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authorGravatar Stephane Glondu <steph@glondu.net>2010-07-21 09:46:51 +0200
committerGravatar Stephane Glondu <steph@glondu.net>2010-07-21 09:46:51 +0200
commit5b7eafd0f00a16d78f99a27f5c7d5a0de77dc7e6 (patch)
tree631ad791a7685edafeb1fb2e8faeedc8379318ae /contrib/subtac
parentda178a880e3ace820b41d38b191d3785b82991f5 (diff)
Imported Upstream snapshot 8.3~beta0+13298
Diffstat (limited to 'contrib/subtac')
-rw-r--r--contrib/subtac/equations.ml41149
-rw-r--r--contrib/subtac/eterm.ml221
-rw-r--r--contrib/subtac/eterm.mli32
-rw-r--r--contrib/subtac/g_eterm.ml427
-rw-r--r--contrib/subtac/g_subtac.ml4156
-rw-r--r--contrib/subtac/subtac.ml241
-rw-r--r--contrib/subtac/subtac.mli2
-rw-r--r--contrib/subtac/subtac_cases.ml2032
-rw-r--r--contrib/subtac/subtac_cases.mli23
-rw-r--r--contrib/subtac/subtac_classes.ml194
-rw-r--r--contrib/subtac/subtac_classes.mli42
-rw-r--r--contrib/subtac/subtac_coercion.ml504
-rw-r--r--contrib/subtac/subtac_coercion.mli4
-rw-r--r--contrib/subtac/subtac_command.ml466
-rw-r--r--contrib/subtac/subtac_command.mli50
-rw-r--r--contrib/subtac/subtac_errors.ml24
-rw-r--r--contrib/subtac/subtac_errors.mli15
-rw-r--r--contrib/subtac/subtac_obligations.ml596
-rw-r--r--contrib/subtac/subtac_obligations.mli63
-rw-r--r--contrib/subtac/subtac_pretyping.ml137
-rw-r--r--contrib/subtac/subtac_pretyping.mli24
-rw-r--r--contrib/subtac/subtac_pretyping_F.ml641
-rw-r--r--contrib/subtac/subtac_utils.ml474
-rw-r--r--contrib/subtac/subtac_utils.mli133
-rw-r--r--contrib/subtac/test/ListDep.v49
-rw-r--r--contrib/subtac/test/ListsTest.v99
-rw-r--r--contrib/subtac/test/Mutind.v20
-rw-r--r--contrib/subtac/test/Test1.v16
-rw-r--r--contrib/subtac/test/euclid.v24
-rw-r--r--contrib/subtac/test/id.v46
-rw-r--r--contrib/subtac/test/measure.v20
-rw-r--r--contrib/subtac/test/rec.v65
-rw-r--r--contrib/subtac/test/take.v34
-rw-r--r--contrib/subtac/test/wf.v48
34 files changed, 0 insertions, 7671 deletions
diff --git a/contrib/subtac/equations.ml4 b/contrib/subtac/equations.ml4
deleted file mode 100644
index 9d120019..00000000
--- a/contrib/subtac/equations.ml4
+++ /dev/null
@@ -1,1149 +0,0 @@
-(* -*- 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
diff --git a/contrib/subtac/eterm.ml b/contrib/subtac/eterm.ml
deleted file mode 100644
index 00a69bba..00000000
--- a/contrib/subtac/eterm.ml
+++ /dev/null
@@ -1,221 +0,0 @@
-(* -*- compile-command: "make -C ../.. bin/coqtop.byte" -*- *)
-(**
- - Get types of existentials ;
- - Flatten dependency tree (prefix order) ;
- - Replace existentials by De Bruijn indices in term, applied to the right arguments ;
- - Apply term prefixed by quantification on "existentials".
-*)
-
-open Term
-open Sign
-open Names
-open Evd
-open List
-open Pp
-open Util
-open Subtac_utils
-open Proof_type
-
-let trace s =
- if !Flags.debug then (msgnl s; msgerr s)
- else ()
-
-let succfix (depth, fixrels) =
- (succ depth, List.map succ fixrels)
-
-type oblinfo =
- { ev_name: int * identifier;
- ev_hyps: named_context;
- ev_status: obligation_definition_status;
- ev_chop: int option;
- ev_loc: Util.loc;
- ev_typ: types;
- ev_tac: Tacexpr.raw_tactic_expr option;
- ev_deps: Intset.t }
-
-(** Substitute evar references in t using De Bruijn indices,
- where n binders were passed through. *)
-
-let subst_evar_constr evs n t =
- let seen = ref Intset.empty in
- let transparent = ref Idset.empty in
- let evar_info id = List.assoc id evs in
- let rec substrec (depth, fixrels) c = match kind_of_term c with
- | Evar (k, args) ->
- let { ev_name = (id, idstr) ;
- ev_hyps = hyps ; ev_chop = chop } =
- try evar_info k
- with Not_found ->
- anomaly ("eterm: existential variable " ^ string_of_int k ^ " not found")
- in
- seen := Intset.add id !seen;
- (* Evar arguments are created in inverse order,
- and we must not apply to defined ones (i.e. LetIn's)
- *)
- let args =
- let n = match chop with None -> 0 | Some c -> c in
- let (l, r) = list_chop n (List.rev (Array.to_list args)) in
- List.rev r
- in
- let args =
- let rec aux hyps args acc =
- match hyps, args with
- ((_, None, _) :: tlh), (c :: tla) ->
- aux tlh tla ((substrec (depth, fixrels) c) :: acc)
- | ((_, Some _, _) :: tlh), (_ :: tla) ->
- aux tlh tla acc
- | [], [] -> acc
- | _, _ -> acc (*failwith "subst_evars: invalid argument"*)
- in aux hyps args []
- in
- if List.exists (fun x -> match kind_of_term x with Rel n -> List.mem n fixrels | _ -> false) args then
- transparent := Idset.add idstr !transparent;
- mkApp (mkVar idstr, Array.of_list args)
- | Fix _ ->
- map_constr_with_binders succfix substrec (depth, 1 :: fixrels) c
- | _ -> map_constr_with_binders succfix substrec (depth, fixrels) c
- in
- let t' = substrec (0, []) t in
- t', !seen, !transparent
-
-
-(** Substitute variable references in t using De Bruijn indices,
- where n binders were passed through. *)
-let subst_vars acc n t =
- let var_index id = Util.list_index id acc in
- let rec substrec depth c = match kind_of_term c with
- | Var v -> (try mkRel (depth + (var_index v)) with Not_found -> c)
- | _ -> map_constr_with_binders succ substrec depth c
- in
- substrec 0 t
-
-(** Rewrite type of an evar ([ H1 : t1, ... Hn : tn |- concl ])
- to a product : forall H1 : t1, ..., forall Hn : tn, concl.
- Changes evars and hypothesis references to variable references.
- A little optimization: don't include unnecessary let-ins and their dependencies.
-*)
-let etype_of_evar evs hyps concl =
- let rec aux acc n = function
- (id, copt, t) :: tl ->
- let t', s, trans = subst_evar_constr evs n t in
- let t'' = subst_vars acc 0 t' in
- let rest, s', trans' = aux (id :: acc) (succ n) tl in
- let s' = Intset.union s s' in
- let trans' = Idset.union trans trans' in
- (match copt with
- Some c ->
-(* if noccurn 1 rest then lift (-1) rest, s', trans' *)
-(* else *)
- let c', s'', trans'' = subst_evar_constr evs n c in
- let c' = subst_vars acc 0 c' in
- mkNamedProd_or_LetIn (id, Some c', t'') rest,
- Intset.union s'' s',
- Idset.union trans'' trans'
- | None ->
- mkNamedProd_or_LetIn (id, None, t'') rest, s', trans')
- | [] ->
- let t', s, trans = subst_evar_constr evs n concl in
- subst_vars acc 0 t', s, trans
- in aux [] 0 (rev hyps)
-
-
-open Tacticals
-
-let trunc_named_context n ctx =
- let len = List.length ctx in
- list_firstn (len - n) ctx
-
-let rec chop_product n t =
- if n = 0 then Some t
- else
- match kind_of_term t with
- | Prod (_, _, b) -> if noccurn 1 b then chop_product (pred n) (Termops.pop b) else None
- | _ -> None
-
-let evar_dependencies evm ev =
- let one_step deps =
- Intset.fold (fun ev s ->
- let evi = Evd.find evm ev in
- Intset.union (Evarutil.evars_of_evar_info evi) s)
- deps deps
- in
- let rec aux deps =
- let deps' = one_step deps in
- if Intset.equal deps deps' then deps
- else aux deps'
- in aux (Intset.singleton ev)
-
-let sort_dependencies evl =
- List.sort (fun (_, _, deps) (_, _, deps') ->
- if Intset.subset deps deps' then (* deps' depends on deps *) -1
- else if Intset.subset deps' deps then 1
- else Intset.compare deps deps')
- evl
-
-let eterm_obligations env name isevars evm fs ?status t ty =
- (* 'Serialize' the evars *)
- let nc = Environ.named_context env in
- let nc_len = Sign.named_context_length nc in
- let evl = List.rev (to_list evm) in
- let evl = List.map (fun (id, ev) -> (id, ev, evar_dependencies evm id)) evl in
- let sevl = sort_dependencies evl in
- let evl = List.map (fun (id, ev, _) -> id, ev) sevl in
- let evn =
- let i = ref (-1) in
- List.rev_map (fun (id, ev) -> incr i;
- (id, (!i, id_of_string
- (string_of_id name ^ "_obligation_" ^ string_of_int (succ !i))),
- ev)) evl
- in
- let evts =
- (* Remove existential variables in types and build the corresponding products *)
- fold_right
- (fun (id, (n, nstr), ev) l ->
- let hyps = Evd.evar_filtered_context ev in
- let hyps = trunc_named_context nc_len hyps in
- let evtyp, deps, transp = etype_of_evar l hyps ev.evar_concl in
- let evtyp, hyps, chop =
- match chop_product fs evtyp with
- | Some t -> t, trunc_named_context fs hyps, fs
- | None -> evtyp, hyps, 0
- in
- let loc, k = evar_source id isevars in
- let status = match k with QuestionMark o -> Some o | _ -> status in
- let status, chop = match status with
- | Some (Define true as stat) ->
- if chop <> fs then Define false, None
- else stat, Some chop
- | Some s -> s, None
- | None -> Define true, None
- in
- let tac = match ev.evar_extra with
- | Some t ->
- if Dyn.tag t = "tactic" then
- Some (Tacinterp.globTacticIn (Tacinterp.tactic_out t))
- else None
- | None -> None
- in
- let info = { ev_name = (n, nstr);
- ev_hyps = hyps; ev_status = status; ev_chop = chop;
- ev_loc = loc; ev_typ = evtyp ; ev_deps = deps; ev_tac = tac }
- in (id, info) :: l)
- evn []
- in
- let t', _, transparent = (* Substitute evar refs in the term by variables *)
- subst_evar_constr evts 0 t
- in
- let ty, _, _ = subst_evar_constr evts 0 ty in
- let evars =
- List.map (fun (_, info) ->
- let { ev_name = (_, name); ev_status = status;
- ev_loc = loc; ev_typ = typ; ev_deps = deps; ev_tac = tac } = info
- in
- let status = match status with
- | Define true when Idset.mem name transparent -> Define false
- | _ -> status
- in name, typ, loc, status, deps, tac) evts
- in Array.of_list (List.rev evars), t', ty
-
-let mkMetas n = list_tabulate (fun _ -> Evarutil.mk_new_meta ()) n
-
-let etermtac (evm, t) = assert(false) (*eterm evm t None *)
diff --git a/contrib/subtac/eterm.mli b/contrib/subtac/eterm.mli
deleted file mode 100644
index 19e8ffe8..00000000
--- a/contrib/subtac/eterm.mli
+++ /dev/null
@@ -1,32 +0,0 @@
-(************************************************************************)
-(* 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 $Id: eterm.mli 11576 2008-11-10 19:13:15Z msozeau $ i*)
-open Environ
-open Tacmach
-open Term
-open Evd
-open Names
-open Util
-open Tacinterp
-
-val mkMetas : int -> constr list
-
-val evar_dependencies : evar_map -> int -> Intset.t
-val sort_dependencies : (int * evar_info * Intset.t) list -> (int * evar_info * Intset.t) list
-
-(* env, id, evars, number of function prototypes to try to clear from
- evars contexts, object and type *)
-val eterm_obligations : env -> identifier -> evar_defs -> evar_map -> int ->
- ?status:obligation_definition_status -> constr -> types ->
- (identifier * types * loc * obligation_definition_status * Intset.t *
- Tacexpr.raw_tactic_expr option) array * constr * types
- (* Obl. name, type as product, location of the original evar, associated tactic,
- status and dependencies as indexes into the array *)
-
-val etermtac : open_constr -> tactic
diff --git a/contrib/subtac/g_eterm.ml4 b/contrib/subtac/g_eterm.ml4
deleted file mode 100644
index d9dd42cd..00000000
--- a/contrib/subtac/g_eterm.ml4
+++ /dev/null
@@ -1,27 +0,0 @@
-(************************************************************************)
-(* 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 *)
-(************************************************************************)
-(**************************************************************************)
-(* *)
-(* Omega: a solver of quantifier-free problems in Presburger Arithmetic *)
-(* *)
-(* Pierre Crégut (CNET, Lannion, France) *)
-(* *)
-(**************************************************************************)
-
-(*i camlp4deps: "parsing/grammar.cma" i*)
-
-(* $Id: g_eterm.ml4 8654 2006-03-22 15:36:58Z msozeau $ *)
-
-open Eterm
-
-TACTIC EXTEND eterm
- [ "eterm" ] -> [
- (fun gl ->
- let evm = Tacmach.project gl and t = Tacmach.pf_concl gl in
- Eterm.etermtac (evm, t) gl) ]
-END
diff --git a/contrib/subtac/g_subtac.ml4 b/contrib/subtac/g_subtac.ml4
deleted file mode 100644
index 7194d435..00000000
--- a/contrib/subtac/g_subtac.ml4
+++ /dev/null
@@ -1,156 +0,0 @@
-(************************************************************************)
-(* 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*)
-
-
-(*
- Syntax for the subtac terms and types.
- Elaborated from correctness/psyntax.ml4 by Jean-Christophe Filliâtre *)
-
-(* $Id: g_subtac.ml4 11576 2008-11-10 19:13:15Z msozeau $ *)
-
-
-open Flags
-open Util
-open Names
-open Nameops
-open Vernacentries
-open Reduction
-open Term
-open Libnames
-open Topconstr
-
-(* We define new entries for programs, with the use of this module
- * Subtac. These entries are named Subtac.<foo>
- *)
-
-module Gram = Pcoq.Gram
-module Vernac = Pcoq.Vernac_
-module Tactic = Pcoq.Tactic
-
-module SubtacGram =
-struct
- let gec s = Gram.Entry.create ("Subtac."^s)
- (* types *)
- let subtac_gallina_loc : Vernacexpr.vernac_expr located Gram.Entry.e = gec "subtac_gallina_loc"
-
- let subtac_nameopt : identifier option Gram.Entry.e = gec "subtac_nameopt"
-end
-
-open Rawterm
-open SubtacGram
-open Util
-open Pcoq
-open Prim
-open Constr
-let sigref = mkRefC (Qualid (dummy_loc, Libnames.qualid_of_string "Coq.Init.Specif.sig"))
-
-GEXTEND Gram
- GLOBAL: subtac_gallina_loc typeclass_constraint Constr.binder subtac_nameopt;
-
- subtac_gallina_loc:
- [ [ g = Vernac.gallina -> loc, g
- | g = Vernac.gallina_ext -> loc, g ] ]
- ;
-
- subtac_nameopt:
- [ [ "ofb"; id=Prim.ident -> Some (id)
- | -> None ] ]
- ;
-
- Constr.binder_let:
- [[ "("; id=Prim.name; ":"; t=Constr.lconstr; "|"; c=Constr.lconstr; ")" ->
- let typ = mkAppC (sigref, [mkLambdaC ([id], default_binder_kind, t, c)]) in
- [LocalRawAssum ([id], default_binder_kind, typ)]
- ] ];
-
- Constr.binder:
- [ [ "("; id=Prim.name; ":"; c=Constr.lconstr; "|"; p=Constr.lconstr; ")" ->
- ([id],default_binder_kind, mkAppC (sigref, [mkLambdaC ([id], default_binder_kind, c, p)]))
- | "("; id=Prim.name; ":"; c=Constr.lconstr; ")" ->
- ([id],default_binder_kind, c)
- | "("; id=Prim.name; lid=LIST1 Prim.name; ":"; c=Constr.lconstr; ")" ->
- (id::lid,default_binder_kind, c)
- ] ];
-
- END
-
-
-type 'a gallina_loc_argtype = (Vernacexpr.vernac_expr located, 'a) Genarg.abstract_argument_type
-
-let (wit_subtac_gallina_loc : Genarg.tlevel gallina_loc_argtype),
- (globwit_subtac_gallina_loc : Genarg.glevel gallina_loc_argtype),
- (rawwit_subtac_gallina_loc : Genarg.rlevel gallina_loc_argtype) =
- Genarg.create_arg "subtac_gallina_loc"
-
-type 'a nameopt_argtype = (identifier option, 'a) Genarg.abstract_argument_type
-
-let (wit_subtac_nameopt : Genarg.tlevel nameopt_argtype),
- (globwit_subtac_nameopt : Genarg.glevel nameopt_argtype),
- (rawwit_subtac_nameopt : Genarg.rlevel nameopt_argtype) =
- Genarg.create_arg "subtac_nameopt"
-
-VERNAC COMMAND EXTEND Subtac
-[ "Program" subtac_gallina_loc(g) ] -> [ Subtac.subtac g ]
- END
-
-VERNAC COMMAND EXTEND Subtac_Obligations
-| [ "Obligation" integer(num) "of" ident(name) ":" lconstr(t) ] -> [ Subtac_obligations.subtac_obligation (num, Some name, Some t) ]
-| [ "Obligation" integer(num) "of" ident(name) ] -> [ Subtac_obligations.subtac_obligation (num, Some name, None) ]
-| [ "Obligation" integer(num) ":" lconstr(t) ] -> [ Subtac_obligations.subtac_obligation (num, None, Some t) ]
-| [ "Obligation" integer(num) ] -> [ Subtac_obligations.subtac_obligation (num, None, None) ]
-| [ "Next" "Obligation" "of" ident(name) ] -> [ Subtac_obligations.next_obligation (Some name) ]
-| [ "Next" "Obligation" ] -> [ Subtac_obligations.next_obligation None ]
-END
-
-VERNAC COMMAND EXTEND Subtac_Solve_Obligation
-| [ "Solve" "Obligation" integer(num) "of" ident(name) "using" tactic(t) ] ->
- [ Subtac_obligations.try_solve_obligation num (Some name) (Some (Tacinterp.interp t)) ]
-| [ "Solve" "Obligation" integer(num) "using" tactic(t) ] ->
- [ Subtac_obligations.try_solve_obligation num None (Some (Tacinterp.interp t)) ]
- END
-
-VERNAC COMMAND EXTEND Subtac_Solve_Obligations
-| [ "Solve" "Obligations" "of" ident(name) "using" tactic(t) ] ->
- [ Subtac_obligations.try_solve_obligations (Some name) (Some (Tacinterp.interp t)) ]
-| [ "Solve" "Obligations" "using" tactic(t) ] ->
- [ Subtac_obligations.try_solve_obligations None (Some (Tacinterp.interp t)) ]
-| [ "Solve" "Obligations" ] ->
- [ Subtac_obligations.try_solve_obligations None None ]
- END
-
-VERNAC COMMAND EXTEND Subtac_Solve_All_Obligations
-| [ "Solve" "All" "Obligations" "using" tactic(t) ] ->
- [ Subtac_obligations.solve_all_obligations (Some (Tacinterp.interp t)) ]
-| [ "Solve" "All" "Obligations" ] ->
- [ Subtac_obligations.solve_all_obligations None ]
- END
-
-VERNAC COMMAND EXTEND Subtac_Admit_Obligations
-| [ "Admit" "Obligations" "of" ident(name) ] -> [ Subtac_obligations.admit_obligations (Some name) ]
-| [ "Admit" "Obligations" ] -> [ Subtac_obligations.admit_obligations None ]
- END
-
-VERNAC COMMAND EXTEND Subtac_Set_Solver
-| [ "Obligation" "Tactic" ":=" tactic(t) ] -> [
- Coqlib.check_required_library ["Coq";"Program";"Tactics"];
- Tacinterp.add_tacdef false
- [(Qualid (dummy_loc, qualid_of_string "Coq.Program.Tactics.obligation_tactic"), true, t)] ]
-END
-
-VERNAC COMMAND EXTEND Subtac_Show_Obligations
-| [ "Obligations" "of" ident(name) ] -> [ Subtac_obligations.show_obligations (Some name) ]
-| [ "Obligations" ] -> [ Subtac_obligations.show_obligations None ]
-END
-
-VERNAC COMMAND EXTEND Subtac_Show_Preterm
-| [ "Preterm" "of" ident(name) ] -> [ Subtac_obligations.show_term (Some name) ]
-| [ "Preterm" ] -> [ Subtac_obligations.show_term None ]
-END
diff --git a/contrib/subtac/subtac.ml b/contrib/subtac/subtac.ml
deleted file mode 100644
index c0b64379..00000000
--- a/contrib/subtac/subtac.ml
+++ /dev/null
@@ -1,241 +0,0 @@
-(************************************************************************)
-(* 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 *)
-(************************************************************************)
-
-(* $Id: subtac.ml 12194 2009-06-17 16:38:09Z msozeau $ *)
-
-open Global
-open Pp
-open Util
-open Names
-open Sign
-open Evd
-open Term
-open Termops
-open Reductionops
-open Environ
-open Type_errors
-open Typeops
-open Libnames
-open Classops
-open List
-open Recordops
-open Evarutil
-open Pretype_errors
-open Rawterm
-open Evarconv
-open Pattern
-open Dyn
-open Vernacexpr
-
-open Subtac_coercion
-open Subtac_utils
-open Coqlib
-open Printer
-open Subtac_errors
-open Eterm
-
-let require_library dirpath =
- let qualid = (dummy_loc, qualid_of_dirpath (dirpath_of_string dirpath)) in
- Library.require_library [qualid] None
-
-open Pp
-open Ppconstr
-open Decl_kinds
-open Tacinterp
-open Tacexpr
-
-let solve_tccs_in_type env id isevars evm c typ =
- if not (evm = Evd.empty) then
- let stmt_id = Nameops.add_suffix id "_stmt" in
- let obls, c', t' = eterm_obligations env stmt_id !isevars evm 0 ~status:Expand c typ in
- match Subtac_obligations.add_definition stmt_id c' typ obls with
- Subtac_obligations.Defined cst -> constant_value (Global.env())
- (match cst with ConstRef kn -> kn | _ -> assert false)
- | _ ->
- errorlabstrm "start_proof"
- (str "The statement obligations could not be resolved automatically, " ++ spc () ++
- str "write a statement definition first.")
- else
- let _ = Typeops.infer_type env c in c
-
-
-let start_proof_com env isevars sopt kind (bl,t) hook =
- let id = match sopt with
- | Some (loc,id) ->
- (* We check existence here: it's a bit late at Qed time *)
- if Nametab.exists_cci (Lib.make_path id) or is_section_variable id then
- user_err_loc (loc,"start_proof",pr_id id ++ str " already exists");
- id
- | None ->
- next_global_ident_away false (id_of_string "Unnamed_thm")
- (Pfedit.get_all_proof_names ())
- in
- let evm, c, typ, _imps =
- Subtac_pretyping.subtac_process env isevars id [] (Command.generalize_constr_expr t bl) None
- in
- let c = solve_tccs_in_type env id isevars evm c typ in
- Command.start_proof id kind c hook
-
-let print_subgoals () = Flags.if_verbose (fun () -> msg (Printer.pr_open_subgoals ())) ()
-
-let start_proof_and_print env isevars idopt k t hook =
- start_proof_com env isevars idopt k t hook;
- print_subgoals ()
-
-let _ = Detyping.set_detype_anonymous (fun loc n -> RVar (loc, id_of_string ("Anonymous_REL_" ^ string_of_int n)))
-
-let assumption_message id =
- Flags.if_verbose message ((string_of_id id) ^ " is assumed")
-
-let declare_assumption env isevars idl is_coe k bl c nl =
- if not (Pfedit.refining ()) then
- let id = snd (List.hd idl) in
- let evm, c, typ, imps =
- Subtac_pretyping.subtac_process env isevars id [] (Command.generalize_constr_expr c bl) None
- in
- let c = solve_tccs_in_type env id isevars evm c typ in
- List.iter (Command.declare_one_assumption is_coe k c imps false [] nl) idl
- else
- errorlabstrm "Command.Assumption"
- (str "Cannot declare an assumption while in proof editing mode.")
-
-let dump_constraint ty ((loc, n), _, _) =
- match n with
- | Name id -> Dumpglob.dump_definition (loc, id) false ty
- | Anonymous -> ()
-
-let dump_variable lid = ()
-
-let vernac_assumption env isevars kind l nl =
- let global = fst kind = Global in
- List.iter (fun (is_coe,(idl,c)) ->
- if Dumpglob.dump () then
- List.iter (fun lid ->
- if global then Dumpglob.dump_definition lid (not global) "ax"
- else dump_variable lid) idl;
- declare_assumption env isevars idl is_coe kind [] c nl) l
-
-let check_fresh (loc,id) =
- if Nametab.exists_cci (Lib.make_path id) or is_section_variable id then
- user_err_loc (loc,"",pr_id id ++ str " already exists")
-
-let subtac (loc, command) =
- check_required_library ["Coq";"Init";"Datatypes"];
- check_required_library ["Coq";"Init";"Specif"];
- let env = Global.env () in
- let isevars = ref (create_evar_defs Evd.empty) in
- try
- match command with
- | VernacDefinition (defkind, (_, id as lid), expr, hook) ->
- check_fresh lid;
- Dumpglob.dump_definition lid false "def";
- (match expr with
- | ProveBody (bl, t) ->
- if Lib.is_modtype () then
- errorlabstrm "Subtac_command.StartProof"
- (str "Proof editing mode not supported in module types");
- start_proof_and_print env isevars (Some lid) (Global, DefinitionBody Definition) (bl,t)
- (fun _ _ -> ())
- | DefineBody (bl, _, c, tycon) ->
- ignore(Subtac_pretyping.subtac_proof defkind hook env isevars id bl c tycon))
- | VernacFixpoint (l, b) ->
- List.iter (fun ((lid, _, _, _, _), _) ->
- check_fresh lid;
- Dumpglob.dump_definition lid false "fix") l;
- let _ = trace (str "Building fixpoint") in
- ignore(Subtac_command.build_recursive l b)
-
- | VernacStartTheoremProof (thkind, [Some id, (bl, t)], lettop, hook) ->
- Dumpglob.dump_definition id false "prf";
- if not(Pfedit.refining ()) then
- if lettop then
- errorlabstrm "Subtac_command.StartProof"
- (str "Let declarations can only be used in proof editing mode");
- if Lib.is_modtype () then
- errorlabstrm "Subtac_command.StartProof"
- (str "Proof editing mode not supported in module types");
- check_fresh id;
- start_proof_and_print env isevars (Some id) (Global, Proof thkind) (bl,t) hook
-
- | VernacAssumption (stre,nl,l) ->
- vernac_assumption env isevars stre l nl
-
- | VernacInstance (glob, sup, is, props, pri) ->
- dump_constraint "inst" is;
- ignore(Subtac_classes.new_instance ~global:glob sup is props pri)
-
- | VernacCoFixpoint (l, b) ->
- if Dumpglob.dump () then
- List.iter (fun ((lid, _, _, _), _) -> Dumpglob.dump_definition lid false "cofix") l;
- ignore(Subtac_command.build_corecursive l b)
-
- (*| VernacEndProof e ->
- subtac_end_proof e*)
-
- | _ -> user_err_loc (loc,"", str ("Invalid Program command"))
- with
- | Typing_error e ->
- msg_warning (str "Type error in Program tactic:");
- let cmds =
- (match e with
- | NonFunctionalApp (loc, x, mux, e) ->
- str "non functional application of term " ++
- e ++ str " to function " ++ x ++ str " of (mu) type " ++ mux
- | NonSigma (loc, t) ->
- str "Term is not of Sigma type: " ++ t
- | NonConvertible (loc, x, y) ->
- str "Unconvertible terms:" ++ spc () ++
- x ++ spc () ++ str "and" ++ spc () ++ y
- | IllSorted (loc, t) ->
- str "Term is ill-sorted:" ++ spc () ++ t
- )
- in msg_warning cmds
-
- | Subtyping_error e ->
- msg_warning (str "(Program tactic) Subtyping error:");
- let cmds =
- match e with
- | UncoercibleInferType (loc, x, y) ->
- str "Uncoercible terms:" ++ spc ()
- ++ x ++ spc () ++ str "and" ++ spc () ++ y
- | UncoercibleInferTerm (loc, x, y, tx, ty) ->
- str "Uncoercible terms:" ++ spc ()
- ++ tx ++ spc () ++ str "of" ++ spc () ++ str "type" ++ spc () ++ x
- ++ str "and" ++ spc() ++ ty ++ spc () ++ str "of" ++ spc () ++ str "type" ++ spc () ++ y
- | UncoercibleRewrite (x, y) ->
- str "Uncoercible terms:" ++ spc ()
- ++ x ++ spc () ++ str "and" ++ spc () ++ y
- in msg_warning cmds
-
- | Cases.PatternMatchingError (env, exn) as e ->
- debug 2 (Himsg.explain_pattern_matching_error env exn);
- raise e
-
- | Type_errors.TypeError (env, exn) as e ->
- debug 2 (Himsg.explain_type_error env exn);
- raise e
-
- | Pretype_errors.PretypeError (env, exn) as e ->
- debug 2 (Himsg.explain_pretype_error env exn);
- raise e
-
- | (Stdpp.Exc_located (loc, Proof_type.LtacLocated (_,e')) |
- Stdpp.Exc_located (loc, e') as e) ->
- debug 2 (str "Parsing exception: ");
- (match e' with
- | Type_errors.TypeError (env, exn) ->
- debug 2 (Himsg.explain_type_error env exn);
- raise e
-
- | Pretype_errors.PretypeError (env, exn) ->
- debug 2 (Himsg.explain_pretype_error env exn);
- raise e
-
- | e'' -> raise e)
-
- | e -> raise e
diff --git a/contrib/subtac/subtac.mli b/contrib/subtac/subtac.mli
deleted file mode 100644
index b51150aa..00000000
--- a/contrib/subtac/subtac.mli
+++ /dev/null
@@ -1,2 +0,0 @@
-val require_library : string -> unit
-val subtac : Util.loc * Vernacexpr.vernac_expr -> unit
diff --git a/contrib/subtac/subtac_cases.ml b/contrib/subtac/subtac_cases.ml
deleted file mode 100644
index bd06407f..00000000
--- a/contrib/subtac/subtac_cases.ml
+++ /dev/null
@@ -1,2032 +0,0 @@
-(* -*- 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 *)
-(************************************************************************)
-
-(* $Id: subtac_cases.ml 12194 2009-06-17 16:38:09Z 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 Subtac_utils
-
-(************************************************************************)
-(* Pattern-matching compilation (Cases) *)
-(************************************************************************)
-
-(************************************************************************)
-(* Configuration, errors and warnings *)
-
-open Pp
-
-let mssg_may_need_inversion () =
- str "Found a matching with no clauses on a term unknown to have an empty inductive type"
-
-(* Utils *)
-let make_anonymous_patvars =
- list_tabulate (fun _ -> PatVar (dummy_loc,Anonymous))
-
-(* Environment management *)
-let push_rels vars env = List.fold_right push_rel vars env
-
-let push_rel_defs =
- List.fold_right (fun (x,d,t) e -> push_rel (x,Some d,t) e)
-
-(* We have x1:t1...xn:tn,xi':ti,y1..yk |- c and re-generalize
- over xi:ti to get x1:t1...xn:tn,xi':ti,y1..yk |- c[xi:=xi'] *)
-
-let regeneralize_rel i k j = if j = i+k then k else if j < i+k then j else j
-
-let rec regeneralize_index i k t = match kind_of_term t with
- | Rel j when j = i+k -> mkRel (k+1)
- | Rel j when j < i+k -> t
- | Rel j when j > i+k -> t
- | _ -> map_constr_with_binders succ (regeneralize_index i) k t
-
-type alias_constr =
- | DepAlias
- | NonDepAlias
-
-let mkSpecialLetInJudge j (na,(deppat,nondeppat,d,t)) =
- { uj_val =
- (match d with
- | DepAlias -> mkLetIn (na,deppat,t,j.uj_val)
- | NonDepAlias ->
- if (not (dependent (mkRel 1) j.uj_type))
- or (* A leaf: *) isRel deppat
- then
- (* The body of pat is not needed to type j - see *)
- (* insert_aliases - and both deppat and nondeppat have the *)
- (* same type, then one can freely substitute one by the other *)
- subst1 nondeppat j.uj_val
- else
- (* The body of pat is not needed to type j but its value *)
- (* is dependent in the type of j; our choice is to *)
- (* enforce this dependency *)
- mkLetIn (na,deppat,t,j.uj_val));
- uj_type = subst1 deppat j.uj_type }
-
-(**********************************************************************)
-(* Structures used in compiling pattern-matching *)
-
-type rhs =
- { rhs_env : env;
- avoid_ids : identifier list;
- it : rawconstr;
- }
-
-type equation =
- { patterns : cases_pattern list;
- rhs : rhs;
- alias_stack : name list;
- eqn_loc : loc;
- used : bool ref }
-
-type matrix = equation list
-
-(* 1st argument of IsInd is the original ind before extracting the summary *)
-type tomatch_type =
- | IsInd of types * inductive_type
- | NotInd of constr option * types
-
-type tomatch_status =
- | Pushed of ((constr * tomatch_type) * int list)
- | Alias of (constr * constr * alias_constr * constr)
- | Abstract of rel_declaration
-
-type tomatch_stack = tomatch_status list
-
-(* The type [predicate_signature] types the terms to match and the rhs:
-
- - [PrLetIn (names,dep,pred)] types a pushed term ([Pushed]),
- if dep<>Anonymous, the term is dependent, let n=|names|, if
- n<>0 then the type of the pushed term is necessarily an
- inductive with n real arguments. Otherwise, it may be
- non inductive, or inductive without real arguments, or inductive
- originating from a subterm in which case real args are not dependent;
- it accounts for n+1 binders if dep or n binders if not dep
- - [PrProd] types abstracted term ([Abstract]); it accounts for one binder
- - [PrCcl] types the right-hand-side
- - Aliases [Alias] have no trace in [predicate_signature]
-*)
-
-type predicate_signature =
- | PrLetIn of (name list * name) * predicate_signature
- | PrProd of predicate_signature
- | PrCcl of constr
-
-(* We keep a constr for aliases and a cases_pattern for error message *)
-
-type alias_builder =
- | AliasLeaf
- | AliasConstructor of constructor
-
-type pattern_history =
- | Top
- | MakeAlias of alias_builder * pattern_continuation
-
-and pattern_continuation =
- | Continuation of int * cases_pattern list * pattern_history
- | Result of cases_pattern list
-
-let start_history n = Continuation (n, [], Top)
-
-let initial_history = function Continuation (_,[],Top) -> true | _ -> false
-
-let feed_history arg = function
- | Continuation (n, l, h) when n>=1 ->
- Continuation (n-1, arg :: l, h)
- | Continuation (n, _, _) ->
- anomaly ("Bad number of expected remaining patterns: "^(string_of_int n))
- | Result _ ->
- anomaly "Exhausted pattern history"
-
-(* This is for non exhaustive error message *)
-
-let rec rawpattern_of_partial_history args2 = function
- | Continuation (n, args1, h) ->
- let args3 = make_anonymous_patvars (n - (List.length args2)) in
- build_rawpattern (List.rev_append args1 (args2@args3)) h
- | Result pl -> pl
-
-and build_rawpattern args = function
- | Top -> args
- | MakeAlias (AliasLeaf, rh) ->
- assert (args = []);
- rawpattern_of_partial_history [PatVar (dummy_loc, Anonymous)] rh
- | MakeAlias (AliasConstructor pci, rh) ->
- rawpattern_of_partial_history
- [PatCstr (dummy_loc, pci, args, Anonymous)] rh
-
-let complete_history = rawpattern_of_partial_history []
-
-(* This is to build glued pattern-matching history and alias bodies *)
-
-let rec simplify_history = function
- | Continuation (0, l, Top) -> Result (List.rev l)
- | Continuation (0, l, MakeAlias (f, rh)) ->
- let pargs = List.rev l in
- let pat = match f with
- | AliasConstructor pci ->
- PatCstr (dummy_loc,pci,pargs,Anonymous)
- | AliasLeaf ->
- assert (l = []);
- PatVar (dummy_loc, Anonymous) in
- feed_history pat rh
- | h -> h
-
-(* Builds a continuation expecting [n] arguments and building [ci] applied
- to this [n] arguments *)
-
-let push_history_pattern n current cont =
- Continuation (n, [], MakeAlias (current, cont))
-
-(* A pattern-matching problem has the following form:
-
- env, isevars |- <pred> Cases tomatch of mat end
-
- where tomatch is some sequence of "instructions" (t1 ... tn)
-
- and mat is some matrix
- (p11 ... p1n -> rhs1)
- ( ... )
- (pm1 ... pmn -> rhsm)
-
- Terms to match: there are 3 kinds of instructions
-
- - "Pushed" terms to match are typed in [env]; these are usually just
- Rel(n) except for the initial terms given by user and typed in [env]
- - "Abstract" instructions means an abstraction has to be inserted in the
- current branch to build (this means a pattern has been detected dependent
- in another one and generalisation is necessary to ensure well-typing)
- - "Alias" instructions means an alias has to be inserted (this alias
- is usually removed at the end, except when its type is not the
- same as the type of the matched term from which it comes -
- typically because the inductive types are "real" parameters)
-
- Right-hand-sides:
-
- They consist of a raw term to type in an environment specific to the
- clause they belong to: the names of declarations are those of the
- variables present in the patterns. Therefore, they come with their
- own [rhs_env] (actually it is the same as [env] except for the names
- of variables).
