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@vstinner vstinner bpo-40989: PyObject_INIT() becomes an alias to PyObject_Init() (GH-20901 04fc4f2 Jun 16, 2020
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/* Long (arbitrary precision) integer object implementation */
/* XXX The functional organization of this file is terrible */
#include "Python.h"
#include "pycore_bitutils.h" // _Py_popcount32()
#include "pycore_interp.h" // _PY_NSMALLPOSINTS
#include "pycore_object.h" // _PyObject_InitVar()
#include "pycore_pystate.h" // _Py_IsMainInterpreter()
#include "longintrepr.h"
#include <float.h>
#include <ctype.h>
#include <stddef.h>
#include "clinic/longobject.c.h"
/*[clinic input]
class int "PyObject *" "&PyLong_Type"
[clinic start generated code]*/
/*[clinic end generated code: output=da39a3ee5e6b4b0d input=ec0275e3422a36e3]*/
#define NSMALLPOSINTS _PY_NSMALLPOSINTS
#define NSMALLNEGINTS _PY_NSMALLNEGINTS
_Py_IDENTIFIER(little);
_Py_IDENTIFIER(big);
/* convert a PyLong of size 1, 0 or -1 to an sdigit */
#define MEDIUM_VALUE(x) (assert(-1 <= Py_SIZE(x) && Py_SIZE(x) <= 1), \
Py_SIZE(x) < 0 ? -(sdigit)(x)->ob_digit[0] : \
(Py_SIZE(x) == 0 ? (sdigit)0 : \
(sdigit)(x)->ob_digit[0]))
PyObject *_PyLong_Zero = NULL;
PyObject *_PyLong_One = NULL;
#if NSMALLNEGINTS + NSMALLPOSINTS > 0
#define IS_SMALL_INT(ival) (-NSMALLNEGINTS <= (ival) && (ival) < NSMALLPOSINTS)
#define IS_SMALL_UINT(ival) ((ival) < NSMALLPOSINTS)
static PyObject *
get_small_int(sdigit ival)
{
assert(IS_SMALL_INT(ival));
PyInterpreterState *interp = _PyInterpreterState_GET();
PyObject *v = (PyObject*)interp->small_ints[ival + NSMALLNEGINTS];
Py_INCREF(v);
return v;
}
static PyLongObject *
maybe_small_long(PyLongObject *v)
{
if (v && Py_ABS(Py_SIZE(v)) <= 1) {
sdigit ival = MEDIUM_VALUE(v);
if (IS_SMALL_INT(ival)) {
Py_DECREF(v);
return (PyLongObject *)get_small_int(ival);
}
}
return v;
}
#else
#define IS_SMALL_INT(ival) 0
#define IS_SMALL_UINT(ival) 0
#define get_small_int(ival) (Py_UNREACHABLE(), NULL)
#define maybe_small_long(val) (val)
#endif
/* If a freshly-allocated int is already shared, it must
be a small integer, so negating it must go to PyLong_FromLong */
Py_LOCAL_INLINE(void)
_PyLong_Negate(PyLongObject **x_p)
{
PyLongObject *x;
x = (PyLongObject *)*x_p;
if (Py_REFCNT(x) == 1) {
Py_SET_SIZE(x, -Py_SIZE(x));
return;
}
*x_p = (PyLongObject *)PyLong_FromLong(-MEDIUM_VALUE(x));
Py_DECREF(x);
}
/* For int multiplication, use the O(N**2) school algorithm unless
* both operands contain more than KARATSUBA_CUTOFF digits (this
* being an internal Python int digit, in base BASE).
*/
#define KARATSUBA_CUTOFF 70
#define KARATSUBA_SQUARE_CUTOFF (2 * KARATSUBA_CUTOFF)
/* For exponentiation, use the binary left-to-right algorithm
* unless the exponent contains more than FIVEARY_CUTOFF digits.
* In that case, do 5 bits at a time. The potential drawback is that
* a table of 2**5 intermediate results is computed.
*/
#define FIVEARY_CUTOFF 8
#define SIGCHECK(PyTryBlock) \
do { \
if (PyErr_CheckSignals()) PyTryBlock \
} while(0)
/* Normalize (remove leading zeros from) an int object.
Doesn't attempt to free the storage--in most cases, due to the nature
of the algorithms used, this could save at most be one word anyway. */
static PyLongObject *
long_normalize(PyLongObject *v)
{
Py_ssize_t j = Py_ABS(Py_SIZE(v));
Py_ssize_t i = j;
while (i > 0 && v->ob_digit[i-1] == 0)
--i;
if (i != j) {
Py_SET_SIZE(v, (Py_SIZE(v) < 0) ? -(i) : i);
}
return v;
}
/* Allocate a new int object with size digits.
Return NULL and set exception if we run out of memory. */
#define MAX_LONG_DIGITS \
((PY_SSIZE_T_MAX - offsetof(PyLongObject, ob_digit))/sizeof(digit))
PyLongObject *
_PyLong_New(Py_ssize_t size)
{
PyLongObject *result;
/* Number of bytes needed is: offsetof(PyLongObject, ob_digit) +
sizeof(digit)*size. Previous incarnations of this code used
sizeof(PyVarObject) instead of the offsetof, but this risks being
incorrect in the presence of padding between the PyVarObject header
and the digits. */
if (size > (Py_ssize_t)MAX_LONG_DIGITS) {
PyErr_SetString(PyExc_OverflowError,
"too many digits in integer");
return NULL;
}
result = PyObject_MALLOC(offsetof(PyLongObject, ob_digit) +
size*sizeof(digit));
if (!result) {
PyErr_NoMemory();
return NULL;
}
_PyObject_InitVar((PyVarObject*)result, &PyLong_Type, size);
return result;
}
PyObject *
_PyLong_Copy(PyLongObject *src)
{
PyLongObject *result;
Py_ssize_t i;
assert(src != NULL);
i = Py_SIZE(src);
if (i < 0)
i = -(i);
if (i < 2) {
sdigit ival = MEDIUM_VALUE(src);
if (IS_SMALL_INT(ival)) {
return get_small_int(ival);
}
}
result = _PyLong_New(i);
if (result != NULL) {
Py_SET_SIZE(result, Py_SIZE(src));
while (--i >= 0) {
result->ob_digit[i] = src->ob_digit[i];
}
}
return (PyObject *)result;
}
/* Create a new int object from a C long int */
PyObject *
PyLong_FromLong(long ival)
{
PyLongObject *v;
unsigned long abs_ival;
unsigned long t; /* unsigned so >> doesn't propagate sign bit */
int ndigits = 0;
int sign;
if (IS_SMALL_INT(ival)) {
return get_small_int((sdigit)ival);
}
if (ival < 0) {
/* negate: can't write this as abs_ival = -ival since that
invokes undefined behaviour when ival is LONG_MIN */
abs_ival = 0U-(unsigned long)ival;
sign = -1;
}
else {
abs_ival = (unsigned long)ival;
sign = ival == 0 ? 0 : 1;
}
/* Fast path for single-digit ints */
if (!(abs_ival >> PyLong_SHIFT)) {
v = _PyLong_New(1);
if (v) {
Py_SET_SIZE(v, sign);
v->ob_digit[0] = Py_SAFE_DOWNCAST(
abs_ival, unsigned long, digit);
}
return (PyObject*)v;
}
#if PyLong_SHIFT==15
/* 2 digits */
if (!(abs_ival >> 2*PyLong_SHIFT)) {
v = _PyLong_New(2);
if (v) {
Py_SET_SIZE(v, 2 * sign);
v->ob_digit[0] = Py_SAFE_DOWNCAST(
abs_ival & PyLong_MASK, unsigned long, digit);
v->ob_digit[1] = Py_SAFE_DOWNCAST(
abs_ival >> PyLong_SHIFT, unsigned long, digit);
}
return (PyObject*)v;
}
#endif
/* Larger numbers: loop to determine number of digits */
t = abs_ival;
while (t) {
++ndigits;
t >>= PyLong_SHIFT;
}
v = _PyLong_New(ndigits);
if (v != NULL) {
digit *p = v->ob_digit;
Py_SET_SIZE(v, ndigits * sign);
t = abs_ival;
while (t) {
*p++ = Py_SAFE_DOWNCAST(
t & PyLong_MASK, unsigned long, digit);
t >>= PyLong_SHIFT;
}
}
return (PyObject *)v;
}
#define PYLONG_FROM_UINT(INT_TYPE, ival) \
do { \
if (IS_SMALL_UINT(ival)) { \
return get_small_int((sdigit)(ival)); \
} \
/* Count the number of Python digits. */ \
Py_ssize_t ndigits = 0; \
INT_TYPE t = (ival); \
while (t) { \
++ndigits; \
t >>= PyLong_SHIFT; \
} \
PyLongObject *v = _PyLong_New(ndigits); \
if (v == NULL) { \
return NULL; \
} \
digit *p = v->ob_digit; \
while ((ival)) { \
*p++ = (digit)((ival) & PyLong_MASK); \
(ival) >>= PyLong_SHIFT; \
} \
return (PyObject *)v; \
} while(0)
/* Create a new int object from a C unsigned long int */
PyObject *
PyLong_FromUnsignedLong(unsigned long ival)
{
PYLONG_FROM_UINT(unsigned long, ival);
}
/* Create a new int object from a C unsigned long long int. */
PyObject *
PyLong_FromUnsignedLongLong(unsigned long long ival)
{
PYLONG_FROM_UINT(unsigned long long, ival);
}
/* Create a new int object from a C size_t. */
PyObject *
PyLong_FromSize_t(size_t ival)
{
PYLONG_FROM_UINT(size_t, ival);
}
/* Create a new int object from a C double */
PyObject *
PyLong_FromDouble(double dval)
{
/* Try to get out cheap if this fits in a long. When a finite value of real
* floating type is converted to an integer type, the value is truncated
* toward zero. If the value of the integral part cannot be represented by
* the integer type, the behavior is undefined. Thus, we must check that
* value is in range (LONG_MIN - 1, LONG_MAX + 1). If a long has more bits
* of precision than a double, casting LONG_MIN - 1 to double may yield an
* approximation, but LONG_MAX + 1 is a power of two and can be represented
* as double exactly (assuming FLT_RADIX is 2 or 16), so for simplicity
* check against [-(LONG_MAX + 1), LONG_MAX + 1).
*/
const double int_max = (unsigned long)LONG_MAX + 1;
if (-int_max < dval && dval < int_max) {
return PyLong_FromLong((long)dval);
}
PyLongObject *v;
double frac;
int i, ndig, expo, neg;
neg = 0;
if (Py_IS_INFINITY(dval)) {
PyErr_SetString(PyExc_OverflowError,
"cannot convert float infinity to integer");
return NULL;
}
if (Py_IS_NAN(dval)) {
PyErr_SetString(PyExc_ValueError,
"cannot convert float NaN to integer");
return NULL;
}
if (dval < 0.0) {
neg = 1;
dval = -dval;
}
frac = frexp(dval, &expo); /* dval = frac*2**expo; 0.0 <= frac < 1.0 */
assert(expo > 0);
ndig = (expo-1) / PyLong_SHIFT + 1; /* Number of 'digits' in result */
v = _PyLong_New(ndig);
if (v == NULL)
return NULL;
frac = ldexp(frac, (expo-1) % PyLong_SHIFT + 1);
for (i = ndig; --i >= 0; ) {
digit bits = (digit)frac;
v->ob_digit[i] = bits;
frac = frac - (double)bits;
frac = ldexp(frac, PyLong_SHIFT);
}
if (neg) {
Py_SET_SIZE(v, -(Py_SIZE(v)));
}
return (PyObject *)v;
}
/* Checking for overflow in PyLong_AsLong is a PITA since C doesn't define
* anything about what happens when a signed integer operation overflows,
* and some compilers think they're doing you a favor by being "clever"
* then. The bit pattern for the largest positive signed long is
* (unsigned long)LONG_MAX, and for the smallest negative signed long
* it is abs(LONG_MIN), which we could write -(unsigned long)LONG_MIN.
* However, some other compilers warn about applying unary minus to an
* unsigned operand. Hence the weird "0-".
*/
#define PY_ABS_LONG_MIN (0-(unsigned long)LONG_MIN)
#define PY_ABS_SSIZE_T_MIN (0-(size_t)PY_SSIZE_T_MIN)
/* Get a C long int from an int object or any object that has an __index__
method.
On overflow, return -1 and set *overflow to 1 or -1 depending on the sign of
the result. Otherwise *overflow is 0.
For other errors (e.g., TypeError), return -1 and set an error condition.
In this case *overflow will be 0.
*/
long
PyLong_AsLongAndOverflow(PyObject *vv, int *overflow)
{
/* This version by Tim Peters */
PyLongObject *v;
unsigned long x, prev;
long res;
Py_ssize_t i;
int sign;
int do_decref = 0; /* if PyNumber_Index was called */
*overflow = 0;
if (vv == NULL) {
PyErr_BadInternalCall();
return -1;
}
if (PyLong_Check(vv)) {
v = (PyLongObject *)vv;
}
else {
v = (PyLongObject *)_PyNumber_Index(vv);
if (v == NULL)
return -1;
do_decref = 1;
}
res = -1;
i = Py_SIZE(v);
switch (i) {
case -1:
res = -(sdigit)v->ob_digit[0];
break;
case 0:
res = 0;
break;
case 1:
res = v->ob_digit[0];
break;
default:
sign = 1;
x = 0;
if (i < 0) {
sign = -1;
i = -(i);
}
while (--i >= 0) {
prev = x;
x = (x << PyLong_SHIFT) | v->ob_digit[i];
if ((x >> PyLong_SHIFT) != prev) {
*overflow = sign;
goto exit;
}
}
/* Haven't lost any bits, but casting to long requires extra
* care (see comment above).
*/
if (x <= (unsigned long)LONG_MAX) {
res = (long)x * sign;
}
else if (sign < 0 && x == PY_ABS_LONG_MIN) {
res = LONG_MIN;
}
else {
*overflow = sign;
/* res is already set to -1 */
}
}
exit:
if (do_decref) {
Py_DECREF(v);
}
return res;
}
/* Get a C long int from an int object or any object that has an __index__
method. Return -1 and set an error if overflow occurs. */
long
PyLong_AsLong(PyObject *obj)
{
int overflow;
long result = PyLong_AsLongAndOverflow(obj, &overflow);
if (overflow) {
/* XXX: could be cute and give a different
message for overflow == -1 */
PyErr_SetString(PyExc_OverflowError,
"Python int too large to convert to C long");
}
return result;
}
/* Get a C int from an int object or any object that has an __index__
method. Return -1 and set an error if overflow occurs. */
int
_PyLong_AsInt(PyObject *obj)
{
int overflow;
long result = PyLong_AsLongAndOverflow(obj, &overflow);
if (overflow || result > INT_MAX || result < INT_MIN) {
/* XXX: could be cute and give a different
message for overflow == -1 */
PyErr_SetString(PyExc_OverflowError,
"Python int too large to convert to C int");
return -1;
}
return (int)result;
}
/* Get a Py_ssize_t from an int object.
Returns -1 and sets an error condition if overflow occurs. */
Py_ssize_t
PyLong_AsSsize_t(PyObject *vv) {
PyLongObject *v;
size_t x, prev;
Py_ssize_t i;
int sign;
if (vv == NULL) {
PyErr_BadInternalCall();
return -1;
}
if (!PyLong_Check(vv)) {
PyErr_SetString(PyExc_TypeError, "an integer is required");
return -1;
}
v = (PyLongObject *)vv;
i = Py_SIZE(v);
switch (i) {
case -1: return -(sdigit)v->ob_digit[0];
case 0: return 0;
case 1: return v->ob_digit[0];
}
sign = 1;
x = 0;
if (i < 0) {
sign = -1;
i = -(i);
}
while (--i >= 0) {
prev = x;
x = (x << PyLong_SHIFT) | v->ob_digit[i];
if ((x >> PyLong_SHIFT) != prev)
goto overflow;
}
/* Haven't lost any bits, but casting to a signed type requires
* extra care (see comment above).
*/
if (x <= (size_t)PY_SSIZE_T_MAX) {
return (Py_ssize_t)x * sign;
}
else if (sign < 0 && x == PY_ABS_SSIZE_T_MIN) {
return PY_SSIZE_T_MIN;
}
/* else overflow */
overflow:
PyErr_SetString(PyExc_OverflowError,
"Python int too large to convert to C ssize_t");
return -1;
}
/* Get a C unsigned long int from an int object.
Returns -1 and sets an error condition if overflow occurs. */
unsigned long
PyLong_AsUnsignedLong(PyObject *vv)
{
PyLongObject *v;
unsigned long x, prev;
Py_ssize_t i;
if (vv == NULL) {
PyErr_BadInternalCall();
return (unsigned long)-1;
}
if (!PyLong_Check(vv)) {
PyErr_SetString(PyExc_TypeError, "an integer is required");
return (unsigned long)-1;
}
v = (PyLongObject *)vv;
i = Py_SIZE(v);
x = 0;
if (i < 0) {
PyErr_SetString(PyExc_OverflowError,
"can't convert negative value to unsigned int");
return (unsigned long) -1;
}
switch (i) {
case 0: return 0;
case 1: return v->ob_digit[0];
}
while (--i >= 0) {
prev = x;
x = (x << PyLong_SHIFT) | v->ob_digit[i];
if ((x >> PyLong_SHIFT) != prev) {
PyErr_SetString(PyExc_OverflowError,
"Python int too large to convert "
"to C unsigned long");
return (unsigned long) -1;
}
}
return x;
}
/* Get a C size_t from an int object. Returns (size_t)-1 and sets
an error condition if overflow occurs. */
size_t
PyLong_AsSize_t(PyObject *vv)
{
PyLongObject *v;
size_t x, prev;
Py_ssize_t i;
if (vv == NULL) {
PyErr_BadInternalCall();
return (size_t) -1;
}
if (!PyLong_Check(vv)) {
PyErr_SetString(PyExc_TypeError, "an integer is required");
return (size_t)-1;
}
v = (PyLongObject *)vv;
i = Py_SIZE(v);
x = 0;
if (i < 0) {
PyErr_SetString(PyExc_OverflowError,
"can't convert negative value to size_t");
return (size_t) -1;
}
switch (i) {
case 0: return 0;
case 1: return v->ob_digit[0];
}
while (--i >= 0) {
prev = x;
x = (x << PyLong_SHIFT) | v->ob_digit[i];
if ((x >> PyLong_SHIFT) != prev) {
PyErr_SetString(PyExc_OverflowError,
"Python int too large to convert to C size_t");
return (size_t) -1;
}
}
return x;
}
/* Get a C unsigned long int from an int object, ignoring the high bits.
