From 4e987026148fe65c323afbc93cd560c07bf06b3f Mon Sep 17 00:00:00 2001 From: Yale AI Dept Date: Wed, 14 Jul 1993 13:08:00 -0500 Subject: Import to github. --- progs/tutorial/tutorial.hs | 2143 ++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 2143 insertions(+) create mode 100644 progs/tutorial/tutorial.hs (limited to 'progs/tutorial/tutorial.hs') diff --git a/progs/tutorial/tutorial.hs b/progs/tutorial/tutorial.hs new file mode 100644 index 0000000..eb6a78d --- /dev/null +++ b/progs/tutorial/tutorial.hs @@ -0,0 +1,2143 @@ +-- Page 0 Introduction + +This is a programming supplement to `A Gentle Introduction to Haskell' +by Hudak and Fasel. This supplement augments the tutorial by +providing executable Haskell programs which you can run and +experiment with. All program fragments in the tutorial are +found here, as well as other examples not included in the tutorial. + + +Using This Tutorial + +You should have a copy of both the `Gentle Introduction' and the +report itself to make full use of this tutorial. Although the +`Gentle Introduction' is meant to stand by itself, it is often easier +to learn a language through actual use and experimentation than by +reading alone. Once you finish this introduction, we recommend that +you proceed section by section through the `Gentle Introduction' and +after having read each section go back to this online tutorial. You +should wait until you have finished the tutorial before attempting to +read the report. We assume that you are familiar with the basics of +Emacs and that Haskell has been installed at your site. + +This tutorial does not assume any familiarity with Haskell or other +functional languages. However, knowledge of almost-functional +languages such as ML or Scheme is very useful. Throughout the +online component of this tutorial, we try to relate Haskell to +other programming languages and clarify the written tutorial through +additional examples and text. + + +Organization of the Online Tutorial + +This online tutorial is divided into a series of pages. Each page +covers one or more sections in the written tutorial. You can use +special Emacs commands to move back and forth through the pages of the +online tutorial. Each page is a single Haskell program. Comments in +the program contain the text of the online tutorial. You can modify +the program freely (this will not change the underlying tutorial +file!) and ask the system to print the value of expressions defined in +the program. + +At the beginning of each page, the sections covered by the page are +listed. In addition, the start of each individual section is +marked within each page. Emacs commands can take you directly to a +specific page or section in the tutorial. + +To create useful, executable examples of Haskell code, some language +constructs need to be revealed well before they are explained in the +tutorial. We attempt to point these out when they occur. Some +small changes have been made to the examples in the written tutorial; +these are usually cosmetic and should be ignored. Don't feel you have +to understand everything on a page before you move on -- many times +concepts become clearer as you move on and can relate them to other +aspect of the language. + +Each page of the tutorial defines a set of variables. Some of +these are named e1, e2, and so on. These `e' variables are the ones +which are meant for you to evaluate as you go through the tutorial. +Of course you may evaluate any other expressions or variables you wish. + + +The Haskell Report + +While the report is not itself a tutorial on the Haskell language, it +can be an invaluable reference to even a novice user. A very +important feature of Haskell is the prelude. The prelude is a +rather large chunk of Haskell code which is implicitly a part of every +Haskell program. Whenever you see functions used which are not +defined in the current page, these come from the Prelude. Appendix A +of the report lists the entire Prelude; the index has an entry for +every function in the Prelude. Looking at the definitions in the +Prelude is sometimes necessary to fully understand the programs in +this tutorial. + +Another reason to look at the report is to understand the syntax of +Haskell. Appendix B contains the complete syntax for Haskell. The +tutorial treats the syntax very informally; the precise details are +found only in the report. + + +The Yale Haskell System + +This version of the tutorial runs under version Y2.0 of Yale Haskell. +The Yale Haskell system is an interactive programming environment for +the Haskell language. The system is best used in conjunction with the +Emacs editor. Yale Haskell is available free of change via ftp. + + +Using the Compiler + +Yale Haskell runs as a subprocess under Emacs. While many commands +are available to the Yale Haskell user, a single command is the +primary means of communicating with the compiler: C-c e. This command +evaluates and prints an expression in the context of the program on +the screen. Here is what this command does: + +a) You are prompted for an expression in the minibuffer. You can +use M-p or M-n to move through a ring of previous inputs. + +b) If an inferior Haskell process is not running, a buffer named *haskell* +is created and the Haskell compiler is started up. The *haskell* buffer +pops onto your screen. + +c) If the program in the current page of the tutorial has not yet been +compiled or the page has been modified after its most recent +compilation, the entire page is compiled. This may result in a short delay. + +d) If there are no errors in the program, the expression entered in +step a) is compiled in the context of the program. Any value defined +in the current page can be referenced. + +e) If there are no errors in the expression, its value is printed in +the *haskell* buffer. + +There are also a few other commands you can use. C-c i interrupts +the Haskell program. Some tight loops cannot be interrupted; in this +case you will have to kill the Haskell process. C-c q exits the Haskell +process. + + +Emacs Commands Used by the Tutorial + +These commands are specific to the tutorial. The tutorial is entered +using M-x haskell-tutorial and is exited with C-c q. To move among +the pages of the tutorial, use + +C-c C-f -- go forward 1 page +C-c C-b -- go back 1 page +M-x ht-goto-page - goto a specific page of the tutorial +M-x ht-goto-section - goto a specific section of the tutorial + +Each page of the tutorial can be modified without changing the +underlying text of the tutorial. Changes are not saved as you go +between pages. To revert a page to its original form use C-c C-l. + +You can get help regarding the Emacs commands with C-c ?. + +Summary of Emacs commands used by the tutorial: + M-x haskell-tutorial - start the tutorial + C-c C-f - Go to the next page of the tutorial program + C-c C-b - Go back to the previous page of the tutorial program + C-c C-l - Restore the current page to its original form + C-c e - Evaluate a Haskell expression + C-c i - Interrupt a running Haskell program + C-c ? - Shows a help message + M-x ht-goto-page - goto a specific page of the tutorial + M-x ht-goto-section - goto a specific section of the tutorial + + +You are now ready to start the tutorial. Start by reading the `Gentle +Introduction' section 1 then proceed through the online tutorial using +C-c C-f to advance to the next page. You should read about each topic +first before turning to the associated programming example in the +online tutorial. + + +-- Page 1 Section 2 + +-- Section 2 Values, Types, and Other Goodies + +-- Haskell uses `--' to designate end of line comments. We use these +-- throughout the tutorial to place explanatory text in the program. + +-- Remember to use C-c e to evaluate expressions, C-c ? for help. + +-- All Haskell programs must start with a module declaration. Ignore this +-- for now. + +module Test(Bool) where + +-- We will start by defining some identifiers (variables) using equations. +-- You can print out the value of an identifier by typing C-c e and +-- typing the name of the identifier you wish to evaluate. This will +-- compile the entire program, not just the line with the definition +-- you want to see. Not all definitions are very interesting to print out - +-- by convention, we will use variables e1, e2, ... to denote values that +-- are `interesting' to print. + +-- We'll start with some constants as well as their associated type. +-- There are two ways to associate a type with a value: a type declaration +-- and an expression type signature. Here is an equation and a type +-- declaration: + +e1 :: Int -- This