(* $Id$ *)
-module DiscriminationTreeIndexing =
- functor (A:Set.S) ->
- struct
+type 'a path_string_elem =
+ | Constant of 'a * int (* name, arity *)
+ | Bound of int * int (* rel, arity *)
+ | Variable (* arity is 0 *)
+ | Proposition (* arity is 0 *)
+ | Datatype (* arity is 0 *)
+ | Dead (* arity is 0 *)
+;;
+
+type 'a path = ('a path_string_elem) list;;
+
+module type Indexable = sig
+ type input
+ type constant_name
+ val compare:
+ constant_name path_string_elem ->
+ constant_name path_string_elem -> int
+ val string_of_path : constant_name path -> string
+ val path_string_of : input -> constant_name path
+end
+
+module CicIndexable : Indexable
+with type input = Cic.term and type constant_name = UriManager.uri
+= struct
+
+ type input = Cic.term
+ type constant_name = UriManager.uri
+
+ let ppelem = function
+ | Constant (uri,arity) ->
+ "("^UriManager.name_of_uri uri ^ "," ^ string_of_int arity^")"
+ | Bound (i,arity) ->
+ "("^string_of_int i ^ "," ^ string_of_int arity^")"
+ | Variable -> "?"
+ | Proposition -> "Prop"
+ | Datatype -> "Type"
+ | Dead -> "Dead"
+ ;;
+
+ let path_string_of =
+ let rec aux arity = function
+ | Cic.Appl ((Cic.Meta _|Cic.Implicit _)::_) -> [Variable]
+ | Cic.Appl (Cic.Lambda _ :: _) ->
+ [Variable] (* maybe we should b-reduce *)
+ | Cic.Appl [] -> assert false
+ | Cic.Appl (hd::tl) ->
+ aux (List.length tl) hd @ List.flatten (List.map (aux 0) tl)
+ | Cic.Cast (t,_) -> aux arity t
+ | Cic.Lambda (_,s,t) | Cic.Prod (_,s,t) -> [Variable]
+ (* I think we should CicSubstitution.subst Implicit t *)
+ | Cic.LetIn (_,s,_,t) -> [Variable] (* z-reduce? *)
+ | Cic.Meta _ | Cic.Implicit _ -> assert (arity = 0); [Variable]
+ | Cic.Rel i -> [Bound (i, arity)]
+ | Cic.Sort (Cic.Prop) -> assert (arity=0); [Proposition]
+ | Cic.Sort _ -> assert (arity=0); [Datatype]
+ | Cic.Const _ | Cic.Var _
+ | Cic.MutInd _ | Cic.MutConstruct _ as t ->
+ [Constant (CicUtil.uri_of_term t, arity)]
+ | Cic.MutCase _ | Cic.Fix _ | Cic.CoFix _ -> [Dead]
+ in
+ aux 0
+ ;;
+
+ let compare e1 e2 =
+ match e1,e2 with
+ | Constant (u1,a1),Constant (u2,a2) ->
+ let x = UriManager.compare u1 u2 in
+ if x = 0 then Pervasives.compare a1 a2 else x
+ | e1,e2 -> Pervasives.compare e1 e2
+ ;;
+
+ let string_of_path l = String.concat "." (List.map ppelem l) ;;
+end
+
+let arity_of = function
+ | Constant (_,a)
+ | Bound (_,a) -> a
+ | _ -> 0
+;;
- type path_string_elem =
- | Function | Constant of UriManager.uri
- | Bound of int | Variable | Proposition | Datatype ;;
- type path_string = path_string_elem list;;
+module type DiscriminationTree =
+ sig
+ type input
+ type data
+ type dataset
+ type constant_name
+ type t
- (* needed by the retrieve_* functions, to know the arities of the
- * "functions" *)
-
- let ppelem = function
- | Function -> "Fun"
- | Constant uri -> UriManager.name_of_uri uri
- | Bound i -> string_of_int i
- | Variable -> "?"
