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esptool.py
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esptool.py
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#!/usr/bin/env python
#
# ESP8266 & ESP32 ROM Bootloader Utility
# Copyright (C) 2014-2016 Fredrik Ahlberg, Angus Gratton, Espressif Systems (Shanghai) PTE LTD, other contributors as noted.
# https://github.com/espressif/esptool
#
# This program is free software; you can redistribute it and/or modify it under
# the terms of the GNU General Public License as published by the Free Software
# Foundation; either version 2 of the License, or (at your option) any later version.
#
# This program is distributed in the hope that it will be useful, but WITHOUT
# ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
# FOR A PARTICULAR PURPOSE. See the 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.
from __future__ import division, print_function
import argparse
import base64
import binascii
import copy
import hashlib
import inspect
import io
import os
import shlex
import struct
import sys
import time
import zlib
import string
try:
import serial
except ImportError:
print("Pyserial is not installed for %s. Check the README for installation instructions." % (sys.executable))
raise
# check 'serial' is 'pyserial' and not 'serial' https://github.com/espressif/esptool/issues/269
try:
if "serialization" in serial.__doc__ and "deserialization" in serial.__doc__:
raise ImportError("""
esptool.py depends on pyserial, but there is a conflict with a currently installed package named 'serial'.
You may be able to work around this by 'pip uninstall serial; pip install pyserial' \
but this may break other installed Python software that depends on 'serial'.
There is no good fix for this right now, apart from configuring virtualenvs. \
See https://github.com/espressif/esptool/issues/269#issuecomment-385298196 for discussion of the underlying issue(s).""")
except TypeError:
pass # __doc__ returns None for pyserial
try:
import serial.tools.list_ports as list_ports
except ImportError:
print("The installed version (%s) of pyserial appears to be too old for esptool.py (Python interpreter %s). "
"Check the README for installation instructions." % (sys.VERSION, sys.executable))
raise
__version__ = "2.7-dev"
MAX_UINT32 = 0xffffffff
MAX_UINT24 = 0xffffff
DEFAULT_TIMEOUT = 3 # timeout for most flash operations
START_FLASH_TIMEOUT = 20 # timeout for starting flash (may perform erase)
CHIP_ERASE_TIMEOUT = 120 # timeout for full chip erase
MAX_TIMEOUT = CHIP_ERASE_TIMEOUT * 2 # longest any command can run
SYNC_TIMEOUT = 0.1 # timeout for syncing with bootloader
MD5_TIMEOUT_PER_MB = 8 # timeout (per megabyte) for calculating md5sum
ERASE_REGION_TIMEOUT_PER_MB = 30 # timeout (per megabyte) for erasing a region
MEM_END_ROM_TIMEOUT = 0.05 # special short timeout for ESP_MEM_END, as it may never respond
DEFAULT_SERIAL_WRITE_TIMEOUT = 10 # timeout for serial port write
def timeout_per_mb(seconds_per_mb, size_bytes):
""" Scales timeouts which are size-specific """
result = seconds_per_mb * (size_bytes / 1e6)
if result < DEFAULT_TIMEOUT:
return DEFAULT_TIMEOUT
return result
DETECTED_FLASH_SIZES = {0x12: '256KB', 0x13: '512KB', 0x14: '1MB',
0x15: '2MB', 0x16: '4MB', 0x17: '8MB', 0x18: '16MB'}
def check_supported_function(func, check_func):
"""
Decorator implementation that wraps a check around an ESPLoader
bootloader function to check if it's supported.
This is used to capture the multidimensional differences in
functionality between the ESP8266 & ESP32 ROM loaders, and the
software stub that runs on both. Not possible to do this cleanly
via inheritance alone.
"""
def inner(*args, **kwargs):
obj = args[0]
if check_func(obj):
return func(*args, **kwargs)
else:
raise NotImplementedInROMError(obj, func)
return inner
def stub_function_only(func):
""" Attribute for a function only supported in the software stub loader """
return check_supported_function(func, lambda o: o.IS_STUB)
def stub_and_esp32_function_only(func):
""" Attribute for a function only supported by software stubs or ESP32 ROM """
return check_supported_function(func, lambda o: o.IS_STUB or o.CHIP_NAME == "ESP32")
PYTHON2 = sys.version_info[0] < 3 # True if on pre-Python 3
# Function to return nth byte of a bitstring
# Different behaviour on Python 2 vs 3
if PYTHON2:
def byte(bitstr, index):
return ord(bitstr[index])
else:
def byte(bitstr, index):
return bitstr[index]
# Provide a 'basestring' class on Python 3
try:
basestring
except NameError:
basestring = str
def esp8266_function_only(func):
""" Attribute for a function only supported on ESP8266 """
return check_supported_function(func, lambda o: o.CHIP_NAME == "ESP8266")
class ESPLoader(object):
""" Base class providing access to ESP ROM & software stub bootloaders.
