open Stack open List exception Found exception Not_comparable exception GraphSort_circular_deps type ('a, 'b) either = Left of 'a | Right of 'b type ('a, 'b) or_option = Or_some of 'a | Or_error of 'b (**********************************************************************************) let internal_error s = failwith ("internal error: " ^ s) let id x = x let double a = a,a let swap (x,y) = (y,x) let safe_tl l = try tl l with _ -> [] let fstfst ((e, _), _) = e let sndfst ((_, e), _) = e let fstsnd (_, (e, _)) = e let sndsnd (_, (_, e)) = e let o f g x = f (g x) let curry f x y = f (x,y) let uncurry f (x, y) = f x y let is_int n = ceil n = n let uncons = function | [] -> failwith "uncons" | e::l -> e,l let has_env var = try let _ = Sys.getenv var in true with Not_found -> false let some = function | Some e -> e | None -> failwith "some" let some_or = function | None -> id | Some e -> fun _ -> e let option2l = function | None -> [] | Some e -> [e] let prefer_some f a b = match a, b with | Some a, Some b -> Some (f a b) | None, _ -> b | _, None -> a let rec collect_accu f accu = function | [] -> accu | e::l -> collect_accu f (rev_append (f e) accu) l let collect f l = rev (collect_accu f [] l) let merge_some merge a b = match a,b with | None, None -> None | _, None -> a | None, _ -> b | Some(a), Some(b) -> Some(merge a b) let rec uniq = function | [] -> [] | e::l -> if mem e l then uniq l else e :: uniq l let rec uniq_ eq = function | [] -> [] | e::l -> try let _ = find (eq e) l in uniq_ eq l with Not_found -> e :: uniq_ eq l let rec non_uniq = function | [] -> [] | e::l -> if mem e l then e :: non_uniq l else non_uniq l let rec member_ eq e = function | [] -> false | e'::l -> if eq e e' then true else member_ eq e l let rec find_some p = function | [] -> raise Not_found | x :: l -> match p x with | Some v -> v | None -> find_some p l let fold_left1 f = function | [] -> failwith "fold_left1" | e :: l -> fold_left f e l let find_index e l = let rec find_index_ i = function | [] -> raise Not_found | e'::l -> if e=e' then i else find_index_ (i+1) l in find_index_ 0 l let rec find_some_ p = function | [] -> None | x :: l -> match p x with | Some v -> Some v | None -> find_some_ p l let rec fpartition p l = let rec part yes no = function | [] -> (rev yes, rev no) | x :: l -> (match p x with | None -> part yes (x :: no) l | Some v -> part (v :: yes) no l) in part [] [] l let partition_either f l = let rec part_either left right = function | [] -> (rev left, rev right) | x :: l -> (match f x with | Left e -> part_either (e :: left) right l | Right e -> part_either left (e :: right) l) in part_either [] [] l let rec keep_best f = let rec partition e = function | [] -> e, [] | e' :: l -> match f(e,e') with | None -> let (e'', l') = partition e l in e'', e' :: l' | Some e'' -> partition e'' l in function | [] -> [] | e::l -> let (e', l') = partition e l in e' :: keep_best f l' let rec keep_bests f l = let rec once e unchanged = function | [] -> None | e' :: l -> match f(e,e') with | None -> once e (e' :: unchanged) l | Some e'' -> Some(e'', unchanged @ l) in let rec as_many_as_possible e l = match once e [] l with | None -> None | Some(e', l') -> Some(some_or (as_many_as_possible e' l') (e', l')) in let rec try_with e l_done l_next = match as_many_as_possible e l_next with | None -> try_with_next (e :: l_done) l_next | Some(e2, l_next2) -> match as_many_as_possible e2 l_done with | None -> try_with_next (e2 :: l_done) l_next2 | Some(e3, l_done2) -> try_with e3 l_done2 l_next2 and try_with_next l_done = function | [] -> rev l_done | e::l_next -> try_with e l_done l_next in try_with_next [] l let rec fold_right1 f = function | [] -> failwith "fold_right1" | [e] -> e | e::l -> f e (fold_right1 f l) let rec for_all2_ p l1 l2 = match (l1, l2) with ([], []) -> true | (a1::l1, a2::l2) -> p a1 a2 && for_all2_ p l1 l2 | (_, _) -> false let maxl l = fold_right1 max l let rec stack2list s = let l = ref [] in Stack.iter (fun e -> l := e :: !l) s ; !l let rec stack_exists f s = try Stack.iter (fun e -> if f e then raise Found) s ; false with Found -> true let rec queue2list q = rev (Queue.fold (fun b a -> a :: b) [] q) let rec fix_point f p = let p' = f p in if p = p' then p else fix_point f p' let rec fix_point_withenv f env p = let p', env' = f env p in if p = p' then (p, env') else fix_point_withenv f env' p' let rec fix_point_ nb f p = let p' = f p in if p = p' then p, nb else fix_point_ (nb+1) f p' let rec group_by_2 = function | [] -> [] | a :: b :: l -> (a, b) :: group_by_2 l | _ -> failwith "group_by_2" (* let rec lfix_point f e = let e' = f(e) in if e = e' then e :: lfix_point f e' else [e] *) let do0_withenv doit f env l = let r_env = ref env in doit (fun e -> r_env := f !r_env e) l ; !r_env let do0_withenv2 doit f env l = let r_env = ref env in doit (fun e e' -> r_env := f !r_env e e') l ; !r_env let do_withenv doit f env l = let r_env = ref env in let l' = doit (fun e -> let e', env' = f !r_env e in r_env := env' ; e' ) l in l', !r_env let do2_withenv doit f env l1 l2 = let r_env = ref env in let l' = doit (fun e1 e2 -> let e', env' = f !r_env e1 e2 in r_env := env' ; e' ) l1 l2 in l', !r_env let do_collect doit f l1 = let l = ref [] in doit (fun i t -> l := f i t @ !l) l1 ; !l let map_withitself f l = let rec map_withitself_ done_ = function | [] -> done_ | e :: l -> let e' = f (done_ @ e :: l) e in map_withitself_ (done_ @ [ e' ]) l in map_withitself_ [] l let map_t2 f (x,y) = f x, f y let map_t3 f (x,y,z) = f x, f y, f z let map_option f = function | Some e -> Some (f e) | None -> None let map_optionoption f = function | Some e -> f e | None -> None let t2_option2option_t2 = function | (Some x, Some y) -> Some(x,y) | _ -> None let rec l_option2option_l = function | [] -> Some [] | None :: _l -> None | Some e :: l -> map_option (fun l -> e :: l) (l_option2option_l l) let map_option_env f (e, env) = map_option f e, env let t2_to_list (a,b) = [ a ; b ] let t3_to_list (a,b,c) = [ a ; b ; c ] let if_some bool val_ = if bool then Some val_ else None let rec fold_left_option f val_ = function | [] -> Some val_ | e::l -> match f val_ e with | None -> None | Some val_' -> fold_left_option f val_' l let collect_some_withenv f env l = let rec collect accu env = function | [] -> rev accu, env | e::l -> let e', env' = f env e in let accu' = match e' with | Some e' -> e'::accu | None -> accu in collect accu' env' l in collect [] env l let for_all_option_withenv remap f env l = let rec for_all env accu = function | [] -> Some(remap (rev accu)), env | e::l -> (match f env e with | None, env' -> None, env' | Some e', env' -> for_all env' (e' :: accu) l) in for_all env [] l let for_all2_option_withenv remap f env la lb = let rec for_all env accu = function | [], [] -> Some(remap (rev accu)), env | a::la, b::lb -> (match f env a b with | None, env' -> None, env' | Some ab, env' -> for_all env' (ab :: accu) (la, lb)) | _ -> None, env in for_all env [] (la, lb) let map_or_option f = function | Or_some e -> Or_some (f e) | Or_error err -> Or_error err let map_index f l = let rec map_ n = function | [] -> [] | e::l -> f e n :: map_ (n+1) l in map_ 0 l let filter_index f l = let rec filter_ n = function | [] -> [] | e::l -> let l' = filter_ (n+1) l in if f e n then e :: l' else l' in filter_ 0 l let iter_index f l = let rec iter_ n = function | [] -> () | e::l -> f e n ; iter_ (n+1) l in iter_ 0 l let map_fst f (x, y) = f x, y let map_snd f (x, y) = x, f y let