is a type declaration for the identifier e1 +e1 = 5 -- This is an equation defining e1 + +-- You can evaluate the expression e1 and watch the system print `5'! Wow! + +-- Remember that C-c e is prompting for an expression. Expressions like +-- e1 or 5 or 1+1 are all valid. However, `e1 = 5' is a definition, +-- not an expression. Trying to evaluate it will result in a syntax error. + +-- The type declaration for e1 is not really necessary but we will try to +-- always provide type declarations for values to help document the program +-- and to ensure that the system infers the same type we do for an expression. +-- If you change the value for e1 to `True', the program will no longer +-- compile due to the type mismatch. + +-- We will briefly mention expression type signatures: these are attached to +-- expressions instead of identifiers. Here are equivalent ways to do +-- the previous definition: + +e2 = 5 :: Int +e3 = (2 :: Int) + (3 :: Int) + +-- The :: has very low precedence in expressions and should usually be placed +-- in parenthesis. + +-- Note that there are two completely separate languages: an expression +-- language for values and a type language for type signatures. The type +-- language is used only in the type declarations previously described and +-- declarations of new types, described later. Haskell uses a +-- uniform syntax so that values resemble their type signature as much as +-- possible. However, you must always be aware of the difference between +-- type expressions and value expressions. + +-- Here are some of the predefined types Haskell provides: +-- type Value Syntax Type Syntax +-- Small integers Int +e4 :: Int +e4 = 12345 +-- Characters '' Char +e5 :: Char +e5 = 'a' +-- Boolean True, False Bool +e6 :: Bool +e6 = True +-- Floating point Float +e7 :: Float +e7 = 123.456 +-- We will introduce these types now; there will be much more to say later. +-- Homogenous List [,,...] [] +e8 :: [Int] +e8 = [1,2,3] +-- Tuple (,,...) (,,...) +e9 :: (Char,Int) +e9 = ('b',4) +-- Functional described later domain type -> range type +succ :: Int -> Int -- a function which takes an Int argument and returns Int +succ x = x + 1 -- test this by evaluating `succ 4' + +-- Here's a few leftover examples from section 2: + +e10 = succ (succ 3) -- you could also evaluate `succ (succ 3)' directly + -- by entering the entire expression to the C-c e + +-- If you want to evaluate something more complex than the `e' variables +-- defined here, it is better to enter a complex expression, such as +-- succ (succ 3), directly than to edit a new definition like e10 into +-- the program. This is because any change to the program will require +-- recompilation of the entire page. The expressions entered to C-c e are +-- compiled separately (and very quickly!). + +-- Uncomment this next line to see a compile time type error. +-- e11 = 'a'+'b' +-- Don't worry about the error message - it will make more sense later. + +-- Proceed to the next page using C-c C-f + +-- Page 2 Section 2.1 + +-- Section 2.1 Polymorphic Types + +module Test(Bool) where + +-- The following line allows us to redefine functions in the standard +-- prelude. Ignore this for now. + +import Prelude hiding (length,head,tail,null) + +-- start with some sample lists to use in test cases + +list1 :: [Int] +list1 = [1,2,3] +list2 :: [Char] -- This is the really a string +list2 = ['a','b','c'] -- This is the same as "abc"; evaluate list2 and see. +list3 :: [[a]] -- The element type of the inner list is unknown +list3 = [[],[],[],[]] -- so this list can't be printed +list4 :: [Int] +list4 = 1:2:3:4:[] -- Exactly the same as [1,2,3,4]; print it and see. + +-- This is the length function. You can test it by evaluating expressions +-- such as `length list1'. Function application is written by +-- simple juxtaposition: `f(x)' in other languages would be `f x' in Haskell. + +length :: [a] -> Int +length [] = 0 +length (x:xs) = 1 + length xs + +-- Function application has the highest precedence, so 1 + length xs is +-- parsed as 1 + (length xs). In general, you have to surround +-- non-atomic arguments to a function with parens. This includes +-- arguments which are also function applications. For example, +-- f g x is the function f applied to arguments g and x, similar to +-- f(g,x) in other languages. However, f (g x) is f applied to (g x), or +-- f(g(x)), which means something quite different! Be especially +-- careful with infix operators: f x+1 y-2 would be parsed as (f x)+(1 y)-2. +-- This is also true on the left of the `=': the parens around (x:xs) are +-- absolutely necessary. length x:xs would be parsed as (length x):xs. + +-- Also be careful with prefix negation, -. The application `f -1' is +-- f-1, not f(-1). Add parens around negative numbers to avoid this +-- problem. + +-- Here are some other list functions: + +head :: [a] -> a -- returns the first element in a list (same as car in lisp) +head (x:xs) = x + +tail :: [a] -> [a] -- removes the first element from a list (same as cdr) +tail (x:xs) = xs + +null :: [a] -> Bool +null [] = True +null (x:xs) = False + +cons :: a -> [a] -> [a] +cons x xs = x:xs + +nil :: [a] +nil = [] + +-- Length could be defined using these functions too. This is +-- not good Haskell style but does illustrate these other list functions. +-- The if - then - else will be discussed later. Haskell programmers feel +-- that the pattern matching style, as used in the previous version of +-- length, is more natural and readable. + +length' :: [a] -> Int -- Note that ' can be part of a name +length' x = if null x then 0 else 1 + length' (tail x) + +-- A test case for length', cons, and nil + +e1 = length' (cons 1 (cons 2 nil)) + +-- We haven't said anything about errors yet. Each of the following +-- examples illustrates a potential runtime or compile time error. The +-- compile time error is commented out so that other examples will compile; +-- you can uncomment them and see what happens. + +-- e2 = cons True False -- Why is this not possible in Haskell? +e3 = tail (tail ['a']) -- What happens if you evaluate this? +e4 = [] -- This is especially mysterious! + +-- This last example, e4, is something hard to explain but is often +-- encountered early by novices. We haven't explained yet how the system +-- prints out the expressions you type in - this will wait until later. +-- However, the problem here is that e4 has the type [a]. The printer for +-- the list datatype is complaining that it needs to know a specific type +-- for the list elements even though the list has no elements! This can +-- be avoided by giving e4 a type such as [Int]. (To further confuse you, +-- try giving e4 the type [Char] and see what happens.) + +-- Page 3 Section 2.2 + +-- Section 2.2 User-Defined Types + +module Test(Bool) where + +-- The type Bool is already defined in the Prelude so there is no +-- need to define it here. + +data Color = Red | Green | Blue | Indigo | Violet deriving Text +-- The `deriving Text' is necessary if you want to print a Color value. + +-- You can now evaluate these expressions. +e1 :: Color +e1 = Red +e2 :: [Color] +e2 = [Red,Blue] + +-- It is very important to keep the expression language and the type +-- language in Haskell separated. The data declaration above defines +-- the type constructor Color. This is a nullary constructor: it takes no +-- arguments. Color is found ONLY in the type language - it can not be +-- part of an expression. e1 = Color is meaningless. (Actually, Color could +-- be both a data constructor and a type constructor but we'll ignore this +-- possibility for now). On the other hand, Red, Blue, and so on are +-- (nullary) data constructors. They can appear in expressions and +-- in patterns (described later). The declaration e1 :: Blue would also +-- be meaningless. Data constructors can be defined ONLY in a data +-- declaration. + +-- In the next example, Point is a type constructor and Pt is a data +-- constructor. Point takes one argument and Pt takes two. A data constructor +-- like Pt is really just an ordinary function except that it can be used in +-- a pattern. Type signatures can not be supplied directly for data +-- constructors; their typing is completely defined by the data declaration. +-- However, data constructors have a signature just like any variable: +-- Pt :: a -> a -> Point a -- Not valid Haskell syntax +-- That is, Pt is a function which takes two arguments with the same +-- arbitrary type and returns a value containing the two argument values. + +data Point a = Pt a a deriving Text + +e3 :: Point Float +e3 = Pt 2.0 3.0 +e4 :: Point Char +e4 = Pt 'a' 