return (MP_COPY(PFILT_F(o)->m));
else if (ECPT_PYCHECK(o)) {
ec p = EC_INIT;
+ if (EC_ATINF(ECPT_P(o))) return (0);
getecptout(&p, o);
x = MP_COPY(p.x);
EC_DESTROY(&p);
mp *z;
mp_pyobj *zz = 0;
int radix = 0;
- char *kwlist[] = { "x", "radix", 0 };
+ static const char *const kwlist[] = { "x", "radix", 0 };
- if (!PyArg_ParseTupleAndKeywords(arg, kw, "O|i:new", kwlist, &x, &radix))
+ if (!PyArg_ParseTupleAndKeywords(arg, kw, "O|i:new", KWLIST, &x, &radix))
goto end;
if (MP_PYCHECK(x)) RETURN_OBJ(x);
if (!good_radix_p(radix, 1)) VALERR("bad radix");
static PyObject *mpmeth_tostring(PyObject *me, PyObject *arg, PyObject *kw)
{
int radix = 10;
- char *kwlist[] = { "radix", 0 };
- if (!PyArg_ParseTupleAndKeywords(arg, kw, "|i:tostring", kwlist, &radix))
+ static const char *const kwlist[] = { "radix", 0 };
+ if (!PyArg_ParseTupleAndKeywords(arg, kw, "|i:tostring", KWLIST, &radix))
goto end;
if (!good_radix_p(radix, 0)) VALERR("bad radix");
return (mp_topystring(MP_X(me), radix, 0, 0, 0));
PyObject *arg, PyObject *kw) \
{ \
long len = -1; \
- char *kwlist[] = { "len", 0 }; \
+ static const char *const kwlist[] = { "len", 0 }; \
PyObject *rc = 0; \
\
if (!PyArg_ParseTupleAndKeywords(arg, kw, "|l:" #name, \
- kwlist, &len)) \
+ KWLIST, &len)) \
goto end; \
if (len < 0) { \
len = mp_octets##c(MP_X(me)); \
static PyObject *mpmeth_primep(PyObject *me, PyObject *arg, PyObject *kw)
{
grand *r = &rand_global;
- char *kwlist[] = { "rng", 0 };
+ static const char *const kwlist[] = { "rng", 0 };
PyObject *rc = 0;
- if (!PyArg_ParseTupleAndKeywords(arg, kw, "|O&", kwlist, convgrand, &r))
+ if (!PyArg_ParseTupleAndKeywords(arg, kw, "|O&", KWLIST, convgrand, &r))
goto end;
rc = getbool(pgen_primep(MP_X(me), r));
end:
static PyObject *mpget_noctets2c(PyObject *me, void *hunoz)
{ return (PyInt_FromLong(mp_octets2c(MP_X(me)))); }
-static PyGetSetDef mp_pygetset[] = {
+static const PyGetSetDef mp_pygetset[] = {
#define GETSETNAME(op, func) mp##op##_##func
GET (nbits, "X.nbits -> bit length of X")
GET (noctets, "X.noctets -> octet length of X")
{ 0 }
};
-static PyMethodDef mp_pymethods[] = {
+static const PyMethodDef mp_pymethods[] = {
#define METHNAME(func) mpmeth_##func
- METH (jacobi, "X.jacobi(Y) -> Jacobi symbol (Y/X) (NB inversion!)")
+ METH (jacobi, "X.jacobi(Y) -> Jacobi symbol (Y|X) (NB inversion!)")
METH (setbit, "X.setbit(N) -> X with bit N set")
METH (clearbit, "X.clearbit(N) -> X with bit N clear")
METH (testbit, "X.testbit(N) -> true/false if bit N set/clear in X")
METH (sqr, "X.sqr() -> X^2")
METH (sqrt, "X.sqrt() -> largest integer <= sqrt(X)")
METH (gcd, "X.gcd(Y) -> gcd(X, Y)")
- METH (gcdx,
- "X.gcdx(Y) -> (gcd(X, Y), U, V) with X U + Y V = gcd(X, Y)")
+ METH (gcdx, "X.gcdx(Y) -> (gcd(X, Y), U, V) "
+ "with X U + Y V = gcd(X, Y)")
METH (modinv, "X.modinv(Y) -> multiplicative inverse of Y mod X")
METH (modsqrt, "X.modsqrt(Y) -> square root of Y mod X, if X prime")
- METH (leastcongruent,
- "X.leastcongruent(B, M) -> smallest Z >= B with Z == X (mod M)")
- KWMETH(primep, "X.primep(rng = rand) -> true/false if X is prime")
- KWMETH(tostring, "X.tostring(radix = 10) -> STR")
- KWMETH(storel, "X.storel(len = -1) -> little-endian bytes")
- KWMETH(storeb, "X.storeb(len = -1) -> big-endian bytes")
- KWMETH(storel2c,
- "X.storel2c(len = -1) -> little-endian bytes, two's complement")
- KWMETH(storeb2c,
- "X.storeb2c(len = -1) -> big-endian bytes, two's complement")
+ METH (leastcongruent, "X.leastcongruent(B, M) -> "
+ "smallest Z >= B with Z == X (mod M)")
+ KWMETH(primep, "X.primep([rng = rand]) -> X is prime?")
