[fs/lustre-release.git] / lnet / klnds / socklnd / socklnd.h

/* -*- mode: c; c-basic-offset: 8; indent-tabs-mode: nil; -*-
 * vim:expandtab:shiftwidth=8:tabstop=8:
 *
 * Copyright  2008 Sun Microsystems, Inc. All rights reserved
 *
 *   Author: Zach Brown <zab@zabbo.net>
 *   Author: Peter J. Braam <braam@clusterfs.com>
 *   Author: Phil Schwan <phil@clusterfs.com>
 *   Author: Eric Barton <eric@bartonsoftware.com>
 *
 *   This file is part of Lustre, http://www.lustre.org
 *
 *   Portals is free software; you can redistribute it and/or
 *   modify it under the terms of version 2 of the GNU General Public
 *   License as published by the Free Software Foundation.
 *
 *   Portals is distributed in the hope that it will be useful,
 *   but WITHOUT ANY WARRANTY; without even the implied warranty of
 *   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *   GNU General Public License for more details.
 *
 *   You should have received a copy of the GNU General Public License
 *   along with Portals; if not, write to the Free Software
 *   Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
 *
 */

#define DEBUG_PORTAL_ALLOC
#ifndef EXPORT_SYMTAB
# define EXPORT_SYMTAB
#endif

#define DEBUG_SUBSYSTEM S_LND

#if defined(__linux__)
#include "socklnd_lib-linux.h"
#elif defined(__APPLE__)
#include "socklnd_lib-darwin.h"
#elif defined(__WINNT__)
#include "socklnd_lib-winnt.h"
#else
#error Unsupported Operating System
#endif

#include <libcfs/libcfs.h>
#include <lnet/lnet.h>
#include <lnet/lib-lnet.h>
#include <lnet/socklnd.h>
#include <lnet/lnet-sysctl.h>

#define SOCKNAL_PEER_HASH_SIZE  101             /* # peer lists */
#define SOCKNAL_RESCHED         100             /* # scheduler loops before reschedule */
#define SOCKNAL_ENOMEM_RETRY    CFS_TICK        /* jiffies between retries */

#define SOCKNAL_SINGLE_FRAG_TX      0           /* disable multi-fragment sends */
#define SOCKNAL_SINGLE_FRAG_RX      0           /* disable multi-fragment receives */

#define SOCKNAL_VERSION_DEBUG       0           /* enable protocol version debugging */

/* risk kmap deadlock on multi-frag I/O (backs off to single-frag if disabled).
 * no risk if we're not running on a CONFIG_HIGHMEM platform. */
#ifdef CONFIG_HIGHMEM
# define SOCKNAL_RISK_KMAP_DEADLOCK  0
#else
# define SOCKNAL_RISK_KMAP_DEADLOCK  1
#endif

typedef struct                                  /* per scheduler state */
{
        cfs_spinlock_t    kss_lock;             /* serialise */
        cfs_list_t        kss_rx_conns;         /* conn waiting to be read */
        cfs_list_t        kss_tx_conns;         /* conn waiting to be written */
        cfs_list_t        kss_zombie_noop_txs;  /* zombie noop tx list */
        cfs_waitq_t       kss_waitq;            /* where scheduler sleeps */
        int               kss_nconns;           /* # connections assigned to this scheduler */
#if !SOCKNAL_SINGLE_FRAG_RX
        struct page      *kss_rx_scratch_pgs[LNET_MAX_IOV];
#endif
#if !SOCKNAL_SINGLE_FRAG_TX || !SOCKNAL_SINGLE_FRAG_RX
        struct iovec      kss_scratch_iov[LNET_MAX_IOV];
#endif
} ksock_sched_t;

typedef struct
{
        unsigned int      ksni_valid:1;         /* been set yet? */
        unsigned int      ksni_bound:1;         /* bound to a cpu yet? */
        unsigned int      ksni_sched:6;         /* which scheduler (assumes < 64) */
} ksock_irqinfo_t;

