File: ne_socket.c

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/* 
   Socket handling routines
   Copyright (C) 1998-2009, Joe Orton <joe@manyfish.co.uk>
   Copyright (C) 2004 Aleix Conchillo Flaque <aleix@member.fsf.org>

   This library is free software; you can redistribute it and/or
   modify it under the terms of the GNU Library General Public
   License as published by the Free Software Foundation; either
   version 2 of the License, or (at your option) any later version.
   
   This library 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
   Library General Public License for more details.

   You should have received a copy of the GNU Library General Public
   License along with this library; if not, write to the Free
   Software Foundation, Inc., 59 Temple Place - Suite 330, Boston,
   MA 02111-1307, USA
*/

/*
  portions were originally under GPL in Mutt, http://www.mutt.org/
  Relicensed under LGPL for neon, http://www.webdav.org/neon/
*/

#include "config.h"

#include <sys/types.h>
#ifdef HAVE_SYS_TIME_H
#include <sys/time.h>
#endif
#include <sys/stat.h>
#ifdef HAVE_SYS_SOCKET_H
#include <sys/socket.h>
#endif

#ifdef NE_USE_POLL
#include <sys/poll.h>
#elif defined(HAVE_SYS_SELECT_H)
#include <sys/select.h>
#endif

#ifdef HAVE_NETINET_IN_H
#include <netinet/in.h>
#endif
#ifdef HAVE_NETINET_TCP_H
#include <netinet/tcp.h>
#endif
#ifdef HAVE_ARPA_INET_H
#include <arpa/inet.h>
#endif
#ifdef HAVE_NETDB_H
#include <netdb.h>
#endif

#ifdef WIN32
#include <winsock2.h>
#include <stddef.h>
#ifdef USE_GETADDRINFO
#include <ws2tcpip.h>
#include <wspiapi.h>
#endif
#endif

#if defined(HAVE_OPENSSL) && defined(HAVE_LIMITS_H)
#include <limits.h> /* for INT_MAX */
#endif
#ifdef HAVE_STRING_H
#include <string.h>
#endif
#ifdef HAVE_STRINGS_H
#include <strings.h>
#endif 
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#ifdef HAVE_SIGNAL_H
#include <signal.h>
#endif
#ifdef HAVE_ERRNO_H
#include <errno.h>
#endif
#ifdef HAVE_STDLIB_H
#include <stdlib.h>
#endif
#ifdef HAVE_FCNTL_H
#include <fcntl.h>
#endif

#ifdef HAVE_SOCKS_H
#include <socks.h>
#endif

#ifdef HAVE_OPENSSL
#include <openssl/ssl.h>
#include <openssl/err.h>
#include <openssl/pkcs12.h> /* for PKCS12_PBE_add */
#include <openssl/rand.h>
#include <openssl/opensslv.h> /* for OPENSSL_VERSION_NUMBER */
#endif

#ifdef HAVE_GNUTLS
#include <gnutls/gnutls.h>
#endif

#define NE_INET_ADDR_DEFINED
/* A slightly ugly hack: change the ne_inet_addr definition to be the
 * real address type used.  The API only exposes ne_inet_addr as a
 * pointer to an opaque object, so this should be well-defined
 * behaviour.  It avoids the hassle of a real wrapper ne_inet_addr
 * structure, or losing type-safety by using void *. */
#ifdef USE_GETADDRINFO
typedef struct addrinfo ne_inet_addr;
#else
typedef struct in_addr ne_inet_addr;
#endif

#include "ne_privssl.h" /* MUST come after ne_inet_addr is defined */

/* To avoid doing AAAA queries unless absolutely necessary, either use
 * AI_ADDRCONFIG where available, or a run-time check for working IPv6
 * support; the latter is only known to work on Linux. */
#if defined(USE_GETADDRINFO) && !defined(USE_GAI_ADDRCONFIG) && defined(__linux__)
#define USE_CHECK_IPV6
#endif

/* "Be Conservative In What You Build". */
#if defined(HAVE_FCNTL) && defined(O_NONBLOCK) && defined(F_SETFL) \
    && defined(HAVE_GETSOCKOPT) && defined(SO_ERROR) \
    && defined(HAVE_SOCKLEN_T) && defined(SOL_SOCKET) \
    && defined(EINPROGRESS)
#define USE_NONBLOCKING_CONNECT
#endif

#include "ne_internal.h"
#include "ne_utils.h"
#include "ne_string.h"
#include "ne_socket.h"
#include "ne_alloc.h"
#include "ne_sspi.h"

#if defined(__BEOS__) && !defined(BONE_VERSION)
/* pre-BONE */
#define ne_close(s) closesocket(s)
#define ne_errno errno
#elif defined(WIN32)
#define ne_close(s) closesocket(s)
#define ne_errno WSAGetLastError()
#else /* really Unix! */
#define ne_close(s) close(s)
#define ne_errno errno
#endif

#ifdef WIN32
#define NE_ISRESET(e) ((e) == WSAECONNABORTED || (e) == WSAETIMEDOUT || \
                       (e) == WSAECONNRESET || (e) == WSAENETRESET)
#define NE_ISCLOSED(e) ((e) == WSAESHUTDOWN || (e) == WSAENOTCONN)
#define NE_ISINTR(e) (0)
#define NE_ISINPROGRESS(e) ((e) == WSAEWOULDBLOCK) /* says MSDN */
#else /* Unix */
/* Also treat ECONNABORTED and ENOTCONN as "connection reset" errors;
 * both can be returned by Winsock-based sockets layers e.g. CygWin */
#ifndef ECONNABORTED
#define ECONNABORTED ECONNRESET
#endif
#ifndef ENOTCONN
#define ENOTCONN ECONNRESET
#endif
#define NE_ISRESET(e) ((e) == ECONNRESET || (e) == ECONNABORTED || (e) == ENOTCONN)
#define NE_ISCLOSED(e) ((e) == EPIPE)
#define NE_ISINTR(e) ((e) == EINTR)
#define NE_ISINPROGRESS(e) ((e) == EINPROGRESS)
#endif

/* Socket read timeout */
#define SOCKET_READ_TIMEOUT 120

/* Critical I/O functions on a socket: useful abstraction for easily
 * handling SSL I/O alongside raw socket I/O. */
struct iofns {
    /* Read up to 'len' bytes into 'buf' from socket.  Return <0 on
     * error or EOF, or >0; number of bytes read. */
    ssize_t (*sread)(ne_socket *s, char *buf, size_t len);
    /* Write up to 'len' bytes from 'buf' to socket.  Return number of
     * bytes written on success, or <0 on error. */
    ssize_t (*swrite)(ne_socket *s, const char *buf, size_t len);
    /* Wait up to 'n' seconds for socket to become readable.  Returns
     * 0 when readable, otherwise NE_SOCK_TIMEOUT or NE_SOCK_ERROR. */
    int (*readable)(ne_socket *s, int n);
    /* Write up to 'count' blocks described by 'vector' to socket.
     * Return number of bytes written on success, or <0 on error. */
    ssize_t (*swritev)(ne_socket *s, const struct ne_iovec *vector, 
                       int count);
};

static const ne_inet_addr dummy_laddr;

struct ne_socket_s {
    int fd;
    unsigned int lport;
    const ne_inet_addr *laddr;

    void *progress_ud;
    int rdtimeout, cotimeout; /* timeouts */
    const struct iofns *ops;
#ifdef NE_HAVE_SSL
    ne_ssl_socket ssl;
#endif
    /* The read buffer: ->buffer stores byte which have been read; as
     * these are consumed and passed back to the caller, bufpos
     * advances through ->buffer.  ->bufavail gives the number of
     * bytes which remain to be consumed in ->buffer (from ->bufpos),
     * and is hence always <= RDBUFSIZ. */
    char *bufpos;
    size_t bufavail;
#define RDBUFSIZ 4096
    char buffer[RDBUFSIZ];
    /* Error string. */
    char error[192];
};

