internal/quic/stateless_reset_test.go - net - Git at Google

 // 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"
 	"crypto/tls"
 	"errors"
 	"net/netip"
 	"testing"
 	"time"
 )

 func TestStatelessResetClientSendsStatelessResetTokenTransportParameter(t *testing.T) {
 	// "[The stateless_reset_token] transport parameter MUST NOT be sent by a client [...]"
 	// https://www.rfc-editor.org/rfc/rfc9000#section-18.2-4.6.1
 	resetToken := testPeerStatelessResetToken(0)
 	tc := newTestConn(t, serverSide, func(p *transportParameters) {
 		p.statelessResetToken = resetToken[:]
 	})
 	tc.writeFrames(packetTypeInitial,
 		debugFrameCrypto{
 			data: tc.cryptoDataIn[tls.QUICEncryptionLevelInitial],
 		})
 	tc.wantFrame("client provided stateless_reset_token transport parameter",
 		packetTypeInitial, debugFrameConnectionCloseTransport{
 			code: errTransportParameter,
 		})
 }

 var testStatelessResetKey = func() (key [32]byte) {
 	if _, err := rand.Read(key[:]); err != nil {
 		panic(err)
 	}
 	return key
 }()

 func testStatelessResetToken(cid []byte) statelessResetToken {
 	var gen statelessResetTokenGenerator
 	gen.init(testStatelessResetKey)
 	return gen.tokenForConnID(cid)
 }

 func testLocalStatelessResetToken(seq int64) statelessResetToken {
 	return testStatelessResetToken(testLocalConnID(seq))
 }

 func newDatagramForReset(cid []byte, size int, addr netip.AddrPort) *datagram {
 	dgram := append([]byte{headerFormShort | fixedBit}, cid...)
 	for len(dgram) < size {
 		dgram = append(dgram, byte(len(dgram))) // semi-random junk
 	}
 	return &datagram{
 		b:    dgram,
 		addr: addr,
 	}
 }

 func TestStatelessResetSentSizes(t *testing.T) {
 	config := &Config{
 		TLSConfig:         newTestTLSConfig(serverSide),
 		StatelessResetKey: testStatelessResetKey,
 	}
 	addr := netip.MustParseAddr("127.0.0.1")
 	te := newTestEndpoint(t, config)
 	for i, test := range []struct {
 		reqSize  int
 		wantSize int
 	}{{
 		// Datagrams larger than 42 bytes result in a 42-byte stateless reset.
 		// This isn't specifically mandated by RFC 9000, but is implied.
 		// https://www.rfc-editor.org/rfc/rfc9000#section-10.3-11
 		reqSize:  1200,
 		wantSize: 42,
 	}, {
 		// "An endpoint that sends a Stateless Reset in response to a packet
 		// that is 43 bytes or shorter SHOULD send a Stateless Reset that is
 		// one byte shorter than the packet it responds to."
 		// https://www.rfc-editor.org/rfc/rfc9000#section-10.3-11
 		reqSize:  43,
 		wantSize: 42,
 	}, {
 		reqSize:  42,
 		wantSize: 41,
 	}, {
 		// We should send a stateless reset in response to the smallest possible
 		// valid datagram the peer can send us.
 		// The smallest packet is 1-RTT:
 		// header byte, conn id, packet num, payload, AEAD.
 		reqSize:  1 + connIDLen + 1 + 1 + 16,
 		wantSize: 1 + connIDLen + 1 + 1 + 16 - 1,
 	}, {
 		// The smallest possible stateless reset datagram is 21 bytes.
 		// Since our response must be smaller than the incoming datagram,
 		// we must not respond to a 21 byte or smaller packet.
 		reqSize:  21,
 		wantSize: 0,
 	}} {
 		cid := testLocalConnID(int64(i))
 		token := testStatelessResetToken(cid)
 		addrport := netip.AddrPortFrom(addr, uint16(8000+i))
 		te.write(newDatagramForReset(cid, test.reqSize, addrport))

