_sys.stderr.write("\n")
lostexchook = default_lostexchook
+## Text/binary conversions.
+def _bin(s): return s
+
+## Iterating over dictionaries.
+def _iteritems(dict): return dict.iteritems()
+def _itervalues(dict): return dict.itervalues()
+
+## The built-in bignum type.
+_long = long
+
## How to fix a name back into the right identifier. Alas, the rules are not
## consistent.
def _fixname(name):
for i in b:
if i[0] != '_':
d[i] = b[i];
- for i in ['ByteString',
- 'MP', 'GF', 'Field',
- 'ECPt', 'ECPtCurve', 'ECCurve', 'ECInfo',
- 'DHInfo', 'BinDHInfo', 'RSAPriv', 'BBSPriv',
- 'PrimeFilter', 'RabinMiller',
- 'Group', 'GE',
- 'KeySZ', 'KeyData']:
- c = d[i]
- pre = '_' + i + '_'
- plen = len(pre)
- for j in b:
- if j[:plen] == pre:
- setattr(c, j[plen:], classmethod(b[j]))
for i in [gcciphers, gcaeads, gchashes, gcmacs, gcprps]:
- for c in i.itervalues():
+ for c in _itervalues(i):
d[_fixname(c.name)] = c
- for c in gccrands.itervalues():
+ for c in _itervalues(gccrands):
d[_fixname(c.name + 'rand')] = c
_init()
def _checkend(r):
x, rest = r
if rest != '':
- raise SyntaxError, 'junk at end of string'
+ raise SyntaxError('junk at end of string')
return x
## Some pretty-printing utilities.
else: pp.text(','); pp.breakable()
printfn(i)
def _pp_dict(pp, items):
- def p((k, v)):
+ def p(kv):
+ k, v = kv
pp.begin_group(0)
pp.pretty(k)
pp.text(':')
def fromhex(x):
return ByteString(_unhexify(x))
fromhex = staticmethod(fromhex)
- def __hex__(me):
- return _hexify(me)
+ def hex(me): return _hexify(me)
+ __hex__ = hex
def __repr__(me):
- return 'bytes(%r)' % hex(me)
+ return 'bytes(%r)' % me.hex()
_augment(ByteString, _tmp)
ByteString.__hash__ = str.__hash__
bytes = ByteString.fromhex
### Symmetric encryption.
class _tmp:
- def encrypt(me, n, m, tsz = None, h = ByteString('')):
+ def encrypt(me, n, m, tsz = None, h = ByteString.zero(0)):
if tsz is None: tsz = me.__class__.tagsz.default
e = me.enc(n, len(h), len(m), tsz)
if not len(h): a = None
c0 = e.encrypt(m)
c1, t = e.done(aad = a)
return c0 + c1, t
- def decrypt(me, n, c, t, h = ByteString('')):
+ def decrypt(me, n, c, t, h = ByteString.zero(0)):
d = me.dec(n, len(h), len(c), len(t))
if not len(h): a = None
else: a = d.aad().hash(h)
