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:
"Multiprecision integers, similar to `long' but more efficient and\n\
versatile. Support all the standard arithmetic operations.\n\
\n\
-Constructor mp(X, radix = R) attempts to convert X to an `mp'. If\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 ints and longs.\n\
\n\
Notes:\n\
\n\
- * Use `//' for division. MPs don't have `/' division.",
+ * Use `//' for integer division. `/' gives exact rational division.",
0, /* @tp_traverse@ */
0, /* @tp_clear@ */
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;
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@ */
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);
Py_TPFLAGS_BASETYPE,
/* @tp_doc@ */
-"A Montgomery reduction context.",
+"MPMont(N): a Montgomery reduction context.",
0, /* @tp_traverse@ */
0, /* @tp_clear@ */
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);
Py_TPFLAGS_BASETYPE,
/* @tp_doc@ */
-"A Barrett reduction context.",
+"MPBarrett(N): a Barrett reduction context.",
0, /* @tp_traverse@ */
0, /* @tp_clear@ */
{
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 - ...)");
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@ */
{
mpcrt_mod *v = 0;
int n, i = 0;
- char *kwlist[] = { "mv", 0 };
+ static const char *const kwlist[] = { "mv", 0 };
PyObject *q = 0, *x;
mp *xx;
mpcrt_pyobj *c = 0;
if (PyTuple_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");
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@ */
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");
\n\
Notes:\n\
\n\
- * Use `//' for division. GFs don't have `/' division.",
+ * Use `//' for Euclidean division. `/' gives exact rational division.",
0, /* @tp_traverse@ */
0, /* @tp_clear@ */
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);
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@ */
{
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);
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@ */