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lib.ml
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lib.ml
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(* Slight modification of lib.ml. *)
module [@warning "-27-39"] M = struct
(* ========================================================================= *)
(* Convenient library functions. *)
(* *)
(* John Harrison, University of Cambridge Computer Laboratory *)
(* *)
(* (c) Copyright, University of Cambridge 1998 *)
(* (c) Copyright, John Harrison 1998-2007 *)
(* ========================================================================= *)
let fail() = failwith "";;
(* ------------------------------------------------------------------------- *)
(* Combinators. *)
(* ------------------------------------------------------------------------- *)
let curry f x y = f(x,y);;
let uncurry f(x,y) = f x y;;
(*REMOVE
let I x = x;;
let K x y = x;;
let C f x y = f y x;;
let W f x = f x x;;
REMOVE*)
let (o) = fun f g x -> f(g x);;
(*REMOVE
let (F_F) = fun f g (x,y) -> (f x,g y);;
REMOVE*)
let (|>) = fun x f -> f x;;
(* ------------------------------------------------------------------------- *)
(* List basics. *)
(* ------------------------------------------------------------------------- *)
let hd l =
match l with
h::t -> h
| _ -> failwith "hd";;
let tl l =
match l with
h::t -> t
| _ -> failwith "tl";;
let map f =
let rec mapf l =
match l with
[] -> []
| (x::t) -> let y = f x in y::(mapf t) in
mapf;;
let rec last l =
match l with
[x] -> x
| (h::t) -> last t
| [] -> failwith "last";;
let rec butlast l =
match l with
[_] -> []
| (h::t) -> h::(butlast t)
| [] -> failwith "butlast";;
let rec el n l =
if n = 0 then hd l else el (n - 1) (tl l);;
let rev =
let rec rev_append acc l =
match l with
[] -> acc
| h::t -> rev_append (h::acc) t in
fun l -> rev_append [] l;;
let rec map2 f l1 l2 =
match (l1,l2) with
[],[] -> []
| (h1::t1),(h2::t2) -> let h = f h1 h2 in h::(map2 f t1 t2)
| _ -> failwith "map2: length mismatch";;
(* ------------------------------------------------------------------------- *)
(* Attempting function or predicate applications. *)
(* ------------------------------------------------------------------------- *)
let can f x = try (ignore(f x); true) with Failure _ -> false;;
let check p x = if p x then x else failwith "check";;
(* ------------------------------------------------------------------------- *)
(* Repetition of a function. *)
(* ------------------------------------------------------------------------- *)
let rec funpow n f x =
if n < 1 then x else funpow (n-1) f (f x);;
let rec repeat f x =
try let y = f x in repeat f y with Failure _ -> x;;
(* ------------------------------------------------------------------------- *)
(* To avoid consing in various situations, we propagate this exception. *)
(* I should probably eliminate this and use pointer EQ tests instead. *)
(* ------------------------------------------------------------------------- *)
exception Unchanged;;
(* ------------------------------------------------------------------------- *)
(* Various versions of list iteration. *)
(* ------------------------------------------------------------------------- *)
let rec itlist f l b =
match l with
[] -> b
| (h::t) -> f h (itlist f t b);;
let rec rev_itlist f l b =
match l with
[] -> b
| (h::t) -> rev_itlist f t (f h b);;
let rec end_itlist f l =
match l with
[] -> failwith "end_itlist"
| [x] -> x
| (h::t) -> f h (end_itlist f t);;
let rec itlist2 f l1 l2 b =
match (l1,l2) with
([],[]) -> b
| (h1::t1,h2::t2) -> f h1 h2 (itlist2 f t1 t2 b)
| _ -> failwith "itlist2";;
