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webrtc / src / befdb843cbb84c7b5b2ab51e2c0ec09991c6089b / . / net / dcsctp / tx / rr_send_queue_test.cc
blob: 425027762d828df6679e187ed1277ac52fc8d192 [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/tx/rr_send_queue.h"
#include <cstdint>
#include <type_traits>
#include <vector>
#include "net/dcsctp/packet/data.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/types.h"
#include "net/dcsctp/testing/testing_macros.h"
#include "net/dcsctp/tx/send_queue.h"
#include "rtc_base/gunit.h"
#include "test/gmock.h"
namespace dcsctp {
namespace {
using ::testing::SizeIs;
constexpr TimeMs kNow = TimeMs(0);
constexpr StreamID kStreamID(1);
constexpr PPID kPPID(53);
constexpr size_t kMaxQueueSize = 1000;
constexpr size_t kBufferedAmountLowThreshold = 500;
constexpr size_t kOneFragmentPacketSize = 100;
constexpr size_t kTwoFragmentPacketSize = 101;
class RRSendQueueTest : public testing::Test {
protected:
RRSendQueueTest()
: buf_("log: ",
kMaxQueueSize,
on_buffered_amount_low_.AsStdFunction(),
kBufferedAmountLowThreshold,
on_total_buffered_amount_low_.AsStdFunction()) {}
const DcSctpOptions options_;
testing::NiceMock<testing::MockFunction<void(StreamID)>>
on_buffered_amount_low_;
testing::NiceMock<testing::MockFunction<void()>>
on_total_buffered_amount_low_;
RRSendQueue buf_;
};
TEST_F(RRSendQueueTest, EmptyBuffer) {
EXPECT_TRUE(buf_.IsEmpty());
EXPECT_FALSE(buf_.Produce(kNow, kOneFragmentPacketSize).has_value());
EXPECT_FALSE(buf_.IsFull());
}
TEST_F(RRSendQueueTest, AddAndGetSingleChunk) {
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, {1, 2, 4, 5, 6}));
EXPECT_FALSE(buf_.IsEmpty());
EXPECT_FALSE(buf_.IsFull());
absl::optional<SendQueue::DataToSend> chunk_opt =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_opt.has_value());
EXPECT_TRUE(chunk_opt->data.is_beginning);
EXPECT_TRUE(chunk_opt->data.is_end);
}
TEST_F(RRSendQueueTest, CarveOutBeginningMiddleAndEnd) {
std::vector<uint8_t> payload(60);
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
absl::optional<SendQueue::DataToSend> chunk_beg =
buf_.Produce(kNow, /*max_size=*/20);
ASSERT_TRUE(chunk_beg.has_value());
EXPECT_TRUE(chunk_beg->data.is_beginning);
EXPECT_FALSE(chunk_beg->data.is_end);
absl::optional<SendQueue::DataToSend> chunk_mid =
buf_.Produce(kNow, /*max_size=*/20);
ASSERT_TRUE(chunk_mid.has_value());
EXPECT_FALSE(chunk_mid->data.is_beginning);
EXPECT_FALSE(chunk_mid->data.is_end);
absl::optional<SendQueue::DataToSend> chunk_end =
buf_.Produce(kNow, /*max_size=*/20);
ASSERT_TRUE(chunk_end.has_value());
EXPECT_FALSE(chunk_end->data.is_beginning);
EXPECT_TRUE(chunk_end->data.is_end);
EXPECT_FALSE(buf_.Produce(kNow, kOneFragmentPacketSize).has_value());
}
TEST_F(RRSendQueueTest, GetChunksFromTwoMessages) {
std::vector<uint8_t> payload(60);
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
buf_.Add(kNow, DcSctpMessage(StreamID(3), PPID(54), payload));
absl::optional<SendQueue::DataToSend> chunk_one =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_one.has_value());
EXPECT_EQ(chunk_one->data.stream_id, kStreamID);
EXPECT_EQ(chunk_one->data.ppid, kPPID);
EXPECT_TRUE(chunk_one->data.is_beginning);
EXPECT_TRUE(chunk_one->data.is_end);
absl::optional<SendQueue::DataToSend> chunk_two =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_two.has_value());
EXPECT_EQ(chunk_two->data.stream_id, StreamID(3));
EXPECT_EQ(chunk_two->data.ppid, PPID(54));
EXPECT_TRUE(chunk_two->data.is_beginning);
EXPECT_TRUE(chunk_two->data.is_end);
}
TEST_F(RRSendQueueTest, BufferBecomesFullAndEmptied) {
std::vector<uint8_t> payload(600);
EXPECT_FALSE(buf_.IsFull());
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
EXPECT_FALSE(buf_.IsFull());
buf_.Add(kNow, DcSctpMessage(StreamID(3), PPID(54), payload));
EXPECT_TRUE(buf_.IsFull());
// However, it's still possible to add messages. It's a soft limit, and it
// might be necessary to forcefully add messages due to e.g. external
// fragmentation.
