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(*
* Copyright (c) Facebook, Inc. and its affiliates.
*
* This source code is licensed under the MIT license found in the
* LICENSE file in the root directory of this source tree.
*)
(** LLAIR (Low-Level Analysis Internal Representation) *)
[@@@warning "+9"]
type inst =
| Move of {reg_exps: (Reg.t * Exp.t) vector; loc: Loc.t}
| Load of {reg: Reg.t; ptr: Exp.t; len: Exp.t; loc: Loc.t}
| Store of {ptr: Exp.t; exp: Exp.t; len: Exp.t; loc: Loc.t}
| Memset of {dst: Exp.t; byt: Exp.t; len: Exp.t; loc: Loc.t}
| Memcpy of {dst: Exp.t; src: Exp.t; len: Exp.t; loc: Loc.t}
| Memmov of {dst: Exp.t; src: Exp.t; len: Exp.t; loc: Loc.t}
| Alloc of {reg: Reg.t; num: Exp.t; len: Exp.t; loc: Loc.t}
| Free of {ptr: Exp.t; loc: Loc.t}
| Nondet of {reg: Reg.t option; msg: string; loc: Loc.t}
| Abort of {loc: Loc.t}
[@@deriving sexp]
type cmnd = inst vector [@@deriving sexp]
type label = string [@@deriving sexp]
type jump = {mutable dst: block; mutable retreating: bool}
and 'a call =
{ callee: 'a
; typ: Typ.t
; actuals: Exp.t list
; areturn: Reg.t option
; return: jump
; throw: jump option
; mutable recursive: bool
; loc: Loc.t }
and term =
| Switch of {key: Exp.t; tbl: (Exp.t * jump) vector; els: jump; loc: Loc.t}
| Iswitch of {ptr: Exp.t; tbl: jump vector; loc: Loc.t}
| Call of Exp.t call
| Return of {exp: Exp.t option; loc: Loc.t}
| Throw of {exc: Exp.t; loc: Loc.t}
| Unreachable
and block =
{ lbl: label
; cmnd: cmnd
; term: term
; mutable parent: func
; mutable sort_index: int }
and func =
{ name: Global.t
; formals: Reg.t list
; freturn: Reg.t option
; fthrow: Reg.t
; locals: Reg.Set.t
; entry: block }
let sexp_cons (hd : Sexp.t) (tl : Sexp.t) =
match tl with
| List xs -> Sexp.List (hd :: xs)
| Atom _ -> Sexp.List [hd; tl]
let sexp_ctor label args = sexp_cons (Sexp.Atom label) args
let sexp_of_jump {dst; retreating} =
[%sexp {dst: label = dst.lbl; retreating: bool}]
let sexp_of_term = function
| Switch {key; tbl; els; loc} ->
sexp_ctor "Switch"
[%sexp
{key: Exp.t; tbl: (Exp.t * jump) vector; els: jump; loc: Loc.t}]
| Iswitch {ptr; tbl; loc} ->
sexp_ctor "Iswitch" [%sexp {ptr: Exp.t; tbl: jump vector; loc: Loc.t}]
| Call {callee; typ; actuals; areturn; return; throw; recursive; loc} ->
sexp_ctor "Call"
[%sexp
{ callee: Exp.t
; typ: Typ.t
; actuals: Exp.t list
; areturn: Reg.t option
; return: jump
; throw: jump option
; recursive: bool
; loc: Loc.t }]
| Return {exp; loc} ->
sexp_ctor "Return" [%sexp {exp: Exp.t option; loc: Loc.t}]
| Throw {exc; loc} -> sexp_ctor "Throw" [%sexp {exc: Exp.t; loc: Loc.t}]
| Unreachable -> Sexp.Atom "Unreachable"
let sexp_of_block {lbl; cmnd; term; parent; sort_index} =
[%sexp
{ lbl: label
; cmnd: cmnd
; term: term
; parent: Reg.t = parent.name.reg
; sort_index: int }]
let sexp_of_func {name; formals; freturn; fthrow; locals; entry} =
