net/dcsctp/tx/outstanding_data.h - 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.
  */
 #ifndef NET_DCSCTP_TX_OUTSTANDING_DATA_H_
 #define NET_DCSCTP_TX_OUTSTANDING_DATA_H_

 #include <deque>
 #include <map>
 #include <set>
 #include <utility>
 #include <vector>

 #include "absl/types/optional.h"
 #include "api/units/timestamp.h"
 #include "net/dcsctp/common/internal_types.h"
 #include "net/dcsctp/common/sequence_numbers.h"
 #include "net/dcsctp/packet/chunk/forward_tsn_chunk.h"
 #include "net/dcsctp/packet/chunk/iforward_tsn_chunk.h"
 #include "net/dcsctp/packet/chunk/sack_chunk.h"
 #include "net/dcsctp/packet/data.h"
 #include "net/dcsctp/public/types.h"
 #include "rtc_base/containers/flat_set.h"

 namespace dcsctp {

 // This class keeps track of outstanding data chunks (sent, not yet acked) and
 // handles acking, nacking, rescheduling and abandoning.
 //
 // Items are added to this queue as they are sent and will be removed when the
 // peer acks them using the cumulative TSN ack.
 class OutstandingData {
  public:
   // State for DATA chunks (message fragments) in the queue - used in tests.
   enum class State {
     // The chunk has been sent but not received yet (from the sender's point of
     // view, as no SACK has been received yet that reference this chunk).
     kInFlight,
     // A SACK has been received which explicitly marked this chunk as missing -
     // it's now NACKED and may be retransmitted if NACKED enough times.
     kNacked,
     // A chunk that will be retransmitted when possible.
     kToBeRetransmitted,
     // A SACK has been received which explicitly marked this chunk as received.
     kAcked,
     // A chunk whose message has expired or has been retransmitted too many
     // times (RFC3758). It will not be retransmitted anymore.
     kAbandoned,
   };

   // Contains variables scoped to a processing of an incoming SACK.
   struct AckInfo {
     explicit AckInfo(UnwrappedTSN cumulative_tsn_ack)
         : highest_tsn_acked(cumulative_tsn_ack) {}

     // Bytes acked by increasing cumulative_tsn_ack and gap_ack_blocks.
     size_t bytes_acked = 0;

     // Indicates if this SACK indicates that packet loss has occurred. Just
     // because a packet is missing in the SACK doesn't necessarily mean that
     // there is packet loss as that packet might be in-flight and received
     // out-of-order. But when it has been reported missing consecutive times, it
     // will eventually be considered "lost" and this will be set.
     bool has_packet_loss = false;

     // Highest TSN Newly Acknowledged, an SCTP variable.
     UnwrappedTSN highest_tsn_acked;

     // The set of lifecycle IDs that were acked using cumulative_tsn_ack.
     std::vector<LifecycleId> acked_lifecycle_ids;
     // The set of lifecycle IDs that were acked, but had been abandoned.
     std::vector<LifecycleId> abandoned_lifecycle_ids;
   };

   OutstandingData(
       size_t data_chunk_header_size,
       UnwrappedTSN last_cumulative_tsn_ack,
       std::function<bool(StreamID, OutgoingMessageId)> discard_from_send_queue)
       : data_chunk_header_size_(data_chunk_header_size),
         last_cumulative_tsn_ack_(last_cumulative_tsn_ack),
         discard_from_send_queue_(std::move(discard_from_send_queue)) {}

   AckInfo HandleSack(
       UnwrappedTSN cumulative_tsn_ack,
       rtc::ArrayView<const SackChunk::GapAckBlock> gap_ack_blocks,
       bool is_in_fast_recovery);

   // Returns as many of the chunks that are eligible for fast retransmissions
   // and that would fit in a single packet of `max_size`. The eligible chunks
   // that didn't fit will be marked for (normal) retransmission and will not be
   // returned if this method is called again.
   std::vector<std::pair<TSN, Data>> GetChunksToBeFastRetransmitted(
       size_t max_size);

