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micropython/espflash: A minimal ESP32 bootloader protocol implementation. #555

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micropython/espflash: A minimal ESP32 bootloader protocol implementation. #555

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308 changes: 308 additions & 0 deletions micropython/espflash/espflash.py
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# This file is part of the MicroPython project, http://micropython.org/
#
# The MIT License (MIT)
#
# Copyright (c) 2022 Ibrahim Abdelkader <[email protected]>
#
# Permission is hereby granted, free of charge, to any person obtaining a copy
# of this software and associated documentation files (the "Software"), to deal
# in the Software without restriction, including without limitation the rights
# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
# copies of the Software, and to permit persons to whom the Software is
# furnished to do so, subject to the following conditions:
#
# The above copyright notice and this permission notice shall be included in
# all copies or substantial portions of the Software.
#
# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
# THE SOFTWARE.
#
# A minimal esptool implementation to communicate with ESP32 ROM bootloader.
# Note this tool does Not support advanced features, other ESP chips or stub loading.
# This is only meant to be used for updating the U-blox Nina module firmware.

import os
import struct
from micropython import const
from time import sleep
import binascii

_CMD_SYNC = const(0x08)
_CMD_CHANGE_BAUDRATE = const(0x0F)

_CMD_ESP_READ_REG = const(0x0A)
_CMD_ESP_WRITE_REG = const(0x09)

_CMD_SPI_ATTACH = const(0x0D)
_CMD_SPI_FLASH_MD5 = const(0x13)
_CMD_SPI_FLASH_PARAMS = const(0x0B)
_CMD_SPI_FLASH_BEGIN = const(0x02)
_CMD_SPI_FLASH_DATA = const(0x03)
_CMD_SPI_FLASH_END = const(0x04)

_FLASH_ID = const(0)
_FLASH_REG_BASE = const(0x60002000)
_FLASH_BLOCK_SIZE = const(64 * 1024)
_FLASH_SECTOR_SIZE = const(4 * 1024)
_FLASH_PAGE_SIZE = const(256)

_ESP_ERRORS = {
0x05: "Received message is invalid",
0x06: "Failed to act on received message",
0x07: "Invalid CRC in message",
0x08: "Flash write error",
0x09: "Flash read error",
0x0A: "Flash read length error",
0x0B: "Deflate error",
}


class ESPFlash:
def __init__(self, reset, gpio0, uart, log_enabled=False):
self.uart = uart
self.reset_pin = reset
self.gpio0_pin = gpio0
self.log = log_enabled
self.baudrate = 115200
self.md5sum = None
try:
import hashlib

if hasattr(hashlib, "md5"):
self.md5sum = hashlib.md5()
except ImportError:
pass

def _log(self, data, out=True):
if self.log:
size = len(data)
print(
f"out({size}) => " if out else f"in({size}) <= ",
"".join("%.2x" % (i) for i in data[0:10]),
)

def _uart_drain(self):
while self.uart.read(1) is not None:
pass

def _read_reg(self, addr):
v, d = self._command(_CMD_ESP_READ_REG, struct.pack("<I", _FLASH_REG_BASE + addr))
if d[0] != 0:
raise Exception("Command ESP_READ_REG failed.")
return v

def _write_reg(self, addr, data, mask=0xFFFFFFFF, delay=0):
v, d = self._command(
_CMD_ESP_WRITE_REG, struct.pack("<IIII", _FLASH_REG_BASE + addr, data, mask, delay)
)
if d[0] != 0:
raise Exception("Command ESP_WRITE_REG failed.")

def _poll_reg(self, addr, flag, retry=10, delay=0.050):
for i in range(0, retry):
reg = self._read_reg(addr)
if (reg & flag) == 0:
break
sleep(delay)
else:
raise Exception(f"Register poll timeout. Addr: 0x{addr:02X} Flag: 0x{flag:02X}.")

