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esptool.py
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esptool.py
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#!/usr/bin/env python
#
# ESP8266 ROM Bootloader Utility
# https://github.com/themadinventor/esptool
#
# Copyright (C) 2014 Fredrik Ahlberg
#
# This program is free software; you can redistribute it and/or modify it under
# the terms of the GNU General Public License as published by the Free Software
# Foundation; either version 2 of the License, or (at your option) any later version.
#
# This program is distributed in the hope that it will be useful, but WITHOUT
# ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
# FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License along with
# this program; if not, write to the Free Software Foundation, Inc., 51 Franklin
# Street, Fifth Floor, Boston, MA 02110-1301 USA.
import sys
import struct
import serial
import math
import time
import argparse
import os
import subprocess
import tempfile
class ESPROM:
# These are the currently known commands supported by the ROM
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
# Maximum block sized for RAM and Flash writes, respectively.
ESP_RAM_BLOCK = 0x1800
ESP_FLASH_BLOCK = 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
# OTP ROM addresses
ESP_OTP_MAC0 = 0x3ff00050
ESP_OTP_MAC1 = 0x3ff00054
ESP_OTP_MAC2 = 0x3ff00058
ESP_OTP_MAC3 = 0x3ff0005c
# Sflash stub: an assembly routine to read from spi flash and send to host
SFLASH_STUB = "\x80\x3c\x00\x40\x1c\x4b\x00\x40\x21\x11\x00\x40\x00\x80" \
"\xfe\x3f\xc1\xfb\xff\xd1\xf8\xff\x2d\x0d\x31\xfd\xff\x41\xf7\xff\x4a" \
"\xdd\x51\xf9\xff\xc0\x05\x00\x21\xf9\xff\x31\xf3\xff\x41\xf5\xff\xc0" \
"\x04\x00\x0b\xcc\x56\xec\xfd\x06\xff\xff\x00\x00"
def __init__(self, port=0, baud=ESP_ROM_BAUD):
self._port = serial.Serial(port, baud)
""" Read bytes from the serial port while performing SLIP unescaping """
def read(self, length=1):
b = ''
while len(b) < length:
c = self._port.read(1)
if c == '\xdb':
c = self._port.read(1)
if c == '\xdc':
b = b + '\xc0'
elif c == '\xdd':
b = b + '\xdb'
else:
raise Exception('Invalid SLIP escape')
else:
b = b + c
return b
""" Write bytes to the serial port while performing SLIP escaping """
def write(self, packet):
buf = '\xc0' + (packet.replace('\xdb', '\xdb\xdd').replace('\xc0', '\xdb\xdc')) + '\xc0'
self._port.write(buf)
""" Calculate checksum of a blob, as it is defined by the ROM """
@staticmethod
def checksum(data, state=ESP_CHECKSUM_MAGIC):
for b in data:
state ^= ord(b)
return state
""" Send a request and read the response """
def command(self, op=None, data=None, chk=0):
if op:
# Construct and send request
pkt = struct.pack('<BBHI', 0x00, op, len(data), chk) + data
self.write(pkt)
# Read header of response and parse
if self._port.read(1) != '\xc0':
raise Exception('Invalid head of packet')
hdr = self.read(8)
(resp, op_ret, len_ret, val) = struct.unpack('<BBHI', hdr)
if resp != 0x01 or (op and op_ret != op):
raise Exception('Invalid response')
# The variable-length body
body = self.read(len_ret)
# Terminating byte
if self._port.read(1) != chr(0xc0):
raise Exception('Invalid end of packet')
return val, body
""" Perform a connection test """
def sync(self):
self.command(ESPROM.ESP_SYNC, '\x07\x07\x12\x20' + 32 * '\x55')
for i in xrange(7):
self.command()
# WiFi Off, Power 32 mA -> 14 mA
self.write_reg(0x60000710, 0x0, 0xffffffff)
""" Try connecting repeatedly until successful, or giving up """
def connect(self):
print 'Connecting...'
