Motivation:
There are numerous usages of internalNioBuffer which hard code 0 for the index when the intention was to use the readerIndex().
Modifications:
- Remove hard coded 0 for the index and use readerIndex()
Result:
We are less susceptible to using the wrong index, and don't make assumptions about the ByteBufAllocator.
Motivation:
Often its useful for the user to be able to get some stats about the memory allocated via an allocator.
Modifications:
- Allow to obtain the used heap and direct memory for an allocator
- Add test case
Result:
Fixes [#6341]
Motivation:
As we may access the metrics exposed of PooledByteBufAllocator from another thread then the allocations happen we need to ensure we synchronize on the PoolArena to ensure correct visibility.
Modifications:
Synchronize on the PoolArena to ensure correct visibility.
Result:
Fix multi-thread issues on the metrics
Motivation:
Commit 8dda984afe introduced a regression which lead to the situation that the allocator is not set when PooledByteBuf.initUnpooled(...) is called. Thus it was possible that PooledByteBuf.alloc() returns null or the wrong allocator if multiple PooledByteBufAllocator are used in an application.
Modifications:
- Correctly set the allocator
- Add test-case
Result:
Fixes [#6436].
Motivation:
We have our own ThreadLocalRandom implementation to support older JDKs . That said we should prefer the JDK provided when running on JDK >= 7
Modification:
Using ThreadLocalRandom implementation of the JDK when possible.
Result:
Make use of JDK implementations when possible.
Motivation:
Java9 does not allow changing access level via reflection by default. This lead to the situation that netty disabled Unsafe completely as ByteBuffer.address could not be read.
Modification:
Use Unsafe to read the address field as this works on all Java versions.
Result:
Again be able to use Unsafe optimisations when using Netty with Java9
Motivation:
When sun.misc.Unsafe is present we want to use *Unsafe*ByteBuf implementations. We missed to do so in PooledByteBufAllocator when the heapArena is null.
Modifications:
- Correctly use UnpooledUnsafeHeapByteBuf
- Add unit tests
Result:
Use most optimal ByteBuf implementation.
Motivation:
We can eliminate unnessary wrapping when call ByteBuf.asReadOnly() in some cases to reduce indirection.
Modifications:
- Check if asReadOnly() needs to create a new instance or not
- Add test cases
Result:
Less object creation / wrapping.
Motivation:
We need to ensure we pass all tests when sun.misc.Unsafe is not present.
Modifications:
- Make *ByteBufAllocatorTest work whenever sun.misc.Unsafe is present or not
- Let Lz4FrameEncoderTest not depend on AbstractByteBufAllocator implementation details which take into account if sun.misc.Unsafe is present or not
Result:
Tests pass even without sun.misc.Unsafe.
Motivation:
We should only try to calculate the direct memory offset when sun.misc.Unsafe is present as otherwise it will fail with an NPE as PlatformDependent.directBufferAddress(...) will throw it.
This problem was introduced by 66b9be3a46.
Modifications:
Use offset of 0 if no sun.misc.Unsafe is present.
Result:
PooledByteBufAllocator also works again when no sun.misc.Unsafe is present.
Motivation:
ReadOnlyByteBufTest contains two tests which are missing the `@Test` annotation and so will never run.
Modifications:
Add missing annotation.
Result:
Tests run as expected.
Motivation:
We used various mocking frameworks. We should only use one...
Modifications:
Make usage of mocking framework consistent by only using Mockito.
Result:
Less dependencies and more consistent mocking usage.
Motivation:
64-byte alignment is recommended by the Intel performance guide (https://software.intel.com/en-us/articles/practical-intel-avx-optimization-on-2nd-generation-intel-core-processors) for data-structures over 64 bytes.
Requiring padding to a multiple of 64 bytes allows for using SIMD instructions consistently in loops without additional conditional checks. This should allow for simpler and more efficient code.
Modification:
At the moment cache alignment must be setup manually. But probably it might be taken from the system. The original code was introduced by @normanmaurer https://github.com/netty/netty/pull/4726/files
Result:
Buffer alignment works better than miss-align cache.
Motivation:
We not had tests for ByteBufAllocator implementations in general.
Modifications:
Added ByteBufAllocatorTest, AbstractByteBufAllocatorTest and UnpooledByteBufAllocatorTest
Result:
More tests for allocator implementations.
Motivation:
PooledByteBuf.capacity(...) miss to enforce maxCapacity() and so its possible to increase the capacity of the buffer even if it will be bigger then maxCapacity().
Modifications:
- Correctly enforce maxCapacity()
- Add unit tests for capacity(...) calls.
Result:
Correctly enforce maxCapacity().
