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Without the break statements, each case would drop through to the next.
If variable declarations appear in the compound statement within a switch statement, initializers on auto or register declarations are ineffective. However, initializations within the statements following a case are effective. Consider the following example:
switch (ch) { int nx = 1; /* Initialization ignored */ printf("%d", n); /* This first printf is not executed */ case 'a' : { int n = 5; /* Proper initialization occurs */ printf("%d", n); break; } case 'b' : { break; } default : { break; } } |
In this example, if
ch == 'a'
, then the program prints the value 5. If the variable equals any other
letter, the program prints nothing because the initialization occurs
outside of the
case
label, and statements outside of the
case
label are ineffective.
7.6 Iteration Statements
An iteration statement, or loop, repeatedly executes a statement, known as the loop body, until the controlling expression is false (0). The control expression must have a scalar type.
The while statement evaluates the control expression before executing the loop body (see Section 7.6.1).
The do statement evaluates the control expression after executing the loop body; at least one execution of the loop body is guaranteed (see Section 7.6.2).
The
for
statement executes the loop body based on the evaluation of the second
of three expressions (see Section 7.6.3).
7.6.1 The while Statement
The while statement evaluates a control expression before each execution of the loop body. If the control expression is true (nonzero), the loop body is executed. If the control expression is false (0), the while statement terminates. The while statement has the following syntax:
while ( expression ) statement |
Consider the following while statement:
n = 0; while (n < 10) { a[n] = n; n++; } |
This statement tests the value of
n
; if
n
is less than 10, it assigns
n
to the nth element of the array
a
and then increments
n
. The control expression (in parentheses) is then evaluated; if true
(nonzero), the loop body is executed again; if false (0), the
while
statement terminates. If the statement
n++
were missing from the loop body, this
while
statement would never terminate. If the statement
n = 0
were replaced by the statement
n = 10
, the control expression is initially false (0), and the loop body is
never executed.
7.6.2 The do Statement
The do statement evaluates the control expression after each execution of the loop body. The do statement has the following syntax:
do statement |
The loop body is executed at least once. The control expression is
evaluated after each execution of the loop body. If the control
expression is true (nonzero), the statement is executed again. If the
control expression is false (0), the
do
statement terminates.
7.6.3 The for Statement
The for statement evaluates three expressions and executes the loop body until the second controlling expression evaluates to false (0). The for statement is useful for executing a loop body a specified number of times. The for statement has the following syntax:
for ( expression-1opt ; expression-2opt ; expression-3opt) |
The for statement is equivalent to the following code:
expression-1; |
while ( expression-2 ) { |
The for statement executes the loop body zero or more times. Semicolons (;) are used to separate the control expressions. A for statement executes the following steps:
Any of the three expressions in a for loop can be omitted:
for (i = 0; ;i++) statement; |
n = 1; for ( ; n < 10; n++) func(n); |
In relaxed ANSI C mode, the first clause of the for statement can be a declaration whose scope includes the remaining clauses of the for header and the entire loop body. This is normally used to declare and initialize a local loop control variable. For example:
for (int i=0; i<10; i++) printf("%d\n", i); |
Jump statements cause an unconditional jump to another statement elsewhere in the code. They are used primarily to interrupt switch statements and loops.
The jump statements are the
goto
statement, the
continue
statement, the
break
statement, and the
return
statement, which are discussed in the following sections.
7.7.1 The goto Statement
The goto statement unconditionally transfers program control to a labeled statement, where the label identifier is in the scope of the function containing the goto statement. The labeled statement is the next statement executed. The goto statement has the following syntax:
goto identifier; |
Care must be taken when branching into a block by using the
goto
statement, because storage is allocated for automatic variables
declared within a block when the block is activated. When a
goto
statement branches into a block, automatic variables declared in the
block are not initialized.
7.7.2 The continue Statement
The continue statement passes control to the end of the immediately enclosing while , do , or for statement. The continue statement has the following syntax:
continue; |
The continue statement is equivalent to a goto statement within an iteration statement that passes control to the end of the loop body. For example, the following two loops are equivalent:
while(1) while(1) { { . . . . . . goto label_1; continue; . . . . . . label_1: ; ; } } |
The
continue
statement can be used only in loops. A
continue
inside a
switch
statement that is inside a loop causes continued execution of the
enclosing loop after exiting from the body of the
switch
statement.
7.7.3 The break Statement
The break statement terminates execution of the immediately enclosing while , do , for , or switch statement. Control passes to the statement following the loop body (or the compound statement of a switch statement). The break statement has the following syntax:
break; |
See Example 7-1 which uses a
break
statement within a
switch
statement.
7.7.4 The return Statement
The return statement terminates execution of a function and returns control to the calling function, with or without a return value. A function may contain any number of return statements. The return statement has the following syntax:
return expressionopt; |
If present, the expression is evaluated and its value is returned to the calling function. If necessary, its value is converted to the declared type of the containing function's return value.
