FreeBSD/Linux Kernel Cross Reference
sys/net/iflib.c

     /*-
      * Copyright (c) 2014-2018, Matthew Macy <mmacy@mattmacy.io>
      * 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. Neither the name of Matthew Macy nor the names of its
     *     contributors may be used to endorse or promote products derived from
     *     this software without specific prior written permission.
     *
     * 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.
     */
    
    #include <sys/cdefs.h>
    __FBSDID("$FreeBSD$");
    
    #include "opt_inet.h"
    #include "opt_inet6.h"
    #include "opt_acpi.h"
    #include "opt_sched.h"
    
    #include <sys/param.h>
    #include <sys/types.h>
    #include <sys/bus.h>
    #include <sys/eventhandler.h>
    #include <sys/kernel.h>
    #include <sys/lock.h>
    #include <sys/mutex.h>
    #include <sys/module.h>
    #include <sys/kobj.h>
    #include <sys/rman.h>
    #include <sys/sbuf.h>
    #include <sys/smp.h>
    #include <sys/socket.h>
    #include <sys/sockio.h>
    #include <sys/sysctl.h>
    #include <sys/syslog.h>
    #include <sys/taskqueue.h>
    #include <sys/limits.h>
    
    #include <net/if.h>
    #include <net/if_var.h>
    #include <net/if_private.h>
    #include <net/if_types.h>
    #include <net/if_media.h>
    #include <net/bpf.h>
    #include <net/ethernet.h>
    #include <net/mp_ring.h>
    #include <net/debugnet.h>
    #include <net/pfil.h>
    #include <net/vnet.h>
    
    #include <netinet/in.h>
    #include <netinet/in_pcb.h>
    #include <netinet/tcp_lro.h>
    #include <netinet/in_systm.h>
    #include <netinet/if_ether.h>
    #include <netinet/ip.h>
    #include <netinet/ip6.h>
    #include <netinet/tcp.h>
    #include <netinet/ip_var.h>
    #include <netinet6/ip6_var.h>
    
    #include <machine/bus.h>
    #include <machine/in_cksum.h>
    
    #include <vm/vm.h>
    #include <vm/pmap.h>
    
    #include <dev/led/led.h>
    #include <dev/pci/pcireg.h>
    #include <dev/pci/pcivar.h>
    #include <dev/pci/pci_private.h>
    
    #include <net/iflib.h>
    #include <net/iflib_private.h>
    
    #include "ifdi_if.h"
    
    #ifdef PCI_IOV
    #include <dev/pci/pci_iov.h>
    #endif
    
    #include <sys/bitstring.h>
    /*
    * enable accounting of every mbuf as it comes in to and goes out of
    * iflib's software descriptor references
    */
   #define MEMORY_LOGGING 0
   /*
    * Enable mbuf vectors for compressing long mbuf chains
    */
   
   /*
    * NB:
    * - Prefetching in tx cleaning should perhaps be a tunable. The distance ahead
    *   we prefetch needs to be determined by the time spent in m_free vis a vis
    *   the cost of a prefetch. This will of course vary based on the workload:
    *      - NFLX's m_free path is dominated by vm-based M_EXT manipulation which
    *        is quite expensive, thus suggesting very little prefetch.
    *      - small packet forwarding which is just returning a single mbuf to
    *        UMA will typically be very fast vis a vis the cost of a memory
    *        access.
    */
   
   /*
    * File organization:
    *  - private structures
    *  - iflib private utility functions
    *  - ifnet functions
    *  - vlan registry and other exported functions
    *  - iflib public core functions
    *
    *
    */
   MALLOC_DEFINE(M_IFLIB, "iflib", "ifnet library");
   
   #define IFLIB_RXEOF_MORE (1U << 0)
   #define IFLIB_RXEOF_EMPTY (2U << 0)
   
   struct iflib_txq;
   typedef struct iflib_txq *iflib_txq_t;
   struct iflib_rxq;
   typedef struct iflib_rxq *iflib_rxq_t;
   struct iflib_fl;
   typedef struct iflib_fl *iflib_fl_t;
   
   struct iflib_ctx;
   
   static void iru_init(if_rxd_update_t iru, iflib_rxq_t rxq, uint8_t flid);
   static void iflib_timer(void *arg);
   static void iflib_tqg_detach(if_ctx_t ctx);
   
   typedef struct iflib_filter_info {
           driver_filter_t *ifi_filter;
           void *ifi_filter_arg;
           struct grouptask *ifi_task;
           void *ifi_ctx;
   } *iflib_filter_info_t;
   
   struct iflib_ctx {
           KOBJ_FIELDS;
           /*
            * Pointer to hardware driver's softc
            */
           void *ifc_softc;
           device_t ifc_dev;
           if_t ifc_ifp;
   
           cpuset_t ifc_cpus;
           if_shared_ctx_t ifc_sctx;
           struct if_softc_ctx ifc_softc_ctx;
   
           struct sx ifc_ctx_sx;
           struct mtx ifc_state_mtx;
   
           iflib_txq_t ifc_txqs;
           iflib_rxq_t ifc_rxqs;
           uint32_t ifc_if_flags;
           uint32_t ifc_flags;
           uint32_t ifc_max_fl_buf_size;
           uint32_t ifc_rx_mbuf_sz;
   
           int ifc_link_state;
           int ifc_watchdog_events;
           struct cdev *ifc_led_dev;
           struct resource *ifc_msix_mem;
   
           struct if_irq ifc_legacy_irq;
           struct grouptask ifc_admin_task;
           struct grouptask ifc_vflr_task;
           struct iflib_filter_info ifc_filter_info;
           struct ifmedia  ifc_media;
           struct ifmedia  *ifc_mediap;
   
           struct sysctl_oid *ifc_sysctl_node;
           uint16_t ifc_sysctl_ntxqs;
           uint16_t ifc_sysctl_nrxqs;
           uint16_t ifc_sysctl_qs_eq_override;
           uint16_t ifc_sysctl_rx_budget;
           uint16_t ifc_sysctl_tx_abdicate;
           uint16_t ifc_sysctl_core_offset;
   #define CORE_OFFSET_UNSPECIFIED 0xffff
           uint8_t  ifc_sysctl_separate_txrx;
           uint8_t  ifc_sysctl_use_logical_cores;
           bool     ifc_cpus_are_physical_cores;
   
           qidx_t ifc_sysctl_ntxds[8];
           qidx_t ifc_sysctl_nrxds[8];
           struct if_txrx ifc_txrx;
   #define isc_txd_encap  ifc_txrx.ift_txd_encap
   #define isc_txd_flush  ifc_txrx.ift_txd_flush
   #define isc_txd_credits_update  ifc_txrx.ift_txd_credits_update
   #define isc_rxd_available ifc_txrx.ift_rxd_available
   #define isc_rxd_pkt_get ifc_txrx.ift_rxd_pkt_get
   #define isc_rxd_refill ifc_txrx.ift_rxd_refill
   #define isc_rxd_flush ifc_txrx.ift_rxd_flush
   #define isc_legacy_intr ifc_txrx.ift_legacy_intr
   #define isc_txq_select ifc_txrx.ift_txq_select
   #define isc_txq_select_v2 ifc_txrx.ift_txq_select_v2
           eventhandler_tag ifc_vlan_attach_event;
           eventhandler_tag ifc_vlan_detach_event;
           struct ether_addr ifc_mac;
   };
   
   void *
   iflib_get_softc(if_ctx_t ctx)
   {
   
           return (ctx->ifc_softc);
   }
   
   device_t
   iflib_get_dev(if_ctx_t ctx)
   {
   
           return (ctx->ifc_dev);
   }
   
   if_t
   iflib_get_ifp(if_ctx_t ctx)
   {
   
           return (ctx->ifc_ifp);
   }
   
   struct ifmedia *
   iflib_get_media(if_ctx_t ctx)
   {
   
           return (ctx->ifc_mediap);
   }
   
   uint32_t
   iflib_get_flags(if_ctx_t ctx)
   {
           return (ctx->ifc_flags);
   }
   
   void
   iflib_set_mac(if_ctx_t ctx, uint8_t mac[ETHER_ADDR_LEN])
   {
   
           bcopy(mac, ctx->ifc_mac.octet, ETHER_ADDR_LEN);
   }
   
   if_softc_ctx_t
   iflib_get_softc_ctx(if_ctx_t ctx)
   {
   
           return (&ctx->ifc_softc_ctx);
   }
   
   if_shared_ctx_t
   iflib_get_sctx(if_ctx_t ctx)
   {
   
           return (ctx->ifc_sctx);
   }
   
   #define IP_ALIGNED(m) ((((uintptr_t)(m)->m_data) & 0x3) == 0x2)
   #define CACHE_PTR_INCREMENT (CACHE_LINE_SIZE/sizeof(void*))
   #define CACHE_PTR_NEXT(ptr) ((void *)(((uintptr_t)(ptr)+CACHE_LINE_SIZE-1) & (CACHE_LINE_SIZE-1)))
   
   #define LINK_ACTIVE(ctx) ((ctx)->ifc_link_state == LINK_STATE_UP)
   #define CTX_IS_VF(ctx) ((ctx)->ifc_sctx->isc_flags & IFLIB_IS_VF)
   
   typedef struct iflib_sw_rx_desc_array {
           bus_dmamap_t    *ifsd_map;         /* bus_dma maps for packet */
           struct mbuf     **ifsd_m;           /* pkthdr mbufs */
           caddr_t         *ifsd_cl;          /* direct cluster pointer for rx */
           bus_addr_t      *ifsd_ba;          /* bus addr of cluster for rx */
   } iflib_rxsd_array_t;
   
   typedef struct iflib_sw_tx_desc_array {
           bus_dmamap_t    *ifsd_map;         /* bus_dma maps for packet */
           bus_dmamap_t    *ifsd_tso_map;     /* bus_dma maps for TSO packet */
           struct mbuf    **ifsd_m;           /* pkthdr mbufs */
   } if_txsd_vec_t;
   
   /* magic number that should be high enough for any hardware */
   #define IFLIB_MAX_TX_SEGS               128
   #define IFLIB_RX_COPY_THRESH            128
   #define IFLIB_MAX_RX_REFRESH            32
   /* The minimum descriptors per second before we start coalescing */
   #define IFLIB_MIN_DESC_SEC              16384
   #define IFLIB_DEFAULT_TX_UPDATE_FREQ    16
   #define IFLIB_QUEUE_IDLE                0
   #define IFLIB_QUEUE_HUNG                1
   #define IFLIB_QUEUE_WORKING             2
   /* maximum number of txqs that can share an rx interrupt */
   #define IFLIB_MAX_TX_SHARED_INTR        4
   
   /* this should really scale with ring size - this is a fairly arbitrary value */
   #define TX_BATCH_SIZE                   32
   
   #define IFLIB_RESTART_BUDGET            8
   
   #define CSUM_OFFLOAD            (CSUM_IP_TSO|CSUM_IP6_TSO|CSUM_IP| \
                                    CSUM_IP_UDP|CSUM_IP_TCP|CSUM_IP_SCTP| \
                                    CSUM_IP6_UDP|CSUM_IP6_TCP|CSUM_IP6_SCTP)
   
   struct iflib_txq {
           qidx_t          ift_in_use;
           qidx_t          ift_cidx;
           qidx_t          ift_cidx_processed;
           qidx_t          ift_pidx;
           uint8_t         ift_gen;
           uint8_t         ift_br_offset;
           uint16_t        ift_npending;
           uint16_t        ift_db_pending;
           uint16_t        ift_rs_pending;
           /* implicit pad */
           uint8_t         ift_txd_size[8];
           uint64_t        ift_processed;
           uint64_t        ift_cleaned;
           uint64_t        ift_cleaned_prev;
   #if MEMORY_LOGGING
           uint64_t        ift_enqueued;
           uint64_t        ift_dequeued;
   #endif
           uint64_t        ift_no_tx_dma_setup;
           uint64_t        ift_no_desc_avail;
           uint64_t        ift_mbuf_defrag_failed;
           uint64_t        ift_mbuf_defrag;
           uint64_t        ift_map_failed;
           uint64_t        ift_txd_encap_efbig;
           uint64_t        ift_pullups;
           uint64_t        ift_last_timer_tick;
   
           struct mtx      ift_mtx;
           struct mtx      ift_db_mtx;
   
           /* constant values */
           if_ctx_t        ift_ctx;
           struct ifmp_ring        *ift_br;
           struct grouptask        ift_task;
           qidx_t          ift_size;
           uint16_t        ift_id;
           struct callout  ift_timer;
   #ifdef DEV_NETMAP
           struct callout  ift_netmap_timer;
   #endif /* DEV_NETMAP */
   
           if_txsd_vec_t   ift_sds;
           uint8_t         ift_qstatus;
           uint8_t         ift_closed;
           uint8_t         ift_update_freq;
           struct iflib_filter_info ift_filter_info;
           bus_dma_tag_t   ift_buf_tag;
           bus_dma_tag_t   ift_tso_buf_tag;
           iflib_dma_info_t        ift_ifdi;
   #define MTX_NAME_LEN    32
           char                    ift_mtx_name[MTX_NAME_LEN];
           bus_dma_segment_t       ift_segs[IFLIB_MAX_TX_SEGS]  __aligned(CACHE_LINE_SIZE);
   #ifdef IFLIB_DIAGNOSTICS
           uint64_t ift_cpu_exec_count[256];
   #endif
   } __aligned(CACHE_LINE_SIZE);
   
   struct iflib_fl {
           qidx_t          ifl_cidx;
           qidx_t          ifl_pidx;
           qidx_t          ifl_credits;
           uint8_t         ifl_gen;
           uint8_t         ifl_rxd_size;
   #if MEMORY_LOGGING
           uint64_t        ifl_m_enqueued;
           uint64_t        ifl_m_dequeued;
           uint64_t        ifl_cl_enqueued;
           uint64_t        ifl_cl_dequeued;
   #endif
           /* implicit pad */
           bitstr_t        *ifl_rx_bitmap;
           qidx_t          ifl_fragidx;
           /* constant */
           qidx_t          ifl_size;
           uint16_t        ifl_buf_size;
           uint16_t        ifl_cltype;
           uma_zone_t      ifl_zone;
           iflib_rxsd_array_t      ifl_sds;
           iflib_rxq_t     ifl_rxq;
           uint8_t         ifl_id;
           bus_dma_tag_t   ifl_buf_tag;
           iflib_dma_info_t        ifl_ifdi;
           uint64_t        ifl_bus_addrs[IFLIB_MAX_RX_REFRESH] __aligned(CACHE_LINE_SIZE);
           qidx_t          ifl_rxd_idxs[IFLIB_MAX_RX_REFRESH];
   }  __aligned(CACHE_LINE_SIZE);
   
   static inline qidx_t
   get_inuse(int size, qidx_t cidx, qidx_t pidx, uint8_t gen)
   {
           qidx_t used;
   
           if (pidx > cidx)
                   used = pidx - cidx;
           else if (pidx < cidx)
                   used = size - cidx + pidx;
           else if (gen == 0 && pidx == cidx)
                   used = 0;
           else if (gen == 1 && pidx == cidx)
                   used = size;
           else
                   panic("bad state");
   
           return (used);
   }
   
   #define TXQ_AVAIL(txq) (txq->ift_size - get_inuse(txq->ift_size, txq->ift_cidx, txq->ift_pidx, txq->ift_gen))
   
   #define IDXDIFF(head, tail, wrap) \
           ((head) >= (tail) ? (head) - (tail) : (wrap) - (tail) + (head))
   
   struct iflib_rxq {
           if_ctx_t        ifr_ctx;
           iflib_fl_t      ifr_fl;
           uint64_t        ifr_rx_irq;
           struct pfil_head        *pfil;
           /*
            * If there is a separate completion queue (IFLIB_HAS_RXCQ), this is
            * the completion queue consumer index.  Otherwise it's unused.
            */
           qidx_t          ifr_cq_cidx;
           uint16_t        ifr_id;
           uint8_t         ifr_nfl;
           uint8_t         ifr_ntxqirq;
           uint8_t         ifr_txqid[IFLIB_MAX_TX_SHARED_INTR];
           uint8_t         ifr_fl_offset;
           struct lro_ctrl                 ifr_lc;
           struct grouptask        ifr_task;
           struct callout          ifr_watchdog;
           struct iflib_filter_info ifr_filter_info;
           iflib_dma_info_t                ifr_ifdi;
   
           /* dynamically allocate if any drivers need a value substantially larger than this */
           struct if_rxd_frag      ifr_frags[IFLIB_MAX_RX_SEGS] __aligned(CACHE_LINE_SIZE);
   #ifdef IFLIB_DIAGNOSTICS
           uint64_t ifr_cpu_exec_count[256];
   #endif
   }  __aligned(CACHE_LINE_SIZE);
   
   typedef struct if_rxsd {
           caddr_t *ifsd_cl;
           iflib_fl_t ifsd_fl;
   } *if_rxsd_t;
   
   /* multiple of word size */
   #ifdef __LP64__
   #define PKT_INFO_SIZE   6
   #define RXD_INFO_SIZE   5
   #define PKT_TYPE uint64_t
   #else
   #define PKT_INFO_SIZE   11
   #define RXD_INFO_SIZE   8
   #define PKT_TYPE uint32_t
   #endif
   #define PKT_LOOP_BOUND  ((PKT_INFO_SIZE/3)*3)
   #define RXD_LOOP_BOUND  ((RXD_INFO_SIZE/4)*4)
   
   typedef struct if_pkt_info_pad {
           PKT_TYPE pkt_val[PKT_INFO_SIZE];
   } *if_pkt_info_pad_t;
   typedef struct if_rxd_info_pad {
           PKT_TYPE rxd_val[RXD_INFO_SIZE];
   } *if_rxd_info_pad_t;
   
   CTASSERT(sizeof(struct if_pkt_info_pad) == sizeof(struct if_pkt_info));
   CTASSERT(sizeof(struct if_rxd_info_pad) == sizeof(struct if_rxd_info));
   
   static inline void
   pkt_info_zero(if_pkt_info_t pi)
   {
           if_pkt_info_pad_t pi_pad;
   
           pi_pad = (if_pkt_info_pad_t)pi;
           pi_pad->pkt_val[0] = 0; pi_pad->pkt_val[1] = 0; pi_pad->pkt_val[2] = 0;
           pi_pad->pkt_val[3] = 0; pi_pad->pkt_val[4] = 0; pi_pad->pkt_val[5] = 0;
   #ifndef __LP64__
           pi_pad->pkt_val[6] = 0; pi_pad->pkt_val[7] = 0; pi_pad->pkt_val[8] = 0;
           pi_pad->pkt_val[9] = 0; pi_pad->pkt_val[10] = 0;
   #endif  
   }
   
   static device_method_t iflib_pseudo_methods[] = {
           DEVMETHOD(device_attach, noop_attach),
           DEVMETHOD(device_detach, iflib_pseudo_detach),
           DEVMETHOD_END
   };
   
   driver_t iflib_pseudodriver = {
           "iflib_pseudo", iflib_pseudo_methods, sizeof(struct iflib_ctx),
   };
   
   static inline void
   rxd_info_zero(if_rxd_info_t ri)
   {
           if_rxd_info_pad_t ri_pad;
           int i;
   
           ri_pad = (if_rxd_info_pad_t)ri;
           for (i = 0; i < RXD_LOOP_BOUND; i += 4) {
                   ri_pad->rxd_val[i] = 0;
                   ri_pad->rxd_val[i+1] = 0;
                   ri_pad->rxd_val[i+2] = 0;
                   ri_pad->rxd_val[i+3] = 0;
           }
   #ifdef __LP64__
           ri_pad->rxd_val[RXD_INFO_SIZE-1] = 0;
   #endif
   }
   
   /*
    * Only allow a single packet to take up most 1/nth of the tx ring
    */
   #define MAX_SINGLE_PACKET_FRACTION 12
   #define IF_BAD_DMA (bus_addr_t)-1
   
   #define CTX_ACTIVE(ctx) ((if_getdrvflags((ctx)->ifc_ifp) & IFF_DRV_RUNNING))
   
   #define CTX_LOCK_INIT(_sc)  sx_init(&(_sc)->ifc_ctx_sx, "iflib ctx lock")
   #define CTX_LOCK(ctx) sx_xlock(&(ctx)->ifc_ctx_sx)
   #define CTX_UNLOCK(ctx) sx_xunlock(&(ctx)->ifc_ctx_sx)
   #define CTX_LOCK_DESTROY(ctx) sx_destroy(&(ctx)->ifc_ctx_sx)
   
   #define STATE_LOCK_INIT(_sc, _name)  mtx_init(&(_sc)->ifc_state_mtx, _name, "iflib state lock", MTX_DEF)
   #define STATE_LOCK(ctx) mtx_lock(&(ctx)->ifc_state_mtx)
   #define STATE_UNLOCK(ctx) mtx_unlock(&(ctx)->ifc_state_mtx)
   #define STATE_LOCK_DESTROY(ctx) mtx_destroy(&(ctx)->ifc_state_mtx)
   
   #define CALLOUT_LOCK(txq)       mtx_lock(&txq->ift_mtx)
   #define CALLOUT_UNLOCK(txq)     mtx_unlock(&txq->ift_mtx)
   
   void
   iflib_set_detach(if_ctx_t ctx)
   {
           STATE_LOCK(ctx);
           ctx->ifc_flags |= IFC_IN_DETACH;
           STATE_UNLOCK(ctx);
   }
   
   /* Our boot-time initialization hook */
   static int      iflib_module_event_handler(module_t, int, void *);
   
   static moduledata_t iflib_moduledata = {
           "iflib",
           iflib_module_event_handler,
           NULL
   };
   
   DECLARE_MODULE(iflib, iflib_moduledata, SI_SUB_INIT_IF, SI_ORDER_ANY);
   MODULE_VERSION(iflib, 1);
   
   MODULE_DEPEND(iflib, pci, 1, 1, 1);
   MODULE_DEPEND(iflib, ether, 1, 1, 1);
   
   TASKQGROUP_DEFINE(if_io_tqg, mp_ncpus, 1);
   TASKQGROUP_DEFINE(if_config_tqg, 1, 1);
   
   #ifndef IFLIB_DEBUG_COUNTERS
   #ifdef INVARIANTS
   #define IFLIB_DEBUG_COUNTERS 1
   #else
   #define IFLIB_DEBUG_COUNTERS 0
   #endif /* !INVARIANTS */
   #endif
   
   static SYSCTL_NODE(_net, OID_AUTO, iflib, CTLFLAG_RD | CTLFLAG_MPSAFE, 0,
       "iflib driver parameters");
   
   /*
    * XXX need to ensure that this can't accidentally cause the head to be moved backwards 
    */
   static int iflib_min_tx_latency = 0;
   SYSCTL_INT(_net_iflib, OID_AUTO, min_tx_latency, CTLFLAG_RW,
                      &iflib_min_tx_latency, 0, "minimize transmit latency at the possible expense of throughput");
   static int iflib_no_tx_batch = 0;
   SYSCTL_INT(_net_iflib, OID_AUTO, no_tx_batch, CTLFLAG_RW,
                      &iflib_no_tx_batch, 0, "minimize transmit latency at the possible expense of throughput");
   static int iflib_timer_default = 1000;
   SYSCTL_INT(_net_iflib, OID_AUTO, timer_default, CTLFLAG_RW,
                      &iflib_timer_default, 0, "number of ticks between iflib_timer calls");
   
   
   #if IFLIB_DEBUG_COUNTERS
   
   static int iflib_tx_seen;
   static int iflib_tx_sent;
   static int iflib_tx_encap;
   static int iflib_rx_allocs;
   static int iflib_fl_refills;
   static int iflib_fl_refills_large;
   static int iflib_tx_frees;
   
   SYSCTL_INT(_net_iflib, OID_AUTO, tx_seen, CTLFLAG_RD,
                      &iflib_tx_seen, 0, "# TX mbufs seen");
   SYSCTL_INT(_net_iflib, OID_AUTO, tx_sent, CTLFLAG_RD,
                      &iflib_tx_sent, 0, "# TX mbufs sent");
   SYSCTL_INT(_net_iflib, OID_AUTO, tx_encap, CTLFLAG_RD,
                      &iflib_tx_encap, 0, "# TX mbufs encapped");
   SYSCTL_INT(_net_iflib, OID_AUTO, tx_frees, CTLFLAG_RD,
                      &iflib_tx_frees, 0, "# TX frees");
   SYSCTL_INT(_net_iflib, OID_AUTO, rx_allocs, CTLFLAG_RD,
                      &iflib_rx_allocs, 0, "# RX allocations");
   SYSCTL_INT(_net_iflib, OID_AUTO, fl_refills, CTLFLAG_RD,
                      &iflib_fl_refills, 0, "# refills");
   SYSCTL_INT(_net_iflib, OID_AUTO, fl_refills_large, CTLFLAG_RD,
                      &iflib_fl_refills_large, 0, "# large refills");
   
   static int iflib_txq_drain_flushing;
   static int iflib_txq_drain_oactive;
   static int iflib_txq_drain_notready;
   
   SYSCTL_INT(_net_iflib, OID_AUTO, txq_drain_flushing, CTLFLAG_RD,
                      &iflib_txq_drain_flushing, 0, "# drain flushes");
   SYSCTL_INT(_net_iflib, OID_AUTO, txq_drain_oactive, CTLFLAG_RD,
                      &iflib_txq_drain_oactive, 0, "# drain oactives");
   SYSCTL_INT(_net_iflib, OID_AUTO, txq_drain_notready, CTLFLAG_RD,
                      &iflib_txq_drain_notready, 0, "# drain notready");
   
   static int iflib_encap_load_mbuf_fail;
   static int iflib_encap_pad_mbuf_fail;
   static int iflib_encap_txq_avail_fail;
   static int iflib_encap_txd_encap_fail;
   
   SYSCTL_INT(_net_iflib, OID_AUTO, encap_load_mbuf_fail, CTLFLAG_RD,
                      &iflib_encap_load_mbuf_fail, 0, "# busdma load failures");
   SYSCTL_INT(_net_iflib, OID_AUTO, encap_pad_mbuf_fail, CTLFLAG_RD,
                      &iflib_encap_pad_mbuf_fail, 0, "# runt frame pad failures");
   SYSCTL_INT(_net_iflib, OID_AUTO, encap_txq_avail_fail, CTLFLAG_RD,
                      &iflib_encap_txq_avail_fail, 0, "# txq avail failures");
   SYSCTL_INT(_net_iflib, OID_AUTO, encap_txd_encap_fail, CTLFLAG_RD,
                      &iflib_encap_txd_encap_fail, 0, "# driver encap failures");
   
   static int iflib_task_fn_rxs;
   static int iflib_rx_intr_enables;
   static int iflib_fast_intrs;
   static int iflib_rx_unavail;
   static int iflib_rx_ctx_inactive;
   static int iflib_rx_if_input;
   static int iflib_rxd_flush;
   
   static int iflib_verbose_debug;
   
   SYSCTL_INT(_net_iflib, OID_AUTO, task_fn_rx, CTLFLAG_RD,
                      &iflib_task_fn_rxs, 0, "# task_fn_rx calls");
   SYSCTL_INT(_net_iflib, OID_AUTO, rx_intr_enables, CTLFLAG_RD,
                      &iflib_rx_intr_enables, 0, "# RX intr enables");
   SYSCTL_INT(_net_iflib, OID_AUTO, fast_intrs, CTLFLAG_RD,
                      &iflib_fast_intrs, 0, "# fast_intr calls");
   SYSCTL_INT(_net_iflib, OID_AUTO, rx_unavail, CTLFLAG_RD,
                      &iflib_rx_unavail, 0, "# times rxeof called with no available data");
   SYSCTL_INT(_net_iflib, OID_AUTO, rx_ctx_inactive, CTLFLAG_RD,
                      &iflib_rx_ctx_inactive, 0, "# times rxeof called with inactive context");
   SYSCTL_INT(_net_iflib, OID_AUTO, rx_if_input, CTLFLAG_RD,
                      &iflib_rx_if_input, 0, "# times rxeof called if_input");
   SYSCTL_INT(_net_iflib, OID_AUTO, rxd_flush, CTLFLAG_RD,
                    &iflib_rxd_flush, 0, "# times rxd_flush called");
   SYSCTL_INT(_net_iflib, OID_AUTO, verbose_debug, CTLFLAG_RW,
                      &iflib_verbose_debug, 0, "enable verbose debugging");
   
   #define DBG_COUNTER_INC(name) atomic_add_int(&(iflib_ ## name), 1)
   static void
   iflib_debug_reset(void)
   {
           iflib_tx_seen = iflib_tx_sent = iflib_tx_encap = iflib_rx_allocs =
                   iflib_fl_refills = iflib_fl_refills_large = iflib_tx_frees =
                   iflib_txq_drain_flushing = iflib_txq_drain_oactive =
                   iflib_txq_drain_notready =
                   iflib_encap_load_mbuf_fail = iflib_encap_pad_mbuf_fail =
                   iflib_encap_txq_avail_fail = iflib_encap_txd_encap_fail =
                   iflib_task_fn_rxs = iflib_rx_intr_enables = iflib_fast_intrs =
                   iflib_rx_unavail =
                   iflib_rx_ctx_inactive = iflib_rx_if_input =
                   iflib_rxd_flush = 0;
   }
   
   #else
   #define DBG_COUNTER_INC(name)
   static void iflib_debug_reset(void) {}
   #endif
   
   #define IFLIB_DEBUG 0
   
   static void iflib_tx_structures_free(if_ctx_t ctx);
   static void iflib_rx_structures_free(if_ctx_t ctx);
   static int iflib_queues_alloc(if_ctx_t ctx);
   static int iflib_tx_credits_update(if_ctx_t ctx, iflib_txq_t txq);
   static int iflib_rxd_avail(if_ctx_t ctx, iflib_rxq_t rxq, qidx_t cidx, qidx_t budget);
   static int iflib_qset_structures_setup(if_ctx_t ctx);
   static int iflib_msix_init(if_ctx_t ctx);
   static int iflib_legacy_setup(if_ctx_t ctx, driver_filter_t filter, void *filterarg, int *rid, const char *str);
   static void iflib_txq_check_drain(iflib_txq_t txq, int budget);
   static uint32_t iflib_txq_can_drain(struct ifmp_ring *);
   #ifdef ALTQ
   static void iflib_altq_if_start(if_t ifp);
   static int iflib_altq_if_transmit(if_t ifp, struct mbuf *m);
   #endif
   static int iflib_register(if_ctx_t);
   static void iflib_deregister(if_ctx_t);
   static void iflib_unregister_vlan_handlers(if_ctx_t ctx);
   static uint16_t iflib_get_mbuf_size_for(unsigned int size);
   static void iflib_init_locked(if_ctx_t ctx);
   static void iflib_add_device_sysctl_pre(if_ctx_t ctx);
   static void iflib_add_device_sysctl_post(if_ctx_t ctx);
   static void iflib_ifmp_purge(iflib_txq_t txq);
   static void _iflib_pre_assert(if_softc_ctx_t scctx);
   static void iflib_if_init_locked(if_ctx_t ctx);
   static void iflib_free_intr_mem(if_ctx_t ctx);
   #ifndef __NO_STRICT_ALIGNMENT
   static struct mbuf * iflib_fixup_rx(struct mbuf *m);
   #endif
   
   static SLIST_HEAD(cpu_offset_list, cpu_offset) cpu_offsets =
       SLIST_HEAD_INITIALIZER(cpu_offsets);
   struct cpu_offset {
           SLIST_ENTRY(cpu_offset) entries;
           cpuset_t        set;
           unsigned int    refcount;
           uint16_t        next_cpuid;
   };
   static struct mtx cpu_offset_mtx;
   MTX_SYSINIT(iflib_cpu_offset, &cpu_offset_mtx, "iflib_cpu_offset lock",
       MTX_DEF);
   
   DEBUGNET_DEFINE(iflib);
   
   static int
   iflib_num_rx_descs(if_ctx_t ctx)
   {
           if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
           if_shared_ctx_t sctx = ctx->ifc_sctx;
           uint16_t first_rxq = (sctx->isc_flags & IFLIB_HAS_RXCQ) ? 1 : 0;
   
           return scctx->isc_nrxd[first_rxq];
   }
   
   static int
   iflib_num_tx_descs(if_ctx_t ctx)
   {
           if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
           if_shared_ctx_t sctx = ctx->ifc_sctx;
           uint16_t first_txq = (sctx->isc_flags & IFLIB_HAS_TXCQ) ? 1 : 0;
   
           return scctx->isc_ntxd[first_txq];
   }
   
   #ifdef DEV_NETMAP
   #include <sys/selinfo.h>
   #include <net/netmap.h>
   #include <dev/netmap/netmap_kern.h>
   
   MODULE_DEPEND(iflib, netmap, 1, 1, 1);
   
   static int netmap_fl_refill(iflib_rxq_t rxq, struct netmap_kring *kring, bool init);
   static void iflib_netmap_timer(void *arg);
   
   /*
    * device-specific sysctl variables:
    *
    * iflib_crcstrip: 0: keep CRC in rx frames (default), 1: strip it.
    *      During regular operations the CRC is stripped, but on some
    *      hardware reception of frames not multiple of 64 is slower,
    *      so using crcstrip=0 helps in benchmarks.
    *
    * iflib_rx_miss, iflib_rx_miss_bufs:
    *      count packets that might be missed due to lost interrupts.
    */
   SYSCTL_DECL(_dev_netmap);
   /*
    * The xl driver by default strips CRCs and we do not override it.
    */
   
   int iflib_crcstrip = 1;
   SYSCTL_INT(_dev_netmap, OID_AUTO, iflib_crcstrip,
       CTLFLAG_RW, &iflib_crcstrip, 1, "strip CRC on RX frames");
   
   int iflib_rx_miss, iflib_rx_miss_bufs;
   SYSCTL_INT(_dev_netmap, OID_AUTO, iflib_rx_miss,
       CTLFLAG_RW, &iflib_rx_miss, 0, "potentially missed RX intr");
   SYSCTL_INT(_dev_netmap, OID_AUTO, iflib_rx_miss_bufs,
       CTLFLAG_RW, &iflib_rx_miss_bufs, 0, "potentially missed RX intr bufs");
   
   /*
    * Register/unregister. We are already under netmap lock.
    * Only called on the first register or the last unregister.
    */
   static int
   iflib_netmap_register(struct netmap_adapter *na, int onoff)
   {
           if_t ifp = na->ifp;
           if_ctx_t ctx = if_getsoftc(ifp);
           int status;
   
           CTX_LOCK(ctx);
           if (!CTX_IS_VF(ctx))
                   IFDI_CRCSTRIP_SET(ctx, onoff, iflib_crcstrip);
   
           iflib_stop(ctx);
   
           /*
            * Enable (or disable) netmap flags, and intercept (or restore)
            * ifp->if_transmit. This is done once the device has been stopped
            * to prevent race conditions. Also, this must be done after
            * calling netmap_disable_all_rings() and before calling
            * netmap_enable_all_rings(), so that these two functions see the
            * updated state of the NAF_NETMAP_ON bit.
            */
           if (onoff) {
                   nm_set_native_flags(na);
           } else {
                   nm_clear_native_flags(na);
           }
   
           iflib_init_locked(ctx);
           IFDI_CRCSTRIP_SET(ctx, onoff, iflib_crcstrip); // XXX why twice ?
           status = if_getdrvflags(ifp) & IFF_DRV_RUNNING ? 0 : 1;
           if (status)
                   nm_clear_native_flags(na);
           CTX_UNLOCK(ctx);
           return (status);
   }
   
   static int
   iflib_netmap_config(struct netmap_adapter *na, struct nm_config_info *info)
   {
           if_t ifp = na->ifp;
           if_ctx_t ctx = if_getsoftc(ifp);
           iflib_rxq_t rxq = &ctx->ifc_rxqs[0];
           iflib_fl_t fl = &rxq->ifr_fl[0];
   
           info->num_tx_rings = ctx->ifc_softc_ctx.isc_ntxqsets;
           info->num_rx_rings = ctx->ifc_softc_ctx.isc_nrxqsets;
           info->num_tx_descs = iflib_num_tx_descs(ctx);
           info->num_rx_descs = iflib_num_rx_descs(ctx);
           info->rx_buf_maxsize = fl->ifl_buf_size;
           nm_prinf("txr %u rxr %u txd %u rxd %u rbufsz %u",
                   info->num_tx_rings, info->num_rx_rings, info->num_tx_descs,
                   info->num_rx_descs, info->rx_buf_maxsize);
   
           return 0;
   }
   
   static int
   netmap_fl_refill(iflib_rxq_t rxq, struct netmap_kring *kring, bool init)
   {
           struct netmap_adapter *na = kring->na;
           u_int const lim = kring->nkr_num_slots - 1;
           struct netmap_ring *ring = kring->ring;
           bus_dmamap_t *map;
           struct if_rxd_update iru;
           if_ctx_t ctx = rxq->ifr_ctx;
           iflib_fl_t fl = &rxq->ifr_fl[0];
           u_int nic_i_first, nic_i;
           u_int nm_i;
           int i, n;
   #if IFLIB_DEBUG_COUNTERS
           int rf_count = 0;
   #endif
   
