I store all of my profiles into a profileCache, which eats up a ton of memory within the Large Object Heap. Therefore, I have implemented a method to help delete unused cache. The problem is the method doesn't seem to be clearing the cache correctly and is throwing a stack overflow error. Here is the two methods I have implemented.
private static void OnScavengeProfileCache(object data)
{
// loop until the runtime is shutting down
while(HostingEnvironment.ShutdownReason == ApplicationShutdownReason.None)
{
// NOTE: Right now we only do the scavenge when traffic is temporarily low,
// to try to amortize the overhead of scavenging the cache into a low utilization period.
// We also only scavenge if the process memory usage is very high.
if (s_timerNoRequests.ElapsedMilliseconds >= 10000)
{
// We dont want to scavenge under lock to avoid slowing down requests,
// so we get the list of keys under lock and then incrementally scan them
IEnumerable<string> profileKeys = null;
lock (s_profileCache)
{
profileKeys = s_profileCache.Keys.ToList();
}
ScavengeProfileCacheIncremental(profileKeys.GetEnumerator());
}
// wait for a bit
Thread.Sleep(60 * 1000);
}
}
My method is constantly scanning traffic, and when traffic is low, it collects all of my profiles and stores them into an IEnumerable called profileKeys. I then invoke this method to delete unused keys -
private static void ScavengeProfileCacheIncremental(IEnumerator<string> profileKeys)
{
if (s_thisProcess.PrivateMemorySize64 >= (200 * 1024 * 1024) ) // 3Gb at least
{
int numProcessed = 0;
while(profileKeys.MoveNext())
{
var key = profileKeys.Current;
Profile profile = null;
if (s_profileCache.TryGetValue(key, out profile))
{
// safely check/remove under lock, its fast but makes sure we dont blow away someone currently being addded
lock (s_profileCache)
{
if (DateTime.UtcNow.Subtract(profile.CreateTime).TotalMinutes > 5)
{
// can clear it out
s_profileCache.Remove(key);
}
}
}
if (++numProcessed >= 5)
{
// stop this scan and check memory again
break;
}
}
// Check again to see if we freed up memory, if not continue scanning the profiles?
ScavengeProfileCacheIncremental(profileKeys);
}
}
The method is not clearing up memory and is throwing a stack overflow error with this trace:
192. ProfileHelper.ScavengeProfileCacheIncremental(
193. ProfileHelper.ScavengeProfileCacheIncremental(
194. ProfileHelper.ScavengeProfileCacheIncremental(
195. ProfileHelper.ScavengeProfileCacheIncremental(
196. ProfileHelper.OnScavengeProfileCache(...)
197. ExecutionContext.RunInternal(...)
198. ExecutionContext.Run(...)
199. IThreadPoolWorkItem.ExecuteWorkItem(...)
200. ThreadPoolWorkQueue.Dispatch(...)
EDIT:
So would this be a possible solution to remove unused profile keys and clear LOH...
private static void ScavengeProfileCacheIncremental(IEnumerator<string> profileKeys)
{
if (s_thisProcess.PrivateMemorySize64 >= (200 * 1024 * 1024) ) // 3Gb at least
{
int numProcessed = 0;
while(profileKeys.MoveNext())
{
var key = profileKeys.Current;
Profile profile = null;
if (s_profileCache.TryGetValue(key, out profile))
{
// safely check/remove under lock, its fast but makes sure we dont blow away someone currently being addded
lock (s_profileCache)
{
if (DateTime.UtcNow.Subtract(profile.CreateTime).TotalMinutes > 5)
{
// can clear it out
s_profileCache.Remove(key);
}
}
}
if (++numProcessed >= 5)
{
// stop this scan and check memory again
break;
}
}
}
GC.Collect;
}
I believe your code is suffering of a problem known as Infinite Recursion.
You are calling method ScavengeProfileCacheIncremental, which in turn calls itself internally. At some point, you call into it enough times that you run out of stack, causing an overflow.
Either your condition is not being met before you run out of stack, or your condition is never met at all. Debugging should show you why.
You can read more on the subject here.
There is no exit from SaveProfileCacheIncremental.
It does its stuff and then calls itself. It then does its stuff and calls itself. It then does its stuff and calls itself. It then does its stuff and calls itself. It then does its stuff and calls itself.
After a while it uses all the stack space and the process crashes.
I'm playing around with Q#, which uses C# as a driver. I'd like to pass a Qubit object to the Q# code but it isn't working as expected.