+ KWMETH(tostring, "X.tostring([radix = 10]) -> STR")
+ KWMETH(storel, "X.storel([len = -1]) -> little-endian bytes")
+ KWMETH(storeb, "X.storeb([len = -1]) -> big-endian bytes")
+ KWMETH(storel2c, "X.storel2c([len = -1]) -> "
+ "little-endian bytes, two's complement")
+ KWMETH(storeb2c, "X.storeb2c([len = -1]) -> "
+ "big-endian bytes, two's complement")
METH (tobuf, "X.tobuf() -> buffer format")
#undef METHNAME
{ 0 }
};
-static PyNumberMethods mp_pynumber = {
+static const PyNumberMethods mp_pynumber = {
mp_pyadd, /* @nb_add@ */
mp_pysub, /* @nb_subtract@ */
mp_pymul, /* @nb_multiply@ */
0, /* @tp_setattr@ */
mp_pycompare, /* @tp_compare@ */
mp_pyrepr, /* @tp_repr@ */
- &mp_pynumber, /* @tp_as_number@ */
+ PYNUMBER(mp), /* @tp_as_number@ */
0, /* @tp_as_sequence@ */
0, /* @tp_as_mapping@ */
mp_pyhash, /* @tp_hash@ */
Py_TPFLAGS_BASETYPE,
/* @tp_doc@ */
-"Multiprecision integers, similar to `long' but more efficient and\n\
-versatile. Support all the standard arithmetic operations, with\n\
-implicit conversions from `PrimeFilter', and other objects which\n\
-convert to `long'.\n\
-\n\
-Constructor MP(X, radix = R) attempts to convert X to an `MP'. If\n\
-X is a string, it's read in radix-R form, or we look for a prefix\n\
-if R = 0. Other acceptable things are field elements, elliptic curve\n\
-points, group elements, Python `int' and `long' objects, and anything\n\
-with an integer conversion.\n\
-\n\
-Notes:\n\
-\n\
- * Use `//' for division. MPs don't have `/' division.",
+ "Multiprecision integers, similar to `long' but more efficient and\n"
+ "versatile. Support all the standard arithmetic operations, with\n"
+ "implicit conversions from `PrimeFilter', and other objects which\n"
+ "convert to `long'.\n"
+ "\n"
+ "Constructor MP(X, [radix = R]) attempts to convert X to an `MP'. If\n"
+ "X is a string, it's read in radix-R form, or we look for a prefix\n"
+ "if R = 0. Other acceptable things are field elements, elliptic curve\n"
+ "points, group elements, Python `int' and `long' objects, and anything\n"
+ "with an integer conversion.\n"
+ "\n"
+ "Notes:\n"
+ "\n"
+ " * Use `//' for integer division: `/' gives exact rational division.",
0, /* @tp_traverse@ */
0, /* @tp_clear@ */
0, /* @tp_weaklistoffset@ */
0, /* @tp_iter@ */
0, /* @tp_iternext@ */
- mp_pymethods, /* @tp_methods@ */
+ PYMETHODS(mp), /* @tp_methods@ */
0, /* @tp_members@ */
- mp_pygetset, /* @tp_getset@ */
+ PYGETSET(mp), /* @tp_getset@ */
0, /* @tp_base@ */
0, /* @tp_dict@ */
0, /* @tp_descr_get@ */
PyObject *z = 0;
mp *zz;
mptext_stringctx sc;
- char *kwlist[] = { "class", "x", "radix", 0 };
+ static const char *const kwlist[] = { "class", "x", "radix", 0 };
if (!PyArg_ParseTupleAndKeywords(arg, kw, "Os#|i:fromstring",
- kwlist, &me, &p, &len, &r))
+ KWLIST, &me, &p, &len, &r))
goto end;
if (!good_radix_p(r, 1)) VALERR("bad radix");
sc.buf = p; sc.lim = p + len;
mp *x;
if (!MPMUL_LIVEP(me)) VALERR("MPMul object invalid");
- if (PyTuple_Size(arg) != 1)
+ if (PyTuple_GET_SIZE(arg) != 1)
i = PyObject_GetIter(arg);
else {
- if ((q = PyTuple_GetItem(arg, 0)) == 0) goto end;
+ if ((q = PyTuple_GET_ITEM(arg, 0)) == 0) goto end;
if ((i = PyObject_GetIter(q)) == 0) {
PyErr_Clear(); /* that's ok */
i = PyObject_GetIter(arg);
static PyObject *mmget_livep(PyObject *me, void *hunoz)
{ return (getbool(MPMUL_LIVEP(me))); }
-static PyGetSetDef mpmul_pygetset[] = {
+static const PyGetSetDef mpmul_pygetset[] = {
#define GETSETNAME(op, name) mm##op##_##name
- GET (livep, "MM.livep -> flag: object still valid?")
+ GET (livep, "MM.livep -> flag: object still valid?")
