Google Git
Sign in
webrtc / src / 2ae3f7bb600a19efcea7e8626d48c7098383da49 / . / net / dcsctp / socket / dcsctp_socket_test.cc
blob: f38624d6061fe1cb78e6bf5c64cff8ca9f47f011 [file] [log] [blame]
/*
* Copyright (c) 2021 The WebRTC project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include "net/dcsctp/socket/dcsctp_socket.h"
#include <cstdint>
#include <deque>
#include <memory>
#include <string>
#include <utility>
#include <vector>
#include "absl/flags/flag.h"
#include "absl/memory/memory.h"
#include "absl/strings/string_view.h"
#include "absl/types/optional.h"
#include "api/array_view.h"
#include "net/dcsctp/common/handover_testing.h"
#include "net/dcsctp/packet/chunk/chunk.h"
#include "net/dcsctp/packet/chunk/cookie_echo_chunk.h"
#include "net/dcsctp/packet/chunk/data_chunk.h"
#include "net/dcsctp/packet/chunk/data_common.h"
#include "net/dcsctp/packet/chunk/error_chunk.h"
#include "net/dcsctp/packet/chunk/heartbeat_ack_chunk.h"
#include "net/dcsctp/packet/chunk/heartbeat_request_chunk.h"
#include "net/dcsctp/packet/chunk/idata_chunk.h"
#include "net/dcsctp/packet/chunk/init_chunk.h"
#include "net/dcsctp/packet/chunk/sack_chunk.h"
#include "net/dcsctp/packet/chunk/shutdown_chunk.h"
#include "net/dcsctp/packet/error_cause/error_cause.h"
#include "net/dcsctp/packet/error_cause/unrecognized_chunk_type_cause.h"
#include "net/dcsctp/packet/parameter/heartbeat_info_parameter.h"
#include "net/dcsctp/packet/parameter/outgoing_ssn_reset_request_parameter.h"
#include "net/dcsctp/packet/parameter/parameter.h"
#include "net/dcsctp/packet/sctp_packet.h"
#include "net/dcsctp/packet/tlv_trait.h"
#include "net/dcsctp/public/dcsctp_message.h"
#include "net/dcsctp/public/dcsctp_options.h"
#include "net/dcsctp/public/dcsctp_socket.h"
#include "net/dcsctp/public/text_pcap_packet_observer.h"
#include "net/dcsctp/public/types.h"
#include "net/dcsctp/rx/reassembly_queue.h"
#include "net/dcsctp/socket/mock_dcsctp_socket_callbacks.h"
#include "net/dcsctp/testing/testing_macros.h"
#include "rtc_base/gunit.h"
#include "test/gmock.h"
ABSL_FLAG(bool, dcsctp_capture_packets, false, "Print packet capture.");
namespace dcsctp {
namespace {
using ::testing::_;
using ::testing::AllOf;
using ::testing::ElementsAre;
using ::testing::HasSubstr;
using ::testing::IsEmpty;
using ::testing::SizeIs;
using ::testing::UnorderedElementsAre;
constexpr SendOptions kSendOptions;
constexpr size_t kLargeMessageSize = DcSctpOptions::kMaxSafeMTUSize * 20;
constexpr size_t kSmallMessageSize = 10;
constexpr int kMaxBurstPackets = 4;
MATCHER_P(HasDataChunkWithStreamId, stream_id, "") {
absl::optional<SctpPacket> packet = SctpPacket::Parse(arg);
if (!packet.has_value()) {
*result_listener << "data didn't parse as an SctpPacket";
return false;
}
if (packet->descriptors()[0].type != DataChunk::kType) {
*result_listener << "the first chunk in the packet is not a data chunk";
return false;
}
absl::optional<DataChunk> dc =
DataChunk::Parse(packet->descriptors()[0].data);
if (!dc.has_value()) {
*result_listener << "The first chunk didn't parse as a data chunk";
return false;
}
if (dc->stream_id() != stream_id) {
*result_listener << "the stream_id is " << *dc->stream_id();
return false;
}
return true;
}
MATCHER_P(HasDataChunkWithPPID, ppid, "") {
absl::optional<SctpPacket> packet = SctpPacket::Parse(arg);
if (!packet.has_value()) {
*result_listener << "data didn't parse as an SctpPacket";
return false;
}
if (packet->descriptors()[0].type != DataChunk::kType) {
*result_listener << "the first chunk in the packet is not a data chunk";
return false;
}
absl::optional<DataChunk> dc =
DataChunk::Parse(packet->descriptors()[0].data);
if (!dc.has_value()) {
*result_listener << "The first chunk didn't parse as a data chunk";
return false;
}
if (dc->ppid() != ppid) {
*result_listener << "the ppid is " << *dc->ppid();
return false;
}
return true;
}
MATCHER_P(HasDataChunkWithSsn, ssn, "") {
absl::optional<SctpPacket> packet = SctpPacket::Parse(arg);
if (!packet.has_value()) {
*result_listener << "data didn't parse as an SctpPacket";
return false;
}
if (packet->descriptors()[0].type != DataChunk::kType) {
*result_listener << "the first chunk in the packet is not a data chunk";
return false;
}
absl::optional<DataChunk> dc =
DataChunk::Parse(packet->descriptors()[0].data);
if (!dc.has_value()) {
*result_listener << "The first chunk didn't parse as a data chunk";
return false;
}
if (dc->ssn() != ssn) {
*result_listener << "the ssn is " << *dc->ssn();
return false;
}
return true;
}
MATCHER_P(HasDataChunkWithMid, mid, "") {
absl::optional<SctpPacket> packet = SctpPacket::Parse(arg);
if (!packet.has_value()) {
*result_listener << "data didn't parse as an SctpPacket";
return false;
}
if (packet->descriptors()[0].type != IDataChunk::kType) {
*result_listener << "the first chunk in the packet is not an i-data chunk";
return false;
}
absl::optional<IDataChunk> dc =
IDataChunk::Parse(packet->descriptors()[0].data);
if (!dc.has_value()) {
*result_listener << "The first chunk didn't parse as an i-data chunk";
return false;
}
if (dc->message_id() != mid) {
*result_listener << "the mid is " << *dc->message_id();
return false;
}
return true;
}
MATCHER_P(HasSackWithCumAckTsn, tsn, "") {
absl::optional<SctpPacket> packet = SctpPacket::Parse(arg);
if (!packet.has_value()) {
*result_listener << "data didn't parse as an SctpPacket";
return false;
}
if (packet->descriptors()[0].type != SackChunk::kType) {
*result_listener << "the first chunk in the packet is not a data chunk";
return false;
}
absl::optional<SackChunk> sc =
SackChunk::Parse(packet->descriptors()[0].data);
if (!sc.has_value()) {
*result_listener << "The first chunk didn't parse as a data chunk";
return false;
}
if (sc->cumulative_tsn_ack() != tsn) {
*result_listener << "the cum_ack_tsn is " << *sc->cumulative_tsn_ack();
return false;
}
return true;
}
MATCHER(HasSackWithNoGapAckBlocks, "") {
absl::optional<SctpPacket> packet = SctpPacket::Parse(arg);
if (!packet.has_value()) {
*result_listener << "data didn't parse as an SctpPacket";
return false;
}
if (packet->descriptors()[0].type != SackChunk::kType) {
*result_listener << "the first chunk in the packet is not a data chunk";
return false;
}
absl::optional<SackChunk> sc =
SackChunk::Parse(packet->descriptors()[0].data);
if (!sc.has_value()) {
*result_listener << "The first chunk didn't parse as a data chunk";
return false;
}
if (!sc->gap_ack_blocks().empty()) {
*result_listener << "there are gap ack blocks";
return false;
}
return true;
}
MATCHER_P(HasReconfigWithStreams, streams_matcher, "") {
absl::optional<SctpPacket> packet = SctpPacket::Parse(arg);
if (!packet.has_value()) {
*result_listener << "data didn't parse as an SctpPacket";
return false;
}
if (packet->descriptors()[0].type != ReConfigChunk::kType) {
*result_listener << "the first chunk in the packet is not a data chunk";
return false;
}
absl::optional<ReConfigChunk> reconfig =
ReConfigChunk::Parse(packet->descriptors()[0].data);
if (!reconfig.has_value()) {
*result_listener << "The first chunk didn't parse as a data chunk";
return false;
}
const Parameters& parameters = reconfig->parameters();
if (parameters.descriptors().size() != 1 ||
parameters.descriptors()[0].type !=
OutgoingSSNResetRequestParameter::kType) {
*result_listener << "Expected the reconfig chunk to have an outgoing SSN "
"reset request parameter";
return false;
}
absl::optional<OutgoingSSNResetRequestParameter> p =
OutgoingSSNResetRequestParameter::Parse(parameters.descriptors()[0].data);
testing::Matcher<rtc::ArrayView<const StreamID>> matcher = streams_matcher;
if (!matcher.MatchAndExplain(p->stream_ids(), result_listener)) {
return false;
}
return true;
}
MATCHER_P(HasReconfigWithResponse, result, "") {
absl::optional<SctpPacket> packet = SctpPacket::Parse(arg);
if (!packet.has_value()) {
*result_listener << "data didn't parse as an SctpPacket";
return false;
}
if (packet->descriptors()[0].type != ReConfigChunk::kType) {
*result_listener << "the first chunk in the packet is not a reconfig chunk";
return false;
}
absl::optional<ReConfigChunk> reconfig =
ReConfigChunk::Parse(packet->descriptors()[0].data);
if (!reconfig.has_value()) {
*result_listener << "The first chunk didn't parse as a reconfig chunk";
return false;
}
const Parameters& parameters = reconfig->parameters();
if (parameters.descriptors().size() != 1 ||
parameters.descriptors()[0].type !=
ReconfigurationResponseParameter::kType) {
*result_listener << "Expected the reconfig chunk to have a "
"ReconfigurationResponse Parameter";
return false;
}
absl::optional<ReconfigurationResponseParameter> p =
ReconfigurationResponseParameter::Parse(parameters.descriptors()[0].data);
if (p->result() != result) {
*result_listener << "ReconfigurationResponse Parameter doesn't contain the "
"expected result";
return false;
}
return true;
}
TSN AddTo(TSN tsn, int delta) {
return TSN(*tsn + delta);
}
DcSctpOptions FixupOptions(DcSctpOptions options = {}) {
DcSctpOptions fixup = options;
// To make the interval more predictable in tests.
fixup.heartbeat_interval_include_rtt = false;
fixup.max_burst = kMaxBurstPackets;
return fixup;
}
std::unique_ptr<PacketObserver> GetPacketObserver(absl::string_view name) {
if (absl::GetFlag(FLAGS_dcsctp_capture_packets)) {
return std::make_unique<TextPcapPacketObserver>(name);
}
return nullptr;
}
struct SocketUnderTest {
explicit SocketUnderTest(absl::string_view name,
const DcSctpOptions& opts = {})
: options(FixupOptions(opts)),
cb(name),
socket(name, cb, GetPacketObserver(name), options) {}
const DcSctpOptions options;
testing::NiceMock<MockDcSctpSocketCallbacks> cb;
DcSctpSocket socket;
};
void ExchangeMessages(SocketUnderTest& a, SocketUnderTest& z) {
bool delivered_packet = false;
do {
delivered_packet = false;
std::vector<uint8_t> packet_from_a = a.cb.ConsumeSentPacket();
if (!packet_from_a.empty()) {
delivered_packet = true;
z.socket.ReceivePacket(std::move(packet_from_a));
}
std::vector<uint8_t> packet_from_z = z.cb.ConsumeSentPacket();
if (!packet_from_z.empty()) {
delivered_packet = true;
a.socket.ReceivePacket(std::move(packet_from_z));
}
} while (delivered_packet);
}
void RunTimers(SocketUnderTest& s) {
for (;;) {
absl::optional<TimeoutID> timeout_id = s.cb.GetNextExpiredTimeout();
if (!timeout_id.has_value()) {
break;
}
s.socket.HandleTimeout(*timeout_id);
}
}
void AdvanceTime(SocketUnderTest& a, SocketUnderTest& z, DurationMs duration) {
a.cb.AdvanceTime(duration);
z.cb.AdvanceTime(duration);
RunTimers(a);
RunTimers(z);
}
// Calls Connect() on `sock_a_` and make the connection established.
void ConnectSockets(SocketUnderTest& a, SocketUnderTest& z) {
EXPECT_CALL(a.cb, OnConnected).Times(1);
EXPECT_CALL(z.cb, OnConnected).Times(1);
a.socket.Connect();
// Z reads INIT, INIT_ACK, COOKIE_ECHO, COOKIE_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
EXPECT_EQ(a.socket.state(), SocketState::kConnected);
EXPECT_EQ(z.socket.state(), SocketState::kConnected);
}
std::unique_ptr<SocketUnderTest> HandoverSocket(
std::unique_ptr<SocketUnderTest> sut) {
EXPECT_EQ(sut->socket.GetHandoverReadiness(), HandoverReadinessStatus());
bool is_closed = sut->socket.state() == SocketState::kClosed;
if (!is_closed) {
EXPECT_CALL(sut->cb, OnClosed).Times(1);
}
absl::optional<DcSctpSocketHandoverState> handover_state =
sut->socket.GetHandoverStateAndClose();
EXPECT_TRUE(handover_state.has_value());
g_handover_state_transformer_for_test(&*handover_state);
auto handover_socket = std::make_unique<SocketUnderTest>("H", sut->options);
if (!is_closed) {
EXPECT_CALL(handover_socket->cb, OnConnected).Times(1);
}
handover_socket->socket.RestoreFromState(*handover_state);
return handover_socket;
}
std::vector<uint32_t> GetReceivedMessagePpids(SocketUnderTest& z) {
std::vector<uint32_t> ppids;
for (;;) {
absl::optional<DcSctpMessage> msg = z.cb.ConsumeReceivedMessage();
if (!msg.has_value()) {
break;
}
ppids.push_back(*msg->ppid());
}
return ppids;
}
// Test parameter that controls whether to perform handovers during the test. A
// test can have multiple points where it conditionally hands over socket Z.
