Haskell (programming language)

Haskell
Paradigm functional, lazy/non-strict, modular
Designed by Lennart Augustsson, Dave Barton, Brian Boutel, Warren Burton, Joseph Fasel, Kevin Hammond, Ralf Hinze, Paul Hudak, John Hughes, Thomas Johnsson, Mark Jones, Simon Peyton Jones, John Launchbury, Erik Meijer, John Peterson, Alastair Reid, Colin Runciman, Philip Wadler
First appeared 1990
Haskell 2010[1] / July 2010
Announced as Haskell 2014[2]
static, strong, inferred
OS Cross-platform
.hs, .lhs
Website haskell.org

Haskell /ˈhæskəl/[22] is a standardized, general-purpose purely functional programming language, with non-strict semantics and strong static typing.[23] It is named after logician Haskell Curry.[24]

History

Following the release of Miranda by Research Software Ltd, in 1985, interest in lazy functional languages grew: by 1987, more than a dozen non-strict, purely functional programming languages existed. Of these, Miranda was the most widely used, but was proprietary software. At the conference on Functional Programming Languages and Computer Architecture (FPCA '87) in Portland, Oregon, a meeting was held during which participants formed a strong consensus that a committee should be formed to define an open standard for such languages. The committee's purpose was to consolidate the existing functional languages into a common one that would serve as a basis for future research in functional-language design.[25]

Haskell 1.0 to 1.4

The first version of Haskell ("Haskell 1.0") was defined in 1990.[24] The committee's efforts resulted in a series of language definitions (1.0, 1.1, 1.2, 1.3, 1.4).

Haskell 98

In late 1997, the series culminated in Haskell 98, intended to specify a stable, minimal, portable version of the language and an accompanying standard library for teaching, and as a base for future extensions. The committee expressly welcomed the creation of extensions and variants of Haskell 98 via adding and incorporating experimental features.[25]

In February 1999, the Haskell 98 language standard was originally published as "The Haskell 98 Report".[25] In January 2003, a revised version was published as "Haskell 98 Language and Libraries: The Revised Report".[23] The language continues to evolve rapidly, with the Glasgow Haskell Compiler (GHC) implementation representing the current de facto standard.[26]

Haskell Prime

In early 2006, the process of defining a successor to the Haskell 98 standard, informally named Haskell Prime, began.[27] This is an ongoing incremental process to revise the language definition, producing a new revision up to once per year. The first revision, named Haskell 2010, was announced in November 2009[1] and published in July 2010.

Haskell 2010

Haskell 2010 adds the foreign function interface (FFI) to Haskell, allowing for bindings to other programming languages, fixes some syntax issues (changes in the formal grammar) and bans so-called "n-plus-k-patterns", that is, definitions of the form fact (n+1) = (n+1) * fact n are no longer allowed. It introduces the Language-Pragma-Syntax-Extension which allows for designating a Haskell source as Haskell 2010 or requiring certain extensions to the Haskell language. The names of the extensions introduced in Haskell 2010 are DoAndIfThenElse, HierarchicalModules, EmptyDataDeclarations, FixityResolution, ForeignFunctionInterface, LineCommentSyntax, PatternGuards, RelaxedDependencyAnalysis, LanguagePragma and NoNPlusKPatterns.[1]

Features

Haskell features lazy evaluation, pattern matching, list comprehension, type classes, and type polymorphism. It is a purely functional language, which means that in general, functions in Haskell do not have side effects. There is a distinct construct for representing side effects, orthogonal to the type of functions. A pure function may return a side effect which is subsequently executed, modeling the impure functions of other languages.

Haskell has a strong, static type system based on Hindley–Milner type inference. Haskell's principal innovation in this area is to add type classes, which were originally conceived as a principled way to add overloading to the language,[28] but have since found many more uses.[29]

The construct which represents side effects is an example of a monad. Monads are a general framework which can model different kinds of computation, including error handling, nondeterminism, parsing, and software transactional memory. Monads are defined as ordinary datatypes, but Haskell provides some syntactic sugar for their use.

The language has an open, published specification,[23] and multiple implementations exist. The main implementation of Haskell, GHC, is both an interpreter and native-code compiler that runs on most platforms. GHC is noted for its high-performance implementation of concurrency and parallelism,[30] and for having a rich type system incorporating recent innovations such as generalized algebraic data types and type families.

