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|
open Printer
open CErrors
open Util
open Constr
open EConstr
open Vars
open Namegen
open Names
open Pp
open Tacmach
open Termops
open Tacticals
open Tactics
open Indfun_common
open Libnames
open Globnames
open Context.Rel.Declaration
module RelDecl = Context.Rel.Declaration
(* let msgnl = Pp.msgnl *)
(*
let observe strm =
if do_observe ()
then Pp.msg_debug strm
else ()
let do_observe_tac s tac g =
try let v = tac g in (* msgnl (goal ++ fnl () ++ (str s)++(str " ")++(str "finished")); *) v
with e ->
let e = ExplainErr.process_vernac_interp_error e in
let goal = begin try (Printer.pr_goal g) with _ -> assert false end in
msg_debug (str "observation "++ s++str " raised exception " ++
Errors.print e ++ str " on goal " ++ goal );
raise e;;
let observe_tac_stream s tac g =
if do_observe ()
then do_observe_tac s tac g
else tac g
let observe_tac s tac g = observe_tac_stream (str s) tac g
*)
let pr_leconstr_fp =
let sigma, env = Pfedit.get_current_context () in
Printer.pr_leconstr_env env sigma
let debug_queue = Stack.create ()
let rec print_debug_queue e =
if not (Stack.is_empty debug_queue)
then
begin
let lmsg,goal = Stack.pop debug_queue in
let _ =
match e with
| Some e ->
Feedback.msg_debug (hov 0 (lmsg ++ (str " raised exception " ++ CErrors.print e) ++ str " on goal" ++ fnl() ++ goal))
| None ->
begin
Feedback.msg_debug (str " from " ++ lmsg ++ str " on goal" ++ fnl() ++ goal);
end in
print_debug_queue None ;
end
let observe strm =
if do_observe ()
then Feedback.msg_debug strm
else ()
let do_observe_tac s tac g =
let goal = Printer.pr_goal g in
let lmsg = (str "observation : ") ++ s in
Stack.push (lmsg,goal) debug_queue;
try
let v = tac g in
ignore(Stack.pop debug_queue);
v
with reraise ->
let reraise = CErrors.push reraise in
if not (Stack.is_empty debug_queue)
then print_debug_queue (Some (fst (ExplainErr.process_vernac_interp_error reraise)));
iraise reraise
let observe_tac_stream s tac g =
if do_observe ()
then do_observe_tac s tac g
else tac g
let observe_tac s = observe_tac_stream (str s)
let list_chop ?(msg="") n l =
try
List.chop n l
with Failure (msg') ->
failwith (msg ^ msg')
let pop t = Vars.lift (-1) t
let make_refl_eq constructor type_of_t t =
(* let refl_equal_term = Lazy.force refl_equal in *)
mkApp(constructor,[|type_of_t;t|])
type pte_info =
{
proving_tac : (Id.t list -> Tacmach.tactic);
is_valid : constr -> bool
}
type ptes_info = pte_info Id.Map.t
type 'a dynamic_info =
{
nb_rec_hyps : int;
rec_hyps : Id.t list ;
eq_hyps : Id.t list;
info : 'a
}
type body_info = constr dynamic_info
let finish_proof dynamic_infos g =
observe_tac "finish"
(Proofview.V82.of_tactic assumption)
g
let refine c =
Tacmach.refine c
let thin l = Proofview.V82.of_tactic (Tactics.clear l)
let eq_constr sigma u v = EConstr.eq_constr_nounivs sigma u v
let is_trivial_eq sigma t =
let res = try
begin
match EConstr.kind sigma t with
| App(f,[|_;t1;t2|]) when eq_constr sigma f (Lazy.force eq) ->
eq_constr sigma t1 t2
| App(f,[|t1;a1;t2;a2|]) when eq_constr sigma f (jmeq ()) ->
eq_constr sigma t1 t2 && eq_constr sigma a1 a2
| _ -> false
end
with e when CErrors.noncritical e -> false
in
(* observe (str "is_trivial_eq " ++ Printer.pr_lconstr t ++ (if res then str " true" else str " false")); *)
res
let rec incompatible_constructor_terms sigma t1 t2 =
let c1,arg1 = decompose_app sigma t1
and c2,arg2 = decompose_app sigma t2
in
(not (eq_constr sigma t1 t2)) &&
isConstruct sigma c1 && isConstruct sigma c2 &&
(
not (eq_constr sigma c1 c2) ||
List.exists2 (incompatible_constructor_terms sigma) arg1 arg2
)
let is_incompatible_eq sigma t =
let res =
try
match EConstr.kind sigma t with
| App(f,[|_;t1;t2|]) when eq_constr sigma f (Lazy.force eq) ->
incompatible_constructor_terms sigma t1 t2
| App(f,[|u1;t1;u2;t2|]) when eq_constr sigma f (jmeq ()) ->
(eq_constr sigma u1 u2 &&
incompatible_constructor_terms sigma t1 t2)
| _ -> false
with e when CErrors.noncritical e -> false
in
if res then observe (str "is_incompatible_eq " ++ pr_leconstr_fp t);
res
let change_hyp_with_using msg hyp_id t tac : tactic =
fun g ->
let prov_id = pf_get_new_id hyp_id g in
tclTHENS
((* observe_tac msg *) Proofview.V82.of_tactic (assert_by (Name prov_id) t (Proofview.V82.tactic (tclCOMPLETE tac))))
[tclTHENLIST
[
(* observe_tac "change_hyp_with_using thin" *) (thin [hyp_id]);
(* observe_tac "change_hyp_with_using rename " *) (Proofview.V82.of_tactic (rename_hyp [prov_id,hyp_id]))
]] g
exception TOREMOVE
let prove_trivial_eq h_id context (constructor,type_of_term,term) =
let nb_intros = List.length context in
tclTHENLIST
[
tclDO nb_intros (Proofview.V82.of_tactic intro); (* introducing context *)
(fun g ->
let context_hyps =
fst (list_chop ~msg:"prove_trivial_eq : " nb_intros (pf_ids_of_hyps g))
in
let context_hyps' =
(mkApp(constructor,[|type_of_term;term|]))::
(List.map mkVar context_hyps)
in
let to_refine = applist(mkVar h_id,List.rev context_hyps') in
refine to_refine g
)
]
let find_rectype env sigma c =
let (t, l) = decompose_app sigma (Reductionops.whd_betaiotazeta sigma c) in
match EConstr.kind sigma t with
| Ind ind -> (t, l)
| Construct _ -> (t,l)
| _ -> raise Not_found
let isAppConstruct ?(env=Global.env ()) sigma t =
try
let t',l = find_rectype env sigma t in
observe (str "isAppConstruct : " ++ Printer.pr_leconstr_env env sigma t ++ str " -> " ++
Printer.pr_leconstr_env env sigma (applist (t',l)));