[%sexp
{ name: Global.t
; formals: Reg.t list
; freturn: Reg.t option
; fthrow: Reg.t
; locals: Reg.Set.t
; entry: block }]
(* blocks in a [t] are uniquely identified by [sort_index] *)
let compare_block x y = Int.compare x.sort_index y.sort_index
let equal_block x y = Int.equal x.sort_index y.sort_index
type functions = func String.Map.t [@@deriving sexp_of]
type t = {globals: Global.t vector; functions: functions}
[@@deriving sexp_of]
let pp_inst fs inst =
let pf pp = Format.fprintf fs pp in
match inst with
| Move {reg_exps; loc} ->
let regs, exps = Vector.unzip reg_exps in
pf "@[<2>@[%a@]@ := @[%a@];@]\t%a" (Vector.pp ",@ " Reg.pp) regs
(Vector.pp ",@ " Exp.pp) exps Loc.pp loc
| Load {reg; ptr; len; loc} ->
pf "@[<2>%a@ := load %a@ %a;@]\t%a" Reg.pp reg Exp.pp len Exp.pp ptr
Loc.pp loc
| Store {ptr; exp; len; loc} ->
pf "@[<2>store %a@ %a@ %a;@]\t%a" Exp.pp len Exp.pp ptr Exp.pp exp
Loc.pp loc
| Memset {dst; byt; len; loc} ->
pf "@[<2>memset %a %a %a;@]\t%a" Exp.pp len Exp.pp dst Exp.pp byt
Loc.pp loc
| Memcpy {dst; src; len; loc} ->
pf "@[<2>memcpy %a %a %a;@]\t%a" Exp.pp len Exp.pp dst Exp.pp src
Loc.pp loc
| Memmov {dst; src; len; loc} ->
pf "@[<2>memmov %a %a %a;@]\t%a" Exp.pp len Exp.pp dst Exp.pp src
Loc.pp loc
| Alloc {reg; num; len; loc} ->
pf "@[<2>%a@ := alloc [%a x %a];@]\t%a" Reg.pp reg Exp.pp num Exp.pp
len Loc.pp loc
| Free {ptr; loc} -> pf "@[<2>free %a;@]\t%a" Exp.pp ptr Loc.pp loc
| Nondet {reg; msg; loc} ->
pf "@[<2>%anondet \"%s\";@]\t%a"
(Option.pp "%a := " Reg.pp)
reg msg Loc.pp loc
| Abort {loc} -> pf "@[<2>abort;@]\t%a" Loc.pp loc
let pp_actuals pp_actual fs actuals =
Format.fprintf fs "@ (@[%a@])" (List.pp ",@ " pp_actual)
(List.rev actuals)
let pp_formal fs reg = Reg.pp fs reg
let pp_jump fs {dst; retreating} =
Format.fprintf fs "@[<2>%s%%%s@]"
(if retreating then "" else "")
dst.lbl
let pp_term fs term =
let pf pp = Format.fprintf fs pp in
let pp_goto fs jmp = Format.fprintf fs "goto %a;" pp_jump jmp in
match term with
| Switch {key; tbl; els; loc} -> (
match Vector.to_array tbl with
| [||] -> pf "@[%a@]\t%a" pp_goto els Loc.pp loc
| [|(z, jmp)|] when Exp.is_false z ->
pf "@[if %a@;<1 2>%a@ @[else@;<1 2>%a@]@]\t%a" Exp.pp key pp_goto
els pp_goto jmp Loc.pp loc
| _ ->
pf "@[<2>switch %a@ @[%a@ else: %a@]@]\t%a" Exp.pp key
(Vector.pp "@ " (fun fs (case, jmp) ->
Format.fprintf fs "%a: %a" Exp.pp case pp_goto jmp ))
tbl pp_goto els Loc.pp loc )
| Iswitch {ptr; tbl; loc} ->
pf "@[<2>iswitch %a@ @[<hv>%a@]@]\t%a" Exp.pp ptr
(Vector.pp "@ " (fun fs jmp ->
Format.fprintf fs "%s: %a" jmp.dst.lbl pp_goto jmp ))
tbl Loc.pp loc
| Call {callee; actuals; areturn; return; throw; recursive; loc; _} ->
pf "@[<2>@[<7>%acall @[<2>%s%a%a@]@]@ @[returnto %a%a;@]@]\t%a"
(Option.pp "%a := " Reg.pp)
areturn
(if recursive then "" else "")