C# Driver
using Microsoft.Quantum.Simulation.Core;
using Microsoft.Quantum.Simulation.Simulators;
namespace Quantum.QSharpApplication1 {
class Driver {
static void Main(string[] args) {
using (var sim = new QuantumSimulator()) {
var x = new Microsoft.Quantum.Simulation.Common.QubitManager(10);
Qubit q1 = x.Allocate();
Solve.Run(sim, q1, 1);
}
System.Console.WriteLine("Press any key to continue...");
System.Console.ReadKey();
}
}
}
Q#
namespace Quantum.QSharpApplication1
{
open Microsoft.Quantum.Primitive;
open Microsoft.Quantum.Canon;
operation Solve (q : Qubit, sign : Int) : ()
{
body
{
let qp = M(q);
if (qp != Zero)
{
X(q);
}
H(q);
}
}
}
When I run this, it runs without error until it reaches the System.Console.* lines at which point it throws the following exception in the Q# code
System.AccessViolationException
HResult=0x80004003
Message=Attempted to read or write protected memory. This is often an indication that other memory is corrupt.
Source=<Cannot evaluate the exception source>
StackTrace:
<Cannot evaluate the exception stack trace>
The debugger associates this with the "let qp = M(q);" line in Q#.
Note this does happen in the Solve.Run call, the real code has multiple Solve calls and the output appear correct. It only appears to occur after the using QuantumSimulator scope is left. I recall reading that the Qubit must be reset to zero before it is released. I'm not sure if that is the problem here, but I don't see a way to do that in C#. Interesting I remove the Console lines, the program will run without error (timing?).
The QubitManager instance you used to create the qubits is not a singleton (each Simulator has its own QubitManager), therefore the Simulator is not aware of the Qubit your trying to manipulate on the Q# code, thus the AccessViolationException.
In general, creating Qubits on the driver is not supported; you can only allocate qubits using the allocate and borrowing statements inside Q#. The recommendation is to create an entry point in Q# to allocate the qubits which does the qubit allocation and call this from the driver, for example:
// MyOp.qs
operation EntryPoint() : ()
{
body
{
using (register = Qubit[2])
{
myOp(register);
}
}
}
// Driver.cs
EntryPoint.Run().Wait();
Finally, note that in your driver code you have this:
Solve.Run(sim, q1, 1);
The Run method returns a tasks that executes asynchronously. You must typically add a Wait() to make sure it finishes execution:
EntryPoint.Run(sim, 1).Wait();
If you do this you will notice that failure during the Run, not the Console.WriteLine.
I'm designing a class that I wish to make readonly after a main thread is done configuring it, i.e. "freeze" it. Eric Lippert calls this popsicle immutability. After it is frozen, it can be accessed by multiple threads concurrently for reading.
My question is how to write this in a thread safe way that is realistically efficient, i.e. without trying to be unnecessarily clever.
Attempt 1:
public class Foobar
{
private Boolean _isFrozen;
public void Freeze() { _isFrozen = true; }
// Only intended to be called by main thread, so checks if class is frozen. If it is the operation is invalid.
public void WriteValue(Object val)
{
if (_isFrozen)
throw new InvalidOperationException();
// write ...
}
public Object ReadSomething()
{
return it;
}
}
Eric Lippert seems to suggest this would be OK in this post.
I know writes have release semantics, but as far as I understand this only pertains to ordering, and it doesn't necessarily mean that all threads will see the value immediately after the write. Can anyone confirm this? This would mean this solution is not thread safe (this may not be the only reason of course).
Attempt 2:
The above, but using Interlocked.Exchange to ensure the value is actually published:
public class Foobar
{
private Int32 _isFrozen;
public void Freeze() { Interlocked.Exchange(ref _isFrozen, 1); }
public void WriteValue(Object val)
{
if (_isFrozen == 1)
throw new InvalidOperationException();
// write ...
}
}
Advantage here would be that we ensure the value is published without suffering the overhead on every read. If none of the reads are moved before the write to _isFrozen as the Interlocked method uses a full memory barrier I would guess this is thread safe. However, who knows what the compiler will do (and according to section 3.10 of the C# spec that seems like quite a lot), so I don't know if this is threadsafe.
Attempt 3:
Also do the read using Interlocked.
public class Foobar
{
private Int32 _isFrozen;
public void Freeze() { Interlocked.Exchange(ref _isFrozen, 1); }
public void WriteValue(Object val)
{
if (Interlocked.CompareExchange(ref _isFrozen, 0, 0) == 1)
throw new InvalidOperationException();
// write ...
}
}
Definitely thread safe, but it seems a little wasteful to have to do the compare exchange for every read. I know this overhead is probably minimal, but I'm looking for a reasonably efficient method (although perhaps this is it).
Attempt 4:
Using volatile:
public class Foobar
{
private volatile Boolean _isFrozen;
public void Freeze() { _isFrozen = true; }
public void WriteValue(Object val)
{
if (_isFrozen)
throw new InvalidOperationException();
// write ...
}
}
But Joe Duffy declared "sayonara volatile", so I won't consider this a solution.
Attempt 5:
Lock everything, seems a bit overkill:
public class Foobar
{
private readonly Object _syncRoot = new Object();
private Boolean _isFrozen;
public void Freeze() { lock(_syncRoot) _isFrozen = true; }
public void WriteValue(Object val)
{
lock(_syncRoot) // as above we could include an attempt that reads *without* this lock
if (_isFrozen)
throw new InvalidOperationException();
// write ...
