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// Copyright 2023 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build go1.21
package quic
import (
"bytes"
"context"
"crypto/rand"
"errors"
"fmt"
"io"
"strings"
"testing"
)
func TestStreamWriteBlockedByOutputBuffer(t *testing.T) {
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
ctx := canceledContext()
want := []byte{0, 1, 2, 3, 4, 5, 6, 7, 8, 9}
const writeBufferSize = 4
tc := newTestConn(t, clientSide, permissiveTransportParameters, func(c *Config) {
c.MaxStreamWriteBufferSize = writeBufferSize
})
tc.handshake()
tc.ignoreFrame(frameTypeAck)
s, err := tc.conn.newLocalStream(ctx, styp)
if err != nil {
t.Fatal(err)
}
// Non-blocking write.
n, err := s.WriteContext(ctx, want)
if n != writeBufferSize || err != context.Canceled {
t.Fatalf("s.WriteContext() = %v, %v; want %v, context.Canceled", n, err, writeBufferSize)
}
s.Flush()
tc.wantFrame("first write buffer of data sent",
packetType1RTT, debugFrameStream{
id: s.id,
data: want[:writeBufferSize],
})
off := int64(writeBufferSize)
// Blocking write, which must wait for buffer space.
w := runAsync(tc, func(ctx context.Context) (int, error) {
n, err := s.WriteContext(ctx, want[writeBufferSize:])
s.Flush()
return n, err
})
tc.wantIdle("write buffer is full, no more data can be sent")
// The peer's ack of the STREAM frame allows progress.
tc.writeAckForAll()
tc.wantFrame("second write buffer of data sent",
packetType1RTT, debugFrameStream{
id: s.id,
off: off,
data: want[off:][:writeBufferSize],
})
off += writeBufferSize
tc.wantIdle("write buffer is full, no more data can be sent")
// The peer's ack of the second STREAM frame allows sending the remaining data.
tc.writeAckForAll()
tc.wantFrame("remaining data sent",
packetType1RTT, debugFrameStream{
id: s.id,
off: off,
data: want[off:],
})
if n, err := w.result(); n != len(want)-writeBufferSize || err != nil {
t.Fatalf("s.WriteContext() = %v, %v; want %v, nil",
len(want)-writeBufferSize, err, writeBufferSize)
}
})
}
func TestStreamWriteBlockedByStreamFlowControl(t *testing.T) {
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
ctx := canceledContext()
want := []byte{0, 1, 2, 3, 4, 5, 6, 7, 8, 9}
tc := newTestConn(t, clientSide, func(p *transportParameters) {
p.initialMaxStreamsBidi = 100
p.initialMaxStreamsUni = 100
p.initialMaxData = 1 << 20
})
tc.handshake()
tc.ignoreFrame(frameTypeAck)
s, err := tc.conn.newLocalStream(ctx, styp)
if err != nil {
t.Fatal(err)
}
// Data is written to the stream output buffer, but we have no flow control.
_, err = s.WriteContext(ctx, want[:1])
if err != nil {
t.Fatalf("write with available output buffer: unexpected error: %v", err)
}
tc.wantFrame("write blocked by flow control triggers a STREAM_DATA_BLOCKED frame",
packetType1RTT, debugFrameStreamDataBlocked{
id: s.id,
max: 0,
})
// Write more data.
_, err = s.WriteContext(ctx, want[1:])
if err != nil {
t.Fatalf("write with available output buffer: unexpected error: %v", err)
}
tc.wantIdle("adding more blocked data does not trigger another STREAM_DATA_BLOCKED")
// Provide some flow control window.
tc.writeFrames(packetType1RTT, debugFrameMaxStreamData{
id: s.id,
max: 4,
})
tc.wantFrame("stream window extended, but still more data to write",
packetType1RTT, debugFrameStreamDataBlocked{
id: s.id,
max: 4,
})
tc.wantFrame("stream window extended to 4, expect blocked write to progress",
packetType1RTT, debugFrameStream{
id: s.id,
data: want[:4],
})
// Provide more flow control window.
tc.writeFrames(packetType1RTT, debugFrameMaxStreamData{
id: s.id,
max: int64(len(want)),
})
tc.wantFrame("stream window extended further, expect blocked write to finish",
packetType1RTT, debugFrameStream{
id: s.id,
off: 4,
data: want[4:],
})
})
}
func TestStreamIgnoresMaxStreamDataReduction(t *testing.T) {
// "A sender MUST ignore any MAX_STREAM_DATA [...] frames that
// do not increase flow control limits."
// https://www.rfc-editor.org/rfc/rfc9000#section-4.1-9
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
ctx := canceledContext()
want := []byte{0, 1, 2, 3, 4, 5, 6, 7, 8, 9}
tc := newTestConn(t, clientSide, func(p *transportParameters) {
if styp == uniStream {
p.initialMaxStreamsUni = 1
p.initialMaxStreamDataUni = 4
} else {
p.initialMaxStreamsBidi = 1
p.initialMaxStreamDataBidiRemote = 4
}
p.initialMaxData = 1 << 20
})
tc.handshake()
tc.ignoreFrame(frameTypeAck)
tc.ignoreFrame(frameTypeStreamDataBlocked)
// Write [0,1).
s, err := tc.conn.newLocalStream(ctx, styp)
if err != nil {
t.Fatal(err)
}
s.WriteContext(ctx, want[:1])
s.Flush()
tc.wantFrame("sent data (1 byte) fits within flow control limit",
packetType1RTT, debugFrameStream{
id: s.id,
off: 0,
data: want[:1],
})
// MAX_STREAM_DATA tries to decrease limit, and is ignored.
tc.writeFrames(packetType1RTT, debugFrameMaxStreamData{
id: s.id,
max: 2,
})
// Write [1,4).
s.WriteContext(ctx, want[1:])
tc.wantFrame("stream limit is 4 bytes, ignoring decrease in MAX_STREAM_DATA",
packetType1RTT, debugFrameStream{
id: s.id,
off: 1,
data: want[1:4],
})
// MAX_STREAM_DATA increases limit.
