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typing.ml
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(**************************************************************************)
(* *)
(* Cubicle *)
(* *)
(* Copyright (C) 2011-2014 *)
(* *)
(* Sylvain Conchon and Alain Mebsout *)
(* Universite Paris-Sud 11 *)
(* *)
(* *)
(* This file is distributed under the terms of the Apache Software *)
(* License version 2.0 *)
(* *)
(**************************************************************************)
open Format
open Util
open Ast
open Types
open Atom
open Stdlib
type error =
| UnknownConstr of Hstring.t
| UnknownVar of Hstring.t
| UnknownGlobal of Hstring.t
| DuplicateAssign of Hstring.t
| DuplicateName of Hstring.t
| DuplicateUpdate of Hstring.t
| UnknownArray of Hstring.t
| UnknownName of Hstring.t
| DuplicateInit of Hstring.t
| NoMoreThanOneArray
| ClashParam of Hstring.t
| MustBeAnArray of Hstring.t
| MustBeOfType of Hstring.t * Hstring.t
| MustBeNum of term
| MustBeOfTypeProc of Hstring.t
| IncompatibleType of Hstring.t list * Hstring.t * Hstring.t list * Hstring.t
| NotATerm of Hstring.t
| WrongNbArgs of Hstring.t * int
| Smt of Smt.error
exception Error of error * loc
let print_htype fmt (args, ty) =
fprintf fmt "%a%a"
(fun fmt -> List.iter (fprintf fmt "%a -> " Hstring.print)) args
Hstring.print ty
let report fmt = function
| UnknownConstr e ->
fprintf fmt "unknown constructor %a" Hstring.print e
| DuplicateAssign s ->
fprintf fmt "duplicate assignment for %a" Hstring.print s
| DuplicateName e ->
fprintf fmt "duplicate name for %a" Hstring.print e
| DuplicateUpdate s ->
fprintf fmt
"duplicate array update for %a (You may want to use a case construct)"
Hstring.print s
| UnknownVar x ->
fprintf fmt "unknown variable %a" Hstring.print x
| UnknownArray a ->
fprintf fmt "unknown array %a" Hstring.print a
| UnknownName s ->
fprintf fmt "unknown name %a" Hstring.print s
| UnknownGlobal s ->
fprintf fmt "unknown global %a" Hstring.print s
| DuplicateInit a ->
fprintf fmt "duplicate initialization for %a" Hstring.print a
| NoMoreThanOneArray ->
fprintf fmt "sorry, no more than one array"
| ClashParam x ->
fprintf fmt "%a already used as a transition's parameter" Hstring.print x
| MustBeAnArray s ->
fprintf fmt "%a must have an array type" Hstring.print s
| MustBeOfType (s, ty) ->
fprintf fmt "%a must be of type %a" Hstring.print s Hstring.print ty
| MustBeNum s ->
fprintf fmt "%a must be of type int or real" Term.print s
| MustBeOfTypeProc s ->
fprintf fmt "%a must be of proc" Hstring.print s
| IncompatibleType (args1, ty1, args2, ty2) ->
fprintf fmt "types %a and %a are not compatible"
print_htype (args1, ty1) print_htype (args2, ty2)
| NotATerm s -> fprintf fmt "%a is not a term" Hstring.print s
| WrongNbArgs (a, nb) -> fprintf fmt "%a must have %d arguments" Hstring.print a nb
| Smt (Smt.DuplicateTypeName s) ->
fprintf fmt "duplicate type name for %a" Hstring.print s
| Smt (Smt.DuplicateSymb e) ->
fprintf fmt "duplicate name for %a" Hstring.print e
