Plsql

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What is PL/SQL? PLSQL stands for "Procedural Language extensions to SQL", and can be used in Oracle databases. PL SQL is closely integrated into the SQL language, yet it adds programming constructs that are not native to SQL. PL/SQL also implements basic exception handling. This tutorial contains an introduction to beginning pl sql. This Oracle pl/sql tutorial also provides a hands on experience for beginning plsql. It contains many free plsql examples which can be reused in your code. Pl/Sql is the procedural implementation of sql i.e. you can pass sql statements in procedural format using pl/sql. Normal sql does not have any procedural capabilities moreover you can only pass one statement at a time to Oracle Engine. Hence, pl/sql have come up to avoid this limitation. Hence, pl/sql is the structured programming language for oracle. It's structure is similar to any other procedural language such as C or C++ PL/SQL Tutorial PL/SQL Tutorial • • • • • • •

Variables and Types Simple PL/SQL Programs Control Flow in PL/SQL Cursors Procedures Discovering Errors Printing Variables Basic Structure of PL/SQL PL/SQL stands for Procedural Language/SQL. PL/SQL extends SQL by adding constructs found in procedural languages, resulting in a structural language that is more powerful than SQL. The basic unit in PL/SQL is a block. All PL/SQL programs are made up of blocks, which can be nested within each other. Typically, each block performs a logical action in he program. A block has the following structure: DECLARE /* Declarative section: variables, types, and local subprograms. */

BEGIN /* Executable section: procedural and SQL statements go here. */ /* This is the only section of the block that is required. */ EXCEPTION /* Exception handling section: error handling statements go here. */ END; Only the executable section is required. The other sections are optional. The only SQL statements allowed in a PL/SQL program are SELECT, INSERT, UPDATE, DELETE and several other data manipulation statements plus some transaction control. However, the SELECT statement has a special form in which a single tuple is placed in variables; more on this later. Data definition statements like CREATE, DROP, or ALTER are not allowed. The executable section also contains constructs such as assignments, branches, loops, procedure calls, and triggers, which are all described below (except triggers). PL/SQL is not case sensitive. C style comments (/* ... */) may be used. To execute a PL/SQL program, we must follow the program text itself by * A line with a single dot ("."), and then * A line with run; As with Oracle SQL programs, we can invoke a PL/SQL program either by typing in sqlplus. Variables and Types Information is transmitted between a PL/SQL program and the database through variables. Every variable has a specific type associated with it. That type can be * One of the types used by SQL for database columns * A generic type used in PL/SQL such as NUMBER * Declared to be the same as the type of some database column The most commonly used generic type is NUMBER. Variables of type NUMBER can hold either an integer or a real number. The most commonly used character string type is VARCHAR(n), where n is the maximum length of the string in bytes. This length is required, and there is no default. For example, we might declare:

DECLARE price NUMBER; myBeer VARCHAR(20); Note that PL/SQL allows BOOLEAN variables, even though Oracle does not support BOOLEAN as a type for database columns. Types in PL/SQL can be tricky. In many cases, a PL/SQL variable will be used to manipulate data stored in a existing relation. In this case, it is essential that the variable have the same type as the relation column. If there is any type mismatch, variable assignments and comparisons may not work the way you expect. To be safe, instead of hard coding the type of a variable, you should use the %TYPE operator. For example: DECLARE myBeer Beers.name%TYPE; gives PL/SQL variable myBeer whatever type was declared for the name column in relation Beers. A variable may also have a type that is a record with several fields. The simplest way to declare such a variable is to use %ROWTYPE on a relation name. The result is a record type in which the fields have the same names and types as the attributes of the relation. For instance: DECLARE beerTuple Beers%ROWTYPE; makes variable beerTuple be a record with fields name and manufacture, assuming that the relation has the schema Beers(name, manufacture). The initial value of any variable, regardless of its type, is NULL. We can assign values to variables, using the ":=" operator. The assignment can occur either immediately after the type of the variable is declared, or anywhere in the executable portion of the program. An example: DECLARE a NUMBER := 3;

BEGIN a := a + 1; END; run; This program has no effect when run, because there are no changes to the database. Simple Programs in PL/SQL The simplest form of program has some declarations followed by an executable section consisting of one or more of the SQL statements with which we are familiar. The major nuance is that the form of the SELECT statement is different from its SQL form. After the SELECT clause, we must have an INTO clause listing variables, one for each attribute in the SELECT clause, into which the components of the retrieved tuple must be placed. Notice we said "tuple" rather than "tuples", since the SELECT statement in PL/SQL only works if the result of the query contains a single tuple. The situation is essentially the same as that of the "singlerow select" discussed in Section 7.1.5 of the text, in connection with embedded SQL. If the query returns more than one tuple, you need to use a cursor. Here is an example: CREATE TABLE T1( e INTEGER, f INTEGER );

DELETE FROM T1; INSERT INTO T1 VALUES(1, 3); INSERT INTO T1 VALUES(2, 4);

