Issue #1580: use short float repr where possible.

- incorporate and adapt David Gay's dtoa and strtod
   into the Python core
 - on platforms where we can use Gay's code (almost
   all!), repr(float) is based on the shortest
   sequence of decimal digits that rounds correctly.
 - add sys.float_repr_style attribute to indicate
   whether we're using Gay's code or not
 - add autoconf magic to detect and enable SSE2
   instructions on x86/gcc
 - slight change to repr and str:  repr switches
   to exponential notation at 1e16 instead of
   1e17, str switches at 1e11 instead of 1e12
This commit is contained in:
Mark Dickinson 2009-04-16 19:52:09 +00:00
parent 579b65c2d6
commit b08a53a99d
19 changed files with 3866 additions and 19 deletions

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@ -266,6 +266,19 @@ always available.
The information in the table is simplified.
.. data:: float_repr_style
A string indicating how the :func:`repr` function behaves for
floats. If the string has value ``'short'`` then for a finite
float ``x``, ``repr(x)`` aims to produce a short string with the
property that ``float(repr(x)) == x``. This is the usual behaviour
in Python 3.1 and later. Otherwise, ``float_repr_style`` has value
``'legacy'`` and ``repr(x)`` behaves in the same way as it did in
versions of Python prior to 3.1.
.. versionadded:: 3.1
.. function:: getcheckinterval()
Return the interpreter's "check interval"; see :func:`setcheckinterval`.

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@ -657,3 +657,35 @@ The :mod:`select` and contains the following notice for the kqueue interface::
LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
SUCH DAMAGE.
strtod and dtoa
---------------
The file :file:`Python/dtoa.c`, which supplies C functions dtoa and
strtod for conversion of C doubles to and from strings, is derived
from the file of the same name by David M. Gay, currently available
from http://www.netlib.org/fp/. The original file, as retrieved on
March 16, 2009, contains the following copyright and licensing
notice::
/****************************************************************
*
* The author of this software is David M. Gay.
*
* Copyright (c) 1991, 2000, 2001 by Lucent Technologies.
*
* Permission to use, copy, modify, and distribute this software for any
* purpose without fee is hereby granted, provided that this entire notice
* is included in all copies of any software which is or includes a copy
* or modification of this software and in all copies of the supporting
* documentation for such software.
*
* THIS SOFTWARE IS BEING PROVIDED "AS IS", WITHOUT ANY EXPRESS OR IMPLIED
* WARRANTY. IN PARTICULAR, NEITHER THE AUTHOR NOR LUCENT MAKES ANY
* REPRESENTATION OR WARRANTY OF ANY KIND CONCERNING THE MERCHANTABILITY
* OF THIS SOFTWARE OR ITS FITNESS FOR ANY PARTICULAR PURPOSE.
*
***************************************************************/

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@ -118,6 +118,7 @@
#include "pystrtod.h"
#include "pystrcmp.h"
#include "dtoa.h"
/* _Py_Mangle is defined in compile.c */
PyAPI_FUNC(PyObject*) _Py_Mangle(PyObject *p, PyObject *name);

15
Include/dtoa.h Normal file
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@ -0,0 +1,15 @@
#ifndef PY_NO_SHORT_FLOAT_REPR
#ifdef __cplusplus
extern "C" {
#endif
PyAPI_FUNC(double) _Py_dg_strtod(const char *str, char **ptr);
PyAPI_FUNC(char *) _Py_dg_dtoa(double d, int mode, int ndigits,
int *decpt, int *sign, char **rve);
PyAPI_FUNC(void) _Py_dg_freedtoa(char *s);
#ifdef __cplusplus
}
#endif
#endif

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@ -17,6 +17,9 @@
# undef SIZEOF_VOID_P
# undef SIZEOF__BOOL
# undef WORDS_BIGENDIAN
# undef DOUBLE_IS_ARM_MIXED_ENDIAN_IEEE754
# undef DOUBLE_IS_BIG_ENDIAN_IEEE754
# undef DOUBLE_IS_LITTLE_ENDIAN_IEEE754
# undef VA_LIST_IS_ARRAY
# if defined(__LP64__) && defined(__x86_64__)
@ -65,6 +68,9 @@
#ifdef __BIG_ENDIAN__
#define WORDS_BIGENDIAN 1
#define DOUBLE_IS_BIG_ENDIAN_IEEE754
#else
#define DOUBLE_IS_LITTLE_ENDIAN_IEEE754
#endif /* __BIG_ENDIAN */

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@ -92,6 +92,11 @@ PyAPI_FUNC(double) _Py_force_double(double);
# endif
#endif
#ifdef HAVE_GCC_ASM_FOR_X87
PyAPI_FUNC(unsigned short) _Py_get_387controlword(void);
PyAPI_FUNC(void) _Py_set_387controlword(unsigned short);
#endif
/* Py_IS_NAN(X)
* Return 1 if float or double arg is a NaN, else 0.
* Caution:

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@ -465,6 +465,53 @@ extern "C" {
errno = 0; \
} while(0)
/* The functions _Py_dg_strtod and _Py_dg_dtoa in Python/dtoa.c require that
the FPU is using 53-bit precision. Here are macros that force this. See
Python/pystrtod.c for an example of their use. */
#ifdef USING_X87_FPU
#define _Py_SET_53BIT_PRECISION_HEADER \
unsigned short old_387controlword, new_387controlword
#define _Py_SET_53BIT_PRECISION_START \
do { \
old_387controlword = _Py_get_387controlword(); \
new_387controlword = (old_387controlword & ~0x0f00) | 0x0200; \
if (new_387controlword != old_387controlword) \
_Py_set_387controlword(new_387controlword); \
} while (0)
#define _Py_SET_53BIT_PRECISION_END \
if (new_387controlword != old_387controlword) \
_Py_set_387controlword(old_387controlword)
#else
#define _Py_SET_53BIT_PRECISION_HEADER
#define _Py_SET_53BIT_PRECISION_START
#define _Py_SET_53BIT_PRECISION_END
#endif
/* If we can't guarantee 53-bit precision, don't use the code
in Python/dtoa.c, but fall back to standard code. This
means that repr of a float will be long (17 sig digits).
Realistically, there are two things that could go wrong:
(1) doubles aren't IEEE 754 doubles, or
(2) we're on x86 with the rounding precision set to 64-bits
(extended precision), and we don't know how to change
the rounding precision.
*/
#if !defined(DOUBLE_IS_LITTLE_ENDIAN_IEEE754) && \
!defined(DOUBLE_IS_BIG_ENDIAN_IEEE754) && \
!defined(DOUBLE_IS_ARM_MIXED_ENDIAN_IEEE754)
#define PY_NO_SHORT_FLOAT_REPR
#endif
/* double rounding is symptomatic of use of extended precision on x86 */
#ifdef X87_DOUBLE_ROUNDING
#define PY_NO_SHORT_FLOAT_REPR
#endif
/* Py_DEPRECATED(version)
* Declare a variable, type, or function deprecated.
* Usage:

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@ -0,0 +1,354 @@
-- 'f' code formatting, with explicit precision (>= 0). Output always
-- has the given number of places after the point; zeros are added if
-- necessary to make this true.
-- zeros
%.0f 0 -> 0
%.1f 0 -> 0.0
%.2f 0 -> 0.00
%.3f 0 -> 0.000
%.50f 0 -> 0.00000000000000000000000000000000000000000000000000
-- precision 0; result should never include a .
%.0f 1.5 -> 2
%.0f 2.5 -> 2
%.0f 3.5 -> 4
%.0f 0.0 -> 0
%.0f 0.1 -> 0
%.0f 0.001 -> 0
%.0f 10.0 -> 10
%.0f 10.1 -> 10
%.0f 10.01 -> 10
%.0f 123.456 -> 123
%.0f 1234.56 -> 1235
%.0f 1e49 -> 9999999999999999464902769475481793196872414789632
-- %.0f 1e50 -> 100000000000000007629769841091887003294964970946560
%.0f 9.9999999999999987e+49 -> 99999999999999986860582406952576489172979654066176
-- precision 1
%.1f 0.0001 -> 0.0
%.1f 0.001 -> 0.0
%.1f 0.01 -> 0.0
%.1f 0.04 -> 0.0
%.1f 0.06 -> 0.1
%.1f 0.25 -> 0.2
%.1f 0.75 -> 0.8
%.1f 1.4 -> 1.4
%.1f 1.5 -> 1.5
%.1f 10.0 -> 10.0
%.1f 1000.03 -> 1000.0
%.1f 1234.5678 -> 1234.6
%.1f 1234.7499 -> 1234.7
%.1f 1234.75 -> 1234.8
-- precision 2
%.2f 0.0001 -> 0.00
%.2f 0.001 -> 0.00
%.2f 0.004999 -> 0.00
%.2f 0.005001 -> 0.01
%.2f 0.01 -> 0.01
%.2f 0.125 -> 0.12
%.2f 0.375 -> 0.38
%.2f 1234500 -> 1234500.00
%.2f 1234560 -> 1234560.00
%.2f 1234567 -> 1234567.00
%.2f 1234567.8 -> 1234567.80
%.2f 1234567.89 -> 1234567.89
%.2f 1234567.891 -> 1234567.89
%.2f 1234567.8912 -> 1234567.89
-- alternate form always includes a decimal point. This only
-- makes a difference when the precision is 0.
%#.0f 0 -> 0.
%#.1f 0 -> 0.0
%#.0f 1.5 -> 2.
%#.0f 2.5 -> 2.
%#.0f 10.1 -> 10.
%#.0f 1234.56 -> 1235.
%#.1f 1.4 -> 1.4
%#.2f 0.375 -> 0.38
-- if precision is omitted it defaults to 6
%f 0 -> 0.000000
%f 1230000 -> 1230000.000000
%f 1234567 -> 1234567.000000
%f 123.4567 -> 123.456700
%f 1.23456789 -> 1.234568
%f 0.00012 -> 0.000120
%f 0.000123 -> 0.000123
%f 0.00012345 -> 0.000123
%f 0.000001 -> 0.000001
%f 0.0000005001 -> 0.000001
%f 0.0000004999 -> 0.000000
-- 'e' code formatting with explicit precision (>= 0). Output should
-- always have exactly the number of places after the point that were
-- requested.
-- zeros
%.0e 0 -> 0e+00
%.1e 0 -> 0.0e+00
%.2e 0 -> 0.00e+00
%.10e 0 -> 0.0000000000e+00
%.50e 0 -> 0.00000000000000000000000000000000000000000000000000e+00
-- precision 0. no decimal point in the output
%.0e 0.01 -> 1e-02
%.0e 0.1 -> 1e-01
%.0e 1 -> 1e+00
%.0e 10 -> 1e+01
%.0e 100 -> 1e+02
%.0e 0.012 -> 1e-02
%.0e 0.12 -> 1e-01
%.0e 1.2 -> 1e+00
%.0e 12 -> 1e+01
%.0e 120 -> 1e+02
%.0e 123.456 -> 1e+02
%.0e 0.000123456 -> 1e-04
%.0e 123456000 -> 1e+08
%.0e 0.5 -> 5e-01
%.0e 1.4 -> 1e+00
%.0e 1.5 -> 2e+00
%.0e 1.6 -> 2e+00
%.0e 2.4999999 -> 2e+00
%.0e 2.5 -> 2e+00
%.0e 2.5000001 -> 3e+00
%.0e 3.499999999999 -> 3e+00
%.0e 3.5 -> 4e+00
%.0e 4.5 -> 4e+00
%.0e 5.5 -> 6e+00
%.0e 6.5 -> 6e+00
%.0e 7.5 -> 8e+00
%.0e 8.5 -> 8e+00
%.0e 9.4999 -> 9e+00
%.0e 9.5 -> 1e+01
%.0e 10.5 -> 1e+01
%.0e 14.999 -> 1e+01
%.0e 15 -> 2e+01
-- precision 1
%.1e 0.0001 -> 1.0e-04
%.1e 0.001 -> 1.0e-03
%.1e 0.01 -> 1.0e-02
%.1e 0.1 -> 1.0e-01
%.1e 1 -> 1.0e+00
%.1e 10 -> 1.0e+01
%.1e 100 -> 1.0e+02
%.1e 120 -> 1.2e+02
%.1e 123 -> 1.2e+02
%.1e 123.4 -> 1.2e+02
-- precision 2
%.2e 0.00013 -> 1.30e-04
%.2e 0.000135 -> 1.35e-04
%.2e 0.0001357 -> 1.36e-04
%.2e 0.0001 -> 1.00e-04
%.2e 0.001 -> 1.00e-03
%.2e 0.01 -> 1.00e-02
%.2e 0.1 -> 1.00e-01
%.2e 1 -> 1.00e+00
%.2e 10 -> 1.00e+01
%.2e 100 -> 1.00e+02
%.2e 1000 -> 1.00e+03
%.2e 1500 -> 1.50e+03
%.2e 1590 -> 1.59e+03
%.2e 1598 -> 1.60e+03
%.2e 1598.7 -> 1.60e+03
%.2e 1598.76 -> 1.60e+03
%.2e 9999 -> 1.00e+04
-- omitted precision defaults to 6
%e 0 -> 0.000000e+00
%e 165 -> 1.650000e+02
%e 1234567 -> 1.234567e+06
%e 12345678 -> 1.234568e+07
%e 1.1 -> 1.100000e+00
-- alternate form always contains a decimal point. This only makes