Returns -1 and sets an error condition if an error occurs. */
static unsigned long
_PyLong_AsUnsignedLongMask(PyObject *vv)
{
PyLongObject *v;
unsigned long x;
Py_ssize_t i;
int sign;
if (vv == NULL || !PyLong_Check(vv)) {
PyErr_BadInternalCall();
return (unsigned long) -1;
}
v = (PyLongObject *)vv;
i = Py_SIZE(v);
switch (i) {
case 0: return 0;
case 1: return v->ob_digit[0];
}
sign = 1;
x = 0;
if (i < 0) {
sign = -1;
i = -i;
}
while (--i >= 0) {
x = (x << PyLong_SHIFT) | v->ob_digit[i];
}
return x * sign;
}
unsigned long
PyLong_AsUnsignedLongMask(PyObject *op)
{
PyLongObject *lo;
unsigned long val;
if (op == NULL) {
PyErr_BadInternalCall();
return (unsigned long)-1;
}
if (PyLong_Check(op)) {
return _PyLong_AsUnsignedLongMask(op);
}
lo = (PyLongObject *)_PyNumber_Index(op);
if (lo == NULL)
return (unsigned long)-1;
val = _PyLong_AsUnsignedLongMask((PyObject *)lo);
Py_DECREF(lo);
return val;
}
int
_PyLong_Sign(PyObject *vv)
{
PyLongObject *v = (PyLongObject *)vv;
assert(v != NULL);
assert(PyLong_Check(v));
return Py_SIZE(v) == 0 ? 0 : (Py_SIZE(v) < 0 ? -1 : 1);
}
static int
bit_length_digit(digit x)
{
Py_BUILD_ASSERT(PyLong_SHIFT <= sizeof(unsigned long) * 8);
return _Py_bit_length((unsigned long)x);
}
size_t
_PyLong_NumBits(PyObject *vv)
{
PyLongObject *v = (PyLongObject *)vv;
size_t result = 0;
Py_ssize_t ndigits;
int msd_bits;
assert(v != NULL);
assert(PyLong_Check(v));
ndigits = Py_ABS(Py_SIZE(v));
assert(ndigits == 0 || v->ob_digit[ndigits - 1] != 0);
if (ndigits > 0) {
digit msd = v->ob_digit[ndigits - 1];
if ((size_t)(ndigits - 1) > SIZE_MAX / (size_t)PyLong_SHIFT)
goto Overflow;
result = (size_t)(ndigits - 1) * (size_t)PyLong_SHIFT;
msd_bits = bit_length_digit(msd);
if (SIZE_MAX - msd_bits < result)
goto Overflow;
result += msd_bits;
}
return result;
Overflow:
PyErr_SetString(PyExc_OverflowError, "int has too many bits "
"to express in a platform size_t");
return (size_t)-1;
}
PyObject *
_PyLong_FromByteArray(const unsigned char* bytes, size_t n,
int little_endian, int is_signed)
{
const unsigned char* pstartbyte; /* LSB of bytes */
int incr; /* direction to move pstartbyte */
const unsigned char* pendbyte; /* MSB of bytes */
size_t numsignificantbytes; /* number of bytes that matter */
Py_ssize_t ndigits; /* number of Python int digits */
PyLongObject* v; /* result */
Py_ssize_t idigit = 0; /* next free index in v->ob_digit */
if (n == 0)
return PyLong_FromLong(0L);
if (little_endian) {
pstartbyte = bytes;
pendbyte = bytes + n - 1;
incr = 1;
}
else {
pstartbyte = bytes + n - 1;
pendbyte = bytes;
incr = -1;
}
if (is_signed)
is_signed = *pendbyte >= 0x80;
/* Compute numsignificantbytes. This consists of finding the most
significant byte. Leading 0 bytes are insignificant if the number
is positive, and leading 0xff bytes if negative. */
{
size_t i;
const unsigned char* p = pendbyte;
const int pincr = -incr; /* search MSB to LSB */
const unsigned char insignificant = is_signed ? 0xff : 0x00;
for (i = 0; i < n; ++i, p += pincr) {
if (*p != insignificant)
break;
}
numsignificantbytes = n - i;
/* 2's-comp is a bit tricky here, e.g. 0xff00 == -0x0100, so
actually has 2 significant bytes. OTOH, 0xff0001 ==
-0x00ffff, so we wouldn't *need* to bump it there; but we
do for 0xffff = -0x0001. To be safe without bothering to
check every case, bump it regardless. */
if (is_signed && numsignificantbytes < n)
++numsignificantbytes;
}
/* How many Python int digits do we need? We have
8*numsignificantbytes bits, and each Python int digit has
PyLong_SHIFT bits, so it's the ceiling of the quotient. */
/* catch overflow before it happens */
if (numsignificantbytes > (PY_SSIZE_T_MAX - PyLong_SHIFT) / 8) {
PyErr_SetString(PyExc_OverflowError,
"byte array too long to convert to int");
return NULL;
}
ndigits = (numsignificantbytes * 8 + PyLong_SHIFT - 1) / PyLong_SHIFT;
v = _PyLong_New(ndigits);
if (v == NULL)
return NULL;
/* Copy the bits over. The tricky parts are computing 2's-comp on
the fly for signed numbers, and dealing with the mismatch between
8-bit bytes and (probably) 15-bit Python digits.*/
{
size_t i;
twodigits carry = 1; /* for 2's-comp calculation */
twodigits accum = 0; /* sliding register */
unsigned int accumbits = 0; /* number of bits in accum */
const unsigned char* p = pstartbyte;
for (i = 0; i < numsignificantbytes; ++i, p += incr) {
twodigits thisbyte = *p;
/* Compute correction for 2's comp, if needed. */
if (is_signed) {
thisbyte = (0xff ^ thisbyte) + carry;
carry = thisbyte >> 8;
thisbyte &= 0xff;
}
/* Because we're going LSB to MSB, thisbyte is
more significant than what's already in accum,
so needs to be prepended to accum. */
accum |= thisbyte << accumbits;
accumbits += 8;
if (accumbits >= PyLong_SHIFT) {
/* There's enough to fill a Python digit. */
assert(idigit < ndigits);
v->ob_digit[idigit] = (digit)(accum & PyLong_MASK);
++idigit;
accum >>= PyLong_SHIFT;
accumbits -= PyLong_SHIFT;
assert(accumbits < PyLong_SHIFT);
}
}
assert(accumbits < PyLong_SHIFT);
if (accumbits) {
assert(idigit < ndigits);
v->ob_digit[idigit] = (digit)accum;
++idigit;
}
}
Py_SET_SIZE(v, is_signed ? -idigit : idigit);
return (PyObject *)long_normalize(v);
}
int
_PyLong_AsByteArray(PyLongObject* v,
unsigned char* bytes, size_t n,
int little_endian, int is_signed)
{
Py_ssize_t i; /* index into v->ob_digit */
Py_ssize_t ndigits; /* |v->ob_size| */
twodigits accum; /* sliding register */
unsigned int accumbits; /* # bits in accum */
int do_twos_comp; /* store 2's-comp? is_signed and v < 0 */
digit carry; /* for computing 2's-comp */
size_t j; /* # bytes filled */
unsigned char* p; /* pointer to next byte in bytes */
int pincr; /* direction to move p */
assert(v != NULL && PyLong_Check(v));
if (Py_SIZE(v) < 0) {
ndigits = -(Py_SIZE(v));
if (!is_signed) {
PyErr_SetString(PyExc_OverflowError,
"can't convert negative int to unsigned");
return -1;
}
do_twos_comp = 1;
}
else {
ndigits = Py_SIZE(v);
do_twos_comp = 0;
}
if (little_endian) {
p = bytes;
pincr = 1;
}
else {
p = bytes + n - 1;
pincr = -1;
}
/* Copy over all the Python digits.
It's crucial that every Python digit except for the MSD contribute
exactly PyLong_SHIFT bits to the total, so first assert that the int is
normalized. */
assert(ndigits == 0 || v->ob_digit[ndigits - 1] != 0);
j = 0;
accum = 0;
accumbits = 0;
carry = do_twos_comp ? 1 : 0;
for (i = 0; i < ndigits; ++i) {
digit thisdigit = v->ob_digit[i];
if (do_twos_comp) {
thisdigit = (thisdigit ^ PyLong_MASK) + carry;
carry = thisdigit >> PyLong_SHIFT;
thisdigit &= PyLong_MASK;
}
/* Because we're going LSB to MSB, thisdigit is more
significant than what's already in accum, so needs to be
prepended to accum. */
accum |= (twodigits)thisdigit << accumbits;
/* The most-significant digit may be (probably is) at least
partly empty. */
if (i == ndigits - 1) {
/* Count # of sign bits -- they needn't be stored,
* although for signed conversion we need later to
* make sure at least one sign bit gets stored. */
digit s = do_twos_comp ? thisdigit ^ PyLong_MASK : thisdigit;
while (s != 0) {
s >>= 1;
accumbits++;
}
}
else
accumbits += PyLong_SHIFT;
/* Store as many bytes as possible. */
while (accumbits >= 8) {
if (j >= n)
goto Overflow;
++j;
*p = (unsigned char)(accum & 0xff);
p += pincr;
accumbits -= 8;
accum >>= 8;
}
}
/* Store the straggler (if any). */
assert(accumbits < 8);
assert(carry == 0); /* else do_twos_comp and *every* digit was 0 */
if (accumbits > 0) {
if (j >= n)
goto Overflow;
++j;
if (do_twos_comp) {
/* Fill leading bits of the byte with sign bits
(appropriately pretending that the int had an
infinite supply of sign bits). */
accum |= (~(twodigits)0) << accumbits;
}
*p = (unsigned char)(accum & 0xff);
p += pincr;
}
else if (j == n && n > 0 && is_signed) {
/* The main loop filled the byte array exactly, so the code
just above didn't get to ensure there's a sign bit, and the
loop below wouldn't add one either. Make sure a sign bit
exists. */
unsigned char msb = *(p - pincr);
int sign_bit_set = msb >= 0x80;
assert(accumbits == 0);
if (sign_bit_set == do_twos_comp)
return 0;
else
goto Overflow;
}
/* Fill remaining bytes with copies of the sign bit. */
{
unsigned char signbyte = do_twos_comp ? 0xffU : 0U;
for ( ; j < n; ++j, p += pincr)
*p = signbyte;
}
return 0;
Overflow:
PyErr_SetString(PyExc_OverflowError, "int too big to convert");
return -1;
}
/* Create a new int object from a C pointer */
PyObject *
PyLong_FromVoidPtr(void *p)
{
#if SIZEOF_VOID_P <= SIZEOF_LONG
return PyLong_FromUnsignedLong((unsigned long)(uintptr_t)p);
#else
#if SIZEOF_LONG_LONG < SIZEOF_VOID_P
# error "PyLong_FromVoidPtr: sizeof(long long) < sizeof(void*)"
#endif
return PyLong_FromUnsignedLongLong((unsigned long long)(uintptr_t)p);
#endif /* SIZEOF_VOID_P <= SIZEOF_LONG */
}
/* Get a C pointer from an int object. */
void *
PyLong_AsVoidPtr(PyObject *vv)
{
#if SIZEOF_VOID_P <= SIZEOF_LONG
long x;
if (PyLong_Check(vv) && _PyLong_Sign(vv) < 0)
x = PyLong_AsLong(vv);
else
x = PyLong_AsUnsignedLong(vv);
#else
#if SIZEOF_LONG_LONG < SIZEOF_VOID_P
# error "PyLong_AsVoidPtr: sizeof(long long) < sizeof(void*)"
#endif
long long x;
if (PyLong_Check(vv) && _PyLong_Sign(vv) < 0)
x = PyLong_AsLongLong(vv);
else
x = PyLong_AsUnsignedLongLong(vv);
#endif /* SIZEOF_VOID_P <= SIZEOF_LONG */
if (x == -1 && PyErr_Occurred())
return NULL;
return (void *)x;
}
/* Initial long long support by Chris Herborth (chrish@qnx.com), later
* rewritten to use the newer PyLong_{As,From}ByteArray API.
*/
#define PY_ABS_LLONG_MIN (0-(unsigned long long)LLONG_MIN)
/* Create a new int object from a C long long int. */
PyObject *
PyLong_FromLongLong(long long ival)
{
PyLongObject *v;
unsigned long long abs_ival;
unsigned long long t; /* unsigned so >> doesn't propagate sign bit */
int ndigits = 0;
int negative = 0;
if (IS_SMALL_INT(ival)) {
return get_small_int((sdigit)ival);
}
if (ival < 0) {
/* avoid signed overflow on negation; see comments
in PyLong_FromLong above. */
abs_ival = (unsigned long long)(-1-ival) + 1;
negative = 1;
}
else {
abs_ival = (unsigned long long)ival;
}
/* Count the number of Python digits.
We used to pick 5 ("big enough for anything"), but that's a
waste of time and space given that 5*15 = 75 bits are rarely
needed. */
t = abs_ival;
while (t) {
++ndigits;
t >>= PyLong_SHIFT;
}
v = _PyLong_New(ndigits);
if (v != NULL) {
digit *p = v->ob_digit;
Py_SET_SIZE(v, negative ? -ndigits : ndigits);
t = abs_ival;
while (t) {
*p++ = (digit)(t & PyLong_MASK);
t >>= PyLong_SHIFT;
}
}
return (PyObject *)v;
}
/* Create a new int object from a C Py_ssize_t. */
PyObject *
PyLong_FromSsize_t(Py_ssize_t ival)
{
PyLongObject *v;
size_t abs_ival;
size_t t; /* unsigned so >> doesn't propagate sign bit */
int ndigits = 0;
int negative = 0;
if (IS_SMALL_INT(ival)) {
return get_small_int((sdigit)ival);
}
if (ival < 0) {
/* avoid signed overflow when ival = SIZE_T_MIN */
abs_ival = (size_t)(-1-ival)+1;
negative = 1;
}
else {
abs_ival = (size_t)ival;
}
/* Count the number of Python digits. */
t = abs_ival;
while (t) {
++ndigits;
t >>= PyLong_SHIFT;
}
v = _PyLong_New(ndigits);
if (v != NULL) {
digit *p = v->ob_digit;
Py_SET_SIZE(v, negative ? -ndigits : ndigits);
t = abs_ival;
while (t) {
*p++ = (digit)(t & PyLong_MASK);
t >>= PyLong_SHIFT;
}
}
return (PyObject *)v;
}
/* Get a C long long int from an int object or any object that has an
__index__ method. Return -1 and set an error if overflow occurs. */
long long
PyLong_AsLongLong(PyObject *vv)
{
PyLongObject *v;
long long bytes;
int res;
int do_decref = 0; /* if PyNumber_Index was called */
if (vv == NULL) {
PyErr_BadInternalCall();
return -1;
}
if (PyLong_Check(vv)) {
v = (PyLongObject *)vv;
}
else {
v = (PyLongObject *)_PyNumber_Index(vv);
if (v == NULL)
return -1;
do_decref = 1;
}
res = 0;
switch(Py_SIZE(v)) {
case -1:
bytes = -(sdigit)v->ob_digit[0];
break;
case 0:
bytes = 0;
break;
case 1:
bytes = v->ob_digit[0];
break;
default:
res = _PyLong_AsByteArray((PyLongObject *)v, (unsigned char *)&bytes,
SIZEOF_LONG_LONG, PY_LITTLE_ENDIAN, 1);
}
if (do_decref) {
Py_DECREF(v);
}
/* Plan 9 can't handle long long in ? : expressions */
if (res < 0)
return (long long)-1;
else
return bytes;
}
/* Get a C unsigned long long int from an int object.
Return -1 and set an error if overflow occurs. */
unsigned long long
PyLong_AsUnsignedLongLong(PyObject *vv)
{
PyLongObject *v;
unsigned long long bytes;
int res;
if (vv == NULL) {
PyErr_BadInternalCall();
return (unsigned long long)-1;
}
if (!PyLong_Check(vv)) {
PyErr_SetString(PyExc_TypeError, "an integer is required");
return (unsigned long long)-1;
}
v = (PyLongObject*)vv;
switch(Py_SIZE(v)) {
case 0: return 0;
case 1: return v->ob_digit[0];
}
res = _PyLong_AsByteArray((PyLongObject *)vv, (unsigned char *)&bytes,
SIZEOF_LONG_LONG, PY_LITTLE_ENDIAN, 0);
/* Plan 9 can't handle long long in ? : expressions */
if (res < 0)
return (unsigned long long)res;
else
return bytes;
}
/* Get a C unsigned long int from an int object, ignoring the high bits.
Returns -1 and sets an error condition if an error occurs. */
static unsigned long long
_PyLong_AsUnsignedLongLongMask(PyObject *vv)
{
PyLongObject *v;
unsigned long long x;
Py_ssize_t i;
int sign;
if (vv == NULL || !PyLong_Check(vv)) {
PyErr_BadInternalCall();
return (unsigned long long) -1;
}
v = (PyLongObject *)vv;
switch(Py_SIZE(v)) {
case 0: return 0;
case 1: return v->ob_digit[0];
}
i = Py_SIZE(v);
sign = 1;
x = 0;
if (i < 0) {
sign = -1;
i = -i;
}
while (--i >= 0) {
x = (x << PyLong_SHIFT) | v->ob_digit[i];
}
return x * sign;
}
unsigned long long
PyLong_AsUnsignedLongLongMask(PyObject *op)
{
PyLongObject *lo;
unsigned long long val;
if (op == NULL) {
PyErr_BadInternalCall();
return (unsigned long long)-1;
}
if (PyLong_Check(op)) {
return _PyLong_AsUnsignedLongLongMask(op);
}
lo = (PyLongObject *)_PyNumber_Index(op);
if (lo == NULL)
return (unsigned long long)-1;
val = _PyLong_AsUnsignedLongLongMask((PyObject *)lo);
Py_DECREF(lo);
return val;
}
/* Get a C long long int from an int object or any object that has an
__index__ method.
On overflow, return -1 and set *overflow to 1 or -1 depending on the sign of
the result. Otherwise *overflow is 0.
For other errors (e.g., TypeError), return -1 and set an error condition.
In this case *overflow will be 0.
*/
long long
PyLong_AsLongLongAndOverflow(PyObject *vv, int *overflow)
{
/* This version by Tim Peters */
PyLongObject *v;
unsigned long long x, prev;
long long res;
Py_ssize_t i;
int sign;
int do_decref = 0; /* if PyNumber_Index was called */
*overflow = 0;
if (vv == NULL) {
PyErr_BadInternalCall();
return -1;
}
if (PyLong_Check(vv)) {
v = (PyLongObject *)vv;
}
else {
v = (PyLongObject *)_PyNumber_Index(vv);
if (v == NULL)
return -1;
do_decref = 1;
}
res = -1;
i = Py_SIZE(v);
switch (i) {
case -1:
res = -(sdigit)v->ob_digit[0];
break;
case 0:
res = 0;
break;
case 1:
res = v->ob_digit[0];
break;
default:
sign = 1;
x = 0;
if (i < 0) {
sign = -1;
i = -(i);
}
while (--i >= 0) {
prev = x;
x = (x << PyLong_SHIFT) + v->ob_digit[i];
if ((x >> PyLong_SHIFT) != prev) {
*overflow = sign;
goto exit;
}
}
/* Haven't lost any bits, but casting to long requires extra
* care (see comment above).
*/
if (x <= (unsigned long long)LLONG_MAX) {
res = (long long)x * sign;
}
else if (sign < 0 && x == PY_ABS_LLONG_MIN) {
res = LLONG_MIN;
}
else {
*overflow = sign;
/* res is already set to -1 */
}
}
exit:
if (do_decref) {
Py_DECREF(v);
}
return res;
}
int
_PyLong_UnsignedShort_Converter(PyObject *obj, void *ptr)
{
unsigned long uval;
if (PyLong_Check(obj) && _PyLong_Sign(obj) < 0) {
PyErr_SetString(PyExc_ValueError, "value must be positive");
return 0;
}
uval = PyLong_AsUnsignedLong(obj);
if (uval == (unsigned long)-1 && PyErr_Occurred())
return 0;
if (uval > USHRT_MAX) {
PyErr_SetString(PyExc_OverflowError,
"Python int too large for C unsigned short");
return 0;
}
*(unsigned short *)ptr = Py_SAFE_DOWNCAST(uval, unsigned long, unsigned short);
return 1;
}
int
_PyLong_UnsignedInt_Converter(PyObject *obj, void *ptr)
{
unsigned long uval;
if (PyLong_Check(obj) && _PyLong_Sign(obj) < 0) {
PyErr_SetString(PyExc_ValueError, "value must be positive");
return 0;
}
uval = PyLong_AsUnsignedLong(obj);
if (uval == (unsigned long)-1 && PyErr_Occurred())
return 0;
if (uval > UINT_MAX) {
PyErr_SetString(PyExc_OverflowError,
"Python int too large for C unsigned int");
return 0;
}
*(unsigned int *)ptr = Py_SAFE_DOWNCAST(uval, unsigned long, unsigned int);
return 1;
}
int
_PyLong_UnsignedLong_Converter(PyObject *obj, void *ptr)
{
unsigned long uval;
if (PyLong_Check(obj) && _PyLong_Sign(obj) < 0) {
PyErr_SetString(PyExc_ValueError, "value must be positive");
return 0;
}
uval = PyLong_AsUnsignedLong(obj);
if (uval == (unsigned long)-1 && PyErr_Occurred())
return 0;
*(unsigned long *)ptr = uval;
return 1;
}
int
_PyLong_UnsignedLongLong_Converter(PyObject *obj, void *ptr)
{
unsigned long long uval;
if (PyLong_Check(obj) && _PyLong_Sign(obj) < 0) {
PyErr_SetString(PyExc_ValueError, "value must be positive");
return 0;
}
uval = PyLong_AsUnsignedLongLong(obj);
if (uval == (unsigned long long)-1 && PyErr_Occurred())
return 0;
*(unsigned long long *)ptr = uval;
return 1;
}
int
_PyLong_Size_t_Converter(PyObject *obj, void *ptr)
{
size_t uval;
if (PyLong_Check(obj) && _PyLong_Sign(obj) < 0) {
PyErr_SetString(PyExc_ValueError, "value must be positive");
return 0;
}
uval = PyLong_AsSize_t(obj);
if (uval == (size_t)-1 && PyErr_Occurred())
return 0;
*(size_t *)ptr = uval;
return 1;
}
#define CHECK_BINOP(v,w) \
do { \
if (!PyLong_Check(v) || !PyLong_Check(w)) \
Py_RETURN_NOTIMPLEMENTED; \
} while(0)
/* x[0:m] and y[0:n] are digit vectors, LSD first, m >= n required. x[0:n]
* is modified in place, by adding y to it. Carries are propagated as far as
* x[m-1], and the remaining carry (0 or 1) is returned.
*/
static digit
v_iadd(digit *x, Py_ssize_t m, digit *y, Py_ssize_t n)
{
Py_ssize_t i;
digit carry = 0;
assert(m >= n);
for (i = 0; i < n; ++i) {
carry += x[i] + y[i];
x[i] = carry & PyLong_MASK;
carry >>= PyLong_SHIFT;
assert((carry & 1) == carry);
}
for (; carry && i < m; ++i) {
carry += x[i];
x[i] = carry & PyLong_MASK;
carry >>= PyLong_SHIFT;
assert((carry & 1) == carry);
}
return carry;
}
/* x[0:m] and y[0:n] are digit vectors, LSD first, m >= n required. x[0:n]
* is modified in place, by subtracting y from it. Borrows are propagated as
* far as x[m-1], and the remaining borrow (0 or 1) is returned.
*/
static digit
v_isub(digit *x, Py_ssize_t m, digit *y, Py_ssize_t n)
{
Py_ssize_t i;
digit borrow = 0;
assert(m >= n);
for (i = 0; i < n; ++i) {
borrow = x[i] - y[i] - borrow;
x[i] = borrow & PyLong_MASK;
borrow >>= PyLong_SHIFT;
borrow &= 1; /* keep only 1 sign bit */
}
for (; borrow && i < m; ++i) {
borrow = x[i] - borrow;
x[i] = borrow & PyLong_MASK;
borrow >>= PyLong_SHIFT;
borrow &= 1;
}
return borrow;
}
/* Shift digit vector a[0:m] d bits left, with 0 <= d < PyLong_SHIFT. Put
* result in z[0:m], and return the d bits shifted out of the top.
*/
static digit
v_lshift(digit *z, digit *a, Py_ssize_t m, int d)
{
Py_ssize_t i;
digit carry = 0;
assert(0 <= d && d < PyLong_SHIFT);
for (i=0; i < m; i++) {
twodigits acc = (twodigits)a[i] << d | carry;
z[i] = (digit)acc & PyLong_MASK;
carry = (digit)(acc >> PyLong_SHIFT);
}
return carry;
}
/* Shift digit vector a[0:m] d bits right, with 0 <= d < PyLong_SHIFT. Put
* result in z[0:m], and return the d bits shifted out of the bottom.
*/
static digit
v_rshift(digit *z, digit *a, Py_ssize_t m, int d)
{
Py_ssize_t i;
digit carry = 0;
digit mask = ((digit)1 << d) - 1U;
assert(0 <= d && d < PyLong_SHIFT);
for (i=m; i-- > 0;) {
twodigits acc = (twodigits)carry << PyLong_SHIFT | a[i];
carry = (digit)acc & mask;
z[i] = (digit)(acc >> d);
}
return carry;
}
/* Divide long pin, w/ size digits, by non-zero digit n, storing quotient
in pout, and returning the remainder. pin and pout point at the LSD.
