reactos/rosapps/taskmgr/perfdata.cpp

/*
 *  ReactOS Task Manager
 *
 *  perfdata.cpp
 *
 *  Copyright (C) 1999 - 2001  Brian Palmer  <brianp@reactos.org>
 *
 *  This program is free software; you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation; either version 2 of the License, or
 *  (at your option) any later version.
 *
 *  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
 *  along with this program; if not, write to the Free Software
 *  Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
 */
	
#ifdef _MSC_VER
#include "stdafx.h"
#else
#define WIN32_LEAN_AND_MEAN		// Exclude rarely-used stuff from Windows headers
#include <windows.h>
#include <commctrl.h>
#include <stdlib.h>
#include <malloc.h>
#include <memory.h>
#include <tchar.h>
#include <process.h>
#include <stdio.h>
#endif
	
#include "TaskMgr.h"
#include "perfdata.h"

PROCNTQSI						NtQuerySystemInformation = NULL;
PROCGGR							GetGuiResources = NULL;
PROCGPIC						GetProcessIoCounters = NULL;
CRITICAL_SECTION				PerfDataCriticalSection;
PPERFDATA						pPerfDataOld = NULL;	// Older perf data (saved to establish delta values)
PPERFDATA						pPerfData = NULL;		// Most recent copy of perf data
ULONG							ProcessCountOld = 0;
ULONG							ProcessCount = 0;
double							dbIdleTime;
double							dbKernelTime;
double							dbSystemTime;
LARGE_INTEGER					liOldIdleTime = {0,0};
double							OldKernelTime = 0;
LARGE_INTEGER					liOldSystemTime = {0,0};
SYSTEM_PERFORMANCE_INFORMATION	SystemPerfInfo;
SYSTEM_BASIC_INFORMATION		SystemBasicInfo;
SYSTEM_CACHE_INFORMATION		SystemCacheInfo;
SYSTEM_HANDLE_INFORMATION		SystemHandleInfo;
PSYSTEM_PROCESSORTIME_INFO		SystemProcessorTimeInfo = NULL;

BOOL PerfDataInitialize(void)
{
	LONG	status;

	NtQuerySystemInformation = (PROCNTQSI)GetProcAddress(GetModuleHandle("ntdll.dll"), "NtQuerySystemInformation");
	GetGuiResources = (PROCGGR)GetProcAddress(GetModuleHandle("user32.dll"), "GetGuiResources");
	GetProcessIoCounters = (PROCGPIC)GetProcAddress(GetModuleHandle("kernel32.dll"), "GetProcessIoCounters");
	
	InitializeCriticalSection(&PerfDataCriticalSection);
	
	if (!NtQuerySystemInformation)
		return FALSE;
	
	//
	// Get number of processors in the system
	//
	status = NtQuerySystemInformation(SystemBasicInformation, &SystemBasicInfo, sizeof(SystemBasicInfo), NULL);
	if (status != NO_ERROR)
		return FALSE;
	
	return TRUE;
}

void PerfDataUninitialize(void)
{
	NtQuerySystemInformation = NULL;

	DeleteCriticalSection(&PerfDataCriticalSection);
}

void PerfDataRefresh(void)
{
	ULONG							ulSize;
	LONG							status;
	LPBYTE							pBuffer;
	ULONG							BufferSize;
	PSYSTEM_PROCESS_INFORMATION		pSPI;
	PPERFDATA						pPDOld;
	ULONG							Idx, Idx2;
	HANDLE							hProcess;
	HANDLE							hProcessToken;
	TCHAR							szTemp[MAX_PATH];
	DWORD							dwSize;
	SYSTEM_PERFORMANCE_INFORMATION	SysPerfInfo;
	SYSTEM_TIME_INFORMATION			SysTimeInfo;
	SYSTEM_CACHE_INFORMATION		SysCacheInfo;
	LPBYTE							SysHandleInfoData;
	PSYSTEM_PROCESSORTIME_INFO		SysProcessorTimeInfo;
	double							CurrentKernelTime;
	

	if (!NtQuerySystemInformation)
		return;

	// Get new system time
	status = NtQuerySystemInformation(SystemTimeInformation, &SysTimeInfo, sizeof(SysTimeInfo), 0);
	if (status != NO_ERROR)
		return;