#undef GETSETNAME
{ 0 }
};
-static PyMethodDef mpmul_pymethods[] = {
+static const PyMethodDef mpmul_pymethods[] = {
#define METHNAME(name) mmmeth_##name
- METH (factor, "MM.factor(ITERABLE) or MM.factor(I, ...)")
- METH (done, "MM.done() -> PRODUCT")
+ METH (factor, "MM.factor(ITERABLE) or MM.factor(I, ...)")
+ METH (done, "MM.done() -> PRODUCT")
#undef METHNAME
{ 0 }
};
Py_TPFLAGS_BASETYPE,
/* @tp_doc@ */
-"An object for multiplying many small integers.",
+ "MPMul(N_0, N_1, ....): an object for multiplying many small integers.",
0, /* @tp_traverse@ */
0, /* @tp_clear@ */
0, /* @tp_weaklistoffset@ */
0, /* @tp_iter@ */
0, /* @tp_iternext@ */
- mpmul_pymethods, /* @tp_methods@ */
+ PYMETHODS(mpmul), /* @tp_methods@ */
0, /* @tp_members@ */
- mpmul_pygetset, /* @tp_getset@ */
+ PYGETSET(mpmul), /* @tp_getset@ */
0, /* @tp_base@ */
0, /* @tp_dict@ */
0, /* @tp_descr_get@ */
static PyObject *mpmont_pynew(PyTypeObject *ty, PyObject *arg, PyObject *kw)
{
mpmont_pyobj *mm = 0;
- char *kwlist[] = { "m", 0 };
+ static const char *const kwlist[] = { "m", 0 };
mp *xx = 0;
- if (!PyArg_ParseTupleAndKeywords(arg, kw, "O&:new", kwlist, convmp, &xx))
+ if (!PyArg_ParseTupleAndKeywords(arg, kw, "O&:new", KWLIST, convmp, &xx))
goto end;
if (!MP_POSP(xx) || !MP_ODDP(xx)) VALERR("m must be positive and odd");
mm = (mpmont_pyobj *)ty->tp_alloc(ty, 0);
static PyObject *mmget_r2(PyObject *me, void *hunoz)
{ return (mp_pywrap(MP_COPY(MPMONT_PY(me)->r2))); }
-static PyGetSetDef mpmont_pygetset[] = {
+static const PyGetSetDef mpmont_pygetset[] = {
#define GETSETNAME(op, name) mm##op##_##name
GET (m, "M.m -> modulus for reduction")
GET (r, "M.r -> multiplicative identity")
{ 0 }
};
-static PyMethodDef mpmont_pymethods[] = {
+static const PyMethodDef mpmont_pymethods[] = {
#define METHNAME(name) mmmeth_##name
METH (int, "M.int(X) -> XR")
METH (mul, "M.mul(XR, YR) -> ZR where Z = X Y")
METH (expr, "M.expr(XR, N) -> ZR where Z = X^N mod M.m")
- METH (mexpr, "\
-M.mexpr([(XR0, N0), (XR1, N1), ...]) = ZR where Z = X0^N0 X1^N1 ... mod M.m\n\
-\t(the list may be flattened if this more convenient.)")
+ METH (mexpr, "M.mexpr([(XR0, N0), (XR1, N1), ...]) = ZR "
+ "where Z = X0^N0 X1^N1 ... mod M.m\n"
+ "\t(the list may be flattened if this more convenient.)")
METH (reduce, "M.reduce(XR) -> X")
METH (ext, "M.ext(XR) -> X")
METH (exp, "M.exp(X, N) -> X^N mod M.m")
- METH (mexp, "\
-M.mexp([(X0, N0), (X1, N1), ...]) = X0^N0 X1^N1 ... mod M.m\n\
-\t(the list may be flattened if this more convenient.)")
+ METH (mexp, "M.mexp([(X0, N0), (X1, N1), ...]) = "
+ "X0^N0 X1^N1 ... mod M.m\n"
+ "\t(the list may be flattened if this more convenient.)")