}
}
Also seems definitely thread safe, but has more overhead than using the Interlocked approach above, so I would favour attempt 3 over this one.
And then I can come up with at least some more (I'm sure there are many more):
Attempt 6: use Thread.VolatileWrite and Thread.VolatileRead, but these are supposedly a little on the heavy side.
Attempt 7: use Thread.MemoryBarrier, seems a little too internal.
Attempt 8: create an immutable copy - don't want to do this
Summarising:
which attempt would you use and why (or how would you do it if entirely different)? (i.e. what is the best way for publishing a value once that is then read concurrently, while being reasonably efficient without being overly "clever"?)
does .NET's memory model "release" semantics of writes imply that all other threads see updates (cache coherency etc.)? I generally don't want to think too much about this, but it's nice to have an understanding.
EDIT:
Perhaps my question wasn't clear, but I am looking in particular for reasons as to why the above attempts are good or bad. Note that I am talking here about a scenario of one single writer that writes then freezes before any concurrent reads. I believe attempt 1 is OK but I'd like to know exactly why (as I wonder if reads could be optimized away somehow, for example).
I care less about whether or not this is good design practice but more about the actual threading aspect of it.
Many thanks for the response the question received, but I have chosen to mark this as an answer myself because I feel that the answers given do not quite answer my question and I do not want to give the impression to anyone visiting the site that the marked answer is correct simply because it was automatically marked as such due to the bounty expiring.
Furthermore I do not think the answer with the highest number of votes was overwhelmingly voted for, not enough to mark it automatically as an answer.
I am still leaning to attempt #1 being correct, however, I would have liked some authoritative answers. I understand x86 has a strong model, but I don't want to (and shouldn't) code for a particular architecture, after all that's one of the nice things about .NET.
If you are in doubt about the answer, go for one of the locking approaches, perhaps with the optimizations shown here to avoid a lot of contention on the lock.
Maybe slightly off topic but just out of curiosity :) Why don't you use "real" immutability? e.g. making Freeze() return an immutable copy (without "write methods" or any other possibility to change the inner state) and using this copy instead of the original object. You could even go without changing the state and return a new copy (with the changed state) on each write operation instead (afaik the string class works this). "Real immutability" is inherently thread safe.
I vote for Attempt 5, use the lock(this) implementation.
This is the most reliable means of making this work. Reader/writer locks could be employed, but to very little gain. Just go with using a normal lock.
If necessary you could improve the 'frozen' performance by first checking _isFrozen and then locking:
void Freeze() { lock (this) _isFrozen = true; }
object ReadValue()
{
if (_isFrozen)
return Read();
else
lock (this) return Read();
}
void WriteValue(object value)
{
lock (this)
{
if (_isFrozen) throw new InvalidOperationException();
Write(value);
}
}
If you really create, fill and freeze the object before showing it to other threads, then you don't need anything special to deal with thread-safety (the strong memory model of .NET is already your guarantee), so the solution 1 is valid.
But, if you give the unfrozen object to another thread (or if you are simple creating your class without knowing how users will use it) then using the version the solution that returns a new fully immutable instance is probably better. In this case, the Mutable instance is like the StringBuilder and the immutable instance is like the string. If you need an extra guarantee, the mutable instance may check its creator thread and throw exceptions if it is used from any other thread (in all methods... to avoid possible partial reads).
Attempt 2 is thread safe on x86 and other processors that have a strong memory model, but how I would do it is to make thread safety the consumers problem because there is no way for you to efficiently do it within the consumed code. Consider:
if(!foo.frozen)
{
foo.apropery = "avalue";
}
the thread saftey of the frozen property and the guard code in apropery's setter doesn't really matter because even they are perfectly thread safe you still have a race condition. Instead I would write it like
lock(foo)
{
if(!foo.frozen)
{
foo.apropery = "avalue";
}
}
and have neither of the properties inherently thread safe.
#1 - reader not threadsafe - I believe problem would be in reader side, not writer (code not shown)
#2 - reader not threadsafe - same as #1
#3 - promising, read check can be optimized out for most cases (when CPU caches are in sync)
Attempt 3:
Also do the read using Interlocked.
public class Foobar {
private object _syncRoot = new object();
private int _isFrozen = 0; // perf compiler warning, but training code, so show defaults
// Why Exchange to 1 then throw away result. Best to just increment.
//public void Freeze() { Interlocked.Exchange(ref _isFrozen, 1); }
public void Freeze() { Interlocked.Increment(ref _isFrozen); }
public void WriteValue(Object val) {
// if this core can see _isFrozen then no special lock or sync needed
if (_isFrozen != 0)
throw new InvalidOperationException();
lock(_syncRoot) {
if (_isFrozen != 0)
throw new InvalidOperationException(); // the 'throw' is 100x-1000x more costly than the lock, just eat it
_val = val;
}
}
public object Read() {
// frozen is one-way, if one-way state has been published
// to my local CPU cache then just read _val.