'b' +e5 :: Point (Point Int) +e5 = Pt (Pt 1 2) (Pt 3 4) +-- e6 = Pt 'a' True -- This is a typing error + +-- The individual components of a point do not have names. +-- Let's jump ahead a little so that we can write functions using these +-- data types. Data constructors (Red, Blue, ..., and Pt) can be used in +-- patterns. When more than one equation is used to define a function, +-- pattern matching occurs top down. + +-- A function to remove red from a list of colors. + +removeRed :: [Color] -> [Color] +removeRed [] = [] +removeRed (Red:cs) = removeRed cs +removeRed (c:cs) = c : removeRed cs -- c cannot be Red at this point + +e7 :: [Color] +e7 = removeRed [Blue,Red,Green,Red] + +-- Pattern matching is capable of testing equality with a specific color. + +-- All equations defining a function must share a common type. A +-- definition such as: +-- foo Red = 1 +-- foo (Pt x y) = x +-- would result in a type error since the argument to foo cannot be both a +-- Color and a Point. Similarly, the right hand sides must also share a +-- common type; a definition such as +-- foo Red = Blue +-- foo Blue = Pt Red Red +-- would also result in a type error. + +-- Here's a couple of functions defined on points. + +dist :: Point Float -> Point Float -> Float +dist (Pt x1 y1) (Pt x2 y2) = sqrt ((x1-x2)^2 + (y1-y2)^2) + +midpoint :: Point Float -> Point Float -> Point Float +midpoint (Pt x1 y1) (Pt x2 y2) = Pt ((x1+x2)/2) ((y1+y2)/2) + +p1 :: Point Float +p1 = Pt 1.0 1.0 +p2 :: Point Float +p2 = Pt 2.0 2.0 + +e8 :: Float +e8 = dist p1 p2 +e9 :: Point Float +e9 = midpoint p1 p2 + +-- The only way to take apart a point is to pattern match. +-- That is, the two values which constitute a point must be extracted +-- by matching a pattern containing the Pt data constructor. Much +-- more will be said about pattern matching later. + +-- Haskell prints values in the same syntax used in expressions. Thus +-- Pt 1 2 would print as Pt 1 2 (of course, Pt 1 (1+1) would also print +-- as Pt 1 2). + +-- Page 4 Section 2.3 + +-- Section 2.3 Recursive Types + +module Test where + +data Tree a = Leaf a | Branch (Tree a) (Tree a) deriving Text + +-- The following typings are implied by this declaration. As before, +-- this is not valid Haskell syntax. +-- Leaf :: a -> Tree a +-- Branch :: Tree a -> Tree a -> Tree a + +fringe :: Tree a -> [a] +fringe (Leaf x) = [x] +fringe (Branch left right) = fringe left ++ fringe right + +-- The following trees can be used to test functions: + +tree1 :: Tree Int +tree1 = Branch (Leaf 1) (Branch (Branch (Leaf 2) (Leaf 3)) (Leaf 4)) +tree2 :: Tree Int +tree2 = Branch (Branch (Leaf 3) (Leaf 1)) (Branch (Leaf 4) (Leaf 1)) +tree3 :: Tree Int +tree3 = Branch tree1 tree2 + +-- Try evaluating `fringe tree1' and others. + +-- Here's another tree function: + +twist :: Tree a -> Tree a +twist (Branch left right) = Branch right left +twist x = x -- This equation only applies to leaves + +-- Here's a function which compares two trees to see if they have the +-- same shape. Note the signature: the two trees need not contain the +-- same type of values. + +sameShape :: Tree a -> Tree b -> Bool +sameShape (Leaf x) (Leaf y) = True +sameShape (Branch l1 r1) (Branch l2 r2) = sameShape l1 l2 && sameShape r1 r2 +sameShape x y = False -- One is a branch, the other is a leaf + +-- The && function is a boolean AND function. + +-- The entire pattern on the left hand side must match in order for the +-- right hand side to be evaluated. The first clause requires both +-- arguments to be a leaf' otherwise the next equation is tested. +-- The last clause will always match: the final x and y match both +-- leaves and branches. + +-- This compares a tree of integers to a tree of booleans. +e1 = sameShape tree1 (Branch (Leaf True) (Leaf False)) + +-- Page 5 Sections 2.4, 2.5, 2.6 + +-- Section 2.4 Type Synonyms + +module Test(Bool) where + +-- Since type synonyms are part of the type language only, it's hard to +-- write a program which shows what they do. Essentially, they are like +-- macros for the type language. They can be used interchangably with their +-- definition: + +e1 :: String +e1 = "abc" +e2 :: [Char] -- No different than String +e2 = e1 + +-- In the written tutorial the declaration of `Addr' is a data type +-- declaration, not a synonym declaration. This shows that the data +-- type declaration as well as a signature can reference a synonym. + +-- Section 2.5 Built-in Types + +-- Tuples are an easy way of grouping a set of data values. Here are +-- a few tuples. Note the consistancy in notation between the values and +-- types. + +e3 :: (Bool,Int) +e3 = (True,4) +e4 :: (Char,[Int],Char) +e4 = ('a',[1,2,3],'b') + +-- Here's a function which returns the second component of a 3 tuple. +second :: (a,b,c) -> b +second (a,b,c) = b + +-- Try out `second e3' and `second e4' - what happens? +-- Each different size of tuple is a completely distinct type. There is +-- no general way to append two arbitrary tuples or randomly select the +-- i'th component of an arbitrary tuple. Here's a function built using +-- 2-tuples to represent intervals. + +-- Use a type synonym to represent homogenous 2 tuples +type Interval a = (a,a) + +containsInterval :: Interval Int -> Interval Int -> Bool +containsInterval (xmin,xmax) (ymin,ymax) = xmin <= ymin && xmax >= ymax + +p1 :: Interval Int +p1 = (2,3) +p2 :: Interval Int +p2 = (1,4) + +e5 = containsInterval p1 p2 +e6 = containsInterval p2 p1 + +-- Here's a type declaration for a type isomorphic to lists: + +data List a = Nil | Cons a (List a) deriving Text + +-- Except for the notation, this is completely equivalent to ordinary lists +-- in Haskell. + +length' :: List a -> Int +length' Nil = 0 +length' (Cons x y) = 1 + length' y + +e7 = length' (Cons 'a' (Cons 'b' (Cons 'c' Nil))) + +-- It's hard to demonstrate much about the `non-specialness' of built-in +-- types. However, here is a brief summary: + +-- Numbers and characters, such as 1, 2.2, or 'a', are the same as nullary +-- type constructors. + +-- Lists have a special type constructor, [a] instead of List a, and +-- an odd looking data constructor, []. The other data constructor, :, is +-- not `unusual', syntactically speaking. The notation [x,y] is just +-- syntax for x:y:[] and "abc" for 'a' : 'b' : 'c' : []. + +-- Tuples use a special syntax. In a type expression, a 2 tuple containing +-- types a and be would be written (a,b) instead of using a prefix type +-- constructor such as Tuple2 a b. This same notation is used to build +-- tuple values: (1,2) would construct a 2 tuple containing the values 1 and 2. + + +-- Page 6 Sections 2.5.1, 2.5.2 + +module Test(Bool) where + +-- Section 2.5.1 List Comprehensions and Arithmetic Sequences + +-- Warning: brackets in Haskell are used in three different types +-- of expressions: lists, as in [a,b,c], sequences (distinguished by +-- the ..), as in [1..2], and list comprehensions (distinguished by the +-- bar: |), as in [x+1 | x <- xs, x > 1]. + +-- Before list comprehensions, let's start out with sequences: + +e1 :: [Int] +e1 = [1..10] -- Step is 1 +e2 :: [Int] +e2 = [1,3..10] -- Step is 3 - 1 +e3 :: [Int] +e3 = [1,-1..-10] +e4 :: [Char] +e4 = ['a'..'z'] -- This works on chars too + +-- We'll avoid infinite sequences like [1..] for now. If you print one, +-- use C-c i to interrupt the Haskell program. + +-- List comprehensions are very similar to nested loops. They return a +-- list of values generated by the expression inside the loop. The filter +-- expressions are similar to conditionals in the loop. + +-- This function does nothing at all! It just scans through a list and +-- copies it into a new one. + +doNothing :: [a] -> [a] +doNothing l = [x | x <- l] + +-- Adding a filter to the previous function allows only selected elements to +-- be generated. This is similar to what is done in quicksort. + +positives :: [Int] -> [Int] +positives l = [x | x <- l, x > 0] + +e5 = positives [2,-4,5,6,-5,3] + +-- Now the full quicksort function. + +quicksort :: [Char] -> [Char] -- Use Char just to be different! +quicksort [] = [] +quicksort (x:xs) = quicksort [y | y <- xs, y <= x] ++ + [x] ++ + quicksort [y | y <- xs, y > x] + +e6 = quicksort "Why use Haskell?" + +-- Now for some nested loops. Each generator, <-, adds another level of +-- nesting to the loop. Note that the variable introduced by each generator +-- can be used in each following generator; all variables can be used in the +-- generated expression: + +e7 :: [(Int,Int)] +e7 = [(x,y) | x <- [1..5], y <- [x..5]] + +-- Now let's add some guards: (the /= function is `not equal') + +e8 :: [(Int,Int)] +e8 = [(x,y) | x <- [1..7], x /= 