formalsec / smtml / 325

coverage: 42.497% (-0.03%) from 42.529%
325

push

github

filipeom 
signed operations as well

2 of 5 new or added lines in 1 file covered. (40.0%)

97 existing lines in 1 file now uncovered.

725 of 1706 relevant lines covered (42.5%)

7.46 hits per line

Source File
Press 'n' to go to next uncovered line, 'b' for previous

29.57
/src/smtml/expr.ml
1 
(* SPDX-License-Identifier: MIT *)
2 
(* Copyright (C) 2023-2024 formalsec *)
3 
(* Written by the Smtml programmers *)
4 









5



type t = expr Hc.hash_consed










6












7



and expr =










8



  | Val of Value.t










9



  | Ptr of










10



      { base : int32










11



      ; offset : t










12



      }










13



  | Symbol of Symbol.t










14



  | List of t list










15



  | App of Symbol.t * t list










16



  | Unop of Ty.t * Ty.Unop.t * t










17



  | Binop of Ty.t * Ty.Binop.t * t * t










18



  | Triop of Ty.t * Ty.Triop.t * t * t * t










19



  | Relop of Ty.t * Ty.Relop.t * t * t










20



  | Cvtop of Ty.t * Ty.Cvtop.t * t










21



  | Naryop of Ty.t * Ty.Naryop.t * t list










22



  | Extract of t * int * int










23



  | Concat of t * t










24



  | Binder of Binder.t * t list * t










25












26



module Expr = struct










27



  type t = expr










28












29



  let list_eq (l1 : 'a list) (l2 : 'a list) : bool =










30



    if List.compare_lengths l1 l2 = 0 then List.for_all2 phys_equal l1 l2




4





31



    else false




×







32












33



  let equal (e1 : expr) (e2 : expr) : bool =










34



    match (e1, e2) with




578





35



    | Val v1, Val v2 -> Value.equal v1 v2




545





36



    | Ptr { base = b1; offset = o1 }, Ptr { base = b2; offset = o2 } ->




4





37



      Int32.equal b1 b2 && phys_equal o1 o2




4





38



    | Symbol s1, Symbol s2 -> Symbol.equal s1 s2




11





39



    | List l1, List l2 -> list_eq l1 l2




4





40



    | App (s1, l1), App (s2, l2) -> Symbol.equal s1 s2 && list_eq l1 l2




×







41



    | Unop (t1, op1, e1), Unop (t2, op2, e2) ->




×







42



      Ty.equal t1 t2 && Ty.Unop.equal op1 op2 && phys_equal e1 e2




×







43



    | Binop (t1, op1, e1, e3), Binop (t2, op2, e2, e4) ->




12





44



      Ty.equal t1 t2 && Ty.Binop.equal op1 op2 && phys_equal e1 e2




12





45



      && phys_equal e3 e4




12





46



    | Relop (t1, op1, e1, e3), Relop (t2, op2, e2, e4) ->




1





47



      Ty.equal t1 t2 && Ty.Relop.equal op1 op2 && phys_equal e1 e2




1





48



      && phys_equal e3 e4




1





49



    | Triop (t1, op1, e1, e3, e5), Triop (t2, op2, e2, e4, e6) ->




×







50



      Ty.equal t1 t2 && Ty.Triop.equal op1 op2 && phys_equal e1 e2




×







51



      && phys_equal e3 e4 && phys_equal e5 e6




×







52



    | Cvtop (t1, op1, e1), Cvtop (t2, op2, e2) ->




×







53



      Ty.equal t1 t2 && Ty.Cvtop.equal op1 op2 && phys_equal e1 e2




×







54



    | Naryop (t1, op1, l1), Naryop (t2, op2, l2) ->




×







55



      Ty.equal t1 t2 && Ty.Naryop.equal op1 op2 && list_eq l1 l2




×







56



    | Extract (e1, h1, l1), Extract (e2, h2, l2) ->




1





57



      phys_equal e1 e2 && h1 = h2 && l1 = l2




1





58



    | Concat (e1, e3), Concat (e2, e4) -> phys_equal e1 e2 && phys_equal e3 e4




×







59



    | Binder (binder1, vars1, e1), Binder (binder2, vars2, e2) ->




×







60



      Binder.equal binder1 binder2 && list_eq vars1 vars2 && phys_equal e1 e2




×







61



    | ( ( Val _ | Ptr _ | Symbol _ | List _ | App _ | Unop _ | Binop _ | Triop _




×







62



        | Relop _ | Cvtop _ | Naryop _ | Extract _ | Concat _ | Binder _ )




×







63



      , _ ) ->










64



      false










65












66



  let hash (e : expr) : int =










67



    let h x = Hashtbl.hash x in




838





68



    match e with










69



    | Val v -> h v




723





70



    | Ptr { base; offset } -> h (base, offset.tag)




12





71



    | Symbol s -> h s




23





72



    | List v -> h v




16





73



    | App (x, es) -> h (x, es)




×







74



    | Unop (ty, op, e) -> h (ty, op, e.tag)




4





75



    | Cvtop (ty, op, e) -> h (ty, op, e.tag)




2





76



    | Binop (ty, op, e1, e2) -> h (ty, op, e1.tag, e2.tag)




34





77



    | Relop (ty, op, e1, e2) -> h (ty, op, e1.tag, e2.tag)




3





78



    | Triop (ty, op, e1, e2, e3) -> h (ty, op, e1.tag, e2.tag, e3.tag)




×







79



    | Naryop (ty, op, es) -> h (ty, op, es)




×







80



    | Extract (e, hi, lo) -> h (e.tag, hi, lo)




15





81



    | Concat (e1, e2) -> h (e1.tag, e2.tag)




