/* * Web Services on Devices * * Copyright 2017-2018 Owen Rudge for CodeWeavers * * 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 */ #include #define COBJMACROS #include "wsdapi_internal.h" #include "wine/debug.h" #include "wine/heap.h" #include "iphlpapi.h" #include "bcrypt.h" WINE_DEFAULT_DEBUG_CHANNEL(wsdapi); #define SEND_ADDRESS_IPV4 0xEFFFFFFA /* 239.255.255.250 */ #define SEND_PORT 3702 static UCHAR send_address_ipv6[] = {0xFF,0x02,0,0,0,0,0,0,0,0,0,0,0,0,0,0xC}; /* FF02::C */ #define UNICAST_UDP_REPEAT 1 #define MULTICAST_UDP_REPEAT 2 #define UDP_MIN_DELAY 50 #define UDP_MAX_DELAY 250 #define UDP_UPPER_DELAY 500 static void send_message(SOCKET s, char *data, int length, SOCKADDR_STORAGE *dest, int max_initial_delay, int repeat) { UINT delay; int len; /* Sleep for a random amount of time before sending the message */ if (max_initial_delay > 0) { BCryptGenRandom(NULL, (BYTE*) &delay, sizeof(UINT), BCRYPT_USE_SYSTEM_PREFERRED_RNG); Sleep(delay % max_initial_delay); } len = (dest->ss_family == AF_INET6) ? sizeof(SOCKADDR_IN6) : sizeof(SOCKADDR_IN); if (sendto(s, data, length, 0, (SOCKADDR *) dest, len) == SOCKET_ERROR) WARN("Unable to send data to socket: %d\n", WSAGetLastError()); if (repeat-- <= 0) return; BCryptGenRandom(NULL, (BYTE*) &delay, sizeof(UINT), BCRYPT_USE_SYSTEM_PREFERRED_RNG); delay = delay % (UDP_MAX_DELAY - UDP_MIN_DELAY + 1) + UDP_MIN_DELAY; for (;;) { Sleep(delay); if (sendto(s, data, length, 0, (SOCKADDR *) dest, len) == SOCKET_ERROR) WARN("Unable to send data to socket: %d\n", WSAGetLastError()); if (repeat-- <= 0) break; delay = min(delay * 2, UDP_UPPER_DELAY); } } typedef struct sending_thread_params { char *data; int length; SOCKET sock; SOCKADDR_STORAGE dest; int max_initial_delay; } sending_thread_params; static DWORD WINAPI sending_thread(LPVOID lpParam) { sending_thread_params *params = (sending_thread_params *) lpParam; send_message(params->sock, params->data, params->length, ¶ms->dest, params->max_initial_delay, MULTICAST_UDP_REPEAT); closesocket(params->sock); heap_free(params->data); heap_free(params); return 0; } static BOOL send_udp_multicast_of_type(char *data, int length, int max_initial_delay, ULONG family) { IP_ADAPTER_ADDRESSES *adapter_addresses = NULL, *adapter_addr; static const struct in6_addr i_addr_zero; sending_thread_params *send_params; ULONG bufferSize = 0; LPSOCKADDR sockaddr; BOOL ret = FALSE; HANDLE thread_handle; const char ttl = 8; ULONG retval; SOCKET s; /* Get size of buffer for adapters */ retval = GetAdaptersAddresses(family, 0, NULL, NULL, &bufferSize); if (retval != ERROR_BUFFER_OVERFLOW) { WARN("GetAdaptorsAddresses failed with error %08x\n", retval); goto cleanup; } adapter_addresses = (IP_ADAPTER_ADDRESSES *) heap_alloc(bufferSize); if (adapter_addresses == NULL) { WARN("Out of memory allocating space for adapter information\n"); goto cleanup; } /* Get list of adapters */ retval = GetAdaptersAddresses(family, 0, NULL, adapter_addresses, &bufferSize); if (retval != ERROR_SUCCESS) { WARN("GetAdaptorsAddresses failed with error %08x\n", retval); goto cleanup; } for (adapter_addr = adapter_addresses; adapter_addr != NULL; adapter_addr = adapter_addr->Next) { if (adapter_addr->FirstUnicastAddress == NULL) { TRACE("No address found for adaptor '%s' (%p)\n", debugstr_a(adapter_addr->AdapterName), adapter_addr); continue; } sockaddr = adapter_addr->FirstUnicastAddress->Address.lpSockaddr; /* Create a socket and bind to the adapter address */ s = socket(family, SOCK_DGRAM, IPPROTO_UDP); if (s == INVALID_SOCKET) { WARN("Unable to create socket: %d\n", WSAGetLastError()); continue; } if (bind(s, sockaddr, adapter_addr->FirstUnicastAddress->Address.iSockaddrLength) == SOCKET_ERROR) { WARN("Unable to bind to socket (adaptor '%s' (%p)): %d\n", debugstr_a(adapter_addr->AdapterName), adapter_addr, WSAGetLastError()); closesocket(s); continue; } /* Set the multicast interface and TTL value */ setsockopt(s, IPPROTO_IP, IP_MULTICAST_IF, (char *) &i_addr_zero, (family == AF_INET6) ? sizeof(struct in6_addr) : sizeof(struct in_addr)); setsockopt(s, IPPROTO_IP, IP_MULTICAST_TTL, &ttl, sizeof(ttl)); /* Set up the thread parameters */ send_params = heap_alloc(sizeof(*send_params)); send_params->data = heap_alloc(length); memcpy(send_params->data, data, length); send_params->length = length; send_params->sock = s; send_params->max_initial_delay = max_initial_delay; memset(&send_params->dest, 0, sizeof(SOCKADDR_STORAGE)); send_params->dest.ss_family = family; if (family == AF_INET) { SOCKADDR_IN *sockaddr4 = (SOCKADDR_IN *)&send_params->dest; sockaddr4->sin_port = htons(SEND_PORT); sockaddr4->sin_addr.S_un.S_addr = htonl(SEND_ADDRESS_IPV4); } else { SOCKADDR_IN6 *sockaddr6 = (SOCKADDR_IN6 *)&send_params->dest; sockaddr6->sin6_port = htons(SEND_PORT); memcpy(&sockaddr6->sin6_addr, &send_address_ipv6, sizeof(send_address_ipv6)); } thread_handle = CreateThread(NULL, 0, sending_thread, send_params, 0, NULL); if (thread_handle == NULL) { WARN("CreateThread failed (error %d)\n", GetLastError()); closesocket(s); heap_free(send_params->data); heap_free(send_params); continue; } CloseHandle(thread_handle); } ret = TRUE; cleanup: heap_free(adapter_addresses); return ret; } BOOL send_udp_multicast(IWSDiscoveryPublisherImpl *impl, char *data, int length, int max_initial_delay) { if ((impl->addressFamily & WSDAPI_ADDRESSFAMILY_IPV4) && (!send_udp_multicast_of_type(data, length,max_initial_delay, AF_INET))) return FALSE; if ((impl->addressFamily & WSDAPI_ADDRESSFAMILY_IPV6) && (!send_udp_multicast_of_type(data, length, max_initial_delay, AF_INET6))) return FALSE; return TRUE; } static int join_multicast_group(SOCKET s, SOCKADDR_STORAGE *group, SOCKADDR_STORAGE *iface) { int level, optname, optlen; struct ipv6_mreq mreqv6; struct ip_mreq mreqv4; char *optval; if (iface->ss_family == AF_INET6) { level = IPPROTO_IPV6; optname = IPV6_ADD_MEMBERSHIP; optval = (char *)&mreqv6; optlen = sizeof(mreqv6); mreqv6.ipv6mr_multiaddr = ((SOCKADDR_IN6 *)group)->sin6_addr; mreqv6.ipv6mr_interface = ((SOCKADDR_IN6 *)iface)->sin6_scope_id; } else { level = IPPROTO_IP; optname = IP_ADD_MEMBERSHIP; optval = (char *)&mreqv4; optlen = sizeof(mreqv4); mreqv4.imr_multiaddr.s_addr = ((SOCKADDR_IN *)group)->sin_addr.s_addr; mreqv4.imr_interface.s_addr = ((SOCKADDR_IN *)iface)->sin_addr.s_addr; } return setsockopt(s, level, optname, optval, optlen); } static int set_send_interface(SOCKET s, SOCKADDR_STORAGE *iface) { int level, optname, optlen; char *optval = NULL; if (iface->ss_family == AF_INET6) { level = IPPROTO_IPV6; optname = IPV6_MULTICAST_IF; optval = (char *) &((SOCKADDR_IN6 *)iface)->sin6_scope_id; optlen = sizeof(((SOCKADDR_IN6 *)iface)->sin6_scope_id); } else { level = IPPROTO_IP; optname = IP_MULTICAST_IF; optval = (char *) &((SOCKADDR_IN *)iface)->sin_addr.s_addr; optlen = sizeof(((SOCKADDR_IN *)iface)->sin_addr.s_addr); } return setsockopt(s, level, optname, optval, optlen); } typedef struct listener_thread_params { IWSDiscoveryPublisherImpl *impl; SOCKET listening_socket; BOOL ipv6; } listener_thread_params; static HRESULT process_received_message(listener_thread_params *params, char *message, int message_len, SOCKADDR_STORAGE *source_addr) { IWSDUdpMessageParameters *msg_params = NULL; IWSDUdpAddress *remote_addr = NULL; struct notificationSink *sink; WSD_SOAP_MESSAGE *msg = NULL; int msg_type; HRESULT ret; ret = read_message(params->impl, message, message_len, &msg, &msg_type); if (FAILED(ret)) return ret; switch (msg_type) { case MSGTYPE_PROBE: TRACE("Received probe message\n"); ret = WSDCreateUdpMessageParameters(&msg_params); if (FAILED(ret)) { ERR("Unable to create IWSDUdpMessageParameters, not processing message.\n"); goto cleanup; } ret = WSDCreateUdpAddress(&remote_addr); if (FAILED(ret)) { ERR("Unable to create IWSDUdpAddress, not processing message.\n"); goto cleanup; } IWSDUdpAddress_SetSockaddr(remote_addr, source_addr); IWSDUdpMessageParameters_SetRemoteAddress(msg_params, (IWSDAddress *)remote_addr); EnterCriticalSection(¶ms->impl->notification_sink_critical_section); LIST_FOR_EACH_ENTRY(sink, ¶ms->impl->notificationSinks, struct notificationSink, entry) { IWSDiscoveryPublisherNotify_ProbeHandler(sink->notificationSink, msg, (IWSDMessageParameters *)msg_params); } LeaveCriticalSection(¶ms->impl->notification_sink_critical_section); break; } cleanup: WSDFreeLinkedMemory(msg); if (remote_addr != NULL) IWSDUdpAddress_Release(remote_addr); if (msg_params != NULL) IWSDUdpMessageParameters_Release(msg_params); return ret; } #define RECEIVE_BUFFER_SIZE 65536 static DWORD WINAPI listening_thread(LPVOID params) { listener_thread_params *parameter = (listener_thread_params *)params; int bytes_received, address_len, err; SOCKADDR_STORAGE source_addr; char *buffer; buffer = heap_alloc(RECEIVE_BUFFER_SIZE); address_len = parameter->ipv6 ? sizeof(SOCKADDR_IN6) : sizeof(SOCKADDR_IN); while (parameter->impl->publisherStarted) { bytes_received = recvfrom(parameter->listening_socket, buffer, RECEIVE_BUFFER_SIZE, 0, (LPSOCKADDR) &source_addr, &address_len); if (bytes_received == SOCKET_ERROR) { err = WSAGetLastError(); if (err != WSAETIMEDOUT) { WARN("Received error when trying to read from socket: %d. Stopping listener.