HAMMER 60I/Many: Mirroring

[dragonfly.git] / sys / netbt / rfcomm_upper.c

/* $DragonFly: src/sys/netbt/rfcomm_upper.c,v 1.3 2008/06/20 20:52:29 aggelos Exp $ */
/* $OpenBSD: src/sys/netbt/rfcomm_upper.c,v 1.4 2008/02/24 21:34:48 uwe Exp $ */
/* $NetBSD: rfcomm_upper.c,v 1.10 2007/11/20 20:25:57 plunky Exp $ */

/*-
 * Copyright (c) 2006 Itronix Inc.
 * All rights reserved.
 *
 * Written by Iain Hibbert for Itronix Inc.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in the
 *    documentation and/or other materials provided with the distribution.
 * 3. The name of Itronix Inc. may not be used to endorse
 *    or promote products derived from this software without specific
 *    prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY ITRONIX INC. ``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 ITRONIX INC. 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/param.h>
#include <sys/kernel.h>
#include <sys/mbuf.h>
#include <sys/proc.h>
#include <sys/systm.h>
#include <sys/socketvar.h>

#include <netbt/bluetooth.h>
#include <netbt/hci.h>
#include <netbt/l2cap.h>
#include <netbt/rfcomm.h>

/****************************************************************************
 *
 *      RFCOMM DLC - Upper Protocol API
 *
 * Currently the only 'Port Emulation Entity' is the RFCOMM socket code
 * but it is should be possible to provide a pseudo-device for a direct
 * tty interface.
 */

/*
 * rfcomm_attach(handle, proto, upper)
 *
 * attach a new RFCOMM DLC to handle, populate with reasonable defaults
 */
int
rfcomm_attach(struct rfcomm_dlc **handle,
                const struct btproto *proto, void *upper)
{
        struct rfcomm_dlc *dlc;

        KKASSERT(handle != NULL);
        KKASSERT(proto != NULL);
        KKASSERT(upper != NULL);

        dlc = kmalloc(sizeof(*dlc), M_BLUETOOTH, M_NOWAIT | M_ZERO);
        if (dlc == NULL)
                return ENOMEM;

        dlc->rd_state = RFCOMM_DLC_CLOSED;
        dlc->rd_mtu = rfcomm_mtu_default;

        dlc->rd_proto = proto;
        dlc->rd_upper = upper;

        dlc->rd_laddr.bt_len = sizeof(struct sockaddr_bt);
        dlc->rd_laddr.bt_family = AF_BLUETOOTH;
        dlc->rd_laddr.bt_psm = L2CAP_PSM_RFCOMM;

        dlc->rd_raddr.bt_len = sizeof(struct sockaddr_bt);
        dlc->rd_raddr.bt_family = AF_BLUETOOTH;
        dlc->rd_raddr.bt_psm = L2CAP_PSM_RFCOMM;

        dlc->rd_lmodem = RFCOMM_MSC_RTC | RFCOMM_MSC_RTR | RFCOMM_MSC_DV;

        callout_init(&dlc->rd_timeout);

        *handle = dlc;
        return 0;
}

/*
 * rfcomm_bind(dlc, sockaddr)
 *
 * bind DLC to local address
 */
int
rfcomm_bind(struct rfcomm_dlc *dlc, struct sockaddr_bt *addr)
{

        memcpy(&dlc->rd_laddr, addr, sizeof(struct sockaddr_bt));
        return 0;
}

/*
 * rfcomm_sockaddr(dlc, sockaddr)
 *
 * return local address
 */
int
rfcomm_sockaddr(struct rfcomm_dlc *dlc, struct sockaddr_bt *addr)
{

        memcpy(addr, &dlc->rd_laddr, sizeof(struct sockaddr_bt));
        return 0;
}

/*
 * rfcomm_connect(dlc, sockaddr)
 *
 * Initiate connection of RFCOMM DLC to remote address.
 */
int
rfcomm_connect(struct rfcomm_dlc *dlc, struct sockaddr_bt *dest)
{
        struct rfcomm_session *rs;
        int err = 0;

        if (dlc->rd_state != RFCOMM_DLC_CLOSED)
                return EISCONN;

        memcpy(&dlc->rd_raddr, dest, sizeof(struct sockaddr_bt));

        if (dlc->rd_raddr.bt_channel < RFCOMM_CHANNEL_MIN
            || dlc->rd_raddr.bt_channel > RFCOMM_CHANNEL_MAX
            || bdaddr_any(&dlc->rd_raddr.bt_bdaddr))
                return EDESTADDRREQ;

        if (dlc->rd_raddr.bt_psm == L2CAP_PSM_ANY)
                dlc->rd_raddr.bt_psm = L2CAP_PSM_RFCOMM;
        else if (dlc->rd_raddr.bt_psm != L2CAP_PSM_RFCOMM
            && (dlc->rd_raddr.bt_psm < 0x1001
            || L2CAP_PSM_INVALID(dlc->rd_raddr.bt_psm)))
                return EINVAL;