buf_.Add(kNow, DcSctpMessage(StreamID(5), PPID(55), payload));
EXPECT_TRUE(buf_.IsFull());
absl::optional<SendQueue::DataToSend> chunk_one = buf_.Produce(kNow, 1000);
ASSERT_TRUE(chunk_one.has_value());
EXPECT_EQ(chunk_one->data.stream_id, kStreamID);
EXPECT_EQ(chunk_one->data.ppid, kPPID);
EXPECT_TRUE(buf_.IsFull());
absl::optional<SendQueue::DataToSend> chunk_two = buf_.Produce(kNow, 1000);
ASSERT_TRUE(chunk_two.has_value());
EXPECT_EQ(chunk_two->data.stream_id, StreamID(3));
EXPECT_EQ(chunk_two->data.ppid, PPID(54));
EXPECT_FALSE(buf_.IsFull());
EXPECT_FALSE(buf_.IsEmpty());
absl::optional<SendQueue::DataToSend> chunk_three = buf_.Produce(kNow, 1000);
ASSERT_TRUE(chunk_three.has_value());
EXPECT_EQ(chunk_three->data.stream_id, StreamID(5));
EXPECT_EQ(chunk_three->data.ppid, PPID(55));
EXPECT_FALSE(buf_.IsFull());
EXPECT_TRUE(buf_.IsEmpty());
}
TEST_F(RRSendQueueTest, WillNotSendTooSmallPacket) {
std::vector<uint8_t> payload(RRSendQueue::kMinimumFragmentedPayload + 1);
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
// Wouldn't fit enough payload (wouldn't want to fragment)
EXPECT_FALSE(
buf_.Produce(kNow,
/*max_size=*/RRSendQueue::kMinimumFragmentedPayload - 1)
.has_value());
// Minimum fragment
absl::optional<SendQueue::DataToSend> chunk_one =
buf_.Produce(kNow,
/*max_size=*/RRSendQueue::kMinimumFragmentedPayload);
ASSERT_TRUE(chunk_one.has_value());
EXPECT_EQ(chunk_one->data.stream_id, kStreamID);
EXPECT_EQ(chunk_one->data.ppid, kPPID);
// There is only one byte remaining - it can be fetched as it doesn't require
// additional fragmentation.
absl::optional<SendQueue::DataToSend> chunk_two =
buf_.Produce(kNow, /*max_size=*/1);
ASSERT_TRUE(chunk_two.has_value());
EXPECT_EQ(chunk_two->data.stream_id, kStreamID);
EXPECT_EQ(chunk_two->data.ppid, kPPID);
EXPECT_TRUE(buf_.IsEmpty());
}
TEST_F(RRSendQueueTest, DefaultsToOrderedSend) {
std::vector<uint8_t> payload(20);
// Default is ordered
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
absl::optional<SendQueue::DataToSend> chunk_one =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_one.has_value());
EXPECT_FALSE(chunk_one->data.is_unordered);
// Explicitly unordered.
SendOptions opts;
opts.unordered = IsUnordered(true);
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload), opts);
absl::optional<SendQueue::DataToSend> chunk_two =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_two.has_value());
EXPECT_TRUE(chunk_two->data.is_unordered);
}
TEST_F(RRSendQueueTest, ProduceWithLifetimeExpiry) {
std::vector<uint8_t> payload(20);
// Default is no expiry
TimeMs now = kNow;
buf_.Add(now, DcSctpMessage(kStreamID, kPPID, payload));
now += DurationMs(1000000);
ASSERT_TRUE(buf_.Produce(now, kOneFragmentPacketSize));
SendOptions expires_2_seconds;
expires_2_seconds.lifetime = DurationMs(2000);
// Add and consume within lifetime
buf_.Add(now, DcSctpMessage(kStreamID, kPPID, payload), expires_2_seconds);
now += DurationMs(2000);
ASSERT_TRUE(buf_.Produce(now, kOneFragmentPacketSize));
// Add and consume just outside lifetime
buf_.Add(now, DcSctpMessage(kStreamID, kPPID, payload), expires_2_seconds);
now += DurationMs(2001);
ASSERT_FALSE(buf_.Produce(now, kOneFragmentPacketSize));
// A long time after expiry
buf_.Add(now, DcSctpMessage(kStreamID, kPPID, payload), expires_2_seconds);
now += DurationMs(1000000);
ASSERT_FALSE(buf_.Produce(now, kOneFragmentPacketSize));
// Expire one message, but produce the second that is not expired.
