/* * iphlpapi dll implementation * * Copyright (C) 2003,2006 Juan Lang * * 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 "config.h" #include #include #include #include #ifdef HAVE_NETINET_IN_H # include #endif #ifdef HAVE_ARPA_INET_H # include #endif #ifdef HAVE_ARPA_NAMESER_H # include #endif #ifdef HAVE_RESOLV_H # include #endif #define NONAMELESSUNION #define NONAMELESSSTRUCT #include "windef.h" #include "winbase.h" #include "winreg.h" #define USE_WS_PREFIX #include "winsock2.h" #include "winternl.h" #include "ws2ipdef.h" #include "windns.h" #include "iphlpapi.h" #include "ifenum.h" #include "ipstats.h" #include "ipifcons.h" #include "fltdefs.h" #include "ifdef.h" #include "netioapi.h" #include "tcpestats.h" #include "ip2string.h" #include "wine/debug.h" #include "wine/unicode.h" WINE_DEFAULT_DEBUG_CHANNEL(iphlpapi); #ifndef IF_NAMESIZE #define IF_NAMESIZE 16 #endif #ifndef INADDR_NONE #define INADDR_NONE ~0UL #endif /****************************************************************** * AddIPAddress (IPHLPAPI.@) * * Add an IP address to an adapter. * * PARAMS * Address [In] IP address to add to the adapter * IpMask [In] subnet mask for the IP address * IfIndex [In] adapter index to add the address * NTEContext [Out] Net Table Entry (NTE) context for the IP address * NTEInstance [Out] NTE instance for the IP address * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub. Currently returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI AddIPAddress(IPAddr Address, IPMask IpMask, DWORD IfIndex, PULONG NTEContext, PULONG NTEInstance) { FIXME(":stub\n"); return ERROR_NOT_SUPPORTED; } /****************************************************************** * AllocateAndGetIfTableFromStack (IPHLPAPI.@) * * Get table of local interfaces. * Like GetIfTable(), but allocate the returned table from heap. * * PARAMS * ppIfTable [Out] pointer into which the MIB_IFTABLE is * allocated and returned. * bOrder [In] whether to sort the table * heap [In] heap from which the table is allocated * flags [In] flags to HeapAlloc * * RETURNS * ERROR_INVALID_PARAMETER if ppIfTable is NULL, whatever * GetIfTable() returns otherwise. */ DWORD WINAPI AllocateAndGetIfTableFromStack(PMIB_IFTABLE *ppIfTable, BOOL bOrder, HANDLE heap, DWORD flags) { DWORD ret; TRACE("ppIfTable %p, bOrder %d, heap %p, flags 0x%08x\n", ppIfTable, bOrder, heap, flags); if (!ppIfTable) ret = ERROR_INVALID_PARAMETER; else { DWORD dwSize = 0; ret = GetIfTable(*ppIfTable, &dwSize, bOrder); if (ret == ERROR_INSUFFICIENT_BUFFER) { *ppIfTable = HeapAlloc(heap, flags, dwSize); ret = GetIfTable(*ppIfTable, &dwSize, bOrder); } } TRACE("returning %d\n", ret); return ret; } static int IpAddrTableNumericSorter(const void *a, const void *b) { int ret = 0; if (a && b) ret = ((const MIB_IPADDRROW*)a)->dwAddr - ((const MIB_IPADDRROW*)b)->dwAddr; return ret; } static int IpAddrTableLoopbackSorter(const void *a, const void *b) { const MIB_IPADDRROW *left = a, *right = b; int ret = 0; if (isIfIndexLoopback(left->dwIndex)) ret = 1; else if (isIfIndexLoopback(right->dwIndex)) ret = -1; return ret; } /****************************************************************** * AllocateAndGetIpAddrTableFromStack (IPHLPAPI.@) * * Get interface-to-IP address mapping table. * Like GetIpAddrTable(), but allocate the returned table from heap. * * PARAMS * ppIpAddrTable [Out] pointer into which the MIB_IPADDRTABLE is * allocated and returned. * bOrder [In] whether to sort the table * heap [In] heap from which the table is allocated * flags [In] flags to HeapAlloc * * RETURNS * ERROR_INVALID_PARAMETER if ppIpAddrTable is NULL, other error codes on * failure, NO_ERROR on success. */ DWORD WINAPI AllocateAndGetIpAddrTableFromStack(PMIB_IPADDRTABLE *ppIpAddrTable, BOOL bOrder, HANDLE heap, DWORD flags) { DWORD ret; TRACE("ppIpAddrTable %p, bOrder %d, heap %p, flags 0x%08x\n", ppIpAddrTable, bOrder, heap, flags); ret = getIPAddrTable(ppIpAddrTable, heap, flags); if (!ret && bOrder) qsort((*ppIpAddrTable)->table, (*ppIpAddrTable)->dwNumEntries, sizeof(MIB_IPADDRROW), IpAddrTableNumericSorter); TRACE("returning %d\n", ret); return ret; } /****************************************************************** * CancelIPChangeNotify (IPHLPAPI.@) * * Cancel a previous notification created by NotifyAddrChange or * NotifyRouteChange. * * PARAMS * overlapped [In] overlapped structure that notifies the caller * * RETURNS * Success: TRUE * Failure: FALSE * * FIXME * Stub, returns FALSE. */ BOOL WINAPI CancelIPChangeNotify(LPOVERLAPPED overlapped) { FIXME("(overlapped %p): stub\n", overlapped); return FALSE; } /****************************************************************** * CancelMibChangeNotify2 (IPHLPAPI.@) */ DWORD WINAPI CancelMibChangeNotify2(HANDLE handle) { FIXME("(handle %p): stub\n", handle); return NO_ERROR; } /****************************************************************** * CreateIpForwardEntry (IPHLPAPI.@) * * Create a route in the local computer's IP table. * * PARAMS * pRoute [In] new route information * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, always returns NO_ERROR. */ DWORD WINAPI CreateIpForwardEntry(PMIB_IPFORWARDROW pRoute) { FIXME("(pRoute %p): stub\n", pRoute); /* could use SIOCADDRT, not sure I want to */ return 0; } /****************************************************************** * CreateIpNetEntry (IPHLPAPI.@) * * Create entry in the ARP table. * * PARAMS * pArpEntry [In] new ARP entry * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, always returns NO_ERROR. */ DWORD WINAPI CreateIpNetEntry(PMIB_IPNETROW pArpEntry) { FIXME("(pArpEntry %p)\n", pArpEntry); /* could use SIOCSARP on systems that support it, not sure I want to */ return 0; } /****************************************************************** * CreateProxyArpEntry (IPHLPAPI.@) * * Create a Proxy ARP (PARP) entry for an IP address. * * PARAMS * dwAddress [In] IP address for which this computer acts as a proxy. * dwMask [In] subnet mask for dwAddress * dwIfIndex [In] interface index * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI CreateProxyArpEntry(DWORD dwAddress, DWORD dwMask, DWORD dwIfIndex) { FIXME("(dwAddress 0x%08x, dwMask 0x%08x, dwIfIndex 0x%08x): stub\n", dwAddress, dwMask, dwIfIndex); return ERROR_NOT_SUPPORTED; } static char *debugstr_ipv6(const struct WS_sockaddr_in6 *sin, char *buf) { const IN6_ADDR *addr = &sin->sin6_addr; char *p = buf; int i; BOOL in_zero = FALSE; for (i = 0; i < 7; i++) { if (!addr->u.Word[i]) { if (i == 0) *p++ = ':'; if (!in_zero) { *p++ = ':'; in_zero = TRUE; } } else { p += sprintf(p, "%x:", ntohs(addr->u.Word[i])); in_zero = FALSE; } } sprintf(p, "%x", ntohs(addr->u.Word[7])); return buf; } static BOOL map_address_6to4( const SOCKADDR_IN6 *addr6, SOCKADDR_IN *addr4 ) { ULONG i; if (addr6->sin6_family != WS_AF_INET6) return FALSE; for (i = 0; i < 5; i++) if (addr6->sin6_addr.u.Word[i]) return FALSE; if (addr6->sin6_addr.u.Word[5] != 0xffff) return FALSE; addr4->sin_family = WS_AF_INET; addr4->sin_port = addr6->sin6_port; addr4->sin_addr.S_un.S_addr = addr6->sin6_addr.u.Word[6] << 16 | addr6->sin6_addr.u.Word[7]; memset( &addr4->sin_zero, 0, sizeof(addr4->sin_zero) ); return TRUE; } static BOOL find_src_address( MIB_IPADDRTABLE *table, const SOCKADDR_IN *dst, SOCKADDR_IN6 *src ) { MIB_IPFORWARDROW row; DWORD i, j; if (GetBestRoute( dst->sin_addr.S_un.S_addr, 0, &row )) return FALSE; for (i = 0; i < table->dwNumEntries; i++) { /* take the first address */ if (table->table[i].dwIndex == row.dwForwardIfIndex) { src->sin6_family = WS_AF_INET6; src->sin6_port = 0; src->sin6_flowinfo = 0; for (j = 0; j < 5; j++) src->sin6_addr.u.Word[j] = 0; src->sin6_addr.u.Word[5] = 0xffff; src->sin6_addr.u.Word[6] = table->table[i].dwAddr & 0xffff; src->sin6_addr.u.Word[7] = table->table[i].dwAddr >> 16; return TRUE; } } return FALSE; } /****************************************************************** * CreateSortedAddressPairs (IPHLPAPI.@) */ DWORD WINAPI CreateSortedAddressPairs( const PSOCKADDR_IN6 src_list, DWORD src_count, const PSOCKADDR_IN6 dst_list, DWORD dst_count, DWORD options, PSOCKADDR_IN6_PAIR *pair_list, DWORD *pair_count ) { DWORD i, size, ret; SOCKADDR_IN6_PAIR *pairs; SOCKADDR_IN6 *ptr; SOCKADDR_IN addr4; MIB_IPADDRTABLE *table; FIXME( "(src_list %p src_count %u dst_list %p dst_count %u options %x pair_list %p pair_count %p): stub\n", src_list, src_count, dst_list, dst_count, options, pair_list, pair_count ); if (src_list || src_count || !dst_list || !pair_list || !pair_count || dst_count > 500) return ERROR_INVALID_PARAMETER; for (i = 0; i < dst_count; i++) { if (!map_address_6to4( &dst_list[i], &addr4 )) { FIXME("only mapped IPv4 addresses are supported\n"); return ERROR_NOT_SUPPORTED; } } size = dst_count * sizeof(*pairs); size += dst_count * sizeof(SOCKADDR_IN6) * 2; /* source address + destination address */ if (!(pairs = HeapAlloc( GetProcessHeap(), 0, size ))) return ERROR_NOT_ENOUGH_MEMORY; ptr = (SOCKADDR_IN6 *)&pairs[dst_count]; if ((ret = getIPAddrTable( &table, GetProcessHeap(), 0 ))) { HeapFree( GetProcessHeap(), 0, pairs ); return ret; } for (i = 0; i < dst_count; i++) { pairs[i].SourceAddress = ptr++; if (!map_address_6to4( &dst_list[i], &addr4 ) || !find_src_address( table, &addr4, pairs[i].SourceAddress )) { char buf[46]; FIXME( "source address for %s not found\n", debugstr_ipv6(&dst_list[i], buf) ); memset( pairs[i].SourceAddress, 0, sizeof(*pairs[i].SourceAddress) ); pairs[i].SourceAddress->sin6_family = WS_AF_INET6; } pairs[i].DestinationAddress = ptr++; memcpy( pairs[i].DestinationAddress, &dst_list[i], sizeof(*pairs[i].DestinationAddress) ); } *pair_list = pairs; *pair_count = dst_count; HeapFree( GetProcessHeap(), 0, table ); return NO_ERROR; } /****************************************************************** * DeleteIPAddress (IPHLPAPI.@) * * Delete an IP address added with AddIPAddress(). * * PARAMS * NTEContext [In] NTE context from AddIPAddress(); * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI DeleteIPAddress(ULONG NTEContext) { FIXME("(NTEContext %d): stub\n", NTEContext); return ERROR_NOT_SUPPORTED; } /****************************************************************** * DeleteIpForwardEntry (IPHLPAPI.@) * * Delete a route. * * PARAMS * pRoute [In] route to delete * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns NO_ERROR. */ DWORD WINAPI DeleteIpForwardEntry(PMIB_IPFORWARDROW pRoute) { FIXME("(pRoute %p): stub\n", pRoute); /* could use SIOCDELRT, not sure I want to */ return 0; } /****************************************************************** * DeleteIpNetEntry (IPHLPAPI.@) * * Delete an ARP entry. * * PARAMS * pArpEntry [In] ARP entry to delete * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns NO_ERROR. */ DWORD WINAPI DeleteIpNetEntry(PMIB_IPNETROW pArpEntry) { FIXME("(pArpEntry %p): stub\n", pArpEntry); /* could use SIOCDARP on systems that support it, not sure I want to */ return 0; } /****************************************************************** * DeleteProxyArpEntry (IPHLPAPI.@) * * Delete a Proxy ARP entry. * * PARAMS * dwAddress [In] IP address for which this computer acts as a proxy. * dwMask [In] subnet mask for dwAddress * dwIfIndex [In] interface index * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI DeleteProxyArpEntry(DWORD dwAddress, DWORD dwMask, DWORD dwIfIndex) { FIXME("(dwAddress 0x%08x, dwMask 0x%08x, dwIfIndex 0x%08x): stub\n", dwAddress, dwMask, dwIfIndex); return ERROR_NOT_SUPPORTED; } /****************************************************************** * EnableRouter (IPHLPAPI.