// Either socket Z will be handed over at all those points or handed over never.
enum class HandoverMode {
kNoHandover,
kPerformHandovers,
};
class DcSctpSocketParametrizedTest
: public ::testing::Test,
public ::testing::WithParamInterface<HandoverMode> {
protected:
// Trigger handover for `sut` depending on the current test param.
std::unique_ptr<SocketUnderTest> MaybeHandoverSocket(
std::unique_ptr<SocketUnderTest> sut) {
if (GetParam() == HandoverMode::kPerformHandovers) {
return HandoverSocket(std::move(sut));
}
return sut;
}
// Trigger handover for socket Z depending on the current test param.
// Then checks message passing to verify the handed over socket is functional.
void MaybeHandoverSocketAndSendMessage(SocketUnderTest& a,
std::unique_ptr<SocketUnderTest> z) {
if (GetParam() == HandoverMode::kPerformHandovers) {
z = HandoverSocket(std::move(z));
}
ExchangeMessages(a, *z);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2}), kSendOptions);
ExchangeMessages(a, *z);
absl::optional<DcSctpMessage> msg = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg.has_value());
EXPECT_EQ(msg->stream_id(), StreamID(1));
}
};
INSTANTIATE_TEST_SUITE_P(Handovers,
DcSctpSocketParametrizedTest,
testing::Values(HandoverMode::kNoHandover,
HandoverMode::kPerformHandovers),
[](const auto& test_info) {
return test_info.param ==
HandoverMode::kPerformHandovers
? "WithHandovers"
: "NoHandover";
});
TEST(DcSctpSocketTest, EstablishConnection) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
EXPECT_CALL(a.cb, OnConnected).Times(1);
EXPECT_CALL(z.cb, OnConnected).Times(1);
EXPECT_CALL(a.cb, OnConnectionRestarted).Times(0);
EXPECT_CALL(z.cb, OnConnectionRestarted).Times(0);
a.socket.Connect();
// Z reads INIT, produces INIT_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads INIT_ACK, produces COOKIE_ECHO
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
// Z reads COOKIE_ECHO, produces COOKIE_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads COOKIE_ACK.
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
EXPECT_EQ(a.socket.state(), SocketState::kConnected);
EXPECT_EQ(z.socket.state(), SocketState::kConnected);
}
TEST(DcSctpSocketTest, EstablishConnectionWithSetupCollision) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
EXPECT_CALL(a.cb, OnConnected).Times(1);
EXPECT_CALL(z.cb, OnConnected).Times(1);
EXPECT_CALL(a.cb, OnConnectionRestarted).Times(0);
EXPECT_CALL(z.cb, OnConnectionRestarted).Times(0);
a.socket.Connect();
z.socket.Connect();
ExchangeMessages(a, z);
EXPECT_EQ(a.socket.state(), SocketState::kConnected);
EXPECT_EQ(z.socket.state(), SocketState::kConnected);
}
TEST(DcSctpSocketTest, ShuttingDownWhileEstablishingConnection) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
EXPECT_CALL(a.cb, OnConnected).Times(0);
EXPECT_CALL(z.cb, OnConnected).Times(1);
a.socket.Connect();
// Z reads INIT, produces INIT_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads INIT_ACK, produces COOKIE_ECHO
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
// Z reads COOKIE_ECHO, produces COOKIE_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// Drop COOKIE_ACK, just to more easily verify shutdown protocol.
z.cb.ConsumeSentPacket();
// As Socket A has received INIT_ACK, it has a TCB and is connected, while
// Socket Z needs to receive COOKIE_ECHO to get there. Socket A still has
// timers running at this point.
EXPECT_EQ(a.socket.state(), SocketState::kConnecting);
EXPECT_EQ(z.socket.state(), SocketState::kConnected);
// Socket A is now shut down, which should make it stop those timers.
a.socket.Shutdown();
EXPECT_CALL(a.cb, OnClosed).Times(1);
EXPECT_CALL(z.cb, OnClosed).Times(1);
// Z reads SHUTDOWN, produces SHUTDOWN_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads SHUTDOWN_ACK, produces SHUTDOWN_COMPLETE
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
// Z reads SHUTDOWN_COMPLETE.
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
EXPECT_TRUE(a.cb.ConsumeSentPacket().empty());
EXPECT_TRUE(z.cb.ConsumeSentPacket().empty());
EXPECT_EQ(a.socket.state(), SocketState::kClosed);
EXPECT_EQ(z.socket.state(), SocketState::kClosed);
}
TEST(DcSctpSocketTest, EstablishSimultaneousConnection) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
EXPECT_CALL(a.cb, OnConnected).Times(1);
EXPECT_CALL(z.cb, OnConnected).Times(1);
EXPECT_CALL(a.cb, OnConnectionRestarted).Times(0);
EXPECT_CALL(z.cb, OnConnectionRestarted).Times(0);
a.socket.Connect();
// INIT isn't received by Z, as it wasn't ready yet.
a.cb.ConsumeSentPacket();
z.socket.Connect();
// A reads INIT, produces INIT_ACK
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
// Z reads INIT_ACK, sends COOKIE_ECHO
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads COOKIE_ECHO - establishes connection.
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
EXPECT_EQ(a.socket.state(), SocketState::kConnected);
// Proceed with the remaining packets.
ExchangeMessages(a, z);
EXPECT_EQ(a.socket.state(), SocketState::kConnected);
EXPECT_EQ(z.socket.state(), SocketState::kConnected);
}
TEST(DcSctpSocketTest, EstablishConnectionLostCookieAck) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
EXPECT_CALL(a.cb, OnConnected).Times(1);
EXPECT_CALL(z.cb, OnConnected).Times(1);
EXPECT_CALL(a.cb, OnConnectionRestarted).Times(0);
EXPECT_CALL(z.cb, OnConnectionRestarted).Times(0);
a.socket.Connect();
// Z reads INIT, produces INIT_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads INIT_ACK, produces COOKIE_ECHO
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
// Z reads COOKIE_ECHO, produces COOKIE_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// COOKIE_ACK is lost.
z.cb.ConsumeSentPacket();
EXPECT_EQ(a.socket.state(), SocketState::kConnecting);
EXPECT_EQ(z.socket.state(), SocketState::kConnected);
// This will make A re-send the COOKIE_ECHO
AdvanceTime(a, z, DurationMs(a.options.t1_cookie_timeout));
// Z reads COOKIE_ECHO, produces COOKIE_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads COOKIE_ACK.
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
EXPECT_EQ(a.socket.state(), SocketState::kConnected);
EXPECT_EQ(z.socket.state(), SocketState::kConnected);
}
TEST(DcSctpSocketTest, ResendInitAndEstablishConnection) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
a.socket.Connect();
// INIT is never received by Z.
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket init_packet,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
EXPECT_EQ(init_packet.descriptors()[0].type, InitChunk::kType);
AdvanceTime(a, z, a.options.t1_init_timeout);
// Z reads INIT, produces INIT_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads INIT_ACK, produces COOKIE_ECHO
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
// Z reads COOKIE_ECHO, produces COOKIE_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads COOKIE_ACK.
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
EXPECT_EQ(a.socket.state(), SocketState::kConnected);
EXPECT_EQ(z.socket.state(), SocketState::kConnected);
}
TEST(DcSctpSocketTest, ResendingInitTooManyTimesAborts) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
a.socket.Connect();
// INIT is never received by Z.
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket init_packet,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
EXPECT_EQ(init_packet.descriptors()[0].type, InitChunk::kType);
for (int i = 0; i < *a.options.max_init_retransmits; ++i) {
AdvanceTime(a, z, a.options.t1_init_timeout * (1 << i));
// INIT is resent
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket resent_init_packet,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
EXPECT_EQ(resent_init_packet.descriptors()[0].type, InitChunk::kType);
}
// Another timeout, after the max init retransmits.
EXPECT_CALL(a.cb, OnAborted).Times(1);
AdvanceTime(
a, z, a.options.t1_init_timeout * (1 << *a.options.max_init_retransmits));
EXPECT_EQ(a.socket.state(), SocketState::kClosed);
}
TEST(DcSctpSocketTest, ResendCookieEchoAndEstablishConnection) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
a.socket.Connect();
// Z reads INIT, produces INIT_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads INIT_ACK, produces COOKIE_ECHO
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
// COOKIE_ECHO is never received by Z.
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket init_packet,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
EXPECT_EQ(init_packet.descriptors()[0].type, CookieEchoChunk::kType);
AdvanceTime(a, z, a.options.t1_init_timeout);
// Z reads COOKIE_ECHO, produces COOKIE_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads COOKIE_ACK.
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
EXPECT_EQ(a.socket.state(), SocketState::kConnected);
EXPECT_EQ(z.socket.state(), SocketState::kConnected);
}
TEST(DcSctpSocketTest, ResendingCookieEchoTooManyTimesAborts) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
a.socket.Connect();
// Z reads INIT, produces INIT_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads INIT_ACK, produces COOKIE_ECHO
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
// COOKIE_ECHO is never received by Z.
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket init_packet,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
EXPECT_EQ(init_packet.descriptors()[0].type, CookieEchoChunk::kType);
for (int i = 0; i < *a.options.max_init_retransmits; ++i) {
AdvanceTime(a, z, a.options.t1_cookie_timeout * (1 << i));
// COOKIE_ECHO is resent
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket resent_init_packet,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
EXPECT_EQ(resent_init_packet.descriptors()[0].type, CookieEchoChunk::kType);
}
// Another timeout, after the max init retransmits.
EXPECT_CALL(a.cb, OnAborted).Times(1);
AdvanceTime(
a, z,
a.options.t1_cookie_timeout * (1 << *a.options.max_init_retransmits));
EXPECT_EQ(a.socket.state(), SocketState::kClosed);
}
TEST(DcSctpSocketTest, DoesntSendMorePacketsUntilCookieAckHasBeenReceived) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53),
std::vector<uint8_t>(kLargeMessageSize)),
kSendOptions);
a.socket.Connect();
// Z reads INIT, produces INIT_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads INIT_ACK, produces COOKIE_ECHO
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
// COOKIE_ECHO is never received by Z.
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket cookie_echo_packet1,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
EXPECT_THAT(cookie_echo_packet1.descriptors(), SizeIs(2));
EXPECT_EQ(cookie_echo_packet1.descriptors()[0].type, CookieEchoChunk::kType);
EXPECT_EQ(cookie_echo_packet1.descriptors()[1].type, DataChunk::kType);
EXPECT_THAT(a.cb.ConsumeSentPacket(), IsEmpty());
// There are DATA chunks in the sent packet (that was lost), which means that
// the T3-RTX timer is running, but as the socket is in kCookieEcho state, it
// will be T1-COOKIE that drives retransmissions, so when the T3-RTX expires,
// nothing should be retransmitted.