Subclasses provide ESP8266 & ESP32 specific functionality.
Don't instantiate this base class directly, either instantiate a subclass or
call ESPLoader.detect_chip() which will interrogate the chip and return the
appropriate subclass instance.
"""
CHIP_NAME = "Espressif device"
IS_STUB = False
DEFAULT_PORT = "/dev/ttyUSB0"
# Commands supported by ESP8266 ROM bootloader
ESP_FLASH_BEGIN = 0x02
ESP_FLASH_DATA = 0x03
ESP_FLASH_END = 0x04
ESP_MEM_BEGIN = 0x05
ESP_MEM_END = 0x06
ESP_MEM_DATA = 0x07
ESP_SYNC = 0x08
ESP_WRITE_REG = 0x09
ESP_READ_REG = 0x0a
# Some comands supported by ESP32 ROM bootloader (or -8266 w/ stub)
ESP_SPI_SET_PARAMS = 0x0B
ESP_SPI_ATTACH = 0x0D
ESP_CHANGE_BAUDRATE = 0x0F
ESP_FLASH_DEFL_BEGIN = 0x10
ESP_FLASH_DEFL_DATA = 0x11
ESP_FLASH_DEFL_END = 0x12
ESP_SPI_FLASH_MD5 = 0x13
# Some commands supported by stub only
ESP_ERASE_FLASH = 0xD0
ESP_ERASE_REGION = 0xD1
ESP_READ_FLASH = 0xD2
ESP_RUN_USER_CODE = 0xD3
# Flash encryption debug more command
ESP_FLASH_ENCRYPT_DATA = 0xD4
# Maximum block sized for RAM and Flash writes, respectively.
ESP_RAM_BLOCK = 0x1800
FLASH_WRITE_SIZE = 0x400
# Default baudrate. The ROM auto-bauds, so we can use more or less whatever we want.
ESP_ROM_BAUD = 115200
# First byte of the application image
ESP_IMAGE_MAGIC = 0xe9
# Initial state for the checksum routine
ESP_CHECKSUM_MAGIC = 0xef
# Flash sector size, minimum unit of erase.
FLASH_SECTOR_SIZE = 0x1000
UART_DATA_REG_ADDR = 0x60000078
# Memory addresses
IROM_MAP_START = 0x40200000
IROM_MAP_END = 0x40300000
# The number of bytes in the UART response that signify command status
STATUS_BYTES_LENGTH = 2
def __init__(self, port=DEFAULT_PORT, baud=ESP_ROM_BAUD, trace_enabled=False):
"""Base constructor for ESPLoader bootloader interaction
Don't call this constructor, either instantiate ESP8266ROM
or ESP32ROM, or use ESPLoader.detect_chip().
This base class has all of the instance methods for bootloader
functionality supported across various chips & stub
loaders. Subclasses replace the functions they don't support
with ones which throw NotImplementedInROMError().
"""
if isinstance(port, basestring):
self._port = serial.serial_for_url(port)
else:
self._port = port
self._slip_reader = slip_reader(self._port, self.trace)
# setting baud rate in a separate step is a workaround for
# CH341 driver on some Linux versions (this opens at 9600 then
# sets), shouldn't matter for other platforms/drivers. See
# https://github.com/espressif/esptool/issues/44#issuecomment-107094446
self._set_port_baudrate(baud)
self._trace_enabled = trace_enabled
# set write timeout, to prevent esptool blocked at write forever.
try:
self._port.write_timeout = DEFAULT_SERIAL_WRITE_TIMEOUT
except NotImplementedError:
# no write timeout for RFC2217 ports
# need to set the property back to None or it will continue to fail
self._port.write_timeout = None
def _set_port_baudrate(self, baud):
try:
self._port.baudrate = baud
except IOError:
raise FatalError("Failed to set baud rate %d. The driver may not support this rate." % baud)
@staticmethod
def detect_chip(port=DEFAULT_PORT, baud=ESP_ROM_BAUD, connect_mode='default_reset', trace_enabled=False):
""" Use serial access to detect the chip type.
We use the UART's datecode register for this, it's mapped at
the same address on ESP8266 & ESP32 so we can use one
memory read and compare to the datecode register for each chip
type.
This routine automatically performs ESPLoader.connect() (passing
connect_mode parameter) as part of querying the chip.