-
-*)
-type pattern_matching_problem =
- { env : env;
- isevars : Evd.evar_defs ref;
- pred : predicate_signature option;
- tomatch : tomatch_stack;
- history : pattern_continuation;
- mat : matrix;
- caseloc : loc;
- casestyle: case_style;
- typing_function: type_constraint -> env -> rawconstr -> unsafe_judgment }
-
-(*--------------------------------------------------------------------------*
- * A few functions to infer the inductive type from the patterns instead of *
- * checking that the patterns correspond to the ind. type of the *
- * destructurated object. Allows type inference of examples like *
- * match n with O => true | _ => false end *
- * match x in I with C => true | _ => false end *
- *--------------------------------------------------------------------------*)
-
-(* Computing the inductive type from the matrix of patterns *)
-
-(* We use the "in I" clause to coerce the terms to match and otherwise
- use the constructor to know in which type is the matching problem
-
- Note that insertion of coercions inside nested patterns is done
- each time the matrix is expanded *)
-
-let rec find_row_ind = function
- [] -> None
- | PatVar _ :: l -> find_row_ind l
- | PatCstr(loc,c,_,_) :: _ -> Some (loc,c)
-
-let inductive_template isevars env tmloc ind =
- let arsign = get_full_arity_sign env ind in
- let hole_source = match tmloc with
- | Some loc -> fun i -> (loc, Evd.TomatchTypeParameter (ind,i))
- | None -> fun _ -> (dummy_loc, Evd.InternalHole) in
- let (_,evarl,_) =
- List.fold_right
- (fun (na,b,ty) (subst,evarl,n) ->
- match b with
- | None ->
- let ty' = substl subst ty in
- let e = e_new_evar isevars env ~src:(hole_source n) ty' in
- (e::subst,e::evarl,n+1)
- | Some b ->
- (b::subst,evarl,n+1))
- arsign ([],[],1) in
- applist (mkInd ind,List.rev evarl)
-
-
-(************************************************************************)
-(* Utils *)
-
-let mkExistential env ?(src=(dummy_loc,Evd.InternalHole)) isevars =
- e_new_evar isevars env ~src:src (new_Type ())
-
-let evd_comb2 f isevars x y =
- let (evd',y) = f !isevars x y in
- isevars := evd';
- y
-
-
-module Cases_F(Coercion : Coercion.S) : S = struct
-
-let inh_coerce_to_ind isevars env ty tyi =
- let expected_typ = inductive_template isevars env None tyi in
- (* devrait être indifférent d'exiger leq ou pas puisque pour
- un inductif cela doit être égal *)
- let _ = e_cumul env isevars expected_typ ty in ()
-
-let unify_tomatch_with_patterns isevars env loc typ pats =
- match find_row_ind pats with
- | None -> NotInd (None,typ)
- | Some (_,(ind,_)) ->
- inh_coerce_to_ind isevars env typ ind;
- try IsInd (typ,find_rectype env (Evd.evars_of !isevars) typ)
- with Not_found -> NotInd (None,typ)
-
-let find_tomatch_tycon isevars env loc = function
- (* Try if some 'in I ...' is present and can be used as a constraint *)
- | Some (_,ind,_,_) -> mk_tycon (inductive_template isevars env loc ind)
- | None -> empty_tycon
-
-let coerce_row typing_fun isevars env pats (tomatch,(_,indopt)) =
- let loc = Some (loc_of_rawconstr tomatch) in
- let tycon = find_tomatch_tycon isevars env loc indopt in
- let j = typing_fun tycon env tomatch in
- let evd, j = Coercion.inh_coerce_to_base (loc_of_rawconstr tomatch) env !isevars j in
- isevars := evd;
- let typ = nf_evar (Evd.evars_of !isevars) j.uj_type in
- let t =
- try IsInd (typ,find_rectype env (Evd.evars_of !isevars) typ)
- with Not_found ->
- unify_tomatch_with_patterns isevars env loc typ pats in
- (j.uj_val,t)
-
-let coerce_to_indtype typing_fun isevars env matx tomatchl =
- let pats = List.map (fun r -> r.patterns) matx in
- let matx' = match matrix_transpose pats with
- | [] -> List.map (fun _ -> []) tomatchl (* no patterns at all *)
- | m -> m in
- List.map2 (coerce_row typing_fun isevars env) matx' tomatchl
-
-
-
-let adjust_tomatch_to_pattern pb ((current,typ),deps) =
- (* Ideally, we could find a common inductive type to which both the
- term to match and the patterns coerce *)
- (* In practice, we coerce the term to match if it is not already an
- inductive type and it is not dependent; moreover, we use only
- the first pattern type and forget about the others *)
- let typ = match typ with IsInd (t,_) -> t | NotInd (_,t) -> t in
- let typ =
- try IsInd (typ,find_rectype pb.env (Evd.evars_of !(pb.isevars)) typ)
- with Not_found -> NotInd (None,typ) in
- let tomatch = ((current,typ),deps) in
- match typ with
- | NotInd (None,typ) ->
- let tm1 = List.map (fun eqn -> List.hd eqn.patterns) pb.mat in
- (match find_row_ind tm1 with
- | None -> tomatch
- | Some (_,(ind,_)) ->
- let indt = inductive_template pb.isevars pb.env None ind in
- let current =
- if deps = [] & isEvar typ then
- (* Don't insert coercions if dependent; only solve evars *)
- let _ = e_cumul pb.env pb.isevars indt typ in
- current
- else
- (evd_comb2 (Coercion.inh_conv_coerce_to dummy_loc pb.env)
- pb.isevars (make_judge current typ) (mk_tycon_type indt)).uj_val in
- let sigma = Evd.evars_of !(pb.isevars) in
- let typ = IsInd (indt,find_rectype pb.env sigma indt) in
- ((current,typ),deps))
- | _ -> tomatch
-
- (* extract some ind from [t], possibly coercing from constructors in [tm] *)
-let to_mutind env isevars tm c t =
-(* match c with
- | Some body -> *) NotInd (c,t)
-(* | None -> unify_tomatch_with_patterns isevars env t tm*)
-
-let type_of_tomatch = function
- | IsInd (t,_) -> t
- | NotInd (_,t) -> t
-
-let mkDeclTomatch na = function
- | IsInd (t,_) -> (na,None,t)
- | NotInd (c,t) -> (na,c,t)
-
-let map_tomatch_type f = function
- | IsInd (t,ind) -> IsInd (f t,map_inductive_type f ind)
- | NotInd (c,t) -> NotInd (Option.map f c, f t)
-
-let liftn_tomatch_type n depth = map_tomatch_type (liftn n depth)
-let lift_tomatch_type n = liftn_tomatch_type n 1
-
-let lift_tomatch n ((current,typ),info) =
- ((lift n current,lift_tomatch_type n typ),info)
-
-(**********************************************************************)
-(* Utilities on patterns *)
-
-let current_pattern eqn =
- match eqn.patterns with
- | pat::_ -> pat
- | [] -> anomaly "Empty list of patterns"
-
-let alias_of_pat = function
- | PatVar (_,name) -> name
- | PatCstr(_,_,_,name) -> name
-
-let unalias_pat = function
- | PatVar (c,name) as p ->
- if name = Anonymous then p else PatVar (c,Anonymous)
- | PatCstr(a,b,c,name) as p ->
- if name = Anonymous then p else PatCstr (a,b,c,Anonymous)
-
-let remove_current_pattern eqn =
- match eqn.patterns with
- | pat::pats ->
- { eqn with
- patterns = pats;
- alias_stack = alias_of_pat pat :: eqn.alias_stack }
- | [] -> anomaly "Empty list of patterns"
-
-let prepend_pattern tms eqn = {eqn with patterns = tms@eqn.patterns }
-
-(**********************************************************************)
-(* Well-formedness tests *)
-(* Partial check on patterns *)
-
-exception NotAdjustable
-
-let rec adjust_local_defs loc = function
- | (pat :: pats, (_,None,_) :: decls) ->
- pat :: adjust_local_defs loc (pats,decls)
- | (pats, (_,Some _,_) :: decls) ->
- PatVar (loc, Anonymous) :: adjust_local_defs loc (pats,decls)
- | [], [] -> []
- | _ -> raise NotAdjustable
-
-let check_and_adjust_constructor env ind cstrs = function
- | PatVar _ as pat -> pat
- | PatCstr (loc,((_,i) as cstr),args,alias) as pat ->
- (* Check it is constructor of the right type *)
- let ind' = inductive_of_constructor cstr in
- if Closure.mind_equiv env ind' ind then
- (* Check the constructor has the right number of args *)
- let ci = cstrs.(i-1) in
- let nb_args_constr = ci.cs_nargs in
- if List.length args = nb_args_constr then pat
- else
- try
- let args' = adjust_local_defs loc (args, List.rev ci.cs_args)
- in PatCstr (loc, cstr, args', alias)
- with NotAdjustable ->
- error_wrong_numarg_constructor_loc loc (Global.env())
- cstr nb_args_constr
- else
- (* Try to insert a coercion *)
- try
- Coercion.inh_pattern_coerce_to loc pat ind' ind
- with Not_found ->
- error_bad_constructor_loc loc cstr ind
-
-let check_all_variables typ mat =
- List.iter
- (fun eqn -> match current_pattern eqn with
- | PatVar (_,id) -> ()
- | PatCstr (loc,cstr_sp,_,_) ->
- error_bad_pattern_loc loc cstr_sp typ)
- mat
-
-let check_unused_pattern env eqn =
- if not !(eqn.used) then
- raise_pattern_matching_error
- (eqn.eqn_loc, env, UnusedClause eqn.patterns)
-
-let set_used_pattern eqn = eqn.used := true
-
-let extract_rhs pb =
- match pb.mat with
- | [] -> errorlabstrm "build_leaf" (mssg_may_need_inversion())
- | eqn::_ ->
- set_used_pattern eqn;
- eqn.rhs
-
-(**********************************************************************)
-(* Functions to deal with matrix factorization *)
-
-let occur_in_rhs na rhs =
- match na with
- | Anonymous -> false
- | Name id -> occur_rawconstr id rhs.it
-
-let is_dep_patt eqn = function
- | PatVar (_,name) -> occur_in_rhs name eqn.rhs
- | PatCstr _ -> true
-
-let dependencies_in_rhs nargs eqns =
- if eqns = [] then list_tabulate (fun _ -> false) nargs (* Only "_" patts *)
- else
- let deps = List.map (fun (tms,eqn) -> List.map (is_dep_patt eqn) tms) eqns in
- let columns = matrix_transpose deps in
- List.map (List.exists ((=) true)) columns
-
-let dependent_decl a = function
- | (na,None,t) -> dependent a t
- | (na,Some c,t) -> dependent a t || dependent a c
-
-(* Computing the matrix of dependencies *)
-
-(* We are in context d1...dn |- and [find_dependencies k 1 nextlist]
- computes for declaration [k+1] in which of declarations in
- [nextlist] (which corresponds to d(k+2)...dn) it depends;
- declarations are expressed by index, e.g. in dependency list
- [n-2;1], [1] points to [dn] and [n-2] to [d3] *)
-
-let rec find_dependency_list k n = function
- | [] -> []
- | (used,tdeps,d)::rest ->
- let deps = find_dependency_list k (n+1) rest in
- if used && dependent_decl (mkRel n) d
- then list_add_set (List.length rest + 1) (list_union deps tdeps)
- else deps
-
-let find_dependencies is_dep_or_cstr_in_rhs d (k,nextlist) =
- let deps = find_dependency_list k 1 nextlist in
- if is_dep_or_cstr_in_rhs || deps <> []
- then (k-1,(true ,deps,d)::nextlist)
- else (k-1,(false,[] ,d)::nextlist)
-
-let find_dependencies_signature deps_in_rhs typs =
- let k = List.length deps_in_rhs in
- let _,l = List.fold_right2 find_dependencies deps_in_rhs typs (k,[]) in
- List.map (fun (_,deps,_) -> deps) l
-
-(******)
-
-(* A Pushed term to match has just been substituted by some
- constructor t = (ci x1...xn) and the terms x1 ... xn have been added to
- match
-
- - all terms to match and to push (dependent on t by definition)
- must have (Rel depth) substituted by t and Rel's>depth lifted by n
- - all pushed terms to match (non dependent on t by definition) must
- be lifted by n
-
- We start with depth=1
-*)
-
-let regeneralize_index_tomatch n =
- let rec genrec depth = function
- | [] -> []
- | Pushed ((c,tm),l)::rest ->
- let c = regeneralize_index n depth c in
- let tm = map_tomatch_type (regeneralize_index n depth) tm in
- let l = List.map (regeneralize_rel n depth) l in
- Pushed ((c,tm),l)::(genrec depth rest)
- | Alias (c1,c2,d,t)::rest ->
- Alias (regeneralize_index n depth c1,c2,d,t)::(genrec depth rest)
- | Abstract d::rest ->
- Abstract (map_rel_declaration (regeneralize_index n depth) d)
- ::(genrec (depth+1) rest) in
- genrec 0
-
-let rec replace_term n c k t =
- if t = mkRel (n+k) then lift k c
- else map_constr_with_binders succ (replace_term n c) k t
-
-let replace_tomatch n c =
- let rec replrec depth = function
- | [] -> []
- | Pushed ((b,tm),l)::rest ->
- let b = replace_term n c depth b in
- let tm = map_tomatch_type (replace_term n c depth) tm in
- List.iter (fun i -> if i=n+depth then anomaly "replace_tomatch") l;
- Pushed ((b,tm),l)::(replrec depth rest)
- | Alias (c1,c2,d,t)::rest ->
- Alias (replace_term n c depth c1,c2,d,t)::(replrec depth rest)
- | Abstract d::rest ->
- Abstract (map_rel_declaration (replace_term n c depth) d)
- ::(replrec (depth+1) rest) in
- replrec 0
-
-let liftn_rel_declaration n k = map_rel_declaration (liftn n k)
-let substnl_rel_declaration sigma k = map_rel_declaration (substnl sigma k)
-
-let rec liftn_tomatch_stack n depth = function
- | [] -> []
- | Pushed ((c,tm),l)::rest ->
- let c = liftn n depth c in
- let tm = liftn_tomatch_type n depth tm in
- let l = List.map (fun i -> if i<depth then i else i+n) l in
- Pushed ((c,tm),l)::(liftn_tomatch_stack n depth rest)
- | Alias (c1,c2,d,t)::rest ->
- Alias (liftn n depth c1,liftn n depth c2,d,liftn n depth t)
- ::(liftn_tomatch_stack n depth rest)
- | Abstract d::rest ->
- Abstract (map_rel_declaration (liftn n depth) d)
- ::(liftn_tomatch_stack n (depth+1) rest)
-
-
-let lift_tomatch_stack n = liftn_tomatch_stack n 1
-
-(* if [current] has type [I(p1...pn u1...um)] and we consider the case
- of constructor [ci] of type [I(p1...pn u'1...u'm)], then the
- default variable [name] is expected to have which type?
- Rem: [current] is [(Rel i)] except perhaps for initial terms to match *)
-
-(************************************************************************)
-(* Some heuristics to get names for variables pushed in pb environment *)
-(* Typical requirement:
-
- [match y with (S (S x)) => x | x => x end] should be compiled into
- [match y with O => y | (S n) => match n with O => y | (S x) => x end end]
-
- and [match y with (S (S n)) => n | n => n end] into
- [match y with O => y | (S n0) => match n0 with O => y | (S n) => n end end]
-
- i.e. user names should be preserved and created names should not
- interfere with user names *)
-
-let merge_name get_name obj = function
- | Anonymous -> get_name obj
- | na -> na
-
-let merge_names get_name = List.map2 (merge_name get_name)
-
-let get_names env sign eqns =
- let names1 = list_tabulate (fun _ -> Anonymous) (List.length sign) in
- (* If any, we prefer names used in pats, from top to bottom *)
- let names2 =
- List.fold_right
- (fun (pats,eqn) names -> merge_names alias_of_pat pats names)
- eqns names1 in
- (* Otherwise, we take names from the parameters of the constructor but
- avoiding conflicts with user ids *)
- let allvars =
- List.fold_left (fun l (_,eqn) -> list_union l eqn.rhs.avoid_ids) [] eqns in
- let names4,_ =
- List.fold_left2
- (fun (l,avoid) d na ->
- let na =
- merge_name
- (fun (na,_,t) -> Name (next_name_away (named_hd env t na) avoid))
- d na
- in
- (na::l,(out_name na)::avoid))
- ([],allvars) (List.rev sign) names2 in
- names4
-
-(************************************************************************)
-(* Recovering names for variables pushed to the rhs' environment *)
-
-let recover_alias_names get_name = List.map2 (fun x (_,c,t) ->(get_name x,c,t))
-
-let all_name sign = List.map (fun (n, b, t) -> let n = match n with Name _ -> n | Anonymous -> Name (id_of_string "Anonymous") in
- (n, b, t)) sign
-
-let push_rels_eqn sign eqn =
- let sign = all_name sign in
- {eqn with rhs = {eqn.rhs with rhs_env = push_rels sign eqn.rhs.rhs_env; } }
-
-let push_rels_eqn_with_names sign eqn =
- let pats = List.rev (list_firstn (List.length sign) eqn.patterns) in
- let sign = recover_alias_names alias_of_pat pats sign in
- push_rels_eqn sign eqn
-
-let build_aliases_context env sigma names allpats pats =
- (* pats is the list of bodies to push as an alias *)
- (* They all are defined in env and we turn them into a sign *)
- (* cuts in sign need to be done in allpats *)
- let rec insert env sign1 sign2 n newallpats oldallpats = function
- | (deppat,_,_,_)::pats, Anonymous::names when not (isRel deppat) ->
- (* Anonymous leaves must be considered named and treated in the *)
- (* next clause because they may occur in implicit arguments *)
- insert env sign1 sign2
- n newallpats (List.map List.tl oldallpats) (pats,names)
- | (deppat,nondeppat,d,t)::pats, na::names ->
- let nondeppat = lift n nondeppat in
- let deppat = lift n deppat in
- let newallpats =
- List.map2 (fun l1 l2 -> List.hd l2::l1) newallpats oldallpats in
- let oldallpats = List.map List.tl oldallpats in
- let decl = (na,Some deppat,t) in
- let a = (deppat,nondeppat,d,t) in
- insert (push_rel decl env) (decl::sign1) ((na,a)::sign2) (n+1)
- newallpats oldallpats (pats,names)
- | [], [] -> newallpats, sign1, sign2, env
- | _ -> anomaly "Inconsistent alias and name lists" in
- let allpats = List.map (fun x -> [x]) allpats
- in insert env [] [] 0 (List.map (fun _ -> []) allpats) allpats (pats, names)
-
-let insert_aliases_eqn sign eqnnames alias_rest eqn =
- let thissign = List.map2 (fun na (_,c,t) -> (na,c,t)) eqnnames sign in
- push_rels_eqn thissign { eqn with alias_stack = alias_rest; }
-
-
-let insert_aliases env sigma alias eqns =
- (* Là, y a une faiblesse, si un alias est utilisé dans un cas par *)
- (* défaut présent mais inutile, ce qui est le cas général, l'alias *)
- (* est introduit même s'il n'est pas utilisé dans les cas réguliers *)
- let eqnsnames = List.map (fun eqn -> List.hd eqn.alias_stack) eqns in
- let alias_rests = List.map (fun eqn -> List.tl eqn.alias_stack) eqns in
- (* names2 takes the meet of all needed aliases *)
- let names2 =
- List.fold_right (merge_name (fun x -> x)) eqnsnames Anonymous in
- (* Only needed aliases are kept by build_aliases_context *)
- let eqnsnames, sign1, sign2, env =
- build_aliases_context env sigma [names2] eqnsnames [alias] in
- let eqns = list_map3 (insert_aliases_eqn sign1) eqnsnames alias_rests eqns in
- sign2, env, eqns
-
-(**********************************************************************)
-(* Functions to deal with elimination predicate *)
-
-exception Occur
-let noccur_between_without_evar n m term =
- let rec occur_rec n c = match kind_of_term c with
- | Rel p -> if n<=p && p<n+m then raise Occur
- | Evar (_,cl) -> ()
- | _ -> iter_constr_with_binders succ occur_rec n c
- in
- try occur_rec n term; true with Occur -> false
-
-(* Inferring the predicate *)
-let prepare_unif_pb typ cs =
- let n = List.length (assums_of_rel_context cs.cs_args) in
-
- (* We may need to invert ci if its parameters occur in typ *)
- let typ' =
- if noccur_between_without_evar 1 n typ then lift (-n) typ
- else (* TODO4-1 *)
- error "Unable to infer return clause of this pattern-matching problem" in
- let args = extended_rel_list (-n) cs.cs_args in
- let ci = applist (mkConstruct cs.cs_cstr, cs.cs_params@args) in
-
- (* This is the problem: finding P s.t. cs_args |- (P realargs ci) = typ' *)
- (Array.map (lift (-n)) cs.cs_concl_realargs, ci, typ')
-
-
-(* Infering the predicate *)
-(*
-The problem to solve is the following:
-
-We match Gamma |- t : I(u01..u0q) against the following constructors:
-
- Gamma, x11...x1p1 |- C1(x11..x1p1) : I(u11..u1q)
- ...
- Gamma, xn1...xnpn |- Cn(xn1..xnp1) : I(un1..unq)
-
-Assume the types in the branches are the following
-
- Gamma, x11...x1p1 |- branch1 : T1
- ...
- Gamma, xn1...xnpn |- branchn : Tn
-
-Assume the type of the global case expression is Gamma |- T
-
-The predicate has the form phi = [y1..yq][z:I(y1..yq)]? and must satisfy
-the following n+1 equations:
-
- Gamma, x11...x1p1 |- (phi u11..u1q (C1 x11..x1p1)) = T1
- ...
- Gamma, xn1...xnpn |- (phi un1..unq (Cn xn1..xnpn)) = Tn
- Gamma |- (phi u01..u0q t) = T
-
-Some hints:
-
-- Clearly, if xij occurs in Ti, then, a "match z with (Ci xi1..xipi) => ..."
- should be inserted somewhere in Ti.
-
-- If T is undefined, an easy solution is to insert a "match z with (Ci
- xi1..xipi) => ..." in front of each Ti
-
-- Otherwise, T1..Tn and T must be step by step unified, if some of them
- diverge, then try to replace the diverging subterm by one of y1..yq or z.
