net/dcsctp/rx/data_tracker.cc - src - Git at Google

 /*
  *  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/rx/data_tracker.h"

 #include <algorithm>
 #include <cstdint>
 #include <iterator>
 #include <set>
 #include <string>
 #include <utility>
 #include <vector>

 #include "absl/algorithm/container.h"
 #include "absl/strings/string_view.h"
 #include "absl/types/optional.h"
 #include "net/dcsctp/common/sequence_numbers.h"
 #include "net/dcsctp/packet/chunk/sack_chunk.h"
 #include "net/dcsctp/timer/timer.h"
 #include "rtc_base/logging.h"
 #include "rtc_base/strings/string_builder.h"

 namespace dcsctp {

 constexpr size_t DataTracker::kMaxDuplicateTsnReported;
 constexpr size_t DataTracker::kMaxGapAckBlocksReported;

 bool DataTracker::AdditionalTsnBlocks::Add(UnwrappedTSN tsn) {
   // Find any block to expand. It will look for any block that includes (also
   // when expanded) the provided `tsn`. It will return the block that is greater
   // than, or equal to `tsn`.
   auto it = absl::c_lower_bound(
       blocks_, tsn, [&](const TsnRange& elem, const UnwrappedTSN& t) {
         return elem.last.next_value() < t;
       });

   if (it == blocks_.end()) {
     // No matching block found. There is no greater than, or equal block - which
     // means that this TSN is greater than any block. It can then be inserted at
     // the end.
     blocks_.emplace_back(tsn, tsn);
     return true;
   }

   if (tsn >= it->first && tsn <= it->last) {
     // It's already in this block.
     return false;
   }

   if (it->last.next_value() == tsn) {
     // This block can be expanded to the right, or merged with the next.
     auto next_it = it + 1;
     if (next_it != blocks_.end() && tsn.next_value() == next_it->first) {
       // Expanding it would make it adjacent to next block - merge those.
       it->last = next_it->last;
       blocks_.erase(next_it);
       return true;
     }

     // Expand to the right
     it->last = tsn;
     return true;
   }

   if (it->first == tsn.next_value()) {
     // This block can be expanded to the left. Merging to the left would've been
     // covered by the above "merge to the right". Both blocks (expand a
     // right-most block to the left and expand a left-most block to the right)
     // would match, but the left-most would be returned by std::lower_bound.
     RTC_DCHECK(it == blocks_.begin() || (it - 1)->last.next_value() != tsn);

     // Expand to the left.
     it->first = tsn;
     return true;
   }

   // Need to create a new block in the middle.
   blocks_.emplace(it, tsn, tsn);
   return true;
 }

 void DataTracker::AdditionalTsnBlocks::EraseTo(UnwrappedTSN tsn) {
   // Find the block that is greater than or equals `tsn`.
   auto it = absl::c_lower_bound(
       blocks_, tsn, [&](const TsnRange& elem, const UnwrappedTSN& t) {
         return elem.last < t;
       });

   // The block that is found is greater or equal (or possibly ::end, when no
   // block is greater or equal). All blocks before this block can be safely
   // removed. the TSN might be within this block, so possibly truncate it.
   bool tsn_is_within_block = it != blocks_.end() && tsn >= it->first;
   blocks_.erase(blocks_.begin(), it);

   if (tsn_is_within_block) {
     blocks_.front().first = tsn.next_value();
   }
 }

 void DataTracker::AdditionalTsnBlocks::PopFront() {
   RTC_DCHECK(!blocks_.empty());
   blocks_.erase(blocks_.begin());
 }

 bool DataTracker::IsTSNValid(TSN tsn) const {
   UnwrappedTSN unwrapped_tsn = tsn_unwrapper_.PeekUnwrap(tsn);

   // Note that this method doesn't return `false` for old DATA chunks, as those
   // are actually valid, and receiving those may affect the generated SACK
   // response (by setting "duplicate TSNs").

