dev/ic/athrate-sample.c

1.9  gdamore /*	$NetBSD: athrate-sample.c,v 1.9 2006/04/02 05:52:50 gdamore Exp $ */
1.7  xtraeme
1.1   dyoung /*-
1.1   dyoung  * Copyright (c) 2005 John Bicket
1.1   dyoung  * All rights reserved.
1.1   dyoung  *
1.1   dyoung  * Redistribution and use in source and binary forms, with or without
1.1   dyoung  * modification, are permitted provided that the following conditions
1.1   dyoung  * are met:
1.1   dyoung  * 1. Redistributions of source code must retain the above copyright
1.1   dyoung  *    notice, this list of conditions and the following disclaimer,
1.1   dyoung  *    without modification.
1.1   dyoung  * 2. Redistributions in binary form must reproduce at minimum a disclaimer
1.1   dyoung  *    similar to the "NO WARRANTY" disclaimer below ("Disclaimer") and any
1.1   dyoung  *    redistribution must be conditioned upon including a substantially
1.1   dyoung  *    similar Disclaimer requirement for further binary redistribution.
1.1   dyoung  * 3. Neither the names of the above-listed copyright holders nor the names
1.1   dyoung  *    of any contributors may be used to endorse or promote products derived
1.1   dyoung  *    from this software without specific prior written permission.
1.1   dyoung  *
1.1   dyoung  * Alternatively, this software may be distributed under the terms of the
1.1   dyoung  * GNU General Public License ("GPL") version 2 as published by the Free
1.1   dyoung  * Software Foundation.
1.1   dyoung  *
1.1   dyoung  * NO WARRANTY
1.1   dyoung  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
1.1   dyoung  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
1.1   dyoung  * LIMITED TO, THE IMPLIED WARRANTIES OF NONINFRINGEMENT, MERCHANTIBILITY
1.1   dyoung  * AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL
1.1   dyoung  * THE COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR SPECIAL, EXEMPLARY,
1.1   dyoung  * OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1   dyoung  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1   dyoung  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER
1.1   dyoung  * IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1   dyoung  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
1.1   dyoung  * THE POSSIBILITY OF SUCH DAMAGES.
1.1   dyoung  */
1.1   dyoung
1.1   dyoung #include <sys/cdefs.h>
1.3   dyoung #ifdef __FreeBSD__
1.5    skrll __FBSDID("$FreeBSD: src/sys/dev/ath/ath_rate/sample/sample.c,v 1.9 2005/07/22 16:50:17 sam Exp $");
1.3   dyoung #endif
1.3   dyoung #ifdef __NetBSD__
1.9  gdamore __KERNEL_RCSID(0, "$NetBSD: athrate-sample.c,v 1.9 2006/04/02 05:52:50 gdamore Exp $");
1.3   dyoung #endif
1.3   dyoung
1.1   dyoung
1.1   dyoung /*
1.1   dyoung  * John Bicket's SampleRate control algorithm.
1.1   dyoung  */
1.1   dyoung #include "opt_inet.h"
1.1   dyoung
1.1   dyoung #include <sys/param.h>
1.1   dyoung #include <sys/systm.h>
1.1   dyoung #include <sys/sysctl.h>
1.1   dyoung #include <sys/kernel.h>
1.1   dyoung #include <sys/lock.h>
1.1   dyoung #include <sys/errno.h>
1.4   martin #include <sys/device.h>
1.1   dyoung
1.1   dyoung #include <machine/bus.h>
1.1   dyoung
1.1   dyoung #include <sys/socket.h>
1.1   dyoung
1.1   dyoung #include <net/if.h>
1.1   dyoung #include <net/if_media.h>
1.1   dyoung #include <net/if_arp.h>
1.3   dyoung #include <net/if_ether.h>		/* XXX for ether_sprintf */
1.1   dyoung
1.1   dyoung #include <net80211/ieee80211_var.h>
1.1   dyoung
1.1   dyoung #include <net/bpf.h>
1.1   dyoung
1.1   dyoung #ifdef INET
1.1   dyoung #include <netinet/in.h>
1.1   dyoung #endif
1.1   dyoung
1.2   dyoung #include <dev/ic/athvar.h>
1.2   dyoung #include <dev/ic/athrate-sample.h>
1.9  gdamore #include <contrib/dev/ath/ah_desc.h>
1.1   dyoung
1.1   dyoung #define	SAMPLE_DEBUG
1.1   dyoung #ifdef SAMPLE_DEBUG
1.1   dyoung enum {
1.8   dyoung 	ATH_DEBUG_RATE		= 0x00000010	/* rate control */
1.1   dyoung };
1.1   dyoung #define	DPRINTF(sc, _fmt, ...) do {				\
1.1   dyoung 	if (sc->sc_debug & ATH_DEBUG_RATE)			\
1.1   dyoung 		printf(_fmt, __VA_ARGS__);			\
1.1   dyoung } while (0)
1.1   dyoung #else
1.1   dyoung #define	DPRINTF(sc, _fmt, ...)
1.1   dyoung #endif
1.1   dyoung
1.1   dyoung /*
1.1   dyoung  * This file is an implementation of the SampleRate algorithm
1.1   dyoung  * in "Bit-rate Selection in Wireless Networks"
1.1   dyoung  * (http://www.pdos.lcs.mit.edu/papers/jbicket-ms.ps)
1.1   dyoung  *
1.1   dyoung  * SampleRate chooses the bit-rate it predicts will provide the most
1.1   dyoung  * throughput based on estimates of the expected per-packet
1.1   dyoung  * transmission time for each bit-rate.  SampleRate periodically sends
1.1   dyoung  * packets at bit-rates other than the current one to estimate when
1.1   dyoung  * another bit-rate will provide better performance. SampleRate
1.1   dyoung  * switches to another bit-rate when its estimated per-packet
1.1   dyoung  * transmission time becomes smaller than the current bit-rate's.
1.1   dyoung  * SampleRate reduces the number of bit-rates it must sample by
1.1   dyoung  * eliminating those that could not perform better than the one
1.1   dyoung  * currently being used.  SampleRate also stops probing at a bit-rate
1.1   dyoung  * if it experiences several successive losses.