Motivation:
When An HTTP server is listening in plaintext mode, it doesn't have
a chance to negotiate "h2" in the tls handshake. HTTP 1 clients
that are not expecting an HTTP2 server will accidentally a request
that isn't an upgrade, which the HTTP/2 decoder will not
understand. The decoder treats the bytes as hex and adds them to
the error message.
These error messages are hard to understand by humans, and result
in extra, manual work to decode.
Modification:
If the first bytes of the request are not the preface, the decoder
will now see if they are an HTTP/1 request first. If so, the error
message will include the method and path of the original request in
the error message.
In case the path is long, the decoder will check up to the first
1024 bytes to see if it matches. This could be a DoS vector if
tons of bad requests or other garbage come in. A future optimization
would be to treat the first few bytes as an AsciiString and not do
any Charset decoding. ByteBuf.toCharSequence alludes to such an
optimization.
The code has been left simple for the time being.
Result:
Faster identification of errant HTTP requests.
Motivation:
Disable ThreadLocal Cache, then allocate Pooled ByteBuf and release all these buffers, PoolArena's tiny/small/normal allocation count is incorrect.
Modifications:
- Calculate PoolArena's tiny/small/normal allocation one time
- Add testAllocationCounter TestCase
Result:
Fixes#6282 .
Motivation:
In PooledByteBuf we missed to null out the chunk and tmpNioBuf fields before recycle it to the Recycler. This could lead to keep objects longer alive then necessary which may hold a lot of memory.
Modifications:
Null out tmpNioBuf and chunk before recycle.
Result:
Possible to earlier GC objects.
Motivation:
ByteBufUtil.compare uses long arithmetic but doesn't check for underflow on when converting from long to int to satisfy the Comparable interface. This will result in incorrect comparisons and violate the Comparable interface contract.
Modifications:
- ByteBufUtil.compare should protect against int underflow
Result:
Fixes https://github.com/netty/netty/issues/6169
Motivation:
In later Java8 versions our Atomic*FieldUpdater are slower then the JDK implementations so we should not use ours anymore. Even worse the JDK implementations provide for example an optimized version of addAndGet(...) using intrinsics which makes it a lot faster for this use-case.
Modifications:
- Remove methods that return our own Atomic*FieldUpdaters.
- Use the JDK implementations everywhere.
Result:
Faster code.
Motivation:
We should assert that the leak aware buffers correctly close the ResourceLeakTracker in the unit tests.
Modifications:
- Keep track of NoopResourceLeakTrackers and check if these were closed once the test completes
- Fix bugs in tests so the buffers are all released.
Result:
Better tests for leak aware buffers
Motivation:
If caches are disabled it does not make sense to schedule a task that will free up memory consumed by the caches.
Modifications:
Do not schedule if caches are disabled.
Result:
Less overhead.
Motivation:
We need to ensure the tracked object can not be GC'ed before ResourceLeak.close() is called as otherwise we may get false-positives reported by the ResourceLeakDetector. This can happen as the JIT / GC may be able to figure out that we do not need the tracked object anymore and so already enqueue it for collection before we actually get a chance to close the enclosing ResourceLeak.
Modifications:
- Add ResourceLeakTracker and deprecate the old ResourceLeak
- Fix some javadocs to correctly release buffers.
- Add a unit test for ResourceLeakDetector that shows that ResourceLeakTracker has not the problems.
Result:
No more false-positives reported by ResourceLeakDetector when ResourceLeakDetector.track(...) is used.
Motivation:
PooledByteBufAllocatorTest uses an ArrayQueue but access it from multiple threads (not concurrently but still from different threads). This may leak to memory visibility issues.
Modifications:
- Use a concurrent queue
- Some cleanup
Result:
Non racy test code.
Motivation:
If a user allocates a lot from outside the EventLoop we may end up creating a lot of caches in the PooledByteBufAllocator. This may be wasteful and so it may be useful for an other to configure that caches should only be used from within EventLoops.
Modifications:
Add new constructor which allows to configure the caching behaviour.
Result:
More flexible configuration of PooledByteBufAllocator possible
Motivation:
We support using Netty without sun.misc.Unsafe, so we should also support building it without it. This way we can also run all tests without sun.misc.Unsafe and so see if it works as expected.
Modifications:
Correctly skip tests that depend on sun.misc.Unsafe if its not present or -Dio.netty.noUnsafe=true is used.
Result:
Be able to build netty without sun.misc.Unsafe
Motivation:
SwappedByteBuf.unwrap() not returned the wrapped buffer but the buffer that was wrapped by the original buffer. This is not correct.
Modifications:
Correctly return wrapped buffer and fix test.
Result:
SwappedByteBuf.unwrap() works as expected.
Motivation:
We had a few tests PooledByteBufAllocatorTests which used parkNanos(...) to give a resource enough time to get destroyed. This is race and may not be good enough.
