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356 lines
13 KiB
356 lines
13 KiB
(*
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* Copyright (c) Facebook, Inc. and its affiliates.
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*
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* This source code is licensed under the MIT license found in the
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* LICENSE file in the root directory of this source tree.
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*)
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(** Abstract domain *)
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type t = Sh.t [@@deriving equal, sexp]
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let pp fs q = Format.fprintf fs "@[{ %a@ }@]" Sh.pp q
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let report_fmt_thunk = Fun.flip pp
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(* set by cli *)
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let simplify_states = ref true
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let simplify q = if !simplify_states then Sh.simplify q else q
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let init globals =
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IArray.fold globals ~init:Sh.emp ~f:(fun q -> function
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| {Global.reg; init= Some arr} ->
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let loc = Term.var (Reg.var reg) in
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let len = Term.size_of (Exp.typ arr) in
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let arr = arr.term in
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Sh.star q (Sh.seg {loc; bas= loc; len; siz= len; arr})
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| _ -> q )
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let join p q =
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[%Trace.call fun {pf} -> pf "%a@ %a" pp p pp q]
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;
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Some (Sh.or_ p q) |> Option.map ~f:simplify
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|>
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[%Trace.retn fun {pf} -> pf "%a" (Option.pp "%a" pp)]
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let is_false = Sh.is_false
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let dnf = Sh.dnf
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let exec_assume q b = Exec.assume q (Exp.term b) |> Option.map ~f:simplify
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let exec_kill q r = Exec.kill q (Reg.var r) |> simplify
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let exec_move q res =
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Exec.move q (IArray.map res ~f:(fun (r, e) -> (Reg.var r, Exp.term e)))
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|> simplify
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let exec_inst pre inst =
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( match (inst : Llair.inst) with
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| Move {reg_exps; _} ->
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Some
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(Exec.move pre
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(IArray.map reg_exps ~f:(fun (r, e) -> (Reg.var r, Exp.term e))))
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| Load {reg; ptr; len; _} ->
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Exec.load pre ~reg:(Reg.var reg) ~ptr:(Exp.term ptr)
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~len:(Exp.term len)
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| Store {ptr; exp; len; _} ->
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Exec.store pre ~ptr:(Exp.term ptr) ~exp:(Exp.term exp)
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~len:(Exp.term len)
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| Memset {dst; byt; len; _} ->
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Exec.memset pre ~dst:(Exp.term dst) ~byt:(Exp.term byt)
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~len:(Exp.term len)
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| Memcpy {dst; src; len; _} ->
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Exec.memcpy pre ~dst:(Exp.term dst) ~src:(Exp.term src)
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~len:(Exp.term len)
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| Memmov {dst; src; len; _} ->
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Exec.memmov pre ~dst:(Exp.term dst) ~src:(Exp.term src)
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~len:(Exp.term len)
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| Alloc {reg; num; len; _} ->
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Exec.alloc pre ~reg:(Reg.var reg) ~num:(Exp.term num)
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~len:(Exp.term len)
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| Free {ptr; _} -> Exec.free pre ~ptr:(Exp.term ptr)
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| Nondet {reg; _} -> Some (Exec.nondet pre (Option.map ~f:Reg.var reg))
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| Abort _ -> Exec.abort pre )
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|> Option.map ~f:simplify
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let exec_intrinsic ~skip_throw q r i es =
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Exec.intrinsic ~skip_throw q (Option.map ~f:Reg.var r) (Reg.var i)
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(List.map ~f:Exp.term es)
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|> Option.map ~f:(Option.map ~f:simplify)
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let term_eq_class_has_only_vars_in fvs cong term =
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[%Trace.call fun {pf} ->
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pf "@[<v> fvs: @[%a@] @,cong: @[%a@] @,term: @[%a@]@]" Var.Set.pp fvs
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Equality.pp cong Term.pp term]
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;
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let term_has_only_vars_in fvs term =
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Var.Set.is_subset (Term.fv term) ~of_:fvs
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in
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let term_eq_class = Equality.class_of cong term in
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List.exists ~f:(term_has_only_vars_in fvs) term_eq_class
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|>
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[%Trace.retn fun {pf} -> pf "%b"]
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let garbage_collect (q : t) ~wrt =
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[%Trace.call fun {pf} -> pf "%a" pp q]
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;
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(* only support DNF for now *)
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assert (List.is_empty q.djns) ;
