title: CUBIC for Fast Long-Distance Networks abbrev: CUBIC docname: draft-eggert-tcpm-rfc8312bis-latest date: {DATE} category: std ipr: trust200902 area: Transport workgroup: TCPM obsoletes: 8312
stand_alone: yes pi: [toc, sortrefs, symrefs, docmapping]
author:
- name: Lisong Xu org: University of Nebraska-Lincoln abbrev: UNL street: Department of Computer Science and Engineering city: Lincoln region: NE code: 68588-0115 country: USA email: [email protected] uri: "https://cse.unl.edu/~xu/"
- name: Sangtae Ha org: University of Colorado at Boulder abbrev: Colorado street: Department of Computer Science city: Boulder region: CO code: 80309-0430 country: USA email: [email protected] uri: "https://netstech.org/sangtaeha/"
- name: Lars Eggert org: NetApp street: Stenbergintie 12 B city: Kauniainen code: "02700" country: FI email: [email protected] uri: "https://eggert.org/" role: editor
informative: FHP00: title: A Comparison of Equation-Based and AIMD Congestion Control date: 2000-5 author: - ins: S. Floyd - ins: M. Handley - ins: J. Padhye target: "https://www.icir.org/tfrc/aimd.pdf"
GV02: title: Extended Analysis of Binary Adjustment Algorithms date: 2002-8-11 seriesinfo: Technical Report: TR2002-29 Department of: Computer Sciences The University of Texas: at Austin author: - ins: S. Gorinsky - ins: H. Vin target: "http://www.cs.utexas.edu/ftp/techreports/tr02-39.ps.gz"
HKLRX06: title: A Step toward Realistic Performance Evaluation of High-Speed TCP Variants date: 2006-2 seriesinfo: International Workshop on: Protocols for Fast Long-Distance Networks author: - ins: S. Ha - ins: Y. Kim - ins: L. Le - ins: I. Rhee - ins: L. Xu target: "https://pfld.net/2006/paper/s2_03.pdf"
HR08: title: Hybrid Slow Start for High-Bandwidth and Long-Distance Networks date: 2008 seriesinfo: International Workshop on: Protocols for Fast Long-Distance Networks author: - ins: S. Ha - ins: I. Rhee target: "https://pdfs.semanticscholar.org/25e9/ef3f03315782c7f1cbcd31b587857adae7d1.pdf"
XHR04: title: Binary Increase Congestion Control (BIC) for Fast Long-Distance Networks date: 2004-3 seriesinfo: IEEE INFOCOM: 2004 DOI: 10.1109/infcom.2004.1354672 author: - name: Lisong Xu - name: Khaled Harfoush - name: Injong Rhee
CEHRX07: DOI.10.1109/INFCOM.2007.111 HRX08: DOI.10.1145/1400097.1400105 K03: DOI.10.1145/956981.956989
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CUBIC is an extension to the current TCP standards. It differs from the current TCP standards only in the congestion control algorithm on the sender side. In particular, it uses a cubic function instead of a linear window increase function of the current TCP standards to improve scalability and stability under fast and long-distance networks. CUBIC and its predecessor algorithm have been adopted as defaults by Linux and have been used for many years. This document provides a specification of CUBIC to enable third-party implementations and to solicit community feedback through experimentation on the performance of CUBIC.
This documents obsoletes {{?RFC8312}}, updating the specification of CUBIC to conform to the current Linux version.
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Discussion of this draft takes place on the TCPM working group mailing list, which is archived at .
Working Group information can be found at ; source code and issues list for this draft can be found at .
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The low utilization problem of TCP in fast long-distance networks is well documented in {{?K03}} and {{?RFC3649}}. This problem arises from a slow increase of the congestion window following a congestion event in a network with a large bandwidth-delay product (BDP). {{HKLRX06}} indicates that this problem is frequently observed even in the range of congestion window sizes over several hundreds of packets. This problem is equally applicable to all Reno-style TCP standards and their variants, including TCP-Reno {{!RFC5681}}, TCP-NewReno {{!RFC6582}}{{!RFC6675}}, SCTP {{?RFC4960}}, and TFRC {{!RFC5348}}, which use the same linear increase function for window growth, which we refer to collectively as "Standard TCP" below.
CUBIC, originally proposed in {{?HRX08}}, is a modification to the congestion control algorithm of Standard TCP to remedy this problem. This document describes the most recent specification of CUBIC. Specifically, CUBIC uses a cubic function instead of a linear window increase function of Standard TCP to improve scalability and stability under fast and long-distance networks.
