < bank->sectors[i].offset + chip->sector_size)
- return &bank->sectors[i];
+ if (samd_check_error(target)) {
+ res = ERROR_FAIL;
+ goto out_user_row;
}
- return NULL;
+
+ /* Success */
+ res = ERROR_OK;
+
+out_user_row:
+ free(buf);
+
+ return res;
}
-/* Write an entire row (four pages) from host buffer 'buf' to row-aligned
- * 'address' in the Flash. */
-static int samd_write_row(struct flash_bank *bank, uint32_t address,
- const uint8_t *buf)
+static int samd_protect(struct flash_bank *bank, int set, int first, int last)
{
- int res;
struct samd_info *chip = (struct samd_info *)bank->driver_priv;
- struct flash_sector *sector = samd_find_sector_by_address(bank, address);
-
- if (!sector) {
- LOG_ERROR("Can't find sector corresponding to address 0x%08" PRIx32, address);
- return ERROR_FLASH_OPERATION_FAILED;
- }
-
- if (sector->is_protected) {
- LOG_ERROR("Trying to write to a protected sector at 0x%08" PRIx32, address);
- return ERROR_FLASH_OPERATION_FAILED;
+ /* We can issue lock/unlock region commands with the target running but
+ * the settings won't persist unless we're able to modify the LOCK regions
+ * and that requires the target to be halted. */
+ if (bank->target->state != TARGET_HALTED) {
+ LOG_ERROR("Target not halted");
+ return ERROR_TARGET_NOT_HALTED;
}
- /* Erase the row that we'll be writing to */
- res = samd_erase_row(bank, address);
- if (res != ERROR_OK)
- return res;
+ int res = ERROR_OK;
- /* Now write the pages in this row. */
- for (unsigned int i = 0; i < 4; i++) {
- bool error;
+ for (int s = first; s <= last; s++) {
+ if (set != bank->sectors[s].is_protected) {
+ /* Load an address that is within this sector (we use offset 0) */
+ res = target_write_u32(bank->target,
+ SAMD_NVMCTRL + SAMD_NVMCTRL_ADDR,
+ ((s * chip->sector_size) >> 1));
+ if (res != ERROR_OK)
+ goto exit;
- /* Write the page contents to the target's page buffer. A page write
- * is issued automatically once the last location is written in the
- * page buffer (ie: a complete page has been written out). */
- res = target_write_memory(bank->target, address, 4,
- chip->page_size / 4, buf);
- if (res != ERROR_OK) {
- LOG_ERROR("%s: %d", __func__, __LINE__);
- return res;
+ /* Tell the controller to lock that sector */
+ res = samd_issue_nvmctrl_command(bank->target,
+ set ? SAMD_NVM_CMD_LR : SAMD_NVM_CMD_UR);
+ if (res != ERROR_OK)
+ goto exit;
}
+ }
- error = samd_check_error(bank);
- if (error)
- return ERROR_FAIL;
+ /* We've now applied our changes, however they will be undone by the next
+ * reset unless we also apply them to the LOCK bits in the User Page. The
+ * LOCK bits start at bit 48, corresponding to Sector 0 and end with bit 63,
+ * corresponding to Sector 15. A '1' means unlocked and a '0' means
+ * locked. See Table 9-3 in the SAMD20 datasheet for more details. */
- /* Next page */
- address += chip->page_size;
- buf += chip->page_size;
- }
+ res = samd_modify_user_row(bank->target, set ? 0x0000 : 0xFFFF,
+ 48 + first, 48 + last);
+ if (res != ERROR_OK)
+ LOG_WARNING("SAMD: protect settings were not made persistent!");
+
+ res = ERROR_OK;
- sector->is_erased = 0;
+exit:
+ samd_protect_check(bank);
return res;
}
-/* Write partial contents into row-aligned 'address' on the Flash from host