// Second MAX_STREAM_DATA decreases it, and is ignored.
tc.writeFrames(packetType1RTT, debugFrameMaxStreamData{
id: s.id,
max: 8,
})
tc.writeFrames(packetType1RTT, debugFrameMaxStreamData{
id: s.id,
max: 6,
})
// Write [1,4).
s.WriteContext(ctx, want[4:])
tc.wantFrame("stream limit is 8 bytes, ignoring decrease in MAX_STREAM_DATA",
packetType1RTT, debugFrameStream{
id: s.id,
off: 4,
data: want[4:8],
})
})
}
func TestStreamWriteBlockedByWriteBufferLimit(t *testing.T) {
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
ctx := canceledContext()
want := []byte{0, 1, 2, 3, 4, 5, 6, 7, 8, 9}
const maxWriteBuffer = 4
tc := newTestConn(t, clientSide, func(p *transportParameters) {
p.initialMaxStreamsBidi = 100
p.initialMaxStreamsUni = 100
p.initialMaxData = 1 << 20
p.initialMaxStreamDataBidiRemote = 1 << 20
p.initialMaxStreamDataUni = 1 << 20
}, func(c *Config) {
c.MaxStreamWriteBufferSize = maxWriteBuffer
})
tc.handshake()
tc.ignoreFrame(frameTypeAck)
// Write more data than StreamWriteBufferSize.
// The peer has given us plenty of flow control,
// so we're just blocked by our local limit.
s, err := tc.conn.newLocalStream(ctx, styp)
if err != nil {
t.Fatal(err)
}
w := runAsync(tc, func(ctx context.Context) (int, error) {
return s.WriteContext(ctx, want)
})
tc.wantFrame("stream write should send as much data as write buffer allows",
packetType1RTT, debugFrameStream{
id: s.id,
off: 0,
data: want[:maxWriteBuffer],
})
tc.wantIdle("no STREAM_DATA_BLOCKED, we're blocked locally not by flow control")
// ACK for previously-sent data allows making more progress.
tc.writeAckForAll()
tc.wantFrame("ACK for previous data allows making progress",
packetType1RTT, debugFrameStream{
id: s.id,
off: maxWriteBuffer,
data: want[maxWriteBuffer:][:maxWriteBuffer],
})
// Cancel the write with data left to send.
w.cancel()
n, err := w.result()
if n != 2*maxWriteBuffer || err == nil {
t.Fatalf("WriteContext() = %v, %v; want %v bytes, error", n, err, 2*maxWriteBuffer)
}
})
}
func TestStreamReceive(t *testing.T) {
// "Endpoints MUST be able to deliver stream data to an application as
// an ordered byte stream."
// https://www.rfc-editor.org/rfc/rfc9000#section-2.2-2
want := make([]byte, 5000)
for i := range want {
want[i] = byte(i)
}
type frame struct {
start int64
end int64
fin bool
want int
wantEOF bool
}
for _, test := range []struct {
name string
frames []frame
}{{
name: "linear",
frames: []frame{{
start: 0,
end: 1000,
want: 1000,
}, {
start: 1000,
end: 2000,
want: 2000,
}, {
start: 2000,
end: 3000,
want: 3000,
fin: true,
wantEOF: true,
}},
}, {
name: "out of order",
frames: []frame{{
start: 1000,
end: 2000,
}, {
start: 2000,
end: 3000,
}, {
start: 0,
end: 1000,
want: 3000,
}},
}, {
name: "resent",
frames: []frame{{
start: 0,
end: 1000,
want: 1000,
}, {
start: 0,
end: 1000,
want: 1000,
}, {
start: 1000,
end: 2000,
want: 2000,
}, {
start: 0,
end: 1000,
want: 2000,
}, {
start: 1000,
end: 2000,
want: 2000,
}},
}, {
name: "overlapping",
frames: []frame{{
start: 0,
end: 1000,
want: 1000,
}, {
start: 3000,
end: 4000,
want: 1000,
}, {
start: 2000,
end: 3000,
want: 1000,
}, {
start: 1000,
end: 3000,
want: 4000,
}},
}, {
name: "early eof",
frames: []frame{{
start: 3000,
end: 3000,
fin: true,
want: 0,
}, {
start: 1000,
end: 2000,
want: 0,
}, {
start: 0,
end: 1000,
want: 2000,
}, {
start: 2000,
end: 3000,
want: 3000,
wantEOF: true,
}},
}, {
name: "empty eof",
frames: []frame{{
start: 0,
end: 1000,
want: 1000,
}, {
start: 1000,
end: 1000,
fin: true,
want: 1000,
wantEOF: true,
}},
}} {
testStreamTypes(t, test.name, func(t *testing.T, styp streamType) {
ctx := canceledContext()
tc := newTestConn(t, serverSide)
tc.handshake()
sid := newStreamID(clientSide, styp, 0)
var s *Stream
got := make([]byte, len(want))
var total int
for _, f := range test.frames {
t.Logf("receive [%v,%v)", f.start, f.end)
tc.writeFrames(packetType1RTT, debugFrameStream{
id: sid,
off: f.start,
data: want[f.start:f.end],
fin: f.fin,
})
if s == nil {
var err error
s, err = tc.conn.AcceptStream(ctx)
if err != nil {
tc.t.Fatalf("conn.AcceptStream() = %v", err)
}
}
for {
n, err := s.ReadContext(ctx, got[total:])
t.Logf("s.ReadContext() = %v, %v", n, err)
total += n
if f.wantEOF && err != io.EOF {
t.Fatalf("ReadContext() error = %v; want io.EOF", err)
}
if !f.wantEOF && err == io.EOF {
t.Fatalf("ReadContext() error = io.EOF, want something else")
}
if err != nil {
break
}
}
if total != f.want {
t.Fatalf("total bytes read = %v, want %v", total, f.want)
}
for i := 0; i < total; i++ {
if got[i] != want[i] {
t.Fatalf("byte %v differs: got %v, want %v", i, got[i], want[i])
}
}
}
})
}
}
func TestStreamReceiveExtendsStreamWindow(t *testing.T) {
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
const maxWindowSize = 20
ctx := canceledContext()