There is an active community around the language, and more than 5400 third-party open-source libraries and tools are available in the online package repository Hackage.[31]

Code examples

The following is a Hello world program written in Haskell (note that all but the last line can be omitted):

module Main where
 
main :: IO ()
main = putStrLn "Hello, World!"

Here is the factorial function in Haskell, defined in a few different ways:

-- Type annotation (optional)
factorial :: (Integral a) => a -> a
 
-- Using recursion
factorial n | n < 2 = 1
factorial n = n * factorial (n - 1)
 
-- Using recursion, with guards
factorial n
  | n < 2     = 1
  | otherwise = n * factorial (n - 1)
 
-- Using recursion but written without pattern matching
factorial n = if n > 0 then n * factorial (n-1) else 1
 
-- Using a list
factorial n = product [1..n]
 
-- Using fold (implements product)
factorial n = foldl (*) 1 [1..n]
 
-- Point-free style
factorial = foldr (*) 1 . enumFromTo 1

An efficient implementation of the Fibonacci numbers, as an infinite list, is this:

-- Type annotation (optional)
fib :: Int -> Integer
 
-- With self-referencing data
fib n = fibs !! n
        where fibs = 0 : scanl (+) 1 fibs
        -- 0,1,1,2,3,5,...
 
-- Same, coded directly
fib n = fibs !! n
        where fibs = 0 : 1 : next fibs
              next (a : t@(b:_)) = (a+b) : next t
 
-- Similar idea, using zipWith
fib n = fibs !! n
        where fibs = 0 : 1 : zipWith (+) fibs (tail fibs)
 
-- Using a generator function
fib n = fibs (0,1) !! n
        where fibs (a,b) = a : fibs (b,a+b)

The Int type refers to a machine-sized integer (used as a list subscript with the !! operator), while Integer is an arbitrary-precision integer. For example, using Integer, the factorial code above easily computes "factorial 100000" as an incredibly large number of 456,574 digits, with no loss of precision.

This is an implementation of an algorithm similar to quick sort over lists, in which the first element is taken as the pivot:

quickSort :: Ord a => [a] -> [a]
quickSort []     = []                               -- The empty list is already sorted
quickSort (x:xs) = quickSort [a | a <- xs, a < x]   -- Sort the left part of the list
                   ++ [x] ++                        -- Insert pivot between two sorted parts
                   quickSort [a | a <- xs, a >= x]  -- Sort the right part of the list

Implementations

All listed implementations are distributed under open source licenses.[32]

The following implementations comply fully, or very nearly, with the Haskell 98 standard.

The following implementations are no longer being actively maintained:

The following implementations are not fully Haskell 98 compliant, and use a language that is a variant of Haskell:

Applications

Darcs is a revision control system written in Haskell, with several innovative features. Cabal is a tool for building and packaging Haskell libraries and programs.[36] Linspire GNU/Linux chose Haskell for system tools development.[37] Xmonad is a window manager for the X Window System, written entirely in Haskell.[38] GHC is also often a testbed for advanced functional programming features and optimizations in other programming languages.

Industry

Web

There are Haskell web frameworks,[40] such as:

Related languages

Clean is a close relative of Haskell. Its biggest deviation from Haskell is in the use of uniqueness types instead of monads for I/O and side-effects.

A series of languages inspired by Haskell, but with different type systems, have been developed, including:

JVM-based:

Other related languages include:

Haskell has served as a testbed for many new ideas in language design. There have been a wide number of Haskell variants produced, exploring new language ideas, including:

Criticism

Jan-Willem Maessen, in 2002, and Simon Peyton Jones, in 2003, discussed problems associated with lazy evaluation while also acknowledging the theoretical motivation for it,[53][54] in addition to purely practical considerations such as improved performance.[55] They note that, in addition to adding some performance overhead, lazy evaluation makes it more difficult for programmers to reason about the performance of their code (particularly its space usage).

Bastiaan Heeren, Daan Leijen, and Arjan van IJzendoorn in 2003 also observed some stumbling blocks for Haskell learners: "The subtle syntax and sophisticated type system of Haskell are a double edged sword — highly appreciated by experienced programmers but also a source of frustration among beginners, since the generality of Haskell often leads to cryptic error messages."[56] To address these, researchers from Utrecht University developed an advanced interpreter called Helium which improved the user-friendliness of error messages by limiting the generality of some Haskell features, and in particular removing support for type classes.