- | Proposition -> "Prop"
- | Datatype -> "Type"
- ;;
- let pppath l = String.concat "::" (List.map ppelem l) ;;
- let elem_of_cic = function
- | Cic.Meta _ -> Variable
- | Cic.Lambda _ -> Function
- | Cic.Rel i -> Bound i
- | Cic.Sort (Cic.Prop) -> Proposition
- | Cic.Sort _ -> Datatype
- | term ->
- try Constant (CicUtil.uri_of_term term)
- with Invalid_argument _ -> Variable (* HACK! *)
- ;;
- let path_string_of_term arities =
- let set_arity n = function
- | Variable -> Hashtbl.replace arities Variable 0
- | e -> Hashtbl.replace arities e n
- in
- let rec aux = function
- | Cic.Appl ((hd::tl) as l) ->
-(*
- if Hashtbl.mem arities (elem_of_cic hd) then
- begin
- let n = Hashtbl.find arities (elem_of_cic hd) in
- if n <> List.length tl then
- begin
- prerr_endline
- (String.concat " "
- (List.map (fun x -> ppelem (elem_of_cic x)) l))
- end;
- assert(n = List.length tl)
- end;
-*)
- set_arity (List.length tl) (elem_of_cic hd);
-(* Hashtbl.replace arities (elem_of_cic hd) (List.length tl); *)
- List.concat (List.map aux l)
- | t -> [elem_of_cic t]
- in
- aux
- ;;
- let compare_elem e1 e2 =
- match e1,e2 with
- | Constant u1,Constant u2 -> UriManager.compare u1 u2
- | e1,e2 -> Pervasives.compare e1 e2
- ;;
+ val iter : t -> (constant_name path -> dataset -> unit) -> unit
+
+ val empty : t
+ val index : t -> input -> data -> t
+ val remove_index : t -> input -> data -> t
+ val in_index : t -> input -> (data -> bool) -> bool
+ val retrieve_generalizations : t -> input -> dataset
+ val retrieve_unifiables : t -> input -> dataset
+ end
+
+module Make (I:Indexable) (A:Set.S) : DiscriminationTree
+with type constant_name = I.constant_name and type input = I.input
+and type data = A.elt and type dataset = A.t =
+
+ struct
module OrderedPathStringElement = struct
- type t = path_string_elem
- let compare = compare_elem
+ type t = I.constant_name path_string_elem
+ let compare = I.compare
end
+ type constant_name = I.constant_name
+ type data = A.elt
+ type dataset = A.t
+ type input = I.input
+
module PSMap = Map.Make(OrderedPathStringElement);;
type key = PSMap.key
module DiscriminationTree = Trie.Make(PSMap);;
- type t = A.t DiscriminationTree.t * (path_string_elem, int) Hashtbl.t
- let empty = DiscriminationTree.empty, Hashtbl.create 11;;
-
-(*
- module OrderedPosEquality = struct
- type t = Utils.pos * Inference.equality
- let compare = Pervasives.compare
- end
+ type t = A.t DiscriminationTree.t
- module PosEqSet = Set.Make(OrderedPosEquality);;
+ let empty = DiscriminationTree.empty;;
- let string_of_discrimination_tree tree =
- let rec to_string level = function
- | DiscriminationTree.Node (value, map) ->
- let s =
- match value with
- | Some v ->
- (String.make (2 * level) ' ') ^
- "{" ^ (String.concat "; "
- (List.map
- (fun (p, e) ->
- "(" ^ (Utils.string_of_pos p) ^ ", " ^
- (Inference.string_of_equality e) ^ ")")
- (PosEqSet.elements v))) ^ "}"
- | None -> ""
- in
- let rest =
- String.concat "\n"
- (PSMap.fold
- (fun k v s ->
- let ks = CicPp.ppterm k in
- let rs = to_string (level+1) v in
- ((String.make (2 * level) ' ') ^ ks ^ "\n" ^ rs)::s)
- map [])
- in
- s ^ rest
- in
- to_string 0 tree
- ;;
-*)
+ let iter dt f = DiscriminationTree.iter (fun p x -> f p x) dt;;
- let index (tree,arity) term info =
- let ps = path_string_of_term arity term in
+ let index tree term info =
+ let ps = I.path_string_of term in
let ps_set =
- try DiscriminationTree.find ps tree
- with Not_found -> A.empty in
- let tree = DiscriminationTree.add ps (A.add info ps_set) tree in
- tree,arity
- ;;
-
-(*
- let index tree equality =
- let _, _, (_, l, r, ordering), _, _ = equality in
