wneuper/isa: src/Pure/library.ML@471b576aad25 (annotated)

wenzelm@41	1	(* Title: Pure/library.ML
clasohm@0	2	ID: $Id$
wenzelm@233	3	Author: Lawrence C Paulson, Cambridge University Computer Laboratory
wenzelm@16188	4	Author: Markus Wenzel, TU Muenchen
clasohm@0	5
wenzelm@233	6	Basic library: functions, options, pairs, booleans, lists, integers,
haftmann@19596	7	strings, lists as sets, balanced trees, orders, current directory, misc.
wenzelm@21395	8
wenzelm@21395	9	See also General/basics.ML for the most fundamental concepts.
clasohm@0	10	*)
clasohm@0	11
wenzelm@21395	12	infix 1 \|>>>
wenzelm@21395	13	infix 2 ?
wenzelm@21395	14	infix 3 o oo ooo oooo
wenzelm@21395	15	infix 4 ~~ upto downto
haftmann@20854	16	infix orf andf \ \\ mem mem_int mem_string union union_int
wenzelm@21395	17	union_string inter inter_int inter_string subset subset_int subset_string
wenzelm@5893	18
wenzelm@15745	19	signature BASIC_LIBRARY =
wenzelm@4621	20	sig
wenzelm@4621	21	(functions)
wenzelm@16842	22	val I: 'a -> 'a
wenzelm@16842	23	val K: 'a -> 'b -> 'a
wenzelm@23220	24	val flip: ('a -> 'b -> 'c) -> 'b -> 'a -> 'c
wenzelm@4621	25	val curry: ('a * 'b -> 'c) -> 'a -> 'b -> 'c
wenzelm@4621	26	val uncurry: ('a -> 'b -> 'c) -> 'a * 'b -> 'c
haftmann@21335	27	val \|>>> : ('a * 'c) * ('a -> 'b * 'd) -> 'b * ('c * 'd)
wenzelm@21565	28	val ? : bool * ('a -> 'a) -> 'a -> 'a
wenzelm@16721	29	val oo: ('a -> 'b) * ('c -> 'd -> 'a) -> 'c -> 'd -> 'b
wenzelm@16721	30	val ooo: ('a -> 'b) * ('c -> 'd -> 'e -> 'a) -> 'c -> 'd -> 'e -> 'b
wenzelm@16721	31	val oooo: ('a -> 'b) * ('c -> 'd -> 'e -> 'f -> 'a) -> 'c -> 'd -> 'e -> 'f -> 'b
wenzelm@16842	32	val funpow: int -> ('a -> 'a) -> 'a -> 'a
clasohm@1364	33
wenzelm@18681	34	(exceptions)
wenzelm@18681	35	exception EXCEPTION of exn * string
wenzelm@18681	36	val do_transform_failure: bool ref
wenzelm@18681	37	val transform_failure: (exn -> exn) -> ('a -> 'b) -> 'a -> 'b
wenzelm@14868	38	datatype 'a result = Result of 'a \| Exn of exn
wenzelm@14868	39	val capture: ('a -> 'b) -> 'a -> 'b result
wenzelm@14868	40	val release: 'a result -> 'a
wenzelm@14868	41	val get_result: 'a result -> 'a option
wenzelm@14868	42	val get_exn: 'a result -> exn option
wenzelm@4621	43
wenzelm@18681	44	(errors)
wenzelm@19542	45	exception SYS_ERROR of string
wenzelm@19542	46	val sys_error: string -> 'a
wenzelm@18681	47	exception ERROR of string
wenzelm@18681	48	val error: string -> 'a
wenzelm@18681	49	val cat_error: string -> string -> 'a
wenzelm@18681	50	val assert_all: ('a -> bool) -> 'a list -> ('a -> string) -> unit
wenzelm@18681	51
wenzelm@4621	52	(pairs)
wenzelm@4621	53	val pair: 'a -> 'b -> 'a * 'b
wenzelm@4621	54	val rpair: 'a -> 'b -> 'b * 'a
wenzelm@4621	55	val fst: 'a * 'b -> 'a
wenzelm@4621	56	val snd: 'a * 'b -> 'b
haftmann@17498	57	val eq_fst: ('a * 'c -> bool) -> ('a * 'b) * ('c * 'd) -> bool
haftmann@17498	58	val eq_snd: ('b * 'd -> bool) -> ('a * 'b) * ('c * 'd) -> bool
haftmann@19454	59	val eq_pair: ('a * 'c -> bool) -> ('b * 'd -> bool) -> ('a * 'b) * ('c * 'd) -> bool
wenzelm@4621	60	val swap: 'a * 'b -> 'b * 'a
wenzelm@4621	61	val apfst: ('a -> 'b) -> 'a * 'c -> 'b * 'c
wenzelm@4621	62	val apsnd: ('a -> 'b) -> 'c * 'a -> 'c * 'b
wenzelm@4621	63	val pairself: ('a -> 'b) -> 'a * 'a -> 'b * 'b
wenzelm@4621	64
wenzelm@4621	65	(booleans)
wenzelm@4621	66	val equal: ''a -> ''a -> bool
wenzelm@4621	67	val not_equal: ''a -> ''a -> bool
wenzelm@4621	68	val orf: ('a -> bool) * ('a -> bool) -> 'a -> bool
wenzelm@4621	69	val andf: ('a -> bool) * ('a -> bool) -> 'a -> bool
wenzelm@4621	70	val exists: ('a -> bool) -> 'a list -> bool
wenzelm@4621	71	val forall: ('a -> bool) -> 'a list -> bool
wenzelm@4621	72	val set: bool ref -> bool
wenzelm@4621	73	val reset: bool ref -> bool
wenzelm@4621	74	val toggle: bool ref -> bool
wenzelm@9118	75	val change: 'a ref -> ('a -> 'a) -> unit
wenzelm@4621	76	val setmp: 'a ref -> 'a -> ('b -> 'c) -> 'b -> 'c
wenzelm@4621	77
wenzelm@4621	78	(lists)
skalberg@15570	79	exception UnequalLengths
wenzelm@5285	80	val single: 'a -> 'a list
wenzelm@20882	81	val the_single: 'a list -> 'a
wenzelm@19273	82	val singleton: ('a list -> 'b list) -> 'a -> 'b
wenzelm@5904	83	val apply: ('a -> 'a) list -> 'a -> 'a
haftmann@18278	84	val foldr1: ('a * 'a -> 'a) -> 'a list -> 'a
wenzelm@4956	85	val foldl_map: ('a * 'b -> 'a * 'c) -> 'a * 'b list -> 'a * 'c list
wenzelm@19461	86	val flat: 'a list list -> 'a list
wenzelm@19424	87	val unflat: 'a list list -> 'b list -> 'b list list
haftmann@18441	88	val burrow: ('a list -> 'b list) -> 'a list list -> 'b list list
haftmann@18549	89	val fold_burrow: ('a list -> 'c -> 'b list * 'd) -> 'a list list -> 'c -> 'b list list * 'd
wenzelm@21395	90	val maps: ('a -> 'b list) -> 'a list -> 'b list
wenzelm@19011	91	val chop: int -> 'a list -> 'a list * 'a list
nipkow@4713	92	val dropwhile: ('a -> bool) -> 'a list -> 'a list
haftmann@18278	93	val nth: 'a list -> int -> 'a
haftmann@18011	94	val nth_map: int -> ('a -> 'a) -> 'a list -> 'a list
wenzelm@18286	95	val nth_list: 'a list list -> int -> 'a list
haftmann@18514	96	val map_index: (int * 'a -> 'b) -> 'a list -> 'b list
haftmann@18514	97	val fold_index: (int * 'a -> 'b -> 'b) -> 'a list -> 'b -> 'b
wenzelm@4621	98	val split_last: 'a list -> 'a list * 'a
wenzelm@4621	99	val find_index: ('a -> bool) -> 'a list -> int
wenzelm@4621	100	val find_index_eq: ''a -> ''a list -> int
wenzelm@4621	101	val find_first: ('a -> bool) -> 'a list -> 'a option
haftmann@19233	102	val get_index: ('a -> 'b option) -> 'a list -> (int * 'b) option
wenzelm@4916	103	val get_first: ('a -> 'b option) -> 'a list -> 'b option
haftmann@19454	104	val eq_list: ('a * 'b -> bool) -> 'a list * 'b list -> bool
haftmann@18330	105	val map2: ('a -> 'b -> 'c) -> 'a list -> 'b list -> 'c list
haftmann@18330	106	val fold2: ('a -> 'b -> 'c -> 'c) -> 'a list -> 'b list -> 'c -> 'c
wenzelm@19799	107	val zip_options: 'a list -> 'b option list -> ('a * 'b) list
haftmann@18330	108	val ~~ : 'a list * 'b list -> ('a * 'b) list
haftmann@18330	109	val split_list: ('a * 'b) list -> 'a list * 'b list
wenzelm@4621	110	val separate: 'a -> 'a list -> 'a list
wenzelm@4621	111	val replicate: int -> 'a -> 'a list
wenzelm@18148	112	val multiply: 'a list -> 'a list list -> 'a list list
wenzelm@14792	113	val product: 'a list -> 'b list -> ('a * 'b) list
wenzelm@16129	114	val filter: ('a -> bool) -> 'a list -> 'a list
wenzelm@4621	115	val filter_out: ('a -> bool) -> 'a list -> 'a list
wenzelm@19483	116	val map_filter: ('a -> 'b option) -> 'a list -> 'b list