tc := newTestConn(t, serverSide, func(c *Config) {
c.MaxStreamReadBufferSize = maxWindowSize
})
tc.handshake()
tc.ignoreFrame(frameTypeAck)
sid := newStreamID(clientSide, styp, 0)
tc.writeFrames(packetType1RTT, debugFrameStream{
id: sid,
off: 0,
data: make([]byte, maxWindowSize),
})
s, err := tc.conn.AcceptStream(ctx)
if err != nil {
t.Fatalf("AcceptStream: %v", err)
}
tc.wantIdle("stream window is not extended before data is read")
buf := make([]byte, maxWindowSize+1)
if n, err := s.ReadContext(ctx, buf); n != maxWindowSize || err != nil {
t.Fatalf("s.ReadContext() = %v, %v; want %v, nil", n, err, maxWindowSize)
}
tc.wantFrame("stream window is extended after reading data",
packetType1RTT, debugFrameMaxStreamData{
id: sid,
max: maxWindowSize * 2,
})
tc.writeFrames(packetType1RTT, debugFrameStream{
id: sid,
off: maxWindowSize,
data: make([]byte, maxWindowSize),
fin: true,
})
if n, err := s.ReadContext(ctx, buf); n != maxWindowSize || err != io.EOF {
t.Fatalf("s.ReadContext() = %v, %v; want %v, io.EOF", n, err, maxWindowSize)
}
tc.wantIdle("stream window is not extended after FIN")
})
}
func TestStreamReceiveViolatesStreamDataLimit(t *testing.T) {
// "A receiver MUST close the connection with an error of type FLOW_CONTROL_ERROR if
// the sender violates the advertised [...] stream data limits [...]"
// https://www.rfc-editor.org/rfc/rfc9000#section-4.1-8
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
const maxStreamData = 10
for _, test := range []struct {
off int64
size int64
}{{
off: maxStreamData,
size: 1,
}, {
off: 0,
size: maxStreamData + 1,
}, {
off: maxStreamData - 1,
size: 2,
}} {
tc := newTestConn(t, serverSide, func(c *Config) {
c.MaxStreamReadBufferSize = maxStreamData
})
tc.handshake()
tc.ignoreFrame(frameTypeAck)
tc.writeFrames(packetType1RTT, debugFrameStream{
id: newStreamID(clientSide, styp, 0),
off: test.off,
data: make([]byte, test.size),
})
tc.wantFrame(
fmt.Sprintf("data [%v,%v) violates stream data limit and closes connection",
test.off, test.off+test.size),
packetType1RTT, debugFrameConnectionCloseTransport{
code: errFlowControl,
},
)
}
})
}
func TestStreamReceiveDuplicateDataDoesNotViolateLimits(t *testing.T) {
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
const maxData = 10
tc := newTestConn(t, serverSide, func(c *Config) {
// TODO: Add connection-level maximum data here as well.
c.MaxStreamReadBufferSize = maxData
})
tc.handshake()
tc.ignoreFrame(frameTypeAck)
for i := 0; i < 3; i++ {
tc.writeFrames(packetType1RTT, debugFrameStream{
id: newStreamID(clientSide, styp, 0),
off: 0,
data: make([]byte, maxData),
})
tc.wantIdle(fmt.Sprintf("conn sends no frames after receiving data frame %v", i))
}
})
}
func finalSizeTest(t *testing.T, wantErr transportError, f func(tc *testConn, sid streamID) (finalSize int64), opts ...any) {
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
for _, test := range []struct {
name string
finalFrame func(tc *testConn, sid streamID, finalSize int64)
}{{
name: "FIN",
finalFrame: func(tc *testConn, sid streamID, finalSize int64) {
tc.writeFrames(packetType1RTT, debugFrameStream{
id: sid,
off: finalSize,
fin: true,
})
},
}, {
name: "RESET_STREAM",
finalFrame: func(tc *testConn, sid streamID, finalSize int64) {
tc.writeFrames(packetType1RTT, debugFrameResetStream{
id: sid,
finalSize: finalSize,
})
},
}} {
t.Run(test.name, func(t *testing.T) {
tc := newTestConn(t, serverSide, opts...)
tc.handshake()
sid := newStreamID(clientSide, styp, 0)
finalSize := f(tc, sid)
test.finalFrame(tc, sid, finalSize)
tc.wantFrame("change in final size of stream is an error",
packetType1RTT, debugFrameConnectionCloseTransport{
code: wantErr,
},
)
})
}
})
}
func TestStreamFinalSizeChangedAfterFin(t *testing.T) {
// "If a RESET_STREAM or STREAM frame is received indicating a change
// in the final size for the stream, an endpoint SHOULD respond with
// an error of type FINAL_SIZE_ERROR [...]"
// https://www.rfc-editor.org/rfc/rfc9000#section-4.5-5
finalSizeTest(t, errFinalSize, func(tc *testConn, sid streamID) (finalSize int64) {
tc.writeFrames(packetType1RTT, debugFrameStream{
id: sid,
off: 10,
fin: true,
})
return 9
})
}
func TestStreamFinalSizeBeforePreviousData(t *testing.T) {
finalSizeTest(t, errFinalSize, func(tc *testConn, sid streamID) (finalSize int64) {
tc.writeFrames(packetType1RTT, debugFrameStream{
id: sid,
off: 10,
data: []byte{0},
})
return 9
})
}
func TestStreamFinalSizePastMaxStreamData(t *testing.T) {
finalSizeTest(t, errFlowControl, func(tc *testConn, sid streamID) (finalSize int64) {
return 11
}, func(c *Config) {
c.MaxStreamReadBufferSize = 10
})
}
func TestStreamDataBeyondFinalSize(t *testing.T) {
// "A receiver SHOULD treat receipt of data at or beyond
// the final size as an error of type FINAL_SIZE_ERROR [...]"
