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SoftEtherVPN/src/Cedar/VLanWin32.c
2014-07-12 02:06:20 +09:00

1618 lines
38 KiB
C

// SoftEther VPN Source Code
// Cedar Communication Module
//
// SoftEther VPN Server, Client and Bridge are free software under GPLv2.
//
// Copyright (c) 2012-2014 Daiyuu Nobori.
// Copyright (c) 2012-2014 SoftEther VPN Project, University of Tsukuba, Japan.
// Copyright (c) 2012-2014 SoftEther Corporation.
//
// All Rights Reserved.
//
// http://www.softether.org/
//
// Author: Daiyuu Nobori
// Comments: Tetsuo Sugiyama, Ph.D.
//
// This program is free software; you can redistribute it and/or
// modify it under the terms of the GNU General Public License
// version 2 as published by the Free Software Foundation.
//
// This program 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 General Public License for more details.
//
// You should have received a copy of the GNU General Public License version 2
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
// EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
// MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
// IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
// CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
// TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
// SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
//
// THE LICENSE AGREEMENT IS ATTACHED ON THE SOURCE-CODE PACKAGE
// AS "LICENSE.TXT" FILE. READ THE TEXT FILE IN ADVANCE TO USE THE SOFTWARE.
//
//
// THIS SOFTWARE IS DEVELOPED IN JAPAN, AND DISTRIBUTED FROM JAPAN,
// UNDER JAPANESE LAWS. YOU MUST AGREE IN ADVANCE TO USE, COPY, MODIFY,
// MERGE, PUBLISH, DISTRIBUTE, SUBLICENSE, AND/OR SELL COPIES OF THIS
// SOFTWARE, THAT ANY JURIDICAL DISPUTES WHICH ARE CONCERNED TO THIS
// SOFTWARE OR ITS CONTENTS, AGAINST US (SOFTETHER PROJECT, SOFTETHER
// CORPORATION, DAIYUU NOBORI OR OTHER SUPPLIERS), OR ANY JURIDICAL
// DISPUTES AGAINST US WHICH ARE CAUSED BY ANY KIND OF USING, COPYING,
// MODIFYING, MERGING, PUBLISHING, DISTRIBUTING, SUBLICENSING, AND/OR
// SELLING COPIES OF THIS SOFTWARE SHALL BE REGARDED AS BE CONSTRUED AND
// CONTROLLED BY JAPANESE LAWS, AND YOU MUST FURTHER CONSENT TO
// EXCLUSIVE JURISDICTION AND VENUE IN THE COURTS SITTING IN TOKYO,
// JAPAN. YOU MUST WAIVE ALL DEFENSES OF LACK OF PERSONAL JURISDICTION
// AND FORUM NON CONVENIENS. PROCESS MAY BE SERVED ON EITHER PARTY IN
// THE MANNER AUTHORIZED BY APPLICABLE LAW OR COURT RULE.
//
// USE ONLY IN JAPAN. DO NOT USE THIS SOFTWARE IN ANOTHER COUNTRY UNLESS
// YOU HAVE A CONFIRMATION THAT THIS SOFTWARE DOES NOT VIOLATE ANY
// CRIMINAL LAWS OR CIVIL RIGHTS IN THAT PARTICULAR COUNTRY. USING THIS
// SOFTWARE IN OTHER COUNTRIES IS COMPLETELY AT YOUR OWN RISK. THE
// SOFTETHER VPN PROJECT HAS DEVELOPED AND DISTRIBUTED THIS SOFTWARE TO
// COMPLY ONLY WITH THE JAPANESE LAWS AND EXISTING CIVIL RIGHTS INCLUDING
// PATENTS WHICH ARE SUBJECTS APPLY IN JAPAN. OTHER COUNTRIES' LAWS OR
// CIVIL RIGHTS ARE NONE OF OUR CONCERNS NOR RESPONSIBILITIES. WE HAVE
// NEVER INVESTIGATED ANY CRIMINAL REGULATIONS, CIVIL LAWS OR
// INTELLECTUAL PROPERTY RIGHTS INCLUDING PATENTS IN ANY OF OTHER 200+
// COUNTRIES AND TERRITORIES. BY NATURE, THERE ARE 200+ REGIONS IN THE
// WORLD, WITH DIFFERENT LAWS. IT IS IMPOSSIBLE TO VERIFY EVERY
// COUNTRIES' LAWS, REGULATIONS AND CIVIL RIGHTS TO MAKE THE SOFTWARE
// COMPLY WITH ALL COUNTRIES' LAWS BY THE PROJECT. EVEN IF YOU WILL BE
// SUED BY A PRIVATE ENTITY OR BE DAMAGED BY A PUBLIC SERVANT IN YOUR
// COUNTRY, THE DEVELOPERS OF THIS SOFTWARE WILL NEVER BE LIABLE TO
// RECOVER OR COMPENSATE SUCH DAMAGES, CRIMINAL OR CIVIL
// RESPONSIBILITIES. NOTE THAT THIS LINE IS NOT LICENSE RESTRICTION BUT
// JUST A STATEMENT FOR WARNING AND DISCLAIMER.
//
//
// SOURCE CODE CONTRIBUTION
// ------------------------
//
// Your contribution to SoftEther VPN Project is much appreciated.
// Please send patches to us through GitHub.
// Read the SoftEther VPN Patch Acceptance Policy in advance:
// http://www.softether.org/5-download/src/9.patch
//
//
// DEAR SECURITY EXPERTS
// ---------------------
//
// If you find a bug or a security vulnerability please kindly inform us
// about the problem immediately so that we can fix the security problem
// to protect a lot of users around the world as soon as possible.
//
// Our e-mail address for security reports is:
// softether-vpn-security [at] softether.org
//
// Please note that the above e-mail address is not a technical support
// inquiry address. If you need technical assistance, please visit
// http://www.softether.org/ and ask your question on the users forum.
