doxygen/socket_8c_source.html

/*

 *  OpenVPN -- An application to securely tunnel IP networks

 *             over a single TCP/UDP port, with support for SSL/TLS-based

 *             session authentication and key exchange,

 *             packet encryption, packet authentication, and

 *             packet compression.

 *

 *  Copyright (C) 2002-2024 OpenVPN Inc <sales@openvpn.net>

 *

 *  This program is free software; you can redistribute it and/or modify

 *  it under the terms of the GNU General Public License version 2

 *  as published by the Free Software Foundation.

 *

 *  This program 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 this program; if not, write to the Free Software Foundation, Inc.,

 *  51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.

 */


#ifdef HAVE_CONFIG_H

#include "config.h"

#endif


#include "syshead.h"


#include "socket.h"

#include "fdmisc.h"

#include "misc.h"

#include "gremlin.h"

#include "plugin.h"

#include "ps.h"

#include "run_command.h"

#include "manage.h"

#include "misc.h"

#include "manage.h"

#include "openvpn.h"

#include "forward.h"


#include "memdbg.h"


bool


sockets_read_residual(const struct context *c)

{

    int i;


    for (i = 0; i < c->c1.link_sockets_num; i++)

    {

        if (c->c2.link_sockets[i]->stream_buf.residual_fully_formed)

        {

            return true;

        }

    }

    return false;

}


/*

 * Convert sockflags/getaddr_flags into getaddr_flags

 */

static unsigned int


sf2gaf(const unsigned int getaddr_flags,

       const unsigned int sockflags)

{

    if (sockflags & SF_HOST_RANDOMIZE)

    {

        return getaddr_flags | GETADDR_RANDOMIZE;

    }

    else

    {

        return getaddr_flags;

    }

}


/*

 * Functions related to the translation of DNS names to IP addresses.

 */

static int


get_addr_generic(sa_family_t af, unsigned int flags, const char *hostname,

                 void *network, unsigned int *netbits,

                 int resolve_retry_seconds, struct signal_info *sig_info,

                 int msglevel)

{

    char *endp, *sep, *var_host = NULL;

    struct addrinfo *ai = NULL;

    unsigned long bits;

    uint8_t max_bits;

    int ret = -1;


    if (!hostname)

    {

        msg(M_NONFATAL, "Can't resolve null hostname!");

        goto out;

    }


    /* assign family specific default values */

    switch (af)

    {

        case AF_INET:

            bits = 0;

            max_bits = sizeof(in_addr_t) * 8;

            break;


        case AF_INET6:

            bits = 64;

            max_bits = sizeof(struct in6_addr) * 8;

            break;


        default:

            msg(M_WARN,

                "Unsupported AF family passed to getaddrinfo for %s (%d)",

                hostname, af);

            goto out;

    }


    /* we need to modify the hostname received as input, but we don't want to

     * touch it directly as it might be a constant string.

     *

     * Therefore, we clone the string here and free it at the end of the

     * function */

    var_host = strdup(hostname);

    if (!var_host)

    {

        msg(M_NONFATAL | M_ERRNO,

            "Can't allocate hostname buffer for getaddrinfo");

        goto out;

    }


    /* check if this hostname has a /bits suffix */

    sep = strchr(var_host, '/');

    if (sep)

    {

        bits = strtoul(sep + 1, &endp, 10);

        if ((*endp != '\0') || (bits > max_bits))

        {

            msg(msglevel, "IP prefix '%s': invalid '/bits' spec (%s)", hostname,

                sep + 1);

            goto out;

        }

        *sep = '\0';

    }


    ret = openvpn_getaddrinfo(flags & ~GETADDR_HOST_ORDER, var_host, NULL,

                              resolve_retry_seconds, sig_info, af, &ai);

    if ((ret == 0) && network)

    {

        struct in6_addr *ip6;

        in_addr_t *ip4;


        switch (af)

        {

            case AF_INET:

                ip4 = network;

                *ip4 = ((struct sockaddr_in *)ai->ai_addr)->sin_addr.s_addr;


                if (flags & GETADDR_HOST_ORDER)

                {

                    *ip4 = ntohl(*ip4);

                }

                break;


            case AF_INET6:

                ip6 = network;

                *ip6 = ((struct sockaddr_in6 *)ai->ai_addr)->sin6_addr;

                break;


            default:

                /* can't get here because 'af' was previously checked */

                msg(M_WARN,

                    "Unsupported AF family for %s (%d)", var_host, af);

                goto out;

        }

    }


    if (netbits)

    {

        *netbits = bits;

    }


    /* restore '/' separator, if any */

    if (sep)

    {

        *sep = '/';

    }

out:

    freeaddrinfo(ai);

    free(var_host);


    return ret;

}


in_addr_t


getaddr(unsigned int flags,

        const char *hostname,

        int resolve_retry_seconds,

        bool *succeeded,

        struct signal_info *sig_info)

{

    in_addr_t addr;

    int status;


    status = get_addr_generic(AF_INET, flags, hostname, &addr, NULL,

                              resolve_retry_seconds, sig_info,

                              M_WARN);

    if (status==0)

    {

        if (succeeded)

        {

            *succeeded = true;

        }

        return addr;

    }

    else

    {

        if (succeeded)

        {

            *succeeded = false;

        }

        return 0;

    }

}


bool


get_ipv6_addr(const char *hostname, struct in6_addr *network,

              unsigned int *netbits, int msglevel)

{

    if (get_addr_generic(AF_INET6, GETADDR_RESOLVE, hostname, network, netbits,

                         0, NULL, msglevel) < 0)

    {

        return false;

    }


    return true;                /* parsing OK, values set */

}


static inline bool


streqnull(const char *a, const char *b)

{

    if (a == NULL && b == NULL)

    {

        return true;

    }

    else if (a == NULL || b == NULL)

    {

        return false;

    }

    else

    {

        return streq(a, b);

    }

}


/*

 * get_cached_dns_entry return 0 on success and -1

 * otherwise. (like getaddrinfo)

 */

static int


get_cached_dns_entry(struct cached_dns_entry *dns_cache,

                     const char *hostname,

                     const char *servname,

                     int ai_family,

                     int resolve_flags,

                     struct addrinfo **ai)

{

    struct cached_dns_entry *ph;

    int flags;


    /* Only use flags that are relevant for the structure */

    flags = resolve_flags & GETADDR_CACHE_MASK;


    for (ph = dns_cache; ph; ph = ph->next)

    {

        if (streqnull(ph->hostname, hostname)

            && streqnull(ph->servname, servname)

            && ph->ai_family == ai_family

            && ph->flags == flags)

        {

            *ai = ph->ai;

            return 0;

        }

    }

    return -1;

}


static int


do_preresolve_host(struct context *c,

                   const char *hostname,

                   const char *servname,

                   const int af,

                   const int flags)

{

    struct addrinfo *ai;

    int status;


    if (get_cached_dns_entry(c->c1.dns_cache,

                             hostname,

                             servname,

                             af,

                             flags,

                             &ai) == 0)

    {

        /* entry already cached, return success */

        return 0;

    }


    status = openvpn_getaddrinfo(flags, hostname, servname,

                                 c->options.resolve_retry_seconds, NULL,

                                 af, &ai);

    if (status == 0)

    {

        struct cached_dns_entry *ph;


        ALLOC_OBJ_CLEAR_GC(ph, struct cached_dns_entry, &c->gc);

        ph->ai = ai;

        ph->hostname = hostname;

        ph->servname = servname;

        ph->flags = flags & GETADDR_CACHE_MASK;


        if (!c->c1.dns_cache)

        {

            c->c1.dns_cache = ph;

        }

        else

        {

            struct cached_dns_entry *prev = c->c1.dns_cache;

            while (prev->next)

            {

                prev = prev->next;

            }

            prev->next = ph;

        }


        gc_addspecial(ai, &gc_freeaddrinfo_callback, &c->gc);


    }

    return status;

}


void


do_preresolve(struct context *c)

{

    struct connection_list *l = c->options.connection_list;

    const unsigned int preresolve_flags = GETADDR_RESOLVE

                                          |GETADDR_UPDATE_MANAGEMENT_STATE

                                          |GETADDR_MENTION_RESOLVE_RETRY

                                          |GETADDR_FATAL;


    for (int i = 0; i < l->len; ++i)

    {

        int status;

        const char *remote;

        int flags = preresolve_flags;


        struct connection_entry *ce = l->array[i];


        if (proto_is_dgram(ce->proto))

        {

            flags |= GETADDR_DATAGRAM;

        }


        if (c->options.sockflags & SF_HOST_RANDOMIZE)

        {

            flags |= GETADDR_RANDOMIZE;

        }


        if (c->options.ip_remote_hint)

        {

            remote = c->options.ip_remote_hint;

        }

        else

        {

            remote = ce->remote;

        }


        /* HTTP remote hostname does not need to be resolved */

        if (!ce->http_proxy_options)

        {

            status = do_preresolve_host(c, remote, ce->remote_port,

                                        ce->af, flags);

            if (status != 0)

            {

                goto err;

            }

        }


        /* Preresolve proxy */

        if (ce->http_proxy_options)

        {

            status = do_preresolve_host(c,

                                        ce->http_proxy_options->server,

                                        ce->http_proxy_options->port,

                                        ce->af,

                                        preresolve_flags);


            if (status != 0)

            {

                goto err;

            }

        }


        if (ce->socks_proxy_server)

        {

            status = do_preresolve_host(c,

                                        ce->socks_proxy_server,

                                        ce->socks_proxy_port,

                                        ce->af,

                                        flags);

            if (status != 0)

            {

                goto err;

            }

        }


        if (ce->bind_local)

        {

            flags |= GETADDR_PASSIVE;

            flags &= ~GETADDR_RANDOMIZE;


            for (int j = 0; j < ce->local_list->len; j++)

            {

                struct local_entry *le = ce->local_list->array[j];


                if (!le->local)

                {

                    continue;

                }


                status = do_preresolve_host(c, le->local, le->port, ce->af, flags);

                if (status != 0)

                {

                    goto err;

                }


            }

        }


    }

    return;


err:

    throw_signal_soft(SIGHUP, "Preresolving failed");

}


static const char *


getaddrinfo_addr_family_name(int af)

{

    switch (af)

    {

        case AF_INET:  return "[AF_INET]";


        case AF_INET6: return "[AF_INET6]";

    }

    return "";

}


/*

 * Translate IPv4/IPv6 addr or hostname into struct addrinfo

 * If resolve error, try again for resolve_retry_seconds seconds.

 */

int


openvpn_getaddrinfo(unsigned int flags,

                    const char *hostname,

                    const char *servname,

                    int resolve_retry_seconds,

                    struct signal_info *sig_info,

                    int ai_family,

                    struct addrinfo **res)

{

    struct addrinfo hints;

    int status;

    struct signal_info sigrec = {0};

    int msglevel = (flags & GETADDR_FATAL) ? M_FATAL : D_RESOLVE_ERRORS;

    struct gc_arena gc = gc_new();

    const char *print_hostname;

    const char *print_servname;


    ASSERT(res);


    ASSERT(hostname || servname);

    ASSERT(!(flags & GETADDR_HOST_ORDER));


    if (servname)

    {

        print_servname = servname;

    }

    else

    {

        print_servname = "";

    }


    if (flags & GETADDR_MSG_VIRT_OUT)

    {

        msglevel |= M_MSG_VIRT_OUT;

    }


    if ((flags & (GETADDR_FATAL_ON_SIGNAL|GETADDR_WARN_ON_SIGNAL))

        && !sig_info)

    {

        sig_info = &sigrec;

    }


    /* try numeric ip addr first */

    CLEAR(hints);

    hints.ai_flags = AI_NUMERICHOST;


    if (flags & GETADDR_PASSIVE)

    {

        hints.ai_flags |= AI_PASSIVE;

    }


    if (flags & GETADDR_DATAGRAM)

    {

        hints.ai_socktype = SOCK_DGRAM;

    }

    else

    {

        hints.ai_socktype = SOCK_STREAM;

    }


    /* if hostname is not set, we want to bind to 'ANY', with

     * the correct address family - v4-only or v6/v6-dual-stack */

    if (!hostname)

    {

        hints.ai_family = ai_family;

    }


    status = getaddrinfo(hostname, servname, &hints, res);


    if (status != 0) /* parse as numeric address failed? */

    {

        const int fail_wait_interval = 5; /* seconds */

        /* Add +4 to cause integer division rounding up (1 + 4) = 5, (0+4)/5=0 */

        int resolve_retries = (flags & GETADDR_TRY_ONCE) ? 1 :

                              ((resolve_retry_seconds + 4)/ fail_wait_interval);

        const char *fmt;

        int level = 0;


        /* this is not a numeric IP, therefore force resolution using the

         * provided ai_family */

        hints.ai_family = ai_family;


        if (hostname && (flags & GETADDR_RANDOMIZE))

        {

            hostname = hostname_randomize(hostname, &gc);

        }


        if (hostname)

        {

            print_hostname = hostname;

        }

        else

        {

            print_hostname = "undefined";

        }


        fmt = "RESOLVE: Cannot resolve host address: %s:%s%s (%s)";

        if ((flags & GETADDR_MENTION_RESOLVE_RETRY)

            && !resolve_retry_seconds)

        {

            fmt = "RESOLVE: Cannot resolve host address: %s:%s%s (%s)"

                  "(I would have retried this name query if you had "

                  "specified the --resolv-retry option.)";

        }


        if (!(flags & GETADDR_RESOLVE) || status == EAI_FAIL)

        {

            msg(msglevel, "RESOLVE: Cannot parse IP address: %s:%s (%s)",

                print_hostname, print_servname, gai_strerror(status));

            goto done;

        }


#ifdef ENABLE_MANAGEMENT

        if (flags & GETADDR_UPDATE_MANAGEMENT_STATE)

        {

            if (management)

            {

                management_set_state(management,

                                     OPENVPN_STATE_RESOLVE,

                                     NULL,

                                     NULL,

                                     NULL,

                                     NULL,

                                     NULL);

            }

        }

#endif


        /*

         * Resolve hostname

         */

        while (true)

        {

#ifndef _WIN32

            /* force resolv.conf reload */

            res_init();

#endif

            /* try hostname lookup */

            hints.ai_flags &= ~AI_NUMERICHOST;

            dmsg(D_SOCKET_DEBUG,

                 "GETADDRINFO flags=0x%04x ai_family=%d ai_socktype=%d",

                 flags, hints.ai_family, hints.ai_socktype);

            status = getaddrinfo(hostname, servname, &hints, res);


            if (sig_info)

            {

                get_signal(&sig_info->signal_received);

                if (sig_info->signal_received) /* were we interrupted by a signal? */

                {

                    /* why are we overwriting SIGUSR1 ? */

                    if (signal_reset(sig_info, SIGUSR1) == SIGUSR1) /* ignore SIGUSR1 */

                    {

                        msg(level,

                            "RESOLVE: Ignored SIGUSR1 signal received during "

                            "DNS resolution attempt");

                    }

                    else

                    {

                        /* turn success into failure (interrupted syscall) */

                        if (0 == status)

                        {

                            ASSERT(res);

                            freeaddrinfo(*res);

                            *res = NULL;

                            status = EAI_AGAIN; /* = temporary failure */

                            errno = EINTR;

                        }

                        goto done;

                    }

                }

            }


            /* success? */

            if (0 == status)

            {

                break;

            }


            /* resolve lookup failed, should we

             * continue or fail? */

            level = msglevel;

            if (resolve_retries > 0)

            {

                level = D_RESOLVE_ERRORS;

            }


            msg(level,

                fmt,

                print_hostname,

                print_servname,

                getaddrinfo_addr_family_name(ai_family),

                gai_strerror(status));


            if (--resolve_retries <= 0)

            {

                goto done;

            }


            management_sleep(fail_wait_interval);

        }


        ASSERT(res);


        /* hostname resolve succeeded */


        /*

         * Do not choose an IP Addresse by random or change the order *

         * of IP addresses, doing so will break RFC 3484 address selection *

         */

    }

    else

    {

        /* IP address parse succeeded */

        if (flags & GETADDR_RANDOMIZE)

        {

            msg(M_WARN,

                "WARNING: ignoring --remote-random-hostname because the "

                "hostname is an IP address");

        }

    }


done:

    if (sig_info && sig_info->signal_received)

    {

        int level = 0;

        if (flags & GETADDR_FATAL_ON_SIGNAL)

        {

            level = M_FATAL;

        }

        else if (flags & GETADDR_WARN_ON_SIGNAL)

        {

            level = M_WARN;

        }

        msg(level, "RESOLVE: signal received during DNS resolution attempt");

    }


    gc_free(&gc);

    return status;

}


/*

 * We do our own inet_aton because the glibc function

 * isn't very good about error checking.

 */

int


openvpn_inet_aton(const char *dotted_quad, struct in_addr *addr)

{

    unsigned int a, b, c, d;


    CLEAR(*addr);

    if (sscanf(dotted_quad, "%u.%u.%u.%u", &a, &b, &c, &d) == 4)

    {

        if (a < 256 && b < 256 && c < 256 && d < 256)

        {

            addr->s_addr = htonl(a<<24 | b<<16 | c<<8 | d);

            return OIA_IP; /* good dotted quad */

        }

    }

    if (string_class(dotted_quad, CC_DIGIT|CC_DOT, 0))

    {

        return OIA_ERROR; /* probably a badly formatted dotted quad */

    }

    else

    {

        return OIA_HOSTNAME; /* probably a hostname */

    }

}


bool


ip_addr_dotted_quad_safe(const char *dotted_quad)

{

    /* verify non-NULL */

    if (!dotted_quad)

    {

        return false;

    }


    /* verify length is within limits */

    if (strlen(dotted_quad) > 15)

    {

        return false;

    }


    /* verify that all chars are either numeric or '.' and that no numeric

     * substring is greater than 3 chars */

    {

        int nnum = 0;

        const char *p = dotted_quad;

        int c;


        while ((c = *p++))

        {

            if (c >= '0' && c <= '9')

            {

                ++nnum;

                if (nnum > 3)

                {

                    return false;

                }

            }

            else if (c == '.')

