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To write C programs using character sets that do not contain all of C's punctuation characters, ANSI C allows the use of nine trigraph sequences in the source file. These three-character sequences are replaced by a single character in the first phase of compilation. (See Section 2.16 for an explanation of compilation phases.) Table 1-1 lists the valid trigraph sequences and their character equivalents.
Trigraph Sequence | Character Equivalent |
---|---|
??= | # |
??( | [ |
??/ | \ |
??) | ] |
??' | ^ |
??< | { |
??! | | |
??> | } |
??- | ~ |
No other trigraph sequences are recognized. A question mark (?) that does not begin a trigraph sequence remains unchanged during compilation. For example, consider the following source line:
printf ("Any questions???/n"); |
After the ??/ sequence is replaced, this line is translated as follows:
printf ("Any questions?\n"); |
Digraph processing is supported when compiling in ISO C 94 mode (/STANDARD=ISOC94 on OpenVMS systems).
Digraphs are pairs of characters that translate into a single character, much like trigraphs, except that trigraphs get replaced inside string literals, but digraphs do not. Table 1-2 lists the valid digraph sequences and their character equivalents.
Digraph Sequence | Character Represented |
---|---|
<: | [ |
:> | ] |
<% | { |
%> | } |
%: | # |
%:%: | ## |
An identifier is a sequence of characters that represents a name for the following:
The following rules apply to identifiers:
struct employee { int number; char sex; } emp; |
An identifier without external linkage has at most 32,767 significant characters. An identifier with external linkage has 1023 significant characters on Tru64 UNIX systems and 31 significant characters for OpenVMS platforms. ( Section 2.8 describes linkage in more detail.) Case is not significant in external identifiers on OpenVMS systems.
Identifiers that differ within their significant characters are different identifiers. If two or more identifiers differ in nonsignificant characters only, they are treated as the same identifier.
The /* character combination introduces a comment and the */ character combination ends a comment, except within a character constant or string literal.
Comments cannot be nested; once a comment is started, the compiler treats the first occurrence of */ as the end of the comment.
To comment out sections of code, avoid using the /* and */ sequences. Using the /* and */ sequences works only for code sections containing no comments, because comments do not nest. A better method is to use the #if and #endif preprocessor directives, as in the following example:
#if 0 /* This code is excluded from execution because ... */ code_to_be_excluded (); #endif |
See Chapter 8 for more information on the preprocessing directives #if and #endif .
Comments cannot span source files. Within a source file, comments can
be of any length and are interpreted as white space by both the
compiler and the preprocessor.
1.4 Keywords
C defines several keywords, each with special meaning to the compiler. Keywords identify statement constructs and specify basic types and storage classes. Keywords cannot be used as identifiers and cannot be declared.
Table 1-3 lists the C keywords.
==:::::::::::::=
auto | double | int | struct |
break | else | long | switch |
case | enum | register | typedef |
char | extern | return | union |
const | float | short | unsigned |
continue | for | signed | void |
default | goto | sizeof | volatile |
do | if | static | while =,==,==,==,==,==,==,==,==,==,==,==,==,= |
In addition to the keywords listed in Table 1-3, the compiler reserves all identifiers that begin with two underscores (__) or with an underscore followed by an uppercase letter. User variable names must never begin with one of these sequences.
The following VAX C keywords are also sometimes 1 recognized by the compiler:
_align globaldef globalref globalvalue noshare readonly variant_struct variant_union |
The following C99 Standard keywords are also sometimes 2 recognized by the compiler:
inline restrict |
Use of a keyword as a superfluous macro name is not recommended, but is legal; for example, to change the default size of a basic data type:
#define int short |
Here, the keyword int has been redefined as short , which causes all data objects declared with the int data type to be stored as short objects.
1 Recognized on OpenVMS systems when /STANDARD=RELAXED_ANSI (the default), /STANDARD=VAXC or /ACCEPT=VAXC_KEYWORDS is specified on the compiler command line. Recognized on Tru64 UNIX systems when -vaxc or -accept vaxc_keywords is specified on the compiler command line.2 Recognized on OpenVMS systems when /STANDARD=RELAXED_ANSI (the default), or /ACCEPT=C99_KEYWORDS is specified on the compiler command line. Recognized on Tru64 UNIX systems when -std (the default) or -accept c99_keywords is specified on the compiler command line. |
An operator is a token that specifies an operation on at least one operand, and yields some result (a value, designator, side effect, or some combination). Operands are expressions or constants (a form of expression). Operators with one operand are unary operators, and operators with two operands are binary operators. For example:
x = -b; /* Unary minus operator */ y = a - c; /* Binary minus operator */ |
Operators with three operands are called ternary operators.