let rec rev_itlist2 f l1 l2 b =
match (l1,l2) with
([],[]) -> b
| (h1::t1,h2::t2) -> rev_itlist2 f t1 t2 (f h1 h2 b)
| _ -> failwith "rev_itlist2";;
(* ------------------------------------------------------------------------- *)
(* Iterative splitting (list) and stripping (tree) via destructor. *)
(* ------------------------------------------------------------------------- *)
let rec splitlist dest x =
try let l,r = dest x in
let ls,res = splitlist dest r in
(l::ls,res)
with Failure _ -> ([],x);;
let rev_splitlist dest =
let rec rsplist ls x =
try let l,r = dest x in
rsplist (r::ls) l
with Failure _ -> (x,ls) in
fun x -> rsplist [] x;;
let striplist dest =
let rec strip x acc =
try let l,r = dest x in
strip l (strip r acc)
with Failure _ -> x::acc in
fun x -> strip x [];;
(* ------------------------------------------------------------------------- *)
(* Apply a destructor as many times as elements in list. *)
(* ------------------------------------------------------------------------- *)
let rec nsplit dest clist x =
if clist = [] then [],x else
let l,r = dest x in
let ll,y = nsplit dest (tl clist) r in
l::ll,y;;
(* ------------------------------------------------------------------------- *)
(* Replication and sequences. *)
(* ------------------------------------------------------------------------- *)
let rec replicate x n =
if n < 1 then []
else x::(replicate x (n - 1));;
let rec (--) = fun m n -> if m > n then [] else m::((m + 1) -- n);;
(* ------------------------------------------------------------------------- *)
(* Various useful list operations. *)
(* ------------------------------------------------------------------------- *)
let rec forall p l =
match l with
[] -> true
| h::t -> p(h) && forall p t;;
let rec forall2 p l1 l2 =
match (l1,l2) with
[],[] -> true
| (h1::t1,h2::t2) -> p h1 h2 && forall2 p t1 t2
| _ -> false;;
let rec exists p l =
match l with
[] -> false
| h::t -> p(h) || exists p t;;
let length =
let rec len k l =
if l = [] then k else len (k + 1) (tl l) in
fun l -> len 0 l;;
let rec filter p l =
match l with
[] -> l
| h::t -> let t' = filter p t in
if p(h) then if t'==t then l else h::t'
else t';;
let rec partition p l =
match l with
[] -> [],l
| h::t -> let yes,no = partition p t in
if p(h) then (if yes == t then l,[] else h::yes,no)
else (if no == t then [],l else yes,h::no);;
let rec mapfilter f l =
match l with
[] -> []
| (h::t) -> let rest = mapfilter f t in
try (f h)::rest with Failure _ -> rest;;
let rec find p l =
match l with
[] -> failwith "find"
| (h::t) -> if p(h) then h else find p t;;
let rec tryfind f l =
match l with
[] -> failwith "tryfind"
| (h::t) -> try f h with Failure _ -> tryfind f t;;
let flat l = itlist (@) l [];;
let rec remove p l =
match l with
[] -> failwith "remove"
| (h::t) -> if p(h) then h,t else
let y,n = remove p t in y,h::n;;
let rec chop_list n l =
if n = 0 then [],l else
try let m,l' = chop_list (n-1) (tl l) in (hd l)::m,l'
with Failure _ -> failwith "chop_list";;
let index x =
let rec ind n l =
match l with
[] -> failwith "index"
| (h::t) -> if Stdlib.compare x h = 0 then n else ind (n + 1) t in
ind 0;;
(* ------------------------------------------------------------------------- *)
(* "Set" operations on lists. *)
(* ------------------------------------------------------------------------- *)
let rec mem x lis =
match lis with
[] -> false
| (h::t) -> Stdlib.compare x h = 0 || mem x t;;
let insert x l =
if mem x l then l else x::l;;
let union l1 l2 = itlist insert l1 l2;;
let unions l = itlist union l [];;
let intersect l1 l2 = filter (fun x -> mem x l2) l1;;
let subtract l1 l2 = filter (fun x -> not (mem x l2)) l1;;