map_withenv f env e = do_withenv map f env e let find_withenv f env e = do_withenv find f env e let filter_withenv f env e = do_withenv filter f env e let exists_withenv f env e = do_withenv exists f env e let map_t2_withenv f env e = do_withenv map_t2 f env e let for_all_withenv f env e = do_withenv for_all f env e let collect_withenv f env e = do_withenv collect f env e let partition_either_withenv f env e = do_withenv partition_either f env e let map2_withenv f env l1 l2 = do2_withenv map2 f env l1 l2 let for_all2_withenv f env l1 l2 = do2_withenv for_all2 f env l1 l2 let rec take n l = if n = 0 then [] else match l with | [] -> raise Not_found | e::l -> e :: take (n-1) l let last_n n l = rev (take n (rev l)) let last l = hd (last_n 1 l) let rec skipfirst e = function | [] -> [] | e'::l when e = e' -> skipfirst e l | l -> l let rec removelast = function | [] -> failwith "removelast" | [_] -> [] | e::l -> e :: removelast l let rec split_last l = let rec spl accu = function | [] -> failwith "split_last" | [e] -> rev accu, e | e::l -> spl (e :: accu) l in spl [] l let iter_assoc_val f l = iter (fun (_,v) -> f v) l let map_assoc_val f l = map (fun (k,v) -> k, f v) l let assoc_or_fail e l = try assoc e l with Not_found -> failwith "assoc failed" let assoc_by is_same e l = find_some (fun (a,b) -> if is_same e a then Some b else None) l let rec update_assoc_by is_same f e = function | [] -> raise Not_found | (a,b) :: l when is_same e a -> (a, f b) :: l | (a,b) :: l -> (a,b) :: update_assoc_by is_same f e l let update_assoc f e = update_assoc_by (=) f e let rec update_assoc_by_with_default default is_same f e = function | [] -> [ e, f default ] | (a,b) :: l when is_same e a -> (a, f b) :: l | (a,b) :: l -> (a,b) :: update_assoc_by_with_default default is_same f e l let update_all_assoc_by is_same f e l = map (fun (a,b) -> a, if is_same e a then f b else b) l let rec rassoc e = function | [] -> raise Not_found | (k,v) :: l -> if e = v then k else rassoc e l let rec all_assoc e = function | [] -> [] | (e',v) :: l when e=e' -> v :: all_assoc e l | _ :: l -> all_assoc e l let rec all_assoc_by is_same e = function | [] -> [] | (e',v) :: l when is_same e e' -> v :: all_assoc_by is_same e l | _ :: l -> all_assoc_by is_same e l let prepare_want_all_assoc l = map (fun n -> n, uniq (all_assoc n l)) (uniq (map fst l)) let prepare_want_all_assoc_by is_same l = map (fun n -> n, uniq_ is_same (all_assoc_by is_same n l)) (uniq_ is_same (map fst l)) let prepare_want_all_assoc_by_ is_same_a is_same_b l = map (fun n -> n, uniq_ is_same_b (all_assoc_by is_same_a n l)) (uniq_ is_same_a (map fst l)) let rec count_uniq = function | [] -> [] | e::l -> let has, l' = partition ((=) e) l in (e, length has + 1) :: count_uniq l' let rec repeat e = function | 0 -> [] | n -> e :: repeat e (n-1) let rec inits = function | [] -> [[]] | e::l -> [] :: map (fun l -> e::l) (inits l) let rec tails = function | [] -> [[]] | (_::xs) as xxs -> xxs :: tails xs let apply f x = f x;; let rec map3 f l1 l2 l3 = match (l1, l2, l3) with ([], [], []) -> [] | (a1::l1, a2::l2, a3::l3) -> let r = f a1 a2 a3 in r :: map3 f l1 l2 l3 | (_, _, _) -> invalid_arg "map3" let filter2 f l1 l2 = split (filter f (combine l1 l2)) let break_at f l = let rec b l1 = function | [] -> l1, [] | e::l2 -> if f e then (l1, e :: l2) else b (l1 @ [e]) l2 in b [] l let break v l = break_at ((=) v) l (* break_at_indice 0 [1;2] gives [], [1;2] break_at_indice 1 [1;2] gives [1], [2] *) let rec break_at_indice i l = if i = 0 then [], l else match l with | [] -> raise Not_found | e::l2 -> let a, b = break_at_indice (i-1) l2 in e::a, b let rev_nth e l = let rec rev_nth' i = function | [] -> raise Not_found | e'::_ when e'=e -> i | _::l -> rev_nth' (i+1) l