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SoftEtherVPN/src/See/time_calls.h

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2014-01-04 17:00:08 +04:00
/*
* Copyright (c) 2001 - 2005 NetGroup, Politecnico di Torino (Italy)
* Copyright (c) 2005 CACE Technologies, Davis (California)
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. Neither the name of the Politecnico di Torino, CACE Technologies
* nor the names of its contributors may be used to endorse or promote
* products derived from this software without specific prior written
* permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
*/
#ifndef _time_calls
#define _time_calls
#ifdef WIN_NT_DRIVER
#include "debug.h"
#include "ndis.h"
#define DEFAULT_TIMESTAMPMODE 0
#define TIMESTAMPMODE_SINGLE_SYNCHRONIZATION 0
#define TIMESTAMPMODE_SYNCHRONIZATION_ON_CPU_WITH_FIXUP 1
#define TIMESTAMPMODE_QUERYSYSTEMTIME 2
#define TIMESTAMPMODE_RDTSC 3
#define TIMESTAMPMODE_SYNCHRONIZATION_ON_CPU_NO_FIXUP 99
#define TIMESTAMPMODE_REGKEY L"TimestampMode"
extern ULONG TimestampMode;
extern ULONG NCpu;
/*!
\brief A microsecond precise timestamp.
included in the sf_pkthdr or the bpf_hdr that NPF associates with every packet.
*/
struct timeval {
long tv_sec; ///< seconds
long tv_usec; ///< microseconds
};
#endif /*WIN_NT_DRIVER*/
struct time_conv
{
ULONGLONG reference;
struct timeval start[32];
};
#ifdef WIN_NT_DRIVER
__inline void TIME_DESYNCHRONIZE(struct time_conv *data)
{
data->reference = 0;
// data->start.tv_sec = 0;
// data->start.tv_usec = 0;
}
__inline void ReadTimeStampModeFromRegistry(PUNICODE_STRING RegistryPath)
{
ULONG NewLength;
PWSTR NullTerminatedString;
RTL_QUERY_REGISTRY_TABLE Queries[2];
ULONG DefaultTimestampMode = DEFAULT_TIMESTAMPMODE;
NewLength = RegistryPath->Length/2;
NullTerminatedString = ExAllocatePool(PagedPool, (NewLength+1) *sizeof(WCHAR));
if (NullTerminatedString != NULL)
{
RtlCopyMemory(NullTerminatedString, RegistryPath->Buffer, RegistryPath->Length);
NullTerminatedString[NewLength]=0;
RtlZeroMemory(Queries, sizeof(Queries));
Queries[0].Flags = RTL_QUERY_REGISTRY_DIRECT;
Queries[0].Name = TIMESTAMPMODE_REGKEY;
Queries[0].EntryContext = &TimestampMode;
Queries[0].DefaultType = REG_DWORD;
Queries[0].DefaultData = &DefaultTimestampMode;
Queries[0].DefaultLength = sizeof(ULONG);
if (RtlQueryRegistryValues(RTL_REGISTRY_ABSOLUTE, NullTerminatedString, Queries, NULL, NULL) != STATUS_SUCCESS)
{
TimestampMode = DEFAULT_TIMESTAMPMODE;
}
RtlWriteRegistryValue( RTL_REGISTRY_ABSOLUTE, NullTerminatedString, TIMESTAMPMODE_REGKEY, REG_DWORD, &TimestampMode,sizeof(ULONG));
ExFreePool(NullTerminatedString);
}
else
TimestampMode = DEFAULT_TIMESTAMPMODE;
}
#pragma optimize ("g",off) //Due to some weird behaviour of the optimizer of DDK build 2600
/* KeQueryPerformanceCounter TimeStamps */
__inline void SynchronizeOnCpu(struct timeval *start)
{
// struct timeval *start = (struct timeval*)Data;
LARGE_INTEGER SystemTime;
LARGE_INTEGER TimeFreq,PTime;
// get the absolute value of the system boot time.
PTime = KeQueryPerformanceCounter(&TimeFreq);
KeQuerySystemTime(&SystemTime);
start->tv_sec = (LONG)(SystemTime.QuadPart/10000000-11644473600);
start->tv_usec = (LONG)((SystemTime.QuadPart%10000000)/10);
start->tv_sec -= (ULONG)(PTime.QuadPart/TimeFreq.QuadPart);
start->tv_usec -= (LONG)((PTime.QuadPart%TimeFreq.QuadPart)*1000000/TimeFreq.QuadPart);
if (start->tv_usec < 0)
{
start->tv_sec --;
start->tv_usec += 1000000;
}
}
//
// inline assembler is not supported with the current AMD64 compilers
// At the moment we simply disable this timestamping mode on AMD64.