typedef struct                                  /* in-use interface */
{
        __u32             ksni_ipaddr;          /* interface's IP address */
        __u32             ksni_netmask;         /* interface's network mask */
        int               ksni_nroutes;         /* # routes using (active) */
        int               ksni_npeers;          /* # peers using (passive) */
        char              ksni_name[16];        /* interface name */
} ksock_interface_t;

typedef struct
{
        int              *ksnd_timeout;         /* "stuck" socket timeout (seconds) */
        int              *ksnd_nconnds;         /* # connection daemons */
        int              *ksnd_min_reconnectms; /* first connection retry after (ms)... */
        int              *ksnd_max_reconnectms; /* ...exponentially increasing to this */
        int              *ksnd_eager_ack;       /* make TCP ack eagerly? */
        int              *ksnd_typed_conns;     /* drive sockets by type? */
        int              *ksnd_min_bulk;        /* smallest "large" message */
        int              *ksnd_tx_buffer_size;  /* socket tx buffer size */
        int              *ksnd_rx_buffer_size;  /* socket rx buffer size */
        int              *ksnd_nagle;           /* enable NAGLE? */
        int              *ksnd_round_robin;     /* round robin for multiple interfaces */
        int              *ksnd_keepalive;       /* # secs for sending keepalive NOOP */
        int              *ksnd_keepalive_idle;  /* # idle secs before 1st probe */
        int              *ksnd_keepalive_count; /* # probes */
        int              *ksnd_keepalive_intvl; /* time between probes */
        int              *ksnd_credits;         /* # concurrent sends */
        int              *ksnd_peertxcredits;   /* # concurrent sends to 1 peer */
        int              *ksnd_peerrtrcredits;  /* # per-peer router buffer credits */
        int              *ksnd_peertimeout;     /* seconds to consider peer dead */
        int              *ksnd_enable_csum;     /* enable check sum */
        int              *ksnd_inject_csum_error; /* set non-zero to inject checksum error */
        unsigned int     *ksnd_zc_min_payload;  /* minimum zero copy payload size */
        int              *ksnd_zc_recv;         /* enable ZC receive (for Chelsio TOE) */
        int              *ksnd_zc_recv_min_nfrags; /* minimum # of fragments to enable ZC receive */
#ifdef CPU_AFFINITY
        int              *ksnd_irq_affinity;    /* enable IRQ affinity? */
#endif
#ifdef SOCKNAL_BACKOFF
        int              *ksnd_backoff_init;    /* initial TCP backoff */
        int              *ksnd_backoff_max;     /* maximum TCP backoff */
#endif
#if SOCKNAL_VERSION_DEBUG
        int              *ksnd_protocol;        /* protocol version */
#endif
#if defined(CONFIG_SYSCTL) && !CFS_SYSFS_MODULE_PARM
        cfs_sysctl_table_header_t *ksnd_sysctl;   /* sysctl interface */
#endif
} ksock_tunables_t;

typedef struct
{
        __u64             ksnn_incarnation;     /* my epoch */
        cfs_spinlock_t    ksnn_lock;            /* serialise */
        int               ksnn_npeers;          /* # peers */
        int               ksnn_shutdown;        /* shutting down? */
        int               ksnn_ninterfaces;     /* IP interfaces */
        ksock_interface_t ksnn_interfaces[LNET_MAX_INTERFACES];
} ksock_net_t;

typedef struct
{
        int               ksnd_init;           /* initialisation state */
        int               ksnd_nnets;          /* # networks set up */

        cfs_rwlock_t      ksnd_global_lock;    /* stabilize peer/conn ops */
        cfs_list_t       *ksnd_peers;          /* hash table of all my known peers */
        int               ksnd_peer_hash_size; /* size of ksnd_peers */

        int               ksnd_nthreads;       /* # live threads */
        int               ksnd_shuttingdown;   /* tell threads to exit */
        int               ksnd_nschedulers;    /* # schedulers */
        ksock_sched_t    *ksnd_schedulers;     /* their state */