-- a difference when precision is 0.
%#.0e 0.01 -> 1.e-02
%#.0e 0.1 -> 1.e-01
%#.0e 1 -> 1.e+00
%#.0e 10 -> 1.e+01
%#.0e 100 -> 1.e+02
%#.0e 0.012 -> 1.e-02
%#.0e 0.12 -> 1.e-01
%#.0e 1.2 -> 1.e+00
%#.0e 12 -> 1.e+01
%#.0e 120 -> 1.e+02
%#.0e 123.456 -> 1.e+02
%#.0e 0.000123456 -> 1.e-04
%#.0e 123456000 -> 1.e+08
%#.0e 0.5 -> 5.e-01
%#.0e 1.4 -> 1.e+00
%#.0e 1.5 -> 2.e+00
%#.0e 1.6 -> 2.e+00
%#.0e 2.4999999 -> 2.e+00
%#.0e 2.5 -> 2.e+00
%#.0e 2.5000001 -> 3.e+00
%#.0e 3.499999999999 -> 3.e+00
%#.0e 3.5 -> 4.e+00
%#.0e 4.5 -> 4.e+00
%#.0e 5.5 -> 6.e+00
%#.0e 6.5 -> 6.e+00
%#.0e 7.5 -> 8.e+00
%#.0e 8.5 -> 8.e+00
%#.0e 9.4999 -> 9.e+00
%#.0e 9.5 -> 1.e+01
%#.0e 10.5 -> 1.e+01
%#.0e 14.999 -> 1.e+01
%#.0e 15 -> 2.e+01
%#.1e 123.4 -> 1.2e+02
%#.2e 0.0001357 -> 1.36e-04
-- 'g' code formatting.
-- zeros
%.0g 0 -> 0
%.1g 0 -> 0
%.2g 0 -> 0
%.3g 0 -> 0
%.4g 0 -> 0
%.10g 0 -> 0
%.50g 0 -> 0
%.100g 0 -> 0
-- precision 0 doesn't make a lot of sense for the 'g' code (what does
-- it mean to have no significant digits?); in practice, it's interpreted
-- as identical to precision 1
%.0g 1000 -> 1e+03
%.0g 100 -> 1e+02
%.0g 10 -> 1e+01
%.0g 1 -> 1
%.0g 0.1 -> 0.1
%.0g 0.01 -> 0.01
%.0g 1e-3 -> 0.001
%.0g 1e-4 -> 0.0001
%.0g 1e-5 -> 1e-05
%.0g 1e-6 -> 1e-06
%.0g 12 -> 1e+01
%.0g 120 -> 1e+02
%.0g 1.2 -> 1
%.0g 0.12 -> 0.1
%.0g 0.012 -> 0.01
%.0g 0.0012 -> 0.001
%.0g 0.00012 -> 0.0001
%.0g 0.000012 -> 1e-05
%.0g 0.0000012 -> 1e-06
-- precision 1 identical to precision 0
%.1g 1000 -> 1e+03
%.1g 100 -> 1e+02
%.1g 10 -> 1e+01
%.1g 1 -> 1
%.1g 0.1 -> 0.1
%.1g 0.01 -> 0.01
%.1g 1e-3 -> 0.001
%.1g 1e-4 -> 0.0001
%.1g 1e-5 -> 1e-05
%.1g 1e-6 -> 1e-06
%.1g 12 -> 1e+01
%.1g 120 -> 1e+02
%.1g 1.2 -> 1
%.1g 0.12 -> 0.1
%.1g 0.012 -> 0.01
%.1g 0.0012 -> 0.001
%.1g 0.00012 -> 0.0001
%.1g 0.000012 -> 1e-05
%.1g 0.0000012 -> 1e-06
-- precision 2
%.2g 1000 -> 1e+03
%.2g 100 -> 1e+02
%.2g 10 -> 10
%.2g 1 -> 1
%.2g 0.1 -> 0.1
%.2g 0.01 -> 0.01
%.2g 0.001 -> 0.001
%.2g 1e-4 -> 0.0001
%.2g 1e-5 -> 1e-05
%.2g 1e-6 -> 1e-06
%.2g 1234 -> 1.2e+03
%.2g 123 -> 1.2e+02
%.2g 12.3 -> 12
%.2g 1.23 -> 1.2
%.2g 0.123 -> 0.12
%.2g 0.0123 -> 0.012
%.2g 0.00123 -> 0.0012
%.2g 0.000123 -> 0.00012
%.2g 0.0000123 -> 1.2e-05
-- alternate g formatting: always include decimal point and
-- exactly <precision> significant digits.
%#.0g 0 -> 0.
%#.1g 0 -> 0.
%#.2g 0 -> 0.0
%#.3g 0 -> 0.00
%#.4g 0 -> 0.000
%#.0g 0.2 -> 0.2
%#.1g 0.2 -> 0.2
%#.2g 0.2 -> 0.20
%#.3g 0.2 -> 0.200
%#.4g 0.2 -> 0.2000
%#.10g 0.2 -> 0.2000000000
%#.0g 2 -> 2.
%#.1g 2 -> 2.
%#.2g 2 -> 2.0
%#.3g 2 -> 2.00
%#.4g 2 -> 2.000
%#.0g 20 -> 2.e+01
%#.1g 20 -> 2.e+01
%#.2g 20 -> 20.
%#.3g 20 -> 20.0
%#.4g 20 -> 20.00
%#.0g 234.56 -> 2.e+02
%#.1g 234.56 -> 2.e+02
%#.2g 234.56 -> 2.3e+02
%#.3g 234.56 -> 235.
%#.4g 234.56 -> 234.6
%#.5g 234.56 -> 234.56
%#.6g 234.56 -> 234.560
-- for repr formatting see the separate test_short_repr test in
-- test_float.py. Not all platforms use short repr for floats.
-- str formatting. Result always includes decimal point and at
-- least one digit after the point, or an exponent.
%s 0 -> 0.0
%s 1 -> 1.0
%s 0.01 -> 0.01
%s 0.02 -> 0.02
%s 0.03 -> 0.03
%s 0.04 -> 0.04
%s 0.05 -> 0.05
-- str truncates to 12 significant digits
%s 1.234123412341 -> 1.23412341234
%s 1.23412341234 -> 1.23412341234
%s 1.2341234123 -> 1.2341234123
-- values >= 1e11 get an exponent
%s 10 -> 10.0
%s 100 -> 100.0
%s 1e10 -> 10000000000.0
%s 9.999e10 -> 99990000000.0
%s 99999999999 -> 99999999999.0
%s 1e11 -> 1e+11
%s 1e12 -> 1e+12
-- as do values < 1e-4
%s 1e-3 -> 0.001
%s 1.001e-4 -> 0.0001001
%s 1.000000000001e-4 -> 0.0001
%s 1.00000000001e-4 -> 0.000100000000001
%s 1.0000000001e-4 -> 0.00010000000001
%s 1e-4 -> 0.0001
%s 0.999999999999e-4 -> 9.99999999999e-05
%s 0.999e-4 -> 9.99e-05
%s 1e-5 -> 1e-05

