unleashed-firmware/scripts/flipper/utils/programmer_openocd.py
Sergey Gavrilov 727f043747
OpenOCD scripts (#2101)
* Scripts: option bytes check
* Scripts: option bytes set
* Scripts: openocd config
* Scripts: increased readability, process IPCCBR option byte
* Scripts: split dap_ob.py
* Updater: process IPCCBR option byte
* Scripts: move chip-related functions to chip definition
* Scripts: freeze CPU registers
* Scripts: flash programming routine
* ob.py
* otp.py
* otp: handle errors correctly
* downgrade to python 3.9
* correct type hinting
* Scripts: fix path to ob.data

Co-authored-by: あく <alleteam@gmail.com>
2022-12-27 21:59:36 +09:00

281 lines
9.6 KiB
Python

import logging
import os
import typing
from flipper.utils.programmer import Programmer
from flipper.utils.openocd import OpenOCD
from flipper.utils.stm32wb55 import STM32WB55
from flipper.assets.obdata import OptionBytesData
class OpenOCDProgrammer(Programmer):
def __init__(
self,
interface: str = "interface/cmsis-dap.cfg",
port_base: typing.Union[int, None] = None,
serial: typing.Union[str, None] = None,
):
super().__init__()
config = {}
config["interface"] = interface
config["target"] = "target/stm32wbx.cfg"
if not serial is None:
if interface == "interface/cmsis-dap.cfg":
config["serial"] = f"cmsis_dap_serial {serial}"
elif "stlink" in interface:
config["serial"] = f"stlink_serial {serial}"
if not port_base is None:
config["port_base"] = port_base
self.openocd = OpenOCD(config)
self.logger = logging.getLogger()
def reset(self, mode: Programmer.RunMode = Programmer.RunMode.Run) -> bool:
stm32 = STM32WB55()
if mode == Programmer.RunMode.Run:
stm32.reset(self.openocd, stm32.RunMode.Run)
elif mode == Programmer.RunMode.Stop:
stm32.reset(self.openocd, stm32.RunMode.Init)
else:
raise Exception("Unknown mode")
return True
def flash(self, address: int, file_path: str, verify: bool = True) -> bool:
if not os.path.exists(file_path):
raise Exception(f"File {file_path} not found")
self.openocd.start()
self.openocd.send_tcl(f"init")
self.openocd.send_tcl(
f"program {file_path} 0x{address:08x}{' verify' if verify else ''} reset exit"
)
self.openocd.stop()
return True
def _ob_print_diff_table(self, ob_reference: bytes, ob_read: bytes, print_fn):
print_fn(
f'{"Reference": <20} {"Device": <20} {"Diff Reference": <20} {"Diff Device": <20}'
)
# Split into 8 byte, word + word
for i in range(0, len(ob_reference), 8):
ref = ob_reference[i : i + 8]
read = ob_read[i : i + 8]
diff_str1 = ""
diff_str2 = ""
for j in range(0, len(ref.hex()), 2):
byte_str_1 = ref.hex()[j : j + 2]
byte_str_2 = read.hex()[j : j + 2]
if byte_str_1 == byte_str_2:
diff_str1 += "__"
diff_str2 += "__"
else:
diff_str1 += byte_str_1
diff_str2 += byte_str_2
print_fn(
f"{ref.hex(): <20} {read.hex(): <20} {diff_str1: <20} {diff_str2: <20}"
)
def option_bytes_validate(self, file_path: str) -> bool:
# Registers
stm32 = STM32WB55()
# OpenOCD
self.openocd.start()
stm32.reset(self.openocd, stm32.RunMode.Init)
# Generate Option Bytes data
ob_data = OptionBytesData(file_path)
ob_values = ob_data.gen_values().export()
ob_reference = ob_values.reference
ob_compare_mask = ob_values.compare_mask
ob_length = len(ob_reference)
ob_words = int(ob_length / 4)
# Read Option Bytes
ob_read = bytes()
for i in range(ob_words):
addr = stm32.OPTION_BYTE_BASE + i * 4
value = self.openocd.read_32(addr)
ob_read += value.to_bytes(4, "little")
# Compare Option Bytes with reference by mask
ob_compare = bytes()
for i in range(ob_length):
ob_compare += bytes([ob_read[i] & ob_compare_mask[i]])
# Compare Option Bytes
return_code = False
if ob_reference == ob_compare:
self.logger.info("Option Bytes are valid")
return_code = True
else:
self.logger.error("Option Bytes are invalid")
self._ob_print_diff_table(ob_reference, ob_compare, self.logger.error)
# Stop OpenOCD
stm32.reset(self.openocd, stm32.RunMode.Run)
self.openocd.stop()
return return_code
def _unpack_u32(self, data: bytes, offset: int):
return int.from_bytes(data[offset : offset + 4], "little")
def option_bytes_set(self, file_path: str) -> bool:
