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review.jami.net / pjproject / 78531d79a3692b6548bc93646598b10ebb25c8f8 / . / pjlib / src / pj / sock_bsd.c
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/* $Id$ */
/*
* Copyright (C) 2008-2009 Teluu Inc. (http://www.teluu.com)
* Copyright (C) 2003-2008 Benny Prijono <benny@prijono.org>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#include <pj/sock.h>
#include <pj/os.h>
#include <pj/assert.h>
#include <pj/string.h>
#include <pj/compat/socket.h>
#include <pj/addr_resolv.h>
#include <pj/errno.h>
#include <pj/unicode.h>
/*
* Address families conversion.
* The values here are indexed based on pj_addr_family.
*/
const pj_uint16_t PJ_AF_UNSPEC = AF_UNSPEC;
const pj_uint16_t PJ_AF_UNIX = AF_UNIX;
const pj_uint16_t PJ_AF_INET = AF_INET;
const pj_uint16_t PJ_AF_INET6 = AF_INET6;
#ifdef AF_PACKET
const pj_uint16_t PJ_AF_PACKET = AF_PACKET;
#else
const pj_uint16_t PJ_AF_PACKET = 0xFFFF;
#endif
#ifdef AF_IRDA
const pj_uint16_t PJ_AF_IRDA = AF_IRDA;
#else
const pj_uint16_t PJ_AF_IRDA = 0xFFFF;
#endif
/*
* Socket types conversion.
* The values here are indexed based on pj_sock_type
*/
const pj_uint16_t PJ_SOCK_STREAM= SOCK_STREAM;
const pj_uint16_t PJ_SOCK_DGRAM = SOCK_DGRAM;
const pj_uint16_t PJ_SOCK_RAW = SOCK_RAW;
const pj_uint16_t PJ_SOCK_RDM = SOCK_RDM;
/*
* Socket level values.
*/
const pj_uint16_t PJ_SOL_SOCKET = SOL_SOCKET;
#ifdef SOL_IP
const pj_uint16_t PJ_SOL_IP = SOL_IP;
#elif defined(PJ_WIN32) && PJ_WIN32
const pj_uint16_t PJ_SOL_IP = IPPROTO_IP;
#else
const pj_uint16_t PJ_SOL_IP = 0xFFFF;
#endif /* SOL_IP */
#if defined(SOL_TCP)
const pj_uint16_t PJ_SOL_TCP = SOL_TCP;
#elif defined(IPPROTO_TCP)
const pj_uint16_t PJ_SOL_TCP = IPPROTO_TCP;
#elif defined(PJ_WIN32) && PJ_WIN32
const pj_uint16_t PJ_SOL_TCP = IPPROTO_TCP;
#else
const pj_uint16_t PJ_SOL_TCP = 0xFFFF;
#endif /* SOL_TCP */
#ifdef SOL_UDP
const pj_uint16_t PJ_SOL_UDP = SOL_UDP;
#elif defined(IPPROTO_UDP)
const pj_uint16_t PJ_SOL_UDP = IPPROTO_UDP;
#elif defined(PJ_WIN32) && PJ_WIN32
const pj_uint16_t PJ_SOL_UDP = IPPROTO_UDP;
#else
const pj_uint16_t PJ_SOL_UDP = 0xFFFF;
#endif /* SOL_UDP */
#ifdef SOL_IPV6
const pj_uint16_t PJ_SOL_IPV6 = SOL_IPV6;
#elif defined(PJ_WIN32) && PJ_WIN32
# if defined(IPPROTO_IPV6) || (_WIN32_WINNT >= 0x0501)
const pj_uint16_t PJ_SOL_IPV6 = IPPROTO_IPV6;
# else
const pj_uint16_t PJ_SOL_IPV6 = 41;
# endif
#else
const pj_uint16_t PJ_SOL_IPV6 = 0xFFFF;
#endif /* SOL_IPV6 */
/* IP_TOS */
#ifdef IP_TOS
const pj_uint16_t PJ_IP_TOS = IP_TOS;
#else
const pj_uint16_t PJ_IP_TOS = 1;
#endif
/* TOS settings (declared in netinet/ip.h) */
#ifdef IPTOS_LOWDELAY
const pj_uint16_t PJ_IPTOS_LOWDELAY = IPTOS_LOWDELAY;
#else
const pj_uint16_t PJ_IPTOS_LOWDELAY = 0x10;
#endif
#ifdef IPTOS_THROUGHPUT
const pj_uint16_t PJ_IPTOS_THROUGHPUT = IPTOS_THROUGHPUT;