haftmann@18441	117	val is_prefix: ('a * 'a -> bool) -> 'a list -> 'a list -> bool
wenzelm@4621	118	val take_prefix: ('a -> bool) -> 'a list -> 'a list * 'a list
haftmann@20108	119	val chop_prefix: ('a * 'b -> bool) -> 'a list * 'b list -> 'a list * ('a list * 'b list)
wenzelm@4621	120	val take_suffix: ('a -> bool) -> 'a list -> 'a list * 'a list
wenzelm@12249	121	val prefixes1: 'a list -> 'a list list
wenzelm@19011	122	val prefixes: 'a list -> 'a list list
wenzelm@12249	123	val suffixes1: 'a list -> 'a list list
wenzelm@19011	124	val suffixes: 'a list -> 'a list list
wenzelm@4621	125
wenzelm@4621	126	(integers)
wenzelm@4621	127	val inc: int ref -> int
wenzelm@4621	128	val dec: int ref -> int
wenzelm@4621	129	val upto: int * int -> int list
wenzelm@4621	130	val downto: int * int -> int list
wenzelm@4621	131	val radixpand: int * int -> int list
wenzelm@4621	132	val radixstring: int * string * int -> string
wenzelm@4621	133	val string_of_int: int -> string
wenzelm@21942	134	val signed_string_of_int: int -> string
wenzelm@4621	135	val string_of_indexname: string * int -> string
wenzelm@20095	136	val read_intinf: int -> string list -> IntInf.int * string list
wenzelm@14826	137	val read_int: string list -> int * string list
wenzelm@14826	138	val oct_char: string -> string
wenzelm@4621	139
wenzelm@4621	140	(strings)
haftmann@18011	141	val nth_string: string -> int -> string
wenzelm@16188	142	val fold_string: (string -> 'a -> 'a) -> string -> 'a -> 'a
wenzelm@6312	143	val exists_string: (string -> bool) -> string -> bool
wenzelm@16188	144	val forall_string: (string -> bool) -> string -> bool
wenzelm@4621	145	val enclose: string -> string -> string -> string
wenzelm@6642	146	val unenclose: string -> string
wenzelm@4621	147	val quote: string -> string
wenzelm@4621	148	val space_implode: string -> string list -> string
wenzelm@4621	149	val commas: string list -> string
wenzelm@4621	150	val commas_quote: string list -> string
wenzelm@4621	151	val cat_lines: string list -> string
wenzelm@4621	152	val space_explode: string -> string -> string list
wenzelm@14826	153	val split_lines: string -> string list
wenzelm@5942	154	val prefix_lines: string -> string -> string
wenzelm@7712	155	val untabify: string list -> string list
wenzelm@18681	156	val prefix: string -> string -> string
wenzelm@5285	157	val suffix: string -> string -> string
wenzelm@18681	158	val unprefix: string -> string -> string
wenzelm@5285	159	val unsuffix: string -> string -> string
wenzelm@10951	160	val replicate_string: int -> string -> string
wenzelm@14926	161	val translate_string: (string -> string) -> string -> string
wenzelm@4621	162
wenzelm@16492	163	(lists as sets -- see also Pure/General/ord_list.ML)
wenzelm@18923	164	val member: ('b * 'a -> bool) -> 'a list -> 'b -> bool
wenzelm@18923	165	val insert: ('a * 'a -> bool) -> 'a -> 'a list -> 'a list
wenzelm@18923	166	val remove: ('b * 'a -> bool) -> 'b -> 'a list -> 'a list
wenzelm@19301	167	val subtract: ('b * 'a -> bool) -> 'b list -> 'a list -> 'a list
wenzelm@18923	168	val merge: ('a * 'a -> bool) -> 'a list * 'a list -> 'a list
wenzelm@4621	169	val mem: ''a * ''a list -> bool
wenzelm@4621	170	val mem_int: int * int list -> bool
wenzelm@4621	171	val mem_string: string * string list -> bool
wenzelm@4621	172	val union: ''a list * ''a list -> ''a list
wenzelm@4621	173	val union_int: int list * int list -> int list
wenzelm@4621	174	val union_string: string list * string list -> string list
wenzelm@4621	175	val gen_union: ('a * 'a -> bool) -> 'a list * 'a list -> 'a list
paulson@7090	176	val gen_inter: ('a * 'b -> bool) -> 'a list * 'b list -> 'a list
wenzelm@4621	177	val inter: ''a list * ''a list -> ''a list
wenzelm@4621	178	val inter_int: int list * int list -> int list
wenzelm@4621	179	val inter_string: string list * string list -> string list
wenzelm@4621	180	val subset: ''a list * ''a list -> bool
wenzelm@4621	181	val subset_int: int list * int list -> bool
wenzelm@4621	182	val subset_string: string list * string list -> bool
wenzelm@4621	183	val eq_set: ''a list * ''a list -> bool
wenzelm@4621	184	val eq_set_string: string list * string list -> bool
wenzelm@4621	185	val gen_subset: ('a * 'b -> bool) -> 'a list * 'b list -> bool
wenzelm@19301	186	val gen_eq_set: ('a * 'b -> bool) -> 'a list * 'b list -> bool
wenzelm@4621	187	val \ : ''a list * ''a -> ''a list
wenzelm@4621	188	val \\ : ''a list * ''a list -> ''a list
wenzelm@19046	189	val distinct: ('a * 'a -> bool) -> 'a list -> 'a list
wenzelm@18966	190	val duplicates: ('a * 'a -> bool) -> 'a list -> 'a list
wenzelm@16878	191	val has_duplicates: ('a * 'a -> bool) -> 'a list -> bool
wenzelm@4621	192
wenzelm@23220	193	(lists as multisets)
nipkow@22142	194	val remove1: ('b * 'a -> bool) -> 'b -> 'a list -> 'a list
wenzelm@23220	195	val submultiset: ('a * 'b -> bool) -> 'a list * 'b list -> bool
wenzelm@4621	196
wenzelm@4621	197	(balanced trees)
wenzelm@4621	198	exception Balance
wenzelm@4621	199	val fold_bal: ('a * 'a -> 'a) -> 'a list -> 'a
wenzelm@4621	200	val access_bal: ('a -> 'a) * ('a -> 'a) * 'a -> int -> int -> 'a
wenzelm@4621	201	val accesses_bal: ('a -> 'a) * ('a -> 'a) * 'a -> int -> 'a list
wenzelm@4621	202
wenzelm@4621	203	(orders)
wenzelm@18966	204	val is_equal: order -> bool
wenzelm@4621	205	val rev_order: order -> order
wenzelm@4621	206	val make_ord: ('a * 'a -> bool) -> 'a * 'a -> order
wenzelm@4621	207	val int_ord: int * int -> order
wenzelm@4621	208	val string_ord: string * string -> order
wenzelm@16676	209	val fast_string_ord: string * string -> order
wenzelm@16492	210	val option_ord: ('a * 'b -> order) -> 'a option * 'b option -> order
wenzelm@4621	211	val prod_ord: ('a * 'b -> order) -> ('c * 'd -> order) -> ('a * 'c) * ('b * 'd) -> order
wenzelm@4621	212	val dict_ord: ('a * 'b -> order) -> 'a list * 'b list -> order
wenzelm@4621	213	val list_ord: ('a * 'b -> order) -> 'a list * 'b list -> order
wenzelm@4621	214	val sort: ('a * 'a -> order) -> 'a list -> 'a list
wenzelm@18427	215	val sort_distinct: ('a * 'a -> order) -> 'a list -> 'a list
wenzelm@4621	216	val sort_strings: string list -> string list
wenzelm@4621	217	val sort_wrt: ('a -> string) -> 'a list -> 'a list
wenzelm@4621	218
berghofe@14106	219	(random numbers)
berghofe@14106	220	exception RANDOM
berghofe@14106	221	val random: unit -> real
berghofe@14106	222	val random_range: int -> int -> int
berghofe@14106	223	val one_of: 'a list -> 'a
berghofe@14106	224	val frequency: (int * 'a) list -> 'a
berghofe@14106	225
