Counter Strike : Global Offensive Source Code
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
 
 
 
 
 
 

1005 lines
41 KiB

//-------------------------------------------------------------------------------------
// CpuTopology.cpp
//
// CpuToplogy class implementation.
//
// Copyright (c) Microsoft Corporation. All rights reserved.
//-------------------------------------------------------------------------------------
#include "pch_tier0.h"
#if defined(_WIN32) && !defined(_X360) && !defined( _PS3 )
#include "cputopology.h"
#include <stdlib.h>
#include <crtdbg.h>
#undef malloc
#undef free
#ifdef _WIN64
#include "intrin.h"
#endif
//---------------------------------------------------------------------------------
// Name: ICpuToplogy
// Desc: Specifies the interface that each class that provides an implementation
// for extracting cpu topology must conform to. This is the Implementor
// class in the traditional Bridge Pattern.
//---------------------------------------------------------------------------------
class ICpuTopology
{
public:
virtual ~ICpuTopology()
{
}
virtual BOOL IsDefaultImpl() const = 0;
virtual DWORD NumberOfProcessCores() const = 0;
virtual DWORD NumberOfSystemCores() const = 0;
virtual DWORD_PTR CoreAffinityMask( DWORD coreIdx ) const = 0;
};
namespace
{
///////////////////////////////////////////////////////////////////////////////////
// Local Class Definitions
///////////////////////////////////////////////////////////////////////////////////
//---------------------------------------------------------------------------------
// Name: DefaultImpl
// Desc: Provides a default implementation for the ICpuTopology interface when
// GetLogicalProcessorInformation and CPUID are not supported for whatever
// reason. This is a ConcreteImplementor class in the traditional Bridge
// Pattern.
//---------------------------------------------------------------------------------
class DefaultImpl : public ICpuTopology
{
public:
//-----------------------------------------------------------------------------
// DefaultImpl::IsDefaultImpl
//-----------------------------------------------------------------------------
/*virtual*/ BOOL IsDefaultImpl() const
{
return TRUE;
}
//-----------------------------------------------------------------------------
// DefaultImpl::NumberOfProcessCores
//-----------------------------------------------------------------------------
/*virtual*/ DWORD NumberOfProcessCores() const
{
return 1;
}
//-----------------------------------------------------------------------------
// DefaultImpl::IsNumberOfSystemCores
//-----------------------------------------------------------------------------
/*virtual*/ DWORD NumberOfSystemCores() const
{
return 1;
}
//-----------------------------------------------------------------------------
// DefaultImpl::CoreAffinityMask
//-----------------------------------------------------------------------------
/*virtual*/ DWORD_PTR CoreAffinityMask( DWORD coreIdx ) const
{
DWORD_PTR coreAffinity = 0;
if( 1 == coreIdx )
{
DWORD_PTR dwSystemAffinity;
GetProcessAffinityMask( GetCurrentProcess(), &coreAffinity, &dwSystemAffinity );
}
return coreAffinity;
}
};
//---------------------------------------------------------------------------------
// Name: GlpiImpl
// Desc: Provides the GetLogicalProcessorInformation implementation for the
// ICpuTopology interface. This is a ConcreteImplementor class in the
// traditional Bridge Pattern.
//---------------------------------------------------------------------------------
class GlpiImpl : public ICpuTopology
{
public:
//-----------------------------------------------------------------------------
// Name: GlpiImpl::GlpiImpl
// Desc: Initializes the internal structures/data with information retrieved
// from a call to GetLogicalProcessorInformation.
//-----------------------------------------------------------------------------
GlpiImpl() : m_pSlpi( NULL ),
m_nItems( 0 )
{
_ASSERT( IsSupported() );
GlpiFnPtr pGlpi = GetGlpiFn_();
_ASSERT( pGlpi );
DWORD cbBuffer = 0;
pGlpi( 0, &cbBuffer );
m_pSlpi = ( SYSTEM_LOGICAL_PROCESSOR_INFORMATION* )malloc( cbBuffer );
pGlpi( m_pSlpi, &cbBuffer );
m_nItems = cbBuffer / sizeof( SYSTEM_LOGICAL_PROCESSOR_INFORMATION );
}
//-----------------------------------------------------------------------------
// Name: GlpiImpl::~GlpiImpl
//-----------------------------------------------------------------------------
/*virtual*/ ~GlpiImpl()
{
free( m_pSlpi );
m_pSlpi = 0;
m_nItems = 0;
}
//-----------------------------------------------------------------------------
// Name: GlpiImpl::IsDefaultImpl
//-----------------------------------------------------------------------------
/*virtual*/ BOOL IsDefaultImpl() const
{
return FALSE;
}
//-----------------------------------------------------------------------------
// Name: GlpiImpl::NumberOfProcessCores
// Desc: Gets the total number of physical processor cores available to the
// current process.
