else: pass # can't do this.
_sys.setdlopenflags(_dlflags)
-import _base
+if _sys.version_info >= (3,): from . import _base
+else: import _base
if _odlflags >= 0:
_sys.setdlopenflags(_odlflags)
lostexchook = default_lostexchook
## Text/binary conversions.
-def _bin(s): return s
+if _sys.version_info >= (3,):
+ def _bin(s): return s.encode('iso8859-1')
+else:
+ def _bin(s): return s
## Iterating over dictionaries.
-def _iteritems(dict): return dict.iteritems()
-def _itervalues(dict): return dict.itervalues()
+if _sys.version_info >= (3,):
+ def _iteritems(dict): return dict.items()
+ def _itervalues(dict): return dict.values()
+else:
+ def _iteritems(dict): return dict.iteritems()
+ def _itervalues(dict): return dict.itervalues()
+
+## The built-in bignum type.
+try: long
+except NameError: _long = int
+else: _long = long
## How to fix a name back into the right identifier. Alas, the rules are not
## consistent.
_pp_commas(pp, p, items)
###--------------------------------------------------------------------------
+### Mappings.
+
+if _sys.version_info >= (3,):
+ class _tmp:
+ def __str__(me): return '%s(%r)' % (type(me).__name__, list(me))
+ __repr__ = __str__
+ def _repr_pretty_(me, pp, cyclep):
+ ind = _pp_bgroup_tyname(pp, me, '([')
+ _pp_commas(pp, pp.pretty, me)
+ pp.end_group(ind, '])')
+ _augment(_base._KeyView, _tmp)
+ _augment(_base._ValueView, _tmp)
+ _augment(_base._ItemView, _tmp)
+
+###--------------------------------------------------------------------------
### Bytestrings.
class _tmp:
def fromhex(x):
return ByteString(_unhexify(x))
fromhex = staticmethod(fromhex)
- def hex(me): return _hexify(me)
- __hex__ = hex
+ if _sys.version_info >= (3,):
+ def hex(me): return _hexify(me).decode()
+ else:
+ def hex(me): return _hexify(me)
+ __hex__ = hex
def __repr__(me):
return 'bytes(%r)' % me.hex()
_augment(ByteString, _tmp)
_augment(GHash, _tmp)
_augment(Poly1305Hash, _tmp)
-class _HashBase (object):
- ## The standard hash methods. Assume that `hash' is defined and returns
- ## the receiver.
- def _check_range(me, n, max):
- if not (0 <= n <= max): raise OverflowError("out of range")
- def hashu8(me, n):
- me._check_range(n, 0xff)
- return me.hash(_pack('B', n))
- def hashu16l(me, n):
- me._check_range(n, 0xffff)
- return me.hash(_pack('<H', n))
- def hashu16b(me, n):
- me._check_range(n, 0xffff)
- return me.hash(_pack('>H', n))
- hashu16 = hashu16b
- def hashu32l(me, n):
- me._check_range(n, 0xffffffff)
- return me.hash(_pack('<L', n))
- def hashu32b(me, n):
- me._check_range(n, 0xffffffff)
- return me.hash(_pack('>L', n))
- hashu32 = hashu32b
- def hashu64l(me, n):
- me._check_range(n, 0xffffffffffffffff)
- return me.hash(_pack('<Q', n))
- def hashu64b(me, n):
- me._check_range(n, 0xffffffffffffffff)
- return me.hash(_pack('>Q', n))
- hashu64 = hashu64b
- def hashbuf8(me, s): return me.hashu8(len(s)).hash(s)
- def hashbuf16l(me, s): return me.hashu16l(len(s)).hash(s)
- def hashbuf16b(me, s): return me.hashu16b(len(s)).hash(s)
- hashbuf16 = hashbuf16b
- def hashbuf32l(me, s): return me.hashu32l(len(s)).hash(s)
- def hashbuf32b(me, s): return me.hashu32b(len(s)).hash(s)
- hashbuf32 = hashbuf32b
- def hashbuf64l(me, s): return me.hashu64l(len(s)).hash(s)
- def hashbuf64b(me, s): return me.hashu64b(len(s)).hash(s)
- hashbuf64 = hashbuf64b
- def hashstrz(me, s): return me.hash(s).hashu8(0)
-
-class _ShakeBase (_HashBase):
-
- ## Python gets really confused if I try to augment `__new__' on native
- ## classes, so wrap and delegate. Sorry.
- def __init__(me, perso = _bin(''), *args, **kw):
- super(_ShakeBase, me).__init__(*args, **kw)
- me._h = me._SHAKE(perso = perso, func = me._FUNC)
-
- ## Delegate methods...
