[racerd] new lock domain

Summary:
The boolean lock domain is simple and surprisingly effective.
But it's starting to cause false positives in the case where locks are nested.
Releasing the inner lock also releases the outer lock.

This diff introduces a new locks domain: a map of locks (access paths) to a bounded count representing an underapproximation of the number of times the lock has been acquired.

For now, we just use a single dummy access path to represent all locks (and thus a count actually would have been sufficiently expressive; we don't need the map yet).
But I'm planning to remove this limitation in a follow-up by refactoring the lock models to give us an access path.
Knowing the names of locks could be useful for error messages and suggesting fixes.

Reviewed By: jberdine

Differential Revision: D6182006

fbshipit-source-id: 6624971
master
Sam Blackshear 7 years ago committed by Facebook Github Bot
parent 315db072ac
commit 584b10647d

@ -298,3 +298,34 @@ module BooleanOr = struct
let pp fmt astate = F.fprintf fmt "%b" astate let pp fmt astate = F.fprintf fmt "%b" astate
end end
module type MaxCount = sig
val max : int
end
module CountDomain (MaxCount : MaxCount) = struct
type astate = int
let top =
assert (MaxCount.max > 0) ;
MaxCount.max
let empty = 0
let is_top = Int.equal top
let is_empty = Int.equal empty
let ( <= ) ~lhs ~rhs = lhs <= rhs
let join astate1 astate2 = Int.min top (Int.max astate1 astate2)
let widen ~prev ~next ~num_iters:_ = join prev next
let increment astate = if is_top astate then top else astate + 1
let decrement astate = if is_empty astate then empty else astate - 1
let pp = Int.pp
end

@ -108,3 +108,26 @@ module BooleanAnd : S with type astate = bool
(** Boolean domain ordered by ~p || q. Useful when you want a boolean that's true only when it's (** Boolean domain ordered by ~p || q. Useful when you want a boolean that's true only when it's
true in one conditional branch. *) true in one conditional branch. *)
module BooleanOr : WithBottom with type astate = bool module BooleanOr : WithBottom with type astate = bool
module type MaxCount = sig
val max : int
(** must be positive *)
end
(** Domain keeping a non-negative count with a bounded maximum value. The count can be only
incremented and decremented *)
module CountDomain (MaxCount : MaxCount) : sig
include WithBottom with type astate = private int
val top : astate [@@warning "-32"]
(** maximum value *)
val is_top : astate -> bool [@@warning "-32"]
(** return true if this is the maximum value *)
val increment : astate -> astate
(** bump the count by one if it is less than the max *)
val decrement : astate -> astate
(** descrease the count by one if it is greater than 0 *)
end