/* ne_sock_addr represents an Internet address. */
struct ne_sock_addr_s {
#ifdef USE_GETADDRINFO
    struct addrinfo *result, *cursor;
#else
    struct in_addr *addrs;
    size_t cursor, count;
#endif
    int errnum;
};

/* set_error: set socket error string to 'str'. */
#define set_error(s, str) ne_strnzcpy((s)->error, (str), sizeof (s)->error)

/* set_strerror: set socket error to system error string for 'errnum' */
#ifdef WIN32
/* Print system error message to given buffer. */
static void print_error(int errnum, char *buffer, size_t buflen)
{
    if (FormatMessage (FORMAT_MESSAGE_FROM_SYSTEM
                       | FORMAT_MESSAGE_IGNORE_INSERTS,
                       NULL, (DWORD) errnum, 0, 
                       buffer, buflen, NULL) == 0)
        ne_snprintf(buffer, buflen, "Socket error %d", errnum);
}
#define set_strerror(s, e) print_error((e), (s)->error, sizeof (s)->error)
#else /* not WIN32 */
#define set_strerror(s, e) ne_strerror((e), (s)->error, sizeof (s)->error)
#endif

#ifdef HAVE_OPENSSL
/* Seed the SSL PRNG, if necessary; returns non-zero on failure. */
static int seed_ssl_prng(void)
{
    /* Check whether the PRNG has already been seeded. */
    if (RAND_status() == 1)
	return 0;

#if defined(EGD_PATH)
    NE_DEBUG(NE_DBG_SOCKET, "Seeding PRNG from " EGD_PATH "...\n");
    if (RAND_egd(EGD_PATH) != -1)
	return 0;
#elif defined(ENABLE_EGD)
    {
	static const char *paths[] = { "/var/run/egd-pool", "/dev/egd-pool",
				       "/etc/egd-pool", "/etc/entropy" };
	size_t n;
	for (n = 0; n < sizeof(paths) / sizeof(char *); n++) {
	    NE_DEBUG(NE_DBG_SOCKET, "Seeding PRNG from %s...\n", paths[n]);
	    if (RAND_egd(paths[n]) != -1)
		return 0;
	}
    }
#endif /* EGD_PATH */

    NE_DEBUG(NE_DBG_SOCKET, "No entropy source found; could not seed PRNG.\n");
    return -1;
}
#endif /* HAVE_OPENSSL */

#ifdef USE_CHECK_IPV6
static int ipv6_disabled = 0;

/* On Linux kernels, IPv6 is typically built as a loadable module, and
 * socket(AF_INET6, ...) will fail if this module is not loaded, so
 * the slow AAAA lookups can be avoided for this common case. */
static void init_ipv6(void)
{
    int fd = socket(AF_INET6, SOCK_STREAM, 0);
    
    if (fd < 0)
        ipv6_disabled = 1;
    else
        close(fd);
}
#elif defined(AF_INET6)
#define ipv6_disabled (0)
#else
#define ipv6_disabled (1)
#endif

/* If init_state is N where > 0, ne_sock_init has been called N times;
 * if == 0, library is not initialized; if < 0, library initialization
 * has failed. */
static int init_state = 0;

int ne_sock_init(void)
{
#ifdef WIN32
    WORD wVersionRequested;
    WSADATA wsaData;
    int err;
#endif

    if (init_state > 0) {
        init_state++;
	return 0;
    } 
    else if (init_state < 0) {
	return -1;
    }

#ifdef WIN32    
    wVersionRequested = MAKEWORD(2, 2);
    
    err = WSAStartup(wVersionRequested, &wsaData);
    if (err != 0) {
	return init_state = -1;
    }
#ifdef HAVE_SSPI
    if (ne_sspi_init() < 0) {
        return init_state = -1;
    }
#endif
#endif

#ifdef NE_HAVE_SOCKS
    SOCKSinit("neon");
#endif

#if defined(HAVE_SIGNAL) && defined(SIGPIPE)
    (void) signal(SIGPIPE, SIG_IGN);
#endif

#ifdef USE_CHECK_IPV6
    init_ipv6();
#endif

#ifdef NE_HAVE_SSL
    if (ne__ssl_init()) {
        return init_state = -1;
    }
#endif

    init_state = 1;
    return 0;
}

void ne_sock_exit(void)
{
    if (init_state > 0 && --init_state == 0) {
#ifdef WIN32
        WSACleanup();
#endif
#ifdef NE_HAVE_SSL
        ne__ssl_exit();
#endif
        
#ifdef HAVE_SSPI
        ne_sspi_deinit();
#endif
    }
}

/* Await readability (rdwr = 0) or writability (rdwr != 0) for socket
 * fd for secs seconds.  Returns <0 on error, zero on timeout, >0 if
 * data is available. */
static int raw_poll(int fdno, int rdwr, int secs)
{
    int ret;
#ifdef NE_USE_POLL
    struct pollfd fds;
    int timeout = secs > 0 ? secs * 1000 : -1;

    fds.fd = fdno;
    fds.events = rdwr == 0 ? POLLIN : POLLOUT;
    fds.revents = 0;

    do {
        ret = poll(&fds, 1, timeout);
    } while (ret < 0 && NE_ISINTR(ne_errno));
#else
    fd_set rdfds, wrfds;
    struct timeval timeout, *tvp = (secs >= 0 ? &timeout : NULL);

    /* Init the fd set */
    FD_ZERO(&rdfds);
    FD_ZERO(&wrfds);

    /* Note that (amazingly) the FD_SET macro does not expand
     * correctly on Netware if not inside a compound statement
     * block. */
    if (rdwr == 0) {
        FD_SET(fdno, &rdfds);
    } else {
        FD_SET(fdno, &wrfds);
    }

    if (tvp) {
        tvp->tv_sec = secs;
        tvp->tv_usec = 0;
    }
    do {
	ret = select(fdno + 1, &rdfds, &wrfds, NULL, tvp);
    } while (ret < 0 && NE_ISINTR(ne_errno));
#endif
    return ret;
}

int ne_sock_block(ne_socket *sock, int n)
{
    if (sock->bufavail)
	return 0;
    return sock->ops->readable(sock, n);
}

/* Cast address object AD to type 'sockaddr_TY' */ 
#define SACAST(ty, ad) ((struct sockaddr_##ty *)(ad))

ssize_t ne_sock_read(ne_socket *sock, char *buffer, size_t buflen)
{
    ssize_t bytes;

#if 0
    NE_DEBUG(NE_DBG_SOCKET, "buf: at %d, %d avail [%s]\n", 
	     sock->bufpos - sock->buffer, sock->bufavail, sock->bufpos);
#endif

    if (sock->bufavail > 0) {
	/* Deliver buffered data. */
	if (buflen > sock->bufavail)
	    buflen = sock->bufavail;
	memcpy(buffer, sock->bufpos, buflen);
	sock->bufpos += buflen;
	sock->bufavail -= buflen;
	return buflen;
    } else if (buflen >= sizeof sock->buffer) {
	/* No need for read buffer. */
	return sock->ops->sread(sock, buffer, buflen);
    } else {
	/* Fill read buffer. */
	bytes = sock->ops->sread(sock, sock->buffer, sizeof sock->buffer);
	if (bytes <= 0)
	    return bytes;

	if (buflen > (size_t)bytes)
	    buflen = bytes;
	memcpy(buffer, sock->buffer, buflen);
	sock->bufpos = sock->buffer + buflen;
	sock->bufavail = bytes - buflen;
	return buflen; 
    }
}

ssize_t ne_sock_peek(ne_socket *sock, char *buffer, size_t buflen)
{
    ssize_t bytes;
    
    if (sock->bufavail) {
	/* just return buffered data. */
	bytes = sock->bufavail;
    } else {
	/* fill the buffer. */
	bytes = sock->ops->sread(sock, sock->buffer, sizeof sock->buffer);
	if (bytes <= 0)
	    return bytes;

	sock->bufpos = sock->buffer;
	sock->bufavail = bytes;
    }

    if (buflen > (size_t)bytes)
	buflen = bytes;

    memcpy(buffer, sock->bufpos, buflen);

