NAME
DBIx::DBStag - Relational Database to Hierarchical (Stag/XML) Mapping
SYNOPSIS
use DBIx::DBStag;
my $dbh = DBIx::DBStag->connect("dbi:Pg:dbname=moviedb");
my $sql = q[
SELECT
studio.*,
movie.*,
star.*
FROM
studio NATURAL JOIN
movie NATURAL JOIN
movie_to_star NATURAL JOIN
star
WHERE
movie.genre = 'sci-fi' AND star.lastname = 'Fisher'
USE NESTING
(set(studio(movie(star))))
];
my $dataset = $dbh->selectall_stag($sql);
my @studios = $dataset->get_studio;
# returns nested data that looks like this -
#
# (studio
# (name "20th C Fox")
# (movie
# (name "star wars") (genre "sci-fi")
# (star
# (firstname "Carrie")(lastname "Fisher")))))
# iterate through result tree -
foreach my $studio (@studios) {
printf "STUDIO: %s\n", $studio->get_name;
my @movies = $studio->get_movie;
foreach my $movie (@movies) {
printf " MOVIE: %s (genre:%s)\n",
$movie->get_name, $movie->get_genre;
my @stars = $movie->get_star;
foreach my $star (@stars) {
printf " STARRING: %s:%s\n",
$star->get_firstname, $star->get_lastname;
}
}
}
# manipulate data then store it back in the database
my @allstars = $dataset->get("movie/studio/star");
$_->set_fullname($_->get_firstname.' '.$_->get_lastname)
foreach(@allstars);
$dbh->storenode($dataset);
Or from the command line:
unix> selectall_xml -d 'dbi:Pg:dbname=spybase' 'SELECT * FROM studio NATURAL JOIN movie'
DESCRIPTION
This module is for mapping from databases to Stag objects (Structured
Tags - see the Data::Stag manpage), which can also be represented as
XML. It has two main uses:
Querying
This module can take the results of any SQL query and decompose the
flattened results into a tree data structure which reflects the
foreign keys in the underlying relational schema. It does this by
looking at the SQL query and introspecting the database schema,
rather than requiring metadata or an object model.
In this respect, the module works just like a regular the DBI
manpage handle, with some extra methods provided.
Storing Data
DBStag objects can store any tree-like datastructure (such as XML
documents) into a database using normalized schema that reflects the
structure of the tree being stored. This is done using little or no
metadata.
XML can also be imported, and a relational schema automatically
generated.
For a tutorial on using DBStag to build and query relational databases
from XML sources, please see the DBIx::DBStag::Cookbook manpage
HOW QUERYING WORKS
This is a general overview of the rules for turning SQL query results
into a tree like data structure.
Relations
Relations (i.e. tables and views) are elements (nodes) in the tree. The
elements have the same name as the relation in the database.
Columns
Table and view columns of a relation are sub-elements of the table or
view to which they belong. These elements will be data elements (i.e.
terminal nodes). Only the columns selected in the SQL query will be
present.
For example, the following query
SELECT name, job FROM person;
will return a data structure that looks like this:
(person
(name "fred")
(job "forklift driver"))
(person
(name "joe")
(job "steamroller mechanic"))
The data is shown as a lisp-style S-Expression - it can also be
expressed as XML, or manipulated as an object within perl.
Table aliases
If an ALIAS is used in the FROM part of the SQL query, the relation
element will be nested inside an element with the same name as the
alias. For instance, the query
SELECT name FROM person AS author WHERE job = 'author';
Will return a data structure like this:
(author
(person
(name "Philip K Dick")))
The underlying assumption is that aliasing is used for a purpose in the
original query; for instance, to determine the context of the relation
where it may be ambiguous.
SELECT *
FROM person AS employee
INNER JOIN
person AS boss ON (employee.boss_id = boss.person_id)
Will generate a nested result structure similar to this -
(employee
(person
(person_id "...")
(name "...")
(foo "...")