- * buffer 'buf' by writing 'nb' of 'buf' at 'row_offset' into the Flash row. */
-static int samd_write_row_partial(struct flash_bank *bank, uint32_t address,
- const uint8_t *buf, uint32_t row_offset, uint32_t nb)
+static int samd_erase(struct flash_bank *bank, int first, int last)
{
int res;
+ int rows_in_sector;
struct samd_info *chip = (struct samd_info *)bank->driver_priv;
- uint32_t row_size = chip->page_size * 4;
- uint8_t *rb = malloc(row_size);
- if (!rb)
- return ERROR_FAIL;
- assert(row_offset + nb < row_size);
- assert((address % row_size) == 0);
+ if (bank->target->state != TARGET_HALTED) {
+ LOG_ERROR("Target not halted");
- /* Retrieve the full row contents from Flash */
- res = target_read_memory(bank->target, address, 4, row_size / 4, rb);
- if (res != ERROR_OK) {
- free(rb);
- return res;
+ return ERROR_TARGET_NOT_HALTED;
}
- /* Insert our partial row over the data from Flash */
- memcpy(rb + (row_offset % row_size), buf, nb);
+ if (!chip->probed) {
+ if (samd_probe(bank) != ERROR_OK)
+ return ERROR_FLASH_BANK_NOT_PROBED;
+ }
- /* Write the row back out */
- res = samd_write_row(bank, address, rb);
- free(rb);
+ /* The SAMD NVM has row erase granularity. There are four pages in a row
+ * and the number of rows in a sector depends on the sector size, which in
+ * turn depends on the Flash capacity as there is a fixed number of
+ * sectors. */
+ rows_in_sector = chip->sector_size / (chip->page_size * 4);
- return res;
+ /* For each sector to be erased */
+ for (int s = first; s <= last; s++) {
+ if (bank->sectors[s].is_protected) {
+ LOG_ERROR("SAMD: failed to erase sector %d. That sector is write-protected", s);
+ return ERROR_FLASH_OPERATION_FAILED;
+ }
+
+ /* For each row in that sector */
+ for (int r = s * rows_in_sector; r < (s + 1) * rows_in_sector; r++) {
+ res = samd_erase_row(bank->target, r * chip->page_size * 4);
+ if (res != ERROR_OK) {
+ LOG_ERROR("SAMD: failed to erase sector %d", s);
+ return res;
+ }
+ }
+ }
+
+ return ERROR_OK;
}
+
static int samd_write(struct flash_bank *bank, const uint8_t *buffer,
uint32_t offset, uint32_t count)
{
int res;
+ uint32_t nvm_ctrlb;
uint32_t address;
- uint32_t nb = 0;
+ uint32_t pg_offset;
+ uint32_t nb;
+ uint32_t nw;
struct samd_info *chip = (struct samd_info *)bank->driver_priv;
- uint32_t row_size = chip->page_size * 4;
+ uint8_t *pb = NULL;
+ bool manual_wp;
if (bank->target->state != TARGET_HALTED) {
LOG_ERROR("Target not halted");
-
return ERROR_TARGET_NOT_HALTED;
}
return ERROR_FLASH_BANK_NOT_PROBED;
}
- if (offset % row_size) {
- /* We're starting at an unaligned offset so we'll write a partial row
- * comprising that offset and up to the end of that row. */
- nb = row_size - (offset % row_size);
- if (nb > count)
- nb = count;
- } else if (count < row_size) {
- /* We're writing an aligned but partial row. */
- nb = count;
+ /* Check if we need to do manual page write commands */
+ res = target_read_u32(bank->target, SAMD_NVMCTRL + SAMD_NVMCTRL_CTRLB, &nvm_ctrlb);
+
+ if (res != ERROR_OK)
+ return res;
+
+ if (nvm_ctrlb & SAMD_NVM_CTRLB_MANW)
+ manual_wp = true;
+ else
+ manual_wp = false;
+
+ res = samd_issue_nvmctrl_command(bank->target, SAMD_NVM_CMD_PBC);
+ if (res != ERROR_OK) {
+ LOG_ERROR("%s: %d", __func__, __LINE__);
