The PostgreSQL formatting functions
provide a powerful set of tools for converting various data types
(date/time, integer, floating point, numeric) to formatted strings
and for converting from formatted strings to specific data types.
Table 9-21 lists them.
These functions all follow a common calling convention: the first
argument is the value to be formatted and the second argument is a
template that defines the output or input format.
A single-argument to_timestamp function is also
available; it accepts a
double precision argument and converts from Unix epoch
(seconds since 1970-01-01 00:00:00+00) to
timestamp with time zone.
(Integer Unix epochs are implicitly cast to
double precision.)
Table 9-21. Formatting Functions
Function
Return Type
Description
Example
to_char(timestamp, text)
text
convert time stamp to string
to_char(current_timestamp, 'HH12:MI:SS')
to_char(interval, text)
text
convert interval to string
to_char(interval '15h 2m 12s', 'HH24:MI:SS')
to_char(int, text)
text
convert integer to string
to_char(125, '999')
to_char(double precision,
text)
text
convert real/double precision to string
to_char(125.8::real, '999D9')
to_char(numeric, text)
text
convert numeric to string
to_char(-125.8, '999D99S')
to_date(text, text)
date
convert string to date
to_date('05 Dec 2000', 'DD Mon YYYY')
to_number(text, text)
numeric
convert string to numeric
to_number('12,454.8-', '99G999D9S')
to_timestamp(text, text)
timestamp with time zone
convert string to time stamp
to_timestamp('05 Dec 2000', 'DD Mon YYYY')
to_timestamp(double precision)
timestamp with time zone
convert Unix epoch to time stamp
to_timestamp(1284352323)
In a to_char output template string, there are certain
patterns that are recognized and replaced with appropriately-formatted
data based on the given value. Any text that is not a template pattern is
simply copied verbatim. Similarly, in an input template string (for the
other functions), template patterns identify the values to be supplied by
the input data string.
Table 9-22 shows the
template patterns available for formatting date and time values.
Table 9-22. Template Patterns for Date/Time Formatting
Pattern
Description
HH
hour of day (01-12)
HH12
hour of day (01-12)
HH24
hour of day (00-23)
MI
minute (00-59)
SS
second (00-59)
MS
millisecond (000-999)
US
microsecond (000000-999999)
SSSS
seconds past midnight (0-86399)
AM, am,
PM or pm
meridiem indicator (without periods)
A.M., a.m.,
P.M. or p.m.
meridiem indicator (with periods)
Y,YYY
year (4 or more digits) with comma
YYYY
year (4 or more digits)
YYY
last 3 digits of year
YY
last 2 digits of year
Y
last digit of year
IYYY
ISO 8601 week-numbering year (4 or more digits)
IYY
last 3 digits of ISO 8601 week-numbering year
IY
last 2 digits of ISO 8601 week-numbering year
I
last digit of ISO 8601 week-numbering year
BC, bc,
AD or ad
era indicator (without periods)
B.C., b.c.,
A.D. or a.d.