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@ -305,6 +305,7 @@ PYTHON_OBJS= \
Python/getopt.o \
Python/pystrcmp.o \
Python/pystrtod.o \
Python/dtoa.o \
Python/formatter_unicode.o \
Python/$(DYNLOADFILE) \
$(LIBOBJS) \
@ -621,6 +622,7 @@ PYTHON_HEADERS= \
Include/complexobject.h \
Include/descrobject.h \
Include/dictobject.h \
Include/dtoa.h \
Include/enumobject.h \
Include/errcode.h \
Include/eval.h \

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@ -160,6 +160,7 @@ Scott David Daniels
Ben Darnell
Jonathan Dasteel
John DeGood
Ned Deily
Vincent Delft
Arnaud Delobelle
Erik Demaine

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@ -12,6 +12,45 @@ What's New in Python 3.1 beta 1?
Core and Builtins
-----------------
- The repr function switches to exponential notation at 1e16, not 1e17
as it did before. This change applies to both 'short' and legacy
float repr styles. For the new repr style, it avoids misleading
output in some cases: an example is repr(2e16+8), which gives
'2.000000000000001e+16'; without this change it would have produced
'20000000000000010.0' instead.
- Similarly, the str function switches to exponential notation at
1e11, not 1e12. This avoids printing 13 significant digits in
situations where only 12 of them are correct. Example problem
value: str(1e11 + 0.5). (This minor issue has existed in 2.x for a
long time.)
- On x86, SSE2 instructions for floating-point are automatically
detected and, where possible, enabled on platforms using the gcc
compiler. As a consequence, some arithmetic operations may have
different (more accurate!) results on some platforms, and
cross-platform consistency of Python arithmetic should be improved.
This applies particularly to Linux/x86.
- Issue #1580: On most platforms, use a 'short' float repr: for a
finite float x, repr(x) now outputs a string based on the shortest
sequence of decimal digits that rounds to x. Previous behaviour was
to output 17 significant digits and then strip trailing zeros.
There's a new sys attribute sys.float_repr_style, which takes
the value 'short' to indicate that we're using short float repr,
and 'legacy' if the short float repr isn't available for one
reason or another.
The float repr change involves incorporating David Gay's 'perfect
rounding' code into the Python core (it's in Python/dtoa.c). As a
secondary consequence, all string-to-float and float-to-string
conversions (including all float formatting operations) will be
correctly rounded on these platforms.
See issue 1580 discussions for details of platforms for which
this change does not apply.
- Issue #5759: float() didn't call __float__ on str subclasses.
- The string.maketrans() function is deprecated; there is a new static method

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@ -752,4 +752,8 @@ Py_NO_ENABLE_SHARED to find out. Also support MS_NO_COREDLL for b/w compat */
socket handles greater than FD_SETSIZE */
#define Py_SOCKET_FD_CAN_BE_GE_FD_SETSIZE
/* Define if C doubles are 64-bit IEEE 754 binary format, stored with the
least significant byte first */
#define DOUBLE_IS_LITTLE_ENDIAN_IEEE754 1
#endif /* !Py_CONFIG_H */

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@ -894,6 +894,10 @@
RelativePath="..\Include\pystrtod.h"
>
</File>
<File
RelativePath="..\Include\dtoa.h"
>
</File>
<File
RelativePath="..\Include\Python-ast.h"
>
@ -1746,6 +1750,10 @@
RelativePath="..\Python\pystrtod.c"
>
</File>
<File
RelativePath="..\Python\dtoa.c"
>
</File>
<File
RelativePath="..\Python\Python-ast.c"
>

2646
Python/dtoa.c Normal file

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@ -13,6 +13,28 @@ double _Py_force_double(double x)
}
#endif
#ifdef USING_X87_FPU
# ifdef HAVE_GCC_ASM_FOR_X87
/* inline assembly for getting and setting the 387 FPU control word on
gcc/x86 */
unsigned short _Py_get_387controlword(void) {
unsigned short cw;
__asm__ __volatile__ ("fnstcw %0" : "=m" (cw));
return cw;
}
void _Py_set_387controlword(unsigned short cw) {
__asm__ __volatile__ ("fldcw %0" : : "m" (cw));
}
# else
# error "Unable to get and set x87 control word"
# endif
#endif
#ifndef HAVE_HYPOT
double hypot(double x, double y)
{

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@ -1025,6 +1025,7 @@ platform -- platform identifier\n\
executable -- pathname of this Python interpreter\n\
prefix -- prefix used to find the Python library\n\
exec_prefix -- prefix used to find the machine-specific Python library\n\
float_repr_style -- string indicating the style of repr() output for floats\n\
"
)
#ifdef MS_WINDOWS
@ -1428,6 +1429,15 @@ _PySys_Init(void)
FlagsType.tp_init = NULL;
FlagsType.tp_new = NULL;
/* float repr style: 0.03 (short) vs 0.029999999999999999 (legacy) */
#ifndef PY_NO_SHORT_FLOAT_REPR
SET_SYS_FROM_STRING("float_repr_style",
PyUnicode_FromString("short"));
#else
SET_SYS_FROM_STRING("float_repr_style",
PyUnicode_FromString("legacy"));
#endif
#undef SET_SYS_FROM_STRING
if (PyErr_Occurred())
return NULL;