        cfs_atomic_t      ksnd_nactive_txs;    /* #active txs */

        cfs_list_t        ksnd_deathrow_conns; /* conns to close: reaper_lock*/
        cfs_list_t        ksnd_zombie_conns;   /* conns to free: reaper_lock */
        cfs_list_t        ksnd_enomem_conns;   /* conns to retry: reaper_lock*/
        cfs_waitq_t       ksnd_reaper_waitq;   /* reaper sleeps here */
        cfs_time_t        ksnd_reaper_waketime;/* when reaper will wake */
        cfs_spinlock_t    ksnd_reaper_lock;    /* serialise */

        int               ksnd_enomem_tx;      /* test ENOMEM sender */
        int               ksnd_stall_tx;       /* test sluggish sender */
        int               ksnd_stall_rx;       /* test sluggish receiver */

        cfs_list_t        ksnd_connd_connreqs; /* incoming connection requests */
        cfs_list_t        ksnd_connd_routes;   /* routes waiting to be connected */
        cfs_waitq_t       ksnd_connd_waitq;    /* connds sleep here */
        int               ksnd_connd_connecting;/* # connds connecting */
        cfs_spinlock_t    ksnd_connd_lock;     /* serialise */

        cfs_list_t        ksnd_idle_noop_txs;  /* list head for freed noop tx */
        cfs_spinlock_t    ksnd_tx_lock;        /* serialise, NOT safe in g_lock */

        ksock_irqinfo_t   ksnd_irqinfo[CFS_NR_IRQS];/* irq->scheduler lookup */

} ksock_nal_data_t;

#define SOCKNAL_INIT_NOTHING    0
#define SOCKNAL_INIT_DATA       1
#define SOCKNAL_INIT_ALL        2

/* A packet just assembled for transmission is represented by 1 or more
 * struct iovec fragments (the first frag contains the portals header),
 * followed by 0 or more lnet_kiov_t fragments.
 *
 * On the receive side, initially 1 struct iovec fragment is posted for
 * receive (the header).  Once the header has been received, the payload is
 * received into either struct iovec or lnet_kiov_t fragments, depending on
 * what the header matched or whether the message needs forwarding. */

struct ksock_conn;                              /* forward ref */
struct ksock_peer;                              /* forward ref */
struct ksock_route;                             /* forward ref */
struct ksock_proto;                             /* forward ref */

typedef struct                                  /* transmit packet */
{
        cfs_list_t     tx_list;        /* queue on conn for transmission etc */
        cfs_list_t     tx_zc_list;     /* queue on peer for ZC request */
        cfs_atomic_t   tx_refcount;    /* tx reference count */
        int            tx_nob;         /* # packet bytes */
        int            tx_resid;       /* residual bytes */
        int            tx_niov;        /* # packet iovec frags */
        struct iovec  *tx_iov;         /* packet iovec frags */
        int            tx_nkiov;       /* # packet page frags */
        unsigned int   tx_zc_capable:1; /* payload is large enough for ZC */
        unsigned int   tx_zc_checked:1; /* Have I checked if I should ZC? */
        unsigned int   tx_nonblk:1;    /* it's a non-blocking ACK */
        lnet_kiov_t   *tx_kiov;        /* packet page frags */
        struct ksock_conn  *tx_conn;        /* owning conn */
        lnet_msg_t    *tx_lnetmsg;     /* lnet message for lnet_finalize() */
        cfs_time_t     tx_deadline;    /* when (in jiffies) tx times out */
        ksock_msg_t    tx_msg;         /* socklnd message buffer */
        int            tx_desc_size;   /* size of this descriptor */
        union {
                struct {
                        struct iovec iov;       /* virt hdr */
                        lnet_kiov_t  kiov[0];   /* paged payload */
                }                  paged;
                struct {
                        struct iovec iov[1];    /* virt hdr + payload */
                }                  virt;
        }                       tx_frags;
} ksock_tx_t;

#define KSOCK_NOOP_TX_SIZE  ((int)offsetof(ksock_tx_t, tx_frags.paged.kiov[0]))

