Ur/Web: doc/intro.ur annotate

annotate doc/intro.ur @ 2278:b7615e0ac4b0

Fix bug in and clean up free path code.

author	Ziv Scully <ziv@mit.edu>
date	Tue, 10 Nov 2015 12:35:00 -0500
parents	544199d8b14a
children

rev	line source
adam@1500	1 (* Chapter 1: Introduction *)
adam@1494	2
adam@1497	3 (* begin hide *)
adam@1497	4 val show_string = mkShow (fn s => "\"" ^ s ^ "\"")
adam@1497	5 (* end *)
adam@1495	6
adam@1497	7 (* This tutorial by <a href="http://adam.chlipala.net/">Adam Chlipala</a> is licensed under a <a href="http://creativecommons.org/licenses/by-nc-nd/3.0/">Creative Commons Attribution-Noncommercial-No Derivative Works 3.0 Unported License</a>. *)
adam@1493	8
adam@1511	9 (* This is a tutorial for the <a href="http://www.impredicative.com/ur/">Ur/Web</a> programming language.<br>
adam@1510	10 <br>
adam@1513	11 Briefly, <b>Ur</b> is a programming language in the tradition of <a target="_top" href="http://en.wikipedia.org/wiki/ML_(programming_language)">ML</a> and <a target="_top" href="http://en.wikipedia.org/wiki/Haskell_(programming_language)">Haskell</a>, but featuring a significantly richer type system. Ur is <a target="_top" href="http://en.wikipedia.org/wiki/Functional_programming">functional</a>, <a target="_top" href="http://en.wikipedia.org/wiki/Purely_functional">pure</a>, <a target="_top" href="http://en.wikipedia.org/wiki/Statically-typed">statically-typed</a>, and <a target="_top" href="http://en.wikipedia.org/wiki/Strict_programming_language">strict</a>. Ur supports a powerful kind of <b><a target="_top" href="http://en.wikipedia.org/wiki/Metaprogramming">metaprogramming</a></b> based on <b><a target=_"top" href="http://citeseer.ist.psu.edu/viewdoc/summary?doi=10.1.1.44.6387">row types</a></b>.<br>
adam@1510	12 <br>
adam@1510	13 <b>Ur/Web</b> is Ur plus a special standard library and associated rules for parsing and optimization. Ur/Web supports construction of dynamic web applications backed by SQL databases, with mixed server-side and client-side applications generated from source code in one language.<br>
adam@1510	14 <br>
adam@1511	15 Ur inherits its foundation from ML and Haskell, then going further to add fancier stuff. This first chapter of the tutorial reviews the key ML and Haskell features, giving their syntax in Ur. I do assume reading familiarity with ML and Haskell and won't dwell too much on explaining the imported features.<br>
adam@1511	16 <br>
adam@1511	17 For information on compiling applications (and for some full example applications), see the intro page of <a href="http://www.impredicative.com/ur/demo/">the online demo</a>, with further detail available in <a href="http://www.impredicative.com/ur/manual.pdf">the reference manual</a>. *)
adam@1497	18
adam@1497	19 (* * Basics *)
adam@1497	20
adam@1501	21 (* Let's start with features shared with both ML and Haskell. First, we have the basic numeric, string, and Boolean stuff. (In the following examples, <tt>==</tt> is used to indicate the result of evaluating an expression. It's not valid Ur syntax!) *)
adam@1493	22
adam@1493	23 (* begin eval *)
adam@1497	24 1 + 1
adam@1493	25 (* end *)
adam@1493	26
adam@1497	27 (* begin eval *)
adam@1497	28 1.2 + 3.4
adam@1497	29 (* end *)
adam@1496	30
adam@1497	31 (* begin eval *)
adam@1497	32 "Hello " ^ "world!"
