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Diffstat (limited to 'contrib/subtac/equations.ml4')
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diff --git a/contrib/subtac/equations.ml4 b/contrib/subtac/equations.ml4 new file mode 100644 index 00000000..9d120019 --- /dev/null +++ b/contrib/subtac/equations.ml4 @@ -0,0 +1,1149 @@ +(* -*- compile-command: "make -C ../.. bin/coqtop.byte" -*- *) +(************************************************************************) +(* v * The Coq Proof Assistant / The Coq Development Team *) +(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *) +(* \VV/ **************************************************************) +(* // * This file is distributed under the terms of the *) +(* * GNU Lesser General Public License Version 2.1 *) +(************************************************************************) + +(*i camlp4deps: "parsing/grammar.cma" i*) +(*i camlp4use: "pa_extend.cmo" i*) + +(* $Id: subtac_cases.ml 11198 2008-07-01 17:03:43Z msozeau $ *) + +open Cases +open Util +open Names +open Nameops +open Term +open Termops +open Declarations +open Inductiveops +open Environ +open Sign +open Reductionops +open Typeops +open Type_errors + +open Rawterm +open Retyping +open Pretype_errors +open Evarutil +open Evarconv +open List +open Libnames + +type pat = + | PRel of int + | PCstr of constructor * pat list + | PInac of constr + +let coq_inacc = lazy (Coqlib.gen_constant "equations" ["Program";"Equality"] "inaccessible_pattern") + +let mkInac env c = + mkApp (Lazy.force coq_inacc, [| Typing.type_of env Evd.empty c ; c |]) + +let rec constr_of_pat ?(inacc=true) env = function + | PRel i -> mkRel i + | PCstr (c, p) -> + let c' = mkConstruct c in + mkApp (c', Array.of_list (constrs_of_pats ~inacc env p)) + | PInac r -> + if inacc then try mkInac env r with _ -> r else r + +and constrs_of_pats ?(inacc=true) env l = map (constr_of_pat ~inacc env) l + +let rec pat_vars = function + | PRel i -> Intset.singleton i + | PCstr (c, p) -> pats_vars p + | PInac _ -> Intset.empty + +and pats_vars l = + fold_left (fun vars p -> + let pvars = pat_vars p in + let inter = Intset.inter pvars vars in + if inter = Intset.empty then + Intset.union pvars vars + else error ("Non-linear pattern: variable " ^ + string_of_int (Intset.choose inter) ^ " appears twice")) + Intset.empty l + +let rec pats_of_constrs l = map pat_of_constr l +and pat_of_constr c = + match kind_of_term c with + | Rel i -> PRel i + | App (f, [| a ; c |]) when eq_constr f (Lazy.force coq_inacc) -> + PInac c + | App (f, args) when isConstruct f -> + PCstr (destConstruct f, pats_of_constrs (Array.to_list args)) + | Construct f -> PCstr (f, []) + | _ -> PInac c + +let inaccs_of_constrs l = map (fun x -> PInac x) l + +exception Conflict + +let rec pmatch p c = + match p, c with + | PRel i, t -> [i, t] + | PCstr (c, pl), PCstr (c', pl') when c = c' -> pmatches pl pl' + | PInac _, _ -> [] + | _, PInac _ -> [] + | _, _ -> raise Conflict + +and pmatches pl l = + match pl, l with + | [], [] -> [] + | hd :: tl, hd' :: tl' -> + pmatch hd hd' @ pmatches tl tl' + | _ -> raise Conflict + +let pattern_matches pl l = try Some (pmatches pl l) with Conflict -> None + +let rec pinclude p c = + match p, c with + | PRel i, t -> true + | PCstr (c, pl), PCstr (c', pl') when c = c' -> pincludes pl pl' + | PInac _, _ -> true + | _, PInac _ -> true + | _, _ -> false + +and pincludes pl l = + match pl, l with + | [], [] -> true + | hd :: tl, hd' :: tl' -> + pinclude hd hd' && pincludes tl tl' + | _ -> false + +let pattern_includes pl l = pincludes pl l + +(** Specialize by a substitution. *) + +let subst_tele s = replace_vars (List.map (fun (id, _, t) -> id, t) s) + +let subst_rel_subst k s c = + let rec aux depth c = + match kind_of_term c with + | Rel n -> + let k = n - depth in + if k >= 0 then + try lift depth (snd (assoc k s)) + with Not_found -> c + else c + | _ -> map_constr_with_binders succ aux depth c + in aux k c + +let subst_context s ctx = + let (_, ctx') = fold_right + (fun (id, b, t) (k, ctx') -> + (succ k, (id, Option.map (subst_rel_subst k s) b, subst_rel_subst k s t) :: ctx')) + ctx (0, []) + in ctx' + +let subst_rel_context k cstr ctx = + let (_, ctx') = fold_right + (fun (id, b, t) (k, ctx') -> + (succ k, (id, Option.map (substnl [cstr] k) b, substnl [cstr] k t) :: ctx')) + ctx (k, []) + in ctx' + +let rec lift_pat n k p = + match p with + | PRel i -> + if i >= k then PRel (i + n) + else p + | PCstr(c, pl) -> PCstr (c, lift_pats n k pl) + | PInac r -> PInac (liftn n k r) + +and lift_pats n k = map (lift_pat n k) + +let rec subst_pat env k t p = + match p with + | PRel i -> + if i = k then t + else if i > k then PRel (pred