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/*- * Copyright (c) 2010-2011 Solarflare Communications, Inc. * All rights reserved. * * This software was developed in part by Philip Paeps under contract for * Solarflare Communications, 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/dev/sfxge/sfxge_rx.c 227569 2011-11-16 17:11:13Z philip $"); #include <sys/types.h> #include <sys/mbuf.h> #include <sys/smp.h> #include <sys/socket.h> #include <sys/sysctl.h> #include <sys/limits.h> #include <net/ethernet.h> #include <net/if.h> #include <net/if_vlan_var.h> #include <netinet/in.h> #include <netinet/ip.h> #include <netinet/ip6.h> #include <netinet/tcp.h> #include <machine/in_cksum.h> #include "common/efx.h" #include "sfxge.h" #include "sfxge_rx.h" #define RX_REFILL_THRESHOLD (EFX_RXQ_LIMIT(SFXGE_NDESCS) * 9 / 10) #define RX_REFILL_THRESHOLD_2 (RX_REFILL_THRESHOLD / 2) /* Size of the LRO hash table. Must be a power of 2. A larger table * means we can accelerate a larger number of streams. */ static unsigned lro_table_size = 128; /* Maximum length of a hash chain. If chains get too long then the lookup * time increases and may exceed the benefit of LRO. */ static unsigned lro_chain_max = 20; /* Maximum time (in ticks) that a connection can be idle before it's LRO * state is discarded. */ static unsigned lro_idle_ticks; /* initialised in sfxge_rx_init() */ /* Number of packets with payload that must arrive in-order before a * connection is eligible for LRO. The idea is we should avoid coalescing * segments when the sender is in slow-start because reducing the ACK rate * can damage performance. */ static int lro_slow_start_packets = 2000; /* Number of packets with payload that must arrive in-order following loss * before a connection is eligible for LRO. The idea is we should avoid * coalescing segments when the sender is recovering from loss, because * reducing the ACK rate can damage performance. */ static int lro_loss_packets = 20; /* Flags for sfxge_lro_conn::l2_id; must not collide with EVL_VLID_MASK */ #define SFXGE_LRO_L2_ID_VLAN 0x4000 #define SFXGE_LRO_L2_ID_IPV6 0x8000 #define SFXGE_LRO_CONN_IS_VLAN_ENCAP(c) ((c)->l2_id & SFXGE_LRO_L2_ID_VLAN) #define SFXGE_LRO_CONN_IS_TCPIPV4(c) (!((c)->l2_id & SFXGE_LRO_L2_ID_IPV6)) /* Compare IPv6 addresses, avoiding conditional branches */ static __inline unsigned long ipv6_addr_cmp(const struct in6_addr *left, const struct in6_addr *right) { #if LONG_BIT == 64 const uint64_t *left64 = (const uint64_t *)left; const uint64_t *right64 = (const uint64_t *)right; return (left64[0] - right64[0]) | (left64[1] - right64[1]); #else return (left->s6_addr32[0] - right->s6_addr32[0]) | (left->s6_addr32[1] - right->s6_addr32[1]) | (left->s6_addr32[2] - right->s6_addr32[2]) | (left->s6_addr32[3] - right->s6_addr32[3]); #endif } void sfxge_rx_qflush_done(struct sfxge_rxq *rxq) { rxq->flush_state = SFXGE_FLUSH_DONE; } void sfxge_rx_qflush_failed(struct sfxge_rxq *rxq) { rxq->flush_state = SFXGE_FLUSH_FAILED; } static uint8_t toep_key[] = { 0x6d, 0x5a, 0x56, 0xda, 0x25, 0x5b, 0x0e, 0xc2, 0x41, 0x67, 0x25, 0x3d, 0x43, 0xa3, 0x8f, 0xb0, 0xd0, 0xca, 0x2b, 0xcb, 0xae, 0x7b, 0x30, 0xb4, 0x77, 0xcb, 0x2d, 0xa3, 0x80, 0x30, 0xf2, 0x0c, 0x6a, 0x42, 0xb7, 0x3b, 0xbe, 0xac, 0x01, 0xfa }; static void sfxge_rx_post_refill(void *arg) { struct sfxge_rxq *rxq = arg; struct sfxge_softc *sc; unsigned int index; struct sfxge_evq *evq; uint16_t magic; sc = rxq->sc; index = rxq->index; evq = sc->evq[index]; magic = SFXGE_MAGIC_RX_QREFILL | index; /* This is guaranteed