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The syntax of the C programming language is the set of rules governing writing of software in C. It is designed to allow for programs that are extremely terse, have a close relationship with the resulting object code, and yet provide relatively high-level data abstraction. C was the first widely successful high-level language for portable operating-system development.
C syntax makes use of the maximal munch principle.
The C programming language represents numbers in three forms: integral , real and complex . This distinction reflects similar distinctions in the instruction set architecture of most central processing units. Integral data types store numbers in the set of integers, while real and complex numbers represent numbers (or pair of numbers) in the set of real numbers in floating-point form.
All C integer types have signed
and unsigned
variants. If signed
or unsigned
is not specified explicitly, in most circumstances, signed
is assumed. However, for historic reasons, plain char
is a type distinct from both signed char
and unsigned char
. It may be a signed type or an unsigned type, depending on the compiler and the character set (C guarantees that members of the C basic character set have positive values). Also, bit field types specified as plain int
may be signed or unsigned, depending on the compiler.
C's integer types come in different fixed sizes, capable of representing various ranges of numbers. The type char
occupies exactly one byte (the smallest addressable storage unit), which is typically 8 bits wide. (Although char
can represent any of C's "basic" characters, a wider type may be required for international character sets.) Most integer types have both signed and unsigned varieties, designated by the signed
and unsigned
keywords. Signed integer types always use the two's complement representation, since C23 [1] (and in practive before; in older C versions before C23 the representation might alternatively have been ones' complement, or sign-and-magnitude, but in practice that has not been the case for decades on modern hardware). In many cases, there are multiple equivalent ways to designate the type; for example, signed short int
and short
are synonymous.
The representation of some types may include unused "padding" bits, which occupy storage but are not included in the width. The following table provides a complete list of the standard integer types and their minimum allowed widths (including any sign bit).
Shortest form of specifier | Minimum width (bits) |
---|---|
_Bool | 1 |
char | 8 |
signed char | 8 |
unsigned char | 8 |
short | 16 |
unsigned short | 16 |
int | 16 |
unsigned int | 16 |
long | 32 |
unsigned long | 32 |
long long [note 1] | 64 |
unsigned long long [note 1] | 64 |
The char
type is distinct from both signed char
and unsigned char
, but is guaranteed to have the same representation as one of them. The _Bool
and long long
types are standardized since 1999, and may not be supported by older C compilers. Type _Bool
is usually accessed via the typedef
name bool
defined by the standard header stdbool.h
.
In general, the widths and representation scheme implemented for any given platform are chosen based on the machine architecture, with some consideration given to the ease of importing source code developed for other platforms. The width of the int
type varies especially widely among C implementations; it often corresponds to the most "natural" word size for the specific platform. The standard header limits.h defines macros for the minimum and maximum representable values of the standard integer types as implemented on any specific platform.
In addition to the standard integer types, there may be other "extended" integer types, which can be used for typedef
s in standard headers. For more precise specification of width, programmers can and should use typedef
s from the standard header stdint.h.
Integer constants may be specified in source code in several ways. Numeric values can be specified as decimal (example: 1022
), octal with zero (0
) as a prefix (01776
), or hexadecimal with 0x
(zero x) as a prefix (0x3FE
). A character in single quotes (example: 'R'
), called a "character constant," represents the value of that character in the execution character set, with type int
. Except for character constants, the type of an integer constant is determined by the width required to represent the specified value, but is always at least as wide as int
. This can be overridden by appending an explicit length and/or signedness modifier; for example, 12lu
has type unsigned long
. There are no negative integer constants, but the same effect can often be obtained by using a unary negation operator "-
".
The enumerated type in C, specified with the enum
keyword, and often just called an "enum" (usually pronounced /ˈiːnʌm/ EE-num or /ˈiːnuːm/ EE-noom), is a type designed to represent values across a series of named constants. Each of the enumerated constants has type int
. Each enum
type itself is compatible with char
or a signed or unsigned integer type, but each implementation defines its own rules for choosing a type.
Some compilers warn if an object with enumerated type is assigned a value that is not one of its constants. However, such an object can be assigned any values in the range of their compatible type, and enum
constants can be used anywhere an integer is expected. For this reason, enum
values are often used in place of preprocessor #define
directives to create named constants. Such constants are generally safer to use than macros, since they reside within a specific identifier namespace.
An enumerated type is declared with the enum
specifier and an optional name (or tag) for the enum, followed by a list of one or more constants contained within curly braces and separated by commas, and an optional list of variable names. Subsequent references to a specific enumerated type use the enum
keyword and the name of the enum. By default, the first constant in an enumeration is assigned the value zero, and each subsequent value is incremented by one over the previous constant. Specific values may also be assigned to constants in the declaration, and any subsequent constants without specific values will be given incremented values from that point onward. For example, consider the following declaration:
enumcolors{RED,GREEN,BLUE=5,YELLOW}paint_color;
This declares the enum colors
type; the int
constants RED
(whose value is 0), GREEN
(whose value is one greater than RED
, 1), BLUE
(whose value is the given value, 5), and YELLOW
(whose value is one greater than BLUE
, 6); and the enum colors
variable paint_color
. The constants may be used outside of the context of the enum
(where any integer value is allowed), and values other than the constants may be assigned to paint_color
, or any other variable of type enum colors
.
A floating-point form is used to represent numbers with a fractional component. They do not, however, represent most rational numbers exactly; they are instead a close approximation. There are three standard types of real values, denoted by their specifiers (and since C23 three more decimal types): single precision (float
), double precision (double
), and double extended precision (long double
). Each of these may represent values in a different form, often one of the IEEE floating-point formats.
Type specifiers | Precision (decimal digits) | Exponent range | ||
---|---|---|---|---|
Minimum | IEEE 754 | Minimum | IEEE 754 | |
float | 6 | 7.2 (24 bits) | ±37 | ±38 (8 bits) |
double | 10 | 15.9 (53 bits) | ±37 | ±307 (11 bits) |
long double | 10 | 34.0 (113 bits) | ±37 | ±4931 (15 bits) |
Floating-point constants may be written in decimal notation, e.g. 1.23
. Decimal scientific notation may be used by adding e
or E
followed by a decimal exponent, also known as E notation, e.g. 1.23e2
(which has the value 1.23 × 102 = 123.0). Either a decimal point or an exponent is required (otherwise, the number is parsed as an integer constant). Hexadecimal floating-point constants follow similar rules, except that they must be prefixed by 0x
and use p
or P
to specify a binary exponent, e.g. 0xAp-2
(which has the value 2.5, since Ah × 2−2 = 10 × 2−2 = 10 ÷ 4). Both decimal and hexadecimal floating-point constants may be suffixed by f
or F
to indicate a constant of type float
, by l
(letter l
) or L
to indicate type long double
, or left unsuffixed for a double
constant.
The standard header file float.h
defines the minimum and maximum values of the implementation's floating-point types float
, double
, and long double
. It also defines other limits that are relevant to the processing of floating-point numbers.