let subset l1 l2 = forall (fun t -> mem t l2) l1;;
let set_eq l1 l2 = subset l1 l2 && subset l2 l1;;
(* ------------------------------------------------------------------------- *)
(* Association lists. *)
(* ------------------------------------------------------------------------- *)
let rec assoc a l =
match l with
(x,y)::t -> if Stdlib.compare x a = 0 then y else assoc a t
| [] -> failwith "find";;
let rec rev_assoc a l =
match l with
(x,y)::t -> if Stdlib.compare y a = 0 then x else rev_assoc a t
| [] -> failwith "find";;
(* ------------------------------------------------------------------------- *)
(* Zipping, unzipping etc. *)
(* ------------------------------------------------------------------------- *)
let rec zip l1 l2 =
match (l1,l2) with
([],[]) -> []
| (h1::t1,h2::t2) -> (h1,h2)::(zip t1 t2)
| _ -> failwith "zip";;
let rec unzip =
function [] -> [],[]
| ((a,b)::rest) -> let alist,blist = unzip rest in
(a::alist,b::blist);;
(* ------------------------------------------------------------------------- *)
(* Sharing out a list according to pattern in list-of-lists. *)
(* ------------------------------------------------------------------------- *)
let rec shareout pat all =
if pat = [] then [] else
let l,r = chop_list (length (hd pat)) all in
l::(shareout (tl pat) r);;
(* ------------------------------------------------------------------------- *)
(* Iterating functions over lists. *)
(* ------------------------------------------------------------------------- *)
let rec do_list f l =
match l with
[] -> ()
| (h::t) -> (f h; do_list f t);;
(* ------------------------------------------------------------------------- *)
(* Sorting. *)
(* ------------------------------------------------------------------------- *)
let rec sort cmp lis =
match lis with
[] -> []
| piv::rest ->
let r,l = partition (cmp piv) rest in
(sort cmp l) @ (piv::(sort cmp r));;
(* ------------------------------------------------------------------------- *)
(* Removing adjacent (NB!) equal elements from list. *)
(* ------------------------------------------------------------------------- *)
let rec uniq l =
match l with
x::(y::_ as t) -> let t' = uniq t in
if Stdlib.compare x y = 0 then t' else
if t'==t then l else x::t'
| _ -> l;;
(* ------------------------------------------------------------------------- *)
(* Convert list into set by eliminating duplicates. *)
(* ------------------------------------------------------------------------- *)
let setify s = uniq (sort (fun x y -> Stdlib.compare x y <= 0) s);;
(* ------------------------------------------------------------------------- *)
(* String operations (surely there is a better way...) *)
(* ------------------------------------------------------------------------- *)
let implode l = itlist (^) l "";;
let explode s =
let rec exap n l =
if n < 0 then l else
exap (n - 1) ((String.sub s n 1)::l) in
exap (String.length s - 1) [];;
(* ------------------------------------------------------------------------- *)
(* Greatest common divisor. *)
(* ------------------------------------------------------------------------- *)
let gcd =
let rec gxd x y =
if y = 0 then x else gxd y (x mod y) in
fun x y -> let x' = abs x and y' = abs y in
if x' < y' then gxd y' x' else gxd x' y';;
(* ------------------------------------------------------------------------- *)
(* Some useful functions on "num" type. *)
(* ------------------------------------------------------------------------- *)
(*REMOVE
let num_0 = Int 0
and num_1 = Int 1
and num_2 = Int 2
and num_10 = Int 10;;
let pow2 n = power_num num_2 (Int n);;
