annotate lib/ur/list.ur @ 2013:77cc9169d6e0

Change context-local memory allocation to return word-aligned addresses (based on patch by Evan Danaher)
author Adam Chlipala <adam@chlipala.net>
date Sun, 18 May 2014 18:58:50 -0400
parents 146ec8e90063
children d9f918b79b5a
rev   line source
adamc@794 1 datatype t = datatype Basis.list
adamc@794 2
adamc@826 3 val show = fn [a] (_ : show a) =>
adamc@826 4 let
adamc@826 5 fun show' (ls : list a) =
adamc@826 6 case ls of
adamc@826 7 [] => "[]"
adamc@826 8 | x :: ls => show x ^ " :: " ^ show' ls
adamc@826 9 in
adamc@826 10 mkShow show'
adamc@826 11 end
adamc@794 12
adamc@846 13 val eq = fn [a] (_ : eq a) =>
adamc@846 14 let
adamc@846 15 fun eq' (ls1 : list a) ls2 =
adamc@846 16 case (ls1, ls2) of
adamc@846 17 ([], []) => True
adamc@846 18 | (x1 :: ls1, x2 :: ls2) => x1 = x2 && eq' ls1 ls2
adamc@846 19 | _ => False
adamc@846 20 in
adamc@846 21 mkEq eq'
adamc@846 22 end
adamc@846 23
adamc@1057 24 fun foldl [a] [b] (f : a -> b -> b) =
adamc@845 25 let
adamc@845 26 fun foldl' acc ls =
adamc@845 27 case ls of
adamc@845 28 [] => acc
adamc@845 29 | x :: ls => foldl' (f x acc) ls
adamc@845 30 in
adamc@845 31 foldl'
adamc@845 32 end
adamc@845 33
adamc@1057 34 val rev = fn [a] =>
adamc@1057 35 let
adamc@1057 36 fun rev' acc (ls : list a) =
adamc@1057 37 case ls of
adamc@1057 38 [] => acc
adamc@1057 39 | x :: ls => rev' (x :: acc) ls
adamc@1057 40 in
adamc@1057 41 rev' []
adamc@1057 42 end
adamc@1057 43
adamc@1057 44 fun foldr [a] [b] f (acc : b) (ls : list a) = foldl f acc (rev ls)
adamc@1057 45
adamc@850 46 fun foldlAbort [a] [b] f =
adamc@846 47 let
adamc@850 48 fun foldlAbort' acc ls =
adamc@846 49 case ls of
adamc@846 50 [] => Some acc
adamc@846 51 | x :: ls =>
adamc@846 52 case f x acc of
adamc@846 53 None => None
adamc@850 54 | Some acc' => foldlAbort' acc' ls
adamc@846 55 in
adamc@850 56 foldlAbort'
adamc@846 57 end
adamc@846 58
adamc@916 59 val length = fn [a] =>
adamc@916 60 let
adamc@916 61 fun length' acc (ls : list a) =
adamc@916 62 case ls of
adamc@916 63 [] => acc
adamc@916 64 | _ :: ls => length' (acc + 1) ls
adamc@916 65 in
adamc@916 66 length' 0
adamc@916 67 end
adamc@916 68
adamc@850 69 fun foldlMapAbort [a] [b] [c] f =
adamc@850 70 let
adamc@850 71 fun foldlMapAbort' ls' acc ls =
adamc@850 72 case ls of
adamc@850 73 [] => Some (rev ls', acc)
adamc@850 74 | x :: ls =>
adamc@850 75 case f x acc of
adamc@850 76 None => None
adamc@850 77 | Some (x', acc') => foldlMapAbort' (x' :: ls') acc' ls
adamc@850 78 in
adamc@850 79 foldlMapAbort' []
adamc@850 80 end
adamc@850 81
adamc@826 82 val revAppend = fn [a] =>
adamc@826 83 let
adamc@826 84 fun ra (ls : list a) acc =
adamc@826 85 case ls of
adamc@826 86 [] => acc
adamc@826 87 | x :: ls => ra ls (x :: acc)