i) + else p + | PCstr(c, pl) -> + PCstr (c, subst_pats env k t pl) + | PInac r -> PInac (substnl [constr_of_pat ~inacc:false env t] (pred k) r) + +and subst_pats env k t = map (subst_pat env k t) + +let rec specialize s p = + match p with + | PRel i -> + if mem_assoc i s then + let b, t = assoc i s in + if b then PInac t + else PRel (destRel t) + else p + | PCstr(c, pl) -> + PCstr (c, specialize_pats s pl) + | PInac r -> PInac (specialize_constr s r) + +and specialize_constr s c = subst_rel_subst 0 s c +and specialize_pats s = map (specialize s) + +let specialize_patterns = function + | [] -> fun p -> p + | s -> specialize_pats s + +let specialize_rel_context s ctx = + snd (fold_right (fun (n, b, t) (k, ctx) -> + (succ k, (n, Option.map (subst_rel_subst k s) b, subst_rel_subst k s t) :: ctx)) + ctx (0, [])) + +let lift_contextn n k sign = + let rec liftrec k = function + | (na,c,t)::sign -> + (na,Option.map (liftn n k) c,liftn n k t)::(liftrec (k-1) sign) + | [] -> [] + in + liftrec (rel_context_length sign + k) sign + +type program = + signature * clause list + +and signature = identifier * rel_context * constr + +and clause = lhs * (constr, int) rhs + +and lhs = rel_context * identifier * pat list + +and ('a, 'b) rhs = + | Program of 'a + | Empty of 'b + +type splitting = + | Compute of clause + | Split of lhs * int * inductive_family * + unification_result array * splitting option array + +and unification_result = + rel_context * int * constr * pat * substitution option + +and substitution = (int * (bool * constr)) list + +type problem = identifier * lhs + +let rels_of_tele tele = rel_list 0 (List.length tele) + +let patvars_of_tele tele = map (fun c -> PRel (destRel c)) (rels_of_tele tele) + +let split_solves split prob = + match split with + | Compute (lhs, rhs) -> lhs = prob + | Split (lhs, id, indf, us, ls) -> lhs = prob + +let ids_of_constr c = + let rec aux vars c = + match kind_of_term c with + | Var id -> Idset.add id vars + | _ -> fold_constr aux vars c + in aux Idset.empty c + +let ids_of_constrs = + fold_left (fun acc x -> Idset.union (ids_of_constr x) acc) Idset.empty + +let idset_of_list = + fold_left (fun s x -> Idset.add x s) Idset.empty + +let intset_of_list = + fold_left (fun s x -> Intset.add x s) Intset.empty + +let solves split (delta, id, pats as prob) = + split_solves split prob && + Intset.equal (pats_vars pats) (intset_of_list (map destRel (rels_of_tele delta))) + +let check_judgment ctx c t = + ignore(Typing.check (push_rel_context ctx (Global.env ())) Evd.empty c t); true + +let check_context env ctx = + fold_right + (fun (_, _, t as decl) env -> + ignore(Typing.sort_of env Evd.empty t); push_rel decl env) + ctx env + +let split_context n c = + let after, before = list_chop n c in + match before with + | hd :: tl -> after, hd, tl + | [] -> raise (Invalid_argument "split_context") + +let split_tele n (ctx : rel_context) = + let rec aux after n l = + match n, l with + | 0, decl :: before -> before, decl, List.rev after + | n, decl :: before -> aux (decl :: after) (pred n) before + | _ -> raise (Invalid_argument "split_tele") + in aux [] n ctx + +let rec add_var_subst env subst n c = + if mem_assoc n subst then + let t = assoc n subst in + if eq_constr t c then subst + else unify env subst t c + else + let rel = mkRel n in + if rel = c then subst + else if dependent rel c then raise Conflict + else (n, c) :: subst + +and unify env subst x y = + match kind_of_term x, kind_of_term y with + | Rel n, _ -> add_var_subst env subst n y + | _, Rel n -> add_var_subst env subst n x + | App (c, l), App (c', l') when eq_constr c c' -> + unify_constrs env subst (Array.to_list l) (Array.to_list l') + | _, _ -> if eq_constr x y then subst else raise Conflict + +and unify_constrs (env : env) subst l l' = + if List.length l = List.length l' then + fold_left2 (unify env) subst l l' + else raise Conflict + +let fold_rel_context_with_binders f ctx init = + snd (List.fold_right (fun decl (depth, acc) -> + (succ depth, f depth decl acc)) ctx (0, init)) + +let dependent_rel_context (ctx : rel_context) k = + fold_rel_context_with_binders + (fun depth (n,b,t) acc -> + let r = mkRel (depth + k) in + acc || dependent r t || + (match b with + | Some b -> dependent r b + | None -> false)) + ctx false + +let liftn_between n k p c = + let rec aux depth c = match kind_of_term c with + | Rel i -> + if i <= depth then c + else if i-depth > p then c + else mkRel (i - n) + | _ -> map_constr_with_binders succ aux depth c + in aux k c + +let liftn_rel_context n k sign = + let rec liftrec k = function + | (na,c,t)::sign -> + (na,Option.map (liftn n k) c,liftn n k t)::(liftrec (k-1) sign) + | [] -> [] + in + liftrec (k + rel_context_length sign) sign + +let substnl_rel_context n l = + map_rel_context_with_binders (fun k -> substnl l (n+k-1)) + +let reduce_rel_context (ctx : rel_context) (subst : (int * (bool * constr)) list) = + let _, s, ctx' = + fold_left (fun (k, s, ctx') (n, b, t as decl) -> + match b with + | None -> (succ k, mkRel k :: s, ctx' @ [decl]) + | Some t -> (k, lift (pred k) t :: map (substnl [t] (pred k)) s, subst_rel_context 0 t ctx')) + (1, [], []) ctx + in + let s = rev s in + let s' = map (fun (korig, (b, knew)) -> korig, (b, substl s knew)) subst in + s', ctx' + +(* Compute the transitive closure of the dependency relation for a term in a context *) + +let rec dependencies_of_rel ctx k = + let (n,b,t) = nth ctx (pred k) in + let b = Option.map (lift k) b and t = lift k t in + let bdeps = match b with Some b -> dependencies_of_term ctx b | None -> Intset.empty in + Intset.union (Intset.singleton k) (Intset.union bdeps (dependencies_of_term ctx t)) + +and dependencies_of_term ctx t = + let rels = free_rels t in + Intset.fold (fun i -> Intset.union (dependencies_of_rel ctx i)) rels Intset.empty + +let subst_telescope k cstr ctx = + let (_, ctx') = fold_left + (fun (k, ctx') (id, b, t) -> + (succ k, (id, Option.map (substnl [cstr] k) b, substnl [cstr] k t) :: ctx')) + (k, []) ctx + in rev ctx' + +let lift_telescope n k sign = + let rec liftrec k = function + | (na,c,t)::sign -> + (na,Option.map (liftn n k) c,liftn n k t)::(liftrec (succ k) sign) + | [] -> [] + in liftrec k sign + +type ('a,'b) either = Inl of 'a | Inr of 'b + +let strengthen (ctx : rel_context) (t : constr) : rel_context * rel_context * (int * (int, int) either) list = + let rels = dependencies_of_term ctx t in + let len = length ctx in + let nbdeps = Intset.cardinal rels in + let lifting = len - nbdeps in (* Number of variables not linked to t *) + let rec aux k n acc m rest s = function + | decl :: ctx' -> + if Intset.mem k rels then + let rest' = subst_telescope 0 (mkRel (nbdeps + lifting - pred m)) rest in + aux (succ k) (succ n) (decl :: acc) m rest' ((k, Inl n) :: s) ctx' + else aux (succ k) n (subst_telescope 0 mkProp acc) (succ m) (decl :: rest) ((k, Inr m) :: s) ctx' + | [] -> rev acc, rev rest, s + in aux 1 1 [] 1 [] [] ctx + +let merge_subst (ctx', rest, s) = + let lenrest = length rest in + map (function (k, Inl x) -> (k, (false, mkRel (x + lenrest))) | (k, Inr x) -> k, (false, mkRel x)) s + +(* let simplify_subst s = *) +(* fold_left (fun s (k, t) -> *) +(* match kind_of_term t with *) +(* | Rel n when n = k -> s *) +(* | _ -> (k, t) :: s) *) +(* [] s *) + +let compose_subst s' s = + map (fun (k, (b, t)) -> (k, (b, specialize_constr s' t))) s + +let substitute_in_ctx n c ctx = + let rec aux k after = function + | [] -> [] + | (name, b, t as decl) :: before -> + if k = n then rev after @ (name, Some c, t) :: before + else aux (succ k) (decl :: after) before + in aux 1 [] ctx + +let rec reduce_subst (ctx : rel_context) (substacc : (int * (bool * constr)) list) (cursubst : (int * (bool * constr)) list) = + match cursubst with + | [] -> ctx, substacc + | (k, (b, t)) :: rest -> + if t = mkRel k then reduce_subst ctx substacc rest + else if noccur_between 1 k t then + (* The term to substitute refers only to previous variables. *) + let t' = lift (-k) t in + let ctx' = substitute_in_ctx k t' ctx in + reduce_subst ctx' substacc rest + else (* The term refers to variables declared after [k], so we have + to move these dependencies before [k]. *) + let (minctx, ctxrest, subst as str) = strengthen ctx t in + match assoc k subst with + | Inl _ -> error "Occurs check in substituted_context" + | Inr k' -> + let s = merge_subst str in + let ctx' = ctxrest @ minctx in + let rest' = + let substsubst (k', (b, t')) = + match kind_of_term (snd (assoc k' s)) with + | Rel k'' -> (k'', (b, specialize_constr s t')) + | _ -> error "Non-variable substituted for variable by strenghtening" + in map substsubst ((k, (b, t)) :: rest) + in + reduce_subst ctx' (compose_subst s substacc) rest' (* (compose_subst s ((k, (b, t)) :: rest)) *) + + +let substituted_context (subst : (int * constr) list) (ctx : rel_context) = + let _, subst = + fold_left (fun (k, s) _ -> + try let t = assoc k subst in + (succ k, (k, (true, t)) :: s) + with Not_found -> + (succ k, ((k, (false, mkRel k)) :: s))) + (1, []) ctx + in + let ctx', subst' = reduce_subst ctx subst subst in + reduce_rel_context ctx' subst' + +let unify_type before ty = + try + let envb = push_rel_context before (Global.env()) in + let IndType (indf, args) = find_rectype envb Evd.empty ty in + let ind, params = dest_ind_family indf in + let vs = map (Reduction.whd_betadeltaiota envb) args in + let cstrs = Inductiveops.arities_of_constructors