for _ in xrange(4):
# issue reset-to-bootloader:
# RTS = either CH_PD or nRESET (both active low = chip in reset)
# DTR = GPIO0 (active low = boot to flasher)
self._port.setDTR(False)
self._port.setRTS(True)
time.sleep(0.05)
self._port.setDTR(True)
self._port.setRTS(False)
time.sleep(0.05)
self._port.setDTR(False)
self._port.timeout = 0.3 # worst-case latency timer should be 255ms (probably <20ms)
for _ in xrange(4):
try:
self._port.flushInput()
self._port.flushOutput()
self.sync()
self._port.timeout = 5
return
except:
time.sleep(0.05)
# this is a workaround for the CH340 serial driver on current versions of Linux,
# which seems to sometimes set the serial port up with wrong parameters
self._port.close()
self._port.open()
raise Exception('Failed to connect')
"""read mac addr"""
def get_mac(self):
try:
reg1 = self.read_reg(esp.ESP_OTP_MAC0)
reg2 = self.read_reg(esp.ESP_OTP_MAC1)
reg3 = self.read_reg(esp.ESP_OTP_MAC2)
# reg4 = self.read_reg(esp.ESP_OTP_MAC3)
except:
print "Read reg error"
return False
chip_flg = (reg3 >> 15) & 0x1
if chip_flg == 0:
print 'Warning : ESP8089 CHIP DETECTED, STOP'
return False
else:
# print 'Chip_flag',chip_flg
m0 = ((reg2 >> 16) & 0xff)
m1 = ((reg2 >> 8) & 0xff)
m2 = ((reg2 & 0xff))
m3 = ((reg1 >> 24) & 0xff)
self.MAC2 = m0
self.MAC3 = m1
self.MAC4 = m2
self.MAC5 = m3
if m0 == 0:
# print "r1: %02x; r2:%02x ; r3: %02x"%(m1,m2,m3)
mac = "1A-FE-34-%02x-%02x-%02x" % (m1, m2, m3)
mac2 = "1AFE34%02x%02x%02x" % (m1, m2, m3)
mac = mac.upper()
mac2 = mac2.upper()
mac_ap = ("1A-FE-34-%02x-%02x-%02x" % (m1, m2, m3)).upper()
mac_sta = ("18-FE-34-%02x-%02x-%02x" % (m1, m2, m3)).upper()
print "MAC AP: %s" % (mac_ap)
print "MAC STA: %s" % (mac_sta)
elif m0 == 1:
# print "r1: %02x; r2:%02x ; r3: %02x"%(m1,m2,m3)
mac = "AC-D0-74-%02x-%02x-%02x" % (m1, m2, m3)
mac2 = "ACD074%02x%02x%02x" % (m1, m2, m3)
mac = mac.upper()
mac2 = mac2.upper()
mac_ap = ("AC-D0-74-%02x-%02x-%02x" % (m1, m2, m3)).upper()
mac_sta = ("AC-D0-74-%02x-%02x-%02x" % (m1, m2, m3)).upper()
print "MAC AP: %s" % (mac_ap)
print "MAC STA: %s" % (mac_sta)
return True
else:
print "MAC read error..."
return False
""" Read memory address in target """
def read_reg(self, addr):
res = self.command(ESPROM.ESP_READ_REG, struct.pack('<I', addr))
if res[1] != "\0\0":
raise Exception('Failed to read target memory')
return res[0]
""" Write to memory address in target """
def write_reg(self, addr, value, mask, delay_us=0):
if self.command(ESPROM.ESP_WRITE_REG,
struct.pack('<IIII', addr, value, mask, delay_us))[1] != "\0\0":
raise Exception('Failed to write target memory')
""" Start downloading an application image to RAM """
def mem_begin(self, size, blocks, blocksize, offset):
if self.command(ESPROM.ESP_MEM_BEGIN,
struct.pack('<IIII', size, blocks, blocksize, offset))[1] != "\0\0":
raise Exception('Failed to enter RAM download mode')
""" Send a block of an image to RAM """
def mem_block(self, data, seq):
if self.command(ESPROM.ESP_MEM_DATA,
struct.pack('<IIII', len(data), seq, 0, 0) + data, ESPROM.checksum(data))[1] != "\0\0":
raise Exception('Failed to write to target RAM')
""" Leave download mode and run the application """
def mem_finish(self, entrypoint=0):
if self.command(ESPROM.ESP_MEM_END,
struct.pack('<II', int(entrypoint == 0), entrypoint))[1] != "\0\0":
raise Exception('Failed to leave RAM download mode')
""" Start downloading to Flash (performs an erase) """
def flash_begin(self, _size, offset):
old_tmo = self._port.timeout
self._port.timeout = 10
area_len = int(_size)
sector_no = offset / 4096;
sector_num_per_block = 16;
# total_sector_num = (0== (area_len%4096))? area_len/4096 : 1+(area_len/4096);
if 0 == (area_len % 4096):
total_sector_num = area_len / 4096