            {

                nnum = 0;

            }

            else

            {

                return false;

            }

        }

    }


    /* verify that string will convert to IP address */

    {

        struct in_addr a;

        return openvpn_inet_aton(dotted_quad, &a) == OIA_IP;

    }

}


bool


ipv6_addr_safe(const char *ipv6_text_addr)

{

    /* verify non-NULL */

    if (!ipv6_text_addr)

    {

        return false;

    }


    /* verify length is within limits */

    if (strlen(ipv6_text_addr) > INET6_ADDRSTRLEN)

    {

        return false;

    }


    /* verify that string will convert to IPv6 address */

    {

        struct in6_addr a6;

        return inet_pton( AF_INET6, ipv6_text_addr, &a6 ) == 1;

    }

}


static bool


dns_addr_safe(const char *addr)

{

    if (addr)

    {

        const size_t len = strlen(addr);

        return len > 0 && len <= 255 && string_class(addr, CC_ALNUM|CC_DASH|CC_DOT, 0);

    }

    else

    {

        return false;

    }

}


bool


ip_or_dns_addr_safe(const char *addr, const bool allow_fqdn)

{

    if (ip_addr_dotted_quad_safe(addr))

    {

        return true;

    }

    else if (allow_fqdn)

    {

        return dns_addr_safe(addr);

    }

    else

    {

        return false;

    }

}


bool


mac_addr_safe(const char *mac_addr)

{

    /* verify non-NULL */

    if (!mac_addr)

    {

        return false;

    }


    /* verify length is within limits */

    if (strlen(mac_addr) > 17)

    {

        return false;

    }


    /* verify that all chars are either alphanumeric or ':' and that no

     * alphanumeric substring is greater than 2 chars */

    {

        int nnum = 0;

        const char *p = mac_addr;

        int c;


        while ((c = *p++))

        {

            if ( (c >= '0' && c <= '9') || (c >= 'a' && c <= 'f') || (c >= 'A' && c <= 'F') )

            {

                ++nnum;

                if (nnum > 2)

                {

                    return false;

                }

            }

            else if (c == ':')

            {

                nnum = 0;

            }

            else

            {

                return false;

            }

        }

    }


    /* error-checking is left to script invoked in lladdr.c */

    return true;

}


static int


socket_get_sndbuf(socket_descriptor_t sd)

{

#if defined(SOL_SOCKET) && defined(SO_SNDBUF)

    int val;

    socklen_t len;


    len = sizeof(val);

    if (getsockopt(sd, SOL_SOCKET, SO_SNDBUF, (void *) &val, &len) == 0

        && len == sizeof(val))

    {

        return val;

    }

#endif

    return 0;

}


static void


socket_set_sndbuf(socket_descriptor_t sd, int size)

{

#if defined(SOL_SOCKET) && defined(SO_SNDBUF)

    if (setsockopt(sd, SOL_SOCKET, SO_SNDBUF, (void *) &size, sizeof(size)) != 0)

    {

        msg(M_WARN, "NOTE: setsockopt SO_SNDBUF=%d failed", size);

    }

#endif

}


static int


socket_get_rcvbuf(socket_descriptor_t sd)

{

#if defined(SOL_SOCKET) && defined(SO_RCVBUF)

    int val;

    socklen_t len;


    len = sizeof(val);

    if (getsockopt(sd, SOL_SOCKET, SO_RCVBUF, (void *) &val, &len) == 0

        && len == sizeof(val))

    {

        return val;

    }

#endif

    return 0;

}


static bool


socket_set_rcvbuf(socket_descriptor_t sd, int size)

{

#if defined(SOL_SOCKET) && defined(SO_RCVBUF)

    if (setsockopt(sd, SOL_SOCKET, SO_RCVBUF, (void *) &size, sizeof(size)) != 0)

    {

        msg(M_WARN, "NOTE: setsockopt SO_RCVBUF=%d failed", size);

        return false;

    }

    return true;

#endif

}


void


socket_set_buffers(socket_descriptor_t fd, const struct socket_buffer_size *sbs,

                   bool reduce_size)

{

    if (sbs)

    {

        const int sndbuf_old = socket_get_sndbuf(fd);

        const int rcvbuf_old = socket_get_rcvbuf(fd);


        if (sbs->sndbuf

            && (reduce_size || sndbuf_old < sbs->sndbuf))

        {

            socket_set_sndbuf(fd, sbs->sndbuf);

        }


        if (sbs->rcvbuf

            && (reduce_size || rcvbuf_old < sbs->rcvbuf))

        {

            socket_set_rcvbuf(fd, sbs->rcvbuf);

        }


        msg(D_OSBUF, "Socket Buffers: R=[%d->%d] S=[%d->%d]",

            rcvbuf_old,

            socket_get_rcvbuf(fd),

            sndbuf_old,

            socket_get_sndbuf(fd));

    }

}


/*

 * Set other socket options

 */


static bool


socket_set_tcp_nodelay(socket_descriptor_t sd, int state)

{

#if defined(_WIN32) || (defined(IPPROTO_TCP) && defined(TCP_NODELAY))

    if (setsockopt(sd, IPPROTO_TCP, TCP_NODELAY, (void *) &state, sizeof(state)) != 0)

    {

        msg(M_WARN, "NOTE: setsockopt TCP_NODELAY=%d failed", state);

        return false;

    }

    else

    {

        dmsg(D_OSBUF, "Socket flags: TCP_NODELAY=%d succeeded", state);

        return true;

    }

#else  /* if defined(_WIN32) || (defined(IPPROTO_TCP) && defined(TCP_NODELAY)) */

    msg(M_WARN, "NOTE: setsockopt TCP_NODELAY=%d failed (No kernel support)", state);

    return false;

#endif

}


static inline void


socket_set_mark(socket_descriptor_t sd, int mark)

{

#if defined(TARGET_LINUX) && HAVE_DECL_SO_MARK

    if (mark && setsockopt(sd, SOL_SOCKET, SO_MARK, (void *) &mark, sizeof(mark)) != 0)

    {

        msg(M_WARN, "NOTE: setsockopt SO_MARK=%d failed", mark);

    }

#endif

}


static bool


socket_set_flags(socket_descriptor_t sd, unsigned int sockflags)

{

    /* SF_TCP_NODELAY doesn't make sense for dco-win */

    if ((sockflags & SF_TCP_NODELAY) && (!(sockflags & SF_DCO_WIN)))

    {

        return socket_set_tcp_nodelay(sd, 1);

    }

    else

    {

        return true;

    }

}


bool


link_socket_update_flags(struct link_socket *sock, unsigned int sockflags)

{

    if (sock && socket_defined(sock->sd))

    {

        sock->sockflags |= sockflags;

        return socket_set_flags(sock->sd, sock->sockflags);

    }

    else

    {

        return false;

    }

}


void


link_socket_update_buffer_sizes(struct link_socket *sock, int rcvbuf, int sndbuf)

{

    if (sock && socket_defined(sock->sd))

    {

        sock->socket_buffer_sizes.sndbuf = sndbuf;

        sock->socket_buffer_sizes.rcvbuf = rcvbuf;

        socket_set_buffers(sock->sd, &sock->socket_buffer_sizes, true);

    }

}


/*

 * SOCKET INITIALIZATION CODE.

 * Create a TCP/UDP socket

 */


socket_descriptor_t


create_socket_tcp(struct addrinfo *addrinfo)

{

    socket_descriptor_t sd;


    ASSERT(addrinfo);

    ASSERT(addrinfo->ai_socktype == SOCK_STREAM);


    if ((sd = socket(addrinfo->ai_family, addrinfo->ai_socktype, addrinfo->ai_protocol)) < 0)

    {

        msg(M_ERR, "Cannot create TCP socket");

    }


#ifndef _WIN32 /* using SO_REUSEADDR on Windows will cause bind to succeed on port conflicts! */

    /* set SO_REUSEADDR on socket */

    {

        int on = 1;

        if (setsockopt(sd, SOL_SOCKET, SO_REUSEADDR,

                       (void *) &on, sizeof(on)) < 0)

        {

            msg(M_ERR, "TCP: Cannot setsockopt SO_REUSEADDR on TCP socket");

        }

    }

#endif


    /* set socket file descriptor to not pass across execs, so that

     * scripts don't have access to it */

    set_cloexec(sd);


    return sd;

}


static socket_descriptor_t


create_socket_udp(struct addrinfo *addrinfo, const unsigned int flags)

{

    socket_descriptor_t sd;


    ASSERT(addrinfo);

    ASSERT(addrinfo->ai_socktype == SOCK_DGRAM);


    if ((sd = socket(addrinfo->ai_family, addrinfo->ai_socktype, addrinfo->ai_protocol)) < 0)

    {

        msg(M_ERR, "UDP: Cannot create UDP/UDP6 socket");

    }

#if ENABLE_IP_PKTINFO

    else if (flags & SF_USE_IP_PKTINFO)

    {

        int pad = 1;

        if (addrinfo->ai_family == AF_INET)

        {

#if defined(HAVE_IN_PKTINFO) && defined(HAVE_IPI_SPEC_DST)

            if (setsockopt(sd, SOL_IP, IP_PKTINFO,

                           (void *)&pad, sizeof(pad)) < 0)

            {

                msg(M_ERR, "UDP: failed setsockopt for IP_PKTINFO");

            }

#elif defined(IP_RECVDSTADDR)

            if (setsockopt(sd, IPPROTO_IP, IP_RECVDSTADDR,

                           (void *)&pad, sizeof(pad)) < 0)

            {

                msg(M_ERR, "UDP: failed setsockopt for IP_RECVDSTADDR");

            }

#else  /* if defined(HAVE_IN_PKTINFO) && defined(HAVE_IPI_SPEC_DST) */

#error ENABLE_IP_PKTINFO is set without IP_PKTINFO xor IP_RECVDSTADDR (fix syshead.h)

#endif

        }

        else if (addrinfo->ai_family == AF_INET6)

        {

#ifndef IPV6_RECVPKTINFO /* Some older Darwin platforms require this */

            if (setsockopt(sd, IPPROTO_IPV6, IPV6_PKTINFO,

                           (void *)&pad, sizeof(pad)) < 0)

#else

            if (setsockopt(sd, IPPROTO_IPV6, IPV6_RECVPKTINFO,

                           (void *)&pad, sizeof(pad)) < 0)

#endif

            { msg(M_ERR, "UDP: failed setsockopt for IPV6_RECVPKTINFO");}

        }

    }

#endif /* if ENABLE_IP_PKTINFO */


    /* set socket file descriptor to not pass across execs, so that

     * scripts don't have access to it */

    set_cloexec(sd);


    return sd;

}


static void


bind_local(struct link_socket *sock, const sa_family_t ai_family)

{

    /* bind to local address/port */

    if (sock->bind_local)

    {

        if (sock->socks_proxy && sock->info.proto == PROTO_UDP)

        {

            socket_bind(sock->ctrl_sd, sock->info.lsa->bind_local,

                        ai_family, "SOCKS", false);

        }

        else

        {

            socket_bind(sock->sd, sock->info.lsa->bind_local,

                        ai_family,

                        "TCP/UDP", sock->info.bind_ipv6_only);

        }

    }

}


static void


create_socket(struct link_socket *sock, struct addrinfo *addr)

{

    if (addr->ai_protocol == IPPROTO_UDP || addr->ai_socktype == SOCK_DGRAM)

    {

        sock->sd = create_socket_udp(addr, sock->sockflags);

        sock->sockflags |= SF_GETADDRINFO_DGRAM;


        /* Assume that control socket and data socket to the socks proxy

         * are using the same IP family */

        if (sock->socks_proxy)

        {

            /* Construct a temporary addrinfo to create the socket,

             * currently resolve two remote addresses is not supported,

             * TODO: Rewrite the whole resolve_remote */

            struct addrinfo addrinfo_tmp = *addr;

            addrinfo_tmp.ai_socktype = SOCK_STREAM;

            addrinfo_tmp.ai_protocol = IPPROTO_TCP;

            sock->ctrl_sd = create_socket_tcp(&addrinfo_tmp);

        }

    }

    else if (addr->ai_protocol == IPPROTO_TCP || addr->ai_socktype == SOCK_STREAM)

    {

        sock->sd = create_socket_tcp(addr);

    }

    else

    {

        ASSERT(0);

    }

    /* Set af field of sock->info, so it always reflects the address family

     * of the created socket */

    sock->info.af = addr->ai_family;


    /* set socket buffers based on --sndbuf and --rcvbuf options */

    socket_set_buffers(sock->sd, &sock->socket_buffer_sizes, true);


    /* set socket to --mark packets with given value */

    socket_set_mark(sock->sd, sock->mark);


#if defined(TARGET_LINUX)

    if (sock->bind_dev)

    {

        msg(M_INFO, "Using bind-dev %s", sock->bind_dev);

        if (setsockopt(sock->sd, SOL_SOCKET, SO_BINDTODEVICE, sock->bind_dev, strlen(sock->bind_dev) + 1) != 0)

        {

            msg(M_WARN|M_ERRNO, "WARN: setsockopt SO_BINDTODEVICE=%s failed", sock->bind_dev);

        }


    }

#endif


    bind_local(sock, addr->ai_family);

}


#ifdef TARGET_ANDROID

static void

protect_fd_nonlocal(int fd, const struct sockaddr *addr)

{

    if (!management)

    {

        msg(M_FATAL, "Required management interface not available.");

    }


    /* pass socket FD to management interface to pass on to VPNService API

     * as "protected socket" (exempt from being routed into tunnel)

     */

    if (addr_local(addr))

    {

        msg(D_SOCKET_DEBUG, "Address is local, not protecting socket fd %d", fd);

        return;

    }


    msg(D_SOCKET_DEBUG, "Protecting socket fd %d", fd);

    management->connection.fdtosend = fd;

    management_android_control(management, "PROTECTFD", __func__);

}

#endif


/*

 * Functions used for establishing a TCP stream connection.

 */

static void


socket_do_listen(socket_descriptor_t sd,

                 const struct addrinfo *local,

                 bool do_listen,

                 bool do_set_nonblock)

{

    struct gc_arena gc = gc_new();

    if (do_listen)

    {

        ASSERT(local);

        msg(M_INFO, "Listening for incoming TCP connection on %s",

            print_sockaddr(local->ai_addr, &gc));

        if (listen(sd, 32))

        {

            msg(M_ERR, "TCP: listen() failed");

        }

    }


    /* set socket to non-blocking mode */

    if (do_set_nonblock)

    {

        set_nonblock(sd);

    }


    gc_free(&gc);

}


socket_descriptor_t


socket_do_accept(socket_descriptor_t sd,

                 struct link_socket_actual *act,

                 const bool nowait)

{

    /* af_addr_size WILL return 0 in this case if AFs other than AF_INET

     * are compiled because act is empty here.

     * could use getsockname() to support later remote_len check

     */

    socklen_t remote_len_af = af_addr_size(act->dest.addr.sa.sa_family);

    socklen_t remote_len = sizeof(act->dest.addr);

    socket_descriptor_t new_sd = SOCKET_UNDEFINED;


    CLEAR(*act);


    if (nowait)

    {

        new_sd = getpeername(sd, &act->dest.addr.sa, &remote_len);


        if (!socket_defined(new_sd))

        {

            msg(D_LINK_ERRORS | M_ERRNO, "TCP: getpeername() failed");

        }

        else

        {

            new_sd = sd;

        }

    }

    else

    {

        new_sd = accept(sd, &act->dest.addr.sa, &remote_len);

    }


#if 0 /* For debugging only, test the effect of accept() failures */

    {

        static int foo = 0;

        ++foo;

        if (foo & 1)

        {

            new_sd = -1;

        }

    }

#endif


    if (!socket_defined(new_sd))

    {

        msg(D_LINK_ERRORS | M_ERRNO, "TCP: accept(%d) failed", (int)sd);

    }

    /* only valid if we have remote_len_af!=0 */

    else if (remote_len_af && remote_len != remote_len_af)

    {

        msg(D_LINK_ERRORS, "TCP: Received strange incoming connection with unknown address length=%d", remote_len);

        openvpn_close_socket(new_sd);

        new_sd = SOCKET_UNDEFINED;

    }

    else

    {

        /* set socket file descriptor to not pass across execs, so that

         * scripts don't have access to it */

        set_cloexec(sd);

    }

    return new_sd;

}


static void


tcp_connection_established(const struct link_socket_actual *act)

{

    struct gc_arena gc = gc_new();

    msg(M_INFO, "TCP connection established with %s",

        print_link_socket_actual(act, &gc));

    gc_free(&gc);

}


static socket_descriptor_t


socket_listen_accept(socket_descriptor_t sd,

                     struct link_socket_actual *act,

                     const char *remote_dynamic,

                     const struct addrinfo *local,

                     bool do_listen,

                     bool nowait,

                     volatile int *signal_received)

{

    struct gc_arena gc = gc_new();

    /* struct openvpn_sockaddr *remote = &act->dest; */

    struct openvpn_sockaddr remote_verify = act->dest;

    socket_descriptor_t new_sd = SOCKET_UNDEFINED;


    CLEAR(*act);

    socket_do_listen(sd, local, do_listen, true);


    while (true)

    {

        int status;

        fd_set reads;

        struct timeval tv;


        FD_ZERO(&reads);

        openvpn_fd_set(sd, &reads);

        tv.tv_sec = 0;

        tv.tv_usec = 0;


        status = select(sd + 1, &reads, NULL, NULL, &tv);


        get_signal(signal_received);

        if (*signal_received)

        {

            gc_free(&gc);

            return sd;

        }


        if (status < 0)

        {

            msg(D_LINK_ERRORS | M_ERRNO, "TCP: select() failed");

        }


        if (status <= 0)

        {

            management_sleep(1);

            continue;

        }


        new_sd = socket_do_accept(sd, act, nowait);


        if (socket_defined(new_sd))

        {

            struct addrinfo *ai = NULL;

            if (remote_dynamic)

            {

                openvpn_getaddrinfo(0, remote_dynamic, NULL, 1, NULL,

                                    remote_verify.addr.sa.sa_family, &ai);

            }


            if (ai && !addrlist_match(&remote_verify, ai))

            {

                msg(M_WARN,

                    "TCP NOTE: Rejected connection attempt from %s due to --remote setting",

                    print_link_socket_actual(act, &gc));

                if (openvpn_close_socket(new_sd))

                {

                    msg(M_ERR, "TCP: close socket failed (new_sd)");

                }

                freeaddrinfo(ai);

            }

            else

            {

                if (ai)

                {

                    freeaddrinfo(ai);

                }

                break;

            }

        }

        management_sleep(1);

    }


    if (!nowait && openvpn_close_socket(sd))

    {

        msg(M_ERR, "TCP: close socket failed (sd)");

    }


    tcp_connection_established(act);


    gc_free(&gc);

    return new_sd;

}


void


socket_bind(socket_descriptor_t sd,

            struct addrinfo *local,

            int ai_family,

            const char *prefix,

            bool ipv6only)

{

    struct gc_arena gc = gc_new();


    /* FIXME (schwabe)

     * getaddrinfo for the bind address might return multiple AF_INET/AF_INET6

     * entries for the requested protocol.

     * For example if an address has multiple A records

     * What is the correct way to deal with it?

     */


    struct addrinfo *cur;


    ASSERT(local);


    /* find the first addrinfo with correct ai_family */

    for (cur = local; cur; cur = cur->ai_next)

    {

        if (cur->ai_family == ai_family)

        {

            break;

        }

    }

    if (!cur)

    {

        msg(M_FATAL, "%s: Socket bind failed: Addr to bind has no %s record",

            prefix, addr_family_name(ai_family));

    }


    if (ai_family == AF_INET6)

    {

        int v6only = ipv6only ? 1 : 0;  /* setsockopt must have an "int" */


        msg(M_INFO, "setsockopt(IPV6_V6ONLY=%d)", v6only);

        if (setsockopt(sd, IPPROTO_IPV6, IPV6_V6ONLY, (void *) &v6only, sizeof(v6only)))

        {

            msg(M_NONFATAL|M_ERRNO, "Setting IPV6_V6ONLY=%d failed", v6only);

        }

    }

    if (bind(sd, cur->ai_addr, cur->ai_addrlen))

    {

        msg(M_FATAL | M_ERRNO, "%s: Socket bind failed on local address %s",

            prefix,

            print_sockaddr_ex(local->ai_addr, ":", PS_SHOW_PORT, &gc));

    }

    gc_free(&gc);

}


int


openvpn_connect(socket_descriptor_t sd,

                const struct sockaddr *remote,

                int connect_timeout,

                volatile int *signal_received)

{

    int status = 0;


#ifdef TARGET_ANDROID

    protect_fd_nonlocal(sd, remote);

#endif

    set_nonblock(sd);

    status = connect(sd, remote, af_addr_size(remote->sa_family));

    if (status)

    {

        status = openvpn_errno();

    }

    if (

#ifdef _WIN32

        status == WSAEWOULDBLOCK

#else

        status == EINPROGRESS

#endif

        )

    {

        while (true)

        {

#if POLL

            struct pollfd fds[1];

            fds[0].fd = sd;

            fds[0].events = POLLOUT;

            status = poll(fds, 1, (connect_timeout > 0) ? 1000 : 0);

#else

            fd_set writes;

            struct timeval tv;


            FD_ZERO(&writes);

            openvpn_fd_set(sd, &writes);

            tv.tv_sec = (connect_timeout > 0) ? 1 : 0;

            tv.tv_usec = 0;


            status = select(sd + 1, NULL, &writes, NULL, &tv);

#endif

            if (signal_received)

            {

                get_signal(signal_received);

                if (*signal_received)

                {

                    status = 0;

                    break;

                }

            }

            if (status < 0)

            {

                status = openvpn_errno();

                break;

            }

            if (status <= 0)

            {

                if (--connect_timeout < 0)

                {

#ifdef _WIN32

                    status = WSAETIMEDOUT;

#else

                    status = ETIMEDOUT;

#endif

                    break;

                }

                management_sleep(0);

                continue;

            }


            /* got it */

            {

                int val = 0;

                socklen_t len;


                len = sizeof(val);

                if (getsockopt(sd, SOL_SOCKET, SO_ERROR, (void *) &val, &len) == 0

                    && len == sizeof(val))

                {

                    status = val;

                }

                else

                {

                    status = openvpn_errno();

                }

                break;

            }

        }

    }


    return status;

}


void


set_actual_address(struct link_socket_actual *actual, struct addrinfo *ai)

{

    CLEAR(*actual);

    ASSERT(ai);


    if (ai->ai_family == AF_INET)

    {

        actual->dest.addr.in4 =

            *((struct sockaddr_in *) ai->ai_addr);

    }

    else if (ai->ai_family == AF_INET6)

    {

        actual->dest.addr.in6 =

            *((struct sockaddr_in6 *) ai->ai_addr);

    }

    else

    {

        ASSERT(0);

    }


}


static void


socket_connect(socket_descriptor_t *sd,

               const struct sockaddr *dest,

               const int connect_timeout,

               struct signal_info *sig_info)

{

    struct gc_arena gc = gc_new();

    int status;


    msg(M_INFO, "Attempting to establish TCP connection with %s",

        print_sockaddr(dest, &gc));


#ifdef ENABLE_MANAGEMENT

    if (management)

    {

        management_set_state(management,

                             OPENVPN_STATE_TCP_CONNECT,

                             NULL,

                             NULL,

                             NULL,

                             NULL,

                             NULL);

    }

#endif


    /* Set the actual address */

    status = openvpn_connect(*sd, dest, connect_timeout, &sig_info->signal_received);


    get_signal(&sig_info->signal_received);

    if (sig_info->signal_received)

    {

        goto done;

    }


    if (status)

    {


        msg(D_LINK_ERRORS, "TCP: connect to %s failed: %s",

            print_sockaddr(dest, &gc), strerror(status));


        openvpn_close_socket(*sd);

        *sd = SOCKET_UNDEFINED;

        register_signal(sig_info, SIGUSR1, "connection-failed");

    }

    else

    {

        msg(M_INFO, "TCP connection established with %s",

            print_sockaddr(dest, &gc));

    }


done:

    gc_free(&gc);

}


/*

 * Stream buffer handling prototypes -- stream_buf is a helper class

 * to assist in the packetization of stream transport protocols

 * such as TCP.