//-----------------------------------------------------------------------------
/*virtual*/ DWORD NumberOfProcessCores() const
{
DWORD_PTR dwProcessAffinity, dwSystemAffinity;
GetProcessAffinityMask( GetCurrentProcess(), &dwProcessAffinity, &dwSystemAffinity );
DWORD nCores = 0;
for( DWORD i = 0; i < m_nItems; ++i )
{
if( ( RelationProcessorCore == m_pSlpi[i].Relationship ) &&
( m_pSlpi[i].ProcessorMask & dwProcessAffinity ) )
{
++nCores;
}
}
return nCores;
}
//-----------------------------------------------------------------------------
// Name: GlpiImpl::NumberOfSystemCores
// Desc: Gets the total number of physical processor cores enabled on the
// system.
//-----------------------------------------------------------------------------
/*virtual*/ DWORD NumberOfSystemCores() const
{
DWORD nCores = 0;
for( DWORD i = 0; i < m_nItems; ++i )
{
if( RelationProcessorCore == m_pSlpi[i].Relationship )
++nCores;
}
return nCores;
}
//-----------------------------------------------------------------------------
// Name: GlpiImpl::CoreAffinityMask
// Desc: Gets an affinity mask that corresponds to the requested processor
// core.
//-----------------------------------------------------------------------------
/*virtual*/ DWORD_PTR CoreAffinityMask( DWORD coreIdx ) const
{
DWORD_PTR dwProcessAffinity, dwSystemAffinity;
GetProcessAffinityMask( GetCurrentProcess(), &dwProcessAffinity, &dwSystemAffinity );
for( DWORD i = 0; i < m_nItems; ++i )
{
if( RelationProcessorCore == m_pSlpi[i].Relationship )
{
if( !coreIdx-- )
{
return m_pSlpi[i].ProcessorMask & dwProcessAffinity;
}
}
}
return 0;
}
//-----------------------------------------------------------------------------
// Name: GlpiImpl::IsSupported
//-----------------------------------------------------------------------------
static BOOL IsSupported()
{
return NULL != GetGlpiFn_();
}
private:
// GetLogicalProcessorInformation function pointer
typedef BOOL( WINAPI* GlpiFnPtr )(
SYSTEM_LOGICAL_PROCESSOR_INFORMATION*,
PDWORD
);
//-----------------------------------------------------------------------------
// Name: GlpiImpl::VerifyGlpiFn_
// Desc: Gets a pointer to the GetLogicalProcessorInformation function only if
// it is supported on the current platform.
// GetLogicalProcessorInformation is supported on Windows Server 2003 and
// XP64, however there is a bug with the implementation. Therefore, only
// GetLogicalProcessorInformation on Windows Vista is supported in this
// sample.