#else
const pj_uint16_t PJ_IPTOS_THROUGHPUT = 0x08;
#endif
#ifdef IPTOS_RELIABILITY
const pj_uint16_t PJ_IPTOS_RELIABILITY = IPTOS_RELIABILITY;
#else
const pj_uint16_t PJ_IPTOS_RELIABILITY = 0x04;
#endif
#ifdef IPTOS_MINCOST
const pj_uint16_t PJ_IPTOS_MINCOST = IPTOS_MINCOST;
#else
const pj_uint16_t PJ_IPTOS_MINCOST = 0x02;
#endif
/* optname values. */
const pj_uint16_t PJ_SO_TYPE = SO_TYPE;
const pj_uint16_t PJ_SO_RCVBUF = SO_RCVBUF;
const pj_uint16_t PJ_SO_SNDBUF = SO_SNDBUF;
const pj_uint16_t PJ_TCP_NODELAY= TCP_NODELAY;
const pj_uint16_t PJ_SO_REUSEADDR= SO_REUSEADDR;
/* Multicasting is not supported e.g. in PocketPC 2003 SDK */
#ifdef IP_MULTICAST_IF
const pj_uint16_t PJ_IP_MULTICAST_IF = IP_MULTICAST_IF;
const pj_uint16_t PJ_IP_MULTICAST_TTL = IP_MULTICAST_TTL;
const pj_uint16_t PJ_IP_MULTICAST_LOOP = IP_MULTICAST_LOOP;
const pj_uint16_t PJ_IP_ADD_MEMBERSHIP = IP_ADD_MEMBERSHIP;
const pj_uint16_t PJ_IP_DROP_MEMBERSHIP = IP_DROP_MEMBERSHIP;
#else
const pj_uint16_t PJ_IP_MULTICAST_IF = 0xFFFF;
const pj_uint16_t PJ_IP_MULTICAST_TTL = 0xFFFF;
const pj_uint16_t PJ_IP_MULTICAST_LOOP = 0xFFFF;
const pj_uint16_t PJ_IP_ADD_MEMBERSHIP = 0xFFFF;
const pj_uint16_t PJ_IP_DROP_MEMBERSHIP = 0xFFFF;
#endif
/* recv() and send() flags */
const int PJ_MSG_OOB = MSG_OOB;
const int PJ_MSG_PEEK = MSG_PEEK;
const int PJ_MSG_DONTROUTE = MSG_DONTROUTE;
#if 0
static void CHECK_ADDR_LEN(const pj_sockaddr *addr, int len)
{
pj_sockaddr *a = (pj_sockaddr*)addr;
pj_assert((a->addr.sa_family==PJ_AF_INET && len==sizeof(pj_sockaddr_in)) ||
(a->addr.sa_family==PJ_AF_INET6 && len==sizeof(pj_sockaddr_in6)));
}
#else
#define CHECK_ADDR_LEN(addr,len)
#endif
/*
* Convert 16-bit value from network byte order to host byte order.
*/
PJ_DEF(pj_uint16_t) pj_ntohs(pj_uint16_t netshort)
{
return ntohs(netshort);
}
/*
* Convert 16-bit value from host byte order to network byte order.
*/
PJ_DEF(pj_uint16_t) pj_htons(pj_uint16_t hostshort)
{
return htons(hostshort);
}
/*
* Convert 32-bit value from network byte order to host byte order.
*/
PJ_DEF(pj_uint32_t) pj_ntohl(pj_uint32_t netlong)
{
return ntohl(netlong);
}
/*
* Convert 32-bit value from host byte order to network byte order.
*/
PJ_DEF(pj_uint32_t) pj_htonl(pj_uint32_t hostlong)
{
return htonl(hostlong);
}
/*
* Convert an Internet host address given in network byte order
* to string in standard numbers and dots notation.
*/
PJ_DEF(char*) pj_inet_ntoa(pj_in_addr inaddr)
{
#if !defined(PJ_LINUX) && !defined(PJ_LINUX_KERNEL)
return inet_ntoa(*(struct in_addr*)&inaddr);
#else
struct in_addr addr;
addr.s_addr = inaddr.s_addr;
return inet_ntoa(addr);
#endif
}
/*
* This function converts the Internet host address cp from the standard
* numbers-and-dots notation into binary data and stores it in the structure
* that inp points to.
