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freebsd-dev/sys/net/iflib.c
Gleb Smirnoff a6b55ee6be net: replace IFF_KNOWSEPOCH with IFF_NEEDSEPOCH 
Expect that drivers call into the network stack with the net epoch
entered. This has already been the fact since early 2020. The net
interrupts, that are marked with INTR_TYPE_NET, were entering epoch
since 511d1afb6b. For the taskqueues there is NET_TASK_INIT() and
all drivers that were known back in 2020 we marked with it in
6c3e93cb5a. However in e87c494015 we took conservative approach
and preferred to opt-in rather than opt-out for the epoch.

This change not only reverts e87c494015 but adds a safety belt to
avoid panicing with INVARIANTS if there is a missed driver. With
INVARIANTS we will run in_epoch() check, print a warning and enter
the net epoch.  A driver that prints can be quickly fixed with the
IFF_NEEDSEPOCH flag, but better be augmented to properly enter the
epoch itself.

Note on TCP LRO: it is a backdoor to enter the TCP stack bypassing
some layers of net stack, ignoring either old IFF_KNOWSEPOCH or the
new IFF_NEEDSEPOCH.  But the tcp_lro_flush_all() asserts the presence
of network epoch.  Indeed, all NIC drivers that support LRO already
provide the epoch, either with help of INTR_TYPE_NET or just running
NET_EPOCH_ENTER() in their code.

Reviewed by:		zlei, gallatin, erj
Differential Revision:	https://reviews.freebsd.org/D39510
2023-04-17 09:08:35 -07:00

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/*-
* 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;
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_mem_in(rxq->pfil, payload, len, ri->iri_ifp, &m);
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' points at new mbuf.
*/
unload = 0;
break;
case PFIL_PASS:
/*
* Filter said it was OK, so receive like
* normal
*/
m = fl->ifl_sds.ifsd_m[cidx];
fl->ifl_sds.ifsd_m[cidx] = NULL;
break;
default:
MPASS(0);
}
} else {
m = fl->ifl_sds.ifsd_m[cidx];
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(if_getvnet(lc->ifp));
#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(if_getvnet(ifp));
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 (if_altq_is_enabled(ifp))
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) && !if_altq_is_enabled(ifp))
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 (if_altq_is_enabled(ifp)) {
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;
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 */
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