           /*
            * This function is used both at initialization and in rxsync.
            * At initialization we need to prepare (with isc_rxd_refill())
            * all the netmap buffers currently owned by the kernel, in
            * such a way to keep fl->ifl_pidx and kring->nr_hwcur in sync
            * (except for kring->nkr_hwofs). These may be less than
            * kring->nkr_num_slots if netmap_reset() was called while
            * an application using the kring that still owned some
            * buffers.
            * At rxsync time, both indexes point to the next buffer to be
            * refilled.
            * In any case we publish (with isc_rxd_flush()) up to
            * (fl->ifl_pidx - 1) % N (included), to avoid the NIC tail/prod
            * pointer to overrun the head/cons pointer, although this is
            * not necessary for some NICs (e.g. vmx).
            */
           if (__predict_false(init)) {
                   n = kring->nkr_num_slots - nm_kr_rxspace(kring);
           } else {
                   n = kring->rhead - kring->nr_hwcur;
                   if (n == 0)
                           return (0); /* Nothing to do. */
                   if (n < 0)
                           n += kring->nkr_num_slots;
           }
   
           iru_init(&iru, rxq, 0 /* flid */);
           map = fl->ifl_sds.ifsd_map;
           nic_i = fl->ifl_pidx;
           nm_i = netmap_idx_n2k(kring, nic_i);
           if (__predict_false(init)) {
                   /*
                    * On init/reset, nic_i must be 0, and we must
                    * start to refill from hwtail (see netmap_reset()).
                    */
                   MPASS(nic_i == 0);
                   MPASS(nm_i == kring->nr_hwtail);
           } else
                   MPASS(nm_i == kring->nr_hwcur);
           DBG_COUNTER_INC(fl_refills);
           while (n > 0) {
   #if IFLIB_DEBUG_COUNTERS
                   if (++rf_count == 9)
                           DBG_COUNTER_INC(fl_refills_large);
   #endif
                   nic_i_first = nic_i;
                   for (i = 0; n > 0 && i < IFLIB_MAX_RX_REFRESH; n--, i++) {
                           struct netmap_slot *slot = &ring->slot[nm_i];
                           uint64_t paddr;
                           void *addr = PNMB(na, slot, &paddr);
   
                           MPASS(i < IFLIB_MAX_RX_REFRESH);
   
                           if (addr == NETMAP_BUF_BASE(na)) /* bad buf */
                                   return netmap_ring_reinit(kring);
   
                           fl->ifl_bus_addrs[i] = paddr +
                               nm_get_offset(kring, slot);
                           fl->ifl_rxd_idxs[i] = nic_i;
   
                           if (__predict_false(init)) {
                                   netmap_load_map(na, fl->ifl_buf_tag,
                                       map[nic_i], addr);
                           } else if (slot->flags & NS_BUF_CHANGED) {
                                   /* buffer has changed, reload map */
                                   netmap_reload_map(na, fl->ifl_buf_tag,
                                       map[nic_i], addr);
                           }
                           bus_dmamap_sync(fl->ifl_buf_tag, map[nic_i],
                               BUS_DMASYNC_PREREAD);
                           slot->flags &= ~NS_BUF_CHANGED;
   
                           nm_i = nm_next(nm_i, lim);
                           nic_i = nm_next(nic_i, lim);
                   }
   
                   iru.iru_pidx = nic_i_first;
                   iru.iru_count = i;
                   ctx->isc_rxd_refill(ctx->ifc_softc, &iru);
           }
           fl->ifl_pidx = nic_i;
           /*
            * At the end of the loop we must have refilled everything
            * we could possibly refill.
            */
           MPASS(nm_i == kring->rhead);
           kring->nr_hwcur = nm_i;
   
           bus_dmamap_sync(fl->ifl_ifdi->idi_tag, fl->ifl_ifdi->idi_map,
               BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
           ctx->isc_rxd_flush(ctx->ifc_softc, rxq->ifr_id, fl->ifl_id,
               nm_prev(nic_i, lim));
           DBG_COUNTER_INC(rxd_flush);
   
           return (0);
   }
   
   #define NETMAP_TX_TIMER_US      90
   
   /*
    * Reconcile kernel and user view of the transmit ring.
    *
    * All information is in the kring.
    * Userspace wants to send packets up to the one before kring->rhead,
    * kernel knows kring->nr_hwcur is the first unsent packet.
    *
    * Here we push packets out (as many as possible), and possibly
    * reclaim buffers from previously completed transmission.
    *
    * The caller (netmap) guarantees that there is only one instance
    * running at any time. Any interference with other driver
    * methods should be handled by the individual drivers.
    */
   static int
   iflib_netmap_txsync(struct netmap_kring *kring, int flags)
   {
           struct netmap_adapter *na = kring->na;
           if_t ifp = na->ifp;
           struct netmap_ring *ring = kring->ring;
           u_int nm_i;     /* index into the netmap kring */
           u_int nic_i;    /* index into the NIC ring */
           u_int const lim = kring->nkr_num_slots - 1;
           u_int const head = kring->rhead;
           struct if_pkt_info pi;
           int tx_pkts = 0, tx_bytes = 0;
   
          /*
           * interrupts on every tx packet are expensive so request
           * them every half ring, or where NS_REPORT is set
           */
          u_int report_frequency = kring->nkr_num_slots >> 1;
          /* device-specific */
          if_ctx_t ctx = if_getsoftc(ifp);
          iflib_txq_t txq = &ctx->ifc_txqs[kring->ring_id];
  
          bus_dmamap_sync(txq->ift_ifdi->idi_tag, txq->ift_ifdi->idi_map,
              BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE);
  
          /*
           * First part: process new packets to send.
           * nm_i is the current index in the netmap kring,
           * nic_i is the corresponding index in the NIC ring.
           *
           * If we have packets to send (nm_i != head)
           * iterate over the netmap ring, fetch length and update
           * the corresponding slot in the NIC ring. Some drivers also
           * need to update the buffer's physical address in the NIC slot
           * even NS_BUF_CHANGED is not set (PNMB computes the addresses).
           *
           * The netmap_reload_map() calls is especially expensive,
           * even when (as in this case) the tag is 0, so do only
           * when the buffer has actually changed.
           *
           * If possible do not set the report/intr bit on all slots,
           * but only a few times per ring or when NS_REPORT is set.
           *
           * Finally, on 10G and faster drivers, it might be useful
           * to prefetch the next slot and txr entry.
           */
  
          nm_i = kring->nr_hwcur;
          if (nm_i != head) {     /* we have new packets to send */
                  uint32_t pkt_len = 0, seg_idx = 0;
                  int nic_i_start = -1, flags = 0;
                  pkt_info_zero(&pi);
                  pi.ipi_segs = txq->ift_segs;
                  pi.ipi_qsidx = kring->ring_id;
                  nic_i = netmap_idx_k2n(kring, nm_i);
  
                  __builtin_prefetch(&ring->slot[nm_i]);
                  __builtin_prefetch(&txq->ift_sds.ifsd_m[nic_i]);
                  __builtin_prefetch(&txq->ift_sds.ifsd_map[nic_i]);
  
                  while (nm_i != head) {
                          struct netmap_slot *slot = &ring->slot[nm_i];
                          uint64_t offset = nm_get_offset(kring, slot);
                          u_int len = slot->len;
                          uint64_t paddr;
                          void *addr = PNMB(na, slot, &paddr);
  
                          flags |= (slot->flags & NS_REPORT ||
                                  nic_i == 0 || nic_i == report_frequency) ?
                                  IPI_TX_INTR : 0;
  
                          /*
                           * If this is the first packet fragment, save the
                           * index of the first NIC slot for later.
                           */
                          if (nic_i_start < 0)
                                  nic_i_start = nic_i;
  
                          pi.ipi_segs[seg_idx].ds_addr = paddr + offset;
                          pi.ipi_segs[seg_idx].ds_len = len;
                          if (len) {
                                  pkt_len += len;
                                  seg_idx++;
                          }
  
                          if (!(slot->flags & NS_MOREFRAG)) {
                                  pi.ipi_len = pkt_len;
                                  pi.ipi_nsegs = seg_idx;
                                  pi.ipi_pidx = nic_i_start;
                                  pi.ipi_ndescs = 0;
                                  pi.ipi_flags = flags;
  
                                  /* Prepare the NIC TX ring. */
                                  ctx->isc_txd_encap(ctx->ifc_softc, &pi);
                                  DBG_COUNTER_INC(tx_encap);
  
                                  /* Update transmit counters */
                                  tx_bytes += pi.ipi_len;
                                  tx_pkts++;
  
                                  /* Reinit per-packet info for the next one. */
                                  flags = seg_idx = pkt_len = 0;
                                  nic_i_start = -1;
                          }
  
                          /* prefetch for next round */
                          __builtin_prefetch(&ring->slot[nm_i + 1]);
                          __builtin_prefetch(&txq->ift_sds.ifsd_m[nic_i + 1]);
                          __builtin_prefetch(&txq->ift_sds.ifsd_map[nic_i + 1]);
  
                          NM_CHECK_ADDR_LEN_OFF(na, len, offset);
  
                          if (slot->flags & NS_BUF_CHANGED) {
                                  /* buffer has changed, reload map */
                                  netmap_reload_map(na, txq->ift_buf_tag,
                                      txq->ift_sds.ifsd_map[nic_i], addr);
                          }
                          /* make sure changes to the buffer are synced */
                          bus_dmamap_sync(txq->ift_buf_tag,
                              txq->ift_sds.ifsd_map[nic_i],
                              BUS_DMASYNC_PREWRITE);
  
                          slot->flags &= ~(NS_REPORT | NS_BUF_CHANGED | NS_MOREFRAG);
                          nm_i = nm_next(nm_i, lim);
                          nic_i = nm_next(nic_i, lim);
                  }
                  kring->nr_hwcur = nm_i;
  
                  /* synchronize the NIC ring */
                  bus_dmamap_sync(txq->ift_ifdi->idi_tag, txq->ift_ifdi->idi_map,
                      BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
  
                  /* (re)start the tx unit up to slot nic_i (excluded) */
                  ctx->isc_txd_flush(ctx->ifc_softc, txq->ift_id, nic_i);
          }
  
          /*
           * Second part: reclaim buffers for completed transmissions.
           *
           * If there are unclaimed buffers, attempt to reclaim them.
           * If we don't manage to reclaim them all, and TX IRQs are not in use,
           * trigger a per-tx-queue timer to try again later.
           */
          if (kring->nr_hwtail != nm_prev(kring->nr_hwcur, lim)) {
                  if (iflib_tx_credits_update(ctx, txq)) {
                          /* some tx completed, increment avail */
                          nic_i = txq->ift_cidx_processed;
                          kring->nr_hwtail = nm_prev(netmap_idx_n2k(kring, nic_i), lim);
                  }
          }
  
          if (!(ctx->ifc_flags & IFC_NETMAP_TX_IRQ))
                  if (kring->nr_hwtail != nm_prev(kring->nr_hwcur, lim)) {
                          callout_reset_sbt_on(&txq->ift_netmap_timer,
                              NETMAP_TX_TIMER_US * SBT_1US, SBT_1US,
                              iflib_netmap_timer, txq,
                              txq->ift_netmap_timer.c_cpu, 0);
                  }
  
          if_inc_counter(ifp, IFCOUNTER_OBYTES, tx_bytes);
          if_inc_counter(ifp, IFCOUNTER_OPACKETS, tx_pkts);
  
          return (0);
  }
  
  /*
   * Reconcile kernel and user view of the receive ring.
   * Same as for the txsync, this routine must be efficient.
   * The caller guarantees a single invocations, but races against
   * the rest of the driver should be handled here.
   *
   * On call, kring->rhead is the first packet that userspace wants
   * to keep, and kring->rcur is the wakeup point.
   * The kernel has previously reported packets up to kring->rtail.
   *
   * If (flags & NAF_FORCE_READ) also check for incoming packets irrespective
   * of whether or not we received an interrupt.
   */
  static int
  iflib_netmap_rxsync(struct netmap_kring *kring, int flags)
  {
          struct netmap_adapter *na = kring->na;
          struct netmap_ring *ring = kring->ring;
          if_t ifp = na->ifp;
          uint32_t nm_i;  /* index into the netmap ring */
          uint32_t nic_i; /* index into the NIC ring */
          u_int n;
          u_int const lim = kring->nkr_num_slots - 1;
          int force_update = (flags & NAF_FORCE_READ) || kring->nr_kflags & NKR_PENDINTR;
          int i = 0, rx_bytes = 0, rx_pkts = 0;
  
          if_ctx_t ctx = if_getsoftc(ifp);
          if_shared_ctx_t sctx = ctx->ifc_sctx;
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          iflib_rxq_t rxq = &ctx->ifc_rxqs[kring->ring_id];
          iflib_fl_t fl = &rxq->ifr_fl[0];
          struct if_rxd_info ri;
          qidx_t *cidxp;
  
          /*
           * netmap only uses free list 0, to avoid out of order consumption
           * of receive buffers
           */
  
          bus_dmamap_sync(fl->ifl_ifdi->idi_tag, fl->ifl_ifdi->idi_map,
              BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE);
  
          /*
           * First part: import newly received packets.
           *
           * nm_i is the index of the next free slot in the netmap ring,
           * nic_i is the index of the next received packet in the NIC ring
           * (or in the free list 0 if IFLIB_HAS_RXCQ is set), and they may
           * differ in case if_init() has been called while
           * in netmap mode. For the receive ring we have
           *
           *      nic_i = fl->ifl_cidx;
           *      nm_i = kring->nr_hwtail (previous)
           * and
           *      nm_i == (nic_i + kring->nkr_hwofs) % ring_size
           *
           * fl->ifl_cidx is set to 0 on a ring reinit
           */
          if (netmap_no_pendintr || force_update) {
                  uint32_t hwtail_lim = nm_prev(kring->nr_hwcur, lim);
                  bool have_rxcq = sctx->isc_flags & IFLIB_HAS_RXCQ;
                  int crclen = iflib_crcstrip ? 0 : 4;
                  int error, avail;
  
                  /*
                   * For the free list consumer index, we use the same
                   * logic as in iflib_rxeof().
                   */
                  if (have_rxcq)
                          cidxp = &rxq->ifr_cq_cidx;
                  else
                          cidxp = &fl->ifl_cidx;
                  avail = ctx->isc_rxd_available(ctx->ifc_softc,
                      rxq->ifr_id, *cidxp, USHRT_MAX);
  
                  nic_i = fl->ifl_cidx;
                  nm_i = netmap_idx_n2k(kring, nic_i);
                  MPASS(nm_i == kring->nr_hwtail);
                  for (n = 0; avail > 0 && nm_i != hwtail_lim; n++, avail--) {
                          rxd_info_zero(&ri);
                          ri.iri_frags = rxq->ifr_frags;
                          ri.iri_qsidx = kring->ring_id;
                          ri.iri_ifp = ctx->ifc_ifp;
                          ri.iri_cidx = *cidxp;
  
                          error = ctx->isc_rxd_pkt_get(ctx->ifc_softc, &ri);
                          for (i = 0; i < ri.iri_nfrags; i++) {
                                  if (error) {
                                          ring->slot[nm_i].len = 0;
                                          ring->slot[nm_i].flags = 0;
                                  } else {
                                          ring->slot[nm_i].len = ri.iri_frags[i].irf_len;
                                          if (i == (ri.iri_nfrags - 1)) {
                                                  ring->slot[nm_i].len -= crclen;
                                                  ring->slot[nm_i].flags = 0;
  
                                                  /* Update receive counters */
                                                  rx_bytes += ri.iri_len;
                                                  rx_pkts++;
                                          } else
                                                  ring->slot[nm_i].flags = NS_MOREFRAG;
                                  }
  
                                  bus_dmamap_sync(fl->ifl_buf_tag,
                                      fl->ifl_sds.ifsd_map[nic_i], BUS_DMASYNC_POSTREAD);
                                  nm_i = nm_next(nm_i, lim);
                                  fl->ifl_cidx = nic_i = nm_next(nic_i, lim);
                          }
  
                          if (have_rxcq) {
                                  *cidxp = ri.iri_cidx;
                                  while (*cidxp >= scctx->isc_nrxd[0])
                                          *cidxp -= scctx->isc_nrxd[0];
                          }
  
                  }
                  if (n) { /* update the state variables */
                          if (netmap_no_pendintr && !force_update) {
                                  /* diagnostics */
                                  iflib_rx_miss ++;
                                  iflib_rx_miss_bufs += n;
                          }
                          kring->nr_hwtail = nm_i;
                  }
                  kring->nr_kflags &= ~NKR_PENDINTR;
          }
          /*
           * Second part: skip past packets that userspace has released.
           * (kring->nr_hwcur to head excluded),
           * and make the buffers available for reception.
           * As usual nm_i is the index in the netmap ring,
           * nic_i is the index in the NIC ring, and
           * nm_i == (nic_i + kring->nkr_hwofs) % ring_size
           */
          netmap_fl_refill(rxq, kring, false);
  
          if_inc_counter(ifp, IFCOUNTER_IBYTES, rx_bytes);
          if_inc_counter(ifp, IFCOUNTER_IPACKETS, rx_pkts);
  
          return (0);
  }
  
  static void
  iflib_netmap_intr(struct netmap_adapter *na, int onoff)
  {
          if_ctx_t ctx = if_getsoftc(na->ifp);
  
          CTX_LOCK(ctx);
          if (onoff) {
                  IFDI_INTR_ENABLE(ctx);
          } else {
                  IFDI_INTR_DISABLE(ctx);
          }
          CTX_UNLOCK(ctx);
  }
  
  static int
  iflib_netmap_attach(if_ctx_t ctx)
  {
          struct netmap_adapter na;
  
          bzero(&na, sizeof(na));
  
          na.ifp = ctx->ifc_ifp;
          na.na_flags = NAF_BDG_MAYSLEEP | NAF_MOREFRAG | NAF_OFFSETS;
          MPASS(ctx->ifc_softc_ctx.isc_ntxqsets);
          MPASS(ctx->ifc_softc_ctx.isc_nrxqsets);
  
          na.num_tx_desc = iflib_num_tx_descs(ctx);
          na.num_rx_desc = iflib_num_rx_descs(ctx);
          na.nm_txsync = iflib_netmap_txsync;
          na.nm_rxsync = iflib_netmap_rxsync;
          na.nm_register = iflib_netmap_register;
          na.nm_intr = iflib_netmap_intr;
          na.nm_config = iflib_netmap_config;
          na.num_tx_rings = ctx->ifc_softc_ctx.isc_ntxqsets;
          na.num_rx_rings = ctx->ifc_softc_ctx.isc_nrxqsets;
          return (netmap_attach(&na));
  }
  
  static int
  iflib_netmap_txq_init(if_ctx_t ctx, iflib_txq_t txq)
  {
          struct netmap_adapter *na = NA(ctx->ifc_ifp);
          struct netmap_slot *slot;
  
          slot = netmap_reset(na, NR_TX, txq->ift_id, 0);
          if (slot == NULL)
                  return (0);
          for (int i = 0; i < ctx->ifc_softc_ctx.isc_ntxd[0]; i++) {
                  /*
                   * In netmap mode, set the map for the packet buffer.
                   * NOTE: Some drivers (not this one) also need to set
                   * the physical buffer address in the NIC ring.
                   * netmap_idx_n2k() maps a nic index, i, into the corresponding
                   * netmap slot index, si
                   */
                  int si = netmap_idx_n2k(na->tx_rings[txq->ift_id], i);
                  netmap_load_map(na, txq->ift_buf_tag, txq->ift_sds.ifsd_map[i],
                      NMB(na, slot + si));
          }
          return (1);
  }
  
  static int
  iflib_netmap_rxq_init(if_ctx_t ctx, iflib_rxq_t rxq)
  {
          struct netmap_adapter *na = NA(ctx->ifc_ifp);
          struct netmap_kring *kring;
          struct netmap_slot *slot;
  
          slot = netmap_reset(na, NR_RX, rxq->ifr_id, 0);
          if (slot == NULL)
                  return (0);
          kring = na->rx_rings[rxq->ifr_id];
          netmap_fl_refill(rxq, kring, true);
          return (1);
  }
  
  static void
  iflib_netmap_timer(void *arg)
  {
          iflib_txq_t txq = arg;
          if_ctx_t ctx = txq->ift_ctx;
  
          /*
           * Wake up the netmap application, to give it a chance to
           * call txsync and reclaim more completed TX buffers.
           */
          netmap_tx_irq(ctx->ifc_ifp, txq->ift_id);
  }
  
  #define iflib_netmap_detach(ifp) netmap_detach(ifp)
  
  #else
  #define iflib_netmap_txq_init(ctx, txq) (0)
  #define iflib_netmap_rxq_init(ctx, rxq) (0)
  #define iflib_netmap_detach(ifp)
  #define netmap_enable_all_rings(ifp)
  #define netmap_disable_all_rings(ifp)
  
  #define iflib_netmap_attach(ctx) (0)
  #define netmap_rx_irq(ifp, qid, budget) (0)
  #endif
  
  #if defined(__i386__) || defined(__amd64__)
  static __inline void
  prefetch(void *x)
  {
          __asm volatile("prefetcht0 %0" :: "m" (*(unsigned long *)x));
  }
  
  static __inline void
  prefetch2cachelines(void *x)
  {
          __asm volatile("prefetcht0 %0" :: "m" (*(unsigned long *)x));
  #if (CACHE_LINE_SIZE < 128)
          __asm volatile("prefetcht0 %0" :: "m" (*(((unsigned long *)x)+CACHE_LINE_SIZE/(sizeof(unsigned long)))));
  #endif
  }
  #else
  static __inline void
  prefetch(void *x)
  {
  }
  
  static __inline void
  prefetch2cachelines(void *x)
  {
  }
  #endif
  
  static void
  iru_init(if_rxd_update_t iru, iflib_rxq_t rxq, uint8_t flid)
  {
          iflib_fl_t fl;
  
          fl = &rxq->ifr_fl[flid];
          iru->iru_paddrs = fl->ifl_bus_addrs;
          iru->iru_idxs = fl->ifl_rxd_idxs;
          iru->iru_qsidx = rxq->ifr_id;
          iru->iru_buf_size = fl->ifl_buf_size;
          iru->iru_flidx = fl->ifl_id;
  }
  
  static void
  _iflib_dmamap_cb(void *arg, bus_dma_segment_t *segs, int nseg, int err)
  {
          if (err)
                  return;
          *(bus_addr_t *) arg = segs[0].ds_addr;
  }
  
  #define DMA_WIDTH_TO_BUS_LOWADDR(width)                         \
          (((width) == 0) || (width) == flsll(BUS_SPACE_MAXADDR) ?        \
              BUS_SPACE_MAXADDR : (1ULL << (width)) - 1ULL)
  
  int
  iflib_dma_alloc_align(if_ctx_t ctx, int size, int align, iflib_dma_info_t dma, int mapflags)
  {
          int err;
          device_t dev = ctx->ifc_dev;
          bus_addr_t lowaddr;
  
          lowaddr = DMA_WIDTH_TO_BUS_LOWADDR(ctx->ifc_softc_ctx.isc_dma_width);
  
          err = bus_dma_tag_create(bus_get_dma_tag(dev),  /* parent */
                                  align, 0,               /* alignment, bounds */
                                  lowaddr,                /* lowaddr */
                                  BUS_SPACE_MAXADDR,      /* highaddr */
                                  NULL, NULL,             /* filter, filterarg */
                                  size,                   /* maxsize */
                                  1,                      /* nsegments */
                                  size,                   /* maxsegsize */
                                  BUS_DMA_ALLOCNOW,       /* flags */
                                  NULL,                   /* lockfunc */
                                  NULL,                   /* lockarg */
                                  &dma->idi_tag);
          if (err) {
                  device_printf(dev,
                      "%s: bus_dma_tag_create failed: %d\n",
                      __func__, err);
                  goto fail_0;
          }
  
          err = bus_dmamem_alloc(dma->idi_tag, (void**) &dma->idi_vaddr,
              BUS_DMA_NOWAIT | BUS_DMA_COHERENT | BUS_DMA_ZERO, &dma->idi_map);
          if (err) {
                  device_printf(dev,
                      "%s: bus_dmamem_alloc(%ju) failed: %d\n",
                      __func__, (uintmax_t)size, err);
                  goto fail_1;
          }
  
          dma->idi_paddr = IF_BAD_DMA;
          err = bus_dmamap_load(dma->idi_tag, dma->idi_map, dma->idi_vaddr,
              size, _iflib_dmamap_cb, &dma->idi_paddr, mapflags | BUS_DMA_NOWAIT);
          if (err || dma->idi_paddr == IF_BAD_DMA) {
                  device_printf(dev,
                      "%s: bus_dmamap_load failed: %d\n",
                      __func__, err);
                  goto fail_2;
          }
  
          dma->idi_size = size;
          return (0);
  
  fail_2:
          bus_dmamem_free(dma->idi_tag, dma->idi_vaddr, dma->idi_map);
  fail_1:
          bus_dma_tag_destroy(dma->idi_tag);
  fail_0:
          dma->idi_tag = NULL;
  
          return (err);
  }
  
  int
  iflib_dma_alloc(if_ctx_t ctx, int size, iflib_dma_info_t dma, int mapflags)
  {
          if_shared_ctx_t sctx = ctx->ifc_sctx;
  
          KASSERT(sctx->isc_q_align != 0, ("alignment value not initialized"));
  
          return (iflib_dma_alloc_align(ctx, size, sctx->isc_q_align, dma, mapflags));
  }
  
  int
  iflib_dma_alloc_multi(if_ctx_t ctx, int *sizes, iflib_dma_info_t *dmalist, int mapflags, int count)
  {
          int i, err;
          iflib_dma_info_t *dmaiter;
  
          dmaiter = dmalist;
          for (i = 0; i < count; i++, dmaiter++) {
                  if ((err = iflib_dma_alloc(ctx, sizes[i], *dmaiter, mapflags)) != 0)
                          break;
          }
          if (err)
                  iflib_dma_free_multi(dmalist, i);
          return (err);
  }
  
  void
  iflib_dma_free(iflib_dma_info_t dma)
  {
          if (dma->idi_tag == NULL)
                  return;
          if (dma->idi_paddr != IF_BAD_DMA) {
                  bus_dmamap_sync(dma->idi_tag, dma->idi_map,
                      BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE);
                  bus_dmamap_unload(dma->idi_tag, dma->idi_map);
                  dma->idi_paddr = IF_BAD_DMA;
          }
          if (dma->idi_vaddr != NULL) {
                  bus_dmamem_free(dma->idi_tag, dma->idi_vaddr, dma->idi_map);
                  dma->idi_vaddr = NULL;
          }
          bus_dma_tag_destroy(dma->idi_tag);
          dma->idi_tag = NULL;
  }
  
  void
  iflib_dma_free_multi(iflib_dma_info_t *dmalist, int count)
  {
          int i;
          iflib_dma_info_t *dmaiter = dmalist;
  
          for (i = 0; i < count; i++, dmaiter++)
                  iflib_dma_free(*dmaiter);
  }
  
  static int
  iflib_fast_intr(void *arg)
  {
          iflib_filter_info_t info = arg;
          struct grouptask *gtask = info->ifi_task;
          int result;
  
          DBG_COUNTER_INC(fast_intrs);
          if (info->ifi_filter != NULL) {
                  result = info->ifi_filter(info->ifi_filter_arg);
                  if ((result & FILTER_SCHEDULE_THREAD) == 0)
                          return (result);
          }
  
          GROUPTASK_ENQUEUE(gtask);
          return (FILTER_HANDLED);
  }
  
  static int
  iflib_fast_intr_rxtx(void *arg)
  {
          iflib_filter_info_t info = arg;
          struct grouptask *gtask = info->ifi_task;
          if_ctx_t ctx;
          iflib_rxq_t rxq = (iflib_rxq_t)info->ifi_ctx;
          iflib_txq_t txq;
          void *sc;
          int i, cidx, result;
          qidx_t txqid;
          bool intr_enable, intr_legacy;
  
          DBG_COUNTER_INC(fast_intrs);
          if (info->ifi_filter != NULL) {
                  result = info->ifi_filter(info->ifi_filter_arg);
                  if ((result & FILTER_SCHEDULE_THREAD) == 0)
                          return (result);
          }
  
          ctx = rxq->ifr_ctx;
          sc = ctx->ifc_softc;
          intr_enable = false;
          intr_legacy = !!(ctx->ifc_flags & IFC_LEGACY);
          MPASS(rxq->ifr_ntxqirq);
          for (i = 0; i < rxq->ifr_ntxqirq; i++) {
                  txqid = rxq->ifr_txqid[i];
                  txq = &ctx->ifc_txqs[txqid];
                  bus_dmamap_sync(txq->ift_ifdi->idi_tag, txq->ift_ifdi->idi_map,
                      BUS_DMASYNC_POSTREAD);
                  if (!ctx->isc_txd_credits_update(sc, txqid, false)) {
                          if (intr_legacy)
                                  intr_enable = true;
                          else
                                  IFDI_TX_QUEUE_INTR_ENABLE(ctx, txqid);
                          continue;
                  }
                  GROUPTASK_ENQUEUE(&txq->ift_task);
          }
          if (ctx->ifc_sctx->isc_flags & IFLIB_HAS_RXCQ)
                  cidx = rxq->ifr_cq_cidx;
          else
                  cidx = rxq->ifr_fl[0].ifl_cidx;
          if (iflib_rxd_avail(ctx, rxq, cidx, 1))
                  GROUPTASK_ENQUEUE(gtask);
          else {
                  if (intr_legacy)
                          intr_enable = true;
                  else
                          IFDI_RX_QUEUE_INTR_ENABLE(ctx, rxq->ifr_id);
                  DBG_COUNTER_INC(rx_intr_enables);
          }
          if (intr_enable)
                  IFDI_INTR_ENABLE(ctx);
          return (FILTER_HANDLED);
  }
  
  static int
  iflib_fast_intr_ctx(void *arg)
  {
          iflib_filter_info_t info = arg;
          struct grouptask *gtask = info->ifi_task;
          int result;
  
          DBG_COUNTER_INC(fast_intrs);
          if (info->ifi_filter != NULL) {
                  result = info->ifi_filter(info->ifi_filter_arg);
                  if ((result & FILTER_SCHEDULE_THREAD) == 0)
                          return (result);
          }
  
          GROUPTASK_ENQUEUE(gtask);
          return (FILTER_HANDLED);
  }
  
  static int
  _iflib_irq_alloc(if_ctx_t ctx, if_irq_t irq, int rid,
                   driver_filter_t filter, driver_intr_t handler, void *arg,
                   const char *name)
  {
          struct resource *res;
          void *tag = NULL;
          device_t dev = ctx->ifc_dev;
          int flags, i, rc;
  
          flags = RF_ACTIVE;
          if (ctx->ifc_flags & IFC_LEGACY)
                  flags |= RF_SHAREABLE;
          MPASS(rid < 512);
          i = rid;
          res = bus_alloc_resource_any(dev, SYS_RES_IRQ, &i, flags);
          if (res == NULL) {
                  device_printf(dev,
                      "failed to allocate IRQ for rid %d, name %s.\n", rid, name);
                  return (ENOMEM);
          }
          irq->ii_res = res;
          KASSERT(filter == NULL || handler == NULL, ("filter and handler can't both be non-NULL"));
          rc = bus_setup_intr(dev, res, INTR_MPSAFE | INTR_TYPE_NET,
                                                  filter, handler, arg, &tag);
          if (rc != 0) {
                  device_printf(dev,
                      "failed to setup interrupt for rid %d, name %s: %d\n",
                                            rid, name ? name : "unknown", rc);
                  return (rc);
          } else if (name)
                  bus_describe_intr(dev, res, tag, "%s", name);
  
          irq->ii_tag = tag;
          return (0);
  }
  
  /*********************************************************************
   *
   *  Allocate DMA resources for TX buffers as well as memory for the TX
   *  mbuf map.  TX DMA maps (non-TSO/TSO) and TX mbuf map are kept in a
   *  iflib_sw_tx_desc_array structure, storing all the information that
   *  is needed to transmit a packet on the wire.  This is called only
   *  once at attach, setup is done every reset.
   *
   **********************************************************************/
  static int
  iflib_txsd_alloc(iflib_txq_t txq)
  {
          if_ctx_t ctx = txq->ift_ctx;
          if_shared_ctx_t sctx = ctx->ifc_sctx;
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          device_t dev = ctx->ifc_dev;
          bus_size_t tsomaxsize;
          bus_addr_t lowaddr;
          int err, nsegments, ntsosegments;
          bool tso;
  
          nsegments = scctx->isc_tx_nsegments;
          ntsosegments = scctx->isc_tx_tso_segments_max;
          tsomaxsize = scctx->isc_tx_tso_size_max;
          if (if_getcapabilities(ctx->ifc_ifp) & IFCAP_VLAN_MTU)
                  tsomaxsize += sizeof(struct ether_vlan_header);
          MPASS(scctx->isc_ntxd[0] > 0);
          MPASS(scctx->isc_ntxd[txq->ift_br_offset] > 0);
          MPASS(nsegments > 0);
          if (if_getcapabilities(ctx->ifc_ifp) & IFCAP_TSO) {
                  MPASS(ntsosegments > 0);
                  MPASS(sctx->isc_tso_maxsize >= tsomaxsize);
          }
  
          lowaddr = DMA_WIDTH_TO_BUS_LOWADDR(scctx->isc_dma_width);
  
          /*
           * Set up DMA tags for TX buffers.
           */
          if ((err = bus_dma_tag_create(bus_get_dma_tag(dev),
                                 1, 0,                    /* alignment, bounds */
                                 lowaddr,                 /* lowaddr */
                                 BUS_SPACE_MAXADDR,       /* highaddr */
                                 NULL, NULL,              /* filter, filterarg */
                                 sctx->isc_tx_maxsize,            /* maxsize */
                                 nsegments,       /* nsegments */
                                 sctx->isc_tx_maxsegsize, /* maxsegsize */
                                 0,                       /* flags */
                                 NULL,                    /* lockfunc */
                                 NULL,                    /* lockfuncarg */
                                 &txq->ift_buf_tag))) {
                  device_printf(dev,"Unable to allocate TX DMA tag: %d\n", err);
                  device_printf(dev,"maxsize: %ju nsegments: %d maxsegsize: %ju\n",
                      (uintmax_t)sctx->isc_tx_maxsize, nsegments, (uintmax_t)sctx->isc_tx_maxsegsize);
                  goto fail;
          }
          tso = (if_getcapabilities(ctx->ifc_ifp) & IFCAP_TSO) != 0;
          if (tso && (err = bus_dma_tag_create(bus_get_dma_tag(dev),
                                 1, 0,                    /* alignment, bounds */
                                 lowaddr,                 /* lowaddr */
                                 BUS_SPACE_MAXADDR,       /* highaddr */
                                 NULL, NULL,              /* filter, filterarg */
                                 tsomaxsize,              /* maxsize */
                                 ntsosegments,    /* nsegments */
                                 sctx->isc_tso_maxsegsize,/* maxsegsize */
                                 0,                       /* flags */
                                 NULL,                    /* lockfunc */
                                 NULL,                    /* lockfuncarg */
                                 &txq->ift_tso_buf_tag))) {
                  device_printf(dev, "Unable to allocate TSO TX DMA tag: %d\n",
                      err);
                  goto fail;
          }
  
          /* Allocate memory for the TX mbuf map. */
          if (!(txq->ift_sds.ifsd_m =
              (struct mbuf **) malloc(sizeof(struct mbuf *) *
              scctx->isc_ntxd[txq->ift_br_offset], M_IFLIB, M_NOWAIT | M_ZERO))) {
                  device_printf(dev, "Unable to allocate TX mbuf map memory\n");
                  err = ENOMEM;
                  goto fail;
          }
  