Binary Increase Congestion Control (BIC-TCP) {{XHR04}}, a predecessor of CUBIC, was selected as the default TCP congestion control algorithm by Linux in the year 2005 and has been used for several years by the Internet community at large. CUBIC uses a similar window increase function as BIC-TCP and is designed to be less aggressive and fairer to Standard TCP in bandwidth usage than BIC-TCP while maintaining the strengths of BIC-TCP such as stability, window scalability, and RTT fairness. CUBIC has already replaced BIC-TCP as the default TCP congestion control algorithm in Linux and has been deployed globally by Linux. Through extensive testing in various Internet scenarios, we believe that CUBIC is safe for testing and deployment in the global Internet.
In the following sections, we first briefly explain the design principles of CUBIC, then provide the exact specification of CUBIC, and finally discuss the safety features of CUBIC following the guidelines specified in {{!RFC5033}}.
{::boilerplate bcp14}
CUBIC is designed according to the following design principles:
Principle 1: : For better network utilization and stability, CUBIC uses both the concave and convex profiles of a cubic function to increase the congestion window size, instead of using just a convex function.
Principle 2: : To be TCP-friendly, CUBIC is designed to behave like Standard TCP in networks with short RTTs and small bandwidth where Standard TCP performs well.
Principle 3: : For RTT-fairness, CUBIC is designed to achieve linear bandwidth sharing among flows with different RTTs.
Principle 4: : CUBIC appropriately sets its multiplicative window decrease factor in order to balance between the scalability and convergence speed.
Principle 1: For better network utilization and stability, CUBIC {{?HRX08}} uses a cubic window increase function in terms of the elapsed time from the last congestion event. While most alternative congestion control algorithms to Standard TCP increase the congestion window using convex functions, CUBIC uses both the concave and convex profiles of a cubic function for window growth. After a window reduction in response to a congestion event is detected by duplicate ACKs or Explicit Congestion Notification-Echo (ECN-Echo) ACKs {{!RFC3168}}, CUBIC registers the congestion window size where it got the congestion event as W_max and performs a multiplicative decrease of congestion window. After it enters into congestion avoidance, it starts to increase the congestion window using the concave profile of the cubic function. The cubic function is set to have its plateau at W_max so that the concave window increase continues until the window size becomes W_max. After that, the cubic function turns into a convex profile and the convex window increase begins. This style of window adjustment (concave and then convex) improves the algorithm stability while maintaining high network utilization {{?CEHRX07}}. This is because the window size remains almost constant, forming a plateau around W_max where network utilization is deemed highest. Under steady state, most window size samples of CUBIC are close to W_max, thus promoting high network utilization and stability. Note that those congestion control algorithms using only convex functions to increase the congestion window size have the maximum increments around W_max, and thus introduce a large number of packet bursts around the saturation point of the network, likely causing frequent global loss synchronizations.
Principle 2: CUBIC promotes per-flow fairness to Standard TCP. Note that Standard TCP performs well under short RTT and small bandwidth (or small BDP) networks. There is only a scalability problem in networks with long RTTs and large bandwidth (or large BDP). An alternative congestion control algorithm to Standard TCP designed to be friendly to Standard TCP on a per-flow basis must operate to increase its congestion window less aggressively in small BDP networks than in large BDP networks. The aggressiveness of CUBIC mainly depends on the maximum window size before a window reduction, which is smaller in small BDP networks than in large BDP networks. Thus, CUBIC increases its congestion window less aggressively in small BDP networks than in large BDP networks. Furthermore, in cases when the cubic function of CUBIC increases its congestion window less aggressively than Standard TCP, CUBIC simply follows the window size of Standard TCP to ensure that CUBIC achieves at least the same throughput as Standard TCP in small BDP networks. We call this region where CUBIC behaves like Standard TCP, the "TCP-friendly region".
Principle 3: Two CUBIC flows with different RTTs have their throughput ratio linearly proportional to the inverse of their RTT ratio, where the throughput of a flow is approximately the size of its congestion window divided by its RTT. Specifically, CUBIC maintains a window increase rate independent of RTTs outside of the TCP-friendly region, and thus flows with different RTTs have similar congestion window sizes under steady state when they operate outside the TCP-friendly region. This notion of a linear throughput ratio is similar to that of Standard TCP under high statistical multiplexing environments where packet losses are independent of individual flow rates. However, under low statistical multiplexing environments, the throughput ratio of Standard TCP flows with different RTTs is quadratically proportional to the inverse of their RTT ratio {{XHR04}}. CUBIC always ensures the linear throughput ratio independent of the levels of statistical multiplexing. This is an improvement over Standard TCP. While there is no consensus on particular throughput ratios of different RTT flows, we believe that under wired Internet, use of a linear throughput ratio seems more reasonable than equal throughputs (i.e., the same throughput for flows with different RTTs) or a higher-order throughput ratio (e.g., a quadratical throughput ratio of Standard TCP under low statistical multiplexing environments).
