Logical Operators

1. Logical Operators • Java provides two binary logical operators (&& and ||) that are used to combine boolean expressions. • Java also provides one unary (!) logical operator to reverse the truth of a boolean expression.

2. Logical Operators

3. The && Operator • The logical AND operator (&&) takes two operands that must both be boolean expressions. • The resulting combined expression is true iff (if and only if) both operands are true.

4. The || Operator • The logical OR operator (||) takes two operands that must both be boolean expressions. • The resulting combined expression is false iff (if and only if) both operands are false.

5. The ! Operator • The ! operator performs a logical NOT operation. • If an expression is true, !expression will be false. if (!(temperature > 100)) System.out.println(“Below the maximum temperature."); • If temperature > 100 evaluates to false, then the output statement will be run.

6. Short Circuiting • Logical AND and logical OR operations perform short-circuit evaluation of expressions. • Logical AND will evaluate to false as soon as it sees that one of its operands is a false expression. • Logical OR will evaluate to true as soon as it sees that one of its operands is a true expression.

7. Order of Precedence • The ! operator has a higher order of precedence than the && and || operators. • The && and || operators have a lower precedence than relational operators like < and >. • Parenthesis can be used to force the precedence to be changed.

8. Order of Precedence

9. Comparing String Objects • In most cases, you cannot use the relational operators to compare two String objects. • Reference variables contain the address of the object they represent. • Unless the references point to the same object, the relational operators will not return true.

10. Ignoring Case in String Comparisons • In the String class the equals and compareTo methods are case sensitive. • In order to compare two String objects that might have different case, use: • equalsIgnoreCase, or • compareToIgnoreCase

11. Variable Scope • In Java, a local variable does not have to be declared at the beginning of the method. • The scope of a local variable begins at the point it is declared and terminates at the end of the method. • When a program enters a section of code where a variable has scope, that variable has come into scope, which means the variable is visible to the program.

12. The Conditional Operator • The conditional operator is a ternary (three operand) operator. • The conditional operator allows a programmer to write a simple if-else type statement. • The format of the operators is: expression1 ? expression2 : expression3 • The conditional operator can also return a value.

13. The Conditional Operator • The conditional operator can be used as a shortened if-else statement: x > y ? z = 10 : z = 5; • This line is functionally equivalent to: if(x > y) z = 10; else z = 5;

14. The Conditional Operator • Many times, the conditional operator is used to supply a value. number = x > y ? 10 : 5; • This is functionally equivalent to: if(x > y) number = 10; else number = 5;

15. The switch Statement • The if-else statements allow the programmer to make true / false branches. • The switch statement allows the programmer to use an ordinal value to determine how a program will branch. • The switch statement can evaluate an integer type or character type variable and make decisions based on the value.

16. The switch Statement • The switch statement takes the form: switch (SwitchExpression) { case CaseExpression: // place one or more statements here break; case CaseExpression: // place one or more statements here break; // case statements may be repeated //as many times as necessary default: // place one or more statements here }

17. The switch Statement • The switch statement takes an ordinal value (byte, short, int, long, char) as the SwitchExpression. switch (SwitchExpression) { … } • The switch statement will evaluate the expression. • If there is an associated case statement that matches that value, program execution will be transferred to that case statement.

18. The switch Statement • Each case statement will have a corresponding CaseExpression that must be unique. case CaseExpression: // place one or more statements here break; • If the SwitchExpression matches the CaseExpression, the Java statements between the colon and the break statement will be executed.

19. The switch Case • The break statement ends the case statement. • The break statement is optional. • If a case does not contain a break, then program execution continues into the next case. • The default case is optional and will be executed if no CaseExpression matches the SwitchExpression.

20. The Increment and Decrement Operators • There are numerous times where a variable must simply be incremented or decremented. number = number + 1; number = number – 1; • Java provide shortened ways to increment and decrement a variable’s value. • Using the ++ or – unary operators, this task can be completed quickly. number++; or ++number; number--; or --number;

21. Differences Between Prefix and Postfix • When an increment or decrement are the only operations in a statement, there is no difference between prefix and postfix notation. • When used in an expression: • prefix notation indicates that the variable will be incremented or decremented prior to the rest of the equation being evaluated. • postfix notation indicates that the variable will be incremented or decremented after the rest of the equation has been evaluated.

22. The while Loop • Java provides three different looping structures. • The while loop has the form: while(condition){ statements; } • While the condition is true, the statements will execute repeatedly. • The while loop is a pretest loop, which means that it will test the value of the condition prior to executing the loop.