"""
detect_port = ESPLoader(port, baud, trace_enabled=trace_enabled)
detect_port.connect(connect_mode)
try:
print('Detecting chip type...', end='')
sys.stdout.flush()
date_reg = detect_port.read_reg(ESPLoader.UART_DATA_REG_ADDR)
for cls in [ESP8266ROM, ESP32ROM]:
if date_reg == cls.DATE_REG_VALUE:
# don't connect a second time
inst = cls(detect_port._port, baud, trace_enabled=trace_enabled)
print(' %s' % inst.CHIP_NAME, end='')
return inst
finally:
print('') # end line
raise FatalError("Unexpected UART datecode value 0x%08x. Failed to autodetect chip type." % date_reg)
""" Read a SLIP packet from the serial port """
def read(self):
return next(self._slip_reader)
""" Write bytes to the serial port while performing SLIP escaping """
def write(self, packet):
buf = b'\xc0' \
+ (packet.replace(b'\xdb',b'\xdb\xdd').replace(b'\xc0',b'\xdb\xdc')) \
+ b'\xc0'
self.trace("Write %d bytes: %s", len(buf), HexFormatter(buf))
self._port.write(buf)
def trace(self, message, *format_args):
if self._trace_enabled:
now = time.time()
try:
delta = now - self._last_trace
except AttributeError:
delta = 0.0
self._last_trace = now
prefix = "TRACE +%.3f " % delta
print(prefix + (message % format_args))
""" Calculate checksum of a blob, as it is defined by the ROM """
@staticmethod
def checksum(data, state=ESP_CHECKSUM_MAGIC):
for b in data:
if type(b) is int: # python 2/3 compat
state ^= b
else:
state ^= ord(b)
return state
""" Send a request and read the response """
def command(self, op=None, data=b"", chk=0, wait_response=True, timeout=DEFAULT_TIMEOUT):
saved_timeout = self._port.timeout
new_timeout = min(timeout, MAX_TIMEOUT)
if new_timeout != saved_timeout:
self._port.timeout = new_timeout
try:
if op is not None:
self.trace("command op=0x%02x data len=%s wait_response=%d timeout=%.3f data=%s",
op, len(data), 1 if wait_response else 0, timeout, HexFormatter(data))
pkt = struct.pack(b'<BBHI', 0x00, op, len(data), chk) + data
self.write(pkt)
if not wait_response:
return
# tries to get a response until that response has the
# same operation as the request or a retries limit has
# exceeded. This is needed for some esp8266s that
# reply with more sync responses than expected.
for retry in range(100):
p = self.read()
if len(p) < 8:
continue
(resp, op_ret, len_ret, val) = struct.unpack('<BBHI', p[:8])
if resp != 1:
continue
data = p[8:]
if op is None or op_ret == op:
return val, data
finally:
if new_timeout != saved_timeout:
self._port.timeout = saved_timeout
raise FatalError("Response doesn't match request")
def check_command(self, op_description, op=None, data=b'', chk=0, timeout=DEFAULT_TIMEOUT):
"""
Execute a command with 'command', check the result code and throw an appropriate
FatalError if it fails.
Returns the "result" of a successful command.
"""
val, data = self.command(op, data, chk, timeout=timeout)
# things are a bit weird here, bear with us
# the status bytes are the last 2/4 bytes in the data (depending on chip)
if len(data) < self.STATUS_BYTES_LENGTH:
raise FatalError("Failed to %s. Only got %d byte status response." % (op_description, len(data)))
status_bytes = data[-self.STATUS_BYTES_LENGTH:]
# we only care if the first one is non-zero. If it is, the second byte is a reason.
if byte(status_bytes, 0) != 0:
raise FatalError.WithResult('Failed to %s' % op_description, status_bytes)
# if we had more data than just the status bytes, return it as the result
# (this is used by the md5sum command, maybe other commands?)
if len(data) > self.STATUS_BYTES_LENGTH:
return data[:-self.STATUS_BYTES_LENGTH]
else: # otherwise, just return the 'val' field which comes from the reply header (this is used by read_reg)
return val
def flush_input(self):
self._port.flushInput()
self._slip_reader = slip_reader(self._port, self.trace)
def sync(self):
self.command(self.ESP_SYNC, b'\x07\x07\x12\x20' + 32 * b'\x55',
timeout=SYNC_TIMEOUT)
for i in range(7):
self.command()
def _setDTR(self, state):
self._port.setDTR(state)
def _setRTS(self, state):
self._port.setRTS(state)
# Work-around for adapters on Windows using the usbser.sys driver:
# generate a dummy change to DTR so that the set-control-line-state
# request is sent with the updated RTS state and the same DTR state
self._port.setDTR(self._port.dtr)
def _connect_attempt(self, mode='default_reset', esp32r0_delay=False):
""" A single connection attempt, with esp32r0 workaround options """