// A solution would be to allocate a small memory from the non-paged
// pool, dump the instructions on that buffer, and then execute them.
// The non paged pool is needed since it's the only area of kernel
// data memory that is not subject to the NX protection.
// Or use some lower level trick, like using an assembler to assemble
// a small function for this.
//
#ifdef __NPF_x86__
/*RDTSC timestamps */
/* callers must be at IRQL=PASSIVE_LEVEL*/
__inline VOID TimeSynchronizeRDTSC(struct time_conv *data)
{
struct timeval tmp;
LARGE_INTEGER system_time;
ULONGLONG curr_ticks;
KIRQL old;
LARGE_INTEGER start_kqpc,stop_kqpc,start_freq,stop_freq;
ULONGLONG start_ticks,stop_ticks;
ULONGLONG delta,delta2;
KEVENT event;
LARGE_INTEGER i;
ULONGLONG reference;
if (data->reference!=0)
return;
KeInitializeEvent(&event,NotificationEvent,FALSE);
i.QuadPart=-3500000;
KeRaiseIrql(HIGH_LEVEL,&old);
start_kqpc=KeQueryPerformanceCounter(&start_freq);
__asm
{
push eax
push edx
push ecx
rdtsc
lea ecx, start_ticks
mov [ecx+4], edx
mov [ecx], eax
pop ecx
pop edx
pop eax
}
KeLowerIrql(old);
KeWaitForSingleObject(&event,UserRequest,KernelMode,TRUE ,&i);
KeRaiseIrql(HIGH_LEVEL,&old);
stop_kqpc=KeQueryPerformanceCounter(&stop_freq);
__asm
{
push eax
push edx
push ecx
rdtsc
lea ecx, stop_ticks
mov [ecx+4], edx
mov [ecx], eax
pop ecx
pop edx
pop eax
}
KeLowerIrql(old);
delta=stop_ticks-start_ticks;
delta2=stop_kqpc.QuadPart-start_kqpc.QuadPart;
if (delta>10000000000)
{
delta/=16;
delta2/=16;
}
reference=delta*(start_freq.QuadPart)/delta2;
data->reference=reference/1000;
if (reference%1000>500)
data->reference++;
data->reference*=1000;
reference=data->reference;
KeQuerySystemTime(&system_time);
__asm
{
push eax
push edx
push ecx
rdtsc
lea ecx, curr_ticks
mov [ecx+4], edx
mov [ecx], eax
pop ecx
pop edx
pop eax
}
tmp.tv_sec=-(LONG)(curr_ticks/reference);
tmp.tv_usec=-(LONG)((curr_ticks%reference)*1000000/reference);
system_time.QuadPart-=116444736000000000;
tmp.tv_sec+=(LONG)(system_time.QuadPart/10000000);
tmp.tv_usec+=(LONG)((system_time.QuadPart%10000000)/10);
if (tmp.tv_usec<0)
{
tmp.tv_sec--;
tmp.tv_usec+=1000000;
}
data->start[0] = tmp;
IF_LOUD(DbgPrint("Frequency %I64u MHz\n",data->reference);)
}
#endif //__NPF_x86__
#pragma optimize ("g",on) //Due to some weird behaviour of the optimizer of DDK build 2600
__inline VOID TIME_SYNCHRONIZE(struct time_conv *data)
{
ULONG NumberOfCpus, i;
KAFFINITY AffinityMask;
if (data->reference != 0)
return;
NumberOfCpus = NCpu;
if ( TimestampMode == TIMESTAMPMODE_SYNCHRONIZATION_ON_CPU_WITH_FIXUP || TimestampMode == TIMESTAMPMODE_SYNCHRONIZATION_ON_CPU_NO_FIXUP)
{
for (i = 0 ; i < NumberOfCpus ; i++ )
{
AffinityMask = (1 << i);
ZwSetInformationThread(NtCurrentThread(), ThreadAffinityMask, &AffinityMask, sizeof(KAFFINITY));
SynchronizeOnCpu(&(data->start[i]));
}
AffinityMask = 0xFFFFFFFF;
ZwSetInformationThread(NtCurrentThread(), ThreadAffinityMask, &AffinityMask, sizeof(KAFFINITY));
data->reference = 1;
}
else
if ( TimestampMode == TIMESTAMPMODE_QUERYSYSTEMTIME )
{
//do nothing
data->reference = 1;
}
else
//
// This timestamp mode is supported on x86 (32 bit) only
//
#ifdef __NPF_x86__
if ( TimestampMode == TIMESTAMPMODE_RDTSC )
{
TimeSynchronizeRDTSC(data);
}
else
#endif // __NPF_x86__
{ //it should be only the normal case i.e. TIMESTAMPMODE_SINGLESYNCHRONIZATION
SynchronizeOnCpu(data->start);
data->reference = 1;
}
return;
}
#pragma optimize ("g",off) //Due to some weird behaviour of the optimizer of DDK build 2600
__inline void GetTimeKQPC(struct timeval *dst, struct time_conv *data)
{
LARGE_INTEGER PTime, TimeFreq;
LONG tmp;
ULONG CurrentCpu;
static struct timeval old_ts={0,0};
PTime = KeQueryPerformanceCounter(&TimeFreq);
tmp = (LONG)(PTime.QuadPart/TimeFreq.QuadPart);
if (TimestampMode == TIMESTAMPMODE_SYNCHRONIZATION_ON_CPU_WITH_FIXUP || TimestampMode == TIMESTAMPMODE_SYNCHRONIZATION_ON_CPU_NO_FIXUP)
{
//actually this code is ok only if we are guaranteed that no thread scheduling will take place.