/* Above is plain SQL; below is the PL/SQL program. */ DECLARE a NUMBER; b NUMBER; BEGIN SELECT e,f INTO a,b FROM T1 WHERE e>1; INSERT INTO T1 VALUES(b,a); END; run; Fortuitously, there is only one tuple of T1 that has first component greater than 1, namely (2,4). The INSERT statement thus inserts (4,2) into T1. Control Flow in PL/SQL PL/SQL allows you to branch and create loops in a fairly familiar way. An IF statement looks like: IF THEN <statement_list> ELSE <statement_list> END IF; The ELSE part is optional. If you want a multiway branch, use: IF THEN ... ELSIF THEN ... ... ... ELSIF THEN ... ELSE ... END IF; The following is an example, slightly modified from the previous one,

where now we only do the insertion if the second component is 1. If not, we first add 10 to each component and then insert: DECLARE a NUMBER; b NUMBER; BEGIN SELECT e,f INTO a,b FROM T1 WHERE e>1; IF b=1 THEN INSERT INTO T1 VALUES(b,a); ELSE INSERT INTO T1 VALUES(b+10,a+10); END IF; END; run; Loops are created with the following: LOOP /* A list of statements. */ END LOOP; At least one of the statements in should be an EXIT statement of the form EXIT WHEN ; The loop breaks if is true. For example, here is a way to insert each of the pairs (1, 1) through (100, 100) into T1 of the above two examples: DECLARE

i NUMBER := 1; BEGIN LOOP INSERT INTO T1 VALUES(i,i); i := i+1; EXIT WHEN i>100; END LOOP; END; .run; Some other useful loop-forming statements are: * EXIT by itself is an unconditional loop break. Use it inside a conditional if you like. * A WHILE loop can be formed with · WHILE LOOP · END LOOP; * A simple FOR loop can be formed with: · FOR IN <start>.. LOOP · · END LOOP; Here, can be any variable; it is local to the for-loop and need not be declared. Also, <start> and are constants. Cursors A cursor is a variable that runs through the tuples of some relation.

This relation can be a stored table, or it can be the answer to some query. By fetching into the cursor each tuple of the relation, we can write a program to read and process the value of each such tuple. If the relation is stored, we can also update or delete the tuple at the current cursor position. The example below illustrates a cursor loop. It uses our example relation T1(e,f) whose tuples are pairs of integers. The program will delete every tuple whose first component is less than the second, and insert the reverse tuple into T1. 1) DECLARE /* Output variables to hold the result of the query: */ 2) a T1.e%TYPE; 3) b T1.f%TYPE; /* Cursor declaration: */ 4) CURSOR T1Cursor IS 5) SELECT e, f 6) FROM T1 7) WHERE e < f 8) FOR UPDATE; 9) BEGIN 10) OPEN T1Cursor; 11) LOOP /* Retrieve each row of the result of the above query into PL/SQL variables: */ 12) FETCH T1Cursor INTO a, b; /* If there are no more rows to fetch, exit the loop: */ 13) EXIT WHEN T1Cursor%NOTFOUND;

/* Delete the current tuple: */ 14) DELETE FROM T1 WHERE CURRENT OF T1Cursor; /* Insert the reverse tuple: */ 15) INSERT INTO T1 VALUES(b, a); 16) END LOOP; /* Free cursor used by the query. */ 17) CLOSE T1Cursor; 18) END; 19) . 20) run; Here are explanations for the various lines of this program: * Line (1) introduces the declaration section. * Lines (2) and (3) declare variables a and b to have types equal to the types of attributes e and f of the relation T1. Although we know these types are INTEGER, we wisely make sure that whatever types they may have are copied to the PL/SQL variables (compare with the previous example, where we were less careful and declared the corresponding variables to be of type NUMBER). * Lines (4) through (8) define the cursor T1Cursor. It ranges over a relation defined by the SELECT-FROM-WHERE query. That query selects those tuples of T1 whose first component is less than the second component. Line (8) declares the cursor FOR UPDATE since we will modify T1 using this cursor later on Line (14). In general, FOR UPDATE is unnecessary if the cursor will not be used for modification. * Line (9) begins the executable section of the program. * Line (10) opens the cursor, an essential step. * Lines (11) through (16) are a PL/SQL loop. Notice that such a loop is bracketed by LOOP and END LOOP. Within the loop we find: o On Line (12), a fetch through the cursor into the local variables. In general, the FETCH statement must provide variables for each component of the tuple retrieved. Since the query of Lines (5) through (7) produces pairs, we have correctly provided two variables, and we know they are of the correct type. o On Line (13), a test for the loop-breaking condition. Its meaning should be clear: %NOTFOUND after the name of a cursor is true exactly

when a fetch through that cursor has failed to find any more tuples. o On Line (14), a SQL DELETE statement that deletes the current tuple using the special WHERE condition CURRENT OF T1Cursor. o On Line (15), a SQL INSERT statement that inserts the reverse tuple into T1. * Line (17) closes the cursor. * Line (18) ends the PL/SQL program. * Lines (19) and (20) cause the program to execute. Procedures PL/SQL procedures behave very much like procedures in other programming language. Here is an example of a PL/SQL procedure addtuple1 that, given an integer i, inserts the tuple (i, 'xxx') into the following example relation: CREATE TABLE T2 ( a INTEGER, b CHAR(10) );