else:
total_sector_num = 1 + (area_len / 4096)
# check if erase area reach over block boundary
head_sector_num = sector_num_per_block - (sector_no % sector_num_per_block);
# head_sector_num = (head_sector_num>=total_sector_num)? total_sector_num : head_sector_num;
if head_sector_num >= total_sector_num :
head_sector_num = total_sector_num
else:
head_sector_num = head_sector_num
if (total_sector_num - 2 * head_sector_num) > 0:
size = (total_sector_num - head_sector_num) * 4096
print "head: ", head_sector_num, ";total:", total_sector_num
print "erase size : ", size
else:
size = int(math.ceil(total_sector_num / 2.0) * 4096)
print "head:", head_sector_num, ";total:", total_sector_num
print "erase size :", size
if self.command(ESPROM.ESP_FLASH_BEGIN,
struct.pack('<IIII', size, 0x200, ESPROM.ESP_FLASH_BLOCK, offset))[1] != "\0\0":
raise Exception('Failed to enter Flash download mode')
self._port.timeout = old_tmo
""" Write block to flash """
def flash_block(self, data, seq):
if self.command(ESPROM.ESP_FLASH_DATA,
struct.pack('<IIII', len(data), seq, 0, 0) + data, ESPROM.checksum(data))[1] != "\0\0":
raise Exception('Failed to write to target Flash')
""" Leave flash mode and run/reboot """
def flash_finish(self, reboot=False):
res = self.command(ESPROM.ESP_FLASH_END,
struct.pack('<I', int(not reboot)))[1]
# if self.command(ESPROM.ESP_FLASH_END,
# struct.pack('<I', int(not reboot)))[1] != "\0\0":
# print res
if res[1] != "\0\0":
pass
# raise Exception('Failed to leave Flash mode')
""" Run application code in flash """
def run(self, reboot=False):
# Fake flash begin immediately followed by flash end
self.flash_begin(0, 0)
self.flash_finish(reboot)
""" Read SPI flash manufacturer and device id """
def flash_id(self):
self.flash_begin(0, 0)
self.write_reg(0x60000240, 0x0, 0xffffffff)
self.write_reg(0x60000200, 0x10000000, 0xffffffff)
flash_id = esp.read_reg(0x60000240)
self.flash_finish(False)
return flash_id
""" Read SPI flash """
def flash_read(self, offset, size, count=1):
# Create a custom stub
stub = struct.pack('<III', offset, size, count) + self.SFLASH_STUB
# Trick ROM to initialize SFlash
self.flash_begin(0, 0)
# Download stub
self.mem_begin(len(stub), 1, len(stub), 0x40100000)
self.mem_block(stub, 0)
self.mem_finish(0x4010001c)
# Fetch the data
data = ''
for _ in xrange(count):
if self._port.read(1) != '\xc0':
raise Exception('Invalid head of packet (sflash read)')
data += self.read(size)
if self._port.read(1) != chr(0xc0):
raise Exception('Invalid end of packet (sflash read)')
return data
""" Perform a chip erase of SPI flash """
def flash_erase(self):
# Trick ROM to initialize SFlash
self.flash_begin(0, 0)
# This is hacky: we don't have a custom stub, instead we trick
# the bootloader to jump to the SPIEraseChip() routine and then halt/crash
# when it tries to boot an unconfigured system.
self.mem_begin(0, 0, 0, 0x40100000)
self.mem_finish(0x40004984)
# Yup - there's no good way to detect if we succeeded.
# It it on the other hand unlikely to fail.
class ESPFirmwareImage:
def __init__(self, filename=None):
self.segments = []
self.entrypoint = 0
self.flash_mode = 0
self.flash_size_freq = 0
if filename is not None:
f = file(filename, 'rb')
(magic, segments, self.flash_mode, self.flash_size_freq, self.entrypoint) = struct.unpack('<BBBBI', f.read(8))
# some sanity check
if magic != ESPROM.ESP_IMAGE_MAGIC or segments > 16:
raise Exception('Invalid firmware image')
for i in xrange(segments):
(offset, size) = struct.unpack('<II', f.read(8))
if offset > 0x40200000 or offset < 0x3ffe0000 or size > 65536:
raise Exception('Suspicious segment %x,%d' % (offset, size))
if size > 0:
self.segments.append((offset, size, f.read(size)))
