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|
(*************************************************************************
PROJET RNRT Calife - 2001
Author: Pierre Crégut - France Télécom R&D
Licence : LGPL version 2.1
*************************************************************************)
open Names
let module_refl_name = "ReflOmegaCore"
let module_refl_path = ["Coq"; "romega"; module_refl_name]
type result =
| Kvar of string
| Kapp of string * EConstr.t list
| Kimp of EConstr.t * EConstr.t
| Kufo
let meaningful_submodule = [ "Z"; "N"; "Pos" ]
let string_of_global r =
let dp = Nametab.dirpath_of_global r in
let prefix = match Names.DirPath.repr dp with
| [] -> ""
| m::_ ->
let s = Names.Id.to_string m in
if Util.String.List.mem s meaningful_submodule then s^"." else ""
in
prefix^(Names.Id.to_string (Nametab.basename_of_global r))
let destructurate sigma t =
let c, args = EConstr.decompose_app sigma t in
let open Constr in
match EConstr.kind sigma c, args with
| Const (sp,_), args ->
Kapp (string_of_global (Globnames.ConstRef sp), args)
| Construct (csp,_) , args ->
Kapp (string_of_global (Globnames.ConstructRef csp), args)
| Ind (isp,_), args ->
Kapp (string_of_global (Globnames.IndRef isp), args)
| Var id, [] -> Kvar(Names.Id.to_string id)
| Prod (Anonymous,typ,body), [] -> Kimp(typ,body)
| _ -> Kufo
exception DestConstApp
let dest_const_apply sigma t =
let open Constr in
let f,args = EConstr.decompose_app sigma t in
let ref =
match EConstr.kind sigma f with
| Const (sp,_) -> Globnames.ConstRef sp
| Construct (csp,_) -> Globnames.ConstructRef csp
| Ind (isp,_) -> Globnames.IndRef isp
| _ -> raise DestConstApp
in Nametab.basename_of_global ref, args
let logic_dir = ["Coq";"Logic";"Decidable"]
let coq_modules =
Coqlib.init_modules @ [logic_dir] @ Coqlib.arith_modules @ Coqlib.zarith_base_modules
@ [["Coq"; "Lists"; "List"]]
@ [module_refl_path]
@ [module_refl_path@["ZOmega"]]
let bin_module = [["Coq";"Numbers";"BinNums"]]
let z_module = [["Coq";"ZArith";"BinInt"]]
let init_constant x =
EConstr.of_constr @@
UnivGen.constr_of_global @@
Coqlib.gen_reference_in_modules "Omega" Coqlib.init_modules x
let constant x =
EConstr.of_constr @@
UnivGen.constr_of_global @@
Coqlib.gen_reference_in_modules "Omega" coq_modules x
let z_constant x =
EConstr.of_constr @@
UnivGen.constr_of_global @@
Coqlib.gen_reference_in_modules "Omega" z_module x
let bin_constant x =
EConstr.of_constr @@
UnivGen.constr_of_global @@
Coqlib.gen_reference_in_modules "Omega" bin_module x
(* Logic *)
let coq_refl_equal = lazy(init_constant "eq_refl")
let coq_and = lazy(init_constant "and")
let coq_not = lazy(init_constant "not")
let coq_or = lazy(init_constant "or")
let coq_True = lazy(init_constant "True")
let coq_False = lazy(init_constant "False")
let coq_I = lazy(init_constant "I")
(* ReflOmegaCore/ZOmega *)
let coq_t_int = lazy (constant "Tint")
let coq_t_plus = lazy (constant "Tplus")
let coq_t_mult = lazy (constant "Tmult")
let coq_t_opp = lazy (constant "Topp")
let coq_t_minus = lazy (constant "Tminus")
let coq_t_var = lazy (constant "Tvar")
let coq_proposition = lazy (constant "proposition")
let coq_p_eq = lazy (constant "EqTerm")
let coq_p_leq = lazy (constant "LeqTerm")
let coq_p_geq = lazy (constant "GeqTerm")
let coq_p_lt = lazy (constant "LtTerm")
let coq_p_gt = lazy (constant "GtTerm")