   uint32_t difference =
       UnwrappedTSN::Difference(unwrapped_tsn, last_cumulative_acked_tsn_);
   if (difference > kMaxAcceptedOutstandingFragments) {
     return false;
   }
   return true;
 }

 void DataTracker::Observe(TSN tsn,
                           AnyDataChunk::ImmediateAckFlag immediate_ack) {
   UnwrappedTSN unwrapped_tsn = tsn_unwrapper_.Unwrap(tsn);

   // IsTSNValid must be called prior to calling this method.
   RTC_DCHECK(
       UnwrappedTSN::Difference(unwrapped_tsn, last_cumulative_acked_tsn_) <=
       kMaxAcceptedOutstandingFragments);

   // Old chunk already seen before?
   if (unwrapped_tsn <= last_cumulative_acked_tsn_) {
     if (duplicate_tsns_.size() < kMaxDuplicateTsnReported) {
       duplicate_tsns_.insert(unwrapped_tsn.Wrap());
     }
     // https://datatracker.ietf.org/doc/html/rfc4960#section-6.2
     // "When a packet arrives with duplicate DATA chunk(s) and with no new DATA
     // chunk(s), the endpoint MUST immediately send a SACK with no delay. If a
     // packet arrives with duplicate DATA chunk(s) bundled with new DATA chunks,
     // the endpoint MAY immediately send a SACK."
     UpdateAckState(AckState::kImmediate, "duplicate data");
   } else {
     if (unwrapped_tsn == last_cumulative_acked_tsn_.next_value()) {
       last_cumulative_acked_tsn_ = unwrapped_tsn;
       // The cumulative acked tsn may be moved even further, if a gap was
       // filled.
       if (!additional_tsn_blocks_.empty() &&
           additional_tsn_blocks_.front().first ==
               last_cumulative_acked_tsn_.next_value()) {
         last_cumulative_acked_tsn_ = additional_tsn_blocks_.front().last;
         additional_tsn_blocks_.PopFront();
       }
     } else {
       bool inserted = additional_tsn_blocks_.Add(unwrapped_tsn);
       if (!inserted) {
         // Already seen before.
         if (duplicate_tsns_.size() < kMaxDuplicateTsnReported) {
           duplicate_tsns_.insert(unwrapped_tsn.Wrap());
         }
         // https://datatracker.ietf.org/doc/html/rfc4960#section-6.2
         // "When a packet arrives with duplicate DATA chunk(s) and with no new
         // DATA chunk(s), the endpoint MUST immediately send a SACK with no
         // delay. If a packet arrives with duplicate DATA chunk(s) bundled with
         // new DATA chunks, the endpoint MAY immediately send a SACK."
         // No need to do this. SACKs are sent immediately on packet loss below.
       }
     }
   }

   // https://tools.ietf.org/html/rfc4960#section-6.7
   // "Upon the reception of a new DATA chunk, an endpoint shall examine the
   // continuity of the TSNs received.  If the endpoint detects a gap in
   // the received DATA chunk sequence, it SHOULD send a SACK with Gap Ack
   // Blocks immediately.  The data receiver continues sending a SACK after
   // receipt of each SCTP packet that doesn't fill the gap."
   if (!additional_tsn_blocks_.empty()) {
     UpdateAckState(AckState::kImmediate, "packet loss");
   }

   // https://tools.ietf.org/html/rfc7053#section-5.2
   // "Upon receipt of an SCTP packet containing a DATA chunk with the I
   // bit set, the receiver SHOULD NOT delay the sending of the corresponding
   // SACK chunk, i.e., the receiver SHOULD immediately respond with the
   // corresponding SACK chunk."
   if (*immediate_ack) {
     UpdateAckState(AckState::kImmediate, "immediate-ack bit set");
   }

   if (!seen_packet_) {
     // https://tools.ietf.org/html/rfc4960#section-5.1
     // "After the reception of the first DATA chunk in an association the
     // endpoint MUST immediately respond with a SACK to acknowledge the DATA
     // chunk."
     seen_packet_ = true;
     UpdateAckState(AckState::kImmediate, "first DATA chunk");
   }