*/
PJ_DEF(int) pj_inet_aton(const pj_str_t *cp, struct pj_in_addr *inp)
{
char tempaddr[PJ_INET_ADDRSTRLEN];
/* Initialize output with PJ_INADDR_NONE.
* Some apps relies on this instead of the return value
* (and anyway the return value is quite confusing!)
*/
inp->s_addr = PJ_INADDR_NONE;
/* Caution:
* this function might be called with cp->slen >= 16
* (i.e. when called with hostname to check if it's an IP addr).
*/
PJ_ASSERT_RETURN(cp && cp->slen && inp, 0);
if (cp->slen >= PJ_INET_ADDRSTRLEN) {
return 0;
}
pj_memcpy(tempaddr, cp->ptr, cp->slen);
tempaddr[cp->slen] = '\0';
#if defined(PJ_SOCK_HAS_INET_ATON) && PJ_SOCK_HAS_INET_ATON != 0
return inet_aton(tempaddr, (struct in_addr*)inp);
#else
inp->s_addr = inet_addr(tempaddr);
return inp->s_addr == PJ_INADDR_NONE ? 0 : 1;
#endif
}
/*
* Convert text to IPv4/IPv6 address.
*/
PJ_DEF(pj_status_t) pj_inet_pton(int af, const pj_str_t *src, void *dst)
{
char tempaddr[PJ_INET6_ADDRSTRLEN];
PJ_ASSERT_RETURN(af==PJ_AF_INET || af==PJ_AF_INET6, PJ_EAFNOTSUP);
PJ_ASSERT_RETURN(src && src->slen && dst, PJ_EINVAL);
/* Initialize output with PJ_IN_ADDR_NONE for IPv4 (to be
* compatible with pj_inet_aton()
*/
if (af==PJ_AF_INET) {
((pj_in_addr*)dst)->s_addr = PJ_INADDR_NONE;
}
/* Caution:
* this function might be called with cp->slen >= 46
* (i.e. when called with hostname to check if it's an IP addr).
*/
if (src->slen >= PJ_INET6_ADDRSTRLEN) {
return PJ_ENAMETOOLONG;
}
pj_memcpy(tempaddr, src->ptr, src->slen);
tempaddr[src->slen] = '\0';
#if defined(PJ_SOCK_HAS_INET_PTON) && PJ_SOCK_HAS_INET_PTON != 0
/*
* Implementation using inet_pton()
*/
if (inet_pton(af, tempaddr, dst) != 1) {
pj_status_t status = pj_get_netos_error();
if (status == PJ_SUCCESS)
status = PJ_EUNKNOWN;
return status;
}
return PJ_SUCCESS;
#elif defined(PJ_WIN32) || defined(PJ_WIN32_WINCE)
/*
* Implementation on Windows, using WSAStringToAddress().
* Should also work on Unicode systems.
*/
{
PJ_DECL_UNICODE_TEMP_BUF(wtempaddr,PJ_INET6_ADDRSTRLEN)
pj_sockaddr sock_addr;
int addr_len = sizeof(sock_addr);
int rc;
sock_addr.addr.sa_family = (pj_uint16_t)af;
rc = WSAStringToAddress(
PJ_STRING_TO_NATIVE(tempaddr,wtempaddr,sizeof(wtempaddr)),
af, NULL, (LPSOCKADDR)&sock_addr, &addr_len);
if (rc != 0) {
/* If you get rc 130022 Invalid argument (WSAEINVAL) with IPv6,
* check that you have IPv6 enabled (install it in the network
* adapter).
*/
pj_status_t status = pj_get_netos_error();
if (status == PJ_SUCCESS)
status = PJ_EUNKNOWN;
return status;
}
if (sock_addr.addr.sa_family == PJ_AF_INET) {
pj_memcpy(dst, &sock_addr.ipv4.sin_addr, 4);
return PJ_SUCCESS;
} else if (sock_addr.addr.sa_family == PJ_AF_INET6) {
pj_memcpy(dst, &sock_addr.ipv6.sin6_addr, 16);
return PJ_SUCCESS;
} else {
pj_assert(!"Shouldn't happen");
return PJ_EBUG;
}
}
#elif !defined(PJ_HAS_IPV6) || PJ_HAS_IPV6==0
/* IPv6 support is disabled, just return error without raising assertion */
return PJ_EIPV6NOTSUP;
#else
pj_assert(!"Not supported");
return PJ_EIPV6NOTSUP;
#endif
}
/*
* Convert IPv4/IPv6 address to text.