true
with Not_found -> false
let nf_betaiotazeta = (* Reductionops.local_strong Reductionops.whd_betaiotazeta *)
Reductionops.clos_norm_flags CClosure.betaiotazeta Environ.empty_env @@ Evd.from_env Environ.empty_env
exception NoChange
let change_eq env sigma hyp_id (context:rel_context) x t end_of_type =
let nochange ?t' msg =
begin
observe (str ("Not treating ( "^msg^" )") ++ pr_leconstr_env env sigma t ++ str " " ++
match t' with None -> str "" | Some t -> Printer.pr_leconstr_env env sigma t );
raise NoChange;
end
in
let eq_constr c1 c2 = Option.has_some (Evarconv.conv env sigma c1 c2) in
if not (noccurn sigma 1 end_of_type)
then nochange "dependent"; (* if end_of_type depends on this term we don't touch it *)
if not (isApp sigma t) then nochange "not an equality";
let f_eq,args = destApp sigma t in
let constructor,t1,t2,t1_typ =
try
if (eq_constr f_eq (Lazy.force eq))
then
let t1 = (args.(1),args.(0))
and t2 = (args.(2),args.(0))
and t1_typ = args.(0)
in
(Lazy.force refl_equal,t1,t2,t1_typ)
else
if (eq_constr f_eq (jmeq ()))
then
(jmeq_refl (),(args.(1),args.(0)),(args.(3),args.(2)),args.(0))
else nochange "not an equality"
with e when CErrors.noncritical e -> nochange "not an equality"
in
if not ((closed0 sigma (fst t1)) && (closed0 sigma (snd t1)))then nochange "not a closed lhs";
let rec compute_substitution sub t1 t2 =
(* observe (str "compute_substitution : " ++ pr_lconstr t1 ++ str " === " ++ pr_lconstr t2); *)
if isRel sigma t2
then
let t2 = destRel sigma t2 in
begin
try
let t1' = Int.Map.find t2 sub in
if not (eq_constr t1 t1') then nochange "twice bound variable";
sub
with Not_found ->
assert (closed0 sigma t1);
Int.Map.add t2 t1 sub
end
else if isAppConstruct sigma t1 && isAppConstruct sigma t2
then
begin
let c1,args1 = find_rectype env sigma t1
and c2,args2 = find_rectype env sigma t2
in
if not (eq_constr c1 c2) then nochange "cannot solve (diff)";
List.fold_left2 compute_substitution sub args1 args2
end
else
if (eq_constr t1 t2) then sub else nochange ~t':(make_refl_eq constructor (Reductionops.whd_all env sigma t1) t2) "cannot solve (diff)"
in
let sub = compute_substitution Int.Map.empty (snd t1) (snd t2) in
let sub = compute_substitution sub (fst t1) (fst t2) in
let end_of_type_with_pop = pop end_of_type in (*the equation will be removed *)
let new_end_of_type =
(* Ugly hack to prevent Map.fold order change between ocaml-3.08.3 and ocaml-3.08.4
Can be safely replaced by the next comment for Ocaml >= 3.08.4
*)
let sub = Int.Map.bindings sub in
List.fold_left (fun end_of_type (i,t) -> liftn 1 i (substnl [t] (i-1) end_of_type))
end_of_type_with_pop
sub
in
let old_context_length = List.length context + 1 in
let witness_fun =
mkLetIn(Anonymous,make_refl_eq constructor t1_typ (fst t1),t,
mkApp(mkVar hyp_id,Array.init old_context_length (fun i -> mkRel (old_context_length - i)))
)
in
let new_type_of_hyp,ctxt_size,witness_fun =
List.fold_left_i
(fun i (end_of_type,ctxt_size,witness_fun) decl ->
try
let witness = Int.Map.find i sub in
if is_local_def decl then anomaly (Pp.str "can not redefine a rel!");
(pop end_of_type,ctxt_size,mkLetIn (RelDecl.get_name decl, witness, RelDecl.get_type decl, witness_fun))
with Not_found ->
(mkProd_or_LetIn decl end_of_type, ctxt_size + 1, mkLambda_or_LetIn decl witness_fun)
)
1
(new_end_of_type,0,witness_fun)
context
in
let new_type_of_hyp =
Reductionops.nf_betaiota env sigma new_type_of_hyp in
let new_ctxt,new_end_of_type =
decompose_prod_n_assum sigma ctxt_size new_type_of_hyp
in
let prove_new_hyp : tactic =
tclTHEN
(tclDO ctxt_size (Proofview.V82.of_tactic intro))
(fun g ->
let all_ids = pf_ids_of_hyps g in
let new_ids,_ = list_chop ctxt_size all_ids in
let to_refine = applist(witness_fun,List.rev_map mkVar new_ids) in
let evm, _ = pf_apply Typing.type_of g to_refine in
tclTHEN (Refiner.tclEVARS evm) (refine to_refine) g
)
in
let simpl_eq_tac =
change_hyp_with_using "prove_pattern_simplification" hyp_id new_type_of_hyp prove_new_hyp
in
(* observe (str "In " ++ Ppconstr.pr_id hyp_id ++ *)
(* str "removing an equation " ++ fnl ()++ *)
(* str "old_typ_of_hyp :=" ++ *)
(* Printer.pr_lconstr_env *)
(* env *)
(* (it_mkProd_or_LetIn ~init:end_of_type ((x,None,t)::context)) *)
(* ++ fnl () ++ *)
(* str "new_typ_of_hyp := "++ *)
(* Printer.pr_lconstr_env env new_type_of_hyp ++ fnl () *)
(* ++ str "old context := " ++ pr_rel_context env context ++ fnl () *)
(* ++ str "new context := " ++ pr_rel_context env new_ctxt ++ fnl () *)
(* ++ str "old type := " ++ pr_lconstr end_of_type ++ fnl () *)
(* ++ str "new type := " ++ pr_lconstr new_end_of_type ++ fnl () *)
(* ); *)
new_ctxt,new_end_of_type,simpl_eq_tac
let is_property sigma (ptes_info:ptes_info) t_x full_type_of_hyp =
if isApp sigma t_x
then
let pte,args = destApp sigma t_x in
if isVar sigma pte && Array.for_all (closed0 sigma) args
then
try
let info = Id.Map.find (destVar sigma pte) ptes_info in
info.is_valid full_type_of_hyp
with Not_found -> false
else false
else false
let isLetIn sigma t =
match EConstr.kind sigma t with
| LetIn _ -> true
| _ -> false
let h_reduce_with_zeta cl =
Proofview.V82.of_tactic (reduce
(Genredexpr.Cbv
{Redops.all_flags
with Genredexpr.rDelta = false;
}) cl)
let rewrite_until_var arg_num eq_ids : tactic =
(* tests if the declares recursive argument is neither a Constructor nor
an applied Constructor since such a form for the recursive argument
will break the Guard when trying to save the Lemma.