It's OK for pin == pout on entry, which saves oodles of mallocs/frees in
_PyLong_Format, but that should be done with great care since ints are
immutable. */
static digit
inplace_divrem1(digit *pout, digit *pin, Py_ssize_t size, digit n)
{
twodigits rem = 0;
assert(n > 0 && n <= PyLong_MASK);
pin += size;
pout += size;
while (--size >= 0) {
digit hi;
rem = (rem << PyLong_SHIFT) | *--pin;
*--pout = hi = (digit)(rem / n);
rem -= (twodigits)hi * n;
}
return (digit)rem;
}
/* Divide an integer by a digit, returning both the quotient
(as function result) and the remainder (through *prem).
The sign of a is ignored; n should not be zero. */
static PyLongObject *
divrem1(PyLongObject *a, digit n, digit *prem)
{
const Py_ssize_t size = Py_ABS(Py_SIZE(a));
PyLongObject *z;
assert(n > 0 && n <= PyLong_MASK);
z = _PyLong_New(size);
if (z == NULL)
return NULL;
*prem = inplace_divrem1(z->ob_digit, a->ob_digit, size, n);
return long_normalize(z);
}
/* Convert an integer to a base 10 string. Returns a new non-shared
string. (Return value is non-shared so that callers can modify the
returned value if necessary.) */
static int
long_to_decimal_string_internal(PyObject *aa,
PyObject **p_output,
_PyUnicodeWriter *writer,
_PyBytesWriter *bytes_writer,
char **bytes_str)
{
PyLongObject *scratch, *a;
PyObject *str = NULL;
Py_ssize_t size, strlen, size_a, i, j;
digit *pout, *pin, rem, tenpow;
int negative;
int d;
enum PyUnicode_Kind kind;
a = (PyLongObject *)aa;
if (a == NULL || !PyLong_Check(a)) {
PyErr_BadInternalCall();
return -1;
}
size_a = Py_ABS(Py_SIZE(a));
negative = Py_SIZE(a) < 0;
/* quick and dirty upper bound for the number of digits
required to express a in base _PyLong_DECIMAL_BASE:
#digits = 1 + floor(log2(a) / log2(_PyLong_DECIMAL_BASE))
But log2(a) < size_a * PyLong_SHIFT, and
log2(_PyLong_DECIMAL_BASE) = log2(10) * _PyLong_DECIMAL_SHIFT
> 3.3 * _PyLong_DECIMAL_SHIFT
size_a * PyLong_SHIFT / (3.3 * _PyLong_DECIMAL_SHIFT) =
size_a + size_a / d < size_a + size_a / floor(d),
where d = (3.3 * _PyLong_DECIMAL_SHIFT) /
(PyLong_SHIFT - 3.3 * _PyLong_DECIMAL_SHIFT)
*/
d = (33 * _PyLong_DECIMAL_SHIFT) /
(10 * PyLong_SHIFT - 33 * _PyLong_DECIMAL_SHIFT);
assert(size_a < PY_SSIZE_T_MAX/2);
size = 1 + size_a + size_a / d;
scratch = _PyLong_New(size);
if (scratch == NULL)
return -1;
/* convert array of base _PyLong_BASE digits in pin to an array of
base _PyLong_DECIMAL_BASE digits in pout, following Knuth (TAOCP,
Volume 2 (3rd edn), section 4.4, Method 1b). */
pin = a->ob_digit;
pout = scratch->ob_digit;
size = 0;
for (i = size_a; --i >= 0; ) {
digit hi = pin[i];
for (j = 0; j < size; j++) {
twodigits z = (twodigits)pout[j] << PyLong_SHIFT | hi;
hi = (digit)(z / _PyLong_DECIMAL_BASE);
pout[j] = (digit)(z - (twodigits)hi *
_PyLong_DECIMAL_BASE);
}
while (hi) {
pout[size++] = hi % _PyLong_DECIMAL_BASE;
hi /= _PyLong_DECIMAL_BASE;
}
/* check for keyboard interrupt */
SIGCHECK({
Py_DECREF(scratch);
return -1;
});
}
/* pout should have at least one digit, so that the case when a = 0
works correctly */
if (size == 0)
pout[size++] = 0;
/* calculate exact length of output string, and allocate */
strlen = negative + 1 + (size - 1) * _PyLong_DECIMAL_SHIFT;
tenpow = 10;
rem = pout[size-1];
while (rem >= tenpow) {
tenpow *= 10;
strlen++;
}
if (writer) {
if (_PyUnicodeWriter_Prepare(writer, strlen, '9') == -1) {
Py_DECREF(scratch);
return -1;
}
kind = writer->kind;
}
else if (bytes_writer) {
*bytes_str = _PyBytesWriter_Prepare(bytes_writer, *bytes_str, strlen);
if (*bytes_str == NULL) {
Py_DECREF(scratch);
return -1;
}
}
else {
str = PyUnicode_New(strlen, '9');
if (str == NULL) {
Py_DECREF(scratch);
return -1;
}
kind = PyUnicode_KIND(str);
}
#define WRITE_DIGITS(p) \
do { \
/* pout[0] through pout[size-2] contribute exactly \
_PyLong_DECIMAL_SHIFT digits each */ \
for (i=0; i < size - 1; i++) { \
rem = pout[i]; \
for (j = 0; j < _PyLong_DECIMAL_SHIFT; j++) { \
*--p = '0' + rem % 10; \
rem /= 10; \
} \
} \
/* pout[size-1]: always produce at least one decimal digit */ \
rem = pout[i]; \
do { \
*--p = '0' + rem % 10; \
rem /= 10; \
} while (rem != 0); \
\
/* and sign */ \
if (negative) \
*--p = '-'; \
} while (0)
#define WRITE_UNICODE_DIGITS(TYPE) \
do { \
if (writer) \
p = (TYPE*)PyUnicode_DATA(writer->buffer) + writer->pos + strlen; \
else \
p = (TYPE*)PyUnicode_DATA(str) + strlen; \
\
WRITE_DIGITS(p); \
\
/* check we've counted correctly */ \
if (writer) \
assert(p == ((TYPE*)PyUnicode_DATA(writer->buffer) + writer->pos)); \
else \
assert(p == (TYPE*)PyUnicode_DATA(str)); \
} while (0)
/* fill the string right-to-left */
if (bytes_writer) {
char *p = *bytes_str + strlen;
WRITE_DIGITS(p);
assert(p == *bytes_str);
}
else if (kind == PyUnicode_1BYTE_KIND) {
Py_UCS1 *p;
WRITE_UNICODE_DIGITS(Py_UCS1);
}
else if (kind == PyUnicode_2BYTE_KIND) {
Py_UCS2 *p;
WRITE_UNICODE_DIGITS(Py_UCS2);
}
else {
Py_UCS4 *p;
assert (kind == PyUnicode_4BYTE_KIND);
WRITE_UNICODE_DIGITS(Py_UCS4);
}
#undef WRITE_DIGITS
#undef WRITE_UNICODE_DIGITS
Py_DECREF(scratch);
if (writer) {
writer->pos += strlen;
}
else if (bytes_writer) {
(*bytes_str) += strlen;
}
else {
assert(_PyUnicode_CheckConsistency(str, 1));
*p_output = (PyObject *)str;
}
return 0;
}
static PyObject *
long_to_decimal_string(PyObject *aa)
{
PyObject *v;
if (long_to_decimal_string_internal(aa, &v, NULL, NULL, NULL) == -1)
return NULL;
return v;
}
/* Convert an int object to a string, using a given conversion base,
which should be one of 2, 8 or 16. Return a string object.
If base is 2, 8 or 16, add the proper prefix '0b', '0o' or '0x'
if alternate is nonzero. */
static int
long_format_binary(PyObject *aa, int base, int alternate,
PyObject **p_output, _PyUnicodeWriter *writer,
_PyBytesWriter *bytes_writer, char **bytes_str)
{
PyLongObject *a = (PyLongObject *)aa;
PyObject *v = NULL;
Py_ssize_t sz;
Py_ssize_t size_a;
enum PyUnicode_Kind kind;
int negative;
int bits;
assert(base == 2 || base == 8 || base == 16);
if (a == NULL || !PyLong_Check(a)) {
PyErr_BadInternalCall();
return -1;
}
size_a = Py_ABS(Py_SIZE(a));
negative = Py_SIZE(a) < 0;
/* Compute a rough upper bound for the length of the string */
switch (base) {
case 16:
bits = 4;
break;
case 8:
bits = 3;
break;
case 2:
bits = 1;
break;
default:
Py_UNREACHABLE();
}
/* Compute exact length 'sz' of output string. */
if (size_a == 0) {
sz = 1;
}
else {
Py_ssize_t size_a_in_bits;
/* Ensure overflow doesn't occur during computation of sz. */
if (size_a > (PY_SSIZE_T_MAX - 3) / PyLong_SHIFT) {
PyErr_SetString(PyExc_OverflowError,
"int too large to format");
return -1;
}
size_a_in_bits = (size_a - 1) * PyLong_SHIFT +
bit_length_digit(a->ob_digit[size_a - 1]);
/* Allow 1 character for a '-' sign. */
sz = negative + (size_a_in_bits + (bits - 1)) / bits;
}
if (alternate) {
/* 2 characters for prefix */
sz += 2;
}
if (writer) {
if (_PyUnicodeWriter_Prepare(writer, sz, 'x') == -1)
return -1;
kind = writer->kind;
}
else if (bytes_writer) {
*bytes_str = _PyBytesWriter_Prepare(bytes_writer, *bytes_str, sz);
if (*bytes_str == NULL)
return -1;
}
else {
v = PyUnicode_New(sz, 'x');
if (v == NULL)
return -1;
kind = PyUnicode_KIND(v);
}
#define WRITE_DIGITS(p) \
do { \
if (size_a == 0) { \
*--p = '0'; \
} \
else { \
/* JRH: special case for power-of-2 bases */ \
twodigits accum = 0; \
int accumbits = 0; /* # of bits in accum */ \
Py_ssize_t i; \
for (i = 0; i < size_a; ++i) { \
accum |= (twodigits)a->ob_digit[i] << accumbits; \
accumbits += PyLong_SHIFT; \
assert(accumbits >= bits); \
do { \
char cdigit; \
cdigit = (char)(accum & (base - 1)); \
cdigit += (cdigit < 10) ? '0' : 'a'-10; \
*--p = cdigit; \
accumbits -= bits; \
accum >>= bits; \
} while (i < size_a-1 ? accumbits >= bits : accum > 0); \
} \
} \
\
if (alternate) { \
if (base == 16) \
*--p = 'x'; \
else if (base == 8) \
*--p = 'o'; \
else /* (base == 2) */ \
*--p = 'b'; \
*--p = '0'; \
} \
if (negative) \
*--p = '-'; \
} while (0)
#define WRITE_UNICODE_DIGITS(TYPE) \
do { \
if (writer) \
p = (TYPE*)PyUnicode_DATA(writer->buffer) + writer->pos + sz; \
else \
p = (TYPE*)PyUnicode_DATA(v) + sz; \
\
WRITE_DIGITS(p); \
\
if (writer) \
assert(p == ((TYPE*)PyUnicode_DATA(writer->buffer) + writer->pos)); \
else \
assert(p == (TYPE*)PyUnicode_DATA(v)); \
} while (0)
if (bytes_writer) {
char *p = *bytes_str + sz;
WRITE_DIGITS(p);
assert(p == *bytes_str);
}
else if (kind == PyUnicode_1BYTE_KIND) {
Py_UCS1 *p;
WRITE_UNICODE_DIGITS(Py_UCS1);
}
else if (kind == PyUnicode_2BYTE_KIND) {
Py_UCS2 *p;
WRITE_UNICODE_DIGITS(Py_UCS2);
}
else {
Py_UCS4 *p;
assert (kind == PyUnicode_4BYTE_KIND);
WRITE_UNICODE_DIGITS(Py_UCS4);
}
#undef WRITE_DIGITS
#undef WRITE_UNICODE_DIGITS
if (writer) {
writer->pos += sz;
}
else if (bytes_writer) {
(*bytes_str) += sz;
}
else {
assert(_PyUnicode_CheckConsistency(v, 1));
*p_output = v;
}
return 0;
}
PyObject *
_PyLong_Format(PyObject *obj, int base)
{
PyObject *str;
int err;
if (base == 10)
err = long_to_decimal_string_internal(obj, &str, NULL, NULL, NULL);
else
err = long_format_binary(obj, base, 1, &str, NULL, NULL, NULL);
if (err == -1)
return NULL;
return str;
}
int
_PyLong_FormatWriter(_PyUnicodeWriter *writer,
PyObject *obj,
int base, int alternate)
{
if (base == 10)
return long_to_decimal_string_internal(obj, NULL, writer,
NULL, NULL);
else
return long_format_binary(obj, base, alternate, NULL, writer,
NULL, NULL);
}
char*
_PyLong_FormatBytesWriter(_PyBytesWriter *writer, char *str,
PyObject *obj,
int base, int alternate)
{
char *str2;
int res;
str2 = str;
if (base == 10)
res = long_to_decimal_string_internal(obj, NULL, NULL,
writer, &str2);
else
res = long_format_binary(obj, base, alternate, NULL, NULL,
writer, &str2);
if (res < 0)
return NULL;
assert(str2 != NULL);
return str2;
}
/* Table of digit values for 8-bit string -> integer conversion.
* '0' maps to 0, ..., '9' maps to 9.
* 'a' and 'A' map to 10, ..., 'z' and 'Z' map to 35.
* All other indices map to 37.
* Note that when converting a base B string, a char c is a legitimate
* base B digit iff _PyLong_DigitValue[Py_CHARPyLong_MASK(c)] < B.
*/
unsigned char _PyLong_DigitValue[256] = {
37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37,
37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37,
37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37,
0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 37, 37, 37, 37, 37, 37,
37, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24,
25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 37, 37, 37, 37, 37,
37, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24,
25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 37, 37, 37, 37, 37,
37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37,
37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37,
37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37,
37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37,
37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37,
37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37,
37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37,
37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37, 37,
};
/* *str points to the first digit in a string of base `base` digits. base
* is a power of 2 (2, 4, 8, 16, or 32). *str is set to point to the first
* non-digit (which may be *str!). A normalized int is returned.
* The point to this routine is that it takes time linear in the number of
* string characters.
*
* Return values:
* -1 on syntax error (exception needs to be set, *res is untouched)
* 0 else (exception may be set, in that case *res is set to NULL)
*/
static int
long_from_binary_base(const char **str, int base, PyLongObject **res)
{
const char *p = *str;
const char *start = p;
char prev = 0;
Py_ssize_t digits = 0;
int bits_per_char;
Py_ssize_t n;
PyLongObject *z;
twodigits accum;
int bits_in_accum;
digit *pdigit;
assert(base >= 2 && base <= 32 && (base & (base - 1)) == 0);
n = base;
for (bits_per_char = -1; n; ++bits_per_char) {
n >>= 1;
}
/* count digits and set p to end-of-string */
while (_PyLong_DigitValue[Py_CHARMASK(*p)] < base || *p == '_') {
if (*p == '_') {
if (prev == '_') {
*str = p - 1;
return -1;
}
} else {
++digits;
}
prev = *p;
++p;
}
if (prev == '_') {
/* Trailing underscore not allowed. */
*str = p - 1;
return -1;
}
*str = p;
/* n <- the number of Python digits needed,
= ceiling((digits * bits_per_char) / PyLong_SHIFT). */
if (digits > (PY_SSIZE_T_MAX - (PyLong_SHIFT - 1)) / bits_per_char) {
PyErr_SetString(PyExc_ValueError,
"int string too large to convert");
*res = NULL;
return 0;
}
n = (digits * bits_per_char + PyLong_SHIFT - 1) / PyLong_SHIFT;
z = _PyLong_New(n);
if (z == NULL) {
*res = NULL;
return 0;
}
/* Read string from right, and fill in int from left; i.e.,
* from least to most significant in both.
*/
accum = 0;
bits_in_accum = 0;
pdigit = z->ob_digit;
while (--p >= start) {
int k;
if (*p == '_') {
continue;
}
k = (int)_PyLong_DigitValue[Py_CHARMASK(*p)];
assert(k >= 0 && k < base);
accum |= (twodigits)k << bits_in_accum;
bits_in_accum += bits_per_char;
if (bits_in_accum >= PyLong_SHIFT) {
*pdigit++ = (digit)(accum & PyLong_MASK);
assert(pdigit - z->ob_digit <= n);
accum >>= PyLong_SHIFT;
bits_in_accum -= PyLong_SHIFT;
assert(bits_in_accum < PyLong_SHIFT);
}
}
if (bits_in_accum) {
assert(bits_in_accum <= PyLong_SHIFT);
*pdigit++ = (digit)accum;
assert(pdigit - z->ob_digit <= n);
}
while (pdigit - z->ob_digit < n)
*pdigit++ = 0;
*res = long_normalize(z);
return 0;
}
/* Parses an int from a bytestring. Leading and trailing whitespace will be
* ignored.
*
* If successful, a PyLong object will be returned and 'pend' will be pointing
* to the first unused byte unless it's NULL.
*
* If unsuccessful, NULL will be returned.
*/
PyObject *
PyLong_FromString(const char *str, char **pend, int base)
{
int sign = 1, error_if_nonzero = 0;
const char *start, *orig_str = str;
PyLongObject *z = NULL;
PyObject *strobj;
Py_ssize_t slen;
if ((base != 0 && base < 2) || base > 36) {
PyErr_SetString(PyExc_ValueError,
"int() arg 2 must be >= 2 and <= 36");
return NULL;
}
while (*str != '\0' && Py_ISSPACE(*str)) {
str++;
}
if (*str == '+') {
++str;
}
else if (*str == '-') {
++str;
sign = -1;
}
if (base == 0) {
if (str[0] != '0') {
base = 10;
}
else if (str[1] == 'x' || str[1] == 'X') {
base = 16;
}
else if (str[1] == 'o' || str[1] == 'O') {
base = 8;
}
else if (str[1] == 'b' || str[1] == 'B') {
base = 2;
}
else {
/* "old" (C-style) octal literal, now invalid.
it might still be zero though */
error_if_nonzero = 1;
base = 10;
}
}
if (str[0] == '0' &&
((base == 16 && (str[1] == 'x' || str[1] == 'X')) ||
(base == 8 && (str[1] == 'o' || str[1] == 'O')) ||
(base == 2 && (str[1] == 'b' || str[1] == 'B')))) {
str += 2;
/* One underscore allowed here. */
if (*str == '_') {
++str;
}
}
if (str[0] == '_') {
/* May not start with underscores. */
goto onError;
}
start = str;
if ((base & (base - 1)) == 0) {
int res = long_from_binary_base(&str, base, &z);
if (res < 0) {
/* Syntax error. */
goto onError;
}
}
else {
/***
Binary bases can be converted in time linear in the number of digits, because
Python's representation base is binary. Other bases (including decimal!) use
the simple quadratic-time algorithm below, complicated by some speed tricks.
First some math: the largest integer that can be expressed in N base-B digits
is B**N-1. Consequently, if we have an N-digit input in base B, the worst-
case number of Python digits needed to hold it is the smallest integer n s.t.
BASE**n-1 >= B**N-1 [or, adding 1 to both sides]
BASE**n >= B**N [taking logs to base BASE]
n >= log(B**N)/log(BASE) = N * log(B)/log(BASE)
The static array log_base_BASE[base] == log(base)/log(BASE) so we can compute
this quickly. A Python int with that much space is reserved near the start,
and the result is computed into it.
The input string is actually treated as being in base base**i (i.e., i digits
are processed at a time), where two more static arrays hold:
convwidth_base[base] = the largest integer i such that base**i <= BASE
convmultmax_base[base] = base ** convwidth_base[base]
The first of these is the largest i such that i consecutive input digits
must fit in a single Python digit. The second is effectively the input
base we're really using.
Viewing the input as a sequence <c0, c1, ..., c_n-1> of digits in base
convmultmax_base[base], the result is "simply"
(((c0*B + c1)*B + c2)*B + c3)*B + ... ))) + c_n-1
where B = convmultmax_base[base].
Error analysis: as above, the number of Python digits `n` needed is worst-
case
n >= N * log(B)/log(BASE)
where `N` is the number of input digits in base `B`. This is computed via
size_z = (Py_ssize_t)((scan - str) * log_base_BASE[base]) + 1;
below. Two numeric concerns are how much space this can waste, and whether
the computed result can be too small. To be concrete, assume BASE = 2**15,
which is the default (and it's unlikely anyone changes that).
Waste isn't a problem: provided the first input digit isn't 0, the difference
between the worst-case input with N digits and the smallest input with N
digits is about a factor of B, but B is small compared to BASE so at most
one allocated Python digit can remain unused on that count. If
N*log(B)/log(BASE) is mathematically an exact integer, then truncating that
and adding 1 returns a result 1 larger than necessary. However, that can't
happen: whenever B is a power of 2, long_from_binary_base() is called
instead, and it's impossible for B**i to be an integer power of 2**15 when
B is not a power of 2 (i.e., it's impossible for N*log(B)/log(BASE) to be
an exact integer when B is not a power of 2, since B**i has a prime factor
other than 2 in that case, but (2**15)**j's only prime factor is 2).
The computed result can be too small if the true value of N*log(B)/log(BASE)
is a little bit larger than an exact integer, but due to roundoff errors (in
computing log(B), log(BASE), their quotient, and/or multiplying that by N)
yields a numeric result a little less than that integer. Unfortunately, "how
close can a transcendental function get to an integer over some range?"
questions are generally theoretically intractable. Computer analysis via
continued fractions is practical: expand log(B)/log(BASE) via continued
fractions, giving a sequence i/j of "the best" rational approximations. Then
j*log(B)/log(BASE) is approximately equal to (the integer) i. This shows that
we can get very close to being in trouble, but very rarely. For example,
76573 is a denominator in one of the continued-fraction approximations to
log(10)/log(2**15), and indeed:
>>> log(10)/log(2**15)*76573
16958.000000654003
is very close to an integer. If we were working with IEEE single-precision,
rounding errors could kill us. Finding worst cases in IEEE double-precision
requires better-than-double-precision log() functions, and Tim didn't bother.
Instead the code checks to see whether the allocated space is enough as each
new Python digit is added, and copies the whole thing to a larger int if not.
This should happen extremely rarely, and in fact I don't have a test case
that triggers it(!). Instead the code was tested by artificially allocating
just 1 digit at the start, so that the copying code was exercised for every
digit beyond the first.