@ -365,7 +365,7 @@ module TransferFunctions (CFG : ProcCfg.S) = struct
OwnershipAbstractValue.unowned OwnershipAbstractValue.unowned
in in
Some Some
{ locks= false { locks= LocksDomain.empty
; threads= ThreadsDomain.empty ; threads= ThreadsDomain.empty
; accesses= callee_accesses ; accesses= callee_accesses
; return_ownership ; return_ownership
@ -531,7 +531,7 @@ module TransferFunctions (CFG : ProcCfg.S) = struct
in in
if AccessData.Precondition.is_true ownership_precondition' then accesses_acc if AccessData.Precondition.is_true ownership_precondition' then accesses_acc
else else
let locks' = locks || pre.lock in let locks' = if pre.lock then LocksDomain.add_lock locks else locks in
(* if the access occurred on a main thread in the callee, we should remember this when (* if the access occurred on a main thread in the callee, we should remember this when
moving it to the callee. if we don't know what thread it ran on, use the caller's moving it to the callee. if we don't know what thread it ran on, use the caller's
thread *) thread *)
@ -604,9 +604,13 @@ module TransferFunctions (CFG : ProcCfg.S) = struct
in in
match Models.get_lock callee_pname actuals with match Models.get_lock callee_pname actuals with
| Lock -> | Lock ->
{astate with locks= true; threads= update_for_lock_use astate.threads} { astate with
locks= LocksDomain.add_lock astate.locks
; threads= update_for_lock_use astate.threads }
| Unlock -> | Unlock ->
{astate with locks= false; threads= update_for_lock_use astate.threads} { astate with
locks= LocksDomain.remove_lock astate.locks
; threads= update_for_lock_use astate.threads }
| LockedIfTrue -> ( | LockedIfTrue -> (
match ret_opt with match ret_opt with
| Some ret_access_path -> | Some ret_access_path ->
@ -631,7 +635,7 @@ module TransferFunctions (CFG : ProcCfg.S) = struct
{summary with accesses= rebased_accesses} ) {summary with accesses= rebased_accesses} )
with with
| Some {threads; locks; accesses; return_ownership; return_attributes} -> | Some {threads; locks; accesses; return_ownership; return_attributes} ->
let locks = locks || astate.locks in let locks = LocksDomain.join locks astate.locks in
let threads = let threads =
match (astate.threads, threads) with match (astate.threads, threads) with
| _, ThreadsDomain.AnyThreadButSelf | AnyThreadButSelf, _ -> | _, ThreadsDomain.AnyThreadButSelf | AnyThreadButSelf, _ ->
@ -767,7 +771,10 @@ module TransferFunctions (CFG : ProcCfg.S) = struct
in in
let add_choice bool_value (acc: Domain.astate) = function let add_choice bool_value (acc: Domain.astate) = function
| Choice.LockHeld -> | Choice.LockHeld ->
let locks = bool_value in let locks =
if bool_value then LocksDomain.add_lock acc.locks
else LocksDomain.remove_lock acc.locks
in
{acc with locks} {acc with locks}
| Choice.OnMainThread -> | Choice.OnMainThread ->
let threads = let threads =
@ -916,7 +923,7 @@ let is_marked_thread_safe pdesc tenv =
let empty_post : RacerDDomain.summary = let empty_post : RacerDDomain.summary =
{ threads= RacerDDomain.ThreadsDomain.empty { threads= RacerDDomain.ThreadsDomain.empty
; locks= false ; locks= RacerDDomain.LocksDomain.empty
; accesses= RacerDDomain.AccessDomain.empty ; accesses= RacerDDomain.AccessDomain.empty
; return_ownership= RacerDDomain.OwnershipAbstractValue.unowned ; return_ownership= RacerDDomain.OwnershipAbstractValue.unowned
; return_attributes= RacerDDomain.AttributeSetDomain.empty } ; return_attributes= RacerDDomain.AttributeSetDomain.empty }