	// Get new CPU's idle time
	status = NtQuerySystemInformation(SystemPerformanceInformation, &SysPerfInfo, sizeof(SysPerfInfo), NULL);
	if (status != NO_ERROR)
		return;

	// Get system cache information
	status = NtQuerySystemInformation(SystemCacheInformation, &SysCacheInfo, sizeof(SysCacheInfo), NULL);
	if (status != NO_ERROR)
		return;
	
	// Get processor time information
	SysProcessorTimeInfo = new SYSTEM_PROCESSORTIME_INFO[SystemBasicInfo.bKeNumberProcessors];
	status = NtQuerySystemInformation(SystemProcessorTimeInformation, SysProcessorTimeInfo, sizeof(SYSTEM_PROCESSORTIME_INFO) * SystemBasicInfo.bKeNumberProcessors, &ulSize);
	if (status != NO_ERROR)
		return;
	
	// Get handle information
	// We don't know how much data there is so just keep
	// increasing the buffer size until the call succeeds
	BufferSize = 0;
	do
	{
		BufferSize += 0x10000;
		SysHandleInfoData = new BYTE[BufferSize];
		
		status = NtQuerySystemInformation(SystemHandleInformation, SysHandleInfoData, BufferSize, &ulSize);
		
		if (status == 0xC0000004 /*STATUS_INFO_LENGTH_MISMATCH*/)
			delete[] SysHandleInfoData;
		
	} while (status == 0xC0000004 /*STATUS_INFO_LENGTH_MISMATCH*/);

	// Get process information
	// We don't know how much data there is so just keep
	// increasing the buffer size until the call succeeds
	BufferSize = 0;
	do
	{
		BufferSize += 0x10000;
		pBuffer = new BYTE[BufferSize];

		status = NtQuerySystemInformation(SystemProcessInformation, pBuffer, BufferSize, &ulSize);

		if (status == 0xC0000004 /*STATUS_INFO_LENGTH_MISMATCH*/)
			delete[] pBuffer;

	} while (status == 0xC0000004 /*STATUS_INFO_LENGTH_MISMATCH*/);

	EnterCriticalSection(&PerfDataCriticalSection);

	//
	// Save system performance info
	//
	memcpy(&SystemPerfInfo, &SysPerfInfo, sizeof(SYSTEM_PERFORMANCE_INFORMATION));

	//
	// Save system cache info
	//
	memcpy(&SystemCacheInfo, &SysCacheInfo, sizeof(SYSTEM_CACHE_INFORMATION));
	
	//
	// Save system processor time info
	//
	if (SystemProcessorTimeInfo)
	{
		delete[] SystemProcessorTimeInfo;
	}
	SystemProcessorTimeInfo = SysProcessorTimeInfo;
	
	//
	// Save system handle info
	//
	memcpy(&SystemHandleInfo, SysHandleInfoData, sizeof(SYSTEM_HANDLE_INFORMATION));
	delete[] SysHandleInfoData;
	
	for (CurrentKernelTime=0, Idx=0; Idx<SystemBasicInfo.bKeNumberProcessors; Idx++)
	{
		CurrentKernelTime += Li2Double(SystemProcessorTimeInfo[Idx].KernelTime);
		CurrentKernelTime += Li2Double(SystemProcessorTimeInfo[Idx].DpcTime);
		CurrentKernelTime += Li2Double(SystemProcessorTimeInfo[Idx].InterruptTime);
	}

	// If it's a first call - skip idle time calcs
	if (liOldIdleTime.QuadPart != 0)
	{
		// CurrentValue = NewValue - OldValue
		dbIdleTime = Li2Double(SysPerfInfo.liIdleTime) - Li2Double(liOldIdleTime);
		dbKernelTime = CurrentKernelTime - OldKernelTime;
		dbSystemTime = Li2Double(SysTimeInfo.liKeSystemTime) - Li2Double(liOldSystemTime);

		// CurrentCpuIdle = IdleTime / SystemTime
		dbIdleTime = dbIdleTime / dbSystemTime;
		dbKernelTime = dbKernelTime / dbSystemTime;
		
		// CurrentCpuUsage% = 100 - (CurrentCpuIdle * 100) / NumberOfProcessors
		dbIdleTime = 100.0 - dbIdleTime * 100.0 / (double)SystemBasicInfo.bKeNumberProcessors;// + 0.5;
		dbKernelTime = 100.0 - dbKernelTime * 100.0 / (double)SystemBasicInfo.bKeNumberProcessors;// + 0.5;
	}