***/
twodigits c; /* current input character */
Py_ssize_t size_z;
Py_ssize_t digits = 0;
int i;
int convwidth;
twodigits convmultmax, convmult;
digit *pz, *pzstop;
const char *scan, *lastdigit;
char prev = 0;
static double log_base_BASE[37] = {0.0e0,};
static int convwidth_base[37] = {0,};
static twodigits convmultmax_base[37] = {0,};
if (log_base_BASE[base] == 0.0) {
twodigits convmax = base;
int i = 1;
log_base_BASE[base] = (log((double)base) /
log((double)PyLong_BASE));
for (;;) {
twodigits next = convmax * base;
if (next > PyLong_BASE) {
break;
}
convmax = next;
++i;
}
convmultmax_base[base] = convmax;
assert(i > 0);
convwidth_base[base] = i;
}
/* Find length of the string of numeric characters. */
scan = str;
lastdigit = str;
while (_PyLong_DigitValue[Py_CHARMASK(*scan)] < base || *scan == '_') {
if (*scan == '_') {
if (prev == '_') {
/* Only one underscore allowed. */
str = lastdigit + 1;
goto onError;
}
}
else {
++digits;
lastdigit = scan;
}
prev = *scan;
++scan;
}
if (prev == '_') {
/* Trailing underscore not allowed. */
/* Set error pointer to first underscore. */
str = lastdigit + 1;
goto onError;
}
/* Create an int object that can contain the largest possible
* integer with this base and length. Note that there's no
* need to initialize z->ob_digit -- no slot is read up before
* being stored into.
*/
double fsize_z = (double)digits * log_base_BASE[base] + 1.0;
if (fsize_z > (double)MAX_LONG_DIGITS) {
/* The same exception as in _PyLong_New(). */
PyErr_SetString(PyExc_OverflowError,
"too many digits in integer");
return NULL;
}
size_z = (Py_ssize_t)fsize_z;
/* Uncomment next line to test exceedingly rare copy code */
/* size_z = 1; */
assert(size_z > 0);
z = _PyLong_New(size_z);
if (z == NULL) {
return NULL;
}
Py_SET_SIZE(z, 0);
/* `convwidth` consecutive input digits are treated as a single
* digit in base `convmultmax`.
*/
convwidth = convwidth_base[base];
convmultmax = convmultmax_base[base];
/* Work ;-) */
while (str < scan) {
if (*str == '_') {
str++;
continue;
}
/* grab up to convwidth digits from the input string */
c = (digit)_PyLong_DigitValue[Py_CHARMASK(*str++)];
for (i = 1; i < convwidth && str != scan; ++str) {
if (*str == '_') {
continue;
}
i++;
c = (twodigits)(c * base +
(int)_PyLong_DigitValue[Py_CHARMASK(*str)]);
assert(c < PyLong_BASE);
}
convmult = convmultmax;
/* Calculate the shift only if we couldn't get
* convwidth digits.
*/
if (i != convwidth) {
convmult = base;
for ( ; i > 1; --i) {
convmult *= base;
}
}
/* Multiply z by convmult, and add c. */
pz = z->ob_digit;
pzstop = pz + Py_SIZE(z);
for (; pz < pzstop; ++pz) {
c += (twodigits)*pz * convmult;
*pz = (digit)(c & PyLong_MASK);
c >>= PyLong_SHIFT;
}
/* carry off the current end? */
if (c) {
assert(c < PyLong_BASE);
if (Py_SIZE(z) < size_z) {
*pz = (digit)c;
Py_SET_SIZE(z, Py_SIZE(z) + 1);
}
else {
PyLongObject *tmp;
/* Extremely rare. Get more space. */
assert(Py_SIZE(z) == size_z);
tmp = _PyLong_New(size_z + 1);
if (tmp == NULL) {
Py_DECREF(z);
return NULL;
}
memcpy(tmp->ob_digit,
z->ob_digit,
sizeof(digit) * size_z);
Py_DECREF(z);
z = tmp;
z->ob_digit[size_z] = (digit)c;
++size_z;
}
}
}
}
if (z == NULL) {
return NULL;
}
if (error_if_nonzero) {
/* reset the base to 0, else the exception message
doesn't make too much sense */
base = 0;
if (Py_SIZE(z) != 0) {
goto onError;
}
/* there might still be other problems, therefore base
remains zero here for the same reason */
}
if (str == start) {
goto onError;
}
if (sign < 0) {
Py_SET_SIZE(z, -(Py_SIZE(z)));
}
while (*str && Py_ISSPACE(*str)) {
str++;
}
if (*str != '\0') {
goto onError;
}
long_normalize(z);
z = maybe_small_long(z);
if (z == NULL) {
return NULL;
}
if (pend != NULL) {
*pend = (char *)str;
}
return (PyObject *) z;
onError:
if (pend != NULL) {
*pend = (char *)str;
}
Py_XDECREF(z);
slen = strlen(orig_str) < 200 ? strlen(orig_str) : 200;
strobj = PyUnicode_FromStringAndSize(orig_str, slen);
if (strobj == NULL) {
return NULL;
}
PyErr_Format(PyExc_ValueError,
"invalid literal for int() with base %d: %.200R",
base, strobj);
Py_DECREF(strobj);
return NULL;
}
/* Since PyLong_FromString doesn't have a length parameter,
* check here for possible NULs in the string.
*
* Reports an invalid literal as a bytes object.
*/
PyObject *
_PyLong_FromBytes(const char *s, Py_ssize_t len, int base)
{
PyObject *result, *strobj;
char *end = NULL;
result = PyLong_FromString(s, &end, base);
if (end == NULL || (result != NULL && end == s + len))
return result;
Py_XDECREF(result);
strobj = PyBytes_FromStringAndSize(s, Py_MIN(len, 200));
if (strobj != NULL) {
PyErr_Format(PyExc_ValueError,
"invalid literal for int() with base %d: %.200R",
base, strobj);
Py_DECREF(strobj);
}
return NULL;
}
PyObject *
PyLong_FromUnicode(Py_UNICODE *u, Py_ssize_t length, int base)
{
PyObject *v, *unicode = PyUnicode_FromWideChar(u, length);
if (unicode == NULL)
return NULL;
v = PyLong_FromUnicodeObject(unicode, base);
Py_DECREF(unicode);
return v;
}
PyObject *
PyLong_FromUnicodeObject(PyObject *u, int base)
{
PyObject *result, *asciidig;
const char *buffer;
char *end = NULL;
Py_ssize_t buflen;
asciidig = _PyUnicode_TransformDecimalAndSpaceToASCII(u);
if (asciidig == NULL)
return NULL;
assert(PyUnicode_IS_ASCII(asciidig));
/* Simply get a pointer to existing ASCII characters. */
buffer = PyUnicode_AsUTF8AndSize(asciidig, &buflen);
assert(buffer != NULL);
result = PyLong_FromString(buffer, &end, base);
if (end == NULL || (result != NULL && end == buffer + buflen)) {
Py_DECREF(asciidig);
return result;
}
Py_DECREF(asciidig);
Py_XDECREF(result);
PyErr_Format(PyExc_ValueError,
"invalid literal for int() with base %d: %.200R",
base, u);
return NULL;
}
/* forward */
static PyLongObject *x_divrem
(PyLongObject *, PyLongObject *, PyLongObject **);
static PyObject *long_long(PyObject *v);
/* Int division with remainder, top-level routine */
static int
long_divrem(PyLongObject *a, PyLongObject *b,
PyLongObject **pdiv, PyLongObject **prem)
{
Py_ssize_t size_a = Py_ABS(Py_SIZE(a)), size_b = Py_ABS(Py_SIZE(b));
PyLongObject *z;
if (size_b == 0) {
PyErr_SetString(PyExc_ZeroDivisionError,
"integer division or modulo by zero");
return -1;
}
if (size_a < size_b ||
(size_a == size_b &&
a->ob_digit[size_a-1] < b->ob_digit[size_b-1])) {
/* |a| < |b|. */
*prem = (PyLongObject *)long_long((PyObject *)a);
if (*prem == NULL) {
return -1;
}
Py_INCREF(_PyLong_Zero);
*pdiv = (PyLongObject*)_PyLong_Zero;
return 0;
}
if (size_b == 1) {
digit rem = 0;
z = divrem1(a, b->ob_digit[0], &rem);
if (z == NULL)
return -1;
*prem = (PyLongObject *) PyLong_FromLong((long)rem);
if (*prem == NULL) {
Py_DECREF(z);
return -1;
}
}
else {
z = x_divrem(a, b, prem);
if (z == NULL)
return -1;
}
/* Set the signs.
The quotient z has the sign of a*b;
the remainder r has the sign of a,
so a = b*z + r. */
if ((Py_SIZE(a) < 0) != (Py_SIZE(b) < 0)) {
_PyLong_Negate(&z);
if (z == NULL) {
Py_CLEAR(*prem);
return -1;
}
}
if (Py_SIZE(a) < 0 && Py_SIZE(*prem) != 0) {
_PyLong_Negate(prem);
if (*prem == NULL) {
Py_DECREF(z);
Py_CLEAR(*prem);
return -1;
}
}
*pdiv = maybe_small_long(z);
return 0;
}
/* Unsigned int division with remainder -- the algorithm. The arguments v1
and w1 should satisfy 2 <= Py_ABS(Py_SIZE(w1)) <= Py_ABS(Py_SIZE(v1)). */
static PyLongObject *
x_divrem(PyLongObject *v1, PyLongObject *w1, PyLongObject **prem)
{
PyLongObject *v, *w, *a;
Py_ssize_t i, k, size_v, size_w;
int d;
digit wm1, wm2, carry, q, r, vtop, *v0, *vk, *w0, *ak;
twodigits vv;
sdigit zhi;
stwodigits z;
/* We follow Knuth [The Art of Computer Programming, Vol. 2 (3rd
edn.), section 4.3.1, Algorithm D], except that we don't explicitly
handle the special case when the initial estimate q for a quotient
digit is >= PyLong_BASE: the max value for q is PyLong_BASE+1, and
that won't overflow a digit. */
/* allocate space; w will also be used to hold the final remainder */
size_v = Py_ABS(Py_SIZE(v1));
size_w = Py_ABS(Py_SIZE(w1));
assert(size_v >= size_w && size_w >= 2); /* Assert checks by div() */
v = _PyLong_New(size_v+1);
if (v == NULL) {
*prem = NULL;
return NULL;
}
w = _PyLong_New(size_w);
if (w == NULL) {
Py_DECREF(v);
*prem = NULL;
return NULL;
}
/* normalize: shift w1 left so that its top digit is >= PyLong_BASE/2.
shift v1 left by the same amount. Results go into w and v. */
d = PyLong_SHIFT - bit_length_digit(w1->ob_digit[size_w-1]);
carry = v_lshift(w->ob_digit, w1->ob_digit, size_w, d);
assert(carry == 0);
carry = v_lshift(v->ob_digit, v1->ob_digit, size_v, d);
if (carry != 0 || v->ob_digit[size_v-1] >= w->ob_digit[size_w-1]) {
v->ob_digit[size_v] = carry;
size_v++;
}
/* Now v->ob_digit[size_v-1] < w->ob_digit[size_w-1], so quotient has
at most (and usually exactly) k = size_v - size_w digits. */
k = size_v - size_w;
assert(k >= 0);
a = _PyLong_New(k);
if (a == NULL) {
Py_DECREF(w);
Py_DECREF(v);
*prem = NULL;
return NULL;
}
v0 = v->ob_digit;
w0 = w->ob_digit;
wm1 = w0[size_w-1];
wm2 = w0[size_w-2];
for (vk = v0+k, ak = a->ob_digit + k; vk-- > v0;) {
/* inner loop: divide vk[0:size_w+1] by w0[0:size_w], giving
single-digit quotient q, remainder in vk[0:size_w]. */
SIGCHECK({
Py_DECREF(a);
Py_DECREF(w);
Py_DECREF(v);
*prem = NULL;
return NULL;
});
/* estimate quotient digit q; may overestimate by 1 (rare) */
vtop = vk[size_w];
assert(vtop <= wm1);
vv = ((twodigits)vtop << PyLong_SHIFT) | vk[size_w-1];
q = (digit)(vv / wm1);
r = (digit)(vv - (twodigits)wm1 * q); /* r = vv % wm1 */
while ((twodigits)wm2 * q > (((twodigits)r << PyLong_SHIFT)
| vk[size_w-2])) {
--q;
r += wm1;
if (r >= PyLong_BASE)
break;
}
assert(q <= PyLong_BASE);
/* subtract q*w0[0:size_w] from vk[0:size_w+1] */
zhi = 0;
for (i = 0; i < size_w; ++i) {
/* invariants: -PyLong_BASE <= -q <= zhi <= 0;
-PyLong_BASE * q <= z < PyLong_BASE */
z = (sdigit)vk[i] + zhi -
(stwodigits)q * (stwodigits)w0[i];
vk[i] = (digit)z & PyLong_MASK;
zhi = (sdigit)Py_ARITHMETIC_RIGHT_SHIFT(stwodigits,
z, PyLong_SHIFT);
}
/* add w back if q was too large (this branch taken rarely) */
assert((sdigit)vtop + zhi == -1 || (sdigit)vtop + zhi == 0);
if ((sdigit)vtop + zhi < 0) {
carry = 0;
for (i = 0; i < size_w; ++i) {
carry += vk[i] + w0[i];
vk[i] = carry & PyLong_MASK;
carry >>= PyLong_SHIFT;
}
--q;
}
/* store quotient digit */
assert(q < PyLong_BASE);
*--ak = q;
}
/* unshift remainder; we reuse w to store the result */
carry = v_rshift(w0, v0, size_w, d);
assert(carry==0);
Py_DECREF(v);
*prem = long_normalize(w);
return long_normalize(a);
}
/* For a nonzero PyLong a, express a in the form x * 2**e, with 0.5 <=
abs(x) < 1.0 and e >= 0; return x and put e in *e. Here x is
rounded to DBL_MANT_DIG significant bits using round-half-to-even.
If a == 0, return 0.0 and set *e = 0. If the resulting exponent
e is larger than PY_SSIZE_T_MAX, raise OverflowError and return
-1.0. */
/* attempt to define 2.0**DBL_MANT_DIG as a compile-time constant */
#if DBL_MANT_DIG == 53
#define EXP2_DBL_MANT_DIG 9007199254740992.0
#else
#define EXP2_DBL_MANT_DIG (ldexp(1.0, DBL_MANT_DIG))
#endif
double
_PyLong_Frexp(PyLongObject *a, Py_ssize_t *e)
{
Py_ssize_t a_size, a_bits, shift_digits, shift_bits, x_size;
/* See below for why x_digits is always large enough. */
digit rem;
digit x_digits[2 + (DBL_MANT_DIG + 1) / PyLong_SHIFT] = {0,};
double dx;
/* Correction term for round-half-to-even rounding. For a digit x,
"x + half_even_correction[x & 7]" gives x rounded to the nearest
multiple of 4, rounding ties to a multiple of 8. */
static const int half_even_correction[8] = {0, -1, -2, 1, 0, -1, 2, 1};
a_size = Py_ABS(Py_SIZE(a));
if (a_size == 0) {
/* Special case for 0: significand 0.0, exponent 0. */
*e = 0;
return 0.0;
}
a_bits = bit_length_digit(a->ob_digit[a_size-1]);
/* The following is an overflow-free version of the check
"if ((a_size - 1) * PyLong_SHIFT + a_bits > PY_SSIZE_T_MAX) ..." */
if (a_size >= (PY_SSIZE_T_MAX - 1) / PyLong_SHIFT + 1 &&
(a_size > (PY_SSIZE_T_MAX - 1) / PyLong_SHIFT + 1 ||
a_bits > (PY_SSIZE_T_MAX - 1) % PyLong_SHIFT + 1))
goto overflow;
a_bits = (a_size - 1) * PyLong_SHIFT + a_bits;
/* Shift the first DBL_MANT_DIG + 2 bits of a into x_digits[0:x_size]
(shifting left if a_bits <= DBL_MANT_DIG + 2).
Number of digits needed for result: write // for floor division.
Then if shifting left, we end up using
1 + a_size + (DBL_MANT_DIG + 2 - a_bits) // PyLong_SHIFT
digits. If shifting right, we use
a_size - (a_bits - DBL_MANT_DIG - 2) // PyLong_SHIFT
digits. Using a_size = 1 + (a_bits - 1) // PyLong_SHIFT along with
the inequalities
m // PyLong_SHIFT + n // PyLong_SHIFT <= (m + n) // PyLong_SHIFT
m // PyLong_SHIFT - n // PyLong_SHIFT <=
1 + (m - n - 1) // PyLong_SHIFT,
valid for any integers m and n, we find that x_size satisfies
x_size <= 2 + (DBL_MANT_DIG + 1) // PyLong_SHIFT
in both cases.
*/
if (a_bits <= DBL_MANT_DIG + 2) {
shift_digits = (DBL_MANT_DIG + 2 - a_bits) / PyLong_SHIFT;
shift_bits = (DBL_MANT_DIG + 2 - a_bits) % PyLong_SHIFT;
x_size = shift_digits;
rem = v_lshift(x_digits + x_size, a->ob_digit, a_size,
(int)shift_bits);
x_size += a_size;
x_digits[x_size++] = rem;
}
else {
shift_digits = (a_bits - DBL_MANT_DIG - 2) / PyLong_SHIFT;
shift_bits = (a_bits - DBL_MANT_DIG - 2) % PyLong_SHIFT;
rem = v_rshift(x_digits, a->ob_digit + shift_digits,
a_size - shift_digits, (int)shift_bits);
x_size = a_size - shift_digits;
/* For correct rounding below, we need the least significant
bit of x to be 'sticky' for this shift: if any of the bits
shifted out was nonzero, we set the least significant bit
of x. */
if (rem)
x_digits[0] |= 1;
else
while (shift_digits > 0)
if (a->ob_digit[--shift_digits]) {
x_digits[0] |= 1;
break;
}
}
assert(1 <= x_size && x_size <= (Py_ssize_t)Py_ARRAY_LENGTH(x_digits));
/* Round, and convert to double. */
x_digits[0] += half_even_correction[x_digits[0] & 7];
dx = x_digits[--x_size];
while (x_size > 0)
dx = dx * PyLong_BASE + x_digits[--x_size];
/* Rescale; make correction if result is 1.0. */
dx /= 4.0 * EXP2_DBL_MANT_DIG;
if (dx == 1.0) {
if (a_bits == PY_SSIZE_T_MAX)
goto overflow;
dx = 0.5;
a_bits += 1;
}
*e = a_bits;
return Py_SIZE(a) < 0 ? -dx : dx;
overflow:
/* exponent > PY_SSIZE_T_MAX */
PyErr_SetString(PyExc_OverflowError,
"huge integer: number of bits overflows a Py_ssize_t");
*e = 0;
return -1.0;
}
/* Get a C double from an int object. Rounds to the nearest double,
using the round-half-to-even rule in the case of a tie. */
double
PyLong_AsDouble(PyObject *v)
{
Py_ssize_t exponent;
double x;
if (v == NULL) {
PyErr_BadInternalCall();
return -1.0;
}
if (!PyLong_Check(v)) {
PyErr_SetString(PyExc_TypeError, "an integer is required");
return -1.0;
}
if (Py_ABS(Py_SIZE(v)) <= 1) {
/* Fast path; single digit long (31 bits) will cast safely
to double. This improves performance of FP/long operations
by 20%.
*/
return (double)MEDIUM_VALUE((PyLongObject *)v);
}
x = _PyLong_Frexp((PyLongObject *)v, &exponent);
if ((x == -1.0 && PyErr_Occurred()) || exponent > DBL_MAX_EXP) {
PyErr_SetString(PyExc_OverflowError,
"int too large to convert to float");
return -1.0;
}
return ldexp(x, (int)exponent);
}
/* Methods */
/* if a < b, return a negative number
if a == b, return 0
if a > b, return a positive number */
static Py_ssize_t
long_compare(PyLongObject *a, PyLongObject *b)
{
Py_ssize_t sign = Py_SIZE(a) - Py_SIZE(b);
if (sign == 0) {
Py_ssize_t i = Py_ABS(Py_SIZE(a));
sdigit diff = 0;
while (--i >= 0) {
diff = (sdigit) a->ob_digit[i] - (sdigit) b->ob_digit[i];
if (diff) {
break;
}
}
sign = Py_SIZE(a) < 0 ? -diff : diff;
}
return sign;
}
static PyObject *
long_richcompare(PyObject *self, PyObject *other, int op)
{
Py_ssize_t result;
CHECK_BINOP(self, other);
if (self == other)
result = 0;
else
result = long_compare((PyLongObject*)self, (PyLongObject*)other);
Py_RETURN_RICHCOMPARE(result, 0, op);
}
static Py_hash_t
long_hash(PyLongObject *v)
{
Py_uhash_t x;
Py_ssize_t i;
int sign;
i = Py_SIZE(v);
switch(i) {
case -1: return v->ob_digit[0]==1 ? -2 : -(sdigit)v->ob_digit[0];
case 0: return 0;
case 1: return v->ob_digit[0];
}
sign = 1;
x = 0;
if (i < 0) {
sign = -1;
i = -(i);
}
while (--i >= 0) {
/* Here x is a quantity in the range [0, _PyHASH_MODULUS); we
want to compute x * 2**PyLong_SHIFT + v->ob_digit[i] modulo
_PyHASH_MODULUS.
The computation of x * 2**PyLong_SHIFT % _PyHASH_MODULUS
amounts to a rotation of the bits of x. To see this, write
x * 2**PyLong_SHIFT = y * 2**_PyHASH_BITS + z
where y = x >> (_PyHASH_BITS - PyLong_SHIFT) gives the top
PyLong_SHIFT bits of x (those that are shifted out of the
original _PyHASH_BITS bits, and z = (x << PyLong_SHIFT) &
_PyHASH_MODULUS gives the bottom _PyHASH_BITS - PyLong_SHIFT
bits of x, shifted up. Then since 2**_PyHASH_BITS is
congruent to 1 modulo _PyHASH_MODULUS, y*2**_PyHASH_BITS is
congruent to y modulo _PyHASH_MODULUS. So
x * 2**PyLong_SHIFT = y + z (mod _PyHASH_MODULUS).