| Smt (Smt.UnknownType s) ->
fprintf fmt "unknown type %a" Hstring.print s
| Smt (Smt.UnknownSymb s) ->
fprintf fmt "unknown symbol %a" Hstring.print s
let error e l = raise (Error (e,l))
let rec unique error = function
| [] -> ()
| x :: l -> if Hstring.list_mem x l then error x; unique error l
let unify loc (args_1, ty_1) (args_2, ty_2) =
if not (Hstring.equal ty_1 ty_2) || Hstring.compare_list args_1 args_2 <> 0
then error (IncompatibleType (args_1, ty_1, args_2, ty_2)) loc
let refinements = Hstring.H.create 17
let infer_type x1 x2 =
try
let h1 = match x1 with
| Const _ | Arith _ -> raise Exit
| Elem (h1, _) | Access (h1, _) -> h1
in
let ref_ty, ref_cs =
try Hstring.H.find refinements h1 with Not_found -> [], [] in
match x2 with
| Elem (e2, Constr) -> Hstring.H.add refinements h1 (e2::ref_ty, ref_cs)
| Elem (e2, Glob) -> Hstring.H.add refinements h1 (ref_ty, e2::ref_cs)
| _ -> ()
with Exit -> ()
let refinement_cycles () = (* TODO *) ()
let rec term loc args = function
| Const cs ->
let c, _ = MConst.choose cs in
(match c with
| ConstInt _ -> [], Smt.Type.type_int
| ConstReal _ -> [], Smt.Type.type_real
| ConstName x ->
try Smt.Symbol.type_of x
with Not_found -> error (UnknownName x) loc)
| Elem (e, Var) ->
if Hstring.list_mem e args then [], Smt.Type.type_proc
else begin
try Smt.Symbol.type_of e with Not_found ->
error (UnknownName e) loc
end
| Elem (e, _) -> Smt.Symbol.type_of e
| Arith (x, _) ->
begin
let args, tx = term loc args x in
if not (Hstring.equal tx Smt.Type.type_int)
&& not (Hstring.equal tx Smt.Type.type_real) then
error (MustBeNum x) loc;
args, tx
end
| Access(a, li) ->
let args_a, ty_a =
try Smt.Symbol.type_of a with Not_found -> error (UnknownArray a) loc in
if List.length args_a <> List.length li then
error (WrongNbArgs (a, List.length args_a)) loc
else
List.iter (fun i ->
let ty_i =
if Hstring.list_mem i args then Smt.Type.type_proc
else
try
let ia, tyi = Smt.Symbol.type_of i in
if ia <> [] then error (MustBeOfTypeProc i) loc;
tyi
with Not_found -> error (UnknownName i) loc
in
if args_a = [] then error (MustBeAnArray a) loc;
if not (Hstring.equal ty_i Smt.Type.type_proc) then
error (MustBeOfTypeProc i) loc;
) li;
[], ty_a
let assignment ?(init_variant=false) g x (_, ty) =
if ty = Smt.Type.type_proc
|| ty = Smt.Type.type_bool
|| ty = Smt.Type.type_int
then ()
else
match x with
| Elem (n, Constr) ->
Smt.Variant.assign_constr g n
| Elem (n, _) | Access (n, _) ->
Smt.Variant.assign_var g n;
if init_variant then
Smt.Variant.assign_var n g
| _ -> ()
let atom loc init_variant args = function
| True | False -> ()
| Comp (Elem(g, Glob) as x, Eq, y)
| Comp (y, Eq, (Elem(g, Glob) as x))
| Comp (y, Eq, (Access(g, _) as x))
| Comp (Access(g, _) as x, Eq, y) ->
let ty = term loc args y in
unify loc (term loc args x) ty;
if init_variant then assignment ~init_variant g y ty
| Comp (x, op, y) ->
unify loc (term loc args x) (term loc args y)
| Ite _ -> assert false
let atoms loc ?(init_variant=false) args =
SAtom.iter (atom loc init_variant args)
let init (loc, args, lsa) = List.iter (atoms loc ~init_variant:true args) lsa
