PostgreSQL
9.9. Date/Time Functions and Operators
Table 9.30 shows the available functions for date/time value processing, with details appearing in the following subsections. Table 9.29 illustrates the behaviors of the basic arithmetic operators (+
, *
, etc.). For formatting functions, refer to Section 9.8. You should be familiar with the background information on date/time data types from Section 8.5.
In addition, the usual comparison operators shown in Table 9.1 are available for the date/time types. Dates and timestamps (with or without time zone) are all comparable, while times (with or without time zone) and intervals can only be compared to other values of the same data type. When comparing a timestamp without time zone to a timestamp with time zone, the former value is assumed to be given in the time zone specified by the TimeZone configuration parameter, and is rotated to UTC for comparison to the latter value (which is already in UTC internally). Similarly, a date value is assumed to represent midnight in the TimeZone
zone when comparing it to a timestamp.
All the functions and operators described below that take time
or timestamp
inputs actually come in two variants: one that takes time with time zone
or timestamp with time zone
, and one that takes time without time zone
or timestamp without time zone
. For brevity, these variants are not shown separately. Also, the +
and *
operators come in commutative pairs (for example both date + integer and integer + date); we show only one of each such pair.
Table 9.29. Date/Time Operators
Operator | Example | Result |
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+
Table 9.30. Date/Time Functions
Function | Return Type | Description | Example | Result |
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Subtract arguments, producing a “[.quote]#symbolic”# result that uses years and months, rather than just days |
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Subtract from |
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Current date and time (changes during statement execution); see Section 9.9.4 |
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Current date; see Section 9.9.4 |
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Current time of day; see Section 9.9.4 |
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Current date and time (start of current transaction); see Section 9.9.4 |
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Get subfield (equivalent to |
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Get subfield (equivalent to |
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Truncate to specified precision; see also Section 9.9.2 |
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Truncate to specified precision; see also Section 9.9.2 |
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Get subfield; see Section 9.9.1 |
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Get subfield; see Section 9.9.1 |
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Test for finite date (not +/-infinity) |
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Test for finite time stamp (not +/-infinity) |
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Test for finite interval |
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Adjust interval so 30-day time periods are represented as months |
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Adjust interval so 24-hour time periods are represented as days |
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Adjust interval using |
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Current time of day; see Section 9.9.4 |
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Current date and time (start of current transaction); see Section 9.9.4 |
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Create date from year, month and day fields |
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Create interval from years, months, weeks, days, hours, minutes and seconds fields |
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Create time from hour, minute and seconds fields |
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Create timestamp from year, month, day, hour, minute and seconds fields |
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Create timestamp with time zone from year, month, day, hour, minute and seconds fields; if `timezone` is not specified, the current time zone is used |
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Current date and time (start of current transaction); see Section 9.9.4 |
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Current date and time (start of current statement); see Section 9.9.4 |
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Current date and time (like |
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Current date and time (start of current transaction); see Section 9.9.4 |
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Convert Unix epoch (seconds since 1970-01-01 00:00:00+00) to timestamp |
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+
In addition to these functions, the SQL `+OVERLAPS+` operator is supported:
(start1, end1) OVERLAPS (start2, end2)
(start1, length1) OVERLAPS (start2, length2)
This expression yields true when two time periods (defined by their endpoints) overlap, false when they do not overlap. The endpoints can be specified as pairs of dates, times, or time stamps; or as a date, time, or time stamp followed by an interval. When a pair of values is provided, either the start or the end can be written first; OVERLAPS
automatically takes the earlier value of the pair as the start. Each time period is considered to represent the half-open interval `start `<= `time
`< `end
, unless start
and end` are equal in which case it represents that single time instant. This means for instance that two time periods with only an endpoint in common do not overlap.
SELECT (DATE '2001-02-16', DATE '2001-12-21') OVERLAPS
(DATE '2001-10-30', DATE '2002-10-30');
Result: true
SELECT (DATE '2001-02-16', INTERVAL '100 days') OVERLAPS
(DATE '2001-10-30', DATE '2002-10-30');
Result: false
SELECT (DATE '2001-10-29', DATE '2001-10-30') OVERLAPS
(DATE '2001-10-30', DATE '2001-10-31');
Result: false
SELECT (DATE '2001-10-30', DATE '2001-10-30') OVERLAPS
(DATE '2001-10-30', DATE '2001-10-31');
Result: true
When adding an interval
value to (or subtracting an interval
value from) a timestamp with time zone
value, the days component advances or decrements the date of the timestamp with time zone
by the indicated number of days, keeping the time of day the same. Across daylight saving time changes (when the session time zone is set to a time zone that recognizes DST), this means interval '1 day'
does not necessarily equal interval '24 hours'
. For example, with the session time zone set to America/Denver
:
SELECT timestamp with time zone '2005-04-02 12:00:00-07' + interval '1 day';
Result: 2005-04-03 12:00:00-06
SELECT timestamp with time zone '2005-04-02 12:00:00-07' + interval '24 hours';
Result: 2005-04-03 13:00:00-06
This happens because an hour was skipped due to a change in daylight saving time at 2005-04-03 02:00:00
in time zone America/Denver
.