Exp.pp callee (pp_actuals Exp.pp) actuals pp_jump return
(Option.pp "@ throwto %a" pp_jump)
throw Loc.pp loc
| Return {exp; loc} ->
pf "@[<2>return%a@]\t%a" (Option.pp " %a" Exp.pp) exp Loc.pp loc
| Throw {exc; loc} -> pf "@[<2>throw %a@]\t%a" Exp.pp exc Loc.pp loc
| Unreachable -> pf "unreachable"
let pp_cmnd = Vector.pp "@ " pp_inst
let pp_block fs {lbl; cmnd; term; parent= _; sort_index} =
Format.fprintf fs "@[<v 2>%%%s: #%i@ @[<v>%a%t%a@]@]" lbl sort_index
pp_cmnd cmnd
(fun fs -> if Vector.is_empty cmnd then () else Format.fprintf fs "@ ")
pp_term term
(** Initial cyclic values *)
let rec dummy_block =
{ lbl= "dummy"
; cmnd= Vector.empty
; term= Unreachable
; parent= dummy_func
; sort_index= 0 }
and dummy_func =
let dummy_reg = Reg.program ~global:() Typ.ptr "dummy" in
{ name= Global.mk dummy_reg Typ.ptr Loc.none
; formals= []
; freturn= None
; fthrow= dummy_reg
; locals= Reg.Set.empty
; entry= dummy_block }
(** Instructions *)
module Inst = struct
type t = inst [@@deriving sexp]
let pp = pp_inst
let move ~reg_exps ~loc = Move {reg_exps; loc}
let load ~reg ~ptr ~len ~loc = Load {reg; ptr; len; loc}
let store ~ptr ~exp ~len ~loc = Store {ptr; exp; len; loc}
let memset ~dst ~byt ~len ~loc = Memset {dst; byt; len; loc}
let memcpy ~dst ~src ~len ~loc = Memcpy {dst; src; len; loc}
let memmov ~dst ~src ~len ~loc = Memmov {dst; src; len; loc}
let alloc ~reg ~num ~len ~loc = Alloc {reg; num; len; loc}
let free ~ptr ~loc = Free {ptr; loc}
let nondet ~reg ~msg ~loc = Nondet {reg; msg; loc}
let abort ~loc = Abort {loc}
let loc = function
| Move {loc; _}
|Load {loc; _}
|Store {loc; _}
|Memset {loc; _}
|Memcpy {loc; _}
|Memmov {loc; _}
|Alloc {loc; _}
|Free {loc; _}
|Nondet {loc; _}
|Abort {loc; _} ->
loc
let union_locals inst vs =
match inst with
| Move {reg_exps; _} ->
Vector.fold ~f:(fun vs (reg, _) -> Set.add vs reg) ~init:vs reg_exps
| Load {reg; _} | Alloc {reg; _} | Nondet {reg= Some reg; _} ->
Set.add vs reg
| Store _ | Memcpy _ | Memmov _ | Memset _ | Free _
|Nondet {reg= None; _}
|Abort _ ->
vs
let locals inst = union_locals inst Reg.Set.empty
let fold_exps inst ~init ~f =
match inst with
| Move {reg_exps; loc= _} ->
Vector.fold reg_exps ~init ~f:(fun acc (_reg, exp) -> f acc exp)
| Load {reg= _; ptr; len; loc= _} -> f (f init ptr) len
| Store {ptr; exp; len; loc= _} -> f (f (f init ptr) exp) len
| Memset {dst; byt; len; loc= _} -> f (f (f init dst) byt) len
| Memcpy {dst; src; len; loc= _} | Memmov {dst; src; len; loc= _} ->
f (f (f init dst) src) len
| Alloc {reg= _; num; len; loc= _} -> f (f init num) len
| Free {ptr; loc= _} -> f init ptr
| Nondet {reg= _; msg= _; loc= _} -> init
| Abort {loc= _} -> init
end
(** Jumps *)
module Jump = struct
type t = jump [@@deriving sexp_of]
let compare x y = compare_block x.dst y.dst
let equal x y = equal_block x.dst y.dst
let pp = pp_jump