// https://www.rfc-editor.org/rfc/rfc9000#section-4.5-5
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
tc := newTestConn(t, serverSide)
tc.handshake()
sid := newStreamID(clientSide, styp, 0)
const write1size = 4
tc.writeFrames(packetType1RTT, debugFrameStream{
id: sid,
off: 0,
data: make([]byte, 16),
fin: true,
})
tc.writeFrames(packetType1RTT, debugFrameStream{
id: sid,
off: 16,
data: []byte{0},
})
tc.wantFrame("received data past final size of stream",
packetType1RTT, debugFrameConnectionCloseTransport{
code: errFinalSize,
},
)
})
}
func TestStreamReceiveUnblocksReader(t *testing.T) {
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
tc := newTestConn(t, serverSide)
tc.handshake()
want := []byte{0, 1, 2, 3, 4, 5, 6, 7, 8, 9}
sid := newStreamID(clientSide, styp, 0)
// AcceptStream blocks until a STREAM frame is received.
accept := runAsync(tc, func(ctx context.Context) (*Stream, error) {
return tc.conn.AcceptStream(ctx)
})
const write1size = 4
tc.writeFrames(packetType1RTT, debugFrameStream{
id: sid,
off: 0,
data: want[:write1size],
})
s, err := accept.result()
if err != nil {
t.Fatalf("AcceptStream() = %v", err)
}
// ReadContext succeeds immediately, since we already have data.
got := make([]byte, len(want))
read := runAsync(tc, func(ctx context.Context) (int, error) {
return s.ReadContext(ctx, got)
})
if n, err := read.result(); n != write1size || err != nil {
t.Fatalf("ReadContext = %v, %v; want %v, nil", n, err, write1size)
}
// ReadContext blocks waiting for more data.
read = runAsync(tc, func(ctx context.Context) (int, error) {
return s.ReadContext(ctx, got[write1size:])
})
tc.writeFrames(packetType1RTT, debugFrameStream{
id: sid,
off: write1size,
data: want[write1size:],
fin: true,
})
if n, err := read.result(); n != len(want)-write1size || err != io.EOF {
t.Fatalf("ReadContext = %v, %v; want %v, io.EOF", n, err, len(want)-write1size)
}
if !bytes.Equal(got, want) {
t.Fatalf("read bytes %x, want %x", got, want)
}
})
}
// testStreamSendFrameInvalidState calls the test func with a stream ID for:
//
// - a remote bidirectional stream that the peer has not created
// - a remote unidirectional stream
//
// It then sends the returned frame (STREAM, STREAM_DATA_BLOCKED, etc.)
// to the conn and expects a STREAM_STATE_ERROR.
func testStreamSendFrameInvalidState(t *testing.T, f func(sid streamID) debugFrame) {
testSides(t, "stream_not_created", func(t *testing.T, side connSide) {
tc := newTestConn(t, side, permissiveTransportParameters)
tc.handshake()
tc.writeFrames(packetType1RTT, f(newStreamID(side, bidiStream, 0)))
tc.wantFrame("frame for local stream which has not been created",
packetType1RTT, debugFrameConnectionCloseTransport{
code: errStreamState,
})
})
testSides(t, "uni_stream", func(t *testing.T, side connSide) {
ctx := canceledContext()
tc := newTestConn(t, side, permissiveTransportParameters)
tc.handshake()
sid := newStreamID(side, uniStream, 0)
s, err := tc.conn.NewSendOnlyStream(ctx)
if err != nil {
t.Fatal(err)
}
s.Flush() // open the stream
tc.wantFrame("new stream is opened",
packetType1RTT, debugFrameStream{
id: sid,
data: []byte{},
})
tc.writeFrames(packetType1RTT, f(sid))
tc.wantFrame("send-oriented frame for send-only stream",
packetType1RTT, debugFrameConnectionCloseTransport{
code: errStreamState,
})
})
}
func TestStreamResetStreamInvalidState(t *testing.T) {
// "An endpoint that receives a RESET_STREAM frame for a send-only
// stream MUST terminate the connection with error STREAM_STATE_ERROR."
// https://www.rfc-editor.org/rfc/rfc9000#section-19.4-3
testStreamSendFrameInvalidState(t, func(sid streamID) debugFrame {
return debugFrameResetStream{
id: sid,
code: 0,
finalSize: 0,
}
})
}
func TestStreamStreamFrameInvalidState(t *testing.T) {
// "An endpoint MUST terminate the connection with error STREAM_STATE_ERROR
// if it receives a STREAM frame for a locally initiated stream
// that has not yet been created, or for a send-only stream."
// https://www.rfc-editor.org/rfc/rfc9000.html#section-19.8-3
testStreamSendFrameInvalidState(t, func(sid streamID) debugFrame {
return debugFrameStream{
id: sid,
}
})
}
func TestStreamDataBlockedInvalidState(t *testing.T) {
// "An endpoint MUST terminate the connection with error STREAM_STATE_ERROR
// if it receives a STREAM frame for a locally initiated stream
// that has not yet been created, or for a send-only stream."
// https://www.rfc-editor.org/rfc/rfc9000.html#section-19.8-3
testStreamSendFrameInvalidState(t, func(sid streamID) debugFrame {
return debugFrameStream{
id: sid,
}
})
}
// testStreamReceiveFrameInvalidState calls the test func with a stream ID for:
//
// - a remote bidirectional stream that the peer has not created
// - a local unidirectional stream
//
// It then sends the returned frame (MAX_STREAM_DATA, STOP_SENDING, etc.)
