/* Copyright 1996-1998,2000-2007,2009,2011-2015,2018,2021,2022 Free Software Foundation, Inc. This file is part of Guile. Guile is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. Guile 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with Guile. If not, see . */ #ifdef HAVE_CONFIG_H # include #endif #include #include #ifdef HAVE_STDINT_H #include #endif #include #include #include #include #ifdef HAVE_WINSOCK2_H #include #else /* ! HAVE_WINSOCK2_H */ #include #include #include #ifdef HAVE_UNIX_DOMAIN_SOCKETS #include #endif #endif /* ! HAVE_WINSOCK2_H */ #include #include #include "scm.h" #if SCM_ENABLE_MINI_GMP #include "mini-gmp.h" #else #include #endif #include "arrays.h" #include "async.h" #include "bytevectors.h" #include "dynwind.h" #include "feature.h" #include "fports.h" #include "gsubr.h" #include "list.h" #include "modules.h" #include "numbers.h" #include "pairs.h" #include "srfi-13.h" #include "strings.h" #include "symbols.h" #include "syscalls.h" #include "vectors.h" #include "socket.h" #if defined (HAVE_UNIX_DOMAIN_SOCKETS) && !defined (SUN_LEN) #define SUN_LEN(ptr) (offsetof (struct sockaddr_un, sun_path) \ + strlen ((ptr)->sun_path)) #endif /* The largest possible socket address. Wrapping it in a union guarantees that the compiler will make it suitably aligned. */ typedef union { struct sockaddr sockaddr; struct sockaddr_in sockaddr_in; #ifdef HAVE_UNIX_DOMAIN_SOCKETS struct sockaddr_un sockaddr_un; #endif #ifdef HAVE_IPV6 struct sockaddr_in6 sockaddr_in6; #endif } scm_t_max_sockaddr; /* Maximum size of a socket address. */ #define MAX_ADDR_SIZE (sizeof (scm_t_max_sockaddr)) #ifdef HAVE_INET_NETOF SCM_DEFINE (scm_inet_netof, "inet-netof", 1, 0, 0, (SCM address), "Return the network number part of the given IPv4\n" "Internet address. E.g.,\n\n" "@lisp\n" "(inet-netof 2130706433) @result{} 127\n" "@end lisp") #define FUNC_NAME s_scm_inet_netof { struct in_addr addr; addr.s_addr = htonl (SCM_NUM2ULONG (1, address)); return scm_from_ulong (inet_netof (addr)); } #undef FUNC_NAME #endif #ifdef HAVE_INET_LNAOF SCM_DEFINE (scm_lnaof, "inet-lnaof", 1, 0, 0, (SCM address), "Return the local-address-with-network part of the given\n" "IPv4 Internet address, using the obsolete class A/B/C system.\n" "E.g.,\n\n" "@lisp\n" "(inet-lnaof 2130706433) @result{} 1\n" "@end lisp") #define FUNC_NAME s_scm_lnaof { struct in_addr addr; addr.s_addr = htonl (SCM_NUM2ULONG (1, address)); return scm_from_ulong (inet_lnaof (addr)); } #undef FUNC_NAME #endif #ifdef HAVE_INET_MAKEADDR SCM_DEFINE (scm_inet_makeaddr, "inet-makeaddr", 2, 0, 0, (SCM net, SCM lna), "Make an IPv4 Internet address by combining the network number\n" "@var{net} with the local-address-within-network number\n" "@var{lna}. E.g.,\n\n" "@lisp\n" "(inet-makeaddr 127 1) @result{} 2130706433\n" "@end lisp") #define FUNC_NAME s_scm_inet_makeaddr { struct in_addr addr; unsigned long netnum; unsigned long lnanum; netnum = SCM_NUM2ULONG (1, net); lnanum = SCM_NUM2ULONG (2, lna); addr = inet_makeaddr (netnum, lnanum); return scm_from_ulong (ntohl (addr.s_addr)); } #undef FUNC_NAME #endif #ifdef HAVE_IPV6 /* flip a 128 bit IPv6 address between host and network order. */ #ifdef WORDS_BIGENDIAN #define FLIP_NET_HOST_128(addr) #else #define FLIP_NET_HOST_128(addr)\ {\ int i;\ \ for (i = 0; i < 8; i++)\ {\ uint8_t c = (addr)[i];\ \ (addr)[i] = (addr)[15 - i];\ (addr)[15 - i] = c;\ }\ } #endif #ifdef WORDS_BIGENDIAN #define FLIPCPY_NET_HOST_128(dest, src) memcpy (dest, src, 16) #else #define FLIPCPY_NET_HOST_128(dest, src) \ { \ const uint8_t *tmp_srcp = (src) + 15; \ uint8_t *tmp_destp = (dest); \ \ do { \ *tmp_destp++ = *tmp_srcp--; \ } while (tmp_srcp != (src)); \ } #endif #if (SIZEOF_UINTPTR_T * SCM_CHAR_BIT) > 128 #error "Assumption that uintptr_t <= 128 bits has been violated." #endif #if (SIZEOF_UNSIGNED_LONG * SCM_CHAR_BIT) > 128 #error "Assumption that unsigned long <= 128 bits has been violated." #endif #if (SIZEOF_UNSIGNED_LONG_LONG * SCM_CHAR_BIT) > 128 #error "Assumption that unsigned long long <= 128 bits has been violated." #endif /* convert a 128 bit IPv6 address in network order to a host ordered SCM integer. */ static SCM scm_from_ipv6 (const uint8_t *src) { mpz_t z; mpz_init (z); mpz_import (z, 1, /* chunk */ 1, /* big-endian chunk ordering */ 16, /* chunks are 16 bytes long */ 1, /* big-endian byte ordering */ 0, /* "nails" -- leading unused bits per chunk */ src); SCM ret = scm_from_mpz (z); mpz_clear (z); return ret; } /* convert a host ordered SCM integer to a 128 bit IPv6 address in network order. */ static void scm_to_ipv6 (uint8_t dst[16], SCM src) { if (SCM_I_INUMP (src)) { scm_t_signed_bits n = SCM_I_INUM (src); if (n < 0) scm_out_of_range (NULL, src); #ifdef WORDS_BIGENDIAN memset (dst, 0, 16 - sizeof (scm_t_signed_bits)); memcpy (dst + (16 - sizeof (scm_t_signed_bits)), &n, sizeof (scm_t_signed_bits)); #else memset (dst + sizeof (scm_t_signed_bits), 0, 16 - sizeof (scm_t_signed_bits)); /* FIXME: this pair of ops is kinda wasteful -- should rewrite as a single loop perhaps, similar to the handling of bignums. */ memcpy (dst, &n, sizeof (scm_t_signed_bits)); FLIP_NET_HOST_128 (dst); #endif } else if (SCM_BIGP (src)) { size_t count; mpz_t z; mpz_init (z); scm_to_mpz (src, z); if (mpz_sgn (z) < 0 || mpz_sizeinbase (z, 2) > 128) { mpz_clear (z); scm_out_of_range (NULL, src); } memset (dst, 0, 16); mpz_export (dst, &count, 1, /* big-endian chunk ordering */ 16, /* chunks are 16 bytes long */ 1, /* big-endian byte ordering */ 0, /* "nails" -- leading unused bits per chunk */ z); mpz_clear (z); } else scm_wrong_type_arg_msg ("scm_to_ipv6", 0, src, "integer"); } #endif /* HAVE_IPV6 */ SCM_DEFINE (scm_inet_ntop, "inet-ntop", 2, 0, 0, (SCM family, SCM address), "Convert a network address into a printable string.\n" "Note that unlike the C version of this function,\n" "the input is an integer with normal host byte ordering.