//
// Thank you for your cooperation.
//
//
// NO MEMORY OR RESOURCE LEAKS
// ---------------------------
//
// The memory-leaks and resource-leaks verification under the stress
// test has been passed before release this source code.
// VLanWin32.c
// Virtual device driver library for Win32
#include <GlobalConst.h>
#ifdef VLAN_C
#include <windows.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <wchar.h>
#include <stdarg.h>
#include <time.h>
#include <errno.h>
#include <Mayaqua/Mayaqua.h>
#include <Cedar/Cedar.h>
#ifdef OS_WIN32
typedef DWORD(CALLBACK* OPENVXDHANDLE)(HANDLE);
// Get the version information of Windows
void Win32GetWinVer(RPC_WINVER *v)
{
// Validate arguments
if (v == NULL)
{
return;
}
Zero(v, sizeof(RPC_WINVER));
v->IsWindows = true;
if (OS_IS_WINDOWS_NT(GetOsType()) == false)
{
// Windows 9x
OSVERSIONINFO os;
Zero(&os, sizeof(os));
os.dwOSVersionInfoSize = sizeof(os);
GetVersionEx(&os);
v->Build = LOWORD(os.dwBuildNumber);
v->VerMajor = os.dwMajorVersion;
v->VerMinor = os.dwMinorVersion;
Format(v->Title, sizeof(v->Title), "%s %s",
GetOsInfo()->OsProductName,
GetOsInfo()->OsVersion);
Trim(v->Title);
}
else
{
// Windows NT 4.0 SP6 or later
OSVERSIONINFOEX os;
Zero(&os, sizeof(os));
os.dwOSVersionInfoSize = sizeof(os);
Win32GetVersionExInternal((LPOSVERSIONINFOA)&os);
v->IsNT = true;
v->Build = os.dwBuildNumber;
v->ServicePack = os.wServicePackMajor;
if (os.wProductType != VER_NT_WORKSTATION)
{
v->IsServer = true;
}
v->VerMajor = os.dwMajorVersion;
v->VerMinor = os.dwMinorVersion;
if (GetOsInfo()->OsServicePack == 0)
{
StrCpy(v->Title, sizeof(v->Title), GetOsInfo()->OsProductName);
}
else
{
Format(v->Title, sizeof(v->Title), "%s Service Pack %u",
GetOsInfo()->OsProductName,
GetOsInfo()->OsServicePack);
}
Trim(v->Title);
if (InStr(GetOsInfo()->OsVersion, "rc") ||
InStr(GetOsInfo()->OsVersion, "beta"))
{
v->IsBeta = true;
}
}
}
// Release the DHCP addresses of all virtual LAN cards
void Win32ReleaseAllDhcp9x(bool wait)
{
TOKEN_LIST *t;
UINT i;
t = MsEnumNetworkAdapters(VLAN_ADAPTER_NAME, VLAN_ADAPTER_NAME_OLD);
if (t == NULL)
{
return;
}
for (i = 0;i < t->NumTokens;i++)
{
char *name = t->Token[i];
UINT id = GetInstanceId(name);
if (id != 0)
{
Win32ReleaseDhcp9x(id, wait);
}
}
FreeToken(t);
}
// Routing table tracking main
void RouteTrackingMain(SESSION *s)
{
ROUTE_TRACKING *t;
UINT64 now;
ROUTE_TABLE *table;
ROUTE_ENTRY *rs;
bool changed = false;
bool check = false;
bool any_modified = false;
// Validate arguments
if (s == NULL)
{
return;
}
if (s->ClientModeAndUseVLan == false)
{
return;
}
// Get the state
t = ((VLAN *)s->PacketAdapter->Param)->RouteState;
if (t == NULL)
{
return;
}
// Current time
PROBE_STR("RouteTrackingMain 1");
now = Tick64();
if (t->RouteChange != NULL)
{
if (t->NextRouteChangeCheckTime == 0 ||
t->NextRouteChangeCheckTime <= now)
{
t->NextRouteChangeCheckTime = now + 1000ULL;
check = IsRouteChanged(t->RouteChange);
if (check)
{
Debug("*** Routing Table Changed ***\n");
t->NextTrackingTime = 0;
}
}
}
if (t->NextTrackingTime != 0 && t->NextTrackingTime > now)
{
if (s->UseUdpAcceleration && s->UdpAccel != NULL && s->UdpAccel->NatT_IP_Changed)
{
// Check always if the IP address of the NAT-T server has changed
}
else
{
PROBE_STR("RouteTrackingMain 2");
return;
}
}
PROBE_STR("RouteTrackingMain 3");
if (s->UseUdpAcceleration && s->UdpAccel != NULL)
{
IP nat_t_ip;
s->UdpAccel->NatT_IP_Changed = false;
Zero(&nat_t_ip, sizeof(nat_t_ip));
Lock(s->UdpAccel->NatT_Lock);
{
Copy(&nat_t_ip, &s->UdpAccel->NatT_IP, sizeof(IP));
}
Unlock(s->UdpAccel->NatT_Lock);
// Add a route to the NAT-T server
if (IsZeroIp(&nat_t_ip) == false)
{
if (t->RouteToNatTServer == NULL)
{
if (t->RouteToEight != NULL)
{
ROUTE_ENTRY *e = Clone(t->RouteToEight, sizeof(ROUTE_ENTRY));
char ip_str[64];
char ip_str2[64];
Copy(&e->DestIP, &nat_t_ip, sizeof(IP));
e->Metric = e->OldIfMetric;
IPToStr(ip_str, sizeof(ip_str), &e->DestIP);
IPToStr(ip_str2, sizeof(ip_str2), &e->GatewayIP);
t->RouteToNatTServer = e;
if (AddRouteEntry(t->RouteToNatTServer))
{
Debug("Adding Static Route to %s via %s metric %u: ok.\n", ip_str, ip_str2, e->Metric);
}
else
{
FreeRouteEntry(t->RouteToNatTServer);
t->RouteToNatTServer = NULL;
