/* =========================================================================== Doom 3 GPL Source Code Copyright (C) 1999-2011 id Software LLC, a ZeniMax Media company. This file is part of the Doom 3 GPL Source Code ("Doom 3 Source Code"). Doom 3 Source Code 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 3 of the License, or (at your option) any later version. Doom 3 Source Code 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 Doom 3 Source Code. If not, see . In addition, the Doom 3 Source Code is also subject to certain additional terms. You should have received a copy of these additional terms immediately following the terms and conditions of the GNU General Public License which accompanied the Doom 3 Source Code. If not, please request a copy in writing from id Software at the address below. If you have questions concerning this license or the applicable additional terms, you may contact in writing id Software LLC, c/o ZeniMax Media Inc., Suite 120, Rockville, Maryland 20850 USA. =========================================================================== */ #include "../../idlib/precompiled.h" #pragma hdrstop #include "win_local.h" /* ============================================================== Clock ticks ============================================================== */ /* ================ Sys_GetClockTicks ================ */ double Sys_GetClockTicks( void ) { #if 0 LARGE_INTEGER li; QueryPerformanceCounter( &li ); return = (double ) li.LowPart + (double) 0xFFFFFFFF * li.HighPart; #else unsigned long lo, hi; __asm { push ebx xor eax, eax cpuid rdtsc mov lo, eax mov hi, edx pop ebx } return (double ) lo + (double) 0xFFFFFFFF * hi; #endif } /* ================ Sys_ClockTicksPerSecond ================ */ double Sys_ClockTicksPerSecond( void ) { static double ticks = 0; #if 0 if ( !ticks ) { LARGE_INTEGER li; QueryPerformanceFrequency( &li ); ticks = li.QuadPart; } #else if ( !ticks ) { HKEY hKey; LPBYTE ProcSpeed; DWORD buflen, ret; if ( !RegOpenKeyEx( HKEY_LOCAL_MACHINE, "HARDWARE\\DESCRIPTION\\System\\CentralProcessor\\0", 0, KEY_READ, &hKey ) ) { ProcSpeed = 0; buflen = sizeof( ProcSpeed ); ret = RegQueryValueEx( hKey, "~MHz", NULL, NULL, (LPBYTE) &ProcSpeed, &buflen ); // If we don't succeed, try some other spellings. if ( ret != ERROR_SUCCESS ) { ret = RegQueryValueEx( hKey, "~Mhz", NULL, NULL, (LPBYTE) &ProcSpeed, &buflen ); } if ( ret != ERROR_SUCCESS ) { ret = RegQueryValueEx( hKey, "~mhz", NULL, NULL, (LPBYTE) &ProcSpeed, &buflen ); } RegCloseKey( hKey ); if ( ret == ERROR_SUCCESS ) { ticks = (double) ((unsigned long)ProcSpeed) * 1000000; } } } #endif return ticks; } /* ============================================================== CPU ============================================================== */ /* ================ HasCPUID ================ */ static bool HasCPUID( void ) { __asm { pushfd // save eflags pop eax test eax, 0x00200000 // check ID bit jz set21 // bit 21 is not set, so jump to set_21 and eax, 0xffdfffff // clear bit 21 push eax // save new value in register popfd // store new value in flags pushfd pop eax test eax, 0x00200000 // check ID bit jz good jmp err // cpuid not supported set21: or eax, 0x00200000 // set ID bit push eax // store new value popfd // store new value in EFLAGS pushfd pop eax test eax, 0x00200000 // if bit 21 is on jnz good jmp err } err: return false; good: return true; } #define _REG_EAX 0 #define _REG_EBX 1 #define _REG_ECX 2 #define _REG_EDX 3 /* ================ CPUID ================ */ static void CPUID( int func, unsigned regs[4] ) { unsigned