.\" This is -*-nroff-*- .\" XXX standard disclaimer belongs here.... .\" $Header: /cvsroot/pgsql/src/man/Attic/pgbuiltin.3,v 1.9 1997/11/17 22:15:03 momjian Exp $ .TH PGBUILTIN INTRO 04/01/97 PostgreSQL PostgreSQL .SH "DESCRIPTION" This section describes the data types, functions and operators available to users in Postgres as it is distributed. .SH "PGBUILTIN TYPES" This section describes .BR pgbuiltin data types. These Built-in types are installed in every database. .PP Users may add new types to Postgres using the .IR "define type" command described in this manual. User-defined types are not described in this section. .SH "List of built-in types" .PP .if n .ta 5 +15 +40 .if t .ta 0.5i +1.5i +3.0i .in 0 .nf \fBPOSTGRES Type\fP \fBMeaning\fP abstime (absolute) limited-range date and time aclitem access control list item bool boolean box 2-dimensional rectangle bpchar blank-padded characters bytea variable length array of bytes char character char2 array of 2 characters char4 array of 4 characters char8 array of 8 characters char16 array of 16 characters cid command identifier type date ANSI SQL date type datetime general-use date and time filename large object filename int2 two-byte signed integer int28 array of 8 int2 int4 four-byte signed integer float4 single-precision floating-point number float8 double-precision floating-point number lseg 2-dimensional line segment money decimal type with fixed precision name a multi-character type for storing system identifiers oid object identifier type oid8 array of 8 oid oidchar16 oid and char16 composed oidint2 oid and int2 composed oidint4 oid and int4 composed path open or closed line segments point 2-dimensional geometric point polygon 2-dimensional polygon (same as a closed path) circle 2-dimensional circle (center and radius) regproc registered procedure reltime (relative) date and time span (duration) smgr storage manager text variable length array of characters tid tuple identifier type time ANSI SQL time type timespan general-use time span (duration) timestamp limited-range ISO-format date and time tinterval time interval (start and stop abstime) varchar variable-length characters xid transaction identifier type .fi .in .PP There are some data types defined by SQL/92 syntax which are mapped directly into native Postgres types. Note that the "exact numerics" .IR decimal and .IR numeric have fully implemented syntax but currently (postgres v6.2) support only a limited range of the values allowed by SQL/92. .SH "List of SQL/92 types" .PP .if n .ta 5 +15 +25 +40 .if t .ta 0.5i +1.5i +3.0i .in 0 .nf \fBPOSTGRES Type\fP \fBSQL/92 Type\fP \fBMeaning\fP char(n) character(n) fixed-length character string varchar(n) character varying(n) variable-length character string float4/8 float(p) floating-point number with precision p float8 double precision double-precision floating-point number float8 real double-precision floating-point number int2 smallint signed two-byte integer int4 int signed 4-byte integer int4 integer signed 4-byte integer int4 decimal(p,s) exact numeric for p <= 9, s = 0 int4 numeric(p,s) exact numeric for p == 9, s = 0 timestamp timestamp with time zone date/time timespan interval general-use time span .fi .in .PP There are some constants and functions defined in SQL/92. .SH "List of SQL/92 constants" .PP .if n .ta 5 +20 +40 .if t .ta 0.5i +1.5i +3.0i +4.0i .in 0 .nf \fBSQL/92 Function\fP \fBMeaning\fP current_date date of current transaction current_time time of current transaction current_timestamp date and time of current transaction .fi .in .PP Many of the built-in types have obvious external formats. However, several types are either unique to Postgres, such as open and closed paths, or have several possibilities for formats, such as date and time types. .SH "Syntax of date and time types" Most date and time types share code for data input. For those types ( .IR datetime , .IR abstime , .IR timestamp , .IR timespan , .IR reltime , .IR date , and .IR time ) the input can have any of a wide variety of styles. For numeric date representations, European and US conventions can differ, and the proper interpretation is obtained by using the .IR set (l) command before entering data. Output formats can be set to one of three styles: ISO-8601, SQL (traditional Oracle/Ingres), and traditional Postgres (see section on .IR "absolute time" ) with the SQL style having European and US variants (see .IR set (l)). In future releases, the number of date/time types will decrease, with the current implementation of datetime becoming timestamp, timespan becoming interval, and (possibly) abstime and reltime being deprecated in favor of timestamp and interval. .SH "DATETIME" General-use date and time is input using a wide range of styles, including ISO-compatible, SQL-compatible, traditional Postgres (see section on .IR "absolute time") and other permutations of date and time. Output styles can be ISO-compatible, SQL-compatible, or traditional Postgres, with the default set to be compatible with Postgres v6.0. .PP datetime is specified using the following