*)
let test_var g =
let sigma = project g in
let _,args = destApp sigma (pf_concl g) in
not ((isConstruct sigma args.(arg_num)) || isAppConstruct sigma args.(arg_num))
in
let rec do_rewrite eq_ids g =
if test_var g
then tclIDTAC g
else
match eq_ids with
| [] -> anomaly (Pp.str "Cannot find a way to prove recursive property.");
| eq_id::eq_ids ->
tclTHEN
(tclTRY (Proofview.V82.of_tactic (Equality.rewriteRL (mkVar eq_id))))
(do_rewrite eq_ids)
g
in
do_rewrite eq_ids
let rec_pte_id = Id.of_string "Hrec"
let clean_hyp_with_heq ptes_infos eq_hyps hyp_id env sigma =
let coq_False = EConstr.of_constr (UnivGen.constr_of_global @@ Coqlib.build_coq_False ()) in
let coq_True = EConstr.of_constr (UnivGen.constr_of_global @@ Coqlib.build_coq_True ()) in
let coq_I = EConstr.of_constr (UnivGen.constr_of_global @@ Coqlib.build_coq_I ()) in
let rec scan_type context type_of_hyp : tactic =
if isLetIn sigma type_of_hyp then
let real_type_of_hyp = it_mkProd_or_LetIn type_of_hyp context in
let reduced_type_of_hyp = nf_betaiotazeta real_type_of_hyp in
(* length of context didn't change ? *)
let new_context,new_typ_of_hyp =
decompose_prod_n_assum sigma (List.length context) reduced_type_of_hyp
in
tclTHENLIST
[ h_reduce_with_zeta (Locusops.onHyp hyp_id);
scan_type new_context new_typ_of_hyp ]
else if isProd sigma type_of_hyp
then
begin
let (x,t_x,t') = destProd sigma type_of_hyp in
let actual_real_type_of_hyp = it_mkProd_or_LetIn t' context in
if is_property sigma ptes_infos t_x actual_real_type_of_hyp then
begin
let pte,pte_args = (destApp sigma t_x) in
let (* fix_info *) prove_rec_hyp = (Id.Map.find (destVar sigma pte) ptes_infos).proving_tac in
let popped_t' = pop t' in
let real_type_of_hyp = it_mkProd_or_LetIn popped_t' context in
let prove_new_type_of_hyp =
let context_length = List.length context in
tclTHENLIST
[
tclDO context_length (Proofview.V82.of_tactic intro);
(fun g ->
let context_hyps_ids =
fst (list_chop ~msg:"rec hyp : context_hyps"
context_length (pf_ids_of_hyps g))
in
let rec_pte_id = pf_get_new_id rec_pte_id g in
let to_refine =
applist(mkVar hyp_id,
List.rev_map mkVar (rec_pte_id::context_hyps_ids)
)
in
(* observe_tac "rec hyp " *)
(tclTHENS
(Proofview.V82.of_tactic (assert_before (Name rec_pte_id) t_x))
[
(* observe_tac "prove rec hyp" *) (prove_rec_hyp eq_hyps);
(* observe_tac "prove rec hyp" *)
(refine to_refine)
])
g
)
]
in
tclTHENLIST
[
(* observe_tac "hyp rec" *)
(change_hyp_with_using "rec_hyp_tac" hyp_id real_type_of_hyp prove_new_type_of_hyp);
scan_type context popped_t'
]
end
else if eq_constr sigma t_x coq_False then
begin
(* observe (str "Removing : "++ Ppconstr.pr_id hyp_id++ *)
(* str " since it has False in its preconds " *)
(* ); *)
raise TOREMOVE; (* False -> .. useless *)
end
else if is_incompatible_eq sigma t_x then raise TOREMOVE (* t_x := C1 ... = C2 ... *)
else if eq_constr sigma t_x coq_True (* Trivial => we remove this precons *)
then
(* observe (str "In "++Ppconstr.pr_id hyp_id++ *)
(* str " removing useless precond True" *)
(* ); *)
let popped_t' = pop t' in
let real_type_of_hyp =
it_mkProd_or_LetIn popped_t' context
in
let prove_trivial =
let nb_intro = List.length context in
tclTHENLIST [
tclDO nb_intro (Proofview.V82.of_tactic intro);
(fun g ->
let context_hyps =
fst (list_chop ~msg:"removing True : context_hyps "nb_intro (pf_ids_of_hyps g))
in
let to_refine =
applist (mkVar hyp_id,
List.rev (coq_I::List.map mkVar context_hyps)
)
in
refine to_refine g
)
]
in
tclTHENLIST[
change_hyp_with_using "prove_trivial" hyp_id real_type_of_hyp
((* observe_tac "prove_trivial" *) prove_trivial);
scan_type context popped_t'
]
else if is_trivial_eq sigma t_x
then (* t_x := t = t => we remove this precond *)
let popped_t' = pop t' in
let real_type_of_hyp =
it_mkProd_or_LetIn popped_t' context
in
let hd,args = destApp sigma t_x in
let get_args hd args =
if eq_constr sigma hd (Lazy.force eq)
then (Lazy.force refl_equal,args.(0),args.(1))
else (jmeq_refl (),args.(0),args.(1))
in
tclTHENLIST
[
change_hyp_with_using
"prove_trivial_eq"
hyp_id
real_type_of_hyp
((* observe_tac "prove_trivial_eq" *)
(prove_trivial_eq hyp_id context (get_args hd args)));
scan_type context popped_t'
]
else
begin
try
let new_context,new_t',tac = change_eq env sigma hyp_id context x t_x t' in
tclTHEN
tac
(scan_type new_context new_t')
with NoChange ->
(* Last thing todo : push the rel in the context and continue *)
scan_type (LocalAssum (x,t_x) :: context) t'
end
end
else
tclIDTAC
in
try
scan_type [] (Typing.unsafe_type_of env sigma (mkVar hyp_id)), [hyp_id]
with TOREMOVE ->
thin [hyp_id],[]
let clean_goal_with_heq ptes_infos continue_tac (dyn_infos:body_info) =
fun g ->
let env = pf_env g
and sigma = project g
in
let tac,new_hyps =
List.fold_left (
fun (hyps_tac,new_hyps) hyp_id ->
let hyp_tac,new_hyp =
clean_hyp_with_heq ptes_infos dyn_infos.eq_hyps hyp_id env sigma
in
(tclTHEN hyp_tac hyps_tac),new_hyp@new_hyps
)
(tclIDTAC,[])
dyn_infos.rec_hyps
in
let new_infos =
{ dyn_infos with
rec_hyps = new_hyps;
nb_rec_hyps = List.length new_hyps
}
in
tclTHENLIST
[
tac ;
(* observe_tac "clean_hyp_with_heq continue" *) (continue_tac new_infos)
]
g
let heq_id = Id.of_string "Heq"
let treat_new_case ptes_infos nb_prod continue_tac term dyn_infos =
fun g ->
let nb_first_intro = nb_prod - 1 - dyn_infos.nb_rec_hyps in
tclTHENLIST
[
(* We first introduce the variables *)
tclDO nb_first_intro (Proofview.V82.of_tactic (intro_avoiding (Id.Set.of_list dyn_infos.rec_hyps)));
(* Then the equation itself *)
Proofview.V82.of_tactic (intro_using heq_id);
onLastHypId (fun heq_id -> tclTHENLIST [
(* Then the new hypothesis *)
tclMAP (fun id -> Proofview.V82.of_tactic (introduction id)) dyn_infos.rec_hyps;
observe_tac "after_introduction" (fun g' ->
(* We get infos on the equations introduced*)
let new_term_value_eq = pf_unsafe_type_of g' (mkVar heq_id) in
(* compute the new value of the body *)
let new_term_value =
match EConstr.kind (project g') new_term_value_eq with
| App(f,[| _;_;args2 |]) -> args2
| _ ->
observe (str "cannot compute new term value : " ++ pr_gls g' ++ fnl () ++ str "last hyp is" ++
pr_leconstr_env (pf_env g') (project g') new_term_value_eq
);
anomaly (Pp.str "cannot compute new term value.")
in
let fun_body =
mkLambda(Anonymous,
pf_unsafe_type_of g' term,
Termops.replace_term (project g') term (mkRel 1) dyn_infos.info
)
in
let new_body = pf_nf_betaiota g' (mkApp(fun_body,[| new_term_value |])) in
let new_infos =
{dyn_infos with
info = new_body;
eq_hyps = heq_id::dyn_infos.eq_hyps
}
in
clean_goal_with_heq ptes_infos continue_tac new_infos g'
)])
]
g
let my_orelse tac1 tac2 g =
try
tac1 g
with e when CErrors.noncritical e ->
(* observe (str "using snd tac since : " ++ CErrors.print e); *)
tac2 g
let instantiate_hyps_with_args (do_prove:Id.t list -> tactic) hyps args_id =
let args = Array.of_list (List.map mkVar args_id) in
let instantiate_one_hyp hid =
my_orelse
( (* we instantiate the hyp if possible *)
fun g ->
let prov_hid = pf_get_new_id hid g in
let c = mkApp(mkVar hid,args) in
let evm, _ = pf_apply Typing.type_of g c in
tclTHENLIST[
Refiner.tclEVARS evm;
Proofview.V82.of_tactic (pose_proof (Name prov_hid) c);
thin [hid];
Proofview.V82.of_tactic (rename_hyp [prov_hid,hid])
] g
)
( (*
if not then we are in a mutual function block
and this hyp is a recursive hyp on an other function.