let unsafe (loc, args, sa) =
unique (fun x-> error (DuplicateName x) loc) args;
atoms loc args sa
let nondets loc l =
unique (fun c -> error (DuplicateAssign c) loc) l;
List.iter
(fun g ->
try
let args_g, ty_g = Smt.Symbol.type_of g in
if args_g <> [] then error (NotATerm g) loc;
(* Add all values to the subtype *)
List.iter (Smt.Variant.assign_constr g) (Smt.Type.constructors ty_g);
(* if not (Hstring.equal ty_g Smt.Type.type_proc) then *)
(* error (MustBeOfTypeProc g) *)
with Not_found -> error (UnknownGlobal g) loc) l
let assigns loc args =
let dv = ref [] in
List.iter
(fun (g, gu) ->
if Hstring.list_mem g !dv then error (DuplicateAssign g) loc;
let ty_g =
try Smt.Symbol.type_of g
with Not_found -> error (UnknownGlobal g) loc in
begin
match gu with
| UTerm x ->
let ty_x = term loc args x in
unify loc ty_x ty_g;
assignment g x ty_x;
| UCase swts ->
List.iter (fun (sa, x) ->
atoms loc args sa;
let ty_x = term loc args x in
unify loc ty_x ty_g;
assignment g x ty_x;
) swts
end;
dv := g ::!dv)
let switchs loc a args ty_e l =
List.iter
(fun (sa, t) ->
atoms loc args sa;
let ty = term loc args t in
unify loc ty ty_e;
assignment a t ty) l
let updates args =
let dv = ref [] in
List.iter
(fun {up_loc=loc; up_arr=a; up_arg=lj; up_swts=swts} ->
if Hstring.list_mem a !dv then error (DuplicateUpdate a) loc;
List.iter (fun j ->
if Hstring.list_mem j args then error (ClashParam j) loc) lj;
let args_a, ty_a =
try Smt.Symbol.type_of a with Not_found -> error (UnknownArray a) loc
in
if args_a = [] then error (MustBeAnArray a) loc;
dv := a ::!dv;
switchs loc a (lj @ args) ([], ty_a) swts)
let check_lets loc args l =
List.iter
(fun (x, t) ->
let _ = term loc args t in ()
) l
let transitions =
List.iter
(fun ({tr_args = args; tr_loc = loc} as t) ->
unique (fun x-> error (DuplicateName x) loc) args;
atoms loc args t.tr_reqs;
List.iter
(fun (x, cnf) ->
List.iter (atoms loc (x::args)) cnf) t.tr_ureq;
check_lets loc args t.tr_lets;
updates args t.tr_upds;
assigns loc args t.tr_assigns;
nondets loc t.tr_nondets)
let declare_type (loc, (x, y)) =
try Smt.Type.declare x y
with Smt.Error e -> error (Smt e) loc
let declare_symbol loc n args ret =
try Smt.Symbol.declare n args ret
with Smt.Error e -> error (Smt e) loc
let init_global_env s =
List.iter declare_type s.type_defs;
(* patch completeness on Boolean *)
(*let mybool = Hstring.make "mbool" in
let mytrue = Hstring.make "@MTrue" in
let myfalse = Hstring.make "@MFalse" in
let dummypos = Lexing.dummy_pos, Lexing.dummy_pos in
declare_type (dummypos, (mybool, [mytrue; myfalse]));*)
let l = ref [] in
List.iter
(fun (loc, n, t) ->
declare_symbol loc n [] t;
l := (n, t)::!l) s.consts;
List.iter
(fun (loc, n, t) ->
declare_symbol loc n [] t;
l := (n, t)::!l) s.globals;
List.iter
(fun (loc, n, (args, ret)) ->
declare_symbol loc n args ret;
l := (n, ret)::!l) s.arrays;
!l
let init_proc () =
List.iter
(fun n -> Smt.Symbol.declare n [] Smt.Type.type_proc) Variable.procs
(* let inv_in_init ivars {cube = {Cube.vars; litterals=lits}} = *)
