snapshot (first version with working pattern matching both 3->2 and 2->1)

[helm.git] / helm / ocaml / cic_notation / cicNotationMatcher.ml

diff --git a/helm/ocaml/cic_notation/cicNotationMatcher.ml b/helm/ocaml/cic_notation/cicNotationMatcher.ml
index 8da7a483d6d4d123cfa71d8307f1926a63ce3af4..f8f73e66bf9cba5dd2aadabb71feed686dcdcd91 100644 (file)
--- a/helm/ocaml/cic_notation/cicNotationMatcher.ml
+++ b/helm/ocaml/cic_notation/cicNotationMatcher.ml
@@ -34,28 +34,34 @@ type pattern_id = int
 exception No_match
 
 module OrderedInt =
-  struct
+struct
   type t = int
   let compare (x1:t) (x2:t) = Pervasives.compare x2 x1  (* reverse order *)
-  end
+end
 
 module IntSet = Set.Make (OrderedInt)
 
 let int_set_of_int_list l =
   List.fold_left (fun acc i -> IntSet.add i acc) IntSet.empty l
 
+type pattern_kind = Variable | Constructor
+type tag_t = int
+
 module type PATTERN =
-  sig
+sig
   type pattern_t
-  val compatible : pattern_t -> pattern_t -> bool
-  end
+  type term_t
+  val classify : pattern_t -> pattern_kind
+  val tag_of_pattern : pattern_t -> tag_t * pattern_t list
+  val tag_of_term : term_t -> tag_t * term_t list
+end
 
-module Patterns (P: PATTERN) =
-  struct
+module Matcher (P: PATTERN) =
+struct
   type row_t = P.pattern_t list * P.pattern_t list * pattern_id
   type t = row_t list
 
-  let empty = []
+  let compatible p1 p2 = P.classify p1 = P.classify p2
 
   let matched = List.map (fun (matched, _, pid) -> matched, pid)
 
@@ -82,21 +88,22 @@ module Patterns (P: PATTERN) =
     (* return 2 lists of rows, first one containing homogeneous rows according
      * to "compatible" below *)
   let horizontal_split t =
-    let ap, first_row, t' =
+    let ap, first_row, t', first_row_class =
       match t with
       | [] -> assert false
       | (_, [], _) :: _ ->
           assert false  (* are_empty should have been invoked in advance *)
-      | ((_, hd :: _ , _) as row) :: tl -> hd, row, tl
+      | ((_, hd :: _ , _) as row) :: tl -> hd, row, tl, P.classify hd
     in
     let rec aux prev_t = function
       | [] -> List.rev prev_t, []
       | (_, [], _) :: _ -> assert false
-      | ((_, hd :: _, _) as row) :: tl when P.compatible ap hd ->
+      | ((_, hd :: _, _) as row) :: tl when compatible ap hd ->
           aux (row :: prev_t) tl
       | t -> List.rev prev_t, t
     in
-    aux [first_row] t'
+    let rows1, rows2 = aux [first_row] t' in
+    first_row_class, rows1, rows2
 