   // Given `max_size` of space left in a packet, which chunks can be added to
   // it?
   std::vector<std::pair<TSN, Data>> GetChunksToBeRetransmitted(size_t max_size);

   size_t unacked_bytes() const { return unacked_bytes_; }

   // Returns the number of DATA chunks that are in-flight (not acked or nacked).
   size_t unacked_items() const { return unacked_items_; }

   // Given the current time `now_ms`, expire and abandon outstanding (sent at
   // least once) chunks that have a limited lifetime.
   void ExpireOutstandingChunks(webrtc::Timestamp now);

   bool empty() const { return outstanding_data_.empty(); }

   bool has_data_to_be_fast_retransmitted() const {
     return !to_be_fast_retransmitted_.empty();
   }

   bool has_data_to_be_retransmitted() const {
     return !to_be_retransmitted_.empty() || !to_be_fast_retransmitted_.empty();
   }

   UnwrappedTSN last_cumulative_tsn_ack() const {
     return last_cumulative_tsn_ack_;
   }

   UnwrappedTSN next_tsn() const {
     return highest_outstanding_tsn().next_value();
   }

   UnwrappedTSN highest_outstanding_tsn() const;

   // Schedules `data` to be sent, with the provided partial reliability
   // parameters. Returns the TSN if the item was actually added and scheduled to
   // be sent, and absl::nullopt if it shouldn't be sent.
   absl::optional<UnwrappedTSN> Insert(
       OutgoingMessageId message_id,
       const Data& data,
       webrtc::Timestamp time_sent,
       MaxRetransmits max_retransmissions = MaxRetransmits::NoLimit(),
       webrtc::Timestamp expires_at = webrtc::Timestamp::PlusInfinity(),
       LifecycleId lifecycle_id = LifecycleId::NotSet());

   // Nacks all outstanding data.
   void NackAll();

   // Creates a FORWARD-TSN chunk.
   ForwardTsnChunk CreateForwardTsn() const;

   // Creates an I-FORWARD-TSN chunk.
   IForwardTsnChunk CreateIForwardTsn() const;

   // Given the current time and a TSN, it returns the measured RTT between when
   // the chunk was sent and now. It takes into acccount Karn's algorithm, so if
   // the chunk has ever been retransmitted, it will return `PlusInfinity()`.
   webrtc::TimeDelta MeasureRTT(webrtc::Timestamp now, UnwrappedTSN tsn) const;

   // Returns the internal state of all queued chunks. This is only used in
   // unit-tests.
   std::vector<std::pair<TSN, State>> GetChunkStatesForTesting() const;

   // Returns true if the next chunk that is not acked by the peer has been
   // abandoned, which means that a FORWARD-TSN should be sent.
   bool ShouldSendForwardTsn() const;

   // Sets the next TSN to be used. This is used in handover.
   void ResetSequenceNumbers(UnwrappedTSN last_cumulative_tsn);

   // Called when an outgoing stream reset is sent, marking the last assigned TSN
   // as a breakpoint that a FORWARD-TSN shouldn't cross.
   void BeginResetStreams();

  private:
   // A fragmented message's DATA chunk while in the retransmission queue, and
   // its associated metadata.
   class Item {
    public:
     enum class NackAction {
       kNothing,
       kRetransmit,
       kAbandon,
     };

     Item(OutgoingMessageId message_id,
          Data data,
          webrtc::Timestamp time_sent,
          MaxRetransmits max_retransmissions,
          webrtc::Timestamp expires_at,
          LifecycleId lifecycle_id)
         : message_id_(message_id),
           time_sent_(time_sent),
           max_retransmissions_(max_retransmissions),
           expires_at_(expires_at),
           lifecycle_id_(lifecycle_id),
           data_(std::move(data)) {}

     Item(const Item&) = delete;
     Item& operator=(const Item&) = delete;