let pow10 n = power_num num_10 (Int n);;
let numdom r =
let r' = Ratio.normalize_ratio (ratio_of_num r) in
num_of_big_int(Ratio.numerator_ratio r'),
num_of_big_int(Ratio.denominator_ratio r');;
let numerator = fst o numdom
and denominator = snd o numdom;;
let gcd_num n1 n2 =
num_of_big_int(Big_int.gcd_big_int (big_int_of_num n1) (big_int_of_num n2));;
let lcm_num x y =
if x =/ num_0 && y =/ num_0 then num_0
else abs_num((x */ y) // gcd_num x y);;
REMOVE*)
(* ------------------------------------------------------------------------- *)
(* All pairs arising from applying a function over two lists. *)
(* ------------------------------------------------------------------------- *)
let rec allpairs f l1 l2 =
match l1 with
h1::t1 -> itlist (fun x a -> f h1 x :: a) l2 (allpairs f t1 l2)
| [] -> [];;
(* ------------------------------------------------------------------------- *)
(* Issue a report with a newline. *)
(* ------------------------------------------------------------------------- *)
let report s =
Format.print_string s; Format.print_newline();;
(* ------------------------------------------------------------------------- *)
(* Convenient function for issuing a warning. *)
(* ------------------------------------------------------------------------- *)
let warn cond s =
if cond then report ("Warning: "^s) else ();;
(* ------------------------------------------------------------------------- *)
(* Flags to switch on verbose mode. *)
(* ------------------------------------------------------------------------- *)
let verbose = ref true;;
let report_timing = ref true;;
(* ------------------------------------------------------------------------- *)
(* Switchable version of "report". *)
(* ------------------------------------------------------------------------- *)
let remark s =
if !verbose then report s else ();;
(* ------------------------------------------------------------------------- *)
(* Time a function. *)
(* ------------------------------------------------------------------------- *)
let time f x =
if not (!report_timing) then f x else
let start_time = Sys.time() in
try let result = f x in
let finish_time = Sys.time() in
report("CPU time (user): "^(string_of_float(finish_time -. start_time)));
result
with e ->
let finish_time = Sys.time() in
Format.print_string("Failed after (user) CPU time of "^
(string_of_float(finish_time -. start_time))^": ");
raise e;;
(* ------------------------------------------------------------------------- *)
(* Versions of assoc and rev_assoc with default rather than failure. *)
(* ------------------------------------------------------------------------- *)
let rec assocd a l d =
match l with
[] -> d
| (x,y)::t -> if Stdlib.compare x a = 0 then y else assocd a t d;;
let rec rev_assocd a l d =
match l with
[] -> d
| (x,y)::t -> if Stdlib.compare y a = 0 then x else rev_assocd a t d;;
(* ------------------------------------------------------------------------- *)
(* Version of map that avoids rebuilding unchanged subterms. *)
(* ------------------------------------------------------------------------- *)
let rec qmap f l =
match l with
h::t -> let h' = f h and t' = qmap f t in
if h' == h && t' == t then l else h'::t'
| _ -> l;;
(* ------------------------------------------------------------------------- *)
(* Merging and bottom-up mergesort. *)
(* ------------------------------------------------------------------------- *)
let rec merge ord l1 l2 =
match l1 with
[] -> l2
| h1::t1 -> match l2 with
[] -> l1
| h2::t2 -> if ord h1 h2 then h1::(merge ord t1 l2)
else h2::(merge ord l1 t2);;
let mergesort ord =
let rec mergepairs l1 l2 =