(* List.fold_left (fun acc sigma -> *)
(* SAtom.fold (fun a dnsf -> *)
(* let na = Atom.neg (Atom.subst sigma a) in *)
(* SAtom.singleton na :: dnsf *)
(* ) lits acc *)
(* ) [] (Variable.all_permutations vars ivars) *)
(* let add_invs hinit invs = *)
(* Hashtbl.iter (fun nb_procs (cdnsf, cdnaf) -> *)
(* let pvars = Variable.give_procs nb_procs in *)
(* let iinstp = *)
(* List.fold_left (fun (cdnsf, cdnaf) inv -> *)
(* let dnsf = inv_in_init pvars inv in *)
(* if dnsf = [] then cdnsf, cdnaf *)
(* else *)
(* let cdnsf = *)
(* List.map (fun dnf -> *)
(* List.fold_left (fun acc sa -> *)
(* List.fold_left (fun acc invsa -> *)
(* SAtom.union sa invsa :: acc *)
(* ) acc dnsf *)
(* ) [] dnf *)
(* ) cdnsf in *)
(* cdnsf, List.rev_map (List.rev_map ArrayAtom.of_satom) cdnsf *)
(* ) (cdnsf, cdnaf) invs *)
(* in *)
(* Hashtbl.replace hinit nb_procs iinstp *)
(* ) hinit *)
let add_invs hinit invs =
Hashtbl.iter (fun nb_procs init_inst ->
let pvars = Variable.give_procs nb_procs in
let init_invs =
List.fold_left (fun acc inv ->
let ainv = Node.array inv in
let vars_inv = Node.variables inv in
let d = Variable.all_permutations vars_inv pvars in
List.fold_left (fun acc sigma ->
let ai = ArrayAtom.apply_subst sigma ainv in
ai :: acc
) acc d
) [] invs
in
Hashtbl.replace hinit nb_procs { init_inst with init_invs }
) hinit
let mk_init_inst_single sa ar = {
init_cdnf = [[sa]];
init_cdnf_a = [[ar]];
init_invs = [];
}
let mk_init_inst init_cdnf init_cdnf_a =
{ init_cdnf;
init_cdnf_a;
init_invs = [] }
let create_init_instances (iargs, l_init) invs =
let init_instances = Hashtbl.create 11 in
begin
match l_init with
| [init] ->
let sa, cst = SAtom.partition (fun a ->
List.exists (fun z -> has_var z a) iargs) init in
let ar0 = ArrayAtom.of_satom cst in
Hashtbl.add init_instances 0 (mk_init_inst_single cst ar0);
let cpt = ref 1 in
ignore (List.fold_left (fun v_acc v ->
let v_acc = v :: v_acc in
let vars = List.rev v_acc in
let si = List.fold_left (fun si sigma ->
SAtom.union (SAtom.subst sigma sa) si)
cst (Variable.all_instantiations iargs vars) in
let ar = ArrayAtom.of_satom si in
Hashtbl.add init_instances !cpt (mk_init_inst_single si ar);
incr cpt;
v_acc) [] Variable.procs)
| _ ->
let dnf_sa0, dnf_ar0 =
List.fold_left (fun (dnf_sa0, dnf_ar0) sa ->
let sa0 = SAtom.filter (fun a ->
not (List.exists (fun z -> has_var z a) iargs)) sa in
let ar0 = ArrayAtom.of_satom sa0 in
sa0 :: dnf_sa0, ar0 :: dnf_ar0) ([],[]) l_init in
Hashtbl.add init_instances 0 (mk_init_inst [dnf_sa0] [dnf_ar0]);
let cpt = ref 1 in
ignore (List.fold_left (fun v_acc v ->
let v_acc = v :: v_acc in
let vars = List.rev v_acc in
let inst_sa, inst_ar =
List.fold_left (fun (cdnf_sa, cdnf_ar) sigma ->
let dnf_sa, dnf_ar =
List.fold_left (fun (dnf_sa, dnf_ar) init ->
let sa = SAtom.subst sigma init in
try
let sa = Cube.simplify_atoms sa in
let ar = ArrayAtom.of_satom sa in
sa :: dnf_sa, ar :: dnf_ar
with Exit (* sa = False, don't add this conjunct*) ->
dnf_sa, dnf_ar
) ([],[]) l_init in
dnf_sa :: cdnf_sa, dnf_ar :: cdnf_ar