# esp32r0_delay is a workaround for bugs with the most common auto reset
# circuit and Windows, if the EN pin on the dev board does not have
# enough capacitance.
#
# Newer dev boards shouldn't have this problem (higher value capacitor
# on the EN pin), and ESP32 revision 1 can't use this workaround as it
# relies on a silicon bug.
#
# Details: https://github.com/espressif/esptool/issues/136
last_error = None
# If we're doing no_sync, we're likely communicating as a pass through
# with an intermediate device to the ESP32
if mode == "no_reset_no_sync":
return last_error
# issue reset-to-bootloader:
# RTS = either CH_PD/EN or nRESET (both active low = chip in reset
# DTR = GPIO0 (active low = boot to flasher)
#
# DTR & RTS are active low signals,
# ie True = pin @ 0V, False = pin @ VCC.
if mode != 'no_reset':
self._setDTR(False) # IO0=HIGH
self._setRTS(True) # EN=LOW, chip in reset
time.sleep(0.1)
if esp32r0_delay:
# Some chips are more likely to trigger the esp32r0
# watchdog reset silicon bug if they're held with EN=LOW
# for a longer period
time.sleep(1.2)
self._setDTR(True) # IO0=LOW
self._setRTS(False) # EN=HIGH, chip out of reset
if esp32r0_delay:
# Sleep longer after reset.
# This workaround only works on revision 0 ESP32 chips,
# it exploits a silicon bug spurious watchdog reset.
time.sleep(0.4) # allow watchdog reset to occur
time.sleep(0.05)
self._setDTR(False) # IO0=HIGH, done
for _ in range(5):
try:
self.flush_input()
self._port.flushOutput()
self.sync()
return None
except FatalError as e:
if esp32r0_delay:
print('_', end='')
else:
print('.', end='')
sys.stdout.flush()
time.sleep(0.05)
last_error = e
return last_error
def connect(self, mode='default_reset'):
""" Try connecting repeatedly until successful, or giving up """
print('Connecting...', end='')
sys.stdout.flush()
last_error = None
try:
for _ in range(7):
last_error = self._connect_attempt(mode=mode, esp32r0_delay=False)
if last_error is None:
return
last_error = self._connect_attempt(mode=mode, esp32r0_delay=True)
if last_error is None:
return
finally:
print('') # end 'Connecting...' line
raise FatalError('Failed to connect to %s: %s' % (self.CHIP_NAME, last_error))
""" Read memory address in target """
def read_reg(self, addr):
# we don't call check_command here because read_reg() function is called
# when detecting chip type, and the way we check for success (STATUS_BYTES_LENGTH) is different
# for different chip types (!)
val, data = self.command(self.ESP_READ_REG, struct.pack('<I', addr))
if byte(data, 0) != 0:
raise FatalError.WithResult("Failed to read register address %08x" % addr, data)
return val
""" Write to memory address in target """
def write_reg(self, addr, value, mask=0xFFFFFFFF, delay_us=0):
return self.check_command("write target memory", self.ESP_WRITE_REG,
struct.pack('<IIII', addr, value, mask, delay_us))
""" Start downloading an application image to RAM """
def mem_begin(self, size, blocks, blocksize, offset):
if self.IS_STUB: # check we're not going to overwrite a running stub with this data
stub = self.STUB_CODE
load_start = offset
load_end = offset + size
for (start, end) in [(stub["data_start"], stub["data_start"] + len(stub["data"])),
(stub["text_start"], stub["text_start"] + len(stub["text"]))]:
if load_start < end and load_end > start:
raise FatalError(("Software loader is resident at 0x%08x-0x%08x. " +
"Can't load binary at overlapping address range 0x%08x-0x%08x. " +
"Either change binary loading address, or use the --no-stub " +
"option to disable the software loader.") % (start, end, load_start, load_end))
return self.check_command("enter RAM download mode", self.ESP_MEM_BEGIN,
struct.pack('<IIII', size, blocks, blocksize, offset))
""" Send a block of an image to RAM """
def mem_block(self, data, seq):
return self.check_command("write to target RAM", self.ESP_MEM_DATA,
struct.pack('<IIII', len(data), seq, 0, 0) + data,
self.checksum(data))
""" Leave download mode and run the application """
def mem_finish(self, entrypoint=0):
# Sending ESP_MEM_END usually sends a correct response back, however sometimes
# (with ROM loader) the executed code may reset the UART or change the baud rate
# before the transmit FIFO is empty. So in these cases we set a short timeout and
# ignore errors.
timeout = DEFAULT_TIMEOUT if self.IS_STUB else MEM_END_ROM_TIMEOUT
data = struct.pack('<II', int(entrypoint == 0), entrypoint)
try:
return self.check_command("leave RAM download mode", self.ESP_MEM_END,
data=data, timeout=timeout)
except FatalError:
if self.IS_STUB:
raise
pass
""" Start downloading to Flash (performs an erase)
Returns number of blocks (of size self.FLASH_WRITE_SIZE) to write.
