The functions and function-like expressions described in this
section operate on values of type xml
. See Section 9.11 for information about the xml
type. The function-like expressions xmlparse
and xmlserialize
for converting to and from
type xml
are documented there, not in this section.
Use of most of these functions
requires LightDB to have been built
with configure --with-libxml
.
A set of functions and function-like expressions is available for producing XML content from SQL data. As such, they are particularly suitable for formatting query results into XML documents for processing in client applications.
xmlcomment
xmlcomment
(text
) →xml
The function xmlcomment
creates an XML value
containing an XML comment with the specified text as content.
The text cannot contain “--
” or end with a
“-
”, otherwise the resulting construct
would not be a valid XML comment.
If the argument is null, the result is null.
Example:
SELECT xmlcomment('hello'); xmlcomment -------------- <!--hello-->
xmlconcat
xmlconcat
(xml
[, ...] ) →xml
The function xmlconcat
concatenates a list
of individual XML values to create a single value containing an
XML content fragment. Null values are omitted; the result is
only null if there are no nonnull arguments.
Example:
SELECT xmlconcat('<abc/>', '<bar>foo</bar>'); xmlconcat ---------------------- <abc/><bar>foo</bar>
XML declarations, if present, are combined as follows. If all argument values have the same XML version declaration, that version is used in the result, else no version is used. If all argument values have the standalone declaration value “yes”, then that value is used in the result. If all argument values have a standalone declaration value and at least one is “no”, then that is used in the result. Else the result will have no standalone declaration. If the result is determined to require a standalone declaration but no version declaration, a version declaration with version 1.0 will be used because XML requires an XML declaration to contain a version declaration. Encoding declarations are ignored and removed in all cases.
Example:
SELECT xmlconcat('<?xml version="1.1"?><foo/>', '<?xml version="1.1" standalone="no"?><bar/>'); xmlconcat ----------------------------------- <?xml version="1.1"?><foo/><bar/>
xmlelement
xmlelement
( [NAME
]name
[,XMLATTRIBUTES
(attvalue
[AS
attname
] [, ...] ) ] [,content
[, ...]] ) →xml
The xmlelement
expression produces an XML
element with the given name, attributes, and content.
The name
and attname
items shown in the syntax are
simple identifiers, not values. The attvalue
and content
items are expressions, which can
yield any LightDB data type. The
argument(s) within XMLATTRIBUTES
generate attributes
of the XML element; the content
value(s) are
concatenated to form its content.
To comply with the syntax of Oracle databases, the name
keyword can be omitted.
Examples:
SELECT xmlelement(name foo); xmlelement ------------ <foo/> SELECT xmlelement(foo); xmlelement ------------ <foo/> SELECT xmlelement(name foo, xmlattributes('xyz' as bar)); xmlelement ------------------ <foo bar="xyz"/> SELECT xmlelement(foo, xmlattributes('xyz' as bar)); xmlelement ------------------ <foo bar="xyz"/> SELECT xmlelement(name foo, xmlattributes(current_date as bar), 'cont', 'ent'); xmlelement ------------------------------------- <foo bar="2007-01-26">content</foo> SELECT xmlelement(foo, xmlattributes(current_date as bar), 'cont', 'ent'); xmlelement ------------------------------------- <foo bar="2007-01-26">content</foo>
Element and attribute names that are not valid XML names are
escaped by replacing the offending characters by the sequence
_x
, where
HHHH
_HHHH
is the character's Unicode
codepoint in hexadecimal notation. For example:
SELECT xmlelement(name "foo$bar", xmlattributes('xyz' as "a&b")); xmlelement ---------------------------------- <foo_x0024_bar a_x0026_b="xyz"/>
An explicit attribute name need not be specified if the attribute value is a column reference, in which case the column's name will be used as the attribute name by default. In other cases, the attribute must be given an explicit name. So this example is valid:
CREATE TABLE test (a xml, b xml); SELECT xmlelement(name test, xmlattributes(a, b)) FROM test;
But these are not:
SELECT xmlelement(name test, xmlattributes('constant'), a, b) FROM test; SELECT xmlelement(name test, xmlattributes(func(a, b))) FROM test;
Element content, if specified, will be formatted according to
its data type. If the content is itself of type xml
,
complex XML documents can be constructed. For example:
SELECT xmlelement(name foo, xmlattributes('xyz' as bar), xmlelement(name abc), xmlcomment('test'), xmlelement(name xyz)); xmlelement ---------------------------------------------- <foo bar="xyz"><abc/><!--test--><xyz/></foo>
Content of other types will be formatted into valid XML character
data. This means in particular that the characters <, >,
and & will be converted to entities. Binary data (data type
bytea
) will be represented in base64 or hex
encoding, depending on the setting of the configuration parameter
xmlbinary. The particular behavior for
individual data types is expected to evolve in order to align the
LightDB mappings with those specified in SQL:2006 and later,
as discussed in Section D.3.1.3.
xmlforest
xmlforest
(content
[AS
name
] [, ...] ) →xml
The xmlforest
expression produces an XML
forest (sequence) of elements using the given names and content.