 */


static void

stream_buf_init(struct stream_buf *sb, struct buffer *buf,

                const unsigned int sockflags, const int proto);


static void

stream_buf_close(struct stream_buf *sb);


static bool

stream_buf_added(struct stream_buf *sb, int length_added);


/* For stream protocols, allocate a buffer to build up packet.

 * Called after frame has been finalized. */


static void


socket_frame_init(const struct frame *frame, struct link_socket *sock)

{

#ifdef _WIN32

    overlapped_io_init(&sock->reads, frame, FALSE);

    overlapped_io_init(&sock->writes, frame, TRUE);

    sock->rw_handle.read = sock->reads.overlapped.hEvent;

    sock->rw_handle.write = sock->writes.overlapped.hEvent;

#endif


    if (link_socket_connection_oriented(sock))

    {

#ifdef _WIN32

        stream_buf_init(&sock->stream_buf,

                        &sock->reads.buf_init,

                        sock->sockflags,

                        sock->info.proto);

#else

        alloc_buf_sock_tun(&sock->stream_buf_data, frame);


        stream_buf_init(&sock->stream_buf,

                        &sock->stream_buf_data,

                        sock->sockflags,

                        sock->info.proto);

#endif

    }

}


static void


resolve_bind_local(struct link_socket *sock, const sa_family_t af)

{

    struct gc_arena gc = gc_new();


    /* resolve local address if undefined */

    if (!sock->info.lsa->bind_local)

    {

        int flags = GETADDR_RESOLVE | GETADDR_WARN_ON_SIGNAL

                    |GETADDR_FATAL | GETADDR_PASSIVE;

        int status;


        if (proto_is_dgram(sock->info.proto))

        {

            flags |= GETADDR_DATAGRAM;

        }


        /* will return AF_{INET|INET6}from local_host */

        status = get_cached_dns_entry(sock->dns_cache,

                                      sock->local_host,

                                      sock->local_port,

                                      af,

                                      flags,

                                      &sock->info.lsa->bind_local);


        if (status)

        {

            status = openvpn_getaddrinfo(flags, sock->local_host, sock->local_port, 0,

                                         NULL, af, &sock->info.lsa->bind_local);

        }


        if (status !=0)

        {

            msg(M_FATAL, "getaddrinfo() failed for local \"%s:%s\": %s",

                sock->local_host, sock->local_port,

                gai_strerror(status));

        }


        /* the address family returned by openvpn_getaddrinfo() should be

         * taken into consideration only if we really passed an hostname

         * to resolve. Otherwise its value is not useful to us and may

         * actually break our socket, i.e. when it returns AF_INET

         * but our remote is v6 only.

         */

        if (sock->local_host)

        {

            /* the resolved 'local entry' might have a different family than

             * what was globally configured

             */

            sock->info.af = sock->info.lsa->bind_local->ai_family;

        }

    }


    gc_free(&gc);

}


static void


resolve_remote(struct link_socket *sock,

               int phase,

               const char **remote_dynamic,

               struct signal_info *sig_info)

{

    volatile int *signal_received = sig_info ? &sig_info->signal_received : NULL;

    struct gc_arena gc = gc_new();


    /* resolve remote address if undefined */

    if (!sock->info.lsa->remote_list)

    {

        if (sock->remote_host)

        {

            unsigned int flags = sf2gaf(GETADDR_RESOLVE|GETADDR_UPDATE_MANAGEMENT_STATE, sock->sockflags);

            int retry = 0;

            int status = -1;

            struct addrinfo *ai;

            if (proto_is_dgram(sock->info.proto))

            {

                flags |= GETADDR_DATAGRAM;

            }


            if (sock->resolve_retry_seconds == RESOLV_RETRY_INFINITE)

            {

                if (phase == 2)

                {

                    flags |= (GETADDR_TRY_ONCE | GETADDR_FATAL);

                }

                retry = 0;

            }

            else if (phase == 1)

            {

                if (sock->resolve_retry_seconds)

                {

                    retry = 0;

                }

                else

                {

                    flags |= (GETADDR_FATAL | GETADDR_MENTION_RESOLVE_RETRY);

                    retry = 0;

                }

            }

            else if (phase == 2)

            {

                if (sock->resolve_retry_seconds)

                {

                    flags |= GETADDR_FATAL;

                    retry = sock->resolve_retry_seconds;

                }

                else

                {

                    ASSERT(0);

                }

            }

            else

            {

                ASSERT(0);

            }


            status = get_cached_dns_entry(sock->dns_cache,

                                          sock->remote_host,

                                          sock->remote_port,

                                          sock->info.af,

                                          flags, &ai);

            if (status)

            {

                status = openvpn_getaddrinfo(flags, sock->remote_host, sock->remote_port,

                                             retry, sig_info, sock->info.af, &ai);

            }


            if (status == 0)

            {

                sock->info.lsa->remote_list = ai;

                sock->info.lsa->current_remote = ai;


                dmsg(D_SOCKET_DEBUG,

                     "RESOLVE_REMOTE flags=0x%04x phase=%d rrs=%d sig=%d status=%d",

                     flags,

                     phase,

                     retry,

                     signal_received ? *signal_received : -1,

                     status);

            }

            if (signal_received && *signal_received)

            {

                goto done;

            }

            if (status!=0)

            {

                if (signal_received)

                {

                    /* potential overwrite of signal */

                    register_signal(sig_info, SIGUSR1, "socks-resolve-failure");

                }

                goto done;

            }

        }

    }


    /* should we re-use previous active remote address? */

    if (link_socket_actual_defined(&sock->info.lsa->actual))

    {

        msg(M_INFO, "TCP/UDP: Preserving recently used remote address: %s",

            print_link_socket_actual(&sock->info.lsa->actual, &gc));

        if (remote_dynamic)

        {

            *remote_dynamic = NULL;

        }

    }

    else

    {

        CLEAR(sock->info.lsa->actual);

        if (sock->info.lsa->current_remote)

        {

            set_actual_address(&sock->info.lsa->actual,

                               sock->info.lsa->current_remote);

        }

    }


done:

    gc_free(&gc);

}


struct link_socket *


link_socket_new(void)

{

    struct link_socket *sock;


    ALLOC_OBJ_CLEAR(sock, struct link_socket);

    sock->sd = SOCKET_UNDEFINED;

    sock->ctrl_sd = SOCKET_UNDEFINED;

    sock->ev_arg.type = EVENT_ARG_LINK_SOCKET;

    sock->ev_arg.u.sock = sock;


    return sock;

}


void


link_socket_init_phase1(struct context *c, int sock_index, int mode)

{

    struct link_socket *sock = c->c2.link_sockets[sock_index];

    struct options *o = &c->options;

    ASSERT(sock);


    const char *host = o->ce.local_list->array[sock_index]->local;

    const char *port = o->ce.local_list->array[sock_index]->port;

    int proto = o->ce.local_list->array[sock_index]->proto;

    const char *remote_host = o->ce.remote;

    const char *remote_port = o->ce.remote_port;


    if (remote_host)

    {

        proto = o->ce.proto;

    }


    if (c->mode == CM_CHILD_TCP || c->mode == CM_CHILD_UDP)

    {

        struct link_socket *tmp_sock = NULL;

        if (c->mode == CM_CHILD_TCP)

        {

            tmp_sock = (struct link_socket *)c->c2.accept_from;

        }

        else if (c->mode == CM_CHILD_UDP)

        {

            tmp_sock = c->c2.link_sockets[0];

        }


        host = tmp_sock->local_host;

        port = tmp_sock->local_port;

        proto = tmp_sock->info.proto;

    }


    sock->local_host = host;

    sock->local_port = port;

    sock->remote_host = remote_host;

    sock->remote_port = remote_port;

    sock->dns_cache = c->c1.dns_cache;

    sock->http_proxy = c->c1.http_proxy;

    sock->socks_proxy = c->c1.socks_proxy;

    sock->bind_local = o->ce.bind_local;

    sock->resolve_retry_seconds = o->resolve_retry_seconds;

    sock->mtu_discover_type = o->ce.mtu_discover_type;


#ifdef ENABLE_DEBUG

    sock->gremlin = o->gremlin;

#endif


    sock->socket_buffer_sizes.rcvbuf = o->rcvbuf;

    sock->socket_buffer_sizes.sndbuf = o->sndbuf;


    sock->sockflags = o->sockflags;


#if PORT_SHARE

    if (o->port_share_host && o->port_share_port)

    {

        sock->sockflags |= SF_PORT_SHARE;

    }

#endif


    sock->mark = o->mark;

    sock->bind_dev = o->bind_dev;

    sock->info.proto = proto;

    sock->info.af = o->ce.af;

    sock->info.remote_float = o->ce.remote_float;

    sock->info.lsa = &c->c1.link_socket_addrs[sock_index];

    sock->info.bind_ipv6_only = o->ce.bind_ipv6_only;

    sock->info.ipchange_command = o->ipchange;

    sock->info.plugins = c->plugins;

    sock->server_poll_timeout = &c->c2.server_poll_interval;


    sock->mode = mode;

    if (mode == LS_MODE_TCP_ACCEPT_FROM)

    {

        ASSERT(c->c2.accept_from);

        ASSERT(sock->info.proto == PROTO_TCP_SERVER);

        sock->sd = c->c2.accept_from->sd;

        /* inherit (possibly guessed) info AF from parent context */

        sock->info.af = c->c2.accept_from->info.af;

    }


    /* are we running in HTTP proxy mode? */

    if (sock->http_proxy)

    {

        ASSERT(sock->info.proto == PROTO_TCP_CLIENT);


        /* the proxy server */

        sock->remote_host = c->c1.http_proxy->options.server;

        sock->remote_port = c->c1.http_proxy->options.port;


        /* the OpenVPN server we will use the proxy to connect to */

        sock->proxy_dest_host = remote_host;

        sock->proxy_dest_port = remote_port;

    }

    /* or in Socks proxy mode? */

    else if (sock->socks_proxy)

    {

        /* the proxy server */

        sock->remote_host = c->c1.socks_proxy->server;

        sock->remote_port = c->c1.socks_proxy->port;


        /* the OpenVPN server we will use the proxy to connect to */

        sock->proxy_dest_host = remote_host;

        sock->proxy_dest_port = remote_port;

    }

    else

    {

        sock->remote_host = remote_host;

        sock->remote_port = remote_port;

    }


    /* bind behavior for TCP server vs. client */

    if (sock->info.proto == PROTO_TCP_SERVER)

    {

        if (sock->mode == LS_MODE_TCP_ACCEPT_FROM)

        {

            sock->bind_local = false;

        }

        else

        {

            sock->bind_local = true;

        }

    }


    if (mode != LS_MODE_TCP_ACCEPT_FROM)

    {

        if (sock->bind_local)

        {

            resolve_bind_local(sock, sock->info.af);

        }

        resolve_remote(sock, 1, NULL, NULL);

    }

}


static void


phase2_set_socket_flags(struct link_socket *sock)

{

    /* set misc socket parameters */

    socket_set_flags(sock->sd, sock->sockflags);


    /* set socket to non-blocking mode */

    set_nonblock(sock->sd);


    /* set Path MTU discovery options on the socket */

    set_mtu_discover_type(sock->sd, sock->mtu_discover_type, sock->info.af);


#if EXTENDED_SOCKET_ERROR_CAPABILITY

    /* if the OS supports it, enable extended error passing on the socket */

    set_sock_extended_error_passing(sock->sd, sock->info.af);

#endif

}


static void


linksock_print_addr(struct link_socket *sock)

{

    struct gc_arena gc = gc_new();

    const int msglevel = (sock->mode == LS_MODE_TCP_ACCEPT_FROM) ? D_INIT_MEDIUM : M_INFO;


    /* print local address */

    if (sock->bind_local)

    {

        sa_family_t ai_family = sock->info.lsa->actual.dest.addr.sa.sa_family;

        /* Socket is always bound on the first matching address,

         * For bound sockets with no remote addr this is the element of

         * the list */

        struct addrinfo *cur;

        for (cur = sock->info.lsa->bind_local; cur; cur = cur->ai_next)

        {

            if (!ai_family || ai_family == cur->ai_family)

            {

                break;

            }

        }

        ASSERT(cur);

        msg(msglevel, "%s link local (bound): %s",

            proto2ascii(sock->info.proto, sock->info.af, true),

            print_sockaddr(cur->ai_addr, &gc));

    }

    else

    {

        msg(msglevel, "%s link local: (not bound)",

            proto2ascii(sock->info.proto, sock->info.af, true));

    }


    /* print active remote address */

    msg(msglevel, "%s link remote: %s",

        proto2ascii(sock->info.proto, sock->info.af, true),

        print_link_socket_actual_ex(&sock->info.lsa->actual,

                                    ":",

                                    PS_SHOW_PORT_IF_DEFINED,

                                    &gc));

    gc_free(&gc);

}


static void


phase2_tcp_server(struct link_socket *sock, const char *remote_dynamic,

                  struct signal_info *sig_info)

{

    ASSERT(sig_info);

    volatile int *signal_received = &sig_info->signal_received;

    switch (sock->mode)

    {

        case LS_MODE_DEFAULT:

            sock->sd = socket_listen_accept(sock->sd,

                                            &sock->info.lsa->actual,

                                            remote_dynamic,

                                            sock->info.lsa->bind_local,

                                            true,

                                            false,

                                            signal_received);

            break;


        case LS_MODE_TCP_LISTEN:

            socket_do_listen(sock->sd,

                             sock->info.lsa->bind_local,

                             true,

                             false);

            break;


        case LS_MODE_TCP_ACCEPT_FROM:

            sock->sd = socket_do_accept(sock->sd,

                                        &sock->info.lsa->actual,

                                        false);

            if (!socket_defined(sock->sd))

            {

                register_signal(sig_info, SIGTERM, "socket-undefined");

                return;

            }

            tcp_connection_established(&sock->info.lsa->actual);

            break;


        default:

            ASSERT(0);

    }

}


static void


phase2_tcp_client(struct link_socket *sock, struct signal_info *sig_info)

{

    bool proxy_retry = false;

    do

    {

        socket_connect(&sock->sd,

                       sock->info.lsa->current_remote->ai_addr,

                       get_server_poll_remaining_time(sock->server_poll_timeout),

                       sig_info);


        if (sig_info->signal_received)

        {

            return;

        }


        if (sock->http_proxy)

        {

            proxy_retry = establish_http_proxy_passthru(sock->http_proxy,

                                                        sock->sd,

                                                        sock->proxy_dest_host,

                                                        sock->proxy_dest_port,

                                                        sock->server_poll_timeout,

                                                        &sock->stream_buf.residual,

                                                        sig_info);

        }

        else if (sock->socks_proxy)

        {

            establish_socks_proxy_passthru(sock->socks_proxy,

                                           sock->sd,

                                           sock->proxy_dest_host,

                                           sock->proxy_dest_port,

                                           sock->server_poll_timeout,

                                           sig_info);

        }

        if (proxy_retry)

        {

            openvpn_close_socket(sock->sd);

            sock->sd = create_socket_tcp(sock->info.lsa->current_remote);

        }


    } while (proxy_retry);


}


static void


phase2_socks_client(struct link_socket *sock, struct signal_info *sig_info)

{

    socket_connect(&sock->ctrl_sd,

                   sock->info.lsa->current_remote->ai_addr,

                   get_server_poll_remaining_time(sock->server_poll_timeout),

                   sig_info);


    if (sig_info->signal_received)

    {

        return;

    }


    establish_socks_proxy_udpassoc(sock->socks_proxy,

                                   sock->ctrl_sd,

                                   &sock->socks_relay.dest,

                                   sock->server_poll_timeout,

                                   sig_info);


    if (sig_info->signal_received)

    {

        return;

    }


    sock->remote_host = sock->proxy_dest_host;

    sock->remote_port = sock->proxy_dest_port;


    addr_zero_host(&sock->info.lsa->actual.dest);

    if (sock->info.lsa->remote_list)

    {

        freeaddrinfo(sock->info.lsa->remote_list);

        sock->info.lsa->current_remote = NULL;

        sock->info.lsa->remote_list = NULL;

    }


    resolve_remote(sock, 1, NULL, sig_info);

}


#if defined(_WIN32)

static void


create_socket_dco_win(struct context *c, struct link_socket *sock,

                      struct signal_info *sig_info)

{

    /* in P2P mode we must have remote resolved at this point */

    struct addrinfo *remoteaddr = sock->info.lsa->current_remote;

    if ((c->options.mode == MODE_POINT_TO_POINT) && (!remoteaddr))

    {

        return;

    }


    if (!c->c1.tuntap)

    {

        struct tuntap *tt;

        ALLOC_OBJ_CLEAR(tt, struct tuntap);


        tt->backend_driver = DRIVER_DCO;

        tt->options.msg_channel = c->options.msg_channel;


        const char *device_guid = NULL; /* not used */

        tun_open_device(tt, c->options.dev_node, &device_guid, &c->gc);


        /* Ensure we can "safely" cast the handle to a socket */

        static_assert(sizeof(sock->sd) == sizeof(tt->hand), "HANDLE and SOCKET size differs");


        c->c1.tuntap = tt;

    }


    if (c->options.mode == MODE_SERVER)

    {

        dco_mp_start_vpn(c->c1.tuntap->hand, sock);

    }

    else

    {

        dco_p2p_new_peer(c->c1.tuntap->hand, &c->c1.tuntap->dco_new_peer_ov, sock, sig_info);

    }

    sock->sockflags |= SF_DCO_WIN;


    if (sig_info->signal_received)

    {

        return;

    }


    sock->sd = (SOCKET)c->c1.tuntap->hand;

    linksock_print_addr(sock);

}


#endif /* if defined(_WIN32) */


/* finalize socket initialization */

void


link_socket_init_phase2(struct context *c,

                        struct link_socket *sock)

{

    const struct frame *frame = &c->c2.frame;

    struct signal_info *sig_info = c->sig;


    const char *remote_dynamic = NULL;

    struct signal_info sig_save = {0};


    ASSERT(sock);

    ASSERT(sig_info);


    if (sig_info->signal_received)

    {

        sig_save = *sig_info;

        sig_save.signal_received = signal_reset(sig_info, 0);

    }


    /* initialize buffers */

    socket_frame_init(frame, sock);


    /*

     * Pass a remote name to connect/accept so that

     * they can test for dynamic IP address changes

     * and throw a SIGUSR1 if appropriate.