@) * * Turn on ip forwarding. * * PARAMS * pHandle [In/Out] * pOverlapped [In/Out] hEvent member should contain a valid handle. * * RETURNS * Success: ERROR_IO_PENDING * Failure: error code from winerror.h * * FIXME * Stub, returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI EnableRouter(HANDLE * pHandle, OVERLAPPED * pOverlapped) { FIXME("(pHandle %p, pOverlapped %p): stub\n", pHandle, pOverlapped); /* could echo "1" > /proc/net/sys/net/ipv4/ip_forward, not sure I want to could map EACCESS to ERROR_ACCESS_DENIED, I suppose */ return ERROR_NOT_SUPPORTED; } /****************************************************************** * FlushIpNetTable (IPHLPAPI.@) * * Delete all ARP entries of an interface * * PARAMS * dwIfIndex [In] interface index * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI FlushIpNetTable(DWORD dwIfIndex) { FIXME("(dwIfIndex 0x%08x): stub\n", dwIfIndex); /* this flushes the arp cache of the given index */ return ERROR_NOT_SUPPORTED; } /****************************************************************** * FreeMibTable (IPHLPAPI.@) * * Free buffer allocated by network functions * * PARAMS * ptr [In] pointer to the buffer to free * */ void WINAPI FreeMibTable(void *ptr) { TRACE("(%p)\n", ptr); HeapFree(GetProcessHeap(), 0, ptr); } /****************************************************************** * GetAdapterIndex (IPHLPAPI.@) * * Get interface index from its name. * * PARAMS * AdapterName [In] unicode string with the adapter name * IfIndex [Out] returns found interface index * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h */ DWORD WINAPI GetAdapterIndex(LPWSTR AdapterName, PULONG IfIndex) { char adapterName[MAX_ADAPTER_NAME]; unsigned int i; DWORD ret; TRACE("(AdapterName %p, IfIndex %p)\n", AdapterName, IfIndex); /* The adapter name is guaranteed not to have any unicode characters, so * this translation is never lossy */ for (i = 0; i < sizeof(adapterName) - 1 && AdapterName[i]; i++) adapterName[i] = (char)AdapterName[i]; adapterName[i] = '\0'; ret = getInterfaceIndexByName(adapterName, IfIndex); TRACE("returning %d\n", ret); return ret; } /****************************************************************** * GetAdaptersInfo (IPHLPAPI.@) * * Get information about adapters. * * PARAMS * pAdapterInfo [Out] buffer for adapter infos * pOutBufLen [In] length of output buffer * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h */ DWORD WINAPI GetAdaptersInfo(PIP_ADAPTER_INFO pAdapterInfo, PULONG pOutBufLen) { DWORD ret; TRACE("pAdapterInfo %p, pOutBufLen %p\n", pAdapterInfo, pOutBufLen); if (!pOutBufLen) ret = ERROR_INVALID_PARAMETER; else { DWORD numNonLoopbackInterfaces = get_interface_indices( TRUE, NULL ); if (numNonLoopbackInterfaces > 0) { DWORD numIPAddresses = getNumIPAddresses(); ULONG size; /* This may slightly overestimate the amount of space needed, because * the IP addresses include the loopback address, but it's easier * to make sure there's more than enough space than to make sure there's * precisely enough space. */ size = sizeof(IP_ADAPTER_INFO) * numNonLoopbackInterfaces; size += numIPAddresses * sizeof(IP_ADDR_STRING); if (!pAdapterInfo || *pOutBufLen < size) { *pOutBufLen = size; ret = ERROR_BUFFER_OVERFLOW; } else { InterfaceIndexTable *table = NULL; PMIB_IPADDRTABLE ipAddrTable = NULL; PMIB_IPFORWARDTABLE routeTable = NULL; ret = getIPAddrTable(&ipAddrTable, GetProcessHeap(), 0); if (!ret) ret = AllocateAndGetIpForwardTableFromStack(&routeTable, FALSE, GetProcessHeap(), 0); if (!ret) get_interface_indices( TRUE, &table ); if (table) { size = sizeof(IP_ADAPTER_INFO) * table->numIndexes; size += ipAddrTable->dwNumEntries * sizeof(IP_ADDR_STRING); if (*pOutBufLen < size) { *pOutBufLen = size; ret = ERROR_INSUFFICIENT_BUFFER; } else { DWORD ndx; HKEY hKey; BOOL winsEnabled = FALSE; IP_ADDRESS_STRING primaryWINS, secondaryWINS; PIP_ADDR_STRING nextIPAddr = (PIP_ADDR_STRING)((LPBYTE)pAdapterInfo + numNonLoopbackInterfaces * sizeof(IP_ADAPTER_INFO)); memset(pAdapterInfo, 0, size); /* @@ Wine registry key: HKCU\Software\Wine\Network */ if (RegOpenKeyA(HKEY_CURRENT_USER, "Software\\Wine\\Network", &hKey) == ERROR_SUCCESS) { DWORD size = sizeof(primaryWINS.String); unsigned long addr; RegQueryValueExA(hKey, "WinsServer", NULL, NULL, (LPBYTE)primaryWINS.String, &size); addr = inet_addr(primaryWINS.String); if (addr != INADDR_NONE && addr != INADDR_ANY) winsEnabled = TRUE; size = sizeof(secondaryWINS.String); RegQueryValueExA(hKey, "BackupWinsServer", NULL, NULL, (LPBYTE)secondaryWINS.String, &size); addr = inet_addr(secondaryWINS.String); if (addr != INADDR_NONE && addr != INADDR_ANY) winsEnabled = TRUE; RegCloseKey(hKey); } for (ndx = 0; ndx < table->numIndexes; ndx++) { PIP_ADAPTER_INFO ptr = &pAdapterInfo[ndx]; DWORD i; PIP_ADDR_STRING currentIPAddr = &ptr->IpAddressList; BOOL firstIPAddr = TRUE; /* on Win98 this is left empty, but whatever */ getInterfaceNameByIndex(table->indexes[ndx], ptr->AdapterName); getInterfaceNameByIndex(table->indexes[ndx], ptr->Description); ptr->AddressLength = sizeof(ptr->Address); getInterfacePhysicalByIndex(table->indexes[ndx], &ptr->AddressLength, ptr->Address, &ptr->Type); ptr->Index = table->indexes[ndx]; for (i = 0; i < ipAddrTable->dwNumEntries; i++) { if (ipAddrTable->table[i].dwIndex == ptr->Index) { if (firstIPAddr) { RtlIpv4AddressToStringA((IN_ADDR *)&ipAddrTable->table[i].dwAddr, ptr->IpAddressList.IpAddress.String); RtlIpv4AddressToStringA((IN_ADDR *)&ipAddrTable->table[i].dwMask, ptr->IpAddressList.IpMask.String); firstIPAddr = FALSE; } else { currentIPAddr->Next = nextIPAddr; currentIPAddr = nextIPAddr; RtlIpv4AddressToStringA((IN_ADDR *)&ipAddrTable->table[i].dwAddr, currentIPAddr->IpAddress.String); RtlIpv4AddressToStringA((IN_ADDR *)&ipAddrTable->table[i].dwMask, currentIPAddr->IpMask.String); nextIPAddr++; } } } /* If no IP was found it probably means that the interface is not * configured. In this case we have to return a zeroed IP and mask. */ if (firstIPAddr) { strcpy(ptr->IpAddressList.IpAddress.String, "0.0.0.0"); strcpy(ptr->IpAddressList.IpMask.String, "0.0.0.0"); } /* Find first router through this interface, which we'll assume * is the default gateway for this adapter */ strcpy(ptr->GatewayList.IpAddress.String, "0.0.0.0"); strcpy(ptr->GatewayList.IpMask.String, "255.255.255.255"); for (i = 0; i < routeTable->dwNumEntries; i++) if (routeTable->table[i].dwForwardIfIndex == ptr->Index && routeTable->table[i].u1.ForwardType == MIB_IPROUTE_TYPE_INDIRECT) { RtlIpv4AddressToStringA((IN_ADDR *)&routeTable->table[i].dwForwardNextHop, ptr->GatewayList.IpAddress.String); RtlIpv4AddressToStringA((IN_ADDR *)&routeTable->table[i].dwForwardMask, ptr->GatewayList.IpMask.String); } if (winsEnabled) { ptr->HaveWins = TRUE; memcpy(ptr->PrimaryWinsServer.IpAddress.String, primaryWINS.String, sizeof(primaryWINS.String)); memcpy(ptr->SecondaryWinsServer.IpAddress.String, secondaryWINS.String, sizeof(secondaryWINS.String)); } if (ndx < table->numIndexes - 1) ptr->Next = &pAdapterInfo[ndx + 1]; else ptr->Next = NULL; ptr->DhcpEnabled = TRUE; } ret = NO_ERROR; } HeapFree(GetProcessHeap(), 0, table); } else ret = ERROR_OUTOFMEMORY; HeapFree(GetProcessHeap(), 0, routeTable); HeapFree(GetProcessHeap(), 0, ipAddrTable); } } else ret = ERROR_NO_DATA; } TRACE("returning %d\n", ret); return ret; } static DWORD typeFromMibType(DWORD mib_type) { switch (mib_type) { case MIB_IF_TYPE_ETHERNET: return IF_TYPE_ETHERNET_CSMACD; case MIB_IF_TYPE_TOKENRING: return IF_TYPE_ISO88025_TOKENRING; case MIB_IF_TYPE_PPP: return IF_TYPE_PPP; case MIB_IF_TYPE_LOOPBACK: return IF_TYPE_SOFTWARE_LOOPBACK; default: return IF_TYPE_OTHER; } } static NET_IF_CONNECTION_TYPE connectionTypeFromMibType(DWORD mib_type) { switch (mib_type) { case MIB_IF_TYPE_PPP: return NET_IF_CONNECTION_DEMAND; case MIB_IF_TYPE_SLIP: return NET_IF_CONNECTION_DEMAND; default: return NET_IF_CONNECTION_DEDICATED; } } static ULONG v4addressesFromIndex(IF_INDEX index, DWORD **addrs, ULONG *num_addrs, DWORD **masks) { ULONG ret, i, j; MIB_IPADDRTABLE *at; *num_addrs = 0; if ((ret = getIPAddrTable(&at, GetProcessHeap(), 0))) return ret; for (i = 0; i < at->dwNumEntries; i++) { if (at->table[i].dwIndex == index) (*num_addrs)++; } if (!(*addrs = HeapAlloc(GetProcessHeap(), 0, *num_addrs * sizeof(DWORD)))) { HeapFree(GetProcessHeap(), 0, at); return ERROR_OUTOFMEMORY; } if (!(*masks = HeapAlloc(GetProcessHeap(), 0, *num_addrs * sizeof(DWORD)))) { HeapFree(GetProcessHeap(), 0, *addrs); HeapFree(GetProcessHeap(), 0, at); return ERROR_OUTOFMEMORY; } for (i = 0, j = 0; i < at->dwNumEntries; i++) { if (at->table[i].dwIndex == index) { (*addrs)[j] = at->table[i].dwAddr; (*masks)[j] = at->table[i].dwMask; j++; } } HeapFree(GetProcessHeap(), 0, at); return ERROR_SUCCESS; } static char *debugstr_ipv4(const in_addr_t *in_addr, char *buf) { const BYTE *addrp; char *p = buf; for (addrp = (const BYTE *)in_addr; addrp - (const BYTE *)in_addr < sizeof(*in_addr); addrp++) { if (addrp == (const BYTE *)in_addr + sizeof(*in_addr) - 1) sprintf(p, "%d", *addrp); else p += sprintf(p, "%d.", *addrp); } return buf; } static ULONG count_v4_gateways(DWORD index, PMIB_IPFORWARDTABLE routeTable) { DWORD i, num_gateways = 0; for (i = 0; i < routeTable->dwNumEntries; i++) { if (routeTable->table[i].dwForwardIfIndex == index && routeTable->table[i].u1.ForwardType == MIB_IPROUTE_TYPE_INDIRECT) num_gateways++; } return num_gateways; } static DWORD mask_v4_to_prefix(DWORD m) { #ifdef HAVE___BUILTIN_POPCOUNT return __builtin_popcount(m); #else m -= m >> 1 & 0x55555555; m = (m & 0x33333333) + (m >> 2 & 0x33333333); return ((m + (m >> 4)) & 0x0f0f0f0f) * 0x01010101 >> 24; #endif } static DWORD mask_v6_to_prefix(SOCKET_ADDRESS *m) { const IN6_ADDR *mask = &((struct WS_sockaddr_in6 *)m->lpSockaddr)->sin6_addr; DWORD ret = 0, i; for (i = 0; i < 8; i++) ret += mask_v4_to_prefix(mask->u.Word[i]); return ret; } static PMIB_IPFORWARDROW findIPv4Gateway(DWORD index, PMIB_IPFORWARDTABLE routeTable) { DWORD i; PMIB_IPFORWARDROW row = NULL; for (i = 0; !row && i < routeTable->dwNumEntries; i++) { if (routeTable->table[i].dwForwardIfIndex == index && routeTable->table[i].u1.ForwardType == MIB_IPROUTE_TYPE_INDIRECT) row = &routeTable->table[i]; } return row; } static void fill_unicast_addr_data(IP_ADAPTER_ADDRESSES *aa, IP_ADAPTER_UNICAST_ADDRESS *ua) { /* Actually this information should be read somewhere from the system * but it doesn't matter much for the bugs found so far. * This information is required for DirectPlay8 games. */ if (aa->IfType != IF_TYPE_SOFTWARE_LOOPBACK) { ua->PrefixOrigin = IpPrefixOriginDhcp; ua->SuffixOrigin = IpSuffixOriginDhcp; } else { ua->PrefixOrigin = IpPrefixOriginManual; ua->SuffixOrigin = IpSuffixOriginManual; } /* The address is not duplicated in the network */ ua->DadState = IpDadStatePreferred; /* Some address life time values, required even for non-dhcp addresses */ ua->ValidLifetime = 60000; ua->PreferredLifetime = 60000; ua->LeaseLifetime = 60000; } static ULONG adapterAddressesFromIndex(ULONG family, ULONG flags, IF_INDEX index, IP_ADAPTER_ADDRESSES *aa, ULONG *size) { ULONG ret = ERROR_SUCCESS, i, j, num_v4addrs = 0, num_v4_gateways = 0, num_v6addrs = 0, total_size; DWORD *v4addrs = NULL, *v4masks = NULL; SOCKET_ADDRESS *v6addrs = NULL, *v6masks = NULL; PMIB_IPFORWARDTABLE routeTable = NULL; BOOL output_gateways; if ((flags & GAA_FLAG_INCLUDE_ALL_GATEWAYS) || !