We are not supposed to use it while proving this
principle so that we can trash it
*)
(fun g ->
(* observe (str "Instanciation: removing hyp " ++ Ppconstr.pr_id hid); *)
thin [hid] g
)
)
in
if List.is_empty args_id
then
tclTHENLIST [
tclMAP (fun hyp_id -> h_reduce_with_zeta (Locusops.onHyp hyp_id)) hyps;
do_prove hyps
]
else
tclTHENLIST
[
tclMAP (fun hyp_id -> h_reduce_with_zeta (Locusops.onHyp hyp_id)) hyps;
tclMAP instantiate_one_hyp hyps;
(fun g ->
let all_g_hyps_id =
List.fold_right Id.Set.add (pf_ids_of_hyps g) Id.Set.empty
in
let remaining_hyps =
List.filter (fun id -> Id.Set.mem id all_g_hyps_id) hyps
in
do_prove remaining_hyps g
)
]
let build_proof
(interactive_proof:bool)
(fnames:Constant.t list)
ptes_infos
dyn_infos
: tactic =
let rec build_proof_aux do_finalize dyn_infos : tactic =
fun g ->
let env = pf_env g in
let sigma = project g in
(* observe (str "proving on " ++ Printer.pr_lconstr_env (pf_env g) term);*)
match EConstr.kind sigma dyn_infos.info with
| Case(ci,ct,t,cb) ->
let do_finalize_t dyn_info' =
fun g ->
let t = dyn_info'.info in
let dyn_infos = {dyn_info' with info =
mkCase(ci,ct,t,cb)} in
let g_nb_prod = nb_prod (project g) (pf_concl g) in
let type_of_term = pf_unsafe_type_of g t in
let term_eq =
make_refl_eq (Lazy.force refl_equal) type_of_term t
in
tclTHENLIST
[
Proofview.V82.of_tactic (generalize (term_eq::(List.map mkVar dyn_infos.rec_hyps)));
thin dyn_infos.rec_hyps;
Proofview.V82.of_tactic (pattern_option [Locus.AllOccurrencesBut [1],t] None);
(fun g -> observe_tac "toto" (
tclTHENLIST [Proofview.V82.of_tactic (Simple.case t);
(fun g' ->
let g'_nb_prod = nb_prod (project g') (pf_concl g') in
let nb_instantiate_partial = g'_nb_prod - g_nb_prod in
observe_tac "treat_new_case"
(treat_new_case
ptes_infos
nb_instantiate_partial
(build_proof do_finalize)
t
dyn_infos)
g'
)
]) g
)
]
g
in
build_proof do_finalize_t {dyn_infos with info = t} g
| Lambda(n,t,b) ->
begin
match EConstr.kind sigma (pf_concl g) with
| Prod _ ->
tclTHEN
(Proofview.V82.of_tactic intro)
(fun g' ->
let open Context.Named.Declaration in
let id = pf_last_hyp g' |> get_id in
let new_term =
pf_nf_betaiota g'
(mkApp(dyn_infos.info,[|mkVar id|]))
in
let new_infos = {dyn_infos with info = new_term} in
let do_prove new_hyps =
build_proof do_finalize
{new_infos with
rec_hyps = new_hyps;
nb_rec_hyps = List.length new_hyps
}
in
(* observe_tac "Lambda" *) (instantiate_hyps_with_args do_prove new_infos.rec_hyps [id]) g'
(* build_proof do_finalize new_infos g' *)
) g
| _ ->
do_finalize dyn_infos g
end
| Cast(t,_,_) ->
build_proof do_finalize {dyn_infos with info = t} g
| Const _ | Var _ | Meta _ | Evar _ | Sort _ | Construct _ | Ind _ ->
do_finalize dyn_infos g
| App(_,_) ->
let f,args = decompose_app sigma dyn_infos.info in
begin
match EConstr.kind sigma f with
| App _ -> assert false (* we have collected all the app in decompose_app *)
| Proj _ -> assert false (*FIXME*)
| Var _ | Construct _ | Rel _ | Evar _ | Meta _ | Ind _ | Sort _ | Prod _ ->
let new_infos =
{ dyn_infos with
info = (f,args)
}
in
build_proof_args do_finalize new_infos g
| Const (c,_) when not (List.mem_f Constant.equal c fnames) ->
let new_infos =
{ dyn_infos with
info = (f,args)
}
in
(* Pp.msgnl (str "proving in " ++ pr_lconstr_env (pf_env g) dyn_infos.info); *)
build_proof_args do_finalize new_infos g
| Const _ ->
do_finalize dyn_infos g
| Lambda _ ->
let new_term =
Reductionops.nf_beta env sigma dyn_infos.info in
build_proof do_finalize {dyn_infos with info = new_term}
g
| LetIn _ ->
let new_infos =
{ dyn_infos with info = nf_betaiotazeta dyn_infos.info }
in
tclTHENLIST
[tclMAP
(fun hyp_id ->
h_reduce_with_zeta (Locusops.onHyp hyp_id))
dyn_infos.rec_hyps;
h_reduce_with_zeta Locusops.onConcl;
build_proof do_finalize new_infos
]
g
| Cast(b,_,_) ->
build_proof do_finalize {dyn_infos with info = b } g
| Case _ | Fix _ | CoFix _ ->
let new_finalize dyn_infos =
let new_infos =
{ dyn_infos with
info = dyn_infos.info,args
}
in
build_proof_args do_finalize new_infos
in
build_proof new_finalize {dyn_infos with info = f } g
end
| Fix _ | CoFix _ ->
user_err Pp.(str ( "Anonymous local (co)fixpoints are not handled yet"))
| Proj _ -> user_err Pp.(str "Prod")
| Prod _ -> do_finalize dyn_infos g
| LetIn _ ->
let new_infos =
{ dyn_infos with
info = nf_betaiotazeta dyn_infos.info
}
in
tclTHENLIST
[tclMAP
(fun hyp_id -> h_reduce_with_zeta (Locusops.onHyp hyp_id))
dyn_infos.rec_hyps;
h_reduce_with_zeta Locusops.onConcl;
build_proof do_finalize new_infos
] g
| Rel _ -> anomaly (Pp.str "Free var in goal conclusion!")
