Table 8.4. Character Types
||variable-length with limit|
||fixed-length, blank padded|
||variable unlimited length|
Table 8.4 shows the general-purpose character types available in PostgreSQL.
SQL defines two primary character types:
character varying( and
n is a positive integer. Both of these types can store strings up to
n characters (not bytes) in length. An attempt to store a longer string into a column of these types will result in an error, unless the excess characters are all spaces, in which case the string will be truncated to the maximum length. (This somewhat bizarre exception is required by the SQL standard.) However, if one explicitly casts a value to
character varying( or
character(, then an over-length value will be truncated to
n characters without raising an error. (This too is required by the SQL standard.) If the string to be stored is shorter than the declared length, values of type
character will be space-padded; values of type
character varying will simply store the shorter string.
In addition, PostgreSQL provides the
text type, which stores strings of any length. Although the
text type is not in the SQL standard, several other SQL database management systems have it as well.
text is PostgreSQL's native string data type, in that most built-in functions operating on strings are declared to take or return
character varying. For many purposes,
character varying acts as though it were a domain over
The type name
varchar is an alias for
character varying, while
bpchar are aliases for
char aliases are defined in the SQL standard, but
bpchar is a PostgreSQL extension.
If specified, the length
n must be greater than zero and cannot exceed 10485760.
character without length specifier is equivalent to
character varying is used without length specifier, the type accepts strings of any size.
Values of type
character are physically padded with spaces to the specified width
n, and are stored and displayed that way. However, trailing spaces are treated as semantically insignificant and disregarded when comparing two values of type
character. In collations where whitespace is significant, this behavior can produce unexpected results; for example
SELECT 'a '::CHAR(2) collate "C" < E'a\n'::CHAR(2) returns true, even though
C locale would consider a space to be greater than a newline. Trailing spaces are removed when converting a
character value to one of the other string types. Note that trailing spaces are semantically significant in
character varying and
text values, and when using pattern matching, that is
LIKE and regular expressions.
The characters that can be stored in any of these data types are determined by the database character set, which is selected when the database is created. Regardless of the specific character set, the character with code zero (sometimes called NUL) cannot be stored. For more information refer to Section 24.3.
The storage requirement for a short string (up to 126 bytes) is 1 byte plus the actual string, which includes the space padding in the case of
character. Longer strings have 4 bytes of overhead instead of 1. Long strings are compressed by the system automatically, so the physical requirement on disk might be less. Very long values are also stored in background tables so that they do not interfere with rapid access to shorter column values. In any case, the longest possible character string that can be stored is about 1 GB. (The maximum value that will be allowed for
n in the data type declaration is less than that. It wouldn't be useful to change this because with multibyte character encodings the number of characters and bytes can be quite different. If you desire to store long strings with no specific upper limit, use
character varying without a length specifier, rather than making up an arbitrary length limit.)
There is no performance difference among these three types, apart from increased storage space when using the blank-padded type, and a few extra CPU cycles to check the length when storing into a length-constrained column. While
character( has performance advantages in some other database systems, there is no such advantage in PostgreSQL; in fact
character( is usually the slowest of the three because of its additional storage costs. In most situations
character varying should be used instead.
Refer to Section 220.127.116.11 for information about the syntax of string literals, and to Chapter 9 for information about available operators and functions.
Example 8.1. Using the Character Types
CREATE TABLE test1 (a character(4)); INSERT INTO test1 VALUES ('ok'); SELECT a, char_length(a) FROM test1; -- (1)
a | char_length ------+------------- ok | 2CREATE TABLE test2 (b varchar(5)); INSERT INTO test2 VALUES ('ok'); INSERT INTO test2 VALUES ('good '); INSERT INTO test2 VALUES ('too long');
ERROR: value too long for type character varying(5)INSERT INTO test2 VALUES ('too long'::varchar(5)); -- explicit truncation SELECT b, char_length(b) FROM test2;
b | char_length -------+------------- ok | 2 good | 5 too l | 5
There are two other fixed-length character types in PostgreSQL, shown in Table 8.5. These are not intended for general-purpose use, only for use in the internal system catalogs. The
name type is used to store identifiers. Its length is currently defined as 64 bytes (63 usable characters plus terminator) but should be referenced using the constant
C source code. The length is set at compile time (and is therefore adjustable for special uses); the default maximum length might change in a future release. The type
"char" (note the quotes) is different from
char(1) in that it only uses one byte of storage, and therefore can store only a single ASCII character. It is used in the system catalogs as a simplistic enumeration type.
Table 8.5. Special Character Types
||1 byte||single-byte internal type|
||64 bytes||internal type for object names|