As for xmlelement
,
each name
must be a simple identifier, while
the content
expressions can have any data
type.
Examples:
SELECT xmlforest('abc' AS foo, 123 AS bar); xmlforest ------------------------------ <foo>abc</foo><bar>123</bar> SELECT xmlforest(table_name, column_name) FROM information_schema.columns WHERE table_schema = 'pg_catalog'; xmlforest ----------------------------------------------------------------------- <table_name>pg_authid</table_name><column_name>rolname</column_name> <table_name>pg_authid</table_name><column_name>rolsuper</column_name> ...
As seen in the second example, the element name can be omitted if the content value is a column reference, in which case the column name is used by default. Otherwise, a name must be specified.
Element names that are not valid XML names are escaped as shown
for xmlelement
above. Similarly, content
data is escaped to make valid XML content, unless it is already
of type xml
.
Note that XML forests are not valid XML documents if they consist
of more than one element, so it might be useful to wrap
xmlforest
expressions in
xmlelement
.
xmlpi
xmlpi
(NAME
name
[,content
] ) →xml
The xmlpi
expression creates an XML
processing instruction.
As for xmlelement
,
the name
must be a simple identifier, while
the content
expression can have any data type.
The content
, if present, must not contain the
character sequence ?>
.
Example:
SELECT xmlpi(name php, 'echo "hello world";'); xmlpi ----------------------------- <?php echo "hello world";?>
xmlroot
xmlroot
(xml
,VERSION
{text
|NO VALUE
} [,STANDALONE
{YES
|NO
|NO VALUE
} ] ) →xml
The xmlroot
expression alters the properties
of the root node of an XML value. If a version is specified,
it replaces the value in the root node's version declaration; if a
standalone setting is specified, it replaces the value in the
root node's standalone declaration.
SELECT xmlroot(xmlparse(document '<?xml version="1.1"?><content>abc</content>'), version '1.0', standalone yes); xmlroot ---------------------------------------- <?xml version="1.0" standalone="yes"?> <content>abc</content>
xmlagg
xmlagg
(xml
) →xml
The function xmlagg
is, unlike the other
functions described here, an aggregate function. It concatenates the
input values to the aggregate function call,
much like xmlconcat
does, except that concatenation
occurs across rows rather than across expressions in a single row.
See Section 10.20 for additional information
about aggregate functions.
Example:
CREATE TABLE test (y int, x xml); INSERT INTO test VALUES (1, '<foo>abc</foo>'); INSERT INTO test VALUES (2, '<bar/>'); SELECT xmlagg(x) FROM test; xmlagg ---------------------- <foo>abc</foo><bar/>
To determine the order of the concatenation, an ORDER BY
clause may be added to the aggregate call as described in
Section 5.2.7. For example:
SELECT xmlagg(x ORDER BY y DESC) FROM test; xmlagg ---------------------- <bar/><foo>abc</foo>
The following non-standard approach used to be recommended in previous versions, and may still be useful in specific cases:
SELECT xmlagg(x) FROM (SELECT * FROM test ORDER BY y DESC) AS tab; xmlagg ---------------------- <bar/><foo>abc</foo>
The following approach used together with getclobval() in oracle compatible mode cases:
SELECT xmlagg(xmlparse(content '1,2,3,')).getclobval() FROM dual; getclobval ------------ 1,2,3, (1 row)
The expressions described in this section check properties
of xml
values.
IS DOCUMENT
xml
IS DOCUMENT
→boolean
The expression IS DOCUMENT
returns true if the
argument XML value is a proper XML document, false if it is not
(that is, it is a content fragment), or null if the argument is
null. See Section 9.11 about the difference
between documents and content fragments.
IS NOT DOCUMENT
xml
IS NOT DOCUMENT
→boolean
The expression IS NOT DOCUMENT
returns false if the
argument XML value is a proper XML document, true if it is not (that is,
it is a content fragment), or null if the argument is null.