era indicator (with periods)
MONTH
full upper case month name (blank-padded to 9 chars)
Month
full capitalized month name (blank-padded to 9 chars)
month
full lower case month name (blank-padded to 9 chars)
MON
abbreviated upper case month name (3 chars in English, localized lengths vary)
Mon
abbreviated capitalized month name (3 chars in English, localized lengths vary)
mon
abbreviated lower case month name (3 chars in English, localized lengths vary)
MM
month number (01-12)
DAY
full upper case day name (blank-padded to 9 chars)
Day
full capitalized day name (blank-padded to 9 chars)
day
full lower case day name (blank-padded to 9 chars)
DY
abbreviated upper case day name (3 chars in English, localized lengths vary)
Dy
abbreviated capitalized day name (3 chars in English, localized lengths vary)
dy
abbreviated lower case day name (3 chars in English, localized lengths vary)
DDD
day of year (001-366)
IDDD
day of ISO 8601 week-numbering year (001-371; day 1 of the year is Monday of the first ISO week)
DD
day of month (01-31)
D
day of the week, Sunday (1) to Saturday (7)
ID
ISO 8601 day of the week, Monday (1) to Sunday (7)
W
week of month (1-5) (the first week starts on the first day of the month)
WW
week number of year (1-53) (the first week starts on the first day of the year)
IW
week number of ISO 8601 week-numbering year (01-53; the first Thursday of the year is in week 1)
CC
century (2 digits) (the twenty-first century starts on 2001-01-01)
J
Julian Day (days since November 24, 4714 BC at midnight)
Q
quarter (ignored by to_date and to_timestamp)
RM
month in upper case Roman numerals (I-XII; I=January)
rm
month in lower case Roman numerals (i-xii; i=January)
TZ
upper case time-zone name
tz
lower case time-zone name
Modifiers can be applied to any template pattern to alter its
behavior. For example, FMMonth
is the Month pattern with the
FM modifier.
Table 9-23 shows the
modifier patterns for date/time formatting.
Table 9-23. Template Pattern Modifiers for Date/Time Formatting
Modifier
Description
Example
FM prefix
fill mode (suppress leading zeroes and padding blanks)
FMMonth
TH suffix
upper case ordinal number suffix
DDTH, e.g., 12TH
th suffix
lower case ordinal number suffix
DDth, e.g., 12th
FX prefix
fixed format global option (see usage notes)
FX Month DD Day
TM prefix
translation mode (print localized day and month names based on
lc_time)
TMMonth
SP suffix
spell mode (not implemented)
DDSP
Usage notes for date/time formatting:
FM suppresses leading zeroes and trailing blanks
that would otherwise be added to make the output of a pattern be
fixed-width. In PostgreSQL,
FM modifies only the next specification, while in
Oracle FM affects all subsequent
specifications, and repeated FM modifiers
toggle fill mode on and off.
TM does not include trailing blanks.
to_timestamp and to_date
skip multiple blank spaces in the input string unless the
FX option is used. For example,
to_timestamp('2000 JUN', 'YYYY MON') works, but
to_timestamp('2000 JUN', 'FXYYYY MON') returns an error
because to_timestamp expects one space only.
FX must be specified as the first item in
the template.
Ordinary text is allowed in to_char
templates and will be output literally. You can put a substring
in double quotes to force it to be interpreted as literal text
even if it contains pattern key words. For example, in
'"Hello Year "YYYY', the YYYY
will be replaced by the year data, but the single Y in Year
will not be. In to_date, to_number,
and to_timestamp, double-quoted strings skip the number of
input characters contained in the string, e.g. "XX"
skips two input characters.
If you want to have a double quote in the output you must
precede it with a backslash, for example '\"YYYY
Month\"'.
The YYYY conversion from string to timestamp or
date has a restriction when processing years with more than 4 digits. You must
use some non-digit character or template after YYYY,
otherwise the year is always interpreted as 4 digits. For example
(with the year 20000):
to_date('200001131', 'YYYYMMDD') will be
interpreted as a 4-digit year; instead use a non-digit
separator after the year, like
to_date('20000-1131', 'YYYY-MMDD') or
to_date('20000Nov31', 'YYYYMonDD').
In conversions from string to timestamp or
date, the CC (century) field is ignored
if there is a YYY, YYYY or
Y,YYY field. If CC is used with
YY or Y then the year is computed
as (CC-1)*100+YY.
An ISO 8601 week-numbering date (as distinct from a Gregorian date)
can be specified to to_timestamp and
to_date in one of two ways:
Year, week number, and weekday: for
example to_date('2006-42-4', 'IYYY-IW-ID')
returns the date 2006-10-19.
If you omit the weekday it is assumed to be 1 (Monday).
Year and day of year: for example to_date('2006-291',
'IYYY-IDDD') also returns 2006-10-19.