5, y <- [x..8] , x*y /= 12] + +-- This is the same as the loop: (going to a psuedo Algol notation) +-- for x := 1 to 7 do +-- if x <> 5 then +-- for y := x to 8 do +-- if x*y <> 12 +-- generate (x,y) + +-- Section 2.5.2 Strings + +e9 = "hello" ++ " world" + +-- Page 7 Sections 3, 3.1 + +module Test(Bool) where +import Prelude hiding (map) + +-- Section 3 Functions + +add :: Int -> Int -> Int +add x y = x+y + +e1 :: Int +e1 = add 1 2 + +-- This Int -> Int is the latter part of the signature of add: +-- add :: Int -> (Int -> Int) + +succ :: Int -> Int +succ = add 1 + +e2 :: Int +e2 = succ 3 + +map :: (a->b) -> [a] -> [b] +map f [] = [] +map f (x:xs) = f x : (map f xs) + +e3 :: [Int] +e3 = map (add 1) [1,2,3] +-- This next definition is the equivalent to e3 +e4 :: [Int] +e4 = map succ [1,2,3] + +-- Heres a more complex example. Define flist to be a list of functions: +flist :: [Int -> Int] +flist = map add [1,2,3] +-- This returns a list of functions which add 1, 2, or 3 to their input. +-- Warning: Haskell should print flist as something like +-- [<>,<>,<>] + + +-- Now, define a function which takes a function and returns its value +-- when applied to the constant 1: +applyTo1 :: (Int -> a) -> a +applyTo1 f = f 1 + +e5 :: [Int] +e5 = map applyTo1 flist -- Apply each function in flist to 1 + +-- If you want to look at how the type inference works, figure out how +-- the signatures of map, applyTo1, and flist combine to yield [Int]. + +-- Section 3.1 Lambda Abstractions + +-- The symbol \ is like `lambda' in lisp or scheme. + +-- Anonymous functions are written as \ arg1 arg2 ... argn -> body +-- Instead of naming every function, you can code it inline with this +-- notation: + +e6 = map (\f -> f 1) flist + +-- Be careful with the syntax here. \x->\y->x+y parses as +-- \ x ->\ y -> x + y. The ->\ is all one token. Use spaces!! + +-- This is identical to e5 except that the applyTo1 function has no name. + +-- Function arguments on the left of an = are the same as lambda on the +-- right: + +add' = \x y -> x+y -- identical to add +succ' = \x -> x+1 -- identical to succ + +-- As with ordinary function, the parameters to anonymous functions +-- can be patterns: + +e7 :: [Int] +e7 = map (\(x,y) -> x+y) [(1,2),(3,4),(5,6)] + +-- Functions defined by more than one equation, like map, cannot +-- be converted to anonymous lambda functions quite as easily - a case +-- statement is also required. This is discussed later. + +-- Page 8 Sections 3.2, 3.2.1, 3.2.2 + +module Test(Bool) where + +import Prelude hiding ((++),(.)) + +-- Section 3.2 Infix operators + +-- Haskell has both identifiers, like x, and operators, like +. +-- These are just two different types of syntax for variables. +-- However, operators are by default used in infix notation. + +-- Briefly, identifiers begin with a letter and may have numbers, _, and ' +-- in them: x, xyz123, x'', xYz'_12a. The case of the first letter +-- distinguishes variables from data constructors (or type variables from +-- type constructors). An operator is a string of symbols, where +-- :!#$%&*+./<=>?@\^| are all symbols. If the first character is : then +-- the operator is a data constructor; otherwise it is an ordinary +-- variable operator. The - and ~ characters may start a symbol but cannot +-- be used after the first character. This allows a*-b to parse as +-- a * - b instead of a *- b. + +-- Operators can be converted to identifiers by enclosing them in parens. +-- This is required in signature declarations. Operators can be defined +-- as well as used in the infix style: + +(++) :: [a] -> [a] -> [a] +[] ++ y = y +(x:xs) ++ y = x : (xs ++ y) + +-- Table 2 (Page 54) of the report is invaluable for sorting out the +-- precedences of the many predefined infix operators. + +e1 = "Foo" ++ "Bar" + +-- This is the same function without operator syntax +appendList :: [a] -> [a] -> [a] +appendList [] y = y +appendList (x:xs) y = x : appendList xs y + +(.) :: (b -> c) -> (a -> b) -> (a -> c) +f . g = \x -> f (g x) + +add1 :: Int -> Int +add1 x = x+1 + +e2 = (add1 . add1) 3 + +-- Section 3.2.1 Sections + +-- Sections are a way of creating unary functions from infix binary +-- functions. When a parenthesized expression starts or ends in an +-- operator, it is a section. Another definition of add1: + +add1' :: Int -> Int +add1' = (+ 1) + +e3 = add1' 4 + +-- Here are a few section examples: + +e4 = map (++ "abc") ["x","y","z"] + +e5 = map ("abc" ++) ["x","y","z"] + + +-- Section 3.2.2 Fixity Declarations + +-- We'll avoid any demonstration of fixity declarations. The Prelude +-- contains numerous examples. + +-- Page 9 Sections 3.3, 3.4, 3.5 +module Test(Bool) where + +import Prelude hiding (take,zip) + +-- Section 3.3 Functions are Non-strict + +-- Observing lazy evaluation can present difficulties. The essential +-- question is `does an expression get evaluated?'. While in theory using a +-- non-terminating computation is the way evaluation issues are examined, +-- we need a more practical approach. The `error' function serves as +-- a bottom value. Evaluating this function prints an error message and +-- halts execution. + +bot = error "Evaluating Bottom" + +e1 :: Bool -- This can be any type at all! +e1 = bot -- evaluate this and see what happens. + +const1 :: a -> Int +const1 x = 1 + +e2 :: Int +e2 = const1 bot -- The bottom is not needed and will thus not be evaluated. + +-- Section 3.4 "Infinite" Data Structures + +-- Data structures are constructed lazily. A constructor like : will not +-- evaluate its arguments until they are demanded. All demands arise from +-- the need to print the result of the computation -- components not needed +-- to compute the printed result will not be evaluated. + +list1 :: [Int] +list1 = (1:bot) + +e3 = head list1 -- doesnt evaluate bot +e4 = tail list1 -- does evaluate bot + +-- Some infinite data structures. Don't print these! If you do, you will +-- need to interrupt the system (C-c i) or kill the Haskell process. + +ones :: [Int] +ones = 1 : ones + +numsFrom :: Int -> [Int] +numsFrom n = n : numsFrom (n+1) + +-- An alternate numsFrom using series notation: + +numsFrom' :: Int -> [Int] +numsFrom' n = [n..] + +squares :: [Int] +squares = map (^2) (numsFrom 0) + +-- Before we start printing anything, we need a function to truncate these +-- infinite lists down to a more manageable size. The `take' function +-- extracts the first k elements of a list: + +take :: Int -> [a] -> [a] +take 0 x = [] -- two base cases: k = 0 +take k [] = [] -- or the list is empty +take k (x:xs) = x : take (k-1) xs + +-- now some printable lists: + +e5 :: [Int] +e5 = take 5 ones + +e6 :: [Int] +e6 = take 5 (numsFrom 10) + +e7 :: [Int] +e7 = take 5 (numsFrom' 0) + +e8 :: [Int] +e8 = take 5 squares + +-- zip is a function which turns two lists into a list of 2 tuples. If +-- the lists are of differing sizes, the result is as long as the +-- shortest list. + +zip (x:xs) (y:ys) = (x,y) : zip xs ys +zip xs ys = [] -- one of the lists is [] + +e9 :: [(Int,Int)] +e9 = zip [1,2,3] [4,5,6] + +e10 :: [(Int,Int)] +e10 = zip [1,2,3] ones + +fib :: [Int] +fib = 1 : 1 : [x+y | (x,y) <- zip fib (tail fib)] + +e11 = take 5 fib + +-- Let's do this without the list comprehension: + +fib' :: [Int] +fib' = 1 : 1 : map (\(x,y) -> x+y) (zip fib (tail fib)) + +-- This could be written even more cleanly using a map function which +-- maps a binary function over two lists at once. This is in the +-- Prelude and is called zipWith. + +fib'' :: [Int] +fib'' = 1 : 1 : zipWith (+) fib (tail fib) + +-- For more examples using infinite structures look in the demo files +-- that come with Yale Haskell. Both the pascal program and the +-- primes program use infinite lists. + +-- Section 3.5 The Error Function + +-- Too late - we already used it! + + +-- Page 10 Sections 4, 4.1, 4.2 + +module Test(Bool) where + +import Prelude hiding (take,(^)) + +-- Section 4 Case Expressions and Pattern Matching + +-- Now for details of pattern matching. We use [Int] instead of [a] +-- since the only value of type [a] is []. + +contrived :: ([Int], Char, (Int, Float), String, Bool) -> Bool +contrived ([], 'b', (1, 2.0), "hi", True) = False +contrived x = True -- add a second equation to avoid runtime errors + +e1 :: Bool +e1 = contrived ([], 'b', (1, 2.0), "hi", True) +e2 :: Bool +e2 = contrived ([1], 'b', (1, 2.0), "hi", True) + +-- Contrived just tests its input against a big constant. + +-- Linearity in pattern matching implies that patterns can only compare +-- values with constants. The following is not valid Haskell: + +-- member x [] = False +-- member x (x:ys) = True -- Invalid since x appears