(flags & GAA_FLAG_SKIP_UNICAST)) { ret = AllocateAndGetIpForwardTableFromStack(&routeTable, FALSE, GetProcessHeap(), 0); if (ret) return ret; num_v4_gateways = count_v4_gateways(index, routeTable); } output_gateways = (flags & GAA_FLAG_INCLUDE_ALL_GATEWAYS) && (family == WS_AF_INET || family == WS_AF_UNSPEC); if (family == WS_AF_INET) { ret = v4addressesFromIndex(index, &v4addrs, &num_v4addrs, &v4masks); } else if (family == WS_AF_INET6) { ret = v6addressesFromIndex(index, &v6addrs, &num_v6addrs, &v6masks); } else if (family == WS_AF_UNSPEC) { ret = v4addressesFromIndex(index, &v4addrs, &num_v4addrs, &v4masks); if (!ret) ret = v6addressesFromIndex(index, &v6addrs, &num_v6addrs, &v6masks); } else { FIXME("address family %u unsupported\n", family); ret = ERROR_NO_DATA; } if (ret) { HeapFree(GetProcessHeap(), 0, v4addrs); HeapFree(GetProcessHeap(), 0, v4masks); HeapFree(GetProcessHeap(), 0, v6addrs); HeapFree(GetProcessHeap(), 0, v6masks); HeapFree(GetProcessHeap(), 0, routeTable); return ret; } total_size = sizeof(IP_ADAPTER_ADDRESSES); total_size += 39; /* "{00000000-0000-0000-0000-000000000000}" */ total_size += IF_NAMESIZE * sizeof(WCHAR); if (!(flags & GAA_FLAG_SKIP_FRIENDLY_NAME)) total_size += IF_NAMESIZE * sizeof(WCHAR); if (flags & GAA_FLAG_INCLUDE_PREFIX) { total_size += sizeof(IP_ADAPTER_PREFIX) * num_v4addrs; total_size += sizeof(IP_ADAPTER_PREFIX) * num_v6addrs; total_size += sizeof(struct sockaddr_in) * num_v4addrs; for (i = 0; i < num_v6addrs; i++) total_size += v6masks[i].iSockaddrLength; } total_size += sizeof(IP_ADAPTER_UNICAST_ADDRESS) * num_v4addrs; total_size += sizeof(struct sockaddr_in) * num_v4addrs; if (output_gateways) total_size += (sizeof(IP_ADAPTER_GATEWAY_ADDRESS) + sizeof(SOCKADDR_IN)) * num_v4_gateways; total_size += sizeof(IP_ADAPTER_UNICAST_ADDRESS) * num_v6addrs; total_size += sizeof(SOCKET_ADDRESS) * num_v6addrs; for (i = 0; i < num_v6addrs; i++) total_size += v6addrs[i].iSockaddrLength; if (aa && *size >= total_size) { char name[IF_NAMESIZE], *ptr = (char *)aa + sizeof(IP_ADAPTER_ADDRESSES), *src; WCHAR *dst; DWORD buflen, type; INTERNAL_IF_OPER_STATUS status; NET_LUID luid; GUID guid; memset(aa, 0, sizeof(IP_ADAPTER_ADDRESSES)); aa->u.s.Length = sizeof(IP_ADAPTER_ADDRESSES); aa->u.s.IfIndex = index; ConvertInterfaceIndexToLuid(index, &luid); ConvertInterfaceLuidToGuid(&luid, &guid); sprintf(ptr, "{%08X-%04X-%04X-%02X%02X-%02X%02X%02X%02X%02X%02X}", guid.Data1, guid.Data2, guid.Data3, guid.Data4[0], guid.Data4[1], guid.Data4[2], guid.Data4[3], guid.Data4[4], guid.Data4[5], guid.Data4[6], guid.Data4[7]); aa->AdapterName = ptr; ptr += 39; getInterfaceNameByIndex(index, name); if (!(flags & GAA_FLAG_SKIP_FRIENDLY_NAME)) { aa->FriendlyName = (WCHAR *)ptr; for (src = name, dst = (WCHAR *)ptr; *src; src++, dst++) *dst = *src; *dst++ = 0; ptr = (char *)dst; } aa->Description = (WCHAR *)ptr; for (src = name, dst = (WCHAR *)ptr; *src; src++, dst++) *dst = *src; *dst++ = 0; ptr = (char *)dst; TRACE("%s: %d IPv4 addresses, %d IPv6 addresses:\n", name, num_v4addrs, num_v6addrs); buflen = MAX_INTERFACE_PHYSADDR; getInterfacePhysicalByIndex(index, &buflen, aa->PhysicalAddress, &type); aa->PhysicalAddressLength = buflen; aa->IfType = typeFromMibType(type); aa->ConnectionType = connectionTypeFromMibType(type); aa->Luid.Info.NetLuidIndex = index; aa->Luid.Info.IfType = aa->IfType; if (output_gateways && num_v4_gateways) { PMIB_IPFORWARDROW adapterRow; if ((adapterRow = findIPv4Gateway(index, routeTable))) { PIP_ADAPTER_GATEWAY_ADDRESS gw; PSOCKADDR_IN sin; gw = (PIP_ADAPTER_GATEWAY_ADDRESS)ptr; aa->FirstGatewayAddress = gw; gw->u.s.Length = sizeof(IP_ADAPTER_GATEWAY_ADDRESS); ptr += sizeof(IP_ADAPTER_GATEWAY_ADDRESS); sin = (PSOCKADDR_IN)ptr; sin->sin_family = WS_AF_INET; sin->sin_port = 0; memcpy(&sin->sin_addr, &adapterRow->dwForwardNextHop, sizeof(DWORD)); gw->Address.lpSockaddr = (LPSOCKADDR)sin; gw->Address.iSockaddrLength = sizeof(SOCKADDR_IN); gw->Next = NULL; ptr += sizeof(SOCKADDR_IN); } } if (num_v4addrs && !(flags & GAA_FLAG_SKIP_UNICAST)) { IP_ADAPTER_UNICAST_ADDRESS *ua; struct WS_sockaddr_in *sa; aa->u1.s1.Ipv4Enabled = TRUE; ua = aa->FirstUnicastAddress = (IP_ADAPTER_UNICAST_ADDRESS *)ptr; for (i = 0; i < num_v4addrs; i++) { char addr_buf[16]; memset(ua, 0, sizeof(IP_ADAPTER_UNICAST_ADDRESS)); ua->u.s.Length = sizeof(IP_ADAPTER_UNICAST_ADDRESS); ua->Address.iSockaddrLength = sizeof(struct sockaddr_in); ua->Address.lpSockaddr = (SOCKADDR *)((char *)ua + ua->u.s.Length); if (num_v4_gateways) ua->u.s.Flags |= IP_ADAPTER_ADDRESS_DNS_ELIGIBLE; sa = (struct WS_sockaddr_in *)ua->Address.lpSockaddr; sa->sin_family = WS_AF_INET; sa->sin_addr.S_un.S_addr = v4addrs[i]; sa->sin_port = 0; TRACE("IPv4 %d/%d: %s\n", i + 1, num_v4addrs, debugstr_ipv4(&sa->sin_addr.S_un.S_addr, addr_buf)); fill_unicast_addr_data(aa, ua); ua->OnLinkPrefixLength = mask_v4_to_prefix(v4masks[i]); ptr += ua->u.s.Length + ua->Address.iSockaddrLength; if (i < num_v4addrs - 1) { ua->Next = (IP_ADAPTER_UNICAST_ADDRESS *)ptr; ua = ua->Next; } } } if (num_v6addrs && !(flags & GAA_FLAG_SKIP_UNICAST)) { IP_ADAPTER_UNICAST_ADDRESS *ua; struct WS_sockaddr_in6 *sa; aa->u1.s1.Ipv6Enabled = TRUE; if (aa->FirstUnicastAddress) { for (ua = aa->FirstUnicastAddress; ua->Next; ua = ua->Next) ; ua->Next = (IP_ADAPTER_UNICAST_ADDRESS *)ptr; ua = (IP_ADAPTER_UNICAST_ADDRESS *)ptr; } else ua = aa->FirstUnicastAddress = (IP_ADAPTER_UNICAST_ADDRESS *)ptr; for (i = 0; i < num_v6addrs; i++) { char addr_buf[46]; memset(ua, 0, sizeof(IP_ADAPTER_UNICAST_ADDRESS)); ua->u.s.Length = sizeof(IP_ADAPTER_UNICAST_ADDRESS); ua->Address.iSockaddrLength = v6addrs[i].iSockaddrLength; ua->Address.lpSockaddr = (SOCKADDR *)((char *)ua + ua->u.s.Length); sa = (struct WS_sockaddr_in6 *)ua->Address.lpSockaddr; memcpy(sa, v6addrs[i].lpSockaddr, sizeof(*sa)); TRACE("IPv6 %d/%d: %s\n", i + 1, num_v6addrs, debugstr_ipv6(sa, addr_buf)); fill_unicast_addr_data(aa, ua); ua->OnLinkPrefixLength = mask_v6_to_prefix(&v6masks[i]); ptr += ua->u.s.Length + ua->Address.iSockaddrLength; if (i < num_v6addrs - 1) { ua->Next = (IP_ADAPTER_UNICAST_ADDRESS *)ptr; ua = ua->Next; } } } if (num_v4addrs && (flags & GAA_FLAG_INCLUDE_PREFIX)) { IP_ADAPTER_PREFIX *prefix; prefix = aa->FirstPrefix = (IP_ADAPTER_PREFIX *)ptr; for (i = 0; i < num_v4addrs; i++) { char addr_buf[16]; struct WS_sockaddr_in *sa; prefix->u.s.Length = sizeof(*prefix); prefix->u.s.Flags = 0; prefix->Next = NULL; prefix->Address.iSockaddrLength = sizeof(struct sockaddr_in); prefix->Address.lpSockaddr = (SOCKADDR *)((char *)prefix + prefix->u.s.Length); sa = (struct WS_sockaddr_in *)prefix->Address.lpSockaddr; sa->sin_family = WS_AF_INET; sa->sin_addr.S_un.S_addr = v4addrs[i] & v4masks[i]; sa->sin_port = 0; prefix->PrefixLength = mask_v4_to_prefix(v4masks[i]); TRACE("IPv4 network: %s/%u\n", debugstr_ipv4((const in_addr_t *)&sa->sin_addr.S_un.S_addr, addr_buf), prefix->PrefixLength); ptr += prefix->u.s.Length + prefix->Address.iSockaddrLength; if (i < num_v4addrs - 1) { prefix->Next = (IP_ADAPTER_PREFIX *)ptr; prefix = prefix->Next; } } } if (num_v6addrs && (flags & GAA_FLAG_INCLUDE_PREFIX)) { IP_ADAPTER_PREFIX *prefix; if (aa->FirstPrefix) { for (prefix = aa->FirstPrefix; prefix->Next; prefix = prefix->Next) ; prefix->Next = (IP_ADAPTER_PREFIX *)ptr; prefix = (IP_ADAPTER_PREFIX *)ptr; } else prefix = aa->FirstPrefix = (IP_ADAPTER_PREFIX *)ptr; for (i = 0; i < num_v6addrs; i++) { char addr_buf[46]; struct WS_sockaddr_in6 *sa; const IN6_ADDR *addr, *mask; prefix->u.s.Length = sizeof(*prefix); prefix->u.s.Flags = 0; prefix->Next = NULL; prefix->Address.iSockaddrLength = sizeof(struct sockaddr_in6); prefix->Address.lpSockaddr = (SOCKADDR *)((char *)prefix + prefix->u.s.Length); sa = (struct WS_sockaddr_in6 *)prefix->Address.lpSockaddr; sa->sin6_family = WS_AF_INET6; sa->sin6_port = 0; sa->sin6_flowinfo = 0; addr = &((struct WS_sockaddr_in6 *)v6addrs[i].lpSockaddr)->sin6_addr; mask = &((struct WS_sockaddr_in6 *)v6masks[i].lpSockaddr)->sin6_addr; for (j = 0; j < 8; j++) sa->sin6_addr.u.Word[j] = addr->u.Word[j] & mask->u.Word[j]; sa->sin6_scope_id = 0; prefix->PrefixLength = mask_v6_to_prefix(&v6masks[i]); TRACE("IPv6 network: %s/%u\n", debugstr_ipv6(sa, addr_buf), prefix->PrefixLength); ptr += prefix->u.s.Length + prefix->Address.iSockaddrLength; if (i < num_v6addrs - 1) { prefix->Next = (IP_ADAPTER_PREFIX *)ptr; prefix = prefix->Next; } } } getInterfaceMtuByName(name, &aa->Mtu); getInterfaceStatusByName(name, &status); if (status == MIB_IF_OPER_STATUS_OPERATIONAL) aa->OperStatus = IfOperStatusUp; else if (status == MIB_IF_OPER_STATUS_NON_OPERATIONAL) aa->OperStatus = IfOperStatusDown; else aa->OperStatus = IfOperStatusUnknown; } *size = total_size; HeapFree(GetProcessHeap(), 0, routeTable); HeapFree(GetProcessHeap(), 0, v6addrs); HeapFree(GetProcessHeap(), 0, v6masks); HeapFree(GetProcessHeap(), 0, v4addrs); HeapFree(GetProcessHeap(), 0, v4masks); return ERROR_SUCCESS; } static void sockaddr_in_to_WS_storage( SOCKADDR_STORAGE *dst, const struct sockaddr_in *src ) { SOCKADDR_IN *s = (SOCKADDR_IN *)dst; s->sin_family = WS_AF_INET; s->sin_port = src->sin_port; memcpy( &s->sin_addr, &src->sin_addr, sizeof(IN_ADDR) ); memset( (char *)s + FIELD_OFFSET( SOCKADDR_IN, sin_zero ), 0, sizeof(SOCKADDR_STORAGE) - FIELD_OFFSET( SOCKADDR_IN, sin_zero) ); } #if defined(HAVE_STRUCT___RES_STATE__U__EXT_NSCOUNT6) || \ (defined(HAVE___RES_GET_STATE) && defined(HAVE___RES_GETSERVERS)) || \ defined(HAVE_RES_GETSERVERS) static void sockaddr_in6_to_WS_storage( SOCKADDR_STORAGE *dst, const struct sockaddr_in6 *src ) { SOCKADDR_IN6 *s = (SOCKADDR_IN6 *)dst; s->sin6_family = WS_AF_INET6; s->sin6_port = src->sin6_port; s->sin6_flowinfo = src->sin6_flowinfo; memcpy( &s->sin6_addr, &src->sin6_addr, sizeof(IN6_ADDR) ); s->sin6_scope_id = src->sin6_scope_id; memset( (char *)s + sizeof(SOCKADDR_IN6), 0, sizeof(SOCKADDR_STORAGE) - sizeof(SOCKADDR_IN6) ); } #endif #ifdef HAVE_STRUCT___RES_STATE /* call res_init() just once because of a bug in Mac OS X 10.4 */ /* Call once per thread on systems that have per-thread _res. */ static CRITICAL_SECTION res_init_cs; static CRITICAL_SECTION_DEBUG res_init_cs_debug = { 0, 0, &res_init_cs, { &res_init_cs_debug.ProcessLocksList, &res_init_cs_debug.ProcessLocksList }, 0, 0, { (DWORD_PTR)(__FILE__ ": res_init_cs") } }; static CRITICAL_SECTION res_init_cs = { &res_init_cs_debug, -1, 0, 0, 0, 0 }; static void initialise_resolver(void) { EnterCriticalSection(&res_init_cs); if ((_res.options & RES_INIT) == 0) res_init(); LeaveCriticalSection(&res_init_cs); } #ifdef HAVE_RES_GETSERVERS static int get_dns_servers( SOCKADDR_STORAGE *servers, int num, BOOL ip4_only ) { struct __res_state *state = &_res; int i, found = 0, total; SOCKADDR_STORAGE *addr = servers; union res_sockaddr_union *buf; initialise_resolver(); total = res_getservers( state, NULL, 0 ); if ((!servers || !num) && !ip4_only) return total; buf = HeapAlloc( GetProcessHeap(), 