"""
def flash_begin(self, size, offset):
num_blocks = (size + self.FLASH_WRITE_SIZE - 1) // self.FLASH_WRITE_SIZE
erase_size = self.get_erase_size(offset, size)
t = time.time()
if self.IS_STUB:
timeout = DEFAULT_TIMEOUT
else:
timeout = timeout_per_mb(ERASE_REGION_TIMEOUT_PER_MB, size) # ROM performs the erase up front
self.check_command("enter Flash download mode", self.ESP_FLASH_BEGIN,
struct.pack('<IIII', erase_size, num_blocks, self.FLASH_WRITE_SIZE, offset),
timeout=timeout)
if size != 0 and not self.IS_STUB:
print("Took %.2fs to erase flash block" % (time.time() - t))
return num_blocks
""" Write block to flash """
def flash_block(self, data, seq, timeout=DEFAULT_TIMEOUT):
self.check_command("write to target Flash after seq %d" % seq,
self.ESP_FLASH_DATA,
struct.pack('<IIII', len(data), seq, 0, 0) + data,
self.checksum(data),
timeout=timeout)
""" Encrypt before writing to flash """
def flash_encrypt_block(self, data, seq, timeout=DEFAULT_TIMEOUT):
self.check_command("Write encrypted to target Flash after seq %d" % seq,
self.ESP_FLASH_ENCRYPT_DATA,
struct.pack('<IIII', len(data), seq, 0, 0) + data,
self.checksum(data),
timeout=timeout)
""" Leave flash mode and run/reboot """
def flash_finish(self, reboot=False):
pkt = struct.pack('<I', int(not reboot))
# stub sends a reply to this command
self.check_command("leave Flash mode", self.ESP_FLASH_END, pkt)
""" Run application code in flash """
def run(self, reboot=False):
# Fake flash begin immediately followed by flash end
self.flash_begin(0, 0)
self.flash_finish(reboot)
""" Read SPI flash manufacturer and device id """
def flash_id(self):
SPIFLASH_RDID = 0x9F
return self.run_spiflash_command(SPIFLASH_RDID, b"", 24)
def parse_flash_size_arg(self, arg):
try:
return self.FLASH_SIZES[arg]
except KeyError:
raise FatalError("Flash size '%s' is not supported by this chip type. Supported sizes: %s"
% (arg, ", ".join(self.FLASH_SIZES.keys())))
def run_stub(self, stub=None):
if stub is None:
if self.IS_STUB:
raise FatalError("Not possible for a stub to load another stub (memory likely to overlap.)")
stub = self.STUB_CODE
# Upload
print("Uploading stub...")
for field in ['text', 'data']:
if field in stub:
offs = stub[field + "_start"]
length = len(stub[field])
blocks = (length + self.ESP_RAM_BLOCK - 1) // self.ESP_RAM_BLOCK
self.mem_begin(length, blocks, self.ESP_RAM_BLOCK, offs)
for seq in range(blocks):
from_offs = seq * self.ESP_RAM_BLOCK
to_offs = from_offs + self.ESP_RAM_BLOCK
self.mem_block(stub[field][from_offs:to_offs], seq)
print("Running stub...")
self.mem_finish(stub['entry'])
p = self.read()
if p != b'OHAI':
raise FatalError("Failed to start stub. Unexpected response: %s" % p)
print("Stub running...")
return self.STUB_CLASS(self)
@stub_and_esp32_function_only
def flash_defl_begin(self, size, compsize, offset):
""" Start downloading compressed data to Flash (performs an erase)
Returns number of blocks (size self.FLASH_WRITE_SIZE) to write.
"""
num_blocks = (compsize + self.FLASH_WRITE_SIZE - 1) // self.FLASH_WRITE_SIZE
erase_blocks = (size + self.FLASH_WRITE_SIZE - 1) // self.FLASH_WRITE_SIZE
t = time.time()
if self.IS_STUB:
write_size = size # stub expects number of bytes here, manages erasing internally
timeout = DEFAULT_TIMEOUT
else:
write_size = erase_blocks * self.FLASH_WRITE_SIZE # ROM expects rounded up to erase block size
timeout = timeout_per_mb(ERASE_REGION_TIMEOUT_PER_MB, write_size) # ROM performs the erase up front
print("Compressed %d bytes to %d..." % (size, compsize))
self.check_command("enter compressed flash mode", self.ESP_FLASH_DEFL_BEGIN,
struct.pack('<IIII', write_size, num_blocks, self.FLASH_WRITE_SIZE, offset),
timeout=timeout)
if size != 0 and not self.IS_STUB:
# (stub erases as it writes, but ROM loaders erase on begin)
print("Took %.2fs to erase flash block" % (time.time() - t))
return num_blocks
""" Write block to flash, send compressed """
@stub_and_esp32_function_only
def flash_defl_block(self, data, seq, timeout=DEFAULT_TIMEOUT):
self.check_command("write compressed data to flash after seq %d" % seq,
self.ESP_FLASH_DEFL_DATA, struct.pack('<IIII', len(data), seq, 0, 0) + data, self.checksum(data), timeout=timeout)
""" Leave compressed flash mode and run/reboot """
@stub_and_esp32_function_only
def flash_defl_finish(self, reboot=False):
if not reboot and not self.IS_STUB:
# skip sending flash_finish to ROM loader, as this
# exits the bootloader. Stub doesn't do this.
return
pkt = struct.pack('<I', int(not reboot))
self.check_command("leave compressed flash mode", self.ESP_FLASH_DEFL_END, pkt)
self.in_bootloader = False
@stub_and_esp32_function_only
def flash_md5sum(self, addr, size):
# the MD5 command returns additional bytes in the standard
# command reply slot
timeout = timeout_per_mb(MD5_TIMEOUT_PER_MB, size)
res = self.check_command('calculate md5sum', self.ESP_SPI_FLASH_MD5, struct.pack('<IIII', addr, size, 0, 0),
timeout=timeout)
if len(res) == 32:
return res.decode("utf-8") # already hex formatted
elif len(res) == 16:
return hexify(res).lower()
else:
raise FatalError("MD5Sum command returned unexpected result: %r" % res)
@stub_and_esp32_function_only
def change_baud(self, baud):
print("Changing baud rate to %d" % baud)
# stub takes the new baud rate and the old one
second_arg = self._port.baudrate if self.IS_STUB else 0
self.command(self.ESP_CHANGE_BAUDRATE, struct.pack('<II', baud, second_arg))
print("Changed.")
self._set_port_baudrate(baud)
time.sleep(0.05) # get rid of crap sent during baud rate change
self.flush_input()
@stub_function_only
def erase_flash(self):
# depending on flash chip model the erase may take this long (maybe longer!)
self.check_command("erase flash", self.ESP_ERASE_FLASH,
timeout=CHIP_ERASE_TIMEOUT)
@stub_function_only
def erase_region(self, offset, size):
if offset % self.FLASH_SECTOR_SIZE != 0:
raise FatalError("Offset to erase from must be a multiple of 4096")
if size % self.FLASH_SECTOR_SIZE != 0:
raise FatalError("Size of data to erase must be a multiple of 4096")
timeout = timeout_per_mb(ERASE_REGION_TIMEOUT_PER_MB, size)
self.check_command("erase region", self.ESP_ERASE_REGION, struct.pack('<II', offset, size), timeout=timeout)
@stub_function_only
def read_flash(self, offset, length, progress_fn=None):
# issue a standard bootloader command to trigger the read
self.check_command("read flash", self.ESP_READ_FLASH,
struct.pack('<IIII',
offset,
length,
self.FLASH_SECTOR_SIZE,
64))
# now we expect (length // block_size) SLIP frames with the data
data = b''
while len(data) < length:
p = self.read()
data += p
if len(data) < length and len(p) < self.FLASH_SECTOR_SIZE:
raise FatalError('Corrupt data, expected 0x%x bytes but received 0x%x bytes' % (self.FLASH_SECTOR_SIZE, len(p)))
self.write(struct.pack('<I', len(data)))
if progress_fn and (len(data) % 1024 == 0 or len(data) == length):
progress_fn(len(data), length)
if progress_fn:
progress_fn(len(data), length)
if len(data) > length:
raise FatalError('Read more than expected')
digest_frame = self.read()
if len(digest_frame) != 16:
raise FatalError('Expected digest, got: %s' % hexify(digest_frame))
expected_digest = hexify(digest_frame).upper()
digest = hashlib.md5(data).hexdigest().upper()
if digest != expected_digest:
raise FatalError('Digest mismatch: expected %s, got %s' % (expected_digest, digest))
return data
def flash_spi_attach(self, hspi_arg):
"""Send SPI attach command to enable the SPI flash pins
ESP8266 ROM does this when you send flash_begin, ESP32 ROM
has it as a SPI command.
"""
# last 3 bytes in ESP_SPI_ATTACH argument are reserved values
arg = struct.pack('<I', hspi_arg)
if not self.IS_STUB:
# ESP32 ROM loader takes additional 'is legacy' arg, which is not
# currently supported in the stub loader or esptool.py (as it's not usually needed.)
is_legacy = 0
arg += struct.pack('BBBB', is_legacy, 0, 0, 0)
self.check_command("configure SPI flash pins", ESP32ROM.ESP_SPI_ATTACH, arg)
def flash_set_parameters(self, size):
"""Tell the ESP bootloader the parameters of the chip
Corresponds to the "flashchip" data structure that the ROM
has in RAM.
