| blob | 0e1a8c91f78eb337c3f0fb1f58dd2497f1f76e2d |
1 /*
2 * TCP Vegas congestion control
3 *
4 * This is based on the congestion detection/avoidance scheme described in
5 * Lawrence S. Brakmo and Larry L. Peterson.
6 * "TCP Vegas: End to end congestion avoidance on a global internet."
7 * IEEE Journal on Selected Areas in Communication, 13(8):1465--1480,
8 * October 1995. Available from:
9 * ftp://ftp.cs.arizona.edu/xkernel/Papers/jsac.ps
10 *
11 * See http://www.cs.arizona.edu/xkernel/ for their implementation.
12 * The main aspects that distinguish this implementation from the
13 * Arizona Vegas implementation are:
14 * o We do not change the loss detection or recovery mechanisms of
15 * Linux in any way. Linux already recovers from losses quite well,
16 * using fine-grained timers, NewReno, and FACK.
17 * o To avoid the performance penalty imposed by increasing cwnd
18 * only every-other RTT during slow start, we increase during
19 * every RTT during slow start, just like Reno.
20 * o Largely to allow continuous cwnd growth during slow start,
21 * we use the rate at which ACKs come back as the "actual"
22 * rate, rather than the rate at which data is sent.
23 * o To speed convergence to the right rate, we set the cwnd
24 * to achieve the right ("actual") rate when we exit slow start.
25 * o To filter out the noise caused by delayed ACKs, we use the
26 * minimum RTT sample observed during the last RTT to calculate
27 * the actual rate.
28 * o When the sender re-starts from idle, it waits until it has
29 * received ACKs for an entire flight of new data before making
30 * a cwnd adjustment decision. The original Vegas implementation
31 * assumed senders never went idle.
32 */
34 #include <linux/mm.h>
35 #include <linux/module.h>
36 #include <linux/skbuff.h>
37 #include <linux/inet_diag.h>
39 #include <net/tcp.h>
43 /* Default values of the Vegas variables, in fixed-point representation
44 * with V_PARAM_SHIFT bits to the right of the binary point.
45 */
46 #define V_PARAM_SHIFT 1
59 /* There are several situations when we must "re-start" Vegas:
60 *
61 * o when a connection is established
62 * o after an RTO
63 * o after fast recovery
64 * o when we send a packet and there is no outstanding
65 * unacknowledged data (restarting an idle connection)
66 *
67 * In these circumstances we cannot do a Vegas calculation at the
68 * end of the first RTT, because any calculation we do is using
69 * stale info -- both the saved cwnd and congestion feedback are
70 * stale.
71 *
72 * Instead we must wait until the completion of an RTT during
73 * which we actually receive ACKs.
74 */
76 {
80 /* Begin taking Vegas samples next time we send something. */
83 /* Set the beginning of the next send window. */
88 }
90 /* Stop taking Vegas samples for now. */
92 {
96 }
99 {
104 }
107 /* Do RTT sampling needed for Vegas.
108 * Basically we:
109 * o min-filter RTT samples from within an RTT to get the current
110 * propagation delay + queuing delay (we are min-filtering to try to
111 * avoid the effects of delayed ACKs)
112 * o min-filter RTT samples from a much longer window (forever for now)
113 * to find the propagation delay (baseRTT)
114 */
116 {
118 u32 vrtt;
123 /* Never allow zero rtt or baseRTT */
126 /* Filter to find propagation delay: */
130 /* Find the min RTT during the last RTT to find
131 * the current prop. delay + queuing delay:
132 */
135 }
139 {
143 else
145 }
148 /*
149 * If the connection is idle and we are restarting,
150 * then we don't want to do any Vegas calculations
151 * until we get fresh RTT samples. So when we
152 * restart, we reset our Vegas state to a clean
153 * slate. After we get acks for this flight of
154 * packets, _then_ we can make Vegas calculations
155 * again.
156 */
158 {
162 }
166 {
173 /* The key players are v_beg_snd_una and v_beg_snd_nxt.