envb ind in + let cstrs = + Array.mapi (fun i ty -> + let ty = prod_applist ty params in + let ctx, ty = decompose_prod_assum ty in + let ctx, ids = + let ids = ids_of_rel_context ctx in + fold_right (fun (n, b, t as decl) (acc, ids) -> + match n with Name _ -> (decl :: acc), ids + | Anonymous -> let id = next_name_away Anonymous ids in + ((Name id, b, t) :: acc), (id :: ids)) + ctx ([], ids) + in + let env' = push_rel_context ctx (Global.env ()) in + let IndType (indf, args) = find_rectype env' Evd.empty ty in + let ind, params = dest_ind_family indf in + let constr = applist (mkConstruct (ind, succ i), params @ rels_of_tele ctx) in + let constrpat = PCstr ((ind, succ i), inaccs_of_constrs params @ patvars_of_tele ctx) in + env', ctx, constr, constrpat, (* params @ *)args) + cstrs + in + let res = + Array.map (fun (env', ctxc, c, cpat, us) -> + let _beforelen = length before and ctxclen = length ctxc in + let fullctx = ctxc @ before in + try + let fullenv = push_rel_context fullctx (Global.env ()) in + let vs' = map (lift ctxclen) vs in + let subst = unify_constrs fullenv [] vs' us in + let subst', ctx' = substituted_context subst fullctx in + (ctx', ctxclen, c, cpat, Some subst') + with Conflict -> + (fullctx, ctxclen, c, cpat, None)) cstrs + in Some (res, indf) + with Not_found -> (* not an inductive type *) + None + +let rec id_of_rel n l = + match n, l with + | 0, (Name id, _, _) :: tl -> id + | n, _ :: tl -> id_of_rel (pred n) tl + | _, _ -> raise (Invalid_argument "id_of_rel") + +let constrs_of_lhs ?(inacc=true) env (ctx, _, pats) = + constrs_of_pats ~inacc (push_rel_context ctx env) pats + +let rec valid_splitting (f, delta, t, pats) tree = + split_solves tree (delta, f, pats) && + valid_splitting_tree (f, delta, t) tree + +and valid_splitting_tree (f, delta, t) = function + | Compute (lhs, Program rhs) -> + let subst = constrs_of_lhs ~inacc:false (Global.env ()) lhs in + ignore(check_judgment (pi1 lhs) rhs (substl subst t)); true + + | Compute ((ctx, id, lhs), Empty split) -> + let before, (x, _, ty), after = split_context split ctx in + let unify = + match unify_type before ty with + | Some (unify, _) -> unify + | None -> assert false + in + array_for_all (fun (_, _, _, _, x) -> x = None) unify + + | Split ((ctx, id, lhs), rel, indf, unifs, ls) -> + let before, (id, _, ty), after = split_tele (pred rel) ctx in + let unify, indf' = Option.get (unify_type before ty) in + assert(indf = indf'); + if not (array_exists (fun (_, _, _, _, x) -> x <> None) unify) then false + else + let ok, splits = + Array.fold_left (fun (ok, splits as acc) (ctx', ctxlen, cstr, cstrpat, subst) -> + match subst with + | None -> acc + | Some subst -> +(* let env' = push_rel_context ctx' (Global.env ()) in *) +(* let ctx_correct = *) +(* ignore(check_context env' (subst_context subst ctxc)); *) +(* ignore(check_context env' (subst_context subst before)); *) +(* true *) +(* in *) + let newdelta = + subst_context subst (subst_rel_context 0 cstr + (lift_contextn ctxlen 0 after)) @ before in + let liftpats = lift_pats ctxlen rel lhs in + let newpats = specialize_patterns subst (subst_pats (Global.env ()) rel cstrpat liftpats) in + (ok, (f, newdelta, newpats) :: splits)) + (true, []) unify + in + let subst = List.map2 (fun (id, _, _) x -> out_name id, x) delta + (constrs_of_pats ~inacc:false (Global.env ()) lhs) + in + let t' = replace_vars subst t in + ok && for_all + (fun (f, delta', pats') -> + array_exists (function None -> false | Some tree -> valid_splitting (f, delta', t', pats') tree) ls) splits + +let valid_tree (f, delta, t) tree = + valid_splitting (f, delta, t, patvars_of_tele delta) tree + +let is_constructor c = + match kind_of_term (fst (decompose_app c)) with + | Construct _ -> true + | _ -> false + +let find_split (_, _, curpats : lhs) (_, _, patcs : lhs) = + let rec find_split_pat curpat patc = + match patc with + | PRel _ -> None + | PCstr (f, args) -> + (match curpat with + | PCstr (f', args') when f = f' -> (* Already split at this level, continue *) + find_split_pats args' args + | PRel i -> (* Split on i *) Some i + | PInac c when isRel c -> Some (destRel c) + | _ -> None) + | PInac _ -> None + + and find_split_pats curpats patcs = + assert(List.length curpats = List.length patcs); + fold_left2 (fun acc -> + match acc with + | None -> find_split_pat | _ -> fun _ _ -> acc) + None curpats patcs + in find_split_pats curpats patcs + +open Pp +open Termops + +let pr_constr_pat env c = + let pr = print_constr_env env c in + match kind_of_term c with + | App _ -> str "(" ++ pr ++ str ")" + | _ -> pr + +let pr_pat env c = + try + let patc = constr_of_pat env c in + try pr_constr_pat env patc with _ -> str"pr_constr_pat raised an exception" + with _ -> str"constr_of_pat raised an exception" + +let pr_context env c = + let pr_decl (id,b,_) = + let bstr = match b with Some b -> str ":=" ++ spc () ++ print_constr_env env b | None -> mt() in + let idstr = match id with Name id -> pr_id id | Anonymous -> str"_" in + idstr ++ bstr + in + prlist_with_sep pr_spc pr_decl (List.rev c) +(* Printer.pr_rel_context env c *) + +let pr_lhs env (delta, f, patcs) = + let env = push_rel_context delta env in + let ctx = pr_context env delta in + (if delta = [] then ctx else str "[" ++ ctx ++ str "]" ++ spc ()) + ++ pr_id f ++ spc () ++ prlist_with_sep spc (pr_pat env) patcs + +let pr_rhs env = function + | Empty var -> spc () ++ str ":=!" ++ spc () ++ print_constr_env env (mkRel var) + | Program rhs -> spc () ++ str ":=" ++ spc () ++ print_constr_env env rhs + +let pr_clause env (lhs, rhs) = + pr_lhs env lhs ++ + (let env' = push_rel_context (pi1 lhs) env in + pr_rhs env' rhs) + +(* let pr_splitting env = function *) +(* | Compute cl -> str "Compute " ++ pr_clause env cl *) +(* | Split (lhs, n, indf, results, splits) -> *) + +(* let pr_unification_result (ctx, n, c, pat, subst) = *) + +(* unification_result array * splitting option array *) + +let pr_clauses env = + prlist_with_sep fnl (pr_clause env) + +let lhs_includes (delta, _, patcs : lhs) (delta', _, patcs' : lhs) = + pattern_includes patcs patcs' + +let lhs_matches (delta, _, patcs : lhs) (delta', _, patcs' : lhs) = + pattern_matches patcs patcs' + +let rec split_on env var (delta, f, curpats as lhs) clauses = + let before, (id, _, ty), after = split_tele (pred var) delta in + let unify, indf = + match unify_type before ty with + | Some r -> r + | None -> assert false (* We decided... so it better be inductive *) + in + let clauses = ref clauses in + let splits = + Array.map (fun (ctx', ctxlen, cstr, cstrpat, s) -> + match s with + | None -> None + | Some s -> + (* ctx' |- s cstr, s cstrpat *) + let newdelta = + subst_context s (subst_rel_context 0 cstr + (lift_contextn ctxlen 1 after)) @ ctx' in + let liftpats = + (* delta |- curpats -> before; ctxc; id; after |- liftpats *) + lift_pats ctxlen (succ var) curpats + in + let liftpat = (* before; ctxc |- cstrpat -> before; ctxc; after |- liftpat *) + lift_pat (pred var) 1 cstrpat + in + let substpat = (* before; ctxc; after |- liftpats[id:=liftpat] *) + subst_pats env var liftpat liftpats + in + let lifts = (* before; ctxc |- s : newdelta -> + before; ctxc; after |- lifts : newdelta ; after *) + map (fun (k,(b,x)) -> (pred var + k, (b, lift (pred var) x))) s + in + let newpats = specialize_patterns lifts substpat in + let newlhs = (newdelta, f, newpats) in + let matching, rest = + fold_right (fun (lhs, rhs as clause) (matching, rest) -> + if lhs_includes newlhs lhs then + (clause :: matching, rest) + else (matching, clause :: rest)) + !clauses ([], []) + in + clauses := rest; + if matching = [] then ( + (* Try finding a splittable variable *) + let (id, _) = + fold_right (fun (id, _, ty as decl) (accid, ctx) -> + match accid with + | Some _ -> (accid, ctx) + | None -> + match unify_type ctx ty with + | Some (unify, indf) -> + if array_for_all (fun (_, _, _, _, x) -> x = None) unify then + (Some id, ctx) + else (None, decl :: ctx) + | None -> (None, decl :: ctx)) + newdelta (None, []) + in + match id with + | None -> + errorlabstrm "deppat" + (str "Non-exhaustive pattern-matching, no clause found for:" ++ fnl () ++ + pr_lhs env newlhs) + | Some id -> + Some (Compute (newlhs, Empty (fst (lookup_rel_id (out_name id) newdelta)))) + ) else ( + let splitting = make_split_aux env newlhs matching in + Some splitting)) + unify + in +(* if !clauses <> [] then *) +(* errorlabstrm "deppat" *) +(* (str "Impossible clauses:" ++ fnl () ++ pr_clauses env !clauses); *) + Split (lhs, var, indf, unify, splits) + +and make_split_aux env lhs clauses = + let split = + fold_left (fun acc (lhs', rhs) -> + match acc with + | None -> find_split lhs lhs' + | _ -> acc) None clauses + in + match split with + | Some var -> split_on env var lhs clauses + | None -> + (match clauses with + | [] -> error "No clauses left" + | [(lhs', rhs)] -> + (* No need to split anymore, fix the environments so that they are correctly aligned. *) + (match lhs_matches lhs' lhs with + | Some s -> + let s = map (fun (x, p) -> x, (true, constr_of_pat ~inacc:false env p)) s in + let rhs' = match rhs with + | Program c -> Program (specialize_constr s c) + | Empty i -> Empty (destRel (snd (assoc i s))) + in Compute ((pi1 lhs, pi2 lhs, specialize_patterns s (pi3 lhs')), rhs') + | None -> anomaly "Non-matching clauses at a leaf of the splitting tree") + | _ -> + errorlabstrm "make_split_aux" + (str "Overlapping clauses:" ++ fnl () ++ pr_clauses env clauses)) + +let make_split env (f, delta, t) clauses = + make_split_aux env (delta, f, patvars_of_tele delta) clauses + +open Evd +open Evarutil + +let lift_substitution n s = map (fun (k, x) -> (k + n, x)) s +let map_substitution s t = map (subst_rel_subst 0 s) t + +let term_of_tree status isevar env (i, delta, ty) ann tree = +(* let envrec = match ann with *) +(* | None -> [] *) +(* | Some (loc, i) -> *) +(* let (n, t) = lookup_rel_id i delta in *) +(* let t' = lift n t in *) + + +(* in *) + let rec aux = function + | Compute ((ctx, _, pats as lhs), Program rhs) -> + let ty' = substl (rev (constrs_of_lhs ~inacc:false env lhs)) ty in + let body = it_mkLambda_or_LetIn rhs ctx and typ = it_mkProd_or_LetIn ty' ctx in + mkCast(body, DEFAULTcast, typ), typ + + | Compute ((ctx, _, pats as lhs), Empty split) -> + let ty' = substl (rev (constrs_of_lhs ~inacc:false env lhs)) ty in + let split = (Name (id_of_string "split"), + Some (Class_tactics.coq_nat_of_int (1 + (length ctx - split))), + Lazy.force Class_tactics.coq_nat) + in + let ty' = it_mkProd_or_LetIn ty' ctx in + let let_ty' = mkLambda_or_LetIn split (lift 1 ty') in + let term = e_new_evar isevar env ~src:(dummy_loc, QuestionMark (Define true)) let_ty' in + term, ty' + + | Split ((ctx, _, pats as lhs), rel, indf, unif, sp) -> + let before, decl, after = split_tele (pred rel) ctx in + let ty' = substl (rev (constrs_of_lhs ~inacc:false env lhs)) ty in + let branches = + array_map2 (fun (ctx', ctxlen, cstr, cstrpat, subst) split -> + match split with + | Some s -> aux s + | None -> + (* dead code, inversion will find a proof of False by splitting on the rel'th hyp *) + Class_tactics.coq_nat_of_int rel, Lazy.force Class_tactics.coq_nat) + unif sp + in + let branches_ctx = + Array.mapi (fun i (br, brt) -> (id_of_string ("m_" ^ string_of_int i), Some br, brt)) + branches + in + let n, branches_lets = + Array.fold_left (fun (n, lets) (id, b, t) -> + (succ n, (Name id, Option.map (lift n) b, lift n t) :: lets)) + (0, []) branches_ctx + in + let liftctx = lift_contextn (Array.length branches) 0 ctx in + let case = + let ty = it_mkProd_or_LetIn ty' liftctx in + let ty = it_mkLambda_or_LetIn ty branches_lets in + let nbbranches = (Name (id_of_string "branches"), + Some (Class_tactics.coq_nat_of_int (length branches_lets)), + Lazy.force Class_tactics.coq_nat) + in + let nbdiscr = (Name (id_of_string "target"), + Some (Class_tactics.coq_nat_of_int (length before)), + Lazy.force Class_tactics.coq_nat) + in + let ty = it_mkLambda_or_LetIn (lift 2 ty) [nbbranches;nbdiscr] in + let term = e_new_evar isevar env ~src:(dummy_loc, QuestionMark status) ty in + term + in + let casetyp = it_mkProd_or_LetIn ty' ctx in + mkCast(case, DEFAULTcast, casetyp), casetyp + + in aux tree + +open Topconstr +open Constrintern +open Decl_kinds + +type equation = constr_expr * (constr_expr, identifier located) rhs + +let locate_reference qid = + match Nametab.extended_locate qid with + | TrueGlobal ref -> true + | SyntacticDef kn -> true + +let is_global id = + try + locate_reference (make_short_qualid id) + with Not_found -> + false + +let is_freevar ids env x = + try + if Idset.mem x ids then false + else + try ignore(Environ.lookup_named x env) ; false + with _ -> not (is_global x) + with _ -> true + +let ids_of_patc c ?(bound=Idset.empty) l = + let found id bdvars l = + if not (is_freevar bdvars (Global.env ()) (snd id)) then l + else if List.exists (fun (_, id') -> id' = snd id) l then l + else id :: l + in + let rec aux bdvars l c = match c with + | CRef (Ident lid) -> found lid bdvars l + | CNotation (_, "{ _ : _ | _ }", ((CRef (Ident (_, id))) :: _, _)) when not (Idset.mem id bdvars) -> + fold_constr_expr_with_binders (fun a l -> Idset.add a l) aux (Idset.add id bdvars) l c + | c -> fold_constr_expr_with_binders (fun a l -> Idset.add a l) aux bdvars l c + in aux bound l c + +let interp_pats i isevar env impls pat sign recu = + let bound = Idset.singleton i in + let vars = ids_of_patc pat ~bound [] in + let varsctx, env' = + fold_right (fun (loc, id) (ctx, env) -> + let decl = + let ty = e_new_evar isevar env ~src:(loc, BinderType (Name id)) (new_Type ()) in + (Name id, None, ty) + in + decl::ctx, push_rel decl env) + vars ([], env) + in + let pats = + let patenv = match recu with None -> env' | Some ty -> push_named (i, None, ty) env' in + let patt, _ = interp_constr_evars_impls ~evdref:isevar patenv ~impls:([],[]) pat in + match kind_of_term patt with + | App (m, args) -> + if not (eq_constr m (mkRel (succ (length varsctx)))) then + user_err_loc (constr_loc pat, "interp_pats", + str "Expecting a pattern for " ++ pr_id i) + else