## Python gets really confused if I try to augment `__new__' on native
## classes, so wrap and delegate. Sorry.
- def __init__(me, perso = '', *args, **kw):
+ def __init__(me, perso = _bin(''), *args, **kw):
super(_ShakeBase, me).__init__(*args, **kw)
me._h = me._SHAKE(perso = perso, func = me._FUNC)
Shake._Z = _ShakeBase._Z = ByteString.zero(200)
class KMAC (_ShakeBase):
- _FUNC = 'KMAC'
+ _FUNC = _bin('KMAC')
def __init__(me, k, *arg, **kw):
super(KMAC, me).__init__(*arg, **kw)
with me.bytepad(): me.stringenc(k)
me.rightenc(0)
return super(KMAC, me).xof()
@classmethod
- def _bare_new(cls): return cls("")
+ def _bare_new(cls): return cls(_bin(""))
class KMAC128 (KMAC): _SHAKE = Shake128; _TAGSZ = 16
class KMAC256 (KMAC): _SHAKE = Shake256; _TAGSZ = 32
return type(me)(me._d*n, me._n*d)
__div__ = __truediv__
__rdiv__ = __rtruediv__
- def __cmp__(me, you):
- n, d = _split_rat(you)
- return cmp(me._n*d, n*me._d)
- def __rcmp__(me, you):
+ def _order(me, you, op):
n, d = _split_rat(you)
- return cmp(n*me._d, me._n*d)
+ return op(me._n*d, n*me._d)
+ def __eq__(me, you): return me._order(you, lambda x, y: x == y)
+ def __ne__(me, you): return me._order(you, lambda x, y: x != y)
+ def __le__(me, you): return me._order(you, lambda x, y: x <= y)
+ def __lt__(me, you): return me._order(you, lambda x, y: x < y)
+ def __gt__(me, you): return me._order(you, lambda x, y: x > y)
+ def __ge__(me, you): return me._order(you, lambda x, y: x >= y)
class IntRat (BaseRat):
RING = MP
+ def __new__(cls, a, b):
+ if isinstance(a, float) or isinstance(b, float): return a/b
+ return super(IntRat, cls).__new__(cls, a, b)
+ def __float__(me): return float(me._n)/float(me._d)
class GFRat (BaseRat):
RING = GF
def mont(x): return MPMont(x)
def barrett(x): return MPBarrett(x)
def reduce(x): return MPReduce(x)
- def __truediv__(me, you): return IntRat(me, you)
- def __rtruediv__(me, you): return IntRat(you, me)
+ def __truediv__(me, you):
+ if isinstance(you, float): return _long(me)/you
+ else: return IntRat(me, you)
+ def __rtruediv__(me, you):
+ if isinstance(you, float): return you/_long(me)
+ else: return IntRat(you, me)
__div__ = __truediv__
__rdiv__ = __rtruediv__
_repr_pretty_ = _pp_str
_augment(Field, _tmp)
class _tmp:
- def __repr__(me): return '%s(%sL)' % (_clsname(me), me.p)
+ def __repr__(me): return '%s(%s)' % (_clsname(me), me.p)
def __hash__(me): return 0x114401de ^ hash(me.p)
def _repr_pretty_(me, pp, cyclep):
ind = _pp_bgroup_tyname(pp, me)
_augment(PrimeField, _tmp)
class _tmp:
- def __repr__(me): return '%s(%#xL)' % (_clsname(me), me.p)
+ def __repr__(me): return '%s(%#x)' % (_clsname(me), me.p)
def ec(me, a, b): return ECBinProjCurve(me, a, b)
def _repr_pretty_(me, pp, cyclep):
ind = _pp_bgroup_tyname(pp, me)
pp.end_group(ind, ')')
def check(me, sz): return me.min <= sz <= me.max and sz%me.mod == 0
def best(me, sz):
- if sz < me.min: raise ValueError, 'key too small'
+ if sz < me.min: raise ValueError('key too small')
elif sz > me.max: return me.max
else: return sz - sz%me.mod
def pad(me, sz):
- if sz > me.max: raise ValueError, 'key too large'
+ if sz > me.max: raise ValueError('key too large')
elif sz < me.min: return me.min
else: sz += me.mod - 1; return sz - sz%me.mod
_augment(KeySZRange, _tmp)
found = -1
for i in me.set:
if found < i <= sz: found = i
- if found < 0: raise ValueError, 'key too small'
+ if found < 0: raise ValueError('key too small')
return found
def pad(me, sz):
found = -1
for i in me.set:
if sz <= i and (found == -1 or i < found): found = i
- if found < 0: raise ValueError, 'key too large'
+ if found < 0: raise ValueError('key too large')
return found
_augment(KeySZSet, _tmp)