adamc@826 88 in
adamc@826 89 ra
adamc@826 90 end
adamc@821 91
adamc@826 92 fun append [a] (ls1 : t a) (ls2 : t a) = revAppend (rev ls1) ls2
adamc@821 93
adamc@826 94 fun mp [a] [b] f =
adamc@794 95 let
adamc@794 96 fun mp' acc ls =
adamc@794 97 case ls of
adamc@794 98 [] => rev acc
adamc@794 99 | x :: ls => mp' (f x :: acc) ls
adamc@794 100 in
adamc@794 101 mp' []
adamc@794 102 end
adamc@796 103
adamc@1279 104 fun mapi [a] [b] f =
adamc@1279 105 let
adamc@1279 106 fun mp' n acc ls =
adamc@1279 107 case ls of
adamc@1279 108 [] => rev acc
adamc@1279 109 | x :: ls => mp' (n + 1) (f n x :: acc) ls
adamc@1279 110 in
adamc@1279 111 mp' 0 []
adamc@1279 112 end
adamc@1279 113
adamc@826 114 fun mapPartial [a] [b] f =
adamc@821 115 let
adamc@821 116 fun mp' acc ls =
adamc@821 117 case ls of
adamc@821 118 [] => rev acc
adamc@821 119 | x :: ls => mp' (case f x of
adamc@821 120 None => acc
adamc@821 121 | Some y => y :: acc) ls
adamc@821 122 in
adamc@821 123 mp' []
adamc@821 124 end
adamc@821 125
adamc@826 126 fun mapX [a] [ctx ::: {Unit}] f =
adamc@796 127 let
adamc@796 128 fun mapX' ls =
adamc@796 129 case ls of
adamc@796 130 [] => <xml/>
adamc@796 131 | x :: ls => <xml>{f x}{mapX' ls}</xml>
adamc@796 132 in
adamc@796 133 mapX'
adamc@796 134 end
adamc@800 135
adam@1539 136 fun mapXi [a] [ctx ::: {Unit}] f =
adam@1539 137 let
adam@1539 138 fun mapX' i ls =
adam@1539 139 case ls of
adam@1539 140 [] => <xml/>
adam@1539 141 | x :: ls => <xml>{f i x}{mapX' (i + 1) ls}</xml>
adam@1539 142 in
adam@1539 143 mapX' 0
adam@1539 144 end
adam@1539 145
adamc@826 146 fun mapM [m ::: (Type -> Type)] (_ : monad m) [a] [b] f =
adamc@800 147 let
adamc@800 148 fun mapM' acc ls =
adamc@800 149 case ls of
adamc@818 150 [] => return (rev acc)
adamc@818 151 | x :: ls => x' <- f x; mapM' (x' :: acc) ls
adamc@800 152 in
adamc@818 153 mapM' []
adamc@800 154 end
adamc@821 155
adamc@1107 156 fun mapPartialM [m ::: (Type -> Type)] (_ : monad m) [a] [b] f =
adamc@1107 157 let
adamc@1107 158 fun mapPartialM' acc ls =
adamc@1107 159 case ls of
adamc@1107 160 [] => return (rev acc)
adamc@1107 161 | x :: ls =>
adamc@1107 162 v <- f x;
adamc@1107 163 mapPartialM' (case v of
adamc@1107 164 None => acc
adamc@1107 165 | Some x' => x' :: acc) ls
adamc@1107 166 in
adamc@1107 167 mapPartialM' []
adamc@1107 168 end
adamc@1107 169
adamc@830 170 fun mapXM [m ::: (Type -> Type)] (_ : monad m) [a] [ctx ::: {Unit}] f =
adamc@830 171 let
adamc@830 172 fun mapXM' ls =
adamc@830 173 case ls of
adamc@830 174 [] => return <xml/>
adamc@830 175 | x :: ls =>
adamc@830 176 this <- f x;
adamc@830 177 rest <- mapXM' ls;
adamc@830 178 return <xml>{this}{rest}</xml>
adamc@830 179 in
adamc@830 180 mapXM'
adamc@830 181 end
adamc@830 182
adamc@826 183 fun filter [a] f =