//-----------------------------------------------------------------------------
static GlpiFnPtr VerifyGlpiFn_()
{
// VerifyVersionInfo function pointer
typedef BOOL ( WINAPI* VviFnPtr )( LPOSVERSIONINFOEX,
DWORD,
DWORDLONG );
HMODULE hMod = GetModuleHandle( TEXT( "kernel32" ) );
#ifdef _UNICODE
VviFnPtr pVvi = (VviFnPtr) GetProcAddress( hMod, "VerifyVersionInfoW" );
#else
VviFnPtr pVvi = ( VviFnPtr )GetProcAddress( hMod, "VerifyVersionInfoA" );
#endif
GlpiFnPtr pGlpi = NULL;
if( pVvi )
{
// VerSetConditionMask function pointer
typedef ULONGLONG ( WINAPI* VscmFnPtr )( ULONGLONG,
DWORD,
BYTE );
VscmFnPtr pVscm = ( VscmFnPtr )GetProcAddress( hMod, "VerSetConditionMask" );
_ASSERT( pVscm );
// Check for Windows Vista
OSVERSIONINFOEX osvi = { sizeof( OSVERSIONINFOEX ) };
osvi.dwMajorVersion = 6;
osvi.dwMinorVersion = 0;
osvi.wServicePackMajor = 0;
osvi.wServicePackMinor = 0;
ULONGLONG dwlMask = 0;
dwlMask = pVscm( dwlMask, VER_MAJORVERSION, VER_GREATER_EQUAL );
dwlMask = pVscm( dwlMask, VER_MINORVERSION, VER_GREATER_EQUAL );
dwlMask = pVscm( dwlMask, VER_SERVICEPACKMAJOR, VER_GREATER_EQUAL );
dwlMask = pVscm( dwlMask, VER_SERVICEPACKMINOR, VER_GREATER_EQUAL );
if( pVvi( &osvi, VER_MAJORVERSION
| VER_MINORVERSION
| VER_SERVICEPACKMAJOR
| VER_SERVICEPACKMINOR,
dwlMask ) )
{
pGlpi = ( GlpiFnPtr )GetProcAddress( hMod, "GetLogicalProcessorInformation" );
_ASSERT( pGlpi );
}
}
return pGlpi;
}
//-----------------------------------------------------------------------------
// Name: GlpiImpl::GetGlpiFn_
// Desc: Gets a cached pointer to the GetLogicalProcessorInformation function.
//-----------------------------------------------------------------------------
static GlpiFnPtr GetGlpiFn_()
{
static GlpiFnPtr pGlpi = VerifyGlpiFn_();
return pGlpi;
}
// Private Members
SYSTEM_LOGICAL_PROCESSOR_INFORMATION* m_pSlpi;
DWORD m_nItems;
};
//---------------------------------------------------------------------------------
// Name: ApicExtractor
// Desc: A utility class that provides an interface for decoding a processor
// APIC ID. An APIC ID is an 8-bit identifier given to each logical
// processor on system boot and can be retrieved by the CPUID instruction.
// Each APIC ID is composed of a PACKAGE_ID, CORE_ID and SMT_ID that describe
// the relationship of a logical processor within the processor topology of
// the system.
//---------------------------------------------------------------------------------
class ApicExtractor
{
public:
//-----------------------------------------------------------------------------
// Name: ApicExtractor::ApicExtractor
//-----------------------------------------------------------------------------
ApicExtractor( DWORD nLogProcsPerPkg = 1, DWORD nCoresPerPkg = 1 )
{
SetPackageTopology( nLogProcsPerPkg, nCoresPerPkg );
}
//-----------------------------------------------------------------------------
// Name: ApicExtractor::SmtId
//-----------------------------------------------------------------------------
BYTE SmtId( BYTE apicId ) const
{
return apicId & m_smtIdMask.mask;
}
//-----------------------------------------------------------------------------
// Name: ApicExtractor::CoreId
//-----------------------------------------------------------------------------
BYTE CoreId( BYTE apicId ) const
{
return ( apicId & m_coreIdMask.mask ) >> m_smtIdMask.width;
}
//-----------------------------------------------------------------------------
// Name: ApicExtractor::PackageId
//-----------------------------------------------------------------------------
BYTE PackageId( BYTE apicId ) const
{
return ( apicId & m_pkgIdMask.mask ) >>
( m_smtIdMask.width + m_coreIdMask.width );
}
//-----------------------------------------------------------------------------
// Name: ApicExtractor::PackageCoreId
//-----------------------------------------------------------------------------
BYTE PackageCoreId( BYTE apicId ) const
{
return ( apicId & ( m_pkgIdMask.mask | m_coreIdMask.mask ) ) >>
m_smtIdMask.width;
}
//-----------------------------------------------------------------------------
// Name: ApicExtractor::GetLogProcsPerPkg
//-----------------------------------------------------------------------------
DWORD GetLogProcsPerPkg() const
{
return m_nLogProcsPerPkg;
}
//-----------------------------------------------------------------------------
// Name: ApicExtractor::GetCoresPerPkg
//-----------------------------------------------------------------------------
DWORD GetCoresPerPkg() const
{
return m_nCoresPerPkg;
}
//-----------------------------------------------------------------------------
// Name: ApicExtractor::SetPackageTopology
// Desc: You should call SetPackageTopology with the number of logical
// processors per package and number of cores per package before calling
// the sub id accessors (SmtId(), CoreId(), PackageId(), PackageCoreId())
// as this information is required to effectively decode an APIC ID into
// its sub parts.