          /*
           * Create the DMA maps for TX buffers.
           */
          if ((txq->ift_sds.ifsd_map = (bus_dmamap_t *)malloc(
              sizeof(bus_dmamap_t) * scctx->isc_ntxd[txq->ift_br_offset],
              M_IFLIB, M_NOWAIT | M_ZERO)) == NULL) {
                  device_printf(dev,
                      "Unable to allocate TX buffer DMA map memory\n");
                  err = ENOMEM;
                  goto fail;
          }
          if (tso && (txq->ift_sds.ifsd_tso_map = (bus_dmamap_t *)malloc(
              sizeof(bus_dmamap_t) * scctx->isc_ntxd[txq->ift_br_offset],
              M_IFLIB, M_NOWAIT | M_ZERO)) == NULL) {
                  device_printf(dev,
                      "Unable to allocate TSO TX buffer map memory\n");
                  err = ENOMEM;
                  goto fail;
          }
          for (int i = 0; i < scctx->isc_ntxd[txq->ift_br_offset]; i++) {
                  err = bus_dmamap_create(txq->ift_buf_tag, 0,
                      &txq->ift_sds.ifsd_map[i]);
                  if (err != 0) {
                          device_printf(dev, "Unable to create TX DMA map\n");
                          goto fail;
                  }
                  if (!tso)
                          continue;
                  err = bus_dmamap_create(txq->ift_tso_buf_tag, 0,
                      &txq->ift_sds.ifsd_tso_map[i]);
                  if (err != 0) {
                          device_printf(dev, "Unable to create TSO TX DMA map\n");
                          goto fail;
                  }
          }
          return (0);
  fail:
          /* We free all, it handles case where we are in the middle */
          iflib_tx_structures_free(ctx);
          return (err);
  }
  
  static void
  iflib_txsd_destroy(if_ctx_t ctx, iflib_txq_t txq, int i)
  {
          bus_dmamap_t map;
  
          if (txq->ift_sds.ifsd_map != NULL) {
                  map = txq->ift_sds.ifsd_map[i];
                  bus_dmamap_sync(txq->ift_buf_tag, map, BUS_DMASYNC_POSTWRITE);
                  bus_dmamap_unload(txq->ift_buf_tag, map);
                  bus_dmamap_destroy(txq->ift_buf_tag, map);
                  txq->ift_sds.ifsd_map[i] = NULL;
          }
  
          if (txq->ift_sds.ifsd_tso_map != NULL) {
                  map = txq->ift_sds.ifsd_tso_map[i];
                  bus_dmamap_sync(txq->ift_tso_buf_tag, map,
                      BUS_DMASYNC_POSTWRITE);
                  bus_dmamap_unload(txq->ift_tso_buf_tag, map);
                  bus_dmamap_destroy(txq->ift_tso_buf_tag, map);
                  txq->ift_sds.ifsd_tso_map[i] = NULL;
          }
  }
  
  static void
  iflib_txq_destroy(iflib_txq_t txq)
  {
          if_ctx_t ctx = txq->ift_ctx;
  
          for (int i = 0; i < txq->ift_size; i++)
                  iflib_txsd_destroy(ctx, txq, i);
  
          if (txq->ift_br != NULL) {
                  ifmp_ring_free(txq->ift_br);
                  txq->ift_br = NULL;
          }
  
          mtx_destroy(&txq->ift_mtx);
  
          if (txq->ift_sds.ifsd_map != NULL) {
                  free(txq->ift_sds.ifsd_map, M_IFLIB);
                  txq->ift_sds.ifsd_map = NULL;
          }
          if (txq->ift_sds.ifsd_tso_map != NULL) {
                  free(txq->ift_sds.ifsd_tso_map, M_IFLIB);
                  txq->ift_sds.ifsd_tso_map = NULL;
          }
          if (txq->ift_sds.ifsd_m != NULL) {
                  free(txq->ift_sds.ifsd_m, M_IFLIB);
                  txq->ift_sds.ifsd_m = NULL;
          }
          if (txq->ift_buf_tag != NULL) {
                  bus_dma_tag_destroy(txq->ift_buf_tag);
                  txq->ift_buf_tag = NULL;
          }
          if (txq->ift_tso_buf_tag != NULL) {
                  bus_dma_tag_destroy(txq->ift_tso_buf_tag);
                  txq->ift_tso_buf_tag = NULL;
          }
          if (txq->ift_ifdi != NULL) {
                  free(txq->ift_ifdi, M_IFLIB);
          }
  }
  
  static void
  iflib_txsd_free(if_ctx_t ctx, iflib_txq_t txq, int i)
  {
          struct mbuf **mp;
  
          mp = &txq->ift_sds.ifsd_m[i];
          if (*mp == NULL)
                  return;
  
          if (txq->ift_sds.ifsd_map != NULL) {
                  bus_dmamap_sync(txq->ift_buf_tag,
                      txq->ift_sds.ifsd_map[i], BUS_DMASYNC_POSTWRITE);
                  bus_dmamap_unload(txq->ift_buf_tag, txq->ift_sds.ifsd_map[i]);
          }
          if (txq->ift_sds.ifsd_tso_map != NULL) {
                  bus_dmamap_sync(txq->ift_tso_buf_tag,
                      txq->ift_sds.ifsd_tso_map[i], BUS_DMASYNC_POSTWRITE);
                  bus_dmamap_unload(txq->ift_tso_buf_tag,
                      txq->ift_sds.ifsd_tso_map[i]);
          }
          m_freem(*mp);
          DBG_COUNTER_INC(tx_frees);
          *mp = NULL;
  }
  
  static int
  iflib_txq_setup(iflib_txq_t txq)
  {
          if_ctx_t ctx = txq->ift_ctx;
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          if_shared_ctx_t sctx = ctx->ifc_sctx;
          iflib_dma_info_t di;
          int i;
  
          /* Set number of descriptors available */
          txq->ift_qstatus = IFLIB_QUEUE_IDLE;
          /* XXX make configurable */
          txq->ift_update_freq = IFLIB_DEFAULT_TX_UPDATE_FREQ;
  
          /* Reset indices */
          txq->ift_cidx_processed = 0;
          txq->ift_pidx = txq->ift_cidx = txq->ift_npending = 0;
          txq->ift_size = scctx->isc_ntxd[txq->ift_br_offset];
  
          for (i = 0, di = txq->ift_ifdi; i < sctx->isc_ntxqs; i++, di++)
                  bzero((void *)di->idi_vaddr, di->idi_size);
  
          IFDI_TXQ_SETUP(ctx, txq->ift_id);
          for (i = 0, di = txq->ift_ifdi; i < sctx->isc_ntxqs; i++, di++)
                  bus_dmamap_sync(di->idi_tag, di->idi_map,
                      BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
          return (0);
  }
  
  /*********************************************************************
   *
   *  Allocate DMA resources for RX buffers as well as memory for the RX
   *  mbuf map, direct RX cluster pointer map and RX cluster bus address
   *  map.  RX DMA map, RX mbuf map, direct RX cluster pointer map and
   *  RX cluster map are kept in a iflib_sw_rx_desc_array structure.
   *  Since we use use one entry in iflib_sw_rx_desc_array per received
   *  packet, the maximum number of entries we'll need is equal to the
   *  number of hardware receive descriptors that we've allocated.
   *
   **********************************************************************/
  static int
  iflib_rxsd_alloc(iflib_rxq_t rxq)
  {
          if_ctx_t ctx = rxq->ifr_ctx;
          if_shared_ctx_t sctx = ctx->ifc_sctx;
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          device_t dev = ctx->ifc_dev;
          iflib_fl_t fl;
          bus_addr_t lowaddr;
          int                     err;
  
          MPASS(scctx->isc_nrxd[0] > 0);
          MPASS(scctx->isc_nrxd[rxq->ifr_fl_offset] > 0);
  
          lowaddr = DMA_WIDTH_TO_BUS_LOWADDR(scctx->isc_dma_width);
  
          fl = rxq->ifr_fl;
          for (int i = 0; i <  rxq->ifr_nfl; i++, fl++) {
                  fl->ifl_size = scctx->isc_nrxd[rxq->ifr_fl_offset]; /* this isn't necessarily the same */
                  /* Set up DMA tag for RX buffers. */
                  err = bus_dma_tag_create(bus_get_dma_tag(dev), /* parent */
                                           1, 0,                  /* alignment, bounds */
                                           lowaddr,               /* lowaddr */
                                           BUS_SPACE_MAXADDR,     /* highaddr */
                                           NULL, NULL,            /* filter, filterarg */
                                           sctx->isc_rx_maxsize,  /* maxsize */
                                           sctx->isc_rx_nsegments,        /* nsegments */
                                           sctx->isc_rx_maxsegsize,       /* maxsegsize */
                                           0,                     /* flags */
                                           NULL,                  /* lockfunc */
                                           NULL,                  /* lockarg */
                                           &fl->ifl_buf_tag);
                  if (err) {
                          device_printf(dev,
                              "Unable to allocate RX DMA tag: %d\n", err);
                          goto fail;
                  }
  
                  /* Allocate memory for the RX mbuf map. */
                  if (!(fl->ifl_sds.ifsd_m =
                        (struct mbuf **) malloc(sizeof(struct mbuf *) *
                                                scctx->isc_nrxd[rxq->ifr_fl_offset], M_IFLIB, M_NOWAIT | M_ZERO))) {
                          device_printf(dev,
                              "Unable to allocate RX mbuf map memory\n");
                          err = ENOMEM;
                          goto fail;
                  }
  
                  /* Allocate memory for the direct RX cluster pointer map. */
                  if (!(fl->ifl_sds.ifsd_cl =
                        (caddr_t *) malloc(sizeof(caddr_t) *
                                                scctx->isc_nrxd[rxq->ifr_fl_offset], M_IFLIB, M_NOWAIT | M_ZERO))) {
                          device_printf(dev,
                              "Unable to allocate RX cluster map memory\n");
                          err = ENOMEM;
                          goto fail;
                  }
  
                  /* Allocate memory for the RX cluster bus address map. */
                  if (!(fl->ifl_sds.ifsd_ba =
                        (bus_addr_t *) malloc(sizeof(bus_addr_t) *
                                                scctx->isc_nrxd[rxq->ifr_fl_offset], M_IFLIB, M_NOWAIT | M_ZERO))) {
                          device_printf(dev,
                              "Unable to allocate RX bus address map memory\n");
                          err = ENOMEM;
                          goto fail;
                  }
  
                  /*
                   * Create the DMA maps for RX buffers.
                   */
                  if (!(fl->ifl_sds.ifsd_map =
                        (bus_dmamap_t *) malloc(sizeof(bus_dmamap_t) * scctx->isc_nrxd[rxq->ifr_fl_offset], M_IFLIB, M_NOWAIT | M_ZERO))) {
                          device_printf(dev,
                              "Unable to allocate RX buffer DMA map memory\n");
                          err = ENOMEM;
                          goto fail;
                  }
                  for (int i = 0; i < scctx->isc_nrxd[rxq->ifr_fl_offset]; i++) {
                          err = bus_dmamap_create(fl->ifl_buf_tag, 0,
                              &fl->ifl_sds.ifsd_map[i]);
                          if (err != 0) {
                                  device_printf(dev, "Unable to create RX buffer DMA map\n");
                                  goto fail;
                          }
                  }
          }
          return (0);
  
  fail:
          iflib_rx_structures_free(ctx);
          return (err);
  }
  
  /*
   * Internal service routines
   */
  
  struct rxq_refill_cb_arg {
          int               error;
          bus_dma_segment_t seg;
          int               nseg;
  };
  
  static void
  _rxq_refill_cb(void *arg, bus_dma_segment_t *segs, int nseg, int error)
  {
          struct rxq_refill_cb_arg *cb_arg = arg;
  
          cb_arg->error = error;
          cb_arg->seg = segs[0];
          cb_arg->nseg = nseg;
  }
  
  /**
   * iflib_fl_refill - refill an rxq free-buffer list
   * @ctx: the iflib context
   * @fl: the free list to refill
   * @count: the number of new buffers to allocate
   *
   * (Re)populate an rxq free-buffer list with up to @count new packet buffers.
   * The caller must assure that @count does not exceed the queue's capacity
   * minus one (since we always leave a descriptor unavailable).
   */
  static uint8_t
  iflib_fl_refill(if_ctx_t ctx, iflib_fl_t fl, int count)
  {
          struct if_rxd_update iru;
          struct rxq_refill_cb_arg cb_arg;
          struct mbuf *m;
          caddr_t cl, *sd_cl;
          struct mbuf **sd_m;
          bus_dmamap_t *sd_map;
          bus_addr_t bus_addr, *sd_ba;
          int err, frag_idx, i, idx, n, pidx;
          qidx_t credits;
  
          MPASS(count <= fl->ifl_size - fl->ifl_credits - 1);
  
          sd_m = fl->ifl_sds.ifsd_m;
          sd_map = fl->ifl_sds.ifsd_map;
          sd_cl = fl->ifl_sds.ifsd_cl;
          sd_ba = fl->ifl_sds.ifsd_ba;
          pidx = fl->ifl_pidx;
          idx = pidx;
          frag_idx = fl->ifl_fragidx;
          credits = fl->ifl_credits;
  
          i = 0;
          n = count;
          MPASS(n > 0);
          MPASS(credits + n <= fl->ifl_size);
  
          if (pidx < fl->ifl_cidx)
                  MPASS(pidx + n <= fl->ifl_cidx);
          if (pidx == fl->ifl_cidx && (credits < fl->ifl_size))
                  MPASS(fl->ifl_gen == 0);
          if (pidx > fl->ifl_cidx)
                  MPASS(n <= fl->ifl_size - pidx + fl->ifl_cidx);
  
          DBG_COUNTER_INC(fl_refills);
          if (n > 8)
                  DBG_COUNTER_INC(fl_refills_large);
          iru_init(&iru, fl->ifl_rxq, fl->ifl_id);
          while (n-- > 0) {
                  /*
                   * We allocate an uninitialized mbuf + cluster, mbuf is
                   * initialized after rx.
                   *
                   * If the cluster is still set then we know a minimum sized
                   * packet was received
                   */
                  bit_ffc_at(fl->ifl_rx_bitmap, frag_idx, fl->ifl_size,
                      &frag_idx);
                  if (frag_idx < 0)
                          bit_ffc(fl->ifl_rx_bitmap, fl->ifl_size, &frag_idx);
                  MPASS(frag_idx >= 0);
                  if ((cl = sd_cl[frag_idx]) == NULL) {
                          cl = uma_zalloc(fl->ifl_zone, M_NOWAIT);
                          if (__predict_false(cl == NULL))
                                  break;
  
                          cb_arg.error = 0;
                          MPASS(sd_map != NULL);
                          err = bus_dmamap_load(fl->ifl_buf_tag, sd_map[frag_idx],
                              cl, fl->ifl_buf_size, _rxq_refill_cb, &cb_arg,
                              BUS_DMA_NOWAIT);
                          if (__predict_false(err != 0 || cb_arg.error)) {
                                  uma_zfree(fl->ifl_zone, cl);
                                  break;
                          }
  
                          sd_ba[frag_idx] = bus_addr = cb_arg.seg.ds_addr;
                          sd_cl[frag_idx] = cl;
  #if MEMORY_LOGGING
                          fl->ifl_cl_enqueued++;
  #endif
                  } else {
                          bus_addr = sd_ba[frag_idx];
                  }
                  bus_dmamap_sync(fl->ifl_buf_tag, sd_map[frag_idx],
                      BUS_DMASYNC_PREREAD);
  
                  if (sd_m[frag_idx] == NULL) {
                          m = m_gethdr_raw(M_NOWAIT, 0);
                          if (__predict_false(m == NULL))
                                  break;
                          sd_m[frag_idx] = m;
                  }
                  bit_set(fl->ifl_rx_bitmap, frag_idx);
  #if MEMORY_LOGGING
                  fl->ifl_m_enqueued++;
  #endif
  
                  DBG_COUNTER_INC(rx_allocs);
                  fl->ifl_rxd_idxs[i] = frag_idx;
                  fl->ifl_bus_addrs[i] = bus_addr;
                  credits++;
                  i++;
                  MPASS(credits <= fl->ifl_size);
                  if (++idx == fl->ifl_size) {
  #ifdef INVARIANTS
                          fl->ifl_gen = 1;
  #endif
                          idx = 0;
                  }
                  if (n == 0 || i == IFLIB_MAX_RX_REFRESH) {
                          iru.iru_pidx = pidx;
                          iru.iru_count = i;
                          ctx->isc_rxd_refill(ctx->ifc_softc, &iru);
                          fl->ifl_pidx = idx;
                          fl->ifl_credits = credits;
                          pidx = idx;
                          i = 0;
                  }
          }
  
          if (n < count - 1) {
                  if (i != 0) {
                          iru.iru_pidx = pidx;
                          iru.iru_count = i;
                          ctx->isc_rxd_refill(ctx->ifc_softc, &iru);
                          fl->ifl_pidx = idx;
                          fl->ifl_credits = credits;
                  }
                  DBG_COUNTER_INC(rxd_flush);
                  bus_dmamap_sync(fl->ifl_ifdi->idi_tag, fl->ifl_ifdi->idi_map,
                      BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
                  ctx->isc_rxd_flush(ctx->ifc_softc, fl->ifl_rxq->ifr_id,
                      fl->ifl_id, fl->ifl_pidx);
                  if (__predict_true(bit_test(fl->ifl_rx_bitmap, frag_idx))) {
                          fl->ifl_fragidx = frag_idx + 1;
                          if (fl->ifl_fragidx == fl->ifl_size)
                                  fl->ifl_fragidx = 0;
                  } else {
                          fl->ifl_fragidx = frag_idx;
                  }
          }
  
          return (n == -1 ? 0 : IFLIB_RXEOF_EMPTY);
  }
  
  static inline uint8_t
  iflib_fl_refill_all(if_ctx_t ctx, iflib_fl_t fl)
  {
          /*
           * We leave an unused descriptor to avoid pidx to catch up with cidx.
           * This is important as it confuses most NICs. For instance,
           * Intel NICs have (per receive ring) RDH and RDT registers, where
           * RDH points to the next receive descriptor to be used by the NIC,
           * and RDT for the next receive descriptor to be published by the
           * driver to the NIC (RDT - 1 is thus the last valid one).
           * The condition RDH == RDT means no descriptors are available to
           * the NIC, and thus it would be ambiguous if it also meant that
           * all the descriptors are available to the NIC.
           */
          int32_t reclaimable = fl->ifl_size - fl->ifl_credits - 1;
  #ifdef INVARIANTS
          int32_t delta = fl->ifl_size - get_inuse(fl->ifl_size, fl->ifl_cidx, fl->ifl_pidx, fl->ifl_gen) - 1;
  #endif
  
          MPASS(fl->ifl_credits <= fl->ifl_size);
          MPASS(reclaimable == delta);
  
          if (reclaimable > 0)
                  return (iflib_fl_refill(ctx, fl, reclaimable));
          return (0);
  }
  
  uint8_t
  iflib_in_detach(if_ctx_t ctx)
  {
          bool in_detach;
  
          STATE_LOCK(ctx);
          in_detach = !!(ctx->ifc_flags & IFC_IN_DETACH);
          STATE_UNLOCK(ctx);
          return (in_detach);
  }
  
  static void
  iflib_fl_bufs_free(iflib_fl_t fl)
  {
          iflib_dma_info_t idi = fl->ifl_ifdi;
          bus_dmamap_t sd_map;
          uint32_t i;
  
          for (i = 0; i < fl->ifl_size; i++) {
                  struct mbuf **sd_m = &fl->ifl_sds.ifsd_m[i];
                  caddr_t *sd_cl = &fl->ifl_sds.ifsd_cl[i];
  
                  if (*sd_cl != NULL) {
                          sd_map = fl->ifl_sds.ifsd_map[i];
                          bus_dmamap_sync(fl->ifl_buf_tag, sd_map,
                              BUS_DMASYNC_POSTREAD);
                          bus_dmamap_unload(fl->ifl_buf_tag, sd_map);
                          uma_zfree(fl->ifl_zone, *sd_cl);
                          *sd_cl = NULL;
                          if (*sd_m != NULL) {
                                  m_init(*sd_m, M_NOWAIT, MT_DATA, 0);
                                  m_free_raw(*sd_m);
                                  *sd_m = NULL;
                          }
                  } else {
                          MPASS(*sd_m == NULL);
                  }
  #if MEMORY_LOGGING
                  fl->ifl_m_dequeued++;
                  fl->ifl_cl_dequeued++;
  #endif
          }
  #ifdef INVARIANTS
          for (i = 0; i < fl->ifl_size; i++) {
                  MPASS(fl->ifl_sds.ifsd_cl[i] == NULL);
                  MPASS(fl->ifl_sds.ifsd_m[i] == NULL);
          }
  #endif
          /*
           * Reset free list values
           */
          fl->ifl_credits = fl->ifl_cidx = fl->ifl_pidx = fl->ifl_gen = fl->ifl_fragidx = 0;
          bzero(idi->idi_vaddr, idi->idi_size);
  }
  
  /*********************************************************************
   *
   *  Initialize a free list and its buffers.
   *
   **********************************************************************/
  static int
  iflib_fl_setup(iflib_fl_t fl)
  {
          iflib_rxq_t rxq = fl->ifl_rxq;
          if_ctx_t ctx = rxq->ifr_ctx;
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          int qidx;
  
          bit_nclear(fl->ifl_rx_bitmap, 0, fl->ifl_size - 1);
          /*
          ** Free current RX buffer structs and their mbufs
          */
          iflib_fl_bufs_free(fl);
          /* Now replenish the mbufs */
          MPASS(fl->ifl_credits == 0);
          qidx = rxq->ifr_fl_offset + fl->ifl_id;
          if (scctx->isc_rxd_buf_size[qidx] != 0)
                  fl->ifl_buf_size = scctx->isc_rxd_buf_size[qidx];
          else
                  fl->ifl_buf_size = ctx->ifc_rx_mbuf_sz;
          /*
           * ifl_buf_size may be a driver-supplied value, so pull it up
           * to the selected mbuf size.
           */
          fl->ifl_buf_size = iflib_get_mbuf_size_for(fl->ifl_buf_size);
          if (fl->ifl_buf_size > ctx->ifc_max_fl_buf_size)
                  ctx->ifc_max_fl_buf_size = fl->ifl_buf_size;
          fl->ifl_cltype = m_gettype(fl->ifl_buf_size);
          fl->ifl_zone = m_getzone(fl->ifl_buf_size);
  
          /*
           * Avoid pre-allocating zillions of clusters to an idle card
           * potentially speeding up attach. In any case make sure
           * to leave a descriptor unavailable. See the comment in
           * iflib_fl_refill_all().
           */
          MPASS(fl->ifl_size > 0);
          (void)iflib_fl_refill(ctx, fl, min(128, fl->ifl_size - 1));
          if (min(128, fl->ifl_size - 1) != fl->ifl_credits)
                  return (ENOBUFS);
          /*
           * handle failure
           */
          MPASS(rxq != NULL);
          MPASS(fl->ifl_ifdi != NULL);
          bus_dmamap_sync(fl->ifl_ifdi->idi_tag, fl->ifl_ifdi->idi_map,
              BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
          return (0);
  }
  
  /*********************************************************************
   *
   *  Free receive ring data structures
   *
   **********************************************************************/
  static void
  iflib_rx_sds_free(iflib_rxq_t rxq)
  {
          iflib_fl_t fl;
          int i, j;
  
          if (rxq->ifr_fl != NULL) {
                  for (i = 0; i < rxq->ifr_nfl; i++) {
                          fl = &rxq->ifr_fl[i];
                          if (fl->ifl_buf_tag != NULL) {
                                  if (fl->ifl_sds.ifsd_map != NULL) {
                                          for (j = 0; j < fl->ifl_size; j++) {
                                                  bus_dmamap_sync(
                                                      fl->ifl_buf_tag,
                                                      fl->ifl_sds.ifsd_map[j],
                                                      BUS_DMASYNC_POSTREAD);
                                                  bus_dmamap_unload(
                                                      fl->ifl_buf_tag,
                                                      fl->ifl_sds.ifsd_map[j]);
                                                  bus_dmamap_destroy(
                                                      fl->ifl_buf_tag,
                                                      fl->ifl_sds.ifsd_map[j]);
                                          }
                                  }
                                  bus_dma_tag_destroy(fl->ifl_buf_tag);
                                  fl->ifl_buf_tag = NULL;
                          }
                          free(fl->ifl_sds.ifsd_m, M_IFLIB);
                          free(fl->ifl_sds.ifsd_cl, M_IFLIB);
                          free(fl->ifl_sds.ifsd_ba, M_IFLIB);
                          free(fl->ifl_sds.ifsd_map, M_IFLIB);
                          free(fl->ifl_rx_bitmap, M_IFLIB);
                          fl->ifl_sds.ifsd_m = NULL;
                          fl->ifl_sds.ifsd_cl = NULL;
                          fl->ifl_sds.ifsd_ba = NULL;
                          fl->ifl_sds.ifsd_map = NULL;
                          fl->ifl_rx_bitmap = NULL;
                  }
                  free(rxq->ifr_fl, M_IFLIB);
                  rxq->ifr_fl = NULL;
                  free(rxq->ifr_ifdi, M_IFLIB);
                  rxq->ifr_ifdi = NULL;
                  rxq->ifr_cq_cidx = 0;
          }
  }
  
  /*
   * Timer routine
   */
  static void
  iflib_timer(void *arg)
  {
          iflib_txq_t txq = arg;
          if_ctx_t ctx = txq->ift_ctx;
          if_softc_ctx_t sctx = &ctx->ifc_softc_ctx;
          uint64_t this_tick = ticks;
  
          if (!(if_getdrvflags(ctx->ifc_ifp) & IFF_DRV_RUNNING))
                  return;
  
          /*
          ** Check on the state of the TX queue(s), this
          ** can be done without the lock because its RO
          ** and the HUNG state will be static if set.
          */
          if (this_tick - txq->ift_last_timer_tick >= iflib_timer_default) {
                  txq->ift_last_timer_tick = this_tick;
                  IFDI_TIMER(ctx, txq->ift_id);
                  if ((txq->ift_qstatus == IFLIB_QUEUE_HUNG) &&
                      ((txq->ift_cleaned_prev == txq->ift_cleaned) ||
                       (sctx->isc_pause_frames == 0)))
                          goto hung;
  
                  if (txq->ift_qstatus != IFLIB_QUEUE_IDLE &&
                      ifmp_ring_is_stalled(txq->ift_br)) {
                          KASSERT(ctx->ifc_link_state == LINK_STATE_UP,
                              ("queue can't be marked as hung if interface is down"));
                          txq->ift_qstatus = IFLIB_QUEUE_HUNG;
                  }
                  txq->ift_cleaned_prev = txq->ift_cleaned;
          }
          /* handle any laggards */
          if (txq->ift_db_pending)
                  GROUPTASK_ENQUEUE(&txq->ift_task);
  
          sctx->isc_pause_frames = 0;
          if (if_getdrvflags(ctx->ifc_ifp) & IFF_DRV_RUNNING) 
                  callout_reset_on(&txq->ift_timer, iflib_timer_default, iflib_timer,
                      txq, txq->ift_timer.c_cpu);
          return;
  
   hung:
          device_printf(ctx->ifc_dev,
              "Watchdog timeout (TX: %d desc avail: %d pidx: %d) -- resetting\n",
              txq->ift_id, TXQ_AVAIL(txq), txq->ift_pidx);
          STATE_LOCK(ctx);
          if_setdrvflagbits(ctx->ifc_ifp, IFF_DRV_OACTIVE, IFF_DRV_RUNNING);
          ctx->ifc_flags |= (IFC_DO_WATCHDOG|IFC_DO_RESET);
          iflib_admin_intr_deferred(ctx);
          STATE_UNLOCK(ctx);
  }
  
  static uint16_t
  iflib_get_mbuf_size_for(unsigned int size)
  {
  
          if (size <= MCLBYTES)
                  return (MCLBYTES);
          else
                  return (MJUMPAGESIZE);
  }
  
  static void
  iflib_calc_rx_mbuf_sz(if_ctx_t ctx)
  {
          if_softc_ctx_t sctx = &ctx->ifc_softc_ctx;
  
          /*
           * XXX don't set the max_frame_size to larger
           * than the hardware can handle
           */
          ctx->ifc_rx_mbuf_sz =
              iflib_get_mbuf_size_for(sctx->isc_max_frame_size);
  }
  
  uint32_t
  iflib_get_rx_mbuf_sz(if_ctx_t ctx)
  {
  
          return (ctx->ifc_rx_mbuf_sz);
  }
  
  static void
  iflib_init_locked(if_ctx_t ctx)
  {
          if_softc_ctx_t sctx = &ctx->ifc_softc_ctx;
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          if_t ifp = ctx->ifc_ifp;
          iflib_fl_t fl;
          iflib_txq_t txq;
          iflib_rxq_t rxq;
          int i, j, tx_ip_csum_flags, tx_ip6_csum_flags;
  
          if_setdrvflagbits(ifp, IFF_DRV_OACTIVE, IFF_DRV_RUNNING);
          IFDI_INTR_DISABLE(ctx);
  
          /*
           * See iflib_stop(). Useful in case iflib_init_locked() is
           * called without first calling iflib_stop().
           */
          netmap_disable_all_rings(ifp);
  
          tx_ip_csum_flags = scctx->isc_tx_csum_flags & (CSUM_IP | CSUM_TCP | CSUM_UDP | CSUM_SCTP);
          tx_ip6_csum_flags = scctx->isc_tx_csum_flags & (CSUM_IP6_TCP | CSUM_IP6_UDP | CSUM_IP6_SCTP);
          /* Set hardware offload abilities */
          if_clearhwassist(ifp);
          if (if_getcapenable(ifp) & IFCAP_TXCSUM)
                  if_sethwassistbits(ifp, tx_ip_csum_flags, 0);
          if (if_getcapenable(ifp) & IFCAP_TXCSUM_IPV6)
                  if_sethwassistbits(ifp,  tx_ip6_csum_flags, 0);
          if (if_getcapenable(ifp) & IFCAP_TSO4)
                  if_sethwassistbits(ifp, CSUM_IP_TSO, 0);
          if (if_getcapenable(ifp) & IFCAP_TSO6)
                  if_sethwassistbits(ifp, CSUM_IP6_TSO, 0);
  
          for (i = 0, txq = ctx->ifc_txqs; i < sctx->isc_ntxqsets; i++, txq++) {
                  CALLOUT_LOCK(txq);
                  callout_stop(&txq->ift_timer);
  #ifdef DEV_NETMAP
                  callout_stop(&txq->ift_netmap_timer);
  #endif /* DEV_NETMAP */
                  CALLOUT_UNLOCK(txq);
                  (void)iflib_netmap_txq_init(ctx, txq);
          }
  
          /*
           * Calculate a suitable Rx mbuf size prior to calling IFDI_INIT, so
           * that drivers can use the value when setting up the hardware receive
           * buffers.
           */
          iflib_calc_rx_mbuf_sz(ctx);
  
  #ifdef INVARIANTS
          i = if_getdrvflags(ifp);
  #endif
          IFDI_INIT(ctx);
          MPASS(if_getdrvflags(ifp) == i);
          for (i = 0, rxq = ctx->ifc_rxqs; i < sctx->isc_nrxqsets; i++, rxq++) {
                  if (iflib_netmap_rxq_init(ctx, rxq) > 0) {
                          /* This rxq is in netmap mode. Skip normal init. */
                          continue;
                  }
                  for (j = 0, fl = rxq->ifr_fl; j < rxq->ifr_nfl; j++, fl++) {
                          if (iflib_fl_setup(fl)) {
                                  device_printf(ctx->ifc_dev,
                                      "setting up free list %d failed - "
                                      "check cluster settings\n", j);
                                  goto done;
                          }
                  }
          }
  done:
          if_setdrvflagbits(ctx->ifc_ifp, IFF_DRV_RUNNING, IFF_DRV_OACTIVE);
          IFDI_INTR_ENABLE(ctx);
          txq = ctx->ifc_txqs;
          for (i = 0; i < sctx->isc_ntxqsets; i++, txq++)
                  callout_reset_on(&txq->ift_timer, iflib_timer_default, iflib_timer, txq,
                          txq->ift_timer.c_cpu);
  
          /* Re-enable txsync/rxsync. */
          netmap_enable_all_rings(ifp);
  }
  
  static int
  iflib_media_change(if_t ifp)
  {
          if_ctx_t ctx = if_getsoftc(ifp);
          int err;
  
          CTX_LOCK(ctx);
          if ((err = IFDI_MEDIA_CHANGE(ctx)) == 0)
                  iflib_if_init_locked(ctx);
          CTX_UNLOCK(ctx);
          return (err);
  }
  
  static void
  iflib_media_status(if_t ifp, struct ifmediareq *ifmr)
  {
          if_ctx_t ctx = if_getsoftc(ifp);
  
          CTX_LOCK(ctx);
          IFDI_UPDATE_ADMIN_STATUS(ctx);
          IFDI_MEDIA_STATUS(ctx, ifmr);
          CTX_UNLOCK(ctx);
  }
  
  void
  iflib_stop(if_ctx_t ctx)
  {
          iflib_txq_t txq = ctx->ifc_txqs;
          iflib_rxq_t rxq = ctx->ifc_rxqs;
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          if_shared_ctx_t sctx = ctx->ifc_sctx;
          iflib_dma_info_t di;
          iflib_fl_t fl;
          int i, j;
  
          /* Tell the stack that the interface is no longer active */
          if_setdrvflagbits(ctx->ifc_ifp, IFF_DRV_OACTIVE, IFF_DRV_RUNNING);
  
          IFDI_INTR_DISABLE(ctx);
          DELAY(1000);
          IFDI_STOP(ctx);
          DELAY(1000);
  
          /*
           * Stop any pending txsync/rxsync and prevent new ones
           * form starting. Processes blocked in poll() will get
           * POLLERR.
           */
          netmap_disable_all_rings(ctx->ifc_ifp);
  
          iflib_debug_reset();
          /* Wait for current tx queue users to exit to disarm watchdog timer. */
          for (i = 0; i < scctx->isc_ntxqsets; i++, txq++) {
                  /* make sure all transmitters have completed before proceeding XXX */
  
                  CALLOUT_LOCK(txq);
                  callout_stop(&txq->ift_timer);
  #ifdef DEV_NETMAP
                  callout_stop(&txq->ift_netmap_timer);
  #endif /* DEV_NETMAP */
                  CALLOUT_UNLOCK(txq);
  
                  /* clean any enqueued buffers */
                  iflib_ifmp_purge(txq);
                  /* Free any existing tx buffers. */
                  for (j = 0; j < txq->ift_size; j++) {
                          iflib_txsd_free(ctx, txq, j);
                  }
                  txq->ift_processed = txq->ift_cleaned = txq->ift_cidx_processed = 0;
                  txq->ift_in_use = txq->ift_gen = txq->ift_no_desc_avail = 0;
                  if (sctx->isc_flags & IFLIB_PRESERVE_TX_INDICES)
                          txq->ift_cidx = txq->ift_pidx;
                  else
                          txq->ift_cidx = txq->ift_pidx = 0;
  
                  txq->ift_closed = txq->ift_mbuf_defrag = txq->ift_mbuf_defrag_failed = 0;
                  txq->ift_no_tx_dma_setup = txq->ift_txd_encap_efbig = txq->ift_map_failed = 0;
                  txq->ift_pullups = 0;
                  ifmp_ring_reset_stats(txq->ift_br);
                  for (j = 0, di = txq->ift_ifdi; j < sctx->isc_ntxqs; j++, di++)
                          bzero((void *)di->idi_vaddr, di->idi_size);
          }
          for (i = 0; i < scctx->isc_nrxqsets; i++, rxq++) {
                  if (rxq->ifr_task.gt_taskqueue != NULL)
                          gtaskqueue_drain(rxq->ifr_task.gt_taskqueue,
                                   &rxq->ifr_task.gt_task);
  
                  rxq->ifr_cq_cidx = 0;
                  for (j = 0, di = rxq->ifr_ifdi; j < sctx->isc_nrxqs; j++, di++)
                          bzero((void *)di->idi_vaddr, di->idi_size);
                  /* also resets the free lists pidx/cidx */
                  for (j = 0, fl = rxq->ifr_fl; j < rxq->ifr_nfl; j++, fl++)
                          iflib_fl_bufs_free(fl);
          }
  }
  
  static inline caddr_t
  calc_next_rxd(iflib_fl_t fl, int cidx)
  {
          qidx_t size;
          int nrxd;
          caddr_t start, end, cur, next;
  
          nrxd = fl->ifl_size;
          size = fl->ifl_rxd_size;
          start = fl->ifl_ifdi->idi_vaddr;
  
          if (__predict_false(size == 0))
                  return (start);
          cur = start + size*cidx;
          end = start + size*nrxd;
          next = CACHE_PTR_NEXT(cur);
          return (next < end ? next : start);
  }
  
  static inline void
  prefetch_pkts(iflib_fl_t fl, int cidx)
  {
          int nextptr;
          int nrxd = fl->ifl_size;
          caddr_t next_rxd;
  
          nextptr = (cidx + CACHE_PTR_INCREMENT) & (nrxd-1);
          prefetch(&fl->ifl_sds.ifsd_m[nextptr]);
          prefetch(&fl->ifl_sds.ifsd_cl[nextptr]);
          next_rxd = calc_next_rxd(fl, cidx);
          prefetch(next_rxd);
          prefetch(fl->ifl_sds.ifsd_m[(cidx + 1) & (nrxd-1)]);
          prefetch(fl->ifl_sds.ifsd_m[(cidx + 2) & (nrxd-1)]);
          prefetch(fl->ifl_sds.ifsd_m[(cidx + 3) & (nrxd-1)]);
          prefetch(fl->ifl_sds.ifsd_m[(cidx + 4) & (nrxd-1)]);
          prefetch(fl->ifl_sds.ifsd_cl[(cidx + 1) & (nrxd-1)]);
          prefetch(fl->ifl_sds.ifsd_cl[(cidx + 2) & (nrxd-1)]);
          prefetch(fl->ifl_sds.ifsd_cl[(cidx + 3) & (nrxd-1)]);
          prefetch(fl->ifl_sds.ifsd_cl[(cidx + 4) & (nrxd-1)]);
  }
  
  static struct mbuf *
  rxd_frag_to_sd(iflib_rxq_t rxq, if_rxd_frag_t irf, bool unload, if_rxsd_t sd,
      int *pf_rv, if_rxd_info_t ri)
  {
          bus_dmamap_t map;
          iflib_fl_t fl;
          caddr_t payload;
          struct mbuf *m;
          int flid, cidx, len, next;
  
          map = NULL;
          flid = irf->irf_flid;
          cidx = irf->irf_idx;
          fl = &rxq->ifr_fl[flid];
          sd->ifsd_fl = fl;
          m = fl->ifl_sds.ifsd_m[cidx];
          sd->ifsd_cl = &fl->ifl_sds.ifsd_cl[cidx];
          fl->ifl_credits--;
  #if MEMORY_LOGGING
          fl->ifl_m_dequeued++;
  #endif
          if (rxq->ifr_ctx->ifc_flags & IFC_PREFETCH)
                  prefetch_pkts(fl, cidx);
          next = (cidx + CACHE_PTR_INCREMENT) & (fl->ifl_size-1);
          prefetch(&fl->ifl_sds.ifsd_map[next]);
          map = fl->ifl_sds.ifsd_map[cidx];
  
          bus_dmamap_sync(fl->ifl_buf_tag, map, BUS_DMASYNC_POSTREAD);
  
          if (rxq->pfil != NULL && PFIL_HOOKED_IN(rxq->pfil) && pf_rv != NULL &&
              irf->irf_len != 0) {
                  payload  = *sd->ifsd_cl;
                  payload +=  ri->iri_pad;
                  len = ri->iri_len - ri->iri_pad;
                  *pf_rv = pfil_run_hooks(rxq->pfil, payload, ri->iri_ifp,
                      len | PFIL_MEMPTR | PFIL_IN, NULL);
                  switch (*pf_rv) {
                  case PFIL_DROPPED:
                  case PFIL_CONSUMED:
                          /*
                           * The filter ate it.  Everything is recycled.
                           */
                          m = NULL;
                          unload = 0;
                          break;
                  case PFIL_REALLOCED:
                          /*
                           * The filter copied it.  Everything is recycled.
                           */
                          m = pfil_mem2mbuf(payload);
                          unload = 0;
                          break;
                  case PFIL_PASS:
                          /*
                           * Filter said it was OK, so receive like
                           * normal
                           */
                          fl->ifl_sds.ifsd_m[cidx] = NULL;
                          break;
                  default:
                          MPASS(0);
                  }
          } else {
                  fl->ifl_sds.ifsd_m[cidx] = NULL;
                  if (pf_rv != NULL)
                          *pf_rv = PFIL_PASS;
          }
  
          if (unload && irf->irf_len != 0)
                  bus_dmamap_unload(fl->ifl_buf_tag, map);
          fl->ifl_cidx = (fl->ifl_cidx + 1) & (fl->ifl_size-1);
          if (__predict_false(fl->ifl_cidx == 0))
                  fl->ifl_gen = 0;
          bit_clear(fl->ifl_rx_bitmap, cidx);
          return (m);
  }
  
  static struct mbuf *
  assemble_segments(iflib_rxq_t rxq, if_rxd_info_t ri, if_rxsd_t sd, int *pf_rv)
  {
          struct mbuf *m, *mh, *mt;
          caddr_t cl;
          int  *pf_rv_ptr, flags, i, padlen;
          bool consumed;
  
          i = 0;
          mh = NULL;
          consumed = false;
          *pf_rv = PFIL_PASS;
          pf_rv_ptr = pf_rv;
          do {
                  m = rxd_frag_to_sd(rxq, &ri->iri_frags[i], !consumed, sd,
                      pf_rv_ptr, ri);
  