ASSERT_TRUE(a.options.rto_initial < a.options.t1_cookie_timeout);
AdvanceTime(a, z, a.options.rto_initial);
EXPECT_THAT(a.cb.ConsumeSentPacket(), IsEmpty());
// When T1-COOKIE expires, both the COOKIE-ECHO and DATA should be present.
AdvanceTime(a, z, a.options.t1_cookie_timeout - a.options.rto_initial);
// And this COOKIE-ECHO and DATA is also lost - never received by Z.
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket cookie_echo_packet2,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
EXPECT_THAT(cookie_echo_packet2.descriptors(), SizeIs(2));
EXPECT_EQ(cookie_echo_packet2.descriptors()[0].type, CookieEchoChunk::kType);
EXPECT_EQ(cookie_echo_packet2.descriptors()[1].type, DataChunk::kType);
EXPECT_THAT(a.cb.ConsumeSentPacket(), IsEmpty());
// COOKIE_ECHO has exponential backoff.
AdvanceTime(a, z, a.options.t1_cookie_timeout * 2);
// Z reads COOKIE_ECHO, produces COOKIE_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads COOKIE_ACK.
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
EXPECT_EQ(a.socket.state(), SocketState::kConnected);
EXPECT_EQ(z.socket.state(), SocketState::kConnected);
ExchangeMessages(a, z);
EXPECT_THAT(z.cb.ConsumeReceivedMessage()->payload(),
SizeIs(kLargeMessageSize));
}
TEST_P(DcSctpSocketParametrizedTest, ShutdownConnection) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
RTC_LOG(LS_INFO) << "Shutting down";
EXPECT_CALL(z->cb, OnClosed).Times(1);
a.socket.Shutdown();
// Z reads SHUTDOWN, produces SHUTDOWN_ACK
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
// A reads SHUTDOWN_ACK, produces SHUTDOWN_COMPLETE
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
// Z reads SHUTDOWN_COMPLETE.
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
EXPECT_EQ(a.socket.state(), SocketState::kClosed);
EXPECT_EQ(z->socket.state(), SocketState::kClosed);
z = MaybeHandoverSocket(std::move(z));
EXPECT_EQ(z->socket.state(), SocketState::kClosed);
}
TEST(DcSctpSocketTest, ShutdownTimerExpiresTooManyTimeClosesConnection) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
ConnectSockets(a, z);
a.socket.Shutdown();
// Drop first SHUTDOWN packet.
a.cb.ConsumeSentPacket();
EXPECT_EQ(a.socket.state(), SocketState::kShuttingDown);
for (int i = 0; i < *a.options.max_retransmissions; ++i) {
AdvanceTime(a, z, DurationMs(a.options.rto_initial * (1 << i)));
// Dropping every shutdown chunk.
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket packet,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
EXPECT_EQ(packet.descriptors()[0].type, ShutdownChunk::kType);
EXPECT_TRUE(a.cb.ConsumeSentPacket().empty());
}
// The last expiry, makes it abort the connection.
EXPECT_CALL(a.cb, OnAborted).Times(1);
AdvanceTime(a, z,
a.options.rto_initial * (1 << *a.options.max_retransmissions));
EXPECT_EQ(a.socket.state(), SocketState::kClosed);
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket packet,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
EXPECT_EQ(packet.descriptors()[0].type, AbortChunk::kType);
EXPECT_TRUE(a.cb.ConsumeSentPacket().empty());
}
TEST(DcSctpSocketTest, EstablishConnectionWhileSendingData) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
a.socket.Connect();
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2}), kSendOptions);
// Z reads INIT, produces INIT_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// // A reads INIT_ACK, produces COOKIE_ECHO
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
// // Z reads COOKIE_ECHO, produces COOKIE_ACK
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// // A reads COOKIE_ACK.
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
EXPECT_EQ(a.socket.state(), SocketState::kConnected);
EXPECT_EQ(z.socket.state(), SocketState::kConnected);
absl::optional<DcSctpMessage> msg = z.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg.has_value());
EXPECT_EQ(msg->stream_id(), StreamID(1));
}
TEST(DcSctpSocketTest, SendMessageAfterEstablished) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
ConnectSockets(a, z);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2}), kSendOptions);
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
absl::optional<DcSctpMessage> msg = z.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg.has_value());
EXPECT_EQ(msg->stream_id(), StreamID(1));
}
TEST_P(DcSctpSocketParametrizedTest, TimeoutResendsPacket) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2}), kSendOptions);
a.cb.ConsumeSentPacket();
RTC_LOG(LS_INFO) << "Advancing time";
AdvanceTime(a, *z, a.options.rto_initial);
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
absl::optional<DcSctpMessage> msg = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg.has_value());
EXPECT_EQ(msg->stream_id(), StreamID(1));
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest, SendALotOfBytesMissedSecondPacket) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
std::vector<uint8_t> payload(kLargeMessageSize);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), payload), kSendOptions);
// First DATA
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
// Second DATA (lost)
a.cb.ConsumeSentPacket();
// Retransmit and handle the rest
ExchangeMessages(a, *z);
absl::optional<DcSctpMessage> msg = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg.has_value());
EXPECT_EQ(msg->stream_id(), StreamID(1));
EXPECT_THAT(msg->payload(), testing::ElementsAreArray(payload));
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest, SendingHeartbeatAnswersWithAck) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
// Inject a HEARTBEAT chunk
SctpPacket::Builder b(a.socket.verification_tag(), DcSctpOptions());
uint8_t info[] = {1, 2, 3, 4};
Parameters::Builder params_builder;
params_builder.Add(HeartbeatInfoParameter(info));
b.Add(HeartbeatRequestChunk(params_builder.Build()));
a.socket.ReceivePacket(b.Build());
// HEARTBEAT_ACK is sent as a reply. Capture it.
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket ack_packet,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
ASSERT_THAT(ack_packet.descriptors(), SizeIs(1));
ASSERT_HAS_VALUE_AND_ASSIGN(
HeartbeatAckChunk ack,
HeartbeatAckChunk::Parse(ack_packet.descriptors()[0].data));
ASSERT_HAS_VALUE_AND_ASSIGN(HeartbeatInfoParameter info_param, ack.info());
EXPECT_THAT(info_param.info(), ElementsAre(1, 2, 3, 4));
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest, ExpectHeartbeatToBeSent) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
EXPECT_THAT(a.cb.ConsumeSentPacket(), IsEmpty());
AdvanceTime(a, *z, a.options.heartbeat_interval);
std::vector<uint8_t> hb_packet_raw = a.cb.ConsumeSentPacket();
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket hb_packet,
SctpPacket::Parse(hb_packet_raw));
ASSERT_THAT(hb_packet.descriptors(), SizeIs(1));
ASSERT_HAS_VALUE_AND_ASSIGN(
HeartbeatRequestChunk hb,
HeartbeatRequestChunk::Parse(hb_packet.descriptors()[0].data));
ASSERT_HAS_VALUE_AND_ASSIGN(HeartbeatInfoParameter info_param, hb.info());
// The info is a single 64-bit number.
EXPECT_THAT(hb.info()->info(), SizeIs(8));
// Feed it to Sock-z and expect a HEARTBEAT_ACK that will be propagated back.
z->socket.ReceivePacket(hb_packet_raw);
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest,
CloseConnectionAfterTooManyLostHeartbeats) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
EXPECT_CALL(z->cb, OnClosed).Times(1);
EXPECT_THAT(a.cb.ConsumeSentPacket(), testing::IsEmpty());
// Force-close socket Z so that it doesn't interfere from now on.
z->socket.Close();
DurationMs time_to_next_hearbeat = a.options.heartbeat_interval;
for (int i = 0; i < *a.options.max_retransmissions; ++i) {
RTC_LOG(LS_INFO) << "Letting HEARTBEAT interval timer expire - sending...";
AdvanceTime(a, *z, time_to_next_hearbeat);
// Dropping every heartbeat.
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket hb_packet,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
EXPECT_EQ(hb_packet.descriptors()[0].type, HeartbeatRequestChunk::kType);
RTC_LOG(LS_INFO) << "Letting the heartbeat expire.";
AdvanceTime(a, *z, DurationMs(1000));
time_to_next_hearbeat = a.options.heartbeat_interval - DurationMs(1000);
}
RTC_LOG(LS_INFO) << "Letting HEARTBEAT interval timer expire - sending...";
AdvanceTime(a, *z, time_to_next_hearbeat);
// Last heartbeat
EXPECT_THAT(a.cb.ConsumeSentPacket(), Not(IsEmpty()));
EXPECT_CALL(a.cb, OnAborted).Times(1);
// Should suffice as exceeding RTO
AdvanceTime(a, *z, DurationMs(1000));
z = MaybeHandoverSocket(std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest, RecoversAfterASuccessfulAck) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
EXPECT_THAT(a.cb.ConsumeSentPacket(), testing::IsEmpty());
EXPECT_CALL(z->cb, OnClosed).Times(1);
// Force-close socket Z so that it doesn't interfere from now on.
z->socket.Close();
DurationMs time_to_next_hearbeat = a.options.heartbeat_interval;
for (int i = 0; i < *a.options.max_retransmissions; ++i) {
AdvanceTime(a, *z, time_to_next_hearbeat);
// Dropping every heartbeat.
a.cb.ConsumeSentPacket();
RTC_LOG(LS_INFO) << "Letting the heartbeat expire.";
AdvanceTime(a, *z, DurationMs(1000));
time_to_next_hearbeat = a.options.heartbeat_interval - DurationMs(1000);
}
RTC_LOG(LS_INFO) << "Getting the last heartbeat - and acking it";
AdvanceTime(a, *z, time_to_next_hearbeat);
std::vector<uint8_t> hb_packet_raw = a.cb.ConsumeSentPacket();
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket hb_packet,
SctpPacket::Parse(hb_packet_raw));
ASSERT_THAT(hb_packet.descriptors(), SizeIs(1));
ASSERT_HAS_VALUE_AND_ASSIGN(
HeartbeatRequestChunk hb,
HeartbeatRequestChunk::Parse(hb_packet.descriptors()[0].data));
SctpPacket::Builder b(a.socket.verification_tag(), a.options);
b.Add(HeartbeatAckChunk(std::move(hb).extract_parameters()));
a.socket.ReceivePacket(b.Build());
// Should suffice as exceeding RTO - which will not fire.
EXPECT_CALL(a.cb, OnAborted).Times(0);
AdvanceTime(a, *z, DurationMs(1000));
EXPECT_THAT(a.cb.ConsumeSentPacket(), IsEmpty());
// Verify that we get new heartbeats again.
RTC_LOG(LS_INFO) << "Expecting a new heartbeat";
AdvanceTime(a, *z, time_to_next_hearbeat);
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket another_packet,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
EXPECT_EQ(another_packet.descriptors()[0].type, HeartbeatRequestChunk::kType);
}
TEST_P(DcSctpSocketParametrizedTest, ResetStream) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2}), {});
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
absl::optional<DcSctpMessage> msg = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg.has_value());
EXPECT_EQ(msg->stream_id(), StreamID(1));
// Handle SACK
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
// Reset the outgoing stream. This will directly send a RE-CONFIG.
a.socket.ResetStreams(std::vector<StreamID>({StreamID(1)}));
// Receiving the packet will trigger a callback, indicating that A has
// reset its stream. It will also send a RE-CONFIG with a response.
EXPECT_CALL(z->cb, OnIncomingStreamsReset).Times(1);
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
// Receiving a response will trigger a callback. Streams are now reset.
