/* * PIE - Proportional Integral controller Enhanced AQM algorithm. * * 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 * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR 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 AUTHOR 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. */ #include #include "opt_inet6.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* IFNAMSIZ, struct ifaddr, ifq head, lock.h mutex.h */ #include #include #include #include /* ip_len, ip_off */ #include /* ip_output(), IP_FORWARDING */ #include #include #include /* various ether_* routines */ #include /* for ip6_input, ip6_output prototypes */ #include #include #ifdef NEW_AQM #include #include #include #include #include /* for debugging */ #include static struct dn_aqm pie_desc; /* PIE defaults * target=15ms, tupdate=15ms, max_burst=150ms, * max_ecnth=0.1, alpha=0.125, beta=1.25, */ struct dn_aqm_pie_parms pie_sysctl = { 15 * AQM_TIME_1MS, 15 * AQM_TIME_1MS, 150 * AQM_TIME_1MS, PIE_SCALE/10 , PIE_SCALE * 0.125, PIE_SCALE * 1.25 , PIE_CAPDROP_ENABLED | PIE_DEPRATEEST_ENABLED | PIE_DERAND_ENABLED }; static int pie_sysctl_alpha_beta_handler(SYSCTL_HANDLER_ARGS) { int error; long value; if (!strcmp(oidp->oid_name,"alpha")) value = pie_sysctl.alpha; else value = pie_sysctl.beta; value = value * 1000 / PIE_SCALE; error = sysctl_handle_long(oidp, &value, 0, req); if (error != 0 || req->newptr == NULL) return (error); if (value < 1 || value > 7 * PIE_SCALE) return (EINVAL); value = (value * PIE_SCALE) / 1000; if (!strcmp(oidp->oid_name,"alpha")) pie_sysctl.alpha = value; else pie_sysctl.beta = value; return (0); } static int pie_sysctl_target_tupdate_maxb_handler(SYSCTL_HANDLER_ARGS) { int error; long value; if (!strcmp(oidp->oid_name,"target")) value = pie_sysctl.qdelay_ref; else if (!strcmp(oidp->oid_name,"tupdate")) value = pie_sysctl.tupdate; else value = pie_sysctl.max_burst; value = value / AQM_TIME_1US; error = sysctl_handle_long(oidp, &value, 0, req); if (error != 0 || req->newptr == NULL) return (error); if (value < 1 || value > 10 * AQM_TIME_1S) return (EINVAL); value = value * AQM_TIME_1US; if (!strcmp(oidp->oid_name,"target")) pie_sysctl.qdelay_ref = value; else if (!strcmp(oidp->oid_name,"tupdate")) pie_sysctl.tupdate = value; else pie_sysctl.max_burst = value; return (0); } static int pie_sysctl_max_ecnth_handler(SYSCTL_HANDLER_ARGS) { int error; long value; value = pie_sysctl.max_ecnth; value = value * 1000 / PIE_SCALE; error = sysctl_handle_long(oidp, &value, 0, req); if (error != 0 || req->newptr == NULL) return (error); if (value < 1 || value > PIE_SCALE) return (EINVAL); value = (value * PIE_SCALE) / 1000; pie_sysctl.max_ecnth = value; return (0); } /* define PIE sysctl variables */ SYSBEGIN(f4) SYSCTL_DECL(_net_inet); SYSCTL_DECL(_net_inet_ip); SYSCTL_DECL(_net_inet_ip_dummynet); static SYSCTL_NODE(_net_inet_ip_dummynet, OID_AUTO, pie, CTLFLAG_RW | CTLFLAG_MPSAFE, 0, "PIE"); #ifdef SYSCTL_NODE SYSCTL_PROC(_net_inet_ip_dummynet_pie, OID_AUTO, target, CTLTYPE_LONG | CTLFLAG_RW | CTLFLAG_NEEDGIANT, NULL, 0, pie_sysctl_target_tupdate_maxb_handler, "L", "queue target in microsecond"); SYSCTL_PROC(_net_inet_ip_dummynet_pie, OID_AUTO, tupdate, CTLTYPE_LONG | CTLFLAG_RW | CTLFLAG_NEEDGIANT, NULL, 0, pie_sysctl_target_tupdate_maxb_handler, "L", "the frequency of drop probability calculation in microsecond"); SYSCTL_PROC(_net_inet_ip_dummynet_pie, OID_AUTO, max_burst, CTLTYPE_LONG | CTLFLAG_RW | CTLFLAG_NEEDGIANT, NULL, 0, pie_sysctl_target_tupdate_maxb_handler, "L", "Burst allowance interval in microsecond"); SYSCTL_PROC(_net_inet_ip_dummynet_pie, OID_AUTO, max_ecnth, CTLTYPE_LONG | CTLFLAG_RW | CTLFLAG_NEEDGIANT, NULL, 0, pie_sysctl_max_ecnth_handler, "L", "ECN safeguard threshold scaled by 1000"); SYSCTL_PROC(_net_inet_ip_dummynet_pie, OID_AUTO, alpha, CTLTYPE_LONG | CTLFLAG_RW | CTLFLAG_NEEDGIANT, NULL, 0, pie_sysctl_alpha_beta_handler, "L", "PIE alpha scaled by 1000"); SYSCTL_PROC(_net_inet_ip_dummynet_pie, OID_AUTO, beta, CTLTYPE_LONG | CTLFLAG_RW | CTLFLAG_NEEDGIANT, NULL, 0, pie_sysctl_alpha_beta_handler, "L", "beta scaled by 1000"); #endif /* * Callout function for drop probability calculation * This function is called over tupdate ms and takes pointer of PIE * status variables as an argument */ static void calculate_drop_prob(void *x) { int64_t p, prob, oldprob; struct dn_aqm_pie_parms *pprms; struct pie_status *pst = (struct pie_status *) x; int p_isneg; pprms = pst->parms; prob = pst->drop_prob; /* calculate current qdelay using DRE method. * If TS is used and no data in the queue, reset current_qdelay * as it stays at last value during dequeue process. */ if (pprms->flags & PIE_DEPRATEEST_ENABLED) pst->current_qdelay = ((uint64_t)pst->pq->ni.len_bytes * pst->avg_dq_time) >> PIE_DQ_THRESHOLD_BITS; else if (!pst->pq->ni.len_bytes) pst->current_qdelay = 0; /* calculate drop probability */ p = (int64_t)pprms->alpha * ((int64_t)pst->current_qdelay - (int64_t)pprms->qdelay_ref); p +=(int64_t) pprms->beta * ((int64_t)pst->current_qdelay - (int64_t)pst->qdelay_old); /* take absolute value so right shift result is well defined */ p_isneg = p < 0; if (p_isneg) { p = -p; } /* We PIE_MAX_PROB shift by 12-bits to increase the division precision */ p *= (PIE_MAX_PROB << 12) / AQM_TIME_1S; /* auto-tune drop probability */ if (prob < (PIE_MAX_PROB / 1000000)) /* 0.000001 */ p >>= 11 + PIE_FIX_POINT_BITS + 12; else if (prob < (PIE_MAX_PROB / 100000)) /* 0.00001 */ p >>= 9 + PIE_FIX_POINT_BITS + 12; else if (prob < (PIE_MAX_PROB / 10000)) /* 0.0001 */ p >>= 7 + PIE_FIX_POINT_BITS + 12; else if (prob < (PIE_MAX_PROB / 1000)) /* 0.001 */ p >>= 5 + PIE_FIX_POINT_BITS + 12; else if (prob < (PIE_MAX_PROB / 100)) /* 0.01 */ p >>= 3 + PIE_FIX_POINT_BITS + 12; else if (prob < (PIE_MAX_PROB / 10)) /* 0.1 */ p >>= 1 + PIE_FIX_POINT_BITS + 12; else p >>= PIE_FIX_POINT_BITS + 12; oldprob = prob; if (p_isneg) { prob = prob - p; /* check for multiplication underflow */ if (prob > oldprob) { prob= 0; D("underflow"); } } else { /* Cap Drop