#undef METHNAME
{ 0 }
};
Py_TPFLAGS_BASETYPE,
/* @tp_doc@ */
-"A Montgomery reduction context.",
+ "MPMont(N): a Montgomery reduction context.",
0, /* @tp_traverse@ */
0, /* @tp_clear@ */
0, /* @tp_weaklistoffset@ */
0, /* @tp_iter@ */
0, /* @tp_iternext@ */
- mpmont_pymethods, /* @tp_methods@ */
+ PYMETHODS(mpmont), /* @tp_methods@ */
0, /* @tp_members@ */
- mpmont_pygetset, /* @tp_getset@ */
+ PYGETSET(mpmont), /* @tp_getset@ */
0, /* @tp_base@ */
0, /* @tp_dict@ */
0, /* @tp_descr_get@ */
PyObject *arg, PyObject *kw)
{
mpbarrett_pyobj *mb = 0;
- char *kwlist[] = { "m", 0 };
+ static const char *const kwlist[] = { "m", 0 };
mp *xx = 0;
- if (!PyArg_ParseTupleAndKeywords(arg, kw, "O&:new", kwlist, convmp, &xx))
+ if (!PyArg_ParseTupleAndKeywords(arg, kw, "O&:new", KWLIST, convmp, &xx))
goto end;
if (!MP_POSP(xx)) VALERR("m must be positive");
mb = (mpbarrett_pyobj *)ty->tp_alloc(ty, 0);
static PyObject *mbget_m(PyObject *me, void *hunoz)
{ return (mp_pywrap(MP_COPY(MPBARRETT_PY(me)->m))); }
-static PyGetSetDef mpbarrett_pygetset[] = {
+static const PyGetSetDef mpbarrett_pygetset[] = {
#define GETSETNAME(op, name) mb##op##_##name
GET (m, "B.m -> modulus for reduction")
#undef GETSETNAME
{ 0 }
};
-static PyMethodDef mpbarrett_pymethods[] = {
+static const PyMethodDef mpbarrett_pymethods[] = {
#define METHNAME(name) mbmeth_##name
METH (reduce, "B.reduce(X) -> X mod B.m")
METH (exp, "B.exp(X, N) -> X^N mod B.m")
- METH (mexp, "\
-B.mexp([(X0, N0), (X1, N1), ...]) = X0^N0 X1^N1 ... mod B.m\n\
-\t(the list may be flattened if this more convenient.)")
+ METH (mexp, "B.mexp([(X0, N0), (X1, N1), ...]) = "
+ "X0^N0 X1^N1 ... mod B.m\n"
+ "\t(the list may be flattened if this more convenient.)")
#undef METHNAME
{ 0 }
};
Py_TPFLAGS_BASETYPE,
/* @tp_doc@ */
-"A Barrett reduction context.",
+ "MPBarrett(N): a Barrett reduction context.",
0, /* @tp_traverse@ */
0, /* @tp_clear@ */
0, /* @tp_weaklistoffset@ */
0, /* @tp_iter@ */
0, /* @tp_iternext@ */
- mpbarrett_pymethods, /* @tp_methods@ */
+ PYMETHODS(mpbarrett), /* @tp_methods@ */
0, /* @tp_members@ */
- mpbarrett_pygetset, /* @tp_getset@ */
+ PYGETSET(mpbarrett), /* @tp_getset@ */
0, /* @tp_base@ */
0, /* @tp_dict@ */
0, /* @tp_descr_get@ */
{
mpreduce_pyobj *mr = 0;
mpreduce r;
- char *kwlist[] = { "m", 0 };
+ static const char *const kwlist[] = { "m", 0 };
mp *xx = 0;
- if (!PyArg_ParseTupleAndKeywords(arg, kw, "O&:new", kwlist, convmp, &xx))
+ if (!PyArg_ParseTupleAndKeywords(arg, kw, "O&:new", KWLIST, convmp, &xx))
goto end;
if (!MP_POSP(xx)) VALERR("m must be positive");
if (mpreduce_create(&r, xx)) VALERR("bad modulus (must be 2^k - ...)");
static PyObject *mrget_m(PyObject *me, void *hunoz)
{ return (mp_pywrap(MP_COPY(MPREDUCE_PY(me)->p))); }
-static PyGetSetDef mpreduce_pygetset[] = {
+static const PyGetSetDef mpreduce_pygetset[] = {
#define GETSETNAME(op, name) mr##op##_##name
GET (m, "R.m -> modulus for reduction")
#undef GETSETNAME
{ 0 }
};
-static PyMethodDef mpreduce_pymethods[] = {
+static const const PyMethodDef mpreduce_pymethods[] = {
#define METHNAME(name) mrmeth_##name
METH (reduce, "R.reduce(X) -> X mod B.m")
METH (exp, "R.exp(X, N) -> X^N mod B.m")
Py_TPFLAGS_BASETYPE,
/* @tp_doc@ */
-"A reduction context for reduction modulo primes of special form.",
+ "MPReduce(N): a reduction context for reduction modulo Solinas primes.",
0, /* @tp_traverse@ */
0, /* @tp_clear@ */
0, /* @tp_weaklistoffset@ */
0, /* @tp_iter@ */
0, /* @tp_iternext@ */
- mpreduce_pymethods, /* @tp_methods@ */
+ PYMETHODS(mpreduce), /* @tp_methods@ */
0, /* @tp_members@ */
- mpreduce_pygetset, /* @tp_getset@ */