     */

    if (sock->resolve_retry_seconds)

    {

        remote_dynamic = sock->remote_host;

    }


    /* Second chance to resolv/create socket */

    resolve_remote(sock, 2, &remote_dynamic,  sig_info);


    /* If a valid remote has been found, create the socket with its addrinfo */

#if defined(_WIN32)

    if (dco_enabled(&c->options))

    {

        create_socket_dco_win(c, sock, sig_info);

        goto done;

    }

#endif

    if (sock->info.lsa->current_remote)

    {

        create_socket(sock, sock->info.lsa->current_remote);

    }


    /* If socket has not already been created create it now */

    if (sock->sd == SOCKET_UNDEFINED)

    {

        /* If we have no --remote and have still not figured out the

         * protocol family to use we will use the first of the bind */


        if (sock->bind_local  && !sock->remote_host && sock->info.lsa->bind_local)

        {

            /* Warn if this is because neither v4 or v6 was specified

             * and we should not connect a remote */

            if (sock->info.af == AF_UNSPEC)

            {

                msg(M_WARN, "Could not determine IPv4/IPv6 protocol. Using %s",

                    addr_family_name(sock->info.lsa->bind_local->ai_family));

                sock->info.af = sock->info.lsa->bind_local->ai_family;

            }

            create_socket(sock, sock->info.lsa->bind_local);

        }

    }


    /* Socket still undefined, give a warning and abort connection */

    if (sock->sd == SOCKET_UNDEFINED)

    {

        msg(M_WARN, "Could not determine IPv4/IPv6 protocol");

        register_signal(sig_info, SIGUSR1, "Could not determine IPv4/IPv6 protocol");

        goto done;

    }


    if (sig_info->signal_received)

    {

        goto done;

    }


    if (sock->info.proto == PROTO_TCP_SERVER)

    {

        phase2_tcp_server(sock, remote_dynamic, sig_info);

    }

    else if (sock->info.proto == PROTO_TCP_CLIENT)

    {

        phase2_tcp_client(sock, sig_info);


    }

    else if (sock->info.proto == PROTO_UDP && sock->socks_proxy)

    {

        phase2_socks_client(sock, sig_info);

    }

#ifdef TARGET_ANDROID

    if (sock->sd != -1)

    {

        protect_fd_nonlocal(sock->sd, &sock->info.lsa->actual.dest.addr.sa);

    }

#endif

    if (sig_info->signal_received)

    {

        goto done;

    }


    phase2_set_socket_flags(sock);

    linksock_print_addr(sock);


done:

    if (sig_save.signal_received)

    {

        /* Always restore the saved signal -- register/throw_signal will handle priority */

        if (sig_save.source == SIG_SOURCE_HARD && sig_info == &siginfo_static)

        {

            throw_signal(sig_save.signal_received);

        }

        else

        {

            register_signal(sig_info, sig_save.signal_received, sig_save.signal_text);

        }

    }

}


void


link_socket_close(struct link_socket *sock)

{

    if (sock)

    {

#ifdef ENABLE_DEBUG

        const int gremlin = GREMLIN_CONNECTION_FLOOD_LEVEL(sock->gremlin);

#else

        const int gremlin = 0;

#endif


        if (socket_defined(sock->sd))

        {

#ifdef _WIN32

            close_net_event_win32(&sock->listen_handle, sock->sd, 0);

#endif

            if (!gremlin)

            {

                msg(D_LOW, "TCP/UDP: Closing socket");

                if (openvpn_close_socket(sock->sd))

                {

                    msg(M_WARN | M_ERRNO, "TCP/UDP: Close Socket failed");

                }

            }

            sock->sd = SOCKET_UNDEFINED;

#ifdef _WIN32

            if (!gremlin)

            {

                overlapped_io_close(&sock->reads);

                overlapped_io_close(&sock->writes);

            }

#endif

        }


        if (socket_defined(sock->ctrl_sd))

        {

            if (openvpn_close_socket(sock->ctrl_sd))

            {

                msg(M_WARN | M_ERRNO, "TCP/UDP: Close Socket (ctrl_sd) failed");

            }

            sock->ctrl_sd = SOCKET_UNDEFINED;

        }


        stream_buf_close(&sock->stream_buf);

        free_buf(&sock->stream_buf_data);

        if (!gremlin)

        {

            free(sock);

        }

    }

}


void


setenv_trusted(struct env_set *es, const struct link_socket_info *info)

{

    setenv_link_socket_actual(es, "trusted", &info->lsa->actual, SA_IP_PORT);

}


static void


ipchange_fmt(const bool include_cmd, struct argv *argv, const struct link_socket_info *info, struct gc_arena *gc)

{

    const char *host = print_sockaddr_ex(&info->lsa->actual.dest.addr.sa, " ", PS_SHOW_PORT, gc);

    if (include_cmd)

    {

        argv_parse_cmd(argv, info->ipchange_command);

        argv_printf_cat(argv, "%s", host);

    }

    else

    {

        argv_printf(argv, "%s", host);

    }


}


void


link_socket_connection_initiated(struct link_socket_info *info,

                                 const struct link_socket_actual *act,

                                 const char *common_name,

                                 struct env_set *es)

{

    struct gc_arena gc = gc_new();


    info->lsa->actual = *act; /* Note: skip this line for --force-dest */

    setenv_trusted(es, info);

    info->connection_established = true;


    /* Print connection initiated message, with common name if available */

    {

        struct buffer out = alloc_buf_gc(256, &gc);

        if (common_name)

        {

            buf_printf(&out, "[%s] ", common_name);

        }

        buf_printf(&out, "Peer Connection Initiated with %s", print_link_socket_actual(&info->lsa->actual, &gc));

        msg(M_INFO, "%s", BSTR(&out));

    }


    /* set environmental vars */

    setenv_str(es, "common_name", common_name);


    /* Process --ipchange plugin */

    if (plugin_defined(info->plugins, OPENVPN_PLUGIN_IPCHANGE))

    {

        struct argv argv = argv_new();

        ipchange_fmt(false, &argv, info, &gc);

        if (plugin_call(info->plugins, OPENVPN_PLUGIN_IPCHANGE, &argv, NULL, es) != OPENVPN_PLUGIN_FUNC_SUCCESS)

        {

            msg(M_WARN, "WARNING: ipchange plugin call failed");

        }

        argv_free(&argv);

    }


    /* Process --ipchange option */

    if (info->ipchange_command)

    {

        struct argv argv = argv_new();

        setenv_str(es, "script_type", "ipchange");

        ipchange_fmt(true, &argv, info, &gc);

        openvpn_run_script(&argv, es, 0, "--ipchange");

        argv_free(&argv);

    }


    gc_free(&gc);

}


void


link_socket_bad_incoming_addr(struct buffer *buf,

                              const struct link_socket_info *info,

                              const struct link_socket_actual *from_addr)

{

    struct gc_arena gc = gc_new();

    struct addrinfo *ai;


    switch (from_addr->dest.addr.sa.sa_family)

    {

        case AF_INET:

        case AF_INET6:

            msg(D_LINK_ERRORS,

                "TCP/UDP: Incoming packet rejected from %s[%d], expected peer address: %s (allow this incoming source address/port by removing --remote or adding --float)",

                print_link_socket_actual(from_addr, &gc),

                (int)from_addr->dest.addr.sa.sa_family,

                print_sockaddr_ex(info->lsa->remote_list->ai_addr, ":", PS_SHOW_PORT, &gc));

            /* print additional remote addresses */

            for (ai = info->lsa->remote_list->ai_next; ai; ai = ai->ai_next)

            {

                msg(D_LINK_ERRORS, "or from peer address: %s",

                    print_sockaddr_ex(ai->ai_addr, ":", PS_SHOW_PORT, &gc));

            }

            break;

    }

    buf->len = 0;

    gc_free(&gc);

}


void


link_socket_bad_outgoing_addr(void)

{

    dmsg(D_READ_WRITE, "TCP/UDP: No outgoing address to send packet");

}


in_addr_t


link_socket_current_remote(const struct link_socket_info *info)

{

    const struct link_socket_addr *lsa = info->lsa;


/*

 * This logic supports "redirect-gateway" semantic, which

 * makes sense only for PF_INET routes over PF_INET endpoints

 *

 * Maybe in the future consider PF_INET6 endpoints also ...

 * by now just ignore it

 *

 * For --remote entries with multiple addresses this

 * only return the actual endpoint we have successfully connected to

 */

    if (lsa->actual.dest.addr.sa.sa_family != AF_INET)

    {

        return IPV4_INVALID_ADDR;

    }


    if (link_socket_actual_defined(&lsa->actual))

    {

        return ntohl(lsa->actual.dest.addr.in4.sin_addr.s_addr);

    }

    else if (lsa->current_remote)

    {

        return ntohl(((struct sockaddr_in *)lsa->current_remote->ai_addr)

                     ->sin_addr.s_addr);

    }

    else

    {

        return 0;

    }

}


const struct in6_addr *


link_socket_current_remote_ipv6(const struct link_socket_info *info)

{

    const struct link_socket_addr *lsa = info->lsa;


/* This logic supports "redirect-gateway" semantic,

 * for PF_INET6 routes over PF_INET6 endpoints

 *

 * For --remote entries with multiple addresses this

 * only return the actual endpoint we have successfully connected to

 */

    if (lsa->actual.dest.addr.sa.sa_family != AF_INET6)

    {

        return NULL;

    }


    if (link_socket_actual_defined(&lsa->actual))

    {

        return &(lsa->actual.dest.addr.in6.sin6_addr);

    }

    else if (lsa->current_remote)

    {

        return &(((struct sockaddr_in6 *)lsa->current_remote->ai_addr)->sin6_addr);

    }

    else

    {

        return NULL;

    }

}


/*

 * Return a status string describing socket state.

 */

const char *


socket_stat(const struct link_socket *s, unsigned int rwflags, struct gc_arena *gc)

{

    struct buffer out = alloc_buf_gc(64, gc);

    if (s)

    {

        if (rwflags & EVENT_READ)

        {

            buf_printf(&out, "S%s",

                       (s->rwflags_debug & EVENT_READ) ? "R" : "r");

#ifdef _WIN32

            buf_printf(&out, "%s",

                       overlapped_io_state_ascii(&s->reads));

#endif

        }

        if (rwflags & EVENT_WRITE)

        {

            buf_printf(&out, "S%s",

                       (s->rwflags_debug & EVENT_WRITE) ? "W" : "w");

#ifdef _WIN32

            buf_printf(&out, "%s",

                       overlapped_io_state_ascii(&s->writes));

#endif

        }

    }

    else

    {

        buf_printf(&out, "S?");

    }

    return BSTR(&out);

}


/*

 * Stream buffer functions, used to packetize a TCP

 * stream connection.

 */


static inline void


stream_buf_reset(struct stream_buf *sb)

{

    dmsg(D_STREAM_DEBUG, "STREAM: RESET");

    sb->residual_fully_formed = false;

    sb->buf = sb->buf_init;

    buf_reset(&sb->next);

    sb->len = -1;

}


static void


stream_buf_init(struct stream_buf *sb,

                struct buffer *buf,

                const unsigned int sockflags,

                const int proto)

{

    sb->buf_init = *buf;

    sb->maxlen = sb->buf_init.len;

    sb->buf_init.len = 0;

    sb->residual = alloc_buf(sb->maxlen);

    sb->error = false;

#if PORT_SHARE

    sb->port_share_state = ((sockflags & SF_PORT_SHARE) && (proto == PROTO_TCP_SERVER))

                           ? PS_ENABLED

                           : PS_DISABLED;

#endif

    stream_buf_reset(sb);


    dmsg(D_STREAM_DEBUG, "STREAM: INIT maxlen=%d", sb->maxlen);

}


static inline void


stream_buf_set_next(struct stream_buf *sb)

{

    /* set up 'next' for next i/o read */

    sb->next = sb->buf;

    sb->next.offset = sb->buf.offset + sb->buf.len;

    sb->next.len = (sb->len >= 0 ? sb->len : sb->maxlen) - sb->buf.len;

    dmsg(D_STREAM_DEBUG, "STREAM: SET NEXT, buf=[%d,%d] next=[%d,%d] len=%d maxlen=%d",

         sb->buf.offset, sb->buf.len,

         sb->next.offset, sb->next.len,

         sb->len, sb->maxlen);

    ASSERT(sb->next.len > 0);

    ASSERT(buf_safe(&sb->buf, sb->next.len));

}


static inline void


stream_buf_get_final(struct stream_buf *sb, struct buffer *buf)

{

    dmsg(D_STREAM_DEBUG, "STREAM: GET FINAL len=%d",

         buf_defined(&sb->buf) ? sb->buf.len : -1);

    ASSERT(buf_defined(&sb->buf));

    *buf = sb->buf;

}


static inline void


stream_buf_get_next(struct stream_buf *sb, struct buffer *buf)

{

    dmsg(D_STREAM_DEBUG, "STREAM: GET NEXT len=%d",

         buf_defined(&sb->next) ? sb->next.len : -1);

    ASSERT(buf_defined(&sb->next));

    *buf = sb->next;

}


bool


stream_buf_read_setup_dowork(struct link_socket *sock)

{

    if (sock->stream_buf.residual.len && !sock->stream_buf.residual_fully_formed)

    {

        ASSERT(buf_copy(&sock->stream_buf.buf, &sock->stream_buf.residual));

        ASSERT(buf_init(&sock->stream_buf.residual, 0));

        sock->stream_buf.residual_fully_formed = stream_buf_added(&sock->stream_buf, 0);

        dmsg(D_STREAM_DEBUG, "STREAM: RESIDUAL FULLY FORMED [%s], len=%d",

             sock->stream_buf.residual_fully_formed ? "YES" : "NO",

             sock->stream_buf.residual.len);

    }


    if (!sock->stream_buf.residual_fully_formed)

    {

        stream_buf_set_next(&sock->stream_buf);

    }

    return !sock->stream_buf.residual_fully_formed;

}


static bool


stream_buf_added(struct stream_buf *sb,

                 int length_added)

{

    dmsg(D_STREAM_DEBUG, "STREAM: ADD length_added=%d", length_added);

    if (length_added > 0)

    {

        sb->buf.len += length_added;

    }


    /* if length unknown, see if we can get the length prefix from

     * the head of the buffer */

    if (sb->len < 0 && sb->buf.len >= (int) sizeof(packet_size_type))

    {

        packet_size_type net_size;


#if PORT_SHARE

        if (sb->port_share_state == PS_ENABLED)

        {

            if (!is_openvpn_protocol(&sb->buf))

            {

                msg(D_STREAM_ERRORS, "Non-OpenVPN client protocol detected");

                sb->port_share_state = PS_FOREIGN;

                sb->error = true;

                return false;

            }

            else

            {

                sb->port_share_state = PS_DISABLED;

            }

        }

#endif


        ASSERT(buf_read(&sb->buf, &net_size, sizeof(net_size)));

        sb->len = ntohps(net_size);


        if (sb->len < 1 || sb->len > sb->maxlen)

        {

            msg(M_WARN, "WARNING: Bad encapsulated packet length from peer (%d), which must be > 0 and <= %d -- please ensure that --tun-mtu or --link-mtu is equal on both peers -- this condition could also indicate a possible active attack on the TCP link -- [Attempting restart...]", sb->len, sb->maxlen);

            stream_buf_reset(sb);

            sb->error = true;

            return false;

        }

    }


    /* is our incoming packet fully read? */

    if (sb->len > 0 && sb->buf.len >= sb->len)

    {

        /* save any residual data that's part of the next packet */

        ASSERT(buf_init(&sb->residual, 0));

        if (sb->buf.len > sb->len)

        {

            ASSERT(buf_copy_excess(&sb->residual, &sb->buf, sb->len));

        }

        dmsg(D_STREAM_DEBUG, "STREAM: ADD returned TRUE, buf_len=%d, residual_len=%d",

             BLEN(&sb->buf),

             BLEN(&sb->residual));

        return true;

    }

    else

    {

        dmsg(D_STREAM_DEBUG, "STREAM: ADD returned FALSE (have=%d need=%d)", sb->buf.len, sb->len);

        stream_buf_set_next(sb);

        return false;

    }

}


static void


stream_buf_close(struct stream_buf *sb)

{

    free_buf(&sb->residual);

}


/*

 * The listen event is a special event whose sole purpose is

 * to tell us that there's a new incoming connection on a

 * TCP socket, for use in server mode.

 */

event_t


socket_listen_event_handle(struct link_socket *s)

{

#ifdef _WIN32

    if (!defined_net_event_win32(&s->listen_handle))

    {

        init_net_event_win32(&s->listen_handle, FD_ACCEPT, s->sd, 0);

    }

    return &s->listen_handle;

#else  /* ifdef _WIN32 */

    return s->sd;

#endif

}


/*

 * Format IP addresses in ascii

 */


const char *


print_sockaddr_ex(const struct sockaddr *sa,

                  const char *separator,

                  const unsigned int flags,

                  struct gc_arena *gc)

{

    struct buffer out = alloc_buf_gc(128, gc);

    bool addr_is_defined = false;

    char hostaddr[NI_MAXHOST] = "";

    char servname[NI_MAXSERV] = "";

    int status;


    socklen_t salen = 0;

    switch (sa->sa_family)

    {

        case AF_INET:

            if (!(flags & PS_DONT_SHOW_FAMILY))

            {

                buf_puts(&out, "[AF_INET]");

            }

            salen = sizeof(struct sockaddr_in);

            addr_is_defined = ((struct sockaddr_in *) sa)->sin_addr.s_addr != 0;

            break;


        case AF_INET6:

            if (!(flags & PS_DONT_SHOW_FAMILY))

            {

                buf_puts(&out, "[AF_INET6]");

            }

            salen = sizeof(struct sockaddr_in6);

            addr_is_defined = !IN6_IS_ADDR_UNSPECIFIED(&((struct sockaddr_in6 *) sa)->sin6_addr);

            break;


        case AF_UNSPEC:

            if (!(flags & PS_DONT_SHOW_FAMILY))

            {

                return "[AF_UNSPEC]";

            }

            else

            {

                return "";

            }


        default:

            ASSERT(0);

    }


    status = getnameinfo(sa, salen, hostaddr, sizeof(hostaddr),

                         servname, sizeof(servname), NI_NUMERICHOST | NI_NUMERICSERV);


    if (status!=0)

    {

        buf_printf(&out, "[nameinfo() err: %s]", gai_strerror(status));

        return BSTR(&out);

    }


    if (!(flags & PS_DONT_SHOW_ADDR))

    {

        if (addr_is_defined)

        {

            buf_puts(&out, hostaddr);

        }

        else

        {

            buf_puts(&out, "[undef]");

        }

    }


    if ((flags & PS_SHOW_PORT) || (flags & PS_SHOW_PORT_IF_DEFINED))

    {

        if (separator)

        {

            buf_puts(&out, separator);

        }


        buf_puts(&out, servname);

    }


    return BSTR(&out);

}


const char *


print_link_socket_actual(const struct link_socket_actual *act, struct gc_arena *gc)

{

    return print_link_socket_actual_ex(act, ":", PS_SHOW_PORT|PS_SHOW_PKTINFO, gc);

}


#ifndef IF_NAMESIZE

#define IF_NAMESIZE 16

#endif


const char *


print_link_socket_actual_ex(const struct link_socket_actual *act,

                            const char *separator,

                            const unsigned int flags,

                            struct gc_arena *gc)

{

    if (act)

    {

        struct buffer out = alloc_buf_gc(128, gc);

        buf_printf(&out, "%s", print_sockaddr_ex(&act->dest.addr.sa, separator, flags, gc));

#if ENABLE_IP_PKTINFO

        char ifname[IF_NAMESIZE] = "[undef]";


        if ((flags & PS_SHOW_PKTINFO) && addr_defined_ipi(act))

        {

            switch (act->dest.addr.sa.sa_family)

            {

                case AF_INET:

                {

                    struct openvpn_sockaddr sa;

                    CLEAR(sa);

                    sa.addr.in4.sin_family = AF_INET;

#if defined(HAVE_IN_PKTINFO) && defined(HAVE_IPI_SPEC_DST)

                    sa.addr.in4.sin_addr = act->pi.in4.ipi_spec_dst;

                    if_indextoname(act->pi.in4.ipi_ifindex, ifname);

#elif defined(IP_RECVDSTADDR)

                    sa.addr.in4.sin_addr = act->pi.in4;

                    ifname[0] = 0;

#else  /* if defined(HAVE_IN_PKTINFO) && defined(HAVE_IPI_SPEC_DST) */

#error ENABLE_IP_PKTINFO is set without IP_PKTINFO xor IP_RECVDSTADDR (fix syshead.h)

#endif

                    buf_printf(&out, " (via %s%%%s)",

                               print_sockaddr_ex(&sa.addr.sa, separator, 0, gc),

                               ifname);

                }

                break;


                case AF_INET6:

                {

                    struct sockaddr_in6 sin6;

                    char buf[INET6_ADDRSTRLEN] = "[undef]";

                    CLEAR(sin6);

                    sin6.sin6_family = AF_INET6;

                    sin6.sin6_addr = act->pi.in6.ipi6_addr;

                    if_indextoname(act->pi.in6.ipi6_ifindex, ifname);

                    if (getnameinfo((struct sockaddr *)&sin6, sizeof(struct sockaddr_in6),

                                    buf, sizeof(buf), NULL, 0, NI_NUMERICHOST) == 0)

                    {

                        buf_printf(&out, " (via %s%%%s)", buf, ifname);

                    }

                    else

                    {

                        buf_printf(&out, " (via [getnameinfo() err]%%%s)", ifname);

                    }

                }

                break;

            }

        }

#endif /* if ENABLE_IP_PKTINFO */

        return BSTR(&out);

    }

    else

    {

        return "[NULL]";

    }

}


/*

 * Convert an in_addr_t in host byte order

 * to an ascii dotted quad.