EXPECT_CALL(a.cb, OnStreamsResetPerformed).Times(1);
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest, ResetStreamWillMakeChunksStartAtZeroSsn) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
std::vector<uint8_t> payload(a.options.mtu - 100);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), payload), {});
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), payload), {});
auto packet1 = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet1, HasDataChunkWithSsn(SSN(0)));
z->socket.ReceivePacket(packet1);
auto packet2 = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet2, HasDataChunkWithSsn(SSN(1)));
z->socket.ReceivePacket(packet2);
// Handle SACK
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
absl::optional<DcSctpMessage> msg1 = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg1.has_value());
EXPECT_EQ(msg1->stream_id(), StreamID(1));
absl::optional<DcSctpMessage> msg2 = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg2.has_value());
EXPECT_EQ(msg2->stream_id(), StreamID(1));
// Reset the outgoing stream. This will directly send a RE-CONFIG.
a.socket.ResetStreams(std::vector<StreamID>({StreamID(1)}));
// RE-CONFIG, req
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
// RE-CONFIG, resp
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), payload), {});
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), payload), {});
auto packet3 = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet3, HasDataChunkWithSsn(SSN(0)));
z->socket.ReceivePacket(packet3);
auto packet4 = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet4, HasDataChunkWithSsn(SSN(1)));
z->socket.ReceivePacket(packet4);
// Handle SACK
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest,
ResetStreamWillOnlyResetTheRequestedStreams) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
std::vector<uint8_t> payload(a.options.mtu - 100);
// Send two ordered messages on SID 1
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), payload), {});
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), payload), {});
auto packet1 = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet1, HasDataChunkWithStreamId(StreamID(1)));
EXPECT_THAT(packet1, HasDataChunkWithSsn(SSN(0)));
z->socket.ReceivePacket(packet1);
auto packet2 = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet1, HasDataChunkWithStreamId(StreamID(1)));
EXPECT_THAT(packet2, HasDataChunkWithSsn(SSN(1)));
z->socket.ReceivePacket(packet2);
// Handle SACK
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
// Do the same, for SID 3
a.socket.Send(DcSctpMessage(StreamID(3), PPID(53), payload), {});
a.socket.Send(DcSctpMessage(StreamID(3), PPID(53), payload), {});
auto packet3 = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet3, HasDataChunkWithStreamId(StreamID(3)));
EXPECT_THAT(packet3, HasDataChunkWithSsn(SSN(0)));
z->socket.ReceivePacket(packet3);
auto packet4 = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet4, HasDataChunkWithStreamId(StreamID(3)));
EXPECT_THAT(packet4, HasDataChunkWithSsn(SSN(1)));
z->socket.ReceivePacket(packet4);
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
// Receive all messages.
absl::optional<DcSctpMessage> msg1 = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg1.has_value());
EXPECT_EQ(msg1->stream_id(), StreamID(1));
absl::optional<DcSctpMessage> msg2 = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg2.has_value());
EXPECT_EQ(msg2->stream_id(), StreamID(1));
absl::optional<DcSctpMessage> msg3 = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg3.has_value());
EXPECT_EQ(msg3->stream_id(), StreamID(3));
absl::optional<DcSctpMessage> msg4 = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg4.has_value());
EXPECT_EQ(msg4->stream_id(), StreamID(3));
// Reset SID 1. This will directly send a RE-CONFIG.
a.socket.ResetStreams(std::vector<StreamID>({StreamID(3)}));
// RE-CONFIG, req
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
// RE-CONFIG, resp
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
// Send a message on SID 1 and 3 - SID 1 should not be reset, but 3 should.
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), payload), {});
a.socket.Send(DcSctpMessage(StreamID(3), PPID(53), payload), {});
auto packet5 = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet5, HasDataChunkWithStreamId(StreamID(1)));
EXPECT_THAT(packet5, HasDataChunkWithSsn(SSN(2))); // Unchanged.
z->socket.ReceivePacket(packet5);
auto packet6 = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet6, HasDataChunkWithStreamId(StreamID(3)));
EXPECT_THAT(packet6, HasDataChunkWithSsn(SSN(0))); // Reset.
z->socket.ReceivePacket(packet6);
// Handle SACK
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest, OnePeerReconnects) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
EXPECT_CALL(a.cb, OnConnectionRestarted).Times(1);
// Let's be evil here - reconnect while a fragmented packet was about to be
// sent. The receiving side should get it in full.
std::vector<uint8_t> payload(kLargeMessageSize);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), payload), kSendOptions);
// First DATA
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
// Create a new association, z2 - and don't use z anymore.
SocketUnderTest z2("Z2");
z2.socket.Connect();
// Retransmit and handle the rest. As there will be some chunks in-flight that
// have the wrong verification tag, those will yield errors.
ExchangeMessages(a, z2);
absl::optional<DcSctpMessage> msg = z2.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg.has_value());
EXPECT_EQ(msg->stream_id(), StreamID(1));
EXPECT_THAT(msg->payload(), testing::ElementsAreArray(payload));
}
TEST_P(DcSctpSocketParametrizedTest, SendMessageWithLimitedRtx) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
SendOptions send_options;
send_options.max_retransmissions = 0;
std::vector<uint8_t> payload(a.options.mtu - 100);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(51), payload), send_options);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(52), payload), send_options);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), payload), send_options);
// First DATA
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
// Second DATA (lost)
a.cb.ConsumeSentPacket();
// Third DATA
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
// Handle SACK for first DATA
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
// Handle delayed SACK for third DATA
AdvanceTime(a, *z, a.options.delayed_ack_max_timeout);
// Handle SACK for second DATA
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
// Now the missing data chunk will be marked as nacked, but it might still be
// in-flight and the reported gap could be due to out-of-order delivery. So
// the RetransmissionQueue will not mark it as "to be retransmitted" until
// after the t3-rtx timer has expired.
AdvanceTime(a, *z, a.options.rto_initial);
// The chunk will be marked as retransmitted, and then as abandoned, which
// will trigger a FORWARD-TSN to be sent.
// FORWARD-TSN (third)
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
// Which will trigger a SACK
a.socket.ReceivePacket(z->cb.ConsumeSentPacket());
absl::optional<DcSctpMessage> msg1 = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg1.has_value());
EXPECT_EQ(msg1->ppid(), PPID(51));
absl::optional<DcSctpMessage> msg2 = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg2.has_value());
EXPECT_EQ(msg2->ppid(), PPID(53));
absl::optional<DcSctpMessage> msg3 = z->cb.ConsumeReceivedMessage();
EXPECT_FALSE(msg3.has_value());
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest, SendManyFragmentedMessagesWithLimitedRtx) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
SendOptions send_options;
send_options.unordered = IsUnordered(true);
send_options.max_retransmissions = 0;
std::vector<uint8_t> payload(a.options.mtu * 2 - 100 /* margin */);
// Sending first message
a.socket.Send(DcSctpMessage(StreamID(1), PPID(51), payload), send_options);
// Sending second message
a.socket.Send(DcSctpMessage(StreamID(1), PPID(52), payload), send_options);
// Sending third message
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), payload), send_options);
// Sending fourth message
a.socket.Send(DcSctpMessage(StreamID(1), PPID(54), payload), send_options);
// First DATA, first fragment
std::vector<uint8_t> packet = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet, HasDataChunkWithPPID(PPID(51)));
z->socket.ReceivePacket(std::move(packet));
// First DATA, second fragment (lost)
packet = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet, HasDataChunkWithPPID(PPID(51)));
// Second DATA, first fragment
packet = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet, HasDataChunkWithPPID(PPID(52)));
z->socket.ReceivePacket(std::move(packet));
// Second DATA, second fragment (lost)
packet = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet, HasDataChunkWithPPID(PPID(52)));
EXPECT_THAT(packet, HasDataChunkWithSsn(SSN(0)));
// Third DATA, first fragment
packet = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet, HasDataChunkWithPPID(PPID(53)));
EXPECT_THAT(packet, HasDataChunkWithSsn(SSN(0)));
z->socket.ReceivePacket(std::move(packet));
// Third DATA, second fragment (lost)
packet = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet, HasDataChunkWithPPID(PPID(53)));
EXPECT_THAT(packet, HasDataChunkWithSsn(SSN(0)));
// Fourth DATA, first fragment
packet = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet, HasDataChunkWithPPID(PPID(54)));
EXPECT_THAT(packet, HasDataChunkWithSsn(SSN(0)));
z->socket.ReceivePacket(std::move(packet));
// Fourth DATA, second fragment
packet = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet, HasDataChunkWithPPID(PPID(54)));
EXPECT_THAT(packet, HasDataChunkWithSsn(SSN(0)));
z->socket.ReceivePacket(std::move(packet));
ExchangeMessages(a, *z);
// Let the RTX timer expire, and exchange FORWARD-TSN/SACKs
AdvanceTime(a, *z, a.options.rto_initial);
ExchangeMessages(a, *z);
absl::optional<DcSctpMessage> msg1 = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg1.has_value());
EXPECT_EQ(msg1->ppid(), PPID(54));
ASSERT_FALSE(z->cb.ConsumeReceivedMessage().has_value());
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
struct FakeChunkConfig : ChunkConfig {
static constexpr int kType = 0x49;
static constexpr size_t kHeaderSize = 4;
static constexpr int kVariableLengthAlignment = 0;
};
class FakeChunk : public Chunk, public TLVTrait<FakeChunkConfig> {
public:
FakeChunk() {}
FakeChunk(FakeChunk&& other) = default;
FakeChunk& operator=(FakeChunk&& other) = default;
void SerializeTo(std::vector<uint8_t>& out) const override {
AllocateTLV(out);
}
std::string ToString() const override { return "FAKE"; }
};
TEST_P(DcSctpSocketParametrizedTest, ReceivingUnknownChunkRespondsWithError) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
// Inject a FAKE chunk
SctpPacket::Builder b(a.socket.verification_tag(), DcSctpOptions());
b.Add(FakeChunk());
a.socket.ReceivePacket(b.Build());
// ERROR is sent as a reply. Capture it.
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket reply_packet,
SctpPacket::Parse(a.cb.ConsumeSentPacket()));
ASSERT_THAT(reply_packet.descriptors(), SizeIs(1));
ASSERT_HAS_VALUE_AND_ASSIGN(
ErrorChunk error, ErrorChunk::Parse(reply_packet.descriptors()[0].data));
ASSERT_HAS_VALUE_AND_ASSIGN(
UnrecognizedChunkTypeCause cause,
error.error_causes().get<UnrecognizedChunkTypeCause>());
EXPECT_THAT(cause.unrecognized_chunk(), ElementsAre(0x49, 0x00, 0x00, 0x04));
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest, ReceivingErrorChunkReportsAsCallback) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
// Inject a ERROR chunk
SctpPacket::Builder b(a.socket.verification_tag(), DcSctpOptions());
b.Add(
ErrorChunk(Parameters::Builder()
.Add(UnrecognizedChunkTypeCause({0x49, 0x00, 0x00, 0x04}))
.Build()));
EXPECT_CALL(a.cb, OnError(ErrorKind::kPeerReported,
HasSubstr("Unrecognized Chunk Type")));
a.socket.ReceivePacket(b.Build());
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST(DcSctpSocketTest, PassingHighWatermarkWillOnlyAcceptCumAckTsn) {
SocketUnderTest a("A");
constexpr size_t kReceiveWindowBufferSize = 2000;
SocketUnderTest z(
"Z", {.mtu = 3000,
.max_receiver_window_buffer_size = kReceiveWindowBufferSize});
EXPECT_CALL(z.cb, OnClosed).Times(0);
EXPECT_CALL(z.cb, OnAborted).Times(0);
a.socket.Connect();
std::vector<uint8_t> init_data = a.cb.ConsumeSentPacket();
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket init_packet,
SctpPacket::Parse(init_data));
ASSERT_HAS_VALUE_AND_ASSIGN(
InitChunk init_chunk,
InitChunk::Parse(init_packet.descriptors()[0].data));
z.socket.ReceivePacket(init_data);
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
// Fill up Z2 to the high watermark limit.
constexpr size_t kWatermarkLimit =
kReceiveWindowBufferSize * ReassemblyQueue::kHighWatermarkLimit;
constexpr size_t kRemainingSize = kReceiveWindowBufferSize - kWatermarkLimit;
TSN tsn = init_chunk.initial_tsn();
AnyDataChunk::Options opts;
opts.is_beginning = Data::IsBeginning(true);
z.socket.ReceivePacket(
SctpPacket::Builder(z.socket.verification_tag(), z.options)
.Add(DataChunk(tsn, StreamID(1), SSN(0), PPID(53),
std::vector<uint8_t>(kWatermarkLimit + 1), opts))
.Build());
// First DATA will always trigger a SACK. It's not interesting.
EXPECT_THAT(z.cb.ConsumeSentPacket(),
AllOf(HasSackWithCumAckTsn(tsn), HasSackWithNoGapAckBlocks()));
// This DATA should be accepted - it's advancing cum ack tsn.
z.socket.ReceivePacket(
SctpPacket::Builder(z.socket.verification_tag(), z.options)
.Add(DataChunk(AddTo(tsn, 1), StreamID(1), SSN(0), PPID(53),
std::vector<uint8_t>(1),
/*options=*/{}))
.Build());
// The receiver might have moved into delayed ack mode.