//-----------------------------------------------------------------------------
void SetPackageTopology( DWORD nLogProcsPerPkg, DWORD nCoresPerPkg )
{
m_nLogProcsPerPkg = ( BYTE )nLogProcsPerPkg;
m_nCoresPerPkg = ( BYTE )nCoresPerPkg;
// fix for Phenom x3 and similar CPUs - it reports 3 logical processors per package, and 4 cores per package
// so one core is probably just disabled for yield, but it causes a bug in GetMaskWidth that propagates
if( m_nCoresPerPkg > m_nLogProcsPerPkg )
{
m_nCoresPerPkg = m_nLogProcsPerPkg;
}
m_smtIdMask.width = GetMaskWidth_( m_nLogProcsPerPkg / m_nCoresPerPkg );
m_coreIdMask.width = GetMaskWidth_( m_nCoresPerPkg );
m_pkgIdMask.width = 8 - ( m_smtIdMask.width + m_coreIdMask.width );
m_pkgIdMask.mask = ( BYTE )( 0xFF << ( m_smtIdMask.width + m_coreIdMask.width ) );
m_coreIdMask.mask = ( BYTE )( ( 0xFF << m_smtIdMask.width ) ^ m_pkgIdMask.mask );
m_smtIdMask.mask = ( BYTE )~( 0xFF << m_smtIdMask.width );
}
private:
//-----------------------------------------------------------------------------
// Name: ApicExtractor::GetMaskWidth_
// Desc: Gets the width of a sub id bit field in an APIC ID. The width of a
// sub id (CORE_ID, SMT_ID) is only wide enough to support the maximum
// number of ids that needs to be represented in the topology.
//-----------------------------------------------------------------------------
static BYTE GetMaskWidth_( BYTE maxIds )
{
--maxIds;
// find index of msb
BYTE msbIdx = 8;
BYTE msbMask = 0x80;
while( msbMask && !( msbMask & maxIds ) )
{
--msbIdx;
msbMask >>= 1;
}
return msbIdx;
}
struct IdMask
{
BYTE width;
BYTE mask;
};
// Private Members
BYTE m_nLogProcsPerPkg;
BYTE m_nCoresPerPkg;
IdMask m_smtIdMask;
IdMask m_coreIdMask;
IdMask m_pkgIdMask;
};
//---------------------------------------------------------------------------------
// Name: Cpuid
// Desc: A utility class that wraps the functionality of the CPUID instruction.
// Call the Call() method with the desired CPUID function, and use the
// register accessors to retrieve the register values.
//---------------------------------------------------------------------------------
class Cpuid
{
public:
// FnSet values are used to indicate a CPUID function set.
enum FnSet
{
Std = 0x00000000,
Ext = 0x80000000
};
//-----------------------------------------------------------------------------
// Name: Cpuid::Cpuid
//-----------------------------------------------------------------------------
Cpuid() : m_eax( 0 ),
m_ebx( 0 ),
m_ecx( 0 ),
m_edx( 0 )
{
}
// Register accessors
DWORD Eax() const
{
return m_eax;
}
DWORD Ebx() const
{
return m_ebx;
}
DWORD Ecx() const
{
return m_ecx;
}
DWORD Edx() const
{
return m_edx;
}
//-----------------------------------------------------------------------------
// Name: Cpuid::Call
// Desc: Calls the CPUID instruction with the specified function. Returns TRUE
// if the CPUID function was supported, FALSE if it wasn't.
//-----------------------------------------------------------------------------
BOOL Call( FnSet fnSet, DWORD fn )
{
if( IsFnSupported( fnSet, fn ) )
{
UncheckedCall_( fnSet, fn );
return true;
}
return false;
}
//-----------------------------------------------------------------------------
// Name: Cpuid::IsVendor
// Desc: Compares a string with the vendor string encoded in the CPUID
// instruction.
//-----------------------------------------------------------------------------
static BOOL IsVendor( const char* strVendor )
{
// Cache the vendor string
static const Cpuid cpu( Std );
return cpu.Ebx() == *reinterpret_cast<const DWORD*>( strVendor )
&& cpu.Ecx() == *reinterpret_cast<const DWORD*>( strVendor + 8 )
&& cpu.Edx() == *reinterpret_cast<const DWORD*>( strVendor + 4 );
}
//-----------------------------------------------------------------------------
// Name: Cpuid::IsFnSupported
// Desc: Checks to see if a CPUID function is supported. Different processors
// support different functions. This method is automatically called from
// the Call() method, so you don't need to call it beforehand.