\n", err); return 0; } } else { process_received_message(parameter, buffer, bytes_received, &source_addr); } } /* The publisher has been stopped */ closesocket(parameter->listening_socket); heap_free(buffer); heap_free(parameter); return 0; } static int start_listening(IWSDiscoveryPublisherImpl *impl, SOCKADDR_STORAGE *bind_address) { SOCKADDR_STORAGE multicast_addr, bind_addr, interface_addr; listener_thread_params *parameter = NULL; const DWORD receive_timeout = 5000; const UINT reuse_addr = 1; HANDLE thread_handle; int address_length; SOCKET s = 0; TRACE("(%p, %p) family %d\n", impl, bind_address, bind_address->ss_family); /* Populate the multicast address */ ZeroMemory(&multicast_addr, sizeof(SOCKADDR_STORAGE)); if (bind_address->ss_family == AF_INET) { SOCKADDR_IN *sockaddr4 = (SOCKADDR_IN *)&multicast_addr; sockaddr4->sin_port = htons(SEND_PORT); sockaddr4->sin_addr.S_un.S_addr = htonl(SEND_ADDRESS_IPV4); address_length = sizeof(SOCKADDR_IN); } else { SOCKADDR_IN6 *sockaddr6 = (SOCKADDR_IN6 *)&multicast_addr; sockaddr6->sin6_port = htons(SEND_PORT); memcpy(&sockaddr6->sin6_addr, &send_address_ipv6, sizeof(send_address_ipv6)); address_length = sizeof(SOCKADDR_IN6); } /* Update the port for the binding address */ memcpy(&bind_addr, bind_address, address_length); ((SOCKADDR_IN *)&bind_addr)->sin_port = htons(SEND_PORT); /* Update the port for the interface address */ memcpy(&interface_addr, bind_address, address_length); ((SOCKADDR_IN *)&interface_addr)->sin_port = htons(0); /* Create the socket */ s = socket(bind_address->ss_family, SOCK_DGRAM, IPPROTO_UDP); if (s == INVALID_SOCKET) { WARN("socket() failed (error %d)\n", WSAGetLastError()); goto cleanup; } /* Ensure the socket can be reused */ if (setsockopt(s, SOL_SOCKET, SO_REUSEADDR, (const char *)&reuse_addr, sizeof(reuse_addr)) == SOCKET_ERROR) { WARN("setsockopt(SO_REUSEADDR) failed (error %d)\n", WSAGetLastError()); goto cleanup; } /* Bind the socket to the local interface so we can receive data */ if (bind(s, (struct sockaddr *)&bind_addr, address_length) == SOCKET_ERROR) { WARN("bind() failed (error %d)\n", WSAGetLastError()); goto cleanup; } /* Join the multicast group */ if (join_multicast_group(s, &multicast_addr, &interface_addr) == SOCKET_ERROR) { WARN("Unable to join multicast group (error %d)\n", WSAGetLastError()); goto cleanup; } /* Set the outgoing interface */ if (set_send_interface(s, &interface_addr) == SOCKET_ERROR) { WARN("Unable to set outgoing interface (error %d)\n", WSAGetLastError()); goto cleanup; } /* Set a 5-second receive timeout */ if (setsockopt(s, SOL_SOCKET, SO_RCVTIMEO, (const char *)&receive_timeout, sizeof(receive_timeout)) == SOCKET_ERROR) { WARN("setsockopt(SO_RCVTIME0) failed (error %d)\n", WSAGetLastError()); goto cleanup; } /* Allocate memory for thread parameters */ parameter = heap_alloc(sizeof(listener_thread_params)); parameter->impl = impl; parameter->listening_socket = s; parameter->ipv6 = (bind_address->ss_family == AF_INET6); thread_handle = CreateThread(NULL, 0, listening_thread, parameter, 0, NULL); if (thread_handle == NULL) { WARN("CreateThread failed (error %d)\n", GetLastError()); goto cleanup; } impl->thread_handles[impl->num_thread_handles] = thread_handle; impl->num_thread_handles++; return 1; cleanup: closesocket(s); heap_free(parameter); return 