buf_.Add(now, DcSctpMessage(kStreamID, kPPID, payload), expires_2_seconds);
SendOptions expires_4_seconds;
expires_4_seconds.lifetime = DurationMs(4000);
buf_.Add(now, DcSctpMessage(kStreamID, kPPID, payload), expires_4_seconds);
now += DurationMs(2001);
ASSERT_TRUE(buf_.Produce(now, kOneFragmentPacketSize));
ASSERT_FALSE(buf_.Produce(now, kOneFragmentPacketSize));
}
TEST_F(RRSendQueueTest, DiscardPartialPackets) {
std::vector<uint8_t> payload(120);
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
buf_.Add(kNow, DcSctpMessage(StreamID(2), PPID(54), payload));
absl::optional<SendQueue::DataToSend> chunk_one =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_one.has_value());
EXPECT_FALSE(chunk_one->data.is_end);
EXPECT_EQ(chunk_one->data.stream_id, kStreamID);
buf_.Discard(IsUnordered(false), chunk_one->data.stream_id,
chunk_one->data.message_id);
absl::optional<SendQueue::DataToSend> chunk_two =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_two.has_value());
EXPECT_FALSE(chunk_two->data.is_end);
EXPECT_EQ(chunk_two->data.stream_id, StreamID(2));
absl::optional<SendQueue::DataToSend> chunk_three =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_three.has_value());
EXPECT_TRUE(chunk_three->data.is_end);
EXPECT_EQ(chunk_three->data.stream_id, StreamID(2));
ASSERT_FALSE(buf_.Produce(kNow, kOneFragmentPacketSize));
// Calling it again shouldn't cause issues.
buf_.Discard(IsUnordered(false), chunk_one->data.stream_id,
chunk_one->data.message_id);
ASSERT_FALSE(buf_.Produce(kNow, kOneFragmentPacketSize));
}
TEST_F(RRSendQueueTest, PrepareResetStreamsDiscardsStream) {
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, {1, 2, 3}));
buf_.Add(kNow, DcSctpMessage(StreamID(2), PPID(54), {1, 2, 3, 4, 5}));
EXPECT_EQ(buf_.total_buffered_amount(), 8u);
buf_.PrepareResetStreams(std::vector<StreamID>({StreamID(1)}));
EXPECT_EQ(buf_.total_buffered_amount(), 5u);
buf_.CommitResetStreams();
buf_.PrepareResetStreams(std::vector<StreamID>({StreamID(2)}));
EXPECT_EQ(buf_.total_buffered_amount(), 0u);
}
TEST_F(RRSendQueueTest, PrepareResetStreamsNotPartialPackets) {
std::vector<uint8_t> payload(120);
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
absl::optional<SendQueue::DataToSend> chunk_one = buf_.Produce(kNow, 50);
ASSERT_TRUE(chunk_one.has_value());
EXPECT_EQ(chunk_one->data.stream_id, kStreamID);
EXPECT_EQ(buf_.total_buffered_amount(), 2 * payload.size() - 50);
StreamID stream_ids[] = {StreamID(1)};
buf_.PrepareResetStreams(stream_ids);
EXPECT_EQ(buf_.total_buffered_amount(), payload.size() - 50);
}
TEST_F(RRSendQueueTest, EnqueuedItemsArePausedDuringStreamReset) {
std::vector<uint8_t> payload(50);
buf_.PrepareResetStreams(std::vector<StreamID>({StreamID(1)}));
EXPECT_EQ(buf_.total_buffered_amount(), 0u);
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
EXPECT_EQ(buf_.total_buffered_amount(), payload.size());
EXPECT_FALSE(buf_.Produce(kNow, kOneFragmentPacketSize).has_value());
buf_.CommitResetStreams();
EXPECT_EQ(buf_.total_buffered_amount(), payload.size());
absl::optional<SendQueue::DataToSend> chunk_one = buf_.Produce(kNow, 50);
ASSERT_TRUE(chunk_one.has_value());
EXPECT_EQ(chunk_one->data.stream_id, kStreamID);
EXPECT_EQ(buf_.total_buffered_amount(), 0u);
}
TEST_F(RRSendQueueTest, CommittingResetsSSN) {
std::vector<uint8_t> payload(50);
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
absl::optional<SendQueue::DataToSend> chunk_one =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_one.has_value());
EXPECT_EQ(chunk_one->data.ssn, SSN(0));
absl::optional<SendQueue::DataToSend> chunk_two =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_two.has_value());
EXPECT_EQ(chunk_two->data.ssn, SSN(1));
StreamID stream_ids[] = {StreamID(1)};
buf_.PrepareResetStreams(stream_ids);
// Buffered
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
EXPECT_TRUE(buf_.CanResetStreams());
buf_.CommitResetStreams();