     OutgoingMessageId message_id() const { return message_id_; }

     webrtc::Timestamp time_sent() const { return time_sent_; }

     const Data& data() const { return data_; }

     // Acks an item.
     void Ack();

     // Nacks an item. If it has been nacked enough times, or if `retransmit_now`
     // is set, it might be marked for retransmission. If the item has reached
     // its max retransmission value, it will instead be abandoned. The action
     // performed is indicated as return value.
     NackAction Nack(bool retransmit_now);

     // Prepares the item to be retransmitted. Sets it as outstanding and
     // clears all nack counters.
     void MarkAsRetransmitted();

     // Marks this item as abandoned.
     void Abandon();

     bool is_outstanding() const { return ack_state_ == AckState::kUnacked; }
     bool is_acked() const { return ack_state_ == AckState::kAcked; }
     bool is_nacked() const { return ack_state_ == AckState::kNacked; }
     bool is_abandoned() const { return lifecycle_ == Lifecycle::kAbandoned; }

     // Indicates if this chunk should be retransmitted.
     bool should_be_retransmitted() const {
       return lifecycle_ == Lifecycle::kToBeRetransmitted;
     }
     // Indicates if this chunk has ever been retransmitted.
     bool has_been_retransmitted() const { return num_retransmissions_ > 0; }

     // Given the current time, and the current state of this DATA chunk, it will
     // indicate if it has expired (SCTP Partial Reliability Extension).
     bool has_expired(webrtc::Timestamp now) const;

     LifecycleId lifecycle_id() const { return lifecycle_id_; }

    private:
     enum class Lifecycle : uint8_t {
       // The chunk is alive (sent, received, etc)
       kActive,
       // The chunk is scheduled to be retransmitted, and will then transition to
       // become active.
       kToBeRetransmitted,
       // The chunk has been abandoned. This is a terminal state.
       kAbandoned
     };
     enum class AckState : uint8_t {
       // The chunk is in-flight.
       kUnacked,
       // The chunk has been received and acknowledged.
       kAcked,
       // The chunk has been nacked and is possibly lost.
       kNacked
     };

     // NOTE: This data structure has been optimized for size, by ordering fields
     // to avoid unnecessary padding.

     const OutgoingMessageId message_id_;

     // When the packet was sent, and placed in this queue.
     const webrtc::Timestamp time_sent_;
     // If the message was sent with a maximum number of retransmissions, this is
     // set to that number. The value zero (0) means that it will never be
     // retransmitted.
     const MaxRetransmits max_retransmissions_;

     // Indicates the life cycle status of this chunk.
     Lifecycle lifecycle_ = Lifecycle::kActive;
     // Indicates the presence of this chunk, if it's in flight (Unacked), has
     // been received (Acked) or is possibly lost (Nacked).
     AckState ack_state_ = AckState::kUnacked;

     // The number of times the DATA chunk has been nacked (by having received a
     // SACK which doesn't include it). Will be cleared on retransmissions.
     uint8_t nack_count_ = 0;
     // The number of times the DATA chunk has been retransmitted.
     uint16_t num_retransmissions_ = 0;

     // At this exact millisecond, the item is considered expired. If the message
     // is not to be expired, this is set to the infinite future.
     const webrtc::Timestamp expires_at_;

     // An optional lifecycle id, which may only be set for the last fragment.
     const LifecycleId lifecycle_id_;

     // The actual data to send/retransmit.
     const Data data_;
   };

   // Returns how large a chunk will be, serialized, carrying the data
   size_t GetSerializedChunkSize(const Data& data) const;

   Item& GetItem(UnwrappedTSN tsn);
   const Item& GetItem(UnwrappedTSN tsn) const;

   // Given a `cumulative_tsn_ack` from an incoming SACK, will remove those items
   // in the retransmission queue up until this value and will update `ack_info`
   // by setting `bytes_acked_by_cumulative_tsn_ack`.
   void RemoveAcked(UnwrappedTSN cumulative_tsn_ack, AckInfo& ack_info);