match (l1,l2) with
([s],[]) -> s
| (l,[]) -> mergepairs [] l
| (l,[s1]) -> mergepairs (s1::l) []
| (l,(s1::s2::ss)) -> mergepairs ((merge ord s1 s2)::l) ss in
fun l -> if l = [] then [] else mergepairs [] (map (fun x -> [x]) l);;
(* ------------------------------------------------------------------------- *)
(* Common measure predicates to use with "sort". *)
(* ------------------------------------------------------------------------- *)
let increasing f x y = Stdlib.compare (f x) (f y) < 0;;
let decreasing f x y = Stdlib.compare (f x) (f y) > 0;;
(* ------------------------------------------------------------------------- *)
(* Polymorphic finite partial functions via Patricia trees. *)
(* *)
(* The point of this strange representation is that it is canonical (equal *)
(* functions have the same encoding) yet reasonably efficient on average. *)
(* *)
(* Idea due to Diego Olivier Fernandez Pons (OCaml list, 2003/11/10). *)
(* ------------------------------------------------------------------------- *)
type ('a,'b)func =
Empty
| Leaf of int * ('a*'b)list
| Branch of int * int * ('a,'b)func * ('a,'b)func;;
(* ------------------------------------------------------------------------- *)
(* Undefined function. *)
(* ------------------------------------------------------------------------- *)
let undefined = Empty;;
(* ------------------------------------------------------------------------- *)
(* In case of equality comparison worries, better use this. *)
(* ------------------------------------------------------------------------- *)
let is_undefined f =
match f with
Empty -> true
| _ -> false;;
(* ------------------------------------------------------------------------- *)
(* Operation analagous to "map" for lists. *)
(* ------------------------------------------------------------------------- *)
let mapf =
let rec map_list f l =
match l with
[] -> []
| (x,y)::t -> (x,f(y))::(map_list f t) in
let rec mapf f t =
match t with
Empty -> Empty
| Leaf(h,l) -> Leaf(h,map_list f l)
| Branch(p,b,l,r) -> Branch(p,b,mapf f l,mapf f r) in
mapf;;
(* ------------------------------------------------------------------------- *)
(* Operations analogous to "fold" for lists. *)
(* ------------------------------------------------------------------------- *)
let foldl =
let rec foldl_list f a l =
match l with
[] -> a
| (x,y)::t -> foldl_list f (f a x y) t in
let rec foldl f a t =
match t with
Empty -> a
| Leaf(h,l) -> foldl_list f a l
| Branch(p,b,l,r) -> foldl f (foldl f a l) r in
foldl;;
let foldr =
let rec foldr_list f l a =
match l with
[] -> a
| (x,y)::t -> f x y (foldr_list f t a) in
let rec foldr f t a =
match t with
Empty -> a
| Leaf(h,l) -> foldr_list f l a
| Branch(p,b,l,r) -> foldr f l (foldr f r a) in
foldr;;
(* ------------------------------------------------------------------------- *)
(* Mapping to sorted-list representation of the graph, domain and range. *)
(* ------------------------------------------------------------------------- *)
let graph f = setify (foldl (fun a x y -> (x,y)::a) [] f);;
let dom f = setify(foldl (fun a x y -> x::a) [] f);;
let ran f = setify(foldl (fun a x y -> y::a) [] f);;
(* ------------------------------------------------------------------------- *)
(* Application. *)
(* ------------------------------------------------------------------------- *)
let applyd =
let rec apply_listd l d x =
match l with
(a,b)::t -> let c = Stdlib.compare x a in
if c = 0 then b else if c > 0 then apply_listd t d x else d x
| [] -> d x in
fun f d x ->
let k = Hashtbl.hash x in
let rec look t =
match t with
Leaf(h,l) when h = k -> apply_listd l d x