) ([],[]) (Variable.all_instantiations iargs vars) in
let inst = mk_init_inst inst_sa inst_ar in
Hashtbl.add init_instances !cpt inst;
incr cpt;
v_acc) [] Variable.procs)
end;
(* add user supplied invariants to init *)
add_invs init_instances invs;
(* Hashtbl.iter (fun nb (cdnf, _) -> *)
(* eprintf "> %d --->@." nb; *)
(* List.iter (fun dnf -> *)
(* eprintf "[[ %a ]]@." (Pretty.print_list SAtom.print " ||@ ") dnf *)
(* ) cdnf; *)
(* eprintf "@." *)
(* ) init_instances; *)
init_instances
let debug_init_instances insts =
Hashtbl.iter
(fun nbp init_inst ->
Pretty.print_double_line err_formatter ();
eprintf "%d PROCS :\n" nbp;
Pretty.print_line err_formatter ();
List.iter
(fun dnf ->
List.iter (eprintf "( %a ) ||@." SAtom.print_inline) dnf;
eprintf "@.";
) init_inst.init_cdnf;
Pretty.print_double_line err_formatter ();
eprintf "@.";
) insts
let create_node_rename kind vars sa =
let sigma = Variable.build_subst vars Variable.procs in
let c = Cube.subst sigma (Cube.create vars sa) in
let c = Cube.normal_form c in
Node.create ~kind c
let fresh_args ({ tr_args = args; tr_upds = upds} as tr) =
if args = [] then tr
else
let sigma = Variable.build_subst args Variable.freshs in
{ tr with
tr_args = List.map (Variable.subst sigma) tr.tr_args;
tr_reqs = SAtom.subst sigma tr.tr_reqs;
tr_ureq =
List.map
(fun (s, dnf) -> s, List.map (SAtom.subst sigma) dnf) tr.tr_ureq;
tr_assigns =
List.map (function
| x, UTerm t -> x, UTerm (Term.subst sigma t)
| x, UCase swts ->
let swts =
List.map
(fun (sa, t) ->
SAtom.subst sigma sa, Term.subst sigma t) swts in
x, UCase swts
) tr.tr_assigns;
tr_upds =
List.map
(fun ({up_swts = swts} as up) ->
let swts =
List.map
(fun (sa, t) -> SAtom.subst sigma sa, Term.subst sigma t) swts
in
{ up with up_swts = swts })
upds}
let add_tau tr =
(* (\* let tr = fresh_args tr in *\) *)
(* { tr with *)
(* tr_tau = Pre.make_tau tr } *)
let pre,reset_memo = Pre.make_tau tr in
{ tr_info = tr;
tr_tau = pre;
tr_reset = reset_memo;
}
let system s =
let l = init_global_env s in
if not Options.notyping then init s.init;
if Options.subtyping then Smt.Variant.init l;
if not Options.notyping then List.iter unsafe s.unsafe;
if not Options.notyping then List.iter unsafe (List.rev s.invs);
if not Options.notyping then transitions s.trans;
if Options.(subtyping && not murphi) then begin
Smt.Variant.close ();
if Options.debug then Smt.Variant.print ();
end;
let init_woloc = let _,v,i = s.init in v,i in
let invs_woloc =
List.map (fun (_,v,i) -> create_node_rename Inv v i) s.invs in
let unsafe_woloc =
List.map (fun (_,v,u) -> create_node_rename Orig v u) s.unsafe in
let init_instances = create_init_instances init_woloc invs_woloc in
if Options.debug && Options.verbose > 0 then
debug_init_instances init_instances;
{
t_globals = List.map (fun (_,g,_) -> g) s.globals;
t_consts = List.map (fun (_,c,_) -> c) s.consts;
t_arrays = List.map (fun (_,a,_) -> a) s.arrays;
t_init = init_woloc;
t_init_instances = init_instances;
t_invs = invs_woloc;
t_unsafe = unsafe_woloc;
t_trans = List.map add_tau s.trans;
}