 */

const char *


print_in_addr_t(in_addr_t addr, unsigned int flags, struct gc_arena *gc)

{

    struct in_addr ia;

    char *out = gc_malloc(INET_ADDRSTRLEN, true, gc);


    if (addr || !(flags & IA_EMPTY_IF_UNDEF))

    {

        CLEAR(ia);

        ia.s_addr = (flags & IA_NET_ORDER) ? addr : htonl(addr);


        inet_ntop(AF_INET, &ia, out, INET_ADDRSTRLEN);

    }

    return out;

}


/*

 * Convert an in6_addr in host byte order

 * to an ascii representation of an IPv6 address

 */

const char *


print_in6_addr(struct in6_addr a6, unsigned int flags, struct gc_arena *gc)

{

    char *out = gc_malloc(INET6_ADDRSTRLEN, true, gc);


    if (memcmp(&a6, &in6addr_any, sizeof(a6)) != 0

        || !(flags & IA_EMPTY_IF_UNDEF))

    {

        inet_ntop(AF_INET6, &a6, out, INET6_ADDRSTRLEN);

    }

    return out;

}


/*

 * Convert an in_port_t in host byte order to a string

 */

const char *


print_in_port_t(in_port_t port, struct gc_arena *gc)

{

    struct buffer buffer = alloc_buf_gc(8, gc);

    buf_printf(&buffer, "%hu", port);

    return BSTR(&buffer);

}


/* add some offset to an ipv6 address

 * (add in steps of 8 bits, taking overflow into next round)

 */

struct in6_addr


add_in6_addr( struct in6_addr base, uint32_t add )

{

    int i;


    for (i = 15; i>=0 && add > 0; i--)

    {

        register int carry;

        register uint32_t h;


        h = (unsigned char) base.s6_addr[i];

        base.s6_addr[i] = (h+add) & UINT8_MAX;


        /* using explicit carry for the 8-bit additions will catch

         * 8-bit and(!) 32-bit overruns nicely

         */

        carry = ((h & 0xff)  + (add & 0xff)) >> 8;

        add = (add>>8) + carry;

    }

    return base;

}


/* set environmental variables for ip/port in *addr */

void


setenv_sockaddr(struct env_set *es, const char *name_prefix, const struct openvpn_sockaddr *addr, const unsigned int flags)

{

    char name_buf[256];


    char buf[INET6_ADDRSTRLEN];

    switch (addr->addr.sa.sa_family)

    {

        case AF_INET:

            if (flags & SA_IP_PORT)

            {

                snprintf(name_buf, sizeof(name_buf), "%s_ip", name_prefix);

            }

            else

            {

                snprintf(name_buf, sizeof(name_buf), "%s", name_prefix);

            }


            inet_ntop(AF_INET, &addr->addr.in4.sin_addr, buf, sizeof(buf));

            setenv_str(es, name_buf, buf);


            if ((flags & SA_IP_PORT) && addr->addr.in4.sin_port)

            {

                snprintf(name_buf, sizeof(name_buf), "%s_port", name_prefix);

                setenv_int(es, name_buf, ntohs(addr->addr.in4.sin_port));

            }

            break;


        case AF_INET6:

            if (IN6_IS_ADDR_V4MAPPED( &addr->addr.in6.sin6_addr ))

            {

                struct in_addr ia;

                memcpy(&ia.s_addr, &addr->addr.in6.sin6_addr.s6_addr[12],

                       sizeof(ia.s_addr));

                snprintf(name_buf, sizeof(name_buf), "%s_ip", name_prefix);

                inet_ntop(AF_INET, &ia, buf, sizeof(buf));

            }

            else

            {

                snprintf(name_buf, sizeof(name_buf), "%s_ip6", name_prefix);

                inet_ntop(AF_INET6, &addr->addr.in6.sin6_addr, buf, sizeof(buf));

            }

            setenv_str(es, name_buf, buf);


            if ((flags & SA_IP_PORT) && addr->addr.in6.sin6_port)

            {

                snprintf(name_buf, sizeof(name_buf), "%s_port", name_prefix);

                setenv_int(es, name_buf, ntohs(addr->addr.in6.sin6_port));

            }

            break;

    }

}


void


setenv_in_addr_t(struct env_set *es, const char *name_prefix, in_addr_t addr, const unsigned int flags)

{

    if (addr || !(flags & SA_SET_IF_NONZERO))

    {

        struct openvpn_sockaddr si;

        CLEAR(si);

        si.addr.in4.sin_family = AF_INET;

        si.addr.in4.sin_addr.s_addr = htonl(addr);

        setenv_sockaddr(es, name_prefix, &si, flags);

    }

}


void


setenv_in6_addr(struct env_set *es,

                const char *name_prefix,

                const struct in6_addr *addr,

                const unsigned int flags)

{

    if (!IN6_IS_ADDR_UNSPECIFIED(addr) || !(flags & SA_SET_IF_NONZERO))

    {

        struct openvpn_sockaddr si;

        CLEAR(si);

        si.addr.in6.sin6_family = AF_INET6;

        si.addr.in6.sin6_addr = *addr;

        setenv_sockaddr(es, name_prefix, &si, flags);

    }

}


void


setenv_link_socket_actual(struct env_set *es,

                          const char *name_prefix,

                          const struct link_socket_actual *act,

                          const unsigned int flags)

{

    setenv_sockaddr(es, name_prefix, &act->dest, flags);

}


/*

 * Convert protocol names between index and ascii form.

 */


struct proto_names {

    const char *short_form;

    const char *display_form;

    sa_family_t proto_af;

    int proto;

};


/* Indexed by PROTO_x */


static const struct proto_names proto_names[] = {

    {"proto-uninitialized", "proto-NONE", AF_UNSPEC, PROTO_NONE},

    /* try IPv4 and IPv6 (client), bind dual-stack (server) */

    {"udp",         "UDP", AF_UNSPEC, PROTO_UDP},

    {"tcp-server",  "TCP_SERVER", AF_UNSPEC, PROTO_TCP_SERVER},

    {"tcp-client",  "TCP_CLIENT", AF_UNSPEC, PROTO_TCP_CLIENT},

    {"tcp",         "TCP", AF_UNSPEC, PROTO_TCP},

    /* force IPv4 */

    {"udp4",        "UDPv4", AF_INET, PROTO_UDP},

    {"tcp4-server", "TCPv4_SERVER", AF_INET, PROTO_TCP_SERVER},

    {"tcp4-client", "TCPv4_CLIENT", AF_INET, PROTO_TCP_CLIENT},

    {"tcp4",        "TCPv4", AF_INET, PROTO_TCP},

    /* force IPv6 */

    {"udp6",        "UDPv6", AF_INET6, PROTO_UDP},

    {"tcp6-server", "TCPv6_SERVER", AF_INET6, PROTO_TCP_SERVER},

    {"tcp6-client", "TCPv6_CLIENT", AF_INET6, PROTO_TCP_CLIENT},

    {"tcp6",        "TCPv6", AF_INET6, PROTO_TCP},

};


int


ascii2proto(const char *proto_name)

{

    for (size_t i = 0; i < SIZE(proto_names); ++i)

    {

        if (!strcmp(proto_name, proto_names[i].short_form))

        {

            return proto_names[i].proto;

        }

    }

    return -1;

}


sa_family_t


ascii2af(const char *proto_name)

{

    for (size_t i = 0; i < SIZE(proto_names); ++i)

    {

        if (!strcmp(proto_name, proto_names[i].short_form))

        {

            return proto_names[i].proto_af;

        }

    }

    return 0;

}


const char *


proto2ascii(int proto, sa_family_t af, bool display_form)

{

    for (size_t i = 0; i < SIZE(proto_names); ++i)

    {

        if (proto_names[i].proto_af == af && proto_names[i].proto == proto)

        {

            if (display_form)

            {

                return proto_names[i].display_form;

            }

            else

            {

                return proto_names[i].short_form;

            }

        }

    }


    return "[unknown protocol]";

}


const char *


proto2ascii_all(struct gc_arena *gc)

{

    struct buffer out = alloc_buf_gc(256, gc);


    for (size_t i = 0; i < SIZE(proto_names); ++i)

    {

        if (i)

        {

            buf_printf(&out, " ");

        }

        buf_printf(&out, "[%s]", proto_names[i].short_form);

    }

    return BSTR(&out);

}


const char *


addr_family_name(int af)

{

    switch (af)

    {

        case AF_INET:  return "AF_INET";


        case AF_INET6: return "AF_INET6";

    }

    return "AF_UNSPEC";

}


/*

 * Given a local proto, return local proto

 * if !remote, or compatible remote proto

 * if remote.

 *

 * This is used for options compatibility

 * checking.

 *

 * IPv6 and IPv4 protocols are comptabile but OpenVPN

 * has always sent UDPv4, TCPv4 over the wire. Keep these

 * strings for backward compatibility

 */

const char *


proto_remote(int proto, bool remote)

{

    ASSERT(proto >= 0 && proto < PROTO_N);

    if (proto == PROTO_UDP)

    {

        return "UDPv4";

    }


    if ( (remote && proto == PROTO_TCP_CLIENT)

         || (!remote && proto == PROTO_TCP_SERVER))

    {

        return "TCPv4_SERVER";

    }

    if ( (remote && proto == PROTO_TCP_SERVER)

         || (!remote && proto == PROTO_TCP_CLIENT))

    {

        return "TCPv4_CLIENT";

    }


    ASSERT(0);

    return ""; /* Make the compiler happy */

}


/*

 * Bad incoming address lengths that differ from what

 * we expect are considered to be fatal errors.

 */

void


bad_address_length(int actual, int expected)

{

    msg(M_FATAL, "ERROR: received strange incoming packet with an address length of %d -- we only accept address lengths of %d.",

        actual,

        expected);

}


/*

 * Socket Read Routines

 */


int


link_socket_read_tcp(struct link_socket *sock,

                     struct buffer *buf)

{

    int len = 0;


    if (!sock->stream_buf.residual_fully_formed)

    {

        /* with Linux-DCO, we sometimes try to access a socket that is

         * already installed in the kernel and has no valid file descriptor

         * anymore.  This is a bug.

         * Handle by resetting client instance instead of crashing.

         */

        if (sock->sd == SOCKET_UNDEFINED)

        {

            msg(M_INFO, "BUG: link_socket_read_tcp(): sock->sd==-1, reset client instance" );

            sock->stream_reset = true;              /* reset client instance */

            return buf->len = 0;                    /* nothing to read */

        }


#ifdef _WIN32

        sockethandle_t sh = { .s = sock->sd };

        len = sockethandle_finalize(sh, &sock->reads, buf, NULL);

#else

        struct buffer frag;

        stream_buf_get_next(&sock->stream_buf, &frag);

        len = recv(sock->sd, BPTR(&frag), BLEN(&frag), MSG_NOSIGNAL);

#endif


        if (!len)

        {

            sock->stream_reset = true;

        }

        if (len <= 0)

        {

            return buf->len = len;

        }

    }


    if (sock->stream_buf.residual_fully_formed

        || stream_buf_added(&sock->stream_buf, len)) /* packet complete? */

    {

        stream_buf_get_final(&sock->stream_buf, buf);

        stream_buf_reset(&sock->stream_buf);

        return buf->len;

    }

    else

    {

        return buf->len = 0; /* no error, but packet is still incomplete */

    }

}


#ifndef _WIN32


#if ENABLE_IP_PKTINFO


/* make the buffer large enough to handle ancillary socket data for

 * both IPv4 and IPv6 destination addresses, plus padding (see RFC 2292)

 */

#if defined(HAVE_IN_PKTINFO) && defined(HAVE_IPI_SPEC_DST)

#define PKTINFO_BUF_SIZE max_int( CMSG_SPACE(sizeof(struct in6_pktinfo)), \

                                  CMSG_SPACE(sizeof(struct in_pktinfo)) )

#else

#define PKTINFO_BUF_SIZE max_int( CMSG_SPACE(sizeof(struct in6_pktinfo)), \

                                  CMSG_SPACE(sizeof(struct in_addr)) )

#endif


static socklen_t

link_socket_read_udp_posix_recvmsg(struct link_socket *sock,

                                   struct buffer *buf,

                                   struct link_socket_actual *from)

{

    struct iovec iov;

    uint8_t pktinfo_buf[PKTINFO_BUF_SIZE];

    struct msghdr mesg = {0};

    socklen_t fromlen = sizeof(from->dest.addr);


    ASSERT(sock->sd >= 0);                      /* can't happen */


    iov.iov_base = BPTR(buf);

    iov.iov_len = buf_forward_capacity_total(buf);

    mesg.msg_iov = &iov;

    mesg.msg_iovlen = 1;

    mesg.msg_name = &from->dest.addr;

    mesg.msg_namelen = fromlen;

    mesg.msg_control = pktinfo_buf;

    mesg.msg_controllen = sizeof pktinfo_buf;

    buf->len = recvmsg(sock->sd, &mesg, 0);

    if (buf->len >= 0)

    {

        struct cmsghdr *cmsg;

        fromlen = mesg.msg_namelen;

        cmsg = CMSG_FIRSTHDR(&mesg);

        if (cmsg != NULL

            && CMSG_NXTHDR(&mesg, cmsg) == NULL

#if defined(HAVE_IN_PKTINFO) && defined(HAVE_IPI_SPEC_DST)

            && cmsg->cmsg_level == SOL_IP

            && cmsg->cmsg_type == IP_PKTINFO

            && cmsg->cmsg_len >= CMSG_LEN(sizeof(struct in_pktinfo)) )

#elif defined(IP_RECVDSTADDR)

            && cmsg->cmsg_level == IPPROTO_IP

            && cmsg->cmsg_type == IP_RECVDSTADDR

            && cmsg->cmsg_len >= CMSG_LEN(sizeof(struct in_addr)) )

#else  /* if defined(HAVE_IN_PKTINFO) && defined(HAVE_IPI_SPEC_DST) */

#error ENABLE_IP_PKTINFO is set without IP_PKTINFO xor IP_RECVDSTADDR (fix syshead.h)

#endif

        {

#if defined(HAVE_IN_PKTINFO) && defined(HAVE_IPI_SPEC_DST)

            struct in_pktinfo *pkti = (struct in_pktinfo *) CMSG_DATA(cmsg);

            from->pi.in4.ipi_ifindex = pkti->ipi_ifindex;

            from->pi.in4.ipi_spec_dst = pkti->ipi_spec_dst;

#elif defined(IP_RECVDSTADDR)

            from->pi.in4 = *(struct in_addr *) CMSG_DATA(cmsg);

#else  /* if defined(HAVE_IN_PKTINFO) && defined(HAVE_IPI_SPEC_DST) */

#error ENABLE_IP_PKTINFO is set without IP_PKTINFO xor IP_RECVDSTADDR (fix syshead.h)

#endif

        }

        else if (cmsg != NULL

                 && CMSG_NXTHDR(&mesg, cmsg) == NULL

                 && cmsg->cmsg_level == IPPROTO_IPV6

                 && cmsg->cmsg_type == IPV6_PKTINFO

                 && cmsg->cmsg_len >= CMSG_LEN(sizeof(struct in6_pktinfo)) )

        {

            struct in6_pktinfo *pkti6 = (struct in6_pktinfo *) CMSG_DATA(cmsg);

            from->pi.in6.ipi6_ifindex = pkti6->ipi6_ifindex;

            from->pi.in6.ipi6_addr = pkti6->ipi6_addr;

        }

        else if (cmsg != NULL)

        {

            msg(M_WARN, "CMSG received that cannot be parsed (cmsg_level=%d, cmsg_type=%d, cmsg=len=%d)", (int)cmsg->cmsg_level, (int)cmsg->cmsg_type, (int)cmsg->cmsg_len );

        }

    }


    return fromlen;

}

#endif /* if ENABLE_IP_PKTINFO */


int

link_socket_read_udp_posix(struct link_socket *sock,

                           struct buffer *buf,

                           struct link_socket_actual *from)

{

    socklen_t fromlen = sizeof(from->dest.addr);

    socklen_t expectedlen = af_addr_size(sock->info.af);

    addr_zero_host(&from->dest);


    ASSERT(sock->sd >= 0);                      /* can't happen */


#if ENABLE_IP_PKTINFO

    /* Both PROTO_UDPv4 and PROTO_UDPv6 */

    if (sock->info.proto == PROTO_UDP && sock->sockflags & SF_USE_IP_PKTINFO)

    {

        fromlen = link_socket_read_udp_posix_recvmsg(sock, buf, from);

    }

    else

#endif

    {

        buf->len = recvfrom(sock->sd, BPTR(buf), buf_forward_capacity(buf), 0,

                            &from->dest.addr.sa, &fromlen);

    }

    /* FIXME: won't do anything when sock->info.af == AF_UNSPEC */

    if (buf->len >= 0 && expectedlen && fromlen != expectedlen)

    {

        bad_address_length(fromlen, expectedlen);

    }

    return buf->len;

}


#endif /* ifndef _WIN32 */


/*

 * Socket Write Routines

 */


ssize_t


link_socket_write_tcp(struct link_socket *sock,

                      struct buffer *buf,

                      struct link_socket_actual *to)

{

    packet_size_type len = BLEN(buf);

    dmsg(D_STREAM_DEBUG, "STREAM: WRITE %d offset=%d", (int)len, buf->offset);

    ASSERT(len <= sock->stream_buf.maxlen);

    len = htonps(len);

    ASSERT(buf_write_prepend(buf, &len, sizeof(len)));

#ifdef _WIN32

    return link_socket_write_win32(sock, buf, to);

#else

    return link_socket_write_tcp_posix(sock, buf);

#endif

}


#if ENABLE_IP_PKTINFO


ssize_t

link_socket_write_udp_posix_sendmsg(struct link_socket *sock,

                                    struct buffer *buf,

                                    struct link_socket_actual *to)

{

    struct iovec iov;

    struct msghdr mesg;

    struct cmsghdr *cmsg;

    uint8_t pktinfo_buf[PKTINFO_BUF_SIZE];


    iov.iov_base = BPTR(buf);

    iov.iov_len = BLEN(buf);

    mesg.msg_iov = &iov;

    mesg.msg_iovlen = 1;

    switch (to->dest.addr.sa.sa_family)

    {

        case AF_INET:

        {

            mesg.msg_name = &to->dest.addr.sa;

            mesg.msg_namelen = sizeof(struct sockaddr_in);

            mesg.msg_control = pktinfo_buf;

            mesg.msg_flags = 0;

#if defined(HAVE_IN_PKTINFO) && defined(HAVE_IPI_SPEC_DST)

            mesg.msg_controllen = CMSG_SPACE(sizeof(struct in_pktinfo));

            cmsg = CMSG_FIRSTHDR(&mesg);

            cmsg->cmsg_len = CMSG_LEN(sizeof(struct in_pktinfo));

            cmsg->cmsg_level = SOL_IP;

            cmsg->cmsg_type = IP_PKTINFO;

            {

                struct in_pktinfo *pkti;

                pkti = (struct in_pktinfo *) CMSG_DATA(cmsg);

                pkti->ipi_ifindex = to->pi.in4.ipi_ifindex;

                pkti->ipi_spec_dst = to->pi.in4.ipi_spec_dst;

                pkti->ipi_addr.s_addr = 0;

            }

#elif defined(IP_RECVDSTADDR)

            ASSERT( CMSG_SPACE(sizeof(struct in_addr)) <= sizeof(pktinfo_buf) );

            mesg.msg_controllen = CMSG_SPACE(sizeof(struct in_addr));

            cmsg = CMSG_FIRSTHDR(&mesg);

            cmsg->cmsg_len = CMSG_LEN(sizeof(struct in_addr));

            cmsg->cmsg_level = IPPROTO_IP;

            cmsg->cmsg_type = IP_RECVDSTADDR;

            *(struct in_addr *) CMSG_DATA(cmsg) = to->pi.in4;

#else  /* if defined(HAVE_IN_PKTINFO) && defined(HAVE_IPI_SPEC_DST) */

#error ENABLE_IP_PKTINFO is set without IP_PKTINFO xor IP_RECVDSTADDR (fix syshead.h)

#endif /* if defined(HAVE_IN_PKTINFO) && defined(HAVE_IPI_SPEC_DST) */

            break;

        }


        case AF_INET6:

        {

            struct in6_pktinfo *pkti6;

            mesg.msg_name = &to->dest.addr.sa;

            mesg.msg_namelen = sizeof(struct sockaddr_in6);


            ASSERT( CMSG_SPACE(sizeof(struct in6_pktinfo)) <= sizeof(pktinfo_buf) );

            mesg.msg_control = pktinfo_buf;

            mesg.msg_controllen = CMSG_SPACE(sizeof(struct in6_pktinfo));

            mesg.msg_flags = 0;

            cmsg = CMSG_FIRSTHDR(&mesg);

            cmsg->cmsg_len = CMSG_LEN(sizeof(struct in6_pktinfo));

            cmsg->cmsg_level = IPPROTO_IPV6;

            cmsg->cmsg_type = IPV6_PKTINFO;


            pkti6 = (struct in6_pktinfo *) CMSG_DATA(cmsg);

            pkti6->ipi6_ifindex = to->pi.in6.ipi6_ifindex;

            pkti6->ipi6_addr = to->pi.in6.ipi6_addr;

            break;

        }


        default: ASSERT(0);

    }

    return sendmsg(sock->sd, &mesg, 0);

}


#endif /* if ENABLE_IP_PKTINFO */


/*

 * Win32 overlapped socket I/O functions.