adamc@821 184 let
adamc@821 185 fun fil acc ls =
adamc@821 186 case ls of
adamc@821 187 [] => rev acc
adamc@821 188 | x :: ls => fil (if f x then x :: acc else acc) ls
adamc@821 189 in
adamc@821 190 fil []
adamc@821 191 end
adamc@822 192
adamc@826 193 fun exists [a] f =
adamc@822 194 let
adamc@822 195 fun ex ls =
adamc@822 196 case ls of
adamc@822 197 [] => False
adamc@822 198 | x :: ls =>
adamc@822 199 if f x then
adamc@822 200 True
adamc@822 201 else
adamc@822 202 ex ls
adamc@822 203 in
adamc@822 204 ex
adamc@822 205 end
adamc@822 206
adamc@826 207 fun foldlMap [a] [b] [c] f =
adamc@822 208 let
adamc@822 209 fun fold ls' st ls =
adamc@822 210 case ls of
adamc@822 211 [] => (rev ls', st)
adamc@822 212 | x :: ls =>
adamc@822 213 case f x st of
adamc@822 214 (y, st) => fold (y :: ls') st ls
adamc@822 215 in
adamc@822 216 fold []
adamc@822 217 end
adamc@839 218
adam@1519 219 fun find [a] f =
adam@1519 220 let
adam@1519 221 fun find' ls =
adam@1519 222 case ls of
adam@1519 223 [] => None
adam@1519 224 | x :: ls =>
adam@1519 225 if f x then
adam@1519 226 Some x
adam@1519 227 else
adam@1519 228 find' ls
adam@1519 229 in
adam@1519 230 find'
adam@1519 231 end
adam@1519 232
adamc@839 233 fun search [a] [b] f =
adamc@839 234 let
adamc@839 235 fun search' ls =
adamc@839 236 case ls of
adamc@839 237 [] => None
adamc@839 238 | x :: ls =>
adamc@839 239 case f x of
adamc@839 240 None => search' ls
adamc@839 241 | v => v
adamc@839 242 in
adamc@839 243 search'
adamc@839 244 end
adamc@839 245
adamc@840 246 fun foldlM [m] (_ : monad m) [a] [b] f =
adamc@840 247 let
adamc@840 248 fun foldlM' acc ls =
adamc@840 249 case ls of
adamc@840 250 [] => return acc
adamc@840 251 | x :: ls =>
adamc@840 252 acc <- f x acc;
adamc@840 253 foldlM' acc ls
adamc@840 254 in
adamc@840 255 foldlM'
adamc@840 256 end
adamc@843 257
adam@1547 258 fun foldlMi [m] (_ : monad m) [a] [b] f =
adam@1547 259 let
adam@1547 260 fun foldlMi' i acc ls =
adam@1547 261 case ls of
adam@1547 262 [] => return acc
adam@1547 263 | x :: ls =>
adam@1547 264 acc <- f i x acc;
adam@1547 265 foldlMi' (i + 1) acc ls
adam@1547 266 in
adam@1547 267 foldlMi' 0
adam@1547 268 end
adam@1547 269
adam@1634 270 fun filterM [m] (_ : monad m) [a] (p : a -> m bool) =
adam@1634 271 let
adam@1634 272 fun filterM' (acc : list a) (xs : list a) : m (list a) =
adam@1634 273 case xs of
adam@1634 274 [] => return (rev acc)
adam@1634 275 | x :: xs =>
adam@1634 276 c <- p x;
adam@1634 277 filterM' (if c then x :: acc else acc) xs
adam@1634 278 in
adam@1634 279 filterM' []
adam@1634 280 end
adam@1634 281
adamc@843 282 fun all [m] f =
adamc@843 283 let
adamc@843 284 fun all' ls =
adamc@843 285 case ls of
adamc@843 286 [] => True
adamc@843 287 | x :: ls => f x && all' ls
adamc@843 288 in