     (* return 2 lists, first one representing first column, second one
      * representing a new pattern matrix where matched patterns have been moved
@@ -107,227 +114,253 @@ module Patterns (P: PATTERN) =
         | decls, hd :: tl, pid -> hd :: decls, tl, pid
         | _ -> assert false)
       t
+
+  let variable_closure k =
+    (fun matched_terms terms ->
+      prerr_endline "variable_closure";
+      match terms with
+      | hd :: tl -> k (hd :: matched_terms) tl
+      | _ -> assert false)
+
+  let constructor_closure ks k =
+    (fun matched_terms terms ->
+      prerr_endline "constructor_closure";
+      match terms with
+      | t :: tl ->
+          (try
+            let tag, subterms = P.tag_of_term t in
+            let k' = List.assoc tag ks in
+            k' matched_terms (subterms @ tl)
+          with Not_found -> k matched_terms terms)
+      | [] -> assert false)
+
+  let compiler rows match_cb fail_k =
+    let rec aux t k =
+      if t = [] then
+        k
+      else if are_empty t then
+        let res = match_cb (matched t) in
+        (fun matched_terms _ -> res matched_terms)
+      else
+        match horizontal_split t with
+        | _, [], _ -> assert false
+        | Variable, t', [] -> variable_closure (aux (vertical_split t') k)
+        | Constructor, t', [] ->
+            let tagl =
+              List.map
+                (function
+                  | _, p :: _, _ -> fst (P.tag_of_pattern p)
+                  | _ -> assert false)
+                t'
+            in
+            let clusters = partition t' tagl in
+            let ks =
+              List.map
+                (fun (tag, cluster) ->
+                  let cluster' =
+                    List.map  (* add args as patterns heads *)
+                      (function
+                        | matched_p, p :: tl, pid ->
+                            let _, subpatterns = P.tag_of_pattern p in
+                            matched_p, subpatterns @ tl, pid
+                        | _ -> assert false)
+                      cluster
+                  in
+                  tag, aux cluster' k)
+                clusters
+            in
+            constructor_closure ks k
+        | _, t', t'' -> aux t' (aux t'' k)
+    in
+    let t = List.map (fun (p, pid) -> [], [p], pid) rows in
+    let matcher = aux t (fun _ _ -> fail_k ()) in
+    (fun term -> matcher [] [term])
+end
+
+module Matcher21 =
+struct
+  module Pattern21 =
+  struct
+    type pattern_t = Pt.term
+    type term_t = Pt.term
+    let classify = function
+      | Pt.Variable _ -> Variable
+      | Pt.Magic _
+      | Pt.Layout _
+      | Pt.Literal _ -> assert false
+      | _ -> Constructor
+    let tag_of_pattern = CicNotationTag.get_tag
+    let tag_of_term = CicNotationTag.get_tag
   end
 