-
-- The main problem is what to do when an existential variables is encountered
-
-let prepare_unif_pb typ cs =
- let n = cs.cs_nargs in
- let _,p = decompose_prod_n n typ in
- let ci = build_dependent_constructor cs in
- (* This is the problem: finding P s.t. cs_args |- (P realargs ci) = p *)
- (n, cs.cs_concl_realargs, ci, p)
-
-let eq_operator_lift k (n,n') = function
- | OpRel p, OpRel p' when p > k & p' > k ->
- if p < k+n or p' < k+n' then false else p - n = p' - n'
- | op, op' -> op = op'
-
-let rec transpose_args n =
- if n=0 then []
- else
- (Array.map (fun l -> List.hd l) lv)::
- (transpose_args (m-1) (Array.init (fun l -> List.tl l)))
-
-let shift_operator k = function OpLambda _ | OpProd _ -> k+1 | _ -> k
-
-let reloc_operator (k,n) = function OpRel p when p > k ->
-let rec unify_clauses k pv =
- let pv'= Array.map (fun (n,sign,_,p) -> n,splay_constr (whd_betaiotaevar (push_rels (List.rev sign) env) (Evd.evars_of isevars)) p) pv in
- let n1,op1 = let (n1,(op1,args1)) = pv'.(0) in n1,op1 in
- if Array.for_all (fun (ni,(opi,_)) -> eq_operator_lift k (n1,ni) (op1,opi)) pv'
- then
- let argvl = transpose_args (List.length args1) pv' in
- let k' = shift_operator k op1 in
- let argl = List.map (unify_clauses k') argvl in
- gather_constr (reloc_operator (k,n1) op1) argl
-*)
-
-let abstract_conclusion typ cs =
- let n = List.length (assums_of_rel_context cs.cs_args) in
- let (sign,p) = decompose_prod_n n typ in
- lam_it p sign
-
-let infer_predicate loc env isevars typs cstrs indf =
- (* Il faudra substituer les isevars a un certain moment *)
- if Array.length cstrs = 0 then (* "TODO4-3" *)
- error "Inference of annotation for empty inductive types not implemented"
- else
- (* Empiric normalization: p may depend in a irrelevant way on args of the*)
- (* cstr as in [c:{_:Alpha & Beta}] match c with (existS a b)=>(a,b) end *)
- let typs =
- Array.map (local_strong whd_beta (Evd.evars_of !isevars)) typs
- in
- let eqns = array_map2 prepare_unif_pb typs cstrs in
- (* First strategy: no dependencies at all *)
-(*
- let (mis,_) = dest_ind_family indf in
- let (cclargs,_,typn) = eqns.(mis_nconstr mis -1) in
-*)
- let (sign,_) = get_arity env indf in
- let mtyp =
- if array_exists is_Type typs then
- (* Heuristic to avoid comparison between non-variables algebric univs*)
- new_Type ()
- else
- mkExistential env ~src:(loc, Evd.CasesType) isevars
- in
- if array_for_all (fun (_,_,typ) -> e_cumul env isevars typ mtyp) eqns
- then
- (* Non dependent case -> turn it into a (dummy) dependent one *)
- let sign = (Anonymous,None,build_dependent_inductive env indf)::sign in
- let pred = it_mkLambda_or_LetIn (lift (List.length sign) mtyp) sign in
- (true,pred) (* true = dependent -- par défaut *)
- else
-(*
- let s = get_sort_of env (evars_of isevars) typs.(0) in
- let predpred = it_mkLambda_or_LetIn (mkSort s) sign in
- let caseinfo = make_default_case_info mis in
- let brs = array_map2 abstract_conclusion typs cstrs in
- let predbody = mkCase (caseinfo, (nf_betaiota predpred), mkRel 1, brs) in
- let pred = it_mkLambda_or_LetIn (lift (List.length sign) mtyp) sign in
-*)
- (* "TODO4-2" *)
- (* We skip parameters *)
- let cis =
- Array.map
- (fun cs ->
- applist (mkConstruct cs.cs_cstr, extended_rel_list 0 cs.cs_args))
- cstrs in
- let ct = array_map2 (fun ci (_,_,t) -> (ci,t)) cis eqns in
- raise_pattern_matching_error (loc,env, CannotInferPredicate ct)
-(*
- (true,pred)
-*)
-
-(* Propagation of user-provided predicate through compilation steps *)
-
-let rec map_predicate f k = function
- | PrCcl ccl -> PrCcl (f k ccl)
- | PrProd pred ->
- PrProd (map_predicate f (k+1) pred)
- | PrLetIn ((names,dep as tm),pred) ->
- let k' = List.length names + (if dep<>Anonymous then 1 else 0) in
- PrLetIn (tm, map_predicate f (k+k') pred)
-
-let rec noccurn_predicate k = function
- | PrCcl ccl -> noccurn k ccl
- | PrProd pred -> noccurn_predicate (k+1) pred
- | PrLetIn ((names,dep),pred) ->
- let k' = List.length names + (if dep<>Anonymous then 1 else 0) in
- noccurn_predicate (k+k') pred
-
-let liftn_predicate n = map_predicate (liftn n)
-
-let lift_predicate n = liftn_predicate n 1
-
-let regeneralize_index_predicate n = map_predicate (regeneralize_index n) 0
-
-let substnl_predicate sigma = map_predicate (substnl sigma)
-
-(* This is parallel bindings *)
-let subst_predicate (args,copt) pred =
- let sigma = match copt with
- | None -> List.rev args
- | Some c -> c::(List.rev args) in
- substnl_predicate sigma 0 pred
-
-let specialize_predicate_var (cur,typ) = function
- | PrProd _ | PrCcl _ ->
- anomaly "specialize_predicate_var: a pattern-variable must be pushed"
- | PrLetIn (([],dep),pred) ->
- subst_predicate ([],if dep<>Anonymous then Some cur else None) pred
- | PrLetIn ((_,dep),pred) ->
- (match typ with
- | IsInd (_,IndType (_,realargs)) ->
- subst_predicate (realargs,if dep<>Anonymous then Some cur else None) pred
- | _ -> anomaly "specialize_predicate_var")
-
-let ungeneralize_predicate = function
- | PrLetIn _ | PrCcl _ -> anomaly "ungeneralize_predicate: expects a product"
- | PrProd pred -> pred
-
-(*****************************************************************************)
-(* We have pred = [X:=realargs;x:=c]P typed in Gamma1, x:I(realargs), Gamma2 *)
-(* and we want to abstract P over y:t(x) typed in the same context to get *)
-(* *)
-(* pred' = [X:=realargs;x':=c](y':t(x'))P[y:=y'] *)
-(* *)
-(* We first need to lift t(x) s.t. it is typed in Gamma, X:=rargs, x' *)
-(* then we have to replace x by x' in t(x) and y by y' in P *)
-(*****************************************************************************)
-let generalize_predicate ny d = function
- | PrLetIn ((names,dep as tm),pred) ->
- if dep=Anonymous then anomaly "Undetected dependency";
- let p = List.length names + 1 in
- let pred = lift_predicate 1 pred in
- let pred = regeneralize_index_predicate (ny+p+1) pred in
- PrLetIn (tm, PrProd pred)
- | PrProd _ | PrCcl _ ->
- anomaly "generalize_predicate: expects a non trivial pattern"
-
-let rec extract_predicate l = function
- | pred, Alias (deppat,nondeppat,_,_)::tms ->
- let tms' = match kind_of_term nondeppat with
- | Rel i -> replace_tomatch i deppat tms
- | _ -> (* initial terms are not dependent *) tms in
- extract_predicate l (pred,tms')
- | PrProd pred, Abstract d'::tms ->
- let d' = map_rel_declaration (lift (List.length l)) d' in
- substl l (mkProd_or_LetIn d' (extract_predicate [] (pred,tms)))
- | PrLetIn (([],dep),pred), Pushed ((cur,_),_)::tms ->
- extract_predicate (if dep<>Anonymous then cur::l else l) (pred,tms)
- | PrLetIn ((_,dep),pred), Pushed ((cur,IsInd (_,(IndType(_,realargs)))),_)::tms ->
- let l = List.rev realargs@l in
- extract_predicate (if dep<>Anonymous then cur::l else l) (pred,tms)
- | PrCcl ccl, [] ->
- substl l ccl
- | _ -> anomaly"extract_predicate: predicate inconsistent with terms to match"
-
-let abstract_predicate env sigma indf cur tms = function
- | (PrProd _ | PrCcl _) -> anomaly "abstract_predicate: must be some LetIn"
- | PrLetIn ((names,dep),pred) ->
- let sign = make_arity_signature env true indf in
- (* n is the number of real args + 1 *)
- let n = List.length sign in
- let tms = lift_tomatch_stack n tms in
- let tms =
- match kind_of_term cur with
- | Rel i -> regeneralize_index_tomatch (i+n) tms
- | _ -> (* Initial case *) tms in
- (* Depending on whether the predicate is dependent or not, and has real
- args or not, we lift it to make room for [sign] *)
- (* Even if not intrinsically dep, we move the predicate into a dep one *)
- let sign,k =
- if names = [] & n <> 1 then
- (* Real args were not considered *)
- (if dep<>Anonymous then
- ((let (_,c,t) = List.hd sign in (dep,c,t)::List.tl sign),n-1)
- else
- (sign,n))
- else
- (* Real args are OK *)
- (List.map2 (fun na (_,c,t) -> (na,c,t)) (dep::names) sign,
- if dep<>Anonymous then 0 else 1) in
- let pred = lift_predicate k pred in
- let pred = extract_predicate [] (pred,tms) in
- (true, it_mkLambda_or_LetIn_name env pred sign)
-
-let rec known_dependent = function
- | None -> false
- | Some (PrLetIn ((_,dep),_)) -> dep<>Anonymous
- | Some (PrCcl _) -> false
- | Some (PrProd _) ->
- anomaly "known_dependent: can only be used when patterns remain"
-
-(* [expand_arg] is used by [specialize_predicate]
- it replaces gamma, x1...xn, x1...xk |- pred
- by gamma, x1...xn, x1...xk-1 |- [X=realargs,xk=xk]pred (if dep) or
- by gamma, x1...xn, x1...xk-1 |- [X=realargs]pred (if not dep) *)
-
-let expand_arg n alreadydep (na,t) deps (k,pred) =
- (* current can occur in pred even if the original problem is not dependent *)
- let dep =
- if alreadydep<>Anonymous then alreadydep
- else if deps = [] && noccurn_predicate 1 pred then Anonymous
- else Name (id_of_string "x") in
- let pred = if dep<>Anonymous then pred else lift_predicate (-1) pred in
- (* There is no dependency in realargs for subpattern *)
- (k-1, PrLetIn (([],dep), pred))
-
-
-(*****************************************************************************)
-(* pred = [X:=realargs;x:=c]P types the following problem: *)
-(* *)
-(* Gamma |- match Pushed(c:I(realargs)) rest with...end: pred *)
-(* *)
-(* where the branch with constructor Ci:(x1:T1)...(xn:Tn)->I(realargsi) *)
-(* is considered. Assume each Ti is some Ii(argsi). *)
-(* We let e=Ci(x1,...,xn) and replace pred by *)
-(* *)
-(* pred' = [X1:=rargs1,x1:=x1']...[Xn:=rargsn,xn:=xn'](P[X:=realargsi;x:=e]) *)
-(* *)
-(* s.t Gamma,x1'..xn' |- match Pushed(x1')..Pushed(xn') rest with..end :pred'*)
-(* *)
-(*****************************************************************************)
-let specialize_predicate tomatchs deps cs = function
- | (PrProd _ | PrCcl _) ->
- anomaly "specialize_predicate: a matched pattern must be pushed"
- | PrLetIn ((names,isdep),pred) ->
- (* Assume some gamma st: gamma, (X,x:=realargs,copt) |- pred *)
- let nrealargs = List.length names in
- let k = nrealargs + (if isdep<>Anonymous then 1 else 0) in
- (* We adjust pred st: gamma, x1..xn, (X,x:=realargs,copt) |- pred' *)
- let n = cs.cs_nargs in
- let pred' = liftn_predicate n (k+1) pred in
- let argsi = if nrealargs <> 0 then Array.to_list cs.cs_concl_realargs else [] in
- let copti = if isdep<>Anonymous then Some (build_dependent_constructor cs) else None in
- (* The substituends argsi, copti are all defined in gamma, x1...xn *)
- (* We need _parallel_ bindings to get gamma, x1...xn |- pred'' *)
- let pred'' = subst_predicate (argsi, copti) pred' in
- (* We adjust pred st: gamma, x1..xn, x1..xn |- pred'' *)
- let pred''' = liftn_predicate n (n+1) pred'' in
- (* We finally get gamma,x1..xn |- [X1,x1:=R1,x1]..[Xn,xn:=Rn,xn]pred'''*)
- snd (List.fold_right2 (expand_arg n isdep) tomatchs deps (n,pred'''))
-
-let find_predicate loc env isevars p typs cstrs current
- (IndType (indf,realargs)) tms =
- let (dep,pred) =
- match p with
- | Some p -> abstract_predicate env (Evd.evars_of !isevars) indf current tms p
- | None -> infer_predicate loc env isevars typs cstrs indf in
- let typ = whd_beta (Evd.evars_of !isevars) (applist (pred, realargs)) in
- if dep then
- (pred, whd_beta (Evd.evars_of !isevars) (applist (typ, [current])),
- new_Type ())
- else
- (pred, typ, new_Type ())
-
-(************************************************************************)
-(* Sorting equations by constructor *)
-
-type inversion_problem =
- (* the discriminating arg in some Ind and its order in Ind *)
- | Incompatible of int * (int * int)
- | Constraints of (int * constr) list
-
-let solve_constraints constr_info indt =
- (* TODO *)
- Constraints []
-
-let rec irrefutable env = function
- | PatVar (_,name) -> true
- | PatCstr (_,cstr,args,_) ->
- let ind = inductive_of_constructor cstr in
- let (_,mip) = Inductive.lookup_mind_specif env ind in
- let one_constr = Array.length mip.mind_user_lc = 1 in
- one_constr & List.for_all (irrefutable env) args
-
-let first_clause_irrefutable env = function
- | eqn::mat -> List.for_all (irrefutable env) eqn.patterns
- | _ -> false
-
-let group_equations pb ind current cstrs mat =
- let mat =
- if first_clause_irrefutable pb.env mat then [List.hd mat] else mat in
- let brs = Array.create (Array.length cstrs) [] in
- let only_default = ref true in
- let _ =
- List.fold_right (* To be sure it's from bottom to top *)
- (fun eqn () ->
- let rest = remove_current_pattern eqn in
- let pat = current_pattern eqn in
- match check_and_adjust_constructor pb.env ind cstrs pat with
- | PatVar (_,name) ->
- (* This is a default clause that we expand *)
- for i=1 to Array.length cstrs do
- let n = cstrs.(i-1).cs_nargs in
- let args = make_anonymous_patvars n in
- brs.(i-1) <- (args, rest) :: brs.(i-1)
- done
- | PatCstr (loc,((_,i)),args,_) ->
- (* This is a regular clause *)
- only_default := false;
- brs.(i-1) <- (args,rest) :: brs.(i-1)) mat () in
- (brs,!only_default)
-
-(************************************************************************)
-(* Here starts the pattern-matching compilation algorithm *)
-
-(* Abstracting over dependent subterms to match *)
-let rec generalize_problem pb = function
- | [] -> pb
- | i::l ->
- let d = map_rel_declaration (lift i) (Environ.lookup_rel i pb.env) in
- let pb' = generalize_problem pb l in
- let tomatch = lift_tomatch_stack 1 pb'.tomatch in
- let tomatch = regeneralize_index_tomatch (i+1) tomatch in
- { pb with
- tomatch = Abstract d :: tomatch;
- pred = Option.map (generalize_predicate i d) pb'.pred }
-
-(* No more patterns: typing the right-hand-side of equations *)
-let build_leaf pb =
- let rhs = extract_rhs pb in
- let tycon = match pb.pred with
- | None -> anomaly "Predicate not found"
- | Some (PrCcl typ) -> mk_tycon typ
- | Some _ -> anomaly "not all parameters of pred have been consumed" in
- pb.typing_function tycon rhs.rhs_env rhs.it
-
-(* Building the sub-problem when all patterns are variables *)
-let shift_problem (current,t) pb =
- {pb with
- tomatch = Alias (current,current,NonDepAlias,type_of_tomatch t)::pb.tomatch;
- pred = Option.map (specialize_predicate_var (current,t)) pb.pred;
- history = push_history_pattern 0 AliasLeaf pb.history;
- mat = List.map remove_current_pattern pb.mat }
-
-(* Building the sub-pattern-matching problem for a given branch *)
-let build_branch current deps pb eqns const_info =
- (* We remember that we descend through a constructor *)
- let alias_type =
- if Array.length const_info.cs_concl_realargs = 0
- & not (known_dependent pb.pred) & deps = []
- then
- NonDepAlias
- else
- DepAlias
- in
- let history =
- push_history_pattern const_info.cs_nargs
- (AliasConstructor const_info.cs_cstr)
- pb.history in
-
- (* We find matching clauses *)
- let cs_args = (*assums_of_rel_context*) const_info.cs_args in
- let names = get_names pb.env cs_args eqns in
- let submat = List.map (fun (tms,eqn) -> prepend_pattern tms eqn) eqns in
- if submat = [] then
- raise_pattern_matching_error
- (dummy_loc, pb.env, NonExhaustive (complete_history history));
- let typs = List.map2 (fun (_,c,t) na -> (na,c,t)) cs_args names in
- let _,typs',_ =
- List.fold_right
- (fun (na,c,t as d) (env,typs,tms) ->
- let tm1 = List.map List.hd tms in
- let tms = List.map List.tl tms in
- (push_rel d env, (na,to_mutind env pb.isevars tm1 c t)::typs,tms))
- typs (pb.env,[],List.map fst eqns) in
-
- let dep_sign =
- find_dependencies_signature
- (dependencies_in_rhs const_info.cs_nargs eqns) (List.rev typs) in
-
- (* The dependent term to subst in the types of the remaining UnPushed
- terms is relative to the current context enriched by topushs *)
- let ci = build_dependent_constructor const_info in
-
- (* We replace [(mkRel 1)] by its expansion [ci] *)
- (* and context "Gamma = Gamma1, current, Gamma2" by "Gamma;typs;curalias" *)
- (* This is done in two steps : first from "Gamma |- tms" *)
- (* into "Gamma; typs; curalias |- tms" *)
- let tomatch = lift_tomatch_stack const_info.cs_nargs pb.tomatch in
-
- let currents =
- list_map2_i
- (fun i (na,t) deps -> Pushed ((mkRel i, lift_tomatch_type i t), deps))
- 1 typs' (List.rev dep_sign) in
-
- let sign = List.map (fun (na,t) -> mkDeclTomatch na t) typs' in
- let ind =
- appvect (
- applist (mkInd (inductive_of_constructor const_info.cs_cstr),
- List.map (lift const_info.cs_nargs) const_info.cs_params),
- const_info.cs_concl_realargs) in
-
- let cur_alias = lift (List.length sign) current in
- let currents = Alias (ci,cur_alias,alias_type,ind) :: currents in
- let env' = push_rels sign pb.env in
- let pred' = Option.map (specialize_predicate (List.rev typs') dep_sign const_info) pb.pred in
- sign,
- { pb with
- env = env';
- tomatch = List.rev_append currents tomatch;
- pred = pred';
- history = history;
- mat = List.map (push_rels_eqn_with_names sign) submat }
-
-(**********************************************************************
- INVARIANT:
-
- pb = { env, subst, tomatch, mat, ...}
- tomatch = list of Pushed (c:T) or Abstract (na:T) or Alias (c:T)
-
- "Pushed" terms and types are relative to env
- "Abstract" types are relative to env enriched by the previous terms to match
-
-*)
-
-(**********************************************************************)
-(* Main compiling descent *)
-let rec compile pb =
- match pb.tomatch with
- | (Pushed cur)::rest -> match_current { pb with tomatch = rest } cur
- | (Alias x)::rest -> compile_alias pb x rest
- | (Abstract d)::rest -> compile_generalization pb d rest
- | [] -> build_leaf pb
-
-and match_current pb tomatch =
- let ((current,typ as ct),deps) = adjust_tomatch_to_pattern pb tomatch in
- match typ with
- | NotInd (_,typ) ->
- check_all_variables typ pb.mat;
- compile (shift_problem ct pb)
- | IsInd (_,(IndType(indf,realargs) as indt)) ->
- let mind,_ = dest_ind_family indf in
- let cstrs = get_constructors pb.env indf in
- let eqns,onlydflt = group_equations pb mind current cstrs pb.mat in
- if (Array.length cstrs <> 0 or pb.mat <> []) & onlydflt then
- compile (shift_problem ct pb)
- else
- let _constraints = Array.map (solve_constraints indt) cstrs in
-
- (* We generalize over terms depending on current term to match *)
- let pb = generalize_problem pb deps in
-
- (* We compile branches *)
- let brs = array_map2 (compile_branch current deps pb) eqns cstrs in
-
- (* We build the (elementary) case analysis *)
- let brvals = Array.map (fun (v,_) -> v) brs in
- let brtyps = Array.map (fun (_,t) -> t) brs in
- let (pred,typ,s) =
- find_predicate pb.caseloc pb.env pb.isevars
- pb.pred brtyps cstrs current indt pb.tomatch in
- let ci = make_case_info pb.env mind pb.casestyle in
- let case = mkCase (ci,nf_betaiota Evd.empty pred,current,brvals) in
- let inst = List.map mkRel deps in
- { uj_val = applist (case, inst);
- uj_type = substl inst typ }
-
-and compile_branch current deps pb eqn cstr =
- let sign, pb = build_branch current deps pb eqn cstr in
- let j = compile pb in
- (it_mkLambda_or_LetIn j.uj_val sign, j.uj_type)
-
-and compile_generalization pb d rest =
- let pb =
- { pb with
- env = push_rel d pb.env;
- tomatch = rest;
- pred = Option.map ungeneralize_predicate pb.pred;
- mat = List.map (push_rels_eqn [d]) pb.mat } in
- let j = compile pb in
- { uj_val = mkLambda_or_LetIn d j.uj_val;
- uj_type = mkProd_or_LetIn d j.uj_type }
-
-and compile_alias pb (deppat,nondeppat,d,t) rest =
- let history = simplify_history pb.history in
- let sign, newenv, mat =
- insert_aliases pb.env (Evd.evars_of !(pb.isevars)) (deppat,nondeppat,d,t) pb.mat in
- let n = List.length sign in
-
- (* We had Gamma1; x:current; Gamma2 |- tomatch(x) and we rebind x to get *)
- (* Gamma1; x:current; Gamma2; typs; x':=curalias |- tomatch(x') *)
- let tomatch = lift_tomatch_stack n rest in
- let tomatch = match kind_of_term nondeppat with
- | Rel i ->
- if n = 1 then regeneralize_index_tomatch (i+n) tomatch
- else replace_tomatch i deppat tomatch
- | _ -> (* initial terms are not dependent *) tomatch in
-
- let pb =
- {pb with
- env = newenv;
- tomatch = tomatch;
- pred = Option.map (lift_predicate n) pb.pred;
- history = history;
- mat = mat } in
- let j = compile pb in
- List.fold_left mkSpecialLetInJudge j sign
-
-(* pour les alias des initiaux, enrichir les env de ce qu'il faut et
-substituer après par les initiaux *)
-
-(**************************************************************************)
-(* Preparation of the pattern-matching problem *)
-
-(* builds the matrix of equations testing that each eqn has n patterns
- * and linearizing the _ patterns.
- * Syntactic correctness has already been done in astterm *)
-let matx_of_eqns env eqns =
- let build_eqn (loc,ids,lpat,rhs) =
- let rhs =
- { rhs_env = env;
- avoid_ids = ids@(ids_of_named_context (named_context env));
- it = rhs;
- } in
- { patterns = lpat;
- alias_stack = [];
- eqn_loc = loc;
- used = ref false;
- rhs = rhs }
- in List.map build_eqn eqns
-
-(************************************************************************)
-(* preparing the elimination predicate if any *)
-
-let oldprepare_predicate_from_tycon loc dep env isevars tomatchs sign c =
- let cook (n, l, env, signs) = function
- | c,IsInd (_,IndType(indf,realargs)) ->
- let indf' = lift_inductive_family n indf in
- let sign = make_arity_signature env dep indf' in
- let p = List.length realargs in
- if dep then
- (n + p + 1, c::(List.rev realargs)@l, push_rels sign env,sign::signs)
- else
- (n + p, (List.rev realargs)@l, push_rels sign env,sign::signs)
- | c,NotInd _ ->
- (n, l, env, []::signs) in
- let n, allargs, env, signs = List.fold_left cook (0, [], env, []) tomatchs in
- let names = List.rev (List.map (List.map pi1) signs) in
- let allargs =
- List.map (fun c -> lift n (nf_betadeltaiota env (Evd.evars_of !isevars) c)) allargs in
- let rec build_skeleton env c =
- (* Don't put into normal form, it has effects on the synthesis of evars *)
- (* let c = whd_betadeltaiota env (evars_of isevars) c in *)
- (* We turn all subterms possibly dependent into an evar with maximum ctxt*)
- if isEvar c or List.exists (eq_constr c) allargs then
- e_new_evar isevars env ~src:(loc, Evd.CasesType)
- (Retyping.get_type_of env (Evd.evars_of !isevars) c)
- else
- map_constr_with_full_binders push_rel build_skeleton env c
- in
- names, build_skeleton env (lift n c)
-
-(* Here, [pred] is assumed to be in the context built from all *)
-(* realargs and terms to match *)
-let build_initial_predicate isdep allnames pred =
- let nar = List.fold_left (fun n names -> List.length names + n) 0 allnames in
- let rec buildrec n pred = function
- | [] -> PrCcl pred
- | names::lnames ->
- let names' = if isdep then List.tl names else names in
- let n' = n + List.length names' in
- let pred, p, user_p =
- if isdep then
- if dependent (mkRel (nar-n')) pred then pred, 1, 1
- else liftn (-1) (nar-n') pred, 0, 1
- else pred, 0, 0 in
- let na =
- if p=1 then
- let na = List.hd names in
- if na = Anonymous then
- (* peut arriver en raison des evars *)
- Name (id_of_string "x") (*Hum*)
- else na
- else Anonymous in
- PrLetIn ((names',na), buildrec (n'+user_p) pred lnames)
- in buildrec 0 pred allnames
-
-let extract_arity_signature env0 tomatchl tmsign =
- let get_one_sign n tm (na,t) =
- match tm with
- | NotInd (bo,typ) ->
- (match t with
- | None -> [na,Option.map (lift n) bo,lift n typ]
- | Some (loc,_,_,_) ->
- user_err_loc (loc,"",
- str "Unexpected type annotation for a term of non inductive type"))
- | IsInd (_,IndType(indf,realargs)) ->
- let indf' = lift_inductive_family n indf in
- let (ind,params) = dest_ind_family indf' in
- let nrealargs = List.length realargs in
- let realnal =
- match t with
- | Some (loc,ind',nparams,realnal) ->
- if ind <> ind' then
- user_err_loc (loc,"",str "Wrong inductive type");
- if List.length params <> nparams
- or nrealargs <> List.length realnal then
- anomaly "Ill-formed 'in' clause in cases";
- List.rev realnal
- | None -> list_tabulate (fun _ -> Anonymous) nrealargs in
- let arsign = fst (get_arity env0 indf') in
- (na,None,build_dependent_inductive env0 indf')
- ::(List.map2 (fun x (_,c,t) ->(x,c,t)) realnal arsign) in
- let rec buildrec n = function
- | [],[] -> []
- | (_,tm)::ltm, x::tmsign ->
- let l = get_one_sign n tm x in
- l :: buildrec (n + List.length l) (ltm,tmsign)
- | _ -> assert false
- in List.rev (buildrec 0 (tomatchl,tmsign))
-
-let extract_arity_signatures env0 tomatchl tmsign =
- let get_one_sign tm (na,t) =
- match tm with
- | NotInd (bo,typ) ->
- (match t with
- | None -> [na,bo,typ]
- | Some (loc,_,_,_) ->
- user_err_loc (loc,"",
- str "Unexpected type annotation for a term of non inductive type"))
- | IsInd (_,IndType(indf,realargs)) ->
- let (ind,params) = dest_ind_family indf in
- let nrealargs = List.length realargs in
- let realnal =
- match t with
- | Some (loc,ind',nparams,realnal) ->
- if ind <> ind' then
- user_err_loc (loc,"",str "Wrong inductive type");
- if List.length params <> nparams
- or nrealargs <> List.length realnal then
- anomaly "Ill-formed 'in' clause in cases";
- List.rev realnal
- | None -> list_tabulate (fun _ -> Anonymous) nrealargs in
- let arsign = fst (get_arity env0 indf) in
- (na,None,build_dependent_inductive env0 indf)
- ::(try List.map2 (fun x (_,c,t) ->(x,c,t)) realnal arsign with _ -> assert false) in
- let rec buildrec = function
- | [],[] -> []
- | (_,tm)::ltm, x::tmsign ->
- let l = get_one_sign tm x in
- l :: buildrec (ltm,tmsign)
- | _ -> assert false
- in List.rev (buildrec (tomatchl,tmsign))
-
-let inh_conv_coerce_to_tycon loc env isevars j tycon =
- match tycon with
- | Some p ->
- let (evd',j) = Coercion.inh_conv_coerce_to loc env !isevars j p in
- isevars := evd';
- j
- | None -> j
-
-let out_ind = function IsInd (_, IndType(x, y)) -> (x, y) | _ -> assert(false)
-
-let string_of_name name =
- match name with
- | Anonymous -> "anonymous"
- | Name n -> string_of_id n
-
-let id_of_name n = id_of_string (string_of_name n)
-
-let make_prime_id name =
- let str = string_of_name name in
- id_of_string str, id_of_string (str ^ "'")
-
-let prime avoid name =
- let previd, id = make_prime_id name in
- previd, next_ident_away_from id avoid
-
-let make_prime avoid prevname =
- let previd, id = prime !avoid prevname in
- avoid := id :: !avoid;
- previd, id
-
-let eq_id avoid id =
- let hid = id_of_string ("Heq_" ^ string_of_id id) in
- let hid' = next_ident_away_from hid avoid in
- hid'
-
-let mk_eq typ x y = mkApp (Lazy.force eq_ind, [| typ; x ; y |])
-let mk_eq_refl typ x = mkApp (Lazy.force eq_refl, [| typ; x |])
-
-let hole = RHole (dummy_loc, Evd.QuestionMark (Evd.Define true))
-
-let context_of_arsign l =
- let (x, _) = List.fold_right
- (fun c (x, n) ->
- (lift_rel_context n c @ x, List.length c + n))
- l ([], 0)
- in x
-
-let constr_of_pat env isevars arsign pat avoid =
- let rec typ env (ty, realargs) pat avoid =
- match pat with
- | PatVar (l,name) ->
- let name, avoid = match name with
- Name n -> name, avoid
- | Anonymous ->
- let previd, id = prime avoid (Name (id_of_string "wildcard")) in
- Name id, id :: avoid
- in
- PatVar (l, name), [name, None, ty] @ realargs, mkRel 1, ty, (List.map (fun x -> mkRel 1) realargs), 1, avoid
- | PatCstr (l,((_, i) as cstr),args,alias) ->
- let cind = inductive_of_constructor cstr in
- let IndType (indf, _) = find_rectype env (Evd.evars_of !isevars) (lift (-(List.length realargs)) ty) in
- let ind, params = dest_ind_family indf in
- if ind <> cind then error_bad_constructor_loc l cstr ind;
- let cstrs = get_constructors env indf in
- let ci = cstrs.(i-1) in
- let nb_args_constr = ci.cs_nargs in
- assert(nb_args_constr = List.length args);
- let patargs, args, sign, env, n, m, avoid =
- List.fold_right2
- (fun (na, c, t) ua (patargs, args, sign, env, n, m, avoid) ->
- let pat', sign', arg', typ', argtypargs, n', avoid =
- typ env (lift (n - m) t, []) ua avoid
- in
- let args' = arg' :: List.map (lift n') args in
- let env' = push_rels sign' env in
- (pat' :: patargs, args', sign' @ sign, env', n' + n, succ m, avoid))
- ci.cs_args (List.rev args) ([], [], [], env, 0, 0, avoid)
- in
- let args = List.rev args in
- let patargs = List.rev patargs in
- let pat' = PatCstr (l, cstr, patargs, alias) in
- let cstr = mkConstruct ci.cs_cstr in
- let app = applistc cstr (List.map (lift (List.length sign)) params) in
- let app = applistc app args in
- let apptype = Retyping.get_type_of env (Evd.evars_of !isevars) app in
- let IndType (indf, realargs) = find_rectype env (Evd.evars_of !isevars) apptype in
- match alias with
- Anonymous ->
- pat', sign, app, apptype, realargs, n, avoid
- | Name id ->
- let sign = (alias, None, lift m ty) :: sign in
- let avoid = id :: avoid in
- let sign, i, avoid =
- try
- let env = push_rels sign env in
- isevars := the_conv_x_leq (push_rels sign env) (lift (succ m) ty) (lift 1 apptype) !isevars;
- let eq_t = mk_eq (lift (succ m) ty)
- (mkRel 1) (* alias *)
- (lift 1 app) (* aliased term *)
- in
- let neq = eq_id avoid id in
- (Name neq, Some (mkRel 0), eq_t) :: sign, 2, neq :: avoid
- with Reduction.NotConvertible -> sign, 1, avoid
- in
- (* Mark the equality as a hole *)
- pat', sign, lift i app, lift i apptype, realargs, n + i, avoid
- in
- let pat', sign, patc, patty, args, z, avoid = typ env (pi3 (List.hd arsign), List.tl arsign) pat avoid in
- pat', (sign, patc, (pi3 (List.hd arsign), args), pat'), avoid
-
-
-(* shadows functional version *)
-let eq_id avoid id =
- let hid = id_of_string ("Heq_" ^ string_of_id id) in
- let hid' = next_ident_away_from hid !avoid in
- avoid := hid' :: !avoid;
- hid'
-
-let rels_of_patsign =
- List.map (fun ((na, b, t) as x) ->
- match b with
- | Some t' when kind_of_term t' = Rel 0 -> (na, None, t)
- | _ -> x)
-
-let vars_of_ctx ctx =
- let _, y =
- List.fold_right (fun (na, b, t) (prev, vars) ->
- match b with
- | Some t' when kind_of_term t' = Rel 0 ->
- prev,
- (RApp (dummy_loc,
- (RRef (dummy_loc, Lazy.force refl_ref)), [hole; RVar (dummy_loc, prev)])) :: vars
- | _ ->
- match na with
- Anonymous -> raise (Invalid_argument "vars_of_ctx")
- | Name n -> n, RVar (dummy_loc, n) :: vars)
- ctx (id_of_string "vars_of_ctx_error", [])
- in List.rev y
-
-let rec is_included x y =
- match x, y with
- | PatVar _, _ -> true
- | _, PatVar _ -> true
- | PatCstr (l, (_, i), args, alias), PatCstr (l', (_, i'), args', alias') ->
- if i = i' then List.for_all2 is_included args args'
- else false
-
-(* liftsign is the current pattern's complete signature length. Hence pats is already typed in its
- full signature. However prevpatterns are in the original one signature per pattern form.
- *)
-let build_ineqs prevpatterns pats liftsign =
- let _tomatchs = List.length pats in
- let diffs =
- List.fold_left
- (fun c eqnpats ->
- let acc = List.fold_left2
- (* ppat is the pattern we are discriminating against, curpat is the current one. *)
- (fun acc (ppat_sign, ppat_c, (ppat_ty, ppat_tyargs), ppat)
- (curpat_sign, curpat_c, (curpat_ty, curpat_tyargs), curpat) ->
- match acc with
- None -> None
- | Some (sign, len, n, c) -> (* FixMe: do not work with ppat_args *)
- if is_included curpat ppat then
- (* Length of previous pattern's signature *)
- let lens = List.length ppat_sign in
- (* Accumulated length of previous pattern's signatures *)
- let len' = lens + len in
- let acc =
- ((* Jump over previous prevpat signs *)
- lift_rel_context len ppat_sign @ sign,
- len',
- succ n, (* nth pattern *)
- mkApp (Lazy.force eq_ind,
- [| lift (len' + liftsign) curpat_ty;
- liftn (len + liftsign) (succ lens) ppat_c ;
- lift len' curpat_c |]) ::
- List.map (lift lens (* Jump over this prevpat signature *)) c)
- in Some acc
- else None)
- (Some ([], 0, 0, [])) eqnpats pats
- in match acc with
- None -> c
- | Some (sign, len, _, c') ->
- let conj = it_mkProd_or_LetIn (mk_not (mk_conj c'))
- (lift_rel_context liftsign sign)
- in
- conj :: c)
- [] prevpatterns
- in match diffs with [] -> None
- | _ -> Some (mk_conj diffs)
-
-let subst_rel_context k ctx subst =
- let (_, ctx') =
- List.fold_right
- (fun (n, b, t) (k, acc) ->
- (succ k, (n, Option.map (substnl subst k) b, substnl subst k t) :: acc))
- ctx (k, [])
- in ctx'
-
-let lift_rel_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
-
-let constrs_of_pats typing_fun env isevars eqns tomatchs sign neqs arity =
- let i = ref 0 in
- let (x, y, z) =
- List.fold_left
- (fun (branches, eqns, prevpatterns) eqn ->
- let _, newpatterns, pats =
- List.fold_left2
- (fun (idents, newpatterns, pats) pat arsign ->
- let pat', cpat, idents = constr_of_pat env isevars arsign pat idents in
- (idents, pat' :: newpatterns, cpat :: pats))
- ([], [], []) eqn.patterns sign
- in
- let newpatterns = List.rev newpatterns and opats = List.rev pats in
- let rhs_rels, pats, signlen =
- List.fold_left
- (fun (renv, pats, n) (sign,c, (s, args), p) ->
- (* Recombine signatures and terms of all of the row's patterns *)
- let sign' = lift_rel_context n sign in
- let len = List.length sign' in
- (sign' @ renv,
- (* lift to get outside of previous pattern's signatures. *)
- (sign', liftn n (succ len) c, (s, List.map (liftn n (succ len)) args), p) :: pats,
- len + n))
- ([], [], 0) opats in
- let pats, _ = List.fold_left
- (* lift to get outside of past patterns to get terms in the combined environment. *)
- (fun (pats, n) (sign, c, (s, args), p) ->
- let len = List.length sign in
- ((rels_of_patsign sign, lift n c, (s, List.map (lift n) args), p) :: pats, len + n))
- ([], 0) pats
- in
- let ineqs = build_ineqs prevpatterns pats signlen in
- let rhs_rels' = rels_of_patsign rhs_rels in
- let _signenv = push_rel_context rhs_rels' env in
- let arity =
- let args, nargs =
- List.fold_right (fun (sign, c, (_, args), _) (allargs,n) ->
- (args @ c :: allargs, List.length args + succ n))
- pats ([], 0)
- in
- let args = List.rev args in
- substl args (liftn signlen (succ nargs) arity)
- in
- let rhs_rels', tycon =
- let neqs_rels, arity =
- match ineqs with
- | None -> [], arity
- | Some ineqs ->
- [Anonymous, None, ineqs], lift 1 arity
- in
- let eqs_rels, arity = decompose_prod_n_assum neqs arity in
- eqs_rels @ neqs_rels @ rhs_rels', arity
- in
- let rhs_env = push_rels rhs_rels' env in
- let j = typing_fun (mk_tycon tycon) rhs_env eqn.rhs.it in
- let bbody = it_mkLambda_or_LetIn j.uj_val rhs_rels'
- and btype = it_mkProd_or_LetIn j.uj_type rhs_rels' in
- let branch_name = id_of_string ("branch_" ^ (string_of_int !i)) in
- let branch_decl = (Name branch_name, Some (lift !i bbody), (lift !i btype)) in
- let branch =
- let bref = RVar (dummy_loc, branch_name) in
- match vars_of_ctx rhs_rels with
- [] -> bref
- | l -> RApp (dummy_loc, bref, l)
- in
- let branch = match ineqs with
- Some _ -> RApp (dummy_loc, branch, [ hole ])
- | None -> branch
- in
- incr i;
- let rhs = { eqn.rhs with it = branch } in
- (branch_decl :: branches,
- { eqn with patterns = newpatterns; rhs = rhs } :: eqns,
- opats :: prevpatterns))
- ([], [], []) eqns
- in x, y
-
-(* Builds the predicate. If the predicate is dependent, its context is
- * made of 1+nrealargs assumptions for each matched term in an inductive
- * type and 1 assumption for each term not _syntactically_ in an
- * inductive type.
