#!/usr/bin/env python # # SPDX-FileCopyrightText: 2014-2022 Fredrik Ahlberg, Angus Gratton, Espressif Systems (Shanghai) CO LTD, other contributors as noted. # # SPDX-License-Identifier: GPL-2.0-or-later from __future__ import division, print_function import argparse import base64 import binascii import copy import hashlib import inspect import io import itertools import os import re import shlex import string import struct import sys import time import zlib 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 except Exception: if sys.platform == "darwin": # swallow the exception, this is a known issue in pyserial+macOS Big Sur preview ref https://github.com/espressif/esptool/issues/540 list_ports = None else: raise __version__ = "3.3.2" 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 ERASE_WRITE_TIMEOUT_PER_MB = 40 # timeout (per megabyte) for erasing and writing data 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 DEFAULT_CONNECT_ATTEMPTS = 7 # default number of times to try connection WRITE_BLOCK_ATTEMPTS = 3 # number of times to try writing a data block SUPPORTED_CHIPS = ['esp8266', 'esp32', 'esp32s2', 'esp32s3beta2', 'esp32s3', 'esp32c3', 'esp32c6beta', 'esp32h2beta1', 'esp32h2beta2', 'esp32c2'] 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 def _chip_to_rom_loader(chip): return { 'esp8266': ESP8266ROM, 'esp32': ESP32ROM, 'esp32s2': ESP32S2ROM, 'esp32s3beta2': ESP32S3BETA2ROM, 'esp32s3': ESP32S3ROM, 'esp32c3': ESP32C3ROM, 'esp32c6beta': ESP32C6BETAROM, 'esp32h2beta1': ESP32H2BETA1ROM, 'esp32h2beta2': ESP32H2BETA2ROM, 'esp32c2': ESP32C2ROM, }[chip] def get_default_connected_device(serial_list, port, connect_attempts, initial_baud, chip='auto', trace=False, before='default_reset'): _esp = None for each_port in reversed(serial_list): print("Serial port %s" % each_port) try: if chip == 'auto': _esp = ESPLoader.detect_chip(each_port, initial_baud, before, trace, connect_attempts) else: chip_class = _chip_to_rom_loader(chip) _esp = chip_class(each_port, initial_baud, trace) _esp.connect(before, connect_attempts) break except (FatalError, OSError) as err: if port is not None: raise print("%s failed to connect: %s" % (each_port, err)) if _esp and _esp._port: _esp._port.close() _esp = None return _esp DETECTED_FLASH_SIZES = { 0x12: "256KB", 0x13: "512KB", 0x14: "1MB", 0x15: "2MB", 0x16: "4MB", 0x17: "8MB", 0x18: "16MB", 0x19: "32MB", 0x1A: "64MB", 0x1B: "128MB", 0x1C: "256MB", 0x20: "64MB", 0x21: "128MB", 0x22: "256MB", 0x32: "256KB", 0x33: "512KB", 0x34: "1MB", 0x35: "2MB", 0x36: "4MB", 0x37: "8MB", 0x38: "16MB", 0x39: "32MB", 0x3A: "64MB", } 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 (and later chips) ROM loaders, and the software stub that runs on these. 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 esp8266_function_only(func): """ Attribute for a function only supported on ESP8266 """ return check_supported_function(func, lambda o: o.CHIP_NAME == "ESP8266") 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 and later chips ROM """ return check_supported_function(func, lambda o: o.IS_STUB or isinstance(o, ESP32ROM)) def esp32s3_or_newer_function_only(func): """ Attribute for a function only supported by ESP32S3 and later chips ROM """ return check_supported_function(func, lambda o: isinstance(o, ESP32S3ROM) or isinstance(o, ESP32C3ROM)) 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 print_overwrite(message, last_line=False): """ Print a message, overwriting the currently printed line. If last_line is False, don't append a newline at the end (expecting another subsequent call will overwrite this one.) After a sequence of calls with last_line=False, call once with last_line=True. If output is not a TTY (for example redirected a pipe), no overwriting happens and this function is the same as print(). """ if sys.stdout.isatty(): print("\r%s" % message, end='\n' if last_line else '') else: print(message) def _mask_to_shift(mask): """ Return the index of the least significant bit in the mask """ shift = 0 while mask & 0x1 == 0: shift += 1 mask >>= 1 return shift class ESPLoader(object): """ Base class providing access to ESP ROM & software stub bootloaders. Subclasses provide ESP8266 & ESP32 Family 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 FPGA_SLOW_BOOT = False DEFAULT_PORT = "/dev/ttyUSB0" USES_RFC2217 = False # 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 and later chips ROM bootloader (or -8266 w/ stub) ESP_SPI_SET_PARAMS = 0x0B ESP_SPI_ATTACH = 0x0D ESP_READ_FLASH_SLOW = 0x0e # ROM only, much slower than the stub flash read ESP_CHANGE_BAUDRATE = 0x0F ESP_FLASH_DEFL_BEGIN = 0x10 ESP_FLASH_DEFL_DATA = 0x11 ESP_FLASH_DEFL_END = 0x12 ESP_SPI_FLASH_MD5 = 0x13 # Commands supported by ESP32-S2 and later chips ROM bootloader only ESP_GET_SECURITY_INFO = 0x14 # 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 encrypted data command ESP_FLASH_ENCRYPT_DATA = 0xD4 # Response code(s) sent by ROM ROM_INVALID_RECV_MSG = 0x05 # response if an invalid message is received # 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_DATE_REG_ADDR = 0x60000078 CHIP_DETECT_MAGIC_REG_ADDR = 0x40001000 # This ROM address has a different value on each chip model UART_CLKDIV_MASK = 0xFFFFF # 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 # Response to ESP_SYNC might indicate that flasher stub is running instead of the ROM bootloader sync_stub_detected = False # Device PIDs USB_JTAG_SERIAL_PID = 0x1001 # Chip IDs that are no longer supported by esptool UNSUPPORTED_CHIPS = {6: "ESP32-S3(beta 3)"} 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(). """ self.secure_download_mode = False # flag is set to True if esptool detects the ROM is in Secure Download Mode self.stub_is_disabled = False # flag is set to True if esptool detects conditions which require the stub to be disabled 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 @property def serial_port(self): return self._port.port 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, connect_attempts=DEFAULT_CONNECT_ATTEMPTS): """ Use serial access to detect the chip type. First, get_security_info command is sent to detect the ID of the chip (supported only by ESP32-C3 and later, works even in the Secure Download Mode). If this fails, we reconnect and fall-back to reading the magic number. It's mapped at a specific ROM address and has a different value on each chip model. This way we can use one memory read and compare it to the magic number for each chip type. This routine automatically performs ESPLoader.connect() (passing connect_mode parameter) as part of querying the chip. """ inst = None detect_port = ESPLoader(port, baud, trace_enabled=trace_enabled) if detect_port.serial_port.startswith("rfc2217:"): detect_port.USES_RFC2217 = True detect_port.connect(connect_mode, connect_attempts, detecting=True) try: print('Detecting chip type...', end='') res = detect_port.check_command('get security info', ESPLoader.ESP_GET_SECURITY_INFO, b'') res = struct.unpack(" 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): val, _ = self.command(self.ESP_SYNC, b'\x07\x07\x12\x20' + 32 * b'\x55', timeout=SYNC_TIMEOUT) # ROM bootloaders send some non-zero "val" response. The flasher stub sends 0. If we receive 0 then it # probably indicates that the chip wasn't or couldn't be reseted properly and esptool is talking to the # flasher stub. self.sync_stub_detected = val == 0 for _ in range(7): val, _ = self.command() self.sync_stub_detected &= val == 0 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 _get_pid(self): if list_ports is None: print("\nListing all serial ports is currently not available. Can't get device PID.") return active_port = self._port.port # Pyserial only identifies regular ports, URL handlers are not supported if not active_port.lower().startswith(("com", "/dev/")): print("\nDevice PID identification is only supported on COM and /dev/ serial ports.") return # Return the real path if the active port is a symlink if active_port.startswith("/dev/") and os.path.islink(active_port): active_port = os.path.realpath(active_port) # The "cu" (call-up) device has to be used for outgoing communication on MacOS if sys.platform == "darwin" and "tty" in active_port: active_port = [active_port, active_port.replace("tty", "cu")] ports = list_ports.comports() for p in ports: if p.device in active_port: return p.pid print("\nFailed to get PID of a device on {}, using standard reset sequence.".format(active_port)) def bootloader_reset(self, usb_jtag_serial=False, extra_delay=False): """ Issue a reset-to-bootloader, with USB-JTAG-Serial custom reset sequence option """ # 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 usb_jtag_serial: # Custom reset sequence, which is required when the device # is connecting via its USB-JTAG-Serial peripheral self._setRTS(False) self._setDTR(False) # Idle time.sleep(0.1) self._setDTR(True) # Set IO0 self._setRTS(False) time.sleep(0.1) self._setRTS(True) # Reset. Note dtr/rts calls inverted so we go through (1,1) instead of (0,0) self._setDTR(False) self._setRTS(True) # Extra RTS set for RTS as Windows only propagates DTR on RTS setting time.sleep(0.1) self._setDTR(False) self._setRTS(False) else: # This fpga delay is for Espressif internal use fpga_delay = True if self.FPGA_SLOW_BOOT and os.environ.get("ESPTOOL_ENV_FPGA", "").strip() == "1" else False delay = 7 if fpga_delay else 0.5 if extra_delay else 0.05 # 0.5 needed for ESP32 rev0 and rev1 self._setDTR(False) # IO0=HIGH self._setRTS(True) # EN=LOW, chip in reset time.sleep(0.1) self._setDTR(True) # IO0=LOW self._setRTS(False) # EN=HIGH, chip out of reset time.sleep(delay) self._setDTR(False) # IO0=HIGH, done def _connect_attempt(self, mode='default_reset', usb_jtag_serial=False, extra_delay=False): """ A single connection attempt """ last_error = None boot_log_detected = False download_mode = False # 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 if mode != 'no_reset': if not self.USES_RFC2217: # Might block on rfc2217 ports self._port.reset_input_buffer() # Empty serial buffer to isolate boot log self.bootloader_reset(usb_jtag_serial, extra_delay) # Detect the ROM boot log and check actual boot mode (ESP32 and later only) waiting = self._port.inWaiting() read_bytes = self._port.read(waiting) data = re.search(b'boot:(0x[0-9a-fA-F]+)(.*waiting for download)?', read_bytes, re.DOTALL) if data is not None: boot_log_detected = True boot_mode = data.group(1) download_mode = data.group(2) is not None for _ in range(5): try: self.flush_input() self._port.flushOutput() self.sync() return None except FatalError as e: print('.', end='') sys.stdout.flush() time.sleep(0.05) last_error = e if boot_log_detected: last_error = FatalError("Wrong boot mode detected ({})! The chip needs to be in download mode.".format(boot_mode.decode("utf-8"))) if download_mode: last_error = FatalError("Download mode successfully detected, but getting no sync reply: The serial TX path seems to be down.") return last_error def get_memory_region(self, name): """ Returns a tuple of (start, end) for the memory map entry with the given name, or None if it doesn't exist """ try: return [(start, end) for (start, end, n) in self.MEMORY_MAP if n == name][0] except IndexError: return None def connect(self, mode='default_reset', attempts=DEFAULT_CONNECT_ATTEMPTS, detecting=False, warnings=True): """ Try connecting repeatedly until successful, or giving up """ if warnings and mode in ['no_reset', 'no_reset_no_sync']: print('WARNING: Pre-connection option "{}" was selected.'.format(mode), 'Connection may fail if the chip is not in bootloader or flasher stub mode.') print('Connecting...', end='') sys.stdout.flush() last_error = None usb_jtag_serial = (mode == 'usb_reset') or (self._get_pid() == self.USB_JTAG_SERIAL_PID) try: for _, extra_delay in zip(range(attempts) if attempts > 0 else itertools.count(), itertools.cycle((False, True))): last_error = self._connect_attempt(mode=mode, usb_jtag_serial=usb_jtag_serial, extra_delay=extra_delay) if last_error is None: break finally: print('') # end 'Connecting...' line if last_error is not None: raise FatalError('Failed to connect to {}: {}' '\nFor troubleshooting steps visit: ' 'https://docs.espressif.com/projects/esptool/en/latest/troubleshooting.html'.format(self.CHIP_NAME, last_error)) if not detecting: try: # check the date code registers match what we expect to see chip_magic_value = self.read_reg(ESPLoader.CHIP_DETECT_MAGIC_REG_ADDR) if chip_magic_value not in self.CHIP_DETECT_MAGIC_VALUE: actually = None for cls in [ESP8266ROM, ESP32ROM, ESP32S2ROM, ESP32S3BETA2ROM, ESP32S3ROM, ESP32C3ROM, ESP32H2BETA1ROM, ESP32H2BETA2ROM, ESP32C2ROM, ESP32C6BETAROM]: if chip_magic_value in cls.CHIP_DETECT_MAGIC_VALUE: actually = cls break if warnings and actually is None: print(("WARNING: This chip doesn't appear to be a %s (chip magic value 0x%08x). " "Probably it is unsupported by this version of esptool.") % (self.CHIP_NAME, chip_magic_value)) else: raise FatalError("This chip is %s not %s. Wrong --chip argument?" % (actually.CHIP_NAME, self.CHIP_NAME)) except UnsupportedCommandError: self.secure_download_mode = True self._post_connect() self.check_chip_id() def _post_connect(self): """ Additional initialization hook, may be overridden by the chip-specific class. Gets called after connect, and after auto-detection. """ pass def read_reg(self, addr, timeout=DEFAULT_TIMEOUT): """ Read memory address in target """ # 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(' 0: # add a dummy write to a date register as an excuse to have a delay command += struct.pack(' 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(' 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(' 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) flags = 0 if dummy_len > 0: flags |= (dummy_len - 1) if addr_len > 0: flags |= (addr_len - 1) << SPI_USR_ADDR_LEN_SHIFT if flags: self.write_reg(SPI_USR1_REG, flags) 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) flags = (miso_mask << SPI_MISO_BITLEN_S) | (mosi_mask << SPI_MOSI_BITLEN_S) if dummy_len > 0: flags |= (dummy_len - 1) if addr_len > 0: flags |= (addr_len - 1) << SPI_USR_ADDR_LEN_SHIFT self.write_reg(SPI_DATA_LEN_REG, flags) # SPI peripheral "command" bitmasks for SPI_CMD_REG SPI_CMD_USR = (1 << 18) # shift values SPI_USR2_COMMAND_LEN_SHIFT = 28 SPI_USR_ADDR_LEN_SHIFT = 26 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 if addr_len > 0: flags |= SPI_USR_ADDR if dummy_len > 0: flags |= SPI_USR_DUMMY set_data_lengths(data_bits, read_bits) self.write_reg(SPI_USR_REG, flags) self.write_reg(SPI_USR2_REG, (7 << SPI_USR2_COMMAND_LEN_SHIFT) | spiflash_command) if addr and addr_len > 0: self.write_reg(SPI_ADDR_REG, addr) 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_spiflash_sfdp(self, addr, read_bits): CMD_RDSFDP = 0x5A return self.run_spiflash_command(CMD_RDSFDP, read_bits=read_bits, addr=addr, addr_len=24, dummy_len=8) 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(">= 8 self.run_spiflash_command(SPIFLASH_WRDI) def get_crystal_freq(self): # Figure out the crystal frequency from the UART clock divider # Returns a normalized value in integer MHz (40 or 26 are the only supported values) # # The logic here is: # - We know that our baud rate and the ESP UART baud rate are roughly the same, or we couldn't communicate # - We can read the UART clock divider register to know how the ESP derives this from the APB bus frequency # - Multiplying these two together gives us the bus frequency which is either the crystal frequency (ESP32) # or double the crystal frequency (ESP8266). See the self.XTAL_CLK_DIVIDER parameter for this factor. uart_div = self.read_reg(self.UART_CLKDIV_REG) & self.UART_CLKDIV_MASK est_xtal = (self._port.baudrate * uart_div) / 1e6 / self.XTAL_CLK_DIVIDER norm_xtal = 40 if est_xtal > 33 else 26 if abs(norm_xtal - est_xtal) > 1: print("WARNING: Detected crystal freq %.2fMHz is quite different to normalized freq %dMHz. Unsupported crystal in use?" % (est_xtal, norm_xtal)) return norm_xtal def hard_reset(self): print('Hard resetting via RTS pin...') 