6





82



    | Binder (b, vars, e) -> h (b, vars, e.tag)




×







83



end










84












85



module Hc = Hc.Make [@inlined hint] (Expr)










86












87



let equal (hte1 : t) (hte2 : t) = phys_equal hte1 hte2 [@@inline]




214





88












89



let hash (hte : t) = hte.tag [@@inline]




6





90












91



module Key = struct










92



  type nonrec t = t










93












94



  let to_int hte = hash hte




×







95



end










96












97



let[@inline] make e = Hc.hashcons e




705





98












99



let[@inline] view (hte : t) = hte.node




491





100












101



let[@inline] compare (hte1 : t) (hte2 : t) = compare hte1.tag hte2.tag




×







102












103



let symbol s = make (Symbol s)




17





104












105



let is_num (e : t) = match view e with Val (Num _) -> true | _ -> false




×







106












107



(** The return type of an expression *)










108



let rec ty (hte : t) : Ty.t =










109



  match view hte with




5





110



  | Val x -> Value.type_of x




×







111



  | Ptr _ -> Ty_bitv 32




×







112



  | Symbol x -> Symbol.type_of x




2





113



  | List _ -> Ty_list




×







114



  | App _ -> Ty_app




×







115



  | Unop (ty, _, _) -> ty




×







116



  | Binop (ty, _, _, _) -> ty




×







117



  | Triop (_, Ite, _, hte1, hte2) ->




×







118



    let ty1 = ty hte1 in










119



    let ty2 = ty hte2 in




×







120



    assert (Ty.equal ty1 ty2);




×







121



    ty1










122



  | Triop (ty, _, _, _, _) -> ty




×







123



  | Relop (ty, _, _, _) -> ty




×







124



  | Cvtop (_, (Zero_extend m | Sign_extend m), hte) -> (




×







125



    match ty hte with Ty_bitv n -> Ty_bitv (n + m) | _ -> assert false )




1





126



  | Cvtop (ty, _, _) -> ty




×







127



  | Naryop (ty, _, _) -> ty




×







128



  | Extract (_, h, l) -> Ty_bitv ((h - l) * 8)




2





129



  | Concat (e1, e2) -> (




×







130



    match (ty e1, ty e2) with




×







131



    | Ty_bitv n1, Ty_bitv n2 -> Ty_bitv (n1 + n2)




×







132



    | t1, t2 ->




×







133



      Fmt.failwith "Invalid concat of (%a) with (%a)" Ty.pp t1 Ty.pp t2 )










134



  | Binder (_, _, e) -> ty e




×







135












136



let rec is_symbolic (v : t) : bool =










137



  match view v with




×







138



  | Val _ -> false




×







139



  | Symbol _ -> true




×







140



  | Ptr { offset; _ } -> is_symbolic offset




×







141



  | List vs -> List.exists is_symbolic vs




×







142



  | App (_, vs) -> List.exists is_symbolic vs




×







143



  | Unop (_, _, v) -> is_symbolic v




×







144



  | Binop (_, _, v1, v2) -> is_symbolic v1 || is_symbolic v2




×







145



  | Triop (_, _, v1, v2, v3) ->




×







146



    is_symbolic v1 || is_symbolic v2 || is_symbolic v3




×







147



  | Cvtop (_, _, v) -> is_symbolic v




×







148



  | Relop (_, _, v1, v2) -> is_symbolic v1 || is_symbolic v2




×







149



  | Naryop (_, _, vs) -> List.exists is_symbolic vs




×







150



  | Extract (e, _, _) -> is_symbolic e




×







151



  | Concat (e1, e2) -> is_symbolic e1 || is_symbolic e2




×







152



  | Binder (_, _, e) -> is_symbolic e




×







153












154



let get_symbols (hte : t list) =










155



  let tbl = Hashtbl.create 64 in




×







156



  let rec symbols (hte : t) =




×







157



    match view hte with




×







158



    | Val _ -> ()




×







159



    | Ptr { offset; _ } -> symbols offset




×







160



    | Symbol s -> Hashtbl.replace tbl s ()




×







161



    | List es -> List.iter symbols es




×







162



    | App (_, es) -> List.iter symbols es




×







163



    | Unop (_, _, e1) -> symbols e1




×







164



    | Binop (_, _, e1, e2) ->




×







165



      symbols e1;










166



      symbols e2




×







167



    | Triop (_, _, e1, e2, e3) ->




×







168



      symbols e1;










169



      symbols e2;




×







170



      symbols e3




×







171



    | Relop (_, _, e1, e2) ->




×







172



      symbols e1;










173



      symbols e2




×







174



    | Cvtop (_, _, e) -> symbols e




×







175



    | Naryop (_, _, es) -> List.iter symbols es




×







176



    | Extract (e, _, _) -> symbols e




×







177



    | Concat (e1, e2) ->




×







178



      symbols e1;










179



      symbols e2




×







180



    | Binder (_, vars, e) ->




×







181



      List.iter symbols vars;










182



      symbols e




×







183



  in










184



  List.iter symbols hte;










185



  Hashtbl.fold (fun k () acc -> k :: acc) tbl []




×







186












187



let negate_relop (hte : t) : (t, string) Result.t =










188



  let e =




×







189



    match view hte with










190



    | Relop (ty, Eq, e1, e2) -> Ok (Relop (ty, Ne, e1, e2))




×







191



    | Relop (ty, Ne, e1, e2) -> Ok (Relop (ty, Eq, e1, e2))




×







192



    | Relop (ty, Lt, e1, e2) -> Ok (Relop (ty, Ge, e1, e2))




×







193



    | Relop (ty, LtU, e1, e2) -> Ok (Relop (ty, GeU, e1, e2))




×







194



    | Relop (ty, Le, e1, e2) -> Ok (Relop (ty, Gt, e1, e2))




×







195



    | Relop (ty, LeU, e1, e2) -> Ok (Relop (ty, GtU, e1, e2))




×







196



    | Relop (ty, Gt, e1, e2) -> Ok (Relop (ty, Le, e1, e2))




×







197



    | Relop (ty, GtU, e1, e2) -> Ok (Relop (ty, LeU, e1, e2))




×







198



    | Relop (ty, Ge, e1, e2) -> Ok (Relop (ty, Lt, e1, e2))




×







199



    | Relop (ty, GeU, e1, e2) -> Ok (Relop (ty, LtU, e1, e2))




×







200



    | _ -> Error "negate_relop: not a relop."




