rfc9002.original | rfc9002.txt | |||
---|---|---|---|---|
QUIC J. Iyengar, Ed. | Internet Engineering Task Force (IETF) J. Iyengar, Ed. | |||
Internet-Draft Fastly | Request for Comments: 9002 Fastly | |||
Intended status: Standards Track I. Swett, Ed. | Category: Standards Track I. Swett, Ed. | |||
Expires: 19 July 2021 Google | ISSN: 2070-1721 Google | |||
15 January 2021 | May 2021 | |||
QUIC Loss Detection and Congestion Control | QUIC Loss Detection and Congestion Control | |||
draft-ietf-quic-recovery-34 | ||||
Abstract | Abstract | |||
This document describes loss detection and congestion control | This document describes loss detection and congestion control | |||
mechanisms for QUIC. | mechanisms for QUIC. | |||
Note to Readers | ||||
Discussion of this draft takes place on the QUIC working group | ||||
mailing list (quic@ietf.org (mailto:quic@ietf.org)), which is | ||||
archived at https://mailarchive.ietf.org/arch/ | ||||
search/?email_list=quic. | ||||
Working Group information can be found at https://github.com/quicwg; | ||||
source code and issues list for this draft can be found at | ||||
https://github.com/quicwg/base-drafts/labels/-recovery. | ||||
Status of This Memo | Status of This Memo | |||
This Internet-Draft is submitted in full conformance with the | This is an Internet Standards Track document. | |||
provisions of BCP 78 and BCP 79. | ||||
Internet-Drafts are working documents of the Internet Engineering | ||||
Task Force (IETF). Note that other groups may also distribute | ||||
working documents as Internet-Drafts. The list of current Internet- | ||||
Drafts is at https://datatracker.ietf.org/drafts/current/. | ||||
Internet-Drafts are draft documents valid for a maximum of six months | This document is a product of the Internet Engineering Task Force | |||
and may be updated, replaced, or obsoleted by other documents at any | (IETF). It represents the consensus of the IETF community. It has | |||
time. It is inappropriate to use Internet-Drafts as reference | received public review and has been approved for publication by the | |||
material or to cite them other than as "work in progress." | Internet Engineering Steering Group (IESG). Further information on | |||
Internet Standards is available in Section 2 of RFC 7841. | ||||
This Internet-Draft will expire on 19 July 2021. | Information about the current status of this document, any errata, | |||
and how to provide feedback on it may be obtained at | ||||
https://www.rfc-editor.org/info/rfc9002. | ||||
Copyright Notice | Copyright Notice | |||
Copyright (c) 2021 IETF Trust and the persons identified as the | Copyright (c) 2021 IETF Trust and the persons identified as the | |||
document authors. All rights reserved. | document authors. All rights reserved. | |||
This document is subject to BCP 78 and the IETF Trust's Legal | This document is subject to BCP 78 and the IETF Trust's Legal | |||
Provisions Relating to IETF Documents (https://trustee.ietf.org/ | Provisions Relating to IETF Documents | |||
license-info) in effect on the date of publication of this document. | (https://trustee.ietf.org/license-info) in effect on the date of | |||
Please review these documents carefully, as they describe your rights | publication of this document. Please review these documents | |||
and restrictions with respect to this document. Code Components | carefully, as they describe your rights and restrictions with respect | |||
extracted from this document must include Simplified BSD License text | to this document. Code Components extracted from this document must | |||
as described in Section 4.e of the Trust Legal Provisions and are | include Simplified BSD License text as described in Section 4.e of | |||
provided without warranty as described in the Simplified BSD License. | the Trust Legal Provisions and are provided without warranty as | |||
described in the Simplified BSD License. | ||||
Table of Contents | Table of Contents | |||
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 4 | 1. Introduction | |||
2. Conventions and Definitions . . . . . . . . . . . . . . . . . 4 | 2. Conventions and Definitions | |||
3. Design of the QUIC Transmission Machinery . . . . . . . . . . 5 | 3. Design of the QUIC Transmission Machinery | |||
4. Relevant Differences Between QUIC and TCP . . . . . . . . . . 6 | 4. Relevant Differences between QUIC and TCP | |||
4.1. Separate Packet Number Spaces . . . . . . . . . . . . . . 6 | 4.1. Separate Packet Number Spaces | |||
4.2. Monotonically Increasing Packet Numbers . . . . . . . . . 6 | 4.2. Monotonically Increasing Packet Numbers | |||
4.3. Clearer Loss Epoch . . . . . . . . . . . . . . . . . . . 7 | 4.3. Clearer Loss Epoch | |||
4.4. No Reneging . . . . . . . . . . . . . . . . . . . . . . . 7 | 4.4. No Reneging | |||
4.5. More ACK Ranges . . . . . . . . . . . . . . . . . . . . . 7 | 4.5. More ACK Ranges | |||
4.6. Explicit Correction For Delayed Acknowledgments . . . . . 7 | 4.6. Explicit Correction for Delayed Acknowledgments | |||
4.7. Probe Timeout Replaces RTO and TLP . . . . . . . . . . . 7 | 4.7. Probe Timeout Replaces RTO and TLP | |||
4.8. The Minimum Congestion Window is Two Packets . . . . . . 8 | 4.8. The Minimum Congestion Window Is Two Packets | |||
5. Estimating the Round-Trip Time . . . . . . . . . . . . . . . 8 | 4.9. Handshake Packets Are Not Special | |||
5.1. Generating RTT samples . . . . . . . . . . . . . . . . . 8 | 5. Estimating the Round-Trip Time | |||
5.2. Estimating min_rtt . . . . . . . . . . . . . . . . . . . 9 | 5.1. Generating RTT Samples | |||
5.3. Estimating smoothed_rtt and rttvar . . . . . . . . . . . 10 | 5.2. Estimating min_rtt | |||
6. Loss Detection . . . . . . . . . . . . . . . . . . . . . . . 12 | 5.3. Estimating smoothed_rtt and rttvar | |||
6.1. Acknowledgment-Based Detection . . . . . . . . . . . . . 12 | 6. Loss Detection | |||
6.1.1. Packet Threshold . . . . . . . . . . . . . . . . . . 13 | 6.1. Acknowledgment-Based Detection | |||
6.1.2. Time Threshold . . . . . . . . . . . . . . . . . . . 13 | 6.1.1. Packet Threshold | |||
6.2. Probe Timeout . . . . . . . . . . . . . . . . . . . . . . 14 | 6.1.2. Time Threshold | |||
6.2.1. Computing PTO . . . . . . . . . . . . . . . . . . . . 14 | 6.2. Probe Timeout | |||
6.2.2. Handshakes and New Paths . . . . . . . . . . . . . . 16 | 6.2.1. Computing PTO | |||
6.2.3. Speeding Up Handshake Completion . . . . . . . . . . 17 | 6.2.2. Handshakes and New Paths | |||
6.2.4. Sending Probe Packets . . . . . . . . . . . . . . . . 18 | 6.2.3. Speeding up Handshake Completion | |||
6.3. Handling Retry Packets . . . . . . . . . . . . . . . . . 19 | 6.2.4. Sending Probe Packets | |||
6.4. Discarding Keys and Packet State . . . . . . . . . . . . 19 | 6.3. Handling Retry Packets | |||
7. Congestion Control . . . . . . . . . . . . . . . . . . . . . 20 | 6.4. Discarding Keys and Packet State | |||
7.1. Explicit Congestion Notification . . . . . . . . . . . . 20 | 7. Congestion Control | |||
7.2. Initial and Minimum Congestion Window . . . . . . . . . . 21 | 7.1. Explicit Congestion Notification | |||
7.3. Congestion Control States . . . . . . . . . . . . . . . . 21 | 7.2. Initial and Minimum Congestion Window | |||
7.3.1. Slow Start . . . . . . . . . . . . . . . . . . . . . 22 | 7.3. Congestion Control States | |||
7.3.2. Recovery . . . . . . . . . . . . . . . . . . . . . . 22 | 7.3.1. Slow Start | |||
7.3.3. Congestion Avoidance . . . . . . . . . . . . . . . . 23 | 7.3.2. Recovery | |||
7.4. Ignoring Loss of Undecryptable Packets . . . . . . . . . 23 | 7.3.3. Congestion Avoidance | |||
7.5. Probe Timeout . . . . . . . . . . . . . . . . . . . . . . 24 | 7.4. Ignoring Loss of Undecryptable Packets | |||
7.6. Persistent Congestion . . . . . . . . . . . . . . . . . . 24 | 7.5. Probe Timeout | |||
7.6.1. Duration . . . . . . . . . . . . . . . . . . . . . . 24 | 7.6. Persistent Congestion | |||
7.6.2. Establishing Persistent Congestion . . . . . . . . . 25 | 7.6.1. Duration | |||
7.6.3. Example . . . . . . . . . . . . . . . . . . . . . . . 26 | 7.6.2. Establishing Persistent Congestion | |||
7.7. Pacing . . . . . . . . . . . . . . . . . . . . . . . . . 27 | 7.6.3. Example | |||
7.8. Under-utilizing the Congestion Window . . . . . . . . . . 28 | 7.7. Pacing | |||
8. Security Considerations . . . . . . . . . . . . . . . . . . . 28 | 7.8. Underutilizing the Congestion Window | |||
8.1. Loss and Congestion Signals . . . . . . . . . . . . . . . 28 | 8. Security Considerations | |||
8.2. Traffic Analysis . . . . . . . . . . . . . . . . . . . . 28 | 8.1. Loss and Congestion Signals | |||
8.3. Misreporting ECN Markings . . . . . . . . . . . . . . . . 28 | 8.2. Traffic Analysis | |||
9. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 29 | 8.3. Misreporting ECN Markings | |||
10. References . . . . . . . . . . . . . . . . . . . . . . . . . 29 | 9. References | |||
10.1. Normative References . . . . . . . . . . . . . . . . . . 29 | 9.1. Normative References | |||
10.2. Informative References . . . . . . . . . . . . . . . . . 30 | 9.2. Informative References | |||
Appendix A. Loss Recovery Pseudocode . . . . . . . . . . . . . . 32 | Appendix A. Loss Recovery Pseudocode | |||
A.1. Tracking Sent Packets . . . . . . . . . . . . . . . . . . 32 | A.1. Tracking Sent Packets | |||
A.1.1. Sent Packet Fields . . . . . . . . . . . . . . . . . 32 | A.1.1. Sent Packet Fields | |||
A.2. Constants of Interest . . . . . . . . . . . . . . . . . . 33 | A.2. Constants of Interest | |||
A.3. Variables of interest . . . . . . . . . . . . . . . . . . 33 | A.3. Variables of Interest | |||
A.4. Initialization . . . . . . . . . . . . . . . . . . . . . 34 | A.4. Initialization | |||
A.5. On Sending a Packet . . . . . . . . . . . . . . . . . . . 34 | A.5. On Sending a Packet | |||
A.6. On Receiving a Datagram . . . . . . . . . . . . . . . . . 35 | A.6. On Receiving a Datagram | |||
A.7. On Receiving an Acknowledgment . . . . . . . . . . . . . 35 | A.7. On Receiving an Acknowledgment | |||
A.8. Setting the Loss Detection Timer . . . . . . . . . . . . 37 | A.8. Setting the Loss Detection Timer | |||
A.9. On Timeout . . . . . . . . . . . . . . . . . . . . . . . 39 | A.9. On Timeout | |||
A.10. Detecting Lost Packets . . . . . . . . . . . . . . . . . 39 | A.10. Detecting Lost Packets | |||
A.11. Upon Dropping Initial or Handshake Keys . . . . . . . . . 40 | A.11. Upon Dropping Initial or Handshake Keys | |||
Appendix B. Congestion Control Pseudocode . . . . . . . . . . . 41 | Appendix B. Congestion Control Pseudocode | |||
B.1. Constants of interest . . . . . . . . . . . . . . . . . . 41 | B.1. Constants of Interest | |||
B.2. Variables of interest . . . . . . . . . . . . . . . . . . 41 | B.2. Variables of Interest | |||
B.3. Initialization . . . . . . . . . . . . . . . . . . . . . 42 | B.3. Initialization | |||
B.4. On Packet Sent . . . . . . . . . . . . . . . . . . . . . 42 | B.4. On Packet Sent | |||
B.5. On Packet Acknowledgment . . . . . . . . . . . . . . . . 42 | B.5. On Packet Acknowledgment | |||
B.6. On New Congestion Event . . . . . . . . . . . . . . . . . 43 | B.6. On New Congestion Event | |||
B.7. Process ECN Information . . . . . . . . . . . . . . . . . 44 | B.7. Process ECN Information | |||
B.8. On Packets Lost . . . . . . . . . . . . . . . . . . . . . 44 | B.8. On Packets Lost | |||
B.9. Removing Discarded Packets From Bytes In Flight . . . . . 44 | B.9. Removing Discarded Packets from Bytes in Flight | |||
Appendix C. Change Log . . . . . . . . . . . . . . . . . . . . . 45 | Contributors | |||
C.1. Since draft-ietf-quic-recovery-32 . . . . . . . . . . . . 45 | Authors' Addresses | |||
C.2. Since draft-ietf-quic-recovery-31 . . . . . . . . . . . . 45 | ||||
C.3. Since draft-ietf-quic-recovery-30 . . . . . . . . . . . . 45 | ||||
C.4. Since draft-ietf-quic-recovery-29 . . . . . . . . . . . . 45 | ||||
C.5. Since draft-ietf-quic-recovery-28 . . . . . . . . . . . . 46 | ||||
C.6. Since draft-ietf-quic-recovery-27 . . . . . . . . . . . . 46 | ||||
C.7. Since draft-ietf-quic-recovery-26 . . . . . . . . . . . . 46 | ||||
C.8. Since draft-ietf-quic-recovery-25 . . . . . . . . . . . . 46 | ||||
C.9. Since draft-ietf-quic-recovery-24 . . . . . . . . . . . . 46 | ||||
C.10. Since draft-ietf-quic-recovery-23 . . . . . . . . . . . . 46 | ||||
C.11. Since draft-ietf-quic-recovery-22 . . . . . . . . . . . . 47 | ||||
C.12. Since draft-ietf-quic-recovery-21 . . . . . . . . . . . . 47 | ||||
C.13. Since draft-ietf-quic-recovery-20 . . . . . . . . . . . . 47 | ||||
C.14. Since draft-ietf-quic-recovery-19 . . . . . . . . . . . . 47 | ||||
C.15. Since draft-ietf-quic-recovery-18 . . . . . . . . . . . . 48 | ||||
C.16. Since draft-ietf-quic-recovery-17 . . . . . . . . . . . . 48 | ||||
C.17. Since draft-ietf-quic-recovery-16 . . . . . . . . . . . . 49 | ||||
C.18. Since draft-ietf-quic-recovery-14 . . . . . . . . . . . . 49 | ||||
C.19. Since draft-ietf-quic-recovery-13 . . . . . . . . . . . . 49 | ||||
C.20. Since draft-ietf-quic-recovery-12 . . . . . . . . . . . . 50 | ||||
C.21. Since draft-ietf-quic-recovery-11 . . . . . . . . . . . . 50 | ||||
C.22. Since draft-ietf-quic-recovery-10 . . . . . . . . . . . . 50 | ||||
C.23. Since draft-ietf-quic-recovery-09 . . . . . . . . . . . . 50 | ||||
C.24. Since draft-ietf-quic-recovery-08 . . . . . . . . . . . . 50 | ||||
C.25. Since draft-ietf-quic-recovery-07 . . . . . . . . . . . . 50 | ||||
C.26. Since draft-ietf-quic-recovery-06 . . . . . . . . . . . . 51 | ||||
C.27. Since draft-ietf-quic-recovery-05 . . . . . . . . . . . . 51 | ||||
C.28. Since draft-ietf-quic-recovery-04 . . . . . . . . . . . . 51 | ||||
C.29. Since draft-ietf-quic-recovery-03 . . . . . . . . . . . . 51 | ||||
C.30. Since draft-ietf-quic-recovery-02 . . . . . . . . . . . . 51 | ||||
C.31. Since draft-ietf-quic-recovery-01 . . . . . . . . . . . . 51 | ||||
C.32. Since draft-ietf-quic-recovery-00 . . . . . . . . . . . . 51 | ||||
C.33. Since draft-iyengar-quic-loss-recovery-01 . . . . . . . . 51 | ||||
Appendix D. Contributors . . . . . . . . . . . . . . . . . . . . 52 | ||||
Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . . . 52 | ||||
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 52 | ||||
1. Introduction | 1. Introduction | |||
QUIC is a secure general-purpose transport protocol, described in | QUIC is a secure, general-purpose transport protocol, described in | |||
[QUIC-TRANSPORT]). This document describes loss detection and | [QUIC-TRANSPORT]. This document describes loss detection and | |||
congestion control mechanisms for QUIC. | congestion control mechanisms for QUIC. | |||
2. Conventions and Definitions | 2. Conventions and Definitions | |||
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", | The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", | |||
"SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and | "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and | |||
"OPTIONAL" in this document are to be interpreted as described in | "OPTIONAL" in this document are to be interpreted as described in BCP | |||
BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all | 14 [RFC2119] [RFC8174] when, and only when, they appear in all | |||
capitals, as shown here. | capitals, as shown here. | |||
Definitions of terms that are used in this document: | Definitions of terms that are used in this document: | |||
Ack-eliciting frames: All frames other than ACK, PADDING, and | Ack-eliciting frames: All frames other than ACK, PADDING, and | |||
CONNECTION_CLOSE are considered ack-eliciting. | CONNECTION_CLOSE are considered ack-eliciting. | |||
Ack-eliciting packets: Packets that contain ack-eliciting frames | Ack-eliciting packets: Packets that contain ack-eliciting frames | |||
elicit an ACK from the receiver within the maximum acknowledgment | elicit an ACK from the receiver within the maximum acknowledgment | |||
delay and are called ack-eliciting packets. | delay and are called ack-eliciting packets. | |||
In-flight packets: Packets are considered in-flight when they are | In-flight packets: Packets are considered in flight when they are | |||
ack-eliciting or contain a PADDING frame, and they have been sent | ack-eliciting or contain a PADDING frame, and they have been sent | |||
but are not acknowledged, declared lost, or discarded along with | but are not acknowledged, declared lost, or discarded along with | |||
old keys. | old keys. | |||
3. Design of the QUIC Transmission Machinery | 3. Design of the QUIC Transmission Machinery | |||
All transmissions in QUIC are sent with a packet-level header, which | All transmissions in QUIC are sent with a packet-level header, which | |||
indicates the encryption level and includes a packet sequence number | indicates the encryption level and includes a packet sequence number | |||
(referred to below as a packet number). The encryption level | (referred to below as a packet number). The encryption level | |||
indicates the packet number space, as described in Section 12.3 in | indicates the packet number space, as described in Section 12.3 of | |||
[QUIC-TRANSPORT]. Packet numbers never repeat within a packet number | [QUIC-TRANSPORT]. Packet numbers never repeat within a packet number | |||
space for the lifetime of a connection. Packet numbers are sent in | space for the lifetime of a connection. Packet numbers are sent in | |||
monotonically increasing order within a space, preventing ambiguity. | monotonically increasing order within a space, preventing ambiguity. | |||
It is permitted for some packet numbers to never be used, leaving | It is permitted for some packet numbers to never be used, leaving | |||
intentional gaps. | intentional gaps. | |||
This design obviates the need for disambiguating between | This design obviates the need for disambiguating between | |||
transmissions and retransmissions; this eliminates significant | transmissions and retransmissions; this eliminates significant | |||
complexity from QUIC's interpretation of TCP loss detection | complexity from QUIC's interpretation of TCP loss detection | |||
mechanisms. | mechanisms. | |||
skipping to change at page 5, line 42 ¶ | skipping to change at line 182 ¶ | |||
* All packets are acknowledged, though packets that contain no ack- | * All packets are acknowledged, though packets that contain no ack- | |||
eliciting frames are only acknowledged along with ack-eliciting | eliciting frames are only acknowledged along with ack-eliciting | |||
packets. | packets. | |||
* Long header packets that contain CRYPTO frames are critical to the | * Long header packets that contain CRYPTO frames are critical to the | |||
performance of the QUIC handshake and use shorter timers for | performance of the QUIC handshake and use shorter timers for | |||
acknowledgment. | acknowledgment. | |||
* Packets containing frames besides ACK or CONNECTION_CLOSE frames | * Packets containing frames besides ACK or CONNECTION_CLOSE frames | |||
count toward congestion control limits and are considered in- | count toward congestion control limits and are considered to be in | |||
flight. | flight. | |||
* PADDING frames cause packets to contribute toward bytes in flight | * PADDING frames cause packets to contribute toward bytes in flight | |||
without directly causing an acknowledgment to be sent. | without directly causing an acknowledgment to be sent. | |||
4. Relevant Differences Between QUIC and TCP | 4. Relevant Differences between QUIC and TCP | |||
Readers familiar with TCP's loss detection and congestion control | Readers familiar with TCP's loss detection and congestion control | |||
will find algorithms here that parallel well-known TCP ones. | will find algorithms here that parallel well-known TCP ones. | |||
However, protocol differences between QUIC and TCP contribute to | However, protocol differences between QUIC and TCP contribute to | |||
algorithmic differences. These protocol differences are briefly | algorithmic differences. These protocol differences are briefly | |||
described below. | described below. | |||
4.1. Separate Packet Number Spaces | 4.1. Separate Packet Number Spaces | |||
QUIC uses separate packet number spaces for each encryption level, | QUIC uses separate packet number spaces for each encryption level, | |||
except 0-RTT and all generations of 1-RTT keys use the same packet | except 0-RTT and all generations of 1-RTT keys use the same packet | |||
number space. Separate packet number spaces ensures acknowledgment | number space. Separate packet number spaces ensures that the | |||