due to the start/stop order of rx and ev */ KASSERT(evq->init_state == SFXGE_EVQ_STARTED, ("evq not started")); KASSERT(rxq->init_state == SFXGE_RXQ_STARTED, ("rxq not started")); efx_ev_qpost(evq->common, magic); } static void sfxge_rx_schedule_refill(struct sfxge_rxq *rxq, boolean_t retrying) { /* Initially retry after 100 ms, but back off in case of * repeated failures as we probably have to wait for the * administrator to raise the pool limit. */ if (retrying) rxq->refill_delay = min(rxq->refill_delay * 2, 10 * hz); else rxq->refill_delay = hz / 10; callout_reset_curcpu(&rxq->refill_callout, rxq->refill_delay, sfxge_rx_post_refill, rxq); } static inline struct mbuf *sfxge_rx_alloc_mbuf(struct sfxge_softc *sc) { struct mb_args args; struct mbuf *m; /* Allocate mbuf structure */ args.flags = M_PKTHDR; args.type = MT_DATA; m = (struct mbuf *)uma_zalloc_arg(zone_mbuf, &args, M_DONTWAIT); /* Allocate (and attach) packet buffer */ if (m && !uma_zalloc_arg(sc->rx_buffer_zone, m, M_DONTWAIT)) { uma_zfree(zone_mbuf, m); m = NULL; } return m; } #define SFXGE_REFILL_BATCH 64 static void sfxge_rx_qfill(struct sfxge_rxq *rxq, unsigned int target, boolean_t retrying) { struct sfxge_softc *sc; unsigned int index; struct sfxge_evq *evq; unsigned int batch; unsigned int rxfill; unsigned int mblksize; int ntodo; efsys_dma_addr_t addr[SFXGE_REFILL_BATCH]; sc = rxq->sc; index = rxq->index; evq = sc->evq[index]; prefetch_read_many(sc->enp); prefetch_read_many(rxq->common); mtx_assert(&evq->lock, MA_OWNED); if (rxq->init_state != SFXGE_RXQ_STARTED) return; rxfill = rxq->added - rxq->completed; KASSERT(rxfill <= EFX_RXQ_LIMIT(SFXGE_NDESCS), ("rxfill > EFX_RXQ_LIMIT(SFXGE_NDESCS)")); ntodo = min(EFX_RXQ_LIMIT(SFXGE_NDESCS) - rxfill, target); KASSERT(ntodo <= EFX_RXQ_LIMIT(SFXGE_NDESCS), ("ntodo > EFX_RQX_LIMIT(SFXGE_NDESCS)")); if (ntodo == 0) return; batch = 0; mblksize = sc->rx_buffer_size; while (ntodo-- > 0) { unsigned int id; struct sfxge_rx_sw_desc *rx_desc; bus_dma_segment_t seg; struct mbuf *m; id = (rxq->added + batch) & (SFXGE_NDESCS - 1); rx_desc = &rxq->queue[id]; KASSERT(rx_desc->mbuf == NULL, ("rx_desc->mbuf != NULL")); rx_desc->flags = EFX_DISCARD; m = rx_desc->mbuf = sfxge_rx_alloc_mbuf(sc); if (m == NULL) break; sfxge_map_mbuf_fast(rxq->mem.esm_tag, rxq->mem.esm_map, m, &seg); addr[batch++] = seg.ds_addr; if (batch == SFXGE_REFILL_BATCH) { efx_rx_qpost(rxq->common, addr, mblksize, batch, rxq->completed, rxq->added); rxq->added += batch; batch = 0; } } if (ntodo != 0) sfxge_rx_schedule_refill(rxq, retrying); if (batch != 0) { efx_rx_qpost(rxq->common, addr, mblksize, batch, rxq->completed, rxq->added); rxq->added += batch; } /* Make the descriptors visible to the hardware */ bus_dmamap_sync(rxq->mem.esm_tag, rxq->mem.esm_map, BUS_DMASYNC_PREWRITE); efx_rx_qpush(rxq->common, rxq->added); } void sfxge_rx_qrefill(struct sfxge_rxq *rxq) { if (rxq->init_state != SFXGE_RXQ_STARTED) return; /* Make sure the queue is full */ sfxge_rx_qfill(rxq, EFX_RXQ_LIMIT(SFXGE_NDESCS), B_TRUE); } static void __sfxge_rx_deliver(struct sfxge_softc *sc, struct mbuf *m) { struct ifnet *ifp = sc->ifnet; m->m_pkthdr.rcvif = ifp; m->m_pkthdr.header = m->m_data; m->m_pkthdr.csum_data = 0xffff; ifp->if_input(ifp, m); } static void sfxge_rx_deliver(struct sfxge_softc *sc, struct sfxge_rx_sw_desc *rx_desc) { struct mbuf *m = rx_desc->mbuf; int csum_flags; /* Convert checksum flags */ csum_flags = (rx_desc->flags & EFX_CKSUM_IPV4) ? (CSUM_IP_CHECKED | CSUM_IP_VALID) : 0; if (rx_desc->flags & EFX_CKSUM_TCPUDP) csum_flags |= CSUM_DATA_VALID | CSUM_PSEUDO_HDR; #ifdef SFXGE_HAVE_MQ /* The hash covers a 4-tuple for TCP only */ if (rx_desc->flags & EFX_PKT_TCP) { m->m_pkthdr.flowid = EFX_RX_HASH_VALUE(EFX_RX_HASHALG_TOEPLITZ, mtod(m, uint8_t *)); m->m_flags |= M_FLOWID; } #endif m->m_data += sc->rx_prefix_size; m->m_len = rx_desc->size - sc->rx_prefix_size; m->m_pkthdr.len = m->m_len; m->m_pkthdr.csum_flags = csum_flags; __sfxge_rx_deliver(sc, rx_desc->mbuf); rx_desc->flags = EFX_DISCARD; rx_desc->mbuf = NULL; } static void sfxge_lro_deliver(struct sfxge_lro_state *st, struct sfxge_lro_conn *c) { struct sfxge_softc *sc = st->sc; struct mbuf *m = c->mbuf; struct tcphdr *c_th; int csum_flags; KASSERT(m, ("no mbuf to deliver")); ++st->n_bursts; /* Finish off packet munging and recalculate IP header checksum. */ if (SFXGE_LRO_CONN_IS_TCPIPV4(c)) { struct ip *iph = c->nh; iph->ip_len = htons(iph->ip_len); iph->ip_sum = 0; iph->ip_sum = in_cksum_hdr(iph); c_th = (struct tcphdr *)(iph + 1); csum_flags = (CSUM_DATA_VALID | CSUM_PSEUDO_HDR | CSUM_IP_CHECKED | CSUM_IP_VALID); } else { struct ip6_hdr *iph = c->nh; iph->ip6_plen = htons(iph->ip6_plen); c_th = (struct tcphdr *)(iph + 1); csum_flags = CSUM_DATA_VALID | CSUM_PSEUDO_HDR; } c_th->th_win = c->th_last->th_win; c_th->th_ack = c->th_last->th_ack; if (c_th->th_off == c->th_last->th_off) { /* Copy TCP options (take care to avoid going negative). */ int optlen = ((c_th->th_off - 5) & 0xf) << 2u; memcpy(c_th + 1, c->th_last + 1, optlen); } #ifdef SFXGE_HAVE_MQ m->m_pkthdr.flowid = c->conn_hash; m->m_flags |= M_FLOWID; #endif m->m_pkthdr.csum_flags = csum_flags; __sfxge_rx_deliver(sc, m); c->mbuf = NULL; c->delivered = 1; } /* Drop the given connection, and add it to the free list. */ static void sfxge_lro_drop(struct sfxge_rxq *rxq, struct sfxge_lro_conn *c) { unsigned bucket; KASSERT(!c->mbuf, ("found orphaned mbuf")); if (c->next_buf.mbuf) { sfxge_rx_deliver(rxq->sc, &c->next_buf); LIST_REMOVE(c, active_link); } bucket = c->conn_hash & rxq->lro.conns_mask; KASSERT(rxq->lro.conns_n[bucket] > 0, ("LRO: bucket fill level wrong")); --rxq->lro.conns_n[bucket]; TAILQ_REMOVE(&rxq->lro.conns[bucket], c, link); TAILQ_INSERT_HEAD(&rxq->lro.free_conns, c, link); } /* Stop tracking connections that have gone idle in order to keep hash * chains short. */ static void sfxge_lro_purge_idle(struct sfxge_rxq *rxq, unsigned now) { struct sfxge_lro_conn *c; unsigned i; KASSERT(LIST_EMPTY(&rxq->lro.active_conns), ("found active connections")); rxq->lro.last_purge_ticks = now; for (i = 0; i <= rxq->lro.conns_mask; ++i) { if (TAILQ_EMPTY(&rxq->lro.conns[i])) continue; c = TAILQ_LAST(&rxq->lro.conns[i], sfxge_lro_tailq); if (now - c->last_pkt_ticks > lro_idle_ticks) { ++rxq->lro.n_drop_idle; sfxge_lro_drop(rxq, c); } } } static void sfxge_lro_merge(struct sfxge_lro_state *st, struct sfxge_lro_conn *c, struct mbuf *mbuf, struct tcphdr *th) { struct tcphdr *c_th; /* Tack the new mbuf onto the chain. */ KASSERT(!mbuf->m_next, ("mbuf already chained")); c->mbuf_tail->m_next = mbuf; c->mbuf_tail = mbuf; /* Increase length appropriately */ c->mbuf->m_pkthdr.len += mbuf->m_len; /* Update the connection state flags */ if (SFXGE_LRO_CONN_IS_TCPIPV4(c)) { struct ip *iph = c->nh; iph->ip_len += mbuf->m_len; c_th = (struct tcphdr *)(iph + 1); } else { struct ip6_hdr *iph = c->nh; iph->ip6_plen += mbuf->m_len; c_th = (struct tcphdr *)(iph + 1); } c_th->th_flags |= (th->th_flags & TH_PUSH); c->th_last = th; ++st->n_merges; /* Pass packet up now if another segment could overflow