// There are very strange corner cases when _isFrozen and _val fields are in
// different cache lines, but should be nearly impossible to hit unless
// dealing with very large structs (make it more likely to cross
// 4k cache line).
if (_isFrozen != 0)
return _val;
// else
lock(_syncRoot) { // _isFrozen is 0 here
if (_isFrozen != 0) // if _isFrozen is 1 here we just collided with writer using lock on other thread, or our CPU cache was out of sync and lock() forced the dirty cache line to be read from main memory
return _val;
throw new InvalidOperationException(); // throw is 100x-1000x more expensive than lock, eat the cost of lock
}
}
}
Joe Duffy's post about 'volatile is dead' is, I think, in the context of his next-gen CLR/OS architecture and for CLR on ARM. Those of us doing multi-core x64/x86 I think volatile is fine. If perf is the primary concern I suggest you measure the code above and compare it to volatile.
Unlike other folks posting answers I wouldn't jump straight to lock() if you have lots of readers (3 or more threads likely to read the same object at the same time). But in your sample you mix perf-sensitive question with exceptions when a collision happens, which doesn't make much sense. If you're using exceptions, then you can also use other higher-level constructs.
If you want complete safety but need to optimize for lots of concurrent readers change lock()/Monitor to ReaderWriterLockSlim.
.NET has new primitives to handle publishing values. Take a look at Rx. It can be very fast and lockless for some cases (I think they use optimizations similar to above).
If written multiple times but only one value is kept - in Rx that is "new ReplaySubject(bufferSize: 1)". If you try it you might be surprised how fast it. At the same time I applaud your attempt to learn this level of detail.
If you want to go lockless get over your distaste for Thread.MemoryBarrier(). It is extremely important. But it has the same gotchas as volatile as described by Joe Duffy - it was designed as a hint to the compiler & CPU to prevent reordering of memory reads (which take a long time in CPU terms, so they are aggressively reordered when there are no hints present). When this reordering is combined with CLR constructs like auto-inline of functions and you can see very surprising behavior at the memory & register level. MemoryBarrier() just disables those single-threaded memory access assumptions that CPU and CLR use most of the time.
Perhaps my question wasn't clear, but I am looking in particular for reasons as to why the above attempts are good or bad. Note that I am talking here about a scenario of one single writer that writes then freezes before any concurrent reads. I believe attempt 1 is OK but I'd like to know exactly why (as I wonder if reads could be optimized away somehow, for example). I care less about whether or not this is good design practice but more about the actual threading aspect of it.
Ok, now I better understand what you are doing and looking for in a response. Allow me to elaborate on my previous answer promoting the use of locks by first addressing each of your attempts.
Attempt 1:
The approach of using a simple class that has no synchronization primitives of any form is entirely viable in your example. Since the 'authoring' thread is the only thread having access to this class during it's mutating state this should be safe. If an only if another thread has the potential to access before the class is 'frozen' would you need to provide synchronization. Essentially, it's not possible for a thread to have a cache of something it has never seen.
Aside from a thread having a cached copy of the internal state of this list there is one other concurrency issue that you should be concerned with. You should consider write reordering by the authoring thread. You example solution doesn't have enough code for me to address this, but the process of handing this 'frozen' list to another thread is the heart of the issue. Are you using Interlocked.Exchange or writing to a volatile state?
I still advocate that is not the best approach simply because there is no guarantee that another thread has not seen the instance while it's mutating.
Attempt 2:
While attempt 2 should not be used. If you are using atomic writes to a member, one should also use atomic reads. I would never recommend one without the other as without both reads and writes being atomic you haven't gained anything. The correct application of atomic reads and writes is your 'Attempt 3'.
Attempt 3:
This will guarantee an exception is thrown if a thread has attempted to mutate an frozen list. However it makes no assertion that a read is only acceptable on a frozen instance. This, IMHO, is just as bad as accessing our _isFrozen variable with atomic and non-atomic accessors. If you are going to say that it's important to safeguard writes, then you should always safeguard reads. One without the other is just 'odd'.
Overlooking my own feeling towards writing code that gaurds writes but not reads this is an acceptable approach given your specific uses. I have one writer, I write, I freeze, then I make it available to readers. Under this scenario you code works correctly. You rely on the atomic operation on the set of _isFrozen to provide the required memory barrier prior to handing the class to another thread.
In a nutshell this approach works, but again if a thread has an instance that is not frozen it's going to break.
Attempt 4:
While at heart this is nearly the same as attempt 3 (given one writer) there is one big difference. In this example, if you check _isFrozen in the reader then every access will require a memory barrier. This is unnecessary overhead once the list is frozen.
Still this has the same issue as Attempt 3 in that no assertions are made about the state of _isFrozen during the read so the performance should be identical in your example usage.
Attempt 5:
As I said this is my preference given the modification to read as appears in my other answer.
Attempt 6:
Is essentially the same as #4.
