/* * Copyright 2002-2005, Instant802 Networks, Inc. * Copyright 2005, Devicescape Software, Inc. * Copyright 2007, Mattias Nissler * Copyright 2007, Stefano Brivio * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. */ #include #include #include #include #include #include "ieee80211_rate.h" #include "rc80211_pid.h" /* This is an implementation of a TX rate control algorithm that uses a PID * controller. Given a target failed frames rate, the controller decides about * TX rate changes to meet the target failed frames rate. * * The controller basically computes the following: * * adj = CP * err + CI * err_avg + CD * (err - last_err) * (1 + sharpening) * * where * adj adjustment value that is used to switch TX rate (see below) * err current error: target vs. current failed frames percentage * last_err last error * err_avg average (i.e. poor man's integral) of recent errors * sharpening non-zero when fast response is needed (i.e. right after * association or no frames sent for a long time), heading * to zero over time * CP Proportional coefficient * CI Integral coefficient * CD Derivative coefficient * * CP, CI, CD are subject to careful tuning. * * The integral component uses a exponential moving average approach instead of * an actual sliding window. The advantage is that we don't need to keep an * array of the last N error values and computation is easier. * * Once we have the adj value, we map it to a rate by means of a learning * algorithm. This algorithm keeps the state of the percentual failed frames * difference between rates. The behaviour of the lowest available rate is kept * as a reference value, and every time we switch between two rates, we compute * the difference between the failed frames each rate exhibited. By doing so, * we compare behaviours which different rates exhibited in adjacent timeslices, * thus the comparison is minimally affected by external conditions. This * difference gets propagated to the whole set of measurements, so that the * reference is always the same. Periodically, we normalize this set so that * recent events weigh the most. By comparing the adj value with this set, we * avoid pejorative switches to lower rates and allow for switches to higher * rates if they behaved well. * * Note that for the computations we use a fixed-point representation to avoid * floating point arithmetic. Hence, all values are shifted left by * RC_PID_ARITH_SHIFT. */ /* Shift the adjustment so that we won't switch to a lower rate if it exhibited * a worse failed frames behaviour and we'll choose the highest rate whose * failed frames behaviour is not worse than the one of the original rate * target. While at it, check that the adjustment is within the ranges. Then, * provide the new rate index. */ static int rate_control_pid_shift_adjust(struct rc_pid_rateinfo *r, int adj, int cur, int l) { int i, j, k, tmp; j = r[cur].rev_index; i = j + adj; if (i < 0) return r[0].index; if (i >= l - 1) return r[l - 1].index; tmp = i; if (adj < 0) { for (k = j; k >= i; k--) if (r[k].diff <= r[j].diff) tmp = k; } else { for (k = i + 1; k + i < l; k++) if (r[k].diff <= r[i].diff) tmp = k; } return r[tmp].index; } static void rate_control_pid_adjust_rate(struct ieee80211_local *local, struct sta_info *sta, int adj, struct rc_pid_rateinfo *rinfo) { struct ieee80211_sub_if_data *sdata; struct ieee80211_hw_mode *mode; int newidx; int maxrate; int back = (adj > 0) ? 