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) def check_chip_id(self): try: chip_id = self.get_chip_id() if chip_id != self.IMAGE_CHIP_ID: print("WARNING: Chip ID {} ({}) doesn't match expected Chip ID {}. esptool may not work correctly." .format(chip_id, self.UNSUPPORTED_CHIPS.get(chip_id, 'Unknown'), self.IMAGE_CHIP_ID)) # Try to flash anyways by disabling stub self.stub_is_disabled = True except NotImplementedInROMError: pass class ESP8266ROM(ESPLoader): """ Access class for ESP8266 ROM bootloader """ CHIP_NAME = "ESP8266" IS_STUB = False CHIP_DETECT_MAGIC_VALUE = [0xfff0c101] # OTP ROM addresses ESP_OTP_MAC0 = 0x3ff00050 ESP_OTP_MAC1 = 0x3ff00054 ESP_OTP_MAC3 = 0x3ff0005c SPI_REG_BASE = 0x60000200 SPI_USR_OFFS = 0x1c SPI_USR1_OFFS = 0x20 SPI_USR2_OFFS = 0x24 SPI_MOSI_DLEN_OFFS = None SPI_MISO_DLEN_OFFS = None SPI_W0_OFFS = 0x40 UART_CLKDIV_REG = 0x60000014 XTAL_CLK_DIVIDER = 2 FLASH_SIZES = { '512KB': 0x00, '256KB': 0x10, '1MB': 0x20, '2MB': 0x30, '4MB': 0x40, '2MB-c1': 0x50, '4MB-c1': 0x60, '8MB': 0x80, '16MB': 0x90, } FLASH_FREQUENCY = { '80m': 0xf, '40m': 0x0, '26m': 0x1, '20m': 0x2, } BOOTLOADER_FLASH_OFFSET = 0 MEMORY_MAP = [[0x3FF00000, 0x3FF00010, "DPORT"], [0x3FFE8000, 0x40000000, "DRAM"], [0x40100000, 0x40108000, "IRAM"], [0x40201010, 0x402E1010, "IROM"]] def get_efuses(self): # Return the 128 bits of ESP8266 efuse as a single Python integer result = self.read_reg(0x3ff0005c) << 96 result |= self.read_reg(0x3ff00058) << 64 result |= self.read_reg(0x3ff00054) << 32 result |= self.read_reg(0x3ff00050) return result def _get_flash_size(self, efuses): # rX_Y = EFUSE_DATA_OUTX[Y] r0_4 = (efuses & (1 << 4)) != 0 r3_25 = (efuses & (1 << 121)) != 0 r3_26 = (efuses & (1 << 122)) != 0 r3_27 = (efuses & (1 << 123)) != 0 if r0_4 and not r3_25: if not r3_27 and not r3_26: return 1 elif not r3_27 and r3_26: return 2 if not r0_4 and r3_25: if not r3_27 and not r3_26: return 2 elif not r3_27 and r3_26: return 4 return -1 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 if is_8285: flash_size = self._get_flash_size(efuses) max_temp = (efuses & (1 << 5)) != 0 # This efuse bit identifies the max flash temperature chip_name = { 1: "ESP8285H08" if max_temp else "ESP8285N08", 2: "ESP8285H16" if max_temp else "ESP8285N16" }.get(flash_size, "ESP8285") return chip_name return "ESP8266EX" def get_chip_features(self): features = ["WiFi"] if "ESP8285" in self.get_chip_description(): 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: super(ESP8266ROM, self).flash_set_parameters(size) def chip_id(self): """ Read Chip ID from efuse - the equivalent of the SDK system_get_chip_id() function """ id0 = self.read_reg(self.ESP_OTP_MAC0) id1 = self.read_reg(self.ESP_OTP_MAC1) return (id0 >> 24) | ((id1 & MAX_UINT24) << 8) def read_mac(self): """ Read MAC from OTP ROM """ mac0 = self.read_reg(self.ESP_OTP_MAC0) mac1 = self.read_reg(self.ESP_OTP_MAC1) mac3 = self.read_reg(self.ESP_OTP_MAC3) if (mac3 != 0): oui = ((mac3 >> 16) & 0xff, (mac3 >> 8) & 0xff, mac3 & 0xff) elif ((mac1 >> 16) & 0xff) == 0: oui = (0x18, 0xfe, 0x34) elif ((mac1 >> 16) & 0xff) == 1: oui = (0xac, 0xd0, 0x74) else: raise FatalError("Unknown OUI") return oui + ((mac1 >> 8) & 0xff, mac1 & 0xff, (mac0 >> 24) & 0xff) def get_erase_size(self, offset, size): """ Calculate an erase size given a specific size in bytes. Provides a workaround for the bootloader erase bug.""" sectors_per_block = 16 sector_size = self.FLASH_SECTOR_SIZE num_sectors = (size + sector_size - 1) // sector_size start_sector = offset // sector_size head_sectors = sectors_per_block - (start_sector % sectors_per_block) if num_sectors < head_sectors: head_sectors = num_sectors if num_sectors < 2 * head_sectors: return (num_sectors + 1) // 2 * sector_size else: return (num_sectors - head_sectors) * sector_size def override_vddsdio(self, new_voltage): raise NotImplementedInROMError("Overriding VDDSDIO setting only applies to ESP32") class ESP8266StubLoader(ESP8266ROM): """ Access class for ESP8266 stub loader, runs on top of ROM. """ FLASH_WRITE_SIZE = 0x4000 # matches MAX_WRITE_BLOCK in stub_loader.c IS_STUB = True def __init__(self, rom_loader): self.secure_download_mode = rom_loader.secure_download_mode self._port = rom_loader._port self._trace_enabled = rom_loader._trace_enabled self.flush_input() # resets _slip_reader def get_erase_size(self, offset, size): return size # stub doesn't have same size bug as ROM loader ESP8266ROM.STUB_CLASS = ESP8266StubLoader class ESP32ROM(ESPLoader): """Access class for ESP32 ROM bootloader """ CHIP_NAME = "ESP32" IMAGE_CHIP_ID = 0 IS_STUB = False FPGA_SLOW_BOOT = True CHIP_DETECT_MAGIC_VALUE = [0x00f01d83] IROM_MAP_START = 0x400d0000 IROM_MAP_END = 0x40400000 DROM_MAP_START = 0x3F400000 DROM_MAP_END = 0x3F800000 # ESP32 uses a 4 byte status reply STATUS_BYTES_LENGTH = 4 SPI_REG_BASE = 0x3ff42000 SPI_USR_OFFS = 0x1c SPI_USR1_OFFS = 0x20 SPI_USR2_OFFS = 0x24 SPI_MOSI_DLEN_OFFS = 0x28 SPI_MISO_DLEN_OFFS = 0x2c EFUSE_RD_REG_BASE = 0x3ff5a000 EFUSE_DIS_DOWNLOAD_MANUAL_ENCRYPT_REG = EFUSE_RD_REG_BASE + 0x18 EFUSE_DIS_DOWNLOAD_MANUAL_ENCRYPT = (1 << 7) # EFUSE_RD_DISABLE_DL_ENCRYPT DR_REG_SYSCON_BASE = 0x3ff66000 SPI_W0_OFFS = 0x80 UART_CLKDIV_REG = 0x3ff40014 XTAL_CLK_DIVIDER = 1 FLASH_SIZES = { '1MB': 0x00, '2MB': 0x10, '4MB': 0x20, '8MB': 0x30, '16MB': 0x40, '32MB': 0x50, '64MB': 0x60, '128MB': 0x70 } FLASH_FREQUENCY = { '80m': 0xf, '40m': 0x0, '26m': 0x1, '20m': 0x2, } BOOTLOADER_FLASH_OFFSET = 0x1000 OVERRIDE_VDDSDIO_CHOICES = ["1.8V", "1.9V", "OFF"] MEMORY_MAP = [[0x00000000, 0x00010000, "PADDING"], [0x3F400000, 0x3F800000, "DROM"], [0x3F800000, 0x3FC00000, "EXTRAM_DATA"], [0x3FF80000, 0x3FF82000, "RTC_DRAM"], [0x3FF90000, 0x40000000, "BYTE_ACCESSIBLE"], [0x3FFAE000, 0x40000000, "DRAM"], [0x3FFE0000, 0x3FFFFFFC, "DIRAM_DRAM"], [0x40000000, 0x40070000, "IROM"], [0x40070000, 0x40078000, "CACHE_PRO"], [0x40078000, 0x40080000, "CACHE_APP"], [0x40080000, 0x400A0000, "IRAM"], [0x400A0000, 0x400BFFFC, "DIRAM_IRAM"], [0x400C0000, 0x400C2000, "RTC_IRAM"], [0x400D0000, 0x40400000, "IROM"], [0x50000000, 0x50002000, "RTC_DATA"]] FLASH_ENCRYPTED_WRITE_ALIGN = 32 """ Try to read the BLOCK1 (encryption key) and check if it is valid """ def is_flash_encryption_key_valid(self): """ Bit 0 of efuse_rd_disable[3:0] is mapped to BLOCK1 this bit is at position 16 in EFUSE_BLK0_RDATA0_REG """ word0 = self.read_efuse(0) rd_disable = (word0 >> 16) & 0x1 # reading of BLOCK1 is NOT ALLOWED so we assume valid key is programmed if rd_disable: return True else: # reading of BLOCK1 is ALLOWED so we will read and verify for non-zero. # When ESP32 has not generated AES/encryption key in BLOCK1, the contents will be readable and 0. # If the flash encryption is enabled it is expected to have a valid non-zero key. We break out on # first occurance of non-zero value key_word = [0] * 7 for i in range(len(key_word)): key_word[i] = self.read_efuse(14 + i) # key is non-zero so break & return if key_word[i] != 0: return True return False def get_flash_crypt_config(self): """ For flash encryption related commands we need to make sure user has programmed all the relevant efuse correctly so before writing encrypted write_flash_encrypt esptool will verify the values of flash_crypt_config to be non zero if they are not read protected. If the values are zero a warning will be printed bit 3 in efuse_rd_disable[3:0] is mapped to flash_crypt_config this bit is at position 19 in EFUSE_BLK0_RDATA0_REG """ word0 = self.read_efuse(0) rd_disable = (word0 >> 19) & 0x1 if rd_disable == 0: """ we can read the flash_crypt_config efuse value so go & read it (EFUSE_BLK0_RDATA5_REG[31:28]) """ word5 = self.read_efuse(5) word5 = (word5 >> 28) & 0xF return word5 else: # if read of the efuse is disabled we assume it is set correctly return 0xF def get_encrypted_download_disabled(self): if self.read_reg(self.EFUSE_DIS_DOWNLOAD_MANUAL_ENCRYPT_REG) & self.EFUSE_DIS_DOWNLOAD_MANUAL_ENCRYPT: return True else: return False def get_pkg_version(self): word3 = self.read_efuse(3) pkg_version = (word3 >> 9) & 0x07 pkg_version += ((word3 >> 2) & 0x1) << 3 return pkg_version def get_chip_revision(self): word3 = self.read_efuse(3) word5 = self.read_efuse(5) apb_ctl_date = self.read_reg(self.DR_REG_SYSCON_BASE + 0x7C) rev_bit0 = (word3 >> 15) & 0x1 rev_bit1 = (word5 >> 20) & 0x1 rev_bit2 = (apb_ctl_date >> 31) & 0x1 if rev_bit0: if rev_bit1: if rev_bit2: return 3 else: return 2 else: return 1 return 0 def get_chip_description(self): pkg_version = self.get_pkg_version() chip_revision = self.get_chip_revision() rev3 = (chip_revision == 3) single_core = self.read_efuse(3) & (1 << 0) # CHIP_VER DIS_APP_CPU chip_name = { 0: "ESP32-S0WDQ6" if single_core else "ESP32-D0WDQ6", 1: "ESP32-S0WD" if single_core else "ESP32-D0WD", 2: "ESP32-D2WD", 4: "ESP32-U4WDH", 5: "ESP32-PICO-V3" if rev3 else "ESP32-PICO-D4", 6: "ESP32-PICO-V3-02", 7: "ESP32-D0WDR2-V3", }.get(pkg_version, "unknown ESP32") # ESP32-D0WD-V3, ESP32-D0WDQ6-V3 if chip_name.startswith("ESP32-D0WD") and rev3: chip_name += "-V3" return "%s (revision %d)" % (chip_name, chip_revision) def get_chip_features(self): features = ["WiFi"] word3 = self.read_efuse(3) # names of variables in this section are lowercase # versions of EFUSE names as documented in TRM and # ESP-IDF efuse_reg.h chip_ver_dis_bt = word3 & (1 << 1) if chip_ver_dis_bt == 0: features += ["BT"] chip_ver_dis_app_cpu = word3 & (1 << 0) if chip_ver_dis_app_cpu: features += ["Single Core"] else: features += ["Dual Core"] chip_cpu_freq_rated = word3 & (1 << 13) if chip_cpu_freq_rated: chip_cpu_freq_low = word3 & (1 << 12) if chip_cpu_freq_low: features += ["160MHz"] else: features += ["240MHz"] pkg_version = self.get_pkg_version() if pkg_version in [2, 4, 5, 6]: features += ["Embedded Flash"] if pkg_version == 6: features += ["Embedded PSRAM"] word4 = self.read_efuse(4) adc_vref = (word4 >> 8) & 0x1F if adc_vref: features += ["VRef calibration in efuse"] blk3_part_res = word3 >> 14 & 0x1 if blk3_part_res: features += ["BLK3 partially reserved"] word6 = self.read_efuse(6) coding_scheme = word6 & 0x3 features += ["Coding Scheme %s" % { 0: "None", 1: "3/4", 2: "Repeat (UNSUPPORTED)", 3: "Invalid"}[coding_scheme]] return features def read_efuse(self, n): """ Read the nth word of the ESP3x EFUSE region. """ return self.read_reg(self.EFUSE_RD_REG_BASE + (4 * n)) def chip_id(self): raise NotSupportedError(self, "chip_id") def read_mac(self): """ Read MAC from EFUSE region """ words = [self.read_efuse(2), self.read_efuse(1)] bitstring = struct.pack(">II", *words) bitstring = bitstring[2:8] # trim the 2 byte CRC try: return tuple(ord(b) for b in bitstring) except TypeError: # Python 3, bitstring elements are already bytes return tuple(bitstring) def get_erase_size(self, offset, size): return size def override_vddsdio(self, new_voltage): new_voltage = new_voltage.upper() if new_voltage not in self.OVERRIDE_VDDSDIO_CHOICES: raise FatalError("The only accepted VDDSDIO overrides are '1.8V', '1.9V' and 'OFF'") RTC_CNTL_SDIO_CONF_REG = 0x3ff48074 RTC_CNTL_XPD_SDIO_REG = (1 << 31) RTC_CNTL_DREFH_SDIO_M = (3 << 29) RTC_CNTL_DREFM_SDIO_M = (3 << 27) RTC_CNTL_DREFL_SDIO_M = (3 << 25) # RTC_CNTL_SDIO_TIEH = (1 << 23) # not used here, setting TIEH=1 would set 3.3V output, not safe for esptool.py to do RTC_CNTL_SDIO_FORCE = (1 << 22) RTC_CNTL_SDIO_PD_EN = (1 << 21) reg_val = RTC_CNTL_SDIO_FORCE # override efuse setting reg_val |= RTC_CNTL_SDIO_PD_EN if new_voltage != "OFF": reg_val |= RTC_CNTL_XPD_SDIO_REG # enable internal LDO if new_voltage == "1.9V": reg_val |= (RTC_CNTL_DREFH_SDIO_M | RTC_CNTL_DREFM_SDIO_M | RTC_CNTL_DREFL_SDIO_M) # boost voltage self.write_reg(RTC_CNTL_SDIO_CONF_REG, reg_val) print("VDDSDIO regulator set to %s" % new_voltage) def read_flash_slow(self, offset, length, progress_fn): BLOCK_LEN = 64 # ROM read limit per command (this limit is why it's so slow) data = b'' while len(data) < length: block_len = min(BLOCK_LEN, length - len(data)) r = self.check_command("read flash block", self.ESP_READ_FLASH_SLOW, struct.pack('> 0) & 0x0F return pkg_version def get_flash_version(self): num_word = 3 block1_addr = self.EFUSE_BASE + 0x044 word3 = self.read_reg(block1_addr + (4 * num_word)) pkg_version = (word3 >> 21) & 0x0F return pkg_version def get_psram_version(self): num_word = 3 block1_addr = self.EFUSE_BASE + 0x044 word3 = self.read_reg(block1_addr + (4 * num_word)) pkg_version = (word3 >> 28) & 0x0F return pkg_version def get_block2_version(self): num_word = 4 block2_addr = self.EFUSE_BASE + 0x05C word4 = self.read_reg(block2_addr + (4 * num_word)) block2_version = (word4 >> 4) & 0x07 return block2_version def get_chip_description(self): chip_name = { 0: "ESP32-S2", 1: "ESP32-S2FH2", 2: "ESP32-S2FH4", 102: "ESP32-S2FNR2", 100: "ESP32-S2R2", }.get(self.get_flash_version() + self.get_psram_version() * 100, "unknown ESP32-S2") return "%s" % (chip_name) def get_chip_features(self): features = ["WiFi"] if self.secure_download_mode: features += ["Secure Download Mode Enabled"] flash_version = { 0: "No Embedded Flash", 1: "Embedded Flash 2MB", 2: "Embedded Flash 4MB", }.get(self.get_flash_version(), "Unknown Embedded Flash") features += [flash_version] psram_version = { 0: "No Embedded PSRAM", 1: "Embedded PSRAM 2MB", 2: "Embedded PSRAM 4MB", }.get(self.get_psram_version(), "Unknown Embedded PSRAM") features += [psram_version] block2_version = { 0: "No calibration in BLK2 of efuse", 1: "ADC and temperature sensor calibration in BLK2 of efuse V1", 2: "ADC and temperature sensor calibration in BLK2 of efuse V2", }.get(self.get_block2_version(), "Unknown Calibration in BLK2") features += [block2_version] return features def get_crystal_freq(self): # ESP32-S2 XTAL is fixed to 40MHz return 40 def override_vddsdio(self, new_voltage): raise NotImplementedInROMError("VDD_SDIO overrides are not supported for ESP32-S2") def read_mac(self): mac0 = self.read_reg(self.MAC_EFUSE_REG) mac1 = self.read_reg(self.MAC_EFUSE_REG + 4) # only bottom 16 bits are MAC bitstring = struct.pack(">II", mac1, mac0)[2:] try: return tuple(ord(b) for b in bitstring) except TypeError: # Python 3, bitstring elements are already bytes return tuple(bitstring) def get_flash_crypt_config(self): return None # doesn't exist on ESP32-S2 def get_key_block_purpose(self, key_block): if key_block < 0 or key_block > 5: raise FatalError("Valid key block numbers must be in range 0-5") reg, shift = [(self.EFUSE_PURPOSE_KEY0_REG, self.EFUSE_PURPOSE_KEY0_SHIFT), (self.EFUSE_PURPOSE_KEY1_REG, self.EFUSE_PURPOSE_KEY1_SHIFT), (self.EFUSE_PURPOSE_KEY2_REG, self.EFUSE_PURPOSE_KEY2_SHIFT), (self.EFUSE_PURPOSE_KEY3_REG, self.EFUSE_PURPOSE_KEY3_SHIFT), (self.EFUSE_PURPOSE_KEY4_REG, self.EFUSE_PURPOSE_KEY4_SHIFT), (self.EFUSE_PURPOSE_KEY5_REG, self.EFUSE_PURPOSE_KEY5_SHIFT)][key_block] return (self.read_reg(reg) >> shift) & 0xF def is_flash_encryption_key_valid(self): # Need to see either an AES-128 key or two AES-256 keys purposes = [self.get_key_block_purpose(b) for b in range(6)] if any(p == self.PURPOSE_VAL_XTS_AES128_KEY for p in purposes): return True return any(p == self.PURPOSE_VAL_XTS_AES256_KEY_1 for p in purposes) \ and any(p == self.PURPOSE_VAL_XTS_AES256_KEY_2 for p in purposes) def uses_usb(self, _cache=[]): if self.secure_download_mode: return False # can't detect native USB in secure download mode if not _cache: buf_no = self.read_reg(self.UARTDEV_BUF_NO) & 0xff _cache.append(buf_no == self.UARTDEV_BUF_NO_USB) return _cache[0] def _post_connect(self): if self.uses_usb(): self.ESP_RAM_BLOCK = self.USB_RAM_BLOCK def _check_if_can_reset(self): """ Check the strapping register to see if we can reset out of download mode. """ if os.getenv("ESPTOOL_TESTING") is not None: print("ESPTOOL_TESTING is set, ignoring strapping mode check") # Esptool tests over USB CDC run with GPIO0 strapped low, don't complain in this case. return strap_reg = self.read_reg(self.GPIO_STRAP_REG) force_dl_reg = self.read_reg(self.RTC_CNTL_OPTION1_REG) if strap_reg & self.GPIO_STRAP_SPI_BOOT_MASK == 0 and force_dl_reg & self.RTC_CNTL_FORCE_DOWNLOAD_BOOT_MASK == 0: print("WARNING: {} chip was placed into download mode using GPIO0.