XMLEXISTS
XMLEXISTS
(text
PASSING
[BY
{REF
|VALUE
}]xml
[BY
{REF
|VALUE
}] ) →boolean
The function xmlexists
evaluates an XPath 1.0
expression (the first argument), with the passed XML value as its context
item. The function returns false if the result of that evaluation
yields an empty node-set, true if it yields any other value. The
function returns null if any argument is null. A nonnull value
passed as the context item must be an XML document, not a content
fragment or any non-XML value.
Example:
SELECT xmlexists('//town[text() = ''Toronto'']' PASSING BY VALUE '<towns><town>Toronto</town><town>Ottawa</town></towns>'); xmlexists ------------ t (1 row)
The BY REF
and BY VALUE
clauses
are accepted in LightDB, but are ignored,
as discussed in Section D.3.2.
In the SQL standard, the xmlexists
function
evaluates an expression in the XML Query language,
but LightDB allows only an XPath 1.0
expression, as discussed in
Section D.3.1.
xml_is_well_formed
xml_is_well_formed
(text
) →boolean
xml_is_well_formed_document
(text
) →boolean
xml_is_well_formed_content
(text
) →boolean
These functions check whether a text
string represents
well-formed XML, returning a Boolean result.
xml_is_well_formed_document
checks for a well-formed
document, while xml_is_well_formed_content
checks
for well-formed content. xml_is_well_formed
does
the former if the xmloption configuration
parameter is set to DOCUMENT
, or the latter if it is set to
CONTENT
. This means that
xml_is_well_formed
is useful for seeing whether
a simple cast to type xml
will succeed, whereas the other two
functions are useful for seeing whether the corresponding variants of
XMLPARSE
will succeed.
Examples:
SET xmloption TO DOCUMENT; SELECT xml_is_well_formed('<>'); xml_is_well_formed -------------------- f (1 row) SELECT xml_is_well_formed('<abc/>'); xml_is_well_formed -------------------- t (1 row) SET xmloption TO CONTENT; SELECT xml_is_well_formed('abc'); xml_is_well_formed -------------------- t (1 row) SELECT xml_is_well_formed_document('<lt:foo xmlns:pg="http://example.org/stuff">bar</lt:foo>'); xml_is_well_formed_document ----------------------------- t (1 row) SELECT xml_is_well_formed_document('<lt:foo xmlns:pg="http://example.org/stuff">bar</my:foo>'); xml_is_well_formed_document ----------------------------- f (1 row)
The last example shows that the checks include whether namespaces are correctly matched.
To process values of data type xml
, LightDB offers
the functions xpath
and
xpath_exists
, which evaluate XPath 1.0
expressions, and the XMLTABLE
table function.
xpath
xpath
(xpath
text
,xml
xml
[,nsarray
text[]
] ) →xml[]
The function xpath
evaluates the XPath 1.0
expression xpath
(given as text)
against the XML value
xml
. It returns an array of XML values
corresponding to the node-set produced by the XPath expression.
If the XPath expression returns a scalar value rather than a node-set,
a single-element array is returned.
The second argument must be a well formed XML document. In particular, it must have a single root node element.
The optional third argument of the function is an array of namespace
mappings. This array should be a two-dimensional text
array with
the length of the second axis being equal to 2 (i.e., it should be an
array of arrays, each of which consists of exactly 2 elements).
The first element of each array entry is the namespace name (alias), the
second the namespace URI. It is not required that aliases provided in
this array be the same as those being used in the XML document itself (in
other words, both in the XML document and in the xpath
function context, aliases are local).
Example:
SELECT xpath('/my:a/text()', '<my:a xmlns:my="http://example.com">test</my:a>', ARRAY[ARRAY['my', 'http://example.com']]); xpath -------- {test} (1 row)
To deal with default (anonymous) namespaces, do something like this:
SELECT xpath('//mydefns:b/text()', '<a xmlns="http://example.com"><b>test</b></a>', ARRAY[ARRAY['mydefns', 'http://example.com']]); xpath -------- {test} (1 row)
xpath_exists
xpath_exists
(xpath
text
,xml
xml
[,nsarray
text[]
] ) →boolean
The function xpath_exists
is a specialized form
of the xpath
function. Instead of returning the
individual XML values that satisfy the XPath 1.0 expression, this function
returns a Boolean indicating whether the query was satisfied or not
(specifically, whether it produced any value other than an empty node-set).