}
}
}
}
}
// Get the current routing table
table = GetRouteTable();
rs = t->RouteToServer;
if (table != NULL)
{
UINT i;
bool route_to_server_erased = true;
bool is_vlan_want_to_be_default_gateway = false;
UINT vlan_default_gatewat_metric = 0;
UINT other_if_default_gateway_metric_min = INFINITE;
// Get whether the routing table have been changed
if (t->LastRoutingTableHash != table->HashedValue)
{
t->LastRoutingTableHash = table->HashedValue;
changed = true;
}
//DebugPrintRouteTable(table);
// Scan the routing table
for (i = 0;i < table->NumEntry;i++)
{
ROUTE_ENTRY *e = table->Entry[i];
if (rs != NULL)
{
if (CmpIpAddr(&e->DestIP, &rs->DestIP) == 0 &&
CmpIpAddr(&e->DestMask, &rs->DestMask) == 0
// && CmpIpAddr(&e->GatewayIP, &rs->GatewayIP) == 0
// && e->InterfaceID == rs->InterfaceID &&
// e->LocalRouting == rs->LocalRouting &&
// e->Metric == rs->Metric
)
{
// Routing entry to the server that added at the time of connection is found
route_to_server_erased = false;
}
}
// Search for the default gateway
if (IPToUINT(&e->DestIP) == 0 &&
IPToUINT(&e->DestMask) == 0)
{
Debug("e->InterfaceID = %u, t->VLanInterfaceId = %u\n",
e->InterfaceID, t->VLanInterfaceId);
if (e->InterfaceID == t->VLanInterfaceId)
{
// The virtual LAN card think that he want to be a default gateway
is_vlan_want_to_be_default_gateway = true;
vlan_default_gatewat_metric = e->Metric;
if (vlan_default_gatewat_metric >= 2 &&
t->OldDefaultGatewayMetric == (vlan_default_gatewat_metric - 1))
{
// Restore because the PPP server rewrites
// the routing table selfishly
DeleteRouteEntry(e);
e->Metric--;
AddRouteEntry(e);
Debug("** Restore metric destroyed by PPP.\n");
any_modified = true;
}
// Keep this entry
if (t->DefaultGatewayByVLan != NULL)
{
// Delete if there is one added last time
FreeRouteEntry(t->DefaultGatewayByVLan);
}
t->DefaultGatewayByVLan = ZeroMalloc(sizeof(ROUTE_ENTRY));
Copy(t->DefaultGatewayByVLan, e, sizeof(ROUTE_ENTRY));
t->OldDefaultGatewayMetric = vlan_default_gatewat_metric;
}
else
{
// There are default gateway other than the virtual LAN card
// Save the metric value of the default gateway
if (other_if_default_gateway_metric_min > e->Metric)
{
// Ignore the metric value of all PPP connection in the case of Windows Vista
if (MsIsVista() == false || e->PPPConnection == false)
{
other_if_default_gateway_metric_min = e->Metric;
}
else
{
// a PPP is used to Connect to the network
// in using Windows Vista
t->VistaAndUsingPPP = true;
}
}
}
}
}
if (t->VistaAndUsingPPP)
{
if (t->DefaultGatewayByVLan != NULL)
{
if (is_vlan_want_to_be_default_gateway)
{
if (t->VistaOldDefaultGatewayByVLan == NULL || Cmp(t->VistaOldDefaultGatewayByVLan, t->DefaultGatewayByVLan, sizeof(ROUTE_ENTRY)) != 0)
{
ROUTE_ENTRY *e;
// Add the route of 0.0.0.0/1 and 128.0.0.0/1
// to the system if the virtual LAN card should be
// the default gateway in the case of the connection
// using PPP in Windows Vista
if (t->VistaOldDefaultGatewayByVLan != NULL)
{
FreeRouteEntry(t->VistaOldDefaultGatewayByVLan);
}
if (t->VistaDefaultGateway1 != NULL)
{
DeleteRouteEntry(t->VistaDefaultGateway1);
FreeRouteEntry(t->VistaDefaultGateway1);
DeleteRouteEntry(t->VistaDefaultGateway2);
FreeRouteEntry(t->VistaDefaultGateway2);
}
t->VistaOldDefaultGatewayByVLan = Clone(t->DefaultGatewayByVLan, sizeof(ROUTE_ENTRY));
e = Clone(t->DefaultGatewayByVLan, sizeof(ROUTE_ENTRY));
SetIP(&e->DestIP, 0, 0, 0, 0);
SetIP(&e->DestMask, 128, 0, 0, 0);
t->VistaDefaultGateway1 = e;
e = Clone(t->DefaultGatewayByVLan, sizeof(ROUTE_ENTRY));
SetIP(&e->DestIP, 128, 0, 0, 0);
SetIP(&e->DestMask, 128, 0, 0, 0);
t->VistaDefaultGateway2 = e;
AddRouteEntry(t->VistaDefaultGateway1);
AddRouteEntry(t->VistaDefaultGateway2);
Debug("Vista PPP Fix Route Table Added.\n");
any_modified = true;
}
}
else
{
if (t->VistaOldDefaultGatewayByVLan != NULL)
{
FreeRouteEntry(t->VistaOldDefaultGatewayByVLan);
t->VistaOldDefaultGatewayByVLan = NULL;
}
if (t->VistaDefaultGateway1 != NULL)
{
Debug("Vista PPP Fix Route Table Deleted.\n");
DeleteRouteEntry(t->VistaDefaultGateway1);
FreeRouteEntry(t->VistaDefaultGateway1);
DeleteRouteEntry(t->VistaDefaultGateway2);
FreeRouteEntry(t->VistaDefaultGateway2);
any_modified = true;
