/*
* Copyright (C) Igor Sysoev
* Copyright (C) NGINX, Inc.
*/
#include <nxt_main.h>
#if (NXT_INET6)
static u_char *nxt_inet6_ntop(u_char *addr, u_char *buf, u_char *end);
#endif
static nxt_int_t nxt_job_sockaddr_unix_parse(nxt_job_sockaddr_parse_t *jbs);
static nxt_int_t nxt_job_sockaddr_inet6_parse(nxt_job_sockaddr_parse_t *jbs);
static nxt_int_t nxt_job_sockaddr_inet_parse(nxt_job_sockaddr_parse_t *jbs);
nxt_sockaddr_t *
nxt_sockaddr_alloc(nxt_mem_pool_t *mp, socklen_t length)
{
nxt_sockaddr_t *sa;
/*
* The current struct sockaddr's define 32-bit fields at maximum
* and may define 64-bit AF_INET6 fields in the future. Alignment
* of memory allocated by nxt_mem_zalloc() is enough for these fields.
* If 128-bit alignment will be required then nxt_mem_malloc() and
* nxt_memzero() should be used instead.
*/
sa = nxt_mem_zalloc(mp, offsetof(nxt_sockaddr_t, u) + length);
if (nxt_fast_path(sa != NULL)) {
nxt_socklen_set(sa, length);
}
return sa;
}
nxt_sockaddr_t *
nxt_sockaddr_create(nxt_mem_pool_t *mp, struct sockaddr *sockaddr,
socklen_t length)
{
size_t size, copy;
nxt_sockaddr_t *sa;
size = length;
copy = length;
#if (NXT_HAVE_UNIX_DOMAIN)
/*
* Unspecified Unix domain sockaddr_un form and length are very
* platform depended (see comment in unix/socket.h). Here they are
* normalized to the sockaddr_un with single zero byte sun_path[].
*/
if (size <= offsetof(struct sockaddr_un, sun_path)) {
/*
* Small socket length means a short unspecified Unix domain
* socket address:
*
* getsockname() and getpeername() on OpenBSD prior to 5.3
* return zero length and does not update a passed sockaddr
* buffer at all.
*
* Linux returns length equal to 2, i.e. sockaddr_un without
* sun_path[], unix(7):
*
* unnamed: A stream socket that has not been bound
* to a pathname using bind(2) has no name. Likewise,
* the two sockets created by socketpair(2) are unnamed.
* When the address of an unnamed socket is returned by
* getsockname(2), getpeername(2), and accept(2), its
* length is sizeof(sa_family_t), and sun_path should
* not be inspected.
*/
size = offsetof(struct sockaddr_un, sun_path) + 1;
#if !(NXT_LINUX)
} else if (sockaddr->sa_family == AF_UNIX && sockaddr->sa_data[0] == '\0') {
/*
* Omit nonsignificant zeros of the unspecified Unix domain socket
* address. This test is disabled for Linux since Linux abstract
* socket address also starts with zero. However Linux unspecified
* Unix domain socket address is short and is handled above.