adamc@843 289 all'
adamc@843 290 end
adamc@844 291
adamc@844 292 fun app [m] (_ : monad m) [a] f =
adamc@844 293 let
adamc@844 294 fun app' ls =
adamc@844 295 case ls of
adamc@844 296 [] => return ()
adamc@844 297 | x :: ls =>
adamc@844 298 f x;
adamc@844 299 app' ls
adamc@844 300 in
adamc@844 301 app'
adamc@844 302 end
adamc@845 303
adamc@908 304 fun mapQuery [tables ::: {{Type}}] [exps ::: {Type}] [t ::: Type]
adam@1394 305 [tables ~ exps] (q : sql_query [] [] tables exps)
adamc@908 306 (f : $(exps ++ map (fn fields :: {Type} => $fields) tables) -> t) =
adamc@995 307 ls <- query q
adamc@995 308 (fn fs acc => return (f fs :: acc))
adamc@995 309 [];
adamc@995 310 return (rev ls)
adamc@908 311
adamc@1107 312 fun mapQueryM [tables ::: {{Type}}] [exps ::: {Type}] [t ::: Type]
adam@1394 313 [tables ~ exps] (q : sql_query [] [] tables exps)
adamc@1107 314 (f : $(exps ++ map (fn fields :: {Type} => $fields) tables) -> transaction t) =
adamc@1107 315 ls <- query q
adamc@1107 316 (fn fs acc => v <- f fs; return (v :: acc))
adamc@1107 317 [];
adamc@1107 318 return (rev ls)
adamc@1107 319
adamc@1107 320 fun mapQueryPartialM [tables ::: {{Type}}] [exps ::: {Type}] [t ::: Type]
adam@1394 321 [tables ~ exps] (q : sql_query [] [] tables exps)
adamc@1107 322 (f : $(exps ++ map (fn fields :: {Type} => $fields) tables) -> transaction (option t)) =
adamc@1107 323 ls <- query q
adamc@1107 324 (fn fs acc => v <- f fs;
adamc@1107 325 return (case v of
adamc@1107 326 None => acc
adamc@1107 327 | Some v => v :: acc))
adamc@1107 328 [];
adamc@1107 329 return (rev ls)
adamc@1107 330
adam@1321 331 fun sort [a] (gt : a -> a -> bool) (ls : t a) : t a =
adam@1321 332 let
adam@1321 333 fun split ls acc1 acc2 =
adam@1321 334 case ls of
adam@1321 335 [] => (rev acc1, rev acc2)
adam@1321 336 | x :: [] => (rev (x :: acc1), rev acc2)
adam@1321 337 | x1 :: x2 :: ls' => split ls' (x1 :: acc1) (x2 :: acc2)
adam@1321 338
adam@1321 339 fun merge ls1 ls2 acc =
adam@1321 340 case (ls1, ls2) of
adam@1321 341 ([], _) => revAppend acc ls2
adam@1321 342 | (_, []) => revAppend acc ls1
adam@1321 343 | (x1 :: ls1', x2 :: ls2') => if gt x1 x2 then merge ls1 ls2' (x2 :: acc) else merge ls1' ls2 (x1 :: acc)
adam@1321 344
adam@1321 345 fun sort' ls =
adam@1321 346 case ls of
adam@1321 347 [] => ls
adam@1321 348 | _ :: [] => ls
adam@1321 349 | _ =>
adam@1321 350 let
adam@1321 351 val (ls1, ls2) = split ls [] []
adam@1321 352 in
adam@1321 353 merge (sort' ls1) (sort' ls2) []
adam@1321 354 end
adam@1321 355 in
adam@1321 356 sort' ls
adam@1321 357 end
adam@1321 358
adam@1322 359 val nth [a] =
adam@1322 360 let
adam@1322 361 fun nth (ls : list a) (n : int) : option a =
adam@1322 362 case ls of
adam@1322 363 [] => None
adam@1322 364 | x :: ls' =>
