/* * nsiproxy.sys icmp_echo implementation * * Copyright 2021 Huw Davies * * This library 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 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA */ #if 0 #pragma makedep unix #endif #include "config.h" #include #include #include #include #include #include #include #ifdef HAVE_SYS_SOCKET_H #include #endif #ifdef HAVE_NETINET_IN_H #include #endif #ifdef HAVE_NETINET_IP_H #include #endif #include "ntstatus.h" #define WIN32_NO_STATUS #include "windef.h" #include "winbase.h" #include "winternl.h" #include "winioctl.h" #define USE_WS_PREFIX #include "ddk/wdm.h" #include "ifdef.h" #include "netiodef.h" #include "ipexport.h" #include "ipmib.h" #include "wine/nsi.h" #include "wine/debug.h" #include "nsiproxy_private.h" WINE_DEFAULT_DEBUG_CHANNEL(nsi); static LONG icmp_sequence; struct ip_hdr { uint8_t v_hl; /* version << 4 | hdr_len */ uint8_t tos; uint16_t tot_len; uint16_t id; uint16_t frag_off; uint8_t ttl; uint8_t protocol; uint16_t checksum; uint32_t saddr; uint32_t daddr; }; struct icmp_hdr { uint8_t type; uint8_t code; uint16_t checksum; union { struct { uint16_t id; uint16_t sequence; } echo; } un; }; struct icmp_reply_ctx { SOCKADDR_INET addr; ULONG status; ULONG round_trip_time; LONG data_size; BYTE ttl; BYTE tos; BYTE flags; BYTE options_size; void *options_data; void *data; }; struct family_ops; struct icmp_data { LARGE_INTEGER send_time; int socket; int cancel_pipe[2]; unsigned short id; unsigned short seq; const struct family_ops *ops; }; #define MAX_HANDLES 256 /* Max number of simultaneous pings - could become dynamic if need be */ static struct icmp_data *handle_table[MAX_HANDLES]; static pthread_mutex_t handle_lock = PTHREAD_MUTEX_INITIALIZER; static struct icmp_data **next_free, **next_unused = handle_table; static HANDLE handle_alloc( struct icmp_data *data ) { struct icmp_data **entry; HANDLE h; pthread_mutex_lock( &handle_lock ); entry = next_free; if (entry) next_free = *(struct icmp_data ***)entry; else if (next_unused < handle_table + MAX_HANDLES) entry = next_unused++; else { pthread_mutex_unlock( &handle_lock ); FIXME( "Exhausted icmp handle count\n" ); return 0; } *entry = data; h = LongToHandle( entry - handle_table + 1 ); pthread_mutex_unlock( &handle_lock ); TRACE( "returning handle %p\n", h ); return h; } static struct icmp_data **handle_entry( HANDLE h ) { unsigned int idx = HandleToLong( h ); if (!idx || idx > MAX_HANDLES) { ERR( "Invalid icmp handle\n" ); return NULL; } return handle_table + idx - 1; } static struct icmp_data *handle_data( HANDLE h ) { struct icmp_data **entry = handle_entry( h ); if (!entry) return NULL; return *entry; } static void handle_free( HANDLE h ) { struct icmp_data **entry; TRACE( "%p\n", h ); pthread_mutex_lock( &handle_lock ); entry = handle_entry( h ); if (entry) { *(struct icmp_data ***)entry = next_free; next_free = entry; } pthread_mutex_unlock( &handle_lock ); } static void ipv4_init_icmp_hdr( struct icmp_data *data, struct icmp_hdr *icmp_hdr ) { icmp_hdr->type = ICMP4_ECHO_REQUEST; icmp_hdr->code = 0; icmp_hdr->checksum = 0; icmp_hdr->un.echo.id = data->id = getpid() & 0xffff; /* will be overwritten for linux ping socks */ icmp_hdr->un.echo.sequence = data->seq = InterlockedIncrement( &icmp_sequence ) & 0xffff; } /* rfc 1071 checksum */ static unsigned short chksum( BYTE *data, unsigned int count ) { unsigned int sum = 0, carry = 0; unsigned short check, s; while (count > 1) { s = *(unsigned short *)data; data += 2; sum += carry; sum += s; carry = s > sum; count -= 2; } sum += carry; /* This won't produce another carry */ sum = (sum & 0xffff) + (sum >> 16); if (count) sum += *data; /* LE-only */ sum = (sum & 0xffff) + (sum >> 16); /* fold in any carry */ sum = (sum & 0xffff) + (sum >> 16); check = ~sum; return check; } #ifdef __linux__ static unsigned short null_chksum( BYTE *data, unsigned int count ) { return 0; } #endif static int ipv4_set_reply_ip_status( IP_STATUS ip_status, unsigned int bits, void *out ) { if (bits == 32) { struct icmp_echo_reply_32 *reply = out; memset( reply, 0, sizeof(*reply) ); reply->status = ip_status; return sizeof(*reply); } else { struct icmp_echo_reply_64 *reply = out; memset( reply, 0, sizeof(*reply) ); reply->status = ip_status; return sizeof(*reply); } } static void ipv4_set_socket_opts( struct icmp_data *data, struct icmp_send_echo_params *params ) { int val; val = params->ttl; if (val) setsockopt( data->socket, IPPROTO_IP, IP_TTL, &val, sizeof(val) ); val = params->tos; if (val) setsockopt( data->socket, IPPROTO_IP, IP_TOS, &val, sizeof(val) ); } #ifdef __linux__ static void ipv4_linux_ping_set_socket_opts( struct icmp_data *data, struct icmp_send_echo_params *params ) { static const int val = 1; ipv4_set_socket_opts( data, params ); setsockopt( data->socket, IPPROTO_IP, IP_RECVTTL, &val, sizeof(val) ); setsockopt( data->socket, IPPROTO_IP, IP_RECVTOS, &val, sizeof(val) ); } #endif static int ipv4_reply_buffer_len( struct icmp_listen_params *params ) { int struct_len = (params->bits == 32) ? sizeof(struct icmp_echo_reply_32) : sizeof(struct icmp_echo_reply_64); return sizeof(struct ip_hdr) + sizeof(struct icmp_hdr) + params->reply_len - struct_len; } #ifdef __linux__ static int ipv4_linux_ping_reply_buffer_len( struct icmp_listen_params *params ) { int struct_len = (params->bits == 32) ? sizeof(struct icmp_echo_reply_32) : sizeof(struct icmp_echo_reply_64); return sizeof(struct icmp_hdr) + params->reply_len - struct_len; } #endif static BOOL ipv4_parse_ip_hdr( struct msghdr *msg, int recvd, int *ip_hdr_len, struct icmp_reply_ctx *ctx ) { struct ip_hdr *ip_hdr; if (recvd < sizeof(*ip_hdr)) return FALSE; ip_hdr = msg->msg_iov[0].iov_base; if (ip_hdr->v_hl >> 4 != 4 || ip_hdr->protocol != IPPROTO_ICMP) return FALSE; *ip_hdr_len = (ip_hdr->v_hl & 0xf) << 2; if (*ip_hdr_len < sizeof(*ip_hdr)) return FALSE; ctx->options_data = ip_hdr + 1; ctx->ttl = ip_hdr->ttl; ctx->tos = ip_hdr->tos; ctx->flags = ip_hdr->frag_off >> 13; ctx->options_size = *ip_hdr_len - sizeof(*ip_hdr); return TRUE; } #ifdef __linux__ static BOOL ipv4_linux_ping_parse_ip_hdr( struct msghdr *msg, int recvd, int *ip_hdr_len, struct icmp_reply_ctx *ctx ) { struct cmsghdr *cmsg; *ip_hdr_len = 0; ctx->options_data = NULL; ctx->ttl = 0; ctx->tos = 0; ctx->flags = 0; ctx->options_size = 0; /* FIXME from IP_OPTIONS but will require checking for space in the reply */ for (cmsg = CMSG_FIRSTHDR( msg ); cmsg; cmsg = CMSG_NXTHDR( msg, cmsg )) { if (cmsg->cmsg_level != IPPROTO_IP) continue; switch (cmsg->cmsg_type) { case IP_TTL: ctx->ttl = *(BYTE *)CMSG_DATA( cmsg ); break; case IP_TOS: ctx->tos = *(BYTE *)CMSG_DATA( cmsg ); break; } } return TRUE; } #endif static