| Branch(p,b,l,r) when (k lxor p) land (b - 1) = 0
-> look (if k land b = 0 then l else r)
| _ -> d x in
look f;;
let apply f = applyd f (fun x -> failwith "apply");;
let tryapplyd f a d = applyd f (fun x -> d) a;;
let defined f x = try apply f x; true with Failure _ -> false;;
(* ------------------------------------------------------------------------- *)
(* Undefinition. *)
(* ------------------------------------------------------------------------- *)
let undefine =
let rec undefine_list x l =
match l with
(a,b as ab)::t ->
let c = Stdlib.compare x a in
if c = 0 then t
else if c < 0 then l else
let t' = undefine_list x t in
if t' == t then l else ab::t'
| [] -> [] in
fun x ->
let k = Hashtbl.hash x in
let rec und t =
match t with
Leaf(h,l) when h = k ->
let l' = undefine_list x l in
if l' == l then t
else if l' = [] then Empty
else Leaf(h,l')
| Branch(p,b,l,r) when k land (b - 1) = p ->
if k land b = 0 then
let l' = und l in
if l' == l then t
else (match l' with Empty -> r | _ -> Branch(p,b,l',r))
else
let r' = und r in
if r' == r then t
else (match r' with Empty -> l | _ -> Branch(p,b,l,r'))
| _ -> t in
und;;
(* ------------------------------------------------------------------------- *)
(* Redefinition and combination. *)
(* ------------------------------------------------------------------------- *)
let (|->),combine =
let newbranch p1 t1 p2 t2 =
let zp = p1 lxor p2 in
let b = zp land (-zp) in
let p = p1 land (b - 1) in
if p1 land b = 0 then Branch(p,b,t1,t2)
else Branch(p,b,t2,t1) in
let rec define_list (x,y as xy) l =
match l with
(a,b as ab)::t ->
let c = Stdlib.compare x a in
if c = 0 then xy::t
else if c < 0 then xy::l
else ab::(define_list xy t)
| [] -> [xy]
and combine_list op z l1 l2 =
match (l1,l2) with
[],_ -> l2
| _,[] -> l1
| ((x1,y1 as xy1)::t1,(x2,y2 as xy2)::t2) ->
let c = Stdlib.compare x1 x2 in
if c < 0 then xy1::(combine_list op z t1 l2)
else if c > 0 then xy2::(combine_list op z l1 t2) else
let y = op y1 y2 and l = combine_list op z t1 t2 in
if z(y) then l else (x1,y)::l in
let (|->) x y =
let k = Hashtbl.hash x in
let rec upd t =
match t with
Empty -> Leaf (k,[x,y])
| Leaf(h,l) ->
if h = k then Leaf(h,define_list (x,y) l)
else newbranch h t k (Leaf(k,[x,y]))
| Branch(p,b,l,r) ->
if k land (b - 1) <> p then newbranch p t k (Leaf(k,[x,y]))
else if k land b = 0 then Branch(p,b,upd l,r)
else Branch(p,b,l,upd r) in
upd in
let rec combine op z t1 t2 =
match (t1,t2) with
Empty,_ -> t2
| _,Empty -> t1
| Leaf(h1,l1),Leaf(h2,l2) ->
if h1 = h2 then
let l = combine_list op z l1 l2 in
if l = [] then Empty else Leaf(h1,l)
else newbranch h1 t1 h2 t2
| (Leaf(k,lis) as lf),(Branch(p,b,l,r) as br) ->
if k land (b - 1) = p then
if k land b = 0 then
(match combine op z lf l with
Empty -> r | l' -> Branch(p,b,l',r))
else
(match combine op z lf r with
Empty -> l | r' -> Branch(p,b,l,r'))
else
newbranch k lf p br
| (Branch(p,b,l,r) as br),(Leaf(k,lis) as lf) ->
if k land (b - 1) = p then
if k land b = 0 then
(match combine op z l lf with
Empty -> r | l' -> Branch(p,b,l',r))
else
(match combine op z r lf with
Empty -> l | r' -> Branch(p,b,l,r'))
else
newbranch p br k lf
| Branch(p1,b1,l1,r1),Branch(p2,b2,l2,r2) ->
if b1 < b2 then
if p2 land (b1 - 1) <> p1 then newbranch p1 t1 p2 t2
else if p2 land b1 = 0 then
(match combine op z l1 t2 with
Empty -> r1 | l -> Branch(p1,b1,l,r1))
else
(match combine op z r1 t2 with
Empty -> l1 | r -> Branch(p1,b1,l1,r))
else if b2 < b1 then
if p1 land (b2 - 1) <> p2 then newbranch p1 t1 p2 t2
else if p1 land b2 = 0 then
(match combine op z t1 l2 with
Empty -> r2 | l -> Branch(p2,b2,l,r2))
else
(match combine op z t1 r2 with