(boss
(person
(person_id "...")
(name "...")
(foo "...")))))
If we neglected the alias, we would have 'person' directly nested under
'person', and the meaning would not be obvious. Note how the contents of
the SQL query dynamically modifies the schema/structure of the result
tree.
NOTE ON SQL SYNTAX
Right now, DBStag is fussy about how you specify aliases; you must use
AS - you must say
SELECT name FROM person AS author;
instead of
SELECT name FROM person author;
Nesting of relations
The main utility of querying using this module is in retrieving the
nested relation elements from the flattened query results. Given a query
over relations A, B, C, D,... there are a number of possible tree
structures. Not all of the tree structures are meaningful.
Usually it will make no sense to nest A under B if there is no foreign
key relationship linking either A to B, or B to A. This is not always
the case - it may be desirable to nest A under B if there is an
intermediate linking table that is required at the relational level but
not required in the tree structure.
DBStag will guess a structure/schema based on the ordering of the
relations in your FROM clause. However, this guess can be over-ridden at
either the SQL level (using DBStag specific SQL extensions) or at the
API level.
The default algorithm is to nest each relation element under the
relation element preceeding it in the FROM clause; for instance:
SELECT * FROM a NATURAL JOIN b NATURAL JOIN c
If there are appropriately named foreign keys, the following data will
be returned (assuming one row in each of a, b and c)
(set
(a
(a_foo "...")
(b
(b_foo "...")
(c
(c_foo "...")))))
where 'x_foo' is a column in relation 'x'
This is not always desirable. If both b and c have foreign keys into
table a, DBStag will not detect this - you have to guide it. There are
two ways of doing this - you can guide by bracketing your FROM clause
like this:
!!##
!!## NOTE - THIS PART IS NOT SET IN STONE - THIS MAY CHANGE
!!##
SELECT * FROM (a NATURAL JOIN b) NATURAL JOIN c
This will generate
(set
(a
(a_foo "...")
(b
(b_foo "..."))
(c
(c_foo "..."))))
Now b and c are siblings in the tree. The algorithm is similar to
before: nest each relation element under the relation element preceeding
it; or, if the preceeding item in the FROM clause is a bracketed
structure, nest it under the first relational element in the bracketed
structure.
(Note that in MySQL you may not place brackets in the FROM clause in
this way)
Another way to achieve the same thing is to specify the desired tree
structure using a DBStag specific SQL extension. The DBStag specific
component is removed from the SQL before being presented to the DBMS.
The extension is the USE NESTING clause, which should come at the end of
the SQL query (and is subsequently removed before processing by the
DBMS).
SELECT *
FROM a NATURAL JOIN b NATURAL JOIN c
USE NESTING (set (a (b)(c)));
This will generate the same tree as above (i.e. 'b' and 'c' are
siblings). Notice how the nesting in the clause is the same as the
nesting in the resulting tree structure.
Note that 'set' is not a table in the underlying relational schema - the
result data tree requires a named top level node to group all the 'a'
relations under. You can call this top level element whatever you like.
If you are using the DBStag API directly, you can pass in the nesting
structure as an argument to the select call; for instance:
my $seq =
$dbh->selectall_xml(-sql=>q[SELECT *
FROM a NATURAL JOIN b
NATURAL JOIN c],
-nesting=>'(set (a (b)(c)))');
or the equivalent -
my $seq =
$dbh->selectall_xml(q[SELECT *
FROM a NATURAL JOIN b
NATURAL JOIN c],
'(set (a (b)(c)))');
If you like, you can also use XML here (only at the API level, not at
the SQL level) -
my $seq =
$dbh->selectall_xml(-sql=>q[SELECT *
FROM a NATURAL JOIN b
NATURAL JOIN c],
-nesting=>q[
]);
As you can see, this is a little more verbose.
Most command line scripts that use this module should allow pass-through
via the '-nesting' switch.
Aliasing of functions and expressions
If you alias a function or an expression, DBStag needs to know where to
put the resulting column; the column must be aliased.
