project64/Source/Project64/Logging.cpp

920 lines
40 KiB
C++

/****************************************************************************
* *
* Project64 - A Nintendo 64 emulator. *
* http://www.pj64-emu.com/ *
* Copyright (C) 2012 Project64. All rights reserved. *
* *
* License: *
* GNU/GPLv2 http://www.gnu.org/licenses/gpl-2.0.html *
* *
****************************************************************************/
#include "stdafx.h"
#include <prsht.h>
void LoadLogSetting (HKEY hKey,char * String, bool * Value);
void SaveLogOptions (void);
LRESULT CALLBACK LogGeneralProc ( HWND, UINT, WPARAM, LPARAM );
LRESULT CALLBACK LogPifProc ( HWND, UINT, WPARAM, LPARAM );
LRESULT CALLBACK LogRegProc ( HWND, UINT, WPARAM, LPARAM );
static HANDLE g_hLogFile = NULL;
LOG_OPTIONS g_LogOptions, TempOptions;
void EnterLogOptions(HWND hwndOwner)
{
PROPSHEETPAGE psp[3];
PROPSHEETHEADER psh;
psp[0].dwSize = sizeof(PROPSHEETPAGE);
psp[0].dwFlags = PSP_USETITLE;
psp[0].hInstance = GetModuleHandle(NULL);
psp[0].pszTemplate = MAKEINTRESOURCE(IDD_Logging_Registers);
psp[0].pfnDlgProc = (DLGPROC)LogRegProc;
psp[0].pszTitle = "Registers";
psp[0].lParam = 0;
psp[0].pfnCallback = NULL;
psp[1].dwSize = sizeof(PROPSHEETPAGE);
psp[1].dwFlags = PSP_USETITLE;
psp[1].hInstance = GetModuleHandle(NULL);
psp[1].pszTemplate = MAKEINTRESOURCE(IDD_Logging_PifRam);
psp[1].pfnDlgProc = (DLGPROC)LogPifProc;
psp[1].pszTitle = "Pif Ram";
psp[1].lParam = 0;
psp[1].pfnCallback = NULL;
psp[2].dwSize = sizeof(PROPSHEETPAGE);
psp[2].dwFlags = PSP_USETITLE;
psp[2].hInstance = GetModuleHandle(NULL);
psp[2].pszTemplate = MAKEINTRESOURCE(IDD_Logging_General);
psp[2].pfnDlgProc = (DLGPROC)LogGeneralProc;
psp[2].pszTitle = "General";
psp[2].lParam = 0;
psp[2].pfnCallback = NULL;
psh.dwSize = sizeof(PROPSHEETHEADER);
psh.dwFlags = PSH_PROPSHEETPAGE | PSH_NOAPPLYNOW;
psh.hwndParent = hwndOwner;
psh.hInstance = GetModuleHandle(NULL);
psh.pszCaption = (LPSTR) "Log Options";
psh.nPages = sizeof(psp) / sizeof(PROPSHEETPAGE);
psh.nStartPage = 0;
psh.ppsp = (LPCPROPSHEETPAGE) &psp;
psh.pfnCallback = NULL;
LoadLogOptions(&TempOptions,TRUE);
#if defined(WINDOWS_UI)
PropertySheet(&psh);
#else
g_Notify -> BreakPoint(__FILEW__, __LINE__);
#endif
SaveLogOptions();
LoadLogOptions(&g_LogOptions, FALSE);
return;
}
void LoadLogOptions (LOG_OPTIONS * LogOptions, bool AlwaysFill)
{
int32_t lResult;
HKEY hKeyResults = 0;
char String[200];
sprintf(String,"Software\\N64 Emulation\\%s\\Logging",g_Settings->LoadStringVal(Setting_ApplicationName).c_str());
lResult = RegOpenKeyEx( HKEY_CURRENT_USER,String,0,KEY_ALL_ACCESS,
&hKeyResults);
if (lResult == ERROR_SUCCESS)
{
//LoadLogSetting(hKeyResults,"Generate Log File",&LogOptions->GenerateLog);
if (LogOptions->GenerateLog || AlwaysFill)
{
LoadLogSetting(hKeyResults,"Log RDRAM",&LogOptions->LogRDRamRegisters);
LoadLogSetting(hKeyResults,"Log SP",&LogOptions->LogSPRegisters);
LoadLogSetting(hKeyResults,"Log DP Command",&LogOptions->LogDPCRegisters);
LoadLogSetting(hKeyResults,"Log DP Span",&LogOptions->LogDPSRegisters);
LoadLogSetting(hKeyResults,"Log MIPS Interface (MI)",&LogOptions->LogMIPSInterface);
LoadLogSetting(hKeyResults,"Log Video Interface (VI)",&LogOptions->LogVideoInterface);
LoadLogSetting(hKeyResults,"Log Audio Interface (AI)",&LogOptions->LogAudioInterface);
LoadLogSetting(hKeyResults,"Log Peripheral Interface (PI)",&LogOptions->LogPerInterface);
LoadLogSetting(hKeyResults,"Log RDRAM Interface (RI)",&LogOptions->LogRDRAMInterface);
LoadLogSetting(hKeyResults,"Log Serial Interface (SI)",&LogOptions->LogSerialInterface);