wenzelm@14826	226	(current directory)
wenzelm@4621	227	val cd: string -> unit
wenzelm@4621	228	val pwd: unit -> string
wenzelm@4621	229
wenzelm@4621	230	(misc)
wenzelm@19644	231	val divide_and_conquer: ('a -> 'a list * ('b list -> 'b)) -> 'a -> 'b
wenzelm@4621	232	val partition_eq: ('a * 'a -> bool) -> 'a list -> 'a list list
wenzelm@4621	233	val partition_list: (int -> 'a -> bool) -> int -> int -> 'a list -> 'a list list
wenzelm@4621	234	val gensym: string -> string
wenzelm@16439	235	type stamp
wenzelm@16439	236	val stamp: unit -> stamp
wenzelm@16439	237	type serial
wenzelm@16439	238	val serial: unit -> serial
wenzelm@19512	239	val serial_string: unit -> string
wenzelm@16535	240	structure Object: sig type T end
wenzelm@4621	241	end;
wenzelm@4621	242
wenzelm@15745	243	signature LIBRARY =
skalberg@15570	244	sig
wenzelm@15745	245	include BASIC_LIBRARY
skalberg@15570	246	val foldl: ('a * 'b -> 'a) -> 'a * 'b list -> 'a
skalberg@15570	247	val foldr: ('a * 'b -> 'b) -> 'a list * 'b -> 'b
skalberg@15570	248	val take: int * 'a list -> 'a list
skalberg@15570	249	val drop: int * 'a list -> 'a list
skalberg@15570	250	val last_elem: 'a list -> 'a
skalberg@15570	251	end;
skalberg@15570	252
wenzelm@15745	253	structure Library: LIBRARY =
clasohm@1364	254	struct
clasohm@0	255
wenzelm@21395	256	(* functions *)
clasohm@0	257
wenzelm@16842	258	fun I x = x;
wenzelm@16842	259	fun K x = fn _ => x;
wenzelm@23220	260	fun flip f x y = f y x;
wenzelm@233	261	fun curry f x y = f (x, y);
wenzelm@233	262	fun uncurry f (x, y) = f x y;
clasohm@0	263
wenzelm@21395	264	(application and structured results -- old version)
wenzelm@16705	265	fun (x, y) \|>>> f = let val (x', z) = f x in (x', (y, z)) end;
wenzelm@16842	266
haftmann@17141	267	(conditional application)
wenzelm@21565	268	fun b ? f = fn x => if b then f x else x;
haftmann@17141	269
wenzelm@16721	270	(composition with multiple args)
wenzelm@16721	271	fun (f oo g) x y = f (g x y);
wenzelm@16721	272	fun (f ooo g) x y z = f (g x y z);
wenzelm@16721	273	fun (f oooo g) x y z w = f (g x y z w);
wenzelm@16721	274
wenzelm@233	275	(function exponentiation: f(...(f x)...) with n applications of f)
wenzelm@233	276	fun funpow n f x =
wenzelm@233	277	let fun rep (0, x) = x
wenzelm@233	278	\| rep (n, x) = rep (n - 1, f x)
wenzelm@233	279	in rep (n, x) end;
clasohm@0	280
clasohm@0	281
wenzelm@17341	282	(* exceptions *)
wenzelm@17341	283
wenzelm@18681	284	val do_transform_failure = ref true;
wenzelm@18681	285
wenzelm@18681	286	fun transform_failure exn f x =
wenzelm@18681	287	if ! do_transform_failure then
wenzelm@18681	288	f x handle Interrupt => raise Interrupt \| e => raise exn e
wenzelm@18681	289	else f x;
wenzelm@18681	290
wenzelm@17341	291	exception EXCEPTION of exn * string;
wenzelm@6959	292
wenzelm@14868	293	datatype 'a result =
wenzelm@14868	294	Result of 'a \|
wenzelm@14868	295	Exn of exn;
wenzelm@14868	296
wenzelm@14868	297	fun capture f x = Result (f x) handle e => Exn e;
wenzelm@14868	298
wenzelm@14868	299	fun release (Result y) = y
wenzelm@14868	300	\| release (Exn e) = raise e;
wenzelm@14868	301
skalberg@15531	302	fun get_result (Result x) = SOME x
skalberg@15531	303	\| get_result _ = NONE;
wenzelm@14868	304
skalberg@15531	305	fun get_exn (Exn exn) = SOME exn
skalberg@15531	306	\| get_exn _ = NONE;
wenzelm@14868	307
wenzelm@14868	308
wenzelm@18681	309	(* errors *)
wenzelm@18681	310
wenzelm@19542	311	exception SYS_ERROR of string;
wenzelm@19542	312	fun sys_error msg = raise SYS_ERROR msg;
wenzelm@19542	313
wenzelm@18681	314	exception ERROR of string;
wenzelm@18681	315	fun error msg = raise ERROR msg;
wenzelm@18681	316
wenzelm@18681	317	fun cat_error "" msg = error msg
wenzelm@18681	318	\| cat_error msg1 msg2 = error (msg1 ^ "\n" ^ msg2);
wenzelm@18681	319
wenzelm@18681	320	fun assert_all pred list msg =
wenzelm@18681	321	let
wenzelm@18681	322	fun ass [] = ()
wenzelm@18681	323	\| ass (x :: xs) = if pred x then ass xs else error (msg x);
wenzelm@18681	324	in ass list end;
wenzelm@18681	325
wenzelm@18681	326
wenzelm@21395	327	(* pairs *)
clasohm@0	328
wenzelm@233	329	fun pair x y = (x, y);
wenzelm@233	330	fun rpair x y = (y, x);
clasohm@0	331
wenzelm@233	332	fun fst (x, y) = x;
wenzelm@233	333	fun snd (x, y) = y;
wenzelm@233	334
haftmann@17498	335	fun eq_fst eq ((x1, _), (x2, _)) = eq (x1, x2);
haftmann@17498	336	fun eq_snd eq ((_, y1), (_, y2)) = eq (y1, y2);
haftmann@19454	337	fun eq_pair eqx eqy ((x1, y1), (x2, y2)) = eqx (x1, x2) andalso eqy (y1, y2);
wenzelm@233	338
wenzelm@233	339	fun swap (x, y) = (y, x);
wenzelm@233	340
wenzelm@233	341	fun apfst f (x, y) = (f x, y);
wenzelm@233	342	fun apsnd f (x, y) = (x, f y);
wenzelm@4212	343	fun pairself f (x, y) = (f x, f y);
wenzelm@233	344
wenzelm@233	345
wenzelm@21395	346	(* booleans *)
wenzelm@233	347
wenzelm@21395	348	(polymorphic equality)
wenzelm@233	349	fun equal x y = x = y;
wenzelm@233	350	fun not_equal x y = x <> y;
wenzelm@233	351
wenzelm@21395	352	(combining predicates)
wenzelm@16721	353	fun p orf q = fn x => p x orelse q x;
wenzelm@16721	354	fun p andf q = fn x => p x andalso q x;
wenzelm@233	355
wenzelm@233	356	(exists pred [x1, ..., xn] ===> pred x1 orelse ... orelse pred xn)
wenzelm@233	357	fun exists (pred: 'a -> bool) : 'a list -> bool =
wenzelm@233	358	let fun boolf [] = false
wenzelm@233	359	\| boolf (x :: xs) = pred x orelse boolf xs
wenzelm@233	360	in boolf end;
wenzelm@233	361
wenzelm@233	362	(forall pred [x1, ..., xn] ===> pred x1 andalso ... andalso pred xn)
wenzelm@233	363	fun forall (pred: 'a -> bool) : 'a list -> bool =
wenzelm@233	364	let fun boolf [] = true
wenzelm@233	365	\| boolf (x :: xs) = pred x andalso boolf xs
wenzelm@233	366	in boolf end;
wenzelm@233	367
wenzelm@19644	368
wenzelm@380	369	(* flags *)
wenzelm@380	370
wenzelm@380	371	fun set flag = (flag := true; true);
wenzelm@380	372	fun reset flag = (flag := false; false);
wenzelm@380	373	fun toggle flag = (flag := not (! flag); ! flag);
wenzelm@380	374
wenzelm@9118	375	fun change r f = r := f (! r);
wenzelm@9118	376
wenzelm@18712	377	(temporarily set flag during execution)
wenzelm@2978	378	fun setmp flag value f x =
wenzelm@2958	379	let
wenzelm@2958	380	val orig_value = ! flag;
wenzelm@18712	381	val _ = flag := value;
wenzelm@18712	382	val result = capture f x;
wenzelm@18712	383	val _ = flag := orig_value;
wenzelm@18712	384	in release result end;
wenzelm@2958	385
wenzelm@19644	386
wenzelm@21395	387
wenzelm@233	388	( lists )
wenzelm@233	389
skalberg@15570	390	exception UnequalLengths;
wenzelm@233	391
