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Issue #23517: fromtimestamp() and utcfromtimestamp() methods of

Browse source 
datetime.datetime now round microseconds to nearest with ties going to nearest
even integer (ROUND_HALF_EVEN), as round(float), instead of rounding towards
-Infinity (ROUND_FLOOR).

pytime API: replace _PyTime_ROUND_HALF_UP with _PyTime_ROUND_HALF_EVEN. Fix
also _PyTime_Divide() for negative numbers.

_PyTime_AsTimeval_impl() now reuses _PyTime_Divide() instead of reimplementing
rounding modes.
This commit is contained in:
Victor Stinner 2015-09-09 01:02:23 +02:00
parent 69cc487df4
commit 7667f58151
8 changed files with 148 additions and 185 deletions
Show stats Download patch file Download diff file Expand all files Collapse all files

9
Include/pytime.h
View file

@ -31,9 +31,9 @@ typedef enum {
/* Round towards infinity (+inf).
For example, used for timeout to wait "at least" N seconds. */
_PyTime_ROUND_CEILING=1,
/* Round to nearest with ties going away from zero.
/* Round to nearest with ties going to nearest even integer.
For example, used to round from a Python float. */
_PyTime_ROUND_HALF_UP
_PyTime_ROUND_HALF_EVEN
} _PyTime_round_t;
/* Convert a time_t to a PyLong. */
@ -44,8 +44,9 @@ PyAPI_FUNC(PyObject *) _PyLong_FromTime_t(
PyAPI_FUNC(time_t) _PyLong_AsTime_t(
PyObject *obj);
/* Round to nearest with ties going away from zero (_PyTime_ROUND_HALF_UP). */
PyAPI_FUNC(double) _PyTime_RoundHalfUp(
/* Round to nearest with ties going to nearest even integer
(_PyTime_ROUND_HALF_EVEN) */
PyAPI_FUNC(double) _PyTime_RoundHalfEven(
double x);
/* Convert a number of seconds, int or float, to time_t. */

2
Lib/datetime.py
View file

@ -1380,7 +1380,7 @@ def _fromtimestamp(cls, t, utc, tz):
A timezone info object may be passed in as well.
"""
frac, t = _math.modf(t)
us = _round_half_up(frac * 1e6)
us = round(frac * 1e6)
if us >= 1000000:
t += 1
us -= 1000000

4
Lib/test/datetimetester.py
View file

@ -1874,7 +1874,7 @@ def test_microsecond_rounding(self):
self.assertEqual(t, zero)
t = fts(-1/2**7)
self.assertEqual(t.second, 59)
self.assertEqual(t.microsecond, 992187)
self.assertEqual(t.microsecond, 992188)
t = fts(1e-7)
self.assertEqual(t, zero)
@ -1888,7 +1888,7 @@ def test_microsecond_rounding(self):
self.assertEqual(t.microsecond, 0)
t = fts(1/2**7)
self.assertEqual(t.second, 0)
self.assertEqual(t.microsecond, 7813)
self.assertEqual(t.microsecond, 7812)
def test_insane_fromtimestamp(self):
# It's possible that some platform maps time_t to double,

