public void PartialReadGenerator_will_create_partial_read()
{
var prepender = new LengthFieldPrepender(4, false);
var decoder = new LengthFieldBasedFrameDecoder(int.MaxValue, 0, 4, 0, 4);
var partialReader = new PartialReadGenerator(new[] { new ReadInstruction(ReadMode.Partial, 5, 8) });
var ec = new EmbeddedChannel(partialReader, prepender, decoder);
var byteBuff = Unpooled.Buffer(10).WriteInt(4).WriteInt(10);
ec.WriteAndFlushAsync(byteBuff.Duplicate()).Wait();
IByteBuf encoded;
do
{
encoded = ec.ReadOutbound <IByteBuf>();
if (encoded != null)
{
ec.WriteInbound(encoded);
}
} while (encoded != null);
// finish the read
ec.Pipeline.FireUserEventTriggered(PartialReadGenerator.FinishPartialReads.Instance);
var inboud = ec.ReadInbound <IByteBuf>();
Assert.Equal(byteBuff.ResetReaderIndex(), inboud, AbstractByteBuf.ByteBufComparer);
}
public Property HeliosBackwardsCompatibilityLengthFrameEncoders_should_correctly_encode_anything_LittleEndian(
Tuple <IByteBuf, ReadInstruction>[] reads)
{
var expectedReads = reads.Select(x => x.Item1).ToArray();
var readModes = reads.Select(x => x.Item2).ToArray();
var partialReader = new PartialReadGenerator(readModes);
var prepender = new HeliosBackwardsCompatabilityLengthFramePrepender(4, false);
var decoder = new LengthFieldBasedFrameDecoder(int.MaxValue, 0, 4, 0, 4);
var ec = new EmbeddedChannel(partialReader, prepender, decoder);
foreach (var read in expectedReads)
{
var task = ec.WriteAndFlushAsync(read.Duplicate());
task.Wait();
IByteBuf encoded;
do
{
encoded = ec.ReadOutbound <IByteBuf>();
if (encoded != null)
{
ec.WriteInbound(encoded);
}
} while (encoded != null);
}
var actualReads = new List <IByteBuf>();
// do one final read in case the last readmode was a partial
ec.Pipeline.FireUserEventTriggered(PartialReadGenerator.FinishPartialReads.Instance);
IByteBuf decoded;
do
{
decoded = ec.ReadInbound <IByteBuf>();
if (decoded != null)
{
actualReads.Add(decoded);
}
} while (decoded != null);
expectedReads = expectedReads.Select(x => x.ResetReaderIndex()).ToArray();
// need to perform a read reset of the buffer
var pass = expectedReads.SequenceEqual(actualReads, AbstractByteBuf.ByteBufComparer);
if (!pass)
{
Debugger.Break();
}
return
(pass
.When(reads.Length > 0 // need something to read
)
.Label($"Expected encoders and decoders to read each other's messages, even with partial reads. " +
$"Expected: {string.Join("|", expectedReads.Select(x => ByteBufferUtil.HexDump(x)))}" +
Environment.NewLine +
$"Actual: {string.Join("|", actualReads.Select(x => ByteBufferUtil.HexDump(x)))}"));
}
public void PartialReadGenerator_will_correctly_handle_multiple_reads()
{
var prepender = new LengthFieldPrepender(4, false);
var decoder = new LengthFieldBasedFrameDecoder(int.MaxValue, 0, 4, 0, 4);
var partialReader =
new PartialReadGenerator(new[]
{
new ReadInstruction(ReadMode.Partial, 2, 8), new ReadInstruction(ReadMode.Partial, 4, 8),
new ReadInstruction(ReadMode.Full, 8, 8)
});
var ec = new EmbeddedChannel(partialReader, prepender, decoder);
var byteBuf1 = Unpooled.Buffer(10).WriteInt(4).WriteInt(10);
var byteBuf2 = Unpooled.Buffer(100).WriteInt(5).WriteInt(6).WriteBytes(new byte[92]);
var byteBuf3 = Unpooled.Buffer(10).WriteInt(21).WriteInt(11);
Task.WaitAll(ec.WriteAndFlushAsync(byteBuf1.Duplicate().Retain()),
ec.WriteAndFlushAsync(byteBuf2.Duplicate().Retain()),
ec.WriteAndFlushAsync(byteBuf3.Duplicate().Retain()));
IByteBuf encoded;
do
{
encoded = ec.ReadOutbound <IByteBuf>();
if (encoded != null)
{
ec.WriteInbound(encoded.Duplicate().Retain());
}
} while (encoded != null);
// finish the read
ec.Pipeline.FireUserEventTriggered(PartialReadGenerator.FinishPartialReads.Instance);
var inbound1 = ec.ReadInbound <IByteBuf>();
var inbound2 = ec.ReadInbound <IByteBuf>();
var inbound3 = ec.ReadInbound <IByteBuf>();
Assert.Equal(byteBuf1.ResetReaderIndex(), inbound1, AbstractByteBuf.ByteBufComparer);
Assert.Equal(byteBuf2.ResetReaderIndex(), inbound2, AbstractByteBuf.ByteBufComparer);
Assert.Equal(byteBuf3.ResetReaderIndex(), inbound3, AbstractByteBuf.ByteBufComparer);
byteBuf1.Release();