0; } static BOOL start_listening_on_all_addresses(IWSDiscoveryPublisherImpl *impl, ULONG family) { IP_ADAPTER_ADDRESSES *adapter_addresses = NULL, *adapter_address; int valid_listeners = 0; ULONG bufferSize = 0; ULONG ret; ret = GetAdaptersAddresses(family, 0, NULL, NULL, &bufferSize); /* family should be AF_INET or AF_INET6 */ if (ret != ERROR_BUFFER_OVERFLOW) { WARN("GetAdaptorsAddresses failed with error %08x\n", ret); return FALSE; } /* Get size of buffer for adapters */ adapter_addresses = (IP_ADAPTER_ADDRESSES *)heap_alloc(bufferSize); if (adapter_addresses == NULL) { WARN("Out of memory allocating space for adapter information\n"); return FALSE; } /* Get list of adapters */ ret = GetAdaptersAddresses(family, 0, NULL, adapter_addresses, &bufferSize); if (ret != ERROR_SUCCESS) { WARN("GetAdaptorsAddresses failed with error %08x\n", ret); goto cleanup; } for (adapter_address = adapter_addresses; adapter_address != NULL; adapter_address = adapter_address->Next) { if (impl->num_thread_handles >= MAX_WSD_THREADS) { WARN("Exceeded maximum number of supported listener threads; too many network interfaces.\n"); goto cleanup; } if (adapter_address->FirstUnicastAddress == NULL) { TRACE("No address found for adaptor '%s' (%p)\n", adapter_address->AdapterName, adapter_address); continue; } valid_listeners += start_listening(impl, (SOCKADDR_STORAGE *)adapter_address->FirstUnicastAddress->Address.lpSockaddr); } cleanup: heap_free(adapter_addresses); return (ret == ERROR_SUCCESS) && (valid_listeners > 0); } HRESULT send_udp_unicast(char *data, int length, IWSDUdpAddress *remote_addr, int max_initial_delay) { SOCKADDR_STORAGE address; HRESULT ret; SOCKET s; ZeroMemory(&address, sizeof(SOCKADDR_STORAGE)); ret = IWSDUdpAddress_GetSockaddr(remote_addr, &address); if (FAILED(ret)) { WARN("No sockaddr specified in send_udp_unicast\n"); return ret; } /* Create a socket and bind to the adapter address */ s = socket(address.ss_family, SOCK_DGRAM, IPPROTO_UDP); if (s == INVALID_SOCKET) { int error = WSAGetLastError(); WARN("Unable to create socket: %d\n", error); return HRESULT_FROM_WIN32(error); } send_message(s, data, length, &address, max_initial_delay, UNICAST_UDP_REPEAT); closesocket(s); return S_OK; } void terminate_networking(IWSDiscoveryPublisherImpl *impl) { BOOL needsCleanup = impl->publisherStarted; int i; impl->publisherStarted = FALSE; WaitForMultipleObjects(impl->num_thread_handles, impl->thread_handles, TRUE, INFINITE); for (i = 0; i < impl->num_thread_handles; i++) { CloseHandle(impl->thread_handles[i]); } if (needsCleanup) WSACleanup(); } BOOL init_networking(IWSDiscoveryPublisherImpl *impl) { WSADATA wsaData; int ret = WSAStartup(MAKEWORD(2, 2), &wsaData); if (ret != 0) { WARN("WSAStartup failed with error: %d\n", ret); return FALSE; } impl->publisherStarted = TRUE; if ((impl->addressFamily & WSDAPI_ADDRESSFAMILY_IPV4) && (!start_listening_on_all_addresses(impl, AF_INET))) goto cleanup; if ((impl->addressFamily & WSDAPI_ADDRESSFAMILY_IPV6) && (!start_listening_on_all_addresses(impl, AF_INET6))) goto cleanup; return TRUE; cleanup: terminate_networking(impl); return FALSE; }