    return buflen;
}

/* Await data on raw fd in socket. */
static int readable_raw(ne_socket *sock, int secs)
{
    int ret = raw_poll(sock->fd, 0, secs);

    if (ret < 0) {
	set_strerror(sock, ne_errno);
	return NE_SOCK_ERROR;
    }
    return (ret == 0) ? NE_SOCK_TIMEOUT : 0;
}

static ssize_t read_raw(ne_socket *sock, char *buffer, size_t len)
{
    ssize_t ret;
    
    ret = readable_raw(sock, sock->rdtimeout);
    if (ret) return ret;

    do {
	ret = recv(sock->fd, buffer, len, 0);
    } while (ret == -1 && NE_ISINTR(ne_errno));

    if (ret == 0) {
	set_error(sock, _("Connection closed"));
	ret = NE_SOCK_CLOSED;
    } else if (ret < 0) {
	int errnum = ne_errno;
	ret = NE_ISRESET(errnum) ? NE_SOCK_RESET : NE_SOCK_ERROR;
	set_strerror(sock, errnum);
    }

    return ret;
}

#define MAP_ERR(e) (NE_ISCLOSED(e) ? NE_SOCK_CLOSED : \
                    (NE_ISRESET(e) ? NE_SOCK_RESET : NE_SOCK_ERROR))

static ssize_t write_raw(ne_socket *sock, const char *data, size_t length) 
{
    ssize_t ret;
    
#ifdef __QNX__
    /* Test failures seen on QNX over loopback, if passing large
     * buffer lengths to send().  */
    if (length > 8192) length = 8192;
#endif

    do {
	ret = send(sock->fd, data, length, 0);
    } while (ret == -1 && NE_ISINTR(ne_errno));

    if (ret < 0) {
	int errnum = ne_errno;
	set_strerror(sock, errnum);
	return MAP_ERR(errnum);
    }
    return ret;
}

static ssize_t writev_raw(ne_socket *sock, const struct ne_iovec *vector, int count) 
{
    ssize_t ret;
#ifdef WIN32
    LPWSABUF wasvector = (LPWSABUF)ne_malloc(count * sizeof(WSABUF));
    DWORD total;
    int i;

    for (i = 0; i < count; i++){
        wasvector[i].buf = vector[i].base;
        wasvector[i].len = vector[i].len;
    }
        
    ret = WSASend(sock->fd, wasvector, count, &total, 0, NULL, NULL);
    if (ret == 0)
        ret = total;
    
    ne_free(wasvector);
#else
    const struct iovec *vec = (const struct iovec *) vector;

    do {
	ret = writev(sock->fd, vec, count);
    } while (ret == -1 && NE_ISINTR(ne_errno));
#endif

    if (ret < 0) {
	int errnum = ne_errno;
	set_strerror(sock, errnum);
	return MAP_ERR(errnum);
    }
    
    return ret;
}

#ifdef NE_HAVE_SSL
static ssize_t writev_dummy(ne_socket *sock, const struct ne_iovec *vector, int count) 
{
    return sock->ops->swrite(sock, vector[0].base, vector[0].len);
}
#endif

static const struct iofns iofns_raw = { read_raw, write_raw, readable_raw, writev_raw };

#ifdef HAVE_OPENSSL
/* OpenSSL I/O function implementations. */
static int readable_ossl(ne_socket *sock, int secs)
{
    if (SSL_pending(sock->ssl))
	return 0;
    return readable_raw(sock, secs);
}

/* SSL error handling, according to SSL_get_error(3). */
static int error_ossl(ne_socket *sock, int sret)
{
    int errnum = SSL_get_error(sock->ssl, sret);
    unsigned long err;

    if (errnum == SSL_ERROR_ZERO_RETURN) {
	set_error(sock, _("Connection closed"));
        return NE_SOCK_CLOSED;
    }
    
    /* for all other errors, look at the OpenSSL error stack */
    err = ERR_get_error();
    if (err == 0) {
        /* Empty error stack, presume this is a system call error: */
        if (sret == 0) {
            /* EOF without close_notify, possible truncation */
            set_error(sock, _("Secure connection truncated"));
            return NE_SOCK_TRUNC;
        } else {
            /* Other socket error. */
            errnum = ne_errno;
            set_strerror(sock, errnum);
            return MAP_ERR(errnum);
        }
    }

    if (ERR_reason_error_string(err)) {
        ne_snprintf(sock->error, sizeof sock->error, 
                    _("SSL error: %s"), ERR_reason_error_string(err));
    } else {
	ne_snprintf(sock->error, sizeof sock->error, 
                    _("SSL error code %d/%d/%lu"), sret, errnum, err);
    }
    
    /* make sure the error stack is now empty. */
    ERR_clear_error();
    return NE_SOCK_ERROR;
}

/* Work around OpenSSL's use of 'int' rather than 'size_t', to prevent
 * accidentally passing a negative number, etc. */
#define CAST2INT(n) (((n) > INT_MAX) ? INT_MAX : (n))

static ssize_t read_ossl(ne_socket *sock, char *buffer, size_t len)
{
    int ret;

    ret = readable_ossl(sock, sock->rdtimeout);
    if (ret) return ret;
    
    ret = SSL_read(sock->ssl, buffer, CAST2INT(len));
    if (ret <= 0)
	ret = error_ossl(sock, ret);

    return ret;
}

static ssize_t write_ossl(ne_socket *sock, const char *data, size_t len)
{
    int ret, ilen = CAST2INT(len);
    ret = SSL_write(sock->ssl, data, ilen);
    /* ssl.h says SSL_MODE_ENABLE_PARTIAL_WRITE must be enabled to
     * have SSL_write return < length...  so, SSL_write should never
     * return < length. */
    if (ret != ilen)
	return error_ossl(sock, ret);
    return ret;
}

static const struct iofns iofns_ssl = {
    read_ossl,
    write_ossl,
    readable_ossl,
    writev_dummy
};

#elif defined(HAVE_GNUTLS)

/* Return zero if an alert value can be ignored. */
static int check_alert(ne_socket *sock, ssize_t ret)
{
    const char *alert;

    if (ret == GNUTLS_E_WARNING_ALERT_RECEIVED) {
        alert = gnutls_alert_get_name(gnutls_alert_get(sock->ssl));
        NE_DEBUG(NE_DBG_SOCKET, "TLS warning alert: %s\n", alert);
        return 0;
    } else if (ret == GNUTLS_E_FATAL_ALERT_RECEIVED) {
        alert = gnutls_alert_get_name(gnutls_alert_get(sock->ssl));
        NE_DEBUG(NE_DBG_SOCKET, "TLS fatal alert: %s\n", alert);
        return -1;
    }
    return ret;
}

static int readable_gnutls(ne_socket *sock, int secs)
{
    if (gnutls_record_check_pending(sock->ssl)) {
        return 0;
    }
    return readable_raw(sock, secs);
}

static ssize_t error_gnutls(ne_socket *sock, ssize_t sret)
{
    ssize_t ret;

    switch (sret) {
    case 0:
	ret = NE_SOCK_CLOSED;
	set_error(sock, _("Connection closed"));
	break;
    case GNUTLS_E_FATAL_ALERT_RECEIVED:
        ret = NE_SOCK_ERROR;
        ne_snprintf(sock->error, sizeof sock->error, 
                    _("SSL alert received: %s"),
                    gnutls_alert_get_name(gnutls_alert_get(sock->ssl)));
        break;
    case GNUTLS_E_UNEXPECTED_PACKET_LENGTH:
        /* It's not exactly an API guarantee but this error will
         * always mean a premature EOF. */
        ret = NE_SOCK_TRUNC;
        set_error(sock, _("Secure connection truncated"));
        break;
    case GNUTLS_E_PUSH_ERROR:
        ret = NE_SOCK_RESET;
        set_error(sock, ("SSL socket write failed"));
        break;
    case GNUTLS_E_PULL_ERROR:
        ret = NE_SOCK_RESET;
        set_error(sock, _("SSL socket read failed"));
        break;
    default:
        ret = NE_SOCK_ERROR;
        ne_snprintf(sock->error, sizeof sock->error, _("SSL error: %s"),
                    gnutls_strerror(sret));
    }
    return ret;
}