wenzelm@5285	392	fun single x = [x];
wenzelm@233	393
wenzelm@20882	394	fun the_single [x] = x
wenzelm@20882	395	\| the_single _ = raise Empty;
wenzelm@20882	396
wenzelm@20882	397	fun singleton f x = the_single (f [x]);
wenzelm@19273	398
wenzelm@5904	399	fun apply [] x = x
wenzelm@5904	400	\| apply (f :: fs) x = apply fs (f x);
wenzelm@5904	401
wenzelm@233	402
wenzelm@21395	403	(* fold -- old versions *)
haftmann@16691	404
wenzelm@233	405	(the following versions of fold are designed to fit nicely with infixes)
wenzelm@233	406
wenzelm@233	407	(* (op @) (e, [x1, ..., xn]) ===> ((e @ x1) @ x2) ... @ xn
wenzelm@233	408	for operators that associate to the left (TAIL RECURSIVE)*)
wenzelm@233	409	fun foldl (f: 'a * 'b -> 'a) : 'a * 'b list -> 'a =
wenzelm@233	410	let fun itl (e, []) = e
wenzelm@233	411	\| itl (e, a::l) = itl (f(e, a), l)
wenzelm@233	412	in itl end;
wenzelm@233	413
wenzelm@233	414	(* (op @) ([x1, ..., xn], e) ===> x1 @ (x2 ... @ (xn @ e))
wenzelm@233	415	for operators that associate to the right (not tail recursive)*)
wenzelm@233	416	fun foldr f (l, e) =
wenzelm@233	417	let fun itr [] = e
wenzelm@233	418	\| itr (a::l) = f(a, itr l)
wenzelm@233	419	in itr l end;
wenzelm@233	420
wenzelm@233	421	(* (op @) [x1, ..., xn] ===> x1 @ (x2 ... @ (x[n-1] @ xn))
wenzelm@233	422	for n > 0, operators that associate to the right (not tail recursive)*)
paulson@20443	423	fun foldr1 f [] = raise Empty
wenzelm@20510	424	\| foldr1 f l =
paulson@20443	425	let fun itr [x] = x
wenzelm@20510	426	\| itr (x::l) = f(x, itr l)
paulson@20443	427	in itr l end;
wenzelm@233	428
wenzelm@16705	429	fun foldl_map f =
wenzelm@16705	430	let
wenzelm@16705	431	fun fold_aux (x, []) = (x, [])
wenzelm@16705	432	\| fold_aux (x, y :: ys) =
wenzelm@16705	433	let
wenzelm@16705	434	val (x', y') = f (x, y);
wenzelm@16705	435	val (x'', ys') = fold_aux (x', ys);
wenzelm@16705	436	in (x'', y' :: ys') end;
wenzelm@16705	437	in fold_aux end;
wenzelm@16705	438
wenzelm@233	439
wenzelm@233	440	(* basic list functions *)
wenzelm@233	441
wenzelm@20510	442	fun eq_list eq (list1, list2) =
haftmann@20348	443	let
wenzelm@20510	444	fun eq_lst (x :: xs, y :: ys) = eq (x, y) andalso eq_lst (xs, ys)
wenzelm@20510	445	\| eq_lst _ = true;
wenzelm@20510	446	in length list1 = length list2 andalso eq_lst (list1, list2) end;
haftmann@20348	447
wenzelm@19483	448	fun maps f [] = []
wenzelm@19483	449	\| maps f (x :: xs) = f x @ maps f xs;
wenzelm@19483	450
wenzelm@23220	451	fun chop 0 xs = ([], xs)
wenzelm@23220	452	\| chop _ [] = ([], [])
wenzelm@23220	453	\| chop n (x :: xs) = chop (n - 1) xs \|>> cons x;
wenzelm@19011	454
wenzelm@233	455	(take the first n elements from a list)
wenzelm@233	456	fun take (n, []) = []
wenzelm@233	457	\| take (n, x :: xs) =
wenzelm@233	458	if n > 0 then x :: take (n - 1, xs) else [];
wenzelm@233	459
wenzelm@233	460	(drop the first n elements from a list)
wenzelm@233	461	fun drop (n, []) = []
wenzelm@233	462	\| drop (n, x :: xs) =
wenzelm@233	463	if n > 0 then drop (n - 1, xs) else x :: xs;
wenzelm@233	464
nipkow@4713	465	fun dropwhile P [] = []
nipkow@4713	466	\| dropwhile P (ys as x::xs) = if P x then dropwhile P xs else ys;
nipkow@4713	467
wenzelm@233	468	(*return nth element of a list, where 0 designates the first element;
wenzelm@18461	469	raise Subscript if list too short*)
haftmann@18011	470	fun nth xs i = List.nth (xs, i);
wenzelm@233	471
wenzelm@18461	472	fun nth_list xss i = nth xss i handle Subscript => [];
wenzelm@18461	473
haftmann@18011	474	fun nth_map 0 f (x :: xs) = f x :: xs
haftmann@18011	475	\| nth_map n f (x :: xs) = x :: nth_map (n - 1) f xs
haftmann@18011	476	\| nth_map _ _ [] = raise Subscript;
wenzelm@11773	477
haftmann@18514	478	fun map_index f =
haftmann@18514	479	let
haftmann@18514	480	fun mapp _ [] = []
haftmann@18514	481	\| mapp i (x :: xs) = f (i, x) :: mapp (i+1) xs
haftmann@18514	482	in mapp 0 end;
haftmann@18514	483
haftmann@21118	484	fun fold_index f =
haftmann@21118	485	let
haftmann@21118	486	fun fold_aux _ [] y = y
haftmann@21118	487	\| fold_aux i (x :: xs) y = fold_aux (i+1) xs (f (i, x) y);
haftmann@21118	488	in fold_aux 0 end;
haftmann@21118	489
skalberg@15570	490	val last_elem = List.last;
wenzelm@233	491
wenzelm@3762	492	(rear decomposition)
skalberg@15570	493	fun split_last [] = raise Empty
wenzelm@3762	494	\| split_last [x] = ([], x)
wenzelm@3762	495	\| split_last (x :: xs) = apfst (cons x) (split_last xs);
wenzelm@3762	496
wenzelm@4212	497	(find the position of an element in a list)
wenzelm@4212	498	fun find_index pred =
wenzelm@4212	499	let fun find _ [] = ~1
wenzelm@4212	500	\| find n (x :: xs) = if pred x then n else find (n + 1) xs;
wenzelm@4212	501	in find 0 end;
wenzelm@3762	502
wenzelm@4224	503	fun find_index_eq x = find_index (equal x);
wenzelm@4212	504
wenzelm@4212	505	(find first element satisfying predicate)
paulson@22593	506	val find_first = List.find;
wenzelm@233	507
wenzelm@4916	508	(get first element by lookup function)
skalberg@15531	509	fun get_first _ [] = NONE
wenzelm@4916	510	\| get_first f (x :: xs) =
wenzelm@4916	511	(case f x of
skalberg@15531	512	NONE => get_first f xs
wenzelm@4916	513	\| some => some);
wenzelm@4916	514
haftmann@19233	515	fun get_index f =
haftmann@19233	516	let
haftmann@19233	517	fun get _ [] = NONE
wenzelm@19461	518	\| get i (x :: xs) =
haftmann@19233	519	case f x
wenzelm@19461	520	of NONE => get (i + 1) xs
haftmann@19233	521	\| SOME y => SOME (i, y)
haftmann@19233	522	in get 0 end;
haftmann@19233	523
skalberg@15531	524	val flat = List.concat;
wenzelm@233	525
wenzelm@12136	526	fun unflat (xs :: xss) ys =
wenzelm@19424	527	let val (ps, qs) = chop (length xs) ys
nipkow@13629	528	in ps :: unflat xss qs end
wenzelm@12136	529	\| unflat [] [] = []
skalberg@15570	530	\| unflat _ _ = raise UnequalLengths;
wenzelm@12136	531
wenzelm@21479	532	fun burrow f xss = unflat xss (f (flat xss));
haftmann@18359	533
haftmann@18549	534	fun fold_burrow f xss s =
haftmann@18549	535	apfst (unflat xss) (f (flat xss) s);
haftmann@18359	536
wenzelm@233	537	(separate s [x1, x2, ..., xn] ===> [x1, s, x2, s, ..., s, xn])
wenzelm@233	538	fun separate s (x :: (xs as _ :: _)) = x :: s :: separate s xs
wenzelm@233	539	\| separate _ xs = xs;
wenzelm@233	540
wenzelm@233	541	(make the list [x, x, ..., x] of length n)
wenzelm@233	542	fun replicate n (x: 'a) : 'a list =
wenzelm@233	543	let fun rep (0, xs) = xs
wenzelm@233	544	\| rep (n, xs) = rep (n - 1, x :: xs)
wenzelm@233	545	in
skalberg@15570	546	if n < 0 then raise Subscript
wenzelm@233	547	else rep (n, [])