CREATE PROCEDURE addtuple1(i IN NUMBER) AS BEGIN INSERT INTO T2 VALUES(i, 'xxx'); END addtuple1; run; A procedure is introduced by the keywords CREATE PROCEDURE followed by the procedure name and its parameters. An option is to follow CREATE by OR REPLACE. The advantage of doing so is that should you have already made the definition, you will not get an error. On the other hand, should the previous definition be a different procedure of the same name, you will not be warned, and the old procedure will be lost. There can be any number of parameters, each followed by a mode and a type. The possible modes are IN (read-only), OUT (write-only), and

INOUT (read and write). Note: Unlike the type specifier in a PL/SQL variable declaration, the type specifier in a parameter declaration must be unconstrained. For example, CHAR(10) and VARCHAR(20) are illegal; CHAR or VARCHAR should be used instead. The actual length of a parameter depends on the corresponding argument that is passed in when the procedure is invoked. Following the arguments is the keyword AS (IS is a synonym). Then comes the body, which is essentially a PL/SQL block. We have repeated the name of the procedure after the END, but this is optional. However, the DECLARE section should not start with the keyword DECLARE. Rather, following AS we have: ... AS BEGIN <procedure_body> END; . run; The run at the end runs the statement that creates the procedure; it does not execute the procedure. To execute the procedure, use another PL/SQL statement, in which the procedure is invoked as an executable statement. For example: BEGIN addtuple1(99); END; . run; The following procedure also inserts a tuple into T2, but it takes both components as arguments: CREATE PROCEDURE addtuple2( x T2.a%TYPE, y T2.b%TYPE)

AS BEGIN INSERT INTO T2(a, b) VALUES(x, y); END addtuple2; . run; Now, to add a tuple (10, 'abc') to T2: BEGIN addtuple2(10, 'abc'); END; . run; The following illustrates the use of an OUT parameter: CREATE TABLE T3 ( a INTEGER, b INTEGER );

CREATE PROCEDURE addtuple3(a NUMBER, b OUT NUMBER) AS BEGIN b := 4;

INSERT INTO T3 VALUES(a, b); END; . run; DECLARE v NUMBER; BEGIN addtuple3(10, v); END; run; Note that assigning values to parameters declared as OUT or INOUT causes the corresponding input arguments to be written. Because of this, the input argument for an OUT or INOUT parameter should be something with an "lvalue", such as a variable like v in the example above. A constant or a literal argument should not be passed in for an OUT/INOUT parameter. We can also write functions instead of procedures. In a function declaration, we follow the parameter list by RETURN and the type of the return value: CREATE FUNCTION (<param_list>) RETURN AS ... In the body of the function definition, "RETURN <expression>;" exits from the function and returns the value of <expression>. To find out what procedures and functions you have created, use the following SQL query: select object_type, object_name from user_objects where object_type = 'PROCEDURE'

or object_type = 'FUNCTION'; To drop a stored procedure/function: drop procedure <procedure_name>; drop function ; Discovering Errors PL/SQL does not always tell you about compilation errors. Instead, it gives you a cryptic message such as "procedure created with compilation errors". If you don't see what is wrong immediately, try issuing the command show errors procedure <procedure_name>; Alternatively, you can type, SHO ERR (short for SHOW ERRORS) to see the most recent compilation error. Printing Variables Sometimes we might want to print the value of a PL/SQL local variable. A ``quick-and-dirty'' way is to store it as the sole tuple of some relation and after the PL/SQL statement print the relation with a SELECT statement. A more couth way is to define a bind variable, which is the only kind that may be printed with a print command. Bind variables are the kind that must be prefixed with a colon in PL/SQL statements. The steps are as follows: 1. We declare a bind variable as follows: VARIABLE where the type can be only one of three things: NUMBER, CHAR, or CHAR(n). 2. We may then assign to the variable in a following PL/SQL statement, but we must prefix it with a colon. 3. Finally, we can execute a statement PRINT :;

outside the PL/SQL statement Here is a trivial example, which prints the value 1. VARIABLE x NUMBER BEGIN :x := 1; END; . run; PRINT :x;