\n" "@var{family} can be @code{AF_INET} or @code{AF_INET6}. E.g.,\n\n" "@lisp\n" "(inet-ntop AF_INET 2130706433) @result{} \"127.0.0.1\"\n" "(inet-ntop AF_INET6 (- (expt 2 128) 1))\n" " @result{} \"ffff:ffff:ffff:ffff:ffff:ffff:ffff:ffff\"\n" "@end lisp") #define FUNC_NAME s_scm_inet_ntop { int af; #ifdef INET6_ADDRSTRLEN char dst[INET6_ADDRSTRLEN]; #else char dst[46]; #endif const char *result; af = scm_to_int (family); SCM_ASSERT_RANGE (1, family, af == AF_INET #ifdef HAVE_IPV6 || af == AF_INET6 #endif ); if (af == AF_INET) { uint32_t addr4; addr4 = htonl (SCM_NUM2ULONG (2, address)); result = inet_ntop (af, &addr4, dst, sizeof (dst)); } #ifdef HAVE_IPV6 else if (af == AF_INET6) { char addr6[16]; scm_to_ipv6 ((uint8_t *) addr6, address); result = inet_ntop (af, &addr6, dst, sizeof (dst)); } #endif else SCM_MISC_ERROR ("unsupported address family", family); if (result == NULL) SCM_SYSERROR; return scm_from_locale_string (dst); } #undef FUNC_NAME SCM_DEFINE (scm_inet_pton, "inet-pton", 2, 0, 0, (SCM family, SCM address), "Convert a string containing a printable network address to\n" "an integer address. Note that unlike the C version of this\n" "function,\n" "the result is an integer with normal host byte ordering.\n" "@var{family} can be @code{AF_INET} or @code{AF_INET6}. E.g.,\n\n" "@lisp\n" "(inet-pton AF_INET \"127.0.0.1\") @result{} 2130706433\n" "(inet-pton AF_INET6 \"::1\") @result{} 1\n" "@end lisp") #define FUNC_NAME s_scm_inet_pton { int af; char *src; uint32_t dst[4]; int rv, eno; af = scm_to_int (family); SCM_ASSERT_RANGE (1, family, af == AF_INET #ifdef HAVE_IPV6 || af == AF_INET6 #endif ); src = scm_to_locale_string (address); rv = inet_pton (af, src, dst); eno = errno; free (src); errno = eno; if (rv == -1) SCM_SYSERROR; else if (rv == 0) SCM_MISC_ERROR ("Bad address", SCM_EOL); if (af == AF_INET) return scm_from_ulong (ntohl (*dst)); #ifdef HAVE_IPV6 else if (af == AF_INET6) return scm_from_ipv6 ((uint8_t *) dst); #endif else SCM_MISC_ERROR ("unsupported address family", family); } #undef FUNC_NAME SCM_SYMBOL (sym_socket, "socket"); static SCM scm_socket_fd_to_port (int fd) { return scm_i_fdes_to_port (fd, scm_mode_bits ("r+0"), sym_socket, SCM_FPORT_OPTION_NOT_SEEKABLE); } SCM_DEFINE (scm_socket, "socket", 3, 0, 0, (SCM family, SCM style, SCM proto), "Return a new socket port of the type specified by @var{family},\n" "@var{style} and @var{proto}. All three parameters are\n" "integers. Supported values for @var{family} are\n" "@code{AF_UNIX}, @code{AF_INET} and @code{AF_INET6}.\n" "Typical values for @var{style} are @code{SOCK_STREAM},\n" "@code{SOCK_DGRAM} and @code{SOCK_RAW}.\n\n" "@var{proto} can be obtained from a protocol name using\n" "@code{getprotobyname}. A value of zero specifies the default\n" "protocol, which is usually right.\n\n" "A single socket port cannot by used for communication until it\n" "has been connected to another socket.") #define FUNC_NAME s_scm_socket { int fd; fd = socket (scm_to_int (family), scm_to_int (style), scm_to_int (proto)); if (fd == -1) SCM_SYSERROR; return scm_socket_fd_to_port (fd); } #undef FUNC_NAME #ifdef HAVE_SOCKETPAIR SCM_DEFINE (scm_socketpair, "socketpair", 3, 0, 0, (SCM family, SCM style, SCM proto), "Return a pair of connected (but unnamed) socket ports of the\n" "type specified by @var{family}, @var{style} and @var{proto}.\n" "Many systems support only socket pairs of the @code{AF_UNIX}\n" "family. Zero is likely to be the only meaningful value for\n" "@var{proto}.") #define FUNC_NAME s_scm_socketpair { int fam; int fd[2]; fam = scm_to_int (family); if (socketpair (fam, scm_to_int (style), scm_to_int (proto), fd) == -1) SCM_SYSERROR; return scm_cons (scm_socket_fd_to_port (fd[0]), scm_socket_fd_to_port (fd[1])); } #undef FUNC_NAME #endif /* Possible results for `getsockopt ()'. Wrapping it into a union guarantees suitable alignment. */ typedef union { #ifdef HAVE_STRUCT_LINGER struct linger linger; #endif size_t size; int integer; } scm_t_getsockopt_result; SCM_DEFINE (scm_getsockopt, "getsockopt", 3, 0, 0, (SCM sock, SCM level, SCM optname), "Return an option value from socket port @var{sock}.\n" "\n" "@var{level} is an integer specifying a protocol layer, either\n" "@code{SOL_SOCKET} for socket level options, or a protocol\n" "number from the @code{IPPROTO} constants or @code{getprotoent}\n" "(@pxref{Network Databases}).\n" "\n" "@defvar SOL_SOCKET\n" "@defvarx IPPROTO_IP\n" "@defvarx IPPROTO_TCP\n" "@defvarx IPPROTO_UDP\n" "@end defvar\n" "\n" "@var{optname} is an integer specifying an option within the\n" "protocol layer.\n" "\n" "For @code{SOL_SOCKET} level the following @var{optname}s are\n" "defined (when provided by the system). For their meaning see\n" "@ref{Socket-Level Options,,, libc, The GNU C Library Reference\n" "Manual}, or @command{man 7 socket}.\n" "\n" "@defvar SO_DEBUG\n" "@defvarx SO_REUSEADDR\n" "@defvarx SO_STYLE\n" "@defvarx SO_TYPE\n" "@defvarx SO_ERROR\n" "@defvarx SO_DONTROUTE\n" "@defvarx SO_BROADCAST\n" "@defvarx SO_SNDBUF\n" "@defvarx SO_RCVBUF\n" "@defvarx SO_KEEPALIVE\n" "@defvarx SO_OOBINLINE\n" "@defvarx SO_NO_CHECK\n" "@defvarx SO_PRIORITY\n" "@defvarx SO_REUSEPORT\n" "The value returned is an integer.\n" "@end defvar\n" "\n" "@defvar SO_LINGER\n" "The value returned is a pair of integers\n" "@code{(@var{enable} . @var{timeout})}. On old systems without\n" "timeout support (ie.@: without @code{struct linger}), only\n" "@var{enable} has an effect but the value in Guile is always a\n" "pair.\n" "@end defvar" "\n" "@defvar SO_RCVTIMEO\n" "@defvarx SO_SNDTIMEO\n" "@var{value} is a pair of integers @code{(@var{SECONDS}\n" ". @var{MICROSECONDS})}.