/*- * SPDX-License-Identifier: BSD-2-Clause * * Copyright (c) 2010 Luigi Rizzo, Riccardo Panicucci, Universita` di Pisa * All rights reserved * * 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. */ /* * internal dummynet APIs. */ #ifndef _IP_DN_PRIVATE_H #define _IP_DN_PRIVATE_H /* debugging support * use ND() to remove debugging, D() to print a line, * DX(level, ...) to print above a certain level * If you redefine D() you are expected to redefine all. */ #ifndef D #define ND(fmt, ...) do {} while (0) #define D1(fmt, ...) do {} while (0) #define D(fmt, ...) printf("%-10s " fmt "\n", \ __FUNCTION__, ## __VA_ARGS__) #define DX(lev, fmt, ...) do { \ if (V_dn_cfg.debug > lev) D(fmt, ## __VA_ARGS__); } while (0) #endif MALLOC_DECLARE(M_DUMMYNET); #ifndef __linux__ #define div64(a, b) ((int64_t)(a) / (int64_t)(b)) #endif #define DN_LOCK_INIT() do { \ mtx_init(&V_dn_cfg.uh_mtx, "dn_uh", NULL, MTX_DEF); \ mtx_init(&V_dn_cfg.bh_mtx, "dn_bh", NULL, MTX_DEF); \ } while (0) #define DN_LOCK_DESTROY() do { \ mtx_destroy(&V_dn_cfg.uh_mtx); \ mtx_destroy(&V_dn_cfg.bh_mtx); \ } while (0) #if 0 /* not used yet */ #define DN_UH_RLOCK() mtx_lock(&V_dn_cfg.uh_mtx) #define DN_UH_RUNLOCK() mtx_unlock(&V_dn_cfg.uh_mtx) #define DN_UH_WLOCK() mtx_lock(&V_dn_cfg.uh_mtx) #define DN_UH_WUNLOCK() mtx_unlock(&V_dn_cfg.uh_mtx) #define DN_UH_LOCK_ASSERT() mtx_assert(&V_dn_cfg.uh_mtx, MA_OWNED) #endif #define DN_BH_RLOCK() mtx_lock(&V_dn_cfg.uh_mtx) #define DN_BH_RUNLOCK() mtx_unlock(&V_dn_cfg.uh_mtx) #define DN_BH_WLOCK() mtx_lock(&V_dn_cfg.uh_mtx) #define DN_BH_WUNLOCK() mtx_unlock(&V_dn_cfg.uh_mtx) #define DN_BH_LOCK_ASSERT() mtx_assert(&V_dn_cfg.uh_mtx, MA_OWNED) SLIST_HEAD(dn_fsk_head, dn_fsk); struct mq { /* a basic queue of packets*/ struct mbuf *head, *tail; int count; }; static inline void set_oid(struct dn_id *o, int type, int len) { o->type = type; o->len = len; o->subtype = 0; } /* * configuration and data for a dummynet instance * * When a configuration is modified from userland, 'id' is incremented * so we can use the value to check for stale pointers. */ struct dn_parms { uint32_t id; /* configuration version */ /* defaults (sysctl-accessible) */ int red_lookup_depth; int red_avg_pkt_size; int red_max_pkt_size; int hash_size; int max_hash_size; long byte_limit; /* max queue sizes */ long slot_limit; int io_fast; int debug; /* timekeeping */ struct timeval prev_t; /* last time dummynet_tick ran */ struct dn_heap evheap; /* scheduled events */ long tick_last; /* Last tick duration (usec). */ long tick_delta; /* Last vs standard tick diff (usec). */ long tick_delta_sum; /* Accumulated tick difference (usec).*/ long tick_adjustment; /* Tick adjustments done. */ long tick_lost; /* Lost(coalesced) ticks number. */ /* Adjusted vs non-adjusted curr_time difference (ticks). */ long tick_diff; /* counters of objects -- used for reporting space */ int schk_count; int si_count; int fsk_count; int queue_count; /* packet counters */ unsigned long io_pkt; unsigned long io_pkt_fast; unsigned long io_pkt_drop; /* ticks and other stuff */ uint64_t curr_time; /* flowsets and schedulers are in hash tables, with 'hash_size' * buckets. fshash is looked up at every packet arrival * so better be generous if we expect many entries. */ struct dn_ht *fshash; struct dn_ht *schedhash; /* list of flowsets without a scheduler -- use sch_chain */ struct dn_fsk_head fsu; /* list of unlinked flowsets */ /* Store the fs/sch to scan when draining. The value is the * bucket number of the hash table. Expire can be disabled * with net.inet.ip.dummynet.expire=0, or it happens every * expire ticks. **/ int drain_fs; int drain_sch; uint32_t expire; uint32_t expire_cycle; /* tick count */ int init_done; #ifdef _KERNEL /* * This file is normally used in the kernel, unless we do * some userland tests, in which case we do not need a mtx. * uh_mtx arbitrates between system calls and also * protects fshash, schedhash and fsunlinked. * These structures are readonly for the lower half. * bh_mtx protects all other structures which may be * modified upon packet arrivals */ #if defined( __linux__ ) || defined( _WIN32 ) spinlock_t uh_mtx; spinlock_t bh_mtx; #else struct mtx uh_mtx; struct mtx bh_mtx; #endif #endif /* _KERNEL */ }; /* * Delay line, contains all packets on output from a link. * Every scheduler instance has one. */ struct delay_line { struct dn_id oid; struct dn_sch_inst *si; struct mq mq; }; /* * The kernel side of a flowset. It is linked in a hash table * of flowsets, and in a list of children of their parent scheduler. * qht is either the queue or (if HAVE_MASK) a hash table queues. * Note that the mask to use is the (flow_mask|sched_mask), which * changes as we attach/detach schedulers. So we store it here. * * XXX If we want to add scheduler-specific parameters, we need to * put them in external storage because the scheduler may not be * available when the fsk is created. */ struct dn_fsk { /* kernel side of a flowset */ struct dn_fs fs; SLIST_ENTRY(dn_fsk) fsk_next; /* hash chain for fshash */ struct ipfw_flow_id fsk_mask; /* qht is a hash table of queues, or just a single queue * a bit in fs.flags tells us which one */ struct dn_ht *qht; struct dn_schk *sched; /* Sched we are linked to */ SLIST_ENTRY(dn_fsk) sch_chain; /* list of fsk attached to sched */ /* bucket index used by drain routine to drain queues for this * flowset */ int drain_bucket; /* Parameter realted to RED / GRED */ /* original values are in dn_fs*/ int w_q ; /* queue weight (scaled) */ int max_th ; /* maximum threshold for queue (scaled) */ int min_th ; /* minimum threshold for queue (scaled) */ int max_p ; /* maximum value for p_b (scaled) */ u_int c_1 ; /* max_p/(max_th-min_th) (scaled) */ u_int c_2 ; /* max_p*min_th/(max_th-min_th) (scaled) */ u_int c_3 ; /* for GRED, (1-max_p)/max_th (scaled) */ u_int c_4 ; /* for GRED, 1 - 2*max_p (scaled) */ u_int * w_q_lookup ; /* lookup table for computing (1-w_q)^t */ u_int lookup_depth ; /* depth of lookup table */ int lookup_step ; /* granularity inside the lookup table */ int lookup_weight ; /* equal to (1-w_q)^t / (1-w_q)^(t+1) */ int avg_pkt_size ; /* medium packet size */ int max_pkt_size ; /* max packet size */ #ifdef NEW_AQM struct dn_aqm *aqmfp; /* Pointer to AQM functions */ void *aqmcfg; /* configuration parameters for AQM */ #endif }; /* * A queue is created as a child of a flowset unless it belongs to * a !MULTIQUEUE scheduler. It is normally in a hash table in the * flowset. fs always points to the parent flowset. * si normally points to the sch_inst, unless the flowset has been * detached from the scheduler -- in this case si == NULL and we * should not enqueue. */ struct dn_queue { struct dn_flow ni; /* oid, flow_id, stats */ struct mq mq; /* packets queue */ struct dn_sch_inst *_si; /* owner scheduler instance */ SLIST_ENTRY(dn_queue) q_next; /* hash chain list for qht */ struct dn_fsk *fs; /* parent flowset. */ /* RED parameters */ int