#define RETRY_GNUTLS(sock, ret) ((ret < 0) \
    && (ret == GNUTLS_E_INTERRUPTED || ret == GNUTLS_E_AGAIN \
        || check_alert(sock, ret) == 0))

static ssize_t read_gnutls(ne_socket *sock, char *buffer, size_t len)
{
    ssize_t ret;
    unsigned reneg = 1; /* number of allowed rehandshakes */

    ret = readable_gnutls(sock, sock->rdtimeout);
    if (ret) return ret;
    
    do {
        do {
            ret = gnutls_record_recv(sock->ssl, buffer, len);
        } while (RETRY_GNUTLS(sock, ret));
        
    } while (ret == GNUTLS_E_REHANDSHAKE && reneg--
             && (ret = gnutls_handshake(sock->ssl)) == GNUTLS_E_SUCCESS);

    if (ret <= 0)
	ret = error_gnutls(sock, ret);

    return ret;
}

static ssize_t write_gnutls(ne_socket *sock, const char *data, size_t len)
{
    ssize_t ret;

    do {
        ret = gnutls_record_send(sock->ssl, data, len);
    } while (RETRY_GNUTLS(sock, ret));

    if (ret < 0)
	return error_gnutls(sock, ret);

    return ret;
}

static const struct iofns iofns_ssl = {
    read_gnutls,
    write_gnutls,
    readable_gnutls,
    writev_dummy
};

#endif

int ne_sock_fullwrite(ne_socket *sock, const char *data, size_t len)
{
    ssize_t ret;

    do {
        ret = sock->ops->swrite(sock, data, len);
        if (ret > 0) {
            data += ret;
            len -= ret;
        }
    } while (ret > 0 && len > 0);

    return ret < 0 ? ret : 0;
}

int ne_sock_fullwritev(ne_socket *sock, const struct ne_iovec *vector, int count)
{
    ssize_t ret;

    do {
        ret = sock->ops->swritev(sock, vector, count);
        if (ret > 0) {
            while (count && (size_t)ret >= vector[0].len) {
                ret -= vector[0].len;
                count--;
                vector++;
            }
            
            if (ret && count) {
                /* Partial buffer sent; send the rest. */
                ret = ne_sock_fullwrite(sock, (char *)vector[0].base + ret,
                                        vector[0].len - ret);
                count--;
                vector++;
            }
        }
    } while (count && ret >= 0);

    return ret < 0 ? ret : 0;
}

ssize_t ne_sock_readline(ne_socket *sock, char *buf, size_t buflen)
{
    char *lf;
    size_t len;
    
    if ((lf = memchr(sock->bufpos, '\n', sock->bufavail)) == NULL
	&& sock->bufavail < RDBUFSIZ) {
	/* The buffered data does not contain a complete line: move it
	 * to the beginning of the buffer. */
	if (sock->bufavail)
	    memmove(sock->buffer, sock->bufpos, sock->bufavail);
	sock->bufpos = sock->buffer;
	
	/* Loop filling the buffer whilst no newline is found in the data
	 * buffered so far, and there is still buffer space available */ 
	do {
	    /* Read more data onto end of buffer. */
	    ssize_t ret = sock->ops->sread(sock, sock->buffer + sock->bufavail,
                                           RDBUFSIZ - sock->bufavail);
	    if (ret < 0) return ret;
	    sock->bufavail += ret;
	} while ((lf = memchr(sock->buffer, '\n', sock->bufavail)) == NULL
		 && sock->bufavail < RDBUFSIZ);
    }

    if (lf)
	len = lf - sock->bufpos + 1;
    else
	len = buflen; /* fall into "line too long" error... */

    if ((len + 1) > buflen) {
	set_error(sock, _("Line too long"));
	return NE_SOCK_ERROR;
    }

    memcpy(buf, sock->bufpos, len);
    buf[len] = '\0';
    /* consume the line from buffer: */
    sock->bufavail -= len;
    sock->bufpos += len;
    return len;
}

ssize_t ne_sock_fullread(ne_socket *sock, char *buffer, size_t buflen) 
{
    ssize_t len;

    while (buflen > 0) {
	len = ne_sock_read(sock, buffer, buflen);
	if (len < 0) return len;
	buflen -= len;
	buffer += len;
    }

    return 0;
}

#ifndef INADDR_NONE
#define INADDR_NONE ((in_addr_t) -1)
#endif

#if !defined(USE_GETADDRINFO) && !defined(WIN32) && !HAVE_DECL_H_ERRNO
/* Ancient versions of netdb.h don't export h_errno. */
extern int h_errno;
#endif

/* This implemementation does not attempt to support IPv6 using
 * gethostbyname2 et al.  */
ne_sock_addr *ne_addr_resolve(const char *hostname, int flags)
{
    ne_sock_addr *addr = ne_calloc(sizeof *addr);
#ifdef USE_GETADDRINFO
    struct addrinfo hints = {0};
    char *pnt;

    hints.ai_socktype = SOCK_STREAM;

#ifdef AF_INET6
    if (hostname[0] == '[' && ((pnt = strchr(hostname, ']')) != NULL)) {
	char *hn = ne_strdup(hostname + 1);
	hn[pnt - hostname - 1] = '\0';
#ifdef AI_NUMERICHOST /* added in the RFC2553 API */
	hints.ai_flags = AI_NUMERICHOST;
#endif
        hints.ai_family = AF_INET6;
	addr->errnum = getaddrinfo(hn, NULL, &hints, &addr->result);
	ne_free(hn);
    } else 
#endif /* AF_INET6 */
    {
#ifdef USE_GAI_ADDRCONFIG /* added in the RFC3493 API */
        hints.ai_flags = AI_ADDRCONFIG;
        hints.ai_family = AF_UNSPEC;
        addr->errnum = getaddrinfo(hostname, NULL, &hints, &addr->result);
#else
        hints.ai_family = ipv6_disabled ? AF_INET : AF_UNSPEC;
	addr->errnum = getaddrinfo(hostname, NULL, &hints, &addr->result);
#endif
    }
#else /* Use gethostbyname() */
    in_addr_t laddr;
    struct hostent *hp;
    
    laddr = inet_addr(hostname);
    if (laddr == INADDR_NONE) {
	hp = gethostbyname(hostname);
	if (hp == NULL) {
#ifdef WIN32
	    addr->errnum = WSAGetLastError();
#else
            addr->errnum = h_errno;
#endif
	} else if (hp->h_length != sizeof(struct in_addr)) {
	    /* fail gracefully if somebody set RES_USE_INET6 */
	    addr->errnum = NO_RECOVERY;
	} else {
	    size_t n;
	    /* count addresses */
	    for (n = 0; hp->h_addr_list[n] != NULL; n++)
		/* noop */;

	    addr->count = n;
	    addr->addrs = ne_malloc(n * sizeof *addr->addrs);

	    for (n = 0; n < addr->count; n++)
		memcpy(&addr->addrs[n], hp->h_addr_list[n], hp->h_length);
	}
    } else {
	addr->addrs = ne_malloc(sizeof *addr->addrs);
	addr->count = 1;
	memcpy(addr->addrs, &laddr, sizeof *addr->addrs);
    }
#endif
    return addr;
}

int ne_addr_result(const ne_sock_addr *addr)
{
    return addr->errnum;
}

const ne_inet_addr *ne_addr_first(ne_sock_addr *addr)
{
#ifdef USE_GETADDRINFO
    addr->cursor = addr->result->ai_next;
    return addr->result;
#else
    addr->cursor = 0;
    return &addr->addrs[0];
#endif
}

const ne_inet_addr *ne_addr_next(ne_sock_addr *addr)
{
#ifdef USE_GETADDRINFO
    struct addrinfo *ret = addr->cursor;
    if (addr->cursor) addr->cursor = addr->cursor->ai_next;
#else
    struct in_addr *ret;
    if (++addr->cursor < addr->count)
	ret = &addr->addrs[addr->cursor];
    else
	ret = NULL;
#endif
    return ret;
}