in rev_nth' 0 l let rec getset_nth l i f = match l, i with | e::l', 0 -> f e :: l' | [], _ -> failwith "getset_nth" | e::l', _ -> e :: getset_nth l' (i - 1) f let set_nth l i v = getset_nth l i (fun _ -> v) let adjustModDown m n = n - (n mod m) let adjustModUp m n = adjustModDown m (n + m - 1) let hashtbl_set h k v = Hashtbl.remove h k; Hashtbl.add h k v let hashtbl_find f h = let r = ref None in Hashtbl.iter (fun v c -> if f v c then r := Some v) h ; match !r with | Some v -> v | None -> raise Not_found let hashtbl_filter f h = Hashtbl.iter (fun v c -> hashtbl_set h v (f v c)) h let hashtbl_to_list h = Hashtbl.fold (fun k v l -> (k,v) :: l) h [] let array_shift a = Array.sub a 1 (Array.length a - 1) let array_last_n n a = let len = Array.length a in Array.sub a (len - n) n let array_collect f a = Array.fold_left (fun l e -> f e @ l) [] a let rec lvector_product = let rec vector_product a b = match a with | [] -> [] | e::l -> map (fun e' -> e :: e') b :: vector_product l b in function | [] -> [] | [e] -> map (fun e -> [e]) e | e::l -> flatten (vector_product e (lvector_product l)) let vector_product2 a b = map (function | [a;b] -> a,b | _ -> failwith "vector_product2" ) (lvector_product [ a ; b ]) let rec transpose = function | [] :: _ -> [] | ll -> let l, ll' = split (map (function e::l -> e,l | _ -> raise Not_found) ll) in l :: transpose ll' let rec range min max = if min >= max then [] else min :: range (min + 1) max let rec filter_some_with f = function | [] -> [] | e :: l -> match f e with | None -> filter_some_with f l | Some e' -> e' :: filter_some_with f l let rec filter_some = function | [] -> [] | None :: l -> filter_some l | Some e :: l -> e :: filter_some l let rec difference l = function | [] -> l | e::l' -> difference (filter ((<>) e) l) l' let rec difference_ eq l = function | [] -> l | e::l' -> let l2 = filter (fun e' -> not (eq e e')) l in difference_ eq l2 l' let intersection_by is_same l1 l2 = filter (fun e -> exists (is_same e) l2) l1 let intersection_and_differences eq l1 l2 = let rec both inter l2_only = function | [], l2 -> inter, [], rev l2_only @ l2 | l1, [] -> inter, l1, rev l2_only | l1, e2 :: l2' -> match partition (eq e2) l1 with | [], _ -> both inter (e2 :: l2_only) (l1, l2') | _, l1' -> both (e2 :: inter) l2_only (l1', l2') in both [] [] (l1, l2) let rec triangularize = function | [] -> [] | e::l -> (e,l) :: triangularize l let diagonalize l = map_index (fun a i -> a, filter_index (fun _ j -> i <> j) l ) l let rec list_of_nonempty_sublists = function | [] -> [] | e :: l -> let l' = list_of_nonempty_sublists l in [e] :: l' @ map (fun l -> e :: l) l' let rec graph_is_sorted_by eq = function | [] -> true | (_,deps) :: l -> for_all (fun e -> try let _ = assoc_by eq e l in false with Not_found -> true) deps && graph_is_sorted_by eq l let graph_closure_by eq graph = let err = ref None in try let graph_rev = collect (fun (i, l) -> map (fun e -> (e, i)) l) graph in let bothway = map (fun (i,l) -> i, (l, all_assoc_by eq i graph_rev)) graph in let closed = fold_left (fun graph j -> let next, prev = assoc_by eq j graph in let graph2 = fold_left (fun graph i -> if member_ eq i next then (err := Some(j,i); raise GraphSort_circular_deps) else update_assoc_by eq (fun (i_next,i_prev) -> i_next @ next, i_prev) i graph ) graph (filter (fun a -> not (eq a j)) prev) in let graph3 = fold_left (fun graph k -> if member_ eq k prev then (err := Some(j,k); raise GraphSort_circular_deps) else update_assoc_by eq (fun (k_next,k_prev) -> k_next, k_prev @ prev) k graph ) graph2 (filter (fun a -> not (eq a j)) next) in graph3 ) bothway (map fst bothway) in Or_some (map (fun (e,(next,_)) -> e, uniq_ eq next) closed) with GraphSort_circular_deps -> Or_error (some !err) let rec graph_sort_by eq l = let cmp (_, deps_a) (b, _) = if member_ eq b deps_a then 1 else -1 in let rec sort_it = function | [] -> [] | [e] -> [e] | e::l -> let l' = sort_it l in let gt, lt = break_at (fun ((_, deps) as e') -> deps = [] or cmp e e' = 1) l' in gt @ [e] @ lt in map_or_option (fun l' -> let l_sorted = rev (sort_it l') in if not (graph_is_sorted_by eq l_sorted) then internal_error "graph_sort failed" else l_sorted ) (graph_closure_by eq l) let int_sort l = sort (fun a b -> a - b) l let str_begins_with s prefix = String.sub s 0 (min (String.length s) (String.length prefix)) = prefix let rec strstr s subs = let len_s, len_subs = String.length s, String.length subs in let rec rec_ i = let i' = String.index_from s i subs.[0] in if i' + len_subs <= len_s then if String.sub s i' len_subs = subs then i' else rec_ (i' + 1) else raise Not_found in rec_ 0 let str_contains s subs = try let _ = strstr s subs in true with Not_found -> false let str_ends_with s suffix = let len = min (String.length s) (String.length suffix) in String.sub s (String.length s - len) len = suffix let chop = function | "" -> "" | s -> String.sub s 0 (String.length s - 1) let chomps s = let i = ref (String.length s - 1) in while !i >= 0 && (s.[!i] = ' ' || s.[!i] = '\t') do decr i done ; String.sub s 0 (!i+1) let rec times e = function | 0 -> [] | n -> e :: times e (n-1) let skip_n_char_ beg end_ s = String.sub s beg (String.length s - beg - end_) let skip_n_char n s = skip_n_char_ n 0 s let rec non_index_from s beg c = if s.[beg] = c then non_index_from s (beg+1) c else beg let non_index s c = non_index_from s 0 c let rec non_rindex_from s beg c = if s.[beg] = c then non_rindex_from s (beg-1) c else beg let non_rindex s c = non_rindex_from s (String.length s - 1) c let rec explode_string = function | "" -> [] | s -> (String.get s 0) :: explode_string (String.sub s 1 (String.length s - 1)) let count_matching_char s c = let rec count_matching_char_ nb i = try let i' = String.index_from s i c in count_matching_char_ (nb+1) (i'+1) with Not_found -> nb in count_matching_char_ 0 0 let is_uppercase c = Char.lowercase c <> c let is_lowercase c = Char.uppercase c <> c let char_is_alphanumerical c = let i = Char.code c in Char.code 'a' <= i && i <= Char.code 'z' || Char.code 'A' <= i && i <= Char.code 'Z' || Char.code '0' <= i && i <= Char.code '9' let char_is_alphanumerical_ c = let i = Char.code c in Char.code 'a' <= i && i <= Char.code 'z' || Char.code 'A' <= i && i <= Char.code 'Z' || Char.code '0' <= i && i <= Char.code '9' || c = '_' let char_is_alpha c = let i = Char.code c in Char.code 'a' <= i && i <= Char.code 'z' || Char.code 'A' <= i && i <= Char.code 'Z' let char_is_number c = let i = Char.code c in Char.code '0' <= i && i <= Char.code '9' let rec string_forall_with f i s = try f s.[i] && string_forall_with f (i+1) s with Invalid_argument _ -> true let starts_with_non_lowercase s = s <> "" && s.[0] <> '_' && not (is_lowercase s.[0]) let rec fold_lines f init chan = try let line = input_line chan in fold_lines f (f init line) chan with End_of_file -> init let readlines chan = List.rev (fold_lines (fun l e -> e::l) [] chan) let split_at c s = let rec split_at_ accu i = try let i' = String.index_from s i c in split_at_ (String.sub s i (i' - i) :: accu) (i'+1) with Not_found -> rev (skip_n_char i s :: accu) in split_at_ [] 0 let split_at2 c1 c2 s = let rec split_at2_ accu i i2 = try let i3 = String.index_from s i2 c1 in if s.