\n" "@end defvar") #define FUNC_NAME s_scm_getsockopt { int fd; /* size of optval is the largest supported option. */ scm_t_getsockopt_result optval; socklen_t optlen = sizeof (optval); int ilevel; int ioptname; memset (&optval, 0, optlen); sock = SCM_COERCE_OUTPORT (sock); SCM_VALIDATE_OPFPORT (1, sock); ilevel = scm_to_int (level); ioptname = scm_to_int (optname); fd = SCM_FPORT_FDES (sock); if (getsockopt (fd, ilevel, ioptname, (void *) &optval, &optlen) == -1) SCM_SYSERROR; #if defined(SO_RCVTIMEO) && defined(SO_SNDTIMEO) if (ioptname == SO_RCVTIMEO || ioptname == SO_SNDTIMEO) { struct timeval *opt_time = (struct timeval *) &optval; return scm_cons (scm_from_long (opt_time->tv_sec), scm_from_long (opt_time->tv_usec)); } #endif if (ilevel == SOL_SOCKET) { #ifdef SO_LINGER if (ioptname == SO_LINGER) { #ifdef HAVE_STRUCT_LINGER struct linger *ling = (struct linger *) &optval; return scm_cons (scm_from_long (ling->l_onoff), scm_from_long (ling->l_linger)); #else return scm_cons (scm_from_long (*(int *) &optval), scm_from_int (0)); #endif } #endif } return scm_from_int (*(int *) &optval); } #undef FUNC_NAME SCM_DEFINE (scm_setsockopt, "setsockopt", 4, 0, 0, (SCM sock, SCM level, SCM optname, SCM value), "Set an option on socket port @var{sock}. The return value is\n" "unspecified.\n" "\n" "@var{level} is an integer specifying a protocol layer, either\n" "@code{SOL_SOCKET} for socket level options, or a protocol\n" "number from the @code{IPPROTO} constants or @code{getprotoent}\n" "(@pxref{Network Databases}).\n" "\n" "@defvar SOL_SOCKET\n" "@defvarx IPPROTO_IP\n" "@defvarx IPPROTO_TCP\n" "@defvarx IPPROTO_UDP\n" "@end defvar\n" "\n" "@var{optname} is an integer specifying an option within the\n" "protocol layer.\n" "\n" "For @code{SOL_SOCKET} level the following @var{optname}s are\n" "defined (when provided by the system). For their meaning see\n" "@ref{Socket-Level Options,,, libc, The GNU C Library Reference\n" "Manual}, or @command{man 7 socket}.\n" "\n" "@defvar SO_DEBUG\n" "@defvarx SO_REUSEADDR\n" "@defvarx SO_STYLE\n" "@defvarx SO_TYPE\n" "@defvarx SO_ERROR\n" "@defvarx SO_DONTROUTE\n" "@defvarx SO_BROADCAST\n" "@defvarx SO_SNDBUF\n" "@defvarx SO_RCVBUF\n" "@defvarx SO_KEEPALIVE\n" "@defvarx SO_OOBINLINE\n" "@defvarx SO_NO_CHECK\n" "@defvarx SO_PRIORITY\n" "@defvarx SO_REUSEPORT\n" "@var{value} is an integer.\n" "@end defvar\n" "\n" "@defvar SO_LINGER\n" "@var{value} is a pair of integers @code{(@var{ENABLE}\n" ". @var{TIMEOUT})}. On old systems without timeout support\n" "(ie.@: without @code{struct linger}), only @var{ENABLE} has an\n" "effect but the value in Guile is always a pair.\n" "@end defvar\n" "\n" "@defvar SO_RCVTIMEO\n" "@defvarx SO_SNDTIMEO\n" "@var{value} is a pair of integers @code{(@var{SECONDS}\n" ". @var{MICROSECONDS})}.\n" "@end defvar\n" "\n" "@c Note that we refer only to ``man ip'' here. On GNU/Linux it's\n" "@c ``man 7 ip'' but on NetBSD it's ``man 4 ip''.\n" "@c \n" "For IP level (@code{IPPROTO_IP}) the following @var{optname}s\n" "are defined (when provided by the system). See @command{man\n" "ip} for what they mean.\n" "\n" "@defvar IP_MULTICAST_IF\n" "This sets the source interface used by multicast traffic.\n" "@end defvar\n" "\n" "@defvar IP_MULTICAST_TTL\n" "This sets the default TTL for multicast traffic. This defaults \n" "to 1 and should be increased to allow traffic to pass beyond the\n" "local network.\n" "@end defvar\n" "\n" "@defvar IP_ADD_MEMBERSHIP\n" "@defvarx IP_DROP_MEMBERSHIP\n" "These can be used only with @code{setsockopt}, not\n" "@code{getsockopt}. @var{value} is a pair\n" "@code{(@var{MULTIADDR} . @var{INTERFACEADDR})} of IPv4\n" "addresses (@pxref{Network Address Conversion}).\n" "@var{MULTIADDR} is a multicast address to be added to or\n" "dropped from the interface @var{INTERFACEADDR}.\n" "@var{INTERFACEADDR} can be @code{INADDR_ANY} to have the system\n" "select the interface. @var{INTERFACEADDR} can also be an\n" "interface index number, on systems supporting that.\n" "@end defvar") #define FUNC_NAME s_scm_setsockopt { int fd; int opt_int; #ifdef HAVE_STRUCT_LINGER struct linger opt_linger; #endif #ifdef HAVE_STRUCT_IP_MREQ struct ip_mreq opt_mreq; #endif struct timeval opt_time; const void *optval = NULL; socklen_t optlen = 0; int ilevel, ioptname; sock = SCM_COERCE_OUTPORT (sock); SCM_VALIDATE_OPFPORT (1, sock); ilevel = scm_to_int (level); ioptname = scm_to_int (optname); fd = SCM_FPORT_FDES (sock); if (ilevel == SOL_SOCKET) { #ifdef SO_LINGER if (ioptname == SO_LINGER) { #ifdef HAVE_STRUCT_LINGER SCM_ASSERT (scm_is_pair (value), value, SCM_ARG4, FUNC_NAME); opt_linger.l_onoff = scm_to_int (SCM_CAR (value)); opt_linger.l_linger = scm_to_int (SCM_CDR (value)); optlen = sizeof (struct linger); optval = &opt_linger; #else SCM_ASSERT (scm_is_pair (value), value, SCM_ARG4, FUNC_NAME); opt_int = scm_to_int (SCM_CAR (value)); /* timeout is ignored, but may as well validate it. */ scm_to_int (SCM_CDR (value)); optlen = sizeof (int); optval = &opt_int; #endif } #endif } #ifdef HAVE_STRUCT_IP_MREQ if (ilevel == IPPROTO_IP && (ioptname == IP_ADD_MEMBERSHIP || ioptname == IP_DROP_MEMBERSHIP)) { /* Fourth argument must be a pair of addresses. */ SCM_ASSERT (scm_is_pair (value), value, SCM_ARG4, FUNC_NAME); opt_mreq.imr_multiaddr.s_addr = htonl (scm_to_ulong (SCM_CAR (value))); opt_mreq.imr_interface.s_addr = htonl (scm_to_ulong (SCM_CDR (value))); optlen = sizeof (opt_mreq); optval = &opt_mreq; } #endif #if defined(SO_RCVTIMEO) && defined(SO_SNDTIMEO) if (ioptname == SO_RCVTIMEO || ioptname == SO_SNDTIMEO) { SCM_ASSERT_TYPE (scm_is_pair (value), value, SCM_ARG4, FUNC_NAME, "value"); opt_time.tv_sec = scm_to_ulong (SCM_CAR (value)); opt_time.tv_usec = scm_to_ulong (SCM_CDR (value)); optlen = sizeof (opt_time); optval = &opt_time; } #endif if (optval == NULL) { /* Most options take an int. */ opt_int = scm_to_int (value); optlen = sizeof (int); optval = &opt_int; } if (setsockopt (fd, ilevel, ioptname, optval, optlen) == -1) SCM_SYSERROR; return SCM_UNSPECIFIED; } #undef FUNC_NAME /* Our documentation hard-codes this mapping, so make sure it holds. */ verify (SHUT_RD == 0); verify (SHUT_WR == 1); verify (SHUT_RDWR == 2); SCM_DEFINE (scm_shutdown, "shutdown", 2, 0, 0, (SCM sock, SCM how), "Sockets can be closed simply by using @code{close-port}. The\n" "@code{shutdown} procedure allows reception or transmission on a\n" "connection to be shut down individually, according to the parameter\n" "@var{how}:\n\n" "@table @asis\n" "@item 0\n" "Stop receiving data for this socket. If further data arrives, reject it.\n" "@item 1\n" "Stop trying to transmit data from this socket. Discard any\n" "data waiting to be sent. Stop looking for acknowledgement of\n" "data already sent; don't retransmit it if it is lost.