# Skip the padding. The checksum is stored in the last byte so that the
# file is a multiple of 16 bytes.
align = 15 - (f.tell() % 16)
f.seek(align, 1)
self.checksum = ord(f.read(1))
def add_segment(self, addr, data):
# Data should be aligned on word boundary
l = len(data)
if l > 0:
if l % 4:
data += b"\x00" * (4 - l % 4)
self.segments.append((addr, len(data), data))
def save(self, filename):
f = file(filename, 'wb')
f.write(struct.pack('<BBBBI', ESPROM.ESP_IMAGE_MAGIC, len(self.segments),
self.flash_mode, self.flash_size_freq, self.entrypoint))
checksum = ESPROM.ESP_CHECKSUM_MAGIC
for (offset, size, data) in self.segments:
f.write(struct.pack('<II', offset, size))
f.write(data)
checksum = ESPROM.checksum(data, checksum)
align = 15 - (f.tell() % 16)
f.seek(align, 1)
f.write(struct.pack('B', checksum))
class ELFFile:
def __init__(self, name):
self.name = name
self.symbols = None
def _fetch_symbols(self):
if self.symbols is not None:
return
self.symbols = {}
try:
tool_nm = "C:\\Espressif\\xtensa-lx106-elf\\bin\\xtensa-lx106-elf-nm.exe"
if os.getenv('XTENSA_CORE') == 'lx106':
tool_nm = "xt-nm"
proc = subprocess.Popen([tool_nm, self.name], stdout=subprocess.PIPE)
except OSError:
print "Error calling " + tool_nm + ", do you have Xtensa toolchain in PATH?"
sys.exit(1)
for l in proc.stdout:
fields = l.strip().split()
try:
self.symbols[fields[2]] = int(fields[0], 16)
except ValueError as verr:
pass
except Exception as ex:
pass
def get_symbol_addr(self, sym):
self._fetch_symbols()
return self.symbols[sym]
def load_section(self, section):
tool_objcopy = "C:\\Espressif\\xtensa-lx106-elf\\bin\\xtensa-lx106-elf-objcopy.exe"
if os.getenv('XTENSA_CORE') == 'lx106':
tool_objcopy = "xt-objcopy"
tmpsection = tempfile.mktemp(suffix=".section")
try:
subprocess.check_call([tool_objcopy, "--only-section", section, "-Obinary", self.name, tmpsection])
with open(tmpsection, "rb") as f:
data = f.read()
finally:
os.remove(tmpsection)
return data
def arg_auto_int(x):
return int(x, 0)
if __name__ == '__main__':
parser = argparse.ArgumentParser(description='ESP8266 ROM Bootloader Utility', prog='esptool')
parser.add_argument(
'--port', '-p',
help='Serial port device',
default='COM0')
parser.add_argument(
'--baud', '-b',
help='Serial port baud rate',
type=arg_auto_int,
default=ESPROM.ESP_ROM_BAUD)
subparsers = parser.add_subparsers(
dest='operation',
help='Run esptool {command} -h for additional help')
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)
parser_write_flash = subparsers.add_parser(
'write_flash',
help='Write a binary blob to flash')
parser_write_flash.add_argument('addr_filename', nargs='+', help='Address and binary file to write there, separated by space')
parser_write_flash.add_argument('--flash_freq', '-ff', help='SPI Flash frequency',
choices=['40m', '26m', '20m', '80m'], default='40m')
parser_write_flash.add_argument('--flash_mode', '-fm', help='SPI Flash mode',
choices=['qio', 'qout', 'dio', 'dout'], default='qio')
parser_write_flash.add_argument('--flash_size', '-fs', help='SPI Flash size in Mbit',
choices=['4m', '2m', '8m', '16m', '32m', '16m-c1', '32m-c1', '32m-c2'], default='4m')
parser_run = 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', type=str)
parser_elf2image.add_argument('--flash_freq', '-ff', help='SPI Flash frequency',
choices=['40m', '26m', '20m', '80m'], default='40m')
parser_elf2image.add_argument('--flash_mode', '-fm', help='SPI Flash mode',
choices=['qio', 'qout', 'dio', 'dout'], default='qio')
parser_elf2image.add_argument('--flash_size', '-fs', help='SPI Flash size in Mbit',
choices=['4m', '2m', '8m', '16m', '32m', '16m-c1', '32m-c1', '32m-c2'], default='4m')
parser_elf2image.add_argument('--entry-symbol', '-es', help='Entry point symbol name (default \'call_user_start\')',
default='call_user_start')
parser_read_mac = subparsers.add_parser(
'read_mac',
help='Read MAC address from OTP ROM')
parser_flash_id = subparsers.add_parser(
'flash_id',
help='Read SPI flash manufacturer and device ID')
parser_read_flash = subparsers.add_parser(
'read_flash',
help='Read SPI flash content')
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_erase_flash = subparsers.add_parser(
'erase_flash',
help='Perform Chip Erase on SPI flash')
args = parser.parse_args()
# Create the ESPROM connection object, if needed
esp = None
if args.operation not in ('image_info', 'make_image', 'elf2image'):
esp = ESPROM(args.port, args.baud)
esp.connect()