Principle 4: To balance between the scalability and convergence speed, CUBIC sets the multiplicative window decrease factor to 0.7 while Standard TCP uses 0.5. While this improves the scalability of CUBIC, a side effect of this decision is slower convergence, especially under low statistical multiplexing environments. This design choice is following the observation that the author of HighSpeed TCP (HSTCP) {{?RFC3649}} has made along with other researchers (e.g., {{GV02}}): the current Internet becomes more asynchronous with less frequent loss synchronizations with high statistical multiplexing. Under this environment, even strict Multiplicative-Increase Multiplicative-Decrease (MIMD) can converge. CUBIC flows with the same RTT always converge to the same throughput independent of statistical multiplexing, thus achieving intra-algorithm fairness. We also find that under the environments with sufficient statistical multiplexing, the convergence speed of CUBIC flows is reasonable.
The unit of all window sizes in this document is segments of the maximum segment size (MSS), and the unit of all times is seconds. Let cwnd denote the congestion window size of a flow, and ssthresh denote the slow-start threshold.
CUBIC maintains the acknowledgment (ACK) clocking of Standard TCP by increasing the congestion window only at the reception of an ACK. It does not make any change to the fast recovery and retransmit of TCP, such as TCP-NewReno {{!RFC6582}}{{!RFC6675}}. During congestion avoidance after a congestion event where a packet loss is detected by duplicate ACKs or a network congestion is detected by ACKs with ECN-Echo flags {{!RFC3168}}, CUBIC changes the window increase function of Standard TCP. Suppose that W_max is the window size just before the window is reduced in the last congestion event.
CUBIC uses the following window increase function:
W_cubic(t) = C * (t - K)^3 + W_max (Eq. 1)
where C is a constant fixed to determine the aggressiveness of window increase in high BDP networks, t is the elapsed time from the beginning of the current congestion avoidance, and K is the time period that the above function takes to increase the current window size to W_max if there are no further congestion events and is calculated using the following equation:
K = cubic_root(W_max * (1 - beta_cubic) / C) (Eq. 2)
where beta_cubic is the CUBIC multiplication decrease factor, that is, when a congestion event is detected, CUBIC reduces its cwnd to W_cubic(0)=W_max*beta_cubic. We discuss how we set beta_cubic in {{mult-dec}} and how we set C in {{discussion}}.
Upon receiving an ACK during congestion avoidance, CUBIC computes the window increase rate during the next RTT period using Eq. 1. It sets W_cubic(t+RTT) as the candidate target value of the congestion window, where RTT is the weighted average RTT calculated by Standard TCP.
Depending on the value of the current congestion window size cwnd, CUBIC runs in three different modes.
-
The TCP-friendly region, which ensures that CUBIC achieves at least the same throughput as Standard TCP.
-
The concave region, if CUBIC is not in the TCP-friendly region and cwnd is less than W_max.
-
The convex region, if CUBIC is not in the TCP-friendly region and cwnd is greater than W_max.
Below, we describe the exact actions taken by CUBIC in each region.
Standard TCP performs well in certain types of networks, for example, under short RTT and small bandwidth (or small BDP) networks. In these networks, we use the TCP-friendly region to ensure that CUBIC achieves at least the same throughput as Standard TCP.
The TCP-friendly region is designed according to the analysis described in {{FHP00}}. The analysis studies the performance of an Additive Increase and Multiplicative Decrease (AIMD) algorithm with an additive factor of alpha_aimd (segments per RTT) and a multiplicative factor of beta_aimd, denoted by AIMD(alpha_aimd, beta_aimd). Specifically, the average congestion window size of AIMD(alpha_aimd, beta_aimd) can be calculated using Eq. 3. The analysis shows that AIMD(alpha_aimd, beta_aimd) with alpha_aimd=3*(1-beta_aimd)/(1+beta_aimd) achieves the same average window size as Standard TCP that uses AIMD(1, 0.5).