+ PYGETSET(mpreduce), /* @tp_getset@ */
0, /* @tp_base@ */
0, /* @tp_dict@ */
0, /* @tp_descr_get@ */
PyObject *q = 0, *x, *z = 0;
mp *xx;
mp **v = 0;
- int i = 0, n = c->k;
+ Py_ssize_t i = 0, n = c->k;
Py_INCREF(me);
- if (PyTuple_Size(arg) == n)
+ if (PyTuple_GET_SIZE(arg) == n)
q = arg;
else if (!PyArg_ParseTuple(arg, "O:solve", &q))
goto end;
Py_INCREF(q);
if (!PySequence_Check(q)) TYERR("want a sequence of residues");
- if (PySequence_Size(q) != n) VALERR("residue count mismatch");
+ i = PySequence_Size(q); if (i < 0) goto end;
+ if (i != n) VALERR("residue count mismatch");
v = xmalloc(n * sizeof(*v));
for (i = 0; i < n; i++) {
if ((x = PySequence_GetItem(q, i)) == 0) goto end;
static PyObject *mpcrt_pynew(PyTypeObject *ty, PyObject *arg, PyObject *kw)
{
mpcrt_mod *v = 0;
- int n, i = 0;
- char *kwlist[] = { "mv", 0 };
+ Py_ssize_t n, i = 0, j;
+ static const char *const kwlist[] = { "mv", 0 };
PyObject *q = 0, *x;
- mp *xx;
+ mp *xx = MP_NEW, *y = MP_NEW, *g = MP_NEW;
+ mpmul mm;
mpcrt_pyobj *c = 0;
- if (PyTuple_Size(arg) > 1)
+ if (PyTuple_GET_SIZE(arg) > 1)
q = arg;
- else if (!PyArg_ParseTupleAndKeywords(arg, kw, "O:new", kwlist, &q))
+ else if (!PyArg_ParseTupleAndKeywords(arg, kw, "O:new", KWLIST, &q))
goto end;
Py_INCREF(q);
if (!PySequence_Check(q)) TYERR("want a sequence of moduli");
- n = PySequence_Size(q);
- if (PyErr_Occurred()) goto end;
+ n = PySequence_Size(q); if (n < 0) goto end;
if (!n) VALERR("want at least one modulus");
v = xmalloc(n * sizeof(*v));
for (i = 0; i < n; i++) {
if ((x = PySequence_GetItem(q, i)) == 0) goto end;
xx = getmp(x); Py_DECREF(x); if (!xx) goto end;
- v[i].m = xx; v[i].n = 0; v[i].ni = 0; v[i].nni = 0;
+ if (MP_CMP(xx, <=, MP_ZERO)) VALERR("moduli must be positive");
+ v[i].m = xx; v[i].n = 0; v[i].ni = 0; v[i].nni = 0; xx = MP_NEW;
+ }
+ mpmul_init(&mm);
+ for (j = 0; j < i; j++) mpmul_add(&mm, v[j].m);
+ xx = mpmul_done(&mm);
+ for (j = 0; j < i; j++) {
+ mp_div(&y, 0, xx, v[j].m);
+ mp_gcd(&g, 0, 0, y, v[j].m);
+ if (!MP_EQ(g, MP_ONE)) VALERR("moduli must be pairwise coprime");
}
+
c = (mpcrt_pyobj *)ty->tp_alloc(ty, 0);
mpcrt_create(&c->c, v, n, 0);
Py_DECREF(q);
+ mp_drop(xx); mp_drop(y); mp_drop(g);
return ((PyObject *)c);
end:
xfree(v);
}
Py_XDECREF(q);
+ mp_drop(xx); mp_drop(y); mp_drop(g);
return (0);
}
if ((q = PyList_New(c->k)) == 0) return (0);
for (i = 0; i < c->k; i++)
- PyList_SetItem(q, i, mp_pywrap(c->v[i].m));
+ PyList_SET_ITEM(q, i, mp_pywrap(c->v[i].m));
return (q);
}
-static PyGetSetDef mpcrt_pygetset[] = {
+static const PyGetSetDef mpcrt_pygetset[] = {
#define GETSETNAME(op, name) mc##op##_##name
GET (product, "C.product -> product of moduli")
GET (moduli, "C.moduli -> list of individual moduli")
{ 0 }
};
-static PyMethodDef mpcrt_pymethods[] = {
+static const PyMethodDef mpcrt_pymethods[] = {
#define METHNAME(name) mcmeth_##name
METH (solve, "C.solve([R0, R1]) -> X mod C.product")
#undef METHNAME
Py_TPFLAGS_BASETYPE,
/* @tp_doc@ */
-"A context for the solution of Chinese Remainder Theorem problems.",
+ "MPCRT(SEQ): a context for solving Chinese Remainder Theorem problems.",
0, /* @tp_traverse@ */
0, /* @tp_clear@ */
0, /* @tp_weaklistoffset@ */
0, /* @tp_iter@ */
0, /* @tp_iternext@ */
- mpcrt_pymethods, /* @tp_methods@ */
+ PYMETHODS(mpcrt), /* @tp_methods@ */
0, /* @tp_members@ */
- mpcrt_pygetset, /* @tp_getset@ */
+ PYGETSET(mpcrt), /* @tp_getset@ */
0, /* @tp_base@ */
0, /* @tp_dict@ */
0, /* @tp_descr_get@ */
mp *z;
mp_pyobj *zz = 0;
int radix = 0;
- char *kwlist[] = { "x", "radix", 0 };
+ static const char *const kwlist[] = { "x", "radix", 0 };
- if (!PyArg_ParseTupleAndKeywords(arg, kw, "O|i:gf", kwlist, &x, &radix))