of packets sent with one level of encryption will not cause spurious | acknowledgment of packets sent with one level of encryption will not | |||
retransmission of packets sent with a different encryption level. | cause spurious retransmission of packets sent with a different | |||
Congestion control and round-trip time (RTT) measurement are unified | encryption level. Congestion control and round-trip time (RTT) | |||
across packet number spaces. | measurement are unified across packet number spaces. | |||
4.2. Monotonically Increasing Packet Numbers | 4.2. Monotonically Increasing Packet Numbers | |||
TCP conflates transmission order at the sender with delivery order at | TCP conflates transmission order at the sender with delivery order at | |||
the receiver, resulting in the retransmission ambiguity problem | the receiver, resulting in the retransmission ambiguity problem | |||
([RETRANSMISSION]). QUIC separates transmission order from delivery | [RETRANSMISSION]. QUIC separates transmission order from delivery | |||
order: packet numbers indicate transmission order, and delivery order | order: packet numbers indicate transmission order, and delivery order | |||
is determined by the stream offsets in STREAM frames. | is determined by the stream offsets in STREAM frames. | |||
QUIC's packet number is strictly increasing within a packet number | QUIC's packet number is strictly increasing within a packet number | |||
space, and directly encodes transmission order. A higher packet | space and directly encodes transmission order. A higher packet | |||
number signifies that the packet was sent later, and a lower packet | number signifies that the packet was sent later, and a lower packet | |||
number signifies that the packet was sent earlier. When a packet | number signifies that the packet was sent earlier. When a packet | |||
containing ack-eliciting frames is detected lost, QUIC includes | containing ack-eliciting frames is detected lost, QUIC includes | |||
necessary frames in a new packet with a new packet number, removing | necessary frames in a new packet with a new packet number, removing | |||
ambiguity about which packet is acknowledged when an ACK is received. | ambiguity about which packet is acknowledged when an ACK is received. | |||
Consequently, more accurate RTT measurements can be made, spurious | Consequently, more accurate RTT measurements can be made, spurious | |||
retransmissions are trivially detected, and mechanisms such as Fast | retransmissions are trivially detected, and mechanisms such as Fast | |||
Retransmit can be applied universally, based only on packet number. | Retransmit can be applied universally, based only on packet number. | |||
This design point significantly simplifies loss detection mechanisms | This design point significantly simplifies loss detection mechanisms | |||
for QUIC. Most TCP mechanisms implicitly attempt to infer | for QUIC. Most TCP mechanisms implicitly attempt to infer | |||
transmission ordering based on TCP sequence numbers - a non-trivial | transmission ordering based on TCP sequence numbers -- a nontrivial | |||
task, especially when TCP timestamps are not available. | task, especially when TCP timestamps are not available. | |||
4.3. Clearer Loss Epoch | 4.3. Clearer Loss Epoch | |||
QUIC starts a loss epoch when a packet is lost. The loss epoch ends | QUIC starts a loss epoch when a packet is lost. The loss epoch ends | |||
when any packet sent after the start of the epoch is acknowledged. | when any packet sent after the start of the epoch is acknowledged. | |||
TCP waits for the gap in the sequence number space to be filled, and | TCP waits for the gap in the sequence number space to be filled, and | |||
so if a segment is lost multiple times in a row, the loss epoch may | so if a segment is lost multiple times in a row, the loss epoch may | |||
not end for several round trips. Because both should reduce their | not end for several round trips. Because both should reduce their | |||
congestion windows only once per epoch, QUIC will do it once for | congestion windows only once per epoch, QUIC will do it once for | |||
every round trip that experiences loss, while TCP may only do it once | every round trip that experiences loss, while TCP may only do it once | |||
across multiple round trips. | across multiple round trips. | |||
4.4. No Reneging | 4.4. No Reneging | |||
QUIC ACK frames contain information similar to that in TCP Selective | QUIC ACK frames contain information similar to that in TCP Selective | |||
Acknowledgements (SACKs, [RFC2018]). However, QUIC does not allow a | Acknowledgments (SACKs) [RFC2018]. However, QUIC does not allow a | |||
packet acknowledgement to be reneged, greatly simplifying | packet acknowledgment to be reneged, greatly simplifying | |||
implementations on both sides and reducing memory pressure on the | implementations on both sides and reducing memory pressure on the | |||
sender. | sender. | |||
4.5. More ACK Ranges | 4.5. More ACK Ranges | |||
QUIC supports many ACK ranges, opposed to TCP's 3 SACK ranges. In | QUIC supports many ACK ranges, as opposed to TCP's three SACK ranges. | |||
high loss environments, this speeds recovery, reduces spurious | In high-loss environments, this speeds recovery, reduces spurious | |||
retransmits, and ensures forward progress without relying on | retransmits, and ensures forward progress without relying on | |||
timeouts. | timeouts. | |||
4.6. Explicit Correction For Delayed Acknowledgments | 4.6. Explicit Correction for Delayed Acknowledgments | |||
QUIC endpoints measure the delay incurred between when a packet is | QUIC endpoints measure the delay incurred between when a packet is | |||
received and when the corresponding acknowledgment is sent, allowing | received and when the corresponding acknowledgment is sent, allowing | |||
a peer to maintain a more accurate round-trip time estimate; see | a peer to maintain a more accurate RTT estimate; see Section 13.2 of | |||
Section 13.2 of [QUIC-TRANSPORT]. | [QUIC-TRANSPORT]. | |||
4.7. Probe Timeout Replaces RTO and TLP | 4.7. Probe Timeout Replaces RTO and TLP | |||
QUIC uses a probe timeout (PTO; see Section 6.2), with a timer based | QUIC uses a probe timeout (PTO; see Section 6.2), with a timer based | |||
on TCP's RTO computation; see [RFC6297]. QUIC's PTO includes the | on TCP's retransmission timeout (RTO) computation; see [RFC6298]. | |||
peer's maximum expected acknowledgment delay instead of using a fixed | QUIC's PTO includes the peer's maximum expected acknowledgment delay | |||
minimum timeout. | instead of using a fixed minimum timeout. | |||
Similar to the RACK-TLP loss detection algorithm for TCP ([RACK]), | Similar to the RACK-TLP loss detection algorithm for TCP [RFC8985], | |||
QUIC does not collapse the congestion window when the PTO expires, | QUIC does not collapse the congestion window when the PTO expires, | |||
since a single packet loss at the tail does not indicate persistent | since a single packet loss at the tail does not indicate persistent | |||
congestion. Instead, QUIC collapses the congestion window when | congestion. Instead, QUIC collapses the congestion window when | |||
persistent congestion is declared; see Section 7.6. In doing this, | persistent congestion is declared; see Section 7.6. In doing this, | |||
QUIC avoids unnecessary congestion window reductions, obviating the | QUIC avoids unnecessary congestion window reductions, obviating the | |||
need for correcting mechanisms such as F-RTO ([RFC5682]). Since QUIC | need for correcting mechanisms such as Forward RTO-Recovery (F-RTO) | |||
does not collapse the congestion window on a PTO expiration, a QUIC | [RFC5682]. Since QUIC does not collapse the congestion window on a | |||
sender is not limited from sending more in-flight packets after a PTO | PTO expiration, a QUIC sender is not limited from sending more in- | |||
expiration if it still has available congestion window. This occurs | flight packets after a PTO expiration if it still has available | |||
when a sender is application-limited and the PTO timer expires. This | congestion window. This occurs when a sender is application limited | |||
is more aggressive than TCP's RTO mechanism when application-limited, | and the PTO timer expires. This is more aggressive than TCP's RTO | |||
but identical when not application-limited. | mechanism when application limited, but identical when not | |||
application limited. | ||||
QUIC allows probe packets to temporarily exceed the congestion window | QUIC allows probe packets to temporarily exceed the congestion window | |||
whenever the timer expires. | whenever the timer expires. | |||
4.8. The Minimum Congestion Window is Two Packets | 4.8. The Minimum Congestion Window Is Two Packets | |||
TCP uses a minimum congestion window of one packet. However, loss of | TCP uses a minimum congestion window of one packet. However, loss of | |||
that single packet means that the sender needs to waiting for a PTO | that single packet means that the sender needs to wait for a PTO to | |||
(Section 6.2) to recover, which can be much longer than a round-trip | recover (Section 6.2), which can be much longer than an RTT. Sending | |||
time. Sending a single ack-eliciting packet also increases the | a single ack-eliciting packet also increases the chances of incurring | |||
chances of incurring additional latency when a receiver delays its | additional latency when a receiver delays its acknowledgment. | |||
acknowledgment. | ||||
QUIC therefore recommends that the minimum congestion window be two | QUIC therefore recommends that the minimum congestion window be two | |||
packets. While this increases network load, it is considered safe, | packets. While this increases network load, it is considered safe | |||
since the sender will still reduce its sending rate exponentially | since the sender will still reduce its sending rate exponentially | |||
under persistent congestion (Section 6.2). | under persistent congestion (Section 6.2). | |||
4.9. Handshake Packets Are Not Special | ||||
TCP treats the loss of SYN or SYN-ACK packet as persistent congestion | ||||
and reduces the congestion window to one packet; see [RFC5681]. QUIC | ||||
treats loss of a packet containing handshake data the same as other | ||||
losses. | ||||
5. Estimating the Round-Trip Time | 5. Estimating the Round-Trip Time | |||
At a high level, an endpoint measures the time from when a packet was | At a high level, an endpoint measures the time from when a packet was | |||
sent to when it is acknowledged as a round-trip time (RTT) sample. | sent to when it is acknowledged as an RTT sample. The endpoint uses | |||
The endpoint uses RTT samples and peer-reported host delays (see | RTT samples and peer-reported host delays (see Section 13.2 of | |||
Section 13.2 of [QUIC-TRANSPORT]) to generate a statistical | [QUIC-TRANSPORT]) to generate a statistical description of the | |||
description of the network path's RTT. An endpoint computes the | network path's RTT. An endpoint computes the following three values | |||
following three values for each path: the minimum value over a period | for each path: the minimum value over a period of time (min_rtt), an | |||
of time (min_rtt), an exponentially-weighted moving average | exponentially weighted moving average (smoothed_rtt), and the mean | |||
(smoothed_rtt), and the mean deviation (referred to as "variation" in | deviation (referred to as "variation" in the rest of this document) | |||
the rest of this document) in the observed RTT samples (rttvar). | in the observed RTT samples (rttvar). | |||
5.1. Generating RTT samples | 5.1. Generating RTT Samples | |||
An endpoint generates an RTT sample on receiving an ACK frame that | An endpoint generates an RTT sample on receiving an ACK frame that | |||
meets the following two conditions: | meets the following two conditions: | |||
* the largest acknowledged packet number is newly acknowledged, and | * the largest acknowledged packet number is newly acknowledged, and | |||
* at least one of the newly acknowledged packets was ack-eliciting. | * at least one of the newly acknowledged packets was ack-eliciting. | |||
The RTT sample, latest_rtt, is generated as the time elapsed since | The RTT sample, latest_rtt, is generated as the time elapsed since | |||
the largest acknowledged packet was sent: | the largest acknowledged packet was sent: | |||
skipping to change at page 9, line 18 ¶ | skipping to change at line 348 ¶ | |||
the RTT sample measurement, it is used to adjust the RTT sample in | the RTT sample measurement, it is used to adjust the RTT sample in | |||
subsequent computations of smoothed_rtt and rttvar (Section 5.3). | subsequent computations of smoothed_rtt and rttvar (Section 5.3). | |||
To avoid generating multiple RTT samples for a single packet, an ACK | To avoid generating multiple RTT samples for a single packet, an ACK | |||
frame SHOULD NOT be used to update RTT estimates if it does not newly | frame SHOULD NOT be used to update RTT estimates if it does not newly | |||
acknowledge the largest acknowledged packet. | acknowledge the largest acknowledged packet. | |||
An RTT sample MUST NOT be generated on receiving an ACK frame that | An RTT sample MUST NOT be generated on receiving an ACK frame that | |||
does not newly acknowledge at least one ack-eliciting packet. A peer | does not newly acknowledge at least one ack-eliciting packet. A peer | |||
usually does not send an ACK frame when only non-ack-eliciting | usually does not send an ACK frame when only non-ack-eliciting | |||
packets are received. Therefore an ACK frame that contains | packets are received. Therefore, an ACK frame that contains | |||
acknowledgments for only non-ack-eliciting packets could include an | acknowledgments for only non-ack-eliciting packets could include an | |||
arbitrarily large ACK Delay value. Ignoring such ACK frames avoids | arbitrarily large ACK Delay value. Ignoring such ACK frames avoids | |||
complications in subsequent smoothed_rtt and rttvar computations. | complications in subsequent smoothed_rtt and rttvar computations. | |||
A sender might generate multiple RTT samples per RTT when multiple | A sender might generate multiple RTT samples per RTT when multiple | |||
ACK frames are received within an RTT. As suggested in [RFC6298], | ACK frames are received within an RTT. As suggested in [RFC6298], | |||
doing so might result in inadequate history in smoothed_rtt and | doing so might result in inadequate history in smoothed_rtt and | |||
rttvar. Ensuring that RTT estimates retain sufficient history is an | rttvar. Ensuring that RTT estimates retain sufficient history is an | |||
open research question. | open research question. | |||
5.2. Estimating min_rtt | 5.2. Estimating min_rtt | |||
min_rtt is the sender's estimate of the minimum RTT observed for a | min_rtt is the sender's estimate of the minimum RTT observed for a | |||
given network path over a period of time. In this document, min_rtt | given network path over a period of time. In this document, min_rtt | |||
is used by loss detection to reject implausibly small rtt samples. | is used by loss detection to reject implausibly small RTT samples. | |||
min_rtt MUST be set to the latest_rtt on the first RTT sample. | min_rtt MUST be set to the latest_rtt on the first RTT sample. | |||
min_rtt MUST be set to the lesser of min_rtt and latest_rtt | min_rtt MUST be set to the lesser of min_rtt and latest_rtt | |||
(Section 5.1) on all other samples. | (Section 5.1) on all other samples. | |||
An endpoint uses only locally observed times in computing the min_rtt | An endpoint uses only locally observed times in computing the min_rtt | |||
and does not adjust for acknowledgment delays reported by the peer. | and does not adjust for acknowledgment delays reported by the peer. | |||
Doing so allows the endpoint to set a lower bound for the | Doing so allows the endpoint to set a lower bound for the | |||
smoothed_rtt based entirely on what it observes (see Section 5.3), | smoothed_rtt based entirely on what it observes (see Section 5.3) and | |||
and limits potential underestimation due to erroneously-reported | limits potential underestimation due to erroneously reported delays | |||
delays by the peer. | by the peer. | |||
The RTT for a network path may change over time. If a path's actual | The RTT for a network path may change over time. If a path's actual | |||
RTT decreases, the min_rtt will adapt immediately on the first low | RTT decreases, the min_rtt will adapt immediately on the first low | |||
sample. If the path's actual RTT increases however, the min_rtt will | sample. If the path's actual RTT increases, however, the min_rtt | |||
not adapt to it, allowing future RTT samples that are smaller than | will not adapt to it, allowing future RTT samples that are smaller | |||
the new RTT to be included in smoothed_rtt. | than the new RTT to be included in smoothed_rtt. | |||
Endpoints SHOULD set the min_rtt to the newest RTT sample after | Endpoints SHOULD set the min_rtt to the newest RTT sample after | |||
persistent congestion is established. This is to allow a connection | persistent congestion is established. This avoids repeatedly | |||
to reset its estimate of min_rtt and smoothed_rtt (Section 5.3) after | declaring persistent congestion when the RTT increases. This also | |||
a disruptive network event, and because it is possible that an | allows a connection to reset its estimate of min_rtt and smoothed_rtt | |||
increase in path delay resulted in persistent congestion being | after a disruptive network event; see Section 5.3. | |||
incorrectly declared. | ||||
Endpoints MAY re-establish the min_rtt at other times in the | Endpoints MAY reestablish the min_rtt at other times in the | |||
connection, such as when traffic volume is low and an acknowledgment | connection, such as when traffic volume is low and an acknowledgment | |||
is received with a low acknowledgment delay. Implementations SHOULD | is received with a low acknowledgment delay. Implementations SHOULD | |||
NOT refresh the min_rtt value too often, since the actual minimum RTT | NOT refresh the min_rtt value too often since the actual minimum RTT | |||
of the path is not frequently observable. | of the path is not frequently observable. | |||
5.3. Estimating smoothed_rtt and rttvar | 5.3. Estimating smoothed_rtt and rttvar | |||
smoothed_rtt is an exponentially-weighted moving average of an | smoothed_rtt is an exponentially weighted moving average of an | |||
endpoint's RTT samples, and rttvar estimates the variation in the RTT | endpoint's RTT samples, and rttvar estimates the variation in the RTT | |||
samples using a mean variation. | samples using a mean variation. | |||
The calculation of smoothed_rtt uses RTT samples after adjusting them | The calculation of smoothed_rtt uses RTT samples after adjusting them | |||
for acknowledgment delays. These delays are decoded from the ACK | for acknowledgment delays. These delays are decoded from the ACK | |||
Delay field of ACK frames as described in Section 19.3 of | Delay field of ACK frames as described in Section 19.3 of | |||
[QUIC-TRANSPORT]. | [QUIC-TRANSPORT]. | |||
The peer might report acknowledgment delays that are larger than the | The peer might report acknowledgment delays that are larger than the | |||
peer's max_ack_delay during the handshake (Section 13.2.1 of | peer's max_ack_delay during the handshake (Section 13.2.1 of | |||
[QUIC-TRANSPORT]). To account for this, the endpoint SHOULD ignore | [QUIC-TRANSPORT]). To account for this, the endpoint SHOULD ignore | |||
max_ack_delay until the handshake is confirmed, as defined in | max_ack_delay until the handshake is confirmed, as defined in | |||
Section 4.1.2 of [QUIC-TLS]. When they occur, these large | Section 4.1.2 of [QUIC-TLS]. When they occur, these large | |||
acknowledgment delays are likely to be non-repeating and limited to | acknowledgment delays are likely to be non-repeating and limited to | |||
the handshake. The endpoint can therefore use them without limiting | the handshake. The endpoint can therefore use them without limiting | |||
them to the max_ack_delay, avoiding unnecessary inflation of the RTT | them to the max_ack_delay, avoiding unnecessary inflation of the RTT | |||
estimate. | estimate. | |||
Note that a large acknowledgment delay can result in a substantially | Note that a large acknowledgment delay can result in a substantially | |||