Attempt 7:
You could solve your specific needs with a Thread.MemoryBarrier. Essentially using the code from Attempt 1, you create the instance, call Freeze(), add your Thread.MemoryBarrier, and then share the instance (or share it within a lock). This should work great, again only under your limited use case.
Attempt 8:
Without knowing more about this, I can't advise on the cost of the copy.
Summary
Again I prefer using a class that has some threading guarantee or none at all. Creating a class that is only 'partially' thread safe is, IMO, dangerous.
In the words of a famous jedi master:
Either do or do not there is no try.
The same goes for thread safety. The class should either be thread safe or not. Taking this approach you are left with either using my augmentation of Attempt 5, or using Attempt 7. Given the choice, I would never recommend #7.
So my recommendation stands firmly behind a completely thread-safe version. The performance cost between the two is so infinitesimally small it's almost non-existent. The reader threads will never hit the lock simply because of your usage scenario of having a single writer. Yet, if they do, proper behavior is still a certainty. Thus as your code changes over time and suddenly your instance is being shared prior to being frozen you don't wind up with race condition that crashes your program. Thread safe, or not, don't be half-in or you wind up with nasty surprise someday.
My preference is all classes shared by more than one thread are one of two types:
Completely immutable.
Completely Thread-safe.
Since a popsicle list is not immutable by design it does not fit #1. Therefore if you are going to share the object across threads it should fit #2.
Hopefully all this ranting further explains my reasoning :)
_syncRoot
Many people have noticed that I skipped the use of a _syncRoot on my locking implementation. While the reasons to use _syncRoot are valid they are not always necessary. In your example usage where you have a single writer the use of lock(this) should suffice nicely without adding another heap allocation for _syncRoot.
Is the thing constructed and written to, then permanently frozen and read multiple times?
Or do you freeze and unfreeze and refreeze it multiple times?
If it's the former, then perhaps the "is frozen" check should be in the reader method not the writer method (to prevent it reading before it's frozen).
Or, if it's the latter, then the use case you need to beware of is:
Main thread invokes the writer method, finds that it's not frozen, and therefore begins to write
Before the write has finished, someone tries to freeze the object and then reads from it, while the other (main) thread is still writing
In the latter case, Google shows a lot of results for multiple reader single writer which you might find interesting.
In general, each mutable object should have precisely one clearly-defined "owner"; shared objects should be immutable. Popsicles should not be accessible by multiple threads until after they are frozen.
Personally, I don't like forms of popsicle immunity with an exposed "freeze" method. I think a cleaner approach is to have AsMutable and AsImmutable methods (each of which would simply return the object unmodified when appropriate). Such an approach can allow for more robust promises about immutability. For example, if an "unshared mutable object" is being mutated while its AsImmutable member is being called (behavior which would be contrary to the object being "unshared"), the state of the data in the copy may be indeterminate, but whatever was returned would be immutable. By contrast, if one thread froze an object and then assumed it was immutable while another thread was writing to it, the "immutable" object could end up changing after it was frozen and its values were read.
Edit
Based on further description, I would suggest having code which writes to the object do so within a monitor lock, and having the freeze routine look something like:
public Thingie Freeze(void) // Returns the object in question
{
if (isFrozen) // Private field
return this;
else
return DoFreeze();
}
Thingie DoFreeze(void)
{
if (Monitor.TryEnter(whatever))
{
isFrozen = true;
return this;
}
else if (isFrozen)
return this;
else
throw new InvalidOperationException("Object in use by writer");
}
The Freeze method may be called any number of times by any number of threads; it should be short enough to be inlined (though I haven't profiled it), and should thus take almost no time to execute. If the first access of the object in any thread is via the Freeze method, that should guarantee proper visibility under any reasonable memory model (even if the thread didn't see the updates to the object performed by the thread which created and originally froze it, it would perform the TryEnter, which would guarantee a memory barrier, and after that failed it would notice that the object was frozen and return it.
If code which is going to write the object acquires the lock first, an attempt to write to a frozen object could deadlock. If one would rather have such code throw an exception, one use TryEnter and throw an exception if it can't get the lock.
The object used for locking should be something which is exclusively held by the object to be frozen. If the object to be frozen doesn't hold a purely-private reference to anything, one could either lock on this or create a private object purely for locking purposes. Note that it is safe to abandon 'entered' monitor locks without cleanup; the GC will simply forget about them, since if no references exist to a lock there's no way anybody will ever care (or could even ask) whether the lock was entered at the time it was abandoned.
I am not sure in terms of cost how the following approach will do, but it is a bit different. Only initially if there are multiple threads trying to write value simultaneously will they encounter locks. Once it is frozen all later calls will get the exception directly.
Attempt 9:
public class Foobar
{
private readonly Object _syncRoot = new Object();
private object _val;
private Boolean _isFrozen;
private Action<object> WriteValInternal;
public void Freeze() { _isFrozen = true; }
public Foobar()
{
WriteValInternal = BeforeFreeze;
}
private void BeforeFreeze(object val)
{
lock (_syncRoot)
{
if (_isFrozen == false)
{
//Write the values....