*/
size = offsetof(struct sockaddr_un, sun_path) + 1;
copy = size;
#endif
}
#endif /* NXT_HAVE_UNIX_DOMAIN */
sa = nxt_sockaddr_alloc(mp, size);
if (nxt_fast_path(sa != NULL)) {
nxt_memcpy(&sa->u.sockaddr, sockaddr, copy);
#if (NXT_SOCKADDR_SA_LEN)
/* Update shortcut sockaddr length overwritten by nxt_memcpy(). */
nxt_socklen_set(sa, size);
#endif
#if (NXT_HAVE_UNIX_DOMAIN && NXT_OPENBSD)
if (length == 0) {
sa->u.sockaddr.sa_family = AF_UNIX;
}
#endif
}
return sa;
}
nxt_sockaddr_t *
nxt_sockaddr_copy(nxt_mem_pool_t *mp, nxt_sockaddr_t *src)
{
size_t length;
nxt_sockaddr_t *dst;
length = offsetof(nxt_sockaddr_t, u) + nxt_socklen(src);
dst = nxt_mem_alloc(mp, length);
if (nxt_fast_path(dst != NULL)) {
nxt_memcpy(dst, src, length);
}
return dst;
}
nxt_sockaddr_t *
nxt_getsockname(nxt_mem_pool_t *mp, nxt_socket_t s)
{
int ret;
socklen_t socklen;
nxt_sockaddr_buf_t sockaddr;
socklen = NXT_SOCKADDR_LEN;
ret = getsockname(s, &sockaddr.buf, &socklen);
if (nxt_fast_path(ret == 0)) {
return nxt_sockaddr_create(mp, &sockaddr.buf, socklen);
}
nxt_thread_log_error(NXT_LOG_ERR, "getsockname(%d) failed %E",
s, nxt_errno);
return NULL;
}
nxt_int_t
nxt_sockaddr_text(nxt_mem_pool_t *mp, nxt_sockaddr_t *sa, nxt_bool_t port)
{
size_t length;
u_char *p;
u_char buf[NXT_SOCKADDR_STR_LEN + NXT_SOCKPORT_STR_LEN];
length = NXT_SOCKADDR_STR_LEN + NXT_SOCKPORT_STR_LEN;
length = nxt_sockaddr_ntop(sa, buf, buf + length, port);
p = nxt_mem_alloc(mp, length);
if (nxt_fast_path(p != NULL)) {
sa->text = p;
sa->text_len = length;
nxt_memcpy(p, buf, length);
return NXT_OK;
}
return NXT_ERROR;
}
uint32_t
nxt_sockaddr_port(nxt_sockaddr_t *sa)
{
uint32_t port;
switch (sa->u.sockaddr.sa_family) {
#if (NXT_INET6)
case AF_INET6:
port = sa->u.sockaddr_in6.sin6_port;
break;
#endif
#if (NXT_HAVE_UNIX_DOMAIN)
case AF_UNIX:
return 0;
#endif
default:
port = sa->u.sockaddr_in.sin_port;
break;
}
return ntohs((uint16_t) port);
}
nxt_bool_t
nxt_sockaddr_cmp(nxt_sockaddr_t *sa1, nxt_sockaddr_t *sa2)
{
if (nxt_socklen(sa1) != nxt_socklen(sa2)) {
return 0;
}
if (sa1->type != sa2->type) {
return 0;
}
if (sa1->u.sockaddr.sa_family != sa2->u.sockaddr.sa_family) {
return 0;
}
/*
* sockaddr struct's cannot be compared in whole since kernel
* may fill some fields in inherited sockaddr struct's.
*/
switch (sa1->u.sockaddr.sa_family) {
#if (NXT_INET6)
case AF_INET6:
if (sa1->u.sockaddr_in6.sin6_port != sa2->u.sockaddr_in6.sin6_port) {
return 0;
}
if (nxt_memcmp(&sa1->u.sockaddr_in6.sin6_addr,
&sa2->u.sockaddr_in6.sin6_addr, 16)
!= 0)
{
return 0;
}
return 1;
#endif
#if (NXT_HAVE_UNIX_DOMAIN)
case AF_UNIX:
{
size_t length;
length = nxt_socklen(sa1) - offsetof(struct sockaddr_un, sun_path);
if (nxt_memcmp(&sa1->u.sockaddr_un.sun_path,
&sa2->u.sockaddr_un.sun_path, length)
!= 0)
{
return 0;
}
return 1;
}
#endif
default: /* AF_INET */
if (sa1->u.sockaddr_in.sin_port != sa2->u.sockaddr_in.sin_port) {