×







201



  in










202



  Result.map make e










203












204



module Set = struct










205



  include PatriciaTree.MakeHashconsedSet (Key) ()










206












207



  let hash = to_int










208












209



  let get_symbols (set : t) =










210



    let tbl = Hashtbl.create 64 in




×







211



    let rec symbols hte =




×







212



      match view hte with




×







213



      | Val _ -> ()




×







214



      | Ptr { offset; _ } -> symbols offset




×







215



      | Symbol s -> Hashtbl.replace tbl s ()




×







216



      | List es -> List.iter symbols es




×







217



      | App (_, es) -> List.iter symbols es




×







218



      | Unop (_, _, e1) -> symbols e1




×







219



      | Binop (_, _, e1, e2) ->




×







220



        symbols e1;










221



        symbols e2




×







222



      | Triop (_, _, e1, e2, e3) ->




×







223



        symbols e1;










224



        symbols e2;




×







225



        symbols e3




×







226



      | Relop (_, _, e1, e2) ->




×







227



        symbols e1;










228



        symbols e2




×







229



      | Cvtop (_, _, e) -> symbols e




×







230



      | Naryop (_, _, es) -> List.iter symbols es




×







231



      | Extract (e, _, _) -> symbols e




×







232



      | Concat (e1, e2) ->




×







233



        symbols e1;










234



        symbols e2




×







235



      | Binder (_, vars, e) ->




×







236



        List.iter symbols vars;










237



        symbols e




×







238



    in










239



    iter symbols set;










240



    Hashtbl.fold (fun k () acc -> k :: acc) tbl []




×







241



end










242












243



module Pp = struct










244



  let rec pp fmt (hte : t) =










245



    match view hte with




×







246



    | Val v -> Value.pp fmt v




×







247



    | Ptr { base; offset } -> Fmt.pf fmt "(Ptr (i32 %ld) %a)" base pp offset




×







248



    | Symbol s -> Fmt.pf fmt "@[<hov 1>%a@]" Symbol.pp s




×







249



    | List v -> Fmt.pf fmt "@[<hov 1>[%a]@]" (Fmt.list ~sep:Fmt.comma pp) v




×







250



    | App (s, v) ->




×







251



      Fmt.pf fmt "@[<hov 1>(%a@ %a)@]" Symbol.pp s










252



        (Fmt.list ~sep:Fmt.comma pp)




×







253



        v










254



    | Unop (ty, op, e) ->




×







255



      Fmt.pf fmt "@[<hov 1>(%a.%a@ %a)@]" Ty.pp ty Ty.Unop.pp op pp e










256



    | Binop (ty, op, e1, e2) ->




×







257



      Fmt.pf fmt "@[<hov 1>(%a.%a@ %a@ %a)@]" Ty.pp ty Ty.Binop.pp op pp e1 pp










258



        e2










259



    | Triop (ty, op, e1, e2, e3) ->




×







260



      Fmt.pf fmt "@[<hov 1>(%a.%a@ %a@ %a@ %a)@]" Ty.pp ty Ty.Triop.pp op pp e1










261



        pp e2 pp e3










262



    | Relop (ty, op, e1, e2) ->




×







263



      Fmt.pf fmt "@[<hov 1>(%a.%a@ %a@ %a)@]" Ty.pp ty Ty.Relop.pp op pp e1 pp










264



        e2










265



    | Cvtop (ty, op, e) ->




×







266



      Fmt.pf fmt "@[<hov 1>(%a.%a@ %a)@]" Ty.pp ty Ty.Cvtop.pp op pp e










267



    | Naryop (ty, op, es) ->




×







268



      Fmt.pf fmt "@[<hov 1>(%a.%a@ (%a))@]" Ty.pp ty Ty.Naryop.pp op










269



        (Fmt.list ~sep:Fmt.comma pp)




×







270



        es










271



    | Extract (e, h, l) ->




×







272



      Fmt.pf fmt "@[<hov 1>(extract@ %a@ %d@ %d)@]" pp e l h










273



    | Concat (e1, e2) -> Fmt.pf fmt "@[<hov 1>(++@ %a@ %a)@]" pp e1 pp e2




×







274



    | Binder (b, vars, e) ->




×







275



      Fmt.pf fmt "@[<hov 1>(%a@ (%a)@ %a)@]" Binder.pp b










276



        (Fmt.list ~sep:Fmt.sp pp) vars pp e




×







277












278



  let pp_list fmt (es : t list) = Fmt.hovbox (Fmt.list ~sep:Fmt.comma pp) fmt es




×







279












280



  let pp_smt fmt (es : t list) : unit =










281



    let pp_symbols fmt syms =




×







282



      Fmt.list ~sep:Fmt.semi




×







283



        (fun fmt sym ->










284



          let t = Symbol.type_of sym in




×







285



          Fmt.pf fmt "(let-const %a %a)" Symbol.pp sym Ty.pp t )