237
Lib/test/test_time.py
View file

@ -30,11 +30,11 @@ class _PyTime(enum.IntEnum):
ROUND_FLOOR = 0
# Round towards infinity (+inf)
ROUND_CEILING = 1
# Round to nearest with ties going away from zero
ROUND_HALF_UP = 2
# Round to nearest with ties going to nearest even integer
ROUND_HALF_EVEN = 2
ALL_ROUNDING_METHODS = (_PyTime.ROUND_FLOOR, _PyTime.ROUND_CEILING,
_PyTime.ROUND_HALF_UP)
_PyTime.ROUND_HALF_EVEN)
class TimeTestCase(unittest.TestCase):
@ -639,27 +639,26 @@ def test_time_t(self):
# Conversion giving different results depending on the rounding method
FLOOR = _PyTime.ROUND_FLOOR
CEILING = _PyTime.ROUND_CEILING
HALF_UP = _PyTime.ROUND_HALF_UP
for obj, time_t, rnd in (
HALF_EVEN = _PyTime.ROUND_HALF_EVEN
for obj, seconds, rnd in (
(-1.9, -2, FLOOR),
(-1.9, -1, CEILING),
(-1.9, -2, HALF_UP),
(-1.9, -2, HALF_EVEN),
(1.9, 1, FLOOR),
(1.9, 2, CEILING),
(1.9, 2, HALF_UP),
(1.9, 2, HALF_EVEN),
# half up
(-0.999, -1, HALF_UP),
(-0.510, -1, HALF_UP),
(-0.500, -1, HALF_UP),
(-0.490, 0, HALF_UP),
( 0.490, 0, HALF_UP),
( 0.500, 1, HALF_UP),
( 0.510, 1, HALF_UP),
( 0.999, 1, HALF_UP),
# half even
(-1.5, -2, HALF_EVEN),
(-0.9, -1, HALF_EVEN),
(-0.5, 0, HALF_EVEN),
( 0.5, 0, HALF_EVEN),
( 0.9, 1, HALF_EVEN),
( 1.5, 2, HALF_EVEN),
):
self.assertEqual(pytime_object_to_time_t(obj, rnd), time_t)
with self.subTest(obj=obj, round=rnd, seconds=seconds):
self.assertEqual(pytime_object_to_time_t(obj, rnd), seconds)
# Test OverflowError
rnd = _PyTime.ROUND_FLOOR
@ -691,15 +690,15 @@ def test_object_to_timespec(self):
# Conversion giving different results depending on the rounding method
FLOOR = _PyTime.ROUND_FLOOR
CEILING = _PyTime.ROUND_CEILING
HALF_UP = _PyTime.ROUND_HALF_UP
HALF_EVEN = _PyTime.ROUND_HALF_EVEN
for obj, timespec, rnd in (
# Round towards minus infinity (-inf)
(-1e-10, (0, 0), CEILING),
(-1e-10, (-1, 999999999), FLOOR),
(-1e-10, (0, 0), HALF_UP),
(-1e-10, (0, 0), HALF_EVEN),
(1e-10, (0, 0), FLOOR),
(1e-10, (0, 1), CEILING),
(1e-10, (0, 0), HALF_UP),
(1e-10, (0, 0), HALF_EVEN),
(0.9999999999, (0, 999999999), FLOOR),
(0.9999999999, (1, 0), CEILING),
@ -714,15 +713,13 @@ def test_object_to_timespec(self):
(-1.1234567890, (-2, 876543211), CEILING),
(-1.1234567891, (-2, 876543211), CEILING),
# half up
(-0.6e-9, (-1, 999999999), HALF_UP),
# skipped, 0.5e-6 is inexact in base 2
#(-0.5e-9, (-1, 999999999), HALF_UP),
(-0.4e-9, (0, 0), HALF_UP),
(0.4e-9, (0, 0), HALF_UP),
(0.5e-9, (0, 1), HALF_UP),
(0.6e-9, (0, 1), HALF_UP),
# half even
(-1.5e-9, (-1, 999999998), HALF_EVEN),
(-0.9e-9, (-1, 999999999), HALF_EVEN),
(-0.5e-9, (0, 0), HALF_EVEN),
(0.5e-9, (0, 0), HALF_EVEN),
(0.9e-9, (0, 1), HALF_EVEN),
(1.5e-9, (0, 2), HALF_EVEN),
):
with self.subTest(obj=obj, round=rnd, timespec=timespec):
self.assertEqual(pytime_object_to_timespec(obj, rnd), timespec)
@ -823,10 +820,10 @@ def test_FromSecondsObject(self):
(-7.0, -7 * SEC_TO_NS),
