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36.2. The PostgreSQL Type System #

   36.2.1. Base Types
   36.2.2. Container Types
   36.2.3. Domains
   36.2.4. Pseudo-Types
   36.2.5. Polymorphic Types

   PostgreSQL data types can be divided into base types, container types,
   domains, and pseudo-types.

36.2.1. Base Types #

   Base types are those, like integer, that are implemented below the
   level of the SQL language (typically in a low-level language such as
   C). They generally correspond to what are often known as abstract data
   types. PostgreSQL can only operate on such types through functions
   provided by the user and only understands the behavior of such types to
   the extent that the user describes them. The built-in base types are
   described in Chapter 8.

   Enumerated (enum) types can be considered as a subcategory of base
   types. The main difference is that they can be created using just SQL
   commands, without any low-level programming. Refer to Section 8.7 for
   more information.

36.2.2. Container Types #

   PostgreSQL has three kinds of “container” types, which are types that
   contain multiple values of other types. These are arrays, composites,
   and ranges.

   Arrays can hold multiple values that are all of the same type. An array
   type is automatically created for each base type, composite type, range
   type, and domain type. But there are no arrays of arrays. So far as the
   type system is concerned, multi-dimensional arrays are the same as
   one-dimensional arrays. Refer to Section 8.15 for more information.

   Composite types, or row types, are created whenever the user creates a
   table. It is also possible to use CREATE TYPE to define a “stand-alone”
   composite type with no associated table. A composite type is simply a
   list of types with associated field names. A value of a composite type
   is a row or record of field values. Refer to Section 8.16 for more
   information.

   A range type can hold two values of the same type, which are the lower
   and upper bounds of the range. Range types are user-created, although a
   few built-in ones exist. Refer to Section 8.17 for more information.

36.2.3. Domains #

   A domain is based on a particular underlying type and for many purposes
   is interchangeable with its underlying type. However, a domain can have
   constraints that restrict its valid values to a subset of what the
   underlying type would allow. Domains are created using the SQL command
   CREATE DOMAIN. Refer to Section 8.18 for more information.

36.2.4. Pseudo-Types #

   There are a few “pseudo-types” for special purposes. Pseudo-types
   cannot appear as columns of tables or components of container types,
   but they can be used to declare the argument and result types of
   functions. This provides a mechanism within the type system to identify
   special classes of functions. Table 8.27 lists the existing
   pseudo-types.

36.2.5. Polymorphic Types #

   Some pseudo-types of special interest are the polymorphic types, which
   are used to declare polymorphic functions. This powerful feature allows
   a single function definition to operate on many different data types,
   with the specific data type(s) being determined by the data types
   actually passed to it in a particular call. The polymorphic types are
   shown in Table 36.1. Some examples of their use appear in
   Section 36.5.11.

   Table 36.1. Polymorphic Types
   Name Family Description
   anyelement Simple Indicates that a function accepts any data type
   anyarray Simple Indicates that a function accepts any array data type
   anynonarray Simple Indicates that a function accepts any non-array data
   type
   anyenum Simple Indicates that a function accepts any enum data type
   (see Section 8.7)
   anyrange Simple Indicates that a function accepts any range data type
   (see Section 8.17)
   anymultirange Simple Indicates that a function accepts any multirange
   data type (see Section 8.17)
   anycompatible Common Indicates that a function accepts any data type,
   with automatic promotion of multiple arguments to a common data type
   anycompatiblearray Common Indicates that a function accepts any array
   data type, with automatic promotion of multiple arguments to a common
   data type
   anycompatiblenonarray Common Indicates that a function accepts any
   non-array data type, with automatic promotion of multiple arguments to
   a common data type
   anycompatiblerange Common Indicates that a function accepts any range
   data type, with automatic promotion of multiple arguments to a common
   data type
   anycompatiblemultirange Common Indicates that a function accepts any
   multirange data type, with automatic promotion of multiple arguments to
   a common data type

   Polymorphic arguments and results are tied to each other and are
   resolved to specific data types when a query calling a polymorphic
   function is parsed. When there is more than one polymorphic argument,
   the actual data types of the input values must match up as described
   below. If the function's result type is polymorphic, or it has output
   parameters of polymorphic types, the types of those results are deduced
   from the actual types of the polymorphic inputs as described below.

   For the “simple” family of polymorphic types, the matching and
   deduction rules work like this:

   Each position (either argument or return value) declared as anyelement
   is allowed to have any specific actual data type, but in any given call
   they must all be the same actual type. Each position declared as
   anyarray can have any array data type, but similarly they must all be
   the same type. And similarly, positions declared as anyrange must all
   be the same range type. Likewise for anymultirange.

