usbexec.py

import struct, sys
import dfu, device_platform

class ExecConfig:
  def __init__(self, info, aes_crypto_cmd):
    self.info           = info
    self.aes_crypto_cmd = aes_crypto_cmd

  def match(self, info):
    return info == self.info[0].ljust(0x40, '\0') + self.info[1].ljust(0x40, '\0') + self.info[2].ljust(0x80, '\0')

configs = [
  ExecConfig(('SecureROM for s5l8947xsi, Copyright 2011, Apple Inc.',   'RELEASE',     'iBoot-1458.2'),          aes_crypto_cmd=0x7060+1),
  ExecConfig(('SecureROM for s5l8950xsi, Copyright 2011, Apple Inc.',   'RELEASE',     'iBoot-1145.3'),          aes_crypto_cmd=0x7300+1),
  ExecConfig(('SecureROM for s5l8955xsi, Copyright 2011, Apple Inc.',   'RELEASE',     'iBoot-1145.3.3'),        aes_crypto_cmd=0x7340+1),
  ExecConfig(('SecureROM for t8002si, Copyright 2007-2014, Apple Inc.', 'ROMRELEASE',  'iBoot-2651.0.0.1.31'),   aes_crypto_cmd=0x86DC+1),
  ExecConfig(('SecureROM for t8004si, Copyright 2007-2014, Apple Inc.', 'ROMRELEASE',  'iBoot-2651.0.0.3.3'),    aes_crypto_cmd=0x786C+1),
  ExecConfig(('SecureROM for s5l8960xsi, Copyright 2012, Apple Inc.',   'RELEASE',     'iBoot-1704.10'),         aes_crypto_cmd=0x10000B9A8),
  ExecConfig(('SecureROM for t8010si, Copyright 2007-2015, Apple Inc.', 'ROMRELEASE',  'iBoot-2696.0.0.1.33'),   aes_crypto_cmd=0x10000C8F4),
  ExecConfig(('SecureROM for t8011si, Copyright 2007-2015, Apple Inc.', 'ROMRELEASE',  'iBoot-3135.0.0.2.3'),    aes_crypto_cmd=0x10000C994),
  ExecConfig(('SecureROM for t8015si, Copyright 2007-2016, Apple Inc.', 'ROMRELEASE',  'iBoot-3332.0.0.1.23'),   aes_crypto_cmd=0x100009E9C),
]

EXEC_MAGIC = 'execexec'[::-1]
DONE_MAGIC = 'donedone'[::-1]
MEMC_MAGIC = 'memcmemc'[::-1]
MEMS_MAGIC = 'memsmems'[::-1]
USB_READ_LIMIT  = 0x8000
CMD_TIMEOUT     = 5000
AES_BLOCK_SIZE  = 16
AES_ENCRYPT     = 16
AES_DECRYPT     = 17
AES_GID_KEY     = 0x20000200
AES_UID_KEY     = 0x20000201

class PwnedUSBDevice():
  def memset(self, address, c, length):          self.command(self.cmd_memset(address, c, length), 0)
  def memcpy(self, dest, src, length):           self.command(self.cmd_memcpy(dest, src, length), 0)
  def read_memory_ptr(self, address):            return struct.unpack('<%s' % self.cmd_arg_type(), self.read_memory(address, self.cmd_arg_size()))[0]
  def read_memory_uint8(self, address):          return struct.unpack('<B', self.read_memory(address, 1))[0]
  def read_memory_uint16(self, address):         return struct.unpack('<H', self.read_memory(address, 2))[0]
  def read_memory_uint32(self, address):         return struct.unpack('<I', self.read_memory(address, 4))[0]
  def read_memory_uint64(self, address):         return struct.unpack('<Q', self.read_memory(address, 8))[0]
  def write_memory(self, address, data):         self.command(self.cmd_memcpy(address, self.cmd_data_address(3), len(data)) + data, 0)
  def write_memory_ptr(self, address, value):    self.write_memory(address, struct.pack('<%s' % self.cmd_arg_type(), value))
  def write_memory_uint8(self, address, value):  self.write_memory(address, struct.pack('<B', value))
  def write_memory_uint16(self, address, value): self.write_memory(address, struct.pack('<H', value))
  def write_memory_uint32(self, address, value): self.write_memory(address, struct.pack('<I', value))
  def write_memory_uint64(self, address, value): self.write_memory(address, struct.pack('<Q', value))
  def cmd_arg_type(self):                        return 'Q' if self.platform.arch == 'arm64' else 'I'
  def cmd_arg_size(self):                        return 8 if self.platform.arch == 'arm64' else 4
  def cmd_data_offset(self, index):              return 16 + index * self.cmd_arg_size()
  def cmd_data_address(self, index):             return self.load_base() + self.cmd_data_offset(index)
  def cmd_memcpy(self, dest, src, length):       return struct.pack('<8s8x3%s' % self.cmd_arg_type(), MEMC_MAGIC, dest, src, length)
  def cmd_memset(self, address, c, length):      return struct.pack('<8s8x3%s' % self.cmd_arg_type(), MEMS_MAGIC, address, c, length)