inflated smoothed_rtt, if there is either an error in the peer's | inflated smoothed_rtt if there is an error either in the peer's | |||
reporting of the acknowledgment delay or in the endpoint's min_rtt | reporting of the acknowledgment delay or in the endpoint's min_rtt | |||
estimate. Therefore, prior to handshake confirmation, an endpoint | estimate. Therefore, prior to handshake confirmation, an endpoint | |||
MAY ignore RTT samples if adjusting the RTT sample for acknowledgment | MAY ignore RTT samples if adjusting the RTT sample for acknowledgment | |||
delay causes the sample to be less than the min_rtt. | delay causes the sample to be less than the min_rtt. | |||
After the handshake is confirmed, any acknowledgment delays reported | After the handshake is confirmed, any acknowledgment delays reported | |||
by the peer that are greater than the peer's max_ack_delay are | by the peer that are greater than the peer's max_ack_delay are | |||
attributed to unintentional but potentially repeating delays, such as | attributed to unintentional but potentially repeating delays, such as | |||
scheduler latency at the peer or loss of previous acknowledgments. | scheduler latency at the peer or loss of previous acknowledgments. | |||
Excess delays could also be due to a non-compliant receiver. | Excess delays could also be due to a noncompliant receiver. | |||
Therefore, these extra delays are considered effectively part of path | Therefore, these extra delays are considered effectively part of path | |||
delay and incorporated into the RTT estimate. | delay and incorporated into the RTT estimate. | |||
Therefore, when adjusting an RTT sample using peer-reported | Therefore, when adjusting an RTT sample using peer-reported | |||
acknowledgment delays, an endpoint: | acknowledgment delays, an endpoint: | |||
* MAY ignore the acknowledgment delay for Initial packets, since | * MAY ignore the acknowledgment delay for Initial packets, since | |||
these acknowledgments are not delayed by the peer (Section 13.2.1 | these acknowledgments are not delayed by the peer (Section 13.2.1 | |||
of [QUIC-TRANSPORT]); | of [QUIC-TRANSPORT]); | |||
skipping to change at page 11, line 49 ¶ | skipping to change at line 474 ¶ | |||
smoothed_rtt and rttvar are initialized as follows, where kInitialRtt | smoothed_rtt and rttvar are initialized as follows, where kInitialRtt | |||
contains the initial RTT value: | contains the initial RTT value: | |||
smoothed_rtt = kInitialRtt | smoothed_rtt = kInitialRtt | |||
rttvar = kInitialRtt / 2 | rttvar = kInitialRtt / 2 | |||
RTT samples for the network path are recorded in latest_rtt; see | RTT samples for the network path are recorded in latest_rtt; see | |||
Section 5.1. On the first RTT sample after initialization, the | Section 5.1. On the first RTT sample after initialization, the | |||
estimator is reset using that sample. This ensures that the | estimator is reset using that sample. This ensures that the | |||
estimator retains no history of past samples. | estimator retains no history of past samples. Packets sent on other | |||
paths do not contribute RTT samples to the current path, as described | ||||
in Section 9.4 of [QUIC-TRANSPORT]. | ||||
On the first RTT sample after initialization, smoothed_rtt and rttvar | On the first RTT sample after initialization, smoothed_rtt and rttvar | |||
are set as follows: | are set as follows: | |||
smoothed_rtt = latest_rtt | smoothed_rtt = latest_rtt | |||
rttvar = latest_rtt / 2 | rttvar = latest_rtt / 2 | |||
On subsequent RTT samples, smoothed_rtt and rttvar evolve as follows: | On subsequent RTT samples, smoothed_rtt and rttvar evolve as follows: | |||
ack_delay = decoded acknowledgment delay from ACK frame | ack_delay = decoded acknowledgment delay from ACK frame | |||
if (handshake confirmed): | if (handshake confirmed): | |||
ack_delay = min(ack_delay, max_ack_delay) | ack_delay = min(ack_delay, max_ack_delay) | |||
adjusted_rtt = latest_rtt | adjusted_rtt = latest_rtt | |||
if (min_rtt + ack_delay < latest_rtt): | if (latest_rtt >= min_rtt + ack_delay): | |||
adjusted_rtt = latest_rtt - ack_delay | adjusted_rtt = latest_rtt - ack_delay | |||
smoothed_rtt = 7/8 * smoothed_rtt + 1/8 * adjusted_rtt | smoothed_rtt = 7/8 * smoothed_rtt + 1/8 * adjusted_rtt | |||
rttvar_sample = abs(smoothed_rtt - adjusted_rtt) | rttvar_sample = abs(smoothed_rtt - adjusted_rtt) | |||
rttvar = 3/4 * rttvar + 1/4 * rttvar_sample | rttvar = 3/4 * rttvar + 1/4 * rttvar_sample | |||
6. Loss Detection | 6. Loss Detection | |||
QUIC senders use acknowledgments to detect lost packets, and a probe | QUIC senders use acknowledgments to detect lost packets and a PTO to | |||
time out (see Section 6.2) to ensure acknowledgments are received. | ensure acknowledgments are received; see Section 6.2. This section | |||
This section provides a description of these algorithms. | provides a description of these algorithms. | |||
If a packet is lost, the QUIC transport needs to recover from that | If a packet is lost, the QUIC transport needs to recover from that | |||
loss, such as by retransmitting the data, sending an updated frame, | loss, such as by retransmitting the data, sending an updated frame, | |||
or discarding the frame. For more information, see Section 13.3 of | or discarding the frame. For more information, see Section 13.3 of | |||
[QUIC-TRANSPORT]. | [QUIC-TRANSPORT]. | |||
Loss detection is separate per packet number space, unlike RTT | Loss detection is separate per packet number space, unlike RTT | |||
measurement and congestion control, because RTT and congestion | measurement and congestion control, because RTT and congestion | |||
control are properties of the path, whereas loss detection also | control are properties of the path, whereas loss detection also | |||
relies upon key availability. | relies upon key availability. | |||
6.1. Acknowledgment-Based Detection | 6.1. Acknowledgment-Based Detection | |||
Acknowledgment-based loss detection implements the spirit of TCP's | Acknowledgment-based loss detection implements the spirit of TCP's | |||
Fast Retransmit ([RFC5681]), Early Retransmit ([RFC5827]), FACK | Fast Retransmit [RFC5681], Early Retransmit [RFC5827], Forward | |||
([FACK]), SACK loss recovery ([RFC6675]), and RACK-TLP ([RACK]). | Acknowledgment [FACK], SACK loss recovery [RFC6675], and RACK-TLP | |||
This section provides an overview of how these algorithms are | [RFC8985]. This section provides an overview of how these algorithms | |||
implemented in QUIC. | are implemented in QUIC. | |||
A packet is declared lost if it meets all the following conditions: | A packet is declared lost if it meets all of the following | |||
conditions: | ||||
* The packet is unacknowledged, in-flight, and was sent prior to an | * The packet is unacknowledged, in flight, and was sent prior to an | |||
acknowledged packet. | acknowledged packet. | |||
* The packet was sent kPacketThreshold packets before an | * The packet was sent kPacketThreshold packets before an | |||
acknowledged packet (Section 6.1.1), or it was sent long enough in | acknowledged packet (Section 6.1.1), or it was sent long enough in | |||
the past (Section 6.1.2). | the past (Section 6.1.2). | |||
The acknowledgment indicates that a packet sent later was delivered, | The acknowledgment indicates that a packet sent later was delivered, | |||
and the packet and time thresholds provide some tolerance for packet | and the packet and time thresholds provide some tolerance for packet | |||
reordering. | reordering. | |||
Spuriously declaring packets as lost leads to unnecessary | Spuriously declaring packets as lost leads to unnecessary | |||
retransmissions and may result in degraded performance due to the | retransmissions and may result in degraded performance due to the | |||
actions of the congestion controller upon detecting loss. | actions of the congestion controller upon detecting loss. | |||
Implementations can detect spurious retransmissions and increase the | Implementations can detect spurious retransmissions and increase the | |||
reordering threshold in packets or time to reduce future spurious | packet or time reordering threshold to reduce future spurious | |||
retransmissions and loss events. Implementations with adaptive time | retransmissions and loss events. Implementations with adaptive time | |||
thresholds MAY choose to start with smaller initial reordering | thresholds MAY choose to start with smaller initial reordering | |||
thresholds to minimize recovery latency. | thresholds to minimize recovery latency. | |||
6.1.1. Packet Threshold | 6.1.1. Packet Threshold | |||
The RECOMMENDED initial value for the packet reordering threshold | The RECOMMENDED initial value for the packet reordering threshold | |||
(kPacketThreshold) is 3, based on best practices for TCP loss | (kPacketThreshold) is 3, based on best practices for TCP loss | |||
detection ([RFC5681], [RFC6675]). In order to remain similar to TCP, | detection [RFC5681] [RFC6675]. In order to remain similar to TCP, | |||
implementations SHOULD NOT use a packet threshold less than 3; see | implementations SHOULD NOT use a packet threshold less than 3; see | |||
[RFC5681]. | [RFC5681]. | |||
Some networks may exhibit higher degrees of packet reordering, | Some networks may exhibit higher degrees of packet reordering, | |||
causing a sender to detect spurious losses. Additionally, packet | causing a sender to detect spurious losses. Additionally, packet | |||
reordering could be more common with QUIC than TCP, because network | reordering could be more common with QUIC than TCP because network | |||
elements that could observe and reorder TCP packets cannot do that | elements that could observe and reorder TCP packets cannot do that | |||
for QUIC, because QUIC packet numbers are encrypted. Algorithms that | for QUIC and also because QUIC packet numbers are encrypted. | |||
increase the reordering threshold after spuriously detecting losses, | Algorithms that increase the reordering threshold after spuriously | |||
such as RACK [RACK], have proven to be useful in TCP and are expected | detecting losses, such as RACK [RFC8985], have proven to be useful in | |||
to be at least as useful in QUIC. | TCP and are expected to be at least as useful in QUIC. | |||
6.1.2. Time Threshold | 6.1.2. Time Threshold | |||
Once a later packet within the same packet number space has been | Once a later packet within the same packet number space has been | |||
acknowledged, an endpoint SHOULD declare an earlier packet lost if it | acknowledged, an endpoint SHOULD declare an earlier packet lost if it | |||
was sent a threshold amount of time in the past. To avoid declaring | was sent a threshold amount of time in the past. To avoid declaring | |||
packets as lost too early, this time threshold MUST be set to at | packets as lost too early, this time threshold MUST be set to at | |||
least the local timer granularity, as indicated by the kGranularity | least the local timer granularity, as indicated by the kGranularity | |||
constant. The time threshold is: | constant. The time threshold is: | |||
skipping to change at page 14, line 12 ¶ | skipping to change at line 584 ¶ | |||
Using max(smoothed_rtt, latest_rtt) protects from the two following | Using max(smoothed_rtt, latest_rtt) protects from the two following | |||
cases: | cases: | |||
* the latest RTT sample is lower than the smoothed RTT, perhaps due | * the latest RTT sample is lower than the smoothed RTT, perhaps due | |||
to reordering where the acknowledgment encountered a shorter path; | to reordering where the acknowledgment encountered a shorter path; | |||
* the latest RTT sample is higher than the smoothed RTT, perhaps due | * the latest RTT sample is higher than the smoothed RTT, perhaps due | |||
to a sustained increase in the actual RTT, but the smoothed RTT | to a sustained increase in the actual RTT, but the smoothed RTT | |||
has not yet caught up. | has not yet caught up. | |||
The RECOMMENDED time threshold (kTimeThreshold), expressed as a | The RECOMMENDED time threshold (kTimeThreshold), expressed as an RTT | |||
round-trip time multiplier, is 9/8. The RECOMMENDED value of the | multiplier, is 9/8. The RECOMMENDED value of the timer granularity | |||
timer granularity (kGranularity) is 1ms. | (kGranularity) is 1 millisecond. | |||
Note: TCP's RACK ([RACK]) specifies a slightly larger threshold, | | Note: TCP's RACK [RFC8985] specifies a slightly larger | |||
equivalent to 5/4, for a similar purpose. Experience with QUIC | | threshold, equivalent to 5/4, for a similar purpose. | |||
shows that 9/8 works well. | | Experience with QUIC shows that 9/8 works well. | |||
Implementations MAY experiment with absolute thresholds, thresholds | Implementations MAY experiment with absolute thresholds, thresholds | |||
from previous connections, adaptive thresholds, or including RTT | from previous connections, adaptive thresholds, or the including of | |||
variation. Smaller thresholds reduce reordering resilience and | RTT variation. Smaller thresholds reduce reordering resilience and | |||
increase spurious retransmissions, and larger thresholds increase | increase spurious retransmissions, and larger thresholds increase | |||
loss detection delay. | loss detection delay. | |||
6.2. Probe Timeout | 6.2. Probe Timeout | |||
A Probe Timeout (PTO) triggers sending one or two probe datagrams | A Probe Timeout (PTO) triggers the sending of one or two probe | |||
when ack-eliciting packets are not acknowledged within the expected | datagrams when ack-eliciting packets are not acknowledged within the | |||
period of time or the server may not have validated the client's | expected period of time or the server may not have validated the | |||
address. A PTO enables a connection to recover from loss of tail | client's address. A PTO enables a connection to recover from loss of | |||
packets or acknowledgments. | tail packets or acknowledgments. | |||
As with loss detection, the probe timeout is per packet number space. | As with loss detection, the PTO is per packet number space. That is, | |||
That is, a PTO value is computed per packet number space. | a PTO value is computed per packet number space. | |||
A PTO timer expiration event does not indicate packet loss and MUST | A PTO timer expiration event does not indicate packet loss and MUST | |||
NOT cause prior unacknowledged packets to be marked as lost. When an | NOT cause prior unacknowledged packets to be marked as lost. When an | |||
acknowledgment is received that newly acknowledges packets, loss | acknowledgment is received that newly acknowledges packets, loss | |||
detection proceeds as dictated by packet and time threshold | detection proceeds as dictated by the packet and time threshold | |||
mechanisms; see Section 6.1. | mechanisms; see Section 6.1. | |||
The PTO algorithm used in QUIC implements the reliability functions | The PTO algorithm used in QUIC implements the reliability functions | |||
of Tail Loss Probe [RACK], RTO [RFC5681], and F-RTO algorithms for | of Tail Loss Probe [RFC8985], RTO [RFC5681], and F-RTO algorithms for | |||
TCP [RFC5682]. The timeout computation is based on TCP's | TCP [RFC5682]. The timeout computation is based on TCP's RTO period | |||
retransmission timeout period [RFC6298]. | [RFC6298]. | |||
6.2.1. Computing PTO | 6.2.1. Computing PTO | |||
When an ack-eliciting packet is transmitted, the sender schedules a | When an ack-eliciting packet is transmitted, the sender schedules a | |||
timer for the PTO period as follows: | timer for the PTO period as follows: | |||
PTO = smoothed_rtt + max(4*rttvar, kGranularity) + max_ack_delay | PTO = smoothed_rtt + max(4*rttvar, kGranularity) + max_ack_delay | |||
The PTO period is the amount of time that a sender ought to wait for | The PTO period is the amount of time that a sender ought to wait for | |||
an acknowledgment of a sent packet. This time period includes the | an acknowledgment of a sent packet. This time period includes the | |||
estimated network roundtrip-time (smoothed_rtt), the variation in the | estimated network RTT (smoothed_rtt), the variation in the estimate | |||
estimate (4*rttvar), and max_ack_delay, to account for the maximum | (4*rttvar), and max_ack_delay, to account for the maximum time by | |||
time by which a receiver might delay sending an acknowledgment. | which a receiver might delay sending an acknowledgment. | |||
When the PTO is armed for Initial or Handshake packet number spaces, | When the PTO is armed for Initial or Handshake packet number spaces, | |||
the max_ack_delay in the PTO period computation is set to 0, since | the max_ack_delay in the PTO period computation is set to 0, since | |||
the peer is expected to not delay these packets intentionally; see | the peer is expected to not delay these packets intentionally; see | |||
13.2.1 of [QUIC-TRANSPORT]. | Section 13.2.1 of [QUIC-TRANSPORT]. | |||
The PTO period MUST be at least kGranularity, to avoid the timer | The PTO period MUST be at least kGranularity to avoid the timer | |||
expiring immediately. | expiring immediately. | |||
When ack-eliciting packets in multiple packet number spaces are in | When ack-eliciting packets in multiple packet number spaces are in | |||
flight, the timer MUST be set to the earlier value of the Initial and | flight, the timer MUST be set to the earlier value of the Initial and | |||
Handshake packet number spaces. | Handshake packet number spaces. | |||
An endpoint MUST NOT set its PTO timer for the application data | An endpoint MUST NOT set its PTO timer for the Application Data | |||
packet number space until the handshake is confirmed. Doing so | packet number space until the handshake is confirmed. Doing so | |||
prevents the endpoint from retransmitting information in packets when | prevents the endpoint from retransmitting information in packets when | |||
either the peer does not yet have the keys to process them or the | either the peer does not yet have the keys to process them or the | |||
endpoint does not yet have the keys to process their acknowledgments. | endpoint does not yet have the keys to process their acknowledgments. | |||
For example, this can happen when a client sends 0-RTT packets to the | For example, this can happen when a client sends 0-RTT packets to the | |||
server; it does so without knowing whether the server will be able to | server; it does so without knowing whether the server will be able to | |||
decrypt them. Similarly, this can happen when a server sends 1-RTT | decrypt them. Similarly, this can happen when a server sends 1-RTT | |||
packets before confirming that the client has verified the server's | packets before confirming that the client has verified the server's | |||
certificate and can therefore read these 1-RTT packets. | certificate and can therefore read these 1-RTT packets. | |||
A sender SHOULD restart its PTO timer every time an ack-eliciting | A sender SHOULD restart its PTO timer every time an ack-eliciting | |||
packet is sent or acknowledged, or when Initial or Handshake keys are | packet is sent or acknowledged, or when Initial or Handshake keys are | |||
discarded (Section 4.9 of [QUIC-TLS]). This ensures the PTO is | discarded (Section 4.9 of [QUIC-TLS]). This ensures the PTO is | |||
always set based on the latest estimate of the round-trip time and | always set based on the latest estimate of the RTT and for the | |||
for the correct packet across packet number spaces. | correct packet across packet number spaces. | |||
When a PTO timer expires, the PTO backoff MUST be increased, | When a PTO timer expires, the PTO backoff MUST be increased, | |||
resulting in the PTO period being set to twice its current value. | resulting in the PTO period being set to twice its current value. | |||
The PTO backoff factor is reset when an acknowledgment is received, | The PTO backoff factor is reset when an acknowledgment is received, | |||
except in the following case. A server might take longer to respond | except in the following case. A server might take longer to respond | |||
to packets during the handshake than otherwise. To protect such a | to packets during the handshake than otherwise. To protect such a | |||
server from repeated client probes, the PTO backoff is not reset at a | server from repeated client probes, the PTO backoff is not reset at a | |||
client that is not yet certain that the server has finished | client that is not yet certain that the server has finished | |||