\n" "esptool.py can not exit the download mode over USB. " "To run the app, reset the chip manually.\n" "To suppress this note, set --after option to 'no_reset'.".format(self.get_chip_description())) raise SystemExit(1) def hard_reset(self): if self.uses_usb(): self._check_if_can_reset() print('Hard resetting via RTS pin...') self._setRTS(True) # EN->LOW if self.uses_usb(): # Give the chip some time to come out of reset, to be able to handle further DTR/RTS transitions time.sleep(0.2) self._setRTS(False) time.sleep(0.2) else: time.sleep(0.1) self._setRTS(False) class ESP32S3ROM(ESP32ROM): CHIP_NAME = "ESP32-S3" IMAGE_CHIP_ID = 9 CHIP_DETECT_MAGIC_VALUE = [0x9] BOOTLOADER_FLASH_OFFSET = 0x0 FPGA_SLOW_BOOT = False IROM_MAP_START = 0x42000000 IROM_MAP_END = 0x44000000 DROM_MAP_START = 0x3c000000 DROM_MAP_END = 0x3e000000 UART_DATE_REG_ADDR = 0x60000080 SPI_REG_BASE = 0x60002000 SPI_USR_OFFS = 0x18 SPI_USR1_OFFS = 0x1c SPI_USR2_OFFS = 0x20 SPI_MOSI_DLEN_OFFS = 0x24 SPI_MISO_DLEN_OFFS = 0x28 SPI_W0_OFFS = 0x58 FLASH_ENCRYPTED_WRITE_ALIGN = 16 # todo: use espefuse APIs to get this info EFUSE_BASE = 0x60007000 # BLOCK0 read base address MAC_EFUSE_REG = EFUSE_BASE + 0x044 EFUSE_RD_REG_BASE = EFUSE_BASE + 0x030 # BLOCK0 read base address EFUSE_PURPOSE_KEY0_REG = EFUSE_BASE + 0x34 EFUSE_PURPOSE_KEY0_SHIFT = 24 EFUSE_PURPOSE_KEY1_REG = EFUSE_BASE + 0x34 EFUSE_PURPOSE_KEY1_SHIFT = 28 EFUSE_PURPOSE_KEY2_REG = EFUSE_BASE + 0x38 EFUSE_PURPOSE_KEY2_SHIFT = 0 EFUSE_PURPOSE_KEY3_REG = EFUSE_BASE + 0x38 EFUSE_PURPOSE_KEY3_SHIFT = 4 EFUSE_PURPOSE_KEY4_REG = EFUSE_BASE + 0x38 EFUSE_PURPOSE_KEY4_SHIFT = 8 EFUSE_PURPOSE_KEY5_REG = EFUSE_BASE + 0x38 EFUSE_PURPOSE_KEY5_SHIFT = 12 EFUSE_DIS_DOWNLOAD_MANUAL_ENCRYPT_REG = EFUSE_RD_REG_BASE EFUSE_DIS_DOWNLOAD_MANUAL_ENCRYPT = 1 << 20 PURPOSE_VAL_XTS_AES256_KEY_1 = 2 PURPOSE_VAL_XTS_AES256_KEY_2 = 3 PURPOSE_VAL_XTS_AES128_KEY = 4 UARTDEV_BUF_NO = 0x3fcef14c # Variable in ROM .bss which indicates the port in use UARTDEV_BUF_NO_USB = 3 # Value of the above variable indicating that USB is in use USB_RAM_BLOCK = 0x800 # Max block size USB CDC is used GPIO_STRAP_REG = 0x60004038 GPIO_STRAP_SPI_BOOT_MASK = 0x8 # Not download mode RTC_CNTL_OPTION1_REG = 0x6000812C RTC_CNTL_FORCE_DOWNLOAD_BOOT_MASK = 0x1 # Is download mode forced over USB? UART_CLKDIV_REG = 0x60000014 MEMORY_MAP = [[0x00000000, 0x00010000, "PADDING"], [0x3C000000, 0x3D000000, "DROM"], [0x3D000000, 0x3E000000, "EXTRAM_DATA"], [0x600FE000, 0x60100000, "RTC_DRAM"], [0x3FC88000, 0x3FD00000, "BYTE_ACCESSIBLE"], [0x3FC88000, 0x403E2000, "MEM_INTERNAL"], [0x3FC88000, 0x3FD00000, "DRAM"], [0x40000000, 0x4001A100, "IROM_MASK"], [0x40370000, 0x403E0000, "IRAM"], [0x600FE000, 0x60100000, "RTC_IRAM"], [0x42000000, 0x42800000, "IROM"], [0x50000000, 0x50002000, "RTC_DATA"]] def get_chip_description(self): return "ESP32-S3" def get_chip_features(self): return ["WiFi", "BLE"] def get_crystal_freq(self): # ESP32S3 XTAL is fixed to 40MHz return 40 def get_flash_crypt_config(self): return None # doesn't exist on ESP32-S3 def get_key_block_purpose(self, key_block): if key_block < 0 or key_block > 5: raise FatalError("Valid key block numbers must be in range 0-5") reg, shift = [(self.EFUSE_PURPOSE_KEY0_REG, self.EFUSE_PURPOSE_KEY0_SHIFT), (self.EFUSE_PURPOSE_KEY1_REG, self.EFUSE_PURPOSE_KEY1_SHIFT), (self.EFUSE_PURPOSE_KEY2_REG, self.EFUSE_PURPOSE_KEY2_SHIFT), (self.EFUSE_PURPOSE_KEY3_REG, self.EFUSE_PURPOSE_KEY3_SHIFT), (self.EFUSE_PURPOSE_KEY4_REG, self.EFUSE_PURPOSE_KEY4_SHIFT), (self.EFUSE_PURPOSE_KEY5_REG, self.EFUSE_PURPOSE_KEY5_SHIFT)][key_block] return (self.read_reg(reg) >> shift) & 0xF def is_flash_encryption_key_valid(self): # Need to see either an AES-128 key or two AES-256 keys purposes = [self.get_key_block_purpose(b) for b in range(6)] if any(p == self.PURPOSE_VAL_XTS_AES128_KEY for p in purposes): return True return any(p == self.PURPOSE_VAL_XTS_AES256_KEY_1 for p in purposes) \ and any(p == self.PURPOSE_VAL_XTS_AES256_KEY_2 for p in purposes) def override_vddsdio(self, new_voltage): raise NotImplementedInROMError("VDD_SDIO overrides are not supported for ESP32-S3") def read_mac(self): mac0 = self.read_reg(self.MAC_EFUSE_REG) mac1 = self.read_reg(self.MAC_EFUSE_REG + 4) # only bottom 16 bits are MAC bitstring = struct.pack(">II", mac1, mac0)[2:] try: return tuple(ord(b) for b in bitstring) except TypeError: # Python 3, bitstring elements are already bytes return tuple(bitstring) def uses_usb(self, _cache=[]): if self.secure_download_mode: return False # can't detect native USB in secure download mode if not _cache: buf_no = self.read_reg(self.UARTDEV_BUF_NO) & 0xff _cache.append(buf_no == self.UARTDEV_BUF_NO_USB) return _cache[0] def _post_connect(self): if self.uses_usb(): self.ESP_RAM_BLOCK = self.USB_RAM_BLOCK def _check_if_can_reset(self): """ Check the strapping register to see if we can reset out of download mode. """ if os.getenv("ESPTOOL_TESTING") is not None: print("ESPTOOL_TESTING is set, ignoring strapping mode check") # Esptool tests over USB CDC run with GPIO0 strapped low, don't complain in this case. return strap_reg = self.read_reg(self.GPIO_STRAP_REG) force_dl_reg = self.read_reg(self.RTC_CNTL_OPTION1_REG) if strap_reg & self.GPIO_STRAP_SPI_BOOT_MASK == 0 and force_dl_reg & self.RTC_CNTL_FORCE_DOWNLOAD_BOOT_MASK == 0: print("WARNING: {} chip was placed into download mode using GPIO0.\n" "esptool.py can not exit the download mode over USB. " "To run the app, reset the chip manually.\n" "To suppress this note, set --after option to 'no_reset'.".format(self.get_chip_description())) raise SystemExit(1) def hard_reset(self): if self.uses_usb(): self._check_if_can_reset() print('Hard resetting via RTS pin...') self._setRTS(True) # EN->LOW if self.uses_usb(): # Give the chip some time to come out of reset, to be able to handle further DTR/RTS transitions time.sleep(0.2) self._setRTS(False) time.sleep(0.2) else: time.sleep(0.1) self._setRTS(False) class ESP32S3BETA2ROM(ESP32S3ROM): CHIP_NAME = "ESP32-S3(beta2)" IMAGE_CHIP_ID = 4 CHIP_DETECT_MAGIC_VALUE = [0xeb004136] EFUSE_BASE = 0x6001A000 # BLOCK0 read base address def get_chip_description(self): return "ESP32-S3(beta2)" class ESP32C3ROM(ESP32ROM): CHIP_NAME = "ESP32-C3" IMAGE_CHIP_ID = 5 FPGA_SLOW_BOOT = False IROM_MAP_START = 0x42000000 IROM_MAP_END = 0x42800000 DROM_MAP_START = 0x3c000000 DROM_MAP_END = 0x3c800000 SPI_REG_BASE = 0x60002000 SPI_USR_OFFS = 0x18 SPI_USR1_OFFS = 0x1C SPI_USR2_OFFS = 0x20 SPI_MOSI_DLEN_OFFS = 0x24 SPI_MISO_DLEN_OFFS = 0x28 SPI_W0_OFFS = 0x58 BOOTLOADER_FLASH_OFFSET = 0x0 # Magic value for ESP32C3 eco 1+2 and ESP32C3 eco3 respectivly CHIP_DETECT_MAGIC_VALUE = [0x6921506f, 0x1b31506f] UART_DATE_REG_ADDR = 0x60000000 + 0x7c EFUSE_BASE = 0x60008800 MAC_EFUSE_REG = EFUSE_BASE + 0x044 EFUSE_RD_REG_BASE = EFUSE_BASE + 0x030 # BLOCK0 read base address EFUSE_PURPOSE_KEY0_REG = EFUSE_BASE + 0x34 EFUSE_PURPOSE_KEY0_SHIFT = 24 EFUSE_PURPOSE_KEY1_REG = EFUSE_BASE + 0x34 EFUSE_PURPOSE_KEY1_SHIFT = 28 EFUSE_PURPOSE_KEY2_REG = EFUSE_BASE + 0x38 EFUSE_PURPOSE_KEY2_SHIFT = 0 EFUSE_PURPOSE_KEY3_REG = EFUSE_BASE + 0x38 EFUSE_PURPOSE_KEY3_SHIFT = 4 EFUSE_PURPOSE_KEY4_REG = EFUSE_BASE + 0x38 EFUSE_PURPOSE_KEY4_SHIFT = 8 EFUSE_PURPOSE_KEY5_REG = EFUSE_BASE + 0x38 EFUSE_PURPOSE_KEY5_SHIFT = 12 EFUSE_DIS_DOWNLOAD_MANUAL_ENCRYPT_REG = EFUSE_RD_REG_BASE EFUSE_DIS_DOWNLOAD_MANUAL_ENCRYPT = 1 << 20 PURPOSE_VAL_XTS_AES128_KEY = 4 GPIO_STRAP_REG = 0x3f404038 FLASH_ENCRYPTED_WRITE_ALIGN = 16 MEMORY_MAP = [[0x00000000, 0x00010000, "PADDING"], [0x3C000000, 0x3C800000, "DROM"], [0x3FC80000, 0x3FCE0000, "DRAM"], [0x3FC88000, 0x3FD00000, "BYTE_ACCESSIBLE"], [0x3FF00000, 0x3FF20000, "DROM_MASK"], [0x40000000, 0x40060000, "IROM_MASK"], [0x42000000, 0x42800000, "IROM"], [0x4037C000, 0x403E0000, "IRAM"], [0x50000000, 0x50002000, "RTC_IRAM"], [0x50000000, 0x50002000, "RTC_DRAM"], [0x600FE000, 0x60100000, "MEM_INTERNAL2"]] def get_pkg_version(self): num_word = 3 block1_addr = self.EFUSE_BASE + 0x044 word3 = self.read_reg(block1_addr + (4 * num_word)) pkg_version = (word3 >> 21) & 0x07 return pkg_version def get_chip_revision(self): # reads WAFER_VERSION field from EFUSE_RD_MAC_SPI_SYS_3_REG block1_addr = self.EFUSE_BASE + 0x044 num_word = 3 pos = 18 return (self.read_reg(block1_addr + (4 * num_word)) & (0x7 << pos)) >> pos def get_chip_description(self): chip_name = { 0: "ESP32-C3", }.get(self.get_pkg_version(), "unknown ESP32-C3") chip_revision = self.get_chip_revision() return "%s (revision %d)" % (chip_name, chip_revision) def get_chip_features(self): return ["Wi-Fi"] def get_crystal_freq(self): # ESP32C3 XTAL is fixed to 40MHz return 40 def override_vddsdio(self, new_voltage): raise NotImplementedInROMError("VDD_SDIO overrides are not supported for ESP32-C3") def read_mac(self): mac0 = self.read_reg(self.MAC_EFUSE_REG) mac1 = self.read_reg(self.MAC_EFUSE_REG + 4) # only bottom 16 bits are MAC bitstring = struct.pack(">II", mac1, mac0)[2:] try: return tuple(ord(b) for b in bitstring) except TypeError: # Python 3, bitstring elements are already bytes return tuple(bitstring) def get_flash_crypt_config(self): return None # doesn't exist on ESP32-C3 def get_key_block_purpose(self, key_block): if key_block < 0 or key_block > 5: raise FatalError("Valid key block numbers must be in range 0-5") reg, shift = [(self.EFUSE_PURPOSE_KEY0_REG, self.EFUSE_PURPOSE_KEY0_SHIFT), (self.EFUSE_PURPOSE_KEY1_REG, self.EFUSE_PURPOSE_KEY1_SHIFT), (self.EFUSE_PURPOSE_KEY2_REG, self.EFUSE_PURPOSE_KEY2_SHIFT), (self.EFUSE_PURPOSE_KEY3_REG, self.EFUSE_PURPOSE_KEY3_SHIFT), (self.EFUSE_PURPOSE_KEY4_REG, self.EFUSE_PURPOSE_KEY4_SHIFT), (self.EFUSE_PURPOSE_KEY5_REG, self.EFUSE_PURPOSE_KEY5_SHIFT)][key_block] return (self.read_reg(reg) >> shift) & 0xF def is_flash_encryption_key_valid(self): # Need to see an AES-128 key purposes = [self.get_key_block_purpose(b) for b in range(6)] return any(p == self.PURPOSE_VAL_XTS_AES128_KEY for p in purposes) class ESP32H2BETA1ROM(ESP32ROM): CHIP_NAME = "ESP32-H2(beta1)" IMAGE_CHIP_ID = 10 IROM_MAP_START = 0x42000000 IROM_MAP_END = 0x42800000 DROM_MAP_START = 0x3c000000 DROM_MAP_END = 0x3c800000 SPI_REG_BASE = 0x60002000 SPI_USR_OFFS = 0x18 SPI_USR1_OFFS = 0x1C SPI_USR2_OFFS = 0x20 SPI_MOSI_DLEN_OFFS = 0x24 SPI_MISO_DLEN_OFFS = 0x28 SPI_W0_OFFS = 0x58 BOOTLOADER_FLASH_OFFSET = 0x0 CHIP_DETECT_MAGIC_VALUE = [0xca26cc22] UART_DATE_REG_ADDR = 0x60000000 + 0x7c EFUSE_BASE = 0x6001A000 MAC_EFUSE_REG = EFUSE_BASE + 0x044 EFUSE_RD_REG_BASE = EFUSE_BASE + 0x030 # BLOCK0 read base address EFUSE_PURPOSE_KEY0_REG = EFUSE_BASE + 0x34 EFUSE_PURPOSE_KEY0_SHIFT = 24 EFUSE_PURPOSE_KEY1_REG = EFUSE_BASE + 0x34 EFUSE_PURPOSE_KEY1_SHIFT = 28 EFUSE_PURPOSE_KEY2_REG = EFUSE_BASE + 0x38 EFUSE_PURPOSE_KEY2_SHIFT = 0 EFUSE_PURPOSE_KEY3_REG = EFUSE_BASE + 0x38 EFUSE_PURPOSE_KEY3_SHIFT = 4 EFUSE_PURPOSE_KEY4_REG = EFUSE_BASE + 0x38 EFUSE_PURPOSE_KEY4_SHIFT = 8 EFUSE_PURPOSE_KEY5_REG = EFUSE_BASE + 0x38 EFUSE_PURPOSE_KEY5_SHIFT = 12 EFUSE_DIS_DOWNLOAD_MANUAL_ENCRYPT_REG = EFUSE_RD_REG_BASE EFUSE_DIS_DOWNLOAD_MANUAL_ENCRYPT = 1 << 20 PURPOSE_VAL_XTS_AES128_KEY = 4 GPIO_STRAP_REG = 0x3f404038 FLASH_ENCRYPTED_WRITE_ALIGN = 16 MEMORY_MAP = [] FLASH_FREQUENCY = { '48m': 0xf, '24m': 0x0, '16m': 0x1, '12m': 0x2, } def get_pkg_version(self): num_word = 3 block1_addr = self.EFUSE_BASE + 0x044 word3 = self.read_reg(block1_addr + (4 * num_word)) pkg_version = (word3 >> 21) & 0x0F return pkg_version def get_chip_revision(self): # reads WAFER_VERSION field from EFUSE_RD_MAC_SPI_SYS_3_REG block1_addr = self.EFUSE_BASE + 0x044 num_word = 3 pos = 18 return (self.read_reg(block1_addr + (4 * num_word)) & (0x7 << pos)) >> pos def get_chip_description(self): chip_name = { 0: "ESP32-H2", }.get(self.get_pkg_version(), "unknown ESP32-H2") chip_revision = self.get_chip_revision() return "%s (revision %d)" % (chip_name, chip_revision) def get_chip_features(self): return ["BLE/802.15.4"] def get_crystal_freq(self): return 32 def override_vddsdio(self, new_voltage): raise NotImplementedInROMError("VDD_SDIO overrides are not supported for ESP32-H2") def read_mac(self): mac0 = self.read_reg(self.MAC_EFUSE_REG) mac1 = self.read_reg(self.MAC_EFUSE_REG + 4) # only bottom 16 bits are MAC bitstring = struct.pack(">II", mac1, mac0)[2:] try: return tuple(ord(b) for b in bitstring) except TypeError: # Python 3, bitstring elements are already bytes return tuple(bitstring) def get_flash_crypt_config(self): return None # doesn't exist on ESP32-H2 def get_key_block_purpose(self, key_block): if key_block < 0 or key_block > 5: raise FatalError("Valid key block numbers must be in range 0-5") reg, shift = [(self.EFUSE_PURPOSE_KEY0_REG, self.EFUSE_PURPOSE_KEY0_SHIFT), (self.EFUSE_PURPOSE_KEY1_REG, self.EFUSE_PURPOSE_KEY1_SHIFT), (self.EFUSE_PURPOSE_KEY2_REG, self.EFUSE_PURPOSE_KEY2_SHIFT), (self.EFUSE_PURPOSE_KEY3_REG, self.EFUSE_PURPOSE_KEY3_SHIFT), (self.EFUSE_PURPOSE_KEY4_REG, self.EFUSE_PURPOSE_KEY4_SHIFT), (self.EFUSE_PURPOSE_KEY5_REG, self.EFUSE_PURPOSE_KEY5_SHIFT)][key_block] return (self.read_reg(reg) >> shift) & 0xF def is_flash_encryption_key_valid(self): # Need to see an AES-128 key purposes = [self.get_key_block_purpose(b) for b in range(6)] return any(p == self.PURPOSE_VAL_XTS_AES128_KEY for p in purposes) class ESP32H2BETA2ROM(ESP32H2BETA1ROM): CHIP_NAME = "ESP32-H2(beta2)" IMAGE_CHIP_ID = 14 class ESP32C2ROM(ESP32C3ROM): CHIP_NAME = "ESP32-C2" IMAGE_CHIP_ID = 12 IROM_MAP_START = 0x42000000 IROM_MAP_END = 0x42400000 DROM_MAP_START = 0x3c000000 DROM_MAP_END = 0x3c400000 # Magic value for ESP32C2 ECO0 and ECO1 respectively CHIP_DETECT_MAGIC_VALUE = [0x6F51306F, 0x7c41a06f] EFUSE_BASE = 0x60008800 MAC_EFUSE_REG = EFUSE_BASE + 0x040 FLASH_FREQUENCY = { '60m': 0xf, '30m': 0x0, '20m': 0x1, '15m': 0x2, } def get_pkg_version(self): num_word = 3 block1_addr = self.EFUSE_BASE + 0x044 word3 = self.read_reg(block1_addr + (4 * num_word)) pkg_version = (word3 >> 21) & 0x0F return pkg_version def get_chip_description(self): chip_name = { 0: "ESP32-C2", }.get(self.get_pkg_version(), "unknown ESP32-C2") chip_revision = self.get_chip_revision() return "%s (revision %d)" % (chip_name, chip_revision) def get_chip_revision(self): si = self.get_security_info() return si["api_version"] def _post_connect(self): # ESP32C2 ECO0 is no longer supported by the flasher stub if self.get_chip_revision() == 0: self.stub_is_disabled = True self.IS_STUB = False class ESP32C6BETAROM(ESP32C3ROM): CHIP_NAME = "ESP32-C6(beta)" IMAGE_CHIP_ID = 7 CHIP_DETECT_MAGIC_VALUE = [0x0da1806f] UART_DATE_REG_ADDR = 0x00000500 def get_chip_description(self): chip_name = { 0: "ESP32-C6", }.get(self.get_pkg_version(), "unknown ESP32-C6") chip_revision = self.get_chip_revision() return "%s (revision %d)" % (chip_name, chip_revision) class ESP32StubLoader(ESP32ROM): """ Access class for ESP32 stub loader, runs on top of ROM. """ FLASH_WRITE_SIZE = 0x4000 # matches MAX_WRITE_BLOCK in stub_loader.c STATUS_BYTES_LENGTH = 2 # same as ESP8266, different to ESP32 ROM IS_STUB = True def __init__(self, rom_loader): self.secure_download_mode = rom_loader.secure_download_mode self._port = rom_loader._port self._trace_enabled = rom_loader._trace_enabled self.flush_input() # resets _slip_reader ESP32ROM.STUB_CLASS = ESP32StubLoader class ESP32S2StubLoader(ESP32S2ROM): """ Access class for ESP32-S2 stub loader, runs on top of ROM. (Basically the same as ESP32StubLoader, but different base class. Can possibly be made into a mixin.) """ FLASH_WRITE_SIZE = 0x4000 # matches MAX_WRITE_BLOCK in stub_loader.c STATUS_BYTES_LENGTH = 2 # same as ESP8266, different to ESP32 ROM IS_STUB = True def __init__(self, rom_loader): self.secure_download_mode = rom_loader.secure_download_mode self._port = rom_loader._port self._trace_enabled = rom_loader._trace_enabled self.flush_input() # resets _slip_reader if rom_loader.uses_usb(): self.ESP_RAM_BLOCK = self.USB_RAM_BLOCK self.FLASH_WRITE_SIZE = self.USB_RAM_BLOCK ESP32S2ROM.STUB_CLASS = ESP32S2StubLoader class ESP32S3BETA2StubLoader(ESP32S3BETA2ROM): """ Access class for ESP32S3 stub loader, runs on top of ROM. (Basically the same as ESP32StubLoader, but different base class. Can possibly be made into a mixin.) """ FLASH_WRITE_SIZE = 0x4000 # matches MAX_WRITE_BLOCK in stub_loader.c STATUS_BYTES_LENGTH = 2 # same as ESP8266, different to ESP32 ROM IS_STUB = True def __init__(self, rom_loader): self.secure_download_mode = rom_loader.secure_download_mode self._port = rom_loader._port self._trace_enabled = rom_loader._trace_enabled self.flush_input() # resets _slip_reader ESP32S3BETA2ROM.STUB_CLASS = ESP32S3BETA2StubLoader class ESP32S3StubLoader(ESP32S3ROM): """ Access class for ESP32S3 stub loader, runs on top of ROM. (Basically the same as ESP32StubLoader, but different base class. Can possibly be made into a mixin.) """ FLASH_WRITE_SIZE = 0x4000 # matches MAX_WRITE_BLOCK in stub_loader.c STATUS_BYTES_LENGTH = 2 # same as ESP8266, different to ESP32 ROM IS_STUB = True def __init__(self, rom_loader): self.secure_download_mode = rom_loader.secure_download_mode self._port = rom_loader._port self._trace_enabled = rom_loader._trace_enabled self.flush_input() # resets _slip_reader if rom_loader.uses_usb(): self.ESP_RAM_BLOCK = self.USB_RAM_BLOCK self.FLASH_WRITE_SIZE = self.USB_RAM_BLOCK ESP32S3ROM.STUB_CLASS = ESP32S3StubLoader class ESP32C3StubLoader(ESP32C3ROM): """ Access class for ESP32C3 stub loader, runs on top of ROM. (Basically the same as ESP32StubLoader, but different base class. Can possibly be made into a mixin.) """ FLASH_WRITE_SIZE = 0x4000 # matches MAX_WRITE_BLOCK in stub_loader.c STATUS_BYTES_LENGTH = 2 # same as ESP8266, different to ESP32 ROM IS_STUB = True def __init__(self, rom_loader): self.secure_download_mode = rom_loader.secure_download_mode self._port = rom_loader._port self._trace_enabled = rom_loader._trace_enabled self.flush_input() # resets _slip_reader ESP32C3ROM.STUB_CLASS = ESP32C3StubLoader class ESP32H2BETA1StubLoader(ESP32H2BETA1ROM): """ Access class for ESP32H2BETA1 stub loader, runs on top of ROM. (Basically the same as ESP32StubLoader, but different base class. Can possibly be made into a mixin.) """ FLASH_WRITE_SIZE = 0x4000 # matches MAX_WRITE_BLOCK in stub_loader.c STATUS_BYTES_LENGTH = 2 # same as ESP8266, different to ESP32 ROM IS_STUB = True def __init__(self, rom_loader): self.secure_download_mode = rom_loader.secure_download_mode self._port = rom_loader._port self._trace_enabled = rom_loader._trace_enabled self.flush_input() # resets _slip_reader ESP32H2BETA1ROM.STUB_CLASS = ESP32H2BETA1StubLoader class ESP32H2BETA2StubLoader(ESP32H2BETA2ROM): """ Access class for ESP32H2BETA2 stub loader, runs on top of ROM. (Basically the same as ESP32StubLoader, but different base class. Can possibly be made into a mixin.) """ FLASH_WRITE_SIZE = 0x4000 # matches MAX_WRITE_BLOCK in stub_loader.c STATUS_BYTES_LENGTH = 2 # same as ESP8266, different to ESP32 ROM IS_STUB = True def __init__(self, rom_loader): self.secure_download_mode = rom_loader.secure_download_mode self._port = rom_loader._port self._trace_enabled = rom_loader._trace_enabled self.flush_input() # resets _slip_reader ESP32H2BETA2ROM.STUB_CLASS = ESP32H2BETA2StubLoader class ESP32C2StubLoader(ESP32C2ROM): """ Access class for ESP32C2 stub loader, runs on top of ROM. (Basically the same as ESP32StubLoader, but different base class. Can possibly be made into a mixin.) """ FLASH_WRITE_SIZE = 0x4000 # matches MAX_WRITE_BLOCK in stub_loader.c STATUS_BYTES_LENGTH = 2 # same as ESP8266, different to ESP32 ROM IS_STUB = True def __init__(self, rom_loader): self.secure_download_mode = rom_loader.secure_download_mode self._port = rom_loader._port self._trace_enabled = rom_loader._trace_enabled self.flush_input() # resets _slip_reader ESP32C2ROM.STUB_CLASS = ESP32C2StubLoader class ESPBOOTLOADER(object): """ These are constants related to software ESP8266 bootloader, working with 'v2' image files """ # First byte of the "v2" application image IMAGE_V2_MAGIC = 0xea # First 'segment' value in a "v2" application image, appears to be a constant version value? IMAGE_V2_SEGMENT = 4 def LoadFirmwareImage(chip, filename): """ Load a firmware image. Can be for any supported SoC. ESP8266 images will be examined to determine if they are original ROM firmware images (ESP8266ROMFirmwareImage) or "v2" OTA bootloader images. Returns a BaseFirmwareImage subclass, either ESP8266ROMFirmwareImage (v1) or ESP8266V2FirmwareImage (v2). """ chip = re.sub(r"[-()]", "", chip.lower()) with open(filename, 'rb') as f: if chip == 'esp32': return ESP32FirmwareImage(f) elif chip == "esp32s2": return ESP32S2FirmwareImage(f) elif chip == "esp32s3beta2": return ESP32S3BETA2FirmwareImage(f) elif chip == "esp32s3": return ESP32S3FirmwareImage(f) elif chip == 'esp32c3': return ESP32C3FirmwareImage(f) elif chip == 'esp32c6beta': return ESP32C6BETAFirmwareImage(f) elif chip == 'esp32h2beta1': return ESP32H2BETA1FirmwareImage(f) elif chip == 'esp32h2beta2': return ESP32H2BETA2FirmwareImage(f) elif chip == 'esp32c2': return ESP32C2FirmwareImage(f) else: # Otherwise, ESP8266 so look at magic to determine the image type magic = ord(f.read(1)) f.seek(0) if magic == ESPLoader.ESP_IMAGE_MAGIC: return ESP8266ROMFirmwareImage(f) elif magic == ESPBOOTLOADER.IMAGE_V2_MAGIC: return ESP8266V2FirmwareImage(f) else: raise FatalError("Invalid image magic number: %d" % magic) class ImageSegment(object): """ Wrapper class for a segment in an ESP image (very similar to a section in an ELFImage also) """ def __init__(self, addr, data, file_offs=None): self.addr = addr self.data = data self.file_offs = file_offs self.include_in_checksum = True if self.addr != 0: self.pad_to_alignment(4) # pad all "real" ImageSegments 4 byte aligned length def copy_with_new_addr(self, new_addr): """ Return a new ImageSegment with same data, but mapped at a new address. """ return ImageSegment(new_addr, self.data, 0) def split_image(self, split_len): """ Return a new ImageSegment which splits "split_len" bytes from the beginning of the data. Remaining bytes are kept in this segment object (and the start address is adjusted to match.) """ result = copy.copy(self) result.data = self.data[:split_len] self.data = self.data[split_len:] self.addr += split_len self.file_offs = None result.file_offs = None return result def __repr__(self): r = "len 0x%05x load 0x%08x" % (len(self.data), self.addr) if self.file_offs is not None: r += " file_offs 0x%08x" % (self.file_offs) return r def get_memory_type(self, image): """ Return a list describing the memory type(s) that is covered by this segment's start address. """ return [map_range[2] for map_range in image.ROM_LOADER.MEMORY_MAP if map_range[0] <= self.addr < map_range[1]] def pad_to_alignment(self, alignment): self.data = pad_to(self.data, alignment, b'\x00') class ELFSection(ImageSegment): """ Wrapper class for a section in an ELF image, has a section name as well as the common properties of an ImageSegment. """ def __init__(self, name, addr, data): super(ELFSection, self).__init__(addr, data) self.name = name.decode("utf-8") def __repr__(self): return "%s %s" % (self.name, super(ELFSection, self).__repr__()) class BaseFirmwareImage(object): SEG_HEADER_LEN = 8 SHA256_DIGEST_LEN = 32 """ Base class with common firmware image functions """ def __init__(self): self.segments = [] self.entrypoint = 0 self.elf_sha256 = None self.elf_sha256_offset = 0 def load_common_header(self, load_file, expected_magic): (magic, segments, self.flash_mode, self.flash_size_freq, self.entrypoint) = struct.unpack(' 16: raise FatalError('Invalid segment count %d (max 16). Usually this indicates a linker script problem.' % len(self.segments)) def load_segment(self, f, is_irom_segment=False): """ Load the next segment from the image file """ file_offs = f.tell() (offset, size) = struct.unpack(' 0x40200000 or offset < 0x3ffe0000 or size > 65536: print('WARNING: Suspicious segment 0x%x, length %d' % (offset, size)) def maybe_patch_segment_data(self, f, segment_data): """If SHA256 digest of the ELF file needs to be inserted into this segment, do so. Returns segment data.""" segment_len = len(segment_data) file_pos = f.tell() # file_pos is position in the .bin file if self.elf_sha256_offset >= file_pos and self.elf_sha256_offset < file_pos + segment_len: # SHA256 digest needs to be patched into this binary segment, # calculate offset of the digest inside the binary segment. patch_offset = self.elf_sha256_offset - file_pos # Sanity checks if patch_offset < self.SEG_HEADER_LEN or patch_offset + self.SHA256_DIGEST_LEN > segment_len: raise FatalError('Cannot place SHA256 digest on segment boundary' '(elf_sha256_offset=%d, file_pos=%d, segment_size=%d)' % (self.elf_sha256_offset, file_pos, segment_len)) # offset relative to the data part patch_offset -= self.SEG_HEADER_LEN if segment_data[patch_offset:patch_offset + self.SHA256_DIGEST_LEN] != b'\x00' * self.SHA256_DIGEST_LEN: raise FatalError('Contents of segment at SHA256 digest offset 0x%x are not all zero. Refusing to overwrite.' % self.elf_sha256_offset) assert len(self.elf_sha256) == self.SHA256_DIGEST_LEN segment_data = segment_data[0:patch_offset] + self.elf_sha256 + \ segment_data[patch_offset + self.SHA256_DIGEST_LEN:] return segment_data def save_segment(self, f, segment, checksum=None): """ Save the next segment to the image file, return next checksum value if provided """ segment_data = self.maybe_patch_segment_data(f, segment.data) f.write(struct.pack(' 0: if len(irom_segments) != 1: raise FatalError('Found %d segments that could be irom0. Bad ELF file?' % len(irom_segments)) return irom_segments[0] return None def get_non_irom_segments(self): irom_segment = self.get_irom_segment() return [s for s in self.segments if s != irom_segment] def merge_adjacent_segments(self): if not self.segments: return # nothing to merge segments = [] # The easiest way to merge the sections is the browse them backward. for i in range(len(self.segments) - 1, 0, -1): # elem is the previous section, the one `next_elem` may need to be # merged in elem = self.segments[i - 1] next_elem = self.segments[i] if all((elem.get_memory_type(self) == next_elem.get_memory_type(self), elem.include_in_checksum == next_elem.include_in_checksum, next_elem.addr == elem.addr + len(elem.data))): # Merge any segment that ends where the next one starts, without spanning memory types # # (don't 'pad' any gaps here as they may be excluded from the image due to 'noinit' # or other reasons.) elem.data += next_elem.data else: # The section next_elem cannot be merged into the previous one, # which means it needs to be part of the final segments. # As we are browsing the list backward, the elements need to be # inserted at the beginning of the final list. segments.insert(0, next_elem) # The first segment will always be here as it cannot be merged into any # "previous" section. segments.insert(0, self.segments[0]) # note: we could sort segments here as well, but the ordering of segments is sometimes # important for other reasons (like embedded ELF SHA-256), so we assume that the linker # script will have produced any adjacent sections in linear order in the ELF, anyhow. self.segments = segments def set_mmu_page_size(self, size): """ If supported, this should be overridden by the chip-specific class. Gets called in elf2image. """ print('WARNING: Changing MMU page size is not supported on {}! Defaulting to 64KB.'.format(self.ROM_LOADER.CHIP_NAME)) class ESP8266ROMFirmwareImage(BaseFirmwareImage): """ 'Version 1' firmware image, segments loaded directly by the ROM bootloader. """ ROM_LOADER = ESP8266ROM def __init__(self, load_file=None): super(ESP8266ROMFirmwareImage, self).__init__() self.flash_mode = 0 self.flash_size_freq = 0 self.version = 1 if load_file is not None: segments = self.load_common_header(load_file, ESPLoader.ESP_IMAGE_MAGIC) for _ in range(segments): self.load_segment(load_file) self.checksum = self.read_checksum(load_file) self.verify() def default_output_name(self, input_file): """ Derive a default output name from the ELF name. """ return input_file + '-' def save(self, basename): """ Save a set of V1 images for flashing. Parameter is a base filename. """ # IROM data goes in its own plain binary file irom_segment = self.get_irom_segment() if irom_segment is not None: with open("%s0x%05x.bin" % (basename, irom_segment.addr - ESP8266ROM.IROM_MAP_START), "wb") as f: f.write(irom_segment.data) # everything but IROM goes at 0x00000 in an image file normal_segments = self.get_non_irom_segments() with open("%s0x00000.bin" % basename, 'wb') as f: self.write_common_header(f, normal_segments) checksum = ESPLoader.ESP_CHECKSUM_MAGIC for segment in normal_segments: checksum = self.save_segment(f, segment, checksum) self.append_checksum(f, checksum) ESP8266ROM.BOOTLOADER_IMAGE = ESP8266ROMFirmwareImage class ESP8266V2FirmwareImage(BaseFirmwareImage): """ 'Version 2' firmware image, segments loaded by software bootloader stub (ie Espressif bootloader or rboot) """ ROM_LOADER = ESP8266ROM def __init__(self, load_file=None): super(ESP8266V2FirmwareImage, self).__init__() self.version = 2 if load_file is not None: segments = self.load_common_header(load_file, ESPBOOTLOADER.IMAGE_V2_MAGIC) if segments != ESPBOOTLOADER.IMAGE_V2_SEGMENT: # segment count is not really segment count here, but we expect to see '4' print('Warning: V2 header has unexpected "segment" count %d (usually 4)' % segments) # irom segment comes before the second header # # the file is saved in the image with a zero load address # in the header, so we need to calculate a load address irom_segment = self.load_segment(load_file, True) irom_segment.addr = 0 # for actual mapped addr, add ESP8266ROM.IROM_MAP_START + flashing_addr + 8 irom_segment.include_in_checksum = False first_flash_mode = self.flash_mode first_flash_size_freq = self.flash_size_freq first_entrypoint = self.entrypoint # load the second header segments = self.load_common_header(load_file, ESPLoader.ESP_IMAGE_MAGIC) if first_flash_mode != self.flash_mode: print('WARNING: Flash mode value in first header (0x%02x) disagrees with second (0x%02x). Using second value.' % (first_flash_mode, self.flash_mode)) if first_flash_size_freq != self.flash_size_freq: print('WARNING: Flash size/freq value in first header (0x%02x) disagrees with second (0x%02x). Using second value.' % (first_flash_size_freq, self.flash_size_freq)) if first_entrypoint != self.entrypoint: print('WARNING: Entrypoint address in first header (0x%08x) disagrees with second header (0x%08x). Using second value.' % (first_entrypoint, self.entrypoint)) # load all the usual segments for _ in range(segments): self.load_segment(load_file) self.checksum = self.read_checksum(load_file) self.verify() def default_output_name(self, input_file): """ Derive a default output name from the ELF name. """ irom_segment = self.get_irom_segment() if irom_segment is not None: irom_offs = irom_segment.addr - ESP8266ROM.IROM_MAP_START else: irom_offs = 0 return "%s-0x%05x.bin" % (os.path.splitext(input_file)[0], irom_offs & ~(ESPLoader.FLASH_SECTOR_SIZE - 1)) def save(self, filename): with open(filename, 'wb') as f: # Save first header for irom0 segment f.write(struct.pack(b' 0: last_addr = flash_segments[0].addr for segment in flash_segments[1:]: if segment.addr // self.IROM_ALIGN == last_addr // self.IROM_ALIGN: raise FatalError(("Segment loaded at 0x%08x lands in same 64KB flash mapping as segment loaded at 0x%08x. " "Can't generate binary. Suggest changing linker script or ELF to merge sections.") % (segment.addr, last_addr)) last_addr = segment.addr def get_alignment_data_needed(segment): # Actual alignment (in data bytes) required for a segment header: positioned so that # after we write the next 8 byte header, file_offs % IROM_ALIGN == segment.addr % IROM_ALIGN # # (this is because the segment's vaddr may not be IROM_ALIGNed, more likely is aligned # IROM_ALIGN+0x18 to account for the binary file header align_past = (segment.addr % self.IROM_ALIGN) - self.SEG_HEADER_LEN pad_len = (self.IROM_ALIGN - (f.tell() % self.IROM_ALIGN)) + align_past if pad_len == 0 or pad_len == self.IROM_ALIGN: return 0 # already aligned # subtract SEG_HEADER_LEN a second time, as the padding block has a header as well pad_len -= self.SEG_HEADER_LEN if pad_len < 0: pad_len += self.IROM_ALIGN