/* * Codel - The Controlled-Delay Active Queue Management algorithm. * * $FreeBSD$ * * Copyright (C) 2016 Centre for Advanced Internet Architectures, * Swinburne University of Technology, Melbourne, Australia. * Portions of this code were made possible in part by a gift from * The Comcast Innovation Fund. * Implemented by Rasool Al-Saadi * * Copyright (C) 2011-2014 Kathleen Nichols . * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * o Redistributions of source code must retain the above copyright * notice, this list of conditions, and the following disclaimer, * without modification. * * o Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * o The names of the authors may not be used to endorse or promote * products derived from this software without specific prior written * permission. * * Alternatively, provided that this notice is retained in full, this * software may be distributed under the terms of the GNU General Public * License ("GPL") version 2, in which case the provisions of the GPL * apply INSTEAD OF those given above. * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #ifndef _IP_DN_AQM_CODEL_H #define _IP_DN_AQM_CODEL_H // XXX How to choose MTAG? #define FIX_POINT_BITS 16 enum { CODEL_ECN_ENABLED = 1 }; /* Codel parameters */ struct dn_aqm_codel_parms { aqm_time_t target; aqm_time_t interval; uint32_t flags; }; /* codel status variables */ struct codel_status { uint32_t count; /* number of dropped pkts since entering drop state */ uint16_t dropping; /* dropping state */ aqm_time_t drop_next_time; /* time for next drop */ aqm_time_t first_above_time; /* time for first ts over target we observed */ uint16_t isqrt; /* last isqrt for control low */ uint16_t maxpkt_size; /* max packet size seen so far */ }; struct mbuf *codel_extract_head(struct dn_queue *, aqm_time_t *); aqm_time_t control_law(struct codel_status *, struct dn_aqm_codel_parms *, aqm_time_t ); __inline static struct mbuf * codel_dodequeue(struct dn_queue *q, aqm_time_t now, uint16_t *ok_to_drop) { struct mbuf * m; struct dn_aqm_codel_parms *cprms; struct codel_status *cst; aqm_time_t pkt_ts, sojourn_time; *ok_to_drop = 0; m = codel_extract_head(q, &pkt_ts); cst = q->aqm_status; if (m == NULL) { /* queue is empty - we can't be above target */ cst->first_above_time= 0; return m; } cprms = q->fs->aqmcfg; /* To span a large range of bandwidths, CoDel runs two * different AQMs in parallel. One is sojourn-time-based * and takes effect when the time to send an MTU-sized * packet is less than target. The 1st term of the "if" * below does this. The other is backlog-based and takes * effect when the time to send an MTU-sized packet is >= * target. The goal here is to keep the output link * utilization high by never allowing the queue to get * smaller than the amount that arrives in a typical * interarrival time (MTU-sized packets arriving spaced * by the amount of time it takes to send such a packet on * the bottleneck). The 2nd term of the "if" does this. */ sojourn_time = now - pkt_ts; if (sojourn_time < cprms->target || q->ni.len_bytes <= cst->maxpkt_size) { /* went below - stay below for at least interval */ cst->first_above_time = 0; } else { if (cst->first_above_time == 0) { /* just went above from below. if still above at * first_above_time, will say it's ok to drop. */ cst->first_above_time = now + cprms->interval; } else if (now >= cst->first_above_time) { *ok_to_drop = 1; } } return m; } /* * Dequeue a packet from queue 'q' */ __inline static struct mbuf * codel_dequeue(struct dn_queue *q) { struct mbuf *m; struct dn_aqm_codel_parms *cprms; struct codel_status *cst; aqm_time_t now; uint16_t ok_to_drop; cst = q->aqm_status; cprms = q->fs->aqmcfg; now = AQM_UNOW; m = codel_dodequeue(q, now, &ok_to_drop); if (cst->dropping) { if (!ok_to_drop) { /* sojourn time below target - leave dropping state */ cst->dropping = false; } /* * Time for the next drop. Drop current packet and dequeue * next. If the dequeue doesn't take us out of dropping * state, schedule the next drop. A large backlog might * result in drop rates so high that the next drop should * happen now, hence the 'while' loop. */ while (now >= cst->drop_next_time && cst->dropping) { /* mark the packet */ if (cprms->flags & CODEL_ECN_ENABLED && ecn_mark(m)) { cst->count++; /* schedule the next mark. */ cst->drop_next_time = control_law(cst, cprms, cst->drop_next_time); return m; } /* drop the packet */ update_stats(q, 0, 1); FREE_PKT(m); m = codel_dodequeue(q, now, &ok_to_drop); if (!ok_to_drop) { /* leave dropping state */ cst->dropping = false; } else { cst->count++; /* schedule the next drop. */ cst->drop_next_time = control_law(cst, cprms, cst->drop_next_time); } } /* If we get here we're not in dropping state. The 'ok_to_drop' * return from dodequeue means that the sojourn time has been * above 'target' for 'interval' so enter dropping state. */ } else if (ok_to_drop) { /* if ECN option is disabled or the packet cannot be marked, * drop the packet and extract another. */ if (!(cprms->flags & CODEL_ECN_ENABLED) || !ecn_mark(m)) { update_stats(q, 0, 1); FREE_PKT(m); m = codel_dodequeue(q, now, &ok_to_drop); } cst->dropping = true; /* If min went above target close to when it last went * below, assume that the drop rate that controlled the * queue on the last cycle is a good starting point to * control it now. ('drop_next' will be at most 'interval' * later than the time of the last drop so 'now - drop_next' * is a good approximation of the time from the last drop * until now.) */ cst->count = (cst->count > 2 && ((aqm_stime_t)now - (aqm_stime_t)cst->drop_next_time) < 8* cprms->interval)? cst->count - 2 : 1; /* we don't have to set initial guess for Newton's method isqrt as * we initilaize isqrt in control_law function when count == 1 */ cst->drop_next_time = control_law(cst, cprms, now); } return m; } #endif