The xml
data type can be used to store XML data. Its
advantage over storing XML data in a text
field is that it
checks the input values for well-formedness, and there are support
functions to perform type-safe operations on it; see Section 9.14. Use of this data type requires the
installation to have been built with configure
--with-libxml
.
The xml
type can store well-formed
“documents”, as defined by the XML standard, as well
as “content” fragments, which are defined by reference
to the more permissive
“document node”
of the XQuery and XPath data model.
Roughly, this means that content fragments can have
more than one top-level element or character node. The expression
can be used to evaluate whether a particular xmlvalue
IS DOCUMENTxml
value is a full document or only a content fragment.
To produce a value of type xml
from character data,
use the function
xmlparse
:
XMLPARSE ( { DOCUMENT | CONTENT } value
)
Examples:
XMLPARSE (DOCUMENT '<?xml version="1.0"?><book><title>Manual</title><chapter>...</chapter></book>') XMLPARSE (CONTENT 'abc<foo>bar</foo><bar>foo</bar>')
While this is the only way to convert character strings into XML values according to the SQL standard, the PostgreSQL-specific syntaxes:
xml '<foo>bar</foo>' '<foo>bar</foo>'::xml
can also be used.
The xml
type does not validate input values
against a document type declaration
(DTD),
even when the input value specifies a DTD.
There is also currently no built-in support for validating against
other XML schema languages such as XML Schema.
The inverse operation, producing a character string value from
xml
, uses the function
xmlserialize
:
XMLSERIALIZE ( { DOCUMENT | CONTENT }value
AStype
)
type
can be
character
, character varying
, or
text
(or an alias for one of those). Again, according
to the SQL standard, this is the only way to convert between type
xml
and character types, but PostgreSQL also allows
you to simply cast the value.
When a character string value is cast to or from type
xml
without going through XMLPARSE
or
XMLSERIALIZE
, respectively, the choice of
DOCUMENT
versus CONTENT
is
determined by the “XML option”
session configuration parameter, which can be set using the
standard command:
SET XML OPTION { DOCUMENT | CONTENT };
or the more PostgreSQL-like syntax
SET xmloption TO { DOCUMENT | CONTENT };
The default is CONTENT
, so all forms of XML
data are allowed.
Care must be taken when dealing with multiple character encodings
on the client, server, and in the XML data passed through them.
When using the text mode to pass queries to the server and query
results to the client (which is the normal mode), PostgreSQL
converts all character data passed between the client and the
server and vice versa to the character encoding of the respective
end; see Section 23.3. This includes string
representations of XML values, such as in the above examples.
This would ordinarily mean that encoding declarations contained in
XML data can become invalid as the character data is converted
to other encodings while traveling between client and server,
because the embedded encoding declaration is not changed. To cope
with this behavior, encoding declarations contained in
character strings presented for input to the xml
type
are ignored, and content is assumed
to be in the current server encoding. Consequently, for correct
processing, character strings of XML data must be sent
from the client in the current client encoding. It is the
responsibility of the client to either convert documents to the
current client encoding before sending them to the server, or to
adjust the client encoding appropriately. On output, values of
type xml
will not have an encoding declaration, and
clients should assume all data is in the current client
encoding.
When using binary mode to pass query parameters to the server and query results back to the client, no encoding conversion is performed, so the situation is different. In this case, an encoding declaration in the XML data will be observed, and if it is absent, the data will be assumed to be in UTF-8 (as required by the XML standard; note that PostgreSQL does not support UTF-16). On output, data will have an encoding declaration specifying the client encoding, unless the client encoding is UTF-8, in which case it will be omitted.
Needless to say, processing XML data with PostgreSQL will be less error-prone and more efficient if the XML data encoding, client encoding, and server encoding are the same. Since XML data is internally processed in UTF-8, computations will be most efficient if the server encoding is also UTF-8.
Some XML-related functions may not work at all on non-ASCII data
when the server encoding is not UTF-8. This is known to be an
issue for xmltable()
and xpath()
in particular.
The xml
data type is unusual in that it does not
provide any comparison operators. This is because there is no
well-defined and universally useful comparison algorithm for XML
data. One consequence of this is that you cannot retrieve rows by
comparing an xml
column against a search value. XML
values should therefore typically be accompanied by a separate key
field such as an ID. An alternative solution for comparing XML
values is to convert them to character strings first, but note
that character string comparison has little to do with a useful
XML comparison method.
Since there are no comparison operators for the xml
data type, it is not possible to create an index directly on a
column of this type. If speedy searches in XML data are desired,
possible workarounds include casting the expression to a
character string type and indexing that, or indexing an XPath
expression. Of course, the actual query would have to be adjusted
to search by the indexed expression.
The text-search functionality in PostgreSQL can also be used to speed up full-document searches of XML data. The necessary preprocessing support is, however, not yet available in the PostgreSQL distribution.