// to the conn and expects a STREAM_STATE_ERROR.
func testStreamReceiveFrameInvalidState(t *testing.T, f func(sid streamID) debugFrame) {
testSides(t, "stream_not_created", func(t *testing.T, side connSide) {
tc := newTestConn(t, side)
tc.handshake()
tc.writeFrames(packetType1RTT, f(newStreamID(side, bidiStream, 0)))
tc.wantFrame("frame for local stream which has not been created",
packetType1RTT, debugFrameConnectionCloseTransport{
code: errStreamState,
})
})
testSides(t, "uni_stream", func(t *testing.T, side connSide) {
tc := newTestConn(t, side)
tc.handshake()
tc.writeFrames(packetType1RTT, f(newStreamID(side.peer(), uniStream, 0)))
tc.wantFrame("receive-oriented frame for receive-only stream",
packetType1RTT, debugFrameConnectionCloseTransport{
code: errStreamState,
})
})
}
func TestStreamStopSendingInvalidState(t *testing.T) {
// "Receiving a STOP_SENDING frame for a locally initiated stream
// that has not yet been created MUST be treated as a connection error
// of type STREAM_STATE_ERROR. An endpoint that receives a STOP_SENDING
// frame for a receive-only stream MUST terminate the connection with
// error STREAM_STATE_ERROR."
// https://www.rfc-editor.org/rfc/rfc9000#section-19.5-2
testStreamReceiveFrameInvalidState(t, func(sid streamID) debugFrame {
return debugFrameStopSending{
id: sid,
}
})
}
func TestStreamMaxStreamDataInvalidState(t *testing.T) {
// "Receiving a MAX_STREAM_DATA frame for a locally initiated stream
// that has not yet been created MUST be treated as a connection error
// of type STREAM_STATE_ERROR. An endpoint that receives a MAX_STREAM_DATA
// frame for a receive-only stream MUST terminate the connection
// with error STREAM_STATE_ERROR."
// https://www.rfc-editor.org/rfc/rfc9000#section-19.10-2
testStreamReceiveFrameInvalidState(t, func(sid streamID) debugFrame {
return debugFrameMaxStreamData{
id: sid,
max: 1000,
}
})
}
func TestStreamOffsetTooLarge(t *testing.T) {
// "Receipt of a frame that exceeds [2^62-1] MUST be treated as a
// connection error of type FRAME_ENCODING_ERROR or FLOW_CONTROL_ERROR."
// https://www.rfc-editor.org/rfc/rfc9000.html#section-19.8-9
tc := newTestConn(t, serverSide)
tc.handshake()
tc.writeFrames(packetType1RTT,
debugFrameStream{
id: newStreamID(clientSide, bidiStream, 0),
off: 1<<62 - 1,
data: []byte{0},
})
got, _ := tc.readFrame()
want1 := debugFrameConnectionCloseTransport{code: errFrameEncoding}
want2 := debugFrameConnectionCloseTransport{code: errFlowControl}
if !frameEqual(got, want1) && !frameEqual(got, want2) {
t.Fatalf("STREAM offset exceeds 2^62-1\ngot: %v\nwant: %v\n or: %v", got, want1, want2)
}
}
func TestStreamReadFromWriteOnlyStream(t *testing.T) {
_, s := newTestConnAndLocalStream(t, serverSide, uniStream, permissiveTransportParameters)
buf := make([]byte, 10)
wantErr := "read from write-only stream"
if n, err := s.Read(buf); err == nil || !strings.Contains(err.Error(), wantErr) {
t.Errorf("s.Read() = %v, %v; want error %q", n, err, wantErr)
}
}
func TestStreamWriteToReadOnlyStream(t *testing.T) {
_, s := newTestConnAndRemoteStream(t, serverSide, uniStream)
buf := make([]byte, 10)
wantErr := "write to read-only stream"
if n, err := s.Write(buf); err == nil || !strings.Contains(err.Error(), wantErr) {
t.Errorf("s.Write() = %v, %v; want error %q", n, err, wantErr)
}
}
func TestStreamReadFromClosedStream(t *testing.T) {
tc, s := newTestConnAndRemoteStream(t, serverSide, bidiStream, permissiveTransportParameters)
s.CloseRead()
tc.wantFrame("CloseRead sends a STOP_SENDING frame",
packetType1RTT, debugFrameStopSending{
id: s.id,
})
wantErr := "read from closed stream"
if n, err := s.Read(make([]byte, 16)); err == nil || !strings.Contains(err.Error(), wantErr) {
t.Errorf("s.Read() = %v, %v; want error %q", n, err, wantErr)
}
// Data which shows up after STOP_SENDING is discarded.
tc.writeFrames(packetType1RTT, debugFrameStream{
id: s.id,
data: []byte{1, 2, 3},
fin: true,
})
if n, err := s.Read(make([]byte, 16)); err == nil || !strings.Contains(err.Error(), wantErr) {
t.Errorf("s.Read() = %v, %v; want error %q", n, err, wantErr)
}
}
func TestStreamCloseReadWithAllDataReceived(t *testing.T) {
tc, s := newTestConnAndRemoteStream(t, serverSide, bidiStream, permissiveTransportParameters)
tc.writeFrames(packetType1RTT, debugFrameStream{
id: s.id,
data: []byte{1, 2, 3},
fin: true,
})
s.CloseRead()
tc.wantIdle("CloseRead in Data Recvd state doesn't need to send STOP_SENDING")
// We had all the data for the stream, but CloseRead discarded it.