This function is equivalent to the XMLEXISTS
predicate,
except that it also offers support for a namespace mapping argument.
Example:
SELECT xpath_exists('/my:a/text()', '<my:a xmlns:my="http://example.com">test</my:a>', ARRAY[ARRAY['my', 'http://example.com']]); xpath_exists -------------- t (1 row)
xmltable
XMLTABLE
( [XMLNAMESPACES
(namespace_uri
AS
namespace_name
[, ...] ), ]row_expression
PASSING
[BY
{REF
|VALUE
}]document_expression
[BY
{REF
|VALUE
}]COLUMNS
name
{type
[PATH
column_expression
] [DEFAULT
default_expression
] [NOT NULL
|NULL
] |FOR ORDINALITY
} [, ...] ) →setof record
The xmltable
expression produces a table based
on an XML value, an XPath filter to extract rows, and a
set of column definitions.
Although it syntactically resembles a function, it can only appear
as a table in a query's FROM
clause.
The optional XMLNAMESPACES
clause gives a
comma-separated list of namespace definitions, where
each namespace_uri
is a text
expression and each namespace_name
is a simple
identifier. It specifies the XML namespaces used in the document and
their aliases. A default namespace specification is not currently
supported.
The required row_expression
argument is an
XPath 1.0 expression (given as text
) that is evaluated,
passing the XML value document_expression
as
its context item, to obtain a set of XML nodes. These nodes are what
xmltable
transforms into output rows. No rows
will be produced if the document_expression
is null, nor if the row_expression
produces
an empty node-set or any value other than a node-set.
document_expression
provides the context
item for the row_expression
. It must be a
well-formed XML document; fragments/forests are not accepted.
The BY REF
and BY VALUE
clauses
are accepted but ignored, as discussed in
Section D.3.2.
In the SQL standard, the xmltable
function
evaluates expressions in the XML Query language,
but LightDB allows only XPath 1.0
expressions, as discussed in
Section D.3.1.
The required COLUMNS
clause specifies the
column(s) that will be produced in the output table.
See the syntax summary above for the format.
A name is required for each column, as is a data type
(unless FOR ORDINALITY
is specified, in which case
type integer
is implicit). The path, default and
nullability clauses are optional.
A column marked FOR ORDINALITY
will be populated
with row numbers, starting with 1, in the order of nodes retrieved from
the row_expression
's result node-set.
At most one column may be marked FOR ORDINALITY
.
XPath 1.0 does not specify an order for nodes in a node-set, so code that relies on a particular order of the results will be implementation-dependent. Details can be found in Section D.3.1.2.
The column_expression
for a column is an
XPath 1.0 expression that is evaluated for each row, with the current
node from the row_expression
result as its
context item, to find the value of the column. If
no column_expression
is given, then the
column name is used as an implicit path.
If a column's XPath expression returns a non-XML value (which is limited
to string, boolean, or double in XPath 1.0) and the column has a
LightDB type other than xml
, the column will be set
as if by assigning the value's string representation to the LightDB
type. (If the value is a boolean, its string representation is taken
to be 1
or 0
if the output
column's type category is numeric, otherwise true
or
false
.)
If a column's XPath expression returns a non-empty set of XML nodes
and the column's LightDB type is xml
, the column will
be assigned the expression result exactly, if it is of document or
content form.
[7]
A non-XML result assigned to an xml
output column produces
content, a single text node with the string value of the result.
An XML result assigned to a column of any other type may not have more than
one node, or an error is raised. If there is exactly one node, the column
will be set as if by assigning the node's string
value (as defined for the XPath 1.0 string
function)
to the LightDB type.
The string value of an XML element is the concatenation, in document order,
of all text nodes contained in that element and its descendants. The string
value of an element with no descendant text nodes is an
empty string (not NULL
).
Any xsi:nil
attributes are ignored.
Note that the whitespace-only text()
node between two non-text
elements is preserved, and that leading whitespace on a text()
node is not flattened.
The XPath 1.0 string
function may be consulted for the
rules defining the string value of other XML node types and non-XML values.
The conversion rules presented here are not exactly those of the SQL standard, as discussed in Section D.3.1.3.
If the path expression returns an empty node-set
(typically, when it does not match)
for a given row, the column will be set to NULL
, unless
a default_expression
is specified; then the
value resulting from evaluating that expression is used.
A default_expression
, rather than being
evaluated immediately when xmltable
is called,
is evaluated each time a default is needed for the column.
If the expression qualifies as stable or immutable, the repeat
evaluation may be skipped.