This is inferred from the first named column in the function or
expression; for example, in the SQL below
SELECT blah.*, foo.*, foo.x - foo.y AS z
The z element will be nested under the foo element
You can force different nesting using a double underscore:
SELECT blah.*, foo.*, foo.x - foo.y AS blah__z
This will nest the z element under the blah element
Conformance to DTD/XML-Schema
DBStag returns the Data::Stag manpage structures that are equivalent to
a simplified subset of XML (and also a simplified subset of lisp
S-Expressions).
These structures are examples of semi-structured data - a good reference
is this book -
Data on the Web: From Relations to Semistructured Data and XML
Serge Abiteboul, Dan Suciu, Peter Buneman
Morgan Kaufmann; 1st edition (January 2000)
The schema for the resulting Stag structures can be seen to conform to a
schema that is dynamically determined at query-time from the underlying
relational schema and from the specification of the query itself.
CLASS METHODS
connect
Usage - $dbh = DBIx::DBStag->connect($DSN);
Returns - L
Args - see the connect() method in L
selectall_stag
Usage - $stag = $dbh->selectall_stag($sql);
$stag = $dbh->selectall_stag($sql, $nesting_clause);
$stag = $dbh->selectall_stag(-template=>$template,
-bind=>{%variable_bindinfs});
Returns - L
Args - sql string,
[nesting string],
[bind hashref],
[template DBIx::DBStag::SQLTemplate]
Executes a query and returns a the Data::Stag manpage structure
An optional nesting expression can be passed in to control how the
relation is decomposed into a tree. The nesting expression can be XML or
an S-Expression; see above for details
selectall_xml
Usage - $xml = $dbh->selectall_xml($sql);
Returns - string
Args - See selectall_stag()
As selectall_stag(), but the results are transformed into an XML string
selectall_sxpr
Usage - $sxpr = $dbh->selectall_sxpr($sql);
Returns - string
Args - See selectall_stag()
As selectall_stag(), but the results are transformed into an
S-Expression string; see the Data::Stag manpage for more details.
selectall_sax
Usage - $dbh->selectall_sax(-sql=>$sql, -handler=>$sax_handler);
Returns - string
Args - sql string, [nesting string], handler SAX
As selectall_stag(), but the results are transformed into SAX events
[currently this is just a wrapper to selectall_xml but a genuine event
generation model will later be used]
selectall_rows
Usage - $tbl = $dbh->selectall_rows($sql);
Returns - arrayref of arrayref
Args - See selectall_stag()
As selectall_stag(), but the results of the SQL query are left
undecomposed and unnested. The resulting structure is just a flat table;
the first row is the column headings. This is similar to
DBI->selectall_arrayref(). The main reason to use this over the direct
DBI method is to take advantage of other stag functionality, such as
templates
prepare_stag SEMI-PRIVATE METHOD
Usage - $prepare_h = $dbh->prepare_stag(-template=>$template);
Returns - hashref (see below)
Args - See selectall_stag()
Returns a hashref
{
sth=>$sth,
exec_args=>\@exec_args,
cols=>\@cols,
col_aliases_ordered=>\@col_aliases_ordered,
alias=>$aliasstruct,
nesting=>$nesting
};
storenode
Usage - $dbh->storenode($stag);
Returns -
Args - L
Recursively stores a tree structure in the database
SQL TEMPLATES
DBStag comes with its own SQL templating system. This allows you to
reuse the same canned SQL or similar SQL qeuries in different contexts.