1.1   dyoung  *
1.1   dyoung  * The difference between the algorithm in the thesis and the one in this
1.1   dyoung  * file is that the one in this file uses a ewma instead of a window.
1.1   dyoung  *
1.8   dyoung  * Also, this implementation tracks the average transmission time for
1.8   dyoung  * a few different packet sizes independently for each link.
1.1   dyoung  */
1.1   dyoung
1.1   dyoung #define STALE_FAILURE_TIMEOUT_MS 10000
1.8   dyoung #define MIN_SWITCH_MS 1000
1.1   dyoung
1.1   dyoung static void	ath_rate_ctl_reset(struct ath_softc *, struct ieee80211_node *);
1.1   dyoung
1.8   dyoung static inline int
1.8   dyoung size_to_bin(int size)
1.1   dyoung {
1.1   dyoung 	int x = 0;
1.1   dyoung 	for (x = 0; x < NUM_PACKET_SIZE_BINS; x++) {
1.1   dyoung 		if (size <= packet_size_bins[x]) {
1.1   dyoung 			return x;
1.1   dyoung 		}
1.1   dyoung 	}
1.1   dyoung 	return NUM_PACKET_SIZE_BINS-1;
1.1   dyoung }
1.6    perry static inline int bin_to_size(int index) {
1.1   dyoung 	return packet_size_bins[index];
1.1   dyoung }
1.1   dyoung
1.8   dyoung static inline int
1.8   dyoung rate_to_ndx(struct sample_node *sn, int rate) {
1.1   dyoung 	int x = 0;
1.1   dyoung 	for (x = 0; x < sn->num_rates; x++) {
1.1   dyoung 		if (sn->rates[x].rate == rate) {
1.1   dyoung 			return x;
1.1   dyoung 		}
1.1   dyoung 	}
1.1   dyoung 	return -1;
1.1   dyoung }
1.1   dyoung
1.1   dyoung void
1.1   dyoung ath_rate_node_init(struct ath_softc *sc, struct ath_node *an)
1.1   dyoung {
1.1   dyoung 	DPRINTF(sc, "%s:\n", __func__);
1.1   dyoung 	/* NB: assumed to be zero'd by caller */
1.1   dyoung }
1.1   dyoung
1.1   dyoung void
1.1   dyoung ath_rate_node_cleanup(struct ath_softc *sc, struct ath_node *an)
1.1   dyoung {
1.1   dyoung 	DPRINTF(sc, "%s:\n", __func__);
1.1   dyoung }
1.1   dyoung
1.1   dyoung
1.1   dyoung /*
1.1   dyoung  * returns the ndx with the lowest average_tx_time,
1.1   dyoung  * or -1 if all the average_tx_times are 0.
1.1   dyoung  */
1.6    perry static inline int best_rate_ndx(struct sample_node *sn, int size_bin,
1.1   dyoung 				  int require_acked_before)
1.1   dyoung {
1.1   dyoung 	int x = 0;
1.3   dyoung         int best_ndx = 0;
1.1   dyoung         int best_rate_tt = 0;
1.1   dyoung         for (x = 0; x < sn->num_rates; x++) {
1.1   dyoung 		int tt = sn->stats[size_bin][x].average_tx_time;
1.1   dyoung 		if (tt <= 0 || (require_acked_before &&
1.1   dyoung 				!sn->stats[size_bin][x].packets_acked)) {
1.1   dyoung 			continue;
1.1   dyoung 		}
1.8   dyoung
1.8   dyoung 		/* 9 megabits never works better than 12 */
1.8   dyoung 		if (sn->rates[x].rate == 18)
1.8   dyoung 			continue;
1.8   dyoung
1.8   dyoung 		/* don't use a bit-rate that has been failing */
1.8   dyoung 		if (sn->stats[size_bin][x].successive_failures > 3)
1.8   dyoung 			continue;
1.8   dyoung
1.1   dyoung 		if (!best_rate_tt || best_rate_tt > tt) {
1.1   dyoung 			best_rate_tt = tt;
1.3   dyoung 			best_ndx = x;
1.1   dyoung 		}
1.1   dyoung         }
1.3   dyoung         return (best_rate_tt) ? best_ndx : -1;
1.1   dyoung }
1.1   dyoung
1.1   dyoung /*
1.8   dyoung  * pick a good "random" bit-rate to sample other than the current one
1.1   dyoung  */
1.8   dyoung static inline int
1.8   dyoung pick_sample_ndx(struct sample_node *sn, int size_bin)
1.1   dyoung {
1.1   dyoung 	int x = 0;
1.1   dyoung 	int current_ndx = 0;
1.1   dyoung 	unsigned current_tt = 0;
1.1   dyoung
1.1   dyoung 	current_ndx = sn->current_rate[size_bin];
1.1   dyoung 	if (current_ndx < 0) {
1.1   dyoung 		/* no successes yet, send at the lowest bit-rate */
1.1   dyoung 		return 0;
1.1   dyoung 	}
1.1   dyoung
1.1   dyoung 	current_tt = sn->stats[size_bin][current_ndx].average_tx_time;