_val = val;
//...
//...
//...
//and then modify the write value function
WriteValInternal = AfterFreeze;
Freeze();
}
else
{
throw new InvalidOperationException();
}
}
}
private void AfterFreeze(object val)
{
throw new InvalidOperationException();
}
public void WriteValue(Object val)
{
WriteValInternal(val);
}
public Object ReadSomething()
{
return _val;
}
}
Have you checked out Lazy
http://msdn.microsoft.com/en-us/library/dd642331.aspx
which uses ThreadLocal
http://msdn.microsoft.com/en-us/library/dd642243.aspx
And actually looking further there is a Freezable class...
http://msdn.microsoft.com/en-us/library/vstudio/ms602734(v=vs.100).aspx
you may achieve this using POST Sharp
take one interface
public interface IPseudoImmutable
{
bool IsFrozen { get; }
bool Freeze();
}
then derive your attribute from InstanceLevelAspect like this
/// <summary>
/// implement by divyang
/// </summary>
[Serializable]
[IntroduceInterface(typeof(IPseudoImmutable),
AncestorOverrideAction = InterfaceOverrideAction.Ignore, OverrideAction = InterfaceOverrideAction.Fail)]
public class PseudoImmutableAttribute : InstanceLevelAspect, IPseudoImmutable
{
private volatile bool isFrozen;
#region "IPseudoImmutable"
[IntroduceMember]
public bool IsFrozen
{
get
{
return this.isFrozen;
}
}
[IntroduceMember(IsVirtual = true, OverrideAction = MemberOverrideAction.Fail)]
public bool Freeze()
{
if (!this.isFrozen)
{
this.isFrozen = true;
}
return this.IsFrozen;
}
#endregion
[OnLocationSetValueAdvice]
[MulticastPointcut(Targets = MulticastTargets.Property | MulticastTargets.Field)]
public void OnValueChange(LocationInterceptionArgs args)
{
if (!this.IsFrozen)
{
args.ProceedSetValue();
}
}
}
public class ImmutableException : Exception
{
/// <summary>
/// The location name.
/// </summary>
private readonly string locationName;
/// <summary>
/// Initializes a new instance of the <see cref="ImmutableException"/> class.
/// </summary>
/// <param name="message">
/// The message.
/// </param>
public ImmutableException(string message)
: base(message)
{
}
public ImmutableException(string message, string locationName)
: base(message)
{
this.locationName = locationName;
}
public string LocationName
{
get
{
return this.locationName;
}
}
}
then apply in your class like this
[PseudoImmutableAttribute]
public class TestClass
{
public string MyString { get; set; }
public int MyInitval { get; set; }
}
then run it in multi thread
/// <summary>
/// The program.
/// </summary>
public class Program
{
/// <summary>
/// The main.
/// </summary>
/// <param name="args">
/// The args.
/// </param>
public static void Main(string[] args)
{
Console.Title = "Divyang Demo ";
var w = new Worker();
w.Run();
Console.ReadLine();
}
}
internal class Worker
{
private object SyncObject = new object();
public Worker()
{
var r = new Random();
this.ObjectOfMyTestClass = new MyTestClass { MyInitval = r.Next(500) };
}
public MyTestClass ObjectOfMyTestClass { get; set; }
public void Run()
{
Task readWork;
readWork = Task.Factory.StartNew(
action: () =>
{
for (;;)
{
Task.Delay(1000);
try
{
this.DoReadWork();
}
catch (Exception exception)
{
// Console.SetCursorPosition(80,80);
// Console.SetBufferSize(100,100);
Console.WriteLine("Read Exception : {0}", exception.Message);
}
}
// ReSharper disable FunctionNeverReturns
});
Task writeWork;
writeWork = Task.Factory.StartNew(
action: () =>
{
for (int i = 0; i < int.MaxValue; i++)
{
Task.Delay(1000);
try
{
this.DoWriteWork();
}
catch (Exception exception)
{
Console.SetCursorPosition(80, 80);
Console.SetBufferSize(100, 100);
Console.WriteLine("write Exception : {0}", exception.Message);
}
if (i == 5000)
{
((IPseudoImmutable)this.ObjectOfMyTestClass).Freeze();
}
}
});
Task.WaitAll();
}
/// <summary>
/// The do read work.
/// </summary>
public void DoReadWork()
{
// ThreadId where reading is done
var threadId = System.Threading.Thread.CurrentThread.ManagedThreadId;
// printing on screen
lock (this.SyncObject)
{
Console.SetCursorPosition(0, 0);
Console.SetBufferSize(290, 290);
Console.WriteLine("\n");
Console.WriteLine("Read Start");
Console.WriteLine("Read => Thread Id: {0} ", threadId);
Console.WriteLine("Read => this.objectOfMyTestClass.MyInitval: {0} ", this.ObjectOfMyTestClass.MyInitval);
Console.WriteLine("Read => this.objectOfMyTestClass.MyString: {0} ", this.ObjectOfMyTestClass.MyString);
Console.WriteLine("Read End");
Console.WriteLine("\n");
}
}
/// <summary>
/// The do write work.