                  MPASS(*sd->ifsd_cl != NULL);
  
                  /*
                   * Exclude zero-length frags & frags from
                   * packets the filter has consumed or dropped
                   */
                  if (ri->iri_frags[i].irf_len == 0 || consumed ||
                      *pf_rv == PFIL_CONSUMED || *pf_rv == PFIL_DROPPED) {
                          if (mh == NULL) {
                                  /* everything saved here */
                                  consumed = true;
                                  pf_rv_ptr = NULL;
                                  continue;
                          }
                          /* XXX we can save the cluster here, but not the mbuf */
                          m_init(m, M_NOWAIT, MT_DATA, 0);
                          m_free(m);
                          continue;
                  }
                  if (mh == NULL) {
                          flags = M_PKTHDR|M_EXT;
                          mh = mt = m;
                          padlen = ri->iri_pad;
                  } else {
                          flags = M_EXT;
                          mt->m_next = m;
                          mt = m;
                          /* assuming padding is only on the first fragment */
                          padlen = 0;
                  }
                  cl = *sd->ifsd_cl;
                  *sd->ifsd_cl = NULL;
  
                  /* Can these two be made one ? */
                  m_init(m, M_NOWAIT, MT_DATA, flags);
                  m_cljset(m, cl, sd->ifsd_fl->ifl_cltype);
                  /*
                   * These must follow m_init and m_cljset
                   */
                  m->m_data += padlen;
                  ri->iri_len -= padlen;
                  m->m_len = ri->iri_frags[i].irf_len;
          } while (++i < ri->iri_nfrags);
  
          return (mh);
  }
  
  /*
   * Process one software descriptor
   */
  static struct mbuf *
  iflib_rxd_pkt_get(iflib_rxq_t rxq, if_rxd_info_t ri)
  {
          struct if_rxsd sd;
          struct mbuf *m;
          int pf_rv;
  
          /* should I merge this back in now that the two paths are basically duplicated? */
          if (ri->iri_nfrags == 1 &&
              ri->iri_frags[0].irf_len != 0 &&
              ri->iri_frags[0].irf_len <= MIN(IFLIB_RX_COPY_THRESH, MHLEN)) {
                  m = rxd_frag_to_sd(rxq, &ri->iri_frags[0], false, &sd,
                      &pf_rv, ri);
                  if (pf_rv != PFIL_PASS && pf_rv != PFIL_REALLOCED)
                          return (m);
                  if (pf_rv == PFIL_PASS) {
                          m_init(m, M_NOWAIT, MT_DATA, M_PKTHDR);
  #ifndef __NO_STRICT_ALIGNMENT
                          if (!IP_ALIGNED(m) && ri->iri_pad == 0)
                                  m->m_data += 2;
  #endif
                          memcpy(m->m_data, *sd.ifsd_cl, ri->iri_len);
                          m->m_len = ri->iri_frags[0].irf_len;
                          m->m_data += ri->iri_pad;
                          ri->iri_len -= ri->iri_pad;
                  }
          } else {
                  m = assemble_segments(rxq, ri, &sd, &pf_rv);
                  if (m == NULL)
                          return (NULL);
                  if (pf_rv != PFIL_PASS && pf_rv != PFIL_REALLOCED)
                          return (m);
          }
          m->m_pkthdr.len = ri->iri_len;
          m->m_pkthdr.rcvif = ri->iri_ifp;
          m->m_flags |= ri->iri_flags;
          m->m_pkthdr.ether_vtag = ri->iri_vtag;
          m->m_pkthdr.flowid = ri->iri_flowid;
          M_HASHTYPE_SET(m, ri->iri_rsstype);
          m->m_pkthdr.csum_flags = ri->iri_csum_flags;
          m->m_pkthdr.csum_data = ri->iri_csum_data;
          return (m);
  }
  
  #if defined(INET6) || defined(INET)
  static void
  iflib_get_ip_forwarding(struct lro_ctrl *lc, bool *v4, bool *v6)
  {
          CURVNET_SET(lc->ifp->if_vnet); /* XXX - DRVAPI */
  #if defined(INET6)
          *v6 = V_ip6_forwarding;
  #endif
  #if defined(INET)
          *v4 = V_ipforwarding;
  #endif
          CURVNET_RESTORE();
  }
  
  /*
   * Returns true if it's possible this packet could be LROed.
   * if it returns false, it is guaranteed that tcp_lro_rx()
   * would not return zero.
   */
  static bool
  iflib_check_lro_possible(struct mbuf *m, bool v4_forwarding, bool v6_forwarding)
  {
          struct ether_header *eh;
  
          eh = mtod(m, struct ether_header *);
          switch (eh->ether_type) {
  #if defined(INET6)
                  case htons(ETHERTYPE_IPV6):
                          return (!v6_forwarding);
  #endif
  #if defined (INET)
                  case htons(ETHERTYPE_IP):
                          return (!v4_forwarding);
  #endif
          }
  
          return false;
  }
  #else
  static void
  iflib_get_ip_forwarding(struct lro_ctrl *lc __unused, bool *v4 __unused, bool *v6 __unused)
  {
  }
  #endif
  
  static void
  _task_fn_rx_watchdog(void *context)
  {
          iflib_rxq_t rxq = context;
  
          GROUPTASK_ENQUEUE(&rxq->ifr_task);
  }
  
  static uint8_t
  iflib_rxeof(iflib_rxq_t rxq, qidx_t budget)
  {
          if_t ifp;
          if_ctx_t ctx = rxq->ifr_ctx;
          if_shared_ctx_t sctx = ctx->ifc_sctx;
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          int avail, i;
          qidx_t *cidxp;
          struct if_rxd_info ri;
          int err, budget_left, rx_bytes, rx_pkts;
          iflib_fl_t fl;
          int lro_enabled;
          bool v4_forwarding, v6_forwarding, lro_possible;
          uint8_t retval = 0;
  
          /*
           * XXX early demux data packets so that if_input processing only handles
           * acks in interrupt context
           */
          struct mbuf *m, *mh, *mt, *mf;
  
          NET_EPOCH_ASSERT();
  
          lro_possible = v4_forwarding = v6_forwarding = false;
          ifp = ctx->ifc_ifp;
          mh = mt = NULL;
          MPASS(budget > 0);
          rx_pkts = rx_bytes = 0;
          if (sctx->isc_flags & IFLIB_HAS_RXCQ)
                  cidxp = &rxq->ifr_cq_cidx;
          else
                  cidxp = &rxq->ifr_fl[0].ifl_cidx;
          if ((avail = iflib_rxd_avail(ctx, rxq, *cidxp, budget)) == 0) {
                  for (i = 0, fl = &rxq->ifr_fl[0]; i < sctx->isc_nfl; i++, fl++)
                          retval |= iflib_fl_refill_all(ctx, fl);
                  DBG_COUNTER_INC(rx_unavail);
                  return (retval);
          }
  
          /* pfil needs the vnet to be set */
          CURVNET_SET_QUIET(ifp->if_vnet); /* XXX - DRVAPI */
          for (budget_left = budget; budget_left > 0 && avail > 0;) {
                  if (__predict_false(!CTX_ACTIVE(ctx))) {
                          DBG_COUNTER_INC(rx_ctx_inactive);
                          break;
                  }
                  /*
                   * Reset client set fields to their default values
                   */
                  rxd_info_zero(&ri);
                  ri.iri_qsidx = rxq->ifr_id;
                  ri.iri_cidx = *cidxp;
                  ri.iri_ifp = ifp;
                  ri.iri_frags = rxq->ifr_frags;
                  err = ctx->isc_rxd_pkt_get(ctx->ifc_softc, &ri);
  
                  if (err)
                          goto err;
                  rx_pkts += 1;
                  rx_bytes += ri.iri_len;
                  if (sctx->isc_flags & IFLIB_HAS_RXCQ) {
                          *cidxp = ri.iri_cidx;
                          /* Update our consumer index */
                          /* XXX NB: shurd - check if this is still safe */
                          while (rxq->ifr_cq_cidx >= scctx->isc_nrxd[0])
                                  rxq->ifr_cq_cidx -= scctx->isc_nrxd[0];
                          /* was this only a completion queue message? */
                          if (__predict_false(ri.iri_nfrags == 0))
                                  continue;
                  }
                  MPASS(ri.iri_nfrags != 0);
                  MPASS(ri.iri_len != 0);
  
                  /* will advance the cidx on the corresponding free lists */
                  m = iflib_rxd_pkt_get(rxq, &ri);
                  avail--;
                  budget_left--;
                  if (avail == 0 && budget_left)
                          avail = iflib_rxd_avail(ctx, rxq, *cidxp, budget_left);
  
                  if (__predict_false(m == NULL))
                          continue;
  
                  /* imm_pkt: -- cxgb */
                  if (mh == NULL)
                          mh = mt = m;
                  else {
                          mt->m_nextpkt = m;
                          mt = m;
                  }
          }
          CURVNET_RESTORE();
          /* make sure that we can refill faster than drain */
          for (i = 0, fl = &rxq->ifr_fl[0]; i < sctx->isc_nfl; i++, fl++)
                  retval |= iflib_fl_refill_all(ctx, fl);
  
          lro_enabled = (if_getcapenable(ifp) & IFCAP_LRO);
          if (lro_enabled)
                  iflib_get_ip_forwarding(&rxq->ifr_lc, &v4_forwarding, &v6_forwarding);
          mt = mf = NULL;
          while (mh != NULL) {
                  m = mh;
                  mh = mh->m_nextpkt;
                  m->m_nextpkt = NULL;
  #ifndef __NO_STRICT_ALIGNMENT
                  if (!IP_ALIGNED(m) && (m = iflib_fixup_rx(m)) == NULL)
                          continue;
  #endif
  #if defined(INET6) || defined(INET)
                  if (lro_enabled) {
                          if (!lro_possible) {
                                  lro_possible = iflib_check_lro_possible(m, v4_forwarding, v6_forwarding);
                                  if (lro_possible && mf != NULL) {
                                          if_input(ifp, mf);
                                          DBG_COUNTER_INC(rx_if_input);
                                          mt = mf = NULL;
                                  }
                          }
                          if ((m->m_pkthdr.csum_flags & (CSUM_L4_CALC|CSUM_L4_VALID)) ==
                              (CSUM_L4_CALC|CSUM_L4_VALID)) {
                                  if (lro_possible && tcp_lro_rx(&rxq->ifr_lc, m, 0) == 0)
                                          continue;
                          }
                  }
  #endif
                  if (lro_possible) {
                          if_input(ifp, m);
                          DBG_COUNTER_INC(rx_if_input);
                          continue;
                  }
  
                  if (mf == NULL)
                          mf = m;
                  if (mt != NULL)
                          mt->m_nextpkt = m;
                  mt = m;
          }
          if (mf != NULL) {
                  if_input(ifp, mf);
                  DBG_COUNTER_INC(rx_if_input);
          }
  
          if_inc_counter(ifp, IFCOUNTER_IBYTES, rx_bytes);
          if_inc_counter(ifp, IFCOUNTER_IPACKETS, rx_pkts);
  
          /*
           * Flush any outstanding LRO work
           */
  #if defined(INET6) || defined(INET)
          tcp_lro_flush_all(&rxq->ifr_lc);
  #endif
          if (avail != 0 || iflib_rxd_avail(ctx, rxq, *cidxp, 1) != 0)
                  retval |= IFLIB_RXEOF_MORE;
          return (retval);
  err:
          STATE_LOCK(ctx);
          ctx->ifc_flags |= IFC_DO_RESET;
          iflib_admin_intr_deferred(ctx);
          STATE_UNLOCK(ctx);
          return (0);
  }
  
  #define TXD_NOTIFY_COUNT(txq) (((txq)->ift_size / (txq)->ift_update_freq)-1)
  static inline qidx_t
  txq_max_db_deferred(iflib_txq_t txq, qidx_t in_use)
  {
          qidx_t notify_count = TXD_NOTIFY_COUNT(txq);
          qidx_t minthresh = txq->ift_size / 8;
          if (in_use > 4*minthresh)
                  return (notify_count);
          if (in_use > 2*minthresh)
                  return (notify_count >> 1);
          if (in_use > minthresh)
                  return (notify_count >> 3);
          return (0);
  }
  
  static inline qidx_t
  txq_max_rs_deferred(iflib_txq_t txq)
  {
          qidx_t notify_count = TXD_NOTIFY_COUNT(txq);
          qidx_t minthresh = txq->ift_size / 8;
          if (txq->ift_in_use > 4*minthresh)
                  return (notify_count);
          if (txq->ift_in_use > 2*minthresh)
                  return (notify_count >> 1);
          if (txq->ift_in_use > minthresh)
                  return (notify_count >> 2);
          return (2);
  }
  
  #define M_CSUM_FLAGS(m) ((m)->m_pkthdr.csum_flags)
  #define M_HAS_VLANTAG(m) (m->m_flags & M_VLANTAG)
  
  #define TXQ_MAX_DB_DEFERRED(txq, in_use) txq_max_db_deferred((txq), (in_use))
  #define TXQ_MAX_RS_DEFERRED(txq) txq_max_rs_deferred(txq)
  #define TXQ_MAX_DB_CONSUMED(size) (size >> 4)
  
  /* forward compatibility for cxgb */
  #define FIRST_QSET(ctx) 0
  #define NTXQSETS(ctx) ((ctx)->ifc_softc_ctx.isc_ntxqsets)
  #define NRXQSETS(ctx) ((ctx)->ifc_softc_ctx.isc_nrxqsets)
  #define QIDX(ctx, m) ((((m)->m_pkthdr.flowid & ctx->ifc_softc_ctx.isc_rss_table_mask) % NTXQSETS(ctx)) + FIRST_QSET(ctx))
  #define DESC_RECLAIMABLE(q) ((int)((q)->ift_processed - (q)->ift_cleaned - (q)->ift_ctx->ifc_softc_ctx.isc_tx_nsegments))
  
  /* XXX we should be setting this to something other than zero */
  #define RECLAIM_THRESH(ctx) ((ctx)->ifc_sctx->isc_tx_reclaim_thresh)
  #define MAX_TX_DESC(ctx) MAX((ctx)->ifc_softc_ctx.isc_tx_tso_segments_max, \
      (ctx)->ifc_softc_ctx.isc_tx_nsegments)
  
  static inline bool
  iflib_txd_db_check(iflib_txq_t txq, int ring)
  {
          if_ctx_t ctx = txq->ift_ctx;
          qidx_t dbval, max;
  
          max = TXQ_MAX_DB_DEFERRED(txq, txq->ift_in_use);
  
          /* force || threshold exceeded || at the edge of the ring */
          if (ring || (txq->ift_db_pending >= max) || (TXQ_AVAIL(txq) <= MAX_TX_DESC(ctx) + 2)) {
  
                  /*
                   * 'npending' is used if the card's doorbell is in terms of the number of descriptors
                   * pending flush (BRCM). 'pidx' is used in cases where the card's doorbeel uses the
                   * producer index explicitly (INTC).
                   */
                  dbval = txq->ift_npending ? txq->ift_npending : txq->ift_pidx;
                  bus_dmamap_sync(txq->ift_ifdi->idi_tag, txq->ift_ifdi->idi_map,
                      BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
                  ctx->isc_txd_flush(ctx->ifc_softc, txq->ift_id, dbval);
  
                  /*
                   * Absent bugs there are zero packets pending so reset pending counts to zero.
                   */
                  txq->ift_db_pending = txq->ift_npending = 0;
                  return (true);
          }
          return (false);
  }
  
  #ifdef PKT_DEBUG
  static void
  print_pkt(if_pkt_info_t pi)
  {
          printf("pi len:  %d qsidx: %d nsegs: %d ndescs: %d flags: %x pidx: %d\n",
                 pi->ipi_len, pi->ipi_qsidx, pi->ipi_nsegs, pi->ipi_ndescs, pi->ipi_flags, pi->ipi_pidx);
          printf("pi new_pidx: %d csum_flags: %lx tso_segsz: %d mflags: %x vtag: %d\n",
                 pi->ipi_new_pidx, pi->ipi_csum_flags, pi->ipi_tso_segsz, pi->ipi_mflags, pi->ipi_vtag);
          printf("pi etype: %d ehdrlen: %d ip_hlen: %d ipproto: %d\n",
                 pi->ipi_etype, pi->ipi_ehdrlen, pi->ipi_ip_hlen, pi->ipi_ipproto);
  }
  #endif
  
  #define IS_TSO4(pi) ((pi)->ipi_csum_flags & CSUM_IP_TSO)
  #define IS_TX_OFFLOAD4(pi) ((pi)->ipi_csum_flags & (CSUM_IP_TCP | CSUM_IP_TSO))
  #define IS_TSO6(pi) ((pi)->ipi_csum_flags & CSUM_IP6_TSO)
  #define IS_TX_OFFLOAD6(pi) ((pi)->ipi_csum_flags & (CSUM_IP6_TCP | CSUM_IP6_TSO))
  
  /**
   * Parses out ethernet header information in the given mbuf.
   * Returns in pi: ipi_etype (EtherType) and ipi_ehdrlen (Ethernet header length)
   *
   * This will account for the VLAN header if present.
   *
   * XXX: This doesn't handle QinQ, which could prevent TX offloads for those
   * types of packets.
   */
  static int
  iflib_parse_ether_header(if_pkt_info_t pi, struct mbuf **mp, uint64_t *pullups)
  {
          struct ether_vlan_header *eh;
          struct mbuf *m;
  
          m = *mp;
          if (__predict_false(m->m_len < sizeof(*eh))) {
                  (*pullups)++;
                  if (__predict_false((m = m_pullup(m, sizeof(*eh))) == NULL))
                          return (ENOMEM);
          }
          eh = mtod(m, struct ether_vlan_header *);
          if (eh->evl_encap_proto == htons(ETHERTYPE_VLAN)) {
                  pi->ipi_etype = ntohs(eh->evl_proto);
                  pi->ipi_ehdrlen = ETHER_HDR_LEN + ETHER_VLAN_ENCAP_LEN;
          } else {
                  pi->ipi_etype = ntohs(eh->evl_encap_proto);
                  pi->ipi_ehdrlen = ETHER_HDR_LEN;
          }
          *mp = m;
  
          return (0);
  }
  
  /**
   * Parse up to the L3 header and extract IPv4/IPv6 header information into pi.
   * Currently this information includes: IP ToS value, IP header version/presence
   *
   * This is missing some checks and doesn't edit the packet content as it goes,
   * unlike iflib_parse_header(), in order to keep the amount of code here minimal.
   */
  static int
  iflib_parse_header_partial(if_pkt_info_t pi, struct mbuf **mp, uint64_t *pullups)
  {
          struct mbuf *m;
          int err;
  
          *pullups = 0;
          m = *mp;
          if (!M_WRITABLE(m)) {
                  if ((m = m_dup(m, M_NOWAIT)) == NULL) {
                          return (ENOMEM);
                  } else {
                          m_freem(*mp);
                          DBG_COUNTER_INC(tx_frees);
                          *mp = m;
                  }
          }
  
          /* Fills out pi->ipi_etype */
          err = iflib_parse_ether_header(pi, mp, pullups);
          if (err)
                  return (err);
          m = *mp;
  
          switch (pi->ipi_etype) {
  #ifdef INET
          case ETHERTYPE_IP:
          {
                  struct mbuf *n;
                  struct ip *ip = NULL;
                  int miniplen;
  
                  miniplen = min(m->m_pkthdr.len, pi->ipi_ehdrlen + sizeof(*ip));
                  if (__predict_false(m->m_len < miniplen)) {
                          /*
                           * Check for common case where the first mbuf only contains
                           * the Ethernet header
                           */
                          if (m->m_len == pi->ipi_ehdrlen) {
                                  n = m->m_next;
                                  MPASS(n);
                                  /* If next mbuf contains at least the minimal IP header, then stop */
                                  if (n->m_len >= sizeof(*ip)) {
                                          ip = (struct ip *)n->m_data;
                                  } else {
                                          (*pullups)++;
                                          if (__predict_false((m = m_pullup(m, miniplen)) == NULL))
                                                  return (ENOMEM);
                                          ip = (struct ip *)(m->m_data + pi->ipi_ehdrlen);
                                  }
                          } else {
                                  (*pullups)++;
                                  if (__predict_false((m = m_pullup(m, miniplen)) == NULL))
                                          return (ENOMEM);
                                  ip = (struct ip *)(m->m_data + pi->ipi_ehdrlen);
                          }
                  } else {
                          ip = (struct ip *)(m->m_data + pi->ipi_ehdrlen);
                  }
  
                  /* Have the IPv4 header w/ no options here */
                  pi->ipi_ip_hlen = ip->ip_hl << 2;
                  pi->ipi_ipproto = ip->ip_p;
                  pi->ipi_ip_tos = ip->ip_tos;
                  pi->ipi_flags |= IPI_TX_IPV4;
  
                  break;
          }
  #endif
  #ifdef INET6
          case ETHERTYPE_IPV6:
          {
                  struct ip6_hdr *ip6;
  
                  if (__predict_false(m->m_len < pi->ipi_ehdrlen + sizeof(struct ip6_hdr))) {
                          (*pullups)++;
                          if (__predict_false((m = m_pullup(m, pi->ipi_ehdrlen + sizeof(struct ip6_hdr))) == NULL))
                                  return (ENOMEM);
                  }
                  ip6 = (struct ip6_hdr *)(m->m_data + pi->ipi_ehdrlen);
  
                  /* Have the IPv6 fixed header here */
                  pi->ipi_ip_hlen = sizeof(struct ip6_hdr);
                  pi->ipi_ipproto = ip6->ip6_nxt;
                  pi->ipi_ip_tos = IPV6_TRAFFIC_CLASS(ip6);
                  pi->ipi_flags |= IPI_TX_IPV6;
  
                  break;
          }
  #endif
          default:
                  pi->ipi_csum_flags &= ~CSUM_OFFLOAD;
                  pi->ipi_ip_hlen = 0;
                  break;
          }
          *mp = m;
  
          return (0);
  
  }
  
  static int
  iflib_parse_header(iflib_txq_t txq, if_pkt_info_t pi, struct mbuf **mp)
  {
          if_shared_ctx_t sctx = txq->ift_ctx->ifc_sctx;
          struct mbuf *m;
          int err;
  
          m = *mp;
          if ((sctx->isc_flags & IFLIB_NEED_SCRATCH) &&
              M_WRITABLE(m) == 0) {
                  if ((m = m_dup(m, M_NOWAIT)) == NULL) {
                          return (ENOMEM);
                  } else {
                          m_freem(*mp);
                          DBG_COUNTER_INC(tx_frees);
                          *mp = m;
                  }
          }
  
          /* Fills out pi->ipi_etype */
          err = iflib_parse_ether_header(pi, mp, &txq->ift_pullups);
          if (__predict_false(err))
                  return (err);
          m = *mp;
  
          switch (pi->ipi_etype) {
  #ifdef INET
          case ETHERTYPE_IP:
          {
                  struct mbuf *n;
                  struct ip *ip = NULL;
                  struct tcphdr *th = NULL;
                  int minthlen;
  
                  minthlen = min(m->m_pkthdr.len, pi->ipi_ehdrlen + sizeof(*ip) + sizeof(*th));
                  if (__predict_false(m->m_len < minthlen)) {
                          /*
                           * if this code bloat is causing too much of a hit
                           * move it to a separate function and mark it noinline
                           */
                          if (m->m_len == pi->ipi_ehdrlen) {
                                  n = m->m_next;
                                  MPASS(n);
                                  if (n->m_len >= sizeof(*ip))  {
                                          ip = (struct ip *)n->m_data;
                                          if (n->m_len >= (ip->ip_hl << 2) + sizeof(*th))
                                                  th = (struct tcphdr *)((caddr_t)ip + (ip->ip_hl << 2));
                                  } else {
                                          txq->ift_pullups++;
                                          if (__predict_false((m = m_pullup(m, minthlen)) == NULL))
                                                  return (ENOMEM);
                                          ip = (struct ip *)(m->m_data + pi->ipi_ehdrlen);
                                  }
                          } else {
                                  txq->ift_pullups++;
                                  if (__predict_false((m = m_pullup(m, minthlen)) == NULL))
                                          return (ENOMEM);
                                  ip = (struct ip *)(m->m_data + pi->ipi_ehdrlen);
                                  if (m->m_len >= (ip->ip_hl << 2) + sizeof(*th))
                                          th = (struct tcphdr *)((caddr_t)ip + (ip->ip_hl << 2));
                          }
                  } else {
                          ip = (struct ip *)(m->m_data + pi->ipi_ehdrlen);
                          if (m->m_len >= (ip->ip_hl << 2) + sizeof(*th))
                                  th = (struct tcphdr *)((caddr_t)ip + (ip->ip_hl << 2));
                  }
                  pi->ipi_ip_hlen = ip->ip_hl << 2;
                  pi->ipi_ipproto = ip->ip_p;
                  pi->ipi_ip_tos = ip->ip_tos;
                  pi->ipi_flags |= IPI_TX_IPV4;
  
                  /* TCP checksum offload may require TCP header length */
                  if (IS_TX_OFFLOAD4(pi)) {
                          if (__predict_true(pi->ipi_ipproto == IPPROTO_TCP)) {
                                  if (__predict_false(th == NULL)) {
                                          txq->ift_pullups++;
                                          if (__predict_false((m = m_pullup(m, (ip->ip_hl << 2) + sizeof(*th))) == NULL))
                                                  return (ENOMEM);
                                          th = (struct tcphdr *)((caddr_t)ip + pi->ipi_ip_hlen);
                                  }
                                  pi->ipi_tcp_hflags = th->th_flags;
                                  pi->ipi_tcp_hlen = th->th_off << 2;
                                  pi->ipi_tcp_seq = th->th_seq;
                          }
                          if (IS_TSO4(pi)) {
                                  if (__predict_false(ip->ip_p != IPPROTO_TCP))
                                          return (ENXIO);
                                  /*
                                   * TSO always requires hardware checksum offload.
                                   */
                                  pi->ipi_csum_flags |= (CSUM_IP_TCP | CSUM_IP);
                                  th->th_sum = in_pseudo(ip->ip_src.s_addr,
                                                         ip->ip_dst.s_addr, htons(IPPROTO_TCP));
                                  pi->ipi_tso_segsz = m->m_pkthdr.tso_segsz;
                                  if (sctx->isc_flags & IFLIB_TSO_INIT_IP) {
                                          ip->ip_sum = 0;
                                          ip->ip_len = htons(pi->ipi_ip_hlen + pi->ipi_tcp_hlen + pi->ipi_tso_segsz);
                                  }
                          }
                  }
                  if ((sctx->isc_flags & IFLIB_NEED_ZERO_CSUM) && (pi->ipi_csum_flags & CSUM_IP))
                         ip->ip_sum = 0;
  
                  break;
          }
  #endif
  #ifdef INET6
          case ETHERTYPE_IPV6:
          {
                  struct ip6_hdr *ip6 = (struct ip6_hdr *)(m->m_data + pi->ipi_ehdrlen);
                  struct tcphdr *th;
                  pi->ipi_ip_hlen = sizeof(struct ip6_hdr);
  
                  if (__predict_false(m->m_len < pi->ipi_ehdrlen + sizeof(struct ip6_hdr))) {
                          txq->ift_pullups++;
                          if (__predict_false((m = m_pullup(m, pi->ipi_ehdrlen + sizeof(struct ip6_hdr))) == NULL))
                                  return (ENOMEM);
                  }
                  th = (struct tcphdr *)((caddr_t)ip6 + pi->ipi_ip_hlen);
  
                  /* XXX-BZ this will go badly in case of ext hdrs. */
                  pi->ipi_ipproto = ip6->ip6_nxt;
                  pi->ipi_ip_tos = IPV6_TRAFFIC_CLASS(ip6);
                  pi->ipi_flags |= IPI_TX_IPV6;
  
                  /* TCP checksum offload may require TCP header length */
                  if (IS_TX_OFFLOAD6(pi)) {
                          if (pi->ipi_ipproto == IPPROTO_TCP) {
                                  if (__predict_false(m->m_len < pi->ipi_ehdrlen + sizeof(struct ip6_hdr) + sizeof(struct tcphdr))) {
                                          txq->ift_pullups++;
                                          if (__predict_false((m = m_pullup(m, pi->ipi_ehdrlen + sizeof(struct ip6_hdr) + sizeof(struct tcphdr))) == NULL))
                                                  return (ENOMEM);
                                  }
                                  pi->ipi_tcp_hflags = th->th_flags;
                                  pi->ipi_tcp_hlen = th->th_off << 2;
                                  pi->ipi_tcp_seq = th->th_seq;
                          }
                          if (IS_TSO6(pi)) {
                                  if (__predict_false(ip6->ip6_nxt != IPPROTO_TCP))
                                          return (ENXIO);
                                  /*
                                   * TSO always requires hardware checksum offload.
                                   */
                                  pi->ipi_csum_flags |= CSUM_IP6_TCP;
                                  th->th_sum = in6_cksum_pseudo(ip6, 0, IPPROTO_TCP, 0);
                                  pi->ipi_tso_segsz = m->m_pkthdr.tso_segsz;
                          }
                  }
                  break;
          }
  #endif
          default:
                  pi->ipi_csum_flags &= ~CSUM_OFFLOAD;
                  pi->ipi_ip_hlen = 0;
                  break;
          }
          *mp = m;
  
          return (0);
  }
  
  /*
   * If dodgy hardware rejects the scatter gather chain we've handed it
   * we'll need to remove the mbuf chain from ifsg_m[] before we can add the
   * m_defrag'd mbufs
   */
  static __noinline struct mbuf *
  iflib_remove_mbuf(iflib_txq_t txq)
  {
          int ntxd, pidx;
          struct mbuf *m, **ifsd_m;
  
          ifsd_m = txq->ift_sds.ifsd_m;
          ntxd = txq->ift_size;
          pidx = txq->ift_pidx & (ntxd - 1);
          ifsd_m = txq->ift_sds.ifsd_m;
          m = ifsd_m[pidx];
          ifsd_m[pidx] = NULL;
          bus_dmamap_unload(txq->ift_buf_tag, txq->ift_sds.ifsd_map[pidx]);
          if (txq->ift_sds.ifsd_tso_map != NULL)
                  bus_dmamap_unload(txq->ift_tso_buf_tag,
                      txq->ift_sds.ifsd_tso_map[pidx]);
  #if MEMORY_LOGGING
          txq->ift_dequeued++;
  #endif
          return (m);
  }
  
  static inline caddr_t
  calc_next_txd(iflib_txq_t txq, int cidx, uint8_t qid)
  {
          qidx_t size;
          int ntxd;
          caddr_t start, end, cur, next;
  
          ntxd = txq->ift_size;
          size = txq->ift_txd_size[qid];
          start = txq->ift_ifdi[qid].idi_vaddr;
  
          if (__predict_false(size == 0))
                  return (start);
          cur = start + size*cidx;
          end = start + size*ntxd;
          next = CACHE_PTR_NEXT(cur);
          return (next < end ? next : start);
  }
  
  /*
   * Pad an mbuf to ensure a minimum ethernet frame size.
   * min_frame_size is the frame size (less CRC) to pad the mbuf to
   */
  static __noinline int
  iflib_ether_pad(device_t dev, struct mbuf **m_head, uint16_t min_frame_size)
  {
          /*
           * 18 is enough bytes to pad an ARP packet to 46 bytes, and
           * and ARP message is the smallest common payload I can think of
           */
          static char pad[18];    /* just zeros */
          int n;
          struct mbuf *new_head;
  
          if (!M_WRITABLE(*m_head)) {
                  new_head = m_dup(*m_head, M_NOWAIT);
                  if (new_head == NULL) {
                          m_freem(*m_head);
                          device_printf(dev, "cannot pad short frame, m_dup() failed");
                          DBG_COUNTER_INC(encap_pad_mbuf_fail);
                          DBG_COUNTER_INC(tx_frees);
                          return ENOMEM;
                  }
                  m_freem(*m_head);
                  *m_head = new_head;
          }
  
          for (n = min_frame_size - (*m_head)->m_pkthdr.len;
               n > 0; n -= sizeof(pad))
                  if (!m_append(*m_head, min(n, sizeof(pad)), pad))
                          break;
  
          if (n > 0) {
                  m_freem(*m_head);
                  device_printf(dev, "cannot pad short frame\n");
                  DBG_COUNTER_INC(encap_pad_mbuf_fail);
                  DBG_COUNTER_INC(tx_frees);
                  return (ENOBUFS);
          }
  
          return 0;
  }
  
  static int
  iflib_encap(iflib_txq_t txq, struct mbuf **m_headp)
  {
          if_ctx_t                ctx;
          if_shared_ctx_t         sctx;
          if_softc_ctx_t          scctx;
          bus_dma_tag_t           buf_tag;
          bus_dma_segment_t       *segs;
          struct mbuf             *m_head, **ifsd_m;
          void                    *next_txd;
          bus_dmamap_t            map;
          struct if_pkt_info      pi;
          int remap = 0;
          int err, nsegs, ndesc, max_segs, pidx, cidx, next, ntxd;
  
          ctx = txq->ift_ctx;
          sctx = ctx->ifc_sctx;
          scctx = &ctx->ifc_softc_ctx;
          segs = txq->ift_segs;
          ntxd = txq->ift_size;
          m_head = *m_headp;
          map = NULL;
  
          /*
           * If we're doing TSO the next descriptor to clean may be quite far ahead
           */
          cidx = txq->ift_cidx;
          pidx = txq->ift_pidx;
          if (ctx->ifc_flags & IFC_PREFETCH) {
                  next = (cidx + CACHE_PTR_INCREMENT) & (ntxd-1);
                  if (!(ctx->ifc_flags & IFLIB_HAS_TXCQ)) {
                          next_txd = calc_next_txd(txq, cidx, 0);
                          prefetch(next_txd);
                  }
  
                  /* prefetch the next cache line of mbuf pointers and flags */
                  prefetch(&txq->ift_sds.ifsd_m[next]);
                  prefetch(&txq->ift_sds.ifsd_map[next]);
                  next = (cidx + CACHE_LINE_SIZE) & (ntxd-1);
          }
          map = txq->ift_sds.ifsd_map[pidx];
          ifsd_m = txq->ift_sds.ifsd_m;
  
          if (m_head->m_pkthdr.csum_flags & CSUM_TSO) {
                  buf_tag = txq->ift_tso_buf_tag;
                  max_segs = scctx->isc_tx_tso_segments_max;
                  map = txq->ift_sds.ifsd_tso_map[pidx];
                  MPASS(buf_tag != NULL);
                  MPASS(max_segs > 0);
          } else {
                  buf_tag = txq->ift_buf_tag;
                  max_segs = scctx->isc_tx_nsegments;
                  map = txq->ift_sds.ifsd_map[pidx];
          }
          if ((sctx->isc_flags & IFLIB_NEED_ETHER_PAD) &&
              __predict_false(m_head->m_pkthdr.len < scctx->isc_min_frame_size)) {
                  err = iflib_ether_pad(ctx->ifc_dev, m_headp, scctx->isc_min_frame_size);
                  if (err) {
                          DBG_COUNTER_INC(encap_txd_encap_fail);
                          return err;
                  }
          }
          m_head = *m_headp;
  
          pkt_info_zero(&pi);
          pi.ipi_mflags = (m_head->m_flags & (M_VLANTAG|M_BCAST|M_MCAST));
          pi.ipi_pidx = pidx;
          pi.ipi_qsidx = txq->ift_id;
          pi.ipi_len = m_head->m_pkthdr.len;
          pi.ipi_csum_flags = m_head->m_pkthdr.csum_flags;
          pi.ipi_vtag = M_HAS_VLANTAG(m_head) ? m_head->m_pkthdr.ether_vtag : 0;
  
