time: Improve performance of time64_to_tm()

The current implementation of time64_to_tm() contains unnecessary loops,
branches and look-up tables. The new one uses an arithmetic-based algorithm
appeared in [1] and is approximately 3x faster (YMMV).

The drawback is that the new code isn't intuitive and contains many 'magic
numbers' (not unusual for this type of algorithm). However, [1] justifies
all those numbers and, given this function's history, the code is unlikely
to need much maintenance, if any at all.

Add a KUnit test for it which checks every day in a 160,000 years interval
centered at 1970-01-01 against the expected result.

[1] Neri, Schneider, "Euclidean Affine Functions and Applications to
Calendar Algorithms". https://arxiv.org/abs/2102.06959

Signed-off-by: Cassio Neri <cassio.neri@gmail.com>
Signed-off-by: Thomas Gleixner <tglx@linutronix.de>
Link: https://lore.kernel.org/r/20210622213616.313046-1-cassio.neri@gmail.com
This commit is contained in:
Cassio Neri 2021-06-22 22:36:16 +01:00 committed by Thomas Gleixner
parent 4e82d2e20f
commit 2760105516
4 changed files with 172 additions and 52 deletions

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@ -64,6 +64,15 @@ config LEGACY_TIMER_TICK
lack support for the generic clockevent framework. lack support for the generic clockevent framework.
New platforms should use generic clockevents instead. New platforms should use generic clockevents instead.
config TIME_KUNIT_TEST
tristate "KUnit test for kernel/time functions" if !KUNIT_ALL_TESTS
depends on KUNIT
default KUNIT_ALL_TESTS
help
Enable this option to test RTC library functions.
If unsure, say N.
if GENERIC_CLOCKEVENTS if GENERIC_CLOCKEVENTS
menu "Timers subsystem" menu "Timers subsystem"

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@ -22,3 +22,4 @@ obj-$(CONFIG_DEBUG_FS) += timekeeping_debug.o
obj-$(CONFIG_TEST_UDELAY) += test_udelay.o obj-$(CONFIG_TEST_UDELAY) += test_udelay.o
obj-$(CONFIG_TIME_NS) += namespace.o obj-$(CONFIG_TIME_NS) += namespace.o
obj-$(CONFIG_TEST_CLOCKSOURCE_WATCHDOG) += clocksource-wdtest.o obj-$(CONFIG_TEST_CLOCKSOURCE_WATCHDOG) += clocksource-wdtest.o
obj-$(CONFIG_TIME_KUNIT_TEST) += time_test.o

98
kernel/time/time_test.c Normal file
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@ -0,0 +1,98 @@
// SPDX-License-Identifier: LGPL-2.1+
#include <kunit/test.h>
#include <linux/time.h>
/*
* Traditional implementation of leap year evaluation.
*/
static bool is_leap(long year)
{
return year % 4 == 0 && (year % 100 != 0 || year % 400 == 0);
}
/*
* Gets the last day of a month.
*/
static int last_day_of_month(long year, int month)
{
if (month == 2)
return 28 + is_leap(year);
if (month == 4 || month == 6 || month == 9 || month == 11)
return 30;
return 31;
}
/*
* Advances a date by one day.
*/
static void advance_date(long *year, int *month, int *mday, int *yday)
{
if (*mday != last_day_of_month(*year, *month)) {
++*mday;
++*yday;
return;
}
*mday = 1;
if (*month != 12) {
++*month;
++*yday;
return;
}
*month = 1;
*yday = 0;
++*year;
}
/*
* Checks every day in a 160000 years interval centered at 1970-01-01
* against the expected result.
*/
static void time64_to_tm_test_date_range(struct kunit *test)
{
/*
* 80000 years = (80000 / 400) * 400 years
* = (80000 / 400) * 146097 days
* = (80000 / 400) * 146097 * 86400 seconds
*/
time64_t total_secs = ((time64_t) 80000) / 400 * 146097 * 86400;
long year = 1970 - 80000;
int month = 1;
int mdday = 1;
int yday = 0;
struct tm result;
time64_t secs;
s64 days;
for (secs = -total_secs; secs <= total_secs; secs += 86400) {
time64_to_tm(secs, 0, &result);
days = div_s64(secs, 86400);
#define FAIL_MSG "%05ld/%02d/%02d (%2d) : %ld", \
year, month, mdday, yday, days
KUNIT_ASSERT_EQ_MSG(test, year - 1900, result.tm_year, FAIL_MSG);
KUNIT_ASSERT_EQ_MSG(test, month - 1, result.tm_mon, FAIL_MSG);
KUNIT_ASSERT_EQ_MSG(test, mdday, result.tm_mday, FAIL_MSG);
KUNIT_ASSERT_EQ_MSG(test, yday, result.tm_yday, FAIL_MSG);
advance_date(&year, &month, &mdday, &yday);
}
}
static struct kunit_case time_test_cases[] = {
KUNIT_CASE(time64_to_tm_test_date_range),
{}
};
static struct kunit_suite time_test_suite = {
.name = "time_test_cases",
.test_cases = time_test_cases,
};
kunit_test_suite(time_test_suite);

