Miranda programming language
From Academic Kids

Miranda is a nonstrict purely functional programming language developed by Professor David Turner as a successor to his earlier programming languages Sasl and KRC, using some concepts from ML and Hope. Marketed by Research Software Ltd. of England, of which the word 'Miranda' is a registered trademark, it was the first purely functional language to be intended for use as a commercial tool rather than for academic purposes.
The solution to most example problems is briefer and simpler in Miranda than in any other programming language except maybe APL, and experience with its use in industry has shown programmers to produce more reliable programs with shorter development times than with their preferred imperative programming languages.
It was first published in 1985, and only one interpreter was ever written for it, in C for Unixflavour operating systems, by its author who only released executable binaries and who now (2002) declares the language "dead". The later Haskell programming language is similar in many ways to Miranda.
Contents 
Overview
Miranda is a lazy purely functional programming language. That is, it lacks side effects and imperative programming features. A Miranda program (called a script) is a set of equations that define various mathematical functions and algebraic data types. The word set is important here: the order of the equations is, in general, irrelevant, and there is no need to define an entity prior to its use.
Since the parsing algorithm makes intelligent use of layout (indentation), there is rarely a need for bracketing statements and no statement terminators are required. This feature is also used in Occam and was popularized by Python.
Commentary is introduced into regular scripts by the characters 
and continue to the end of the same line.
An alternative commenting convention affects an entire source code file, known as a "literate script", in which every line is considered a comment unless it starts with a >
sign.
Miranda's basic data types are char, num and bool. A character string is simply a list of char, while num is silently converted between two underlying forms: infiniteprecision integers (a.k.a. Bignums) by default, and regular floatingpoint values as required.
Tuples are sequences of elements of potentially mixed types, analogous to records in Pascallike languages, and are written delimited with parenthesis:
this_employee = ("Folland, Mary", 10560, False, 35)
The list instead is the most commonly used data structure in Miranda. It is written delimited by square brackets and with commaseparated elements, all of which must be of the same type:
week_days = ["Mon","Tue","Wed","Thur","Fri"]
List concatenation is ++
, subtraction is 
, construction is :
, sizing is #
and indexing is !
, so:
days = week_days ++ ["Sat","Sun"] days = "Nil":days days!0 → "Nil" days = days  ["Nil"] #days → 7
There are several listbuilding shortcuts: ..
is used for lists whose elements form an arithmetic series, with the possibility for specifying an increment other than 1:
fac n = product [1..n] odd_sum = sum [1,3..100]
More general and powerful listbuilding facilities are provided by "list comprehensions" (previously known as "ZF expressions"), which come in two main forms: an expression applied to a series of terms, e.g.:
squares = [ n * n  n < [1..] ]
(which is read: list of n squared where n is taken from the list of all positive integers) and a series where each term is a function of the previous one, e.g.:
powers_of_2 = [ n  n < 1, 2*n .. ]
As these two examples imply, Miranda allows for lists with an infinite number of elements, of which the simplest is the list of all positive integers: [1..]
The notation for function application is simply juxtaposition, as in sin x
.
In Miranda, as in many other purely functional languages, functions are firstclass citizens, which is to say that they can be passed as parameters to other functions, returned as results, or included as elements of data structures. What is more, a function requiring two or more parameters may be "partially parameterised" (curried) by supplying less than the full number of parameters. This gives another function which, given the remaining parameters, will return a result. For example:
add a b = a + b increment = add 1
is a roundabout way of creating a function "increment" which adds one to its argument. In reality, add 4 7
takes the twoparameter function add
, applies it to 4
obtaining a singleparameter function that adds four to its argument, then applies that to 7
.
Any function taking two parameters can be turned into an infix operator (for example, given the definition of the add
function above, the term $add
is in every way equivalent to the +
operator) and every infix operator taking two parameters can be turned into a corresponding function.
Thus:
increment = (+) 1
is the briefest way to create a function that adds one to its argument. Similarly, in
half = (/ 2) reciprocal = (1 /)
two singleparameter functions are generated. The interpreter understands in each case which of the divide operator's two parameters is being supplied, giving functions which respectively divide a number by two and return its reciprocal.
Although Miranda is a stronglytyped language, it does not insist on explicit type declarations. If a function's type is not explicitly declared, the interpreter infers it from the type of its parameters and how they are used within the function. In addition to the basic types, char, num, bool, it includes an "anything" type where the type of a parameter does not matter, as in the listreversing function:
rev [] = [] rev (a:x) = rev x ++ [a]
which can be applied to a list of any data type, for which the explicit function type declaration would be:
rev :: [*] > [*]
Finally, it has mechanisms for creating and managing program modules whose internal functions are invisible to programs calling those modules.
Sample code
The following Miranda script determines the set of all subsets of a set of numbers
subsets [] = [[]] subsets (x:xs) = [[x] ++ y  y < ys] ++ ys where ys = subsets xs
and this is a literate script for a function primes
which gives the list of all prime numbers
>  The infinite list of all prime numbers, by the sieve of Eratosthenes. The list of potential prime numbers starts as all integers from 2 onwards; as each prime is returned, all the following numbers that can exactly be divided by it are filtered out of the list of candidates. > primes = sieve [2..] > sieve (p:x) = p : sieve [n  n < x; n mod p ~= 0]
External links
 Official website (http://www.engin.umd.umich.edu/CIS/course.des/cis400/miranda/miranda.html)
 Licensed publicaccess Unix system with Miranda (http://medialab.freaknet.org)
 Free infiniteprecision scientific calculator in Miranda (http://medialab.freaknet.org/bignum)