+ return res;
}
- address = (offset / row_size) * row_size + bank->base;
+ while (count) {
+ nb = chip->page_size - offset % chip->page_size;
+ if (count < nb)
+ nb = count;
- if (nb > 0) {
- res = samd_write_row_partial(bank, address, buffer,
- offset % row_size, nb);
- if (res != ERROR_OK)
- return res;
+ address = bank->base + offset;
+ pg_offset = offset % chip->page_size;
- /* We're done with the row contents */
- count -= nb;
- offset += nb;
- buffer += row_size;
- }
-
- /* There's at least one aligned row to write out. */
- if (count >= row_size) {
- int nr = count / row_size + ((count % row_size) ? 1 : 0);
- unsigned int r = 0;
-
- for (unsigned int i = address / row_size;
- (i < (address / row_size) + nr) && count > 0; i++) {
- address = (i * row_size) + bank->base;
-
- if (count >= row_size) {
- res = samd_write_row(bank, address, buffer + (r * row_size));
- /* Advance one row */
- offset += row_size;
- count -= row_size;
- } else {
- res = samd_write_row_partial(bank, address,
- buffer + (r * row_size), 0, count);
- /* We're done after this. */
- offset += count;
- count = 0;
+ if (offset % 4 || (offset + nb) % 4) {
+ /* Either start or end of write is not word aligned */
+ if (!pb) {
+ pb = malloc(chip->page_size);
+ if (!pb)
+ return ERROR_FAIL;
+ }
+
+ /* Set temporary page buffer to 0xff and overwrite the relevant part */
+ memset(pb, 0xff, chip->page_size);
+ memcpy(pb + pg_offset, buffer, nb);
+
+ /* Align start address to a word boundary */
+ address -= offset % 4;
+ pg_offset -= offset % 4;
+ assert(pg_offset % 4 == 0);
+
+ /* Extend length to whole words */
+ nw = (nb + offset % 4 + 3) / 4;
+ assert(pg_offset + 4 * nw <= chip->page_size);
+
+ /* Now we have original data extended by 0xff bytes
+ * to the nearest word boundary on both start and end */
+ res = target_write_memory(bank->target, address, 4, nw, pb + pg_offset);
+ } else {
+ assert(nb % 4 == 0);
+ nw = nb / 4;
+ assert(pg_offset + 4 * nw <= chip->page_size);
+
+ /* Word aligned data, use direct write from buffer */
+ res = target_write_memory(bank->target, address, 4, nw, buffer);
+ }
+ if (res != ERROR_OK) {
+ LOG_ERROR("%s: %d", __func__, __LINE__);
+ goto free_pb;
+ }
+
+ /* Devices with errata 13134 have automatic page write enabled by default
+ * For other devices issue a write page CMD to the NVM
+ * If the page has not been written up to the last word
+ * then issue CMD_WP always */
+ if (manual_wp || pg_offset + 4 * nw < chip->page_size) {
+ res = samd_issue_nvmctrl_command(bank->target, SAMD_NVM_CMD_WP);
+ if (res != ERROR_OK) {
+ LOG_ERROR("%s: %d", __func__, __LINE__);
+ goto free_pb;
}
+ }
- r++;
+ /* Access through AHB is stalled while flash is being programmed */
+ usleep(200);
- if (res != ERROR_OK)
- return res;
+ if (samd_check_error(bank->target)) {
+ LOG_ERROR("%s: write failed at address 0x%08" PRIx32, __func__, address);
+ res = ERROR_FAIL;
+ goto free_pb;
}
+
+ /* We're done with the page contents */
+ count -= nb;
+ offset += nb;
+ buffer += nb;
}
- return ERROR_OK;
+free_pb:
+ if (pb)
+ free(pb);
+
+ return res;
}
FLASH_BANK_COMMAND_HANDLER(samd_flash_bank_command)
return ERROR_OK;
}
+COMMAND_HANDLER(samd_handle_chip_erase_command)
+{
+ struct target *target = get_current_target(CMD_CTX);
