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|
open Names
open Pp
open Libnames
let mk_prefix pre id = id_of_string (pre^(string_of_id id))
let mk_rel_id = mk_prefix "R_"
let mk_correct_id id = Nameops.add_suffix (mk_rel_id id) "_correct"
let mk_complete_id id = Nameops.add_suffix (mk_rel_id id) "_complete"
let mk_equation_id id = Nameops.add_suffix id "_equation"
let msgnl m =
()
let invalid_argument s = raise (Invalid_argument s)
let fresh_id avoid s = Termops.next_global_ident_away true (id_of_string s) avoid
let fresh_name avoid s = Name (fresh_id avoid s)
let get_name avoid ?(default="H") = function
| Anonymous -> fresh_name avoid default
| Name n -> Name n
let array_get_start a =
try
Array.init
(Array.length a - 1)
(fun i -> a.(i))
with Invalid_argument "index out of bounds" ->
invalid_argument "array_get_start"
let id_of_name = function
Name id -> id
| _ -> raise Not_found
let locate ref =
let (loc,qid) = qualid_of_reference ref in
Nametab.locate qid
let locate_ind ref =
match locate ref with
| IndRef x -> x
| _ -> raise Not_found
let locate_constant ref =
match locate ref with
| ConstRef x -> x
| _ -> raise Not_found
let locate_with_msg msg f x =
try
f x
with
| Not_found -> raise (Util.UserError("", msg))
| e -> raise e
let filter_map filter f =
let rec it = function
| [] -> []
| e::l ->
if filter e
then
(f e) :: it l
else it l
in
it
let chop_rlambda_n =
let rec chop_lambda_n acc n rt =
if n == 0
then List.rev acc,rt
else
match rt with
| Rawterm.RLambda(_,name,k,t,b) -> chop_lambda_n ((name,t,false)::acc) (n-1) b
| Rawterm.RLetIn(_,name,v,b) -> chop_lambda_n ((name,v,true)::acc) (n-1) b
| _ ->
raise (Util.UserError("chop_rlambda_n",
str "chop_rlambda_n: Not enough Lambdas"))
in
chop_lambda_n []
let chop_rprod_n =
let rec chop_prod_n acc n rt =
if n == 0
then List.rev acc,rt
else
match rt with
| Rawterm.RProd(_,name,k,t,b) -> chop_prod_n ((name,t)::acc) (n-1) b
| _ -> raise (Util.UserError("chop_rprod_n",str "chop_rprod_n: Not enough products"))
in
chop_prod_n []
let list_union_eq eq_fun l1 l2 =
let rec urec = function
| [] -> l2
| a::l -> if List.exists (eq_fun a) l2 then urec l else a::urec l
in
urec l1
let list_add_set_eq eq_fun x l =
if List.exists (eq_fun x) l then l else x::l
let const_of_id id =
let _,princ_ref =
qualid_of_reference (Libnames.Ident (Util.dummy_loc,id))
in
try Nametab.locate_constant princ_ref
with Not_found -> Util.error ("cannot find "^ string_of_id id)
let def_of_const t =
match (Term.kind_of_term t) with
Term.Const sp ->
(try (match (Global.lookup_constant sp) with
{Declarations.const_body=Some c} -> Declarations.force c
|_ -> assert false)
with _ -> assert false)
|_ -> assert false
let coq_constant s =
Coqlib.gen_constant_in_modules "RecursiveDefinition"
(Coqlib.init_modules @ Coqlib.arith_modules) s;;
let constant sl s =
constr_of_global
(Nametab.locate (make_qualid(Names.make_dirpath
(List.map id_of_string (List.rev sl)))
(id_of_string s)));;
let find_reference sl s =
(Nametab.locate (make_qualid(Names.make_dirpath
(List.map id_of_string (List.rev sl)))
(id_of_string s)));;
let eq = lazy(coq_constant "eq")
let refl_equal = lazy(coq_constant "refl_equal")
(*****************************************************************)
(* Copy of the standart save mechanism but without the much too *)
(* slow reduction function *)
(*****************************************************************)
open Declarations
open Entries
open Decl_kinds
open Declare
let definition_message id =
Flags.if_verbose message ((string_of_id id) ^ " is defined")
let save with_clean id const (locality,kind) hook =
let {const_entry_body = pft;
const_entry_type = tpo;
const_entry_opaque = opacity } = const in
let l,r = match locality with