C23 introduces three additional decimal (as opposed to binary) real floating-point types: _Decimal32, _Decimal64, and _Decimal128.
Despite that, the radix has historically been binary (base 2), meaning numbers like 1/2 or 1/4 are exact, but not 1/10, 1/100 or 1/3. With decimal floating point all the same numbers are exact plus numbers like 1/10 and 1/100, but still not e.g. 1/3. No known implementation does opt into the decimal radix for the previously known to be binary types. Since most computers do not even have the hardware for the decimal types, and those few that do (e.g. IBM mainframes since IBM System z10), can use the explicitly decimal types.
Every object has a storage class. This specifies most basically the storage duration, which may be static (default for global), automatic (default for local), or dynamic (allocated), together with other features (linkage and register hint).
Specifiers | Lifetime | Scope | Default initializer |
---|---|---|---|
auto | Block (stack) | Block | Uninitialized |
register | Block (stack or CPU register) | Block | Uninitialized |
static | Program | Block or compilation unit | Zero |
extern | Program | Global (entire program) | Zero |
_Thread_local | Thread | ||
(none)1 | Dynamic (heap) | Uninitialized (initialized to 0 if using calloc() ) |
malloc()
and free()
library functions.Variables declared within a block by default have automatic storage, as do those explicitly declared with the auto
[note 2] or register
storage class specifiers. The auto
and register
specifiers may only be used within functions and function argument declarations; as such, the auto
specifier is always redundant. Objects declared outside of all blocks and those explicitly declared with the static
storage class specifier have static storage duration. Static variables are initialized to zero by default by the compiler.
Objects with automatic storage are local to the block in which they were declared and are discarded when the block is exited. Additionally, objects declared with the register
storage class may be given higher priority by the compiler for access to registers; although the compiler may choose not to actually store any of them in a register. Objects with this storage class may not be used with the address-of (&
) unary operator. Objects with static storage persist for the program's entire duration. In this way, the same object can be accessed by a function across multiple calls. Objects with allocated storage duration are created and destroyed explicitly with malloc
, free
, and related functions.
The extern
storage class specifier indicates that the storage for an object has been defined elsewhere. When used inside a block, it indicates that the storage has been defined by a declaration outside of that block. When used outside of all blocks, it indicates that the storage has been defined outside of the compilation unit. The extern
storage class specifier is redundant when used on a function declaration. It indicates that the declared function has been defined outside of the compilation unit.
The _Thread_local
(thread_local
in C++, and in C since C23, and in earlier versions of C if the header <threads.h>
is included) storage class specifier, introduced in C11, is used to declare a thread-local variable. It can be combined with static
or extern
to determine linkage.
Note that storage specifiers apply only to functions and objects; other things such as type and enum declarations are private to the compilation unit in which they appear. Types, on the other hand, have qualifiers (see below).
Types can be qualified to indicate special properties of their data. The type qualifier const
indicates that a value does not change once it has been initialized. Attempting to modify a const
qualified value yields undefined behavior, so some C compilers store them in rodata or (for embedded systems) in read-only memory (ROM). The type qualifier volatile
indicates to an optimizing compiler that it may not remove apparently redundant reads or writes, as the value may change even if it was not modified by any expression or statement, or multiple writes may be necessary, such as for memory-mapped I/O.
An incomplete type is a structure or union type whose members have not yet been specified, an array type whose dimension has not yet been specified, or the void
type (the void
type cannot be completed). Such a type may not be instantiated (its size is not known), nor may its members be accessed (they, too, are unknown); however, the derived pointer type may be used (but not dereferenced).
They are often used with pointers, either as forward or external declarations. For instance, code could declare an incomplete type like this:
structthing*pt;
This declares pt
as a pointer to struct thing
and the incomplete type struct thing
. Pointers to data always have the same byte-width regardless of what they point to, so this statement is valid by itself (as long as pt
is not dereferenced). The incomplete type can be completed later in the same scope by redeclaring it:
structthing{intnum;};/* thing struct type is now completed */
Incomplete types are used to implement recursive structures; the body of the type declaration may be deferred to later in the translation unit:
typedefstructBertBert;typedefstructWilmaWilma;structBert{Wilma*wilma;};structWilma{Bert*bert;};
Incomplete types are also used for data hiding; the incomplete type is defined in a header file, and the body only within the relevant source file.
In declarations the asterisk modifier (*
) specifies a pointer type. For example, where the specifier int
would refer to the integer type, the specifier int*
refers to the type "pointer to integer". Pointer values associate two pieces of information: a memory address and a data type. The following line of code declares a pointer-to-integer variable called ptr:
int*ptr;
When a non-static pointer is declared, it has an unspecified value associated with it. The address associated with such a pointer must be changed by assignment prior to using it. In the following example, ptr is set so that it points to the data associated with the variable a:
inta=0;int*ptr=&a;
In order to accomplish this, the "address-of" operator (unary &
) is used. It produces the memory location of the data object that follows.
The pointed-to data can be accessed through a pointer value. In the following example, the integer variable b is set to the value of integer variable a, which is 10:
inta=10;int*p;p=&a;intb=*p;
In order to accomplish that task, the unary dereference operator, denoted by an asterisk (*), is used. It returns the data to which its operand—which must be of pointer type—points. Thus, the expression *p denotes the same value as a. Dereferencing a null pointer is illegal.
Arrays are used in C to represent structures of consecutive elements of the same type. The definition of a (fixed-size) array has the following syntax:
intarray[100];
which defines an array named array to hold 100 values of the primitive type int
. If declared within a function, the array dimension may also be a non-constant expression, in which case memory for the specified number of elements will be allocated. In most contexts in later use, a mention of the variable array is converted to a pointer to the first item in the array. The sizeof
operator is an exception: sizeof array
yields the size of the entire array (that is, 100 times the size of an int
, and sizeof(array) / sizeof(int)
will return 100). Another exception is the & (address-of) operator, which yields a pointer to the entire array, for example
int(*ptr_to_array)[100]=&array;
The primary facility for accessing the values of the elements of an array is the array subscript operator. To access the i-indexed element of array, the syntax would be array[i]
, which refers to the value stored in that array element.
Array subscript numbering begins at 0 (see Zero-based indexing). The largest allowed array subscript is therefore equal to the number of elements in the array minus 1. To illustrate this, consider an array a declared as having 10 elements; the first element would be a[0]
and the last element would be a[9]
.
C provides no facility for automatic bounds checking for array usage. Though logically the last subscript in an array of 10 elements would be 9, subscripts 10, 11, and so forth could accidentally be specified, with undefined results.
Due to arrays and pointers being interchangeable, the addresses of each of the array elements can be expressed in equivalent pointer arithmetic. The following table illustrates both methods for the existing array:
Element | First | Second | Third | nth |
---|---|---|---|---|
Array subscript | array[0] | array[1] | array[2] | array[n-1] |
Dereferenced pointer | *array | *(array+1) | *(array+2) | *(array+n-1) |
Since the expression a[i]
is semantically equivalent to *(a+i)
, which in turn is equivalent to *(i+a)
, the expression can also be written as i[a]
, although this form is rarely used.