let mk lbl = {dst= {dummy_block with lbl}; retreating= false}
end
(** Basic-Block Terminators *)
module Term = struct
type t = term [@@deriving sexp_of]
let pp = pp_term
let invariant ?parent term =
Invariant.invariant [%here] term [%sexp_of: t]
@@ fun () ->
match term with
| Switch _ | Iswitch _ -> assert true
| Call {typ; actuals; areturn; _} -> (
match typ with
| Pointer {elt= Function {args; return= retn_typ; _}} ->
assert (Vector.length args = List.length actuals) ;
assert (Option.is_some retn_typ || Option.is_none areturn)
| _ -> assert false )
| Return {exp; _} -> (
match parent with
| Some parent ->
assert (Bool.(Option.is_some exp = Option.is_some parent.freturn))
| None -> assert true )
| Throw _ | Unreachable -> assert true
let goto ~dst ~loc =
Switch {key= Exp.false_; tbl= Vector.empty; els= dst; loc}
|> check invariant
let branch ~key ~nzero ~zero ~loc =
let tbl = Vector.of_array [|(Exp.false_, zero)|] in
let els = nzero in
Switch {key; tbl; els; loc} |> check invariant
let switch ~key ~tbl ~els ~loc =
Switch {key; tbl; els; loc} |> check invariant
let iswitch ~ptr ~tbl ~loc = Iswitch {ptr; tbl; loc} |> check invariant
let call ~callee ~typ ~actuals ~areturn ~return ~throw ~loc =
Call
{callee; typ; actuals; areturn; return; throw; recursive= false; loc}
|> check invariant
let return ~exp ~loc = Return {exp; loc} |> check invariant
let throw ~exc ~loc = Throw {exc; loc} |> check invariant
let unreachable = Unreachable |> check invariant
let loc = function
| Switch {loc; _}
|Iswitch {loc; _}
|Call {loc; _}
|Return {loc; _}
|Throw {loc; _} ->
loc
| Unreachable -> Loc.none
let union_locals term vs =
match term with
| Call {areturn; _} -> Set.add_option areturn vs
| _ -> vs
end
(** Basic-Blocks *)
module Block = struct
module T = struct type t = block [@@deriving compare, equal, sexp_of] end
include T
module Map = Map.Make (T)
let pp = pp_block
let mk ~lbl ~cmnd ~term =
{ lbl
; cmnd
; term
; parent= dummy_block.parent
; sort_index= dummy_block.sort_index }
end
(* Blocks compared by label, which are unique within a function, used to
compute unique sort_index ids *)
module Block_label = struct
module T = struct
module T0 = struct
type t = block [@@deriving sexp_of]
let compare x y =
[%compare: string * Global.t] (x.lbl, x.parent.name)
(y.lbl, y.parent.name)
let hash b = [%hash: string * Global.t] (b.lbl, b.parent.name)
end
include T0
include Comparator.Make (T0)
end
include T
let empty_set = Set.empty (module T)
end
module BlockQ = Hash_queue.Make (Block_label)
module FuncQ = Hash_queue.Make (Reg)
(** Functions *)
module Func = struct
type t = func [@@deriving sexp_of]
let is_undefined = function
| {entry= {cmnd; term= Unreachable; _}; _} -> Vector.is_empty cmnd
| _ -> false
let fold_cfg ~init ~f func =
let seen = Hash_set.create (module Block_label) in
let rec fold_cfg_ s blk =