AVG_W_aimd = [alpha_aimd * (1 + beta_aimd) /
(2 * (1 - beta_aimd) * p)]^0.5 (Eq. 3)
Based on the above analysis, CUBIC uses Eq. 4 to estimate the window size W_est of AIMD(alpha_aimd, beta_aimd) with alpha_aimd=3*(1-beta_cubic)/(1+beta_cubic) and beta_aimd=beta_cubic, which achieves the same average window size as Standard TCP. When receiving an ACK in congestion avoidance (cwnd could be greater than or less than W_max), CUBIC checks whether W_cubic(t) is less than W_est(t). If so, CUBIC is in the TCP-friendly region and cwnd SHOULD be set to W_est(t) at each reception of an ACK.
W_est(t) = W_max * beta_cubic +
[3 * (1 - beta_cubic) / (1 + beta_cubic)] *
(t / RTT) (Eq. 4)
When receiving an ACK in congestion avoidance, if CUBIC is not in the TCP-friendly region and cwnd is less than W_max, then CUBIC is in the concave region. In this region, cwnd MUST be incremented by (W_cubic(t+RTT) - cwnd)/cwnd for each received ACK, where W_cubic(t+RTT) is calculated using Eq. 1.
When receiving an ACK in congestion avoidance, if CUBIC is not in the TCP-friendly region and cwnd is larger than or equal to W_max, then CUBIC is in the convex region. The convex region indicates that the network conditions might have been perturbed since the last congestion event, possibly implying more available bandwidth after some flow departures. Since the Internet is highly asynchronous, some amount of perturbation is always possible without causing a major change in available bandwidth. In this region, CUBIC is being very careful by very slowly increasing its window size. The convex profile ensures that the window increases very slowly at the beginning and gradually increases its increase rate. We also call this region the "maximum probing phase" since CUBIC is searching for a new W_max. In this region, cwnd MUST be incremented by (W_cubic(t+RTT) - cwnd)/cwnd for each received ACK, where W_cubic(t+RTT) is calculated using Eq. 1.
When a packet loss is detected by duplicate ACKs or a network congestion is detected by ECN-Echo ACKs, CUBIC updates its W_max, cwnd, and ssthresh as follows. Parameter beta_cubic SHOULD be set to 0.7.
W_max = cwnd // save window size before reduction
ssthresh = cwnd * beta_cubic // new slow-start threshold
ssthresh = max(ssthresh, 2) // threshold is at least 2 MSS
cwnd = cwnd * beta_cubic // window reduction
A side effect of setting beta_cubic to a value bigger than 0.5 is slower convergence. We believe that while a more adaptive setting of beta_cubic could result in faster convergence, it will make the analysis of CUBIC much harder. This adaptive adjustment of beta_cubic is an item for the next version of CUBIC.
To improve the convergence speed of CUBIC, we add a heuristic in CUBIC. When a new flow joins the network, existing flows in the network need to give up some of their bandwidth to allow the new flow some room for growth if the existing flows have been using all the bandwidth of the network. To speed up this bandwidth release by existing flows, the following mechanism called "fast convergence" SHOULD be implemented.
With fast convergence, when a congestion event occurs, before the window reduction of the congestion window, a flow remembers the last value of W_max before it updates W_max for the current congestion event. Let us call the last value of W_max to be W_last_max.
if (W_max < W_last_max) { // should we make room for others
W_last_max = W_max // remember the last W_max
W_max = W_max * (1.0 + beta_cubic) / 2.0 // further reduce
} else {
W_last_max = W_max // remember the last W_max
}
At a congestion event, if the current value of W_max is less than W_last_max, this indicates that the saturation point experienced by this flow is getting reduced because of the change in available bandwidth. Then we allow this flow to release more bandwidth by reducing W_max further. This action effectively lengthens the time for this flow to increase its congestion window because the reduced W_max forces the flow to have the plateau earlier. This allows more time for the new flow to catch up to its congestion window size.
The fast convergence is designed for network environments with multiple CUBIC flows. In network environments with only a single CUBIC flow and without any other traffic, the fast convergence SHOULD be disabled.
In case of timeout, CUBIC follows Standard TCP to reduce cwnd {{!RFC5681}}, but sets ssthresh using beta_cubic (same as in {{mult-dec}}) that is different from Standard TCP {{!RFC5681}}.
During the first congestion avoidance after a timeout, CUBIC increases its congestion window size using Eq. 1, where t is the elapsed time since the beginning of the current congestion avoidance, K is set to 0, and W_max is set to the congestion window size at the beginning of the current congestion avoidance.
