| blob | 6c4d79baff2696b859d214bb63108b9f2f61f457 |
1 /* Bottleneck Bandwidth and RTT (BBR) congestion control
2 *
3 * BBR congestion control computes the sending rate based on the delivery
4 * rate (throughput) estimated from ACKs. In a nutshell:
5 *
6 * On each ACK, update our model of the network path:
7 * bottleneck_bandwidth = windowed_max(delivered / elapsed, 10 round trips)
8 * min_rtt = windowed_min(rtt, 10 seconds)
9 * pacing_rate = pacing_gain * bottleneck_bandwidth
10 * cwnd = max(cwnd_gain * bottleneck_bandwidth * min_rtt, 4)
11 *
12 * The core algorithm does not react directly to packet losses or delays,
13 * although BBR may adjust the size of next send per ACK when loss is
14 * observed, or adjust the sending rate if it estimates there is a
15 * traffic policer, in order to keep the drop rate reasonable.
16 *
17 * Here is a state transition diagram for BBR:
18 *
19 * |
20 * V
21 * +---> STARTUP ----+
22 * | | |
23 * | V |
24 * | DRAIN ----+
25 * | | |
26 * | V |
27 * +---> PROBE_BW ----+
28 * | ^ | |
29 * | | | |
30 * | +----+ |
31 * | |
32 * +---- PROBE_RTT <--+
33 *
34 * A BBR flow starts in STARTUP, and ramps up its sending rate quickly.
35 * When it estimates the pipe is full, it enters DRAIN to drain the queue.
36 * In steady state a BBR flow only uses PROBE_BW and PROBE_RTT.
37 * A long-lived BBR flow spends the vast majority of its time remaining
38 * (repeatedly) in PROBE_BW, fully probing and utilizing the pipe's bandwidth
39 * in a fair manner, with a small, bounded queue. *If* a flow has been
40 * continuously sending for the entire min_rtt window, and hasn't seen an RTT
41 * sample that matches or decreases its min_rtt estimate for 10 seconds, then
42 * it briefly enters PROBE_RTT to cut inflight to a minimum value to re-probe
43 * the path's two-way propagation delay (min_rtt). When exiting PROBE_RTT, if
44 * we estimated that we reached the full bw of the pipe then we enter PROBE_BW;
45 * otherwise we enter STARTUP to try to fill the pipe.
46 *
47 * BBR is described in detail in:
48 * "BBR: Congestion-Based Congestion Control",
49 * Neal Cardwell, Yuchung Cheng, C. Stephen Gunn, Soheil Hassas Yeganeh,
50 * Van Jacobson. ACM Queue, Vol. 14 No. 5, September-October 2016.
51 *
52 * There is a public e-mail list for discussing BBR development and testing:
53 * https://groups.google.com/forum/#!forum/bbr-dev
54 *
55 * NOTE: BBR might be used with the fq qdisc ("man tc-fq") with pacing enabled,
56 * otherwise TCP stack falls back to an internal pacing using one high
57 * resolution timer per TCP socket and may use more resources.
58 */
59 #include <linux/module.h>
60 #include <net/tcp.h>
61 #include <linux/inet_diag.h>
62 #include <linux/inet.h>
63 #include <linux/random.h>
64 #include <linux/win_minmax.h>
66 /* Scale factor for rate in pkt/uSec unit to avoid truncation in bandwidth
67 * estimation. The rate unit ~= (1500 bytes / 1 usec / 2^24) ~= 715 bps.
68 * This handles bandwidths from 0.06pps (715bps) to 256Mpps (3Tbps) in a u32.
69 * Since the minimum window is >=4 packets, the lower bound isn't
70 * an issue. The upper bound isn't an issue with existing technologies.
71 */
72 #define BW_SCALE 24
73 #define BW_UNIT (1 << BW_SCALE)
76 #define BBR_UNIT (1 << BBR_SCALE)
78 /* BBR has the following modes for deciding how fast to send: */
84 };
86 /* BBR congestion control block */
119 /* For tracking ACK aggregation: */
126 };
130 /* Window length of bw filter (in rounds): */
132 /* Window length of min_rtt filter (in sec): */
134 /* Minimum time (in ms) spent at bbr_cwnd_min_target in BBR_PROBE_RTT mode: */
136 /* Skip TSO below the following bandwidth (bits/sec): */
139 /* Pace at ~1% below estimated bw, on average, to reduce queue at bottleneck.