AdvanceTime(a, z, z.options.rto_initial);
EXPECT_THAT(
z.cb.ConsumeSentPacket(),
AllOf(HasSackWithCumAckTsn(AddTo(tsn, 1)), HasSackWithNoGapAckBlocks()));
// This DATA will not be accepted - it's not advancing cum ack tsn.
z.socket.ReceivePacket(
SctpPacket::Builder(z.socket.verification_tag(), z.options)
.Add(DataChunk(AddTo(tsn, 3), StreamID(1), SSN(0), PPID(53),
std::vector<uint8_t>(1),
/*options=*/{}))
.Build());
// Sack will be sent in IMMEDIATE mode when this is happening.
EXPECT_THAT(
z.cb.ConsumeSentPacket(),
AllOf(HasSackWithCumAckTsn(AddTo(tsn, 1)), HasSackWithNoGapAckBlocks()));
// This DATA will not be accepted either.
z.socket.ReceivePacket(
SctpPacket::Builder(z.socket.verification_tag(), z.options)
.Add(DataChunk(AddTo(tsn, 4), StreamID(1), SSN(0), PPID(53),
std::vector<uint8_t>(1),
/*options=*/{}))
.Build());
// Sack will be sent in IMMEDIATE mode when this is happening.
EXPECT_THAT(
z.cb.ConsumeSentPacket(),
AllOf(HasSackWithCumAckTsn(AddTo(tsn, 1)), HasSackWithNoGapAckBlocks()));
// This DATA should be accepted, and it fills the reassembly queue.
z.socket.ReceivePacket(
SctpPacket::Builder(z.socket.verification_tag(), z.options)
.Add(DataChunk(AddTo(tsn, 2), StreamID(1), SSN(0), PPID(53),
std::vector<uint8_t>(kRemainingSize),
/*options=*/{}))
.Build());
// The receiver might have moved into delayed ack mode.
AdvanceTime(a, z, z.options.rto_initial);
EXPECT_THAT(
z.cb.ConsumeSentPacket(),
AllOf(HasSackWithCumAckTsn(AddTo(tsn, 2)), HasSackWithNoGapAckBlocks()));
EXPECT_CALL(z.cb, OnAborted(ErrorKind::kResourceExhaustion, _));
EXPECT_CALL(z.cb, OnClosed).Times(0);
// This DATA will make the connection close. It's too full now.
z.socket.ReceivePacket(
SctpPacket::Builder(z.socket.verification_tag(), z.options)
.Add(DataChunk(AddTo(tsn, 3), StreamID(1), SSN(0), PPID(53),
std::vector<uint8_t>(kSmallMessageSize),
/*options=*/{}))
.Build());
}
TEST(DcSctpSocketTest, SetMaxMessageSize) {
SocketUnderTest a("A");
a.socket.SetMaxMessageSize(42u);
EXPECT_EQ(a.socket.options().max_message_size, 42u);
}
TEST_P(DcSctpSocketParametrizedTest, SendsMessagesWithLowLifetime) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
// Mock that the time always goes forward.
TimeMs now(0);
EXPECT_CALL(a.cb, TimeMillis).WillRepeatedly([&]() {
now += DurationMs(3);
return now;
});
EXPECT_CALL(z->cb, TimeMillis).WillRepeatedly([&]() {
now += DurationMs(3);
return now;
});
// Queue a few small messages with low lifetime, both ordered and unordered,
// and validate that all are delivered.
static constexpr int kIterations = 100;
for (int i = 0; i < kIterations; ++i) {
SendOptions send_options;
send_options.unordered = IsUnordered((i % 2) == 0);
send_options.lifetime = DurationMs(i % 3); // 0, 1, 2 ms
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2}), send_options);
}
ExchangeMessages(a, *z);
for (int i = 0; i < kIterations; ++i) {
EXPECT_TRUE(z->cb.ConsumeReceivedMessage().has_value());
}
EXPECT_FALSE(z->cb.ConsumeReceivedMessage().has_value());
// Validate that the sockets really make the time move forward.
EXPECT_GE(*now, kIterations * 2);
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest,
DiscardsMessagesWithLowLifetimeIfMustBuffer) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
SendOptions lifetime_0;
lifetime_0.unordered = IsUnordered(true);
lifetime_0.lifetime = DurationMs(0);
SendOptions lifetime_1;
lifetime_1.unordered = IsUnordered(true);
lifetime_1.lifetime = DurationMs(1);
// Mock that the time always goes forward.
TimeMs now(0);
EXPECT_CALL(a.cb, TimeMillis).WillRepeatedly([&]() {
now += DurationMs(3);
return now;
});
EXPECT_CALL(z->cb, TimeMillis).WillRepeatedly([&]() {
now += DurationMs(3);
return now;
});
// Fill up the send buffer with a large message.
std::vector<uint8_t> payload(kLargeMessageSize);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), payload), kSendOptions);
// And queue a few small messages with lifetime=0 or 1 ms - can't be sent.
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2, 3}), lifetime_0);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {4, 5, 6}), lifetime_1);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {7, 8, 9}), lifetime_0);
// Handle all that was sent until congestion window got full.
for (;;) {
std::vector<uint8_t> packet_from_a = a.cb.ConsumeSentPacket();
if (packet_from_a.empty()) {
break;
}
z->socket.ReceivePacket(std::move(packet_from_a));
}
// Shouldn't be enough to send that large message.
EXPECT_FALSE(z->cb.ConsumeReceivedMessage().has_value());
// Exchange the rest of the messages, with the time ever increasing.
ExchangeMessages(a, *z);
// The large message should be delivered. It was sent reliably.
ASSERT_HAS_VALUE_AND_ASSIGN(DcSctpMessage m1, z->cb.ConsumeReceivedMessage());
EXPECT_EQ(m1.stream_id(), StreamID(1));
EXPECT_THAT(m1.payload(), SizeIs(kLargeMessageSize));
// But none of the smaller messages.
EXPECT_FALSE(z->cb.ConsumeReceivedMessage().has_value());
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest, HasReasonableBufferedAmountValues) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
EXPECT_EQ(a.socket.buffered_amount(StreamID(1)), 0u);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53),
std::vector<uint8_t>(kSmallMessageSize)),
kSendOptions);
// Sending a small message will directly send it as a single packet, so
// nothing is left in the queue.
EXPECT_EQ(a.socket.buffered_amount(StreamID(1)), 0u);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53),
std::vector<uint8_t>(kLargeMessageSize)),
kSendOptions);
// Sending a message will directly start sending a few packets, so the
// buffered amount is not the full message size.
EXPECT_GT(a.socket.buffered_amount(StreamID(1)), 0u);
EXPECT_LT(a.socket.buffered_amount(StreamID(1)), kLargeMessageSize);
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST(DcSctpSocketTest, HasDefaultOnBufferedAmountLowValueZero) {
SocketUnderTest a("A");
EXPECT_EQ(a.socket.buffered_amount_low_threshold(StreamID(1)), 0u);
}
TEST_P(DcSctpSocketParametrizedTest,
TriggersOnBufferedAmountLowWithDefaultValueZero) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
EXPECT_CALL(a.cb, OnBufferedAmountLow).Times(0);
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
EXPECT_CALL(a.cb, OnBufferedAmountLow(StreamID(1)));
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53),
std::vector<uint8_t>(kSmallMessageSize)),
kSendOptions);
ExchangeMessages(a, *z);
EXPECT_CALL(a.cb, OnBufferedAmountLow).WillRepeatedly(testing::Return());
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest,
DoesntTriggerOnBufferedAmountLowIfBelowThreshold) {
static constexpr size_t kMessageSize = 1000;
static constexpr size_t kBufferedAmountLowThreshold = kMessageSize * 10;
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
a.socket.SetBufferedAmountLowThreshold(StreamID(1),
kBufferedAmountLowThreshold);
EXPECT_CALL(a.cb, OnBufferedAmountLow).Times(0);
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
EXPECT_CALL(a.cb, OnBufferedAmountLow(StreamID(1))).Times(0);
a.socket.Send(
DcSctpMessage(StreamID(1), PPID(53), std::vector<uint8_t>(kMessageSize)),
kSendOptions);
ExchangeMessages(a, *z);
a.socket.Send(
DcSctpMessage(StreamID(1), PPID(53), std::vector<uint8_t>(kMessageSize)),
kSendOptions);
ExchangeMessages(a, *z);
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest, TriggersOnBufferedAmountMultipleTimes) {
static constexpr size_t kMessageSize = 1000;
static constexpr size_t kBufferedAmountLowThreshold = kMessageSize / 2;
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
a.socket.SetBufferedAmountLowThreshold(StreamID(1),
kBufferedAmountLowThreshold);
EXPECT_CALL(a.cb, OnBufferedAmountLow).Times(0);
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
EXPECT_CALL(a.cb, OnBufferedAmountLow(StreamID(1))).Times(3);
EXPECT_CALL(a.cb, OnBufferedAmountLow(StreamID(2))).Times(2);
a.socket.Send(
DcSctpMessage(StreamID(1), PPID(53), std::vector<uint8_t>(kMessageSize)),
kSendOptions);
ExchangeMessages(a, *z);
a.socket.Send(
DcSctpMessage(StreamID(2), PPID(53), std::vector<uint8_t>(kMessageSize)),
kSendOptions);
ExchangeMessages(a, *z);
a.socket.Send(
DcSctpMessage(StreamID(1), PPID(53), std::vector<uint8_t>(kMessageSize)),
kSendOptions);
ExchangeMessages(a, *z);
a.socket.Send(
DcSctpMessage(StreamID(2), PPID(53), std::vector<uint8_t>(kMessageSize)),
kSendOptions);
ExchangeMessages(a, *z);
a.socket.Send(
DcSctpMessage(StreamID(1), PPID(53), std::vector<uint8_t>(kMessageSize)),
kSendOptions);
ExchangeMessages(a, *z);
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest,
TriggersOnBufferedAmountLowOnlyWhenCrossingThreshold) {
static constexpr size_t kMessageSize = 1000;
static constexpr size_t kBufferedAmountLowThreshold = kMessageSize * 1.5;
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
a.socket.SetBufferedAmountLowThreshold(StreamID(1),
kBufferedAmountLowThreshold);
EXPECT_CALL(a.cb, OnBufferedAmountLow).Times(0);
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
EXPECT_CALL(a.cb, OnBufferedAmountLow).Times(0);
// Add a few messages to fill up the congestion window. When that is full,
// messages will start to be fully buffered.
while (a.socket.buffered_amount(StreamID(1)) <= kBufferedAmountLowThreshold) {
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53),
std::vector<uint8_t>(kMessageSize)),
kSendOptions);
}
size_t initial_buffered = a.socket.buffered_amount(StreamID(1));
ASSERT_GT(initial_buffered, kBufferedAmountLowThreshold);
// Start ACKing packets, which will empty the send queue, and trigger the
// callback.