/// </summary>
public void DoWriteWork()
{
// ThreadId where reading is done
var threadId = System.Threading.Thread.CurrentThread.ManagedThreadId;
// random number generator
var r = new Random();
var count = r.Next(15);
// new value for Int property
var tempInt = r.Next(5000);
this.ObjectOfMyTestClass.MyInitval = tempInt;
// new value for string Property
var tempString = "Randome" + r.Next(500).ToString(CultureInfo.InvariantCulture);
this.ObjectOfMyTestClass.MyString = tempString;
// printing on screen
lock (this.SyncObject)
{
Console.SetBufferSize(290, 290);
Console.SetCursorPosition(125, 25);
Console.WriteLine("\n");
Console.WriteLine("Write Start");
Console.WriteLine("Write => Thread Id: {0} ", threadId);
Console.WriteLine("Write => this.objectOfMyTestClass.MyInitval: {0} and New Value :{1} ", this.ObjectOfMyTestClass.MyInitval, tempInt);
Console.WriteLine("Write => this.objectOfMyTestClass.MyString: {0} and New Value :{1} ", this.ObjectOfMyTestClass.MyString, tempString);
Console.WriteLine("Write End");
Console.WriteLine("\n");
}
}
}
but still it will allow you to change property like array ,list . but if you apply more login in that then it may work for all type of property and field
I'd do something like this, inspired by C++ movable types. Just remember not to access the object after Freeze/Thaw.
Of course, you can add a _data != null check/throw if you want to be clear about why the user gets an NRE if accessing after thaw/freeze.
public class Data
{
public string _foo;
public int _bar;
}
public class Mutable
{
private Data _data = new Data();
public Mutable() {}
public string Foo { get => _data._foo; set => _data._foo = value; }
public int Bar { get => _data._bar; set => _data._bar = value; }
public Frozen Freeze()
{
var f = new Frozen(_data);
_data = null;
return f;
}
}
public class Frozen
{
private Data _data;
public Frozen(Data data) => _data = data;
public string Foo => _data._foo;
public int Bar => _data._bar;
public Mutable Thaw()
{
var m = new Mutable(_data);
_data = null;
return m;
}
}
I'm looking for ways to make remote calls to services out of my control until a connect is successful. I also don't want to simply set a timer where an action gets executed every n seconds/minutes until successful. After a bunch of research it appears that the circuit breaker pattern is a great fit.
I found an implementation that uses an Castle Windsor interceptor, which looks awesome. The only problem is I don't know how to use it. From the few articles I found regarding the topic the only usage example I was able to find was to simply use the circuit breaker to call an action only once, which doesn't seem very useful. From that it seems I need to simply run my action using the circuit breaker in a while(true) loop.
How do I use the Windsor interceptor to execute an action making a call to an external service until it is successful without slamming our servers?
Could someone please fill in the missing pieces?
Here is what I was able to come up with
while(true)
{
try
{
service.Subscribe();
break;
}
catch (Exception e)
{
Console.WriteLine("Gotcha!");
Thread.Sleep(TimeSpan.FromSeconds(10));
}
}
Console.WriteLine("Success!");
public interface IService
{
void Subscribe();
}
public class Service : IService
{
private readonly Random _random = new Random();
public void Subscribe()
{
var a = _random.Next(0, 10) % 2421;
if(_random.Next(0, 10) % 2 != 0)
throw new AbandonedMutexException();
}
}
Based on that I think I now understand this concept as well as how to apply it.
This is an interesting idea if you have lots of threads hitting the same resource. The way this works is by pooling the count for attempts from all threads. Rather than worrying about writing a loop to try and hit the database 5 times before actually failing, you have the circuit breaker keep track of all attempts to hit the resource.
In one example, you have say 5 threads running a loop like this (pseudo-code):
int errorCount = 0;
while(errorCount < 10) // 10 tries
{
if(tryConnect() == false)
errorCount++;
else
break;
}
Assuming your error handling is correct and all, this loop could be run 5 times, and ping the resource a total of 50 times.
The circuit breaker tries to reduce the total number of times it attempts to reach the resource. Each thread, or request attempt, will increment a single error counter. Once the error limit is reached, the circuit breaker will not try to connect to it's resource for any more calls on any threads until the timeout has elapsed. It's still the same effect of polling the resource until it's ready, but you reduce the total load.
static volatile int errorCount = 0;
while(errorCount < 10)
{
if(tryConnect() == false)
errorCount++;
else
break;
}
With this interceptor implementation, the interceptor is being registered as a singleton. So, all instances of your resource class will have code redirected through the circuit breaker first for any call made to any method. The interceptor is just a proxy to your class. It basically overrides your methods and calls the interceptor method first before calling your method.