          /* deliberate bitwise OR to make one condition */
          if (__predict_true((pi.ipi_csum_flags | pi.ipi_vtag))) {
                  if (__predict_false((err = iflib_parse_header(txq, &pi, m_headp)) != 0)) {
                          DBG_COUNTER_INC(encap_txd_encap_fail);
                          return (err);
                  }
                  m_head = *m_headp;
          }
  
  retry:
          err = bus_dmamap_load_mbuf_sg(buf_tag, map, m_head, segs, &nsegs,
              BUS_DMA_NOWAIT);
  defrag:
          if (__predict_false(err)) {
                  switch (err) {
                  case EFBIG:
                          /* try collapse once and defrag once */
                          if (remap == 0) {
                                  m_head = m_collapse(*m_headp, M_NOWAIT, max_segs);
                                  /* try defrag if collapsing fails */
                                  if (m_head == NULL)
                                          remap++;
                          }
                          if (remap == 1) {
                                  txq->ift_mbuf_defrag++;
                                  m_head = m_defrag(*m_headp, M_NOWAIT);
                          }
                          /*
                           * remap should never be >1 unless bus_dmamap_load_mbuf_sg
                           * failed to map an mbuf that was run through m_defrag
                           */
                          MPASS(remap <= 1);
                          if (__predict_false(m_head == NULL || remap > 1))
                                  goto defrag_failed;
                          remap++;
                          *m_headp = m_head;
                          goto retry;
                          break;
                  case ENOMEM:
                          txq->ift_no_tx_dma_setup++;
                          break;
                  default:
                          txq->ift_no_tx_dma_setup++;
                          m_freem(*m_headp);
                          DBG_COUNTER_INC(tx_frees);
                          *m_headp = NULL;
                          break;
                  }
                  txq->ift_map_failed++;
                  DBG_COUNTER_INC(encap_load_mbuf_fail);
                  DBG_COUNTER_INC(encap_txd_encap_fail);
                  return (err);
          }
          ifsd_m[pidx] = m_head;
          /*
           * XXX assumes a 1 to 1 relationship between segments and
           *        descriptors - this does not hold true on all drivers, e.g.
           *        cxgb
           */
          if (__predict_false(nsegs + 2 > TXQ_AVAIL(txq))) {
                  txq->ift_no_desc_avail++;
                  bus_dmamap_unload(buf_tag, map);
                  DBG_COUNTER_INC(encap_txq_avail_fail);
                  DBG_COUNTER_INC(encap_txd_encap_fail);
                  if ((txq->ift_task.gt_task.ta_flags & TASK_ENQUEUED) == 0)
                          GROUPTASK_ENQUEUE(&txq->ift_task);
                  return (ENOBUFS);
          }
          /*
           * On Intel cards we can greatly reduce the number of TX interrupts
           * we see by only setting report status on every Nth descriptor.
           * However, this also means that the driver will need to keep track
           * of the descriptors that RS was set on to check them for the DD bit.
           */
          txq->ift_rs_pending += nsegs + 1;
          if (txq->ift_rs_pending > TXQ_MAX_RS_DEFERRED(txq) ||
               iflib_no_tx_batch || (TXQ_AVAIL(txq) - nsegs) <= MAX_TX_DESC(ctx) + 2) {
                  pi.ipi_flags |= IPI_TX_INTR;
                  txq->ift_rs_pending = 0;
          }
  
          pi.ipi_segs = segs;
          pi.ipi_nsegs = nsegs;
  
          MPASS(pidx >= 0 && pidx < txq->ift_size);
  #ifdef PKT_DEBUG
          print_pkt(&pi);
  #endif
          if ((err = ctx->isc_txd_encap(ctx->ifc_softc, &pi)) == 0) {
                  bus_dmamap_sync(buf_tag, map, BUS_DMASYNC_PREWRITE);
                  DBG_COUNTER_INC(tx_encap);
                  MPASS(pi.ipi_new_pidx < txq->ift_size);
  
                  ndesc = pi.ipi_new_pidx - pi.ipi_pidx;
                  if (pi.ipi_new_pidx < pi.ipi_pidx) {
                          ndesc += txq->ift_size;
                          txq->ift_gen = 1;
                  }
                  /*
                   * drivers can need as many as 
                   * two sentinels
                   */
                  MPASS(ndesc <= pi.ipi_nsegs + 2);
                  MPASS(pi.ipi_new_pidx != pidx);
                  MPASS(ndesc > 0);
                  txq->ift_in_use += ndesc;
                  txq->ift_db_pending += ndesc;
  
                  /*
                   * We update the last software descriptor again here because there may
                   * be a sentinel and/or there may be more mbufs than segments
                   */
                  txq->ift_pidx = pi.ipi_new_pidx;
                  txq->ift_npending += pi.ipi_ndescs;
          } else {
                  *m_headp = m_head = iflib_remove_mbuf(txq);
                  if (err == EFBIG) {
                          txq->ift_txd_encap_efbig++;
                          if (remap < 2) {
                                  remap = 1;
                                  goto defrag;
                          }
                  }
                  goto defrag_failed;
          }
          /*
           * err can't possibly be non-zero here, so we don't neet to test it
           * to see if we need to DBG_COUNTER_INC(encap_txd_encap_fail).
           */
          return (err);
  
  defrag_failed:
          txq->ift_mbuf_defrag_failed++;
          txq->ift_map_failed++;
          m_freem(*m_headp);
          DBG_COUNTER_INC(tx_frees);
          *m_headp = NULL;
          DBG_COUNTER_INC(encap_txd_encap_fail);
          return (ENOMEM);
  }
  
  static void
  iflib_tx_desc_free(iflib_txq_t txq, int n)
  {
          uint32_t qsize, cidx, mask, gen;
          struct mbuf *m, **ifsd_m;
          bool do_prefetch;
  
          cidx = txq->ift_cidx;
          gen = txq->ift_gen;
          qsize = txq->ift_size;
          mask = qsize-1;
          ifsd_m = txq->ift_sds.ifsd_m;
          do_prefetch = (txq->ift_ctx->ifc_flags & IFC_PREFETCH);
  
          while (n-- > 0) {
                  if (do_prefetch) {
                          prefetch(ifsd_m[(cidx + 3) & mask]);
                          prefetch(ifsd_m[(cidx + 4) & mask]);
                  }
                  if ((m = ifsd_m[cidx]) != NULL) {
                          prefetch(&ifsd_m[(cidx + CACHE_PTR_INCREMENT) & mask]);
                          if (m->m_pkthdr.csum_flags & CSUM_TSO) {
                                  bus_dmamap_sync(txq->ift_tso_buf_tag,
                                      txq->ift_sds.ifsd_tso_map[cidx],
                                      BUS_DMASYNC_POSTWRITE);
                                  bus_dmamap_unload(txq->ift_tso_buf_tag,
                                      txq->ift_sds.ifsd_tso_map[cidx]);
                          } else {
                                  bus_dmamap_sync(txq->ift_buf_tag,
                                      txq->ift_sds.ifsd_map[cidx],
                                      BUS_DMASYNC_POSTWRITE);
                                  bus_dmamap_unload(txq->ift_buf_tag,
                                      txq->ift_sds.ifsd_map[cidx]);
                          }
                          /* XXX we don't support any drivers that batch packets yet */
                          MPASS(m->m_nextpkt == NULL);
                          m_freem(m);
                          ifsd_m[cidx] = NULL;
  #if MEMORY_LOGGING
                          txq->ift_dequeued++;
  #endif
                          DBG_COUNTER_INC(tx_frees);
                  }
                  if (__predict_false(++cidx == qsize)) {
                          cidx = 0;
                          gen = 0;
                  }
          }
          txq->ift_cidx = cidx;
          txq->ift_gen = gen;
  }
  
  static __inline int
  iflib_completed_tx_reclaim(iflib_txq_t txq, int thresh)
  {
          int reclaim;
          if_ctx_t ctx = txq->ift_ctx;
  
          KASSERT(thresh >= 0, ("invalid threshold to reclaim"));
          MPASS(thresh /*+ MAX_TX_DESC(txq->ift_ctx) */ < txq->ift_size);
  
          /*
           * Need a rate-limiting check so that this isn't called every time
           */
          iflib_tx_credits_update(ctx, txq);
          reclaim = DESC_RECLAIMABLE(txq);
  
          if (reclaim <= thresh /* + MAX_TX_DESC(txq->ift_ctx) */) {
  #ifdef INVARIANTS
                  if (iflib_verbose_debug) {
                          printf("%s processed=%ju cleaned=%ju tx_nsegments=%d reclaim=%d thresh=%d\n", __FUNCTION__,
                                 txq->ift_processed, txq->ift_cleaned, txq->ift_ctx->ifc_softc_ctx.isc_tx_nsegments,
                                 reclaim, thresh);
                  }
  #endif
                  return (0);
          }
          iflib_tx_desc_free(txq, reclaim);
          txq->ift_cleaned += reclaim;
          txq->ift_in_use -= reclaim;
  
          return (reclaim);
  }
  
  static struct mbuf **
  _ring_peek_one(struct ifmp_ring *r, int cidx, int offset, int remaining)
  {
          int next, size;
          struct mbuf **items;
  
          size = r->size;
          next = (cidx + CACHE_PTR_INCREMENT) & (size-1);
          items = __DEVOLATILE(struct mbuf **, &r->items[0]);
  
          prefetch(items[(cidx + offset) & (size-1)]);
          if (remaining > 1) {
                  prefetch2cachelines(&items[next]);
                  prefetch2cachelines(items[(cidx + offset + 1) & (size-1)]);
                  prefetch2cachelines(items[(cidx + offset + 2) & (size-1)]);
                  prefetch2cachelines(items[(cidx + offset + 3) & (size-1)]);
          }
          return (__DEVOLATILE(struct mbuf **, &r->items[(cidx + offset) & (size-1)]));
  }
  
  static void
  iflib_txq_check_drain(iflib_txq_t txq, int budget)
  {
  
          ifmp_ring_check_drainage(txq->ift_br, budget);
  }
  
  static uint32_t
  iflib_txq_can_drain(struct ifmp_ring *r)
  {
          iflib_txq_t txq = r->cookie;
          if_ctx_t ctx = txq->ift_ctx;
  
          if (TXQ_AVAIL(txq) > MAX_TX_DESC(ctx) + 2)
                  return (1);
          bus_dmamap_sync(txq->ift_ifdi->idi_tag, txq->ift_ifdi->idi_map,
              BUS_DMASYNC_POSTREAD);
          return (ctx->isc_txd_credits_update(ctx->ifc_softc, txq->ift_id,
              false));
  }
  
  static uint32_t
  iflib_txq_drain(struct ifmp_ring *r, uint32_t cidx, uint32_t pidx)
  {
          iflib_txq_t txq = r->cookie;
          if_ctx_t ctx = txq->ift_ctx;
          if_t ifp = ctx->ifc_ifp;
          struct mbuf *m, **mp;
          int avail, bytes_sent, skipped, count, err, i;
          int mcast_sent, pkt_sent, reclaimed;
          bool do_prefetch, rang, ring;
  
          if (__predict_false(!(if_getdrvflags(ifp) & IFF_DRV_RUNNING) ||
                              !LINK_ACTIVE(ctx))) {
                  DBG_COUNTER_INC(txq_drain_notready);
                  return (0);
          }
          reclaimed = iflib_completed_tx_reclaim(txq, RECLAIM_THRESH(ctx));
          rang = iflib_txd_db_check(txq, reclaimed && txq->ift_db_pending);
          avail = IDXDIFF(pidx, cidx, r->size);
  
          if (__predict_false(ctx->ifc_flags & IFC_QFLUSH)) {
                  /*
                   * The driver is unloading so we need to free all pending packets.
                   */
                  DBG_COUNTER_INC(txq_drain_flushing);
                  for (i = 0; i < avail; i++) {
                          if (__predict_true(r->items[(cidx + i) & (r->size-1)] != (void *)txq))
                                  m_freem(r->items[(cidx + i) & (r->size-1)]);
                          r->items[(cidx + i) & (r->size-1)] = NULL;
                  }
                  return (avail);
          }
  
          if (__predict_false(if_getdrvflags(ctx->ifc_ifp) & IFF_DRV_OACTIVE)) {
                  txq->ift_qstatus = IFLIB_QUEUE_IDLE;
                  CALLOUT_LOCK(txq);
                  callout_stop(&txq->ift_timer);
                  CALLOUT_UNLOCK(txq);
                  DBG_COUNTER_INC(txq_drain_oactive);
                  return (0);
          }
  
          /*
           * If we've reclaimed any packets this queue cannot be hung.
           */
          if (reclaimed)
                  txq->ift_qstatus = IFLIB_QUEUE_IDLE;
          skipped = mcast_sent = bytes_sent = pkt_sent = 0;
          count = MIN(avail, TX_BATCH_SIZE);
  #ifdef INVARIANTS
          if (iflib_verbose_debug)
                  printf("%s avail=%d ifc_flags=%x txq_avail=%d ", __FUNCTION__,
                         avail, ctx->ifc_flags, TXQ_AVAIL(txq));
  #endif
          do_prefetch = (ctx->ifc_flags & IFC_PREFETCH);
          err = 0;
          for (i = 0; i < count && TXQ_AVAIL(txq) >= MAX_TX_DESC(ctx) + 2; i++) {
                  int rem = do_prefetch ? count - i : 0;
  
                  mp = _ring_peek_one(r, cidx, i, rem);
                  MPASS(mp != NULL && *mp != NULL);
  
                  /*
                   * Completion interrupts will use the address of the txq
                   * as a sentinel to enqueue _something_ in order to acquire
                   * the lock on the mp_ring (there's no direct lock call).
                   * We obviously whave to check for these sentinel cases
                   * and skip them.
                   */
                  if (__predict_false(*mp == (struct mbuf *)txq)) {
                          skipped++;
                          continue;
                  }
                  err = iflib_encap(txq, mp);
                  if (__predict_false(err)) {
                          /* no room - bail out */
                          if (err == ENOBUFS)
                                  break;
                          skipped++;
                          /* we can't send this packet - skip it */
                          continue;
                  }
                  pkt_sent++;
                  m = *mp;
                  DBG_COUNTER_INC(tx_sent);
                  bytes_sent += m->m_pkthdr.len;
                  mcast_sent += !!(m->m_flags & M_MCAST);
  
                  if (__predict_false(!(if_getdrvflags(ifp) & IFF_DRV_RUNNING)))
                          break;
                  ETHER_BPF_MTAP(ifp, m);
                  rang = iflib_txd_db_check(txq, false);
          }
  
          /* deliberate use of bitwise or to avoid gratuitous short-circuit */
          ring = rang ? false  : (iflib_min_tx_latency | err);
          iflib_txd_db_check(txq, ring);
          if_inc_counter(ifp, IFCOUNTER_OBYTES, bytes_sent);
          if_inc_counter(ifp, IFCOUNTER_OPACKETS, pkt_sent);
          if (mcast_sent)
                  if_inc_counter(ifp, IFCOUNTER_OMCASTS, mcast_sent);
  #ifdef INVARIANTS
          if (iflib_verbose_debug)
                  printf("consumed=%d\n", skipped + pkt_sent);
  #endif
          return (skipped + pkt_sent);
  }
  
  static uint32_t
  iflib_txq_drain_always(struct ifmp_ring *r)
  {
          return (1);
  }
  
  static uint32_t
  iflib_txq_drain_free(struct ifmp_ring *r, uint32_t cidx, uint32_t pidx)
  {
          int i, avail;
          struct mbuf **mp;
          iflib_txq_t txq;
  
          txq = r->cookie;
  
          txq->ift_qstatus = IFLIB_QUEUE_IDLE;
          CALLOUT_LOCK(txq);
          callout_stop(&txq->ift_timer);
          CALLOUT_UNLOCK(txq);
  
          avail = IDXDIFF(pidx, cidx, r->size);
          for (i = 0; i < avail; i++) {
                  mp = _ring_peek_one(r, cidx, i, avail - i);
                  if (__predict_false(*mp == (struct mbuf *)txq))
                          continue;
                  m_freem(*mp);
                  DBG_COUNTER_INC(tx_frees);
          }
          MPASS(ifmp_ring_is_stalled(r) == 0);
          return (avail);
  }
  
  static void
  iflib_ifmp_purge(iflib_txq_t txq)
  {
          struct ifmp_ring *r;
  
          r = txq->ift_br;
          r->drain = iflib_txq_drain_free;
          r->can_drain = iflib_txq_drain_always;
  
          ifmp_ring_check_drainage(r, r->size);
  
          r->drain = iflib_txq_drain;
          r->can_drain = iflib_txq_can_drain;
  }
  
  static void
  _task_fn_tx(void *context)
  {
          iflib_txq_t txq = context;
          if_ctx_t ctx = txq->ift_ctx;
          if_t ifp = ctx->ifc_ifp;
          int abdicate = ctx->ifc_sysctl_tx_abdicate;
  
  #ifdef IFLIB_DIAGNOSTICS
          txq->ift_cpu_exec_count[curcpu]++;
  #endif
          if (!(if_getdrvflags(ifp) & IFF_DRV_RUNNING))
                  return;
  #ifdef DEV_NETMAP
          if ((if_getcapenable(ifp) & IFCAP_NETMAP) &&
              netmap_tx_irq(ifp, txq->ift_id))
                  goto skip_ifmp;
  #endif
  #ifdef ALTQ
          if (ALTQ_IS_ENABLED(&ifp->if_snd)) /* XXX - DRVAPI */
                  iflib_altq_if_start(ifp);
  #endif
          if (txq->ift_db_pending)
                  ifmp_ring_enqueue(txq->ift_br, (void **)&txq, 1, TX_BATCH_SIZE, abdicate);
          else if (!abdicate)
                  ifmp_ring_check_drainage(txq->ift_br, TX_BATCH_SIZE);
          /*
           * When abdicating, we always need to check drainage, not just when we don't enqueue
           */
          if (abdicate)
                  ifmp_ring_check_drainage(txq->ift_br, TX_BATCH_SIZE);
  #ifdef DEV_NETMAP
  skip_ifmp:
  #endif
          if (ctx->ifc_flags & IFC_LEGACY)
                  IFDI_INTR_ENABLE(ctx);
          else
                  IFDI_TX_QUEUE_INTR_ENABLE(ctx, txq->ift_id);
  }
  
  static void
  _task_fn_rx(void *context)
  {
          iflib_rxq_t rxq = context;
          if_ctx_t ctx = rxq->ifr_ctx;
          uint8_t more;
          uint16_t budget;
  #ifdef DEV_NETMAP
          u_int work = 0;
          int nmirq;
  #endif
  
  #ifdef IFLIB_DIAGNOSTICS
          rxq->ifr_cpu_exec_count[curcpu]++;
  #endif
          DBG_COUNTER_INC(task_fn_rxs);
          if (__predict_false(!(if_getdrvflags(ctx->ifc_ifp) & IFF_DRV_RUNNING)))
                  return;
  #ifdef DEV_NETMAP
          nmirq = netmap_rx_irq(ctx->ifc_ifp, rxq->ifr_id, &work);
          if (nmirq != NM_IRQ_PASS) {
                  more = (nmirq == NM_IRQ_RESCHED) ? IFLIB_RXEOF_MORE : 0;
                  goto skip_rxeof;
          }
  #endif
          budget = ctx->ifc_sysctl_rx_budget;
          if (budget == 0)
                  budget = 16;    /* XXX */
          more = iflib_rxeof(rxq, budget);
  #ifdef DEV_NETMAP
  skip_rxeof:
  #endif
          if ((more & IFLIB_RXEOF_MORE) == 0) {
                  if (ctx->ifc_flags & IFC_LEGACY)
                          IFDI_INTR_ENABLE(ctx);
                  else
                          IFDI_RX_QUEUE_INTR_ENABLE(ctx, rxq->ifr_id);
                  DBG_COUNTER_INC(rx_intr_enables);
          }
          if (__predict_false(!(if_getdrvflags(ctx->ifc_ifp) & IFF_DRV_RUNNING)))
                  return;
  
          if (more & IFLIB_RXEOF_MORE)
                  GROUPTASK_ENQUEUE(&rxq->ifr_task);
          else if (more & IFLIB_RXEOF_EMPTY)
                  callout_reset_curcpu(&rxq->ifr_watchdog, 1, &_task_fn_rx_watchdog, rxq);
  }
  
  static void
  _task_fn_admin(void *context)
  {
          if_ctx_t ctx = context;
          if_softc_ctx_t sctx = &ctx->ifc_softc_ctx;
          iflib_txq_t txq;
          int i;
          bool oactive, running, do_reset, do_watchdog, in_detach;
  
          STATE_LOCK(ctx);
          running = (if_getdrvflags(ctx->ifc_ifp) & IFF_DRV_RUNNING);
          oactive = (if_getdrvflags(ctx->ifc_ifp) & IFF_DRV_OACTIVE);
          do_reset = (ctx->ifc_flags & IFC_DO_RESET);
          do_watchdog = (ctx->ifc_flags & IFC_DO_WATCHDOG);
          in_detach = (ctx->ifc_flags & IFC_IN_DETACH);
          ctx->ifc_flags &= ~(IFC_DO_RESET|IFC_DO_WATCHDOG);
          STATE_UNLOCK(ctx);
  
          if ((!running && !oactive) && !(ctx->ifc_sctx->isc_flags & IFLIB_ADMIN_ALWAYS_RUN))
                  return;
          if (in_detach)
                  return;
  
          CTX_LOCK(ctx);
          for (txq = ctx->ifc_txqs, i = 0; i < sctx->isc_ntxqsets; i++, txq++) {
                  CALLOUT_LOCK(txq);
                  callout_stop(&txq->ift_timer);
                  CALLOUT_UNLOCK(txq);
          }
          if (ctx->ifc_sctx->isc_flags & IFLIB_HAS_ADMINCQ)
                  IFDI_ADMIN_COMPLETION_HANDLE(ctx);
          if (do_watchdog) {
                  ctx->ifc_watchdog_events++;
                  IFDI_WATCHDOG_RESET(ctx);
          }
          IFDI_UPDATE_ADMIN_STATUS(ctx);
          for (txq = ctx->ifc_txqs, i = 0; i < sctx->isc_ntxqsets; i++, txq++) {
                  callout_reset_on(&txq->ift_timer, iflib_timer_default, iflib_timer, txq,
                      txq->ift_timer.c_cpu);
          }
          IFDI_LINK_INTR_ENABLE(ctx);
          if (do_reset)
                  iflib_if_init_locked(ctx);
          CTX_UNLOCK(ctx);
  
          if (LINK_ACTIVE(ctx) == 0)
                  return;
          for (txq = ctx->ifc_txqs, i = 0; i < sctx->isc_ntxqsets; i++, txq++)
                  iflib_txq_check_drain(txq, IFLIB_RESTART_BUDGET);
  }
  
  static void
  _task_fn_iov(void *context)
  {
          if_ctx_t ctx = context;
  
          if (!(if_getdrvflags(ctx->ifc_ifp) & IFF_DRV_RUNNING) &&
              !(ctx->ifc_sctx->isc_flags & IFLIB_ADMIN_ALWAYS_RUN))
                  return;
  
          CTX_LOCK(ctx);
          IFDI_VFLR_HANDLE(ctx);
          CTX_UNLOCK(ctx);
  }
  
  static int
  iflib_sysctl_int_delay(SYSCTL_HANDLER_ARGS)
  {
          int err;
          if_int_delay_info_t info;
          if_ctx_t ctx;
  
          info = (if_int_delay_info_t)arg1;
          ctx = info->iidi_ctx;
          info->iidi_req = req;
          info->iidi_oidp = oidp;
          CTX_LOCK(ctx);
          err = IFDI_SYSCTL_INT_DELAY(ctx, info);
          CTX_UNLOCK(ctx);
          return (err);
  }
  
  /*********************************************************************
   *
   *  IFNET FUNCTIONS
   *
   **********************************************************************/
  
  static void
  iflib_if_init_locked(if_ctx_t ctx)
  {
          iflib_stop(ctx);
          iflib_init_locked(ctx);
  }
  
  static void
  iflib_if_init(void *arg)
  {
          if_ctx_t ctx = arg;
  
          CTX_LOCK(ctx);
          iflib_if_init_locked(ctx);
          CTX_UNLOCK(ctx);
  }
  
  static int
  iflib_if_transmit(if_t ifp, struct mbuf *m)
  {
          if_ctx_t ctx = if_getsoftc(ifp);
          iflib_txq_t txq;
          int err, qidx;
          int abdicate;
  
          if (__predict_false((if_getdrvflags(ifp) & IFF_DRV_RUNNING) == 0 || !LINK_ACTIVE(ctx))) {
                  DBG_COUNTER_INC(tx_frees);
                  m_freem(m);
                  return (ENETDOWN);
          }
  
          MPASS(m->m_nextpkt == NULL);
          /* ALTQ-enabled interfaces always use queue 0. */
          qidx = 0;
          /* Use driver-supplied queue selection method if it exists */
          if (ctx->isc_txq_select_v2) {
                  struct if_pkt_info pi;
                  uint64_t early_pullups = 0;
                  pkt_info_zero(&pi);
  
                  err = iflib_parse_header_partial(&pi, &m, &early_pullups);
                  if (__predict_false(err != 0)) {
                          /* Assign pullups for bad pkts to default queue */
                          ctx->ifc_txqs[0].ift_pullups += early_pullups;
                          DBG_COUNTER_INC(encap_txd_encap_fail);
                          return (err);
                  }
                  /* Let driver make queueing decision */
                  qidx = ctx->isc_txq_select_v2(ctx->ifc_softc, m, &pi);
                  ctx->ifc_txqs[qidx].ift_pullups += early_pullups;
          }
          /* Backwards compatibility w/ simpler queue select */
          else if (ctx->isc_txq_select)
                  qidx = ctx->isc_txq_select(ctx->ifc_softc, m);
          /* If not, use iflib's standard method */
          else if ((NTXQSETS(ctx) > 1) && M_HASHTYPE_GET(m) && !ALTQ_IS_ENABLED(&ifp->if_snd))
                  qidx = QIDX(ctx, m);
  
          /* Set TX queue */
          txq = &ctx->ifc_txqs[qidx];
  
  #ifdef DRIVER_BACKPRESSURE
          if (txq->ift_closed) {
                  while (m != NULL) {
                          next = m->m_nextpkt;
                          m->m_nextpkt = NULL;
                          m_freem(m);
                          DBG_COUNTER_INC(tx_frees);
                          m = next;
                  }
                  return (ENOBUFS);
          }
  #endif
  #ifdef notyet
          qidx = count = 0;
          mp = marr;
          next = m;
          do {
                  count++;
                  next = next->m_nextpkt;
          } while (next != NULL);
  
          if (count > nitems(marr))
                  if ((mp = malloc(count*sizeof(struct mbuf *), M_IFLIB, M_NOWAIT)) == NULL) {
                          /* XXX check nextpkt */
                          m_freem(m);
                          /* XXX simplify for now */
                          DBG_COUNTER_INC(tx_frees);
                          return (ENOBUFS);
                  }
          for (next = m, i = 0; next != NULL; i++) {
                  mp[i] = next;
                  next = next->m_nextpkt;
                  mp[i]->m_nextpkt = NULL;
          }
  #endif
          DBG_COUNTER_INC(tx_seen);
          abdicate = ctx->ifc_sysctl_tx_abdicate;
  
          err = ifmp_ring_enqueue(txq->ift_br, (void **)&m, 1, TX_BATCH_SIZE, abdicate);
  
          if (abdicate)
                  GROUPTASK_ENQUEUE(&txq->ift_task);
          if (err) {
                  if (!abdicate)
                          GROUPTASK_ENQUEUE(&txq->ift_task);
                  /* support forthcoming later */
  #ifdef DRIVER_BACKPRESSURE
                  txq->ift_closed = TRUE;
  #endif
                  ifmp_ring_check_drainage(txq->ift_br, TX_BATCH_SIZE);
                  m_freem(m);
                  DBG_COUNTER_INC(tx_frees);
          }
  
          return (err);
  }
  
  #ifdef ALTQ
  /*
   * The overall approach to integrating iflib with ALTQ is to continue to use
   * the iflib mp_ring machinery between the ALTQ queue(s) and the hardware
   * ring.  Technically, when using ALTQ, queueing to an intermediate mp_ring
   * is redundant/unnecessary, but doing so minimizes the amount of
   * ALTQ-specific code required in iflib.  It is assumed that the overhead of
   * redundantly queueing to an intermediate mp_ring is swamped by the
   * performance limitations inherent in using ALTQ.
   *
   * When ALTQ support is compiled in, all iflib drivers will use a transmit
   * routine, iflib_altq_if_transmit(), that checks if ALTQ is enabled for the
   * given interface.  If ALTQ is enabled for an interface, then all
   * transmitted packets for that interface will be submitted to the ALTQ
   * subsystem via IFQ_ENQUEUE().  We don't use the legacy if_transmit()
   * implementation because it uses IFQ_HANDOFF(), which will duplicatively
   * update stats that the iflib machinery handles, and which is sensitve to
   * the disused IFF_DRV_OACTIVE flag.  Additionally, iflib_altq_if_start()
   * will be installed as the start routine for use by ALTQ facilities that
   * need to trigger queue drains on a scheduled basis.
   *
   */
  static void
  iflib_altq_if_start(if_t ifp)
  {
          struct ifaltq *ifq = &ifp->if_snd; /* XXX - DRVAPI */
          struct mbuf *m;
  
          IFQ_LOCK(ifq);
          IFQ_DEQUEUE_NOLOCK(ifq, m);
          while (m != NULL) {
                  iflib_if_transmit(ifp, m);
                  IFQ_DEQUEUE_NOLOCK(ifq, m);
          }
          IFQ_UNLOCK(ifq);
  }
  
  static int
  iflib_altq_if_transmit(if_t ifp, struct mbuf *m)
  {
          int err;
  
          if (ALTQ_IS_ENABLED(&ifp->if_snd)) { /* XXX - DRVAPI */
                  IFQ_ENQUEUE(&ifp->if_snd, m, err); /* XXX - DRVAPI */
                  if (err == 0)
                          iflib_altq_if_start(ifp);
          } else
                  err = iflib_if_transmit(ifp, m);
  
          return (err);
  }
  #endif /* ALTQ */
  
  static void
  iflib_if_qflush(if_t ifp)
  {
          if_ctx_t ctx = if_getsoftc(ifp);
          iflib_txq_t txq = ctx->ifc_txqs;
          int i;
  
          STATE_LOCK(ctx);
          ctx->ifc_flags |= IFC_QFLUSH;
          STATE_UNLOCK(ctx);
          for (i = 0; i < NTXQSETS(ctx); i++, txq++)
                  while (!(ifmp_ring_is_idle(txq->ift_br) || ifmp_ring_is_stalled(txq->ift_br)))
                          iflib_txq_check_drain(txq, 0);
          STATE_LOCK(ctx);
          ctx->ifc_flags &= ~IFC_QFLUSH;
          STATE_UNLOCK(ctx);
  
          /*
           * When ALTQ is enabled, this will also take care of purging the
           * ALTQ queue(s).
           */
          if_qflush(ifp);
  }
  
  #define IFCAP_FLAGS (IFCAP_HWCSUM_IPV6 | IFCAP_HWCSUM | IFCAP_LRO | \
                       IFCAP_TSO | IFCAP_VLAN_HWTAGGING | IFCAP_HWSTATS | \
                       IFCAP_VLAN_MTU | IFCAP_VLAN_HWFILTER | \
                       IFCAP_VLAN_HWTSO | IFCAP_VLAN_HWCSUM | IFCAP_MEXTPG)
  
  static int
  iflib_if_ioctl(if_t ifp, u_long command, caddr_t data)
  {
          if_ctx_t ctx = if_getsoftc(ifp);
          struct ifreq    *ifr = (struct ifreq *)data;
  #if defined(INET) || defined(INET6)
          struct ifaddr   *ifa = (struct ifaddr *)data;
  #endif
          bool            avoid_reset = false;
          int             err = 0, reinit = 0, bits;
  
          switch (command) {
          case SIOCSIFADDR:
  #ifdef INET
                  if (ifa->ifa_addr->sa_family == AF_INET)
                          avoid_reset = true;
  #endif
  #ifdef INET6
                  if (ifa->ifa_addr->sa_family == AF_INET6)
                          avoid_reset = true;
  #endif
                  /*
                  ** Calling init results in link renegotiation,
                  ** so we avoid doing it when possible.
                  */
                  if (avoid_reset) {
                          if_setflagbits(ifp, IFF_UP,0);
                          if (!(if_getdrvflags(ifp) & IFF_DRV_RUNNING))
                                  reinit = 1;
  #ifdef INET
                          if (!(if_getflags(ifp) & IFF_NOARP))
                                  arp_ifinit(ifp, ifa);
  #endif
                  } else
                          err = ether_ioctl(ifp, command, data);
                  break;
          case SIOCSIFMTU:
                  CTX_LOCK(ctx);
                  if (ifr->ifr_mtu == if_getmtu(ifp)) {
                          CTX_UNLOCK(ctx);
                          break;
                  }
                  bits = if_getdrvflags(ifp);
                  /* stop the driver and free any clusters before proceeding */
                  iflib_stop(ctx);
  
                  if ((err = IFDI_MTU_SET(ctx, ifr->ifr_mtu)) == 0) {
                          STATE_LOCK(ctx);
                          if (ifr->ifr_mtu > ctx->ifc_max_fl_buf_size)
                                  ctx->ifc_flags |= IFC_MULTISEG;
                          else
                                  ctx->ifc_flags &= ~IFC_MULTISEG;
                          STATE_UNLOCK(ctx);
                          err = if_setmtu(ifp, ifr->ifr_mtu);
                  }
                  iflib_init_locked(ctx);
                  STATE_LOCK(ctx);
                  if_setdrvflags(ifp, bits);
                  STATE_UNLOCK(ctx);
                  CTX_UNLOCK(ctx);
                  break;
          case SIOCSIFFLAGS:
                  CTX_LOCK(ctx);
                  if (if_getflags(ifp) & IFF_UP) {
                          if (if_getdrvflags(ifp) & IFF_DRV_RUNNING) {
                                  if ((if_getflags(ifp) ^ ctx->ifc_if_flags) &
                                      (IFF_PROMISC | IFF_ALLMULTI)) {
                                          CTX_UNLOCK(ctx);
                                          err = IFDI_PROMISC_SET(ctx, if_getflags(ifp));
                                          CTX_LOCK(ctx);
                                  }
                          } else
                                  reinit = 1;
                  } else if (if_getdrvflags(ifp) & IFF_DRV_RUNNING) {
                          iflib_stop(ctx);
                  }
                  ctx->ifc_if_flags = if_getflags(ifp);
                  CTX_UNLOCK(ctx);
                  break;
          case SIOCADDMULTI:
          case SIOCDELMULTI:
                  if (if_getdrvflags(ifp) & IFF_DRV_RUNNING) {
                          CTX_LOCK(ctx);
                          IFDI_INTR_DISABLE(ctx);
                          IFDI_MULTI_SET(ctx);
                          IFDI_INTR_ENABLE(ctx);
                          CTX_UNLOCK(ctx);
                  }
                  break;
          case SIOCSIFMEDIA:
                  CTX_LOCK(ctx);
                  IFDI_MEDIA_SET(ctx);
                  CTX_UNLOCK(ctx);
                  /* FALLTHROUGH */
          case SIOCGIFMEDIA:
          case SIOCGIFXMEDIA:
                  err = ifmedia_ioctl(ifp, ifr, ctx->ifc_mediap, command);
                  break;
          case SIOCGI2C:
          {
                  struct ifi2creq i2c;
  
                  err = copyin(ifr_data_get_ptr(ifr), &i2c, sizeof(i2c));
                  if (err != 0)
                          break;
                  if (i2c.dev_addr != 0xA0 && i2c.dev_addr != 0xA2) {
                          err = EINVAL;
                          break;
                  }
                  if (i2c.len > sizeof(i2c.data)) {
                          err = EINVAL;
                          break;
                  }
  
                  if ((err = IFDI_I2C_REQ(ctx, &i2c)) == 0)
                          err = copyout(&i2c, ifr_data_get_ptr(ifr),
                              sizeof(i2c));
                  break;
          }
          case SIOCSIFCAP:
          {
                  int mask, setmask, oldmask;
  
                  oldmask = if_getcapenable(ifp);
                  mask = ifr->ifr_reqcap ^ oldmask;
                  mask &= ctx->ifc_softc_ctx.isc_capabilities | IFCAP_MEXTPG;
                  setmask = 0;
  #ifdef TCP_OFFLOAD
                  setmask |= mask & (IFCAP_TOE4|IFCAP_TOE6);
  #endif
                  setmask |= (mask & IFCAP_FLAGS);
                  setmask |= (mask & IFCAP_WOL);
  