PL/SQL BLOCK The pl/sql block contains the following section:------The DECLARE section. -----The Master BEGIN and END section that contains the EXCEPTION section. The declare section contains declaration of memory variables, constants, cursors etc. The begin section contains sql executable statements and pl/sql executable statements. The exception section contains code to handle errors that may arise during the execution of the code block. The end declares the end of pl/sql block. A bit about it's working. When you typed out the pl/sql block for execution. It is sent to the pl/sql engine, where procedural statements are executed; and sql statements are sent to the sql executor in the oracle engine. Since pl/sql engine resides in the oracle engine, the codes executes smoothly and efficiently. PL/SQL DATA-TYPE This is easy since it includes almost all the data types which u have used in sql such as date, varchar, number, char etc etc... Some of the attributes such as %TYPE is also used. This attribute automatically takes in the default data type of the sql table from which u have

passed the query. We will discuss this later. Remember in pl/sql a variable name must begin with a character and can be followed by maximum of 29 other characters. Reserved words can't be used unless enclosed within double quotes. Variables must be separated from each other by at least one space or by a punctuation mark. You can assign values of operator using := operator. I won't discuss about logical comparisons operators such as <, > , >=, NOT, TRUE, AND, OR, NULL etc since they r quite easy to understand. HOW TO DISPLAY MESSAGES ON SCREEN --DBMS_OUTPUT : is a package that includes a number of procedure and functions that accumulate information in a buffer so that it can be retrieved later. These functions can also be used to display messages to the user. PUT_LINE : Put a piece of information in the package buffer followed by an end-of-line marker. It can also be used to display message to the user. Put_line expects a single parameter of character data type. If used to display a message, it is the message 'string'. EG: dbms_output.put_line(x); REMEMBER: To display messages to the user the SERVEROUTPUT should be set to ON. SERVEROUTPUT is a sql*plus environment parameter that displays the information pased as a parameter to the PUT_LINE function. EG: SET SERVEROUTPUT ON A bit about comments. A comment can have 2 forms i.e. -- The comment line begins with a double hyphen (--). The entire line will be treated as a comment. -- The C style comment such as /* i am a comment */ CONDITIONAL CONTROL AND ITERATIVE CONTROL AND SEQUENTIAL CONTROL IF and else..... IF --Condition THEN --Action ELSEIF --Condition THEN --Action ELSE --Action END IF;

SIMPLE LOOP loop -- Sequence of statements; end loop; the loop ends when u use EXIT WHEN statement --condition WHILE LOOP While --condition loop --sequence of statements end loop; FOR LOOP FOR i in 1..10 loop --sequence of statements end loop; GOTO (sequential control) GOTO X; << X >> EXAMPLES --ADDITION declare a number; b number; c number; begin a:=&a; b:=&b; c:=a+b; dbms_output.put_line('Sum of ' || a || ' and ' || b || ' is ' || c); Here & is used to take user input at runtime..... --SUM OF 100 NUMBERS Declare a number; s1 number default 0; Begin a:=1; loop

s1:=s1+a; exit when (a=100); a:=a+1; end loop; dbms_output.put_line('Sum between 1 to 100 is '||s1); End; --SUM OF odd NUMBERS USING USER INPUT...for loop declare n number; sum1 number default 0; endvalue number; begin endvalue:=&endvalue; n:=1; for n in 1.. endvalue loop if mod(n,2)=1 then sum1:=sum1+n; end if end loop; dbms_output.put_line('sum = ' || sum1); end; --SUM OF 100 ODD NUMBER .. WHILE LOOP declare n number; endvalue number; sum1 number default 0; begin endvalue:=&endvalue; n:=1; while (n < endvalue) loop sum1:=sum1+n; n:=n+2; end loop; dbms_output.put_line('Sum of odd numbers between 1 and ' || endvalue || ' is ' || sum1); end; --CALCULATION OF NET SALARY

declare ename varchar2(15); basic number; da number; hra number; pf number; netsalary number; begin ename:=&ename; basic:=&basic; da:=basic * (41/100); hra:=basic * (15/100); if (basic < 3000) then pf:=basic * (5/100); elsif (basic >= 3000 and basic <= 5000) then pf:=basic * (7/100); elsif (basic >= 5000 and basic <= 8000) then pf:=basic * (8/100); else pf:=basic * (10/100); end if; netsalary:=basic + da + hra -pf; dbms_output.put_line('Employee name : ' || ename); dbms_output.put_line('Providend Fund : ' || pf); dbms_output.put_line('Net salary : ' || netsalary); end; --MAXIMUM OF 3 NUMBERS Declare a number; b number; c number; d number; Begin dbms_output.put_line('Enter a:'); a:=&a; dbms_output.put_line('Enter b:'); b:=&b; dbms_output.put_line('Enter c:'); c:=&b;

if (a>b) and (a>c) then dbms_output.putline('A is Maximum'); elsif (b>a) and (b>c) then dbms_output.putline('B is Maximum'); else dbms_output.putline('C is Maximum'); end if; End; --QUERY EXAMPLE--IS SMITH EARNING ENOUGH declare s1 emp.sal %type; begin select sal into s1 from emp where ename = 'SMITH'; if(no_data_found) then raise_application_error (20001,'smith is not present'); end if; if(s1 > 10000) then raise_application_error (20002,'smith is earning enough'); end if; update emp set sal=sal + 500 where ename='SMITH'; end; --PRIME NO OR NOT DECLARE no NUMBER (3) := &no; a NUMBER (4); b NUMBER (2); BEGIN FOR i IN 2..no - 1 LOOP a := no MOD i; IF a = 0 THEN GOTO out; END IF;