'size' is in bytes.
All other flash parameters are currently hardcoded (on ESP8266
these are mostly ignored by ROM code, on ESP32 I'm not sure.)
"""
fl_id = 0
total_size = size
block_size = 64 * 1024
sector_size = 4 * 1024
page_size = 256
status_mask = 0xffff
self.check_command("set SPI params", ESP32ROM.ESP_SPI_SET_PARAMS,
struct.pack('<IIIIII', fl_id, total_size, block_size, sector_size, page_size, status_mask))
def run_spiflash_command(self, spiflash_command, data=b"", read_bits=0):
"""Run an arbitrary SPI flash command.
This function uses the "USR_COMMAND" functionality in the ESP
SPI hardware, rather than the precanned commands supported by
hardware. So the value of spiflash_command is an actual command
byte, sent over the wire.
After writing command byte, writes 'data' to MOSI and then
reads back 'read_bits' of reply on MISO. Result is a number.
"""
# SPI_USR register flags
SPI_USR_COMMAND = (1 << 31)
SPI_USR_MISO = (1 << 28)
SPI_USR_MOSI = (1 << 27)
# SPI registers, base address differs ESP32 vs 8266
base = self.SPI_REG_BASE
SPI_CMD_REG = base + 0x00
SPI_USR_REG = base + 0x1C
SPI_USR1_REG = base + 0x20
SPI_USR2_REG = base + 0x24
SPI_W0_REG = base + self.SPI_W0_OFFS
# following two registers are ESP32 only
if self.SPI_HAS_MOSI_DLEN_REG:
# ESP32 has a more sophisticated wayto set up "user" commands
def set_data_lengths(mosi_bits, miso_bits):
SPI_MOSI_DLEN_REG = base + 0x28
SPI_MISO_DLEN_REG = base + 0x2C
if mosi_bits > 0:
self.write_reg(SPI_MOSI_DLEN_REG, mosi_bits - 1)
if miso_bits > 0:
self.write_reg(SPI_MISO_DLEN_REG, miso_bits - 1)
else:
def set_data_lengths(mosi_bits, miso_bits):
SPI_DATA_LEN_REG = SPI_USR1_REG
SPI_MOSI_BITLEN_S = 17
SPI_MISO_BITLEN_S = 8
mosi_mask = 0 if (mosi_bits == 0) else (mosi_bits - 1)
miso_mask = 0 if (miso_bits == 0) else (miso_bits - 1)
self.write_reg(SPI_DATA_LEN_REG,
(miso_mask << SPI_MISO_BITLEN_S) | (
mosi_mask << SPI_MOSI_BITLEN_S))
# SPI peripheral "command" bitmasks for SPI_CMD_REG
SPI_CMD_USR = (1 << 18)
# shift values
SPI_USR2_DLEN_SHIFT = 28
if read_bits > 32:
raise FatalError("Reading more than 32 bits back from a SPI flash operation is unsupported")
if len(data) > 64:
raise FatalError("Writing more than 64 bytes of data with one SPI command is unsupported")
data_bits = len(data) * 8
old_spi_usr = self.read_reg(SPI_USR_REG)
old_spi_usr2 = self.read_reg(SPI_USR2_REG)
flags = SPI_USR_COMMAND
if read_bits > 0:
flags |= SPI_USR_MISO
if data_bits > 0:
flags |= SPI_USR_MOSI
set_data_lengths(data_bits, read_bits)
self.write_reg(SPI_USR_REG, flags)
self.write_reg(SPI_USR2_REG,
(7 << SPI_USR2_DLEN_SHIFT) | spiflash_command)
if data_bits == 0:
self.write_reg(SPI_W0_REG, 0) # clear data register before we read it
else:
data = pad_to(data, 4, b'\00') # pad to 32-bit multiple
words = struct.unpack("I" * (len(data) // 4), data)
next_reg = SPI_W0_REG
for word in words:
self.write_reg(next_reg, word)
next_reg += 4
self.write_reg(SPI_CMD_REG, SPI_CMD_USR)
def wait_done():
for _ in range(10):
if (self.read_reg(SPI_CMD_REG) & SPI_CMD_USR) == 0:
return
raise FatalError("SPI command did not complete in time")
wait_done()
status = self.read_reg(SPI_W0_REG)
# restore some SPI controller registers
self.write_reg(SPI_USR_REG, old_spi_usr)
self.write_reg(SPI_USR2_REG, old_spi_usr2)
return status
def read_status(self, num_bytes=2):
"""Read up to 24 bits (num_bytes) of SPI flash status register contents
via RDSR, RDSR2, RDSR3 commands
Not all SPI flash supports all three commands. The upper 1 or 2
bytes may be 0xFF.