+
+ if (target) {
+ /* Enable access to the DSU by disabling the write protect bit */
+ target_write_u32(target, SAMD_PAC1, (1<<1));
+ /* Tell the DSU to perform a full chip erase. It takes about 240ms to
+ * perform the erase. */
+ target_write_u8(target, SAMD_DSU, (1<<4));
+
+ command_print(CMD_CTX, "chip erased");
+ }
+
+ return ERROR_OK;
+}
+
+COMMAND_HANDLER(samd_handle_set_security_command)
+{
+ int res = ERROR_OK;
+ struct target *target = get_current_target(CMD_CTX);
+
+ if (CMD_ARGC < 1 || (CMD_ARGC >= 1 && (strcmp(CMD_ARGV[0], "enable")))) {
+ command_print(CMD_CTX, "supply the \"enable\" argument to proceed.");
+ return ERROR_COMMAND_SYNTAX_ERROR;
+ }
+
+ if (target) {
+ if (target->state != TARGET_HALTED) {
+ LOG_ERROR("Target not halted");
+ return ERROR_TARGET_NOT_HALTED;
+ }
+
+ res = samd_issue_nvmctrl_command(target, SAMD_NVM_CMD_SSB);
+
+ /* Check (and clear) error conditions */
+ if (res == ERROR_OK)
+ command_print(CMD_CTX, "chip secured on next power-cycle");
+ else
+ command_print(CMD_CTX, "failed to secure chip");
+ }
+
+ return res;
+}
+
+COMMAND_HANDLER(samd_handle_eeprom_command)
+{
+ int res = ERROR_OK;
+ struct target *target = get_current_target(CMD_CTX);
+
+ if (target) {
+ if (target->state != TARGET_HALTED) {
+ LOG_ERROR("Target not halted");
+ return ERROR_TARGET_NOT_HALTED;
+ }
+
+ if (CMD_ARGC >= 1) {
+ int val = atoi(CMD_ARGV[0]);
+ uint32_t code;
+
+ if (val == 0)
+ code = 7;
+ else {
+ /* Try to match size in bytes with corresponding size code */
+ for (code = 0; code <= 6; code++) {
+ if (val == (2 << (13 - code)))
+ break;
+ }
+
+ if (code > 6) {
+ command_print(CMD_CTX, "Invalid EEPROM size. Please see "
+ "datasheet for a list valid sizes.");
+ return ERROR_COMMAND_SYNTAX_ERROR;
+ }
+ }
+
+ res = samd_modify_user_row(target, code, 4, 6);
+ } else {
+ uint16_t val;
+ res = target_read_u16(target, SAMD_USER_ROW, &val);
+ if (res == ERROR_OK) {
+ uint32_t size = ((val >> 4) & 0x7); /* grab size code */
+
+ if (size == 0x7)
+ command_print(CMD_CTX, "EEPROM is disabled");
+ else {
+ /* Otherwise, 6 is 256B, 0 is 16KB */
+ command_print(CMD_CTX, "EEPROM size is %u bytes",
+ (2 << (13 - size)));
+ }
+ }
+ }
+ }
+
+ return res;
+}
+
+COMMAND_HANDLER(samd_handle_bootloader_command)
+{
+ int res = ERROR_OK;
+ struct target *target = get_current_target(CMD_CTX);
+
+ if (target) {
+ if (target->state != TARGET_HALTED) {
+ LOG_ERROR("Target not halted");
+ return ERROR_TARGET_NOT_HALTED;
+ }
+
+ /* Retrieve the MCU's page size, in bytes. */
+ uint32_t page_size;
+ res = samd_get_flash_page_info(target, &page_size, NULL);
+ if (res != ERROR_OK) {
+ LOG_ERROR("Couldn't determine Flash page size");
+ return res;
+ }
+
+ if (CMD_ARGC >= 1) {
+ int val = atoi(CMD_ARGV[0]);
+ uint32_t code;
+
+ if (val == 0)
+ code = 7;
+ else {
+ /* Try to match size in bytes with corresponding size code */
+ for (code = 0; code <= 6; code++) {
+ if ((unsigned int)val == (2UL << (8UL - code)) * page_size)
+ break;
+ }
+
+ if (code > 6) {
+ command_print(CMD_CTX, "Invalid bootloader size. Please "
+ "see datasheet for a list valid sizes.");
+ return ERROR_COMMAND_SYNTAX_ERROR;
+ }
+
+ }
+
+ res = samd_modify_user_row(target, code, 0, 2);
+ } else {
+ uint16_t val;