140 * In order to help drive the network toward lower queues and low latency while
141 * maintaining high utilization, the average pacing rate aims to be slightly
142 * lower than the estimated bandwidth. This is an important aspect of the
143 * design.
144 */
147 /* We use a high_gain value of 2/ln(2) because it's the smallest pacing gain
148 * that will allow a smoothly increasing pacing rate that will double each RTT
149 * and send the same number of packets per RTT that an un-paced, slow-starting
150 * Reno or CUBIC flow would:
151 */
153 /* The pacing gain of 1/high_gain in BBR_DRAIN is calculated to typically drain
154 * the queue created in BBR_STARTUP in a single round:
155 */
157 /* The gain for deriving steady-state cwnd tolerates delayed/stretched ACKs: */
159 /* The pacing_gain values for the PROBE_BW gain cycle, to discover/share bw: */
165 };
166 /* Randomize the starting gain cycling phase over N phases: */
169 /* Try to keep at least this many packets in flight, if things go smoothly. For
170 * smooth functioning, a sliding window protocol ACKing every other packet
171 * needs at least 4 packets in flight:
172 */
175 /* To estimate if BBR_STARTUP mode (i.e. high_gain) has filled pipe... */
176 /* If bw has increased significantly (1.25x), there may be more bw available: */
178 /* But after 3 rounds w/o significant bw growth, estimate pipe is full: */
181 /* "long-term" ("LT") bandwidth estimator parameters... */
182 /* The minimum number of rounds in an LT bw sampling interval: */
184 /* If lost/delivered ratio > 20%, interval is "lossy" and we may be policed: */
186 /* If 2 intervals have a bw ratio <= 1/8, their bw is "consistent": */
188 /* If 2 intervals have a bw diff <= 4 Kbit/sec their bw is "consistent": */
190 /* If we estimate we're policed, use lt_bw for this many round trips: */
193 /* Gain factor for adding extra_acked to target cwnd: */
195 /* Window length of extra_acked window. */
197 /* Max allowed val for ack_epoch_acked, after which sampling epoch is reset */
199 /* Time period for clamping cwnd increment due to ack aggregation */
204 /* Do we estimate that STARTUP filled the pipe? */
206 {
210 }
212 /* Return the windowed max recent bandwidth sample, in pkts/uS << BW_SCALE. */
214 {
218 }
220 /* Return the estimated bandwidth of the path, in pkts/uS << BW_SCALE. */
222 {
226 }
228 /* Return maximum extra acked in past k-2k round trips,
229 * where k = bbr_extra_acked_win_rtts.
230 */
232 {
236 }
238 /* Return rate in bytes per second, optionally with a gain.
239 * The order here is chosen carefully to avoid overflow of u64. This should
240 * work for input rates of up to 2.9Tbit/sec and gain of 2.89x.
241 */
243 {
251 }
253 /* Convert a BBR bw and gain factor to a pacing rate in bytes per second. */
255 {
261 }
263 /* Initialize pacing rate to: high_gain * init_cwnd / RTT. */
265 {
268 u64 bw;
269 u32 rtt_us;
276 }
280 }
282 /* Pace using current bw estimate and a gain factor. */
284 {
293 }
295 /* override sysctl_tcp_min_tso_segs */
297 {
299 }
302 {
306 /* Sort of tcp_tso_autosize() but ignoring
307 * driver provided sk_gso_max_size.
308 */
315 }
317 /* Save "last known good" cwnd so we can restore it after losses or PROBE_RTT */
319 {
327 }
330 {
338 /* Avoid pointless buffer overflows: pace at est. bw if we don't
339 * need more speed (we're restarting from idle and app-limited).