*/
PJ_DEF(pj_status_t) pj_inet_ntop(int af, const void *src,
char *dst, int size)
{
PJ_ASSERT_RETURN(src && dst && size, PJ_EINVAL);
*dst = '\0';
PJ_ASSERT_RETURN(af==PJ_AF_INET || af==PJ_AF_INET6, PJ_EAFNOTSUP);
#if defined(PJ_SOCK_HAS_INET_NTOP) && PJ_SOCK_HAS_INET_NTOP != 0
/*
* Implementation using inet_ntop()
*/
if (inet_ntop(af, src, dst, size) == NULL) {
pj_status_t status = pj_get_netos_error();
if (status == PJ_SUCCESS)
status = PJ_EUNKNOWN;
return status;
}
return PJ_SUCCESS;
#elif defined(PJ_WIN32) || defined(PJ_WIN32_WINCE)
/*
* Implementation on Windows, using WSAAddressToString().
* Should also work on Unicode systems.
*/
{
PJ_DECL_UNICODE_TEMP_BUF(wtempaddr,PJ_INET6_ADDRSTRLEN)
pj_sockaddr sock_addr;
DWORD addr_len, addr_str_len;
int rc;
pj_bzero(&sock_addr, sizeof(sock_addr));
sock_addr.addr.sa_family = (pj_uint16_t)af;
if (af == PJ_AF_INET) {
if (size < PJ_INET_ADDRSTRLEN)
return PJ_ETOOSMALL;
pj_memcpy(&sock_addr.ipv4.sin_addr, src, 4);
addr_len = sizeof(pj_sockaddr_in);
addr_str_len = PJ_INET_ADDRSTRLEN;
} else if (af == PJ_AF_INET6) {
if (size < PJ_INET6_ADDRSTRLEN)
return PJ_ETOOSMALL;
pj_memcpy(&sock_addr.ipv6.sin6_addr, src, 16);
addr_len = sizeof(pj_sockaddr_in6);
addr_str_len = PJ_INET6_ADDRSTRLEN;
} else {
pj_assert(!"Unsupported address family");
return PJ_EAFNOTSUP;
}
#if PJ_NATIVE_STRING_IS_UNICODE
rc = WSAAddressToString((LPSOCKADDR)&sock_addr, addr_len,
NULL, wtempaddr, &addr_str_len);
if (rc == 0) {
pj_unicode_to_ansi(wtempaddr, wcslen(wtempaddr), dst, size);
}
#else
rc = WSAAddressToString((LPSOCKADDR)&sock_addr, addr_len,
NULL, dst, &addr_str_len);
#endif
if (rc != 0) {
pj_status_t status = pj_get_netos_error();
if (status == PJ_SUCCESS)
status = PJ_EUNKNOWN;
return status;
}
return PJ_SUCCESS;
}
#elif !defined(PJ_HAS_IPV6) || PJ_HAS_IPV6==0
/* IPv6 support is disabled, just return error without raising assertion */
return PJ_EIPV6NOTSUP;
#else
pj_assert(!"Not supported");
return PJ_EIPV6NOTSUP;
#endif
}
/*
* Get hostname.
*/
PJ_DEF(const pj_str_t*) pj_gethostname(void)
{
static char buf[PJ_MAX_HOSTNAME];
static pj_str_t hostname;
PJ_CHECK_STACK();
if (hostname.ptr == NULL) {
hostname.ptr = buf;
if (gethostname(buf, sizeof(buf)) != 0) {
hostname.ptr[0] = '\0';
hostname.slen = 0;
} else {
hostname.slen = strlen(buf);
}
}
return &hostname;
}
#if defined(PJ_WIN32)
/*
* Create new socket/endpoint for communication and returns a descriptor.