int ipv4_parse_icmp_hdr_( struct icmp_data *data, struct icmp_hdr *icmp, int icmp_size, struct icmp_reply_ctx *ctx, int ping_socket ) { static const IP_STATUS unreach_codes[] = { IP_DEST_NET_UNREACHABLE, /* ICMP_UNREACH_NET */ IP_DEST_HOST_UNREACHABLE, /* ICMP_UNREACH_HOST */ IP_DEST_PROT_UNREACHABLE, /* ICMP_UNREACH_PROTOCOL */ IP_DEST_PORT_UNREACHABLE, /* ICMP_UNREACH_PORT */ IP_PACKET_TOO_BIG, /* ICMP_UNREACH_NEEDFRAG */ IP_BAD_ROUTE, /* ICMP_UNREACH_SRCFAIL */ IP_DEST_NET_UNREACHABLE, /* ICMP_UNREACH_NET_UNKNOWN */ IP_DEST_HOST_UNREACHABLE, /* ICMP_UNREACH_HOST_UNKNOWN */ IP_DEST_HOST_UNREACHABLE, /* ICMP_UNREACH_ISOLATED */ IP_DEST_NET_UNREACHABLE, /* ICMP_UNREACH_NET_PROHIB */ IP_DEST_HOST_UNREACHABLE, /* ICMP_UNREACH_HOST_PROHIB */ IP_DEST_NET_UNREACHABLE, /* ICMP_UNREACH_TOSNET */ IP_DEST_HOST_UNREACHABLE, /* ICMP_UNREACH_TOSHOST */ IP_DEST_HOST_UNREACHABLE, /* ICMP_UNREACH_FILTER_PROHIB */ IP_DEST_HOST_UNREACHABLE, /* ICMP_UNREACH_HOST_PRECEDENCE */ IP_DEST_HOST_UNREACHABLE /* ICMP_UNREACH_PRECEDENCE_CUTOFF */ }; const struct ip_hdr *orig_ip_hdr; const struct icmp_hdr *orig_icmp_hdr; int orig_ip_hdr_len; IP_STATUS status; switch (icmp->type) { case ICMP4_ECHO_REPLY: if ((!ping_socket && icmp->un.echo.id != data->id) || icmp->un.echo.sequence != data->seq) return -1; ctx->status = IP_SUCCESS; return icmp_size - sizeof(*icmp); case ICMP4_DST_UNREACH: if (icmp->code < ARRAY_SIZE(unreach_codes)) status = unreach_codes[icmp->code]; else status = IP_DEST_HOST_UNREACHABLE; break; case ICMP4_TIME_EXCEEDED: if (icmp->code == 1) /* ICMP_TIMXCEED_REASS */ status = IP_TTL_EXPIRED_REASSEM; else status = IP_TTL_EXPIRED_TRANSIT; break; case ICMP4_PARAM_PROB: status = IP_PARAM_PROBLEM; break; case ICMP4_SOURCE_QUENCH: status = IP_SOURCE_QUENCH; break; default: return -1; } /* Check that the appended packet is really ours - * all handled icmp replies have an 8-byte header * followed by the original ip hdr. */ if (icmp_size < sizeof(*icmp) + sizeof(*orig_ip_hdr)) return -1; orig_ip_hdr = (struct ip_hdr *)(icmp + 1); if (orig_ip_hdr->v_hl >> 4 != 4 || orig_ip_hdr->protocol != IPPROTO_ICMP) return -1; orig_ip_hdr_len = (orig_ip_hdr->v_hl & 0xf) << 2; if (icmp_size < sizeof(*icmp) + orig_ip_hdr_len + sizeof(*orig_icmp_hdr)) return -1; orig_icmp_hdr = (const struct icmp_hdr *)((const BYTE *)orig_ip_hdr + orig_ip_hdr_len); if (orig_icmp_hdr->type != ICMP4_ECHO_REQUEST || orig_icmp_hdr->code != 0 || (!ping_socket && orig_icmp_hdr->un.echo.id != data->id) || orig_icmp_hdr->un.echo.sequence != data->seq) return -1; ctx->status = status; return 0; } static int ipv4_parse_icmp_hdr( struct icmp_data *data, struct icmp_hdr *icmp, int icmp_size, struct icmp_reply_ctx *ctx) { return ipv4_parse_icmp_hdr_( data, icmp, icmp_size, ctx, 0 ); } #ifdef __linux__ static int ipv4_linux_ping_parse_icmp_hdr( struct icmp_data *data, struct icmp_hdr *icmp, int icmp_size, struct icmp_reply_ctx *ctx ) { return ipv4_parse_icmp_hdr_( data, icmp, icmp_size, ctx, 1 ); } #endif static void ipv4_fill_reply( struct icmp_listen_params *params, struct icmp_reply_ctx *ctx) { void *options_data; ULONG data_offset; if (params->bits == 32) { struct icmp_echo_reply_32 *reply = params->reply; data_offset = sizeof(*reply) + ((ctx->options_size + 3) & ~3); reply->addr = ctx->addr.Ipv4.sin_addr.WS_s_addr; reply->status = ctx->status; reply->round_trip_time = ctx->round_trip_time; reply->data_size = ctx->data_size; reply->num_of_pkts = 1; reply->data_ptr = params->user_reply_ptr + data_offset; reply->opts.ttl = ctx->ttl; reply->opts.tos = ctx->tos; reply->opts.flags = ctx->flags; reply->opts.options_size = ctx->options_size; reply->opts.options_ptr = params->user_reply_ptr + sizeof(*reply); options_data = reply + 1; } else { struct icmp_echo_reply_64 *reply = params->reply; data_offset = sizeof(*reply) + ((ctx->options_size + 3) & ~3); reply->addr = ctx->addr.Ipv4.sin_addr.WS_s_addr; reply->status = ctx->status; reply->round_trip_time = ctx->round_trip_time; reply->data_size = ctx->data_size; reply->num_of_pkts = 1; reply->data_ptr = params->user_reply_ptr + data_offset; reply->opts.ttl = ctx->ttl; reply->opts.tos = ctx->tos; reply->opts.flags = ctx->flags; reply->opts.options_size = ctx->options_size; reply->opts.options_ptr = params->user_reply_ptr + sizeof(*reply); options_data = reply + 1; } memcpy( options_data, ctx->options_data, ctx->options_size ); if (ctx->options_size & 3) memset( (char *)options_data + ctx->options_size, 0, 4 - (ctx->options_size & 3) ); memcpy( (char *)params->reply + data_offset, ctx->data, ctx->data_size ); params->reply_len = data_offset + ctx->data_size; } struct family_ops { int family; int icmp_protocol; void (*init_icmp_hdr)( struct icmp_data *data, struct icmp_hdr *icmp_hdr ); unsigned short (*chksum)( BYTE *data, unsigned int count ); int (*set_reply_ip_status)( IP_STATUS ip_status, unsigned int bits, void *out ); void (*set_socket_opts)( struct icmp_data *data, struct icmp_send_echo_params *params ); int (*reply_buffer_len)( struct icmp_listen_params *params ); BOOL (*parse_ip_hdr)( struct msghdr *msg, int recvd, int *ip_hdr_len, struct icmp_reply_ctx *ctx ); int (*parse_icmp_hdr)( struct icmp_data *data, struct icmp_hdr *icmp, int icmp_len, struct icmp_reply_ctx *ctx ); void (*fill_reply)( struct icmp_listen_params *params, struct icmp_reply_ctx *ctx ); }; static const struct family_ops ipv4 = { AF_INET, IPPROTO_ICMP, ipv4_init_icmp_hdr, chksum, ipv4_set_reply_ip_status, ipv4_set_socket_opts, ipv4_reply_buffer_len, ipv4_parse_ip_hdr, ipv4_parse_icmp_hdr, ipv4_fill_reply, }; #ifdef __linux__ /* linux ipv4 ping sockets behave more like ipv6 raw sockets */ static const struct family_ops ipv4_linux_ping = { AF_INET, IPPROTO_ICMP, ipv4_init_icmp_hdr, null_chksum, ipv4_set_reply_ip_status, ipv4_linux_ping_set_socket_opts, ipv4_linux_ping_reply_buffer_len, ipv4_linux_ping_parse_ip_hdr, ipv4_linux_ping_parse_icmp_hdr, ipv4_fill_reply, }; #endif static IP_STATUS errno_to_ip_status( int err ) { switch( err ) { case EHOSTUNREACH: return IP_DEST_HOST_UNREACHABLE; default: return IP_GENERAL_FAILURE; } } static int SOCKADDR_INET_to_sockaddr( const SOCKADDR_INET *in, struct sockaddr *out, int len ) { switch (in->si_family) { case WS_AF_INET: { struct sockaddr_in *sa = (struct sockaddr_in *)out; if (len < sizeof(*sa)) return 0; sa->sin_family = AF_INET; sa->sin_port = in->Ipv4.sin_port; sa->sin_addr.s_addr = in->Ipv4.sin_addr.WS_s_addr; return sizeof(*sa); } case WS_AF_INET6: { struct sockaddr_in6 *sa = (struct sockaddr_in6 *)out; if (len < sizeof(*sa)) return 0; sa->sin6_family = AF_INET6; sa->sin6_port = in->Ipv6.sin6_port; sa->sin6_flowinfo = in->Ipv6.sin6_flowinfo; memcpy( sa->sin6_addr.s6_addr, in->Ipv6.sin6_addr.WS_s6_addr, sizeof(sa->sin6_addr.s6_addr) ); sa->sin6_scope_id = in->Ipv6.sin6_scope_id; return sizeof(*sa); } } return 0; } static BOOL sockaddr_to_SOCKADDR_INET( const struct sockaddr *in, SOCKADDR_INET *out ) { switch (in->sa_family) { case AF_INET: { struct sockaddr_in *sa = (struct sockaddr_in *)in; out->Ipv4.sin_family = WS_AF_INET; out->Ipv4.sin_port = sa->sin_port; out->Ipv4.sin_addr.WS_s_addr = sa->sin_addr.s_addr; return TRUE; } case AF_INET6: { struct sockaddr_in6 *sa = (struct sockaddr_in6 *)in; out->Ipv6.sin6_family = WS_AF_INET6; out->Ipv6.sin6_port = sa->sin6_port; out->Ipv6.sin6_flowinfo = sa->sin6_flowinfo; memcpy( out->Ipv6.sin6_addr.WS_s6_addr, sa->sin6_addr.s6_addr, sizeof(sa->sin6_addr.s6_addr) ); out->Ipv6.sin6_scope_id = sa->sin6_scope_id; return TRUE; } } return FALSE; } static NTSTATUS icmp_data_create( ADDRESS_FAMILY win_family, struct icmp_data **icmp_data ) { struct icmp_data *data; const struct family_ops *ops; if (win_family == WS_AF_INET) ops = &ipv4; else return STATUS_INVALID_PARAMETER; data = malloc( sizeof(*data) ); if (!data) return STATUS_NO_MEMORY; data->socket = socket( ops->family, SOCK_RAW, ops->icmp_protocol ); if (data->socket < 0) /* Try a ping-socket */ { TRACE( "failed to open raw sock, trying a dgram sock\n" ); data->socket = socket( ops->family, SOCK_DGRAM, ops->icmp_protocol ); if (data->socket < 0) { WARN( "Unable to create socket\n" ); free( data ); return STATUS_ACCESS_DENIED; } #ifdef __linux__ if (ops->family == AF_INET) ops = &ipv4_linux_ping; #endif } if (pipe( data->cancel_pipe )) { close( data->socket ); free( data ); return STATUS_ACCESS_DENIED; } data->ops = ops; *icmp_data = data; return STATUS_SUCCESS; } static void icmp_data_free( struct icmp_data *data ) { close( data->socket ); close( data->cancel_pipe[0] ); close( data->cancel_pipe[1] ); free( data ); } NTSTATUS icmp_send_echo( void *args ) { struct icmp_send_echo_params *params = args; struct icmp_hdr *icmp_hdr; /* this is the same for both ipv4 and ipv6 */ struct sockaddr_storage dst_storage; struct sockaddr *dst = (struct sockaddr *)&dst_storage; struct icmp_data *data; int dst_len, ret; NTSTATUS status; status = icmp_data_create( params->dst->si_family, &data ); if (status) return status; data->ops->set_socket_opts( data, params ); icmp_hdr = malloc( sizeof(*icmp_hdr) + params->request_size ); if (!icmp_hdr) { icmp_data_free( data ); return STATUS_NO_MEMORY; } data->ops->init_icmp_hdr( data, icmp_hdr ); memcpy( icmp_hdr + 1, params->request, params->request_size ); icmp_hdr->checksum = data->ops->chksum( (BYTE *)icmp_hdr, sizeof(*icmp_hdr) + params->request_size ); dst_len = SOCKADDR_INET_to_sockaddr( params->dst, dst, sizeof(dst_storage) ); NtQueryPerformanceCounter( &data->send_time, NULL ); ret = sendto( data->socket, icmp_hdr, sizeof(*icmp_hdr) + params->request_size, 0, dst, dst_len ); free( icmp_hdr ); if (ret < 0) { TRACE( "sendto() rets %d errno %d\n", ret, errno ); icmp_data_free( data ); params->reply_len = data->ops->set_reply_ip_status( errno_to_ip_status( errno ), params->bits, params->reply ); return STATUS_SUCCESS; } params->handle = handle_alloc( data ); if (!params->handle) icmp_data_free( data ); return params->handle ? STATUS_PENDING : STATUS_NO_MEMORY; } static int get_timeout( LARGE_INTEGER start, DWORD timeout ) { LARGE_INTEGER