/* Copyright (C) 2007-2008 The Android Open Source Project ** ** This software is licensed under the terms of the GNU General Public ** License version 2, as published by the Free Software Foundation, and ** may be copied, distributed, and modified under those terms. ** ** 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. */ #include "sockets.h" #include "qemu-common.h" #include <fcntl.h> #include <stddef.h> #include "qemu_debug.h" #include "qemu-char.h" #include <stdlib.h> #include <string.h> #include "android/utils/path.h" #include "android/utils/debug.h" #include "android/utils/misc.h" #define D(...) VERBOSE_PRINT(socket,__VA_ARGS__) #ifdef _WIN32 # define xxWIN32_LEAN_AND_MEAN # include <windows.h> # include <winsock2.h> # include <ws2tcpip.h> #else /* !_WIN32 */ # include <sys/ioctl.h> # include <sys/socket.h> # include <netinet/in.h> # include <netinet/tcp.h> # ifdef __linux__ /* Recent versions of glibc only define EAI_NODATA, which is an extension to the POSIX standard, if __USE_GNU is defined. */ # define __USE_GNU # include <netdb.h> # undef __USE_GNU # else /* !__linux__ */ # include <netdb.h> # endif /* !__linux__ */ # if HAVE_UNIX_SOCKETS # include <sys/un.h> # ifndef UNIX_PATH_MAX # define UNIX_PATH_MAX (sizeof(((struct sockaddr_un*)0)->sun_path)-1) # endif # endif #endif /* !_WIN32 */ /* QSOCKET_CALL is used to deal with the fact that EINTR happens pretty * easily in QEMU since we use SIGALRM to implement periodic timers */ #ifdef _WIN32 # define QSOCKET_CALL(_ret,_cmd) \ do { _ret = (_cmd); } while ( _ret < 0 && WSAGetLastError() == WSAEINTR ) #else # define QSOCKET_CALL(_ret,_cmd) \ do { \ errno = 0; \ do { _ret = (_cmd); } while ( _ret < 0 && errno == EINTR ); \ } while (0); #endif #ifdef _WIN32 #include <errno.h> static int winsock_error; #define WINSOCK_ERRORS_LIST \ EE(WSA_INVALID_HANDLE,EINVAL,"invalid handle") \ EE(WSA_NOT_ENOUGH_MEMORY,ENOMEM,"not enough memory") \ EE(WSA_INVALID_PARAMETER,EINVAL,"invalid parameter") \ EE(WSAEINTR,EINTR,"interrupted function call") \ EE(WSAEALREADY,EALREADY,"operation already in progress") \ EE(WSAEBADF,EBADF,"bad file descriptor") \ EE(WSAEACCES,EACCES,"permission denied") \ EE(WSAEFAULT,EFAULT,"bad address") \ EE(WSAEINVAL,EINVAL,"invalid argument") \ EE(WSAEMFILE,EMFILE,"too many opened files") \ EE(WSAEWOULDBLOCK,EWOULDBLOCK,"resource temporarily unavailable") \ EE(WSAEINPROGRESS,EINPROGRESS,"operation now in progress") \ EE(WSAEALREADY,EAGAIN,"operation already in progress") \ EE(WSAENOTSOCK,EBADF,"socket operation not on socket") \ EE(WSAEDESTADDRREQ,EDESTADDRREQ,"destination address required") \ EE(WSAEMSGSIZE,EMSGSIZE,"message too long") \ EE(WSAEPROTOTYPE,EPROTOTYPE,"wrong protocol type for socket") \ EE(WSAENOPROTOOPT,ENOPROTOOPT,"bad protocol option") \ EE(WSAEADDRINUSE,EADDRINUSE,"address already in use") \ EE(WSAEADDRNOTAVAIL,EADDRNOTAVAIL,"cannot assign requested address") \ EE(WSAENETDOWN,ENETDOWN,"network is down") \ EE(WSAENETUNREACH,ENETUNREACH,"network unreachable") \ EE(WSAENETRESET,ENETRESET,"network dropped connection on reset") \ EE(WSAECONNABORTED,ECONNABORTED,"software caused connection abort") \ EE(WSAECONNRESET,ECONNRESET,"connection reset by peer") \ EE(WSAENOBUFS,ENOBUFS,"no buffer space available") \ EE(WSAEISCONN,EISCONN,"socket is already connected") \ EE(WSAENOTCONN,ENOTCONN,"socket is not connected") \ EE(WSAESHUTDOWN,ESHUTDOWN,"cannot send after socket shutdown") \ EE(WSAETOOMANYREFS,ETOOMANYREFS,"too many references") \ EE(WSAETIMEDOUT,ETIMEDOUT,"connection timed out") \ EE(WSAECONNREFUSED,ECONNREFUSED,"connection refused") \ EE(WSAELOOP,ELOOP,"cannot translate name") \ EE(WSAENAMETOOLONG,ENAMETOOLONG,"name too long") \ EE(WSAEHOSTDOWN,EHOSTDOWN,"host is down") \ EE(WSAEHOSTUNREACH,EHOSTUNREACH,"no route to host") \ typedef struct { int winsock; int unix; const char* string; } WinsockError; static const WinsockError _winsock_errors[] = { #define EE(w,u,s) { w, u, s }, WINSOCK_ERRORS_LIST #undef EE { -1, -1, NULL } }; /* this function reads the latest winsock error code and updates * errno to a matching value. It also returns the new value of * errno. */ static int _fix_errno( void ) { const WinsockError* werr = _winsock_errors; int unix = EINVAL; /* generic error code */ winsock_error = WSAGetLastError(); for ( ; werr->string != NULL; werr++ ) { if (werr->winsock == winsock_error) { unix = werr->unix; break; } } errno = unix; return -1; } static int _set_errno( int code ) { winsock_error = -1; errno = code; return -1; } /* this function returns a string describing the latest Winsock error */ const char* _errno_str(void) { const WinsockError* werr = _winsock_errors; const char* result = NULL; for ( ; werr->string; werr++ ) { if (werr->winsock == winsock_error) { result = werr->string; break; } } if (result == NULL) { result = tempstr_format( "Unkown socket error (Winsock=0x%08x) errno=%d: %s", winsock_error, errno, strerror(errno)); } return result; } #else static int _fix_errno( void ) { return -1; } static int _set_errno( int code ) { errno = code; return -1; } #endif /* socket types */ static int socket_family_to_bsd( SocketFamily family ) { switch (family) { case SOCKET_INET: return AF_INET; case SOCKET_IN6: return AF_INET6; #if HAVE_UNIX_SOCKETS case SOCKET_UNIX: return AF_LOCAL; #endif default: return -1; } } static int socket_type_to_bsd( SocketType type ) { switch (type) { case SOCKET_DGRAM: return SOCK_DGRAM; case SOCKET_STREAM: return SOCK_STREAM; default: return 0; } } static SocketType socket_type_from_bsd( int type ) { switch (type) { case SOCK_DGRAM: return SOCKET_DGRAM; case SOCK_STREAM: return SOCKET_STREAM; default: return (SocketType) SOCKET_UNSPEC; } } #if 0 static int socket_type_check( SocketType type ) { return (type == SOCKET_DGRAM || type == SOCKET_STREAM); } #endif /* socket addresses */ void sock_address_init_inet( SockAddress* a, uint32_t ip, uint16_t port ) { a->family = SOCKET_INET; a->u.inet.port = port; a->u.inet.address = ip; } void sock_address_init_in6 ( SockAddress* a, const uint8_t* ip6[16], uint16_t port ) { a->family = SOCKET_IN6; a->u.in6.port = port; memcpy( a->u.in6.address, ip6, sizeof(a->u.in6.address) ); } void sock_address_init_unix( SockAddress* a, const char* path ) { a->family = SOCKET_UNIX; a->u._unix.path = strdup(path ? path : ""); a->u._unix.owner = 1; } void sock_address_done( SockAddress* a ) { if (a->family == SOCKET_UNIX && a->u._unix.owner) { a->u._unix.owner = 0; free((char*)a->u._unix.path); } } static char* format_char( char* buf, char* end, int c ) { if (buf < end) { if (buf+1 == end) { *buf++ = 0; } else { *buf++ = (char) c; *buf = 0; } } return buf; } static char* format_str( char* buf, char* end, const char* str ) { int len = strlen(str); int avail = end - buf; if (len > avail) len = avail; memcpy( buf, str, len ); buf += len; if (buf == end) buf[-1] = 0; else buf[0] = 0; return buf; } static char* format_unsigned( char* buf, char* end, unsigned val ) { char temp[16]; int nn; for ( nn = 0; val != 0; nn++ ) { int rem = val % 10; temp[nn] = '0'+rem; val /= 10; } if (nn == 0) temp[nn++] = '0'; while (nn > 0) buf = format_char(buf, end, temp[--nn]); return buf; } static