\n" "@item 2\n" "Stop both reception and transmission.\n" "@end table\n\n" "The return value is unspecified.") #define FUNC_NAME s_scm_shutdown { int fd; sock = SCM_COERCE_OUTPORT (sock); SCM_VALIDATE_OPFPORT (1, sock); fd = SCM_FPORT_FDES (sock); if (shutdown (fd, scm_to_signed_integer (how, 0, 2)) == -1) SCM_SYSERROR; return SCM_UNSPECIFIED; } #undef FUNC_NAME /* convert fam/address/args into a sockaddr of the appropriate type. args is modified by removing the arguments actually used. which_arg and proc are used when reporting errors: which_arg is the position of address in the original argument list. proc is the name of the original procedure. size returns the size of the structure allocated. */ #define MAX(A, B) ((A) >= (B) ? (A) : (B)) static struct sockaddr * scm_fill_sockaddr (int fam, SCM address, SCM *args, int which_arg, const char *proc, size_t *size) #define FUNC_NAME proc { switch (fam) { case AF_INET: { struct sockaddr_in *soka; unsigned long addr; int port; SCM_VALIDATE_ULONG_COPY (which_arg, address, addr); SCM_VALIDATE_CONS (which_arg + 1, *args); port = scm_to_int (SCM_CAR (*args)); *args = SCM_CDR (*args); soka = (struct sockaddr_in *) scm_malloc (sizeof (struct sockaddr_in)); memset (soka, '\0', sizeof (struct sockaddr_in)); #ifdef HAVE_STRUCT_SOCKADDR_IN_SIN_LEN soka->sin_len = sizeof (struct sockaddr_in); #endif soka->sin_family = AF_INET; soka->sin_addr.s_addr = htonl (addr); soka->sin_port = htons (port); *size = sizeof (struct sockaddr_in); return (struct sockaddr *) soka; } #ifdef HAVE_IPV6 case AF_INET6: { /* see RFC2553. */ int port; struct sockaddr_in6 *soka; unsigned long flowinfo = 0; unsigned long scope_id = 0; SCM_VALIDATE_CONS (which_arg + 1, *args); port = scm_to_int (SCM_CAR (*args)); *args = SCM_CDR (*args); if (scm_is_pair (*args)) { SCM_VALIDATE_ULONG_COPY (which_arg + 2, SCM_CAR (*args), flowinfo); *args = SCM_CDR (*args); if (scm_is_pair (*args)) { SCM_VALIDATE_ULONG_COPY (which_arg + 3, SCM_CAR (*args), scope_id); *args = SCM_CDR (*args); } } soka = (struct sockaddr_in6 *) scm_malloc (sizeof (struct sockaddr_in6)); #ifdef HAVE_STRUCT_SOCKADDR_IN6_SIN6_LEN soka->sin6_len = sizeof (struct sockaddr_in6); #endif soka->sin6_family = AF_INET6; scm_to_ipv6 (soka->sin6_addr.s6_addr, address); soka->sin6_port = htons (port); soka->sin6_flowinfo = flowinfo; #ifdef HAVE_SIN6_SCOPE_ID soka->sin6_scope_id = scope_id; #endif *size = sizeof (struct sockaddr_in6); return (struct sockaddr *) soka; } #endif #ifdef HAVE_UNIX_DOMAIN_SOCKETS case AF_UNIX: { struct sockaddr_un *soka; int addr_size; char *c_address; size_t c_address_size; scm_dynwind_begin (0); c_address = scm_to_locale_stringn (address, &c_address_size); scm_dynwind_free (c_address); /* the static buffer size in sockaddr_un seems to be arbitrary and not necessarily a hard limit. e.g., the glibc manual suggests it may be possible to declare it size 0. let's ignore it. if the O/S doesn't like the size it will cause connect/bind etc., to fail. sun_path is always the last member of the structure. */ addr_size = sizeof (struct sockaddr_un) + MAX (0, c_address_size + 1 - (sizeof soka->sun_path)); soka = (struct sockaddr_un *) scm_malloc (addr_size); memset (soka, 0, addr_size); soka->sun_family = AF_UNIX; /* we accept 0-bytes here (used for abstract sockets in Linux); therefore do not use strlen() or SUN_LEN! */ memcpy (soka->sun_path, c_address, c_address_size); *size = offsetof (struct sockaddr_un, sun_path) + c_address_size; scm_dynwind_end (); return (struct sockaddr *) soka; } #endif default: scm_out_of_range (proc, scm_from_int (fam)); } } #undef FUNC_NAME SCM_DEFINE (scm_connect, "connect", 2, 1, 1, (SCM sock, SCM fam_or_sockaddr, SCM address, SCM args), "Initiate a connection from a socket using a specified address\n" "family to the address\n" "specified by @var{address} and possibly @var{args}.\n" "The format required for @var{address}\n" "and @var{args} depends on the family of the socket.\n\n" "For a socket of family @code{AF_UNIX},\n" "only @var{address} is specified and must be a string with the\n" "filename where the socket is to be created.\n\n" "For a socket of family @code{AF_INET},\n" "@var{address} must be an integer IPv4 host address and\n" "@var{args} must be a single integer port number.\n\n" "For a socket of family @code{AF_INET6},\n" "@var{address} must be an integer IPv6 host address and\n" "@var{args} may be up to three integers:\n" "port [flowinfo] [scope_id],\n" "where flowinfo and scope_id default to zero.\n\n" "Alternatively, the second argument can be a socket address object " "as returned by @code{make-socket-address}, in which case the " "no additional arguments should be passed.\n\n" "Return true, unless the socket was configured to be non-blocking\n" "and the operation has not finished yet.\n") #define FUNC_NAME s_scm_connect { int fd; struct sockaddr *soka; size_t size; sock = SCM_COERCE_OUTPORT (sock); SCM_VALIDATE_OPFPORT (1, sock); fd = SCM_FPORT_FDES (sock); if (scm_is_eq (address, SCM_UNDEFINED)) /* No third argument was passed to FAM_OR_SOCKADDR must actually be a `socket address' object. */ soka = scm_to_sockaddr (fam_or_sockaddr, &size); else soka = scm_fill_sockaddr (scm_to_int (fam_or_sockaddr), address, &args, 3, FUNC_NAME, &size); if (connect (fd, soka, size) == -1) { int save_errno = errno; free (soka); errno = save_errno; if (errno == EINPROGRESS || errno == EAGAIN) return SCM_BOOL_F; SCM_SYSERROR; } free (soka); return SCM_BOOL_T; } #undef FUNC_NAME SCM_DEFINE (scm_bind, "bind", 2, 1, 1, (SCM sock, SCM fam_or_sockaddr, SCM address, SCM args), "Assign an address to the socket port @var{sock}.\n" "Generally this only needs to be done for server sockets,\n" "so they know where to look for incoming connections. A socket\n" "without an address will be assigned one automatically when it\n" "starts communicating.\n\n" "The format of @var{address} and @var{args} depends\n" "on the family of the socket.