1.1   dyoung
1.1   dyoung 	for (x = 0; x < sn->num_rates; x++) {
1.8   dyoung 		int ndx = (sn->last_sample_ndx[size_bin]+1+x) % sn->num_rates;
1.8   dyoung
1.8   dyoung 	        /* don't sample the current bit-rate */
1.8   dyoung 		if (ndx == current_ndx)
1.8   dyoung 			continue;
1.8   dyoung
1.8   dyoung 		/* this bit-rate is always worse than the current one */
1.8   dyoung 		if (sn->stats[size_bin][ndx].perfect_tx_time > current_tt)
1.8   dyoung 			continue;
1.8   dyoung
1.8   dyoung 		/* rarely sample bit-rates that fail a lot */
1.8   dyoung 		if (ticks - sn->stats[size_bin][ndx].last_tx < ((hz * STALE_FAILURE_TIMEOUT_MS)/1000) &&
1.8   dyoung 		    sn->stats[size_bin][ndx].successive_failures > 3)
1.8   dyoung 			continue;
1.8   dyoung
1.8   dyoung 		/* don't sample more than 2 indexes higher
1.8   dyoung 		 * for rates higher than 11 megabits
1.1   dyoung 		 */
1.8   dyoung 		if (sn->rates[ndx].rate > 22 && ndx > current_ndx + 2)
1.8   dyoung 			continue;
1.8   dyoung
1.8   dyoung 		/* 9 megabits never works better than 12 */
1.8   dyoung 		if (sn->rates[ndx].rate == 18)
1.8   dyoung 			continue;
1.8   dyoung
1.8   dyoung 		/* if we're using 11 megabits, only sample up to 12 megabits
1.8   dyoung 		 */
1.8   dyoung 		if (sn->rates[current_ndx].rate == 22 && ndx > current_ndx + 1)
1.8   dyoung 			continue;
1.1   dyoung
1.8   dyoung 		sn->last_sample_ndx[size_bin] = ndx;
1.8   dyoung 		return ndx;
1.1   dyoung 	}
1.1   dyoung 	return current_ndx;
1.1   dyoung }
1.1   dyoung
1.1   dyoung void
1.1   dyoung ath_rate_findrate(struct ath_softc *sc, struct ath_node *an,
1.1   dyoung 		  int shortPreamble, size_t frameLen,
1.1   dyoung 		  u_int8_t *rix, int *try0, u_int8_t *txrate)
1.1   dyoung {
1.1   dyoung 	struct sample_node *sn = ATH_NODE_SAMPLE(an);
1.1   dyoung 	struct sample_softc *ssc = ATH_SOFTC_SAMPLE(sc);
1.1   dyoung 	struct ieee80211com *ic = &sc->sc_ic;
1.8   dyoung 	int ndx, size_bin, mrr, best_ndx, change_rates;
1.1   dyoung 	unsigned average_tx_time;
1.1   dyoung
1.8   dyoung 	mrr = sc->sc_mrretry && !(ic->ic_flags & IEEE80211_F_USEPROT);
1.1   dyoung 	size_bin = size_to_bin(frameLen);
1.1   dyoung 	best_ndx = best_rate_ndx(sn, size_bin, !mrr);
1.1   dyoung
1.1   dyoung 	if (best_ndx >= 0) {
1.1   dyoung 		average_tx_time = sn->stats[size_bin][best_ndx].average_tx_time;
1.1   dyoung 	} else {
1.1   dyoung 		average_tx_time = 0;
1.1   dyoung 	}
1.8   dyoung
1.1   dyoung 	if (sn->static_rate_ndx != -1) {
1.1   dyoung 		ndx = sn->static_rate_ndx;
1.1   dyoung 		*try0 = ATH_TXMAXTRY;
1.1   dyoung 	} else {
1.1   dyoung 		*try0 = mrr ? 2 : ATH_TXMAXTRY;
1.8   dyoung
1.8   dyoung 		if (sn->sample_tt[size_bin] < average_tx_time * (sn->packets_since_sample[size_bin]*ssc->ath_sample_rate/100)) {
1.1   dyoung 			/*
1.1   dyoung 			 * we want to limit the time measuring the performance
1.1   dyoung 			 * of other bit-rates to ath_sample_rate% of the
1.1   dyoung 			 * total transmission time.
1.1   dyoung 			 */
1.1   dyoung 			ndx = pick_sample_ndx(sn, size_bin);
1.1   dyoung 			if (ndx != sn->current_rate[size_bin]) {
1.1   dyoung 				sn->current_sample_ndx[size_bin] = ndx;
1.1   dyoung 			} else {
1.1   dyoung 				sn->current_sample_ndx[size_bin] = -1;
1.1   dyoung 			}
1.1   dyoung 			sn->packets_since_sample[size_bin] = 0;
1.1   dyoung
1.1   dyoung 		} else {
1.8   dyoung 			change_rates = 0;
1.8   dyoung 			if (!sn->packets_sent[size_bin] || best_ndx == -1) {
1.8   dyoung 				/* no packet has been sent successfully yet */
1.8   dyoung 				for (ndx = sn->num_rates-1; ndx > 0; ndx--) {
1.8   dyoung 					/*
1.8   dyoung 					 * pick the highest rate <= 36 Mbps
1.8   dyoung 					 * that hasn't failed.