   // https://tools.ietf.org/html/rfc4960#section-6.2
   // "Specifically, an acknowledgement SHOULD be generated for at least
   // every second packet (not every second DATA chunk) received, and SHOULD be
   // generated within 200 ms of the arrival of any unacknowledged DATA chunk."
   if (ack_state_ == AckState::kIdle) {
     UpdateAckState(AckState::kBecomingDelayed, "received DATA when idle");
   } else if (ack_state_ == AckState::kDelayed) {
     UpdateAckState(AckState::kImmediate, "received DATA when already delayed");
   }
 }

 void DataTracker::HandleForwardTsn(TSN new_cumulative_ack) {
   // ForwardTSN is sent to make the receiver (this socket) "forget" about partly
   // received (or not received at all) data, up until `new_cumulative_ack`.

   UnwrappedTSN unwrapped_tsn = tsn_unwrapper_.Unwrap(new_cumulative_ack);
   UnwrappedTSN prev_last_cum_ack_tsn = last_cumulative_acked_tsn_;

   // Old chunk already seen before?
   if (unwrapped_tsn <= last_cumulative_acked_tsn_) {
     // https://tools.ietf.org/html/rfc3758#section-3.6
     // "Note, if the "New Cumulative TSN" value carried in the arrived
     // FORWARD TSN chunk is found to be behind or at the current cumulative TSN
     // point, the data receiver MUST treat this FORWARD TSN as out-of-date and
     // MUST NOT update its Cumulative TSN.  The receiver SHOULD send a SACK to
     // its peer (the sender of the FORWARD TSN) since such a duplicate may
     // indicate the previous SACK was lost in the network."
     UpdateAckState(AckState::kImmediate,
                    "FORWARD_TSN new_cumulative_tsn was behind");
     return;
   }

   // https://tools.ietf.org/html/rfc3758#section-3.6
   // "When a FORWARD TSN chunk arrives, the data receiver MUST first update
   // its cumulative TSN point to the value carried in the FORWARD TSN chunk, and
   // then MUST further advance its cumulative TSN point locally if possible, as
   // shown by the following example..."

   // The `new_cumulative_ack` will become the current
   // `last_cumulative_acked_tsn_`, and if there have been prior "gaps" that are
   // now overlapping with the new value, remove them.
   last_cumulative_acked_tsn_ = unwrapped_tsn;
   additional_tsn_blocks_.EraseTo(unwrapped_tsn);

   // See if the `last_cumulative_acked_tsn_` can be moved even further:
   if (!additional_tsn_blocks_.empty() &&
       additional_tsn_blocks_.front().first ==
           last_cumulative_acked_tsn_.next_value()) {
     last_cumulative_acked_tsn_ = additional_tsn_blocks_.front().last;
     additional_tsn_blocks_.PopFront();
   }

   RTC_DLOG(LS_VERBOSE) << log_prefix_ << "FORWARD_TSN, cum_ack_tsn="
                        << *prev_last_cum_ack_tsn.Wrap() << "->"
                        << *new_cumulative_ack << "->"
                        << *last_cumulative_acked_tsn_.Wrap();

   // https://tools.ietf.org/html/rfc3758#section-3.6
   // "Any time a FORWARD TSN chunk arrives, for the purposes of sending a
   // SACK, the receiver MUST follow the same rules as if a DATA chunk had been
   // received (i.e., follow the delayed sack rules specified in ..."
   if (ack_state_ == AckState::kIdle) {
     UpdateAckState(AckState::kBecomingDelayed,
                    "received FORWARD_TSN when idle");
   } else if (ack_state_ == AckState::kDelayed) {
     UpdateAckState(AckState::kImmediate,
                    "received FORWARD_TSN when already delayed");
   }
 }