1 : -1; sdata = IEEE80211_DEV_TO_SUB_IF(sta->dev); mode = local->oper_hw_mode; maxrate = sdata->bss ? sdata->bss->max_ratectrl_rateidx : -1; newidx = rate_control_pid_shift_adjust(rinfo, adj, sta->txrate, mode->num_rates); while (newidx != sta->txrate) { if (rate_supported(sta, mode, newidx) && (maxrate < 0 || newidx <= maxrate)) { sta->txrate = newidx; break; } newidx += back; } #ifdef CONFIG_MAC80211_DEBUGFS rate_control_pid_event_rate_change( &((struct rc_pid_sta_info *)sta->rate_ctrl_priv)->events, newidx, mode->rates[newidx].rate); #endif } /* Normalize the failed frames per-rate differences. */ static void rate_control_pid_normalize(struct rc_pid_info *pinfo, int l) { int i, norm_offset = pinfo->norm_offset; struct rc_pid_rateinfo *r = pinfo->rinfo; if (r[0].diff > norm_offset) r[0].diff -= norm_offset; else if (r[0].diff < -norm_offset) r[0].diff += norm_offset; for (i = 0; i < l - 1; i++) if (r[i + 1].diff > r[i].diff + norm_offset) r[i + 1].diff -= norm_offset; else if (r[i + 1].diff <= r[i].diff) r[i + 1].diff += norm_offset; } static void rate_control_pid_sample(struct rc_pid_info *pinfo, struct ieee80211_local *local, struct sta_info *sta) { struct rc_pid_sta_info *spinfo = sta->rate_ctrl_priv; struct rc_pid_rateinfo *rinfo = pinfo->rinfo; struct ieee80211_hw_mode *mode; u32 pf; s32 err_avg; u32 err_prop; u32 err_int; u32 err_der; int adj, i, j, tmp; unsigned long period; mode = local->oper_hw_mode; spinfo = sta->rate_ctrl_priv; /* In case nothing happened during the previous control interval, turn * the sharpening factor on. */ period = (HZ * pinfo->sampling_period + 500) / 1000; if (!period) period = 1; if (jiffies - spinfo->last_sample > 2 * period) spinfo->sharp_cnt = pinfo->sharpen_duration; spinfo->last_sample = jiffies; /* This should never happen, but in case, we assume the old sample is * still a good measurement and copy it. */ if (unlikely(spinfo->tx_num_xmit == 0)) pf = spinfo->last_pf; else { pf = spinfo->tx_num_failed * 100 / spinfo->tx_num_xmit; pf <<= RC_PID_ARITH_SHIFT; } spinfo->tx_num_xmit = 0; spinfo->tx_num_failed = 0; /* If we just switched rate, update the rate behaviour info. */ if (pinfo->oldrate != sta->txrate) { i = rinfo[pinfo->oldrate].rev_index; j = rinfo[sta->txrate].rev_index; tmp = (pf - spinfo->last_pf); tmp = RC_PID_DO_ARITH_RIGHT_SHIFT(tmp, RC_PID_ARITH_SHIFT); rinfo[j].diff = rinfo[i].diff + tmp; pinfo->oldrate = sta->txrate; } rate_control_pid_normalize(pinfo, mode->num_rates); /* Compute the proportional, integral and derivative errors. */ err_prop = (pinfo->target << RC_PID_ARITH_SHIFT) - pf; err_avg = spinfo->err_avg_sc >> pinfo->smoothing_shift; spinfo->err_avg_sc = spinfo->err_avg_sc - err_avg + err_prop; err_int = spinfo->err_avg_sc >> pinfo->smoothing_shift; err_der = (pf - spinfo->last_pf) * (1 + pinfo->sharpen_factor * spinfo->sharp_cnt); spinfo->last_pf = pf; if (spinfo->sharp_cnt) spinfo->sharp_cnt--; #ifdef CONFIG_MAC80211_DEBUGFS rate_control_pid_event_pf_sample(&spinfo->events, pf, err_prop, err_int, err_der); #endif /* Compute the controller output. */ adj = (err_prop * pinfo->coeff_p + err_int * pinfo->coeff_i + err_der * pinfo->coeff_d); adj = RC_PID_DO_ARITH_RIGHT_SHIFT(adj, 2 * RC_PID_ARITH_SHIFT); /* Change rate. */ if (adj) rate_control_pid_adjust_rate(local, sta, adj, rinfo); } static void rate_control_pid_tx_status(void *priv, struct net_device *dev, struct sk_buff *skb, struct ieee80211_tx_status *status) { struct ieee80211_local *local = wdev_priv(dev->ieee80211_ptr); struct ieee80211_hdr *hdr = (struct ieee80211_hdr *) skb->data; struct ieee80211_sub_if_data *sdata; struct rc_pid_info *pinfo = priv; struct sta_info *sta; struct rc_pid_sta_info *spinfo; unsigned long period; sta = sta_info_get(local, hdr->addr1); if (!sta) return; /* Don't update the state if we're not controlling the rate. */ sdata = IEEE80211_DEV_TO_SUB_IF(sta->dev); if (sdata->bss && sdata->bss->force_unicast_rateidx > -1) { sta->txrate = sdata->bss->max_ratectrl_rateidx; return; } /* Ignore all frames that were sent with a different rate than the rate * we currently advise mac80211 to use. */ if (status->control.rate != &local->oper_hw_mode->rates[sta->txrate]) goto ignore; spinfo = sta->rate_ctrl_priv; spinfo->tx_num_xmit++; #ifdef