char* format_hex( char* buf, char* end, unsigned val, int ndigits ) { int shift = 4*ndigits; static const char hex[16] = "0123456789abcdef"; while (shift >= 0) { buf = format_char(buf, end, hex[(val >> shift) & 15]); shift -= 4; } return buf; } static char* format_ip4( char* buf, char* end, uint32_t ip ) { buf = format_unsigned( buf, end, (unsigned)(ip >> 24) ); buf = format_char( buf, end, '.'); buf = format_unsigned( buf, end, (unsigned)((ip >> 16) & 255)); buf = format_char( buf, end, '.'); buf = format_unsigned( buf, end, (unsigned)((ip >> 8) & 255)); buf = format_char( buf, end, '.'); buf = format_unsigned( buf, end, (unsigned)(ip & 255)); return buf; } static char* format_ip6( char* buf, char* end, const uint8_t* ip6 ) { int nn; for (nn = 0; nn < 8; nn++) { int val = (ip6[0] << 16) | ip6[1]; ip6 += 2; if (nn > 0) buf = format_char(buf, end, ':'); if (val == 0) continue; buf = format_hex(buf, end, val, 4); } return buf; } const char* sock_address_to_string( const SockAddress* a ) { static char buf0[MAX_PATH]; char *buf = buf0, *end = buf + sizeof(buf0); switch (a->family) { case SOCKET_INET: buf = format_ip4( buf, end, a->u.inet.address ); buf = format_char( buf, end, ':' ); buf = format_unsigned( buf, end, (unsigned) a->u.inet.port ); break; case SOCKET_IN6: buf = format_ip6( buf, end, a->u.in6.address ); buf = format_char( buf, end, ':' ); buf = format_unsigned( buf, end, (unsigned) a->u.in6.port ); break; case SOCKET_UNIX: buf = format_str( buf, end, a->u._unix.path ); break; default: return NULL; } return buf0; } int sock_address_equal( const SockAddress* a, const SockAddress* b ) { if (a->family != b->family) return 0; switch (a->family) { case SOCKET_INET: return (a->u.inet.address == b->u.inet.address && a->u.inet.port == b->u.inet.port); case SOCKET_IN6: return (!memcmp(a->u.in6.address, b->u.in6.address, 16) && a->u.in6.port == b->u.in6.port); case SOCKET_UNIX: return (!strcmp(a->u._unix.path, b->u._unix.path)); default: return 0; } } int sock_address_get_port( const SockAddress* a ) { switch (a->family) { case SOCKET_INET: return a->u.inet.port; case SOCKET_IN6: return a->u.in6.port; default: return -1; } } void sock_address_set_port( SockAddress* a, uint16_t port ) { switch (a->family) { case SOCKET_INET: a->u.inet.port = port; break; case SOCKET_IN6: a->u.in6.port = port; break; default: ; } } const char* sock_address_get_path( const SockAddress* a ) { if (a->family == SOCKET_UNIX) return a->u._unix.path; else return NULL; } int sock_address_get_ip( const SockAddress* a ) { if (a->family == SOCKET_INET) return a->u.inet.address; return -1; } #if 0 char* bufprint_sock_address( char* p, char* end, const SockAddress* a ) { switch (a->family) { case SOCKET_INET: { uint32_t ip = a->u.inet.address; return bufprint( p, end, "%d.%d.%d.%d:%d", (ip >> 24) & 255, (ip >> 16) & 255, (ip >> 8) & 255, ip & 255, a->u.inet.port ); } case SOCKET_IN6: { int nn = 0; const char* column = ""; const uint8_t* tab = a->u.in6.address; for (nn = 0; nn < 16; nn += 2) { p = bufprint(p, end, "%s%04x", column, (tab[n] << 8) | tab[n+1]); column = ":"; } return bufprint(p, end, ":%d", a->u.in6.port); } case SOCKET_UNIX: { return bufprint(p, end, "%s", a->u._unix.path); } default: return p; } } #endif int sock_address_to_bsd( const SockAddress* a, void* paddress, size_t *psize ) { switch (a->family) { case SOCKET_INET: { struct sockaddr_in* dst = (struct sockaddr_in*) paddress; *psize = sizeof(*dst); memset( paddress, 0, *psize ); dst->sin_family = AF_INET; dst->sin_port = htons(a->u.inet.port); dst->sin_addr.s_addr = htonl(a->u.inet.address); } break; #if