        /*
         * We are allowed only one RFCOMM session between any 2 Bluetooth
         * devices, so see if there is a session already otherwise create
         * one and set it connecting.
         */
        rs = rfcomm_session_lookup(&dlc->rd_laddr, &dlc->rd_raddr);
        if (rs == NULL) {
                rs = rfcomm_session_alloc(&rfcomm_session_active,
                                                &dlc->rd_laddr);
                if (rs == NULL)
                        return ENOMEM;

                rs->rs_flags |= RFCOMM_SESSION_INITIATOR;
                rs->rs_state = RFCOMM_SESSION_WAIT_CONNECT;

                err = l2cap_connect(rs->rs_l2cap, &dlc->rd_raddr);
                if (err) {
                        rfcomm_session_free(rs);
                        return err;
                }

                /*
                 * This session will start up automatically when its
                 * L2CAP channel is connected.
                 */
        }

        /* construct DLC */
        dlc->rd_dlci = RFCOMM_MKDLCI(IS_INITIATOR(rs) ? 0:1, dest->bt_channel);
        if (rfcomm_dlc_lookup(rs, dlc->rd_dlci))
                return EBUSY;

        l2cap_sockaddr(rs->rs_l2cap, &dlc->rd_laddr);

        /*
         * attach the DLC to the session and start it off
         */
        dlc->rd_session = rs;
        dlc->rd_state = RFCOMM_DLC_WAIT_SESSION;
        LIST_INSERT_HEAD(&rs->rs_dlcs, dlc, rd_next);

        if (rs->rs_state == RFCOMM_SESSION_OPEN)
                err = rfcomm_dlc_connect(dlc);

        return err;
}

/*
 * rfcomm_peeraddr(dlc, sockaddr)
 *
 * return remote address
 */
int
rfcomm_peeraddr(struct rfcomm_dlc *dlc, struct sockaddr_bt *addr)
{

        memcpy(addr, &dlc->rd_raddr, sizeof(struct sockaddr_bt));
        return 0;
}

/*
 * rfcomm_disconnect(dlc, linger)
 *
 * disconnect RFCOMM DLC
 */
int
rfcomm_disconnect(struct rfcomm_dlc *dlc, int linger)
{
        struct rfcomm_session *rs = dlc->rd_session;
        int err = 0;

        KKASSERT(dlc != NULL);

        switch (dlc->rd_state) {
        case RFCOMM_DLC_CLOSED:
        case RFCOMM_DLC_LISTEN:
                return EINVAL;

        case RFCOMM_DLC_WAIT_SEND_UA:
                err = rfcomm_session_send_frame(rs,
                                RFCOMM_FRAME_DM, dlc->rd_dlci);

                /* fall through */
        case RFCOMM_DLC_WAIT_SESSION:
        case RFCOMM_DLC_WAIT_CONNECT:
        case RFCOMM_DLC_WAIT_SEND_SABM:
                rfcomm_dlc_close(dlc, 0);
                break;

        case RFCOMM_DLC_OPEN:
                if (dlc->rd_txbuf != NULL && linger != 0) {
                        dlc->rd_flags |= RFCOMM_DLC_SHUTDOWN;
                        break;
                }

                /* else fall through */
        case RFCOMM_DLC_WAIT_RECV_UA:
                dlc->rd_state = RFCOMM_DLC_WAIT_DISCONNECT;
                err = rfcomm_session_send_frame(rs, RFCOMM_FRAME_DISC,
                                                        dlc->rd_dlci);
                callout_reset(&dlc->rd_timeout, rfcomm_ack_timeout * hz,
                    rfcomm_dlc_timeout, dlc);
                break;

        case RFCOMM_DLC_WAIT_DISCONNECT:
                err = EALREADY;
                break;

        default:
                UNKNOWN(dlc->rd_state);
                break;
        }

        return err;
}

/*
 * rfcomm_detach(handle)
 *
 * detach RFCOMM DLC from handle
 */
int
rfcomm_detach(struct rfcomm_dlc **handle)
{
        struct rfcomm_dlc *dlc = *handle;

        if (dlc->rd_state != RFCOMM_DLC_CLOSED)
                rfcomm_dlc_close(dlc, 0);

        if (dlc->rd_txbuf != NULL) {
                m_freem(dlc->rd_txbuf);
                dlc->rd_txbuf = NULL;
        }

        dlc->rd_upper = NULL;
        *handle = NULL;