EXPECT_CALL(a.cb, OnBufferedAmountLow(StreamID(1))).Times(1);
ExchangeMessages(a, *z);
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest,
DoesntTriggerOnTotalBufferAmountLowWhenBelow) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
EXPECT_CALL(a.cb, OnTotalBufferedAmountLow).Times(0);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53),
std::vector<uint8_t>(kLargeMessageSize)),
kSendOptions);
ExchangeMessages(a, *z);
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest,
TriggersOnTotalBufferAmountLowWhenCrossingThreshold) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
EXPECT_CALL(a.cb, OnTotalBufferedAmountLow).Times(0);
// Fill up the send queue completely.
for (;;) {
if (a.socket.Send(DcSctpMessage(StreamID(1), PPID(53),
std::vector<uint8_t>(kLargeMessageSize)),
kSendOptions) == SendStatus::kErrorResourceExhaustion) {
break;
}
}
EXPECT_CALL(a.cb, OnTotalBufferedAmountLow).Times(1);
ExchangeMessages(a, *z);
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST(DcSctpSocketTest, InitialMetricsAreUnset) {
SocketUnderTest a("A");
EXPECT_FALSE(a.socket.GetMetrics().has_value());
}
TEST(DcSctpSocketTest, MessageInterleavingMetricsAreSet) {
std::vector<std::pair<bool, bool>> combinations = {
{false, false}, {false, true}, {true, false}, {true, true}};
for (const auto& [a_enable, z_enable] : combinations) {
DcSctpOptions a_options = {.enable_message_interleaving = a_enable};
DcSctpOptions z_options = {.enable_message_interleaving = z_enable};
SocketUnderTest a("A", a_options);
SocketUnderTest z("Z", z_options);
ConnectSockets(a, z);
EXPECT_EQ(a.socket.GetMetrics()->uses_message_interleaving,
a_enable && z_enable);
}
}
TEST(DcSctpSocketTest, RxAndTxPacketMetricsIncrease) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
ConnectSockets(a, z);
const size_t initial_a_rwnd = a.options.max_receiver_window_buffer_size *
ReassemblyQueue::kHighWatermarkLimit;
EXPECT_EQ(a.socket.GetMetrics()->tx_packets_count, 2u);
EXPECT_EQ(a.socket.GetMetrics()->rx_packets_count, 2u);
EXPECT_EQ(a.socket.GetMetrics()->tx_messages_count, 0u);
EXPECT_EQ(a.socket.GetMetrics()->cwnd_bytes,
a.options.cwnd_mtus_initial * a.options.mtu);
EXPECT_EQ(a.socket.GetMetrics()->unack_data_count, 0u);
EXPECT_EQ(z.socket.GetMetrics()->rx_packets_count, 2u);
EXPECT_EQ(z.socket.GetMetrics()->rx_messages_count, 0u);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2}), kSendOptions);
EXPECT_EQ(a.socket.GetMetrics()->unack_data_count, 1u);
z.socket.ReceivePacket(a.cb.ConsumeSentPacket()); // DATA
a.socket.ReceivePacket(z.cb.ConsumeSentPacket()); // SACK
EXPECT_EQ(a.socket.GetMetrics()->peer_rwnd_bytes, initial_a_rwnd);
EXPECT_EQ(a.socket.GetMetrics()->unack_data_count, 0u);
EXPECT_TRUE(z.cb.ConsumeReceivedMessage().has_value());
EXPECT_EQ(a.socket.GetMetrics()->tx_packets_count, 3u);
EXPECT_EQ(a.socket.GetMetrics()->rx_packets_count, 3u);
EXPECT_EQ(a.socket.GetMetrics()->tx_messages_count, 1u);
EXPECT_EQ(z.socket.GetMetrics()->rx_packets_count, 3u);
EXPECT_EQ(z.socket.GetMetrics()->rx_messages_count, 1u);
// Send one more (large - fragmented), and receive the delayed SACK.
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53),
std::vector<uint8_t>(a.options.mtu * 2 + 1)),
kSendOptions);
EXPECT_EQ(a.socket.GetMetrics()->unack_data_count, 3u);
z.socket.ReceivePacket(a.cb.ConsumeSentPacket()); // DATA
z.socket.ReceivePacket(a.cb.ConsumeSentPacket()); // DATA
a.socket.ReceivePacket(z.cb.ConsumeSentPacket()); // SACK
EXPECT_EQ(a.socket.GetMetrics()->unack_data_count, 1u);
EXPECT_GT(a.socket.GetMetrics()->peer_rwnd_bytes, 0u);
EXPECT_LT(a.socket.GetMetrics()->peer_rwnd_bytes, initial_a_rwnd);
z.socket.ReceivePacket(a.cb.ConsumeSentPacket()); // DATA
EXPECT_TRUE(z.cb.ConsumeReceivedMessage().has_value());
EXPECT_EQ(a.socket.GetMetrics()->tx_packets_count, 6u);
EXPECT_EQ(a.socket.GetMetrics()->rx_packets_count, 4u);
EXPECT_EQ(a.socket.GetMetrics()->tx_messages_count, 2u);
EXPECT_EQ(z.socket.GetMetrics()->rx_packets_count, 6u);
EXPECT_EQ(z.socket.GetMetrics()->rx_messages_count, 2u);
// Delayed sack
AdvanceTime(a, z, a.options.delayed_ack_max_timeout);
a.socket.ReceivePacket(z.cb.ConsumeSentPacket()); // SACK
EXPECT_EQ(a.socket.GetMetrics()->unack_data_count, 0u);
EXPECT_EQ(a.socket.GetMetrics()->rx_packets_count, 5u);
EXPECT_EQ(a.socket.GetMetrics()->peer_rwnd_bytes, initial_a_rwnd);
}
TEST_P(DcSctpSocketParametrizedTest, UnackDataAlsoIncludesSendQueue) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53),
std::vector<uint8_t>(kLargeMessageSize)),
kSendOptions);
size_t payload_bytes =
a.options.mtu - SctpPacket::kHeaderSize - DataChunk::kHeaderSize;
size_t expected_sent_packets = a.options.cwnd_mtus_initial;
size_t expected_queued_bytes =
kLargeMessageSize - expected_sent_packets * payload_bytes;
size_t expected_queued_packets = expected_queued_bytes / payload_bytes;
// Due to alignment, padding etc, it's hard to calculate the exact number, but
// it should be in this range.
EXPECT_GE(a.socket.GetMetrics()->unack_data_count,
expected_sent_packets + expected_queued_packets);
EXPECT_LE(a.socket.GetMetrics()->unack_data_count,
expected_sent_packets + expected_queued_packets + 2);
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest, DoesntSendMoreThanMaxBurstPackets) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53),
std::vector<uint8_t>(kLargeMessageSize)),
kSendOptions);
for (int i = 0; i < kMaxBurstPackets; ++i) {
std::vector<uint8_t> packet = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet, Not(IsEmpty()));
z->socket.ReceivePacket(std::move(packet)); // DATA
}
EXPECT_THAT(a.cb.ConsumeSentPacket(), IsEmpty());
ExchangeMessages(a, *z);
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST_P(DcSctpSocketParametrizedTest, SendsOnlyLargePackets) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
// A really large message, to ensure that the congestion window is often full.
constexpr size_t kMessageSize = 100000;
a.socket.Send(
DcSctpMessage(StreamID(1), PPID(53), std::vector<uint8_t>(kMessageSize)),
kSendOptions);
bool delivered_packet = false;
std::vector<size_t> data_packet_sizes;
do {
delivered_packet = false;
std::vector<uint8_t> packet_from_a = a.cb.ConsumeSentPacket();
if (!packet_from_a.empty()) {
data_packet_sizes.push_back(packet_from_a.size());
delivered_packet = true;
z->socket.ReceivePacket(std::move(packet_from_a));
}
std::vector<uint8_t> packet_from_z = z->cb.ConsumeSentPacket();
if (!packet_from_z.empty()) {
delivered_packet = true;
a.socket.ReceivePacket(std::move(packet_from_z));
}
} while (delivered_packet);
size_t packet_payload_bytes =
a.options.mtu - SctpPacket::kHeaderSize - DataChunk::kHeaderSize;
// +1 accounts for padding, and rounding up.
size_t expected_packets =
(kMessageSize + packet_payload_bytes - 1) / packet_payload_bytes + 1;
EXPECT_THAT(data_packet_sizes, SizeIs(expected_packets));
// Remove the last size - it will be the remainder. But all other sizes should
// be large.
data_packet_sizes.pop_back();
for (size_t size : data_packet_sizes) {
// The 4 is for padding/alignment.
EXPECT_GE(size, a.options.mtu - 4);
}
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST(DcSctpSocketTest, SendMessagesAfterHandover) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
// Send message before handover to move socket to a not initial state
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2}), kSendOptions);
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
z->cb.ConsumeReceivedMessage();
z = HandoverSocket(std::move(z));
absl::optional<DcSctpMessage> msg;
RTC_LOG(LS_INFO) << "Sending A #1";
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {3, 4}), kSendOptions);
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
msg = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg.has_value());
EXPECT_EQ(msg->stream_id(), StreamID(1));
EXPECT_THAT(msg->payload(), testing::ElementsAre(3, 4));
RTC_LOG(LS_INFO) << "Sending A #2";
a.socket.Send(DcSctpMessage(StreamID(2), PPID(53), {5, 6}), kSendOptions);
z->socket.ReceivePacket(a.cb.ConsumeSentPacket());
msg = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg.has_value());
EXPECT_EQ(msg->stream_id(), StreamID(2));
EXPECT_THAT(msg->payload(), testing::ElementsAre(5, 6));
RTC_LOG(LS_INFO) << "Sending Z #1";
z->socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2, 3}), kSendOptions);
a.socket.ReceivePacket(z->cb.ConsumeSentPacket()); // ack
a.socket.ReceivePacket(z->cb.ConsumeSentPacket()); // data
msg = a.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg.has_value());
EXPECT_EQ(msg->stream_id(), StreamID(1));
EXPECT_THAT(msg->payload(), testing::ElementsAre(1, 2, 3));
}
TEST(DcSctpSocketTest, CanDetectDcsctpImplementation) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
ConnectSockets(a, z);
EXPECT_EQ(a.socket.peer_implementation(), SctpImplementation::kDcsctp);
// As A initiated the connection establishment, Z will not receive enough
// information to know about A's implementation
EXPECT_EQ(z.socket.peer_implementation(), SctpImplementation::kUnknown);
}
TEST(DcSctpSocketTest, BothCanDetectDcsctpImplementation) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
EXPECT_CALL(a.cb, OnConnected).Times(1);
EXPECT_CALL(z.cb, OnConnected).Times(1);
a.socket.Connect();
z.socket.Connect();
ExchangeMessages(a, z);
EXPECT_EQ(a.socket.peer_implementation(), SctpImplementation::kDcsctp);
EXPECT_EQ(z.socket.peer_implementation(), SctpImplementation::kDcsctp);
}
TEST_P(DcSctpSocketParametrizedTest, CanLoseFirstOrderedMessage) {
SocketUnderTest a("A");
auto z = std::make_unique<SocketUnderTest>("Z");
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
SendOptions send_options;
send_options.unordered = IsUnordered(false);
send_options.max_retransmissions = 0;
std::vector<uint8_t> payload(a.options.mtu - 100);
// Send a first message (SID=1, SSN=0)
a.socket.Send(DcSctpMessage(StreamID(1), PPID(51), payload), send_options);
// First DATA is lost, and retransmission timer will delete it.
a.cb.ConsumeSentPacket();
AdvanceTime(a, *z, a.options.rto_initial);
ExchangeMessages(a, *z);
// Send a second message (SID=0, SSN=1).
a.socket.Send(DcSctpMessage(StreamID(1), PPID(52), payload), send_options);
ExchangeMessages(a, *z);
// The Z socket should receive the second message, but not the first.
absl::optional<DcSctpMessage> msg = z->cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg.has_value());
EXPECT_EQ(msg->ppid(), PPID(52));
EXPECT_FALSE(z->cb.ConsumeReceivedMessage().has_value());
MaybeHandoverSocketAndSendMessage(a, std::move(z));
}
TEST(DcSctpSocketTest, ReceiveBothUnorderedAndOrderedWithSameTSN) {
/* This issue was found by fuzzing. */
SocketUnderTest a("A");
SocketUnderTest z("Z");
a.socket.Connect();
std::vector<uint8_t> init_data = a.cb.ConsumeSentPacket();
ASSERT_HAS_VALUE_AND_ASSIGN(SctpPacket init_packet,
SctpPacket::Parse(init_data));
ASSERT_HAS_VALUE_AND_ASSIGN(
InitChunk init_chunk,
InitChunk::Parse(init_packet.descriptors()[0].data));
z.socket.ReceivePacket(init_data);
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
a.socket.ReceivePacket(z.cb.ConsumeSentPacket());
// Receive a short unordered message with tsn=INITIAL_TSN+1
TSN tsn = init_chunk.initial_tsn();
AnyDataChunk::Options opts;
opts.is_beginning = Data::IsBeginning(true);
opts.is_end = Data::IsEnd(true);
opts.is_unordered = IsUnordered(true);
z.socket.ReceivePacket(
SctpPacket::Builder(z.socket.verification_tag(), z.options)
.Add(DataChunk(TSN(*tsn + 1), StreamID(1), SSN(0), PPID(53),
std::vector<uint8_t>(10), opts))
.Build());
// Now receive a longer _ordered_ message with [INITIAL_TSN, INITIAL_TSN+1].