return 0;
}
if (sa1->u.sockaddr_in.sin_addr.s_addr
!= sa2->u.sockaddr_in.sin_addr.s_addr)
{
return 0;
}
return 1;
}
}
size_t
nxt_sockaddr_ntop(nxt_sockaddr_t *sa, u_char *buf, u_char *end, nxt_bool_t port)
{
u_char *p;
switch (sa->u.sockaddr.sa_family) {
case AF_INET:
p = (u_char *) &sa->u.sockaddr_in.sin_addr;
if (port) {
p = nxt_sprintf(buf, end, "%ud.%ud.%ud.%ud:%d",
p[0], p[1], p[2], p[3],
ntohs(sa->u.sockaddr_in.sin_port));
} else {
p = nxt_sprintf(buf, end, "%ud.%ud.%ud.%ud",
p[0], p[1], p[2], p[3]);
}
return p - buf;
#if (NXT_INET6)
case AF_INET6:
p = buf;
if (port) {
*p++ = '[';
}
p = nxt_inet6_ntop(sa->u.sockaddr_in6.sin6_addr.s6_addr, p, end);
if (port) {
p = nxt_sprintf(p, end, "]:%d",
ntohs(sa->u.sockaddr_in6.sin6_port));
}
return p - buf;
#endif
#if (NXT_HAVE_UNIX_DOMAIN)
case AF_UNIX:
#if (NXT_LINUX)
p = (u_char *) sa->u.sockaddr_un.sun_path;
if (p[0] == '\0') {
int length;
/* Linux abstract socket address has no trailing zero. */
length = nxt_socklen(sa)
- offsetof(struct sockaddr_un, sun_path) - 1;
p = nxt_sprintf(buf, end, "unix:\\0%*s", length, p + 1);
} else {
p = nxt_sprintf(buf, end, "unix:%s", p);
}
#else /* !(NXT_LINUX) */
p = nxt_sprintf(buf, end, "unix:%s", sa->u.sockaddr_un.sun_path);
#endif
return p - buf;
#endif /* NXT_HAVE_UNIX_DOMAIN */
default:
return 0;
}
}
#if (NXT_INET6)
static u_char *
nxt_inet6_ntop(u_char *addr, u_char *buf, u_char *end)
{
u_char *p;
size_t zero_groups, last_zero_groups, ipv6_bytes;
nxt_uint_t i, zero_start, last_zero_start;
if (buf + NXT_INET6_ADDR_STR_LEN > end) {
return buf;
}
zero_start = 8;
zero_groups = 0;
last_zero_start = 8;
last_zero_groups = 0;
for (i = 0; i < 16; i += 2) {
if (addr[i] == 0 && addr[i + 1] == 0) {
if (last_zero_groups == 0) {
last_zero_start = i;
}
last_zero_groups++;
} else {
if (zero_groups < last_zero_groups) {
zero_groups = last_zero_groups;
zero_start = last_zero_start;
}
last_zero_groups = 0;
}
}
if (zero_groups < last_zero_groups) {
zero_groups = last_zero_groups;
zero_start = last_zero_start;
}
ipv6_bytes = 16;
p = buf;
if (zero_start == 0) {
/* IPv4-mapped address */
if ((zero_groups == 5 && addr[10] == 0xff && addr[11] == 0xff)
/* IPv4-compatible address */
|| (zero_groups == 6)
/* not IPv6 loopback address */
|| (zero_groups == 7 && addr[14] != 0 && addr[15] != 1))
{
ipv6_bytes = 12;
}
*p++ = ':';
}
for (i = 0; i < ipv6_bytes; i += 2) {
if (i == zero_start) {
/* Output maximum number of consecutive zero groups as "::". */
i += (zero_groups - 1) * 2;
*p++ = ':';
continue;
}
p = nxt_sprintf(p, end, "%uxd", (addr[i] << 8) + addr[i + 1]);
if (i < 14) {
*p++ = ':';
}
}
if (ipv6_bytes == 12) {
p = nxt_sprintf(p, end, "%ud.%ud.%ud.%ud",
addr[12], addr[13], addr[14], addr[15]);
}
return p;
}
#endif
void
nxt_job_sockaddr_parse(nxt_job_sockaddr_parse_t *jbs)
{
u_char *p;
size_t length;
nxt_int_t ret;