472
configure vendored
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@ -1,5 +1,5 @@
#! /bin/sh
# From configure.in Revision: 71261 .
# From configure.in Revision: 71274 .
# Guess values for system-dependent variables and create Makefiles.
# Generated by GNU Autoconf 2.61 for python 3.1.
#
@ -21603,12 +21603,455 @@ echo "${ECHO_T}default LIBC=\"$LIBC\"" >&6; }
fi
# ************************************
# * Check for mathematical functions *
# ************************************
# **************************************************
# * Check for various properties of floating point *
# **************************************************
LIBS_SAVE=$LIBS
LIBS="$LIBS $LIBM"
{ echo "$as_me:$LINENO: checking whether C doubles are little-endian IEEE 754 binary64" >&5
echo $ECHO_N "checking whether C doubles are little-endian IEEE 754 binary64... $ECHO_C" >&6; }
if test "${ac_cv_little_endian_double+set}" = set; then
echo $ECHO_N "(cached) $ECHO_C" >&6
else
if test "$cross_compiling" = yes; then
ac_cv_little_endian_double=no
else
cat >conftest.$ac_ext <<_ACEOF
/* confdefs.h. */
_ACEOF
cat confdefs.h >>conftest.$ac_ext
cat >>conftest.$ac_ext <<_ACEOF
/* end confdefs.h. */
#include <string.h>
int main() {
double x = 9006104071832581.0;
if (memcmp(&x, "\x05\x04\x03\x02\x01\xff\x3f\x43", 8) == 0)
return 0;
else
return 1;
}
_ACEOF
rm -f conftest$ac_exeext
if { (ac_try="$ac_link"
case "(($ac_try" in
*\"* | *\`* | *\\*) ac_try_echo=\$ac_try;;
*) ac_try_echo=$ac_try;;
esac
eval "echo \"\$as_me:$LINENO: $ac_try_echo\"") >&5
(eval "$ac_link") 2>&5
ac_status=$?
echo "$as_me:$LINENO: \$? = $ac_status" >&5
(exit $ac_status); } && { ac_try='./conftest$ac_exeext'
{ (case "(($ac_try" in
*\"* | *\`* | *\\*) ac_try_echo=\$ac_try;;
*) ac_try_echo=$ac_try;;
esac
eval "echo \"\$as_me:$LINENO: $ac_try_echo\"") >&5
(eval "$ac_try") 2>&5
ac_status=$?
echo "$as_me:$LINENO: \$? = $ac_status" >&5
(exit $ac_status); }; }; then
ac_cv_little_endian_double=yes
else
echo "$as_me: program exited with status $ac_status" >&5
echo "$as_me: failed program was:" >&5
sed 's/^/| /' conftest.$ac_ext >&5
( exit $ac_status )
ac_cv_little_endian_double=no
fi
rm -f core *.core core.conftest.* gmon.out bb.out conftest$ac_exeext conftest.$ac_objext conftest.$ac_ext
fi
fi
{ echo "$as_me:$LINENO: result: $ac_cv_little_endian_double" >&5
echo "${ECHO_T}$ac_cv_little_endian_double" >&6; }
if test "$ac_cv_little_endian_double" = yes
then
cat >>confdefs.h <<\_ACEOF
#define DOUBLE_IS_LITTLE_ENDIAN_IEEE754 1
_ACEOF
fi
{ echo "$as_me:$LINENO: checking whether C doubles are big-endian IEEE 754 binary64" >&5
echo $ECHO_N "checking whether C doubles are big-endian IEEE 754 binary64... $ECHO_C" >&6; }
if test "${ac_cv_big_endian_double+set}" = set; then
echo $ECHO_N "(cached) $ECHO_C" >&6
else
if test "$cross_compiling" = yes; then
ac_cv_big_endian_double=no
else
cat >conftest.$ac_ext <<_ACEOF
/* confdefs.h. */
_ACEOF
cat confdefs.h >>conftest.$ac_ext
cat >>conftest.$ac_ext <<_ACEOF
/* end confdefs.h. */
#include <string.h>
int main() {
double x = 9006104071832581.0;
if (memcmp(&x, "\x43\x3f\xff\x01\x02\x03\x04\x05", 8) == 0)
return 0;
else
return 1;
}
_ACEOF
rm -f conftest$ac_exeext
if { (ac_try="$ac_link"
case "(($ac_try" in
*\"* | *\`* | *\\*) ac_try_echo=\$ac_try;;
*) ac_try_echo=$ac_try;;
esac
eval "echo \"\$as_me:$LINENO: $ac_try_echo\"") >&5
(eval "$ac_link") 2>&5
ac_status=$?
echo "$as_me:$LINENO: \$? = $ac_status" >&5
(exit $ac_status); } && { ac_try='./conftest$ac_exeext'
{ (case "(($ac_try" in
*\"* | *\`* | *\\*) ac_try_echo=\$ac_try;;
*) ac_try_echo=$ac_try;;
esac
eval "echo \"\$as_me:$LINENO: $ac_try_echo\"") >&5
(eval "$ac_try") 2>&5
ac_status=$?
echo "$as_me:$LINENO: \$? = $ac_status" >&5
(exit $ac_status); }; }; then
ac_cv_big_endian_double=yes
else
echo "$as_me: program exited with status $ac_status" >&5
echo "$as_me: failed program was:" >&5
sed 's/^/| /' conftest.$ac_ext >&5
( exit $ac_status )
ac_cv_big_endian_double=no
fi
rm -f core *.core core.conftest.* gmon.out bb.out conftest$ac_exeext conftest.$ac_objext conftest.$ac_ext
fi
fi
{ echo "$as_me:$LINENO: result: $ac_cv_big_endian_double" >&5
echo "${ECHO_T}$ac_cv_big_endian_double" >&6; }
if test "$ac_cv_big_endian_double" = yes
then
cat >>confdefs.h <<\_ACEOF
#define DOUBLE_IS_BIG_ENDIAN_IEEE754 1
_ACEOF
fi
# Some ARM platforms use a mixed-endian representation for doubles.
# While Python doesn't currently have full support for these platforms
# (see e.g., issue 1762561), we can at least make sure that float <-> string
# conversions work.
{ echo "$as_me:$LINENO: checking whether C doubles are ARM mixed-endian IEEE 754 binary64" >&5
