cpython/Include/internal/pycore_long.h

354 lines
12 KiB
C

#ifndef Py_INTERNAL_LONG_H
#define Py_INTERNAL_LONG_H
#ifdef __cplusplus
extern "C" {
#endif
#ifndef Py_BUILD_CORE
# error "this header requires Py_BUILD_CORE define"
#endif
#include "pycore_bytesobject.h" // _PyBytesWriter
#include "pycore_global_objects.h"// _PY_NSMALLNEGINTS
#include "pycore_runtime.h" // _PyRuntime
/*
* Default int base conversion size limitation: Denial of Service prevention.
*
* Chosen such that this isn't wildly slow on modern hardware and so that
* everyone's existing deployed numpy test suite passes before
* https://github.com/numpy/numpy/issues/22098 is widely available.
*
* $ python -m timeit -s 's = "1"*4300' 'int(s)'
* 2000 loops, best of 5: 125 usec per loop
* $ python -m timeit -s 's = "1"*4300; v = int(s)' 'str(v)'
* 1000 loops, best of 5: 311 usec per loop
* (zen2 cloud VM)
*
* 4300 decimal digits fits a ~14284 bit number.
*/
#define _PY_LONG_DEFAULT_MAX_STR_DIGITS 4300
/*
* Threshold for max digits check. For performance reasons int() and
* int.__str__() don't checks values that are smaller than this
* threshold. Acts as a guaranteed minimum size limit for bignums that
* applications can expect from CPython.
*
* % python -m timeit -s 's = "1"*640; v = int(s)' 'str(int(s))'
* 20000 loops, best of 5: 12 usec per loop
*
* "640 digits should be enough for anyone." - gps
* fits a ~2126 bit decimal number.
*/
#define _PY_LONG_MAX_STR_DIGITS_THRESHOLD 640
#if ((_PY_LONG_DEFAULT_MAX_STR_DIGITS != 0) && \
(_PY_LONG_DEFAULT_MAX_STR_DIGITS < _PY_LONG_MAX_STR_DIGITS_THRESHOLD))
# error "_PY_LONG_DEFAULT_MAX_STR_DIGITS smaller than threshold."
#endif
/* runtime lifecycle */
extern PyStatus _PyLong_InitTypes(PyInterpreterState *);
extern void _PyLong_FiniTypes(PyInterpreterState *interp);
/* other API */
#define _PyLong_SMALL_INTS _Py_SINGLETON(small_ints)
// _PyLong_GetZero() and _PyLong_GetOne() must always be available
// _PyLong_FromUnsignedChar must always be available
#if _PY_NSMALLPOSINTS < 257
# error "_PY_NSMALLPOSINTS must be greater than or equal to 257"
#endif
// Return a reference to the immortal zero singleton.
// The function cannot return NULL.
static inline PyObject* _PyLong_GetZero(void)
{ return (PyObject *)&_PyLong_SMALL_INTS[_PY_NSMALLNEGINTS]; }
// Return a reference to the immortal one singleton.
// The function cannot return NULL.
static inline PyObject* _PyLong_GetOne(void)
{ return (PyObject *)&_PyLong_SMALL_INTS[_PY_NSMALLNEGINTS+1]; }
static inline PyObject* _PyLong_FromUnsignedChar(unsigned char i)
{
return (PyObject *)&_PyLong_SMALL_INTS[_PY_NSMALLNEGINTS+i];
}
// _PyLong_Frexp returns a double x and an exponent e such that the
// true value is approximately equal to x * 2**e. e is >= 0. x is
// 0.0 if and only if the input is 0 (in which case, e and x are both
// zeroes); otherwise, 0.5 <= abs(x) < 1.0. On overflow, which is
// possible if the number of bits doesn't fit into a Py_ssize_t, sets
// OverflowError and returns -1.0 for x, 0 for e.
//
// Export for 'math' shared extension
PyAPI_DATA(double) _PyLong_Frexp(PyLongObject *a, Py_ssize_t *e);
extern PyObject* _PyLong_FromBytes(const char *, Py_ssize_t, int);
// _PyLong_DivmodNear. Given integers a and b, compute the nearest
// integer q to the exact quotient a / b, rounding to the nearest even integer
// in the case of a tie. Return (q, r), where r = a - q*b. The remainder r
// will satisfy abs(r) <= abs(b)/2, with equality possible only if q is
// even.
//
// Export for '_datetime' shared extension.
PyAPI_DATA(PyObject*) _PyLong_DivmodNear(PyObject *, PyObject *);
// _PyLong_FromByteArray: View the n unsigned bytes as a binary integer in
// base 256, and return a Python int with the same numeric value.
// If n is 0, the integer is 0. Else:
// If little_endian is 1/true, bytes[n-1] is the MSB and bytes[0] the LSB;
// else (little_endian is 0/false) bytes[0] is the MSB and bytes[n-1] the
// LSB.
// If is_signed is 0/false, view the bytes as a non-negative integer.