nxt_work_handler_t handler;
nxt_job_set_name(&jbs->resolve.job, "job sockaddr parse");
length = jbs->addr.length;
p = jbs->addr.start;
if (length > 6 && nxt_memcmp(p, (u_char *) "unix:", 5) == 0) {
ret = nxt_job_sockaddr_unix_parse(jbs);
} else if (length != 0 && *p == '[') {
ret = nxt_job_sockaddr_inet6_parse(jbs);
} else {
ret = nxt_job_sockaddr_inet_parse(jbs);
}
switch (ret) {
case NXT_OK:
handler = jbs->resolve.ready_handler;
break;
case NXT_ERROR:
handler = jbs->resolve.error_handler;
break;
default: /* NXT_AGAIN */
return;
}
nxt_job_return(jbs->resolve.job.task, &jbs->resolve.job, handler);
}
static nxt_int_t
nxt_job_sockaddr_unix_parse(nxt_job_sockaddr_parse_t *jbs)
{
#if (NXT_HAVE_UNIX_DOMAIN)
size_t length, socklen;
u_char *path;
nxt_mem_pool_t *mp;
nxt_sockaddr_t *sa;
/*
* Actual sockaddr_un length can be lesser or even larger than defined
* struct sockaddr_un length (see comment in unix/nxt_socket.h). So
* limit maximum Unix domain socket address length by defined sun_path[]
* length because some OSes accept addresses twice larger than defined
* struct sockaddr_un. Also reserve space for a trailing zero to avoid
* ambiguity, since many OSes accept Unix domain socket addresses
* without a trailing zero.
*/
const size_t max_len = sizeof(struct sockaddr_un)
- offsetof(struct sockaddr_un, sun_path) - 1;
/* cutting "unix:" */
length = jbs->addr.length - 5;
path = jbs->addr.start + 5;
if (length > max_len) {
nxt_thread_log_error(jbs->resolve.log_level,
"unix domain socket \"%V\" name is too long",
&jbs->addr);
return NXT_ERROR;
}
socklen = offsetof(struct sockaddr_un, sun_path) + length + 1;
#if (NXT_LINUX)
/*
* Linux unix(7):
*
* abstract: an abstract socket address is distinguished by the fact
* that sun_path[0] is a null byte ('\0'). The socket's address in
* this namespace is given by the additional bytes in sun_path that
* are covered by the specified length of the address structure.
* (Null bytes in the name have no special significance.)
*/
if (path[0] == '\0') {
socklen--;
}
#endif
mp = jbs->resolve.job.mem_pool;
jbs->resolve.sockaddrs = nxt_mem_alloc(mp, sizeof(void *));
if (nxt_fast_path(jbs->resolve.sockaddrs != NULL)) {
sa = nxt_sockaddr_alloc(mp, socklen);
if (nxt_fast_path(sa != NULL)) {
jbs->resolve.count = 1;
jbs->resolve.sockaddrs[0] = sa;
sa->u.sockaddr_un.sun_family = AF_UNIX;
nxt_memcpy(sa->u.sockaddr_un.sun_path, path, length);
return NXT_OK;
}
}
return NXT_ERROR;
#else /* !(NXT_HAVE_UNIX_DOMAIN) */
nxt_thread_log_error(jbs->resolve.log_level,
"unix domain socket \"%V\" is not supported",
&jbs->addr);
return NXT_ERROR;
#endif
}
static nxt_int_t
nxt_job_sockaddr_inet6_parse(nxt_job_sockaddr_parse_t *jbs)
{
#if (NXT_INET6)
u_char *p, *addr, *addr_end;
size_t length;
nxt_int_t port;
nxt_mem_pool_t *mp;
nxt_sockaddr_t *sa;
struct in6_addr *in6_addr;
length = jbs->addr.length - 1;