C99 standardised variable-length arrays (VLAs) within block scope. Such array variables are allocated based on the value of an integer value at runtime upon entry to a block, and are deallocated at the end of the block. [3] As of C11 this feature is no longer required to be implemented by the compiler.
intn=...;inta[n];a[3]=10;
This syntax produces an array whose size is fixed until the end of the block.
Arrays that can be resized dynamically can be produced with the help of the C standard library. The malloc
function provides a simple method for allocating memory. It takes one parameter: the amount of memory to allocate in bytes. Upon successful allocation, malloc
returns a generic (void
) pointer value, pointing to the beginning of the allocated space. The pointer value returned is converted to an appropriate type implicitly by assignment. If the allocation could not be completed, malloc
returns a null pointer. The following segment is therefore similar in function to the above desired declaration:
#include<stdlib.h> /* declares malloc */...int*a=malloc(n*sizeof*a);a[3]=10;
The result is a "pointer to int
" variable (a) that points to the first of n contiguous int
objects; due to array–pointer equivalence this can be used in place of an actual array name, as shown in the last line. The advantage in using this dynamic allocation is that the amount of memory that is allocated to it can be limited to what is actually needed at run time, and this can be changed as needed (using the standard library function realloc
).
When the dynamically allocated memory is no longer needed, it should be released back to the run-time system. This is done with a call to the free
function. It takes a single parameter: a pointer to previously allocated memory. This is the value that was returned by a previous call to malloc
.
As a security measure, some programmers [ who? ] then set the pointer variable to NULL
:
free(a);a=NULL;
This ensures that further attempts to dereference the pointer, on most systems, will crash the program. If this is not done, the variable becomes a dangling pointer which can lead to a use-after-free bug. However, if the pointer is a local variable, setting it to NULL
does not prevent the program from using other copies of the pointer. Local use-after-free bugs are usually easy for static analyzers to recognize. Therefore, this approach is less useful for local pointers and it is more often used with pointers stored in long-living structs. In general though, setting pointers to NULL
is good practice [ according to whom? ] as it allows a programmer to NULL
-check pointers prior to dereferencing, thus helping prevent crashes.
Recalling the array example, one could also create a fixed-size array through dynamic allocation:
int(*a)[100]=malloc(sizeof*a);
...Which yields a pointer-to-array.
Accessing the pointer-to-array can be done in two ways:
(*a)[index];index[*a];
Iterating can also be done in two ways:
for(inti=0;i<100;i++)(*a)[i];for(int*i=a[0];i<a[1];i++)*i;
The benefit to using the second example is that the numeric limit of the first example isn't required, which means that the pointer-to-array could be of any size and the second example can execute without any modifications.
In addition, C supports arrays of multiple dimensions, which are stored in row-major order. Technically, C multidimensional arrays are just one-dimensional arrays whose elements are arrays. The syntax for declaring multidimensional arrays is as follows:
intarray2d[ROWS][COLUMNS];
where ROWS and COLUMNS are constants. This defines a two-dimensional array. Reading the subscripts from left to right, array2d is an array of length ROWS, each element of which is an array of COLUMNS integers.
To access an integer element in this multidimensional array, one would use
array2d[4][3]
Again, reading from left to right, this accesses the 5th row, and the 4th element in that row. The expression array2d[4]
is an array, which we are then subscripting with [3] to access the fourth integer.
Element | First | Second row, second column | ith row, jth column |
---|---|---|---|
Array subscript | array[0][0] | array[1][1] | array[i-1][j-1] |
Dereferenced pointer | *(*(array+0)+0) | *(*(array+1)+1) | *(*(array+i-1)+j-1) |
Higher-dimensional arrays can be declared in a similar manner.
A multidimensional array should not be confused with an array of pointers to arrays (also known as an Iliffe vector or sometimes an array of arrays). The former is always rectangular (all subarrays must be the same size), and occupies a contiguous region of memory. The latter is a one-dimensional array of pointers, each of which may point to the first element of a subarray in a different place in memory, and the sub-arrays do not have to be the same size. The latter can be created by multiple uses of malloc
.
In C, string literals are surrounded by double quotes ("
) (e.g., "Hello world!"
) and are compiled to an array of the specified char
values with an additional null terminating character (0-valued) code to mark the end of the string.
String literals may not contain embedded newlines; this proscription somewhat simplifies parsing of the language. To include a newline in a string, the backslash escape \n
may be used, as below.
There are several standard library functions for operating with string data (not necessarily constant) organized as array of char
using this null-terminated format; see below.
C's string-literal syntax has been very influential, and has made its way into many other languages, such as C++, Objective-C, Perl, Python, PHP, Java, JavaScript, C#, and Ruby. Nowadays, almost all new languages adopt or build upon C-style string syntax. Languages that lack this syntax tend to precede C.
Because certain characters cannot be part of a literal string expression directly, they are instead identified by an escape sequence starting with a backslash (\
). For example, the backslashes in "This string contains \"double quotes\"."
indicate (to the compiler) that the inner pair of quotes are intended as an actual part of the string, rather than the default reading as a delimiter (endpoint) of the string itself.
Backslashes may be used to enter various control characters, etc., into a string:
Escape | Meaning |
---|---|
\\ | Literal backslash |
\" | Double quote |
\' | Single quote |
\n | Newline (line feed) |
\r | Carriage return |
\b | Backspace |
\t | Horizontal tab |
\f | Form feed |
\a | Alert (bell) |
\v | Vertical tab |
\? | Question mark (used to escape trigraphs, obsolete features dropped in C23) |
%% | Percentage mark, printf format strings only (Note \% is non standard and is not always recognised) |
\OOO | Character with octal value OOO (where OOO is 1-3 octal digits, '0'-'7') |
\xHH | Character with hexadecimal value HH (where HH is 1 or more hex digits, '0'-'9','A'-'F','a'-'f') |
The use of other backslash escapes is not defined by the C standard, although compiler vendors often provide additional escape codes as language extensions. One of these is the escape sequence \e
for the escape character with ASCII hex value 1B which was not added to the C standard due to lacking representation in other character sets (such as EBCDIC). It is available in GCC, clang and tcc.
C has string literal concatenation, meaning that adjacent string literals are concatenated at compile time; this allows long strings to be split over multiple lines, and also allows string literals resulting from C preprocessor defines and macros to be appended to strings at compile time:
printf(__FILE__": %d: Hello ""world\n",__LINE__);
will expand to
printf("helloworld.c"": %d: Hello ""world\n",10);
which is syntactically equivalent to
printf("helloworld.c: %d: Hello world\n",10);
Individual character constants are single-quoted, e.g. 'A'
, and have type int
(in C++, char
). The difference is that "A"
represents a null-terminated array of two characters, 'A' and '\0', whereas 'A'
directly represents the character value (65 if ASCII is used). The same backslash-escapes are supported as for strings, except that (of course) "
can validly be used as a character without being escaped, whereas '
must now be escaped.