END LOOP; <> IF a = 1 THEN DBMS_OUTPUT.PUT_LINE (no || ' is a prime number'); ELSE DBMS_OUTPUT.PUT_LINE (no || ' is not a prime number'); END IF; END; --SIMPLE EXAMPLE OF LOOP STATEMENT I.E. EXIT WHEN Declare a number:= 100; begin loop a := a+25; exit when a=250; end loop; dbms_output.put_line (to_Char(a)); end; --EXAMPLE OF WHILE LOOP Declare i number:=0; j number:= 0; begin while i <=100 loop j := j+1; i := i +2; end loop; dbms_output.put_line(to_char(i)); end; --EXAMPLE OF FOR LOOP Declare begin for i in 1..10 loop dbms_output.put_line(to_char(i)); end loop; end; --SEQUENTIAL CONTROL GOTO

declare --takes the default datatype of the column of the table price cost price.minprice%type; begin select stdprice into cost from price where prodial in (Select prodid from product where prodese = "shampoo"); if cost > 7000 then goto Upd; end if; << Upd >> Update price set minprice = 6999 where prodid=111; end; --CALCULATE THE AREA OF A CIRCLE FOR A VALUE OF RADIUS VARYING FROM 3 TO 7. STORE THE RADIUS AND THE CORRESPONDING VALUES OF CALCULATED AREA IN A TABLE AREAS. Declare pi constant number(4,2) := 3.14; radius number(5); area number(14,2); Begin radius := 3; While radius <=7 Loop area := pi* power(radius,2); Insert into areas values (radius, area); radius:= radius+1; end loop; end; --REVERSING A NUMBER 5639 TO 9365 Declare given_number varchar(5) := '5639'; str_length number(2); inverted_number varchar(5); Begin str_length := length(given_number); For cntr in reverse 1..str_length loop inverted_number := inverted_number || substr(given_number, cntr, 1); end loop;

dbms_output.put_line('The Given no is ' || given_number); dbms_output.put_line('The inverted number is ' || inverted_number); end; EXCEPTION HANDLING IN PLSQL Errors in pl/sql block can be handled...error handling refers to the way we handle the errors in pl/sql block so that no crashing stuff of code takes place...This is exactly the same as we do in C++ or java..right!! There are two type: ===> predefined exceptions ===> user defined exceptions The above 2 terms are self explanatory predefined exceptions: No-data-found == when no rows are returned Cursor-already-open == when a cursor is opened in advance Dup-val-On-index == for duplicate entry of index.. Storage-error == if memory is damaged Program-error == internal problem in pl/sql Zero-divide == divide by zero invalid-cursor == if a cursor is not open and u r trying to close it Login-denied == invalid user name or password Invalid-number == if u r inserting a string datatype for a number datatype which is already declared Too-many-rows == if more rows r returned by select statement SYNTAX begin sequence of statements; exception when --exception name then sequence of statements; end; EXAMPLES --When there is no data returned by row declare price item.actualprice%type; begin Select actual price into price from item where qty=888; when no-data-found then dbms_output.put_line('item missing');

end; --EXAMPLE OF USER DEFINED EXCEPTION DECLARE e_rec emp%ROWTYPE; e1 EXCEPTION; sal1 emp.sal%TYPE; BEGIN SELECT sal INTO sal1 FROM emp WHERE deptno = 30 AND ename = 'John'; IF sal1 < 5000 THEN RAISE e1; sal1 := 8500; UPDATE emp SET sal = sal1 WHERE deptno = 30 AND ename = 'John'; END IF; EXCEPTION WHEN no_data_found THEN RAISE_APPLICATION_ERROR (-20001, 'John is not there.'); WHEN e1 THEN RAISE_APPLICATION_ERROR (-20002, 'Less Salary.'); END; --EXAMPLE OF RAISE-APPLICATION-ERROR... THIS IS YOUR OWN ERROR STATEMENT...YOU RAISE YOUR OWN ERROR Declare s1 emp.sal %type; begin select sal into s1 from emp where ename='SOMDUTT'; if(no-data-found) then raise_application_error(20001, 'somdutt is not there'); end if; if(s1 > 10000) then raise_application_error(20002, 'somdutt is earing a lot'); end if; update emp set sal=sal+500 where ename='SOMDUTT'; end; --INTERESTING EG OF USER DEFINED EXCEPTIONS Declare zero-price exception; price number(8); begin select actualprice into price from item where ordid =400;

if price=0 or price is null then raise zero-price; end if; exception when zero-price then dbms_output.put_line('raised xero-price exception'); end; CURSORS Cursor is a work area in pl/sql which is used by sql server used to store the result of a query. Each column value is pointed using pointer. You can independently manipulate cursor values. A bit about it's working..... suppose you ask for a query stored in the server ... at first a cursor consisting of query result is created in server...now the cursor is transferred to the client where again cursor is created and hence the result is displayed...... Cursors are of 2 types: implicit and explicit.......implicit cursors are created by oracle engine itself while explicit cursors are created by the users......cursors are generally used in such a case when a query returns more than one rows....normal pl/sql returning more than one rows givens error but using cursor this limitation can be avoided....so cursors are used.... Cursor attributes %ISOPEN == returns true if ursor is open, false otherwise %FOUND == returns true if recod was fetched successfully, false otherwise %NOTFOUND == returns true if record was not fetched successfully, false otherwise %ROWCOUNT == returns number of records processed from the cursor. Very important: Cursor can be controlled using following 3 control statements. They are Open, Fetch, Close.....open statement identifies the active set...i.e. query returned by select statement...close statement closes the cursor...and fetch statement fetches rows into the variables...Cursors can be made into use using cursor for loop and fetch statement...we will see the corresponding examples... EXAMPLES --EXAMPLE OF SQL%FOUND (IMPLICIT CURSORS)