t->VistaDefaultGateway1 = t->VistaDefaultGateway2 = NULL;
}
}
}
}
// If the virtual LAN card want to be the default gateway and
// there is no LAN card with smaller metric of 0.0.0.0/0 than
// the virtual LAN card, delete other default gateway entries
// to elect the virtual LAN card as the default gateway
// Debug("is_vlan_want_to_be_default_gateway = %u, rs = %u, route_to_server_erased = %u, other_if_default_gateway_metric_min = %u, vlan_default_gatewat_metric = %u\n",
// is_vlan_want_to_be_default_gateway, rs, route_to_server_erased, other_if_default_gateway_metric_min, vlan_default_gatewat_metric);
if (is_vlan_want_to_be_default_gateway && (rs != NULL && route_to_server_erased == false) &&
other_if_default_gateway_metric_min >= vlan_default_gatewat_metric)
{
// Scan the routing table again
for (i = 0;i < table->NumEntry;i++)
{
ROUTE_ENTRY *e = table->Entry[i];
if (e->InterfaceID != t->VLanInterfaceId)
{
if (IPToUINT(&e->DestIP) == 0 &&
IPToUINT(&e->DestMask) == 0)
{
char str[64];
// Default gateway is found
ROUTE_ENTRY *r = ZeroMalloc(sizeof(ROUTE_ENTRY));
Copy(r, e, sizeof(ROUTE_ENTRY));
// Put in the queue
InsertQueue(t->DeletedDefaultGateway, r);
// Delete this gateway entry once
DeleteRouteEntry(e);
IPToStr(str, sizeof(str), &e->GatewayIP);
Debug("Default Gateway %s Deleted.\n", str);
any_modified = true;
}
}
}
}
if (rs != NULL && route_to_server_erased)
{
// Physical entry to the server has disappeared
Debug("Route to Server entry ERASED !!!\n");
// Forced disconnection (reconnection enabled)
s->RetryFlag = true;
s->Halt = true;
}
// Release the routing table
FreeRouteTable(table);
}
// Set the time to perform the next track
if (t->NextTrackingTimeAdd == 0 || changed)
{
t->NextTrackingTimeAdd = TRACKING_INTERVAL_INITIAL;
}
else
{
UINT64 max_value = TRACKING_INTERVAL_MAX;
if (t->RouteChange != NULL)
{
max_value = TRACKING_INTERVAL_MAX_RC;
}
t->NextTrackingTimeAdd += TRACKING_INTERVAL_ADD;
if (t->NextTrackingTimeAdd >= max_value)
{
t->NextTrackingTimeAdd = max_value;
}
}
//Debug("t->NextTrackingTimeAdd = %I64u\n", t->NextTrackingTimeAdd);
t->NextTrackingTime = now + t->NextTrackingTimeAdd;
if (any_modified)
{
// Clear the DNS cache
Win32FlushDnsCache();
}
}
// Start tracking of the routing table
void RouteTrackingStart(SESSION *s)
{
VLAN *v;
ROUTE_TRACKING *t;
UINT if_id = 0;
ROUTE_ENTRY *e;
ROUTE_ENTRY *dns = NULL;
ROUTE_ENTRY *route_to_real_server_global = NULL;
char tmp[64];
UINT exclude_if_id = 0;
bool already_exists = false;
bool already_exists_by_other_account = false;
IP eight;
// Validate arguments
if (s == NULL)
{
return;
}
v = (VLAN *)s->PacketAdapter->Param;
if (v->RouteState != NULL)
{
return;
}
// Get the interface ID of the virtual LAN card
if_id = GetInstanceId(v->InstanceName);
Debug("[InstanceId of %s] = 0x%x\n", v->InstanceName, if_id);
if (MsIsVista())
{
// The routing table by the virtual LAN card body should be
// excluded explicitly in Windows Vista
exclude_if_id = if_id;
}
// Get the route to the server
e = GetBestRouteEntryEx(&s->ServerIP, exclude_if_id);
if (e == NULL)
{
// Acquisition failure
Debug("Failed to get GetBestRouteEntry().\n");
return;
}
IPToStr(tmp, sizeof(tmp), &e->GatewayIP);
Debug("GetBestRouteEntry() Succeed. [Gateway: %s]\n", tmp);
// Add a route
if (MsIsVista())
{
e->Metric = e->OldIfMetric;
}
if (AddRouteEntryEx(e, &already_exists) == false)
{
FreeRouteEntry(e);
e = NULL;
}
Debug("already_exists: %u\n", already_exists);
if (already_exists)
{
if (s->Cedar->Client != NULL && s->Account != NULL)
{
UINT i;
ACCOUNT *a;
for (i = 0;i < LIST_NUM(s->Cedar->Client->AccountList);i++)
{
a = LIST_DATA(s->Cedar->Client->AccountList, i);
Lock(a->lock);
{
SESSION *sess = a->ClientSession;
if (sess != NULL && sess != s)
{
VLAN *v = sess->PacketAdapter->Param;
if (v != NULL)
{
ROUTE_TRACKING *tr = v->RouteState;
if (tr != NULL && e != NULL)
{
if (Cmp(tr->RouteToServer, e, sizeof(ROUTE_ENTRY)) == 0)
{
already_exists_by_other_account = true;
}
}
}
}
}
Unlock(a->lock);
}
}
if (already_exists_by_other_account)
{
Debug("already_exists_by_other_account = %u\n", already_exists_by_other_account);
already_exists = false;
}
}
// Get the routing table to the DNS server