char *ne_addr_error(const ne_sock_addr *addr, char *buf, size_t bufsiz)
{
#ifdef WIN32
    print_error(addr->errnum, buf, bufsiz);
#else
    const char *err;
#ifdef USE_GETADDRINFO
    /* override horrible generic "Name or service not known" error. */
    if (addr->errnum == EAI_NONAME)
	err = _("Host not found");
    else
	err = gai_strerror(addr->errnum);
#elif defined(HAVE_HSTRERROR)
    err = hstrerror(addr->errnum);
#else
    err = _("Host not found");
#endif
    ne_strnzcpy(buf, err, bufsiz);
#endif /* WIN32 */
    return buf;
}

char *ne_iaddr_print(const ne_inet_addr *ia, char *buf, size_t bufsiz)
{
#if defined(USE_GETADDRINFO) && defined(HAVE_INET_NTOP)
    const char *ret;
#ifdef AF_INET6
    if (ia->ai_family == AF_INET6) {
	struct sockaddr_in6 *in6 = SACAST(in6, ia->ai_addr);
	ret = inet_ntop(AF_INET6, &in6->sin6_addr, buf, bufsiz);
    } else
#endif
    if (ia->ai_family == AF_INET) {
	struct sockaddr_in *in = SACAST(in, ia->ai_addr);
	ret = inet_ntop(AF_INET, &in->sin_addr, buf, bufsiz);
    } else
	ret = NULL;
    if (ret == NULL)
	ne_strnzcpy(buf, "[IP address]", bufsiz);
#elif defined(USE_GETADDRINFO) && defined(NI_NUMERICHOST)
    /* use getnameinfo instead for Win32, which lacks inet_ntop: */
    if (getnameinfo(ia->ai_addr, ia->ai_addrlen, buf, bufsiz, NULL, 0,
                    NI_NUMERICHOST))
        ne_strnzcpy(buf, "[IP address]", bufsiz);
#else /* USE_GETADDRINFO */
    ne_strnzcpy(buf, inet_ntoa(*ia), bufsiz);
#endif
    return buf;
}

unsigned char *ne_iaddr_raw(const ne_inet_addr *ia, unsigned char *buf)
{
#ifdef USE_GETADDRINFO
#ifdef AF_INET6
    if (ia->ai_family == AF_INET6) {
	struct sockaddr_in6 *in6 = SACAST(in6, ia->ai_addr);
        return memcpy(buf, in6->sin6_addr.s6_addr, sizeof in6->sin6_addr.s6_addr);
    } else
#endif /* AF_INET6 */
    {
	struct sockaddr_in *in = SACAST(in, ia->ai_addr);
        return memcpy(buf, &in->sin_addr.s_addr, sizeof in->sin_addr.s_addr);
    }
#else /* !USE_GETADDRINFO */
    return memcpy(buf, &ia->s_addr, sizeof ia->s_addr);
#endif
}

ne_inet_addr *ne_iaddr_parse(const char *addr, ne_iaddr_type type)
{
#if defined(USE_GETADDRINFO) && defined(HAVE_INET_PTON)
    char dst[sizeof(struct in6_addr)];
    int af = type == ne_iaddr_ipv6 ? AF_INET6 : AF_INET;

    if (inet_pton(af, addr, dst) != 1) {
        return NULL;
    }
    
    return ne_iaddr_make(type, (unsigned char *)dst);
#elif defined(USE_GETADDRINFO) && !defined(HAVE_INET_PTON)
    /* For Windows, which lacks inet_pton(). */
    struct addrinfo *ai, *rv, hints;

    memset(&hints, 0, sizeof hints);
    hints.ai_socktype = SOCK_STREAM;
    hints.ai_flags = AI_NUMERICHOST;
    hints.ai_family = type == ne_iaddr_ipv6 ? AF_INET6 : AF_INET;
    
    if (getaddrinfo(addr, NULL, &hints, &ai)) {
        return NULL;
    }
    
    /* Copy the returned addrinfo, since it needs to be ne_free()-able
     * later; must only call freeaddrinfo() on ai. */
    rv = ne_calloc(sizeof *rv);
    memcpy(rv, ai, sizeof *rv);
    rv->ai_next = NULL;
    rv->ai_canonname = NULL;
    rv->ai_addr = ne_calloc(ai->ai_addrlen);
    memcpy(rv->ai_addr, ai->ai_addr, ai->ai_addrlen);
    freeaddrinfo(ai);
    
    return rv;    
#else /* !USE_GETADDRINFO */
    struct in_addr a;
    
    if (type == ne_iaddr_ipv6) {
        return NULL;
    }

#ifdef WIN32
    /* inet_addr() is broken because INADDR_NONE is a valid
     * broadcast address, so only use it on Windows. */
    a.s_addr = inet_addr(addr);
    if (a.s_addr == INADDR_NONE) {
        return NULL;
    }
#else /* !WIN32 */
    if (inet_aton(addr, &a) == 0) {
        return NULL;
    }
#endif
    
    return ne_iaddr_make(ne_iaddr_ipv4, (unsigned char *)&a.s_addr);
#endif /* !USE_GETADDRINFO */
}

int ne_iaddr_reverse(const ne_inet_addr *ia, char *buf, size_t bufsiz)
{
#ifdef USE_GETADDRINFO
    return getnameinfo(ia->ai_addr, ia->ai_addrlen, buf, bufsiz,
                       NULL, 0, 0);
#else
    struct hostent *hp;
    
    hp = gethostbyaddr(ia, sizeof *ia, AF_INET);
    if (hp && hp->h_name) {
        ne_strnzcpy(buf, hp->h_name, bufsiz);
        return 0;
    }
    return -1;
#endif
}

void ne_addr_destroy(ne_sock_addr *addr)
{
#ifdef USE_GETADDRINFO
    if (addr->result)
	freeaddrinfo(addr->result);
#else
    if (addr->addrs)
	ne_free(addr->addrs);
#endif
    ne_free(addr);
}

/* Perform a connect() for given fd, handling EINTR retries.  Returns
 * zero on success or -1 on failure, in which case, ne_errno is set
 * appropriately. */
static int raw_connect(int fd, const struct sockaddr *sa, size_t salen)
{
    int ret;

    do {
        ret = connect(fd, sa, salen);
    } while (ret < 0 && NE_ISINTR(ne_errno));

    return ret;
}

/* Perform a connect() for fd to address sa of length salen, with a
 * timeout if supported on this platform.  Returns zero on success or
 * NE_SOCK_* on failure, with sock->error set appropriately. */
static int timed_connect(ne_socket *sock, int fd,
                         const struct sockaddr *sa, size_t salen)
{
    int ret;

#ifdef USE_NONBLOCKING_CONNECT
    if (sock->cotimeout) {
        int errnum, flags;

        /* Get flags and then set O_NONBLOCK. */
        flags = fcntl(fd, F_GETFL);
        if (flags & O_NONBLOCK) {
            /* This socket was created using SOCK_NONBLOCK... flip the
             * bit for restoring flags later. */
            flags &= ~O_NONBLOCK;
        }
        else if (fcntl(fd, F_SETFL, flags | O_NONBLOCK) == -1) {
            set_strerror(sock, errno);
            return NE_SOCK_ERROR;
        }
        
        ret = raw_connect(fd, sa, salen);
        if (ret == -1) {
            errnum = ne_errno;
            if (NE_ISINPROGRESS(errnum)) {
                ret = raw_poll(fd, 1, sock->cotimeout);
                if (ret > 0) { /* poll got data */
                    socklen_t len = sizeof(errnum);
                    