adam@1322 365 if n <= 0 then
adam@1322 366 Some x
adam@1322 367 else
adam@1322 368 nth ls' (n-1)
adam@1322 369 in
adam@1322 370 nth
adam@1322 371 end
adam@1322 372
adam@1345 373 fun replaceNth [a] (ls : list a) (n : int) (v : a) : list a =
adam@1345 374 let
adam@1345 375 fun repNth (ls : list a) (n : int) (acc : list a) =
adam@1345 376 case ls of
adam@1345 377 [] => rev acc
adam@1345 378 | x :: ls' => if n <= 0 then
adam@1345 379 revAppend acc (v :: ls')
adam@1345 380 else
adam@1345 381 repNth ls' (n-1) (x :: acc)
adam@1345 382 in
adam@1345 383 repNth ls n []
adam@1345 384 end
adam@1345 385
adamc@845 386 fun assoc [a] [b] (_ : eq a) (x : a) =
adamc@845 387 let
adamc@845 388 fun assoc' (ls : list (a * b)) =
adamc@845 389 case ls of
adamc@845 390 [] => None
adamc@845 391 | (y, z) :: ls =>
adamc@845 392 if x = y then
adamc@845 393 Some z
adamc@845 394 else
adamc@845 395 assoc' ls
adamc@845 396 in
adamc@845 397 assoc'
adamc@845 398 end
adamc@845 399
adamc@845 400 fun assocAdd [a] [b] (_ : eq a) (x : a) (y : b) (ls : t (a * b)) =
adamc@845 401 case assoc x ls of
adamc@845 402 None => (x, y) :: ls
adamc@845 403 | Some _ => ls
greenrd@1481 404
greenrd@1481 405 fun recToList [a ::: Type] [r ::: {Unit}] (fl : folder r)
greenrd@1481 406 = @foldUR [a] [fn _ => list a] (fn [nm ::_] [rest ::_] [[nm] ~ rest] x xs =>
greenrd@1481 407 x :: xs) [] fl
adam@1634 408
adam@1634 409 fun take [a] (n : int) (xs : list a) : list a =
adam@1634 410 if n <= 0 then
adam@1634 411 []
adam@1634 412 else
adam@1634 413 case xs of
adam@1634 414 [] => []
adam@1634 415 | x :: xs => x :: take (n-1) xs
adam@1634 416
adam@1634 417 fun drop [a] (n : int) (xs : list a) : list a =
adam@1634 418 if n <= 0 then
adam@1634 419 xs
adam@1634 420 else
adam@1634 421 case xs of
adam@1634 422 [] => []
adam@1634 423 | x :: xs => drop (n-1) xs
adam@1634 424
adam@1634 425 fun splitAt [a] (n : int) (xs : list a) : list a * list a =
adam@1634 426 (take n xs, drop n xs)
adam@1768 427
adam@1768 428 fun mapXiM [m ::: Type -> Type] (_ : monad m) [a] [ctx ::: {Unit}] (f : int -> a -> m (xml ctx [] [])) : t a -> m (xml ctx [] []) =
adam@1768 429 let
adam@1768 430 fun mapXiM' i ls =
adam@1768 431 case ls of
adam@1768 432 [] => return <xml/>
adam@1768 433 | x :: ls =>
adam@1768 434 this <- f i x;
adam@1768 435 rest <- mapXiM' (i+1) ls;
adam@1768 436 return <xml>{this}{rest}</xml>
adam@1768 437 in
adam@1768 438 mapXiM' 0
adam@1768 439 end
adam@1840 440
adam@1840 441 fun tabulateM [m] (_ : monad m) [a] (f : int -> m a) n =
adam@1840 442 let
adam@1840 443 fun tabulate' n acc =
adam@1840 444 if n <= 0 then
adam@1840 445 return acc
adam@1840 446 else
adam@1840 447 (v <- f (n-1);
adam@1840 448 tabulate' (n-1) (v :: acc))
adam@1840 449 in
adam@1840 450 tabulate' n []
adam@1840 451 end