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/*- * Copyright (c) 2010-2011 Juniper Networks, Inc. * All rights reserved. * * This software was developed by Robert N. M. Watson under contract * to Juniper Networks, Inc. * * 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 <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/netinet/in_pcbgroup.c 222748 2011-06-06 12:55:02Z rwatson $"); #include "opt_inet6.h" #include <sys/param.h> #include <sys/lock.h> #include <sys/malloc.h> #include <sys/mbuf.h> #include <sys/mutex.h> #include <sys/smp.h> #include <sys/socketvar.h> #include <netinet/in.h> #include <netinet/in_pcb.h> #ifdef INET6 #include <netinet6/in6_pcb.h> #endif /* INET6 */ /* * pcbgroups, or "connection groups" are based on Willman, Rixner, and Cox's * 2006 USENIX paper, "An Evaluation of Network Stack Parallelization * Strategies in Modern Operating Systems". This implementation differs * significantly from that described in the paper, in that it attempts to * introduce not just notions of affinity for connections and distribute work * so as to reduce lock contention, but also align those notions with * hardware work distribution strategies such as RSS. In this construction, * connection groups supplement, rather than replace, existing reservation * tables for protocol 4-tuples, offering CPU-affine lookup tables with * minimal cache line migration and lock contention during steady state * operation. * * Internet protocols, such as UDP and TCP, register to use connection groups * by providing an ipi_hashfields value other than IPI_HASHFIELDS_NONE; this * indicates to the connection group code whether a 2-tuple or 4-tuple is * used as an argument to hashes that assign a connection to a particular * group. This must be aligned with any hardware offloaded distribution * model, such as RSS or similar approaches taken in embedded network boards. * Wildcard sockets require special handling, as in Willman 2006, and are * shared between connection groups -- while being protected by group-local * locks. This means that connection establishment and teardown can be * signficantly more expensive than without connection groups, but that * steady-state processing can be significantly faster. * * Most of the implementation of connection groups is in this file; however, * connection group lookup is implemented in in_pcb.c alongside reservation * table lookups -- see in_pcblookup_group(). * * TODO: * * Implement dynamic rebalancing of buckets with connection groups; when * load is unevenly distributed, search for more optimal balancing on * demand. This might require scaling up the number of connection groups * by <<1. * * Provide an IP 2-tuple or 4-tuple netisr m2cpu handler based on connection * groups for ip_input and ip6_input, allowing non-offloaded work * distribution. * * Expose effective CPU affinity of connections to userspace using socket * options. * * Investigate per-connection affinity overrides based on socket options; an * option could be set, certainly resulting in work being distributed * differently in software, and