Note there can be ambiguity in the months
field returned by age
because different months have different numbers of days. PostgreSQL’s approach uses the month from the earlier of the two dates when calculating partial months. For example, age('2004-06-01', '2004-04-30')
uses April to yield 1 mon 1 day
, while using May would yield 1 mon 2 days
because May has 31 days, while April has only 30.
Subtraction of dates and timestamps can also be complex. One conceptually simple way to perform subtraction is to convert each value to a number of seconds using EXTRACT(EPOCH FROM ...)
, then subtract the results; this produces the number of seconds between the two values. This will adjust for the number of days in each month, timezone changes, and daylight saving time adjustments. Subtraction of date or timestamp values with the “[.quote]-
” operator returns the number of days (24-hours) and hours/minutes/seconds between the values, making the same adjustments. The age
function returns years, months, days, and hours/minutes/seconds, performing field-by-field subtraction and then adjusting for negative field values. The following queries illustrate the differences in these approaches. The sample results were produced with timezone = 'US/Eastern'
; there is a daylight saving time change between the two dates used:
SELECT EXTRACT(EPOCH FROM timestamptz '2013-07-01 12:00:00') -
EXTRACT(EPOCH FROM timestamptz '2013-03-01 12:00:00');
Result: 10537200
SELECT (EXTRACT(EPOCH FROM timestamptz '2013-07-01 12:00:00') -
EXTRACT(EPOCH FROM timestamptz '2013-03-01 12:00:00'))
/ 60 / 60 / 24;
Result: 121.958333333333
SELECT timestamptz '2013-07-01 12:00:00' - timestamptz '2013-03-01 12:00:00';
Result: 121 days 23:00:00
SELECT age(timestamptz '2013-07-01 12:00:00', timestamptz '2013-03-01 12:00:00');
Result: 4 mons
9.9.1. EXTRACT
, date_part
EXTRACT(field FROM source)
The extract
function retrieves subfields such as year or hour from date/time values. `source must be a value expression of type `timestamp,
time
, or interval
. (Expressions of type date
are cast to timestamp
and can therefore be used as well.) `field is an identifier or string that selects what field to extract from the source value. The `extract function returns values of type
double precision
. The following are valid field names:
century
-
The century +
SELECT EXTRACT(CENTURY FROM TIMESTAMP '2000-12-16 12:21:13');
Result: 20
SELECT EXTRACT(CENTURY FROM TIMESTAMP '2001-02-16 20:38:40');
Result: 21
+ The first century starts at 0001-01-01 00:00:00 AD, although they did not know it at the time. This definition applies to all Gregorian calendar countries. There is no century number 0, you go from -1 century to 1 century. If you disagree with this, please write your complaint to: Pope, Cathedral Saint-Peter of Roma, Vatican. [.term]#`+day+`#:: For `+timestamp+` values, the day (of the month) field (1 - 31) ; for `+interval+` values, the number of days +
SELECT EXTRACT(DAY FROM TIMESTAMP '2001-02-16 20:38:40');
Result: 16
SELECT EXTRACT(DAY FROM INTERVAL '40 days 1 minute');
Result: 40
decade
-
The year field divided by 10 +
SELECT EXTRACT(DECADE FROM TIMESTAMP '2001-02-16 20:38:40');
Result: 200
dow
-
The day of the week as Sunday (
0
) to Saturday (6
) +
SELECT EXTRACT(DOW FROM TIMESTAMP '2001-02-16 20:38:40');
Result: 5
+ Note that `+extract+`'s day of the week numbering differs from that of the `+to_char(..., 'D')+` function. [.term]#`+doy+`#:: The day of the year (1 - 365/366) +
SELECT EXTRACT(DOY FROM TIMESTAMP '2001-02-16 20:38:40');
Result: 47
epoch
-
For
timestamp with time zone
values, the number of seconds since 1970-01-01 00:00:00 UTC (negative for timestamps before that); fordate
andtimestamp