echo $ECHO_N "checking whether C doubles are ARM mixed-endian IEEE 754 binary64... $ECHO_C" >&6; }
if test "${ac_cv_mixed_endian_double+set}" = set; then
echo $ECHO_N "(cached) $ECHO_C" >&6
else
if test "$cross_compiling" = yes; then
ac_cv_mixed_endian_double=no
else
cat >conftest.$ac_ext <<_ACEOF
/* confdefs.h. */
_ACEOF
cat confdefs.h >>conftest.$ac_ext
cat >>conftest.$ac_ext <<_ACEOF
/* end confdefs.h. */
#include <string.h>
int main() {
double x = 9006104071832581.0;
if (memcmp(&x, "\x01\xff\x3f\x43\x05\x04\x03\x02", 8) == 0)
return 0;
else
return 1;
}
_ACEOF
rm -f conftest$ac_exeext
if { (ac_try="$ac_link"
case "(($ac_try" in
*\"* | *\`* | *\\*) ac_try_echo=\$ac_try;;
*) ac_try_echo=$ac_try;;
esac
eval "echo \"\$as_me:$LINENO: $ac_try_echo\"") >&5
(eval "$ac_link") 2>&5
ac_status=$?
echo "$as_me:$LINENO: \$? = $ac_status" >&5
(exit $ac_status); } && { ac_try='./conftest$ac_exeext'
{ (case "(($ac_try" in
*\"* | *\`* | *\\*) ac_try_echo=\$ac_try;;
*) ac_try_echo=$ac_try;;
esac
eval "echo \"\$as_me:$LINENO: $ac_try_echo\"") >&5
(eval "$ac_try") 2>&5
ac_status=$?
echo "$as_me:$LINENO: \$? = $ac_status" >&5
(exit $ac_status); }; }; then
ac_cv_mixed_endian_double=yes
else
echo "$as_me: program exited with status $ac_status" >&5
echo "$as_me: failed program was:" >&5
sed 's/^/| /' conftest.$ac_ext >&5
( exit $ac_status )
ac_cv_mixed_endian_double=no
fi
rm -f core *.core core.conftest.* gmon.out bb.out conftest$ac_exeext conftest.$ac_objext conftest.$ac_ext
fi
fi
{ echo "$as_me:$LINENO: result: $ac_cv_mixed_endian_double" >&5
echo "${ECHO_T}$ac_cv_mixed_endian_double" >&6; }
if test "$ac_cv_mixed_endian_double" = yes
then
cat >>confdefs.h <<\_ACEOF
#define DOUBLE_IS_ARM_MIXED_ENDIAN_IEEE754 1
_ACEOF
fi
# David Gay's code in Python/dtoa.c requires that the FPU uses 53-bit
# rounding; this is a particular problem on x86, where the x87 FPU has
# a default rounding precision of 64 bits. For gcc/x86, we try to fix
# this by:
#
# (1) using the SSE2 instruction set when available (it usually is
# on modern machines)
# (2) using inline assembler to get and set the x87 FPU control word
# otherwise.
#
# On AMD64 (aka x86-64), gcc automatically enables use of SSE2
# instructions, so we don't bother trying to detect.
if test "$GCC" = yes && test -n "`$CC -dM -E - </dev/null | grep i386`"
then
# determine whether we're already using the SSE2 instruction set for math
# (e.g., this is true by default on OS X/x86)
{ echo "$as_me:$LINENO: checking whether SSE2 instructions are already enabled for math" >&5
echo $ECHO_N "checking whether SSE2 instructions are already enabled for math... $ECHO_C" >&6; }
if test -n "`$CC -dM -E - </dev/null | grep __SSE2_MATH__`"
then
ac_sse2_enabled=yes
else
ac_sse2_enabled=no
fi
{ echo "$as_me:$LINENO: result: $ac_sse2_enabled" >&5
echo "${ECHO_T}$ac_sse2_enabled" >&6; }
# if we're not using SSE2 already, we need to either enable it
# (when available), or use inline assembler to get and set the
# 387 control word.
if test $ac_sse2_enabled = no
then
# Check cpuid for SSE2 availability. Bits 25 and 26 of edx tell
# us about SSE and SSE2 respectively.
{ echo "$as_me:$LINENO: checking whether SSE2 instructions are available on this CPU" >&5
echo $ECHO_N "checking whether SSE2 instructions are available on this CPU... $ECHO_C" >&6; }
if test "$cross_compiling" = yes; then
ac_cv_cpu_has_sse2=no
else
cat >conftest.$ac_ext <<_ACEOF
/* confdefs.h. */
_ACEOF
cat confdefs.h >>conftest.$ac_ext
cat >>conftest.$ac_ext <<_ACEOF
/* end confdefs.h. */
int main() {
unsigned int ax, bx, cx, dx, func;
func = 1U;
__asm__ __volatile__ (
"pushl %%ebx\n\t" /* don't clobber ebx */
"cpuid\n\t"
"movl %%ebx, %1\n\t"
"popl %%ebx"
: "=a" (ax), "=r" (bx), "=c" (cx), "=d" (dx)
: "a" (func)
: "cc" );
if ((dx & (1U << 25)) && (dx & (1U << 26)))
return 0;
else
return 1;
}
_ACEOF
rm -f conftest$ac_exeext
if { (ac_try="$ac_link"
case "(($ac_try" in
*\"* | *\`* | *\\*) ac_try_echo=\$ac_try;;
*) ac_try_echo=$ac_try;;
esac
eval "echo \"\$as_me:$LINENO: $ac_try_echo\"") >&5
(eval "$ac_link") 2>&5
ac_status=$?
echo "$as_me:$LINENO: \$? = $ac_status" >&5
(exit $ac_status); } && { ac_try='./conftest$ac_exeext'
{ (case "(($ac_try" in
*\"* | *\`* | *\\*) ac_try_echo=\$ac_try;;
*) ac_try_echo=$ac_try;;
esac
eval "echo \"\$as_me:$LINENO: $ac_try_echo\"") >&5
(eval "$ac_try") 2>&5
ac_status=$?
echo "$as_me:$LINENO: \$? = $ac_status" >&5
(exit $ac_status); }; }; then
ac_cv_cpu_has_sse2=yes
else
echo "$as_me: program exited with status $ac_status" >&5
echo "$as_me: failed program was:" >&5
sed 's/^/| /' conftest.$ac_ext >&5
( exit $ac_status )
ac_cv_cpu_has_sse2=no
fi
rm -f core *.core core.conftest.* gmon.out bb.out conftest$ac_exeext conftest.$ac_objext conftest.$ac_ext