@ -151,14 +151,37 @@ module TraceElem = struct
make (Access.InterfaceCall pname) site make (Access.InterfaceCall pname) site
end end
(* In this domain true<=false. The intended denotations [[.]] are module LockCount = AbstractDomain.CountDomain (struct
[[true]] = the set of all states where we know according, to annotations let max = 5
or assertions or lock instructions, that some lock is held.
[[false]] = the empty set (* arbitrary threshold for max locks we expect to be held simultaneously *)
The use of && for join in this domain enforces that, to know a lock is held, one must hold in end)
all branches.
*) module LocksDomain = struct
module LocksDomain = AbstractDomain.BooleanAnd include AbstractDomain.Map (AccessPath) (LockCount)
(* TODO: eventually, we'll ask add_lock/remove_lock to pass the lock name. for now, this is a hack
to model having a single lock used everywhere *)
let the_only_lock = ((Var.of_id (Ident.create Ident.knormal 0), Typ.void_star), [])
let is_locked astate =
(* we only add locks with positive count, so safe to just check emptiness *)
not (is_empty astate)
let add_lock astate =
let count = try find the_only_lock astate with Not_found -> LockCount.empty in
add the_only_lock (LockCount.increment count) astate
let remove_lock astate =
try
let count = find the_only_lock astate in
let count' = LockCount.decrement count in
if LockCount.is_empty count' then remove the_only_lock astate
else add the_only_lock count' astate
with Not_found -> astate
end
module ThreadsDomain = struct module ThreadsDomain = struct
type astate = NoThread | AnyThreadButSelf | AnyThread [@@deriving compare] type astate = NoThread | AnyThreadButSelf | AnyThread [@@deriving compare]
@ -379,12 +402,12 @@ module AccessData = struct
type t = {thread: bool; lock: bool; ownership_precondition: Precondition.t} [@@deriving compare] type t = {thread: bool; lock: bool; ownership_precondition: Precondition.t} [@@deriving compare]
let make locks threads ownership_precondition pdesc = let make lock threads ownership_precondition pdesc =
(* shouldn't be creating metadata for accesses that are known to be owned; we should discard (* shouldn't be creating metadata for accesses that are known to be owned; we should discard
such accesses *) such accesses *)
assert (not (Precondition.is_true ownership_precondition)) ; assert (not (Precondition.is_true ownership_precondition)) ;
let thread = ThreadsDomain.is_any_but_self threads in let thread = ThreadsDomain.is_any_but_self threads in
let lock = locks || Procdesc.is_java_synchronized pdesc in let lock = LocksDomain.is_locked lock || Procdesc.is_java_synchronized pdesc in
{thread; lock; ownership_precondition} {thread; lock; ownership_precondition}
@ -417,7 +440,7 @@ type astate =
let empty = let empty =
let threads = ThreadsDomain.empty in let threads = ThreadsDomain.empty in
let locks = false in let locks = LocksDomain.empty in
let accesses = AccessDomain.empty in let accesses = AccessDomain.empty in
let ownership = OwnershipDomain.empty in let ownership = OwnershipDomain.empty in
let attribute_map = AttributeMapDomain.empty in let attribute_map = AttributeMapDomain.empty in
@ -425,7 +448,7 @@ let empty =
let is_empty {threads; locks; accesses; ownership; attribute_map} = let is_empty {threads; locks; accesses; ownership; attribute_map} =
ThreadsDomain.is_empty threads && not locks && AccessDomain.is_empty accesses ThreadsDomain.is_empty threads && LocksDomain.is_empty locks && AccessDomain.is_empty accesses
&& OwnershipDomain.is_empty ownership && AttributeMapDomain.is_empty attribute_map && OwnershipDomain.is_empty ownership && AttributeMapDomain.is_empty attribute_map

@ -51,12 +51,20 @@ module TraceElem : sig
val make_unannotated_call_access : Typ.Procname.t -> Location.t -> t val make_unannotated_call_access : Typ.Procname.t -> Location.t -> t
end end
(** A bool that is true if a lock is definitely held. Note that this is unsound because it assumes (** Overapproximation of number of locks that are currently held *)
the existence of one global lock. In the case that a lock is held on the access to a variable, module LocksDomain : sig
but the lock held is the wrong one, we will erroneously say that the access is thread-safe. include AbstractDomain.WithBottom
However, this coarse abstraction saves us from the complexity of tracking which locks are held
and which memory locations correspond to the same lock. *) val is_locked : astate -> bool
module LocksDomain : AbstractDomain.S with type astate = bool [@@warning "-32"]
(** returns true if the number of locks held is greater than zero or Top *)
val add_lock : astate -> astate
(** record acquisition of a lock *)
val remove_lock : astate -> astate
(** record release of a lock *)
end
(** Abstraction of threads that may run in parallel with the current thread. (** Abstraction of threads that may run in parallel with the current thread.
NoThread < AnyThreadExceptSelf < AnyThread *) NoThread < AnyThreadExceptSelf < AnyThread *)

@ -54,12 +54,44 @@ class Basic {
int read_array_outside_lock_ok(char* arr2, int i) { return arr2[i]; } int read_array_outside_lock_ok(char* arr2, int i) { return arr2[i]; }
void set_double(int new_value) {
mutex_.lock();
mutex_2.lock();
double_lock_guarded = new_value;
mutex_2.unlock();
single_lock_guarded = new_value;
single_lock_suspiciously_read = new_value;
mutex_.unlock();
}
int test_double_lock_1_ok() {
int result;
mutex_2.lock();
result = double_lock_guarded;
mutex_2.unlock();
return result;
}
int test_double_lock_2_ok() {
int result;
mutex_.lock();
result = single_lock_guarded;
mutex_.unlock();
return result;
}
int test_double_lock_bad() { return single_lock_suspiciously_read; }
private: private:
int well_guarded; int well_guarded;
int suspiciously_read; int suspiciously_read;
int suspiciously_written; int suspiciously_written;
int not_guarded; int not_guarded;
int double_lock_guarded;
int single_lock_guarded;
int single_lock_suspiciously_read;
std::mutex mutex_; std::mutex mutex_;
std::mutex mutex_2;
int get_private_suspiciously_read() { return suspiciously_read; } int get_private_suspiciously_read() { return suspiciously_read; }
}; };