340 */
345 }
346 }
348 /* Calculate bdp based on min RTT and the estimated bottleneck bandwidth:
349 *
350 * bdp = ceil(bw * min_rtt * gain)
351 *
352 * The key factor, gain, controls the amount of queue. While a small gain
353 * builds a smaller queue, it becomes more vulnerable to noise in RTT
354 * measurements (e.g., delayed ACKs or other ACK compression effects). This
355 * noise may cause BBR to under-estimate the rate.
356 */
358 {
360 u32 bdp;
361 u64 w;
363 /* If we've never had a valid RTT sample, cap cwnd at the initial
364 * default. This should only happen when the connection is not using TCP
365 * timestamps and has retransmitted all of the SYN/SYNACK/data packets
366 * ACKed so far. In this case, an RTO can cut cwnd to 1, in which
367 * case we need to slow-start up toward something safe: TCP_INIT_CWND.
368 */
374 /* Apply a gain to the given value, remove the BW_SCALE shift, and
375 * round the value up to avoid a negative feedback loop.
376 */
380 }
382 /* To achieve full performance in high-speed paths, we budget enough cwnd to
383 * fit full-sized skbs in-flight on both end hosts to fully utilize the path:
384 * - one skb in sending host Qdisc,
385 * - one skb in sending host TSO/GSO engine
386 * - one skb being received by receiver host LRO/GRO/delayed-ACK engine
387 * Don't worry, at low rates (bbr_min_tso_rate) this won't bloat cwnd because
388 * in such cases tso_segs_goal is 1. The minimum cwnd is 4 packets,
389 * which allows 2 outstanding 2-packet sequences, to try to keep pipe
390 * full even with ACK-every-other-packet delayed ACKs.
391 */
393 {
396 /* Allow enough full-sized skbs in flight to utilize end systems. */
399 /* Reduce delayed ACKs by rounding up cwnd to the next even number. */
402 /* Ensure gain cycling gets inflight above BDP even for small BDPs. */
407 }
409 /* Find inflight based on min RTT and the estimated bottleneck bandwidth. */
411 {
412 u32 inflight;
418 }
420 /* With pacing at lower layers, there's often less data "in the network" than
421 * "in flight". With TSQ and departure time pacing at lower layers (e.g. fq),
422 * we often have several skbs queued in the pacing layer with a pre-scheduled
423 * earliest departure time (EDT). BBR adapts its pacing rate based on the
424 * inflight level that it estimates has already been "baked in" by previous
425 * departure time decisions. We calculate a rough estimate of the number of our
426 * packets that might be in the network at the earliest departure time for the
427 * next skb scheduled:
428 * in_network_at_edt = inflight_at_edt - (EDT - now) * bw
429 * If we're increasing inflight, then we want to know if the transmit of the
430 * EDT skb will push inflight above the target, so inflight_at_edt includes
431 * bbr_tso_segs_goal() from the skb departing at EDT. If decreasing inflight,
432 * then estimate if inflight will sink too low just before the EDT transmit.
433 */
435 {
451 }
453 /* Find the cwnd increment based on estimate of ack aggregation */
455 {
464 }
467 }
469 /* An optimization in BBR to reduce losses: On the first round of recovery, we
470 * follow the packet conservation principle: send P packets per P packets acked.
471 * After that, we slow-start and send at most 2*P packets per P packets acked.
472 * After recovery finishes, or upon undo, we restore the cwnd we had when
473 * recovery started (capped by the target cwnd based on estimated BDP).
474 *
475 * TODO(ycheng/ncardwell): implement a rate-based approach.
476 */
479 {
485 /* An ACK for P pkts should release at most 2*P packets. We do this
486 * in two steps. First, here we deduct the number of lost packets.
487 * Then, in bbr_set_cwnd() we slow start up toward the target cwnd.
488 */
493 /* Starting 1st round of Recovery, so do packet conservation. */
496 /* Cut unused cwnd from app behavior, TSQ, or TSO deferral: */
499 /* Exiting loss recovery; restore cwnd saved before recovery. */
502 }
508 }
511 }
513 /* Slow-start up toward target cwnd (if bw estimate is growing, or packet loss
514 * has drawn us down below target), or snap down to target if we're above it.