*/
PJ_DEF(pj_status_t) pj_sock_socket(int af,
int type,
int proto,
pj_sock_t *sock)
{
PJ_CHECK_STACK();
/* Sanity checks. */
PJ_ASSERT_RETURN(sock!=NULL, PJ_EINVAL);
PJ_ASSERT_RETURN((unsigned)PJ_INVALID_SOCKET==INVALID_SOCKET,
(*sock=PJ_INVALID_SOCKET, PJ_EINVAL));
*sock = WSASocket(af, type, proto, NULL, 0, WSA_FLAG_OVERLAPPED);
if (*sock == PJ_INVALID_SOCKET)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else
return PJ_SUCCESS;
}
#else
/*
* Create new socket/endpoint for communication and returns a descriptor.
*/
PJ_DEF(pj_status_t) pj_sock_socket(int af,
int type,
int proto,
pj_sock_t *sock)
{
PJ_CHECK_STACK();
/* Sanity checks. */
PJ_ASSERT_RETURN(sock!=NULL, PJ_EINVAL);
PJ_ASSERT_RETURN(PJ_INVALID_SOCKET==-1,
(*sock=PJ_INVALID_SOCKET, PJ_EINVAL));
*sock = socket(af, type, proto);
if (*sock == PJ_INVALID_SOCKET)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else
return PJ_SUCCESS;
}
#endif
/*
* Bind socket.
*/
PJ_DEF(pj_status_t) pj_sock_bind( pj_sock_t sock,
const pj_sockaddr_t *addr,
int len)
{
PJ_CHECK_STACK();
PJ_ASSERT_RETURN(addr && len >= (int)sizeof(struct sockaddr_in), PJ_EINVAL);
CHECK_ADDR_LEN(addr, len);
if (bind(sock, (struct sockaddr*)addr, len) != 0)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else
return PJ_SUCCESS;
}
/*
* Bind socket.
*/
PJ_DEF(pj_status_t) pj_sock_bind_in( pj_sock_t sock,
pj_uint32_t addr32,
pj_uint16_t port)
{
pj_sockaddr_in addr;
PJ_CHECK_STACK();
PJ_SOCKADDR_SET_LEN(&addr, sizeof(pj_sockaddr_in));
addr.sin_family = PJ_AF_INET;
pj_bzero(addr.sin_zero, sizeof(addr.sin_zero));
addr.sin_addr.s_addr = pj_htonl(addr32);
addr.sin_port = pj_htons(port);
return pj_sock_bind(sock, &addr, sizeof(pj_sockaddr_in));
}
/*
* Close socket.
*/
PJ_DEF(pj_status_t) pj_sock_close(pj_sock_t sock)
{
int rc;
PJ_CHECK_STACK();
#if defined(PJ_WIN32) && PJ_WIN32!=0 || \
defined(PJ_WIN32_WINCE) && PJ_WIN32_WINCE!=0
rc = closesocket(sock);
#else
rc = close(sock);
#endif
if (rc != 0)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else
return PJ_SUCCESS;
}
/*
* Get remote's name.
*/
PJ_DEF(pj_status_t) pj_sock_getpeername( pj_sock_t sock,
pj_sockaddr_t *addr,
int *namelen)
{
PJ_CHECK_STACK();
if (getpeername(sock, (struct sockaddr*)addr, (socklen_t*)namelen) != 0)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else {
PJ_SOCKADDR_RESET_LEN(addr);
return PJ_SUCCESS;
}
}
/*
* Get socket name.
*/
PJ_DEF(pj_status_t) pj_sock_getsockname( pj_sock_t sock,
pj_sockaddr_t *addr,
int *namelen)
{
PJ_CHECK_STACK();
if (getsockname(sock, (struct sockaddr*)addr, (socklen_t*)namelen) != 0)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else {
PJ_SOCKADDR_RESET_LEN(addr);
return PJ_SUCCESS;
}
}
/*
* Send data
*/
PJ_DEF(pj_status_t) pj_sock_send(pj_sock_t sock,
const void *buf,
pj_ssize_t *len,
unsigned flags)
{
PJ_CHECK_STACK();
PJ_ASSERT_RETURN(len, PJ_EINVAL);
*len = send(sock, (const char*)buf, *len, flags);
if (*len < 0)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else
return PJ_SUCCESS;
}
/*
* Send data.