@ -1,6 +1,7 @@
codetoanalyze/cpp/racerd/basics.cpp, basics::Basic_get2, 3, LOCK_CONSISTENCY_VIOLATION, [<Read trace>,access to `&this.suspiciously_written`,<Write trace>,access to `&this.suspiciously_written`] codetoanalyze/cpp/racerd/basics.cpp, basics::Basic_get2, 3, LOCK_CONSISTENCY_VIOLATION, [<Read trace>,access to `&this.suspiciously_written`,<Write trace>,access to `&this.suspiciously_written`]
codetoanalyze/cpp/racerd/basics.cpp, basics::Basic_get4, 0, LOCK_CONSISTENCY_VIOLATION, [<Read trace>,access to `&this.suspiciously_read`,<Write trace>,access to `&this.suspiciously_read`] codetoanalyze/cpp/racerd/basics.cpp, basics::Basic_get4, 0, LOCK_CONSISTENCY_VIOLATION, [<Read trace>,access to `&this.suspiciously_read`,<Write trace>,access to `&this.suspiciously_read`]
codetoanalyze/cpp/racerd/basics.cpp, basics::Basic_get5, 0, LOCK_CONSISTENCY_VIOLATION, [<Read trace>,call to basics::Basic_get_private_suspiciously_read,access to `&this.suspiciously_read`,<Write trace>,access to `&this.suspiciously_read`] codetoanalyze/cpp/racerd/basics.cpp, basics::Basic_get5, 0, LOCK_CONSISTENCY_VIOLATION, [<Read trace>,call to basics::Basic_get_private_suspiciously_read,access to `&this.suspiciously_read`,<Write trace>,access to `&this.suspiciously_read`]
codetoanalyze/cpp/racerd/basics.cpp, basics::Basic_test_double_lock_bad, 0, LOCK_CONSISTENCY_VIOLATION, [<Read trace>,access to `&this.single_lock_suspiciously_read`,<Write trace>,access to `&this.single_lock_suspiciously_read`]
codetoanalyze/cpp/racerd/constructor_ownership.cpp, constructors::TSL_not_locked_race, 0, LOCK_CONSISTENCY_VIOLATION, [<Read trace>,call to constructors::BSS_toJson_race,call to constructors::dynamic_operator=,access to `&this.type_`,<Write trace>,call to constructors::BSS_toJson_race,call to constructors::dynamic_operator=,access to `&this.type_`] codetoanalyze/cpp/racerd/constructor_ownership.cpp, constructors::TSL_not_locked_race, 0, LOCK_CONSISTENCY_VIOLATION, [<Read trace>,call to constructors::BSS_toJson_race,call to constructors::dynamic_operator=,access to `&this.type_`,<Write trace>,call to constructors::BSS_toJson_race,call to constructors::dynamic_operator=,access to `&this.type_`]
codetoanalyze/cpp/racerd/locals_ownership.cpp, locals::Ownership_test2_bad, 5, LOCK_CONSISTENCY_VIOLATION, [<Read trace>,access to `&x.f`,<Write trace>,access to `&x.f`] codetoanalyze/cpp/racerd/locals_ownership.cpp, locals::Ownership_test2_bad, 5, LOCK_CONSISTENCY_VIOLATION, [<Read trace>,access to `&x.f`,<Write trace>,access to `&x.f`]
codetoanalyze/cpp/racerd/locals_ownership.cpp, locals::Ownership_test3_bad, 5, LOCK_CONSISTENCY_VIOLATION, [<Read trace>,access to `&x.f`,<Write trace>,access to `&x.f`] codetoanalyze/cpp/racerd/locals_ownership.cpp, locals::Ownership_test3_bad, 5, LOCK_CONSISTENCY_VIOLATION, [<Read trace>,access to `&x.f`,<Write trace>,access to `&x.f`]