LoadLogSetting(hKeyResults,"Log PifRam DMA Operations",&LogOptions->LogPRDMAOperations);
LoadLogSetting(hKeyResults,"Log PifRam Direct Memory Loads",&LogOptions->LogPRDirectMemLoads);
LoadLogSetting(hKeyResults,"Log PifRam DMA Memory Loads",&LogOptions->LogPRDMAMemLoads);
LoadLogSetting(hKeyResults,"Log PifRam Direct Memory Stores",&LogOptions->LogPRDirectMemStores);
LoadLogSetting(hKeyResults,"Log PifRam DMA Memory Stores",&LogOptions->LogPRDMAMemStores);
LoadLogSetting(hKeyResults,"Log Controller Pak",&LogOptions->LogControllerPak);
LoadLogSetting(hKeyResults,"Log CP0 changes",&LogOptions->LogCP0changes);
LoadLogSetting(hKeyResults,"Log CP0 reads",&LogOptions->LogCP0reads);
LoadLogSetting(hKeyResults,"Log Exceptions",&LogOptions->LogExceptions);
LoadLogSetting(hKeyResults,"No Interrupts",&LogOptions->NoInterrupts);
LoadLogSetting(hKeyResults,"Log TLB",&LogOptions->LogTLB);
LoadLogSetting(hKeyResults,"Log Cache Operations",&LogOptions->LogCache);
LoadLogSetting(hKeyResults,"Log Rom Header",&LogOptions->LogRomHeader);
LoadLogSetting(hKeyResults,"Log Unknown access",&LogOptions->LogUnknown);
return;
}
}
LogOptions->GenerateLog = FALSE;
LogOptions->LogRDRamRegisters = FALSE;
LogOptions->LogSPRegisters = FALSE;
LogOptions->LogDPCRegisters = FALSE;
LogOptions->LogDPSRegisters = FALSE;
LogOptions->LogMIPSInterface = FALSE;
LogOptions->LogVideoInterface = FALSE;
LogOptions->LogAudioInterface = FALSE;
LogOptions->LogPerInterface = FALSE;
LogOptions->LogRDRAMInterface = FALSE;
LogOptions->LogSerialInterface = FALSE;
LogOptions->LogPRDMAOperations = FALSE;
LogOptions->LogPRDirectMemLoads = FALSE;
LogOptions->LogPRDMAMemLoads = FALSE;
LogOptions->LogPRDirectMemStores = FALSE;
LogOptions->LogPRDMAMemStores = FALSE;
LogOptions->LogControllerPak = FALSE;
LogOptions->LogCP0changes = FALSE;
LogOptions->LogCP0reads = FALSE;
LogOptions->LogCache = FALSE;
LogOptions->LogExceptions = FALSE;
LogOptions->NoInterrupts = FALSE;
LogOptions->LogTLB = FALSE;
LogOptions->LogRomHeader = FALSE;
LogOptions->LogUnknown = FALSE;
}
void LoadLogSetting (HKEY hKey,char * String, bool * Value)
{
DWORD Type, dwResult, Bytes = 4;
int32_t lResult;
lResult = RegQueryValueEx(hKey,String,0,&Type,(LPBYTE)(&dwResult),&Bytes);
if (Type == REG_DWORD && lResult == ERROR_SUCCESS)
{
*Value = dwResult != 0;
}
else
{
*Value = FALSE;
}
}
LRESULT CALLBACK LogGeneralProc (HWND hDlg, UINT uMsg, WPARAM /*wParam*/, LPARAM lParam)
{
switch (uMsg)
{
case WM_INITDIALOG:
if (TempOptions.LogCP0changes) { CheckDlgButton(hDlg,IDC_CP0_WRITE,BST_CHECKED); }
if (TempOptions.LogCP0reads) { CheckDlgButton(hDlg,IDC_CP0_READ,BST_CHECKED); }
if (TempOptions.LogCache) { CheckDlgButton(hDlg,IDC_CACHE,BST_CHECKED); }
if (TempOptions.LogExceptions) { CheckDlgButton(hDlg,IDC_EXCEPTIONS,BST_CHECKED); }
if (TempOptions.NoInterrupts) { CheckDlgButton(hDlg,IDC_INTERRUPTS,BST_CHECKED); }
if (TempOptions.LogTLB) { CheckDlgButton(hDlg,IDC_TLB,BST_CHECKED); }
if (TempOptions.LogRomHeader) { CheckDlgButton(hDlg,IDC_ROM_HEADER,BST_CHECKED); }
if (TempOptions.LogUnknown) { CheckDlgButton(hDlg,IDC_UNKOWN,BST_CHECKED); }
break;
case WM_NOTIFY:
if (((NMHDR FAR *) lParam)->code != PSN_APPLY) { break; }
TempOptions.LogCP0changes = IsDlgButtonChecked(hDlg,IDC_CP0_WRITE) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogCP0reads = IsDlgButtonChecked(hDlg,IDC_CP0_READ) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogCache = IsDlgButtonChecked(hDlg,IDC_CACHE) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogExceptions = IsDlgButtonChecked(hDlg,IDC_EXCEPTIONS) == BST_CHECKED?TRUE:FALSE;