 SackChunk DataTracker::CreateSelectiveAck(size_t a_rwnd) {
   // Note that in SCTP, the receiver side is allowed to discard received data
   // and signal that to the sender, but only chunks that have previously been
   // reported in the gap-ack-blocks. However, this implementation will never do
   // that. So this SACK produced is more like a NR-SACK as explained in
   // https://ieeexplore.ieee.org/document/4697037 and which there is an RFC
   // draft at https://tools.ietf.org/html/draft-tuexen-tsvwg-sctp-multipath-17.
   std::set<TSN> duplicate_tsns;
   duplicate_tsns_.swap(duplicate_tsns);

   return SackChunk(last_cumulative_acked_tsn_.Wrap(), a_rwnd,
                    CreateGapAckBlocks(), std::move(duplicate_tsns));
 }

 std::vector<SackChunk::GapAckBlock> DataTracker::CreateGapAckBlocks() const {
   const auto& blocks = additional_tsn_blocks_.blocks();
   std::vector<SackChunk::GapAckBlock> gap_ack_blocks;
   gap_ack_blocks.reserve(std::min(blocks.size(), kMaxGapAckBlocksReported));
   for (size_t i = 0; i < blocks.size() && i < kMaxGapAckBlocksReported; ++i) {
     auto start_diff =
         UnwrappedTSN::Difference(blocks[i].first, last_cumulative_acked_tsn_);
     auto end_diff =
         UnwrappedTSN::Difference(blocks[i].last, last_cumulative_acked_tsn_);
     gap_ack_blocks.emplace_back(static_cast<uint16_t>(start_diff),
                                 static_cast<uint16_t>(end_diff));
   }

   return gap_ack_blocks;
 }

 bool DataTracker::ShouldSendAck(bool also_if_delayed) {
   if (ack_state_ == AckState::kImmediate ||
       (also_if_delayed && (ack_state_ == AckState::kBecomingDelayed ||
                            ack_state_ == AckState::kDelayed))) {
     UpdateAckState(AckState::kIdle, "sending SACK");
     return true;
   }

   return false;
 }

 bool DataTracker::will_increase_cum_ack_tsn(TSN tsn) const {
   UnwrappedTSN unwrapped = tsn_unwrapper_.PeekUnwrap(tsn);
   return unwrapped == last_cumulative_acked_tsn_.next_value();
 }

 void DataTracker::ForceImmediateSack() {
   ack_state_ = AckState::kImmediate;
 }

 void DataTracker::HandleDelayedAckTimerExpiry() {
   UpdateAckState(AckState::kImmediate, "delayed ack timer expired");
 }

 void DataTracker::ObservePacketEnd() {
   if (ack_state_ == AckState::kBecomingDelayed) {
     UpdateAckState(AckState::kDelayed, "packet end");
   }
 }

 void DataTracker::UpdateAckState(AckState new_state, absl::string_view reason) {
   if (new_state != ack_state_) {
     RTC_DLOG(LS_VERBOSE) << log_prefix_ << "State changed from "
                          << ToString(ack_state_) << " to "
                          << ToString(new_state) << " due to " << reason;
     if (ack_state_ == AckState::kDelayed) {
       delayed_ack_timer_.Stop();
     } else if (new_state == AckState::kDelayed) {
       delayed_ack_timer_.Start();
     }
     ack_state_ = new_state;
   }
 }

 absl::string_view DataTracker::ToString(AckState ack_state) {
   switch (ack_state) {
     case AckState::kIdle:
       return "IDLE";
     case AckState::kBecomingDelayed:
       return "BECOMING_DELAYED";
     case AckState::kDelayed:
       return "DELAYED";
     case AckState::kImmediate:
       return "IMMEDIATE";
   }
 }

 HandoverReadinessStatus DataTracker::GetHandoverReadiness() const {
   HandoverReadinessStatus status;
   if (!additional_tsn_blocks_.empty()) {
     status.Add(HandoverUnreadinessReason::kDataTrackerTsnBlocksPending);
   }
   return status;
 }

 void DataTracker::AddHandoverState(DcSctpSocketHandoverState& state) {
   state.rx.last_cumulative_acked_tsn = last_cumulative_acked_tsn().value();
   state.rx.seen_packet = seen_packet_;
 }

