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mirror of https://github.com/trezor/trezor-firmware.git synced 2024-11-18 13:38:12 +00:00
trezor-firmware/legacy/bootloader/firmware_sign.py
2021-10-13 11:53:17 +02:00

258 lines
7.3 KiB
Python
Executable File

#!/usr/bin/env python3
import argparse
import hashlib
import struct
import ecdsa
SLOTS = 3
pubkeys = {
1: "04d571b7f148c5e4232c3814f777d8faeaf1a84216c78d569b71041ffc768a5b2d810fc3bb134dd026b57e65005275aedef43e155f48fc11a32ec790a93312bd58",
2: "0463279c0c0866e50c05c799d32bd6bab0188b6de06536d1109d2ed9ce76cb335c490e55aee10cc901215132e853097d5432eda06b792073bd7740c94ce4516cb1",
3: "0443aedbb6f7e71c563f8ed2ef64ec9981482519e7ef4f4aa98b27854e8c49126d4956d300ab45fdc34cd26bc8710de0a31dbdf6de7435fd0b492be70ac75fde58",
4: "04877c39fd7c62237e038235e9c075dab261630f78eeb8edb92487159fffedfdf6046c6f8b881fa407c4a4ce6c28de0b19c1f4e29f1fcbc5a58ffd1432a3e0938a",
5: "047384c51ae81add0a523adbb186c91b906ffb64c2c765802bf26dbd13bdf12c319e80c2213a136c8ee03d7874fd22b70d68e7dee469decfbbb510ee9a460cda45",
}
FWHEADER_SIZE = 1024
SIGNATURES_START = 6 * 4 + 8 + 512
INDEXES_START = SIGNATURES_START + 3 * 64
def parse_args():
parser = argparse.ArgumentParser(
description="Commandline tool for signing Trezor firmware."
)
parser.add_argument("-f", "--file", dest="path", help="Firmware file to modify")
parser.add_argument(
"-s",
"--sign",
dest="sign",
action="store_true",
help="Add signature to firmware slot",
)
parser.add_argument(
"-p", "--pem", dest="pem", action="store_true", help="Use PEM instead of SECEXP"
)
parser.add_argument(
"-g",
"--generate",
dest="generate",
action="store_true",
help="Generate new ECDSA keypair",
)
return parser.parse_args()
def pad_to_size(data, size):
if len(data) > size:
raise ValueError("Chunk too big already")
if len(data) == size:
return data
return data + b"\xFF" * (size - len(data))
# see memory.h for details
def prepare_hashes(data):
# process chunks
start = 0
end = (64 - 1) * 1024
hashes = []
for i in range(16):
sector = data[start:end]
if len(sector) > 0:
chunk = pad_to_size(sector, end - start)
hashes.append(hashlib.sha256(chunk).digest())
else:
hashes.append(b"\x00" * 32)
start = end
end += 64 * 1024
return hashes
def check_hashes(data):
expected_hashes = data[0x20 : 0x20 + 16 * 32]
hashes = b""
for h in prepare_hashes(data[FWHEADER_SIZE:]):
hashes += h
if expected_hashes == hashes:
print("HASHES OK")
else:
print("HASHES NOT OK")
def update_hashes_in_header(data):
# Store hashes in the firmware header
data = bytearray(data)
o = 0
for h in prepare_hashes(data[FWHEADER_SIZE:]):
data[0x20 + o : 0x20 + o + 32] = h
o += 32
return bytes(data)
def get_header(data, zero_signatures=False):
if not zero_signatures:
return data[:FWHEADER_SIZE]
else:
data = bytearray(data[:FWHEADER_SIZE])
data[SIGNATURES_START : SIGNATURES_START + 3 * 64 + 3] = b"\x00" * (3 * 64 + 3)
return bytes(data)
def check_size(data):
size = struct.unpack("<L", data[12:16])[0]
assert size == len(data) - 1024
def check_signatures(data):
# Analyses given firmware and prints out
# status of included signatures
indexes = [x for x in data[INDEXES_START : INDEXES_START + SLOTS]]
to_sign = get_header(data, zero_signatures=True)