def _write_slip(self, pkt):
pkt = pkt.replace(b"\xDB", b"\xdb\xdd").replace(b"\xc0", b"\xdb\xdc")
self.uart.write(b"\xC0" + pkt + b"\xC0")
self._log(pkt)

def _read_slip(self):
pkt = None
# Find the packet start.
if self.uart.read(1) == b"\xC0":
pkt = bytearray()
while True:
b = self.uart.read(1)
if b is None or b == b"\xC0":
break
pkt += b
pkt = pkt.replace(b"\xDB\xDD", b"\xDB").replace(b"\xDB\xDC", b"\xC0")
self._log(b"\xC0" + pkt + b"\xC0", False)
return pkt

def _strerror(self, err):
if err in _ESP_ERRORS:
return _ESP_ERRORS[err]
return "Unknown error"

def _checksum(self, data):
checksum = 0xEF
for i in data:
checksum ^= i
return checksum

def _command(self, cmd, payload=b"", checksum=0):
self._write_slip(struct.pack(b"<BBHI", 0, cmd, len(payload), checksum) + payload)
for i in range(10):
pkt = self._read_slip()
if pkt is not None and len(pkt) >= 8:
(flag, _cmd, size, val) = struct.unpack("<BBHI", pkt[:8])
if flag == 1 and cmd == _cmd:
status = list(pkt[-4:])
if status[0] == 1:
raise Exception(f"Command {cmd} failed {self._strerror(status[1])}")
return val, pkt[8:]
raise Exception(f"Failed to read response to command {cmd}.")

def set_baudrate(self, baudrate, timeout=350):
if not hasattr(self.uart, "init"):
return
if baudrate != self.baudrate:
print(f"Changing baudrate => {baudrate}")
self._uart_drain()
self._command(_CMD_CHANGE_BAUDRATE, struct.pack("<II", baudrate, 0))
self.baudrate = baudrate
self.uart.init(baudrate)
self._uart_drain()

def bootloader(self, retry=6):
for i in range(retry):
self.gpio0_pin(1)
self.reset_pin(0)
sleep(0.1)
self.gpio0_pin(0)
self.reset_pin(1)
sleep(0.1)
self.gpio0_pin(1)

if "POWERON_RESET" not in self.uart.read():
continue

for i in range(10):
self._uart_drain()
try:
# 36 bytes: 0x07 0x07 0x12 0x20, followed by 32 x 0x55
self._command(_CMD_SYNC, b"\x07\x07\x12\x20" + 32 * b"\x55")
self._uart_drain()
return True
except Exception as e:
print(e)

raise Exception("Failed to enter download mode!")

def flash_read_size(self):
SPI_REG_CMD = 0x00
SPI_USR_FLAG = 1 << 18
SPI_REG_USR = 0x1C
SPI_REG_USR2 = 0x24
SPI_REG_W0 = 0x80
SPI_REG_DLEN = 0x2C

# Command bit len | command
SPI_RDID_CMD = ((8 - 1) << 28) | 0x9F
SPI_RDID_LEN = 24 - 1

# Save USR and USR2 registers
reg_usr = self._read_reg(SPI_REG_USR)
reg_usr2 = self._read_reg(SPI_REG_USR2)

# Enable command phase and read phase.
self._write_reg(SPI_REG_USR, (1 << 31) | (1 << 28))

# Configure command.
self._write_reg(SPI_REG_DLEN, SPI_RDID_LEN)
self._write_reg(SPI_REG_USR2, SPI_RDID_CMD)

self._write_reg(SPI_REG_W0, 0)
# Trigger SPI operation.
self._write_reg(SPI_REG_CMD, SPI_USR_FLAG)

# Poll CMD_USER flag.
self._poll_reg(SPI_REG_CMD, SPI_USR_FLAG)

# Restore USR and USR2 registers
self._write_reg(SPI_REG_USR, reg_usr)
self._write_reg(SPI_REG_USR2, reg_usr2)

flash_bits = int(self._read_reg(SPI_REG_W0)) >> 16
if flash_bits < 0x12 or flash_bits > 0x19:
raise Exception(f"Unexpected flash size bits: 0x{flash_bits:02X}.")