 }  // namespace dcsctp
	/*
	* 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/rx/data_tracker.h"

	#include <algorithm>
	#include <cstdint>
	#include <iterator>
	#include <set>
	#include <string>
	#include <utility>
	#include <vector>

	#include "absl/algorithm/container.h"
	#include "absl/strings/string_view.h"
	#include "absl/types/optional.h"
	#include "net/dcsctp/common/sequence_numbers.h"
	#include "net/dcsctp/packet/chunk/sack_chunk.h"
	#include "net/dcsctp/timer/timer.h"
	#include "rtc_base/logging.h"
	#include "rtc_base/strings/string_builder.h"

	namespace dcsctp {

	constexpr size_t DataTracker::kMaxDuplicateTsnReported;
	constexpr size_t DataTracker::kMaxGapAckBlocksReported;

	bool DataTracker::AdditionalTsnBlocks::Add(UnwrappedTSN tsn) {
	// Find any block to expand. It will look for any block that includes (also
	// when expanded) the provided `tsn`. It will return the block that is greater
	// than, or equal to `tsn`.
	auto it = absl::c_lower_bound(
	blocks_, tsn, [&](const TsnRange& elem, const UnwrappedTSN& t) {
	return elem.last.next_value() < t;
	});

	if (it == blocks_.end()) {
	// No matching block found. There is no greater than, or equal block - which
	// means that this TSN is greater than any block. It can then be inserted at
	// the end.
	blocks_.emplace_back(tsn, tsn);
	return true;
	}

	if (tsn >= it->first && tsn <= it->last) {
	// It's already in this block.
	return false;
	}

	if (it->last.next_value() == tsn) {
	// This block can be expanded to the right, or merged with the next.
	auto next_it = it + 1;
	if (next_it != blocks_.end() && tsn.next_value() == next_it->first) {
	// Expanding it would make it adjacent to next block - merge those.
	it->last = next_it->last;
	blocks_.erase(next_it);
	return true;
	}

	// Expand to the right
	it->last = tsn;
	return true;
	}

	if (it->first == tsn.next_value()) {
	// This block can be expanded to the left. Merging to the left would've been
	// covered by the above "merge to the right". Both blocks (expand a
	// right-most block to the left and expand a left-most block to the right)
	// would match, but the left-most would be returned by std::lower_bound.
	RTC_DCHECK(it == blocks_.begin() \|\| (it - 1)->last.next_value() != tsn);

	// Expand to the left.
	it->first = tsn;
	return true;
	}

	// Need to create a new block in the middle.
	blocks_.emplace(it, tsn, tsn);
	return true;
	}

	void DataTracker::AdditionalTsnBlocks::EraseTo(UnwrappedTSN tsn) {
	// Find the block that is greater than or equals `tsn`.
	auto it = absl::c_lower_bound(
	blocks_, tsn, [&](const TsnRange& elem, const UnwrappedTSN& t) {
	return elem.last < t;
	});

	// The block that is found is greater or equal (or possibly ::end, when no
	// block is greater or equal). All blocks before this block can be safely
	// removed. the TSN might be within this block, so possibly truncate it.
	bool tsn_is_within_block = it != blocks_.end() && tsn >= it->first;
	blocks_.erase(blocks_.begin(), it);

	if (tsn_is_within_block) {
	blocks_.front().first = tsn.next_value();
	}
	}

	void DataTracker::AdditionalTsnBlocks::PopFront() {
	RTC_DCHECK(!blocks_.empty());
	blocks_.erase(blocks_.begin());
	}

	bool DataTracker::IsTSNValid(TSN tsn) const {
	UnwrappedTSN unwrapped_tsn = tsn_unwrapper_.PeekUnwrap(tsn);

	// Note that this method doesn't return `false` for old DATA chunks, as those
	// are actually valid, and receiving those may affect the generated SACK
	// response (by setting "duplicate TSNs").