A character constant cannot be empty (i.e. ''
is invalid syntax), although a string may be (it still has the null terminating character). Multi-character constants (e.g. 'xy'
) are valid, although rarely useful — they let one store several characters in an integer (e.g. 4 ASCII characters can fit in a 32-bit integer, 8 in a 64-bit one). Since the order in which the characters are packed into an int
is not specified (left to the implementation to define), portable use of multi-character constants is difficult.
Nevertheless, in situations limited to a specific platform and the compiler implementation, multicharacter constants do find their use in specifying signatures. One common use case is the OSType, where the combination of Classic Mac OS compilers and its inherent big-endianness means that bytes in the integer appear in the exact order of characters defined in the literal. The definition by popular "implementations" are in fact consistent: in GCC, Clang, and Visual C++, '1234'
yields 0x31323334
under ASCII. [5] [6]
Like string literals, character constants can also be modified by prefixes, for example L'A'
has type wchar_t
and represents the character value of "A" in the wide character encoding.
Since type char
is 1 byte wide, a single char
value typically can represent at most 255 distinct character codes, not nearly enough for all the characters in use worldwide. To provide better support for international characters, the first C standard (C89) introduced wide characters (encoded in type wchar_t
) and wide character strings, which are written as L"Hello world!"
Wide characters are most commonly either 2 bytes (using a 2-byte encoding such as UTF-16) or 4 bytes (usually UTF-32), but Standard C does not specify the width for wchar_t
, leaving the choice to the implementor. Microsoft Windows generally uses UTF-16, thus the above string would be 26 bytes long for a Microsoft compiler; the Unix world prefers UTF-32, thus compilers such as GCC would generate a 52-byte string. A 2-byte wide wchar_t
suffers the same limitation as char
, in that certain characters (those outside the BMP) cannot be represented in a single wchar_t
; but must be represented using surrogate pairs.
The original C standard specified only minimal functions for operating with wide character strings; in 1995 the standard was modified to include much more extensive support, comparable to that for char
strings. The relevant functions are mostly named after their char
equivalents, with the addition of a "w" or the replacement of "str" with "wcs"; they are specified in <wchar.h>
, with <wctype.h>
containing wide-character classification and mapping functions.
The now generally recommended method [note 3] of supporting international characters is through UTF-8, which is stored in char
arrays, and can be written directly in the source code if using a UTF-8 editor, because UTF-8 is a direct ASCII extension.
A common alternative to wchar_t
is to use a variable-width encoding, whereby a logical character may extend over multiple positions of the string. Variable-width strings may be encoded into literals verbatim, at the risk of confusing the compiler, or using numerical backslash escapes (e.g. "\xc3\xa9"
for "é" in UTF-8). The UTF-8 encoding was specifically designed (under Plan 9) for compatibility with the standard library string functions; supporting features of the encoding include a lack of embedded nulls, no valid interpretations for subsequences, and trivial resynchronisation. Encodings lacking these features are likely to prove incompatible with the standard library functions; encoding-aware string functions are often used in such cases.
Strings, both constant and variable, can be manipulated without using the standard library. However, the library contains many useful functions for working with null-terminated strings.
Structures and unions in C are defined as data containers consisting of a sequence of named members of various types. They are similar to records in other programming languages. The members of a structure are stored in consecutive locations in memory, although the compiler is allowed to insert padding between or after members (but not before the first member) for efficiency or as padding required for proper alignment by the target architecture. The size of a structure is equal to the sum of the sizes of its members, plus the size of the padding.
Unions in C are related to structures and are defined as objects that may hold (at different times) objects of different types and sizes. They are analogous to variant records in other programming languages. Unlike structures, the components of a union all refer to the same location in memory. In this way, a union can be used at various times to hold different types of objects, without the need to create a separate object for each new type. The size of a union is equal to the size of its largest component type.
Structures are declared with the struct
keyword and unions are declared with the union
keyword. The specifier keyword is followed by an optional identifier name, which is used to identify the form of the structure or union. The identifier is followed by the declaration of the structure or union's body: a list of member declarations, contained within curly braces, with each declaration terminated by a semicolon. Finally, the declaration concludes with an optional list of identifier names, which are declared as instances of the structure or union.
For example, the following statement declares a structure named s
that contains three members; it will also declare an instance of the structure known as tee
:
structs{intx;floaty;char*z;}tee;
And the following statement will declare a similar union named u
and an instance of it named n
:
unionu{intx;floaty;char*z;}n;
Members of structures and unions cannot have an incomplete or function type. Thus members cannot be an instance of the structure or union being declared (because it is incomplete at that point) but can be pointers to the type being declared.
Once a structure or union body has been declared and given a name, it can be considered a new data type using the specifier struct
or union
, as appropriate, and the name. For example, the following statement, given the above structure declaration, declares a new instance of the structure s
named r
:
structsr;
It is also common to use the typedef
specifier to eliminate the need for the struct
or union
keyword in later references to the structure. The first identifier after the body of the structure is taken as the new name for the structure type (structure instances may not be declared in this context). For example, the following statement will declare a new type known as s_type that will contain some structure:
typedefstruct{...}s_type;
Future statements can then use the specifier s_type (instead of the expanded struct
... specifier) to refer to the structure.
Members are accessed using the name of the instance of a structure or union, a period (.
), and the name of the member. For example, given the declaration of tee from above, the member known as y (of type float
) can be accessed using the following syntax:
tee.y
Structures are commonly accessed through pointers. Consider the following example that defines a pointer to tee, known as ptr_to_tee:
structs*ptr_to_tee=&tee;
Member y of tee can then be accessed by dereferencing ptr_to_tee and using the result as the left operand:
(*ptr_to_tee).y
Which is identical to the simpler tee.y
above as long as ptr_to_tee points to tee. Due to operator precedence ("." being higher than "*"), the shorter *ptr_to_tee.y
is incorrect for this purpose, instead being parsed as *(ptr_to_tee.y)
and thus the parentheses are necessary. Because this operation is common, C provides an abbreviated syntax for accessing a member directly from a pointer. With this syntax, the name of the instance is replaced with the name of the pointer and the period is replaced with the character sequence ->
. Thus, the following method of accessing y is identical to the previous two:
ptr_to_tee->y
Members of unions are accessed in the same way.
This can be chained; for example, in a linked list, one may refer to n->next->next
for the second following node (assuming that n->next
is not null).
Assigning values to individual members of structures and unions is syntactically identical to assigning values to any other object. The only difference is that the lvalue of the assignment is the name of the member, as accessed by the syntax mentioned above.
A structure can also be assigned as a unit to another structure of the same type. Structures (and pointers to structures) may also be used as function parameter and return types.
For example, the following statement assigns the value of 74 (the ASCII code point for the letter 't') to the member named x in the structure tee, from above:
tee.x=74;
And the same assignment, using ptr_to_tee in place of tee, would look like:
ptr_to_tee->x=74;
Assignment with members of unions is identical.