The Open/Closed bit might be confusing if you don't have any circuit theory knowledge.
wiki:
An electric circuit is an "open circuit" if it lacks a complete path
between the positive and negative terminals of its power source
In theory, this circuit is Open when the connection is down and Closed when the connection is available. The important part of your example is this:
public void Intercept(IInvocation invocation)
{
using (TimedLock.Lock(monitor))
{
state.ProtectedCodeIsAboutToBeCalled(); /* only throws an exception when state is Open, otherwise, it doesn't do anything. */
}
try
{
invocation.Proceed(); /* tells the interceptor to call the 'actual' method for the class that's being proxied.*/
}
catch (Exception e)
{
using (TimedLock.Lock(monitor))
{
failures++; /* increments the shared error count */
state.ActUponException(e); /* only implemented in the ClosedState class, so it changes the state to Open if the error count is at it's threshold. */
}
throw;
}
using (TimedLock.Lock(monitor))
{
state.ProtectedCodeHasBeenCalled(); /* only implemented in HalfOpen, if it succeeds the "switch" is thrown in the closed position */
}
}
I've created a library called CircuitBreaker.Net that encapsulates all serving logic to safely perform calls. It's easy to use, an example could look like:
// Initialize the circuit breaker
var circuitBreaker = new CircuitBreaker(
TaskScheduler.Default,
maxFailures: 3,
invocationTimeout: TimeSpan.FromMilliseconds(100),
circuitResetTimeout: TimeSpan.FromMilliseconds(10000));
try
{
// perform a potentially fragile call through the circuit breaker
circuitBreaker.Execute(externalService.Call);
// or its async version
// await circuitBreaker.ExecuteAsync(externalService.CallAsync);
}
catch (CircuitBreakerOpenException)
{
// the service is unavailable, failover here
}
catch (CircuitBreakerTimeoutException)
{
// handle timeouts
}
catch (Exception)
{
// handle other unexpected exceptions
}
It's available via a nuget package. You can find the sources on github.
I have a thread which produces data in the form of simple object (record). The thread may produce a thousand records for each one that successfully passes a filter and is actually enqueued. Once the object is enqueued it is read-only.
I have one lock, which I acquire once the record has passed the filter, and I add the item to the back of the producer_queue.
On the consumer thread, I acquire the lock, confirm that the producer_queue is not empty,
set consumer_queue to equal producer_queue, create a new (empty) queue, and set it on producer_queue. Without any further locking I process consumer_queue until it's empty and repeat.
Everything works beautifully on most machines, but on one particular dual-quad server I see in ~1/500k iterations an object that is not fully initialized when I read it out of consumer_queue. The condition is so fleeting that when I dump the object after detecting the condition the fields are correct 90% of the time.
So my question is this: how can I assure that the writes to the object are flushed to main memory when the queue is swapped?
Edit:
On the producer thread:
(producer_queue above is m_fillingQueue; consumer_queue above is m_drainingQueue)
private void FillRecordQueue() {
while (!m_done) {
int count;
lock (m_swapLock) {
count = m_fillingQueue.Count;
}
if (count > 5000) {
Thread.Sleep(60);
} else {
DataRecord rec = GetNextRecord();
if (rec == null) break;
lock (m_swapLock) {
m_fillingQueue.AddLast(rec);
}
}
}
}
In the consumer thread:
private DataRecord Next(bool remove) {
bool drained = false;
while (!drained) {
if (m_drainingQueue.Count > 0) {
DataRecord rec = m_drainingQueue.First.Value;
if (remove) m_drainingQueue.RemoveFirst();
if (rec.Time < FIRST_VALID_TIME) {
throw new InvalidOperationException("Detected invalid timestamp in Next(): " + rec.Time + " from record " + rec);
}
return rec;
} else {
lock (m_swapLock) {
m_drainingQueue = m_fillingQueue;
m_fillingQueue = new LinkedList<DataRecord>();
if (m_drainingQueue.Count == 0) drained = true;
}
}
}
return null;
}
The consumer is rate-limited, so it can't get ahead of the consumer.
The behavior I see is that sometimes the Time field is reading as DateTime.MinValue; by the time I construct the string to throw the exception, however, it's perfectly fine.
Have you tried the obvious: is microcode update applied on the fancy 8-core box(via BIOS update)? Did you run Windows Updates to get the latest processor driver?
At the first glance, it looks like you're locking your containers. So I am recommending the systems approach, as it sound like you're not seeing this issue on a good-ol' dual core box.
Assuming these are in fact the only methods that interact with the m_fillingQueue variable, and that DataRecord cannot be changed after GetNextRecord() creates it (read-only properties hopefully?), then the code at least on the face of it appears to be correct.
In which case I suggest that GregC's answer would be the first thing to check; make sure the failing machine is fully updated (OS / drivers / .NET Framework), becasue the lock statement should involve all the required memory barriers to ensure that the rec variable is fully flushed out of any caches before the object is added to the list.