View File

@ -22,47 +22,16 @@
/* /*
* Converts the calendar time to broken-down time representation * Converts the calendar time to broken-down time representation
* Based on code from glibc-2.6
* *
* 2009-7-14: * 2009-7-14:
* Moved from glibc-2.6 to kernel by Zhaolei<zhaolei@cn.fujitsu.com> * Moved from glibc-2.6 to kernel by Zhaolei<zhaolei@cn.fujitsu.com>
* 2021-06-02:
* Reimplemented by Cassio Neri <cassio.neri@gmail.com>
*/ */
#include <linux/time.h> #include <linux/time.h>
#include <linux/module.h> #include <linux/module.h>
#include <linux/kernel.h>
/*
* Nonzero if YEAR is a leap year (every 4 years,
* except every 100th isn't, and every 400th is).
*/
static int __isleap(long year)
{
return (year) % 4 == 0 && ((year) % 100 != 0 || (year) % 400 == 0);
}
/* do a mathdiv for long type */
static long math_div(long a, long b)
{
return a / b - (a % b < 0);
}
/* How many leap years between y1 and y2, y1 must less or equal to y2 */
static long leaps_between(long y1, long y2)
{
long leaps1 = math_div(y1 - 1, 4) - math_div(y1 - 1, 100)
+ math_div(y1 - 1, 400);
long leaps2 = math_div(y2 - 1, 4) - math_div(y2 - 1, 100)
+ math_div(y2 - 1, 400);
return leaps2 - leaps1;
}
/* How many days come before each month (0-12). */
static const unsigned short __mon_yday[2][13] = {
/* Normal years. */
{0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334, 365},
/* Leap years. */
{0, 31, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335, 366}
};
#define SECS_PER_HOUR (60 * 60) #define SECS_PER_HOUR (60 * 60)
#define SECS_PER_DAY (SECS_PER_HOUR * 24) #define SECS_PER_DAY (SECS_PER_HOUR * 24)
@ -77,9 +46,11 @@ static const unsigned short __mon_yday[2][13] = {
*/ */
void time64_to_tm(time64_t totalsecs, int offset, struct tm *result) void time64_to_tm(time64_t totalsecs, int offset, struct tm *result)
{ {
long days, rem, y; u32 u32tmp, day_of_century, year_of_century, day_of_year, month, day;
u64 u64tmp, udays, century, year;
bool is_Jan_or_Feb, is_leap_year;
long days, rem;
int remainder; int remainder;
const unsigned short *ip;
days = div_s64_rem(totalsecs, SECS_PER_DAY, &remainder); days = div_s64_rem(totalsecs, SECS_PER_DAY, &remainder);
rem = remainder; rem = remainder;
@ -103,27 +74,68 @@ void time64_to_tm(time64_t totalsecs, int offset, struct tm *result)
if (result->tm_wday < 0) if (result->tm_wday < 0)
result->tm_wday += 7; result->tm_wday += 7;
y = 1970; /*
* The following algorithm is, basically, Proposition 6.3 of Neri
* and Schneider [1]. In a few words: it works on the computational
* (fictitious) calendar where the year starts in March, month = 2
* (*), and finishes in February, month = 13. This calendar is
* mathematically convenient because the day of the year does not
* depend on whether the year is leap or not. For instance:
*
* March 1st 0-th day of the year;
* ...
* April 1st 31-st day of the year;
* ...
* January 1st 306-th day of the year; (Important!)
* ...
* February 28th 364-th day of the year;
* February 29th 365-th day of the year (if it exists).
*
* After having worked out the date in the computational calendar
* (using just arithmetics) it's easy to convert it to the
* corresponding date in the Gregorian calendar.
*
* [1] "Euclidean Affine Functions and Applications to Calendar
* Algorithms". https://arxiv.org/abs/2102.06959
*
* (*) The numbering of months follows tm more closely and thus,
* is slightly different from [1].
*/
while (days < 0 || days >= (__isleap(y) ? 366 : 365)) { udays = ((u64) days) + 2305843009213814918ULL;
/* Guess a corrected year, assuming 365 days per year. */
long yg = y + math_div(days, 365);
/* Adjust DAYS and Y to match the guessed year. */ u64tmp = 4 * udays + 3;
days -= (yg - y) * 365 + leaps_between(y, yg); century = div64_u64_rem(u64tmp, 146097, &u64tmp);
y = yg; day_of_century = (u32) (u64tmp / 4);
}
result->tm_year = y - 1900; u32tmp = 4 * day_of_century + 3;
u64tmp = 2939745ULL * u32tmp;
year_of_century = upper_32_bits(u64tmp);
day_of_year = lower_32_bits(u64tmp) / 2939745 / 4;
result->tm_yday = days; year = 100 * century + year_of_century;
is_leap_year = year_of_century ? !(year_of_century % 4) : !(century % 4);
ip = __mon_yday[__isleap(y)]; u32tmp = 2141 * day_of_year + 132377;
for (y = 11; days < ip[y]; y--) month = u32tmp >> 16;
continue; day = ((u16) u32tmp) / 2141;
days -= ip[y];
result->tm_mon = y; /*
result->tm_mday = days + 1; * Recall that January 1st is the 306-th day of the year in the
* computational (not Gregorian) calendar.
*/
is_Jan_or_Feb = day_of_year >= 306;
/* Convert to the Gregorian calendar and adjust to Unix time. */
year = year + is_Jan_or_Feb - 6313183731940000ULL;
month = is_Jan_or_Feb ? month - 12 : month;
day = day + 1;
day_of_year += is_Jan_or_Feb ? -306 : 31 + 28 + is_leap_year;
/* Convert to tm's format. */
result->tm_year = (long) (year - 1900);
result->tm_mon = (int) month;
result->tm_mday = (int) day;
result->tm_yday = (int) day_of_year;
} }
EXPORT_SYMBOL(time64_to_tm); EXPORT_SYMBOL(time64_to_tm);