# Registers
stm32 = STM32WB55()
# OpenOCD
self.openocd.start()
stm32.reset(self.openocd, stm32.RunMode.Init)
# Generate Option Bytes data
ob_data = OptionBytesData(file_path)
ob_values = ob_data.gen_values().export()
ob_reference_bytes = ob_values.reference
ob_compare_mask_bytes = ob_values.compare_mask
ob_write_mask_bytes = ob_values.write_mask
ob_length = len(ob_reference_bytes)
ob_dwords = int(ob_length / 8)
# Clear flash errors
stm32.clear_flash_errors(self.openocd)
# Unlock Flash and Option Bytes
stm32.flash_unlock(self.openocd)
stm32.option_bytes_unlock(self.openocd)
ob_need_to_apply = False
for i in range(ob_dwords):
device_addr = stm32.OPTION_BYTE_BASE + i * 8
device_value = self.openocd.read_32(device_addr)
ob_write_mask = self._unpack_u32(ob_write_mask_bytes, i * 8)
ob_compare_mask = self._unpack_u32(ob_compare_mask_bytes, i * 8)
ob_value_ref = self._unpack_u32(ob_reference_bytes, i * 8)
ob_value_masked = device_value & ob_compare_mask
need_patch = ((ob_value_masked ^ ob_value_ref) & ob_write_mask) != 0
if need_patch:
ob_need_to_apply = True
self.logger.info(
f"Need to patch: {device_addr:08X}: {ob_value_masked:08X} != {ob_value_ref:08X}, REG[{i}]"
)
# Check if this option byte (dword) is mapped to a register
device_reg_addr = stm32.option_bytes_id_to_address(i)
# Construct new value for the OB register
ob_value = device_value & (~ob_write_mask)
ob_value |= ob_value_ref & ob_write_mask
self.logger.info(f"Writing {ob_value:08X} to {device_reg_addr:08X}")
self.openocd.write_32(device_reg_addr, ob_value)
if ob_need_to_apply:
stm32.option_bytes_apply(self.openocd)
else:
self.logger.info(f"Option Bytes are already correct")
# Load Option Bytes
# That will reset and also lock the Option Bytes and the Flash
stm32.option_bytes_load(self.openocd)
# Stop OpenOCD
stm32.reset(self.openocd, stm32.RunMode.Run)
self.openocd.stop()
return True
def otp_write(self, address: int, file_path: str) -> bool:
# Open file, check that it aligned to 8 bytes
with open(file_path, "rb") as f:
data = f.read()
if len(data) % 8 != 0:
self.logger.error(f"File {file_path} is not aligned to 8 bytes")
return False
# Check that address is aligned to 8 bytes
if address % 8 != 0:
self.logger.error(f"Address {address} is not aligned to 8 bytes")
return False
# Get size of data
data_size = len(data)
# Check that data size is aligned to 8 bytes
if data_size % 8 != 0:
self.logger.error(f"Data size {data_size} is not aligned to 8 bytes")
return False
self.logger.debug(f"Writing {data_size} bytes to OTP at {address:08X}")
self.logger.debug(f"Data: {data.hex().upper()}")
# Start OpenOCD
oocd = self.openocd
oocd.start()
# Registers
stm32 = STM32WB55()
try:
# Check that OTP is empty for the given address
# Also check that data is already written
already_written = True
for i in range(0, data_size, 4):
file_word = int.from_bytes(data[i : i + 4], "little")
device_word = oocd.read_32(address + i)
if device_word != 0xFFFFFFFF and device_word != file_word:
self.logger.error(
f"OTP memory at {address + i:08X} is not empty: {device_word:08X}"
)
raise Exception("OTP memory is not empty")
if device_word != file_word:
already_written = False
if already_written:
self.logger.info(f"OTP memory is already written with the given data")
return True
self.reset(self.RunMode.Stop)
stm32.clear_flash_errors(oocd)
# Write OTP memory by 8 bytes
for i in range(0, data_size, 8):
word_1 = int.from_bytes(data[i : i + 4], "little")
word_2 = int.from_bytes(data[i + 4 : i + 8], "little")
self.logger.debug(
f"Writing {word_1:08X} {word_2:08X} to {address + i:08X}"
)
stm32.write_flash_64(oocd, address + i, word_1, word_2)
# Validate OTP memory
validation_result = True
for i in range(0, data_size, 4):
file_word = int.from_bytes(data[i : i + 4], "little")
device_word = oocd.read_32(address + i)
if file_word != device_word:
self.logger.error(
f"Validation failed: {file_word:08X} != {device_word:08X} at {address + i:08X}"
)
validation_result = False
finally:
# Stop OpenOCD
stm32.reset(oocd, stm32.RunMode.Run)
oocd.stop()
return validation_result