                  /*
                   * If any RX csum has changed, change all the ones that
                   * are supported by the driver.
                   */
                  if (setmask & (IFCAP_RXCSUM | IFCAP_RXCSUM_IPV6)) {
                          setmask |= ctx->ifc_softc_ctx.isc_capabilities &
                              (IFCAP_RXCSUM | IFCAP_RXCSUM_IPV6);
                  }
  
                  /*
                   * want to ensure that traffic has stopped before we change any of the flags
                   */
                  if (setmask) {
                          CTX_LOCK(ctx);
                          bits = if_getdrvflags(ifp);
                          if (bits & IFF_DRV_RUNNING && setmask & ~IFCAP_WOL)
                                  iflib_stop(ctx);
                          STATE_LOCK(ctx);
                          if_togglecapenable(ifp, setmask);
                          ctx->ifc_softc_ctx.isc_capenable ^= setmask;
                          STATE_UNLOCK(ctx);
                          if (bits & IFF_DRV_RUNNING && setmask & ~IFCAP_WOL)
                                  iflib_init_locked(ctx);
                          STATE_LOCK(ctx);
                          if_setdrvflags(ifp, bits);
                          STATE_UNLOCK(ctx);
                          CTX_UNLOCK(ctx);
                  }
                  if_vlancap(ifp);
                  break;
          }
          case SIOCGPRIVATE_0:
          case SIOCSDRVSPEC:
          case SIOCGDRVSPEC:
                  CTX_LOCK(ctx);
                  err = IFDI_PRIV_IOCTL(ctx, command, data);
                  CTX_UNLOCK(ctx);
                  break;
          default:
                  err = ether_ioctl(ifp, command, data);
                  break;
          }
          if (reinit)
                  iflib_if_init(ctx);
          return (err);
  }
  
  static uint64_t
  iflib_if_get_counter(if_t ifp, ift_counter cnt)
  {
          if_ctx_t ctx = if_getsoftc(ifp);
  
          return (IFDI_GET_COUNTER(ctx, cnt));
  }
  
  /*********************************************************************
   *
   *  OTHER FUNCTIONS EXPORTED TO THE STACK
   *
   **********************************************************************/
  
  static void
  iflib_vlan_register(void *arg, if_t ifp, uint16_t vtag)
  {
          if_ctx_t ctx = if_getsoftc(ifp);
  
          if ((void *)ctx != arg)
                  return;
  
          if ((vtag == 0) || (vtag > 4095))
                  return;
  
          if (iflib_in_detach(ctx))
                  return;
  
          CTX_LOCK(ctx);
          /* Driver may need all untagged packets to be flushed */
          if (IFDI_NEEDS_RESTART(ctx, IFLIB_RESTART_VLAN_CONFIG))
                  iflib_stop(ctx);
          IFDI_VLAN_REGISTER(ctx, vtag);
          /* Re-init to load the changes, if required */
          if (IFDI_NEEDS_RESTART(ctx, IFLIB_RESTART_VLAN_CONFIG))
                  iflib_init_locked(ctx);
          CTX_UNLOCK(ctx);
  }
  
  static void
  iflib_vlan_unregister(void *arg, if_t ifp, uint16_t vtag)
  {
          if_ctx_t ctx = if_getsoftc(ifp);
  
          if ((void *)ctx != arg)
                  return;
  
          if ((vtag == 0) || (vtag > 4095))
                  return;
  
          CTX_LOCK(ctx);
          /* Driver may need all tagged packets to be flushed */
          if (IFDI_NEEDS_RESTART(ctx, IFLIB_RESTART_VLAN_CONFIG))
                  iflib_stop(ctx);
          IFDI_VLAN_UNREGISTER(ctx, vtag);
          /* Re-init to load the changes, if required */
          if (IFDI_NEEDS_RESTART(ctx, IFLIB_RESTART_VLAN_CONFIG))
                  iflib_init_locked(ctx);
          CTX_UNLOCK(ctx);
  }
  
  static void
  iflib_led_func(void *arg, int onoff)
  {
          if_ctx_t ctx = arg;
  
          CTX_LOCK(ctx);
          IFDI_LED_FUNC(ctx, onoff);
          CTX_UNLOCK(ctx);
  }
  
  /*********************************************************************
   *
   *  BUS FUNCTION DEFINITIONS
   *
   **********************************************************************/
  
  int
  iflib_device_probe(device_t dev)
  {
          const pci_vendor_info_t *ent;
          if_shared_ctx_t sctx;
          uint16_t pci_device_id, pci_rev_id, pci_subdevice_id, pci_subvendor_id;
          uint16_t pci_vendor_id;
  
          if ((sctx = DEVICE_REGISTER(dev)) == NULL || sctx->isc_magic != IFLIB_MAGIC)
                  return (ENOTSUP);
  
          pci_vendor_id = pci_get_vendor(dev);
          pci_device_id = pci_get_device(dev);
          pci_subvendor_id = pci_get_subvendor(dev);
          pci_subdevice_id = pci_get_subdevice(dev);
          pci_rev_id = pci_get_revid(dev);
          if (sctx->isc_parse_devinfo != NULL)
                  sctx->isc_parse_devinfo(&pci_device_id, &pci_subvendor_id, &pci_subdevice_id, &pci_rev_id);
  
          ent = sctx->isc_vendor_info;
          while (ent->pvi_vendor_id != 0) {
                  if (pci_vendor_id != ent->pvi_vendor_id) {
                          ent++;
                          continue;
                  }
                  if ((pci_device_id == ent->pvi_device_id) &&
                      ((pci_subvendor_id == ent->pvi_subvendor_id) ||
                       (ent->pvi_subvendor_id == 0)) &&
                      ((pci_subdevice_id == ent->pvi_subdevice_id) ||
                       (ent->pvi_subdevice_id == 0)) &&
                      ((pci_rev_id == ent->pvi_rev_id) ||
                       (ent->pvi_rev_id == 0))) {
                          device_set_desc_copy(dev, ent->pvi_name);
                          /* this needs to be changed to zero if the bus probing code
                           * ever stops re-probing on best match because the sctx
                           * may have its values over written by register calls
                           * in subsequent probes
                           */
                          return (BUS_PROBE_DEFAULT);
                  }
                  ent++;
          }
          return (ENXIO);
  }
  
  int
  iflib_device_probe_vendor(device_t dev)
  {
          int probe;
  
          probe = iflib_device_probe(dev);
          if (probe == BUS_PROBE_DEFAULT)
                  return (BUS_PROBE_VENDOR);
          else
                  return (probe);
  }
  
  static void
  iflib_reset_qvalues(if_ctx_t ctx)
  {
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          if_shared_ctx_t sctx = ctx->ifc_sctx;
          device_t dev = ctx->ifc_dev;
          int i;
  
          if (ctx->ifc_sysctl_ntxqs != 0)
                  scctx->isc_ntxqsets = ctx->ifc_sysctl_ntxqs;
          if (ctx->ifc_sysctl_nrxqs != 0)
                  scctx->isc_nrxqsets = ctx->ifc_sysctl_nrxqs;
  
          for (i = 0; i < sctx->isc_ntxqs; i++) {
                  if (ctx->ifc_sysctl_ntxds[i] != 0)
                          scctx->isc_ntxd[i] = ctx->ifc_sysctl_ntxds[i];
                  else
                          scctx->isc_ntxd[i] = sctx->isc_ntxd_default[i];
          }
  
          for (i = 0; i < sctx->isc_nrxqs; i++) {
                  if (ctx->ifc_sysctl_nrxds[i] != 0)
                          scctx->isc_nrxd[i] = ctx->ifc_sysctl_nrxds[i];
                  else
                          scctx->isc_nrxd[i] = sctx->isc_nrxd_default[i];
          }
  
          for (i = 0; i < sctx->isc_nrxqs; i++) {
                  if (scctx->isc_nrxd[i] < sctx->isc_nrxd_min[i]) {
                          device_printf(dev, "nrxd%d: %d less than nrxd_min %d - resetting to min\n",
                                        i, scctx->isc_nrxd[i], sctx->isc_nrxd_min[i]);
                          scctx->isc_nrxd[i] = sctx->isc_nrxd_min[i];
                  }
                  if (scctx->isc_nrxd[i] > sctx->isc_nrxd_max[i]) {
                          device_printf(dev, "nrxd%d: %d greater than nrxd_max %d - resetting to max\n",
                                        i, scctx->isc_nrxd[i], sctx->isc_nrxd_max[i]);
                          scctx->isc_nrxd[i] = sctx->isc_nrxd_max[i];
                  }
                  if (!powerof2(scctx->isc_nrxd[i])) {
                          device_printf(dev, "nrxd%d: %d is not a power of 2 - using default value of %d\n",
                                        i, scctx->isc_nrxd[i], sctx->isc_nrxd_default[i]);
                          scctx->isc_nrxd[i] = sctx->isc_nrxd_default[i];
                  }
          }
  
          for (i = 0; i < sctx->isc_ntxqs; i++) {
                  if (scctx->isc_ntxd[i] < sctx->isc_ntxd_min[i]) {
                          device_printf(dev, "ntxd%d: %d less than ntxd_min %d - resetting to min\n",
                                        i, scctx->isc_ntxd[i], sctx->isc_ntxd_min[i]);
                          scctx->isc_ntxd[i] = sctx->isc_ntxd_min[i];
                  }
                  if (scctx->isc_ntxd[i] > sctx->isc_ntxd_max[i]) {
                          device_printf(dev, "ntxd%d: %d greater than ntxd_max %d - resetting to max\n",
                                        i, scctx->isc_ntxd[i], sctx->isc_ntxd_max[i]);
                          scctx->isc_ntxd[i] = sctx->isc_ntxd_max[i];
                  }
                  if (!powerof2(scctx->isc_ntxd[i])) {
                          device_printf(dev, "ntxd%d: %d is not a power of 2 - using default value of %d\n",
                                        i, scctx->isc_ntxd[i], sctx->isc_ntxd_default[i]);
                          scctx->isc_ntxd[i] = sctx->isc_ntxd_default[i];
                  }
          }
  }
  
  static void
  iflib_add_pfil(if_ctx_t ctx)
  {
          struct pfil_head *pfil;
          struct pfil_head_args pa;
          iflib_rxq_t rxq;
          int i;
  
          pa.pa_version = PFIL_VERSION;
          pa.pa_flags = PFIL_IN;
          pa.pa_type = PFIL_TYPE_ETHERNET;
          pa.pa_headname = if_name(ctx->ifc_ifp);
          pfil = pfil_head_register(&pa);
  
          for (i = 0, rxq = ctx->ifc_rxqs; i < NRXQSETS(ctx); i++, rxq++) {
                  rxq->pfil = pfil;
          }
  }
  
  static void
  iflib_rem_pfil(if_ctx_t ctx)
  {
          struct pfil_head *pfil;
          iflib_rxq_t rxq;
          int i;
  
          rxq = ctx->ifc_rxqs;
          pfil = rxq->pfil;
          for (i = 0; i < NRXQSETS(ctx); i++, rxq++) {
                  rxq->pfil = NULL;
          }
          pfil_head_unregister(pfil);
  }
  
  
  /*
   * Advance forward by n members of the cpuset ctx->ifc_cpus starting from
   * cpuid and wrapping as necessary.
   */
  static unsigned int
  cpuid_advance(if_ctx_t ctx, unsigned int cpuid, unsigned int n)
  {
          unsigned int first_valid;
          unsigned int last_valid;
  
          /* cpuid should always be in the valid set */
          MPASS(CPU_ISSET(cpuid, &ctx->ifc_cpus));
  
          /* valid set should never be empty */
          MPASS(!CPU_EMPTY(&ctx->ifc_cpus));
  
          first_valid = CPU_FFS(&ctx->ifc_cpus) - 1;
          last_valid = CPU_FLS(&ctx->ifc_cpus) - 1;
          n = n % CPU_COUNT(&ctx->ifc_cpus);
          while (n > 0) {
                  do {
                          cpuid++;
                          if (cpuid > last_valid)
                                  cpuid = first_valid;
                  } while (!CPU_ISSET(cpuid, &ctx->ifc_cpus));
                  n--;
          }
  
          return (cpuid);
  }
  
  #if defined(SMP) && defined(SCHED_ULE)
  extern struct cpu_group *cpu_top;              /* CPU topology */
  
  static int
  find_child_with_core(int cpu, struct cpu_group *grp)
  {
          int i;
  
          if (grp->cg_children == 0)
                  return -1;
  
          MPASS(grp->cg_child);
          for (i = 0; i < grp->cg_children; i++) {
                  if (CPU_ISSET(cpu, &grp->cg_child[i].cg_mask))
                          return i;
          }
  
          return -1;
  }
  
  
  /*
   * Find an L2 neighbor of the given CPU or return -1 if none found.  This
   * does not distinguish among multiple L2 neighbors if the given CPU has
   * more than one (it will always return the same result in that case).
   */
  static int
  find_l2_neighbor(int cpu)
  {
          struct cpu_group *grp;
          int i;
  
          grp = cpu_top;
          if (grp == NULL)
                  return -1;
  
          /*
           * Find the smallest CPU group that contains the given core.
           */
          i = 0;
          while ((i = find_child_with_core(cpu, grp)) != -1) {
                  /*
                   * If the smallest group containing the given CPU has less
                   * than two members, we conclude the given CPU has no
                   * L2 neighbor.
                   */
                  if (grp->cg_child[i].cg_count <= 1)
                          return (-1);
                  grp = &grp->cg_child[i];
          }
  
          /* Must share L2. */
          if (grp->cg_level > CG_SHARE_L2 || grp->cg_level == CG_SHARE_NONE)
                  return -1;
  
          /*
           * Select the first member of the set that isn't the reference
           * CPU, which at this point is guaranteed to exist.
           */
          for (i = 0; i < CPU_SETSIZE; i++) {
                  if (CPU_ISSET(i, &grp->cg_mask) && i != cpu)
                          return (i);
          }
  
          /* Should never be reached */
          return (-1);
  }
  
  #else
  static int
  find_l2_neighbor(int cpu)
  {
  
          return (-1);
  }
  #endif
  
  /*
   * CPU mapping behaviors
   * ---------------------
   * 'separate txrx' refers to the separate_txrx sysctl
   * 'use logical' refers to the use_logical_cores sysctl
   * 'INTR CPUS' indicates whether bus_get_cpus(INTR_CPUS) succeeded
   *
   *  separate     use     INTR
   *    txrx     logical   CPUS   result
   * ---------- --------- ------ ------------------------------------------------
   *     -          -       X     RX and TX queues mapped to consecutive physical
   *                              cores with RX/TX pairs on same core and excess
   *                              of either following
   *     -          X       X     RX and TX queues mapped to consecutive cores
   *                              of any type with RX/TX pairs on same core and
   *                              excess of either following
   *     X          -       X     RX and TX queues mapped to consecutive physical
   *                              cores; all RX then all TX
   *     X          X       X     RX queues mapped to consecutive physical cores
   *                              first, then TX queues mapped to L2 neighbor of
   *                              the corresponding RX queue if one exists,
   *                              otherwise to consecutive physical cores
   *     -         n/a      -     RX and TX queues mapped to consecutive cores of
   *                              any type with RX/TX pairs on same core and excess
   *                              of either following
   *     X         n/a      -     RX and TX queues mapped to consecutive cores of
   *                              any type; all RX then all TX
   */
  static unsigned int
  get_cpuid_for_queue(if_ctx_t ctx, unsigned int base_cpuid, unsigned int qid,
      bool is_tx)
  {
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          unsigned int core_index;
  
          if (ctx->ifc_sysctl_separate_txrx) {
                  /*
                   * When using separate CPUs for TX and RX, the assignment
                   * will always be of a consecutive CPU out of the set of
                   * context CPUs, except for the specific case where the
                   * context CPUs are phsyical cores, the use of logical cores
                   * has been enabled, the assignment is for TX, the TX qid
                   * corresponds to an RX qid, and the CPU assigned to the
                   * corresponding RX queue has an L2 neighbor.
                   */
                  if (ctx->ifc_sysctl_use_logical_cores &&
                      ctx->ifc_cpus_are_physical_cores &&
                      is_tx && qid < scctx->isc_nrxqsets) {
                          int l2_neighbor;
                          unsigned int rx_cpuid;
  
                          rx_cpuid = cpuid_advance(ctx, base_cpuid, qid);
                          l2_neighbor = find_l2_neighbor(rx_cpuid);
                          if (l2_neighbor != -1) {
                                  return (l2_neighbor);
                          }
                          /*
                           * ... else fall through to the normal
                           * consecutive-after-RX assignment scheme.
                           *
                           * Note that we are assuming that all RX queue CPUs
                           * have an L2 neighbor, or all do not.  If a mixed
                           * scenario is possible, we will have to keep track
                           * separately of how many queues prior to this one
                           * were not able to be assigned to an L2 neighbor.
                           */
                  }
                  if (is_tx)
                          core_index = scctx->isc_nrxqsets + qid;
                  else
                          core_index = qid;
          } else {
                  core_index = qid;
          }
  
          return (cpuid_advance(ctx, base_cpuid, core_index));
  }
  
  static uint16_t
  get_ctx_core_offset(if_ctx_t ctx)
  {
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          struct cpu_offset *op;
          cpuset_t assigned_cpus;
          unsigned int cores_consumed;
          unsigned int base_cpuid = ctx->ifc_sysctl_core_offset;
          unsigned int first_valid;
          unsigned int last_valid;
          unsigned int i;
  
          first_valid = CPU_FFS(&ctx->ifc_cpus) - 1;
          last_valid = CPU_FLS(&ctx->ifc_cpus) - 1;
  
          if (base_cpuid != CORE_OFFSET_UNSPECIFIED) {
                  /*
                   * Align the user-chosen base CPU ID to the next valid CPU
                   * for this device.  If the chosen base CPU ID is smaller
                   * than the first valid CPU or larger than the last valid
                   * CPU, we assume the user does not know what the valid
                   * range is for this device and is thinking in terms of a
                   * zero-based reference frame, and so we shift the given
                   * value into the valid range (and wrap accordingly) so the
                   * intent is translated to the proper frame of reference.
                   * If the base CPU ID is within the valid first/last, but
                   * does not correspond to a valid CPU, it is advanced to the
                   * next valid CPU (wrapping if necessary).
                   */
                  if (base_cpuid < first_valid || base_cpuid > last_valid) {
                          /* shift from zero-based to first_valid-based */
                          base_cpuid += first_valid;
                          /* wrap to range [first_valid, last_valid] */
                          base_cpuid = (base_cpuid - first_valid) %
                              (last_valid - first_valid + 1);
                  }
                  if (!CPU_ISSET(base_cpuid, &ctx->ifc_cpus)) {
                          /*
                           * base_cpuid is in [first_valid, last_valid], but
                           * not a member of the valid set.  In this case,
                           * there will always be a member of the valid set
                           * with a CPU ID that is greater than base_cpuid,
                           * and we simply advance to it.
                           */
                          while (!CPU_ISSET(base_cpuid, &ctx->ifc_cpus))
                                  base_cpuid++;
                  }
                  return (base_cpuid);
          }
  
          /*
           * Determine how many cores will be consumed by performing the CPU
           * assignments and counting how many of the assigned CPUs correspond
           * to CPUs in the set of context CPUs.  This is done using the CPU
           * ID first_valid as the base CPU ID, as the base CPU must be within
           * the set of context CPUs.
           *
           * Note not all assigned CPUs will be in the set of context CPUs
           * when separate CPUs are being allocated to TX and RX queues,
           * assignment to logical cores has been enabled, the set of context
           * CPUs contains only physical CPUs, and TX queues are mapped to L2
           * neighbors of CPUs that RX queues have been mapped to - in this
           * case we do only want to count how many CPUs in the set of context
           * CPUs have been consumed, as that determines the next CPU in that
           * set to start allocating at for the next device for which
           * core_offset is not set.
           */
          CPU_ZERO(&assigned_cpus);
          for (i = 0; i < scctx->isc_ntxqsets; i++)
                  CPU_SET(get_cpuid_for_queue(ctx, first_valid, i, true),
                      &assigned_cpus);
          for (i = 0; i < scctx->isc_nrxqsets; i++)
                  CPU_SET(get_cpuid_for_queue(ctx, first_valid, i, false),
                      &assigned_cpus);
          CPU_AND(&assigned_cpus, &assigned_cpus, &ctx->ifc_cpus);
          cores_consumed = CPU_COUNT(&assigned_cpus);
  
          mtx_lock(&cpu_offset_mtx);
          SLIST_FOREACH(op, &cpu_offsets, entries) {
                  if (CPU_CMP(&ctx->ifc_cpus, &op->set) == 0) {
                          base_cpuid = op->next_cpuid;
                          op->next_cpuid = cpuid_advance(ctx, op->next_cpuid,
                              cores_consumed);
                          MPASS(op->refcount < UINT_MAX);
                          op->refcount++;
                          break;
                  }
          }
          if (base_cpuid == CORE_OFFSET_UNSPECIFIED) {
                  base_cpuid = first_valid;
                  op = malloc(sizeof(struct cpu_offset), M_IFLIB,
                      M_NOWAIT | M_ZERO);
                  if (op == NULL) {
                          device_printf(ctx->ifc_dev,
                              "allocation for cpu offset failed.\n");
                  } else {
                          op->next_cpuid = cpuid_advance(ctx, base_cpuid,
                              cores_consumed);
                          op->refcount = 1;
                          CPU_COPY(&ctx->ifc_cpus, &op->set);
                          SLIST_INSERT_HEAD(&cpu_offsets, op, entries);
                  }
          }
          mtx_unlock(&cpu_offset_mtx);
  
          return (base_cpuid);
  }
  
  static void
  unref_ctx_core_offset(if_ctx_t ctx)
  {
          struct cpu_offset *op, *top;
  
          mtx_lock(&cpu_offset_mtx);
          SLIST_FOREACH_SAFE(op, &cpu_offsets, entries, top) {
                  if (CPU_CMP(&ctx->ifc_cpus, &op->set) == 0) {
                          MPASS(op->refcount > 0);
                          op->refcount--;
                          if (op->refcount == 0) {
                                  SLIST_REMOVE(&cpu_offsets, op, cpu_offset, entries);
                                  free(op, M_IFLIB);
                          }
                          break;
                  }
          }
          mtx_unlock(&cpu_offset_mtx);
  }
  
  int
  iflib_device_register(device_t dev, void *sc, if_shared_ctx_t sctx, if_ctx_t *ctxp)
  {
          if_ctx_t ctx;
          if_t ifp;
          if_softc_ctx_t scctx;
          kobjop_desc_t kobj_desc;
          kobj_method_t *kobj_method;
          int err, msix, rid;
          int num_txd, num_rxd;
  
          ctx = malloc(sizeof(* ctx), M_IFLIB, M_WAITOK|M_ZERO);
  
          if (sc == NULL) {
                  sc = malloc(sctx->isc_driver->size, M_IFLIB, M_WAITOK|M_ZERO);
                  device_set_softc(dev, ctx);
                  ctx->ifc_flags |= IFC_SC_ALLOCATED;
          }
  
          ctx->ifc_sctx = sctx;
          ctx->ifc_dev = dev;
          ctx->ifc_softc = sc;
  
          if ((err = iflib_register(ctx)) != 0) {
                  device_printf(dev, "iflib_register failed %d\n", err);
                  goto fail_ctx_free;
          }
          iflib_add_device_sysctl_pre(ctx);
  
          scctx = &ctx->ifc_softc_ctx;
          ifp = ctx->ifc_ifp;
  
          iflib_reset_qvalues(ctx);
          IFNET_WLOCK();
          CTX_LOCK(ctx);
          if ((err = IFDI_ATTACH_PRE(ctx)) != 0) {
                  device_printf(dev, "IFDI_ATTACH_PRE failed %d\n", err);
                  goto fail_unlock;
          }
          _iflib_pre_assert(scctx);
          ctx->ifc_txrx = *scctx->isc_txrx;
  
          MPASS(scctx->isc_dma_width <= flsll(BUS_SPACE_MAXADDR));
  
          if (sctx->isc_flags & IFLIB_DRIVER_MEDIA)
                  ctx->ifc_mediap = scctx->isc_media;
  
  #ifdef INVARIANTS
          if (scctx->isc_capabilities & IFCAP_TXCSUM)
                  MPASS(scctx->isc_tx_csum_flags);
  #endif
  
          if_setcapabilities(ifp,
              scctx->isc_capabilities | IFCAP_HWSTATS | IFCAP_MEXTPG);
          if_setcapenable(ifp,
              scctx->isc_capenable | IFCAP_HWSTATS | IFCAP_MEXTPG);
  
          if (scctx->isc_ntxqsets == 0 || (scctx->isc_ntxqsets_max && scctx->isc_ntxqsets_max < scctx->isc_ntxqsets))
                  scctx->isc_ntxqsets = scctx->isc_ntxqsets_max;
          if (scctx->isc_nrxqsets == 0 || (scctx->isc_nrxqsets_max && scctx->isc_nrxqsets_max < scctx->isc_nrxqsets))
                  scctx->isc_nrxqsets = scctx->isc_nrxqsets_max;
  
          num_txd = iflib_num_tx_descs(ctx);
          num_rxd = iflib_num_rx_descs(ctx);
  
          /* XXX change for per-queue sizes */
          device_printf(dev, "Using %d TX descriptors and %d RX descriptors\n",
              num_txd, num_rxd);
  
          if (scctx->isc_tx_nsegments > num_txd / MAX_SINGLE_PACKET_FRACTION)
                  scctx->isc_tx_nsegments = max(1, num_txd /
                      MAX_SINGLE_PACKET_FRACTION);
          if (scctx->isc_tx_tso_segments_max > num_txd /
              MAX_SINGLE_PACKET_FRACTION)
                  scctx->isc_tx_tso_segments_max = max(1,
                      num_txd / MAX_SINGLE_PACKET_FRACTION);
  
          /* TSO parameters - dig these out of the data sheet - simply correspond to tag setup */
          if (if_getcapabilities(ifp) & IFCAP_TSO) {
                  /*
                   * The stack can't handle a TSO size larger than IP_MAXPACKET,
                   * but some MACs do.
                   */
                  if_sethwtsomax(ifp, min(scctx->isc_tx_tso_size_max,
                      IP_MAXPACKET));
                  /*
                   * Take maximum number of m_pullup(9)'s in iflib_parse_header()
                   * into account.  In the worst case, each of these calls will
                   * add another mbuf and, thus, the requirement for another DMA
                   * segment.  So for best performance, it doesn't make sense to
                   * advertize a maximum of TSO segments that typically will
                   * require defragmentation in iflib_encap().
                   */
                  if_sethwtsomaxsegcount(ifp, scctx->isc_tx_tso_segments_max - 3);
                  if_sethwtsomaxsegsize(ifp, scctx->isc_tx_tso_segsize_max);
          }
          if (scctx->isc_rss_table_size == 0)
                  scctx->isc_rss_table_size = 64;
          scctx->isc_rss_table_mask = scctx->isc_rss_table_size-1;
  
          GROUPTASK_INIT(&ctx->ifc_admin_task, 0, _task_fn_admin, ctx);
          /* XXX format name */
          taskqgroup_attach(qgroup_if_config_tqg, &ctx->ifc_admin_task, ctx,
              NULL, NULL, "admin");
  
          /* Set up cpu set.  If it fails, use the set of all CPUs. */
          if (bus_get_cpus(dev, INTR_CPUS, sizeof(ctx->ifc_cpus), &ctx->ifc_cpus) != 0) {
                  device_printf(dev, "Unable to fetch CPU list\n");
                  CPU_COPY(&all_cpus, &ctx->ifc_cpus);
                  ctx->ifc_cpus_are_physical_cores = false;
          } else
                  ctx->ifc_cpus_are_physical_cores = true;
          MPASS(CPU_COUNT(&ctx->ifc_cpus) > 0);
  
          /*
          ** Now set up MSI or MSI-X, should return us the number of supported
          ** vectors (will be 1 for a legacy interrupt and MSI).
          */
          if (sctx->isc_flags & IFLIB_SKIP_MSIX) {
                  msix = scctx->isc_vectors;
          } else if (scctx->isc_msix_bar != 0)
                 /*
                  * The simple fact that isc_msix_bar is not 0 does not mean we
                  * we have a good value there that is known to work.
                  */
                  msix = iflib_msix_init(ctx);
          else {
                  scctx->isc_vectors = 1;
                  scctx->isc_ntxqsets = 1;
                  scctx->isc_nrxqsets = 1;
                  scctx->isc_intr = IFLIB_INTR_LEGACY;
                  msix = 0;
          }
          /* Get memory for the station queues */
          if ((err = iflib_queues_alloc(ctx))) {
                  device_printf(dev, "Unable to allocate queue memory\n");
                  goto fail_intr_free;
          }
  
          if ((err = iflib_qset_structures_setup(ctx)))
                  goto fail_queues;
  
          /*
           * Now that we know how many queues there are, get the core offset.
           */
          ctx->ifc_sysctl_core_offset = get_ctx_core_offset(ctx);
  
          if (msix > 1) {
                  /*
                   * When using MSI-X, ensure that ifdi_{r,t}x_queue_intr_enable
                   * aren't the default NULL implementation.
                   */
                  kobj_desc = &ifdi_rx_queue_intr_enable_desc;
                  kobj_method = kobj_lookup_method(((kobj_t)ctx)->ops->cls, NULL,
                      kobj_desc);
                  if (kobj_method == &kobj_desc->deflt) {
                          device_printf(dev,
                              "MSI-X requires ifdi_rx_queue_intr_enable method");
                          err = EOPNOTSUPP;
                          goto fail_queues;
                  }
                  kobj_desc = &ifdi_tx_queue_intr_enable_desc;
                  kobj_method = kobj_lookup_method(((kobj_t)ctx)->ops->cls, NULL,
                      kobj_desc);
                  if (kobj_method == &kobj_desc->deflt) {
                          device_printf(dev,
                              "MSI-X requires ifdi_tx_queue_intr_enable method");
                          err = EOPNOTSUPP;
                          goto fail_queues;
                  }
  
                  /*
                   * Assign the MSI-X vectors.
                   * Note that the default NULL ifdi_msix_intr_assign method will
                   * fail here, too.
                   */
                  err = IFDI_MSIX_INTR_ASSIGN(ctx, msix);
                  if (err != 0) {
                          device_printf(dev, "IFDI_MSIX_INTR_ASSIGN failed %d\n",
                              err);
                          goto fail_queues;
                  }
          } else if (scctx->isc_intr != IFLIB_INTR_MSIX) {
                  rid = 0;
                  if (scctx->isc_intr == IFLIB_INTR_MSI) {
                          MPASS(msix == 1);
                          rid = 1;
                  }
                  if ((err = iflib_legacy_setup(ctx, ctx->isc_legacy_intr, ctx->ifc_softc, &rid, "irq0")) != 0) {
                          device_printf(dev, "iflib_legacy_setup failed %d\n", err);
                          goto fail_queues;
                  }
          } else {
                  device_printf(dev,
                      "Cannot use iflib with only 1 MSI-X interrupt!\n");
                  err = ENODEV;
                  goto fail_queues;
          }
  
          ether_ifattach(ctx->ifc_ifp, ctx->ifc_mac.octet);
  
          if ((err = IFDI_ATTACH_POST(ctx)) != 0) {
                  device_printf(dev, "IFDI_ATTACH_POST failed %d\n", err);
                  goto fail_detach;
          }
  
          /*
           * Tell the upper layer(s) if IFCAP_VLAN_MTU is supported.
           * This must appear after the call to ether_ifattach() because
           * ether_ifattach() sets if_hdrlen to the default value.
           */
          if (if_getcapabilities(ifp) & IFCAP_VLAN_MTU)
                  if_setifheaderlen(ifp, sizeof(struct ether_vlan_header));
  
          if ((err = iflib_netmap_attach(ctx))) {
                  device_printf(ctx->ifc_dev, "netmap attach failed: %d\n", err);
                  goto fail_detach;
          }
          *ctxp = ctx;
  
          DEBUGNET_SET(ctx->ifc_ifp, iflib);
  
          if_setgetcounterfn(ctx->ifc_ifp, iflib_if_get_counter);
          iflib_add_device_sysctl_post(ctx);
          iflib_add_pfil(ctx);
          ctx->ifc_flags |= IFC_INIT_DONE;
          CTX_UNLOCK(ctx);
          IFNET_WUNLOCK();
  
          return (0);
  
  fail_detach:
          ether_ifdetach(ctx->ifc_ifp);
  fail_queues:
          iflib_tqg_detach(ctx);
          iflib_tx_structures_free(ctx);
          iflib_rx_structures_free(ctx);
          IFDI_DETACH(ctx);
          IFDI_QUEUES_FREE(ctx);
  fail_intr_free:
          iflib_free_intr_mem(ctx);
  fail_unlock:
          CTX_UNLOCK(ctx);
          IFNET_WUNLOCK();
          iflib_deregister(ctx);
  fail_ctx_free:
          device_set_softc(ctx->ifc_dev, NULL);
          if (ctx->ifc_flags & IFC_SC_ALLOCATED)
                  free(ctx->ifc_softc, M_IFLIB);
          free(ctx, M_IFLIB);
          return (err);
  }
  
  int
  iflib_pseudo_register(device_t dev, if_shared_ctx_t sctx, if_ctx_t *ctxp,
                                            struct iflib_cloneattach_ctx *clctx)
  {
          int num_txd, num_rxd;
          int err;
          if_ctx_t ctx;
          if_t ifp;
          if_softc_ctx_t scctx;
          int i;
          void *sc;
  
          ctx = malloc(sizeof(*ctx), M_IFLIB, M_WAITOK|M_ZERO);
          sc = malloc(sctx->isc_driver->size, M_IFLIB, M_WAITOK|M_ZERO);
          ctx->ifc_flags |= IFC_SC_ALLOCATED;
          if (sctx->isc_flags & (IFLIB_PSEUDO|IFLIB_VIRTUAL))
                  ctx->ifc_flags |= IFC_PSEUDO;
  
          ctx->ifc_sctx = sctx;
          ctx->ifc_softc = sc;
          ctx->ifc_dev = dev;
  
          if ((err = iflib_register(ctx)) != 0) {
                  device_printf(dev, "%s: iflib_register failed %d\n", __func__, err);
                  goto fail_ctx_free;
          }
          iflib_add_device_sysctl_pre(ctx);
  
          scctx = &ctx->ifc_softc_ctx;
          ifp = ctx->ifc_ifp;
  
          iflib_reset_qvalues(ctx);
          CTX_LOCK(ctx);
          if ((err = IFDI_ATTACH_PRE(ctx)) != 0) {
                  device_printf(dev, "IFDI_ATTACH_PRE failed %d\n", err);
                  goto fail_unlock;
          }
          if (sctx->isc_flags & IFLIB_GEN_MAC)
                  ether_gen_addr(ifp, &ctx->ifc_mac);
          if ((err = IFDI_CLONEATTACH(ctx, clctx->cc_ifc, clctx->cc_name,
                                                                  clctx->cc_params)) != 0) {
                  device_printf(dev, "IFDI_CLONEATTACH failed %d\n", err);
                  goto fail_unlock;
          }
  #ifdef INVARIANTS
          if (scctx->isc_capabilities & IFCAP_TXCSUM)
                  MPASS(scctx->isc_tx_csum_flags);
  #endif
  
          if_setcapabilities(ifp, scctx->isc_capabilities | IFCAP_HWSTATS | IFCAP_LINKSTATE);
          if_setcapenable(ifp, scctx->isc_capenable | IFCAP_HWSTATS | IFCAP_LINKSTATE);
  
          if_setflagbits(ifp, IFF_NOGROUP, 0);
          if (sctx->isc_flags & IFLIB_PSEUDO) {
                  ifmedia_add(ctx->ifc_mediap, IFM_ETHER | IFM_AUTO, 0, NULL);
                  ifmedia_set(ctx->ifc_mediap, IFM_ETHER | IFM_AUTO);
                  if (sctx->isc_flags & IFLIB_PSEUDO_ETHER) {
                          ether_ifattach(ctx->ifc_ifp, ctx->ifc_mac.octet);
                  } else {
                          if_attach(ctx->ifc_ifp);
                          bpfattach(ctx->ifc_ifp, DLT_NULL, sizeof(u_int32_t));
                  }
  
                  if ((err = IFDI_ATTACH_POST(ctx)) != 0) {
                          device_printf(dev, "IFDI_ATTACH_POST failed %d\n", err);
                          goto fail_detach;
                  }
                  *ctxp = ctx;
  
                  /*
                   * Tell the upper layer(s) if IFCAP_VLAN_MTU is supported.
                   * This must appear after the call to ether_ifattach() because
                   * ether_ifattach() sets if_hdrlen to the default value.
                   */
                  if (if_getcapabilities(ifp) & IFCAP_VLAN_MTU)
                          if_setifheaderlen(ifp,
                              sizeof(struct ether_vlan_header));
  
                  if_setgetcounterfn(ctx->ifc_ifp, iflib_if_get_counter);
                  iflib_add_device_sysctl_post(ctx);
                  ctx->ifc_flags |= IFC_INIT_DONE;
                  CTX_UNLOCK(ctx);
                  return (0);
          }
          ifmedia_add(ctx->ifc_mediap, IFM_ETHER | IFM_1000_T | IFM_FDX, 0, NULL);
          ifmedia_add(ctx->ifc_mediap, IFM_ETHER | IFM_AUTO, 0, NULL);
          ifmedia_set(ctx->ifc_mediap, IFM_ETHER | IFM_AUTO);
  