TempOptions.NoInterrupts = IsDlgButtonChecked(hDlg,IDC_INTERRUPTS) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogTLB = IsDlgButtonChecked(hDlg,IDC_TLB) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogRomHeader = IsDlgButtonChecked(hDlg,IDC_ROM_HEADER) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogUnknown = IsDlgButtonChecked(hDlg,IDC_UNKOWN) == BST_CHECKED?TRUE:FALSE;
break;
default:
return FALSE;
}
return TRUE;
}
void Log_LW (uint32_t PC, uint32_t VAddr)
{
if (!g_LogOptions.GenerateLog)
{
return;
}
if ( VAddr < 0xA0000000 || VAddr >= 0xC0000000 )
{
uint32_t PAddr;
if (!g_TransVaddr->TranslateVaddr(VAddr,PAddr))
{
if (g_LogOptions.LogUnknown)
{
LogMessage("%08X: read from unknown ??? (%08X)",PC,VAddr);
}
return;
}
VAddr = PAddr + 0xA0000000;
}
uint32_t Value;
if ( VAddr >= 0xA0000000 && VAddr < (0xA0000000 + g_MMU->RdramSize()))
{
return;
}
if ( VAddr >= 0xA3F00000 && VAddr <= 0xA3F00024)
{
if (!g_LogOptions.LogRDRamRegisters)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
switch (VAddr)
{
case 0xA3F00000: LogMessage("%08X: read from RDRAM_CONFIG_REG/RDRAM_DEVICE_TYPE_REG (%08X)",PC, Value); return;
case 0xA3F00004: LogMessage("%08X: read from RDRAM_DEVICE_ID_REG (%08X)",PC, Value); return;
case 0xA3F00008: LogMessage("%08X: read from RDRAM_DELAY_REG (%08X)",PC, Value); return;
case 0xA3F0000C: LogMessage("%08X: read from RDRAM_MODE_REG (%08X)",PC, Value); return;
case 0xA3F00010: LogMessage("%08X: read from RDRAM_REF_INTERVAL_REG (%08X)",PC, Value); return;
case 0xA3F00014: LogMessage("%08X: read from RDRAM_REF_ROW_REG (%08X)",PC, Value); return;
case 0xA3F00018: LogMessage("%08X: read from RDRAM_RAS_INTERVAL_REG (%08X)",PC, Value); return;
case 0xA3F0001C: LogMessage("%08X: read from RDRAM_MIN_INTERVAL_REG (%08X)",PC, Value); return;
case 0xA3F00020: LogMessage("%08X: read from RDRAM_ADDR_SELECT_REG (%08X)",PC, Value); return;
case 0xA3F00024: LogMessage("%08X: read from RDRAM_DEVICE_MANUF_REG (%08X)",PC, Value); return;
}
}
if ( VAddr >= 0xA4000000 && VAddr <= 0xA4001FFC )
{
return;
}
if ( VAddr >= 0xA4040000 && VAddr <= 0xA404001C )
{
if (!g_LogOptions.LogSPRegisters)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
switch (VAddr)
{
case 0xA4040000: LogMessage("%08X: read from SP_MEM_ADDR_REG (%08X)",PC, Value); break;
case 0xA4040004: LogMessage("%08X: read from SP_DRAM_ADDR_REG (%08X)",PC, Value); break;
case 0xA4040008: LogMessage("%08X: read from SP_RD_LEN_REG (%08X)",PC, Value); break;
case 0xA404000C: LogMessage("%08X: read from SP_WR_LEN_REG (%08X)",PC, Value); break;
case 0xA4040010: LogMessage("%08X: read from SP_STATUS_REG (%08X)",PC, Value); break;
case 0xA4040014: LogMessage("%08X: read from SP_DMA_FULL_REG (%08X)",PC, Value); break;
case 0xA4040018: LogMessage("%08X: read from SP_DMA_BUSY_REG (%08X)",PC, Value); break;
case 0xA404001C: LogMessage("%08X: read from SP_SEMAPHORE_REG (%08X)",PC, Value); break;
}
return;
}
if ( VAddr == 0xA4080000)
{
if (!g_LogOptions.LogSPRegisters)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
LogMessage("%08X: read from SP_PC (%08X)",PC, Value);
return;
}
if (VAddr >= 0xA4100000 && VAddr <= 0xA410001C)
{
if (!g_LogOptions.LogDPCRegisters)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
switch (VAddr)
{
case 0xA4100000: LogMessage("%08X: read from DPC_START_REG (%08X)",PC, Value); return;
case 0xA4100004: LogMessage("%08X: read from DPC_END_REG (%08X)",PC, Value); return;