	// Store new CPU's idle and system time
	liOldIdleTime = SysPerfInfo.liIdleTime;
	liOldSystemTime = SysTimeInfo.liKeSystemTime;
	OldKernelTime = CurrentKernelTime;

	// Determine the process count
	// We loop through the data we got from NtQuerySystemInformation
	// and count how many structures there are (until RelativeOffset is 0)
	ProcessCountOld = ProcessCount;
	ProcessCount = 0;
	pSPI = (PSYSTEM_PROCESS_INFORMATION)pBuffer;
	while (pSPI)
	{
		ProcessCount++;

		if (pSPI->RelativeOffset == 0)
			break;

		pSPI = (PSYSTEM_PROCESS_INFORMATION)((LPBYTE)pSPI + pSPI->RelativeOffset);
	}

	// Now alloc a new PERFDATA array and fill in the data
	if (pPerfDataOld)
		delete[] pPerfDataOld;
	pPerfDataOld = pPerfData;
	pPerfData = new PERFDATA[ProcessCount];
	pSPI = (PSYSTEM_PROCESS_INFORMATION)pBuffer;
	for (Idx=0; Idx<ProcessCount; Idx++)
	{
		// Get the old perf data for this process (if any)
		// so that we can establish delta values
		pPDOld = NULL;
		for (Idx2=0; Idx2<ProcessCountOld; Idx2++)
		{
			if (pPerfDataOld[Idx2].ProcessId == pSPI->ProcessId)
			{
				pPDOld = &pPerfDataOld[Idx2];
				break;
			}
		}

		// Clear out process perf data structure
		memset(&pPerfData[Idx], 0, sizeof(PERFDATA));

		if (pSPI->Name.Buffer)
			wcscpy(pPerfData[Idx].ImageName, pSPI->Name.Buffer);
		else
			wcscpy(pPerfData[Idx].ImageName, L"System Idle Process");

		pPerfData[Idx].ProcessId = pSPI->ProcessId;

		if (pPDOld)
		{
			double	CurTime = Li2Double(pSPI->KernelTime) + Li2Double(pSPI->UserTime);
			double	OldTime = Li2Double(pPDOld->KernelTime) + Li2Double(pPDOld->UserTime);

			double	CpuTime = (CurTime - OldTime) / dbSystemTime;

			CpuTime = CpuTime * 100.0 / (double)SystemBasicInfo.bKeNumberProcessors;// + 0.5;

			pPerfData[Idx].CPUUsage = (ULONG)CpuTime;
		}
		pPerfData[Idx].CPUTime.QuadPart = pSPI->UserTime.QuadPart + pSPI->KernelTime.QuadPart;
		pPerfData[Idx].WorkingSetSizeBytes = pSPI->TotalWorkingSetSizeBytes;
		pPerfData[Idx].PeakWorkingSetSizeBytes = pSPI->PeakWorkingSetSizeBytes;
		if (pPDOld)
			pPerfData[Idx].WorkingSetSizeDelta = labs((LONG)pSPI->TotalWorkingSetSizeBytes - (LONG)pPDOld->WorkingSetSizeBytes);
		else
			pPerfData[Idx].WorkingSetSizeDelta = 0;
		pPerfData[Idx].PageFaultCount = pSPI->PageFaultCount;
		if (pPDOld)
			pPerfData[Idx].PageFaultCountDelta = labs((LONG)pSPI->PageFaultCount - (LONG)pPDOld->PageFaultCount);
		else
			pPerfData[Idx].PageFaultCountDelta = 0;
		pPerfData[Idx].VirtualMemorySizeBytes = pSPI->TotalVirtualSizeBytes;
		pPerfData[Idx].PagedPoolUsagePages = pSPI->TotalPagedPoolUsagePages;
		pPerfData[Idx].NonPagedPoolUsagePages = pSPI->TotalNonPagedPoolUsagePages;
		pPerfData[Idx].BasePriority = pSPI->BasePriority;
		pPerfData[Idx].HandleCount = pSPI->HandleCount;
		pPerfData[Idx].ThreadCount = pSPI->ThreadCount;

		pPerfData[Idx].SessionId = pSPI->SessionId;
		
		hProcess = OpenProcess(PROCESS_QUERY_INFORMATION, FALSE, pSPI->ProcessId);
		if (hProcess)
		{
			if (OpenProcessToken(hProcess, TOKEN_QUERY|TOKEN_DUPLICATE|TOKEN_IMPERSONATE, &hProcessToken))
			{
				ImpersonateLoggedOnUser(hProcessToken);
				memset(szTemp, 0, sizeof(TCHAR[MAX_PATH]));
				dwSize = MAX_PATH;
				GetUserName(szTemp, &dwSize);
				MultiByteToWideChar(CP_ACP, MB_PRECOMPOSED, szTemp, -1, pPerfData[Idx].UserName, MAX_PATH);
				RevertToSelf();
				