the IP * length. */ if (c->mbuf->m_pkthdr.len > 65536 - 9200) sfxge_lro_deliver(st, c); } static void sfxge_lro_start(struct sfxge_lro_state *st, struct sfxge_lro_conn *c, struct mbuf *mbuf, void *nh, struct tcphdr *th) { /* Start the chain */ c->mbuf = mbuf; c->mbuf_tail = c->mbuf; c->nh = nh; c->th_last = th; mbuf->m_pkthdr.len = mbuf->m_len; /* Mangle header fields for later processing */ if (SFXGE_LRO_CONN_IS_TCPIPV4(c)) { struct ip *iph = nh; iph->ip_len = ntohs(iph->ip_len); } else { struct ip6_hdr *iph = nh; iph->ip6_plen = ntohs(iph->ip6_plen); } } /* Try to merge or otherwise hold or deliver (as appropriate) the * packet buffered for this connection (c->next_buf). Return a flag * indicating whether the connection is still active for LRO purposes. */ static int sfxge_lro_try_merge(struct sfxge_rxq *rxq, struct sfxge_lro_conn *c) { struct sfxge_rx_sw_desc *rx_buf = &c->next_buf; char *eh = c->next_eh; int data_length, hdr_length, dont_merge; unsigned th_seq, pkt_length; struct tcphdr *th; unsigned now; if (SFXGE_LRO_CONN_IS_TCPIPV4(c)) { struct ip *iph = c->next_nh; th = (struct tcphdr *)(iph + 1); pkt_length = ntohs(iph->ip_len) + (char *) iph - eh; } else { struct ip6_hdr *iph = c->next_nh; th = (struct tcphdr *)(iph + 1); pkt_length = ntohs(iph->ip6_plen) + (char *) th - eh; } hdr_length = (char *) th + th->th_off * 4 - eh; data_length = (min(pkt_length, rx_buf->size - rxq->sc->rx_prefix_size) - hdr_length); th_seq = ntohl(th->th_seq); dont_merge = ((data_length <= 0) | (th->th_flags & (TH_URG | TH_SYN | TH_RST | TH_FIN))); /* Check for options other than aligned timestamp. */ if (th->th_off != 5) { const uint32_t *opt_ptr = (const uint32_t *) (th + 1); if (th->th_off == 8 && opt_ptr[0] == ntohl((TCPOPT_NOP << 24) | (TCPOPT_NOP << 16) | (TCPOPT_TIMESTAMP << 8) | TCPOLEN_TIMESTAMP)) { /* timestamp option -- okay */ } else { dont_merge = 1; } } if (__predict_false(th_seq != c->next_seq)) { /* Out-of-order, so start counting again. */ if (c->mbuf) sfxge_lro_deliver(&rxq->lro, c); c->n_in_order_pkts -= lro_loss_packets; c->next_seq = th_seq + data_length; ++rxq->lro.n_misorder; goto deliver_buf_out; } c->next_seq = th_seq + data_length; now = ticks; if (now - c->last_pkt_ticks > lro_idle_ticks) { ++rxq->lro.n_drop_idle; if (c->mbuf) sfxge_lro_deliver(&rxq->lro, c); sfxge_lro_drop(rxq, c); return 0; } c->last_pkt_ticks = ticks; if (c->n_in_order_pkts < lro_slow_start_packets) { /* May be in slow-start, so don't merge. */ ++rxq->lro.n_slow_start; ++c->n_in_order_pkts; goto deliver_buf_out; } if (__predict_false(dont_merge)) { if (c->mbuf) sfxge_lro_deliver(&rxq->lro, c); if (th->th_flags & (TH_FIN | TH_RST)) { ++rxq->lro.n_drop_closed; sfxge_lro_drop(rxq, c); return 0; } goto deliver_buf_out; } rx_buf->mbuf->m_data += rxq->sc->rx_prefix_size; if (__predict_true(c->mbuf != NULL)) { /* Remove headers and any padding */ rx_buf->mbuf->m_data += hdr_length; rx_buf->mbuf->m_len = data_length; sfxge_lro_merge(&rxq->lro, c, rx_buf->mbuf, th); } else { /* Remove any padding */ rx_buf->mbuf->m_len = pkt_length; sfxge_lro_start(&rxq->lro, c, rx_buf->mbuf, c->next_nh, th); } rx_buf->mbuf = NULL; return 1; deliver_buf_out: sfxge_rx_deliver(rxq->sc, rx_buf); return 1; } static void sfxge_lro_new_conn(struct sfxge_lro_state *st, uint32_t conn_hash, uint16_t l2_id, void *nh, struct tcphdr *th) { unsigned bucket = conn_hash & st->conns_mask; struct sfxge_lro_conn *c; if (st->conns_n[bucket] >= lro_chain_max) { ++st->n_too_many; return; } if (!TAILQ_EMPTY(&st->free_conns)) { c = TAILQ_FIRST(&st->free_conns); TAILQ_REMOVE(&st->free_conns, c, link); } else { c = malloc(sizeof(*c), M_SFXGE, M_DONTWAIT); if (c == NULL) return; c->mbuf = NULL; c->next_buf.mbuf = NULL; } /* Create the connection tracking data */ ++st->conns_n[bucket]; TAILQ_INSERT_HEAD(&st->conns[bucket], c, link); c->l2_id = l2_id; c->conn_hash = conn_hash; c->source = th->th_sport; c->dest = th->th_dport; c->n_in_order_pkts = 0; c->last_pkt_ticks = *(volatile int *)&ticks; c->delivered = 0; ++st->n_new_stream; /* NB. We don't initialise c->next_seq, and it doesn't matter what * value it has. Most likely the next packet received for this * connection will not match -- no harm done. */ } /* Process mbuf and decide whether to dispatch it to the stack now or * later. */ static void sfxge_lro(struct sfxge_rxq *rxq, struct sfxge_rx_sw_desc *rx_buf) { struct sfxge_softc *sc = rxq->sc; struct mbuf *m = rx_buf->mbuf; struct ether_header *eh; struct sfxge_lro_conn *c; uint16_t l2_id; uint16_t l3_proto; void *nh; struct tcphdr *th; uint32_t conn_hash; unsigned bucket; /* Get the hardware hash */ conn_hash = EFX_RX_HASH_VALUE(EFX_RX_HASHALG_TOEPLITZ, mtod(m, uint8_t *)); eh = (struct ether_header *)(m->m_data + sc->rx_prefix_size); if (eh->ether_type == htons(ETHERTYPE_VLAN)) { struct ether_vlan_header *veh = (struct ether_vlan_header *)eh; l2_id = EVL_VLANOFTAG(ntohs(veh->evl_tag)) | SFXGE_LRO_L2_ID_VLAN; l3_proto = veh->evl_proto; nh = veh + 1; } else { l2_id = 0; l3_proto = eh->ether_type; nh = eh + 1; } /* Check whether this is a suitable packet (unfragmented * TCP/IPv4 or TCP/IPv6). If so, find the TCP header and * length, and compute a hash if necessary. If not, return. */ if (l3_proto == htons(ETHERTYPE_IP)) { struct ip *iph = nh; if ((iph->ip_p - IPPROTO_TCP) | (iph->ip_hl - (sizeof(*iph) >> 2u)) | (iph->ip_off & htons(IP_MF | IP_OFFMASK))) goto deliver_now; th = (struct tcphdr *)(iph + 1); } else if (l3_proto == htons(ETHERTYPE_IPV6)) { struct ip6_hdr *iph = nh; if (iph->ip6_nxt != IPPROTO_TCP) goto deliver_now; l2_id |= SFXGE_LRO_L2_ID_IPV6; th = (struct tcphdr *)(iph + 1); } else { goto deliver_now; } bucket = conn_hash & rxq->lro.conns_mask; TAILQ_FOREACH(c, &rxq->lro.conns[bucket], link) { if ((c->l2_id - l2_id) | (c->conn_hash - conn_hash)) continue; if ((c->source - th->th_sport) | (c->dest - th->th_dport)) continue; if (c->mbuf) { if (SFXGE_LRO_CONN_IS_TCPIPV4(c)) { struct ip *c_iph, *iph = nh; c_iph = c->nh; if ((c_iph->ip_src.s_addr - iph->ip_src.s_addr) | (c_iph->ip_dst.s_addr - iph->ip_dst.s_addr)) continue; } else { struct ip6_hdr *c_iph, *iph = nh; c_iph = c->nh; if (ipv6_addr_cmp(&c_iph->ip6_src, &iph->ip6_src) | ipv6_addr_cmp(&c_iph->ip6_dst, &iph->ip6_dst)) continue; } } /* Re-insert at head of list to reduce lookup time. */ TAILQ_REMOVE(&rxq->lro.conns[bucket], c, link); TAILQ_INSERT_HEAD(&rxq->lro.conns[bucket], c, link); if (c->next_buf.mbuf) { if (!sfxge_lro_try_merge(rxq, c)) goto deliver_now; } else { LIST_INSERT_HEAD(&rxq->lro.active_conns, c, active_link); } c->next_buf = *rx_buf; c->next_eh = eh; c->next_nh = nh; rx_buf->mbuf = NULL; rx_buf->flags = EFX_DISCARD; return; } sfxge_lro_new_conn(&rxq->lro, conn_hash, l2_id, nh, th); deliver_now: sfxge_rx_deliver(sc, rx_buf); } static void sfxge_lro_end_of_burst(struct sfxge_rxq *rxq) { struct sfxge_lro_state *st = &rxq->lro; struct sfxge_lro_conn *c; unsigned t; while (!LIST_EMPTY(&st->active_conns)) { c = LIST_FIRST(&st->active_conns); if (!c->delivered && c->mbuf) sfxge_lro_deliver(st, c); if (sfxge_lro_try_merge(rxq, c)) { if (c->mbuf) sfxge_lro_deliver(st, c); LIST_REMOVE(c, active_link); } c->delivered = 0; } t = *(volatile int *)&ticks; if (__predict_false(t != st->last_purge_ticks)) sfxge_lro_purge_idle(rxq, t); } void sfxge_rx_qcomplete(struct sfxge_rxq *rxq, boolean_t eop) { struct sfxge_softc *sc = rxq->sc; int lro_enabled = sc->ifnet->if_capenable & IFCAP_LRO; unsigned int index; struct sfxge_evq *evq; unsigned int completed; unsigned int level; struct mbuf *m; struct sfxge_rx_sw_desc *prev = NULL; index = rxq->index; evq = sc->evq[index]; mtx_assert(&evq->lock, MA_OWNED); completed = rxq->completed; while (completed != rxq->pending) { unsigned int id; struct sfxge_rx_sw_desc *rx_desc; id = completed++ & (SFXGE_NDESCS - 1); rx_desc = &rxq->queue[id]; m = rx_desc->mbuf; if (rxq->init_state != SFXGE_RXQ_STARTED) goto discard; if (rx_desc->flags & (EFX_ADDR_MISMATCH | EFX_DISCARD)) goto discard; prefetch_read_many(mtod(m, caddr_t)); /* Check for loopback packets */ if (!(rx_desc->flags & EFX_PKT_IPV4) && !(rx_desc->flags & EFX_PKT_IPV6)) { struct ether_header *etherhp; /*LINTED*/ etherhp = mtod(m, struct ether_header *); if (etherhp->ether_type == htons(SFXGE_ETHERTYPE_LOOPBACK)) { EFSYS_PROBE(loopback); rxq->loopback++; goto discard; } } /* Pass packet up the stack or into LRO (pipelined) */ if (prev != NULL) { if (lro_enabled) sfxge_lro(rxq, prev); else sfxge_rx_deliver(sc, prev); } prev = rx_desc; continue; discard: /* Return the packet to the pool */ m_free(m); rx_desc->mbuf = NULL; } rxq->completed = completed; level = rxq->added - rxq->completed; /* Pass last packet up the stack or into LRO */ if (prev != NULL) { if (lro_enabled) sfxge_lro(rxq, prev); else sfxge_rx_deliver(sc, prev); } /* * If there are any pending flows and this is the end of the * poll then they must be completed. */ if (eop) sfxge_lro_end_of_burst(rxq); /* Top up the queue if necessary */ if (level < RX_REFILL_THRESHOLD) sfxge_rx_qfill(rxq, EFX_RXQ_LIMIT(SFXGE_NDESCS), B_FALSE); } static void sfxge_rx_qstop(struct sfxge_softc *sc, unsigned int index) { struct sfxge_rxq *rxq; struct sfxge_evq *evq; unsigned int count; rxq = sc->rxq[index]; evq = sc->evq[index]; mtx_lock(&evq->lock); KASSERT(rxq->init_state == SFXGE_RXQ_STARTED, ("rxq not started")); rxq->init_state = SFXGE_RXQ_INITIALIZED; callout_stop(&rxq->refill_callout); again: rxq->flush_state = SFXGE_FLUSH_PENDING; /* Flush the receive queue */ efx_rx_qflush(rxq->common); mtx_unlock(&evq->lock); count = 0; do { /* Spin for 100 ms */ DELAY(100000); if (rxq->flush_state != SFXGE_FLUSH_PENDING) break; } while (++count < 20); mtx_lock(&evq->lock); if (rxq->flush_state == SFXGE_FLUSH_FAILED) goto again; rxq->flush_state = SFXGE_FLUSH_DONE; rxq->pending = rxq->added; sfxge_rx_qcomplete(rxq, B_TRUE); KASSERT(rxq->completed == rxq->pending, ("rxq->completed != rxq->pending")); rxq->added = 0; rxq->pending = 0; rxq->completed = 0; rxq->loopback = 0; /* Destroy the common code receive queue. */ efx_rx_qdestroy(rxq->common); efx_sram_buf_tbl_clear(sc->enp, rxq->buf_base_id, EFX_RXQ_NBUFS(SFXGE_NDESCS)); mtx_unlock(&evq->lock); } static int sfxge_rx_qstart(struct sfxge_softc *sc, unsigned int index) { struct sfxge_rxq *rxq; efsys_mem_t *esmp; struct sfxge_evq *evq; int rc; rxq = sc->rxq[index]; esmp = &rxq->mem; evq = sc->evq[index]; KASSERT(rxq->init_state == SFXGE_RXQ_INITIALIZED, ("rxq->init_state != SFXGE_RXQ_INITIALIZED")); KASSERT(evq->init_state == SFXGE_EVQ_STARTED, ("evq->init_state != SFXGE_EVQ_STARTED")); /* Program the buffer table. */ if ((rc = efx_sram_buf_tbl_set(sc->enp, rxq->buf_base_id, esmp, EFX_RXQ_NBUFS(SFXGE_NDESCS))) != 0) return rc; /* Create the common code receive queue. */ if ((rc = efx_rx_qcreate(sc->enp, index, index, EFX_RXQ_TYPE_DEFAULT, esmp, SFXGE_NDESCS, rxq->buf_base_id, evq->common, &rxq->common)) != 0) goto fail; mtx_lock(&evq->lock); /* Enable the receive queue. */ efx_rx_qenable(rxq->common); rxq->init_state = SFXGE_RXQ_STARTED; /* Try to fill the queue from the pool. */ sfxge_rx_qfill(rxq, EFX_RXQ_LIMIT(SFXGE_NDESCS), B_FALSE); mtx_unlock(&evq->lock); return (0); fail: efx_sram_buf_tbl_clear(sc->enp, rxq->buf_base_id, EFX_RXQ_NBUFS(SFXGE_NDESCS)); return rc; } void sfxge_rx_stop(struct sfxge_softc *sc) { struct sfxge_intr *intr; int index; intr = &sc->intr; /* Stop the receive queue(s) */ index = intr->n_alloc; while (--index >= 0) sfxge_rx_qstop(sc, index); sc->rx_prefix_size = 0; sc->rx_buffer_size = 0; efx_rx_fini(sc->enp); } int sfxge_rx_start(struct sfxge_softc *sc) { struct sfxge_intr *intr; int index; int rc; intr = &sc->intr; /* Initialize the common code receive module. */ if ((rc = efx_rx_init(sc->enp)) != 0) return (rc); /* Calculate the receive packet buffer size. */ sc->rx_prefix_size = EFX_RX_PREFIX_SIZE; sc->rx_buffer_size = (EFX_MAC_PDU(sc->ifnet->if_mtu) + sc->rx_prefix_size); /* Select zone for packet buffers */ if (sc->rx_buffer_size <= MCLBYTES) sc->rx_buffer_zone = zone_clust; else if (sc->rx_buffer_size <= MJUMPAGESIZE) sc->rx_buffer_zone = zone_jumbop; else if (sc->rx_buffer_size <= MJUM9BYTES) sc->rx_buffer_zone = zone_jumbo9; else sc->rx_buffer_zone = zone_jumbo16; /* * Set up the scale table. Enable all hash types and hash insertion. */ for (index = 0; index < SFXGE_RX_SCALE_MAX; index++) sc->rx_indir_table[index] = index % sc->intr.n_alloc; if ((rc = efx_rx_scale_tbl_set(sc->enp, sc->rx_indir_table, SFXGE_RX_SCALE_MAX)) != 0) goto fail; (void)efx_rx_scale_mode_set(sc->enp, EFX_RX_HASHALG_TOEPLITZ, (1 << EFX_RX_HASH_IPV4) | (1 << EFX_RX_HASH_TCPIPV4) | (1 << EFX_RX_HASH_IPV6) | (1 << EFX_RX_HASH_TCPIPV6), B_TRUE); if ((rc = efx_rx_scale_toeplitz_ipv4_key_set(sc->enp, toep_key, sizeof(toep_key))) != 0) goto fail; /* Start the receive queue(s). */ for (index = 0; index < intr->n_alloc; index++) { if ((rc = sfxge_rx_qstart(sc, index)) != 0) goto fail2; } return (0); fail2: while (--index >= 0) sfxge_rx_qstop(sc, index); fail: efx_rx_fini(sc->enp); return (rc); } static void sfxge_lro_init(struct sfxge_rxq *rxq) { struct sfxge_lro_state *st = &rxq->lro; unsigned i; st->conns_mask = lro_table_size - 1; KASSERT(!((st->conns_mask + 1) & st->conns_mask), ("lro_table_size must be a power of 2")); st->sc = rxq->sc; st->conns = malloc((st->conns_mask + 1) * sizeof(st->conns[0]), M_SFXGE, M_WAITOK); st->conns_n = malloc((st->conns_mask + 1) * sizeof(st->conns_n[0]), M_SFXGE, M_WAITOK); for (i = 0; i <= st->conns_mask; ++i) { TAILQ_INIT(&st->conns[i]); st->conns_n[i] = 0; } LIST_INIT(&st->active_conns); TAILQ_INIT(&st->free_conns); } static void sfxge_lro_fini(struct sfxge_rxq *rxq) { struct sfxge_lro_state *st = &rxq->lro; struct sfxge_lro_conn *c; unsigned i; /* Return cleanly if sfxge_lro_init() has not been called. */ if (st->conns == NULL) return; KASSERT(LIST_EMPTY(&st->active_conns), ("found active connections")); for (i = 0; i <= st->conns_mask; ++i) { while (!TAILQ_EMPTY(&st->conns[i])) { c = TAILQ_LAST(&st->conns[i], sfxge_lro_tailq); sfxge_lro_drop(rxq, c); } } while (!TAILQ_EMPTY(&st->free_conns)) { c = TAILQ_FIRST(&st->free_conns); TAILQ_REMOVE(&st->free_conns, c, link); KASSERT(!c->mbuf, ("found