twice +-- member x (y:ys) = member x ys + +f :: [a] -> [a] +f s@(x:xs) = x:s +f _ = [] + +e3 = f "abc" + +-- Another use of _: + +middle :: (a,b,c) -> b +middle (_,x,_) = x + +e4 :: Char +e4 = middle (True, 'a', "123") + +(^) :: Int -> Int -> Int +x ^ 0 = 1 +x ^ (n+1) = x*(x^n) + +e5 :: Int +e5 = 3^3 +e6 :: Int +e6 = 4^(-2) -- Notice the behavior of the + pattern on this one + +-- Section 4.1 Pattern Matching Semantics + +-- Here's an extended example to illustrate the left -> right, top -> bottom +-- semantics of pattern matching. + +foo :: (Int,[Int],Int) -> Int +foo (1,[2],3) = 1 +foo (2,(3:_),3) = 2 +foo (1,_,3) = 3 +foo _ = 4 + +bot = error "Bottom Evaluated" + +e7 = foo (1,[],3) +e8 = foo (1,bot,3) +e9 = foo (1,1:bot,3) +e10 = foo (2,bot,2) +e11 = foo (3,bot,bot) + +-- Now add some guards: + +sign :: Int -> Int +sign x | x > 0 = 1 + | x == 0 = 0 + | x < 0 = -1 + +e12 = sign 3 + +-- The last guard is often `True' to catch all other cases. The identifier +-- `otherwise' is defined as True for use in guards: + +max' :: Int -> Int -> Int +max' x y | x > y = x + | otherwise = y + +-- Guards can refer to any variables bound by pattern matching. When +-- no guard is true, pattern matching resumes at the next equation. Guards +-- may also refer to values bound in an associated where declaration. + + +inOrder :: [Int] -> Bool +inOrder (x1:x2:xs) | x1 <= x2 = True +inOrder _ = False + +e13 = inOrder [1,2,3] +e14 = inOrder [2,1] + +-- Section 4.2 An Example + +take :: Int -> [a] -> [a] +take 0 _ = [] +take _ [] = [] +take (n+1) (x:xs) = x:take n xs + +take' :: Int -> [a] -> [a] +take' _ [] = [] +take' 0 _ = [] +take' (n+1) (x:xs) = x:take' n xs + +e15, e16, e17, e18 :: [Int] +e15 = take 0 bot +e16 = take' 0 bot +e17 = take bot [] +e18 = take' bot [] + +-- Page 11 Sections 4.3, 4.4, 4.5, 4.6 + +module Test(Bool) where + +-- import Prelude hiding (take,Request(..),Response(..)) -- Standard Haskell +import Prelude hiding (take) -- Y2.0-b4 only + +-- Section 4.3 Case Expressions + +-- The function take using a case statement instead of multiple equations + +take :: Int -> [a] -> [a] +take m ys = case (m,ys) of + (0 ,_) -> [] + (_ ,[]) -> [] + (n+1,x:xs) -> x : take n xs + +-- The function take using if then else. We can also eliminate the n+k +-- pattern just for fun. The original version of take is much easier to read! + +take' :: Int -> [a] -> [a] +take' m ys = if m == 0 then [] else + if null ys then [] else + if m > 0 then head ys : take (m-1) (tail ys) + else error "m < 0" + +-- Section 4.4 Lazy Patterns + +-- Before the client-server example, here is a contrived example of lazy +-- patterns. The first version will fail to pattern match whenever the +-- the first argument is []. The second version will always pattern +-- match initially but x will fail if used when the list is []. + +nonlazy :: [Int] -> Bool -> [Int] +nonlazy (x:xs) isNull = if isNull then [] else [x] + +e1 = nonlazy [1,2] False +e2 = nonlazy [] True +e3 = nonlazy [] False + +-- This version will never fail the initial pattern match +lazy :: [Int] -> Bool -> [Int] +lazy ~(x:xs) isNull = if isNull then [] else [x] + +e4 = lazy [1,2] False +e5 = lazy [] True +e6 = lazy [] False + +-- The server - client example is a little hard to demonstrate. We'll avoid +-- the initial version which loops. Here is the version with irrefutable +-- patterns. + +type Response = Int +type Request = Int + +client :: Request -> [Response] -> [Request] +client init ~(resp:resps) = init : client (next resp) resps + +server :: [Request] -> [Response] +server (req : reqs) = process req : server reqs + +-- Next maps the response from the previous request onto the next request +next :: Response -> Request +next resp = resp + +-- Process maps a request to a response +process :: Request -> Response +process req = req+1 + +requests :: [Request] +requests = client 0 responses + +responses :: [Response] +responses = server requests + +e7 = take 5 responses + +-- The lists of requests and responses are infinite - there is no need to +-- check for [] in this program. These lists correspond to streams in other +-- languages. + +-- Here is fib again: + +fib :: [Int] +fib@(1:tfib) = 1 : 1 : [ a+b | (a,b) <- zip fib tfib] + +e8 = take 10 fib + +-- Section 4.5 Lexical Scoping and Nested Forms + +-- One thing that is important to note is that the order of the +-- definitions in a program, let expression, or where clauses is +-- completely arbitrary. Definitions can be arranged 'top down' +-- or `bottom up' without changing the program. + +e9 = let y = 2 :: Float + f x = (x+y)/y + in f 1 + f 2 + +f :: Int -> Int -> String +f x y | y > z = "y > x^2" + | y == z = "y = x^2" + | y < z = "y < x^2" + where + z = x*x + +e10 = f 2 5 +e11 = f 2 4 + +-- Section 4.6 Layout + +-- There's nothing much to demonstrate here. We have been using layout all +-- through the tutorial. The main thing is to be careful line up the +-- first character of each definition. For example, if you +-- change the indentation of the definition of f in e9 you will get a +-- parse error. + +-- Page 12 Section 5 +module Test(Bool) where + +import Prelude hiding (elem) + +-- Section 5 Type Classes + +-- Names in the basic class structure of Haskell cannot be hidden (they are +-- in PreludeCore) so we have to modify the names used in the tutorial. + +-- Here is a new Eq class: + +class Eq' a where + eq :: a -> a -> Bool + +-- Now we can define elem using eq from above: + +elem :: (Eq' a) => a -> [a] -> Bool +x `elem` [] = False +x `elem` (y:ys) = x `eq` y || x `elem` ys + +-- Before this is of any use, we need to admit some types to Eq' + +instance Eq' Int where + x `eq` y = abs (x-y) < 3 -- Let's make this `nearly equal' just for fun + +instance Eq' Float where + x `eq` y = abs (x-y) < 0.1 + +list1 :: [Int] +list1 = [1,5,9,23] + +list2 :: [Float] +list2 = [0.2,5.6,33,12.34] + +e1 = 2 `elem` list1 +e2 = 100 `elem` list1 +e3 = 0.22 `elem` list2 + +-- Watch out! Integers in Haskell are overloaded - without a type signature +-- to designate an integer as an Int, expressions like 3 `eq` 3 will be +-- ambiguous. See 5.5.4 about this problem. + +-- Now to add the tree type: + +data Tree a = Leaf a | Branch (Tree a) (Tree a) deriving Text + +instance (Eq' a) => Eq' (Tree a) where + (Leaf a) `eq` (Leaf b) = a `eq` b + (Branch l1 r1) `eq` (Branch l2 r2) = (l1 `eq` l2) && (r1 `eq` r2) + _ `eq` _ = False + +tree1,tree2 :: Tree Int +tree1 = Branch (Leaf 1) (Leaf 2) +tree2 = Branch (Leaf 2) (Leaf 1) + +e4 = tree1 `eq` tree2 + +-- Now make a new class with Eq' as a super class: + +class (Eq' a) => Ord' a where + lt,le :: a -> a -> Bool -- lt and le are operators in Ord' + x `le` y = x `eq` y || x `lt` y -- This is a default for le + +-- The typing of lt & le is +-- le,lt :: (Ord' a) => a -> a -> Bool +-- This is identical to +-- le,lt :: (Eq' a,Ord' a) => a -> a -> Bool + +-- Make Int an instance of Ord +instance Ord' Int where + x `lt` y = x < y+1 + +i :: Int -- Avoid ambiguity +i = 3 +e5 :: Bool +e5 = i `lt` i + +-- Some constraints on instance declarations: +-- A program can never have more than one instance declaration for +-- a given combination of data type and class. +-- If a type is declared to be a member of a class, it must also be +-- declared in all superclasses of that class. +-- An instance declaration does not need to supply a method for every +-- operator in the class. When a method is not supplied in an +-- instance declaration and no default is present in the class +-- declaration, a runtime error occurs if the method is invoked. +-- You must supply the correct context for an instance declaration -- +-- this context is not inferred automatically. + +-- Section 5.1 Equality and Ordered Classes +-- Section 5.2 Enumeration and Index Classes + +-- No examples are provided for 5.1 or 5.2. The standard Prelude contains +-- many instance declarations which illustrate the Eq, Ord, and Enum classes. + +-- Page 13 Section 5.3 + +module Test(Bool) where + +-- Section 5.3 Text and Binary Classes + +-- This is the slow showTree. The `show' function is part of the +-- Text class and works with all the built-in types. The context `Text a' +-- arises from the call to show for leaf values. + +data Tree a = Leaf a | Branch (Tree a) (Tree a) deriving Text + +showTree :: (Text a) => Tree a -> String +showTree (Leaf x) = show x +showTree (Branch l r) = "<" ++ showTree l ++ "|" ++ showTree r ++ ">" + +tree1 :: Tree Int +tree1 = Branch (Leaf 1) (Branch (Leaf 3) (Leaf 6)) + +e1 = showTree tree1 + +-- Now the improved showTree; shows is already defined for all +-- built in types. + +showsTree :: Text a => Tree a -> String -> String +showsTree (Leaf x) s = shows x s +showsTree (Branch l r) s = '<' : showsTree l ('|' : showsTree r ('>' : s)) + +e2 = showsTree tree1 "" + +-- The final polished version. ShowS is predefined in the Prelude so we +-- don't need it here. + + +showsTree' :: Text a => Tree a -> ShowS +showsTree' (Leaf x) = shows x +showsTree' (Branch l r) = ('<' :) . showsTree' l . ('|' :) . + showsTree' r . ('>' :) + +e3 = showsTree' tree1 "" + + +-- Page 14 This page break is just to keep recompilation from getting too +-- long. The compiler takes a little longer to compile this +-- page than other pages. + +module Test(Bool) where + +data Tree a = Leaf a | Branch (Tree a) (Tree a) deriving Text + +-- Now for the reading function. Again, ReadS is predefined and reads works +-- for all built-in types. The generators in the list comprehensions are +-- patterns: p <- l binds pattern p to successive elements of l which match +-- p. Elements not matching p are skipped. + +readsTree :: (Text a) => ReadS (Tree a) +readsTree ('<':s) = [(Branch l r, u) | (l, '|':t) <- readsTree s, + (r, '>':u) <- readsTree t ] +readsTree s = [(Leaf x,t) | (x,t) <- reads s] + +e4 :: [(Int,String)] +e4 = reads "5 golden rings" + +e5 :: [(Tree Int,String)] +e5 = readsTree "<1|<2|3>>" +e6 :: [(Tree Int,String)] +e6 = readsTree "<1|2" +e7 :: [(Tree Int,String)] +e7 = readsTree "<1|<<2|3>|<4|5>>> junk at end" + +-- Before we do the next readTree, let's play with the lex function. + +e8 :: [(String,String)] +e8 = lex "foo bar bletch" + +-- Here's a function to completely lex a string. This does not handle +-- lexical ambiguity - lex would return more than one possible lexeme +-- when an ambiguity is encountered and the patterns used here would not +-- match. + +lexAll :: String -> [String] +lexAll s = case lex s of + [("",_)] -> [] -- lex returns an empty token if none is found + [(token,rest)] -> token : lexAll rest + +e9 = lexAll "lexAll :: String -> [String]" +e10 = lexAll "<1|>" + +-- Finally, the `hard core' reader. This is not sensitive to +-- white space as were the previous versions. + + +readsTree' :: (Text a) => ReadS (Tree a) +readsTree' s = [(Branch l r, x) | ("<", t) <- lex s, + (l, u) <- readsTree' t, + ("|", v) <- lex u, + (r, w) <- readsTree' v, + (">", x) <- lex w ] + ++ + [(Leaf x, t) | (x, t) <- reads s] + +-- When testing this program, you must make sure the input conforms to +-- Haskell lexical syntax. If you remove spaces between | and < or +-- > and > they will lex as a single token. + +e11 :: [(Tree Int,String)] +e11 = readsTree' "<1 | <2 | 3> >" +e12 :: [(Tree Bool,String)] +e12 = readsTree' "" + +-- Finally, here is a simple version of read for trees only: + +read' :: (Text a) => String -> (Tree a) +read' s = case (readsTree' s) of + [(tree,"")] -> tree -- Only one parse, no junk at end + [] -> error "Couldn't parse tree" + [_] -> error "Crud after the tree" -- unread chars at end + _ -> error "Ambiguous parse of tree" + +e13 :: Tree Int +e13 = read' "foo" +e14 :: Tree Int +e14 = read' "< 1 | < 2 | 3 > >" +e15 :: Tree Int +e15 = read' "3 xxx" + +-- Page 15 Section 5.4 + +module Test(Bool) where + +-- Section 5.4 Derived Instances + +-- We have actually been using the derived Text instances all along for +-- printing out trees and other structures we have defined. The code +-- in the tutorial for the Eq and Ord instance of Tree is created +-- implicitly by the deriving clause so there is no need to write it +-- here. + +data Tree a = Leaf a | Branch (Tree a) (Tree a) deriving (Eq,Ord,Text) + +-- Now we can fire up both Eq and Ord functions for trees: + +tree1, tree2, tree3, tree4 :: Tree Int +tree1 = Branch (Leaf 1) (Leaf 3) +tree2 = Branch (Leaf 1) (Leaf 5) +tree3 = Leaf 4 +tree4 = Branch (Branch (Leaf 4) (Leaf 3)) (Leaf 5) + +e1 = tree1 == tree1 +e2 = tree1 == tree2 +e3 = tree1 < tree2 + +quicksort :: Ord a => [a] -> [a] +quicksort [] = [] +quicksort (x:xs) = quicksort [y | y <- xs, y <= x] ++ + [x] ++ + quicksort [y | y <- xs, y > x] + +e4 = quicksort [tree1,tree2,tree3,tree4] + +-- Now for Enum: + +data Day = Sunday | Monday | Tuesday | Wednesday | Thursday | + Friday | Saturday deriving (Text,Eq,Ord,Enum) + +e5 = quicksort [Monday,Saturday,Friday,Sunday] +e6 = [Wednesday .. Friday] +e7 = [Monday, Wednesday ..] +e8 = [Saturday, Friday ..] + + +-- Page 16 Sections 5.5, 5.5.1, 5.5.2, 5.5.3 + +module Test(Bool) where + +-- Section 5.5 Numbers +-- Section 5.5.1 Numeric Class Structure +-- Section 5.5.2 Constructed Numbers + +-- Here's a brief summary of Haskell numeric classes. + +-- Class Num +-- Most general numeric class. Has addition, subtraction, multiplication. +-- Integers can be coerced to any instance of Num with fromInteger. +-- All integer constants are in this class. +-- Instances: Int, Integer, Float, Double, Ratio a, Complex a + +-- Class Real +-- This class contains ordered numbers which can be converted to +-- rationals. +-- Instances: Int, Integer, Float, Double, Ratio a + +-- Class Integral +-- This class deals with integer division. All values in Integral can +-- be mapped onto Integer. +-- Instances: Int, Integer + +-- Class Fractional +-- These are numbers which can be divided. Any rational number can +-- be converted to a fractional. Floating point constants are in +-- this class: 1.2 would be 12/10. +-- Instances: Float, Double, Ratio a + +-- Class Floating +-- This class contains all the standard floating point functions such +-- as sqrt and sin. +-- Instances: Float, Double, Complex a + +-- Class RealFrac +-- These values can be rounded to integers and approximated by rationals. +-- Instances: Float, Double, Ratio a + +-- Class RealFloat +-- These are floating point numbers constructed from a fixed precision +-- mantissa and exponent. +-- Instances: Float, Double + +-- There are only a few sensible combinations of the constructed numerics +-- with built-in types: +-- Ratio Integer (same as Rational): arbitrary precision rationals +-- Ratio Int: limited precision rationals +-- Complex Float: complex numbers with standard precision components +-- Complex Double: complex numbers with double precision components + + +-- The following function works for arbitrary numerics: + +fact :: (Num a) => a -> a +fact 0 = 1 +fact n = n*(fact (n-1)) + +-- Note the behavior when applied to different types of numbers: + +e1 :: Int +e1 = fact 6 +e2 :: Int +e2 = fact 20 -- Yale Haskell may not handle overflow gracefully! +e3 :: Integer +e3 = fact 20 +e4 :: Rational +e4 = fact 6 +e5 :: Float +e5 = fact 6 +e6 :: Complex Float +e6 = fact 6 + +-- Be careful: values like `fact 1.5' will loop! + +-- As a practical matter, Int operations are much faster than Integer +-- operations. Also, overloaded functions can be much slower than non- +-- overloaded functions. Giving a function like fact a precise typing: + +-- fact :: Int -> Int + +-- will yield much faster code. + +-- In general, numeric expressions work as expected. Literals are +-- a little tricky - they are coerced to the appropriate value. A +-- constant like 1 can be used as ANY numeric type. + +e7 :: Float +e7 = sqrt 2 +e8 :: Rational +e8 = ((4%5) * (1%2)) / (3%4) +e9 :: Rational +e9 = 2.2 * (3%11) - 1 +e10 :: Complex Float +e10 = (2 * (3:+3)) / (1.1:+2.0 - 1) +e11 :: Complex Float +e11 = sqrt (-1) +e12 :: Integer +e12 = numerator (4%2) +e13 :: Complex Float +e13 = conjugate (4:+5.2) + +-- A function using pattern matching on complex numbers: + +mag :: (RealFloat a) => Complex a -> a +mag (a:+b) = sqrt (a^2 + b^2) + +e14 :: Float +e14 = mag (1:+1) + +-- Section 5.5.3 Numeric Coercions and Overloaded Literals + +-- The Haskell type system does NOT implicitly coerce values between +-- the different numeric types! Although overloaded constants are +-- coerced when the overloading is resolved, no implicit coercion goes +-- on when values of different types are mixed. For example: + +f :: Float +f = 1.1 +i1 :: Int +i1 = 1 +i2 :: Integer +i2 = 2 + +-- All of these expressions would result in a type error (try them!): + +-- g = i1 + f +-- h = i1 + i2 +-- i3 :: Int +-- i3 = i2 + +-- Appropriate coercions must be introduced by the user to allow +-- the mixing of types in arithmetic expressions. + +e15 :: Float +e15 = f + fromIntegral i1 +e16 :: Integer +e16 = fromIntegral i1 + i2 +e17 :: Int +e17 = i1 + fromInteger i2 -- fromIntegral would have worked too. + +-- Page 17 Section 5.5.4 +module Test(Bool) where + +-- Section 5.5.4 Default Numeric Types + +-- Ambiguous contexts arise frequently in numeric expressions. When an +-- expression which produces a value with a general type, such as +-- `1' (same as `fromInteger 1'; the type is (Num a) => a), with +-- another