CUBIC MUST employ a slow-start algorithm, when the cwnd is no more than ssthresh. Among the slow-start algorithms, CUBIC MAY choose the standard TCP slow start {{!RFC5681}} in general networks, or the limited slow start {{?RFC3742}} or hybrid slow start {{HR08}} for fast and long- distance networks.
In the case when CUBIC runs the hybrid slow start {{HR08}}, it may exit the first slow start without incurring any packet loss and thus W_max is undefined. In this special case, CUBIC switches to congestion avoidance and increases its congestion window size using Eq. 1, where t is the elapsed time since the beginning of the current congestion avoidance, K is set to 0, and W_max is set to the congestion window size at the beginning of the current congestion avoidance.
In this section, we further discuss the safety features of CUBIC following the guidelines specified in {{!RFC5033}}.
With a deterministic loss model where the number of packets between two successive packet losses is always 1/p, CUBIC always operates with the concave window profile, which greatly simplifies the performance analysis of CUBIC. The average window size of CUBIC can be obtained by the following function:
AVG_W_cubic = [C * (3 + beta_cubic) /
(4 * (1 - beta_cubic))]^0.25 *
(RTT^0.75) / (p^0.75) (Eq. 5)
With beta_cubic set to 0.7, the above formula is reduced to:
AVG_W_cubic = (C * 3.7 / 1.2)^0.25 * (RTT^0.75) / (p^0.75)
(Eq. 6)
We will determine the value of C in the following subsection using Eq. 6.
In environments where Standard TCP is able to make reasonable use of the available bandwidth, CUBIC does not significantly change this state.
Standard TCP performs well in the following two types of networks:
-
networks with a small bandwidth-delay product (BDP)
-
networks with a short RTTs, but not necessarily a small BDP
CUBIC is designed to behave very similarly to Standard TCP in the above two types of networks. The following two tables show the average window sizes of Standard TCP, HSTCP, and CUBIC. The average window sizes of Standard TCP and HSTCP are from {{?RFC3649}}. The average window size of CUBIC is calculated using Eq. 6 and the CUBIC TCP-friendly region for three different values of C.
+--------+----------+-----------+------------+-----------+----------+
| Loss | Average | Average | CUBIC | CUBIC | CUBIC |
| Rate P | TCP W | HSTCP W | (C=0.04) | (C=0.4) | (C=4) |
+--------+----------+-----------+------------+-----------+----------+
| 10^-2 | 12 | 12 | 12 | 12 | 12 |
| 10^-3 | 38 | 38 | 38 | 38 | 59 |
| 10^-4 | 120 | 263 | 120 | 187 | 333 |
| 10^-5 | 379 | 1795 | 593 | 1054 | 1874 |
| 10^-6 | 1200 | 12279 | 3332 | 5926 | 10538 |
| 10^-7 | 3795 | 83981 | 18740 | 33325 | 59261 |
| 10^-8 | 12000 | 574356 | 105383 | 187400 | 333250 |
+--------+----------+-----------+------------+-----------+----------+
Table 1
Table 1 describes the response function of Standard TCP, HSTCP, and CUBIC in networks with RTT = 0.1 seconds. The average window size is in MSS-sized segments.
+--------+-----------+-----------+------------+-----------+---------+
| Loss | Average | Average | CUBIC | CUBIC | CUBIC |
| Rate P | TCP W | HSTCP W | (C=0.04) | (C=0.4) | (C=4) |
+--------+-----------+-----------+------------+-----------+---------+
| 10^-2 | 12 | 12 | 12 | 12 | 12 |
| 10^-3 | 38 | 38 | 38 | 38 | 38 |
| 10^-4 | 120 | 263 | 120 | 120 | 120 |
| 10^-5 | 379 | 1795 | 379 | 379 | 379 |
| 10^-6 | 1200 | 12279 | 1200 | 1200 | 1874 |
| 10^-7 | 3795 | 83981 | 3795 | 5926 | 10538 |
| 10^-8 | 12000 | 574356 | 18740 | 33325 | 59261 |
+--------+-----------+-----------+------------+-----------+---------+
Table 2
Table 2 describes the response function of Standard TCP, HSTCP, and CUBIC in networks with RTT = 0.01 seconds. The average window size is in MSS-sized segments.