# nanosecond are kept for value <= 2^23 seconds,
# except 2**23-1e-9 with HALF_UP
(2**22 - 1e-9, 4194303999999999),
(2**22, 4194304000000000),
(2**22 + 1e-9, 4194304000000001),
(2**23 - 1e-9, 8388607999999999),
(2**23, 8388608000000000),
# start loosing precision for value > 2^23 seconds
@ -859,38 +856,31 @@ def test_FromSecondsObject(self):
# Conversion giving different results depending on the rounding method
FLOOR = _PyTime.ROUND_FLOOR
CEILING = _PyTime.ROUND_CEILING
HALF_UP = _PyTime.ROUND_HALF_UP
HALF_EVEN = _PyTime.ROUND_HALF_EVEN
for obj, ts, rnd in (
# close to zero
( 1e-10, 0, FLOOR),
( 1e-10, 1, CEILING),
( 1e-10, 0, HALF_UP),
( 1e-10, 0, HALF_EVEN),
(-1e-10, -1, FLOOR),
(-1e-10, 0, CEILING),
(-1e-10, 0, HALF_UP),
(-1e-10, 0, HALF_EVEN),
# test rounding of the last nanosecond
( 1.1234567899, 1123456789, FLOOR),
( 1.1234567899, 1123456790, CEILING),
( 1.1234567899, 1123456790, HALF_UP),
( 1.1234567899, 1123456790, HALF_EVEN),
(-1.1234567899, -1123456790, FLOOR),
(-1.1234567899, -1123456789, CEILING),
(-1.1234567899, -1123456790, HALF_UP),
(-1.1234567899, -1123456790, HALF_EVEN),
# close to 1 second
( 0.9999999999, 999999999, FLOOR),
( 0.9999999999, 1000000000, CEILING),
( 0.9999999999, 1000000000, HALF_UP),
( 0.9999999999, 1000000000, HALF_EVEN),
(-0.9999999999, -1000000000, FLOOR),
(-0.9999999999, -999999999, CEILING),
(-0.9999999999, -1000000000, HALF_UP),
# close to 2^23 seconds
(2**23 - 1e-9, 8388607999999999, FLOOR),
(2**23 - 1e-9, 8388607999999999, CEILING),
# Issue #23517: skip HALF_UP test because the result is different
# depending on the FPU and how the compiler optimize the code :-/
#(2**23 - 1e-9, 8388608000000000, HALF_UP),
(-0.9999999999, -1000000000, HALF_EVEN),
):
with self.subTest(obj=obj, round=rnd, timestamp=ts):
self.assertEqual(PyTime_FromSecondsObject(obj, rnd), ts)
@ -958,33 +948,23 @@ def test_timeval(self):
FLOOR = _PyTime.ROUND_FLOOR
CEILING = _PyTime.ROUND_CEILING
HALF_UP = _PyTime.ROUND_HALF_UP
HALF_EVEN = _PyTime.ROUND_HALF_EVEN
for ns, tv, rnd in (
# nanoseconds
(1, (0, 0), FLOOR),
(1, (0, 1), CEILING),
(1, (0, 0), HALF_UP),
(1, (0, 0), HALF_EVEN),
(-1, (-1, 999999), FLOOR),
(-1, (0, 0), CEILING),
(-1, (0, 0), HALF_UP),
(-1, (0, 0), HALF_EVEN),
# seconds + nanoseconds
(1234567001, (1, 234567), FLOOR),
(1234567001, (1, 234568), CEILING),
(1234567001, (1, 234567), HALF_UP),
(-1234567001, (-2, 765432), FLOOR),
(-1234567001, (-2, 765433), CEILING),
(-1234567001, (-2, 765433), HALF_UP),
# half up
(499, (0, 0), HALF_UP),
(500, (0, 1), HALF_UP),
(501, (0, 1), HALF_UP),
(999, (0, 1), HALF_UP),
(-499, (0, 0), HALF_UP),
(-500, (0, 0), HALF_UP),
(-501, (-1, 999999), HALF_UP),
(-999, (-1, 999999), HALF_UP),
# half even
(-1500, (-1, 999998), HALF_EVEN),
(-999, (-1, 999999), HALF_EVEN),
(-500, (0, 0), HALF_EVEN),
(500, (0, 0), HALF_EVEN),
(999, (0, 1), HALF_EVEN),
(1500, (0, 2), HALF_EVEN),