values, the nominal number of seconds since 1970-01-01 00:00:00, without regard to timezone or daylight-savings rules; forinterval
values, the total number of seconds in the interval +
SELECT EXTRACT(EPOCH FROM TIMESTAMP WITH TIME ZONE '2001-02-16 20:38:40.12-08');
Result: 982384720.12
SELECT EXTRACT(EPOCH FROM TIMESTAMP '2001-02-16 20:38:40.12');
Result: 982355920.12
SELECT EXTRACT(EPOCH FROM INTERVAL '5 days 3 hours');
Result: 442800
+ You can convert an epoch value back to a `+timestamp with time zone+` with `+to_timestamp+`: +
SELECT to_timestamp(982384720.12);
Result: 2001-02-17 04:38:40.12+00
+ Beware that applying `+to_timestamp+` to an epoch extracted from a `+date+` or `+timestamp+` value could produce a misleading result: the result will effectively assume that the original value had been given in UTC, which might not be the case. [.term]#`+hour+`#:: The hour field (0 - 23) +
SELECT EXTRACT(HOUR FROM TIMESTAMP '2001-02-16 20:38:40');
Result: 20
isodow
-
The day of the week as Monday (
1
) to Sunday (7
) +
SELECT EXTRACT(ISODOW FROM TIMESTAMP '2001-02-18 20:38:40');
Result: 7
+ This is identical to `+dow+` except for Sunday. This matches the ISO 8601 day of the week numbering. [.term]#`+isoyear+`#:: The ISO 8601 week-numbering year that the date falls in (not applicable to intervals) +
SELECT EXTRACT(ISOYEAR FROM DATE '2006-01-01');
Result: 2005
SELECT EXTRACT(ISOYEAR FROM DATE '2006-01-02');
Result: 2006
+ Each ISO 8601 week-numbering year begins with the Monday of the week containing the 4th of January, so in early January or late December the ISO year may be different from the Gregorian year. See the `+week+` field for more information. + This field is not available in PostgreSQL releases prior to 8.3. [.term]#`+julian+`#:: The _Julian Date_ corresponding to the date or timestamp (not applicable to intervals). Timestamps that are not local midnight result in a fractional value. See link:datetime-julian-dates.html[Section B.7] for more information. +
SELECT EXTRACT(JULIAN FROM DATE '2006-01-01');
Result: 2453737
SELECT EXTRACT(JULIAN FROM TIMESTAMP '2006-01-01 12:00');
Result: 2453737.5
microseconds
-
The seconds field, including fractional parts, multiplied by 1 000 000; note that this includes full seconds +
SELECT EXTRACT(MICROSECONDS FROM TIME '17:12:28.5');
Result: 28500000
millennium
-
The millennium +
SELECT EXTRACT(MILLENNIUM FROM TIMESTAMP '2001-02-16 20:38:40');
Result: 3
+ Years in the 1900s are in the second millennium. The third millennium started January 1, 2001. [.term]#`+milliseconds+`#:: The seconds field, including fractional parts, multiplied by 1000. Note that this includes full seconds. +
SELECT EXTRACT(MILLISECONDS FROM TIME '17:12:28.5');
Result: 28500
minute
-
The minutes field (0 - 59) +
SELECT EXTRACT(MINUTE FROM TIMESTAMP '2001-02-16 20:38:40');
Result: 38
month
-
For
timestamp
values, the number of the month within the year (1 - 12) ; forinterval
values, the number of months, modulo 12 (0 - 11) +
SELECT EXTRACT(MONTH FROM TIMESTAMP '2001-02-16 20:38:40');
Result: 2
SELECT EXTRACT(MONTH FROM INTERVAL '2 years 3 months');
Result: 3
SELECT EXTRACT(MONTH FROM INTERVAL '2 years 13 months');
Result: 1
quarter
-
The quarter of the year (1 - 4) that the date is in +
SELECT EXTRACT(QUARTER FROM TIMESTAMP '2001-02-16 20:38:40');
Result: 1
second
-
The seconds field, including fractional parts (0 - 59[7]) +
SELECT EXTRACT(SECOND FROM TIMESTAMP '2001-02-16 20:38:40');
Result: 40
SELECT EXTRACT(SECOND FROM TIME '17:12:28.5');
Result: 28.5
timezone
-
The time zone offset from UTC, measured in seconds. Positive values correspond to time zones east of UTC, negative values to zones west of UTC. (Technically, PostgreSQL does not use UTC because leap seconds are not handled.)