Array.to_list args + | _ -> user_err_loc (constr_loc pat, "interp_pats", + str "Error parsing pattern: unnexpected left-hand side") + in + isevar := nf_evar_defs !isevar; + (nf_rel_context_evar (Evd.evars_of !isevar) varsctx, + nf_env_evar (Evd.evars_of !isevar) env', + rev_map (nf_evar (Evd.evars_of !isevar)) pats) + +let interp_eqn i isevar env impls sign arity recu (pats, rhs) = + let ctx, env', patcs = interp_pats i isevar env impls pats sign recu in + let rhs' = match rhs with + | Program p -> + let ty = nf_isevar !isevar (substl patcs arity) in + Program (interp_casted_constr_evars isevar env' ~impls p ty) + | Empty lid -> Empty (fst (lookup_rel_id (snd lid) ctx)) + in ((ctx, i, pats_of_constrs (rev patcs)), rhs') + +open Entries + +open Tacmach +open Tacexpr +open Tactics +open Tacticals + +let contrib_tactics_path = + make_dirpath (List.map id_of_string ["Equality";"Program";"Coq"]) + +let tactics_tac s = + make_kn (MPfile contrib_tactics_path) (make_dirpath []) (mk_label s) + +let equations_tac = lazy + (Tacinterp.eval_tactic + (TacArg(TacCall(dummy_loc, + ArgArg(dummy_loc, tactics_tac "equations"), [])))) + +let define_by_eqs with_comp i (l,ann) t nt eqs = + let env = Global.env () in + let isevar = ref (create_evar_defs Evd.empty) in + let (env', sign), impls = interp_context_evars isevar env l in + let arity = interp_type_evars isevar env' t in + let sign = nf_rel_context_evar (Evd.evars_of !isevar) sign in + let arity = nf_evar (Evd.evars_of !isevar) arity in + let arity = + if with_comp then + let compid = add_suffix i "_comp" in + let ce = + { const_entry_body = it_mkLambda_or_LetIn arity sign; + const_entry_type = None; + const_entry_opaque = false; + const_entry_boxed = false} + in + let c = + Declare.declare_constant compid (DefinitionEntry ce, IsDefinition Definition) + in mkApp (mkConst c, rel_vect 0 (length sign)) + else arity + in + let env = Global.env () in + let ty = it_mkProd_or_LetIn arity sign in + let data = Command.compute_interning_datas env Constrintern.Recursive [] [i] [ty] [impls] in + let fixdecls = [(Name i, None, ty)] in + let fixenv = push_rel_context fixdecls env in + let equations = + States.with_heavy_rollback (fun () -> + Option.iter (Command.declare_interning_data data) nt; + map (interp_eqn i isevar fixenv data sign arity None) eqs) () + in + let sign = nf_rel_context_evar (Evd.evars_of !isevar) sign in + let arity = nf_evar (Evd.evars_of !isevar) arity in + let prob = (i, sign, arity) in + let fixenv = nf_env_evar (Evd.evars_of !isevar) fixenv in + let fixdecls = nf_rel_context_evar (Evd.evars_of !isevar) fixdecls in + (* let ce = check_evars fixenv Evd.empty !isevar in *) + (* List.iter (function (_, _, Program rhs) -> ce rhs | _ -> ()) equations; *) + let is_recursive, env' = + let occur_eqn ((ctx, _, _), rhs) = + match rhs with + | Program c -> dependent (mkRel (succ (length ctx))) c + | _ -> false + in if exists occur_eqn equations then true, fixenv else false, env + in + let split = make_split env' prob equations in + (* if valid_tree prob split then *) + let status = (* if is_recursive then Expand else *) Define false in + let t, ty = term_of_tree status isevar env' prob ann split in + let undef = undefined_evars !isevar in + let t, ty = if is_recursive then + (it_mkLambda_or_LetIn t fixdecls, it_mkProd_or_LetIn ty fixdecls) + else t, ty + in + let obls, t', ty' = + Eterm.eterm_obligations env i !isevar (Evd.evars_of undef) 0 ~status t ty + in + if is_recursive then + ignore(Subtac_obligations.add_mutual_definitions [(i, t', ty', impls, obls)] [] + ~tactic:(Lazy.force equations_tac) + (Command.IsFixpoint [None, CStructRec])) + else + ignore(Subtac_obligations.add_definition + ~implicits:impls i t' ty' ~tactic:(Lazy.force equations_tac) obls) + +module Gram = Pcoq.Gram +module Vernac = Pcoq.Vernac_ +module Tactic = Pcoq.Tactic + +module DeppatGram = +struct + let gec s = Gram.Entry.create ("Deppat."^s) + + let deppat_equations : equation list Gram.Entry.e = gec "deppat_equations" + + let binders_let2 : (local_binder list * (identifier located option * recursion_order_expr)) Gram.Entry.e = gec "binders_let2" + +(* let where_decl : decl_notation Gram.Entry.e = gec "where_decl" *) + +end + +open Rawterm +open DeppatGram +open Util +open Pcoq +open Prim +open Constr +open G_vernac + +GEXTEND Gram + GLOBAL: (* deppat_gallina_loc *) deppat_equations binders_let2; + + deppat_equations: + [ [ l = LIST1 equation SEP ";" -> l ] ] + ; + + binders_let2: + [ [ l = binders_let_fixannot -> l ] ] + ; + + equation: + [ [ c = Constr.lconstr; r=rhs -> (c, r) ] ] + ; + + rhs: + [ [ ":=!"; id = identref -> Empty id + |":="; c = Constr.lconstr -> Program c + ] ] + ; + + END + +type 'a