1.8   dyoung 					 */
1.8   dyoung 					if (sn->rates[ndx].rate <= 72 &&
1.8   dyoung 					    sn->stats[size_bin][ndx].successive_failures == 0) {
1.8   dyoung 						break;
1.8   dyoung 					}
1.8   dyoung 				}
1.8   dyoung 				change_rates = 1;
1.8   dyoung 				best_ndx = ndx;
1.8   dyoung 			} else if (sn->packets_sent[size_bin] < 20) {
1.8   dyoung 				/* let the bit-rate switch quickly during the first few packets */
1.8   dyoung 				change_rates = 1;
1.8   dyoung 			} else if (ticks - ((hz*MIN_SWITCH_MS)/1000) > sn->ticks_since_switch[size_bin]) {
1.8   dyoung 				/* 2 seconds have gone by */
1.8   dyoung 				change_rates = 1;
1.8   dyoung 			} else if (average_tx_time * 2 < sn->stats[size_bin][sn->current_rate[size_bin]].average_tx_time) {
1.8   dyoung 				/* the current bit-rate is twice as slow as the best one */
1.8   dyoung 				change_rates = 1;
1.8   dyoung 			}
1.8   dyoung
1.1   dyoung 			sn->packets_since_sample[size_bin]++;
1.8   dyoung
1.8   dyoung 			if (change_rates) {
1.8   dyoung 				if (best_ndx != sn->current_rate[size_bin]) {
1.8   dyoung 					DPRINTF(sc, "%s: %s size %d switch rate %d (%d/%d) -> %d (%d/%d) after %d packets mrr %d\n",
1.1   dyoung 						__func__,
1.1   dyoung 						ether_sprintf(an->an_node.ni_macaddr),
1.1   dyoung 						packet_size_bins[size_bin],
1.1   dyoung 						sn->rates[sn->current_rate[size_bin]].rate,
1.1   dyoung 						sn->stats[size_bin][sn->current_rate[size_bin]].average_tx_time,
1.1   dyoung 						sn->stats[size_bin][sn->current_rate[size_bin]].perfect_tx_time,
1.1   dyoung 						sn->rates[best_ndx].rate,
1.1   dyoung 						sn->stats[size_bin][best_ndx].average_tx_time,
1.1   dyoung 						sn->stats[size_bin][best_ndx].perfect_tx_time,
1.1   dyoung 						sn->packets_since_switch[size_bin],
1.1   dyoung 						mrr);
1.1   dyoung 				}
1.1   dyoung 				sn->packets_since_switch[size_bin] = 0;
1.1   dyoung 				sn->current_rate[size_bin] = best_ndx;
1.8   dyoung 				sn->ticks_since_switch[size_bin] = ticks;
1.1   dyoung 			}
1.1   dyoung 			ndx = sn->current_rate[size_bin];
1.1   dyoung 			sn->packets_since_switch[size_bin]++;
1.8   dyoung 			if (size_bin == 0) {
1.8   dyoung 	    			/*
1.8   dyoung 	    			 * set the visible txrate for this node
1.8   dyoung 			         * to the rate of small packets
1.8   dyoung 			         */
1.8   dyoung 				an->an_node.ni_txrate = ndx;
1.8   dyoung 			}
1.1   dyoung 		}
1.1   dyoung 	}
1.1   dyoung
1.8   dyoung 	KASSERT(ndx >= 0 && ndx < sn->num_rates, ("ndx is %d", ndx));
1.8   dyoung
1.1   dyoung 	*rix = sn->rates[ndx].rix;
1.1   dyoung 	if (shortPreamble) {
1.1   dyoung 		*txrate = sn->rates[ndx].shortPreambleRateCode;
1.1   dyoung 	} else {
1.1   dyoung 		*txrate = sn->rates[ndx].rateCode;
1.1   dyoung 	}
1.1   dyoung 	sn->packets_sent[size_bin]++;
1.1   dyoung }
1.1   dyoung
1.1   dyoung void
1.1   dyoung ath_rate_setupxtxdesc(struct ath_softc *sc, struct ath_node *an,
1.1   dyoung 		      struct ath_desc *ds, int shortPreamble, u_int8_t rix)
1.1   dyoung {
1.1   dyoung 	struct sample_node *sn = ATH_NODE_SAMPLE(an);
1.1   dyoung 	int rateCode = -1;
1.8   dyoung 	int frame_size = 0;
1.8   dyoung 	int size_bin = 0;
1.8   dyoung 	int ndx = 0;
1.1   dyoung
1.8   dyoung 	size_bin = size_to_bin(frame_size);	// TODO: it's correct that frame_size alway 0 ?
1.8   dyoung 	ndx = sn->current_rate[size_bin]; /* retry at the current bit-rate */
1.8   dyoung
1.8   dyoung 	if (!sn->stats[size_bin][ndx].packets_acked) {
1.8   dyoung 		ndx = 0;  /* use the lowest bit-rate */
1.8   dyoung 	}
1.1   dyoung
1.1   dyoung 	if (shortPreamble) {
1.1   dyoung 		rateCode = sn->rates[ndx].shortPreambleRateCode;
1.1   dyoung 	} else {
1.1   dyoung 		rateCode = sn->rates[ndx].rateCode;
1.1   dyoung 	}
1.1   dyoung 	ath_hal_setupxtxdesc(sc->sc_ah, ds
1.1   dyoung 			     , rateCode, 3	        /* series 1 */
1.1   dyoung 			     , sn->rates[0].rateCode, 3	/* series 2 */
1.1   dyoung 			     , 0, 0	                /* series 3 */
1.1   dyoung 			     );
1.1   dyoung }
1.1   dyoung
1.1   dyoung static void
1.1   dyoung update_stats(struct ath_softc *sc, struct ath_node *an,
1.1   dyoung 		  int frame_size,
1.1   dyoung 		  int ndx0, int tries0,
1.1   dyoung 		  int ndx1, int tries1,
1.1   dyoung 		  int ndx2, int tries2,
1.1   dyoung 		  int ndx3, int tries3,
1.1   dyoung 		  int short_tries, int tries, int status)
1.1   dyoung {
1.1   dyoung 	struct sample_node *sn = ATH_NODE_SAMPLE(an);
1.1   dyoung 	struct sample_softc *ssc = ATH_SOFTC_SAMPLE(sc);
1.1   dyoung 	int tt = 0;
1.1   dyoung 	int tries_so_far = 0;
1.1   dyoung 	int size_bin = 0;
1.1   dyoung 	int size = 0;
1.1   dyoung 	int rate = 0;
1.1   dyoung
1.1   dyoung 	size_bin = size_to_bin(frame_size);
1.1   dyoung 	size = bin_to_size(size_bin);
1.1   dyoung 	rate = sn->rates[ndx0].rate;
1.1   dyoung
1.1   dyoung 	tt += calc_usecs_unicast_packet(sc, size, sn->rates[ndx0].rix,