515 */
518 {
531 /* Increment the cwnd to account for excess ACKed data that seems
532 * due to aggregation (of data and/or ACKs) visible in the ACK stream.
533 */
537 /* If we're below target cwnd, slow start cwnd toward target cwnd. */
544 done:
548 }
550 /* End cycle phase if it's time and/or we hit the phase's in-flight target. */
553 {
561 /* The pacing_gain of 1.0 paces at the estimated bw to try to fully
562 * use the pipe without increasing the queue.
563 */
570 /* A pacing_gain > 1.0 probes for bw by trying to raise inflight to at
571 * least pacing_gain*BDP; this may take more than min_rtt if min_rtt is
572 * small (e.g. on a LAN). We do not persist if packets are lost, since
573 * a path with small buffers may not hold that much.
574 */
580 /* A pacing_gain < 1.0 tries to drain extra queue we added if bw
581 * probing didn't find more bw. If inflight falls to match BDP then we
582 * estimate queue is drained; persisting would underutilize the pipe.
583 */
586 }
589 {
595 }
597 /* Gain cycling: cycle pacing gain to converge to fair share of available bw. */
600 {
605 }
608 {
612 }
615 {
621 }
624 {
627 else
629 }
631 /* Start a new long-term sampling interval. */
633 {
641 }
643 /* Completely reset long-term bandwidth sampling. */
645 {
652 }
654 /* Long-term bw sampling interval is done. Estimate whether we're policed. */
656 {
658 u32 diff;
661 /* Is new bw close to the lt_bw from the previous interval? */
665 bbr_lt_bw_diff)) {
666 /* All criteria are met; estimate we're policed. */
672 }
673 }
676 }
678 /* Token-bucket traffic policers are common (see "An Internet-Wide Analysis of
679 * Traffic Policing", SIGCOMM 2016). BBR detects token-bucket policers and
680 * explicitly models their policed rate, to reduce unnecessary losses. We
681 * estimate that we're policed if we see 2 consecutive sampling intervals with
682 * consistent throughput and high packet loss. If we think we're being policed,
683 * set lt_bw to the "long-term" average delivery rate from those 2 intervals.
684 */
686 {
690 u64 bw;
691 u32 t;
698 }
700 }
702 /* Wait for the first loss before sampling, to let the policer exhaust
703 * its tokens and estimate the steady-state rate allowed by the policer.
704 * Starting samples earlier includes bursts that over-estimate the bw.
705 */
711 }
713 /* To avoid underestimates, reset sampling if we run out of data. */
717 }
726 }
728 /* End sampling interval when a packet is lost, so we estimate the
729 * policer tokens were exhausted. Stopping the sampling before the
730 * tokens are exhausted under-estimates the policed rate.
731 */
735 /* Calculate packets lost and delivered in sampling interval. */
738 /* Is loss rate (lost/delivered) >= lt_loss_thresh? If not, wait. */
742 /* Find average delivery rate in this sampling interval. */
746 /* Check if can multiply without overflow */
750 }
755 }
757 /* Estimate the bandwidth based on how fast packets are delivered */
759 {
762 u64 bw;
768 /* See if we've reached the next RTT */
774 }
778 /* Divide delivered by the interval to find a (lower bound) bottleneck
779 * bandwidth sample. Delivered is in packets and interval_us in uS and
780 * ratio will be <<1 for most connections. So delivered is first scaled.
781 */
784 /* If this sample is application-limited, it is likely to have a very
785 * low delivered count that represents application behavior rather than
786 * the available network rate. Such a sample could drag down estimated
787 * bw, causing needless slow-down. Thus, to continue to send at the
788 * last measured network rate, we filter out app-limited samples unless
789 * they describe the path bw at least as well as our bw model.
790 *
791 * So the goal during app-limited phase is to proceed with the best
792 * network rate no matter how long. We automatically leave this
793 * phase when app writes faster than the network can deliver :)
794 */
796 /* Incorporate new sample into our max bw filter. */
798 }
799 }
801 /* Estimates the windowed max degree of ack aggregation.