-
- * Each matched terms are independently considered dependent or not.
-
- * A type constraint but no annotation case: it is assumed non dependent.
- *)
-
-let lift_ctx n ctx =
- let ctx', _ =
- List.fold_right (fun (c, t) (ctx, n') -> (liftn n n' c, liftn_tomatch_type n n' t) :: ctx, succ n') ctx ([], 0)
- in ctx'
-
-(* Turn matched terms into variables. *)
-let abstract_tomatch env tomatchs =
- let prev, ctx, names =
- List.fold_left
- (fun (prev, ctx, names) (c, t) ->
- let lenctx = List.length ctx in
- match kind_of_term c with
- Rel n -> (lift lenctx c, lift_tomatch_type lenctx t) :: prev, ctx, names
- | _ ->
- let name = next_ident_away_from (id_of_string "filtered_var") names in
- (mkRel 1, lift_tomatch_type (succ lenctx) t) :: lift_ctx 1 prev,
- (Name name, Some (lift lenctx c), lift lenctx $ type_of_tomatch t) :: ctx,
- name :: names)
- ([], [], []) tomatchs
- in List.rev prev, ctx
-
-let is_dependent_ind = function
- IsInd (_, IndType (indf, args)) when List.length args > 0 -> true
- | _ -> false
-
-let build_dependent_signature env evars avoid tomatchs arsign =
- let avoid = ref avoid in
- let arsign = List.rev arsign in
- let allnames = List.rev (List.map (List.map pi1) arsign) in
- let nar = List.fold_left (fun n names -> List.length names + n) 0 allnames in
- let eqs, neqs, refls, slift, arsign' =
- List.fold_left2
- (fun (eqs, neqs, refl_args, slift, arsigns) (tm, ty) arsign ->
- (* The accumulator:
- previous eqs,
- number of previous eqs,
- lift to get outside eqs and in the introduced variables ('as' and 'in'),
- new arity signatures
- *)
- match ty with
- IsInd (ty, IndType (indf, args)) when List.length args > 0 ->
- (* Build the arity signature following the names in matched terms as much as possible *)
- let argsign = List.tl arsign in (* arguments in inverse application order *)
- let (appn, appb, appt) as _appsign = List.hd arsign in (* The matched argument *)
- let argsign = List.rev argsign in (* arguments in application order *)
- let env', nargeqs, argeqs, refl_args, slift, argsign' =
- List.fold_left2
- (fun (env, nargeqs, argeqs, refl_args, slift, argsign') arg (name, b, t) ->
- let argt = Retyping.get_type_of env evars arg in
- let eq, refl_arg =
- if Reductionops.is_conv env evars argt t then
- (mk_eq (lift (nargeqs + slift) argt)
- (mkRel (nargeqs + slift))
- (lift (nargeqs + nar) arg),
- mk_eq_refl argt arg)
- else
- (mk_JMeq (lift (nargeqs + slift) t)
- (mkRel (nargeqs + slift))
- (lift (nargeqs + nar) argt)
- (lift (nargeqs + nar) arg),
- mk_JMeq_refl argt arg)
- in
- let previd, id =
- let name =
- match kind_of_term arg with
- Rel n -> pi1 (Environ.lookup_rel n env)
- | _ -> name
- in
- make_prime avoid name
- in
- (env, succ nargeqs,
- (Name (eq_id avoid previd), None, eq) :: argeqs,
- refl_arg :: refl_args,
- pred slift,
- (Name id, b, t) :: argsign'))
- (env, 0, [], [], slift, []) args argsign
- in
- let eq = mk_JMeq
- (lift (nargeqs + slift) appt)
- (mkRel (nargeqs + slift))
- (lift (nargeqs + nar) ty)
- (lift (nargeqs + nar) tm)
- in
- let refl_eq = mk_JMeq_refl ty tm in
- let previd, id = make_prime avoid appn in
- (((Name (eq_id avoid previd), None, eq) :: argeqs) :: eqs,
- succ nargeqs,
- refl_eq :: refl_args,
- pred slift,
- (((Name id, appb, appt) :: argsign') :: arsigns))
-
- | _ ->
- (* Non dependent inductive or not inductive, just use a regular equality *)
- let (name, b, typ) = match arsign with [x] -> x | _ -> assert(false) in
- let previd, id = make_prime avoid name in
- let arsign' = (Name id, b, typ) in
- let tomatch_ty = type_of_tomatch ty in
- let eq =
- mk_eq (lift nar tomatch_ty)
- (mkRel slift) (lift nar tm)
- in
- ([(Name (eq_id avoid previd), None, eq)] :: eqs, succ neqs,
- (mk_eq_refl tomatch_ty tm) :: refl_args,
- pred slift, (arsign' :: []) :: arsigns))
- ([], 0, [], nar, []) tomatchs arsign
- in
- let arsign'' = List.rev arsign' in
- assert(slift = 0); (* we must have folded over all elements of the arity signature *)
- arsign'', allnames, nar, eqs, neqs, refls
-
-(**************************************************************************)
-(* Main entry of the matching compilation *)
-
-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 nf_evars_env evar_defs (env : env) : env =
- let nf t = nf_isevar evar_defs t in
- let env0 : env = reset_context env in
- let f e (na, b, t) e' : env =
- Environ.push_named (na, Option.map nf b, nf t) e'
- in
- let env' = Environ.fold_named_context f ~init:env0 env in
- Environ.fold_rel_context (fun e (na, b, t) e' -> Environ.push_rel (na, Option.map nf b, nf t) e')
- ~init:env' env
-
-(* We put the tycon inside the arity signature, possibly discovering dependencies. *)
-
-let prepare_predicate_from_arsign_tycon loc env evm tomatchs arsign c =
- let nar = List.fold_left (fun n sign -> List.length sign + n) 0 arsign in
- let subst, len =
- List.fold_left2 (fun (subst, len) (tm, tmtype) sign ->
- let signlen = List.length sign in
- match kind_of_term tm with
- | Rel n when dependent tm c
- && signlen = 1 (* The term to match is not of a dependent type itself *) ->
- ((n, len) :: subst, len - signlen)
- | Rel _ when not (dependent tm c)
- && signlen > 1 (* The term is of a dependent type but does not appear in
- the tycon, maybe some variable in its type does. *) ->
- (match tmtype with
- NotInd _ -> (* len - signlen, subst*) assert false (* signlen > 1 *)
- | IsInd (_, IndType(indf,realargs)) ->
- List.fold_left
- (fun (subst, len) arg ->
- match kind_of_term arg with
- | Rel n when dependent arg c ->
- ((n, len) :: subst, pred len)
- | _ -> (subst, pred len))
- (subst, len) realargs)
- | _ -> (subst, len - signlen))
- ([], nar) tomatchs arsign
- in
- let rec predicate lift c =
- match kind_of_term c with
- | Rel n when n > lift ->
- (try
- (* Make the predicate dependent on the matched variable *)
- let idx = List.assoc (n - lift) subst in
- mkRel (idx + lift)
- with Not_found ->
- (* A variable that is not matched, lift over the arsign. *)
- mkRel (n + nar))
- | _ ->
- map_constr_with_binders succ predicate lift c
- in
- try
- (* The tycon may be ill-typed after abstraction. *)
- let pred = predicate 0 c in
- let env' = push_rel_context (context_of_arsign arsign) env in
- ignore(Typing.sort_of env' evm pred); pred
- with _ -> lift nar c
-
-
-let prepare_predicate_from_rettyp loc typing_fun isevars env tomatchs sign tycon rtntyp =
- (* We extract the signature of the arity *)
- let arsign = extract_arity_signature env tomatchs sign in
- let newenv = List.fold_right push_rels arsign env in
- let allnames = List.rev (List.map (List.map pi1) arsign) in
- match rtntyp with
- | Some rtntyp ->
- let predcclj = typing_fun (mk_tycon (new_Type ())) newenv rtntyp in
- let predccl = (j_nf_isevar !isevars predcclj).uj_val in
- Some (build_initial_predicate true allnames predccl)
- | None ->
- match valcon_of_tycon tycon with
- | Some ty ->
- let pred =
- prepare_predicate_from_arsign_tycon loc env (Evd.evars_of !isevars) tomatchs arsign ty
- in Some (build_initial_predicate true allnames pred)
- | None -> None
-
-let compile_cases loc style (typing_fun, isevars) (tycon : Evarutil.type_constraint) env (predopt, tomatchl, eqns) =
-
- let typing_fun tycon env = typing_fun tycon env isevars in
-
- (* We build the matrix of patterns and right-hand-side *)
- let matx = matx_of_eqns env eqns in
-
- (* We build the vector of terms to match consistently with the *)
- (* constructors found in patterns *)
- let tomatchs = coerce_to_indtype typing_fun isevars env matx tomatchl in
- let _isdep = List.exists (fun (x, y) -> is_dependent_ind y) tomatchs in
- if predopt = None then
- let tomatchs, tomatchs_lets = abstract_tomatch env tomatchs in
- let tomatchs_len = List.length tomatchs_lets in
- let env = push_rel_context tomatchs_lets env in
- let len = List.length eqns in
- let sign, allnames, signlen, eqs, neqs, args =
- (* The arity signature *)
- let arsign = extract_arity_signatures env tomatchs (List.map snd tomatchl) in
- (* Build the dependent arity signature, the equalities which makes
- the first part of the predicate and their instantiations. *)
- let avoid = [] in
- build_dependent_signature env (Evd.evars_of !isevars) avoid tomatchs arsign
-
- in
- let tycon, arity =
- match valcon_of_tycon tycon with
- | None -> let ev = mkExistential env isevars in ev, ev
- | Some t ->
- t, prepare_predicate_from_arsign_tycon loc env (Evd.evars_of !isevars)
- tomatchs sign (lift tomatchs_len t)
- in
- let neqs, arity =
- let ctx = context_of_arsign eqs in
- let neqs = List.length ctx in
- neqs, it_mkProd_or_LetIn (lift neqs arity) ctx
- in
- let lets, matx =
- (* Type the rhs under the assumption of equations *)
- constrs_of_pats typing_fun env isevars matx tomatchs sign neqs arity
- in
- let matx = List.rev matx in
- let _ = assert(len = List.length lets) in
- let env = push_rels lets env in
- let matx = List.map (fun eqn -> { eqn with rhs = { eqn.rhs with rhs_env = env } }) matx in
- let tomatchs = List.map (fun (x, y) -> lift len x, lift_tomatch_type len y) tomatchs in
- let args = List.rev_map (lift len) args in
- let pred = liftn len (succ signlen) arity in
- let pred = build_initial_predicate true allnames pred in
-
- (* We push the initial terms to match and push their alias to rhs' envs *)
- (* names of aliases will be recovered from patterns (hence Anonymous here) *)
- let initial_pushed = List.map (fun tm -> Pushed (tm,[])) tomatchs in
-
- let pb =
- { env = env;
- isevars = isevars;
- pred = Some pred;
- tomatch = initial_pushed;
- history = start_history (List.length initial_pushed);
- mat = matx;
- caseloc = loc;
- casestyle= style;
- typing_function = typing_fun } in
-
- let j = compile pb in
- (* We check for unused patterns *)
- List.iter (check_unused_pattern env) matx;
- let body = it_mkLambda_or_LetIn (applistc j.uj_val args) lets in
- let j =
- { uj_val = it_mkLambda_or_LetIn body tomatchs_lets;
- uj_type = nf_isevar !isevars tycon; }
- in j
- else
- (* We build the elimination predicate if any and check its consistency *)
- (* with the type of arguments to match *)
- let tmsign = List.map snd tomatchl in
- let pred = prepare_predicate_from_rettyp loc typing_fun isevars env tomatchs tmsign tycon predopt in
-
- (* We push the initial terms to match and push their alias to rhs' envs *)
- (* names of aliases will be recovered from patterns (hence Anonymous here) *)
- let initial_pushed = List.map (fun tm -> Pushed (tm,[])) tomatchs in
- let pb =
- { env = env;
- isevars = isevars;
- pred = pred;
- tomatch = initial_pushed;
- history = start_history (List.length initial_pushed);
- mat = matx;
- caseloc = loc;
- casestyle= style;
- typing_function = typing_fun } in
-
- let j = compile pb in
- (* We check for unused patterns *)
- List.iter (check_unused_pattern env) matx;
- inh_conv_coerce_to_tycon loc env isevars j tycon
-
-end
-
diff --git a/contrib/subtac/subtac_cases.mli b/contrib/subtac/subtac_cases.mli
deleted file mode 100644
index 6b8a0981..00000000
--- a/contrib/subtac/subtac_cases.mli
+++ /dev/null
@@ -1,23 +0,0 @@
-(************************************************************************)
-(* 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 $Id: subtac_cases.mli 10739 2008-04-01 14:45:20Z herbelin $ i*)
-
-(*i*)
-open Util
-open Names
-open Term
-open Evd
-open Environ
-open Inductiveops
-open Rawterm
-open Evarutil
-(*i*)
-
-(*s Compilation of pattern-matching, subtac style. *)
-module Cases_F(C : Coercion.S) : Cases.S
diff --git a/contrib/subtac/subtac_classes.ml b/contrib/subtac/subtac_classes.ml
deleted file mode 100644
index 9b692d85..00000000
--- a/contrib/subtac/subtac_classes.ml
+++ /dev/null
@@ -1,194 +0,0 @@
-(************************************************************************)
-(* 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 $Id: subtac_classes.ml 12187 2009-06-13 19:36:59Z msozeau $ i*)
-
-open Pretyping
-open Evd
-open Environ
-open Term
-open Rawterm
-open Topconstr
-open Names
-open Libnames
-open Pp
-open Vernacexpr
-open Constrintern
-open Subtac_command
-open Typeclasses
-open Typeclasses_errors
-open Termops
-open Decl_kinds
-open Entries
-open Util
-
-module SPretyping = Subtac_pretyping.Pretyping
-
-let interp_binder_evars evdref env na t =
- let t = Constrintern.intern_gen true (Evd.evars_of !evdref) env t in
- SPretyping.understand_tcc_evars evdref env IsType t
-
-let interp_binders_evars isevars env avoid l =
- List.fold_left
- (fun (env, ids, params) ((loc, i), t) ->
- let n = Name i in
- let t' = interp_binder_evars isevars env n t in
- let d = (i,None,t') in
- (push_named d env, i :: ids, d::params))
- (env, avoid, []) l
-
-let interp_typeclass_context_evars isevars env avoid l =
- List.fold_left
- (fun (env, ids, params) (iid, bk, cl) ->
- let t' = interp_binder_evars isevars env (snd iid) cl in
- let i = match snd iid with
- | Anonymous -> Nameops.next_name_away (Termops.named_hd env t' Anonymous) ids
- | Name id -> id
- in
- let d = (i,None,t') in
- (push_named d env, i :: ids, d::params))
- (env, avoid, []) l
-
-let interp_constrs_evars isevars env avoid l =
- List.fold_left
- (fun (env, ids, params) t ->
- let t' = interp_binder_evars isevars env Anonymous t in
- let id = Nameops.next_name_away (Termops.named_hd env t' Anonymous) ids in
- let d = (id,None,t') in
- (push_named d env, id :: ids, d::params))
- (env, avoid, []) l
-
-let interp_constr_evars_gen evdref env ?(impls=([],[])) kind c =
- SPretyping.understand_tcc_evars evdref env kind
- (intern_gen (kind=IsType) ~impls (Evd.evars_of !evdref) env c)
-
-let interp_casted_constr_evars evdref env ?(impls=([],[])) c typ =
- interp_constr_evars_gen evdref env ~impls (OfType (Some typ)) c
-
-let type_ctx_instance isevars env ctx inst subst =
- List.fold_left2
- (fun (subst, instctx) (na, _, t) ce ->
- let t' = substl subst t in
- let c = interp_casted_constr_evars isevars env ce t' in
- isevars := resolve_typeclasses ~onlyargs:true ~fail:true env !isevars;
- let d = na, Some c, t' in
- c :: subst, d :: instctx)
- (subst, []) (List.rev ctx) inst
-
-let type_class_instance_params isevars env id n ctx inst subst =
- List.fold_left2
- (fun (subst, instctx) (na, _, t) ce ->
- let t' = replace_vars subst t in
- let c = interp_casted_constr_evars isevars env ce t' in
- let d = na, Some c, t' in
- (na, c) :: subst, d :: instctx)
- (subst, []) (List.rev ctx) inst
-
-let substitution_of_constrs ctx cstrs =
- List.fold_right2 (fun c (na, _, _) acc -> (na, c) :: acc) cstrs ctx []
-
-let new_instance ?(global=false) ctx (instid, bk, cl) props ?(generalize=true) pri =
- let env = Global.env() in
- let isevars = ref (Evd.create_evar_defs Evd.empty) in
- let tclass =
- match bk with
- | Implicit ->
- Implicit_quantifiers.implicit_application Idset.empty (* need no avoid *)
- ~allow_partial:false (fun avoid (clname, (id, _, t)) ->
- match clname with
- | Some (cl, b) ->
- let t =
- if b then
- let _k = class_info cl in
- CHole (Util.dummy_loc, Some Evd.InternalHole)
- else CHole (Util.dummy_loc, None)
- in t, avoid
- | None -> failwith ("new instance: under-applied typeclass"))
- cl
- | Explicit -> cl
- in
- let tclass = if generalize then CGeneralization (dummy_loc, Implicit, Some AbsPi, tclass) else tclass in
- let k, ctx', imps, subst =
- let c = Command.generalize_constr_expr tclass ctx in
- let c', imps = interp_type_evars_impls ~evdref:isevars env c in
- let ctx, c = Sign.decompose_prod_assum c' in
- let cl, args = Typeclasses.dest_class_app (push_rel_context ctx env) c in
- cl, ctx, imps, (List.rev args)
- in
- let id =
- match snd instid with
- | Name id ->
- let sp = Lib.make_path id in
- if Nametab.exists_cci sp then
- errorlabstrm "new_instance" (Nameops.pr_id id ++ Pp.str " already exists");
- id
- | Anonymous ->
- let i = Nameops.add_suffix (Classes.id_of_class k) "_instance_0" in
- Termops.next_global_ident_away false i (Termops.ids_of_context env)
- in
- let env' = push_rel_context ctx' env in
- isevars := Evarutil.nf_evar_defs !isevars;
- isevars := resolve_typeclasses ~onlyargs:false ~fail:true env' !isevars;
- let sigma = Evd.evars_of !isevars in
- let subst = List.map (Evarutil.nf_evar sigma) subst in
- let subst =
- let props =
- match props with
- | CRecord (loc, _, fs) ->
- if List.length fs > List.length k.cl_props then
- Classes.mismatched_props env' (List.map snd fs) k.cl_props;
- fs
- | _ ->
- if List.length k.cl_props <> 1 then
- errorlabstrm "new_instance" (Pp.str "Expected a definition for the instance body")
- else [(dummy_loc, Nameops.out_name (pi1 (List.hd k.cl_props))), props]
- in
- match k.cl_props with
- | [(na,b,ty)] ->
- let term = match props with [] -> CHole (Util.dummy_loc, None) | [(_,f)] -> f | _ -> assert false in
- let ty' = substl subst ty in
- let c = interp_casted_constr_evars isevars env' term ty' in
- c :: subst
- | _ ->
- let props, rest =
- List.fold_left
- (fun (props, rest) (id,_,_) ->
- try
- let ((loc, mid), c) = List.find (fun ((_,id'), c) -> Name id' = id) rest in
- let rest' = List.filter (fun ((_,id'), c) -> Name id' <> id) rest in
- Option.iter (fun x -> Dumpglob.add_glob loc (ConstRef x)) (List.assoc mid k.cl_projs);
- c :: props, rest'
- with Not_found -> (CHole (Util.dummy_loc, None) :: props), rest)
- ([], props) k.cl_props
- in
- if rest <> [] then
- unbound_method env' k.cl_impl (fst (List.hd rest))
- else
- fst (type_ctx_instance isevars env' k.cl_props props subst)
- in
- let subst = List.fold_left2
- (fun subst' s (_, b, _) -> if b = None then s :: subst' else subst')
- [] subst (k.cl_props @ snd k.cl_context)
- in
- let inst_constr, ty_constr = instance_constructor k subst in
- isevars := Evarutil.nf_evar_defs !isevars;
- let term = Evarutil.nf_isevar !isevars (it_mkLambda_or_LetIn inst_constr ctx')
- and termtype = Evarutil.nf_isevar !isevars (it_mkProd_or_LetIn ty_constr ctx')
- in
- isevars := undefined_evars !isevars;
- Evarutil.check_evars env Evd.empty !isevars termtype;
- let hook vis gr =
- let cst = match gr with ConstRef kn -> kn | _ -> assert false in
- let inst = Typeclasses.new_instance k pri global cst in
- Impargs.declare_manual_implicits false gr ~enriching:false imps;
- Typeclasses.add_instance inst
- in
- let evm = Subtac_utils.evars_of_term (Evd.evars_of !isevars) Evd.empty term in
- let obls, constr, typ = Eterm.eterm_obligations env id !isevars evm 0 term termtype in
- id, Subtac_obligations.add_definition id constr typ ~kind:(Global,false,Instance) ~hook obls
-
diff --git a/contrib/subtac/subtac_classes.mli b/contrib/subtac/subtac_classes.mli
deleted file mode 100644
index 96a51027..00000000
--- a/contrib/subtac/subtac_classes.mli
+++ /dev/null
@@ -1,42 +0,0 @@
-(************************************************************************)
-(* 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 $Id: subtac_classes.mli 11709 2008-12-20 11:42:15Z msozeau $ i*)
-
-(*i*)
-open Names
-open Decl_kinds
-open Term
-open Sign
-open Evd
-open Environ
-open Nametab
-open Mod_subst
-open Topconstr
-open Util
-open Typeclasses
-open Implicit_quantifiers
-open Classes
-(*i*)
-
-val type_ctx_instance : Evd.evar_defs ref ->
- Environ.env ->
- ('a * Term.constr option * Term.constr) list ->
- Topconstr.constr_expr list ->
- Term.constr list ->
- Term.constr list *
- ('a * Term.constr option * Term.constr) list
-
-val new_instance :
- ?global:bool ->
- local_binder list ->
- typeclass_constraint ->
- constr_expr ->
- ?generalize:bool ->
- int option ->
- identifier * Subtac_obligations.progress
diff --git a/contrib/subtac/subtac_coercion.ml b/contrib/subtac/subtac_coercion.ml
deleted file mode 100644
index 1bbbfbb1..00000000
--- a/contrib/subtac/subtac_coercion.ml
+++ /dev/null
@@ -1,504 +0,0 @@
-(* -*- 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 *)
-(************************************************************************)
-(* $Id: subtac_coercion.ml 11576 2008-11-10 19:13:15Z msozeau $ *)
-
-open Util
-open Names
-open Term
-open Reductionops
-open Environ
-open Typeops
-open Pretype_errors
-open Classops
-open Recordops
-open Evarutil
-open Evarconv
-open Retyping
-open Evd
-
-open Global
-open Subtac_utils
-open Coqlib
-open Printer
-open Subtac_errors
-open Eterm
-open Pp
-
-let pair_of_array a = (a.(0), a.(1))
-let make_name s = Name (id_of_string s)
-
-let rec disc_subset x =
- match kind_of_term x with
- | App (c, l) ->
- (match kind_of_term c with
- Ind i ->
- let len = Array.length l in
- let sig_ = Lazy.force sig_ in
- if len = 2 && i = Term.destInd sig_.typ
- then
- let (a, b) = pair_of_array l in
- Some (a, b)
- else None
- | _ -> None)
- | _ -> None
-
-and disc_exist env x =
- match kind_of_term x with
- | App (c, l) ->
- (match kind_of_term c with
- Construct c ->
- if c = Term.destConstruct (Lazy.force sig_).intro
- then Some (l.(0), l.(1), l.(2), l.(3))
- else None
- | _ -> None)
- | _ -> None
-
-module Coercion = struct
-
- exception NoSubtacCoercion
-
- let disc_proj_exist env x =
- match kind_of_term x with
- | App (c, l) ->
- (if Term.eq_constr c (Lazy.force sig_).proj1
- && Array.length l = 3
- then disc_exist env l.(2)
- else None)
- | _ -> None
-
-
- let sort_rel s1 s2 =
- match s1, s2 with
- Prop Pos, Prop Pos -> Prop Pos
- | Prop Pos, Prop Null -> Prop Null
- | Prop Null, Prop Null -> Prop Null
- | Prop Null, Prop Pos -> Prop Pos
- | Type _, Prop Pos -> Prop Pos
- | Type _, Prop Null -> Prop Null
- | _, Type _ -> s2
-
- let hnf env isevars c = whd_betadeltaiota env (evars_of !isevars) c
-
- let lift_args n sign =
- let rec liftrec k = function
- | t::sign -> liftn n k t :: (liftrec (k-1) sign)
- | [] -> []
- in
- liftrec (List.length sign) sign
-
- let rec mu env isevars t =
- let isevars = ref isevars in
- let rec aux v =
- let v = hnf env isevars v in
- match disc_subset v with
- Some (u, p) ->
- let f, ct = aux u in
- (Some (fun x ->
- app_opt f (mkApp ((Lazy.force sig_).proj1,
- [| u; p; x |]))),
- ct)
- | None -> (None, v)
- in aux t
-
- and coerce loc env isevars (x : Term.constr) (y : Term.constr)
- : (Term.constr -> Term.constr) option
- =
- let x = nf_evar (evars_of !isevars) x and y = nf_evar (evars_of !isevars) y in
- let rec coerce_unify env x y =
- let x = hnf env isevars x and y = hnf env isevars y in
- try
- isevars := the_conv_x_leq env x y !isevars;
- None
- with Reduction.NotConvertible -> coerce' env x y
- and coerce' env x y : (Term.constr -> Term.constr) option =
- let subco () = subset_coerce env isevars x y in
- let dest_prod c =
- match Reductionops.decomp_n_prod env (evars_of !isevars) 1 c with
- | [(na,b,t)], c -> (na,t), c
- | _ -> raise NoSubtacCoercion
- in
- let rec coerce_application typ typ' c c' l l' =
- let len = Array.length l in
- let rec aux tele typ typ' i co =
- if i < len then
- let hdx = l.(i) and hdy = l'.(i) in
- try isevars := the_conv_x_leq env hdx hdy !isevars;
- let (n, eqT), restT = dest_prod typ in
- let (n', eqT'), restT' = dest_prod typ' in
- aux (hdx :: tele) (subst1 hdx restT) (subst1 hdy restT') (succ i) co
- with Reduction.NotConvertible ->
- let (n, eqT), restT = dest_prod typ in
- let (n', eqT'), restT' = dest_prod typ' in
- let _ =
- try isevars := the_conv_x_leq env eqT eqT' !isevars
- with Reduction.NotConvertible -> raise NoSubtacCoercion
- in
- (* Disallow equalities on arities *)
- if Reduction.is_arity env eqT then raise NoSubtacCoercion;
- let restargs = lift_args 1
- (List.rev (Array.to_list (Array.sub l (succ i) (len - (succ i)))))
- in
- let args = List.rev (restargs @ mkRel 1 :: lift_args 1 tele) in
- let pred = mkLambda (n, eqT, applistc (lift 1 c) args) in
- let eq = mkApp (Lazy.force eq_ind, [| eqT; hdx; hdy |]) in
- let evar = make_existential loc env isevars eq in
