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(*
* Copyright (c) 2016 - present Facebook, Inc.
* All rights reserved.
*
* This source code is licensed under the BSD style license found in the
* LICENSE file in the root directory of this source tree. An additional grant
* of patent rights can be found in the PATENTS file in the same directory.
*)
open! IStd
module F = Format
module L = Logging
module type S = sig
module TraceDomain : AbstractDomain.WithBottom
module AccessMap : PrettyPrintable.PPMap with type key = AccessPath.access
module BaseMap = AccessPath.BaseMap
type node = TraceDomain.astate * tree
and tree = Subtree of node AccessMap.t | Star
type t = node BaseMap.t
include AbstractDomain.WithBottom with type astate = t
val empty_node : node
val make_node : TraceDomain.astate -> node AccessMap.t -> node
val make_access_node : TraceDomain.astate -> AccessPath.access -> TraceDomain.astate -> node
val make_normal_leaf : TraceDomain.astate -> node
val make_starred_leaf : TraceDomain.astate -> node
val get_node : AccessPath.Abs.t -> t -> node option
val get_trace : AccessPath.Abs.t -> t -> TraceDomain.astate option
val add_node : AccessPath.Abs.t -> node -> t -> t
val add_trace : AccessPath.Abs.t -> TraceDomain.astate -> t -> t
val node_join : node -> node -> node
val fold : ('a -> AccessPath.Abs.t -> node -> 'a) -> t -> 'a -> 'a
val trace_fold : ('a -> AccessPath.Abs.t -> TraceDomain.astate -> 'a) -> t -> 'a -> 'a
val pp_node : F.formatter -> node -> unit
end
module Make (TraceDomain : AbstractDomain.WithBottom) = struct
module TraceDomain = TraceDomain
module AccessMap = PrettyPrintable.MakePPMap (struct
type t = AccessPath.access
let compare a1 a2 =
match (a1, a2) with
| AccessPath.ArrayAccess (t1, _), AccessPath.ArrayAccess (t2, _)
-> (* ignore indexes *)
Typ.compare t1 t2
| _
-> AccessPath.compare_access a1 a2
let pp = AccessPath.pp_access
end)
module BaseMap = AccessPath.BaseMap
type node = (TraceDomain.astate * tree)
and tree = Subtree of node AccessMap.t | Star
type t = node BaseMap.t
type astate = t
let empty = BaseMap.empty
let make_node trace subtree = (trace, Subtree subtree)
let empty_node = make_node TraceDomain.empty AccessMap.empty
let make_normal_leaf trace = make_node trace AccessMap.empty
let make_starred_leaf trace = (trace, Star)
let make_access_node base_trace access trace =
make_node base_trace (AccessMap.singleton access (make_normal_leaf trace))
(** find all of the traces in the subtree and join them with [orig_trace] *)
let rec join_all_traces orig_trace = function
| Subtree subtree
-> let join_all_traces_ orig_trace tree =
let node_join_traces _ (trace, node) trace_acc =
join_all_traces (TraceDomain.join trace_acc trace) node
in
AccessMap.fold node_join_traces tree orig_trace
in
join_all_traces_ orig_trace subtree
| Star
-> orig_trace
let get_node ap tree =
let rec accesses_get_node access_list trace tree =
match (access_list, tree) with
| _, Star
-> (trace, Star)
| [], (Subtree _ as tree)
-> (trace, tree)
| access :: accesses, Subtree subtree
-> let access_trace, access_subtree = AccessMap.find access subtree in
accesses_get_node accesses access_trace access_subtree
in
let get_node_ base accesses tree =
let base_trace, base_tree = BaseMap.find base tree in
accesses_get_node accesses base_trace base_tree
in
let base, accesses = AccessPath.Abs.extract ap in
match get_node_ base accesses tree with
| trace, subtree