case 0xA4100008: LogMessage("%08X: read from DPC_CURRENT_REG (%08X)",PC, Value); return;
case 0xA410000C: LogMessage("%08X: read from DPC_STATUS_REG (%08X)",PC, Value); return;
case 0xA4100010: LogMessage("%08X: read from DPC_CLOCK_REG (%08X)",PC, Value); return;
case 0xA4100014: LogMessage("%08X: read from DPC_BUFBUSY_REG (%08X)",PC, Value); return;
case 0xA4100018: LogMessage("%08X: read from DPC_PIPEBUSY_REG (%08X)",PC, Value); return;
case 0xA410001C: LogMessage("%08X: read from DPC_TMEM_REG (%08X)",PC, Value); return;
}
}
if (VAddr >= 0xA4300000 && VAddr <= 0xA430000C)
{
if (!g_LogOptions.LogMIPSInterface)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
switch (VAddr)
{
case 0xA4300000: LogMessage("%08X: read from MI_INIT_MODE_REG/MI_MODE_REG (%08X)",PC, Value); return;
case 0xA4300004: LogMessage("%08X: read from MI_VERSION_REG/MI_NOOP_REG (%08X)",PC, Value); return;
case 0xA4300008: LogMessage("%08X: read from MI_INTR_REG (%08X)",PC, Value); return;
case 0xA430000C: LogMessage("%08X: read from MI_INTR_MASK_REG (%08X)",PC, Value); return;
}
}
if (VAddr >= 0xA4400000 && VAddr <= 0xA4400034)
{
if (!g_LogOptions.LogVideoInterface)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
switch (VAddr)
{
case 0xA4400000: LogMessage("%08X: read from VI_STATUS_REG/VI_CONTROL_REG (%08X)",PC, Value); return;
case 0xA4400004: LogMessage("%08X: read from VI_ORIGIN_REG/VI_DRAM_ADDR_REG (%08X)",PC, Value); return;
case 0xA4400008: LogMessage("%08X: read from VI_WIDTH_REG/VI_H_WIDTH_REG (%08X)",PC, Value); return;
case 0xA440000C: LogMessage("%08X: read from VI_INTR_REG/VI_V_INTR_REG (%08X)",PC, Value); return;
case 0xA4400010: LogMessage("%08X: read from VI_CURRENT_REG/VI_V_CURRENT_LINE_REG (%08X)",PC, Value); return;
case 0xA4400014: LogMessage("%08X: read from VI_BURST_REG/VI_TIMING_REG (%08X)",PC, Value); return;
case 0xA4400018: LogMessage("%08X: read from VI_V_SYNC_REG (%08X)",PC, Value); return;
case 0xA440001C: LogMessage("%08X: read from VI_H_SYNC_REG (%08X)",PC, Value); return;
case 0xA4400020: LogMessage("%08X: read from VI_LEAP_REG/VI_H_SYNC_LEAP_REG (%08X)",PC, Value); return;
case 0xA4400024: LogMessage("%08X: read from VI_H_START_REG/VI_H_VIDEO_REG (%08X)",PC, Value); return;
case 0xA4400028: LogMessage("%08X: read from VI_V_START_REG/VI_V_VIDEO_REG (%08X)",PC, Value); return;
case 0xA440002C: LogMessage("%08X: read from VI_V_BURST_REG (%08X)",PC, Value); return;
case 0xA4400030: LogMessage("%08X: read from VI_X_SCALE_REG (%08X)",PC, Value); return;
case 0xA4400034: LogMessage("%08X: read from VI_Y_SCALE_REG (%08X)",PC, Value); return;
}
}
if (VAddr >= 0xA4500000 && VAddr <= 0xA4500014)
{
if (!g_LogOptions.LogAudioInterface)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
switch (VAddr)
{
case 0xA4500000: LogMessage("%08X: read from AI_DRAM_ADDR_REG (%08X)",PC, Value); return;
case 0xA4500004: LogMessage("%08X: read from AI_LEN_REG (%08X)",PC, Value); return;
case 0xA4500008: LogMessage("%08X: read from AI_CONTROL_REG (%08X)",PC, Value); return;
case 0xA450000C: LogMessage("%08X: read from AI_STATUS_REG (%08X)",PC, Value); return;
case 0xA4500010: LogMessage("%08X: read from AI_DACRATE_REG (%08X)",PC, Value); return;
case 0xA4500014: LogMessage("%08X: read from AI_BITRATE_REG (%08X)",PC, Value); return;
}
}
if (VAddr >= 0xA4600000 && VAddr <= 0xA4600030)
{
if (!g_LogOptions.LogPerInterface)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
switch (VAddr)
{
case 0xA4600000: LogMessage("%08X: read from PI_DRAM_ADDR_REG (%08X)",PC, Value); return;