and build_proof do_finalize dyn_infos g =
(* observe (str "proving with "++Printer.pr_lconstr dyn_infos.info++ str " on goal " ++ pr_gls g); *)
observe_tac_stream (str "build_proof with " ++ pr_leconstr_fp dyn_infos.info ) (build_proof_aux do_finalize dyn_infos) g
and build_proof_args do_finalize dyn_infos (* f_args' args *) :tactic =
fun g ->
let (f_args',args) = dyn_infos.info in
let tac : tactic =
fun g ->
match args with
| [] ->
do_finalize {dyn_infos with info = f_args'} g
| arg::args ->
(* observe (str "build_proof_args with arg := "++ pr_lconstr_env (pf_env g) arg++ *)
(* fnl () ++ *)
(* pr_goal (Tacmach.sig_it g) *)
(* ); *)
let do_finalize dyn_infos =
let new_arg = dyn_infos.info in
(* tclTRYD *)
(build_proof_args
do_finalize
{dyn_infos with info = (mkApp(f_args',[|new_arg|])), args}
)
in
build_proof do_finalize
{dyn_infos with info = arg }
g
in
(* observe_tac "build_proof_args" *) (tac ) g
in
let do_finish_proof dyn_infos =
(* tclTRYD *) (clean_goal_with_heq
ptes_infos
finish_proof dyn_infos)
in
(* observe_tac "build_proof" *)
(build_proof (clean_goal_with_heq ptes_infos do_finish_proof) dyn_infos)
(* Proof of principles from structural functions *)
type static_fix_info =
{
idx : int;
name : Id.t;
types : types;
offset : int;
nb_realargs : int;
body_with_param : constr;
num_in_block : int
}
let prove_rec_hyp_for_struct fix_info =
(fun eq_hyps -> tclTHEN
(rewrite_until_var (fix_info.idx) eq_hyps)
(fun g ->
let _,pte_args = destApp (project g) (pf_concl g) in
let rec_hyp_proof =
mkApp(mkVar fix_info.name,array_get_start pte_args)
in
refine rec_hyp_proof g
))
let prove_rec_hyp fix_info =
{ proving_tac = prove_rec_hyp_for_struct fix_info
;
is_valid = fun _ -> true
}
let generalize_non_dep hyp g =
(* observe (str "rec id := " ++ Ppconstr.pr_id hyp); *)
let hyps = [hyp] in
let env = Global.env () in
let hyp_typ = pf_unsafe_type_of g (mkVar hyp) in
let to_revert,_ =
let open Context.Named.Declaration in
Environ.fold_named_context_reverse (fun (clear,keep) decl ->
let decl = map_named_decl EConstr.of_constr decl in
let hyp = get_id decl in
if Id.List.mem hyp hyps
|| List.exists (Termops.occur_var_in_decl env (project g) hyp) keep
|| Termops.occur_var env (project g) hyp hyp_typ
|| Termops.is_section_variable hyp (* should be dangerous *)
then (clear,decl::keep)
else (hyp::clear,keep))
~init:([],[]) (pf_env g)
in
(* observe (str "to_revert := " ++ prlist_with_sep spc Ppconstr.pr_id to_revert); *)
tclTHEN
((* observe_tac "h_generalize" *) (Proofview.V82.of_tactic (generalize (List.map mkVar to_revert) )))
((* observe_tac "thin" *) (thin to_revert))
g
let id_of_decl = RelDecl.get_name %> Nameops.Name.get_id
let var_of_decl = id_of_decl %> mkVar
let revert idl =
tclTHEN
(Proofview.V82.of_tactic (generalize (List.map mkVar idl)))
(thin idl)
let generate_equation_lemma evd fnames f fun_num nb_params nb_args rec_args_num =
(* observe (str "nb_args := " ++ str (string_of_int nb_args)); *)
(* observe (str "nb_params := " ++ str (string_of_int nb_params)); *)
(* observe (str "rec_args_num := " ++ str (string_of_int (rec_args_num + 1) )); *)
let f_def = Global.lookup_constant (fst (destConst evd f)) in
let eq_lhs = mkApp(f,Array.init (nb_params + nb_args) (fun i -> mkRel(nb_params + nb_args - i))) in
let (f_body, _) = Option.get (Global.body_of_constant_body f_def) in
let f_body = EConstr.of_constr f_body in
let params,f_body_with_params = decompose_lam_n evd nb_params f_body in
let (_,num),(_,_,bodies) = destFix evd f_body_with_params in
let fnames_with_params =
let params = Array.init nb_params (fun i -> mkRel(nb_params - i)) in
let fnames = List.rev (Array.to_list (Array.map (fun f -> mkApp(f,params)) fnames)) in
fnames
in
(* observe (str "fnames_with_params " ++ prlist_with_sep fnl pr_lconstr fnames_with_params); *)
(* observe (str "body " ++ pr_lconstr bodies.(num)); *)
let f_body_with_params_and_other_fun = substl fnames_with_params bodies.(num) in
(* observe (str "f_body_with_params_and_other_fun " ++ pr_lconstr f_body_with_params_and_other_fun); *)
let eq_rhs = nf_betaiotazeta (mkApp(compose_lam params f_body_with_params_and_other_fun,Array.init (nb_params + nb_args) (fun i -> mkRel(nb_params + nb_args - i)))) in
(* observe (str "eq_rhs " ++ pr_lconstr eq_rhs); *)
let (type_ctxt,type_of_f),evd =
let evd,t = Typing.type_of ~refresh:true (Global.env ()) evd f
in
decompose_prod_n_assum evd
(nb_params + nb_args) t,evd
in
let eqn = mkApp(Lazy.force eq,[|type_of_f;eq_lhs;eq_rhs|]) in
let lemma_type = it_mkProd_or_LetIn eqn type_ctxt in
(* Pp.msgnl (str "lemma type " ++ Printer.pr_lconstr lemma_type ++ fnl () ++ str "f_body " ++ Printer.pr_lconstr f_body); *)
let f_id = Label.to_id (Constant.label (fst (destConst evd f))) in
let prove_replacement =
tclTHENLIST
[
tclDO (nb_params + rec_args_num + 1) (Proofview.V82.of_tactic intro);
observe_tac "" (fun g ->
let rec_id = pf_nth_hyp_id g 1 in
tclTHENLIST
[observe_tac "generalize_non_dep in generate_equation_lemma" (generalize_non_dep rec_id);
observe_tac "h_case" (Proofview.V82.of_tactic (simplest_case (mkVar rec_id)));
(Proofview.V82.of_tactic intros_reflexivity)] g
)
]
in
(* Pp.msgnl (str "lemma type (2) " ++ Printer.pr_lconstr_env (Global.env ()) evd lemma_type); *)
Lemmas.start_proof
(*i The next call to mk_equation_id is valid since we are constructing the lemma
Ensures by: obvious
i*)
(mk_equation_id f_id)
(Decl_kinds.Global, Flags.is_universe_polymorphism (), (Decl_kinds.Proof Decl_kinds.Theorem))
evd
lemma_type
(Lemmas.mk_hook (fun _ _ -> ()));
ignore (Pfedit.by (Proofview.V82.tactic prove_replacement));
Lemmas.save_proof (Vernacexpr.(Proved(Proof_global.Transparent,None)));
evd
let do_replace (evd:Evd.evar_map ref) params rec_arg_num rev_args_id f fun_num all_funs g =
let equation_lemma =
try
let finfos = find_Function_infos (fst (destConst !evd f)) (*FIXME*) in
mkConst (Option.get finfos.equation_lemma)
with (Not_found | Option.IsNone as e) ->
let f_id = Label.to_id (Constant.label (fst (destConst !evd f))) in
(*i The next call to mk_equation_id is valid since we will construct the lemma
Ensures by: obvious
i*)
let equation_lemma_id = (mk_equation_id f_id) in
evd := generate_equation_lemma !evd all_funs f fun_num (List.length params) (List.length rev_args_id) rec_arg_num;
let _ =
match e with
| Option.IsNone ->
let finfos = find_Function_infos (fst (destConst !evd f)) in
update_Function
{finfos with
equation_lemma = Some (match Nametab.locate (qualid_of_ident equation_lemma_id) with
ConstRef c -> c
| _ -> CErrors.anomaly (Pp.str "Not a constant.")