//-----------------------------------------------------------------------------
static BOOL IsFnSupported( FnSet fnSet, DWORD fn )
{
// Cache the maximum supported standard function
static const DWORD MaxStdFn = Cpuid( Std ).Eax();
// Cache the maximum supported extended function
static const DWORD MaxExtFn = Cpuid( Ext ).Eax();
bool ret = false;
switch( fnSet )
{
case Std:
ret = ( fn <= MaxStdFn );
break;
case Ext:
ret = ( fn <= MaxExtFn );
break;
default:
_ASSERT( 0 ); // should never get here
break;
}
return ret;
}
private:
//-----------------------------------------------------------------------------
// Name: Cpuid::Cpuid
// Desc: This constructor is private and is only used to set a Cpuid object to
// initial values retrieved from CPUID functions 0x00000000 and
// 0x80000000. Good for caching values from the CPUID instruction that
// are not variable, like the encoded vendor string and the maximum
// supported CPUID function values.
//-----------------------------------------------------------------------------
explicit Cpuid( FnSet fnSet )
{
UncheckedCall_( fnSet, 0 );
}
//-----------------------------------------------------------------------------
// Name: Cpuid::UncheckedCall_
// Desc: Calls the CPUID instruction without checking for CPUID function
// support.
//-----------------------------------------------------------------------------
void UncheckedCall_( FnSet fnSet, DWORD fn )
{
#ifdef _WIN64
int out[4];
__cpuidex( out, fnSet | fn, 0 );
m_eax = out[0];
m_ebx = out[1];
m_ecx = out[2];
m_edx = out[3];
#else
__asm
{
mov ecx, 0
mov eax, fn
or eax, fnSet
cpuid
mov edi, this
mov [edi].m_eax, eax
mov [edi].m_ebx, ebx
mov [edi].m_ecx, ecx
mov [edi].m_edx, edx
}
#endif
}
// Private Members
DWORD m_eax;
DWORD m_ebx;
DWORD m_ecx;
DWORD m_edx;
};
//---------------------------------------------------------------------------------
// Name: CpuidImpl
// Desc: Provides the CPUID instruction implementation for the ICpuTopology
// interface. This is a ConcreteImplementor class in the traditional Bridge
// Pattern.
//---------------------------------------------------------------------------------
class CpuidImpl : public ICpuTopology
{
public:
// CpuidFnMasks are used when extracting bit-encoded information retrieved from
// the CPUID instruction
enum CpuidFnMasks
{
HTT = 0x10000000, // Fn0000_0001 EDX[28]
LogicalProcessorCount = 0x00FF0000, // Fn0000_0001 EBX[23:16]
ApicId = 0xFF000000, // Fn0000_0001 EBX[31:24]
NC_Intel = 0xFC000000, // Fn0000_0004 EAX[31:26]
NC_Amd = 0x000000FF, // Fn8000_0008 ECX[7:0]
CmpLegacy_Amd = 0x00000002, // Fn8000_0001 ECX[1]
ApicIdCoreIdSize_Amd = 0x0000F000 // Fn8000_0008 ECX[15:12]
};
enum
{
MaxLogicalProcessors = sizeof( DWORD_PTR ) * 8
};
//-----------------------------------------------------------------------------
// Name: CpuidImpl::CpuidImpl
// Desc: Initializes internal structures/data with information retrieved from
// calling the CPUID instruction.
//-----------------------------------------------------------------------------
CpuidImpl() : m_nItems( 0 )
{
_ASSERT( IsSupported() );
DWORD nLogProcsPerPkg = 1;
DWORD nCoresPerPkg = 1;
Cpuid cpu;
// Determine if hardware threading is enabled.
cpu.Call( Cpuid::Std, 1 );
if( cpu.Edx() & HTT )
{
// Determine the total number of logical processors per package.
nLogProcsPerPkg = ( cpu.Ebx() & LogicalProcessorCount ) >> 16;
// Determine the total number of cores per package. This info
// is extracted differently dependending on the cpu vendor.