-> if AccessPath.Abs.is_exact ap then Some (trace, subtree)
else
(* input query was [ap]*, and [trace] is the trace associated with [ap]. get the traces
associated with the children of [ap] in [tree] and join them with [trace] *)
Some (join_all_traces trace subtree, subtree)
| exception Not_found
-> None
let get_trace ap tree = Option.map ~f:fst (get_node ap tree)
let rec access_tree_lteq (lhs_trace, lhs_tree as lhs) (rhs_trace, rhs_tree as rhs) =
if phys_equal lhs rhs then true
else TraceDomain.( <= ) ~lhs:lhs_trace ~rhs:rhs_trace
&&
match (lhs_tree, rhs_tree) with
| Subtree lhs_subtree, Subtree rhs_subtree
-> AccessMap.for_all
(fun k lhs_v ->
try
let rhs_v = AccessMap.find k rhs_subtree in
access_tree_lteq lhs_v rhs_v
with Not_found -> false)
lhs_subtree
| _, Star
-> true
| Star, Subtree _
-> false
let ( <= ) ~lhs ~rhs =
if phys_equal lhs rhs then true
else
BaseMap.for_all
(fun k lhs_v ->
try
let rhs_v = BaseMap.find k rhs in
access_tree_lteq lhs_v rhs_v
with Not_found -> false)
lhs
let node_join_ f_node_merge f_trace_merge (trace1, tree1 as node1) (trace2, tree2 as node2) =
if phys_equal node1 node2 then node1
else
let trace' = f_trace_merge trace1 trace2 in
(* note: this is much-uglified by address equality optimization checks. skip to the else cases
for the actual semantics *)
match (tree1, tree2) with
| Subtree subtree1, Subtree subtree2
-> let tree' = AccessMap.merge (fun _ v1 v2 -> f_node_merge v1 v2) subtree1 subtree2 in
if phys_equal trace' trace1 && phys_equal tree' subtree1 then node1
else if phys_equal trace' trace2 && phys_equal tree' subtree2 then node2
else (trace', Subtree tree')
| Star, t
-> (* vacuum up all the traces associated with the subtree t and join them with trace' *)
let trace'' = join_all_traces trace' t in
if phys_equal trace'' trace1 then node1 else (trace'', Star)
| t, Star
-> (* same as above, but kind-of duplicated to allow address equality optimization *)
let trace'' = join_all_traces trace' t in
if phys_equal trace'' trace2 then node2 else (trace'', Star)
let rec node_join node1 node2 = node_join_ node_merge TraceDomain.join node1 node2
and node_merge node1_opt node2_opt =
match (node1_opt, node2_opt) with
| Some node1, Some node2
-> let joined_node = node_join node1 node2 in
if phys_equal joined_node node1 then node1_opt
else if phys_equal joined_node node2 then node2_opt
else Some joined_node
| None, node_opt | node_opt, None
-> node_opt
(* helper for [add_access]. [last_trace] is the trace associated with [tree] in the parent. *)
let access_tree_add_trace ~node_to_add ~seen_array_access ~is_exact accesses node =
let rec access_tree_add_trace_ ~seen_array_access accesses node =
match (accesses, node) with
| [], (trace, tree) -> (
match (is_exact, seen_array_access) with
| true, false
-> (* adding x.f, do strong update on both subtree and its traces *)
node_to_add
| true, true
-> (* adding x[_], do weak update on subtree and on its immediate trace *)
node_join node_to_add node
| _
-> (* adding x.f* or x[_]*, join with traces of subtree and replace it with * *)
let node_trace, node_tree = node_to_add in
let trace' = join_all_traces (TraceDomain.join trace node_trace) tree in
make_starred_leaf (join_all_traces trace' node_tree) )
| _, (_, Star)
-> node_join node_to_add node
| access :: accesses, (trace, Subtree subtree)
-> let access_node =
try AccessMap.find access subtree
with Not_found -> make_normal_leaf TraceDomain.empty
in