+ res = target_read_u16(target, SAMD_USER_ROW, &val);
+ if (res == ERROR_OK) {
+ uint32_t size = (val & 0x7); /* grab size code */
+ uint32_t nb;
+
+ if (size == 0x7)
+ nb = 0;
+ else
+ nb = (2 << (8 - size)) * page_size;
+
+ /* There are 4 pages per row */
+ command_print(CMD_CTX, "Bootloader size is %" PRIu32 " bytes (%" PRIu32 " rows)",
+ nb, (uint32_t)(nb / (page_size * 4)));
+ }
+ }
+ }
+
+ return res;
+}
+
+
+
+COMMAND_HANDLER(samd_handle_reset_deassert)
+{
+ struct target *target = get_current_target(CMD_CTX);
+ int retval = ERROR_OK;
+ enum reset_types jtag_reset_config = jtag_get_reset_config();
+
+ /* If the target has been unresponsive before, try to re-establish
+ * communication now - CPU is held in reset by DSU, DAP is working */
+ if (!target_was_examined(target))
+ target_examine_one(target);
+ target_poll(target);
+
+ /* In case of sysresetreq, debug retains state set in cortex_m_assert_reset()
+ * so we just release reset held by DSU
+ *
+ * n_RESET (srst) clears the DP, so reenable debug and set vector catch here
+ *
+ * After vectreset DSU release is not needed however makes no harm
+ */
+ if (target->reset_halt && (jtag_reset_config & RESET_HAS_SRST)) {
+ retval = target_write_u32(target, DCB_DHCSR, DBGKEY | C_HALT | C_DEBUGEN);
+ if (retval == ERROR_OK)
+ retval = target_write_u32(target, DCB_DEMCR,
+ TRCENA | VC_HARDERR | VC_BUSERR | VC_CORERESET);
+ /* do not return on error here, releasing DSU reset is more important */
+ }
+
+ /* clear CPU Reset Phase Extension bit */
+ int retval2 = target_write_u8(target, SAMD_DSU + SAMD_DSU_STATUSA, (1<<1));
+ if (retval2 != ERROR_OK)
+ return retval2;
+
+ return retval;
+}
+
static const struct command_registration at91samd_exec_command_handlers[] = {
+ {
+ .name = "dsu_reset_deassert",
+ .handler = samd_handle_reset_deassert,
+ .mode = COMMAND_EXEC,
+ .help = "deasert internal reset held by DSU"
+ },
{
.name = "info",
.handler = samd_handle_info_command,
.help = "Print information about the current at91samd chip"
"and its flash configuration.",
},
+ {
+ .name = "chip-erase",
+ .handler = samd_handle_chip_erase_command,
+ .mode = COMMAND_EXEC,
+ .help = "Erase the entire Flash by using the Chip"
+ "Erase feature in the Device Service Unit (DSU).",
+ },
+ {
+ .name = "set-security",
+ .handler = samd_handle_set_security_command,
+ .mode = COMMAND_EXEC,
+ .help = "Secure the chip's Flash by setting the Security Bit."
+ "This makes it impossible to read the Flash contents."
+ "The only way to undo this is to issue the chip-erase"
+ "command.",
+ },
+ {
+ .name = "eeprom",
+ .usage = "[size_in_bytes]",
+ .handler = samd_handle_eeprom_command,
+ .mode = COMMAND_EXEC,
+ .help = "Show or set the EEPROM size setting, stored in the User Row."
+ "Please see Table 20-3 of the SAMD20 datasheet for allowed values."
+ "Changes are stored immediately but take affect after the MCU is"
+ "reset.",
+ },
+ {
+ .name = "bootloader",
+ .usage = "[size_in_bytes]",
+ .handler = samd_handle_bootloader_command,
+ .mode = COMMAND_EXEC,
+ .help = "Show or set the bootloader size, stored in the User Row."
+ "Please see Table 20-2 of the SAMD20 datasheet for allowed values."
+ "Changes are stored immediately but take affect after the MCU is"
+ "reset.",
+ },
COMMAND_REGISTRATION_DONE
};