adam@1497	33 (* end *)
adam@1497	34
adam@1497	35 (* begin eval *)
adam@1497	36 1 + 1 < 6
adam@1497	37 (* end *)
adam@1497	38
adam@1497	39 (* begin eval *)
adam@1497	40 0.0 < -3.2
adam@1497	41 (* end *)
adam@1497	42
adam@1497	43 (* begin eval *)
adam@1497	44 "Hello" = "Goodbye" \|\| (1 * 2 <> 8 && True <> False)
adam@1497	45 (* end *)
adam@1497	46
adam@1497	47 (* We also have function definitions with type inference for parameter and return types. *)
adam@1497	48
adam@1497	49 fun double n = 2 * n
adam@1497	50
adam@1497	51 (* begin eval *)
adam@1497	52 double 8
adam@1497	53 (* end *)
adam@1497	54
adam@1497	55 fun fact n = if n = 0 then 1 else n * fact (n - 1)
adam@1497	56
adam@1497	57 (* begin eval *)
adam@1497	58 fact 5
adam@1497	59 (* end *)
adam@1497	60
adam@2168	61 fun isEven n = n = 0 \|\| (n > 1 && isOdd (n - 1))
adam@2168	62 and isOdd n = n = 1 \|\| (n > 1 && isEven (n - 1))
adam@1502	63
adam@1502	64 (* begin eval *)
adam@1502	65 isEven 32
adam@1502	66 (* end *)
adam@2168	67 (* begin eval *)
adam@2168	68 isEven 31
adam@2168	69 (* end *)
adam@1502	70
adam@1502	71
adam@1497	72 (* Of course we have anonymous functions, too. *)
adam@1497	73
adam@1497	74 val inc = fn x => x + 1
adam@1497	75
adam@1497	76 (* begin eval *)
adam@1497	77 inc 3
adam@1497	78 (* end *)
adam@1497	79
adam@1497	80 (* Then there's parametric polymorphism. Unlike in ML and Haskell, polymorphic functions in Ur/Web often require full type annotations. That is because more advanced features (which we'll get to in the next chapter) make Ur type inference undecidable. *)
adam@1497	81
adam@1497	82 fun id [a] (x : a) : a = x
adam@1497	83
adam@1497	84 (* begin eval *)
adam@1497	85 id "hi"
adam@1497	86 (* end *)
adam@1497	87
adam@1497	88 fun compose [a] [b] [c] (f : b -> c) (g : a -> b) (x : a) : c = f (g x)
adam@1497	89
adam@1497	90 (* begin eval *)
adam@1497	91 compose inc inc 3
adam@1497	92 (* end *)
adam@1498	93
adam@1502	94 (* The <tt>option</tt> type family is like ML's <tt>option</tt> or Haskell's <tt>Maybe</tt>. We also have a <tt>case</tt> expression form lifted directly from ML. Note that, while Ur follows most syntactic conventions of ML, one key difference is that type family names appear before their arguments, as in Haskell. *)
adam@1498	95
adam@1498	96 fun predecessor (n : int) : option int = if n >= 1 then Some (n - 1) else None
adam@1498	97
adam@1498	98 (* begin hide *)
adam@1498	99 fun show_option [t] (_ : show t) : show (option t) =
adam@1498	100 mkShow (fn x => case x of
adam@1498	101 None => "None"
adam@1498	102 \| Some x => "Some(" ^ show x ^ ")")
adam@1498	103 (* end *)
adam@1498	104
adam@1498	105 (* begin eval *)
adam@1498	106 predecessor 6
adam@1498	107 (* end *)
adam@1498	108
adam@1498	109 (* begin eval *)
adam@1498	110 predecessor 0
adam@1498	111 (* end *)
adam@1499	112
adam@1499	113 (* Naturally, there are lists, too! *)
adam@1499	114
adam@1499	115 val numbers : list int = 1 :: 2 :: 3 :: []
adam@1499	116 val strings : list string = "a" :: "bc" :: []
adam@1499	117
adam@1499	118 fun length [a] (ls : list a) : int =
adam@1499	119 case ls of
adam@1499	120 [] => 0
adam@1499	121 \| _ :: ls' => 1 + length ls'
adam@1499	122
adam@1499	123 (* begin eval *)
adam@1499	124 length numbers
adam@1499	125 (* end *)
adam@1499	126
adam@1499	127 (* begin eval *)
adam@1499	128 length strings
adam@1499	129 (* end *)
adam@1500	130
