mymc/ps2mc_ecc.py
2016-10-01 16:25:49 -05:00

183 lines
4.5 KiB
Python
Executable File

#
# ps2mc_ecc.py
#
# By Ross Ridge
# Public Domain
#
"""
Routines for calculating the Hamming codes, a simple form of error
correcting codes (ECC), as used on PS2 memory cards.
"""
_SCCS_ID = "@(#) mysc ps2mc_ecc.py 1.4 07/12/17 02:34:04\n"
import array
from round import div_round_up
try:
import ctypes
import mymcsup
except ImportError:
mymcsup = None
__ALL__ = ["ECC_CHECK_OK", "ECC_CHECK_CORRECTED", "ECC_CHECK_FAILED",
"ecc_calculate", "ecc_check",
"ecc_calculate_page", "ecc_check_page"]
ECC_CHECK_OK = 0
ECC_CHECK_CORRECTED = 1
ECC_CHECK_FAILED = 2
def _popcount(a):
count = 0
while a != 0:
a &= a - 1
count += 1
return count
def _parityb(a):
a = (a ^ (a >> 1))
a = (a ^ (a >> 2))
a = (a ^ (a >> 4))
return a & 1
def _make_ecc_tables():
parity_table = [_parityb(b)
for b in range(256)]
cpmasks = [0x55, 0x33, 0x0F, 0x00, 0xAA, 0xCC, 0xF0]
column_parity_masks = [None] * 256
for b in range(256):
mask = 0
for i in range(len(cpmasks)):
mask |= parity_table[b & cpmasks[i]] << i
column_parity_masks[b] = mask
return parity_table, column_parity_masks
_parity_table, _column_parity_masks = _make_ecc_tables()
def _ecc_calculate(s):
"Calculate the Hamming code for a 128 byte long string or byte array."
if not isinstance(s, array.array):
a = array.array('B')
a.fromstring(s)
s = a
column_parity = 0x77
line_parity_0 = 0x7F
line_parity_1 = 0x7F
for i in range(len(s)):
b = s[i]
column_parity ^= _column_parity_masks[b]
if _parity_table[b]:
line_parity_0 ^= ~i
line_parity_1 ^= i
return [column_parity, line_parity_0 & 0x7F, line_parity_1]
def _ecc_check(s, ecc):
"""Detect and correct any single bit errors.
The parameters "s" and "ecc", the data and expected Hamming code
repectively, must be modifiable sequences of integers and are
updated with the corrected values if necessary."""
computed = ecc_calculate(s)
if computed == ecc:
return ECC_CHECK_OK
#print
#_print_bin(0, s.tostring())
#print "computed %02x %02x %02x" % tuple(computed)
#print "actual %02x %02x %02x" % tuple(ecc)
# ECC mismatch
cp_diff = (computed[0] ^ ecc[0]) & 0x77
lp0_diff = (computed[1] ^ ecc[1]) & 0x7F
lp1_diff = (computed[2] ^ ecc[2]) & 0x7F
lp_comp = lp0_diff ^ lp1_diff
cp_comp = (cp_diff >> 4) ^ (cp_diff & 0x07)
#print "%02x %02x %02x %02x %02x" % (cp_diff, lp0_diff, lp1_diff,
# lp_comp, cp_comp)
if lp_comp == 0x7F and cp_comp == 0x07:
print "corrected 1"
# correctable 1 bit error in data
s[lp1_diff] ^= 1 << (cp_diff >> 4)
return ECC_CHECK_CORRECTED
if ((cp_diff == 0 and lp0_diff == 0 and lp1_diff == 0)
or _popcount(lp_comp) + _popcount(cp_comp) == 1):
print "corrected 2"
# correctable 1 bit error in ECC
# (and/or one of the unused bits was set)
ecc[0] = computed[0]
ecc[1] = computed[1]
ecc[2] = computed[2]
return ECC_CHECK_CORRECTED
# uncorrectable error
return ECC_CHECK_FAILED
def ecc_calculate_page(page):
"""Return a list of the ECC codes for a PS2 memory card page."""
return [ecc_calculate(page[i * 128 : i * 128 + 128])
for i in range(div_round_up(len(page), 128))]
def ecc_check_page(page, spare):
"Check and correct any single bit errors in a PS2 memory card page."
failed = False
corrected = False
#chunks = [(array.array('B', page[i * 128 : i * 128 + 128]),
# map(ord, spare[i * 3 : i * 3 + 3]))
# for i in range(div_round_up(len(page), 128))]
chunks = []
for i in range(div_round_up(len(page), 128)):
a = array.array('B')
a.fromstring(page[i * 128 : i * 128 + 128])
chunks.append((a, map(ord, spare[i * 3 : i * 3 + 3])))
r = [ecc_check(s, ecc)
for (s, ecc) in chunks]
ret = ECC_CHECK_OK
if ECC_CHECK_CORRECTED in r:
# rebuild sector and spare from the corrected versions
page = "".join([a[0].tostring()
for a in chunks])
spare = "".join([chr(a[1][i])
for a in chunks
for i in range(3)])
ret = ECC_CHECK_CORRECTED
if ECC_CHECK_FAILED in r:
ret = ECC_CHECK_FAILED
return (ret, page, spare)
if mymcsup == None:
ecc_calculate = _ecc_calculate
ecc_check = _ecc_check
else:
# _c_ubyte_p = ctypes.POINTER(ctypes.c_ubyte)
def ecc_calculate(s):
aecc = array.array('B', "\0\0\0")
cecc = ctypes.c_ubyte.from_address(aecc.buffer_info()[0])
mymcsup.ecc_calculate(s, len(s), cecc)
return list(aecc)
def ecc_check(s, ecc):
cs = ctypes.c_ubyte.from_address(s.buffer_info()[0])
# print "%08X" % s.buffer_info()[0]
aecc = array.array('B', ecc)
cecc = ctypes.c_ubyte.from_address(aecc.buffer_info()[0])
ret = mymcsup.ecc_check(cs, len(s), cecc)
ecc[0] = aecc[0]
ecc[1] = aecc[1]
ecc[2] = aecc[2]
return ret