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|
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 =
lazy (check_required_library ["Coq";"Logic";"JMeq"];
init_constant ["Logic";"JMeq"] "JMeq")
let jmeq_rec =
lazy (check_required_library ["Coq";"Logic";"JMeq"];
init_constant ["Logic";"JMeq"] "JMeq_rec")
let jmeq_refl =
lazy (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 = 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 true (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 (Lazy.force jmeq_ind, [| typ; x ; typ'; y |])
let mk_JMeq_refl typ x = mkApp (Lazy.force 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))
|