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SoftEtherVPN/src/Neo6/NDIS6.c

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// SoftEther VPN Source Code
// Kernel Device Driver
//
// SoftEther VPN Server, Client and Bridge are free software under GPLv2.
//
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// Copyright (c) 2012-2016 Daiyuu Nobori.
// Copyright (c) 2012-2016 SoftEther VPN Project, University of Tsukuba, Japan.
// Copyright (c) 2012-2016 SoftEther Corporation.
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//
// 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.
//
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// 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.
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//
//
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// 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
//
//
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// 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.
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//
//
// NO MEMORY OR RESOURCE LEAKS
// ---------------------------
//
// The memory-leaks and resource-leaks verification under the stress
// test has been passed before release this source code.
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// NDIS6.c
// Windows NDIS 6.2 Routine
#include <GlobalConst.h>
#define NEO_DEVICE_DRIVER
#include "Neo6.h"
static UINT64 max_speed = NEO_MAX_SPEED_DEFAULT;
static bool keep_link = false;
BOOLEAN
PsGetVersion(
PULONG MajorVersion OPTIONAL,
PULONG MinorVersion OPTIONAL,
PULONG BuildNumber OPTIONAL,
PUNICODE_STRING CSDVersion OPTIONAL
);
// Memory related
static NDIS_PHYSICAL_ADDRESS HighestAcceptableMax = NDIS_PHYSICAL_ADDRESS_CONST(-1, -1);
NDIS_HANDLE ndis_miniport_driver_handle = NULL;
// Flag for whether Windows 8
bool g_is_win8 = false;
// Win32 driver entry point
NDIS_STATUS DriverEntry(DRIVER_OBJECT *DriverObject, UNICODE_STRING *RegistryPath)
{
NDIS_MINIPORT_DRIVER_CHARACTERISTICS miniport;
ULONG os_major_ver = 0, os_minor_ver = 0;
NDIS_STATUS ret;
// Initialize the Neo library
if (NeoInit() == FALSE)
{
// Initialization Failed
return STATUS_UNSUCCESSFUL;
}
g_is_win8 = false;
// Get the OS version
PsGetVersion(&os_major_ver, &os_minor_ver, NULL, NULL);
if (os_major_ver >= 7 || (os_major_ver == 6 && os_minor_ver >= 2))
{
// Windows 8
g_is_win8 = true;
}
// Register a NDIS miniport driver
NeoZero(&miniport, sizeof(NDIS_MINIPORT_DRIVER_CHARACTERISTICS));
miniport.Header.Type = NDIS_OBJECT_TYPE_MINIPORT_DRIVER_CHARACTERISTICS;
miniport.Header.Revision = NDIS_MINIPORT_DRIVER_CHARACTERISTICS_REVISION_2;
miniport.Header.Size = NDIS_SIZEOF_MINIPORT_DRIVER_CHARACTERISTICS_REVISION_2;
miniport.MajorNdisVersion = NEO_NDIS_MAJOR_VERSION;
miniport.MinorNdisVersion = NEO_NDIS_MINOR_VERSION;
// Register the handler
miniport.InitializeHandlerEx = NeoNdisInitEx;
miniport.HaltHandlerEx = NeoNdisHaltEx;
miniport.OidRequestHandler = NeoNdisOidRequest;
miniport.ResetHandlerEx = NeoNdisResetEx;
miniport.CheckForHangHandlerEx = NeoNdisCheckForHangEx;
miniport.UnloadHandler = NeoNdisDriverUnload;
miniport.SendNetBufferListsHandler = NeoNdisSendNetBufferLists;
miniport.SetOptionsHandler = NeoNdisSetOptions;
miniport.PauseHandler = NeoNdisPause;
miniport.RestartHandler = NeoNdisRestart;
miniport.ReturnNetBufferListsHandler = NeoNdisReturnNetBufferLists;
miniport.CancelSendHandler = NeoNdisCancelSend;
miniport.DevicePnPEventNotifyHandler = NeoNdisDevicePnPEventNotify;
miniport.ShutdownHandlerEx = NeoNdisShutdownEx;
miniport.CancelOidRequestHandler = NeoNdisCancelOidRequest;
ret = NdisMRegisterMiniportDriver(DriverObject, RegistryPath,
NULL, &miniport, &ndis_miniport_driver_handle);
if (NG(ret))
{
// Registration failure
return STATUS_UNSUCCESSFUL;
}
// Initialization success
return STATUS_SUCCESS;
}
NDIS_STATUS NeoNdisSetOptions(NDIS_HANDLE NdisDriverHandle, NDIS_HANDLE DriverContext)
{
return NDIS_STATUS_SUCCESS;
}
NDIS_STATUS NeoNdisPause(NDIS_HANDLE MiniportAdapterContext, PNDIS_MINIPORT_PAUSE_PARAMETERS MiniportPauseParameters)
{
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UINT counter_dbg = 0;
ctx->Paused = true;
NeoLockPacketQueue();
NeoUnlockPacketQueue();
// Wait for complete all tasks
while (ctx->NumCurrentDispatch != 0)
{
NdisMSleep(10000);
counter_dbg++;
if (counter_dbg >= 1500)
{
break;
}
}
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return NDIS_STATUS_SUCCESS;
}
NDIS_STATUS NeoNdisRestart(NDIS_HANDLE MiniportAdapterContext, PNDIS_MINIPORT_RESTART_PARAMETERS MiniportRestartParameters)
{
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ctx->Paused = false;
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return NDIS_STATUS_SUCCESS;
}
void NeoNdisReturnNetBufferLists(NDIS_HANDLE MiniportAdapterContext, PNET_BUFFER_LIST NetBufferLists, ULONG ReturnFlags)
{
}
void NeoNdisCancelSend(NDIS_HANDLE MiniportAdapterContext, PVOID CancelId)
{
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//NeoNdisCrash2(__LINE__, __LINE__, __LINE__, __LINE__);
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}
void NeoNdisDevicePnPEventNotify(NDIS_HANDLE MiniportAdapterContext, PNET_DEVICE_PNP_EVENT NetDevicePnPEvent)
{
}
void NeoNdisShutdownEx(NDIS_HANDLE MiniportAdapterContext, NDIS_SHUTDOWN_ACTION ShutdownAction)
{
}
void NeoNdisCancelOidRequest(NDIS_HANDLE MiniportAdapterContext, PVOID RequestId)
{
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//NeoNdisCrash2(__LINE__, __LINE__, __LINE__, __LINE__);
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}
// Initialization handler of adapter
NDIS_STATUS NeoNdisInitEx(NDIS_HANDLE MiniportAdapterHandle,
NDIS_HANDLE MiniportDriverContext,
PNDIS_MINIPORT_INIT_PARAMETERS MiniportInitParameters)
{
NDIS_MINIPORT_ADAPTER_REGISTRATION_ATTRIBUTES attr;
NDIS_MINIPORT_ADAPTER_GENERAL_ATTRIBUTES gen;
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NDIS_PM_CAPABILITIES pnpcap;
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if (ctx == NULL)
{
return NDIS_STATUS_FAILURE;
}
if (ctx->NdisMiniportDriverHandle == NULL)
{
ctx->NdisMiniportDriverHandle = ndis_miniport_driver_handle;
}
// Prevention of multiple start
if (ctx->Initing != FALSE)
{
// Multiple started
return NDIS_STATUS_FAILURE;
}
ctx->Initing = TRUE;
// Examine whether it has already been initialized
if (ctx->Inited != FALSE)
{
// Driver is started on another instance already.