(* once we encounter a subtree rooted in an array access, we have to do weak updates in
the entire subtree. the reason: if I do x[i].f.g = <interesting trace>, then
x[j].f.g = <empty trace>, I don't want to overwrite <interesting trace>. instead, I
should get <interesting trace> |_| <empty trace> *)
let seen_array_access =
seen_array_access
||
match access with
| AccessPath.ArrayAccess _
-> true
| AccessPath.FieldAccess _
-> false
in
let access_node' = access_tree_add_trace_ ~seen_array_access accesses access_node in
(trace, Subtree (AccessMap.add access access_node' subtree))
in
access_tree_add_trace_ ~seen_array_access accesses node
let add_node ap node_to_add tree =
let base, accesses = AccessPath.Abs.extract ap in
let is_exact = AccessPath.Abs.is_exact ap in
let base_node =
try BaseMap.find base tree
with Not_found -> make_normal_leaf TraceDomain.empty
in
let base_node' =
access_tree_add_trace ~node_to_add ~seen_array_access:false ~is_exact accesses base_node
in
BaseMap.add base base_node' tree
let add_trace ap trace tree = add_node ap (make_normal_leaf trace) tree
let join tree1 tree2 =
if phys_equal tree1 tree2 then tree1
else BaseMap.merge (fun _ n1 n2 -> node_merge n1 n2) tree1 tree2
let rec access_map_fold_ f base accesses m acc =
AccessMap.fold (fun access node acc -> node_fold_ f base (accesses @ [access]) node acc) m acc
and node_fold_ f base accesses (_, tree as node) acc =
let cur_ap_raw = (base, accesses) in
match tree with
| Subtree access_map
-> let acc' = f acc (AccessPath.Abs.Exact cur_ap_raw) node in
access_map_fold_ f base accesses access_map acc'
| Star
-> f acc (AccessPath.Abs.Abstracted cur_ap_raw) node
let node_fold (f: 'a -> AccessPath.Abs.t -> node -> 'a) base node acc =
node_fold_ f base [] node acc
let fold (f: 'a -> AccessPath.Abs.t -> node -> 'a) tree acc_ =
BaseMap.fold (fun base node acc -> node_fold f base node acc) tree acc_
let trace_fold (f: 'a -> AccessPath.Abs.t -> TraceDomain.astate -> 'a) =
let f_ acc ap (trace, _) = f acc ap trace in
fold f_
(* replace the normal leaves of [node] with starred leaves *)
let rec node_add_stars (trace, tree as node) =
match tree with
| Subtree subtree
-> if AccessMap.is_empty subtree then make_starred_leaf trace
else
let subtree' = AccessMap.map node_add_stars subtree in
if phys_equal subtree' subtree then node else (trace, Subtree subtree')
| Star
-> node
let widen ~prev ~next ~num_iters =
if phys_equal prev next then prev
else
let trace_widen prev next = TraceDomain.widen ~prev ~next ~num_iters in
let rec node_widen prev_node_opt next_node_opt =
match (prev_node_opt, next_node_opt) with
| Some prev_node, Some next_node
-> let widened_node = node_join_ node_widen trace_widen prev_node next_node in
if phys_equal widened_node prev_node then prev_node_opt
else if phys_equal widened_node next_node then next_node_opt
else Some widened_node
| None, Some next_node
-> let widened_node = node_add_stars next_node in
if phys_equal widened_node next_node then next_node_opt else Some widened_node
| Some _, None | None, None
-> prev_node_opt
in
BaseMap.merge (fun _ prev_node next_node -> node_widen prev_node next_node) prev next
let rec pp_node fmt (trace, subtree) =
let pp_subtree fmt = function
| Subtree access_map
-> AccessMap.pp ~pp_value:pp_node fmt access_map
| Star
-> F.fprintf fmt "*"
in
F.fprintf fmt "(%a, %a)" TraceDomain.pp trace pp_subtree subtree
let pp fmt base_tree = BaseMap.pp ~pp_value:pp_node fmt base_tree
end