Ben Lippmeier designed Disciple[57] as a strict-by-default (lazy by explicit annotation) dialect of Haskell with a type-and-effect system, to address Haskell's difficulties in reasoning about lazy evaluation and in using traditional data structures such as mutable arrays.[58] He argues (p. 20) that "destructive update furnishes the programmer with two important and powerful tools... a set of efficient array-like data structures for managing collections of objects, and ... the ability to broadcast a new value to all parts of a program with minimal burden on the programmer."

Robert Harper, one of the authors of Standard ML, has given his reasons for not using Haskell to teach introductory programming. Among these are the difficulty of reasoning about resource usage with non-strict evaluation, that lazy evaluation complicates the definition of data types and inductive reasoning,[59] and the "inferiority" of Haskell's (old) class system compared to ML's module system.[60]

Conferences and workshops

The Haskell community meets regularly for research and development activities. The primary events are:

Since 2006, there have been a series of organized "hackathons", the Hac series, aimed at improving the programming language tools and libraries.[61]

Since 2005, a growing number of Haskell users' groups have formed, in the United States, Canada, Australia, South America, Europe and Asia.

References

  1. 1.0 1.1 1.2 Marlow, Simon (24 November 2009). "Announcing Haskell 2010". Haskell (Mailing list). Retrieved 12 March 2011.
  2. Lynagh, Ian (1 May 2013). "Haskell 2014". Haskell-prime (Mailing list). Retrieved 9 October 2013.
  3. 3.0 3.1 3.2 3.3 3.4 3.5 3.6 3.7 3.8 3.9 3.10 3.11 3.12 Peyton Jones 2003, p. xi
  4. Norell, Ulf (2008). "Dependently Typed Programming in Agda" (PDF). Gothenburg: Chalmers University. Retrieved 9 February 2012.
  5. Hudak et al. 2007, p. 12-38,43.
  6. Stroustrup, Bjarne; Sutton, Andrew (2011). "Design of Concept Libraries for C++" (PDF).
  7. 7.0 7.1 7.2 7.3 7.4 7.5 7.6 7.7 7.8 7.9 Hudak et al. 2007, pp. 12-45–46.
  8. 8.0 8.1 Meijer, Erik. "Confessions of a Used Programming Language Salesman: Getting the Masses Hooked on Haskell" (PDF). OOPSLA 2007.
  9. Meijer, Erik (1 October 2009). "C9 Lectures: Dr. Erik Meijer – Functional Programming Fundamentals, Chapter 1 of 13". Channel 9. Microsoft. Retrieved 9 February 2012.
  10. Drobi, Sadek (4 March 2009). "Erik Meijer on LINQ". InfoQ (QCon SF 2008: C4Media Inc.). Retrieved 9 February 2012.
  11. Hickey, Rich. "Clojure Bookshelf". Listmania!. Amazon.com. Retrieved 9 February 2012.
  12. Heller, Martin (18 October 2011). "Turn up your nose at Dart and smell the CoffeeScript". JavaWorld (InfoWorld). Retrieved 9 February 2012.
  13. Syme, Don; Granicz, Adam; Cisternino, Antonio (2007). Expert F#. Apress. p. 2. F# also draws from Haskell particularly with regard to two advanced language features called sequence expressions and workflows.
  14. Wechsung, Ingo. "The Frege Programmin Language" (PDF). Retrieved 26 February 2014.
  15. "Idris, a dependently typed language". Retrieved 2014-10-26.
  16. "Kaya Inspiration". Retrieved 2014-11-22.
  17. "LiveScript Inspiration". Retrieved 2014-02-04.
  18. "Glossary of Terms and Jargon". Perl Foundation Perl 6 Wiki. The Perl Foundation. 28 February. Retrieved 9 February 2012. Check date values in: |date= (help)
  19. Kuchling, A. M. "Functional Programming HOWTO". Python v2.7.2 documentation. Python Software Foundation. Retrieved 9 February 2012.
  20. Fogus, Michael (6 August 2010). "MartinOdersky take(5) toList". Send More Paramedics. Retrieved 9 February 2012.