According to the C standard, the only legal operations that can be performed on a structure are copying it, assigning to it as a unit (or initializing it), taking its address with the address-of (&
) unary operator, and accessing its members. Unions have the same restrictions. One of the operations implicitly forbidden is comparison: structures and unions cannot be compared using C's standard comparison facilities (==
, >
, <
, etc.).
C also provides a special type of member known as a bit field, which is an integer with an explicitly specified number of bits. A bit field is declared as a structure (or union) member of type int
, signed int
, unsigned int
, or _Bool
, [note 4] following the member name by a colon (:
) and the number of bits it should occupy. The total number of bits in a single bit field must not exceed the total number of bits in its declared type (this is allowed in C++ however, where the extra bits are used for padding).
As a special exception to the usual C syntax rules, it is implementation-defined whether a bit field declared as type int
, without specifying signed
or unsigned
, is signed or unsigned. Thus, it is recommended to explicitly specify signed
or unsigned
on all structure members for portability.
Unnamed fields consisting of just a colon followed by a number of bits are also allowed; these indicate padding. Specifying a width of zero for an unnamed field is used to force alignment to a new word. [7] Since all members of a union occupy the same memory, unnamed bit-fields of width zero do nothing in unions, however unnamed bit-fields of non zero width can change the size of the union since they have to fit in it.
The members of bit fields do not have addresses, and as such cannot be used with the address-of (&
) unary operator. The sizeof
operator may not be applied to bit fields.
The following declaration declares a new structure type known as f
and an instance of it known as g
. Comments provide a description of each of the members:
structf{unsignedintflag:1;/* a bit flag: can either be on (1) or off (0) */signedintnum:4;/* a signed 4-bit field; range -7...7 or -8...7 */signedint:3;/* 3 bits of padding to round out to 8 bits */}g;
Default initialization depends on the storage class specifier, described above.
Because of the language's grammar, a scalar initializer may be enclosed in any number of curly brace pairs. Most compilers issue a warning if there is more than one such pair, though.
intx=12;inty={23};//Legal, no warningintz={{34}};//Legal, expect a warning
Structures, unions and arrays can be initialized in their declarations using an initializer list. Unless designators are used, the components of an initializer correspond with the elements in the order they are defined and stored, thus all preceding values must be provided before any particular element's value. Any unspecified elements are set to zero (except for unions). Mentioning too many initialization values yields an error.
The following statement will initialize a new instance of the structure s known as pi:
structs{intx;floaty;char*z;};structspi={3,3.1415,"Pi"};
Designated initializers allow members to be initialized by name, in any order, and without explicitly providing the preceding values. The following initialization is equivalent to the previous one:
structspi={.z="Pi",.x=3,.y=3.1415};
Using a designator in an initializer moves the initialization "cursor". In the example below, if MAX
is greater than 10, there will be some zero-valued elements in the middle of a
; if it is less than 10, some of the values provided by the first five initializers will be overridden by the second five (if MAX
is less than 5, there will be a compilation error):
inta[MAX]={1,3,5,7,9,[MAX-5]=8,6,4,2,0};
In C89, a union was initialized with a single value applied to its first member. That is, the union u defined above could only have its int x member initialized:
unionuvalue={3};
Using a designated initializer, the member to be initialized does not have to be the first member:
unionuvalue={.y=3.1415};
If an array has unknown size (i.e. the array was an incomplete type), the number of initializers determines the size of the array and its type becomes complete:
intx[]={0,1,2};
Compound designators can be used to provide explicit initialization when unadorned initializer lists might be misunderstood. In the example below, w
is declared as an array of structures, each structure consisting of a member a
(an array of 3 int
) and a member b
(an int
). The initializer sets the size of w
to 2 and sets the values of the first element of each a
:
struct{inta[3],b;}w[]={[0].a={1},[1].a[0]=2};
This is equivalent to:
struct{inta[3],b;}w[]={{{1,0,0},0},{{2,0,0},0}};
There is no way to specify repetition of an initializer in standard C.
It is possible to borrow the initialization methodology to generate compound structure and array literals:
// pointer created from array literal.int*ptr=(int[]){10,20,30,40};// pointer to array.float(*foo)[3]=&(float[]){0.5f,1.f,-0.5f};structspi=(structs){3,3.1415,"Pi"};
Compound literals are often combined with designated initializers to make the declaration more readable: [3]
pi=(structs){.z="Pi",.x=3,.y=3.1415};
C is a free-form language.
Bracing style varies from programmer to programmer and can be the subject of debate. See Indentation style for more details.
In the items in this section, any <statement> can be replaced with a compound statement. Compound statements have the form:
{<optional-declaration-list><optional-statement-list>}
and are used as the body of a function or anywhere that a single statement is expected. The declaration-list declares variables to be used in that scope, and the statement-list are the actions to be performed. Brackets define their own scope, and variables defined inside those brackets will be automatically deallocated at the closing bracket. Declarations and statements can be freely intermixed within a compound statement (as in C++).
C has two types of selection statements: the if
statement and the switch
statement.
The if
statement is in the form:
if(<expression>)<statement1>else<statement2>
In the if
statement, if the <expression>
in parentheses is nonzero (true), control passes to <statement1>
. If the else
clause is present and the <expression>
is zero (false), control will pass to <statement2>
. The else <statement2>
part is optional and, if absent, a false <expression>
will simply result in skipping over the <statement1>
. An else
always matches the nearest previous unmatched if
; braces may be used to override this when necessary, or for clarity.
The switch
statement causes control to be transferred to one of several statements depending on the value of an expression, which must have integral type. The substatement controlled by a switch is typically compound. Any statement within the substatement may be labeled with one or more case
labels, which consist of the keyword case
followed by a constant expression and then a colon (:). The syntax is as follows:
switch(<expression>){case<label1>:<statements1>case<label2>:<statements2>break;default:<statements3>}
No two of the case constants associated with the same switch may have the same value. There may be at most one default
label associated with a switch. If none of the case labels are equal to the expression in the parentheses following switch
, control passes to the default
label or, if there is no default
label, execution resumes just beyond the entire construct.
Switches may be nested; a case
or default
label is associated with the innermost switch
that contains it. Switch statements can "fall through", that is, when one case section has completed its execution, statements will continue to be executed downward until a break;
statement is encountered. Fall-through is useful in some circumstances, but is usually not desired. In the preceding example, if <label2>
is reached, the statements <statements 2>
are executed and nothing more inside the braces. However, if <label1>
is reached, both <statements 1>
and <statements 2>
are executed since there is no break
to separate the two case statements.