# Do the actual work. Should probably be split into separate functions.
if args.operation == 'load_ram':
image = ESPFirmwareImage(args.filename)
print 'RAM boot...'
for (offset, size, data) in image.segments:
print 'Downloading %d bytes at %08x...' % (size, offset),
sys.stdout.flush()
esp.mem_begin(size, math.ceil(size / float(esp.ESP_RAM_BLOCK)), esp.ESP_RAM_BLOCK, offset)
seq = 0
while len(data) > 0:
esp.mem_block(data[0:esp.ESP_RAM_BLOCK], seq)
data = data[esp.ESP_RAM_BLOCK:]
seq += 1
print 'done!'
print 'All segments done, executing at %08x' % image.entrypoint
esp.mem_finish(image.entrypoint)
elif args.operation == 'read_mem':
print '0x%08x = 0x%08x' % (args.address, esp.read_reg(args.address))
elif args.operation == 'write_mem':
esp.write_reg(args.address, args.value, args.mask, 0)
print 'Wrote %08x, mask %08x to %08x' % (args.value, args.mask, args.address)
elif args.operation == 'dump_mem':
f = file(args.filename, 'wb')
for i in xrange(args.size / 4):
d = esp.read_reg(args.address + (i * 4))
f.write(struct.pack('<I', d))
if f.tell() % 1024 == 0:
print '\r%d bytes read... (%d %%)' % (f.tell(), f.tell() * 100 / args.size),
sys.stdout.flush()
print 'Done!'
elif args.operation == 'write_flash':
assert len(args.addr_filename) % 2 == 0
flash_mode = {'qio':0, 'qout':1, 'dio':2, 'dout': 3}[args.flash_mode]
flash_size_freq = {'4m':0x00, '2m':0x10, '8m':0x20, '16m':0x30, '32m':0x40, '16m-c1': 0x50, '32m-c1':0x60, '32m-c2':0x70}[args.flash_size]
flash_size_freq += {'40m':0, '26m':1, '20m':2, '80m': 0xf}[args.flash_freq]
flash_info = struct.pack('BB', flash_mode, flash_size_freq)
while args.addr_filename:
address = int(args.addr_filename[0], 0)
filename = args.addr_filename[1]
args.addr_filename = args.addr_filename[2:]
image = file(filename, 'rb').read()
print 'Erasing flash...'
blocks = math.ceil(len(image) / float(esp.ESP_FLASH_BLOCK))
esp.flash_begin(blocks * esp.ESP_FLASH_BLOCK, address)
seq = 0
written = 0
t = time.time()
while len(image) > 0:
print '\rWriting at 0x%08x... (%d %%)' % (address + seq * esp.ESP_FLASH_BLOCK, 100 * (seq + 1) / blocks),
sys.stdout.flush()
block = image[0:esp.ESP_FLASH_BLOCK]
# Fix sflash config data
if address == 0 and seq == 0 and block[0] == '\xe9':
block = block[0:2] + flash_info + block[4:]
# Pad the last block
block = block + '\xff' * (esp.ESP_FLASH_BLOCK - len(block))
esp.flash_block(block, seq)
image = image[esp.ESP_FLASH_BLOCK:]
seq += 1
written += len(block)
t = time.time() - t
print '\nWritten %d bytes in %.2f seconds (%.2f kbit/s)...' % (written, t, written / t * 8 / 1000)
print "\nLeaving..."