	uint32_t difference =
	UnwrappedTSN::Difference(unwrapped_tsn, last_cumulative_acked_tsn_);
	if (difference > kMaxAcceptedOutstandingFragments) {
	return false;
	}
	return true;
	}

	void DataTracker::Observe(TSN tsn,
	AnyDataChunk::ImmediateAckFlag immediate_ack) {
	UnwrappedTSN unwrapped_tsn = tsn_unwrapper_.Unwrap(tsn);

	// IsTSNValid must be called prior to calling this method.
	RTC_DCHECK(
	UnwrappedTSN::Difference(unwrapped_tsn, last_cumulative_acked_tsn_) <=
	kMaxAcceptedOutstandingFragments);

	// Old chunk already seen before?
	if (unwrapped_tsn <= last_cumulative_acked_tsn_) {
	if (duplicate_tsns_.size() < kMaxDuplicateTsnReported) {
	duplicate_tsns_.insert(unwrapped_tsn.Wrap());
	}
	// https://datatracker.ietf.org/doc/html/rfc4960#section-6.2
	// "When a packet arrives with duplicate DATA chunk(s) and with no new DATA
	// chunk(s), the endpoint MUST immediately send a SACK with no delay. If a
	// packet arrives with duplicate DATA chunk(s) bundled with new DATA chunks,
	// the endpoint MAY immediately send a SACK."
	UpdateAckState(AckState::kImmediate, "duplicate data");
	} else {
	if (unwrapped_tsn == last_cumulative_acked_tsn_.next_value()) {
	last_cumulative_acked_tsn_ = unwrapped_tsn;
	// The cumulative acked tsn may be moved even further, if a gap was
	// filled.
	if (!additional_tsn_blocks_.empty() &&
	additional_tsn_blocks_.front().first ==
	last_cumulative_acked_tsn_.next_value()) {
	last_cumulative_acked_tsn_ = additional_tsn_blocks_.front().last;
	additional_tsn_blocks_.PopFront();
	}
	} else {
	bool inserted = additional_tsn_blocks_.Add(unwrapped_tsn);
	if (!inserted) {
	// Already seen before.
	if (duplicate_tsns_.size() < kMaxDuplicateTsnReported) {
	duplicate_tsns_.insert(unwrapped_tsn.Wrap());
	}
	// https://datatracker.ietf.org/doc/html/rfc4960#section-6.2
	// "When a packet arrives with duplicate DATA chunk(s) and with no new
	// DATA chunk(s), the endpoint MUST immediately send a SACK with no
	// delay. If a packet arrives with duplicate DATA chunk(s) bundled with
	// new DATA chunks, the endpoint MAY immediately send a SACK."
	// No need to do this. SACKs are sent immediately on packet loss below.
	}
	}
	}

	// https://tools.ietf.org/html/rfc4960#section-6.7
	// "Upon the reception of a new DATA chunk, an endpoint shall examine the
	// continuity of the TSNs received. If the endpoint detects a gap in
	// the received DATA chunk sequence, it SHOULD send a SACK with Gap Ack
	// Blocks immediately. The data receiver continues sending a SACK after
	// receipt of each SCTP packet that doesn't fill the gap."
	if (!additional_tsn_blocks_.empty()) {
	UpdateAckState(AckState::kImmediate, "packet loss");
	}

	// https://tools.ietf.org/html/rfc7053#section-5.2
	// "Upon receipt of an SCTP packet containing a DATA chunk with the I
	// bit set, the receiver SHOULD NOT delay the sending of the corresponding
	// SACK chunk, i.e., the receiver SHOULD immediately respond with the
	// corresponding SACK chunk."
	if (*immediate_ack) {
	UpdateAckState(AckState::kImmediate, "immediate-ack bit set");
	}

	if (!seen_packet_) {
	// https://tools.ietf.org/html/rfc4960#section-5.1
	// "After the reception of the first DATA chunk in an association the
	// endpoint MUST immediately respond with a SACK to acknowledge the DATA
	// chunk."
	seen_packet_ = true;
	UpdateAckState(AckState::kImmediate, "first DATA chunk");
	}