):
with self.subTest(nanoseconds=ns, timeval=tv, round=rnd):
self.assertEqual(PyTime_AsTimeval(ns, rnd), tv)
@ -1027,33 +1007,31 @@ def test_milliseconds(self):
FLOOR = _PyTime.ROUND_FLOOR
CEILING = _PyTime.ROUND_CEILING
HALF_UP = _PyTime.ROUND_HALF_UP
HALF_EVEN = _PyTime.ROUND_HALF_EVEN
for ns, ms, rnd in (
# nanoseconds
(1, 0, FLOOR),
(1, 1, CEILING),
(1, 0, HALF_UP),
(-1, 0, FLOOR),
(-1, -1, CEILING),
(-1, 0, HALF_UP),
(1, 0, HALF_EVEN),
(-1, -1, FLOOR),
(-1, 0, CEILING),
(-1, 0, HALF_EVEN),
# seconds + nanoseconds
(1234 * MS_TO_NS + 1, 1234, FLOOR),
(1234 * MS_TO_NS + 1, 1235, CEILING),
(1234 * MS_TO_NS + 1, 1234, HALF_UP),
(-1234 * MS_TO_NS - 1, -1234, FLOOR),
(-1234 * MS_TO_NS - 1, -1235, CEILING),
(-1234 * MS_TO_NS - 1, -1234, HALF_UP),
(1234 * MS_TO_NS + 1, 1234, HALF_EVEN),
(-1234 * MS_TO_NS - 1, -1235, FLOOR),
(-1234 * MS_TO_NS - 1, -1234, CEILING),
(-1234 * MS_TO_NS - 1, -1234, HALF_EVEN),
# half up
(499999, 0, HALF_UP),
(499999, 0, HALF_UP),
(500000, 1, HALF_UP),
(999999, 1, HALF_UP),
(-499999, 0, HALF_UP),
(-500000, -1, HALF_UP),
(-500001, -1, HALF_UP),
(-999999, -1, HALF_UP),
(-1500000, -2, HALF_EVEN),
(-999999, -1, HALF_EVEN),
(-500000, 0, HALF_EVEN),
(500000, 0, HALF_EVEN),
(999999, 1, HALF_EVEN),
(1500000, 2, HALF_EVEN),
):
with self.subTest(nanoseconds=ns, milliseconds=ms, round=rnd):
self.assertEqual(PyTime_AsMilliseconds(ns, rnd), ms)
@ -1079,31 +1057,31 @@ def test_microseconds(self):
FLOOR = _PyTime.ROUND_FLOOR
CEILING = _PyTime.ROUND_CEILING
HALF_UP = _PyTime.ROUND_HALF_UP
HALF_EVEN = _PyTime.ROUND_HALF_EVEN
for ns, ms, rnd in (
# nanoseconds
(1, 0, FLOOR),
(1, 1, CEILING),
(1, 0, HALF_UP),
(-1, 0, FLOOR),
(-1, -1, CEILING),
(-1, 0, HALF_UP),
(1, 0, HALF_EVEN),
(-1, -1, FLOOR),
(-1, 0, CEILING),
(-1, 0, HALF_EVEN),
# seconds + nanoseconds
(1234 * US_TO_NS + 1, 1234, FLOOR),
(1234 * US_TO_NS + 1, 1235, CEILING),
(1234 * US_TO_NS + 1, 1234, HALF_UP),
(-1234 * US_TO_NS - 1, -1234, FLOOR),
(-1234 * US_TO_NS - 1, -1235, CEILING),
(-1234 * US_TO_NS - 1, -1234, HALF_UP),
(1234 * US_TO_NS + 1, 1234, HALF_EVEN),
(-1234 * US_TO_NS - 1, -1235, FLOOR),
(-1234 * US_TO_NS - 1, -1234, CEILING),
(-1234 * US_TO_NS - 1, -1234, HALF_EVEN),
# half up
(1499, 1, HALF_UP),
(1500, 2, HALF_UP),
(1501, 2, HALF_UP),
(-1499, -1, HALF_UP),
(-1500, -2, HALF_UP),
(-1501, -2, HALF_UP),
(-1500, -2, HALF_EVEN),
(-999, -1, HALF_EVEN),
(-500, 0, HALF_EVEN),
(500, 0, HALF_EVEN),
(999, 1, HALF_EVEN),
(1500, 2, HALF_EVEN),
):
with self.subTest(nanoseconds=ns, milliseconds=ms, round=rnd):
self.assertEqual(PyTime_AsMicroseconds(ns, rnd), ms)
@ -1142,23 +1120,23 @@ def test_time_t(self):
# Conversion giving different results depending on the rounding method
FLOOR = _PyTime.ROUND_FLOOR
CEILING = _PyTime.ROUND_CEILING
HALF_UP = _PyTime.ROUND_HALF_UP
HALF_EVEN = _PyTime.ROUND_HALF_EVEN
for obj, time_t, rnd in (
(-1.9, -2, FLOOR),