if( Cpuid::IsVendor( GenuineIntel ) )
{
if( cpu.Call( Cpuid::Std, 4 ) )
{
nCoresPerPkg = ( ( cpu.Eax() & NC_Intel ) >> 26 ) + 1;
}
}
else
{
_ASSERT( Cpuid::IsVendor( AuthenticAMD ) );
if( cpu.Call( Cpuid::Ext, 8 ) )
{
// AMD reports the msb width of the CORE_ID bit field of the APIC ID
// in ApicIdCoreIdSize_Amd. The maximum value represented by the msb
// width is the theoretical number of cores the processor can support
// and not the actual number of current cores, which is how the msb width
// of the CORE_ID bit field has been traditionally determined. If the
// ApicIdCoreIdSize_Amd value is zero, then you use the traditional method
// to determine the CORE_ID msb width.
DWORD msbWidth = cpu.Ecx() & ApicIdCoreIdSize_Amd;
if( msbWidth )
{
// Set nCoresPerPkg to the maximum theortical number of cores
// the processor package can support (2 ^ width) so the APIC
// extractor object can be configured to extract the proper
// values from an APIC.
nCoresPerPkg = 1 << ( msbWidth >> 12 );
}
else
{
// Set nCoresPerPkg to the actual number of cores being reported
// by the CPUID instruction.
nCoresPerPkg = ( cpu.Ecx() & NC_Amd ) + 1;
}
}
}
}
// Configure the APIC extractor object with the information it needs to
// be able to decode the APIC.
m_apicExtractor.SetPackageTopology( nLogProcsPerPkg, nCoresPerPkg );
DWORD_PTR dwProcessAffinity, dwSystemAffinity;
HANDLE hProcess = GetCurrentProcess();
HANDLE hThread = GetCurrentThread();
GetProcessAffinityMask( hProcess, &dwProcessAffinity, &dwSystemAffinity );
if( 1 == dwSystemAffinity )
{
// Since we only have 1 logical processor present on the system, we
// can explicitly set a single APIC ID to zero.
_ASSERT( 1 == nLogProcsPerPkg );
m_apicIds[m_nItems++] = 0;
}
else
{
// Set the process affinity to the system affinity if they are not
// equal so that all logical processors can be accounted for.
if( dwProcessAffinity != dwSystemAffinity )
{
SetProcessAffinityMask( hProcess, dwSystemAffinity );
}
// Call cpuid on each active logical processor in the system affinity.
DWORD_PTR dwPrevThreadAffinity = 0;
for( DWORD_PTR dwThreadAffinity = 1;
dwThreadAffinity && dwThreadAffinity <= dwSystemAffinity;
dwThreadAffinity <<= 1 )
{
if( dwSystemAffinity & dwThreadAffinity )
{
if( 0 == dwPrevThreadAffinity )
{
// Save the previous thread affinity so we can return
// the executing thread affinity back to this state.
_ASSERT( 0 == m_nItems );
dwPrevThreadAffinity = SetThreadAffinityMask( hThread,
dwThreadAffinity );
}
else
{
_ASSERT( m_nItems > 0 );
SetThreadAffinityMask( hThread, dwThreadAffinity );
}
// Allow the thread to switch to masked logical processor.
Sleep( 0 );
// Store the APIC ID
cpu.Call( Cpuid::Std, 1 );
m_apicIds[m_nItems++] = ( BYTE )( ( cpu.Ebx() & ApicId ) >> 24 );
}
}
// Restore the previous process and thread affinity state.
SetProcessAffinityMask( hProcess, dwProcessAffinity );
SetThreadAffinityMask( hThread, dwPrevThreadAffinity );
Sleep( 0 );
}
}
//-----------------------------------------------------------------------------
// Name: CpuidImpl::IsDefaultImpl
//-----------------------------------------------------------------------------
/*virtual*/ BOOL IsDefaultImpl() const
{
return FALSE;
}
//-----------------------------------------------------------------------------
// Name: CpuidImpl::NumberOfProcessCores
// Desc: Gets the number of processor cores available to the current process.
// The total accounts for cores that may have been masked out by process
// affinity.