CONFIG_MAC80211_DEBUGFS rate_control_pid_event_tx_status(&spinfo->events, status); #endif /* We count frames that totally failed to be transmitted as two bad * frames, those that made it out but had some retries as one good and * one bad frame. */ if (status->excessive_retries) { spinfo->tx_num_failed += 2; spinfo->tx_num_xmit++; } else if (status->retry_count) { spinfo->tx_num_failed++; spinfo->tx_num_xmit++; } if (status->excessive_retries) { sta->tx_retry_failed++; sta->tx_num_consecutive_failures++; sta->tx_num_mpdu_fail++; } else { sta->last_ack_rssi[0] = sta->last_ack_rssi[1]; sta->last_ack_rssi[1] = sta->last_ack_rssi[2]; sta->last_ack_rssi[2] = status->ack_signal; sta->tx_num_consecutive_failures = 0; sta->tx_num_mpdu_ok++; } sta->tx_retry_count += status->retry_count; sta->tx_num_mpdu_fail += status->retry_count; /* Update PID controller state. */ period = (HZ * pinfo->sampling_period + 500) / 1000; if (!period) period = 1; if (time_after(jiffies, spinfo->last_sample + period)) rate_control_pid_sample(pinfo, local, sta); ignore: sta_info_put(sta); } static void rate_control_pid_get_rate(void *priv, struct net_device *dev, struct ieee80211_hw_mode *mode, struct sk_buff *skb, struct rate_selection *sel) { struct ieee80211_local *local = wdev_priv(dev->ieee80211_ptr); struct ieee80211_hdr *hdr = (struct ieee80211_hdr *) skb->data; struct ieee80211_sub_if_data *sdata; struct sta_info *sta; int rateidx; u16 fc; sta = sta_info_get(local, hdr->addr1); /* Send management frames and broadcast/multicast data using lowest * rate. */ fc = le16_to_cpu(hdr->frame_control); if ((fc & IEEE80211_FCTL_FTYPE) != IEEE80211_FTYPE_DATA || is_multicast_ether_addr(hdr->addr1) || !sta) { sel->rate = rate_lowest(local, mode, sta); if (sta) sta_info_put(sta); return; } /* If a forced rate is in effect, select it. */ sdata = IEEE80211_DEV_TO_SUB_IF(dev); if (sdata->bss && sdata->bss->force_unicast_rateidx > -1) sta->txrate = sdata->bss->force_unicast_rateidx; rateidx = sta->txrate; if (rateidx >= mode->num_rates) rateidx = mode->num_rates - 1; sta->last_txrate = rateidx; sta_info_put(sta); sel->rate = &mode->rates[rateidx]; #ifdef CONFIG_MAC80211_DEBUGFS rate_control_pid_event_tx_rate( &((struct rc_pid_sta_info *) sta->rate_ctrl_priv)->events, rateidx, mode->rates[rateidx].rate); #endif } static void rate_control_pid_rate_init(void *priv, void *priv_sta, struct ieee80211_local *local, struct sta_info *sta) { /* TODO: This routine should consider using RSSI from previous packets * as we need to have IEEE 802.1X auth succeed immediately after assoc.. * Until that method is implemented, we will use the lowest supported * rate as a workaround. */ sta->txrate = rate_lowest_index(local, local->oper_hw_mode, sta); } static void *rate_control_pid_alloc(struct ieee80211_local *local) { struct rc_pid_info *pinfo; struct rc_pid_rateinfo *rinfo; struct ieee80211_hw_mode *mode; int i, j, tmp; bool s; #ifdef CONFIG_MAC80211_DEBUGFS struct rc_pid_debugfs_entries *de; #endif pinfo = kmalloc(sizeof(*pinfo), GFP_ATOMIC); if (!pinfo) return NULL; /* We can safely assume that oper_hw_mode won't change unless we get * reinitialized. */ mode = local->oper_hw_mode; rinfo = kmalloc(sizeof(*rinfo) * mode->num_rates, GFP_ATOMIC); if (!rinfo) { kfree(pinfo); return NULL; } /* Sort the rates. This is optimized for the most common case (i.e. * almost-sorted CCK+OFDM rates). Kind of bubble-sort with reversed * mapping too. */ for (i = 0; i < mode->num_rates; i++) { rinfo[i].index = i; rinfo[i].rev_index = i; if (pinfo->fast_start) rinfo[i].diff = 0; else rinfo[i].diff = i * pinfo->norm_offset; } for (i = 1; i < mode->num_rates; i++) { s = 0; for (j = 0; j < mode->num_rates - i; j++) if (unlikely(mode->rates[rinfo[j].index].rate > mode->rates[rinfo[j + 1].index].rate)) { tmp = rinfo[j].index; rinfo[j].index = rinfo[j + 1].index; rinfo[j + 1].index = tmp; rinfo[rinfo[j].index].rev_index = j; rinfo[rinfo[j + 1].index].rev_index = j + 1; s = 1; } if (!s) break; } pinfo->target = RC_PID_TARGET_PF; pinfo->sampling_period = RC_PID_INTERVAL; pinfo->coeff_p = RC_PID_COEFF_P; pinfo->coeff_i = RC_PID_COEFF_I; pinfo->coeff_d = RC_PID_COEFF_D; pinfo->smoothing_shift = RC_PID_SMOOTHING_SHIFT; pinfo->sharpen_factor = RC_PID_SHARPENING_FACTOR; pinfo->sharpen_duration = RC_PID_SHARPENING_DURATION; pinfo->norm_offset = RC_PID_NORM_OFFSET; pinfo->fast_start = RC_PID_FAST_START; pinfo->rinfo = rinfo; pinfo->oldrate = 0; #ifdef CONFIG_MAC80211_DEBUGFS de = &pinfo->dentries; de->dir = debugfs_create_dir("rc80211_pid", local->hw.wiphy->debugfsdir); de->target = debugfs_create_u32("target_pf", S_IRUSR | S_IWUSR, de->dir, &pinfo->target); de->sampling_period = debugfs_create_u32("sampling_period", S_IRUSR | S_IWUSR, de->dir, &pinfo->sampling_period); de->coeff_p = debugfs_create_u32("coeff_p", S_IRUSR | S_IWUSR, de->dir, &pinfo->coeff_p); de->coeff_i = debugfs_create_u32("coeff_i", S_IRUSR | S_IWUSR, de->dir, &pinfo->coeff_i); de->coeff_d = debugfs_create_u32("coeff_d", S_IRUSR | S_IWUSR, de->dir, &pinfo->coeff_d); de->smoothing_shift = debugfs_create_u32("smoothing_shift", S_IRUSR | S_IWUSR, de->dir, &pinfo->smoothing_shift); de->sharpen_factor = debugfs_create_u32("sharpen_factor", S_IRUSR | S_IWUSR, de->dir, &pinfo->sharpen_factor); de->sharpen_duration = debugfs_create_u32("sharpen_duration", S_IRUSR | S_IWUSR, de->dir, &pinfo->sharpen_duration); de->norm_offset = debugfs_create_u32("norm_offset", S_IRUSR | S_IWUSR, de->dir, &pinfo->norm_offset); de->fast_start = debugfs_create_bool("fast_start", S_IRUSR | S_IWUSR, de->dir, &pinfo->fast_start); #endif return pinfo; } static void rate_control_pid_free(void *priv) { struct rc_pid_info *pinfo = priv; #ifdef CONFIG_MAC80211_DEBUGFS struct rc_pid_debugfs_entries *de = &pinfo->dentries; debugfs_remove(de->fast_start); debugfs_remove(de->norm_offset); debugfs_remove(de->sharpen_duration); debugfs_remove(de->sharpen_factor); debugfs_remove(de->smoothing_shift); debugfs_remove(de->coeff_d); debugfs_remove(de->coeff_i); debugfs_remove(de->coeff_p); debugfs_remove(de->sampling_period); debugfs_remove(de->target); debugfs_remove(de->dir); #endif kfree(pinfo->rinfo); kfree(pinfo); } static void rate_control_pid_clear(void *priv) { } static void *rate_control_pid_alloc_sta(void *priv, gfp_t gfp) { struct rc_pid_sta_info *spinfo; spinfo = kzalloc(sizeof(*spinfo), gfp); if (spinfo == NULL) return NULL; spinfo->last_sample = jiffies; #ifdef CONFIG_MAC80211_DEBUGFS spin_lock_init(&spinfo->events.lock); init_waitqueue_head(&spinfo->events.waitqueue); #endif return spinfo; } static void rate_control_pid_free_sta(void *priv, void *priv_sta) { struct rc_pid_sta_info *spinfo = priv_sta; kfree(spinfo); } static struct rate_control_ops mac80211_rcpid = { .name = "pid", .tx_status = rate_control_pid_tx_status, .get_rate = rate_control_pid_get_rate, .rate_init = rate_control_pid_rate_init, .clear = rate_control_pid_clear, .alloc = rate_control_pid_alloc, .free = rate_control_pid_free, .alloc_sta = rate_control_pid_alloc_sta, .free_sta = rate_control_pid_free_sta, #ifdef CONFIG_MAC80211_DEBUGFS .add_sta_debugfs = rate_control_pid_add_sta_debugfs, .remove_sta_debugfs = rate_control_pid_remove_sta_debugfs, #endif }; MODULE_DESCRIPTION("PID controller based rate control algorithm"); MODULE_AUTHOR("Stefano Brivio"); MODULE_AUTHOR("Mattias Nissler"); MODULE_LICENSE("GPL"); int __init rc80211_pid_init(void) { return ieee80211_rate_control_register(&mac80211_rcpid); } void __exit rc80211_pid_exit(void) { ieee80211_rate_control_unregister(&mac80211_rcpid); } #ifdef CONFIG_MAC80211_RC_PID_MODULE module_init(rc80211_pid_init); module_exit(rc80211_pid_exit); #endif