23. The while Loop • Care must be taken to set the condition to false somewhere in the loop so the loop will end. • Loops that do not end are called infinite loops. • A while loop executes 0 or more times since if the condition is false, the loop will not execute.

24. true boolean expression? statement(s) false The while loop Flowchart

25. Infinite Loops • In order for a while loop to end, the condition must become false. { int x = 20; while(x > 0){ System.out.println(“x is greater than 0”); } } • The variable x never gets decremented so it will always be greater than 0.

26. Infinite Loops • In order for a while loop to end, the condition must become false. { int x = 20; while(x > 0){ System.out.println(“x is greater than 0”); x--; } } • The variable x never gets decremented so it will always be greater than 0. • Adding the x-- above fixes the problem.

27. Block Statements in Loops • Although not required for single statement while loops, convention holds that while loops always use curly braces. • Curly braces are required to enclose block statement while loops. (like block if statements) while(condition){ single or block statements; }

28. The while Loop for Input Validation • Input validation is the process of ensuring that user input is valid. System.out.print("Enter a number in the " + "range of 1 through 100: "); number = Keyboard.readInt(); // Validate the input. while (number < 1 || number > 100) { System.out.println("That number is invalid."); System.out.print("Enter a number in the " + "range of 1 through 100: "); number = Keyboard.readInt(); }

29. The do-while Loop • The do-while loop is a post-test loop, which means it will execute the loop prior to testing the condition. • The do-while loop, more commonly called a do loop, takes the form: do{ statements }while(condition);

30. statement(s) true boolean expression? false The do-while Loop Flowchart

31. The for Loop • The for loop is a specialized form of the while loop, meaning it is a pre-test loop. • The for loop allows the programmer to initialize a control variable, test a condition, and modify the control variable all in one line of code. • The for loop takes the form: for(initialization; test; update) { loop statements; }

32. true boolean expression? statement(s) update false The for Loop Flowchart

33. The Sections of the for Loop • The initialization section of the for loop allows the loop to initialize its own control variable. • The test section of the for statement acts in the same manner as the condition section of a while loop. • The update section of the for loop is the last thing to execute at the end of each loop.

34. The for Loop Initialization • The initialization section of a for loop is optional; however, it is usually provided. • Typically, for loops initialize a counting variable that will be tested by the test section of the loop and updated by the update section. • The initialization section can initialize multiple variables. • Variables declared in this section have scope only for the for loop.

35. The Update Expression • The update expression is usually used to increment or decrement the counting variable(s) declared in the initialization section of the for loop. • The update section of the loop executes last in the loop. • The update section may update multiple variables. • Each variable updated is executed as if it were on a line by itself.

36. Modifying The Control Variable • It is bad programming style to update the control variable of a for loop within the body of the loop. • The update section should be used to update the control variable. • Updating the control variable in the for loop body leads to hard to maintain code and difficult debugging.

37. Multiple Initializations and Updates • The for loop may initialize and update multiple variables. for(int i = 5, int j = 0; i < 10 || j < 20; i++, j+=2){ loop statements; } • Note that the only parts of a for loop that are mandatory are the semicolons. for(;;){ loop statements; }//infinite loop. • If left out, the test section defaults to true.

38. Running Totals • Loops allow the program to keep running totals while evaluating data. • Imagine needing to keep a running total of user input.

39. Sentinel Values • Sometimes (usually) the end point of input data is not known. • A sentinel value can be used to notify the program to stop acquiring input. • If it is a user input, the user could be prompted to input data that is not normally in the input data range (i.e. –1 where normal input would be positive.) • Programs that get file input typically use the end-of-file marker to stop acquiring input data.

40. Nested Loops • Like if statements, loops can be nested. • If a loop is nested, the inner loop will execute all of its iterations for each time the outer loop executes once. for(int i = 0; i < 10; i++) for(int j = 0; j < 10; j++) loop statements; • The loop statements in this example will execute 100 times.

41. The break and continue Statements • The break statement can be used to abnormally terminate a loop. • The use of the break statement in loops bypasses the normal mechanisms and makes the code hard to read and maintain. • It is considered bad form to use the break statement in this manner.

42. The continue Statement • The continue statement will cause the currently executing iteration of a loop to terminate and the next iteration will begin. • The continue statement will cause the evaluation of the condition in while and for loops. The update statement will also be executed in for loops. • Like the break statement, the continue statement should be avoided because it makes the code hard to read and debug.

43. Deciding Which Loops to Use • The while loop: • Pretest loop • Use it where you do not want the statements to execute if the condition is false in the beginning. • The do-while loop: • Post-test loop • Use it where you want the statements to execute at least one time. • The for loop: • Pretest loop • Use it where there is some type of counting variable that can be evaluated.