HAVE_IN6_SOCKETS case SOCKET_IN6: { struct sockaddr_in6* dst = (struct sockaddr_in6*) paddress; *psize = sizeof(*dst); memset( paddress, 0, *psize ); dst->sin6_family = AF_INET6; dst->sin6_port = htons(a->u.in6.port); memcpy( dst->sin6_addr.s6_addr, a->u.in6.address, 16 ); } break; #endif /* HAVE_IN6_SOCKETS */ #if HAVE_UNIX_SOCKETS case SOCKET_UNIX: { int slen = strlen(a->u._unix.path); struct sockaddr_un* dst = (struct sockaddr_un*) paddress; if (slen >= UNIX_PATH_MAX) return -1; memset( paddress, 0, sizeof(*dst) ); dst->sun_family = AF_LOCAL; memcpy( dst->sun_path, a->u._unix.path, slen ); dst->sun_path[slen] = 0; *psize = (char*)&dst->sun_path[slen+1] - (char*)dst; } break; #endif /* HAVE_UNIX_SOCKETS */ default: return _set_errno(EINVAL); } return 0; } int sock_address_to_inet( SockAddress* a, int *paddr_ip, int *paddr_port ) { struct sockaddr addr; socklen_t addrlen; if (a->family != SOCKET_INET) { return _set_errno(EINVAL); } if (sock_address_to_bsd(a, &addr, &addrlen) < 0) return -1; *paddr_ip = ntohl(((struct sockaddr_in*)&addr)->sin_addr.s_addr); *paddr_port = ntohs(((struct sockaddr_in*)&addr)->sin_port); return 0; } int sock_address_from_bsd( SockAddress* a, const void* from, size_t fromlen ) { switch (((struct sockaddr*)from)->sa_family) { case AF_INET: { struct sockaddr_in* src = (struct sockaddr_in*) from; if (fromlen < sizeof(*src)) return _set_errno(EINVAL); a->family = SOCKET_INET; a->u.inet.port = ntohs(src->sin_port); a->u.inet.address = ntohl(src->sin_addr.s_addr); } break; #ifdef HAVE_IN6_SOCKETS case AF_INET6: { struct sockaddr_in6* src = (struct sockaddr_in6*) from; if (fromlen < sizeof(*src)) return _set_errno(EINVAL); a->family = SOCKET_IN6; a->u.in6.port = ntohs(src->sin6_port); memcpy(a->u.in6.address, src->sin6_addr.s6_addr, 16); } break; #endif #ifdef HAVE_UNIX_SOCKETS case AF_LOCAL: { struct sockaddr_un* src = (struct sockaddr_un*) from; char* end; if (fromlen < sizeof(*src)) return _set_errno(EINVAL); /* check that the path is zero-terminated */ end = memchr(src->sun_path, 0, UNIX_PATH_MAX); if (end == NULL) return _set_errno(EINVAL); a->family = SOCKET_UNIX; a->u._unix.owner = 1; a->u._unix.path = strdup(src->sun_path); } break; #endif default: return _set_errno(EINVAL); } return 0; } int sock_address_init_resolve( SockAddress* a, const char* hostname, uint16_t port, int preferIn6 ) { struct addrinfo hints[1]; struct addrinfo* res; int ret; memset(hints, 0, sizeof(hints)); hints->ai_family = preferIn6 ? AF_INET6 : AF_UNSPEC; ret = getaddrinfo(hostname, NULL, hints, &res); if (ret != 0) { int err; switch (ret) { case EAI_AGAIN: /* server is down */ case EAI_FAIL: /* server is sick */ err = EHOSTDOWN; break; #ifdef EAI_NODATA case EAI_NODATA: #endif case EAI_NONAME: err = ENOENT; break; case EAI_MEMORY: err = ENOMEM; break; default: err = EINVAL; } return _set_errno(err); } /* Parse the returned list of addresses. */ { struct addrinfo* res_ipv4 = NULL; struct addrinfo* res_ipv6 = NULL; struct addrinfo* r; /* If preferIn6 is false, we stop on the first IPv4 address, * otherwise, we stop on the first IPv6 one */ for (r = res; r != NULL; r = r->ai_next) { if (r->ai_family == AF_INET && res_ipv4 == NULL) { res_ipv4 = r; if (!preferIn6) break; } else if (r->ai_family == AF_INET6 && res_ipv6 == NULL) { res_ipv6 = r; if (preferIn6) break; } } /* Select the best address in 'r', which will be NULL * if there is no corresponding address. */ if (preferIn6) { r = res_ipv6; if (r == NULL) r = res_ipv4; } else { r = res_ipv4; if (r == NULL) r = res_ipv6; } if (r == NULL) { ret = _set_errno(ENOENT); goto Exit; } /* Convert to a SockAddress */ ret = sock_address_from_bsd( a, r->ai_addr, r->ai_addrlen ); if (ret < 0) goto Exit; } /* need to set the port */ switch (a->family) { case SOCKET_INET: a->u.inet.port = port; break; case SOCKET_IN6: a->u.in6.port = port; break; default: ; } Exit: freeaddrinfo(res); return ret; } /* The Winsock headers for mingw lack some definitions */ #ifndef AI_ADDRCONFIG # define AI_ADDRCONFIG 0 #endif SockAddress** sock_address_list_create( const char* hostname, const char* port, unsigned flags ) { SockAddress** list = NULL; SockAddress* addr; int nn, count, ret; struct addrinfo ai, *res, *e; memset(&ai, 0, sizeof(ai)); ai.ai_flags |= AI_ADDRCONFIG; ai.ai_family = PF_UNSPEC; if (flags & SOCKET_LIST_FORCE_INET) ai.ai_family = PF_INET; else if (flags & SOCKET_LIST_FORCE_IN6) ai.ai_family = PF_INET6; if (flags & SOCKET_LIST_PASSIVE) ai.ai_flags |= AI_PASSIVE; else ai.ai_flags |= AI_CANONNAME; while (1) { struct addrinfo hints = ai; ret = getaddrinfo(hostname, port, &hints, &res); if (ret == 0) break; switch (ret) { #ifdef EAI_ADDRFAMILY case EAI_ADDRFAMILY: #endif case EAI_NODATA: _set_errno(ENOENT); break; case EAI_FAMILY: _set_errno(EAFNOSUPPORT); break; case EAI_AGAIN: _set_errno(EAGAIN); break; #ifdef EAI_SYSTEM case EAI_SYSTEM: if (errno == EINTR) continue; break; #endif default: _set_errno(EINVAL); } return NULL; } /* allocate result list */ for (count = 0, e = res; e != NULL; e = e->ai_next) count += 1; list = (SockAddress**) qemu_malloc((count+1)*sizeof(SockAddress*)); addr = (SockAddress*) qemu_malloc(count*sizeof(SockAddress)); for (nn = 0, e = res; e != NULL; e = e->ai_next) { ret = sock_address_from_bsd(addr, e->ai_addr, e->ai_addrlen); if (ret < 0) continue; list[nn++] = addr++; } list[nn] = NULL; freeaddrinfo(res); return list; } void sock_address_list_free( SockAddress** list ) { int nn; SockAddress* addr; if (list == NULL) return; addr = list[0]; for (nn = 0; list[nn] != NULL; nn++) { sock_address_done(list[nn]); list[nn] = NULL; } qemu_free(addr); qemu_free(list); } int sock_address_get_numeric_info( SockAddress* a, char* host, size_t hostlen, char* serv, size_t servlen ) { struct sockaddr* saddr; socklen_t slen; int ret; switch (a->family) { case SOCKET_INET: saddr = (struct sockaddr*) &a->u.inet.address; slen = sizeof(a->u.inet.address); break; #if HAVE_IN6_SOCKET case SOCKET_IN6: saddr = (struct sockaddr*) &a->u.in6.address; slen = sizeof(a->u.in6.address); break; #endif default: return _set_errno(EINVAL); } ret = getnameinfo( saddr, slen, host, hostlen, serv, servlen, NI_NUMERICHOST | NI_NUMERICSERV ); switch (ret) { case 0: break; case EAI_AGAIN: ret = EAGAIN; break; default: ret = EINVAL; } return ret; } int socket_create( SocketFamily family, SocketType type ) { int ret; int sfamily = socket_family_to_bsd(family); int stype = socket_type_to_bsd(type); if (sfamily < 0 || stype < 0) { return _set_errno(EINVAL); } QSOCKET_CALL(ret, socket(sfamily, stype, 0)); if (ret < 0) return _fix_errno(); return ret; } int socket_create_inet( SocketType type ) { return socket_create( SOCKET_INET, type ); } #if HAVE_IN6_SOCKETS int socket_create_in6 ( SocketType type ) { return socket_create( SOCKET_IN6, type ); } #endif #if HAVE_UNIX_SOCKETS int socket_create_unix( SocketType type ) { return socket_create( SOCKET_UNIX, type ); } #endif int socket_can_read(int fd) { #ifdef _WIN32 unsigned long opt; if (ioctlsocket(fd, FIONREAD, &opt) < 0) return 0; return opt; #else int opt; if (ioctl(fd, FIONREAD, &opt) < 0) return 0; return opt; #endif } #define SOCKET_CALL(cmd) \ int