 */


#ifdef _WIN32


static int


socket_get_last_error(const struct link_socket *sock)

{

    if (socket_is_dco_win(sock))

    {

        return GetLastError();

    }


    return WSAGetLastError();

}


int


socket_recv_queue(struct link_socket *sock, int maxsize)

{

    if (sock->reads.iostate == IOSTATE_INITIAL)

    {

        WSABUF wsabuf[1];

        int status;


        /* reset buf to its initial state */

        if (proto_is_udp(sock->info.proto))

        {

            sock->reads.buf = sock->reads.buf_init;

        }

        else if (proto_is_tcp(sock->info.proto))

        {

            stream_buf_get_next(&sock->stream_buf, &sock->reads.buf);

        }

        else

        {

            ASSERT(0);

        }


        /* Win32 docs say it's okay to allocate the wsabuf on the stack */

        wsabuf[0].buf = BSTR(&sock->reads.buf);

        wsabuf[0].len = maxsize ? maxsize : BLEN(&sock->reads.buf);


        /* check for buffer overflow */

        ASSERT(wsabuf[0].len <= BLEN(&sock->reads.buf));


        /* the overlapped read will signal this event on I/O completion */

        ASSERT(ResetEvent(sock->reads.overlapped.hEvent));

        sock->reads.flags = 0;


        if (socket_is_dco_win(sock))

        {

            status = ReadFile((HANDLE)sock->sd, wsabuf[0].buf, wsabuf[0].len,

                              &sock->reads.size, &sock->reads.overlapped);

            /* Readfile status is inverted from WSARecv */

            status = !status;

        }

        else if (proto_is_udp(sock->info.proto))

        {

            sock->reads.addr_defined = true;

            sock->reads.addrlen = sizeof(sock->reads.addr6);

            status = WSARecvFrom(

                sock->sd,

                wsabuf,

                1,

                &sock->reads.size,

                &sock->reads.flags,

                (struct sockaddr *) &sock->reads.addr,

                &sock->reads.addrlen,

                &sock->reads.overlapped,

                NULL);

        }

        else if (proto_is_tcp(sock->info.proto))

        {

            sock->reads.addr_defined = false;

            status = WSARecv(

                sock->sd,

                wsabuf,

                1,

                &sock->reads.size,

                &sock->reads.flags,

                &sock->reads.overlapped,

                NULL);

        }

        else

        {

            status = 0;

            ASSERT(0);

        }


        if (!status) /* operation completed immediately? */

        {

            /* FIXME: won't do anything when sock->info.af == AF_UNSPEC */

            int af_len = af_addr_size(sock->info.af);

            if (sock->reads.addr_defined && af_len && sock->reads.addrlen != af_len)

            {

                bad_address_length(sock->reads.addrlen, af_len);

            }

            sock->reads.iostate = IOSTATE_IMMEDIATE_RETURN;


            /* since we got an immediate return, we must signal the event object ourselves */

            ASSERT(SetEvent(sock->reads.overlapped.hEvent));

            sock->reads.status = 0;


            dmsg(D_WIN32_IO, "WIN32 I/O: Socket Receive immediate return [%d,%d]",

                 (int) wsabuf[0].len,

                 (int) sock->reads.size);

        }

        else

        {

            status = socket_get_last_error(sock);

            if (status == WSA_IO_PENDING) /* operation queued? */

            {

                sock->reads.iostate = IOSTATE_QUEUED;

                sock->reads.status = status;

                dmsg(D_WIN32_IO, "WIN32 I/O: Socket Receive queued [%d]",

                     (int) wsabuf[0].len);

            }

            else /* error occurred */

            {

                struct gc_arena gc = gc_new();

                ASSERT(SetEvent(sock->reads.overlapped.hEvent));

                sock->reads.iostate = IOSTATE_IMMEDIATE_RETURN;

                sock->reads.status = status;

                dmsg(D_WIN32_IO, "WIN32 I/O: Socket Receive error [%d]: %s",

                     (int) wsabuf[0].len,

                     strerror_win32(status, &gc));

                gc_free(&gc);

            }

        }

    }

    return sock->reads.iostate;

}


int


socket_send_queue(struct link_socket *sock, struct buffer *buf, const struct link_socket_actual *to)

{

    if (sock->writes.iostate == IOSTATE_INITIAL)

    {

        WSABUF wsabuf[1];

        int status;


        /* make a private copy of buf */

        sock->writes.buf = sock->writes.buf_init;

        sock->writes.buf.len = 0;

        ASSERT(buf_copy(&sock->writes.buf, buf));


        /* Win32 docs say it's okay to allocate the wsabuf on the stack */

        wsabuf[0].buf = BSTR(&sock->writes.buf);

        wsabuf[0].len = BLEN(&sock->writes.buf);


        /* the overlapped write will signal this event on I/O completion */

        ASSERT(ResetEvent(sock->writes.overlapped.hEvent));

        sock->writes.flags = 0;


        if (socket_is_dco_win(sock))

        {

            status = WriteFile((HANDLE)sock->sd, wsabuf[0].buf, wsabuf[0].len,

                               &sock->writes.size, &sock->writes.overlapped);


            /* WriteFile status is inverted from WSASendTo */

            status = !status;


        }

        else if (proto_is_udp(sock->info.proto))

        {

            /* set destination address for UDP writes */

            sock->writes.addr_defined = true;

            if (to->dest.addr.sa.sa_family == AF_INET6)

            {

                sock->writes.addr6 = to->dest.addr.in6;

                sock->writes.addrlen = sizeof(sock->writes.addr6);

            }

            else

            {

                sock->writes.addr = to->dest.addr.in4;

                sock->writes.addrlen = sizeof(sock->writes.addr);

            }


            status = WSASendTo(

                sock->sd,

                wsabuf,

                1,

                &sock->writes.size,

                sock->writes.flags,

                (struct sockaddr *) &sock->writes.addr,

                sock->writes.addrlen,

                &sock->writes.overlapped,

                NULL);

        }

        else if (proto_is_tcp(sock->info.proto))

        {

            /* destination address for TCP writes was established on connection initiation */

            sock->writes.addr_defined = false;


            status = WSASend(

                sock->sd,

                wsabuf,

                1,

                &sock->writes.size,

                sock->writes.flags,

                &sock->writes.overlapped,

                NULL);

        }

        else

        {

            status = 0;

            ASSERT(0);

        }


        if (!status) /* operation completed immediately? */

        {

            sock->writes.iostate = IOSTATE_IMMEDIATE_RETURN;


            /* since we got an immediate return, we must signal the event object ourselves */

            ASSERT(SetEvent(sock->writes.overlapped.hEvent));


            sock->writes.status = 0;


            dmsg(D_WIN32_IO, "WIN32 I/O: Socket Send immediate return [%d,%d]",

                 (int) wsabuf[0].len,

                 (int) sock->writes.size);

        }

        else

        {

            status = socket_get_last_error(sock);

            /* both status code have the identical value */

            if (status == WSA_IO_PENDING || status == ERROR_IO_PENDING) /* operation queued? */

            {

                sock->writes.iostate = IOSTATE_QUEUED;

                sock->writes.status = status;

                dmsg(D_WIN32_IO, "WIN32 I/O: Socket Send queued [%d]",

                     (int) wsabuf[0].len);

            }

            else /* error occurred */

            {

                struct gc_arena gc = gc_new();

                ASSERT(SetEvent(sock->writes.overlapped.hEvent));

                sock->writes.iostate = IOSTATE_IMMEDIATE_RETURN;

                sock->writes.status = status;


                dmsg(D_WIN32_IO, "WIN32 I/O: Socket Send error [%d]: %s",

                     (int) wsabuf[0].len,

                     strerror_win32(status, &gc));


                gc_free(&gc);

            }

        }

    }

    return sock->writes.iostate;

}


void


read_sockaddr_from_overlapped(struct overlapped_io *io, struct sockaddr *dst, int overlapped_ret)

{

    if (overlapped_ret >= 0 && io->addr_defined)

    {

        /* TODO(jjo): streamline this mess */

        /* in this func we don't have relevant info about the PF_ of this

         * endpoint, as link_socket_actual will be zero for the 1st received packet

         *

         * Test for inets PF_ possible sizes

         */

        switch (io->addrlen)

        {

            case sizeof(struct sockaddr_in):

            case sizeof(struct sockaddr_in6):

            /* TODO(jjo): for some reason (?) I'm getting 24,28 for AF_INET6

             * under _WIN32*/

            case sizeof(struct sockaddr_in6) - 4:

                break;


            default:

                bad_address_length(io->addrlen, af_addr_size(io->addr.sin_family));

        }


        switch (io->addr.sin_family)

        {

            case AF_INET:

                memcpy(dst, &io->addr, sizeof(struct sockaddr_in));

                break;


            case AF_INET6:

                memcpy(dst, &io->addr6, sizeof(struct sockaddr_in6));

                break;

        }

    }

    else

    {

        CLEAR(*dst);

    }

}


static int


read_sockaddr_from_packet(struct buffer *buf, struct sockaddr *dst)

{

    int sa_len = 0;


    const struct sockaddr *sa = (const struct sockaddr *)BPTR(buf);

    switch (sa->sa_family)

    {

        case AF_INET:

            sa_len = sizeof(struct sockaddr_in);

            if (buf_len(buf) < sa_len)

            {

                msg(M_FATAL, "ERROR: received incoming packet with too short length of %d -- must be at least %d.", buf_len(buf), sa_len);

            }

            memcpy(dst, sa, sa_len);

            buf_advance(buf, sa_len);

            break;


        case AF_INET6:

            sa_len = sizeof(struct sockaddr_in6);

            if (buf_len(buf) < sa_len)

            {

                msg(M_FATAL, "ERROR: received incoming packet with too short length of %d -- must be at least %d.", buf_len(buf), sa_len);

            }

            memcpy(dst, sa, sa_len);

            buf_advance(buf, sa_len);

            break;


        default:

            msg(M_FATAL, "ERROR: received incoming packet with invalid address family %d.", sa->sa_family);

    }


    return sa_len;

}


/* Returns the number of bytes successfully read */

int


sockethandle_finalize(sockethandle_t sh,

                      struct overlapped_io *io,

                      struct buffer *buf,

                      struct link_socket_actual *from)

{

    int ret = -1;

    BOOL status;


    switch (io->iostate)

    {

        case IOSTATE_QUEUED:

            status = SocketHandleGetOverlappedResult(sh, io);

            if (status)

            {

                /* successful return for a queued operation */

                if (buf)

                {

                    *buf = io->buf;

                }

                ret = io->size;

                io->iostate = IOSTATE_INITIAL;

                ASSERT(ResetEvent(io->overlapped.hEvent));


                dmsg(D_WIN32_IO, "WIN32 I/O: Completion success [%d]", ret);

            }

            else

            {

                /* error during a queued operation */

                ret = -1;

                if (SocketHandleGetLastError(sh) != ERROR_IO_INCOMPLETE)

                {

                    /* if no error (i.e. just not finished yet), then DON'T execute this code */

                    io->iostate = IOSTATE_INITIAL;

                    ASSERT(ResetEvent(io->overlapped.hEvent));

                    msg(D_WIN32_IO | M_ERRNO, "WIN32 I/O: Completion error");

                }

            }

            break;


        case IOSTATE_IMMEDIATE_RETURN:

            io->iostate = IOSTATE_INITIAL;

            ASSERT(ResetEvent(io->overlapped.hEvent));

            if (io->status)

            {

                /* error return for a non-queued operation */

                SocketHandleSetLastError(sh, io->status);

                ret = -1;

                msg(D_WIN32_IO | M_ERRNO, "WIN32 I/O: Completion non-queued error");

            }

            else

            {

                /* successful return for a non-queued operation */

                if (buf)

                {

                    *buf = io->buf;

                }

                ret = io->size;

                dmsg(D_WIN32_IO, "WIN32 I/O: Completion non-queued success [%d]", ret);

            }

            break;


        case IOSTATE_INITIAL: /* were we called without proper queueing? */

            SocketHandleSetInvalError(sh);

            ret = -1;

            dmsg(D_WIN32_IO, "WIN32 I/O: Completion BAD STATE");

            break;


        default:

            ASSERT(0);

    }


    if (from && ret > 0 && sh.is_handle && sh.prepend_sa)

    {

        ret -= read_sockaddr_from_packet(buf, &from->dest.addr.sa);

    }


    if (!sh.is_handle && from)

    {

        read_sockaddr_from_overlapped(io, &from->dest.addr.sa, ret);

    }


    if (buf)

    {

        buf->len = ret;

    }

    return ret;

}


#endif /* _WIN32 */


/*

 * Socket event notification

 */


unsigned int


socket_set(struct link_socket *s,

           struct event_set *es,

           unsigned int rwflags,

           void *arg,

           unsigned int *persistent)

{

    if (s)

    {

        if ((rwflags & EVENT_READ) && !stream_buf_read_setup(s))

        {

            ASSERT(!persistent);

            rwflags &= ~EVENT_READ;

        }


#ifdef _WIN32

        if (rwflags & EVENT_READ)

        {

            socket_recv_queue(s, 0);

        }

#endif


        /* if persistent is defined, call event_ctl only if rwflags has changed since last call */

        if (!persistent || *persistent != rwflags)

        {

            event_ctl(es, socket_event_handle(s), rwflags, arg);

            if (persistent)

            {

                *persistent = rwflags;

            }

        }


        s->rwflags_debug = rwflags;

    }

    return rwflags;

}


void


sd_close(socket_descriptor_t *sd)

{

    if (sd && socket_defined(*sd))

    {

        openvpn_close_socket(*sd);

        *sd = SOCKET_UNDEFINED;

    }

}


#if UNIX_SOCK_SUPPORT


/*

 * code for unix domain sockets

 */


const char *

sockaddr_unix_name(const struct sockaddr_un *local, const char *null)

{

    if (local && local->sun_family == PF_UNIX)

    {

        return local->sun_path;

    }

    else

    {

        return null;

    }

}


socket_descriptor_t

create_socket_unix(void)

{

    socket_descriptor_t sd;


    if ((sd = socket(PF_UNIX, SOCK_STREAM, 0)) < 0)

    {

        msg(M_ERR, "Cannot create unix domain socket");

    }


    /* set socket file descriptor to not pass across execs, so that

     * scripts don't have access to it */

    set_cloexec(sd);


    return sd;

}


void

socket_bind_unix(socket_descriptor_t sd,

                 struct sockaddr_un *local,

                 const char *prefix)

{

    struct gc_arena gc = gc_new();

    const mode_t orig_umask = umask(0);


    if (bind(sd, (struct sockaddr *) local, sizeof(struct sockaddr_un)))

    {

        msg(M_FATAL | M_ERRNO,

            "%s: Socket bind[%d] failed on unix domain socket %s",

            prefix,

            (int)sd,

            sockaddr_unix_name(local, "NULL"));

    }


    umask(orig_umask);

    gc_free(&gc);

}


socket_descriptor_t

socket_accept_unix(socket_descriptor_t sd,

                   struct sockaddr_un *remote)

{

    socklen_t remote_len = sizeof(struct sockaddr_un);

    socket_descriptor_t ret;


    CLEAR(*remote);

    ret = accept(sd, (struct sockaddr *) remote, &remote_len);

    if (ret >= 0)

    {

        /* set socket file descriptor to not pass across execs, so that

         * scripts don't have access to it */

        set_cloexec(ret);

    }

    return ret;

}


int

socket_connect_unix(socket_descriptor_t sd,

                    struct sockaddr_un *remote)

{

    int status = connect(sd, (struct sockaddr *) remote, sizeof(struct sockaddr_un));

    if (status)

    {

        status = openvpn_errno();

    }

    return status;

}


void

sockaddr_unix_init(struct sockaddr_un *local, const char *path)

{

    local->sun_family = PF_UNIX;

    strncpynt(local->sun_path, path, sizeof(local->sun_path));

}


void

socket_delete_unix(const struct sockaddr_un *local)

{

    const char *name = sockaddr_unix_name(local, NULL);

    if (name && strlen(name))

    {

        unlink(name);

    }

}


bool

unix_socket_get_peer_uid_gid(const socket_descriptor_t sd, int *uid, int *gid)

{

#ifdef HAVE_GETPEEREID

    uid_t u;

    gid_t g;

    if (getpeereid(sd, &u, &g) == -1)

    {

        return false;

    }

    if (uid)

    {

        *uid = u;

    }

    if (gid)

    {

        *gid = g;

    }

    return true;

#elif defined(SO_PEERCRED)

    struct ucred peercred;

    socklen_t so_len = sizeof(peercred);

    if (getsockopt(sd, SOL_SOCKET, SO_PEERCRED, &peercred, &so_len) == -1)

    {

        return false;

    }

    if (uid)

    {

        *uid = peercred.uid;

    }

    if (gid)

    {

        *gid = peercred.gid;

    }

    return true;

#else  /* ifdef HAVE_GETPEEREID */

    return false;

#endif /* ifdef HAVE_GETPEEREID */

}


#endif /* if UNIX_SOCK_SUPPORT */

argv_parse_cmd
void argv_parse_cmd(struct argv *argres, const char *cmdstr)
Parses a command string, tokenizes it and puts each element into a separate struct argv argument slot...
Definition argv.c:483

argv_free
void argv_free(struct argv *a)
Frees all memory allocations allocated by the struct argv related functions.
Definition argv.c:102

argv_printf
bool argv_printf(struct argv *argres, const char *format,...)
printf() variant which populates a struct argv.
Definition argv.c:440

argv_printf_cat
bool argv_printf_cat(struct argv *argres, const char *format,...)
printf() inspired argv concatenation.
Definition argv.c:464

argv_new
struct argv argv_new(void)
Allocates a new struct argv and ensures it is initialised.
Definition argv.c:88

free_buf
void free_buf(struct buffer *buf)
Definition buffer.c:183

buf_printf
bool buf_printf(struct buffer *buf, const char *format,...)
Definition buffer.c:240

buf_puts
bool buf_puts(struct buffer *buf, const char *str)
Definition buffer.c:267

string_class
bool string_class(const char *str, const unsigned int inclusive, const unsigned int exclusive)
Definition buffer.c:1022

gc_malloc
void * gc_malloc(size_t size, bool clear, struct gc_arena *a)
Definition buffer.c:336

alloc_buf_gc
struct buffer alloc_buf_gc(size_t size, struct gc_arena *gc)
Definition buffer.c:88

alloc_buf
struct buffer alloc_buf(size_t size)
Definition buffer.c:62

gc_addspecial
void gc_addspecial(void *addr, void(*free_function)(void *), struct gc_arena *a)
Definition buffer.c:438

CC_DASH
#define CC_DASH
dash
Definition buffer.h:902

BSTR
#define BSTR(buf)
Definition buffer.h:129

buf_copy
static bool buf_copy(struct buffer *dest, const struct buffer *src)
Definition buffer.h:712

BPTR
#define BPTR(buf)
Definition buffer.h:124

buf_copy_excess
static bool buf_copy_excess(struct buffer *dest, struct buffer *src, int len)
Definition buffer.h:753

buf_write_prepend
static bool buf_write_prepend(struct buffer *dest, const void *src, int size)
Definition buffer.h:680

CC_DIGIT
#define CC_DIGIT
digit isdigit()
Definition buffer.h:890

CC_DOT
#define CC_DOT
dot
Definition buffer.h:903

buf_reset
static void buf_reset(struct buffer *buf)
Definition buffer.h:303

buf_safe
static bool buf_safe(const struct buffer *buf, size_t len)
Definition buffer.h:520

buf_read
static bool buf_read(struct buffer *src, void *dest, int size)
Definition buffer.h:778

buf_advance
static bool buf_advance(struct buffer *buf, int size)
Definition buffer.h:618

buf_len
static int buf_len(const struct buffer *buf)
Definition buffer.h:253

buf_forward_capacity
static int buf_forward_capacity(const struct buffer *buf)
Definition buffer.h:541

ALLOC_OBJ_CLEAR_GC
#define ALLOC_OBJ_CLEAR_GC(dptr, type, gc)
Definition buffer.h:1097

BLEN
#define BLEN(buf)
Definition buffer.h:127

strncpynt
static void strncpynt(char *dest, const char *src, size_t maxlen)
Definition buffer.h:361

gc_free
static void gc_free(struct gc_arena *a)
Definition buffer.h:1033

ALLOC_OBJ_CLEAR
#define ALLOC_OBJ_CLEAR(dptr, type)
Definition buffer.h:1060

buf_defined
static bool buf_defined(const struct buffer *buf)
Definition buffer.h:228

CC_ALNUM
#define CC_ALNUM
alphanumeric isalnum()
Definition buffer.h:886

buf_init
#define buf_init(buf, offset)
Definition buffer.h:209

gc_freeaddrinfo_callback
static void gc_freeaddrinfo_callback(void *addr)
Definition buffer.h:215

gc_new
static struct gc_arena gc_new(void)
Definition buffer.h:1025

buf_forward_capacity_total
static int buf_forward_capacity_total(const struct buffer *buf)
Definition buffer.h:559

config.h

HAVE_IPI_SPEC_DST
#define HAVE_IPI_SPEC_DST
Definition config.h:231

HAVE_IN_PKTINFO
#define HAVE_IN_PKTINFO
Definition config.h:219

dco_mp_start_vpn
void dco_mp_start_vpn(HANDLE handle, struct link_socket *sock)
Initializes and binds the kernel UDP transport socket for multipeer mode.
Definition dco_win.c:280

dco_p2p_new_peer
void dco_p2p_new_peer(HANDLE handle, OVERLAPPED *ov, struct link_socket *sock, struct signal_info *sig_info)
Definition dco_win.c:324

setenv_int
void setenv_int(struct env_set *es, const char *name, int value)
Definition env_set.c:292

setenv_str
void setenv_str(struct env_set *es, const char *name, const char *value)
Definition env_set.c:308