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let rec all_reachable_vars previous current (q : t) =
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if Var.Set.equal previous current then current
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else
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let new_set =
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List.fold ~init:current q.heap ~f:(fun current seg ->
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if term_eq_class_has_only_vars_in current q.cong seg.loc then
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List.fold (Equality.class_of q.cong seg.arr) ~init:current
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~f:(fun c e -> Var.Set.union c (Term.fv e))
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else current )
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in
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all_reachable_vars current new_set q
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in
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let r_vars = all_reachable_vars Var.Set.empty wrt q in
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Sh.filter_heap q ~f:(fun seg ->
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term_eq_class_has_only_vars_in r_vars q.cong seg.loc )
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|>
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[%Trace.retn fun {pf} -> pf "%a" pp]
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let and_eqs sub formals actuals q =
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let and_eq q formal actual =
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let actual' = Term.rename sub actual in
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Sh.and_ (Term.eq (Term.var formal) actual') q
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in
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List.fold2_exn ~f:and_eq formals actuals ~init:q
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let localize_entry globals actuals formals freturn locals subst pre entry =
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(* Add the formals here to do garbage collection and then get rid of them *)
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let formals_set = Var.Set.of_list formals in
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let freturn_locals = Reg.Set.vars (Reg.Set.add_option freturn locals) in
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let function_summary_pre =
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garbage_collect entry
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~wrt:(Var.Set.union formals_set (Reg.Set.vars globals))
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in
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[%Trace.info "function summary pre %a" pp function_summary_pre] ;
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let foot = Sh.exists formals_set function_summary_pre in
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let xs, foot = Sh.bind_exists ~wrt:pre.Sh.us foot in
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let frame =
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Option.value_exn
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(Solver.infer_frame pre xs foot)
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~message:"Solver couldn't infer frame of a garbage-collected pre"
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in
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let q'' =
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Sh.extend_us freturn_locals (and_eqs subst formals actuals foot)
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in
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(q'', frame)
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type from_call = {areturn: Var.t option; subst: Var.Subst.t; frame: Sh.t}
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[@@deriving compare, equal, sexp]
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(** Express formula in terms of formals instead of actuals, and enter scope
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of locals: rename formals to fresh vars in formula and actuals, add
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equations between each formal and actual, and quantify fresh vars. *)
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let call ~summaries ~globals ~actuals ~areturn ~formals ~freturn ~locals q =
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[%Trace.call fun {pf} ->
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pf
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"@[<hv>actuals: (@[%a@])@ formals: (@[%a@])@ locals: {@[%a@]}@ \
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globals: {@[%a@]}@ q: %a@]"
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(List.pp ",@ " Exp.pp) (List.rev actuals) (List.pp ",@ " Reg.pp)
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(List.rev formals) Reg.Set.pp locals Reg.Set.pp globals pp q]
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;
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let actuals = List.map ~f:Exp.term actuals in
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let areturn = Option.map ~f:Reg.var areturn in
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let formals = List.map ~f:Reg.var formals in
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let freturn_locals = Reg.Set.vars (Reg.Set.add_option freturn locals) in
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let modifs = Var.Set.of_option areturn in
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(* quantify modifs, their current value will be overwritten and so does
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not need to be saved in the freshening renaming *)
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let q = Sh.exists modifs q in
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(* save current values of shadowed formals and locals with a renaming *)
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let q', subst =
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Sh.freshen q ~wrt:(Var.Set.add_list formals freturn_locals)
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in
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assert (Var.Set.disjoint modifs (Var.Subst.domain subst)) ;
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(* pass arguments by conjoining equations between formals and actuals *)
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let entry = and_eqs subst formals actuals q' in
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(* note: locals and formals are in scope *)
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assert (
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Var.Set.is_subset
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(Var.Set.add_list formals freturn_locals)
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~of_:entry.us ) ;
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(* simplify *)
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let entry = simplify entry in