fi
{ echo "$as_me:$LINENO: result: $ac_cv_cpu_has_sse2" >&5
echo "${ECHO_T}$ac_cv_cpu_has_sse2" >&6; }
# determine whether gcc accepts options to turn on SSE2
{ echo "$as_me:$LINENO: checking whether $CC accepts -msse2 -mfpmath=sse" >&5
echo $ECHO_N "checking whether $CC accepts -msse2 -mfpmath=sse... $ECHO_C" >&6; }
ac_save_cc="$CC"
CC="$CC -msse2 -mfpmath=sse"
if test "$cross_compiling" = yes; then
ac_cv_msse2_ok=no
else
cat >conftest.$ac_ext <<_ACEOF
/* confdefs.h. */
_ACEOF
cat confdefs.h >>conftest.$ac_ext
cat >>conftest.$ac_ext <<_ACEOF
/* end confdefs.h. */
int main() { return 0; }
_ACEOF
rm -f conftest$ac_exeext
if { (ac_try="$ac_link"
case "(($ac_try" in
*\"* | *\`* | *\\*) ac_try_echo=\$ac_try;;
*) ac_try_echo=$ac_try;;
esac
eval "echo \"\$as_me:$LINENO: $ac_try_echo\"") >&5
(eval "$ac_link") 2>&5
ac_status=$?
echo "$as_me:$LINENO: \$? = $ac_status" >&5
(exit $ac_status); } && { ac_try='./conftest$ac_exeext'
{ (case "(($ac_try" in
*\"* | *\`* | *\\*) ac_try_echo=\$ac_try;;
*) ac_try_echo=$ac_try;;
esac
eval "echo \"\$as_me:$LINENO: $ac_try_echo\"") >&5
(eval "$ac_try") 2>&5
ac_status=$?
echo "$as_me:$LINENO: \$? = $ac_status" >&5
(exit $ac_status); }; }; then
ac_cv_msse2_ok=yes
else
echo "$as_me: program exited with status $ac_status" >&5
echo "$as_me: failed program was:" >&5
sed 's/^/| /' conftest.$ac_ext >&5
( exit $ac_status )
ac_cv_msse2_ok=no
fi
rm -f core *.core core.conftest.* gmon.out bb.out conftest$ac_exeext conftest.$ac_objext conftest.$ac_ext
fi
CC="$ac_save_cc"
{ echo "$as_me:$LINENO: result: $ac_cv_msse2_ok" >&5
echo "${ECHO_T}$ac_cv_msse2_ok" >&6; }
if test $ac_cv_cpu_has_sse2 = yes && test $ac_cv_msse2_ok = yes
then
BASECFLAGS="$BASECFLAGS -msse2 -mfpmath=sse"
else
# SSE2 doesn't appear to be available. Check that it's okay
# to use gcc inline assembler to get and set x87 control word
cat >>confdefs.h <<\_ACEOF
#define USING_X87_FPU 1
_ACEOF
{ echo "$as_me:$LINENO: checking whether we can use gcc inline assembler to get and set x87 control word" >&5
echo $ECHO_N "checking whether we can use gcc inline assembler to get and set x87 control word... $ECHO_C" >&6; }
cat >conftest.$ac_ext <<_ACEOF
/* confdefs.h. */
_ACEOF
cat confdefs.h >>conftest.$ac_ext
cat >>conftest.$ac_ext <<_ACEOF
/* end confdefs.h. */
int
main ()
{
unsigned short cw;
__asm__ __volatile__ ("fnstcw %0" : "=m" (cw));
__asm__ __volatile__ ("fldcw %0" : : "m" (cw));
;
return 0;
}
_ACEOF
rm -f conftest.$ac_objext
if { (ac_try="$ac_compile"
case "(($ac_try" in
*\"* | *\`* | *\\*) ac_try_echo=\$ac_try;;
*) ac_try_echo=$ac_try;;
esac
eval "echo \"\$as_me:$LINENO: $ac_try_echo\"") >&5
(eval "$ac_compile") 2>conftest.er1
ac_status=$?
grep -v '^ *+' conftest.er1 >conftest.err
rm -f conftest.er1
cat conftest.err >&5
echo "$as_me:$LINENO: \$? = $ac_status" >&5
(exit $ac_status); } && {
test -z "$ac_c_werror_flag" ||
test ! -s conftest.err
} && test -s conftest.$ac_objext; then
have_gcc_asm_for_x87=yes
else
echo "$as_me: failed program was:" >&5
sed 's/^/| /' conftest.$ac_ext >&5
have_gcc_asm_for_x87=no
fi
rm -f core conftest.err conftest.$ac_objext conftest.$ac_ext
{ echo "$as_me:$LINENO: result: $have_gcc_asm_for_x87" >&5
echo "${ECHO_T}$have_gcc_asm_for_x87" >&6; }
if test "$have_gcc_asm_for_x87" = yes
then
cat >>confdefs.h <<\_ACEOF
#define HAVE_GCC_ASM_FOR_X87 1
_ACEOF
fi
fi
fi
fi
# Detect whether system arithmetic is subject to x87-style double
# rounding issues. The result of this test has little meaning on non
@ -21617,10 +22060,9 @@ LIBS="$LIBS $LIBM"
# 0 otherwise. See http://bugs.python.org/issue2937 for more info.
{ echo "$as_me:$LINENO: checking for x87-style double rounding" >&5
echo $ECHO_N "checking for x87-style double rounding... $ECHO_C" >&6; }
if test "${ac_cv_x87_double_rounding+set}" = set; then
echo $ECHO_N "(cached) $ECHO_C" >&6
else
# $BASECFLAGS may affect the result
ac_save_cc="$CC"
CC="$CC $BASECFLAGS"
if test "$cross_compiling" = yes; then
ac_cv_x87_double_rounding=no
else
@ -21684,8 +22126,7 @@ rm -f core *.core core.conftest.* gmon.out bb.out conftest$ac_exeext conftest.$a
fi
fi
CC="$ac_save_cc"
{ echo "$as_me:$LINENO: result: $ac_cv_x87_double_rounding" >&5
echo "${ECHO_T}$ac_cv_x87_double_rounding" >&6; }
if test "$ac_cv_x87_double_rounding" = yes
@ -21697,6 +22138,13 @@ _ACEOF
fi
# ************************************
# * Check for mathematical functions *
# ************************************
LIBS_SAVE=$LIBS
LIBS="$LIBS $LIBM"
# Multiprocessing check for broken sem_getvalue
{ echo "$as_me:$LINENO: checking for broken sem_getvalue" >&5
echo $ECHO_N "checking for broken sem_getvalue... $ECHO_C" >&6; }