### Key data objects.
class _tmp:
+ def merge(me, file, report = None):
+ """KF.merge(FILE, [report = <built-in-reporter>])"""
+ name = file.name
+ lno = 1
+ for line in file:
+ me.mergeline(name, lno, line, report)
+ lno += 1
+ return me
def __repr__(me): return '%s(%r)' % (_clsname(me), me.name)
_augment(KeyFile, _tmp)
class _tmp:
+ def extract(me, file, filter = ''):
+ """KEY.extract(FILE, [filter = <any>])"""
+ line = me.extractline(filter)
+ file.write(line)
+ return me
def __repr__(me): return '%s(%r)' % (_clsname(me), me.fulltag)
_augment(Key, _tmp)
class _tmp:
def __repr__(me):
return '%s({%s})' % (_clsname(me),
- ', '.join(['%r: %r' % kv for kv in me.iteritems()]))
+ ', '.join(['%r: %r' % kv for kv in _iteritems(me)()]))
def _repr_pretty_(me, pp, cyclep):
ind = _pp_bgroup_tyname(pp, me)
if cyclep: pp.text('...')
- else: _pp_dict(pp, me.iteritems())
+ else: _pp_dict(pp, _iteritems(me))
pp.end_group(ind, ')')
_augment(KeyAttributes, _tmp)
pp.text(','); pp.breakable()
pp.pretty(me.writeflags(me.flags))
pp.end_group(ind, ')')
+ def __hash__(me): return me._HASHBASE ^ hash(me._guts())
+ def __eq__(me, kd):
+ return type(me) == type(kd) and \
+ me._guts() == kd._guts() and \
+ me.flags == kd.flags
+ def __ne__(me, kd):
+ return not me == kd
_augment(KeyData, _tmp)
class _tmp:
def _guts(me): return me.bin
+ def __eq__(me, kd):
+ return isinstance(kd, KeyDataBinary) and me.bin == kd.bin
_augment(KeyDataBinary, _tmp)
+KeyDataBinary._HASHBASE = 0x961755c3
class _tmp:
def _guts(me): return me.ct
_augment(KeyDataEncrypted, _tmp)
+KeyDataEncrypted._HASHBASE = 0xffe000d4
class _tmp:
def _guts(me): return me.mp
_augment(KeyDataMP, _tmp)
+KeyDataMP._HASHBASE = 0x1cb64d69
class _tmp:
def _guts(me): return me.str
_augment(KeyDataString, _tmp)
+KeyDataString._HASHBASE = 0x349c33ea
class _tmp:
def _guts(me): return me.ecpt
_augment(KeyDataECPt, _tmp)
+KeyDataECPt._HASHBASE = 0x2509718b
class _tmp:
def __repr__(me):
return '%s({%s})' % (_clsname(me),
- ', '.join(['%r: %r' % kv for kv in me.iteritems()]))
+ ', '.join(['%r: %r' % kv for kv in _iteritems(me)]))
def _repr_pretty_(me, pp, cyclep):
ind = _pp_bgroup_tyname(pp, me, '({ ')
if cyclep: pp.text('...')
- else: _pp_dict(pp, me.iteritems())
+ else: _pp_dict(pp, _iteritems(me))
pp.end_group(ind, ' })')
+ def __hash__(me):
+ h = me._HASHBASE
+ for k, v in _iteritems(me):
+ h = ((h << 1) ^ 3*hash(k) ^ 5*hash(v))&0xffffffff
+ return h
+ def __eq__(me, kd):
+ if type(me) != type(kd) or me.flags != kd.flags or len(me) != len(kd):
+ return False
+ for k, v in _iteritems(me):
+ try: vv = kd[k]
+ except KeyError: return False
+ if v != vv: return False
+ return True
_augment(KeyDataStructured, _tmp)