ret; \ QSOCKET_CALL(ret, (cmd)); \ if (ret < 0) \ return _fix_errno(); \ return ret; \ int socket_send(int fd, const void* buf, int buflen) { SOCKET_CALL(send(fd, buf, buflen, 0)) } int socket_send_oob( int fd, const void* buf, int buflen ) { SOCKET_CALL(send(fd, buf, buflen, MSG_OOB)); } int socket_sendto(int fd, const void* buf, int buflen, const SockAddress* to) { struct sockaddr sa; socklen_t salen; if (sock_address_to_bsd(to, &sa, &salen) < 0) return -1; SOCKET_CALL(sendto(fd, buf, buflen, 0, &sa, salen)); } int socket_recv(int fd, void* buf, int len) { SOCKET_CALL(recv(fd, buf, len, 0)); } int socket_recvfrom(int fd, void* buf, int len, SockAddress* from) { struct sockaddr sa; socklen_t salen = sizeof(sa); int ret; QSOCKET_CALL(ret,recvfrom(fd,buf,len,0,&sa,&salen)); if (ret < 0) return _fix_errno(); if (sock_address_from_bsd(from, &sa, salen) < 0) return -1; return ret; } int socket_connect( int fd, const SockAddress* address ) { struct sockaddr addr; socklen_t addrlen; if (sock_address_to_bsd(address, &addr, &addrlen) < 0) return -1; SOCKET_CALL(connect(fd,&addr,addrlen)); } int socket_bind( int fd, const SockAddress* address ) { struct sockaddr addr; socklen_t addrlen; if (sock_address_to_bsd(address, &addr, &addrlen) < 0) return -1; SOCKET_CALL(bind(fd, &addr, addrlen)); } int socket_get_address( int fd, SockAddress* address ) { struct sockaddr addr; socklen_t addrlen = sizeof(addr); int ret; QSOCKET_CALL(ret, getsockname(fd, &addr, &addrlen)); if (ret < 0) return _fix_errno(); return sock_address_from_bsd(address, &addr, addrlen); } int socket_get_peer_address( int fd, SockAddress* address ) { struct sockaddr addr; socklen_t addrlen = sizeof(addr); int ret; QSOCKET_CALL(ret, getpeername(fd, &addr, &addrlen)); if (ret < 0) return _fix_errno(); return sock_address_from_bsd(address, &addr, addrlen); } int socket_listen( int fd, int backlog ) { SOCKET_CALL(listen(fd, backlog)); } int socket_accept( int fd, SockAddress* address ) { struct sockaddr addr; socklen_t addrlen = sizeof(addr); int ret; QSOCKET_CALL(ret, accept(fd, &addr, &addrlen)); if (ret < 0) return _fix_errno(); if (address) { if (sock_address_from_bsd(address, &addr, addrlen) < 0) { socket_close(ret); return -1; } } return ret; } static int socket_getoption(int fd, int domain, int option, int defaut) { int ret; while (1) { #ifdef _WIN32 DWORD opt = (DWORD)-1; #else int opt = -1; #endif size_t optlen = sizeof(opt); ret = getsockopt(fd, domain, option, (char*)&opt, &optlen); if (ret == 0) return (int)opt; if (errno != EINTR) return defaut; } #undef OPT_CAST } SocketType socket_get_type(int fd) { int so_type = socket_getoption(fd, SOL_SOCKET, SO_TYPE, -1); return socket_type_from_bsd(so_type); } int socket_set_nonblock(int fd) { #ifdef _WIN32 unsigned long opt = 1; return ioctlsocket(fd, FIONBIO, &opt); #else int flags = fcntl(fd, F_GETFL); return fcntl(fd, F_SETFL, flags | O_NONBLOCK); #endif } int socket_set_blocking(int fd) { #ifdef _WIN32 unsigned long opt = 0; return ioctlsocket(fd, FIONBIO, &opt); #else int flags = fcntl(fd, F_GETFL); return fcntl(fd, F_SETFL, flags & ~O_NONBLOCK); #endif } static int socket_setoption(int fd, int domain, int option, int _flag) { #ifdef _WIN32 DWORD flag = (DWORD) _flag; #else int flag = _flag; #endif return setsockopt( fd, domain, option, (const char*)&flag, sizeof(flag) ); } int socket_set_xreuseaddr(int fd) { #ifdef _WIN32 /* on Windows, SO_REUSEADDR is used to indicate that several programs can * bind to the same port. this is completely different from the Unix * semantics. instead of SO_EXCLUSIVEADDR to ensure