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( if not summaries then (entry, {areturn; subst; frame= Sh.emp})
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else
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let q'', frame =
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localize_entry globals actuals formals freturn locals subst q' entry
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in
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(q'', {areturn; subst; frame}) )
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|>
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[%Trace.retn fun {pf} (entry, {subst; frame}) ->
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pf "@[<v>subst: %a@ frame: %a@ entry: %a@]" Var.Subst.pp subst pp frame
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pp entry]
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(** Leave scope of locals: existentially quantify locals. *)
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let post locals _ q =
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[%Trace.call fun {pf} ->
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pf "@[<hv>locals: {@[%a@]}@ q: %a@]" Reg.Set.pp locals Sh.pp q]
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;
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Sh.exists (Reg.Set.vars locals) q |> simplify
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|>
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[%Trace.retn fun {pf} -> pf "%a" Sh.pp]
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(** Express in terms of actuals instead of formals: existentially quantify
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formals, and apply inverse of fresh variables for formals renaming to
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restore the shadowed variables. *)
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let retn formals freturn {areturn; subst; frame} q =
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[%Trace.call fun {pf} ->
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pf "@[<v>formals: {@[%a@]}%a%a@ subst: %a@ q: %a@ frame: %a@]"
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(List.pp ", " Reg.pp) formals
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(Option.pp "@ freturn: %a" Reg.pp)
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freturn
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(Option.pp "@ areturn: %a" Var.pp)
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areturn Var.Subst.pp (Var.Subst.invert subst) pp q pp frame]
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;
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let formals = List.map ~f:Reg.var formals in
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let freturn = Option.map ~f:Reg.var freturn in
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let inv_subst = Var.Subst.invert subst in
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let q, inv_subst =
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match areturn with
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| Some areturn -> (
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(* reenter scope of areturn just before exiting scope of formals *)
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let q = Sh.extend_us (Var.Set.of_ areturn) q in
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(* pass return value *)
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match freturn with
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| Some freturn ->
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(Exec.move q (IArray.of_ (areturn, Term.var freturn)), inv_subst)
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| None -> (Exec.kill q areturn, inv_subst) )
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| None -> (q, inv_subst)
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in
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(* exit scope of formals *)
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let q =
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Sh.exists (Var.Set.add_list formals (Var.Set.of_option freturn)) q
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in
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(* reinstate shadowed values of locals *)
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let q = Sh.rename inv_subst q in
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(* reconjoin frame *)
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Sh.star frame q
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(* simplify *)
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|> simplify
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|>
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[%Trace.retn fun {pf} -> pf "%a" pp]
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let resolve_callee lookup ptr q =
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match Reg.of_exp ptr with
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| Some callee -> (lookup (Reg.name callee), q)
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| None -> ([], q)
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let recursion_beyond_bound = `prune
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type summary = {xs: Var.Set.t; foot: t; post: t}
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let pp_summary fs {xs; foot; post} =
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Format.fprintf fs "@[<v>xs: @[%a@]@ foot: %a@ post: %a @]" Var.Set.pp xs
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pp foot pp post
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let create_summary ~locals ~formals ~entry ~current:(post : Sh.t) =
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[%Trace.call fun {pf} ->
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pf "formals %a@ entry: %a@ current: %a" Reg.Set.pp formals pp entry pp
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post]
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;
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let locals = Reg.Set.vars locals in
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let formals = Reg.Set.vars formals in
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let foot = Sh.exists locals entry in
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let foot, subst = Sh.freshen ~wrt:(Var.Set.union foot.us post.us) foot in
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let restore_formals q =
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Var.Set.fold formals ~init:q ~f:(fun q var ->
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let var = Term.var var in
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let renamed_var = Term.rename subst var in
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Sh.and_ (Term.eq renamed_var var) q )
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in
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(* Add back the original formals name *)
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let post = Sh.rename subst post in