D_WIN32_IO
#define D_WIN32_IO
Definition errlevel.h:173

D_STREAM_ERRORS
#define D_STREAM_ERRORS
Definition errlevel.h:63

D_SOCKET_DEBUG
#define D_SOCKET_DEBUG
Definition errlevel.h:140

D_STREAM_DEBUG
#define D_STREAM_DEBUG
Definition errlevel.h:172

D_INIT_MEDIUM
#define D_INIT_MEDIUM
Definition errlevel.h:104

D_READ_WRITE
#define D_READ_WRITE
Definition errlevel.h:167

D_OSBUF
#define D_OSBUF
Definition errlevel.h:91

D_RESOLVE_ERRORS
#define D_RESOLVE_ERRORS
Definition errlevel.h:60

D_LOW
#define D_LOW
Definition errlevel.h:97

M_INFO
#define M_INFO
Definition errlevel.h:55

D_LINK_ERRORS
#define D_LINK_ERRORS
Definition errlevel.h:57

EVENT_WRITE
#define EVENT_WRITE
Definition event.h:40

EVENT_READ
#define EVENT_READ
Definition event.h:39

EVENT_ARG_LINK_SOCKET
@ EVENT_ARG_LINK_SOCKET
Definition event.h:137

event_ctl
static void event_ctl(struct event_set *es, event_t event, unsigned int rwflags, void *arg)
Definition event.h:181

set_nonblock
void set_nonblock(socket_descriptor_t fd)
Definition fdmisc.c:69

set_cloexec
void set_cloexec(socket_descriptor_t fd)
Definition fdmisc.c:79

fdmisc.h

openvpn_fd_set
static void openvpn_fd_set(socket_descriptor_t fd, fd_set *setp)
Definition fdmisc.h:40

get_server_poll_remaining_time
int get_server_poll_remaining_time(struct event_timeout *server_poll_timeout)
Definition forward.c:509

forward.h
Interface functions to the internal and external multiplexers.

gremlin.h

status
static SERVICE_STATUS status
Definition interactive.c:52

management_set_state
void management_set_state(struct management *man, const int state, const char *detail, const in_addr_t *tun_local_ip, const struct in6_addr *tun_local_ip6, const struct openvpn_sockaddr *local, const struct openvpn_sockaddr *remote)
Definition manage.c:2750

management_sleep
void management_sleep(const int n)
A sleep function that services the management layer for n seconds rather than doing nothing.
Definition manage.c:4121

manage.h

OPENVPN_STATE_RESOLVE
#define OPENVPN_STATE_RESOLVE
Definition manage.h:481

OPENVPN_STATE_TCP_CONNECT
#define OPENVPN_STATE_TCP_CONNECT
Definition manage.h:482

memdbg.h

hostname_randomize
const char * hostname_randomize(const char *hostname, struct gc_arena *gc)
Definition misc.c:82

misc.h

alloc_buf_sock_tun
void alloc_buf_sock_tun(struct buffer *buf, const struct frame *frame)
Definition mtu.c:42

set_mtu_discover_type
void set_mtu_discover_type(socket_descriptor_t sd, int mtu_type, sa_family_t proto_af)
Definition mtu.c:225

OPENVPN_PLUGIN_IPCHANGE
#define OPENVPN_PLUGIN_IPCHANGE
Definition openvpn-plugin.h:120

OPENVPN_PLUGIN_FUNC_SUCCESS
#define OPENVPN_PLUGIN_FUNC_SUCCESS
Definition openvpn-plugin.h:148

CLEAR
#define CLEAR(x)
Definition basic.h:33

SIZE
#define SIZE(x)
Definition basic.h:30

strerror_win32
const char * strerror_win32(DWORD errnum, struct gc_arena *gc)
Definition error.c:812

M_FATAL
#define M_FATAL
Definition error.h:89

M_NONFATAL
#define M_NONFATAL
Definition error.h:90

dmsg
#define dmsg(flags,...)
Definition error.h:148

M_ERR
#define M_ERR
Definition error.h:105

openvpn_errno
#define openvpn_errno()
Definition error.h:72

msg
#define msg(flags,...)
Definition error.h:144

ASSERT
#define ASSERT(x)
Definition error.h:195

M_WARN
#define M_WARN
Definition error.h:91

M_MSG_VIRT_OUT
#define M_MSG_VIRT_OUT
Definition error.h:99

M_ERRNO
#define M_ERRNO
Definition error.h:94

openvpn.h

CM_CHILD_TCP
#define CM_CHILD_TCP
Definition openvpn.h:488

CM_CHILD_UDP
#define CM_CHILD_UDP
Definition openvpn.h:487

MODE_POINT_TO_POINT
#define MODE_POINT_TO_POINT
Definition options.h:258

MODE_SERVER
#define MODE_SERVER
Definition options.h:259

streq
#define streq(x, y)
Definition options.h:724

dco_enabled
static bool dco_enabled(const struct options *o)
Returns whether the current configuration has dco enabled.
Definition options.h:926

plugin_defined
bool plugin_defined(const struct plugin_list *pl, const int type)
Definition plugin.c:932

plugin.h

plugin_call
static int plugin_call(const struct plugin_list *pl, const int type, const struct argv *av, struct plugin_return *pr, struct env_set *es)
Definition plugin.h:202

establish_http_proxy_passthru
bool establish_http_proxy_passthru(struct http_proxy_info *p, socket_descriptor_t sd, const char *host, const char *port, struct event_timeout *server_poll_timeout, struct buffer *lookahead, struct signal_info *sig_info)
Definition proxy.c:644

ps.h

run_command.h

openvpn_run_script
static int openvpn_run_script(const struct argv *a, const struct env_set *es, const unsigned int flags, const char *hook)
Will run a script and return the exit code of the script if between 0 and 255, -1 otherwise.
Definition run_command.h:87

throw_signal_soft
void throw_signal_soft(const int signum, const char *signal_text)
Throw a soft global signal.
Definition sig.c:206

signal_reset
int signal_reset(struct signal_info *si, int signum)
Clear the signal if its current value equals signum.
Definition sig.c:266

throw_signal
void throw_signal(const int signum)
Throw a hard signal.
Definition sig.c:177

siginfo_static
struct signal_info siginfo_static
Definition sig.c:45

register_signal
void register_signal(struct signal_info *si, int signum, const char *signal_text)
Register a soft signal in the signal_info struct si respecting priority.
Definition sig.c:231

SIG_SOURCE_HARD
#define SIG_SOURCE_HARD
Definition sig.h:31

get_signal
static void get_signal(volatile int *sig)
Copy the global signal_received (if non-zero) to the passed-in argument sig.
Definition sig.h:110

link_socket_init_phase1
void link_socket_init_phase1(struct context *c, int sock_index, int mode)
Definition socket.c:1904

resolve_bind_local
static void resolve_bind_local(struct link_socket *sock, const sa_family_t af)
Definition socket.c:1707

socket_get_sndbuf
static int socket_get_sndbuf(socket_descriptor_t sd)
Definition socket.c:887

socket_set_sndbuf
static void socket_set_sndbuf(socket_descriptor_t sd, int size)
Definition socket.c:904

socket_listen_accept
static socket_descriptor_t socket_listen_accept(socket_descriptor_t sd, struct link_socket_actual *act, const char *remote_dynamic, const struct addrinfo *local, bool do_listen, bool nowait, volatile int *signal_received)
Definition socket.c:1341

dns_addr_safe
static bool dns_addr_safe(const char *addr)
Definition socket.c:809

link_socket_init_phase2
void link_socket_init_phase2(struct context *c, struct link_socket *sock)
Definition socket.c:2277

socket_send_queue
int socket_send_queue(struct link_socket *sock, struct buffer *buf, const struct link_socket_actual *to)
Definition socket.c:3730

ipchange_fmt
static void ipchange_fmt(const bool include_cmd, struct argv *argv, const struct link_socket_info *info, struct gc_arena *gc)
Definition socket.c:2458

proto2ascii
const char * proto2ascii(int proto, sa_family_t af, bool display_form)
Definition socket.c:3225

socket_get_last_error
static int socket_get_last_error(const struct link_socket *sock)
Definition socket.c:3602

get_ipv6_addr
bool get_ipv6_addr(const char *hostname, struct in6_addr *network, unsigned int *netbits, int msglevel)
Translate an IPv6 addr or hostname from string form to in6_addr.
Definition socket.c:226

link_socket_write_tcp
ssize_t link_socket_write_tcp(struct link_socket *sock, struct buffer *buf, struct link_socket_actual *to)
Definition socket.c:3500

link_socket_update_buffer_sizes
void link_socket_update_buffer_sizes(struct link_socket *sock, int rcvbuf, int sndbuf)
Definition socket.c:1037

create_socket_udp
static socket_descriptor_t create_socket_udp(struct addrinfo *addrinfo, const unsigned int flags)
Definition socket.c:1085

phase2_tcp_server
static void phase2_tcp_server(struct link_socket *sock, const char *remote_dynamic, struct signal_info *sig_info)
Definition socket.c:2101

create_socket
static void create_socket(struct link_socket *sock, struct addrinfo *addr)
Definition socket.c:1160

link_socket_current_remote_ipv6
const struct in6_addr * link_socket_current_remote_ipv6(const struct link_socket_info *info)
Definition socket.c:2595

set_actual_address
void set_actual_address(struct link_socket_actual *actual, struct addrinfo *ai)
Definition socket.c:1583

openvpn_getaddrinfo
int openvpn_getaddrinfo(unsigned int flags, const char *hostname, const char *servname, int resolve_retry_seconds, struct signal_info *sig_info, int ai_family, struct addrinfo **res)
Definition socket.c:469

socket_set_rcvbuf
static bool socket_set_rcvbuf(socket_descriptor_t sd, int size)
Definition socket.c:932

stream_buf_set_next
static void stream_buf_set_next(struct stream_buf *sb)
Definition socket.c:2696

socket_stat
const char * socket_stat(const struct link_socket *s, unsigned int rwflags, struct gc_arena *gc)
Definition socket.c:2628

bad_address_length
void bad_address_length(int actual, int expected)
Definition socket.c:3314

mac_addr_safe
bool mac_addr_safe(const char *mac_addr)
Definition socket.c:840

setenv_in_addr_t
void setenv_in_addr_t(struct env_set *es, const char *name_prefix, in_addr_t addr, const unsigned int flags)
Definition socket.c:3130

print_sockaddr_ex
const char * print_sockaddr_ex(const struct sockaddr *sa, const char *separator, const unsigned int flags, struct gc_arena *gc)
Definition socket.c:2845

stream_buf_added
static bool stream_buf_added(struct stream_buf *sb, int length_added)
Definition socket.c:2749

socket_listen_event_handle
event_t socket_listen_event_handle(struct link_socket *s)
Definition socket.c:2827

sd_close
void sd_close(socket_descriptor_t *sd)
Definition socket.c:4066

print_in_port_t
const char * print_in_port_t(in_port_t port, struct gc_arena *gc)
Definition socket.c:3043

get_addr_generic
static int get_addr_generic(sa_family_t af, unsigned int flags, const char *hostname, void *network, unsigned int *netbits, int resolve_retry_seconds, struct signal_info *sig_info, int msglevel)
Definition socket.c:81

linksock_print_addr
static void linksock_print_addr(struct link_socket *sock)
Definition socket.c:2059

proto2ascii_all
const char * proto2ascii_all(struct gc_arena *gc)
Definition socket.c:3246

setenv_link_socket_actual
void setenv_link_socket_actual(struct env_set *es, const char *name_prefix, const struct link_socket_actual *act, const unsigned int flags)
Definition socket.c:3159

socket_set_mark
static void socket_set_mark(socket_descriptor_t sd, int mark)
Definition socket.c:998

setenv_in6_addr
void setenv_in6_addr(struct env_set *es, const char *name_prefix, const struct in6_addr *addr, const unsigned int flags)
Definition socket.c:3143

stream_buf_close
static void stream_buf_close(struct stream_buf *sb)
Definition socket.c:2816

print_link_socket_actual
const char * print_link_socket_actual(const struct link_socket_actual *act, struct gc_arena *gc)
Definition socket.c:2926

stream_buf_get_final
static void stream_buf_get_final(struct stream_buf *sb, struct buffer *buf)
Definition socket.c:2711

socket_connect
static void socket_connect(socket_descriptor_t *sd, const struct sockaddr *dest, const int connect_timeout, struct signal_info *sig_info)
Definition socket.c:1606

bind_local
static void bind_local(struct link_socket *sock, const sa_family_t ai_family)
Definition socket.c:1140

stream_buf_read_setup_dowork
bool stream_buf_read_setup_dowork(struct link_socket *sock)
Definition socket.c:2729

phase2_socks_client
static void phase2_socks_client(struct link_socket *sock, struct signal_info *sig_info)
Definition socket.c:2189

socket_set_tcp_nodelay
static bool socket_set_tcp_nodelay(socket_descriptor_t sd, int state)
Definition socket.c:978

socket_do_accept
socket_descriptor_t socket_do_accept(socket_descriptor_t sd, struct link_socket_actual *act, const bool nowait)
Definition socket.c:1268

socket_do_listen
static void socket_do_listen(socket_descriptor_t sd, const struct addrinfo *local, bool do_listen, bool do_set_nonblock)
Definition socket.c:1241

setenv_sockaddr
void setenv_sockaddr(struct env_set *es, const char *name_prefix, const struct openvpn_sockaddr *addr, const unsigned int flags)
Definition socket.c:3077

socket_recv_queue
int socket_recv_queue(struct link_socket *sock, int maxsize)
Definition socket.c:3613

link_socket_close
void link_socket_close(struct link_socket *sock)
Definition socket.c:2400

link_socket_connection_initiated
void link_socket_connection_initiated(struct link_socket_info *info, const struct link_socket_actual *act, const char *common_name, struct env_set *es)
Definition socket.c:2474

print_link_socket_actual_ex
const char * print_link_socket_actual_ex(const struct link_socket_actual *act, const char *separator, const unsigned int flags, struct gc_arena *gc)
Definition socket.c:2936

socket_set_buffers
void socket_set_buffers(socket_descriptor_t fd, const struct socket_buffer_size *sbs, bool reduce_size)
Sets the receive and send buffer sizes of a socket descriptor.
Definition socket.c:945

add_in6_addr
struct in6_addr add_in6_addr(struct in6_addr base, uint32_t add)
Definition socket.c:3054

streqnull
static bool streqnull(const char *a, const char *b)
Definition socket.c:239

phase2_set_socket_flags
static void phase2_set_socket_flags(struct link_socket *sock)
Definition socket.c:2040

resolve_remote
static void resolve_remote(struct link_socket *sock, int phase, const char **remote_dynamic, struct signal_info *sig_info)
Definition socket.c:1763

ascii2af
sa_family_t ascii2af(const char *proto_name)
Definition socket.c:3212

do_preresolve_host
static int do_preresolve_host(struct context *c, const char *hostname, const char *servname, const int af, const int flags)
Definition socket.c:289

link_socket_bad_outgoing_addr
void link_socket_bad_outgoing_addr(void)
Definition socket.c:2554

sockethandle_finalize
int sockethandle_finalize(sockethandle_t sh, struct overlapped_io *io, struct buffer *buf, struct link_socket_actual *from)
Definition socket.c:3934

link_socket_current_remote
in_addr_t link_socket_current_remote(const struct link_socket_info *info)
Definition socket.c:2560

openvpn_inet_aton
int openvpn_inet_aton(const char *dotted_quad, struct in_addr *addr)
Definition socket.c:713

socket_get_rcvbuf
static int socket_get_rcvbuf(socket_descriptor_t sd)
Definition socket.c:915

link_socket_read_tcp
int link_socket_read_tcp(struct link_socket *sock, struct buffer *buf)
Definition socket.c:3326

openvpn_connect
int openvpn_connect(socket_descriptor_t sd, const struct sockaddr *remote, int connect_timeout, volatile int *signal_received)
Definition socket.c:1488

socket_set
unsigned int socket_set(struct link_socket *s, struct event_set *es, unsigned int rwflags, void *arg, unsigned int *persistent)
Definition socket.c:4029

proto_remote
const char * proto_remote(int proto, bool remote)
Definition socket.c:3286

sf2gaf
static unsigned int sf2gaf(const unsigned int getaddr_flags, const unsigned int sockflags)
Definition socket.c:64

get_cached_dns_entry
static int get_cached_dns_entry(struct cached_dns_entry *dns_cache, const char *hostname, const char *servname, int ai_family, int resolve_flags, struct addrinfo **ai)
Definition socket.c:260

ipv6_addr_safe
bool ipv6_addr_safe(const char *ipv6_text_addr)
Definition socket.c:787

print_in6_addr
const char * print_in6_addr(struct in6_addr a6, unsigned int flags, struct gc_arena *gc)
Definition socket.c:3027

do_preresolve
void do_preresolve(struct context *c)
Definition socket.c:343

ip_or_dns_addr_safe
bool ip_or_dns_addr_safe(const char *addr, const bool allow_fqdn)
Definition socket.c:823

link_socket_bad_incoming_addr
void link_socket_bad_incoming_addr(struct buffer *buf, const struct link_socket_info *info, const struct link_socket_actual *from_addr)
Definition socket.c:2525

phase2_tcp_client
static void phase2_tcp_client(struct link_socket *sock, struct signal_info *sig_info)
Definition socket.c:2144

socket_bind
void socket_bind(socket_descriptor_t sd, struct addrinfo *local, int ai_family, const char *prefix, bool ipv6only)
Definition socket.c:1434

ascii2proto
int ascii2proto(const char *proto_name)
Definition socket.c:3199

create_socket_tcp
socket_descriptor_t create_socket_tcp(struct addrinfo *addrinfo)
Definition socket.c:1053

socket_frame_init
static void socket_frame_init(const struct frame *frame, struct link_socket *sock)
Definition socket.c:1679

print_in_addr_t
const char * print_in_addr_t(in_addr_t addr, unsigned int flags, struct gc_arena *gc)
Definition socket.c:3007

stream_buf_reset
static void stream_buf_reset(struct stream_buf *sb)
Definition socket.c:2665

stream_buf_get_next
static void stream_buf_get_next(struct stream_buf *sb, struct buffer *buf)
Definition socket.c:2720

create_socket_dco_win
static void create_socket_dco_win(struct context *c, struct link_socket *sock, struct signal_info *sig_info)
Definition socket.c:2228

tcp_connection_established
static void tcp_connection_established(const struct link_socket_actual *act)
Definition socket.c:1332

socket_set_flags
static bool socket_set_flags(socket_descriptor_t sd, unsigned int sockflags)
Definition socket.c:1009

link_socket_new
struct link_socket * link_socket_new(void)
Definition socket.c:1890

getaddrinfo_addr_family_name
static const char * getaddrinfo_addr_family_name(int af)
Small helper function for openvpn_getaddrinfo to print the address family when resolving fails.
Definition socket.c:453

read_sockaddr_from_packet
static int read_sockaddr_from_packet(struct buffer *buf, struct sockaddr *dst)
Extracts a sockaddr from a packet payload.
Definition socket.c:3898

sockets_read_residual
bool sockets_read_residual(const struct context *c)
Definition socket.c:46

getaddr
in_addr_t getaddr(unsigned int flags, const char *hostname, int resolve_retry_seconds, bool *succeeded, struct signal_info *sig_info)
Translate an IPv4 addr or hostname from string form to in_addr_t.
Definition socket.c:195

setenv_trusted
void setenv_trusted(struct env_set *es, const struct link_socket_info *info)
Definition socket.c:2452

IF_NAMESIZE
#define IF_NAMESIZE
Definition socket.c:2932

addr_family_name
const char * addr_family_name(int af)
Definition socket.c:3262

read_sockaddr_from_overlapped
void read_sockaddr_from_overlapped(struct overlapped_io *io, struct sockaddr *dst, int overlapped_ret)
Definition socket.c:3848

link_socket_update_flags
bool link_socket_update_flags(struct link_socket *sock, unsigned int sockflags)
Definition socket.c:1023

ip_addr_dotted_quad_safe
bool ip_addr_dotted_quad_safe(const char *dotted_quad)
Definition socket.c:737

stream_buf_init
static void stream_buf_init(struct stream_buf *sb, struct buffer *buf, const unsigned int sockflags, const int proto)
Definition socket.c:2675

socket.h

IA_EMPTY_IF_UNDEF
#define IA_EMPTY_IF_UNDEF
Definition socket.h:401

OIA_HOSTNAME
#define OIA_HOSTNAME
Definition socket.h:469

socket_event_handle
static event_t socket_event_handle(const struct link_socket *sock)
Definition socket.h:1259

IPV4_INVALID_ADDR
#define IPV4_INVALID_ADDR
Definition socket.h:438

print_sockaddr
static const char * print_sockaddr(const struct sockaddr *addr, struct gc_arena *gc)
Definition socket.h:384

SocketHandleGetOverlappedResult
static BOOL SocketHandleGetOverlappedResult(sockethandle_t sh, struct overlapped_io *io)
Definition socket.h:300

GETADDR_CACHE_MASK
#define GETADDR_CACHE_MASK
Definition socket.h:530

link_socket_actual_defined
static bool link_socket_actual_defined(const struct link_socket_actual *act)
Definition socket.h:726