validating the client's address. That is, a client does not reset | validating the client's address. That is, a client does not reset | |||
the PTO backoff factor on receiving acknowledgments in Initial | the PTO backoff factor on receiving acknowledgments in Initial | |||
packets. | packets. | |||
This exponential reduction in the sender's rate is important because | This exponential reduction in the sender's rate is important because | |||
consecutive PTOs might be caused by loss of packets or | consecutive PTOs might be caused by loss of packets or | |||
acknowledgments due to severe congestion. Even when there are ack- | acknowledgments due to severe congestion. Even when there are ack- | |||
eliciting packets in-flight in multiple packet number spaces, the | eliciting packets in flight in multiple packet number spaces, the | |||
exponential increase in probe timeout occurs across all spaces to | exponential increase in PTO occurs across all spaces to prevent | |||
prevent excess load on the network. For example, a timeout in the | excess load on the network. For example, a timeout in the Initial | |||
Initial packet number space doubles the length of the timeout in the | packet number space doubles the length of the timeout in the | |||
Handshake packet number space. | Handshake packet number space. | |||
The total length of time over which consecutive PTOs expire is | The total length of time over which consecutive PTOs expire is | |||
limited by the idle timeout. | limited by the idle timeout. | |||
The PTO timer MUST NOT be set if a timer is set for time threshold | The PTO timer MUST NOT be set if a timer is set for time threshold | |||
loss detection; see Section 6.1.2. A timer that is set for time | loss detection; see Section 6.1.2. A timer that is set for time | |||
threshold loss detection will expire earlier than the PTO timer in | threshold loss detection will expire earlier than the PTO timer in | |||
most cases and is less likely to spuriously retransmit data. | most cases and is less likely to spuriously retransmit data. | |||
6.2.2. Handshakes and New Paths | 6.2.2. Handshakes and New Paths | |||
Resumed connections over the same network MAY use the previous | Resumed connections over the same network MAY use the previous | |||
connection's final smoothed RTT value as the resumed connection's | connection's final smoothed RTT value as the resumed connection's | |||
initial RTT. When no previous RTT is available, the initial RTT | initial RTT. When no previous RTT is available, the initial RTT | |||
SHOULD be set to 333ms. This results in handshakes starting with a | SHOULD be set to 333 milliseconds. This results in handshakes | |||
PTO of 1 second, as recommended for TCP's initial retransmission | starting with a PTO of 1 second, as recommended for TCP's initial | |||
timeout; see Section 2 of [RFC6298]. | RTO; see Section 2 of [RFC6298]. | |||
A connection MAY use the delay between sending a PATH_CHALLENGE and | A connection MAY use the delay between sending a PATH_CHALLENGE and | |||
receiving a PATH_RESPONSE to set the initial RTT (see kInitialRtt in | receiving a PATH_RESPONSE to set the initial RTT (see kInitialRtt in | |||
Appendix A.2) for a new path, but the delay SHOULD NOT be considered | Appendix A.2) for a new path, but the delay SHOULD NOT be considered | |||
an RTT sample. | an RTT sample. | |||
Initial packets and Handshake packets could be never acknowledged, | When the Initial keys and Handshake keys are discarded (see | |||
but they are removed from bytes in flight when the Initial and | Section 6.4), any Initial packets and Handshake packets can no longer | |||
Handshake keys are discarded, as described below in Section 6.4. | be acknowledged, so they are removed from bytes in flight. When | |||
When Initial or Handshake keys are discarded, the PTO and loss | Initial or Handshake keys are discarded, the PTO and loss detection | |||
detection timers MUST be reset, because discarding keys indicates | timers MUST be reset, because discarding keys indicates forward | |||
forward progress and the loss detection timer might have been set for | progress and the loss detection timer might have been set for a now- | |||
a now discarded packet number space. | discarded packet number space. | |||
6.2.2.1. Before Address Validation | 6.2.2.1. Before Address Validation | |||
Until the server has validated the client's address on the path, the | Until the server has validated the client's address on the path, the | |||
amount of data it can send is limited to three times the amount of | amount of data it can send is limited to three times the amount of | |||
data received, as specified in Section 8.1 of [QUIC-TRANSPORT]. If | data received, as specified in Section 8.1 of [QUIC-TRANSPORT]. If | |||
no additional data can be sent, the server's PTO timer MUST NOT be | no additional data can be sent, the server's PTO timer MUST NOT be | |||
armed until datagrams have been received from the client, because | armed until datagrams have been received from the client because | |||
packets sent on PTO count against the anti-amplification limit. Note | packets sent on PTO count against the anti-amplification limit. | |||
that the server could fail to validate the client's address even if | ||||
0-RTT is accepted. | When the server receives a datagram from the client, the | |||
amplification limit is increased and the server resets the PTO timer. | ||||
If the PTO timer is then set to a time in the past, it is executed | ||||
immediately. Doing so avoids sending new 1-RTT packets prior to | ||||
packets critical to the completion of the handshake. In particular, | ||||
this can happen when 0-RTT is accepted but the server fails to | ||||
validate the client's address. | ||||
Since the server could be blocked until more datagrams are received | Since the server could be blocked until more datagrams are received | |||
from the client, it is the client's responsibility to send packets to | from the client, it is the client's responsibility to send packets to | |||
unblock the server until it is certain that the server has finished | unblock the server until it is certain that the server has finished | |||
its address validation (see Section 8 of [QUIC-TRANSPORT]). That is, | its address validation (see Section 8 of [QUIC-TRANSPORT]). That is, | |||
the client MUST set the probe timer if the client has not received an | the client MUST set the PTO timer if the client has not received an | |||
acknowledgment for any of its Handshake packets and the handshake is | acknowledgment for any of its Handshake packets and the handshake is | |||
not confirmed (see Section 4.1.2 of [QUIC-TLS]), even if there are no | not confirmed (see Section 4.1.2 of [QUIC-TLS]), even if there are no | |||
packets in flight. When the PTO fires, the client MUST send a | packets in flight. When the PTO fires, the client MUST send a | |||
Handshake packet if it has Handshake keys, otherwise it MUST send an | Handshake packet if it has Handshake keys, otherwise it MUST send an | |||
Initial packet in a UDP datagram with a payload of at least 1200 | Initial packet in a UDP datagram with a payload of at least 1200 | |||
bytes. | bytes. | |||
6.2.3. Speeding Up Handshake Completion | 6.2.3. Speeding up Handshake Completion | |||
When a server receives an Initial packet containing duplicate CRYPTO | When a server receives an Initial packet containing duplicate CRYPTO | |||
data, it can assume the client did not receive all of the server's | data, it can assume the client did not receive all of the server's | |||
CRYPTO data sent in Initial packets, or the client's estimated RTT is | CRYPTO data sent in Initial packets, or the client's estimated RTT is | |||
too small. When a client receives Handshake or 1-RTT packets prior | too small. When a client receives Handshake or 1-RTT packets prior | |||
to obtaining Handshake keys, it may assume some or all of the | to obtaining Handshake keys, it may assume some or all of the | |||
server's Initial packets were lost. | server's Initial packets were lost. | |||
To speed up handshake completion under these conditions, an endpoint | To speed up handshake completion under these conditions, an endpoint | |||
MAY, for a limited number of times per connection, send a packet | MAY, for a limited number of times per connection, send a packet | |||
containing unacknowledged CRYPTO data earlier than the PTO expiry, | containing unacknowledged CRYPTO data earlier than the PTO expiry, | |||
subject to the address validation limits in Section 8.1 of | subject to the address validation limits in Section 8.1 of | |||
[QUIC-TRANSPORT]. Doing so at most once for each connection is | [QUIC-TRANSPORT]. Doing so at most once for each connection is | |||
adequate to quickly recover from a single packet loss. An endpoint | adequate to quickly recover from a single packet loss. An endpoint | |||
that always retransmits packets in response to receiving packets that | that always retransmits packets in response to receiving packets that | |||
it cannot process risks creating an infinite exchange of packets. | it cannot process risks creating an infinite exchange of packets. | |||
Endpoints can also use coalesced packets (see Section 12.2 of | Endpoints can also use coalesced packets (see Section 12.2 of | |||
[QUIC-TRANSPORT]) to ensure that each datagram elicits at least one | [QUIC-TRANSPORT]) to ensure that each datagram elicits at least one | |||
acknowledgment. For example, a client can coalesce an Initial packet | acknowledgment. For example, a client can coalesce an Initial packet | |||
containing PING and PADDING frames with a 0-RTT data packet and a | containing PING and PADDING frames with a 0-RTT data packet, and a | |||
server can coalesce an Initial packet containing a PING frame with | server can coalesce an Initial packet containing a PING frame with | |||
one or more packets in its first flight. | one or more packets in its first flight. | |||
6.2.4. Sending Probe Packets | 6.2.4. Sending Probe Packets | |||
When a PTO timer expires, a sender MUST send at least one ack- | When a PTO timer expires, a sender MUST send at least one ack- | |||
eliciting packet in the packet number space as a probe. An endpoint | eliciting packet in the packet number space as a probe. An endpoint | |||
MAY send up to two full-sized datagrams containing ack-eliciting | MAY send up to two full-sized datagrams containing ack-eliciting | |||
packets, to avoid an expensive consecutive PTO expiration due to a | packets to avoid an expensive consecutive PTO expiration due to a | |||
single lost datagram, or transmit data from multiple packet number | single lost datagram or to transmit data from multiple packet number | |||
spaces. All probe packets sent on a PTO MUST be ack-eliciting. | spaces. All probe packets sent on a PTO MUST be ack-eliciting. | |||
In addition to sending data in the packet number space for which the | In addition to sending data in the packet number space for which the | |||
timer expired, the sender SHOULD send ack-eliciting packets from | timer expired, the sender SHOULD send ack-eliciting packets from | |||
other packet number spaces with in-flight data, coalescing packets if | other packet number spaces with in-flight data, coalescing packets if | |||
possible. This is particularly valuable when the server has both | possible. This is particularly valuable when the server has both | |||
Initial and Handshake data in-flight or the client has both Handshake | Initial and Handshake data in flight or when the client has both | |||
and Application Data in-flight, because the peer might only have | Handshake and Application Data in flight because the peer might only | |||
receive keys for one of the two packet number spaces. | have receive keys for one of the two packet number spaces. | |||
If the sender wants to elicit a faster acknowledgment on PTO, it can | If the sender wants to elicit a faster acknowledgment on PTO, it can | |||
skip a packet number to eliminate the acknowledgment delay. | skip a packet number to eliminate the acknowledgment delay. | |||
An endpoint SHOULD include new data in packets that are sent on PTO | An endpoint SHOULD include new data in packets that are sent on PTO | |||
expiration. Previously sent data MAY be sent if no new data can be | expiration. Previously sent data MAY be sent if no new data can be | |||
sent. Implementations MAY use alternative strategies for determining | sent. Implementations MAY use alternative strategies for determining | |||
the content of probe packets, including sending new or retransmitted | the content of probe packets, including sending new or retransmitted | |||
data based on the application's priorities. | data based on the application's priorities. | |||
It is possible the sender has no new or previously-sent data to send. | It is possible the sender has no new or previously sent data to send. | |||
As an example, consider the following sequence of events: new | As an example, consider the following sequence of events: new | |||
application data is sent in a STREAM frame, deemed lost, then | application data is sent in a STREAM frame, deemed lost, then | |||
retransmitted in a new packet, and then the original transmission is | retransmitted in a new packet, and then the original transmission is | |||
acknowledged. When there is no data to send, the sender SHOULD send | acknowledged. When there is no data to send, the sender SHOULD send | |||
a PING or other ack-eliciting frame in a single packet, re-arming the | a PING or other ack-eliciting frame in a single packet, rearming the | |||
PTO timer. | PTO timer. | |||
Alternatively, instead of sending an ack-eliciting packet, the sender | Alternatively, instead of sending an ack-eliciting packet, the sender | |||
MAY mark any packets still in flight as lost. Doing so avoids | MAY mark any packets still in flight as lost. Doing so avoids | |||
sending an additional packet, but increases the risk that loss is | sending an additional packet but increases the risk that loss is | |||
declared too aggressively, resulting in an unnecessary rate reduction | declared too aggressively, resulting in an unnecessary rate reduction | |||
by the congestion controller. | by the congestion controller. | |||
Consecutive PTO periods increase exponentially, and as a result, | Consecutive PTO periods increase exponentially, and as a result, | |||
connection recovery latency increases exponentially as packets | connection recovery latency increases exponentially as packets | |||
continue to be dropped in the network. Sending two packets on PTO | continue to be dropped in the network. Sending two packets on PTO | |||
expiration increases resilience to packet drops, thus reducing the | expiration increases resilience to packet drops, thus reducing the | |||
probability of consecutive PTO events. | probability of consecutive PTO events. | |||
When the PTO timer expires multiple times and new data cannot be | When the PTO timer expires multiple times and new data cannot be | |||
sent, implementations must choose between sending the same payload | sent, implementations must choose between sending the same payload | |||
every time or sending different payloads. Sending the same payload | every time or sending different payloads. Sending the same payload | |||
may be simpler and ensures the highest priority frames arrive first. | may be simpler and ensures the highest priority frames arrive first. | |||
Sending different payloads each time reduces the chances of spurious | Sending different payloads each time reduces the chances of spurious | |||
retransmission. | retransmission. | |||
6.3. Handling Retry Packets | 6.3. Handling Retry Packets | |||
A Retry packet causes a client to send another Initial packet, | A Retry packet causes a client to send another Initial packet, | |||
effectively restarting the connection process. A Retry packet | effectively restarting the connection process. A Retry packet | |||
indicates that the Initial was received, but not processed. A Retry | indicates that the Initial packet was received but not processed. A | |||
packet cannot be treated as an acknowledgment, because it does not | Retry packet cannot be treated as an acknowledgment because it does | |||
indicate that a packet was processed or specify the packet number. | not indicate that a packet was processed or specify the packet | |||
number. | ||||
Clients that receive a Retry packet reset congestion control and loss | Clients that receive a Retry packet reset congestion control and loss | |||
recovery state, including resetting any pending timers. Other | recovery state, including resetting any pending timers. Other | |||
connection state, in particular cryptographic handshake messages, is | connection state, in particular cryptographic handshake messages, is | |||
retained; see Section 17.2.5 of [QUIC-TRANSPORT]. | retained; see Section 17.2.5 of [QUIC-TRANSPORT]. | |||
The client MAY compute an RTT estimate to the server as the time | The client MAY compute an RTT estimate to the server as the time | |||
period from when the first Initial was sent to when a Retry or a | period from when the first Initial packet was sent to when a Retry or | |||
Version Negotiation packet is received. The client MAY use this | a Version Negotiation packet is received. The client MAY use this | |||
value in place of its default for the initial RTT estimate. | value in place of its default for the initial RTT estimate. | |||
6.4. Discarding Keys and Packet State | 6.4. Discarding Keys and Packet State | |||
When Initial and Handshake packet protection keys are discarded (see | When Initial and Handshake packet protection keys are discarded (see | |||
Section 4.9 of [QUIC-TLS]), all packets that were sent with those | Section 4.9 of [QUIC-TLS]), all packets that were sent with those | |||
keys can no longer be acknowledged because their acknowledgments | keys can no longer be acknowledged because their acknowledgments | |||
cannot be processed. The sender MUST discard all recovery state | cannot be processed. The sender MUST discard all recovery state | |||
associated with those packets and MUST remove them from the count of | associated with those packets and MUST remove them from the count of | |||
bytes in flight. | bytes in flight. | |||
skipping to change at page 20, line 5 ¶ | skipping to change at line 859 ¶ | |||
[QUIC-TRANSPORT]. At this point, recovery state for all in-flight | [QUIC-TRANSPORT]. At this point, recovery state for all in-flight | |||
Initial packets is discarded. | Initial packets is discarded. | |||
When 0-RTT is rejected, recovery state for all in-flight 0-RTT | When 0-RTT is rejected, recovery state for all in-flight 0-RTT | |||
packets is discarded. | packets is discarded. | |||
If a server accepts 0-RTT, but does not buffer 0-RTT packets that | If a server accepts 0-RTT, but does not buffer 0-RTT packets that | |||
arrive before Initial packets, early 0-RTT packets will be declared | arrive before Initial packets, early 0-RTT packets will be declared | |||
lost, but that is expected to be infrequent. | lost, but that is expected to be infrequent. | |||
It is expected that keys are discarded after packets encrypted with | It is expected that keys are discarded at some time after the packets | |||
them would be acknowledged or declared lost. However, Initial and | encrypted with them are either acknowledged or declared lost. | |||
Handshake secrets are discarded as soon as handshake and 1-RTT keys | However, Initial and Handshake secrets are discarded as soon as | |||
are proven to be available to both client and server; see | Handshake and 1-RTT keys are proven to be available to both client | |||
Section 4.9.1 of [QUIC-TLS]. | and server; see Section 4.9.1 of [QUIC-TLS]. | |||
7. Congestion Control | 7. Congestion Control | |||
This document specifies a sender-side congestion controller for QUIC | This document specifies a sender-side congestion controller for QUIC | |||
similar to TCP NewReno ([RFC6582]). | similar to TCP NewReno [RFC6582]. | |||
The signals QUIC provides for congestion control are generic and are | The signals QUIC provides for congestion control are generic and are | |||
designed to support different sender-side algorithms. A sender can | designed to support different sender-side algorithms. A sender can | |||
unilaterally choose a different algorithm to use, such as Cubic | unilaterally choose a different algorithm to use, such as CUBIC | |||