avg; /* average queue length est. (scaled) */ int count; /* arrivals since last RED drop */ int random; /* random value (scaled) */ uint64_t q_time; /* start of queue idle time */ #ifdef NEW_AQM void *aqm_status; /* per-queue status variables*/ #endif }; /* * The kernel side of a scheduler. Contains the userland config, * a link, pointer to extra config arguments from command line, * kernel flags, and a pointer to the scheduler methods. * It is stored in a hash table, and holds a list of all * flowsets and scheduler instances. * XXX sch must be at the beginning, see schk_hash(). */ struct dn_schk { struct dn_sch sch; struct dn_alg *fp; /* Pointer to scheduler functions */ struct dn_link link; /* The link, embedded */ struct dn_profile *profile; /* delay profile, if any */ struct dn_id *cfg; /* extra config arguments */ SLIST_ENTRY(dn_schk) schk_next; /* hash chain for schedhash */ struct dn_fsk_head fsk_list; /* all fsk linked to me */ struct dn_fsk *fs; /* Flowset for !MULTIQUEUE */ /* bucket index used by the drain routine to drain the scheduler * instance for this flowset. */ int drain_bucket; /* Hash table of all instances (through sch.sched_mask) * or single instance if no mask. Always valid. */ struct dn_ht *siht; }; /* * Scheduler instance. * Contains variables and all queues relative to a this instance. * This struct is created a runtime. */ struct dn_sch_inst { struct dn_flow ni; /* oid, flowid and stats */ SLIST_ENTRY(dn_sch_inst) si_next; /* hash chain for siht */ struct delay_line dline; struct dn_schk *sched; /* the template */ int kflags; /* DN_ACTIVE */ int64_t credit; /* bits I can transmit (more or less). */ uint64_t sched_time; /* time link was scheduled in ready_heap */ uint64_t idle_time; /* start of scheduler instance idle time */ /* q_count is the number of queues that this instance is using. * The counter is incremented or decremented when * a reference from the queue is created or deleted. * It is used to make sure that a scheduler instance can be safely * deleted by the drain routine. See notes below. */ int q_count; }; /* * NOTE about object drain. * The system will automatically (XXX check when) drain queues and * scheduler instances when they are idle. * A queue is idle when it has no packets; an instance is idle when * it is not in the evheap heap, and the corresponding delay line is empty. * A queue can be safely deleted when it is idle because of the scheduler * function xxx_free_queue() will remove any references to it. * An instance can be only deleted when no queues reference it. To be sure * of that, a counter (q_count) stores the number of queues that are pointing * to the instance. * * XXX * Order of scan: * - take all flowset in a bucket for the flowset hash table * - take all queues in a bucket for the flowset * - increment the queue bucket * - scan next flowset bucket * Nothing is done if a bucket contains no entries. * * The same schema is used for sceduler instances */ /* kernel-side flags. Linux has DN_DELETE in fcntl.h */ enum { /* 1 and 2 are reserved for the SCAN flags */ DN_DESTROY = 0x0004, /* destroy */ DN_DELETE_FS = 0x0008, /* destroy flowset */ DN_DETACH = 0x0010, DN_ACTIVE = 0x0020, /* object is in evheap */ DN_F_DLINE = 0x0040, /* object is a delay line */ DN_DEL_SAFE = 0x0080, /* delete a queue only if no longer needed * by scheduler */ DN_QHT_IS_Q = 0x0100, /* in flowset, qht is a single queue */ }; /* * Packets processed by dummynet have an mbuf tag associated with * them that carries their dummynet state. * Outside dummynet, only the 'rule' field is relevant, and it must * be at the beginning of the structure. */ struct dn_pkt_tag { struct ipfw_rule_ref rule; /* matching rule */ /* second part, dummynet specific */ int dn_dir; /* action when packet comes out.