orphaned mbuf")); free(c, M_SFXGE); } free(st->conns_n, M_SFXGE); free(st->conns, M_SFXGE); st->conns = NULL; } static void sfxge_rx_qfini(struct sfxge_softc *sc, unsigned int index) { struct sfxge_rxq *rxq; rxq = sc->rxq[index]; KASSERT(rxq->init_state == SFXGE_RXQ_INITIALIZED, ("rxq->init_state != SFXGE_RXQ_INITIALIZED")); /* Free the context array and the flow table. */ free(rxq->queue, M_SFXGE); sfxge_lro_fini(rxq); /* Release DMA memory. */ sfxge_dma_free(&rxq->mem); sc->rxq[index] = NULL; free(rxq, M_SFXGE); } static int sfxge_rx_qinit(struct sfxge_softc *sc, unsigned int index) { struct sfxge_rxq *rxq; struct sfxge_evq *evq; efsys_mem_t *esmp; int rc; KASSERT(index < sc->intr.n_alloc, ("index >= %d", sc->intr.n_alloc)); rxq = malloc(sizeof(struct sfxge_rxq), M_SFXGE, M_ZERO | M_WAITOK); rxq->sc = sc; rxq->index = index; sc->rxq[index] = rxq; esmp = &rxq->mem; evq = sc->evq[index]; /* Allocate and zero DMA space. */ if ((rc = sfxge_dma_alloc(sc, EFX_RXQ_SIZE(SFXGE_NDESCS), esmp)) != 0) return (rc); (void)memset(esmp->esm_base, 0, EFX_RXQ_SIZE(SFXGE_NDESCS)); /* Allocate buffer table entries. */ sfxge_sram_buf_tbl_alloc(sc, EFX_RXQ_NBUFS(SFXGE_NDESCS), &rxq->buf_base_id); /* Allocate the context array and the flow table. */ rxq->queue = malloc(sizeof(struct sfxge_rx_sw_desc) * SFXGE_NDESCS, M_SFXGE, M_WAITOK | M_ZERO); sfxge_lro_init(rxq); callout_init(&rxq->refill_callout, B_TRUE); rxq->init_state = SFXGE_RXQ_INITIALIZED; return (0); } static const struct { const char *name; size_t offset; } sfxge_rx_stats[] = { #define SFXGE_RX_STAT(name, member) \ { #name, offsetof(struct sfxge_rxq, member) } SFXGE_RX_STAT(lro_merges, lro.n_merges), SFXGE_RX_STAT(lro_bursts, lro.n_bursts), SFXGE_RX_STAT(lro_slow_start, lro.n_slow_start), SFXGE_RX_STAT(lro_misorder, lro.n_misorder), SFXGE_RX_STAT(lro_too_many, lro.n_too_many), SFXGE_RX_STAT(lro_new_stream, lro.n_new_stream), SFXGE_RX_STAT(lro_drop_idle, lro.n_drop_idle), SFXGE_RX_STAT(lro_drop_closed, lro.n_drop_closed) }; static int sfxge_rx_stat_handler(SYSCTL_HANDLER_ARGS) { struct sfxge_softc *sc = arg1; unsigned int id = arg2; unsigned int sum, index; /* Sum across all RX queues */ sum = 0; for (index = 0; index < sc->intr.n_alloc; index++) sum += *(unsigned int *)((caddr_t)sc->rxq[index] + sfxge_rx_stats[id].offset); return SYSCTL_OUT(req, &sum, sizeof(sum)); } static void sfxge_rx_stat_init(struct sfxge_softc *sc) { struct sysctl_ctx_list *ctx = device_get_sysctl_ctx(sc->dev); struct sysctl_oid_list *stat_list; unsigned int id; stat_list = SYSCTL_CHILDREN(sc->stats_node); for (id = 0; id < sizeof(sfxge_rx_stats) / sizeof(sfxge_rx_stats[0]); id++) { SYSCTL_ADD_PROC( ctx, stat_list, OID_AUTO, sfxge_rx_stats[id].name, CTLTYPE_UINT|CTLFLAG_RD, sc, id, sfxge_rx_stat_handler, "IU", ""); } } void sfxge_rx_fini(struct sfxge_softc *sc) { struct sfxge_intr *intr; int index; intr = &sc->intr; index = intr->n_alloc; while (--index >= 0) sfxge_rx_qfini(sc, index); } int sfxge_rx_init(struct sfxge_softc *sc) { struct sfxge_intr *intr; int index; int rc; if (lro_idle_ticks == 0) lro_idle_ticks = hz / 10 + 1; /* 100 ms */ intr = &sc->intr; KASSERT(intr->state == SFXGE_INTR_INITIALIZED, ("intr->state != SFXGE_INTR_INITIALIZED")); /* Initialize the receive queue(s) - one per interrupt. */ for (index = 0; index < intr->n_alloc; index++) { if ((rc = sfxge_rx_qinit(sc, index)) != 0) goto fail; } sfxge_rx_stat_init(sc); return (0); fail: /* Tear down the receive queue(s). */ while (--index >= 0) sfxge_rx_qfini(sc, index); return (rc); }