mp *x;
size_t sz;
TEXT_PTRLEN(o, sc.buf, sz); sc.lim = sc.buf + sz;
+ if (sc.buf + 2 < sc.lim && sc.buf[0] == '0' &&
+ (radix == 16 ? (sc.buf[1] == 'x' || sc.buf[1] == 'X') :
+ radix == 8 ? (sc.buf[1] == 'o' || sc.buf[1] == 'O') :
+ radix == 2 ? (sc.buf[1] == 'b' || sc.buf[1] == 'B') :
+ 0))
+ sc.buf += 2;
x = mp_read(MP_NEW, radix, &mptext_stringops, &sc);
if (!x) return (0);
if (sc.buf < sc.lim) { MP_DROP(x); return (0); }
return (rc);
}
-/*----- Python interface --------------------------------------------------*/
+/*----- Arbitrary-precision integers --------------------------------------*/
static void mp_pydealloc(PyObject *o)
{
mp *implicitmp(PyObject *o)
{
- if (!o ||
- GF_PYCHECK(o) ||
- ECPT_PYCHECK(o) ||
- FE_PYCHECK(o) ||
- GE_PYCHECK(o))
- return (0);
- return (tomp(o));
+ PyObject *l;
+
+ if (!o || GF_PYCHECK(o) || FE_PYCHECK(o)) return (0);
+ else if (MP_PYCHECK(o)) return (MP_COPY(MP_X(o)));
+ else if (PFILT_PYCHECK(o)) return (MP_COPY(PFILT_F(o)->m));
+#ifdef PY2
+ else if (PyInt_Check(o)) return (mp_fromlong(MP_NEW, PyInt_AS_LONG(o)));
+#endif
+ else if ((l = PyNumber_Index(o)) != 0) {
+#ifdef PY2
+ if (PyInt_Check(o)) return (mp_fromlong(MP_NEW, PyInt_AS_LONG(o)));
+#endif
+ if (PyLong_Check(o)) return (mp_frompylong(o));
+ }
+ PyErr_Clear(); return (0);
}
mp *implicitgf(PyObject *o)
{
- if (!o ||
- MP_PYCHECK(o) ||
- ECPT_PYCHECK(o) ||
- FE_PYCHECK(o) ||
- GE_PYCHECK(o))
- return (0);
- return (tomp(o));
+ if (GF_PYCHECK(o)) return (MP_COPY(MP_X(o)));
+ return (0);
}
static int mpbinop(PyObject *x, PyObject *y, mp **xx, mp **yy)
static PyObject *mp_pyid(PyObject *x) { RETURN_OBJ(x); }
#define gf_lsr mp_lsr
-#define SHIFTOP(pre, name, rname) \
+#define SHIFTOP(pre, PRE, name, rname) \
static PyObject *pre##_py##name(PyObject *x, PyObject *y) { \
- mp *xx, *yy; \
+ PyObject *yix = 0; \
PyObject *z = 0; \
long n; \
- if (pre##binop(x, y, &xx, &yy)) RETURN_NOTIMPL; \
- if (mp_tolong_checked(yy, &n, 1)) goto end; \
- if (n < 0) \
- z = pre##_pywrap(mp_##rname(MP_NEW, xx, -n)); \
- else \
- z = pre##_pywrap(mp_##name(MP_NEW, xx, n)); \
- end: \
- MP_DROP(xx); MP_DROP(yy); \
+ if (!PRE##_PYCHECK(x)) RETURN_NOTIMPL; \
+ if (GF_PYCHECK(y) || FE_PYCHECK(y)) RETURN_NOTIMPL; \
+ yix = PyNumber_Index(y); if (!yix) { PyErr_Clear(); RETURN_NOTIMPL; } \
+ n = PyInt_AsLong(yix); Py_DECREF(yix); \
+ if (n == -1 && PyErr_Occurred()) { PyErr_Clear(); RETURN_NOTIMPL; } \
+ if (n < 0) z = pre##_pywrap(mp_##rname(MP_NEW, MP_X(x), -n)); \
+ else z = pre##_pywrap(mp_##name(MP_NEW, MP_X(x), n)); \
return (z); \