  def load_base(self):
    if 'SRTG:' in self.serial_number:
      return self.platform.dfu_image_base
    else:
      return self.platform.dfu_load_base

  def image_base(self):
    if 'SRTG:' in self.serial_number:
      return self.platform.rom_base
    else:
      return self.platform.dfu_image_base

  def usb_serial_number(self, key):
    for pair in self.serial_number.split(' '):
      if pair.startswith(key + ':'):
        k,v = pair.split(':')
        if v[0] == '[' and v[-1] == ']':
          return v[1:-1]
        else:
          return int(v, 16)
    return None

  def aes(self, data, action, key):
    assert len(data) % AES_BLOCK_SIZE == 0
    (retval, received) = self.execute(len(data), self.config.aes_crypto_cmd, action, self.cmd_data_address(7), self.cmd_data_address(0), len(data), key, 0, 0, data)
    assert retval & 0xFFFFFFFF == 0
    return received[:len(data)]      

  def read_memory(self, address, length):
    data = str()
    while len(data) < length:
      part_length = min(length - len(data), USB_READ_LIMIT - self.cmd_data_offset(0))
      response = self.command(self.cmd_memcpy(self.cmd_data_address(0), address + len(data), part_length), self.cmd_data_offset(0) + part_length)
      assert response[:8] == DONE_MAGIC
      data += response[self.cmd_data_offset(0):]
    return data

  def command(self, request_data, response_length):
    assert 0 <= response_length <= USB_READ_LIMIT
    device = dfu.acquire_device()
    assert self.serial_number == device.serial_number
    dfu.send_data(device, '\0' * 16)
    device.ctrl_transfer(0x21, 1, 0, 0, 0, 100)
    device.ctrl_transfer(0xA1, 3, 0, 0, 6, 100)
    device.ctrl_transfer(0xA1, 3, 0, 0, 6, 100)
    dfu.send_data(device, request_data)

    # HACK
    if response_length == 0:
      response = device.ctrl_transfer(0xA1, 2, 0xFFFF, 0, response_length + 1, CMD_TIMEOUT).tostring()[1:]
    else:
      response = device.ctrl_transfer(0xA1, 2, 0xFFFF, 0, response_length, CMD_TIMEOUT).tostring()
    dfu.release_device(device)
    assert len(response) == response_length
    return response

  def execute(self, response_length, *args):
    cmd = str()
    for i in range(len(args)):
      if isinstance(args[i], (int, long)):
        cmd += struct.pack('<%s' % self.cmd_arg_type(), args[i])
      elif isinstance(args[i], basestring) and i == len(args) - 1:
        cmd += args[i]
      else:
        print 'ERROR: usbexec.execute: invalid argument at position %s' % i
        sys.exit(1)
      if i == 0 and self.platform.arch != 'arm64':
        cmd += '\0' * 4
    response = self.command(EXEC_MAGIC + cmd, self.cmd_data_offset(0) + response_length)
    done, retval = struct.unpack('<8sQ', response[:self.cmd_data_offset(0)])
    assert done == DONE_MAGIC
    return retval, response[self.cmd_data_offset(0):]

  def __init__(self):
    self.config = None
    self.platform = None

    device = dfu.acquire_device()
    self.serial_number = device.serial_number
    dfu.release_device(device)
 
    for dp in device_platform.all_platforms:
      if self.serial_number.startswith('CPID:%04x CPRV:%02x ' % (dp.cpid, dp.cprv)):
        self.platform = dp
        break
    if self.platform is None:
      print self.serial_number
      print 'ERROR: No matching usbexec.platform found for this device.'
      sys.exit(1)

    info = self.read_memory(self.image_base() + 0x200, 0x100)
    for config in configs:
      if config.match(info):
        self.config = config
        break
    if self.config is None:
      print info
      print 'ERROR: No matching usbexec.config found for this image.'
      sys.exit(1)