flash_size = 2**flash_bits
print(f"Flash size {flash_size/1024/1024} MBytes")
return flash_size

def flash_attach(self):
self._command(_CMD_SPI_ATTACH, struct.pack("<II", 0, 0))
print(f"Flash attached")

def flash_config(self, flash_size=2 * 1024 * 1024):
self._command(
_CMD_SPI_FLASH_PARAMS,
struct.pack(
"<IIIIII",
_FLASH_ID,
flash_size,
_FLASH_BLOCK_SIZE,
_FLASH_SECTOR_SIZE,
_FLASH_PAGE_SIZE,
0xFFFF,
),
)

def flash_write_file(self, path, blksize=0x1000):
size = os.stat(path)[6]
total_blocks = (size + blksize - 1) // blksize
erase_blocks = 1
print(f"Flash write size: {size} total_blocks: {total_blocks} block size: {blksize}")
with open(path, "rb") as f:
seq = 0
subseq = 0
for i in range(total_blocks):
buf = f.read(blksize)
# Update digest
if self.md5sum is not None:
self.md5sum.update(buf)
# The last data block should be padded to the block size with 0xFF bytes.
if len(buf) < blksize:
buf += b"\xFF" * (blksize - len(buf))
checksum = self._checksum(buf)
if seq % erase_blocks == 0:
# print(f"Erasing {seq} -> {seq+erase_blocks}...")
self._command(
_CMD_SPI_FLASH_BEGIN,
struct.pack(
"<IIII", erase_blocks * blksize, erase_blocks, blksize, seq * blksize
),
)
print(f"Writing sequence number {seq}/{total_blocks}...")
self._command(
_CMD_SPI_FLASH_DATA,
struct.pack("<IIII", len(buf), seq % erase_blocks, 0, 0) + buf,
checksum,
)
seq += 1

print("Flash write finished")

def flash_verify_file(self, path, digest=None, offset=0):
if digest is None:
if self.md5sum is None:
raise Exception(f"MD5 checksum missing.")
digest = binascii.hexlify(self.md5sum.digest())

size = os.stat(path)[6]
val, data = self._command(_CMD_SPI_FLASH_MD5, struct.pack("<IIII", offset, size, 0, 0))

print(f"Flash verify: File MD5 {digest}")
print(f"Flash verify: Flash MD5 {bytes(data[0:32])}")

if digest == data[0:32]:
print("Firmware verified.")
else:
raise Exception(f"Firmware verification failed.")

def reboot(self):
payload = struct.pack("<I", 0)
self._write_slip(struct.pack(b"<BBHI", 0, _CMD_SPI_FLASH_END, len(payload), 0) + payload)
29 changes: 29 additions & 0 deletions micropython/espflash/example.py
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import espflash
from machine import Pin
from machine import UART

if __name__ == "__main__":
reset = Pin(3, Pin.OUT)
gpio0 = Pin(2, Pin.OUT)
uart = UART(1, 115200, tx=Pin(8), rx=Pin(9), timeout=350)

md5sum = b"9a6cf1257769c9f1af08452558e4d60e"
path = "NINA_W102-v1.5.0-Nano-RP2040-Connect.bin"

esp = espflash.ESPFlash(reset, gpio0, uart)
# Enter bootloader download mode, at 115200
esp.bootloader()
# Can now chage to higher/lower baudrate
esp.set_baudrate(921600)
# Must call this first before any flash functions.
esp.flash_attach()
# Read flash size
size = esp.flash_read_size()
# Configure flash parameters.
esp.flash_config(size)
# Write firmware image from internal storage.
esp.flash_write_file(path)
# Compares file and flash MD5 checksum.
esp.flash_verify_file(path, md5sum)
# Resets the ESP32 chip.
esp.reboot()
6 changes: 6 additions & 0 deletions micropython/espflash/manifest.py
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metadata(
version="0.1",
description="Provides a minimal ESP32 bootloader protocol implementation.",
)

module("espflash.py")