// This isn't allowed as it reuses TSN=53 with different properties, but it
// shouldn't cause any issues.
opts.is_unordered = IsUnordered(false);
opts.is_end = Data::IsEnd(false);
z.socket.ReceivePacket(
SctpPacket::Builder(z.socket.verification_tag(), z.options)
.Add(DataChunk(tsn, StreamID(1), SSN(0), PPID(53),
std::vector<uint8_t>(10), opts))
.Build());
opts.is_beginning = Data::IsBeginning(false);
opts.is_end = Data::IsEnd(true);
z.socket.ReceivePacket(
SctpPacket::Builder(z.socket.verification_tag(), z.options)
.Add(DataChunk(TSN(*tsn + 1), StreamID(1), SSN(0), PPID(53),
std::vector<uint8_t>(10), opts))
.Build());
}
TEST(DcSctpSocketTest, CloseTwoStreamsAtTheSameTime) {
// Reported as https://crbug.com/1312009.
SocketUnderTest a("A");
SocketUnderTest z("Z");
EXPECT_CALL(z.cb, OnIncomingStreamsReset(ElementsAre(StreamID(1)))).Times(1);
EXPECT_CALL(z.cb, OnIncomingStreamsReset(ElementsAre(StreamID(2)))).Times(1);
EXPECT_CALL(a.cb, OnStreamsResetPerformed(ElementsAre(StreamID(1)))).Times(1);
EXPECT_CALL(a.cb, OnStreamsResetPerformed(ElementsAre(StreamID(2)))).Times(1);
ConnectSockets(a, z);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2}), kSendOptions);
a.socket.Send(DcSctpMessage(StreamID(2), PPID(53), {1, 2}), kSendOptions);
ExchangeMessages(a, z);
a.socket.ResetStreams(std::vector<StreamID>({StreamID(1)}));
a.socket.ResetStreams(std::vector<StreamID>({StreamID(2)}));
ExchangeMessages(a, z);
}
TEST(DcSctpSocketTest, CloseThreeStreamsAtTheSameTime) {
// Similar to CloseTwoStreamsAtTheSameTime, but ensuring that the two
// remaining streams are reset at the same time in the second request.
SocketUnderTest a("A");
SocketUnderTest z("Z");
EXPECT_CALL(z.cb, OnIncomingStreamsReset(ElementsAre(StreamID(1)))).Times(1);
EXPECT_CALL(z.cb, OnIncomingStreamsReset(
UnorderedElementsAre(StreamID(2), StreamID(3))))
.Times(1);
EXPECT_CALL(a.cb, OnStreamsResetPerformed(ElementsAre(StreamID(1)))).Times(1);
EXPECT_CALL(a.cb, OnStreamsResetPerformed(
UnorderedElementsAre(StreamID(2), StreamID(3))))
.Times(1);
ConnectSockets(a, z);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2}), kSendOptions);
a.socket.Send(DcSctpMessage(StreamID(2), PPID(53), {1, 2}), kSendOptions);
a.socket.Send(DcSctpMessage(StreamID(3), PPID(53), {1, 2}), kSendOptions);
ExchangeMessages(a, z);
a.socket.ResetStreams(std::vector<StreamID>({StreamID(1)}));
a.socket.ResetStreams(std::vector<StreamID>({StreamID(2)}));
a.socket.ResetStreams(std::vector<StreamID>({StreamID(3)}));
ExchangeMessages(a, z);
}
TEST(DcSctpSocketTest, CloseStreamsWithPendingRequest) {
// Checks that stream reset requests are properly paused when they can't be
// immediately reset - i.e. when there is already an ongoing stream reset
// request (and there can only be a single one in-flight).
SocketUnderTest a("A");
SocketUnderTest z("Z");
EXPECT_CALL(z.cb, OnIncomingStreamsReset(ElementsAre(StreamID(1)))).Times(1);
EXPECT_CALL(z.cb, OnIncomingStreamsReset(
UnorderedElementsAre(StreamID(2), StreamID(3))))
.Times(1);
EXPECT_CALL(a.cb, OnStreamsResetPerformed(ElementsAre(StreamID(1)))).Times(1);
EXPECT_CALL(a.cb, OnStreamsResetPerformed(
UnorderedElementsAre(StreamID(2), StreamID(3))))
.Times(1);
ConnectSockets(a, z);
SendOptions send_options = {.unordered = IsUnordered(false)};
// Send a few ordered messages
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2}), send_options);
a.socket.Send(DcSctpMessage(StreamID(2), PPID(53), {1, 2}), send_options);
a.socket.Send(DcSctpMessage(StreamID(3), PPID(53), {1, 2}), send_options);
ExchangeMessages(a, z);
// Receive these messages
absl::optional<DcSctpMessage> msg1 = z.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg1.has_value());
EXPECT_EQ(msg1->stream_id(), StreamID(1));
absl::optional<DcSctpMessage> msg2 = z.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg2.has_value());
EXPECT_EQ(msg2->stream_id(), StreamID(2));
absl::optional<DcSctpMessage> msg3 = z.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg3.has_value());
EXPECT_EQ(msg3->stream_id(), StreamID(3));
// Reset the streams - not all at once.
a.socket.ResetStreams(std::vector<StreamID>({StreamID(1)}));
std::vector<uint8_t> packet = a.cb.ConsumeSentPacket();
EXPECT_THAT(packet, HasReconfigWithStreams(ElementsAre(StreamID(1))));
z.socket.ReceivePacket(std::move(packet));
// Sending more reset requests while this one is ongoing.
a.socket.ResetStreams(std::vector<StreamID>({StreamID(2)}));
a.socket.ResetStreams(std::vector<StreamID>({StreamID(3)}));
ExchangeMessages(a, z);
// Send a few more ordered messages
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), {1, 2}), send_options);
a.socket.Send(DcSctpMessage(StreamID(2), PPID(53), {1, 2}), send_options);
a.socket.Send(DcSctpMessage(StreamID(3), PPID(53), {1, 2}), send_options);
ExchangeMessages(a, z);
// Receive these messages
absl::optional<DcSctpMessage> msg4 = z.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg4.has_value());
EXPECT_EQ(msg4->stream_id(), StreamID(1));
absl::optional<DcSctpMessage> msg5 = z.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg5.has_value());
EXPECT_EQ(msg5->stream_id(), StreamID(2));
absl::optional<DcSctpMessage> msg6 = z.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg6.has_value());
EXPECT_EQ(msg6->stream_id(), StreamID(3));
}
TEST(DcSctpSocketTest, StreamsHaveInitialPriority) {
DcSctpOptions options = {.default_stream_priority = StreamPriority(42)};
SocketUnderTest a("A", options);
EXPECT_EQ(a.socket.GetStreamPriority(StreamID(1)),
options.default_stream_priority);
a.socket.Send(DcSctpMessage(StreamID(2), PPID(53), {1, 2}), kSendOptions);
EXPECT_EQ(a.socket.GetStreamPriority(StreamID(2)),
options.default_stream_priority);
}
TEST(DcSctpSocketTest, CanChangeStreamPriority) {
DcSctpOptions options = {.default_stream_priority = StreamPriority(42)};
SocketUnderTest a("A", options);
a.socket.SetStreamPriority(StreamID(1), StreamPriority(43));
EXPECT_EQ(a.socket.GetStreamPriority(StreamID(1)), StreamPriority(43));
a.socket.Send(DcSctpMessage(StreamID(2), PPID(53), {1, 2}), kSendOptions);
a.socket.SetStreamPriority(StreamID(2), StreamPriority(43));
EXPECT_EQ(a.socket.GetStreamPriority(StreamID(2)), StreamPriority(43));
}
TEST_P(DcSctpSocketParametrizedTest, WillHandoverPriority) {
DcSctpOptions options = {.default_stream_priority = StreamPriority(42)};
auto a = std::make_unique<SocketUnderTest>("A", options);
SocketUnderTest z("Z");
ConnectSockets(*a, z);
a->socket.SetStreamPriority(StreamID(1), StreamPriority(43));
a->socket.Send(DcSctpMessage(StreamID(2), PPID(53), {1, 2}), kSendOptions);
a->socket.SetStreamPriority(StreamID(2), StreamPriority(43));
ExchangeMessages(*a, z);
a = MaybeHandoverSocket(std::move(a));
EXPECT_EQ(a->socket.GetStreamPriority(StreamID(1)), StreamPriority(43));
EXPECT_EQ(a->socket.GetStreamPriority(StreamID(2)), StreamPriority(43));
}
TEST(DcSctpSocketTest, ReconnectSocketWithPendingStreamReset) {
// This is an issue found by fuzzing, and doesn't really make sense in WebRTC
// data channels as a SCTP connection is never ever closed and then
// reconnected. SCTP connections are closed when the peer connection is
// deleted, and then it doesn't do more with SCTP.
SocketUnderTest a("A");
SocketUnderTest z("Z");
ConnectSockets(a, z);
a.socket.ResetStreams(std::vector<StreamID>({StreamID(1)}));
EXPECT_CALL(z.cb, OnAborted).Times(1);
a.socket.Close();
EXPECT_EQ(a.socket.state(), SocketState::kClosed);
EXPECT_CALL(a.cb, OnConnected).Times(1);
EXPECT_CALL(z.cb, OnConnected).Times(1);
a.socket.Connect();
ExchangeMessages(a, z);
a.socket.ResetStreams(std::vector<StreamID>({StreamID(2)}));
}
TEST(DcSctpSocketTest, SmallSentMessagesWithPrioWillArriveInSpecificOrder) {
DcSctpOptions options = {.enable_message_interleaving = true};
SocketUnderTest a("A", options);
SocketUnderTest z("A", options);
a.socket.SetStreamPriority(StreamID(1), StreamPriority(700));
a.socket.SetStreamPriority(StreamID(2), StreamPriority(200));
a.socket.SetStreamPriority(StreamID(3), StreamPriority(100));
// Enqueue messages before connecting the socket, to ensure they aren't send
// as soon as Send() is called.
a.socket.Send(DcSctpMessage(StreamID(3), PPID(301),
std::vector<uint8_t>(kSmallMessageSize)),
kSendOptions);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(101),
std::vector<uint8_t>(kSmallMessageSize)),
kSendOptions);
a.socket.Send(DcSctpMessage(StreamID(2), PPID(201),
std::vector<uint8_t>(kSmallMessageSize)),
kSendOptions);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(102),
std::vector<uint8_t>(kSmallMessageSize)),
kSendOptions);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(103),
std::vector<uint8_t>(kSmallMessageSize)),
kSendOptions);
ConnectSockets(a, z);
ExchangeMessages(a, z);
std::vector<uint32_t> received_ppids;
for (;;) {
absl::optional<DcSctpMessage> msg = z.cb.ConsumeReceivedMessage();
if (!msg.has_value()) {
break;
}
received_ppids.push_back(*msg->ppid());
}
EXPECT_THAT(received_ppids, ElementsAre(101, 102, 103, 201, 301));
}
TEST(DcSctpSocketTest, LargeSentMessagesWithPrioWillArriveInSpecificOrder) {
DcSctpOptions options = {.enable_message_interleaving = true};
SocketUnderTest a("A", options);
SocketUnderTest z("A", options);
a.socket.SetStreamPriority(StreamID(1), StreamPriority(700));
a.socket.SetStreamPriority(StreamID(2), StreamPriority(200));
a.socket.SetStreamPriority(StreamID(3), StreamPriority(100));
// Enqueue messages before connecting the socket, to ensure they aren't send
// as soon as Send() is called.
a.socket.Send(DcSctpMessage(StreamID(3), PPID(301),
std::vector<uint8_t>(kLargeMessageSize)),
kSendOptions);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(101),
std::vector<uint8_t>(kLargeMessageSize)),
kSendOptions);
a.socket.Send(DcSctpMessage(StreamID(2), PPID(201),
std::vector<uint8_t>(kLargeMessageSize)),
kSendOptions);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(102),
std::vector<uint8_t>(kLargeMessageSize)),
kSendOptions);
ConnectSockets(a, z);
ExchangeMessages(a, z);
EXPECT_THAT(GetReceivedMessagePpids(z), ElementsAre(101, 102, 201, 301));
}
TEST(DcSctpSocketTest, MessageWithHigherPrioWillInterruptLowerPrioMessage) {
DcSctpOptions options = {.enable_message_interleaving = true};
SocketUnderTest a("A", options);
SocketUnderTest z("Z", options);
ConnectSockets(a, z);
a.socket.SetStreamPriority(StreamID(2), StreamPriority(128));
a.socket.Send(DcSctpMessage(StreamID(2), PPID(201),
std::vector<uint8_t>(kLargeMessageSize)),
kSendOptions);
// Due to a non-zero initial congestion window, the message will already start
// to send, but will not succeed to be sent completely before filling the
// congestion window or stopping due to reaching how many packets that can be
// sent at once (max burst). The important thing is that the entire message
// doesn't get sent in full.