*/ /* see ip_fw_private.h */ uint64_t output_time; /* when the pkt is due for delivery*/ struct ifnet *ifp; /* interface, for ip_output */ struct _ip6dn_args ip6opt; /* XXX ipv6 options */ uint16_t iphdr_off; /* IP header offset for mtodo() */ }; /* * Possible values for dn_dir. XXXGL: this needs to be reviewed * and converted to same values ip_fw_args.flags use. */ enum { DIR_OUT = 0, DIR_IN = 1, DIR_FWD = 2, DIR_DROP = 3, PROTO_LAYER2 = 0x4, /* set for layer 2 */ PROTO_IPV4 = 0x08, PROTO_IPV6 = 0x10, PROTO_IFB = 0x0c, /* layer2 + ifbridge */ }; //extern struct dn_parms V_dn_cfg; VNET_DECLARE(struct dn_parms, dn_cfg); #define V_dn_cfg VNET(dn_cfg) int dummynet_io(struct mbuf **, struct ip_fw_args *); void dummynet_task(void *context, int pending); void dn_reschedule(void); struct dn_pkt_tag * dn_tag_get(struct mbuf *m); struct dn_queue *ipdn_q_find(struct dn_fsk *, struct dn_sch_inst *, struct ipfw_flow_id *); struct dn_sch_inst *ipdn_si_find(struct dn_schk *, struct ipfw_flow_id *); /* * copy_range is a template for requests for ranges of pipes/queues/scheds. * The number of ranges is variable and can be derived by o.len. * As a default, we use a small number of entries so that the struct * fits easily on the stack and is sufficient for most common requests. */ #define DEFAULT_RANGES 5 struct copy_range { struct dn_id o; uint32_t r[ 2 * DEFAULT_RANGES ]; }; struct copy_args { char **start; char *end; int flags; int type; struct copy_range *extra; /* extra filtering */ }; struct sockopt; int ip_dummynet_compat(struct sockopt *sopt); int dummynet_get(struct sockopt *sopt, void **compat); int dn_c_copy_q (void *_ni, void *arg); int dn_c_copy_pipe(struct dn_schk *s, struct copy_args *a, int nq); int dn_c_copy_fs(struct dn_fsk *f, struct copy_args *a, int nq); int dn_compat_copy_queue(struct copy_args *a, void *_o); int dn_compat_copy_pipe(struct copy_args *a, void *_o); int copy_data_helper_compat(void *_o, void *_arg); int dn_compat_calc_size(void); int do_config(void *p, size_t l); /* function to drain idle object */ void dn_drain_scheduler(void); void dn_drain_queue(void); #ifdef NEW_AQM int ecn_mark(struct mbuf* m); /* moved from ip_dn_io.c to here to be available for AQMs modules*/ static inline void mq_append(struct mq *q, struct mbuf *m) { #ifdef USERSPACE // buffers from netmap need to be copied // XXX note that the routine is not expected to fail ND("append %p to %p", m, q); if (m->m_flags & M_STACK) { struct mbuf *m_new; void *p; int l, ofs; ofs = m->m_data - m->__m_extbuf; // XXX allocate MGETHDR(m_new, M_NOWAIT, MT_DATA); ND("*** WARNING, volatile buf %p ext %p %d dofs %d m_new %p", m, m->__m_extbuf, m->__m_extlen, ofs, m_new); p = m_new->__m_extbuf; /* new pointer */ l = m_new->__m_extlen; /* new len */ if (l <= m->__m_extlen) { panic("extlen too large"); } *m_new = *m; // copy m_new->m_flags &= ~M_STACK; m_new->__m_extbuf = p; // point to new buffer _pkt_copy(m->__m_extbuf, p, m->__m_extlen); m_new->m_data = p + ofs; m = m_new; } #endif /* USERSPACE */ if (q->head == NULL) q->head = m; else q->tail->m_nextpkt = m; q->count++; q->tail = m; m->m_nextpkt = NULL; } #endif /* NEW_AQM */ #endif /* _IP_DN_PRIVATE_H */