0, total * sizeof(union res_sockaddr_union) ); total = res_getservers( state, buf, total ); for (i = 0; i < total; i++) { if (buf[i].sin6.sin6_family == AF_INET6 && ip4_only) continue; if (buf[i].sin.sin_family != AF_INET && buf[i].sin6.sin6_family != AF_INET6) continue; found++; if (!servers || !num) continue; if (buf[i].sin6.sin6_family == AF_INET6) { sockaddr_in6_to_WS_storage( addr, &buf[i].sin6 ); } else { sockaddr_in_to_WS_storage( addr, &buf[i].sin ); } if (++addr >= servers + num) break; } HeapFree( GetProcessHeap(), 0, buf ); return found; } #else static int get_dns_servers( SOCKADDR_STORAGE *servers, int num, BOOL ip4_only ) { int i, ip6_count = 0; SOCKADDR_STORAGE *addr; initialise_resolver(); #ifdef HAVE_STRUCT___RES_STATE__U__EXT_NSCOUNT6 ip6_count = _res._u._ext.nscount6; #endif if (!servers || !num) { num = _res.nscount; if (ip4_only) num -= ip6_count; return num; } for (i = 0, addr = servers; addr < (servers + num) && i < _res.nscount; i++) { #ifdef HAVE_STRUCT___RES_STATE__U__EXT_NSCOUNT6 if (_res._u._ext.nsaddrs[i] && _res._u._ext.nsaddrs[i]->sin6_family == AF_INET6) { if (ip4_only) continue; sockaddr_in6_to_WS_storage( addr, _res._u._ext.nsaddrs[i] ); } else #endif { sockaddr_in_to_WS_storage( addr, _res.nsaddr_list + i ); } addr++; } return addr - servers; } #endif #elif defined(HAVE___RES_GET_STATE) && defined(HAVE___RES_GETSERVERS) static int get_dns_servers( SOCKADDR_STORAGE *servers, int num, BOOL ip4_only ) { extern struct res_state *__res_get_state( void ); extern int __res_getservers( struct res_state *, struct sockaddr_storage *, int ); struct res_state *state = __res_get_state(); int i, found = 0, total = __res_getservers( state, NULL, 0 ); SOCKADDR_STORAGE *addr = servers; struct sockaddr_storage *buf; if ((!servers || !num) && !ip4_only) return total; buf = HeapAlloc( GetProcessHeap(), 0, total * sizeof(struct sockaddr_storage) ); total = __res_getservers( state, buf, total ); for (i = 0; i < total; i++) { if (buf[i].ss_family == AF_INET6 && ip4_only) continue; if (buf[i].ss_family != AF_INET && buf[i].ss_family != AF_INET6) continue; found++; if (!servers || !num) continue; if (buf[i].ss_family == AF_INET6) { sockaddr_in6_to_WS_storage( addr, (struct sockaddr_in6 *)(buf + i) ); } else { sockaddr_in_to_WS_storage( addr, (struct sockaddr_in *)(buf + i) ); } if (++addr >= servers + num) break; } HeapFree( GetProcessHeap(), 0, buf ); return found; } #else static int get_dns_servers( SOCKADDR_STORAGE *servers, int num, BOOL ip4_only ) { FIXME("Unimplemented on this system\n"); return 0; } #endif static ULONG get_dns_server_addresses(PIP_ADAPTER_DNS_SERVER_ADDRESS address, ULONG *len) { int num = get_dns_servers( NULL, 0, FALSE ); DWORD size; size = num * (sizeof(IP_ADAPTER_DNS_SERVER_ADDRESS) + sizeof(SOCKADDR_STORAGE)); if (!address || *len < size) { *len = size; return ERROR_BUFFER_OVERFLOW; } *len = size; if (num > 0) { PIP_ADAPTER_DNS_SERVER_ADDRESS addr = address; SOCKADDR_STORAGE *sock_addrs = (SOCKADDR_STORAGE *)(address + num); int i; get_dns_servers( sock_addrs, num, FALSE ); for (i = 0; i < num; i++, addr = addr->Next) { addr->u.s.Length = sizeof(*addr); if (sock_addrs[i].ss_family == WS_AF_INET6) addr->Address.iSockaddrLength = sizeof(SOCKADDR_IN6); else addr->Address.iSockaddrLength = sizeof(SOCKADDR_IN); addr->Address.lpSockaddr = (SOCKADDR *)(sock_addrs + i); if (i == num - 1) addr->Next = NULL; else addr->Next = addr + 1; } } return ERROR_SUCCESS; } #ifdef HAVE_STRUCT___RES_STATE static BOOL is_ip_address_string(const char *str) { struct in_addr in; int ret; ret = inet_aton(str, &in); return ret != 0; } #endif static ULONG get_dns_suffix(WCHAR *suffix, ULONG *len) { ULONG size; const char *found_suffix = ""; /* Always return a NULL-terminated string, even if it's empty. */ #ifdef HAVE_STRUCT___RES_STATE { ULONG i; initialise_resolver(); for (i = 0; !*found_suffix && i < MAXDNSRCH + 1 && _res.dnsrch[i]; i++) { /* This uses a heuristic to select a DNS suffix: * the first, non-IP address string is selected. */ if (!is_ip_address_string(_res.dnsrch[i])) found_suffix = _res.dnsrch[i]; } } #endif size = MultiByteToWideChar( CP_UNIXCP, 0, found_suffix, -1, NULL, 0 ) * sizeof(WCHAR); if (!suffix || *len < size) { *len = size; return ERROR_BUFFER_OVERFLOW; } *len = MultiByteToWideChar( CP_UNIXCP, 0, found_suffix, -1, suffix, *len / sizeof(WCHAR) ) * sizeof(WCHAR); return ERROR_SUCCESS; } ULONG WINAPI DECLSPEC_HOTPATCH GetAdaptersAddresses(ULONG family, ULONG flags, PVOID reserved, PIP_ADAPTER_ADDRESSES aa, PULONG buflen) { InterfaceIndexTable *table; ULONG i, size, dns_server_size = 0, dns_suffix_size, total_size, ret = ERROR_NO_DATA; TRACE("(%d, %08x, %p, %p, %p)\n", family, flags, reserved, aa, buflen); if (!buflen) return ERROR_INVALID_PARAMETER; get_interface_indices( FALSE, &table ); if (!table || !table->numIndexes) { HeapFree(GetProcessHeap(), 0, table); return ERROR_NO_DATA; } total_size = 0; for (i = 0; i < table->numIndexes; i++) { size = 0; if ((ret = adapterAddressesFromIndex(family, flags, table->indexes[i], NULL, &size))) { HeapFree(GetProcessHeap(), 0, table); return ret; } total_size += size; } if (!(flags & GAA_FLAG_SKIP_DNS_SERVER)) { /* Since DNS servers aren't really per adapter, get enough space for a * single copy of them. */ get_dns_server_addresses(NULL, &dns_server_size); total_size += dns_server_size; } /* Since DNS suffix also isn't really per adapter, get enough space for a * single copy of it. */ get_dns_suffix(NULL, &dns_suffix_size); total_size += dns_suffix_size; if (aa && *buflen >= total_size) { ULONG bytes_left = size = total_size; PIP_ADAPTER_ADDRESSES first_aa = aa; PIP_ADAPTER_DNS_SERVER_ADDRESS firstDns; WCHAR *dnsSuffix; for (i = 0; i < table->numIndexes; i++) { if ((ret = adapterAddressesFromIndex(family, flags, table->indexes[i], aa, &size))) { HeapFree(GetProcessHeap(), 0, table); return ret; } if (i < table->numIndexes - 1) { aa->Next = (IP_ADAPTER_ADDRESSES *)((char *)aa + size); aa = aa->Next; size = bytes_left -= size; } } if (dns_server_size) { firstDns = (PIP_ADAPTER_DNS_SERVER_ADDRESS)((BYTE *)first_aa + total_size - dns_server_size - dns_suffix_size); get_dns_server_addresses(firstDns, &dns_server_size); for (aa = first_aa; aa; aa = aa->Next) { if (aa->IfType != IF_TYPE_SOFTWARE_LOOPBACK && aa->OperStatus == IfOperStatusUp) aa->FirstDnsServerAddress = firstDns; } } aa = first_aa; dnsSuffix = (WCHAR *)((BYTE *)aa + total_size - dns_suffix_size); get_dns_suffix(dnsSuffix, &dns_suffix_size); for (; aa; aa = aa->Next) { if (aa->IfType != IF_TYPE_SOFTWARE_LOOPBACK && aa->OperStatus == IfOperStatusUp) aa->DnsSuffix = dnsSuffix; else aa->DnsSuffix = dnsSuffix + dns_suffix_size / sizeof(WCHAR) - 1; } ret = ERROR_SUCCESS; } else { ret = ERROR_BUFFER_OVERFLOW; *buflen = total_size; } TRACE("num adapters %u\n", table->numIndexes); HeapFree(GetProcessHeap(), 0, table); return ret; } /****************************************************************** * GetBestInterface (IPHLPAPI.@) * * Get the interface, with the best route for the given IP address. * * PARAMS * dwDestAddr [In] IP address to search the interface for * pdwBestIfIndex [Out] found best interface * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h */ DWORD WINAPI GetBestInterface(IPAddr dwDestAddr, PDWORD pdwBestIfIndex) { struct WS_sockaddr_in sa_in; memset(&sa_in, 0, sizeof(sa_in)); sa_in.sin_family = WS_AF_INET; sa_in.sin_addr.S_un.S_addr = dwDestAddr; return GetBestInterfaceEx((struct WS_sockaddr *)&sa_in, pdwBestIfIndex); } /****************************************************************** * GetBestInterfaceEx (IPHLPAPI.@) * * Get the interface, with the best route for the given IP address. * * PARAMS * dwDestAddr [In] IP address to search the interface for * pdwBestIfIndex [Out] found best interface * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h */ DWORD WINAPI GetBestInterfaceEx(struct WS_sockaddr *pDestAddr, PDWORD pdwBestIfIndex) { DWORD ret; TRACE("pDestAddr %p, pdwBestIfIndex %p\n", pDestAddr, pdwBestIfIndex); if (!pDestAddr || !pdwBestIfIndex) ret = ERROR_INVALID_PARAMETER; else { MIB_IPFORWARDROW ipRow; if (pDestAddr->sa_family == WS_AF_INET) { ret = GetBestRoute(((struct WS_sockaddr_in *)pDestAddr)->sin_addr.S_un.S_addr, 0, &ipRow); if (ret == ERROR_SUCCESS) *pdwBestIfIndex = ipRow.dwForwardIfIndex; } else { FIXME("address family %d not supported\n", pDestAddr->sa_family); ret = ERROR_NOT_SUPPORTED; } } TRACE("returning %d\n", ret); return ret; } /****************************************************************** * GetBestRoute (IPHLPAPI.@) * * Get the best route for the given IP address. * * PARAMS * dwDestAddr [In] IP address to search the best route for * dwSourceAddr [In] optional source IP address * pBestRoute [Out] found best route * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h */ DWORD WINAPI GetBestRoute(DWORD dwDestAddr, DWORD dwSourceAddr, PMIB_IPFORWARDROW pBestRoute) { PMIB_IPFORWARDTABLE table; DWORD ret; TRACE("dwDestAddr 0x%08x, dwSourceAddr 0x%08x, pBestRoute %p\n", dwDestAddr, dwSourceAddr, pBestRoute); if (!pBestRoute) return ERROR_INVALID_PARAMETER; ret = AllocateAndGetIpForwardTableFromStack(&table, FALSE, GetProcessHeap(), 0); if (!ret) { DWORD ndx, matchedBits, matchedNdx = table->dwNumEntries; for (ndx = 0, matchedBits = 0; ndx < table->dwNumEntries; ndx++) { if (table->table[ndx].u1.ForwardType != MIB_IPROUTE_TYPE_INVALID && (dwDestAddr & table->table[ndx].dwForwardMask) == (table->table[ndx].dwForwardDest & table->table[ndx].dwForwardMask)) { DWORD numShifts, mask; for (numShifts = 0, mask = table->table[ndx].dwForwardMask; mask && mask & 1; mask >>= 1, numShifts++) ; if (numShifts > matchedBits) { matchedBits = numShifts; matchedNdx = ndx; } else if (!matchedBits) { matchedNdx = ndx; } } } if (matchedNdx < table->dwNumEntries) { memcpy(pBestRoute, &table->table[matchedNdx], sizeof(MIB_IPFORWARDROW)); ret = ERROR_SUCCESS; } else { /* No route matches, which can happen if there's no default route. */ ret = ERROR_HOST_UNREACHABLE; } HeapFree(GetProcessHeap(), 0, table); } TRACE("returning %d\n", ret); return ret; } /****************************************************************** * GetFriendlyIfIndex (IPHLPAPI.@) * * Get a "friendly" version of IfIndex, which is one that doesn't * have the top byte set. Doesn't validate whether IfIndex is a valid * adapter index. * * PARAMS * IfIndex [In] interface index to get the friendly one for * * RETURNS * A friendly version of IfIndex. */ DWORD WINAPI GetFriendlyIfIndex(DWORD IfIndex) { /* windows doesn't validate these, either, just makes sure the top byte is cleared. I assume my ifenum module never gives an index with the top byte set. */ TRACE("returning %d\n", IfIndex); return IfIndex; } /****************************************************************** * GetIfEntry (IPHLPAPI.@) * * Get information about an interface. * * PARAMS * pIfRow [In/Out] In: dwIndex of MIB_IFROW selects the interface. * Out: interface information * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h */ DWORD WINAPI GetIfEntry(PMIB_IFROW pIfRow) { DWORD ret; char nameBuf[MAX_ADAPTER_NAME]; char *name; TRACE("pIfRow %p\n", pIfRow); if (!pIfRow) return ERROR_INVALID_PARAMETER; name = getInterfaceNameByIndex(pIfRow->dwIndex, nameBuf); if (name) { ret = getInterfaceEntryByName(name, pIfRow); if (ret == NO_ERROR) ret = getInterfaceStatsByName(name, pIfRow); } else ret = ERROR_INVALID_DATA; TRACE("returning %d\n", ret); return ret; } /****************************************************************** * GetIfEntry2 (IPHLPAPI.