timezone_hour
-
The hour component of the time zone offset
timezone_minute
-
The minute component of the time zone offset
week
-
The number of the ISO 8601 week-numbering week of the year. By definition, ISO weeks start on Mondays and the first week of a year contains January 4 of that year. In other words, the first Thursday of a year is in week 1 of that year. + In the ISO week-numbering system, it is possible for early-January dates to be part of the 52nd or 53rd week of the previous year, and for late-December dates to be part of the first week of the next year. For example,
2005-01-01
is part of the 53rd week of year 2004, and2006-01-01
is part of the 52nd week of year 2005, while2012-12-31
is part of the first week of 2013. It’s recommended to use theisoyear
field together withweek
to get consistent results. +
SELECT EXTRACT(WEEK FROM TIMESTAMP '2001-02-16 20:38:40');
Result: 7
year
-
The year field. Keep in mind there is no
0 AD
, so subtractingBC
years fromAD
years should be done with care. +
SELECT EXTRACT(YEAR FROM TIMESTAMP '2001-02-16 20:38:40');
Result: 2001
Note
When the input value is /-Infinity, `+extract` returns /-Infinity for monotonically-increasing fields (`+epoch, `julian
, year
, isoyear
, decade
, century
, and millennium
). For other fields, NULL is returned. PostgreSQL versions before 9.6 returned zero for all cases of infinite input.
The extract
function is primarily intended for computational processing. For formatting date/time values for display, see Section 9.8.
The date_part
function is modeled on the traditional Ingres equivalent to the SQL-standard function extract
:
date_part('field', source)
Note that here the `field parameter needs to be a string value, not a name. The valid field names for `date_part are the same as for
extract
.
SELECT date_part('day', TIMESTAMP '2001-02-16 20:38:40');
Result: 16
SELECT date_part('hour', INTERVAL '4 hours 3 minutes');
Result: 4
9.9.2. date_trunc
The function date_trunc
is conceptually similar to the trunc
function for numbers.
date_trunc('field', source)
`source is a value expression of type `timestamp or
interval
. (Values of type date
and time
are cast automatically to timestamp
or interval
, respectively.) `field selects to which precision to truncate the input value. The return value is of type `timestamp or
interval
with all fields that are less significant than the selected one set to zero (or one, for day and month).
Valid values for `field` are:
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Examples:
SELECT date_trunc('hour', TIMESTAMP '2001-02-16 20:38:40');
Result: 2001-02-16 20:00:00
SELECT date_trunc('year', TIMESTAMP '2001-02-16 20:38:40');
Result: 2001-01-01 00:00:00
9.9.3. AT TIME ZONE
The AT TIME ZONE
converts time stamp without time zone to/from time stamp with time zone, and time values to different time zones. Table 9.31 shows its variants.
Table 9.31. AT TIME ZONE
Variants
Expression | Return Type | Description |
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Treat given time stamp without time zone as located in the specified time zone |
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Convert given time stamp with time zone to the new time zone, with no time zone designation |
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Convert given time with time zone to the new time zone |
+
In these expressions, the desired time zone `zone can be specified either as a text string (e.g., `'America/Los_Angeles') or as an interval (e.g.,
INTERVAL '-08:00'
). In the text case, a time zone name can be specified in any of the ways described in Section 8.5.3.
Examples (assuming the local time zone is America/Los_Angeles
):
SELECT TIMESTAMP '2001-02-16 20:38:40' AT TIME ZONE 'America/Denver';
Result: 2001-02-16 19:38:40-08
SELECT TIMESTAMP WITH TIME ZONE '2001-02-16 20:38:40-05' AT TIME ZONE 'America/Denver';
Result: 2001-02-16 18:38:40
SELECT TIMESTAMP '2001-02-16 20:38:40-05' AT TIME ZONE 'Asia/Tokyo' AT TIME ZONE 'America/Chicago';
Result: 2001-02-16 05:38:40
The first example adds a time zone to a value that lacks it, and displays the value using the current TimeZone
setting. The second example shifts the time stamp with time zone value to the specified time zone, and returns the value without a time zone. This allows storage and display of values different from the current TimeZone
setting. The third example converts Tokyo time to Chicago time. Converting time values to other time zones uses the currently active time zone rules since no date is supplied.
The function timezone`
(zone
, +`_`+timestamp
)` is equivalent to the SQL-conforming construct _`timestamp
+ AT TIME ZONE `_`+zone`_.