case 0xA4600004: LogMessage("%08X: read from PI_CART_ADDR_REG (%08X)",PC, Value); return;
case 0xA4600008: LogMessage("%08X: read from PI_RD_LEN_REG (%08X)",PC, Value); return;
case 0xA460000C: LogMessage("%08X: read from PI_WR_LEN_REG (%08X)",PC, Value); return;
case 0xA4600010: LogMessage("%08X: read from PI_STATUS_REG (%08X)",PC, Value); return;
case 0xA4600014: LogMessage("%08X: read from PI_BSD_DOM1_LAT_REG/PI_DOMAIN1_REG (%08X)",PC, Value); return;
case 0xA4600018: LogMessage("%08X: read from PI_BSD_DOM1_PWD_REG (%08X)",PC, Value); return;
case 0xA460001C: LogMessage("%08X: read from PI_BSD_DOM1_PGS_REG (%08X)",PC, Value); return;
case 0xA4600020: LogMessage("%08X: read from PI_BSD_DOM1_RLS_REG (%08X)",PC, Value); return;
case 0xA4600024: LogMessage("%08X: read from PI_BSD_DOM2_LAT_REG/PI_DOMAIN2_REG (%08X)",PC, Value); return;
case 0xA4600028: LogMessage("%08X: read from PI_BSD_DOM2_PWD_REG (%08X)",PC, Value); return;
case 0xA460002C: LogMessage("%08X: read from PI_BSD_DOM2_PGS_REG (%08X)",PC, Value); return;
case 0xA4600030: LogMessage("%08X: read from PI_BSD_DOM2_RLS_REG (%08X)",PC, Value); return;
}
}
if (VAddr >= 0xA4700000 && VAddr <= 0xA470001C)
{
if (!g_LogOptions.LogRDRAMInterface)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
switch (VAddr)
{
case 0xA4700000: LogMessage("%08X: read from RI_MODE_REG (%08X)",PC, Value); return;
case 0xA4700004: LogMessage("%08X: read from RI_CONFIG_REG (%08X)",PC, Value); return;
case 0xA4700008: LogMessage("%08X: read from RI_CURRENT_LOAD_REG (%08X)",PC, Value); return;
case 0xA470000C: LogMessage("%08X: read from RI_SELECT_REG (%08X)",PC, Value); return;
case 0xA4700010: LogMessage("%08X: read from RI_REFRESH_REG/RI_COUNT_REG (%08X)",PC, Value); return;
case 0xA4700014: LogMessage("%08X: read from RI_LATENCY_REG (%08X)",PC, Value); return;
case 0xA4700018: LogMessage("%08X: read from RI_RERROR_REG (%08X)",PC, Value); return;
case 0xA470001C: LogMessage("%08X: read from RI_WERROR_REG (%08X)",PC, Value); return;
}
}
if ( VAddr == 0xA4800000)
{
if (!g_LogOptions.LogSerialInterface)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
LogMessage("%08X: read from SI_DRAM_ADDR_REG (%08X)",PC, Value);
return;
}
if ( VAddr == 0xA4800004)
{
if (!g_LogOptions.LogSerialInterface)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
LogMessage("%08X: read from SI_PIF_ADDR_RD64B_REG (%08X)",PC, Value);
return;
}
if ( VAddr == 0xA4800010)
{
if (!g_LogOptions.LogSerialInterface)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
LogMessage("%08X: read from SI_PIF_ADDR_WR64B_REG (%08X)",PC, Value);
return;
}
if ( VAddr == 0xA4800018)
{
if (!g_LogOptions.LogSerialInterface)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
LogMessage("%08X: read from SI_STATUS_REG (%08X)",PC, Value);
return;
}
if ( VAddr >= 0xBFC00000 && VAddr <= 0xBFC007C0 )
{
return;
}
if ( VAddr >= 0xBFC007C0 && VAddr <= 0xBFC007FC )
{
if (!g_LogOptions.LogPRDirectMemLoads)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
LogMessage("%08X: read word from Pif Ram at 0x%X (%08X)",PC,VAddr - 0xBFC007C0, Value);
return;
}
if ( VAddr >= 0xB0000040 && ((VAddr - 0xB0000000) < g_Rom->GetRomSize()))
{
return;
}
if ( VAddr >= 0xB0000000 && VAddr < 0xB0000040)
{
if (!g_LogOptions.LogRomHeader)
{
return;
}
g_MMU->LW_VAddr(VAddr,Value);
switch (VAddr)
{
case 0xB0000004: LogMessage("%08X: read from Rom Clock Rate (%08X)",PC, Value); break;
case 0xB0000008: LogMessage("%08X: read from Rom Boot address offset (%08X)",PC, Value); break;