 		got := te.read()
 		if len(got) != test.wantSize {
 			t.Errorf("got %v-byte response to %v-byte req, want %v",
 				len(got), test.reqSize, test.wantSize)
 		}
 		if len(got) == 0 {
 			continue
 		}
 		// "Endpoints MUST send Stateless Resets formatted as
 		// a packet with a short header."
 		// https://www.rfc-editor.org/rfc/rfc9000#section-10.3-15
 		if isLongHeader(got[0]) {
 			t.Errorf("response to %v-byte request is not a short-header packet\ngot: %x", test.reqSize, got)
 		}
 		if !bytes.HasSuffix(got, token[:]) {
 			t.Errorf("response to %v-byte request does not end in stateless reset token\ngot: %x\nwant suffix: %x", test.reqSize, got, token)
 		}
 	}
 }

 func TestStatelessResetSuccessfulNewConnectionID(t *testing.T) {
 	// "[...] Stateless Reset Token field values from [...] NEW_CONNECTION_ID frames [...]"
 	// https://www.rfc-editor.org/rfc/rfc9000#section-10.3.1-1
 	qr := &qlogRecord{}
 	tc := newTestConn(t, clientSide, qr.config)
 	tc.handshake()
 	tc.ignoreFrame(frameTypeAck)

 	// Retire connection ID 0.
 	tc.writeFrames(packetType1RTT,
 		debugFrameNewConnectionID{
 			retirePriorTo: 1,
 			seq:           2,
 			connID:        testPeerConnID(2),
 		})
 	tc.wantFrame("peer requested we retire conn id 0",
 		packetType1RTT, debugFrameRetireConnectionID{
 			seq: 0,
 		})

 	resetToken := testPeerStatelessResetToken(1) // provided during handshake
 	dgram := append(make([]byte, 100), resetToken[:]...)
 	tc.endpoint.write(&datagram{
 		b: dgram,
 	})

 	if err := tc.conn.Wait(canceledContext()); !errors.Is(err, errStatelessReset) {
 		t.Errorf("conn.Wait() = %v, want errStatelessReset", err)
 	}
 	tc.wantIdle("closed connection is idle in draining")
 	tc.advance(1 * time.Second) // long enough to exit the draining state
 	tc.wantIdle("closed connection is idle after draining")

 	qr.wantEvents(t, jsonEvent{
 		"name": "connectivity:connection_closed",
 		"data": map[string]any{
 			"trigger": "stateless_reset",
 		},
 	})
 }

 func TestStatelessResetSuccessfulTransportParameter(t *testing.T) {
 	// "[...] Stateless Reset Token field values from [...]
 	// the server's transport parameters [...]"
 	// https://www.rfc-editor.org/rfc/rfc9000#section-10.3.1-1
 	resetToken := testPeerStatelessResetToken(0)
 	tc := newTestConn(t, clientSide, func(p *transportParameters) {
 		p.statelessResetToken = resetToken[:]
 	})
 	tc.handshake()

 	dgram := append(make([]byte, 100), resetToken[:]...)
 	tc.endpoint.write(&datagram{
 		b: dgram,
 	})

 	if err := tc.conn.Wait(canceledContext()); !errors.Is(err, errStatelessReset) {
 		t.Errorf("conn.Wait() = %v, want errStatelessReset", err)
 	}
 	tc.wantIdle("closed connection is idle")
 }

 func TestStatelessResetSuccessfulPrefix(t *testing.T) {
 	for _, test := range []struct {
 		name   string
 		prefix []byte
 		size   int
 	}{{
 		name: "short header and fixed bit",
 		prefix: []byte{
 			headerFormShort | fixedBit,
 		},
 		size: 100,
 	}, {
 		// "[...] endpoints MUST treat [long header packets] ending in a
 		// valid stateless reset token as a Stateless Reset [...]"
 		// https://www.rfc-editor.org/rfc/rfc9000#section-10.3-15
 		name: "long header no fixed bit",
 		prefix: []byte{
 			headerFormLong,
 		},
 		size: 100,
 	}, {
 		// "[...] the comparison MUST be performed when the first packet
 		// in an incoming datagram [...] cannot be decrypted."
 		// https://www.rfc-editor.org/rfc/rfc9000#section-10.3.1-2
 		name: "short header valid DCID",
 		prefix: append([]byte{
 			headerFormShort | fixedBit,
 		}, testLocalConnID(0)...),
 		size: 100,
 	}, {
 		name: "handshake valid DCID",
 		prefix: append([]byte{
 			headerFormLong | fixedBit | longPacketTypeHandshake,
 		}, testLocalConnID(0)...),
 		size: 100,
 	}, {
 		name: "no fixed bit valid DCID",
 		prefix: append([]byte{
 			0,
 		}, testLocalConnID(0)...),
 		size: 100,
 	}} {
 		t.Run(test.name, func(t *testing.T) {
 			resetToken := testPeerStatelessResetToken(0)
 			tc := newTestConn(t, clientSide, func(p *transportParameters) {
 				p.statelessResetToken = resetToken[:]
 			})
 			tc.handshake()