   // Will mark the chunks covered by the `gap_ack_blocks` from an incoming SACK
   // as "acked" and update `ack_info` by adding new TSNs to `added_tsns`.
   void AckGapBlocks(UnwrappedTSN cumulative_tsn_ack,
                     rtc::ArrayView<const SackChunk::GapAckBlock> gap_ack_blocks,
                     AckInfo& ack_info);

   // Mark chunks reported as "missing", as "nacked" or "to be retransmitted"
   // depending how many times this has happened. Only packets up until
   // `ack_info.highest_tsn_acked` (highest TSN newly acknowledged) are
   // nacked/retransmitted. The method will set `ack_info.has_packet_loss`.
   void NackBetweenAckBlocks(
       UnwrappedTSN cumulative_tsn_ack,
       rtc::ArrayView<const SackChunk::GapAckBlock> gap_ack_blocks,
       bool is_in_fast_recovery,
       OutstandingData::AckInfo& ack_info);

   // Process the acknowledgement of the chunk referenced by `iter` and updates
   // state in `ack_info` and the object's state.
   void AckChunk(AckInfo& ack_info, UnwrappedTSN tsn, Item& item);

   // Helper method to process an incoming nack of an item and perform the
   // correct operations given the action indicated when nacking an item (e.g.
   // retransmitting or abandoning). The return value indicate if an action was
   // performed, meaning that packet loss was detected and acted upon. If
   // `do_fast_retransmit` is set and if the item has been nacked sufficiently
   // many times so that it should be retransmitted, this will schedule it to be
   // "fast retransmitted". This is only done just before going into fast
   // recovery.
   //
   // Note that since nacking an item may result in it becoming abandoned, which
   // in turn could alter `outstanding_data_`, any iterators are invalidated
   // after having called this method.
   bool NackItem(UnwrappedTSN tsn, bool retransmit_now, bool do_fast_retransmit);

   // Given that a message fragment, `item` has been abandoned, abandon all other
   // fragments that share the same message - both never-before-sent fragments
   // that are still in the SendQueue and outstanding chunks.
   void AbandonAllFor(const OutstandingData::Item& item);

   std::vector<std::pair<TSN, Data>> ExtractChunksThatCanFit(
       std::set<UnwrappedTSN>& chunks,
       size_t max_size);

   bool IsConsistent() const;

   // The size of the data chunk (DATA/I-DATA) header that is used.
   const size_t data_chunk_header_size_;
   // The last cumulative TSN ack number.
   UnwrappedTSN last_cumulative_tsn_ack_;
   // Callback when to discard items from the send queue.
   std::function<bool(StreamID, OutgoingMessageId)> discard_from_send_queue_;

   // Outstanding items. If non-empty, the first element has
   // `TSN=last_cumulative_tsn_ack_ + 1` and the following items are in strict
   // increasing TSN order. The last item has `TSN=highest_outstanding_tsn()`.
   std::deque<Item> outstanding_data_;
   // The number of bytes that are in-flight (sent but not yet acked or nacked).
   size_t unacked_bytes_ = 0;
   // The number of DATA chunks that are in-flight (sent but not yet acked or
   // nacked).
   size_t unacked_items_ = 0;
   // Data chunks that are eligible for fast retransmission.
   std::set<UnwrappedTSN> to_be_fast_retransmitted_;
   // Data chunks that are to be retransmitted.
   std::set<UnwrappedTSN> to_be_retransmitted_;
   // Wben a stream reset has begun, the "next TSN to assign" is added to this
   // set, and removed when the cum-ack TSN reaches it. This is used to limit a
   // FORWARD-TSN to reset streams past a "stream reset last assigned TSN".
   webrtc::flat_set<UnwrappedTSN> stream_reset_breakpoint_tsns_;
 };
 }  // namespace dcsctp
 #endif  // NET_DCSCTP_TX_OUTSTANDING_DATA_H_
	/*
	* 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.
	*/
	#ifndef NET_DCSCTP_TX_OUTSTANDING_DATA_H_
	#define NET_DCSCTP_TX_OUTSTANDING_DATA_H_