absl::optional<SendQueue::DataToSend> chunk_three =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_three.has_value());
EXPECT_EQ(chunk_three->data.ssn, SSN(0));
}
TEST_F(RRSendQueueTest, CommittingResetsSSNForPausedStreamsOnly) {
std::vector<uint8_t> payload(50);
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, payload));
buf_.Add(kNow, DcSctpMessage(StreamID(3), kPPID, payload));
absl::optional<SendQueue::DataToSend> chunk_one =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_one.has_value());
EXPECT_EQ(chunk_one->data.stream_id, StreamID(1));
EXPECT_EQ(chunk_one->data.ssn, SSN(0));
absl::optional<SendQueue::DataToSend> chunk_two =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_two.has_value());
EXPECT_EQ(chunk_two->data.stream_id, StreamID(3));
EXPECT_EQ(chunk_two->data.ssn, SSN(0));
StreamID stream_ids[] = {StreamID(3)};
buf_.PrepareResetStreams(stream_ids);
// Send two more messages - SID 3 will buffer, SID 1 will send.
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, payload));
buf_.Add(kNow, DcSctpMessage(StreamID(3), kPPID, payload));
EXPECT_TRUE(buf_.CanResetStreams());
buf_.CommitResetStreams();
absl::optional<SendQueue::DataToSend> chunk_three =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_three.has_value());
EXPECT_EQ(chunk_three->data.stream_id, StreamID(1));
EXPECT_EQ(chunk_three->data.ssn, SSN(1));
absl::optional<SendQueue::DataToSend> chunk_four =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_four.has_value());
EXPECT_EQ(chunk_four->data.stream_id, StreamID(3));
EXPECT_EQ(chunk_four->data.ssn, SSN(0));
}
TEST_F(RRSendQueueTest, RollBackResumesSSN) {
std::vector<uint8_t> payload(50);
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
absl::optional<SendQueue::DataToSend> chunk_one =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_one.has_value());
EXPECT_EQ(chunk_one->data.ssn, SSN(0));
absl::optional<SendQueue::DataToSend> chunk_two =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_two.has_value());
EXPECT_EQ(chunk_two->data.ssn, SSN(1));
buf_.PrepareResetStreams(std::vector<StreamID>({StreamID(1)}));
// Buffered
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
EXPECT_TRUE(buf_.CanResetStreams());
buf_.RollbackResetStreams();
absl::optional<SendQueue::DataToSend> chunk_three =
buf_.Produce(kNow, kOneFragmentPacketSize);
ASSERT_TRUE(chunk_three.has_value());
EXPECT_EQ(chunk_three->data.ssn, SSN(2));
}
TEST_F(RRSendQueueTest, ReturnsFragmentsForOneMessageBeforeMovingToNext) {
std::vector<uint8_t> payload(200);
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, payload));
buf_.Add(kNow, DcSctpMessage(StreamID(2), kPPID, payload));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk1,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk1.data.stream_id, StreamID(1));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk2,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk2.data.stream_id, StreamID(1));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk3,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk3.data.stream_id, StreamID(2));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk4,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk4.data.stream_id, StreamID(2));
}
TEST_F(RRSendQueueTest, ReturnsAlsoSmallFragmentsBeforeMovingToNext) {
std::vector<uint8_t> payload(kTwoFragmentPacketSize);
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, payload));
buf_.Add(kNow, DcSctpMessage(StreamID(2), kPPID, payload));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk1,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk1.data.stream_id, StreamID(1));
EXPECT_THAT(chunk1.data.payload, SizeIs(kOneFragmentPacketSize));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk2,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk2.data.stream_id, StreamID(1));
EXPECT_THAT(chunk2.data.payload,
SizeIs(kTwoFragmentPacketSize - kOneFragmentPacketSize));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk3,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk3.data.stream_id, StreamID(2));