| Local when Lib.sections_are_opened () ->
let k = logical_kind_of_goal_kind kind in
let c = SectionLocalDef (pft, tpo, opacity) in
let _ = declare_variable id (Lib.cwd(), c, k) in
(Local, VarRef id)
| Local ->
let k = logical_kind_of_goal_kind kind in
let kn = declare_constant id (DefinitionEntry const, k) in
(Global, ConstRef kn)
| Global ->
let k = logical_kind_of_goal_kind kind in
let kn = declare_constant id (DefinitionEntry const, k) in
(Global, ConstRef kn) in
if with_clean then Pfedit.delete_current_proof ();
hook l r;
definition_message id
let extract_pftreestate pts =
let pfterm,subgoals = Refiner.extract_open_pftreestate pts in
let tpfsigma = Refiner.evc_of_pftreestate pts in
let exl = Evarutil.non_instantiated tpfsigma in
if subgoals <> [] or exl <> [] then
Util.errorlabstrm "extract_proof"
(if subgoals <> [] then
str "Attempt to save an incomplete proof"
else
str "Attempt to save a proof with existential variables still non-instantiated");
let env = Global.env_of_context (Refiner.proof_of_pftreestate pts).Proof_type.goal.Evd.evar_hyps in
env,tpfsigma,pfterm
let nf_betaiotazeta =
let clos_norm_flags flgs env sigma t =
Closure.norm_val (Closure.create_clos_infos flgs env) (Closure.inject (Reductionops.nf_evar sigma t)) in
clos_norm_flags Closure.betaiotazeta
let nf_betaiota =
let clos_norm_flags flgs env sigma t =
Closure.norm_val (Closure.create_clos_infos flgs env) (Closure.inject (Reductionops.nf_evar sigma t)) in
clos_norm_flags Closure.betaiota
let cook_proof do_reduce =
let pfs = Pfedit.get_pftreestate ()
(* and ident = Pfedit.get_current_proof_name () *)
and (ident,strength,concl,hook) = Pfedit.current_proof_statement () in
let env,sigma,pfterm = extract_pftreestate pfs in
let pfterm =
if do_reduce
then nf_betaiota env sigma pfterm
else pfterm
in
(ident,
({ const_entry_body = pfterm;
const_entry_type = Some concl;
const_entry_opaque = false;
const_entry_boxed = false},
strength, hook))
let new_save_named opacity =
let id,(const,persistence,hook) = cook_proof true in
let const = { const with const_entry_opaque = opacity } in
save true id const persistence hook
let get_proof_clean do_reduce =
let result = cook_proof do_reduce in
Pfedit.delete_current_proof ();
result
let with_full_print f a =
let old_implicit_args = Impargs.is_implicit_args ()
and old_strict_implicit_args = Impargs.is_strict_implicit_args ()
and old_contextual_implicit_args = Impargs.is_contextual_implicit_args () in
let old_rawprint = !Flags.raw_print in
Flags.raw_print := true;
Impargs.make_implicit_args false;
Impargs.make_strict_implicit_args false;
Impargs.make_contextual_implicit_args false;
Impargs.make_contextual_implicit_args false;
Dumpglob.pause ();
try
let res = f a in
Impargs.make_implicit_args old_implicit_args;
Impargs.make_strict_implicit_args old_strict_implicit_args;
Impargs.make_contextual_implicit_args old_contextual_implicit_args;
Flags.raw_print := old_rawprint;
Dumpglob.continue ();
res
with
| e ->
Impargs.make_implicit_args old_implicit_args;
Impargs.make_strict_implicit_args old_strict_implicit_args;
Impargs.make_contextual_implicit_args old_contextual_implicit_args;
Flags.raw_print := old_rawprint;
Dumpglob.continue ();
raise e
(**********************)
type function_info =
{
function_constant : constant;
graph_ind : inductive;
equation_lemma : constant option;
correctness_lemma : constant option;
completeness_lemma : constant option;
rect_lemma : constant option;
rec_lemma : constant option;
prop_lemma : constant option;
is_general : bool; (* Has this function been defined using general recursive definition *)
}
(* type function_db = function_info list *)
(* let function_table = ref ([] : function_db) *)
let from_function = ref Cmap.empty
let from_graph = ref Indmap.empty
(*