possibly propagated to supporting hardware * with TCAMs or hardware hash tables. This might require connections to * exist in more than one connection group at a time. * * Hook netisr thread reconfiguration events, and propagate those to RSS so * that rebalancing can occur when the thread pool grows or shrinks. * * Expose per-pcbgroup statistics to userspace monitoring tools such as * netstat, in order to allow better debugging and profiling. */ void in_pcbgroup_init(struct inpcbinfo *pcbinfo, u_int hashfields, int hash_nelements) { struct inpcbgroup *pcbgroup; u_int numpcbgroups, pgn; /* * Only enable connection groups for a protocol if it has been * specifically requested. */ if (hashfields == IPI_HASHFIELDS_NONE) return; /* * Connection groups are about multi-processor load distribution, * lock contention, and connection CPU affinity. As such, no point * in turning them on for a uniprocessor machine, it only wastes * memory. */ if (mp_ncpus == 1) return; /* * Use one group per CPU for now. If we decide to do dynamic * rebalancing a la RSS, we'll need to shift left by at least 1. */ numpcbgroups = mp_ncpus; pcbinfo->ipi_hashfields = hashfields; pcbinfo->ipi_pcbgroups = malloc(numpcbgroups * sizeof(*pcbinfo->ipi_pcbgroups), M_PCB, M_WAITOK | M_ZERO); pcbinfo->ipi_npcbgroups = numpcbgroups; pcbinfo->ipi_wildbase = hashinit(hash_nelements, M_PCB, &pcbinfo->ipi_wildmask); for (pgn = 0; pgn < pcbinfo->ipi_npcbgroups; pgn++) { pcbgroup = &pcbinfo->ipi_pcbgroups[pgn]; pcbgroup->ipg_hashbase = hashinit(hash_nelements, M_PCB, &pcbgroup->ipg_hashmask); INP_GROUP_LOCK_INIT(pcbgroup, "pcbgroup"); /* * Initialise notional affinity of the pcbgroup -- for RSS, * we want the same notion of affinity as NICs to be used. * Just round robin for the time being. */ pcbgroup->ipg_cpu = (pgn % mp_ncpus); } } void in_pcbgroup_destroy(struct inpcbinfo *pcbinfo) { struct inpcbgroup *pcbgroup; u_int pgn; if (pcbinfo->ipi_npcbgroups == 0) return; for (pgn = 0; pgn < pcbinfo->ipi_npcbgroups; pgn++) { pcbgroup = &pcbinfo->ipi_pcbgroups[pgn]; KASSERT(LIST_EMPTY(pcbinfo->ipi_listhead), ("in_pcbinfo_destroy: listhead not empty")); INP_GROUP_LOCK_DESTROY(pcbgroup); hashdestroy(pcbgroup->ipg_hashbase, M_PCB, pcbgroup->ipg_hashmask); } hashdestroy(pcbinfo->ipi_wildbase, M_PCB, pcbinfo->ipi_wildmask); free(pcbinfo->ipi_pcbgroups, M_PCB); pcbinfo->ipi_pcbgroups = NULL; pcbinfo->ipi_npcbgroups = 0; pcbinfo->ipi_hashfields = 0; } /* * Given a hash of whatever the covered tuple might be, return a pcbgroup * index. */ static __inline u_int in_pcbgroup_getbucket(struct inpcbinfo *pcbinfo, uint32_t hash) { return (hash % pcbinfo->ipi_npcbgroups); } /* * Map a (hashtype, hash) tuple into a connection group, or NULL if the hash * information is insufficient to identify the pcbgroup. */ struct inpcbgroup * in_pcbgroup_byhash(struct inpcbinfo *pcbinfo, u_int hashtype, uint32_t hash) { return (NULL); } static struct inpcbgroup * in_pcbgroup_bymbuf(struct inpcbinfo *pcbinfo, struct mbuf *m) { return (in_pcbgroup_byhash(pcbinfo, M_HASHTYPE_GET(m), m->m_pkthdr.flowid)); } struct inpcbgroup * in_pcbgroup_bytuple(struct inpcbinfo *pcbinfo, struct in_addr laddr, u_short lport, struct in_addr faddr, u_short fport) { uint32_t hash; switch (pcbinfo->ipi_hashfields) { case IPI_HASHFIELDS_4TUPLE: hash = faddr.s_addr ^ fport; break; case IPI_HASHFIELDS_2TUPLE: hash = faddr.s_addr ^ laddr.s_addr; break; default: hash = 0; } return (&pcbinfo->ipi_pcbgroups[in_pcbgroup_getbucket(pcbinfo, hash)]); } struct inpcbgroup * in_pcbgroup_byinpcb(struct inpcb *inp) { return (in_pcbgroup_bytuple(inp->inp_pcbinfo, inp->inp_laddr, inp->inp_lport, inp->inp_faddr, inp->inp_fport)); } static void in_pcbwild_add(struct inpcb *inp) { struct inpcbinfo *pcbinfo; struct inpcbhead *head; u_int pgn; INP_WLOCK_ASSERT(inp); KASSERT(!(inp->inp_flags2 & INP_PCBGROUPWILD), ("%s: is wild",__func__)); pcbinfo = inp->inp_pcbinfo; for (pgn = 0; pgn < pcbinfo->ipi_npcbgroups; pgn++) INP_GROUP_LOCK(&pcbinfo->ipi_pcbgroups[pgn]); head = &pcbinfo->ipi_wildbase[INP_PCBHASH(INADDR_ANY, inp->inp_lport, 0, pcbinfo->ipi_wildmask)]; LIST_INSERT_HEAD(head, inp, inp_pcbgroup_wild); inp->inp_flags2 |= INP_PCBGROUPWILD; for (pgn = 0; pgn < pcbinfo->ipi_npcbgroups; pgn++) INP_GROUP_UNLOCK(&pcbinfo->ipi_pcbgroups[pgn]); } static void in_pcbwild_remove(struct inpcb *inp) { struct inpcbinfo *pcbinfo; u_int pgn; INP_WLOCK_ASSERT(inp); KASSERT((inp->inp_flags2 & INP_PCBGROUPWILD), ("%s: not wild", __func__)); pcbinfo = inp->inp_pcbinfo; for (pgn = 0; pgn < pcbinfo->ipi_npcbgroups; pgn++) INP_GROUP_LOCK(&pcbinfo->ipi_pcbgroups[pgn]); LIST_REMOVE(inp, inp_pcbgroup_wild); for (pgn = 0; pgn < pcbinfo->ipi_npcbgroups; pgn++) INP_GROUP_UNLOCK(&pcbinfo->ipi_pcbgroups[pgn]); inp->inp_flags2 &= ~INP_PCBGROUPWILD; } static __inline int in_pcbwild_needed(struct inpcb *inp) { #ifdef INET6 if (inp->inp_vflag & INP_IPV6) return (IN6_IS_ADDR_UNSPECIFIED(&inp->in6p_faddr)); else #endif return (inp->inp_faddr.s_addr == htonl(INADDR_ANY)); } static void in_pcbwild_update_internal(struct inpcb *inp) { int wildcard_needed; wildcard_needed = in_pcbwild_needed(inp); if (wildcard_needed && !(inp->inp_flags2 & INP_PCBGROUPWILD)) in_pcbwild_add(inp); else if (!wildcard_needed && (inp->inp_flags2 & INP_PCBGROUPWILD)) in_pcbwild_remove(inp); } /* * Update the pcbgroup of an inpcb, which might include removing an old * pcbgroup reference and/or adding a new one. Wildcard processing is not * performed here, although ideally we'll never install a pcbgroup for a * wildcard inpcb (asserted below). */ static void in_pcbgroup_update_internal(struct inpcbinfo *pcbinfo, struct inpcbgroup *newpcbgroup, struct inpcb *inp) { struct inpcbgroup *oldpcbgroup; struct inpcbhead *pcbhash; uint32_t hashkey_faddr; INP_WLOCK_ASSERT(inp); oldpcbgroup = inp->inp_pcbgroup; if (oldpcbgroup != NULL && oldpcbgroup != newpcbgroup) { INP_GROUP_LOCK(oldpcbgroup); LIST_REMOVE(inp, inp_pcbgrouphash); inp->inp_pcbgroup = NULL; INP_GROUP_UNLOCK(oldpcbgroup); } if (newpcbgroup != NULL && oldpcbgroup != newpcbgroup) { #ifdef INET6 if (inp->inp_vflag & INP_IPV6) hashkey_faddr = inp->in6p_faddr.s6_addr32[3]; /* XXX */ else #endif hashkey_faddr = inp->inp_faddr.s_addr; INP_GROUP_LOCK(newpcbgroup); pcbhash = &newpcbgroup->ipg_hashbase[ INP_PCBHASH(hashkey_faddr, inp->inp_lport, inp->inp_fport, newpcbgroup->ipg_hashmask)]; LIST_INSERT_HEAD(pcbhash, inp, inp_pcbgrouphash); inp->inp_pcbgroup = newpcbgroup; INP_GROUP_UNLOCK(newpcbgroup); } KASSERT(!