now, end; end.QuadPart = start.QuadPart + (ULONGLONG)timeout * 10000; NtQueryPerformanceCounter( &now, NULL ); if (now.QuadPart >= end.QuadPart) return 0; return min( (end.QuadPart - now.QuadPart) / 10000, INT_MAX ); } static ULONG get_rtt( LARGE_INTEGER start ) { LARGE_INTEGER now; NtQueryPerformanceCounter( &now, NULL ); return (now.QuadPart - start.QuadPart) / 10000; } static NTSTATUS recv_msg( struct icmp_data *data, struct icmp_listen_params *params ) { struct sockaddr_storage addr; struct icmp_reply_ctx ctx; struct iovec iov[1]; BYTE cmsg_buf[1024]; struct msghdr msg = { .msg_name = &addr, .msg_namelen = sizeof(addr), .msg_iov = iov, .msg_iovlen = ARRAY_SIZE(iov), .msg_control = cmsg_buf, .msg_controllen = sizeof(cmsg_buf) }; int ip_hdr_len, recvd, reply_buf_len; char *reply_buf; struct icmp_hdr *icmp_hdr; reply_buf_len = data->ops->reply_buffer_len( params ); reply_buf = malloc( reply_buf_len ); if (!reply_buf) return STATUS_NO_MEMORY; iov[0].iov_base = reply_buf; iov[0].iov_len = reply_buf_len; recvd = recvmsg( data->socket, &msg, 0 ); TRACE( "recvmsg() rets %d errno %d addr_len %d iovlen %d msg_flags %x\n", recvd, errno, msg.msg_namelen, (int)iov[0].iov_len, msg.msg_flags ); if (!data->ops->parse_ip_hdr( &msg, recvd, &ip_hdr_len, &ctx )) goto skip; if (recvd < ip_hdr_len + sizeof(*icmp_hdr)) goto skip; icmp_hdr = (struct icmp_hdr *)(reply_buf + ip_hdr_len); if ((ctx.data_size = data->ops->parse_icmp_hdr( data, icmp_hdr, recvd - ip_hdr_len, &ctx )) < 0) goto skip; if (ctx.data_size && msg.msg_flags & MSG_TRUNC) { free( reply_buf ); params->reply_len = data->ops->set_reply_ip_status( IP_GENERAL_FAILURE, params->bits, params->reply ); return STATUS_SUCCESS; } sockaddr_to_SOCKADDR_INET( (struct sockaddr *)&addr, &ctx.addr ); ctx.round_trip_time = get_rtt( data->send_time ); ctx.data = icmp_hdr + 1; data->ops->fill_reply( params, &ctx ); free( reply_buf ); return STATUS_SUCCESS; skip: free( reply_buf ); return STATUS_RETRY; } NTSTATUS icmp_listen( void *args ) { struct icmp_listen_params *params = args; struct icmp_data *data; struct pollfd fds[2]; NTSTATUS status; int ret; data = handle_data( params->handle ); if (!data) return STATUS_INVALID_PARAMETER; fds[0].fd = data->socket; fds[0].events = POLLIN; fds[1].fd = data->cancel_pipe[0]; fds[1].events = POLLIN; while ((ret = poll( fds, ARRAY_SIZE(fds), get_timeout( data->send_time, params->timeout ) )) > 0) { if (fds[1].revents & POLLIN) { TRACE( "cancelled\n" ); return STATUS_CANCELLED; } status = recv_msg( data, params ); if (status == STATUS_RETRY) continue; return status; } if (!ret) /* timeout */ { TRACE( "timeout\n" ); params->reply_len = data->ops->set_reply_ip_status( IP_REQ_TIMED_OUT, params->bits, params->reply ); return STATUS_SUCCESS; } /* ret < 0 */ params->reply_len = data->ops->set_reply_ip_status( errno_to_ip_status( errno ), params->bits, params->reply ); return STATUS_SUCCESS; } NTSTATUS icmp_cancel_listen( void *args ) { HANDLE handle = args; struct icmp_data *data = handle_data( handle ); if (!data) return STATUS_INVALID_PARAMETER; write( data->cancel_pipe[1], "x", 1 ); return STATUS_SUCCESS; } NTSTATUS icmp_close( void *args ) { HANDLE handle = args; struct icmp_data *data = handle_data( handle ); if (!data) return STATUS_INVALID_PARAMETER; icmp_data_free( data ); handle_free( handle ); return STATUS_SUCCESS; }