adjustment */ if ((pprms->flags & PIE_CAPDROP_ENABLED) && prob >= PIE_MAX_PROB / 10 && p > PIE_MAX_PROB / 50 ) { p = PIE_MAX_PROB / 50; } prob = prob + p; /* check for multiplication overflow */ if (probcurrent_qdelay == 0 && pst->qdelay_old == 0) { /* 0.98 ~= 1- 1/64 */ prob = prob - (prob >> 6); } if (prob > PIE_MAX_PROB) { prob = PIE_MAX_PROB; } } pst->drop_prob = prob; /* store current queue delay value in old queue delay*/ pst->qdelay_old = pst->current_qdelay; /* update burst allowance */ if ((pst->sflags & PIE_ACTIVE) && pst->burst_allowance>0) { if (pst->burst_allowance > pprms->tupdate ) pst->burst_allowance -= pprms->tupdate; else pst->burst_allowance = 0; } /* reschedule calculate_drop_prob function */ if (pst->sflags & PIE_ACTIVE) callout_reset_sbt(&pst->aqm_pie_callout, (uint64_t)pprms->tupdate * SBT_1US, 0, calculate_drop_prob, pst, 0); mtx_unlock(&pst->lock_mtx); } /* * Extract a packet from the head of queue 'q' * Return a packet or NULL if the queue is empty. * If getts is set, also extract packet's timestamp from mtag. */ static struct mbuf * pie_extract_head(struct dn_queue *q, aqm_time_t *pkt_ts, int getts) { struct m_tag *mtag; struct mbuf *m = q->mq.head; if (m == NULL) return m; q->mq.head = m->m_nextpkt; /* Update stats */ update_stats(q, -m->m_pkthdr.len, 0); if (q->ni.length == 0) /* queue is now idle */ q->q_time = V_dn_cfg.curr_time; if (getts) { /* extract packet TS*/ mtag = m_tag_locate(m, MTAG_ABI_COMPAT, DN_AQM_MTAG_TS, NULL); if (mtag == NULL) { D("PIE timestamp mtag not found!"); *pkt_ts = 0; } else { *pkt_ts = *(aqm_time_t *)(mtag + 1); m_tag_delete(m,mtag); } } return m; } /* * Initiate PIE variable and optionally activate it */ __inline static void init_activate_pie(struct pie_status *pst, int resettimer) { struct dn_aqm_pie_parms *pprms; mtx_lock(&pst->lock_mtx); pprms = pst->parms; pst->drop_prob = 0; pst->qdelay_old = 0; pst->burst_allowance = pprms->max_burst; pst->accu_prob = 0; pst->dq_count = 0; pst->avg_dq_time = 0; pst->sflags = PIE_INMEASUREMENT; pst->measurement_start = AQM_UNOW; if (resettimer) { pst->sflags |= PIE_ACTIVE; callout_reset_sbt(&pst->aqm_pie_callout, (uint64_t)pprms->tupdate * SBT_1US, 0, calculate_drop_prob, pst, 0); } //DX(2, "PIE Activated"); mtx_unlock(&pst->lock_mtx); } /* * Deactivate PIE and stop probe update callout */ __inline static void deactivate_pie(struct pie_status *pst) { mtx_lock(&pst->lock_mtx); pst->sflags &= ~(PIE_ACTIVE | PIE_INMEASUREMENT); callout_stop(&pst->aqm_pie_callout); //D("PIE Deactivated"); mtx_unlock(&pst->lock_mtx); } /* * Dequeue and return a pcaket from queue 'q' or NULL if 'q' is empty. * Also, caculate depature time or queue delay using timestamp */ static struct mbuf * aqm_pie_dequeue(struct dn_queue *q) { struct mbuf *m; struct dn_flow *ni; /* stats for scheduler instance */ struct dn_aqm_pie_parms *pprms; struct pie_status *pst; aqm_time_t now; aqm_time_t pkt_ts, dq_time; int32_t w; pst = q->aqm_status; pprms = pst->parms; ni = &q->_si->ni; /*we extarct packet ts only when Departure Rate Estimation dis not used*/ m = pie_extract_head(q, &pkt_ts, !