case 0xB000000C: LogMessage("%08X: read from Rom Release offset (%08X)",PC, Value); break;
case 0xB0000010: LogMessage("%08X: read from Rom CRC1 (%08X)",PC, Value); break;
case 0xB0000014: LogMessage("%08X: read from Rom CRC2 (%08X)",PC, Value); break;
default: LogMessage("%08X: read from Rom header 0x%X (%08X)",PC, VAddr & 0xFF,Value); break;
}
return;
}
if (!g_LogOptions.LogUnknown)
{
return;
}
LogMessage("%08X: read from unknown ??? (%08X)",PC,VAddr);
}
void Log_SW (uint32_t PC, uint32_t VAddr, uint32_t Value)
{
if (!g_LogOptions.GenerateLog)
{
return;
}
if ( VAddr < 0xA0000000 || VAddr >= 0xC0000000 )
{
uint32_t PAddr;
if (!g_TransVaddr->TranslateVaddr(VAddr,PAddr))
{
if (g_LogOptions.LogUnknown)
{
LogMessage("%08X: Writing 0x%08X to %08X",PC, Value, VAddr );
}
return;
}
VAddr = PAddr + 0xA0000000;
}
if ( VAddr >= 0xA0000000 && VAddr < (0xA0000000 + g_MMU->RdramSize()))
{
return;
}
if ( VAddr >= 0xA3F00000 && VAddr <= 0xA3F00024)
{
if (!g_LogOptions.LogRDRamRegisters)
{
return;
}
switch (VAddr)
{
case 0xA3F00000: LogMessage("%08X: Writing 0x%08X to RDRAM_CONFIG_REG/RDRAM_DEVICE_TYPE_REG",PC, Value ); return;
case 0xA3F00004: LogMessage("%08X: Writing 0x%08X to RDRAM_DEVICE_ID_REG",PC, Value ); return;
case 0xA3F00008: LogMessage("%08X: Writing 0x%08X to RDRAM_DELAY_REG",PC, Value ); return;
case 0xA3F0000C: LogMessage("%08X: Writing 0x%08X to RDRAM_MODE_REG",PC, Value ); return;
case 0xA3F00010: LogMessage("%08X: Writing 0x%08X to RDRAM_REF_INTERVAL_REG",PC, Value ); return;
case 0xA3F00014: LogMessage("%08X: Writing 0x%08X to RDRAM_REF_ROW_REG",PC, Value ); return;
case 0xA3F00018: LogMessage("%08X: Writing 0x%08X to RDRAM_RAS_INTERVAL_REG",PC, Value ); return;
case 0xA3F0001C: LogMessage("%08X: Writing 0x%08X to RDRAM_MIN_INTERVAL_REG",PC, Value ); return;
case 0xA3F00020: LogMessage("%08X: Writing 0x%08X to RDRAM_ADDR_SELECT_REG",PC, Value ); return;
case 0xA3F00024: LogMessage("%08X: Writing 0x%08X to RDRAM_DEVICE_MANUF_REG",PC, Value ); return;
}
}
if ( VAddr >= 0xA4000000 && VAddr <= 0xA4001FFC )
{
return;
}
if ( VAddr >= 0xA4040000 && VAddr <= 0xA404001C)
{
if (!g_LogOptions.LogSPRegisters)
{
return;
}
switch (VAddr)
{
case 0xA4040000: LogMessage("%08X: Writing 0x%08X to SP_MEM_ADDR_REG",PC, Value ); return;
case 0xA4040004: LogMessage("%08X: Writing 0x%08X to SP_DRAM_ADDR_REG",PC, Value ); return;
case 0xA4040008: LogMessage("%08X: Writing 0x%08X to SP_RD_LEN_REG",PC, Value ); return;
case 0xA404000C: LogMessage("%08X: Writing 0x%08X to SP_WR_LEN_REG",PC, Value ); return;
case 0xA4040010: LogMessage("%08X: Writing 0x%08X to SP_STATUS_REG",PC, Value ); return;
case 0xA4040014: LogMessage("%08X: Writing 0x%08X to SP_DMA_FULL_REG",PC, Value ); return;
case 0xA4040018: LogMessage("%08X: Writing 0x%08X to SP_DMA_BUSY_REG",PC, Value ); return;
case 0xA404001C: LogMessage("%08X: Writing 0x%08X to SP_SEMAPHORE_REG",PC, Value ); return;
}
}
if ( VAddr == 0xA4080000)
{
if (!g_LogOptions.LogSPRegisters)
{
return;
}
LogMessage("%08X: Writing 0x%08X to SP_PC",PC, Value ); return;
}
if ( VAddr >= 0xA4100000 && VAddr <= 0xA410001C)
{
if (!g_LogOptions.LogDPCRegisters)
{
return;
}
switch (VAddr)
{
case 0xA4100000: LogMessage("%08X: Writing 0x%08X to DPC_START_REG",PC, Value ); return;
case 0xA4100004: LogMessage("%08X: Writing 0x%08X to DPC_END_REG",PC, Value ); return;
case 0xA4100008: LogMessage("%08X: Writing 0x%08X to DPC_CURRENT_REG",PC, Value ); return;
case 0xA410000C: LogMessage("%08X: Writing 0x%08X to DPC_STATUS_REG",PC, Value ); return;