Modifications:
Ensure the ThreadCache is really destroyed.
Result:
No more racy tests that depend on ThreadCaches.
Motivation:
IntelliJ issues several warnings.
Modifications:
* `ClientCookieDecoder` and `ServerCookieDecoder`:
* `nameEnd`, `valueBegin` and `valueEnd` don't need to be initialized
* `keyValLoop` loop doesn't been to be labelled, as it's the most inner one (same thing for labelled breaks)
* Remove `if (i != headerLen)` as condition is always true
* `ClientCookieEncoder` javadoc still mention old logic
* `DefaultCookie`, `ServerCookieEncoder` and `DefaultHttpHeaders` use ternary ops that can be turned into simple boolean ones
* `DefaultHeaders` uses a for(int) loop over an array. It can be turned into a foreach one as javac doesn't allocate an iterator to iterate over arrays
* `DefaultHttp2Headers` and `AbstractByteBuf` `equal` can be turned into a single boolean statement
Result:
Cleaner code
Motivation:
4bba7526e2 introduced changes which made pooled and unpooled derived buffers inconsistent in a few ways:
- Pooled derived buffers always generated a duplicate buffer when duplicate() was called and always generated a sliced buffer when slice() was called. Unpooled derived buffers some times generated a sliced buffer when duplicate() was called.
- The indexes that were set for duplicate buffers generated from slices were not always consistent.
There were also some various bugs in the derived pooled buffer implementation.
Modifications:
- Make pooled/unpooled consistently generate duplicate buffers when duplicate() is called and sliced buffers when slice() is called.
- Fix bugs in the derived pooled buffer
Result:
More consistent behavior from the derived pooled/unpooled buffers.
Motiviation:
We used ReferenceCountUtil.releaseLater(...) in our tests which simplifies a bit the releasing of ReferenceCounted objects. The problem with this is that while it simplifies stuff it increase memory usage a lot as memory may not be freed up in a timely manner.
Modifications:
- Deprecate releaseLater(...)
- Remove usage of releaseLater(...) in tests.
Result:
Less memory needed to build netty while running the tests.
Motivation:
Currently the ByteBuf created as a result of retained[Slice|Duplicate] maintains its own reference count, and when this reference count is depleated it will release the ByteBuf returned from unwrap(). The unwrap() buffer is designed to be the 'root parent' and will skip all intermediate layers of buffers. If the intermediate layers of buffers contain a retained[Slice|Duplicate] then these reference counts will be ignored during deallocation. This may lead to deallocating the 'root parent' before all derived pooled buffers are actually released. This same issue holds if a retained[Slice|Duplicate] is in the heirachy and a 'regular' slice() or duplicate() buffer is created.
Modifications:
- AbstractPooledDerivedByteBuf must maintain a reference to the direct parent (the buffer which retained[Slice|Duplicate] was called on) and release on this buffer instead of the 'root parent' returned by unwrap()
- slice() and duplicate() buffers created from AbstractPooledDerivedByteBuf must also delegate reference count operations to their immediate parent (or first ancestor which maintains an independent reference count).
Result:
Fixes https://github.com/netty/netty/issues/5999
Motivation:
Netty provides a adaptor from ByteBuf to Java's InputStream interface. The JDK Stream interfaces have an explicit lifetime because they implement the Closable interface. This lifetime may be differnt than the ByteBuf which is wrapped, and controlled by the interface which accepts the JDK Stream. However Netty's ByteBufInputStream currently does not take reference count ownership of the underlying ByteBuf. There may be no way for existing classes which only accept the InputStream interface to communicate when they are done with the stream, other than calling close(). This means that when the stream is closed it may be appropriate to release the underlying ByteBuf, as the ownership of the underlying ByteBuf resource may be transferred to the Java Stream.
Motivation:
- ByteBufInputStream.close() supports taking reference count ownership of the underyling ByteBuf
Result:
ByteBufInputStream can assume reference count ownership so the underlying ByteBuf can be cleaned up when the stream is closed.
Motivation:
In some ByteBuf implementations we not correctly implement getBytes(index, ByteBuffer).
Modifications:
Correct code to do what is defined in the javadocs and adding test.
Result:
Implementation works as described.
Motivation:
the build doesnt seem to enforce this, so they piled up
Modifications:
removed unused import lines
Result:
less unused imports
Signed-off-by: radai-rosenblatt <radai.rosenblatt@gmail.com>
Motivation:
We need to ensure we release all direct memory once the DirectPoolArena is collected. Otherwise we may never reclaim the memory and so leak memory.
Modifications:
Ensure we destroy all PoolChunk memory when DirectPoolArena is collected.
Result:
Free up unreleased memory when DirectPoolArena is collected.