([RFC8312]). | [RFC8312]. | |||
If a sender uses a different controller than that specified in this | If a sender uses a different controller than that specified in this | |||
document, the chosen controller MUST conform to the congestion | document, the chosen controller MUST conform to the congestion | |||
control guidelines specified in Section 3.1 of [RFC8085]. | control guidelines specified in Section 3.1 of [RFC8085]. | |||
Similar to TCP, packets containing only ACK frames do not count | Similar to TCP, packets containing only ACK frames do not count | |||
towards bytes in flight and are not congestion controlled. Unlike | toward bytes in flight and are not congestion controlled. Unlike | |||
TCP, QUIC can detect the loss of these packets and MAY use that | TCP, QUIC can detect the loss of these packets and MAY use that | |||
information to adjust the congestion controller or the rate of ACK- | information to adjust the congestion controller or the rate of ACK- | |||
only packets being sent, but this document does not describe a | only packets being sent, but this document does not describe a | |||
mechanism for doing so. | mechanism for doing so. | |||
The congestion controller is per path, so packets sent on other paths | ||||
do not alter the current path's congestion controller, as described | ||||
in Section 9.4 of [QUIC-TRANSPORT]. | ||||
The algorithm in this document specifies and uses the controller's | The algorithm in this document specifies and uses the controller's | |||
congestion window in bytes. | congestion window in bytes. | |||
An endpoint MUST NOT send a packet if it would cause bytes_in_flight | An endpoint MUST NOT send a packet if it would cause bytes_in_flight | |||
(see Appendix B.2) to be larger than the congestion window, unless | (see Appendix B.2) to be larger than the congestion window, unless | |||
the packet is sent on a PTO timer expiration (see Section 6.2) or | the packet is sent on a PTO timer expiration (see Section 6.2) or | |||
when entering recovery (see Section 7.3.2). | when entering recovery (see Section 7.3.2). | |||
7.1. Explicit Congestion Notification | 7.1. Explicit Congestion Notification | |||
If a path has been validated to support ECN ([RFC3168], [RFC8311]), | If a path has been validated to support Explicit Congestion | |||
QUIC treats a Congestion Experienced (CE) codepoint in the IP header | Notification (ECN) [RFC3168] [RFC8311], QUIC treats a Congestion | |||
as a signal of congestion. This document specifies an endpoint's | Experienced (CE) codepoint in the IP header as a signal of | |||
response when the peer-reported ECN-CE count increases; see | congestion. This document specifies an endpoint's response when the | |||
Section 13.4.2 of [QUIC-TRANSPORT]. | peer-reported ECN-CE count increases; see Section 13.4.2 of | |||
[QUIC-TRANSPORT]. | ||||
7.2. Initial and Minimum Congestion Window | 7.2. Initial and Minimum Congestion Window | |||
QUIC begins every connection in slow start with the congestion window | QUIC begins every connection in slow start with the congestion window | |||
set to an initial value. Endpoints SHOULD use an initial congestion | set to an initial value. Endpoints SHOULD use an initial congestion | |||
window of 10 times the maximum datagram size (max_datagram_size), | window of ten times the maximum datagram size (max_datagram_size), | |||
while limiting the window to the larger of 14720 bytes or twice the | while limiting the window to the larger of 14,720 bytes or twice the | |||
maximum datagram size. This follows the analysis and recommendations | maximum datagram size. This follows the analysis and recommendations | |||
in [RFC6928], increasing the byte limit to account for the smaller | in [RFC6928], increasing the byte limit to account for the smaller | |||
8-byte overhead of UDP compared to the 20-byte overhead for TCP. | 8-byte overhead of UDP compared to the 20-byte overhead for TCP. | |||
If the maximum datagram size changes during the connection, the | If the maximum datagram size changes during the connection, the | |||
initial congestion window SHOULD be recalculated with the new size. | initial congestion window SHOULD be recalculated with the new size. | |||
If the maximum datagram size is decreased in order to complete the | If the maximum datagram size is decreased in order to complete the | |||
handshake, the congestion window SHOULD be set to the new initial | handshake, the congestion window SHOULD be set to the new initial | |||
congestion window. | congestion window. | |||
Prior to validating the client's address, the server can be further | Prior to validating the client's address, the server can be further | |||
limited by the anti-amplification limit as specified in Section 8.1 | limited by the anti-amplification limit as specified in Section 8.1 | |||
of [QUIC-TRANSPORT]. Though the anti-amplification limit can prevent | of [QUIC-TRANSPORT]. Though the anti-amplification limit can prevent | |||
the congestion window from being fully utilized and therefore slow | the congestion window from being fully utilized and therefore slow | |||
down the increase in congestion window, it does not directly affect | down the increase in congestion window, it does not directly affect | |||
the congestion window. | the congestion window. | |||
The minimum congestion window is the smallest value the congestion | The minimum congestion window is the smallest value the congestion | |||
window can decrease to as a response to loss, increase in the peer- | window can attain in response to loss, an increase in the peer- | |||
reported ECN-CE count, or persistent congestion. The RECOMMENDED | reported ECN-CE count, or persistent congestion. The RECOMMENDED | |||
value is 2 * max_datagram_size. | value is 2 * max_datagram_size. | |||
7.3. Congestion Control States | 7.3. Congestion Control States | |||
The NewReno congestion controller described in this document has | The NewReno congestion controller described in this document has | |||
three distinct states, as shown in Figure 1. | three distinct states, as shown in Figure 1. | |||
New Path or +------------+ | New path or +------------+ | |||
persistent congestion | Slow | | persistent congestion | Slow | | |||
(O)---------------------->| Start | | (O)---------------------->| Start | | |||
+------------+ | +------------+ | |||
| | | | |||
Loss or | | Loss or | | |||
ECN-CE increase | | ECN-CE increase | | |||
v | v | |||
+------------+ Loss or +------------+ | +------------+ Loss or +------------+ | |||
| Congestion | ECN-CE increase | Recovery | | | Congestion | ECN-CE increase | Recovery | | |||
| Avoidance |------------------>| Period | | | Avoidance |------------------>| Period | | |||
skipping to change at page 22, line 43 ¶ | skipping to change at line 978 ¶ | |||
While a sender is in slow start, the congestion window increases by | While a sender is in slow start, the congestion window increases by | |||
the number of bytes acknowledged when each acknowledgment is | the number of bytes acknowledged when each acknowledgment is | |||
processed. This results in exponential growth of the congestion | processed. This results in exponential growth of the congestion | |||
window. | window. | |||
The sender MUST exit slow start and enter a recovery period when a | The sender MUST exit slow start and enter a recovery period when a | |||
packet is lost or when the ECN-CE count reported by its peer | packet is lost or when the ECN-CE count reported by its peer | |||
increases. | increases. | |||
A sender re-enters slow start any time the congestion window is less | A sender reenters slow start any time the congestion window is less | |||
than the slow start threshold, which only occurs after persistent | than the slow start threshold, which only occurs after persistent | |||
congestion is declared. | congestion is declared. | |||
7.3.2. Recovery | 7.3.2. Recovery | |||
A NewReno sender enters a recovery period when it detects the loss of | A NewReno sender enters a recovery period when it detects the loss of | |||
a packet or the ECN-CE count reported by its peer increases. A | a packet or when the ECN-CE count reported by its peer increases. A | |||
sender that is already in a recovery period stays in it and does not | sender that is already in a recovery period stays in it and does not | |||
re-enter it. | reenter it. | |||
On entering a recovery period, a sender MUST set the slow start | On entering a recovery period, a sender MUST set the slow start | |||
threshold to half the value of the congestion window when loss is | threshold to half the value of the congestion window when loss is | |||
detected. The congestion window MUST be set to the reduced value of | detected. The congestion window MUST be set to the reduced value of | |||
the slow start threshold before exiting the recovery period. | the slow start threshold before exiting the recovery period. | |||
Implementations MAY reduce the congestion window immediately upon | Implementations MAY reduce the congestion window immediately upon | |||
entering a recovery period or use other mechanisms, such as | entering a recovery period or use other mechanisms, such as | |||
Proportional Rate Reduction ([PRR]), to reduce the congestion window | Proportional Rate Reduction [PRR], to reduce the congestion window | |||
more gradually. If the congestion window is reduced immediately, a | more gradually. If the congestion window is reduced immediately, a | |||
single packet can be sent prior to reduction. This speeds up loss | single packet can be sent prior to reduction. This speeds up loss | |||
recovery if the data in the lost packet is retransmitted and is | recovery if the data in the lost packet is retransmitted and is | |||
similar to TCP as described in Section 5 of [RFC6675]. | similar to TCP as described in Section 5 of [RFC6675]. | |||
The recovery period aims to limit congestion window reduction to once | The recovery period aims to limit congestion window reduction to once | |||
per round trip. Therefore during a recovery period, the congestion | per round trip. Therefore, during a recovery period, the congestion | |||
window does not change in response to new losses or increases in the | window does not change in response to new losses or increases in the | |||
ECN-CE count. | ECN-CE count. | |||
A recovery period ends and the sender enters congestion avoidance | A recovery period ends and the sender enters congestion avoidance | |||
when a packet sent during the recovery period is acknowledged. This | when a packet sent during the recovery period is acknowledged. This | |||
is slightly different from TCP's definition of recovery, which ends | is slightly different from TCP's definition of recovery, which ends | |||
when the lost segment that started recovery is acknowledged | when the lost segment that started recovery is acknowledged | |||
([RFC5681]). | [RFC5681]. | |||
7.3.3. Congestion Avoidance | 7.3.3. Congestion Avoidance | |||
A NewReno sender is in congestion avoidance any time the congestion | A NewReno sender is in congestion avoidance any time the congestion | |||
window is at or above the slow start threshold and not in a recovery | window is at or above the slow start threshold and not in a recovery | |||
period. | period. | |||
A sender in congestion avoidance uses an Additive Increase | A sender in congestion avoidance uses an Additive Increase | |||
Multiplicative Decrease (AIMD) approach that MUST limit the increase | Multiplicative Decrease (AIMD) approach that MUST limit the increase | |||
to the congestion window to at most one maximum datagram size for | to the congestion window to at most one maximum datagram size for | |||
each congestion window that is acknowledged. | each congestion window that is acknowledged. | |||
The sender exits congestion avoidance and enters a recovery period | The sender exits congestion avoidance and enters a recovery period | |||
when a packet is lost or when the ECN-CE count reported by its peer | when a packet is lost or when the ECN-CE count reported by its peer | |||
increases. | increases. | |||
7.4. Ignoring Loss of Undecryptable Packets | 7.4. Ignoring Loss of Undecryptable Packets | |||
During the handshake, some packet protection keys might not be | During the handshake, some packet protection keys might not be | |||
available when a packet arrives and the receiver can choose to drop | available when a packet arrives, and the receiver can choose to drop | |||
the packet. In particular, Handshake and 0-RTT packets cannot be | the packet. In particular, Handshake and 0-RTT packets cannot be | |||
processed until the Initial packets arrive and 1-RTT packets cannot | processed until the Initial packets arrive, and 1-RTT packets cannot | |||
be processed until the handshake completes. Endpoints MAY ignore the | be processed until the handshake completes. Endpoints MAY ignore the | |||
loss of Handshake, 0-RTT, and 1-RTT packets that might have arrived | loss of Handshake, 0-RTT, and 1-RTT packets that might have arrived | |||
before the peer had packet protection keys to process those packets. | before the peer had packet protection keys to process those packets. | |||
Endpoints MUST NOT ignore the loss of packets that were sent after | Endpoints MUST NOT ignore the loss of packets that were sent after | |||
the earliest acknowledged packet in a given packet number space. | the earliest acknowledged packet in a given packet number space. | |||
7.5. Probe Timeout | 7.5. Probe Timeout | |||
Probe packets MUST NOT be blocked by the congestion controller. A | Probe packets MUST NOT be blocked by the congestion controller. A | |||
sender MUST however count these packets as being additionally in | sender MUST however count these packets as being additionally in | |||
flight, since these packets add network load without establishing | flight, since these packets add network load without establishing | |||
packet loss. Note that sending probe packets might cause the | packet loss. Note that sending probe packets might cause the | |||
sender's bytes in flight to exceed the congestion window until an | sender's bytes in flight to exceed the congestion window until an | |||
skipping to change at page 24, line 37 ¶ | skipping to change at line 1069 ¶ | |||
(smoothed_rtt + max(4*rttvar, kGranularity) + max_ack_delay) * | (smoothed_rtt + max(4*rttvar, kGranularity) + max_ack_delay) * | |||
kPersistentCongestionThreshold | kPersistentCongestionThreshold | |||
Unlike the PTO computation in Section 6.2, this duration includes the | Unlike the PTO computation in Section 6.2, this duration includes the | |||
max_ack_delay irrespective of the packet number spaces in which | max_ack_delay irrespective of the packet number spaces in which | |||
losses are established. | losses are established. | |||
This duration allows a sender to send as many packets before | This duration allows a sender to send as many packets before | |||
establishing persistent congestion, including some in response to PTO | establishing persistent congestion, including some in response to PTO | |||
expiration, as TCP does with Tail Loss Probes ([RACK]) and a | expiration, as TCP does with Tail Loss Probes [RFC8985] and an RTO | |||
Retransmission Timeout ([RFC5681]). | [RFC5681]. | |||
Larger values of kPersistentCongestionThreshold cause the sender to | Larger values of kPersistentCongestionThreshold cause the sender to | |||
become less responsive to persistent congestion in the network, which | become less responsive to persistent congestion in the network, which | |||
can result in aggressive sending into a congested network. Too small | can result in aggressive sending into a congested network. Too small | |||
a value can result in a sender declaring persistent congestion | a value can result in a sender declaring persistent congestion | |||
unnecessarily, resulting in reduced throughput for the sender. | unnecessarily, resulting in reduced throughput for the sender. | |||
The RECOMMENDED value for kPersistentCongestionThreshold is 3, which | The RECOMMENDED value for kPersistentCongestionThreshold is 3, which | |||
results in behavior that is approximately equivalent to a TCP sender | results in behavior that is approximately equivalent to a TCP sender | |||
declaring an RTO after two TLPs. | declaring an RTO after two TLPs. | |||
This design does not use consecutive PTO events to establish | This design does not use consecutive PTO events to establish | |||
persistent congestion, since application patterns impact PTO | persistent congestion, since application patterns impact PTO | |||
expirations. For example, a sender that sends small amounts of data | expiration. For example, a sender that sends small amounts of data | |||
with silence periods between them restarts the PTO timer every time | with silence periods between them restarts the PTO timer every time | |||
it sends, potentially preventing the PTO timer from expiring for a | it sends, potentially preventing the PTO timer from expiring for a | |||
long period of time, even when no acknowledgments are being received. | long period of time, even when no acknowledgments are being received. | |||
The use of a duration enables a sender to establish persistent | The use of a duration enables a sender to establish persistent | |||
congestion without depending on PTO expiration. | congestion without depending on PTO expiration. | |||
7.6.2. Establishing Persistent Congestion | 7.6.2. Establishing Persistent Congestion | |||
A sender establishes persistent congestion after the receipt of an | A sender establishes persistent congestion after the receipt of an | |||
acknowledgment if two packets that are ack-eliciting are declared | acknowledgment if two packets that are ack-eliciting are declared | |||
skipping to change at page 25, line 25 ¶ | skipping to change at line 1106 ¶ | |||
* across all packet number spaces, none of the packets sent between | * across all packet number spaces, none of the packets sent between | |||
the send times of these two packets are acknowledged; | the send times of these two packets are acknowledged; | |||
* the duration between the send times of these two packets exceeds | * the duration between the send times of these two packets exceeds | |||
the persistent congestion duration (Section 7.6.1); and | the persistent congestion duration (Section 7.6.1); and | |||
* a prior RTT sample existed when these two packets were sent. | * a prior RTT sample existed when these two packets were sent. | |||
These two packets MUST be ack-eliciting, since a receiver is required | These two packets MUST be ack-eliciting, since a receiver is required | |||
to acknowledge only ack-eliciting packets within its maximum ack | to acknowledge only ack-eliciting packets within its maximum | |||
delay; see Section 13.2 of [QUIC-TRANSPORT]. | acknowledgment delay; see Section 13.2 of [QUIC-TRANSPORT]. | |||
The persistent congestion period SHOULD NOT start until there is at | The persistent congestion period SHOULD NOT start until there is at | |||
least one RTT sample. Before the first RTT sample, a sender arms its | least one RTT sample. Before the first RTT sample, a sender arms its | |||
PTO timer based on the initial RTT (Section 6.2.2), which could be | PTO timer based on the initial RTT (Section 6.2.2), which could be | |||
substantially larger than the actual RTT. Requiring a prior RTT | substantially larger than the actual RTT. Requiring a prior RTT | |||
sample prevents a sender from establishing persistent congestion with | sample prevents a sender from establishing persistent congestion with | |||
potentially too few probes. | potentially too few probes. | |||
Since network congestion is not affected by packet number spaces, | Since network congestion is not affected by packet number spaces, | |||
persistent congestion SHOULD consider packets sent across packet | persistent congestion SHOULD consider packets sent across packet | |||
number spaces. A sender that does not have state for all packet | number spaces. A sender that does not have state for all packet | |||
number spaces or an implementation that cannot compare send times | number spaces or an implementation that cannot compare send times | |||
across packet number spaces MAY use state for just the packet number | across packet number spaces MAY use state for just the packet number | |||
