#!/usr/bin/python """ME7 Update binary parser.""" # Copyright (C) 2020 Tom Hiller # Copyright (C) 2016-2018 Nicola Corna # # 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 3 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. # # Based on the amazing me_cleaner, https://github.com/corna/me_cleaner, parses # the required signed partition from an ME update file to generate a valid # flashable ME binary. # # This was written for Heads ROM, https://github.com/osresearch/heads # to allow continuous integration reproducible builds for Lenovo xx20 models # (X220, T420, T520, etc). # # A full model list can be found: # https://download.lenovo.com/ibmdl/pub/pc/pccbbs/mobiles/83rf46ww.txt from struct import pack, unpack from typing import List import argparse import sys import hashlib import binascii import os.path ############################################################################# FTPR_END = 0x76000 MINIFIED_FTPR_OFFSET = 0x400 # offset start of Factory Partition (FTPR) ORIG_FTPR_OFFSET = 0xCC000 PARTITION_HEADER_OFFSET = 0x30 # size of partition header DEFAULT_OUTPUT_FILE_NAME = "flashregion_2_intel_me.bin" ############################################################################# class EntryFlags: """EntryFlag bitmap values.""" ExclBlockUse = 8192 WOPDisable = 4096 Logical = 2048 Execute = 1024 Write = 512 Read = 256 DirectAccess = 128 Type = 64 def generateHeader() -> bytes: """Generate Header.""" ROM_BYPASS_INSTR_0 = binascii.unhexlify("2020800F") ROM_BYPASS_INSTR_1 = binascii.unhexlify("40000010") ROM_BYPASS_INSTR_2 = pack(" bytes: """Partition table entry.""" ENTRY_NAME = binascii.unhexlify("46545052") ENTRY_OWNER = binascii.unhexlify("FFFFFFFF") # "None" ENTRY_OFFSET = binascii.unhexlify("00040000") ENTRY_LENGTH = binascii.unhexlify("00600700") ENTRY_START_TOKENS = pack(" bytes: """Copy data of a given size from FTPR starting from offset.""" offset_end = offset + size return self.ftpr[offset:offset_end] def unpack_next_int(self, offset: int) -> int: """Sugar syntax for unpacking a little-endian UINT at offset.""" return self.unpack_val(self.slice(offset, 4)) def unpack_val(self, data: bytes) -> int: """Sugar syntax for unpacking a little-endian unsigned integer.""" return unpack(" str: """Decode bytes into ASCII.""" return data.rstrip(b"\x00").decode("ascii") def clear_ftpr_data(self, start: int, end: int) -> None: """Replace values in range with 0xFF.""" empty_data = bytes() for i in range(0, end - start): empty_data += b"\xff" self.write_ftpr_data(start, empty_data) def write_ftpr_data(self, start: int, data: bytes) -> None: """Replace data in FTPR starting at a given offset.""" end = len(data) + start new_partition = self.ftpr[:start] new_partition += data if end != FTPR_END: new_partition += self.ftpr[end:] self.ftpr = new_partition ###################################################################### # FTPR cleanig/checking functions ###################################################################### def get_chunks_offsets(self, llut: bytes): """Calculate Chunk offsets from LLUT.""" chunk_count = self.unpack_val(llut[0x04:0x08]) huffman_stream_end = sum(unpack(" int: """Relocate partition.""" new_offset = MINIFIED_FTPR_OFFSET name = self.bytes_to_ascii(self.slice(PARTITION_HEADER_OFFSET, 4)) old_offset, partition_size = unpack( "> 4) & 7 == 0x01: llut_start = self.unpack_val(mod_header[0x38:0x3C]) llut_start += old_offset break if self.mod_headers and llut_start != 0: # Bytes 0x9:0xb of the LLUT (bytes 0x1:0x3 of the AddrBase) are # added to the SpiBase (bytes 0xc:0x10 of