In programming languages and type theory, a **product** of *types* is another, compounded, type in a structure. The "operands" of the product are types, and the structure of a product type is determined by the fixed order of the operands in the product. An instance of a product type retains the fixed order, but otherwise may contain all possible instances of its primitive data types. The expression of an instance of a product type will be a tuple, and is called a "tuple type" of expression. A product of types is a direct product of two or more types.

If there are only two component types, it can be called a "pair type". For example, if two component types **A** and **B** are the set of all possible values that type, the product type written **A** × **B** contains elements that are pairs (a,b), where "a" and "b" are instances of **A** and **B** respectively. The pair type is a special case of the dependent pair type, where the type **B** may depend on the instance picked from **A**.

In many languages, product types take the form of a record type, for which the components of a tuple can be accessed by label. In languages that have algebraic data types, as in most functional programming languages, algebraic data types with one constructor are isomorphic to a product type.

In the Curry–Howard correspondence, product types are associated with logical conjunction (AND) in logic.

The notion directly extends to the product of an arbitrary finite number of types (a n-ary product type), and in this case, it characterizes the expressions which behave as tuples of expressions of the corresponding types. A degenerated form of product type is the unit type: it is the product of no types.

In call-by-value programming languages, a product type can be interpreted as a set of pairs whose first component is a value in the first type and whose second component is a value in the second type. In short, it is a cartesian product and it corresponds to a product in the category of types.

Most functional programming languages have a primitive notion of product type. For instance, the product of *type _{1}*, ...,

*type*is written

_{n}*type*

_{1}` * `

...` * `

*type*in ML and

_{n}`(`

*type*

_{1}`,`

...`,`

*type*

_{n}`)`

in Haskell. In both these languages, tuples are written `(`

*v*

_{1}`,`

...`,`

*v*

_{n}`)`

and the components of a tuple are extracted by pattern-matching. Additionally, many functional programming languages provide more general algebraic data types, which extend both product and sum types. Product types are the dual of sum types.
## Example

An example of a product type is the type of a vector in a vector space or an algebra over a field: the type is a product of a number type, and a direction type. Thus, for example, the brochure for the International System of Units starts out in section 1.1 saying "The value of a quantity is generally expressed as the product of a number and a unit", and also presents the unit product of a Newton and a meter with the product notation of mathematics: Newton meter (N m or N · m). This is properly indicative of the vector space nature of SI units over the abelian group of dimensions under multiplication, and the field of real numbers -- the SI units form an algebra over a field.