com.google.inject.internal.CycleDetectingLock Maven / Gradle / Ivy
package com.google.inject.internal;
import com.google.common.base.Preconditions;
import com.google.common.base.Supplier;
import com.google.common.collect.ImmutableListMultimap;
import com.google.common.collect.LinkedHashMultimap;
import com.google.common.collect.ListMultimap;
import com.google.common.collect.Lists;
import com.google.common.collect.Maps;
import com.google.common.collect.Multimap;
import com.google.common.collect.Multimaps;
import java.util.Collection;
import java.util.LinkedHashMap;
import java.util.List;
import java.util.Map;
import java.util.concurrent.locks.Lock;
import java.util.concurrent.locks.ReentrantLock;
/**
* Simplified version of {@link Lock} that is special due to how it handles deadlocks detection.
*
* Is an inherent part of {@link SingletonScope}, moved into a upper level class due to its size
* and complexity.
*
* @param Lock identification provided by the client, is returned unmodified to the client when
* lock cycle is detected to identify it. Only toString() needs to be implemented. Lock
* references this object internally, for the purposes of Garbage Collection you should not use
* heavy IDs. Lock is referenced by a lock factory as long as it's owned by a thread.
* @see SingletonScope
* @see com.google.inject.internal.CycleDetectingLock.CycleDetectingLockFactory
* @author timofeyb (Timothy Basanov)
*/
interface CycleDetectingLock {
/**
* Takes a lock in a blocking fashion in case no potential deadlocks are detected. If the lock was
* successfully owned, returns an empty map indicating no detected potential deadlocks.
*
* Otherwise, a map indicating threads involved in a potential deadlock are returned. Map is
* ordered by dependency cycle and lists locks for each thread that are part of the loop in order,
* the last lock in the list is the one that the thread is currently waiting for. Returned map is
* created atomically.
*
*
In case no cycle is detected performance is O(threads creating singletons), in case cycle is
* detected performance is O(singleton locks).
*/
ListMultimap lockOrDetectPotentialLocksCycle();
/** Unlocks previously locked lock. */
void unlock();
/**
* Wraps locks so they would never cause a deadlock. On each {@link
* CycleDetectingLock#lockOrDetectPotentialLocksCycle} we check for dependency cycles within locks
* created by the same factory. Either we detect a cycle and return it or take it atomically.
*
* Important to note that we do not prevent deadlocks in the client code. As an example: Thread
* A takes lock L and creates singleton class CA depending on the singleton class CB. Meanwhile
* thread B is creating class CB and is waiting on the lock L. Issue happens due to client code
* creating interdependent classes and using locks, where no guarantees on the creation order from
* Guice are provided.
*
*
Instances of these locks are not intended to be exposed outside of {@link SingletonScope}.
*/
class CycleDetectingLockFactory {
/**
* Specifies lock that thread is currently waiting on to own it. Used only for purposes of locks
* cycle detection.
*
*
* - Key: thread
*
- Value: lock that is being waited on
*
*
* Element is added inside {@link #lockOrDetectPotentialLocksCycle()} before {@link
* Lock#lock} is called. Element is removed inside {@link #lockOrDetectPotentialLocksCycle()}
* after {@link Lock#lock} and synchronously with adding it to {@link #locksOwnedByThread}.
*
*
Same lock can be added for several threads in case all of them are trying to take it.
*
*
Guarded by {@code CycleDetectingLockFactory.class}.
*/
private static Map> lockThreadIsWaitingOn =
Maps.newHashMap();
/**
* Lists locks that thread owns. Used only to populate locks in a potential cycle when it is
* detected.
*
*
* - Key: thread
*
- Value: stack of locks that were owned.
*
*
* Element is added inside {@link #lockOrDetectPotentialLocksCycle()} after {@link Lock#lock}
* is called. Element is removed inside {@link #unlock()} synchronously with {@link
* Lock#unlock()} call.
*
*
Same lock can only be present several times for the same thread as locks are reentrant.
* Lock can not be owned by several different threads as the same time.
*
*
Guarded by {@code CycleDetectingLockFactory.class}.