- let psl = path_string_of_term l
- and psr = path_string_of_term r in
- let index pos tree ps =
- let ps_set =
- try DiscriminationTree.find ps tree with Not_found -> PosEqSet.empty in
- let tree =
- DiscriminationTree.add ps (PosEqSet.add (pos, equality) ps_set) tree in
- tree
+ try DiscriminationTree.find ps tree with Not_found -> A.empty
in
- match ordering with
- | Utils.Gt -> index Utils.Left tree psl
- | Utils.Lt -> index Utils.Right tree psr
- | _ ->
- let tree = index Utils.Left tree psl in
- index Utils.Right tree psr
+ DiscriminationTree.add ps (A.add info ps_set) tree
;;
-*)
- let remove_index (tree,arity) term info =
- let ps = path_string_of_term arity term in
+ let remove_index tree term info =
+ let ps = I.path_string_of term in
try
let ps_set = A.remove info (DiscriminationTree.find ps tree) in
- if A.is_empty ps_set then
- DiscriminationTree.remove ps tree,arity
- else
- DiscriminationTree.add ps ps_set tree,arity
- with Not_found ->
- tree,arity
+ if A.is_empty ps_set then DiscriminationTree.remove ps tree
+ else DiscriminationTree.add ps ps_set tree
+ with Not_found -> tree
;;
-(*
-let remove_index tree equality =
- let _, _, (_, l, r, ordering), _, _ = equality in
- let psl = path_string_of_term l
- and psr = path_string_of_term r in
- let remove_index pos tree ps =
- try
- let ps_set =
- PosEqSet.remove (pos, equality) (DiscriminationTree.find ps tree) in
- if PosEqSet.is_empty ps_set then
- DiscriminationTree.remove ps tree
- else
- DiscriminationTree.add ps ps_set tree
- with Not_found ->
- tree
- in
- match ordering with
- | Utils.Gt -> remove_index Utils.Left tree psl
- | Utils.Lt -> remove_index Utils.Right tree psr
- | _ ->
- let tree = remove_index Utils.Left tree psl in
- remove_index Utils.Right tree psr
-;;
-*)
-
-
- let in_index (tree,arity) term test =
- let ps = path_string_of_term arity term in
+ let in_index tree term test =
+ let ps = I.path_string_of term in
try
let ps_set = DiscriminationTree.find ps tree in
A.exists test ps_set
- with Not_found ->
- false
- ;;
-
-(*
- let in_index tree equality =
- let _, _, (_, l, r, ordering), _, _ = equality in
- let psl = path_string_of_term l
- and psr = path_string_of_term r in
- let meta_convertibility = Inference.meta_convertibility_eq equality in
- let ok ps =
- try
- let set = DiscriminationTree.find ps tree in
- PosEqSet.exists (fun (p, e) -> meta_convertibility e) set
- with Not_found ->
- false
- in
- (ok psl) || (ok psr)
-;;
-*)
-
-
- let head_of_term = function
- | Cic.Appl (hd::tl) -> hd
- | term -> term
+ with Not_found -> false
;;
-
- let rec subterm_at_pos pos term =
- match pos with
- | [] -> term
- | index::pos ->
- match term with
- | Cic.Appl l ->
- (try subterm_at_pos pos (List.nth l index)
- with Failure _ -> raise Not_found)
- | _ -> raise Not_found
- ;;
-
-
- let rec after_t pos term =
- let pos' =
- match pos with
- | [] -> raise Not_found
- | pos ->
- List.fold_right
- (fun i r -> if r = [] then [i+1] else i::r) pos []
- in
- try
- ignore(subterm_at_pos pos' term ); pos'
- with Not_found ->
- let pos, _ =
- List.fold_right
- (fun i (r, b) -> if b then (i::r, true) else (r, true))
- pos ([], false)
- in
- after_t pos term
+ (* You have h(f(x,g(y,z)),t) whose path_string_of_term_with_jl is
+ (h,2).(f,2).(x,0).(g,2).(y,0).(z,0).(t,0) and you are at f and want to
+ skip all its progeny, thus you want to reach t.
+
+ You need to skip as many elements as the sum of all arieties contained
+ in the progeny of f.
+
+ The input ariety is the one of f while the path is x.g....t
+ Should be the equivalent of after_t in the literature (handbook A.R.)