that explicitely prevent * this. */ return socket_setoption(fd, SOL_SOCKET, SO_EXCLUSIVEADDRUSE, 1); #else return socket_setoption(fd, SOL_SOCKET, SO_REUSEADDR, 1); #endif } int socket_set_oobinline(int fd) { return socket_setoption(fd, SOL_SOCKET, SO_OOBINLINE, 1); } int socket_set_nodelay(int fd) { return socket_setoption(fd, IPPROTO_TCP, TCP_NODELAY, 1); } int socket_set_ipv6only(int fd) { /* IPV6_ONLY is only supported since Vista on Windows, * and the Mingw headers lack its definition anyway. */ #if defined(_WIN32) && !defined(IPV6_V6ONLY) return 0; #else return socket_setoption(fd, IPPROTO_IPV6, IPV6_V6ONLY, 1); #endif } int socket_get_error(int fd) { return socket_getoption(fd, SOL_SOCKET, SO_ERROR, -1); } #ifdef _WIN32 #include <stdlib.h> static void socket_cleanup(void) { WSACleanup(); } int socket_init(void) { WSADATA Data; int ret, err; ret = WSAStartup(MAKEWORD(2,2), &Data); if (ret != 0) { err = WSAGetLastError(); return -1; } atexit(socket_cleanup); return 0; } #else /* !_WIN32 */ int socket_init(void) { return 0; /* nothing to do on Unix */ } #endif /* !_WIN32 */ #ifdef _WIN32 static void socket_close_handler( void* _fd ) { int fd = (int)_fd; int ret; char buff[64]; /* we want to drain the read side of the socket before closing it */ do { ret = recv( fd, buff, sizeof(buff), 0 ); } while (ret < 0 && WSAGetLastError() == WSAEINTR); if (ret < 0 && WSAGetLastError() == EWOULDBLOCK) return; qemu_set_fd_handler( fd, NULL, NULL, NULL ); closesocket( fd ); } void socket_close( int fd ) { int old_errno = errno; shutdown( fd, SD_BOTH ); /* we want to drain the socket before closing it */ qemu_set_fd_handler( fd, socket_close_handler, NULL, (void*)fd ); errno = old_errno; } #else /* !_WIN32 */ #include <unistd.h> void socket_close( int fd ) { int old_errno = errno; shutdown( fd, SHUT_RDWR ); close( fd ); errno = old_errno; } #endif /* !_WIN32 */ static int socket_bind_server( int s, const SockAddress* to, SocketType type ) { socket_set_xreuseaddr(s); if (socket_bind(s, to) < 0) { D("could not bind server socket address %s: %s", sock_address_to_string(to), errno_str); goto FAIL; } if (type == SOCKET_STREAM) { if (socket_listen(s, 4) < 0) { D("could not listen server socket %s: %s", sock_address_to_string(to), errno_str); goto FAIL; } } return s; FAIL: socket_close(s); return -1; } static int socket_connect_client( int s, const SockAddress* to ) { if (socket_connect(s, to) < 0) { D( "could not connect client socket to %s: %s\n", sock_address_to_string(to), errno_str ); socket_close(s); return -1; } socket_set_nonblock( s ); return s; } static int socket_in_server( int address, int port, SocketType type ) { SockAddress addr; int s; sock_address_init_inet( &addr, address, port ); s = socket_create_inet( type ); if (s < 0) return -1; return socket_bind_server( s, &addr, type ); } static int socket_in_client( SockAddress* to, SocketType type ) { int s; s = socket_create_inet( type ); if (s < 0) return -1; return socket_connect_client( s, to ); } int socket_loopback_server( int port, SocketType type ) { return socket_in_server( SOCK_ADDRESS_INET_LOOPBACK, port, type ); } int socket_loopback_client( int port, SocketType type ) { SockAddress addr; sock_address_init_inet( &addr, SOCK_ADDRESS_INET_LOOPBACK, port ); return socket_in_client( &addr, type ); } int socket_network_client( const char* host, int port, SocketType type ) { SockAddress addr; if (sock_address_init_resolve( &addr, host, port, 0) < 0) return -1; return socket_in_client( &addr, type ); } int socket_anyaddr_server( int port, SocketType type ) { return