×







286



        fmt syms










287



    in










288



    let pp_asserts fmt es =










289



      Fmt.list ~sep:Fmt.semi




×







290



        (fun fmt e -> Fmt.pf fmt "(assert @[<h 2>%a@])" pp e)




×







291



        fmt es










292



    in










293



    let syms = get_symbols es in










294



    if List.length syms > 0 then Fmt.pf fmt "%a@\n" pp_symbols syms;




×







295



    if List.length es > 0 then Fmt.pf fmt "%a@\n" pp_asserts es;




×







296



    Fmt.string fmt "(check-sat)"




×







297



end










298












299



let pp = Pp.pp










300












301



let pp_list = Pp.pp_list










302












303



let pp_smt = Pp.pp_smt










304












305



let to_string e = Fmt.str "%a" pp e




×







306












307



let value (v : Value.t) : t = make (Val v) [@@inline]




631





308












309



let ptr base offset = make (Ptr { base; offset })




8





310












311



let list l = make (List l)




5





312












313



let app symbol args = make (App (symbol, args))




×







314












315



let[@inline] binder bt vars expr = make (Binder (bt, vars, expr))




×







316












317



let let_in vars body = binder Let_in vars body




×







318












319



let forall vars body = binder Forall vars body




×







320












321



let exists vars body = binder Exists vars body




×







322












323



let raw_unop ty op hte = make (Unop (ty, op, hte)) [@@inline]




2





324












325



let unop ty op hte =










326



  match (op, view hte) with




32





327



  | Ty.Unop.(Regexp_loop _ | Regexp_star), _ -> raw_unop ty op hte




×







328



  | _, Val v -> value (Eval.unop ty op v)




23





329



  | Not, Unop (_, Not, hte') -> hte'




1






UNCOV

330



  | Not, Relop (t, Eq, a,b) -> make (Relop (t, Ne, a, b))




×








NEW


331



  | Not, Relop (t, Ne, a,b) -> make (Relop (t, Eq, a, b))




×







332



  | Neg, Unop (_, Neg, hte') -> hte'




1






UNCOV

333



  | Trim, Cvtop (Ty_real, ToString, _) -> hte




×







334



  | Head, List (hd :: _) -> hd




1





335



  | Tail, List (_ :: tl) -> make (List tl)




1





336



  | Reverse, List es -> make (List (List.rev es))




2





337



  | Length, List es -> value (Int (List.length es))




1





338



  | _ -> raw_unop ty op hte




2





339












340



let raw_binop ty op hte1 hte2 = make (Binop (ty, op, hte1, hte2)) [@@inline]




23





341












342



let rec binop ty op hte1 hte2 =










343



  match (op, view hte1, view hte2) with




96






UNCOV

344



  | Ty.Binop.(String_in_re | Regexp_range), _, _ -> raw_binop ty op hte1 hte2




×







345



  | op, Val v1, Val v2 -> value (Eval.binop ty op v1 v2)




67





346



  | Sub, Ptr { base = b1; offset = os1 }, Ptr { base = b2; offset = os2 } ->




1





347



    if Int32.equal b1 b2 then binop ty Sub os1 os2




1






UNCOV

348



    else raw_binop ty op hte1 hte2




×







349



  | Add, Ptr { base; offset }, _ ->




1





350



    ptr base (binop (Ty_bitv 32) Add offset hte2)




1





351



  | Sub, Ptr { base; offset }, _ ->




1





352



    ptr base (binop (Ty_bitv 32) Sub offset hte2)




1





353



  | Rem, Ptr { base; offset }, _ ->




1





354



    let rhs = value (Num (I32 base)) in










355



    let addr = binop (Ty_bitv 32) Add rhs offset in




1





356



    binop ty Rem addr hte2




1





357



  | Add, _, Ptr { base; offset } ->




1





358



    ptr base (binop (Ty_bitv 32) Add offset hte1)




1





359



  | Sub, _, Ptr { base; offset } ->




×







360



    binop ty Sub hte1 (binop (Ty_bitv 32) Add (value (Num (I32 base))) offset)




×







361



  | (Add | Or), Val (Num (I32 0l)), _ -> hte2




×







362



  | (And | Div | DivU | Mul | Rem | RemU), Val (Num (I32 0l)), _ -> hte1




×







363



  | (Add | Or), _, Val (Num (I32 0l)) -> hte1




×








UNCOV

364



  | (And | Mul), _, Val (Num (I32 0l)) -> hte2




×







365



  | Add, Binop (ty, Add, x, { node = Val v1; _ }), Val v2 ->




1





366



    let v = value (Eval.binop ty Add v1 v2) in




1





367



    raw_binop ty Add x v




1





368



  | Sub, Binop (ty, Sub, x, { node = Val v1; _ }), Val v2 ->




1





369



    let v = value (Eval.binop ty Add v1 v2) in




1





370



    raw_binop ty Sub x v




1





371



  | Mul, Binop (ty, Mul, x, { node = Val v1; _ }), Val v2 ->




1





372



    let v = value (Eval.binop ty Mul v1 v2) in




1





373



    raw_binop ty Mul x v




1





374



  | Add, Val v1, Binop (ty, Add, x, { node = Val v2; _ }) ->




1





375



    let v = value (Eval.binop ty Add v1 v2) in




1





376



    raw_binop ty Add v x




1





377



  | Mul, Val v1, Binop (ty, Mul, x, { node = Val v2; _ }) ->




1





378



    let v = value (Eval.binop ty Mul v1 v2) in




1





379



    raw_binop ty Mul v x




1





380



  | At, List es, Val (Int n) ->




1





381



    (* TODO: use another datastructure? *)