fingerprint = hashlib.sha256(to_sign).hexdigest()
print("Firmware fingerprint:", fingerprint)
used = []
for x in range(SLOTS):
signature = data[SIGNATURES_START + 64 * x : SIGNATURES_START + 64 * x + 64]
if indexes[x] == 0:
print(f"Slot #{x + 1}", "is empty")
else:
pk = pubkeys[indexes[x]]
verify = ecdsa.VerifyingKey.from_string(
bytes.fromhex(pk)[1:],
curve=ecdsa.curves.SECP256k1,
hashfunc=hashlib.sha256,
)
try:
verify.verify(signature, to_sign, hashfunc=hashlib.sha256)
if indexes[x] in used:
print(f"Slot #{x + 1} signature: DUPLICATE", signature.hex())
else:
used.append(indexes[x])
print(f"Slot #{x + 1} signature: VALID", signature.hex())
except Exception:
print(f"Slot #{x + 1} signature: INVALID", signature.hex())
def modify(data, slot, index, signature):
data = bytearray(data)
# put index to data
data[INDEXES_START + slot - 1] = index
# put signature to data
data[SIGNATURES_START + 64 * (slot - 1) : SIGNATURES_START + 64 * slot] = signature
return bytes(data)
def sign(data, is_pem):
# Ask for index and private key and signs the firmware
slot = int(input(f"Enter signature slot (1-{SLOTS}): "))
if slot < 1 or slot > SLOTS:
raise Exception("Invalid slot")
if is_pem:
print("Paste ECDSA private key in PEM format and press Enter:")
print("(blank private key removes the signature on given index)")
pem_key = ""
while True:
key = input()
pem_key += key + "\n"
if key == "":
break
if pem_key.strip() == "":
# Blank key,let's remove existing signature from slot
return modify(data, slot, 0, b"\x00" * 64)
key = ecdsa.SigningKey.from_pem(pem_key)
else:
print("Paste SECEXP (in hex) and press Enter:")
print("(blank private key removes the signature on given index)")
secexp = input()
if secexp.strip() == "":
# Blank key,let's remove existing signature from slot
return modify(data, slot, 0, b"\x00" * 64)
key = ecdsa.SigningKey.from_secret_exponent(
secexp=int(secexp, 16),
curve=ecdsa.curves.SECP256k1,
hashfunc=hashlib.sha256,
)
to_sign = get_header(data, zero_signatures=True)
# Locate proper index of current signing key
pubkey = "04" + key.get_verifying_key().to_string().hex()
index = None
for i, pk in pubkeys.items():
if pk == pubkey:
index = i
break
if index is None:
raise Exception("Unable to find private key index. Unknown private key?")
signature = key.sign_deterministic(to_sign, hashfunc=hashlib.sha256)
return modify(data, slot, index, signature)
def main(args):
if args.generate:
key = ecdsa.SigningKey.generate(
curve=ecdsa.curves.SECP256k1, hashfunc=hashlib.sha256
)
print("PRIVATE KEY (SECEXP):")
print(key.to_string().hex())
print()
print("PRIVATE KEY (PEM):")
print(key.to_pem())
print("PUBLIC KEY:")
print("04" + key.get_verifying_key().to_string().hex())
return
if not args.path:
raise Exception("-f/--file is required")
data = open(args.path, "rb").read()
assert len(data) % 4 == 0
if data[:4] != b"TRZF":
raise Exception("Firmware header expected")
data = update_hashes_in_header(data)
print(f"Firmware size {len(data)} bytes")
check_size(data)
check_signatures(data)
check_hashes(data)
if args.sign:
data = sign(data, args.pem)
check_signatures(data)
check_hashes(data)
fp = open(args.path, "wb")
fp.write(data)
fp.close()
if __name__ == "__main__":
args = parse_args()
main(args)