// If is_signed is 1/true, view the bytes as a 2's-complement integer,
// non-negative if bit 0x80 of the MSB is clear, negative if set.
// Error returns:
// + Return NULL with the appropriate exception set if there's not
// enough memory to create the Python int.
//
// Export for '_multibytecodec' shared extension.
PyAPI_DATA(PyObject*) _PyLong_FromByteArray(
const unsigned char* bytes, size_t n,
int little_endian, int is_signed);
// _PyLong_AsByteArray: Convert the least-significant 8*n bits of long
// v to a base-256 integer, stored in array bytes. Normally return 0,
// return -1 on error.
// If little_endian is 1/true, store the MSB at bytes[n-1] and the LSB at
// bytes[0]; else (little_endian is 0/false) store the MSB at bytes[0] and
// the LSB at bytes[n-1].
// If is_signed is 0/false, it's an error if v < 0; else (v >= 0) n bytes
// are filled and there's nothing special about bit 0x80 of the MSB.
// If is_signed is 1/true, bytes is filled with the 2's-complement
// representation of v's value. Bit 0x80 of the MSB is the sign bit.
// Error returns (-1):
// + is_signed is 0 and v < 0. TypeError is set in this case, and bytes
// isn't altered.
// + n isn't big enough to hold the full mathematical value of v. For
// example, if is_signed is 0 and there are more digits in the v than
// fit in n; or if is_signed is 1, v < 0, and n is just 1 bit shy of
// being large enough to hold a sign bit. OverflowError is set in this
// case, but bytes holds the least-significant n bytes of the true value.
//
// Export for '_struct' shared extension.
PyAPI_DATA(int) _PyLong_AsByteArray(PyLongObject* v,
unsigned char* bytes, size_t n,
int little_endian, int is_signed);
// _PyLong_Format: Convert the long to a string object with given base,
// appending a base prefix of 0[box] if base is 2, 8 or 16.
// Export for '_tkinter' shared extension.
PyAPI_DATA(PyObject*) _PyLong_Format(PyObject *obj, int base);
// For use by the math.gcd() function.
// Export for 'math' shared extension.
PyAPI_DATA(PyObject*) _PyLong_GCD(PyObject *, PyObject *);
// Export for 'math' shared extension
PyAPI_DATA(PyObject*) _PyLong_Rshift(PyObject *, size_t);
// Export for 'math' shared extension
PyAPI_DATA(PyObject*) _PyLong_Lshift(PyObject *, size_t);
extern PyObject* _PyLong_Add(PyLongObject *left, PyLongObject *right);
extern PyObject* _PyLong_Multiply(PyLongObject *left, PyLongObject *right);
extern PyObject* _PyLong_Subtract(PyLongObject *left, PyLongObject *right);
// Export for 'binascii' shared extension.
PyAPI_DATA(unsigned char) _PyLong_DigitValue[256];
/* Format the object based on the format_spec, as defined in PEP 3101
(Advanced String Formatting). */
extern int _PyLong_FormatAdvancedWriter(
_PyUnicodeWriter *writer,
PyObject *obj,
PyObject *format_spec,
Py_ssize_t start,
Py_ssize_t end);
extern int _PyLong_FormatWriter(
_PyUnicodeWriter *writer,
PyObject *obj,
int base,
int alternate);
extern char* _PyLong_FormatBytesWriter(
_PyBytesWriter *writer,
char *str,
PyObject *obj,
int base,
int alternate);
// Argument converters used by Argument Clinic
// Export for 'select' shared extension (Argument Clinic code)
PyAPI_FUNC(int) _PyLong_UnsignedShort_Converter(PyObject *, void *);
// Export for '_testclinic' shared extension (Argument Clinic code)
PyAPI_FUNC(int) _PyLong_UnsignedInt_Converter(PyObject *, void *);
// Export for '_blake2' shared extension (Argument Clinic code)
PyAPI_FUNC(int) _PyLong_UnsignedLong_Converter(PyObject *, void *);
// Export for '_blake2' shared extension (Argument Clinic code)
PyAPI_FUNC(int) _PyLong_UnsignedLongLong_Converter(PyObject *, void *);
// Export for '_testclinic' shared extension (Argument Clinic code)
PyAPI_FUNC(int) _PyLong_Size_t_Converter(PyObject *, void *);
/* Long value tag bits:
* 0-1: Sign bits value = (1-sign), ie. negative=2, positive=0, zero=1.
* 2: Reserved for immortality bit
* 3+ Unsigned digit count
*/
#define SIGN_MASK 3
#define SIGN_ZERO 1
#define SIGN_NEGATIVE 2
#define NON_SIZE_BITS 3
/* The functions _PyLong_IsCompact and _PyLong_CompactValue are defined
* in Include/cpython/longobject.h, since they need to be inline.
*
* "Compact" values have at least one bit to spare,
* so that addition and subtraction can be performed on the values
* without risk of overflow.
*
* The inline functions need tag bits.