1.1   dyoung 					short_tries-1,
1.1   dyoung 					MIN(tries0, tries) - 1);
1.1   dyoung 	tries_so_far += tries0;
1.1   dyoung 	if (tries1 && tries0 < tries) {
1.1   dyoung 		tt += calc_usecs_unicast_packet(sc, size, sn->rates[ndx1].rix,
1.1   dyoung 						short_tries-1,
1.1   dyoung 						MIN(tries1 + tries_so_far, tries) - tries_so_far - 1);
1.1   dyoung 	}
1.1   dyoung 	tries_so_far += tries1;
1.1   dyoung
1.1   dyoung 	if (tries2 && tries0 + tries1 < tries) {
1.1   dyoung 		tt += calc_usecs_unicast_packet(sc, size, sn->rates[ndx2].rix,
1.1   dyoung 					       short_tries-1,
1.1   dyoung 						MIN(tries2 + tries_so_far, tries) - tries_so_far - 1);
1.1   dyoung 	}
1.1   dyoung
1.1   dyoung 	tries_so_far += tries2;
1.1   dyoung
1.1   dyoung 	if (tries3 && tries0 + tries1 + tries2 < tries) {
1.1   dyoung 		tt += calc_usecs_unicast_packet(sc, size, sn->rates[ndx3].rix,
1.1   dyoung 						short_tries-1,
1.1   dyoung 						MIN(tries3 + tries_so_far, tries) - tries_so_far - 1);
1.1   dyoung 	}
1.1   dyoung 	if (sn->stats[size_bin][ndx0].total_packets < (100 / (100 - ssc->ath_smoothing_rate))) {
1.1   dyoung 		/* just average the first few packets */
1.1   dyoung 		int avg_tx = sn->stats[size_bin][ndx0].average_tx_time;
1.1   dyoung 		int packets = sn->stats[size_bin][ndx0].total_packets;
1.1   dyoung 		sn->stats[size_bin][ndx0].average_tx_time = (tt+(avg_tx*packets))/(packets+1);
1.1   dyoung 	} else {
1.1   dyoung 		/* use a ewma */
1.1   dyoung 		sn->stats[size_bin][ndx0].average_tx_time =
1.1   dyoung 			((sn->stats[size_bin][ndx0].average_tx_time * ssc->ath_smoothing_rate) +
1.1   dyoung 			 (tt * (100 - ssc->ath_smoothing_rate))) / 100;
1.1   dyoung 	}
1.1   dyoung
1.1   dyoung 	if (status) {
1.1   dyoung 		int y;
1.8   dyoung 		sn->stats[size_bin][ndx0].successive_failures++;
1.8   dyoung 		for (y = size_bin+1; y < NUM_PACKET_SIZE_BINS; y++) {
1.8   dyoung 			/* also say larger packets failed since we
1.8   dyoung 			 * assume if a small packet fails at a lower
1.8   dyoung 			 * bit-rate then a larger one will also.
1.8   dyoung 			 */
1.1   dyoung 			sn->stats[y][ndx0].successive_failures++;
1.1   dyoung 			sn->stats[y][ndx0].last_tx = ticks;
1.8   dyoung 			sn->stats[y][ndx0].tries += tries;
1.8   dyoung 			sn->stats[y][ndx0].total_packets++;
1.1   dyoung 		}
1.1   dyoung 	} else {
1.1   dyoung 		sn->stats[size_bin][ndx0].packets_acked++;
1.1   dyoung 		sn->stats[size_bin][ndx0].successive_failures = 0;
1.1   dyoung 	}
1.1   dyoung 	sn->stats[size_bin][ndx0].tries += tries;
1.1   dyoung 	sn->stats[size_bin][ndx0].last_tx = ticks;
1.1   dyoung 	sn->stats[size_bin][ndx0].total_packets++;
1.1   dyoung
1.1   dyoung
1.1   dyoung 	if (ndx0 == sn->current_sample_ndx[size_bin]) {
1.1   dyoung 		DPRINTF(sc, "%s: %s size %d sample rate %d tries (%d/%d) tt %d avg_tt (%d/%d) status %d\n",
1.1   dyoung 			__func__, ether_sprintf(an->an_node.ni_macaddr),
1.1   dyoung 			size, rate, short_tries, tries, tt,
1.1   dyoung 			sn->stats[size_bin][ndx0].average_tx_time,
1.1   dyoung 			sn->stats[size_bin][ndx0].perfect_tx_time,
1.1   dyoung 			status);
1.1   dyoung 		sn->sample_tt[size_bin] = tt;
1.1   dyoung 		sn->current_sample_ndx[size_bin] = -1;
1.1   dyoung 	}
1.1   dyoung }
1.1   dyoung
1.1   dyoung void
1.1   dyoung ath_rate_tx_complete(struct ath_softc *sc, struct ath_node *an,
1.1   dyoung 	const struct ath_desc *ds, const struct ath_desc *ds0)
1.1   dyoung {
1.8   dyoung 	struct ieee80211com *ic = &sc->sc_ic;
1.1   dyoung 	struct sample_node *sn = ATH_NODE_SAMPLE(an);
1.1   dyoung 	const struct ar5212_desc *ads = (const struct ar5212_desc *)&ds->ds_ctl0;
1.1   dyoung 	int final_rate, short_tries, long_tries, frame_size;
1.1   dyoung 	int ndx = -1;
1.8   dyoung 	int mrr;
1.1   dyoung
1.1   dyoung 	final_rate = sc->sc_hwmap[ds->ds_txstat.ts_rate &~ HAL_TXSTAT_ALTRATE].ieeerate;
1.1   dyoung 	short_tries = ds->ds_txstat.ts_shortretry + 1;
1.1   dyoung 	long_tries = ds->ds_txstat.ts_longretry + 1;
1.1   dyoung 	frame_size = ds0->ds_ctl0 & 0x0fff; /* low-order 12 bits of ds_ctl0 */
1.1   dyoung 	if (frame_size == 0)		    /* NB: should not happen */
1.1   dyoung 		frame_size = 1500;
1.1   dyoung
1.1   dyoung 	if (sn->num_rates <= 0) {
1.1   dyoung 		DPRINTF(sc, "%s: %s size %d status %d rate/try %d/%d "
1.1   dyoung 			"no rates yet\n",
1.1   dyoung 			__func__, ether_sprintf(an->an_node.ni_macaddr),
1.1   dyoung 			bin_to_size(size_to_bin(frame_size)),
1.1   dyoung 			ds->ds_txstat.ts_status,
1.1   dyoung 			short_tries, long_tries);
1.1   dyoung 		return;
1.1   dyoung 	}
1.1   dyoung
1.8   dyoung 	mrr = sc->sc_mrretry && !(ic->ic_flags & IEEE80211_F_USEPROT);
1.8   dyoung
1.1   dyoung 	if (sc->sc_mrretry && ds->ds_txstat.ts_status) {
1.1   dyoung 		/* this packet failed */
1.1   dyoung 		DPRINTF(sc, "%s: %s size %d rate/try %d/%d %d/%d %d/%d %d/%d status %s retries (%d/%d)\n",
1.1   dyoung 			__func__,