[i3+1] = c2 then split_at2_ (String.sub s i (i3 - i) :: accu) (i3+2) (i3+2) else split_at2_ accu i i3 with Not_found | Invalid_argument _ -> rev (skip_n_char i s :: accu) in split_at2_ [] 0 0 let words s = let rec words_ accu i s = try let i2 = non_index_from s i ' ' in try let i3 = String.index_from s i2 ' ' in words_ (String.sub s i2 (i3 - i2) :: accu) (i3+1) s with Not_found -> rev (skip_n_char i2 s :: accu) with Invalid_argument _ -> rev accu in collect (words_ [] 0) (split_at '\n' s) let to_CamelCase s_ = let l = ref [] in let s = String.copy s_ in for i = 1 to String.length s - 1 do if is_uppercase (String.unsafe_get s i) && is_lowercase (String.unsafe_get s (i-1)) then ( String.set s i (Char.lowercase (String.get s i)) ; l := i :: !l ) done ; if !l = [] then None else let offset, s' = fold_left (fun (offset, s') i -> i, s' ^ String.sub s offset (i-offset) ^ "_" ) (0, "") (rev !l) in Some (s' ^ String.sub s offset (String.length s - offset)) let (string_of_ref : 'a ref -> string) = fun r -> Printf.sprintf "0x%x" (Obj.magic r : int) let print_endline_flush_quiet = ref false let print_endline_flush s = if not !print_endline_flush_quiet then (print_endline s ; flush stdout) let is_int n = n = floor n (* total order *) let rec compare_lists cmp l1 l2 = match l1, l2 with | [], [] -> 0 | [], _ -> -1 | _, [] -> 1 | e1::l1, e2::l2 -> match cmp e1 e2 with | 0 -> compare_lists cmp l1 l2 | v -> v let compare_best a b = match a, b with | 0, 0 -> 0 | 1, 1 | 1, 0 | 0, 1 -> 1 | -1, -1 | -1, 0 | 0, -1 -> -1 | 1, -1 | -1, 1 -> raise Not_comparable | _ -> failwith "uh?" (* partial order *) let combine_comparison_list l = fold_left compare_best 0 l let min_with_cmp less_than a b = if less_than a b then a else if less_than b a then b else raise Not_comparable let max_with_cmp less_than a b = if less_than a b then b else if less_than b a then a else raise Not_comparable let rec fold_left2_compare f e l1 l2 = match l1, l2 with | [], [] -> e | e1::l1, e2::l2 -> fold_left2_compare f (f e e1 e2) l1 l2 | _ -> raise Not_comparable let rec exists_compare cmp = function | [] -> raise Not_comparable | e :: l -> try cmp e with Not_comparable -> exists_compare cmp l let forall_compare cmp = fold_left (fun n e -> compare_best n (cmp e)) 0 let forall2_compare cmp = fold_left2_compare (fun n e1 e2 -> compare_best n (cmp e1 e2)) 0 let exists2_compare left_dropping cmp l1 l2 = let rec forall_compare_ n = function | [], [] -> n | _, [] -> compare_best n left_dropping | [], _ -> compare_best n (-left_dropping) | e1::l1, e2::l2 -> match try Some (cmp e1 e2) with Not_comparable -> None with | Some n' -> forall_compare_ (compare_best n n') (l1, l2) | None -> if n = left_dropping then forall_compare_ left_dropping (l1, e2::l2) else if n = -left_dropping then forall_compare_ (-left_dropping) (e1::l1, l2) else (* need to try both *) try forall_compare_ left_dropping (l1, e2::l2) with Not_comparable -> forall_compare_ (-left_dropping) (e1::l1, l2) in forall_compare_ 0 (l1, l2) let rec compare_sorted_sets is_same l1 l2 = match l1, l2 with | [], [] -> 0 | [], _ -> -1 | _, [] -> 1 | e1::l1, e2::l2 -> if is_same e1 e2 then compare_sorted_sets is_same l1 l2 else raise Not_found let scan_list_while_modifying f l = let rec scan_list_while_modifying_ prev = function | [] -> prev | e :: next -> let prev', next' = some_or (f prev next e) (prev @ [e], next) in scan_list_while_modifying_ prev' next' in scan_list_while_modifying_ [] l let bools2compare = function | true, true -> 0 | true, false -> -1 | false, true -> 1 | _ -> raise Not_comparable let lpush l e = l := e :: !l (* let is_greater2compare is_greater a b = match is_greater a b, is_greater b a with *) module OrderedString = struct type t = string let compare = compare end;; module StringSet = Set.Make(OrderedString);; let stringSet_to_list = StringSet.elements let stringSet_add set e = StringSet.add e set let stringSet_difference = StringSet.diff let list_to_StringSet l = fold_left stringSet_add StringSet.empty l