-module T21 =
+  module M = Matcher (Pattern21)
+
+  let extract_magic term =
+    let magic_map = ref [] in
+    let add_magic m =
+      let name = Util.fresh_name () in
+      magic_map := (name, m) :: !magic_map;
+      Pt.Variable (Pt.TermVar name)
+    in
+    let rec aux = function
+      | Pt.AttributedTerm (_, t) -> aux t
+      | Pt.Literal _
+      | Pt.Layout _ -> assert false
+      | Pt.Variable v -> Pt.Variable v
+      | Pt.Magic m -> add_magic m
+      | t -> Util.visit_ast aux t
+    in
+    let term' = aux term in
+    term', !magic_map
+
+  let env_of_matched pl tl =
+    List.map2
+      (fun p t ->
+        match p, t with
+          Pt.Variable (Pt.TermVar name), _ ->
+            name, (Env.TermType, Env.TermValue t)
+        | Pt.Variable (Pt.NumVar name), (Pt.Num (s, _)) ->
+            name, (Env.NumType, Env.NumValue s)
+        | Pt.Variable (Pt.IdentVar name), (Pt.Ident (s, None)) ->
+            name, (Env.StringType, Env.StringValue s)
+        | _ -> assert false)
+      pl tl
+
+  let decls_of_pattern p = 
+    List.map Env.declaration_of_var (Util.variables_of_term p)
+
+  let rec compiler rows =
+    let rows', magic_maps =
+      List.split
+        (List.map
+          (fun (p, pid) ->
+            let p', map = extract_magic p in
+            (p', pid), (pid, map))
+          rows)
+    in
+    let magichecker map =
+      List.fold_left
+        (fun f (name, m) ->
+          let m_checker = compile_magic m in
+          (fun env ->
+            match m_checker (Env.lookup_term env name) env with
+            | None -> None
+            | Some env' -> f env'))
+        (fun env -> Some env)
+        map
+    in
+    let magichooser candidates =
+      List.fold_left
+        (fun f (pid, pl, checker) ->
+          (fun matched_terms ->
+            let env = env_of_matched pl matched_terms in
+            match checker env with
+            | None -> f matched_terms
+            | Some env -> Some (env, pid)))
+        (fun _ -> None)
+        candidates
+    in
+    let match_cb rows =
+      prerr_endline (sprintf "match_cb on %d row(s)" (List.length rows));
+      let candidates =
+        List.map
+          (fun (pl, pid) ->
+            let magic_map =
+              try List.assoc pid magic_maps with Not_found -> assert false
+            in
+            pid, pl, magichecker magic_map)
+          rows
+      in
+      magichooser candidates
+    in
+    M.compiler rows match_cb (fun _ -> None)
+
+  and compile_magic = function
+    | Pt.Fold (kind, p_base, names, p_rec) ->
+        let p_rec_decls = decls_of_pattern p_rec in
+        let acc_name = try List.hd names with Failure _ -> assert false in
+        let t_magic = [p_base, 0; p_rec, 1] in
+        let compiled = compiler t_magic in
+        (fun term env ->
+          let rec aux term =
+            match compiled term with
+            | None -> None
+            | Some (env', 0) -> Some (env', [])
+            | Some (env', 1) ->
+                begin
+                  let acc = Env.lookup_term env' acc_name in
+                  let env'' = Env.remove env' acc_name in
+                  match aux acc with
+                  | None -> None
+                  | Some (base_env, rec_envl) -> 
+                      Some (base_env, env'' :: rec_envl )
+                end
+            | _ -> assert false
+          in
+            match aux term with
+            | None -> None
+            | Some (base_env, rec_envl) ->
+                Some (base_env @ Env.coalesce_env p_rec_decls rec_envl))
+    | _ -> assert false
+end
+
+module Matcher32 =
 struct
+  module Pattern32 =
+  struct
+    type cic_mask_t =
+      Blob
+    | Uri of string
+    | Appl of cic_mask_t list
+
+    let uri_of_term t = CicUtil.uri_of_term (Deannotate.deannotate_term t)
+
+    let mask_of_cic = function
+      | Cic.AAppl (_, tl) -> Appl (List.map (fun _ -> Blob) tl), tl
+      | Cic.AConst (_, _, [])
+      | Cic.AVar (_, _, [])
+      | Cic.AMutInd (_, _, _, [])
+      | Cic.AMutConstruct (_, _, _, _, []) as t -> Uri (uri_of_term t), []
+      | _ -> Blob, []
 