This means that you can usefully use volatile functions like
nextval
in
default_expression
.
Columns may be marked NOT NULL
. If the
column_expression
for a NOT
NULL
column does not match anything and there is
no DEFAULT
or
the default_expression
also evaluates to null,
an error is reported.
Examples:
CREATE TABLE xmldata AS SELECT xml $$ <ROWS> <ROW id="1"> <COUNTRY_ID>AU</COUNTRY_ID> <COUNTRY_NAME>Australia</COUNTRY_NAME> </ROW> <ROW id="5"> <COUNTRY_ID>JP</COUNTRY_ID> <COUNTRY_NAME>Japan</COUNTRY_NAME> <PREMIER_NAME>Shinzo Abe</PREMIER_NAME> <SIZE unit="sq_mi">145935</SIZE> </ROW> <ROW id="6"> <COUNTRY_ID>SG</COUNTRY_ID> <COUNTRY_NAME>Singapore</COUNTRY_NAME> <SIZE unit="sq_km">697</SIZE> </ROW> </ROWS> $$ AS data; SELECT xmltable.* FROM xmldata, XMLTABLE('//ROWS/ROW' PASSING data COLUMNS id int PATH '@id', ordinality FOR ORDINALITY, "COUNTRY_NAME" text, country_id text PATH 'COUNTRY_ID', size_sq_km float PATH 'SIZE[@unit = "sq_km"]', size_other text PATH 'concat(SIZE[@unit!="sq_km"], " ", SIZE[@unit!="sq_km"]/@unit)', premier_name text PATH 'PREMIER_NAME' DEFAULT 'not specified'); id | ordinality | COUNTRY_NAME | country_id | size_sq_km | size_other | premier_name ----+------------+--------------+------------+------------+--------------+--------------- 1 | 1 | Australia | AU | | | not specified 5 | 2 | Japan | JP | | 145935 sq_mi | Shinzo Abe 6 | 3 | Singapore | SG | 697 | | not specified
The following example shows concatenation of multiple text() nodes, usage of the column name as XPath filter, and the treatment of whitespace, XML comments and processing instructions:
CREATE TABLE xmlelements AS SELECT xml $$ <root> <element> Hello<!-- xyxxz -->2a2<?aaaaa?> <!--x--> bbb<x>xxx</x>CC </element> </root> $$ AS data; SELECT xmltable.* FROM xmlelements, XMLTABLE('/root' PASSING data COLUMNS element text); element ------------------------- Hello2a2 bbbxxxCC
The following example illustrates how
the XMLNAMESPACES
clause can be used to specify
a list of namespaces
used in the XML document as well as in the XPath expressions:
WITH xmldata(data) AS (VALUES (' <example xmlns="http://example.com/myns" xmlns:B="http://example.com/b"> <item foo="1" B:bar="2"/> <item foo="3" B:bar="4"/> <item foo="4" B:bar="5"/> </example>'::xml) ) SELECT xmltable.* FROM XMLTABLE(XMLNAMESPACES('http://example.com/myns' AS x, 'http://example.com/b' AS "B"), '/x:example/x:item' PASSING (SELECT data FROM xmldata) COLUMNS foo int PATH '@foo', bar int PATH '@B:bar'); foo | bar -----+----- 1 | 2 3 | 4 4 | 5 (3 rows)
The following functions map the contents of relational tables to XML values. They can be thought of as XML export functionality:
table_to_xml
(table
regclass
,nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
query_to_xml
(query
text
,nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
cursor_to_xml
(cursor
refcursor
,count
integer
,nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
table_to_xml
maps the content of the named
table, passed as parameter table
. The
regclass
type accepts strings identifying tables using the
usual notation, including optional schema qualifications and
double quotes. query_to_xml
executes the
query whose text is passed as parameter
query
and maps the result set.
cursor_to_xml
fetches the indicated number of
rows from the cursor specified by the parameter
cursor
. This variant is recommended if
large tables have to be mapped, because the result value is built
up in memory by each function.
If tableforest
is false, then the resulting
XML document looks like this:
<tablename> <row> <columnname1>data</columnname1> <columnname2>data</columnname2> </row> <row> ... </row> ... </tablename>
If tableforest
is true, the result is an
XML content fragment that looks like this:
<tablename> <columnname1>data</columnname1> <columnname2>data</columnname2> </tablename> <tablename> ... </tablename> ...
If no table name is available, that is, when mapping a query or a
cursor, the string table
is used in the first
format, row
in the second format.