Both tables show that CUBIC with any of these three C values is more friendly to TCP than HSTCP, especially in networks with a short RTT where TCP performs reasonably well. For example, in a network with RTT = 0.01 seconds and p=10^-6, TCP has an average window of 1200 packets. If the packet size is 1500 bytes, then TCP can achieve an average rate of 1.44 Gbps. In this case, CUBIC with C=0.04 or C=0.4 achieves exactly the same rate as Standard TCP, whereas HSTCP is about ten times more aggressive than Standard TCP.
We can see that C determines the aggressiveness of CUBIC in competing with other congestion control algorithms for bandwidth. CUBIC is more friendly to Standard TCP, if the value of C is lower. However, we do not recommend setting C to a very low value like 0.04, since CUBIC with a low C cannot efficiently use the bandwidth in long RTT and high-bandwidth networks. Based on these observations and our experiments, we find C=0.4 gives a good balance between TCP- friendliness and aggressiveness of window increase. Therefore, C SHOULD be set to 0.4. With C set to 0.4, Eq. 6 is reduced to:
AVG_W_cubic = 1.054 * (RTT^0.75) / (p^0.75) (Eq. 7)
Eq. 7 is then used in the next subsection to show the scalability of CUBIC.
CUBIC uses a more aggressive window increase function than Standard TCP under long RTT and high-bandwidth networks.
The following table shows that to achieve the 10 Gbps rate, Standard TCP requires a packet loss rate of 2.0e-10, while CUBIC requires a packet loss rate of 2.9e-8.
+------------------+-----------+---------+---------+---------+
| Throughput(Mbps) | Average W | TCP P | HSTCP P | CUBIC P |
+------------------+-----------+---------+---------+---------+
| 1 | 8.3 | 2.0e-2 | 2.0e-2 | 2.0e-2 |
| 10 | 83.3 | 2.0e-4 | 3.9e-4 | 2.9e-4 |
| 100 | 833.3 | 2.0e-6 | 2.5e-5 | 1.4e-5 |
| 1000 | 8333.3 | 2.0e-8 | 1.5e-6 | 6.3e-7 |
| 10000 | 83333.3 | 2.0e-10 | 1.0e-7 | 2.9e-8 |
+------------------+-----------+---------+---------+---------+
Table 3
Table 3 describes the required packet loss rate for Standard TCP, HSTCP, and CUBIC to achieve a certain throughput. We use 1500-byte packets and an RTT of 0.1 seconds.
Our test results in {{HKLRX06}} indicate that CUBIC uses the spare bandwidth left unused by existing Standard TCP flows in the same bottleneck link without taking away much bandwidth from the existing flows.
CUBIC is designed to remedy the poor performance of TCP in fast and long-distance networks.
CUBIC has been extensively studied by using both NS-2 simulation and test-bed experiments covering a wide range of network environments. More information can be found in {{HKLRX06}}.
Same as Standard TCP, CUBIC is a loss-based congestion control algorithm. Because CUBIC is designed to be more aggressive (due to a faster window increase function and bigger multiplicative decrease factor) than Standard TCP in fast and long-distance networks, it can fill large drop-tail buffers more quickly than Standard TCP and increase the risk of a standing queue {{?RFC8511}}. In this case, proper queue sizing and management {{!RFC7567}} could be used to reduce the packet queuing delay.
With regard to the potential of causing congestion collapse, CUBIC behaves like Standard TCP since CUBIC modifies only the window adjustment algorithm of TCP. Thus, it does not modify the ACK clocking and Timeout behaviors of Standard TCP.
CUBIC ensures convergence of competing CUBIC flows with the same RTT in the same bottleneck links to an equal throughput. When competing flows have different RTTs, their throughput ratio is linearly proportional to the inverse of their RTT ratios. This is true independent of the level of statistical multiplexing in the link.
This is not considered in the current CUBIC.
CUBIC does not raise its congestion window size if the flow is currently limited by the application instead of the congestion window. In case of long periods when cwnd has not been updated due to the application rate limit, such as idle periods, t in Eq. 1 MUST NOT include these periods; otherwise, W_cubic(t) might be very high after restarting from these periods.
If there is a sudden congestion, a routing change, or a mobility event, CUBIC behaves the same as Standard TCP.
CUBIC requires only the change of TCP senders, and it does not make any changes to TCP receivers. That is, a CUBIC sender works correctly with the Standard TCP receivers. In addition, CUBIC does not require any changes to the routers and does not require any assistance from the routers.
This proposal makes no changes to the underlying security of TCP. More information about TCP security concerns can be found in {{!RFC5681}}.
This document does not require any IANA actions.
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