LS_MODE_TCP_ACCEPT_FROM
#define LS_MODE_TCP_ACCEPT_FROM
Definition socket.h:211

GETADDR_MSG_VIRT_OUT
#define GETADDR_MSG_VIRT_OUT
Definition socket.h:523

GETADDR_TRY_ONCE
#define GETADDR_TRY_ONCE
Definition socket.h:524

SA_IP_PORT
#define SA_IP_PORT
Definition socket.h:411

GETADDR_PASSIVE
#define GETADDR_PASSIVE
Definition socket.h:527

proto_is_udp
static bool proto_is_udp(int proto)
Returns if the protocol being used is UDP.
Definition socket.h:586

GETADDR_FATAL
#define GETADDR_FATAL
Definition socket.h:518

GETADDR_UPDATE_MANAGEMENT_STATE
#define GETADDR_UPDATE_MANAGEMENT_STATE
Definition socket.h:525

SF_DCO_WIN
#define SF_DCO_WIN
Definition socket.h:226

link_socket_connection_oriented
static bool link_socket_connection_oriented(const struct link_socket *sock)
Definition socket.h:648

addr_local
static bool addr_local(const struct sockaddr *addr)
Definition socket.h:678

stream_buf_read_setup
static bool stream_buf_read_setup(struct link_socket *sock)
Definition socket.h:1009

PS_SHOW_PORT
#define PS_SHOW_PORT
Definition socket.h:364

PROTO_NONE
@ PROTO_NONE
Definition socket.h:567

PROTO_UDP
@ PROTO_UDP
Definition socket.h:568

PROTO_TCP
@ PROTO_TCP
Definition socket.h:569

PROTO_TCP_CLIENT
@ PROTO_TCP_CLIENT
Definition socket.h:571

PROTO_N
@ PROTO_N
Definition socket.h:572

PROTO_TCP_SERVER
@ PROTO_TCP_SERVER
Definition socket.h:570

PS_DONT_SHOW_ADDR
#define PS_DONT_SHOW_ADDR
Definition socket.h:366

GETADDR_HOST_ORDER
#define GETADDR_HOST_ORDER
Definition socket.h:519

SocketHandleSetLastError
static void SocketHandleSetLastError(sockethandle_t sh, DWORD err)
Definition socket.h:314

OIA_ERROR
#define OIA_ERROR
Definition socket.h:471

SocketHandleGetLastError
static int SocketHandleGetLastError(sockethandle_t sh)
Definition socket.h:308

SocketHandleSetInvalError
static void SocketHandleSetInvalError(sockethandle_t sh)
Definition socket.h:320

PS_SHOW_PORT_IF_DEFINED
#define PS_SHOW_PORT_IF_DEFINED
Definition socket.h:363

SF_TCP_NODELAY
#define SF_TCP_NODELAY
Definition socket.h:222

GETADDR_RANDOMIZE
#define GETADDR_RANDOMIZE
Definition socket.h:526

RESOLV_RETRY_INFINITE
#define RESOLV_RETRY_INFINITE
Definition socket.h:48

GETADDR_DATAGRAM
#define GETADDR_DATAGRAM
Definition socket.h:528

proto_is_tcp
static bool proto_is_tcp(int proto)
returns if the proto is a TCP variant (tcp-server, tcp-client or tcp)
Definition socket.h:606

GETADDR_FATAL_ON_SIGNAL
#define GETADDR_FATAL_ON_SIGNAL
Definition socket.h:521

addr_zero_host
static void addr_zero_host(struct openvpn_sockaddr *addr)
Definition socket.h:849

addr_defined_ipi
static bool addr_defined_ipi(const struct link_socket_actual *lsa)
Definition socket.h:699

SF_USE_IP_PKTINFO
#define SF_USE_IP_PKTINFO
Definition socket.h:221

LS_MODE_DEFAULT
#define LS_MODE_DEFAULT
Definition socket.h:209

OIA_IP
#define OIA_IP
Definition socket.h:470

MSG_NOSIGNAL
#define MSG_NOSIGNAL
Definition socket.h:272

proto_is_dgram
static bool proto_is_dgram(int proto)
Return if the protocol is datagram (UDP)
Definition socket.h:597

packet_size_type
uint16_t packet_size_type
Definition socket.h:56

socket_is_dco_win
static bool socket_is_dco_win(const struct link_socket *s)
Returns true if we are on Windows and this link is running on DCO-WIN.
Definition socket.h:1027

af_addr_size
static int af_addr_size(sa_family_t af)
Definition socket.h:864

SF_HOST_RANDOMIZE
#define SF_HOST_RANDOMIZE
Definition socket.h:224

SF_GETADDRINFO_DGRAM
#define SF_GETADDRINFO_DGRAM
Definition socket.h:225

LS_MODE_TCP_LISTEN
#define LS_MODE_TCP_LISTEN
Definition socket.h:210

SF_PORT_SHARE
#define SF_PORT_SHARE
Definition socket.h:223

GETADDR_RESOLVE
#define GETADDR_RESOLVE
Definition socket.h:517

ntohps
#define ntohps(x)
Definition socket.h:62

PS_DONT_SHOW_FAMILY
#define PS_DONT_SHOW_FAMILY
Definition socket.h:367

link_socket_write_win32
static int link_socket_write_win32(struct link_socket *sock, struct buffer *buf, struct link_socket_actual *to)
Definition socket.h:1107

IA_NET_ORDER
#define IA_NET_ORDER
Definition socket.h:402

SA_SET_IF_NONZERO
#define SA_SET_IF_NONZERO
Definition socket.h:412

openvpn_close_socket
#define openvpn_close_socket(s)
Definition socket.h:277

GETADDR_MENTION_RESOLVE_RETRY
#define GETADDR_MENTION_RESOLVE_RETRY
Definition socket.h:520

htonps
#define htonps(x)
Definition socket.h:59

GETADDR_WARN_ON_SIGNAL
#define GETADDR_WARN_ON_SIGNAL
Definition socket.h:522

addrlist_match
static bool addrlist_match(const struct openvpn_sockaddr *a1, const struct addrinfo *addrlist)
Definition socket.h:747

PS_SHOW_PKTINFO
#define PS_SHOW_PKTINFO
Definition socket.h:365

establish_socks_proxy_passthru
void establish_socks_proxy_passthru(struct socks_proxy_info *p, socket_descriptor_t sd, const char *host, const char *servname, struct event_timeout *server_poll_timeout, struct signal_info *sig_info)
Definition socks.c:455

establish_socks_proxy_udpassoc
void establish_socks_proxy_udpassoc(struct socks_proxy_info *p, socket_descriptor_t ctrl_sd, struct openvpn_sockaddr *relay_addr, struct event_timeout *server_poll_timeout, struct signal_info *sig_info)
Definition socks.c:517

argv
Definition argv.h:35

buffer
Wrapper structure for dynamically allocated memory.
Definition buffer.h:61

buffer::len
int len
Length in bytes of the actual content within the allocated memory.
Definition buffer.h:66

buffer::offset
int offset
Offset in bytes of the actual content within the allocated memory.
Definition buffer.h:64

cached_dns_entry
Definition socket.h:76

cached_dns_entry::hostname
const char * hostname
Definition socket.h:77

cached_dns_entry::ai_family
int ai_family
Definition socket.h:79

cached_dns_entry::servname
const char * servname
Definition socket.h:78

cached_dns_entry::flags
int flags
Definition socket.h:80

cached_dns_entry::ai
struct addrinfo * ai
Definition socket.h:81

cached_dns_entry::next
struct cached_dns_entry * next
Definition socket.h:82

connection_entry
Definition options.h:105

connection_entry::local_list
struct local_list * local_list
Definition options.h:106

connection_entry::bind_local
bool bind_local
Definition options.h:116

connection_entry::remote
const char * remote
Definition options.h:112

connection_entry::socks_proxy_port
const char * socks_proxy_port
Definition options.h:122

connection_entry::http_proxy_options
struct http_proxy_options * http_proxy_options
Definition options.h:120

connection_entry::bind_ipv6_only
bool bind_ipv6_only
Definition options.h:115

connection_entry::remote_float
bool remote_float
Definition options.h:113

connection_entry::remote_port
const char * remote_port
Definition options.h:111

connection_entry::socks_proxy_server
const char * socks_proxy_server
Definition options.h:121

connection_entry::mtu_discover_type
int mtu_discover_type
Definition options.h:137

connection_entry::proto
int proto
Definition options.h:107

connection_entry::af
sa_family_t af
Definition options.h:108

connection_entry::flags
unsigned int flags
Definition options.h:159

connection_list
Definition options.h:196

connection_list::array
struct connection_entry ** array
Definition options.h:200

connection_list::len
int len
Definition options.h:198

context_1::link_socket_addrs
struct link_socket_addr * link_socket_addrs
Local and remote addresses on the external network.
Definition openvpn.h:160

context_1::link_sockets_num
int link_sockets_num
Definition openvpn.h:159

context_1::http_proxy
struct http_proxy_info * http_proxy
Definition openvpn.h:190

context_1::socks_proxy
struct socks_proxy_info * socks_proxy
Definition openvpn.h:194

context_1::dns_cache
struct cached_dns_entry * dns_cache
Definition openvpn.h:168

context_1::tuntap
struct tuntap * tuntap
Tun/tap virtual network interface.
Definition openvpn.h:173

context_2::server_poll_interval
struct event_timeout server_poll_interval
Definition openvpn.h:410

context_2::accept_from
const struct link_socket * accept_from
Definition openvpn.h:244

context_2::frame
struct frame frame
Definition openvpn.h:250

context_2::link_sockets
struct link_socket ** link_sockets
Definition openvpn.h:239

context
Contains all state information for one tunnel.
Definition openvpn.h:476

context::mode
int mode
Role of this context within the OpenVPN process.
Definition openvpn.h:489

context::sig
struct signal_info * sig
Internal error signaling object.
Definition openvpn.h:502

context::plugins
struct plugin_list * plugins
List of plug-ins.
Definition openvpn.h:504

context::c2
struct context_2 c2
Level 2 context.
Definition openvpn.h:516

context::options
struct options options
Options loaded from command line or configuration file.
Definition openvpn.h:477

context::gc
struct gc_arena gc
Garbage collection arena for allocations done in the scope of this context structure.
Definition openvpn.h:494

context::c1
struct context_1 c1
Level 1 context.
Definition openvpn.h:515

env_set
Definition env_set.h:42

event_arg::sock
struct link_socket * sock
Definition event.h:146

event_arg::u
union event_arg::@1 u

event_arg::type
event_arg_t type
Definition event.h:143

event_set
Definition event.h:131

frame
Packet geometry parameters.
Definition mtu.h:98

gc_arena
Garbage collection arena used to keep track of dynamically allocated memory.
Definition buffer.h:117

http_proxy_info::options
struct http_proxy_options options
Definition proxy.h:67

http_proxy_options::port
const char * port
Definition proxy.h:46

http_proxy_options::server
const char * server
Definition proxy.h:45

link_socket_actual
Definition socket.h:87

link_socket_actual::dest
struct openvpn_sockaddr dest
Definition socket.h:90

link_socket_addr
Definition socket.h:105

link_socket_addr::actual
struct link_socket_actual actual
Definition socket.h:110

link_socket_addr::remote_list
struct addrinfo * remote_list
Definition socket.h:107

link_socket_addr::bind_local
struct addrinfo * bind_local
Definition socket.h:106

link_socket_addr::current_remote
struct addrinfo * current_remote
Definition socket.h:108

link_socket_info
Definition socket.h:114

link_socket_info::connection_established
bool connection_established
Definition socket.h:116

link_socket_info::af
sa_family_t af
Definition socket.h:121

link_socket_info::lsa
struct link_socket_addr * lsa
Definition socket.h:115

link_socket_info::ipchange_command
const char * ipchange_command
Definition socket.h:117

link_socket_info::remote_float
bool remote_float
Definition socket.h:119

link_socket_info::plugins
const struct plugin_list * plugins
Definition socket.h:118

link_socket_info::bind_ipv6_only
bool bind_ipv6_only
Definition socket.h:122

link_socket_info::proto
int proto
Definition socket.h:120

link_socket
Definition socket.h:178

link_socket::server_poll_timeout
struct event_timeout * server_poll_timeout
Definition socket.h:250

link_socket::remote_host
const char * remote_host
Definition socket.h:202

link_socket::rwflags_debug
unsigned int rwflags_debug
Definition socket.h:197

link_socket::socket_buffer_sizes
struct socket_buffer_size socket_buffer_sizes
Definition socket.h:217

link_socket::socks_relay
struct link_socket_actual socks_relay
Definition socket.h:242

link_socket::listen_handle
struct rw_handle listen_handle
Definition socket.h:193

link_socket::info
struct link_socket_info info
Definition socket.h:179

link_socket::remote_port
const char * remote_port
Definition socket.h:203

link_socket::bind_local
bool bind_local
Definition socket.h:207

link_socket::local_host
const char * local_host
Definition socket.h:204

link_socket::proxy_dest_port
const char * proxy_dest_port
Definition socket.h:246

link_socket::mark
int mark
Definition socket.h:229

link_socket::local_port
const char * local_port
Definition socket.h:205

link_socket::rw_handle
struct rw_handle rw_handle
Definition socket.h:192

link_socket::writes
struct overlapped_io writes
Definition socket.h:191

link_socket::mtu_discover_type
int mtu_discover_type
Definition socket.h:215

link_socket::sockflags
unsigned int sockflags
Definition socket.h:228

link_socket::ctrl_sd
socket_descriptor_t ctrl_sd
Definition socket.h:187

link_socket::stream_buf
struct stream_buf stream_buf
Definition socket.h:233

link_socket::mode
int mode
Definition socket.h:212

link_socket::socks_proxy
struct socks_proxy_info * socks_proxy
Definition socket.h:241

link_socket::bind_dev
const char * bind_dev
Definition socket.h:230

link_socket::resolve_retry_seconds
int resolve_retry_seconds
Definition socket.h:214

link_socket::proxy_dest_host
const char * proxy_dest_host
Definition socket.h:245

link_socket::http_proxy
struct http_proxy_info * http_proxy
Definition socket.h:238

link_socket::dns_cache
struct cached_dns_entry * dns_cache
Definition socket.h:206

link_socket::stream_buf_data
struct buffer stream_buf_data
Definition socket.h:234

link_socket::ev_arg
struct event_arg ev_arg
this struct will store a pointer to either mi or link_socket, depending on the event type,...
Definition socket.h:181

link_socket::sd
socket_descriptor_t sd
Definition socket.h:186

link_socket::stream_reset
bool stream_reset
Definition socket.h:235

link_socket::reads
struct overlapped_io reads
Definition socket.h:190

local_entry
Definition options.h:98

local_entry::port
const char * port
Definition options.h:100

local_entry::proto
int proto
Definition options.h:101

local_entry::local
const char * local
Definition options.h:99

local_list::len
int len
Definition options.h:191

local_list::array
struct local_entry * array[CONNECTION_LIST_SIZE]
Definition options.h:192

management
Definition manage.h:336

management::connection
struct man_connection connection
Definition manage.h:339

openvpn_sockaddr
Definition socket.h:66

openvpn_sockaddr::sa
struct sockaddr sa
Definition socket.h:69

openvpn_sockaddr::addr
union openvpn_sockaddr::@24 addr

openvpn_sockaddr::in4
struct sockaddr_in in4
Definition socket.h:70

openvpn_sockaddr::in6
struct sockaddr_in6 in6
Definition socket.h:71

options
Definition options.h:250

options::resolve_retry_seconds
int resolve_retry_seconds
Definition options.h:365

options::rcvbuf
int rcvbuf
Definition options.h:414

options::ip_remote_hint
const char * ip_remote_hint
Definition options.h:367

options::msg_channel
HANDLE msg_channel
Definition options.h:692

options::ce
struct connection_entry ce
Definition options.h:288

options::ipchange
const char * ipchange
Definition options.h:315

options::mode
int mode
Definition options.h:260

options::bind_dev
char * bind_dev
Definition options.h:419

options::sndbuf
int sndbuf
Definition options.h:415

options::mark
int mark
Definition options.h:418

options::sockflags
unsigned int sockflags
Definition options.h:422

options::dev_node
const char * dev_node
Definition options.h:318

overlapped_io
Definition win32.h:202

overlapped_io::flags
DWORD flags
Definition win32.h:209

overlapped_io::buf
struct buffer buf
Definition win32.h:218

overlapped_io::size
DWORD size
Definition win32.h:208

overlapped_io::overlapped
OVERLAPPED overlapped
Definition win32.h:207

overlapped_io::buf_init
struct buffer buf_init
Definition win32.h:217

overlapped_io::addrlen
int addrlen
Definition win32.h:216

overlapped_io::addr_defined
bool addr_defined
Definition win32.h:211

overlapped_io::iostate
int iostate
Definition win32.h:206

overlapped_io::addr6
struct sockaddr_in6 addr6
Definition win32.h:214

overlapped_io::addr
struct sockaddr_in addr
Definition win32.h:213

overlapped_io::status
int status
Definition win32.h:210

proto_names
Definition socket.c:3171

proto_names::short_form
const char * short_form
Definition socket.c:3172

proto_names::display_form
const char * display_form
Definition socket.c:3173

proto_names::proto
int proto
Definition socket.c:3175

proto_names::proto_af
sa_family_t proto_af
Definition socket.c:3174

rw_handle
Definition win32.h:79

rw_handle::write
HANDLE write
Definition win32.h:81

rw_handle::read
HANDLE read
Definition win32.h:80

signal_info
Definition sig.h:42

signal_info::signal_text
const char * signal_text
Definition sig.h:45

signal_info::signal_received
volatile int signal_received
Definition sig.h:43

signal_info::source
volatile int source
Definition sig.h:44

socket_buffer_size
Definition socket.h:155

socket_buffer_size::sndbuf
int sndbuf
Definition socket.h:157

socket_buffer_size::rcvbuf
int rcvbuf
Definition socket.h:156

sockethandle_t
Definition socket.h:285

sockethandle_t::s
SOCKET s
Definition socket.h:287

sockethandle_t::is_handle
bool is_handle
Definition socket.h:290

sockethandle_t::prepend_sa
bool prepend_sa
Definition socket.h:291

socks_proxy_info::server
char server[128]
Definition socks.h:40

socks_proxy_info::port
const char * port
Definition socks.h:41

stream_buf
Definition socket.h:131

stream_buf::buf
struct buffer buf
Definition socket.h:137

stream_buf::residual
struct buffer residual
Definition socket.h:133

stream_buf::residual_fully_formed
bool residual_fully_formed
Definition socket.h:135

stream_buf::maxlen
int maxlen
Definition socket.h:134

tuntap_options::msg_channel
HANDLE msg_channel
Definition tun.h:87

tuntap
Definition tun.h:178

tuntap::backend_driver
enum tun_driver_type backend_driver
The backend driver that used for this tun/tap device.
Definition tun.h:188

tuntap::dco_new_peer_ov
OVERLAPPED dco_new_peer_ov
Definition tun.h:214

tuntap::options
struct tuntap_options options
Definition tun.h:200

tuntap::hand
HANDLE hand
Definition tun.h:213

syshead.h

sa_family_t
unsigned short sa_family_t
Definition syshead.h:395

SOCKET_UNDEFINED
#define SOCKET_UNDEFINED
Definition syshead.h:437

SOL_IP
#define SOL_IP
Definition syshead.h:388

socket_descriptor_t
SOCKET socket_descriptor_t
Definition syshead.h:439

socket_defined
static int socket_defined(const socket_descriptor_t sd)
Definition syshead.h:447

ENABLE_IP_PKTINFO
#define ENABLE_IP_PKTINFO
Definition syshead.h:380

es
struct env_set * es
Definition test_pkcs11.c:141

gc
struct gc_arena gc
Definition test_ssl.c:155

tun_open_device
void tun_open_device(struct tuntap *tt, const char *dev_node, const char **device_guid, struct gc_arena *gc)
Definition tun.c:6503

DRIVER_DCO
@ DRIVER_DCO
Definition tun.h:53

init_net_event_win32
void init_net_event_win32(struct rw_handle *event, long network_events, socket_descriptor_t sd, unsigned int flags)
Definition win32.c:223

overlapped_io_init
void overlapped_io_init(struct overlapped_io *o, const struct frame *frame, BOOL event_state)
Definition win32.c:171

close_net_event_win32
void close_net_event_win32(struct rw_handle *event, socket_descriptor_t sd, unsigned int flags)
Definition win32.c:277

overlapped_io_state_ascii
char * overlapped_io_state_ascii(const struct overlapped_io *o)
Definition win32.c:202

overlapped_io_close
void overlapped_io_close(struct overlapped_io *o)
Definition win32.c:189

defined_net_event_win32
static bool defined_net_event_win32(const struct rw_handle *event)
Definition win32.h:92

IOSTATE_IMMEDIATE_RETURN
#define IOSTATE_IMMEDIATE_RETURN
Definition win32.h:205

IOSTATE_INITIAL
#define IOSTATE_INITIAL
Definition win32.h:203

IOSTATE_QUEUED
#define IOSTATE_QUEUED
Definition win32.h:204