174 *
175 * These are so named because they represent the approximate values
176 * of snd_una and snd_nxt at the beginning of the current RTT. More
177 * precisely, they represent the amount of data sent during the RTT.
178 * At the end of the RTT, when we receive an ACK for v_beg_snd_nxt,
179 * we will calculate that (v_beg_snd_nxt - v_beg_snd_una) outstanding
180 * bytes of data have been ACKed during the course of the RTT, giving
181 * an "actual" rate of:
182 *
183 * (v_beg_snd_nxt - v_beg_snd_una) / (rtt duration)
184 *
185 * Unfortunately, v_beg_snd_una is not exactly equal to snd_una,
186 * because delayed ACKs can cover more than one segment, so they
187 * don't line up nicely with the boundaries of RTTs.
188 *
189 * Another unfortunate fact of life is that delayed ACKs delay the
190 * advance of the left edge of our send window, so that the number
191 * of bytes we send in an RTT is often less than our cwnd will allow.
192 * So we keep track of our cwnd separately, in v_beg_snd_cwnd.
193 */
196 /* Do the Vegas once-per-RTT cwnd adjustment. */
200 /* Here old_wnd is essentially the window of data that was
201 * sent during the previous RTT, and has all
202 * been acknowledged in the course of the RTT that ended
203 * with the ACK we just received. Likewise, old_snd_cwnd
204 * is the cwnd during the previous RTT.
205 */
210 /* Save the extent of the current window so we can use this
211 * at the end of the next RTT.
212 */
217 /* We do the Vegas calculations only if we got enough RTT
218 * samples that we can be reasonably sure that we got
219 * at least one RTT sample that wasn't from a delayed ACK.
220 * If we only had 2 samples total,
221 * then that means we're getting only 1 ACK per RTT, which
222 * means they're almost certainly delayed ACKs.
223 * If we have 3 samples, we should be OK.
224 */
227 /* We don't have enough RTT samples to do the Vegas
228 * calculation, so we'll behave like Reno.
229 */
233 u64 target_cwnd;
235 /* We have enough RTT samples, so, using the Vegas
236 * algorithm, we determine if we should increase or
237 * decrease cwnd, and by how much.
238 */
240 /* Pluck out the RTT we are using for the Vegas
241 * calculations. This is the min RTT seen during the
242 * last RTT. Taking the min filters out the effects
243 * of delayed ACKs, at the cost of noticing congestion
244 * a bit later.
245 */
248 /* Calculate the cwnd we should have, if we weren't
249 * going too fast.
250 *
251 * This is:
252 * (actual rate in segments) * baseRTT
253 * We keep it as a fixed point number with
254 * V_PARAM_SHIFT bits to the right of the binary point.
255 */
260 /* Calculate the difference between the window we had,
261 * and the window we would like to have. This quantity
262 * is the "Diff" from the Arizona Vegas papers.
263 *
264 * Again, this is a fixed point number with
265 * V_PARAM_SHIFT bits to the right of the binary
266 * point.
267 */
271 /* Going too fast. Time to slow down
272 * and switch to congestion avoidance.
273 */
276 /* Set cwnd to match the actual rate
277 * exactly:
278 * cwnd = (actual rate) * baseRTT
279 * Then we add 1 because the integer
280 * truncation robs us of full link
281 * utilization.
282 */
288 /* Slow start. */
291 /* Congestion avoidance. */
292 u32 next_snd_cwnd;
294 /* Figure out where we would like cwnd
295 * to be.
296 */
298 /* The old window was too fast, so
299 * we slow down.
300 */
303 /* We don't have enough extra packets
304 * in the network, so speed up.
305 */
308 /* Sending just as fast as we
309 * should be.
310 */
312 }
314 /* Adjust cwnd upward or downward, toward the
315 * desired value.
316 */
321 }
327 }
329 /* Wipe the slate clean for the next RTT. */
332 }
333 /* Use normal slow start */
337 }
339 /* Extract info for Tcp socket info provided via netlink. */
341 {
349 };
352 }
353 }
369 };
372 {
376 }
379 {
381 }