wantErr := "read from closed stream"
if n, err := s.Read(make([]byte, 16)); err == nil || !strings.Contains(err.Error(), wantErr) {
t.Errorf("s.Read() = %v, %v; want error %q", n, err, wantErr)
}
}
func TestStreamWriteToClosedStream(t *testing.T) {
tc, s := newTestConnAndLocalStream(t, serverSide, bidiStream, permissiveTransportParameters)
s.CloseWrite()
tc.wantFrame("stream is opened after being closed",
packetType1RTT, debugFrameStream{
id: s.id,
off: 0,
fin: true,
data: []byte{},
})
wantErr := "write to closed stream"
if n, err := s.Write([]byte{}); err == nil || !strings.Contains(err.Error(), wantErr) {
t.Errorf("s.Write() = %v, %v; want error %q", n, err, wantErr)
}
}
func TestStreamResetBlockedStream(t *testing.T) {
tc, s := newTestConnAndLocalStream(t, serverSide, bidiStream, permissiveTransportParameters,
func(c *Config) {
c.MaxStreamWriteBufferSize = 4
})
tc.ignoreFrame(frameTypeStreamDataBlocked)
writing := runAsync(tc, func(ctx context.Context) (int, error) {
return s.WriteContext(ctx, []byte{0, 1, 2, 3, 4, 5, 6, 7})
})
tc.wantFrame("stream writes data until write buffer fills",
packetType1RTT, debugFrameStream{
id: s.id,
off: 0,
data: []byte{0, 1, 2, 3},
})
s.Reset(42)
tc.wantFrame("stream is reset",
packetType1RTT, debugFrameResetStream{
id: s.id,
code: 42,
finalSize: 4,
})
wantErr := "write to reset stream"
if n, err := writing.result(); n != 4 || !strings.Contains(err.Error(), wantErr) {
t.Errorf("s.Write() interrupted by Reset: %v, %q; want 4, %q", n, err, wantErr)
}
tc.writeAckForAll()
tc.wantIdle("buffer space is available, but stream has been reset")
s.Reset(100)
tc.wantIdle("resetting stream a second time has no effect")
if n, err := s.Write([]byte{}); err == nil || !strings.Contains(err.Error(), wantErr) {
t.Errorf("s.Write() = %v, %v; want error %q", n, err, wantErr)
}
}
func TestStreamWriteMoreThanOnePacketOfData(t *testing.T) {
tc, s := newTestConnAndLocalStream(t, serverSide, uniStream, func(p *transportParameters) {
p.initialMaxStreamsUni = 1
p.initialMaxData = 1 << 20
p.initialMaxStreamDataUni = 1 << 20
})
want := make([]byte, 4096)
rand.Read(want) // doesn't need to be crypto/rand, but non-deprecated and harmless
w := runAsync(tc, func(ctx context.Context) (int, error) {
n, err := s.WriteContext(ctx, want)
s.Flush()
return n, err
})
got := make([]byte, 0, len(want))
for {
f, _ := tc.readFrame()
if f == nil {
break
}
sf, ok := f.(debugFrameStream)
if !ok {
t.Fatalf("unexpected frame: %v", sf)
}
if len(got) != int(sf.off) {
t.Fatalf("got frame: %v\nwant offset %v", sf, len(got))
}
got = append(got, sf.data...)
}
if n, err := w.result(); n != len(want) || err != nil {
t.Fatalf("s.WriteContext() = %v, %v; want %v, nil", n, err, len(want))
}
if !bytes.Equal(got, want) {
t.Fatalf("mismatch in received stream data")
}
}
func TestStreamCloseWaitsForAcks(t *testing.T) {
ctx := canceledContext()
tc, s := newTestConnAndLocalStream(t, serverSide, uniStream, permissiveTransportParameters)
data := make([]byte, 100)
s.WriteContext(ctx, data)
s.Flush()
tc.wantFrame("conn sends data for the stream",
packetType1RTT, debugFrameStream{
id: s.id,
data: data,
})
if err := s.CloseContext(ctx); err != context.Canceled {
t.Fatalf("s.Close() = %v, want context.Canceled (data not acked yet)", err)
}
tc.wantFrame("conn sends FIN for closed stream",
packetType1RTT, debugFrameStream{
id: s.id,
off: int64(len(data)),
fin: true,
data: []byte{},
})
closing := runAsync(tc, func(ctx context.Context) (struct{}, error) {
return struct{}{}, s.CloseContext(ctx)
})
if _, err := closing.result(); err != errNotDone {
t.Fatalf("s.CloseContext() = %v, want it to block waiting for acks", err)
}
tc.writeAckForAll()
if _, err := closing.result(); err != nil {
t.Fatalf("s.CloseContext() = %v, want nil (all data acked)", err)
}
}
func TestStreamCloseReadOnly(t *testing.T) {
tc, s := newTestConnAndRemoteStream(t, serverSide, uniStream, permissiveTransportParameters)
if err := s.CloseContext(canceledContext()); err != nil {
t.Errorf("s.CloseContext() = %v, want nil", err)
}
tc.wantFrame("closed stream sends STOP_SENDING",
packetType1RTT, debugFrameStopSending{
id: s.id,
})
}
func TestStreamCloseUnblocked(t *testing.T) {
for _, test := range []struct {
name string
unblock func(tc *testConn, s *Stream)
}{{
name: "data received",
unblock: func(tc *testConn, s *Stream) {
tc.writeAckForAll()
},
}, {
name: "stop sending received",
unblock: func(tc *testConn, s *Stream) {
tc.writeFrames(packetType1RTT, debugFrameStopSending{
id: s.id,
})
},
}, {
name: "stream reset",
unblock: func(tc *testConn, s *Stream) {
s.Reset(0)
tc.wait() // wait for test conn to process the Reset
},
}} {
t.Run(test.name, func(t *testing.T) {
ctx := canceledContext()