addr = jbs->addr.start + 1;
addr_end = nxt_memchr(addr, ']', length);
if (addr_end == NULL) {
goto invalid_address;
}
mp = jbs->resolve.job.mem_pool;
jbs->resolve.sockaddrs = nxt_mem_alloc(mp, sizeof(void *));
if (nxt_slow_path(jbs->resolve.sockaddrs == NULL)) {
return NXT_ERROR;
}
sa = nxt_sockaddr_alloc(mp, sizeof(struct sockaddr_in6));
if (nxt_slow_path(sa == NULL)) {
return NXT_ERROR;
}
jbs->resolve.count = 1;
jbs->resolve.sockaddrs[0] = sa;
in6_addr = &sa->u.sockaddr_in6.sin6_addr;
if (nxt_inet6_addr(in6_addr, addr, addr_end - addr) != NXT_OK) {
goto invalid_address;
}
p = addr_end + 1;
length = (addr + length) - p;
if (length == 0) {
jbs->no_port = 1;
port = jbs->resolve.port;
goto found;
}
if (*p == ':') {
port = nxt_int_parse(p + 1, length - 1);
if (port >= 1 && port <= 65535) {
port = htons((in_port_t) port);
goto found;
}
}
nxt_thread_log_error(jbs->resolve.log_level,
"invalid port in \"%V\"", &jbs->addr);
return NXT_ERROR;
found:
sa->u.sockaddr_in6.sin6_family = AF_INET6;
sa->u.sockaddr_in6.sin6_port = (in_port_t) port;
if (IN6_IS_ADDR_UNSPECIFIED(in6_addr)) {
jbs->wildcard = 1;
}
return NXT_OK;
invalid_address:
nxt_thread_log_error(jbs->resolve.log_level,
"invalid IPv6 address in \"%V\"", &jbs->addr);
return NXT_ERROR;
#else
nxt_thread_log_error(jbs->resolve.log_level,
"IPv6 socket \"%V\" is not supported", &jbs->addr);
return NXT_ERROR;
#endif
}
static nxt_int_t
nxt_job_sockaddr_inet_parse(nxt_job_sockaddr_parse_t *jbs)
{
u_char *p, *host;
size_t length;
in_addr_t addr;
nxt_int_t port;
nxt_mem_pool_t *mp;
nxt_sockaddr_t *sa;
addr = INADDR_ANY;
length = jbs->addr.length;
host = jbs->addr.start;
p = nxt_memchr(host, ':', length);
if (p == NULL) {
/* single value port, address, or host name */
port = nxt_int_parse(host, length);
if (port > 0) {
if (port < 1 || port > 65535) {
goto invalid_port;
}
/* "*:XX" */
port = htons((in_port_t) port);
jbs->resolve.port = (in_port_t) port;
} else {
jbs->no_port = 1;
addr = nxt_inet_addr(host, length);
if (addr == INADDR_NONE) {
jbs->resolve.name.length = length;
jbs->resolve.name.start = host;
nxt_job_resolve(&jbs->resolve);
return NXT_AGAIN;
}
/* "x.x.x.x" */
port = jbs->resolve.port;
}
} else {
/* x.x.x.x:XX or host:XX */
p++;
length = (host + length) - p;
port = nxt_int_parse(p, length);
if (port < 1 || port > 65535) {
goto invalid_port;
}
port = htons((in_port_t) port);
length = (p - 1) - host;
if (length != 1 || host[0] != '*') {
addr = nxt_inet_addr(host, length);
if (addr == INADDR_NONE) {
jbs->resolve.name.length = length;
jbs->resolve.name.start = host;
jbs->resolve.port = (in_port_t) port;
nxt_job_resolve(&jbs->resolve);
return NXT_AGAIN;
}
/* "x.x.x.x:XX" */
}
}
mp = jbs->resolve.job.mem_pool;
jbs->resolve.sockaddrs = nxt_mem_alloc(mp, sizeof(void *));
if (nxt_slow_path(jbs->resolve.sockaddrs == NULL)) {
return NXT_ERROR;
}
sa = nxt_sockaddr_alloc(mp, sizeof(struct sockaddr_in));