if Result.is_error (Hash_set.strict_add seen blk) then s
else
let s =
let f s j = fold_cfg_ s j.dst in
match blk.term with
| Switch {tbl; els; _} ->
let s = Vector.fold ~f:(fun s (_, j) -> f s j) ~init:s tbl in
f s els
| Iswitch {tbl; _} -> Vector.fold ~f ~init:s tbl
| Call {return; throw; _} ->
let s = f s return in
Option.fold ~f ~init:s throw
| Return _ | Throw _ | Unreachable -> s
in
f s blk
in
fold_cfg_ init func.entry
let fold_term func ~init ~f =
fold_cfg func ~init ~f:(fun s blk -> f s blk.term)
let iter_term func ~f =
fold_cfg func ~init:() ~f:(fun () blk -> f blk.term)
let entry_cfg func = fold_cfg ~init:[] ~f:(fun cfg blk -> blk :: cfg) func
let pp fs func =
let {name; formals; freturn; entry; _} = func in
let {cmnd; term; sort_index; _} = entry in
let pp_if cnd str fs = if cnd then Format.fprintf fs str in
Format.fprintf fs "@[<v>@[<v>%a%a@[<2>%a%a@]%t@]"
(Option.pp "%a " Typ.pp)
( match name.typ with
| Pointer {elt= Function {return; _}} -> return
| _ -> None )
(Option.pp " %a := " Reg.pp)
freturn Global.pp name (pp_actuals pp_formal) formals
(fun fs ->
if is_undefined func then Format.fprintf fs " #%i@]" sort_index
else
let cfg =
List.sort ~compare:Block.compare (List.tl_exn (entry_cfg func))
in
Format.fprintf fs " { #%i %a@;<1 4>@[<v>%a@ %a@]%t%a@]@ }"
sort_index Loc.pp name.loc pp_cmnd cmnd Term.pp term
(pp_if (not (List.is_empty cfg)) "@ @ ")
(List.pp "@\n@\n " Block.pp)
cfg )
let invariant func =
Invariant.invariant [%here] func [%sexp_of: t]
@@ fun () ->
assert (func == func.entry.parent) ;
match func.name.typ with
| Pointer {elt= Function {return; _}; _} ->
assert (
not
(List.contains_dup (entry_cfg func) ~compare:(fun b1 b2 ->
String.compare b1.lbl b2.lbl )) ) ;
assert (Bool.(Option.is_some return = Option.is_some func.freturn)) ;
iter_term func ~f:(fun term -> Term.invariant ~parent:func term)
| _ -> assert false
let find functions name = String.Map.find functions name
let mk ~(name : Global.t) ~formals ~freturn ~fthrow ~entry ~cfg =
let locals =
let locals_cmnd locals cmnd =
Vector.fold_right ~f:Inst.union_locals cmnd ~init:locals
in
let locals_block locals block =
locals_cmnd (Term.union_locals block.term locals) block.cmnd
in
let init = locals_block Reg.Set.empty entry in
Vector.fold ~f:locals_block cfg ~init
in
let func = {name; formals; freturn; fthrow; locals; entry} in
let resolve_parent_and_jumps block =
block.parent <- func ;
let lookup cfg lbl : block =
Vector.find_exn cfg ~f:(fun k -> String.equal lbl k.lbl)
in
let set_dst jmp = jmp.dst <- lookup cfg jmp.dst.lbl in
match block.term with
| Switch {tbl; els; _} ->
Vector.iter tbl ~f:(fun (_, jmp) -> set_dst jmp) ;
set_dst els
| Iswitch {tbl; _} -> Vector.iter tbl ~f:set_dst
| Call {return; throw; _} ->
set_dst return ;
Option.iter throw ~f:set_dst
| Return _ | Throw _ | Unreachable -> ()
in
resolve_parent_and_jumps entry ;