\n\n" "For a socket of family @code{AF_UNIX}, only @var{address}\n" "is specified and must be a string with the filename where\n" "the socket is to be created.\n\n" "For a socket of family @code{AF_INET}, @var{address}\n" "must be an integer IPv4 address and @var{args}\n" "must be a single integer port number.\n\n" "The values of the following variables can also be used for\n" "@var{address}:\n\n" "@defvar INADDR_ANY\n" "Allow connections from any address.\n" "@end defvar\n\n" "@defvar INADDR_LOOPBACK\n" "The address of the local host using the loopback device.\n" "@end defvar\n\n" "@defvar INADDR_BROADCAST\n" "The broadcast address on the local network.\n" "@end defvar\n\n" "@defvar INADDR_NONE\n" "No address.\n" "@end defvar\n\n" "For a socket of family @code{AF_INET6}, @var{address}\n" "must be an integer IPv6 address and @var{args}\n" "may be up to three integers:\n" "port [flowinfo] [scope_id],\n" "where flowinfo and scope_id default to zero.\n\n" "Alternatively, the second argument can be a socket address object " "as returned by @code{make-socket-address}, in which case the " "no additional arguments should be passed.\n\n" "The return value is unspecified.") #define FUNC_NAME s_scm_bind { struct sockaddr *soka; size_t size; int fd; sock = SCM_COERCE_OUTPORT (sock); SCM_VALIDATE_OPFPORT (1, sock); fd = SCM_FPORT_FDES (sock); if (scm_is_eq (address, SCM_UNDEFINED)) /* No third argument was passed to FAM_OR_SOCKADDR must actually be a `socket address' object. */ soka = scm_to_sockaddr (fam_or_sockaddr, &size); else soka = scm_fill_sockaddr (scm_to_int (fam_or_sockaddr), address, &args, 3, FUNC_NAME, &size); if (bind (fd, soka, size) == -1) { int save_errno = errno; free (soka); errno = save_errno; SCM_SYSERROR; } free (soka); return SCM_UNSPECIFIED; } #undef FUNC_NAME SCM_DEFINE (scm_listen, "listen", 2, 0, 0, (SCM sock, SCM backlog), "Enable @var{sock} to accept connection\n" "requests. @var{backlog} is an integer specifying\n" "the maximum length of the queue for pending connections.\n" "If the queue fills, new clients will fail to connect until\n" "the server calls @code{accept} to accept a connection from\n" "the queue.\n\n" "The return value is unspecified.") #define FUNC_NAME s_scm_listen { int fd; sock = SCM_COERCE_OUTPORT (sock); SCM_VALIDATE_OPFPORT (1, sock); fd = SCM_FPORT_FDES (sock); if (listen (fd, scm_to_int (backlog)) == -1) SCM_SYSERROR; return SCM_UNSPECIFIED; } #undef FUNC_NAME /* Put the components of a sockaddr into a new SCM vector. */ static SCM_C_INLINE_KEYWORD SCM _scm_from_sockaddr (const scm_t_max_sockaddr *address, unsigned addr_size, const char *proc) { SCM result = SCM_EOL; short int fam = ((struct sockaddr *) address)->sa_family; switch (fam) { case AF_INET: { const struct sockaddr_in *nad = (struct sockaddr_in *) address; result = scm_c_make_vector (3, SCM_UNSPECIFIED); SCM_SIMPLE_VECTOR_SET(result, 0, scm_from_short (fam)); SCM_SIMPLE_VECTOR_SET(result, 1, scm_from_ulong (ntohl (nad->sin_addr.s_addr))); SCM_SIMPLE_VECTOR_SET(result, 2, scm_from_ushort (ntohs (nad->sin_port))); } break; #ifdef HAVE_IPV6 case AF_INET6: { const struct sockaddr_in6 *nad = (struct sockaddr_in6 *) address; result = scm_c_make_vector (5, SCM_UNSPECIFIED); SCM_SIMPLE_VECTOR_SET(result, 0, scm_from_short (fam)); SCM_SIMPLE_VECTOR_SET(result, 1, scm_from_ipv6 (nad->sin6_addr.s6_addr)); SCM_SIMPLE_VECTOR_SET(result, 2, scm_from_ushort (ntohs (nad->sin6_port))); SCM_SIMPLE_VECTOR_SET(result, 3, scm_from_uint32 (nad->sin6_flowinfo)); #ifdef HAVE_SIN6_SCOPE_ID SCM_SIMPLE_VECTOR_SET(result, 4, scm_from_ulong (nad->sin6_scope_id)); #else SCM_SIMPLE_VECTOR_SET(result, 4, SCM_INUM0); #endif } break; #endif #ifdef HAVE_UNIX_DOMAIN_SOCKETS case AF_UNIX: { const struct sockaddr_un *nad = (struct sockaddr_un *) address; result = scm_c_make_vector (2, SCM_UNSPECIFIED); SCM_SIMPLE_VECTOR_SET(result, 0, scm_from_short (fam)); /* When addr_size is not enough to cover sun_path, do not try to access it. */ if (addr_size <= offsetof (struct sockaddr_un, sun_path)) SCM_SIMPLE_VECTOR_SET(result, 1, SCM_BOOL_F); else { size_t path_size = addr_size - offsetof (struct sockaddr_un, sun_path); SCM_SIMPLE_VECTOR_SET (result, 1, scm_from_locale_stringn (nad->sun_path, path_size)); } } break; #endif default: result = SCM_UNSPECIFIED; scm_misc_error (proc, "unrecognised address family: ~A", scm_list_1 (scm_from_int (fam))); } return result; } /* The publicly-visible function. Return a Scheme object representing ADDRESS, an address of ADDR_SIZE bytes. */ SCM scm_from_sockaddr (const struct sockaddr *address, unsigned addr_size) { return (_scm_from_sockaddr ((scm_t_max_sockaddr *) address, addr_size, "scm_from_sockaddr")); } /* Convert ADDRESS, an address object returned by either `scm_from_sockaddr ()' or `scm_make_socket_address ()', into its C representation. On success, a non-NULL pointer is returned and ADDRESS_SIZE is updated to the actual size (in bytes) of the returned address. The result must eventually be freed using `free ()'. */ struct sockaddr * scm_to_sockaddr (SCM address, size_t *address_size) #define FUNC_NAME "scm_to_sockaddr" { short int family; struct sockaddr *c_address = NULL; SCM_VALIDATE_VECTOR (1, address); *address_size = 0; family = scm_to_short (SCM_SIMPLE_VECTOR_REF (address, 0)); switch (family) { case AF_INET: { if (SCM_SIMPLE_VECTOR_LENGTH (address) != 3) scm_misc_error (FUNC_NAME, "invalid inet address representation: ~A", scm_list_1 (address)); else { struct sockaddr_in c_inet; memset (&c_inet, '\0', sizeof (struct sockaddr_in)); #ifdef HAVE_STRUCT_SOCKADDR_IN_SIN_LEN c_inet.sin_len = sizeof (struct sockaddr_in); #endif c_inet.sin_addr.s_addr = htonl (scm_to_ulong (SCM_SIMPLE_VECTOR_REF (address, 1))); c_inet.sin_port = htons (scm_to_ushort (SCM_SIMPLE_VECTOR_REF (address, 2))); c_inet.sin_family = AF_INET; *address_size = sizeof (c_inet); c_address = scm_malloc (sizeof (c_inet)); memcpy (c_address, &c_inet, sizeof (c_inet)); } break; } #ifdef HAVE_IPV6 case AF_INET6: { if (SCM_SIMPLE_VECTOR_LENGTH (address) != 5) scm_misc_error (FUNC_NAME, "invalid inet6 address representation: ~A", scm_list_1 (address)); else { struct sockaddr_in6 c_inet6; scm_to_ipv6 (c_inet6.sin6_addr.s6_addr, SCM_SIMPLE_VECTOR_REF (address, 1)); c_inet6.sin6_port = htons (scm_to_ushort (SCM_SIMPLE_VECTOR_REF (address, 2))); c_inet6.sin6_flowinfo = scm_to_uint32 (SCM_SIMPLE_VECTOR_REF (address, 3)); #ifdef HAVE_SIN6_SCOPE_ID c_inet6.sin6_scope_id = scm_to_ulong (SCM_SIMPLE_VECTOR_REF (address, 4)); #endif c_inet6.sin6_family = AF_INET6; *address_size = sizeof (c_inet6); c_address = scm_malloc (sizeof (c_inet6)); memcpy (c_address, &c_inet6, sizeof (c_inet6)); } break; } #endif #ifdef HAVE_UNIX_DOMAIN_SOCKETS case AF_UNIX: { if (SCM_SIMPLE_VECTOR_LENGTH (address) != 2) scm_misc_error (FUNC_NAME, "invalid unix address representation: ~A", scm_list_1 (address)); else { SCM path; size_t path_len = 0; path = SCM_SIMPLE_VECTOR_REF (address, 1); if (!scm_is_string (path) && !scm_is_false (path)) scm_misc_error (FUNC_NAME, "invalid unix address " "path: ~A", scm_list_1 (path)); else { struct sockaddr_un c_unix; if (scm_is_false (path)) path_len = 0; else path_len = scm_c_string_length (path); #ifdef UNIX_PATH_MAX if (path_len >= UNIX_PATH_MAX) #else /* We can hope that this limit will eventually vanish, at least on GNU. However, currently, while glibc doesn't define `UNIX_PATH_MAX', it documents it has being limited to 108 bytes. */ if (path_len >= sizeof (c_unix.sun_path)) #endif scm_misc_error (FUNC_NAME, "unix address path " "too long: ~A", scm_list_1 (path)); else { if (path_len) { scm_to_locale_stringbuf (path, c_unix.sun_path, #ifdef UNIX_PATH_MAX UNIX_PATH_MAX); #else sizeof (c_unix.sun_path)); #endif c_unix.sun_path[path_len] = '\0'; /* Sanity check. */ if (strlen (c_unix.sun_path) != path_len) scm_misc_error (FUNC_NAME, "unix address path " "contains nul characters: ~A", scm_list_1 (path)); } else c_unix.sun_path[0] = '\0'; c_unix.sun_family = AF_UNIX; *address_size = SUN_LEN (&c_unix); c_address = scm_malloc (sizeof (c_unix)); memcpy (c_address, &c_unix, sizeof (c_unix)); } } } break; } #endif default: scm_misc_error (FUNC_NAME, "unrecognised address family: ~A", scm_list_1 (scm_from_ushort (family))); } return c_address; } #undef FUNC_NAME /* Return a newly-allocated `sockaddr' structure that reflects ADDRESS, being an address of family FAMILY, with the family-specific parameters ARGS (see the description of `connect' for details). The returned structure may be freed using `free ()'. */ struct sockaddr * scm_c_make_socket_address (SCM family, SCM address, SCM args, size_t *address_size) { struct sockaddr *soka; soka = scm_fill_sockaddr (scm_to_ushort (family), address, &args, 1, "scm_c_make_socket_address", address_size); return soka; } SCM_DEFINE (scm_make_socket_address, "make-socket-address", 2, 0, 1, (SCM family, SCM address, SCM args), "Return a Scheme address object that reflects @var{address}, " "being an address of family @var{family}, with the " "family-specific parameters @var{args} (see the description of " "@code{connect} for details).") #define FUNC_NAME s_scm_make_socket_address { SCM result = SCM_BOOL_F; struct sockaddr *c_address; size_t c_address_size; c_address = scm_c_make_socket_address (family, address, args, &c_address_size); if (c_address != NULL) { result = scm_from_sockaddr (c_address, c_address_size); free (c_address); } return result; } #undef FUNC_NAME SCM_DEFINE (scm_accept4, "accept", 1, 1, 0, (SCM sock, SCM flags), "Accept a connection on a bound, listening socket. If there\n" "are no pending connections in the queue, there are two\n" "possibilities: if the socket has been configured as\n" "non-blocking, return @code{#f} directly. Otherwise wait\n" "until a connection is available. When a connection comes,\n" "the return value is a pair in which the @emph{car} is a new\n" "socket port for the connection and the @emph{cdr} is an\n" "object with address information about the client which\n" "initiated the connection.\n\n" "@var{sock} does not become part of the\n" "connection and will continue to accept new requests.") #define FUNC_NAME s_scm_accept4 { int fd; int newfd; int c_flags; SCM address; SCM newsock; socklen_t addr_size = MAX_ADDR_SIZE; scm_t_max_sockaddr addr; sock = SCM_COERCE_OUTPORT (sock); SCM_VALIDATE_OPFPORT (1, sock); c_flags = SCM_UNBNDP (flags) ? 0 : scm_to_int (flags); fd = SCM_FPORT_FDES (sock); SCM_SYSCALL (newfd = accept4 (fd, (struct sockaddr *) &addr, &addr_size, c_flags)); if (newfd == -1) { if (errno == EAGAIN || errno == EWOULDBLOCK) return SCM_BOOL_F; SCM_SYSERROR; } newsock = scm_socket_fd_to_port (newfd); address = _scm_from_sockaddr (&addr, addr_size, FUNC_NAME); return scm_cons (newsock, address); } #undef FUNC_NAME SCM scm_accept (SCM sock) { return scm_accept4 (sock, SCM_UNDEFINED); } SCM_DEFINE (scm_getsockname, "getsockname", 1, 0, 0, (SCM sock), "Return the address of @var{sock}, in the same form as the\n" "object returned by @code{accept}. On many systems the address\n" "of a socket in the @code{AF_FILE} namespace cannot be read.") #define FUNC_NAME s_scm_getsockname { int fd; socklen_t addr_size = MAX_ADDR_SIZE; scm_t_max_sockaddr addr; sock = SCM_COERCE_OUTPORT (sock); SCM_VALIDATE_OPFPORT (1, sock); fd = SCM_FPORT_FDES (sock); if (getsockname (fd, (struct sockaddr *) &addr, &addr_size) == -1) SCM_SYSERROR; return _scm_from_sockaddr (&addr, addr_size, FUNC_NAME); } #undef FUNC_NAME SCM_DEFINE (scm_getpeername, "getpeername", 1, 0, 0, (SCM sock), "Return the address that @var{sock}\n" "is connected to, in the same form as the object returned by\n" "@code{accept}. On many systems the address of a socket in the\n" "@code{AF_FILE} namespace cannot be read.") #define FUNC_NAME s_scm_getpeername { int fd; socklen_t addr_size = MAX_ADDR_SIZE; scm_t_max_sockaddr addr; sock = SCM_COERCE_OUTPORT (sock); SCM_VALIDATE_OPFPORT (1, sock); fd = SCM_FPORT_FDES (sock); if (getpeername (fd, (struct sockaddr *) &addr, &addr_size) == -1) SCM_SYSERROR; return _scm_from_sockaddr (&addr, addr_size, FUNC_NAME); } #undef FUNC_NAME SCM_DEFINE (scm_recv, "recv!", 2, 1, 0, (SCM sock, SCM buf, SCM flags), "Receive data from a socket port.