382



    begin










383



      match List.nth_opt es n with None -> assert false | Some v -> v




1





384



    end










385



  | List_cons, _, List es -> make (List (hte1 :: es))




1





386



  | List_append, List _, (List [] | Val (List [])) -> hte1




×








UNCOV

387



  | List_append, (List [] | Val (List [])), List _ -> hte2




×







388



  | List_append, List l0, Val (List l1) -> make (List (l0 @ List.map value l1))




1





389



  | List_append, Val (List l0), List l1 -> make (List (List.map value l0 @ l1))




×








UNCOV

390



  | List_append, List l0, List l1 -> make (List (l0 @ l1))




×







391



  | _ -> raw_binop ty op hte1 hte2




12





392













UNCOV

393



let raw_triop ty op e1 e2 e3 = make (Triop (ty, op, e1, e2, e3)) [@@inline]




×







394












395



let triop ty op e1 e2 e3 =










396



  match (op, view e1, view e2, view e3) with




6





397



  | Ty.Triop.Ite, Val True, _, _ -> e2




1





398



  | Ite, Val False, _, _ -> e3




1





399



  | op, Val v1, Val v2, Val v3 -> value (Eval.triop ty op v1 v2 v3)




4






UNCOV

400



  | Ite, _, Triop (_, Ite, c2, r1, r2), Triop (_, Ite, _, _, _) ->




×







401



    let else_ = raw_triop ty Ite e1 r2 e3 in










402



    let cond = binop Ty_bool And e1 c2 in




×







403



    raw_triop ty Ite cond r1 else_




×








UNCOV

404



  | _ -> raw_triop ty op e1 e2 e3




×







405












406



let raw_relop ty op hte1 hte2 = make (Relop (ty, op, hte1, hte2)) [@@inline]




2





407












408



let rec relop ty op hte1 hte2 =










409



  match (op, view hte1, view hte2) with




77





410



  | op, Val v1, Val v2 -> value (if Eval.relop ty op v1 v2 then True else False)




29





411



  | Ty.Relop.Ne, Val (Real v), _ | Ne, _, Val (Real v) ->




×







412



    if Float.is_nan v || Float.is_infinite v then value True




×







413



    else raw_relop ty op hte1 hte2




×







414



  | _, Val (Real v), _ | _, _, Val (Real v) ->




×







415



    if Float.is_nan v || Float.is_infinite v then value False




×







416



    else raw_relop ty op hte1 hte2




×







417



  | Eq, _, Val Nothing | Eq, Val Nothing, _ -> value False




×







418



  | Ne, _, Val Nothing | Ne, Val Nothing, _ -> value True




×







419



  | Eq, _, Val (App (`Op "symbol", [ Str _ ]))




×








UNCOV

420



  | Eq, Val (App (`Op "symbol", [ Str _ ])), _ ->




×







421



    value False










422



  | Ne, _, Val (App (`Op "symbol", [ Str _ ]))




×








UNCOV

423



  | Ne, Val (App (`Op "symbol", [ Str _ ])), _ ->




×







424



    value True










425



  | Eq, Ptr { base = b1; offset = os1 }, Ptr { base = b2; offset = os2 } ->




2





426



    if Int32.equal b1 b2 then relop Ty_bool Eq os1 os2 else value False




1





427



  | Ne, Ptr { base = b1; offset = os1 }, Ptr { base = b2; offset = os2 } ->




2





428



    if Int32.equal b1 b2 then relop Ty_bool Ne os1 os2 else value True




1





429



  | ( (LtU | LeU)




2





430



    , Ptr { base = b1; offset = os1 }










431



    , Ptr { base = b2; offset = os2 } ) ->










432



    if Int32.equal b1 b2 then relop ty op os1 os2




2





433



    else










434



      value




2





435



        (if Eval.relop ty op (Num (I32 b1)) (Num (I32 b2)) then True else False)




1





436



  | op, Val (Num _ as n), Ptr { base; offset = { node = Val (Num _ as o); _ } }




2





437



    ->










438



    let base = Eval.binop (Ty_bitv 32) Add (Num (I32 base)) o in










439



    value (if Eval.relop ty op n base then True else False)




1





440



  | op, Ptr { base; offset = { node = Val (Num _ as o); _ } }, Val (Num _ as n)




2





441



    ->










442



    let base = Eval.binop (Ty_bitv 32) Add (Num (I32 base)) o in










443



    value (if Eval.relop ty op base n then True else False)




1






UNCOV

444



  | op, List l1, List l2 -> relop_list op l1 l2




×








NEW


445



  | Gt, _, _ -> relop ty Lt hte2 hte1




×








446



  | GtU, _, _ -> relop ty LtU hte2 hte1




1






NEW


447



  | Ge, _, _ -> relop ty Le hte2 hte1




×








448



  | GeU, _, _ -> relop ty LeU hte2 hte1




1





449



  | _, _, _ -> raw_relop ty op hte1 hte2




2





450












451



and relop_list op l1 l2 =










452



  match (op, l1, l2) with




×







453



  | Eq, [], [] -> value True




×








UNCOV

454



  | Eq, _, [] | Eq, [], _ -> value False




×







455



  | Eq, l1, l2 ->




×








UNCOV

456



    if not (List.compare_lengths l1 l2 = 0) then value False




×







457



    else











UNCOV

458



      List.fold_left2




×







459



        (fun acc a b ->










460



          binop Ty_bool And acc




×







461



          @@










462



          match (ty a, ty b) with




×







463



          | Ty_real, Ty_real -> relop Ty_real Eq a b




×








UNCOV

464



          | _ -> relop Ty_bool Eq a b )