wenzelm@233	548	end;
wenzelm@233	549
wenzelm@14926	550	fun translate_string f = String.translate (f o String.str);
wenzelm@14926	551
wenzelm@4248	552	(multiply [a, b, c, ...] [xs, ys, zs, ...]*)
wenzelm@18148	553	fun multiply [] _ = []
wenzelm@18148	554	\| multiply (x :: xs) yss = map (cons x) yss @ multiply xs yss;
wenzelm@4248	555
wenzelm@14792	556	(direct product)
wenzelm@14792	557	fun product _ [] = []
wenzelm@14792	558	\| product [] _ = []
wenzelm@14792	559	\| product (x :: xs) ys = map (pair x) ys @ product xs ys;
wenzelm@14792	560
wenzelm@233	561
wenzelm@233	562	(* filter *)
wenzelm@233	563
wenzelm@233	564	(copy the list preserving elements that satisfy the predicate)
skalberg@15531	565	val filter = List.filter;
clasohm@0	566	fun filter_out f = filter (not o f);
wenzelm@19483	567	val map_filter = List.mapPartial;
wenzelm@233	568
wenzelm@233	569
wenzelm@233	570	(* lists of pairs *)
wenzelm@233	571
skalberg@15570	572	exception UnequalLengths;
skalberg@15570	573
haftmann@18330	574	fun map2 _ [] [] = []
haftmann@18330	575	\| map2 f (x :: xs) (y :: ys) = f x y :: map2 f xs ys
haftmann@18330	576	\| map2 _ _ _ = raise UnequalLengths;
wenzelm@380	577
wenzelm@23220	578	fun fold2 f [] [] z = z
wenzelm@23220	579	\| fold2 f (x :: xs) (y :: ys) z = fold2 f xs ys (f x y z)
wenzelm@23220	580	\| fold2 f _ _ _ = raise UnequalLengths;
wenzelm@380	581
wenzelm@19799	582	fun zip_options (x :: xs) (SOME y :: ys) = (x, y) :: zip_options xs ys
wenzelm@19799	583	\| zip_options (_ :: xs) (NONE :: ys) = zip_options xs ys
wenzelm@19799	584	\| zip_options _ [] = []
wenzelm@19799	585	\| zip_options [] _ = raise UnequalLengths;
wenzelm@4956	586
wenzelm@233	587	(*combine two lists forming a list of pairs:
wenzelm@233	588	[x1, ..., xn] ~~ [y1, ..., yn] ===> [(x1, y1), ..., (xn, yn)]*)
wenzelm@233	589	fun [] ~~ [] = []
wenzelm@233	590	\| (x :: xs) ~~ (y :: ys) = (x, y) :: (xs ~~ ys)
skalberg@15570	591	\| _ ~~ _ = raise UnequalLengths;
wenzelm@233	592
wenzelm@233	593	(*inverse of ~~; the old 'split':
wenzelm@233	594	[(x1, y1), ..., (xn, yn)] ===> ([x1, ..., xn], [y1, ..., yn])*)
skalberg@15570	595	val split_list = ListPair.unzip;
wenzelm@233	596
wenzelm@233	597
wenzelm@233	598	(* prefixes, suffixes *)
wenzelm@233	599
haftmann@18441	600	fun is_prefix _ [] _ = true
haftmann@18441	601	\| is_prefix eq (x :: xs) (y :: ys) = eq (x, y) andalso is_prefix eq xs ys
haftmann@18441	602	\| is_prefix eq _ _ = false;
wenzelm@233	603
wenzelm@233	604	(* [x1, ..., xi, ..., xn] ---> ([x1, ..., x(i-1)], [xi, ..., xn])
wenzelm@233	605	where xi is the first element that does not satisfy the predicate*)
wenzelm@233	606	fun take_prefix (pred : 'a -> bool) (xs: 'a list) : 'a list * 'a list =
wenzelm@233	607	let fun take (rxs, []) = (rev rxs, [])
wenzelm@255	608	\| take (rxs, x :: xs) =
wenzelm@255	609	if pred x then take(x :: rxs, xs) else (rev rxs, x :: xs)
wenzelm@233	610	in take([], xs) end;
wenzelm@233	611
haftmann@20108	612	fun chop_prefix eq ([], ys) = ([], ([], ys))
haftmann@20108	613	\| chop_prefix eq (xs, []) = ([], (xs, []))
wenzelm@23220	614	\| chop_prefix eq (xs as x :: xs', ys as y :: ys') =
haftmann@20108	615	if eq (x, y) then
haftmann@20108	616	let val (ps', xys'') = chop_prefix eq (xs', ys')
wenzelm@23220	617	in (x :: ps', xys'') end
haftmann@20108	618	else ([], (xs, ys));
haftmann@20108	619
wenzelm@233	620	(* [x1, ..., xi, ..., xn] ---> ([x1, ..., xi], [x(i+1), ..., xn])
wenzelm@233	621	where xi is the last element that does not satisfy the predicate*)
wenzelm@233	622	fun take_suffix _ [] = ([], [])
wenzelm@233	623	\| take_suffix pred (x :: xs) =
wenzelm@233	624	(case take_suffix pred xs of
wenzelm@233	625	([], sffx) => if pred x then ([], x :: sffx) else ([x], sffx)
wenzelm@233	626	\| (prfx, sffx) => (x :: prfx, sffx));
wenzelm@233	627
wenzelm@12249	628	fun prefixes1 [] = []
wenzelm@12249	629	\| prefixes1 (x :: xs) = map (cons x) ([] :: prefixes1 xs);
wenzelm@12249	630
wenzelm@19011	631	fun prefixes xs = [] :: prefixes1 xs;
wenzelm@19011	632
wenzelm@12249	633	fun suffixes1 xs = map rev (prefixes1 (rev xs));
wenzelm@19011	634	fun suffixes xs = [] :: suffixes1 xs;
wenzelm@233	635
wenzelm@23220	636
wenzelm@23220	637
wenzelm@233	638	( integers )
wenzelm@233	639
wenzelm@2958	640	fun inc i = (i := ! i + 1; ! i);
wenzelm@2958	641	fun dec i = (i := ! i - 1; ! i);
wenzelm@233	642
wenzelm@233	643
wenzelm@233	644	(* lists of integers *)
wenzelm@233	645
wenzelm@233	646	(make the list [from, from + 1, ..., to])
wenzelm@21859	647	fun (i upto j) =
wenzelm@21859	648	if i > j then [] else i :: (i + 1 upto j);
wenzelm@233	649
wenzelm@233	650	(make the list [from, from - 1, ..., to])
wenzelm@21859	651	fun (i downto j) =
wenzelm@21859	652	if i < j then [] else i :: (i - 1 downto j);
wenzelm@233	653
wenzelm@233	654
wenzelm@233	655	(* convert integers to strings *)
wenzelm@233	656
wenzelm@233	657	(*expand the number in the given base;
wenzelm@233	658	example: radixpand (2, 8) gives [1, 0, 0, 0]*)
wenzelm@233	659	fun radixpand (base, num) : int list =
wenzelm@233	660	let
wenzelm@233	661	fun radix (n, tail) =
wenzelm@233	662	if n < base then n :: tail
wenzelm@233	663	else radix (n div base, (n mod base) :: tail)
wenzelm@233	664	in radix (num, []) end;
wenzelm@233	665
wenzelm@233	666	(*expands a number into a string of characters starting from "zerochar";
wenzelm@233	667	example: radixstring (2, "0", 8) gives "1000"*)
wenzelm@233	668	fun radixstring (base, zerochar, num) =
wenzelm@233	669	let val offset = ord zerochar;
wenzelm@233	670	fun chrof n = chr (offset + n)
wenzelm@233	671	in implode (map chrof (radixpand (base, num))) end;
wenzelm@233	672
wenzelm@233	673
paulson@3407	674	val string_of_int = Int.toString;
wenzelm@233	675
wenzelm@21942	676	fun signed_string_of_int i =
wenzelm@21942	677	if i < 0 then "-" ^ string_of_int (~ i) else string_of_int i;
wenzelm@21942	678
wenzelm@23220	679	fun string_of_indexname (a, 0) = a
wenzelm@23220	680	\| string_of_indexname (a, i) = a ^ "_" ^ string_of_int i;
wenzelm@233	681
wenzelm@233	682
wenzelm@14826	683	(* read integers *)
wenzelm@14826	684
wenzelm@20095	685	fun read_intinf radix cs =
wenzelm@20095	686	let
wenzelm@20095	687	val zero = ord "0";
wenzelm@20095	688	val limit = zero + radix;
wenzelm@20095	689	fun scan (num, []) = (num, [])
wenzelm@20095	690	\| scan (num, c :: cs) =
wenzelm@20095	691	if zero <= ord c andalso ord c < limit then
wenzelm@20095	692	scan (IntInf.fromInt radix * num + IntInf.fromInt (ord c - zero), cs)
wenzelm@20095	693	else (num, c :: cs);