	#include <deque>
	#include <map>
	#include <set>
	#include <utility>
	#include <vector>

	#include "absl/types/optional.h"
	#include "api/units/timestamp.h"
	#include "net/dcsctp/common/internal_types.h"
	#include "net/dcsctp/common/sequence_numbers.h"
	#include "net/dcsctp/packet/chunk/forward_tsn_chunk.h"
	#include "net/dcsctp/packet/chunk/iforward_tsn_chunk.h"
	#include "net/dcsctp/packet/chunk/sack_chunk.h"
	#include "net/dcsctp/packet/data.h"
	#include "net/dcsctp/public/types.h"
	#include "rtc_base/containers/flat_set.h"

	namespace dcsctp {

	// This class keeps track of outstanding data chunks (sent, not yet acked) and
	// handles acking, nacking, rescheduling and abandoning.
	//
	// Items are added to this queue as they are sent and will be removed when the
	// peer acks them using the cumulative TSN ack.
	class OutstandingData {
	public:
	// State for DATA chunks (message fragments) in the queue - used in tests.
	enum class State {
	// The chunk has been sent but not received yet (from the sender's point of
	// view, as no SACK has been received yet that reference this chunk).
	kInFlight,
	// A SACK has been received which explicitly marked this chunk as missing -
	// it's now NACKED and may be retransmitted if NACKED enough times.
	kNacked,
	// A chunk that will be retransmitted when possible.
	kToBeRetransmitted,
	// A SACK has been received which explicitly marked this chunk as received.
	kAcked,
	// A chunk whose message has expired or has been retransmitted too many
	// times (RFC3758). It will not be retransmitted anymore.
	kAbandoned,
	};

	// Contains variables scoped to a processing of an incoming SACK.
	struct AckInfo {
	explicit AckInfo(UnwrappedTSN cumulative_tsn_ack)
	: highest_tsn_acked(cumulative_tsn_ack) {}

	// Bytes acked by increasing cumulative_tsn_ack and gap_ack_blocks.
	size_t bytes_acked = 0;

	// Indicates if this SACK indicates that packet loss has occurred. Just
	// because a packet is missing in the SACK doesn't necessarily mean that
	// there is packet loss as that packet might be in-flight and received
	// out-of-order. But when it has been reported missing consecutive times, it
	// will eventually be considered "lost" and this will be set.
	bool has_packet_loss = false;

	// Highest TSN Newly Acknowledged, an SCTP variable.
	UnwrappedTSN highest_tsn_acked;

	// The set of lifecycle IDs that were acked using cumulative_tsn_ack.
	std::vector<LifecycleId> acked_lifecycle_ids;
	// The set of lifecycle IDs that were acked, but had been abandoned.
	std::vector<LifecycleId> abandoned_lifecycle_ids;
	};

	OutstandingData(
	size_t data_chunk_header_size,
	UnwrappedTSN last_cumulative_tsn_ack,
	std::function<bool(StreamID, OutgoingMessageId)> discard_from_send_queue)
	: data_chunk_header_size_(data_chunk_header_size),
	last_cumulative_tsn_ack_(last_cumulative_tsn_ack),
	discard_from_send_queue_(std::move(discard_from_send_queue)) {}

	AckInfo HandleSack(
	UnwrappedTSN cumulative_tsn_ack,
	rtc::ArrayView<const SackChunk::GapAckBlock> gap_ack_blocks,
	bool is_in_fast_recovery);

	// Returns as many of the chunks that are eligible for fast retransmissions
	// and that would fit in a single packet of `max_size`. The eligible chunks
	// that didn't fit will be marked for (normal) retransmission and will not be
	// returned if this method is called again.
	std::vector<std::pair<TSN, Data>> GetChunksToBeFastRetransmitted(
	size_t max_size);