                    /* Check whether there is a pending error for the
                     * socket.  Per Stevens UNPv1§15.4, Solaris will
                     * return a pending error via errno by failing the
                     * getsockopt() call. */

                    errnum = 0;
                    if (getsockopt(fd, SOL_SOCKET, SO_ERROR, &errnum, &len))
                        errnum = errno;
                    
                    if (errnum == 0) {
                        ret = 0;
                    } else {
                        set_strerror(sock, errnum);
                        ret = NE_SOCK_ERROR;
                    }
                } else if (ret == 0) { /* poll timed out */
                    set_error(sock, _("Connection timed out"));
                    ret = NE_SOCK_TIMEOUT;
                } else /* poll failed */ {
                    set_strerror(sock, errno);
                    ret = NE_SOCK_ERROR;
                }
            } else /* non-EINPROGRESS error from connect() */ { 
                set_strerror(sock, errnum);
                ret = NE_SOCK_ERROR;
            }
        }
        
        /* Reset to old flags: */
        if (fcntl(fd, F_SETFL, flags) == -1) {
            set_strerror(sock, errno);
            ret = NE_SOCK_ERROR;
        }       
    } else 
#endif /* USE_NONBLOCKING_CONNECT */
    {
        ret = raw_connect(fd, sa, salen);
        
        if (ret < 0) {
            set_strerror(sock, errno);
            ret = NE_SOCK_ERROR;
        }
    }

    return ret;
}

/* Connect socket to address 'addr' on given 'port'.  Returns zero on
 * success or NE_SOCK_* on failure with sock->error set
 * appropriately. */
static int connect_socket(ne_socket *sock, int fd,
                          const ne_inet_addr *addr, unsigned int port)
{
#ifdef USE_GETADDRINFO
#ifdef AF_INET6
    /* fill in the _family field for AIX 4.3, which forgets to do so. */
    if (addr->ai_family == AF_INET6) {
	struct sockaddr_in6 in6;
	memcpy(&in6, addr->ai_addr, sizeof in6);
	in6.sin6_port = port;
        in6.sin6_family = AF_INET6;
        return timed_connect(sock, fd, (struct sockaddr *)&in6, sizeof in6);
    } else
#endif
    if (addr->ai_family == AF_INET) {
	struct sockaddr_in in;
	memcpy(&in, addr->ai_addr, sizeof in);
	in.sin_port = port;
        in.sin_family = AF_INET;
        return timed_connect(sock, fd, (struct sockaddr *)&in, sizeof in);
    } else {
        set_strerror(sock, EINVAL);
        return NE_SOCK_ERROR;
    }
#else
    struct sockaddr_in sa = {0};
    sa.sin_family = AF_INET;
    sa.sin_port = port;
    sa.sin_addr = *addr;
    return timed_connect(sock, fd, (struct sockaddr *)&sa, sizeof sa);
#endif
}

ne_socket *ne_sock_create(void)
{
    ne_socket *sock = ne_calloc(sizeof *sock);
    sock->rdtimeout = SOCKET_READ_TIMEOUT;
    sock->cotimeout = 0;
    sock->bufpos = sock->buffer;
    sock->ops = &iofns_raw;
    sock->fd = -1;
    return sock;
}


#ifdef USE_GETADDRINFO
#define ia_family(a) ((a)->ai_family)
#define ia_proto(a)  ((a)->ai_protocol)
#else
#define ia_family(a) AF_INET
#define ia_proto(a)  0
#endif

void ne_sock_prebind(ne_socket *sock, const ne_inet_addr *addr,
                     unsigned int port)
{
    sock->lport = port;
    sock->laddr = addr ? addr : &dummy_laddr;    
}

/* Bind socket 'fd' to address/port 'addr' and 'port', for subsequent
 * connect() to address of family 'peer_family'. */
static int do_bind(int fd, int peer_family, 
                   const ne_inet_addr *addr, unsigned int port)
{
#if defined(HAVE_SETSOCKOPT) && defined(SO_REUSEADDR) && defined(SOL_SOCKET)
    {
        int flag = 1;

        (void) setsockopt(fd, SOL_SOCKET, SO_REUSEADDR, &flag, sizeof flag);
        /* An error here is not fatal, so ignore it. */
    }
#endif        
    

#if defined(USE_GETADDRINFO) && defined(AF_INET6)
    /* Use a sockaddr_in6 if an AF_INET6 local address is specifed, or
     * if no address is specified and the peer address is AF_INET6: */
    if ((addr != &dummy_laddr && addr->ai_family == AF_INET6)
        || (addr == &dummy_laddr && peer_family == AF_INET6)) {
        struct sockaddr_in6 in6;
        
        if (addr == &dummy_laddr)
            memset(&in6, 0, sizeof in6);
        else
            memcpy(&in6, addr->ai_addr, sizeof in6);
        in6.sin6_port = htons(port);
        /* fill in the _family field for AIX 4.3, which forgets to do so. */
        in6.sin6_family = AF_INET6;

        return bind(fd, (struct sockaddr *)&in6, sizeof in6);
    } else
#endif
    {
	struct sockaddr_in in;

        if (addr == &dummy_laddr)
            memset(&in, 0, sizeof in);
        else {
#ifdef USE_GETADDRINFO
            memcpy(&in, addr->ai_addr, sizeof in);
#else
            in.sin_addr = *addr;
#endif
        }
        in.sin_port = htons(port);
        in.sin_family = AF_INET;

        return bind(fd, (struct sockaddr *)&in, sizeof in);
    }
}

#ifdef SOCK_CLOEXEC
/* sock_cloexec is initialized to SOCK_CLOEXEC and cleared to zero if
 * a socket() call ever fails with EINVAL. */
static int sock_cloexec = SOCK_CLOEXEC;
#define RETRY_ON_EINVAL
#else
#define sock_cloexec 0
#endif

int ne_sock_connect(ne_socket *sock,
                    const ne_inet_addr *addr, unsigned int port)
{
    int fd, ret;
    int type = SOCK_STREAM | sock_cloexec;

#if defined(RETRY_ON_EINVAL) && defined(SOCK_NONBLOCK) \
    && defined(USE_NONBLOCKING_CONNECT)
    /* If the SOCK_NONBLOCK flag is defined, and the retry-on-EINVAL
     * logic is enabled, and the socket has a configured timeout, then
     * also use the SOCK_NONBLOCK flag to save enabling O_NONBLOCK
     * later. */
    if (sock->cotimeout && sock_cloexec) {
        type |= SOCK_NONBLOCK;
    }
#endif

    /* use SOCK_STREAM rather than ai_socktype: some getaddrinfo
     * implementations do not set ai_socktype, e.g. RHL6.2. */
    fd = socket(ia_family(addr), type, ia_proto(addr));
#ifdef RETRY_ON_EINVAL
    /* Handle forwards compat for new glibc on an older kernels; clear
     * the sock_cloexec flag and retry the call: */
    if (fd < 0 && sock_cloexec && errno == EINVAL) {
        sock_cloexec = 0;
        fd = socket(ia_family(addr), SOCK_STREAM, ia_proto(addr));
    }
#endif
    if (fd < 0) {
        set_strerror(sock, ne_errno);
	return -1;
    }
    
#if !defined(NE_USE_POLL) && !defined(WIN32)
    if (fd > FD_SETSIZE) {
        ne_close(fd);
        set_error(sock, _("Socket descriptor number exceeds FD_SETSIZE"));
        return NE_SOCK_ERROR;
    }
#endif
   
#if defined(HAVE_FCNTL) && defined(F_GETFD) && defined(F_SETFD) \
  && defined(FD_CLOEXEC)
    /* Set the FD_CLOEXEC bit for the new fd, if the socket was not
     * created with the CLOEXEC bit already set. */
    if (!sock_cloexec && (ret = fcntl(fd, F_GETFD)) >= 0) {
        fcntl(fd, F_SETFD, ret | FD_CLOEXEC);
        /* ignore failure; not a critical error. */
    }
#endif

    if (sock->laddr && (sock->laddr == &dummy_laddr || 
                        ia_family(sock->laddr) == ia_family(addr))) {
        ret = do_bind(fd, ia_family(addr), sock->laddr, sock->lport);
        if (ret < 0) {
            int errnum = errno;
            ne_close(fd);
            set_strerror(sock, errnum);
            return NE_SOCK_ERROR;
        }
    }