 			dgram := test.prefix
 			for len(dgram) < test.size-len(resetToken) {
 				dgram = append(dgram, byte(len(dgram))) // semi-random junk
 			}
 			dgram = append(dgram, resetToken[:]...)
 			tc.endpoint.write(&datagram{
 				b: dgram,
 			})
 			if err := tc.conn.Wait(canceledContext()); !errors.Is(err, errStatelessReset) {
 				t.Errorf("conn.Wait() = %v, want errStatelessReset", err)
 			}
 		})
 	}
 }

 func TestStatelessResetRetiredConnID(t *testing.T) {
 	// "An endpoint MUST NOT check for any stateless reset tokens [...]
 	// for connection IDs that have been retired."
 	// https://www.rfc-editor.org/rfc/rfc9000#section-10.3.1-3
 	resetToken := testPeerStatelessResetToken(0)
 	tc := newTestConn(t, clientSide, func(p *transportParameters) {
 		p.statelessResetToken = resetToken[:]
 	})
 	tc.handshake()
 	tc.ignoreFrame(frameTypeAck)

 	// We retire connection ID 0.
 	tc.writeFrames(packetType1RTT,
 		debugFrameNewConnectionID{
 			seq:           2,
 			retirePriorTo: 1,
 			connID:        testPeerConnID(2),
 		})
 	tc.wantFrame("peer asked for conn id 0 to be retired",
 		packetType1RTT, debugFrameRetireConnectionID{
 			seq: 0,
 		})

 	// Receive a stateless reset for connection ID 0.
 	dgram := append(make([]byte, 100), resetToken[:]...)
 	tc.endpoint.write(&datagram{
 		b: dgram,
 	})

 	if err := tc.conn.Wait(canceledContext()); !errors.Is(err, context.Canceled) {
 		t.Errorf("conn.Wait() = %v, want connection to be alive", err)
 	}
 }
	// 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"
	"crypto/tls"
	"errors"
	"net/netip"
	"testing"
	"time"
	)

	func TestStatelessResetClientSendsStatelessResetTokenTransportParameter(t *testing.T) {
	// "[The stateless_reset_token] transport parameter MUST NOT be sent by a client [...]"
	// https://www.rfc-editor.org/rfc/rfc9000#section-18.2-4.6.1
	resetToken := testPeerStatelessResetToken(0)
	tc := newTestConn(t, serverSide, func(p *transportParameters) {
	p.statelessResetToken = resetToken[:]
	})
	tc.writeFrames(packetTypeInitial,
	debugFrameCrypto{
	data: tc.cryptoDataIn[tls.QUICEncryptionLevelInitial],
	})
	tc.wantFrame("client provided stateless_reset_token transport parameter",
	packetTypeInitial, debugFrameConnectionCloseTransport{
	code: errTransportParameter,
	})
	}

	var testStatelessResetKey = func() (key [32]byte) {
	if _, err := rand.Read(key[:]); err != nil {
	panic(err)
	}
	return key
	}()

	func testStatelessResetToken(cid []byte) statelessResetToken {
	var gen statelessResetTokenGenerator
	gen.init(testStatelessResetKey)
	return gen.tokenForConnID(cid)
	}

	func testLocalStatelessResetToken(seq int64) statelessResetToken {
	return testStatelessResetToken(testLocalConnID(seq))
	}

	func newDatagramForReset(cid []byte, size int, addr netip.AddrPort) *datagram {
	dgram := append([]byte{headerFormShort \| fixedBit}, cid...)
	for len(dgram) < size {
	dgram = append(dgram, byte(len(dgram))) // semi-random junk
	}
	return &datagram{
	b: dgram,
	addr: addr,
	}
	}