tc, s := newTestConnAndLocalStream(t, serverSide, uniStream, permissiveTransportParameters)
data := make([]byte, 100)
s.WriteContext(ctx, data)
s.Flush()
tc.wantFrame("conn sends data for the stream",
packetType1RTT, debugFrameStream{
id: s.id,
data: data,
})
if err := s.CloseContext(ctx); err != context.Canceled {
t.Fatalf("s.Close() = %v, want context.Canceled (data not acked yet)", err)
}
tc.wantFrame("conn sends FIN for closed stream",
packetType1RTT, debugFrameStream{
id: s.id,
off: int64(len(data)),
fin: true,
data: []byte{},
})
closing := runAsync(tc, func(ctx context.Context) (struct{}, error) {
return struct{}{}, s.CloseContext(ctx)
})
if _, err := closing.result(); err != errNotDone {
t.Fatalf("s.CloseContext() = %v, want it to block waiting for acks", err)
}
test.unblock(tc, s)
if _, err := closing.result(); err != nil {
t.Fatalf("s.CloseContext() = %v, want nil (all data acked)", err)
}
})
}
}
func TestStreamCloseWriteWhenBlockedByStreamFlowControl(t *testing.T) {
ctx := canceledContext()
tc, s := newTestConnAndLocalStream(t, serverSide, uniStream, permissiveTransportParameters,
func(p *transportParameters) {
//p.initialMaxData = 0
p.initialMaxStreamDataUni = 0
})
tc.ignoreFrame(frameTypeStreamDataBlocked)
if _, err := s.WriteContext(ctx, []byte{0, 1}); err != nil {
t.Fatalf("s.Write = %v", err)
}
s.CloseWrite()
tc.wantIdle("stream write is blocked by flow control")
tc.writeFrames(packetType1RTT, debugFrameMaxStreamData{
id: s.id,
max: 1,
})
tc.wantFrame("send data up to flow control limit",
packetType1RTT, debugFrameStream{
id: s.id,
data: []byte{0},
})
tc.wantIdle("stream write is again blocked by flow control")
tc.writeFrames(packetType1RTT, debugFrameMaxStreamData{
id: s.id,
max: 2,
})
tc.wantFrame("send remaining data and FIN",
packetType1RTT, debugFrameStream{
id: s.id,
off: 1,
data: []byte{1},
fin: true,
})
}
func TestStreamPeerResetsWithUnreadAndUnsentData(t *testing.T) {
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
ctx := canceledContext()
tc, s := newTestConnAndRemoteStream(t, serverSide, styp)
data := []byte{0, 1, 2, 3, 4, 5, 6, 7}
tc.writeFrames(packetType1RTT, debugFrameStream{
id: s.id,
data: data,
})
got := make([]byte, 4)
if n, err := s.ReadContext(ctx, got); n != len(got) || err != nil {
t.Fatalf("Read start of stream: got %v, %v; want %v, nil", n, err, len(got))
}
const sentCode = 42
tc.writeFrames(packetType1RTT, debugFrameResetStream{
id: s.id,
finalSize: 20,
code: sentCode,
})
wantErr := StreamErrorCode(sentCode)
if n, err := s.ReadContext(ctx, got); n != 0 || !errors.Is(err, wantErr) {
t.Fatalf("Read reset stream: got %v, %v; want 0, %v", n, err, wantErr)
}
})
}
func TestStreamPeerResetWakesBlockedRead(t *testing.T) {
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
tc, s := newTestConnAndRemoteStream(t, serverSide, styp)
reader := runAsync(tc, func(ctx context.Context) (int, error) {
got := make([]byte, 4)
return s.ReadContext(ctx, got)
})
const sentCode = 42
tc.writeFrames(packetType1RTT, debugFrameResetStream{
id: s.id,
finalSize: 20,
code: sentCode,
})
wantErr := StreamErrorCode(sentCode)
if n, err := reader.result(); n != 0 || !errors.Is(err, wantErr) {
t.Fatalf("Read reset stream: got %v, %v; want 0, %v", n, err, wantErr)
}
})
}
func TestStreamPeerResetFollowedByData(t *testing.T) {
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
tc, s := newTestConnAndRemoteStream(t, serverSide, styp)
tc.writeFrames(packetType1RTT, debugFrameResetStream{
id: s.id,
finalSize: 4,
code: 1,
})
tc.writeFrames(packetType1RTT, debugFrameStream{
id: s.id,
data: []byte{0, 1, 2, 3},
})
// Another reset with a different code, for good measure.
tc.writeFrames(packetType1RTT, debugFrameResetStream{
id: s.id,
finalSize: 4,
code: 2,
})
wantErr := StreamErrorCode(1)
if n, err := s.Read(make([]byte, 16)); n != 0 || !errors.Is(err, wantErr) {
t.Fatalf("Read from reset stream: got %v, %v; want 0, %v", n, err, wantErr)
}
})
}
func TestStreamResetInvalidCode(t *testing.T) {
tc, s := newTestConnAndLocalStream(t, serverSide, uniStream, permissiveTransportParameters)
s.Reset(1 << 62)
tc.wantFrame("reset with invalid code sends a RESET_STREAM anyway",
packetType1RTT, debugFrameResetStream{
id: s.id,
// The code we send here isn't specified,
// so this could really be any value.
code: (1 << 62) - 1,
})
}
func TestStreamResetReceiveOnly(t *testing.T) {
tc, s := newTestConnAndRemoteStream(t, serverSide, uniStream)
s.Reset(0)
tc.wantIdle("resetting a receive-only stream has no effect")
}
func TestStreamPeerStopSendingForActiveStream(t *testing.T) {
// "An endpoint that receives a STOP_SENDING frame MUST send a RESET_STREAM frame if
// the stream is in the "Ready" or "Send" state."