expression which `consumes' the type, such as `show' or +-- `toInteger', ambiguity arises. This ambiguity can be resolved +-- using expression type signatures, but this gets tedious fast! +-- Assigning a type to the top level of an ambiguous expression does +-- not help: the ambiguity does not propagate to the top level. + +e1 :: String -- This type does not influence the type of the argument to show +e1 = show 1 -- Does this mean to show an Int or a Float or ... +e2 :: String +e2 = show (1 :: Float) +e3 :: String +e3 = show (1 :: Complex Float) + +-- The reason the first example works is that ambiguous numeric types are +-- resolved using defaults. The defaults in effect here are Int and +-- Double. Since Int `fits' in the expression for e1, Int is used. +-- When Int is not valid (due to other context constraints), Double +-- will be tried. + +-- This function defaults the type of the 2's to be Int + +rms :: (Floating a) => a -> a -> a +rms x y = sqrt ((x^2 + y^2) * 0.5) + +-- The C-c e evaluation used to the Haskell system also makes use of +-- defaulting. When you type an expression, the system creates a +-- simple program to print the value of the expression using a function +-- like show. If no type signature for the printed expression is given, +-- defaulting may occur. + +-- One of the reasons for adding type signatures throughout these examples +-- is to avoid unexpected defaulting. Many of the top level signatures are +-- required to avoid ambiguity. + +-- Defaulting can lead to overflow problems when values exceed Int limits. +-- Evaluate a very large integer without a type signature to observe this +-- (unfortunately this may cause a core dump or other unpleasantness). + +-- Notice that defaulting applies only to numeric classes. The +-- show (read "xyz") -- Try this if you want! +-- example uses only class Text so no defaulting occurs. + +-- Ambiguity also arises with polymorphic types. As discussed previously, +-- expressions like [] have a similar problem. + +-- e4 = [] -- Won't work since [] has type [a] and `a' is not known. + +-- Note the difference: even though the lists have no components, the type +-- of component makes a difference in printing. + +e5 = ([] :: [Int]) +e6 = ([] :: [Char]) + +-- Page 18 Sections 6, 6.1, 6.2 + +-- Section 6 Modules + +module Tree ( Tree(Leaf,Branch), fringe ) where +-- Tree(..) would work also + +data Tree a = Leaf a | Branch (Tree a) (Tree a) deriving Text + +fringe :: Tree a -> [a] +fringe (Leaf x) = [x] +fringe (Branch left right) = fringe left ++ fringe right + +-- The Emacs interface to Haskell performs evaluation within the +-- module containing the cursor. To evaluate e1 you must place the +-- cursor in module Main. + +module Main (Tree) where +import Tree ( Tree(Leaf, Branch), fringe) +-- import Tree -- this would be the same thing +e1 :: [Int] +e1 = fringe (Branch (Leaf 1) (Leaf 2)) + +-- This interactive Haskell environment can evaluate expressions in +-- any module. The use of module Main is optional. + +-- Section 6.1 Original Names and Renaming + +module Renamed where +import Tree ( Tree(Leaf,Branch), fringe) + renaming (Leaf to Root, Branch to Twig) + +e2 :: Tree Int +e2 = Twig (Root 1) (Root 2) -- Printing always uses the original names + +-- Section 6.2 Interfaces and Implementations + +-- Yale Haskell allows separate compilation of modules using +-- unit files. These are described in the user's guide. + + +-- Page 19 Sections 6.3, 6.4 + +-- Section 6.3 Abstract Data Types + +-- Since TreeADT does not import Tree it can use the name Tree without +-- any conflict. Each module has its own separate namespace. + +module TreeADT (Tree, leaf, branch, cell, left, + right, isLeaf) where + +data Tree a = Leaf a | Branch (Tree a) (Tree a) deriving Text + +leaf = Leaf +branch = Branch +cell (Leaf a) = a +left (Branch l r) = l +right (Branch l r) = r +isLeaf (Leaf _) = True +isLeaf _ = False + +module Test where +import TreeADT + +-- Since the constructors for type Tree are hidden, pattern matching +-- cannot be used. + +fringe :: Tree a -> [a] +fringe x = if isLeaf x then [cell x] + else fringe (left x) ++ fringe (right x) + +e1 :: [Int] +e1 = fringe (branch (branch (leaf 3) (leaf 2)) (leaf 1)) + +-- Section 6.4 + + +-- Page 20 Sections 7, 7.1, 7.2, 7.3 + +-- Section 7 Typing Pitfalls + +-- Section 7.1 Let-Bound Polymorphism + +module Test(e2) where + +-- f g = (g 'a',g []) -- This won't typecheck. + +-- Section 7.2 Overloaded Numerals + +-- Overloaded numerics were covered previously - here is one more example. +-- sum is a prelude function which sums the elements of a list. + +average :: (Fractional a) => [a] -> a +average xs = sum xs / fromIntegral (length xs) + +e1 :: Float -- Note that e1 would default to Double instead of Int - + -- this is due to the Fractional context. +e1 = average [1,2,3] + +-- Section 7.3 The Monomorphism Restriction + +-- The monomorphism restriction is usually encountered when functions +-- are defined without parameters. If you remove the signature for sum' +-- the monomorphism restriction will apply. +-- This will generate an error if either: +-- sum' is added to the module export list at the start of this section +-- both sumInt and sumFloat remain in the program. +-- If sum' is not exported and all uses of sum' have the same overloading, +-- there is no type error. + +sum' :: (Num a) => [a] -> a +sum' = foldl (+) 0 -- foldl reduces a list with a binary function + -- 0 is the initial value. + +sumInt :: Int +sumInt = sum' [1,2,3] + +sumFloat :: Float +sumFloat = sum' [1,2,3] + +-- If you use overloaded constants you also may encounter monomorphism: + +x :: Num a => a +x = 1 -- The type of x is Num a => a +y :: Int +y = x -- Uses x as an Int +z :: Integer +z = x -- Uses x as an Integer. A monomorphism will occur of the + -- signature for x is removed. + -- comments to see an error. + +-- Finally, if a value is exported it must not be overloaded unless bound +-- by a function binding. e2 is the only value exported. + +e2 :: Int -- Remove this to get an error. Without this line e1 will + -- be overloaded. +e2 = 1 + +-- To prevent annoying error messages about exported monomorphic variables, +-- most modules in this tutorial do not implicitly export everything - they +-- only export a single value, Bool, which was chosen to keep the export +-- list non-empty (a syntactic restriction!). In Haskell systems without +-- the evaluator used here, a module which does not export any names would +-- be useless. + +-- module Test where -- this would export everything in the module +-- module Test(Bool) -- exports only Bool +-- module Test() -- this is what we really want to do but is not valid. + +-- Page 21 Sections 8, 8.1 + +module Test(Bool) where + +-- Section 8 Input/Output +-- Section 8.1 Introduction to Continuations + +-- Simplify f here to be 1/x. + +data Maybe a = Ok a | Oops String deriving Text + +f :: Float -> Maybe Float +f x = if x == 0 then Oops "Divide by 0" else Ok (1/x) + +-- g is a `safe' call to x. The call to error could be replaced by +-- some explicit value like Oops msg -> 0. + +g x = case f x of + Ok y -> y + Oops msg -> error msg + +e1 = f 0 +e2 = g 0 +e3 = g 1 + +-- Here is the same example using continuations: + +f' :: Float -> (String -> Float) -> Float +f' x c = if x == 0 then c "Divide by 0" + else 1/x + +g' x = f' x error -- calls error on divide by 0 +g'' x = f' x (\s -> 0) -- returns 0 on divide by 0 + +e4 = g' 0 +e5 = g'' 0 + +-- Page 22 Sections 8.2, 8.3 + +module Test where + +-- Section 8.2 Continuation Based I/O + +-- We will skip the program fragments at the start of this section and +-- move directly to the writeFile / readFile example. + +-- Before we can use Haskell I/O, we need to introduce a new Emacs command: +-- C-c r. This command runs a dialogue instead of printing a value. +-- (Actually C-c e creates a dialogue on the fly and runs it in the same +-- manner as C-c r). As with C-c e you are prompted for an expression. +-- In this case, the expression must be of type Dialogue and it is +-- executed by the I/O system. We use d1,d2,... for dialogues to be +-- executed by C-c r. + +-- We make the file name a parameter to allow for easier testing. +-- Don't expect much error handling in exit. + +s1 = "This is a test of Haskell" + +main file = writeFile file s1 exit ( + readFile file exit (\s2 -> + appendChan stdout (if s1==s2 then "contents match" + else "something intervened!") exit + done)) + +d1,d2 :: Dialogue +d1 = main "/tmp/ReadMe" +d2 = main "/dev/null" -- this will read back as the empty string + +-- A simple IO program using $ for readability: ($ is defined in