@) */ DWORD WINAPI GetIfEntry2( MIB_IF_ROW2 *row2 ) { DWORD ret, len = ARRAY_SIZE(row2->Description); char buf[MAX_ADAPTER_NAME], *name; MIB_IFROW row; TRACE("%p\n", row2); if (!row2 || (!(name = getInterfaceNameByIndex( row2->InterfaceIndex, buf )) && !(name = getInterfaceNameByIndex( row2->InterfaceLuid.Info.NetLuidIndex, buf )))) { return ERROR_INVALID_PARAMETER; } if ((ret = getInterfaceEntryByName( name, &row ))) return ret; if ((ret = getInterfaceStatsByName( name, &row ))) return ret; memset( row2, 0, sizeof(*row2) ); row2->InterfaceLuid.Info.Reserved = 0; row2->InterfaceLuid.Info.NetLuidIndex = row.dwIndex; row2->InterfaceLuid.Info.IfType = row.dwType; row2->InterfaceIndex = row.dwIndex; ConvertInterfaceLuidToGuid( &row2->InterfaceLuid, &row2->InterfaceGuid ); row2->Type = row.dwType; row2->Mtu = row.dwMtu; MultiByteToWideChar( CP_UNIXCP, 0, (const char *)row.bDescr, -1, row2->Description, len ); row2->PhysicalAddressLength = row.dwPhysAddrLen; memcpy( &row2->PhysicalAddress, &row.bPhysAddr, row.dwPhysAddrLen ); memcpy( &row2->PermanentPhysicalAddress, &row.bPhysAddr, row.dwPhysAddrLen ); row2->OperStatus = IfOperStatusUp; row2->AdminStatus = NET_IF_ADMIN_STATUS_UP; row2->MediaConnectState = MediaConnectStateConnected; row2->ConnectionType = NET_IF_CONNECTION_DEDICATED; /* stats */ row2->InOctets = row.dwInOctets; row2->InUcastPkts = row.dwInUcastPkts; row2->InNUcastPkts = row.dwInNUcastPkts; row2->InDiscards = row.dwInDiscards; row2->InErrors = row.dwInErrors; row2->InUnknownProtos = row.dwInUnknownProtos; row2->OutOctets = row.dwOutOctets; row2->OutUcastPkts = row.dwOutUcastPkts; row2->OutNUcastPkts = row.dwOutNUcastPkts; row2->OutDiscards = row.dwOutDiscards; row2->OutErrors = row.dwOutErrors; return NO_ERROR; } static int IfTableSorter(const void *a, const void *b) { int ret; if (a && b) ret = ((const MIB_IFROW*)a)->dwIndex - ((const MIB_IFROW*)b)->dwIndex; else ret = 0; return ret; } /****************************************************************** * GetIfTable (IPHLPAPI.@) * * Get a table of local interfaces. * * PARAMS * pIfTable [Out] buffer for local interfaces table * pdwSize [In/Out] length of output buffer * bOrder [In] whether to sort the table * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * NOTES * If pdwSize is less than required, the function will return * ERROR_INSUFFICIENT_BUFFER, and *pdwSize will be set to the required byte * size. * If bOrder is true, the returned table will be sorted by interface index. */ DWORD WINAPI GetIfTable(PMIB_IFTABLE pIfTable, PULONG pdwSize, BOOL bOrder) { DWORD ret; TRACE("pIfTable %p, pdwSize %p, bOrder %d\n", pIfTable, pdwSize, bOrder); if (!pdwSize) ret = ERROR_INVALID_PARAMETER; else { DWORD numInterfaces = get_interface_indices( FALSE, NULL ); ULONG size = sizeof(MIB_IFTABLE); if (numInterfaces > 1) size += (numInterfaces - 1) * sizeof(MIB_IFROW); if (!pIfTable || *pdwSize < size) { *pdwSize = size; ret = ERROR_INSUFFICIENT_BUFFER; } else { InterfaceIndexTable *table; get_interface_indices( FALSE, &table ); if (table) { size = sizeof(MIB_IFTABLE); if (table->numIndexes > 1) size += (table->numIndexes - 1) * sizeof(MIB_IFROW); if (*pdwSize < size) { *pdwSize = size; ret = ERROR_INSUFFICIENT_BUFFER; } else { DWORD ndx; *pdwSize = size; pIfTable->dwNumEntries = 0; for (ndx = 0; ndx < table->numIndexes; ndx++) { pIfTable->table[ndx].dwIndex = table->indexes[ndx]; GetIfEntry(&pIfTable->table[ndx]); pIfTable->dwNumEntries++; } if (bOrder) qsort(pIfTable->table, pIfTable->dwNumEntries, sizeof(MIB_IFROW), IfTableSorter); ret = NO_ERROR; } HeapFree(GetProcessHeap(), 0, table); } else ret = ERROR_OUTOFMEMORY; } } TRACE("returning %d\n", ret); return ret; } /****************************************************************** * GetIfTable2Ex (IPHLPAPI.@) */ DWORD WINAPI GetIfTable2Ex( MIB_IF_TABLE_LEVEL level, MIB_IF_TABLE2 **table ) { DWORD i, nb_interfaces, size = sizeof(MIB_IF_TABLE2); InterfaceIndexTable *index_table; MIB_IF_TABLE2 *ret; TRACE( "level %u, table %p\n", level, table ); if (!table || level > MibIfTableNormalWithoutStatistics) return ERROR_INVALID_PARAMETER; if (level != MibIfTableNormal) FIXME("level %u not fully supported\n", level); if ((nb_interfaces = get_interface_indices( FALSE, NULL )) > 1) size += (nb_interfaces - 1) * sizeof(MIB_IF_ROW2); if (!(ret = HeapAlloc( GetProcessHeap(), 0, size ))) return ERROR_OUTOFMEMORY; get_interface_indices( FALSE, &index_table ); if (!index_table) { HeapFree( GetProcessHeap(), 0, ret ); return ERROR_OUTOFMEMORY; } ret->NumEntries = 0; for (i = 0; i < index_table->numIndexes; i++) { ret->Table[i].InterfaceIndex = index_table->indexes[i]; GetIfEntry2( &ret->Table[i] ); ret->NumEntries++; } HeapFree( GetProcessHeap(), 0, index_table ); *table = ret; return NO_ERROR; } /****************************************************************** * GetIfTable2 (IPHLPAPI.@) */ DWORD WINAPI GetIfTable2( MIB_IF_TABLE2 **table ) { TRACE( "table %p\n", table ); return GetIfTable2Ex(MibIfTableNormal, table); } /****************************************************************** * GetInterfaceInfo (IPHLPAPI.@) * * Get a list of network interface adapters. * * PARAMS * pIfTable [Out] buffer for interface adapters * dwOutBufLen [Out] if buffer is too small, returns required size * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * BUGS * MSDN states this should return non-loopback interfaces only. */ DWORD WINAPI GetInterfaceInfo(PIP_INTERFACE_INFO pIfTable, PULONG dwOutBufLen) { DWORD ret; TRACE("pIfTable %p, dwOutBufLen %p\n", pIfTable, dwOutBufLen); if (!dwOutBufLen) ret = ERROR_INVALID_PARAMETER; else { DWORD numInterfaces = get_interface_indices( FALSE, NULL ); ULONG size = sizeof(IP_INTERFACE_INFO); if (numInterfaces > 1) size += (numInterfaces - 1) * sizeof(IP_ADAPTER_INDEX_MAP); if (!pIfTable || *dwOutBufLen < size) { *dwOutBufLen = size; ret = ERROR_INSUFFICIENT_BUFFER; } else { InterfaceIndexTable *table; get_interface_indices( FALSE, &table ); if (table) { size = sizeof(IP_INTERFACE_INFO); if (table->numIndexes > 1) size += (table->numIndexes - 1) * sizeof(IP_ADAPTER_INDEX_MAP); if (*dwOutBufLen < size) { *dwOutBufLen = size; ret = ERROR_INSUFFICIENT_BUFFER; } else { DWORD ndx; char nameBuf[MAX_ADAPTER_NAME]; *dwOutBufLen = size; pIfTable->NumAdapters = 0; for (ndx = 0; ndx < table->numIndexes; ndx++) { const char *walker, *name; WCHAR *assigner; pIfTable->Adapter[ndx].Index = table->indexes[ndx]; name = getInterfaceNameByIndex(table->indexes[ndx], nameBuf); for (walker = name, assigner = pIfTable->Adapter[ndx].Name; walker && *walker && assigner - pIfTable->Adapter[ndx].Name < MAX_ADAPTER_NAME - 1; walker++, assigner++) *assigner = *walker; *assigner = 0; pIfTable->NumAdapters++; } ret = NO_ERROR; } HeapFree(GetProcessHeap(), 0, table); } else ret = ERROR_OUTOFMEMORY; } } TRACE("returning %d\n", ret); return ret; } /****************************************************************** * GetIpAddrTable (IPHLPAPI.@) * * Get interface-to-IP address mapping table. * * PARAMS * pIpAddrTable [Out] buffer for mapping table * pdwSize [In/Out] length of output buffer * bOrder [In] whether to sort the table * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * NOTES * If pdwSize is less than required, the function will return * ERROR_INSUFFICIENT_BUFFER, and *pdwSize will be set to the required byte * size. * If bOrder is true, the returned table will be sorted by the next hop and * an assortment of arbitrary parameters. */ DWORD WINAPI GetIpAddrTable(PMIB_IPADDRTABLE pIpAddrTable, PULONG pdwSize, BOOL bOrder) { DWORD ret; TRACE("pIpAddrTable %p, pdwSize %p, bOrder %d\n", pIpAddrTable, pdwSize, (DWORD)bOrder); if (!pdwSize) ret = ERROR_INVALID_PARAMETER; else { PMIB_IPADDRTABLE table; ret = getIPAddrTable(&table, GetProcessHeap(), 0); if (ret == NO_ERROR) { ULONG size = FIELD_OFFSET(MIB_IPADDRTABLE, table[table->dwNumEntries]); if (!pIpAddrTable || *pdwSize < size) { *pdwSize = size; ret = ERROR_INSUFFICIENT_BUFFER; } else { *pdwSize = size; memcpy(pIpAddrTable, table, size); /* sort by numeric IP value */ if (bOrder) qsort(pIpAddrTable->table, pIpAddrTable->dwNumEntries, sizeof(MIB_IPADDRROW), IpAddrTableNumericSorter); /* sort ensuring loopback interfaces are in the end */ else qsort(pIpAddrTable->table, pIpAddrTable->dwNumEntries, sizeof(MIB_IPADDRROW), IpAddrTableLoopbackSorter); ret = NO_ERROR; } HeapFree(GetProcessHeap(), 0, table); } } TRACE("returning %d\n", ret); return ret; } /****************************************************************** * GetIpForwardTable (IPHLPAPI.@) * * Get the route table. * * PARAMS * pIpForwardTable [Out] buffer for route table * pdwSize [In/Out] length of output buffer * bOrder [In] whether to sort the table * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * NOTES * If pdwSize is less than required, the function will return * ERROR_INSUFFICIENT_BUFFER, and *pdwSize will be set to the required byte * size. * If bOrder is true, the returned table will be sorted by the next hop and * an assortment of arbitrary parameters. */ DWORD WINAPI GetIpForwardTable(PMIB_IPFORWARDTABLE pIpForwardTable, PULONG pdwSize, BOOL bOrder) { DWORD ret; PMIB_IPFORWARDTABLE table; TRACE("pIpForwardTable %p, pdwSize %p, bOrder %d\n", pIpForwardTable, pdwSize, bOrder); if (!pdwSize) return ERROR_INVALID_PARAMETER; ret = AllocateAndGetIpForwardTableFromStack(&table, bOrder, GetProcessHeap(), 0); if (!ret) { DWORD size = FIELD_OFFSET( MIB_IPFORWARDTABLE, table[table->dwNumEntries] ); if (!pIpForwardTable || *pdwSize < size) { *pdwSize = size; ret = ERROR_INSUFFICIENT_BUFFER; } else { *pdwSize = size; memcpy(pIpForwardTable, table, size); } HeapFree(GetProcessHeap(), 0, table); } TRACE("returning %d\n", ret); return ret; } /****************************************************************** * GetIpNetTable (IPHLPAPI.