// https://www.rfc-editor.org/rfc/rfc9000#section-3.5-4
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
tc, s := newTestConnAndLocalStream(t, serverSide, styp, permissiveTransportParameters)
for i := 0; i < 4; i++ {
s.Write([]byte{byte(i)})
s.Flush()
tc.wantFrame("write sends a STREAM frame to peer",
packetType1RTT, debugFrameStream{
id: s.id,
off: int64(i),
data: []byte{byte(i)},
})
}
tc.writeFrames(packetType1RTT, debugFrameStopSending{
id: s.id,
code: 42,
})
tc.wantFrame("receiving STOP_SENDING causes stream reset",
packetType1RTT, debugFrameResetStream{
id: s.id,
code: 42,
finalSize: 4,
})
if n, err := s.Write([]byte{0}); err == nil {
t.Errorf("s.Write() after STOP_SENDING = %v, %v; want error", n, err)
}
// This ack will result in some of the previous frames being marked as lost.
tc.writeAckForLatest()
tc.wantIdle("lost STREAM frames for reset stream are not resent")
})
}
func TestStreamReceiveDataBlocked(t *testing.T) {
tc := newTestConn(t, serverSide, permissiveTransportParameters)
tc.handshake()
tc.ignoreFrame(frameTypeAck)
// We don't do anything with these frames,
// but should accept them if the peer sends one.
tc.writeFrames(packetType1RTT, debugFrameStreamDataBlocked{
id: newStreamID(clientSide, bidiStream, 0),
max: 100,
})
tc.writeFrames(packetType1RTT, debugFrameDataBlocked{
max: 100,
})
tc.wantIdle("no response to STREAM_DATA_BLOCKED and DATA_BLOCKED")
}
func TestStreamFlushExplicit(t *testing.T) {
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
tc, s := newTestConnAndLocalStream(t, clientSide, styp, permissiveTransportParameters)
want := []byte{0, 1, 2, 3}
n, err := s.Write(want)
if n != len(want) || err != nil {
t.Fatalf("s.Write() = %v, %v; want %v, nil", n, err, len(want))
}
tc.wantIdle("unflushed data is not sent")
s.Flush()
tc.wantFrame("data is sent after flush",
packetType1RTT, debugFrameStream{
id: s.id,
data: want,
})
})
}
func TestStreamFlushImplicitExact(t *testing.T) {
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
const writeBufferSize = 4
tc, s := newTestConnAndLocalStream(t, clientSide, styp,
permissiveTransportParameters,
func(c *Config) {
c.MaxStreamWriteBufferSize = writeBufferSize
})
want := []byte{0, 1, 2, 3, 4, 5, 6}
// This write doesn't quite fill the output buffer.
n, err := s.Write(want[:3])
if n != 3 || err != nil {
t.Fatalf("s.Write() = %v, %v; want %v, nil", n, err, len(want))
}
tc.wantIdle("unflushed data is not sent")
// This write fills the output buffer exactly.
n, err = s.Write(want[3:4])
if n != 1 || err != nil {
t.Fatalf("s.Write() = %v, %v; want %v, nil", n, err, len(want))
}
tc.wantFrame("data is sent after write buffer fills",
packetType1RTT, debugFrameStream{
id: s.id,
data: want[0:4],
})
})
}
func TestStreamFlushImplicitLargerThanBuffer(t *testing.T) {
testStreamTypes(t, "", func(t *testing.T, styp streamType) {
const writeBufferSize = 4
tc, s := newTestConnAndLocalStream(t, clientSide, styp,
permissiveTransportParameters,
func(c *Config) {
c.MaxStreamWriteBufferSize = writeBufferSize
})
want := []byte{0, 1, 2, 3, 4, 5, 6, 7, 8, 9}
w := runAsync(tc, func(ctx context.Context) (int, error) {
n, err := s.WriteContext(ctx, want)
return n, err
})
tc.wantFrame("data is sent after write buffer fills",
packetType1RTT, debugFrameStream{
id: s.id,
data: want[0:4],
})
tc.writeAckForAll()
tc.wantFrame("ack permits sending more data",
packetType1RTT, debugFrameStream{
id: s.id,
off: 4,
data: want[4:8],
})
tc.writeAckForAll()
tc.wantIdle("write buffer is not full")
if n, err := w.result(); n != len(want) || err != nil {
t.Fatalf("Write() = %v, %v; want %v, nil", n, err, len(want))
}
s.Flush()
tc.wantFrame("flush sends last buffer of data",
packetType1RTT, debugFrameStream{
id: s.id,
off: 8,
data: want[8:],
})
})
}
type streamSide string
const (
localStream = streamSide("local")
remoteStream = streamSide("remote")
)
func newTestConnAndStream(t *testing.T, side connSide, sside streamSide, styp streamType, opts ...any) (*testConn, *Stream) {
if sside == localStream {
return newTestConnAndLocalStream(t, side, styp, opts...)
} else {
return newTestConnAndRemoteStream(t, side, styp, opts...)
}
}
func newTestConnAndLocalStream(t *testing.T, side connSide, styp streamType, opts ...any) (*testConn, *Stream) {
t.Helper()
ctx := canceledContext()
tc := newTestConn(t, side, opts...)
tc.handshake()
tc.ignoreFrame(frameTypeAck)
s, err := tc.conn.newLocalStream(ctx, styp)
if err != nil {
t.Fatalf("conn.newLocalStream(%v) = %v", styp, err)
}
return tc, s
}
func newTestConnAndRemoteStream(t *testing.T, side connSide, styp streamType, opts ...any) (*testConn, *Stream) {
t.Helper()
ctx := canceledContext()
tc := newTestConn(t, side, opts...)
tc.handshake()
tc.ignoreFrame(frameTypeAck)
tc.writeFrames(packetType1RTT, debugFrameStream{
id: newStreamID(side.peer(), styp, 0),
})
s, err := tc.conn.AcceptStream(ctx)
if err != nil {
t.Fatalf("conn.AcceptStream() = %v", err)
}
return tc, s
}
// permissiveTransportParameters may be passed as an option to newTestConn.
func permissiveTransportParameters(p *transportParameters) {
p.initialMaxStreamsBidi = maxStreamsLimit
p.initialMaxStreamsUni = maxStreamsLimit
p.initialMaxData = maxVarint
p.initialMaxStreamDataBidiRemote = maxVarint
p.initialMaxStreamDataBidiLocal = maxVarint
p.initialMaxStreamDataUni = maxVarint
}
func makeTestData(n int) []byte {
b := make([]byte, n)
for i := 0; i < n; i++ {
b[i] = byte(i)
}
return b
}