@ -25,7 +25,8 @@ public class Locks {
ReentrantLock mReentrantLock; ReentrantLock mReentrantLock;
ReentrantReadWriteLock mReentrantReadWriteLock; ReentrantReadWriteLock mReentrantReadWriteLock;
public void lockInOneBranchBad(boolean b) { // we allow this for now
public void FN_lockInOneBranchBad(boolean b) {
if (b) { if (b) {
mLock.lock(); mLock.lock();
} }
@ -164,8 +165,111 @@ public class Locks {
mLock.unlock(); mLock.unlock();
} }
// our "squish all locks into one" abstraction is not ideal here... void nested1Ok() {
public void FP_unlockOneLock() { synchronized (this) {
synchronized (this) {
}
// a bad abstraction of locks will treat this as unlocked...
f = 32;
}
}
void nested2Ok() {
synchronized (this) {
synchronized (this) {
f = 32;
}
}
}
void nested3Ok() {
synchronized (this) {
f = 32;
synchronized (this) {
}
}
}
void nested1Bad() {
synchronized (this) {
synchronized (this) {
}
}
f = 32;
}
void nested2Bad() {
synchronized (this) {
}
f = 32;
synchronized (this) {
}
}
void nested3Bad() {
synchronized (this) {
}
synchronized (this) {
}
f = 32;
}
void useLock() {
synchronized (this) {
}
}
void useLockInCalleeBad() {
useLock();
f = 32;
}
void lockInLoopOk(int i) {
while (i > 0) {
i++;
mLock.lock();
}
f = 32;
}
void unlockInLoopOk(int i) {
mLock.lock();
while (i > 0) {
i++;
mLock.unlock();
}
f = 32;
}
void lockInLoopLexicalBad(int i) {
while (i > 0) {
i++;
synchronized(this) {
}
}
f = 32;
}
void lockInLoopLexicalOk(int i) {
while (i > 0) {
i++;
synchronized(this) {
f = 32;
}
}
}
void loopInLockLexicalBad(int i) {
synchronized(this) {
while (i > 0) {
i++;
}
f = 32;
}
}
public void unlockOneLockOk() {
mLock.lock(); mLock.lock();
mReentrantLock.lock(); mReentrantLock.lock();
mReentrantLock.unlock(); mReentrantLock.unlock();