*/
private static final Multimap> locksOwnedByThread =
LinkedHashMultimap.create();
/**
* Creates new lock within this factory context. We can guarantee that locks created by the same
* factory would not deadlock.
*
* @param userLockId lock id that would be used to report lock cycles if detected
*/
CycleDetectingLock create(ID userLockId) {
return new ReentrantCycleDetectingLock(this, userLockId, new ReentrantLock());
}
/** The implementation for {@link CycleDetectingLock}. */
static class ReentrantCycleDetectingLock implements CycleDetectingLock {
/** Underlying lock used for actual waiting when no potential deadlocks are detected. */
private final Lock lockImplementation;
/** User id for this lock. */
private final ID userLockId;
/** Factory that was used to create this lock. */
private final CycleDetectingLockFactory lockFactory;
/**
* Thread that owns this lock. Nullable. Guarded by {@code CycleDetectingLockFactory.this}.
*/
private Thread lockOwnerThread = null;
/**
* Number of times that thread owned this lock. Guarded by {@code
* CycleDetectingLockFactory.this}.
*/
private int lockReentranceCount = 0;
ReentrantCycleDetectingLock(
CycleDetectingLockFactory lockFactory, ID userLockId, Lock lockImplementation) {
this.lockFactory = lockFactory;
this.userLockId = Preconditions.checkNotNull(userLockId, "userLockId");
this.lockImplementation =
Preconditions.checkNotNull(lockImplementation, "lockImplementation");
}
@Override
public ListMultimap lockOrDetectPotentialLocksCycle() {
final Thread currentThread = Thread.currentThread();
synchronized (CycleDetectingLockFactory.class) {
checkState();
// Add this lock to the waiting map to ensure it is included in any reported lock cycle.
lockThreadIsWaitingOn.put(currentThread, this);
ListMultimap locksInCycle = detectPotentialLocksCycle();
if (!locksInCycle.isEmpty()) {
// We aren't actually going to wait for this lock, so remove it from the map.
lockThreadIsWaitingOn.remove(currentThread);
// potential deadlock is found, we don't try to take this lock
return locksInCycle;
}
}
// this may be blocking, but we don't expect it to cause a deadlock
lockImplementation.lock();
synchronized (CycleDetectingLockFactory.class) {
// current thread is no longer waiting on this lock
lockThreadIsWaitingOn.remove(currentThread);
checkState();
// mark it as owned by us
lockOwnerThread = currentThread;
lockReentranceCount++;
// add this lock to the list of locks owned by a current thread
locksOwnedByThread.put(currentThread, this);
}
// no deadlock is found, locking successful
return ImmutableListMultimap.of();
}
@Override
public void unlock() {
final Thread currentThread = Thread.currentThread();
synchronized (CycleDetectingLockFactory.class) {
checkState();
Preconditions.checkState(
lockOwnerThread != null, "Thread is trying to unlock a lock that is not locked");
Preconditions.checkState(
lockOwnerThread == currentThread,
"Thread is trying to unlock a lock owned by another thread");
// releasing underlying lock
lockImplementation.unlock();
// be sure to release the lock synchronously with updating internal state
lockReentranceCount--;
if (lockReentranceCount == 0) {
// we no longer own this lock
lockOwnerThread = null;
Preconditions.checkState(
locksOwnedByThread.remove(currentThread, this),
"Internal error: Can not find this lock in locks owned by a current thread");
if (locksOwnedByThread.get(currentThread).isEmpty()) {
// clearing memory
locksOwnedByThread.removeAll(currentThread);
}
}
}
}
/** Check consistency of an internal state. */
void checkState() throws IllegalStateException {
final Thread currentThread = Thread.currentThread();
Preconditions.checkState(
!lockThreadIsWaitingOn.containsKey(currentThread),
"Internal error: Thread should not be in a waiting thread on a lock now");
if (lockOwnerThread != null) {
// check state of a locked lock
Preconditions.checkState(
lockReentranceCount >= 0,
"Internal error: Lock ownership and reentrance count internal states do not match");
Preconditions.checkState(
locksOwnedByThread.get(lockOwnerThread).contains(this),
"Internal error: Set of locks owned by a current thread and lock "
+ "ownership status do not match");
} else {
// check state of a non locked lock
Preconditions.checkState(
lockReentranceCount == 0,
"Internal error: Reentrance count of a non locked lock is expect to be zero");
Preconditions.checkState(
!locksOwnedByThread.values().contains(this),
"Internal error: Non locked lock should not be owned by any thread");
}
}
/**
* Algorithm to detect a potential lock cycle.