//-----------------------------------------------------------------------------
/*virtual*/ DWORD NumberOfProcessCores() const
{
DWORD_PTR dwProcessAffinity, dwSystemAffinity;
GetProcessAffinityMask( GetCurrentProcess(), &dwProcessAffinity, &dwSystemAffinity );
BYTE pkgCoreIds[MaxLogicalProcessors] = { 0 };
DWORD nPkgCoreIds = 0;
for( DWORD i = 0; i < m_nItems; ++i )
{
if( dwProcessAffinity & ( ( DWORD_PTR )1 << i ) )
{
AddUniquePkgCoreId_( i, pkgCoreIds, nPkgCoreIds );
}
}
return nPkgCoreIds;
}
//-----------------------------------------------------------------------------
// Name: CpuidImpl::NumberOfSystemCores
// Desc: Gets the number of processor cores on the system.
//-----------------------------------------------------------------------------
/*virtual*/ DWORD NumberOfSystemCores() const
{
BYTE pkgCoreIds[MaxLogicalProcessors] = { 0 };
DWORD nPkgCoreIds = 0;
for( DWORD i = 0; i < m_nItems; ++i )
{
AddUniquePkgCoreId_( i, pkgCoreIds, nPkgCoreIds );
}
return nPkgCoreIds;
}
//-----------------------------------------------------------------------------
// Name: CpuidImpl::CoreAffinityMask
// Desc: Gets an affinity mask that corresponds to a specific processor core.
// coreIdx must be less than the total number of processor cores
// recognized by the operating system (NumberOfSystemCores()).
//-----------------------------------------------------------------------------
/*virtual*/ DWORD_PTR CoreAffinityMask( DWORD coreIdx ) const
{
BYTE pkgCoreIds[MaxLogicalProcessors] = { 0 };
DWORD nPkgCoreIds = 0;
for( DWORD i = 0; i < m_nItems; ++i )
{
AddUniquePkgCoreId_( i, pkgCoreIds, nPkgCoreIds );
}
DWORD_PTR dwProcessAffinity, dwSystemAffinity;
GetProcessAffinityMask( GetCurrentProcess(), &dwProcessAffinity, &dwSystemAffinity );
DWORD_PTR coreAffinity = 0;
if( coreIdx < nPkgCoreIds )
{
for( DWORD i = 0; i < m_nItems; ++i )
{
if( m_apicExtractor.PackageCoreId( m_apicIds[i] ) == pkgCoreIds[coreIdx] )
{
coreAffinity |= ( dwProcessAffinity & ( ( DWORD_PTR )1 << i ) );
}
}
}
return coreAffinity;
}
//-----------------------------------------------------------------------------
// Name: CpuidImpl::IsSupported
// Desc: Indicates if a CpuidImpl object is supported on this platform.
// Support is only granted on Intel and AMD platforms where the current
// calling process has security rights to query process affinity and
// change it if the process and system affinity differ. CpuidImpl is
// also not supported if thread affinity cannot be set on systems with
// more than 1 logical processor.
//-----------------------------------------------------------------------------
static BOOL IsSupported()
{
BOOL bSupported = Cpuid::IsVendor( GenuineIntel )
|| Cpuid::IsVendor( AuthenticAMD );
if( bSupported )
{
DWORD_PTR dwProcessAffinity, dwSystemAffinity;
HANDLE hProcess = GetCurrentProcess();
// Query process affinity mask
bSupported = GetProcessAffinityMask( hProcess, &dwProcessAffinity, &dwSystemAffinity );
if( bSupported )
{
if( dwProcessAffinity != dwSystemAffinity )
{
// The process and system affinities differ. Attempt to set
// the process affinity to the system affinity.
bSupported = SetProcessAffinityMask( hProcess, dwSystemAffinity );
if( bSupported )
{
// Restore previous process affinity
bSupported = SetProcessAffinityMask( hProcess, dwProcessAffinity );
}
}
if( bSupported && ( dwSystemAffinity > 1 ) )
{
// Attempt to set the thread affinity
HANDLE hThread = GetCurrentThread();
DWORD_PTR dwThreadAffinity = SetThreadAffinityMask( hThread, dwProcessAffinity );
if( dwThreadAffinity )
{
// Restore the previous thread affinity
bSupported = 0 != SetThreadAffinityMask( hThread, dwThreadAffinity );
}
else
{
bSupported = FALSE;
}
}
}
}
return bSupported;
}
private:
//-----------------------------------------------------------------------------
// Name: CpuidImpl::AddUniquePkgCoreId_
// Desc: Adds the package/core id extracted from the APIC ID at m_apicIds[idx]
// in the if the package/core id is unique to the pkgCoreIds array.