EXPECT_THAT(chunk3.data.payload, SizeIs(kOneFragmentPacketSize));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk4,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk4.data.stream_id, StreamID(2));
EXPECT_THAT(chunk4.data.payload,
SizeIs(kTwoFragmentPacketSize - kOneFragmentPacketSize));
}
TEST_F(RRSendQueueTest, WillCycleInRoundRobinFashionBetweenStreams) {
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, std::vector<uint8_t>(1)));
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, std::vector<uint8_t>(2)));
buf_.Add(kNow, DcSctpMessage(StreamID(2), kPPID, std::vector<uint8_t>(3)));
buf_.Add(kNow, DcSctpMessage(StreamID(2), kPPID, std::vector<uint8_t>(4)));
buf_.Add(kNow, DcSctpMessage(StreamID(3), kPPID, std::vector<uint8_t>(5)));
buf_.Add(kNow, DcSctpMessage(StreamID(3), kPPID, std::vector<uint8_t>(6)));
buf_.Add(kNow, DcSctpMessage(StreamID(4), kPPID, std::vector<uint8_t>(7)));
buf_.Add(kNow, DcSctpMessage(StreamID(4), kPPID, std::vector<uint8_t>(8)));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk1,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk1.data.stream_id, StreamID(1));
EXPECT_THAT(chunk1.data.payload, SizeIs(1));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk2,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk2.data.stream_id, StreamID(2));
EXPECT_THAT(chunk2.data.payload, SizeIs(3));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk3,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk3.data.stream_id, StreamID(3));
EXPECT_THAT(chunk3.data.payload, SizeIs(5));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk4,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk4.data.stream_id, StreamID(4));
EXPECT_THAT(chunk4.data.payload, SizeIs(7));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk5,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk5.data.stream_id, StreamID(1));
EXPECT_THAT(chunk5.data.payload, SizeIs(2));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk6,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk6.data.stream_id, StreamID(2));
EXPECT_THAT(chunk6.data.payload, SizeIs(4));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk7,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk7.data.stream_id, StreamID(3));
EXPECT_THAT(chunk7.data.payload, SizeIs(6));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk8,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk8.data.stream_id, StreamID(4));
EXPECT_THAT(chunk8.data.payload, SizeIs(8));
}
TEST_F(RRSendQueueTest, DoesntTriggerOnBufferedAmountLowWhenSetToZero) {
EXPECT_CALL(on_buffered_amount_low_, Call).Times(0);
buf_.SetBufferedAmountLowThreshold(StreamID(1), 0u);
}
TEST_F(RRSendQueueTest, TriggersOnBufferedAmountAtZeroLowWhenSent) {
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, std::vector<uint8_t>(1)));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 1u);
EXPECT_CALL(on_buffered_amount_low_, Call(StreamID(1)));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk1,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk1.data.stream_id, StreamID(1));
EXPECT_THAT(chunk1.data.payload, SizeIs(1));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 0u);
}
TEST_F(RRSendQueueTest, WillRetriggerOnBufferedAmountLowIfAddingMore) {
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, std::vector<uint8_t>(1)));
EXPECT_CALL(on_buffered_amount_low_, Call(StreamID(1)));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk1,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk1.data.stream_id, StreamID(1));
EXPECT_THAT(chunk1.data.payload, SizeIs(1));
EXPECT_CALL(on_buffered_amount_low_, Call).Times(0);
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, std::vector<uint8_t>(1)));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 1u);
// Should now trigger again, as buffer_amount went above the threshold.