let rec do_cache_info finfo = function
| [] -> raise Not_found
| (finfo'::finfos as l) ->
if finfo' == finfo then l
else if finfo'.function_constant = finfo.function_constant
then finfo::finfos
else
let res = do_cache_info finfo finfos in
if res == finfos then l else finfo'::l
let cache_Function (_,(finfos)) =
let new_tbl =
try do_cache_info finfos !function_table
with Not_found -> finfos::!function_table
in
if new_tbl != !function_table
then function_table := new_tbl
*)
let cache_Function (_,finfos) =
from_function := Cmap.add finfos.function_constant finfos !from_function;
from_graph := Indmap.add finfos.graph_ind finfos !from_graph
let load_Function _ = cache_Function
let open_Function _ = cache_Function
let subst_Function (_,subst,finfos) =
let do_subst_con c = fst (Mod_subst.subst_con subst c)
and do_subst_ind (kn,i) = (Mod_subst.subst_kn subst kn,i)
in
let function_constant' = do_subst_con finfos.function_constant in
let graph_ind' = do_subst_ind finfos.graph_ind in
let equation_lemma' = Option.smartmap do_subst_con finfos.equation_lemma in
let correctness_lemma' = Option.smartmap do_subst_con finfos.correctness_lemma in
let completeness_lemma' = Option.smartmap do_subst_con finfos.completeness_lemma in
let rect_lemma' = Option.smartmap do_subst_con finfos.rect_lemma in
let rec_lemma' = Option.smartmap do_subst_con finfos.rec_lemma in
let prop_lemma' = Option.smartmap do_subst_con finfos.prop_lemma in
if function_constant' == finfos.function_constant &&
graph_ind' == finfos.graph_ind &&
equation_lemma' == finfos.equation_lemma &&
correctness_lemma' == finfos.correctness_lemma &&
completeness_lemma' == finfos.completeness_lemma &&
rect_lemma' == finfos.rect_lemma &&
rec_lemma' == finfos.rec_lemma &&
prop_lemma' == finfos.prop_lemma
then finfos
else
{ function_constant = function_constant';
graph_ind = graph_ind';
equation_lemma = equation_lemma' ;
correctness_lemma = correctness_lemma' ;
completeness_lemma = completeness_lemma' ;
rect_lemma = rect_lemma' ;
rec_lemma = rec_lemma';
prop_lemma = prop_lemma';
is_general = finfos.is_general
}
let classify_Function (_,infos) = Libobject.Substitute infos
let export_Function infos = Some infos
let discharge_Function (_,finfos) =
let function_constant' = Lib.discharge_con finfos.function_constant
and graph_ind' = Lib.discharge_inductive finfos.graph_ind
and equation_lemma' = Option.smartmap Lib.discharge_con finfos.equation_lemma
and correctness_lemma' = Option.smartmap Lib.discharge_con finfos.correctness_lemma
and completeness_lemma' = Option.smartmap Lib.discharge_con finfos.completeness_lemma
and rect_lemma' = Option.smartmap Lib.discharge_con finfos.rect_lemma
and rec_lemma' = Option.smartmap Lib.discharge_con finfos.rec_lemma
and prop_lemma' = Option.smartmap Lib.discharge_con finfos.prop_lemma
in
if function_constant' == finfos.function_constant &&
graph_ind' == finfos.graph_ind &&
equation_lemma' == finfos.equation_lemma &&
correctness_lemma' == finfos.correctness_lemma &&
completeness_lemma' == finfos.completeness_lemma &&
rect_lemma' == finfos.rect_lemma &&
rec_lemma' == finfos.rec_lemma &&
prop_lemma' == finfos.prop_lemma
then Some finfos
else
Some { function_constant = function_constant' ;
graph_ind = graph_ind' ;
equation_lemma = equation_lemma' ;
correctness_lemma = correctness_lemma' ;
completeness_lemma = completeness_lemma';
rect_lemma = rect_lemma';
rec_lemma = rec_lemma';
prop_lemma = prop_lemma' ;
is_general = finfos.is_general
}
open Term
let pr_info f_info =
str "function_constant := " ++ Printer.pr_lconstr (mkConst f_info.function_constant)++ fnl () ++
str "function_constant_type := " ++
(try Printer.pr_lconstr (Global.type_of_global (ConstRef f_info.function_constant)) with _ -> mt ()) ++ fnl () ++