let coq_p_neq = lazy (constant "NeqTerm")
let coq_p_true = lazy (constant "TrueTerm")
let coq_p_false = lazy (constant "FalseTerm")
let coq_p_not = lazy (constant "Tnot")
let coq_p_or = lazy (constant "Tor")
let coq_p_and = lazy (constant "Tand")
let coq_p_imp = lazy (constant "Timp")
let coq_p_prop = lazy (constant "Tprop")
let coq_s_bad_constant = lazy (constant "O_BAD_CONSTANT")
let coq_s_divide = lazy (constant "O_DIVIDE")
let coq_s_not_exact_divide = lazy (constant "O_NOT_EXACT_DIVIDE")
let coq_s_sum = lazy (constant "O_SUM")
let coq_s_merge_eq = lazy (constant "O_MERGE_EQ")
let coq_s_split_ineq =lazy (constant "O_SPLIT_INEQ")
(* construction for the [extract_hyp] tactic *)
let coq_direction = lazy (constant "direction")
let coq_d_left = lazy (constant "D_left")
let coq_d_right = lazy (constant "D_right")
let coq_e_split = lazy (constant "E_SPLIT")
let coq_e_extract = lazy (constant "E_EXTRACT")
let coq_e_solve = lazy (constant "E_SOLVE")
let coq_interp_sequent = lazy (constant "interp_goal_concl")
let coq_do_omega = lazy (constant "do_omega")
(* Nat *)
let coq_S = lazy(init_constant "S")
let coq_O = lazy(init_constant "O")
let rec mk_nat = function
| 0 -> Lazy.force coq_O
| n -> EConstr.mkApp (Lazy.force coq_S, [| mk_nat (n-1) |])
(* Lists *)
let mkListConst c =
let r =
Coqlib.coq_reference "" ["Init";"Datatypes"] c
in
let inst =
if Global.is_polymorphic r then
fun u -> EConstr.EInstance.make (Univ.Instance.of_array [|u|])
else
fun _ -> EConstr.EInstance.empty
in
fun u -> EConstr.mkConstructU (Globnames.destConstructRef r, inst u)
let coq_cons univ typ = EConstr.mkApp (mkListConst "cons" univ, [|typ|])
let coq_nil univ typ = EConstr.mkApp (mkListConst "nil" univ, [|typ|])
let mk_list univ typ l =
let rec loop = function
| [] -> coq_nil univ typ
| (step :: l) ->
EConstr.mkApp (coq_cons univ typ, [| step; loop l |]) in
loop l
let mk_plist =
let type1lev = UnivGen.new_univ_level () in
fun l -> mk_list type1lev EConstr.mkProp l
let mk_list = mk_list Univ.Level.set
type parse_term =
| Tplus of EConstr.t * EConstr.t
| Tmult of EConstr.t * EConstr.t
| Tminus of EConstr.t * EConstr.t
| Topp of EConstr.t
| Tsucc of EConstr.t
| Tnum of Bigint.bigint
| Tother
type parse_rel =
| Req of EConstr.t * EConstr.t
| Rne of EConstr.t * EConstr.t
| Rlt of EConstr.t * EConstr.t
| Rle of EConstr.t * EConstr.t
| Rgt of EConstr.t * EConstr.t
| Rge of EConstr.t * EConstr.t
| Rtrue
| Rfalse
| Rnot of EConstr.t
| Ror of EConstr.t * EConstr.t
| Rand of EConstr.t * EConstr.t
| Rimp of EConstr.t * EConstr.t
| Riff of EConstr.t * EConstr.t
| Rother
let parse_logic_rel sigma c = match destructurate sigma c with
| Kapp("True",[]) -> Rtrue
| Kapp("False",[]) -> Rfalse
| Kapp("not",[t]) -> Rnot t
| Kapp("or",[t1;t2]) -> Ror (t1,t2)
| Kapp("and",[t1;t2]) -> Rand (t1,t2)
| Kimp(t1,t2) -> Rimp (t1,t2)
| Kapp("iff",[t1;t2]) -> Riff (t1,t2)
| _ -> Rother
(* Binary numbers *)
let coq_Z = lazy (bin_constant "Z")
let coq_xH = lazy (bin_constant "xH")
let coq_xO = lazy (bin_constant "xO")
let coq_xI = lazy (bin_constant "xI")
let coq_Z0 = lazy (bin_constant "Z0")
let coq_Zpos = lazy (bin_constant "Zpos")
let coq_Zneg = lazy (bin_constant "Zneg")
let coq_N0 = lazy (bin_constant "N0")
let coq_Npos = lazy (bin_constant "Npos")
let rec mk_positive n =
if Bigint.equal n Bigint.one then Lazy.force coq_xH