if (nxt_fast_path(sa != NULL)) {
jbs->resolve.count = 1;
jbs->resolve.sockaddrs[0] = sa;
jbs->wildcard = (addr == INADDR_ANY);
sa->u.sockaddr_in.sin_family = AF_INET;
sa->u.sockaddr_in.sin_port = (in_port_t) port;
sa->u.sockaddr_in.sin_addr.s_addr = addr;
return NXT_OK;
}
return NXT_ERROR;
invalid_port:
nxt_thread_log_error(jbs->resolve.log_level,
"invalid port in \"%V\"", &jbs->addr);
return NXT_ERROR;
}
in_addr_t
nxt_inet_addr(u_char *buf, size_t length)
{
u_char c, *end;
in_addr_t addr;
nxt_uint_t digit, octet, dots;
addr = 0;
octet = 0;
dots = 0;
end = buf + length;
while (buf < end) {
c = *buf++;
digit = c - '0';
/* values below '0' become large unsigned integers */
if (digit < 10) {
octet = octet * 10 + digit;
continue;
}
if (c == '.' && octet < 256) {
addr = (addr << 8) + octet;
octet = 0;
dots++;
continue;
}
return INADDR_NONE;
}
if (dots == 3 && octet < 256) {
addr = (addr << 8) + octet;
return htonl(addr);
}
return INADDR_NONE;
}
#if (NXT_INET6)
nxt_int_t
nxt_inet6_addr(struct in6_addr *in6_addr, u_char *buf, size_t length)
{
u_char c, *addr, *zero_start, *ipv4, *dst, *src, *end;
nxt_uint_t digit, group, nibbles, groups_left;
if (length == 0) {
return NXT_ERROR;
}
end = buf + length;
if (buf[0] == ':') {
buf++;
}
addr = in6_addr->s6_addr;
zero_start = NULL;
groups_left = 8;
nibbles = 0;
group = 0;
ipv4 = NULL;
while (buf < end) {
c = *buf++;
if (c == ':') {
if (nibbles != 0) {
ipv4 = buf;
*addr++ = (u_char) (group >> 8);
*addr++ = (u_char) (group & 0xff);
groups_left--;
if (groups_left != 0) {
nibbles = 0;
group = 0;
continue;
}
} else {
if (zero_start == NULL) {
ipv4 = buf;
zero_start = addr;
continue;
}
}
return NXT_ERROR;
}
if (c == '.' && nibbles != 0) {
if (groups_left < 2 || ipv4 == NULL) {
return NXT_ERROR;
}
group = nxt_inet_addr(ipv4, end - ipv4);
if (group == INADDR_NONE) {
return NXT_ERROR;
}
group = ntohl(group);
*addr++ = (u_char) ((group >> 24) & 0xff);
*addr++ = (u_char) ((group >> 16) & 0xff);
groups_left--;
/* the low 16-bit are copied below */
break;
}
nibbles++;
if (nibbles > 4) {
return NXT_ERROR;
}
group <<= 4;
digit = c - '0';
/* values below '0' become large unsigned integers */
if (digit < 10) {
group += digit;
continue;
}
c |= 0x20;
digit = c - 'a';
/* values below 'a' become large unsigned integers */
if (digit < 6) {
group += 10 + digit;
continue;
}
return NXT_ERROR;
}
if (nibbles == 0 && zero_start == NULL) {
return NXT_ERROR;
}
*addr++ = (u_char) (group >> 8);
*addr++ = (u_char) (group & 0xff);
groups_left--;
if (groups_left != 0) {
if (zero_start != NULL) {
/* moving part before consecutive zero groups to the end */
groups_left *= 2;
src = addr - 1;
dst = src + groups_left;
while (src >= zero_start) {
*dst-- = *src--;
}
nxt_memzero(zero_start, groups_left);
return NXT_OK;
}
} else {
if (zero_start == NULL) {
return NXT_OK;
}
}
return NXT_ERROR;
}
#endif