The right-hand side is just the result of rotating the
_PyHASH_BITS bits of x left by PyLong_SHIFT places; since
not all _PyHASH_BITS bits of x are 1s, the same is true
after rotation, so 0 <= y+z < _PyHASH_MODULUS and y + z is
the reduction of x*2**PyLong_SHIFT modulo
_PyHASH_MODULUS. */
x = ((x << PyLong_SHIFT) & _PyHASH_MODULUS) |
(x >> (_PyHASH_BITS - PyLong_SHIFT));
x += v->ob_digit[i];
if (x >= _PyHASH_MODULUS)
x -= _PyHASH_MODULUS;
}
x = x * sign;
if (x == (Py_uhash_t)-1)
x = (Py_uhash_t)-2;
return (Py_hash_t)x;
}
/* Add the absolute values of two integers. */
static PyLongObject *
x_add(PyLongObject *a, PyLongObject *b)
{
Py_ssize_t size_a = Py_ABS(Py_SIZE(a)), size_b = Py_ABS(Py_SIZE(b));
PyLongObject *z;
Py_ssize_t i;
digit carry = 0;
/* Ensure a is the larger of the two: */
if (size_a < size_b) {
{ PyLongObject *temp = a; a = b; b = temp; }
{ Py_ssize_t size_temp = size_a;
size_a = size_b;
size_b = size_temp; }
}
z = _PyLong_New(size_a+1);
if (z == NULL)
return NULL;
for (i = 0; i < size_b; ++i) {
carry += a->ob_digit[i] + b->ob_digit[i];
z->ob_digit[i] = carry & PyLong_MASK;
carry >>= PyLong_SHIFT;
}
for (; i < size_a; ++i) {
carry += a->ob_digit[i];
z->ob_digit[i] = carry & PyLong_MASK;
carry >>= PyLong_SHIFT;
}
z->ob_digit[i] = carry;
return long_normalize(z);
}
/* Subtract the absolute values of two integers. */
static PyLongObject *
x_sub(PyLongObject *a, PyLongObject *b)
{
Py_ssize_t size_a = Py_ABS(Py_SIZE(a)), size_b = Py_ABS(Py_SIZE(b));
PyLongObject *z;
Py_ssize_t i;
int sign = 1;
digit borrow = 0;
/* Ensure a is the larger of the two: */
if (size_a < size_b) {
sign = -1;
{ PyLongObject *temp = a; a = b; b = temp; }
{ Py_ssize_t size_temp = size_a;
size_a = size_b;
size_b = size_temp; }
}
else if (size_a == size_b) {
/* Find highest digit where a and b differ: */
i = size_a;
while (--i >= 0 && a->ob_digit[i] == b->ob_digit[i])
;
if (i < 0)
return (PyLongObject *)PyLong_FromLong(0);
if (a->ob_digit[i] < b->ob_digit[i]) {
sign = -1;
{ PyLongObject *temp = a; a = b; b = temp; }
}
size_a = size_b = i+1;
}
z = _PyLong_New(size_a);
if (z == NULL)
return NULL;
for (i = 0; i < size_b; ++i) {
/* The following assumes unsigned arithmetic
works module 2**N for some N>PyLong_SHIFT. */
borrow = a->ob_digit[i] - b->ob_digit[i] - borrow;
z->ob_digit[i] = borrow & PyLong_MASK;
borrow >>= PyLong_SHIFT;
borrow &= 1; /* Keep only one sign bit */
}
for (; i < size_a; ++i) {
borrow = a->ob_digit[i] - borrow;
z->ob_digit[i] = borrow & PyLong_MASK;
borrow >>= PyLong_SHIFT;
borrow &= 1; /* Keep only one sign bit */
}
assert(borrow == 0);
if (sign < 0) {
Py_SET_SIZE(z, -Py_SIZE(z));
}
return maybe_small_long(long_normalize(z));
}
static PyObject *
long_add(PyLongObject *a, PyLongObject *b)
{
PyLongObject *z;
CHECK_BINOP(a, b);
if (Py_ABS(Py_SIZE(a)) <= 1 && Py_ABS(Py_SIZE(b)) <= 1) {
return PyLong_FromLong(MEDIUM_VALUE(a) + MEDIUM_VALUE(b));
}
if (Py_SIZE(a) < 0) {
if (Py_SIZE(b) < 0) {
z = x_add(a, b);
if (z != NULL) {
/* x_add received at least one multiple-digit int,
and thus z must be a multiple-digit int.
That also means z is not an element of
small_ints, so negating it in-place is safe. */
assert(Py_REFCNT(z) == 1);
Py_SET_SIZE(z, -(Py_SIZE(z)));
}
}
else
z = x_sub(b, a);
}
else {
if (Py_SIZE(b) < 0)
z = x_sub(a, b);
else
z = x_add(a, b);
}
return (PyObject *)z;
}
static PyObject *
long_sub(PyLongObject *a, PyLongObject *b)
{
PyLongObject *z;
CHECK_BINOP(a, b);
if (Py_ABS(Py_SIZE(a)) <= 1 && Py_ABS(Py_SIZE(b)) <= 1) {
return PyLong_FromLong(MEDIUM_VALUE(a) - MEDIUM_VALUE(b));
}
if (Py_SIZE(a) < 0) {
if (Py_SIZE(b) < 0) {
z = x_sub(b, a);
}
else {
z = x_add(a, b);
if (z != NULL) {
assert(Py_SIZE(z) == 0 || Py_REFCNT(z) == 1);
Py_SET_SIZE(z, -(Py_SIZE(z)));
}
}
}
else {
if (Py_SIZE(b) < 0)
z = x_add(a, b);
else
z = x_sub(a, b);
}
return (PyObject *)z;
}
/* Grade school multiplication, ignoring the signs.
* Returns the absolute value of the product, or NULL if error.
*/
static PyLongObject *
x_mul(PyLongObject *a, PyLongObject *b)
{
PyLongObject *z;
Py_ssize_t size_a = Py_ABS(Py_SIZE(a));
Py_ssize_t size_b = Py_ABS(Py_SIZE(b));
Py_ssize_t i;
z = _PyLong_New(size_a + size_b);
if (z == NULL)
return NULL;
memset(z->ob_digit, 0, Py_SIZE(z) * sizeof(digit));
if (a == b) {
/* Efficient squaring per HAC, Algorithm 14.16:
* http://www.cacr.math.uwaterloo.ca/hac/about/chap14.pdf
* Gives slightly less than a 2x speedup when a == b,
* via exploiting that each entry in the multiplication
* pyramid appears twice (except for the size_a squares).
*/
for (i = 0; i < size_a; ++i) {
twodigits carry;
twodigits f = a->ob_digit[i];
digit *pz = z->ob_digit + (i << 1);
digit *pa = a->ob_digit + i + 1;
digit *paend = a->ob_digit + size_a;
SIGCHECK({
Py_DECREF(z);
return NULL;
});
carry = *pz + f * f;
*pz++ = (digit)(carry & PyLong_MASK);
carry >>= PyLong_SHIFT;
assert(carry <= PyLong_MASK);
/* Now f is added in twice in each column of the
* pyramid it appears. Same as adding f<<1 once.
*/
f <<= 1;
while (pa < paend) {
carry += *pz + *pa++ * f;
*pz++ = (digit)(carry & PyLong_MASK);
carry >>= PyLong_SHIFT;
assert(carry <= (PyLong_MASK << 1));
}
if (carry) {
carry += *pz;
*pz++ = (digit)(carry & PyLong_MASK);
carry >>= PyLong_SHIFT;
}
if (carry)
*pz += (digit)(carry & PyLong_MASK);
assert((carry >> PyLong_SHIFT) == 0);
}
}
else { /* a is not the same as b -- gradeschool int mult */
for (i = 0; i < size_a; ++i) {
twodigits carry = 0;
twodigits f = a->ob_digit[i];
digit *pz = z->ob_digit + i;
digit *pb = b->ob_digit;
digit *pbend = b->ob_digit + size_b;
SIGCHECK({
Py_DECREF(z);
return NULL;
});
while (pb < pbend) {
carry += *pz + *pb++ * f;
*pz++ = (digit)(carry & PyLong_MASK);
carry >>= PyLong_SHIFT;
assert(carry <= PyLong_MASK);
}
if (carry)
*pz += (digit)(carry & PyLong_MASK);
assert((carry >> PyLong_SHIFT) == 0);
}
}
return long_normalize(z);
}
/* A helper for Karatsuba multiplication (k_mul).
Takes an int "n" and an integer "size" representing the place to
split, and sets low and high such that abs(n) == (high << size) + low,
viewing the shift as being by digits. The sign bit is ignored, and
the return values are >= 0.
Returns 0 on success, -1 on failure.
*/
static int
kmul_split(PyLongObject *n,
Py_ssize_t size,
PyLongObject **high,
PyLongObject **low)
{
PyLongObject *hi, *lo;
Py_ssize_t size_lo, size_hi;
const Py_ssize_t size_n = Py_ABS(Py_SIZE(n));
size_lo = Py_MIN(size_n, size);
size_hi = size_n - size_lo;
if ((hi = _PyLong_New(size_hi)) == NULL)
return -1;
if ((lo = _PyLong_New(size_lo)) == NULL) {
Py_DECREF(hi);
return -1;
}
memcpy(lo->ob_digit, n->ob_digit, size_lo * sizeof(digit));
memcpy(hi->ob_digit, n->ob_digit + size_lo, size_hi * sizeof(digit));
*high = long_normalize(hi);
*low = long_normalize(lo);
return 0;
}
static PyLongObject *k_lopsided_mul(PyLongObject *a, PyLongObject *b);
/* Karatsuba multiplication. Ignores the input signs, and returns the
* absolute value of the product (or NULL if error).
* See Knuth Vol. 2 Chapter 4.3.3 (Pp. 294-295).
*/
static PyLongObject *
k_mul(PyLongObject *a, PyLongObject *b)
{
Py_ssize_t asize = Py_ABS(Py_SIZE(a));
Py_ssize_t bsize = Py_ABS(Py_SIZE(b));
PyLongObject *ah = NULL;
PyLongObject *al = NULL;
PyLongObject *bh = NULL;
PyLongObject *bl = NULL;
PyLongObject *ret = NULL;
PyLongObject *t1, *t2, *t3;
Py_ssize_t shift; /* the number of digits we split off */
Py_ssize_t i;
/* (ah*X+al)(bh*X+bl) = ah*bh*X*X + (ah*bl + al*bh)*X + al*bl
* Let k = (ah+al)*(bh+bl) = ah*bl + al*bh + ah*bh + al*bl
* Then the original product is
* ah*bh*X*X + (k - ah*bh - al*bl)*X + al*bl
* By picking X to be a power of 2, "*X" is just shifting, and it's
* been reduced to 3 multiplies on numbers half the size.
*/
/* We want to split based on the larger number; fiddle so that b
* is largest.
*/
if (asize > bsize) {
t1 = a;
a = b;
b = t1;
i = asize;
asize = bsize;
bsize = i;
}
/* Use gradeschool math when either number is too small. */
i = a == b ? KARATSUBA_SQUARE_CUTOFF : KARATSUBA_CUTOFF;
if (asize <= i) {
if (asize == 0)
return (PyLongObject *)PyLong_FromLong(0);
else
return x_mul(a, b);
}
/* If a is small compared to b, splitting on b gives a degenerate
* case with ah==0, and Karatsuba may be (even much) less efficient
* than "grade school" then. However, we can still win, by viewing
* b as a string of "big digits", each of width a->ob_size. That
* leads to a sequence of balanced calls to k_mul.
*/
if (2 * asize <= bsize)
return k_lopsided_mul(a, b);
/* Split a & b into hi & lo pieces. */
shift = bsize >> 1;
if (kmul_split(a, shift, &ah, &al) < 0) goto fail;
assert(Py_SIZE(ah) > 0); /* the split isn't degenerate */
if (a == b) {
bh = ah;
bl = al;
Py_INCREF(bh);
Py_INCREF(bl);
}
else if (kmul_split(b, shift, &bh, &bl) < 0) goto fail;
/* The plan:
* 1. Allocate result space (asize + bsize digits: that's always
* enough).
* 2. Compute ah*bh, and copy into result at 2*shift.
* 3. Compute al*bl, and copy into result at 0. Note that this
* can't overlap with #2.
* 4. Subtract al*bl from the result, starting at shift. This may
* underflow (borrow out of the high digit), but we don't care:
* we're effectively doing unsigned arithmetic mod
* BASE**(sizea + sizeb), and so long as the *final* result fits,
* borrows and carries out of the high digit can be ignored.
* 5. Subtract ah*bh from the result, starting at shift.
* 6. Compute (ah+al)*(bh+bl), and add it into the result starting
* at shift.
*/
/* 1. Allocate result space. */
ret = _PyLong_New(asize + bsize);
if (ret == NULL) goto fail;
#ifdef Py_DEBUG
/* Fill with trash, to catch reference to uninitialized digits. */
memset(ret->ob_digit, 0xDF, Py_SIZE(ret) * sizeof(digit));
#endif
/* 2. t1 <- ah*bh, and copy into high digits of result. */
if ((t1 = k_mul(ah, bh)) == NULL) goto fail;
assert(Py_SIZE(t1) >= 0);
assert(2*shift + Py_SIZE(t1) <= Py_SIZE(ret));
memcpy(ret->ob_digit + 2*shift, t1->ob_digit,
Py_SIZE(t1) * sizeof(digit));
/* Zero-out the digits higher than the ah*bh copy. */
i = Py_SIZE(ret) - 2*shift - Py_SIZE(t1);
if (i)
memset(ret->ob_digit + 2*shift + Py_SIZE(t1), 0,
i * sizeof(digit));
/* 3. t2 <- al*bl, and copy into the low digits. */
if ((t2 = k_mul(al, bl)) == NULL) {
Py_DECREF(t1);
goto fail;
}
assert(Py_SIZE(t2) >= 0);
assert(Py_SIZE(t2) <= 2*shift); /* no overlap with high digits */
memcpy(ret->ob_digit, t2->ob_digit, Py_SIZE(t2) * sizeof(digit));
/* Zero out remaining digits. */
i = 2*shift - Py_SIZE(t2); /* number of uninitialized digits */
if (i)
memset(ret->ob_digit + Py_SIZE(t2), 0, i * sizeof(digit));
/* 4 & 5. Subtract ah*bh (t1) and al*bl (t2). We do al*bl first
* because it's fresher in cache.
*/
i = Py_SIZE(ret) - shift; /* # digits after shift */
(void)v_isub(ret->ob_digit + shift, i, t2->ob_digit, Py_SIZE(t2));
Py_DECREF(t2);
(void)v_isub(ret->ob_digit + shift, i, t1->ob_digit, Py_SIZE(t1));
Py_DECREF(t1);
/* 6. t3 <- (ah+al)(bh+bl), and add into result. */
if ((t1 = x_add(ah, al)) == NULL) goto fail;
Py_DECREF(ah);
Py_DECREF(al);
ah = al = NULL;
if (a == b) {
t2 = t1;
Py_INCREF(t2);
}
else if ((t2 = x_add(bh, bl)) == NULL) {
Py_DECREF(t1);
goto fail;
}
Py_DECREF(bh);
Py_DECREF(bl);
bh = bl = NULL;
t3 = k_mul(t1, t2);
Py_DECREF(t1);
Py_DECREF(t2);
if (t3 == NULL) goto fail;
assert(Py_SIZE(t3) >= 0);
/* Add t3. It's not obvious why we can't run out of room here.
* See the (*) comment after this function.
*/
(void)v_iadd(ret->ob_digit + shift, i, t3->ob_digit, Py_SIZE(t3));
Py_DECREF(t3);
return long_normalize(ret);
fail:
Py_XDECREF(ret);
Py_XDECREF(ah);
Py_XDECREF(al);
Py_XDECREF(bh);
Py_XDECREF(bl);
return NULL;
}
/* (*) Why adding t3 can't "run out of room" above.
Let f(x) mean the floor of x and c(x) mean the ceiling of x. Some facts
to start with:
1. For any integer i, i = c(i/2) + f(i/2). In particular,
bsize = c(bsize/2) + f(bsize/2).
2. shift = f(bsize/2)
3. asize <= bsize
4. Since we call k_lopsided_mul if asize*2 <= bsize, asize*2 > bsize in this
routine, so asize > bsize/2 >= f(bsize/2) in this routine.
We allocated asize + bsize result digits, and add t3 into them at an offset
of shift. This leaves asize+bsize-shift allocated digit positions for t3
to fit into, = (by #1 and #2) asize + f(bsize/2) + c(bsize/2) - f(bsize/2) =
asize + c(bsize/2) available digit positions.
bh has c(bsize/2) digits, and bl at most f(size/2) digits. So bh+hl has
at most c(bsize/2) digits + 1 bit.
If asize == bsize, ah has c(bsize/2) digits, else ah has at most f(bsize/2)
digits, and al has at most f(bsize/2) digits in any case. So ah+al has at
most (asize == bsize ? c(bsize/2) : f(bsize/2)) digits + 1 bit.
The product (ah+al)*(bh+bl) therefore has at most
c(bsize/2) + (asize == bsize ? c(bsize/2) : f(bsize/2)) digits + 2 bits
and we have asize + c(bsize/2) available digit positions. We need to show
this is always enough. An instance of c(bsize/2) cancels out in both, so
the question reduces to whether asize digits is enough to hold
(asize == bsize ? c(bsize/2) : f(bsize/2)) digits + 2 bits. If asize < bsize,
then we're asking whether asize digits >= f(bsize/2) digits + 2 bits. By #4,
asize is at least f(bsize/2)+1 digits, so this in turn reduces to whether 1
digit is enough to hold 2 bits. This is so since PyLong_SHIFT=15 >= 2. If
asize == bsize, then we're asking whether bsize digits is enough to hold
c(bsize/2) digits + 2 bits, or equivalently (by #1) whether f(bsize/2) digits
is enough to hold 2 bits. This is so if bsize >= 2, which holds because
bsize >= KARATSUBA_CUTOFF >= 2.
Note that since there's always enough room for (ah+al)*(bh+bl), and that's
clearly >= each of ah*bh and al*bl, there's always enough room to subtract
ah*bh and al*bl too.
*/
/* b has at least twice the digits of a, and a is big enough that Karatsuba
* would pay off *if* the inputs had balanced sizes. View b as a sequence
* of slices, each with a->ob_size digits, and multiply the slices by a,
* one at a time. This gives k_mul balanced inputs to work with, and is
* also cache-friendly (we compute one double-width slice of the result
* at a time, then move on, never backtracking except for the helpful
* single-width slice overlap between successive partial sums).
*/
static PyLongObject *
k_lopsided_mul(PyLongObject *a, PyLongObject *b)
{
const Py_ssize_t asize = Py_ABS(Py_SIZE(a));
Py_ssize_t bsize = Py_ABS(Py_SIZE(b));
Py_ssize_t nbdone; /* # of b digits already multiplied */
PyLongObject *ret;
PyLongObject *bslice = NULL;
assert(asize > KARATSUBA_CUTOFF);
assert(2 * asize <= bsize);
/* Allocate result space, and zero it out. */
ret = _PyLong_New(asize + bsize);
if (ret == NULL)
return NULL;
memset(ret->ob_digit, 0, Py_SIZE(ret) * sizeof(digit));
/* Successive slices of b are copied into bslice. */
bslice = _PyLong_New(asize);
if (bslice == NULL)
goto fail;
nbdone = 0;
while (bsize > 0) {
PyLongObject *product;
const Py_ssize_t nbtouse = Py_MIN(bsize, asize);
/* Multiply the next slice of b by a. */
memcpy(bslice->ob_digit, b->ob_digit + nbdone,
nbtouse * sizeof(digit));
Py_SET_SIZE(bslice, nbtouse);
product = k_mul(a, bslice);
if (product == NULL)
goto fail;
/* Add into result. */
(void)v_iadd(ret->ob_digit + nbdone, Py_SIZE(ret) - nbdone,
product->ob_digit, Py_SIZE(product));
Py_DECREF(product);
bsize -= nbtouse;
nbdone += nbtouse;
}
Py_DECREF(bslice);
return long_normalize(ret);
fail:
Py_DECREF(ret);
Py_XDECREF(bslice);
return NULL;
}
static PyObject *
long_mul(PyLongObject *a, PyLongObject *b)
{
PyLongObject *z;
CHECK_BINOP(a, b);
/* fast path for single-digit multiplication */
if (Py_ABS(Py_SIZE(a)) <= 1 && Py_ABS(Py_SIZE(b)) <= 1) {
stwodigits v = (stwodigits)(MEDIUM_VALUE(a)) * MEDIUM_VALUE(b);
return PyLong_FromLongLong((long long)v);
}
z = k_mul(a, b);
/* Negate if exactly one of the inputs is negative. */
if (((Py_SIZE(a) ^ Py_SIZE(b)) < 0) && z) {
_PyLong_Negate(&z);
if (z == NULL)
return NULL;
}
return (PyObject *)z;
}
/* Fast modulo division for single-digit longs. */
static PyObject *
fast_mod(PyLongObject *a, PyLongObject *b)
{
sdigit left = a->ob_digit[0];
sdigit right = b->ob_digit[0];
sdigit mod;
assert(Py_ABS(Py_SIZE(a)) == 1);
assert(Py_ABS(Py_SIZE(b)) == 1);
if (Py_SIZE(a) == Py_SIZE(b)) {
/* 'a' and 'b' have the same sign. */
mod = left % right;
}
else {
/* Either 'a' or 'b' is negative. */
mod = right - 1 - (left - 1) % right;
}
return PyLong_FromLong(mod * (sdigit)Py_SIZE(b));
}
/* Fast floor division for single-digit longs. */
static PyObject *
fast_floor_div(PyLongObject *a, PyLongObject *b)
{
sdigit left = a->ob_digit[0];
sdigit right = b->ob_digit[0];
sdigit div;
assert(Py_ABS(Py_SIZE(a)) == 1);
assert(Py_ABS(Py_SIZE(b)) == 1);
if (Py_SIZE(a) == Py_SIZE(b)) {
/* 'a' and 'b' have the same sign. */
div = left / right;
}
else {
/* Either 'a' or 'b' is negative. */
div = -1 - (left - 1) / right;
}
return PyLong_FromLong(div);
}
/* The / and % operators are now defined in terms of divmod().