#if defined(HAVE_SETSOCKOPT) && (defined(TCP_NODELAY) || defined(WIN32))
    { /* Disable the Nagle algorithm. */
        int flag = 1;
        setsockopt(fd, IPPROTO_TCP, TCP_NODELAY, &flag, sizeof flag);
    }
#endif
    
    ret = connect_socket(sock, fd, addr, htons(port));
    if (ret == 0)
        sock->fd = fd;
    else
        ne_close(fd);

    return ret;
}

ne_inet_addr *ne_sock_peer(ne_socket *sock, unsigned int *port)
{
    union saun {
        struct sockaddr sa;
        struct sockaddr_in sin;
#if defined(USE_GETADDRINFO) && defined(AF_INET6)
        struct sockaddr_in6 sin6;
#endif
    } saun;
    socklen_t len = sizeof saun;
    ne_inet_addr *ia;
    struct sockaddr *sad = (struct sockaddr *)&saun;

    if (getpeername(sock->fd, sad, &len) != 0) {
        set_strerror(sock, errno);
        return NULL;
    }

#if !defined(USE_GETADDRINFO) || !defined(AF_INET6)
    if (sad->sa_family != AF_INET) {
        set_error(sock, _("Socket family not supported"));
        return NULL;
    }
#endif                  

    ia = ne_calloc(sizeof *ia);
#ifdef USE_GETADDRINFO
    ia->ai_addr = ne_malloc(sizeof *ia);
    ia->ai_addrlen = len;
    memcpy(ia->ai_addr, sad, len);
    ia->ai_family = saun.sa.sa_family;
#else
    memcpy(ia, &saun.sin.sin_addr.s_addr, sizeof *ia);
#endif    

#if defined(USE_GETADDRINFO) && defined(AF_INET6)
    *port = ntohs(saun.sa.sa_family == AF_INET ? 
                  saun.sin.sin_port : saun.sin6.sin6_port);
#else
    *port = ntohs(saun.sin.sin_port);
#endif

    return ia;
}

ne_inet_addr *ne_iaddr_make(ne_iaddr_type type, const unsigned char *raw)
{
    ne_inet_addr *ia;
#if !defined(AF_INET6) || !defined(USE_GETADDRINFO)
    /* fail if IPv6 address is given if IPv6 is not supported. */
    if (type == ne_iaddr_ipv6)
	return NULL;
#endif
    ia = ne_calloc(sizeof *ia);
#ifdef USE_GETADDRINFO
    /* ai_protocol and ai_socktype aren't used by connect_socket() so
     * ignore them here. (for now) */
    if (type == ne_iaddr_ipv4) {
	struct sockaddr_in *in4 = ne_calloc(sizeof *in4);
	ia->ai_family = AF_INET;
	ia->ai_addr = (struct sockaddr *)in4;
	ia->ai_addrlen = sizeof *in4;
	in4->sin_family = AF_INET;
	memcpy(&in4->sin_addr.s_addr, raw, sizeof in4->sin_addr.s_addr);
    }
#ifdef AF_INET6
    else {
	struct sockaddr_in6 *in6 = ne_calloc(sizeof *in6);
	ia->ai_family = AF_INET6;
	ia->ai_addr = (struct sockaddr *)in6;
	ia->ai_addrlen = sizeof *in6;
	in6->sin6_family = AF_INET6;
	memcpy(&in6->sin6_addr, raw, sizeof in6->sin6_addr.s6_addr);
    }
#endif
#else /* !USE_GETADDRINFO */
    memcpy(&ia->s_addr, raw, sizeof ia->s_addr);
#endif    
    return ia;
}

ne_iaddr_type ne_iaddr_typeof(const ne_inet_addr *ia)
{
#if defined(USE_GETADDRINFO) && defined(AF_INET6)
    return ia->ai_family == AF_INET6 ? ne_iaddr_ipv6 : ne_iaddr_ipv4;
#else
    return ne_iaddr_ipv4;
#endif
}

int ne_iaddr_cmp(const ne_inet_addr *i1, const ne_inet_addr *i2)
{
#ifdef USE_GETADDRINFO
    if (i1->ai_family != i2->ai_family)
	return i2->ai_family - i1->ai_family;
    if (i1->ai_family == AF_INET) {
	struct sockaddr_in *in1 = SACAST(in, i1->ai_addr), 
	    *in2 = SACAST(in, i2->ai_addr);
	return memcmp(&in1->sin_addr.s_addr, &in2->sin_addr.s_addr, 
		      sizeof in1->sin_addr.s_addr);
    } 
#ifdef AF_INET6
    else if (i1->ai_family == AF_INET6) {
	struct sockaddr_in6 *in1 = SACAST(in6, i1->ai_addr), 
	    *in2 = SACAST(in6, i2->ai_addr);
	return memcmp(in1->sin6_addr.s6_addr, in2->sin6_addr.s6_addr,
		      sizeof in1->sin6_addr.s6_addr);
    } 
#endif /* AF_INET6 */
    else
	return -1;
#else
    return memcmp(&i1->s_addr, &i2->s_addr, sizeof i1->s_addr);
#endif /* USE_GETADDRINFO */
}

void ne_iaddr_free(ne_inet_addr *addr)
{
#ifdef USE_GETADDRINFO
    ne_free(addr->ai_addr);
#endif
    ne_free(addr);
}

int ne_sock_accept(ne_socket *sock, int listener) 
{
    int fd = accept(listener, NULL, NULL);

    if (fd < 0)
        return -1;

    sock->fd = fd;
    return 0;
}

int ne_sock_fd(const ne_socket *sock)
{
    return sock->fd;
}

void ne_sock_read_timeout(ne_socket *sock, int timeout)
{
    sock->rdtimeout = timeout;
}

void ne_sock_connect_timeout(ne_socket *sock, int timeout)
{
    sock->cotimeout = timeout;
}

#ifdef NE_HAVE_SSL

#ifdef HAVE_GNUTLS
/* Dumb server session cache implementation for GNUTLS; holds a single
 * session. */

/* Copy datum 'src' to 'dest'. */
static void copy_datum(gnutls_datum *dest, gnutls_datum *src)
{
    dest->size = src->size;
    dest->data = memcpy(gnutls_malloc(src->size), src->data, src->size);
}

/* Callback to store a session 'data' with id 'key'. */
static int store_sess(void *userdata, gnutls_datum key, gnutls_datum data)
{
    ne_ssl_context *ctx = userdata;

    if (ctx->cache.server.key.data) { 
        gnutls_free(ctx->cache.server.key.data);
        gnutls_free(ctx->cache.server.data.data);
    }

    copy_datum(&ctx->cache.server.key, &key);
    copy_datum(&ctx->cache.server.data, &data);

    return 0;
}

/* Returns non-zero if d1 and d2 are the same datum. */
static int match_datum(gnutls_datum *d1, gnutls_datum *d2)
{
    return d1->size == d2->size
        && memcmp(d1->data, d2->data, d1->size) == 0;
}

/* Callback to retrieve a session of id 'key'. */
static gnutls_datum retrieve_sess(void *userdata, gnutls_datum key)
{
    ne_ssl_context *ctx = userdata;
    gnutls_datum ret = { NULL, 0 };

    if (match_datum(&ctx->cache.server.key, &key)) {
        copy_datum(&ret, &ctx->cache.server.data);
    }

    return ret;
}

/* Callback to remove a session of id 'key'; stub needed but
 * implementation seems unnecessary. */
static int remove_sess(void *userdata, gnutls_datum key)
{
    return -1;
}
#endif

int ne_sock_accept_ssl(ne_socket *sock, ne_ssl_context *ctx)
{
    int ret;
    ne_ssl_socket ssl;

#if defined(HAVE_OPENSSL)
    ssl = SSL_new(ctx->ctx);
    