- def copy(me): new = me.__class__._bare_new(); new._copy(me); return new
- def _copy(me, other): me._h = other._h.copy()
- def hash(me, m): me._h.hash(m); return me
- def xof(me): me._h.xof(); return me
- def get(me, n): return me._h.get(n)
- def mask(me, m): return me._h.mask(m)
- def done(me, n): return me._h.done(n)
- def check(me, h): return ctstreq(h, me.done(len(h)))
- @property
- def state(me): return me._h.state
- @property
- def buffered(me): return me._h.buffered
- @property
- def rate(me): return me._h.rate
- @classmethod
- def _bare_new(cls): return cls()
-
class _tmp:
def check(me, h):
return ctstreq(h, me.done(len(h)))
- def leftenc(me, n):
- nn = MP(n).storeb()
- return me.hashu8(len(nn)).hash(nn)
- def rightenc(me, n):
- nn = MP(n).storeb()
- return me.hash(nn).hashu8(len(nn))
- def stringenc(me, str):
- return me.leftenc(8*len(str)).hash(str)
- def bytepad_before(me):
- return me.leftenc(me.rate)
- def bytepad_after(me):
- if me.buffered: me.hash(me._Z[:me.rate - me.buffered])
- return me
- @_ctxmgr
- def bytepad(me):
- me.bytepad_before()
- yield me
- me.bytepad_after()
_augment(Shake, _tmp)
-_augment(_ShakeBase, _tmp)
-Shake._Z = _ShakeBase._Z = ByteString.zero(200)
-
-class KMAC (_ShakeBase):
- _FUNC = _bin('KMAC')
- def __init__(me, k, *arg, **kw):
- super(KMAC, me).__init__(*arg, **kw)
- with me.bytepad(): me.stringenc(k)
- def done(me, n = -1):
- if n < 0: n = me._TAGSZ
- me.rightenc(8*n)
- return super(KMAC, me).done(n)
- def xof(me):
- me.rightenc(0)
- return super(KMAC, me).xof()
- @classmethod
- def _bare_new(cls): return cls(_bin(""))
-class KMAC128 (KMAC): _SHAKE = Shake128; _TAGSZ = 16
-class KMAC256 (KMAC): _SHAKE = Shake256; _TAGSZ = 32
+KMAC128.keysz = KeySZAny(16); KMAC128.tagsz = 16
+KMAC256.keysz = KeySZAny(32); KMAC256.tagsz = 32
###--------------------------------------------------------------------------
### NaCl `secretbox'.
###--------------------------------------------------------------------------
### Multiprecision integers and binary polynomials.
-def _split_rat(x):
- if isinstance(x, BaseRat): return x._n, x._d
- else: return x, 1
class BaseRat (object):
"""Base class implementing fields of fractions over Euclidean domains."""
def __new__(cls, a, b):
- a, b = cls.RING(a), cls.RING(b)
+ a, b = cls.RING._implicit(a), cls.RING._implicit(b)
q, r = divmod(a, b)
- if r == 0: return q
+ if r == cls.ZERO: return q
g = b.gcd(r)
me = super(BaseRat, cls).__new__(cls)
me._n = a//g
def __repr__(me): return '%s(%s, %s)' % (_clsname(me), me._n, me._d)
_repr_pretty_ = _pp_str
+ def _split_rat(me, x):
+ if isinstance(x, me.__class__): return x._n, x._d
+ else: return x, me.ONE
def __add__(me, you):
- n, d = _split_rat(you)
+ n, d = me._split_rat(you)
return type(me)(me._n*d + n*me._d, d*me._d)
__radd__ = __add__
def __sub__(me, you):
- n, d = _split_rat(you)
+ n, d = me._split_rat(you)
return type(me)(me._n*d - n*me._d, d*me._d)
def __rsub__(me, you):
- n, d = _split_rat(you)
+ n, d = me._split_rat(you)
return type(me)(n*me._d - me._n*d, d*me._d)
def __mul__(me, you):
- n, d = _split_rat(you)
+ n, d = me._split_rat(you)
return type(me)(me._n*n, me._d*d)
__rmul__ = __mul__
def __truediv__(me, you):
- n, d = _split_rat(you)
+ n, d = me._split_rat(you)
return type(me)(me._n*d, me._d*n)
def __rtruediv__(me, you):
- n, d = _split_rat(you)
+ n, d = me._split_rat(you)
return type(me)(me._d*n, me._n*d)
- __div__ = __truediv__
- __rdiv__ = __rtruediv__
+ if _sys.version_info < (3,):
+ __div__ = __truediv__
+ __rdiv__ = __rtruediv__
def _order(me, you, op):
- n, d = _split_rat(you)
+ n, d = me._split_rat(you)
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)
class IntRat (BaseRat):
RING = MP
+ ZERO, ONE = MP(0), MP(1)
+ 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
+ ZERO, ONE = GF(0), GF(1)
class _tmp:
def negp(x): return x < 0
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)
- __div__ = __truediv__
- __rdiv__ = __rtruediv__
+ 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)
+ if _sys.version_info < (3,):
+ __div__ = __truediv__
+ __rdiv__ = __rtruediv__
_repr_pretty_ = _pp_str
_augment(MP, _tmp)
def quadsolve(x, y): return x.reduce().quadsolve(y)
def __truediv__(me, you): return GFRat(me, you)
def __rtruediv__(me, you): return GFRat(you, me)
- __div__ = __truediv__
- __rdiv__ = __rtruediv__
+ if _sys.version_info < (3,):
+ __div__ = __truediv__
+ __rdiv__ = __rtruediv__
_repr_pretty_ = _pp_str
_augment(GF, _tmp)
_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)
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')
- elif sz > me.max: return me.max
+ elif me.max is not None and 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 me.max is not None and 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)