+KeyDataStructured._HASHBASE = 0x85851b21
###--------------------------------------------------------------------------
### Abstract groups.
### RSA encoding techniques.
class PKCS1Crypt (object):
- def __init__(me, ep = '', rng = rand):
+ def __init__(me, ep = _bin(''), rng = rand):
me.ep = ep
me.rng = rng
def encode(me, msg, nbits):
return _base._p1crypt_decode(ct, nbits, me.ep, me.rng)
class PKCS1Sig (object):
- def __init__(me, ep = '', rng = rand):
+ def __init__(me, ep = _bin(''), rng = rand):
me.ep = ep
me.rng = rng
def encode(me, msg, nbits):
return _base._p1sig_decode(msg, sig, nbits, me.ep, me.rng)
class OAEP (object):
- def __init__(me, mgf = sha_mgf, hash = sha, ep = '', rng = rand):
+ def __init__(me, mgf = sha_mgf, hash = sha, ep = _bin(''), rng = rand):
me.mgf = mgf
me.hash = hash
me.ep = ep
class _BasePub (object):
def __init__(me, pub, *args, **kw):
- if not me._PUBSZ.check(len(pub)): raise ValueError, 'bad public key'
+ if not me._PUBSZ.check(len(pub)): raise ValueError('bad public key')
super(_BasePub, me).__init__(*args, **kw)
me.pub = pub
def __repr__(me): return '%s(pub = %r)' % (_clsname(me), me.pub)
class _BasePriv (object):
def __init__(me, priv, pub = None, *args, **kw):
- if not me._KEYSZ.check(len(priv)): raise ValueError, 'bad private key'
+ if not me._KEYSZ.check(len(priv)): raise ValueError('bad private key')
if pub is None: pub = me._pubkey(priv)
super(_BasePriv, me).__init__(pub = pub, *args, **kw)
me.priv = priv
return ed448_sign(me.priv, msg, pub = me.pub, **kw)
###--------------------------------------------------------------------------
-### Built-in named curves and prime groups.
-
-class _groupmap (object):
- def __init__(me, map, nth):
- me.map = map
- me.nth = nth
- me._n = max(map.values()) + 1
- me.i = me._n*[None]
+### Built-in algorithm and group tables.
+
+class _tmp:
def __repr__(me):
- return '{%s}' % ', '.join(['%r: %r' % kv for kv in me.iteritems()])
+ return '{%s}' % ', '.join(['%r: %r' % kv for kv in _iteritems(me)])
def _repr_pretty_(me, pp, cyclep):
ind = _pp_bgroup(pp, '{ ')
if cyclep: pp.text('...')
- else: _pp_dict(pp, me.iteritems())
+ else: _pp_dict(pp, _iteritems(me))
pp.end_group(ind, ' }')
- def __len__(me):
- return me._n
- def __contains__(me, k):
- return k in me.map
- def __getitem__(me, k):
- i = me.map[k]
- if me.i[i] is None:
- me.i[i] = me.nth(i)
- return me.i[i]
- def __setitem__(me, k, v):
- raise TypeError, "immutable object"
- def __iter__(me):
- return iter(me.map)
- def iterkeys(me):
- return iter(me.map)
- def itervalues(me):
- for k in me:
- yield me[k]
- def iteritems(me):
- for k in me:
- yield k, me[k]
- def keys(me):
- return [k for k in me]
- def values(me):
- return [me[k] for k in me]
- def items(me):
- return [(k, me[k]) for k in me]
-eccurves = _groupmap(_base._eccurves, ECInfo._curven)
-primegroups = _groupmap(_base._pgroups, DHInfo._groupn)
-bingroups = _groupmap(_base._bingroups, BinDHInfo._groupn)
+_augment(_base._MiscTable, _tmp)
###--------------------------------------------------------------------------
### Prime number generation.
me.add = add
def _stepfn(me, step):
if step <= 0:
- raise ValueError, 'step must be positive'
+ raise ValueError('step must be positive')
if step <= MPW_MAX:
return lambda f: f.step(step)
j = PrimeFilter(step)