return pad_len # try to fit each flash segment on a 64kB aligned boundary # by padding with parts of the non-flash segments... while len(flash_segments) > 0: segment = flash_segments[0] pad_len = get_alignment_data_needed(segment) if pad_len > 0: # need to pad if len(ram_segments) > 0 and pad_len > self.SEG_HEADER_LEN: pad_segment = ram_segments[0].split_image(pad_len) if len(ram_segments[0].data) == 0: ram_segments.pop(0) else: pad_segment = ImageSegment(0, b'\x00' * pad_len, f.tell()) checksum = self.save_segment(f, pad_segment, checksum) total_segments += 1 else: # write the flash segment assert (f.tell() + 8) % self.IROM_ALIGN == segment.addr % self.IROM_ALIGN checksum = self.save_flash_segment(f, segment, checksum) flash_segments.pop(0) total_segments += 1 # flash segments all written, so write any remaining RAM segments for segment in ram_segments: checksum = self.save_segment(f, segment, checksum) total_segments += 1 if self.secure_pad: # pad the image so that after signing it will end on a a 64KB boundary. # This ensures all mapped flash content will be verified. if not self.append_digest: raise FatalError("secure_pad only applies if a SHA-256 digest is also appended to the image") align_past = (f.tell() + self.SEG_HEADER_LEN) % self.IROM_ALIGN # 16 byte aligned checksum (force the alignment to simplify calculations) checksum_space = 16 if self.secure_pad == '1': # after checksum: SHA-256 digest + (to be added by signing process) version, signature + 12 trailing bytes due to alignment space_after_checksum = 32 + 4 + 64 + 12 elif self.secure_pad == '2': # Secure Boot V2 # after checksum: SHA-256 digest + signature sector, but we place signature sector after the 64KB boundary space_after_checksum = 32 pad_len = (self.IROM_ALIGN - align_past - checksum_space - space_after_checksum) % self.IROM_ALIGN pad_segment = ImageSegment(0, b'\x00' * pad_len, f.tell()) checksum = self.save_segment(f, pad_segment, checksum) total_segments += 1 # done writing segments self.append_checksum(f, checksum) image_length = f.tell() if self.secure_pad: assert ((image_length + space_after_checksum) % self.IROM_ALIGN) == 0 # kinda hacky: go back to the initial header and write the new segment count # that includes padding segments. This header is not checksummed f.seek(1) try: f.write(chr(total_segments)) except TypeError: # Python 3 f.write(bytes([total_segments])) if self.append_digest: # calculate the SHA256 of the whole file and append it f.seek(0) digest = hashlib.sha256() digest.update(f.read(image_length)) f.write(digest.digest()) with open(filename, 'wb') as real_file: real_file.write(f.getvalue()) def save_flash_segment(self, f, segment, checksum=None): """ Save the next segment to the image file, return next checksum value if provided """ segment_end_pos = f.tell() + len(segment.data) + self.SEG_HEADER_LEN segment_len_remainder = segment_end_pos % self.IROM_ALIGN if segment_len_remainder < 0x24: # Work around a bug in ESP-IDF 2nd stage bootloader, that it didn't map the # last MMU page, if an IROM/DROM segment was < 0x24 bytes over the page boundary. segment.data += b'\x00' * (0x24 - segment_len_remainder) return self.save_segment(f, segment, checksum) def load_extended_header(self, load_file): def split_byte(n): return (n & 0x0F, (n >> 4) & 0x0F) fields = list(struct.unpack(self.EXTENDED_HEADER_STRUCT_FMT, load_file.read(16))) self.wp_pin = fields[0] # SPI pin drive stengths are two per byte self.clk_drv, self.q_drv = split_byte(fields[1]) self.d_drv, self.cs_drv = split_byte(fields[2]) self.hd_drv, self.wp_drv = split_byte(fields[3]) chip_id = fields[4] if chip_id != self.ROM_LOADER.IMAGE_CHIP_ID: print(("Unexpected chip id in image. Expected %d but value was %d. " "Is this image for a different chip model?") % (self.ROM_LOADER.IMAGE_CHIP_ID, chip_id)) self.min_rev = fields[5] # reserved fields in the middle should all be zero if any(f for f in fields[6:-1] if f != 0): print("Warning: some reserved header fields have non-zero values. This image may be from a newer esptool.py?") append_digest = fields[-1] # last byte is append_digest if append_digest in [0, 1]: self.append_digest = (append_digest == 1) else: raise RuntimeError("Invalid value for append_digest field (0x%02x). Should be 0 or 1.", append_digest) def save_extended_header(self, save_file): def join_byte(ln, hn): return (ln & 0x0F) + ((hn & 0x0F) << 4) append_digest = 1 if self.append_digest else 0 fields = [self.wp_pin, join_byte(self.clk_drv, self.q_drv), join_byte(self.d_drv, self.cs_drv), join_byte(self.hd_drv, self.wp_drv), self.ROM_LOADER.IMAGE_CHIP_ID, self.min_rev] fields += [0] * 8 # padding fields += [append_digest] packed = struct.pack(self.EXTENDED_HEADER_STRUCT_FMT, *fields) save_file.write(packed) class ESP8266V3FirmwareImage(ESP32FirmwareImage): """ ESP8266 V3 firmware image is very similar to ESP32 image """ EXTENDED_HEADER_STRUCT_FMT = "B" * 16 def is_flash_addr(self, addr): return (addr > ESP8266ROM.IROM_MAP_START) def save(self, filename): total_segments = 0 with io.BytesIO() as f: # write file to memory first self.write_common_header(f, self.segments) checksum = ESPLoader.ESP_CHECKSUM_MAGIC # split segments into flash-mapped vs ram-loaded, and take copies so we can mutate them flash_segments = [copy.deepcopy(s) for s in sorted(self.segments, key=lambda s:s.addr) if self.is_flash_addr(s.addr) and len(s.data)] ram_segments = [copy.deepcopy(s) for s in sorted(self.segments, key=lambda s:s.addr) if not self.is_flash_addr(s.addr) and len(s.data)] # check for multiple ELF sections that are mapped in the same flash mapping region. # this is usually a sign of a broken linker script, but if you have a legitimate # use case then let us know if len(flash_segments) > 0: last_addr = flash_segments[0].addr for segment in flash_segments[1:]: if segment.addr // self.IROM_ALIGN == last_addr // self.IROM_ALIGN: raise FatalError(("Segment loaded at 0x%08x lands in same 64KB flash mapping as segment loaded at 0x%08x. " "Can't generate binary. Suggest changing linker script or ELF to merge sections.") % (segment.addr, last_addr)) last_addr = segment.addr # try to fit each flash segment on a 64kB aligned boundary # by padding with parts of the non-flash segments... while len(flash_segments) > 0: segment = flash_segments[0] # remove 8 bytes empty data for insert segment header if segment.name == '.flash.rodata': segment.data = segment.data[8:] # write the flash segment checksum = self.save_segment(f, segment, checksum) flash_segments.pop(0) total_segments += 1 # flash segments all written, so write any remaining RAM segments for segment in ram_segments: checksum = self.save_segment(f, segment, checksum) total_segments += 1 # done writing segments self.append_checksum(f, checksum) image_length = f.tell() # kinda hacky: go back to the initial header and write the new segment count # that includes padding segments. This header is not checksummed f.seek(1) try: f.write(chr(total_segments)) except TypeError: # Python 3 f.write(bytes([total_segments])) if self.append_digest: # calculate the SHA256 of the whole file and append it f.seek(0) digest = hashlib.sha256() digest.update(f.read(image_length)) f.write(digest.digest()) with open(filename, 'wb') as real_file: real_file.write(f.getvalue()) def load_extended_header(self, load_file): def split_byte(n): return (n & 0x0F, (n >> 4) & 0x0F) fields = list(struct.unpack(self.EXTENDED_HEADER_STRUCT_FMT, load_file.read(16))) self.wp_pin = fields[0] # SPI pin drive stengths are two per byte self.clk_drv, self.q_drv = split_byte(fields[1]) self.d_drv, self.cs_drv = split_byte(fields[2]) self.hd_drv, self.wp_drv = split_byte(fields[3]) if fields[15] in [0, 1]: self.append_digest = (fields[15] == 1) else: raise RuntimeError("Invalid value for append_digest field (0x%02x). Should be 0 or 1.", fields[15]) # remaining fields in the middle should all be zero if any(f for f in fields[4:15] if f != 0): print("Warning: some reserved header fields have non-zero values. This image may be from a newer esptool.py?") ESP32ROM.BOOTLOADER_IMAGE = ESP32FirmwareImage class ESP32S2FirmwareImage(ESP32FirmwareImage): """ ESP32S2 Firmware Image almost exactly the same as ESP32FirmwareImage """ ROM_LOADER = ESP32S2ROM ESP32S2ROM.BOOTLOADER_IMAGE = ESP32S2FirmwareImage class ESP32S3BETA2FirmwareImage(ESP32FirmwareImage): """ ESP32S3 Firmware Image almost exactly the same as ESP32FirmwareImage """ ROM_LOADER = ESP32S3BETA2ROM ESP32S3BETA2ROM.BOOTLOADER_IMAGE = ESP32S3BETA2FirmwareImage class ESP32S3FirmwareImage(ESP32FirmwareImage): """ ESP32S3 Firmware Image almost exactly the same as ESP32FirmwareImage """ ROM_LOADER = ESP32S3ROM ESP32S3ROM.BOOTLOADER_IMAGE = ESP32S3FirmwareImage class ESP32C3FirmwareImage(ESP32FirmwareImage): """ ESP32C3 Firmware Image almost exactly the same as ESP32FirmwareImage """ ROM_LOADER = ESP32C3ROM ESP32C3ROM.BOOTLOADER_IMAGE = ESP32C3FirmwareImage class ESP32C6BETAFirmwareImage(ESP32FirmwareImage): """ ESP32C6 Firmware Image almost exactly the same as ESP32FirmwareImage """ ROM_LOADER = ESP32C6BETAROM ESP32C6BETAROM.BOOTLOADER_IMAGE = ESP32C6BETAFirmwareImage class ESP32H2BETA1FirmwareImage(ESP32FirmwareImage): """ ESP32H2 Firmware Image almost exactly the same as ESP32FirmwareImage """ ROM_LOADER = ESP32H2BETA1ROM ESP32H2BETA1ROM.BOOTLOADER_IMAGE = ESP32H2BETA1FirmwareImage class ESP32H2BETA2FirmwareImage(ESP32FirmwareImage): """ ESP32H2 Firmware Image almost exactly the same as ESP32FirmwareImage """ ROM_LOADER = ESP32H2BETA2ROM ESP32H2BETA2ROM.BOOTLOADER_IMAGE = ESP32H2BETA2FirmwareImage class ESP32C2FirmwareImage(ESP32FirmwareImage): """ ESP32C2 Firmware Image almost exactly the same as ESP32FirmwareImage """ ROM_LOADER = ESP32C2ROM def set_mmu_page_size(self, size): if size not in [16384, 32768, 65536]: raise FatalError("{} is not a valid page size.".format(size)) self.IROM_ALIGN = size ESP32C2ROM.BOOTLOADER_IMAGE = ESP32C2FirmwareImage class ELFFile(object): SEC_TYPE_PROGBITS = 0x01 SEC_TYPE_STRTAB = 0x03 SEC_TYPE_INITARRAY = 0x0e SEC_TYPE_FINIARRAY = 0x0f PROG_SEC_TYPES = (SEC_TYPE_PROGBITS, SEC_TYPE_INITARRAY, SEC_TYPE_FINIARRAY) LEN_SEC_HEADER = 0x28 SEG_TYPE_LOAD = 0x01 LEN_SEG_HEADER = 0x20 def __init__(self, name): # Load sections from the ELF file self.name = name with open(self.name, 'rb') as f: self._read_elf_file(f) def get_section(self, section_name): for s in self.sections: if s.name == section_name: return s raise ValueError("No section %s in ELF file" % section_name) def _read_elf_file(self, f): # read the ELF file header LEN_FILE_HEADER = 0x34 try: (ident, _type, machine, _version, self.entrypoint, _phoff, shoff, _flags, _ehsize, _phentsize, _phnum, shentsize, shnum, shstrndx) = struct.unpack("<16sHHLLLLLHHHHHH", f.read(LEN_FILE_HEADER)) except struct.error as e: raise FatalError("Failed to read a valid ELF header from %s: %s" % (self.name, e)) if byte(ident, 0) != 0x7f or ident[1:4] != b'ELF': raise FatalError("%s has invalid ELF magic header" % self.name) if machine not in [0x5e, 0xf3]: raise FatalError("%s does not appear to be an Xtensa or an RISCV ELF file. e_machine=%04x" % (self.name, machine)) if shentsize != self.LEN_SEC_HEADER: raise FatalError("%s has unexpected section header entry size 0x%x (not 0x%x)" % (self.name, shentsize, self.LEN_SEC_HEADER)) if shnum == 0: raise FatalError("%s has 0 section headers" % (self.name)) self._read_sections(f, shoff, shnum, shstrndx) self._read_segments(f, _phoff, _phnum, shstrndx) def _read_sections(self, f, section_header_offs, section_header_count, shstrndx): f.seek(section_header_offs) len_bytes = section_header_count * self.LEN_SEC_HEADER section_header = f.read(len_bytes) if len(section_header) == 0: raise FatalError("No section header found at offset %04x in ELF file." % section_header_offs) if len(section_header) != (len_bytes): raise FatalError("Only read 0x%x bytes from section header (expected 0x%x.) Truncated ELF file?" % (len(section_header), len_bytes)) # walk through the section header and extract all sections section_header_offsets = range(0, len(section_header), self.LEN_SEC_HEADER) def read_section_header(offs): name_offs, sec_type, _flags, lma, sec_offs, size = struct.unpack_from(" 0] self.sections = prog_sections def _read_segments(self, f, segment_header_offs, segment_header_count, shstrndx): f.seek(segment_header_offs) len_bytes = segment_header_count * self.LEN_SEG_HEADER segment_header = f.read(len_bytes) if len(segment_header) == 0: raise FatalError("No segment header found at offset %04x in ELF file." % segment_header_offs) if len(segment_header) != (len_bytes): raise FatalError("Only read 0x%x bytes from segment header (expected 0x%x.) Truncated ELF file?" % (len(segment_header), len_bytes)) # walk through the segment header and extract all segments segment_header_offsets = range(0, len(segment_header), self.LEN_SEG_HEADER) def read_segment_header(offs): seg_type, seg_offs, _vaddr, lma, size, _memsize, _flags, _align = struct.unpack_from(" 0] self.segments = prog_segments def sha256(self): # return SHA256 hash of the input ELF file sha256 = hashlib.sha256() with open(self.name, 'rb') as f: sha256.update(f.read()) return sha256.digest() def slip_reader(port, trace_function): """Generator to read SLIP packets from a serial port. Yields one full SLIP packet at a time, raises exception on timeout or invalid data. Designed to avoid too many calls to serial.read(1), which can bog down on slow systems. """ partial_packet = None in_escape = False successful_slip = False while True: waiting = port.inWaiting() read_bytes = port.read(1 if waiting == 0 else waiting) if read_bytes == b'': if partial_packet is None: # fail due to no data msg = "Serial data stream stopped: Possible serial noise or corruption." if successful_slip else "No serial data received." else: # fail during packet transfer msg = "Packet content transfer stopped (received {} bytes)".format(len(partial_packet)) trace_function(msg) raise FatalError(msg) trace_function("Read %d bytes: %s", len(read_bytes), HexFormatter(read_bytes)) for b in read_bytes: if type(b) is int: b = bytes([b]) # python 2/3 compat if partial_packet is None: # waiting for packet header if b == b'\xc0': partial_packet = b"" else: trace_function("Read invalid data: %s", HexFormatter(read_bytes)) trace_function("Remaining data in serial buffer: %s", HexFormatter(port.read(port.inWaiting()))) raise FatalError('Invalid head of packet (0x%s): Possible serial noise or corruption.' % hexify(b)) elif in_escape: # part-way through escape sequence in_escape = False if b == b'\xdc': partial_packet += b'\xc0' elif b == b'\xdd': partial_packet += b'\xdb' else: trace_function("Read invalid data: %s", HexFormatter(read_bytes)) trace_function("Remaining data in serial buffer: %s", HexFormatter(port.read(port.inWaiting()))) raise FatalError('Invalid SLIP escape (0xdb, 0x%s)' % (hexify(b))) elif b == b'\xdb': # start of escape sequence in_escape = True elif b == b'\xc0': # end of packet trace_function("Received full packet: %s", HexFormatter(partial_packet)) yield partial_packet partial_packet = None successful_slip = True else: # normal byte in packet partial_packet += b def arg_auto_int(x): return int(x, 0) def format_chip_name(c): """ Normalize chip name from user input """ c = c.lower().replace('-', '') if c == 'esp8684': # TODO: Delete alias, ESPTOOL-389 print('WARNING: Chip name ESP8684 is deprecated in favor of ESP32-C2 and will be removed in a future release. Using ESP32-C2 instead.') return 'esp32c2' return c def div_roundup(a, b): """ Return a/b rounded up to nearest integer, equivalent result to int(math.ceil(float(int(a)) / float(int(b))), only without possible floating point accuracy errors. """ return (int(a) + int(b) - 1) // int(b) def align_file_position(f, size): """ Align the position in the file to the next block of specified size """ align = (size - 1) - (f.tell() % size) f.seek(align, 1) def flash_size_bytes(size): """ Given a flash size of the type passed in args.flash_size (ie 512KB or 1MB) then return the size in bytes. """ if "MB" in size: return int(size[:size.index("MB")]) * 1024 * 1024 elif "KB" in size: return int(size[:size.index("KB")]) * 1024 else: raise FatalError("Unknown size %s" % size) def hexify(s, uppercase=True): format_str = '%02X' if uppercase else '%02x' if not PYTHON2: return ''.join(format_str % c for c in s) else: return ''.join(format_str % ord(c) for c in s) class HexFormatter(object): """ Wrapper class which takes binary data in its constructor and returns a hex string as it's __str__ method. This is intended for "lazy formatting" of trace() output in hex format. Avoids overhead (significant on slow computers) of generating long hex strings even if tracing is disabled. Note that this doesn't save any overhead if passed as an argument to "%", only when passed to trace() If auto_split is set (default), any long line (> 16 bytes) will be printed as separately indented lines, with ASCII decoding at the end of each line. """ def __init__(self, binary_string, auto_split=True): self._s = binary_string self._auto_split = auto_split def __str__(self): if self._auto_split and len(self._s) > 16: result = "" s = self._s while len(s) > 0: line = s[:16] ascii_line = "".join(c if (c == ' ' or (c in string.printable and c not in string.whitespace)) else '.' for c in line.decode('ascii', 'replace')) s = s[16:] result += "\n %-16s %-16s | %s" % (hexify(line[:8], False), hexify(line[8:], False), ascii_line) return result else: return hexify(self._s, False) def pad_to(data, alignment, pad_character=b'\xFF'): """ Pad to the next alignment boundary """ pad_mod = len(data) % alignment if pad_mod != 0: data += pad_character * (alignment - pad_mod) return data class FatalError(RuntimeError): """ Wrapper class for runtime errors that aren't caused by internal bugs, but by ESP ROM responses or input content. """ def __init__(self, message): RuntimeError.