It is possible, although unusual, to insert the switch
labels into the sub-blocks of other control structures. Examples of this include Duff's device and Simon Tatham's implementation of coroutines in Putty. [8]
C has three forms of iteration statement:
do<statement>while(<expression>);while(<expression>)<statement>for(<expression>;<expression>;<expression>)<statement>
In the while
and do
statements, the sub-statement is executed repeatedly so long as the value of the expression
remains non-zero (equivalent to true). With while
, the test, including all side effects from <expression>
, occurs before each iteration (execution of <statement>
); with do
, the test occurs after each iteration. Thus, a do
statement always executes its sub-statement at least once, whereas while
may not execute the sub-statement at all.
The statement:
for(e1;e2;e3)s;
is equivalent to:
e1;while(e2){s;cont:e3;}
except for the behaviour of a continue;
statement (which in the for
loop jumps to e3
instead of e2
). If e2
is blank, it would have to be replaced with a 1
.
Any of the three expressions in the for
loop may be omitted. A missing second expression makes the while
test always non-zero, creating a potentially infinite loop.
Since C99, the first expression may take the form of a declaration, typically including an initializer, such as:
for(inti=0;i<limit;++i){// ...}
The declaration's scope is limited to the extent of the for
loop.
Jump statements transfer control unconditionally. There are four types of jump statements in C: goto
, continue
, break
, and return
.
The goto
statement looks like this:
goto<identifier>;
The identifier must be a label (followed by a colon) located in the current function. Control transfers to the labeled statement.
A continue
statement may appear only within an iteration statement and causes control to pass to the loop-continuation portion of the innermost enclosing iteration statement. That is, within each of the statements
while(expression){/* ... */cont:;}do{/* ... */cont:;}while(expression);for(expr1;expr2;expr3){/* ... */cont:;}
a continue
not contained within a nested iteration statement is the same as goto cont
.
The break
statement is used to end a for
loop, while
loop, do
loop, or switch
statement. Control passes to the statement following the terminated statement.
A function returns to its caller by the return
statement. When return
is followed by an expression, the value is returned to the caller as the value of the function. Encountering the end of the function is equivalent to a return
with no expression. In that case, if the function is declared as returning a value and the caller tries to use the returned value, the result is undefined.
GCC extends the C language with a unary &&
operator that returns the address of a label. This address can be stored in a void*
variable type and may be used later in a goto
instruction. For example, the following prints "hi "
in an infinite loop:
void*ptr=&&J1;J1:printf("hi ");goto*ptr;
This feature can be used to implement a jump table.
A C function definition consists of a return type (void
if no value is returned), a unique name, a list of parameters in parentheses, and various statements:
<return-type>functionName(<parameter-list>){<statements>return<expressionoftypereturn-type>;}
A function with non-void
return type should include at least one return
statement. The parameters are given by the <parameter-list>
, a comma-separated list of parameter declarations, each item in the list being a data type followed by an identifier: <data-type> <variable-identifier>, <data-type> <variable-identifier>, ...
.
The return type cannot be an array type or function type.
intf()[3];// Error: function returning an arrayint(*g())[3];// OK: function returning a pointer to an array.voidh()();// Error: function returning a functionvoid(*k())();// OK: function returning a function pointer
If there are no parameters, the <parameter-list>
may be left empty or optionally be specified with the single word void
.
It is possible to define a function as taking a variable number of parameters by providing the ...
keyword as the last parameter instead of a data type ad variable identifier. A commonly used function that does this is the standard library function printf
, which has the declaration:
intprintf(constchar*,...);
Manipulation of these parameters can be done by using the routines in the standard library header <stdarg.h>
.
A pointer to a function can be declared as follows:
<return-type>(*<function-name>)(<parameter-list>);
The following program shows use of a function pointer for selecting between addition and subtraction:
#include<stdio.h>int(*operation)(intx,inty);intadd(intx,inty){returnx+y;}intsubtract(intx,inty){returnx-y;}intmain(intargc,char*args[]){intfoo=1,bar=1;operation=add;printf("%d + %d = %d\n",foo,bar,operation(foo,bar));operation=subtract;printf("%d - %d = %d\n",foo,bar,operation(foo,bar));return0;}
After preprocessing, at the highest level a C program consists of a sequence of declarations at file scope. These may be partitioned into several separate source files, which may be compiled separately; the resulting object modules are then linked along with implementation-provided run-time support modules to produce an executable image.
The declarations introduce functions, variables and types. C functions are akin to the subroutines of Fortran or the procedures of Pascal.
A definition is a special type of declaration. A variable definition sets aside storage and possibly initializes it, a function definition provides its body.
An implementation of C providing all of the standard library functions is called a hosted implementation. Programs written for hosted implementations are required to define a special function called main
, which is the first function called when a program begins executing.
Hosted implementations start program execution by invoking the main
function, which must be defined following one of these prototypes (using different parameter names or spelling the types differently is allowed):
intmain(){...}intmain(void){...}intmain(intargc,char*argv[]){...}intmain(intargc,char**argv){...}// char *argv[] and char **argv have the same type as function parameters
The first two definitions are equivalent (and both are compatible with C++). It is probably up to individual preference which one is used (the current C standard contains two examples of main()
and two of main(void)
, but the draft C++ standard uses main()
). The return value of main
(which should be int
) serves as termination status returned to the host environment.
The C standard defines return values 0
and EXIT_SUCCESS
as indicating success and EXIT_FAILURE
as indicating failure. (EXIT_SUCCESS
and EXIT_FAILURE
are defined in <stdlib.h>
). Other return values have implementation-defined meanings; for example, under Linux a program killed by a signal yields a return code of the numerical value of the signal plus 128.
A minimal correct C program consists of an empty main
routine, taking no arguments and doing nothing:
intmain(void){}
Because no return
statement is present, main
returns 0 on exit. [3] (This is a special-case feature introduced in C99 that applies only to main
.)
The main
function will usually call other functions to help it perform its job.
Some implementations are not hosted, usually because they are not intended to be used with an operating system. Such implementations are called free-standing in the C standard. A free-standing implementation is free to specify how it handles program startup; in particular it need not require a program to define a main
function.
Functions may be written by the programmer or provided by existing libraries. Interfaces for the latter are usually declared by including header files—with the #include
preprocessing directive—and the library objects are linked into the final executable image. Certain library functions, such as printf
, are defined by the C standard; these are referred to as the standard library functions.
A function may return a value to caller (usually another C function, or the hosting environment for the function main
). The printf
function mentioned above returns how many characters were printed, but this value is often ignored.
In C, arguments are passed to functions by value while other languages may pass variables by reference. This means that the receiving function gets copies of the values and has no direct way of altering the original variables. For a function to alter a variable passed from another function, the caller must pass its address (a pointer to it), which can then be dereferenced in the receiving function. See Pointers for more information.
voidincInt(int*y){(*y)++;// Increase the value of 'x', in 'main' below, by one}intmain(void){intx=0;incInt(&x);// pass a reference to the var 'x'return0;}
The function scanf works the same way:
intx;scanf("%d",&x);
In order to pass an editable pointer to a function (such as for the purpose of returning an allocated array to the calling code) you have to pass a pointer to that pointer: its address.
