There is no
denying the fact that Computing technology has made a permanent change in the
ways businesses work around the world. Information that was at one time stored
in warehouses full of filing cabinets can now be accessed instantaneously at
the click of a mouse button. Orders placed by customers in foreign countries
can now be instantly processed on the floor of a manufacturing facility. Even
though 20 years ago much of this information had been transported onto
corporate mainframe databases, offices still operated in a batch-processing
environment. If a query needed to be performed, someone notified the management
information systems (MIS) department; the requested data was delivered as soon
as possible. In addition to the development of the relational database model,
two technologies led to the rapid growth of what are now called client/server
database systems. The first important technology was the personal computer.
Inexpensive, easy-to-use applications such as Lotus 1-2-3 and Word Perfect enabled employees (and
home computer users) to create documents and manage data quickly and
accurately. Users became accustomed to continually upgrading systems because
the rate of change was so rapid, even as the price of the more advanced systems
continued to fall.
The vital decision
for a database designer, after the hardware platform and the RDBMS have been
preferred, is the structure of the tables. Decisions made at this stage of the
design can affect performance and programming later during the development
process. The process of separating data into distinct, unique sets is called normalization. The next important
technology was the local area network (LAN) and its integration into offices
across the world. Although users were accustomed to terminal connections to a
corporate mainframe, now word processing files could be stored locally within
an office and accessed from any computer attached to the network. After the
Apple Macintosh introduced a friendly graphical user interface, computers were
not only inexpensive and powerful but also easy to use. In addition, they could
be accessed from remote sites, and large amounts of data could be off-loaded to
departmental data servers.
According to Dr. Codd, the term SQL can be confusing. The S,
for Structured, and the L, for Language, is undemanding enough, but the Q
is a little misleading. Q, of course, stands for "Query,"
which--if taken literally--would restrict you to asking the database questions.
But SQL does much more than ask questions. With SQL you can also create tables,
add data, delete data, splice data together, trigger actions based on changes
to the database, and store your queries within your program or database.
Unfortunately, there is no good substitute for Query. Obviously, Structured
Add Modify Delete Join Store Trigger and Query Language (SAMDJSTQL) is a bit
cumbersome. In the interest of harmony, we will stay with SQL. However, you now
know that its function is bigger than its name. The most commonly used
statement in SQL is the SELECT statement (see Day 2, "Introduction to the Query: The
SELECT
Statement"), which retrieves data from the database and returns the data
to the user. The EMPLOYEE
table example illustrates a typical example of a SELECT statement situation. In addition to the SELECT statement, SQL provides
statements for creating new databases, tables, fields, and indexes, as well as
statements for inserting and deleting records. ANSI SQL also recommends a core
group of data manipulation functions. As you will find out, many database
systems also have tools for ensuring data integrity and enforcing security (see
Day 11, "Controlling Transactions") that enable programmers to stop
the execution of a group of commands if a certain condition occurs.
The context
phenomenon pioneers some of the more popular implementations of SQL, each of
which has its own strengths and weaknesses. Where some implementations of SQL
have been developed for PC use and easy user interactivity, others have been
developed to accommodate very large databases (VLDB). This implemented context
introduces selected key features of some implementations. In addition to
serving as an SQL reference, this article also contains many practical software
development examples. SQL is useful only when it solves your real-world
problems, which occur inside your code. We use Microsoft Access, a PC-based
DBMS, to illustrate some of the examples in this text. Access is very easy to
use. We can use GUI tools or manually enter your SQL statements.
In view of the
above discussion, it is obvious that in creating an object oriented programming
software, the importance SQL is inevitable. In integrating parent-child
relationship, SQL is very important. From SQL, Insert, Update and Delete
Command are helpful. In a nut shell, we exercise Oracle7, which represent the
larger corporate database world, to demonstrate command-line SQL and database
management techniques. These techniques are imperative for the reason that the
days of the standalone machine are drawing to an end, as are the days when
expressive one database or one in commission system was enough. In command-line, simple
stand+[cedilla]one SQL statements are entered into Oracle's SQL*Plus tool. This
tool then returns data to the screen for the user to see, or it performs the
apposite action on the database. Most examples are directed toward the
beginning programmer or first-time user of SQL. We begin with the simplest of
SQL statements and advance to the topics of transaction running and stored
procedure programming. The Oracle RDBMS is circulated with a full complement of
development tools. It comprises a C++ and Visual Basic language library (Oracle
Objects for OLE) that can link an application to a Personal Oracle database. It
also comes with graphical tools for database, user, and object administration,
as well as the SQL*Loader utility, which is used to introduce internally and
send abroad data to and from Oracle.
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