the Prelude) + +d3 = appendChan "stdout" "Type something: " exit $ + readChan "stdin" exit $ \s2 -> + appendChan "stdout" ("You typed " ++ head (lines s2)) exit $ + done + +-- This program suffers from a strictness problem. Strictness deals +-- with when things get evaluated. In this program, the input is not +-- needed until after the "You typed " is printed. Fixing this would +-- require some operation to look at the string before the final +-- appendChan. Here is one possible fix: + +d4 = appendChan "stdout" "Type something: " exit $ + readChan "stdin" exit $ \s2 -> + let str = head (lines s2) in + if str == str then -- This evaluates str + appendChan "stdout" ("You typed " ++ head (lines s2)) exit $ + done + else done + + +-- Section 8.3 Terminal I/O + +-- Since this programming environment runs under Emacs, the issue of +-- echoing does not really apply. However, the synchronization between +-- input and output can be seen in the following example. Since the input +-- comes a line at a time, the X's come in groups between input lines. +-- The cursor will move into the haskell dialogue buffer when the program +-- requests input. Use a ^D to stop the program (^Q^D actually). [Warning: +-- some brain damaged lisps stop not only the Haskell program but also +-- the entire compiler on ^D] + +d5 = readChan stdin exit processInput where + processInput s = loop 1 s + loop n [] = done + loop n (x:xs) | n == 10 = appendChan stdout "X" exit (loop 1 xs) + | True = loop (n+1) xs + +-- For more examples using the I/O system look in the demo programs +-- that come with haskell (in $HASKELL/progs/demo) and the report. + +-- Page 23 Sections 9, 9.1, 9.2 + +module Test(Bool) where + +-- Section 9 Arrays +-- Section 9.1 Index Types + +-- Arrays are built on the class Ix. Here are some quick examples of Ix: + +e1 :: [Int] +e1 = range (0,4) +e2 :: Int +e2 = index (0,4) 2 +low,high :: (Int,Int) +low = (1,1) +high = (3,4) +e3 = range (low,high) +e4 = index (low,high) (3,2) +e5 = inRange (low,high) (4,3) + +-- Section 9.2 Array Creation + +squares :: Array Int Int +squares = array (1,100) [i := i*i | i <- [1..100]] + +-- We can also parameterize this a little: + +squares' :: Int -> Array Int Int +squares' n = array (1,n) [i := i*i | i <- [1..n]] + +e6 :: Int +e6 = squares!6 +e7 :: (Int,Int) +e7 = bounds squares +e8 :: Array Int Int +e8 = squares' 10 + +-- Here is a function which corresponds to `take' for lists. It takes +-- an arbitrary slice out of an array. + +atake :: (Ix a) => Array a b -> (a,a) -> Array a b +atake a (l,u) | inRange (bounds a) l && inRange (bounds a) u = + array (l,u) [i := a!i | i <- range (l,u)] + | otherwise = error "Subarray out of range" + +e9 = atake squares (4,8) + +mkArray :: Ix a => (a -> b) -> (a,a) -> Array a b +mkArray f bnds = array bnds [i := f i | i <- range bnds] + +e10 :: Array Int Int +e10 = mkArray (\i -> i*i) (1,10) + +fibs :: Int -> Array Int Int +fibs n = a where + a = array (0,n) ([0 := 1, 1 := 1] ++ + [i := a!(i-1) + a!(i-2) | i <- [2..n]]) + +e11 = atake (fibs 50) (3,10) + +wavefront :: Int -> Array (Int,Int) Int +wavefront n = a where + a = array ((1,1),(n,n)) + ([(1,j) := 1 | j <- [1..n]] ++ + [(i,1) := 1 | i <- [2..n]] ++ + [(i,j) := a!(i,j-1) + a!(i-1,j-1) + a!(i-1,j) + | i <- [2..n], j <- [2..n]]) + +wave = wavefront 20 +e12 = atake wave ((1,1),(3,3)) +e13 = atake wave ((3,3),(5,5)) + +-- Here are some errors in array operations: + +e14 :: Int +e14 = wave ! (0,0) -- Out of bounds +arr1 :: Array Int Int +arr1 = array (1,10) [1 := 1] -- No value provided for 2..10 +e15,e16 :: Int +e15 = arr1 ! 1 -- works OK +e16 = arr1 ! 2 -- undefined by array + +-- Page 24 Sections 9.3, 9.4 + +module Test(Bool) where + +-- Section 9.3 Accumulation + +hist :: (Ix a, Integral b) => (a,a) -> [a] -> Array a b +hist bnds is = accumArray (+) 0 bnds [i := 1 | i <- is, inRange bnds i] + +e1 :: Array Char Int +e1 = hist ('a','z') "This counts the frequencies of each lowercase letter" + +decades :: (RealFrac a) => a -> a -> [a] -> Array Int Int +decades a b = hist (0,9) . map decade + where + decade x = floor ((x-a) * s) + s = 10 / (b - a) + +test1 :: [Float] +test1 = map sin [0..100] -- take the sine of the 0 - 100 +e2 = decades 0 1 test1 + +-- Section 9.4 Incremental Updates + +swapRows :: (Ix a, Ix b, Enum b) => a -> a -> Array (a,b) c -> Array (a,b) c +swapRows i i' a = a // ([(i,j) := a!(i',j) | j <- [jLo..jHi]] ++ + [(i',j) := a!(i,j) | j <- [jLo..jHi]]) + where ((iLo,jLo),(iHi,jHi)) = bounds a + +arr1 :: Array (Int,Int) (Int,Int) +arr1 = array ((1,1),(5,5)) [(i,j) := (i,j) | (i,j) <- range ((1,1),(5,5))] + +e3 = swapRows 2 3 arr1 + +-- Printing the arrays in more readable form makes the results easier +-- to view. + +-- This is a printer for 2d arrays + +aprint a width = shows (bounds a) . showChar '\n' . showRows lx ly where + showRows r c | r > ux = showChar '\n' + showRows r c | c > uy = showChar '\n' . showRows (r+1) ly + showRows r c = showElt (a!(r,c)) . showRows r (c+1) + showElt e = showString (take width (show e ++ repeat ' ')) . showChar ' ' + ((lx,ly),(ux,uy)) = bounds a + +showArray a w = appendChan stdout (aprint a w "") abort done + +d1 = showArray e3 6 + +swapRows' :: (Ix a, Ix b, Enum b) => a -> a -> Array (a,b) c -> Array (a,b) c +swapRows' i i' a = a // [assoc | j <- [jLo..jHi], + assoc <- [(i,j) := a!(i',j), + (i',j) := a!(i,j)]] + where ((iLo,jLo),(iHi,jHi)) = bounds a + +d2 = showArray (swapRows' 1 5 arr1) 6 + +-- Page 25 Section 9.5 + +module Test(Bool) where + +-- Section 9.5 An example: Matrix Multiplication + +aprint a width = shows (bounds a) . showChar '\n' . showRows lx ly where + showRows r c | r > ux = showChar '\n' + showRows r c | c > uy = showChar '\n' . showRows (r+1) ly + showRows r c = showElt (a!(r,c)) . showRows r (c+1) + showElt e = showString (take width (show e ++ repeat ' ')) . showChar ' ' + ((lx,ly),(ux,uy)) = bounds a + +showArray a w = appendChan stdout (aprint a w "") abort done + +matMult :: (Ix a, Ix b, Ix c, Num d) => + Array (a,b) d -> Array (b,c) d -> Array (a,c) d +matMult x y = + array resultBounds + [(i,j) := sum [x!(i,k) * y!(k,j) | k <- range (lj,uj)] + | i <- range (li,ui), + j <- range (lj',uj')] + where + ((li,lj),(ui,uj)) = bounds x + ((li',lj'),(ui',uj')) = bounds y + resultBounds + | (lj,uj)==(li',ui') = ((li,lj'),(ui,uj')) + | otherwise = error "matMult: incompatible bounds" + +mat1,mat2,mat3,mat4 :: Array (Int,Int) Int +mat1 = array ((0,0),(1,1)) [(0,0) := 1,(0,1) := 0,(1,0) := 0,(1,1) := 1] +mat2 = array ((0,0),(1,1)) [(0,0) := 1,(0,1) := 1,(1,0) := 1,(1,1) := 1] +mat3 = array ((0,0),(1,1)) [(0,0) := 1,(0,1) := 2,(1,0) := 3,(1,1) := 4] +mat4 = array ((0,0),(1,2)) [(0,0) := 1,(0,1) := 2,(0,2) := 3, + (1,0) := 4,(1,1) := 5,(1,2) := 6] + +d1 = showArray (matMult mat1 mat2) 4 +d2 = showArray (matMult mat2 mat3) 4 +d3 = showArray (matMult mat1 mat4) 4 +d4 = showArray (matMult mat4 mat1) 4 + +matMult' :: (Ix a, Ix b, Ix c, Num d) => + Array (a,b) d -> Array (b,c) d -> Array (a,c) d +matMult' x y = + accumArray (+) 0 ((li,lj'),(ui,uj')) + [(i,j) := x!(i,k) * y!(k,j) + | i <- range (li,ui), + j <- range (lj',uj'), + k <- range (lj,uj)] + + where + ((li,lj),(ui,uj)) = bounds x + ((li',lj'),(ui',uj')) = bounds y + resultBounds + | (lj,uj)==(li',ui') = ((li,lj'),(ui,uj')) + | otherwise = error "matMult: incompatible bounds" + +d5 = showArray (matMult mat1 mat2) 4 +d6 = showArray (matMult mat2 mat3) 4 + +genMatMul :: (Ix a, Ix b, Ix c) => + ([f] -> g) -> (d -> e -> f) -> + Array (a,b) d -> Array (b,c) e -> Array (a,c) g +genMatMul f g x y = + array ((li,lj'),(ui,uj')) + [(i,j) := f [(x!(i,k)) `g` (y!(k,j)) | k <- range (lj,uj)] + | i <- range (li,ui), + j <- range (lj',uj')] + where + ((li,lj),(ui,uj)) = bounds x + ((li',lj'),(ui',uj')) = bounds y + resultBounds + | (lj,uj)==(li',ui') = ((li,lj'),(ui,uj')) + | otherwise = error "matMult: incompatible bounds" + +d7 = showArray (genMatMul maximum (-) mat2 mat1) 4 +d8 = showArray (genMatMul and (==) mat1 mat2) 6 +d9 = showArray (genMatMul and (==) mat1 mat1) 6 + +-- Page 26 More about Haskell + +This is the end of the tutorial. If you wish to see more examples of +Haskell programming, Yale Haskell comes with a set of demo programs. +These can be found in $HASKELL/progs/demo. Once you have mastered the +tutorial, both the report and the user manual for Yale Haskell should +be understandable. Many examples of Haskell programming can be found in +the Prelude. The directory $HASKELL/progs/prelude contains the sources +for the Prelude. + +We appreciate any comments you have on this tutorial. Send any comments +to haskell-requests@cs.yale.edu. + + The Yale Haskell Group -- cgit v1.2.3