	// Given `max_size` of space left in a packet, which chunks can be added to
	// it?
	std::vector<std::pair<TSN, Data>> GetChunksToBeRetransmitted(size_t max_size);

	size_t unacked_bytes() const { return unacked_bytes_; }

	// Returns the number of DATA chunks that are in-flight (not acked or nacked).
	size_t unacked_items() const { return unacked_items_; }

	// Given the current time `now_ms`, expire and abandon outstanding (sent at
	// least once) chunks that have a limited lifetime.
	void ExpireOutstandingChunks(webrtc::Timestamp now);

	bool empty() const { return outstanding_data_.empty(); }

	bool has_data_to_be_fast_retransmitted() const {
	return !to_be_fast_retransmitted_.empty();
	}

	bool has_data_to_be_retransmitted() const {
	return !to_be_retransmitted_.empty() \|\| !to_be_fast_retransmitted_.empty();
	}

	UnwrappedTSN last_cumulative_tsn_ack() const {
	return last_cumulative_tsn_ack_;
	}

	UnwrappedTSN next_tsn() const {
	return highest_outstanding_tsn().next_value();
	}

	UnwrappedTSN highest_outstanding_tsn() const;

	// Schedules `data` to be sent, with the provided partial reliability
	// parameters. Returns the TSN if the item was actually added and scheduled to
	// be sent, and absl::nullopt if it shouldn't be sent.
	absl::optional<UnwrappedTSN> Insert(
	OutgoingMessageId message_id,
	const Data& data,
	webrtc::Timestamp time_sent,
	MaxRetransmits max_retransmissions = MaxRetransmits::NoLimit(),
	webrtc::Timestamp expires_at = webrtc::Timestamp::PlusInfinity(),
	LifecycleId lifecycle_id = LifecycleId::NotSet());

	// Nacks all outstanding data.
	void NackAll();

	// Creates a FORWARD-TSN chunk.
	ForwardTsnChunk CreateForwardTsn() const;

	// Creates an I-FORWARD-TSN chunk.
	IForwardTsnChunk CreateIForwardTsn() const;

	// Given the current time and a TSN, it returns the measured RTT between when
	// the chunk was sent and now. It takes into acccount Karn's algorithm, so if
	// the chunk has ever been retransmitted, it will return `PlusInfinity()`.
	webrtc::TimeDelta MeasureRTT(webrtc::Timestamp now, UnwrappedTSN tsn) const;

	// Returns the internal state of all queued chunks. This is only used in
	// unit-tests.
	std::vector<std::pair<TSN, State>> GetChunkStatesForTesting() const;

	// Returns true if the next chunk that is not acked by the peer has been
	// abandoned, which means that a FORWARD-TSN should be sent.
	bool ShouldSendForwardTsn() const;

	// Sets the next TSN to be used. This is used in handover.
	void ResetSequenceNumbers(UnwrappedTSN last_cumulative_tsn);

	// Called when an outgoing stream reset is sent, marking the last assigned TSN
	// as a breakpoint that a FORWARD-TSN shouldn't cross.
	void BeginResetStreams();

	private:
	// A fragmented message's DATA chunk while in the retransmission queue, and
	// its associated metadata.
	class Item {
	public:
	enum class NackAction {
	kNothing,
	kRetransmit,
	kAbandon,
	};

	Item(OutgoingMessageId message_id,
	Data data,
	webrtc::Timestamp time_sent,
	MaxRetransmits max_retransmissions,
	webrtc::Timestamp expires_at,
	LifecycleId lifecycle_id)
	: message_id_(message_id),
	time_sent_(time_sent),
	max_retransmissions_(max_retransmissions),
	expires_at_(expires_at),
	lifecycle_id_(lifecycle_id),
	data_(std::move(data)) {}

	Item(const Item&) = delete;
	Item& operator=(const Item&) = delete;