(pprms->flags & PIE_DEPRATEEST_ENABLED)); if (!m || !(pst->sflags & PIE_ACTIVE)) return m; now = AQM_UNOW; if (pprms->flags & PIE_DEPRATEEST_ENABLED) { /* calculate average depature time */ if(pst->sflags & PIE_INMEASUREMENT) { pst->dq_count += m->m_pkthdr.len; if (pst->dq_count >= PIE_DQ_THRESHOLD) { dq_time = now - pst->measurement_start; /* * if we don't have old avg dq_time i.e PIE is (re)initialized, * don't use weight to calculate new avg_dq_time */ if(pst->avg_dq_time == 0) pst->avg_dq_time = dq_time; else { /* * weight = PIE_DQ_THRESHOLD/2^6, but we scaled * weight by 2^8. Thus, scaled * weight = PIE_DQ_THRESHOLD /2^8 * */ w = PIE_DQ_THRESHOLD >> 8; pst->avg_dq_time = (dq_time* w + (pst->avg_dq_time * ((1L << 8) - w))) >> 8; pst->sflags &= ~PIE_INMEASUREMENT; } } } /* * Start new measurement cycle when the queue has * PIE_DQ_THRESHOLD worth of bytes. */ if(!(pst->sflags & PIE_INMEASUREMENT) && q->ni.len_bytes >= PIE_DQ_THRESHOLD) { pst->sflags |= PIE_INMEASUREMENT; pst->measurement_start = now; pst->dq_count = 0; } } /* Optionally, use packet timestamp to estimate queue delay */ else pst->current_qdelay = now - pkt_ts; return m; } /* * Enqueue a packet in q, subject to space and PIE queue management policy * (whose parameters are in q->fs). * Update stats for the queue and the scheduler. * Return 0 on success, 1 on drop. The packet is consumed anyways. */ static int aqm_pie_enqueue(struct dn_queue *q, struct mbuf* m) { struct dn_fs *f; uint64_t len; uint32_t qlen; struct pie_status *pst; struct dn_aqm_pie_parms *pprms; int t; len = m->m_pkthdr.len; pst = q->aqm_status; if(!pst) { DX(2, "PIE queue is not initialized\n"); update_stats(q, 0, 1); FREE_PKT(m); return 1; } f = &(q->fs->fs); pprms = pst->parms; t = ENQUE; /* get current queue length in bytes or packets*/ qlen = (f->flags & DN_QSIZE_BYTES) ? q->ni.len_bytes : q->ni.length; /* check for queue size and drop the tail if exceed queue limit*/ if (qlen >= f->qsize) t = DROP; /* drop/mark the packet when PIE is active and burst time elapsed */ else if ((pst->sflags & PIE_ACTIVE) && pst->burst_allowance==0 && drop_early(pst, q->ni.len_bytes) == DROP) { /* * if drop_prob over ECN threshold, drop the packet * otherwise mark and enqueue it. */ if ((pprms->flags & PIE_ECN_ENABLED) && pst->drop_prob < (pprms->max_ecnth << (PIE_PROB_BITS - PIE_FIX_POINT_BITS)) && ecn_mark(m)) t = ENQUE; else t = DROP; } /* Turn PIE on when 1/3 of the queue is full */ if (!(pst->sflags & PIE_ACTIVE) && qlen >= pst->one_third_q_size) { init_activate_pie(pst, 1); } /* Reset burst tolerance and optinally turn PIE off*/ if ((pst->sflags & PIE_ACTIVE) && pst->drop_prob == 0 && pst->current_qdelay < (pprms->qdelay_ref >> 1) && pst->qdelay_old < (pprms->qdelay_ref >> 1)) { pst->burst_allowance = pprms->max_burst; if ((pprms->flags & PIE_ON_OFF_MODE_ENABLED) && qlen<=0) deactivate_pie(pst); } /* Timestamp the packet if Departure Rate Estimation is disabled */ if (t != DROP && !