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let foot = restore_formals foot in
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let post = restore_formals post in
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[%Trace.info "subst: %a" Var.Subst.pp subst] ;
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let xs = Var.Set.inter (Sh.fv foot) (Sh.fv post) in
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let xs = Var.Set.diff xs formals in
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let xs_and_formals = Var.Set.union xs formals in
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let foot = Sh.exists (Var.Set.diff foot.us xs_and_formals) foot in
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let post = Sh.exists (Var.Set.diff post.us xs_and_formals) post in
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let current = Sh.extend_us xs post in
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({xs; foot; post}, current)
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|>
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[%Trace.retn fun {pf} (fs, _) -> pf "@,%a" pp_summary fs]
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let apply_summary q ({xs; foot; post} as fs) =
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[%Trace.call fun {pf} -> pf "fs: %a@ q: %a" pp_summary fs pp q]
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;
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let xs_in_q = Var.Set.inter xs q.Sh.us in
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let xs_in_fv_q = Var.Set.inter xs (Sh.fv q) in
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(* Between creation of a summary and its use, the vocabulary of q (q.us)
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might have been extended. That means infer_frame would fail, because q
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and foot have different vocabulary. This might indicate that the
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summary cannot be applied to q, however in the case where
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free-variables of q and foot match it is benign. In the case where free
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variables match, we temporarily reduce the vocabulary of q to match the
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vocabulary of foot. *)
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[%Trace.info "xs inter q.us: %a" Var.Set.pp xs_in_q] ;
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[%Trace.info "xs inter fv.q %a" Var.Set.pp xs_in_fv_q] ;
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let q, add_back =
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if Var.Set.is_empty xs_in_fv_q then (Sh.exists xs_in_q q, xs_in_q)
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else (q, Var.Set.empty)
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in
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let frame =
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if Var.Set.is_empty xs_in_fv_q then Solver.infer_frame q xs foot
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else None
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in
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[%Trace.info "frame %a" (Option.pp "%a" pp) frame] ;
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Option.map ~f:(Sh.extend_us add_back) (Option.map ~f:(Sh.star post) frame)
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|>
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[%Trace.retn fun {pf} r ->
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match r with None -> pf "None" | Some q -> pf "@,%a" pp q]
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let%test_module _ =
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( module struct
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let pp = Format.printf "@.%a@." Sh.pp
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let wrt = Var.Set.empty
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let main_, wrt = Var.fresh "main" ~wrt
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let a_, wrt = Var.fresh "a" ~wrt
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let n_, wrt = Var.fresh "n" ~wrt
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let b_, wrt = Var.fresh "b" ~wrt
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let end_, _ = Var.fresh "end" ~wrt
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let a = Term.var a_
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let main = Term.var main_
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let b = Term.var b_
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let n = Term.var n_
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let endV = Term.var end_
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let seg_main = Sh.seg {loc= main; bas= b; len= n; siz= n; arr= a}
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let seg_a = Sh.seg {loc= a; bas= b; len= n; siz= n; arr= endV}
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let seg_cycle = Sh.seg {loc= a; bas= b; len= n; siz= n; arr= main}
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let%expect_test _ =
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pp (garbage_collect seg_main ~wrt:(Var.Set.of_list [])) ;
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[%expect {| emp |}]
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let%expect_test _ =
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pp
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(garbage_collect (Sh.star seg_a seg_main)
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~wrt:(Var.Set.of_list [a_])) ;
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[%expect {| %a_2 -[ %b_4, %n_3 )-> ⟨%n_3,%end_5⟩ |}]
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let%expect_test _ =
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pp
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(garbage_collect (Sh.star seg_a seg_main)
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~wrt:(Var.Set.of_list [main_])) ;
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[%expect
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{|
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%main_1 -[ %b_4, %n_3 )-> ⟨%n_3,%a_2⟩
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* %a_2 -[ %b_4, %n_3 )-> ⟨%n_3,%end_5⟩ |}]
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let%expect_test _ =
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pp
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(garbage_collect
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(Sh.star seg_cycle seg_main)
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~wrt:(Var.Set.of_list [a_])) ;
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[%expect
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{|
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%main_1 -[ %b_4, %n_3 )-> ⟨%n_3,%a_2⟩
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* %a_2 -[ %b_4, %n_3 )-> ⟨%n_3,%main_1⟩ |}]
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end )
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