/* network zero copy callback descriptor embedded in ksock_tx_t */

/* space for the rx frag descriptors; we either read a single contiguous
 * header, or up to LNET_MAX_IOV frags of payload of either type. */
typedef union {
        struct iovec     iov[LNET_MAX_IOV];
        lnet_kiov_t      kiov[LNET_MAX_IOV];
} ksock_rxiovspace_t;

#define SOCKNAL_RX_KSM_HEADER   1               /* reading ksock message header */
#define SOCKNAL_RX_LNET_HEADER  2               /* reading lnet message header */
#define SOCKNAL_RX_PARSE        3               /* Calling lnet_parse() */
#define SOCKNAL_RX_PARSE_WAIT   4               /* waiting to be told to read the body */
#define SOCKNAL_RX_LNET_PAYLOAD 5               /* reading lnet payload (to deliver here) */
#define SOCKNAL_RX_SLOP         6               /* skipping body */

typedef struct ksock_conn
{
        struct ksock_peer  *ksnc_peer;         /* owning peer */
        struct ksock_route *ksnc_route;        /* owning route */
        cfs_list_t          ksnc_list;         /* stash on peer's conn list */
        cfs_socket_t       *ksnc_sock;         /* actual socket */
        void               *ksnc_saved_data_ready; /* socket's original data_ready() callback */
        void               *ksnc_saved_write_space; /* socket's original write_space() callback */
        cfs_atomic_t        ksnc_conn_refcount; /* conn refcount */
        cfs_atomic_t        ksnc_sock_refcount; /* sock refcount */
        ksock_sched_t      *ksnc_scheduler;  /* who schedules this connection */
        __u32               ksnc_myipaddr;   /* my IP */
        __u32               ksnc_ipaddr;     /* peer's IP */
        int                 ksnc_port;       /* peer's port */
        int                 ksnc_type:3;     /* type of connection, should be signed value */
        int                 ksnc_closing:1;  /* being shut down */
        int                 ksnc_flip:1;     /* flip or not, only for V2.x */
        int                 ksnc_zc_capable:1; /* enable to ZC */
        struct ksock_proto *ksnc_proto;      /* protocol for the connection */

        /* reader */
        cfs_list_t  ksnc_rx_list;     /* where I enq waiting input or a forwarding descriptor */
        cfs_time_t            ksnc_rx_deadline; /* when (in jiffies) receive times out */
        __u8                  ksnc_rx_started;  /* started receiving a message */
        __u8                  ksnc_rx_ready;    /* data ready to read */
        __u8                  ksnc_rx_scheduled;/* being progressed */
        __u8                  ksnc_rx_state;    /* what is being read */
        int                   ksnc_rx_nob_left; /* # bytes to next hdr/body */
        int                   ksnc_rx_nob_wanted; /* bytes actually wanted */
        int                   ksnc_rx_niov;     /* # iovec frags */
        struct iovec         *ksnc_rx_iov;      /* the iovec frags */
        int                   ksnc_rx_nkiov;    /* # page frags */
        lnet_kiov_t          *ksnc_rx_kiov;     /* the page frags */
        ksock_rxiovspace_t    ksnc_rx_iov_space;/* space for frag descriptors */
        __u32                 ksnc_rx_csum;     /* partial checksum for incoming data */
        void                 *ksnc_cookie;      /* rx lnet_finalize passthru arg */
        ksock_msg_t           ksnc_msg;         /* incoming message buffer:
                                                 * V2.x message takes the
                                                 * whole struct
                                                 * V1.x message is a bare
                                                 * lnet_hdr_t, it's stored in
                                                 * ksnc_msg.ksm_u.lnetmsg */