begin update employee set salary=salary *0.15 where emp_code = &emp_code; if sql%found then dbms_output.put_line('employee record modified successfully'); else dbms_output.put_line('employee no does not exist'); end if; end; --EXAMPLE FOR SQL%NOTFOUND (IMPLICIT CURSORS) begin update employee set salary = salary*0.15 where emp_code = &emp_code; if sql%notfound then dbms_output.put_line('employee no . does not exist'); else dbms_output.put_line('employee record modified successfully'); end if; end; --EXAMPLE FOR SQL%ROWCOUNT (IMPLICIT CURSORS) declare rows_affected char(4); begin update employee set salary = salary*0.15 where job='programmers'; rows_affected := to_char(sql%rowcount); if sql%rowcount > 0 then dbms_output.put_line(rows_affected || 'employee records modified successfully'); else dbms_output.put_line('There are no employees working as programmers'); end if; end; Syntax Syntax Syntax Syntax

of of of of

explicit cursor: Cursor cursorname is sql select statement; fetch : fetch cursorname into variable1, variable2...; close; close cursorname; open cursor; open cursorname;

--EXPLICIT CURSOR EG

DECLARE CURSOR c1 is SELECT * FROM emp; str_empno emp.empno%type; str_ename emp.ename%type; str_job emp.job%type; str_mgr emp.mgr%type; str_hiredate emp.hiredate%type; str_sal emp.sal%type; str_comm emp.comm%type; str_deptno emp.deptno%type; rno number; BEGIN rno := &rno; FOR e_rec IN c1 LOOP IF c1%rowcount = rno THEN DBMS_OUTPUT.PUT_LINE (str_empno || ' ' || str_ename || ' ' || str_job || ' ' || str_mgr || ' ' || str_hiredate || ' ' || str_sal || ' ' || str_comm || ' ' || str_deptno); END IF; END LOOP; END; --ANOTHER EG DISPLAYING VALUE OF A TABLE DECLARE CURSOR c1 IS SELECT * FROM emp; e_rec emp%rowtype; BEGIN OPEN c1; LOOP FETCH c1 INTO e_rec; DBMS_OUTPUT.PUT_LINE('Number: ' || ' ' || e_rec.empno); DBMS_OUTPUT.PUT_LINE('Name : ' || ' ' || e_rec.ename); DBMS_OUTPUT.PUT_LINE('Salary: ' || ' ' || e_rec.sal); EXIT WHEN c1%NOTFOUND; END LOOP; CLOSE c1; END; -- Display details of Highest 10 salary paid employee DECLARE CURSOR c1 IS SELECT * FROM emp ORDER BY sal DESC; e_rec emp%rowtype; BEGIN

FOR e_rec IN c1 LOOP DBMS_OUTPUT.PUT_LINE('Number: ' || ' ' || e_rec.empno); DBMS_OUTPUT.PUT_LINE('Name : ' || ' ' || e_rec.ename); DBMS_OUTPUT.PUT_LINE('Salary: ' || ' ' || e_rec.sal); EXIT WHEN c1%ROWCOUNT >= 10; END LOOP; END; -- EXAMPLE OF CURSOR FOR LOOP declare cursor c1 is select * from somdutt; begin for outvariable in c1 loop exit when c1%notfound; if outvariable.age < 21 then dbms_output.put_line(outvariable.age || ' ' || outvariable.name); end if; end loop; end; --ref STRONG CURSORS DECLARE TYPE ecursor IS REF CURSOR RETURN emp%ROWTYPE; ecur ecursor; e_rec emp%ROWTYPE; dn NUMBER; BEGIN dn := &deptno; OPEN ecur FOR SELECT * FROM emp WHERE deptno = dn; FOR e_rec IN ecur LOOP DBMS_OUTPUT.PUT_LINE ('Employee No : ' || e_rec.empno); DBMS_OUTPUT.PUT_LINE ('Employee Salary: ' || e_rec.salary); END LOOP; END; --REF WEAK CURSORS DECLARE TYPE tcursor IS REF CURSOR; tcur tcursor; e1 emp%ROWTYPE; d1 dept%ROWTYPE;