case 0xA4100010: LogMessage("%08X: Writing 0x%08X to DPC_CLOCK_REG",PC, Value ); return;
case 0xA4100014: LogMessage("%08X: Writing 0x%08X to DPC_BUFBUSY_REG",PC, Value ); return;
case 0xA4100018: LogMessage("%08X: Writing 0x%08X to DPC_PIPEBUSY_REG",PC, Value ); return;
case 0xA410001C: LogMessage("%08X: Writing 0x%08X to DPC_TMEM_REG",PC, Value ); return;
}
}
if ( VAddr >= 0xA4200000 && VAddr <= 0xA420000C)
{
if (!g_LogOptions.LogDPSRegisters)
{
return;
}
switch (VAddr)
{
case 0xA4200000: LogMessage("%08X: Writing 0x%08X to DPS_TBIST_REG",PC, Value ); return;
case 0xA4200004: LogMessage("%08X: Writing 0x%08X to DPS_TEST_MODE_REG",PC, Value ); return;
case 0xA4200008: LogMessage("%08X: Writing 0x%08X to DPS_BUFTEST_ADDR_REG",PC, Value ); return;
case 0xA420000C: LogMessage("%08X: Writing 0x%08X to DPS_BUFTEST_DATA_REG",PC, Value ); return;
}
}
if ( VAddr >= 0xA4300000 && VAddr <= 0xA430000C)
{
if (!g_LogOptions.LogMIPSInterface)
{
return;
}
switch (VAddr)
{
case 0xA4300000: LogMessage("%08X: Writing 0x%08X to MI_INIT_MODE_REG/MI_MODE_REG",PC, Value ); return;
case 0xA4300004: LogMessage("%08X: Writing 0x%08X to MI_VERSION_REG/MI_NOOP_REG",PC, Value ); return;
case 0xA4300008: LogMessage("%08X: Writing 0x%08X to MI_INTR_REG",PC, Value ); return;
case 0xA430000C: LogMessage("%08X: Writing 0x%08X to MI_INTR_MASK_REG",PC, Value ); return;
}
}
if ( VAddr >= 0xA4400000 && VAddr <= 0xA4400034)
{
if (!g_LogOptions.LogVideoInterface)
{
return;
}
switch (VAddr)
{
case 0xA4400000: LogMessage("%08X: Writing 0x%08X to VI_STATUS_REG/VI_CONTROL_REG",PC, Value ); return;
case 0xA4400004: LogMessage("%08X: Writing 0x%08X to VI_ORIGIN_REG/VI_DRAM_ADDR_REG",PC, Value ); return;
case 0xA4400008: LogMessage("%08X: Writing 0x%08X to VI_WIDTH_REG/VI_H_WIDTH_REG",PC, Value ); return;
case 0xA440000C: LogMessage("%08X: Writing 0x%08X to VI_INTR_REG/VI_V_INTR_REG",PC, Value ); return;
case 0xA4400010: LogMessage("%08X: Writing 0x%08X to VI_CURRENT_REG/VI_V_CURRENT_LINE_REG",PC, Value ); return;
case 0xA4400014: LogMessage("%08X: Writing 0x%08X to VI_BURST_REG/VI_TIMING_REG",PC, Value ); return;
case 0xA4400018: LogMessage("%08X: Writing 0x%08X to VI_V_SYNC_REG",PC, Value ); return;
case 0xA440001C: LogMessage("%08X: Writing 0x%08X to VI_H_SYNC_REG",PC, Value ); return;
case 0xA4400020: LogMessage("%08X: Writing 0x%08X to VI_LEAP_REG/VI_H_SYNC_LEAP_REG",PC, Value ); return;
case 0xA4400024: LogMessage("%08X: Writing 0x%08X to VI_H_START_REG/VI_H_VIDEO_REG",PC, Value ); return;
case 0xA4400028: LogMessage("%08X: Writing 0x%08X to VI_V_START_REG/VI_V_VIDEO_REG",PC, Value ); return;
case 0xA440002C: LogMessage("%08X: Writing 0x%08X to VI_V_BURST_REG",PC, Value ); return;
case 0xA4400030: LogMessage("%08X: Writing 0x%08X to VI_X_SCALE_REG",PC, Value ); return;
case 0xA4400034: LogMessage("%08X: Writing 0x%08X to VI_Y_SCALE_REG",PC, Value ); return;
}
}
if ( VAddr >= 0xA4500000 && VAddr <= 0xA4500014)
{
if (!g_LogOptions.LogAudioInterface)
{
return;
}
switch (VAddr)
{
case 0xA4500000: LogMessage("%08X: Writing 0x%08X to AI_DRAM_ADDR_REG",PC, Value ); return;
case 0xA4500004: LogMessage("%08X: Writing 0x%08X to AI_LEN_REG",PC, Value ); return;
case 0xA4500008: LogMessage("%08X: Writing 0x%08X to AI_CONTROL_REG",PC, Value ); return;
case 0xA450000C: LogMessage("%08X: Writing 0x%08X to AI_STATUS_REG",PC, Value ); return;
case 0xA4500010: LogMessage("%08X: Writing 0x%08X to AI_DACRATE_REG",PC, Value ); return;
case 0xA4500014: LogMessage("%08X: Writing 0x%08X to AI_BITRATE_REG",PC, Value ); return;
}
}
if ( VAddr >= 0xA4600000 && VAddr <= 0xA4600030)