				CloseHandle(hProcessToken);
			}
			
			if (GetGuiResources)
			{
				pPerfData[Idx].USERObjectCount = GetGuiResources(hProcess, GR_USEROBJECTS);
				pPerfData[Idx].GDIObjectCount = GetGuiResources(hProcess, GR_GDIOBJECTS);
			}
			if (GetProcessIoCounters)
				GetProcessIoCounters(hProcess, &pPerfData[Idx].IOCounters);
			
			CloseHandle(hProcess);
		}
		
		pPerfData[Idx].UserTime.QuadPart = pSPI->UserTime.QuadPart;
		pPerfData[Idx].KernelTime.QuadPart = pSPI->KernelTime.QuadPart;
		
		pSPI = (PSYSTEM_PROCESS_INFORMATION)((LPBYTE)pSPI + pSPI->RelativeOffset);
	}

	delete[] pBuffer;

	LeaveCriticalSection(&PerfDataCriticalSection);
}

ULONG PerfDataGetProcessCount(void)
{
	return ProcessCount;
}

ULONG PerfDataGetProcessorUsage(void)
{
	return (ULONG)dbIdleTime;
}

ULONG PerfDataGetProcessorSystemUsage(void)
{
	return (ULONG)dbKernelTime;
}

BOOL PerfDataGetImageName(ULONG Index, LPTSTR lpImageName, int nMaxCount)
{
	BOOL	bSuccessful;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
	{
		#ifdef _UNICODE
			wcsncpy(lpImageName, pPerfData[Index].ImageName, nMaxCount);
		#else
			WideCharToMultiByte(CP_ACP, 0, pPerfData[Index].ImageName, -1, lpImageName, nMaxCount, NULL, NULL);
		#endif

		bSuccessful = TRUE;
	}
	else
		bSuccessful = FALSE;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return bSuccessful;
}

ULONG PerfDataGetProcessId(ULONG Index)
{
	ULONG	ProcessId;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		ProcessId = pPerfData[Index].ProcessId;
	else
		ProcessId = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return ProcessId;
}

BOOL PerfDataGetUserName(ULONG Index, LPTSTR lpUserName, int nMaxCount)
{
	BOOL	bSuccessful;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
	{
		#ifdef _UNICODE
			wcsncpy(lpUserName, pPerfData[Index].UserName, nMaxCount);
		#else
			WideCharToMultiByte(CP_ACP, 0, pPerfData[Index].UserName, -1, lpUserName, nMaxCount, NULL, NULL);
		#endif

		bSuccessful = TRUE;
	}
	else
		bSuccessful = FALSE;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return bSuccessful;
}

ULONG PerfDataGetSessionId(ULONG Index)
{
	ULONG	SessionId;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		SessionId = pPerfData[Index].SessionId;
	else
		SessionId = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return SessionId;
}

ULONG PerfDataGetCPUUsage(ULONG Index)
{
	ULONG	CpuUsage;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		CpuUsage = pPerfData[Index].CPUUsage;
	else
		CpuUsage = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return CpuUsage;
}

TIME PerfDataGetCPUTime(ULONG Index)
{
	TIME	CpuTime = {0,0};

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		CpuTime = pPerfData[Index].CPUTime;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return CpuTime;
}

ULONG PerfDataGetWorkingSetSizeBytes(ULONG Index)
{
	ULONG	WorkingSetSizeBytes;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		WorkingSetSizeBytes = pPerfData[Index].WorkingSetSizeBytes;
	else
		WorkingSetSizeBytes = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return WorkingSetSizeBytes;
}

ULONG PerfDataGetPeakWorkingSetSizeBytes(ULONG Index)
{
	ULONG	PeakWorkingSetSizeBytes;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		PeakWorkingSetSizeBytes = pPerfData[Index].PeakWorkingSetSizeBytes;
	else
		PeakWorkingSetSizeBytes = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return PeakWorkingSetSizeBytes;
}