tname VARCHAR2(20); BEGIN tname := &tablename; IF tname = 'emp' THEN OPEN tcur FOR SELECT * FORM emp; DBMS_OUTPUT.PUT_LINE ('Emp table opened.'); close tcur; DBMS_OUTPUT.PUT_LINE ('Emp table closed.'); ELSE IF tname = 'dept' THEN OPEN tcur FOR SELECT * FROM dept; DBMS_OUTPUT.PUT_LINE ('Dept table opened.'); close tcur; DBMS_OUTPUT.PUT_LINE ('Emp table closed.'); ELSE RAISE_APPLICATION_ERROR (-20004, 'Table name is wrong'); END IF; END; --CURSOR FOR LOOP WITH PARAMETERS Declare Cursor c1(Dno number) is select * from emp where deptno = dno; begin for empree in c1(10) loop; dbms_output.put_line(empree.ename); end loop; end; TRIGGERS Trigger is a stored procedure which is called implicitly by oracle engine whenever a insert, update or delete statement is fired. Advantages of database triggers: ---> Data is generated on it's own ---> Replicate table can be maintained ---> To enforce complex integrity contraints ---> To edit data modifications ---> To autoincrement a field etc.. Syntax: Create or replace trigger --triggername-- [before/after] [insert/pdate/delete] on --tablename-- [for each satement/ for each row] [when --condition--] plus..begin.and exception

Triggers are of following type: before or after trigger ....and for each row and for each statement trigger... before trigger is fired before insert/update/delete statement while after trigger is fired after insert/update/delete statement...for each row and for each statements triggers are self explainatory.. EXAMPLE -- A database trigger that allows changes to employee table only during the business hours(i.e. from 8 a.m to 5.00 p.m.) from monday to saturday. There is no restriction on viewing data from the table -CREATE OR REPLACE TRIGGER Time_Check BEFORE INSERT OR UPDATE OR DELETE ON EMP BEGIN IF TO_NUMBER(TO_CHAR(SYSDATE,'hh24')) < 10 OR TO_NUMBER(TO_CHAR(SYSDATE,'hh24')) >= 17 OR TO_CHAR(SYSDATE,'DAY') = 'SAT' OR TO_CHAR(SYSDATE,'DAY') = 'SAT' THEN RAISE_APPLICATION_ERROR (-20004,'YOU CAN ACCESS ONLY BETWEEN 10 AM TO 5 PM ON MONDAY TO FRIDAY ONLY.'); END IF; END; --YOU HAVE 2 TABLES WITH THE SAME STRUCTURE. IF U DELETE A RECORD FROM ONE TABLE , IT WILL BE INSERTED IN 2ND TABLE ED TRIGGERNAME Create or replace trigger backup after delete on emp fro each row begin insert into emp/values (:old.ename,:old.job,:old.sal); end; save the file.. and then sql> @ triggername --To STICK IN SAL FIELD BY TRIGGER MEANS WHEN U ENTER GREATER THAN 5000, THEN THIS TRIGGER IS EXECUTED Create or replace trigger check before insert on emp for each row when (New.sal > 5000); begin raise_application_error(-20000, 'your no is greater than 5000'); end; -NO CHANGES CAN BE DONE ON A PARTICULAR TABLE ON SUNDAY AND SATURDAY Create or replace trigger change before on emp for each row when (to_char(sysdate,'dy') in ('SAT','SUN')) begin raise_application_error(-200001, 'u cannot enter data in saturnday and sunday'); end; --IF U ENTER IN EMP TABLE ENAME FIELD'S DATA IN ANY CASE IT WILL BE INSERTED IN CAPITAL LETTERS'S ONLY Create or replace trigger cap before insert on emp for each row begin :New.ename = upper(:New.ename); end; --A TRIGGER WHICH WILL NOT ALLOW U TO ENTER DUPLICATE VALUES IN FIELD EMPNO IN EMP TABLE Create or replace trigger dubb before insert on emp for each row Declare cursor c1 is select * from emp; x emp%rowtype; begin open c1; loop fetch c1 into x; if :New.empno = x.empno then dbms_output.put_line('you entered duplicated no'); elseif :New.empno is null then dbms_output.put_line('you empno is null'); end if; exit when c1%notfound; end loop; close c1; end; Remember trigger can be dropped using Drop Trigger triggername ; statement...

PROCEDURES AND FUNCTIONS procedure is a subprogram...which consists of a set of sql statement. Procedures are not very different from functions. A procedure or function is a logically grouped set of SQL and PL/SQL statements that perform a specific task. A stored procedure or function is a named pl/sql code block that have been compiled and stored in one of the oracle engines's system tables. To make a procedure or function dynamic either of them can be passed parameters before execution. A procedure or function can then change the way it works depending upon the parameters passed prior to its execution. Procedures and function are made up of a declarative part, an executable part and an optional exception-handling part A declaration part consists of declarations of variables. A executable part consists of the logic i.e. sql statements....and exception handling part handles any error during run-time The oracle engine performs the following steps to execute a procedure or function....Verifies user access, Verifies procedure or function validity and executes the procedure or function. Some of the advantages of using procedures and functions are: security, performance, memory allocation, productivity, integrity. Most important the difference between procedures and functions: A function must return a value back to the caller. A function can return only one value to the calling pl/sql block. By defining multiple out parameters in a procedure, multiple values can be passed to the caller. The out variable being global by nature, its value is accessible by any pl/sql code block including the calling pl/sql block. Syntax for stored procedure: CREATE OR REPLACE PROCEDURE [schema] procedure name (argument { IN, OUT, IN OUT} data type, ..) {IS, AS} variable declarations; constant declarations; BEGIN pl/sql subprogram body; EXCEPTION exception pl/sql block; END; Syntax for stored function: CREATE OR REPLACE FUNCTION [schema] functionname(argument IN