adam@1502	131 (* And lists make a good setting for demonstrating higher-order functions and local functions. (This example also introduces one idiosyncrasy of Ur, which is that <tt>map</tt> is a keyword, so we name our "map" function <tt>mp</tt>.) *)
adam@1500	132
adam@1500	133 (* begin hide *)
adam@1500	134 fun show_list [t] (_ : show t) : show (list t) =
adam@1500	135 mkShow (let
adam@1500	136 fun shower (ls : list t) =
adam@1500	137 case ls of
adam@1500	138 [] => "[]"
adam@1500	139 \| x :: ls' => show x ^ " :: " ^ shower ls'
adam@1500	140 in
adam@1500	141 shower
adam@1500	142 end)
adam@1500	143 (* end *)
adam@1500	144
adam@1500	145 fun mp [a] [b] (f : a -> b) : list a -> list b =
adam@1500	146 let
adam@1500	147 fun loop (ls : list a) =
adam@1500	148 case ls of
adam@1500	149 [] => []
adam@1500	150 \| x :: ls' => f x :: loop ls'
adam@1500	151 in
adam@1500	152 loop
adam@1500	153 end
adam@1500	154
adam@1500	155 (* begin eval *)
adam@1500	156 mp inc numbers
adam@1500	157 (* end *)
adam@1500	158
adam@1500	159 (* begin eval *)
adam@1500	160 mp (fn s => s ^ "!") strings
adam@1500	161 (* end *)
adam@1500	162
adam@1500	163 (* We can define our own polymorphic datatypes and write higher-order functions over them. *)
adam@1500	164
adam@1500	165 datatype tree a = Leaf of a \| Node of tree a * tree a
adam@1500	166
adam@1500	167 (* begin hide *)
adam@1500	168 fun show_tree [t] (_ : show t) : show (tree t) =
adam@1500	169 mkShow (let
adam@1500	170 fun shower (t : tree t) =
adam@1500	171 case t of
adam@1500	172 Leaf x => "Leaf(" ^ show x ^ ")"
adam@1500	173 \| Node (t1, t2) => "Node(" ^ shower t1 ^ ", " ^ shower t2 ^ ")"
adam@1500	174 in
adam@1500	175 shower
adam@1500	176 end)
adam@1500	177 (* end *)
adam@1500	178
adam@1500	179 fun size [a] (t : tree a) : int =
adam@1500	180 case t of
adam@1500	181 Leaf _ => 1
adam@1500	182 \| Node (t1, t2) => size t1 + size t2
adam@1500	183
adam@1500	184 (* begin eval *)
adam@1500	185 size (Node (Leaf 0, Leaf 1))
adam@1500	186 (* end *)
adam@1500	187
adam@1500	188 (* begin eval *)
adam@1500	189 size (Node (Leaf 1.2, Node (Leaf 3.4, Leaf 4.5)))
adam@1500	190 (* end *)
adam@1500	191
adam@1500	192 fun tmap [a] [b] (f : a -> b) : tree a -> tree b =
adam@1500	193 let
adam@1500	194 fun loop (t : tree a) : tree b =
adam@1500	195 case t of
adam@1500	196 Leaf x => Leaf (f x)
adam@1500	197 \| Node (t1, t2) => Node (loop t1, loop t2)
adam@1500	198 in
adam@1500	199 loop
adam@1500	200 end
adam@1500	201
adam@1500	202 (* begin eval *)
adam@1500	203 tmap inc (Node (Leaf 0, Leaf 1))
adam@1500	204 (* end *)
adam@1500	205
adam@1501	206 (* We also have anonymous record types, as in Standard ML. The next chapter will show that there is quite a lot more going on here with records than in SML or OCaml, but we'll stick to the basics in this chapter. We will add one tantalizing hint of what's to come by demonstrating the record concatention operator <tt>++</tt> and the record field removal operator <tt>--</tt>. *)
adam@1500	207
adam@1500	208 val x = { A = 0, B = 1.2, C = "hi", D = True }
adam@1500	209
adam@1500	210 (* begin eval *)
adam@1500	211 x.A
adam@1500	212 (* end *)
adam@1500	213
adam@1500	214 (* begin eval *)
adam@1500	215 x.C
adam@1500	216 (* end *)
adam@1500	217
adam@1500	218 type myRecord = { A : int, B : float, C : string, D : bool }
adam@1500	219
adam@1500	220 fun getA (r : myRecord) = r.A
adam@1500	221
adam@1500	222 (* begin eval *)
adam@1500	223 getA x
adam@1500	224 (* end *)
adam@1500	225
adam@1500	226 (* begin eval *)
adam@1500	227 getA (x -- #A ++ {A = 4})