socket_in_server( SOCK_ADDRESS_INET_ANY, port, type ); } int socket_accept_any( int server_fd ) { int fd; QSOCKET_CALL(fd, accept( server_fd, NULL, 0 )); if (fd < 0) { D( "could not accept client connection from fd %d: %s", server_fd, errno_str ); return -1; } /* set to non-blocking */ socket_set_nonblock( fd ); return fd; } #if HAVE_UNIX_SOCKETS int socket_unix_server( const char* name, SocketType type ) { SockAddress addr; int s, ret; s = socket_create_unix( type ); if (s < 0) return -1; sock_address_init_unix( &addr, name ); do { ret = unlink( name ); } while (ret < 0 && errno == EINTR); ret = socket_bind_server( s, &addr, type ); sock_address_done( &addr ); return ret; } int socket_unix_client( const char* name, SocketType type ) { SockAddress addr; int s, ret; s = socket_create_unix(type); if (s < 0) return -1; sock_address_init_unix( &addr, name ); ret = socket_connect_client( s, &addr ); sock_address_done( &addr ); return ret; } #endif /* HAVE_UNIX_SOCKETS */ int socket_pair(int *fd1, int *fd2) { #ifndef _WIN32 int fds[2]; int ret = socketpair(AF_UNIX, SOCK_STREAM, 0, fds); if (!ret) { socket_set_nonblock(fds[0]); socket_set_nonblock(fds[1]); *fd1 = fds[0]; *fd2 = fds[1]; } return ret; #else /* _WIN32 */ /* on Windows, select() only works with network sockets, which * means we absolutely cannot use Win32 PIPEs to implement * socket pairs with the current event loop implementation. * We're going to do like Cygwin: create a random pair * of localhost TCP sockets and connect them together */ int s0, s1, s2, port; struct sockaddr_in sockin; socklen_t len; /* first, create the 'server' socket. * a port number of 0 means 'any port between 1024 and 5000. * see Winsock bind() documentation for details */ s0 = socket_loopback_server( 0, SOCK_STREAM ); if (s0 < 0) return -1; /* now connect a client socket to it, we first need to * extract the server socket's port number */ len = sizeof sockin; if (getsockname(s0, (struct sockaddr*) &sockin, &len) < 0) { closesocket (s0); return -1; } port = ntohs(sockin.sin_port); s2 = socket_loopback_client( port, SOCK_STREAM ); if (s2 < 0) { closesocket(s0); return -1; } /* we need to accept the connection on the server socket * this will create the second socket for the pair */ len = sizeof sockin; s1 = accept(s0, (struct sockaddr*) &sockin, &len); if (s1 == INVALID_SOCKET) { closesocket (s0); closesocket (s2); return -1; } socket_set_nonblock(s1); /* close server socket */ closesocket(s0); *fd1 = s1; *fd2 = s2; return 0; #endif /* _WIN32 */ } int socket_mcast_inet_add_membership( int s, uint32_t ip ) { struct ip_mreq imr; imr.imr_multiaddr.s_addr = htonl(ip); imr.imr_interface.s_addr = htonl(INADDR_ANY); if ( setsockopt( s, IPPROTO_IP, IP_ADD_MEMBERSHIP, (const char *)&imr, sizeof(struct ip_mreq)) < 0 ) { return _fix_errno(); } return 0; } int socket_mcast_inet_drop_membership( int s, uint32_t ip ) { struct ip_mreq imr; imr.imr_multiaddr.s_addr = htonl(ip); imr.imr_interface.s_addr = htonl(INADDR_ANY); if ( setsockopt( s, IPPROTO_IP, IP_DROP_MEMBERSHIP, (const char *)&imr, sizeof(struct ip_mreq)) < 0 ) { return _fix_errno(); } return 0; } int socket_mcast_inet_set_loop( int s, int enabled ) { return socket_setoption( s, IPPROTO_IP, IP_MULTICAST_LOOP, !!enabled ); } int socket_mcast_inet_set_ttl( int s, int ttl ) { return socket_setoption( s, IPPROTO_IP, IP_MULTICAST_TTL, ttl ); } char* host_name( void ) { static char buf[256]; /* 255 is the max host name length supported by DNS */ int ret; QSOCKET_CALL(ret, gethostname(buf, sizeof(buf))); if (ret < 0) return "localhost"; else return buf; }