        /* WRITER */
        cfs_list_t            ksnc_tx_list;     /* where I enq waiting for output space */
        cfs_list_t            ksnc_tx_queue;    /* packets waiting to be sent */
        ksock_tx_t           *ksnc_tx_carrier;  /* next TX that can carry a LNet message or ZC-ACK */
        cfs_time_t            ksnc_tx_deadline; /* when (in jiffies) tx times out */
        int                   ksnc_tx_bufnob;     /* send buffer marker */
        cfs_atomic_t          ksnc_tx_nob;        /* # bytes queued */
        int                   ksnc_tx_ready;      /* write space */
        int                   ksnc_tx_scheduled;  /* being progressed */
        cfs_time_t            ksnc_tx_last_post;  /* time stamp of the last posted TX */
} ksock_conn_t;

typedef struct ksock_route
{
        cfs_list_t            ksnr_list;        /* chain on peer route list */
        cfs_list_t            ksnr_connd_list;  /* chain on ksnr_connd_routes */
        struct ksock_peer    *ksnr_peer;        /* owning peer */
        cfs_atomic_t          ksnr_refcount;    /* # users */
        cfs_time_t            ksnr_timeout;     /* when (in jiffies) reconnection can happen next */
        cfs_duration_t        ksnr_retry_interval; /* how long between retries */
        __u32                 ksnr_myipaddr;    /* my IP */
        __u32                 ksnr_ipaddr;      /* IP address to connect to */
        int                   ksnr_port;        /* port to connect to */
        unsigned int          ksnr_scheduled:1; /* scheduled for attention */
        unsigned int          ksnr_connecting:1;/* connection establishment in progress */
        unsigned int          ksnr_connected:4; /* connections established by type */
        unsigned int          ksnr_deleted:1;   /* been removed from peer? */
        unsigned int          ksnr_share_count; /* created explicitly? */
        int                   ksnr_conn_count;  /* # conns established by this route */
} ksock_route_t;

#define SOCKNAL_KEEPALIVE_PING          1       /* cookie for keepalive ping */

typedef struct ksock_peer
{
        cfs_list_t            ksnp_list;        /* stash on global peer list */
        cfs_time_t            ksnp_last_alive;  /* when (in jiffies) I was last alive */
        lnet_process_id_t     ksnp_id;       /* who's on the other end(s) */
        cfs_atomic_t          ksnp_refcount; /* # users */
        int                   ksnp_sharecount;  /* lconf usage counter */
        int                   ksnp_closing;  /* being closed */
        int                   ksnp_accepting;/* # passive connections pending */
        int                   ksnp_error;    /* errno on closing last conn */
        __u64                 ksnp_zc_next_cookie;/* ZC completion cookie */
        __u64                 ksnp_incarnation;   /* latest known peer incarnation */
        struct ksock_proto   *ksnp_proto;    /* latest known peer protocol */
        cfs_list_t            ksnp_conns;    /* all active connections */
        cfs_list_t            ksnp_routes;   /* routes */
        cfs_list_t            ksnp_tx_queue; /* waiting packets */
        cfs_spinlock_t        ksnp_lock;     /* serialize, NOT safe in g_lock */
        cfs_list_t            ksnp_zc_req_list;   /* zero copy requests wait for ACK  */
        cfs_time_t            ksnp_send_keepalive; /* time to send keepalive */
        lnet_ni_t            *ksnp_ni;       /* which network */
        int                   ksnp_n_passive_ips; /* # of... */
        __u32                 ksnp_passive_ips[LNET_MAX_INTERFACES]; /* preferred local interfaces */
} ksock_peer_t;

typedef struct ksock_connreq
{
        cfs_list_t            ksncr_list;     /* stash on ksnd_connd_connreqs */
        lnet_ni_t            *ksncr_ni;       /* chosen NI */
        cfs_socket_t         *ksncr_sock;     /* accepted socket */
} ksock_connreq_t;

extern ksock_nal_data_t ksocknal_data;
extern ksock_tunables_t ksocknal_tunables;