Attempting to enter a date using a mixture of ISO 8601 week-numbering
fields and Gregorian date fields is nonsensical, and will cause an
error. In the context of an ISO 8601 week-numbering year, the
concept of a "month" or "day of month" has no
meaning. In the context of a Gregorian year, the ISO week has no
meaning.
Caution
While to_date will reject a mixture of
Gregorian and ISO week-numbering date
fields, to_char will not, since output format
specifications like YYYY-MM-DD (IYYY-IDDD) can be
useful. But avoid writing something like IYYY-MM-DD;
that would yield surprising results near the start of the year.
(See Section 9.9.1 for more
information.)
In a conversion from string to timestamp, millisecond
(MS) or microsecond (US)
values are used as the
seconds digits after the decimal point. For example
to_timestamp('12:3', 'SS:MS') is not 3 milliseconds,
but 300, because the conversion counts it as 12 + 0.3 seconds.
This means for the format SS:MS, the input values
12:3, 12:30, and 12:300 specify the
same number of milliseconds. To get three milliseconds, one must use
12:003, which the conversion counts as
12 + 0.003 = 12.003 seconds.
Here is a more
complex example:
to_timestamp('15:12:02.020.001230', 'HH:MI:SS.MS.US')
is 15 hours, 12 minutes, and 2 seconds + 20 milliseconds +
1230 microseconds = 2.021230 seconds.
to_char(..., 'ID')'s day of the week numbering
matches the extract(isodow from ...) function, but
to_char(..., 'D')'s does not match
extract(dow from ...)'s day numbering.
to_char(interval) formats HH and
HH12 as shown on a 12-hour clock, i.e. zero hours
and 36 hours output as 12, while HH24
outputs the full hour value, which can exceed 23 for intervals.
Table 9-24 shows the
template patterns available for formatting numeric values.
Table 9-24. Template Patterns for Numeric Formatting
Pattern
Description
9
value with the specified number of digits
0
value with leading zeros
. (period)
decimal point
, (comma)
group (thousand) separator
PR
negative value in angle brackets
S
sign anchored to number (uses locale)
L
currency symbol (uses locale)
D
decimal point (uses locale)
G
group separator (uses locale)
MI
minus sign in specified position (if number < 0)
PL
plus sign in specified position (if number > 0)
SG
plus/minus sign in specified position
RN
Roman numeral (input between 1 and 3999)
TH or th
ordinal number suffix
V
shift specified number of digits (see notes)
EEEE
exponent for scientific notation
Usage notes for numeric formatting:
A sign formatted using SG, PL, or
MI is not anchored to
the number; for example,
to_char(-12, 'MI9999') produces '- 12'
but to_char(-12, 'S9999') produces ' -12'.
The Oracle implementation does not allow the use of
MI before 9, but rather
requires that 9 precede
MI.
9 results in a value with the same number of
digits as there are 9s. If a digit is
not available it outputs a space.
TH does not convert values less than zero
and does not convert fractional numbers.
PL, SG, and
TH are PostgreSQL
extensions.
V effectively
multiplies the input values by
10^n, where
n is the number of digits following
V.
to_char does not support the use of
V combined with a decimal point
(e.g., 99.9V99 is not allowed).
EEEE (scientific notation) cannot be used in
combination with any of the other formatting patterns or
modifiers other than digit and decimal point patterns, and must be at the end of the format string
(e.g., 9.99EEEE is a valid pattern).
Certain modifiers can be applied to any template pattern to alter its
behavior. For example, FM9999
is the 9999 pattern with the
FM modifier.
Table 9-25 shows the
modifier patterns for numeric formatting.
Table 9-25. Template Pattern Modifiers for Numeric Formatting
Modifier
Description
Example
FM prefix
fill mode (suppress leading zeroes and padding blanks)
FM9999
TH suffix
upper case ordinal number suffix
999TH
th suffix
lower case ordinal number suffix
999th
Table 9-26 shows some
examples of the use of the to_char function.