// VPN driver can start only one instance per one service.
// User can start multiple drivers with different instance ID
return NDIS_STATUS_FAILURE;
}
// Current value of the packet filter
ctx->CurrentPacketFilter = NDIS_PACKET_TYPE_ALL_LOCAL | NDIS_PACKET_TYPE_BROADCAST | NDIS_PACKET_TYPE_DIRECTED | NDIS_PACKET_TYPE_ALL_FUNCTIONAL;
// Initialize the adapter information
ctx->NdisMiniport = MiniportAdapterHandle;
ctx->NdisContext = ctx;
ctx->HardwareStatus = NdisHardwareStatusReady;
ctx->Halting = FALSE;
ctx->Connected = ctx->ConnectedOld = FALSE;
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//if (keep_link == false)
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{
ctx->ConnectedForce = TRUE;
}
// Read the information from the registry
if (NeoLoadRegistory() == FALSE)
{
// Failure
ctx->Initing = FALSE;
return NDIS_STATUS_FAILURE;
}
// Register the device attributes
NeoZero(&attr, sizeof(attr));
attr.Header.Type = NDIS_OBJECT_TYPE_MINIPORT_ADAPTER_REGISTRATION_ATTRIBUTES;
attr.Header.Revision = NDIS_MINIPORT_ADAPTER_REGISTRATION_ATTRIBUTES_REVISION_1;
attr.Header.Size = sizeof(NDIS_MINIPORT_ADAPTER_REGISTRATION_ATTRIBUTES);
attr.AttributeFlags = NDIS_MINIPORT_ATTRIBUTES_NO_HALT_ON_SUSPEND;
attr.InterfaceType = NdisInterfaceInternal;
attr.MiniportAdapterContext = ctx->NdisContext;
NdisMSetMiniportAttributes(ctx->NdisMiniport, (PNDIS_MINIPORT_ADAPTER_ATTRIBUTES)&attr);
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NeoZero(&pnpcap, sizeof(pnpcap));
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NeoZero(&gen, sizeof(gen));
gen.Header.Type = NDIS_OBJECT_TYPE_MINIPORT_ADAPTER_GENERAL_ATTRIBUTES;
gen.Header.Revision = NDIS_MINIPORT_ADAPTER_GENERAL_ATTRIBUTES_REVISION_2;
gen.Header.Size = NDIS_SIZEOF_MINIPORT_ADAPTER_GENERAL_ATTRIBUTES_REVISION_2;
gen.MediaType = NdisMedium802_3;
gen.PhysicalMediumType = NdisPhysicalMedium802_3;
gen.MtuSize = NEO_MAX_PACKET_SIZE_ANNOUNCE - NEO_MIN_PACKET_SIZE;
gen.MaxXmitLinkSpeed = gen.MaxRcvLinkSpeed = max_speed;
gen.RcvLinkSpeed = gen.XmitLinkSpeed = max_speed;
gen.MediaConnectState = MediaConnectStateDisconnected;
gen.LookaheadSize = NEO_MAX_PACKET_SIZE_ANNOUNCE - NEO_MIN_PACKET_SIZE;
gen.MacOptions = NDIS_MAC_OPTION_TRANSFERS_NOT_PEND | NDIS_MAC_OPTION_COPY_LOOKAHEAD_DATA | NDIS_MAC_OPTION_NO_LOOPBACK;
gen.SupportedPacketFilters = NDIS_PACKET_TYPE_ALL_LOCAL | NDIS_PACKET_TYPE_BROADCAST | NDIS_PACKET_TYPE_DIRECTED | NDIS_PACKET_TYPE_ALL_FUNCTIONAL;
gen.MaxMulticastListSize = NEO_MAX_MULTICASE;
gen.MacAddressLength = NEO_MAC_ADDRESS_SIZE;
NeoCopy(gen.PermanentMacAddress, ctx->MacAddress, NEO_MAC_ADDRESS_SIZE);
NeoCopy(gen.CurrentMacAddress, ctx->MacAddress, NEO_MAC_ADDRESS_SIZE);
gen.AccessType = NET_IF_ACCESS_BROADCAST;
gen.DirectionType = NET_IF_DIRECTION_SENDRECEIVE;
gen.ConnectionType = NET_IF_CONNECTION_DEDICATED;
gen.IfType = IF_TYPE_ETHERNET_CSMACD;
gen.IfConnectorPresent = TRUE;
gen.SupportedStatistics =
NDIS_STATISTICS_FLAGS_VALID_DIRECTED_FRAMES_RCV |
NDIS_STATISTICS_FLAGS_VALID_MULTICAST_FRAMES_RCV |
NDIS_STATISTICS_FLAGS_VALID_BROADCAST_FRAMES_RCV |
NDIS_STATISTICS_FLAGS_VALID_BYTES_RCV |
NDIS_STATISTICS_FLAGS_VALID_RCV_DISCARDS |
NDIS_STATISTICS_FLAGS_VALID_RCV_ERROR |
NDIS_STATISTICS_FLAGS_VALID_DIRECTED_FRAMES_XMIT |
NDIS_STATISTICS_FLAGS_VALID_MULTICAST_FRAMES_XMIT |
NDIS_STATISTICS_FLAGS_VALID_BROADCAST_FRAMES_XMIT |
NDIS_STATISTICS_FLAGS_VALID_BYTES_XMIT |
NDIS_STATISTICS_FLAGS_VALID_XMIT_ERROR |
NDIS_STATISTICS_FLAGS_VALID_XMIT_DISCARDS |
NDIS_STATISTICS_FLAGS_VALID_DIRECTED_BYTES_RCV |
NDIS_STATISTICS_FLAGS_VALID_MULTICAST_BYTES_RCV |
NDIS_STATISTICS_FLAGS_VALID_BROADCAST_BYTES_RCV |
NDIS_STATISTICS_FLAGS_VALID_DIRECTED_BYTES_XMIT |
NDIS_STATISTICS_FLAGS_VALID_MULTICAST_BYTES_XMIT |
NDIS_STATISTICS_FLAGS_VALID_BROADCAST_BYTES_XMIT;
gen.SupportedPauseFunctions = NdisPauseFunctionsUnsupported;
gen.AutoNegotiationFlags = NDIS_LINK_STATE_XMIT_LINK_SPEED_AUTO_NEGOTIATED |
NDIS_LINK_STATE_RCV_LINK_SPEED_AUTO_NEGOTIATED |
NDIS_LINK_STATE_DUPLEX_AUTO_NEGOTIATED |
NDIS_LINK_STATE_PAUSE_FUNCTIONS_AUTO_NEGOTIATED;
gen.SupportedOidList = SupportedOids;
gen.SupportedOidListLength = sizeof(SupportedOids);
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NeoZero(&pnpcap, sizeof(pnpcap));
pnpcap.Header.Type = NDIS_OBJECT_TYPE_DEFAULT;
pnpcap.Header.Revision = NDIS_PM_CAPABILITIES_REVISION_1;
pnpcap.Header.Size = NDIS_SIZEOF_NDIS_PM_CAPABILITIES_REVISION_1;
pnpcap.MinMagicPacketWakeUp = NdisDeviceStateUnspecified;
pnpcap.MinPatternWakeUp = NdisDeviceStateUnspecified;
pnpcap.MinLinkChangeWakeUp = NdisDeviceStateUnspecified;
gen.PowerManagementCapabilitiesEx = &pnpcap;
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NdisMSetMiniportAttributes(ctx->NdisMiniport, (PNDIS_MINIPORT_ADAPTER_ATTRIBUTES)&gen);
// Initialize the received packet array
NeoInitPacketArray();
// Initialize the control device
NeoInitControlDevice();
// Start the adapter
NeoStartAdapter();
// Flag setting
ctx->Initing = FALSE;
ctx->Inited = TRUE;
// Notify the connection state
NeoSetConnectState(FALSE);
return NDIS_STATUS_SUCCESS;
}
// Open the device
BOOL NeoNdisOnOpen(IRP *irp, IO_STACK_LOCATION *stack)
{
char name[MAX_SIZE];
if (ctx == NULL)
{
return FALSE;
}
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if (ctx->Opened)
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{
// Another client is connected already
return FALSE;
}
ctx->Opened = TRUE;
// Initialize the event name
sprintf(name, NDIS_NEO_EVENT_NAME, ctx->HardwareID);
// Register a Event
ctx->Event = NeoNewEvent(name);
if (ctx->Event == NULL)