data type, ..) RETURN data type {IS, AS} variable declarations; constant declarations; BEGIN pl/sql subprogram body; EXCEPTION exception pl/sql block; END; The above syntax i think is self explanatory...but i will give you some details...IN : specifies that a value for the argument must be specified when calling the procedure or function. argument : is the name of an argument to the procedure or function. parentheses can be omitted if no arguments are present. OUT : specifies that the procedure passes a value for this argument back to its calling environment after execution. IN OUT : specifies that a value for the argument must be specified when calling the procedure and that the procedure passes a value for this argument back to its calling environment after execution. By default it takes IN. Data type : is the data type of an argument. EXAMPLES --PROCEDURE USING NO ARGUMENT..AND USING CURSOR CREATE OR REPLACE PROCEDURE P2 IS cursor cur1 is select * from emp; begin for erec in cur1 loop dbms_output.put_line(erec.ename); end loop; end; --PROCEDURE USING ARGUMENT CREATE OR REPLACE PROCEDURE ME( X IN NUMBER) IS BEGIN dbms_output.put_line(x*x); end; sql> exec me(3); --FUNCTION using argument CREATE OR REPLACE FUNCTION RMT(X IN NUMBER) RETURN NUMBER IS BEGIN dbms_output.put_line(x*x); --return (x*x); end;

(make a block like this to run it.....) begin dbms_output.put_line(rmt(3)); end; --CREATE A PROCEDURE THAT DELETE ROWS FROM ENQUIRY --WHICH ARE 1 YRS BEFORE Create or replace procedure myprocedure is begin delete from enquiry where enquirydate <= sysdate - 1; end; --CREATE A PROCEDURE THAT TAKES ARGUMENT STUDENT NAME, --AND FIND OUT FEES PAID BY THAT STUDENT CREATE or REPLACE procedure me (namee in varchar) is cursor c1 is select a.feespaiddate from feespaid a, enrollment b, enquiry c where c.enquiryno = b.enquiryno and a.rollno = b.rollno and c.fname = namee; begin for erec in c1 loop dbms_output.put_line(erec.feespaiddate); end loop; end; --SUM OF 2 Numbers CREATE or replace procedure p1 is Declare a number; b number; c number; Begin a:=50; b:=89; c:=a+b; dbms_output.put_line('Sum of '||a||' and '||b||' is '||c); End; --DELETION PROCEDURE

create or replace procedure myproc is begin delete from enquiry where fname='somdutt'; end; --IN and OUT procedure example Create or replace procedure lest ( a number, b out number) is identify number; begin select ordid into identity from item where itemid = a; if identity < 1000 then b := 100; end if; end l --in out parameter Create or replace procedure sample ( a in number, b in out number) is identity number; begin select ordid, prodid into identity, b from item where itemid=a; if b<600 then b := b + 100; end if; end; now procedure is called by passing parameter declare a number; b number; begin sample(3000, b) dbms_output.put_line(1th value of b is 11 b); end ; --SIMILAR EXAMPLE AS BEFORE create or replace procedure getsal( sal1 in out number) is begin select sal into sal1 from emp where empno = sal1; end ;

now use the above in plsql block declare sal1 number := 7999; begin getsal(sal1); dbms_output.put_line('The employee salary is' || sal1); end ; You can make a procedure and functions similarly.....also if u wanna drop a function then use drop function functionname and for procedure use drop procedure procedurename PACKAGES A package is an oracle object, which holds other objects within it. Objects commonly held within a package are procedures, functions, variables, constants, cursors and exceptions. Packages in plsql is very much similar to those packages which we use in JAVA......yeah!! java packages holds numerous classes..right!!!... A package has 2 parts..... package specification and package body A package specification part consists of all sort of declaration of functions and procedures while package body consists of codings and logic of declared functions and procedures... EXAMPLE --SIMPLEST EG --specification create or replace package pack2 is function rmt(x in number) return number; procedure rmt1(x in number); end; --body create or replace package body pack2 is function rmt(x in number) return number is begin return (x*x);

end; procedure rmt1(x in number) is begin dbms_output.put_line(x*x); end; end; (how to run.....) exec packagename.procedurename i.e. exec pack2.rmt1(3); As shown above u can put in complicated procedures and functions inside the package...I have just shown a simple example...you can easily modify the above code to fit your requirement......Just try out packages which includes cursors, procedures and functions..etc..Remeber pl/sql supports overloading...i.e. you can use the same function or procedure name in your application but with different no or type of arguments.

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