Vector.iter cfg ~f:resolve_parent_and_jumps ;
func |> check invariant
let mk_undefined ~name ~formals ~freturn ~fthrow =
let entry =
Block.mk ~lbl:"" ~cmnd:Vector.empty ~term:Term.unreachable
in
let cfg = Vector.empty in
mk ~name ~entry ~formals ~freturn ~fthrow ~cfg
end
(** Derived meta-data *)
let set_derived_metadata functions =
let compute_roots functions =
let roots = FuncQ.create () in
String.Map.iter functions ~f:(fun func ->
FuncQ.enqueue_back_exn roots func.name.reg func ) ;
String.Map.iter functions ~f:(fun func ->
Func.fold_term func ~init:() ~f:(fun () -> function
| Call {callee; _} -> (
match Reg.of_exp callee with
| Some callee ->
FuncQ.remove roots callee |> (ignore : [> ] -> unit)
| None -> () )
| _ -> () ) ) ;
roots
in
let topsort functions roots =
let tips_to_roots = BlockQ.create () in
let rec visit ancestors func src =
if BlockQ.mem tips_to_roots src then ()
else
let ancestors = Set.add ancestors src in
let jump jmp =
if Set.mem ancestors jmp.dst then jmp.retreating <- true
else visit ancestors func jmp.dst
in
( match src.term with
| Switch {tbl; els; _} ->
Vector.iter tbl ~f:(fun (_, jmp) -> jump jmp) ;
jump els
| Iswitch {tbl; _} -> Vector.iter tbl ~f:jump
| Call ({callee; return; throw; _} as call) ->
( match
Option.bind ~f:(Func.find functions)
(Option.map ~f:Reg.name (Reg.of_exp callee))
with
| Some func ->
if Set.mem ancestors func.entry then call.recursive <- true
else visit ancestors func func.entry
| None ->
(* conservatively assume all virtual calls are recursive *)
call.recursive <- true ) ;
jump return ; Option.iter ~f:jump throw
| Return _ | Throw _ | Unreachable -> () ) ;
BlockQ.enqueue_back_exn tips_to_roots src ()
in
FuncQ.iter roots ~f:(fun root ->
visit Block_label.empty_set root root.entry ) ;
tips_to_roots
in
let set_sort_indices tips_to_roots =
let index = ref (BlockQ.length tips_to_roots) in
BlockQ.iteri tips_to_roots ~f:(fun ~key:block ~data:_ ->
block.sort_index <- !index ;
index := !index - 1 )
in
let functions =
List.fold functions ~init:String.Map.empty ~f:(fun m func ->
String.Map.add_exn m ~key:(Reg.name func.name.reg) ~data:func )
in
let roots = compute_roots functions in
let tips_to_roots = topsort functions roots in
set_sort_indices tips_to_roots ;
functions
let invariant pgm =
Invariant.invariant [%here] pgm [%sexp_of: t]
@@ fun () ->
assert (
not
(Vector.contains_dup pgm.globals ~compare:(fun g1 g2 ->
Reg.compare g1.Global.reg g2.Global.reg )) )
let mk ~globals ~functions =
{ globals= Vector.of_list_rev globals
; functions= set_derived_metadata functions }
|> check invariant
let pp fs {globals; functions} =
Format.fprintf fs "@[<v>@[%a@]@ @ @ @[%a@]@]"
(Vector.pp "@\n@\n" Global.pp_defn)
globals
(List.pp "@\n@\n" Func.pp)
( String.Map.data functions
|> List.sort ~compare:(fun x y -> compare_block x.entry y.entry) )