ULONG PerfDataGetWorkingSetSizeDelta(ULONG Index)
{
	ULONG	WorkingSetSizeDelta;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		WorkingSetSizeDelta = pPerfData[Index].WorkingSetSizeDelta;
	else
		WorkingSetSizeDelta = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return WorkingSetSizeDelta;
}

ULONG PerfDataGetPageFaultCount(ULONG Index)
{
	ULONG	PageFaultCount;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		PageFaultCount = pPerfData[Index].PageFaultCount;
	else
		PageFaultCount = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return PageFaultCount;
}

ULONG PerfDataGetPageFaultCountDelta(ULONG Index)
{
	ULONG	PageFaultCountDelta;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		PageFaultCountDelta = pPerfData[Index].PageFaultCountDelta;
	else
		PageFaultCountDelta = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return PageFaultCountDelta;
}

ULONG PerfDataGetVirtualMemorySizeBytes(ULONG Index)
{
	ULONG	VirtualMemorySizeBytes;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		VirtualMemorySizeBytes = pPerfData[Index].VirtualMemorySizeBytes;
	else
		VirtualMemorySizeBytes = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return VirtualMemorySizeBytes;
}

ULONG PerfDataGetPagedPoolUsagePages(ULONG Index)
{
	ULONG	PagedPoolUsagePages;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		PagedPoolUsagePages = pPerfData[Index].PagedPoolUsagePages;
	else
		PagedPoolUsagePages = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return PagedPoolUsagePages;
}

ULONG PerfDataGetNonPagedPoolUsagePages(ULONG Index)
{
	ULONG	NonPagedPoolUsagePages;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		NonPagedPoolUsagePages = pPerfData[Index].NonPagedPoolUsagePages;
	else
		NonPagedPoolUsagePages = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return NonPagedPoolUsagePages;
}

ULONG PerfDataGetBasePriority(ULONG Index)
{
	ULONG	BasePriority;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		BasePriority = pPerfData[Index].BasePriority;
	else
		BasePriority = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return BasePriority;
}

ULONG PerfDataGetHandleCount(ULONG Index)
{
	ULONG	HandleCount;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		HandleCount = pPerfData[Index].HandleCount;
	else
		HandleCount = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return HandleCount;
}

ULONG PerfDataGetThreadCount(ULONG Index)
{
	ULONG	ThreadCount;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		ThreadCount = pPerfData[Index].ThreadCount;
	else
		ThreadCount = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return ThreadCount;
}

ULONG PerfDataGetUSERObjectCount(ULONG Index)
{
	ULONG	USERObjectCount;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		USERObjectCount = pPerfData[Index].USERObjectCount;
	else
		USERObjectCount = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return USERObjectCount;
}

ULONG PerfDataGetGDIObjectCount(ULONG Index)
{
	ULONG	GDIObjectCount;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
		GDIObjectCount = pPerfData[Index].GDIObjectCount;
	else
		GDIObjectCount = 0;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return GDIObjectCount;
}

BOOL PerfDataGetIOCounters(ULONG Index, PIO_COUNTERS pIoCounters)
{
	BOOL	bSuccessful;

	EnterCriticalSection(&PerfDataCriticalSection);

	if (Index < ProcessCount)
	{
		memcpy(pIoCounters, &pPerfData[Index].IOCounters, sizeof(IO_COUNTERS));
		bSuccessful = TRUE;
	}
	else
		bSuccessful = FALSE;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return bSuccessful;
}

ULONG PerfDataGetCommitChargeTotalK(void)
{
	ULONG	Total;
	ULONG	PageSize;

	EnterCriticalSection(&PerfDataCriticalSection);

	Total = SystemPerfInfo.MmTotalCommitedPages;
	PageSize = SystemBasicInfo.uPageSize;

	LeaveCriticalSection(&PerfDataCriticalSection);

	Total = Total * (PageSize / 1024);

	return Total;
}

ULONG PerfDataGetCommitChargeLimitK(void)
{
	ULONG	Limit;
	ULONG	PageSize;

	EnterCriticalSection(&PerfDataCriticalSection);

	Limit = SystemPerfInfo.MmTotalCommitLimit;
	PageSize = SystemBasicInfo.uPageSize;