// (If the DNS server is this PC itself, there's no need to get)
if (IsZeroIP(&s->DefaultDns) == false)
{
if (IsMyIPAddress(&s->DefaultDns) == false)
{
dns = GetBestRouteEntryEx(&s->DefaultDns, exclude_if_id);
if (dns == NULL)
{
// Getting failure
Debug("Failed to get GetBestRouteEntry DNS.\n");
}
else
{
// Add a route
if (MsIsVista())
{
dns->Metric = dns->OldIfMetric;
if (AddRouteEntry(dns) == false)
{
FreeRouteEntry(dns);
dns = NULL;
}
}
}
}
}
if (s->IsAzureSession && IsZeroIP(&s->AzureRealServerGlobalIp) == false)
{
// Add also a static route to the real server in the case of via VPN Azure
if (IsMyIPAddress(&s->AzureRealServerGlobalIp) == false)
{
route_to_real_server_global = GetBestRouteEntryEx(&s->AzureRealServerGlobalIp, exclude_if_id);
if (route_to_real_server_global != NULL)
{
if (MsIsVista())
{
route_to_real_server_global->Metric = route_to_real_server_global->OldIfMetric;
}
if (AddRouteEntry(route_to_real_server_global) == false)
{
FreeRouteEntry(route_to_real_server_global);
route_to_real_server_global = NULL;
}
}
}
}
// Initialize
if (s->Cedar->Client != NULL && s->Account != NULL)
{
Lock(s->Account->lock);
}
t = ZeroMalloc(sizeof(ROUTE_TRACKING));
v->RouteState = t;
t->RouteToServerAlreadyExists = already_exists;
t->RouteToServer = e;
t->RouteToDefaultDns = dns;
t->RouteToRealServerGlobal = route_to_real_server_global;
t->VLanInterfaceId = if_id;
t->NextTrackingTime = 0;
t->DeletedDefaultGateway = NewQueue();
t->OldDefaultGatewayMetric = 0x7fffffff;
if (s->Cedar->Client != NULL && s->Account != NULL)
{
Unlock(s->Account->lock);
}
// Get the route to 8.8.8.8
SetIP(&eight, 8, 8, 8, 8);
t->RouteToEight = GetBestRouteEntryEx(&eight, exclude_if_id);
// Get the current default DNS server to detect network changes
GetDefaultDns(&t->OldDnsServer);
// Get as soon as releasing the IP address in the case of using DHCP
if (IsNt())
{
char tmp[MAX_SIZE];
MS_ADAPTER *a;
Format(tmp, sizeof(tmp), VLAN_ADAPTER_NAME_TAG, v->InstanceName);
a = MsGetAdapter(tmp);
if (a != NULL)
{
if (a->UseDhcp)
{
bool ret = Win32ReleaseAddressByGuidEx(a->Guid, 100);
Debug("*** Win32ReleaseAddressByGuidEx = %u\n", ret);
ret = Win32RenewAddressByGuidEx(a->Guid, 100);
Debug("*** Win32RenewAddressByGuidEx = %u\n", ret);
}
MsFreeAdapter(a);
}
}
else
{
// For Win9x
Win32RenewDhcp9x(if_id);
}
// Clear the DNS cache
Win32FlushDnsCache();
// Detect a change in the routing table (for only supported OS)
t->RouteChange = NewRouteChange();
Debug("t->RouteChange = 0x%p\n", t->RouteChange);
}
// End the tracking of the routing table
void RouteTrackingStop(SESSION *s, ROUTE_TRACKING *t)
{
ROUTE_ENTRY *e;
ROUTE_TABLE *table;
IP dns_ip;
bool network_has_changed = false;
bool do_not_delete_routing_entry = false;
// Validate arguments
if (s == NULL || t == NULL)
{
return;
}
Zero(&dns_ip, sizeof(dns_ip));
// Remove the default gateway added by the virtual LAN card
if (MsIsVista() == false)
{
if (t->DefaultGatewayByVLan != NULL)
{
Debug("Default Gateway by VLAN was deleted.\n");
DeleteRouteEntry(t->DefaultGatewayByVLan);
}
if (t->VistaOldDefaultGatewayByVLan != NULL)
{
FreeRouteEntry(t->VistaOldDefaultGatewayByVLan);
}
}
if (t->DefaultGatewayByVLan != NULL)
{
FreeRouteEntry(t->DefaultGatewayByVLan);
t->DefaultGatewayByVLan = NULL;
}
if (t->VistaDefaultGateway1 != NULL)
{
Debug("Vista PPP Fix Route Table Deleted.\n");
DeleteRouteEntry(t->VistaDefaultGateway1);
FreeRouteEntry(t->VistaDefaultGateway1);
DeleteRouteEntry(t->VistaDefaultGateway2);
FreeRouteEntry(t->VistaDefaultGateway2);
}
if (MsIsNt() == false)
{
// Only in the case of Windows 9x, release the DHCP address of the virtual LAN card
Win32ReleaseDhcp9x(t->VLanInterfaceId, false);
}
// Clear the DNS cache
Win32FlushDnsCache();
if (s->Cedar->Client != NULL && s->Account != NULL)
{
UINT i;
ACCOUNT *a;
for (i = 0;i < LIST_NUM(s->Cedar->Client->AccountList);i++)
{
a = LIST_DATA(s->Cedar->Client->AccountList, i);
Lock(a->lock);
{
SESSION *sess = a->ClientSession;
if (sess != NULL && sess != s)
{
VLAN *v = sess->PacketAdapter->Param;
if (v != NULL)
{
ROUTE_TRACKING *tr = v->RouteState;
if (tr != NULL)
{
if (Cmp(tr->RouteToServer, t->RouteToServer, sizeof(ROUTE_ENTRY)) == 0)
{