	func TestStatelessResetSentSizes(t *testing.T) {
	config := &Config{
	TLSConfig: newTestTLSConfig(serverSide),
	StatelessResetKey: testStatelessResetKey,
	}
	addr := netip.MustParseAddr("127.0.0.1")
	te := newTestEndpoint(t, config)
	for i, test := range []struct {
	reqSize int
	wantSize int
	}{{
	// Datagrams larger than 42 bytes result in a 42-byte stateless reset.
	// This isn't specifically mandated by RFC 9000, but is implied.
	// https://www.rfc-editor.org/rfc/rfc9000#section-10.3-11
	reqSize: 1200,
	wantSize: 42,
	}, {
	// "An endpoint that sends a Stateless Reset in response to a packet
	// that is 43 bytes or shorter SHOULD send a Stateless Reset that is
	// one byte shorter than the packet it responds to."
	// https://www.rfc-editor.org/rfc/rfc9000#section-10.3-11
	reqSize: 43,
	wantSize: 42,
	}, {
	reqSize: 42,
	wantSize: 41,
	}, {
	// We should send a stateless reset in response to the smallest possible
	// valid datagram the peer can send us.
	// The smallest packet is 1-RTT:
	// header byte, conn id, packet num, payload, AEAD.
	reqSize: 1 + connIDLen + 1 + 1 + 16,
	wantSize: 1 + connIDLen + 1 + 1 + 16 - 1,
	}, {
	// The smallest possible stateless reset datagram is 21 bytes.
	// Since our response must be smaller than the incoming datagram,
	// we must not respond to a 21 byte or smaller packet.
	reqSize: 21,
	wantSize: 0,
	}} {
	cid := testLocalConnID(int64(i))
	token := testStatelessResetToken(cid)
	addrport := netip.AddrPortFrom(addr, uint16(8000+i))
	te.write(newDatagramForReset(cid, test.reqSize, addrport))

	got := te.read()
	if len(got) != test.wantSize {
	t.Errorf("got %v-byte response to %v-byte req, want %v",
	len(got), test.reqSize, test.wantSize)
	}
	if len(got) == 0 {
	continue
	}
	// "Endpoints MUST send Stateless Resets formatted as
	// a packet with a short header."
	// https://www.rfc-editor.org/rfc/rfc9000#section-10.3-15
	if isLongHeader(got[0]) {
	t.Errorf("response to %v-byte request is not a short-header packet\ngot: %x", test.reqSize, got)
	}
	if !bytes.HasSuffix(got, token[:]) {
	t.Errorf("response to %v-byte request does not end in stateless reset token\ngot: %x\nwant suffix: %x", test.reqSize, got, token)
	}
	}
	}

	func TestStatelessResetSuccessfulNewConnectionID(t *testing.T) {
	// "[...] Stateless Reset Token field values from [...] NEW_CONNECTION_ID frames [...]"
	// https://www.rfc-editor.org/rfc/rfc9000#section-10.3.1-1
	qr := &qlogRecord{}
	tc := newTestConn(t, clientSide, qr.config)
	tc.handshake()
	tc.ignoreFrame(frameTypeAck)

	// Retire connection ID 0.
	tc.writeFrames(packetType1RTT,
	debugFrameNewConnectionID{
	retirePriorTo: 1,
	seq: 2,
	connID: testPeerConnID(2),
	})
	tc.wantFrame("peer requested we retire conn id 0",
	packetType1RTT, debugFrameRetireConnectionID{
	seq: 0,
	})

	resetToken := testPeerStatelessResetToken(1) // provided during handshake
	dgram := append(make([]byte, 100), resetToken[:]...)
	tc.endpoint.write(&datagram{
	b: dgram,
	})

	if err := tc.conn.Wait(canceledContext()); !errors.Is(err, errStatelessReset) {
	t.Errorf("conn.Wait() = %v, want errStatelessReset", err)
	}
	tc.wantIdle("closed connection is idle in draining")
	tc.advance(1 * time.Second) // long enough to exit the draining state
	tc.wantIdle("closed connection is idle after draining")

	qr.wantEvents(t, jsonEvent{
	"name": "connectivity:connection_closed",
	"data": map[string]any{
	"trigger": "stateless_reset",
	},
	})
	}

