Composite data type

In computer science, a composite data type or compound data type is any data type which can be constructed in a program using the programming language's primitive data types and other composite types. It is sometimes called a structure or aggregate data type,^[1] although the latter term may also refer to arrays, lists, etc. The act of constructing a composite type is known as composition.

C/C++ structures and classes

For more details on this topic, see C++ classes.

A struct is C's and C++'s notion of a composite type, a datatype that composes a fixed set of labeled fields or members. It is so called because of the struct keyword used in declaring them, which is short for structure or, more precisely, user-defined data structure.

In C++, the only difference between a struct and a class is the default access level, which is private for classes and public for structs.

Note that while classes and the class keyword were completely new in C++, the C programming language already had a crude type of structs. For all intents and purposes, C++ structs form a superset of C structs: virtually all valid C structs are valid C++ structs with the same semantics.

Declaration

A struct declaration consists of a list of fields, each of which can have any type. The total storage required for a struct object is the sum of the storage requirements of all the fields, plus any internal padding.

For example:

struct Account {
   int account_number;
   char *first_name;
   char *last_name;
   float balance;
};

defines a type, referred to as struct Account. To create a new variable of this type, we can write struct Account myAccount; which has an integer component, accessed by myAccount.account_number, and a floating-point component, accessed by myAccount.balance, as well as the first_name and last_name components. The structure myAccount contains all four values, and all four fields may be changed independently.

Since writing struct Account repeatedly in code becomes cumbersome, it is not unusual to see a typedef statement in C code to provide a more convenient synonym for the struct.

For example:

typedef struct Account_ {
   int    account_number;
   char   *first_name;
   char   *last_name;
   float  balance;
} Account;

In C++ code, the typedef is not needed because types defined using struct are already part of the regular namespace, so the type can be referred to as either struct Account or simply Account.

As another example, a three-dimensional Vector composite type that uses the floating point data type could be created with:

struct Vector {
  float x;
  float y;
  float z;
};

A variable named velocity with a Vector composite type would be declared as Vector velocity; Members of the velocity would be accessed using a dot notation. For example, velocity.x = 5; would set the x component of velocity equal to 5.

Likewise, a color structure could be created using:

struct Color {
  unsigned int red;
  unsigned int green;
  unsigned int blue;
};

In 3D graphics, you usually must keep track of both the position and color of each vertex. One way to do this would be to create a Vertex composite type, using the previously created Vector and Color composite types:

struct Vertex {
  Vector position;
  Color color;
};

Instantiation

Create a variable of type struct Vertex using the same format as before: Vertex v;

Member access

Assign values to the components of v like so:

v.position.x = 0.0;
v.position.y = 1.5;
v.position.z = 0.0;
v.color.red = 128;
v.color.green = 0;
v.color.blue = 255;

Primitive subtype

The primary use of struct is for the construction of complex datatypes, but sometimes it is used to create primitive structural subtyping. For example, since Standard C requires that if two structs have the same initial fields, those fields will be represented in the same way, the code

struct ifoo_old_stub {
   long x, y;
};
struct ifoo_version_42 {
   long x, y, z;
   char *name;
   long a, b, c;
};
void operate_on_ifoo(struct ifoo_old_stub *);
struct ifoo_version_42 s;
. . .
operate_on_ifoo(&s);

will work correctly.

Type signature

Type signatures (or Function types) are constructed from primitive and composite types, and can serve as types themselves when constructing composite types:

typedef struct {
    int x;
    int y;
} Point;

typedef double (*Metric) (Point p1, Point p2);

typedef struct {
    Point centre;
    double radius;
    Metric metric;
} Circle;

References

↑ Howe, Denis. "The Free On-line Dictionary of Computing". Dictionary.com. Retrieved 1 February 2016.

Data types

Uninterpreted	Bit Byte Trit Tryte Word Bit array

Numeric	Arbitrary-precision or bignum Complex Decimal Fixed point Floating point Double precision Extended precision Half precision Long double Minifloat Octuple precision Quadruple precision Single precision Integer signedness Interval Rational

Text	Character String null-terminated

Pointer	Address physical virtual Reference

Composite	Algebraic data type generalized Array Associative array Class Dependent Equality Inductive List Object metaobject Option type Product Record Set Union tagged

Other	Boolean Bottom type Collection Enumerated type Exception Function type Opaque data type Recursive data type Semaphore Stream Top type Type class Unit type Void

Related topics	Abstract data type Data structure Generic Kind metaclass Parametric polymorphism Primitive data type Protocol interface Subtyping Type constructor Type conversion Type system

See also platform-dependent and independent units of information

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