{
ctx->Opened = FALSE;
return FALSE;
}
// Set the connection state
NeoSetConnectState(TRUE);
return TRUE;
}
// Close the device
BOOL NeoNdisOnClose(IRP *irp, IO_STACK_LOCATION *stack)
{
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NEO_EVENT *free_event = NULL;
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if (ctx == NULL)
{
return FALSE;
}
if (ctx->Opened == FALSE)
{
// Client is not connected
return FALSE;
}
ctx->Opened = FALSE;
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NeoLockPacketQueue();
{
// Release the event
free_event = ctx->Event;
ctx->Event = NULL;
// Release all packets
NeoClearPacketQueue(true);
}
NeoUnlockPacketQueue();
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if (free_event != NULL)
{
NeoFreeEvent(free_event);
}
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NeoSetConnectState(FALSE);
return TRUE;
}
// Crash 2
void NeoNdisCrash2(UINT a, UINT b, UINT c, UINT d)
{
KeBugCheckEx(0x00000061, (ULONG_PTR)a, (ULONG_PTR)b, (ULONG_PTR)c, (ULONG_PTR)d);
}
// Crash
void NeoNdisCrash()
{
NEO_QUEUE *q;
q = (NEO_QUEUE *)0xACACACAC;
q->Size = 128;
NeoCopy(q->Buf, "ABCDEFG", 8);
}
// Dispatch table for control
NTSTATUS NeoNdisDispatch(DEVICE_OBJECT *DeviceObject, IRP *Irp)
{
NTSTATUS status;
IO_STACK_LOCATION *stack;
void *buf;
BOOL ok;
status = STATUS_SUCCESS;
if (ctx == NULL)
{
return NDIS_STATUS_FAILURE;
}
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InterlockedIncrement(&ctx->NumCurrentDispatch);
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// Get the IRP stack
stack = IoGetCurrentIrpStackLocation(Irp);
// Initialize the number of bytes
Irp->IoStatus.Information = 0;
Irp->IoStatus.Status = STATUS_SUCCESS;
buf = Irp->UserBuffer;
if (ctx->Halting != FALSE)
{
// Device driver is terminating
Irp->IoStatus.Information = STATUS_UNSUCCESSFUL;
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InterlockedDecrement(&ctx->NumCurrentDispatch);
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IoCompleteRequest(Irp, IO_NO_INCREMENT);
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return STATUS_SUCCESS;
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}
// Branch to each operation
switch (stack->MajorFunction)
{
case IRP_MJ_CREATE:
// Device is opened
if (NeoNdisOnOpen(Irp, stack) == FALSE)
{
Irp->IoStatus.Status = STATUS_UNSUCCESSFUL;
status = STATUS_UNSUCCESSFUL;
}
break;
case IRP_MJ_CLOSE:
// Device is closed
if (NeoNdisOnClose(Irp, stack) == FALSE)
{
Irp->IoStatus.Status = STATUS_UNSUCCESSFUL;
status = STATUS_UNSUCCESSFUL;
}
break;
case IRP_MJ_READ:
// Read (Reading of the received packet)
ok = false;
if (buf != NULL)
{
if (ctx->Opened && ctx->Inited)
{
if (stack->Parameters.Read.Length == NEO_EXCHANGE_BUFFER_SIZE)
{
// Address check
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bool check_ok = true;
__try
{
ProbeForWrite(buf, NEO_EXCHANGE_BUFFER_SIZE, 1);
}
__except (EXCEPTION_EXECUTE_HANDLER)
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{
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check_ok = false;
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}
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if (check_ok)
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{
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// Address check
MDL *mdl = IoAllocateMdl(buf, NEO_EXCHANGE_BUFFER_SIZE, false, false, NULL);
if (mdl != NULL)
{
MmProbeAndLockPages(mdl, KernelMode, IoWriteAccess);
}
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// Read
NeoRead(buf);
Irp->IoStatus.Information = NEO_EXCHANGE_BUFFER_SIZE;
ok = true;
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if (mdl != NULL)
{
MmUnlockPages(mdl);
IoFreeMdl(mdl);
}
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}
}
}
}
if (ok == FALSE)
{
// An error occurred
Irp->IoStatus.Status = STATUS_UNSUCCESSFUL;
status = STATUS_UNSUCCESSFUL;
}
break;
case IRP_MJ_WRITE:
// Write (Writing of a transmission packet)
ok = false;
if (buf != NULL)
{
if (ctx->Opened && ctx->Inited)
{
if (stack->Parameters.Write.Length == NEO_EXCHANGE_BUFFER_SIZE)
{
// Address check
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bool check_ok = true;
__try
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{
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ProbeForRead(buf, NEO_EXCHANGE_BUFFER_SIZE, 1);
}
__except (EXCEPTION_EXECUTE_HANDLER)
{
check_ok = false;
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}
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if (check_ok)
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{
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// Address check
MDL *mdl = IoAllocateMdl(buf, NEO_EXCHANGE_BUFFER_SIZE, false, false, NULL);
if (mdl != NULL)
{
MmProbeAndLockPages(mdl, KernelMode, IoReadAccess);
}
ProbeForRead(buf, NEO_EXCHANGE_BUFFER_SIZE, 1);
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// Write
NeoWrite(buf);
Irp->IoStatus.Information = stack->Parameters.Write.Length;
ok = true;
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if (mdl != NULL)
{
MmUnlockPages(mdl);
IoFreeMdl(mdl);
}
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}
}
}
}
if (ok == FALSE)
{
// An error occurred
Irp->IoStatus.Status = STATUS_UNSUCCESSFUL;
status = STATUS_UNSUCCESSFUL;
}
break;
}
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InterlockedDecrement(&ctx->NumCurrentDispatch);
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IoCompleteRequest(Irp, IO_NO_INCREMENT);
return STATUS_SUCCESS;
}
// Initialize the control device