CurrentCpu = KeGetCurrentProcessorNumber();
dst->tv_sec = data->start[CurrentCpu].tv_sec + tmp;
dst->tv_usec = data->start[CurrentCpu].tv_usec + (LONG)((PTime.QuadPart%TimeFreq.QuadPart)*1000000/TimeFreq.QuadPart);
if (dst->tv_usec >= 1000000)
{
dst->tv_sec ++;
dst->tv_usec -= 1000000;
}
if (TimestampMode == TIMESTAMPMODE_SYNCHRONIZATION_ON_CPU_WITH_FIXUP)
{
if (old_ts.tv_sec > dst->tv_sec || (old_ts.tv_sec == dst->tv_sec && old_ts.tv_usec > dst->tv_usec) )
*dst = old_ts;
else
old_ts = *dst;
}
}
else
{ //it should be only the normal case i.e. TIMESTAMPMODE_SINGLESYNCHRONIZATION
dst->tv_sec = data->start[0].tv_sec + tmp;
dst->tv_usec = data->start[0].tv_usec + (LONG)((PTime.QuadPart%TimeFreq.QuadPart)*1000000/TimeFreq.QuadPart);
if (dst->tv_usec >= 1000000)
{
dst->tv_sec ++;
dst->tv_usec -= 1000000;
}
}
}
//
// inline assembler is not supported with the current AMD64 compilers
// At the moment we simply disable this timestamping mode on AMD64.
// A solution would be to allocate a small memory from the non-paged
// pool, dump the instructions on that buffer, and then execute them.
// The non paged pool is needed since it's the only area of kernel
// data memory that is not subject to the NX protection.
// Or use some lower level trick, like using an assembler to assemble
// a small function for this.
//
#ifdef __NPF_x86__
__inline void GetTimeRDTSC(struct timeval *dst, struct time_conv *data)
{
ULONGLONG tmp;
__asm
{
push eax
push edx
push ecx
rdtsc
lea ecx, tmp
mov [ecx+4], edx
mov [ecx], eax
pop ecx
pop edx
pop eax
}
if (data->reference==0)
{
return;
}
dst->tv_sec=(LONG)(tmp/data->reference);
dst->tv_usec=(LONG)((tmp-dst->tv_sec*data->reference)*1000000/data->reference);
dst->tv_sec+=data->start[0].tv_sec;
dst->tv_usec+=data->start[0].tv_usec;
if (dst->tv_usec>=1000000)
{
dst->tv_sec++;
dst->tv_usec-=1000000;
}
}
#endif //__NPF_x86__
__inline void GetTimeQST(struct timeval *dst, struct time_conv *data)
{
LARGE_INTEGER SystemTime;
KeQuerySystemTime(&SystemTime);
dst->tv_sec = (LONG)(SystemTime.QuadPart/10000000-11644473600);
dst->tv_usec = (LONG)((SystemTime.QuadPart%10000000)/10);
}
#pragma optimize ("g",on) //Due to some weird behaviour of the optimizer of DDK build 2600
__inline void GET_TIME(struct timeval *dst, struct time_conv *data)
{
return;
#if 0
//
// This timestamp mode is supported on x86 (32 bit) only
//
#ifdef __NPF_x86__
if ( TimestampMode == TIMESTAMPMODE_RDTSC )
{
GetTimeRDTSC(dst,data);
}
else
#endif
if ( TimestampMode == TIMESTAMPMODE_QUERYSYSTEMTIME )
{
GetTimeQST(dst,data);
}
else
{
GetTimeKQPC(dst,data);
}
#endif
}
#else /*WIN_NT_DRIVER*/
__inline void FORCE_TIME(struct timeval *src, struct time_conv *dest)
{
dest->start[0]=*src;
}
__inline void GET_TIME(struct timeval *dst, struct time_conv *data)
{
return;
*dst=data->start[0];
}
#endif /*WIN_NT_DRIVER*/
#endif /*_time_calls*/