          _iflib_pre_assert(scctx);
          ctx->ifc_txrx = *scctx->isc_txrx;
  
          if (scctx->isc_ntxqsets == 0 || (scctx->isc_ntxqsets_max && scctx->isc_ntxqsets_max < scctx->isc_ntxqsets))
                  scctx->isc_ntxqsets = scctx->isc_ntxqsets_max;
          if (scctx->isc_nrxqsets == 0 || (scctx->isc_nrxqsets_max && scctx->isc_nrxqsets_max < scctx->isc_nrxqsets))
                  scctx->isc_nrxqsets = scctx->isc_nrxqsets_max;
  
          num_txd = iflib_num_tx_descs(ctx);
          num_rxd = iflib_num_rx_descs(ctx);
  
          /* XXX change for per-queue sizes */
          device_printf(dev, "Using %d TX descriptors and %d RX descriptors\n",
              num_txd, num_rxd);
  
          if (scctx->isc_tx_nsegments > num_txd / MAX_SINGLE_PACKET_FRACTION)
                  scctx->isc_tx_nsegments = max(1, num_txd /
                      MAX_SINGLE_PACKET_FRACTION);
          if (scctx->isc_tx_tso_segments_max > num_txd /
              MAX_SINGLE_PACKET_FRACTION)
                  scctx->isc_tx_tso_segments_max = max(1,
                      num_txd / MAX_SINGLE_PACKET_FRACTION);
  
          /* TSO parameters - dig these out of the data sheet - simply correspond to tag setup */
          if (if_getcapabilities(ifp) & IFCAP_TSO) {
                  /*
                   * The stack can't handle a TSO size larger than IP_MAXPACKET,
                   * but some MACs do.
                   */
                  if_sethwtsomax(ifp, min(scctx->isc_tx_tso_size_max,
                      IP_MAXPACKET));
                  /*
                   * Take maximum number of m_pullup(9)'s in iflib_parse_header()
                   * into account.  In the worst case, each of these calls will
                   * add another mbuf and, thus, the requirement for another DMA
                   * segment.  So for best performance, it doesn't make sense to
                   * advertize a maximum of TSO segments that typically will
                   * require defragmentation in iflib_encap().
                   */
                  if_sethwtsomaxsegcount(ifp, scctx->isc_tx_tso_segments_max - 3);
                  if_sethwtsomaxsegsize(ifp, scctx->isc_tx_tso_segsize_max);
          }
          if (scctx->isc_rss_table_size == 0)
                  scctx->isc_rss_table_size = 64;
          scctx->isc_rss_table_mask = scctx->isc_rss_table_size-1;
  
          GROUPTASK_INIT(&ctx->ifc_admin_task, 0, _task_fn_admin, ctx);
          /* XXX format name */
          taskqgroup_attach(qgroup_if_config_tqg, &ctx->ifc_admin_task, ctx,
              NULL, NULL, "admin");
  
          /* XXX --- can support > 1 -- but keep it simple for now */
          scctx->isc_intr = IFLIB_INTR_LEGACY;
  
          /* Get memory for the station queues */
          if ((err = iflib_queues_alloc(ctx))) {
                  device_printf(dev, "Unable to allocate queue memory\n");
                  goto fail_iflib_detach;
          }
  
          if ((err = iflib_qset_structures_setup(ctx))) {
                  device_printf(dev, "qset structure setup failed %d\n", err);
                  goto fail_queues;
          }
  
          /*
           * XXX What if anything do we want to do about interrupts?
           */
          ether_ifattach(ctx->ifc_ifp, ctx->ifc_mac.octet);
          if ((err = IFDI_ATTACH_POST(ctx)) != 0) {
                  device_printf(dev, "IFDI_ATTACH_POST failed %d\n", err);
                  goto fail_detach;
          }
  
          /*
           * Tell the upper layer(s) if IFCAP_VLAN_MTU is supported.
           * This must appear after the call to ether_ifattach() because
           * ether_ifattach() sets if_hdrlen to the default value.
           */
          if (if_getcapabilities(ifp) & IFCAP_VLAN_MTU)
                  if_setifheaderlen(ifp, sizeof(struct ether_vlan_header));
  
          /* XXX handle more than one queue */
          for (i = 0; i < scctx->isc_nrxqsets; i++)
                  IFDI_RX_CLSET(ctx, 0, i, ctx->ifc_rxqs[i].ifr_fl[0].ifl_sds.ifsd_cl);
  
          *ctxp = ctx;
  
          if_setgetcounterfn(ctx->ifc_ifp, iflib_if_get_counter);
          iflib_add_device_sysctl_post(ctx);
          ctx->ifc_flags |= IFC_INIT_DONE;
          CTX_UNLOCK(ctx);
  
          return (0);
  fail_detach:
          ether_ifdetach(ctx->ifc_ifp);
  fail_queues:
          iflib_tqg_detach(ctx);
          iflib_tx_structures_free(ctx);
          iflib_rx_structures_free(ctx);
  fail_iflib_detach:
          IFDI_DETACH(ctx);
          IFDI_QUEUES_FREE(ctx);
  fail_unlock:
          CTX_UNLOCK(ctx);
          iflib_deregister(ctx);
  fail_ctx_free:
          free(ctx->ifc_softc, M_IFLIB);
          free(ctx, M_IFLIB);
          return (err);
  }
  
  int
  iflib_pseudo_deregister(if_ctx_t ctx)
  {
          if_t ifp = ctx->ifc_ifp;
          if_shared_ctx_t sctx = ctx->ifc_sctx;
  
          /* Unregister VLAN event handlers early */
          iflib_unregister_vlan_handlers(ctx);
  
          if ((sctx->isc_flags & IFLIB_PSEUDO)  &&
                  (sctx->isc_flags & IFLIB_PSEUDO_ETHER) == 0) {
                  bpfdetach(ifp);
                  if_detach(ifp);
          } else {
                  ether_ifdetach(ifp);
          }
  
          iflib_tqg_detach(ctx);
          iflib_tx_structures_free(ctx);
          iflib_rx_structures_free(ctx);
          IFDI_DETACH(ctx);
          IFDI_QUEUES_FREE(ctx);
  
          iflib_deregister(ctx);
  
          if (ctx->ifc_flags & IFC_SC_ALLOCATED)
                  free(ctx->ifc_softc, M_IFLIB);
          free(ctx, M_IFLIB);
          return (0);
  }
  
  int
  iflib_device_attach(device_t dev)
  {
          if_ctx_t ctx;
          if_shared_ctx_t sctx;
  
          if ((sctx = DEVICE_REGISTER(dev)) == NULL || sctx->isc_magic != IFLIB_MAGIC)
                  return (ENOTSUP);
  
          pci_enable_busmaster(dev);
  
          return (iflib_device_register(dev, NULL, sctx, &ctx));
  }
  
  int
  iflib_device_deregister(if_ctx_t ctx)
  {
          if_t ifp = ctx->ifc_ifp;
          device_t dev = ctx->ifc_dev;
  
          /* Make sure VLANS are not using driver */
          if (if_vlantrunkinuse(ifp)) {
                  device_printf(dev, "Vlan in use, detach first\n");
                  return (EBUSY);
          }
  #ifdef PCI_IOV
          if (!CTX_IS_VF(ctx) && pci_iov_detach(dev) != 0) {
                  device_printf(dev, "SR-IOV in use; detach first.\n");
                  return (EBUSY);
          }
  #endif
  
          STATE_LOCK(ctx);
          ctx->ifc_flags |= IFC_IN_DETACH;
          STATE_UNLOCK(ctx);
  
          /* Unregister VLAN handlers before calling iflib_stop() */
          iflib_unregister_vlan_handlers(ctx);
  
          iflib_netmap_detach(ifp);
          ether_ifdetach(ifp);
  
          CTX_LOCK(ctx);
          iflib_stop(ctx);
          CTX_UNLOCK(ctx);
  
          iflib_rem_pfil(ctx);
          if (ctx->ifc_led_dev != NULL)
                  led_destroy(ctx->ifc_led_dev);
  
          iflib_tqg_detach(ctx);
          iflib_tx_structures_free(ctx);
          iflib_rx_structures_free(ctx);
  
          CTX_LOCK(ctx);
          IFDI_DETACH(ctx);
          IFDI_QUEUES_FREE(ctx);
          CTX_UNLOCK(ctx);
  
          /* ether_ifdetach calls if_qflush - lock must be destroy afterwards*/
          iflib_free_intr_mem(ctx);
  
          bus_generic_detach(dev);
  
          iflib_deregister(ctx);
  
          device_set_softc(ctx->ifc_dev, NULL);
          if (ctx->ifc_flags & IFC_SC_ALLOCATED)
                  free(ctx->ifc_softc, M_IFLIB);
          unref_ctx_core_offset(ctx);
          free(ctx, M_IFLIB);
          return (0);
  }
  
  static void
  iflib_tqg_detach(if_ctx_t ctx)
  {
          iflib_txq_t txq;
          iflib_rxq_t rxq;
          int i;
          struct taskqgroup *tqg;
  
          /* XXX drain any dependent tasks */
          tqg = qgroup_if_io_tqg;
          for (txq = ctx->ifc_txqs, i = 0; i < NTXQSETS(ctx); i++, txq++) {
                  callout_drain(&txq->ift_timer);
  #ifdef DEV_NETMAP
                  callout_drain(&txq->ift_netmap_timer);
  #endif /* DEV_NETMAP */
                  if (txq->ift_task.gt_uniq != NULL)
                          taskqgroup_detach(tqg, &txq->ift_task);
          }
          for (i = 0, rxq = ctx->ifc_rxqs; i < NRXQSETS(ctx); i++, rxq++) {
                  if (rxq->ifr_task.gt_uniq != NULL)
                          taskqgroup_detach(tqg, &rxq->ifr_task);
          }
          tqg = qgroup_if_config_tqg;
          if (ctx->ifc_admin_task.gt_uniq != NULL)
                  taskqgroup_detach(tqg, &ctx->ifc_admin_task);
          if (ctx->ifc_vflr_task.gt_uniq != NULL)
                  taskqgroup_detach(tqg, &ctx->ifc_vflr_task);
  }
  
  static void
  iflib_free_intr_mem(if_ctx_t ctx)
  {
  
          if (ctx->ifc_softc_ctx.isc_intr != IFLIB_INTR_MSIX) {
                  iflib_irq_free(ctx, &ctx->ifc_legacy_irq);
          }
          if (ctx->ifc_softc_ctx.isc_intr != IFLIB_INTR_LEGACY) {
                  pci_release_msi(ctx->ifc_dev);
          }
          if (ctx->ifc_msix_mem != NULL) {
                  bus_release_resource(ctx->ifc_dev, SYS_RES_MEMORY,
                      rman_get_rid(ctx->ifc_msix_mem), ctx->ifc_msix_mem);
                  ctx->ifc_msix_mem = NULL;
          }
  }
  
  int
  iflib_device_detach(device_t dev)
  {
          if_ctx_t ctx = device_get_softc(dev);
  
          return (iflib_device_deregister(ctx));
  }
  
  int
  iflib_device_suspend(device_t dev)
  {
          if_ctx_t ctx = device_get_softc(dev);
  
          CTX_LOCK(ctx);
          IFDI_SUSPEND(ctx);
          CTX_UNLOCK(ctx);
  
          return bus_generic_suspend(dev);
  }
  int
  iflib_device_shutdown(device_t dev)
  {
          if_ctx_t ctx = device_get_softc(dev);
  
          CTX_LOCK(ctx);
          IFDI_SHUTDOWN(ctx);
          CTX_UNLOCK(ctx);
  
          return bus_generic_suspend(dev);
  }
  
  int
  iflib_device_resume(device_t dev)
  {
          if_ctx_t ctx = device_get_softc(dev);
          iflib_txq_t txq = ctx->ifc_txqs;
  
          CTX_LOCK(ctx);
          IFDI_RESUME(ctx);
          iflib_if_init_locked(ctx);
          CTX_UNLOCK(ctx);
          for (int i = 0; i < NTXQSETS(ctx); i++, txq++)
                  iflib_txq_check_drain(txq, IFLIB_RESTART_BUDGET);
  
          return (bus_generic_resume(dev));
  }
  
  int
  iflib_device_iov_init(device_t dev, uint16_t num_vfs, const nvlist_t *params)
  {
          int error;
          if_ctx_t ctx = device_get_softc(dev);
  
          CTX_LOCK(ctx);
          error = IFDI_IOV_INIT(ctx, num_vfs, params);
          CTX_UNLOCK(ctx);
  
          return (error);
  }
  
  void
  iflib_device_iov_uninit(device_t dev)
  {
          if_ctx_t ctx = device_get_softc(dev);
  
          CTX_LOCK(ctx);
          IFDI_IOV_UNINIT(ctx);
          CTX_UNLOCK(ctx);
  }
  
  int
  iflib_device_iov_add_vf(device_t dev, uint16_t vfnum, const nvlist_t *params)
  {
          int error;
          if_ctx_t ctx = device_get_softc(dev);
  
          CTX_LOCK(ctx);
          error = IFDI_IOV_VF_ADD(ctx, vfnum, params);
          CTX_UNLOCK(ctx);
  
          return (error);
  }
  
  /*********************************************************************
   *
   *  MODULE FUNCTION DEFINITIONS
   *
   **********************************************************************/
  
  /*
   * - Start a fast taskqueue thread for each core
   * - Start a taskqueue for control operations
   */
  static int
  iflib_module_init(void)
  {
          iflib_timer_default = hz / 2;
          return (0);
  }
  
  static int
  iflib_module_event_handler(module_t mod, int what, void *arg)
  {
          int err;
  
          switch (what) {
          case MOD_LOAD:
                  if ((err = iflib_module_init()) != 0)
                          return (err);
                  break;
          case MOD_UNLOAD:
                  return (EBUSY);
          default:
                  return (EOPNOTSUPP);
          }
  
          return (0);
  }
  
  /*********************************************************************
   *
   *  PUBLIC FUNCTION DEFINITIONS
   *     ordered as in iflib.h
   *
   **********************************************************************/
  
  static void
  _iflib_assert(if_shared_ctx_t sctx)
  {
          int i;
  
          MPASS(sctx->isc_tx_maxsize);
          MPASS(sctx->isc_tx_maxsegsize);
  
          MPASS(sctx->isc_rx_maxsize);
          MPASS(sctx->isc_rx_nsegments);
          MPASS(sctx->isc_rx_maxsegsize);
  
          MPASS(sctx->isc_nrxqs >= 1 && sctx->isc_nrxqs <= 8);
          for (i = 0; i < sctx->isc_nrxqs; i++) {
                  MPASS(sctx->isc_nrxd_min[i]);
                  MPASS(powerof2(sctx->isc_nrxd_min[i]));
                  MPASS(sctx->isc_nrxd_max[i]);
                  MPASS(powerof2(sctx->isc_nrxd_max[i]));
                  MPASS(sctx->isc_nrxd_default[i]);
                  MPASS(powerof2(sctx->isc_nrxd_default[i]));
          }
  
          MPASS(sctx->isc_ntxqs >= 1 && sctx->isc_ntxqs <= 8);
          for (i = 0; i < sctx->isc_ntxqs; i++) {
                  MPASS(sctx->isc_ntxd_min[i]);
                  MPASS(powerof2(sctx->isc_ntxd_min[i]));
                  MPASS(sctx->isc_ntxd_max[i]);
                  MPASS(powerof2(sctx->isc_ntxd_max[i]));
                  MPASS(sctx->isc_ntxd_default[i]);
                  MPASS(powerof2(sctx->isc_ntxd_default[i]));
          }
  }
  
  static void
  _iflib_pre_assert(if_softc_ctx_t scctx)
  {
  
          MPASS(scctx->isc_txrx->ift_txd_encap);
          MPASS(scctx->isc_txrx->ift_txd_flush);
          MPASS(scctx->isc_txrx->ift_txd_credits_update);
          MPASS(scctx->isc_txrx->ift_rxd_available);
          MPASS(scctx->isc_txrx->ift_rxd_pkt_get);
          MPASS(scctx->isc_txrx->ift_rxd_refill);
          MPASS(scctx->isc_txrx->ift_rxd_flush);
  }
  
  static int
  iflib_register(if_ctx_t ctx)
  {
          if_shared_ctx_t sctx = ctx->ifc_sctx;
          driver_t *driver = sctx->isc_driver;
          device_t dev = ctx->ifc_dev;
          if_t ifp;
          u_char type;
          int iflags;
  
          if ((sctx->isc_flags & IFLIB_PSEUDO) == 0)
                  _iflib_assert(sctx);
  
          CTX_LOCK_INIT(ctx);
          STATE_LOCK_INIT(ctx, device_get_nameunit(ctx->ifc_dev));
          if (sctx->isc_flags & IFLIB_PSEUDO) {
                  if (sctx->isc_flags & IFLIB_PSEUDO_ETHER)
                          type = IFT_ETHER;
                  else
                          type = IFT_PPP;
          } else
                  type = IFT_ETHER;
          ifp = ctx->ifc_ifp = if_alloc(type);
          if (ifp == NULL) {
                  device_printf(dev, "can not allocate ifnet structure\n");
                  return (ENOMEM);
          }
  
          /*
           * Initialize our context's device specific methods
           */
          kobj_init((kobj_t) ctx, (kobj_class_t) driver);
          kobj_class_compile((kobj_class_t) driver);
  
          if_initname(ifp, device_get_name(dev), device_get_unit(dev));
          if_setsoftc(ifp, ctx);
          if_setdev(ifp, dev);
          if_setinitfn(ifp, iflib_if_init);
          if_setioctlfn(ifp, iflib_if_ioctl);
  #ifdef ALTQ
          if_setstartfn(ifp, iflib_altq_if_start);
          if_settransmitfn(ifp, iflib_altq_if_transmit);
          if_setsendqready(ifp);
  #else
          if_settransmitfn(ifp, iflib_if_transmit);
  #endif
          if_setqflushfn(ifp, iflib_if_qflush);
          iflags = IFF_MULTICAST | IFF_KNOWSEPOCH;
  
          if ((sctx->isc_flags & IFLIB_PSEUDO) &&
                  (sctx->isc_flags & IFLIB_PSEUDO_ETHER) == 0)
                  iflags |= IFF_POINTOPOINT;
          else
                  iflags |= IFF_BROADCAST | IFF_SIMPLEX;
          if_setflags(ifp, iflags);
          ctx->ifc_vlan_attach_event =
                  EVENTHANDLER_REGISTER(vlan_config, iflib_vlan_register, ctx,
                                                            EVENTHANDLER_PRI_FIRST);
          ctx->ifc_vlan_detach_event =
                  EVENTHANDLER_REGISTER(vlan_unconfig, iflib_vlan_unregister, ctx,
                                                            EVENTHANDLER_PRI_FIRST);
  
          if ((sctx->isc_flags & IFLIB_DRIVER_MEDIA) == 0) {
                  ctx->ifc_mediap = &ctx->ifc_media;
                  ifmedia_init(ctx->ifc_mediap, IFM_IMASK,
                      iflib_media_change, iflib_media_status);
          }
          return (0);
  }
  
  static void
  iflib_unregister_vlan_handlers(if_ctx_t ctx)
  {
          /* Unregister VLAN events */
          if (ctx->ifc_vlan_attach_event != NULL) {
                  EVENTHANDLER_DEREGISTER(vlan_config, ctx->ifc_vlan_attach_event);
                  ctx->ifc_vlan_attach_event = NULL;
          }
          if (ctx->ifc_vlan_detach_event != NULL) {
                  EVENTHANDLER_DEREGISTER(vlan_unconfig, ctx->ifc_vlan_detach_event);
                  ctx->ifc_vlan_detach_event = NULL;
          }
  
  }
  
  static void
  iflib_deregister(if_ctx_t ctx)
  {
          if_t ifp = ctx->ifc_ifp;
  
          /* Remove all media */
          ifmedia_removeall(&ctx->ifc_media);
  
          /* Ensure that VLAN event handlers are unregistered */
          iflib_unregister_vlan_handlers(ctx);
  
          /* Release kobject reference */
          kobj_delete((kobj_t) ctx, NULL);
  
          /* Free the ifnet structure */
          if_free(ifp);
  
          STATE_LOCK_DESTROY(ctx);
  
          /* ether_ifdetach calls if_qflush - lock must be destroy afterwards*/
          CTX_LOCK_DESTROY(ctx);
  }
  
  static int
  iflib_queues_alloc(if_ctx_t ctx)
  {
          if_shared_ctx_t sctx = ctx->ifc_sctx;
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          device_t dev = ctx->ifc_dev;
          int nrxqsets = scctx->isc_nrxqsets;
          int ntxqsets = scctx->isc_ntxqsets;
          iflib_txq_t txq;
          iflib_rxq_t rxq;
          iflib_fl_t fl = NULL;
          int i, j, cpu, err, txconf, rxconf;
          iflib_dma_info_t ifdip;
          uint32_t *rxqsizes = scctx->isc_rxqsizes;
          uint32_t *txqsizes = scctx->isc_txqsizes;
          uint8_t nrxqs = sctx->isc_nrxqs;
          uint8_t ntxqs = sctx->isc_ntxqs;
          int nfree_lists = sctx->isc_nfl ? sctx->isc_nfl : 1;
          int fl_offset = (sctx->isc_flags & IFLIB_HAS_RXCQ ? 1 : 0);
          caddr_t *vaddrs;
          uint64_t *paddrs;
  
          KASSERT(ntxqs > 0, ("number of queues per qset must be at least 1"));
          KASSERT(nrxqs > 0, ("number of queues per qset must be at least 1"));
          KASSERT(nrxqs >= fl_offset + nfree_lists,
             ("there must be at least a rxq for each free list"));
  
          /* Allocate the TX ring struct memory */
          if (!(ctx->ifc_txqs =
              (iflib_txq_t) malloc(sizeof(struct iflib_txq) *
              ntxqsets, M_IFLIB, M_NOWAIT | M_ZERO))) {
                  device_printf(dev, "Unable to allocate TX ring memory\n");
                  err = ENOMEM;
                  goto fail;
          }
  
          /* Now allocate the RX */
          if (!(ctx->ifc_rxqs =
              (iflib_rxq_t) malloc(sizeof(struct iflib_rxq) *
              nrxqsets, M_IFLIB, M_NOWAIT | M_ZERO))) {
                  device_printf(dev, "Unable to allocate RX ring memory\n");
                  err = ENOMEM;
                  goto rx_fail;
          }
  
          txq = ctx->ifc_txqs;
          rxq = ctx->ifc_rxqs;
  
          /*
           * XXX handle allocation failure
           */
          for (txconf = i = 0, cpu = CPU_FIRST(); i < ntxqsets; i++, txconf++, txq++, cpu = CPU_NEXT(cpu)) {
                  /* Set up some basics */
  
                  if ((ifdip = malloc(sizeof(struct iflib_dma_info) * ntxqs,
                      M_IFLIB, M_NOWAIT | M_ZERO)) == NULL) {
                          device_printf(dev,
                              "Unable to allocate TX DMA info memory\n");
                          err = ENOMEM;
                          goto err_tx_desc;
                  }
                  txq->ift_ifdi = ifdip;
                  for (j = 0; j < ntxqs; j++, ifdip++) {
                          if (iflib_dma_alloc(ctx, txqsizes[j], ifdip, 0)) {
                                  device_printf(dev,
                                      "Unable to allocate TX descriptors\n");
                                  err = ENOMEM;
                                  goto err_tx_desc;
                          }
                          txq->ift_txd_size[j] = scctx->isc_txd_size[j];
                          bzero((void *)ifdip->idi_vaddr, txqsizes[j]);
                  }
                  txq->ift_ctx = ctx;
                  txq->ift_id = i;
                  if (sctx->isc_flags & IFLIB_HAS_TXCQ) {
                          txq->ift_br_offset = 1;
                  } else {
                          txq->ift_br_offset = 0;
                  }
  
                  if (iflib_txsd_alloc(txq)) {
                          device_printf(dev, "Critical Failure setting up TX buffers\n");
                          err = ENOMEM;
                          goto err_tx_desc;
                  }
  
                  /* Initialize the TX lock */
                  snprintf(txq->ift_mtx_name, MTX_NAME_LEN, "%s:TX(%d):callout",
                      device_get_nameunit(dev), txq->ift_id);
                  mtx_init(&txq->ift_mtx, txq->ift_mtx_name, NULL, MTX_DEF);
                  callout_init_mtx(&txq->ift_timer, &txq->ift_mtx, 0);
                  txq->ift_timer.c_cpu = cpu;
  #ifdef DEV_NETMAP
                  callout_init_mtx(&txq->ift_netmap_timer, &txq->ift_mtx, 0);
                  txq->ift_netmap_timer.c_cpu = cpu;
  #endif /* DEV_NETMAP */
  
                  err = ifmp_ring_alloc(&txq->ift_br, 2048, txq, iflib_txq_drain,
                                        iflib_txq_can_drain, M_IFLIB, M_WAITOK);
                  if (err) {
                          /* XXX free any allocated rings */
                          device_printf(dev, "Unable to allocate buf_ring\n");
                          goto err_tx_desc;
                  }
          }
  
          for (rxconf = i = 0; i < nrxqsets; i++, rxconf++, rxq++) {
                  /* Set up some basics */
                  callout_init(&rxq->ifr_watchdog, 1);
  
                  if ((ifdip = malloc(sizeof(struct iflib_dma_info) * nrxqs,
                     M_IFLIB, M_NOWAIT | M_ZERO)) == NULL) {
                          device_printf(dev,
                              "Unable to allocate RX DMA info memory\n");
                          err = ENOMEM;
                          goto err_tx_desc;
                  }
  
                  rxq->ifr_ifdi = ifdip;
                  /* XXX this needs to be changed if #rx queues != #tx queues */
                  rxq->ifr_ntxqirq = 1;
                  rxq->ifr_txqid[0] = i;
                  for (j = 0; j < nrxqs; j++, ifdip++) {
                          if (iflib_dma_alloc(ctx, rxqsizes[j], ifdip, 0)) {
                                  device_printf(dev,
                                      "Unable to allocate RX descriptors\n");
                                  err = ENOMEM;
                                  goto err_tx_desc;
                          }
                          bzero((void *)ifdip->idi_vaddr, rxqsizes[j]);
                  }
                  rxq->ifr_ctx = ctx;
                  rxq->ifr_id = i;
                  rxq->ifr_fl_offset = fl_offset;
                  rxq->ifr_nfl = nfree_lists;
                  if (!(fl =
                            (iflib_fl_t) malloc(sizeof(struct iflib_fl) * nfree_lists, M_IFLIB, M_NOWAIT | M_ZERO))) {
                          device_printf(dev, "Unable to allocate free list memory\n");
                          err = ENOMEM;
                          goto err_tx_desc;
                  }
                  rxq->ifr_fl = fl;
                  for (j = 0; j < nfree_lists; j++) {
                          fl[j].ifl_rxq = rxq;
                          fl[j].ifl_id = j;
                          fl[j].ifl_ifdi = &rxq->ifr_ifdi[j + rxq->ifr_fl_offset];
                          fl[j].ifl_rxd_size = scctx->isc_rxd_size[j];
                  }
                  /* Allocate receive buffers for the ring */
                  if (iflib_rxsd_alloc(rxq)) {
                          device_printf(dev,
                              "Critical Failure setting up receive buffers\n");
                          err = ENOMEM;
                          goto err_rx_desc;
                  }
  
                  for (j = 0, fl = rxq->ifr_fl; j < rxq->ifr_nfl; j++, fl++) 
                          fl->ifl_rx_bitmap = bit_alloc(fl->ifl_size, M_IFLIB,
                              M_WAITOK);
          }
  
          /* TXQs */
          vaddrs = malloc(sizeof(caddr_t)*ntxqsets*ntxqs, M_IFLIB, M_WAITOK);
          paddrs = malloc(sizeof(uint64_t)*ntxqsets*ntxqs, M_IFLIB, M_WAITOK);
          for (i = 0; i < ntxqsets; i++) {
                  iflib_dma_info_t di = ctx->ifc_txqs[i].ift_ifdi;
  
                  for (j = 0; j < ntxqs; j++, di++) {
                          vaddrs[i*ntxqs + j] = di->idi_vaddr;
                          paddrs[i*ntxqs + j] = di->idi_paddr;
                  }
          }
          if ((err = IFDI_TX_QUEUES_ALLOC(ctx, vaddrs, paddrs, ntxqs, ntxqsets)) != 0) {
                  device_printf(ctx->ifc_dev,
                      "Unable to allocate device TX queue\n");
                  iflib_tx_structures_free(ctx);
                  free(vaddrs, M_IFLIB);
                  free(paddrs, M_IFLIB);
                  goto err_rx_desc;
          }
          free(vaddrs, M_IFLIB);
          free(paddrs, M_IFLIB);
  
          /* RXQs */
          vaddrs = malloc(sizeof(caddr_t)*nrxqsets*nrxqs, M_IFLIB, M_WAITOK);
          paddrs = malloc(sizeof(uint64_t)*nrxqsets*nrxqs, M_IFLIB, M_WAITOK);
          for (i = 0; i < nrxqsets; i++) {
                  iflib_dma_info_t di = ctx->ifc_rxqs[i].ifr_ifdi;
  
                  for (j = 0; j < nrxqs; j++, di++) {
                          vaddrs[i*nrxqs + j] = di->idi_vaddr;
                          paddrs[i*nrxqs + j] = di->idi_paddr;
                  }
          }
          if ((err = IFDI_RX_QUEUES_ALLOC(ctx, vaddrs, paddrs, nrxqs, nrxqsets)) != 0) {
                  device_printf(ctx->ifc_dev,
                      "Unable to allocate device RX queue\n");
                  iflib_tx_structures_free(ctx);
                  free(vaddrs, M_IFLIB);
                  free(paddrs, M_IFLIB);
                  goto err_rx_desc;
          }
          free(vaddrs, M_IFLIB);
          free(paddrs, M_IFLIB);
  
          return (0);
  
  /* XXX handle allocation failure changes */
  err_rx_desc:
  err_tx_desc:
  rx_fail:
          if (ctx->ifc_rxqs != NULL)
                  free(ctx->ifc_rxqs, M_IFLIB);
          ctx->ifc_rxqs = NULL;
          if (ctx->ifc_txqs != NULL)
                  free(ctx->ifc_txqs, M_IFLIB);
          ctx->ifc_txqs = NULL;
  fail:
          return (err);
  }
  
  static int
  iflib_tx_structures_setup(if_ctx_t ctx)
  {
          iflib_txq_t txq = ctx->ifc_txqs;
          int i;
  
          for (i = 0; i < NTXQSETS(ctx); i++, txq++)
                  iflib_txq_setup(txq);
  
          return (0);
  }
  
  static void
  iflib_tx_structures_free(if_ctx_t ctx)
  {
          iflib_txq_t txq = ctx->ifc_txqs;
          if_shared_ctx_t sctx = ctx->ifc_sctx;
          int i, j;
  
          for (i = 0; i < NTXQSETS(ctx); i++, txq++) {
                  for (j = 0; j < sctx->isc_ntxqs; j++)
                          iflib_dma_free(&txq->ift_ifdi[j]);
                  iflib_txq_destroy(txq);
          }
          free(ctx->ifc_txqs, M_IFLIB);
          ctx->ifc_txqs = NULL;
  }
  
  /*********************************************************************
   *
   *  Initialize all receive rings.
   *
   **********************************************************************/
  static int
  iflib_rx_structures_setup(if_ctx_t ctx)
  {
          iflib_rxq_t rxq = ctx->ifc_rxqs;
          int q;
  #if defined(INET6) || defined(INET)
          int err, i;
  #endif
  
          for (q = 0; q < ctx->ifc_softc_ctx.isc_nrxqsets; q++, rxq++) {
  #if defined(INET6) || defined(INET)
                  err = tcp_lro_init_args(&rxq->ifr_lc, ctx->ifc_ifp,
                      TCP_LRO_ENTRIES, min(1024,
                      ctx->ifc_softc_ctx.isc_nrxd[rxq->ifr_fl_offset]));
                  if (err != 0) {
                          device_printf(ctx->ifc_dev,
                              "LRO Initialization failed!\n");
                          goto fail;
                  }
  #endif
                  IFDI_RXQ_SETUP(ctx, rxq->ifr_id);
          }
          return (0);
  #if defined(INET6) || defined(INET)
  fail:
          /*
           * Free LRO resources allocated so far, we will only handle
           * the rings that completed, the failing case will have
           * cleaned up for itself.  'q' failed, so its the terminus.
           */
          rxq = ctx->ifc_rxqs;
          for (i = 0; i < q; ++i, rxq++) {
                  tcp_lro_free(&rxq->ifr_lc);
          }
          return (err);
  #endif
  }
  
  /*********************************************************************
   *
   *  Free all receive rings.
   *
   **********************************************************************/
  static void
  iflib_rx_structures_free(if_ctx_t ctx)
  {
          iflib_rxq_t rxq = ctx->ifc_rxqs;
          if_shared_ctx_t sctx = ctx->ifc_sctx;
          int i, j;
  
          for (i = 0; i < ctx->ifc_softc_ctx.isc_nrxqsets; i++, rxq++) {
                  for (j = 0; j < sctx->isc_nrxqs; j++)
                          iflib_dma_free(&rxq->ifr_ifdi[j]);
                  iflib_rx_sds_free(rxq);
  #if defined(INET6) || defined(INET)
                  tcp_lro_free(&rxq->ifr_lc);
  #endif
          }
          free(ctx->ifc_rxqs, M_IFLIB);
          ctx->ifc_rxqs = NULL;
  }
  
  static int
  iflib_qset_structures_setup(if_ctx_t ctx)
  {
          int err;
  