deppat_equations_argtype = (equation list, 'a) Genarg.abstract_argument_type + +let (wit_deppat_equations : Genarg.tlevel deppat_equations_argtype), + (globwit_deppat_equations : Genarg.glevel deppat_equations_argtype), + (rawwit_deppat_equations : Genarg.rlevel deppat_equations_argtype) = + Genarg.create_arg "deppat_equations" + +type 'a binders_let2_argtype = (local_binder list * (identifier located option * recursion_order_expr), 'a) Genarg.abstract_argument_type + +let (wit_binders_let2 : Genarg.tlevel binders_let2_argtype), + (globwit_binders_let2 : Genarg.glevel binders_let2_argtype), + (rawwit_binders_let2 : Genarg.rlevel binders_let2_argtype) = + Genarg.create_arg "binders_let2" + +type 'a decl_notation_argtype = (Vernacexpr.decl_notation, 'a) Genarg.abstract_argument_type + +let (wit_decl_notation : Genarg.tlevel decl_notation_argtype), + (globwit_decl_notation : Genarg.glevel decl_notation_argtype), + (rawwit_decl_notation : Genarg.rlevel decl_notation_argtype) = + Genarg.create_arg "decl_notation" + +let equations wc i l t nt eqs = + try define_by_eqs wc i l t nt eqs + with e -> msg (Cerrors.explain_exn e) + +VERNAC COMMAND EXTEND Define_equations +| [ "Equations" ident(i) binders_let2(l) ":" lconstr(t) ":=" deppat_equations(eqs) + decl_notation(nt) ] -> + [ equations true i l t nt eqs ] + END + +VERNAC COMMAND EXTEND Define_equations2 +| [ "Equations_nocomp" ident(i) binders_let2(l) ":" lconstr(t) ":=" deppat_equations(eqs) + decl_notation(nt) ] -> + [ equations false i l t nt eqs ] +END + +let rec int_of_coq_nat c = + match kind_of_term c with + | App (f, [| arg |]) -> succ (int_of_coq_nat arg) + | _ -> 0 + +let solve_equations_goal destruct_tac tac gl = + let concl = pf_concl gl in + let targetn, branchesn, targ, brs, b = + match kind_of_term concl with + | LetIn (Name target, targ, _, b) -> + (match kind_of_term b with + | LetIn (Name branches, brs, _, b) -> + target, branches, int_of_coq_nat targ, int_of_coq_nat brs, b + | _ -> error "Unnexpected goal") + | _ -> error "Unnexpected goal" + in + let branches, b = + let rec aux n c = + if n = 0 then [], c + else match kind_of_term c with + | LetIn (Name id, br, brt, b) -> + let rest, b = aux (pred n) b in + (id, br, brt) :: rest, b + | _ -> error "Unnexpected goal" + in aux brs b + in + let ids = targetn :: branchesn :: map pi1 branches in + let cleantac = tclTHEN (intros_using ids) (thin ids) in + let dotac = tclDO (succ targ) intro in + let subtacs = + tclTHENS destruct_tac + (map (fun (id, br, brt) -> tclTHEN (letin_tac None (Name id) br (Some brt) onConcl) tac) branches) + in tclTHENLIST [cleantac ; dotac ; subtacs] gl + +TACTIC EXTEND solve_equations + [ "solve_equations" tactic(destruct) tactic(tac) ] -> [ solve_equations_goal (snd destruct) (snd tac) ] + END + +let coq_eq = Lazy.lazy_from_fun Coqlib.build_coq_eq +let coq_eq_refl = lazy ((Coqlib.build_coq_eq_data ()).Coqlib.refl) + +let coq_heq = lazy (Coqlib.coq_constant "mkHEq" ["Logic";"JMeq"] "JMeq") +let coq_heq_refl = lazy (Coqlib.coq_constant "mkHEq" ["Logic";"JMeq"] "JMeq_refl") + +let specialize_hyp id gl = + let env = pf_env gl in + let ty = pf_get_hyp_typ gl id in + let evars = ref (create_evar_defs (project gl)) in + let rec aux in_eqs acc ty = + match kind_of_term ty with + | Prod (_, t, b) -> + (match kind_of_term t with + | App (eq, [| eqty; x; y |]) when eq_constr eq (Lazy.force coq_eq) -> + let pt = mkApp (Lazy.force coq_eq, [| eqty; x; x |]) in + let p = mkApp (Lazy.force coq_eq_refl, [| eqty; x |]) in + if e_conv env evars pt t then + aux true (mkApp (acc, [| p |])) (subst1 p b) + else error "Unconvertible members of an homogeneous equality" + | App (heq, [| eqty; x; eqty'; y |]) when eq_constr heq (Lazy.force coq_heq) -> + let pt = mkApp (Lazy.force coq_heq, [| eqty; x; eqty; x |]) in + let p = mkApp (Lazy.force coq_heq_refl, [| eqty; x |]) in + if e_conv env evars pt t then + aux true (mkApp (acc, [| p |])) (subst1 p b) + else error "Unconvertible members of an heterogeneous equality" + | _ -> + if in_eqs then acc, in_eqs, ty + else + let e = e_new_evar evars env t in + aux false (mkApp (acc, [| e |])) (subst1 e b)) + | t -> acc, in_eqs, ty + in + try + let acc, worked, ty = aux false (mkVar id) ty in + let ty = Evarutil.nf_isevar !evars ty in + if worked then + tclTHENFIRST + (fun g -> Tacmach.internal_cut true id ty g) + (exact_no_check (Evarutil.nf_isevar !evars acc)) gl + else tclFAIL 0 (str "Nothing to do in hypothesis " ++ pr_id id) gl + with e -> tclFAIL 0 (Cerrors.explain_exn e) gl + +TACTIC EXTEND specialize_hyp +[ "specialize_hypothesis" constr(c) ] -> [ + match kind_of_term c with + | Var id -> specialize_hyp id + | _ -> tclFAIL 0 (str "Not an hypothesis") ] +END |