\n" "@var{sock} must already\n" "be bound to the address from which data is to be received.\n" "@var{buf} is a bytevector into which\n" "the data will be written. The size of @var{buf} limits\n" "the amount of\n" "data which can be received: in the case of packet\n" "protocols, if a packet larger than this limit is encountered\n" "then some data\n" "will be irrevocably lost.\n\n" "The optional @var{flags} argument is a value or\n" "bitwise OR of MSG_OOB, MSG_PEEK, MSG_DONTROUTE etc.\n\n" "The value returned is the number of bytes read from the\n" "socket.\n\n" "Note that the data is read directly from the socket file\n" "descriptor:\n" "any unread buffered port data is ignored.") #define FUNC_NAME s_scm_recv { int rv, fd, flg; SCM_VALIDATE_OPFPORT (1, sock); if (SCM_UNBNDP (flags)) flg = 0; else flg = scm_to_int (flags); fd = SCM_FPORT_FDES (sock); SCM_VALIDATE_BYTEVECTOR (1, buf); SCM_SYSCALL (rv = recv (fd, SCM_BYTEVECTOR_CONTENTS (buf), SCM_BYTEVECTOR_LENGTH (buf), flg)); if (SCM_UNLIKELY (rv == -1)) SCM_SYSERROR; scm_remember_upto_here (buf); return scm_from_int (rv); } #undef FUNC_NAME SCM_DEFINE (scm_send, "send", 2, 1, 0, (SCM sock, SCM message, SCM flags), "Transmit bytevector @var{message} on socket port @var{sock}.\n" "@var{sock} must already be bound to a destination address. The\n" "value returned is the number of bytes transmitted --\n" "it's possible for\n" "this to be less than the length of @var{message}\n" "if the socket is\n" "set to be non-blocking. The optional @var{flags} argument\n" "is a value or\n" "bitwise OR of MSG_OOB, MSG_PEEK, MSG_DONTROUTE etc.\n\n" "Note that the data is written directly to the socket\n" "file descriptor:\n" "any unflushed buffered port data is ignored.\n\n" "This operation is defined only for strings containing codepoints\n" "zero to 255.") #define FUNC_NAME s_scm_send { int rv, fd, flg; sock = SCM_COERCE_OUTPORT (sock); SCM_VALIDATE_OPFPORT (1, sock); if (SCM_UNBNDP (flags)) flg = 0; else flg = scm_to_int (flags); fd = SCM_FPORT_FDES (sock); SCM_VALIDATE_BYTEVECTOR (1, message); SCM_SYSCALL (rv = send (fd, SCM_BYTEVECTOR_CONTENTS (message), SCM_BYTEVECTOR_LENGTH (message), flg)); if (rv == -1) SCM_SYSERROR; scm_remember_upto_here_1 (message); return scm_from_int (rv); } #undef FUNC_NAME SCM_DEFINE (scm_recvfrom, "recvfrom!", 2, 3, 0, (SCM sock, SCM buf, SCM flags, SCM start, SCM end), "Receive data from socket port @var{sock} (which must be already\n" "bound), returning the originating address as well as the data.\n" "This is usually for use on datagram sockets, but can be used on\n" "stream-oriented sockets too.\n" "\n" "The data received is stored in bytevector @var{buf}, using\n" "either the whole bytevector or just the region between the optional\n" "@var{start} and @var{end} positions. The size of @var{buf}\n" "limits the amount of data that can be received. For datagram\n" "protocols, if a packet larger than this is received then excess\n" "bytes are irrevocably lost.\n" "\n" "The return value is a pair. The @code{car} is the number of\n" "bytes read. The @code{cdr} is a socket address object which is\n" "where the data came from, or @code{#f} if the origin is\n" "unknown.\n" "\n" "The optional @var{flags} argument is a or bitwise OR\n" "(@code{logior}) of @code{MSG_OOB}, @code{MSG_PEEK},\n" "@code{MSG_DONTROUTE} etc.\n" "\n" "Data is read directly from the socket file descriptor, any\n" "buffered port data is ignored.\n" "\n" "On a GNU/Linux system @code{recvfrom!} is not multi-threading,\n" "all threads stop while a @code{recvfrom!} call is in progress.\n" "An application may need to use @code{select}, @code{O_NONBLOCK}\n" "or @code{MSG_DONTWAIT} to avoid this.") #define FUNC_NAME s_scm_recvfrom { int rv, fd, flg; SCM address; size_t offset, cend; socklen_t addr_size = MAX_ADDR_SIZE; scm_t_max_sockaddr addr; SCM_VALIDATE_OPFPORT (1, sock); fd = SCM_FPORT_FDES (sock); if (SCM_UNBNDP (flags)) flg = 0; else SCM_VALIDATE_ULONG_COPY (3, flags, flg); ((struct sockaddr *) &addr)->sa_family = AF_UNSPEC; SCM_VALIDATE_BYTEVECTOR (1, buf); if (SCM_UNBNDP (end)) cend = SCM_BYTEVECTOR_LENGTH (buf); else { cend = scm_to_size_t (end); if (SCM_UNLIKELY (cend > SCM_BYTEVECTOR_LENGTH (buf))) scm_out_of_range (FUNC_NAME, end); } if (SCM_UNBNDP (start)) offset = 0; else { offset = scm_to_size_t (start); if (SCM_UNLIKELY (cend < offset)) scm_out_of_range (FUNC_NAME, start); } SCM_SYSCALL (rv = recvfrom (fd, SCM_BYTEVECTOR_CONTENTS (buf) + offset, cend - offset, flg, (struct sockaddr *) &addr, &addr_size)); if (rv == -1) SCM_SYSERROR; /* `recvfrom' does not necessarily return an address. Usually nothing is returned for stream sockets. */ if (((struct sockaddr *) &addr)->sa_family != AF_UNSPEC) address = _scm_from_sockaddr (&addr, addr_size, FUNC_NAME); else address = SCM_BOOL_F; scm_remember_upto_here_1 (buf); return scm_cons (scm_from_int (rv), address); } #undef FUNC_NAME SCM_DEFINE (scm_sendto, "sendto", 3, 1, 1, (SCM sock, SCM message, SCM fam_or_sockaddr, SCM address, SCM args_and_flags), "Transmit bytevector @var{message} on socket port\n" "@var{sock}. The\n" "destination address is specified using the @var{fam_or_sockaddr},\n" "@var{address} and\n" "@var{args_and_flags} arguments, or just a socket address object " "returned by @code{make-socket-address}, in a similar way to the\n" "@code{connect} procedure. @var{args_and_flags} contains\n" "the usual connection arguments optionally followed by\n" "a flags argument, which is a value or\n" "bitwise OR of MSG_OOB, MSG_PEEK, MSG_DONTROUTE etc.\n\n" "The value returned is the number of bytes transmitted --\n" "it's possible for\n" "this to be less than the length of @var{message} if the\n" "socket is\n" "set to be non-blocking.\n" "Note that the data is written directly to the socket\n" "file descriptor:\n" "any unflushed buffered port data is ignored.