View File

@ -3065,12 +3065,176 @@ else AC_MSG_ERROR([proper usage is --with-libc=STRING])
fi],
[AC_MSG_RESULT(default LIBC="$LIBC")])
# ************************************
# * Check for mathematical functions *
# ************************************
# **************************************************
# * Check for various properties of floating point *
# **************************************************
LIBS_SAVE=$LIBS
LIBS="$LIBS $LIBM"
AC_MSG_CHECKING(whether C doubles are little-endian IEEE 754 binary64)
AC_CACHE_VAL(ac_cv_little_endian_double, [
AC_TRY_RUN([
#include <string.h>
int main() {
double x = 9006104071832581.0;
if (memcmp(&x, "\x05\x04\x03\x02\x01\xff\x3f\x43", 8) == 0)
return 0;
else
return 1;
}
],
ac_cv_little_endian_double=yes,
ac_cv_little_endian_double=no,
ac_cv_little_endian_double=no)])
AC_MSG_RESULT($ac_cv_little_endian_double)
if test "$ac_cv_little_endian_double" = yes
then
AC_DEFINE(DOUBLE_IS_LITTLE_ENDIAN_IEEE754, 1,
[Define if C doubles are 64-bit IEEE 754 binary format, stored
with the least significant byte first])
fi
AC_MSG_CHECKING(whether C doubles are big-endian IEEE 754 binary64)
AC_CACHE_VAL(ac_cv_big_endian_double, [
AC_TRY_RUN([
#include <string.h>
int main() {
double x = 9006104071832581.0;
if (memcmp(&x, "\x43\x3f\xff\x01\x02\x03\x04\x05", 8) == 0)
return 0;
else
return 1;
}
],
ac_cv_big_endian_double=yes,
ac_cv_big_endian_double=no,
ac_cv_big_endian_double=no)])
AC_MSG_RESULT($ac_cv_big_endian_double)
if test "$ac_cv_big_endian_double" = yes
then
AC_DEFINE(DOUBLE_IS_BIG_ENDIAN_IEEE754, 1,
[Define if C doubles are 64-bit IEEE 754 binary format, stored
with the most significant byte first])
fi
# Some ARM platforms use a mixed-endian representation for doubles.
# While Python doesn't currently have full support for these platforms
# (see e.g., issue 1762561), we can at least make sure that float <-> string
# conversions work.
AC_MSG_CHECKING(whether C doubles are ARM mixed-endian IEEE 754 binary64)
AC_CACHE_VAL(ac_cv_mixed_endian_double, [
AC_TRY_RUN([
#include <string.h>
int main() {
double x = 9006104071832581.0;
if (memcmp(&x, "\x01\xff\x3f\x43\x05\x04\x03\x02", 8) == 0)
return 0;
else
return 1;
}
],
ac_cv_mixed_endian_double=yes,
ac_cv_mixed_endian_double=no,
ac_cv_mixed_endian_double=no)])
AC_MSG_RESULT($ac_cv_mixed_endian_double)
if test "$ac_cv_mixed_endian_double" = yes
then
AC_DEFINE(DOUBLE_IS_ARM_MIXED_ENDIAN_IEEE754, 1,
[Define if C doubles are 64-bit IEEE 754 binary format, stored
in ARM mixed-endian order (byte order 45670123)])
fi
# David Gay's code in Python/dtoa.c requires that the FPU uses 53-bit
# rounding; this is a particular problem on x86, where the x87 FPU has
# a default rounding precision of 64 bits. For gcc/x86, we try to fix
# this by:
#
# (1) using the SSE2 instruction set when available (it usually is
# on modern machines)
# (2) using inline assembler to get and set the x87 FPU control word
# otherwise.
#
# On AMD64 (aka x86-64), gcc automatically enables use of SSE2
# instructions, so we don't bother trying to detect.
if test "$GCC" = yes && test -n "`$CC -dM -E - </dev/null | grep i386`"
then
# determine whether we're already using the SSE2 instruction set for math
# (e.g., this is true by default on OS X/x86)
AC_MSG_CHECKING(whether SSE2 instructions are already enabled for math)
if test -n "`$CC -dM -E - </dev/null | grep __SSE2_MATH__`"
then
ac_sse2_enabled=yes
else
ac_sse2_enabled=no
fi
AC_MSG_RESULT($ac_sse2_enabled)
# if we're not using SSE2 already, we need to either enable it
# (when available), or use inline assembler to get and set the
# 387 control word.
if test $ac_sse2_enabled = no
then
# Check cpuid for SSE2 availability. Bits 25 and 26 of edx tell
# us about SSE and SSE2 respectively.
AC_MSG_CHECKING(whether SSE2 instructions are available on this CPU)
AC_TRY_RUN([
int main() {
unsigned int ax, bx, cx, dx, func;
func = 1U;
__asm__ __volatile__ (
"pushl %%ebx\n\t" /* don't clobber ebx */
"cpuid\n\t"
"movl %%ebx, %1\n\t"
"popl %%ebx"
: "=a" (ax), "=r" (bx), "=c" (cx), "=d" (dx)
: "a" (func)
: "cc" );
if ((dx & (1U << 25)) && (dx & (1U << 26)))
return 0;
else
return 1;
}
],
ac_cv_cpu_has_sse2=yes,
ac_cv_cpu_has_sse2=no,
ac_cv_cpu_has_sse2=no)
AC_MSG_RESULT($ac_cv_cpu_has_sse2)
# determine whether gcc accepts options to turn on SSE2
AC_MSG_CHECKING(whether $CC accepts -msse2 -mfpmath=sse)
ac_save_cc="$CC"
CC="$CC -msse2 -mfpmath=sse"
AC_TRY_RUN([int main() { return 0; }],
ac_cv_msse2_ok=yes,
ac_cv_msse2_ok=no,
ac_cv_msse2_ok=no)
CC="$ac_save_cc"
AC_MSG_RESULT($ac_cv_msse2_ok)
if test $ac_cv_cpu_has_sse2 = yes && test $ac_cv_msse2_ok = yes
then
BASECFLAGS="$BASECFLAGS -msse2 -mfpmath=sse"
else
# SSE2 doesn't appear to be available. Check that it's okay
# to use gcc inline assembler to get and set x87 control word
AC_DEFINE(USING_X87_FPU, 1,
[Define on x86 hardware if the x87 FPU is being used
for floating-point arithmetic])
AC_MSG_CHECKING(whether we can use gcc inline assembler to get and set x87 control word)
AC_TRY_COMPILE([], [
unsigned short cw;
__asm__ __volatile__ ("fnstcw %0" : "=m" (cw));
__asm__ __volatile__ ("fldcw %0" : : "m" (cw));
],
[have_gcc_asm_for_x87=yes], [have_gcc_asm_for_x87=no])
AC_MSG_RESULT($have_gcc_asm_for_x87)
if test "$have_gcc_asm_for_x87" = yes
then
AC_DEFINE(HAVE_GCC_ASM_FOR_X87, 1,
[Define if we can use gcc inline assembler to get and set x87 control word])
fi
fi
fi
fi
# Detect whether system arithmetic is subject to x87-style double
# rounding issues. The result of this test has little meaning on non
@ -3078,7 +3242,9 @@ LIBS="$LIBS $LIBM"
# mode is round-to-nearest and double rounding issues are present, and
# 0 otherwise. See http://bugs.python.org/issue2937 for more info.
AC_MSG_CHECKING(for x87-style double rounding)
AC_CACHE_VAL(ac_cv_x87_double_rounding, [
# $BASECFLAGS may affect the result
ac_save_cc="$CC"
CC="$CC $BASECFLAGS"
AC_TRY_RUN([
#include <stdlib.h>
#include <math.h>
@ -3101,7 +3267,8 @@ int main() {
],
ac_cv_x87_double_rounding=no,
ac_cv_x87_double_rounding=yes,
ac_cv_x87_double_rounding=no)])
ac_cv_x87_double_rounding=no)
CC="$ac_save_cc"
AC_MSG_RESULT($ac_cv_x87_double_rounding)
if test "$ac_cv_x87_double_rounding" = yes
then
@ -3109,6 +3276,13 @@ then
[Define if arithmetic is subject to x87-style double rounding issue])
fi
# ************************************
# * Check for mathematical functions *
# ************************************
LIBS_SAVE=$LIBS
LIBS="$LIBS $LIBM"
# Multiprocessing check for broken sem_getvalue
AC_MSG_CHECKING(for broken sem_getvalue)
AC_TRY_RUN([

View File

@ -15,6 +15,18 @@
/* Define if you have the Mach cthreads package */
#undef C_THREADS
/* Define if C doubles are 64-bit IEEE 754 binary format, stored in ARM
mixed-endian order (byte order 45670123) */
#undef DOUBLE_IS_ARM_MIXED_ENDIAN_IEEE754
/* Define if C doubles are 64-bit IEEE 754 binary format, stored with the most
significant byte first */
#undef DOUBLE_IS_BIG_ENDIAN_IEEE754
/* Define if C doubles are 64-bit IEEE 754 binary format, stored with the
least significant byte first */
#undef DOUBLE_IS_LITTLE_ENDIAN_IEEE754
/* Define if --enable-ipv6 is specified */
#undef ENABLE_IPV6
@ -232,6 +244,10 @@
/* Define to 1 if you have the `gai_strerror' function. */
#undef HAVE_GAI_STRERROR
/* Define if we can use gcc inline assembler to get and set x87 control word
*/
#undef HAVE_GCC_ASM_FOR_X87
/* Define if you have the getaddrinfo function. */
#undef HAVE_GETADDRINFO
@ -970,6 +986,10 @@
/* Define if you want to use computed gotos in ceval.c. */
#undef USE_COMPUTED_GOTOS
/* Define on x86 hardware if the x87 FPU is being used for floating-point
arithmetic */
#undef USING_X87_FPU
/* Define if a va_list is an array of some kind */
#undef VA_LIST_IS_ARRAY