adam@1500	228 (* end *)
adam@1500	229
adam@1500	230 val y = { A = "uhoh", B = 2.3, C = "bye", D = False }
adam@1500	231
adam@1500	232 (* begin eval *)
adam@1500	233 getA (y -- #A ++ {A = 5})
adam@1500	234 (* end *)
adam@1501	235
adam@1501	236
adam@1501	237 (* * Borrowed from ML *)
adam@1501	238
adam@1502	239 (* Ur includes an ML-style <b>module system</b>. The most basic use case involves packaging abstract types with their "methods." *)
adam@1501	240
adam@1501	241 signature COUNTER = sig
adam@1501	242 type t
adam@1501	243 val zero : t
adam@1501	244 val increment : t -> t
adam@1501	245 val toInt : t -> int
adam@1501	246 end
adam@1501	247
adam@1501	248 structure Counter : COUNTER = struct
adam@1501	249 type t = int
adam@1502	250 val zero = 0
adam@1501	251 val increment = plus 1
adam@1501	252 fun toInt x = x
adam@1501	253 end
adam@1501	254
adam@1501	255 (* begin eval *)
adam@1501	256 Counter.toInt (Counter.increment Counter.zero)
adam@1501	257 (* end *)
adam@1501	258
adam@1502	259 (* We may package not just abstract types, but also abstract type families. Here we see our first use of the <tt>con</tt> keyword, which stands for <b>constructor</b>. Constructors are a generalization of types to include other "compile-time things"; for instance, basic type families, which are assigned the <b>kind</b> <tt>Type -> Type</tt>. Kinds are to constructors as types are to normal values. We also see how to write the type of a polymorphic function, using the <tt>:::</tt> syntax for type variable binding. This <tt>:::</tt> differs from the <tt>::</tt> used with the <tt>con</tt> keyword because it marks a type parameter as implicit, so that it need not be supplied explicitly at call sites. Such an option is the only one available in ML and Haskell, but, in the next chapter, we'll meet cases where it is appropriate to use explicit constructor parameters. *)
adam@1501	260
adam@1501	261 signature STACK = sig
adam@1501	262 con t :: Type -> Type
adam@1501	263 val empty : a ::: Type -> t a
adam@1501	264 val push : a ::: Type -> t a -> a -> t a
adam@1525	265 val peek : a ::: Type -> t a -> option a
adam@1525	266 val pop : a ::: Type -> t a -> option (t a)
adam@1501	267 end
adam@1501	268
adam@1501	269 structure Stack : STACK = struct
adam@1501	270 con t = list
adam@1501	271 val empty [a] = []
adam@1501	272 fun push [a] (t : t a) (x : a) = x :: t
adam@1525	273 fun peek [a] (t : t a) = case t of
adam@1525	274 [] => None
adam@1525	275 \| x :: _ => Some x
adam@1501	276 fun pop [a] (t : t a) = case t of
adam@1525	277 [] => None
adam@1525	278 \| _ :: t' => Some t'
adam@1501	279 end
adam@1501	280
adam@1501	281 (* begin eval *)
adam@1525	282 Stack.peek (Stack.push (Stack.push Stack.empty "A") "B")
adam@1501	283 (* end *)
adam@1501	284
adam@1501	285 (* Ur also inherits the ML concept of <b>functors</b>, which are functions from modules to modules. *)
adam@1501	286
adam@1501	287 datatype order = Less \| Equal \| Greater
adam@1501	288
adam@1501	289 signature COMPARABLE = sig
adam@1501	290 type t
adam@1501	291 val compare : t -> t -> order
adam@1501	292 end
adam@1501	293
adam@1501	294 signature DICTIONARY = sig
adam@1501	295 type key
adam@1501	296 con t :: Type -> Type
adam@1501	297 val empty : a ::: Type -> t a
adam@1501	298 val insert : a ::: Type -> t a -> key -> a -> t a
adam@1501	299 val lookup : a ::: Type -> t a -> key -> option a
adam@1501	300 end
adam@1501	301