do_not_delete_routing_entry = true;
}
}
}
}
}
Unlock(a->lock);
}
Lock(s->Account->lock);
}
if (do_not_delete_routing_entry == false)
{
// Delete the route that is added firstly
if (t->RouteToServerAlreadyExists == false)
{
DeleteRouteEntry(t->RouteToServer);
}
DeleteRouteEntry(t->RouteToDefaultDns);
DeleteRouteEntry(t->RouteToNatTServer);
DeleteRouteEntry(t->RouteToRealServerGlobal);
}
FreeRouteEntry(t->RouteToDefaultDns);
FreeRouteEntry(t->RouteToServer);
FreeRouteEntry(t->RouteToEight);
FreeRouteEntry(t->RouteToNatTServer);
FreeRouteEntry(t->RouteToRealServerGlobal);
t->RouteToDefaultDns = t->RouteToServer = t->RouteToEight =
t->RouteToNatTServer = t->RouteToRealServerGlobal = NULL;
if (s->Cedar->Client != NULL && s->Account != NULL)
{
Unlock(s->Account->lock);
}
#if 0
// Get the current DNS server
if (GetDefaultDns(&dns_ip))
{
if (IPToUINT(&t->OldDnsServer) != 0)
{
if (IPToUINT(&t->OldDnsServer) != IPToUINT(&dns_ip))
{
char s1[MAX_SIZE], s2[MAX_SIZE];
network_has_changed = true;
IPToStr(s1, sizeof(s1), &t->OldDnsServer);
IPToStr(s2, sizeof(s2), &dns_ip);
Debug("Old Dns: %s, New Dns: %s\n",
s1, s2);
}
}
}
if (network_has_changed == false)
{
Debug("Network: not changed.\n");
}
else
{
Debug("Network: Changed.\n");
}
#endif
// Get the current routing table
table = GetRouteTable();
// Restore the routing table which has been removed so far
while (e = GetNext(t->DeletedDefaultGateway))
{
bool restore = true;
UINT i;
// If the restoring routing entry is a default gateway and
// the existing routing table contains another default gateway
// on the interface, give up restoring the entry
if (IPToUINT(&e->DestIP) == 0 && IPToUINT(&e->DestMask) == 0)
{
for (i = 0;i < table->NumEntry;i++)
{
ROUTE_ENTRY *r = table->Entry[i];
if (IPToUINT(&r->DestIP) == 0 && IPToUINT(&r->DestMask) == 0)
{
if (r->InterfaceID == e->InterfaceID)
{
restore = false;
}
}
}
if (network_has_changed)
{
restore = false;
}
}
if (restore)
{
// Routing table restoration
AddRouteEntry(e);
}
// Memory release
FreeRouteEntry(e);
}
// Release
FreeRouteTable(table);
ReleaseQueue(t->DeletedDefaultGateway);
FreeRouteChange(t->RouteChange);
Free(t);
}
// Get the instance ID of the virtual LAN card
UINT GetInstanceId(char *name)
{
char tmp[MAX_SIZE];
UINT id = 0;
// Validate arguments
if (name == NULL)
{
return 0;
}
Format(tmp, sizeof(tmp), VLAN_ADAPTER_NAME_TAG, name);
id = GetVLanInterfaceID(tmp);
if (id != 0)
{
return id;
}
else
{
Format(tmp, sizeof(tmp), VLAN_ADAPTER_NAME_TAG_OLD, name);
id = GetVLanInterfaceID(tmp);
return id;
}
}
// Get the instance list of virtual LAN card
INSTANCE_LIST *GetInstanceList()
{
INSTANCE_LIST *n = ZeroMalloc(sizeof(INSTANCE_LIST));
// Enumeration
char **ss = EnumVLan(VLAN_ADAPTER_NAME);
if (ss == NULL)
{
// Failure
n->NumInstance = 0;
n->InstanceName = Malloc(0);
return n;
}
else
{
UINT i, num;
i = num = 0;
while (true)
{
if (ss[i++] == NULL)
{
break;
}
num++;
}
i = 0;
n->NumInstance = num;
n->InstanceName = (char **)ZeroMalloc(sizeof(char *) * n->NumInstance);
for (i = 0;i < num;i++)
{
char *s = ss[i] + StrLen(VLAN_ADAPTER_NAME) + StrLen(" - ");
if (StrLen(ss[i]) > StrLen(VLAN_ADAPTER_NAME) + StrLen(" - "))
{
n->InstanceName[i] = CopyStr(s);
}
}
FreeEnumVLan(ss);
}
ss = EnumVLan(VLAN_ADAPTER_NAME_OLD);
if (ss != NULL)
{
UINT i, num, j;
i = num = 0;
while (true)
{
if (ss[i++] == NULL)
{
break;
}
num++;
}
j = n->NumInstance;
n->NumInstance += num;
n->InstanceName = (char **)ReAlloc(n->InstanceName, sizeof(char) * n->NumInstance);
for (i = 0;i < num;i++)
{
char *s = ss[i] + StrLen(VLAN_ADAPTER_NAME_OLD) + StrLen(" - ");
if (StrLen(ss[i]) > StrLen(VLAN_ADAPTER_NAME_OLD) + StrLen(" - "))
{
n->InstanceName[j] = CopyStr(s);
}
j++;
}
FreeEnumVLan(ss);
}
return n;
}
// Release the instance list
void FreeInstanceList(INSTANCE_LIST *n)
{
UINT i;
// Validate arguments
if (n == NULL)
{
return;
}
for (i = 0;i < n->NumInstance;i++)
{
Free(n->InstanceName[i]);
}
Free(n->InstanceName);
Free(n);
}
// Release the packet adapter
void VLanPaFree(SESSION *s)
{
VLAN *v;
ROUTE_TRACKING *t;
// Validate arguments
if ((s == NULL) || ((v = s->PacketAdapter->Param) == NULL))
{
return;
}
// Release the IP address if you are using DHCP
if (IsNt())
{