        /*
         * If callout is invoking we can't free the DLC so
         * mark it and let the callout release it.
         */
        if (callout_active(&dlc->rd_timeout))
                dlc->rd_flags |= RFCOMM_DLC_DETACH;
        else
                kfree(dlc, M_BLUETOOTH);

        return 0;
}

/*
 * rfcomm_listen(dlc)
 *
 * This DLC is a listener. We look for an existing listening session
 * with a matching address to attach to or else create a new one on
 * the listeners list. If the ANY channel is given, allocate the first
 * available for the session.
 */
int
rfcomm_listen(struct rfcomm_dlc *dlc)
{
        struct rfcomm_session *rs;
        struct rfcomm_dlc *used;
        struct sockaddr_bt addr;
        int err, channel;

        if (dlc->rd_state != RFCOMM_DLC_CLOSED)
                return EISCONN;

        if (dlc->rd_laddr.bt_channel != RFCOMM_CHANNEL_ANY
            && (dlc->rd_laddr.bt_channel < RFCOMM_CHANNEL_MIN
            || dlc->rd_laddr.bt_channel > RFCOMM_CHANNEL_MAX))
                return EADDRNOTAVAIL;

        if (dlc->rd_laddr.bt_psm == L2CAP_PSM_ANY)
                dlc->rd_laddr.bt_psm = L2CAP_PSM_RFCOMM;
        else if (dlc->rd_laddr.bt_psm != L2CAP_PSM_RFCOMM
            && (dlc->rd_laddr.bt_psm < 0x1001
            || L2CAP_PSM_INVALID(dlc->rd_laddr.bt_psm)))
                return EADDRNOTAVAIL;

        LIST_FOREACH(rs, &rfcomm_session_listen, rs_next) {
                l2cap_sockaddr(rs->rs_l2cap, &addr);

                if (addr.bt_psm != dlc->rd_laddr.bt_psm)
                        continue;

                if (bdaddr_same(&dlc->rd_laddr.bt_bdaddr, &addr.bt_bdaddr))
                        break;
        }

        if (rs == NULL) {
                rs = rfcomm_session_alloc(&rfcomm_session_listen,
                                                &dlc->rd_laddr);
                if (rs == NULL)
                        return ENOMEM;

                rs->rs_state = RFCOMM_SESSION_LISTEN;

                err = l2cap_listen(rs->rs_l2cap);
                if (err) {
                        rfcomm_session_free(rs);
                        return err;
                }
        }

        if (dlc->rd_laddr.bt_channel == RFCOMM_CHANNEL_ANY) {
                channel = RFCOMM_CHANNEL_MIN;
                used = LIST_FIRST(&rs->rs_dlcs);

                while (used != NULL) {
                        if (used->rd_laddr.bt_channel == channel) {
                                if (channel++ == RFCOMM_CHANNEL_MAX)
                                        return EADDRNOTAVAIL;

                                used = LIST_FIRST(&rs->rs_dlcs);
                        } else {
                                used = LIST_NEXT(used, rd_next);
                        }
                }

                dlc->rd_laddr.bt_channel = channel;
        }

        dlc->rd_session = rs;
        dlc->rd_state = RFCOMM_DLC_LISTEN;
        LIST_INSERT_HEAD(&rs->rs_dlcs, dlc, rd_next);

        return 0;
}

/*
 * rfcomm_send(dlc, mbuf)
 *
 * Output data on DLC. This is streamed data, so we add it
 * to our buffer and start the DLC, which will assemble
 * packets and send them if it can.
 */
int
rfcomm_send(struct rfcomm_dlc *dlc, struct mbuf *m)
{

        if (dlc->rd_txbuf != NULL) {
                dlc->rd_txbuf->m_pkthdr.len += m->m_pkthdr.len;
                m_cat(dlc->rd_txbuf, m);
        } else {
                dlc->rd_txbuf = m;
        }

        if (dlc->rd_state == RFCOMM_DLC_OPEN)
                rfcomm_dlc_start(dlc);

        return 0;
}

/*
 * rfcomm_rcvd(dlc, space)
 *
 * Indicate space now available in receive buffer
 *
 * This should be used to give an initial value of the receive buffer
 * size when the DLC is attached and anytime data is cleared from the
 * buffer after that.
 */
int
rfcomm_rcvd(struct rfcomm_dlc *dlc, size_t space)
{