@) * * Get the IP-to-physical address mapping table. * * PARAMS * pIpNetTable [Out] buffer for mapping table * pdwSize [In/Out] length of output buffer * bOrder [In] whether to sort the table * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * NOTES * If pdwSize is less than required, the function will return * ERROR_INSUFFICIENT_BUFFER, and *pdwSize will be set to the required byte * size. * If bOrder is true, the returned table will be sorted by IP address. */ DWORD WINAPI GetIpNetTable(PMIB_IPNETTABLE pIpNetTable, PULONG pdwSize, BOOL bOrder) { DWORD ret; PMIB_IPNETTABLE table; TRACE("pIpNetTable %p, pdwSize %p, bOrder %d\n", pIpNetTable, pdwSize, bOrder); if (!pdwSize) return ERROR_INVALID_PARAMETER; ret = AllocateAndGetIpNetTableFromStack( &table, bOrder, GetProcessHeap(), 0 ); if (!ret) { DWORD size = FIELD_OFFSET( MIB_IPNETTABLE, table[table->dwNumEntries] ); if (!pIpNetTable || *pdwSize < size) { *pdwSize = size; ret = ERROR_INSUFFICIENT_BUFFER; } else { *pdwSize = size; memcpy(pIpNetTable, table, size); } HeapFree(GetProcessHeap(), 0, table); } TRACE("returning %d\n", ret); return ret; } /* Gets the DNS server list into the list beginning at list. Assumes that * a single server address may be placed at list if *len is at least * sizeof(IP_ADDR_STRING) long. Otherwise, list->Next is set to firstDynamic, * and assumes that all remaining DNS servers are contiguously located * beginning at firstDynamic. On input, *len is assumed to be the total number * of bytes available for all DNS servers, and is ignored if list is NULL. * On return, *len is set to the total number of bytes required for all DNS * servers. * Returns ERROR_BUFFER_OVERFLOW if *len is insufficient, * ERROR_SUCCESS otherwise. */ static DWORD get_dns_server_list(PIP_ADDR_STRING list, PIP_ADDR_STRING firstDynamic, DWORD *len) { DWORD size; int num = get_dns_servers( NULL, 0, TRUE ); size = num * sizeof(IP_ADDR_STRING); if (!list || *len < size) { *len = size; return ERROR_BUFFER_OVERFLOW; } *len = size; if (num > 0) { PIP_ADDR_STRING ptr; int i; SOCKADDR_STORAGE *addr = HeapAlloc( GetProcessHeap(), 0, num * sizeof(SOCKADDR_STORAGE) ); get_dns_servers( addr, num, TRUE ); for (i = 0, ptr = list; i < num; i++, ptr = ptr->Next) { RtlIpv4AddressToStringA((IN_ADDR *)&((struct sockaddr_in *)(addr + i))->sin_addr.s_addr, ptr->IpAddress.String); if (i == num - 1) ptr->Next = NULL; else if (i == 0) ptr->Next = firstDynamic; else ptr->Next = (PIP_ADDR_STRING)((PBYTE)ptr + sizeof(IP_ADDR_STRING)); } HeapFree( GetProcessHeap(), 0, addr ); } return ERROR_SUCCESS; } /****************************************************************** * GetNetworkParams (IPHLPAPI.@) * * Get the network parameters for the local computer. * * PARAMS * pFixedInfo [Out] buffer for network parameters * pOutBufLen [In/Out] length of output buffer * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * NOTES * If pOutBufLen is less than required, the function will return * ERROR_INSUFFICIENT_BUFFER, and pOutBufLen will be set to the required byte * size. */ DWORD WINAPI GetNetworkParams(PFIXED_INFO pFixedInfo, PULONG pOutBufLen) { DWORD ret, size, serverListSize; LONG regReturn; HKEY hKey; TRACE("pFixedInfo %p, pOutBufLen %p\n", pFixedInfo, pOutBufLen); if (!pOutBufLen) return ERROR_INVALID_PARAMETER; get_dns_server_list(NULL, NULL, &serverListSize); size = sizeof(FIXED_INFO) + serverListSize - sizeof(IP_ADDR_STRING); if (!pFixedInfo || *pOutBufLen < size) { *pOutBufLen = size; return ERROR_BUFFER_OVERFLOW; } memset(pFixedInfo, 0, size); size = sizeof(pFixedInfo->HostName); GetComputerNameExA(ComputerNameDnsHostname, pFixedInfo->HostName, &size); size = sizeof(pFixedInfo->DomainName); GetComputerNameExA(ComputerNameDnsDomain, pFixedInfo->DomainName, &size); get_dns_server_list(&pFixedInfo->DnsServerList, (PIP_ADDR_STRING)((BYTE *)pFixedInfo + sizeof(FIXED_INFO)), &serverListSize); /* Assume the first DNS server in the list is the "current" DNS server: */ pFixedInfo->CurrentDnsServer = &pFixedInfo->DnsServerList; pFixedInfo->NodeType = HYBRID_NODETYPE; regReturn = RegOpenKeyExA(HKEY_LOCAL_MACHINE, "SYSTEM\\CurrentControlSet\\Services\\VxD\\MSTCP", 0, KEY_READ, &hKey); if (regReturn != ERROR_SUCCESS) regReturn = RegOpenKeyExA(HKEY_LOCAL_MACHINE, "SYSTEM\\CurrentControlSet\\Services\\NetBT\\Parameters", 0, KEY_READ, &hKey); if (regReturn == ERROR_SUCCESS) { DWORD size = sizeof(pFixedInfo->ScopeId); RegQueryValueExA(hKey, "ScopeID", NULL, NULL, (LPBYTE)pFixedInfo->ScopeId, &size); RegCloseKey(hKey); } /* FIXME: can check whether routing's enabled in /proc/sys/net/ipv4/ip_forward I suppose could also check for a listener on port 53 to set EnableDns */ ret = NO_ERROR; TRACE("returning %d\n", ret); return ret; } /****************************************************************** * GetNumberOfInterfaces (IPHLPAPI.@) * * Get the number of interfaces. * * PARAMS * pdwNumIf [Out] number of interfaces * * RETURNS * NO_ERROR on success, ERROR_INVALID_PARAMETER if pdwNumIf is NULL. */ DWORD WINAPI GetNumberOfInterfaces(PDWORD pdwNumIf) { DWORD ret; TRACE("pdwNumIf %p\n", pdwNumIf); if (!pdwNumIf) ret = ERROR_INVALID_PARAMETER; else { *pdwNumIf = get_interface_indices( FALSE, NULL ); ret = NO_ERROR; } TRACE("returning %d\n", ret); return ret; } /****************************************************************** * GetPerAdapterInfo (IPHLPAPI.@) * * Get information about an adapter corresponding to an interface. * * PARAMS * IfIndex [In] interface info * pPerAdapterInfo [Out] buffer for per adapter info * pOutBufLen [In/Out] length of output buffer * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h */ DWORD WINAPI GetPerAdapterInfo(ULONG IfIndex, PIP_PER_ADAPTER_INFO pPerAdapterInfo, PULONG pOutBufLen) { ULONG bytesNeeded = sizeof(IP_PER_ADAPTER_INFO), serverListSize = 0; DWORD ret = NO_ERROR; TRACE("(IfIndex %d, pPerAdapterInfo %p, pOutBufLen %p)\n", IfIndex, pPerAdapterInfo, pOutBufLen); if (!pOutBufLen) return ERROR_INVALID_PARAMETER; if (!isIfIndexLoopback(IfIndex)) { get_dns_server_list(NULL, NULL, &serverListSize); if (serverListSize > sizeof(IP_ADDR_STRING)) bytesNeeded += serverListSize - sizeof(IP_ADDR_STRING); } if (!pPerAdapterInfo || *pOutBufLen < bytesNeeded) { *pOutBufLen = bytesNeeded; return ERROR_BUFFER_OVERFLOW; } memset(pPerAdapterInfo, 0, bytesNeeded); if (!isIfIndexLoopback(IfIndex)) { ret = get_dns_server_list(&pPerAdapterInfo->DnsServerList, (PIP_ADDR_STRING)((PBYTE)pPerAdapterInfo + sizeof(IP_PER_ADAPTER_INFO)), &serverListSize); /* Assume the first DNS server in the list is the "current" DNS server: */ pPerAdapterInfo->CurrentDnsServer = &pPerAdapterInfo->DnsServerList; } return ret; } /****************************************************************** * GetRTTAndHopCount (IPHLPAPI.@) * * Get round-trip time (RTT) and hop count. * * PARAMS * * DestIpAddress [In] destination address to get the info for * HopCount [Out] retrieved hop count * MaxHops [In] maximum hops to search for the destination * RTT [Out] RTT in milliseconds * * RETURNS * Success: TRUE * Failure: FALSE * * FIXME * Stub, returns FALSE. */ BOOL WINAPI GetRTTAndHopCount(IPAddr DestIpAddress, PULONG HopCount, ULONG MaxHops, PULONG RTT) { FIXME("(DestIpAddress 0x%08x, HopCount %p, MaxHops %d, RTT %p): stub\n", DestIpAddress, HopCount, MaxHops, RTT); return FALSE; } /****************************************************************** * GetTcpTable (IPHLPAPI.@) * * Get the table of active TCP connections. * * PARAMS * pTcpTable [Out] buffer for TCP connections table * pdwSize [In/Out] length of output buffer * bOrder [In] whether to order the table * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * NOTES * If pdwSize is less than required, the function will return * ERROR_INSUFFICIENT_BUFFER, and *pdwSize will be set to * the required byte size. * If bOrder is true, the returned table will be sorted, first by * local address and port number, then by remote address and port * number. */ DWORD WINAPI GetTcpTable(PMIB_TCPTABLE pTcpTable, PDWORD pdwSize, BOOL bOrder) { TRACE("pTcpTable %p, pdwSize %p, bOrder %d\n", pTcpTable, pdwSize, bOrder); return GetExtendedTcpTable(pTcpTable, pdwSize, bOrder, WS_AF_INET, TCP_TABLE_BASIC_ALL, 0); } /****************************************************************** * GetExtendedTcpTable (IPHLPAPI.@) */ DWORD WINAPI GetExtendedTcpTable(PVOID pTcpTable, PDWORD pdwSize, BOOL bOrder, ULONG ulAf, TCP_TABLE_CLASS TableClass, ULONG Reserved) { DWORD ret, size; void *table; TRACE("pTcpTable %p, pdwSize %p, bOrder %d, ulAf %u, TableClass %u, Reserved %u\n", pTcpTable, pdwSize, bOrder, ulAf, TableClass, Reserved); if (!pdwSize) return ERROR_INVALID_PARAMETER; if (TableClass >= TCP_TABLE_OWNER_MODULE_LISTENER) FIXME("module classes not fully supported\n"); switch (ulAf) { case WS_AF_INET: ret = build_tcp_table(TableClass, &table, bOrder, GetProcessHeap(), 0, &size); break; case WS_AF_INET6: ret = build_tcp6_table(TableClass, &table, bOrder, GetProcessHeap(), 0, &size); break; default: FIXME("ulAf = %u not supported\n", ulAf); ret = ERROR_NOT_SUPPORTED; } if (ret) return ret; if (!pTcpTable || *pdwSize < size) { *pdwSize = size; ret = ERROR_INSUFFICIENT_BUFFER; } else { *pdwSize = size; memcpy(pTcpTable, table, size); } HeapFree(GetProcessHeap(), 0, table); return ret; } /****************************************************************** * GetUdpTable (IPHLPAPI.@) * * Get a table of active UDP connections. * * PARAMS * pUdpTable [Out] buffer for UDP connections table * pdwSize [In/Out] length of output buffer * bOrder [In] whether to order the table * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * NOTES * If pdwSize is less than required, the function will return * ERROR_INSUFFICIENT_BUFFER, and *pdwSize will be set to the * required byte size. * If bOrder is true, the returned table will be sorted, first by * local address, then by local port number. */ DWORD WINAPI GetUdpTable(PMIB_UDPTABLE pUdpTable, PDWORD pdwSize, BOOL bOrder) { return GetExtendedUdpTable(pUdpTable, pdwSize, bOrder, WS_AF_INET, UDP_TABLE_BASIC, 0); } /****************************************************************** * GetUdp6Table (IPHLPAPI.@) */ DWORD WINAPI GetUdp6Table(PMIB_UDP6TABLE pUdpTable, PDWORD pdwSize, BOOL bOrder) { return GetExtendedUdpTable(pUdpTable, pdwSize, bOrder, WS_AF_INET6, UDP_TABLE_BASIC, 0); } /****************************************************************** * GetExtendedUdpTable (IPHLPAPI.@) */ DWORD WINAPI GetExtendedUdpTable(PVOID pUdpTable, PDWORD pdwSize, BOOL bOrder, ULONG ulAf, UDP_TABLE_CLASS TableClass, ULONG Reserved) { DWORD ret, size; void *table; TRACE("pUdpTable %p, pdwSize %p, bOrder %d, ulAf %u, TableClass %u, Reserved %u\n", pUdpTable, pdwSize, bOrder, ulAf, TableClass, Reserved); if (!pdwSize) return ERROR_INVALID_PARAMETER; if (TableClass == UDP_TABLE_OWNER_MODULE) FIXME("UDP_TABLE_OWNER_MODULE not fully supported\n"); switch (ulAf) { case WS_AF_INET: ret = build_udp_table(TableClass, &table, bOrder, GetProcessHeap(), 0, &size); break; case WS_AF_INET6: ret = build_udp6_table(TableClass, &table, bOrder, GetProcessHeap(), 0, &size); break; default: FIXME("ulAf = %u not supported\n", ulAf); ret = ERROR_NOT_SUPPORTED; } if (ret) return ret; if (!pUdpTable || *pdwSize < size) { *pdwSize = size; ret = ERROR_INSUFFICIENT_BUFFER; } else { *pdwSize = size; memcpy(pUdpTable, table, size); } HeapFree(GetProcessHeap(), 0, table); return ret; } DWORD WINAPI GetUnicastIpAddressEntry(MIB_UNICASTIPADDRESS_ROW *row) { IP_ADAPTER_ADDRESSES *aa, *ptr; ULONG size = 0; DWORD ret; TRACE("%p\n", row); if (!row) return ERROR_INVALID_PARAMETER; ret = GetAdaptersAddresses(row->Address.si_family, 0, NULL, NULL, &size); if (ret != ERROR_BUFFER_OVERFLOW) return ret; if (!