The expression a mod b has the value a - b*floor(a/b).
The long_divrem function gives the remainder after division of
|a| by |b|, with the sign of a. This is also expressed
as a - b*trunc(a/b), if trunc truncates towards zero.
Some examples:
a b a rem b a mod b
13 10 3 3
-13 10 -3 7
13 -10 3 -7
-13 -10 -3 -3
So, to get from rem to mod, we have to add b if a and b
have different signs. We then subtract one from the 'div'
part of the outcome to keep the invariant intact. */
/* Compute
* *pdiv, *pmod = divmod(v, w)
* NULL can be passed for pdiv or pmod, in which case that part of
* the result is simply thrown away. The caller owns a reference to
* each of these it requests (does not pass NULL for).
*/
static int
l_divmod(PyLongObject *v, PyLongObject *w,
PyLongObject **pdiv, PyLongObject **pmod)
{
PyLongObject *div, *mod;
if (Py_ABS(Py_SIZE(v)) == 1 && Py_ABS(Py_SIZE(w)) == 1) {
/* Fast path for single-digit longs */
div = NULL;
if (pdiv != NULL) {
div = (PyLongObject *)fast_floor_div(v, w);
if (div == NULL) {
return -1;
}
}
if (pmod != NULL) {
mod = (PyLongObject *)fast_mod(v, w);
if (mod == NULL) {
Py_XDECREF(div);
return -1;
}
*pmod = mod;
}
if (pdiv != NULL) {
/* We only want to set `*pdiv` when `*pmod` is
set successfully. */
*pdiv = div;
}
return 0;
}
if (long_divrem(v, w, &div, &mod) < 0)
return -1;
if ((Py_SIZE(mod) < 0 && Py_SIZE(w) > 0) ||
(Py_SIZE(mod) > 0 && Py_SIZE(w) < 0)) {
PyLongObject *temp;
temp = (PyLongObject *) long_add(mod, w);
Py_DECREF(mod);
mod = temp;
if (mod == NULL) {
Py_DECREF(div);
return -1;
}
temp = (PyLongObject *) long_sub(div, (PyLongObject *)_PyLong_One);
if (temp == NULL) {
Py_DECREF(mod);
Py_DECREF(div);
return -1;
}
Py_DECREF(div);
div = temp;
}
if (pdiv != NULL)
*pdiv = div;
else
Py_DECREF(div);
if (pmod != NULL)
*pmod = mod;
else
Py_DECREF(mod);
return 0;
}
static PyObject *
long_div(PyObject *a, PyObject *b)
{
PyLongObject *div;
CHECK_BINOP(a, b);
if (Py_ABS(Py_SIZE(a)) == 1 && Py_ABS(Py_SIZE(b)) == 1) {
return fast_floor_div((PyLongObject*)a, (PyLongObject*)b);
}
if (l_divmod((PyLongObject*)a, (PyLongObject*)b, &div, NULL) < 0)
div = NULL;
return (PyObject *)div;
}
/* PyLong/PyLong -> float, with correctly rounded result. */
#define MANT_DIG_DIGITS (DBL_MANT_DIG / PyLong_SHIFT)
#define MANT_DIG_BITS (DBL_MANT_DIG % PyLong_SHIFT)
static PyObject *
long_true_divide(PyObject *v, PyObject *w)
{
PyLongObject *a, *b, *x;
Py_ssize_t a_size, b_size, shift, extra_bits, diff, x_size, x_bits;
digit mask, low;
int inexact, negate, a_is_small, b_is_small;
double dx, result;
CHECK_BINOP(v, w);
a = (PyLongObject *)v;
b = (PyLongObject *)w;
/*
Method in a nutshell:
0. reduce to case a, b > 0; filter out obvious underflow/overflow
1. choose a suitable integer 'shift'
2. use integer arithmetic to compute x = floor(2**-shift*a/b)
3. adjust x for correct rounding
4. convert x to a double dx with the same value
5. return ldexp(dx, shift).
In more detail:
0. For any a, a/0 raises ZeroDivisionError; for nonzero b, 0/b
returns either 0.0 or -0.0, depending on the sign of b. For a and
b both nonzero, ignore signs of a and b, and add the sign back in
at the end. Now write a_bits and b_bits for the bit lengths of a
and b respectively (that is, a_bits = 1 + floor(log_2(a)); likewise
for b). Then
2**(a_bits - b_bits - 1) < a/b < 2**(a_bits - b_bits + 1).
So if a_bits - b_bits > DBL_MAX_EXP then a/b > 2**DBL_MAX_EXP and
so overflows. Similarly, if a_bits - b_bits < DBL_MIN_EXP -
DBL_MANT_DIG - 1 then a/b underflows to 0. With these cases out of
the way, we can assume that
DBL_MIN_EXP - DBL_MANT_DIG - 1 <= a_bits - b_bits <= DBL_MAX_EXP.
1. The integer 'shift' is chosen so that x has the right number of
bits for a double, plus two or three extra bits that will be used
in the rounding decisions. Writing a_bits and b_bits for the
number of significant bits in a and b respectively, a
straightforward formula for shift is:
shift = a_bits - b_bits - DBL_MANT_DIG - 2
This is fine in the usual case, but if a/b is smaller than the
smallest normal float then it can lead to double rounding on an
IEEE 754 platform, giving incorrectly rounded results. So we
adjust the formula slightly. The actual formula used is:
shift = MAX(a_bits - b_bits, DBL_MIN_EXP) - DBL_MANT_DIG - 2
2. The quantity x is computed by first shifting a (left -shift bits
if shift <= 0, right shift bits if shift > 0) and then dividing by
b. For both the shift and the division, we keep track of whether
the result is inexact, in a flag 'inexact'; this information is
needed at the rounding stage.
With the choice of shift above, together with our assumption that
a_bits - b_bits >= DBL_MIN_EXP - DBL_MANT_DIG - 1, it follows
that x >= 1.
3. Now x * 2**shift <= a/b < (x+1) * 2**shift. We want to replace
this with an exactly representable float of the form
round(x/2**extra_bits) * 2**(extra_bits+shift).
For float representability, we need x/2**extra_bits <
2**DBL_MANT_DIG and extra_bits + shift >= DBL_MIN_EXP -
DBL_MANT_DIG. This translates to the condition:
extra_bits >= MAX(x_bits, DBL_MIN_EXP - shift) - DBL_MANT_DIG
To round, we just modify the bottom digit of x in-place; this can
end up giving a digit with value > PyLONG_MASK, but that's not a
problem since digits can hold values up to 2*PyLONG_MASK+1.
With the original choices for shift above, extra_bits will always
be 2 or 3. Then rounding under the round-half-to-even rule, we
round up iff the most significant of the extra bits is 1, and
either: (a) the computation of x in step 2 had an inexact result,
or (b) at least one other of the extra bits is 1, or (c) the least
significant bit of x (above those to be rounded) is 1.
4. Conversion to a double is straightforward; all floating-point
operations involved in the conversion are exact, so there's no
danger of rounding errors.
5. Use ldexp(x, shift) to compute x*2**shift, the final result.
The result will always be exactly representable as a double, except
in the case that it overflows. To avoid dependence on the exact
behaviour of ldexp on overflow, we check for overflow before
applying ldexp. The result of ldexp is adjusted for sign before
returning.
*/
/* Reduce to case where a and b are both positive. */
a_size = Py_ABS(Py_SIZE(a));
b_size = Py_ABS(Py_SIZE(b));
negate = (Py_SIZE(a) < 0) ^ (Py_SIZE(b) < 0);
if (b_size == 0) {
PyErr_SetString(PyExc_ZeroDivisionError,
"division by zero");
goto error;
}
if (a_size == 0)
goto underflow_or_zero;
/* Fast path for a and b small (exactly representable in a double).
Relies on floating-point division being correctly rounded; results
may be subject to double rounding on x86 machines that operate with
the x87 FPU set to 64-bit precision. */
a_is_small = a_size <= MANT_DIG_DIGITS ||
(a_size == MANT_DIG_DIGITS+1 &&
a->ob_digit[MANT_DIG_DIGITS] >> MANT_DIG_BITS == 0);
b_is_small = b_size <= MANT_DIG_DIGITS ||
(b_size == MANT_DIG_DIGITS+1 &&
b->ob_digit[MANT_DIG_DIGITS] >> MANT_DIG_BITS == 0);
if (a_is_small && b_is_small) {
double da, db;
da = a->ob_digit[--a_size];
while (a_size > 0)
da = da * PyLong_BASE + a->ob_digit[--a_size];
db = b->ob_digit[--b_size];
while (b_size > 0)
db = db * PyLong_BASE + b->ob_digit[--b_size];
result = da / db;
goto success;
}
/* Catch obvious cases of underflow and overflow */
diff = a_size - b_size;
if (diff > PY_SSIZE_T_MAX/PyLong_SHIFT - 1)
/* Extreme overflow */
goto overflow;
else if (diff < 1 - PY_SSIZE_T_MAX/PyLong_SHIFT)
/* Extreme underflow */
goto underflow_or_zero;
/* Next line is now safe from overflowing a Py_ssize_t */
diff = diff * PyLong_SHIFT + bit_length_digit(a->ob_digit[a_size - 1]) -
bit_length_digit(b->ob_digit[b_size - 1]);
/* Now diff = a_bits - b_bits. */
if (diff > DBL_MAX_EXP)
goto overflow;
else if (diff < DBL_MIN_EXP - DBL_MANT_DIG - 1)
goto underflow_or_zero;
/* Choose value for shift; see comments for step 1 above. */
shift = Py_MAX(diff, DBL_MIN_EXP) - DBL_MANT_DIG - 2;
inexact = 0;
/* x = abs(a * 2**-shift) */
if (shift <= 0) {
Py_ssize_t i, shift_digits = -shift / PyLong_SHIFT;
digit rem;
/* x = a << -shift */
if (a_size >= PY_SSIZE_T_MAX - 1 - shift_digits) {
/* In practice, it's probably impossible to end up
here. Both a and b would have to be enormous,
using close to SIZE_T_MAX bytes of memory each. */
PyErr_SetString(PyExc_OverflowError,
"intermediate overflow during division");
goto error;
}
x = _PyLong_New(a_size + shift_digits + 1);
if (x == NULL)
goto error;
for (i = 0; i < shift_digits; i++)
x->ob_digit[i] = 0;
rem = v_lshift(x->ob_digit + shift_digits, a->ob_digit,
a_size, -shift % PyLong_SHIFT);
x->ob_digit[a_size + shift_digits] = rem;
}
else {
Py_ssize_t shift_digits = shift / PyLong_SHIFT;
digit rem;
/* x = a >> shift */
assert(a_size >= shift_digits);
x = _PyLong_New(a_size - shift_digits);
if (x == NULL)
goto error;
rem = v_rshift(x->ob_digit, a->ob_digit + shift_digits,
a_size - shift_digits, shift % PyLong_SHIFT);
/* set inexact if any of the bits shifted out is nonzero */
if (rem)
inexact = 1;
while (!inexact && shift_digits > 0)
if (a->ob_digit[--shift_digits])
inexact = 1;
}
long_normalize(x);
x_size = Py_SIZE(x);
/* x //= b. If the remainder is nonzero, set inexact. We own the only
reference to x, so it's safe to modify it in-place. */
if (b_size == 1) {
digit rem = inplace_divrem1(x->ob_digit, x->ob_digit, x_size,
b->ob_digit[0]);
long_normalize(x);
if (rem)
inexact = 1;
}
else {
PyLongObject *div, *rem;
div = x_divrem(x, b, &rem);
Py_DECREF(x);
x = div;
if (x == NULL)
goto error;
if (Py_SIZE(rem))
inexact = 1;
Py_DECREF(rem);
}
x_size = Py_ABS(Py_SIZE(x));
assert(x_size > 0); /* result of division is never zero */
x_bits = (x_size-1)*PyLong_SHIFT+bit_length_digit(x->ob_digit[x_size-1]);
/* The number of extra bits that have to be rounded away. */
extra_bits = Py_MAX(x_bits, DBL_MIN_EXP - shift) - DBL_MANT_DIG;
assert(extra_bits == 2 || extra_bits == 3);
/* Round by directly modifying the low digit of x. */
mask = (digit)1 << (extra_bits - 1);
low = x->ob_digit[0] | inexact;
if ((low & mask) && (low & (3U*mask-1U)))
low += mask;
x->ob_digit[0] = low & ~(2U*mask-1U);
/* Convert x to a double dx; the conversion is exact. */
dx = x->ob_digit[--x_size];
while (x_size > 0)
dx = dx * PyLong_BASE + x->ob_digit[--x_size];
Py_DECREF(x);
/* Check whether ldexp result will overflow a double. */
if (shift + x_bits >= DBL_MAX_EXP &&
(shift + x_bits > DBL_MAX_EXP || dx == ldexp(1.0, (int)x_bits)))
goto overflow;
result = ldexp(dx, (int)shift);
success:
return PyFloat_FromDouble(negate ? -result : result);
underflow_or_zero:
return PyFloat_FromDouble(negate ? -0.0 : 0.0);
overflow:
PyErr_SetString(PyExc_OverflowError,
"integer division result too large for a float");
error:
return NULL;
}
static PyObject *
long_mod(PyObject *a, PyObject *b)
{
PyLongObject *mod;
CHECK_BINOP(a, b);
if (Py_ABS(Py_SIZE(a)) == 1 && Py_ABS(Py_SIZE(b)) == 1) {
return fast_mod((PyLongObject*)a, (PyLongObject*)b);
}
if (l_divmod((PyLongObject*)a, (PyLongObject*)b, NULL, &mod) < 0)
mod = NULL;
return (PyObject *)mod;
}
static PyObject *
long_divmod(PyObject *a, PyObject *b)
{
PyLongObject *div, *mod;
PyObject *z;
CHECK_BINOP(a, b);
if (l_divmod((PyLongObject*)a, (PyLongObject*)b, &div, &mod) < 0) {
return NULL;
}
z = PyTuple_New(2);
if (z != NULL) {
PyTuple_SET_ITEM(z, 0, (PyObject *) div);
PyTuple_SET_ITEM(z, 1, (PyObject *) mod);
}
else {
Py_DECREF(div);
Py_DECREF(mod);
}
return z;
}
/* Compute an inverse to a modulo n, or raise ValueError if a is not
invertible modulo n. Assumes n is positive. The inverse returned
is whatever falls out of the extended Euclidean algorithm: it may
be either positive or negative, but will be smaller than n in
absolute value.
Pure Python equivalent for long_invmod:
def invmod(a, n):
b, c = 1, 0
while n:
q, r = divmod(a, n)
a, b, c, n = n, c, b - q*c, r
# at this point a is the gcd of the original inputs
if a == 1:
return b
raise ValueError("Not invertible")
*/
static PyLongObject *
long_invmod(PyLongObject *a, PyLongObject *n)
{
PyLongObject *b, *c;
/* Should only ever be called for positive n */
assert(Py_SIZE(n) > 0);
b = (PyLongObject *)PyLong_FromLong(1L);
if (b == NULL) {
return NULL;
}
c = (PyLongObject *)PyLong_FromLong(0L);
if (c == NULL) {
Py_DECREF(b);
return NULL;
}
Py_INCREF(a);
Py_INCREF(n);
/* references now owned: a, b, c, n */
while (Py_SIZE(n) != 0) {
PyLongObject *q, *r, *s, *t;
if (l_divmod(a, n, &q, &r) == -1) {
goto Error;
}
Py_DECREF(a);
a = n;
n = r;
t = (PyLongObject *)long_mul(q, c);
Py_DECREF(q);
if (t == NULL) {
goto Error;
}
s = (PyLongObject *)long_sub(b, t);
Py_DECREF(t);
if (s == NULL) {
goto Error;
}
Py_DECREF(b);
b = c;
c = s;
}
/* references now owned: a, b, c, n */
Py_DECREF(c);
Py_DECREF(n);
if (long_compare(a, (PyLongObject *)_PyLong_One)) {
/* a != 1; we don't have an inverse. */
Py_DECREF(a);
Py_DECREF(b);
PyErr_SetString(PyExc_ValueError,
"base is not invertible for the given modulus");
return NULL;
}
else {
/* a == 1; b gives an inverse modulo n */
Py_DECREF(a);
return b;
}
Error:
Py_DECREF(a);
Py_DECREF(b);
Py_DECREF(c);
Py_DECREF(n);
return NULL;
}
/* pow(v, w, x) */
static PyObject *
long_pow(PyObject *v, PyObject *w, PyObject *x)
{
PyLongObject *a, *b, *c; /* a,b,c = v,w,x */
int negativeOutput = 0; /* if x<0 return negative output */
PyLongObject *z = NULL; /* accumulated result */
Py_ssize_t i, j, k; /* counters */
PyLongObject *temp = NULL;
/* 5-ary values. If the exponent is large enough, table is
* precomputed so that table[i] == a**i % c for i in range(32).
*/
PyLongObject *table[32] = {0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0};
/* a, b, c = v, w, x */
CHECK_BINOP(v, w);
a = (PyLongObject*)v; Py_INCREF(a);
b = (PyLongObject*)w; Py_INCREF(b);
if (PyLong_Check(x)) {
c = (PyLongObject *)x;
Py_INCREF(x);
}
else if (x == Py_None)
c = NULL;
else {
Py_DECREF(a);
Py_DECREF(b);
Py_RETURN_NOTIMPLEMENTED;
}
if (Py_SIZE(b) < 0 && c == NULL) {
/* if exponent is negative and there's no modulus:
return a float. This works because we know
that this calls float_pow() which converts its
arguments to double. */
Py_DECREF(a);
Py_DECREF(b);
return PyFloat_Type.tp_as_number->nb_power(v, w, x);
}
if (c) {
/* if modulus == 0:
raise ValueError() */
if (Py_SIZE(c) == 0) {
PyErr_SetString(PyExc_ValueError,
"pow() 3rd argument cannot be 0");
goto Error;
}
/* if modulus < 0:
negativeOutput = True
modulus = -modulus */
if (Py_SIZE(c) < 0) {
negativeOutput = 1;
temp = (PyLongObject *)_PyLong_Copy(c);
if (temp == NULL)
goto Error;
Py_DECREF(c);
c = temp;
temp = NULL;
_PyLong_Negate(&c);
if (c == NULL)
goto Error;
}
/* if modulus == 1:
return 0 */
if ((Py_SIZE(c) == 1) && (c->ob_digit[0] == 1)) {
z = (PyLongObject *)PyLong_FromLong(0L);
goto Done;
}
/* if exponent is negative, negate the exponent and
replace the base with a modular inverse */
if (Py_SIZE(b) < 0) {
temp = (PyLongObject *)_PyLong_Copy(b);
if (temp == NULL)
goto Error;
Py_DECREF(b);
b = temp;
temp = NULL;
_PyLong_Negate(&b);
if (b == NULL)
goto Error;
temp = long_invmod(a, c);
if (temp == NULL)
goto Error;
Py_DECREF(a);
a = temp;
}
/* Reduce base by modulus in some cases:
1. If base < 0. Forcing the base non-negative makes things easier.
2. If base is obviously larger than the modulus. The "small
exponent" case later can multiply directly by base repeatedly,
while the "large exponent" case multiplies directly by base 31
times. It can be unboundedly faster to multiply by
base % modulus instead.
We could _always_ do this reduction, but l_divmod() isn't cheap,
so we only do it when it buys something. */
if (Py_SIZE(a) < 0 || Py_SIZE(a) > Py_SIZE(c)) {
if (l_divmod(a, c, NULL, &temp) < 0)
goto Error;
Py_DECREF(a);
a = temp;
temp = NULL;
}
}
/* At this point a, b, and c are guaranteed non-negative UNLESS
c is NULL, in which case a may be negative. */
z = (PyLongObject *)PyLong_FromLong(1L);
if (z == NULL)
goto Error;
/* Perform a modular reduction, X = X % c, but leave X alone if c
* is NULL.