#define SOCKNAL_MATCH_NO        0        /* TX can't match type of connection */
#define SOCKNAL_MATCH_YES       1        /* TX matches type of connection */
#define SOCKNAL_MATCH_MAY       2        /* TX can be sent on the connection, but not preferred */

typedef struct ksock_proto
{
        int           pro_version;                                              /* version number of protocol */
        int         (*pro_send_hello)(ksock_conn_t *, ksock_hello_msg_t *);     /* handshake function */
        int         (*pro_recv_hello)(ksock_conn_t *, ksock_hello_msg_t *, int);/* handshake function */
        void        (*pro_pack)(ksock_tx_t *);                                  /* message pack */
        void        (*pro_unpack)(ksock_msg_t *);                               /* message unpack */
        ksock_tx_t *(*pro_queue_tx_msg)(ksock_conn_t *, ksock_tx_t *);          /* queue tx on the connection */
        int         (*pro_queue_tx_zcack)(ksock_conn_t *, ksock_tx_t *, __u64); /* queue ZC ack on the connection */
        int         (*pro_handle_zcreq)(ksock_conn_t *, __u64, int);            /* handle ZC request */
        int         (*pro_handle_zcack)(ksock_conn_t *, __u64, __u64);          /* handle ZC ACK */
        int         (*pro_match_tx)(ksock_conn_t *, ksock_tx_t *, int);         /* msg type matches the connection type:
                                                                                 * return value:
                                                                                 *   return MATCH_NO  : no
                                                                                 *   return MATCH_YES : matching type
                                                                                 *   return MATCH_MAY : can be backup */
} ksock_proto_t;

extern ksock_proto_t ksocknal_protocol_v1x;
extern ksock_proto_t ksocknal_protocol_v2x;
extern ksock_proto_t ksocknal_protocol_v3x;

#define KSOCK_PROTO_V1_MAJOR    LNET_PROTO_TCP_VERSION_MAJOR
#define KSOCK_PROTO_V1_MINOR    LNET_PROTO_TCP_VERSION_MINOR
#define KSOCK_PROTO_V1          KSOCK_PROTO_V1_MAJOR

#ifndef CPU_MASK_NONE
#define CPU_MASK_NONE   0UL
#endif

static inline int
ksocknal_route_mask(void)
{
        if (!*ksocknal_tunables.ksnd_typed_conns)
                return (1 << SOCKLND_CONN_ANY);

        return ((1 << SOCKLND_CONN_CONTROL) |
                (1 << SOCKLND_CONN_BULK_IN) |
                (1 << SOCKLND_CONN_BULK_OUT));
}

static inline cfs_list_t *
ksocknal_nid2peerlist (lnet_nid_t nid)
{
        unsigned int hash = ((unsigned int)nid) % ksocknal_data.ksnd_peer_hash_size;

        return (&ksocknal_data.ksnd_peers [hash]);
}

static inline void
ksocknal_conn_addref (ksock_conn_t *conn)
{
        LASSERT (cfs_atomic_read(&conn->ksnc_conn_refcount) > 0);
        cfs_atomic_inc(&conn->ksnc_conn_refcount);
}

extern void ksocknal_queue_zombie_conn (ksock_conn_t *conn);
extern void ksocknal_finalize_zcreq(ksock_conn_t *conn);

static inline void
ksocknal_conn_decref (ksock_conn_t *conn)
{
        LASSERT (cfs_atomic_read(&conn->ksnc_conn_refcount) > 0);
        if (cfs_atomic_dec_and_test(&conn->ksnc_conn_refcount))
                ksocknal_queue_zombie_conn(conn);
}

static inline int
ksocknal_connsock_addref (ksock_conn_t *conn)
{
        int   rc = -ESHUTDOWN;

        cfs_read_lock (&ksocknal_data.ksnd_global_lock);
        if (!conn->ksnc_closing) {
                LASSERT (cfs_atomic_read(&conn->ksnc_sock_refcount) > 0);
                cfs_atomic_inc(&conn->ksnc_sock_refcount);
                rc = 0;
        }
        cfs_read_unlock (&ksocknal_data.ksnd_global_lock);