- let eq_app x = mkApp (Lazy.force eq_rect,
- [| eqT; hdx; pred; x; hdy; evar|]) in
- aux (hdy :: tele) (subst1 hdx restT) (subst1 hdy restT') (succ i) (fun x -> eq_app (co x))
- else Some co
- in
- if isEvar c || isEvar c' then
- (* Second-order unification needed. *)
- raise NoSubtacCoercion;
- aux [] typ typ' 0 (fun x -> x)
- in
- match (kind_of_term x, kind_of_term y) with
- | Sort s, Sort s' ->
- (match s, s' with
- Prop x, Prop y when x = y -> None
- | Prop _, Type _ -> None
- | Type x, Type y when x = y -> None (* false *)
- | _ -> subco ())
- | Prod (name, a, b), Prod (name', a', b') ->
- let name' = Name (Nameops.next_ident_away (id_of_string "x") (Termops.ids_of_context env)) in
- let env' = push_rel (name', None, a') env in
- let c1 = coerce_unify env' (lift 1 a') (lift 1 a) in
- (* env, x : a' |- c1 : lift 1 a' > lift 1 a *)
- let coec1 = app_opt c1 (mkRel 1) in
- (* env, x : a' |- c1[x] : lift 1 a *)
- let c2 = coerce_unify env' (subst1 coec1 (liftn 1 2 b)) b' in
- (* env, x : a' |- c2 : b[c1[x]/x]] > b' *)
- (match c1, c2 with
- None, None -> failwith "subtac.coerce': Should have detected equivalence earlier"
- | _, _ ->
- Some
- (fun f ->
- mkLambda (name', a',
- app_opt c2
- (mkApp (Term.lift 1 f, [| coec1 |])))))
-
- | App (c, l), App (c', l') ->
- (match kind_of_term c, kind_of_term c' with
- Ind i, Ind i' -> (* Inductive types *)
- let len = Array.length l in
- let existS = Lazy.force existS in
- let prod = Lazy.force prod in
- (* Sigma types *)
- if len = Array.length l' && len = 2 && i = i'
- && (i = Term.destInd existS.typ || i = Term.destInd prod.typ)
- then
- if i = Term.destInd existS.typ
- then
- begin
- let (a, pb), (a', pb') =
- pair_of_array l, pair_of_array l'
- in
- let c1 = coerce_unify env a a' in
- let rec remove_head a c =
- match kind_of_term c with
- | Lambda (n, t, t') -> c, t'
- (*| Prod (n, t, t') -> t'*)
- | Evar (k, args) ->
- let (evs, t) = Evarutil.define_evar_as_lambda !isevars (k,args) in
- isevars := evs;
- let (n, dom, rng) = destLambda t in
- let (domk, args) = destEvar dom in
- isevars := evar_define domk a !isevars;
- t, rng
- | _ -> raise NoSubtacCoercion
- in
- let (pb, b), (pb', b') = remove_head a pb, remove_head a' pb' in
- let env' = push_rel (make_name "x", None, a) env in
- let c2 = coerce_unify env' b b' in
- match c1, c2 with
- None, None ->
- None
- | _, _ ->
- Some
- (fun x ->
- let x, y =
- app_opt c1 (mkApp (existS.proj1,
- [| a; pb; x |])),
- app_opt c2 (mkApp (existS.proj2,
- [| a; pb; x |]))
- in
- mkApp (existS.intro, [| a'; pb'; x ; y |]))
- end
- else
- begin
- let (a, b), (a', b') =
- pair_of_array l, pair_of_array l'
- in
- let c1 = coerce_unify env a a' in
- let c2 = coerce_unify env b b' in
- match c1, c2 with
- None, None -> None
- | _, _ ->
- Some
- (fun x ->
- let x, y =
- app_opt c1 (mkApp (prod.proj1,
- [| a; b; x |])),
- app_opt c2 (mkApp (prod.proj2,
- [| a; b; x |]))
- in
- mkApp (prod.intro, [| a'; b'; x ; y |]))
- end
- else
- if i = i' && len = Array.length l' then
- let evm = evars_of !isevars in
- (try subco ()
- with NoSubtacCoercion ->
- let typ = Typing.type_of env evm c in
- let typ' = Typing.type_of env evm c' in
- (* if not (is_arity env evm typ) then *)
- coerce_application typ typ' c c' l l')
- (* else subco () *)
- else
- subco ()
- | x, y when x = y ->
- if Array.length l = Array.length l' then
- let evm = evars_of !isevars in
- let lam_type = Typing.type_of env evm c in
- let lam_type' = Typing.type_of env evm c' in
-(* if not (is_arity env evm lam_type) then ( *)
- coerce_application lam_type lam_type' c c' l l'
-(* ) else subco () *)
- else subco ()
- | _ -> subco ())
- | _, _ -> subco ()
-
- and subset_coerce env isevars x y =
- match disc_subset x with
- Some (u, p) ->
- let c = coerce_unify env u y in
- let f x =
- app_opt c (mkApp ((Lazy.force sig_).proj1,
- [| u; p; x |]))
- in Some f
- | None ->
- match disc_subset y with
- Some (u, p) ->
- let c = coerce_unify env x u in
- Some
- (fun x ->
- let cx = app_opt c x in
- let evar = make_existential loc env isevars (mkApp (p, [| cx |]))
- in
- (mkApp
- ((Lazy.force sig_).intro,
- [| u; p; cx; evar |])))
- | None ->
- raise NoSubtacCoercion
- (*isevars := Evd.add_conv_pb (Reduction.CONV, x, y) !isevars;
- None*)
- in coerce_unify env x y
-
- let coerce_itf loc env isevars v t c1 =
- let evars = ref isevars in
- let coercion = coerce loc env evars t c1 in
- !evars, Option.map (app_opt coercion) v
-
- (* Taken from pretyping/coercion.ml *)
-
- (* Typing operations dealing with coercions *)
-
- (* Here, funj is a coercion therefore already typed in global context *)
- let apply_coercion_args env argl funj =
- let rec apply_rec acc typ = function
- | [] -> { uj_val = applist (j_val funj,argl);
- uj_type = typ }
- | h::restl ->
- (* On devrait pouvoir s'arranger pour qu'on n'ait pas à faire hnf_constr *)
- match kind_of_term (whd_betadeltaiota env Evd.empty typ) with
- | Prod (_,c1,c2) ->
- (* Typage garanti par l'appel à app_coercion*)
- apply_rec (h::acc) (subst1 h c2) restl
- | _ -> anomaly "apply_coercion_args"
- in
- apply_rec [] funj.uj_type argl
-
- (* appliquer le chemin de coercions de patterns p *)
- exception NoCoercion
-
- let apply_pattern_coercion loc pat p =
- List.fold_left
- (fun pat (co,n) ->
- let f i = if i<n then Rawterm.PatVar (loc, Anonymous) else pat in
- Rawterm.PatCstr (loc, co, list_tabulate f (n+1), Anonymous))
- pat p
-
- (* raise Not_found if no coercion found *)
- let inh_pattern_coerce_to loc pat ind1 ind2 =
- let p = lookup_pattern_path_between (ind1,ind2) in
- apply_pattern_coercion loc pat p
-
- (* appliquer le chemin de coercions p à hj *)
-
- let apply_coercion env sigma p hj typ_cl =
- try
- fst (List.fold_left
- (fun (ja,typ_cl) i ->
- let fv,isid = coercion_value i in
- let argl = (class_args_of env sigma typ_cl)@[ja.uj_val] in
- let jres = apply_coercion_args env argl fv in
- (if isid then
- { uj_val = ja.uj_val; uj_type = jres.uj_type }
- else
- jres),
- jres.uj_type)
- (hj,typ_cl) p)
- with _ -> anomaly "apply_coercion"
-
- let inh_app_fun env isevars j =
- let t = whd_betadeltaiota env (evars_of isevars) j.uj_type in
- match kind_of_term t with
- | Prod (_,_,_) -> (isevars,j)
- | Evar ev when not (is_defined_evar isevars ev) ->
- let (isevars',t) = define_evar_as_product isevars ev in
- (isevars',{ uj_val = j.uj_val; uj_type = t })
- | _ ->
- (try
- let t,p =
- lookup_path_to_fun_from env (evars_of isevars) j.uj_type in
- (isevars,apply_coercion env (evars_of isevars) p j t)
- with Not_found ->
- try
- let coercef, t = mu env isevars t in
- (isevars, { uj_val = app_opt coercef j.uj_val; uj_type = t })
- with NoSubtacCoercion | NoCoercion ->
- (isevars,j))
-
- let inh_tosort_force loc env isevars j =
- try
- let t,p = lookup_path_to_sort_from env (evars_of isevars) j.uj_type in
- let j1 = apply_coercion env (evars_of isevars) p j t in
- (isevars,type_judgment env (j_nf_evar (evars_of isevars) j1))
- with Not_found ->
- error_not_a_type_loc loc env (evars_of isevars) j
-
- let inh_coerce_to_sort loc env isevars j =
- let typ = whd_betadeltaiota env (evars_of isevars) j.uj_type in
- match kind_of_term typ with
- | Sort s -> (isevars,{ utj_val = j.uj_val; utj_type = s })
- | Evar ev when not (is_defined_evar isevars ev) ->
- let (isevars',s) = define_evar_as_sort isevars ev in
- (isevars',{ utj_val = j.uj_val; utj_type = s })
- | _ ->
- inh_tosort_force loc env isevars j
-
- let inh_coerce_to_base loc env isevars j =
- let typ = whd_betadeltaiota env (evars_of isevars) j.uj_type in
- let ct, typ' = mu env isevars typ in
- isevars, { uj_val = app_opt ct j.uj_val;
- uj_type = typ' }
-
- let inh_coerce_to_prod loc env isevars t =
- let typ = whd_betadeltaiota env (evars_of isevars) (snd t) in
- let _, typ' = mu env isevars typ in
- isevars, (fst t, typ')
-
- let inh_coerce_to_fail env evd rigidonly v t c1 =
- if rigidonly & not (Heads.is_rigid env c1 && Heads.is_rigid env t)
- then
- raise NoCoercion
- else
- let v', t' =
- try
- let t2,t1,p = lookup_path_between env (evars_of evd) (t,c1) in
- match v with
- Some v ->
- let j = apply_coercion env (evars_of evd) p
- {uj_val = v; uj_type = t} t2 in
- Some j.uj_val, j.uj_type
- | None -> None, t
- with Not_found -> raise NoCoercion
- in
- try (the_conv_x_leq env t' c1 evd, v')
- with Reduction.NotConvertible -> raise NoCoercion
-
-
- let rec inh_conv_coerce_to_fail loc env evd rigidonly v t c1 =
- try (the_conv_x_leq env t c1 evd, v)
- with Reduction.NotConvertible ->
- try inh_coerce_to_fail env evd rigidonly v t c1
- with NoCoercion ->
- match
- kind_of_term (whd_betadeltaiota env (evars_of evd) t),
- kind_of_term (whd_betadeltaiota env (evars_of evd) c1)
- with
- | Prod (name,t1,t2), Prod (_,u1,u2) ->
- (* Conversion did not work, we may succeed with a coercion. *)
- (* We eta-expand (hence possibly modifying the original term!) *)
- (* and look for a coercion c:u1->t1 s.t. fun x:u1 => v' (c x)) *)
- (* has type forall (x:u1), u2 (with v' recursively obtained) *)
- let name = match name with
- | Anonymous -> Name (id_of_string "x")
- | _ -> name in
- let env1 = push_rel (name,None,u1) env in
- let (evd', v1) =
- inh_conv_coerce_to_fail loc env1 evd rigidonly
- (Some (mkRel 1)) (lift 1 u1) (lift 1 t1) in
- let v1 = Option.get v1 in
- let v2 = Option.map (fun v -> beta_applist (lift 1 v,[v1])) v in
- let t2 = Termops.subst_term v1 t2 in
- let (evd'',v2') = inh_conv_coerce_to_fail loc env1 evd' rigidonly v2 t2 u2 in
- (evd'', Option.map (fun v2' -> mkLambda (name, u1, v2')) v2')
- | _ -> raise NoCoercion
-
- (* Look for cj' obtained from cj by inserting coercions, s.t. cj'.typ = t *)
- let inh_conv_coerce_to_gen rigidonly loc env evd cj ((n, t) as _tycon) =
- let evd = nf_evar_defs evd in
- match n with
- None ->
- let (evd', val') =
- try
- inh_conv_coerce_to_fail loc env evd rigidonly
- (Some (nf_isevar evd cj.uj_val))
- (nf_isevar evd cj.uj_type) (nf_isevar evd t)
- with NoCoercion ->
- let sigma = evars_of evd in
- try
- coerce_itf loc env evd (Some cj.uj_val) cj.uj_type t
- with NoSubtacCoercion ->
- error_actual_type_loc loc env sigma cj t
- in
- let val' = match val' with Some v -> v | None -> assert(false) in
- (evd',{ uj_val = val'; uj_type = t })
- | Some (init, cur) ->
- (evd, cj)
-
- let inh_conv_coerce_to = inh_conv_coerce_to_gen false
- let inh_conv_coerce_rigid_to = inh_conv_coerce_to_gen true
-
- let inh_conv_coerces_to loc env isevars t ((abs, t') as _tycon) =
- let nabsinit, nabs =
- match abs with
- None -> 0, 0
- | Some (init, cur) -> init, cur
- in
- try
- let rels, rng = Reductionops.decomp_n_prod env (evars_of isevars) nabs t in
- (* The final range free variables must have been replaced by evars, we accept only that evars
- in rng are applied to free vars. *)
- if noccur_with_meta 1 (succ nabs) rng then (
- let env', t, t' =
- let env' = push_rel_context rels env in
- env', rng, lift nabs t'
- in
- try
- fst (try inh_conv_coerce_to_fail loc env' isevars false None t t'
- with NoCoercion ->
- coerce_itf loc env' isevars None t t')
- with NoSubtacCoercion ->
- let sigma = evars_of isevars in
- error_cannot_coerce env' sigma (t, t'))
- else isevars
- with _ -> isevars
-end
diff --git a/contrib/subtac/subtac_coercion.mli b/contrib/subtac/subtac_coercion.mli
deleted file mode 100644
index 5678c10e..00000000
--- a/contrib/subtac/subtac_coercion.mli
+++ /dev/null
@@ -1,4 +0,0 @@
-open Term
-val disc_subset : types -> (types * types) option
-
-module Coercion : Coercion.S
diff --git a/contrib/subtac/subtac_command.ml b/contrib/subtac/subtac_command.ml
deleted file mode 100644
index c8c7ff72..00000000
--- a/contrib/subtac/subtac_command.ml
+++ /dev/null
@@ -1,466 +0,0 @@
-open Closure
-open RedFlags
-open Declarations
-open Entries
-open Dyn
-open Libobject
-open Pattern
-open Matching
-open Pp
-open Rawterm
-open Sign
-open Tacred
-open Util
-open Names
-open Nameops
-open Libnames
-open Nametab
-open Pfedit
-open Proof_type
-open Refiner
-open Tacmach
-open Tactic_debug
-open Topconstr
-open Term
-open Termops
-open Tacexpr
-open Safe_typing
-open Typing
-open Hiddentac
-open Genarg
-open Decl_kinds
-open Mod_subst
-open Printer
-open Inductiveops
-open Syntax_def
-open Environ
-open Tactics
-open Tacticals
-open Tacinterp
-open Vernacexpr
-open Notation
-open Evd
-open Evarutil
-
-module SPretyping = Subtac_pretyping.Pretyping
-open Subtac_utils
-open Pretyping
-open Subtac_obligations
-
-(*********************************************************************)
-(* Functions to parse and interpret constructions *)
-
-let evar_nf isevars c =
- isevars := Evarutil.nf_evar_defs !isevars;
- Evarutil.nf_isevar !isevars c
-
-let interp_gen kind isevars env
- ?(impls=([],[])) ?(allow_patvar=false) ?(ltacvars=([],[]))
- c =
- let c' = Constrintern.intern_gen (kind=IsType) ~impls ~allow_patvar ~ltacvars (Evd.evars_of !isevars) env c in
- let c' = SPretyping.pretype_gen isevars env ([],[]) kind c' in
- evar_nf isevars c'
-
-let interp_constr isevars env c =
- interp_gen (OfType None) isevars env c
-
-let interp_type_evars isevars env ?(impls=([],[])) c =
- interp_gen IsType isevars env ~impls c
-
-let interp_casted_constr isevars env ?(impls=([],[])) c typ =
- interp_gen (OfType (Some typ)) isevars env ~impls c
-
-let interp_casted_constr_evars isevars env ?(impls=([],[])) c typ =
- interp_gen (OfType (Some typ)) isevars env ~impls c
-
-let interp_open_constr isevars env c =
- msgnl (str "Pretyping " ++ my_print_constr_expr c);
- let c = Constrintern.intern_constr (Evd.evars_of !isevars) env c in
- let c' = SPretyping.pretype_gen isevars env ([], []) (OfType None) c in
- evar_nf isevars c'
-
-let interp_constr_judgment isevars env c =
- let j =
- SPretyping.understand_judgment_tcc isevars env
- (Constrintern.intern_constr (Evd.evars_of !isevars) env c)
- in
- { uj_val = evar_nf isevars j.uj_val; uj_type = evar_nf isevars j.uj_type }
-
-let locate_if_isevar loc na = function
- | RHole _ ->
- (try match na with
- | Name id -> Reserve.find_reserved_type id
- | Anonymous -> raise Not_found
- with Not_found -> RHole (loc, Evd.BinderType na))
- | x -> x
-
-let interp_binder sigma env na t =
- let t = Constrintern.intern_gen true (Evd.evars_of !sigma) env t in
- SPretyping.pretype_gen sigma env ([], []) IsType (locate_if_isevar (loc_of_rawconstr t) na t)
-
-let interp_context_evars evdref env params =
- let bl = Constrintern.intern_context false (Evd.evars_of !evdref) env params in
- let (env, par, _, impls) =
- List.fold_left
- (fun (env,params,n,impls) (na, k, b, t) ->
- match b with
- None ->
- let t' = locate_if_isevar (loc_of_rawconstr t) na t in
- let t = SPretyping.understand_tcc_evars evdref env IsType t' in
- let d = (na,None,t) in
- let impls =
- if k = Implicit then
- let na = match na with Name n -> Some n | Anonymous -> None in
- (ExplByPos (n, na), (true, true)) :: impls
- else impls
- in
- (push_rel d env, d::params, succ n, impls)
- | Some b ->
- let c = SPretyping.understand_judgment_tcc evdref env b in
- let d = (na, Some c.uj_val, c.uj_type) in
- (push_rel d env,d::params, succ n, impls))
- (env,[],1,[]) (List.rev bl)
- in (env, par), impls
-
-(* try to find non recursive definitions *)
-
-let list_chop_hd i l = match list_chop i l with
- | (l1,x::l2) -> (l1,x,l2)
- | (x :: [], l2) -> ([], x, [])
- | _ -> assert(false)
-
-let collect_non_rec env =
- let rec searchrec lnonrec lnamerec ldefrec larrec nrec =
- try
- let i =
- list_try_find_i
- (fun i f ->
- if List.for_all (fun (_, def) -> not (occur_var env f def)) ldefrec
- then i else failwith "try_find_i")
- 0 lnamerec
- in
- let (lf1,f,lf2) = list_chop_hd i lnamerec in
- let (ldef1,def,ldef2) = list_chop_hd i ldefrec in
- let (lar1,ar,lar2) = list_chop_hd i larrec in
- let newlnv =
- try
- match list_chop i nrec with
- | (lnv1,_::lnv2) -> (lnv1@lnv2)
- | _ -> [] (* nrec=[] for cofixpoints *)
- with Failure "list_chop" -> []
- in
- searchrec ((f,def,ar)::lnonrec)
- (lf1@lf2) (ldef1@ldef2) (lar1@lar2) newlnv
- with Failure "try_find_i" ->
- (List.rev lnonrec,
- (Array.of_list lnamerec, Array.of_list ldefrec,
- Array.of_list larrec, Array.of_list nrec))
- in
- searchrec []
-
-let list_of_local_binders l =
- let rec aux acc = function
- Topconstr.LocalRawDef (n, c) :: tl -> aux ((n, Some c, None) :: acc) tl
- | Topconstr.LocalRawAssum (nl, k, c) :: tl ->
- aux (List.fold_left (fun acc n -> (n, None, Some c) :: acc) acc nl) tl
- | [] -> List.rev acc
- in aux [] l
-
-let lift_binders k n l =
- let rec aux n = function
- | (id, t, c) :: tl -> (id, Option.map (liftn k n) t, liftn k n c) :: aux (pred n) tl
- | [] -> []
- in aux n l
-
-let rec gen_rels = function
- 0 -> []
- | n -> mkRel n :: gen_rels (pred n)
-
-let split_args n rel = match list_chop ((List.length rel) - n) rel with
- (l1, x :: l2) -> l1, x, l2
- | _ -> assert(false)
-
-let build_wellfounded (recname, n, bl,arityc,body) r measure notation boxed =
- Coqlib.check_required_library ["Coq";"Program";"Wf"];
- let sigma = Evd.empty in
- let isevars = ref (Evd.create_evar_defs sigma) in
- let env = Global.env() in
- let pr c = my_print_constr env c in
- let prr = Printer.pr_rel_context env in
- let _prn = Printer.pr_named_context env in
- let _pr_rel env = Printer.pr_rel_context env in
-(* let _ = *)
-(* try debug 2 (str "In named context: " ++ prn (named_context env) ++ str "Rewriting fixpoint: " ++ Ppconstr.pr_id recname ++ *)
-(* Ppconstr.pr_binders bl ++ str " : " ++ *)
-(* Ppconstr.pr_constr_expr arityc ++ str " := " ++ spc () ++ *)
-(* Ppconstr.pr_constr_expr body) *)
-(* with _ -> () *)
- (* in *)
- let (env', binders_rel), impls = interp_context_evars isevars env bl in
- let after, ((argname, _, argtyp) as arg), before =
- let idx = list_index (Name (snd n)) (List.rev_map (fun (na, _, _) -> na) binders_rel) in
- split_args idx binders_rel in
- let before_length, after_length = List.length before, List.length after in
- let argid = match argname with Name n -> n | _ -> assert(false) in
- let liftafter = lift_binders 1 after_length after in
- let envwf = push_rel_context before env in
- let wf_rel, wf_rel_fun, measure_fn =
- let rconstr_body, rconstr =
- let app = mkAppC (r, [mkIdentC (id_of_name argname)]) in
- let env = push_rel_context [arg] envwf in
- let capp = interp_constr isevars env app in
- capp, mkLambda (argname, argtyp, capp)
- in
- trace (str"rconstr_body: " ++ pr rconstr_body);
- if measure then
- let lt_rel = constr_of_global (Lazy.force lt_ref) in
- let name s = Name (id_of_string s) in
- let wf_rel_fun lift x y = (* lift to before_env *)
- trace (str"lifter rconstr_body:" ++ pr (liftn lift 2 rconstr_body));
- mkApp (lt_rel, [| subst1 x (liftn lift 2 rconstr_body);
- subst1 y (liftn lift 2 rconstr_body) |])
- in
- let wf_rel =
- mkLambda (name "x", argtyp,
- mkLambda (name "y", lift 1 argtyp,
- wf_rel_fun 0 (mkRel 2) (mkRel 1)))
- in
- wf_rel, wf_rel_fun , Some rconstr
- else rconstr, (fun lift x y -> mkApp (rconstr, [|x; y|])), None
- in
- let wf_proof = mkApp (Lazy.force well_founded, [| argtyp ; wf_rel |])
- in
- let argid' = id_of_string (string_of_id argid ^ "'") in
- let wfarg len = (Name argid', None,
- mkSubset (Name argid') (lift len argtyp)
- (wf_rel_fun (succ len) (mkRel 1) (mkRel (len + 1))))
- in
- let top_bl = after @ (arg :: before) in
- let top_env = push_rel_context top_bl env in
- let top_arity = interp_type_evars isevars top_env arityc in
- let intern_bl = wfarg 1 :: arg :: before in
- let _intern_env = push_rel_context intern_bl env in
- let proj = (Lazy.force sig_).Coqlib.proj1 in
- let projection =
- mkApp (proj, [| argtyp ;
- (mkLambda (Name argid', argtyp,
- (wf_rel_fun 1 (mkRel 1) (mkRel 3)))) ;
- mkRel 1
- |])
- in
- let intern_arity = it_mkProd_or_LetIn top_arity after in
- (* Intern arity is in top_env = arg :: before *)
- let intern_arity = liftn 2 2 intern_arity in
-(* trace (str "After lifting arity: " ++ *)
-(* my_print_constr (push_rel (Name argid', None, lift 2 argtyp) intern_env) *)
-(* intern_arity); *)
- (* arity is now in something :: wfarg :: arg :: before
- where what refered to arg now refers to something *)
- let intern_arity = substl [projection] intern_arity in
- (* substitute the projection of wfarg for something *)
- let intern_before_env = push_rel_context before env in
- let intern_fun_arity_prod = it_mkProd_or_LetIn intern_arity [wfarg 1] in
- let intern_fun_binder = (Name recname, None, intern_fun_arity_prod) in
- let fun_bl = liftafter @ (intern_fun_binder :: [arg]) in
- let fun_env = push_rel_context fun_bl intern_before_env in
- let fun_arity = interp_type_evars isevars fun_env arityc in
- let intern_body = interp_casted_constr isevars fun_env body fun_arity in
- let intern_body_lam = it_mkLambda_or_LetIn intern_body fun_bl in
- let _ =
- try trace ((* str "Fun bl: " ++ prr fun_bl ++ spc () ++ *)
- str "Intern bl" ++ prr intern_bl ++ spc ())
-(* str "Top bl" ++ prr top_bl ++ spc () ++ *)
-(* str "Intern arity: " ++ pr intern_arity ++ *)
-(* str "Top arity: " ++ pr top_arity ++ spc () ++ *)
-(* str "Intern body " ++ pr intern_body_lam) *)
- with _ -> ()
- in
- let prop = mkLambda (Name argid, argtyp, it_mkProd_or_LetIn top_arity after) in
- (* Lift to get to constant arguments *)
- let lift_cst = List.length after + 1 in
- let fix_def =
- match measure_fn with
- None ->
- mkApp (constr_of_global (Lazy.force fix_sub_ref),
- [| argtyp ;
- wf_rel ;
- make_existential dummy_loc ~opaque:(Define false) env isevars wf_proof ;
- lift lift_cst prop ;
- lift lift_cst intern_body_lam |])
- | Some f ->
- mkApp (constr_of_global (Lazy.force fix_measure_sub_ref),
- [| lift lift_cst argtyp ;
- lift lift_cst f ;
- lift lift_cst prop ;
- lift lift_cst intern_body_lam |])
- in
- let def_appl = applist (fix_def, gen_rels (after_length + 1)) in
- let def = it_mkLambda_or_LetIn def_appl binders_rel in
- let typ = it_mkProd_or_LetIn top_arity binders_rel in
- let fullcoqc = Evarutil.nf_isevar !isevars def in
- let fullctyp = Evarutil.nf_isevar !isevars typ in
- let evm = evars_of_term (Evd.evars_of !isevars) Evd.empty fullctyp in
- let evm = evars_of_term (Evd.evars_of !isevars) evm fullcoqc in
- let evm = non_instanciated_map env isevars evm in
- let evars, evars_def, evars_typ = Eterm.eterm_obligations env recname !isevars evm 0 fullcoqc fullctyp in
- Subtac_obligations.add_definition recname evars_def evars_typ ~implicits:impls evars
-
-let nf_evar_context isevars ctx =
- List.map (fun (n, b, t) ->
- (n, Option.map (Evarutil.nf_isevar isevars) b, Evarutil.nf_isevar isevars t)) ctx
-
-let interp_fix_context evdref env fix =
- interp_context_evars evdref env fix.Command.fix_binders
-
-let interp_fix_ccl evdref (env,_) fix =
- interp_type_evars evdref env fix.Command.fix_type
-
-let interp_fix_body evdref env_rec impls (_,ctx) fix ccl =
- let env = push_rel_context ctx env_rec in
- let body = interp_casted_constr_evars evdref env ~impls fix.Command.fix_body ccl in
- it_mkLambda_or_LetIn body ctx
-
-let build_fix_type (_,ctx) ccl = it_mkProd_or_LetIn ccl ctx
-
-let prepare_recursive_declaration fixnames fixtypes fixdefs =
- let defs = List.map (subst_vars (List.rev fixnames)) fixdefs in
- let names = List.map (fun id -> Name id) fixnames in
- (Array.of_list names, Array.of_list fixtypes, Array.of_list defs)
-
-let rel_index n ctx =
- list_index0 (Name n) (List.rev_map pi1 (List.filter (fun x -> pi2 x = None) ctx))
-
-let rec unfold f b =
- match f b with
- | Some (x, b') -> x :: unfold f b'
- | None -> []
-
-let compute_possible_guardness_evidences (n,_) (_, fixctx) fixtype =
- match n with
- | Some (loc, n) -> [rel_index n fixctx]
- | None ->
- (* If recursive argument was not given by user, we try all args.