adam@1501	302 functor BinarySearchTree(M : COMPARABLE) : DICTIONARY where type key = M.t = struct
adam@1501	303 type key = M.t
adam@1501	304 datatype t a = Leaf \| Node of t a * key * a * t a
adam@1501	305
adam@1501	306 val empty [a] = Leaf
adam@1501	307
adam@1501	308 fun insert [a] (t : t a) (k : key) (v : a) : t a =
adam@1501	309 case t of
adam@1501	310 Leaf => Node (Leaf, k, v, Leaf)
adam@1501	311 \| Node (left, k', v', right) =>
adam@1502	312 case M.compare k k' of
adam@1501	313 Equal => Node (left, k, v, right)
adam@1501	314 \| Less => Node (insert left k v, k', v', right)
adam@1501	315 \| Greater => Node (left, k', v', insert right k v)
adam@1501	316
adam@1501	317 fun lookup [a] (t : t a) (k : key) : option a =
adam@1501	318 case t of
adam@1501	319 Leaf => None
adam@1501	320 \| Node (left, k', v, right) =>
adam@1502	321 case M.compare k k' of
adam@1501	322 Equal => Some v
adam@1501	323 \| Less => lookup left k
adam@1501	324 \| Greater => lookup right k
adam@1501	325 end
adam@1501	326
adam@1501	327 structure IntTree = BinarySearchTree(struct
adam@1501	328 type t = int
adam@1501	329 fun compare n1 n2 =
adam@1501	330 if n1 = n2 then
adam@1501	331 Equal
adam@1501	332 else if n1 < n2 then
adam@1501	333 Less
adam@1501	334 else
adam@1501	335 Greater
adam@1501	336 end)
adam@1501	337
adam@1501	338 (* begin eval *)
adam@1501	339 IntTree.lookup (IntTree.insert (IntTree.insert IntTree.empty 0 "A") 1 "B") 1
adam@1501	340 (* end *)
adam@1501	341
adam@1501	342 (* It is sometimes handy to rebind modules to shorter names. *)
adam@1501	343
adam@1501	344 structure IT = IntTree
adam@1501	345
adam@1501	346 (* begin eval *)
adam@1501	347 IT.lookup (IT.insert (IT.insert IT.empty 0 "A") 1 "B") 0
adam@1501	348 (* end *)
adam@1501	349
adam@1501	350 (* One can even use the <tt>open</tt> command to import a module's namespace wholesale, though this can make it harder for someone reading code to tell which identifiers come from which modules. *)
adam@1501	351
adam@1501	352 open IT
adam@1501	353
adam@1501	354 (* begin eval *)
adam@1501	355 lookup (insert (insert empty 0 "A") 1 "B") 2
adam@1501	356 (* end *)
adam@1502	357
adam@1502	358 (* Ur adopts OCaml's approach to splitting projects across source files. When a project contains files <tt>foo.ur</tt> and <tt>foo.urs</tt>, these are taken as defining a module named <tt>Foo</tt> whose signature is drawn from <tt>foo.urs</tt> and whose implementation is drawn from <tt>foo.ur</tt>. If <tt>foo.ur</tt> exists without <tt>foo.urs</tt>, then module <tt>Foo</tt> is defined without an explicit signature, so that it is assigned its <b>principal signature</b>, which exposes all typing details without abstraction. *)
adam@1502	359
adam@1502	360
adam@1502	361 (* * Borrowed from Haskell *)
adam@1502	362
adam@1502	363 (* Ur includes a take on <b>type classes</b>. For instance, here is a generic "max" function that relies on a type class <tt>ord</tt>. Notice that the type class membership witness is treated like an ordinary function parameter, though we don't assign it a name here, because type inference figures out where it should be used. The more advanced examples of the next chapter will include cases where we manipulate type class witnesses explicitly. *)
adam@1502	364
adam@1502	365 fun max [a] (_ : ord a) (x : a) (y : a) : a =
adam@1502	366 if x < y then
adam@1502	367 y
adam@1502	368 else
adam@1502	369 x
adam@1502	370
adam@1502	371 (* begin eval *)
adam@1502	372 max 1 2
adam@1502	373 (* end *)
adam@1502	374