(-1.9, -2, HALF_UP),
(-1.9, -2, HALF_EVEN),
(-1.9, -1, CEILING),
(1.9, 1, FLOOR),
(1.9, 2, HALF_UP),
(1.9, 2, HALF_EVEN),
(1.9, 2, CEILING),
(-0.6, -1, HALF_UP),
(-0.5, -1, HALF_UP),
(-0.4, 0, HALF_UP),
(0.4, 0, HALF_UP),
(0.5, 1, HALF_UP),
(0.6, 1, HALF_UP),
# half even
(-1.5, -2, HALF_EVEN),
(-0.9, -1, HALF_EVEN),
(-0.5, 0, HALF_EVEN),
( 0.5, 0, HALF_EVEN),
( 0.9, 1, HALF_EVEN),
( 1.5, 2, HALF_EVEN),
):
self.assertEqual(pytime_object_to_time_t(obj, rnd), time_t)
@ -1192,29 +1170,27 @@ def test_object_to_timeval(self):
# Conversion giving different results depending on the rounding method
FLOOR = _PyTime.ROUND_FLOOR
CEILING = _PyTime.ROUND_CEILING
HALF_UP = _PyTime.ROUND_HALF_UP
HALF_EVEN = _PyTime.ROUND_HALF_EVEN
for obj, timeval, rnd in (
(-1e-7, (-1, 999999), FLOOR),
(-1e-7, (0, 0), CEILING),
(-1e-7, (0, 0), HALF_UP),
(-1e-7, (0, 0), HALF_EVEN),
(1e-7, (0, 0), FLOOR),
(1e-7, (0, 1), CEILING),
(1e-7, (0, 0), HALF_UP),
(1e-7, (0, 0), HALF_EVEN),
(0.9999999, (0, 999999), FLOOR),
(0.9999999, (1, 0), CEILING),
(0.9999999, (1, 0), HALF_UP),
(0.9999999, (1, 0), HALF_EVEN),
(-0.6e-6, (-1, 999999), HALF_UP),
# skipped, -0.5e-6 is inexact in base 2
#(-0.5e-6, (-1, 999999), HALF_UP),
(-0.4e-6, (0, 0), HALF_UP),
(0.4e-6, (0, 0), HALF_UP),
# skipped, 0.5e-6 is inexact in base 2
#(0.5e-6, (0, 1), HALF_UP),
(0.6e-6, (0, 1), HALF_UP),
# half even
(-1.5e-6, (-1, 999998), HALF_EVEN),
(-0.9e-6, (-1, 999999), HALF_EVEN),
(-0.5e-6, (0, 0), HALF_EVEN),
(0.5e-6, (0, 0), HALF_EVEN),
(0.9e-6, (0, 1), HALF_EVEN),
(1.5e-6, (0, 2), HALF_EVEN),
):
with self.subTest(obj=obj, round=rnd, timeval=timeval):
self.assertEqual(pytime_object_to_timeval(obj, rnd), timeval)
@ -1248,28 +1224,27 @@ def test_timespec(self):
# Conversion giving different results depending on the rounding method
FLOOR = _PyTime.ROUND_FLOOR
CEILING = _PyTime.ROUND_CEILING
HALF_UP = _PyTime.ROUND_HALF_UP
HALF_EVEN = _PyTime.ROUND_HALF_EVEN
for obj, timespec, rnd in (
(-1e-10, (-1, 999999999), FLOOR),
(-1e-10, (0, 0), CEILING),
(-1e-10, (0, 0), HALF_UP),
(-1e-10, (0, 0), HALF_EVEN),
(1e-10, (0, 0), FLOOR),
(1e-10, (0, 1), CEILING),
(1e-10, (0, 0), HALF_UP),
(1e-10, (0, 0), HALF_EVEN),
(0.9999999999, (0, 999999999), FLOOR),
(0.9999999999, (1, 0), CEILING),
(0.9999999999, (1, 0), HALF_UP),
(0.9999999999, (1, 0), HALF_EVEN),
(-0.6e-9, (-1, 999999999), HALF_UP),
# skipped, 0.5e-6 is inexact in base 2
#(-0.5e-9, (-1, 999999999), HALF_UP),
(-0.4e-9, (0, 0), HALF_UP),
(0.4e-9, (0, 0), HALF_UP),
(0.5e-9, (0, 1), HALF_UP),
(0.6e-9, (0, 1), HALF_UP),
# half even
(-1.5e-9, (-1, 999999998), HALF_EVEN),
(-0.9e-9, (-1, 999999999), HALF_EVEN),
(-0.5e-9, (0, 0), HALF_EVEN),
(0.5e-9, (0, 0), HALF_EVEN),
(0.9e-9, (0, 1), HALF_EVEN),
(1.5e-9, (0, 2), HALF_EVEN),
):
with self.subTest(obj=obj, round=rnd, timespec=timespec):
self.assertEqual(pytime_object_to_timespec(obj, rnd), timespec)