void NeoInitControlDevice()
{
char name_kernel[MAX_SIZE];
char name_win32[MAX_SIZE];
UNICODE *unicode_kernel, *unicode_win32;
DEVICE_OBJECT *control_device_object;
NDIS_HANDLE ndis_control_handle;
NDIS_DEVICE_OBJECT_ATTRIBUTES t;
if (ctx == NULL)
{
return;
}
// Initialize the dispatch table
NeoZero(ctx->DispatchTable, sizeof(PDRIVER_DISPATCH) * IRP_MJ_MAXIMUM_FUNCTION);
// Register the handler
ctx->DispatchTable[IRP_MJ_CREATE] =
ctx->DispatchTable[IRP_MJ_CLOSE] =
ctx->DispatchTable[IRP_MJ_READ] =
ctx->DispatchTable[IRP_MJ_WRITE] =
ctx->DispatchTable[IRP_MJ_DEVICE_CONTROL] = NeoNdisDispatch;
ctx->Opened = FALSE;
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ctx->Paused = FALSE;
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// Generate the device name
sprintf(name_kernel, NDIS_NEO_DEVICE_NAME, ctx->HardwareID);
unicode_kernel = NewUnicode(name_kernel);
sprintf(name_win32, NDIS_NEO_DEVICE_NAME_WIN32, ctx->HardwareID);
unicode_win32 = NewUnicode(name_win32);
// Register the device
NeoZero(&t, sizeof(t));
t.Header.Type = NDIS_OBJECT_TYPE_DEVICE_OBJECT_ATTRIBUTES;
t.Header.Revision = NDIS_DEVICE_OBJECT_ATTRIBUTES_REVISION_1;
t.Header.Size = NDIS_SIZEOF_DEVICE_OBJECT_ATTRIBUTES_REVISION_1;
t.DeviceName = GetUnicode(unicode_kernel);
t.SymbolicName = GetUnicode(unicode_win32);
t.MajorFunctions = ctx->DispatchTable;
NdisRegisterDeviceEx(ndis_miniport_driver_handle, &t,
&control_device_object,
&ndis_control_handle);
ctx->NdisControlDevice = control_device_object;
ctx->NdisControl = ndis_control_handle;
// Initialize the display name
if (strlen(ctx->HardwareID) > 11)
{
sprintf(ctx->HardwarePrintableID, NDIS_NEO_HARDWARE_ID, ctx->HardwareID_Raw + 11);
}
else
{
sprintf(ctx->HardwarePrintableID, NDIS_NEO_HARDWARE_ID, ctx->HardwareID_Raw);
}
}
// Release the control device
void NeoFreeControlDevice()
{
if (ctx == NULL)
{
return;
}
if (ctx->Opened != FALSE)
{
// Delete the event
NeoSet(ctx->Event);
NeoFreeEvent(ctx->Event);
ctx->Event = NULL;
ctx->Opened = FALSE;
}
// Delete the device
NdisDeregisterDeviceEx(ctx->NdisControl);
}
// Read the information from the registry
BOOL NeoLoadRegistory()
{
void *buf;
NDIS_STATUS ret;
UINT size;
NDIS_HANDLE config;
NDIS_CONFIGURATION_PARAMETER *param;
UNICODE *name;
ANSI_STRING ansi;
UNICODE_STRING *unicode;
UINT64 speed;
BOOL keep;
NDIS_CONFIGURATION_OBJECT config_obj;
// Get the Config handle
NeoZero(&config_obj, sizeof(config_obj));
config_obj.Header.Type = NDIS_OBJECT_TYPE_CONFIGURATION_OBJECT;
config_obj.Header.Revision = NDIS_CONFIGURATION_OBJECT_REVISION_1;
config_obj.Header.Size = NDIS_SIZEOF_CONFIGURATION_OBJECT_REVISION_1;
config_obj.NdisHandle = ctx->NdisMiniport;
ret = NdisOpenConfigurationEx(&config_obj, &config);
if (NG(ret))
{
// Failure
return FALSE;
}
// Read the MAC address
NdisReadNetworkAddress(&ret, &buf, &size, config);
if (NG(ret))
{
// Failure
NdisCloseConfiguration(config);
return FALSE;
}
// Copy the MAC address
if (size != NEO_MAC_ADDRESS_SIZE)
{
// Invalid size
NdisCloseConfiguration(config);
return FALSE;
}
NeoCopy(ctx->MacAddress, buf, NEO_MAC_ADDRESS_SIZE);
if (ctx->MacAddress[0] == 0x00 &&
ctx->MacAddress[1] == 0x00 &&
ctx->MacAddress[2] == 0x01 &&
ctx->MacAddress[3] == 0x00 &&
ctx->MacAddress[4] == 0x00 &&
ctx->MacAddress[5] == 0x01)
{
// Special MAC address
UINT ptr32 = (UINT)((UINT64)ctx);
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LARGE_INTEGER current_time;
UCHAR *current_time_bytes;
KeQuerySystemTime(&current_time);
current_time_bytes = (UCHAR *)&current_time;
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ctx->MacAddress[0] = 0x00;
ctx->MacAddress[1] = 0xAD;
ctx->MacAddress[2] = ((UCHAR *)(&ptr32))[0];
ctx->MacAddress[3] = ((UCHAR *)(&ptr32))[1];
ctx->MacAddress[4] = ((UCHAR *)(&ptr32))[2];
ctx->MacAddress[5] = ((UCHAR *)(&ptr32))[3];
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ctx->MacAddress[2] ^= current_time_bytes[0];
ctx->MacAddress[3] ^= current_time_bytes[1];
ctx->MacAddress[4] ^= current_time_bytes[2];
ctx->MacAddress[5] ^= current_time_bytes[3];
ctx->MacAddress[2] ^= current_time_bytes[4];
ctx->MacAddress[3] ^= current_time_bytes[5];
ctx->MacAddress[4] ^= current_time_bytes[6];
ctx->MacAddress[5] ^= current_time_bytes[7];
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}
// Initialize the key name of the device name
name = NewUnicode("MatchingDeviceId");
// Read the hardware ID
NdisReadConfiguration(&ret, &param, config, GetUnicode(name), NdisParameterString);
FreeUnicode(name);
if (NG(ret))
{
// Failure
NdisCloseConfiguration(config);
return FALSE;
}
// Type checking
if (param->ParameterType != NdisParameterString)
{
// Failure
NdisCloseConfiguration(config);
return FALSE;
}
unicode = &param->ParameterData.StringData;
// Prepare a buffer for ANSI string
NeoZero(&ansi, sizeof(ANSI_STRING));
ansi.MaximumLength = MAX_SIZE - 1;
ansi.Buffer = NeoZeroMalloc(MAX_SIZE);
// Convert to ANSI string
NdisUnicodeStringToAnsiString(&ansi, unicode);
// Copy
strcpy(ctx->HardwareID, ansi.Buffer);
strcpy(ctx->HardwareID_Raw, ctx->HardwareID);
// Convert to upper case
_strupr(ctx->HardwareID);
// Release the memory
NeoFree(ansi.Buffer);
// Read the bit rate
name = NewUnicode("MaxSpeed");
NdisReadConfiguration(&ret, &param, config, GetUnicode(name), NdisParameterInteger);
FreeUnicode(name);
if (NG(ret) || param->ParameterType != NdisParameterInteger)
{
speed = NEO_MAX_SPEED_DEFAULT;
}
else
{
speed = (UINT64)param->ParameterData.IntegerData * 1000000ULL;
}
max_speed = speed;
// Read the link keeping flag
name = NewUnicode("KeepLink");