__init__(self, message) @staticmethod def WithResult(message, result): """ Return a fatal error object that appends the hex values of 'result' and its meaning as a string formatted argument. """ err_defs = { 0x101: 'Out of memory', 0x102: 'Invalid argument', 0x103: 'Invalid state', 0x104: 'Invalid size', 0x105: 'Requested resource not found', 0x106: 'Operation or feature not supported', 0x107: 'Operation timed out', 0x108: 'Received response was invalid', 0x109: 'CRC or checksum was invalid', 0x10A: 'Version was invalid', 0x10B: 'MAC address was invalid', # Flasher stub error codes 0xC000: 'Bad data length', 0xC100: 'Bad data checksum', 0xC200: 'Bad blocksize', 0xC300: 'Invalid command', 0xC400: 'Failed SPI operation', 0xC500: 'Failed SPI unlock', 0xC600: 'Not in flash mode', 0xC700: 'Inflate error', 0xC800: 'Not enough data', 0xC900: 'Too much data', 0xFF00: 'Command not implemented', } err_code = struct.unpack(">H", result[:2]) message += " (result was {}: {})".format(hexify(result), err_defs.get(err_code[0], 'Unknown result')) return FatalError(message) class NotImplementedInROMError(FatalError): """ Wrapper class for the error thrown when a particular ESP bootloader function is not implemented in the ROM bootloader. """ def __init__(self, bootloader, func): FatalError.__init__(self, "%s ROM does not support function %s." % (bootloader.CHIP_NAME, func.__name__)) class NotSupportedError(FatalError): def __init__(self, esp, function_name): FatalError.__init__(self, "Function %s is not supported for %s." % (function_name, esp.CHIP_NAME)) # "Operation" commands, executable at command line. One function each # # Each function takes either two args (, ) or a single # argument. class UnsupportedCommandError(RuntimeError): """ Wrapper class for when ROM loader returns an invalid command response. Usually this indicates the loader is running in Secure Download Mode. """ def __init__(self, esp, op): if esp.secure_download_mode: msg = "This command (0x%x) is not supported in Secure Download Mode" % op else: msg = "Invalid (unsupported) command 0x%x" % op RuntimeError.__init__(self, msg) def load_ram(esp, args): image = LoadFirmwareImage(esp.CHIP_NAME, args.filename) print('RAM boot...') for seg in image.segments: size = len(seg.data) print('Downloading %d bytes at %08x...' % (size, seg.addr), end=' ') sys.stdout.flush() esp.mem_begin(size, div_roundup(size, esp.ESP_RAM_BLOCK), esp.ESP_RAM_BLOCK, seg.addr) seq = 0 while len(seg.data) > 0: esp.mem_block(seg.data[0:esp.ESP_RAM_BLOCK], seq) seg.data = seg.data[esp.ESP_RAM_BLOCK:] seq += 1 print('done!') print('All segments done, executing at %08x' % image.entrypoint) esp.mem_finish(image.entrypoint) def read_mem(esp, args): print('0x%08x = 0x%08x' % (args.address, esp.read_reg(args.address))) def write_mem(esp, args): esp.write_reg(args.address, args.value, args.mask, 0) print('Wrote %08x, mask %08x to %08x' % (args.value, args.mask, args.address)) def dump_mem(esp, args): with open(args.filename, 'wb') as f: for i in range(args.size // 4): d = esp.read_reg(args.address + (i * 4)) f.write(struct.pack(b'> 16 args.flash_size = DETECTED_FLASH_SIZES.get(size_id) if args.flash_size is None: print('Warning: Could not auto-detect Flash size (FlashID=0x%x, SizeID=0x%x), defaulting to 4MB' % (flash_id, size_id)) args.flash_size = '4MB' else: print('Auto-detected Flash size:', args.flash_size) def _update_image_flash_params(esp, address, args, image): """ Modify the flash mode & size bytes if this looks like an executable bootloader image """ if len(image) < 8: return image # not long enough to be a bootloader image # unpack the (potential) image header magic, _, flash_mode, flash_size_freq = struct.unpack("BBBB", image[:4]) if address != esp.BOOTLOADER_FLASH_OFFSET: return image # not flashing bootloader offset, so don't modify this if (args.flash_mode, args.flash_freq, args.flash_size) == ('keep',) * 3: return image # all settings are 'keep', not modifying anything # easy check if this is an image: does it start with a magic byte? if magic != esp.ESP_IMAGE_MAGIC: print("Warning: Image file at 0x%x doesn't look like an image file, so not changing any flash settings." % address) return image # make sure this really is an image, and not just data that # starts with esp.ESP_IMAGE_MAGIC (mostly a problem for encrypted # images that happen to start with a magic byte try: test_image = esp.BOOTLOADER_IMAGE(io.BytesIO(image)) test_image.verify() except Exception: print("Warning: Image file at 0x%x is not a valid %s image, so not changing any flash settings." % (address, esp.CHIP_NAME)) return image if args.flash_mode != 'keep': flash_mode = {'qio': 0, 'qout': 1, 'dio': 2, 'dout': 3}[args.flash_mode] flash_freq = flash_size_freq & 0x0F if args.flash_freq != 'keep': flash_freq = esp.parse_flash_freq_arg(args.flash_freq) flash_size = flash_size_freq & 0xF0 if args.flash_size != 'keep': flash_size = esp.parse_flash_size_arg(args.flash_size) flash_params = struct.pack(b'BB', flash_mode, flash_size + flash_freq) if flash_params != image[2:4]: print('Flash params set to 0x%04x' % struct.unpack(">H", flash_params)) image = image[0:2] + flash_params + image[4:] return image def write_flash(esp, args): # set args.compress based on default behaviour: # -> if either --compress or --no-compress is set, honour that # -> otherwise, set --compress unless --no-stub is set if args.compress is None and not args.no_compress: args.compress = not args.no_stub # In case we have encrypted files to write, we first do few sanity checks before actual flash if args.encrypt or args.encrypt_files is not None: do_write = True if not esp.secure_download_mode: if esp.get_encrypted_download_disabled(): raise FatalError("This chip has encrypt functionality in UART download mode disabled. " "This is the Flash Encryption configuration for Production mode instead of Development mode.") crypt_cfg_efuse = esp.get_flash_crypt_config() if crypt_cfg_efuse is not None and crypt_cfg_efuse != 0xF: print('Unexpected FLASH_CRYPT_CONFIG value: 0x%x' % (crypt_cfg_efuse)) do_write = False enc_key_valid = esp.is_flash_encryption_key_valid() if not enc_key_valid: print('Flash encryption key is not programmed') do_write = False # Determine which files list contain the ones to encrypt files_to_encrypt = args.addr_filename if args.encrypt else args.encrypt_files for address, argfile in files_to_encrypt: if address % esp.FLASH_ENCRYPTED_WRITE_ALIGN: print("File %s address 0x%x is not %d byte aligned, can't flash encrypted" % (argfile.name, address, esp.FLASH_ENCRYPTED_WRITE_ALIGN)) do_write = False if not do_write and not args.ignore_flash_encryption_efuse_setting: raise FatalError("Can't perform encrypted flash write, consult Flash Encryption documentation for more information") # verify file sizes fit in flash if args.flash_size != 'keep': # TODO: check this even with 'keep' flash_end = flash_size_bytes(args.flash_size) for address, argfile in args.addr_filename: argfile.seek(0, os.SEEK_END) if address + argfile.tell() > flash_end: raise FatalError(("File %s (length %d) at offset %d will not fit in %d bytes of flash. " "Use --flash_size argument, or change flashing address.") % (argfile.name, argfile.tell(), address, flash_end)) argfile.seek(0) if args.erase_all: erase_flash(esp, args) else: for address, argfile in args.addr_filename: argfile.seek(0, os.SEEK_END) write_end = address + argfile.tell() argfile.seek(0) bytes_over = address % esp.FLASH_SECTOR_SIZE if bytes_over != 0: print("WARNING: Flash address {:#010x} is not aligned to a {:#x} byte flash sector. " "{:#x} bytes before this address will be erased." .format(address, esp.FLASH_SECTOR_SIZE, bytes_over)) # Print the address range of to-be-erased flash memory region print("Flash will be erased from {:#010x} to {:#010x}..." .format(address - bytes_over, div_roundup(write_end, esp.FLASH_SECTOR_SIZE) * esp.FLASH_SECTOR_SIZE - 1)) """ Create a list describing all the files we have to flash. Each entry holds an "encrypt" flag marking whether the file needs encryption or not. This list needs to be sorted. First, append to each entry of our addr_filename list the flag args.encrypt For example, if addr_filename is [(0x1000, "partition.bin"), (0x8000, "bootloader")], all_files will be [(0x1000, "partition.bin", args.encrypt), (0x8000, "bootloader", args.encrypt)], where, of course, args.encrypt is either True or False """ all_files = [(offs, filename, args.encrypt) for (offs, filename) in args.addr_filename] """Now do the same with encrypt_files list, if defined. In this case, the flag is True """ if args.encrypt_files is not None: encrypted_files_flag = [(offs, filename, True) for (offs, filename) in args.encrypt_files] # Concatenate both lists and sort them. # As both list are already sorted, we could simply do a merge instead, # but for the sake of simplicity and because the lists are very small, # let's use sorted. all_files = sorted(all_files + encrypted_files_flag, key=lambda x: x[0]) for address, argfile, encrypted in all_files: compress = args.compress # Check whether we can compress the current file before flashing if compress and encrypted: print('\nWARNING: - compress and encrypt options are mutually exclusive ') print('Will flash %s uncompressed' % argfile.name) compress = False if args.no_stub: print('Erasing flash...') image = pad_to(argfile.read(), esp.FLASH_ENCRYPTED_WRITE_ALIGN if encrypted else 4) if len(image) == 0: print('WARNING: File %s is empty' % argfile.name) continue image = _update_image_flash_params(esp, address, args, image) calcmd5 = hashlib.md5(image).hexdigest() uncsize = len(image) if compress: uncimage = image image = zlib.compress(uncimage, 9) # Decompress the compressed binary a block at a time, to dynamically calculate the # timeout based on the real write size decompress = zlib.decompressobj() blocks = esp.flash_defl_begin(uncsize, len(image), address) else: blocks = esp.flash_begin(uncsize, address, begin_rom_encrypted=encrypted) argfile.seek(0) # in case we need it again seq = 0 bytes_sent = 0 # bytes sent on wire bytes_written = 0 # bytes written to flash t = time.time() timeout = DEFAULT_TIMEOUT while len(image) > 0: print_overwrite('Writing at 0x%08x... (%d %%)' % (address + bytes_written, 100 * (seq + 1) // blocks)) sys.stdout.flush() block = image[0:esp.FLASH_WRITE_SIZE] if compress: # feeding each compressed block into the decompressor lets us see block-by-block how much will be written block_uncompressed = len(decompress.decompress(block)) bytes_written += block_uncompressed block_timeout = max(DEFAULT_TIMEOUT, timeout_per_mb(ERASE_WRITE_TIMEOUT_PER_MB, block_uncompressed)) if not esp.IS_STUB: timeout = block_timeout # ROM code writes block to flash before ACKing esp.flash_defl_block(block, seq, timeout=timeout) if esp.IS_STUB: timeout = block_timeout # Stub ACKs when block is received, then writes to flash while receiving the block after it else: # Pad the last block block = block + b'\xff' * (esp.FLASH_WRITE_SIZE - len(block)) if encrypted: esp.flash_encrypt_block(block, seq) else: esp.flash_block(block, seq) bytes_written += len(block) bytes_sent += len(block) image = image[esp.FLASH_WRITE_SIZE:] seq += 1 if esp.IS_STUB: # Stub only writes each block to flash after 'ack'ing the receive, so do a final dummy operation which will # not be 'ack'ed until the last block has actually been written out to flash esp.read_reg(ESPLoader.CHIP_DETECT_MAGIC_REG_ADDR, timeout=timeout) t = time.time() - t speed_msg = "" if compress: if t > 0.0: speed_msg = " (effective %.1f kbit/s)" % (uncsize / t * 8 / 1000) print_overwrite('Wrote %d bytes (%d compressed) at 0x%08x in %.1f seconds%s...' % (uncsize, bytes_sent, address, t, speed_msg), last_line=True) else: if t > 0.0: speed_msg = " (%.1f kbit/s)" % (bytes_written / t * 8 / 1000) print_overwrite('Wrote %d bytes at 0x%08x in %.1f seconds%s...' % (bytes_written, address, t, speed_msg), last_line=True) if not encrypted and not esp.secure_download_mode: try: res = esp.flash_md5sum(address, uncsize) if res != calcmd5: print('File md5: %s' % calcmd5) print('Flash md5: %s' % res) print('MD5 of 0xFF is %s' % (hashlib.md5(b'\xFF' * uncsize).hexdigest())) raise FatalError("MD5 of file does not match data in flash!") else: print('Hash of data verified.') except NotImplementedInROMError: pass print('\nLeaving...') if esp.IS_STUB: # skip sending flash_finish to ROM loader here, # as it causes the loader to exit and run user code esp.flash_begin(0, 0) # Get the "encrypted" flag for the last file flashed # Note: all_files list contains triplets like: # (address: Integer, filename: String, encrypted: Boolean) last_file_encrypted = all_files[-1][2] # Check whether the last file flashed was compressed or not if args.compress and not last_file_encrypted: esp.flash_defl_finish(False) else: esp.flash_finish(False) if args.verify: print('Verifying just-written flash...') print('(This option is deprecated, flash contents are now always read back after flashing.)') # If some encrypted files have been flashed print a warning saying that we won't check them if args.encrypt or args.encrypt_files is not None: print('WARNING: - cannot verify encrypted files, they will be ignored') # Call verify_flash function only if there at least one non-encrypted file flashed if not args.encrypt: verify_flash(esp, args) def image_info(args): if args.chip == "auto": print("WARNING: --chip not specified, defaulting to ESP8266.") image = LoadFirmwareImage(args.chip, args.filename) print('Image version: %d' % image.version) print('Entry point: %08x' % image.entrypoint if image.entrypoint != 0 else 'Entry point not set') print('%d segments' % len(image.segments)) print() idx = 0 for seg in image.segments: idx += 1 segs = seg.get_memory_type(image) seg_name = ",".join(segs) print('Segment %d: %r [%s]' % (idx, seg, seg_name)) calc_checksum = image.calculate_checksum() print('Checksum: %02x (%s)' % (image.checksum, 'valid' if image.checksum == calc_checksum else 'invalid - calculated %02x' % calc_checksum)) try: digest_msg = 'Not appended' if image.append_digest: is_valid = image.stored_digest == image.calc_digest digest_msg = "%s (%s)" % (hexify(image.calc_digest).lower(), "valid" if is_valid else "invalid") print('Validation Hash: %s' % digest_msg) except AttributeError: pass # ESP8266 image has no append_digest field def