1.1   dyoung 			ether_sprintf(an->an_node.ni_macaddr),
1.1   dyoung 			bin_to_size(size_to_bin(frame_size)),
1.1   dyoung 			sc->sc_hwmap[ads->xmit_rate0].ieeerate,
1.1   dyoung 				ads->xmit_tries0,
1.1   dyoung 			sc->sc_hwmap[ads->xmit_rate1].ieeerate,
1.1   dyoung 				ads->xmit_tries1,
1.1   dyoung 			sc->sc_hwmap[ads->xmit_rate2].ieeerate,
1.1   dyoung 				ads->xmit_tries2,
1.1   dyoung 			sc->sc_hwmap[ads->xmit_rate3].ieeerate,
1.1   dyoung 				ads->xmit_tries3,
1.1   dyoung 			ds->ds_txstat.ts_status ? "FAIL" : "OK",
1.1   dyoung 			short_tries,
1.1   dyoung 			long_tries);
1.1   dyoung 	}
1.1   dyoung
1.8   dyoung 	if (!mrr || !(ds->ds_txstat.ts_rate & HAL_TXSTAT_ALTRATE)) {
1.1   dyoung 		/* only one rate was used */
1.1   dyoung 		ndx = rate_to_ndx(sn, final_rate);
1.1   dyoung 		DPRINTF(sc, "%s: %s size %d status %d rate/try %d/%d/%d\n",
1.1   dyoung 			__func__, ether_sprintf(an->an_node.ni_macaddr),
1.1   dyoung 			bin_to_size(size_to_bin(frame_size)),
1.1   dyoung 			ds->ds_txstat.ts_status,
1.1   dyoung 			ndx, short_tries, long_tries);
1.1   dyoung 		if (ndx >= 0 && ndx < sn->num_rates) {
1.1   dyoung 			update_stats(sc, an, frame_size,
1.1   dyoung 				     ndx, long_tries,
1.1   dyoung 				     0, 0,
1.1   dyoung 				     0, 0,
1.1   dyoung 				     0, 0,
1.1   dyoung 				     short_tries, long_tries, ds->ds_txstat.ts_status);
1.1   dyoung 		}
1.1   dyoung 	} else {
1.1   dyoung 		int rate0, tries0, ndx0;
1.1   dyoung 		int rate1, tries1, ndx1;
1.1   dyoung 		int rate2, tries2, ndx2;
1.1   dyoung 		int rate3, tries3, ndx3;
1.1   dyoung 		int finalTSIdx = ads->final_ts_index;
1.1   dyoung
1.1   dyoung 		/*
1.1   dyoung 		 * Process intermediate rates that failed.
1.1   dyoung 		 */
1.1   dyoung
1.1   dyoung 		rate0 = sc->sc_hwmap[ads->xmit_rate0].ieeerate;
1.1   dyoung 		tries0 = ads->xmit_tries0;
1.1   dyoung 		ndx0 = rate_to_ndx(sn, rate0);
1.1   dyoung
1.1   dyoung 		rate1 = sc->sc_hwmap[ads->xmit_rate1].ieeerate;
1.1   dyoung 		tries1 = ads->xmit_tries1;
1.1   dyoung 		ndx1 = rate_to_ndx(sn, rate1);
1.1   dyoung
1.1   dyoung 		rate2 = sc->sc_hwmap[ads->xmit_rate2].ieeerate;
1.1   dyoung 		tries2 = ads->xmit_tries2;
1.1   dyoung 		ndx2 = rate_to_ndx(sn, rate2);
1.1   dyoung
1.1   dyoung 		rate3 = sc->sc_hwmap[ads->xmit_rate3].ieeerate;
1.1   dyoung 		tries3 = ads->xmit_tries3;
1.1   dyoung 		ndx3 = rate_to_ndx(sn, rate3);
1.1   dyoung
1.1   dyoung #if 1
1.1   dyoung 		DPRINTF(sc, "%s: %s size %d finaltsidx %d tries %d status %d rate/try %d/%d %d/%d %d/%d %d/%d\n",
1.1   dyoung 			__func__, ether_sprintf(an->an_node.ni_macaddr),
1.1   dyoung 			bin_to_size(size_to_bin(frame_size)),
1.1   dyoung 			finalTSIdx,
1.1   dyoung 			long_tries,
1.1   dyoung 			ds->ds_txstat.ts_status,
1.1   dyoung 			rate0, tries0,
1.1   dyoung 			rate1, tries1,
1.1   dyoung 			rate2, tries2,
1.1   dyoung 			rate3, tries3);
1.1   dyoung #endif
1.1   dyoung
1.1   dyoung 		if (tries0) {
1.1   dyoung 			update_stats(sc, an, frame_size,
1.1   dyoung 				     ndx0, tries0,
1.1   dyoung 				     ndx1, tries1,
1.1   dyoung 				     ndx2, tries2,
1.1   dyoung 				     ndx3, tries3,
1.1   dyoung 				     short_tries, ds->ds_txstat.ts_longretry + 1,
1.8   dyoung 				     long_tries > tries0);
1.1   dyoung 		}
1.1   dyoung
1.1   dyoung 		if (tries1 && finalTSIdx > 0) {
1.1   dyoung 			update_stats(sc, an, frame_size,
1.1   dyoung 				     ndx1, tries1,
1.1   dyoung 				     ndx2, tries2,
1.1   dyoung 				     ndx3, tries3,
1.1   dyoung 				     0, 0,
1.1   dyoung 				     short_tries, ds->ds_txstat.ts_longretry + 1 - tries0,
1.1   dyoung 				     ds->ds_txstat.ts_status);
1.1   dyoung 		}
1.1   dyoung
1.1   dyoung 		if (tries2 && finalTSIdx > 1) {
1.1   dyoung 			update_stats(sc, an, frame_size,
1.1   dyoung 				     ndx2, tries2,
1.1   dyoung 				     ndx3, tries3,
1.1   dyoung 				     0, 0,
1.1   dyoung 				     0, 0,
1.1   dyoung 				     short_tries, ds->ds_txstat.ts_longretry + 1 - tries0 - tries1,
1.1   dyoung 				     ds->ds_txstat.ts_status);
1.1   dyoung 		}
1.1   dyoung
1.1   dyoung 		if (tries3 && finalTSIdx > 2) {
1.1   dyoung 			update_stats(sc, an, frame_size,
1.1   dyoung 				     ndx3, tries3,
1.1   dyoung 				     0, 0,
1.1   dyoung 				     0, 0,
1.1   dyoung 				     0, 0,
1.1   dyoung 				     short_tries, ds->ds_txstat.ts_longretry + 1 - tries0 - tries1 - tries2,
1.1   dyoung 				     ds->ds_txstat.ts_status);
1.1   dyoung 		}
1.1   dyoung 	}
1.1   dyoung }
1.1   dyoung
1.1   dyoung void
1.1   dyoung ath_rate_newassoc(struct ath_softc *sc, struct ath_node *an, int isnew)
1.1   dyoung {
1.1   dyoung 	DPRINTF(sc, "%s: %s isnew %d\n", __func__,
1.1   dyoung 		ether_sprintf(an->an_node.ni_macaddr), isnew);
1.1   dyoung 	if (isnew)
1.1   dyoung 		ath_rate_ctl_reset(sc, &an->an_node);
1.1   dyoung }
1.1   dyoung
1.1   dyoung /*
1.1   dyoung  * Initialize the tables for a node.