    SSL_set_fd(ssl, sock->fd);

    sock->ssl = ssl;
    ret = SSL_accept(ssl);
    if (ret != 1) {
        return error_ossl(sock, ret);
    }

    if (SSL_session_reused(ssl)) {
        NE_DEBUG(NE_DBG_SSL, "ssl: Server reused session.\n");
    }
#elif defined(HAVE_GNUTLS)
    gnutls_init(&ssl, GNUTLS_SERVER);
    gnutls_credentials_set(ssl, GNUTLS_CRD_CERTIFICATE, ctx->cred);
    gnutls_set_default_priority(ssl);

    /* Set up dummy session cache. */
    gnutls_db_set_store_function(ssl, store_sess);
    gnutls_db_set_retrieve_function(ssl, retrieve_sess);    
    gnutls_db_set_remove_function(ssl, remove_sess);    
    gnutls_db_set_ptr(ssl, ctx);

    if (ctx->verify)
        gnutls_certificate_server_set_request(ssl, GNUTLS_CERT_REQUEST);

    sock->ssl = ssl;
    gnutls_transport_set_ptr(sock->ssl, (gnutls_transport_ptr)(long)sock->fd);
    ret = gnutls_handshake(ssl);
    if (ret < 0) {
        return error_gnutls(sock, ret);
    }
    if (ctx->verify && gnutls_certificate_verify_peers(ssl)) {
        set_error(sock, _("Client certificate verification failed"));
        return NE_SOCK_ERROR;
    }
#endif
    sock->ops = &iofns_ssl;
    return 0;
}

int ne_sock_connect_ssl(ne_socket *sock, ne_ssl_context *ctx, void *userdata)
{
    int ret;

#if defined(HAVE_OPENSSL)
    SSL *ssl;

    if (seed_ssl_prng()) {
	set_error(sock, _("SSL disabled due to lack of entropy"));
	return NE_SOCK_ERROR;
    }

    /* If runtime library version differs from compile-time version
     * number in major/minor/fix level, abort soon. */
    if ((SSLeay() ^ OPENSSL_VERSION_NUMBER) & 0xFFFFF000) {
        set_error(sock, _("SSL disabled due to library version mismatch"));
        return NE_SOCK_ERROR;
    }

    sock->ssl = ssl = SSL_new(ctx->ctx);
    if (!ssl) {
	set_error(sock, _("Could not create SSL structure"));
	return NE_SOCK_ERROR;
    }
    
    SSL_set_app_data(ssl, userdata);
    SSL_set_mode(ssl, SSL_MODE_AUTO_RETRY);
    SSL_set_fd(ssl, sock->fd);
    sock->ops = &iofns_ssl;

#ifdef SSL_set_tlsext_host_name
    if (ctx->hostname) {
        /* Try to enable SNI, but ignore failure (should only fail for
         * >255 char hostnames, which are probably not legal
         * anyway).  */
        if (SSL_set_tlsext_host_name(ssl, ctx->hostname) != 1) {
            ERR_clear_error();
        }
    }
#endif
    
    if (ctx->sess)
	SSL_set_session(ssl, ctx->sess);

    ret = SSL_connect(ssl);
    if (ret != 1) {
	error_ossl(sock, ret);
	SSL_free(ssl);
	sock->ssl = NULL;
	return NE_SOCK_ERROR;
    }
#elif defined(HAVE_GNUTLS)
    /* DH and RSA params are set in ne_ssl_context_create */
    gnutls_init(&sock->ssl, GNUTLS_CLIENT);
    gnutls_set_default_priority(sock->ssl);
    gnutls_session_set_ptr(sock->ssl, userdata);
    gnutls_credentials_set(sock->ssl, GNUTLS_CRD_CERTIFICATE, ctx->cred);

#ifdef HAVE_GNUTLS_SIGN_CALLBACK_SET
    if (ctx->sign_func)
        gnutls_sign_callback_set(sock->ssl, ctx->sign_func, ctx->sign_data);    
#endif

    if (ctx->hostname) {
        gnutls_server_name_set(sock->ssl, GNUTLS_NAME_DNS, ctx->hostname,
                               strlen(ctx->hostname));
    }                               

    gnutls_transport_set_ptr(sock->ssl, (gnutls_transport_ptr)(long)sock->fd);

    if (ctx->cache.client.data) {
#if defined(HAVE_GNUTLS_SESSION_GET_DATA2)
        gnutls_session_set_data(sock->ssl, 
                                ctx->cache.client.data, 
                                ctx->cache.client.size);
#else
        gnutls_session_set_data(sock->ssl, 
                                ctx->cache.client.data, 
                                ctx->cache.client.len);
#endif
    }
    sock->ops = &iofns_ssl;

    ret = gnutls_handshake(sock->ssl);
    if (ret < 0) {
	error_gnutls(sock, ret);
        return NE_SOCK_ERROR;
    }

    if (!gnutls_session_is_resumed(sock->ssl)) {
        /* New session.  The old method of using the _get_data
         * function seems to be broken with 1.3.0 and later*/
#if defined(HAVE_GNUTLS_SESSION_GET_DATA2)
        gnutls_session_get_data2(sock->ssl, &ctx->cache.client);
#else
        ctx->cache.client.len = 0;
        if (gnutls_session_get_data(sock->ssl, NULL, 
                                    &ctx->cache.client.len) == 0) {
            ctx->cache.client.data = ne_malloc(ctx->cache.client.len);
            gnutls_session_get_data(sock->ssl, ctx->cache.client.data, 
                                    &ctx->cache.client.len);
        }
#endif
    }
#endif
    return 0;
}

ne_ssl_socket ne__sock_sslsock(ne_socket *sock)
{
    return sock->ssl;
}

#endif

int ne_sock_sessid(ne_socket *sock, unsigned char *buf, size_t *buflen)
{
#ifdef NE_HAVE_SSL
#ifdef HAVE_GNUTLS
    if (sock->ssl) {
        return gnutls_session_get_id(sock->ssl, buf, buflen);
    } else {
        return -1;
    }
#else
    SSL_SESSION *sess;

    if (!sock->ssl) {
        return -1;
    }

    sess = SSL_get0_session(sock->ssl);

    if (!buf) {
        *buflen = sess->session_id_length;
        return 0;
    }

    if (*buflen < sess->session_id_length) {
        return -1;
    }

    *buflen = sess->session_id_length;
    memcpy(buf, sess->session_id, *buflen);
    return 0;
#endif
#else
    return -1;
#endif
}

char *ne_sock_cipher(ne_socket *sock)
{
#ifdef NE_HAVE_SSL
    if (sock->ssl) {
#ifdef HAVE_OPENSSL
        const char *name = SSL_get_cipher(sock->ssl);
        return ne_strdup(name);
#elif defined(HAVE_GNUTLS)
        const char *name = gnutls_cipher_get_name(gnutls_cipher_get(sock->ssl));
        return ne_strdup(name);
#endif
    }
    else 
#endif /* NE_HAVE_SSL */
    {
        return NULL;
    }    
}

const char *ne_sock_error(const ne_socket *sock)
{
    return sock->error;
}

void ne_sock_set_error(ne_socket *sock, const char *format, ...)
{
    va_list params;

    va_start(params, format);
    ne_vsnprintf(sock->error, sizeof sock->error, format, params);
    va_end(params);
}

/* Closes given ne_socket */
int ne_sock_close(ne_socket *sock)
{
    int ret;

#if defined(HAVE_OPENSSL)
    if (sock->ssl) {
        /* Correct SSL shutdown procedure: call once... */
        if (SSL_shutdown(sock->ssl) == 0) {
            /* close_notify sent but not received; wait for peer to
             * send close_notify... */
            SSL_shutdown(sock->ssl);
        }
	SSL_free(sock->ssl);
    }
#elif defined(HAVE_GNUTLS)
    if (sock->ssl) {
        do {
            ret = gnutls_bye(sock->ssl, GNUTLS_SHUT_RDWR);
        } while (ret < 0
                 && (ret == GNUTLS_E_INTERRUPTED || ret == GNUTLS_E_AGAIN));
    }
#endif

    if (sock->fd < 0)
        ret = 0;
    else
        ret = ne_close(sock->fd);
    ne_free(sock);
    return ret;
}