}
-SHIFTOP(mp, lsl2c, lsr2c)
-SHIFTOP(mp, lsr2c, lsl2c)
-SHIFTOP(gf, lsl, lsr)
-SHIFTOP(gf, lsr, lsl)
+SHIFTOP(mp, MP, lsl2c, lsr2c)
+SHIFTOP(mp, MP, lsr2c, lsl2c)
+SHIFTOP(gf, GF, lsl, lsr)
+SHIFTOP(gf, GF, lsr, lsl)
#undef SHIFTOP
#define DIVOP(pre, name, qq, rr, gather) \
PyObject *rc = 0;
if ((xx = implicitmp(x)) == 0 || (yy = implicitmp(y)) == 0 ||
- (z && z != Py_None && (zz = tomp(z)) == 0)) {
+ (z && z != Py_None && (zz = implicitmp(z)) == 0)) {
mp_drop(xx); mp_drop(yy); mp_drop(zz);
RETURN_NOTIMPL;
}
Py_INCREF(*x); Py_INCREF(*y); \
return (0); \
} \
- if ((z = tomp(*y)) != 0) { \
+ if ((z = implicit##pre(*y)) != 0) { \
Py_INCREF(*x); \
*y = pre##_pywrap(z); \
return (0); \
return ((PyObject *)zz);
}
+#define IMPLICIT(pre) \
+ static PyObject *pre##meth__implicit(PyObject *me, PyObject *arg) \
+ { \
+ PyObject *x, *rc = 0; \
+ mp *y = MP_NEW; \
+ if (!PyArg_ParseTuple(arg, "O:_implicit", &x)) goto end; \
+ y = implicit##pre(x); \
+ if (!y) TYERR("can't convert implicitly to " #pre); \
+ rc = pre##_pywrap(y); \
+ end: \
+ return (rc); \
+ }
+IMPLICIT(mp)
+IMPLICIT(gf)
+#undef IMPLICIT
+
Py_hash_t mphash(mp *x)
{
PyObject *l = mp_topylong(x);
" 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.")
+ SMTH (_implicit, 0)
SMTH (factorial, "factorial(I) -> I!: compute factorial")
SMTH (fibonacci, "fibonacci(I) -> F(I): compute Fibonacci number")
SMTH (loadl, "loadl(STR) -> X: read little-endian bytes")
mp **v = 0;
Py_ssize_t i = 0, n = c->k;
- Py_INCREF(me);
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");
i = PySequence_Size(q); if (i < 0) goto end;
if (i != n) VALERR("residue count mismatch");
MP_DROP(v[i]);
xfree(v);
}
- Py_DECREF(me);
- Py_XDECREF(q);
return (z);
}
q = arg;
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 (n < 0) goto end;
if (!n) VALERR("want at least one modulus");
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);
MP_DROP(v[i].m);
xfree(v);
}
- Py_XDECREF(q);
mp_drop(xx); mp_drop(y); mp_drop(g);
return (0);
}
mp *r = 0;
PyObject *rc = 0;
- if ((xx = tomp(x)) == 0 || (yy = tomp(y)) == 0 ||
- (z && z != Py_None && (zz = tomp(z)) == 0)) {
+ if ((xx = implicitgf(x)) == 0 || (yy = implicitmp(y)) == 0 ||
+ (z && z != Py_None && (zz = implicitgf(z)) == 0)) {
mp_drop(xx); mp_drop(yy); mp_drop(zz);
RETURN_NOTIMPL;
}
" 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.")
+ SMTH (_implicit, 0)
SMTH (loadl, "loadl(STR) -> X: read little-endian bytes")
SMTH (loadb, "loadb(STR) -> X: read big-endian bytes")
SMTH (frombuf, "frombuf(STR) -> (X, REST): read buffer format")