(ptr = HeapAlloc(GetProcessHeap(), 0, size))) return ERROR_OUTOFMEMORY; if ((ret = GetAdaptersAddresses(row->Address.si_family, 0, NULL, ptr, &size))) { HeapFree(GetProcessHeap(), 0, ptr); return ret; } ret = ERROR_FILE_NOT_FOUND; for (aa = ptr; aa; aa = aa->Next) { IP_ADAPTER_UNICAST_ADDRESS *ua; if (aa->u.s.IfIndex != row->InterfaceIndex && memcmp(&aa->Luid, &row->InterfaceLuid, sizeof(row->InterfaceLuid))) continue; ret = ERROR_NOT_FOUND; ua = aa->FirstUnicastAddress; while (ua) { SOCKADDR_INET *uaaddr = (SOCKADDR_INET *)ua->Address.lpSockaddr; if ((row->Address.si_family == WS_AF_INET6 && !memcmp(&row->Address.Ipv6.sin6_addr, &uaaddr->Ipv6.sin6_addr, sizeof(uaaddr->Ipv6.sin6_addr))) || (row->Address.si_family == WS_AF_INET && row->Address.Ipv4.sin_addr.S_un.S_addr == uaaddr->Ipv4.sin_addr.S_un.S_addr)) { memcpy(&row->InterfaceLuid, &aa->Luid, sizeof(aa->Luid)); row->InterfaceIndex = aa->u.s.IfIndex; row->PrefixOrigin = ua->PrefixOrigin; row->SuffixOrigin = ua->SuffixOrigin; row->ValidLifetime = ua->ValidLifetime; row->PreferredLifetime = ua->PreferredLifetime; row->OnLinkPrefixLength = ua->OnLinkPrefixLength; row->SkipAsSource = 0; row->DadState = ua->DadState; if (row->Address.si_family == WS_AF_INET6) row->ScopeId.u.Value = row->Address.Ipv6.sin6_scope_id; else row->ScopeId.u.Value = 0; NtQuerySystemTime(&row->CreationTimeStamp); HeapFree(GetProcessHeap(), 0, ptr); return NO_ERROR; } ua = ua->Next; } } HeapFree(GetProcessHeap(), 0, ptr); return ret; } DWORD WINAPI GetUnicastIpAddressTable(ADDRESS_FAMILY family, MIB_UNICASTIPADDRESS_TABLE **table) { IP_ADAPTER_ADDRESSES *aa, *ptr; MIB_UNICASTIPADDRESS_TABLE *data; DWORD ret, count = 0; ULONG size, flags; TRACE("%u, %p\n", family, table); if (!table || (family != WS_AF_INET && family != WS_AF_INET6 && family != WS_AF_UNSPEC)) return ERROR_INVALID_PARAMETER; flags = GAA_FLAG_SKIP_ANYCAST | GAA_FLAG_SKIP_MULTICAST | GAA_FLAG_SKIP_DNS_SERVER | GAA_FLAG_SKIP_FRIENDLY_NAME; ret = GetAdaptersAddresses(family, flags, NULL, NULL, &size); if (ret != ERROR_BUFFER_OVERFLOW) return ret; if (!(ptr = HeapAlloc(GetProcessHeap(), 0, size))) return ERROR_OUTOFMEMORY; if ((ret = GetAdaptersAddresses(family, flags, NULL, ptr, &size))) { HeapFree(GetProcessHeap(), 0, ptr); return ret; } for (aa = ptr; aa; aa = aa->Next) { IP_ADAPTER_UNICAST_ADDRESS *ua = aa->FirstUnicastAddress; while (ua) { count++; ua = ua->Next; } } if (!(data = HeapAlloc(GetProcessHeap(), 0, sizeof(*data) + (count - 1) * sizeof(data->Table[0])))) { HeapFree(GetProcessHeap(), 0, ptr); return ERROR_OUTOFMEMORY; } data->NumEntries = 0; for (aa = ptr; aa; aa = aa->Next) { IP_ADAPTER_UNICAST_ADDRESS *ua = aa->FirstUnicastAddress; while (ua) { MIB_UNICASTIPADDRESS_ROW *row = &data->Table[data->NumEntries]; memcpy(&row->Address, ua->Address.lpSockaddr, ua->Address.iSockaddrLength); memcpy(&row->InterfaceLuid, &aa->Luid, sizeof(aa->Luid)); row->InterfaceIndex = aa->u.s.IfIndex; row->PrefixOrigin = ua->PrefixOrigin; row->SuffixOrigin = ua->SuffixOrigin; row->ValidLifetime = ua->ValidLifetime; row->PreferredLifetime = ua->PreferredLifetime; row->OnLinkPrefixLength = ua->OnLinkPrefixLength; row->SkipAsSource = 0; row->DadState = ua->DadState; if (row->Address.si_family == WS_AF_INET6) row->ScopeId.u.Value = row->Address.Ipv6.sin6_scope_id; else row->ScopeId.u.Value = 0; NtQuerySystemTime(&row->CreationTimeStamp); data->NumEntries++; ua = ua->Next; } } HeapFree(GetProcessHeap(), 0, ptr); *table = data; return ret; } /****************************************************************** * GetUniDirectionalAdapterInfo (IPHLPAPI.@) * * This is a Win98-only function to get information on "unidirectional" * adapters. Since this is pretty nonsensical in other contexts, it * never returns anything. * * PARAMS * pIPIfInfo [Out] buffer for adapter infos * dwOutBufLen [Out] length of the output buffer * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI GetUniDirectionalAdapterInfo(PIP_UNIDIRECTIONAL_ADAPTER_ADDRESS pIPIfInfo, PULONG dwOutBufLen) { TRACE("pIPIfInfo %p, dwOutBufLen %p\n", pIPIfInfo, dwOutBufLen); /* a unidirectional adapter?? not bloody likely! */ return ERROR_NOT_SUPPORTED; } /****************************************************************** * IpReleaseAddress (IPHLPAPI.@) * * Release an IP obtained through DHCP, * * PARAMS * AdapterInfo [In] adapter to release IP address * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * NOTES * Since GetAdaptersInfo never returns adapters that have DHCP enabled, * this function does nothing. * * FIXME * Stub, returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI IpReleaseAddress(PIP_ADAPTER_INDEX_MAP AdapterInfo) { FIXME("Stub AdapterInfo %p\n", AdapterInfo); return ERROR_NOT_SUPPORTED; } /****************************************************************** * IpRenewAddress (IPHLPAPI.@) * * Renew an IP obtained through DHCP. * * PARAMS * AdapterInfo [In] adapter to renew IP address * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * NOTES * Since GetAdaptersInfo never returns adapters that have DHCP enabled, * this function does nothing. * * FIXME * Stub, returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI IpRenewAddress(PIP_ADAPTER_INDEX_MAP AdapterInfo) { FIXME("Stub AdapterInfo %p\n", AdapterInfo); return ERROR_NOT_SUPPORTED; } /****************************************************************** * NotifyAddrChange (IPHLPAPI.@) * * Notify caller whenever the ip-interface map is changed. * * PARAMS * Handle [Out] handle usable in asynchronous notification * overlapped [In] overlapped structure that notifies the caller * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI NotifyAddrChange(PHANDLE Handle, LPOVERLAPPED overlapped) { FIXME("(Handle %p, overlapped %p): stub\n", Handle, overlapped); if (Handle) *Handle = INVALID_HANDLE_VALUE; if (overlapped) ((IO_STATUS_BLOCK *) overlapped)->u.Status = STATUS_PENDING; return ERROR_IO_PENDING; } /****************************************************************** * NotifyIpInterfaceChange (IPHLPAPI.@) */ DWORD WINAPI NotifyIpInterfaceChange(ADDRESS_FAMILY family, PIPINTERFACE_CHANGE_CALLBACK callback, PVOID context, BOOLEAN init_notify, PHANDLE handle) { FIXME("(family %d, callback %p, context %p, init_notify %d, handle %p): stub\n", family, callback, context, init_notify, handle); if (handle) *handle = NULL; return NO_ERROR; } /****************************************************************** * NotifyRouteChange2 (IPHLPAPI.@) */ DWORD WINAPI NotifyRouteChange2(ADDRESS_FAMILY family, PIPFORWARD_CHANGE_CALLBACK callback, VOID* context, BOOLEAN init_notify, HANDLE* handle) { FIXME("(family %d, callback %p, context %p, init_notify %d, handle %p): stub\n", family, callback, context, init_notify, handle); if (handle) *handle = NULL; return NO_ERROR; } /****************************************************************** * NotifyRouteChange (IPHLPAPI.@) * * Notify caller whenever the ip routing table is changed. * * PARAMS * Handle [Out] handle usable in asynchronous notification * overlapped [In] overlapped structure that notifies the caller * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI NotifyRouteChange(PHANDLE Handle, LPOVERLAPPED overlapped) { FIXME("(Handle %p, overlapped %p): stub\n", Handle, overlapped); return ERROR_NOT_SUPPORTED; } /****************************************************************** * NotifyUnicastIpAddressChange (IPHLPAPI.@) */ DWORD WINAPI NotifyUnicastIpAddressChange(ADDRESS_FAMILY family, PUNICAST_IPADDRESS_CHANGE_CALLBACK callback, PVOID context, BOOLEAN init_notify, PHANDLE handle) { FIXME("(family %d, callback %p, context %p, init_notify %d, handle %p): semi-stub\n", family, callback, context, init_notify, handle); if (handle) *handle = NULL; if (init_notify) callback(context, NULL, MibInitialNotification); return NO_ERROR; } /****************************************************************** * SendARP (IPHLPAPI.@) * * Send an ARP request. * * PARAMS * DestIP [In] attempt to obtain this IP * SrcIP [In] optional sender IP address * pMacAddr [Out] buffer for the mac address * PhyAddrLen [In/Out] length of the output buffer * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI SendARP(IPAddr DestIP, IPAddr SrcIP, PULONG pMacAddr, PULONG PhyAddrLen) { FIXME("(DestIP 0x%08x, SrcIP 0x%08x, pMacAddr %p, PhyAddrLen %p): stub\n", DestIP, SrcIP, pMacAddr, PhyAddrLen); return ERROR_NOT_SUPPORTED; } /****************************************************************** * SetIfEntry (IPHLPAPI.@) * * Set the administrative status of an interface. * * PARAMS * pIfRow [In] dwAdminStatus member specifies the new status. * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI SetIfEntry(PMIB_IFROW pIfRow) { FIXME("(pIfRow %p): stub\n", pIfRow); /* this is supposed to set an interface administratively up or down. Could do SIOCSIFFLAGS and set/clear IFF_UP, but, not sure I want to, and this sort of down is indistinguishable from other sorts of down (e.g. no link). */ return ERROR_NOT_SUPPORTED; } /****************************************************************** * SetIpForwardEntry (IPHLPAPI.@) * * Modify an existing route. * * PARAMS * pRoute [In] route with the new information * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns NO_ERROR. */ DWORD WINAPI SetIpForwardEntry(PMIB_IPFORWARDROW pRoute) { FIXME("(pRoute %p): stub\n", pRoute); /* this is to add a route entry, how's it distinguishable from CreateIpForwardEntry? could use SIOCADDRT, not sure I want to */ return 0; } /****************************************************************** * SetIpNetEntry (IPHLPAPI.@) * * Modify an existing ARP entry. * * PARAMS * pArpEntry [In] ARP entry with the new information * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns NO_ERROR. */ DWORD WINAPI SetIpNetEntry(PMIB_IPNETROW pArpEntry) { FIXME("(pArpEntry %p): stub\n", pArpEntry); /* same as CreateIpNetEntry here, could use SIOCSARP, not sure I want to */ return 0; } /****************************************************************** * SetIpStatistics (IPHLPAPI.@) * * Toggle IP forwarding and det the default TTL value. * * PARAMS * pIpStats [In] IP statistics with the new information * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns NO_ERROR. */ DWORD WINAPI SetIpStatistics(PMIB_IPSTATS pIpStats) { FIXME("(pIpStats %p): stub\n", pIpStats); return 0; } /****************************************************************** * SetIpTTL (IPHLPAPI.@) * * Set the default TTL value. * * PARAMS * nTTL [In] new TTL value * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns NO_ERROR. */ DWORD WINAPI SetIpTTL(UINT nTTL) { FIXME("(nTTL %d): stub\n", nTTL); /* could echo nTTL > /proc/net/sys/net/ipv4/ip_default_ttl, not sure I want to. Could map EACCESS to ERROR_ACCESS_DENIED, I suppose */ return 0; } /****************************************************************** * SetTcpEntry (IPHLPAPI.@) * * Set the state of a TCP connection. * * PARAMS * pTcpRow [In] specifies connection with new state * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns NO_ERROR. */ DWORD WINAPI SetTcpEntry(PMIB_TCPROW pTcpRow) { FIXME("(pTcpRow %p): stub\n", pTcpRow); return 0; } /****************************************************************** * SetPerTcpConnectionEStats (IPHLPAPI.@) */ DWORD WINAPI SetPerTcpConnectionEStats(PMIB_TCPROW row, TCP_ESTATS_TYPE state, PBYTE rw, ULONG version, ULONG size, ULONG offset) { FIXME("(row %p, state %d, rw %p, version %u, size %u, offset %u): stub\n", row, state, rw, version, size, offset); return ERROR_NOT_SUPPORTED; } /****************************************************************** * UnenableRouter (IPHLPAPI.@) * * Decrement the IP-forwarding reference count. Turn off IP-forwarding * if it reaches zero. * * PARAMS * pOverlapped [In/Out] should be the same as in EnableRouter() * lpdwEnableCount [Out] optional, receives reference count * * RETURNS * Success: NO_ERROR * Failure: error code from winerror.h * * FIXME * Stub, returns ERROR_NOT_SUPPORTED. */ DWORD WINAPI UnenableRouter(OVERLAPPED * pOverlapped, LPDWORD lpdwEnableCount) { FIXME("(pOverlapped %p, lpdwEnableCount %p): stub\n", pOverlapped, lpdwEnableCount); /* could echo "0" > /proc/net/sys/net/ipv4/ip_forward, not sure I want to could map EACCESS to ERROR_ACCESS_DENIED, I suppose */ return ERROR_NOT_SUPPORTED; } /****************************************************************** * PfCreateInterface (IPHLPAPI.