)
}
| _ -> ()
in
(* let res = Constrintern.construct_reference (pf_hyps g) equation_lemma_id in *)
let evd',res =
Evd.fresh_global
(Global.env ()) !evd
(Constrintern.locate_reference (qualid_of_ident equation_lemma_id))
in
evd:=evd';
let sigma, _ = Typing.type_of ~refresh:true (Global.env ()) !evd res in
evd := sigma;
res
in
let nb_intro_to_do = nb_prod (project g) (pf_concl g) in
tclTHEN
(tclDO nb_intro_to_do (Proofview.V82.of_tactic intro))
(
fun g' ->
let just_introduced = nLastDecls nb_intro_to_do g' in
let open Context.Named.Declaration in
let just_introduced_id = List.map get_id just_introduced in
tclTHEN (Proofview.V82.of_tactic (Equality.rewriteLR equation_lemma))
(revert just_introduced_id) g'
)
g
let prove_princ_for_struct (evd:Evd.evar_map ref) interactive_proof fun_num fnames all_funs _nparams : tactic =
fun g ->
let princ_type = pf_concl g in
(* Pp.msgnl (str "princ_type " ++ Printer.pr_lconstr princ_type); *)
(* Pp.msgnl (str "all_funs "); *)
(* Array.iter (fun c -> Pp.msgnl (Printer.pr_lconstr c)) all_funs; *)
let princ_info = compute_elim_sig (project g) princ_type in
let fresh_id =
let avoid = ref (pf_ids_of_hyps g) in
(fun na ->
let new_id =
match na with
Name id -> fresh_id !avoid (Id.to_string id)
| Anonymous -> fresh_id !avoid "H"
in
avoid := new_id :: !avoid;
(Name new_id)
)
in
let fresh_decl = RelDecl.map_name fresh_id in
let princ_info : elim_scheme =
{ princ_info with
params = List.map fresh_decl princ_info.params;
predicates = List.map fresh_decl princ_info.predicates;
branches = List.map fresh_decl princ_info.branches;
args = List.map fresh_decl princ_info.args
}
in
let get_body const =
match Global.body_of_constant const with
| Some (body, _) ->
let env = Global.env () in
let sigma = Evd.from_env env in
Tacred.cbv_norm_flags
(CClosure.RedFlags.mkflags [CClosure.RedFlags.fZETA])
env
sigma
(EConstr.of_constr body)
| None -> user_err Pp.(str "Cannot define a principle over an axiom ")
in
let fbody = get_body fnames.(fun_num) in
let f_ctxt,f_body = decompose_lam (project g) fbody in
let f_ctxt_length = List.length f_ctxt in
let diff_params = princ_info.nparams - f_ctxt_length in
let full_params,princ_params,fbody_with_full_params =
if diff_params > 0
then
let princ_params,full_params =
list_chop diff_params princ_info.params
in
(full_params, (* real params *)
princ_params, (* the params of the principle which are not params of the function *)
substl (* function instantiated with real params *)
(List.map var_of_decl full_params)
f_body
)
else
let f_ctxt_other,f_ctxt_params =
list_chop (- diff_params) f_ctxt in
let f_body = compose_lam f_ctxt_other f_body in
(princ_info.params, (* real params *)
[],(* all params are full params *)
substl (* function instantiated with real params *)
(List.map var_of_decl princ_info.params)
f_body
)
in
observe (str "full_params := " ++
prlist_with_sep spc (RelDecl.get_name %> Nameops.Name.get_id %> Ppconstr.pr_id)
full_params
);
observe (str "princ_params := " ++
prlist_with_sep spc (RelDecl.get_name %> Nameops.Name.get_id %> Ppconstr.pr_id)
princ_params
);
observe (str "fbody_with_full_params := " ++
pr_leconstr_env (Global.env ()) !evd fbody_with_full_params
);
let all_funs_with_full_params =
Array.map (fun f -> applist(f, List.rev_map var_of_decl full_params)) all_funs
in
let fix_offset = List.length princ_params in
let ptes_to_fix,infos =
match EConstr.kind (project g) fbody_with_full_params with
| Fix((idxs,i),(names,typess,bodies)) ->
let bodies_with_all_params =
Array.map
(fun body ->
Reductionops.nf_betaiota (pf_env g) (project g)
(applist(substl (List.rev (Array.to_list all_funs_with_full_params)) body,
List.rev_map var_of_decl princ_params))
)
bodies
in
let info_array =
Array.mapi
(fun i types ->
let types = prod_applist (project g) types (List.rev_map var_of_decl princ_params) in
{ idx = idxs.(i) - fix_offset;
name = Nameops.Name.get_id (fresh_id names.(i));
types = types;
offset = fix_offset;
nb_realargs =
List.length
(fst (decompose_lam (project g) bodies.(i))) - fix_offset;
body_with_param = bodies_with_all_params.(i);
num_in_block = i
}
)
typess
in
let pte_to_fix,rev_info =
List.fold_left_i
(fun i (acc_map,acc_info) decl ->
let pte = RelDecl.get_name decl in
let infos = info_array.(i) in
let type_args,_ = decompose_prod (project g) infos.types in
let nargs = List.length type_args in
let f = applist(mkConst fnames.(i), List.rev_map var_of_decl princ_info.params) in
let first_args = Array.init nargs (fun i -> mkRel (nargs -i)) in
let app_f = mkApp(f,first_args) in
let pte_args = (Array.to_list first_args)@[app_f] in
let app_pte = applist(mkVar (Nameops.Name.get_id pte),pte_args) in
let body_with_param,num =
let body = get_body fnames.(i) in
let body_with_full_params =
Reductionops.nf_betaiota (pf_env g) (project g) (
applist(body,List.rev_map var_of_decl full_params))
in
match EConstr.kind (project g) body_with_full_params with
| Fix((_,num),(_,_,bs)) ->
Reductionops.nf_betaiota (pf_env g) (project g)
(
(applist
(substl
(List.rev
(Array.to_list all_funs_with_full_params))
bs.(num),
List.rev_map var_of_decl princ_params))
),num
| _ -> user_err Pp.(str "Not a mutual block")
in
let info =
{infos with
types = compose_prod type_args app_pte;
body_with_param = body_with_param;
num_in_block = num
}
in
(* observe (str "binding " ++ Ppconstr.pr_id (Nameops.Name.get_id pte) ++ *)
(* str " to " ++ Ppconstr.pr_id info.name); *)
(Id.Map.add (Nameops.Name.get_id pte) info acc_map,info::acc_info)
)
0
(Id.Map.empty,[])
(List.rev princ_info.predicates)
in
pte_to_fix,List.rev rev_info
| _ ->
Id.Map.empty,[]
in
let mk_fixes : tactic =
let pre_info,infos = list_chop fun_num infos in
match pre_info,infos with
| _,[] -> tclIDTAC
| _, this_fix_info::others_infos ->
let other_fix_infos =
List.map
(fun fi -> fi.name,fi.idx + 1 ,fi.types)
(pre_info@others_infos)
in
if List.is_empty other_fix_infos
then
if this_fix_info.idx + 1 = 0
then tclIDTAC (* Someone tries to defined a principle on a fully parametric definition declared as a fixpoint (strange but ....) *)
else
observe_tac_stream (str "h_fix " ++ int (this_fix_info.idx +1) ) (Proofview.V82.of_tactic (fix this_fix_info.name (this_fix_info.idx +1)))
else
Proofview.V82.of_tactic (Tactics.mutual_fix this_fix_info.name (this_fix_info.idx + 1)
other_fix_infos 0)
in
let first_tac : tactic = (* every operations until fix creations *)
tclTHENLIST
[ observe_tac "introducing params" (Proofview.V82.of_tactic (intros_using (List.rev_map id_of_decl princ_info.params)));
observe_tac "introducing predictes" (Proofview.V82.of_tactic (intros_using (List.rev_map id_of_decl princ_info.predicates)));
observe_tac "introducing branches" (Proofview.V82.of_tactic (intros_using (List.rev_map id_of_decl princ_info.branches)));
observe_tac "building fixes" mk_fixes;
]
in
let intros_after_fixes : tactic =
fun gl ->
let ctxt,pte_app = (decompose_prod_assum (project gl) (pf_concl gl)) in
let pte,pte_args = (decompose_app (project gl) pte_app) in
try
let pte =
try destVar (project gl) pte
with DestKO -> anomaly (Pp.str "Property is not a variable.")