×








UNCOV

465



        (value True) l1 l2




×








UNCOV

466



  | Ne, _, _ -> unop Ty_bool Not @@ relop_list Eq l1 l2




×







467



  | (Lt | LtU | Gt | GtU | Le | LeU | Ge | GeU), _, _ -> assert false










468












469



let raw_cvtop ty op hte = make (Cvtop (ty, op, hte)) [@@inline]




1





470












471



let cvtop ty op hte =










472



  match (op, view hte) with




21






UNCOV

473



  | Ty.Cvtop.String_to_re, _ -> raw_cvtop ty op hte




×







474



  | _, Val v -> value (Eval.cvtop ty op v)




20





475



  | String_to_float, Cvtop (Ty_real, ToString, real) -> real




×







476



  | _ -> raw_cvtop ty op hte




1





477












478



let raw_naryop ty op es = make (Naryop (ty, op, es)) [@@inline]




×







479












480



let naryop ty op es =











UNCOV

481



  if List.for_all (fun e -> match view e with Val _ -> true | _ -> false) es




×







482



  then










483



    let vs =




7





484



      List.map (fun e -> match view e with Val v -> v | _ -> assert false) es




18





485



    in










486



    value (Eval.naryop ty op vs)




7





487



  else











UNCOV

488



    match (ty, op, List.map view es) with




×








UNCOV

489



    | ( Ty_str




×







490



      , Concat










491



      , [ Naryop (Ty_str, Concat, l1); Naryop (Ty_str, Concat, l2) ] ) ->










492



      raw_naryop Ty_str Concat (l1 @ l2)










493



    | Ty_str, Concat, [ Naryop (Ty_str, Concat, htes); hte ] ->




×







494



      raw_naryop Ty_str Concat (htes @ [ make hte ])




×








UNCOV

495



    | Ty_str, Concat, [ hte; Naryop (Ty_str, Concat, htes) ] ->




×








UNCOV

496



      raw_naryop Ty_str Concat (make hte :: htes)




×







497



    | _ -> raw_naryop ty op es




×







498












499



let nland64 (x : int64) (n : int) =











UNCOV

500



  let rec loop x' n' acc =




×








UNCOV

501



    if n' = 0 then Int64.logand x' acc




×








UNCOV

502



    else loop x' (n' - 1) Int64.(logor (shift_left acc 8) 0xffL)




×







503



  in










504



  loop x n 0L










505












506



let nland32 (x : int32) (n : int) =











UNCOV

507



  let rec loop x' n' acc =




×








UNCOV

508



    if n' = 0 then Int32.logand x' acc




×








UNCOV

509



    else loop x' (n' - 1) Int32.(logor (shift_left acc 8) 0xffl)




×







510



  in










511



  loop x n 0l










512












513



let raw_extract (hte : t) ~(high : int) ~(low : int) : t =










514



  make (Extract (hte, high, low))




8





515



[@@inline]










516












517



let extract (hte : t) ~(high : int) ~(low : int) : t =










518



  match (view hte, high, low) with




2





519



  | Val (Num (I64 x)), high, low ->




×







520



    let x' = nland64 (Int64.shift_right x (low * 8)) (high - low) in




×








UNCOV

521



    value (Num (I64 x'))




×








UNCOV

522



  | Concat (_, e), 4, 0 when Ty.size (ty e) = 4 -> e




×








UNCOV

523



  | Concat (e, _), 8, 4 when Ty.size (ty e) = 4 -> e




×







524



  | _ ->




2





525



    if high - low = Ty.size (ty hte) then hte else raw_extract hte ~high ~low




1





526












527



let extract2 (hte : t) (pos : int) : t =











UNCOV

528



  match view hte with




×







529



  | Val (Num (I32 i)) ->




×







530



    let i' = Int32.(to_int @@ logand 0xffl @@ shift_right i (pos * 8)) in




×







531



    value (Num (I8 i'))










532



  | Val (Num (I64 i)) ->




×








UNCOV

533



    let i' = Int64.(to_int @@ logand 0xffL @@ shift_right i (pos * 8)) in




×







534



    value (Num (I8 i'))











UNCOV

535



  | Cvtop




×







536



      ( _










537



      , (Zero_extend 24 | Sign_extend 24)




×







538



      , ({ node = Symbol { ty = Ty_bitv 8; _ }; _ } as sym) ) ->










539



    sym











UNCOV

540



  | _ -> make (Extract (hte, pos + 1, pos))




×







541












542



let raw_concat (msb : t) (lsb : t) : t = make (Concat (msb, lsb)) [@@inline]




3





543












544



let concat (msb : t) (lsb : t) : t =










545



  match (view msb, view lsb) with




3






UNCOV

546



  | ( Extract ({ node = Val (Num (I64 x2)); _ }, h2, l2)




×







547



    , Extract ({ node = Val (Num (I64 x1)); _ }, h1, l1) ) ->










548



    let d1 = h1 - l1 in










549



    let d2 = h2 - l2 in










550



    let x1' = nland64 (Int64.shift_right x1 (l1 * 8)) d1 in




×







551



    let x2' = nland64 (Int64.shift_right x2 (l2 * 8)) d2 in




×








UNCOV

552



    let x = Int64.(logor (shift_left x2' (d1 * 8)) x1') in




×








UNCOV

553



    raw_extract (value (Num (I64 x))) ~high:(d1 + d2) ~low:0




×








UNCOV

554



  | ( Extract ({ node = Val (Num (I32 x2)); _ }, h2, l2)