* For readability, rather than do `#define SIGN_MASK _PyLong_SIGN_MASK`
* we define them to the numbers in both places and then assert that
* they're the same.
*/
static_assert(SIGN_MASK == _PyLong_SIGN_MASK, "SIGN_MASK does not match _PyLong_SIGN_MASK");
static_assert(NON_SIZE_BITS == _PyLong_NON_SIZE_BITS, "NON_SIZE_BITS does not match _PyLong_NON_SIZE_BITS");
/* All *compact" values are guaranteed to fit into
* a Py_ssize_t with at least one bit to spare.
* In other words, for 64 bit machines, compact
* will be signed 63 (or fewer) bit values
*/
/* Return 1 if the argument is compact int */
static inline int
_PyLong_IsNonNegativeCompact(const PyLongObject* op) {
assert(PyLong_Check(op));
return op->long_value.lv_tag <= (1 << NON_SIZE_BITS);
}
static inline int
_PyLong_BothAreCompact(const PyLongObject* a, const PyLongObject* b) {
assert(PyLong_Check(a));
assert(PyLong_Check(b));
return (a->long_value.lv_tag | b->long_value.lv_tag) < (2 << NON_SIZE_BITS);
}
static inline bool
_PyLong_IsZero(const PyLongObject *op)
{
return (op->long_value.lv_tag & SIGN_MASK) == SIGN_ZERO;
}
static inline bool
_PyLong_IsNegative(const PyLongObject *op)
{
return (op->long_value.lv_tag & SIGN_MASK) == SIGN_NEGATIVE;
}
static inline bool
_PyLong_IsPositive(const PyLongObject *op)
{
return (op->long_value.lv_tag & SIGN_MASK) == 0;
}
static inline Py_ssize_t
_PyLong_DigitCount(const PyLongObject *op)
{
assert(PyLong_Check(op));
return op->long_value.lv_tag >> NON_SIZE_BITS;
}
/* Equivalent to _PyLong_DigitCount(op) * _PyLong_NonCompactSign(op) */
static inline Py_ssize_t
_PyLong_SignedDigitCount(const PyLongObject *op)
{
assert(PyLong_Check(op));
Py_ssize_t sign = 1 - (op->long_value.lv_tag & SIGN_MASK);
return sign * (Py_ssize_t)(op->long_value.lv_tag >> NON_SIZE_BITS);
}
static inline int
_PyLong_CompactSign(const PyLongObject *op)
{
assert(PyLong_Check(op));
assert(_PyLong_IsCompact(op));
return 1 - (op->long_value.lv_tag & SIGN_MASK);
}
static inline int
_PyLong_NonCompactSign(const PyLongObject *op)
{
assert(PyLong_Check(op));
assert(!_PyLong_IsCompact(op));
return 1 - (op->long_value.lv_tag & SIGN_MASK);
}
/* Do a and b have the same sign? */
static inline int
_PyLong_SameSign(const PyLongObject *a, const PyLongObject *b)
{
return (a->long_value.lv_tag & SIGN_MASK) == (b->long_value.lv_tag & SIGN_MASK);
}
#define TAG_FROM_SIGN_AND_SIZE(sign, size) ((1 - (sign)) | ((size) << NON_SIZE_BITS))
static inline void
_PyLong_SetSignAndDigitCount(PyLongObject *op, int sign, Py_ssize_t size)
{
assert(size >= 0);
assert(-1 <= sign && sign <= 1);
assert(sign != 0 || size == 0);
op->long_value.lv_tag = TAG_FROM_SIGN_AND_SIZE(sign, (size_t)size);
}
static inline void
_PyLong_SetDigitCount(PyLongObject *op, Py_ssize_t size)
{
assert(size >= 0);
op->long_value.lv_tag = (((size_t)size) << NON_SIZE_BITS) | (op->long_value.lv_tag & SIGN_MASK);
}
#define NON_SIZE_MASK ~((1 << NON_SIZE_BITS) - 1)
static inline void
_PyLong_FlipSign(PyLongObject *op) {
unsigned int flipped_sign = 2 - (op->long_value.lv_tag & SIGN_MASK);
op->long_value.lv_tag &= NON_SIZE_MASK;
op->long_value.lv_tag |= flipped_sign;
}
#define _PyLong_DIGIT_INIT(val) \
{ \
.ob_base = _PyObject_HEAD_INIT(&PyLong_Type) \
.long_value = { \
.lv_tag = TAG_FROM_SIGN_AND_SIZE( \
(val) == 0 ? 0 : ((val) < 0 ? -1 : 1), \
(val) == 0 ? 0 : 1), \
{ ((val) >= 0 ? (val) : -(val)) }, \
} \
}
#define _PyLong_FALSE_TAG TAG_FROM_SIGN_AND_SIZE(0, 0)
#define _PyLong_TRUE_TAG TAG_FROM_SIGN_AND_SIZE(1, 1)
#ifdef __cplusplus
}
#endif
#endif /* !Py_INTERNAL_LONG_H */