in
let fix_info = Id.Map.find pte ptes_to_fix in
let nb_args = fix_info.nb_realargs in
tclTHENLIST
[
(* observe_tac ("introducing args") *) (tclDO nb_args (Proofview.V82.of_tactic intro));
(fun g -> (* replacement of the function by its body *)
let args = nLastDecls nb_args g in
let fix_body = fix_info.body_with_param in
(* observe (str "fix_body := "++ pr_lconstr_env (pf_env gl) fix_body); *)
let open Context.Named.Declaration in
let args_id = List.map get_id args in
let dyn_infos =
{
nb_rec_hyps = -100;
rec_hyps = [];
info =
Reductionops.nf_betaiota (pf_env g) (project g)
(applist(fix_body,List.rev_map mkVar args_id));
eq_hyps = []
}
in
tclTHENLIST
[
observe_tac "do_replace"
(do_replace evd
full_params
(fix_info.idx + List.length princ_params)
(args_id@(List.map (RelDecl.get_name %> Nameops.Name.get_id) princ_params))
(all_funs.(fix_info.num_in_block))
fix_info.num_in_block
all_funs
);
let do_prove =
build_proof
interactive_proof
(Array.to_list fnames)
(Id.Map.map prove_rec_hyp ptes_to_fix)
in
let prove_tac branches =
let dyn_infos =
{dyn_infos with
rec_hyps = branches;
nb_rec_hyps = List.length branches
}
in
observe_tac "cleaning" (clean_goal_with_heq
(Id.Map.map prove_rec_hyp ptes_to_fix)
do_prove
dyn_infos)
in
(* observe (str "branches := " ++ *)
(* prlist_with_sep spc (fun decl -> Ppconstr.pr_id (id_of_decl decl)) princ_info.branches ++ fnl () ++ *)
(* str "args := " ++ prlist_with_sep spc Ppconstr.pr_id args_id *)
(* ); *)
(* observe_tac "instancing" *) (instantiate_hyps_with_args prove_tac
(List.rev_map id_of_decl princ_info.branches)
(List.rev args_id))
]
g
);
] gl
with Not_found ->
let nb_args = min (princ_info.nargs) (List.length ctxt) in
tclTHENLIST
[
tclDO nb_args (Proofview.V82.of_tactic intro);
(fun g -> (* replacement of the function by its body *)
let args = nLastDecls nb_args g in
let open Context.Named.Declaration in
let args_id = List.map get_id args in
let dyn_infos =
{
nb_rec_hyps = -100;
rec_hyps = [];
info =
Reductionops.nf_betaiota (pf_env g) (project g)
(applist(fbody_with_full_params,
(List.rev_map var_of_decl princ_params)@
(List.rev_map mkVar args_id)
));
eq_hyps = []
}
in
let fname = destConst (project g) (fst (decompose_app (project g) (List.hd (List.rev pte_args)))) in
tclTHENLIST
[Proofview.V82.of_tactic (unfold_in_concl [(Locus.AllOccurrences, Names.EvalConstRef (fst fname))]);
let do_prove =
build_proof
interactive_proof
(Array.to_list fnames)
(Id.Map.map prove_rec_hyp ptes_to_fix)
in
let prove_tac branches =
let dyn_infos =
{dyn_infos with
rec_hyps = branches;
nb_rec_hyps = List.length branches
}
in
clean_goal_with_heq
(Id.Map.map prove_rec_hyp ptes_to_fix)
do_prove
dyn_infos
in
instantiate_hyps_with_args prove_tac
(List.rev_map id_of_decl princ_info.branches)
(List.rev args_id)
]
g
)
]
gl
in
tclTHEN
first_tac
intros_after_fixes
g
(* Proof of principles of general functions *)
(* let hrec_id = Recdef.hrec_id *)
(* and acc_inv_id = Recdef.acc_inv_id *)
(* and ltof_ref = Recdef.ltof_ref *)
(* and acc_rel = Recdef.acc_rel *)
(* and well_founded = Recdef.well_founded *)
(* and list_rewrite = Recdef.list_rewrite *)
(* and evaluable_of_global_reference = Recdef.evaluable_of_global_reference *)
let prove_with_tcc tcc_lemma_constr eqs : tactic =
match !tcc_lemma_constr with
| Undefined -> anomaly (Pp.str "No tcc proof !!")
| Value lemma ->
fun gls ->
(* let hid = next_ident_away_in_goal h_id (pf_ids_of_hyps gls) in *)
(* let ids = hid::pf_ids_of_hyps gls in *)
tclTHENLIST
[
(* generalize [lemma]; *)
(* h_intro hid; *)
(* Elim.h_decompose_and (mkVar hid); *)
tclTRY(list_rewrite true eqs);
(* (fun g -> *)
(* let ids' = pf_ids_of_hyps g in *)
(* let ids = List.filter (fun id -> not (List.mem id ids)) ids' in *)
(* rewrite *)
(* ) *)
Proofview.V82.of_tactic (Eauto.gen_eauto (false,5) [] (Some []))
]
gls
| Not_needed -> tclIDTAC
let backtrack_eqs_until_hrec hrec eqs : tactic =
fun gls ->
let eqs = List.map mkVar eqs in
let rewrite =
tclFIRST (List.map (fun x -> Proofview.V82.of_tactic (Equality.rewriteRL x)) eqs )
in
let _,hrec_concl = decompose_prod (project gls) (pf_unsafe_type_of gls (mkVar hrec)) in
let f_app = Array.last (snd (destApp (project gls) hrec_concl)) in
let f = (fst (destApp (project gls) f_app)) in
let rec backtrack : tactic =
fun g ->
let f_app = Array.last (snd (destApp (project g) (pf_concl g))) in
match EConstr.kind (project g) f_app with
| App(f',_) when eq_constr (project g) f' f -> tclIDTAC g
| _ -> tclTHEN rewrite backtrack g
in
backtrack gls
let rec rewrite_eqs_in_eqs eqs =
match eqs with
| [] -> tclIDTAC
| eq::eqs ->
tclTHEN
(tclMAP
(fun id gl ->
observe_tac
(Format.sprintf "rewrite %s in %s " (Id.to_string eq) (Id.to_string id))
(tclTRY (Proofview.V82.of_tactic (Equality.general_rewrite_in true Locus.AllOccurrences
true (* dep proofs also: *) true id (mkVar eq) false)))
gl
)
eqs
)
(rewrite_eqs_in_eqs eqs)
let new_prove_with_tcc is_mes acc_inv hrec tcc_hyps eqs : tactic =
fun gls ->
(tclTHENLIST
[
backtrack_eqs_until_hrec hrec eqs;
(* observe_tac ("new_prove_with_tcc ( applying "^(Id.to_string hrec)^" )" ) *)
(tclTHENS (* We must have exactly ONE subgoal !*)
(Proofview.V82.of_tactic (apply (mkVar hrec)))
[ tclTHENLIST
[
(Proofview.V82.of_tactic (keep (tcc_hyps@eqs)));
(Proofview.V82.of_tactic (apply (Lazy.force acc_inv)));
(fun g ->
if is_mes
then
Proofview.V82.of_tactic (unfold_in_concl [(Locus.AllOccurrences, evaluable_of_global_reference (delayed_force ltof_ref))]) g
else tclIDTAC g
);
observe_tac "rew_and_finish"
(tclTHENLIST
[tclTRY(list_rewrite false (List.map (fun v -> (mkVar v,true)) eqs));
observe_tac "rewrite_eqs_in_eqs" (rewrite_eqs_in_eqs eqs);
(observe_tac "finishing using"
(
tclCOMPLETE(
Eauto.eauto_with_bases
(true,5)
[(fun _ sigma -> (sigma, Lazy.force refl_equal))]
[Hints.Hint_db.empty empty_transparent_state false]
)
)
)
]
)
]
])
])
gls
let is_valid_hypothesis sigma predicates_name =
let predicates_name = List.fold_right Id.Set.add predicates_name Id.Set.empty in
let is_pte typ =
if isApp sigma typ
then
let pte,_ = destApp sigma typ in
if isVar sigma pte
then Id.Set.mem (destVar sigma pte) predicates_name
else false
else false
in
let rec is_valid_hypothesis typ =
is_pte typ ||
match EConstr.kind sigma typ with
| Prod(_,pte,typ') -> is_pte pte && is_valid_hypothesis typ'
| _ -> false
in
is_valid_hypothesis
let prove_principle_for_gen
(f_ref,functional_ref,eq_ref) tcc_lemma_ref is_mes