+ if (!PyArg_ParseTupleAndKeywords(arg, kw, "O|i:gf", KWLIST, &x, &radix))
goto end;
if (GF_PYCHECK(x)) RETURN_OBJ(x);
if (!good_radix_p(radix, 1)) VALERR("radix out of range");
static PyObject *gfget_degree(PyObject *me, void *hunoz)
{ return (PyInt_FromLong(mp_bits(MP_X(me)) - 1)); }
-static PyGetSetDef gf_pygetset[] = {
+static const PyGetSetDef gf_pygetset[] = {
#define GETSETNAME(op, name) gf##op##_##name
GET (degree, "X.degree -> polynomial degree of X")
#undef GETSETNAME
{ 0 }
};
-static PyMethodDef gf_pymethods[] = {
+static const PyMethodDef gf_pymethods[] = {
#define METHNAME(func) gfmeth_##func
METH (setbit, "X.setbit(N) -> X with bit N set")
METH (clearbit, "X.clearbit(N) -> X with bit N clear")
METH (testbit, "X.testbit(N) -> true/false if bit N set/clear in X")
METH (sqr, "X.sqr() -> X^2")
METH (gcd, "X.gcd(Y) -> gcd(X, Y)")
- METH (gcdx,
- "X.gcdx(Y) -> (gcd(X, Y), U, V) with X U + Y V = gcd(X, Y)")
+ METH (gcdx, "X.gcdx(Y) -> (gcd(X, Y), U, V) with X U + Y V = gcd(X, Y)")
METH (modinv, "X.modinv(Y) -> multiplicative inverse of Y mod X")
METH (irreduciblep, "X.irreduciblep() -> true/false")
#undef METHNAME
#define METHNAME(func) mpmeth_##func
- KWMETH(tostring, "X.tostring(radix = 10) -> STR")
- KWMETH(storel, "X.storel(len = -1) -> little-endian bytes")
- KWMETH(storeb, "X.storeb(len = -1) -> big-endian bytes")
- KWMETH(storel2c,
- "X.storel2c(len = -1) -> little-endian bytes, two's complement")
- KWMETH(storeb2c,
- "X.storeb2c(len = -1) -> big-endian bytes, two's complement")
+ KWMETH(tostring, "X.tostring([radix = 10]) -> STR")
+ KWMETH(storel, "X.storel([len = -1]) -> little-endian bytes")
+ KWMETH(storeb, "X.storeb([len = -1]) -> big-endian bytes")
+ KWMETH(storel2c, "X.storel2c([len = -1]) -> "
+ "little-endian bytes, two's complement")
+ KWMETH(storeb2c, "X.storeb2c([len = -1]) -> "
+ "big-endian bytes, two's complement")
METH (tobuf, "X.tobuf() -> buffer format")
#undef METHNAME
{ 0 }
};
-static PyNumberMethods gf_pynumber = {
+static const PyNumberMethods gf_pynumber = {
gf_pyadd, /* @nb_add@ */
gf_pysub, /* @nb_subtract@ */
gf_pymul, /* @nb_multiply@ */
0, /* @tp_setattr@ */
0, /* @tp_compare@ */
gf_pyrepr, /* @tp_repr@ */
- &gf_pynumber, /* @tp_as_number@ */
+ PYNUMBER(gf), /* @tp_as_number@ */
0, /* @tp_as_sequence@ */
0, /* @tp_as_mapping@ */
mp_pyhash, /* @tp_hash@ */
Py_TPFLAGS_BASETYPE,
/* @tp_doc@ */
-"Binary polynomials. Support almost all the standard arithmetic\n\
-operations.\n\
-\n\
-Constructor GF(X, radix = R) attempts to convert X to a `GF'. If\n\
-X is a string, it's read in radix-R form, or we look for a prefix\n\
-if R = 0. Other acceptable things are field elements, elliptic curve\n\
-points, group elements, Python `int' and `long' objects, and anything\n\
-with an integer conversion.\n\
-\n\
-The name is hopelessly wrong from a technical point of view, but\n\
-but it's much easier to type than `p2' or `c2' or whatever.\n\
-\n\
-Notes:\n\
-\n\
- * Use `//' for division. GFs don't have `/' division.",
+ "Binary polynomials. Support almost all the standard arithmetic\n"
+ "operations.\n"
+ "\n"
+ "Constructor GF(X, [radix = R]) attempts to convert X to a `GF'. If\n"
+ "X is a string, it's read in radix-R form, or we look for a prefix\n"
+ "if R = 0. Other acceptable things are field elements, elliptic curve\n"
+ "points, group elements, Python `int' and `long' objects, and anything\n"
+ "with an integer conversion.\n"
+ "\n"
+ "The name is hopelessly wrong from a technical point of view, but\n"
+ "but it's much easier to type than `p2' or `c2' or whatever.\n"
+ "\n"
+ "Notes:\n"
+ "\n"