wenzelm@21859	694	in scan (IntInf.fromInt 0, cs) end;
wenzelm@14826	695
wenzelm@20095	696	fun read_int cs = apfst IntInf.toInt (read_intinf 10 cs);
wenzelm@14826	697
wenzelm@20095	698	fun oct_char s = chr (IntInf.toInt (#1 (read_intinf 8 (explode s))));
wenzelm@14826	699
wenzelm@14826	700
wenzelm@14826	701
wenzelm@233	702	( strings )
wenzelm@233	703
wenzelm@16188	704	(* functions tuned for strings, avoiding explode *)
wenzelm@6312	705
haftmann@18011	706	fun nth_string str i =
wenzelm@6959	707	(case try String.substring (str, i, 1) of
skalberg@15531	708	SOME s => s
skalberg@15570	709	\| NONE => raise Subscript);
wenzelm@6312	710
wenzelm@16188	711	fun fold_string f str x0 =
wenzelm@6282	712	let
wenzelm@6282	713	val n = size str;
wenzelm@16188	714	fun iter (x, i) =
wenzelm@16188	715	if i < n then iter (f (String.substring (str, i, 1)) x, i + 1) else x;
wenzelm@16188	716	in iter (x0, 0) end;
wenzelm@6282	717
wenzelm@14968	718	fun exists_string pred str =
wenzelm@14968	719	let
wenzelm@14968	720	val n = size str;
wenzelm@14968	721	fun ex i = i < n andalso (pred (String.substring (str, i, 1)) orelse ex (i + 1));
wenzelm@14968	722	in ex 0 end;
wenzelm@6312	723
wenzelm@16188	724	fun forall_string pred = not o exists_string (not o pred);
wenzelm@16188	725
lcp@512	726	(enclose in brackets)
lcp@512	727	fun enclose lpar rpar str = lpar ^ str ^ rpar;
wenzelm@6642	728	fun unenclose str = String.substring (str, 1, size str - 2);
wenzelm@255	729
wenzelm@233	730	(simple quoting (does not escape special chars))
lcp@512	731	val quote = enclose "\"" "\"";
wenzelm@233	732
wenzelm@4212	733	(space_implode "..." (explode "hello") = "h...e...l...l...o")
wenzelm@233	734	fun space_implode a bs = implode (separate a bs);
wenzelm@233	735
wenzelm@255	736	val commas = space_implode ", ";
wenzelm@380	737	val commas_quote = commas o map quote;
wenzelm@255	738
wenzelm@233	739	(concatenate messages, one per line, into a string)
wenzelm@255	740	val cat_lines = space_implode "\n";
wenzelm@233	741
wenzelm@4212	742	(space_explode "." "h.e..l.lo" = ["h", "e", "", "l", "lo"])
wenzelm@3832	743	fun space_explode _ "" = []
paulson@21899	744	\| space_explode sep s = String.fields (fn c => str c = sep) s;
wenzelm@3832	745
wenzelm@3832	746	val split_lines = space_explode "\n";
wenzelm@3832	747
wenzelm@14826	748	fun prefix_lines "" txt = txt
wenzelm@14826	749	\| prefix_lines prfx txt = txt \|> split_lines \|> map (fn s => prfx ^ s) \|> cat_lines;
wenzelm@14826	750
wenzelm@7712	751	fun untabify chs =
wenzelm@7712	752	let
wenzelm@7712	753	val tab_width = 8;
wenzelm@7712	754
wenzelm@22582	755	fun untab pos [] ys = rev ys
berghofe@22256	756	\| untab pos ("\n" :: xs) ys = untab 0 xs ("\n" :: ys)
berghofe@22256	757	\| untab pos ("\t" :: xs) ys =
wenzelm@22582	758	let val d = tab_width - (pos mod tab_width)
wenzelm@22582	759	in untab (pos + d) xs (replicate d " " @ ys) end
berghofe@22256	760	\| untab pos (c :: xs) ys = untab (pos + 1) xs (c :: ys);
wenzelm@7712	761	in
wenzelm@19301	762	if not (exists (fn c => c = "\t") chs) then chs
berghofe@22256	763	else untab 0 chs []
wenzelm@7712	764	end;
wenzelm@7712	765
wenzelm@18681	766	fun prefix prfx s = prfx ^ s;
wenzelm@16188	767	fun suffix sffx s = s ^ sffx;
wenzelm@5285	768
wenzelm@18681	769	fun unprefix prfx s =
wenzelm@18681	770	if String.isPrefix prfx s then String.substring (s, size prfx, size s - size prfx)
wenzelm@18681	771	else raise Fail "unprefix";
wenzelm@18681	772
wenzelm@16188	773	fun unsuffix sffx s =
wenzelm@17061	774	if String.isSuffix sffx s then String.substring (s, 0, size s - size sffx)
wenzelm@17061	775	else raise Fail "unsuffix";
wenzelm@5285	776
wenzelm@10951	777	fun replicate_string 0 _ = ""
wenzelm@10951	778	\| replicate_string 1 a = a
wenzelm@10951	779	\| replicate_string k a =
wenzelm@10951	780	if k mod 2 = 0 then replicate_string (k div 2) (a ^ a)
wenzelm@10951	781	else replicate_string (k div 2) (a ^ a) ^ a;
wenzelm@10951	782
wenzelm@233	783
wenzelm@23220	784
wenzelm@16492	785	( lists as sets -- see also Pure/General/ord_list.ML )
wenzelm@233	786
wenzelm@18923	787	(canonical member, insert, remove)
wenzelm@18923	788	fun member eq list x =
wenzelm@18923	789	let
wenzelm@18923	790	fun memb [] = false
wenzelm@18923	791	\| memb (y :: ys) = eq (x, y) orelse memb ys;
wenzelm@18923	792	in memb list end;
wenzelm@233	793
wenzelm@18923	794	fun insert eq x xs = if member eq xs x then xs else x :: xs;
wenzelm@18923	795	fun remove eq x xs = if member eq xs x then filter_out (fn y => eq (x, y)) xs else xs;
berghofe@1576	796
wenzelm@19301	797	fun subtract eq = fold (remove eq);
wenzelm@19301	798
wenzelm@18923	799	fun merge _ ([], ys) = ys
wenzelm@18923	800	\| merge eq (xs, ys) = fold_rev (insert eq) ys xs;
berghofe@1576	801
wenzelm@18923	802	(old-style infixes)
wenzelm@18923	803	fun x mem xs = member (op =) xs x;
wenzelm@18923	804	fun (x: int) mem_int xs = member (op =) xs x;
wenzelm@18923	805	fun (x: string) mem_string xs = member (op =) xs x;
wenzelm@233	806
wenzelm@233	807
wenzelm@233	808	(union of sets represented as lists: no repetitions)
wenzelm@233	809	fun xs union [] = xs
wenzelm@233	810	\| [] union ys = ys
haftmann@20854	811	\| (x :: xs) union ys = xs union (insert (op =) x ys);
wenzelm@233	812
paulson@2175	813	(union of sets, optimized version for ints)
berghofe@1576	814	fun (xs:int list) union_int [] = xs
berghofe@1576	815	\| [] union_int ys = ys
haftmann@20854	816	\| (x :: xs) union_int ys = xs union_int (insert (op =) x ys);
berghofe@1576	817
paulson@2175	818	(union of sets, optimized version for strings)
berghofe@1576	819	fun (xs:string list) union_string [] = xs
berghofe@1576	820	\| [] union_string ys = ys
haftmann@20854	821	\| (x :: xs) union_string ys = xs union_string (insert (op =) x ys);
berghofe@1576	822
wenzelm@233	823	(generalized union)
wenzelm@233	824	fun gen_union eq (xs, []) = xs
wenzelm@233	825	\| gen_union eq ([], ys) = ys
wenzelm@18923	826	\| gen_union eq (x :: xs, ys) = gen_union eq (xs, insert eq x ys);
wenzelm@233	827
wenzelm@233	828
wenzelm@233	829	(intersection)
wenzelm@233	830	fun [] inter ys = []
wenzelm@233	831	\| (x :: xs) inter ys =
wenzelm@233	832	if x mem ys then x :: (xs inter ys) else xs inter ys;
wenzelm@233	833
paulson@2175	834	(intersection, optimized version for ints)
berghofe@1576	835	fun ([]:int list) inter_int ys = []
berghofe@1576	836	\| (x :: xs) inter_int ys =
berghofe@1576	837	if x mem_int ys then x :: (xs inter_int ys) else xs inter_int ys;
berghofe@1576	838
paulson@2175	839	(intersection, optimized version for strings )
