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238 lines
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<TITLE>The POSTGRES95 User Manual - ADVANCED POSTGRES SQL FEATURES</TITLE>
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<A HREF="pg95user.html">[ TOC ]</A>
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<H1>5. ADVANCED POSTGRES <B>SQL</B> FEATURES</H1>
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<HR>
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Having covered the basics of using POSTGRES <B>SQL</B> to
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access your data, we will now discuss those features of
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POSTGRES that distinguish it from conventional data
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managers. These features include inheritance, time
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travel and non-atomic data values (array- and
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set-valued attributes).
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Examples in this section can also be found in
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<CODE>advance.sql</CODE> in the tutorial directory. (Refer to the
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introduction of the <A HREF="query.html">previous chapter</A> for how to use
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it.)
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<H2><A NAME="inheritance">5.1. Inheritance</A></H2>
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Let's create two classes. The capitals class contains
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state capitals which are also cities. Naturally, the
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capitals class should inherit from cities.
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<pre> CREATE TABLE cities (
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name text,
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population float,
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altitude int -- (in ft)
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);
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CREATE TABLE capitals (
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state char2
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) INHERITS (cities);
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</pre>
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In this case, an instance of capitals <B>inherits</B> all
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attributes (name, population, and altitude) from its
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parent, cities. The type of the attribute name is
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<B>text</B>, a built-in POSTGRES type for variable length
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ASCII strings. The type of the attribute population is
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<B>float4</B>, a built-in POSTGRES type for double precision
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floating point numbres. State capitals have an extra
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attribute, state, that shows their state. In POSTGRES,
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a class can inherit from zero or more other classes,<A HREF="#4"><font size=-1>[4]</font></A>
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and a query can reference either all instances of a
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class or all instances of a class plus all of its
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descendants. For example, the following query finds
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all the cities that are situated at an attitude of 500
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'ft or higher:
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<pre> SELECT name, altitude
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FROM cities
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WHERE altitude > 500;
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+----------+----------+
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|name | altitude |
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+----------+----------+
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|Las Vegas | 2174 |
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+----------+----------+
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|Mariposa | 1953 |
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+----------+----------+
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</pre>
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On the other hand, to find the names of all cities,
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including state capitals, that are located at an altitude
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over 500 'ft, the query is:
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<pre> SELECT c.name, c.altitude
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FROM cities* c
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WHERE c.altitude > 500;
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</pre>
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which returns:
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<pre> +----------+----------+
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|name | altitude |
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+----------+----------+
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|Las Vegas | 2174 |
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+----------+----------+
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|Mariposa | 1953 |
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+----------+----------+
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|Madison | 845 |
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+----------+----------+
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</pre>
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Here the * after cities indicates that the query should
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be run over cities and all classes below cities in the
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inheritance hierarchy. Many of the commands that we
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have already discussed -- select, update and delete --
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support this * notation, as do others, like alter command.
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<H2><A NAME="time-travel">5.2. Time Travel</A></H2>
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POSTGRES supports the notion of time travel. This feature
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allows a user to run historical queries. For
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example, to find the current population of Mariposa
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city, one would query:
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<pre> SELECT * FROM cities WHERE name = 'Mariposa';
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+---------+------------+----------+
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|name | population | altitude |
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+---------+------------+----------+
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|Mariposa | 1320 | 1953 |
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+---------+------------+----------+
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</pre>
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POSTGRES will automatically find the version of Mariposa's
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record valid at the current time.
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One can also give a time range. For example to see the
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past and present populations of Mariposa, one would
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query:
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<pre> SELECT name, population
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FROM cities['epoch', 'now']
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WHERE name = 'Mariposa';
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</pre>
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where "epoch" indicates the beginning of the system
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clock.<A HREF="#5"><font size=-1>[5]</font></A> If you have executed all of the examples so
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far, then the above query returns:
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<pre> +---------+------------+
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|name | population |
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+---------+------------+
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|Mariposa | 1200 |
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+---------+------------+
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|Mariposa | 1320 |
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+---------+------------+
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</pre>
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The default beginning of a time range is the earliest
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time representable by the system and the default end is
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the current time; thus, the above time range can be
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abbreviated as ``[,].''
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<H2><A NAME="non-atomic-values">5.3. Non-Atomic Values</A></H2>
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One of the tenets of the relational model is that the
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attributes of a relation are atomic. POSTGRES does not
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have this restriction; attributes can themselves contain
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sub-values that can be accessed from the query
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language. For example, you can create attributes that
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are arrays of base types.
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<H3><A NAME="arrays">5.3.1. Arrays</A></H3>
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POSTGRES allows attributes of an instance to be defined
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as fixed-length or variable-length multi-dimensional
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arrays. Arrays of any base type or user-defined type
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can be created. To illustrate their use, we first create a
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class with arrays of base types.
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<pre> * CREATE TABLE SAL_EMP (
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name text,
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pay_by_quarter int4[],
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schedule char16[][]
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);
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</pre>
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The above query will create a class named SAL_EMP with
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a <B>text</B> string (name), a one-dimensional array of <B>int4</B>
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(pay_by_quarter), which represents the employee's
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salary by quarter and a two-dimensional array of <B>char16</B>
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(schedule), which represents the employee's weekly
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schedule. Now we do some <B>INSERTS</B>s; note that when
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appending to an array, we enclose the values within
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braces and separate them by commas. If you know <B>C</B>,
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this is not unlike the syntax for initializing structures.
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<pre> INSERT INTO SAL_EMP
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VALUES ('Bill',
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'{10000, 10000, 10000, 10000}',
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'{{"meeting", "lunch"}, {}}');
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INSERT INTO SAL_EMP
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VALUES ('Carol',
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'{20000, 25000, 25000, 25000}',
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'{{"talk", "consult"}, {"meeting"}}');
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</pre>
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By default, POSTGRES uses the "one-based" numbering
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convention for arrays -- that is, an array of n elements starts with array[1] and ends with array[n].
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Now, we can run some queries on SAL_EMP. First, we
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show how to access a single element of an array at a
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time. This query retrieves the names of the employees
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whose pay changed in the second quarter:
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<pre> * SELECT name
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FROM SAL_EMP
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WHERE SAL_EMP.pay_by_quarter[1] <>
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SAL_EMP.pay_by_quarter[2];
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+------+
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|name |
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+------+
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|Carol |
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+------+
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</pre>
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This query retrieves the third quarter pay of all
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employees:
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<pre> * SELECT SAL_EMP.pay_by_quarter[3] FROM SAL_EMP;
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+---------------+
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|pay_by_quarter |
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+---------------+
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|10000 |
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+---------------+
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|25000 |
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+---------------+
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</pre>
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We can also access arbitrary slices of an array, or
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subarrays. This query retrieves the first item on
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Bill's schedule for the first two days of the week.
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<pre> * SELECT SAL_EMP.schedule[1:2][1:1]
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FROM SAL_EMP
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WHERE SAL_EMP.name = 'Bill';
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+-------------------+
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|schedule |
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+-------------------+
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|{{"meeting"},{""}} |
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+-------------------+
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</pre>
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<p>
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<HR>
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<A NAME="4"><B>4.</B></A> i.e., the inheritance hierarchy is a directed acyclic
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graph.<br>
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<A NAME="5"><B>5.</B></A> On UNIX systems, this is always midnight, January 1,
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1970 GMT.<br>
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<HR>
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<font size=-1>
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<A HREF="pg95user.html">[ TOC ]</A>
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<A HREF="query.html">[ Previous ]</A>
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<A HREF="extend.html">[ Next ]</A>
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</font>
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