-module P = Patterns (CicNotationTag)
-
-(* let return_closure matched =
-  (fun matched_terms terms ->
-    prerr_endline "T21.return_closure";
-    match terms with
-    | [] -> matched_terms, matched
-    | _ -> assert false) *)
-
-let variable_closure k =
-  (fun matched_terms terms ->
-    prerr_endline "T21.variable_closure";
-    match terms with
-    | hd :: tl ->
-        prerr_endline (sprintf "binding: %s" (CicNotationPp.pp_term hd));
-        k (hd :: matched_terms) tl
-    | _ -> assert false)
-
-let constructor_closure ks k =
-  (fun matched_terms terms ->
-    prerr_endline "T21.constructor_closure";
-    match terms with
-    | t :: tl ->
-        prerr_endline (sprintf "on term %s" (CicNotationPp.pp_term t));
-        (try
-          let tag, subterms = CicNotationTag.get_tag t in
-          let k' = List.assoc tag ks in
-          k' matched_terms (subterms @ tl)
-        with Not_found -> k matched_terms terms)
-    | [] -> assert false)
-
-(* let fold_closure kind p_names names matcher success_k k =
-  let acc_name = try List.hd names with Failure _ -> assert false in
-|+   List.iter (fun (name, _) -> Printf.printf "/// %s\n" name) p_names ; +|
-  (fun matched_terms terms ->
-    prerr_endline "T21.fold_closure";
-    (match terms with
-    | t :: tl ->
-        let rec aux t =
-          prerr_endline "PORCA TORCIA SONO IN AUX" ;
-          match matcher t with
-          | _, [] -> None
-          | matched_terms, [matched_p, 0] -> Some (matched_terms, [])
-          | matched_terms, [matched_p, 1] ->
-              let acc = CicNotationEnv.lookup_term env acc_name in
-              let env = CicNotationEnv.remove env acc_name in
-              (match aux acc with
-              | None -> None
-              | Some env' -> Some (env :: env'))
-          | envl ->
-              List.iter
-                (fun (env, pid) ->
-                   Printf.printf "*** %s %d\n" (CicNotationPp.pp_env env) pid)
-                envl ;
-              flush stdout ;
-              assert false |+ overlapping patterns, to be handled ... +|
+    let tag_of_term t =
+      let mask, tl = mask_of_cic t in
+      Hashtbl.hash mask, tl
+
+    let mask_of_appl_pattern = function
+      | Pt.UriPattern s -> Uri s, []
+      | Pt.VarPattern _ -> Blob, []
+      | Pt.ApplPattern pl -> Appl (List.map (fun _ -> Blob) pl), pl
+
+    let tag_of_pattern p =
+      let mask, pl = mask_of_appl_pattern p in
+      Hashtbl.hash mask, pl
+
+    type pattern_t = Pt.cic_appl_pattern
+    type term_t = Cic.annterm
+
+    let classify = function
+      | Pt.VarPattern _ -> Variable
+      | _ -> Constructor
+  end
+
+  module M = Matcher (Pattern32)
+
+  let compiler rows =
+    let match_cb rows =
+      prerr_endline (sprintf "match_cb on %d row(s)" (List.length rows));
+      let pl, pid = try List.hd rows with Not_found -> assert false in
+      (fun matched_terms ->
+        let env =
+          List.map2
+            (fun p t ->
+              match p with
+              | Pt.VarPattern name -> name, t
+              | _ -> assert false)
+            pl matched_terms
         in
-        (match aux t with
-        | None -> k terms envl
-        | Some env ->
-            let magic_env = CicNotationEnv.coalesce_env p_names env in
-            List.map (fun (env, pid) -> magic_env @ env, pid) envl)
-    | [] -> assert false)) *)
-
-let compiler0 rows match_cb fail_k =
-  let rec aux t k =
-    if t = [] then
-      k
-    else if P.are_empty t then
-      match_cb (P.matched t)
-    else
-      match P.horizontal_split t with
-      | t', [] ->
-          (match t' with
-          | []
-          | (_, [], _) :: _ -> assert false
-          | (_, Pt.Variable _ :: _, _) :: _ ->
-              variable_closure (aux (P.vertical_split t') k)
-          | _ ->
-              let tagl =
-                List.map
-                  (function
-                    | _, p :: _, _ -> fst (CicNotationTag.get_tag p)
-                    | _ -> assert false)
-                  t'
-              in
-              let clusters = P.partition t' tagl in
-              let ks =
-                List.map
-                  (fun (tag, cluster) ->