Empty -> l2 | r -> Branch(p2,b2,l2,r))
else if p1 = p2 then
(match (combine op z l1 l2,combine op z r1 r2) with
(Empty,r) -> r | (l,Empty) -> l | (l,r) -> Branch(p1,b1,l,r))
else
newbranch p1 t1 p2 t2 in
(|->),combine;;
(* ------------------------------------------------------------------------- *)
(* Special case of point function. *)
(* ------------------------------------------------------------------------- *)
let (|=>) = fun x y -> (x |-> y) undefined;;
(* ------------------------------------------------------------------------- *)
(* Grab an arbitrary element. *)
(* ------------------------------------------------------------------------- *)
let rec choose t =
match t with
Empty -> failwith "choose: completely undefined function"
| Leaf(h,l) -> hd l
| Branch(b,p,t1,t2) -> choose t1;;
(* ------------------------------------------------------------------------- *)
(* Install a trivial printer for the general polymorphic case. *)
(* ------------------------------------------------------------------------- *)
let pp_print_fpf fmt (f:('a,'b)func) = Format.pp_print_string fmt "<func>";;
(*REMOVE
let print_fpf = pp_print_fpf Format.std_formatter;;
#install_printer pp_print_fpf;;
REMOVE*)
(* ------------------------------------------------------------------------- *)
(* Set operations parametrized by equality (from Steven Obua). *)
(* ------------------------------------------------------------------------- *)
let rec mem' eq =
let rec mem x lis =
match lis with
[] -> false
| (h::t) -> eq x h || mem x t
in mem;;
let insert' eq x l =
if mem' eq x l then l else x::l;;
let union' eq l1 l2 = itlist (insert' eq) l1 l2;;
let unions' eq l = itlist (union' eq) l [];;
let subtract' eq l1 l2 = filter (fun x -> not (mem' eq x l2)) l1;;
(* ------------------------------------------------------------------------- *)
(* Accepts decimal, hex or binary numeral, using C notation 0x... for hex *)
(* and analogous 0b... for binary. *)
(* ------------------------------------------------------------------------- *)
(*REMOVE
let num_of_string =
let values =
["0",0; "1",1; "2",2; "3",3; "4",4;
"5",5; "6",6; "7",7; "8",8; "9",9;
"a",10; "A",10; "b",11; "B",11;
"c",12; "C",12; "d",13; "D",13;
"e",14; "E",14; "f",15; "F",15] in
let valof b s =
let v = Int(assoc s values) in
if v </ b then v else failwith "num_of_string: invalid digit for base"
and two = num_2 and ten = num_10 and sixteen = Int 16 in
let rec num_of_stringlist b l =
match l with
[] -> failwith "num_of_string: no digits after base indicator"
| [h] -> valof b h
| h::t -> valof b h +/ b */ num_of_stringlist b t in
fun s ->
match explode(s) with
[] -> failwith "num_of_string: no digits"
| "0"::"x"::hexdigits -> num_of_stringlist sixteen (rev hexdigits)
| "0"::"b"::bindigits -> num_of_stringlist two (rev bindigits)
| decdigits -> num_of_stringlist ten (rev decdigits);;
REMOVE*)
(* ------------------------------------------------------------------------- *)
(* Convenient conversion between files and (lists of) strings. *)
(* ------------------------------------------------------------------------- *)
let strings_of_file filename =
let fd = try Stdlib.open_in filename
with Sys_error _ ->
failwith("strings_of_file: can't open "^filename) in
let rec suck_lines acc =
try let l = Stdlib.input_line fd in
suck_lines (l::acc)
with End_of_file -> rev acc in
let data = suck_lines [] in
(Stdlib.close_in fd; data);;
let string_of_file filename =
end_itlist (fun s t -> s^"\n"^t) (strings_of_file filename);;
let file_of_string filename s =
let fd = Stdlib.open_out filename in
output_string fd s; close_out fd;;
end
include M