the LLUT) to compute the # final start of the LLUT. Since AddrBase is not modifiable, we can # act only on SpiBase and here we compute the minimum allowed # new_offset. llut_start_corr = unpack(" int: """Remove modules.""" unremovable_huff_chunks = [] chunks_offsets = [] base = 0 chunk_size = 0 end_addr = 0 for mod_header in self.mod_headers: name = self.bytes_to_ascii(mod_header[0x04:0x14]) offset = self.unpack_val(mod_header[0x38:0x3C]) size = self.unpack_val(mod_header[0x40:0x44]) flags = self.unpack_val(mod_header[0x50:0x54]) comp_type = (flags >> 4) & 7 comp_type_name = self.COMPRESSION_TYPE_NAME[comp_type] print(" {:<16} ({:<7}, ".format(name, comp_type_name), end="") # If compresion type uncompressed or LZMA if comp_type == 0x00 or comp_type == 0x02: offset_end = offset + size range_msg = "0x{:06x} - 0x{:06x} ): " print(range_msg.format(offset, offset_end), end="") if name in self.UNREMOVABLE_MODULES: end_addr = max(end_addr, offset + size) print("NOT removed, essential") else: offset_end = min(offset + size, FTPR_END) self.clear_ftpr_data(offset, offset_end) print("removed") # Else if compression type huffman elif comp_type == 0x01: if not chunks_offsets: # Check if Local Look Up Table (LLUT) is present if self.slice(offset, 4) == b"LLUT": llut = self.slice(offset, 0x40) chunk_count = self.unpack_val(llut[0x4:0x8]) base = self.unpack_val(llut[0x8:0xC]) + 0x10000000 chunk_size = self.unpack_val(llut[0x30:0x34]) llut = self.slice(offset, (chunk_count * 4) + 0x40) # calculate offsets of chunks from LLUT chunks_offsets = self.get_chunks_offsets(llut) else: no_llut_msg = "Huffman modules found," no_llut_msg += "but LLUT is not present." sys.exit(no_llut_msg) module_base = self.unpack_val(mod_header[0x34:0x38]) module_size = self.unpack_val(mod_header[0x3C:0x40]) first_chunk_num = (module_base - base) // chunk_size last_chunk_num = first_chunk_num + module_size // chunk_size huff_size = 0 chunk_length = last_chunk_num + 1 for chunk in chunks_offsets[first_chunk_num:chunk_length]: huff_size += chunk[1] - chunk[0] size_in_kiB = "~" + str(int(round(huff_size / 1024))) + " KiB" print( "fragmented data, {:<9}): ".format(size_in_kiB), end="", ) # Check if module is in the unremovable list if name in self.UNREMOVABLE_MODULES: print("NOT removed, essential") # add to list of unremovable chunks for x in chunks_offsets[first_chunk_num:chunk_length]: if x[0] != 0: unremovable_huff_chunks.append(x) else: print("removed") # Else unknown compression type else: unkwn_comp_msg = " 0x{:06x} - 0x{:06x}): " unkwn_comp_msg += "unknown compression, skipping" print(unkwn_comp_msg.format(offset, offset + size), end="") if chunks_offsets: removable_huff_chunks = [] for chunk in chunks_offsets: # if chunk is not in a unremovable chunk, it must be removable if all( not ( unremovable_chk[0] <= chunk[0] < unremovable_chk[1] or unremovable_chk[0] < chunk[1] <= unremovable_chk[1] ) for unremovable_chk in unremovable_huff_chunks ): removable_huff_chunks.append(chunk) for removable_chunk in removable_huff_chunks: if removable_chunk[1] > removable_chunk[0]: chunk_start = removable_chunk[0] - ORIG_FTPR_OFFSET chunk_end = removable_chunk[1] - ORIG_FTPR_OFFSET self.clear_ftpr_data(chunk_start, chunk_end) end_addr = max( end_addr, max(unremovable_huff_chunks, key=lambda x: x[1])[1] ) end_addr -= ORIG_FTPR_OFFSET return end_addr def find_mod_header_size(self) -> None: """Find module header size.""" self.mod_header_size = 0 data = self.slice(0x290, 0x84) # check header size if data[0x0:0x4] == b"$MME": if data[0x60:0x64] == b"$MME" or