*/
#define REDUCE(X) \
do { \
if (c != NULL) { \
if (l_divmod(X, c, NULL, &temp) < 0) \
goto Error; \
Py_XDECREF(X); \
X = temp; \
temp = NULL; \
} \
} while(0)
/* Multiply two values, then reduce the result:
result = X*Y % c. If c is NULL, skip the mod. */
#define MULT(X, Y, result) \
do { \
temp = (PyLongObject *)long_mul(X, Y); \
if (temp == NULL) \
goto Error; \
Py_XDECREF(result); \
result = temp; \
temp = NULL; \
REDUCE(result); \
} while(0)
if (Py_SIZE(b) <= FIVEARY_CUTOFF) {
/* Left-to-right binary exponentiation (HAC Algorithm 14.79) */
/* http://www.cacr.math.uwaterloo.ca/hac/about/chap14.pdf */
for (i = Py_SIZE(b) - 1; i >= 0; --i) {
digit bi = b->ob_digit[i];
for (j = (digit)1 << (PyLong_SHIFT-1); j != 0; j >>= 1) {
MULT(z, z, z);
if (bi & j)
MULT(z, a, z);
}
}
}
else {
/* Left-to-right 5-ary exponentiation (HAC Algorithm 14.82) */
Py_INCREF(z); /* still holds 1L */
table[0] = z;
for (i = 1; i < 32; ++i)
MULT(table[i-1], a, table[i]);
for (i = Py_SIZE(b) - 1; i >= 0; --i) {
const digit bi = b->ob_digit[i];
for (j = PyLong_SHIFT - 5; j >= 0; j -= 5) {
const int index = (bi >> j) & 0x1f;
for (k = 0; k < 5; ++k)
MULT(z, z, z);
if (index)
MULT(z, table[index], z);
}
}
}
if (negativeOutput && (Py_SIZE(z) != 0)) {
temp = (PyLongObject *)long_sub(z, c);
if (temp == NULL)
goto Error;
Py_DECREF(z);
z = temp;
temp = NULL;
}
goto Done;
Error:
Py_CLEAR(z);
/* fall through */
Done:
if (Py_SIZE(b) > FIVEARY_CUTOFF) {
for (i = 0; i < 32; ++i)
Py_XDECREF(table[i]);
}
Py_DECREF(a);
Py_DECREF(b);
Py_XDECREF(c);
Py_XDECREF(temp);
return (PyObject *)z;
}
static PyObject *
long_invert(PyLongObject *v)
{
/* Implement ~x as -(x+1) */
PyLongObject *x;
if (Py_ABS(Py_SIZE(v)) <=1)
return PyLong_FromLong(-(MEDIUM_VALUE(v)+1));
x = (PyLongObject *) long_add(v, (PyLongObject *)_PyLong_One);
if (x == NULL)
return NULL;
_PyLong_Negate(&x);
/* No need for maybe_small_long here, since any small
longs will have been caught in the Py_SIZE <= 1 fast path. */
return (PyObject *)x;
}
static PyObject *
long_neg(PyLongObject *v)
{
PyLongObject *z;
if (Py_ABS(Py_SIZE(v)) <= 1)
return PyLong_FromLong(-MEDIUM_VALUE(v));
z = (PyLongObject *)_PyLong_Copy(v);
if (z != NULL)
Py_SET_SIZE(z, -(Py_SIZE(v)));
return (PyObject *)z;
}
static PyObject *
long_abs(PyLongObject *v)
{
if (Py_SIZE(v) < 0)
return long_neg(v);
else
return long_long((PyObject *)v);
}
static int
long_bool(PyLongObject *v)
{
return Py_SIZE(v) != 0;
}
/* wordshift, remshift = divmod(shiftby, PyLong_SHIFT) */
static int
divmod_shift(PyObject *shiftby, Py_ssize_t *wordshift, digit *remshift)
{
assert(PyLong_Check(shiftby));
assert(Py_SIZE(shiftby) >= 0);
Py_ssize_t lshiftby = PyLong_AsSsize_t((PyObject *)shiftby);
if (lshiftby >= 0) {
*wordshift = lshiftby / PyLong_SHIFT;
*remshift = lshiftby % PyLong_SHIFT;
return 0;
}
/* PyLong_Check(shiftby) is true and Py_SIZE(shiftby) >= 0, so it must
be that PyLong_AsSsize_t raised an OverflowError. */
assert(PyErr_ExceptionMatches(PyExc_OverflowError));
PyErr_Clear();
PyLongObject *wordshift_obj = divrem1((PyLongObject *)shiftby, PyLong_SHIFT, remshift);
if (wordshift_obj == NULL) {
return -1;
}
*wordshift = PyLong_AsSsize_t((PyObject *)wordshift_obj);
Py_DECREF(wordshift_obj);
if (*wordshift >= 0 && *wordshift < PY_SSIZE_T_MAX / (Py_ssize_t)sizeof(digit)) {
return 0;
}
PyErr_Clear();
/* Clip the value. With such large wordshift the right shift
returns 0 and the left shift raises an error in _PyLong_New(). */
*wordshift = PY_SSIZE_T_MAX / sizeof(digit);
*remshift = 0;
return 0;
}
static PyObject *
long_rshift1(PyLongObject *a, Py_ssize_t wordshift, digit remshift)
{
PyLongObject *z = NULL;
Py_ssize_t newsize, hishift, i, j;
digit lomask, himask;
if (Py_SIZE(a) < 0) {
/* Right shifting negative numbers is harder */
PyLongObject *a1, *a2;
a1 = (PyLongObject *) long_invert(a);
if (a1 == NULL)
return NULL;
a2 = (PyLongObject *) long_rshift1(a1, wordshift, remshift);
Py_DECREF(a1);
if (a2 == NULL)
return NULL;
z = (PyLongObject *) long_invert(a2);
Py_DECREF(a2);
}
else {
newsize = Py_SIZE(a) - wordshift;
if (newsize <= 0)
return PyLong_FromLong(0);
hishift = PyLong_SHIFT - remshift;
lomask = ((digit)1 << hishift) - 1;
himask = PyLong_MASK ^ lomask;
z = _PyLong_New(newsize);
if (z == NULL)
return NULL;
for (i = 0, j = wordshift; i < newsize; i++, j++) {
z->ob_digit[i] = (a->ob_digit[j] >> remshift) & lomask;
if (i+1 < newsize)
z->ob_digit[i] |= (a->ob_digit[j+1] << hishift) & himask;
}
z = maybe_small_long(long_normalize(z));
}
return (PyObject *)z;
}
static PyObject *
long_rshift(PyObject *a, PyObject *b)
{
Py_ssize_t wordshift;
digit remshift;
CHECK_BINOP(a, b);
if (Py_SIZE(b) < 0) {
PyErr_SetString(PyExc_ValueError, "negative shift count");
return NULL;
}
if (Py_SIZE(a) == 0) {
return PyLong_FromLong(0);
}
if (divmod_shift(b, &wordshift, &remshift) < 0)
return NULL;
return long_rshift1((PyLongObject *)a, wordshift, remshift);
}
/* Return a >> shiftby. */
PyObject *
_PyLong_Rshift(PyObject *a, size_t shiftby)
{
Py_ssize_t wordshift;
digit remshift;
assert(PyLong_Check(a));
if (Py_SIZE(a) == 0) {
return PyLong_FromLong(0);
}
wordshift = shiftby / PyLong_SHIFT;
remshift = shiftby % PyLong_SHIFT;
return long_rshift1((PyLongObject *)a, wordshift, remshift);
}
static PyObject *
long_lshift1(PyLongObject *a, Py_ssize_t wordshift, digit remshift)
{
/* This version due to Tim Peters */
PyLongObject *z = NULL;
Py_ssize_t oldsize, newsize, i, j;
twodigits accum;
oldsize = Py_ABS(Py_SIZE(a));
newsize = oldsize + wordshift;
if (remshift)
++newsize;
z = _PyLong_New(newsize);
if (z == NULL)
return NULL;
if (Py_SIZE(a) < 0) {
assert(Py_REFCNT(z) == 1);
Py_SET_SIZE(z, -Py_SIZE(z));
}
for (i = 0; i < wordshift; i++)
z->ob_digit[i] = 0;
accum = 0;
for (i = wordshift, j = 0; j < oldsize; i++, j++) {
accum |= (twodigits)a->ob_digit[j] << remshift;
z->ob_digit[i] = (digit)(accum & PyLong_MASK);
accum >>= PyLong_SHIFT;
}
if (remshift)
z->ob_digit[newsize-1] = (digit)accum;
else
assert(!accum);
z = long_normalize(z);
return (PyObject *) maybe_small_long(z);
}
static PyObject *
long_lshift(PyObject *a, PyObject *b)
{
Py_ssize_t wordshift;
digit remshift;
CHECK_BINOP(a, b);
if (Py_SIZE(b) < 0) {
PyErr_SetString(PyExc_ValueError, "negative shift count");
return NULL;
}
if (Py_SIZE(a) == 0) {
return PyLong_FromLong(0);
}
if (divmod_shift(b, &wordshift, &remshift) < 0)
return NULL;
return long_lshift1((PyLongObject *)a, wordshift, remshift);
}
/* Return a << shiftby. */
PyObject *
_PyLong_Lshift(PyObject *a, size_t shiftby)
{
Py_ssize_t wordshift;
digit remshift;
assert(PyLong_Check(a));
if (Py_SIZE(a) == 0) {
return PyLong_FromLong(0);
}
wordshift = shiftby / PyLong_SHIFT;
remshift = shiftby % PyLong_SHIFT;
return long_lshift1((PyLongObject *)a, wordshift, remshift);
}
/* Compute two's complement of digit vector a[0:m], writing result to
z[0:m]. The digit vector a need not be normalized, but should not
be entirely zero. a and z may point to the same digit vector. */
static void
v_complement(digit *z, digit *a, Py_ssize_t m)
{
Py_ssize_t i;
digit carry = 1;
for (i = 0; i < m; ++i) {
carry += a[i] ^ PyLong_MASK;
z[i] = carry & PyLong_MASK;
carry >>= PyLong_SHIFT;
}
assert(carry == 0);
}
/* Bitwise and/xor/or operations */
static PyObject *
long_bitwise(PyLongObject *a,
char op, /* '&', '|', '^' */
PyLongObject *b)
{
int nega, negb, negz;
Py_ssize_t size_a, size_b, size_z, i;
PyLongObject *z;
/* Bitwise operations for negative numbers operate as though
on a two's complement representation. So convert arguments
from sign-magnitude to two's complement, and convert the
result back to sign-magnitude at the end. */
/* If a is negative, replace it by its two's complement. */
size_a = Py_ABS(Py_SIZE(a));
nega = Py_SIZE(a) < 0;
if (nega) {
z = _PyLong_New(size_a);
if (z == NULL)
return NULL;
v_complement(z->ob_digit, a->ob_digit, size_a);
a = z;
}
else
/* Keep reference count consistent. */
Py_INCREF(a);
/* Same for b. */
size_b = Py_ABS(Py_SIZE(b));
negb = Py_SIZE(b) < 0;
if (negb) {
z = _PyLong_New(size_b);
if (z == NULL) {
Py_DECREF(a);
return NULL;
}
v_complement(z->ob_digit, b->ob_digit, size_b);
b = z;
}
else
Py_INCREF(b);
/* Swap a and b if necessary to ensure size_a >= size_b. */
if (size_a < size_b) {
z = a; a = b; b = z;
size_z = size_a; size_a = size_b; size_b = size_z;
negz = nega; nega = negb; negb = negz;
}
/* JRH: The original logic here was to allocate the result value (z)
as the longer of the two operands. However, there are some cases
where the result is guaranteed to be shorter than that: AND of two
positives, OR of two negatives: use the shorter number. AND with
mixed signs: use the positive number. OR with mixed signs: use the
negative number.
*/
switch (op) {
case '^':
negz = nega ^ negb;
size_z = size_a;
break;
case '&':
negz = nega & negb;
size_z = negb ? size_a : size_b;
break;
case '|':
negz = nega | negb;
size_z = negb ? size_b : size_a;
break;
default:
Py_UNREACHABLE();
}
/* We allow an extra digit if z is negative, to make sure that
the final two's complement of z doesn't overflow. */
z = _PyLong_New(size_z + negz);
if (z == NULL) {
Py_DECREF(a);
Py_DECREF(b);
return NULL;
}
/* Compute digits for overlap of a and b. */
switch(op) {
case '&':
for (i = 0; i < size_b; ++i)
z->ob_digit[i] = a->ob_digit[i] & b->ob_digit[i];
break;
case '|':
for (i = 0; i < size_b; ++i)
z->ob_digit[i] = a->ob_digit[i] | b->ob_digit[i];
break;
case '^':
for (i = 0; i < size_b; ++i)
z->ob_digit[i] = a->ob_digit[i] ^ b->ob_digit[i];
break;
default:
Py_UNREACHABLE();
}
/* Copy any remaining digits of a, inverting if necessary. */
if (op == '^' && negb)
for (; i < size_z; ++i)
z->ob_digit[i] = a->ob_digit[i] ^ PyLong_MASK;
else if (i < size_z)
memcpy(&z->ob_digit[i], &a->ob_digit[i],
(size_z-i)*sizeof(digit));
/* Complement result if negative. */
if (negz) {
Py_SET_SIZE(z, -(Py_SIZE(z)));
z->ob_digit[size_z] = PyLong_MASK;
v_complement(z->ob_digit, z->ob_digit, size_z+1);
}
Py_DECREF(a);
Py_DECREF(b);
return (PyObject *)maybe_small_long(long_normalize(z));
}
static PyObject *
long_and(PyObject *a, PyObject *b)
{
PyObject *c;
CHECK_BINOP(a, b);
c = long_bitwise((PyLongObject*)a, '&', (PyLongObject*)b);
return c;
}
static PyObject *
long_xor(PyObject *a, PyObject *b)
{
PyObject *c;
CHECK_BINOP(a, b);
c = long_bitwise((PyLongObject*)a, '^', (PyLongObject*)b);
return c;
}
static PyObject *
long_or(PyObject *a, PyObject *b)
{
PyObject *c;
CHECK_BINOP(a, b);
c = long_bitwise((PyLongObject*)a, '|', (PyLongObject*)b);
return c;
}
static PyObject *
long_long(PyObject *v)
{
if (PyLong_CheckExact(v))
Py_INCREF(v);
else
v = _PyLong_Copy((PyLongObject *)v);
return v;
}
PyObject *
_PyLong_GCD(PyObject *aarg, PyObject *barg)
{
PyLongObject *a, *b, *c = NULL, *d = NULL, *r;
stwodigits x, y, q, s, t, c_carry, d_carry;
stwodigits A, B, C, D, T;
int nbits, k;
Py_ssize_t size_a, size_b, alloc_a, alloc_b;
digit *a_digit, *b_digit, *c_digit, *d_digit, *a_end, *b_end;
a = (PyLongObject *)aarg;
b = (PyLongObject *)barg;
size_a = Py_SIZE(a);
size_b = Py_SIZE(b);
if (-2 <= size_a && size_a <= 2 && -2 <= size_b && size_b <= 2) {
Py_INCREF(a);
Py_INCREF(b);
goto simple;
}
/* Initial reduction: make sure that 0 <= b <= a. */
a = (PyLongObject *)long_abs(a);
if (a == NULL)
return NULL;
b = (PyLongObject *)long_abs(b);
if (b == NULL) {
Py_DECREF(a);
return NULL;
}
if (long_compare(a, b) < 0) {
r = a;
a = b;
b = r;
}
/* We now own references to a and b */
alloc_a = Py_SIZE(a);
alloc_b = Py_SIZE(b);
/* reduce until a fits into 2 digits */
while ((size_a = Py_SIZE(a)) > 2) {
nbits = bit_length_digit(a->ob_digit[size_a-1]);
/* extract top 2*PyLong_SHIFT bits of a into x, along with
corresponding bits of b into y */
size_b = Py_SIZE(b);
assert(size_b <= size_a);
if (size_b == 0) {
if (size_a < alloc_a) {
r = (PyLongObject *)_PyLong_Copy(a);
Py_DECREF(a);
}
else
r = a;
Py_DECREF(b);
Py_XDECREF(c);
Py_XDECREF(d);
return (PyObject *)r;
}
x = (((twodigits)a->ob_digit[size_a-1] << (2*PyLong_SHIFT-nbits)) |
((twodigits)a->ob_digit[size_a-2] << (PyLong_SHIFT-nbits)) |
(a->ob_digit[size_a-3] >> nbits));
y = ((size_b >= size_a - 2 ? b->ob_digit[size_a-3] >> nbits : 0) |
(size_b >= size_a - 1 ? (twodigits)b->ob_digit[size_a-2] << (PyLong_SHIFT-nbits) : 0) |
(size_b >= size_a ? (twodigits)b->ob_digit[size_a-1] << (2*PyLong_SHIFT-nbits) : 0));
/* inner loop of Lehmer's algorithm; A, B, C, D never grow
larger than PyLong_MASK during the algorithm. */
A = 1; B = 0; C = 0; D = 1;
for (k=0;; k++) {
if (y-C == 0)
break;
q = (x+(A-1))/(y-C);
s = B+q*D;
t = x-q*y;
if (s > t)
break;
x = y; y = t;
t = A+q*C; A = D; B = C; C = s; D = t;
}
if (k == 0) {
/* no progress; do a Euclidean step */
if (l_divmod(a, b, NULL, &r) < 0)
goto error;
Py_DECREF(a);
a = b;
b = r;
alloc_a = alloc_b;
alloc_b = Py_SIZE(b);
continue;
}
/*
a, b = A*b-B*a, D*a-C*b if k is odd
a, b = A*a-B*b, D*b-C*a if k is even
*/
if (k&1) {
T = -A; A = -B; B = T;
T = -C; C = -D; D = T;
}
if (c != NULL) {
Py_SET_SIZE(c, size_a);
}
else if (Py_REFCNT(a) == 1) {
Py_INCREF(a);
c = a;
}
else {
alloc_a = size_a;
c = _PyLong_New(size_a);
if (c == NULL)
goto error;
}
if (d != NULL) {
Py_SET_SIZE(d, size_a);
}
else if (Py_REFCNT(b) == 1 && size_a <= alloc_b) {
Py_INCREF(b);
d = b;
Py_SET_SIZE(d, size_a);
}
else {
alloc_b = size_a;
d = _PyLong_New(size_a);
if (d == NULL)
goto error;
}
a_end = a->ob_digit + size_a;
b_end = b->ob_digit + size_b;
/* compute new a and new b in parallel */
a_digit = a->ob_digit;
b_digit = b->ob_digit;
c_digit = c->ob_digit;
d_digit = d->ob_digit;
c_carry = 0;
d_carry = 0;
while (b_digit < b_end) {
c_carry += (A * *a_digit) - (B * *b_digit);
d_carry += (D * *b_digit++) - (C * *a_digit++);
*c_digit++ = (digit)(c_carry & PyLong_MASK);
*d_digit++ = (digit)(d_carry & PyLong_MASK);
c_carry >>= PyLong_SHIFT;
d_carry >>= PyLong_SHIFT;
}
while (a_digit < a_end) {
c_carry += A * *a_digit;
d_carry -= C * *a_digit++;
*c_digit++ = (digit)(c_carry & PyLong_MASK);
*d_digit++ = (digit)(d_carry & PyLong_MASK);
c_carry >>= PyLong_SHIFT;
d_carry >>= PyLong_SHIFT;
}
assert(c_carry == 0);
assert(d_carry == 0);
Py_INCREF(c);
Py_INCREF(d);
Py_DECREF(a);
Py_DECREF(b);
a = long_normalize(c);
b = long_normalize(d);
}
Py_XDECREF(c);
Py_XDECREF(d);
simple:
assert(Py_REFCNT(a) > 0);
assert(Py_REFCNT(b) > 0);
/* Issue #24999: use two shifts instead of ">> 2*PyLong_SHIFT" to avoid
undefined behaviour when LONG_MAX type is smaller than 60 bits */
#if LONG_MAX >> PyLong_SHIFT >> PyLong_SHIFT
/* a fits into a long, so b must too */
x = PyLong_AsLong((PyObject *)a);
y = PyLong_AsLong((PyObject *)b);
#elif LLONG_MAX >> PyLong_SHIFT >> PyLong_SHIFT
x = PyLong_AsLongLong((PyObject *)a);
y = PyLong_AsLongLong((PyObject *)b);
#else
# error "_PyLong_GCD"
#endif
x = Py_ABS(x);
y = Py_ABS(y);
Py_DECREF(a);
Py_DECREF(b);
/* usual Euclidean algorithm for longs */
while (y != 0) {
t = y;
y = x % y;
x = t;
}
#if LONG_MAX >> PyLong_SHIFT >> PyLong_SHIFT
return PyLong_FromLong(x);
#elif LLONG_MAX >> PyLong_SHIFT >> PyLong_SHIFT
return PyLong_FromLongLong(x);
#else
# error "_PyLong_GCD"
#endif
error:
Py_DECREF(a);
Py_DECREF(b);
Py_XDECREF(c);
Py_XDECREF(d);
return NULL;
}
static PyObject *
long_float(PyObject *v)
{
double result;
result = PyLong_AsDouble(v);
if (result == -1.0 && PyErr_Occurred())
return NULL;
return PyFloat_FromDouble(result);
}
static PyObject *
long_subtype_new(PyTypeObject *type, PyObject *x, PyObject *obase);
/*[clinic input]
@classmethod
int.__new__ as long_new
x: object(c_default="NULL") = 0
/
base as obase: object(c_default="NULL") = 10
[clinic start generated code]*/
static PyObject *
long_new_impl(PyTypeObject *type, PyObject *x, PyObject *obase)
/*[clinic end generated code: output=e47cfe777ab0f24c input=81c98f418af9eb6f]*/
{
Py_ssize_t base;
if (type != &PyLong_Type)
return long_subtype_new(type, x, obase); /* Wimp out */
if (x == NULL) {
if (obase != NULL) {
PyErr_SetString(PyExc_TypeError,
"int() missing string argument");
return NULL;
}
return PyLong_FromLong(0L);
}
if (obase == NULL)
return PyNumber_Long(x);
base = PyNumber_AsSsize_t(obase, NULL);
if (base == -1 && PyErr_Occurred())
return NULL;
if ((base != 0 && base < 2) || base > 36) {
PyErr_SetString(PyExc_ValueError,
"int() base must be >= 2 and <= 36, or 0");
return NULL;
}
if (PyUnicode_Check(x))
return PyLong_FromUnicodeObject(x, (int)base);
else if (PyByteArray_Check(x) || PyBytes_Check(x)) {
const char *string;
if (PyByteArray_Check(x))
string = PyByteArray_AS_STRING(x);
else
string = PyBytes_AS_STRING(x);
return _PyLong_FromBytes(string, Py_SIZE(x), (int)base);
}
else {
PyErr_SetString(PyExc_TypeError,
"int() can't convert non-string with explicit base");
return NULL;
}
}
/* Wimpy, slow approach to tp_new calls for subtypes of int:
first create a regular int from whatever arguments we got,
then allocate a subtype instance and initialize it from
the regular int. The regular int is then thrown away.
*/
static PyObject *
long_subtype_new(PyTypeObject *type, PyObject *x, PyObject *obase)
{
PyLongObject *tmp, *newobj;
Py_ssize_t i, n;
assert(PyType_IsSubtype(type, &PyLong_Type));
tmp = (PyLongObject *)long_new_impl(&PyLong_Type, x, obase);
if (tmp == NULL)
return NULL;
assert(PyLong_Check(tmp));
n = Py_SIZE(tmp);
if (n < 0)
n = -n;
newobj = (PyLongObject *)type->tp_alloc(type, n);
if (newobj == NULL) {
Py_DECREF(tmp);
return NULL;
}
assert(PyLong_Check(newobj));
Py_SET_SIZE(newobj, Py_SIZE(tmp));
for (i = 0; i < n; i++) {
newobj->ob_digit[i] = tmp->ob_digit[i];
}
Py_DECREF(tmp);
return (PyObject *)newobj;
}
/*[clinic input]
int.__getnewargs__
[clinic start generated code]*/
static PyObject *
int___getnewargs___impl(PyObject *self)
/*[clinic end generated code: output=839a49de3f00b61b input=5904770ab1fb8c75]*/
{
return Py_BuildValue("(N)", _PyLong_Copy((PyLongObject *)self));
}
static PyObject *
long_get0(PyObject *Py_UNUSED(self), void *Py_UNUSED(context))
{
return PyLong_FromLong(0L);
}
static PyObject *
long_get1(PyObject *Py_UNUSED(self), void *Py_UNUSED(ignored))
{
return PyLong_FromLong(1L);
}
/*[clinic input]
int.__format__
format_spec: unicode
/
[clinic start generated code]*/
static PyObject *
int___format___impl(PyObject *self, PyObject *format_spec)
/*[clinic end generated code: output=b4929dee9ae18689 input=e31944a9b3e428b7]*/
{
_PyUnicodeWriter writer;
int ret;
_PyUnicodeWriter_Init(&writer);
ret = _PyLong_FormatAdvancedWriter(
&writer,
self,
format_spec, 0, PyUnicode_GET_LENGTH(format_spec));
if (ret == -1) {
_PyUnicodeWriter_Dealloc(&writer);
return NULL;
}
return _PyUnicodeWriter_Finish(&writer);
}
/* Return a pair (q, r) such that a = b * q + r, and
abs(r) <= abs(b)/2, with equality possible only if q is even.