        return (rc);
}

static inline void
ksocknal_connsock_decref (ksock_conn_t *conn)
{
        LASSERT (cfs_atomic_read(&conn->ksnc_sock_refcount) > 0);
        if (cfs_atomic_dec_and_test(&conn->ksnc_sock_refcount)) {
                LASSERT (conn->ksnc_closing);
                libcfs_sock_release(conn->ksnc_sock);
                conn->ksnc_sock = NULL;
                ksocknal_finalize_zcreq(conn);
        }
}

static inline void
ksocknal_tx_addref (ksock_tx_t *tx)
{
        LASSERT (cfs_atomic_read(&tx->tx_refcount) > 0);
        cfs_atomic_inc(&tx->tx_refcount);
}

extern void ksocknal_tx_prep (ksock_conn_t *, ksock_tx_t *tx);
extern void ksocknal_tx_done (lnet_ni_t *ni, ksock_tx_t *tx);

static inline void
ksocknal_tx_decref (ksock_tx_t *tx)
{
        LASSERT (cfs_atomic_read(&tx->tx_refcount) > 0);
        if (cfs_atomic_dec_and_test(&tx->tx_refcount))
                ksocknal_tx_done(NULL, tx);
}

static inline void
ksocknal_route_addref (ksock_route_t *route)
{
        LASSERT (cfs_atomic_read(&route->ksnr_refcount) > 0);
        cfs_atomic_inc(&route->ksnr_refcount);
}

extern void ksocknal_destroy_route (ksock_route_t *route);

static inline void
ksocknal_route_decref (ksock_route_t *route)
{
        LASSERT (cfs_atomic_read (&route->ksnr_refcount) > 0);
        if (cfs_atomic_dec_and_test(&route->ksnr_refcount))
                ksocknal_destroy_route (route);
}

static inline void
ksocknal_peer_addref (ksock_peer_t *peer)
{
        LASSERT (cfs_atomic_read (&peer->ksnp_refcount) > 0);
        cfs_atomic_inc(&peer->ksnp_refcount);
}

extern void ksocknal_destroy_peer (ksock_peer_t *peer);

static inline void
ksocknal_peer_decref (ksock_peer_t *peer)
{
        LASSERT (cfs_atomic_read (&peer->ksnp_refcount) > 0);
        if (cfs_atomic_dec_and_test(&peer->ksnp_refcount))
                ksocknal_destroy_peer (peer);
}

int ksocknal_startup (lnet_ni_t *ni);
void ksocknal_shutdown (lnet_ni_t *ni);
int ksocknal_ctl(lnet_ni_t *ni, unsigned int cmd, void *arg);
int ksocknal_send (lnet_ni_t *ni, void *private, lnet_msg_t *lntmsg);
int ksocknal_recv(lnet_ni_t *ni, void *private, lnet_msg_t *lntmsg, 
                  int delayed, unsigned int niov, 
                  struct iovec *iov, lnet_kiov_t *kiov,
                  unsigned int offset, unsigned int mlen, unsigned int rlen);
int ksocknal_accept(lnet_ni_t *ni, cfs_socket_t *sock);

extern int ksocknal_add_peer(lnet_ni_t *ni, lnet_process_id_t id, __u32 ip, int port);
extern ksock_peer_t *ksocknal_find_peer_locked (lnet_ni_t *ni, lnet_process_id_t id);
extern ksock_peer_t *ksocknal_find_peer (lnet_ni_t *ni, lnet_process_id_t id);
extern void ksocknal_peer_failed (ksock_peer_t *peer);
extern int ksocknal_create_conn (lnet_ni_t *ni, ksock_route_t *route,
                                 cfs_socket_t *sock, int type);
extern void ksocknal_close_conn_locked (ksock_conn_t *conn, int why);
extern void ksocknal_terminate_conn (ksock_conn_t *conn);
extern void ksocknal_destroy_conn (ksock_conn_t *conn);
extern int  ksocknal_close_peer_conns_locked (ksock_peer_t *peer,
                                              __u32 ipaddr, int why);
extern int ksocknal_close_conn_and_siblings (ksock_conn_t *conn, int why);
extern int ksocknal_close_matching_conns (lnet_process_id_t id, __u32 ipaddr);
extern ksock_conn_t *ksocknal_find_conn_locked(ksock_peer_t *peer,
                                               ksock_tx_t *tx, int nonblk);