EXPECT_CALL(on_buffered_amount_low_, Call(StreamID(1)));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk2,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk2.data.stream_id, StreamID(1));
EXPECT_THAT(chunk2.data.payload, SizeIs(1));
}
TEST_F(RRSendQueueTest, OnlyTriggersWhenTransitioningFromAboveToBelowOrEqual) {
buf_.SetBufferedAmountLowThreshold(StreamID(1), 1000);
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, std::vector<uint8_t>(10)));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 10u);
EXPECT_CALL(on_buffered_amount_low_, Call).Times(0);
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk1,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk1.data.stream_id, StreamID(1));
EXPECT_THAT(chunk1.data.payload, SizeIs(10));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 0u);
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, std::vector<uint8_t>(20)));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 20u);
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk2,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk2.data.stream_id, StreamID(1));
EXPECT_THAT(chunk2.data.payload, SizeIs(20));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 0u);
}
TEST_F(RRSendQueueTest, WillTriggerOnBufferedAmountLowSetAboveZero) {
EXPECT_CALL(on_buffered_amount_low_, Call).Times(0);
buf_.SetBufferedAmountLowThreshold(StreamID(1), 700);
std::vector<uint8_t> payload(1000);
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, payload));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk1,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk1.data.stream_id, StreamID(1));
EXPECT_THAT(chunk1.data.payload, SizeIs(kOneFragmentPacketSize));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 900u);
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk2,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk2.data.stream_id, StreamID(1));
EXPECT_THAT(chunk2.data.payload, SizeIs(kOneFragmentPacketSize));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 800u);
EXPECT_CALL(on_buffered_amount_low_, Call(StreamID(1)));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk3,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk3.data.stream_id, StreamID(1));
EXPECT_THAT(chunk3.data.payload, SizeIs(kOneFragmentPacketSize));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 700u);
// Doesn't trigger when reducing even further.
EXPECT_CALL(on_buffered_amount_low_, Call).Times(0);
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk4,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk3.data.stream_id, StreamID(1));
EXPECT_THAT(chunk3.data.payload, SizeIs(kOneFragmentPacketSize));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 600u);
}
TEST_F(RRSendQueueTest, WillRetriggerOnBufferedAmountLowSetAboveZero) {
EXPECT_CALL(on_buffered_amount_low_, Call).Times(0);
buf_.SetBufferedAmountLowThreshold(StreamID(1), 700);
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, std::vector<uint8_t>(1000)));
EXPECT_CALL(on_buffered_amount_low_, Call(StreamID(1)));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk1,
buf_.Produce(kNow, 400));
EXPECT_EQ(chunk1.data.stream_id, StreamID(1));
EXPECT_THAT(chunk1.data.payload, SizeIs(400));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 600u);
EXPECT_CALL(on_buffered_amount_low_, Call).Times(0);
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, std::vector<uint8_t>(200)));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 800u);
// Will trigger again, as it went above the limit.
EXPECT_CALL(on_buffered_amount_low_, Call(StreamID(1)));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk2,
buf_.Produce(kNow, 200));
EXPECT_EQ(chunk2.data.stream_id, StreamID(1));
EXPECT_THAT(chunk2.data.payload, SizeIs(200));
EXPECT_EQ(buf_.buffered_amount(StreamID(1)), 600u);
}
TEST_F(RRSendQueueTest, TriggersOnBufferedAmountLowOnThresholdChanged) {
EXPECT_CALL(on_buffered_amount_low_, Call).Times(0);
buf_.Add(kNow, DcSctpMessage(StreamID(1), kPPID, std::vector<uint8_t>(100)));
// Modifying the threshold, still under buffered_amount, should not trigger.
buf_.SetBufferedAmountLowThreshold(StreamID(1), 50);
buf_.SetBufferedAmountLowThreshold(StreamID(1), 99);
// When the threshold reaches buffered_amount, it will trigger.
EXPECT_CALL(on_buffered_amount_low_, Call(StreamID(1)));
buf_.SetBufferedAmountLowThreshold(StreamID(1), 100);
// But not when it's set low again.
EXPECT_CALL(on_buffered_amount_low_, Call).Times(0);
buf_.SetBufferedAmountLowThreshold(StreamID(1), 50);
// But it will trigger when it overshoots.
EXPECT_CALL(on_buffered_amount_low_, Call(StreamID(1)));
buf_.SetBufferedAmountLowThreshold(StreamID(1), 150);
// But not when it's set low again.