// Now enqueue two messages; one small and one large higher priority message.
a.socket.SetStreamPriority(StreamID(1), StreamPriority(512));
a.socket.Send(DcSctpMessage(StreamID(1), PPID(101),
std::vector<uint8_t>(kSmallMessageSize)),
kSendOptions);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(102),
std::vector<uint8_t>(kLargeMessageSize)),
kSendOptions);
ExchangeMessages(a, z);
EXPECT_THAT(GetReceivedMessagePpids(z), ElementsAre(101, 102, 201));
}
TEST(DcSctpSocketTest, LifecycleEventsAreGeneratedForAckedMessages) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
ConnectSockets(a, z);
a.socket.Send(DcSctpMessage(StreamID(2), PPID(101),
std::vector<uint8_t>(kLargeMessageSize)),
{.lifecycle_id = LifecycleId(41)});
a.socket.Send(DcSctpMessage(StreamID(2), PPID(102),
std::vector<uint8_t>(kLargeMessageSize)),
kSendOptions);
a.socket.Send(DcSctpMessage(StreamID(2), PPID(103),
std::vector<uint8_t>(kLargeMessageSize)),
{.lifecycle_id = LifecycleId(42)});
EXPECT_CALL(a.cb, OnLifecycleMessageDelivered(LifecycleId(41)));
EXPECT_CALL(a.cb, OnLifecycleEnd(LifecycleId(41)));
EXPECT_CALL(a.cb, OnLifecycleMessageDelivered(LifecycleId(42)));
EXPECT_CALL(a.cb, OnLifecycleEnd(LifecycleId(42)));
ExchangeMessages(a, z);
// In case of delayed ack.
AdvanceTime(a, z, a.options.delayed_ack_max_timeout);
ExchangeMessages(a, z);
EXPECT_THAT(GetReceivedMessagePpids(z), ElementsAre(101, 102, 103));
}
TEST(DcSctpSocketTest, LifecycleEventsForFailMaxRetransmissions) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
ConnectSockets(a, z);
std::vector<uint8_t> payload(a.options.mtu - 100);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(51), payload),
{
.max_retransmissions = 0,
.lifecycle_id = LifecycleId(1),
});
a.socket.Send(DcSctpMessage(StreamID(1), PPID(52), payload),
{
.max_retransmissions = 0,
.lifecycle_id = LifecycleId(2),
});
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53), payload),
{
.max_retransmissions = 0,
.lifecycle_id = LifecycleId(3),
});
// First DATA
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// Second DATA (lost)
a.cb.ConsumeSentPacket();
EXPECT_CALL(a.cb, OnLifecycleMessageDelivered(LifecycleId(1)));
EXPECT_CALL(a.cb, OnLifecycleEnd(LifecycleId(1)));
EXPECT_CALL(a.cb, OnLifecycleMessageExpired(LifecycleId(2),
/*maybe_delivered=*/true));
EXPECT_CALL(a.cb, OnLifecycleEnd(LifecycleId(2)));
EXPECT_CALL(a.cb, OnLifecycleMessageDelivered(LifecycleId(3)));
EXPECT_CALL(a.cb, OnLifecycleEnd(LifecycleId(3)));
ExchangeMessages(a, z);
// Handle delayed SACK.
AdvanceTime(a, z, a.options.delayed_ack_max_timeout);
ExchangeMessages(a, z);
// The chunk is now NACKed. Let the RTO expire, to discard the message.
AdvanceTime(a, z, a.options.rto_initial);
ExchangeMessages(a, z);
// Handle delayed SACK.
AdvanceTime(a, z, a.options.delayed_ack_max_timeout);
ExchangeMessages(a, z);
EXPECT_THAT(GetReceivedMessagePpids(z), ElementsAre(51, 53));
}
TEST(DcSctpSocketTest, LifecycleEventsForExpiredMessageWithRetransmitLimit) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
ConnectSockets(a, z);
// Will not be able to send it in full within the congestion window, but will
// need to wait for SACKs to be received for more fragments to be sent.
std::vector<uint8_t> payload(kLargeMessageSize);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(51), payload),
{
.max_retransmissions = 0,
.lifecycle_id = LifecycleId(1),
});
// First DATA
z.socket.ReceivePacket(a.cb.ConsumeSentPacket());
// Second DATA (lost)
a.cb.ConsumeSentPacket();
EXPECT_CALL(a.cb, OnLifecycleMessageExpired(LifecycleId(1),
/*maybe_delivered=*/false));
EXPECT_CALL(a.cb, OnLifecycleEnd(LifecycleId(1)));
ExchangeMessages(a, z);
EXPECT_THAT(GetReceivedMessagePpids(z), IsEmpty());
}
TEST(DcSctpSocketTest, LifecycleEventsForExpiredMessageWithLifetimeLimit) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
// Send it before the socket is connected, to prevent it from being sent too
// quickly. The idea is that it should be expired before even attempting to
// send it in full.
std::vector<uint8_t> payload(kSmallMessageSize);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(51), payload),
{
.lifetime = DurationMs(100),
.lifecycle_id = LifecycleId(1),
});
AdvanceTime(a, z, DurationMs(200));
EXPECT_CALL(a.cb, OnLifecycleMessageExpired(LifecycleId(1),
/*maybe_delivered=*/false));
EXPECT_CALL(a.cb, OnLifecycleEnd(LifecycleId(1)));
ConnectSockets(a, z);
ExchangeMessages(a, z);
EXPECT_THAT(GetReceivedMessagePpids(z), IsEmpty());
}
TEST_P(DcSctpSocketParametrizedTest, ExposesTheNumberOfNegotiatedStreams) {
DcSctpOptions options_a = {
.announced_maximum_incoming_streams = 12,
.announced_maximum_outgoing_streams = 45,
};
SocketUnderTest a("A", options_a);
DcSctpOptions options_z = {
.announced_maximum_incoming_streams = 23,
.announced_maximum_outgoing_streams = 34,
};
auto z = std::make_unique<SocketUnderTest>("Z", options_z);
ConnectSockets(a, *z);
z = MaybeHandoverSocket(std::move(z));
ASSERT_HAS_VALUE_AND_ASSIGN(Metrics metrics_a, a.socket.GetMetrics());
EXPECT_EQ(metrics_a.negotiated_maximum_incoming_streams, 12);
EXPECT_EQ(metrics_a.negotiated_maximum_outgoing_streams, 23);
ASSERT_HAS_VALUE_AND_ASSIGN(Metrics metrics_z, z->socket.GetMetrics());
EXPECT_EQ(metrics_z.negotiated_maximum_incoming_streams, 23);
EXPECT_EQ(metrics_z.negotiated_maximum_outgoing_streams, 12);
}
TEST(DcSctpSocketTest, ResetStreamsDeferred) {
// Guaranteed to be fragmented into two fragments.
constexpr size_t kTwoFragmentsSize = DcSctpOptions::kMaxSafeMTUSize + 100;
SocketUnderTest a("A");
SocketUnderTest z("Z");
ConnectSockets(a, z);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(53),
std::vector<uint8_t>(kTwoFragmentsSize)),
{});
a.socket.Send(DcSctpMessage(StreamID(1), PPID(54),
std::vector<uint8_t>(kSmallMessageSize)),
{});
a.socket.ResetStreams(std::vector<StreamID>({StreamID(1)}));
auto data1 = a.cb.ConsumeSentPacket();
auto data2 = a.cb.ConsumeSentPacket();
auto data3 = a.cb.ConsumeSentPacket();
auto reconfig = a.cb.ConsumeSentPacket();
EXPECT_THAT(data1, HasDataChunkWithSsn(SSN(0)));
EXPECT_THAT(data2, HasDataChunkWithSsn(SSN(0)));
EXPECT_THAT(data3, HasDataChunkWithSsn(SSN(1)));
EXPECT_THAT(reconfig, HasReconfigWithStreams(ElementsAre(StreamID(1))));
// Receive them slightly out of order to make stream resetting deferred.
z.socket.ReceivePacket(reconfig);
z.socket.ReceivePacket(data1);
z.socket.ReceivePacket(data2);
z.socket.ReceivePacket(data3);
absl::optional<DcSctpMessage> msg1 = z.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg1.has_value());
EXPECT_EQ(msg1->stream_id(), StreamID(1));
EXPECT_EQ(msg1->ppid(), PPID(53));
EXPECT_EQ(msg1->payload().size(), kTwoFragmentsSize);
absl::optional<DcSctpMessage> msg2 = z.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg2.has_value());
EXPECT_EQ(msg2->stream_id(), StreamID(1));
EXPECT_EQ(msg2->ppid(), PPID(54));
EXPECT_EQ(msg2->payload().size(), kSmallMessageSize);
EXPECT_CALL(a.cb, OnStreamsResetPerformed(ElementsAre(StreamID(1))));
ExchangeMessages(a, z);
// Z sent "in progress", which will make A buffer packets until it's sure
// that the reconfiguration has been applied. A will retry - wait for that.
AdvanceTime(a, z, a.options.rto_initial);
auto reconfig2 = a.cb.ConsumeSentPacket();
EXPECT_THAT(reconfig2, HasReconfigWithStreams(ElementsAre(StreamID(1))));
EXPECT_CALL(z.cb, OnIncomingStreamsReset(ElementsAre(StreamID(1))));
z.socket.ReceivePacket(reconfig2);
auto reconfig3 = z.cb.ConsumeSentPacket();
EXPECT_THAT(reconfig3,
HasReconfigWithResponse(
ReconfigurationResponseParameter::Result::kSuccessPerformed));
a.socket.ReceivePacket(reconfig3);
EXPECT_THAT(data1, HasDataChunkWithSsn(SSN(0)));
EXPECT_THAT(data2, HasDataChunkWithSsn(SSN(0)));
EXPECT_THAT(data3, HasDataChunkWithSsn(SSN(1)));
EXPECT_THAT(reconfig, HasReconfigWithStreams(ElementsAre(StreamID(1))));
// Send a new message after the stream has been reset.
a.socket.Send(DcSctpMessage(StreamID(1), PPID(55),
std::vector<uint8_t>(kSmallMessageSize)),
{});
ExchangeMessages(a, z);
absl::optional<DcSctpMessage> msg3 = z.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg3.has_value());
EXPECT_EQ(msg3->stream_id(), StreamID(1));
EXPECT_EQ(msg3->ppid(), PPID(55));
EXPECT_EQ(msg3->payload().size(), kSmallMessageSize);
}
TEST(DcSctpSocketTest, ResetStreamsWithPausedSenderResumesWhenPerformed) {
SocketUnderTest a("A");
SocketUnderTest z("Z");
ConnectSockets(a, z);
a.socket.Send(DcSctpMessage(StreamID(1), PPID(51),
std::vector<uint8_t>(kSmallMessageSize)),
{});
a.socket.ResetStreams(std::vector<StreamID>({StreamID(1)}));
// Will be queued, as the stream has an outstanding reset operation.
a.socket.Send(DcSctpMessage(StreamID(1), PPID(52),
std::vector<uint8_t>(kSmallMessageSize)),
{});
EXPECT_CALL(a.cb, OnStreamsResetPerformed(ElementsAre(StreamID(1))));
EXPECT_CALL(z.cb, OnIncomingStreamsReset(ElementsAre(StreamID(1))));
ExchangeMessages(a, z);
absl::optional<DcSctpMessage> msg1 = z.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg1.has_value());
EXPECT_EQ(msg1->stream_id(), StreamID(1));
EXPECT_EQ(msg1->ppid(), PPID(51));
EXPECT_EQ(msg1->payload().size(), kSmallMessageSize);
absl::optional<DcSctpMessage> msg2 = z.cb.ConsumeReceivedMessage();
ASSERT_TRUE(msg2.has_value());
EXPECT_EQ(msg2->stream_id(), StreamID(1));
EXPECT_EQ(msg2->ppid(), PPID(52));
EXPECT_EQ(msg2->payload().size(), kSmallMessageSize);
}
} // namespace
} // namespace dcsctp