NdisReadConfiguration(&ret, &param, config, GetUnicode(name), NdisParameterInteger);
FreeUnicode(name);
if (NG(ret) || param->ParameterType != NdisParameterInteger)
{
keep = false;
}
else
{
keep = (param->ParameterData.IntegerData == 0 ? false : true);
}
keep_link = keep;
// Close the config handle
NdisCloseConfiguration(config);
return TRUE;
}
// Unload the driver
VOID NeoNdisDriverUnload(PDRIVER_OBJECT DriverObject)
{
NdisMDeregisterMiniportDriver(ndis_miniport_driver_handle);
}
// Stop handler of adapter
void NeoNdisHaltEx(NDIS_HANDLE MiniportAdapterContext, NDIS_HALT_ACTION HaltAction)
{
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NEO_EVENT *free_event = NULL;
UINT counter_dbg = 0;
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if (ctx == NULL)
{
return;
}
if (ctx->Halting != FALSE)
{
// That has already been stopped
return;
}
ctx->Halting = TRUE;
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ctx->Opened = FALSE;
NeoLockPacketQueue();
{
// Release the event
free_event = ctx->Event;
ctx->Event = NULL;
// Release all packets
NeoClearPacketQueue(true);
}
NeoUnlockPacketQueue();
if (free_event != NULL)
{
NeoSet(free_event);
}
// Wait for complete all tasks
while (ctx->NumCurrentDispatch != 0)
{
NdisMSleep(10000);
counter_dbg++;
if (counter_dbg >= 1500)
{
break;
}
}
if (free_event != NULL)
{
NeoFreeEvent(free_event);
}
// Delete the control device
NeoFreeControlDevice();
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// Stop the adapter
NeoStopAdapter();
// Release the packet array
NeoFreePacketArray();
// Complete to stop
ctx->Initing = ctx->Inited = FALSE;
ctx->Connected = ctx->ConnectedForce = ctx->ConnectedOld = FALSE;
ctx->Halting = FALSE;
// Shutdown of Neo
NeoShutdown();
}
// Reset handler of adapter
NDIS_STATUS NeoNdisResetEx(NDIS_HANDLE MiniportAdapterContext, PBOOLEAN AddressingReset)
{
return NDIS_STATUS_SUCCESS;
}
// Hang-up check handler of adapter
BOOLEAN NeoNdisCheckForHangEx(NDIS_HANDLE MiniportAdapterContext)
{
return FALSE;
}
// OID request handler
NDIS_STATUS NeoNdisOidRequest(NDIS_HANDLE MiniportAdapterContext,
PNDIS_OID_REQUEST OidRequest)
{
NDIS_STATUS ret = STATUS_UNSUCCESSFUL;
ULONG dummy = 0;
switch (OidRequest->RequestType)
{
case NdisRequestQueryInformation:
case NdisRequestQueryStatistics:
ret = NeoNdisQuery(MiniportAdapterContext,
OidRequest->DATA.QUERY_INFORMATION.Oid,
OidRequest->DATA.QUERY_INFORMATION.InformationBuffer,
OidRequest->DATA.QUERY_INFORMATION.InformationBufferLength,
&OidRequest->DATA.QUERY_INFORMATION.BytesWritten,
&OidRequest->DATA.QUERY_INFORMATION.BytesNeeded);
break;
case NdisRequestSetInformation:
ret = NeoNdisSet(MiniportAdapterContext,
OidRequest->DATA.SET_INFORMATION.Oid,
OidRequest->DATA.SET_INFORMATION.InformationBuffer,
OidRequest->DATA.SET_INFORMATION.InformationBufferLength,
&dummy,
&OidRequest->DATA.SET_INFORMATION.BytesNeeded);
break;
default:
ret = NDIS_STATUS_NOT_SUPPORTED;
break;
}
return ret;
}
// Information acquisition handler of adapter
NDIS_STATUS NeoNdisQuery(NDIS_HANDLE MiniportAdapterContext,
NDIS_OID Oid,
void *InformationBuffer,
ULONG InformationBufferLength,
ULONG *BytesWritten,
ULONG *BytesNeeded)
{
NDIS_MEDIUM media;
void *buf;
UINT value32;
USHORT value16;
UINT size;
NDIS_STATISTICS_INFO stat;
NDIS_INTERRUPT_MODERATION_PARAMETERS intp;
if (ctx == NULL)
{
return NDIS_STATUS_FAILURE;
}
// Initialization
size = sizeof(UINT);
value32 = value16 = 0;
buf = &value32;
// Branch processing
switch (Oid)
{
case OID_GEN_SUPPORTED_LIST:
// Return a list of supported OID
buf = SupportedOids;
size = sizeof(SupportedOids);
break;
case OID_GEN_MAC_OPTIONS:
// Ethernet option
value32 = NDIS_MAC_OPTION_TRANSFERS_NOT_PEND | NDIS_MAC_OPTION_RECEIVE_SERIALIZED |
NDIS_MAC_OPTION_COPY_LOOKAHEAD_DATA | NDIS_MAC_OPTION_NO_LOOPBACK;
break;
case OID_GEN_HARDWARE_STATUS:
// Hardware state
buf = &ctx->HardwareStatus;
size = sizeof(NDIS_HARDWARE_STATUS);
break;
case OID_GEN_MEDIA_SUPPORTED:
case OID_GEN_MEDIA_IN_USE:
// Type of media
media = NdisMedium802_3;
buf = &media;
size = sizeof(NDIS_MEDIUM);
break;
case OID_GEN_CURRENT_LOOKAHEAD:
case OID_GEN_MAXIMUM_LOOKAHEAD:
// Read-ahead available size
value32 = NEO_MAX_PACKET_SIZE_ANNOUNCE - NEO_MIN_PACKET_SIZE;
break;
case OID_GEN_MAXIMUM_FRAME_SIZE:
// Maximum frame size
value32 = NEO_MAX_PACKET_SIZE_ANNOUNCE - NEO_MIN_PACKET_SIZE;
break;
case OID_GEN_MAXIMUM_TOTAL_SIZE:
case OID_GEN_TRANSMIT_BLOCK_SIZE:
case OID_GEN_RECEIVE_BLOCK_SIZE:
// Maximum packet size
value32 = NEO_MAX_PACKET_SIZE_ANNOUNCE;
break;
case OID_GEN_TRANSMIT_BUFFER_SPACE:
case OID_GEN_RECEIVE_BUFFER_SPACE:
// Buffer size
value32 = NEO_MAX_PACKET_SIZE_ANNOUNCE * NEO_MAX_PACKET_EXCHANGE;
break;
case OID_GEN_LINK_SPEED:
// Communication speed
value32 = (UINT)(max_speed / 100);
break;
case OID_GEN_VENDOR_ID:
// Vendor ID
NeoCopy(&value32, ctx->MacAddress, 3);
value32 &= 0xFFFFFF00;
value32 |= 0x01;
break;
case OID_GEN_VENDOR_DESCRIPTION:
// Hardware ID
buf = ctx->HardwarePrintableID;
size = (UINT)strlen(ctx->HardwarePrintableID) + 1;
break;
case OID_GEN_DRIVER_VERSION:
// Driver version
value16 = ((USHORT)NEO_NDIS_MAJOR_VERSION << 8) | NEO_NDIS_MINOR_VERSION;
buf = &value16;
size = sizeof(USHORT);
break;
case OID_GEN_VENDOR_DRIVER_VERSION:
// Vendor driver version
value16 = ((USHORT)NEO_NDIS_MAJOR_VERSION << 8) | NEO_NDIS_MINOR_VERSION;
buf = &value16;
size = sizeof(USHORT);
break;
case OID_802_3_PERMANENT_ADDRESS:
case OID_802_3_CURRENT_ADDRESS:
// MAC address
buf = ctx->MacAddress;
size = NEO_MAC_ADDRESS_SIZE;
break;
case OID_802_3_MAXIMUM_LIST_SIZE:
// Number of multicast
value32 = NEO_MAX_MULTICASE;
break;
case OID_GEN_MAXIMUM_SEND_PACKETS:
// Number of packets that can be sent at a time
value32 = NEO_MAX_PACKET_EXCHANGE;
break;
case OID_GEN_XMIT_OK:
// Number of packets sent
value32 = ctx->Status.NumPacketSend;
break;
case OID_GEN_RCV_OK:
// Number of received packets
value32 = ctx->Status.NumPacketRecv;
break;
case OID_GEN_XMIT_ERROR:
// Number of transmission error packets
value32 = ctx->Status.NumPacketSendError;
break;
case OID_GEN_RCV_ERROR:
// Number of error packets received
value32 = ctx->Status.NumPacketRecvError;
break;
case OID_GEN_RCV_NO_BUFFER:
// Number of reception buffer shortage occurrences
value32 = ctx->Status.NumPacketRecvNoBuffer;
break;
case OID_802_3_RCV_ERROR_ALIGNMENT:
// Number of errors
value32 = 0;
break;
case OID_GEN_MEDIA_CONNECT_STATUS:
// Cable connection state
NeoCheckConnectState();
if (keep_link == false)
{
value32 = ctx->Connected ? NdisMediaStateConnected : NdisMediaStateDisconnected;
}
else
{
value32 = NdisMediaStateConnected;
}
break;
case OID_802_3_XMIT_ONE_COLLISION:
case OID_802_3_XMIT_MORE_COLLISIONS:
// Number of collisions
value32 = 0;
break;
case OID_GEN_CURRENT_PACKET_FILTER:
// Current settings of the packet filter
value32 = ctx->CurrentPacketFilter;
break;
/* case OID_GEN_PROTOCOL_OPTIONS:
// Current value of the protocol option
value32 = ctx->CurrentProtocolOptions;
break;*/
case OID_GEN_STATISTICS:
// Statistics (NDIS 6.0)
NeoZero(&stat, sizeof(stat));
buf = &stat;
size = sizeof(stat);
stat.Header.Type = NDIS_OBJECT_TYPE_DEFAULT;
stat.Header.Revision = NDIS_STATISTICS_INFO_REVISION_1;
stat.Header.Size = NDIS_SIZEOF_STATISTICS_INFO_REVISION_1;
stat.SupportedStatistics =
NDIS_STATISTICS_FLAGS_VALID_DIRECTED_FRAMES_RCV |
NDIS_STATISTICS_FLAGS_VALID_MULTICAST_FRAMES_RCV |
NDIS_STATISTICS_FLAGS_VALID_BROADCAST_FRAMES_RCV |
NDIS_STATISTICS_FLAGS_VALID_BYTES_RCV |
NDIS_STATISTICS_FLAGS_VALID_RCV_DISCARDS |
NDIS_STATISTICS_FLAGS_VALID_RCV_ERROR |
NDIS_STATISTICS_FLAGS_VALID_DIRECTED_FRAMES_XMIT |
NDIS_STATISTICS_FLAGS_VALID_MULTICAST_FRAMES_XMIT |
NDIS_STATISTICS_FLAGS_VALID_BROADCAST_FRAMES_XMIT |
NDIS_STATISTICS_FLAGS_VALID_BYTES_XMIT |
NDIS_STATISTICS_FLAGS_VALID_XMIT_ERROR |
NDIS_STATISTICS_FLAGS_VALID_XMIT_DISCARDS |
NDIS_STATISTICS_FLAGS_VALID_DIRECTED_BYTES_RCV |
NDIS_STATISTICS_FLAGS_VALID_MULTICAST_BYTES_RCV |
NDIS_STATISTICS_FLAGS_VALID_BROADCAST_BYTES_RCV |
NDIS_STATISTICS_FLAGS_VALID_DIRECTED_BYTES_XMIT |
NDIS_STATISTICS_FLAGS_VALID_MULTICAST_BYTES_XMIT |
NDIS_STATISTICS_FLAGS_VALID_BROADCAST_BYTES_XMIT;
stat.ifInErrors = ctx->Status.Int64NumRecvError;
stat.ifHCInOctets = ctx->Status.Int64BytesRecvTotal;
stat.ifHCInUcastPkts = ctx->Status.Int64NumRecvUnicast;
stat.ifHCInBroadcastPkts = ctx->Status.Int64NumRecvBroadcast;
stat.ifHCOutOctets = ctx->Status.Int64BytesSendTotal;
stat.ifHCOutUcastPkts = ctx->Status.Int64NumSendUnicast;
stat.ifHCOutBroadcastPkts = ctx->Status.Int64NumSendBroadcast;
stat.ifOutErrors = ctx->Status.Int64NumSendError;
stat.ifHCInUcastOctets = ctx->Status.Int64BytesRecvUnicast;
stat.ifHCInBroadcastOctets = ctx->Status.Int64BytesRecvBroadcast;
stat.ifHCOutUcastOctets = ctx->Status.Int64BytesSendUnicast;
stat.ifHCOutBroadcastOctets = ctx->Status.Int64BytesSendBroadcast;
break;
case OID_GEN_INTERRUPT_MODERATION:
// Interrupt Moderation (NDIS 6.0)
NeoZero(&intp, sizeof(intp));
buf = &intp;
size = sizeof(intp);
intp.Header.Type = NDIS_OBJECT_TYPE_DEFAULT;
intp.Header.Revision = NDIS_INTERRUPT_MODERATION_PARAMETERS_REVISION_1;
intp.Header.Size = NDIS_SIZEOF_INTERRUPT_MODERATION_PARAMETERS_REVISION_1;
intp.InterruptModeration = NdisInterruptModerationNotSupported;
break;
default:
// Unknown OID
*BytesWritten = 0;
return NDIS_STATUS_INVALID_OID;
}
if (size > InformationBufferLength)
{
// Undersize
*BytesNeeded = size;
*BytesWritten = 0;
return NDIS_STATUS_INVALID_LENGTH;
}
// Data copy
NeoCopy(InformationBuffer, buf, size);
*BytesWritten = size;
return NDIS_STATUS_SUCCESS;
}
// Set the cable connection state
void NeoSetConnectState(BOOL connected)
{
if (ctx == NULL)
{
return;
}
ctx->Connected = connected;
NeoCheckConnectState();
}
// Check the cable connection state
void NeoCheckConnectState()
{
NDIS_STATUS_INDICATION t;
NDIS_LINK_STATE state;
if (ctx == NULL || ctx->NdisMiniport == NULL)
{
return;
}
NeoZero(&t, sizeof(t));
t.Header.Type = NDIS_OBJECT_TYPE_STATUS_INDICATION;
t.Header.Revision = NDIS_STATUS_INDICATION_REVISION_1;
t.Header.Size = NDIS_SIZEOF_STATUS_INDICATION_REVISION_1;
t.SourceHandle = ctx->NdisMiniport;
NeoZero(&state, sizeof(state));
state.Header.Type = NDIS_OBJECT_TYPE_DEFAULT;
state.Header.Revision = NDIS_LINK_STATE_REVISION_1;
state.Header.Size = NDIS_SIZEOF_LINK_STATE_REVISION_1;
state.MediaDuplexState = NdisPauseFunctionsSendAndReceive;
state.XmitLinkSpeed = state.RcvLinkSpeed = max_speed;
state.PauseFunctions = NdisPauseFunctionsUnsupported;
t.StatusCode = NDIS_STATUS_LINK_STATE;
t.StatusBuffer = &state;
t.StatusBufferSize = sizeof(NDIS_LINK_STATE);
if (keep_link == false)
{
if (ctx->ConnectedOld != ctx->Connected || ctx->ConnectedForce)
{
ctx->ConnectedForce = FALSE;
ctx->ConnectedOld = ctx->Connected;
if (ctx->Halting == FALSE)
{
state.MediaConnectState = ctx->Connected ? MediaConnectStateConnected : MediaConnectStateDisconnected;
NdisMIndicateStatusEx(ctx->NdisMiniport, &t);
}
}
}
else
{
if (ctx->ConnectedForce)
{
ctx->ConnectedForce = false;
if (ctx->Halting == FALSE)
{
state.MediaConnectState = MediaConnectStateConnected;
NdisMIndicateStatusEx(ctx->NdisMiniport, &t);
}
}
}
}