space that was acknowledged. This might result in erroneously | space that was acknowledged. This might result in erroneously | |||
declaring persistent congestion, but it will not lead to a failure to | declaring persistent congestion, but it will not lead to a failure to | |||
detect persistent congestion. | detect persistent congestion. | |||
When persistent congestion is declared, the sender's congestion | When persistent congestion is declared, the sender's congestion | |||
window MUST be reduced to the minimum congestion window | window MUST be reduced to the minimum congestion window | |||
(kMinimumWindow), similar to a TCP sender's response on an RTO | (kMinimumWindow), similar to a TCP sender's response on an RTO | |||
([RFC5681]). | [RFC5681]. | |||
7.6.3. Example | 7.6.3. Example | |||
The following example illustrates how a sender might establish | The following example illustrates how a sender might establish | |||
persistent congestion. Assume: | persistent congestion. Assume: | |||
smoothed_rtt + max(4*rttvar, kGranularity) + max_ack_delay = 2 | smoothed_rtt + max(4*rttvar, kGranularity) + max_ack_delay = 2 | |||
kPersistentCongestionThreshold = 3 | kPersistentCongestionThreshold = 3 | |||
Consider the following sequence of events: | Consider the following sequence of events: | |||
+========+===========================+ | +========+===================================+ | |||
| Time | Action | | | Time | Action | | |||
+========+===========================+ | +========+===================================+ | |||
| t=0 | Send packet #1 (app data) | | | t=0 | Send packet #1 (application data) | | |||
+--------+---------------------------+ | +--------+-----------------------------------+ | |||
| t=1 | Send packet #2 (app data) | | | t=1 | Send packet #2 (application data) | | |||
+--------+---------------------------+ | +--------+-----------------------------------+ | |||
| t=1.2 | Recv acknowledgment of #1 | | | t=1.2 | Receive acknowledgment of #1 | | |||
+--------+---------------------------+ | +--------+-----------------------------------+ | |||
| t=2 | Send packet #3 (app data) | | | t=2 | Send packet #3 (application data) | | |||
+--------+---------------------------+ | +--------+-----------------------------------+ | |||
| t=3 | Send packet #4 (app data) | | | t=3 | Send packet #4 (application data) | | |||
+--------+---------------------------+ | +--------+-----------------------------------+ | |||
| t=4 | Send packet #5 (app data) | | | t=4 | Send packet #5 (application data) | | |||
+--------+---------------------------+ | +--------+-----------------------------------+ | |||
| t=5 | Send packet #6 (app data) | | | t=5 | Send packet #6 (application data) | | |||
+--------+---------------------------+ | +--------+-----------------------------------+ | |||
| t=6 | Send packet #7 (app data) | | | t=6 | Send packet #7 (application data) | | |||
+--------+---------------------------+ | +--------+-----------------------------------+ | |||
| t=8 | Send packet #8 (PTO 1) | | | t=8 | Send packet #8 (PTO 1) | | |||
+--------+---------------------------+ | +--------+-----------------------------------+ | |||
| t=12 | Send packet #9 (PTO 2) | | | t=12 | Send packet #9 (PTO 2) | | |||
+--------+---------------------------+ | +--------+-----------------------------------+ | |||
| t=12.2 | Recv acknowledgment of #9 | | | t=12.2 | Receive acknowledgment of #9 | | |||
+--------+---------------------------+ | +--------+-----------------------------------+ | |||
Table 1 | Table 1 | |||
Packets 2 through 8 are declared lost when the acknowledgment for | Packets 2 through 8 are declared lost when the acknowledgment for | |||
packet 9 is received at t = 12.2. | packet 9 is received at "t = 12.2". | |||
The congestion period is calculated as the time between the oldest | The congestion period is calculated as the time between the oldest | |||
and newest lost packets: 8 - 1 = 7. The persistent congestion | and newest lost packets: "8 - 1 = 7". The persistent congestion | |||
duration is: 2 * 3 = 6. Because the threshold was reached and | duration is "2 * 3 = 6". Because the threshold was reached and | |||
because none of the packets between the oldest and the newest lost | because none of the packets between the oldest and the newest lost | |||
packets were acknowledged, the network is considered to have | packets were acknowledged, the network is considered to have | |||
experienced persistent congestion. | experienced persistent congestion. | |||
While this example shows PTO expiration, they are not required for | While this example shows PTO expiration, they are not required for | |||
persistent congestion to be established. | persistent congestion to be established. | |||
7.7. Pacing | 7.7. Pacing | |||
A sender SHOULD pace sending of all in-flight packets based on input | A sender SHOULD pace sending of all in-flight packets based on input | |||
skipping to change at page 27, line 27 ¶ | skipping to change at line 1200 ¶ | |||
Section 7.2. A sender with knowledge that the network path to the | Section 7.2. A sender with knowledge that the network path to the | |||
receiver can absorb larger bursts MAY use a higher limit. | receiver can absorb larger bursts MAY use a higher limit. | |||
An implementation should take care to architect its congestion | An implementation should take care to architect its congestion | |||
controller to work well with a pacer. For instance, a pacer might | controller to work well with a pacer. For instance, a pacer might | |||
wrap the congestion controller and control the availability of the | wrap the congestion controller and control the availability of the | |||
congestion window, or a pacer might pace out packets handed to it by | congestion window, or a pacer might pace out packets handed to it by | |||
the congestion controller. | the congestion controller. | |||
Timely delivery of ACK frames is important for efficient loss | Timely delivery of ACK frames is important for efficient loss | |||
recovery. Packets containing only ACK frames SHOULD therefore not be | recovery. To avoid delaying their delivery to the peer, packets | |||
paced, to avoid delaying their delivery to the peer. | containing only ACK frames SHOULD therefore not be paced. | |||
Endpoints can implement pacing as they choose. A perfectly paced | Endpoints can implement pacing as they choose. A perfectly paced | |||
sender spreads packets exactly evenly over time. For a window-based | sender spreads packets exactly evenly over time. For a window-based | |||
congestion controller, such as the one in this document, that rate | congestion controller, such as the one in this document, that rate | |||
can be computed by averaging the congestion window over the round- | can be computed by averaging the congestion window over the RTT. | |||
trip time. Expressed as a rate in units of bytes per time, where | Expressed as a rate in units of bytes per time, where | |||
congestion_window is in bytes: | congestion_window is in bytes: | |||
rate = N * congestion_window / smoothed_rtt | rate = N * congestion_window / smoothed_rtt | |||
Or, expressed as an inter-packet interval in units of time: | Or expressed as an inter-packet interval in units of time: | |||
interval = ( smoothed_rtt * packet_size / congestion_window ) / N | interval = ( smoothed_rtt * packet_size / congestion_window ) / N | |||
Using a value for "N" that is small, but at least 1 (for example, | Using a value for "N" that is small, but at least 1 (for example, | |||
1.25) ensures that variations in round-trip time do not result in | 1.25) ensures that variations in RTT do not result in | |||
under-utilization of the congestion window. | underutilization of the congestion window. | |||
Practical considerations, such as packetization, scheduling delays, | Practical considerations, such as packetization, scheduling delays, | |||
and computational efficiency, can cause a sender to deviate from this | and computational efficiency, can cause a sender to deviate from this | |||
rate over time periods that are much shorter than a round-trip time. | rate over time periods that are much shorter than an RTT. | |||
One possible implementation strategy for pacing uses a leaky bucket | One possible implementation strategy for pacing uses a leaky bucket | |||
algorithm, where the capacity of the "bucket" is limited to the | algorithm, where the capacity of the "bucket" is limited to the | |||
maximum burst size and the rate the "bucket" fills is determined by | maximum burst size and the rate the "bucket" fills is determined by | |||
the above function. | the above function. | |||
7.8. Under-utilizing the Congestion Window | 7.8. Underutilizing the Congestion Window | |||
When bytes in flight is smaller than the congestion window and | When bytes in flight is smaller than the congestion window and | |||
sending is not pacing limited, the congestion window is under- | sending is not pacing limited, the congestion window is | |||
utilized. When this occurs, the congestion window SHOULD NOT be | underutilized. This can happen due to insufficient application data | |||
increased in either slow start or congestion avoidance. This can | or flow control limits. When this occurs, the congestion window | |||
happen due to insufficient application data or flow control limits. | SHOULD NOT be increased in either slow start or congestion avoidance. | |||
A sender that paces packets (see Section 7.7) might delay sending | A sender that paces packets (see Section 7.7) might delay sending | |||
packets and not fully utilize the congestion window due to this | packets and not fully utilize the congestion window due to this | |||
delay. A sender SHOULD NOT consider itself application limited if it | delay. A sender SHOULD NOT consider itself application limited if it | |||
would have fully utilized the congestion window without pacing delay. | would have fully utilized the congestion window without pacing delay. | |||
A sender MAY implement alternative mechanisms to update its | A sender MAY implement alternative mechanisms to update its | |||
congestion window after periods of under-utilization, such as those | congestion window after periods of underutilization, such as those | |||
proposed for TCP in [RFC7661]. | proposed for TCP in [RFC7661]. | |||
8. Security Considerations | 8. Security Considerations | |||
8.1. Loss and Congestion Signals | 8.1. Loss and Congestion Signals | |||
Loss detection and congestion control fundamentally involve | Loss detection and congestion control fundamentally involve the | |||
consumption of signals, such as delay, loss, and ECN markings, from | consumption of signals, such as delay, loss, and ECN markings, from | |||
unauthenticated entities. An attacker can cause endpoints to reduce | unauthenticated entities. An attacker can cause endpoints to reduce | |||
their sending rate by manipulating these signals; by dropping | their sending rate by manipulating these signals: by dropping | |||
packets, by altering path delay strategically, or by changing ECN | packets, by altering path delay strategically, or by changing ECN | |||
codepoints. | codepoints. | |||
8.2. Traffic Analysis | 8.2. Traffic Analysis | |||
Packets that carry only ACK frames can be heuristically identified by | Packets that carry only ACK frames can be heuristically identified by | |||
observing packet size. Acknowledgment patterns may expose | observing packet size. Acknowledgment patterns may expose | |||
information about link characteristics or application behavior. To | information about link characteristics or application behavior. To | |||
reduce leaked information, endpoints can bundle acknowledgments with | reduce leaked information, endpoints can bundle acknowledgments with | |||
other frames, or they can use PADDING frames at a potential cost to | other frames, or they can use PADDING frames at a potential cost to | |||
skipping to change at page 29, line 9 ¶ | skipping to change at line 1277 ¶ | |||
A receiver can misreport ECN markings to alter the congestion | A receiver can misreport ECN markings to alter the congestion | |||
response of a sender. Suppressing reports of ECN-CE markings could | response of a sender. Suppressing reports of ECN-CE markings could | |||
cause a sender to increase their send rate. This increase could | cause a sender to increase their send rate. This increase could | |||
result in congestion and loss. | result in congestion and loss. | |||
A sender can detect suppression of reports by marking occasional | A sender can detect suppression of reports by marking occasional | |||
packets that it sends with an ECN-CE marking. If a packet sent with | packets that it sends with an ECN-CE marking. If a packet sent with | |||
an ECN-CE marking is not reported as having been CE marked when the | an ECN-CE marking is not reported as having been CE marked when the | |||
packet is acknowledged, then the sender can disable ECN for that path | packet is acknowledged, then the sender can disable ECN for that path | |||
by not setting ECT codepoints in subsequent packets sent on that path | by not setting ECN-Capable Transport (ECT) codepoints in subsequent | |||
[RFC3168]. | packets sent on that path [RFC3168]. | |||
Reporting additional ECN-CE markings will cause a sender to reduce | Reporting additional ECN-CE markings will cause a sender to reduce | |||
their sending rate, which is similar in effect to advertising reduced | their sending rate, which is similar in effect to advertising reduced | |||
connection flow control limits and so no advantage is gained by doing | connection flow control limits and so no advantage is gained by doing | |||
so. | so. | |||
Endpoints choose the congestion controller that they use. Congestion | Endpoints choose the congestion controller that they use. Congestion | |||
controllers respond to reports of ECN-CE by reducing their rate, but | controllers respond to reports of ECN-CE by reducing their rate, but | |||
the response may vary. Markings can be treated as equivalent to loss | the response may vary. Markings can be treated as equivalent to loss | |||
([RFC3168]), but other responses can be specified, such as | [RFC3168], but other responses can be specified, such as [RFC8511] or | |||
([RFC8511]) or ([RFC8311]). | [RFC8311]. | |||
9. IANA Considerations | ||||
This document has no IANA actions. | ||||
10. References | 9. References | |||
10.1. Normative References | 9.1. Normative References | |||
[QUIC-TLS] Thomson, M., Ed. and S. Turner, Ed., "Using TLS to Secure | [QUIC-TLS] Thomson, M., Ed. and S. Turner, Ed., "Using TLS to Secure | |||
QUIC", Work in Progress, Internet-Draft, draft-ietf-quic- | QUIC", RFC 9001, DOI 10.17487/RFC9001, May 2021, | |||
tls-34, 15 January 2021, | <https://www.rfc-editor.org/info/rfc9001>. | |||
<https://tools.ietf.org/html/draft-ietf-quic-tls-34>. | ||||
[QUIC-TRANSPORT] | [QUIC-TRANSPORT] | |||
Iyengar, J., Ed. and M. Thomson, Ed., "QUIC: A UDP-Based | Iyengar, J., Ed. and M. Thomson, Ed., "QUIC: A UDP-Based | |||
Multiplexed and Secure Transport", Work in Progress, | Multiplexed and Secure Transport", RFC 9000, | |||
Internet-Draft, draft-ietf-quic-transport-34, 15 January | DOI 10.17487/RFC9000, May 2021, | |||
2021, <https://tools.ietf.org/html/draft-ietf-quic- | <https://www.rfc-editor.org/info/rfc9000>. | |||
transport-34>. | ||||
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate | [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate | |||
Requirement Levels", BCP 14, RFC 2119, | Requirement Levels", BCP 14, RFC 2119, | |||
DOI 10.17487/RFC2119, March 1997, | DOI 10.17487/RFC2119, March 1997, | |||
<https://www.rfc-editor.org/info/rfc2119>. | <https://www.rfc-editor.org/info/rfc2119>. | |||
[RFC3168] Ramakrishnan, K., Floyd, S., and D. Black, "The Addition | [RFC3168] Ramakrishnan, K., Floyd, S., and D. Black, "The Addition | |||
of Explicit Congestion Notification (ECN) to IP", | of Explicit Congestion Notification (ECN) to IP", | |||
RFC 3168, DOI 10.17487/RFC3168, September 2001, | RFC 3168, DOI 10.17487/RFC3168, September 2001, | |||
<https://www.rfc-editor.org/info/rfc3168>. | <https://www.rfc-editor.org/info/rfc3168>. | |||
[RFC8085] Eggert, L., Fairhurst, G., and G. Shepherd, "UDP Usage | [RFC8085] Eggert, L., Fairhurst, G., and G. Shepherd, "UDP Usage | |||
Guidelines", BCP 145, RFC 8085, DOI 10.17487/RFC8085, | Guidelines", BCP 145, RFC 8085, DOI 10.17487/RFC8085, | |||
March 2017, <https://www.rfc-editor.org/info/rfc8085>. | March 2017, <https://www.rfc-editor.org/info/rfc8085>. | |||
[RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC | [RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC | |||
2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, | 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, | |||
May 2017, <https://www.rfc-editor.org/info/rfc8174>. | May 2017, <https://www.rfc-editor.org/info/rfc8174>. | |||
10.2. Informative References | 9.2. Informative References | |||
[FACK] Mathis, M. and J. Mahdavi, "Forward Acknowledgement: | [FACK] Mathis, M. and J. Mahdavi, "Forward acknowledgement: | |||
Refining TCP Congestion Control", ACM SIGCOMM , August | Refining TCP Congestion Control", ACM SIGCOMM Computer | |||
1996. | Communication Review, DOI 10.1145/248157.248181, August | |||
1996, <https://doi.org/10.1145/248157.248181>. | ||||
[PRR] Mathis, M., Dukkipati, N., and Y. Cheng, "Proportional | [PRR] Mathis, M., Dukkipati, N., and Y. Cheng, "Proportional | |||
Rate Reduction for TCP", RFC 6937, DOI 10.17487/RFC6937, | Rate Reduction for TCP", RFC 6937, DOI 10.17487/RFC6937, | |||
May 2013, <https://www.rfc-editor.org/info/rfc6937>. | May 2013, <https://www.rfc-editor.org/info/rfc6937>. | |||
[RACK] Cheng, Y., Cardwell, N., Dukkipati, N., and P. Jha, "The | ||||
RACK-TLP loss detection algorithm for TCP", Work in | ||||
Progress, Internet-Draft, draft-ietf-tcpm-rack-15, 22 | ||||
December 2020, <http://www.ietf.org/internet-drafts/draft- | ||||
ietf-tcpm-rack-15.txt>. | ||||
[RETRANSMISSION] | [RETRANSMISSION] | |||
Karn, P. and C. Partridge, "Improving Round-Trip Time | Karn, P. and C. Partridge, "Improving Round-Trip Time | |||
Estimates in Reliable Transport Protocols", ACM SIGCOMM | Estimates in Reliable Transport Protocols", ACM | |||
CCR , January 1995. | Transactions on Computer Systems, | |||
DOI 10.1145/118544.118549, November 1991, | ||||
<https://doi.org/10.1145/118544.118549>. | ||||
[RFC2018] Mathis, M., Mahdavi, J., Floyd, S., and A. Romanow, "TCP | [RFC2018] Mathis, M., Mahdavi, J., Floyd, S., and A. Romanow, "TCP | |||
Selective Acknowledgment Options", RFC 2018, | Selective Acknowledgment Options", RFC 2018, | |||
DOI 10.17487/RFC2018, October 1996, | DOI 10.17487/RFC2018, October 1996, | |||
<https://www.rfc-editor.org/info/rfc2018>. | <https://www.rfc-editor.org/info/rfc2018>. | |||
[RFC3465] Allman, M., "TCP Congestion Control with Appropriate Byte | [RFC3465] Allman, M., "TCP Congestion Control with Appropriate Byte | |||
Counting (ABC)", RFC 3465, DOI 10.17487/RFC3465, February | Counting (ABC)", RFC 3465, DOI 10.17487/RFC3465, February | |||
2003, <https://www.rfc-editor.org/info/rfc3465>. | 2003, <https://www.rfc-editor.org/info/rfc3465>. | |||
skipping to change at page 31, line 11 ¶ | skipping to change at line 1366 ¶ | |||
Spurious Retransmission Timeouts with TCP", RFC 5682, | Spurious Retransmission Timeouts with TCP", RFC 5682, | |||
DOI 10.17487/RFC5682, September 2009, | DOI 10.17487/RFC5682, September 2009, | |||
<https://www.rfc-editor.org/info/rfc5682>. | <https://www.rfc-editor.org/info/rfc5682>. | |||
[RFC5827] Allman, M., Avrachenkov, K., Ayesta, U., Blanton, J., and | [RFC5827] Allman, M., Avrachenkov, K., Ayesta, U., Blanton, J., and | |||
P. Hurtig, "Early Retransmit for TCP and Stream Control | P. Hurtig, "Early Retransmit for TCP and Stream Control | |||
Transmission Protocol (SCTP)", RFC 5827, | Transmission Protocol (SCTP)", RFC 5827, | |||
DOI 10.17487/RFC5827, May 2010, | DOI 10.17487/RFC5827, May 2010, | |||
<https://www.rfc-editor.org/info/rfc5827>. | <https://www.rfc-editor.org/info/rfc5827>. | |||
[RFC6297] Welzl, M. and D. Ros, "A Survey of Lower-than-Best-Effort | ||||
Transport Protocols", RFC 6297, DOI 10.17487/RFC6297, June | ||||
2011, <https://www.rfc-editor.org/info/rfc6297>. | ||||
[RFC6298] Paxson, V., Allman, M., Chu, J., and M. Sargent, | [RFC6298] Paxson, V., Allman, M., Chu, J., and M. Sargent, | |||
"Computing TCP's Retransmission Timer", RFC 6298, | "Computing TCP's Retransmission Timer", RFC 6298, | |||