	LeaveCriticalSection(&PerfDataCriticalSection);

	Limit = Limit * (PageSize / 1024);

	return Limit;
}

ULONG PerfDataGetCommitChargePeakK(void)
{
	ULONG	Peak;
	ULONG	PageSize;

	EnterCriticalSection(&PerfDataCriticalSection);

	Peak = SystemPerfInfo.MmPeakLimit;
	PageSize = SystemBasicInfo.uPageSize;

	LeaveCriticalSection(&PerfDataCriticalSection);

	Peak = Peak * (PageSize / 1024);

	return Peak;
}

ULONG PerfDataGetKernelMemoryTotalK(void)
{
	ULONG	Total;
	ULONG	Paged;
	ULONG	NonPaged;
	ULONG	PageSize;

	EnterCriticalSection(&PerfDataCriticalSection);

	Paged = SystemPerfInfo.PoolPagedBytes;
	NonPaged = SystemPerfInfo.PoolNonPagedBytes;
	PageSize = SystemBasicInfo.uPageSize;

	LeaveCriticalSection(&PerfDataCriticalSection);

	Paged = Paged * (PageSize / 1024);
	NonPaged = NonPaged * (PageSize / 1024);

	Total = Paged + NonPaged;

	return Total;
}

ULONG PerfDataGetKernelMemoryPagedK(void)
{
	ULONG	Paged;
	ULONG	PageSize;

	EnterCriticalSection(&PerfDataCriticalSection);

	Paged = SystemPerfInfo.PoolPagedBytes;
	PageSize = SystemBasicInfo.uPageSize;

	LeaveCriticalSection(&PerfDataCriticalSection);

	Paged = Paged * (PageSize / 1024);

	return Paged;
}

ULONG PerfDataGetKernelMemoryNonPagedK(void)
{
	ULONG	NonPaged;
	ULONG	PageSize;

	EnterCriticalSection(&PerfDataCriticalSection);

	NonPaged = SystemPerfInfo.PoolNonPagedBytes;
	PageSize = SystemBasicInfo.uPageSize;

	LeaveCriticalSection(&PerfDataCriticalSection);

	NonPaged = NonPaged * (PageSize / 1024);

	return NonPaged;
}

ULONG PerfDataGetPhysicalMemoryTotalK(void)
{
	ULONG	Total;
	ULONG	PageSize;

	EnterCriticalSection(&PerfDataCriticalSection);

	Total = SystemBasicInfo.uMmNumberOfPhysicalPages;
	PageSize = SystemBasicInfo.uPageSize;

	LeaveCriticalSection(&PerfDataCriticalSection);

	Total = Total * (PageSize / 1024);

	return Total;
}

ULONG PerfDataGetPhysicalMemoryAvailableK(void)
{
	ULONG	Available;
	ULONG	PageSize;

	EnterCriticalSection(&PerfDataCriticalSection);

	Available = SystemPerfInfo.MmAvailablePages;
	PageSize = SystemBasicInfo.uPageSize;

	LeaveCriticalSection(&PerfDataCriticalSection);

	Available = Available * (PageSize / 1024);

	return Available;
}

ULONG PerfDataGetPhysicalMemorySystemCacheK(void)
{
	ULONG	SystemCache;
	ULONG	PageSize;

	EnterCriticalSection(&PerfDataCriticalSection);

	SystemCache = SystemCacheInfo.CurrentSize;
	PageSize = SystemBasicInfo.uPageSize;

	LeaveCriticalSection(&PerfDataCriticalSection);

	//SystemCache = SystemCache * (PageSize / 1024);
	SystemCache = SystemCache / 1024;

	return SystemCache;
}

ULONG PerfDataGetSystemHandleCount(void)
{
	ULONG	HandleCount;

	EnterCriticalSection(&PerfDataCriticalSection);

	HandleCount = SystemHandleInfo.Count;

	LeaveCriticalSection(&PerfDataCriticalSection);

	return HandleCount;
}

ULONG PerfDataGetTotalThreadCount(void)
{
	ULONG	ThreadCount = 0;
	ULONG	i;

	EnterCriticalSection(&PerfDataCriticalSection);

	for (i=0; i<ProcessCount; i++)
	{
		ThreadCount += pPerfData[i].ThreadCount;
	}

	LeaveCriticalSection(&PerfDataCriticalSection);

	return ThreadCount;
}