Caml

Caml

Paradigm	Multi-paradigm: functional, imperative
Family	ML
Designed by	Gérard Huet, Guy Cousineau, Ascánder Suárez, Pierre Weis, Michel Mauny (Heavy Caml), Xavier Leroy (Caml Light)
Developer	INRIA, ENS
First appeared	1985; 40 years ago (1985)
Stable release	0.75[1] / January 26, 2002; 23 years ago (2002-01-26)
Typing discipline	inferred, static, strong
Memory management	automatic
OS	Cross-platform: Unix, Linux, macOS; Windows
License	QPL 1, LGPL 2 (Caml Light)
Website	caml.inria.fr
Influenced by
ML
Influenced
OCaml

Caml (originally an acronym for Categorical Abstract Machine Language) is a multi-paradigm, general-purpose, high-level, functional programming language which is a dialect of the ML programming language family. Caml was developed in France at French Institute for Research in Computer Science and Automation (INRIA) and École normale supérieure (Paris) (ENS).

Caml is statically typed, strictly evaluated, and uses automatic memory management. OCaml, the main descendant of Caml, adds many features to the language, including an object-oriented programming (object) layer.

In the following, # represents the Caml prompt.

A "Hello, World!" program is:

print_endline "Hello, world!";;

Many mathematical functions, such as factorial, are most naturally represented in a purely functional form. The following recursive, purely functional Caml function implements factorial:

let rec fact n = if n=0 then 1 else n * fact(n - 1);;

The function can be written equivalently using pattern matching:

let rec fact = function
  | 0 -> 1
  | n -> n * fact(n - 1);;

This latter form is the mathematical definition of factorial as a recurrence relation.

Note that the compiler inferred the type of this function to be int -> int, meaning that this function maps ints onto ints. For example, 12! is:

 # fact 12;;
 - : int = 479001600

Since Caml is a functional programming language, it is easy to create and pass around functions in Caml programs. This ability has very many applications. Calculating the numerical derivative of a function is one example. The following Caml function d computes the numerical derivative of a given function f at a given point x:

let d delta f x =
  (f (x +. delta) -. f (x -. delta)) /. (2. *. delta);;

This function requires a small value delta. A good choice for delta is the cube root of the machine epsilon.^{[citation needed]}.

The type of the function d indicates that it maps a float onto another function with the type (float -> float) -> float -> float. This allows us to partially apply arguments. This functional style is known as currying. In this case, it is useful to partially apply the first argument delta to d, to obtain a more specialised function:

# let d = d (sqrt epsilon_float);;
val d : (float -> float) -> float -> float = <fun>

Note that the inferred type indicates that the replacement d is expecting a function with the type float -> float as its first argument. We can compute a numerical approximation to the derivative of ${\displaystyle x^{3}-x-1}$ at ${\displaystyle x=3}$ with:

# d (fun x -> x *. x *. x -. x -. 1.) 3.;;
- : float = 26.

The correct answer is ${\displaystyle f'(x)=3x^{2}-1\rightarrow f'(3)=27-1=26}$.

The function d is called a "higher-order function" because it accepts another function (f) as an argument. Going further can create the (approximate) derivative of f, by applying d while omitting the x argument:

# let f' = d (fun x -> x *. x *. x -. x -. 1.) ;;
val f' : float -> float = <fun>

The concepts of curried and higher-order functions are clearly useful in mathematical programs. These concepts are equally applicable to most other forms of programming and can be used to factor code much more aggressively, resulting in shorter programs and fewer bugs.

The 1D Haar wavelet transform of an integer-power-of-two-length list of numbers can be implemented very succinctly in Caml and is an excellent example of the use of pattern matching over lists, taking pairs of elements (h1 and h2) off the front and storing their sums and differences on the lists s and d, respectively:

# let haar l =
   let rec aux l s d = 
     match l, s, d with
       [s], [], d -> s :: d
     | [], s, d -> aux s [] d
     | h1 :: h2 :: t, s, d -> aux t (h1 + h2 :: s) (h1 - h2 :: d)
     | _ -> invalid_arg "haar" 
     in aux l [] [];;
val haar : int list -> int list = <fun>

For example:

  # haar [1; 2; 3; 4; -4; -3; -2; -1];;
   - : int list = [0; 20; 4; 4; -1; -1; -1; -1]

Pattern matching allows complicated transformations to be represented clearly and succinctly. Moreover, the Caml compiler turns pattern matches into very efficient code, at times resulting in programs that are shorter and faster than equivalent code written with a case statement (Cardelli 1984, p. 210.).

The first Caml implementation was written in Lisp by Ascánder Suárez in 1987 at the French Institute for Research in Computer Science and Automation (INRIA).^[2]

Its successor, Caml Light, was implemented in C by Xavier Leroy and Damien Doligez,^[2] and the original was nicknamed "Heavy Caml" because of its higher memory and CPU requirements.^[2]

Caml Special Light was a further complete rewrite that added a powerful module system to the core language. It was augmented with an object-oriented programming (object) layer to become Objective Caml, eventually renamed OCaml.

• Categorical abstract machine
• OCaml

• The Functional Approach to Programming with Caml Archived 2007-12-24 at the Wayback Machine by Guy Cousineau and Michel Mauny.
• Cardelli, Luca (1984). Compiling a functional language ACM Symposium on LISP and functional programming, Association of Computer Machinery.

• Official website, INRIA