char tmp[MAX_SIZE];
MS_ADAPTER *a;
Format(tmp, sizeof(tmp), VLAN_ADAPTER_NAME_TAG, v->InstanceName);
a = MsGetAdapter(tmp);
if (a != NULL)
{
if (a->UseDhcp)
{
bool ret = Win32ReleaseAddressByGuidEx(a->Guid, 50);
Debug("*** Win32ReleaseAddressByGuid = %u\n", ret);
}
MsFreeAdapter(a);
}
}
t = v->RouteState;
// End the virtual LAN card
FreeVLan(v);
// End the routing table tracking
if (s->ClientModeAndUseVLan)
{
RouteTrackingStop(s, t);
}
s->PacketAdapter->Param = NULL;
}
// Write a packet
bool VLanPaPutPacket(SESSION *s, void *data, UINT size)
{
VLAN *v;
// Validate arguments
if ((s == NULL) || ((v = s->PacketAdapter->Param) == NULL))
{
return false;
}
return VLanPutPacket(v, data, size);
}
// Get the next packet
UINT VLanPaGetNextPacket(SESSION *s, void **data)
{
VLAN *v;
UINT size;
// Validate arguments
if (data == NULL || (s == NULL) || ((v = s->PacketAdapter->Param) == NULL))
{
return 0;
}
RouteTrackingMain(s);
if (VLanGetNextPacket(v, data, &size) == false)
{
return INFINITE;
}
return size;
}
// Get the cancel object
CANCEL *VLanPaGetCancel(SESSION *s)
{
VLAN *v;
// Validate arguments
if ((s == NULL) || ((v = s->PacketAdapter->Param) == NULL))
{
return NULL;
}
return VLanGetCancel(v);
}
// Initialize the packet adapter
bool VLanPaInit(SESSION *s)
{
VLAN *v;
// Validate arguments
if ((s == NULL)/* || (s->ServerMode != false) || (s->ClientOption == NULL)*/)
{
return false;
}
// Get the IP address of the DNS server at the time just before the connection
if (s->ClientModeAndUseVLan)
{
Zero(&s->DefaultDns, sizeof(IP));
GetDefaultDns(&s->DefaultDns);
}
// Normalize the setting of interface metric of the default gateway
if (s->ClientModeAndUseVLan)
{
if (MsIsVista())
{
MsNormalizeInterfaceDefaultGatewaySettings(VLAN_ADAPTER_NAME_TAG, s->ClientOption->DeviceName);
MsNormalizeInterfaceDefaultGatewaySettings(VLAN_ADAPTER_NAME_TAG_OLD, s->ClientOption->DeviceName);
}
}
// Connect to the driver
v = NewVLan(s->ClientOption->DeviceName, NULL);
if (v == NULL)
{
// Failure
return false;
}
s->PacketAdapter->Param = v;
// Routing table tracking start
if (s->ClientModeAndUseVLan)
{
RouteTrackingStart(s);
}
return true;
}
// Get the packet adapter of the VLAN
PACKET_ADAPTER *VLanGetPacketAdapter()
{
PACKET_ADAPTER *pa;
pa = NewPacketAdapter(VLanPaInit, VLanPaGetCancel,
VLanPaGetNextPacket, VLanPaPutPacket, VLanPaFree);
if (pa == NULL)
{
return NULL;
}
return pa;
}
// Write the next received packet to the driver
bool VLanPutPacket(VLAN *v, void *buf, UINT size)
{
// Validate arguments
if (v == NULL)
{
return false;
}
if (v->Halt)
{
return false;
}
if (size > MAX_PACKET_SIZE)
{
return false;
}
// First, examine whether the current buffer is full
if ((NEO_NUM_PACKET(v->PutBuffer) >= NEO_MAX_PACKET_EXCHANGE) ||
(buf == NULL && NEO_NUM_PACKET(v->PutBuffer) != 0))
{
#ifdef USE_PROBE
{
char tmp[MAX_SIZE];
snprintf(tmp, sizeof(tmp), "VLanPutPacket: NEO_NUM_PACKET(v->PutBuffer) = %u", NEO_NUM_PACKET(v->PutBuffer));
PROBE_DATA2(tmp, NULL, 0);
}
#endif // USE_PROBE
// Write a packet to the driver
if (VLanPutPacketsToDriver(v) == false)
{
return false;
}
NEO_NUM_PACKET(v->PutBuffer) = 0;
}
// Add the next packet to the buffer
if (buf != NULL)
{
UINT i = NEO_NUM_PACKET(v->PutBuffer);
NEO_NUM_PACKET(v->PutBuffer)++;
NEO_SIZE_OF_PACKET(v->PutBuffer, i) = size;
Copy(NEO_ADDR_OF_PACKET(v->PutBuffer, i), buf, size);
Free(buf);
}
return true;
}
// Read the next sent packet from the driver
bool VLanGetNextPacket(VLAN *v, void **buf, UINT *size)
{
// Validate arguments
if (v == NULL || buf == NULL || size == NULL)
{
return false;
}
if (v->Halt)
{
return false;
}
PROBE_STR("VLanGetNextPacket");
while (true)
{
if (v->CurrentPacketCount < NEO_NUM_PACKET(v->GetBuffer))
{
// There are still packets that have been read already
*size = NEO_SIZE_OF_PACKET(v->GetBuffer, v->CurrentPacketCount);
*buf = MallocFast(*size);
Copy(*buf, NEO_ADDR_OF_PACKET(v->GetBuffer, v->CurrentPacketCount), *size);
// Increment the packet number
v->CurrentPacketCount++;
return true;
}
else
{
// Read the next packet from the driver
if (VLanGetPacketsFromDriver(v) == false)
{
return false;
}
if (NEO_NUM_PACKET(v->GetBuffer) == 0)
{
// Packet is not received currently