See the DBIx::DBStag::SQLTemplate manpage
find_template
Usage - $template = $dbh->find_template("my-template-name");
Returns - L
Args - str
Returns an object representing a canned paramterized SQL query. See the
DBIx::DBStag::SQLTemplate manpage for documentation on templates
list_templates
Usage - $templates = $dbh->list_templates();
Returns - Arrayref of L
Args -
Returns a list of ALL defined templates - See the
DBIx::DBStag::SQLTemplate manpage
find_templates_by_schema
Usage - $templates = $dbh->find_templates_by_schema($schema_name);
Returns - Arrayref of L
Args - str
Returns a list of templates for a particular schema - See the
DBIx::DBStag::SQLTemplate manpage
find_templates_by_dbname
Usage - $templates = $dbh->find_templates_by_dbname("mydb");
Returns - Arrayref of L
Args - db name
Returns a list of templates for a particular db
Requires resources to be set up (see below)
RESOURCES
resources_list
Usage - $rlist = $dbh->resources_list
Returns - arrayref to a hashref
Args - none
Returns a list of resources; each resource is a hash
{name=>"mydbname",
type=>"rdb",
schema=>"myschema",
}
SETTING UP RESOURCES
The above methods rely on you having a file describing all the
relational dbs available to you, and setting the env var
DBSTAG_DBIMAP_FILE set (this is a : separated list of paths).
This is alpha code - not fully documented, API may change
Currently a resources file is a whitespace delimited text file -
XML/Sxpr/IText definitions may be available later
Here is an example of a resources file:
# LOCAL
mytestdb rdb Pg:mytestdb schema=test
# SYSTEM
worldfactbook rdb Pg:worldfactbook@db1.mycompany.com schema=wfb
employees rdb Pg:employees@db2.mycompany.com schema=employees
The first column is the nickname or logical name of the resource/db.
This nickname can be used instead of the full DBI locator path (eg you
can just use employees instead of
dbi:Pg:dbname=employees;host=db2.mycompany.com
The second column is the resource type - rdb is for relational database.
You can use the same file to track other system datasources available to
you, but DBStag is only interested in relational dbs.
The 3rd column is a way of locating the resource - driver:name@host
The 4th column is a ; separated list of tag=value pairs; the most
important tag is the schema tag. Multiple dbs may share the same schema,
and hence share SQL Templates
COMMAND LINE SCRIPTS
DBStag is usable without writing any perl, you can use command line
scripts and files that utilise tree structures (XML, S-Expressions)
selectall_xml.pl
selectall_xml.pl -d [-n ]
Queries database and writes decomposed relation as XML
Can also be used with templates:
selectall_xml.pl -d / ...
selectall_html.pl
selectall_html.pl -d [-n ]
Queries database and writes decomposed relation as HTML with nested
tables indicating the nested structures.
stag-storenode.pl
stag-storenode.pl -d
Stores data from a file (Supported formats: XML, Sxpr, IText - see
the Data::Stag manpage) in a normalized database. Gets it right most
of the time.
TODO - metadata help
stag-autoddl.pl
stag-autoddl.pl [-l ]*
Takes data from a file (Supported formats: XML, Sxpr, IText - see
the Data::Stag manpage) and generates a relational schema in the
form of SQL CREATE TABLE statements.
ENVIRONMENT VARIABLES
DBSTAG_TRACE
setting this environment will cause all SQL statements to be printed
on STDERR
BUGS
This is alpha software! Probably several bugs.
The SQL parsing can be quite particular - sometimes the SQL can be
parsed by the DBMS but not by DBStag. The error messages are not always
helpful.
There are probably a few cases the SQL SELECT parsing grammar cannot
deal with.
If you want to select from views, you need to hack DBIx::DBSchema (as of
v0.21)
TODO
Use SQL::Translator to make SQL DDL generation less Pg-specific; also
for deducing foreign keys (right now foreign keys are guessed by the
name of the column, eg table_id)
Can we cache the grammar so that startup is not so slow?
Improve algorithm so that events are fired rather than building up
entire structure in-memory
Tie in all DBI attributes accessible by hash, i.e.: $dbh->{...}
Error handling
WEBSITE
http://stag.sourceforge.net
AUTHOR
Chris Mungall
COPYRIGHT
Copyright (c) 2004 Chris Mungall
This module is free software. You may distribute this module under the
same terms as perl itself