-                    let cluster' =
-                      List.map  (* add args as patterns heads *)
-                        (function
-                          | matched_p, p :: tl, pid ->
-                              let _, subpatterns = CicNotationTag.get_tag p in
-                              matched_p, subpatterns @ tl, pid
-                          | _ -> assert false)
-                        cluster
-                    in
-                    tag, aux cluster' k)
-                  clusters
-              in
-              constructor_closure ks k)
-      | t', tl -> aux t' (aux tl k)
-  in
-  let t = List.map (fun (p, pid) -> [], [p], pid) rows in
-  let matcher = aux t (fun _ _ -> fail_k ()) in
-  (fun term -> matcher [] [term])
-
-let extract_magic term =
-  let magic_map = ref [] in
-  let add_magic m =
-    let name = Util.fresh_name () in
-    magic_map := (name, m) :: !magic_map;
-    Pt.Variable (Pt.TermVar name)
-  in
-  let rec aux = function
-    | Pt.AttributedTerm (_, t) -> aux t
-    | Pt.Literal _
-    | Pt.Layout _ -> assert false
-    | Pt.Variable v -> Pt.Variable v
-    | Pt.Magic m -> add_magic m
-    | t -> Util.visit_ast aux t
-  in
-  let term' = aux term in
-  term', !magic_map
-
-let env_of_matched pl tl =
-  List.map2
-    (fun p t ->
-      match p, t with
-        Pt.Variable (Pt.TermVar name), _ ->
-          name, (Env.TermType, Env.TermValue t)
-      | Pt.Variable (Pt.NumVar name), (Pt.Num (s, _)) ->
-          name, (Env.NumType, Env.NumValue s)
-      | Pt.Variable (Pt.IdentVar name), (Pt.Ident (s, None)) ->
-          name, (Env.StringType, Env.StringValue s)
-      | _ -> assert false)
-    pl tl
-
-let decls_of_pattern p = 
-  List.map Env.declaration_of_var (Util.variables_of_term p)
-
-let rec compiler rows =
-  let rows', magic_maps =
-    List.split
-      (List.map
-        (fun (p, pid) ->
-          let p', map = extract_magic p in
-          (p', pid), (pid, map))
-        rows)
-  in
-  let magichecker map =
-    List.fold_left
-      (fun f (name, m) ->
-        let m_checker = compile_magic m in
-        (fun env ->
-          match m_checker (Env.lookup_term env name) env with
-          | None -> None
-          | Some env' -> f env'))
-      (fun env -> Some env)
-      map
-  in
-  let magichooser candidates =
-    List.fold_left
-      (fun f (pid, pl, checker) ->
-        (fun matched_terms ->
-          let env = env_of_matched pl matched_terms in
-          match checker env with
-          | None -> f matched_terms
-          | Some env -> Some (env, pid)))
-      (fun _ -> None)
-      candidates
-  in
-  let match_cb rows =
-    prerr_endline (sprintf "match_cb on %d row(s)" (List.length rows));
-    let candidates =
-      List.map
-        (fun (pl, pid) ->
-          let magic_map =
-            try List.assoc pid magic_maps with Not_found -> assert false
-          in
-          pid, pl, magichecker magic_map)
-        rows
+        Some (env, pid))
     in
-    (fun matched_terms _ -> magichooser candidates matched_terms)
-  in
-  compiler0 rows match_cb (fun _ -> None)
-
-and compile_magic = function
-  | Pt.Fold (kind, p_base, names, p_rec) ->
-      let p_rec_decls = decls_of_pattern p_rec in
-      let acc_name = try List.hd names with Failure _ -> assert false in
-      let t_magic = [p_base, 0; p_rec, 1] in
-      let compiled = compiler t_magic in
-      (fun term env ->
-        let rec aux term =
-          match compiled term with
-          | None -> None
-          | Some (env', 0) -> Some (env', [])
-          | Some (env', 1) ->
-              begin
-                let acc = Env.lookup_term env' acc_name in
-                let env'' = Env.remove env' acc_name in
-                match aux acc with
-                | None -> None
-                | Some (base_env, rec_envl) -> 
-                    Some (base_env, env'' :: rec_envl )
-              end
-          | _ -> assert false
-        in
-          match aux term with
-          | None -> None
-          | Some (base_env, rec_envl) ->
-              Some (base_env @ Env.coalesce_env p_rec_decls rec_envl))
-  | _ -> assert false
-
+    M.compiler rows match_cb (fun () -> None)
 end