- An earlier approach was to look only for inductive arguments,
- but doing it properly involves delta-reduction, and it finally
- doesn't seem to worth the effort (except for huge mutual
- fixpoints ?) *)
- let len = List.length fixctx in
- unfold (function x when x = len -> None
- | n -> Some (n, succ n)) 0
-
-let push_named_context = List.fold_right push_named
-
-let check_evars env initial_sigma evd c =
- let sigma = evars_of evd in
- let c = nf_evar sigma c in
- let rec proc_rec c =
- match kind_of_term c with
- | Evar (evk,args) ->
- assert (Evd.mem sigma evk);
- if not (Evd.mem initial_sigma evk) then
- let (loc,k) = evar_source evk evd in
- (match k with
- | QuestionMark _ -> ()
- | _ ->
- let evi = nf_evar_info sigma (Evd.find sigma evk) in
- Pretype_errors.error_unsolvable_implicit loc env sigma evi k None)
- | _ -> iter_constr proc_rec c
- in proc_rec c
-
-let interp_recursive fixkind l boxed =
- let env = Global.env() in
- let fixl, ntnl = List.split l in
- let kind = if fixkind <> Command.IsCoFixpoint then Fixpoint else CoFixpoint in
- let fixnames = List.map (fun fix -> fix.Command.fix_name) fixl in
-
- (* Interp arities allowing for unresolved types *)
- let evdref = ref (Evd.create_evar_defs Evd.empty) in
- let fixctxs, fiximps = List.split (List.map (interp_fix_context evdref env) fixl) in
- let fixccls = List.map2 (interp_fix_ccl evdref) fixctxs fixl in
- let fixtypes = List.map2 build_fix_type fixctxs fixccls in
- let rec_sign =
- List.fold_left2 (fun env id t -> (id,None,t) :: env)
- [] fixnames fixtypes
- in
- let env_rec = push_named_context rec_sign env in
-
- (* Get interpretation metadatas *)
- let impls = Command.compute_interning_datas env Constrintern.Recursive [] fixnames fixtypes fiximps in
- let notations = List.fold_right Option.List.cons ntnl [] in
-
- (* Interp bodies with rollback because temp use of notations/implicit *)
- let fixdefs =
- States.with_state_protection (fun () ->
- List.iter (Command.declare_interning_data impls) notations;
- list_map3 (interp_fix_body evdref env_rec impls) fixctxs fixl fixccls)
- () in
-
- (* Instantiate evars and check all are resolved *)
- let evd,_ = Evarconv.consider_remaining_unif_problems env_rec !evdref in
- let fixdefs = List.map (nf_evar (evars_of evd)) fixdefs in
- let fixtypes = List.map (nf_evar (evars_of evd)) fixtypes in
- let rec_sign = nf_named_context_evar (evars_of evd) rec_sign in
-
- let recdefs = List.length rec_sign in
- List.iter (check_evars env_rec Evd.empty evd) fixdefs;
- List.iter (check_evars env Evd.empty evd) fixtypes;
- Command.check_mutuality env kind (List.combine fixnames fixdefs);
-
- (* Russell-specific code *)
-
- (* Get the interesting evars, those that were not instanciated *)
- let isevars = Evd.undefined_evars evd in
- let evm = Evd.evars_of isevars in
- (* Solve remaining evars *)
- let rec collect_evars id def typ imps =
- (* Generalize by the recursive prototypes *)
- let def =
- Termops.it_mkNamedLambda_or_LetIn def rec_sign
- and typ =
- Termops.it_mkNamedProd_or_LetIn typ rec_sign
- in
- let evm' = Subtac_utils.evars_of_term evm Evd.empty def in
- let evm' = Subtac_utils.evars_of_term evm evm' typ in
- let evars, def, typ = Eterm.eterm_obligations env id isevars evm' recdefs def typ in
- (id, def, typ, imps, evars)
- in
- let defs = list_map4 collect_evars fixnames fixdefs fixtypes fiximps in
- (match fixkind with
- | Command.IsFixpoint wfl ->
- let possible_indexes =
- list_map3 compute_possible_guardness_evidences wfl fixctxs fixtypes in
- let fixdecls = Array.of_list (List.map (fun x -> Name x) fixnames),
- Array.of_list fixtypes,
- Array.of_list (List.map (subst_vars (List.rev fixnames)) fixdefs)
- in
- let indexes = Pretyping.search_guard dummy_loc (Global.env ()) possible_indexes fixdecls in
- list_iter_i (fun i _ -> Inductive.check_fix env ((indexes,i),fixdecls)) l
- | Command.IsCoFixpoint -> ());
- Subtac_obligations.add_mutual_definitions defs notations fixkind
-
-let out_n = function
- Some n -> n
- | None -> raise Not_found
-
-let build_recursive l b =
- let g = List.map (fun ((_,wf,_,_,_),_) -> wf) l in
- match g, l with
- [(n, CWfRec r)], [(((_,id),_,bl,typ,def),ntn)] ->
- ignore(build_wellfounded (id, out_n n, bl, typ, def) r false ntn false)
-
- | [(n, CMeasureRec r)], [(((_,id),_,bl,typ,def),ntn)] ->
- ignore(build_wellfounded (id, out_n n, bl, typ, def) r true ntn false)
-
- | _, _ when List.for_all (fun (n, ro) -> ro = CStructRec) g ->
- let fixl = List.map (fun (((_,id),_,bl,typ,def),ntn) ->
- ({Command.fix_name = id; Command.fix_binders = bl; Command.fix_body = def; Command.fix_type = typ},ntn)) l
- in interp_recursive (Command.IsFixpoint g) fixl b
- | _, _ ->
- errorlabstrm "Subtac_command.build_recursive"
- (str "Well-founded fixpoints not allowed in mutually recursive blocks")
-
-let build_corecursive l b =
- let fixl = List.map (fun (((_,id),bl,typ,def),ntn) ->
- ({Command.fix_name = id; Command.fix_binders = bl; Command.fix_body = def; Command.fix_type = typ},ntn))
- l in
- interp_recursive Command.IsCoFixpoint fixl b
diff --git a/contrib/subtac/subtac_command.mli b/contrib/subtac/subtac_command.mli
deleted file mode 100644
index 3a6a351b..00000000
--- a/contrib/subtac/subtac_command.mli
+++ /dev/null
@@ -1,50 +0,0 @@
-open Pretyping
-open Evd
-open Environ
-open Term
-open Topconstr
-open Names
-open Libnames
-open Pp
-open Vernacexpr
-open Constrintern
-
-val interp_gen :
- typing_constraint ->
- evar_defs ref ->
- env ->
- ?impls:full_implicits_env ->
- ?allow_patvar:bool ->
- ?ltacvars:ltac_sign ->
- constr_expr -> constr
-val interp_constr :
- evar_defs ref ->
- env -> constr_expr -> constr
-val interp_type_evars :
- evar_defs ref ->
- env ->
- ?impls:full_implicits_env ->
- constr_expr -> constr
-val interp_casted_constr_evars :
- evar_defs ref ->
- env ->
- ?impls:full_implicits_env ->
- constr_expr -> types -> constr
-val interp_open_constr :
- evar_defs ref -> env -> constr_expr -> constr
-val interp_constr_judgment :
- evar_defs ref ->
- env ->
- constr_expr -> unsafe_judgment
-val list_chop_hd : int -> 'a list -> 'a list * 'a * 'a list
-
-val interp_binder : Evd.evar_defs ref ->
- Environ.env -> Names.name -> Topconstr.constr_expr -> Term.constr
-
-
-
-val build_recursive :
- (fixpoint_expr * decl_notation) list -> bool -> unit
-
-val build_corecursive :
- (cofixpoint_expr * decl_notation) list -> bool -> unit
diff --git a/contrib/subtac/subtac_errors.ml b/contrib/subtac/subtac_errors.ml
deleted file mode 100644
index 3bbfe22b..00000000
--- a/contrib/subtac/subtac_errors.ml
+++ /dev/null
@@ -1,24 +0,0 @@
-open Util
-open Pp
-open Printer
-
-type term_pp = Pp.std_ppcmds
-
-type subtyping_error =
- | UncoercibleInferType of loc * term_pp * term_pp
- | UncoercibleInferTerm of loc * term_pp * term_pp * term_pp * term_pp
- | UncoercibleRewrite of term_pp * term_pp
-
-type typing_error =
- | NonFunctionalApp of loc * term_pp * term_pp * term_pp
- | NonConvertible of loc * term_pp * term_pp
- | NonSigma of loc * term_pp
- | IllSorted of loc * term_pp
-
-exception Subtyping_error of subtyping_error
-exception Typing_error of typing_error
-
-exception Debug_msg of string
-
-let typing_error e = raise (Typing_error e)
-let subtyping_error e = raise (Subtyping_error e)
diff --git a/contrib/subtac/subtac_errors.mli b/contrib/subtac/subtac_errors.mli
deleted file mode 100644
index 8d75b9c0..00000000
--- a/contrib/subtac/subtac_errors.mli
+++ /dev/null
@@ -1,15 +0,0 @@
-type term_pp = Pp.std_ppcmds
-type subtyping_error =
- UncoercibleInferType of Util.loc * term_pp * term_pp
- | UncoercibleInferTerm of Util.loc * term_pp * term_pp * term_pp * term_pp
- | UncoercibleRewrite of term_pp * term_pp
-type typing_error =
- NonFunctionalApp of Util.loc * term_pp * term_pp * term_pp
- | NonConvertible of Util.loc * term_pp * term_pp
- | NonSigma of Util.loc * term_pp
- | IllSorted of Util.loc * term_pp
-exception Subtyping_error of subtyping_error
-exception Typing_error of typing_error
-exception Debug_msg of string
-val typing_error : typing_error -> 'a
-val subtyping_error : subtyping_error -> 'a
diff --git a/contrib/subtac/subtac_obligations.ml b/contrib/subtac/subtac_obligations.ml
deleted file mode 100644
index 3dcd43d2..00000000
--- a/contrib/subtac/subtac_obligations.ml
+++ /dev/null
@@ -1,596 +0,0 @@
-(* -*- compile-command: "make -C ../.. bin/coqtop.byte" -*- *)
-open Printf
-open Pp
-open Subtac_utils
-open Command
-open Environ
-
-open Term
-open Names
-open Libnames
-open Summary
-open Libobject
-open Entries
-open Decl_kinds
-open Util
-open Evd
-open Declare
-open Proof_type
-
-let ppwarn cmd = Pp.warn (str"Program:" ++ cmd)
-let pperror cmd = Util.errorlabstrm "Program" cmd
-let error s = pperror (str s)
-
-exception NoObligations of identifier option
-
-let explain_no_obligations = function
- Some ident -> str "No obligations for program " ++ str (string_of_id ident)
- | None -> str "No obligations remaining"
-
-type obligation_info = (Names.identifier * Term.types * loc * obligation_definition_status * Intset.t
- * Tacexpr.raw_tactic_expr option) array
-
-type obligation =
- { obl_name : identifier;
- obl_type : types;
- obl_location : loc;
- obl_body : constr option;
- obl_status : obligation_definition_status;
- obl_deps : Intset.t;
- obl_tac : Tacexpr.raw_tactic_expr option;
- }
-
-type obligations = (obligation array * int)
-
-type notations = (string * Topconstr.constr_expr * Topconstr.scope_name option) list
-
-type program_info = {
- prg_name: identifier;
- prg_body: constr;
- prg_type: constr;
- prg_obligations: obligations;
- prg_deps : identifier list;
- prg_fixkind : Command.fixpoint_kind option ;
- prg_implicits : (Topconstr.explicitation * (bool * bool)) list;
- prg_notations : notations ;
- prg_kind : definition_kind;
- prg_hook : Tacexpr.declaration_hook;
-}
-
-let assumption_message id =
- Flags.if_verbose message ((string_of_id id) ^ " is assumed")
-
-let default_tactic : Proof_type.tactic ref = ref Refiner.tclIDTAC
-let default_tactic_expr : Tacexpr.glob_tactic_expr ref = ref (Tacexpr.TacId [])
-
-let set_default_tactic t = default_tactic_expr := t; default_tactic := Tacinterp.eval_tactic t
-
-(* true = All transparent, false = Opaque if possible *)
-let proofs_transparency = ref true
-
-let set_proofs_transparency = (:=) proofs_transparency
-let get_proofs_transparency () = !proofs_transparency
-
-open Goptions
-
-let _ =
- declare_bool_option
- { optsync = true;
- optname = "transparency of Program obligations";
- optkey = (SecondaryTable ("Transparent","Obligations"));
- optread = get_proofs_transparency;
- optwrite = set_proofs_transparency; }
-
-let evar_of_obligation o = make_evar (Global.named_context_val ()) o.obl_type
-
-let get_obligation_body expand obl =
- let c = Option.get obl.obl_body in
- if expand && obl.obl_status = Expand then
- match kind_of_term c with
- | Const c -> constant_value (Global.env ()) c
- | _ -> c
- else c
-
-let subst_deps expand obls deps t =
- let subst =
- Intset.fold
- (fun x acc ->
- let xobl = obls.(x) in
- let oblb =
- try get_obligation_body expand xobl
- with _ -> assert(false)
- in (xobl.obl_name, oblb) :: acc)
- deps []
- in(* Termops.it_mkNamedProd_or_LetIn t subst *)
- Term.replace_vars subst t
-
-let subst_deps_obl obls obl =
- let t' = subst_deps false obls obl.obl_deps obl.obl_type in
- { obl with obl_type = t' }
-
-module ProgMap = Map.Make(struct type t = identifier let compare = compare end)
-
-let map_replace k v m = ProgMap.add k v (ProgMap.remove k m)
-
-let map_cardinal m =
- let i = ref 0 in
- ProgMap.iter (fun _ _ -> incr i) m;
- !i
-
-exception Found of program_info
-
-let map_first m =
- try
- ProgMap.iter (fun _ v -> raise (Found v)) m;
- assert(false)
- with Found x -> x
-
-let from_prg : program_info ProgMap.t ref = ref ProgMap.empty
-
-let freeze () = !from_prg, !default_tactic_expr
-let unfreeze (v, t) = from_prg := v; set_default_tactic t
-let init () =
- from_prg := ProgMap.empty; set_default_tactic (Subtac_utils.tactics_call "obligation_tactic" [])
-
-let _ =
- Summary.declare_summary "program-tcc-table"
- { Summary.freeze_function = freeze;
- Summary.unfreeze_function = unfreeze;
- Summary.init_function = init;
- Summary.survive_module = false;
- Summary.survive_section = false }
-
-let progmap_union = ProgMap.fold ProgMap.add
-
-let cache (_, (infos, tac)) =
- from_prg := infos;
- set_default_tactic tac
-
-let (input,output) =
- declare_object
- { (default_object "Program state") with
- cache_function = cache;
- load_function = (fun _ -> cache);
- open_function = (fun _ -> cache);
- classify_function = (fun _ -> Dispose);
- export_function = (fun x -> Some x) }
-
-open Evd
-
-let rec intset_to = function
- -1 -> Intset.empty
- | n -> Intset.add n (intset_to (pred n))
-
-let subst_body expand prg =
- let obls, _ = prg.prg_obligations in
- let ints = intset_to (pred (Array.length obls)) in
- subst_deps expand obls ints prg.prg_body,
- subst_deps expand obls ints (Termops.refresh_universes prg.prg_type)
-
-let declare_definition prg =
- let body, typ = subst_body false prg in
- (try trace (str "Declaring: " ++ Ppconstr.pr_id prg.prg_name ++ spc () ++
- my_print_constr (Global.env()) body ++ str " : " ++
- my_print_constr (Global.env()) prg.prg_type);
- with _ -> ());
- let (local, boxed, kind) = prg.prg_kind in
- let ce =
- { const_entry_body = body;
- const_entry_type = Some typ;
- const_entry_opaque = false;
- const_entry_boxed = boxed}
- in
- (Command.get_declare_definition_hook ()) ce;
- match local with
- | Local when Lib.sections_are_opened () ->
- let c =
- SectionLocalDef(ce.const_entry_body,ce.const_entry_type,false) in
- let _ = declare_variable prg.prg_name (Lib.cwd(),c,IsDefinition kind) in
- print_message (Subtac_utils.definition_message prg.prg_name);
- if Pfedit.refining () then
- Flags.if_verbose msg_warning
- (str"Local definition " ++ Nameops.pr_id prg.prg_name ++
- str" is not visible from current goals");
- VarRef prg.prg_name
- | (Global|Local) ->
- let c =
- Declare.declare_constant
- prg.prg_name (DefinitionEntry ce,IsDefinition (pi3 prg.prg_kind))
- in
- let gr = ConstRef c in
- if Impargs.is_implicit_args () || prg.prg_implicits <> [] then
- Impargs.declare_manual_implicits false gr prg.prg_implicits;
- print_message (Subtac_utils.definition_message prg.prg_name);
- prg.prg_hook local gr;
- gr
-
-open Pp
-open Ppconstr
-
-let rec lam_index n t acc =
- match kind_of_term t with
- | Lambda (na, _, b) ->
- if na = Name n then acc
- else lam_index n b (succ acc)
- | _ -> raise Not_found
-
-let compute_possible_guardness_evidences (n,_) fixbody fixtype =
- match n with
- | Some (loc, n) -> [lam_index n fixbody 0]
- | None ->
- (* If recursive argument was not given by user, we try all args.
- An earlier approach was to look only for inductive arguments,
- but doing it properly involves delta-reduction, and it finally
- doesn't seem to worth the effort (except for huge mutual
- fixpoints ?) *)
- let m = Term.nb_prod fixtype in
- let ctx = fst (Sign.decompose_prod_n_assum m fixtype) in
- list_map_i (fun i _ -> i) 0 ctx
-
-let reduce_fix =
- Reductionops.clos_norm_flags Closure.betaiotazeta (Global.env ()) Evd.empty
-
-let declare_mutual_definition l =
- let len = List.length l in
- let first = List.hd l in
- let fixdefs, fixtypes, fiximps =
- list_split3
- (List.map (fun x ->
- let subs, typ = (subst_body false x) in
- snd (decompose_lam_n len subs), snd (decompose_prod_n len typ), x.prg_implicits) l)
- in
-(* let fixdefs = List.map reduce_fix fixdefs in *)
- let fixkind = Option.get first.prg_fixkind in
- let arrrec, recvec = Array.of_list fixtypes, Array.of_list fixdefs in
- let fixdecls = (Array.of_list (List.map (fun x -> Name x.prg_name) l), arrrec, recvec) in
- let (local,boxed,kind) = first.prg_kind in
- let fixnames = first.prg_deps in
- let kind = if fixkind <> IsCoFixpoint then Fixpoint else CoFixpoint in
- let indexes, fixdecls =
- match fixkind with
- | IsFixpoint wfl ->
- let possible_indexes =
- list_map3 compute_possible_guardness_evidences wfl fixdefs fixtypes in
- let indexes = Pretyping.search_guard dummy_loc (Global.env ()) possible_indexes fixdecls in
- Some indexes, list_map_i (fun i _ -> mkFix ((indexes,i),fixdecls)) 0 l
- | IsCoFixpoint ->
- None, list_map_i (fun i _ -> mkCoFix (i,fixdecls)) 0 l
- in
- (* Declare the recursive definitions *)
- let kns = list_map4 (declare_fix boxed kind) fixnames fixdecls fixtypes fiximps in
- (* Declare notations *)
- List.iter (Command.declare_interning_data ([],[])) first.prg_notations;
- Flags.if_verbose ppnl (Command.recursive_message kind indexes fixnames);
- let gr = List.hd kns in
- let kn = match gr with ConstRef kn -> kn | _ -> assert false in
- first.prg_hook local gr; kn
-
-let declare_obligation obl body =
- match obl.obl_status with
- | Expand -> { obl with obl_body = Some body }
- | Define opaque ->
- let ce =
- { const_entry_body = body;
- const_entry_type = Some obl.obl_type;
- const_entry_opaque =
- (if get_proofs_transparency () then false
- else opaque) ;
- const_entry_boxed = false}
- in
- let constant = Declare.declare_constant obl.obl_name
- (DefinitionEntry ce,IsProof Property)
- in
- print_message (Subtac_utils.definition_message obl.obl_name);
- { obl with obl_body = Some (mkConst constant) }
-
-let red = Reductionops.nf_betaiota Evd.empty
-
-let init_prog_info n b t deps fixkind notations obls impls kind hook =
- let obls' =
- Array.mapi
- (fun i (n, t, l, o, d, tac) ->
- debug 2 (str "Adding obligation " ++ int i ++ str " with deps : " ++ str (string_of_intset d));
- { obl_name = n ; obl_body = None;
- obl_location = l; obl_type = red t; obl_status = o;
- obl_deps = d; obl_tac = tac })
- obls
- in
- { prg_name = n ; prg_body = b; prg_type = red t; prg_obligations = (obls', Array.length obls');
- prg_deps = deps; prg_fixkind = fixkind ; prg_notations = notations ;
- prg_implicits = impls; prg_kind = kind; prg_hook = hook; }
-
-let get_prog name =
- let prg_infos = !from_prg in
- match name with
- Some n ->
- (try ProgMap.find n prg_infos
- with Not_found -> raise (NoObligations (Some n)))
- | None ->
- (let n = map_cardinal prg_infos in
- match n with
- 0 -> raise (NoObligations None)
- | 1 -> map_first prg_infos
- | _ -> error "More than one program with unsolved obligations")
-
-let get_prog_err n =
- try get_prog n with NoObligations id -> pperror (explain_no_obligations id)
-
-let obligations_solved prg = (snd prg.prg_obligations) = 0
-
-let update_state s =
-(* msgnl (str "Updating obligations info"); *)
- Lib.add_anonymous_leaf (input s)
-
-type progress =
- | Remain of int
- | Dependent
- | Defined of global_reference
-
-let obligations_message rem =
- if rem > 0 then
- if rem = 1 then
- Flags.if_verbose msgnl (int rem ++ str " obligation remaining")
- else
- Flags.if_verbose msgnl (int rem ++ str " obligations remaining")
- else
- Flags.if_verbose msgnl (str "No more obligations remaining")
-
-let update_obls prg obls rem =
- let prg' = { prg with prg_obligations = (obls, rem) } in
- from_prg := map_replace prg.prg_name prg' !from_prg;
- obligations_message rem;
- let res =
- if rem > 0 then Remain rem
- else (
- match prg'.prg_deps with
- [] ->
- let kn = declare_definition prg' in
- from_prg := ProgMap.remove prg.prg_name !from_prg;
- Defined kn
- | l ->
- let progs = List.map (fun x -> ProgMap.find x !from_prg) prg'.prg_deps in
- if List.for_all (fun x -> obligations_solved x) progs then
- (let kn = declare_mutual_definition progs in
- from_prg := List.fold_left
- (fun acc x ->
- ProgMap.remove x.prg_name acc) !from_prg progs;
- Defined (ConstRef kn))
- else Dependent);
- in
- update_state (!from_prg, !default_tactic_expr);
- res
-
-let is_defined obls x = obls.(x).obl_body <> None
-
-let deps_remaining obls deps =
- Intset.fold
- (fun x acc ->
- if is_defined obls x then acc
- else x :: acc)
- deps []
-
-let has_dependencies obls n =
- let res = ref false in
- Array.iteri
- (fun i obl ->
- if i <> n && Intset.mem n obl.obl_deps then
- res := true)
- obls;
- !res
-
-let kind_of_opacity o =
- match o with
- | Define false | Expand -> Subtac_utils.goal_kind
- | _ -> Subtac_utils.goal_proof_kind
-
-let not_transp_msg =
- str "Obligation should be transparent but was declared opaque." ++ spc () ++
- str"Use 'Defined' instead."
-
-let warn_not_transp () = ppwarn not_transp_msg
-let error_not_transp () = pperror not_transp_msg
-
-let rec solve_obligation prg num =
- let user_num = succ num in
- let obls, rem = prg.prg_obligations in
- let obl = obls.(num) in
- if obl.obl_body <> None then
- pperror (str "Obligation" ++ spc () ++ int user_num ++ str "already" ++ spc() ++ str "solved.")
- else
- match deps_remaining obls obl.obl_deps with
- | [] ->
- let obl = subst_deps_obl obls obl in
- Command.start_proof obl.obl_name (kind_of_opacity obl.obl_status) obl.obl_type
- (fun strength gr ->
- let cst = match gr with ConstRef cst -> cst | _ -> assert false in
- let obl =
- let transparent = evaluable_constant cst (Global.env ()) in
- let body =
- match obl.obl_status with
- | Expand ->
- if not transparent then error_not_transp ()
- else constant_value (Global.env ()) cst
- | Define opaque ->
- if not opaque && not transparent then error_not_transp ()
- else Libnames.constr_of_global gr
- in { obl with obl_body = Some body }
- in
- let obls = Array.copy obls in
- let _ = obls.(num) <- obl in
- match update_obls prg obls (pred rem) with
- | Remain n when n > 0 ->
- if has_dependencies obls num then
- ignore(auto_solve_obligations (Some prg.prg_name) None)
- | _ -> ());
- trace (str "Started obligation " ++ int user_num ++ str " proof: " ++
- Subtac_utils.my_print_constr (Global.env ()) obl.obl_type);
- Pfedit.by !default_tactic;
- Flags.if_verbose (fun () -> msg (Printer.pr_open_subgoals ())) ()
- | l -> pperror (str "Obligation " ++ int user_num ++ str " depends on obligation(s) "
- ++ str (string_of_list ", " (fun x -> string_of_int (succ x)) l))
-
-and subtac_obligation (user_num, name, typ) =
- let num = pred user_num in
- let prg = get_prog_err name in
- let obls, rem = prg.prg_obligations in
- if num < Array.length obls then
- let obl = obls.(num) in
- match obl.obl_body with
- None -> solve_obligation prg num
- | Some r -> error "Obligation already solved"
- else error (sprintf "Unknown obligation number %i" (succ num))
-
-
-and solve_obligation_by_tac prg obls i tac =
- let obl = obls.(i) in
- match obl.obl_body with
- Some _ -> false
- | None ->
- (try
- if deps_remaining obls obl.obl_deps = [] then
- let obl = subst_deps_obl obls obl in
- let tac =
- match tac with
- | Some t -> t
- | None ->
- match obl.obl_tac with
- | Some t -> Tacinterp.interp t
- | None -> !default_tactic
- in
- let t = Subtac_utils.solve_by_tac (evar_of_obligation obl) tac in
- obls.(i) <- declare_obligation obl t;
- true
- else false
- with
- | Stdpp.Exc_located(_, Proof_type.LtacLocated (_, Refiner.FailError (_, s)))
- | Stdpp.Exc_located(_, Refiner.FailError (_, s))
- | Refiner.FailError (_, s) ->
- user_err_loc (obl.obl_location, "solve_obligation", s)
- | e -> false)
-
-and solve_prg_obligations prg tac =
- let obls, rem = prg.prg_obligations in
- let rem = ref rem in
- let obls' = Array.copy obls in
- let _ =
- Array.iteri (fun i x ->
- if solve_obligation_by_tac prg obls' i tac then
- decr rem)
- obls'
- in
- update_obls prg obls' !rem
-
-and solve_obligations n tac =
- let prg = get_prog_err n in
- solve_prg_obligations prg tac
-
-and solve_all_obligations tac =
- ProgMap.iter (fun k v -> ignore(solve_prg_obligations v tac)) !from_prg
-
-and try_solve_obligation n prg tac =
- let prg = get_prog prg in
- let obls, rem = prg.prg_obligations in
- let obls' = Array.copy obls in
- if solve_obligation_by_tac prg obls' n tac then
- ignore(update_obls prg obls' (pred rem));
-
-and try_solve_obligations n tac =
- try ignore (solve_obligations n tac) with NoObligations _ -> ()
-
-and auto_solve_obligations n tac : progress =
- Flags.if_verbose msgnl (str "Solving obligations automatically...");
- try solve_prg_obligations (get_prog_err n) tac with NoObligations _ -> Dependent
-
-open Pp
-let show_obligations ?(msg=true) n =
- let prg = get_prog_err n in
- let n = prg.prg_name in
- let obls, rem = prg.prg_obligations in
- let showed = ref 5 in
- if msg then msgnl (int rem ++ str " obligation(s) remaining: ");
- Array.iteri (fun i x ->
- match x.obl_body with
- | None ->
- if !showed > 0 then (
- decr showed;
- msgnl (str "Obligation" ++ spc() ++ int (succ i) ++ spc () ++
- str "of" ++ spc() ++ str (string_of_id n) ++ str ":" ++ spc () ++
- hov 1 (my_print_constr (Global.env ()) x.obl_type ++ str "." ++ fnl ())))
- | Some _ -> ())
- obls
-
-let show_term n =
- let prg = get_prog_err n in
- let n = prg.prg_name in
- msgnl (str (string_of_id n) ++ spc () ++ str":" ++ spc () ++
- my_print_constr (Global.env ()) prg.prg_type ++ spc () ++ str ":=" ++ fnl ()
- ++ my_print_constr (Global.env ()) prg.prg_body)
-
-let add_definition n b t ?(implicits=[]) ?(kind=Global,false,Definition) ?tactic ?(hook=fun _ _ -> ()) obls =
- Flags.if_verbose pp (str (string_of_id n) ++ str " has type-checked");
- let prg = init_prog_info n b t [] None [] obls implicits kind hook in
- let obls,_ = prg.prg_obligations in
- if Array.length obls = 0 then (
- Flags.if_verbose ppnl (str ".");
- let cst = declare_definition prg in
- from_prg := ProgMap.remove prg.prg_name !from_prg;
- Defined cst)
- else (
- let len = Array.length obls in
- let _ = Flags.if_verbose ppnl (str ", generating " ++ int len ++ str " obligation(s)") in
- from_prg := ProgMap.add n prg !from_prg;
- let res = auto_solve_obligations (Some n) tactic in
- match res with
- | Remain rem -> Flags.if_verbose (fun () -> show_obligations ~msg:false (Some n)) (); res
- | _ -> res)
-
-let add_mutual_definitions l ?tactic ?(kind=Global,false,Definition) ?(hook=fun _ _ -> ()) notations fixkind =
- let deps = List.map (fun (n, b, t, imps, obls) -> n) l in
- let upd = List.fold_left
- (fun acc (n, b, t, imps, obls) ->
- let prg = init_prog_info n b t deps (Some fixkind) notations obls imps kind hook in
- ProgMap.add n prg acc)
- !from_prg l
- in
- from_prg := upd;
- let _defined =
- List.fold_left (fun finished x ->
- if finished then finished
- else
- let res = auto_solve_obligations (Some x) tactic in
- match res with
- | Defined _ -> (* If one definition is turned into a constant, the whole block is defined. *) true
- | _ -> false)
- false deps
- in ()
-
-let admit_obligations n =
- let prg = get_prog_err n in
- let obls, rem = prg.prg_obligations in
- Array.iteri (fun i x ->
- match x.obl_body with
- None ->
- let x = subst_deps_obl obls x in
- let kn = Declare.declare_constant x.obl_name (ParameterEntry (x.obl_type,false), IsAssumption Conjectural) in
- assumption_message x.obl_name;
- obls.(i) <- { x with obl_body = Some (mkConst kn) }
- | Some _ -> ())
- obls;
- ignore(update_obls prg obls 0)
-
-exception Found of int
-
-let array_find f arr =
- try Array.iteri (fun i x -> if f x then raise (Found i)) arr;
- raise Not_found
- with Found i -> i
-
-let next_obligation n =
- let prg = get_prog_err n in
- let obls, rem = prg.prg_obligations in
- let i =
- try array_find (fun x -> x.obl_body = None && deps_remaining obls x.obl_deps = []) obls
- with Not_found -> anomaly "Could not find a solvable obligation."