+ " * Use `//' for Euclidean division: `/' gives exact rational division.",
0, /* @tp_traverse@ */
0, /* @tp_clear@ */
0, /* @tp_weaklistoffset@ */
0, /* @tp_iter@ */
0, /* @tp_iternext@ */
- gf_pymethods, /* @tp_methods@ */
+ PYMETHODS(gf), /* @tp_methods@ */
0, /* @tp_members@ */
- gf_pygetset, /* @tp_getset@ */
+ PYGETSET(gf), /* @tp_getset@ */
0, /* @tp_base@ */
0, /* @tp_dict@ */
0, /* @tp_descr_get@ */
PyObject *z = 0;
mp *zz;
mptext_stringctx sc;
- char *kwlist[] = { "class", "x", "radix", 0 };
+ static const char *const kwlist[] = { "class", "x", "radix", 0 };
if (!PyArg_ParseTupleAndKeywords(arg, kw, "Os#|i:fromstring",
- kwlist, &me, &p, &len, &r))
+ KWLIST, &me, &p, &len, &r))
goto end;
if (!good_radix_p(r, 1)) VALERR("bad radix");
sc.buf = p; sc.lim = p + len;
{
gfreduce_pyobj *mr = 0;
gfreduce r;
- char *kwlist[] = { "m", 0 };
+ static const char *const kwlist[] = { "m", 0 };
mp *xx = 0;
- if (!PyArg_ParseTupleAndKeywords(arg, kw, "O&:new", kwlist, convgf, &xx))
+ if (!PyArg_ParseTupleAndKeywords(arg, kw, "O&:new", KWLIST, convgf, &xx))
goto end;
if (MP_ZEROP(xx)) ZDIVERR("modulus is zero!");
gfreduce_create(&r, xx);
static PyObject *grget_m(PyObject *me, void *hunoz)
{ return (gf_pywrap(MP_COPY(GFREDUCE_PY(me)->p))); }
-static PyGetSetDef gfreduce_pygetset[] = {
+static const PyGetSetDef gfreduce_pygetset[] = {
#define GETSETNAME(op, name) gr##op##_##name
GET (m, "R.m -> reduction polynomial")
#undef GETSETNAME
{ 0 }
};
-static PyMethodDef gfreduce_pymethods[] = {
+static const PyMethodDef gfreduce_pymethods[] = {
#define METHNAME(name) grmeth_##name
METH (reduce, "R.reduce(X) -> X mod B.m")
METH (trace, "R.trace(X) -> Tr(X) = x + x^2 + ... + x^{2^{m - 1}}")
- METH (halftrace, "R.halftrace(X) -> x + x^{2^2} + ... + x^{2^{m - 1}}")
+ METH (halftrace, "R.halftrace(X) -> x + x^{2^2} + ... + x^{2^{m - 1}}")
METH (sqrt, "R.sqrt(X) -> Y where Y^2 = X mod R")
METH (quadsolve, "R.quadsolve(X) -> Y where Y^2 + Y = X mod R")
METH (exp, "R.exp(X, N) -> X^N mod B.m")
Py_TPFLAGS_BASETYPE,
/* @tp_doc@ */
-"A reduction context for reduction modulo sparse irreducible polynomials.",
+ "GFReduce(N): a context for reduction modulo sparse polynomials.",
0, /* @tp_traverse@ */
0, /* @tp_clear@ */
0, /* @tp_weaklistoffset@ */
0, /* @tp_iter@ */
0, /* @tp_iternext@ */
- gfreduce_pymethods, /* @tp_methods@ */
+ PYMETHODS(gfreduce), /* @tp_methods@ */
0, /* @tp_members@ */
- gfreduce_pygetset, /* @tp_getset@ */
+ PYGETSET(gfreduce), /* @tp_getset@ */
0, /* @tp_base@ */
0, /* @tp_dict@ */
0, /* @tp_descr_get@ */
{
mp *p = 0, *beta = 0;
gfn_pyobj *gg = 0;
- char *kwlist[] = { "p", "beta", 0 };
+ static const char *const kwlist[] = { "p", "beta", 0 };
- if (!PyArg_ParseTupleAndKeywords(arg, kw, "O&O&:new", kwlist,
+ if (!PyArg_ParseTupleAndKeywords(arg, kw, "O&O&:new", KWLIST,
convgf, &p, convgf, &beta))
goto end;
gg = PyObject_New(gfn_pyobj, ty);
+ gg->p = 0;
if (gfn_create(p, beta, &gg->ntop, &gg->pton)) {
- FREEOBJ(gg);
+ Py_DECREF(gg);
gg = 0;
VALERR("can't invert transformation matrix");
}
end: \
mp_drop(xx); \
if (!z) return (0); \
- return (mp_pywrap(z)); \
+ return (gf_pywrap(z)); \
}
XFORMOP(pton, PTON)
XFORMOP(ntop, NTOP)
static void gfn_pydealloc(PyObject *me)
{
- gfn_destroy(GFN_PTON(me));
- gfn_destroy(GFN_NTOP(me));
+ if (GFN_P(me)) {
+ MP_DROP(GFN_P(me));
+ gfn_destroy(GFN_PTON(me));
+ gfn_destroy(GFN_NTOP(me));
+ }
FREEOBJ(me);
}
-static PyGetSetDef gfn_pygetset[] = {
+static const PyGetSetDef gfn_pygetset[] = {
#define GETSETNAME(op, name) gfn##op##_##name
GET (p, "X.p -> polynomial basis, as polynomial")
GET (beta, "X.beta -> normal basis element, in poly form")