rec_arg_num rec_arg_type relation gl =
let princ_type = pf_concl gl in
let princ_info = compute_elim_sig (project gl) princ_type in
let fresh_id =
let avoid = ref (pf_ids_of_hyps gl) in
fun na ->
let new_id =
match na with
| Name id -> fresh_id !avoid (Id.to_string id)
| Anonymous -> fresh_id !avoid "H"
in
avoid := new_id :: !avoid;
Name new_id
in
let fresh_decl = map_name fresh_id in
let princ_info : elim_scheme =
{ princ_info with
params = List.map fresh_decl princ_info.params;
predicates = List.map fresh_decl princ_info.predicates;
branches = List.map fresh_decl princ_info.branches;
args = List.map fresh_decl princ_info.args
}
in
let wf_tac =
if is_mes
then
(fun b -> Recdef.tclUSER_if_not_mes tclIDTAC b None)
else fun _ -> prove_with_tcc tcc_lemma_ref []
in
let real_rec_arg_num = rec_arg_num - princ_info.nparams in
let npost_rec_arg = princ_info.nargs - real_rec_arg_num + 1 in
(* observe ( *)
(* str "princ_type := " ++ pr_lconstr princ_type ++ fnl () ++ *)
(* str "princ_info.nparams := " ++ int princ_info.nparams ++ fnl () ++ *)
(* str "princ_info.nargs := " ++ int princ_info.nargs ++ fnl () ++ *)
(* str "rec_arg_num := " ++ int rec_arg_num ++ fnl() ++ *)
(* str "real_rec_arg_num := " ++ int real_rec_arg_num ++ fnl () ++ *)
(* str "npost_rec_arg := " ++ int npost_rec_arg ); *)
let (post_rec_arg,pre_rec_arg) =
Util.List.chop npost_rec_arg princ_info.args
in
let rec_arg_id =
match List.rev post_rec_arg with
| (LocalAssum (Name id,_) | LocalDef (Name id,_,_)) :: _ -> id
| _ -> assert false
in
(* observe (str "rec_arg_id := " ++ pr_lconstr (mkVar rec_arg_id)); *)
let subst_constrs = List.map (get_name %> Nameops.Name.get_id %> mkVar) (pre_rec_arg@princ_info.params) in
let relation = substl subst_constrs relation in
let input_type = substl subst_constrs rec_arg_type in
let wf_thm_id = Nameops.Name.get_id (fresh_id (Name (Id.of_string "wf_R"))) in
let acc_rec_arg_id =
Nameops.Name.get_id (fresh_id (Name (Id.of_string ("Acc_"^(Id.to_string rec_arg_id)))))
in
let revert l =
tclTHEN (Proofview.V82.of_tactic (Tactics.generalize (List.map mkVar l))) (Proofview.V82.of_tactic (clear l))
in
let fix_id = Nameops.Name.get_id (fresh_id (Name hrec_id)) in
let prove_rec_arg_acc g =
((* observe_tac "prove_rec_arg_acc" *)
(tclCOMPLETE
(tclTHEN
(Proofview.V82.of_tactic (assert_by (Name wf_thm_id)
(mkApp (delayed_force well_founded,[|input_type;relation|]))
(Proofview.V82.tactic (fun g -> (* observe_tac "prove wf" *) (tclCOMPLETE (wf_tac is_mes)) g))))
(
(* observe_tac *)
(* "apply wf_thm" *)
Proofview.V82.of_tactic (Tactics.Simple.apply (mkApp(mkVar wf_thm_id,[|mkVar rec_arg_id|])))
)
)
)
)
g
in
let args_ids = List.map (get_name %> Nameops.Name.get_id) princ_info.args in
let lemma =
match !tcc_lemma_ref with
| Undefined -> user_err Pp.(str "No tcc proof !!")
| Value lemma -> EConstr.of_constr lemma
| Not_needed -> EConstr.of_constr (UnivGen.constr_of_global @@ Coqlib.build_coq_I ())
in
(* let rec list_diff del_list check_list = *)
(* match del_list with *)
(* [] -> *)
(* [] *)
(* | f::r -> *)
(* if List.mem f check_list then *)
(* list_diff r check_list *)
(* else *)
(* f::(list_diff r check_list) *)
(* in *)
let tcc_list = ref [] in
let start_tac gls =
let hyps = pf_ids_of_hyps gls in
let hid =
next_ident_away_in_goal
(Id.of_string "prov")
(Id.Set.of_list hyps)
in
tclTHENLIST
[
Proofview.V82.of_tactic (generalize [lemma]);
Proofview.V82.of_tactic (Simple.intro hid);
Proofview.V82.of_tactic (Elim.h_decompose_and (mkVar hid));
(fun g ->
let new_hyps = pf_ids_of_hyps g in
tcc_list := List.rev (List.subtract Id.equal new_hyps (hid::hyps));
if List.is_empty !tcc_list
then
begin
tcc_list := [hid];
tclIDTAC g
end
else thin [hid] g
)
]
gls
in
tclTHENLIST
[
observe_tac "start_tac" start_tac;
h_intros
(List.rev_map (get_name %> Nameops.Name.get_id)
(princ_info.args@princ_info.branches@princ_info.predicates@princ_info.params)
);
(* observe_tac "" *) Proofview.V82.of_tactic (assert_by
(Name acc_rec_arg_id)
(mkApp (delayed_force acc_rel,[|input_type;relation;mkVar rec_arg_id|]))
(Proofview.V82.tactic prove_rec_arg_acc)
);
(* observe_tac "reverting" *) (revert (List.rev (acc_rec_arg_id::args_ids)));
(* (fun g -> observe (Printer.pr_goal (sig_it g) ++ fnl () ++ *)
(* str "fix arg num" ++ int (List.length args_ids + 1) ); tclIDTAC g); *)
(* observe_tac "h_fix " *) (Proofview.V82.of_tactic (fix fix_id (List.length args_ids + 1)));
(* (fun g -> observe (Printer.pr_goal (sig_it g) ++ fnl() ++ pr_lconstr_env (pf_env g ) (pf_unsafe_type_of g (mkVar fix_id) )); tclIDTAC g); *)
h_intros (List.rev (acc_rec_arg_id::args_ids));
Proofview.V82.of_tactic (Equality.rewriteLR (mkConst eq_ref));
(* observe_tac "finish" *) (fun gl' ->
let body =
let _,args = destApp (project gl') (pf_concl gl') in
Array.last args
in
let body_info rec_hyps =
{
nb_rec_hyps = List.length rec_hyps;
rec_hyps = rec_hyps;
eq_hyps = [];
info = body
}
in
let acc_inv =
lazy (
mkApp (
delayed_force acc_inv_id,
[|input_type;relation;mkVar rec_arg_id|]
)
)
in
let acc_inv = lazy (mkApp(Lazy.force acc_inv, [|mkVar acc_rec_arg_id|])) in
let predicates_names =
List.map (get_name %> Nameops.Name.get_id) princ_info.predicates
in
let pte_info =
{ proving_tac =
(fun eqs ->
(* msgnl (str "tcc_list := "++ prlist_with_sep spc Ppconstr.pr_id !tcc_list); *)
(* msgnl (str "princ_info.args := "++ prlist_with_sep spc Ppconstr.pr_id (List.map (fun (na,_,_) -> (Nameops.Name.get_id na)) princ_info.args)); *)
(* msgnl (str "princ_info.params := "++ prlist_with_sep spc Ppconstr.pr_id (List.map (fun (na,_,_) -> (Nameops.Name.get_id na)) princ_info.params)); *)
(* msgnl (str "acc_rec_arg_id := "++ Ppconstr.pr_id acc_rec_arg_id); *)
(* msgnl (str "eqs := "++ prlist_with_sep spc Ppconstr.pr_id eqs); *)
(* observe_tac "new_prove_with_tcc" *)
(new_prove_with_tcc
is_mes acc_inv fix_id
(!tcc_list@(List.map
(get_name %> Nameops.Name.get_id)
(princ_info.args@princ_info.params)
)@ ([acc_rec_arg_id])) eqs
)
);
is_valid = is_valid_hypothesis (project gl') predicates_names
}
in
let ptes_info : pte_info Id.Map.t =
List.fold_left
(fun map pte_id ->
Id.Map.add pte_id
pte_info
map
)
Id.Map.empty
predicates_names
in
let make_proof rec_hyps =
build_proof
false
[f_ref]
ptes_info
(body_info rec_hyps)
in
(* observe_tac "instantiate_hyps_with_args" *)
(instantiate_hyps_with_args
make_proof
(List.map (get_name %> Nameops.Name.get_id) princ_info.branches)
(List.rev args_ids)
)
gl'
)
]
gl
|