- in solve_obligation prg i
-
-let default_tactic () = !default_tactic
diff --git a/contrib/subtac/subtac_obligations.mli b/contrib/subtac/subtac_obligations.mli
deleted file mode 100644
index 766af2fa..00000000
--- a/contrib/subtac/subtac_obligations.mli
+++ /dev/null
@@ -1,63 +0,0 @@
-open Names
-open Util
-open Libnames
-open Evd
-open Proof_type
-
-type obligation_info =
- (identifier * Term.types * loc *
- obligation_definition_status * Intset.t * Tacexpr.raw_tactic_expr option) array
- (* ident, type, location, (opaque or transparent, expand or define),
- dependencies, tactic to solve it *)
-
-type progress = (* Resolution status of a program *)
- | Remain of int (* n obligations remaining *)
- | Dependent (* Dependent on other definitions *)
- | Defined of global_reference (* Defined as id *)
-
-val set_default_tactic : Tacexpr.glob_tactic_expr -> unit
-val default_tactic : unit -> Proof_type.tactic
-
-val set_proofs_transparency : bool -> unit (* true = All transparent, false = Opaque if possible *)
-val get_proofs_transparency : unit -> bool
-
-val add_definition : Names.identifier -> Term.constr -> Term.types ->
- ?implicits:(Topconstr.explicitation * (bool * bool)) list ->
- ?kind:Decl_kinds.definition_kind ->
- ?tactic:Proof_type.tactic ->
- ?hook:Tacexpr.declaration_hook -> obligation_info -> progress
-
-type notations = (string * Topconstr.constr_expr * Topconstr.scope_name option) list
-
-val add_mutual_definitions :
- (Names.identifier * Term.constr * Term.types *
- (Topconstr.explicitation * (bool * bool)) list * obligation_info) list ->
- ?tactic:Proof_type.tactic ->
- ?kind:Decl_kinds.definition_kind ->
- ?hook:Tacexpr.declaration_hook ->
- notations ->
- Command.fixpoint_kind -> unit
-
-val subtac_obligation : int * Names.identifier option * Topconstr.constr_expr option -> unit
-
-val next_obligation : Names.identifier option -> unit
-
-val solve_obligations : Names.identifier option -> Proof_type.tactic option -> progress
-(* Number of remaining obligations to be solved for this program *)
-
-val solve_all_obligations : Proof_type.tactic option -> unit
-
-val try_solve_obligation : int -> Names.identifier option -> Proof_type.tactic option -> unit
-
-val try_solve_obligations : Names.identifier option -> Proof_type.tactic option -> unit
-
-val show_obligations : ?msg:bool -> Names.identifier option -> unit
-
-val show_term : Names.identifier option -> unit
-
-val admit_obligations : Names.identifier option -> unit
-
-exception NoObligations of Names.identifier option
-
-val explain_no_obligations : Names.identifier option -> Pp.std_ppcmds
-
diff --git a/contrib/subtac/subtac_pretyping.ml b/contrib/subtac/subtac_pretyping.ml
deleted file mode 100644
index 3ae7c95d..00000000
--- a/contrib/subtac/subtac_pretyping.ml
+++ /dev/null
@@ -1,137 +0,0 @@
-(************************************************************************)
-(* 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 *)
-(************************************************************************)
-
-(* $Id: subtac_pretyping.ml 12187 2009-06-13 19:36:59Z msozeau $ *)
-
-open Global
-open Pp
-open Util
-open Names
-open Sign
-open Evd
-open Term
-open Termops
-open Reductionops
-open Environ
-open Type_errors
-open Typeops
-open Libnames
-open Classops
-open List
-open Recordops
-open Evarutil
-open Pretype_errors
-open Rawterm
-open Evarconv
-open Pattern
-open Dyn
-
-open Subtac_coercion
-open Subtac_utils
-open Coqlib
-open Printer
-open Subtac_errors
-open Eterm
-
-module Pretyping = Subtac_pretyping_F.SubtacPretyping_F(Subtac_coercion.Coercion)
-
-open Pretyping
-
-let _ = Pretyping.allow_anonymous_refs := true
-
-type recursion_info = {
- arg_name: name;
- arg_type: types; (* A *)
- args_after : rel_context;
- wf_relation: constr; (* R : A -> A -> Prop *)
- wf_proof: constr; (* : well_founded R *)
- f_type: types; (* f: A -> Set *)
- f_fulltype: types; (* Type with argument and wf proof product first *)
-}
-
-let my_print_rec_info env t =
- str "Name: " ++ Nameops.pr_name t.arg_name ++ spc () ++
- str "Arg type: " ++ my_print_constr env t.arg_type ++ spc () ++
- str "Wf relation: " ++ my_print_constr env t.wf_relation ++ spc () ++
- str "Wf proof: " ++ my_print_constr env t.wf_proof ++ spc () ++
- str "Abbreviated Type: " ++ my_print_constr env t.f_type ++ spc () ++
- str "Full type: " ++ my_print_constr env t.f_fulltype
-(* trace (str "pretype for " ++ (my_print_rawconstr env c) ++ *)
-(* str " and tycon "++ my_print_tycon env tycon ++ *)
-(* str " in environment: " ++ my_print_env env); *)
-
-let merge_evms x y =
- Evd.fold (fun ev evi evm -> Evd.add evm ev evi) x y
-
-let interp env isevars c tycon =
- let j = pretype tycon env isevars ([],[]) c in
- let _ = isevars := Evarutil.nf_evar_defs !isevars in
- let evd,_ = consider_remaining_unif_problems env !isevars in
-(* let unevd = undefined_evars evd in *)
- let unevd' = Typeclasses.resolve_typeclasses ~onlyargs:true ~split:true ~fail:true env evd in
- let evm = evars_of unevd' in
- isevars := unevd';
- nf_evar evm j.uj_val, nf_evar evm j.uj_type
-
-let find_with_index x l =
- let rec aux i = function
- (y, _, _) as t :: tl -> if x = y then i, t else aux (succ i) tl
- | [] -> raise Not_found
- in aux 0 l
-
-open Vernacexpr
-
-let coqintern_constr evd env : Topconstr.constr_expr -> Rawterm.rawconstr = Constrintern.intern_constr (evars_of evd) env
-let coqintern_type evd env : Topconstr.constr_expr -> Rawterm.rawconstr = Constrintern.intern_type (evars_of evd) env
-
-let env_with_binders env isevars l =
- let rec aux ((env, rels) as acc) = function
- Topconstr.LocalRawDef ((loc, name), def) :: tl ->
- let rawdef = coqintern_constr !isevars env def in
- let coqdef, deftyp = interp env isevars rawdef empty_tycon in
- let reldecl = (name, Some coqdef, deftyp) in
- aux (push_rel reldecl env, reldecl :: rels) tl
- | Topconstr.LocalRawAssum (bl, k, typ) :: tl ->
- let rawtyp = coqintern_type !isevars env typ in
- let coqtyp, typtyp = interp env isevars rawtyp empty_tycon in
- let acc =
- List.fold_left (fun (env, rels) (loc, name) ->
- let reldecl = (name, None, coqtyp) in
- (push_rel reldecl env,
- reldecl :: rels))
- (env, rels) bl
- in aux acc tl
- | [] -> acc
- in aux (env, []) l
-
-let subtac_process env isevars id bl c tycon =
- let c = Command.abstract_constr_expr c bl in
- let tycon =
- match tycon with
- None -> empty_tycon
- | Some t ->
- let t = Command.generalize_constr_expr t bl in
- let t = coqintern_type !isevars env t in
- let coqt, ttyp = interp env isevars t empty_tycon in
- mk_tycon coqt
- in
- let c = coqintern_constr !isevars env c in
- let imps = Implicit_quantifiers.implicits_of_rawterm c in
- let coqc, ctyp = interp env isevars c tycon in
- let evm = non_instanciated_map env isevars (evars_of !isevars) in
- let ty = nf_isevar !isevars (match tycon with Some (None, c) -> c | _ -> ctyp) in
- evm, coqc, ty, imps
-
-open Subtac_obligations
-
-let subtac_proof kind hook env isevars id bl c tycon =
- let evm, coqc, coqt, imps = subtac_process env isevars id bl c tycon in
- let evm' = Subtac_utils.evars_of_term evm Evd.empty coqc in
- let evm' = Subtac_utils.evars_of_term evm evm' coqt in
- let evars, def, ty = Eterm.eterm_obligations env id !isevars evm' 0 coqc coqt in
- add_definition id def ty ~implicits:imps ~kind ~hook evars
diff --git a/contrib/subtac/subtac_pretyping.mli b/contrib/subtac/subtac_pretyping.mli
deleted file mode 100644
index ba0b7cd2..00000000
--- a/contrib/subtac/subtac_pretyping.mli
+++ /dev/null
@@ -1,24 +0,0 @@
-open Term
-open Environ
-open Names
-open Sign
-open Evd
-open Global
-open Topconstr
-open Implicit_quantifiers
-open Impargs
-
-module Pretyping : Pretyping.S
-
-val interp :
- Environ.env ->
- Evd.evar_defs ref ->
- Rawterm.rawconstr ->
- Evarutil.type_constraint -> Term.constr * Term.constr
-
-val subtac_process : env -> evar_defs ref -> identifier -> local_binder list ->
- constr_expr -> constr_expr option -> evar_map * constr * types * manual_explicitation list
-
-val subtac_proof : Decl_kinds.definition_kind -> Tacexpr.declaration_hook ->
- env -> evar_defs ref -> identifier -> local_binder list ->
- constr_expr -> constr_expr option -> Subtac_obligations.progress
diff --git a/contrib/subtac/subtac_pretyping_F.ml b/contrib/subtac/subtac_pretyping_F.ml
deleted file mode 100644
index 00d37f35..00000000
--- a/contrib/subtac/subtac_pretyping_F.ml
+++ /dev/null
@@ -1,641 +0,0 @@
-(* -*- 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 *)
-(************************************************************************)
-
-(* $Id: subtac_pretyping_F.ml 11576 2008-11-10 19:13:15Z msozeau $ *)
-
-open Pp
-open Util
-open Names
-open Sign
-open Evd
-open Term
-open Termops
-open Reductionops
-open Environ
-open Type_errors
-open Typeops
-open Libnames
-open Nameops
-open Classops
-open List
-open Recordops
-open Evarutil
-open Pretype_errors
-open Rawterm
-open Evarconv
-open Pattern
-open Dyn
-open Pretyping
-
-(************************************************************************)
-(* This concerns Cases *)
-open Declarations
-open Inductive
-open Inductiveops
-
-module SubtacPretyping_F (Coercion : Coercion.S) = struct
-
- module Cases = Subtac_cases.Cases_F(Coercion)
-
- (* Allow references to syntaxically inexistent variables (i.e., if applied on an inductive) *)
- let allow_anonymous_refs = ref true
-
- let evd_comb0 f isevars =
- let (evd',x) = f !isevars in
- isevars := evd';
- x
-
- let evd_comb1 f isevars x =
- let (evd',y) = f !isevars x in
- isevars := evd';
- y
-
- let evd_comb2 f isevars x y =
- let (evd',z) = f !isevars x y in
- isevars := evd';
- z
-
- let evd_comb3 f isevars x y z =
- let (evd',t) = f !isevars x y z in
- isevars := evd';
- t
-
- let mt_evd = Evd.empty
-
- (* Utilisé pour inférer le prédicat des Cases *)
- (* Semble exagérement fort *)
- (* Faudra préférer une unification entre les types de toutes les clauses *)
- (* et autoriser des ? à rester dans le résultat de l'unification *)
-
- let evar_type_fixpoint loc env isevars lna lar vdefj =
- let lt = Array.length vdefj in
- if Array.length lar = lt then
- for i = 0 to lt-1 do
- if not (e_cumul env isevars (vdefj.(i)).uj_type
- (lift lt lar.(i))) then
- error_ill_typed_rec_body_loc loc env (evars_of !isevars)
- i lna vdefj lar
- done
-
- let check_branches_message loc env isevars c (explft,lft) =
- for i = 0 to Array.length explft - 1 do
- if not (e_cumul env isevars lft.(i) explft.(i)) then
- let sigma = evars_of !isevars in
- error_ill_formed_branch_loc loc env sigma c i lft.(i) explft.(i)
- done
-
- (* coerce to tycon if any *)
- let inh_conv_coerce_to_tycon loc env isevars j = function
- | None -> j_nf_isevar !isevars j
- | Some t -> evd_comb2 (Coercion.inh_conv_coerce_to loc env) isevars j t
-
- let push_rels vars env = List.fold_right push_rel vars env
-
- (*
- let evar_type_case isevars env ct pt lft p c =
- let (mind,bty,rslty) = type_case_branches env (evars_of isevars) ct pt p c
- in check_branches_message isevars env (c,ct) (bty,lft); (mind,rslty)
- *)
-
- let strip_meta id = (* For Grammar v7 compatibility *)
- let s = string_of_id id in
- if s.[0]='$' then id_of_string (String.sub s 1 (String.length s - 1))
- else id
-
- let pretype_id loc env (lvar,unbndltacvars) id =
- let id = strip_meta id in (* May happen in tactics defined by Grammar *)
- try
- let (n,typ) = lookup_rel_id id (rel_context env) in
- { uj_val = mkRel n; uj_type = lift n typ }
- with Not_found ->
- try
- List.assoc id lvar
- with Not_found ->
- try
- let (_,_,typ) = lookup_named id env in
- { uj_val = mkVar id; uj_type = typ }
- with Not_found ->
- try (* To build a nicer ltac error message *)
- match List.assoc id unbndltacvars with
- | None -> user_err_loc (loc,"",
- str "variable " ++ pr_id id ++ str " should be bound to a term")
- | Some id0 -> Pretype_errors.error_var_not_found_loc loc id0
- with Not_found ->
- error_var_not_found_loc loc id
-
- (* make a dependent predicate from an undependent one *)
-
- let make_dep_of_undep env (IndType (indf,realargs)) pj =
- let n = List.length realargs in
- let rec decomp n p =
- if n=0 then p else
- match kind_of_term p with
- | Lambda (_,_,c) -> decomp (n-1) c
- | _ -> decomp (n-1) (applist (lift 1 p, [mkRel 1]))
- in
- let sign,s = decompose_prod_n n pj.uj_type in
- let ind = build_dependent_inductive env indf in
- let s' = mkProd (Anonymous, ind, s) in
- let ccl = lift 1 (decomp n pj.uj_val) in
- let ccl' = mkLambda (Anonymous, ind, ccl) in
- {uj_val=lam_it ccl' sign; uj_type=prod_it s' sign}
-
- (*************************************************************************)
- (* Main pretyping function *)
-
- let pretype_ref isevars env ref =
- let c = constr_of_global ref in
- make_judge c (Retyping.get_type_of env Evd.empty c)
-
- let pretype_sort = function
- | RProp c -> judge_of_prop_contents c
- | RType _ -> judge_of_new_Type ()
-
- (* [pretype tycon env isevars lvar lmeta cstr] attempts to type [cstr] *)
- (* in environment [env], with existential variables [(evars_of isevars)] and *)
- (* the type constraint tycon *)
- let rec pretype (tycon : type_constraint) env isevars lvar c =
-(* let _ = try Subtac_utils.trace (str "pretype " ++ Subtac_utils.my_print_rawconstr env c ++ *)
-(* str " with tycon " ++ Evarutil.pr_tycon env tycon) *)
-(* with _ -> () *)
-(* in *)
- match c with
- | RRef (loc,ref) ->
- inh_conv_coerce_to_tycon loc env isevars
- (pretype_ref isevars env ref)
- tycon
-
- | RVar (loc, id) ->
- inh_conv_coerce_to_tycon loc env isevars
- (pretype_id loc env lvar id)
- tycon
-
- | REvar (loc, ev, instopt) ->
- (* Ne faudrait-il pas s'assurer que hyps est bien un
- sous-contexte du contexte courant, et qu'il n'y a pas de Rel "caché" *)
- let hyps = evar_context (Evd.find (evars_of !isevars) ev) in
- let args = match instopt with
- | None -> instance_from_named_context hyps
- | Some inst -> failwith "Evar subtitutions not implemented" in
- let c = mkEvar (ev, args) in
- let j = (Retyping.get_judgment_of env (evars_of !isevars) c) in
- inh_conv_coerce_to_tycon loc env isevars j tycon
-
- | RPatVar (loc,(someta,n)) ->
- anomaly "Found a pattern variable in a rawterm to type"
-
- | RHole (loc,k) ->
- let ty =
- match tycon with
- | Some (None, ty) -> ty
- | None | Some _ ->
- e_new_evar isevars env ~src:(loc,InternalHole) (new_Type ()) in
- { uj_val = e_new_evar isevars env ~src:(loc,k) ty; uj_type = ty }
-
- | RRec (loc,fixkind,names,bl,lar,vdef) ->
- let rec type_bl env ctxt = function
- [] -> ctxt
- | (na,k,None,ty)::bl ->
- let ty' = pretype_type empty_valcon env isevars lvar ty in
- let dcl = (na,None,ty'.utj_val) in
- type_bl (push_rel dcl env) (add_rel_decl dcl ctxt) bl
- | (na,k,Some bd,ty)::bl ->
- let ty' = pretype_type empty_valcon env isevars lvar ty in
- let bd' = pretype (mk_tycon ty'.utj_val) env isevars lvar ty in
- let dcl = (na,Some bd'.uj_val,ty'.utj_val) in
- type_bl (push_rel dcl env) (add_rel_decl dcl ctxt) bl in
- let ctxtv = Array.map (type_bl env empty_rel_context) bl in
- let larj =
- array_map2
- (fun e ar ->
- pretype_type empty_valcon (push_rel_context e env) isevars lvar ar)
- ctxtv lar in
- let lara = Array.map (fun a -> a.utj_val) larj in
- let ftys = array_map2 (fun e a -> it_mkProd_or_LetIn a e) ctxtv lara in
- let nbfix = Array.length lar in
- let names = Array.map (fun id -> Name id) names in
- (* Note: bodies are not used by push_rec_types, so [||] is safe *)
- let newenv = push_rec_types (names,ftys,[||]) env in
- let fixi = match fixkind with RFix (vn, i) -> i | RCoFix i -> i in
- let vdefj =
- array_map2_i
- (fun i ctxt def ->
- let fty =
- let ty = ftys.(i) in
- if i = fixi then (
- Option.iter (fun tycon ->
- isevars := Coercion.inh_conv_coerces_to loc env !isevars ftys.(i) tycon)
- tycon;
- nf_isevar !isevars ty)
- else ty
- in
- (* we lift nbfix times the type in tycon, because of
- * the nbfix variables pushed to newenv *)
- let (ctxt,ty) =
- decompose_prod_n_assum (rel_context_length ctxt)
- (lift nbfix fty) in
- let nenv = push_rel_context ctxt newenv in
- let j = pretype (mk_tycon ty) nenv isevars lvar def in
- { uj_val = it_mkLambda_or_LetIn j.uj_val ctxt;
- uj_type = it_mkProd_or_LetIn j.uj_type ctxt })
- ctxtv vdef in
- evar_type_fixpoint loc env isevars names ftys vdefj;
- let ftys = Array.map (nf_evar (evars_of !isevars)) ftys in
- let fdefs = Array.map (fun x -> nf_evar (evars_of !isevars) (j_val x)) vdefj in
- let fixj = match fixkind with
- | RFix (vn,i) ->
- (* First, let's find the guard indexes. *)
- (* If recursive argument was not given by user, we try all args.
- An earlier approach was to look only for inductive arguments,
- but doing it properly involves delta-reduction, and it finally
- doesn't seem worth the effort (except for huge mutual
- fixpoints ?) *)
- let possible_indexes = Array.to_list (Array.mapi
- (fun i (n,_) -> match n with
- | Some n -> [n]
- | None -> list_map_i (fun i _ -> i) 0 ctxtv.(i))
- vn)
- in
- let fixdecls = (names,ftys,fdefs) in
- let indexes = search_guard loc env possible_indexes fixdecls in
- make_judge (mkFix ((indexes,i),fixdecls)) ftys.(i)
- | RCoFix i ->
- let cofix = (i,(names,ftys,fdefs)) in
- (try check_cofix env cofix with e -> Stdpp.raise_with_loc loc e);
- make_judge (mkCoFix cofix) ftys.(i) in
- inh_conv_coerce_to_tycon loc env isevars fixj tycon
-
- | RSort (loc,s) ->
- inh_conv_coerce_to_tycon loc env isevars (pretype_sort s) tycon
-
- | RApp (loc,f,args) ->
- let length = List.length args in
- let ftycon =
- let ty =
- if length > 0 then
- match tycon with
- | None -> None
- | Some (None, ty) -> mk_abstr_tycon length ty
- | Some (Some (init, cur), ty) ->
- Some (Some (length + init, length + cur), ty)
- else tycon
- in
- match ty with
- | Some (_, t) when Subtac_coercion.disc_subset t = None -> ty
- | _ -> None
- in
- let fj = pretype ftycon env isevars lvar f in
- let floc = loc_of_rawconstr f in
- let rec apply_rec env n resj tycon = function
- | [] -> resj
- | c::rest ->
- let argloc = loc_of_rawconstr c in
- let resj = evd_comb1 (Coercion.inh_app_fun env) isevars resj in
- let resty = whd_betadeltaiota env (evars_of !isevars) resj.uj_type in
- match kind_of_term resty with
- | Prod (na,c1,c2) ->
- Option.iter (fun ty -> isevars :=
- Coercion.inh_conv_coerces_to loc env !isevars resty ty) tycon;
- let evd, (_, _, tycon) = split_tycon loc env !isevars tycon in
- isevars := evd;
- let hj = pretype (mk_tycon (nf_isevar !isevars c1)) env isevars lvar c in
- let value, typ = applist (j_val resj, [j_val hj]), subst1 hj.uj_val c2 in
- let typ' = nf_isevar !isevars typ in
- apply_rec env (n+1)
- { uj_val = nf_isevar !isevars value;
- uj_type = nf_isevar !isevars typ' }
- (Option.map (fun (abs, c) -> abs, nf_isevar !isevars c) tycon) rest
-
- | _ ->
- let hj = pretype empty_tycon env isevars lvar c in
- error_cant_apply_not_functional_loc
- (join_loc floc argloc) env (evars_of !isevars)
- resj [hj]
- in
- let resj = j_nf_evar (evars_of !isevars) (apply_rec env 1 fj ftycon args) in
- let resj =
- match kind_of_term resj.uj_val with
- | App (f,args) when isInd f or isConst f ->
- let sigma = evars_of !isevars in
- let c = mkApp (f,Array.map (whd_evar sigma) args) in
- let t = Retyping.get_type_of env sigma c in
- make_judge c t
- | _ -> resj in
- inh_conv_coerce_to_tycon loc env isevars resj tycon
-
- | RLambda(loc,name,k,c1,c2) ->
- let tycon' = evd_comb1
- (fun evd tycon ->
- match tycon with
- | None -> evd, tycon
- | Some ty ->
- let evd, ty' = Coercion.inh_coerce_to_prod loc env evd ty in
- evd, Some ty')
- isevars tycon
- in
- let (name',dom,rng) = evd_comb1 (split_tycon loc env) isevars tycon' in
- let dom_valcon = valcon_of_tycon dom in
- let j = pretype_type dom_valcon env isevars lvar c1 in
- let var = (name,None,j.utj_val) in
- let j' = pretype rng (push_rel var env) isevars lvar c2 in
- let resj = judge_of_abstraction env name j j' in
- inh_conv_coerce_to_tycon loc env isevars resj tycon
-
- | RProd(loc,name,k,c1,c2) ->
- let j = pretype_type empty_valcon env isevars lvar c1 in
- let var = (name,j.utj_val) in
- let env' = push_rel_assum var env in
- let j' = pretype_type empty_valcon env' isevars lvar c2 in
- let resj =
- try judge_of_product env name j j'
- with TypeError _ as e -> Stdpp.raise_with_loc loc e in
- inh_conv_coerce_to_tycon loc env isevars resj tycon
-
- | RLetIn(loc,name,c1,c2) ->
- let j = pretype empty_tycon env isevars lvar c1 in
- let t = refresh_universes j.uj_type in
- let var = (name,Some j.uj_val,t) in
- let tycon = lift_tycon 1 tycon in
- let j' = pretype tycon (push_rel var env) isevars lvar c2 in
- { uj_val = mkLetIn (name, j.uj_val, t, j'.uj_val) ;
- uj_type = subst1 j.uj_val j'.uj_type }
-
- | RLetTuple (loc,nal,(na,po),c,d) ->
- let cj = pretype empty_tycon env isevars lvar c in
- let (IndType (indf,realargs)) =
- try find_rectype env (evars_of !isevars) cj.uj_type
- with Not_found ->
- let cloc = loc_of_rawconstr c in
- error_case_not_inductive_loc cloc env (evars_of !isevars) cj
- in
- let cstrs = get_constructors env indf in
- if Array.length cstrs <> 1 then
- user_err_loc (loc,"",str "Destructing let is only for inductive types with one constructor");
- let cs = cstrs.(0) in
- if List.length nal <> cs.cs_nargs then
- user_err_loc (loc,"", str "Destructing let on this type expects " ++ int cs.cs_nargs ++ str " variables");
- let fsign = List.map2 (fun na (_,c,t) -> (na,c,t))
- (List.rev nal) cs.cs_args in
- let env_f = push_rels fsign env in
- (* Make dependencies from arity signature impossible *)
- let arsgn =
- let arsgn,_ = get_arity env indf in
- if not !allow_anonymous_refs then
- List.map (fun (_,b,t) -> (Anonymous,b,t)) arsgn
- else arsgn
- in
- let psign = (na,None,build_dependent_inductive env indf)::arsgn in
- let nar = List.length arsgn in
- (match po with
- | Some p ->
- let env_p = push_rels psign env in
- let pj = pretype_type empty_valcon env_p isevars lvar p in
- let ccl = nf_evar (evars_of !isevars) pj.utj_val in
- let psign = make_arity_signature env true indf in (* with names *)
- let p = it_mkLambda_or_LetIn ccl psign in
- let inst =
- (Array.to_list cs.cs_concl_realargs)
- @[build_dependent_constructor cs] in
- let lp = lift cs.cs_nargs p in
- let fty = hnf_lam_applist env (evars_of !isevars) lp inst in
- let fj = pretype (mk_tycon fty) env_f isevars lvar d in
- let f = it_mkLambda_or_LetIn fj.uj_val fsign in
- let v =
- let mis,_ = dest_ind_family indf in
- let ci = make_case_info env mis LetStyle in
- mkCase (ci, p, cj.uj_val,[|f|]) in
- { uj_val = v; uj_type = substl (realargs@[cj.uj_val]) ccl }
-
- | None ->
- let tycon = lift_tycon cs.cs_nargs tycon in
- let fj = pretype tycon env_f isevars lvar d in
- let f = it_mkLambda_or_LetIn fj.uj_val fsign in
- let ccl = nf_evar (evars_of !isevars) fj.uj_type in
- let ccl =
- if noccur_between 1 cs.cs_nargs ccl then
- lift (- cs.cs_nargs) ccl
- else
- error_cant_find_case_type_loc loc env (evars_of !isevars)
- cj.uj_val in
- let p = it_mkLambda_or_LetIn (lift (nar+1) ccl) psign in
- let v =
- let mis,_ = dest_ind_family indf in
- let ci = make_case_info env mis LetStyle in
- mkCase (ci, p, cj.uj_val,[|f|] )
- in
- { uj_val = v; uj_type = ccl })
-
- | RIf (loc,c,(na,po),b1,b2) ->
- let cj = pretype empty_tycon env isevars lvar c in
- let (IndType (indf,realargs)) =
- try find_rectype env (evars_of !isevars) cj.uj_type
- with Not_found ->
- let cloc = loc_of_rawconstr c in
- error_case_not_inductive_loc cloc env (evars_of !isevars) cj in
- let cstrs = get_constructors env indf in
- if Array.length cstrs <> 2 then
- user_err_loc (loc,"",
- str "If is only for inductive types with two constructors");
-
- let arsgn =
- let arsgn,_ = get_arity env indf in
- if not !allow_anonymous_refs then
- (* Make dependencies from arity signature impossible *)
- List.map (fun (_,b,t) -> (Anonymous,b,t)) arsgn
- else arsgn
- in
- let nar = List.length arsgn in
- let psign = (na,None,build_dependent_inductive env indf)::arsgn in
- let pred,p = match po with
- | Some p ->
- let env_p = push_rels psign env in
- let pj = pretype_type empty_valcon env_p isevars lvar p in
- let ccl = nf_evar (evars_of !isevars) pj.utj_val in
- let pred = it_mkLambda_or_LetIn ccl psign in
- let typ = lift (- nar) (beta_applist (pred,[cj.uj_val])) in
- let jtyp = inh_conv_coerce_to_tycon loc env isevars {uj_val = pred;
- uj_type = typ} tycon
- in
- jtyp.uj_val, jtyp.uj_type
- | None ->
- let p = match tycon with
- | Some (None, ty) -> ty
- | None | Some _ ->
- e_new_evar isevars env ~src:(loc,InternalHole) (new_Type ())
- in
- it_mkLambda_or_LetIn (lift (nar+1) p) psign, p in
- let pred = nf_evar (evars_of !isevars) pred in
- let p = nf_evar (evars_of !isevars) p in
- (* msgnl (str "Pred is: " ++ Termops.print_constr_env env pred);*)
- let f cs b =
- let n = rel_context_length cs.cs_args in
- let pi = lift n pred in (* liftn n 2 pred ? *)
- let pi = beta_applist (pi, [build_dependent_constructor cs]) in
- let csgn =
- if not !allow_anonymous_refs then
- List.map (fun (_,b,t) -> (Anonymous,b,t)) cs.cs_args
- else
- List.map
- (fun (n, b, t) ->
- match n with
- Name _ -> (n, b, t)
- | Anonymous -> (Name (id_of_string "H"), b, t))
- cs.cs_args
- in
- let env_c = push_rels csgn env in
-(* msgnl (str "Pi is: " ++ Termops.print_constr_env env_c pi); *)
- let bj = pretype (mk_tycon pi) env_c isevars lvar b in
- it_mkLambda_or_LetIn bj.uj_val cs.cs_args in
- let b1 = f cstrs.(0) b1 in
- let b2 = f cstrs.(1) b2 in
- let v =
- let mis,_ = dest_ind_family indf in
- let ci = make_case_info env mis IfStyle in
- mkCase (ci, pred, cj.uj_val, [|b1;b2|])
- in
- { uj_val = v; uj_type = p }
-
- | RCases (loc,sty,po,tml,eqns) ->
- Cases.compile_cases loc sty
- ((fun vtyc env isevars -> pretype vtyc env isevars lvar),isevars)
- tycon env (* loc *) (po,tml,eqns)
-
- | RCast(loc,c,k) ->
- let cj =
- match k with
- CastCoerce ->
- let cj = pretype empty_tycon env isevars lvar c in
- evd_comb1 (Coercion.inh_coerce_to_base loc env) isevars cj
- | CastConv (k,t) ->
- let tj = pretype_type empty_valcon env isevars lvar t in
- let cj = pretype (mk_tycon tj.utj_val) env isevars lvar c in
- (* User Casts are for helping pretyping, experimentally not to be kept*)
- (* ... except for Correctness *)
- let v = mkCast (cj.uj_val, k, tj.utj_val) in
- { uj_val = v; uj_type = tj.utj_val }
- in
- inh_conv_coerce_to_tycon loc env isevars cj tycon
-
- | RDynamic (loc,d) ->
- if (tag d) = "constr" then
- let c = constr_out d in
- let j = (Retyping.get_judgment_of env (evars_of !isevars) c) in
- j
- (*inh_conv_coerce_to_tycon loc env isevars j tycon*)
- else
- user_err_loc (loc,"pretype",(str "Not a constr tagged Dynamic"))
-
- (* [pretype_type valcon env isevars lvar c] coerces [c] into a type *)
- and pretype_type valcon env isevars lvar = function
- | RHole loc ->
- (match valcon with
- | Some v ->
- let s =
- let sigma = evars_of !isevars in
- let t = Retyping.get_type_of env sigma v in
- match kind_of_term (whd_betadeltaiota env sigma t) with
- | Sort s -> s
- | Evar v when is_Type (existential_type sigma v) ->
- evd_comb1 (define_evar_as_sort) isevars v
- | _ -> anomaly "Found a type constraint which is not a type"
- in
- { utj_val = v;
- utj_type = s }
- | None ->
- let s = new_Type_sort () in
- { utj_val = e_new_evar isevars env ~src:loc (mkSort s);
- utj_type = s})
- | c ->
- let j = pretype empty_tycon env isevars lvar c in
- let loc = loc_of_rawconstr c in
- let tj = evd_comb1 (Coercion.inh_coerce_to_sort loc env) isevars j in
- match valcon with
- | None -> tj
- | Some v ->
- if e_cumul env isevars v tj.utj_val then tj
- else
- error_unexpected_type_loc
- (loc_of_rawconstr c) env (evars_of !isevars) tj.utj_val v
-
- let pretype_gen_aux isevars env lvar kind c =
- let c' = match kind with
- | OfType exptyp ->
- let tycon = match exptyp with None -> empty_tycon | Some t -> mk_tycon t in
- (pretype tycon env isevars lvar c).uj_val
- | IsType ->
- (pretype_type empty_valcon env isevars lvar c).utj_val in
- let evd,_ = consider_remaining_unif_problems env !isevars in
- isevars:=evd;
- nf_evar (evars_of !isevars) c'
-
- let pretype_gen isevars env lvar kind c =
- let c = pretype_gen_aux isevars env lvar kind c in
- isevars := Typeclasses.resolve_typeclasses ~onlyargs:true ~fail:false env !isevars;
- nf_evar (evars_of !isevars) c
-
- (* TODO: comment faire remonter l'information si le typage a resolu des
- variables du sigma original. il faudrait que la fonction de typage
- retourne aussi le nouveau sigma...