*buf = NULL;
*size = 0;
return true;
}
v->CurrentPacketCount = 0;
}
}
}
// Write all the current packets to the driver
bool VLanPutPacketsToDriver(VLAN *v)
{
DWORD write_size;
// Validate arguments
if (v == NULL)
{
return false;
}
if (v->Halt)
{
return false;
}
if (v->Win9xMode == false)
{
// Windows NT
PROBE_STR("VLanPutPacketsToDriver: WriteFile");
if (WriteFile(v->Handle, v->PutBuffer, NEO_EXCHANGE_BUFFER_SIZE, &write_size,
NULL) == false)
{
v->Halt = true;
return false;
}
PROBE_STR("VLanPutPacketsToDriver: WriteFile Completed.");
if (write_size != NEO_EXCHANGE_BUFFER_SIZE)
{
v->Halt = true;
return false;
}
}
else
{
// Windows 9x
if (DeviceIoControl(v->Handle, NEO_IOCTL_PUT_PACKET, v->PutBuffer,
NEO_EXCHANGE_BUFFER_SIZE, NULL, 0, &write_size, NULL) == false)
{
v->Halt = true;
return false;
}
}
return true;
}
// Read the next packet from the driver
bool VLanGetPacketsFromDriver(VLAN *v)
{
DWORD read_size;
// Validate arguments
if (v == NULL)
{
return false;
}
if (v->Halt)
{
return false;
}
if (v->Win9xMode == false)
{
// Windows NT
PROBE_STR("VLanGetPacketsFromDriver: ReadFile");
if (ReadFile(v->Handle, v->GetBuffer, NEO_EXCHANGE_BUFFER_SIZE,
&read_size, NULL) == false)
{
v->Halt = true;
return false;
}
}
else
{
// Windows 9x
if (DeviceIoControl(v->Handle, NEO_IOCTL_GET_PACKET, NULL, 0,
v->GetBuffer, NEO_EXCHANGE_BUFFER_SIZE, &read_size, NULL) == false)
{
v->Halt = true;
return false;
}
}
if (read_size != NEO_EXCHANGE_BUFFER_SIZE)
{
v->Halt = true;
return false;
}
return true;
}
// Get the cancel object
CANCEL *VLanGetCancel(VLAN *v)
{
CANCEL *c;
// Validate arguments
if (v == NULL)
{
return NULL;
}
// Create a cancel object
c = NewCancel();
c->SpecialFlag = true;
CloseHandle(c->hEvent);
c->hEvent = v->Event;
return c;
}
// Release the VLAN object
void FreeVLan(VLAN *v)
{
// Validate arguments
if (v == NULL)
{
return;
}
// Close the handle
CloseHandle(v->Event);
CloseHandle(v->Handle);
// Memory release
Free(v->InstanceName);
Free(v->EventNameWin32);
Free(v->DeviceNameWin32);
Free(v->PutBuffer);
Free(v->GetBuffer);
Free(v);
}
// Create a VLAN object
VLAN *NewVLan(char *instance_name, VLAN_PARAM *param)
{
VLAN *v;
HANDLE h = INVALID_HANDLE_VALUE;
HANDLE e = INVALID_HANDLE_VALUE;
char tmp[MAX_SIZE];
char name_upper[MAX_SIZE];
// Validate arguments
if (instance_name == NULL)
{
return NULL;
}
v = ZeroMalloc(sizeof(VLAN));
if (OS_IS_WINDOWS_9X(GetOsInfo()->OsType))
{
v->Win9xMode = true;
}
// Initialize the name
Format(name_upper, sizeof(name_upper), "%s", instance_name);
StrUpper(name_upper);
v->InstanceName = CopyStr(name_upper);
Format(tmp, sizeof(tmp), NDIS_NEO_DEVICE_FILE_NAME, v->InstanceName);
v->DeviceNameWin32 = CopyStr(tmp);
if (v->Win9xMode == false)
{
Format(tmp, sizeof(tmp), NDIS_NEO_EVENT_NAME_WIN32, v->InstanceName);
v->EventNameWin32 = CopyStr(tmp);
}
// Connect to the device
h = CreateFile(v->DeviceNameWin32,
GENERIC_READ | GENERIC_WRITE,
0,
NULL,
OPEN_EXISTING,
0,
NULL);
if (h == INVALID_HANDLE_VALUE)
{
// Connection failure
goto CLEANUP;
}
if (v->Win9xMode == false)
{
// Connect to the event
e = OpenEvent(SYNCHRONIZE, FALSE, v->EventNameWin32);
if (e == INVALID_HANDLE_VALUE)
{
// Connection failure
goto CLEANUP;
}
}
else
{
OPENVXDHANDLE OpenVxDHandle;
DWORD vxd_handle;
UINT bytes_returned;
OpenVxDHandle = (OPENVXDHANDLE)GetProcAddress(GetModuleHandle("KERNEL32"),
"OpenVxDHandle");
// Deliver to the driver by creating an event
e = CreateEvent(NULL, FALSE, FALSE, NULL);
vxd_handle = (DWORD)OpenVxDHandle(e);
DeviceIoControl(h, NEO_IOCTL_SET_EVENT, &vxd_handle, sizeof(DWORD),
NULL, 0, &bytes_returned, NULL);
}
v->Event = e;
v->Handle = h;
v->GetBuffer = ZeroMalloc(NEO_EXCHANGE_BUFFER_SIZE);
v->PutBuffer = ZeroMalloc(NEO_EXCHANGE_BUFFER_SIZE);
return v;
CLEANUP:
if (h != INVALID_HANDLE_VALUE)
{
CloseHandle(h);
}
if (e != INVALID_HANDLE_VALUE)
{
CloseHandle(e);
}
Free(v->InstanceName);
Free(v->EventNameWin32);
Free(v->DeviceNameWin32);
Free(v);
return NULL;
}
#endif // OS_WIN32
#endif //VLAN_C
// Developed by SoftEther VPN Project at University of Tsukuba in Japan.
// Department of Computer Science has dozens of overly-enthusiastic geeks.
// Join us: http://www.tsukuba.ac.jp/english/admission/