Mercury (programming language)

Mercury
Paradigm(s) Logic, functional
Appeared in 1995
Designed by Zoltán Somogyi
Developer University of Melbourne
Stable release 11.07 (December 22, 2011; 55 days ago (2011-12-22))
Typing discipline Strong, static, polymorphic
Major implementations Melbourne Mercury Compiler
Influenced by Prolog, Haskell
OS Cross-platform (Unix, Mac OS X, Windows)
License GPL for compiler, LGPL for standard library
Website www.mercury.csse.unimelb.edu.au

Mercury is a functional logic programming language geared towards real-world applications. It is developed at the University Of Melbourne Computer Science department under the supervision of Zoltan Somogyi. The first version was developed by Fergus Henderson, Thomas Conway and Zoltan Somogyi and was released on April 8, 1995.

Mercury is a purely declarative logic language. It is related to both Prolog and Haskell.[1] It features a strong, static, polymorphic type system, as well as a strong mode and determinism system.

The official implementation, the Melbourne Mercury Compiler, is available for most Unix platforms, including Mac OS X, as well as for Microsoft Windows (in Windows, it requires one of the Cygwin or MinGW toolsets, and can be compiled either with GCC or Microsoft Visual C++).

Contents

Overview

Mercury is based on the logic programming language Prolog. It has the same syntax, and the same basic concepts such as the SLD resolution algorithm. It can ostensibly be viewed as a pure subset of Prolog with strong types and modes. As such, it is often compared to its predecessor, both in terms of features, and run-time efficiency.

The language is designed with software engineering principles in mind. Unlike the original implementations of Prolog, it has a separate compilation phase, rather than being directly interpreted, which allows a much wider range of errors to be caught before running a program. It features a sophisticated, strict type and mode system, which its authors claim makes it much easier to write robust software.[1] Mercury's module system enables division into self-contained units, a problem for past logic programming languages.

Due to the use of information obtained at compile time (such as type and mode information), programs written in Mercury typically perform significantly faster than equivalent programs written in Prolog.[2][3] The authors claim that Mercury is the fastest logic language in the world, by a wide margin.[1]

Mercury is a purely declarative language, unlike Prolog, since it lacks "extra-logical" Prolog statements such as "cut" and imperative I/O. This enables advanced program optimization, but can make certain programming constructs (such as a switch over a number of options, with a default) harder to express. (Note that while Mercury does allow impure functionality, it is not necessary in most software, and serves primarily as a way of calling foreign language code. Also, all impure code must be explicitly marked.)

Operations which would typically be impure (such as input/output) are expressed using pure constructs in Mercury using linear types, by threading a dummy "world" value through all relevant code.

Notable programs written in Mercury include the Mercury compiler itself and the Prince XML formatter. Mission Critical IT [1], a software company, has also been using Mercury since 2000 to develop enterprise applications.

Back-ends

Mercury has several back-ends, which means it is possible to compile Mercury code into the following languages and code-styles:

Production level:

Beta quality:

Alpha quality (may not work well, or even be completely broken):

Past back-ends:

This makes Mercury a useful high-level language for targeting multiple platforms, or for linking with code written using multiple back-ends.

Mercury also has a strong foreign language interface, allowing code in other languages (depending on the chosen back-end) to be linked with Mercury code. The following foreign languages are possible:

Back-end Foreign language(s)
C (both levels) C
Java Java
Erlang Erlang
IL IL or C#

Other languages can then be interfaced to by calling them from these languages. However, this means that foreign language code may need to be written several times for the different backends, otherwise portability between backends will be lost.

The most commonly used back-end is the original low-level C back-end. As both C backends are considered production quality, this means that you will not lose a great deal of portability using foreign-language C code.

Examples

Hello World:

 :- module hello.
 :- interface.
 :- import_module io.
 :- pred main(io::di, io::uo) is det.

 :- implementation.
 main(!IO) :-
 	io.write_string("Hello, World!\n", !IO).

Calculating the 10th Fibonacci number (in the most obvious way)[4]:

 :- module fib.
 :- interface.
 :- import_module io.
 :- pred main(io::di, io::uo) is det.
 
 :- implementation.
 :- import_module int.

 :-func fib(int) = int.
 fib(N) = (if N =< 2 then 1 else fib(N - 1) + fib(N - 2)).

 main(!IO) :-
        io.write_string("fib(10) = ", !IO),
        io.write_int(fib(10), !IO),
        io.nl(!IO).
        % Could instead use io.format("fib(10) = %d\n", [i(fib(10))], !IO).

Release schedule

The Mercury project has a new 6 monthly release cycle. Releases are named according to the year and month of the release. The current release is 11.07 (December 2011). Previously releases were numbered 0.12, 0.13, etc. and the period between stable releases was very large (3 years).

The Mercury project also makes a snapshot release daily. The snapshot release is the latest development snapshot of the system and has all the latest features and bug fixes added to the last stable release.

See also

References

  1. ^ a b c The Mercury Project - Motivation
  2. ^ The Mercury Project - Benchmarks
  3. ^ Somogyi, Zoltan; Henderson, Fergus and Conway, Thomas (October–December 1996). "The execution algorithm of Mercury: an efficient purely declarative logic programming language". Journal of Logic Programming 29 (1–3): 17–64. doi:10.1016/S0743-1066(96)00068-4. http://www.mercury.csse.unimelb.edu.au/information/papers.html#jlp. Retrieved 2008-08-30. 
  4. ^ Adapted from Ralph Becket's Mercury tutorial

External links