regEAX, regEBX, regECX, regEDX; __asm pusha __asm mov eax, func __asm __emit 00fh __asm __emit 0a2h __asm mov regEAX, eax __asm mov regEBX, ebx __asm mov regECX, ecx __asm mov regEDX, edx __asm popa regs[_REG_EAX] = regEAX; regs[_REG_EBX] = regEBX; regs[_REG_ECX] = regECX; regs[_REG_EDX] = regEDX; } /* ================ IsAMD ================ */ static bool IsAMD( void ) { char pstring[16]; char processorString[13]; // get name of processor CPUID( 0, ( unsigned int * ) pstring ); processorString[0] = pstring[4]; processorString[1] = pstring[5]; processorString[2] = pstring[6]; processorString[3] = pstring[7]; processorString[4] = pstring[12]; processorString[5] = pstring[13]; processorString[6] = pstring[14]; processorString[7] = pstring[15]; processorString[8] = pstring[8]; processorString[9] = pstring[9]; processorString[10] = pstring[10]; processorString[11] = pstring[11]; processorString[12] = 0; if ( strcmp( processorString, "AuthenticAMD" ) == 0 ) { return true; } return false; } /* ================ HasCMOV ================ */ static bool HasCMOV( void ) { unsigned regs[4]; // get CPU feature bits CPUID( 1, regs ); // bit 15 of EDX denotes CMOV existence if ( regs[_REG_EDX] & ( 1 << 15 ) ) { return true; } return false; } /* ================ Has3DNow ================ */ static bool Has3DNow( void ) { unsigned regs[4]; // check AMD-specific functions CPUID( 0x80000000, regs ); if ( regs[_REG_EAX] < 0x80000000 ) { return false; } // bit 31 of EDX denotes 3DNow! support CPUID( 0x80000001, regs ); if ( regs[_REG_EDX] & ( 1 << 31 ) ) { return true; } return false; } /* ================ HasMMX ================ */ static bool HasMMX( void ) { unsigned regs[4]; // get CPU feature bits CPUID( 1, regs ); // bit 23 of EDX denotes MMX existence if ( regs[_REG_EDX] & ( 1 << 23 ) ) { return true; } return false; } /* ================ HasSSE ================ */ static bool HasSSE( void ) { unsigned regs[4]; // get CPU feature bits CPUID( 1, regs ); // bit 25 of EDX denotes SSE existence if ( regs[_REG_EDX] & ( 1 << 25 ) ) { return true; } return false; } /* ================ HasSSE2 ================ */ static bool HasSSE2( void ) { unsigned regs[4]; // get CPU feature bits CPUID( 1, regs ); // bit 26 of EDX denotes SSE2 existence if ( regs[_REG_EDX] & ( 1 << 26 ) ) { return true; } return false; } /* ================ HasSSE3 ================ */ static bool HasSSE3( void ) { unsigned regs[4]; // get CPU feature bits CPUID( 1, regs ); // bit 0 of ECX denotes SSE3 existence if ( regs[_REG_ECX] & ( 1 << 0 ) ) { return true; } return false; } /* ================ LogicalProcPerPhysicalProc ================ */ #define NUM_LOGICAL_BITS 0x00FF0000 // EBX[23:16] Bit 16-23 in ebx contains the number of logical // processors per physical processor when execute cpuid with // eax set to 1 static unsigned char LogicalProcPerPhysicalProc( void ) { unsigned int regebx = 0; __asm { mov eax, 1 cpuid mov regebx, ebx } return (unsigned char) ((regebx & NUM_LOGICAL_BITS) >> 16); } /* ================ GetAPIC_ID ================ */ #define INITIAL_APIC_ID_BITS 0xFF000000 // EBX[31:24] Bits 24-31 (8 bits) return the 8-bit unique // initial APIC ID for the processor this code is running on. // Default value = 0xff if HT is not supported static unsigned char GetAPIC_ID( void ) { unsigned int regebx = 0; __asm { mov eax, 1 cpuid mov regebx, ebx } return (unsigned char) ((regebx & INITIAL_APIC_ID_BITS) >> 24); } /* ================ CPUCount logicalNum is the number of logical CPU per physical CPU physicalNum is the total number of physical processor returns one of the HT_* flags ================ */ #define HT_NOT_CAPABLE 0 #define HT_ENABLED 1 #define HT_DISABLED 2 #define HT_SUPPORTED_NOT_ENABLED 3 #define HT_CANNOT_DETECT 4 int CPUCount( int &logicalNum, int &physicalNum ) { int statusFlag; SYSTEM_INFO info; physicalNum = 1; logicalNum = 1; statusFlag = HT_NOT_CAPABLE; info.dwNumberOfProcessors = 0; GetSystemInfo (&info); // Number of physical processors in a non-Intel system // or in a 32-bit Intel system with Hyper-Threading technology disabled physicalNum = info.dwNumberOfProcessors; unsigned char HT_Enabled = 0; logicalNum = LogicalProcPerPhysicalProc(); if ( logicalNum >= 1 ) { // > 1 doesn't mean HT is enabled in the BIOS HANDLE hCurrentProcessHandle; DWORD dwProcessAffinity; DWORD dwSystemAffinity; DWORD dwAffinityMask; // Calculate the appropriate shifts and mask based on the // number of logical processors. unsigned char i = 1, PHY_ID_MASK = 0xFF, PHY_ID_SHIFT = 0; while( i < logicalNum ) { i *= 2; PHY_ID_MASK <<= 1; PHY_ID_SHIFT++; } hCurrentProcessHandle = GetCurrentProcess(); GetProcessAffinityMask( hCurrentProcessHandle, &dwProcessAffinity, &dwSystemAffinity ); // Check if available process affinity mask is equal to the // available system affinity mask if ( dwProcessAffinity != dwSystemAffinity ) { statusFlag = HT_CANNOT_DETECT; physicalNum = -1; return statusFlag; } dwAffinityMask = 1; while ( dwAffinityMask != 0 && dwAffinityMask <= dwProcessAffinity ) { // Check if this CPU is available if ( dwAffinityMask & dwProcessAffinity ) { if ( SetProcessAffinityMask( hCurrentProcessHandle, dwAffinityMask ) ) { unsigned char APIC_ID, LOG_ID, PHY_ID; Sleep( 0 ); // Give OS time to switch CPU APIC_ID = GetAPIC_ID(); LOG_ID = APIC_ID & ~PHY_ID_MASK; PHY_ID = APIC_ID >> PHY_ID_SHIFT; if ( LOG_ID != 0 ) { HT_Enabled = 1; } } } dwAffinityMask = dwAffinityMask << 1; } // Reset the processor affinity SetProcessAffinityMask( hCurrentProcessHandle, dwProcessAffinity ); if ( logicalNum == 1 ) { // Normal P4 : HT is disabled in hardware statusFlag = HT_DISABLED; } else { if ( HT_Enabled ) { // Total physical processors in a Hyper-Threading enabled system. physicalNum /= logicalNum; statusFlag = HT_ENABLED; } else { statusFlag = HT_SUPPORTED_NOT_ENABLED; } } } return statusFlag; } /* ================ HasHTT ================ */ static bool HasHTT( void ) { unsigned regs[4]; int logicalNum, physicalNum, HTStatusFlag; // get CPU feature bits CPUID( 1, regs ); // bit 28 of EDX denotes HTT existence if ( !( regs[_REG_EDX] & ( 1 << 28 ) ) ) { return false; } HTStatusFlag = CPUCount( logicalNum, physicalNum ); if ( HTStatusFlag != HT_ENABLED ) { return false; } return true; } /* ================ HasHTT ================ */ static bool HasDAZ( void ) { __declspec(align(16)) unsigned char FXSaveArea[512]; unsigned char *FXArea = FXSaveArea; DWORD dwMask = 0; unsigned regs[4]; // get CPU feature bits CPUID( 1, regs ); // bit 24 of EDX denotes support for FXSAVE if ( !( regs[_REG_EDX] & ( 1 << 24 ) ) ) { return false; } memset( FXArea, 0, sizeof( FXSaveArea ) ); __asm { mov eax, FXArea FXSAVE [eax] } dwMask = *(DWORD *)&FXArea[28]; // Read the MXCSR Mask return ( ( dwMask & ( 1 << 6 ) ) == ( 1 << 6 ) ); // Return if the DAZ bit is set } /* ================ Sys_GetCPUId ================ */ cpuid_t Sys_GetCPUId( void ) { int flags; // verify we're at least a Pentium or 486 with CPUID support if ( !HasCPUID() ) { return CPUID_UNSUPPORTED; } // check for an AMD if ( IsAMD() ) { flags = CPUID_AMD; } else { flags = CPUID_INTEL; } // check for Multi Media Extensions if ( HasMMX() ) { flags |= CPUID_MMX; } // check for 3DNow! if ( Has3DNow() ) { flags |= CPUID_3DNOW; } // check for Streaming SIMD Extensions if ( HasSSE() ) { flags |= CPUID_SSE | CPUID_FTZ; } // check for Streaming SIMD Extensions 2 if ( HasSSE2() ) { flags |= CPUID_SSE2; } // check for Streaming SIMD Extensions 3 aka Prescott's New Instructions if ( HasSSE3() ) { flags |= CPUID_SSE3; } // check for Hyper-Threading Technology if ( HasHTT() ) { flags |= CPUID_HTT; } // check for Conditional Move (CMOV) and fast floating point comparison (FCOMI) instructions if ( HasCMOV() ) { flags |= CPUID_CMOV; } // check for Denormals-Are-Zero mode if ( HasDAZ() ) { flags |= CPUID_DAZ; } return (cpuid_t)flags; } /* =============================================================================== FPU =============================================================================== */ typedef struct bitFlag_s { char * name; int bit; } bitFlag_t; static byte fpuState[128], *statePtr = fpuState; static char fpuString[2048]; static bitFlag_t controlWordFlags[] = { { "Invalid operation", 0 }, { "Denormalized operand", 1 }, { "Divide-by-zero", 2 }, { "Numeric overflow", 3 }, { "Numeric underflow", 4 }, { "Inexact result (precision)", 5 }, { "Infinity control", 12 }, { "", 0 } }; static char *precisionControlField[] = { "Single Precision (24-bits)", "Reserved", "Double Precision (53-bits)", "Double Extended Precision (64-bits)" }; static char *roundingControlField[] = { "Round to nearest", "Round down", "Round up", "Round toward zero" }; static bitFlag_t statusWordFlags[] = { { "Invalid operation", 0 }, { "Denormalized operand", 1 }, { "Divide-by-zero", 2 }, { "Numeric overflow", 3 }, { "Numeric underflow", 4 }, { "Inexact result (precision)", 5 }, { "Stack fault", 6 }, { "Error summary status", 7 }, { "FPU busy", 15 }, { "", 0 } }; /* =============== Sys_FPU_PrintStateFlags =============== */ int Sys_FPU_PrintStateFlags( char *ptr, int ctrl, int stat, int tags, int inof, int inse, int opof, int opse ) { int i, length = 0; length += sprintf( ptr+length, "CTRL = %08x\n" "STAT = %08x\n" "TAGS = %08x\n" "INOF = %08x\n" "INSE = %08x\n" "OPOF = %08x\n" "OPSE = %08x\n" "\n", ctrl, stat, tags, inof, inse, opof, opse ); length += sprintf( ptr+length, "Control Word:\n" ); for ( i = 0; controlWordFlags[i].name[0]; i++ ) { length += sprintf( ptr+length, " %-30s = %s\n", controlWordFlags[i].name, ( ctrl & ( 1 << controlWordFlags[i].bit ) ) ? "true" : "false" ); } length += sprintf( ptr+length, " %-30s = %s\n", "Precision control", precisionControlField[(ctrl>>8)&3] ); length += sprintf( ptr+length, " %-30s = %s\n", "Rounding control", roundingControlField[(ctrl>>10)&3] ); length += sprintf( ptr+length, "Status Word:\n" ); for ( i = 0; statusWordFlags[i].name[0]; i++ ) { ptr += sprintf( ptr+length, " %-30s = %s\n", statusWordFlags[i].name, ( stat & ( 1 << statusWordFlags[i].bit ) ) ? "true" : "false" ); } length += sprintf( ptr+length, " %-30s = %d%d%d%d\n", "Condition code", (stat>>8)&1, (stat>>9)&1, (stat>>10)&1, (stat>>14)&1 ); length += sprintf( ptr+length, " %-30s = %d\n", "Top of stack pointer", (stat>>11)&7 ); return length; } /* =============== Sys_FPU_StackIsEmpty =============== */ bool Sys_FPU_StackIsEmpty( void ) { __asm { mov eax, statePtr fnstenv [eax] mov eax, [eax+8] xor eax, 0xFFFFFFFF and eax, 0x0000FFFF jz empty } return false; empty: return true; } /* =============== Sys_FPU_ClearStack =============== */ void Sys_FPU_ClearStack( void ) { __asm { mov eax, statePtr fnstenv [eax] mov eax, [eax+8] xor eax, 0xFFFFFFFF mov edx, (3<<14) emptyStack: mov ecx, eax and ecx, edx jz done fstp st shr edx, 2 jmp emptyStack done: } } /* =============== Sys_FPU_GetState gets the FPU state without changing the state =============== */ const char *Sys_FPU_GetState( void ) { double fpuStack[8] = { 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0 }; double *fpuStackPtr = fpuStack; int i, numValues; char *ptr; __asm { mov esi, statePtr mov edi, fpuStackPtr fnstenv [esi] mov esi, [esi+8] xor esi, 0xFFFFFFFF mov edx, (3<<14) xor eax, eax mov ecx, esi and ecx, edx jz done fst qword ptr [edi+0] inc eax shr edx, 2 mov ecx, esi and ecx, edx jz done fxch st(1) fst qword ptr [edi+8] inc eax fxch st(1) shr edx, 2 mov ecx, esi and ecx, edx jz done fxch st(2) fst qword ptr [edi+16] inc eax fxch st(2) shr edx, 2 mov ecx, esi and ecx, edx jz done fxch st(3) fst qword ptr [edi+24] inc eax fxch st(3) shr edx, 2 mov ecx, esi and ecx, edx jz done fxch st(4) fst qword ptr [edi+32] inc eax fxch st(4) shr edx, 2 mov ecx, esi and ecx, edx jz done fxch st(5) fst qword ptr [edi+40] inc eax fxch st(5) shr edx, 2 mov ecx, esi and ecx, edx jz done fxch st(6) fst qword ptr [edi+48] inc eax fxch st(6) shr edx, 2 mov ecx, esi and ecx, edx jz done fxch st(7) fst qword ptr [edi+56] inc eax fxch st(7) done: mov numValues, eax } int ctrl = *(int *)&fpuState[0]; int stat = *(int *)&fpuState[4]; int tags = *(int *)&fpuState[8]; int inof = *(int *)&fpuState[12]; int inse = *(int *)&fpuState[16]; int opof = *(int *)&fpuState[20]; int opse = *(int *)&fpuState[24]; ptr = fpuString; ptr += sprintf( ptr,"FPU State:\n" "num values on stack = %d\n", numValues ); for ( i = 0; i < 8; i++ ) { ptr += sprintf( ptr, "ST%d = %1.10e\n", i, fpuStack[i] ); } Sys_FPU_PrintStateFlags( ptr, ctrl, stat, tags, inof, inse, opof, opse ); return fpuString; } /* =============== Sys_FPU_EnableExceptions =============== */ void Sys_FPU_EnableExceptions( int exceptions ) { __asm { mov eax, statePtr mov ecx, exceptions and cx, 63 not cx fnstcw word ptr [eax] mov bx, word ptr [eax] or bx, 63 and bx, cx mov word ptr [eax], bx fldcw word ptr [eax] } } /* =============== Sys_FPU_SetPrecision =============== */ void Sys_FPU_SetPrecision( int precision ) { short precisionBitTable[4] = { 0, 1, 3, 0 }; short precisionBits = precisionBitTable[precision & 3] << 8; short precisionMask = ~( ( 1 << 9 ) | ( 1 << 8 ) ); __asm { mov eax, statePtr mov cx, precisionBits fnstcw word ptr [eax] mov bx, word ptr [eax] and bx, precisionMask or bx, cx mov word ptr [eax], bx fldcw word ptr [eax] } } /* ================ Sys_FPU_SetRounding ================ */ void Sys_FPU_SetRounding( int rounding ) { short roundingBitTable[4] = { 0, 1, 2, 3 }; short roundingBits = roundingBitTable[rounding & 3] << 10; short roundingMask = ~( ( 1 << 11 ) | ( 1 << 10 ) ); __asm { mov eax, statePtr mov cx, roundingBits fnstcw word ptr [eax] mov bx, word ptr [eax] and bx, roundingMask or bx, cx mov word ptr [eax], bx fldcw word ptr [eax] } } /* ================ Sys_FPU_SetDAZ ================ */ void Sys_FPU_SetDAZ( bool enable ) { DWORD dwData; _asm { movzx ecx, byte ptr enable and ecx, 1 shl ecx, 6 STMXCSR dword ptr dwData mov eax, dwData and eax, ~(1<<6) // clear DAX bit or eax, ecx // set the DAZ bit mov dwData, eax LDMXCSR dword ptr dwData } } /* ================ Sys_FPU_SetFTZ ================ */ void Sys_FPU_SetFTZ( bool enable ) { DWORD dwData; _asm { movzx ecx, byte ptr enable and ecx, 1 shl ecx, 15 STMXCSR dword ptr dwData mov eax, dwData and eax, ~(1<<15) // clear FTZ bit or eax, ecx // set the FTZ bit mov dwData, eax LDMXCSR dword ptr dwData } }