syntax: .PP .nf Year-Month-Day [ Hour : Minute : Second ] [AD,BC] [ Timezone ] .nf YearMonthDay [ Hour : Minute : Second ] [AD,BC] [ Timezone ] .nf Month Day [ Hour : Minute : Second ] Year [AD,BC] [ Timezone ] .sp where Year is 4013 BC, ..., very large Month is Jan, Feb, ..., Dec or 1, 2, ..., 12 Day is 1, 2, ..., 31 Hour is 00, 02, ..., 23 Minute is 00, 01, ..., 59 Second is 00, 01, ..., 59 (60 for leap second) Timezone is 3 characters or ISO offset to GMT .fi .PP Valid dates are from Nov 13 00:00:00 4013 BC GMT to far into the future. Timezones are either three characters (e.g. "GMT" or "PST") or ISO-compatible offsets to GMT (e.g. "-08" or "-08:00" when in Pacific Standard Time). Dates are stored internally in Greenwich Mean Time. Input and output routines translate time to the local time zone of the server. .PP The special values `current', `infinity' and `-infinity' are provided. `infinity' specifies a time later than any valid time, and `-infinity' specifies a time earlier than any valid time. `current' indicates that the current time should be substituted whenever this value appears in a computation. .PP The strings `now', `today', `yesterday', `tomorrow', and `epoch' can be used to specify time values. `now' means the current time, and differs from `current' in that the current time is immediately substituted for it. `epoch' means Jan 1 00:00:00 1970 GMT. .SH "TIMESPAN" General-use time span is input using a wide range of syntaxes, including ISO-compatible, SQL-compatible, traditional Postgres (see section on .IR "relative time" ) and other permutations of time span. Output formats can be ISO-compatible, SQL-compatible, or traditional Postgres, with the default set to be Postgres-compatible. Months and years are a "qualitative" time interval, and are stored separately from the other "quantitative" time intervals such as day or hour. For date arithmetic, the qualitative time units are instantiated in the context of the relevant date or time. .PP Time span is specified with the following syntax: .PP .nf Quantity Unit [Quantity Unit...] [Direction] .nf @ Quantity Unit [Direction] .sp where Quantity is ..., `-1', `0', `1', `2', ... Unit is `second', `minute', `hour', `day', `week', `month', `year', or abbreviations or plurals of these units. Direction is `ago'. .fi .SH "ABSOLUTE TIME" Absolute time (abstime) is a limited-range (+/- 68 years) and limited-precision (1 sec) date data type. .IR "datetime" may be preferred, since it covers a larger range with greater precision. .PP Absolute time is specified using the following syntax: .PP .nf Month Day [ Hour : Minute : Second ] Year [ Timezone ] .sp where Month is Jan, Feb, ..., Dec Day is 1, 2, ..., 31 Hour is 01, 02, ..., 24 Minute is 00, 01, ..., 59 Second is 00, 01, ..., 59 Year is 1901, 1902, ..., 2038 .fi .PP Valid dates are from Dec 13 20:45:53 1901 GMT to Jan 19 03:14:04 2038 GMT. As of Version 3.0, times are no longer read and written using Greenwich Mean Time; the input and output routines default to the local time zone. .PP All special values allowed for .IR "datetime" are also allowed for .IR "absolute time". .SH "RELATIVE TIME" Relative time (reltime) is a limited-range (+/- 68 years) and limited-precision (1 sec) time span data type. .IR "timespan" may be preferred, since it covers a larger range with greater precision, allows multiple units for an entry, and correctly handles qualitative time units such as year and month. For reltime, only one quantity and unit is allowed per entry, which can be inconvenient for complicated time spans. .PP Relative time is specified with the following syntax: .PP .nf @ Quantity Unit [Direction] .sp where Quantity is `1', `2', ... Unit is ``second'', ``minute'', ``hour'', ``day'', ``week'', ``month'' (30-days), or ``year'' (365-days), or PLURAL of these units. Direction is ``ago'' .fi .PP .RB ( Note : Valid relative times are less than or equal to 68 years.) In addition, the special relative time \*(lqUndefined RelTime\*(rq is provided. .SH "TIMESTAMP" This is currently a limited-range absolute time which closely resembles the .IR abstime data type. It shares the general input parser with the other date/time types. In future releases this type will absorb the capabilities of the datetime type and will move toward SQL92 compliance. .PP timestamp is specified using the same syntax as for datetime. .SH "TIME RANGES" Time ranges are specified as: .PP .nf [ 'abstime' 'abstime'] .fi where .IR abstime is a time in the absolute time format. Special abstime values such as \*(lqcurrent\*(rq, \*(lqinfinity\*(rq and \*(lq-infinity\*(rq can be used. .SH "Syntax of geometric types" .SH "POINT" Points are specified using the following syntax: .PP .nf ( x , y ) .nf x , y .sp where x is the x-axis coordinate as a floating point number y is the y-axis coordinate as a floating point number .fi .PP .SH "LSEG" Line segments are represented by pairs of points. .PP lseg is specified using the following syntax: .PP .nf ( ( x1 , y1 ) , ( x2 , y2 ) ) .nf ( x1 , y1 ) , ( x2 , y2 ) .nf x1 , y1 , x2 , y2 .sp where (x1,y1) and (x2,y2) are the endpoints of the segment .fi .PP .SH "BOX" Boxes are represented by pairs of points which are opposite corners of the box. .PP box is specified using the following syntax: .PP .nf ( ( x1 , y1 ) , ( x2 , y2 ) ) .nf ( x1 , y1 ) , ( x2 , y2 ) .nf x1 , y1 , x2 , y2 .sp where (x1,y1) and (x2,y2) are opposite corners .fi .PP Boxes are output using the first syntax. The corners are reordered on input to store the lower left corner first and the upper right corner last. Other corners of the box can be entered, but the lower left and upper right corners are determined from the input and stored. .SH "PATH" Paths are represented by sets of points. Paths can be "open", where the first and last points in the set are not connected, and "closed", where the first and last point are connected. Functions .IR popen(p) and .IR pclose(p) are supplied to force a path to be open or closed, and functions .IR isopen(p) and .IR isclosed(p) are supplied to select either type in a query. .PP path is specified using the following syntax: .PP .nf ( ( x1 , y1 ) , ... , ( xn , yn ) ) .nf [ ( x1 , y1 ) , ... , ( xn , yn ) ] .nf ( x1 , y1 ) , ... , ( xn , yn ) .nf ( x1 , y1 , ... , xn , yn ) .nf x1 , y1 , ... , xn , yn .sp where (x1,y1),...,(xn,yn) are points 1 through n a leading "[" indicates an open path a leading "(" indicates a closed path .fi .PP Paths are output using the first syntax. Note that Postgres versions prior to v6.1 used a format for paths which had a single leading parenthesis, a "closed" flag, an integer count of the number of points, then the list of points followed by a closing parenthesis. The built-in function upgradepath() is supplied to convert paths dumped and reloaded from pre-v6.1 databases. .SH "POLYGON" Polygons are represented by sets of points. Polygons should probably be considered equivalent to closed paths, but are stored differently and have their own set of support routines. .PP polygon is specified using the following syntax: .PP .nf ( ( x1 , y1 ) , ... , ( xn , yn ) ) .nf ( x1 , y1 ) , ... , ( xn , yn ) .nf ( x1 , y1 , ... , xn , yn ) .nf x1 , y1 , ... , xn , yn .sp where (x1,y1),...,(xn,yn) are points 1 through n .fi .PP Polygons are output using the first syntax. The last format is supplied to be backward compatible with v6.0 and earlier path formats and will not be supported in future versions of Postgres. a single leading "(" indicates a v6.0-compatible format ( x1 , ... , xn , y1 , ... , yn ) Note that Postgres versions prior to v6.1 used a format for polygons which had a single leading parenthesis, the list of x-axis coordinates, the list of y-axis coordinates, followed by a closing parenthesis. The built-in function upgradepoly() is supplied to convert polygons dumped and reloaded from pre-v6.1 databases. .SH "CIRCLE" Circles are represented by a center point and a radius. .PP circle is specified using the following syntax: .PP .nf < ( x , y ) , r > .nf ( ( x , y ) , r ) .nf ( x , y ) , r .nf x , y , r .sp where (x,y) is the center of the circle r is the radius of the circle .fi .PP Circles are output using the first syntax. .SH "Built-in operators and functions" .SH OPERATORS Postgres provides a large number of built-in operators on system types. These operators are declared in the system catalog \*(lqpg_operator\*(rq. Every entry in \*(lqpg_operator\*(rq includes the object ID of the procedure that implements the operator. .PP Users may invoke operators using the operator name, as in .nf select * from emp where salary < 40000; .fi Alternatively, users may call the functions that implement the operators directly. In this case, the query above would be expressed as .nf select * from emp where int4lt(salary, 40000); .fi The rest of this section provides a list of the built-in operators and the functions that implement them. Binary operators are listed first, followed by unary operators. .nf Operators: general <\(eq less or equal <> inequality < less than <\(eq greater or equal >\(eq greater or equal > greater than \(eq equality ~ A matches regular expression B, case-sensitive !~ A does not match regular expression B, case-sensitive ~* A matches regular expression B, case-insensitive. !~* A does not match regular expression B, case-insensitive ~~ A matches LIKE expression B, case-sensitive !~~ A does not match LIKE expression B, case-sensitive + addition \(mi subtraction * multiplication / division % modulus @ absolute value geometric @ A contained by (inside or on) B ~ A contains (around or on) B @@ center of object <-> distance between A and B && objects overlap &< A overlaps B, but does not extend to right of B &> A overlaps B, but does not extend to left of B << A is left of B >> A is right of B >^ A is above B <^ A is below B float8 ^ exponentiation % truncate to integer |/ square root ||/ cube root : exponential function ; natural logarithm (in psql, protect with parentheses) point << A is left of B >> A is right of B >^ A is above B <^ A is below B ~\(eq A same as B (equality) @ point inside (or on) path, box, circle, polygon box && boxes overlap &< box A