\n" "This operation is defined only for strings containing codepoints\n" "zero to 255.") #define FUNC_NAME s_scm_sendto { int rv, fd, flg; struct sockaddr *soka; size_t size; sock = SCM_COERCE_OUTPORT (sock); SCM_VALIDATE_FPORT (1, sock); fd = SCM_FPORT_FDES (sock); if (!scm_is_number (fam_or_sockaddr)) { /* FAM_OR_SOCKADDR must actually be a `socket address' object. This means that the following arguments, i.e. ADDRESS and those listed in ARGS_AND_FLAGS, are the `MSG_' flags. */ soka = scm_to_sockaddr (fam_or_sockaddr, &size); if (!scm_is_eq (address, SCM_UNDEFINED)) args_and_flags = scm_cons (address, args_and_flags); } else soka = scm_fill_sockaddr (scm_to_int (fam_or_sockaddr), address, &args_and_flags, 3, FUNC_NAME, &size); if (scm_is_null (args_and_flags)) flg = 0; else { SCM_VALIDATE_CONS (5, args_and_flags); flg = SCM_NUM2ULONG (5, SCM_CAR (args_and_flags)); } SCM_VALIDATE_BYTEVECTOR (1, message); SCM_SYSCALL (rv = sendto (fd, SCM_BYTEVECTOR_CONTENTS (message), SCM_BYTEVECTOR_LENGTH (message), flg, soka, size)); if (rv == -1) { int save_errno = errno; free (soka); errno = save_errno; SCM_SYSERROR; } free (soka); scm_remember_upto_here_1 (message); return scm_from_int (rv); } #undef FUNC_NAME void scm_init_socket () { /* protocol families. */ #ifdef AF_UNSPEC scm_c_define ("AF_UNSPEC", scm_from_int (AF_UNSPEC)); #endif #if defined HAVE_UNIX_DOMAIN_SOCKETS && defined AF_UNIX scm_c_define ("AF_UNIX", scm_from_int (AF_UNIX)); #endif #ifdef AF_INET scm_c_define ("AF_INET", scm_from_int (AF_INET)); #endif #ifdef AF_INET6 scm_c_define ("AF_INET6", scm_from_int (AF_INET6)); #endif #ifdef PF_UNSPEC scm_c_define ("PF_UNSPEC", scm_from_int (PF_UNSPEC)); #endif #ifdef PF_UNIX scm_c_define ("PF_UNIX", scm_from_int (PF_UNIX)); #endif #ifdef PF_INET scm_c_define ("PF_INET", scm_from_int (PF_INET)); #endif #ifdef PF_INET6 scm_c_define ("PF_INET6", scm_from_int (PF_INET6)); #endif /* standard addresses. */ #ifdef INADDR_ANY scm_c_define ("INADDR_ANY", scm_from_ulong (INADDR_ANY)); scm_c_define ("IN6ADDR_ANY", scm_from_ulong (0)); #endif #ifdef INADDR_BROADCAST scm_c_define ("INADDR_BROADCAST", scm_from_ulong (INADDR_BROADCAST)); #endif #ifdef INADDR_NONE scm_c_define ("INADDR_NONE", scm_from_ulong (INADDR_NONE)); #endif #ifdef INADDR_LOOPBACK scm_c_define ("INADDR_LOOPBACK", scm_from_ulong (INADDR_LOOPBACK)); scm_c_define ("IN6ADDR_LOOPBACK", scm_from_ulong (1)); #endif /* socket types. SOCK_PACKET is deliberately omitted, the GNU/Linux socket(2) and packet(7) advise that it's obsolete and strongly deprecated. */ #ifdef SOCK_STREAM scm_c_define ("SOCK_STREAM", scm_from_int (SOCK_STREAM)); #endif #ifdef SOCK_DGRAM scm_c_define ("SOCK_DGRAM", scm_from_int (SOCK_DGRAM)); #endif #ifdef SOCK_SEQPACKET scm_c_define ("SOCK_SEQPACKET", scm_from_int (SOCK_SEQPACKET)); #endif #ifdef SOCK_RAW scm_c_define ("SOCK_RAW", scm_from_int (SOCK_RAW)); #endif #ifdef SOCK_RDM scm_c_define ("SOCK_RDM", scm_from_int (SOCK_RDM)); #endif /* accept4 flags. */ #ifdef SOCK_CLOEXEC scm_c_define ("SOCK_CLOEXEC", scm_from_int (SOCK_CLOEXEC)); #endif #ifdef SOCK_NONBLOCK scm_c_define ("SOCK_NONBLOCK", scm_from_int (SOCK_NONBLOCK)); #endif /* setsockopt level. SOL_IP, SOL_TCP and SOL_UDP are defined on gnu/linux, but not on for instance NetBSD. We define IPPROTOs because that's what the posix spec shows in its example at http://www.opengroup.org/onlinepubs/007904975/functions/getsockopt.html */ #ifdef SOL_SOCKET scm_c_define ("SOL_SOCKET", scm_from_int (SOL_SOCKET)); #endif #ifdef IPPROTO_IP scm_c_define ("IPPROTO_IP", scm_from_int (IPPROTO_IP)); #endif #ifdef IPPROTO_IPV6 scm_c_define ("IPPROTO_IPV6", scm_from_int (IPPROTO_IPV6)); #endif #ifdef IPPROTO_TCP scm_c_define ("IPPROTO_TCP", scm_from_int (IPPROTO_TCP)); #endif #ifdef IPPROTO_UDP scm_c_define ("IPPROTO_UDP", scm_from_int (IPPROTO_UDP)); #endif /* setsockopt names. */ #ifdef SO_DEBUG scm_c_define ("SO_DEBUG", scm_from_int (SO_DEBUG)); #endif #ifdef SO_REUSEADDR scm_c_define ("SO_REUSEADDR", scm_from_int (SO_REUSEADDR)); #endif #ifdef SO_STYLE scm_c_define ("SO_STYLE", scm_from_int (SO_STYLE)); #endif #ifdef SO_TYPE scm_c_define ("SO_TYPE", scm_from_int (SO_TYPE)); #endif #ifdef SO_ERROR scm_c_define ("SO_ERROR", scm_from_int (SO_ERROR)); #endif #ifdef SO_DONTROUTE scm_c_define ("SO_DONTROUTE", scm_from_int (SO_DONTROUTE)); #endif #ifdef SO_BROADCAST scm_c_define ("SO_BROADCAST", scm_from_int (SO_BROADCAST)); #endif #ifdef SO_SNDBUF scm_c_define ("SO_SNDBUF", scm_from_int (SO_SNDBUF)); #endif #ifdef SO_RCVBUF scm_c_define ("SO_RCVBUF", scm_from_int (SO_RCVBUF)); #endif #ifdef SO_KEEPALIVE scm_c_define ("SO_KEEPALIVE", scm_from_int (SO_KEEPALIVE)); #endif #ifdef SO_OOBINLINE scm_c_define ("SO_OOBINLINE", scm_from_int (SO_OOBINLINE)); #endif #ifdef SO_NO_CHECK scm_c_define ("SO_NO_CHECK", scm_from_int (SO_NO_CHECK)); #endif #ifdef SO_PRIORITY scm_c_define ("SO_PRIORITY", scm_from_int (SO_PRIORITY)); #endif #ifdef SO_LINGER scm_c_define ("SO_LINGER", scm_from_int (SO_LINGER)); #endif #ifdef SO_REUSEPORT /* new in Linux 3.9 */ scm_c_define ("SO_REUSEPORT", scm_from_int (SO_REUSEPORT)); #endif #ifdef SO_RCVTIMEO scm_c_define ("SO_RCVTIMEO", scm_from_int (SO_RCVTIMEO)); #endif #ifdef SO_SNDTIMEO scm_c_define ("SO_SNDTIMEO", scm_from_int (SO_SNDTIMEO)); #endif /* recv/send options. */ #ifdef MSG_DONTWAIT scm_c_define ("MSG_DONTWAIT", scm_from_int (MSG_DONTWAIT)); #endif #ifdef MSG_OOB scm_c_define ("MSG_OOB", scm_from_int (MSG_OOB)); #endif #ifdef MSG_PEEK scm_c_define ("MSG_PEEK", scm_from_int (MSG_PEEK)); #endif #ifdef MSG_DONTROUTE scm_c_define ("MSG_DONTROUTE", scm_from_int (MSG_DONTROUTE)); #endif /* TCP options. */ #ifdef TCP_NODELAY scm_c_define ("TCP_NODELAY", scm_from_int (TCP_NODELAY)); #endif #ifdef TCP_CORK scm_c_define ("TCP_CORK", scm_from_int (TCP_CORK)); #endif #ifdef IP_ADD_MEMBERSHIP scm_c_define ("IP_ADD_MEMBERSHIP", scm_from_int (IP_ADD_MEMBERSHIP)); scm_c_define ("IP_DROP_MEMBERSHIP", scm_from_int (IP_DROP_MEMBERSHIP)); #endif #ifdef IP_MULTICAST_TTL scm_c_define ("IP_MULTICAST_TTL", scm_from_int ( IP_MULTICAST_TTL)); #endif #ifdef IP_MULTICAST_IF scm_c_define ("IP_MULTICAST_IF", scm_from_int ( IP_MULTICAST_IF)); #endif #ifdef IPV6_V6ONLY scm_c_define ("IPV6_V6ONLY", scm_from_int (IPV6_V6ONLY)); #endif scm_add_feature ("socket"); #include "socket.x" }