All operators are ranked by precedence, a ranking system determining which operators are evaluated before others in a statement. See Chapter 6 for information on what each operator does and for the rules of operator precedence.
Some operators in C are composed of more than one character, while others are single characters. The single-character operators in C are:
! % ^ & * - + = ~ | . < > / ? : , [ ] ( ) # |
The multiple-character operators in C are:
++ -- -> << >> <= >= == != *= /= %= += -= <<= >>= &= ^= |= ## && || |
The # and ## operators can only be used in preprocessor macro definitions. See Chapter 8 for more information on predefined macros and preprocessor directives.
The sizeof operator determines the size of a data type. See Chapter 6 for more information on the sizeof operator.
The old form for compound assignment operators ( =+ , =- , =* , =/ , =% , =<< , =>> , =& , =^ , and =| ) is not supported by the ANSI C standard. Use of these operators in a program is unsupported, and will produce unpredictable results. For example:
x =-3; |
This construction means
x
is assigned the value
-3
, not
x
is assigned the value
x - 3
.
The error-checking compiler option provides a warning message when the
old form of compound assignment operators is encountered.
1.6 Punctuators
Some characters in C are used as punctuators, which have their own syntactic and semantic significance. Punctuators are not operators or identifiers. Table 1-4 lists the C punctuators.
Punctuator | Use | Example |
---|---|---|
< > | Header name | <limits.h> |
[ ] | Array delimiter | char a[7]; |
{ } | Initializer list, function body, or compound statement delimiter | char x[4] = {'H', 'i', '!', '\0' }; |
( ) | Function parameter list delimiter; also used in expression grouping | int f (x,y) |
* | Pointer declaration | int *x; |
, | Argument list separator | char x[4] = { 'H', 'i', '!', '\0'}; |
: | Statement label | labela: if (x == 0) x += 1; |
= | Declaration initializer | char x[4] = { "Hi!" }; |
; | Statement end | x += 1; |
... | Variable-length argument list | int f ( int y, ...) |
# | Preprocessor directive | #include <limits.h> |
' ' | Character constant | char x = 'x'; |
" " | String literal or header name | char x[] = "Hi!"; |
The following punctuators must be used in pairs:
< >
[ ]
( )
' '
" "
{ }
Some characters can be used either as a punctuator or as an operator,
or as part of an operator. The context of the occurrence specifies the
meaning. Punctuators usually delineate a specific type of C construct,
as shown in Table 1-4.
1.7 String Literals
Strings are sequences of zero or more characters. String literals are character strings surrounded by quotation marks. String literals can include any valid character, including white-space characters and character escape sequences. Once stored as a string literal, modification of the string leads to undefined results.
In the following example, ABC is the string literal. It is assigned to a character array where each character in the string literal is stored as one array element. Storing a string literal in a character array lets you modify the characters of the array.
char x[] = "ABC"; |
String literals are typically stored as arrays of type char (or wchar_t ) if prefaced with an L , and have static storage duration.
The following declaration declares a character array to hold the string "Hello!":
char s[] = "Hello!"; |
The character array s is initialized with the characters specified in the double quotation marks, and terminated with a null character ( \0 ) . The null character marks the end of each string, and is automatically concatenated to the end of the string literal by the compiler. Adjacent string literals are automatically concatenated (with a single null character added at the end) to reduce the need for the line continuation character (the backslash at the end of a line).
Following are some valid string literals:
"" /* Here's a string with only the null character */ "You can have many characters in a string." "\"You can mix characters and escape sequences.\"\n" "Long lines of text can be continued on the next line \ by using the backslash character at the end of a line." "Or, long lines of text can be continued by using " "ANSI's concatenation of adjacent string literals." "\'\n" /* Only escape sequences are in this string */ |
To determine the length of a given string literal (not including the
null character), use the
strlen
function. See Chapter 9 for more information on other library
routines available for string manipulation.
1.8 Constants
There are four categories of constants in C:
The following sections describe these constants.
The value of any constant must be within the range of representable values for the specified type. Regardless of its type, a constant is a literal or symbolic value that does not change. A constant is also an rvalue, as defined in Section 2.14.
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