DOI 10.17487/RFC6298, June 2011, | DOI 10.17487/RFC6298, June 2011, | |||
<https://www.rfc-editor.org/info/rfc6298>. | <https://www.rfc-editor.org/info/rfc6298>. | |||
[RFC6582] Henderson, T., Floyd, S., Gurtov, A., and Y. Nishida, "The | [RFC6582] Henderson, T., Floyd, S., Gurtov, A., and Y. Nishida, "The | |||
NewReno Modification to TCP's Fast Recovery Algorithm", | NewReno Modification to TCP's Fast Recovery Algorithm", | |||
RFC 6582, DOI 10.17487/RFC6582, April 2012, | RFC 6582, DOI 10.17487/RFC6582, April 2012, | |||
<https://www.rfc-editor.org/info/rfc6582>. | <https://www.rfc-editor.org/info/rfc6582>. | |||
skipping to change at page 32, line 10 ¶ | skipping to change at line 1407 ¶ | |||
[RFC8312] Rhee, I., Xu, L., Ha, S., Zimmermann, A., Eggert, L., and | [RFC8312] Rhee, I., Xu, L., Ha, S., Zimmermann, A., Eggert, L., and | |||
R. Scheffenegger, "CUBIC for Fast Long-Distance Networks", | R. Scheffenegger, "CUBIC for Fast Long-Distance Networks", | |||
RFC 8312, DOI 10.17487/RFC8312, February 2018, | RFC 8312, DOI 10.17487/RFC8312, February 2018, | |||
<https://www.rfc-editor.org/info/rfc8312>. | <https://www.rfc-editor.org/info/rfc8312>. | |||
[RFC8511] Khademi, N., Welzl, M., Armitage, G., and G. Fairhurst, | [RFC8511] Khademi, N., Welzl, M., Armitage, G., and G. Fairhurst, | |||
"TCP Alternative Backoff with ECN (ABE)", RFC 8511, | "TCP Alternative Backoff with ECN (ABE)", RFC 8511, | |||
DOI 10.17487/RFC8511, December 2018, | DOI 10.17487/RFC8511, December 2018, | |||
<https://www.rfc-editor.org/info/rfc8511>. | <https://www.rfc-editor.org/info/rfc8511>. | |||
[RFC8985] Cheng, Y., Cardwell, N., Dukkipati, N., and P. Jha, "The | ||||
RACK-TLP Loss Detection Algorithm for TCP", RFC 8985, | ||||
DOI 10.17487/RFC8985, February 2021, | ||||
<https://www.rfc-editor.org/info/rfc8985>. | ||||
Appendix A. Loss Recovery Pseudocode | Appendix A. Loss Recovery Pseudocode | |||
We now describe an example implementation of the loss detection | We now describe an example implementation of the loss detection | |||
mechanisms described in Section 6. | mechanisms described in Section 6. | |||
The pseudocode segments in this section are licensed as Code | The pseudocode segments in this section are licensed as Code | |||
Components; see the copyright notice. | Components; see the copyright notice. | |||
A.1. Tracking Sent Packets | A.1. Tracking Sent Packets | |||
skipping to change at page 32, line 38 ¶ | skipping to change at line 1440 ¶ | |||
see Section 13.3 of [QUIC-TRANSPORT]. This enables a sender to | see Section 13.3 of [QUIC-TRANSPORT]. This enables a sender to | |||
detect spurious retransmissions. | detect spurious retransmissions. | |||
Sent packets are tracked for each packet number space, and ACK | Sent packets are tracked for each packet number space, and ACK | |||
processing only applies to a single space. | processing only applies to a single space. | |||
A.1.1. Sent Packet Fields | A.1.1. Sent Packet Fields | |||
packet_number: The packet number of the sent packet. | packet_number: The packet number of the sent packet. | |||
ack_eliciting: A boolean that indicates whether a packet is ack- | ack_eliciting: A Boolean that indicates whether a packet is ack- | |||
eliciting. If true, it is expected that an acknowledgment will be | eliciting. If true, it is expected that an acknowledgment will be | |||
received, though the peer could delay sending the ACK frame | received, though the peer could delay sending the ACK frame | |||
containing it by up to the max_ack_delay. | containing it by up to the max_ack_delay. | |||
in_flight: A boolean that indicates whether the packet counts | in_flight: A Boolean that indicates whether the packet counts toward | |||
towards bytes in flight. | bytes in flight. | |||
sent_bytes: The number of bytes sent in the packet, not including | sent_bytes: The number of bytes sent in the packet, not including | |||
UDP or IP overhead, but including QUIC framing overhead. | UDP or IP overhead, but including QUIC framing overhead. | |||
time_sent: The time the packet was sent. | time_sent: The time the packet was sent. | |||
A.2. Constants of Interest | A.2. Constants of Interest | |||
Constants used in loss recovery are based on a combination of RFCs, | Constants used in loss recovery are based on a combination of RFCs, | |||
papers, and common practice. | papers, and common practice. | |||
kPacketThreshold: Maximum reordering in packets before packet | kPacketThreshold: Maximum reordering in packets before packet | |||
threshold loss detection considers a packet lost. The value | threshold loss detection considers a packet lost. The value | |||
recommended in Section 6.1.1 is 3. | recommended in Section 6.1.1 is 3. | |||
kTimeThreshold: Maximum reordering in time before time threshold | kTimeThreshold: Maximum reordering in time before time threshold | |||
loss detection considers a packet lost. Specified as an RTT | loss detection considers a packet lost. Specified as an RTT | |||
multiplier. The value recommended in Section 6.1.2 is 9/8. | multiplier. The value recommended in Section 6.1.2 is 9/8. | |||
kGranularity: Timer granularity. This is a system-dependent value, | kGranularity: Timer granularity. This is a system-dependent value, | |||
and Section 6.1.2 recommends a value of 1ms. | and Section 6.1.2 recommends a value of 1 ms. | |||
kInitialRtt: The RTT used before an RTT sample is taken. The value | kInitialRtt: The RTT used before an RTT sample is taken. The value | |||
recommended in Section 6.2.2 is 333ms. | recommended in Section 6.2.2 is 333 ms. | |||
kPacketNumberSpace: An enum to enumerate the three packet number | kPacketNumberSpace: An enum to enumerate the three packet number | |||
spaces. | spaces: | |||
enum kPacketNumberSpace { | enum kPacketNumberSpace { | |||
Initial, | Initial, | |||
Handshake, | Handshake, | |||
ApplicationData, | ApplicationData, | |||
} | } | |||
A.3. Variables of interest | A.3. Variables of Interest | |||
Variables required to implement the congestion control mechanisms are | Variables required to implement the congestion control mechanisms are | |||
described in this section. | described in this section. | |||
latest_rtt: The most recent RTT measurement made when receiving an | latest_rtt: The most recent RTT measurement made when receiving an | |||
ack for a previously unacked packet. | acknowledgment for a previously unacknowledged packet. | |||
smoothed_rtt: The smoothed RTT of the connection, computed as | smoothed_rtt: The smoothed RTT of the connection, computed as | |||
described in Section 5.3. | described in Section 5.3. | |||
rttvar: The RTT variation, computed as described in Section 5.3. | rttvar: The RTT variation, computed as described in Section 5.3. | |||
min_rtt: The minimum RTT seen over a period of time, ignoring | min_rtt: The minimum RTT seen over a period of time, ignoring | |||
acknowledgment delay, as described in Section 5.2. | acknowledgment delay, as described in Section 5.2. | |||
first_rtt_sample: The time that the first RTT sample was obtained. | first_rtt_sample: The time that the first RTT sample was obtained. | |||
skipping to change at page 34, line 13 ¶ | skipping to change at line 1509 ¶ | |||
max_ack_delay: The maximum amount of time by which the receiver | max_ack_delay: The maximum amount of time by which the receiver | |||
intends to delay acknowledgments for packets in the Application | intends to delay acknowledgments for packets in the Application | |||
Data packet number space, as defined by the eponymous transport | Data packet number space, as defined by the eponymous transport | |||
parameter (Section 18.2 of [QUIC-TRANSPORT]). Note that the | parameter (Section 18.2 of [QUIC-TRANSPORT]). Note that the | |||
actual ack_delay in a received ACK frame may be larger due to late | actual ack_delay in a received ACK frame may be larger due to late | |||
timers, reordering, or loss. | timers, reordering, or loss. | |||
loss_detection_timer: Multi-modal timer used for loss detection. | loss_detection_timer: Multi-modal timer used for loss detection. | |||
pto_count: The number of times a PTO has been sent without receiving | pto_count: The number of times a PTO has been sent without receiving | |||
an ack. | an acknowledgment. | |||
time_of_last_ack_eliciting_packet[kPacketNumberSpace]: The time the | time_of_last_ack_eliciting_packet[kPacketNumberSpace]: The time the | |||
most recent ack-eliciting packet was sent. | most recent ack-eliciting packet was sent. | |||
largest_acked_packet[kPacketNumberSpace]: The largest packet number | largest_acked_packet[kPacketNumberSpace]: The largest packet number | |||
acknowledged in the packet number space so far. | acknowledged in the packet number space so far. | |||
loss_time[kPacketNumberSpace]: The time at which the next packet in | loss_time[kPacketNumberSpace]: The time at which the next packet in | |||
that packet number space can be considered lost based on exceeding | that packet number space can be considered lost based on exceeding | |||
the reordering window in time. | the reordering window in time. | |||
skipping to change at page 35, line 27 ¶ | skipping to change at line 1570 ¶ | |||
if (ack_eliciting): | if (ack_eliciting): | |||
time_of_last_ack_eliciting_packet[pn_space] = now() | time_of_last_ack_eliciting_packet[pn_space] = now() | |||
OnPacketSentCC(sent_bytes) | OnPacketSentCC(sent_bytes) | |||
SetLossDetectionTimer() | SetLossDetectionTimer() | |||
A.6. On Receiving a Datagram | A.6. On Receiving a Datagram | |||
When a server is blocked by anti-amplification limits, receiving a | When a server is blocked by anti-amplification limits, receiving a | |||
datagram unblocks it, even if none of the packets in the datagram are | datagram unblocks it, even if none of the packets in the datagram are | |||
successfully processed. In such a case, the PTO timer will need to | successfully processed. In such a case, the PTO timer will need to | |||
be re-armed. | be rearmed. | |||
Pseudocode for OnDatagramReceived follows: | Pseudocode for OnDatagramReceived follows: | |||
OnDatagramReceived(datagram): | OnDatagramReceived(datagram): | |||
// If this datagram unblocks the server, arm the | // If this datagram unblocks the server, arm the | |||
// PTO timer to avoid deadlock. | // PTO timer to avoid deadlock. | |||
if (server was at anti-amplification limit): | if (server was at anti-amplification limit): | |||
SetLossDetectionTimer() | SetLossDetectionTimer() | |||
if loss_detection_timer.timeout < now(): | ||||
// Execute PTO if it would have expired | ||||
// while the amplification limit applied. | ||||
OnLossDetectionTimeout() | ||||
A.7. On Receiving an Acknowledgment | A.7. On Receiving an Acknowledgment | |||
When an ACK frame is received, it may newly acknowledge any number of | When an ACK frame is received, it may newly acknowledge any number of | |||
packets. | packets. | |||
Pseudocode for OnAckReceived and UpdateRtt follow: | Pseudocode for OnAckReceived and UpdateRtt follow: | |||
IncludesAckEliciting(packets): | IncludesAckEliciting(packets): | |||
for packet in packets: | for packet in packets: | |||
skipping to change at page 37, line 10 ¶ | skipping to change at line 1653 ¶ | |||
// min_rtt ignores acknowledgment delay. | // min_rtt ignores acknowledgment delay. | |||
min_rtt = min(min_rtt, latest_rtt) | min_rtt = min(min_rtt, latest_rtt) | |||
// Limit ack_delay by max_ack_delay after handshake | // Limit ack_delay by max_ack_delay after handshake | |||
// confirmation. | // confirmation. | |||
if (handshake confirmed): | if (handshake confirmed): | |||
ack_delay = min(ack_delay, max_ack_delay) | ack_delay = min(ack_delay, max_ack_delay) | |||
// Adjust for acknowledgment delay if plausible. | // Adjust for acknowledgment delay if plausible. | |||
adjusted_rtt = latest_rtt | adjusted_rtt = latest_rtt | |||
if (latest_rtt > min_rtt + ack_delay): | if (latest_rtt >= min_rtt + ack_delay): | |||
adjusted_rtt = latest_rtt - ack_delay | adjusted_rtt = latest_rtt - ack_delay | |||
rttvar = 3/4 * rttvar + 1/4 * abs(smoothed_rtt - adjusted_rtt) | rttvar = 3/4 * rttvar + 1/4 * abs(smoothed_rtt - adjusted_rtt) | |||
smoothed_rtt = 7/8 * smoothed_rtt + 1/8 * adjusted_rtt | smoothed_rtt = 7/8 * smoothed_rtt + 1/8 * adjusted_rtt | |||
A.8. Setting the Loss Detection Timer | A.8. Setting the Loss Detection Timer | |||
QUIC loss detection uses a single timer for all timeout loss | QUIC loss detection uses a single timer for all timeout loss | |||
detection. The duration of the timer is based on the timer's mode, | detection. The duration of the timer is based on the timer's mode, | |||
which is set in the packet and timer events further below. The | which is set in the packet and timer events further below. The | |||
skipping to change at page 37, line 43 ¶ | skipping to change at line 1686 ¶ | |||
space = Initial | space = Initial | |||
for pn_space in [ Handshake, ApplicationData ]: | for pn_space in [ Handshake, ApplicationData ]: | |||
if (time == 0 || loss_time[pn_space] < time): | if (time == 0 || loss_time[pn_space] < time): | |||
time = loss_time[pn_space]; | time = loss_time[pn_space]; | |||
space = pn_space | space = pn_space | |||
return time, space | return time, space | |||
GetPtoTimeAndSpace(): | GetPtoTimeAndSpace(): | |||
duration = (smoothed_rtt + max(4 * rttvar, kGranularity)) | duration = (smoothed_rtt + max(4 * rttvar, kGranularity)) | |||
* (2 ^ pto_count) | * (2 ^ pto_count) | |||
// Arm PTO from now when there are no inflight packets. | // Anti-deadlock PTO starts from the current time | |||
if (no in-flight packets): | if (no ack-eliciting packets in flight): | |||
assert(!PeerCompletedAddressValidation()) | assert(!PeerCompletedAddressValidation()) | |||
if (has handshake keys): | if (has handshake keys): | |||
return (now() + duration), Handshake | return (now() + duration), Handshake | |||
else: | else: | |||
return (now() + duration), Initial | return (now() + duration), Initial | |||
pto_timeout = infinite | pto_timeout = infinite | |||
pto_space = Initial | pto_space = Initial | |||
for space in [ Initial, Handshake, ApplicationData ]: | for space in [ Initial, Handshake, ApplicationData ]: | |||
if (no in-flight packets in space): | if (no ack-eliciting packets in flight in space): | |||
continue; | continue; | |||
if (space == ApplicationData): | if (space == ApplicationData): | |||
// Skip Application Data until handshake confirmed. | // Skip Application Data until handshake confirmed. | |||
if (handshake is not confirmed): | if (handshake is not confirmed): | |||
return pto_timeout, pto_space | return pto_timeout, pto_space | |||
// Include max_ack_delay and backoff for Application Data. | // Include max_ack_delay and backoff for Application Data. | |||
duration += max_ack_delay * (2 ^ pto_count) | duration += max_ack_delay * (2 ^ pto_count) | |||
t = time_of_last_ack_eliciting_packet[space] + duration | t = time_of_last_ack_eliciting_packet[space] + duration | |||
if (t < pto_timeout): | if (t < pto_timeout): | |||
skipping to change at page 39, line 22 ¶ | skipping to change at line 1760 ¶ | |||
OnLossDetectionTimeout(): | OnLossDetectionTimeout(): | |||
earliest_loss_time, pn_space = GetLossTimeAndSpace() | earliest_loss_time, pn_space = GetLossTimeAndSpace() | |||
if (earliest_loss_time != 0): | if (earliest_loss_time != 0): | |||
// Time threshold loss Detection | // Time threshold loss Detection | |||
lost_packets = DetectAndRemoveLostPackets(pn_space) | lost_packets = DetectAndRemoveLostPackets(pn_space) | |||
assert(!lost_packets.empty()) | assert(!lost_packets.empty()) | |||
OnPacketsLost(lost_packets) | OnPacketsLost(lost_packets) | |||
SetLossDetectionTimer() | SetLossDetectionTimer() | |||
return | return | |||
if (bytes_in_flight > 0): | if (no ack-eliciting packets in flight): | |||
// PTO. Send new data if available, else retransmit old data. | ||||
// If neither is available, send a single PING frame. | ||||
_, pn_space = GetPtoTimeAndSpace() | ||||
SendOneOrTwoAckElicitingPackets(pn_space) | ||||
else: | ||||
assert(!PeerCompletedAddressValidation()) | assert(!PeerCompletedAddressValidation()) | |||
// Client sends an anti-deadlock packet: Initial is padded | // Client sends an anti-deadlock packet: Initial is padded | |||
// to earn more anti-amplification credit, | // to earn more anti-amplification credit, | |||
// a Handshake packet proves address ownership. | // a Handshake packet proves address ownership. | |||
if (has Handshake keys): | if (has Handshake keys): | |||
SendOneAckElicitingHandshakePacket() | SendOneAckElicitingHandshakePacket() | |||
else: | else: | |||
SendOneAckElicitingPaddedInitialPacket() | SendOneAckElicitingPaddedInitialPacket() | |||
else: | ||||
// PTO. Send new data if available, else retransmit old data. | ||||
// If neither is available, send a single PING frame. | ||||
_, pn_space = GetPtoTimeAndSpace() | ||||
SendOneOrTwoAckElicitingPackets(pn_space) | ||||
pto_count++ | pto_count++ | |||
SetLossDetectionTimer() | SetLossDetectionTimer() | |||
A.10. Detecting Lost Packets | A.10. Detecting Lost Packets | |||
DetectAndRemoveLostPackets is called every time an ACK is received or | DetectAndRemoveLostPackets is called every time an ACK is received or | |||
the time threshold loss detection timer expires. This function | the time threshold loss detection timer expires. This function | |||
operates on the sent_packets for that packet number space and returns | operates on the sent_packets for that packet number space and returns | |||
a list of packets newly detected as lost. | a list of packets newly detected as lost. | |||
skipping to change at page 41, line 13 ¶ | skipping to change at line 1844 ¶ | |||
SetLossDetectionTimer() | SetLossDetectionTimer() | |||
Appendix B. Congestion Control Pseudocode | Appendix B. Congestion Control Pseudocode | |||
We now describe an example implementation of the congestion | We now describe an example implementation of the congestion | |||
controller described in Section 7. | controller described in Section 7. | |||
The pseudocode segments in this section are licensed as Code | The pseudocode segments in this section are licensed as Code | |||
Components; see the copyright notice. | Components; see the copyright notice. | |||
B.1. Constants of interest | B.1. Constants of Interest | |||
Constants used in congestion control are based on a combination of | Constants used in congestion control are based on a combination of | |||
RFCs, papers, and common practice. | RFCs, papers, and common practice. | |||
kInitialWindow: Default limit on the initial bytes in flight as | kInitialWindow: Default limit on the initial bytes in flight as | |||
described in Section 7.2. | described in Section 7.2. | |||
kMinimumWindow: Minimum congestion window in bytes as described in | kMinimumWindow: Minimum congestion window in bytes as described in | |||
Section 7.2. | Section 7.2. | |||
kLossReductionFactor: Scaling factor applied to reduce the | kLossReductionFactor: Scaling factor applied to reduce the | |||
congestion window when a new loss event is detected. Section 7 | congestion window when a new loss event is detected. Section 7 | |||
recommends a value is 0.5. | recommends a value of 0.5. | |||
kPersistentCongestionThreshold: Period of time for persistent | kPersistentCongestionThreshold: Period of time for persistent | |||
congestion to be established, specified as a PTO multiplier. | congestion to be established, specified as a PTO multiplier. | |||
Section 7.6 recommends a value of 3. | Section 7.6 recommends a value of 3. | |||
B.2. Variables of interest | B.2. Variables of Interest | |||
Variables required to implement the congestion control mechanisms are | Variables required to implement the congestion control mechanisms are | |||
described in this section. | described in this section. | |||
max_datagram_size: The sender's current maximum payload size. Does | max_datagram_size: The sender's current maximum payload size. This | |||
not include UDP or IP overhead. The max datagram size is used for | does not include UDP or IP overhead. The max datagram size is | |||
congestion window computations. An endpoint sets the value of | used for congestion window computations. An endpoint sets the | |||
this variable based on its Path Maximum Transmission Unit (PMTU; | value of this variable based on its Path Maximum Transmission Unit | |||
see Section 14.2 of [QUIC-TRANSPORT]), with a minimum value of | (PMTU; see Section 14.2 of [QUIC-TRANSPORT]), with a minimum value | |||