   Furthermore, if there are positions declared anyarray and others
   declared anyelement, the actual array type in the anyarray positions
   must be an array whose elements are the same type appearing in the
   anyelement positions. anynonarray is treated exactly the same as
   anyelement, but adds the additional constraint that the actual type
   must not be an array type. anyenum is treated exactly the same as
   anyelement, but adds the additional constraint that the actual type
   must be an enum type.

   Similarly, if there are positions declared anyrange and others declared
   anyelement or anyarray, the actual range type in the anyrange positions
   must be a range whose subtype is the same type appearing in the
   anyelement positions and the same as the element type of the anyarray
   positions. If there are positions declared anymultirange, their actual
   multirange type must contain ranges matching parameters declared
   anyrange and base elements matching parameters declared anyelement and
   anyarray.

   Thus, when more than one argument position is declared with a
   polymorphic type, the net effect is that only certain combinations of
   actual argument types are allowed. For example, a function declared as
   equal(anyelement, anyelement) will take any two input values, so long
   as they are of the same data type.

   When the return value of a function is declared as a polymorphic type,
   there must be at least one argument position that is also polymorphic,
   and the actual data type(s) supplied for the polymorphic arguments
   determine the actual result type for that call. For example, if there
   were not already an array subscripting mechanism, one could define a
   function that implements subscripting as subscript(anyarray, integer)
   returns anyelement. This declaration constrains the actual first
   argument to be an array type, and allows the parser to infer the
   correct result type from the actual first argument's type. Another
   example is that a function declared as f(anyarray) returns anyenum will
   only accept arrays of enum types.

   In most cases, the parser can infer the actual data type for a
   polymorphic result type from arguments that are of a different
   polymorphic type in the same family; for example anyarray can be
   deduced from anyelement or vice versa. An exception is that a
   polymorphic result of type anyrange requires an argument of type
   anyrange; it cannot be deduced from anyarray or anyelement arguments.
   This is because there could be multiple range types with the same
   subtype.

   Note that anynonarray and anyenum do not represent separate type
   variables; they are the same type as anyelement, just with an
   additional constraint. For example, declaring a function as
   f(anyelement, anyenum) is equivalent to declaring it as f(anyenum,
   anyenum): both actual arguments have to be the same enum type.

   For the “common” family of polymorphic types, the matching and
   deduction rules work approximately the same as for the “simple” family,
   with one major difference: the actual types of the arguments need not
   be identical, so long as they can be implicitly cast to a single common
   type. The common type is selected following the same rules as for UNION
   and related constructs (see Section 10.5). Selection of the common type
   considers the actual types of anycompatible and anycompatiblenonarray
   inputs, the array element types of anycompatiblearray inputs, the range
   subtypes of anycompatiblerange inputs, and the multirange subtypes of
   anycompatiblemultirange inputs. If anycompatiblenonarray is present
   then the common type is required to be a non-array type. Once a common
   type is identified, arguments in anycompatible and
   anycompatiblenonarray positions are automatically cast to that type,
   and arguments in anycompatiblearray positions are automatically cast to
   the array type for that type.

   Since there is no way to select a range type knowing only its subtype,
   use of anycompatiblerange and/or anycompatiblemultirange requires that
   all arguments declared with that type have the same actual range and/or
   multirange type, and that that type's subtype agree with the selected
   common type, so that no casting of the range values is required. As
   with anyrange and anymultirange, use of anycompatiblerange and
   anymultirange as a function result type requires that there be an
   anycompatiblerange or anycompatiblemultirange argument.

   Notice that there is no anycompatibleenum type. Such a type would not
   be very useful, since there normally are not any implicit casts to enum
   types, meaning that there would be no way to resolve a common type for
   dissimilar enum inputs.

   The “simple” and “common” polymorphic families represent two
   independent sets of type variables. Consider for example
CREATE FUNCTION myfunc(a anyelement, b anyelement,
                       c anycompatible, d anycompatible)
RETURNS anycompatible AS ...

   In an actual call of this function, the first two inputs must have
   exactly the same type. The last two inputs must be promotable to a
   common type, but this type need not have anything to do with the type
   of the first two inputs. The result will have the common type of the
   last two inputs.

   A variadic function (one taking a variable number of arguments, as in
   Section 36.5.6) can be polymorphic: this is accomplished by declaring
   its last parameter as VARIADIC anyarray or VARIADIC anycompatiblearray.
   For purposes of argument matching and determining the actual result
   type, such a function behaves the same as if you had written the
   appropriate number of anynonarray or anycompatiblenonarray parameters.