// nPkgCore is an in/out parm that will reflect the total number of items
// in pkgCoreIds array. It will be incrememted if a unique package/core
// id is found and added.
//-----------------------------------------------------------------------------
void AddUniquePkgCoreId_( DWORD idx, BYTE* pkgCoreIds, DWORD& nPkgCoreIds ) const
{
_ASSERT( idx < m_nItems );
_ASSERT( NULL != pkgCoreIds );
DWORD j;
for( j = 0; j < nPkgCoreIds; ++j )
{
if( pkgCoreIds[j] == m_apicExtractor.PackageCoreId( m_apicIds[idx] ) )
break;
}
if( j == nPkgCoreIds )
{
pkgCoreIds[j] = m_apicExtractor.PackageCoreId( m_apicIds[idx] );
++nPkgCoreIds;
}
}
// Private Members
BYTE m_apicIds[MaxLogicalProcessors];
BYTE m_nItems;
ApicExtractor m_apicExtractor;
// Supported Vendor Strings
static const char GenuineIntel[];
static const char AuthenticAMD[];
};
// Static initialization of vendor strings
const char CpuidImpl::GenuineIntel[] = "GenuineIntel";
const char CpuidImpl::AuthenticAMD[] = "AuthenticAMD";
} // unnamed-namespace
//-------------------------------------------------------------------------------------
// Name: CpuTopology::CpuTopology
// Desc: Initializes this object with the appropriately supported cpu topology
// implementation object.
//-------------------------------------------------------------------------------------
CpuTopology::CpuTopology( BOOL bForceCpuid ) : m_pImpl( NULL )
{
ForceCpuid( bForceCpuid );
}
//-------------------------------------------------------------------------------------
// Name: CpuTopology::~CpuTopology
//-------------------------------------------------------------------------------------
CpuTopology::~CpuTopology()
{
Destroy_();
}
//-------------------------------------------------------------------------------------
// Name: CpuTopology::NumberOfProcessCores
// Desc: Gets the total number of physical processor cores available to the current
// process.
//-------------------------------------------------------------------------------------
DWORD CpuTopology::NumberOfProcessCores() const
{
return m_pImpl->NumberOfProcessCores();
}
//-------------------------------------------------------------------------------------
// Name: CpuTopology::NumberOfSystemCores
// Desc: Gets the total number of physical processor cores enabled on the system.
//-------------------------------------------------------------------------------------
DWORD CpuTopology::NumberOfSystemCores() const
{
return m_pImpl->NumberOfSystemCores();
}
//-------------------------------------------------------------------------------------
// Name: CpuTopology::CoreAffinityMask
// Desc: Gets an affinity mask that corresponds to the requested processor core.
//-------------------------------------------------------------------------------------
DWORD_PTR CpuTopology::CoreAffinityMask( DWORD coreIdx ) const
{
return m_pImpl->CoreAffinityMask( coreIdx );
}
//-------------------------------------------------------------------------------------
// Name: CpuTopology::IsDefaultImpl
// Desc: Returns TRUE if m_pImpl is a DefaultImpl object, FALSE if not. Used to
// indicate whether or not the prescribed methods (CPUID or
// GetLogicalProcessorInformation) are supported on the system.
//-------------------------------------------------------------------------------------
BOOL CpuTopology::IsDefaultImpl() const
{
return m_pImpl->IsDefaultImpl();
}
//-------------------------------------------------------------------------------------
// Name: CpuTopology::ForceCpuid
// Desc: Constructs a cpu topology object. If bForce is FALSE, then a GlpiImpl object
// is first attempted, then CpuidImpl, then finally DefaultImpl. If bForce is
// TRUE, then GlpiImpl is never attempted.
//-------------------------------------------------------------------------------------
void CpuTopology::ForceCpuid( BOOL bForce )
{
Destroy_();
if( !bForce && GlpiImpl::IsSupported() )
{
m_pImpl = new GlpiImpl();
}
else if( CpuidImpl::IsSupported() )
{
m_pImpl = new CpuidImpl();
}
else
{
m_pImpl = new DefaultImpl();
}
}
//-------------------------------------------------------------------------------------
// Name: CpuTopology::Destroy_
//-------------------------------------------------------------------------------------
void CpuTopology::Destroy_()
{
delete m_pImpl;
m_pImpl = NULL;
}
#endif