	OutgoingMessageId message_id() const { return message_id_; }

	webrtc::Timestamp time_sent() const { return time_sent_; }

	const Data& data() const { return data_; }

	// Acks an item.
	void Ack();

	// Nacks an item. If it has been nacked enough times, or if `retransmit_now`
	// is set, it might be marked for retransmission. If the item has reached
	// its max retransmission value, it will instead be abandoned. The action
	// performed is indicated as return value.
	NackAction Nack(bool retransmit_now);

	// Prepares the item to be retransmitted. Sets it as outstanding and
	// clears all nack counters.
	void MarkAsRetransmitted();

	// Marks this item as abandoned.
	void Abandon();

	bool is_outstanding() const { return ack_state_ == AckState::kUnacked; }
	bool is_acked() const { return ack_state_ == AckState::kAcked; }
	bool is_nacked() const { return ack_state_ == AckState::kNacked; }
	bool is_abandoned() const { return lifecycle_ == Lifecycle::kAbandoned; }

	// Indicates if this chunk should be retransmitted.
	bool should_be_retransmitted() const {
	return lifecycle_ == Lifecycle::kToBeRetransmitted;
	}
	// Indicates if this chunk has ever been retransmitted.
	bool has_been_retransmitted() const { return num_retransmissions_ > 0; }

	// Given the current time, and the current state of this DATA chunk, it will
	// indicate if it has expired (SCTP Partial Reliability Extension).
	bool has_expired(webrtc::Timestamp now) const;

	LifecycleId lifecycle_id() const { return lifecycle_id_; }

	private:
	enum class Lifecycle : uint8_t {
	// The chunk is alive (sent, received, etc)
	kActive,
	// The chunk is scheduled to be retransmitted, and will then transition to
	// become active.
	kToBeRetransmitted,
	// The chunk has been abandoned. This is a terminal state.
	kAbandoned
	};
	enum class AckState : uint8_t {
	// The chunk is in-flight.
	kUnacked,
	// The chunk has been received and acknowledged.
	kAcked,
	// The chunk has been nacked and is possibly lost.
	kNacked
	};

	// NOTE: This data structure has been optimized for size, by ordering fields
	// to avoid unnecessary padding.

	const OutgoingMessageId message_id_;

	// When the packet was sent, and placed in this queue.
	const webrtc::Timestamp time_sent_;
	// If the message was sent with a maximum number of retransmissions, this is
	// set to that number. The value zero (0) means that it will never be
	// retransmitted.
	const MaxRetransmits max_retransmissions_;

	// Indicates the life cycle status of this chunk.
	Lifecycle lifecycle_ = Lifecycle::kActive;
	// Indicates the presence of this chunk, if it's in flight (Unacked), has
	// been received (Acked) or is possibly lost (Nacked).
	AckState ack_state_ = AckState::kUnacked;

	// The number of times the DATA chunk has been nacked (by having received a
	// SACK which doesn't include it). Will be cleared on retransmissions.
	uint8_t nack_count_ = 0;
	// The number of times the DATA chunk has been retransmitted.
	uint16_t num_retransmissions_ = 0;

	// At this exact millisecond, the item is considered expired. If the message
	// is not to be expired, this is set to the infinite future.
	const webrtc::Timestamp expires_at_;

	// An optional lifecycle id, which may only be set for the last fragment.
	const LifecycleId lifecycle_id_;

	// The actual data to send/retransmit.
	const Data data_;
	};

	// Returns how large a chunk will be, serialized, carrying the data
	size_t GetSerializedChunkSize(const Data& data) const;

	Item& GetItem(UnwrappedTSN tsn);
	const Item& GetItem(UnwrappedTSN tsn) const;

	// Given a `cumulative_tsn_ack` from an incoming SACK, will remove those items
	// in the retransmission queue up until this value and will update `ack_info`
	// by setting `bytes_acked_by_cumulative_tsn_ack`.
	void RemoveAcked(UnwrappedTSN cumulative_tsn_ack, AckInfo& ack_info);