#include<stdio.h>#include<stdlib.h>voidallocate_array(int**consta_p,constintA){/* allocate array of A ints assigning to *a_p alters the 'a' in main()*/*a_p=malloc(sizeof(int)*A);}intmain(void){int*a;/* create a pointer to one or more ints, this will be the array *//* pass the address of 'a' */allocate_array(&a,42);/* 'a' is now an array of length 42 and can be manipulated and freed here */free(a);return0;}
The parameter int **a_p
is a pointer to a pointer to an int
, which is the address of the pointer p
defined in the main function in this case.
Function parameters of array type may at first glance appear to be an exception to C's pass-by-value rule. The following program will print 2, not 1:
#include<stdio.h>voidsetArray(intarray[],intindex,intvalue){array[index]=value;}intmain(void){inta[1]={1};setArray(a,0,2);printf("a[0]=%d\n",a[0]);return0;}
However, there is a different reason for this behavior. In fact, a function parameter declared with an array type is treated like one declared to be a pointer. That is, the preceding declaration of setArray
is equivalent to the following:
voidsetArray(int*array,intindex,intvalue)
At the same time, C rules for the use of arrays in expressions cause the value of a
in the call to setArray
to be converted to a pointer to the first element of array a
. Thus, in fact this is still an example of pass-by-value, with the caveat that it is the address of the first element of the array being passed by value, not the contents of the array.
Since C99, the programmer can specify that a function takes an array of a certain size by using the keyword static
. In void setArray(int array[static 4], int index, int value)
the first parameter must be a pointer to the first element of an array of length at least 4. It is also possible to add qualifiers (const
, volatile
and restrict
) to the pointer type that the array is converted to by putting them between the brackets.
The anonymous function is not supported by standard C programming language, but supported by some C dialects, such as GCC [9] and Clang.
The GNU Compiler Collection (GCC) supports anonymous functions, mixed by nested functions and statement expressions. It has the form:
({return_typeanonymous_functions_name(parameters){function_body}anonymous_functions_name;})
The following example works only with GCC. Because of how macros are expanded, the l_body
cannot contain any commas outside of parentheses; GCC treats the comma as a delimiter between macro arguments. The argument l_ret_type
can be removed if __typeof__
is available; in the example below using __typeof__
on array would return testtype *
, which can be dereferenced for the actual value if needed.
#include<stdio.h>//* this is the definition of the anonymous function */#define lambda(l_ret_type, l_arguments, l_body) \ ({ \ l_ret_type l_anonymous_functions_name l_arguments \ l_body \ &l_anonymous_functions_name; \ })#define forEachInArray(fe_arrType, fe_arr, fe_fn_body) \{ \ int i=0; \ for(;i<sizeof(fe_arr)/sizeof(fe_arrType);i++) { fe_arr[i] = fe_fn_body(&fe_arr[i]); } \}typedefstruct{inta;intb;}testtype;voidprintout(consttesttype*array){inti;for(i=0;i<3;++i)printf("%d %d\n",array[i].a,array[i].b);printf("\n");}intmain(void){testtypearray[]={{0,1},{2,3},{4,5}};printout(array);/* the anonymous function is given as function for the foreach */forEachInArray(testtype,array,lambda(testtype,(void*item),{inttemp=(*(testtype*)item).a;(*(testtype*)item).a=(*(testtype*)item).b;(*(testtype*)item).b=temp;return(*(testtype*)item);}));printout(array);return0;}
Clang supports anonymous functions, called blocks, [10] which have the form:
^return_type(parameters){function_body}
The type of the blocks above is return_type (^)(parameters)
.
Using the aforementioned blocks extension and Grand Central Dispatch (libdispatch), the code could look simpler:
#include<stdio.h>#include<dispatch/dispatch.h>intmain(void){void(^count_loop)()=^{for(inti=0;i<100;i++)printf("%d\n",i);printf("ah ah ah\n");};/* Pass as a parameter to another function */dispatch_async(dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_DEFAULT,0),count_loop);/* Invoke directly */count_loop();return0;}
-fblocks
and linked with -lBlocksRuntime
The following words are reserved, and may not be used as identifiers:
|
|
|
|
Implementations may reserve other keywords, such as asm
, although implementations typically provide non-standard keywords that begin with one or two underscores.
C identifiers are case sensitive (e.g., foo
, FOO
, and Foo
are the names of different objects). Some linkers may map external identifiers to a single case, although this is uncommon in most modern linkers.
Text starting with the token /*
is treated as a comment and ignored. The comment ends at the next */
; it can occur within expressions, and can span multiple lines. Accidental omission of the comment terminator is problematic in that the next comment's properly constructed comment terminator will be used to terminate the initial comment, and all code in between the comments will be considered as a comment. C-style comments do not nest; that is, accidentally placing a comment within a comment has unintended results:
/*This line will be ignored./*A compiler warning may be produced here. These lines will also be ignored.The comment opening token above did not start a new comment,and the comment closing token below will close the comment begun on line 1.*/Thislineandthelinebelowitwillnotbeignored.Bothwilllikelyproducecompileerrors.*/
C++ style line comments start with //
and extend to the end of the line. This style of comment originated in BCPL and became valid C syntax in C99; it is not available in the original K&R C nor in ANSI C:
// this line will be ignored by the compiler/* these lines will be ignored by the compiler */x=*p/*q; /* this comment starts after the 'p' */
The parameters given on a command line are passed to a C program with two predefined variables - the count of the command-line arguments in argc
and the individual arguments as character strings in the pointer array argv
. So the command:
myFilt p1 p2 p3
results in something like:
m | y | F | i | l | t | \0 | p | 1 | \0 | p | 2 | \0 | p | 3 | \0 |
argv[0] | argv[1] | argv[2] | argv[3] |
While individual strings are arrays of contiguous characters, there is no guarantee that the strings are stored as a contiguous group.
The name of the program, argv[0]
, may be useful when printing diagnostic messages or for making one binary serve multiple purposes. The individual values of the parameters may be accessed with argv[1]
, argv[2]
, and argv[3]
, as shown in the following program:
#include<stdio.h>intmain(intargc,char*argv[]){printf("argc\t= %d\n",argc);for(inti=0;i<argc;i++)printf("argv[%i]\t= %s\n",i,argv[i]);}
In any reasonably complex expression, there arises a choice as to the order in which to evaluate the parts of the expression: (1+1)+(3+3)
may be evaluated in the order (1+1)+(3+3)
, (2)+(3+3)
, (2)+(6)
, (8)
, or in the order (1+1)+(3+3)
, (1+1)+(6)
, (2)+(6)
, (8)
. Formally, a conforming C compiler may evaluate expressions in any order between sequence points (this allows the compiler to do some optimization). Sequence points are defined by:
&&
, which can be read and then) and logical or (||
, which can be read or else).?:
): This operator evaluates its first sub-expression first, and then its second or third (never both of them) based on the value of the first.Expressions before a sequence point are always evaluated before those after a sequence point. In the case of short-circuit evaluation, the second expression may not be evaluated depending on the result of the first expression. For example, in the expression (a()||b())
, if the first argument evaluates to nonzero (true), the result of the entire expression cannot be anything else than true, so b()
is not evaluated. Similarly, in the expression (a()&&b())
, if the first argument evaluates to zero (false), the result of the entire expression cannot be anything else than false, so b()
is not evaluated.