A return statement with an expression cannot appear in a function whose return type is void . For more information about the void data type and function return types, see Sections 3.5 and 3.4.1.
If there is no expression and the function is not defined as void , the return value is undefined. For example, the following main function returns an unpredictable value to the operating system:
main ( ) { return; } |
Reaching the closing brace that terminates a function is equivalent to executing a return statement without an expression.
The C preprocessor provides the ability to perform macro substitution, conditional compilation, and inclusion of named files. Preprocessor directives, lines beginning with # and possibly preceded by white space, are used to communicate with the preprocessor.
The following sections describe the preprocessor directives and operators available with the Compaq C compiler:
Preprocessor directives are independent of the usual scope rules; they remain in effect from their occurrence until the end of the compilation unit or until their effect is canceled.
See Section 8.2 for more information about conditional compilation.
See your platform-specific Compaq C documentation for
implementation-defined information about preprocessor directives.
The ANSI standard allows only comments as text following a
preprocessing directive. The Compaq C compiler issues a warning if
this syntax rule is violated in all modes but the strict ANSI mode, in
which it issues an error message.
8.1 Macro Definition (#define and #undef)
The #define directive specifies a macro identifier and a replacement list, and terminates with a new-line character. The replacement list, a sequence of preprocessing tokens, is substituted for every subsequent occurrence of that macro identifier in the program text, unless the identifier occurs inside a character constant, a comment, or a literal string. The #undef directive is used to cancel a definition for a macro.
A macro definition is independent of block structure, and is in effect from the #define directive that defines it until either a corresponding #undef directive or the end of the compilation unit is encountered.
The #define directive has the following syntax:
#define identifier replacement-list newline |
#define identifier ( identifier-listopt ) replacement-list newline |
#define identifier ( ... ) replacement-list newline |
#define identifier ( identifier-list, ... replacement-list newline |
If the replacement-list is empty, subsequent occurrences of the identifier are deleted from the source file.
The first form of the #define directive is called an object-like macro. The last three forms are called function-like macros.
The #undef directive has the following syntax:
#undef identifier newline |
This directive cancels a previous definition of the identifier by #define . Redefining a macro previously defined is not legal, unless the new definition is precisely the same as the old.
The replacement list in the macro definition, as well as arguments in a function-like macro reference, can contain other macro references. Compaq C does not limit the depth to which such references can be nested.
For a given macro definition, any macro names contained in the replacement list are themselves replaced by their currently specified replacement lists. If a macro name being defined is contained in its own replacement list or in a nested replacement list, it is not replaced. These nonreplaced macro names are then no longer available for further replacement, even if they are later examined in contexts in which they would otherwise be replaced.
The following example shows nested #define directives:
/* Show multiple substitutions and listing format. */ #define AUTHOR james + LAST main() { int writer,james,michener,joyce; #define LAST michener writer = AUTHOR; #undef LAST #define LAST joyce writer = AUTHOR; } |
After this example is compiled with the appropriate options to show intermediate macro expansions, the following listing results:
1 /* Show multiple substitutions and listing format. */ 2 3 #define AUTHOR james + LAST 4 5 main() 6 { 7 int writer, james, michener, joyce; 8 9 #define LAST michener 10 writer = AUTHOR; 10.1 james + LAST 10.2 michener 11 #undef LAST 12 #define LAST joyce 13 writer = AUTHOR; 13.1 james + LAST 13.2 joyce 14 } |
On the first pass, the compiler replaces the identifier AUTHOR with the replacement list james + LAST . On the second pass, the compiler replaces the identifier LAST with its currently defined replacement list value. At line 9, the replacement list value for LAST is the identifier michener , so michener is substituted at line 10. At line 12, the replacement list value for LAST is redefined to be the identifier joyce , so joyce is substituted at line 13.
The #define directive may be continued onto subsequent lines if necessary. To do this, end each line to be continued with a backslash (\) immediately followed by a new-line character. The backslash and new-line characters do not become part of the definition. The first character in the next line is logically adjacent to the character that immediately precedes the backslash. The backslash/newline as a continuation sequence is valid anywhere. However, comments within the definition line can be continued without the backslash/newline.
If you plan to port programs to and from other C implementations, take
care in choosing which macro definitions to use within your programs,
because some implementations define different macros than others.
8.1.1 Object-Like Form
A preprocessing directive of the following form defines an object-like macro that causes each subsequent occurrence of the macro name to be replaced by the replacement list:
#define identifier replacement-list newline |
An object like macro may be redefined by another #define directive provided that the second definition is an object-like macro definition and the two replacement lists are identical. This means that two files, each with a definition of a certain macro, must be consistent in that definition.
The object-like form of macro definition defines a descriptive name for a frequently used token. A common use of the directive is to define the end-of-file ( EOF ) indicator as follows:
#define EOF (-1) |
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