9.9.4. Current Date/Time
PostgreSQL provides a number of functions that return values related to the current date and time. These SQL-standard functions all return values based on the start time of the current transaction:
CURRENT_DATE
CURRENT_TIME
CURRENT_TIMESTAMP
CURRENT_TIME(precision)
CURRENT_TIMESTAMP(precision)
LOCALTIME
LOCALTIMESTAMP
LOCALTIME(precision)
LOCALTIMESTAMP(precision)
CURRENT_TIME
and CURRENT_TIMESTAMP
deliver values with time zone; LOCALTIME
and LOCALTIMESTAMP
deliver values without time zone.
CURRENT_TIME
, CURRENT_TIMESTAMP
, LOCALTIME
, and LOCALTIMESTAMP
can optionally take a precision parameter, which causes the result to be rounded to that many fractional digits in the seconds field. Without a precision parameter, the result is given to the full available precision.
Some examples:
SELECT CURRENT_TIME;
Result: 14:39:53.662522-05
SELECT CURRENT_DATE;
Result: 2001-12-23
SELECT CURRENT_TIMESTAMP;
Result: 2001-12-23 14:39:53.662522-05
SELECT CURRENT_TIMESTAMP(2);
Result: 2001-12-23 14:39:53.66-05
SELECT LOCALTIMESTAMP;
Result: 2001-12-23 14:39:53.662522
Since these functions return the start time of the current transaction, their values do not change during the transaction. This is considered a feature: the intent is to allow a single transaction to have a consistent notion of the “[.quote]#current”# time, so that multiple modifications within the same transaction bear the same time stamp.
Note
Other database systems might advance these values more frequently.
PostgreSQL also provides functions that return the start time of the current statement, as well as the actual current time at the instant the function is called. The complete list of non-SQL-standard time functions is:
transaction_timestamp()
statement_timestamp()
clock_timestamp()
timeofday()
now()
transaction_timestamp()
is equivalent to CURRENT_TIMESTAMP
, but is named to clearly reflect what it returns. statement_timestamp()
returns the start time of the current statement (more specifically, the time of receipt of the latest command message from the client). statement_timestamp()
and transaction_timestamp()
return the same value during the first command of a transaction, but might differ during subsequent commands. clock_timestamp()
returns the actual current time, and therefore its value changes even within a single SQL command. timeofday()
is a historical PostgreSQL function. Like clock_timestamp()
, it returns the actual current time, but as a formatted text
string rather than a timestamp with time zone
value. now()
is a traditional PostgreSQL equivalent to transaction_timestamp()
.
All the date/time data types also accept the special literal value now
to specify the current date and time (again, interpreted as the transaction start time). Thus, the following three all return the same result:
SELECT CURRENT_TIMESTAMP;
SELECT now();
SELECT TIMESTAMP 'now'; -- but see tip below
Tip
Do not use the third form when specifying a value to be evaluated later, for example in a DEFAULT
clause for a table column. The system will convert now
to a timestamp
as soon as the constant is parsed, so that when the default value is needed, the time of the table creation would be used! The first two forms will not be evaluated until the default value is used, because they are function calls. Thus they will give the desired behavior of defaulting to the time of row insertion. (See also Section 8.5.1.4.)
9.9.5. Delaying Execution
The following functions are available to delay execution of the server process:
pg_sleep(seconds)
pg_sleep_for(interval)
pg_sleep_until(timestamp with time zone)
pg_sleep
makes the current session’s process sleep until `seconds seconds have elapsed. seconds
is a value of type `double precision, so fractional-second delays can be specified.
pg_sleep_for
is a convenience function for larger sleep times specified as an interval
. pg_sleep_until
is a convenience function for when a specific wake-up time is desired. For example:
SELECT pg_sleep(1.5);
SELECT pg_sleep_for('5 minutes');
SELECT pg_sleep_until('tomorrow 03:00');
Note
The effective resolution of the sleep interval is platform-specific; 0.01 seconds is a common value. The sleep delay will be at least as long as specified. It might be longer depending on factors such as server load. In particular, pg_sleep_until
is not guaranteed to wake up exactly at the specified time, but it will not wake up any earlier.
Warning
Make sure that your session does not hold more locks than necessary when calling pg_sleep
or its variants. Otherwise other sessions might have to wait for your sleeping process, slowing down the entire system.
+
[7] 60 if leap seconds are implemented by the operating system
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---|---|---|
9.8. Data Type Formatting Functions |
9.10. Enum Support Functions |
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