In other words, q == a / b, rounded to the nearest integer using
round-half-to-even. */
PyObject *
_PyLong_DivmodNear(PyObject *a, PyObject *b)
{
PyLongObject *quo = NULL, *rem = NULL;
PyObject *twice_rem, *result, *temp;
int quo_is_odd, quo_is_neg;
Py_ssize_t cmp;
/* Equivalent Python code:
def divmod_near(a, b):
q, r = divmod(a, b)
# round up if either r / b > 0.5, or r / b == 0.5 and q is odd.
# The expression r / b > 0.5 is equivalent to 2 * r > b if b is
# positive, 2 * r < b if b negative.
greater_than_half = 2*r > b if b > 0 else 2*r < b
exactly_half = 2*r == b
if greater_than_half or exactly_half and q % 2 == 1:
q += 1
r -= b
return q, r
*/
if (!PyLong_Check(a) || !PyLong_Check(b)) {
PyErr_SetString(PyExc_TypeError,
"non-integer arguments in division");
return NULL;
}
/* Do a and b have different signs? If so, quotient is negative. */
quo_is_neg = (Py_SIZE(a) < 0) != (Py_SIZE(b) < 0);
if (long_divrem((PyLongObject*)a, (PyLongObject*)b, &quo, &rem) < 0)
goto error;
/* compare twice the remainder with the divisor, to see
if we need to adjust the quotient and remainder */
twice_rem = long_lshift((PyObject *)rem, _PyLong_One);
if (twice_rem == NULL)
goto error;
if (quo_is_neg) {
temp = long_neg((PyLongObject*)twice_rem);
Py_DECREF(twice_rem);
twice_rem = temp;
if (twice_rem == NULL)
goto error;
}
cmp = long_compare((PyLongObject *)twice_rem, (PyLongObject *)b);
Py_DECREF(twice_rem);
quo_is_odd = Py_SIZE(quo) != 0 && ((quo->ob_digit[0] & 1) != 0);
if ((Py_SIZE(b) < 0 ? cmp < 0 : cmp > 0) || (cmp == 0 && quo_is_odd)) {
/* fix up quotient */
if (quo_is_neg)
temp = long_sub(quo, (PyLongObject *)_PyLong_One);
else
temp = long_add(quo, (PyLongObject *)_PyLong_One);
Py_DECREF(quo);
quo = (PyLongObject *)temp;
if (quo == NULL)
goto error;
/* and remainder */
if (quo_is_neg)
temp = long_add(rem, (PyLongObject *)b);
else
temp = long_sub(rem, (PyLongObject *)b);
Py_DECREF(rem);
rem = (PyLongObject *)temp;
if (rem == NULL)
goto error;
}
result = PyTuple_New(2);
if (result == NULL)
goto error;
/* PyTuple_SET_ITEM steals references */
PyTuple_SET_ITEM(result, 0, (PyObject *)quo);
PyTuple_SET_ITEM(result, 1, (PyObject *)rem);
return result;
error:
Py_XDECREF(quo);
Py_XDECREF(rem);
return NULL;
}
static PyObject *
long_round(PyObject *self, PyObject *args)
{
PyObject *o_ndigits=NULL, *temp, *result, *ndigits;
/* To round an integer m to the nearest 10**n (n positive), we make use of
* the divmod_near operation, defined by:
*
* divmod_near(a, b) = (q, r)
*
* where q is the nearest integer to the quotient a / b (the
* nearest even integer in the case of a tie) and r == a - q * b.
* Hence q * b = a - r is the nearest multiple of b to a,
* preferring even multiples in the case of a tie.
*
* So the nearest multiple of 10**n to m is:
*
* m - divmod_near(m, 10**n)[1].
*/
if (!PyArg_ParseTuple(args, "|O", &o_ndigits))
return NULL;
if (o_ndigits == NULL)
return long_long(self);
ndigits = _PyNumber_Index(o_ndigits);
if (ndigits == NULL)
return NULL;
/* if ndigits >= 0 then no rounding is necessary; return self unchanged */
if (Py_SIZE(ndigits) >= 0) {
Py_DECREF(ndigits);
return long_long(self);
}
/* result = self - divmod_near(self, 10 ** -ndigits)[1] */
temp = long_neg((PyLongObject*)ndigits);
Py_DECREF(ndigits);
ndigits = temp;
if (ndigits == NULL)
return NULL;
result = PyLong_FromLong(10L);
if (result == NULL) {
Py_DECREF(ndigits);
return NULL;
}
temp = long_pow(result, ndigits, Py_None);
Py_DECREF(ndigits);
Py_DECREF(result);
result = temp;
if (result == NULL)
return NULL;
temp = _PyLong_DivmodNear(self, result);
Py_DECREF(result);
result = temp;
if (result == NULL)
return NULL;
temp = long_sub((PyLongObject *)self,
(PyLongObject *)PyTuple_GET_ITEM(result, 1));
Py_DECREF(result);
result = temp;
return result;
}
/*[clinic input]
int.__sizeof__ -> Py_ssize_t
Returns size in memory, in bytes.
[clinic start generated code]*/
static Py_ssize_t
int___sizeof___impl(PyObject *self)
/*[clinic end generated code: output=3303f008eaa6a0a5 input=9b51620c76fc4507]*/
{
Py_ssize_t res;
res = offsetof(PyLongObject, ob_digit) + Py_ABS(Py_SIZE(self))*sizeof(digit);
return res;
}
/*[clinic input]
int.bit_length
Number of bits necessary to represent self in binary.
>>> bin(37)
'0b100101'
>>> (37).bit_length()
6
[clinic start generated code]*/
static PyObject *
int_bit_length_impl(PyObject *self)
/*[clinic end generated code: output=fc1977c9353d6a59 input=e4eb7a587e849a32]*/
{
PyLongObject *result, *x, *y;
Py_ssize_t ndigits;
int msd_bits;
digit msd;
assert(self != NULL);
assert(PyLong_Check(self));
ndigits = Py_ABS(Py_SIZE(self));
if (ndigits == 0)
return PyLong_FromLong(0);
msd = ((PyLongObject *)self)->ob_digit[ndigits-1];
msd_bits = bit_length_digit(msd);
if (ndigits <= PY_SSIZE_T_MAX/PyLong_SHIFT)
return PyLong_FromSsize_t((ndigits-1)*PyLong_SHIFT + msd_bits);
/* expression above may overflow; use Python integers instead */
result = (PyLongObject *)PyLong_FromSsize_t(ndigits - 1);
if (result == NULL)
return NULL;
x = (PyLongObject *)PyLong_FromLong(PyLong_SHIFT);
if (x == NULL)
goto error;
y = (PyLongObject *)long_mul(result, x);
Py_DECREF(x);
if (y == NULL)
goto error;
Py_DECREF(result);
result = y;
x = (PyLongObject *)PyLong_FromLong((long)msd_bits);
if (x == NULL)
goto error;
y = (PyLongObject *)long_add(result, x);
Py_DECREF(x);
if (y == NULL)
goto error;
Py_DECREF(result);
result = y;
return (PyObject *)result;
error:
Py_DECREF(result);
return NULL;
}
static int
popcount_digit(digit d)
{
// digit can be larger than uint32_t, but only PyLong_SHIFT bits
// of it will be ever used.
Py_BUILD_ASSERT(PyLong_SHIFT <= 32);
return _Py_popcount32((uint32_t)d);
}
/*[clinic input]
int.bit_count
Number of ones in the binary representation of the absolute value of self.
Also known as the population count.
>>> bin(13)
'0b1101'
>>> (13).bit_count()
3
[clinic start generated code]*/
static PyObject *
int_bit_count_impl(PyObject *self)
/*[clinic end generated code: output=2e571970daf1e5c3 input=7e0adef8e8ccdf2e]*/
{
assert(self != NULL);
assert(PyLong_Check(self));
PyLongObject *z = (PyLongObject *)self;
Py_ssize_t ndigits = Py_ABS(Py_SIZE(z));
Py_ssize_t bit_count = 0;
/* Each digit has up to PyLong_SHIFT ones, so the accumulated bit count
from the first PY_SSIZE_T_MAX/PyLong_SHIFT digits can't overflow a
Py_ssize_t. */
Py_ssize_t ndigits_fast = Py_MIN(ndigits, PY_SSIZE_T_MAX/PyLong_SHIFT);
for (Py_ssize_t i = 0; i < ndigits_fast; i++) {
bit_count += popcount_digit(z->ob_digit[i]);
}
PyObject *result = PyLong_FromSsize_t(bit_count);
if (result == NULL) {
return NULL;
}
/* Use Python integers if bit_count would overflow. */
for (Py_ssize_t i = ndigits_fast; i < ndigits; i++) {
PyObject *x = PyLong_FromLong(popcount_digit(z->ob_digit[i]));
if (x == NULL) {
goto error;
}
PyObject *y = long_add((PyLongObject *)result, (PyLongObject *)x);
Py_DECREF(x);
if (y == NULL) {
goto error;
}
Py_DECREF(result);
result = y;
}
return result;
error:
Py_DECREF(result);
return NULL;
}
/*[clinic input]
int.as_integer_ratio
Return integer ratio.
Return a pair of integers, whose ratio is exactly equal to the original int
and with a positive denominator.
>>> (10).as_integer_ratio()
(10, 1)
>>> (-10).as_integer_ratio()
(-10, 1)
>>> (0).as_integer_ratio()
(0, 1)
[clinic start generated code]*/
static PyObject *
int_as_integer_ratio_impl(PyObject *self)
/*[clinic end generated code: output=e60803ae1cc8621a input=55ce3058e15de393]*/
{
PyObject *ratio_tuple;
PyObject *numerator = long_long(self);
if (numerator == NULL) {
return NULL;
}
ratio_tuple = PyTuple_Pack(2, numerator, _PyLong_One);
Py_DECREF(numerator);
return ratio_tuple;
}
/*[clinic input]
int.to_bytes
length: Py_ssize_t
Length of bytes object to use. An OverflowError is raised if the
integer is not representable with the given number of bytes.
byteorder: unicode
The byte order used to represent the integer. If byteorder is 'big',
the most significant byte is at the beginning of the byte array. If
byteorder is 'little', the most significant byte is at the end of the
byte array. To request the native byte order of the host system, use
`sys.byteorder' as the byte order value.
*
signed as is_signed: bool = False
Determines whether two's complement is used to represent the integer.
If signed is False and a negative integer is given, an OverflowError
is raised.
Return an array of bytes representing an integer.
[clinic start generated code]*/
static PyObject *
int_to_bytes_impl(PyObject *self, Py_ssize_t length, PyObject *byteorder,
int is_signed)
/*[clinic end generated code: output=89c801df114050a3 input=ddac63f4c7bf414c]*/
{
int little_endian;
PyObject *bytes;
if (_PyUnicode_EqualToASCIIId(byteorder, &PyId_little))
little_endian = 1;
else if (_PyUnicode_EqualToASCIIId(byteorder, &PyId_big))
little_endian = 0;
else {
PyErr_SetString(PyExc_ValueError,
"byteorder must be either 'little' or 'big'");
return NULL;
}
if (length < 0) {
PyErr_SetString(PyExc_ValueError,
"length argument must be non-negative");
return NULL;
}
bytes = PyBytes_FromStringAndSize(NULL, length);
if (bytes == NULL)
return NULL;
if (_PyLong_AsByteArray((PyLongObject *)self,
(unsigned char *)PyBytes_AS_STRING(bytes),
length, little_endian, is_signed) < 0) {
Py_DECREF(bytes);
return NULL;
}
return bytes;
}
/*[clinic input]
@classmethod
int.from_bytes
bytes as bytes_obj: object
Holds the array of bytes to convert. The argument must either
support the buffer protocol or be an iterable object producing bytes.
Bytes and bytearray are examples of built-in objects that support the
buffer protocol.
byteorder: unicode
The byte order used to represent the integer. If byteorder is 'big',
the most significant byte is at the beginning of the byte array. If
byteorder is 'little', the most significant byte is at the end of the
byte array. To request the native byte order of the host system, use
`sys.byteorder' as the byte order value.
*
signed as is_signed: bool = False
Indicates whether two's complement is used to represent the integer.
Return the integer represented by the given array of bytes.
[clinic start generated code]*/
static PyObject *
int_from_bytes_impl(PyTypeObject *type, PyObject *bytes_obj,
PyObject *byteorder, int is_signed)
/*[clinic end generated code: output=efc5d68e31f9314f input=cdf98332b6a821b0]*/
{
int little_endian;
PyObject *long_obj, *bytes;
if (_PyUnicode_EqualToASCIIId(byteorder, &PyId_little))
little_endian = 1;
else if (_PyUnicode_EqualToASCIIId(byteorder, &PyId_big))
little_endian = 0;
else {
PyErr_SetString(PyExc_ValueError,
"byteorder must be either 'little' or 'big'");
return NULL;
}
bytes = PyObject_Bytes(bytes_obj);
if (bytes == NULL)
return NULL;
long_obj = _PyLong_FromByteArray(
(unsigned char *)PyBytes_AS_STRING(bytes), Py_SIZE(bytes),
little_endian, is_signed);
Py_DECREF(bytes);
if (long_obj != NULL && type != &PyLong_Type) {
Py_SETREF(long_obj, PyObject_CallOneArg((PyObject *)type, long_obj));
}
return long_obj;
}
static PyObject *
long_long_meth(PyObject *self, PyObject *Py_UNUSED(ignored))
{
return long_long(self);
}
static PyMethodDef long_methods[] = {
{"conjugate", long_long_meth, METH_NOARGS,
"Returns self, the complex conjugate of any int."},
INT_BIT_LENGTH_METHODDEF
INT_BIT_COUNT_METHODDEF
INT_TO_BYTES_METHODDEF
INT_FROM_BYTES_METHODDEF
INT_AS_INTEGER_RATIO_METHODDEF
{"__trunc__", long_long_meth, METH_NOARGS,
"Truncating an Integral returns itself."},
{"__floor__", long_long_meth, METH_NOARGS,
"Flooring an Integral returns itself."},
{"__ceil__", long_long_meth, METH_NOARGS,
"Ceiling of an Integral returns itself."},
{"__round__", (PyCFunction)long_round, METH_VARARGS,
"Rounding an Integral returns itself.\n"
"Rounding with an ndigits argument also returns an integer."},
INT___GETNEWARGS___METHODDEF
INT___FORMAT___METHODDEF
INT___SIZEOF___METHODDEF
{NULL, NULL} /* sentinel */
};
static PyGetSetDef long_getset[] = {
{"real",
(getter)long_long_meth, (setter)NULL,
"the real part of a complex number",
NULL},
{"imag",
long_get0, (setter)NULL,
"the imaginary part of a complex number",
NULL},
{"numerator",
(getter)long_long_meth, (setter)NULL,
"the numerator of a rational number in lowest terms",
NULL},
{"denominator",
long_get1, (setter)NULL,
"the denominator of a rational number in lowest terms",
NULL},
{NULL} /* Sentinel */
};
PyDoc_STRVAR(long_doc,
"int([x]) -> integer\n\
int(x, base=10) -> integer\n\
\n\
Convert a number or string to an integer, or return 0 if no arguments\n\
are given. If x is a number, return x.__int__(). For floating point\n\
numbers, this truncates towards zero.\n\
\n\
If x is not a number or if base is given, then x must be a string,\n\
bytes, or bytearray instance representing an integer literal in the\n\
given base. The literal can be preceded by '+' or '-' and be surrounded\n\
by whitespace. The base defaults to 10. Valid bases are 0 and 2-36.\n\
Base 0 means to interpret the base from the string as an integer literal.\n\
>>> int('0b100', base=0)\n\
4");
static PyNumberMethods long_as_number = {
(binaryfunc)long_add, /*nb_add*/
(binaryfunc)long_sub, /*nb_subtract*/
(binaryfunc)long_mul, /*nb_multiply*/
long_mod, /*nb_remainder*/
long_divmod, /*nb_divmod*/
long_pow, /*nb_power*/
(unaryfunc)long_neg, /*nb_negative*/
long_long, /*tp_positive*/
(unaryfunc)long_abs, /*tp_absolute*/
(inquiry)long_bool, /*tp_bool*/
(unaryfunc)long_invert, /*nb_invert*/
long_lshift, /*nb_lshift*/
long_rshift, /*nb_rshift*/
long_and, /*nb_and*/
long_xor, /*nb_xor*/
long_or, /*nb_or*/
long_long, /*nb_int*/
0, /*nb_reserved*/
long_float, /*nb_float*/
0, /* nb_inplace_add */
0, /* nb_inplace_subtract */
0, /* nb_inplace_multiply */
0, /* nb_inplace_remainder */
0, /* nb_inplace_power */
0, /* nb_inplace_lshift */
0, /* nb_inplace_rshift */
0, /* nb_inplace_and */
0, /* nb_inplace_xor */
0, /* nb_inplace_or */
long_div, /* nb_floor_divide */
long_true_divide, /* nb_true_divide */
0, /* nb_inplace_floor_divide */
0, /* nb_inplace_true_divide */
long_long, /* nb_index */
};
PyTypeObject PyLong_Type = {
PyVarObject_HEAD_INIT(&PyType_Type, 0)
"int", /* tp_name */
offsetof(PyLongObject, ob_digit), /* tp_basicsize */
sizeof(digit), /* tp_itemsize */
0, /* tp_dealloc */
0, /* tp_vectorcall_offset */
0, /* tp_getattr */
0, /* tp_setattr */
0, /* tp_as_async */
long_to_decimal_string, /* tp_repr */
&long_as_number, /* tp_as_number */
0, /* tp_as_sequence */
0, /* tp_as_mapping */
(hashfunc)long_hash, /* tp_hash */
0, /* tp_call */
0, /* tp_str */
PyObject_GenericGetAttr, /* tp_getattro */
0, /* tp_setattro */
0, /* tp_as_buffer */
Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE |
Py_TPFLAGS_LONG_SUBCLASS, /* tp_flags */
long_doc, /* tp_doc */
0, /* tp_traverse */
0, /* tp_clear */
long_richcompare, /* tp_richcompare */
0, /* tp_weaklistoffset */
0, /* tp_iter */
0, /* tp_iternext */
long_methods, /* tp_methods */
0, /* tp_members */
long_getset, /* tp_getset */
0, /* tp_base */
0, /* tp_dict */
0, /* tp_descr_get */
0, /* tp_descr_set */
0, /* tp_dictoffset */
0, /* tp_init */
0, /* tp_alloc */
long_new, /* tp_new */
PyObject_Del, /* tp_free */
};
static PyTypeObject Int_InfoType;
PyDoc_STRVAR(int_info__doc__,
"sys.int_info\n\
\n\
A named tuple that holds information about Python's\n\
internal representation of integers. The attributes are read only.");
static PyStructSequence_Field int_info_fields[] = {
{"bits_per_digit", "size of a digit in bits"},
{"sizeof_digit", "size in bytes of the C type used to represent a digit"},
{NULL, NULL}
};
static PyStructSequence_Desc int_info_desc = {
"sys.int_info", /* name */
int_info__doc__, /* doc */
int_info_fields, /* fields */
2 /* number of fields */
};
PyObject *
PyLong_GetInfo(void)
{
PyObject* int_info;
int field = 0;
int_info = PyStructSequence_New(&Int_InfoType);
if (int_info == NULL)
return NULL;
PyStructSequence_SET_ITEM(int_info, field++,
PyLong_FromLong(PyLong_SHIFT));
PyStructSequence_SET_ITEM(int_info, field++,
PyLong_FromLong(sizeof(digit)));
if (PyErr_Occurred()) {
Py_CLEAR(int_info);
return NULL;
}
return int_info;
}
int
_PyLong_Init(PyThreadState *tstate)
{
#if NSMALLNEGINTS + NSMALLPOSINTS > 0
for (Py_ssize_t i=0; i < NSMALLNEGINTS + NSMALLPOSINTS; i++) {
sdigit ival = (sdigit)i - NSMALLNEGINTS;
int size = (ival < 0) ? -1 : ((ival == 0) ? 0 : 1);
PyLongObject *v = _PyLong_New(1);
if (!v) {
return -1;
}
Py_SET_SIZE(v, size);
v->ob_digit[0] = (digit)abs(ival);
tstate->interp->small_ints[i] = v;
}
#endif
if (_Py_IsMainInterpreter(tstate)) {
_PyLong_Zero = PyLong_FromLong(0);
if (_PyLong_Zero == NULL) {
return 0;
}
_PyLong_One = PyLong_FromLong(1);
if (_PyLong_One == NULL) {
return 0;
}
/* initialize int_info */
if (Int_InfoType.tp_name == NULL) {
if (PyStructSequence_InitType2(&Int_InfoType, &int_info_desc) < 0) {
return 0;
}
}
}
return 1;
}
void
_PyLong_Fini(PyThreadState *tstate)
{
if (_Py_IsMainInterpreter(tstate)) {
Py_CLEAR(_PyLong_One);
Py_CLEAR(_PyLong_Zero);
}
#if NSMALLNEGINTS + NSMALLPOSINTS > 0
for (Py_ssize_t i = 0; i < NSMALLNEGINTS + NSMALLPOSINTS; i++) {
Py_CLEAR(tstate->interp->small_ints[i]);
}
#endif
}
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