esp.flash_finish(False)
elif args.operation == 'run':
esp.run()
elif args.operation == 'image_info':
image = ESPFirmwareImage(args.filename)
print ('Entry point: %08x' % image.entrypoint) if image.entrypoint != 0 else 'Entry point not set'
print '%d segments' % len(image.segments)
print
checksum = ESPROM.ESP_CHECKSUM_MAGIC
for (idx, (offset, size, data)) in enumerate(image.segments):
print 'Segment %d: %5d bytes at %08x' % (idx + 1, size, offset)
checksum = ESPROM.checksum(data, checksum)
print
print 'Checksum: %02x (%s)' % (image.checksum, 'valid' if image.checksum == checksum else 'invalid!')
elif args.operation == 'make_image':
image = ESPFirmwareImage()
if len(args.segfile) == 0:
raise Exception('No segments specified')
if len(args.segfile) != len(args.segaddr):
raise Exception('Number of specified files does not match number of specified addresses')
for (seg, addr) in zip(args.segfile, args.segaddr):
data = file(seg, 'rb').read()
image.add_segment(addr, data)
image.entrypoint = args.entrypoint
image.save(args.output)
elif args.operation == 'elf2image':
if args.output is None:
args.output = args.input + '-'
e = ELFFile(args.input)
image = ESPFirmwareImage()
image.entrypoint = e.get_symbol_addr(args.entry_symbol)
for section, start in ((".text", "_text_start"), (".data", "_data_start"), (".rodata", "_rodata_start")):
data = e.load_section(section)
image.add_segment(e.get_symbol_addr(start), data)
image.flash_mode = {'qio':0, 'qout':1, 'dio':2, 'dout': 3}[args.flash_mode]
image.flash_size_freq = {'4m':0x00, '2m':0x10, '8m':0x20, '16m':0x30, '32m':0x40, '16m-c1': 0x50, '32m-c1':0x60, '32m-c2':0x70}[args.flash_size]
image.flash_size_freq += {'40m':0, '26m':1, '20m':2, '80m': 0xf}[args.flash_freq]
image.save(args.output + "0x00000.bin")
data = e.load_section(".irom0.text")
off = e.get_symbol_addr("_irom0_text_start") - 0x40200000
assert off >= 0
f = open(args.output + "0x%05x.bin" % off, "wb")
f.write(data)
f.close()
print "{0:>10}|{1:>30}|{2:>12}|{3:>12}|{4:>8}".format("Section", "Description", "Start (hex)", "End (hex)", "Used space")
print "------------------------------------------------------------------------------"
sec_name = ["data", "rodata", "bss", "lit4", "text", "irom0_text"]
sec_des = ["Initialized Data (RAM)", "ReadOnly Data (RAM)", "Uninitialized Data (RAM)", "Uninitialized Data (IRAM)", "Uncached Code (IRAM)", "Cached Code (SPI)"]
sec_size = []
for i in range(len(sec_name)):
ss = e.get_symbol_addr('_' + sec_name[i] + '_start')
se = e.get_symbol_addr('_' + sec_name[i] + '_end')
sec_size.append(int(se - ss))
print "{0:>10}|{1:>30}|{2:>12X}|{3:>12X}|{4:>8d}".format(sec_name[i], sec_des[i], ss, se, sec_size[i])
print "------------------------------------------------------------------------------"
print "{0} : {1:X} {2}()".format("Entry Point", image.entrypoint, args.entry_symbol)
ram_used = sec_size[0] + sec_size[1] + sec_size[2]
iram_used = sec_size[3] + sec_size[4]
print "{0} : {1:d}".format("Total Used RAM", ram_used + iram_used)
print "{0} : {1:d} or {2:d} (option 48k IRAM)".format("Free IRam", 0x08000 - iram_used, 0x0C000 - iram_used)
print "{0} : {1:d}".format("Free Heap", 0x014000 - ram_used)
print "{0} : {1:d}".format("Total Free RAM", 0x020000 - iram_used - ram_used)
elif args.operation == 'read_mac':
esp.get_mac()
elif args.operation == 'flash_id':
flash_id = esp.flash_id()
print 'Manufacturer: %02x' % (flash_id & 0xff)
print 'Device: %02x%02x' % ((flash_id >> 8) & 0xff, (flash_id >> 16) & 0xff)
elif args.operation == 'read_flash':
print 'Please wait...'
file(args.filename, 'wb').write(esp.flash_read(args.address, 1024, int(math.ceil(args.size / 1024.)))[:args.size])
elif args.operation == 'erase_flash':
esp.flash_erase()