          /*
           * It is expected that the caller takes care of freeing queues if this
           * fails.
           */
          if ((err = iflib_tx_structures_setup(ctx)) != 0) {
                  device_printf(ctx->ifc_dev, "iflib_tx_structures_setup failed: %d\n", err);
                  return (err);
          }
  
          if ((err = iflib_rx_structures_setup(ctx)) != 0)
                  device_printf(ctx->ifc_dev, "iflib_rx_structures_setup failed: %d\n", err);
  
          return (err);
  }
  
  int
  iflib_irq_alloc(if_ctx_t ctx, if_irq_t irq, int rid,
                  driver_filter_t filter, void *filter_arg, driver_intr_t handler, void *arg, const char *name)
  {
  
          return (_iflib_irq_alloc(ctx, irq, rid, filter, handler, arg, name));
  }
  
  /* Just to avoid copy/paste */
  static inline int
  iflib_irq_set_affinity(if_ctx_t ctx, if_irq_t irq, iflib_intr_type_t type,
      int qid, struct grouptask *gtask, struct taskqgroup *tqg, void *uniq,
      const char *name)
  {
          device_t dev;
          unsigned int base_cpuid, cpuid;
          int err;
  
          dev = ctx->ifc_dev;
          base_cpuid = ctx->ifc_sysctl_core_offset;
          cpuid = get_cpuid_for_queue(ctx, base_cpuid, qid, type == IFLIB_INTR_TX);
          err = taskqgroup_attach_cpu(tqg, gtask, uniq, cpuid, dev,
              irq ? irq->ii_res : NULL, name);
          if (err) {
                  device_printf(dev, "taskqgroup_attach_cpu failed %d\n", err);
                  return (err);
          }
  #ifdef notyet
          if (cpuid > ctx->ifc_cpuid_highest)
                  ctx->ifc_cpuid_highest = cpuid;
  #endif
          return (0);
  }
  
  int
  iflib_irq_alloc_generic(if_ctx_t ctx, if_irq_t irq, int rid,
                          iflib_intr_type_t type, driver_filter_t *filter,
                          void *filter_arg, int qid, const char *name)
  {
          device_t dev;
          struct grouptask *gtask;
          struct taskqgroup *tqg;
          iflib_filter_info_t info;
          gtask_fn_t *fn;
          int tqrid, err;
          driver_filter_t *intr_fast;
          void *q;
  
          info = &ctx->ifc_filter_info;
          tqrid = rid;
  
          switch (type) {
          /* XXX merge tx/rx for netmap? */
          case IFLIB_INTR_TX:
                  q = &ctx->ifc_txqs[qid];
                  info = &ctx->ifc_txqs[qid].ift_filter_info;
                  gtask = &ctx->ifc_txqs[qid].ift_task;
                  tqg = qgroup_if_io_tqg;
                  fn = _task_fn_tx;
                  intr_fast = iflib_fast_intr;
                  GROUPTASK_INIT(gtask, 0, fn, q);
                  ctx->ifc_flags |= IFC_NETMAP_TX_IRQ;
                  break;
          case IFLIB_INTR_RX:
                  q = &ctx->ifc_rxqs[qid];
                  info = &ctx->ifc_rxqs[qid].ifr_filter_info;
                  gtask = &ctx->ifc_rxqs[qid].ifr_task;
                  tqg = qgroup_if_io_tqg;
                  fn = _task_fn_rx;
                  intr_fast = iflib_fast_intr;
                  NET_GROUPTASK_INIT(gtask, 0, fn, q);
                  break;
          case IFLIB_INTR_RXTX:
                  q = &ctx->ifc_rxqs[qid];
                  info = &ctx->ifc_rxqs[qid].ifr_filter_info;
                  gtask = &ctx->ifc_rxqs[qid].ifr_task;
                  tqg = qgroup_if_io_tqg;
                  fn = _task_fn_rx;
                  intr_fast = iflib_fast_intr_rxtx;
                  NET_GROUPTASK_INIT(gtask, 0, fn, q);
                  break;
          case IFLIB_INTR_ADMIN:
                  q = ctx;
                  tqrid = -1;
                  info = &ctx->ifc_filter_info;
                  gtask = &ctx->ifc_admin_task;
                  tqg = qgroup_if_config_tqg;
                  fn = _task_fn_admin;
                  intr_fast = iflib_fast_intr_ctx;
                  break;
          default:
                  device_printf(ctx->ifc_dev, "%s: unknown net intr type\n",
                      __func__);
                  return (EINVAL);
          }
  
          info->ifi_filter = filter;
          info->ifi_filter_arg = filter_arg;
          info->ifi_task = gtask;
          info->ifi_ctx = q;
  
          dev = ctx->ifc_dev;
          err = _iflib_irq_alloc(ctx, irq, rid, intr_fast, NULL, info,  name);
          if (err != 0) {
                  device_printf(dev, "_iflib_irq_alloc failed %d\n", err);
                  return (err);
          }
          if (type == IFLIB_INTR_ADMIN)
                  return (0);
  
          if (tqrid != -1) {
                  err = iflib_irq_set_affinity(ctx, irq, type, qid, gtask, tqg, q,
                      name);
                  if (err)
                          return (err);
          } else {
                  taskqgroup_attach(tqg, gtask, q, dev, irq->ii_res, name);
          }
  
          return (0);
  }
  
  void
  iflib_softirq_alloc_generic(if_ctx_t ctx, if_irq_t irq, iflib_intr_type_t type, void *arg, int qid, const char *name)
  {
          device_t dev;
          struct grouptask *gtask;
          struct taskqgroup *tqg;
          gtask_fn_t *fn;
          void *q;
          int err;
  
          switch (type) {
          case IFLIB_INTR_TX:
                  q = &ctx->ifc_txqs[qid];
                  gtask = &ctx->ifc_txqs[qid].ift_task;
                  tqg = qgroup_if_io_tqg;
                  fn = _task_fn_tx;
                  GROUPTASK_INIT(gtask, 0, fn, q);
                  break;
          case IFLIB_INTR_RX:
                  q = &ctx->ifc_rxqs[qid];
                  gtask = &ctx->ifc_rxqs[qid].ifr_task;
                  tqg = qgroup_if_io_tqg;
                  fn = _task_fn_rx;
                  NET_GROUPTASK_INIT(gtask, 0, fn, q);
                  break;
          case IFLIB_INTR_IOV:
                  q = ctx;
                  gtask = &ctx->ifc_vflr_task;
                  tqg = qgroup_if_config_tqg;
                  fn = _task_fn_iov;
                  GROUPTASK_INIT(gtask, 0, fn, q);
                  break;
          default:
                  panic("unknown net intr type");
          }
          err = iflib_irq_set_affinity(ctx, irq, type, qid, gtask, tqg, q, name);
          if (err) {
                  dev = ctx->ifc_dev;
                  taskqgroup_attach(tqg, gtask, q, dev, irq ? irq->ii_res : NULL,
                      name);
          }
  }
  
  void
  iflib_irq_free(if_ctx_t ctx, if_irq_t irq)
  {
  
          if (irq->ii_tag)
                  bus_teardown_intr(ctx->ifc_dev, irq->ii_res, irq->ii_tag);
  
          if (irq->ii_res)
                  bus_release_resource(ctx->ifc_dev, SYS_RES_IRQ,
                      rman_get_rid(irq->ii_res), irq->ii_res);
  }
  
  static int
  iflib_legacy_setup(if_ctx_t ctx, driver_filter_t filter, void *filter_arg, int *rid, const char *name)
  {
          iflib_txq_t txq = ctx->ifc_txqs;
          iflib_rxq_t rxq = ctx->ifc_rxqs;
          if_irq_t irq = &ctx->ifc_legacy_irq;
          iflib_filter_info_t info;
          device_t dev;
          struct grouptask *gtask;
          struct resource *res;
          struct taskqgroup *tqg;
          void *q;
          int err, tqrid;
          bool rx_only;
  
          q = &ctx->ifc_rxqs[0];
          info = &rxq[0].ifr_filter_info;
          gtask = &rxq[0].ifr_task;
          tqg = qgroup_if_io_tqg;
          tqrid = *rid;
          rx_only = (ctx->ifc_sctx->isc_flags & IFLIB_SINGLE_IRQ_RX_ONLY) != 0;
  
          ctx->ifc_flags |= IFC_LEGACY;
          info->ifi_filter = filter;
          info->ifi_filter_arg = filter_arg;
          info->ifi_task = gtask;
          info->ifi_ctx = rx_only ? ctx : q;
  
          dev = ctx->ifc_dev;
          /* We allocate a single interrupt resource */
          err = _iflib_irq_alloc(ctx, irq, tqrid, rx_only ? iflib_fast_intr_ctx :
              iflib_fast_intr_rxtx, NULL, info, name);
          if (err != 0)
                  return (err);
          NET_GROUPTASK_INIT(gtask, 0, _task_fn_rx, q);
          res = irq->ii_res;
          taskqgroup_attach(tqg, gtask, q, dev, res, name);
  
          GROUPTASK_INIT(&txq->ift_task, 0, _task_fn_tx, txq);
          taskqgroup_attach(qgroup_if_io_tqg, &txq->ift_task, txq, dev, res,
              "tx");
          return (0);
  }
  
  void
  iflib_led_create(if_ctx_t ctx)
  {
  
          ctx->ifc_led_dev = led_create(iflib_led_func, ctx,
              device_get_nameunit(ctx->ifc_dev));
  }
  
  void
  iflib_tx_intr_deferred(if_ctx_t ctx, int txqid)
  {
  
          GROUPTASK_ENQUEUE(&ctx->ifc_txqs[txqid].ift_task);
  }
  
  void
  iflib_rx_intr_deferred(if_ctx_t ctx, int rxqid)
  {
  
          GROUPTASK_ENQUEUE(&ctx->ifc_rxqs[rxqid].ifr_task);
  }
  
  void
  iflib_admin_intr_deferred(if_ctx_t ctx)
  {
  
          MPASS(ctx->ifc_admin_task.gt_taskqueue != NULL);
          GROUPTASK_ENQUEUE(&ctx->ifc_admin_task);
  }
  
  void
  iflib_iov_intr_deferred(if_ctx_t ctx)
  {
  
          GROUPTASK_ENQUEUE(&ctx->ifc_vflr_task);
  }
  
  void
  iflib_io_tqg_attach(struct grouptask *gt, void *uniq, int cpu, const char *name)
  {
  
          taskqgroup_attach_cpu(qgroup_if_io_tqg, gt, uniq, cpu, NULL, NULL,
              name);
  }
  
  void
  iflib_config_gtask_init(void *ctx, struct grouptask *gtask, gtask_fn_t *fn,
          const char *name)
  {
  
          GROUPTASK_INIT(gtask, 0, fn, ctx);
          taskqgroup_attach(qgroup_if_config_tqg, gtask, gtask, NULL, NULL,
              name);
  }
  
  void
  iflib_config_gtask_deinit(struct grouptask *gtask)
  {
  
          taskqgroup_detach(qgroup_if_config_tqg, gtask); 
  }
  
  void
  iflib_link_state_change(if_ctx_t ctx, int link_state, uint64_t baudrate)
  {
          if_t ifp = ctx->ifc_ifp;
          iflib_txq_t txq = ctx->ifc_txqs;
  
          if_setbaudrate(ifp, baudrate);
          if (baudrate >= IF_Gbps(10)) {
                  STATE_LOCK(ctx);
                  ctx->ifc_flags |= IFC_PREFETCH;
                  STATE_UNLOCK(ctx);
          }
          /* If link down, disable watchdog */
          if ((ctx->ifc_link_state == LINK_STATE_UP) && (link_state == LINK_STATE_DOWN)) {
                  for (int i = 0; i < ctx->ifc_softc_ctx.isc_ntxqsets; i++, txq++)
                          txq->ift_qstatus = IFLIB_QUEUE_IDLE;
          }
          ctx->ifc_link_state = link_state;
          if_link_state_change(ifp, link_state);
  }
  
  static int
  iflib_tx_credits_update(if_ctx_t ctx, iflib_txq_t txq)
  {
          int credits;
  #ifdef INVARIANTS
          int credits_pre = txq->ift_cidx_processed;
  #endif
  
          bus_dmamap_sync(txq->ift_ifdi->idi_tag, txq->ift_ifdi->idi_map,
              BUS_DMASYNC_POSTREAD);
          if ((credits = ctx->isc_txd_credits_update(ctx->ifc_softc, txq->ift_id, true)) == 0)
                  return (0);
  
          txq->ift_processed += credits;
          txq->ift_cidx_processed += credits;
  
          MPASS(credits_pre + credits == txq->ift_cidx_processed);
          if (txq->ift_cidx_processed >= txq->ift_size)
                  txq->ift_cidx_processed -= txq->ift_size;
          return (credits);
  }
  
  static int
  iflib_rxd_avail(if_ctx_t ctx, iflib_rxq_t rxq, qidx_t cidx, qidx_t budget)
  {
          iflib_fl_t fl;
          u_int i;
  
          for (i = 0, fl = &rxq->ifr_fl[0]; i < rxq->ifr_nfl; i++, fl++)
                  bus_dmamap_sync(fl->ifl_ifdi->idi_tag, fl->ifl_ifdi->idi_map,
                      BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE);
          return (ctx->isc_rxd_available(ctx->ifc_softc, rxq->ifr_id, cidx,
              budget));
  }
  
  void
  iflib_add_int_delay_sysctl(if_ctx_t ctx, const char *name,
          const char *description, if_int_delay_info_t info,
          int offset, int value)
  {
          info->iidi_ctx = ctx;
          info->iidi_offset = offset;
          info->iidi_value = value;
          SYSCTL_ADD_PROC(device_get_sysctl_ctx(ctx->ifc_dev),
              SYSCTL_CHILDREN(device_get_sysctl_tree(ctx->ifc_dev)),
              OID_AUTO, name, CTLTYPE_INT | CTLFLAG_RW | CTLFLAG_MPSAFE,
              info, 0, iflib_sysctl_int_delay, "I", description);
  }
  
  struct sx *
  iflib_ctx_lock_get(if_ctx_t ctx)
  {
  
          return (&ctx->ifc_ctx_sx);
  }
  
  static int
  iflib_msix_init(if_ctx_t ctx)
  {
          device_t dev = ctx->ifc_dev;
          if_shared_ctx_t sctx = ctx->ifc_sctx;
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          int admincnt, bar, err, iflib_num_rx_queues, iflib_num_tx_queues;
          int msgs, queuemsgs, queues, rx_queues, tx_queues, vectors;
  
          iflib_num_tx_queues = ctx->ifc_sysctl_ntxqs;
          iflib_num_rx_queues = ctx->ifc_sysctl_nrxqs;
  
          if (bootverbose)
                  device_printf(dev, "msix_init qsets capped at %d\n",
                      imax(scctx->isc_ntxqsets, scctx->isc_nrxqsets));
  
          /* Override by tuneable */
          if (scctx->isc_disable_msix)
                  goto msi;
  
          /* First try MSI-X */
          if ((msgs = pci_msix_count(dev)) == 0) {
                  if (bootverbose)
                          device_printf(dev, "MSI-X not supported or disabled\n");
                  goto msi;
          }
  
          bar = ctx->ifc_softc_ctx.isc_msix_bar;
          /*
           * bar == -1 => "trust me I know what I'm doing"
           * Some drivers are for hardware that is so shoddily
           * documented that no one knows which bars are which
           * so the developer has to map all bars. This hack
           * allows shoddy garbage to use MSI-X in this framework.
           */
          if (bar != -1) {
                  ctx->ifc_msix_mem = bus_alloc_resource_any(dev,
                      SYS_RES_MEMORY, &bar, RF_ACTIVE);
                  if (ctx->ifc_msix_mem == NULL) {
                          device_printf(dev, "Unable to map MSI-X table\n");
                          goto msi;
                  }
          }
  
          admincnt = sctx->isc_admin_intrcnt;
  #if IFLIB_DEBUG
          /* use only 1 qset in debug mode */
          queuemsgs = min(msgs - admincnt, 1);
  #else
          queuemsgs = msgs - admincnt;
  #endif
  #ifdef RSS
          queues = imin(queuemsgs, rss_getnumbuckets());
  #else
          queues = queuemsgs;
  #endif
          queues = imin(CPU_COUNT(&ctx->ifc_cpus), queues);
          if (bootverbose)
                  device_printf(dev,
                      "intr CPUs: %d queue msgs: %d admincnt: %d\n",
                      CPU_COUNT(&ctx->ifc_cpus), queuemsgs, admincnt);
  #ifdef  RSS
          /* If we're doing RSS, clamp at the number of RSS buckets */
          if (queues > rss_getnumbuckets())
                  queues = rss_getnumbuckets();
  #endif
          if (iflib_num_rx_queues > 0 && iflib_num_rx_queues < queuemsgs - admincnt)
                  rx_queues = iflib_num_rx_queues;
          else
                  rx_queues = queues;
  
          if (rx_queues > scctx->isc_nrxqsets)
                  rx_queues = scctx->isc_nrxqsets;
  
          /*
           * We want this to be all logical CPUs by default
           */
          if (iflib_num_tx_queues > 0 && iflib_num_tx_queues < queues)
                  tx_queues = iflib_num_tx_queues;
          else
                  tx_queues = mp_ncpus;
  
          if (tx_queues > scctx->isc_ntxqsets)
                  tx_queues = scctx->isc_ntxqsets;
  
          if (ctx->ifc_sysctl_qs_eq_override == 0) {
  #ifdef INVARIANTS
                  if (tx_queues != rx_queues)
                          device_printf(dev,
                              "queue equality override not set, capping rx_queues at %d and tx_queues at %d\n",
                              min(rx_queues, tx_queues), min(rx_queues, tx_queues));
  #endif
                  tx_queues = min(rx_queues, tx_queues);
                  rx_queues = min(rx_queues, tx_queues);
          }
  
          vectors = rx_queues + admincnt;
          if (msgs < vectors) {
                  device_printf(dev,
                      "insufficient number of MSI-X vectors "
                      "(supported %d, need %d)\n", msgs, vectors);
                  goto msi;
          }
  
          device_printf(dev, "Using %d RX queues %d TX queues\n", rx_queues,
              tx_queues);
          msgs = vectors;
          if ((err = pci_alloc_msix(dev, &vectors)) == 0) {
                  if (vectors != msgs) {
                          device_printf(dev,
                              "Unable to allocate sufficient MSI-X vectors "
                              "(got %d, need %d)\n", vectors, msgs);
                          pci_release_msi(dev);
                          if (bar != -1) {
                                  bus_release_resource(dev, SYS_RES_MEMORY, bar,
                                      ctx->ifc_msix_mem);
                                  ctx->ifc_msix_mem = NULL;
                          }
                          goto msi;
                  }
                  device_printf(dev, "Using MSI-X interrupts with %d vectors\n",
                      vectors);
                  scctx->isc_vectors = vectors;
                  scctx->isc_nrxqsets = rx_queues;
                  scctx->isc_ntxqsets = tx_queues;
                  scctx->isc_intr = IFLIB_INTR_MSIX;
  
                  return (vectors);
          } else {
                  device_printf(dev,
                      "failed to allocate %d MSI-X vectors, err: %d\n", vectors,
                      err);
                  if (bar != -1) {
                          bus_release_resource(dev, SYS_RES_MEMORY, bar,
                              ctx->ifc_msix_mem);
                          ctx->ifc_msix_mem = NULL;
                  }
          }
  
  msi:
          vectors = pci_msi_count(dev);
          scctx->isc_nrxqsets = 1;
          scctx->isc_ntxqsets = 1;
          scctx->isc_vectors = vectors;
          if (vectors == 1 && pci_alloc_msi(dev, &vectors) == 0) {
                  device_printf(dev,"Using an MSI interrupt\n");
                  scctx->isc_intr = IFLIB_INTR_MSI;
          } else {
                  scctx->isc_vectors = 1;
                  device_printf(dev,"Using a Legacy interrupt\n");
                  scctx->isc_intr = IFLIB_INTR_LEGACY;
          }
  
          return (vectors);
  }
  
  static const char *ring_states[] = { "IDLE", "BUSY", "STALLED", "ABDICATED" };
  
  static int
  mp_ring_state_handler(SYSCTL_HANDLER_ARGS)
  {
          int rc;
          uint16_t *state = ((uint16_t *)oidp->oid_arg1);
          struct sbuf *sb;
          const char *ring_state = "UNKNOWN";
  
          /* XXX needed ? */
          rc = sysctl_wire_old_buffer(req, 0);
          MPASS(rc == 0);
          if (rc != 0)
                  return (rc);
          sb = sbuf_new_for_sysctl(NULL, NULL, 80, req);
          MPASS(sb != NULL);
          if (sb == NULL)
                  return (ENOMEM);
          if (state[3] <= 3)
                  ring_state = ring_states[state[3]];
  
          sbuf_printf(sb, "pidx_head: %04hd pidx_tail: %04hd cidx: %04hd state: %s",
                      state[0], state[1], state[2], ring_state);
          rc = sbuf_finish(sb);
          sbuf_delete(sb);
          return(rc);
  }
  
  enum iflib_ndesc_handler {
          IFLIB_NTXD_HANDLER,
          IFLIB_NRXD_HANDLER,
  };
  
  static int
  mp_ndesc_handler(SYSCTL_HANDLER_ARGS)
  {
          if_ctx_t ctx = (void *)arg1;
          enum iflib_ndesc_handler type = arg2;
          char buf[256] = {0};
          qidx_t *ndesc;
          char *p, *next;
          int nqs, rc, i;
  
          nqs = 8;
          switch(type) {
          case IFLIB_NTXD_HANDLER:
                  ndesc = ctx->ifc_sysctl_ntxds;
                  if (ctx->ifc_sctx)
                          nqs = ctx->ifc_sctx->isc_ntxqs;
                  break;
          case IFLIB_NRXD_HANDLER:
                  ndesc = ctx->ifc_sysctl_nrxds;
                  if (ctx->ifc_sctx)
                          nqs = ctx->ifc_sctx->isc_nrxqs;
                  break;
          default:
                  printf("%s: unhandled type\n", __func__);
                  return (EINVAL);
          }
          if (nqs == 0)
                  nqs = 8;
  
          for (i=0; i<8; i++) {
                  if (i >= nqs)
                          break;
                  if (i)
                          strcat(buf, ",");
                  sprintf(strchr(buf, 0), "%d", ndesc[i]);
          }
  
          rc = sysctl_handle_string(oidp, buf, sizeof(buf), req);
          if (rc || req->newptr == NULL)
                  return rc;
  
          for (i = 0, next = buf, p = strsep(&next, " ,"); i < 8 && p;
              i++, p = strsep(&next, " ,")) {
                  ndesc[i] = strtoul(p, NULL, 10);
          }
  
          return(rc);
  }
  
  #define NAME_BUFLEN 32
  static void
  iflib_add_device_sysctl_pre(if_ctx_t ctx)
  {
          device_t dev = iflib_get_dev(ctx);
          struct sysctl_oid_list *child, *oid_list;
          struct sysctl_ctx_list *ctx_list;
          struct sysctl_oid *node;
  
          ctx_list = device_get_sysctl_ctx(dev);
          child = SYSCTL_CHILDREN(device_get_sysctl_tree(dev));
          ctx->ifc_sysctl_node = node = SYSCTL_ADD_NODE(ctx_list, child, OID_AUTO, "iflib",
              CTLFLAG_RD | CTLFLAG_MPSAFE, NULL, "IFLIB fields");
          oid_list = SYSCTL_CHILDREN(node);
  
          SYSCTL_ADD_CONST_STRING(ctx_list, oid_list, OID_AUTO, "driver_version",
                         CTLFLAG_RD, ctx->ifc_sctx->isc_driver_version,
                         "driver version");
  
          SYSCTL_ADD_U16(ctx_list, oid_list, OID_AUTO, "override_ntxqs",
                         CTLFLAG_RWTUN, &ctx->ifc_sysctl_ntxqs, 0,
                          "# of txqs to use, 0 => use default #");
          SYSCTL_ADD_U16(ctx_list, oid_list, OID_AUTO, "override_nrxqs",
                         CTLFLAG_RWTUN, &ctx->ifc_sysctl_nrxqs, 0,
                          "# of rxqs to use, 0 => use default #");
          SYSCTL_ADD_U16(ctx_list, oid_list, OID_AUTO, "override_qs_enable",
                         CTLFLAG_RWTUN, &ctx->ifc_sysctl_qs_eq_override, 0,
                         "permit #txq != #rxq");
          SYSCTL_ADD_INT(ctx_list, oid_list, OID_AUTO, "disable_msix",
                        CTLFLAG_RWTUN, &ctx->ifc_softc_ctx.isc_disable_msix, 0,
                        "disable MSI-X (default 0)");
          SYSCTL_ADD_U16(ctx_list, oid_list, OID_AUTO, "rx_budget",
                         CTLFLAG_RWTUN, &ctx->ifc_sysctl_rx_budget, 0,
                         "set the RX budget");
          SYSCTL_ADD_U16(ctx_list, oid_list, OID_AUTO, "tx_abdicate",
                         CTLFLAG_RWTUN, &ctx->ifc_sysctl_tx_abdicate, 0,
                         "cause TX to abdicate instead of running to completion");
          ctx->ifc_sysctl_core_offset = CORE_OFFSET_UNSPECIFIED;
          SYSCTL_ADD_U16(ctx_list, oid_list, OID_AUTO, "core_offset",
                         CTLFLAG_RDTUN, &ctx->ifc_sysctl_core_offset, 0,
                         "offset to start using cores at");
          SYSCTL_ADD_U8(ctx_list, oid_list, OID_AUTO, "separate_txrx",
                         CTLFLAG_RDTUN, &ctx->ifc_sysctl_separate_txrx, 0,
                         "use separate cores for TX and RX");
          SYSCTL_ADD_U8(ctx_list, oid_list, OID_AUTO, "use_logical_cores",
                        CTLFLAG_RDTUN, &ctx->ifc_sysctl_use_logical_cores, 0,
                        "try to make use of logical cores for TX and RX");
  
          /* XXX change for per-queue sizes */
          SYSCTL_ADD_PROC(ctx_list, oid_list, OID_AUTO, "override_ntxds",
              CTLTYPE_STRING | CTLFLAG_RWTUN | CTLFLAG_NEEDGIANT, ctx,
              IFLIB_NTXD_HANDLER, mp_ndesc_handler, "A",
              "list of # of TX descriptors to use, 0 = use default #");
          SYSCTL_ADD_PROC(ctx_list, oid_list, OID_AUTO, "override_nrxds",
              CTLTYPE_STRING | CTLFLAG_RWTUN | CTLFLAG_NEEDGIANT, ctx,
              IFLIB_NRXD_HANDLER, mp_ndesc_handler, "A",
              "list of # of RX descriptors to use, 0 = use default #");
  }
  
  static void
  iflib_add_device_sysctl_post(if_ctx_t ctx)
  {
          if_shared_ctx_t sctx = ctx->ifc_sctx;
          if_softc_ctx_t scctx = &ctx->ifc_softc_ctx;
          device_t dev = iflib_get_dev(ctx);
          struct sysctl_oid_list *child;
          struct sysctl_ctx_list *ctx_list;
          iflib_fl_t fl;
          iflib_txq_t txq;
          iflib_rxq_t rxq;
          int i, j;
          char namebuf[NAME_BUFLEN];
          char *qfmt;
          struct sysctl_oid *queue_node, *fl_node, *node;
          struct sysctl_oid_list *queue_list, *fl_list;
          ctx_list = device_get_sysctl_ctx(dev);
  
          node = ctx->ifc_sysctl_node;
          child = SYSCTL_CHILDREN(node);
  
          if (scctx->isc_ntxqsets > 100)
                  qfmt = "txq%03d";
          else if (scctx->isc_ntxqsets > 10)
                  qfmt = "txq%02d";
          else
                  qfmt = "txq%d";
          for (i = 0, txq = ctx->ifc_txqs; i < scctx->isc_ntxqsets; i++, txq++) {
                  snprintf(namebuf, NAME_BUFLEN, qfmt, i);
                  queue_node = SYSCTL_ADD_NODE(ctx_list, child, OID_AUTO, namebuf,
                      CTLFLAG_RD | CTLFLAG_MPSAFE, NULL, "Queue Name");
                  queue_list = SYSCTL_CHILDREN(queue_node);
                  SYSCTL_ADD_INT(ctx_list, queue_list, OID_AUTO, "cpu",
                                 CTLFLAG_RD,
                                 &txq->ift_task.gt_cpu, 0, "cpu this queue is bound to");
  #if MEMORY_LOGGING
                  SYSCTL_ADD_QUAD(ctx_list, queue_list, OID_AUTO, "txq_dequeued",
                                  CTLFLAG_RD,
                                  &txq->ift_dequeued, "total mbufs freed");
                  SYSCTL_ADD_QUAD(ctx_list, queue_list, OID_AUTO, "txq_enqueued",
                                  CTLFLAG_RD,
                                  &txq->ift_enqueued, "total mbufs enqueued");
  #endif
                  SYSCTL_ADD_QUAD(ctx_list, queue_list, OID_AUTO, "mbuf_defrag",
                                     CTLFLAG_RD,
                                     &txq->ift_mbuf_defrag, "# of times m_defrag was called");
                  SYSCTL_ADD_QUAD(ctx_list, queue_list, OID_AUTO, "m_pullups",
                                     CTLFLAG_RD,
                                     &txq->ift_pullups, "# of times m_pullup was called");
                  SYSCTL_ADD_QUAD(ctx_list, queue_list, OID_AUTO, "mbuf_defrag_failed",
                                     CTLFLAG_RD,
                                     &txq->ift_mbuf_defrag_failed, "# of times m_defrag failed");
                  SYSCTL_ADD_QUAD(ctx_list, queue_list, OID_AUTO, "no_desc_avail",
                                     CTLFLAG_RD,
                                     &txq->ift_no_desc_avail, "# of times no descriptors were available");
                  SYSCTL_ADD_QUAD(ctx_list, queue_list, OID_AUTO, "tx_map_failed",
                                     CTLFLAG_RD,
                                     &txq->ift_map_failed, "# of times DMA map failed");
                  SYSCTL_ADD_QUAD(ctx_list, queue_list, OID_AUTO, "txd_encap_efbig",
                                     CTLFLAG_RD,
                                     &txq->ift_txd_encap_efbig, "# of times txd_encap returned EFBIG");
                  SYSCTL_ADD_QUAD(ctx_list, queue_list, OID_AUTO, "no_tx_dma_setup",
                                     CTLFLAG_RD,
                                     &txq->ift_no_tx_dma_setup, "# of times map failed for other than EFBIG");
                  SYSCTL_ADD_U16(ctx_list, queue_list, OID_AUTO, "txq_pidx",
                                     CTLFLAG_RD,
                                     &txq->ift_pidx, 1, "Producer Index");
                  SYSCTL_ADD_U16(ctx_list, queue_list, OID_AUTO, "txq_cidx",
                                     CTLFLAG_RD,
                                     &txq->ift_cidx, 1, "Consumer Index");
                  SYSCTL_ADD_U16(ctx_list, queue_list, OID_AUTO, "txq_cidx_processed",
                                     CTLFLAG_RD,
                                     &txq->ift_cidx_processed, 1, "Consumer Index seen by credit update");
                  SYSCTL_ADD_U16(ctx_list, queue_list, OID_AUTO, "txq_in_use",
                                     CTLFLAG_RD,
                                     &txq->ift_in_use, 1, "descriptors in use");
                  SYSCTL_ADD_QUAD(ctx_list, queue_list, OID_AUTO, "txq_processed",
                                     CTLFLAG_RD,
                                     &txq->ift_processed, "descriptors procesed for clean");
                  SYSCTL_ADD_QUAD(ctx_list, queue_list, OID_AUTO, "txq_cleaned",
                                     CTLFLAG_RD,
                                     &txq->ift_cleaned, "total cleaned");
                  SYSCTL_ADD_PROC(ctx_list, queue_list, OID_AUTO, "ring_state",
                      CTLTYPE_STRING | CTLFLAG_RD | CTLFLAG_NEEDGIANT,
                      __DEVOLATILE(uint64_t *, &txq->ift_br->state), 0,
                      mp_ring_state_handler, "A", "soft ring state");
                  SYSCTL_ADD_COUNTER_U64(ctx_list, queue_list, OID_AUTO, "r_enqueues",
                                         CTLFLAG_RD, &txq->ift_br->enqueues,
                                         "# of enqueues to the mp_ring for this queue");
                  SYSCTL_ADD_COUNTER_U64(ctx_list, queue_list, OID_AUTO, "r_drops",
                                         CTLFLAG_RD, &txq->ift_br->drops,
                                         "# of drops in the mp_ring for this queue");
                  SYSCTL_ADD_COUNTER_U64(ctx_list, queue_list, OID_AUTO, "r_starts",
                                         CTLFLAG_RD, &txq->ift_br->starts,
                                         "# of normal consumer starts in the mp_ring for this queue");
                  SYSCTL_ADD_COUNTER_U64(ctx_list, queue_list, OID_AUTO, "r_stalls",
                                         CTLFLAG_RD, &txq->ift_br->stalls,
                                                 "# of consumer stalls in the mp_ring for this queue");
                  SYSCTL_ADD_COUNTER_U64(ctx_list, queue_list, OID_AUTO, "r_restarts",
                                 CTLFLAG_RD, &txq->ift_br->restarts,
                                         "# of consumer restarts in the mp_ring for this queue");
                  SYSCTL_ADD_COUNTER_U64(ctx_list, queue_list, OID_AUTO, "r_abdications",
                                         CTLFLAG_RD, &txq->ift_br->abdications,
                                         "# of consumer abdications in the mp_ring for this queue");
          }
  
          if (scctx->isc_nrxqsets > 100)
                  qfmt = "rxq%03d";
          else if (scctx->isc_nrxqsets > 10)
                  qfmt = "rxq%02d";
          else
                  qfmt = "rxq%d";
          for (i = 0, rxq = ctx->ifc_rxqs; i < scctx->isc_nrxqsets; i++, rxq++) {
                  snprintf(namebuf, NAME_BUFLEN, qfmt, i);
                  queue_node = SYSCTL_ADD_NODE(ctx_list, child, OID_AUTO, namebuf,
                      CTLFLAG_RD | CTLFLAG_MPSAFE, NULL, "Queue Name");
                  queue_list = SYSCTL_CHILDREN(queue_node);
                  SYSCTL_ADD_INT(ctx_list, queue_list, OID_AUTO, "cpu",
                                 CTLFLAG_RD,
                                 &rxq->ifr_task.gt_cpu, 0, "cpu this queue is bound to");
                  if (sctx->isc_flags & IFLIB_HAS_RXCQ) {
                          SYSCTL_ADD_U16(ctx_list, queue_list, OID_AUTO, "rxq_cq_cidx",
                                         CTLFLAG_RD,
                                         &rxq->ifr_cq_cidx, 1, "Consumer Index");
                  }
  
                  for (j = 0, fl = rxq->ifr_fl; j < rxq->ifr_nfl; j++, fl++) {
                          snprintf(namebuf, NAME_BUFLEN, "rxq_fl%d", j);
                          fl_node = SYSCTL_ADD_NODE(ctx_list, queue_list, OID_AUTO, namebuf,
                              CTLFLAG_RD | CTLFLAG_MPSAFE, NULL, "freelist Name");
                          fl_list = SYSCTL_CHILDREN(fl_node);
                          SYSCTL_ADD_U16(ctx_list, fl_list, OID_AUTO, "pidx",
                                         CTLFLAG_RD,
                                         &fl->ifl_pidx, 1, "Producer Index");
                          SYSCTL_ADD_U16(ctx_list, fl_list, OID_AUTO, "cidx",
                                         CTLFLAG_RD,
                                         &fl->ifl_cidx, 1, "Consumer Index");
                          SYSCTL_ADD_U16(ctx_list, fl_list, OID_AUTO, "credits",
                                         CTLFLAG_RD,
                                         &fl->ifl_credits, 1, "credits available");
                          SYSCTL_ADD_U16(ctx_list, fl_list, OID_AUTO, "buf_size",
                                         CTLFLAG_RD,
                                         &fl->ifl_buf_size, 1, "buffer size");
  #if MEMORY_LOGGING
                          SYSCTL_ADD_QUAD(ctx_list, fl_list, OID_AUTO, "fl_m_enqueued",
                                          CTLFLAG_RD,
                                          &fl->ifl_m_enqueued, "mbufs allocated");
                          SYSCTL_ADD_QUAD(ctx_list, fl_list, OID_AUTO, "fl_m_dequeued",
                                          CTLFLAG_RD,
                                          &fl->ifl_m_dequeued, "mbufs freed");
                          SYSCTL_ADD_QUAD(ctx_list, fl_list, OID_AUTO, "fl_cl_enqueued",
                                          CTLFLAG_RD,
                                          &fl->ifl_cl_enqueued, "clusters allocated");
                          SYSCTL_ADD_QUAD(ctx_list, fl_list, OID_AUTO, "fl_cl_dequeued",
                                          CTLFLAG_RD,
                                          &fl->ifl_cl_dequeued, "clusters freed");
  #endif
                  }
          }
  
  }
  
  void
  iflib_request_reset(if_ctx_t ctx)
  {
  
          STATE_LOCK(ctx);
          ctx->ifc_flags |= IFC_DO_RESET;
          STATE_UNLOCK(ctx);
  }
  
  #ifndef __NO_STRICT_ALIGNMENT
  static struct mbuf *
  iflib_fixup_rx(struct mbuf *m)
  {
          struct mbuf *n;
  
          if (m->m_len <= (MCLBYTES - ETHER_HDR_LEN)) {
                  bcopy(m->m_data, m->m_data + ETHER_HDR_LEN, m->m_len);
                  m->m_data += ETHER_HDR_LEN;
                  n = m;
          } else {
                  MGETHDR(n, M_NOWAIT, MT_DATA);
                  if (n == NULL) {
                          m_freem(m);
                          return (NULL);
                  }
                  bcopy(m->m_data, n->m_data, ETHER_HDR_LEN);
                  m->m_data += ETHER_HDR_LEN;
                  m->m_len -= ETHER_HDR_LEN;
                  n->m_len = ETHER_HDR_LEN;
                  M_MOVE_PKTHDR(n, m);
                  n->m_next = m;
          }
          return (n);
  }
  #endif
  
  #ifdef DEBUGNET
  static void
  iflib_debugnet_init(if_t ifp, int *nrxr, int *ncl, int *clsize)
  {
          if_ctx_t ctx;
  
          ctx = if_getsoftc(ifp);
          CTX_LOCK(ctx);
          *nrxr = NRXQSETS(ctx);
          *ncl = ctx->ifc_rxqs[0].ifr_fl->ifl_size;
          *clsize = ctx->ifc_rxqs[0].ifr_fl->ifl_buf_size;
          CTX_UNLOCK(ctx);
  }
  
  static void
  iflib_debugnet_event(if_t ifp, enum debugnet_ev event)
  {
          if_ctx_t ctx;
          if_softc_ctx_t scctx;
          iflib_fl_t fl;
          iflib_rxq_t rxq;
          int i, j;
  
          ctx = if_getsoftc(ifp);
          scctx = &ctx->ifc_softc_ctx;
  
          switch (event) {
          case DEBUGNET_START:
                  for (i = 0; i < scctx->isc_nrxqsets; i++) {
                          rxq = &ctx->ifc_rxqs[i];
                          for (j = 0; j < rxq->ifr_nfl; j++) {
                                  fl = rxq->ifr_fl;
                                  fl->ifl_zone = m_getzone(fl->ifl_buf_size);
                          }
                  }
                  iflib_no_tx_batch = 1;
                  break;
          default:
                  break;
          }
  }
  
  static int
  iflib_debugnet_transmit(if_t ifp, struct mbuf *m)
  {
          if_ctx_t ctx;
          iflib_txq_t txq;
          int error;
  
          ctx = if_getsoftc(ifp);
          if ((if_getdrvflags(ifp) & (IFF_DRV_RUNNING | IFF_DRV_OACTIVE)) !=
              IFF_DRV_RUNNING)
                  return (EBUSY);
  
          txq = &ctx->ifc_txqs[0];
          error = iflib_encap(txq, &m);
          if (error == 0)
                  (void)iflib_txd_db_check(txq, true);
          return (error);
  }
  
  static int
  iflib_debugnet_poll(if_t ifp, int count)
  {
          struct epoch_tracker et;
          if_ctx_t ctx;
          if_softc_ctx_t scctx;
          iflib_txq_t txq;
          int i;
  
          ctx = if_getsoftc(ifp);
          scctx = &ctx->ifc_softc_ctx;
  
          if ((if_getdrvflags(ifp) & (IFF_DRV_RUNNING | IFF_DRV_OACTIVE)) !=
              IFF_DRV_RUNNING)
                  return (EBUSY);
  
          txq = &ctx->ifc_txqs[0];
          (void)iflib_completed_tx_reclaim(txq, RECLAIM_THRESH(ctx));
  
          NET_EPOCH_ENTER(et);
          for (i = 0; i < scctx->isc_nrxqsets; i++)
                  (void)iflib_rxeof(&ctx->ifc_rxqs[i], 16 /* XXX */);
          NET_EPOCH_EXIT(et);
          return (0);
  }
  #endif /* DEBUGNET */