*/
PJ_DEF(pj_status_t) pj_sock_sendto(pj_sock_t sock,
const void *buf,
pj_ssize_t *len,
unsigned flags,
const pj_sockaddr_t *to,
int tolen)
{
PJ_CHECK_STACK();
PJ_ASSERT_RETURN(len, PJ_EINVAL);
CHECK_ADDR_LEN(to, tolen);
*len = sendto(sock, (const char*)buf, *len, flags,
(const struct sockaddr*)to, tolen);
if (*len < 0)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else
return PJ_SUCCESS;
}
/*
* Receive data.
*/
PJ_DEF(pj_status_t) pj_sock_recv(pj_sock_t sock,
void *buf,
pj_ssize_t *len,
unsigned flags)
{
PJ_CHECK_STACK();
PJ_ASSERT_RETURN(buf && len, PJ_EINVAL);
*len = recv(sock, (char*)buf, *len, flags);
if (*len < 0)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else
return PJ_SUCCESS;
}
/*
* Receive data.
*/
PJ_DEF(pj_status_t) pj_sock_recvfrom(pj_sock_t sock,
void *buf,
pj_ssize_t *len,
unsigned flags,
pj_sockaddr_t *from,
int *fromlen)
{
PJ_CHECK_STACK();
PJ_ASSERT_RETURN(buf && len, PJ_EINVAL);
PJ_ASSERT_RETURN(from && fromlen, (*len=-1, PJ_EINVAL));
*len = recvfrom(sock, (char*)buf, *len, flags,
(struct sockaddr*)from, (socklen_t*)fromlen);
if (*len < 0)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else {
PJ_SOCKADDR_RESET_LEN(from);
return PJ_SUCCESS;
}
}
/*
* Get socket option.
*/
PJ_DEF(pj_status_t) pj_sock_getsockopt( pj_sock_t sock,
pj_uint16_t level,
pj_uint16_t optname,
void *optval,
int *optlen)
{
PJ_CHECK_STACK();
PJ_ASSERT_RETURN(optval && optlen, PJ_EINVAL);
if (getsockopt(sock, level, optname, (char*)optval, (socklen_t*)optlen)!=0)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else
return PJ_SUCCESS;
}
/*
* Set socket option.
*/
PJ_DEF(pj_status_t) pj_sock_setsockopt( pj_sock_t sock,
pj_uint16_t level,
pj_uint16_t optname,
const void *optval,
int optlen)
{
PJ_CHECK_STACK();
if (setsockopt(sock, level, optname, (const char*)optval, optlen) != 0)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else
return PJ_SUCCESS;
}
/*
* Connect socket.
*/
PJ_DEF(pj_status_t) pj_sock_connect( pj_sock_t sock,
const pj_sockaddr_t *addr,
int namelen)
{
PJ_CHECK_STACK();
if (connect(sock, (struct sockaddr*)addr, namelen) != 0)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else
return PJ_SUCCESS;
}
/*
* Shutdown socket.
*/
#if PJ_HAS_TCP
PJ_DEF(pj_status_t) pj_sock_shutdown( pj_sock_t sock,
int how)
{
PJ_CHECK_STACK();
if (shutdown(sock, how) != 0)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else
return PJ_SUCCESS;
}
/*
* Start listening to incoming connections.
*/
PJ_DEF(pj_status_t) pj_sock_listen( pj_sock_t sock,
int backlog)
{
PJ_CHECK_STACK();
if (listen(sock, backlog) != 0)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else
return PJ_SUCCESS;
}
/*
* Accept incoming connections
*/
PJ_DEF(pj_status_t) pj_sock_accept( pj_sock_t serverfd,
pj_sock_t *newsock,
pj_sockaddr_t *addr,
int *addrlen)
{
PJ_CHECK_STACK();
PJ_ASSERT_RETURN(newsock != NULL, PJ_EINVAL);
#if defined(PJ_SOCKADDR_HAS_LEN) && PJ_SOCKADDR_HAS_LEN!=0
if (addr) {
PJ_SOCKADDR_SET_LEN(addr, *addrlen);
}
#endif
*newsock = accept(serverfd, (struct sockaddr*)addr, (socklen_t*)addrlen);
if (*newsock==PJ_INVALID_SOCKET)
return PJ_RETURN_OS_ERROR(pj_get_native_netos_error());
else {
#if defined(PJ_SOCKADDR_HAS_LEN) && PJ_SOCKADDR_HAS_LEN!=0
if (addr) {
PJ_SOCKADDR_RESET_LEN(addr);
}
#endif
return PJ_SUCCESS;
}
}
#endif /* PJ_HAS_TCP */