// Information setting handler of adapter
NDIS_STATUS NeoNdisSet(
NDIS_HANDLE MiniportAdapterContext,
NDIS_OID Oid,
void *InformationBuffer,
ULONG InformationBufferLength,
ULONG *BytesRead,
ULONG *BytesNeeded)
{
if (ctx == NULL)
{
return STATUS_UNSUCCESSFUL;
}
// Initialization
*BytesRead = 0;
*BytesNeeded = 0;
// Branch processing
switch (Oid)
{
case OID_GEN_CURRENT_PACKET_FILTER:
/* Packet filter */
if (InformationBufferLength != 4)
{
*BytesNeeded = 4;
return NDIS_STATUS_INVALID_LENGTH;
}
*BytesRead = 4;
ctx->CurrentPacketFilter = *((UINT *)InformationBuffer);
return NDIS_STATUS_SUCCESS;
// case OID_GEN_PROTOCOL_OPTIONS:
/* Current protocol option value */
/* if (InformationBufferLength != 4)
{
*BytesNeeded = 4;
return NDIS_STATUS_INVALID_LENGTH;
}
*BytesRead = 4;
ctx->CurrentProtocolOptions = *((UINT *)InformationBuffer);
return NDIS_STATUS_SUCCESS;*/
case OID_GEN_CURRENT_LOOKAHEAD:
/* Look ahead */
if (InformationBufferLength != 4)
{
*BytesNeeded = 4;
return NDIS_STATUS_INVALID_LENGTH;
}
*BytesRead = 4;
return NDIS_STATUS_SUCCESS;
case OID_GEN_LINK_PARAMETERS:
// NDIS 6.0 Link setting
*BytesRead = InformationBufferLength;
return NDIS_STATUS_SUCCESS;
case OID_802_3_MULTICAST_LIST:
// Multicast list
*BytesRead = InformationBufferLength;
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return NDIS_STATUS_SUCCESS;
case OID_PNP_SET_POWER:
case OID_PNP_QUERY_POWER:
// Power events
*BytesRead = InformationBufferLength;
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return NDIS_STATUS_SUCCESS;
}
return NDIS_STATUS_INVALID_OID;
}
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// Set status values of NET_BUFFER_LISTs
void NeoNdisSetNetBufferListsStatus(NET_BUFFER_LIST *nbl, UINT status)
{
if (nbl == NULL)
{
return;
}
while (nbl != NULL)
{
NET_BUFFER_LIST_STATUS(nbl) = status;
nbl = NET_BUFFER_LIST_NEXT_NBL(nbl);
}
}
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// Packet send handler
void NeoNdisSendNetBufferLists(NDIS_HANDLE MiniportAdapterContext,
NET_BUFFER_LIST *NetBufferLists,
NDIS_PORT_NUMBER PortNumber,
ULONG SendFlags)
{
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bool is_dispatch_level = SendFlags & NDIS_SEND_FLAGS_DISPATCH_LEVEL;
UINT send_complete_flags = 0;
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if (ctx == NULL)
{
return;
}
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if (is_dispatch_level)
{
send_complete_flags |= NDIS_SEND_COMPLETE_FLAGS_DISPATCH_LEVEL;
}
InterlockedIncrement(&ctx->NumCurrentDispatch);
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// Update the connection state
NeoCheckConnectState();
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if (ctx->Halting != FALSE || ctx->Opened == FALSE || ctx->Paused)
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{
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UINT status = NDIS_STATUS_FAILURE;
if (ctx->Paused)
{
status = NDIS_STATUS_PAUSED;
}
else if (ctx->Halting)
{
status = NDIS_STATUS_FAILURE;
}
else if (ctx->Opened == false && keep_link)
{
status = NDIS_STATUS_SUCCESS;
}
NeoNdisSetNetBufferListsStatus(NetBufferLists, status);
InterlockedDecrement(&ctx->NumCurrentDispatch);
NdisMSendNetBufferListsComplete(ctx->NdisMiniport, NetBufferLists, send_complete_flags);
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return;
}
// Operation of the packet queue
NeoLockPacketQueue();
{
NET_BUFFER_LIST *nbl;
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if (ctx->Halting != FALSE || ctx->Opened == FALSE || ctx->Paused)
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{
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UINT status = NDIS_STATUS_FAILURE;
if (ctx->Paused)
{
status = NDIS_STATUS_PAUSED;
}
else if (ctx->Halting)
{
status = NDIS_STATUS_FAILURE;
}
else if (ctx->Opened == false && keep_link)
{
status = NDIS_STATUS_SUCCESS;
}
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NeoUnlockPacketQueue();
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NeoNdisSetNetBufferListsStatus(NetBufferLists, status);
InterlockedDecrement(&ctx->NumCurrentDispatch);
NdisMSendNetBufferListsComplete(ctx->NdisMiniport, NetBufferLists, send_complete_flags);
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return;
}
nbl = NetBufferLists;
while (nbl != NULL)
{
NET_BUFFER *nb = NET_BUFFER_LIST_FIRST_NB(nbl);
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NET_BUFFER_LIST_STATUS(nbl) = NDIS_STATUS_SUCCESS;
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while (nb != NULL)
{
UINT size = NET_BUFFER_DATA_LENGTH(nb);
if (size >= NEO_MIN_PACKET_SIZE && size <= NEO_MAX_PACKET_SIZE)
{
UCHAR *buf = NeoMalloc(size);
void *ptr;
ptr = NdisGetDataBuffer(nb, size, buf, 1, 0);
if (ptr == NULL)
{
ctx->Status.NumPacketSendError++;
ctx->Status.Int64NumSendError++;
NeoFree(buf);
}
else
{
if (ptr != buf)
{
NeoCopy(buf, ptr, size);
}
NeoInsertQueue(buf, size);
ctx->Status.NumPacketSend++;
if (buf[0] & 0x40)
{
ctx->Status.Int64NumSendBroadcast++;
ctx->Status.Int64BytesSendBroadcast += (UINT64)size;
}
else
{
ctx->Status.Int64NumSendUnicast++;
ctx->Status.Int64BytesSendUnicast += (UINT64)size;
}
ctx->Status.Int64BytesSendTotal += (UINT64)size;
}
}
else
{
ctx->Status.NumPacketSendError++;
ctx->Status.Int64NumSendError++;
}
nb = NET_BUFFER_NEXT_NB(nb);
}
nbl = NET_BUFFER_LIST_NEXT_NBL(nbl);
}
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// Reception event
NeoSet(ctx->Event);
}
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NeoUnlockPacketQueue();
// Notify the transmission completion