make_image(args): image = ESP8266ROMFirmwareImage() if len(args.segfile) == 0: raise FatalError('No segments specified') if len(args.segfile) != len(args.segaddr): raise FatalError('Number of specified files does not match number of specified addresses') for (seg, addr) in zip(args.segfile, args.segaddr): with open(seg, 'rb') as f: data = f.read() image.segments.append(ImageSegment(addr, data)) image.entrypoint = args.entrypoint image.save(args.output) def elf2image(args): e = ELFFile(args.input) if args.chip == 'auto': # Default to ESP8266 for backwards compatibility args.chip = 'esp8266' print("Creating {} image...".format(args.chip)) if args.chip == 'esp32': image = ESP32FirmwareImage() if args.secure_pad: image.secure_pad = '1' elif args.secure_pad_v2: image.secure_pad = '2' elif args.chip == 'esp32s2': image = ESP32S2FirmwareImage() if args.secure_pad_v2: image.secure_pad = '2' elif args.chip == 'esp32s3beta2': image = ESP32S3BETA2FirmwareImage() if args.secure_pad_v2: image.secure_pad = '2' elif args.chip == 'esp32s3': image = ESP32S3FirmwareImage() if args.secure_pad_v2: image.secure_pad = '2' elif args.chip == 'esp32c3': image = ESP32C3FirmwareImage() if args.secure_pad_v2: image.secure_pad = '2' elif args.chip == 'esp32c6beta': image = ESP32C6BETAFirmwareImage() if args.secure_pad_v2: image.secure_pad = '2' elif args.chip == 'esp32h2beta1': image = ESP32H2BETA1FirmwareImage() if args.secure_pad_v2: image.secure_pad = '2' elif args.chip == 'esp32h2beta2': image = ESP32H2BETA2FirmwareImage() if args.secure_pad_v2: image.secure_pad = '2' elif args.chip == 'esp32c2': image = ESP32C2FirmwareImage() if args.secure_pad_v2: image.secure_pad = '2' elif args.version == '1': # ESP8266 image = ESP8266ROMFirmwareImage() elif args.version == '2': image = ESP8266V2FirmwareImage() else: image = ESP8266V3FirmwareImage() image.entrypoint = e.entrypoint image.flash_mode = {'qio': 0, 'qout': 1, 'dio': 2, 'dout': 3}[args.flash_mode] if args.chip != 'esp8266': image.min_rev = int(args.min_rev) if args.flash_mmu_page_size: image.set_mmu_page_size(flash_size_bytes(args.flash_mmu_page_size)) # ELFSection is a subclass of ImageSegment, so can use interchangeably image.segments = e.segments if args.use_segments else e.sections image.flash_size_freq = image.ROM_LOADER.parse_flash_size_arg(args.flash_size) image.flash_size_freq += image.ROM_LOADER.parse_flash_freq_arg(args.flash_freq) if args.elf_sha256_offset: image.elf_sha256 = e.sha256() image.elf_sha256_offset = args.elf_sha256_offset before = len(image.segments) image.merge_adjacent_segments() if len(image.segments) != before: delta = before - len(image.segments) print("Merged %d ELF section%s" % (delta, "s" if delta > 1 else "")) image.verify() if args.output is None: args.output = image.default_output_name(args.input) image.save(args.output) print("Successfully created {} image.".format(args.chip)) def read_mac(esp, args): mac = esp.read_mac() def print_mac(label, mac): print('%s: %s' % (label, ':'.join(map(lambda x: '%02x' % x, mac)))) print_mac("MAC", mac) def chip_id(esp, args): try: chipid = esp.chip_id() print('Chip ID: 0x%08x' % chipid) except NotSupportedError: print('Warning: %s has no Chip ID. Reading MAC instead.' % esp.CHIP_NAME) read_mac(esp, args) def erase_flash(esp, args): print('Erasing flash (this may take a while)...') t = time.time() esp.erase_flash() print('Chip erase completed successfully in %.1fs' % (time.time() - t)) def erase_region(esp, args): print('Erasing region (may be slow depending on size)...') t = time.time() esp.erase_region(args.address, args.size) print('Erase completed successfully in %.1f seconds.' % (time.time() - t)) def run(esp, args): esp.run() def flash_id(esp, args): flash_id = esp.flash_id() print('Manufacturer: %02x' % (flash_id & 0xff)) flid_lowbyte = (flash_id >> 16) & 0xFF print('Device: %02x%02x' % ((flash_id >> 8) & 0xff, flid_lowbyte)) print('Detected flash size: %s' % (DETECTED_FLASH_SIZES.get(flid_lowbyte, "Unknown"))) def read_flash(esp, args): if args.no_progress: flash_progress = None else: def flash_progress(progress, length): msg = '%d (%d %%)' % (progress, progress * 100.0 / length) padding = '\b' * len(msg) if progress == length: padding = '\n' sys.stdout.write(msg + padding) sys.stdout.flush() t = time.time() data = esp.read_flash(args.address, args.size, flash_progress) t = time.time() - t print_overwrite('Read %d bytes at 0x%x in %.1f seconds (%.1f kbit/s)...' % (len(data), args.address, t, len(data) / t * 8 / 1000), last_line=True) with open(args.filename, 'wb') as f: f.write(data) def verify_flash(esp, args): differences = False for address, argfile in args.addr_filename: image = pad_to(argfile.read(), 4) argfile.seek(0) # rewind in case we need it again image = _update_image_flash_params(esp, address, args, image) image_size = len(image) print('Verifying 0x%x (%d) bytes @ 0x%08x in flash against %s...' % (image_size, image_size, address, argfile.name)) # Try digest first, only read if there are differences. digest = esp.flash_md5sum(address, image_size) expected_digest = hashlib.md5(image).hexdigest() if digest == expected_digest: print('-- verify OK (digest matched)') continue else: differences = True if getattr(args, 'diff', 'no') != 'yes': print('-- verify FAILED (digest mismatch)') continue flash = esp.read_flash(address, image_size) assert flash != image diff = [i for i in range(image_size) if flash[i] != image[i]] print('-- verify FAILED: %d differences, first @ 0x%08x' % (len(diff), address + diff[0])) for d in diff: flash_byte = flash[d] image_byte = image[d] if PYTHON2: flash_byte = ord(flash_byte) image_byte = ord(image_byte) print(' %08x %02x %02x' % (address + d, flash_byte, image_byte)) if differences: raise FatalError("Verify failed.") def read_flash_status(esp, args): print('Status value: 0x%04x' % esp.read_status(args.bytes)) def write_flash_status(esp, args): fmt = "0x%%0%dx" % (args.bytes * 2) args.value = args.value & ((1 << (args.bytes * 8)) - 1) print(('Initial flash status: ' + fmt) % esp.read_status(args.bytes)) print(('Setting flash status: ' + fmt) % args.value) esp.write_status(args.value, args.bytes, args.non_volatile) print(('After flash status: ' + fmt) % esp.read_status(args.bytes)) def get_security_info(esp, args): si = esp.get_security_info() # TODO: better display and tests print('Flags: {:#010x} ({})'.format(si["flags"], bin(si["flags"]))) print('Flash_Crypt_Cnt: {:#x}'.format(si["flash_crypt_cnt"])) print('Key_Purposes: {}'.format(si["key_purposes"])) if si["chip_id"] is not None and si["api_version"] is not None: print('Chip_ID: {}'.format(si["chip_id"])) print('Api_Version: {}'.format(si["api_version"])) def merge_bin(args): try: chip_class = _chip_to_rom_loader(args.chip) except KeyError: msg = "Please specify the chip argument" if args.chip == "auto" else "Invalid chip choice: '{}'".format(args.chip) msg = msg + " (choose from {})".format(', '.join(SUPPORTED_CHIPS)) raise FatalError(msg) # sort the files by offset. The AddrFilenamePairAction has already checked for overlap input_files = sorted(args.addr_filename, key=lambda x: x[0]) if not input_files: raise FatalError("No input files specified") first_addr = input_files[0][0] if first_addr < args.target_offset: raise FatalError("Output file target offset is 0x%x. Input file offset 0x%x is before this." % (args.target_offset, first_addr)) if args.format != 'raw': raise FatalError("This version of esptool only supports the 'raw' output format") with open(args.output, 'wb') as of: def pad_to(flash_offs): # account for output file offset if there is any of.write(b'\xFF' * (flash_offs - args.target_offset - of.tell())) for addr, argfile in input_files: pad_to(addr) image = argfile.read() image = _update_image_flash_params(chip_class, addr, args, image) of.write(image) if args.fill_flash_size: pad_to(flash_size_bytes(args.fill_flash_size)) print("Wrote 0x%x bytes to file %s, ready to flash to offset 0x%x" % (of.tell(), args.output, args.target_offset)) def version(args): print(__version__) # # End of operations functions # def main(argv=None, esp=None): """ Main function for esptool argv - Optional override for default arguments parsing (that uses sys.argv), can be a list of custom arguments as strings. Arguments and their values need to be added as individual items to the list e.g. "-b 115200" thus becomes ['-b', '115200']. esp - Optional override of the connected device previously returned by get_default_connected_device() """ external_esp = esp is not None parser = argparse.ArgumentParser(description='esptool.py v%s - Espressif chips ROM Bootloader Utility' % __version__, prog='esptool') parser.add_argument('--chip', '-c', help='Target chip type', type=format_chip_name, # support ESP32-S2, etc. choices=['auto'] + SUPPORTED_CHIPS, default=os.environ.get('ESPTOOL_CHIP', 'auto')) parser.add_argument( '--port', '-p', help='Serial port device', default=os.environ.get('ESPTOOL_PORT', None)) parser.add_argument( '--baud', '-b', help='Serial port baud rate used when flashing/reading', type=arg_auto_int, default=os.environ.get('ESPTOOL_BAUD', ESPLoader.ESP_ROM_BAUD)) parser.add_argument( '--before', help='What to do before connecting to the chip', choices=['default_reset', 'usb_reset', 'no_reset', 'no_reset_no_sync'], default=os.environ.get('ESPTOOL_BEFORE', 'default_reset')) parser.add_argument( '--after', '-a', help='What to do after esptool.py is finished', choices=['hard_reset', 'soft_reset', 'no_reset', 'no_reset_stub'], default=os.environ.get('ESPTOOL_AFTER', 'hard_reset')) parser.add_argument( '--no-stub', help="Disable launching the flasher stub, only talk to ROM bootloader. Some features will not be available.", action='store_true') parser.add_argument( '--trace', '-t', help="Enable trace-level output of esptool.py interactions.", action='store_true') parser.add_argument( '--override-vddsdio', help="Override ESP32 VDDSDIO internal voltage regulator (use with care)", choices=ESP32ROM.OVERRIDE_VDDSDIO_CHOICES, nargs='?') parser.add_argument( '--connect-attempts', help=('Number of attempts to connect, negative or 0 for infinite. ' 'Default: %d.' % DEFAULT_CONNECT_ATTEMPTS), type=int, default=os.environ.get('ESPTOOL_CONNECT_ATTEMPTS', DEFAULT_CONNECT_ATTEMPTS)) subparsers = parser.add_subparsers( dest='operation', help='Run esptool {command} -h for additional help') def add_spi_connection_arg(parent): parent.add_argument('--spi-connection', '-sc', help='ESP32-only argument. Override default SPI Flash connection. ' 'Value can be SPI, HSPI or a comma-separated list of 5 I/O numbers to use for SPI flash (CLK,Q,D,HD,CS).', action=SpiConnectionAction) parser_load_ram = subparsers.add_parser( 'load_ram', help='Download an image to RAM and execute') parser_load_ram.add_argument('filename', help='Firmware image') parser_dump_mem = subparsers.add_parser( 'dump_mem', help='Dump arbitrary memory to disk') parser_dump_mem.add_argument('address', help='Base address', type=arg_auto_int) parser_dump_mem.add_argument('size', help='Size of region to dump', type=arg_auto_int) parser_dump_mem.add_argument('filename', help='Name of binary dump') parser_read_mem = subparsers.add_parser( 'read_mem', help='Read arbitrary memory location') parser_read_mem.add_argument('address', help='Address to read', type=arg_auto_int) parser_write_mem = subparsers.add_parser( 'write_mem', help='Read-modify-write to arbitrary memory location') parser_write_mem.add_argument('address', help='Address to write', type=arg_auto_int) parser_write_mem.add_argument('value', help='Value', type=arg_auto_int) parser_write_mem.add_argument('mask', help='Mask of bits to write', type=arg_auto_int, nargs='?', default='0xFFFFFFFF') def add_spi_flash_subparsers(parent, allow_keep, auto_detect): """ Add common parser arguments for SPI flash properties """ extra_keep_args = ['keep'] if allow_keep else [] if auto_detect and allow_keep: extra_fs_message = ", detect, or keep" elif auto_detect: extra_fs_message = ", or detect" elif allow_keep: extra_fs_message = ", or keep" else: extra_fs_message = "" parent.add_argument('--flash_freq', '-ff', help='SPI Flash frequency', choices=extra_keep_args + ['80m', '60m', '48m', '40m', '30m', '26m', '24m', '20m', '16m', '15m', '12m'], default=os.environ.get('ESPTOOL_FF', 'keep' if allow_keep else '40m')) parent.add_argument('--flash_mode', '-fm', help='SPI Flash mode', choices=extra_keep_args + ['qio', 'qout', 'dio', 'dout'], default=os.environ.get('ESPTOOL_FM', 'keep' if allow_keep else 'qio')) parent.add_argument('--flash_size', '-fs', help='SPI Flash size in MegaBytes (1MB, 2MB, 4MB, 8MB, 16MB, 32MB, 64MB, 128MB)' ' plus ESP8266-only (256KB, 512KB, 2MB-c1, 4MB-c1)' + extra_fs_message, action=FlashSizeAction, auto_detect=auto_detect, default=os.environ.get('ESPTOOL_FS', 'keep' if allow_keep else '1MB')) add_spi_connection_arg(parent) parser_write_flash = subparsers.add_parser( 'write_flash', help='Write a binary blob to flash') parser_write_flash.add_argument('addr_filename', metavar='
', help='Address followed by binary filename, separated by space', action=AddrFilenamePairAction) parser_write_flash.add_argument('--erase-all', '-e', help='Erase all regions of flash (not just write areas) before programming', action="store_true") add_spi_flash_subparsers(parser_write_flash, allow_keep=True, auto_detect=True) parser_write_flash.add_argument('--no-progress', '-p', help='Suppress progress output', action="store_true") parser_write_flash.add_argument('--verify', help='Verify just-written data on flash ' '(mostly superfluous, data is read back during flashing)', action='store_true') parser_write_flash.add_argument('--encrypt', help='Apply flash encryption when writing data (required correct efuse settings)', action='store_true') # In order to not break backward compatibility, our list of encrypted files to flash is a new parameter parser_write_flash.add_argument('--encrypt-files', metavar='