×







555



    , Extract ({ node = Val (Num (I32 x1)); _ }, h1, l1) ) ->










556



    let d1 = h1 - l1 in










557



    let d2 = h2 - l2 in










558



    let x1' = nland32 (Int32.shift_right x1 (l1 * 8)) d1 in




×








UNCOV

559



    let x2' = nland32 (Int32.shift_right x2 (l2 * 8)) d2 in




×








UNCOV

560



    let x = Int32.(logor (shift_left x2' (d1 * 8)) x1') in




×







561



    raw_extract (value (Num (I32 x))) ~high:(d1 + d2) ~low:0




×







562



  | Extract (s1, h, m1), Extract (s2, m2, l) when equal s1 s2 && m1 = m2 ->




3





563



    raw_extract s1 ~high:h ~low:l




3





564



  | ( Extract ({ node = Val (Num (I64 x2)); _ }, h2, l2)




×







565



    , Concat










566



        ({ node = Extract ({ node = Val (Num (I64 x1)); _ }, h1, l1); _ }, se) )










567



    when not (is_num se) ->




×







568



    let d1 = h1 - l1 in




×







569



    let d2 = h2 - l2 in










570



    let x1' = nland64 (Int64.shift_right x1 (l1 * 8)) d1 in




×







571



    let x2' = nland64 (Int64.shift_right x2 (l2 * 8)) d2 in




×








UNCOV

572



    let x = Int64.(logor (shift_left x2' (d1 * 8)) x1') in




×








UNCOV

573



    raw_concat (raw_extract (value (Num (I64 x))) ~high:(d1 + d2) ~low:0) se




×








UNCOV

574



  | _ -> raw_concat msb lsb




×







575












576



(* TODO: don't rebuild so many values it generates unecessary hc lookups *)










577



let merge_extracts (e1, h, m1) (e2, m2, l) =










578



  let ty = ty e1 in




×








UNCOV

579



  if m1 = m2 && equal e1 e2 then




×








UNCOV

580



    if h - l = Ty.size ty then e1 else make (Extract (e1, h, l))




×







581



  else make (Concat (make (Extract (e1, h, m1)), make (Extract (e2, m2, l))))




×







582












583



let concat3 ~msb ~lsb offset =










584



  assert (offset > 0 && offset <= 8);




×







585



  match (view msb, view lsb) with




×








UNCOV

586



  | Val (Num (I8 i1)), Val (Num (I8 i2)) ->




×








UNCOV

587



    value (Num (I32 Int32.(logor (shift_left (of_int i1) 8) (of_int i2))))




×







588



  | Val (Num (I8 i1)), Val (Num (I32 i2)) ->




×







589



    let offset = offset * 8 in










590



    if offset < 32 then










591



      value (Num (I32 Int32.(logor (shift_left (of_int i1) offset) i2)))




×







592



    else










593



      let i1' = Int64.of_int i1 in




×








UNCOV

594



      let i2' = Int64.of_int32 i2 in




×







595



      value (Num (I64 Int64.(logor (shift_left i1' offset) i2')))




×







596



  | Val (Num (I8 i1)), Val (Num (I64 i2)) ->




×







597



    let offset = offset * 8 in










598



    value (Num (I64 Int64.(logor (shift_left (of_int i1) offset) i2)))




×







599



  | Extract (e1, h, m1), Extract (e2, m2, l) ->




×







600



    merge_extracts (e1, h, m1) (e2, m2, l)











UNCOV

601



  | Extract (e1, h, m1), Concat ({ node = Extract (e2, m2, l); _ }, e3) ->




×








UNCOV

602



    make (Concat (merge_extracts (e1, h, m1) (e2, m2, l), e3))




×








UNCOV

603



  | _ -> make (Concat (msb, lsb))




×







604












605



let rec simplify_expr ?(rm_extract = true) (hte : t) : t =




19





606



  match view hte with




25





607



  | Val _ | Symbol _ -> hte




5





608



  | Ptr { base; offset } -> ptr base (simplify_expr offset)




×








UNCOV

609



  | List es -> make @@ List (List.map simplify_expr es)




×







610



  | App (x, es) -> make @@ App (x, List.map simplify_expr es)




×








UNCOV

611



  | Unop (ty, op, e) ->




×







612



    let e = simplify_expr e in











UNCOV

613



    unop ty op e




×







614



  | Binop (ty, op, e1, e2) ->




6





615



    let e1 = simplify_expr e1 in










616



    let e2 = simplify_expr e2 in




6





617



    binop ty op e1 e2




6





618



  | Relop (ty, op, e1, e2) ->




×







619



    let e1 = simplify_expr e1 in











UNCOV

620



    let e2 = simplify_expr e2 in




×







621



    relop ty op e1 e2




×







622



  | Triop (ty, op, c, e1, e2) ->




×







623



    let c = simplify_expr c in










624



    let e1 = simplify_expr e1 in




×








UNCOV

625



    let e2 = simplify_expr e2 in




×







626



    triop ty op c e1 e2




×







627



  | Cvtop (ty, op, e) ->




×







628



    let e = simplify_expr e in










629



    cvtop ty op e




×








UNCOV

630



  | Naryop (ty, op, es) ->




×







631



    let es = List.map (simplify_expr ~rm_extract:false) es in











UNCOV

632



    naryop ty op es




×







633



  | Extract (s, high, low) ->




5





634



    if not rm_extract then hte else extract s ~high ~low




1





635



  | Concat (e1, e2) ->




3





636



    let msb = simplify_expr ~rm_extract:false e1 in










637



    let lsb = simplify_expr ~rm_extract:false e2 in




3





638



    concat msb lsb




3






UNCOV

639



  | Binder _ ->




×







640



    (* Not simplifying anything atm *)