(pprms->flags & PIE_DEPRATEEST_ENABLED)) { /* Add TS to mbuf as a TAG */ struct m_tag *mtag; mtag = m_tag_locate(m, MTAG_ABI_COMPAT, DN_AQM_MTAG_TS, NULL); if (mtag == NULL) mtag = m_tag_alloc(MTAG_ABI_COMPAT, DN_AQM_MTAG_TS, sizeof(aqm_time_t), M_NOWAIT); if (mtag == NULL) { t = DROP; } else { *(aqm_time_t *)(mtag + 1) = AQM_UNOW; m_tag_prepend(m, mtag); } } if (t != DROP) { mq_append(&q->mq, m); update_stats(q, len, 0); return (0); } else { update_stats(q, 0, 1); /* reset accu_prob after packet drop */ pst->accu_prob = 0; FREE_PKT(m); return 1; } return 0; } /* * initialize PIE for queue 'q' * First allocate memory for PIE status. */ static int aqm_pie_init(struct dn_queue *q) { struct pie_status *pst; struct dn_aqm_pie_parms *pprms; int err = 0; pprms = q->fs->aqmcfg; do { /* exit with break when error occurs*/ if (!pprms){ DX(2, "AQM_PIE is not configured"); err = EINVAL; break; } q->aqm_status = malloc(sizeof(struct pie_status), M_DUMMYNET, M_NOWAIT | M_ZERO); if (q->aqm_status == NULL) { D("cannot allocate PIE private data"); err = ENOMEM ; break; } pst = q->aqm_status; /* increase reference count for PIE module */ pie_desc.ref_count++; pst->pq = q; pst->parms = pprms; /* For speed optimization, we caculate 1/3 queue size once here */ // we can use x/3 = (x >>2) + (x >>4) + (x >>7) pst->one_third_q_size = q->fs->fs.qsize/3; mtx_init(&pst->lock_mtx, "mtx_pie", NULL, MTX_DEF); callout_init_mtx(&pst->aqm_pie_callout, &pst->lock_mtx, CALLOUT_RETURNUNLOCKED); pst->current_qdelay = 0; init_activate_pie(pst, !(pprms->flags & PIE_ON_OFF_MODE_ENABLED)); //DX(2, "aqm_PIE_init"); } while(0); return err; } /* * Callout function to destroy pie mtx and free PIE status memory */ static void pie_callout_cleanup(void *x) { struct pie_status *pst = (struct pie_status *) x; mtx_unlock(&pst->lock_mtx); mtx_destroy(&pst->lock_mtx); free(x, M_DUMMYNET); DN_BH_WLOCK(); pie_desc.ref_count--; DN_BH_WUNLOCK(); } /* * Clean up PIE status for queue 'q' * Destroy memory allocated for PIE status. */ static int aqm_pie_cleanup(struct dn_queue *q) { if(!q) { D("q is null"); return 0; } struct pie_status *pst = q->aqm_status; if(!pst) { //D("queue is already cleaned up"); return 0; } if(!q->fs || !q->fs->aqmcfg) { D("fs is null or no cfg"); return 1; } if (q->fs->aqmfp && q->fs->aqmfp->type !=DN_AQM_PIE) { D("Not PIE fs (%d)", q->fs->fs.fs_nr); return 1; } /* * Free PIE status allocated memory using pie_callout_cleanup() callout * function to avoid any potential race. * We reset aqm_pie_callout to call pie_callout_cleanup() in next 1um. This * stops the scheduled calculate_drop_prob() callout and call pie_callout_cleanup() * which does memory freeing. */ mtx_lock(&pst->lock_mtx); callout_reset_sbt(&pst->aqm_pie_callout, SBT_1US, 0, pie_callout_cleanup, pst, 0); q->aqm_status = NULL; mtx_unlock(&pst->lock_mtx); return 0; } /* * Config PIE parameters * also allocate memory for PIE configurations */ static int aqm_pie_config(struct dn_fsk* fs, struct dn_extra_parms *ep, int len) { struct dn_aqm_pie_parms *pcfg; int l = sizeof(struct dn_extra_parms); if (len < l) { D("invalid sched parms length got %d need %d", len, l); return EINVAL; } /* we free the old cfg because maybe the orignal allocation * was used for diffirent AQM type. */ if (fs->aqmcfg) { free(fs->aqmcfg, M_DUMMYNET); fs->aqmcfg = NULL; } fs->aqmcfg = malloc(sizeof(struct dn_aqm_pie_parms), M_DUMMYNET, M_NOWAIT | M_ZERO); if (fs->aqmcfg== NULL) { D("cannot allocate PIE configuration parameters"); return ENOMEM; } /* par array contains pie configuration as follow * 0- qdelay_ref,1- tupdate, 2- max_burst * 3- max_ecnth, 4- alpha, 5- beta, 6- flags */ /* configure PIE parameters */ pcfg = fs->aqmcfg; if (ep->par[0] < 0) pcfg->qdelay_ref = pie_sysctl.qdelay_ref * AQM_TIME_1US; else pcfg->qdelay_ref = ep->par[0]; if (ep->par[1] < 0) pcfg->tupdate = pie_sysctl.tupdate * AQM_TIME_1US; else pcfg->tupdate = ep->par[1]; if (ep->par[2] < 0) pcfg->max_burst = pie_sysctl.max_burst * AQM_TIME_1US; else pcfg->max_burst = ep->par[2]; if (ep->par[3] < 0) pcfg->max_ecnth = pie_sysctl.max_ecnth; else pcfg->max_ecnth = ep->par[3]; if (ep->par[4] < 0) pcfg->alpha = pie_sysctl.alpha; else pcfg->alpha = ep->par[4]; if (ep->par[5] < 0) pcfg->beta = pie_sysctl.beta; else pcfg->beta = ep->par[5]; if (ep->par[6] < 0) pcfg->flags = pie_sysctl.flags; else pcfg->flags = ep->par[6]; /* bound PIE configurations */ pcfg->qdelay_ref = BOUND_VAR(pcfg->qdelay_ref, 1, 10 * AQM_TIME_1S); pcfg->tupdate = BOUND_VAR(pcfg->tupdate, 1, 10 * AQM_TIME_1S); pcfg->max_burst = BOUND_VAR(pcfg->max_burst, 0, 10 * AQM_TIME_1S); pcfg->max_ecnth = BOUND_VAR(pcfg->max_ecnth, 0, PIE_SCALE); pcfg->alpha = BOUND_VAR(pcfg->alpha, 0, 7 * PIE_SCALE); pcfg->beta = BOUND_VAR(pcfg->beta, 0 , 7 * PIE_SCALE); pie_desc.cfg_ref_count++; //D("pie cfg_ref_count=%d", pie_desc.cfg_ref_count); return 0; } /* * Deconfigure PIE and free memory allocation */ static int aqm_pie_deconfig(struct dn_fsk* fs) { if (fs && fs->aqmcfg) { free(fs->aqmcfg, M_DUMMYNET); fs->aqmcfg = NULL; pie_desc.cfg_ref_count--; } return 0; } /* * Retrieve PIE configuration parameters. */ static int aqm_pie_getconfig (struct dn_fsk *fs, struct dn_extra_parms * ep) { struct dn_aqm_pie_parms *pcfg; if (fs->aqmcfg) { strlcpy(ep->name, pie_desc.name, sizeof(ep->name)); pcfg = fs->aqmcfg; ep->par[0] = pcfg->qdelay_ref / AQM_TIME_1US; ep->par[1] = pcfg->tupdate / AQM_TIME_1US; ep->par[2] = pcfg->max_burst / AQM_TIME_1US; ep->par[3] = pcfg->max_ecnth; ep->par[4] = pcfg->alpha; ep->par[5] = pcfg->beta; ep->par[6] = pcfg->flags; return 0; } return 1; } static struct dn_aqm pie_desc = { _SI( .type = ) DN_AQM_PIE, _SI( .name = ) "PIE", _SI( .ref_count = ) 0, _SI( .cfg_ref_count = ) 0, _SI( .enqueue = ) aqm_pie_enqueue, _SI( .dequeue = ) aqm_pie_dequeue, _SI( .config = ) aqm_pie_config, _SI( .deconfig = ) aqm_pie_deconfig, _SI( .getconfig = ) aqm_pie_getconfig, _SI( .init = ) aqm_pie_init, _SI( .cleanup = ) aqm_pie_cleanup, }; DECLARE_DNAQM_MODULE(dn_aqm_pie, &pie_desc); #endif