"""
SPIFLASH_RDSR = 0x05
SPIFLASH_RDSR2 = 0x35
SPIFLASH_RDSR3 = 0x15
status = 0
shift = 0
for cmd in [SPIFLASH_RDSR, SPIFLASH_RDSR2, SPIFLASH_RDSR3][0:num_bytes]:
status += self.run_spiflash_command(cmd, read_bits=8) << shift
shift += 8
return status
def write_status(self, new_status, num_bytes=2, set_non_volatile=False):
"""Write up to 24 bits (num_bytes) of new status register
num_bytes can be 1, 2 or 3.
Not all flash supports the additional commands to write the
second and third byte of the status register. When writing 2
bytes, esptool also sends a 16-byte WRSR command (as some
flash types use this instead of WRSR2.)
If the set_non_volatile flag is set, non-volatile bits will
be set as well as volatile ones (WREN used instead of WEVSR).
"""
SPIFLASH_WRSR = 0x01
SPIFLASH_WRSR2 = 0x31
SPIFLASH_WRSR3 = 0x11
SPIFLASH_WEVSR = 0x50
SPIFLASH_WREN = 0x06
SPIFLASH_WRDI = 0x04
enable_cmd = SPIFLASH_WREN if set_non_volatile else SPIFLASH_WEVSR
# try using a 16-bit WRSR (not supported by all chips)
# this may be redundant, but shouldn't hurt
if num_bytes == 2:
self.run_spiflash_command(enable_cmd)
self.run_spiflash_command(SPIFLASH_WRSR, struct.pack("<H", new_status))
# also try using individual commands (also not supported by all chips for num_bytes 2 & 3)
for cmd in [SPIFLASH_WRSR, SPIFLASH_WRSR2, SPIFLASH_WRSR3][0:num_bytes]:
self.run_spiflash_command(enable_cmd)
self.run_spiflash_command(cmd, struct.pack("B", new_status & 0xFF))
new_status >>= 8
self.run_spiflash_command(SPIFLASH_WRDI)
def hard_reset(self):
self._setRTS(True) # EN->LOW
time.sleep(0.1)
self._setRTS(False)
def soft_reset(self, stay_in_bootloader):
if not self.IS_STUB:
if stay_in_bootloader:
return # ROM bootloader is already in bootloader!
else:
# 'run user code' is as close to a soft reset as we can do
self.flash_begin(0, 0)
self.flash_finish(False)
else:
if stay_in_bootloader:
# soft resetting from the stub loader
# will re-load the ROM bootloader
self.flash_begin(0, 0)
self.flash_finish(True)
elif self.CHIP_NAME != "ESP8266":
raise FatalError("Soft resetting is currently only supported on ESP8266")
else:
# running user code from stub loader requires some hacks
# in the stub loader
self.command(self.ESP_RUN_USER_CODE, wait_response=False)
class ESP8266ROM(ESPLoader):
""" Access class for ESP8266 ROM bootloader
"""
CHIP_NAME = "ESP8266"
IS_STUB = False
DATE_REG_VALUE = 0x00062000
# OTP ROM addresses
ESP_OTP_MAC0 = 0x3ff00050
ESP_OTP_MAC1 = 0x3ff00054
ESP_OTP_MAC3 = 0x3ff0005c
SPI_REG_BASE = 0x60000200
SPI_W0_OFFS = 0x40
SPI_HAS_MOSI_DLEN_REG = False
FLASH_SIZES = {
'512KB':0x00,
'256KB':0x10,
'1MB':0x20,
'2MB':0x30,
'4MB':0x40,
'2MB-c1': 0x50,
'4MB-c1':0x60,
'8MB':0x80,
'16MB':0x90,
}
BOOTLOADER_FLASH_OFFSET = 0
def get_efuses(self):
# Return the 128 bits of ESP8266 efuse as a single Python integer
return (self.read_reg(0x3ff0005c) << 96 |
self.read_reg(0x3ff00058) << 64 |
self.read_reg(0x3ff00054) << 32 |
self.read_reg(0x3ff00050))
def get_chip_description(self):
efuses = self.get_efuses()
is_8285 = (efuses & ((1 << 4) | 1 << 80)) != 0 # One or the other efuse bit is set for ESP8285
return "ESP8285" if is_8285 else "ESP8266EX"
def get_chip_features(self):
features = ["WiFi"]
if self.get_chip_description() == "ESP8285":
features += ["Embedded Flash"]
return features
def flash_spi_attach(self, hspi_arg):
if self.IS_STUB:
super(ESP8266ROM, self).flash_spi_attach(hspi_arg)
else:
# ESP8266 ROM has no flash_spi_attach command in serial protocol,
# but flash_begin will do it
self.flash_begin(0, 0)
def flash_set_parameters(self, size):
# not implemented in ROM, but OK to silently skip for ROM
if self.IS_STUB: