pcsx2/common/src/x86emitter/cpudetect.cpp

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/* Cpudetection lib
* Copyright (C) 2002-2009 PCSX2 Dev Team
*
* PCSX2 is free software: you can redistribute it and/or modify it under the terms
* of the GNU Lesser General Public License as published by the Free Software Found-
* ation, either version 3 of the License, or (at your option) any later version.
*
* PCSX2 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 PCSX2.
* If not, see <http://www.gnu.org/licenses/>.
*/
#include "PrecompiledHeader.h"
#include "Utilities/RedtapeWindows.h"
#include "Utilities/Threading.h"
#include "internal.h"
#include "tools.h"
using namespace x86Emitter;
__aligned16 x86CPU_INFO x86caps;
static s32 iCpuId( u32 cmd, u32 *regs )
{
#ifdef _MSC_VER
__asm xor ecx, ecx; // ecx should be zero for CPUID(4)
#else
__asm__ __volatile__ ( "xor %ecx, %ecx" );
#endif
__cpuid( (int*)regs, cmd );
return 0;
}
static u64 GetRdtsc( void )
{
return __rdtsc();
}
//////////////////////////////////////////////////////////////////////////////////////////
// Note: This function doesn't support GCC/Linux. Looking online it seems the only
// way to simulate the Microsoft SEH model is to use unix signals, and the 'sigaction'
// function specifically. Maybe a project for a linux developer at a later date. :)
//
#ifdef _MSC_VER
static bool _test_instruction( void* pfnCall )
{
__try {
((void (*)())pfnCall)();
}
__except(EXCEPTION_EXECUTE_HANDLER) {
return false;
}
return true;
}
static char* bool_to_char( bool testcond )
{
return testcond ? "true" : "false";
}
#endif
#ifdef __LINUX__
# include <sys/time.h>
# include <errno.h>
#endif
#ifdef _WINDOWS_
static HANDLE s_threadId = NULL;
static DWORD s_oldmask = ERROR_INVALID_PARAMETER;
#endif
static void SetSingleAffinity()
{
#ifdef _WINDOWS_
// Assign a single CPU thread affinity to ensure rdtsc() accuracy.
// (rdtsc for each CPU/core can differ, causing skewed results)
DWORD_PTR availProcCpus, availSysCpus;
if( !GetProcessAffinityMask( GetCurrentProcess(), &availProcCpus, &availSysCpus ) ) return;
int i;
for( i=0; i<32; ++i )
{
if( availProcCpus & (1<<i) ) break;
}
s_threadId = GetCurrentThread();
s_oldmask = SetThreadAffinityMask( s_threadId, (1UL<<i) );
if( s_oldmask == ERROR_INVALID_PARAMETER )
{
Console.Warning(
"CpuDetect: SetThreadAffinityMask failed...\n"
"\tSystem Affinity : 0x%08x"
"\tProcess Affinity: 0x%08x"
"\tAttempted Thread Affinity CPU: i",
availProcCpus, availSysCpus, i
);
}
#endif
}
//////////////////////////////////////////////////////////////////////////////////////////
//
static s64 CPUSpeedHz( u64 time )
{
u64 timeStart, timeStop;
s64 startTick, endTick;
if( ! x86caps.hasTimeStampCounter )
return 0; //check if function is supported
SetSingleAffinity();
// Align the cpu execution to a cpuTick boundary.
do { timeStart = GetCPUTicks();
} while( GetCPUTicks() == timeStart );
do
{
timeStop = GetCPUTicks( );
startTick = GetRdtsc( );
} while( ( timeStop - timeStart ) == 0 );
timeStart = timeStop;
do
{
timeStop = GetCPUTicks();
endTick = GetRdtsc();
}
while( ( timeStop - timeStart ) < time );
#ifdef _WINDOWS_
if( s_oldmask != ERROR_INVALID_PARAMETER )
SetThreadAffinityMask( s_threadId, s_oldmask );
#endif
return (s64)( endTick - startTick );
}
////////////////////////////////////////////////////
int arr[] = {
0x65746e49, 0x2952286c, 0x726f4320, 0x4d542865,
0x51203229,0x20646175,0x20555043,0x20202020 ,
0x20202020,0x20402020,0x36362e32,0x7a4847
};
void cpudetectInit()
{
u32 regs[ 4 ];
u32 cmds;
int cputype=0; // Cpu type
//AMD 64 STUFF
u32 x86_64_8BITBRANDID;
u32 x86_64_12BITBRANDID;
int num;
char str[50];
memzero( x86caps.VendorName );
x86caps.FamilyID = 0;
x86caps.Model = 0;
x86caps.TypeID = 0;
x86caps.StepID = 0;
x86caps.Flags = 0;
x86caps.EFlags = 0;
if ( iCpuId( 0, regs ) == -1 ) return;
cmds = regs[ 0 ];
((u32*)x86caps.VendorName)[ 0 ] = regs[ 1 ];
((u32*)x86caps.VendorName)[ 1 ] = regs[ 3 ];
((u32*)x86caps.VendorName)[ 2 ] = regs[ 2 ];
// Hack - prevents reg[2] & reg[3] from being optimized out of existance!
num = sprintf(str, "\tx86Flags = %8.8x %8.8x\n", regs[3], regs[2]);
u32 LogicalCoresPerPhysicalCPU = 0;
u32 PhysicalCoresPerPhysicalCPU = 1;
if ( cmds >= 0x00000001 )
{
if ( iCpuId( 0x00000001, regs ) != -1 )
{
x86caps.StepID = regs[ 0 ] & 0xf;
x86caps.Model = (regs[ 0 ] >> 4) & 0xf;
x86caps.FamilyID = (regs[ 0 ] >> 8) & 0xf;
x86caps.TypeID = (regs[ 0 ] >> 12) & 0x3;
LogicalCoresPerPhysicalCPU = ( regs[1] >> 16 ) & 0xff;
x86_64_8BITBRANDID = regs[ 1 ] & 0xff;
x86caps.Flags = regs[ 3 ];
x86caps.Flags2 = regs[ 2 ];
}
}
/* detect multicore for intel cpu */
if ((cmds >= 0x00000004) && !strcmp("GenuineIntel",x86caps.VendorName))
{
if ( iCpuId( 0x00000004, regs ) != -1 )
{
PhysicalCoresPerPhysicalCPU += ( regs[0] >> 26) & 0x3f;
}
}
if ( iCpuId( 0x80000000, regs ) != -1 )
{
cmds = regs[ 0 ];
if ( cmds >= 0x80000001 )
{
if ( iCpuId( 0x80000001, regs ) != -1 )
{
x86_64_12BITBRANDID = regs[1] & 0xfff;
x86caps.EFlags2 = regs[ 2 ];
x86caps.EFlags = regs[ 3 ];
}
}
/* detect multicore for amd cpu */
if ((cmds >= 0x80000008) && !strcmp("AuthenticAMD",x86caps.VendorName))
{
if ( iCpuId( 0x80000008, regs ) != -1 )
{
PhysicalCoresPerPhysicalCPU += ( regs[2] ) & 0xff;
}
}
}
switch(x86caps.TypeID)
{
case 0:
strcpy( x86caps.TypeName, "Standard OEM");
break;
case 1:
strcpy( x86caps.TypeName, "Overdrive");
break;
case 2:
strcpy( x86caps.TypeName, "Dual");
break;
case 3:
strcpy( x86caps.TypeName, "Reserved");
break;
default:
strcpy( x86caps.TypeName, "Unknown");
break;
}
if ( x86caps.VendorName[ 0 ] == 'G' ){ cputype=0;}//trick lines but if you know a way better ;p
if ( x86caps.VendorName[ 0 ] == 'A' ){ cputype=1;}
memzero( x86caps.FamilyName );
iCpuId( 0x80000002, (u32*)x86caps.FamilyName);
iCpuId( 0x80000003, (u32*)(x86caps.FamilyName+16));
iCpuId( 0x80000004, (u32*)(x86caps.FamilyName+32));
//capabilities
x86caps.hasFloatingPointUnit = ( x86caps.Flags >> 0 ) & 1;
x86caps.hasVirtual8086ModeEnhancements = ( x86caps.Flags >> 1 ) & 1;
x86caps.hasDebuggingExtensions = ( x86caps.Flags >> 2 ) & 1;
x86caps.hasPageSizeExtensions = ( x86caps.Flags >> 3 ) & 1;
x86caps.hasTimeStampCounter = ( x86caps.Flags >> 4 ) & 1;
x86caps.hasModelSpecificRegisters = ( x86caps.Flags >> 5 ) & 1;
x86caps.hasPhysicalAddressExtension = ( x86caps.Flags >> 6 ) & 1;
x86caps.hasMachineCheckArchitecture = ( x86caps.Flags >> 7 ) & 1;
x86caps.hasCOMPXCHG8BInstruction = ( x86caps.Flags >> 8 ) & 1;
x86caps.hasAdvancedProgrammableInterruptController = ( x86caps.Flags >> 9 ) & 1;
x86caps.hasSEPFastSystemCall = ( x86caps.Flags >> 11 ) & 1;
x86caps.hasMemoryTypeRangeRegisters = ( x86caps.Flags >> 12 ) & 1;
x86caps.hasPTEGlobalFlag = ( x86caps.Flags >> 13 ) & 1;
x86caps.hasMachineCheckArchitecture = ( x86caps.Flags >> 14 ) & 1;
x86caps.hasConditionalMoveAndCompareInstructions = ( x86caps.Flags >> 15 ) & 1;
x86caps.hasFGPageAttributeTable = ( x86caps.Flags >> 16 ) & 1;
x86caps.has36bitPageSizeExtension = ( x86caps.Flags >> 17 ) & 1;
x86caps.hasProcessorSerialNumber = ( x86caps.Flags >> 18 ) & 1;
x86caps.hasCFLUSHInstruction = ( x86caps.Flags >> 19 ) & 1;
x86caps.hasDebugStore = ( x86caps.Flags >> 21 ) & 1;
x86caps.hasACPIThermalMonitorAndClockControl = ( x86caps.Flags >> 22 ) & 1;
x86caps.hasMultimediaExtensions = ( x86caps.Flags >> 23 ) & 1; //mmx
x86caps.hasFastStreamingSIMDExtensionsSaveRestore = ( x86caps.Flags >> 24 ) & 1;
x86caps.hasStreamingSIMDExtensions = ( x86caps.Flags >> 25 ) & 1; //sse
x86caps.hasStreamingSIMD2Extensions = ( x86caps.Flags >> 26 ) & 1; //sse2
x86caps.hasSelfSnoop = ( x86caps.Flags >> 27 ) & 1;
x86caps.hasMultiThreading = ( x86caps.Flags >> 28 ) & 1;
x86caps.hasThermalMonitor = ( x86caps.Flags >> 29 ) & 1;
x86caps.hasIntel64BitArchitecture = ( x86caps.Flags >> 30 ) & 1;
//that is only for AMDs
x86caps.hasMultimediaExtensionsExt = ( x86caps.EFlags >> 22 ) & 1; //mmx2
x86caps.hasAMD64BitArchitecture = ( x86caps.EFlags >> 29 ) & 1; //64bit cpu
x86caps.has3DNOWInstructionExtensionsExt = ( x86caps.EFlags >> 30 ) & 1; //3dnow+
x86caps.has3DNOWInstructionExtensions = ( x86caps.EFlags >> 31 ) & 1; //3dnow
x86caps.hasStreamingSIMD4ExtensionsA = ( x86caps.EFlags2 >> 6 ) & 1; //INSERTQ / EXTRQ / MOVNT
InitCPUTicks();
u64 span = GetTickFrequency();
if( (span % 1000) < 400 ) // helps minimize rounding errors
x86caps.Speed = (u32)( CPUSpeedHz( span / 1000 ) / 1000 );
else
x86caps.Speed = (u32)( CPUSpeedHz( span / 500 ) / 2000 );
// --> SSE3 / SSSE3 / SSE4.1 / SSE 4.2 detection <--
x86caps.hasStreamingSIMD3Extensions = ( x86caps.Flags2 >> 0 ) & 1; //sse3
x86caps.hasSupplementalStreamingSIMD3Extensions = ( x86caps.Flags2 >> 9 ) & 1; //ssse3
x86caps.hasStreamingSIMD4Extensions = ( x86caps.Flags2 >> 19 ) & 1; //sse4.1
x86caps.hasStreamingSIMD4Extensions2 = ( x86caps.Flags2 >> 20 ) & 1; //sse4.2
//////////////////////////////////////////////////////////////////////////////////////////
// SIMD Instruction Support Detection
//
// Can the SSE3 / SSE4.1 bits be trusted? Using an instruction test is a very "complete"
// approach to ensuring the instruction set is supported, and at least one reported case
// of a Q9550 not having it's SSE 4.1 bit set but still supporting it properly is fixed
// by this --air
// (note: the user who reported the case later fixed the problem by doing a CMOS reset)
//
// Linux support note: Linux/GCC doesn't have SEH-style exceptions which allow handling of
// CPU-level exceptions (__try/__except in msvc) so this code is disabled on GCC, and
// detection relies on the CPUID bits alone.
#ifdef _MSC_VER
u8* recSSE = (u8*)HostSys::Mmap( NULL, 0x1000 );
if( recSSE != NULL )
{
xSetPtr( recSSE );
xMOVSLDUP( xmm1, xmm0 );
xRET();
u8* funcSSSE3 = xGetPtr();
xPABS.W( xmm0, xmm1 );
xRET();
u8* funcSSE41 = xGetPtr();
xBLEND.VPD( xmm1, xmm0 );
xRET();
bool sse3_result = _test_instruction( recSSE ); // sse3
bool ssse3_result = _test_instruction( funcSSSE3 );
bool sse41_result = _test_instruction( funcSSE41 );
HostSys::Munmap( recSSE, 0x1000 );
// Test for and log any irregularities here.
// We take the instruction test result over cpuid since (in theory) it should be a
// more reliable gauge of the cpu's actual ability. But since a difference in bit
// and actual ability may represent a cmos/bios problem, we report it to the user.
if( sse3_result != !!x86caps.hasStreamingSIMD3Extensions )
{
Console.Warning( "SSE3 Detection Inconsistency: cpuid=%s, test_result=%s",
bool_to_char( !!x86caps.hasStreamingSIMD3Extensions ), bool_to_char( sse3_result ) );
x86caps.hasStreamingSIMD3Extensions = sse3_result;
}
if( ssse3_result != !!x86caps.hasSupplementalStreamingSIMD3Extensions )
{
Console.Warning( "SSSE3 Detection Inconsistency: cpuid=%s, test_result=%s",
bool_to_char( !!x86caps.hasSupplementalStreamingSIMD3Extensions ), bool_to_char( ssse3_result ) );
x86caps.hasSupplementalStreamingSIMD3Extensions = ssse3_result;
}
if( sse41_result != !!x86caps.hasStreamingSIMD4Extensions )
{
Console.Warning( "SSE4 Detection Inconsistency: cpuid=%s, test_result=%s",
bool_to_char( !!x86caps.hasStreamingSIMD4Extensions ), bool_to_char( sse41_result ) );
x86caps.hasStreamingSIMD4Extensions = sse41_result;
}
}
else
{
Console.Warning(
"Notice: Could not allocate memory for SSE3/4 detection.\n"
"\tRelying on CPUID results. [this is not an error]"
);
}
#endif
////////////////////////////////////////////////////////////////////////////////////////////
// Core Counting!
if( !x86caps.hasMultiThreading || LogicalCoresPerPhysicalCPU == 0 )
LogicalCoresPerPhysicalCPU = 1;
// This will assign values into x86caps.LogicalCores and PhysicalCores
Threading::CountLogicalCores( LogicalCoresPerPhysicalCPU, PhysicalCoresPerPhysicalCPU );
}