	// https://tools.ietf.org/html/rfc4960#section-6.2
	// "Specifically, an acknowledgement SHOULD be generated for at least
	// every second packet (not every second DATA chunk) received, and SHOULD be
	// generated within 200 ms of the arrival of any unacknowledged DATA chunk."
	if (ack_state_ == AckState::kIdle) {
	UpdateAckState(AckState::kBecomingDelayed, "received DATA when idle");
	} else if (ack_state_ == AckState::kDelayed) {
	UpdateAckState(AckState::kImmediate, "received DATA when already delayed");
	}
	}

	void DataTracker::HandleForwardTsn(TSN new_cumulative_ack) {
	// ForwardTSN is sent to make the receiver (this socket) "forget" about partly
	// received (or not received at all) data, up until `new_cumulative_ack`.

	UnwrappedTSN unwrapped_tsn = tsn_unwrapper_.Unwrap(new_cumulative_ack);
	UnwrappedTSN prev_last_cum_ack_tsn = last_cumulative_acked_tsn_;

	// Old chunk already seen before?
	if (unwrapped_tsn <= last_cumulative_acked_tsn_) {
	// https://tools.ietf.org/html/rfc3758#section-3.6
	// "Note, if the "New Cumulative TSN" value carried in the arrived
	// FORWARD TSN chunk is found to be behind or at the current cumulative TSN
	// point, the data receiver MUST treat this FORWARD TSN as out-of-date and
	// MUST NOT update its Cumulative TSN. The receiver SHOULD send a SACK to
	// its peer (the sender of the FORWARD TSN) since such a duplicate may
	// indicate the previous SACK was lost in the network."
	UpdateAckState(AckState::kImmediate,
	"FORWARD_TSN new_cumulative_tsn was behind");
	return;
	}

	// https://tools.ietf.org/html/rfc3758#section-3.6
	// "When a FORWARD TSN chunk arrives, the data receiver MUST first update
	// its cumulative TSN point to the value carried in the FORWARD TSN chunk, and
	// then MUST further advance its cumulative TSN point locally if possible, as
	// shown by the following example..."

	// The `new_cumulative_ack` will become the current
	// `last_cumulative_acked_tsn_`, and if there have been prior "gaps" that are
	// now overlapping with the new value, remove them.
	last_cumulative_acked_tsn_ = unwrapped_tsn;
	additional_tsn_blocks_.EraseTo(unwrapped_tsn);

	// See if the `last_cumulative_acked_tsn_` can be moved even further:
	if (!additional_tsn_blocks_.empty() &&
	additional_tsn_blocks_.front().first ==
	last_cumulative_acked_tsn_.next_value()) {
	last_cumulative_acked_tsn_ = additional_tsn_blocks_.front().last;
	additional_tsn_blocks_.PopFront();
	}

	RTC_DLOG(LS_VERBOSE) << log_prefix_ << "FORWARD_TSN, cum_ack_tsn="
	<< *prev_last_cum_ack_tsn.Wrap() << "->"
	<< *new_cumulative_ack << "->"
	<< *last_cumulative_acked_tsn_.Wrap();

	// https://tools.ietf.org/html/rfc3758#section-3.6
	// "Any time a FORWARD TSN chunk arrives, for the purposes of sending a
	// SACK, the receiver MUST follow the same rules as if a DATA chunk had been
	// received (i.e., follow the delayed sack rules specified in ..."
	if (ack_state_ == AckState::kIdle) {
	UpdateAckState(AckState::kBecomingDelayed,
	"received FORWARD_TSN when idle");
	} else if (ack_state_ == AckState::kDelayed) {
	UpdateAckState(AckState::kImmediate,
	"received FORWARD_TSN when already delayed");
	}
	}