', help='Files to be encrypted on the flash. Address followed by binary filename, separated by space.', action=AddrFilenamePairAction) parser_write_flash.add_argument('--ignore-flash-encryption-efuse-setting', help='Ignore flash encryption efuse settings ', action='store_true') compress_args = parser_write_flash.add_mutually_exclusive_group(required=False) compress_args.add_argument('--compress', '-z', help='Compress data in transfer (default unless --no-stub is specified)', action="store_true", default=None) compress_args.add_argument('--no-compress', '-u', help='Disable data compression during transfer (default if --no-stub is specified)', action="store_true") subparsers.add_parser( 'run', help='Run application code in flash') parser_image_info = subparsers.add_parser( 'image_info', help='Dump headers from an application image') parser_image_info.add_argument('filename', help='Image file to parse') parser_make_image = subparsers.add_parser( 'make_image', help='Create an application image from binary files') parser_make_image.add_argument('output', help='Output image file') parser_make_image.add_argument('--segfile', '-f', action='append', help='Segment input file') parser_make_image.add_argument('--segaddr', '-a', action='append', help='Segment base address', type=arg_auto_int) parser_make_image.add_argument('--entrypoint', '-e', help='Address of entry point', type=arg_auto_int, default=0) parser_elf2image = subparsers.add_parser( 'elf2image', help='Create an application image from ELF file') parser_elf2image.add_argument('input', help='Input ELF file') parser_elf2image.add_argument('--output', '-o', help='Output filename prefix (for version 1 image), or filename (for version 2 single image)', type=str) parser_elf2image.add_argument('--version', '-e', help='Output image version', choices=['1', '2', '3'], default='1') parser_elf2image.add_argument('--min-rev', '-r', help='Minimum chip revision', choices=['0', '1', '2', '3'], default='0') parser_elf2image.add_argument('--secure-pad', action='store_true', help='Pad image so once signed it will end on a 64KB boundary. For Secure Boot v1 images only.') parser_elf2image.add_argument('--secure-pad-v2', action='store_true', help='Pad image to 64KB, so once signed its signature sector will start at the next 64K block. ' 'For Secure Boot v2 images only.') parser_elf2image.add_argument('--elf-sha256-offset', help='If set, insert SHA256 hash (32 bytes) of the input ELF file at specified offset in the binary.', type=arg_auto_int, default=None) parser_elf2image.add_argument('--use_segments', help='If set, ELF segments will be used instead of ELF sections to genereate the image.', action='store_true') parser_elf2image.add_argument('--flash-mmu-page-size', help="Change flash MMU page size.", choices=['64KB', '32KB', '16KB']) add_spi_flash_subparsers(parser_elf2image, allow_keep=False, auto_detect=False) subparsers.add_parser( 'read_mac', help='Read MAC address from OTP ROM') subparsers.add_parser( 'chip_id', help='Read Chip ID from OTP ROM') parser_flash_id = subparsers.add_parser( 'flash_id', help='Read SPI flash manufacturer and device ID') add_spi_connection_arg(parser_flash_id) parser_read_status = subparsers.add_parser( 'read_flash_status', help='Read SPI flash status register') add_spi_connection_arg(parser_read_status) parser_read_status.add_argument('--bytes', help='Number of bytes to read (1-3)', type=int, choices=[1, 2, 3], default=2) parser_write_status = subparsers.add_parser( 'write_flash_status', help='Write SPI flash status register') add_spi_connection_arg(parser_write_status) parser_write_status.add_argument('--non-volatile', help='Write non-volatile bits (use with caution)', action='store_true') parser_write_status.add_argument('--bytes', help='Number of status bytes to write (1-3)', type=int, choices=[1, 2, 3], default=2) parser_write_status.add_argument('value', help='New value', type=arg_auto_int) parser_read_flash = subparsers.add_parser( 'read_flash', help='Read SPI flash content') add_spi_connection_arg(parser_read_flash) parser_read_flash.add_argument('address', help='Start address', type=arg_auto_int) parser_read_flash.add_argument('size', help='Size of region to dump', type=arg_auto_int) parser_read_flash.add_argument('filename', help='Name of binary dump') parser_read_flash.add_argument('--no-progress', '-p', help='Suppress progress output', action="store_true") parser_verify_flash = subparsers.add_parser( 'verify_flash', help='Verify a binary blob against flash') parser_verify_flash.add_argument('addr_filename', help='Address and binary file to verify there, separated by space', action=AddrFilenamePairAction) parser_verify_flash.add_argument('--diff', '-d', help='Show differences', choices=['no', 'yes'], default='no') add_spi_flash_subparsers(parser_verify_flash, allow_keep=True, auto_detect=True) parser_erase_flash = subparsers.add_parser( 'erase_flash', help='Perform Chip Erase on SPI flash') add_spi_connection_arg(parser_erase_flash) parser_erase_region = subparsers.add_parser( 'erase_region', help='Erase a region of the flash') add_spi_connection_arg(parser_erase_region) parser_erase_region.add_argument('address', help='Start address (must be multiple of 4096)', type=arg_auto_int) parser_erase_region.add_argument('size', help='Size of region to erase (must be multiple of 4096)', type=arg_auto_int) parser_merge_bin = subparsers.add_parser( 'merge_bin', help='Merge multiple raw binary files into a single file for later flashing') parser_merge_bin.add_argument('--output', '-o', help='Output filename', type=str, required=True) parser_merge_bin.add_argument('--format', '-f', help='Format of the output file', choices='raw', default='raw') # for future expansion add_spi_flash_subparsers(parser_merge_bin, allow_keep=True, auto_detect=False) parser_merge_bin.add_argument('--target-offset', '-t', help='Target offset where the output file will be flashed', type=arg_auto_int, default=0) parser_merge_bin.add_argument('--fill-flash-size', help='If set, the final binary file will be padded with FF ' 'bytes up to this flash size.', action=FlashSizeAction) parser_merge_bin.add_argument('addr_filename', metavar='
', help='Address followed by binary filename, separated by space', action=AddrFilenamePairAction) subparsers.add_parser('get_security_info', help='Get some security-related data') subparsers.add_parser('version', help='Print esptool version') # internal sanity check - every operation matches a module function of the same name for operation in subparsers.choices.keys(): assert operation in globals(), "%s should be a module function" % operation argv = expand_file_arguments(argv or sys.argv[1:]) args = parser.parse_args(argv) print('esptool.py v%s' % __version__) # operation function can take 1 arg (args), 2 args (esp, arg) # or be a member function of the ESPLoader class. if args.operation is None: parser.print_help() sys.exit(1) # Forbid the usage of both --encrypt, which means encrypt all the given files, # and --encrypt-files, which represents the list of files to encrypt. # The reason is that allowing both at the same time increases the chances of # having contradictory lists (e.g. one file not available in one of list). if args.operation == "write_flash" and args.encrypt and args.encrypt_files is not None: raise FatalError("Options --encrypt and --encrypt-files must not be specified at the same time.") operation_func = globals()[args.operation] if PYTHON2: # This function is depreciated in Python3 operation_args = inspect.getargspec(operation_func).args else: operation_args = inspect.getfullargspec(operation_func).args if operation_args[0] == 'esp': # operation function takes an ESPLoader connection object if args.before != "no_reset_no_sync": initial_baud = min(ESPLoader.ESP_ROM_BAUD, args.baud) # don't sync faster than the default baud rate else: initial_baud = args.baud if args.port is None: ser_list = get_port_list() print("Found %d serial ports" % len(ser_list)) else: ser_list = [args.port] esp = esp or get_default_connected_device(ser_list, port=args.port, connect_attempts=args.connect_attempts, initial_baud=initial_baud, chip=args.chip, trace=args.trace, before=args.before) if esp is None: raise FatalError("Could not connect to an Espressif device on any of the %d available serial ports." % len(ser_list)) if esp.secure_download_mode: print("Chip is %s in Secure Download Mode" % esp.CHIP_NAME) else: print("Chip is %s" % (esp.get_chip_description())) print("Features: %s" % ", ".join(esp.get_chip_features())) print("Crystal is %dMHz" % esp.get_crystal_freq()) read_mac(esp, args) if not args.no_stub: if esp.secure_download_mode: print("WARNING: Stub loader is not supported in Secure Download Mode, setting --no-stub") args.no_stub = True elif not esp.IS_STUB and esp.stub_is_disabled: print("WARNING: Stub loader has been disabled for compatibility, setting --no-stub") args.no_stub = True else: esp = esp.run_stub() if args.override_vddsdio: esp.override_vddsdio(args.override_vddsdio) if args.baud > initial_baud: try: esp.change_baud(args.baud) except NotImplementedInROMError: print("WARNING: ROM doesn't support changing baud rate. Keeping initial baud rate %d" % initial_baud) # override common SPI flash parameter stuff if configured to do so if hasattr(args, "spi_connection") and args.spi_connection is not None: if esp.CHIP_NAME != "ESP32": raise FatalError("Chip %s does not support --spi-connection option." % esp.CHIP_NAME) print("Configuring SPI flash mode...") esp.flash_spi_attach(args.spi_connection) elif args.no_stub: print("Enabling default SPI flash mode...") # ROM loader doesn't enable flash unless we explicitly do it esp.flash_spi_attach(0) # XMC chip startup sequence XMC_VENDOR_ID = 0x20 def is_xmc_chip_strict(): id = esp.flash_id() rdid = ((id & 0xff) << 16) | ((id >> 16) & 0xff) | (id & 0xff00) vendor_id = ((rdid >> 16) & 0xFF) mfid = ((rdid >> 8) & 0xFF) cpid = (rdid & 0xFF) if vendor_id != XMC_VENDOR_ID: return False matched = False if mfid == 0x40: if cpid >= 0x13 and cpid <= 0x20: matched = True elif mfid == 0x41: if cpid >= 0x17 and cpid <= 0x20: matched = True elif mfid == 0x50: if cpid >= 0x15 and cpid <= 0x16: matched = True return matched def flash_xmc_startup(): # If the RDID value is a valid XMC one, may skip the flow fast_check = True if fast_check and is_xmc_chip_strict(): return # Successful XMC flash chip boot-up detected by RDID, skipping. sfdp_mfid_addr = 0x10 mf_id = esp.read_spiflash_sfdp(sfdp_mfid_addr, 8) if mf_id != XMC_VENDOR_ID: # Non-XMC chip detected by SFDP Read, skipping. return print("WARNING: XMC flash chip boot-up failure detected! Running XMC25QHxxC startup flow") esp.run_spiflash_command(0xB9) # Enter DPD esp.run_spiflash_command(0x79) # Enter UDPD esp.run_spiflash_command(0xFF) # Exit UDPD time.sleep(0.002) # Delay tXUDPD esp.run_spiflash_command(0xAB) # Release Power-Down time.sleep(0.00002) # Check for success if not is_xmc_chip_strict(): print("WARNING: XMC flash boot-up fix failed.") print("XMC flash chip boot-up fix successful!") # Check flash chip connection if not esp.secure_download_mode: try: flash_id = esp.flash_id() if flash_id in (0xffffff, 0x000000): print('WARNING: Failed to communicate with the flash chip, read/write operations will fail. ' 'Try checking the chip connections or removing any other hardware connected to IOs.') except Exception as e: esp.trace('Unable to verify flash chip connection ({}).'.format(e)) # Check if XMC SPI flash chip booted-up successfully, fix if not if not esp.secure_download_mode: try: flash_xmc_startup() except Exception as e: esp.trace('Unable to perform XMC flash chip startup sequence ({}).'.format(e)) if hasattr(args, "flash_size"): print("Configuring flash size...") detect_flash_size(esp, args) if args.flash_size != 'keep': # TODO: should set this even with 'keep' esp.flash_set_parameters(flash_size_bytes(args.flash_size)) # Check if stub supports chosen flash size if esp.IS_STUB and args.flash_size in ('32MB', '64MB', '128MB'): print("WARNING: Flasher stub doesn't fully support flash size larger than 16MB, in case of failure use --no-stub.") if esp.IS_STUB and hasattr(args, "address") and hasattr(args, "size"): if args.address + args.size > 0x1000000: print("WARNING: Flasher stub doesn't fully support flash size larger than 16MB, in case of failure use --no-stub.") try: operation_func(esp, args) finally: try: # Clean up AddrFilenamePairAction files for address, argfile in args.addr_filename: argfile.close() except AttributeError: pass # Handle post-operation behaviour (reset or other) if operation_func == load_ram: # the ESP is now running the loaded image, so let it run print('Exiting immediately.') elif args.after == 'hard_reset': esp.hard_reset() elif args.after == 'soft_reset': print('Soft resetting...') # flash_finish will trigger a soft reset esp.soft_reset(False) elif args.after == 'no_reset_stub': print('Staying in flasher stub.') else: # args.after == 'no_reset' print('Staying in bootloader.') if esp.IS_STUB: esp.soft_reset(True) # exit stub back to ROM loader if not external_esp: esp._port.close() else: operation_func(args) def get_port_list(): if list_ports is None: raise FatalError("Listing all serial ports is currently not available. Please try to specify the port when " "running esptool.py or update the pyserial package to the latest version") return sorted(ports.device for ports in list_ports.comports()) def expand_file_arguments(argv): """ Any argument starting with "@" gets replaced with all values read from a text file. Text file arguments can be split by newline or by space. Values are added "as-is", as if they were specified in this order on the command line. """ new_args = [] expanded = False for arg in argv: if arg.startswith("@"): expanded = True with open(arg[1:], "r") as f: for line in f.readlines(): new_args += shlex.split(line) else: new_args.append(arg) if expanded: print("esptool.py %s" % (" ".join(new_args[1:]))) return new_args return argv class FlashSizeAction(argparse.Action): """ Custom flash size parser class to support backwards compatibility with megabit size arguments. (At next major relase, remove deprecated sizes and this can become a 'normal' choices= argument again.) """ def __init__(self, option_strings, dest, nargs=1, auto_detect=False, **kwargs): super(FlashSizeAction, self).__init__(option_strings, dest, nargs, **kwargs) self._auto_detect = auto_detect def __call__(self, parser, namespace, values, option_string=None): try: value = { '2m': '256KB', '4m': '512KB', '8m': '1MB', '16m': '2MB', '32m': '4MB', '16m-c1': '2MB-c1', '32m-c1': '4MB-c1', }[values[0]] print("WARNING: Flash size arguments in megabits like '%s' are deprecated." % (values[0])) print("Please use the equivalent size '%s'." % (value)) print("Megabit arguments may be removed in a future release.") except KeyError: value = values[0] known_sizes = dict(ESP8266ROM.FLASH_SIZES) known_sizes.update(ESP32ROM.FLASH_SIZES) if self._auto_detect: known_sizes['detect'] = 'detect' known_sizes['keep'] = 'keep' if value not in known_sizes: raise argparse.ArgumentError(self, '%s is not a known flash size. Known sizes: %s' % (value, ", ".join(known_sizes.keys()))) setattr(namespace, self.dest, value) class SpiConnectionAction(argparse.Action): """ Custom action to parse 'spi connection' override. Values are SPI, HSPI, or a sequence of 5 pin numbers separated by commas. """ def __call__(self, parser, namespace, value, option_string=None): if value.upper() == "SPI": value = 0 elif value.upper() == "HSPI": value = 1 elif "," in value: values = value.split(",") if len(values) != 5: raise argparse.ArgumentError(self, '%s is not a valid list of comma-separate pin numbers. Must be 5 numbers - CLK,Q,D,HD,CS.' % value) try: values = tuple(int(v, 0) for v in values) except ValueError: raise argparse.ArgumentError(self, '%s is not a valid argument. All pins must be numeric values' % values) if any([v for v in values if v > 33 or v < 0]): raise argparse.ArgumentError(self, 'Pin numbers must be in the range 0-33.') # encode the pin numbers as a 32-bit integer with packed 6-bit values, the same way ESP32 ROM takes them # TODO: make this less ESP32 ROM specific somehow... clk, q, d, hd, cs = values value = (hd << 24) | (cs << 18) | (d << 12) | (q << 6) | clk else: raise argparse.ArgumentError(self, '%s is not a valid spi-connection value. ' 'Values are SPI, HSPI, or a sequence of 5 pin numbers CLK,Q,D,HD,CS).' % value) setattr(namespace, self.dest, value) class AddrFilenamePairAction(argparse.Action): """ Custom parser class for the address/filename pairs passed as arguments """ def __init__(self, option_strings, dest, nargs='+', **kwargs): super(AddrFilenamePairAction, self).__init__(option_strings, dest, nargs, **kwargs) def __call__(self, parser, namespace, values, option_string=None): # validate pair arguments pairs = [] for i in range(0, len(values), 2): try: address = int(values[i], 0) except ValueError: raise argparse.ArgumentError(self, 'Address "%s" must be a number' % values[i]) try: argfile = open(values[i + 1], 'rb') except IOError as e: raise argparse.ArgumentError(self, e) except IndexError: raise argparse.ArgumentError(self, 'Must be pairs of an address and the binary filename to write there') pairs.append((address, argfile)) # Sort the addresses and check for overlapping end = 0 for address, argfile in sorted(pairs, key=lambda x: x[0]): argfile.seek(0, 2) # seek to end size = argfile.tell() argfile.seek(0) sector_start = address & ~(ESPLoader.FLASH_SECTOR_SIZE - 1) sector_end = ((address + size + ESPLoader.FLASH_SECTOR_SIZE - 1) & ~(ESPLoader.FLASH_SECTOR_SIZE - 1)) - 1 if sector_start < end: message = 'Detected overlap at address: 0x%x for file: %s' % (address, argfile.name) raise argparse.ArgumentError(self, message) end = sector_end setattr(namespace, self.dest, pairs) # Binary stub code (see flasher_stub dir for source & details) ESP8266ROM.STUB_CODE = eval(zlib.decompress(base64.b64decode(b""" eNq9Pftj1DbS/4rthCQbkiLZXq/Mo2w2yQItXCEcKddL28gvelxpwzZXcj34/vbP85Jl7yaB67U/LFl5ZWk0M5q3xH8265/OF//evB1oNUlNmmTjeCfYrOy5bZ8VmycXypxcGH1y0dT328aYP2n7Ue0nbj9J+5lw\ O+FPQe0iP7mo2t+0mp5c1I3X0FXbMNworGv80PZzfer2cY6Nc/ft5KJUruH3Ni0sleVG03gNfKEYvNB9e9n+Wg6etf9WDb8OC6kVNu64b6sGouUtdWjX1w5Va2y0S6pjfmxbTNUJNtr56xS/tf/W40unWPWtXVmd\ 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