        KKASSERT(dlc != NULL);

        dlc->rd_rxsize = space;

        /*
         * if we are using credit based flow control, we may
         * want to send some credits..
         */
        if (dlc->rd_state == RFCOMM_DLC_OPEN
            && (dlc->rd_session->rs_flags & RFCOMM_SESSION_CFC))
                rfcomm_dlc_start(dlc);

        return 0;
}

/*
 * rfcomm_setopt(dlc, option, addr)
 *
 * set DLC options
 */
int
rfcomm_setopt(struct rfcomm_dlc *dlc, int opt, void *addr)
{
        int mode, err = 0;
        uint16_t mtu;

        switch (opt) {
        case SO_RFCOMM_MTU:
                mtu = *(uint16_t *)addr;
                if (mtu < RFCOMM_MTU_MIN || mtu > RFCOMM_MTU_MAX)
                        err = EINVAL;
                else if (dlc->rd_state == RFCOMM_DLC_CLOSED)
                        dlc->rd_mtu = mtu;
                else
                        err = EBUSY;

                break;

        case SO_RFCOMM_LM:
                mode = *(int *)addr;
                mode &= (RFCOMM_LM_SECURE | RFCOMM_LM_ENCRYPT | RFCOMM_LM_AUTH);

                if (mode & RFCOMM_LM_SECURE)
                        mode |= RFCOMM_LM_ENCRYPT;

                if (mode & RFCOMM_LM_ENCRYPT)
                        mode |= RFCOMM_LM_AUTH;

                dlc->rd_mode = mode;

                if (dlc->rd_state == RFCOMM_DLC_OPEN)
                        err = rfcomm_dlc_setmode(dlc);

                break;

        default:
                err = ENOPROTOOPT;
                break;
        }
        return err;
}


int
rfcomm_setopt2(struct rfcomm_dlc *dlc, int opt, struct socket *so,
    struct sockopt *sopt)
{
        int mode, err = 0;
        uint16_t mtu;

        switch (opt) {
        case SO_RFCOMM_MTU:
                err = soopt_to_kbuf(sopt, &mtu, sizeof(uint16_t),
                    sizeof(uint16_t)); 
                if (err) break;

                if (mtu < RFCOMM_MTU_MIN || mtu > RFCOMM_MTU_MAX)
                        err = EINVAL;
                else if (dlc->rd_state == RFCOMM_DLC_CLOSED)
                        dlc->rd_mtu = mtu;
                else
                        err = EBUSY;

                break;

        case SO_RFCOMM_LM:
                err = soopt_to_kbuf(sopt, &mode, sizeof(int), sizeof(int)); 
                if (err) break;

                mode &= (RFCOMM_LM_SECURE | RFCOMM_LM_ENCRYPT | RFCOMM_LM_AUTH);

                if (mode & RFCOMM_LM_SECURE)
                        mode |= RFCOMM_LM_ENCRYPT;

                if (mode & RFCOMM_LM_ENCRYPT)
                        mode |= RFCOMM_LM_AUTH;

                dlc->rd_mode = mode;

                if (dlc->rd_state == RFCOMM_DLC_OPEN)
                        err = rfcomm_dlc_setmode(dlc);

                break;

        default:
                err = ENOPROTOOPT;
                break;
        }
        return err;
}

/*
 * rfcomm_getopt(dlc, option, addr)
 *
 * get DLC options
 */
int
rfcomm_getopt(struct rfcomm_dlc *dlc, int opt, void *addr)
{
        struct rfcomm_fc_info *fc;

        switch (opt) {
        case SO_RFCOMM_MTU:
                *(uint16_t *)addr = dlc->rd_mtu;
                return sizeof(uint16_t);

        case SO_RFCOMM_FC_INFO:
                fc = addr;
                memset(fc, 0, sizeof(*fc));
                fc->lmodem = dlc->rd_lmodem;
                fc->rmodem = dlc->rd_rmodem;
                fc->tx_cred = max(dlc->rd_txcred, 0xff);
                fc->rx_cred = max(dlc->rd_rxcred, 0xff);
                if (dlc->rd_session
                    && (dlc->rd_session->rs_flags & RFCOMM_SESSION_CFC))
                        fc->cfc = 1;

                return sizeof(*fc);

        case SO_RFCOMM_LM:
                *(int *)addr = dlc->rd_mode;
                return sizeof(int);

        default:
                break;
        }

        return 0;
}