	// Will mark the chunks covered by the `gap_ack_blocks` from an incoming SACK
	// as "acked" and update `ack_info` by adding new TSNs to `added_tsns`.
	void AckGapBlocks(UnwrappedTSN cumulative_tsn_ack,
	rtc::ArrayView<const SackChunk::GapAckBlock> gap_ack_blocks,
	AckInfo& ack_info);

	// Mark chunks reported as "missing", as "nacked" or "to be retransmitted"
	// depending how many times this has happened. Only packets up until
	// `ack_info.highest_tsn_acked` (highest TSN newly acknowledged) are
	// nacked/retransmitted. The method will set `ack_info.has_packet_loss`.
	void NackBetweenAckBlocks(
	UnwrappedTSN cumulative_tsn_ack,
	rtc::ArrayView<const SackChunk::GapAckBlock> gap_ack_blocks,
	bool is_in_fast_recovery,
	OutstandingData::AckInfo& ack_info);

	// Process the acknowledgement of the chunk referenced by `iter` and updates
	// state in `ack_info` and the object's state.
	void AckChunk(AckInfo& ack_info, UnwrappedTSN tsn, Item& item);

	// Helper method to process an incoming nack of an item and perform the
	// correct operations given the action indicated when nacking an item (e.g.
	// retransmitting or abandoning). The return value indicate if an action was
	// performed, meaning that packet loss was detected and acted upon. If
	// `do_fast_retransmit` is set and if the item has been nacked sufficiently
	// many times so that it should be retransmitted, this will schedule it to be
	// "fast retransmitted". This is only done just before going into fast
	// recovery.
	//
	// Note that since nacking an item may result in it becoming abandoned, which
	// in turn could alter `outstanding_data_`, any iterators are invalidated
	// after having called this method.
	bool NackItem(UnwrappedTSN tsn, bool retransmit_now, bool do_fast_retransmit);

	// Given that a message fragment, `item` has been abandoned, abandon all other
	// fragments that share the same message - both never-before-sent fragments
	// that are still in the SendQueue and outstanding chunks.
	void AbandonAllFor(const OutstandingData::Item& item);

	std::vector<std::pair<TSN, Data>> ExtractChunksThatCanFit(
	std::set<UnwrappedTSN>& chunks,
	size_t max_size);

	bool IsConsistent() const;

	// The size of the data chunk (DATA/I-DATA) header that is used.
	const size_t data_chunk_header_size_;
	// The last cumulative TSN ack number.
	UnwrappedTSN last_cumulative_tsn_ack_;
	// Callback when to discard items from the send queue.
	std::function<bool(StreamID, OutgoingMessageId)> discard_from_send_queue_;

	// Outstanding items. If non-empty, the first element has
	// `TSN=last_cumulative_tsn_ack_ + 1` and the following items are in strict
	// increasing TSN order. The last item has `TSN=highest_outstanding_tsn()`.
	std::deque<Item> outstanding_data_;
	// The number of bytes that are in-flight (sent but not yet acked or nacked).
	size_t unacked_bytes_ = 0;
	// The number of DATA chunks that are in-flight (sent but not yet acked or
	// nacked).
	size_t unacked_items_ = 0;
	// Data chunks that are eligible for fast retransmission.
	std::set<UnwrappedTSN> to_be_fast_retransmitted_;
	// Data chunks that are to be retransmitted.
	std::set<UnwrappedTSN> to_be_retransmitted_;
	// Wben a stream reset has begun, the "next TSN to assign" is added to this
	// set, and removed when the cum-ack TSN reaches it. This is used to limit a
	// FORWARD-TSN to reset streams past a "stream reset last assigned TSN".
	webrtc::flat_set<UnwrappedTSN> stream_reset_breakpoint_tsns_;
	};
	} // namespace dcsctp
	#endif // NET_DCSCTP_TX_OUTSTANDING_DATA_H_