berghofe@1576	840	fun ([]:string list) inter_string ys = []
berghofe@1576	841	\| (x :: xs) inter_string ys =
berghofe@1576	842	if x mem_string ys then x :: (xs inter_string ys) else xs inter_string ys;
berghofe@1576	843
paulson@7090	844	(generalized intersection)
paulson@7090	845	fun gen_inter eq ([], ys) = []
wenzelm@12284	846	\| gen_inter eq (x::xs, ys) =
wenzelm@18923	847	if member eq ys x then x :: gen_inter eq (xs, ys)
wenzelm@18923	848	else gen_inter eq (xs, ys);
paulson@7090	849
wenzelm@233	850
wenzelm@233	851	(subset)
wenzelm@233	852	fun [] subset ys = true
wenzelm@233	853	\| (x :: xs) subset ys = x mem ys andalso xs subset ys;
wenzelm@233	854
paulson@2175	855	(subset, optimized version for ints)
wenzelm@16439	856	fun ([]: int list) subset_int ys = true
berghofe@1576	857	\| (x :: xs) subset_int ys = x mem_int ys andalso xs subset_int ys;
berghofe@1576	858
paulson@2175	859	(subset, optimized version for strings)
wenzelm@16439	860	fun ([]: string list) subset_string ys = true
berghofe@1576	861	\| (x :: xs) subset_string ys = x mem_string ys andalso xs subset_string ys;
berghofe@1576	862
wenzelm@4363	863	(set equality)
wenzelm@4363	864	fun eq_set (xs, ys) =
wenzelm@4363	865	xs = ys orelse (xs subset ys andalso ys subset xs);
wenzelm@4363	866
paulson@2182	867	(set equality for strings)
wenzelm@16439	868	fun eq_set_string ((xs: string list), ys) =
berghofe@1576	869	xs = ys orelse (xs subset_string ys andalso ys subset_string xs);
berghofe@1576	870
wenzelm@18923	871	fun gen_subset eq (xs, ys) = forall (member eq ys) xs;
paulson@2182	872
wenzelm@19301	873	fun gen_eq_set eq (xs, ys) =
haftmann@20348	874	eq_list eq (xs, ys) orelse
wenzelm@19301	875	(gen_subset eq (xs, ys) andalso gen_subset (eq o swap) (ys, xs));
wenzelm@19301	876
wenzelm@265	877
wenzelm@233	878	(removing an element from a list WITHOUT duplicates)
wenzelm@233	879	fun (y :: ys) \ x = if x = y then ys else y :: (ys \ x)
wenzelm@233	880	\| [] \ x = [];
paulson@2243	881	fun ys \\ xs = foldl (op \) (ys,xs);
clasohm@0	882
clasohm@0	883
wenzelm@233	884	(*makes a list of the distinct members of the input; preserves order, takes
wenzelm@233	885	first of equal elements*)
wenzelm@19046	886	fun distinct eq lst =
wenzelm@233	887	let
wenzelm@233	888	fun dist (rev_seen, []) = rev rev_seen
wenzelm@233	889	\| dist (rev_seen, x :: xs) =
wenzelm@18923	890	if member eq rev_seen x then dist (rev_seen, xs)
wenzelm@233	891	else dist (x :: rev_seen, xs);
wenzelm@19046	892	in dist ([], lst) end;
wenzelm@233	893
wenzelm@255	894	(*returns a list containing all repeated elements exactly once; preserves
wenzelm@255	895	order, takes first of equal elements*)
wenzelm@18966	896	fun duplicates eq lst =
wenzelm@255	897	let
wenzelm@255	898	fun dups (rev_dups, []) = rev rev_dups
wenzelm@255	899	\| dups (rev_dups, x :: xs) =
wenzelm@18923	900	if member eq rev_dups x orelse not (member eq xs x) then
wenzelm@255	901	dups (rev_dups, xs)
wenzelm@255	902	else dups (x :: rev_dups, xs);
wenzelm@18966	903	in dups ([], lst) end;
wenzelm@255	904
wenzelm@16878	905	fun has_duplicates eq =
wenzelm@16878	906	let
wenzelm@16878	907	fun dups [] = false
wenzelm@16878	908	\| dups (x :: xs) = member eq xs x orelse dups xs;
wenzelm@16878	909	in dups end;
wenzelm@16878	910
wenzelm@255	911
wenzelm@23220	912
nipkow@22142	913	( lists as multisets )
nipkow@22142	914
nipkow@22142	915	fun remove1 _ _ [] = raise Empty
wenzelm@23220	916	\| remove1 eq y (x::xs) = if eq (y, x) then xs else x :: remove1 eq y xs;
nipkow@22142	917
wenzelm@23220	918	fun submultiset _ ([], _) = true
wenzelm@23220	919	\| submultiset eq (x :: xs, ys) = member eq ys x andalso submultiset eq (xs, remove1 eq x ys);
nipkow@22142	920
nipkow@22142	921
wenzelm@233	922
wenzelm@233	923	( balanced trees )
wenzelm@233	924
wenzelm@233	925	exception Balance; (indicates non-positive argument to balancing fun)
wenzelm@233	926
wenzelm@233	927	(balanced folding; avoids deep nesting)
wenzelm@233	928	fun fold_bal f [x] = x
wenzelm@233	929	\| fold_bal f [] = raise Balance
wenzelm@233	930	\| fold_bal f xs =
wenzelm@19474	931	let val (ps, qs) = chop (length xs div 2) xs
nipkow@13629	932	in f (fold_bal f ps, fold_bal f qs) end;
wenzelm@233	933
wenzelm@233	934	(construct something of the form f(...g(...(x)...)) for balanced access)
wenzelm@233	935	fun access_bal (f, g, x) n i =
wenzelm@233	936	let fun acc n i = (1<=i<=n)
wenzelm@233	937	if n=1 then x else
wenzelm@233	938	let val n2 = n div 2
wenzelm@233	939	in if i<=n2 then f (acc n2 i)
wenzelm@233	940	else g (acc (n-n2) (i-n2))
wenzelm@233	941	end
wenzelm@233	942	in if 1<=i andalso i<=n then acc n i else raise Balance end;
wenzelm@233	943
wenzelm@233	944	(construct ALL such accesses; could try harder to share recursive calls!)
wenzelm@233	945	fun accesses_bal (f, g, x) n =
wenzelm@233	946	let fun acc n =
wenzelm@233	947	if n=1 then [x] else
wenzelm@233	948	let val n2 = n div 2
wenzelm@233	949	val acc2 = acc n2
wenzelm@233	950	in if n-n2=n2 then map f acc2 @ map g acc2
wenzelm@233	951	else map f acc2 @ map g (acc (n-n2)) end
wenzelm@233	952	in if 1<=n then acc n else raise Balance end;
wenzelm@233	953
wenzelm@233	954
wenzelm@233	955
wenzelm@2506	956	( orders )
wenzelm@2506	957
wenzelm@18966	958	fun is_equal EQUAL = true
wenzelm@18966	959	\| is_equal _ = false;
wenzelm@18966	960
wenzelm@4445	961	fun rev_order LESS = GREATER
wenzelm@4445	962	\| rev_order EQUAL = EQUAL
wenzelm@4445	963	\| rev_order GREATER = LESS;
wenzelm@4445	964
wenzelm@4479	965	(assume rel is a linear strict order)
wenzelm@4445	966	fun make_ord rel (x, y) =
wenzelm@4445	967	if rel (x, y) then LESS
wenzelm@4445	968	else if rel (y, x) then GREATER
wenzelm@4445	969	else EQUAL;
wenzelm@4445	970
wenzelm@15051	971	val int_ord = Int.compare;
wenzelm@15051	972	val string_ord = String.compare;
wenzelm@2506	973
wenzelm@16676	974	fun fast_string_ord (s1, s2) =
wenzelm@16676	975	(case int_ord (size s1, size s2) of EQUAL => string_ord (s1, s2) \| ord => ord);
wenzelm@16676	976
wenzelm@16492	977	fun option_ord ord (SOME x, SOME y) = ord (x, y)
wenzelm@16492	978	\| option_ord _ (NONE, NONE) = EQUAL
wenzelm@16492	979	\| option_ord _ (NONE, SOME _) = LESS
wenzelm@16492	980	\| option_ord _ (SOME _, NONE) = GREATER;
wenzelm@16492	981
wenzelm@4343	982	(lexicographic product)
wenzelm@4343	983	fun prod_ord a_ord b_ord ((x, y), (x', y')) =
wenzelm@4343	984	(case a_ord (x, x') of EQUAL => b_ord (y, y') \| ord => ord);
wenzelm@4343	985
wenzelm@4343	986	(dictionary order -- in general NOT well-founded!)