- *)
-
- let understand_judgment sigma env c =
- let isevars = ref (create_evar_defs sigma) in
- let j = pretype empty_tycon env isevars ([],[]) c in
- let j = j_nf_evar (evars_of !isevars) j in
- let isevars,_ = consider_remaining_unif_problems env !isevars in
- check_evars env sigma isevars (mkCast(j.uj_val,DEFAULTcast, j.uj_type));
- j
-
- let understand_judgment_tcc isevars env c =
- let j = pretype empty_tycon env isevars ([],[]) c in
- let sigma = evars_of !isevars in
- let j = j_nf_evar sigma j in
- j
-
- (* Raw calls to the unsafe inference machine: boolean says if we must
- fail on unresolved evars; the unsafe_judgment list allows us to
- extend env with some bindings *)
-
- let ise_pretype_gen fail_evar sigma env lvar kind c =
- let isevars = ref (Evd.create_evar_defs sigma) in
- let c = pretype_gen isevars env lvar kind c in
- let evd = !isevars in
- if fail_evar then check_evars env Evd.empty evd c;
- evd, c
-
- (** Entry points of the high-level type synthesis algorithm *)
-
- let understand_gen kind sigma env c =
- snd (ise_pretype_gen true sigma env ([],[]) kind c)
-
- let understand sigma env ?expected_type:exptyp c =
- snd (ise_pretype_gen true sigma env ([],[]) (OfType exptyp) c)
-
- let understand_type sigma env c =
- snd (ise_pretype_gen false sigma env ([],[]) IsType c)
-
- let understand_ltac sigma env lvar kind c =
- ise_pretype_gen false sigma env lvar kind c
-
- let understand_tcc_evars evdref env kind c =
- pretype_gen evdref env ([],[]) kind c
-
- let understand_tcc ?(resolve_classes=true) sigma env ?expected_type:exptyp c =
- let ev, t =
- if resolve_classes then
- ise_pretype_gen false sigma env ([],[]) (OfType exptyp) c
- else
- let isevars = ref (Evd.create_evar_defs sigma) in
- let c = pretype_gen_aux isevars env ([],[]) (OfType exptyp) c in
- !isevars, c
- in
- Evd.evars_of ev, t
-end
-
-module Default : S = SubtacPretyping_F(Coercion.Default)
diff --git a/contrib/subtac/subtac_utils.ml b/contrib/subtac/subtac_utils.ml
deleted file mode 100644
index 2ee2018e..00000000
--- a/contrib/subtac/subtac_utils.ml
+++ /dev/null
@@ -1,474 +0,0 @@
-open Evd
-open Libnames
-open Coqlib
-open Term
-open Names
-open Util
-
-let ($) f x = f x
-
-(****************************************************************************)
-(* Library linking *)
-
-let contrib_name = "Program"
-
-let subtac_dir = [contrib_name]
-let fix_sub_module = "Wf"
-let utils_module = "Utils"
-let fixsub_module = subtac_dir @ [fix_sub_module]
-let utils_module = subtac_dir @ [utils_module]
-let init_constant dir s = gen_constant contrib_name dir s
-let init_reference dir s = gen_reference contrib_name dir s
-
-let fixsub = lazy (init_constant fixsub_module "Fix_sub")
-let ex_pi1 = lazy (init_constant utils_module "ex_pi1")
-let ex_pi2 = lazy (init_constant utils_module "ex_pi2")
-
-let make_ref l s = lazy (init_reference l s)
-let well_founded_ref = make_ref ["Init";"Wf"] "Well_founded"
-let acc_ref = make_ref ["Init";"Wf"] "Acc"
-let acc_inv_ref = make_ref ["Init";"Wf"] "Acc_inv"
-let fix_sub_ref = make_ref fixsub_module "Fix_sub"
-let fix_measure_sub_ref = make_ref fixsub_module "Fix_measure_sub"
-let lt_ref = make_ref ["Init";"Peano"] "lt"
-let lt_wf_ref = make_ref ["Wf_nat"] "lt_wf"
-let refl_ref = make_ref ["Init";"Logic"] "refl_equal"
-
-let make_ref s = Qualid (dummy_loc, qualid_of_string s)
-let sig_ref = make_ref "Init.Specif.sig"
-let proj1_sig_ref = make_ref "Init.Specif.proj1_sig"
-let proj2_sig_ref = make_ref "Init.Specif.proj2_sig"
-
-let build_sig () =
- { proj1 = init_constant ["Init"; "Specif"] "proj1_sig";
- proj2 = init_constant ["Init"; "Specif"] "proj2_sig";
- elim = init_constant ["Init"; "Specif"] "sig_rec";
- intro = init_constant ["Init"; "Specif"] "exist";
- typ = init_constant ["Init"; "Specif"] "sig" }
-
-let sig_ = lazy (build_sig ())
-
-let eq_ind = lazy (init_constant ["Init"; "Logic"] "eq")
-let eq_rec = lazy (init_constant ["Init"; "Logic"] "eq_rec")
-let eq_rect = lazy (init_constant ["Init"; "Logic"] "eq_rect")
-let eq_refl = lazy (init_constant ["Init"; "Logic"] "refl_equal")
-let eq_ind_ref = lazy (init_reference ["Init"; "Logic"] "eq")
-let refl_equal_ref = lazy (init_reference ["Init"; "Logic"] "refl_equal")
-
-let not_ref = lazy (init_constant ["Init"; "Logic"] "not")
-
-let and_typ = lazy (Coqlib.build_coq_and ())
-
-let eqdep_ind = lazy (init_constant [ "Logic";"Eqdep"] "eq_dep")
-let eqdep_rec = lazy (init_constant ["Logic";"Eqdep"] "eq_dep_rec")
-let eqdep_ind_ref = lazy (init_reference [ "Logic";"Eqdep"] "eq_dep")
-let eqdep_intro_ref = lazy (init_reference [ "Logic";"Eqdep"] "eq_dep_intro")
-
-let jmeq_ind () =
- check_required_library ["Coq";"Logic";"JMeq"];
- init_constant ["Logic";"JMeq"] "JMeq"
-
-let jmeq_rec () =
- check_required_library ["Coq";"Logic";"JMeq"];
- init_constant ["Logic";"JMeq"] "JMeq_rec"
-
-let jmeq_refl () =
- check_required_library ["Coq";"Logic";"JMeq"];
- init_constant ["Logic";"JMeq"] "JMeq_refl"
-
-let ex_ind = lazy (init_constant ["Init"; "Logic"] "ex")
-let ex_intro = lazy (init_reference ["Init"; "Logic"] "ex_intro")
-
-let proj1 = lazy (init_constant ["Init"; "Logic"] "proj1")
-let proj2 = lazy (init_constant ["Init"; "Logic"] "proj2")
-
-let boolind = lazy (init_constant ["Init"; "Datatypes"] "bool")
-let sumboolind = lazy (init_constant ["Init"; "Specif"] "sumbool")
-let natind = lazy (init_constant ["Init"; "Datatypes"] "nat")
-let intind = lazy (init_constant ["ZArith"; "binint"] "Z")
-let existSind = lazy (init_constant ["Init"; "Specif"] "sigS")
-
-let existS = lazy (build_sigma_type ())
-
-let prod = lazy (build_prod ())
-
-
-(* orders *)
-let well_founded = lazy (init_constant ["Init"; "Wf"] "well_founded")
-let fix = lazy (init_constant ["Init"; "Wf"] "Fix")
-let acc = lazy (init_constant ["Init"; "Wf"] "Acc")
-let acc_inv = lazy (init_constant ["Init"; "Wf"] "Acc_inv")
-
-let extconstr = Constrextern.extern_constr true (Global.env ())
-let extsort s = Constrextern.extern_constr true (Global.env ()) (mkSort s)
-
-open Pp
-
-let my_print_constr = Termops.print_constr_env
-let my_print_constr_expr = Ppconstr.pr_constr_expr
-let my_print_rel_context env ctx = Printer.pr_rel_context env ctx
-let my_print_context = Termops.print_rel_context
-let my_print_named_context = Termops.print_named_context
-let my_print_env = Termops.print_env
-let my_print_rawconstr = Printer.pr_rawconstr_env
-let my_print_evardefs = Evd.pr_evar_defs
-
-let my_print_tycon_type = Evarutil.pr_tycon_type
-
-let debug_level = 2
-
-let debug_on = true
-
-let debug n s =
- if debug_on then
- if !Flags.debug && n >= debug_level then
- msgnl s
- else ()
- else ()
-
-let debug_msg n s =
- if debug_on then
- if !Flags.debug && n >= debug_level then s
- else mt ()
- else mt ()
-
-let trace s =
- if debug_on then
- if !Flags.debug && debug_level > 0 then msgnl s
- else ()
- else ()
-
-let rec pp_list f = function
- [] -> mt()
- | x :: y -> f x ++ spc () ++ pp_list f y
-
-let wf_relations = Hashtbl.create 10
-
-let std_relations () =
- let add k v = Hashtbl.add wf_relations k v in
- add (init_constant ["Init"; "Peano"] "lt")
- (lazy (init_constant ["Arith"; "Wf_nat"] "lt_wf"))
-
-let std_relations = Lazy.lazy_from_fun std_relations
-
-type binders = Topconstr.local_binder list
-
-let app_opt c e =
- match c with
- Some constr -> constr e
- | None -> e
-
-let print_args env args =
- Array.fold_right (fun a acc -> my_print_constr env a ++ spc () ++ acc) args (str "")
-
-let make_existential loc ?(opaque = Define true) env isevars c =
- let evar = Evarutil.e_new_evar isevars env ~src:(loc, QuestionMark opaque) c in
- let (key, args) = destEvar evar in
- (try trace (str "Constructed evar " ++ int key ++ str " applied to args: " ++
- print_args env args ++ str " for type: "++
- my_print_constr env c) with _ -> ());
- evar
-
-let make_existential_expr loc env c =
- let key = Evarutil.new_untyped_evar () in
- let evar = Topconstr.CEvar (loc, key, None) in
- debug 2 (str "Constructed evar " ++ int key);
- evar
-
-let string_of_hole_kind = function
- | ImplicitArg _ -> "ImplicitArg"
- | BinderType _ -> "BinderType"
- | QuestionMark _ -> "QuestionMark"
- | CasesType -> "CasesType"
- | InternalHole -> "InternalHole"
- | TomatchTypeParameter _ -> "TomatchTypeParameter"
- | GoalEvar -> "GoalEvar"
- | ImpossibleCase -> "ImpossibleCase"
-
-let evars_of_term evc init c =
- let rec evrec acc c =
- match kind_of_term c with
- | Evar (n, _) when Evd.mem evc n -> Evd.add acc n (Evd.find evc n)
- | Evar (n, _) -> assert(false)
- | _ -> fold_constr evrec acc c
- in
- evrec init c
-
-let non_instanciated_map env evd evm =
- List.fold_left
- (fun evm (key, evi) ->
- let (loc,k) = evar_source key !evd in
- debug 2 (str "evar " ++ int key ++ str " has kind " ++
- str (string_of_hole_kind k));
- match k with
- QuestionMark _ -> Evd.add evm key evi
- | _ ->
- debug 2 (str " and is an implicit");
- Pretype_errors.error_unsolvable_implicit loc env evm (Evarutil.nf_evar_info evm evi) k None)
- Evd.empty (Evarutil.non_instantiated evm)
-
-let global_kind = Decl_kinds.IsDefinition Decl_kinds.Definition
-let goal_kind = Decl_kinds.Global, Decl_kinds.DefinitionBody Decl_kinds.Definition
-
-let global_proof_kind = Decl_kinds.IsProof Decl_kinds.Lemma
-let goal_proof_kind = Decl_kinds.Global, Decl_kinds.Proof Decl_kinds.Lemma
-
-let global_fix_kind = Decl_kinds.IsDefinition Decl_kinds.Fixpoint
-let goal_fix_kind = Decl_kinds.Global, Decl_kinds.DefinitionBody Decl_kinds.Fixpoint
-
-open Tactics
-open Tacticals
-
-let id x = x
-let filter_map f l =
- let rec aux acc = function
- hd :: tl -> (match f hd with Some t -> aux (t :: acc) tl
- | None -> aux acc tl)
- | [] -> List.rev acc
- in aux [] l
-
-let build_dependent_sum l =
- let rec aux names conttac conttype = function
- (n, t) :: ((_ :: _) as tl) ->
- let hyptype = substl names t in
- trace (spc () ++ str ("treating evar " ^ string_of_id n));
- (try trace (str " assert: " ++ my_print_constr (Global.env ()) hyptype)
- with _ -> ());
- let tac = assert_tac (Name n) hyptype in
- let conttac =
- (fun cont ->
- conttac
- (tclTHENS tac
- ([intros;
- (tclTHENSEQ
- [constructor_tac false (Some 1) 1
- (Rawterm.ImplicitBindings [inj_open (mkVar n)]);
- cont]);
- ])))
- in
- let conttype =
- (fun typ ->
- let tex = mkLambda (Name n, t, typ) in
- conttype
- (mkApp (Lazy.force ex_ind, [| t; tex |])))
- in
- aux (mkVar n :: names) conttac conttype tl
- | (n, t) :: [] ->
- (conttac intros, conttype t)
- | [] -> raise (Invalid_argument "build_dependent_sum")
- in aux [] id id (List.rev l)
-
-open Proof_type
-open Tacexpr
-
-let mkProj1 a b c =
- mkApp (Lazy.force proj1, [| a; b; c |])
-
-let mkProj2 a b c =
- mkApp (Lazy.force proj2, [| a; b; c |])
-
-let mk_ex_pi1 a b c =
- mkApp (Lazy.force ex_pi1, [| a; b; c |])
-
-let mk_ex_pi2 a b c =
- mkApp (Lazy.force ex_pi2, [| a; b; c |])
-
-let mkSubset name typ prop =
- mkApp ((Lazy.force sig_).typ,
- [| typ; mkLambda (name, typ, prop) |])
-
-let mk_eq typ x y = mkApp (Lazy.force eq_ind, [| typ; x ; y |])
-let mk_eq_refl typ x = mkApp (Lazy.force eq_refl, [| typ; x |])
-let mk_JMeq typ x typ' y = mkApp (jmeq_ind (), [| typ; x ; typ'; y |])
-let mk_JMeq_refl typ x = mkApp (jmeq_refl (), [| typ; x |])
-
-let unsafe_fold_right f = function
- hd :: tl -> List.fold_right f tl hd
- | [] -> raise (Invalid_argument "unsafe_fold_right")
-
-let mk_conj l =
- let conj_typ = Lazy.force and_typ in
- unsafe_fold_right
- (fun c conj ->
- mkApp (conj_typ, [| c ; conj |]))
- l
-
-let mk_not c =
- let notc = Lazy.force not_ref in
- mkApp (notc, [| c |])
-
-let and_tac l hook =
- let andc = Coqlib.build_coq_and () in
- let rec aux ((accid, goal, tac, extract) as acc) = function
- | [] -> (* Singleton *) acc
-
- | (id, x, elgoal, eltac) :: tl ->
- let tac' = tclTHEN simplest_split (tclTHENLIST [tac; eltac]) in
- let proj = fun c -> mkProj2 goal elgoal c in
- let extract = List.map (fun (id, x, y, f) -> (id, x, y, (fun c -> f (mkProj1 goal elgoal c)))) extract in
- aux ((string_of_id id) ^ "_" ^ accid, mkApp (andc, [| goal; elgoal |]), tac',
- (id, x, elgoal, proj) :: extract) tl
-
- in
- let and_proof_id, and_goal, and_tac, and_extract =
- match l with
- | [] -> raise (Invalid_argument "and_tac: empty list of goals")
- | (hdid, x, hdg, hdt) :: tl ->
- aux (string_of_id hdid, hdg, hdt, [hdid, x, hdg, (fun c -> c)]) tl
- in
- let and_proofid = id_of_string (and_proof_id ^ "_and_proof") in
- Command.start_proof and_proofid goal_kind and_goal
- (hook (fun c -> List.map (fun (id, x, t, f) -> (id, x, t, f c)) and_extract));
- trace (str "Started and proof");
- Pfedit.by and_tac;
- trace (str "Applied and tac")
-
-
-let destruct_ex ext ex =
- let rec aux c acc =
- match kind_of_term c with
- App (f, args) ->
- (match kind_of_term f with
- Ind i when i = Term.destInd (Lazy.force ex_ind) && Array.length args = 2 ->
- let (dom, rng) =
- try (args.(0), args.(1))
- with _ -> assert(false)
- in
- let pi1 = (mk_ex_pi1 dom rng acc) in
- let rng_body =
- match kind_of_term rng with
- Lambda (_, _, t) -> subst1 pi1 t
- | t -> rng
- in
- pi1 :: aux rng_body (mk_ex_pi2 dom rng acc)
- | _ -> [acc])
- | _ -> [acc]
- in aux ex ext
-
-open Rawterm
-
-let id_of_name = function
- Name n -> n
- | Anonymous -> raise (Invalid_argument "id_of_name")
-
-let definition_message id =
- Nameops.pr_id id ++ str " is defined"
-
-let recursive_message v =
- match Array.length v with
- | 0 -> error "no recursive definition"
- | 1 -> (Printer.pr_constant (Global.env ()) v.(0) ++ str " is recursively defined")
- | _ -> hov 0 (prvect_with_sep pr_coma (Printer.pr_constant (Global.env ())) v ++
- spc () ++ str "are recursively defined")
-
-let print_message m =
- Flags.if_verbose ppnl m
-
-(* Solve an obligation using tactics, return the corresponding proof term *)
-let solve_by_tac evi t =
- let id = id_of_string "H" in
- try
- Pfedit.start_proof id goal_kind evi.evar_hyps evi.evar_concl
- (fun _ _ -> ());
- Pfedit.by (tclCOMPLETE t);
- let _,(const,_,_,_) = Pfedit.cook_proof ignore in
- Pfedit.delete_current_proof (); const.Entries.const_entry_body
- with e ->
- Pfedit.delete_current_proof();
- raise e
-
-(* let apply_tac t goal = t goal *)
-
-(* let solve_by_tac evi t = *)
-(* let ev = 1 in *)
-(* let evm = Evd.add Evd.empty ev evi in *)
-(* let goal = {it = evi; sigma = evm } in *)
-(* let (res, valid) = apply_tac t goal in *)
-(* if res.it = [] then *)
-(* let prooftree = valid [] in *)
-(* let proofterm, obls = Refiner.extract_open_proof res.sigma prooftree in *)
-(* if obls = [] then proofterm *)
-(* else raise Exit *)
-(* else raise Exit *)
-
-let rec string_of_list sep f = function
- [] -> ""
- | x :: [] -> f x
- | x :: ((y :: _) as tl) -> f x ^ sep ^ string_of_list sep f tl
-
-let string_of_intset d =
- string_of_list "," string_of_int (Intset.elements d)
-
-(**********************************************************)
-(* Pretty-printing *)
-open Printer
-open Ppconstr
-open Nameops
-open Termops
-open Evd
-
-let pr_meta_map evd =
- let ml = meta_list evd in
- let pr_name = function
- Name id -> str"[" ++ pr_id id ++ str"]"
- | _ -> mt() in
- let pr_meta_binding = function
- | (mv,Cltyp (na,b)) ->
- hov 0
- (pr_meta mv ++ pr_name na ++ str " : " ++
- print_constr b.rebus ++ fnl ())
- | (mv,Clval(na,b,_)) ->
- hov 0
- (pr_meta mv ++ pr_name na ++ str " := " ++
- print_constr (fst b).rebus ++ fnl ())
- in
- prlist pr_meta_binding ml
-
-let pr_idl idl = prlist_with_sep pr_spc pr_id idl
-
-let pr_evar_info evi =
- let phyps =
- (*pr_idl (List.rev (ids_of_named_context (evar_context evi))) *)
- Printer.pr_named_context (Global.env()) (evar_context evi)
- in
- let pty = print_constr evi.evar_concl in
- let pb =
- match evi.evar_body with
- | Evar_empty -> mt ()
- | Evar_defined c -> spc() ++ str"=> " ++ print_constr c
- in
- hov 2 (str"[" ++ phyps ++ spc () ++ str"|- " ++ pty ++ pb ++ str"]")
-
-let pr_evar_map sigma =
- h 0
- (prlist_with_sep pr_fnl
- (fun (ev,evi) ->
- h 0 (str(string_of_existential ev)++str"=="++ pr_evar_info evi))
- (to_list sigma))
-
-let pr_constraints pbs =
- h 0
- (prlist_with_sep pr_fnl (fun (pbty,t1,t2) ->
- print_constr t1 ++ spc() ++
- str (match pbty with
- | Reduction.CONV -> "=="
- | Reduction.CUMUL -> "<=") ++
- spc() ++ print_constr t2) pbs)
-
-let pr_evar_defs evd =
- let pp_evm =
- let evars = evars_of evd in
- if evars = empty then mt() else
- str"EVARS:"++brk(0,1)++pr_evar_map evars++fnl() in
- let pp_met =
- if meta_list evd = [] then mt() else
- str"METAS:"++brk(0,1)++pr_meta_map evd in
- v 0 (pp_evm ++ pp_met)
-
-let contrib_tactics_path =
- make_dirpath (List.map id_of_string ["Tactics";contrib_name;"Coq"])
-let tactics_tac s =
- lazy(make_kn (MPfile contrib_tactics_path) (make_dirpath []) (mk_label s))
-
-let tactics_call tac args =
- TacArg(TacCall(dummy_loc, ArgArg(dummy_loc, Lazy.force (tactics_tac tac)),args))
diff --git a/contrib/subtac/subtac_utils.mli b/contrib/subtac/subtac_utils.mli
deleted file mode 100644
index 9c014286..00000000
--- a/contrib/subtac/subtac_utils.mli
+++ /dev/null
@@ -1,133 +0,0 @@
-open Term
-open Libnames
-open Coqlib
-open Environ
-open Pp
-open Evd
-open Decl_kinds
-open Topconstr
-open Rawterm
-open Util
-open Evarutil
-open Names
-open Sign
-
-val ($) : ('a -> 'b) -> 'a -> 'b
-val contrib_name : string
-val subtac_dir : string list
-val fix_sub_module : string
-val fixsub_module : string list
-val init_constant : string list -> string -> constr
-val init_reference : string list -> string -> global_reference
-val fixsub : constr lazy_t
-val well_founded_ref : global_reference lazy_t
-val acc_ref : global_reference lazy_t
-val acc_inv_ref : global_reference lazy_t
-val fix_sub_ref : global_reference lazy_t
-val fix_measure_sub_ref : global_reference lazy_t
-val lt_ref : global_reference lazy_t
-val lt_wf_ref : global_reference lazy_t
-val refl_ref : global_reference lazy_t
-val sig_ref : reference
-val proj1_sig_ref : reference
-val proj2_sig_ref : reference
-val build_sig : unit -> coq_sigma_data
-val sig_ : coq_sigma_data lazy_t
-
-val eq_ind : constr lazy_t
-val eq_rec : constr lazy_t
-val eq_rect : constr lazy_t
-val eq_refl : constr lazy_t
-
-val not_ref : constr lazy_t
-val and_typ : constr lazy_t
-
-val eqdep_ind : constr lazy_t
-val eqdep_rec : constr lazy_t
-
-val jmeq_ind : unit -> constr
-val jmeq_rec : unit -> constr
-val jmeq_refl : unit -> constr
-
-val boolind : constr lazy_t
-val sumboolind : constr lazy_t
-val natind : constr lazy_t
-val intind : constr lazy_t
-val existSind : constr lazy_t
-val existS : coq_sigma_data lazy_t
-val prod : coq_sigma_data lazy_t
-
-val well_founded : constr lazy_t
-val fix : constr lazy_t
-val acc : constr lazy_t
-val acc_inv : constr lazy_t
-val extconstr : constr -> constr_expr
-val extsort : sorts -> constr_expr
-
-val my_print_constr : env -> constr -> std_ppcmds
-val my_print_constr_expr : constr_expr -> std_ppcmds
-val my_print_evardefs : evar_defs -> std_ppcmds
-val my_print_context : env -> std_ppcmds
-val my_print_rel_context : env -> rel_context -> std_ppcmds
-val my_print_named_context : env -> std_ppcmds
-val my_print_env : env -> std_ppcmds
-val my_print_rawconstr : env -> rawconstr -> std_ppcmds
-val my_print_tycon_type : env -> type_constraint_type -> std_ppcmds
-
-
-val debug : int -> std_ppcmds -> unit
-val debug_msg : int -> std_ppcmds -> std_ppcmds
-val trace : std_ppcmds -> unit
-val wf_relations : (constr, constr lazy_t) Hashtbl.t
-
-type binders = local_binder list
-val app_opt : ('a -> 'a) option -> 'a -> 'a
-val print_args : env -> constr array -> std_ppcmds
-val make_existential : loc -> ?opaque:obligation_definition_status ->
- env -> evar_defs ref -> types -> constr
-val make_existential_expr : loc -> 'a -> 'b -> constr_expr
-val string_of_hole_kind : hole_kind -> string
-val evars_of_term : evar_map -> evar_map -> constr -> evar_map
-val non_instanciated_map : env -> evar_defs ref -> evar_map -> evar_map
-val global_kind : logical_kind
-val goal_kind : locality * goal_object_kind
-val global_proof_kind : logical_kind
-val goal_proof_kind : locality * goal_object_kind
-val global_fix_kind : logical_kind
-val goal_fix_kind : locality * goal_object_kind
-
-val mkSubset : name -> constr -> constr -> constr
-val mkProj1 : constr -> constr -> constr -> constr
-val mkProj1 : constr -> constr -> constr -> constr
-val mk_ex_pi1 : constr -> constr -> constr -> constr
-val mk_ex_pi1 : constr -> constr -> constr -> constr
-val mk_eq : types -> constr -> constr -> types
-val mk_eq_refl : types -> constr -> constr
-val mk_JMeq : types -> constr -> types -> constr -> types
-val mk_JMeq_refl : types -> constr -> constr
-val mk_conj : types list -> types
-val mk_not : types -> types
-
-val build_dependent_sum : (identifier * types) list -> Proof_type.tactic * types
-val and_tac : (identifier * 'a * constr * Proof_type.tactic) list ->
- ((constr -> (identifier * 'a * constr * constr) list) -> Tacexpr.declaration_hook) -> unit
-
-val destruct_ex : constr -> constr -> constr list
-
-val id_of_name : name -> identifier
-
-val definition_message : identifier -> std_ppcmds
-val recursive_message : constant array -> std_ppcmds
-
-val print_message : std_ppcmds -> unit
-
-val solve_by_tac : evar_info -> Tacmach.tactic -> constr
-
-val string_of_list : string -> ('a -> string) -> 'a list -> string
-val string_of_intset : Intset.t -> string
-
-val pr_evar_defs : evar_defs -> Pp.std_ppcmds
-
-val tactics_call : string -> Tacexpr.glob_tactic_arg list -> Tacexpr.glob_tactic_expr
-
-val pp_list : ('a -> Pp.std_ppcmds) -> 'a list -> Pp.std_ppcmds
diff --git a/contrib/subtac/test/ListDep.v b/contrib/subtac/test/ListDep.v
deleted file mode 100644
index da612c43..00000000
--- a/contrib/subtac/test/ListDep.v
+++ /dev/null
@@ -1,49 +0,0 @@
-(* -*- coq-prog-args: ("-emacs-U" "-debug") -*- *)
-Require Import List.
-Require Import Coq.Program.Program.
-
-Set Implicit Arguments.
-
-Definition sub_list (A : Set) (l' l : list A) := (forall v, In v l' -> In v l) /\ length l' <= length l.
-
-Lemma sub_list_tl : forall A : Set, forall x (l l' : list A), sub_list (x :: l) l' -> sub_list l l'.
-Proof.
- intros.
- inversion H.
- split.
- intros.
- apply H0.
- auto with datatypes.
- auto with arith.
-Qed.
-
-Section Map_DependentRecursor.
- Variable U V : Set.
- Variable l : list U.
- Variable f : { x : U | In x l } -> V.
-
- Obligations Tactic := unfold sub_list in * ;
- program_simpl ; intuition.
-
- Program Fixpoint map_rec ( l' : list U | sub_list l' l )
- { measure length l' } : { r : list V | length r = length l' } :=
- match l' with
- | nil => nil
- | cons x tl => let tl' := map_rec tl in
- f x :: tl'
- end.
-
- Next Obligation.
- destruct_call map_rec.
- simpl in *.
- subst l'.
- simpl ; auto with arith.
- Qed.
-
- Program Definition map : list V := map_rec l.
-
-End Map_DependentRecursor.
-
-Extraction map.
-Extraction map_rec.
-
diff --git a/contrib/subtac/test/ListsTest.v b/contrib/subtac/test/ListsTest.v
deleted file mode 100644
index 05fc0803..00000000
--- a/contrib/subtac/test/ListsTest.v
+++ /dev/null
@@ -1,99 +0,0 @@
-(* -*- coq-prog-args: ("-emacs-U" "-debug") -*- *)
-Require Import Coq.Program.Program.
-Require Import List.
-
-Set Implicit Arguments.
-
-Section Accessors.
- Variable A : Set.
-
- Program Definition myhd : forall (l : list A | length l <> 0), A :=
- fun l =>
- match l with
- | nil => !
- | hd :: tl => hd
- end.
-
- Program Definition mytail (l : list A | length l <> 0) : list A :=
- match l with
- | nil => !
- | hd :: tl => tl
- end.
-End Accessors.
-
-Program Definition test_hd : nat := myhd (cons 1 nil).
-
-(*Eval compute in test_hd*)
-(*Program Definition test_tail : list A := mytail nil.*)
-
-Section app.
- Variable A : Set.
-
- Program Fixpoint app (l : list A) (l' : list A) { struct l } :
- { r : list A | length r = length l + length l' } :=
- match l with
- | nil => l'
- | hd :: tl => hd :: (tl ++ l')
- end
- where "x ++ y" := (app x y).
-
- Next Obligation.
- intros.
- destruct_call app ; program_simpl.
- Defined.
-
- Program Lemma app_id_l : forall l : list A, l = nil ++ l.
- Proof.
- simpl ; auto.
- Qed.
-
- Program Lemma app_id_r : forall l : list A, l = l ++ nil.
- Proof.
- induction l ; simpl in * ; auto.
- rewrite <- IHl ; auto.
- Qed.
-
-End app.
-
-Extraction app.
-
-Section Nth.
-
- Variable A : Set.
-
- Program Fixpoint nth (l : list A) (n : nat | n < length l) { struct l } : A :=
- match n, l with
- | 0, hd :: _ => hd
- | S n', _ :: tl => nth tl n'
- | _, nil => !
- end.
-
- Next Obligation.
- Proof.
- simpl in *. auto with arith.
- Defined.
-
- Next Obligation.
- Proof.
- inversion H.
- Qed.
-
- Program Fixpoint nth' (l : list A) (n : nat | n < length l) { struct l } : A :=
- match l, n with
- | hd :: _, 0 => hd
- | _ :: tl, S n' => nth' tl n'
- | nil, _ => !
- end.
- Next Obligation.
- Proof.
- simpl in *. auto with arith.
- Defined.
-
- Next Obligation.
- Proof.
- intros.
- inversion H.
- Defined.
-
-End Nth.
-
diff --git a/contrib/subtac/test/Mutind.v b/contrib/subtac/test/Mutind.v
deleted file mode 100644
index ac49ca96..00000000
--- a/contrib/subtac/test/Mutind.v
+++ /dev/null
@@ -1,20 +0,0 @@
-Require Import List.
-
-Program Fixpoint f a : { x : nat | x > 0 } :=
- match a with
- | 0 => 1
- | S a' => g a a'
- end
-with g a b : { x : nat | x > 0 } :=
- match b with
- | 0 => 1
- | S b' => f b'
- end.
-
-Check f.
-Check g.
-
-
-
-
-
diff --git a/contrib/subtac/test/Test1.v b/contrib/subtac/test/Test1.v
deleted file mode 100644
index 14b80854..00000000
--- a/contrib/subtac/test/Test1.v
+++ /dev/null
@@ -1,16 +0,0 @@
-Program Definition test (a b : nat) : { x : nat | x = a + b } :=
- ((a + b) : { x : nat | x = a + b }).
-Proof.
-intros.
-reflexivity.
-Qed.
-
-Print test.
-
-Require Import List.
-
-Program hd_opt (l : list nat) : { x : nat | x <> 0 } :=
- match l with
- nil => 1
- | a :: l => a
- end.
diff --git a/contrib/subtac/test/euclid.v b/contrib/subtac/test/euclid.v
deleted file mode 100644
index 501aa798..00000000
--- a/contrib/subtac/test/euclid.v
+++ /dev/null
@@ -1,24 +0,0 @@
-Require Import Coq.Program.Program.
-Require Import Coq.Arith.Compare_dec.
-Notation "( x & y )" := (existS _ x y) : core_scope.
-
-Require Import Omega.
-
-Program Fixpoint euclid (a : nat) (b : { b : nat | b <> O }) {wf lt a} :
- { q : nat & { r : nat | a = b * q + r /\ r < b } } :=
- if le_lt_dec b a then let (q', r) := euclid (a - b) b in
- (S q' & r)
- else (O & a).
-
-Next Obligation.
- assert(b * S q' = b * q' + b) by auto with arith ; omega.
-Defined.
-
-Program Definition test_euclid : (prod nat nat) := let (q, r) := euclid 4 2 in (q, q).
-
-Eval lazy beta zeta delta iota in test_euclid.
-
-Program Definition testsig (a : nat) : { x : nat & { y : nat | x < y } } :=
- (a & S a).
-
-Check testsig.
diff --git a/contrib/subtac/test/id.v b/contrib/subtac/test/id.v
deleted file mode 100644
index 9ae11088..00000000
--- a/contrib/subtac/test/id.v
+++ /dev/null
@@ -1,46 +0,0 @@
-Require Coq.Arith.Arith.
-
-Require Import Coq.subtac.Utils.
-Program Fixpoint id (n : nat) : { x : nat | x = n } :=
- match n with
- | O => O
- | S p => S (id p)
- end.
-intros ; auto.
-
-pose (subset_simpl (id p)).
-simpl in e.
-unfold p0.
-rewrite e.
-auto.
-Defined.
-
-Check id.
-Print id.
-Extraction id.
-
-Axiom le_gt_dec : forall n m, { n <= m } + { n > m }.
-Require Import Omega.
-
-Program Fixpoint id_if (n : nat) { wf n lt }: { x : nat | x = n } :=
- if le_gt_dec n 0 then 0
- else S (id_if (pred n)).
-intros.
-auto with arith.
-intros.
-pose (subset_simpl (id_if (pred n))).
-simpl in e.
-rewrite e.
-induction n ; auto with arith.
-Defined.
-
-Print id_if_instance.
-Extraction id_if_instance.
-
-Notation "( x & y )" := (@existS _ _ x y) : core_scope.
-
-Program Definition testsig ( a : nat ) : { x : nat & { y : nat | x = y }} :=
- (a & a).
-intros.
-auto.
-Qed.
diff --git a/contrib/subtac/test/measure.v b/contrib/subtac/test/measure.v
deleted file mode 100644
index 4f938f4f..00000000
--- a/contrib/subtac/test/measure.v
+++ /dev/null
@@ -1,20 +0,0 @@
-Notation "( x & y )" := (@existS _ _ x y) : core_scope.
-Unset Printing All.
-Require Import Coq.Arith.Compare_dec.
-
-Require Import Coq.Program.Program.
-
-Fixpoint size (a : nat) : nat :=
- match a with
- 0 => 1
- | S n => S (size n)
- end.
-
-Program Fixpoint test_measure (a : nat) {measure size a} : nat :=
- match a with
- | S (S n) => S (test_measure n)
- | 0 | S 0 => a
- end.
-
-Check test_measure.
-Print test_measure. \ No newline at end of file
diff --git a/contrib/subtac/test/rec.v b/contrib/subtac/test/rec.v
deleted file mode 100644
index aaefd8cc..00000000
--- a/contrib/subtac/test/rec.v
+++ /dev/null
@@ -1,65 +0,0 @@
-Require Import Coq.Arith.Arith.
-Require Import Lt.
-Require Import Omega.
-
-Axiom lt_ge_dec : forall x y : nat, { x < y } + { x >= y }.
-(*Proof.
- intros.
- elim (le_lt_dec y x) ; intros ; auto with arith.
-Defined.
-*)
-Require Import Coq.subtac.FixSub.
-Require Import Wf_nat.
-
-Lemma preda_lt_a : forall a, 0 < a -> pred a < a.
-auto with arith.
-Qed.
-
-Program Fixpoint id_struct (a : nat) : nat :=
- match a with
- 0 => 0
- | S n => S (id_struct n)
- end.
-
-Check struct_rec.
-
- if (lt_ge_dec O a)
- then S (wfrec (pred a))
- else O.
-
-Program Fixpoint wfrec (a : nat) { wf a lt } : nat :=
- if (lt_ge_dec O a)
- then S (wfrec (pred a))
- else O.
-intros.
-apply preda_lt_a ; auto.
-
-Defined.
-
-Extraction wfrec.
-Extraction Inline proj1_sig.
-Extract Inductive bool => "bool" [ "true" "false" ].
-Extract Inductive sumbool => "bool" [ "true" "false" ].
-Extract Inlined Constant lt_ge_dec => "<".
-
-Extraction wfrec.
-Extraction Inline lt_ge_dec le_lt_dec.
-Extraction wfrec.
-
-
-Program Fixpoint structrec (a : nat) { wf a lt } : nat :=
- match a with
- S n => S (structrec n)
- | 0 => 0
- end.
-intros.
-unfold n0.
-omega.
-Defined.
-
-Print structrec.
-Extraction structrec.
-Extraction structrec.
-
-Definition structrec_fun (a : nat) : nat := structrec a (lt_wf a).
-Print structrec_fun.
diff --git a/contrib/subtac/test/take.v b/contrib/subtac/test/take.v
deleted file mode 100644
index 2e17959c..00000000
--- a/contrib/subtac/test/take.v
+++ /dev/null
@@ -1,34 +0,0 @@
-(* -*- coq-prog-args: ("-emacs-U" "-debug") -*- *)
-Require Import JMeq.
-Require Import List.
-Require Import Program.
-
-Set Implicit Arguments.
-Obligations Tactic := idtac.
-
-Print cons.
-
-Program Fixpoint take (A : Set) (l : list A) (n : nat | n <= length l) { struct l } : { l' : list A | length l' = n } :=
- match n with
- | 0 => nil
- | S p =>
- match l with
- | cons hd tl => let rest := take tl p in cons hd rest
- | nil => !
- end
- end.
-
-Require Import Omega.
-Solve All Obligations.
-Next Obligation.
- destruct_call take ; program_simpl.
-Defined.
-
-Next Obligation.
- intros.
- inversion H.
-Defined.
-
-
-
-
diff --git a/contrib/subtac/test/wf.v b/contrib/subtac/test/wf.v
deleted file mode 100644
index 49fec2b8..00000000
--- a/contrib/subtac/test/wf.v
+++ /dev/null
@@ -1,48 +0,0 @@
-Notation "( x & y )" := (@existS _ _ x y) : core_scope.
-Unset Printing All.
-Require Import Coq.Arith.Compare_dec.
-
-Require Import Coq.subtac.Utils.
-
-Ltac one_simpl_hyp :=
- match goal with
- | [H : (`exist _ _ _) = _ |- _] => simpl in H
- | [H : _ = (`exist _ _ _) |- _] => simpl in H
- | [H : (`exist _ _ _) < _ |- _] => simpl in H
- | [H : _ < (`exist _ _ _) |- _] => simpl in H
- | [H : (`exist _ _ _) <= _ |- _] => simpl in H
- | [H : _ <= (`exist _ _ _) |- _] => simpl in H
- | [H : (`exist _ _ _) > _ |- _] => simpl in H
- | [H : _ > (`exist _ _ _) |- _] => simpl in H
- | [H : (`exist _ _ _) >= _ |- _] => simpl in H
- | [H : _ >= (`exist _ _ _) |- _] => simpl in H
- end.
-
-Ltac one_simpl_subtac :=
- destruct_exists ;
- repeat one_simpl_hyp ; simpl.
-
-Ltac simpl_subtac := do 3 one_simpl_subtac ; simpl.
-
-Require Import Omega.
-Require Import Wf_nat.
-
-Program Fixpoint euclid (a : nat) (b : { b : nat | b <> O }) {wf a lt} :
- { q : nat & { r : nat | a = b * q + r /\ r < b } } :=
- if le_lt_dec b a then let (q', r) := euclid (a - b) b in
- (S q' & r)
- else (O & a).
-destruct b ; simpl_subtac.
-omega.
-simpl_subtac.
-assert(x0 * S q' = x0 + x0 * q').
-rewrite <- mult_n_Sm.
-omega.
-rewrite H2 ; omega.
-simpl_subtac.
-split ; auto with arith.
-omega.
-apply lt_wf.
-Defined.
-
-Check euclid_evars_proof. \ No newline at end of file