6
Misc/NEWS
View file

@ -20,9 +20,9 @@ Library
- Issue #22241: timezone.utc name is now plain 'UTC', not 'UTC-00:00'.
- Issue #23517: fromtimestamp() and utcfromtimestamp() methods of
datetime.datetime now round microseconds to nearest with ties going away from
zero (ROUND_HALF_UP), as Python 2 and Python older than 3.3, instead of
rounding towards -Infinity (ROUND_FLOOR).
datetime.datetime now round microseconds to nearest with ties going to
nearest even integer (ROUND_HALF_EVEN), as round(float), instead of rounding
towards -Infinity (ROUND_FLOOR).
- Issue #23552: Timeit now warns when there is substantial (4x) variance
between best and worst times. Patch from Serhiy Storchaka.

2
Modules/_datetimemodule.c
View file

@ -4103,7 +4103,7 @@ datetime_from_timestamp(PyObject *cls, TM_FUNC f, PyObject *timestamp,
long us;
if (_PyTime_ObjectToTimeval(timestamp,
&timet, &us, _PyTime_ROUND_HALF_UP) == -1)
&timet, &us, _PyTime_ROUND_HALF_EVEN) == -1)
return NULL;
return datetime_from_timet_and_us(cls, f, timet, (int)us, tzinfo);

2
Modules/_testcapimodule.c
View file

@ -2648,7 +2648,7 @@ check_time_rounding(int round)
{
if (round != _PyTime_ROUND_FLOOR
&& round != _PyTime_ROUND_CEILING
&& round != _PyTime_ROUND_HALF_UP) {
&& round != _PyTime_ROUND_HALF_EVEN) {
PyErr_SetString(PyExc_ValueError, "invalid rounding");
return -1;
}