1.1   dyoung  */
1.1   dyoung static void
1.1   dyoung ath_rate_ctl_reset(struct ath_softc *sc, struct ieee80211_node *ni)
1.1   dyoung {
1.1   dyoung #define	RATE(_ix)	(ni->ni_rates.rs_rates[(_ix)] & IEEE80211_RATE_VAL)
1.1   dyoung 	struct ieee80211com *ic = &sc->sc_ic;
1.1   dyoung 	struct ath_node *an = ATH_NODE(ni);
1.1   dyoung 	struct sample_node *sn = ATH_NODE_SAMPLE(an);
1.1   dyoung 	const HAL_RATE_TABLE *rt = sc->sc_currates;
1.1   dyoung 	int x, y, srate;
1.1   dyoung
1.1   dyoung 	KASSERT(rt != NULL, ("no rate table, mode %u", sc->sc_curmode));
1.1   dyoung         sn->static_rate_ndx = -1;
1.5    skrll 	if (ic->ic_fixed_rate != IEEE80211_FIXED_RATE_NONE) {
1.1   dyoung 		/*
1.1   dyoung 		 * A fixed rate is to be used; ic_fixed_rate is an
1.1   dyoung 		 * index into the supported rate set.  Convert this
1.1   dyoung 		 * to the index into the negotiated rate set for
1.1   dyoung 		 * the node.  We know the rate is there because the
1.1   dyoung 		 * rate set is checked when the station associates.
1.1   dyoung 		 */
1.1   dyoung 		const struct ieee80211_rateset *rs =
1.1   dyoung 			&ic->ic_sup_rates[ic->ic_curmode];
1.1   dyoung 		int r = rs->rs_rates[ic->ic_fixed_rate] & IEEE80211_RATE_VAL;
1.1   dyoung 		/* NB: the rate set is assumed sorted */
1.1   dyoung 		srate = ni->ni_rates.rs_nrates - 1;
1.1   dyoung 		for (; srate >= 0 && RATE(srate) != r; srate--)
1.1   dyoung 			;
1.1   dyoung 		KASSERT(srate >= 0,
1.1   dyoung 			("fixed rate %d not in rate set", ic->ic_fixed_rate));
1.1   dyoung                 sn->static_rate_ndx = srate;
1.1   dyoung 	}
1.1   dyoung
1.1   dyoung         DPRINTF(sc, "%s: %s size 1600 rate/tt", __func__, ether_sprintf(ni->ni_macaddr));
1.1   dyoung
1.1   dyoung 	sn->num_rates = ni->ni_rates.rs_nrates;
1.1   dyoung         for (x = 0; x < ni->ni_rates.rs_nrates; x++) {
1.1   dyoung 		sn->rates[x].rate = ni->ni_rates.rs_rates[x] & IEEE80211_RATE_VAL;
1.1   dyoung 		sn->rates[x].rix = sc->sc_rixmap[sn->rates[x].rate];
1.1   dyoung 		sn->rates[x].rateCode = rt->info[sn->rates[x].rix].rateCode;
1.1   dyoung 		sn->rates[x].shortPreambleRateCode =
1.1   dyoung 			rt->info[sn->rates[x].rix].rateCode |
1.1   dyoung 			rt->info[sn->rates[x].rix].shortPreamble;
1.1   dyoung
1.1   dyoung 		DPRINTF(sc, " %d/%d", sn->rates[x].rate,
1.1   dyoung 			calc_usecs_unicast_packet(sc, 1600, sn->rates[x].rix,
1.1   dyoung 						  0,0));
1.1   dyoung 	}
1.1   dyoung 	DPRINTF(sc, "%s\n", "");
1.1   dyoung
1.1   dyoung 	/* set the visible bit-rate to the lowest one available */
1.1   dyoung 	ni->ni_txrate = 0;
1.1   dyoung 	sn->num_rates = ni->ni_rates.rs_nrates;
1.1   dyoung
1.1   dyoung 	for (y = 0; y < NUM_PACKET_SIZE_BINS; y++) {
1.1   dyoung 		int size = bin_to_size(y);
1.8   dyoung 		int ndx = 0;
1.1   dyoung 		sn->packets_sent[y] = 0;
1.1   dyoung 		sn->current_sample_ndx[y] = -1;
1.1   dyoung 		sn->last_sample_ndx[y] = 0;
1.1   dyoung
1.1   dyoung 		for (x = 0; x < ni->ni_rates.rs_nrates; x++) {
1.1   dyoung 			sn->stats[y][x].successive_failures = 0;
1.1   dyoung 			sn->stats[y][x].tries = 0;
1.1   dyoung 			sn->stats[y][x].total_packets = 0;
1.1   dyoung 			sn->stats[y][x].packets_acked = 0;
1.1   dyoung 			sn->stats[y][x].last_tx = 0;
1.1   dyoung
1.1   dyoung 			sn->stats[y][x].perfect_tx_time =
1.1   dyoung 				calc_usecs_unicast_packet(sc, size,
1.1   dyoung 							  sn->rates[x].rix,
1.1   dyoung 							  0, 0);
1.1   dyoung 			sn->stats[y][x].average_tx_time = sn->stats[y][x].perfect_tx_time;
1.1   dyoung 		}
1.8   dyoung
1.8   dyoung 		/* set the initial rate */
1.8   dyoung 		for (ndx = sn->num_rates-1; ndx > 0; ndx--) {