EXPECT_CALL(on_buffered_amount_low_, Call).Times(0);
buf_.SetBufferedAmountLowThreshold(StreamID(1), 0);
}
TEST_F(RRSendQueueTest,
OnTotalBufferedAmountLowDoesNotTriggerOnBufferFillingUp) {
EXPECT_CALL(on_total_buffered_amount_low_, Call).Times(0);
std::vector<uint8_t> payload(kBufferedAmountLowThreshold - 1);
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
EXPECT_EQ(buf_.total_buffered_amount(), payload.size());
// Will not trigger if going above but never below.
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID,
std::vector<uint8_t>(kOneFragmentPacketSize)));
}
TEST_F(RRSendQueueTest, TriggersOnTotalBufferedAmountLowWhenCrossing) {
EXPECT_CALL(on_total_buffered_amount_low_, Call).Times(0);
std::vector<uint8_t> payload(kBufferedAmountLowThreshold);
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, payload));
EXPECT_EQ(buf_.total_buffered_amount(), payload.size());
// Reaches it.
buf_.Add(kNow, DcSctpMessage(kStreamID, kPPID, std::vector<uint8_t>(1)));
// Drain it a bit - will trigger.
EXPECT_CALL(on_total_buffered_amount_low_, Call).Times(1);
absl::optional<SendQueue::DataToSend> chunk_two =
buf_.Produce(kNow, kOneFragmentPacketSize);
}
TEST_F(RRSendQueueTest, WillStayInAStreamAsLongAsThatMessageIsSending) {
buf_.Add(kNow, DcSctpMessage(StreamID(5), kPPID, std::vector<uint8_t>(1)));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk1,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk1.data.stream_id, StreamID(5));
EXPECT_THAT(chunk1.data.payload, SizeIs(1));
// Next, it should pick a different stream.
buf_.Add(kNow,
DcSctpMessage(StreamID(1), kPPID,
std::vector<uint8_t>(kOneFragmentPacketSize * 2)));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk2,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk2.data.stream_id, StreamID(1));
EXPECT_THAT(chunk2.data.payload, SizeIs(kOneFragmentPacketSize));
// It should still stay on the Stream1 now, even if might be tempted to switch
// to this stream, as it's the stream following 5.
buf_.Add(kNow, DcSctpMessage(StreamID(6), kPPID, std::vector<uint8_t>(1)));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk3,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk3.data.stream_id, StreamID(1));
EXPECT_THAT(chunk3.data.payload, SizeIs(kOneFragmentPacketSize));
// After stream id 1 is complete, it's time to do stream 6.
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk4,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk4.data.stream_id, StreamID(6));
EXPECT_THAT(chunk4.data.payload, SizeIs(1));
EXPECT_FALSE(buf_.Produce(kNow, kOneFragmentPacketSize).has_value());
}
TEST_F(RRSendQueueTest, WillStayInStreamWhenOnlySmallFragmentRemaining) {
buf_.Add(kNow,
DcSctpMessage(StreamID(5), kPPID,
std::vector<uint8_t>(kOneFragmentPacketSize * 2)));
buf_.Add(kNow, DcSctpMessage(StreamID(6), kPPID, std::vector<uint8_t>(1)));
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk1,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk1.data.stream_id, StreamID(5));
EXPECT_THAT(chunk1.data.payload, SizeIs(kOneFragmentPacketSize));
// Now assume that there will be a lot of previous chunks that need to be
// retransmitted, which fills up the next packet and there is little space
// left in the packet for new chunks. What it should NOT do right now is to
// try to send a message from StreamID 6. And it should not try to send a very
// small fragment from StreamID 5 either. So just skip this one.
EXPECT_FALSE(buf_.Produce(kNow, 8).has_value());
// When the next produce request comes with a large buffer to fill, continue
// sending from StreamID 5.
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk2,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk2.data.stream_id, StreamID(5));
EXPECT_THAT(chunk2.data.payload, SizeIs(kOneFragmentPacketSize));
// Lastly, produce a message on StreamID 6.
ASSERT_HAS_VALUE_AND_ASSIGN(SendQueue::DataToSend chunk3,
buf_.Produce(kNow, kOneFragmentPacketSize));
EXPECT_EQ(chunk3.data.stream_id, StreamID(6));
EXPECT_THAT(chunk3.data.payload, SizeIs(1));
EXPECT_FALSE(buf_.Produce(kNow, 8).has_value());
}
} // namespace
} // namespace dcsctp