postgresql/doc/manual/extend.html
1997-01-15 15:16:25 +00:00

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<TITLE>The POSTGRES95 User Manual - EXTENDING SQL: AN OVERVIEW</TITLE>
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<H1>6. EXTENDING SQL: AN OVERVIEW</H1>
<HR>
In the sections that follow, we will discuss how you
can extend the POSTGRES <B>SQL</B> query language by adding:
<UL>
<LI>functions
<LI>types
<LI>operators
<LI>aggregates
</UL>
<p>
<H2><A NAME="how-extensibility-works">6.1. How Extensibility Works</A></H2>
POSTGRES is extensible because its operation is
catalog-driven. If you are familiar with standard
relational systems, you know that they store information
about databases, tables, columns, etc., in what are
commonly known as system catalogs. (Some systems call
this the data dictionary). The catalogs appear to the
user as classes, like any other, but the DBMS stores
its internal bookkeeping in them. One key difference
between POSTGRES and standard relational systems is
that POSTGRES stores much more information in its
catalogs -- not only information about tables and columns,
but also information about its types, functions, access
methods, and so on. These classes can be modified by
the user, and since POSTGRES bases its internal operation
on these classes, this means that POSTGRES can be
extended by users. By comparison, conventional
database systems can only be extended by changing hardcoded
procedures within the DBMS or by loading modules
specially-written by the DBMS vendor.
POSTGRES is also unlike most other data managers in
that the server can incorporate user-written code into
itself through dynamic loading. That is, the user can
specify an object code file (e.g., a compiled .o file
or shared library) that implements a new type or function
and POSTGRES will load it as required. Code written
in <B>SQL</B> are even more trivial to add to the server.
This ability to modify its operation "on the fly" makes
POSTGRES uniquely suited for rapid prototyping of new
applications and storage structures.
<H2><A NAME="the-postgres-type-system">6.2. The POSTGRES Type System</A></H2>
The POSTGRES type system can be broken down in several
ways.
Types are divided into base types and composite types.
Base types are those, like <CODE>int4</CODE>, that are implemented
in a language such as <B>C</B>. They generally correspond to
what are often known as "abstract data types"; POSTGRES
can only operate on such types through methods provided
by the user and only understands the behavior of such
types to the extent that the user describes them.
Composite types are created whenever the user creates a
class. EMP is an example of a composite type.
POSTGRES stores these types in only one way (within the
file that stores all instances of the class) but the
user can "look inside" at the attributes of these types
from the query language and optimize their retrieval by
(for example) defining indices on the attributes.
POSTGRES base types are further divided into built-in
types and user-defined types. Built-in types (like
<CODE>int4</CODE>) are those that are compiled into the system.
User-defined types are those created by the user in the
manner to be described below.
<H2><A NAME="about-the-postgres-system-catalogs">6.3. About the POSTGRES System Catalogs</A></H2>
Having introduced the basic extensibility concepts, we
can now take a look at how the catalogs are actually
laid out. You can skip this section for now, but some
later sections will be incomprehensible without the
information given here, so mark this page for later
reference.
All system catalogs have names that begin with <CODE>pg_</CODE>.
The following classes contain information that may be
useful to the end user. (There are many other system
catalogs, but there should rarely be a reason to query
them directly.)
<p>
<center>
<table border=1>
<tr>
<th>catalog name</th><th> description </th>
</tr>
<tr>
<td><CODE>pg_database</CODE> </td><td> databases </td>
</tr>
<tr>
<td><CODE>pg_class</CODE> </td><td> classes </td>
</tr>
<tr>
<td><CODE>pg_attribute</CODE> </td><td> class attributes </td>
</tr>
<tr>
<td><CODE>pg_index</CODE> </td><td> secondary indices </td>
</tr>
<tr>
</tr>
<tr>
<td><CODE>pg_proc</CODE> </td><td> procedures (both C and SQL) </td>
</tr>
<tr>
<td><CODE>pg_type</CODE> </td><td> types (both base and complex) </td>
</tr>
<tr>
<td><CODE>pg_operator</CODE> </td><td> operators </td>
</tr>
<tr>
<td><CODE>pg_aggregate</CODE> </td><td> aggregates and aggregate functions </td>
</tr>
<tr>
</tr>
<tr>
</tr>
<tr>
<td><CODE>pg_am</CODE> </td><td> access methods </td>
</tr>
<tr>
<td><CODE>pg_amop</CODE> </td><td> access method operators </td>
</tr>
<tr>
<td><CODE>pg_amproc</CODE> </td><td> access method support functions </td>
</tr>
<tr>
<td><CODE>pg_opclass</CODE> </td><td> access method operator classes </td>
</tr>
</table>
</center>
<p>
<IMG SRC="figure03.gif"
ALT="Figure 3. The major POSTGRES system catalogs">
The Reference Manual gives a more detailed explanation
of these catalogs and their attributes. However, Figure 3
shows the major entities and their relationships
in the system catalogs. (Attributes that do not refer
to other entities are not shown unless they are part of
a primary key.)
This diagram is more or less incomprehensible until you
actually start looking at the contents of the catalogs
and see how they relate to each other. For now, the
main things to take away from this diagram are as follows:
<OL>
<LI> In several of the sections that follow, we will
present various join queries on the system
catalogs that display information we need to extend
the system. Looking at this diagram should make
some of these join queries (which are often
three- or four-way joins) more understandable,
because you will be able to see that the
attributes used in the queries form foreign keys
in other classes.
<LI> Many different features (classes, attributes,
functions, types, access methods, etc.) are
tightly integrated in this schema. A simple
create command may modify many of these catalogs.
<LI> Types and procedures <A HREF="#6"><font size=-1>[6]</font></A>
are central to the schema.
Nearly every catalog contains some reference to
instances in one or both of these classes. For
example, POSTGRES frequently uses type
signatures (e.g., of functions and operators) to
identify unique instances of other catalogs.
<LI> There are many attributes and relationships that
have obvious meanings, but there are many
(particularly those that have to do with access
methods) that do not. The relationships between
<CODE>pg_am, pg_amop, pg_amproc, pg_operator</CODE> and
<CODE>pg_opclass</CODE> are particularly hard to understand
and will be described in depth (in the section
on interfacing types and operators to indices)
after we have discussed basic extensions.
</OL>
<p>
<HR>
<A NAME="6"><B>6.</B></A> We use the words <I>procedure</I> and <I>function</I> more or less
interchangably.
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