self.num_modules == 1: self.mod_header_size = 0x60 elif data[0x80:0x84] == b"$MME": self.mod_header_size = 0x80 def find_mod_headers(self) -> None: """Find module headers.""" data = self.slice(0x290, self.mod_header_size * self.num_modules) for i in range(0, self.num_modules): header_start = i * self.mod_header_size header_end = (i + 1) * self.mod_header_size self.mod_headers.append(data[header_start:header_end]) def resize_partition(self, end_addr: int) -> None: """Resize partition.""" spared_blocks = 4 if end_addr > 0: end_addr = (end_addr // 0x1000 + 1) * 0x1000 end_addr += spared_blocks * 0x1000 # partition header not added yet # remove trailing data the same size as the header. end_addr -= MINIFIED_FTPR_OFFSET me_size_msg = "The ME minimum size should be {0} " me_size_msg += "bytes ({0:#x} bytes)" print(me_size_msg.format(end_addr)) print("Truncating file at {:#x}...".format(end_addr)) self.ftpr = self.ftpr[:end_addr] def check_and_clean_ftpr(self) -> None: """Check and clean FTPR (factory partition).""" self.num_modules = self.unpack_next_int(0x20) self.find_mod_header_size() if self.mod_header_size != 0: self.find_mod_headers() # ensure all of the headers begin with b'$MME' if all(hdr.startswith(b"$MME") for hdr in self.mod_headers): end_addr = self.remove_modules() new_offset = self.relocate_partition() end_addr += new_offset self.resize_partition(end_addr) # flip bit # XXX: I have no idea why this works and passes RSA signiture self.write_ftpr_data(0x39, b"\x00") else: sys.exit( "Found less modules than expected in the FTPR " "partition; skipping modules removal and exiting." ) else: sys.exit( "Can't find the module header size; skipping modules" "removal and exiting." ) ########################################################################## def check_partition_signature(f, offset) -> bool: """check_partition_signature copied/shamelessly stolen from me_cleaner.""" f.seek(offset) header = f.read(0x80) modulus = int(binascii.hexlify(f.read(0x100)[::-1]), 16) public_exponent = unpack(" None: """Generate ME blob.""" print("Starting ME 7.x Update parser.") orig_f = open(input_file, "rb") cleaned_ftpr = clean_ftpr(orig_f.read(FTPR_END)) orig_f.close() fo = open(output_file, "wb") fo.write(generateHeader()) fo.write(generateFtpPartition()) fo.write(cleaned_ftpr.ftpr) fo.close() def verify_output(output_file: str) -> None: """Verify Generated ME file.""" file_verifiy = open(output_file, "rb") if check_partition_signature(file_verifiy, MINIFIED_FTPR_OFFSET): print(output_file + " is VALID") file_verifiy.close() else: print(output_file + " is INVALID!!") file_verifiy.close() sys.exit("The FTPR partition signature is not valid.") if __name__ == "__main__": parser = argparse.ArgumentParser( description="Tool to remove as much code " "as possible from Intel ME/TXE 7.x firmware " "update and create paratition for a flashable ME parition." ) parser.add_argument("file", help="ME/TXE image or full dump") parser.add_argument( "-O", "--output", metavar="output_file", help="save " "save file name other than the default '" + DEFAULT_OUTPUT_FILE_NAME + "'", ) args = parser.parse_args() output_file_name = DEFAULT_OUTPUT_FILE_NAME if not args.output else args.output # Check if output file exists, ask to overwrite or exit if os.path.isfile(output_file_name): input_msg = output_file_name input_msg += " exists. Do you want to overwrite? [y/N]: " if not str(input(input_msg)).lower().startswith("y"): sys.exit("Not overwriting file. Exiting.") generate_me_blob(args.file, output_file_name) verify_output(output_file_name)