@ -56,14 +56,17 @@ codetoanalyze/java/racerd/Inference.java, int Inference.unprotectedRead2Bad(), 1
codetoanalyze/java/racerd/Locks.java, Object Locks.unownedReadBad(), 1, THREAD_SAFETY_VIOLATION, [<Read trace>,access to `&this.codetoanalyze.java.checkers.Locks.mField3`,<Write trace>,call to void Locks.lockedWriteInCallee2(),access to `&this.codetoanalyze.java.checkers.Locks.mField3`] codetoanalyze/java/racerd/Locks.java, Object Locks.unownedReadBad(), 1, THREAD_SAFETY_VIOLATION, [<Read trace>,access to `&this.codetoanalyze.java.checkers.Locks.mField3`,<Write trace>,call to void Locks.lockedWriteInCallee2(),access to `&this.codetoanalyze.java.checkers.Locks.mField3`]
codetoanalyze/java/racerd/Locks.java, boolean Locks.readOutsideLock1Bad(), 3, THREAD_SAFETY_VIOLATION, [<Read trace>,access to `&this.codetoanalyze.java.checkers.Locks.mField`,<Write trace>,access to `&this.codetoanalyze.java.checkers.Locks.mField`] codetoanalyze/java/racerd/Locks.java, boolean Locks.readOutsideLock1Bad(), 3, THREAD_SAFETY_VIOLATION, [<Read trace>,access to `&this.codetoanalyze.java.checkers.Locks.mField`,<Write trace>,access to `&this.codetoanalyze.java.checkers.Locks.mField`]
codetoanalyze/java/racerd/Locks.java, boolean Locks.readOutsideLock2Bad(), 1, THREAD_SAFETY_VIOLATION, [<Read trace>,access to `&this.codetoanalyze.java.checkers.Locks.mField`,<Write trace>,access to `&this.codetoanalyze.java.checkers.Locks.mField`] codetoanalyze/java/racerd/Locks.java, boolean Locks.readOutsideLock2Bad(), 1, THREAD_SAFETY_VIOLATION, [<Read trace>,access to `&this.codetoanalyze.java.checkers.Locks.mField`,<Write trace>,access to `&this.codetoanalyze.java.checkers.Locks.mField`]
codetoanalyze/java/racerd/Locks.java, void Locks.FP_unlockOneLock(), 4, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`]
codetoanalyze/java/racerd/Locks.java, void Locks.afterReentrantLockUnlockBad(), 3, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`] codetoanalyze/java/racerd/Locks.java, void Locks.afterReentrantLockUnlockBad(), 3, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`]
codetoanalyze/java/racerd/Locks.java, void Locks.afterUnlockBad(), 3, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`] codetoanalyze/java/racerd/Locks.java, void Locks.afterUnlockBad(), 3, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`]
codetoanalyze/java/racerd/Locks.java, void Locks.afterWriteLockUnlockBad(), 3, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`] codetoanalyze/java/racerd/Locks.java, void Locks.afterWriteLockUnlockBad(), 3, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`]
codetoanalyze/java/racerd/Locks.java, void Locks.lockInOneBranchBad(boolean), 4, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`] codetoanalyze/java/racerd/Locks.java, void Locks.lockInLoopLexicalBad(int), 6, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`]
codetoanalyze/java/racerd/Locks.java, void Locks.negatedReentrantLockTryLockBad(), 2, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`] codetoanalyze/java/racerd/Locks.java, void Locks.negatedReentrantLockTryLockBad(), 2, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`]
codetoanalyze/java/racerd/Locks.java, void Locks.nested1Bad(), 5, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`]
codetoanalyze/java/racerd/Locks.java, void Locks.nested2Bad(), 3, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`]
codetoanalyze/java/racerd/Locks.java, void Locks.nested3Bad(), 5, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`]
codetoanalyze/java/racerd/Locks.java, void Locks.tryLockNoCheckBad(), 2, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`] codetoanalyze/java/racerd/Locks.java, void Locks.tryLockNoCheckBad(), 2, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`]
codetoanalyze/java/racerd/Locks.java, void Locks.tryLockWrongBranchBad(), 3, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`] codetoanalyze/java/racerd/Locks.java, void Locks.tryLockWrongBranchBad(), 3, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`]
codetoanalyze/java/racerd/Locks.java, void Locks.useLockInCalleeBad(), 2, THREAD_SAFETY_VIOLATION, [access to `&this.codetoanalyze.java.checkers.Locks.f`]
codetoanalyze/java/racerd/Ownership.java, Ownership.<init>(Obj,Object), 1, THREAD_SAFETY_VIOLATION, [access to `&obj.codetoanalyze.java.checkers.Obj.f`] codetoanalyze/java/racerd/Ownership.java, Ownership.<init>(Obj,Object), 1, THREAD_SAFETY_VIOLATION, [access to `&obj.codetoanalyze.java.checkers.Obj.f`]
codetoanalyze/java/racerd/Ownership.java, int Ownership.readGlobalBad(), 1, THREAD_SAFETY_VIOLATION, [<Read trace>,access to `&#GB<>$codetoanalyze.java.checkers.Ownership.codetoanalyze.java.checkers.Ownership.global`,<Write trace>,access to `&#GB<>$codetoanalyze.java.checkers.Ownership.codetoanalyze.java.checkers.Ownership.global`] codetoanalyze/java/racerd/Ownership.java, int Ownership.readGlobalBad(), 1, THREAD_SAFETY_VIOLATION, [<Read trace>,access to `&#GB<>$codetoanalyze.java.checkers.Ownership.codetoanalyze.java.checkers.Ownership.global`,<Write trace>,access to `&#GB<>$codetoanalyze.java.checkers.Ownership.codetoanalyze.java.checkers.Ownership.global`]
codetoanalyze/java/racerd/Ownership.java, void Ownership.cantOwnThisBad(), 1, THREAD_SAFETY_VIOLATION, [call to void Ownership.setField(Obj),access to `&this.codetoanalyze.java.checkers.Ownership.field`] codetoanalyze/java/racerd/Ownership.java, void Ownership.cantOwnThisBad(), 1, THREAD_SAFETY_VIOLATION, [call to void Ownership.setField(Obj),access to `&this.codetoanalyze.java.checkers.Ownership.field`]

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