{ 0 }
};
-static PyMethodDef gfn_pymethods[] = {
+static const PyMethodDef gfn_pymethods[] = {
#define METHNAME(name) gfnmeth_##name
METH (pton, "X.pton(A) -> normal-basis representation of A")
METH (ntop, "X.ntop(A) -> polynomial-basis representation of A")
Py_TPFLAGS_BASETYPE,
/* @tp_doc@ */
-"An object for transforming elements of binary fields between polynomial\n\
-and normal basis representations.",
+ "GFN(P, BETA): an object for transforming elements of binary fields\n"
+ " between polynomial and normal basis representations.",
0, /* @tp_traverse@ */
0, /* @tp_clear@ */
0, /* @tp_weaklistoffset@ */
0, /* @tp_iter@ */
0, /* @tp_iternext@ */
- gfn_pymethods, /* @tp_methods@ */
+ PYMETHODS(gfn), /* @tp_methods@ */
0, /* @tp_members@ */
- gfn_pygetset, /* @tp_getset@ */
+ PYGETSET(gfn), /* @tp_getset@ */
0, /* @tp_base@ */
0, /* @tp_dict@ */
0, /* @tp_descr_get@ */
/*----- Glue --------------------------------------------------------------*/
-static PyMethodDef methods[] = {
+static const PyMethodDef methods[] = {
#define METHNAME(func) meth_##func
- KWMETH(_MP_fromstring, "\
-fromstring(STR, radix = 0) -> (X, REST)\n\
-\n\
-Parse STR as a large integer, according to radix. If radix is zero,\n\
-read a prefix from STR to decide radix: allow `0' for octal, `0x' for hex\n\
-or `R_' for other radix R.")
- KWMETH(_GF_fromstring, "\
-fromstring(STR, radix = 0) -> (X, REST)\n\
-\n\
-Parse STR as a binary polynomial, according to radix. If radix is zero,\n\
-read a prefix from STR to decide radix: allow `0' for octal, `0x' for hex\n\
-or `R_' for other radix R.")
- METH (_MP_factorial, "\
-factorial(I) -> I!: compute factorial")
- METH (_MP_fibonacci, "\
-fibonacci(I) -> F(I): compute Fibonacci number")
- METH (_MP_loadl, "\
-loadl(STR) -> X: read little-endian bytes")
- METH (_MP_loadb, "\
-loadb(STR) -> X: read big-endian bytes")
- METH (_MP_loadl2c, "\
-loadl2c(STR) -> X: read little-endian bytes, two's complement")
- METH (_MP_loadb2c, "\
-loadb2c(STR) -> X: read big-endian bytes, two's complement")
- METH (_MP_frombuf, "\
-frombuf(STR) -> (X, REST): read buffer format")
- METH (_GF_loadl, "\
-loadl(STR) -> X: read little-endian bytes")
- METH (_GF_loadb, "\
-loadb(STR) -> X: read big-endian bytes")
- METH (_GF_frombuf, "\
-frombuf(STR) -> (X, REST): read buffer format")
+ KWMETH(_MP_fromstring, "fromstring(STR, [radix = 0]) -> (X, REST)\n"
+ " Parse STR as a large integer, according to RADIX. If RADIX is\n"
+ " zero, read a prefix from STR to decide radix: allow `0b' for binary,\n"
+ " `0' or `0o' for octal, `0x' for hex, or `R_' for other radix R.")
+ KWMETH(_GF_fromstring, "fromstring(STR, [radix = 0]) -> (X, REST)\n"
+ " Parse STR as a binary polynomial, according to RADIX. If RADIX is\n"
+ " zero, read a prefix from STR to decide radix: allow `0b' for binary,\n"
+ " `0' or `0o' for octal, `0x' for hex, or `R_' for other radix R.")
+ METH (_MP_factorial, "factorial(I) -> I!: compute factorial")
+ METH (_MP_fibonacci, "fibonacci(I) -> F(I): compute Fibonacci number")
+ METH (_MP_loadl, "loadl(STR) -> X: read little-endian bytes")
+ METH (_MP_loadb, "loadb(STR) -> X: read big-endian bytes")
+ METH (_MP_loadl2c, "loadl2c(STR) -> X: "
+ "read little-endian bytes, two's complement")
+ METH (_MP_loadb2c, "loadb2c(STR) -> X: "
+ "read big-endian bytes, two's complement")
+ METH (_MP_frombuf, "frombuf(STR) -> (X, REST): read buffer format")
+ METH (_GF_loadl, "loadl(STR) -> X: read little-endian bytes")
+ METH (_GF_loadb, "loadb(STR) -> X: read big-endian bytes")
+ METH (_GF_frombuf, "frombuf(STR) -> (X, REST): read buffer format")
#undef METHNAME
{ 0 }
};