overlaps box B, but does not extend to right of box B &> box A overlaps box B, but does not extend to left of box B << A is left of B >> A is right of B >^ A is above B <^ A is below B \(eq area equal < area less than <\(eq area less or equal >\(eq area greater or equal > area greater than ~\(eq A same as B (equality) @ A is contained in B ~ A contains B @@ center of box polygon && polygons overlap &< A overlaps B but does not extend to right of B &> A overlaps B but does not extend to left of B << A is left of B >> A is right of B ~\(eq A same as B (equality) @ A is contained by B ~ A contains B circle && circles overlap &< A overlaps B but does not extend to right of B &> A overlaps B but does not extend to left of B << A is left of B >> A is right of B >^ A is above B <^ A is below B ~\(eq A same as B (equality) @ A is contained by B ~ A contains B tinterval #<\(eq interval length less or equal reltime #<> interval length not equal to reltime. #< interval length less than reltime #\(eq interval length equal to reltime #>\(eq interval length greater or equal reltime #> interval length greater than reltime && intervals overlap << A contains B \(eq equality <> interval bounded by two abstimes abstime in tinterval | start of interval <#> convert to interval .fi .SH "FUNCTIONS" Many data types have functions available for conversion to other related types. In addition, there are some type-specific functions. Functions which are also available through operators are documented as operators only. .PP Some functions defined for text are also available for char() and varchar(). .PP For the date_part() and date_trunc() functions, arguments can be `year', `month', `day', `hour', `minute', and `second', as well as the more specialized quantities `decade', `century', `millenium', `millisecond', and `microsecond'. date_part() allows `dow' to return day of week and `epoch' to return seconds since 1970 for datetime and 'epoch' to return total elapsed seconds for timespan. .nf Functions: integer float8 float(int) convert integer to floating point float4 float4(int) convert integer to floating point float int integer(float) convert floating point to integer text text lower(text) convert text to lower case text lpad(text,int,text) left pad string to specified length text ltrim(text,text) left trim characters from text text position(text,text) extract specified substring text rpad(text,int,text) right pad string to specified length text rtrim(text,text) right trim characters from text text substr(text,int[,int]) extract specified substring text upper(text) convert text to upper case abstime bool isfinite(abstime) TRUE if this is a finite time datetime datetime(abstime) convert to datetime date datetime datetime(date) convert to datetime datetime datetime(date,time) convert to datetime datetime timespan age(datetime,datetime) date difference preserving months and years float8 date_part(text,datetime) specified portion of date field datetime date_trunc(text,datetime) truncate date at specified units bool isfinite(datetime) TRUE if this is a finite time abstime abstime(datetime) convert to abstime reltime timespan timespan(reltime) convert to timespan time datetime datetime(date,time) convert to datetime timespan float8 date_part(text,timespan) specified portion of time field bool isfinite(timespan) TRUE if this is a finite time reltime reltime(timespan) convert to reltime box box box(point,point) convert points to box float8 area(box) area of box path bool isopen(path) TRUE if this is an open path bool isclosed(path) TRUE if this is a closed path circle circle circle(point,float8) convert to circle polygon polygon(npts,circle) convert to polygon with npts points float8 center(circle) radius of circle float8 radius(circle) radius of circle float8 diameter(circle) diameter of circle float8 area(circle) area of circle .fi .PP SQL/92 defines functions with specific syntax. Some of these are implemented using other Postgres functions. .nf SQL/92 Functions: text text position(text in text) extract specified substring text substring(text [from int] [for int]) extract specified substring text trim([leading|trailing|both] [text] from text) trim characters from text .fi .SH "PSQL HELP" .IR "psq" has a variety of \ed commands for showing system information. Consult those .IR "psql" commands for more listings. .in .SH "SEE ALSO" .IR set (l), .IR show (l), .IR reset (l), .IR psql (1). For examples on specifying literals of built-in types, see .IR SQL (l). .SH BUGS .PP Although most of the input and output functions corresponding to the base types (e.g., integers and floating point numbers) do some error-checking, some are not particularly rigorous about it. More importantly, few of the operators and functions (e.g., addition and multiplication) perform any error-checking at all. Consequently, many of the numeric operators can (for example) silently underflow or overflow. .PP Some of the input and output functions are not invertible. That is, the result of an output function may lose precision when compared to the original input.