	SackChunk DataTracker::CreateSelectiveAck(size_t a_rwnd) {
	// Note that in SCTP, the receiver side is allowed to discard received data
	// and signal that to the sender, but only chunks that have previously been
	// reported in the gap-ack-blocks. However, this implementation will never do
	// that. So this SACK produced is more like a NR-SACK as explained in
	// https://ieeexplore.ieee.org/document/4697037 and which there is an RFC
	// draft at https://tools.ietf.org/html/draft-tuexen-tsvwg-sctp-multipath-17.
	std::set<TSN> duplicate_tsns;
	duplicate_tsns_.swap(duplicate_tsns);

	return SackChunk(last_cumulative_acked_tsn_.Wrap(), a_rwnd,
	CreateGapAckBlocks(), std::move(duplicate_tsns));
	}

	std::vector<SackChunk::GapAckBlock> DataTracker::CreateGapAckBlocks() const {
	const auto& blocks = additional_tsn_blocks_.blocks();
	std::vector<SackChunk::GapAckBlock> gap_ack_blocks;
	gap_ack_blocks.reserve(std::min(blocks.size(), kMaxGapAckBlocksReported));
	for (size_t i = 0; i < blocks.size() && i < kMaxGapAckBlocksReported; ++i) {
	auto start_diff =
	UnwrappedTSN::Difference(blocks[i].first, last_cumulative_acked_tsn_);
	auto end_diff =
	UnwrappedTSN::Difference(blocks[i].last, last_cumulative_acked_tsn_);
	gap_ack_blocks.emplace_back(static_cast<uint16_t>(start_diff),
	static_cast<uint16_t>(end_diff));
	}

	return gap_ack_blocks;
	}

	bool DataTracker::ShouldSendAck(bool also_if_delayed) {
	if (ack_state_ == AckState::kImmediate \|\|
	(also_if_delayed && (ack_state_ == AckState::kBecomingDelayed \|\|
	ack_state_ == AckState::kDelayed))) {
	UpdateAckState(AckState::kIdle, "sending SACK");
	return true;
	}

	return false;
	}

	bool DataTracker::will_increase_cum_ack_tsn(TSN tsn) const {
	UnwrappedTSN unwrapped = tsn_unwrapper_.PeekUnwrap(tsn);
	return unwrapped == last_cumulative_acked_tsn_.next_value();
	}

	void DataTracker::ForceImmediateSack() {
	ack_state_ = AckState::kImmediate;
	}

	void DataTracker::HandleDelayedAckTimerExpiry() {
	UpdateAckState(AckState::kImmediate, "delayed ack timer expired");
	}

	void DataTracker::ObservePacketEnd() {
	if (ack_state_ == AckState::kBecomingDelayed) {
	UpdateAckState(AckState::kDelayed, "packet end");
	}
	}

	void DataTracker::UpdateAckState(AckState new_state, absl::string_view reason) {
	if (new_state != ack_state_) {
	RTC_DLOG(LS_VERBOSE) << log_prefix_ << "State changed from "
	<< ToString(ack_state_) << " to "
	<< ToString(new_state) << " due to " << reason;
	if (ack_state_ == AckState::kDelayed) {
	delayed_ack_timer_.Stop();
	} else if (new_state == AckState::kDelayed) {
	delayed_ack_timer_.Start();
	}
	ack_state_ = new_state;
	}
	}

	absl::string_view DataTracker::ToString(AckState ack_state) {
	switch (ack_state) {
	case AckState::kIdle:
	return "IDLE";
	case AckState::kBecomingDelayed:
	return "BECOMING_DELAYED";
	case AckState::kDelayed:
	return "DELAYED";
	case AckState::kImmediate:
	return "IMMEDIATE";
	}
	}

	HandoverReadinessStatus DataTracker::GetHandoverReadiness() const {
	HandoverReadinessStatus status;
	if (!additional_tsn_blocks_.empty()) {
	status.Add(HandoverUnreadinessReason::kDataTrackerTsnBlocksPending);
	}
	return status;
	}

	void DataTracker::AddHandoverState(DcSctpSocketHandoverState& state) {
	state.rx.last_cumulative_acked_tsn = last_cumulative_acked_tsn().value();
	state.rx.seen_packet = seen_packet_;
	}

	} // namespace dcsctp