The choice between these formats is up to the user. The first
format is a proper XML document, which will be important in many
applications. The second format tends to be more useful in the
cursor_to_xml
function if the result values are to be
reassembled into one document later on. The functions for
producing XML content discussed above, in particular
xmlelement
, can be used to alter the results
to taste.
The data values are mapped in the same way as described for the
function xmlelement
above.
The parameter nulls
determines whether null
values should be included in the output. If true, null values in
columns are represented as:
<columnname xsi:nil="true"/>
where xsi
is the XML namespace prefix for XML
Schema Instance. An appropriate namespace declaration will be
added to the result value. If false, columns containing null
values are simply omitted from the output.
The parameter targetns
specifies the
desired XML namespace of the result. If no particular namespace
is wanted, an empty string should be passed.
The following functions return XML Schema documents describing the mappings performed by the corresponding functions above:
table_to_xmlschema
(table
regclass
,nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
query_to_xmlschema
(query
text
,nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
cursor_to_xmlschema
(cursor
refcursor
,nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
It is essential that the same parameters are passed in order to obtain matching XML data mappings and XML Schema documents.
The following functions produce XML data mappings and the corresponding XML Schema in one document (or forest), linked together. They can be useful where self-contained and self-describing results are wanted:
table_to_xml_and_xmlschema
(table
regclass
,nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
query_to_xml_and_xmlschema
(query
text
,nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
In addition, the following functions are available to produce analogous mappings of entire schemas or the entire current database:
schema_to_xml
(schema
name
,nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
schema_to_xmlschema
(schema
name
,nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
schema_to_xml_and_xmlschema
(schema
name
,nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
database_to_xml
(nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
database_to_xmlschema
(nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
database_to_xml_and_xmlschema
(nulls
boolean
,tableforest
boolean
,targetns
text
) →xml
These functions ignore tables that are not readable by the current user.
The database-wide functions additionally ignore schemas that the current
user does not have USAGE
(lookup) privilege for.
Note that these potentially produce a lot of data, which needs to be built up in memory. When requesting content mappings of large schemas or databases, it might be worthwhile to consider mapping the tables separately instead, possibly even through a cursor.
The result of a schema content mapping looks like this:
<schemaname> table1-mapping table2-mapping ... </schemaname>
where the format of a table mapping depends on the
tableforest
parameter as explained above.
The result of a database content mapping looks like this:
<dbname> <schema1name> ... </schema1name> <schema2name> ... </schema2name> ... </dbname>
where the schema mapping is as above.
As an example of using the output produced by these functions,
Example 10.1 shows an XSLT stylesheet that
converts the output of
table_to_xml_and_xmlschema
to an HTML
document containing a tabular rendition of the table data. In a
similar manner, the results from these functions can be
converted into other XML-based formats.
Example 10.1. XSLT Stylesheet for Converting SQL/XML Output to HTML
<?xml version="1.0"?> <xsl:stylesheet version="1.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:xsd="http://www.w3.org/2001/XMLSchema" xmlns="http://www.w3.org/1999/xhtml" > <xsl:output method="xml" doctype-system="http://www.w3.org/TR/xhtml1/DTD/xhtml1-strict.dtd" doctype-public="-//W3C/DTD XHTML 1.0 Strict//EN" indent="yes"/> <xsl:template match="/*"> <xsl:variable name="schema" select="//xsd:schema"/> <xsl:variable name="tabletypename" select="$schema/xsd:element[@name=name(current())]/@type"/> <xsl:variable name="rowtypename" select="$schema/xsd:complexType[@name=$tabletypename]/xsd:sequence/xsd:element[@name='row']/@type"/> <html> <head> <title><xsl:value-of select="name(current())"/></title> </head> <body> <table> <tr> <xsl:for-each select="$schema/xsd:complexType[@name=$rowtypename]/xsd:sequence/xsd:element/@name"> <th><xsl:value-of select="."/></th> </xsl:for-each> </tr> <xsl:for-each select="row"> <tr> <xsl:for-each select="*"> <td><xsl:value-of select="."/></td> </xsl:for-each> </tr> </xsl:for-each> </table> </body> </html> </xsl:template> </xsl:stylesheet>
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A result containing more than one element node at the top level, or
non-whitespace text outside of an element, is an example of content form.
An XPath result can be of neither form, for example if it returns an
attribute node selected from the element that contains it. Such a result
will be put into content form with each such disallowed node replaced by
its string value, as defined for the XPath 1.0
string
function.