str "equation_lemma := " ++ (Option.fold_right (fun v acc -> Printer.pr_lconstr (mkConst v)) f_info.equation_lemma (mt ()) ) ++ fnl () ++
str "completeness_lemma :=" ++ (Option.fold_right (fun v acc -> Printer.pr_lconstr (mkConst v)) f_info.completeness_lemma (mt ()) ) ++ fnl () ++
str "correctness_lemma := " ++ (Option.fold_right (fun v acc -> Printer.pr_lconstr (mkConst v)) f_info.correctness_lemma (mt ()) ) ++ fnl () ++
str "rect_lemma := " ++ (Option.fold_right (fun v acc -> Printer.pr_lconstr (mkConst v)) f_info.rect_lemma (mt ()) ) ++ fnl () ++
str "rec_lemma := " ++ (Option.fold_right (fun v acc -> Printer.pr_lconstr (mkConst v)) f_info.rec_lemma (mt ()) ) ++ fnl () ++
str "prop_lemma := " ++ (Option.fold_right (fun v acc -> Printer.pr_lconstr (mkConst v)) f_info.prop_lemma (mt ()) ) ++ fnl () ++
str "graph_ind := " ++ Printer.pr_lconstr (mkInd f_info.graph_ind) ++ fnl ()
let pr_table tb =
let l = Cmap.fold (fun k v acc -> v::acc) tb [] in
Util.prlist_with_sep fnl pr_info l
let in_Function,out_Function =
Libobject.declare_object
{(Libobject.default_object "FUNCTIONS_DB") with
Libobject.cache_function = cache_Function;
Libobject.load_function = load_Function;
Libobject.classify_function = classify_Function;
Libobject.subst_function = subst_Function;
Libobject.export_function = export_Function;
Libobject.discharge_function = discharge_Function
(* Libobject.open_function = open_Function; *)
}
(* Synchronisation with reset *)
let freeze () =
!from_function,!from_graph
let unfreeze (functions,graphs) =
(* Pp.msgnl (str "unfreezing function_table : " ++ pr_table l); *)
from_function := functions;
from_graph := graphs
let init () =
(* Pp.msgnl (str "reseting function_table"); *)
from_function := Cmap.empty;
from_graph := Indmap.empty
let _ =
Summary.declare_summary "functions_db_sum"
{ Summary.freeze_function = freeze;
Summary.unfreeze_function = unfreeze;
Summary.init_function = init;
Summary.survive_module = false;
Summary.survive_section = false }
let find_or_none id =
try Some
(match Nametab.locate (make_short_qualid id) with ConstRef c -> c | _ -> Util.anomaly "Not a constant"
)
with Not_found -> None
let find_Function_infos f =
Cmap.find f !from_function
let find_Function_of_graph ind =
Indmap.find ind !from_graph
let update_Function finfo =
(* Pp.msgnl (pr_info finfo); *)
Lib.add_anonymous_leaf (in_Function finfo)
let add_Function is_general f =
let f_id = id_of_label (con_label f) in
let equation_lemma = find_or_none (mk_equation_id f_id)
and correctness_lemma = find_or_none (mk_correct_id f_id)
and completeness_lemma = find_or_none (mk_complete_id f_id)
and rect_lemma = find_or_none (Nameops.add_suffix f_id "_rect")
and rec_lemma = find_or_none (Nameops.add_suffix f_id "_rec")
and prop_lemma = find_or_none (Nameops.add_suffix f_id "_ind")
and graph_ind =
match Nametab.locate (make_short_qualid (mk_rel_id f_id))
with | IndRef ind -> ind | _ -> Util.anomaly "Not an inductive"
in
let finfos =
{ function_constant = f;
equation_lemma = equation_lemma;
completeness_lemma = completeness_lemma;
correctness_lemma = correctness_lemma;
rect_lemma = rect_lemma;
rec_lemma = rec_lemma;
prop_lemma = prop_lemma;
graph_ind = graph_ind;
is_general = is_general
}
in
update_Function finfos
let pr_table () = pr_table !from_function
(*********************************)
(* Debuging *)
let function_debug = ref false
open Goptions
let function_debug_sig =
{
optsync = false;
optname = "Function debug";
optkey = PrimaryTable("Function_debug");
optread = (fun () -> !function_debug);
optwrite = (fun b -> function_debug := b)
}
let _ = declare_bool_option function_debug_sig
let do_observe () =
!function_debug = true
exception Building_graph of exn
exception Defining_principle of exn
|