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InterlockedDecrement(&ctx->NumCurrentDispatch);
NdisMSendNetBufferListsComplete(ctx->NdisMiniport, NetBufferLists, send_complete_flags);
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}
// Initialize the packet array
void NeoInitPacketArray()
{
UINT i;
// Create a packet buffer
for (i = 0;i < NEO_MAX_PACKET_EXCHANGE;i++)
{
ctx->PacketBuffer[i] = NeoNewPacketBuffer();
}
}
// Release the packet array
void NeoFreePacketArray()
{
UINT i;
for (i = 0;i < NEO_MAX_PACKET_EXCHANGE;i++)
{
NeoFreePacketBuffer(ctx->PacketBuffer[i]);
ctx->PacketBuffer[i] = NULL;
}
}
// Release the packet buffer
void NeoFreePacketBuffer(PACKET_BUFFER *p)
{
// Validate arguments
if (p == NULL)
{
return;
}
// Release the NET_BUFFER_LIST
NdisFreeNetBufferList(p->NetBufferList);
// Release the NET_BUFFER_LIST pool
NdisFreeNetBufferListPool(p->NetBufferListPool);
// Release the memory
NeoFree(p);
}
// Create a packet buffer
PACKET_BUFFER *NeoNewPacketBuffer()
{
PACKET_BUFFER *p;
NET_BUFFER_LIST_POOL_PARAMETERS p1;
// Memory allocation
p = NeoZeroMalloc(sizeof(PACKET_BUFFER));
// Create a NET_BUFFER_LIST pool
NeoZero(&p1, sizeof(p1));
p1.Header.Type = NDIS_OBJECT_TYPE_DEFAULT;
p1.Header.Revision = NET_BUFFER_LIST_POOL_PARAMETERS_REVISION_1;
p1.Header.Size = NDIS_SIZEOF_NET_BUFFER_LIST_POOL_PARAMETERS_REVISION_1;
p1.ProtocolId = NDIS_PROTOCOL_ID_DEFAULT;
p1.fAllocateNetBuffer = TRUE;
p1.DataSize = NEO_MAX_PACKET_SIZE;
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p1.PoolTag = 'SETH';
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p->NetBufferListPool = NdisAllocateNetBufferListPool(NULL, &p1);
// Create a NET_BUFFER_LIST
p->NetBufferList = NdisAllocateNetBufferList(p->NetBufferListPool, 0, 0);
return p;
}
// Reset the event
void NeoReset(NEO_EVENT *event)
{
// Validate arguments
if (event == NULL)
{
return;
}
KeResetEvent(event->event);
}
// Set the event
void NeoSet(NEO_EVENT *event)
{
// Validate arguments
if (event == NULL)
{
return;
}
KeSetEvent(event->event, 0, FALSE);
}
// Release the event
void NeoFreeEvent(NEO_EVENT *event)
{
// Validate arguments
if (event == NULL)
{
return;
}
ZwClose(event->event_handle);
// Release the memory
NeoFree(event);
}
// Create a new event
NEO_EVENT *NeoNewEvent(char *name)
{
UNICODE *unicode_name;
NEO_EVENT *event;
// Validate arguments
if (name == NULL)
{
return NULL;
}
// Convert the name to Unicode
unicode_name = NewUnicode(name);
if (unicode_name == NULL)
{
return NULL;
}
// Memory allocation
event = NeoZeroMalloc(sizeof(NEO_EVENT));
if (event == NULL)
{
FreeUnicode(unicode_name);
return NULL;
}
// Create an Event
event->event = IoCreateNotificationEvent(GetUnicode(unicode_name), &event->event_handle);
if (event->event == NULL)
{
NeoFree(event);
FreeUnicode(unicode_name);
return NULL;
}
// Initialize the event
KeInitializeEvent(event->event, NotificationEvent, FALSE);
KeClearEvent(event->event);
// Release a string
FreeUnicode(unicode_name);
return event;
}
// Get the Unicode string
NDIS_STRING *GetUnicode(UNICODE *u)
{
// Validate arguments
if (u == NULL)
{
return NULL;
}
return &u->String;
}
// Release the Unicode strings
void FreeUnicode(UNICODE *u)
{
// Validate arguments
if (u == NULL)
{
return;
}
// Release a string
NdisFreeString(u->String);
// Release the memory
NeoFree(u);
}
// Create a new Unicode string
UNICODE *NewUnicode(char *str)
{
UNICODE *u;
// Validate arguments
if (str == NULL)
{
return NULL;
}
// Memory allocation
u = NeoZeroMalloc(sizeof(UNICODE));
if (u == NULL)
{
return NULL;
}
// String initialization
NdisInitializeString(&u->String, str);
return u;
}
// Release the lock
void NeoFreeLock(NEO_LOCK *lock)
{
NDIS_SPIN_LOCK *spin_lock;
// Validate arguments
if (lock == NULL)
{
return;
}
spin_lock = &lock->spin_lock;
NdisFreeSpinLock(spin_lock);
// Release the memory
NeoFree(lock);
}
// Unlock
void NeoUnlock(NEO_LOCK *lock)
{
NDIS_SPIN_LOCK *spin_lock;
// Validate arguments
if (lock == NULL)
{
return;
}
spin_lock = &lock->spin_lock;
NdisReleaseSpinLock(spin_lock);
}
// Lock
void NeoLock(NEO_LOCK *lock)
{
NDIS_SPIN_LOCK *spin_lock;
// Validate arguments
if (lock == NULL)
{
return;
}
spin_lock = &lock->spin_lock;
NdisAcquireSpinLock(spin_lock);
}
// Creating a new lock
NEO_LOCK *NeoNewLock()
{
NDIS_SPIN_LOCK *spin_lock;
// Memory allocation
NEO_LOCK *lock = NeoZeroMalloc(sizeof(NEO_LOCK));
if (lock == NULL)
{
return NULL;
}
// Initialize spin lock
spin_lock = &lock->spin_lock;
NdisAllocateSpinLock(spin_lock);
return lock;
}
// Memory copy
void NeoCopy(void *dst, void *src, UINT size)
{
// Validate arguments
if (dst == NULL || src == NULL || size == 0)
{
return;
}
// Copy
NdisMoveMemory(dst, src, size);
}
// Memory clear
void NeoZero(void *dst, UINT size)
{
// Validate arguments
if (dst == NULL || size == 0)
{
return;
}
// Clear
NdisZeroMemory(dst, size);
}
// Clear to zero by memory allocation
void *NeoZeroMalloc(UINT size)
{
void *p = NeoMalloc(size);
if (p == NULL)
{
// Memory allocation failure
return NULL;
}
// Clear to zero
NeoZero(p, size);
return p;
}
// Memory allocation
void *NeoMalloc(UINT size)
{
NDIS_STATUS r;
void *p;
if (size == 0)
{
size = 1;
}
// Allocate the non-paged memory
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r = NdisAllocateMemoryWithTag(&p, size, 'SETH');
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if (NG(r))
{
return NULL;
}
return p;
}
// Release the memory
void NeoFree(void *p)
{
// Validate arguments
if (p == NULL)
{
return;
}
// Release the memory
NdisFreeMemory(p, 0, 0);
}
// 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/