1200 bytes. | of 1200 bytes. | |||
ecn_ce_counters[kPacketNumberSpace]: The highest value reported for | ecn_ce_counters[kPacketNumberSpace]: The highest value reported for | |||
the ECN-CE counter in the packet number space by the peer in an | the ECN-CE counter in the packet number space by the peer in an | |||
ACK frame. This value is used to detect increases in the reported | ACK frame. This value is used to detect increases in the reported | |||
ECN-CE counter. | ECN-CE counter. | |||
bytes_in_flight: The sum of the size in bytes of all sent packets | bytes_in_flight: The sum of the size in bytes of all sent packets | |||
that contain at least one ack-eliciting or PADDING frame, and have | that contain at least one ack-eliciting or PADDING frame and have | |||
not been acknowledged or declared lost. The size does not include | not been acknowledged or declared lost. The size does not include | |||
IP or UDP overhead, but does include the QUIC header and AEAD | IP or UDP overhead, but does include the QUIC header and | |||
overhead. Packets only containing ACK frames do not count towards | Authenticated Encryption with Associated Data (AEAD) overhead. | |||
Packets only containing ACK frames do not count toward | ||||
bytes_in_flight to ensure congestion control does not impede | bytes_in_flight to ensure congestion control does not impede | |||
congestion feedback. | congestion feedback. | |||
congestion_window: Maximum number of bytes allowed to be in flight. | congestion_window: Maximum number of bytes allowed to be in flight. | |||
congestion_recovery_start_time: The time the current recovery period | congestion_recovery_start_time: The time the current recovery period | |||
started due to the detection of loss or ECN. When a packet sent | started due to the detection of loss or ECN. When a packet sent | |||
after this time is acknowledged, QUIC exits congestion recovery. | after this time is acknowledged, QUIC exits congestion recovery. | |||
ssthresh: Slow start threshold in bytes. When the congestion window | ssthresh: Slow start threshold in bytes. When the congestion window | |||
skipping to change at page 42, line 35 ¶ | skipping to change at line 1916 ¶ | |||
congestion_window = kInitialWindow | congestion_window = kInitialWindow | |||
bytes_in_flight = 0 | bytes_in_flight = 0 | |||
congestion_recovery_start_time = 0 | congestion_recovery_start_time = 0 | |||
ssthresh = infinite | ssthresh = infinite | |||
for pn_space in [ Initial, Handshake, ApplicationData ]: | for pn_space in [ Initial, Handshake, ApplicationData ]: | |||
ecn_ce_counters[pn_space] = 0 | ecn_ce_counters[pn_space] = 0 | |||
B.4. On Packet Sent | B.4. On Packet Sent | |||
Whenever a packet is sent, and it contains non-ACK frames, the packet | Whenever a packet is sent and it contains non-ACK frames, the packet | |||
increases bytes_in_flight. | increases bytes_in_flight. | |||
OnPacketSentCC(sent_bytes): | OnPacketSentCC(sent_bytes): | |||
bytes_in_flight += sent_bytes | bytes_in_flight += sent_bytes | |||
B.5. On Packet Acknowledgment | B.5. On Packet Acknowledgment | |||
Invoked from loss detection's OnAckReceived and is supplied with the | This is invoked from loss detection's OnAckReceived and is supplied | |||
newly acked_packets from sent_packets. | with the newly acked_packets from sent_packets. | |||
In congestion avoidance, implementers that use an integer | In congestion avoidance, implementers that use an integer | |||
representation for congestion_window should be careful with division, | representation for congestion_window should be careful with division | |||
and can use the alternative approach suggested in Section 2.1 of | and can use the alternative approach suggested in Section 2.1 of | |||
[RFC3465]. | [RFC3465]. | |||
InCongestionRecovery(sent_time): | InCongestionRecovery(sent_time): | |||
return sent_time <= congestion_recovery_start_time | return sent_time <= congestion_recovery_start_time | |||
OnPacketsAcked(acked_packets): | OnPacketsAcked(acked_packets): | |||
for acked_packet in acked_packets: | for acked_packet in acked_packets: | |||
OnPacketAcked(acked_packet) | OnPacketAcked(acked_packet) | |||
skipping to change at page 43, line 35 ¶ | skipping to change at line 1962 ¶ | |||
// Slow start. | // Slow start. | |||
congestion_window += acked_packet.sent_bytes | congestion_window += acked_packet.sent_bytes | |||
else: | else: | |||
// Congestion avoidance. | // Congestion avoidance. | |||
congestion_window += | congestion_window += | |||
max_datagram_size * acked_packet.sent_bytes | max_datagram_size * acked_packet.sent_bytes | |||
/ congestion_window | / congestion_window | |||
B.6. On New Congestion Event | B.6. On New Congestion Event | |||
Invoked from ProcessECN and OnPacketsLost when a new congestion event | This is invoked from ProcessECN and OnPacketsLost when a new | |||
is detected. If not already in recovery, this starts a recovery | congestion event is detected. If not already in recovery, this | |||
period and reduces the slow start threshold and congestion window | starts a recovery period and reduces the slow start threshold and | |||
immediately. | congestion window immediately. | |||
OnCongestionEvent(sent_time): | OnCongestionEvent(sent_time): | |||
// No reaction if already in a recovery period. | // No reaction if already in a recovery period. | |||
if (InCongestionRecovery(sent_time)): | if (InCongestionRecovery(sent_time)): | |||
return | return | |||
// Enter recovery period. | // Enter recovery period. | |||
congestion_recovery_start_time = now() | congestion_recovery_start_time = now() | |||
ssthresh = congestion_window * kLossReductionFactor | ssthresh = congestion_window * kLossReductionFactor | |||
congestion_window = max(ssthresh, kMinimumWindow) | congestion_window = max(ssthresh, kMinimumWindow) | |||
// A packet can be sent to speed up loss recovery. | // A packet can be sent to speed up loss recovery. | |||
MaybeSendOnePacket() | MaybeSendOnePacket() | |||
B.7. Process ECN Information | B.7. Process ECN Information | |||
Invoked when an ACK frame with an ECN section is received from the | This is invoked when an ACK frame with an ECN section is received | |||
peer. | from the peer. | |||
ProcessECN(ack, pn_space): | ProcessECN(ack, pn_space): | |||
// If the ECN-CE counter reported by the peer has increased, | // If the ECN-CE counter reported by the peer has increased, | |||
// this could be a new congestion event. | // this could be a new congestion event. | |||
if (ack.ce_counter > ecn_ce_counters[pn_space]): | if (ack.ce_counter > ecn_ce_counters[pn_space]): | |||
ecn_ce_counters[pn_space] = ack.ce_counter | ecn_ce_counters[pn_space] = ack.ce_counter | |||
sent_time = sent_packets[ack.largest_acked].time_sent | sent_time = sent_packets[ack.largest_acked].time_sent | |||
OnCongestionEvent(sent_time) | OnCongestionEvent(sent_time) | |||
B.8. On Packets Lost | B.8. On Packets Lost | |||
Invoked when DetectAndRemoveLostPackets deems packets lost. | This is invoked when DetectAndRemoveLostPackets deems packets lost. | |||
OnPacketsLost(lost_packets): | OnPacketsLost(lost_packets): | |||
sent_time_of_last_loss = 0 | sent_time_of_last_loss = 0 | |||
// Remove lost packets from bytes_in_flight. | // Remove lost packets from bytes_in_flight. | |||
for lost_packet in lost_packets: | for lost_packet in lost_packets: | |||
if lost_packet.in_flight: | if lost_packet.in_flight: | |||
bytes_in_flight -= lost_packet.sent_bytes | bytes_in_flight -= lost_packet.sent_bytes | |||
sent_time_of_last_loss = | sent_time_of_last_loss = | |||
max(sent_time_of_last_loss, lost_packet.time_sent) | max(sent_time_of_last_loss, lost_packet.time_sent) | |||
// Congestion event if in-flight packets were lost | // Congestion event if in-flight packets were lost | |||
skipping to change at page 44, line 47 ¶ | skipping to change at line 2021 ¶ | |||
if (first_rtt_sample == 0): | if (first_rtt_sample == 0): | |||
return | return | |||
pc_lost = [] | pc_lost = [] | |||
for lost in lost_packets: | for lost in lost_packets: | |||
if lost.time_sent > first_rtt_sample: | if lost.time_sent > first_rtt_sample: | |||
pc_lost.insert(lost) | pc_lost.insert(lost) | |||
if (InPersistentCongestion(pc_lost)): | if (InPersistentCongestion(pc_lost)): | |||
congestion_window = kMinimumWindow | congestion_window = kMinimumWindow | |||
congestion_recovery_start_time = 0 | congestion_recovery_start_time = 0 | |||
B.9. Removing Discarded Packets From Bytes In Flight | B.9. Removing Discarded Packets from Bytes in Flight | |||
When Initial or Handshake keys are discarded, packets sent in that | When Initial or Handshake keys are discarded, packets sent in that | |||
space no longer count toward bytes in flight. | space no longer count toward bytes in flight. | |||
Pseudocode for RemoveFromBytesInFlight follows: | Pseudocode for RemoveFromBytesInFlight follows: | |||
RemoveFromBytesInFlight(discarded_packets): | RemoveFromBytesInFlight(discarded_packets): | |||
// Remove any unacknowledged packets from flight. | // Remove any unacknowledged packets from flight. | |||
foreach packet in discarded_packets: | foreach packet in discarded_packets: | |||
if packet.in_flight | if packet.in_flight | |||
bytes_in_flight -= size | bytes_in_flight -= size | |||
Appendix C. Change Log | Contributors | |||
*RFC Editor's Note:* Please remove this section prior to | ||||
publication of a final version of this document. | ||||
Issue and pull request numbers are listed with a leading octothorp. | ||||
C.1. Since draft-ietf-quic-recovery-32 | ||||
* Clarifications to definition of persistent congestion (#4413, | ||||
#4414, #4421, #4429, #4437) | ||||
C.2. Since draft-ietf-quic-recovery-31 | ||||
* Limit the number of Initial packets sent in response to | ||||
unauthenticated packets (#4183, #4188) | ||||
C.3. Since draft-ietf-quic-recovery-30 | ||||
Editorial changes only. | ||||
C.4. Since draft-ietf-quic-recovery-29 | ||||
* Allow caching of packets that can't be decrypted, by allowing the | ||||
reported acknowledgment delay to exceed max_ack_delay prior to | ||||
confirming the handshake (#3821, #3980, #4035, #3874) | ||||
* Persistent congestion cannot include packets sent before the first | ||||
RTT sample for the path (#3875, #3889) | ||||
* Recommend reset of min_rtt in persistent congestion (#3927, #3975) | ||||
* Persistent congestion is independent of packet number space | ||||
(#3939, #3961) | ||||
* Only limit bursts to the initial window without information about | ||||
the path (#3892, #3936) | ||||
* Add normative requirements for increasing and reducing the | ||||
congestion window (#3944, #3978, #3997, #3998) | ||||
C.5. Since draft-ietf-quic-recovery-28 | ||||
* Refactored pseudocode to correct PTO calculation (#3564, #3674, | ||||
#3681) | ||||
C.6. Since draft-ietf-quic-recovery-27 | ||||
* Added recommendations for speeding up handshake under some loss | ||||
conditions (#3078, #3080) | ||||
* PTO count is reset when handshake progress is made (#3272, #3415) | ||||
* PTO count is not reset by a client when the server might be | ||||
awaiting address validation (#3546, #3551) | ||||
* Recommend repairing losses immediately after entering the recovery | ||||
period (#3335, #3443) | ||||
* Clarified what loss conditions can be ignored during the handshake | ||||
(#3456, #3450) | ||||
* Allow, but don't recommend, using RTT from previous connection to | ||||
seed RTT (#3464, #3496) | ||||
* Recommend use of adaptive loss detection thresholds (#3571, #3572) | ||||
C.7. Since draft-ietf-quic-recovery-26 | ||||
No changes. | ||||
C.8. Since draft-ietf-quic-recovery-25 | ||||
No significant changes. | ||||
C.9. Since draft-ietf-quic-recovery-24 | ||||
* Require congestion control of some sort (#3247, #3244, #3248) | ||||
* Set a minimum reordering threshold (#3256, #3240) | ||||
* PTO is specific to a packet number space (#3067, #3074, #3066) | ||||
C.10. Since draft-ietf-quic-recovery-23 | ||||
* Define under-utilizing the congestion window (#2630, #2686, #2675) | ||||
* PTO MUST send data if possible (#3056, #3057) | ||||
* Connection Close is not ack-eliciting (#3097, #3098) | ||||
* MUST limit bursts to the initial congestion window (#3160) | ||||
* Define the current max_datagram_size for congestion control | ||||
(#3041, #3167) | ||||
C.11. Since draft-ietf-quic-recovery-22 | ||||
* PTO should always send an ack-eliciting packet (#2895) | ||||
* Unify the Handshake Timer with the PTO timer (#2648, #2658, #2886) | ||||
* Move ACK generation text to transport draft (#1860, #2916) | ||||
C.12. Since draft-ietf-quic-recovery-21 | ||||
* No changes | ||||
C.13. Since draft-ietf-quic-recovery-20 | ||||
* Path validation can be used as initial RTT value (#2644, #2687) | ||||
* max_ack_delay transport parameter defaults to 0 (#2638, #2646) | ||||
* ACK delay only measures intentional delays induced by the | ||||
implementation (#2596, #2786) | ||||
C.14. Since draft-ietf-quic-recovery-19 | ||||
* Change kPersistentThreshold from an exponent to a multiplier | ||||
(#2557) | ||||
* Send a PING if the PTO timer fires and there's nothing to send | ||||
(#2624) | ||||
* Set loss delay to at least kGranularity (#2617) | ||||
* Merge application limited and sending after idle sections. Always | ||||
limit burst size instead of requiring resetting CWND to initial | ||||
CWND after idle (#2605) | ||||
* Rewrite RTT estimation, allow RTT samples where a newly acked | ||||
packet is ack-eliciting but the largest_acked is not (#2592) | ||||
* Don't arm the handshake timer if there is no handshake data | ||||
(#2590) | ||||
* Clarify that the time threshold loss alarm takes precedence over | ||||
the crypto handshake timer (#2590, #2620) | ||||
* Change initial RTT to 500ms to align with RFC6298 (#2184) | ||||
C.15. Since draft-ietf-quic-recovery-18 | ||||
* Change IW byte limit to 14720 from 14600 (#2494) | ||||
* Update PTO calculation to match RFC6298 (#2480, #2489, #2490) | ||||
* Improve loss detection's description of multiple packet number | ||||
spaces and pseudocode (#2485, #2451, #2417) | ||||
* Declare persistent congestion even if non-probe packets are sent | ||||
and don't make persistent congestion more aggressive than RTO | ||||
verified was (#2365, #2244) | ||||
* Move pseudocode to the appendices (#2408) | ||||
* What to send on multiple PTOs (#2380) | ||||
C.16. Since draft-ietf-quic-recovery-17 | ||||
* After Probe Timeout discard in-flight packets or send another | ||||
(#2212, #1965) | ||||
* Endpoints discard initial keys as soon as handshake keys are | ||||
available (#1951, #2045) | ||||
* 0-RTT state is discarded when 0-RTT is rejected (#2300) | ||||
* Loss detection timer is cancelled when ack-eliciting frames are in | ||||
flight (#2117, #2093) | ||||
* Packets are declared lost if they are in flight (#2104) | ||||
* After becoming idle, either pace packets or reset the congestion | ||||
controller (#2138, 2187) | ||||
* Process ECN counts before marking packets lost (#2142) | ||||
* Mark packets lost before resetting crypto_count and pto_count | ||||
(#2208, #2209) | ||||
* Congestion and loss recovery state are discarded when keys are | ||||
discarded (#2327) | ||||
C.17. Since draft-ietf-quic-recovery-16 | ||||
* Unify TLP and RTO into a single PTO; eliminate min RTO, min TLP | ||||
and min crypto timeouts; eliminate timeout validation (#2114, | ||||
#2166, #2168, #1017) | ||||
* Redefine how congestion avoidance in terms of when the period | ||||
starts (#1928, #1930) | ||||
* Document what needs to be tracked for packets that are in flight | ||||
(#765, #1724, #1939) | ||||
* Integrate both time and packet thresholds into loss detection | ||||
(#1969, #1212, #934, #1974) | ||||
* Reduce congestion window after idle, unless pacing is used (#2007, | ||||
#2023) | ||||
* Disable RTT calculation for packets that don't elicit | ||||
acknowledgment (#2060, #2078) | ||||
* Limit ack_delay by max_ack_delay (#2060, #2099) | ||||
* Initial keys are discarded once Handshake keys are available | ||||
(#1951, #2045) | ||||
* Reorder ECN and loss detection in pseudocode (#2142) | ||||
* Only cancel loss detection timer if ack-eliciting packets are in | ||||
flight (#2093, #2117) | ||||
C.18. Since draft-ietf-quic-recovery-14 | ||||
* Used max_ack_delay from transport params (#1796, #1782) | ||||
* Merge ACK and ACK_ECN (#1783) | ||||
C.19. Since draft-ietf-quic-recovery-13 | ||||
* Corrected the lack of ssthresh reduction in CongestionEvent | ||||
pseudocode (#1598) | ||||
* Considerations for ECN spoofing (#1426, #1626) | ||||
* Clarifications for PADDING and congestion control (#837, #838, | ||||
#1517, #1531, #1540) | ||||
* Reduce early retransmission timer to RTT/8 (#945, #1581) | ||||
* Packets are declared lost after an RTO is verified (#935, #1582) | ||||
C.20. Since draft-ietf-quic-recovery-12 | ||||
* Changes to manage separate packet number spaces and encryption | ||||
levels (#1190, #1242, #1413, #1450) | ||||
* Added ECN feedback mechanisms and handling; new ACK_ECN frame | ||||
(#804, #805, #1372) | ||||
C.21. Since draft-ietf-quic-recovery-11 | ||||
No significant changes. | ||||
C.22. Since draft-ietf-quic-recovery-10 | ||||
* Improved text on ack generation (#1139, #1159) | ||||
* Make references to TCP recovery mechanisms informational (#1195) | ||||
* Define time_of_last_sent_handshake_packet (#1171) | ||||
* Added signal from TLS the data it includes needs to be sent in a | ||||
Retry packet (#1061, #1199) | ||||
* Minimum RTT (min_rtt) is initialized with an infinite value | ||||
(#1169) | ||||
C.23. Since draft-ietf-quic-recovery-09 | ||||
No significant changes. | ||||
C.24. Since draft-ietf-quic-recovery-08 | ||||
* Clarified pacing and RTO (#967, #977) | ||||
C.25. Since draft-ietf-quic-recovery-07 | ||||
* Include ACK delay in RTO(and TLP) computations (#981) | ||||
* ACK delay in SRTT computation (#961) | ||||
* Default RTT and Slow Start (#590) | ||||
* Many editorial fixes. | ||||
C.26. Since draft-ietf-quic-recovery-06 | ||||
No significant changes. | ||||
C.27. Since draft-ietf-quic-recovery-05 | ||||
* Add more congestion control text (#776) | ||||
C.28. Since draft-ietf-quic-recovery-04 | ||||
No significant changes. | ||||
C.29. Since draft-ietf-quic-recovery-03 | ||||
No significant changes. | ||||
C.30. Since draft-ietf-quic-recovery-02 | ||||
* Integrate F-RTO (#544, #409) | ||||
* Add congestion control (#545, #395) | ||||
* Require connection abort if a skipped packet was acknowledged | ||||
(#415) | ||||
* Simplify RTO calculations (#142, #417) | ||||
C.31. Since draft-ietf-quic-recovery-01 | ||||
* Overview added to loss detection | ||||
* Changes initial default RTT to 100ms | ||||
* Added time-based loss detection and fixes early retransmit | ||||
* Clarified loss recovery for handshake packets | ||||
* Fixed references and made TCP references informative | ||||
C.32. Since draft-ietf-quic-recovery-00 | ||||
* Improved description of constants and ACK behavior | ||||
C.33. Since draft-iyengar-quic-loss-recovery-01 | ||||
* Adopted as base for draft-ietf-quic-recovery | ||||
* Updated authors/editors list | ||||
* Added table of contents | ||||
Appendix D. Contributors | ||||
The IETF QUIC Working Group received an enormous amount of support | The IETF QUIC Working Group received an enormous amount of support | |||
from many people. The following people provided substantive | from many people. The following people provided substantive | |||
contributions to this document: | contributions to this document: | |||
* Alessandro Ghedini | * Alessandro Ghedini | |||
* Benjamin Saunders | * Benjamin Saunders | |||
* Gorry Fairhurst | * Gorry Fairhurst | |||
* 山本和彦 (Kazu Yamamoto) | * 山本和彦 (Kazu Yamamoto) | |||
* 奥 一穂 (Kazuho Oku) | * 奥 一穂 (Kazuho Oku) | |||
* Lars Eggert | * Lars Eggert | |||
* Magnus Westerlund | * Magnus Westerlund | |||
* Marten Seemann | * Marten Seemann | |||
* Martin Duke | * Martin Duke | |||
* Martin Thomson | * Martin Thomson | |||
* Mirja Kühlewind | * Mirja Kühlewind | |||
* Nick Banks | * Nick Banks | |||
* Praveen Balasubramanian | * Praveen Balasubramanian | |||
Acknowledgments | ||||
Authors' Addresses | Authors' Addresses | |||
Jana Iyengar (editor) | Jana Iyengar (editor) | |||
Fastly | Fastly | |||
Email: jri.ietf@gmail.com | Email: jri.ietf@gmail.com | |||
Ian Swett (editor) | Ian Swett (editor) | |||
End of changes. 166 change blocks. | ||||
790 lines changed or deleted | 416 lines changed or added | |||
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