wenzelm@16984	987	fun dict_ord elem_ord (x :: xs, y :: ys) =
wenzelm@16984	988	(case elem_ord (x, y) of EQUAL => dict_ord elem_ord (xs, ys) \| ord => ord)
wenzelm@16984	989	\| dict_ord _ ([], []) = EQUAL
wenzelm@4343	990	\| dict_ord _ ([], _ :: _) = LESS
wenzelm@16984	991	\| dict_ord _ (_ :: _, []) = GREATER;
wenzelm@4343	992
wenzelm@4343	993	(lexicographic product of lists)
wenzelm@4343	994	fun list_ord elem_ord (xs, ys) =
wenzelm@16676	995	(case int_ord (length xs, length ys) of EQUAL => dict_ord elem_ord (xs, ys) \| ord => ord);
wenzelm@4343	996
wenzelm@2506	997
wenzelm@4621	998	(* sorting *)
wenzelm@4621	999
wenzelm@18427	1000	(quicksort -- stable, i.e. does not reorder equal elements)
wenzelm@18427	1001	fun quicksort unique ord =
wenzelm@4621	1002	let
wenzelm@16878	1003	fun qsort [] = []
wenzelm@16878	1004	\| qsort (xs as [_]) = xs
wenzelm@18427	1005	\| qsort (xs as [x, y]) =
wenzelm@18427	1006	(case ord (x, y) of
wenzelm@18427	1007	LESS => xs
wenzelm@18427	1008	\| EQUAL => if unique then [x] else xs
wenzelm@18427	1009	\| GREATER => [y, x])
wenzelm@16878	1010	\| qsort xs =
haftmann@18011	1011	let val (lts, eqs, gts) = part (nth xs (length xs div 2)) xs
wenzelm@16878	1012	in qsort lts @ eqs @ qsort gts end
wenzelm@4621	1013	and part _ [] = ([], [], [])
wenzelm@4621	1014	\| part pivot (x :: xs) = add (ord (x, pivot)) x (part pivot xs)
wenzelm@4621	1015	and add LESS x (lts, eqs, gts) = (x :: lts, eqs, gts)
wenzelm@18427	1016	\| add EQUAL x (lts, [], gts) = (lts, [x], gts)
wenzelm@18427	1017	\| add EQUAL x (res as (lts, eqs, gts)) = if unique then res else (lts, x :: eqs, gts)
wenzelm@4621	1018	\| add GREATER x (lts, eqs, gts) = (lts, eqs, x :: gts);
wenzelm@4621	1019	in qsort end;
wenzelm@4621	1020
wenzelm@18427	1021	fun sort ord = quicksort false ord;
wenzelm@18427	1022	fun sort_distinct ord = quicksort true ord;
wenzelm@18427	1023
wenzelm@4621	1024	val sort_strings = sort string_ord;
wenzelm@4621	1025	fun sort_wrt sel xs = sort (string_ord o pairself sel) xs;
wenzelm@4621	1026
wenzelm@4621	1027
wenzelm@2506	1028
berghofe@14106	1029	( random numbers )
berghofe@14106	1030
berghofe@14106	1031	exception RANDOM;
berghofe@14106	1032
berghofe@14618	1033	fun rmod x y = x - y * Real.realFloor (x / y);
berghofe@14106	1034
berghofe@14106	1035	local
berghofe@14106	1036	val a = 16807.0;
berghofe@14106	1037	val m = 2147483647.0;
berghofe@14106	1038	val random_seed = ref 1.0;
berghofe@14106	1039	in
berghofe@14106	1040
berghofe@14106	1041	fun random () =
berghofe@14106	1042	let val r = rmod (a * !random_seed) m
berghofe@14106	1043	in (random_seed := r; r) end;
berghofe@14106	1044
berghofe@14106	1045	end;
berghofe@14106	1046
berghofe@14106	1047	fun random_range l h =
berghofe@14106	1048	if h < l orelse l < 0 then raise RANDOM
berghofe@14106	1049	else l + Real.floor (rmod (random ()) (real (h - l + 1)));
berghofe@14106	1050
haftmann@18011	1051	fun one_of xs = nth xs (random_range 0 (length xs - 1));
berghofe@14106	1052
berghofe@14106	1053	fun frequency xs =
berghofe@14106	1054	let
berghofe@14106	1055	val sum = foldl op + (0, map fst xs);
wenzelm@17756	1056	fun pick n ((k: int, x) :: xs) =
berghofe@14106	1057	if n <= k then x else pick (n - k) xs
berghofe@14106	1058	in pick (random_range 1 sum) xs end;
berghofe@14106	1059
berghofe@14106	1060
wenzelm@23220	1061
wenzelm@14826	1062	( current directory )
wenzelm@233	1063
paulson@2243	1064	val cd = OS.FileSys.chDir;
wenzelm@2317	1065	val pwd = OS.FileSys.getDir;
paulson@2243	1066
berghofe@3606	1067
wenzelm@19644	1068
wenzelm@4621	1069	( misc )
wenzelm@233	1070
wenzelm@19644	1071	fun divide_and_conquer decomp x =
wenzelm@19644	1072	let val (ys, recomb) = decomp x
wenzelm@19644	1073	in recomb (map (divide_and_conquer decomp) ys) end;
wenzelm@19644	1074
clasohm@0	1075
wenzelm@233	1076	(*Partition a list into buckets [ bi, b(i+1), ..., bj ]
clasohm@0	1077	putting x in bk if p(k)(x) holds. Preserve order of elements if possible.*)
clasohm@0	1078	fun partition_list p i j =
wenzelm@233	1079	let fun part k xs =
wenzelm@233	1080	if k>j then
clasohm@0	1081	(case xs of [] => []
skalberg@15570	1082	\| _ => raise Fail "partition_list")
clasohm@0	1083	else
wenzelm@19691	1084	let val (ns, rest) = List.partition (p k) xs;
wenzelm@233	1085	in ns :: part(k+1)rest end
clasohm@0	1086	in part i end;
clasohm@0	1087
wenzelm@19691	1088	fun partition_eq (eq:'a * 'a -> bool) =
wenzelm@19691	1089	let
wenzelm@19691	1090	fun part [] = []
wenzelm@19691	1091	\| part (x :: ys) =
wenzelm@19691	1092	let val (xs, xs') = List.partition (fn y => eq (x, y)) ys
wenzelm@19691	1093	in (x::xs)::(part xs') end
wenzelm@19691	1094	in part end;
wenzelm@19691	1095
wenzelm@19691	1096
clasohm@0	1097
wenzelm@233	1098	(* generating identifiers *)
clasohm@0	1099
paulson@4063	1100	( Freshly generated identifiers; supplied prefix MUST start with a letter )
wenzelm@22369	1101	local
wenzelm@22369	1102	(Maps 0-61 to A-Z, a-z, 0-9; exclude _ or ' to avoid clash with internal/unusual indentifiers)
wenzelm@22582	1103	fun gensym_char i =
paulson@22368	1104	if i<26 then chr (ord "A" + i)
paulson@22368	1105	else if i<52 then chr (ord "a" + i - 26)
wenzelm@22369	1106	else chr (ord "0" + i - 52);
paulson@4063	1107
wenzelm@22369	1108	val char_vec = Vector.tabulate (62, gensym_char);
wenzelm@22369	1109	fun newid n = implode (map (fn i => Vector.sub (char_vec, i)) (radixpand (62, n)));
paulson@2003	1110
paulson@22368	1111	val gensym_seed = ref 0;
paulson@4063	1112
wenzelm@22369	1113	in
wenzelm@22369	1114	fun gensym pre = pre ^ newid (inc gensym_seed);
wenzelm@22369	1115	end;
paulson@4063	1116
paulson@4063	1117
wenzelm@16439	1118	(* stamps and serial numbers *)
wenzelm@16439	1119
wenzelm@16439	1120	type stamp = unit ref;
wenzelm@16439	1121	val stamp: unit -> stamp = ref;
wenzelm@16439	1122
wenzelm@16439	1123	type serial = int;
wenzelm@16439	1124	local val count = ref 0
wenzelm@16439	1125	in fun serial () = inc count end;
wenzelm@16439	1126
wenzelm@19512	1127	val serial_string = string_of_int o serial;
wenzelm@19512	1128
wenzelm@16535	1129
wenzelm@16535	1130	(* generic objects *)
wenzelm@16535	1131
wenzelm@16535	1132	(*note that the builtin exception datatype may be extended by new
wenzelm@16535	1133	constructors at any time*)
wenzelm@16535	1134	structure Object = struct type T = exn end;
wenzelm@16535	1135
clasohm@1364	1136	end;
clasohm@1364	1137
wenzelm@15745	1138	structure BasicLibrary: BASIC_LIBRARY = Library;
wenzelm@15745	1139	open BasicLibrary;

author	haftmann
	Tue, 05 Jun 2007 15:17:02 +0200
changeset 23251	471b576aad25
parent 23220	9e04da929160
child 23424	d0580634f128
permissions	-rw-r--r--