(newpcbgroup != NULL && in_pcbwild_needed(inp)), ("%s: pcbgroup and wildcard!", __func__)); } /* * Two update paths: one in which the 4-tuple on an inpcb has been updated * and therefore connection groups may need to change (or a wildcard entry * may needed to be installed), and another in which the 4-tuple has been * set as a result of a packet received, in which case we may be able to use * the hash on the mbuf to avoid doing a software hash calculation for RSS. * * In each case: first, let the wildcard code have a go at placing it as a * wildcard socket. If it was a wildcard, or if the connection has been * dropped, then no pcbgroup is required (so potentially clear it); * otherwise, calculate and update the pcbgroup for the inpcb. */ void in_pcbgroup_update(struct inpcb *inp) { struct inpcbinfo *pcbinfo; struct inpcbgroup *newpcbgroup; INP_WLOCK_ASSERT(inp); pcbinfo = inp->inp_pcbinfo; if (!in_pcbgroup_enabled(pcbinfo)) return; in_pcbwild_update_internal(inp); if (!(inp->inp_flags2 & INP_PCBGROUPWILD) && !(inp->inp_flags & INP_DROPPED)) { #ifdef INET6 if (inp->inp_vflag & INP_IPV6) newpcbgroup = in6_pcbgroup_byinpcb(inp); else #endif newpcbgroup = in_pcbgroup_byinpcb(inp); } else newpcbgroup = NULL; in_pcbgroup_update_internal(pcbinfo, newpcbgroup, inp); } void in_pcbgroup_update_mbuf(struct inpcb *inp, struct mbuf *m) { struct inpcbinfo *pcbinfo; struct inpcbgroup *newpcbgroup; INP_WLOCK_ASSERT(inp); pcbinfo = inp->inp_pcbinfo; if (!in_pcbgroup_enabled(pcbinfo)) return; /* * Possibly should assert !INP_PCBGROUPWILD rather than testing for * it; presumably this function should never be called for anything * other than non-wildcard socket? */ in_pcbwild_update_internal(inp); if (!(inp->inp_flags2 & INP_PCBGROUPWILD) && !(inp->inp_flags & INP_DROPPED)) { newpcbgroup = in_pcbgroup_bymbuf(pcbinfo, m); #ifdef INET6 if (inp->inp_vflag & INP_IPV6) { if (newpcbgroup == NULL) newpcbgroup = in6_pcbgroup_byinpcb(inp); } else { #endif if (newpcbgroup == NULL) newpcbgroup = in_pcbgroup_byinpcb(inp); #ifdef INET6 } #endif } else newpcbgroup = NULL; in_pcbgroup_update_internal(pcbinfo, newpcbgroup, inp); } /* * Remove pcbgroup entry and optional pcbgroup wildcard entry for this inpcb. */ void in_pcbgroup_remove(struct inpcb *inp) { struct inpcbgroup *pcbgroup; INP_WLOCK_ASSERT(inp); if (!in_pcbgroup_enabled(inp->inp_pcbinfo)) return; if (inp->inp_flags2 & INP_PCBGROUPWILD) in_pcbwild_remove(inp); pcbgroup = inp->inp_pcbgroup; if (pcbgroup != NULL) { INP_GROUP_LOCK(pcbgroup); LIST_REMOVE(inp, inp_pcbgrouphash); inp->inp_pcbgroup = NULL; INP_GROUP_UNLOCK(pcbgroup); } } /* * Query whether or not it is appropriate to use pcbgroups to look up inpcbs * for a protocol. */ int in_pcbgroup_enabled(struct inpcbinfo *pcbinfo) { return (pcbinfo->ipi_npcbgroups > 0); }