else
let (q,r) = Bigint.euclid n Bigint.two in
EConstr.mkApp
((if Bigint.equal r Bigint.zero
then Lazy.force coq_xO else Lazy.force coq_xI),
[| mk_positive q |])
let mk_N = function
| 0 -> Lazy.force coq_N0
| n -> EConstr.mkApp (Lazy.force coq_Npos,
[| mk_positive (Bigint.of_int n) |])
module type Int = sig
val typ : EConstr.t Lazy.t
val is_int_typ : Proofview.Goal.t -> EConstr.t -> bool
val plus : EConstr.t Lazy.t
val mult : EConstr.t Lazy.t
val opp : EConstr.t Lazy.t
val minus : EConstr.t Lazy.t
val mk : Bigint.bigint -> EConstr.t
val parse_term : Evd.evar_map -> EConstr.t -> parse_term
val parse_rel : Proofview.Goal.t -> EConstr.t -> parse_rel
(* check whether t is built only with numbers and + * - *)
val get_scalar : Evd.evar_map -> EConstr.t -> Bigint.bigint option
end
module Z : Int = struct
let typ = coq_Z
let plus = lazy (z_constant "Z.add")
let mult = lazy (z_constant "Z.mul")
let opp = lazy (z_constant "Z.opp")
let minus = lazy (z_constant "Z.sub")
let recognize_pos sigma t =
let rec loop t =
let f,l = dest_const_apply sigma t in
match Id.to_string f,l with
| "xI",[t] -> Bigint.add Bigint.one (Bigint.mult Bigint.two (loop t))
| "xO",[t] -> Bigint.mult Bigint.two (loop t)
| "xH",[] -> Bigint.one
| _ -> raise DestConstApp
in
try Some (loop t) with DestConstApp -> None
let recognize_Z sigma t =
try
let f,l = dest_const_apply sigma t in
match Id.to_string f,l with
| "Zpos",[t] -> recognize_pos sigma t
| "Zneg",[t] -> Option.map Bigint.neg (recognize_pos sigma t)
| "Z0",[] -> Some Bigint.zero
| _ -> None
with DestConstApp -> None
let mk_Z n =
if Bigint.equal n Bigint.zero then Lazy.force coq_Z0
else if Bigint.is_strictly_pos n then
EConstr.mkApp (Lazy.force coq_Zpos, [| mk_positive n |])
else
EConstr.mkApp (Lazy.force coq_Zneg, [| mk_positive (Bigint.neg n) |])
let mk = mk_Z
let parse_term sigma t =
match destructurate sigma t with
| Kapp("Z.add",[t1;t2]) -> Tplus (t1,t2)
| Kapp("Z.sub",[t1;t2]) -> Tminus (t1,t2)
| Kapp("Z.mul",[t1;t2]) -> Tmult (t1,t2)
| Kapp("Z.opp",[t]) -> Topp t
| Kapp("Z.succ",[t]) -> Tsucc t
| Kapp("Z.pred",[t]) -> Tplus(t, mk_Z (Bigint.neg Bigint.one))
| Kapp(("Zpos"|"Zneg"|"Z0"),_) ->
(match recognize_Z sigma t with Some t -> Tnum t | None -> Tother)
| _ -> Tother
let is_int_typ gl t =
Tacmach.New.pf_apply Reductionops.is_conv gl t (Lazy.force coq_Z)
let parse_rel gl t =
let sigma = Proofview.Goal.sigma gl in
match destructurate sigma t with
| Kapp("eq",[typ;t1;t2]) when is_int_typ gl typ -> Req (t1,t2)
| Kapp("Zne",[t1;t2]) -> Rne (t1,t2)
| Kapp("Z.le",[t1;t2]) -> Rle (t1,t2)
| Kapp("Z.lt",[t1;t2]) -> Rlt (t1,t2)
| Kapp("Z.ge",[t1;t2]) -> Rge (t1,t2)
| Kapp("Z.gt",[t1;t2]) -> Rgt (t1,t2)
| _ -> parse_logic_rel sigma t
let rec get_scalar sigma t =
match destructurate sigma t with
| Kapp("Z.add", [t1;t2]) ->
Option.lift2 Bigint.add (get_scalar sigma t1) (get_scalar sigma t2)
| Kapp ("Z.sub",[t1;t2]) ->
Option.lift2 Bigint.sub (get_scalar sigma t1) (get_scalar sigma t2)
| Kapp ("Z.mul",[t1;t2]) ->
Option.lift2 Bigint.mult (get_scalar sigma t1) (get_scalar sigma t2)
| Kapp("Z.opp", [t]) -> Option.map Bigint.neg (get_scalar sigma t)
| Kapp("Z.succ", [t]) -> Option.map Bigint.add_1 (get_scalar sigma t)
| Kapp("Z.pred", [t]) -> Option.map Bigint.sub_1 (get_scalar sigma t)
| Kapp(("Zpos"|"Zneg"|"Z0"),_) -> recognize_Z sigma t
| _ -> None
end
|