*
* For lock's thread owner check which lock is it trying to take. Repeat recursively. When
* current thread is found a potential cycle is detected.
*
* @see CycleDetectingLock#lockOrDetectPotentialLocksCycle()
*/
private ListMultimap detectPotentialLocksCycle() {
final Thread currentThread = Thread.currentThread();
if (lockOwnerThread == null || lockOwnerThread == currentThread) {
// if nobody owns this lock, lock cycle is impossible
// if a current thread owns this lock, we let Guice to handle it
return ImmutableListMultimap.of();
}
ListMultimap potentialLocksCycle =
Multimaps.newListMultimap(
new LinkedHashMap>(),
new Supplier>() {
@Override
public List get() {
return Lists.newArrayList();
}
});
// lock that is a part of a potential locks cycle, starts with current lock
ReentrantCycleDetectingLock> lockOwnerWaitingOn = this;
// try to find a dependency path between lock's owner thread and a current thread
while (lockOwnerWaitingOn != null && lockOwnerWaitingOn.lockOwnerThread != null) {
Thread threadOwnerThreadWaits = lockOwnerWaitingOn.lockOwnerThread;
// in case locks cycle exists lock we're waiting for is part of it
lockOwnerWaitingOn =
addAllLockIdsAfter(threadOwnerThreadWaits, lockOwnerWaitingOn, potentialLocksCycle);
if (threadOwnerThreadWaits == currentThread) {
// owner thread depends on current thread, cycle detected
return potentialLocksCycle;
}
}
// no dependency path from an owner thread to a current thread
return ImmutableListMultimap.of();
}
/**
* Adds all locks held by the given thread that are after the given lock and then returns the
* lock the thread is currently waiting on, if any
*/
private ReentrantCycleDetectingLock> addAllLockIdsAfter(
Thread thread,
ReentrantCycleDetectingLock> lock,
ListMultimap potentialLocksCycle) {
boolean found = false;
Collection> ownedLocks = locksOwnedByThread.get(thread);
Preconditions.checkNotNull(
ownedLocks, "Internal error: No locks were found taken by a thread");
for (ReentrantCycleDetectingLock> ownedLock : ownedLocks) {
if (ownedLock == lock) {
found = true;
}
if (found && ownedLock.lockFactory == this.lockFactory) {
// All locks are stored in a shared map therefore there is no way to
// enforce type safety. We know that our cast is valid as we check for a lock's
// factory. If the lock was generated by the
// same factory it has to have same type as the current lock.
@SuppressWarnings("unchecked")
ID userLockId = (ID) ownedLock.userLockId;
potentialLocksCycle.put(thread, userLockId);
}
}
Preconditions.checkState(
found,
"Internal error: We can not find locks that created a cycle that we detected");
ReentrantCycleDetectingLock> unownedLock = lockThreadIsWaitingOn.get(thread);
// If this thread is waiting for a lock add it to the cycle and return it
if (unownedLock != null && unownedLock.lockFactory == this.lockFactory) {
@SuppressWarnings("unchecked")
ID typed = (ID) unownedLock.userLockId;
potentialLocksCycle.put(thread, typed);
}
return unownedLock;
}
@Override
public String toString() {
// copy is made to prevent a data race
// no synchronization is used, potentially stale data, should be good enough
Thread thread = this.lockOwnerThread;
if (thread != null) {
return String.format("%s[%s][locked by %s]", super.toString(), userLockId, thread);
} else {
return String.format("%s[%s][unlocked]", super.toString(), userLockId);
}
}
}
}
}