@) */ DWORD WINAPI PfCreateInterface(DWORD dwName, PFFORWARD_ACTION inAction, PFFORWARD_ACTION outAction, BOOL bUseLog, BOOL bMustBeUnique, INTERFACE_HANDLE *ppInterface) { FIXME("(%d %d %d %x %x %p) stub\n", dwName, inAction, outAction, bUseLog, bMustBeUnique, ppInterface); return ERROR_CALL_NOT_IMPLEMENTED; } /****************************************************************** * PfUnBindInterface (IPHLPAPI.@) */ DWORD WINAPI PfUnBindInterface(INTERFACE_HANDLE interface) { FIXME("(%p) stub\n", interface); return ERROR_CALL_NOT_IMPLEMENTED; } /****************************************************************** * PfDeleteInterface(IPHLPAPI.@) */ DWORD WINAPI PfDeleteInterface(INTERFACE_HANDLE interface) { FIXME("(%p) stub\n", interface); return ERROR_CALL_NOT_IMPLEMENTED; } /****************************************************************** * PfBindInterfaceToIPAddress(IPHLPAPI.@) */ DWORD WINAPI PfBindInterfaceToIPAddress(INTERFACE_HANDLE interface, PFADDRESSTYPE type, PBYTE ip) { FIXME("(%p %d %p) stub\n", interface, type, ip); return ERROR_CALL_NOT_IMPLEMENTED; } /****************************************************************** * GetTcpTable2 (IPHLPAPI.@) */ ULONG WINAPI GetTcpTable2(PMIB_TCPTABLE2 table, PULONG size, BOOL order) { FIXME("pTcpTable2 %p, pdwSize %p, bOrder %d: stub\n", table, size, order); return ERROR_NOT_SUPPORTED; } /****************************************************************** * GetTcp6Table (IPHLPAPI.@) */ ULONG WINAPI GetTcp6Table(PMIB_TCP6TABLE table, PULONG size, BOOL order) { TRACE("(table %p, size %p, order %d)\n", table, size, order); return GetExtendedTcpTable(table, size, order, WS_AF_INET6, TCP_TABLE_BASIC_ALL, 0); } /****************************************************************** * GetTcp6Table2 (IPHLPAPI.@) */ ULONG WINAPI GetTcp6Table2(PMIB_TCP6TABLE2 table, PULONG size, BOOL order) { FIXME("pTcp6Table2 %p, size %p, order %d: stub\n", table, size, order); return ERROR_NOT_SUPPORTED; } /****************************************************************** * ConvertInterfaceGuidToLuid (IPHLPAPI.@) */ DWORD WINAPI ConvertInterfaceGuidToLuid(const GUID *guid, NET_LUID *luid) { DWORD ret; MIB_IFROW row; TRACE("(%s %p)\n", debugstr_guid(guid), luid); if (!guid || !luid) return ERROR_INVALID_PARAMETER; row.dwIndex = guid->Data1; if ((ret = GetIfEntry( &row ))) return ret; luid->Info.Reserved = 0; luid->Info.NetLuidIndex = guid->Data1; luid->Info.IfType = row.dwType; return NO_ERROR; } /****************************************************************** * ConvertInterfaceIndexToLuid (IPHLPAPI.@) */ DWORD WINAPI ConvertInterfaceIndexToLuid(NET_IFINDEX index, NET_LUID *luid) { MIB_IFROW row; TRACE("(%u %p)\n", index, luid); if (!luid) return ERROR_INVALID_PARAMETER; memset( luid, 0, sizeof(*luid) ); row.dwIndex = index; if (GetIfEntry( &row )) return ERROR_FILE_NOT_FOUND; luid->Info.Reserved = 0; luid->Info.NetLuidIndex = index; luid->Info.IfType = row.dwType; return NO_ERROR; } /****************************************************************** * ConvertInterfaceLuidToGuid (IPHLPAPI.@) */ DWORD WINAPI ConvertInterfaceLuidToGuid(const NET_LUID *luid, GUID *guid) { DWORD ret; MIB_IFROW row; TRACE("(%p %p)\n", luid, guid); if (!luid || !guid) return ERROR_INVALID_PARAMETER; row.dwIndex = luid->Info.NetLuidIndex; if ((ret = GetIfEntry( &row ))) return ret; memset( guid, 0, sizeof(*guid) ); guid->Data1 = luid->Info.NetLuidIndex; memcpy( guid->Data4+2, "NetDev", 6 ); return NO_ERROR; } /****************************************************************** * ConvertInterfaceLuidToIndex (IPHLPAPI.@) */ DWORD WINAPI ConvertInterfaceLuidToIndex(const NET_LUID *luid, NET_IFINDEX *index) { DWORD ret; MIB_IFROW row; TRACE("(%p %p)\n", luid, index); if (!luid || !index) return ERROR_INVALID_PARAMETER; row.dwIndex = luid->Info.NetLuidIndex; if ((ret = GetIfEntry( &row ))) return ret; *index = luid->Info.NetLuidIndex; return NO_ERROR; } /****************************************************************** * ConvertInterfaceLuidToNameA (IPHLPAPI.@) */ DWORD WINAPI ConvertInterfaceLuidToNameA(const NET_LUID *luid, char *name, SIZE_T len) { DWORD ret; MIB_IFROW row; TRACE("(%p %p %u)\n", luid, name, (DWORD)len); if (!luid) return ERROR_INVALID_PARAMETER; row.dwIndex = luid->Info.NetLuidIndex; if ((ret = GetIfEntry( &row ))) return ret; if (!name || len < WideCharToMultiByte( CP_UNIXCP, 0, row.wszName, -1, NULL, 0, NULL, NULL )) return ERROR_NOT_ENOUGH_MEMORY; WideCharToMultiByte( CP_UNIXCP, 0, row.wszName, -1, name, len, NULL, NULL ); return NO_ERROR; } /****************************************************************** * ConvertInterfaceLuidToNameW (IPHLPAPI.@) */ DWORD WINAPI ConvertInterfaceLuidToNameW(const NET_LUID *luid, WCHAR *name, SIZE_T len) { DWORD ret; MIB_IFROW row; TRACE("(%p %p %u)\n", luid, name, (DWORD)len); if (!luid || !name) return ERROR_INVALID_PARAMETER; row.dwIndex = luid->Info.NetLuidIndex; if ((ret = GetIfEntry( &row ))) return ret; if (len < strlenW( row.wszName ) + 1) return ERROR_NOT_ENOUGH_MEMORY; strcpyW( name, row.wszName ); return NO_ERROR; } /****************************************************************** * ConvertInterfaceNameToLuidA (IPHLPAPI.@) */ DWORD WINAPI ConvertInterfaceNameToLuidA(const char *name, NET_LUID *luid) { DWORD ret; IF_INDEX index; MIB_IFROW row; TRACE("(%s %p)\n", debugstr_a(name), luid); if ((ret = getInterfaceIndexByName( name, &index ))) return ERROR_INVALID_NAME; if (!luid) return ERROR_INVALID_PARAMETER; row.dwIndex = index; if ((ret = GetIfEntry( &row ))) return ret; luid->Info.Reserved = 0; luid->Info.NetLuidIndex = index; luid->Info.IfType = row.dwType; return NO_ERROR; } /****************************************************************** * ConvertInterfaceNameToLuidW (IPHLPAPI.@) */ DWORD WINAPI ConvertInterfaceNameToLuidW(const WCHAR *name, NET_LUID *luid) { DWORD ret; IF_INDEX index; MIB_IFROW row; char nameA[IF_MAX_STRING_SIZE + 1]; TRACE("(%s %p)\n", debugstr_w(name), luid); if (!luid) return ERROR_INVALID_PARAMETER; memset( luid, 0, sizeof(*luid) ); if (!WideCharToMultiByte( CP_UNIXCP, 0, name, -1, nameA, sizeof(nameA), NULL, NULL )) return ERROR_INVALID_NAME; if ((ret = getInterfaceIndexByName( nameA, &index ))) return ret; row.dwIndex = index; if ((ret = GetIfEntry( &row ))) return ret; luid->Info.Reserved = 0; luid->Info.NetLuidIndex = index; luid->Info.IfType = row.dwType; return NO_ERROR; } /****************************************************************** * ConvertLengthToIpv4Mask (IPHLPAPI.@) */ DWORD WINAPI ConvertLengthToIpv4Mask(ULONG mask_len, ULONG *mask) { if (mask_len > 32) { *mask = INADDR_NONE; return ERROR_INVALID_PARAMETER; } if (mask_len == 0) *mask = 0; else *mask = htonl(~0u << (32 - mask_len)); return NO_ERROR; } /****************************************************************** * if_nametoindex (IPHLPAPI.@) */ IF_INDEX WINAPI IPHLP_if_nametoindex(const char *name) { IF_INDEX idx; TRACE("(%s)\n", name); if (getInterfaceIndexByName(name, &idx) == NO_ERROR) return idx; return 0; } /****************************************************************** * if_indextoname (IPHLPAPI.@) */ PCHAR WINAPI IPHLP_if_indextoname(NET_IFINDEX index, PCHAR name) { TRACE("(%u, %p)\n", index, name); return getInterfaceNameByIndex(index, name); } /****************************************************************** * GetIpForwardTable2 (IPHLPAPI.@) */ DWORD WINAPI GetIpForwardTable2(ADDRESS_FAMILY family, PMIB_IPFORWARD_TABLE2 *table) { static int once; if (!once++) FIXME("(%u %p): stub\n", family, table); return ERROR_NOT_SUPPORTED; } /****************************************************************** * GetIpNetTable2 (IPHLPAPI.@) */ DWORD WINAPI GetIpNetTable2(ADDRESS_FAMILY family, PMIB_IPNET_TABLE2 *table) { static int once; if (!once++) FIXME("(%u %p): stub\n", family, table); return ERROR_NOT_SUPPORTED; } /****************************************************************** * GetIpInterfaceTable (IPHLPAPI.@) */ DWORD WINAPI GetIpInterfaceTable(ADDRESS_FAMILY family, PMIB_IPINTERFACE_TABLE *table) { FIXME("(%u %p): stub\n", family, table); return ERROR_NOT_SUPPORTED; } /****************************************************************** * GetBestRoute2 (IPHLPAPI.@) */ DWORD WINAPI GetBestRoute2(NET_LUID *luid, NET_IFINDEX index, const SOCKADDR_INET *source, const SOCKADDR_INET *destination, ULONG options, PMIB_IPFORWARD_ROW2 bestroute, SOCKADDR_INET *bestaddress) { static int once; if (!once++) FIXME("(%p, %d, %p, %p, 0x%08x, %p, %p): stub\n", luid, index, source, destination, options, bestroute, bestaddress); if (!destination || !bestroute || !bestaddress) return ERROR_INVALID_PARAMETER; return ERROR_NOT_SUPPORTED; } /****************************************************************** * ParseNetworkString (IPHLPAPI.@) */ DWORD WINAPI ParseNetworkString(const WCHAR *str, DWORD type, NET_ADDRESS_INFO *info, USHORT *port, BYTE *prefix_len) { IN_ADDR temp_addr4; IN6_ADDR temp_addr6; ULONG temp_scope; USHORT temp_port = 0; NTSTATUS status; TRACE("(%s, %d, %p, %p, %p)\n", debugstr_w(str), type, info, port, prefix_len); if (!str) return ERROR_INVALID_PARAMETER; if (type & NET_STRING_IPV4_ADDRESS) { status = RtlIpv4StringToAddressExW(str, TRUE, &temp_addr4, &temp_port); if (SUCCEEDED(status) && !temp_port) { if (info) { info->Format = NET_ADDRESS_IPV4; info->u.Ipv4Address.sin_addr = temp_addr4; info->u.Ipv4Address.sin_port = 0; } if (port) *port = 0; if (prefix_len) *prefix_len = 255; return ERROR_SUCCESS; } } if (type & NET_STRING_IPV4_SERVICE) { status = RtlIpv4StringToAddressExW(str, TRUE, &temp_addr4, &temp_port); if (SUCCEEDED(status) && temp_port) { if (info) { info->Format = NET_ADDRESS_IPV4; info->u.Ipv4Address.sin_addr = temp_addr4; info->u.Ipv4Address.sin_port = temp_port; } if (port) *port = ntohs(temp_port); if (prefix_len) *prefix_len = 255; return ERROR_SUCCESS; } } if (type & NET_STRING_IPV6_ADDRESS) { status = RtlIpv6StringToAddressExW(str, &temp_addr6, &temp_scope, &temp_port); if (SUCCEEDED(status) && !temp_port) { if (info) { info->Format = NET_ADDRESS_IPV6; info->u.Ipv6Address.sin6_addr = temp_addr6; info->u.Ipv6Address.sin6_scope_id = temp_scope; info->u.Ipv6Address.sin6_port = 0; } if (port) *port = 0; if (prefix_len) *prefix_len = 255; return ERROR_SUCCESS; } } if (type & NET_STRING_IPV6_SERVICE) { status = RtlIpv6StringToAddressExW(str, &temp_addr6, &temp_scope, &temp_port); if (SUCCEEDED(status) && temp_port) { if (info) { info->Format = NET_ADDRESS_IPV6; info->u.Ipv6Address.sin6_addr = temp_addr6; info->u.Ipv6Address.sin6_scope_id = temp_scope; info->u.Ipv6Address.sin6_port = temp_port; } if (port) *port = ntohs(temp_port); if (prefix_len) *prefix_len = 255; return ERROR_SUCCESS; } } if (info) info->Format = NET_ADDRESS_FORMAT_UNSPECIFIED; if (type & ~(NET_STRING_IPV4_ADDRESS|NET_STRING_IPV4_SERVICE|NET_STRING_IPV6_ADDRESS|NET_STRING_IPV6_SERVICE)) { FIXME("Unimplemented type 0x%x\n", type); return ERROR_NOT_SUPPORTED; } return ERROR_INVALID_PARAMETER; }