  21. Lattner, Chris (2014-06-03). "Chris Lattner's Homepage". Chris Lattner. Retrieved 2014-06-03. The Swift language is the product of tireless effort from a team of language experts, documentation gurus, compiler optimization ninjas, and an incredibly important internal dogfooding group who provided feedback to help refine and battle-test ideas. Of course, it also greatly benefited from the experiences hard-won by many other languages in the field, drawing ideas from Objective-C, Rust, Haskell, Ruby, Python, C#, CLU, and far too many others to list.
  22. Chevalier, Tim (28 January 2008). "anybody can tell me the pronuncation of "haskell"?". Haskell-cafe (Mailing list). Retrieved 12 March 2011.
  23. 23.0 23.1 23.2 Peyton Jones 2003.
  24. 24.0 24.1 Hudak et al. 2007.
  25. 25.0 25.1 25.2 Peyton Jones 2003, Preface.
  26. "Haskell Wiki: Implementations". Retrieved 18 December 2012.
  27. "Welcome to Haskell'". The Haskell' Wiki.
  28. Wadler, P.; Blott, S. (1989). "How to make ad-hoc polymorphism less ad hoc". Proceedings of the 16th ACM SIGPLAN-SIGACT Symposium on Principles of Programming Languages (ACM): 60–76. doi:10.1145/75277.75283. ISBN 0-89791-294-2.
  29. Hallgren, T. (January 2001). "Fun with Functional Dependencies, or Types as Values in Static Computations in Haskell". Proceedings of the Joint CS/CE Winter Meeting (Varberg, Sweden).
  30. Computer Language Benchmarks Game
  31. "HackageDB statistics". Hackage.haskell.org. Retrieved 2013-06-26.
  32. "Implementations" at the Haskell Wiki
  33. C. Ryder and S. Thompson (2005). "Porting HaRe to the GHC API"
  34. Boquist, Urban; Johnsson, Thomas (1996). "The GRIN Project: A Highly Optimising Back End for Lazy Functional Languages". LNCS 1268: 58–84.
  35. Hudak et al. 2007, p. 12-22.
  36. "The Haskell Cabal". Retrieved 8 April 2015.
  37. "Linspire/Freespire Core OS Team and Haskell". Debian Haskell mailing list. May 2006.
  38. xmonad.org
  39. 39.0 39.1 39.2 39.3 A formal proof of functional correctness was completed in 2009. Klein, Gerwin; Elphinstone, Kevin; Heiser, Gernot; Andronick, June; Cock, David; Derrin, Philip; Elkaduwe, Dhammika; Engelhardt, Kai; Kolanski, Rafal; Norrish, Michael; Sewell, Thomas; Tuch, Harvey; Winwood, Simon (October 2009). "seL4: Formal verification of an OS kernel" (PDF). 22nd ACM Symposium on Operating System Principles. Big Sky, MT, USA.
  40. HaskellWiki – Haskell web frameworks
  41. "Snap: A Haskell Web Framework: Home". Snapframework.com. Retrieved 2013-06-26.
  42. The Frege prog. lang.
  43. Project Frege at google code
  44. Hellow World and more with Frege
  45. Jaskell
  46. Glasgow Parallel Haskell
  47. GHC Language Features: Parallel Haskell
  48. Using GHC: Using SML parallelism
  49. MIT Parallel Haskell
  50. OHaskell at HaskellWiki
  51. Scotch
  52. Jan-Willem Maessen. Eager Haskell: Resource-bounded execution yields efficient iteration. Proceedings of the 2002 ACM SIGPLAN workshop on Haskell.
  53. Simon Peyton Jones. Wearing the hair shirt: a retrospective on Haskell. Invited talk at POPL 2003.
  54. Lazy evaluation can lead to excellent performance, such as in The Computer Language Benchmarks Game
  55. Heeren, Bastiaan; Leijen, Daan; van IJzendoorn, Arjan (2003). "Helium, for learning Haskell" (PDF). Proceedings of the 2003 ACM SIGPLAN workshop on Haskell.
  56. "DDC – HaskellWiki". Haskell.org. 2010-12-03. Retrieved 2013-06-26.
  57. Ben Lippmeier, Type Inference and Optimisation for an Impure World, Australian National University (2010) PhD thesis, chapter 1
  58. Robert Harper. "The point of laziness".
  59. Robert Harper. "Modules matter most.".
  60. "Hackathon – HaskellWiki".

Further reading

Reports
Textbooks
History

External links

Wikibooks has a book on the topic of: Haskell
Wikibooks has a book on the topic of: Write Yourself a Scheme in 48 Hours
Tutorials
Books
Various
Applications