641



    hte










642












643



module Cache = Hashtbl.Make (struct










644



  type nonrec t = t










645












646



  let hash = hash










647












648



  let equal = equal










649



end)










650












651



let simplify =










652



  (* TODO: it may make sense to share the cache with simplify_expr ? *)










653



  let cache = Cache.create 512 in










654



  fun e ->




1





655



    match Cache.find_opt cache e with




3






UNCOV

656



    | Some simplified -> simplified




×







657



    | None ->




3





658



      let rec loop x =










659



        let x' = simplify_expr x in




7





660



        if equal x x' then begin




3





661



          Cache.add cache e x';










662



          x'




3





663



        end










664



        else loop x'




4





665



      in










666



      loop e










667












668



module Bool = struct










669



  open Ty










670












671



  let of_val = function











UNCOV

672



    | Val True -> Some true




×








UNCOV

673



    | Val False -> Some false




×








UNCOV

674



    | _ -> None




×







675












676



  let true_ = value True




1





677












678



  let false_ = value False




1





679













UNCOV

680



  let to_val b = if b then true_ else false_




×







681












682



  let v b = to_val b [@@inline]




×







683












684



  let not b =










685



    let bexpr = view b in




×








UNCOV

686



    match of_val bexpr with




×







687



    | Some b -> to_val (not b)




×







688



    | None -> (




×







689



      match bexpr with











UNCOV

690



      | Unop (Ty_bool, Not, cond) -> cond




×







691



      | _ -> unop Ty_bool Not b )




×







692












693



  let equal b1 b2 =











UNCOV

694



    match (view b1, view b2) with




×








UNCOV

695



    | Val True, Val True | Val False, Val False -> true_




×







696



    | _ -> relop Ty_bool Eq b1 b2




×







697












698



  let distinct b1 b2 =











UNCOV

699



    match (view b1, view b2) with




×








UNCOV

700



    | Val True, Val False | Val False, Val True -> true_




×







701



    | _ -> relop Ty_bool Ne b1 b2




×







702












703



  let and_ b1 b2 =










704



    match (of_val (view b1), of_val (view b2)) with




×







705



    | Some true, _ -> b2




×








UNCOV

706



    | _, Some true -> b1




×








UNCOV

707



    | Some false, _ | _, Some false -> false_




×







708



    | _ -> binop Ty_bool And b1 b2




×







709












710



  let or_ b1 b2 =










711



    match (of_val (view b1), of_val (view b2)) with




×







712



    | Some false, _ -> b2




×








UNCOV

713



    | _, Some false -> b1




×







714



    | Some true, _ | _, Some true -> true_




×








UNCOV

715



    | _ -> binop Ty_bool Or b1 b2




×







716













UNCOV

717



  let ite c r1 r2 = triop Ty_bool Ite c r1 r2




×







718



end










719












720



module Make (T : sig










721



  type elt










722












723



  val ty : Ty.t










724












725



  val num : elt -> Num.t










726



end) =










727



struct










728



  open Ty










729













UNCOV

730



  let v i = value (Num (T.num i))




×







731













UNCOV

732



  let sym x = symbol Symbol.(x @: T.ty)




×







733













UNCOV

734



  let ( ~- ) e = unop T.ty Neg e




×







735













UNCOV

736



  let ( = ) e1 e2 = relop Ty_bool Eq e1 e2




×







737













UNCOV

738



  let ( != ) e1 e2 = relop Ty_bool Ne e1 e2




×







739













UNCOV

740



  let ( > ) e1 e2 = relop T.ty Gt e1 e2




×







741













UNCOV

742



  let ( >= ) e1 e2 = relop T.ty Ge e1 e2




×







743













UNCOV

744



  let ( < ) e1 e2 = relop T.ty Lt e1 e2




×







745













UNCOV

746



  let ( <= ) e1 e2 = relop T.ty Le e1 e2




×







747



end










748












749



module Bitv = struct










750



  open Ty










751












752



  module I8 = Make (struct










753



    type elt = int










754












755



    let ty = Ty_bitv 8










756













UNCOV

757



    let num i = Num.I8 i




×







758



  end)










759












760



  module I32 = Make (struct










761



    type elt = int32










762












763



    let ty = Ty_bitv 32










764













UNCOV

765



    let num i = Num.I32 i




×







766



  end)










767












768



  module I64 = Make (struct










769



    type elt = int64










770












771



    let ty = Ty_bitv 64










772













UNCOV

773



    let num i = Num.I64 i




×







774



  end)










775



end










776












777



module Fpa = struct










778



  open Ty










779












780



  module F32 = struct










781



    include Make (struct










782



      type elt = float










783












784



      let ty = Ty_fp 32










785













UNCOV

786



      let num f = Num.F32 (Int32.bits_of_float f)




×







787



    end)










788












789



    (* Redeclare equality due to incorrect theory annotation *)











UNCOV

790



    let ( = ) e1 e2 = relop (Ty_fp 32) Eq e1 e2




×







791













UNCOV

792



    let ( != ) e1 e2 = relop (Ty_fp 32) Ne e1 e2




×







793



  end










794












795



  module F64 = struct










796



    include Make (struct










797



      type elt = float










798












799



      let ty = Ty_fp 64










800













UNCOV

801



      let num f = Num.F64 (Int64.bits_of_float f)




×







802



    end)










803












804



    (* Redeclare equality due to incorrect theory annotation *)











UNCOV

805



    let ( = ) e1 e2 = relop (Ty_fp 64) Eq e1 e2




×







806













UNCOV

807



    let ( != ) e1 e2 = relop (Ty_fp 64) Ne e1 e2




×







808



  end










809



end
























    

  • 

    •