adam@1502	375 (* begin eval *)
adam@1502	376 max "ABC" "ABA"
adam@1502	377 (* end *)
adam@1502	378
adam@1502	379 (* The idiomatic way to define a new type class is to stash it inside a module, like in this example: *)
adam@1502	380
adam@1502	381 signature DOUBLE = sig
adam@1502	382 class double
adam@1502	383 val double : a ::: Type -> double a -> a -> a
adam@1502	384 val mkDouble : a ::: Type -> (a -> a) -> double a
adam@1502	385
adam@1502	386 val double_int : double int
adam@1502	387 val double_string : double string
adam@1502	388 end
adam@1502	389
adam@1502	390 structure Double : DOUBLE = struct
adam@1814	391 con double a = a -> a
adam@1502	392
adam@1502	393 fun double [a] (f : double a) (x : a) : a = f x
adam@1502	394 fun mkDouble [a] (f : a -> a) : double a = f
adam@1502	395
adam@1502	396 val double_int = mkDouble (times 2)
adam@1502	397 val double_string = mkDouble (fn s => s ^ s)
adam@1502	398 end
adam@1502	399
adam@1502	400 open Double
adam@1502	401
adam@1502	402 (* begin eval *)
adam@1502	403 double 13
adam@1502	404 (* end *)
adam@1502	405
adam@1502	406 (* begin eval *)
adam@1502	407 double "ho"
adam@1502	408 (* end *)
adam@1502	409
adam@1502	410 val double_float = mkDouble (times 2.0)
adam@1502	411
adam@1502	412 (* begin eval *)
adam@1502	413 double 2.3
adam@1502	414 (* end *)
adam@1502	415
adam@1502	416 (* That example had a mix of instances defined with a class and instances defined outside its module. Its possible to create <b>closed type classes</b> simply by omitting from the module an instance creation function like <tt>mkDouble</tt>. This way, only the instances you decide on may be allowed, which enables you to enforce program-wide invariants over instances. *)
adam@1502	417
adam@1502	418 signature OK_TYPE = sig
adam@1502	419 class ok
adam@1502	420 val importantOperation : a ::: Type -> ok a -> a -> string
adam@1502	421 val ok_int : ok int
adam@1502	422 val ok_float : ok float
adam@1502	423 end
adam@1502	424
adam@1502	425 structure OkType : OK_TYPE = struct
adam@1814	426 con ok a = unit
adam@1502	427 fun importantOperation [a] (_ : ok a) (_ : a) = "You found an OK value!"
adam@1502	428 val ok_int = ()
adam@1502	429 val ok_float = ()
adam@1502	430 end
adam@1502	431
adam@1502	432 open OkType
adam@1502	433
adam@1502	434 (* begin eval *)
adam@1502	435 importantOperation 13
adam@1502	436 (* end *)
adam@1502	437
adam@1502	438 (* Like Haskell, Ur supports the more general notion of <b>constructor classes</b>, whose instances may be parameterized over constructors with kinds beside <tt>Type</tt>. Also like in Haskell, the flagship constructor class is <tt>monad</tt>. Ur/Web's counterpart of Haskell's <tt>IO</tt> monad is <tt>transaction</tt>, which indicates the tight coupling with transactional execution in server-side code. Just as in Haskell, <tt>transaction</tt> must be used to create side-effecting actions, since Ur is purely functional (but has eager evaluation). Here is a quick example transaction, showcasing Ur's variation on Haskell <tt>do</tt> notation. *)
adam@1502	439
adam@1502	440 val readBack : transaction int =
adam@1502	441 src <- source 0;
adam@1502	442 set src 1;
adam@1502	443 n <- get src;
adam@1502	444 return (n + 1)
adam@1502	445
adam@1502	446 (* We get ahead of ourselves a bit here, as this example uses functions associated with client-side code to create and manipulate a mutable data source. *)

Mercurial > urweb

annotate doc/intro.ur @ 2278:b7615e0ac4b0