	func TestStatelessResetSuccessfulTransportParameter(t *testing.T) {
	// "[...] Stateless Reset Token field values from [...]
	// the server's transport parameters [...]"
	// https://www.rfc-editor.org/rfc/rfc9000#section-10.3.1-1
	resetToken := testPeerStatelessResetToken(0)
	tc := newTestConn(t, clientSide, func(p *transportParameters) {
	p.statelessResetToken = resetToken[:]
	})
	tc.handshake()

	dgram := append(make([]byte, 100), resetToken[:]...)
	tc.endpoint.write(&datagram{
	b: dgram,
	})

	if err := tc.conn.Wait(canceledContext()); !errors.Is(err, errStatelessReset) {
	t.Errorf("conn.Wait() = %v, want errStatelessReset", err)
	}
	tc.wantIdle("closed connection is idle")
	}

	func TestStatelessResetSuccessfulPrefix(t *testing.T) {
	for _, test := range []struct {
	name string
	prefix []byte
	size int
	}{{
	name: "short header and fixed bit",
	prefix: []byte{
	headerFormShort \| fixedBit,
	},
	size: 100,
	}, {
	// "[...] endpoints MUST treat [long header packets] ending in a
	// valid stateless reset token as a Stateless Reset [...]"
	// https://www.rfc-editor.org/rfc/rfc9000#section-10.3-15
	name: "long header no fixed bit",
	prefix: []byte{
	headerFormLong,
	},
	size: 100,
	}, {
	// "[...] the comparison MUST be performed when the first packet
	// in an incoming datagram [...] cannot be decrypted."
	// https://www.rfc-editor.org/rfc/rfc9000#section-10.3.1-2
	name: "short header valid DCID",
	prefix: append([]byte{
	headerFormShort \| fixedBit,
	}, testLocalConnID(0)...),
	size: 100,
	}, {
	name: "handshake valid DCID",
	prefix: append([]byte{
	headerFormLong \| fixedBit \| longPacketTypeHandshake,
	}, testLocalConnID(0)...),
	size: 100,
	}, {
	name: "no fixed bit valid DCID",
	prefix: append([]byte{
	0,
	}, testLocalConnID(0)...),
	size: 100,
	}} {
	t.Run(test.name, func(t *testing.T) {
	resetToken := testPeerStatelessResetToken(0)
	tc := newTestConn(t, clientSide, func(p *transportParameters) {
	p.statelessResetToken = resetToken[:]
	})
	tc.handshake()

	dgram := test.prefix
	for len(dgram) < test.size-len(resetToken) {
	dgram = append(dgram, byte(len(dgram))) // semi-random junk
	}
	dgram = append(dgram, resetToken[:]...)
	tc.endpoint.write(&datagram{
	b: dgram,
	})
	if err := tc.conn.Wait(canceledContext()); !errors.Is(err, errStatelessReset) {
	t.Errorf("conn.Wait() = %v, want errStatelessReset", err)
	}
	})
	}
	}

	func TestStatelessResetRetiredConnID(t *testing.T) {
	// "An endpoint MUST NOT check for any stateless reset tokens [...]
	// for connection IDs that have been retired."
	// https://www.rfc-editor.org/rfc/rfc9000#section-10.3.1-3
	resetToken := testPeerStatelessResetToken(0)
	tc := newTestConn(t, clientSide, func(p *transportParameters) {
	p.statelessResetToken = resetToken[:]
	})
	tc.handshake()
	tc.ignoreFrame(frameTypeAck)

	// We retire connection ID 0.
	tc.writeFrames(packetType1RTT,
	debugFrameNewConnectionID{
	seq: 2,
	retirePriorTo: 1,
	connID: testPeerConnID(2),
	})
	tc.wantFrame("peer asked for conn id 0 to be retired",
	packetType1RTT, debugFrameRetireConnectionID{
	seq: 0,
	})

	// Receive a stateless reset for connection ID 0.
	dgram := append(make([]byte, 100), resetToken[:]...)
	tc.endpoint.write(&datagram{
	b: dgram,
	})

	if err := tc.conn.Wait(canceledContext()); !errors.Is(err, context.Canceled) {
	t.Errorf("conn.Wait() = %v, want connection to be alive", err)
	}
	}