71
Python/pytime.c
View file

@ -61,18 +61,15 @@ _PyLong_FromTime_t(time_t t)
}
double
_PyTime_RoundHalfUp(double x)
_PyTime_RoundHalfEven(double x)
{
/* volatile avoids optimization changing how numbers are rounded */
volatile double d = x;
if (d >= 0.0)
d = floor(d + 0.5);
else
d = ceil(d - 0.5);
return d;
double rounded = round(x);
if (fabs(x-rounded) == 0.5)
/* halfway case: round to even */
rounded = 2.0*round(x/2.0);
return rounded;
}
static int
_PyTime_DoubleToDenominator(double d, time_t *sec, long *numerator,
double denominator, _PyTime_round_t round)
@ -84,8 +81,8 @@ _PyTime_DoubleToDenominator(double d, time_t *sec, long *numerator,
floatpart = modf(d, &intpart);
floatpart *= denominator;
if (round == _PyTime_ROUND_HALF_UP)
floatpart = _PyTime_RoundHalfUp(floatpart);
if (round == _PyTime_ROUND_HALF_EVEN)
floatpart = _PyTime_RoundHalfEven(floatpart);
else if (round == _PyTime_ROUND_CEILING)
floatpart = ceil(floatpart);
else
@ -140,8 +137,8 @@ _PyTime_ObjectToTime_t(PyObject *obj, time_t *sec, _PyTime_round_t round)
volatile double d;
d = PyFloat_AsDouble(obj);
if (round == _PyTime_ROUND_HALF_UP)
d = _PyTime_RoundHalfUp(d);
if (round == _PyTime_ROUND_HALF_EVEN)
d = _PyTime_RoundHalfEven(d);
else if (round == _PyTime_ROUND_CEILING)
d = ceil(d);
else
@ -266,8 +263,8 @@ _PyTime_FromFloatObject(_PyTime_t *t, double value, _PyTime_round_t round,
d = value;
d *= to_nanoseconds;
if (round == _PyTime_ROUND_HALF_UP)
d = _PyTime_RoundHalfUp(d);
if (round == _PyTime_ROUND_HALF_EVEN)
d = _PyTime_RoundHalfEven(d);
else if (round == _PyTime_ROUND_CEILING)
d = ceil(d);
else
@ -351,14 +348,16 @@ _PyTime_AsNanosecondsObject(_PyTime_t t)
}
static _PyTime_t
_PyTime_Divide(_PyTime_t t, _PyTime_t k, _PyTime_round_t round)
_PyTime_Divide(const _PyTime_t t, const _PyTime_t k,
const _PyTime_round_t round)
{
assert(k > 1);
if (round == _PyTime_ROUND_HALF_UP) {
_PyTime_t x, r;
if (round == _PyTime_ROUND_HALF_EVEN) {
_PyTime_t x, r, abs_r;
x = t / k;
r = t % k;
if (Py_ABS(r) >= k / 2) {
abs_r = Py_ABS(r);
if (abs_r > k / 2 || (abs_r == k / 2 && (Py_ABS(x) & 1))) {
if (t >= 0)
x++;
else
@ -369,11 +368,15 @@ _PyTime_Divide(_PyTime_t t, _PyTime_t k, _PyTime_round_t round)
else if (round == _PyTime_ROUND_CEILING) {
if (t >= 0)
return (t + k - 1) / k;
else
return t / k;
}
else {
if (t >= 0)
return t / k;
else
return (t - (k - 1)) / k;
}
else
return t / k;
}
_PyTime_t
@ -392,17 +395,12 @@ static int
_PyTime_AsTimeval_impl(_PyTime_t t, struct timeval *tv, _PyTime_round_t round,
int raise)
{
const long k = US_TO_NS;
_PyTime_t secs, ns;
int res = 0;
int usec;
secs = t / SEC_TO_NS;
ns = t % SEC_TO_NS;
if (ns < 0) {
ns += SEC_TO_NS;
secs -= 1;
}
#ifdef MS_WINDOWS
/* On Windows, timeval.tv_sec is a long (32 bit),
@ -427,23 +425,12 @@ _PyTime_AsTimeval_impl(_PyTime_t t, struct timeval *tv, _PyTime_round_t round,
res = -1;
#endif
if (round == _PyTime_ROUND_HALF_UP) {
_PyTime_t r;
usec = (int)(ns / k);
r = ns % k;
if (Py_ABS(r) >= k / 2) {
if (ns >= 0)
usec++;
else
usec--;
}
usec = (int)_PyTime_Divide(ns, US_TO_NS, round);
if (usec < 0) {
usec += SEC_TO_US;
tv->tv_sec -= 1;
}
else if (round == _PyTime_ROUND_CEILING)
usec = (int)((ns + k - 1) / k);
else
usec = (int)(ns / k);
if (usec >= SEC_TO_US) {
else if (usec >= SEC_TO_US) {
usec -= SEC_TO_US;
tv->tv_sec += 1;
}