+ *)
+ let rec skip arity path =
+ if arity = 0 then path else match path with
+ | [] -> assert false
+ | m::tl -> skip (arity-1+arity_of m) tl
;;
-
- let next_t pos term =
- let t = subterm_at_pos pos term in
- try
- let _ = subterm_at_pos [1] t in
- pos @ [1]
- with Not_found ->
- match pos with
- | [] -> [1]
- | pos -> after_t pos term
- ;;
-
- let retrieve_generalizations (tree,arity) term =
- let rec retrieve tree term pos =
- match tree with
- | DiscriminationTree.Node (Some s, _) when pos = [] -> s
- | DiscriminationTree.Node (_, map) ->
- let res =
- try
- let hd_term = head_of_term (subterm_at_pos pos term) in
- let n = PSMap.find (elem_of_cic hd_term) map in
- match n with
- | DiscriminationTree.Node (Some s, _) -> s
- | DiscriminationTree.Node (None, _) ->
- let newpos =
- try next_t pos term
- with Not_found -> []
- in
- retrieve n term newpos
- with Not_found ->
- A.empty
- in
- try
- let n = PSMap.find Variable map in
- let newpos = try after_t pos term with Not_found -> [-1] in
- if newpos = [-1] then
- match n with
- | DiscriminationTree.Node (Some s, _) -> A.union s res
- | _ -> res
- else
- A.union res (retrieve n term newpos)
- with Not_found ->
- res
+ (* the equivalent of skip, but on the index, thus the list of trees
+ that are rooted just after the term represented by the tree root
+ are returned (we are skipping the root) *)
+ let skip_root = function DiscriminationTree.Node (value, map) ->
+ let rec get n = function DiscriminationTree.Node (v, m) as tree ->
+ if n = 0 then [tree] else
+ PSMap.fold (fun k v res -> (get (n-1 + arity_of k) v) @ res) m []
in
- retrieve tree term []
+ PSMap.fold (fun k v res -> (get (arity_of k) v) @ res) map []
;;
-
- let jump_list arities = function
- | DiscriminationTree.Node (value, map) ->
- let rec get n tree =
- match tree with
- | DiscriminationTree.Node (v, m) ->
- if n = 0 then
- [tree]
- else
- PSMap.fold
- (fun k v res ->
- let a =
- try Hashtbl.find arities k
- with Not_found -> 0
- in
- (get (n-1 + a) v) @ res) m []
- in
- PSMap.fold
- (fun k v res ->
- let arity = try Hashtbl.find arities k with Not_found -> 0 in
- (get arity v) @ res)
- map []
+ let retrieve unif tree term =
+ let path = I.path_string_of term in
+ let rec retrieve path tree =
+ match tree, path with
+ | DiscriminationTree.Node (Some s, _), [] -> s
+ | DiscriminationTree.Node (None, _), [] -> A.empty
+ | DiscriminationTree.Node (_, map), Variable::path when unif ->
+ List.fold_left A.union A.empty
+ (List.map (retrieve path) (skip_root tree))
+ | DiscriminationTree.Node (_, map), node::path ->
+ A.union
+ (if not unif && node = Variable then A.empty else
+ try retrieve path (PSMap.find node map)
+ with Not_found -> A.empty)
+ (try
+ match PSMap.find Variable map,skip (arity_of node) path with
+ | DiscriminationTree.Node (Some s, _), [] -> s
+ | n, path -> retrieve path n
+ with Not_found -> A.empty)
+ in
+ retrieve path tree
;;
-
- let retrieve_unifiables (tree,arities) term =
- let rec retrieve tree term pos =
- match tree with
- | DiscriminationTree.Node (Some s, _) when pos = [] -> s
- | DiscriminationTree.Node (_, map) ->
- let subterm =
- try Some (subterm_at_pos pos term) with Not_found -> None
- in
- match subterm with
- | None -> A.empty
- | Some (Cic.Meta _) ->
- let newpos = try next_t pos term with Not_found -> [] in
- let jl = jump_list arities tree in
- List.fold_left
- (fun r s -> A.union r s)
- A.empty
- (List.map (fun t -> retrieve t term newpos) jl)
- | Some subterm ->
- let res =
- try
- let hd_term = head_of_term subterm in
- let n = PSMap.find (elem_of_cic hd_term) map in
- match n with
- | DiscriminationTree.Node (Some s, _) -> s
- | DiscriminationTree.Node (None, _) ->
- retrieve n term (next_t pos term)
- with Not_found ->
- A.empty
- in
- try
- let n = PSMap.find Variable map in
- let newpos =
- try after_t pos term
- with Not_found -> [-1]
- in
- if newpos = [-1] then
- match n with
- | DiscriminationTree.Node (Some s, _) ->
- A.union s res
- | _ -> res
- else
- A.union res (retrieve n term newpos)
- with Not_found ->
- res
- in
- retrieve tree term []
+ let retrieve_generalizations tree term = retrieve false tree term;;
+ let retrieve_unifiables tree term = retrieve true tree term;;
end
;;