802 * This is used to provision extra in-flight data to keep sending during
803 * inter-ACK silences.
804 *
805 * Degree of ack aggregation is estimated as extra data acked beyond expected.
806 *
807 * max_extra_acked = "maximum recent excess data ACKed beyond max_bw * interval"
808 * cwnd += max_extra_acked
809 *
810 * Max extra_acked is clamped by cwnd and bw * bbr_extra_acked_max_us (100 ms).
811 * Max filter is an approximate sliding window of 5-10 (packet timed) round
812 * trips.
813 */
816 {
833 }
834 }
836 /* Compute how many packets we expected to be delivered over epoch. */
841 /* Reset the aggregation epoch if ACK rate is below expected rate or
842 * significantly large no. of ack received since epoch (potentially
843 * quite old epoch).
844 */
847 bbr_ack_epoch_acked_reset_thresh)) {
851 }
853 /* Compute excess data delivered, beyond what was expected. */
860 }
862 /* Estimate when the pipe is full, using the change in delivery rate: BBR
863 * estimates that STARTUP filled the pipe if the estimated bw hasn't changed by
864 * at least bbr_full_bw_thresh (25%) after bbr_full_bw_cnt (3) non-app-limited
865 * rounds. Why 3 rounds: 1: rwin autotuning grows the rwin, 2: we fill the
866 * higher rwin, 3: we get higher delivery rate samples. Or transient
867 * cross-traffic or radio noise can go away. CUBIC Hystart shares a similar
868 * design goal, but uses delay and inter-ACK spacing instead of bandwidth.
869 */
872 {
874 u32 bw_thresh;
884 }
887 }
889 /* If pipe is probably full, drain the queue and then enter steady-state. */
891 {
903 }
906 {
917 }
919 /* The goal of PROBE_RTT mode is to have BBR flows cooperatively and
920 * periodically drain the bottleneck queue, to converge to measure the true
921 * min_rtt (unloaded propagation delay). This allows the flows to keep queues
922 * small (reducing queuing delay and packet loss) and achieve fairness among
923 * BBR flows.
924 *
925 * The min_rtt filter window is 10 seconds. When the min_rtt estimate expires,
926 * we enter PROBE_RTT mode and cap the cwnd at bbr_cwnd_min_target=4 packets.
927 * After at least bbr_probe_rtt_mode_ms=200ms and at least one packet-timed
928 * round trip elapsed with that flight size <= 4, we leave PROBE_RTT mode and
929 * re-enter the previous mode. BBR uses 200ms to approximately bound the
930 * performance penalty of PROBE_RTT's cwnd capping to roughly 2% (200ms/10s).
931 *
932 * Note that flows need only pay 2% if they are busy sending over the last 10
933 * seconds. Interactive applications (e.g., Web, RPCs, video chunks) often have
934 * natural silences or low-rate periods within 10 seconds where the rate is low
935 * enough for long enough to drain its queue in the bottleneck. We pick up
936 * these min RTT measurements opportunistically with our min_rtt filter. :-)
937 */
939 {
944 /* Track min RTT seen in the min_rtt_win_sec filter window: */
952 }
959 }
962 /* Ignore low rate samples during this mode. */
965 /* Maintain min packets in flight for max(200 ms, 1 round). */
977 }
978 }
979 /* Restart after idle ends only once we process a new S/ACK for data */
982 }
985 {
999 BBR_UNIT :
1010 }
1011 }
1014 {
1022 }
1025 {
1027 u32 bw;
1034 }
1037 {
1076 }
1079 {
1080 /* Provision 3 * cwnd since BBR may slow-start even during recovery. */
1082 }
1084 /* In theory BBR does not need to undo the cwnd since it does not
1085 * always reduce cwnd on losses (see bbr_main()). Keep it for now.
1086 */
1088 {
1095 }
1097 /* Entering loss recovery, so save cwnd for when we exit or undo recovery. */
1099 {
1102 }
1106 {
1122 }
1124 }
1127 {
1137 }
1138 }
1153 };
1156 {
1159 }
1162 {
1164 }