byteBuf2.Release();
byteBuf3.Release();
}
public void PartialReadGenerator_will_correctly_handle_multiple_reads()
{
var prepender = new LengthFieldPrepender(4, false);
var decoder = new LengthFieldBasedFrameDecoder(int.MaxValue, 0, 4, 0, 4);
var partialReader =
new PartialReadGenerator(new[]
{
new ReadInstruction(ReadMode.Partial, 2, 8), new ReadInstruction(ReadMode.Partial, 4, 8),
new ReadInstruction(ReadMode.Full, 8, 8)
});
var ec = new EmbeddedChannel(partialReader, prepender, decoder);
var byteBuf1 = Unpooled.Buffer(10).WriteInt(4).WriteInt(10);
var byteBuf2 = Unpooled.Buffer(100).WriteInt(5).WriteInt(6).WriteBytes(new byte[92]);
var byteBuf3 = Unpooled.Buffer(10).WriteInt(21).WriteInt(11);
Task.WaitAll(ec.WriteAndFlushAsync(byteBuf1.Duplicate().Retain()),
ec.WriteAndFlushAsync(byteBuf2.Duplicate().Retain()),
ec.WriteAndFlushAsync(byteBuf3.Duplicate().Retain()));
IByteBuf encoded;
do
{
encoded = ec.ReadOutbound<IByteBuf>();
if (encoded != null)
ec.WriteInbound(encoded.Duplicate().Retain());
} while (encoded != null);
// finish the read
ec.Pipeline.FireUserEventTriggered(PartialReadGenerator.FinishPartialReads.Instance);
var inbound1 = ec.ReadInbound<IByteBuf>();
var inbound2 = ec.ReadInbound<IByteBuf>();
var inbound3 = ec.ReadInbound<IByteBuf>();
Assert.Equal(byteBuf1.ResetReaderIndex(), inbound1, AbstractByteBuf.ByteBufComparer);
Assert.Equal(byteBuf2.ResetReaderIndex(), inbound2, AbstractByteBuf.ByteBufComparer);
Assert.Equal(byteBuf3.ResetReaderIndex(), inbound3, AbstractByteBuf.ByteBufComparer);
byteBuf1.Release();
byteBuf2.Release();
byteBuf3.Release();
}
public void PartialReadGenerator_will_create_partial_read()
{
var prepender = new LengthFieldPrepender(4, false);
var decoder = new LengthFieldBasedFrameDecoder(int.MaxValue, 0, 4, 0, 4);
var partialReader = new PartialReadGenerator(new[] {new ReadInstruction(ReadMode.Partial, 5, 8)});
var ec = new EmbeddedChannel(partialReader, prepender, decoder);
var byteBuff = Unpooled.Buffer(10).WriteInt(4).WriteInt(10);
ec.WriteAndFlushAsync(byteBuff.Duplicate()).Wait();
IByteBuf encoded;
do
{
encoded = ec.ReadOutbound<IByteBuf>();
if (encoded != null)
ec.WriteInbound(encoded);
} while (encoded != null);
// finish the read
ec.Pipeline.FireUserEventTriggered(PartialReadGenerator.FinishPartialReads.Instance);
var inboud = ec.ReadInbound<IByteBuf>();
Assert.Equal(byteBuff.ResetReaderIndex(), inboud, AbstractByteBuf.ByteBufComparer);
}
public Property LengthFrameEncoders_should_correctly_encode_anything_LittleEndian(
Tuple<IByteBuf, ReadInstruction>[] reads)
{
var expectedReads = reads.Select(x => x.Item1).ToArray();
var readModes = reads.Select(x => x.Item2).ToArray();
var partialReader = new PartialReadGenerator(readModes);
var prepender = new LengthFieldPrepender(4, false);
var decoder = new LengthFieldBasedFrameDecoder(int.MaxValue, 0, 4, 0, 4);
var ec = new EmbeddedChannel(partialReader, prepender, decoder);
foreach (var read in expectedReads)
{
ec.WriteAndFlushAsync(read.Duplicate()).Wait();
IByteBuf encoded;
do
{
encoded = ec.ReadOutbound<IByteBuf>();
if (encoded != null)
ec.WriteInbound(encoded);
} while (encoded != null);
}
var actualReads = new List<IByteBuf>();
// do one final read in case the last readmode was a partial
ec.Pipeline.FireUserEventTriggered(PartialReadGenerator.FinishPartialReads.Instance);
IByteBuf decoded;
do
{
decoded = ec.ReadInbound<IByteBuf>();
if (decoded != null)
{
actualReads.Add(decoded);
}
} while (decoded != null);
expectedReads = expectedReads.Select(x => x.ResetReaderIndex()).ToArray();
// need to perform a read reset of the buffer
var pass = expectedReads.SequenceEqual(actualReads, AbstractByteBuf.ByteBufComparer);
if (!pass)
{
Debugger.Break();
}
return
pass
.When(reads.Length > 0 // need something to read
)
.Label($"Expected encoders and decoders to read each other's messages, even with partial reads. " +
$"Expected: {string.Join("|", expectedReads.Select(x => ByteBufferUtil.HexDump(x)))}" +
Environment.NewLine +
$"Actual: {string.Join("|", actualReads.Select(x => ByteBufferUtil.HexDump(x)))}");
}