extern int  ksocknal_launch_packet(lnet_ni_t *ni, ksock_tx_t *tx,
                                   lnet_process_id_t id);
extern ksock_tx_t *ksocknal_alloc_tx(int type, int size);
extern void ksocknal_free_tx (ksock_tx_t *tx);
extern ksock_tx_t *ksocknal_alloc_tx_noop(__u64 cookie, int nonblk);
extern void ksocknal_next_tx_carrier(ksock_conn_t *conn);
extern void ksocknal_queue_tx_locked (ksock_tx_t *tx, ksock_conn_t *conn);
extern void ksocknal_txlist_done (lnet_ni_t *ni, cfs_list_t *txlist,
                                  int error);
extern void ksocknal_notify (lnet_ni_t *ni, lnet_nid_t gw_nid, int alive);
extern void ksocknal_query (struct lnet_ni *ni, lnet_nid_t nid, cfs_time_t *when);
extern int ksocknal_thread_start (int (*fn)(void *arg), void *arg);
extern void ksocknal_thread_fini (void);
extern void ksocknal_launch_all_connections_locked (ksock_peer_t *peer);
extern ksock_route_t *ksocknal_find_connectable_route_locked (ksock_peer_t *peer);
extern ksock_route_t *ksocknal_find_connecting_route_locked (ksock_peer_t *peer);
extern int ksocknal_new_packet (ksock_conn_t *conn, int skip);
extern int ksocknal_scheduler (void *arg);
extern int ksocknal_connd (void *arg);
extern int ksocknal_reaper (void *arg);
extern int ksocknal_send_hello (lnet_ni_t *ni, ksock_conn_t *conn,
                                lnet_nid_t peer_nid, ksock_hello_msg_t *hello);
extern int ksocknal_recv_hello (lnet_ni_t *ni, ksock_conn_t *conn,
                                ksock_hello_msg_t *hello, lnet_process_id_t *id,
                                __u64 *incarnation);
extern void ksocknal_read_callback(ksock_conn_t *conn);
extern void ksocknal_write_callback(ksock_conn_t *conn);

extern int ksocknal_lib_zc_capable(ksock_conn_t *conn);
extern void ksocknal_lib_save_callback(cfs_socket_t *sock, ksock_conn_t *conn);
extern void ksocknal_lib_set_callback(cfs_socket_t *sock,  ksock_conn_t *conn);
extern void ksocknal_lib_reset_callback(cfs_socket_t *sock, ksock_conn_t *conn);
extern void ksocknal_lib_push_conn (ksock_conn_t *conn);
extern void ksocknal_lib_bind_irq (unsigned int irq);
extern int ksocknal_lib_get_conn_addrs (ksock_conn_t *conn);
extern unsigned int ksocknal_lib_sock_irq (cfs_socket_t *sock);
extern int ksocknal_lib_setup_sock (cfs_socket_t *so);
extern int ksocknal_lib_send_iov (ksock_conn_t *conn, ksock_tx_t *tx);
extern int ksocknal_lib_send_kiov (ksock_conn_t *conn, ksock_tx_t *tx);
extern void ksocknal_lib_eager_ack (ksock_conn_t *conn);
extern int ksocknal_lib_recv_iov (ksock_conn_t *conn);
extern int ksocknal_lib_recv_kiov (ksock_conn_t *conn);
extern int ksocknal_lib_get_conn_tunables (ksock_conn_t *conn, int *txmem, 
                                           int *rxmem, int *nagle);

extern int ksocknal_tunables_init(void);
extern void ksocknal_tunables_fini(void);
extern int ksocknal_lib_tunables_init(void);
extern void ksocknal_lib_tunables_fini(void);

extern void ksocknal_lib_csum_tx(ksock_tx_t *tx);

extern int ksocknal_lib_memory_pressure(ksock_conn_t *conn);
extern int ksocknal_lib_bind_thread_to_cpu(int id);