1.8   dyoung 			if (sn->rates[ndx].rate <= 72) {
1.8   dyoung 				break;
1.8   dyoung 			}
1.8   dyoung 		}
1.8   dyoung 		sn->current_rate[y] = ndx;
1.1   dyoung 	}
1.8   dyoung
1.8   dyoung 	DPRINTF(sc, "%s: %s %d rates %d%sMbps (%dus)- %d%sMbps (%dus)\n",
1.8   dyoung 		__func__, ether_sprintf(ni->ni_macaddr),
1.8   dyoung 		sn->num_rates,
1.8   dyoung 		sn->rates[0].rate/2, sn->rates[0].rate % 0x1 ? ".5" : "",
1.8   dyoung 		sn->stats[1][0].perfect_tx_time,
1.8   dyoung 		sn->rates[sn->num_rates-1].rate/2,
1.8   dyoung 			sn->rates[sn->num_rates-1].rate % 0x1 ? ".5" : "",
1.8   dyoung 		sn->stats[1][sn->num_rates-1].perfect_tx_time
1.8   dyoung 	);
1.8   dyoung
1.8   dyoung 	ni->ni_txrate = sn->current_rate[0];
1.1   dyoung #undef RATE
1.1   dyoung }
1.1   dyoung
1.1   dyoung static void
1.1   dyoung rate_cb(void *arg, struct ieee80211_node *ni)
1.1   dyoung {
1.1   dyoung 	struct ath_softc *sc = arg;
1.1   dyoung
1.1   dyoung 	ath_rate_newassoc(sc, ATH_NODE(ni), 1);
1.1   dyoung }
1.1   dyoung
1.1   dyoung /*
1.1   dyoung  * Reset the rate control state for each 802.11 state transition.
1.1   dyoung  */
1.1   dyoung void
1.1   dyoung ath_rate_newstate(struct ath_softc *sc, enum ieee80211_state state)
1.1   dyoung {
1.1   dyoung 	struct ieee80211com *ic = &sc->sc_ic;
1.1   dyoung
1.1   dyoung 	if (state == IEEE80211_S_RUN) {
1.1   dyoung 		if (ic->ic_opmode != IEEE80211_M_STA) {
1.1   dyoung 			/*
1.1   dyoung 			 * Sync rates for associated stations and neighbors.
1.1   dyoung 			 */
1.1   dyoung 			ieee80211_iterate_nodes(&ic->ic_sta, rate_cb, sc);
1.1   dyoung 		}
1.1   dyoung 		ath_rate_newassoc(sc, ATH_NODE(ic->ic_bss), 1);
1.1   dyoung 	}
1.1   dyoung }
1.1   dyoung
1.1   dyoung static void
1.1   dyoung ath_rate_sysctlattach(struct ath_softc *sc, struct sample_softc *osc)
1.1   dyoung {
1.3   dyoung 	int rc;
1.3   dyoung 	struct sysctllog **log = &sc->sc_sysctllog;
1.3   dyoung 	const struct sysctlnode *cnode, *rnode;
1.3   dyoung
1.3   dyoung 	if ((rnode = ath_sysctl_instance(sc->sc_dev.dv_xname, log)) == NULL)
1.3   dyoung 		return;
1.1   dyoung
1.1   dyoung 	/* XXX bounds check [0..100] */
1.3   dyoung 	if ((rc = SYSCTL_PFX_INT(osc->ath_, CTLFLAG_READWRITE, smoothing_rate,
1.3   dyoung 	    "rate control: retry threshold to credit rate raise (%%)")) != 0)
1.3   dyoung 		goto err;
1.3   dyoung
1.1   dyoung 	/* XXX bounds check [2..100] */
1.3   dyoung 	if ((rc = SYSCTL_PFX_INT(osc->ath_, CTLFLAG_READWRITE, sample_rate,
1.3   dyoung 	    "rate control: # good periods before raising rate")) != 0)
1.3   dyoung 		goto err;
1.3   dyoung
1.3   dyoung 	return;
1.3   dyoung err:
1.3   dyoung 	printf("%s: sysctl_createv failed, rc = %d\n", __func__, rc);
1.1   dyoung }
1.1   dyoung
1.1   dyoung struct ath_ratectrl *
1.1   dyoung ath_rate_attach(struct ath_softc *sc)
1.1   dyoung {
1.1   dyoung 	struct sample_softc *osc;
1.1   dyoung
1.1   dyoung 	DPRINTF(sc, "%s:\n", __func__);
1.1   dyoung 	osc = malloc(sizeof(struct sample_softc), M_DEVBUF, M_NOWAIT|M_ZERO);
1.1   dyoung 	if (osc == NULL)
1.1   dyoung 		return NULL;
1.1   dyoung 	osc->arc.arc_space = sizeof(struct sample_node);
1.1   dyoung 	osc->ath_smoothing_rate = 95;	/* ewma percentage (out of 100) */
1.1   dyoung 	osc->ath_sample_rate = 10;	/* send a different bit-rate 1/X packets */
1.1   dyoung 	ath_rate_sysctlattach(sc, osc);
1.1   dyoung 	return &osc->arc;
1.1   dyoung }
1.1   dyoung
1.1   dyoung void
1.1   dyoung ath_rate_detach(struct ath_ratectrl *arc)
1.1   dyoung {
1.1   dyoung 	struct sample_softc *osc = (struct sample_softc *) arc;
1.1   dyoung
1.1   dyoung 	free(osc, M_DEVBUF);
1.1   dyoung }