The arguments to a function call may be evaluated in any order, as long as they are all evaluated by the time the function is entered. The following expression, for example, has undefined behavior:
printf("%s %s\n",argv[i=0],argv[++i]);
An aspect of the C standard (not unique to C) is that the behavior of certain code is said to be "undefined". In practice, this means that the program produced from this code can do anything, from working as the programmer intended, to crashing every time it is run.
For example, the following code produces undefined behavior, because the variable b is modified more than once with no intervening sequence point:
#include<stdio.h>intmain(void){intb=1;inta=b+++b++;printf("%d\n",a);}
Because there is no sequence point between the modifications of b in "b++ + b++", it is possible to perform the evaluation steps in more than one order, resulting in an ambiguous statement. This can be fixed by rewriting the code to insert a sequence point in order to enforce an unambiguous behavior, for example:
a=b++;a+=b++;
long long
modifier was introduced in the C99 standard.C is a general-purpose programming language. It was created in the 1970s by Dennis Ritchie and remains very widely used and influential. By design, C's features cleanly reflect the capabilities of the targeted CPUs. It has found lasting use in operating systems code, device drivers, and protocol stacks, but its use in application software has been decreasing. C is commonly used on computer architectures that range from the largest supercomputers to the smallest microcontrollers and embedded systems.
In computer science, a pointer is an object in many programming languages that stores a memory address. This can be that of another value located in computer memory, or in some cases, that of memory-mapped computer hardware. A pointer references a location in memory, and obtaining the value stored at that location is known as dereferencing the pointer. As an analogy, a page number in a book's index could be considered a pointer to the corresponding page; dereferencing such a pointer would be done by flipping to the page with the given page number and reading the text found on that page. The actual format and content of a pointer variable is dependent on the underlying computer architecture.
In computer science, a union is a value that may have any of multiple representations or formats within the same area of memory; that consists of a variable that may hold such a data structure. Some programming languages support a union type for such a data type. In other words, a union type specifies the permitted types that may be stored in its instances, e.g., float
and integer
. In contrast with a record, which could be defined to contain both a float and an integer; a union would hold only one at a time.
A function pointer, also called a subroutine pointer or procedure pointer, is a pointer referencing executable code, rather than data. Dereferencing the function pointer yields the referenced function, which can be invoked and passed arguments just as in a normal function call. Such an invocation is also known as an "indirect" call, because the function is being invoked indirectly through a variable instead of directly through a fixed identifier or address.
In some programming languages, const is a type qualifier that indicates that the data is read-only. While this can be used to declare constants, const in the C family of languages differs from similar constructs in other languages in that it is part of the type, and thus has complicated behavior when combined with pointers, references, composite data types, and type-checking. In other languages, the data is not in a single memory location, but copied at compile time for each use. Languages which use it include C, C++, D, JavaScript, Julia, and Rust.
The computer programming languages C and Pascal have similar times of origin, influences, and purposes. Both were used to design their own compilers early in their lifetimes. The original Pascal definition appeared in 1969 and a first compiler in 1970. The first version of C appeared in 1972.
In the C programming language, data types constitute the semantics and characteristics of storage of data elements. They are expressed in the language syntax in form of declarations for memory locations or variables. Data types also determine the types of operations or methods of processing of data elements.
typedef is a reserved keyword in the programming languages C, C++, and Objective-C. It is used to create an additional name (alias) for another data type, but does not create a new type, except in the obscure case of a qualified typedef of an array type where the typedef qualifiers are transferred to the array element type. As such, it is often used to simplify the syntax of declaring complex data structures consisting of struct and union types, although it is also commonly used to provide specific descriptive type names for integer data types of varying sizes.
In computer programming, a forward declaration is a declaration of an identifier for which the programmer has not yet given a complete definition.
scanf, short for scan formatted, is a C standard library function that reads and parses text from standard input.
A class in C++ is a user-defined type or data structure declared with any of the keywords class
, struct
or union
that has data and functions as its members whose access is governed by the three access specifiers private, protected or public. By default access to members of a C++ class declared with the keyword class
is private. The private members are not accessible outside the class; they can be accessed only through member functions of the class. The public members form an interface to the class and are accessible outside the class.
sizeof is a unary operator in the programming languages C and C++. It generates the storage size of an expression or a data type, measured in the number of char-sized units. Consequently, the construct sizeof (char) is guaranteed to be 1. The actual number of bits of type char is specified by the preprocessor macro CHAR_BIT, defined in the standard include file limits.h. On most modern computing platforms this is eight bits. The result of sizeof has an unsigned integer type that is usually denoted by size_t.
The C and C++ programming languages are closely related but have many significant differences. C++ began as a fork of an early, pre-standardized C, and was designed to be mostly source-and-link compatible with C compilers of the time. Due to this, development tools for the two languages are often integrated into a single product, with the programmer able to specify C or C++ as their source language.
In computer programming, an enumerated type is a data type consisting of a set of named values called elements, members, enumeral, or enumerators of the type. The enumerator names are usually identifiers that behave as constants in the language. An enumerated type can be seen as a degenerate tagged union of unit type. A variable that has been declared as having an enumerated type can be assigned any of the enumerators as a value. In other words, an enumerated type has values that are different from each other, and that can be compared and assigned, but are not specified by the programmer as having any particular concrete representation in the computer's memory; compilers and interpreters can represent them arbitrarily.
C++11 is a version of a joint technical standard, ISO/IEC 14882, by the International Organization for Standardization (ISO) and International Electrotechnical Commission (IEC), for the C++ programming language. C++11 replaced the prior version of the C++ standard, named C++03, and was later replaced by C++14. The name follows the tradition of naming language versions by the publication year of the specification, though it was formerly named C++0x because it was expected to be published before 2010.
C's offsetof macro is an ANSI C library feature found in stddef.h. It evaluates to the offset of a given member within a struct or union type, an expression of type size_t. The offsetof
macro takes two parameters, the first being a structure or union name, and the second being the name of a subobject of the structure/union that is not a bit field. It cannot be described as a C prototype.
This article describes the syntax of the C# programming language. The features described are compatible with .NET Framework and Mono.
This article compares a large number of programming languages by tabulating their data types, their expression, statement, and declaration syntax, and some common operating-system interfaces.
In computer programming, variadic templates are templates that take a variable number of arguments.
C++14 is a version of the ISO/IEC 14882 standard for the C++ programming language. It is intended to be a small extension over C++11, featuring mainly bug fixes and small improvements, and was replaced by C++17. Its approval was announced on August 18, 2014. C++14 was published as ISO/IEC 14882:2014 in December 2014.