{
if (!g_LogOptions.LogPerInterface)
{
return;
}
switch (VAddr)
{
case 0xA4600000: LogMessage("%08X: Writing 0x%08X to PI_DRAM_ADDR_REG",PC, Value ); return;
case 0xA4600004: LogMessage("%08X: Writing 0x%08X to PI_CART_ADDR_REG",PC, Value ); return;
case 0xA4600008: LogMessage("%08X: Writing 0x%08X to PI_RD_LEN_REG",PC, Value ); return;
case 0xA460000C: LogMessage("%08X: Writing 0x%08X to PI_WR_LEN_REG",PC, Value ); return;
case 0xA4600010: LogMessage("%08X: Writing 0x%08X to PI_STATUS_REG",PC, Value ); return;
case 0xA4600014: LogMessage("%08X: Writing 0x%08X to PI_BSD_DOM1_LAT_REG/PI_DOMAIN1_REG",PC, Value ); return;
case 0xA4600018: LogMessage("%08X: Writing 0x%08X to PI_BSD_DOM1_PWD_REG",PC, Value ); return;
case 0xA460001C: LogMessage("%08X: Writing 0x%08X to PI_BSD_DOM1_PGS_REG",PC, Value ); return;
case 0xA4600020: LogMessage("%08X: Writing 0x%08X to PI_BSD_DOM1_RLS_REG",PC, Value ); return;
case 0xA4600024: LogMessage("%08X: Writing 0x%08X to PI_BSD_DOM2_LAT_REG/PI_DOMAIN2_REG",PC, Value ); return;
case 0xA4600028: LogMessage("%08X: Writing 0x%08X to PI_BSD_DOM2_PWD_REG",PC, Value ); return;
case 0xA460002C: LogMessage("%08X: Writing 0x%08X to PI_BSD_DOM2_PGS_REG",PC, Value ); return;
case 0xA4600030: LogMessage("%08X: Writing 0x%08X to PI_BSD_DOM2_RLS_REG",PC, Value ); return;
}
}
if ( VAddr >= 0xA4700000 && VAddr <= 0xA470001C)
{
if (!g_LogOptions.LogRDRAMInterface)
{
return;
}
switch (VAddr)
{
case 0xA4700000: LogMessage("%08X: Writing 0x%08X to RI_MODE_REG",PC, Value ); return;
case 0xA4700004: LogMessage("%08X: Writing 0x%08X to RI_CONFIG_REG",PC, Value ); return;
case 0xA4700008: LogMessage("%08X: Writing 0x%08X to RI_CURRENT_LOAD_REG",PC, Value ); return;
case 0xA470000C: LogMessage("%08X: Writing 0x%08X to RI_SELECT_REG",PC, Value ); return;
case 0xA4700010: LogMessage("%08X: Writing 0x%08X to RI_REFRESH_REG/RI_COUNT_REG",PC, Value ); return;
case 0xA4700014: LogMessage("%08X: Writing 0x%08X to RI_LATENCY_REG",PC, Value ); return;
case 0xA4700018: LogMessage("%08X: Writing 0x%08X to RI_RERROR_REG",PC, Value ); return;
case 0xA470001C: LogMessage("%08X: Writing 0x%08X to RI_WERROR_REG",PC, Value ); return;
}
}
if ( VAddr == 0xA4800000)
{
if (!g_LogOptions.LogSerialInterface)
{
return;
}
LogMessage("%08X: Writing 0x%08X to SI_DRAM_ADDR_REG",PC, Value ); return;
}
if ( VAddr == 0xA4800004)
{
if (g_LogOptions.LogPRDMAOperations)
{
LogMessage("%08X: A DMA transfer from the PIF ram has occured",PC );
}
if (!g_LogOptions.LogSerialInterface)
{
return;
}
LogMessage("%08X: Writing 0x%08X to SI_PIF_ADDR_RD64B_REG",PC, Value ); return;
}
if ( VAddr == 0xA4800010)
{
if (g_LogOptions.LogPRDMAOperations)
{
LogMessage("%08X: A DMA transfer to the PIF ram has occured",PC );
}
if (!g_LogOptions.LogSerialInterface)
{
return;
}
LogMessage("%08X: Writing 0x%08X to SI_PIF_ADDR_WR64B_REG",PC, Value ); return;
}
if ( VAddr == 0xA4800018)
{
if (!g_LogOptions.LogSerialInterface)
{
return;
}
LogMessage("%08X: Writing 0x%08X to SI_STATUS_REG",PC, Value ); return;
}
if ( VAddr >= 0xBFC007C0 && VAddr <= 0xBFC007FC )
{
if (!g_LogOptions.LogPRDirectMemStores)
{
return;
}
LogMessage("%08X: Writing 0x%08X to Pif Ram at 0x%X",PC,Value, VAddr - 0xBFC007C0);
return;
}
if (!g_LogOptions.LogUnknown)
{
return;
}
LogMessage("%08X: Writing 0x%08X to %08X ????",PC, Value, VAddr );
}
LRESULT CALLBACK LogPifProc (HWND hDlg, UINT uMsg, WPARAM /*wParam*/, LPARAM lParam)
{
switch (uMsg)
{
case WM_INITDIALOG:
if (TempOptions.LogPRDMAOperations) { CheckDlgButton(hDlg,IDC_SI_DMA,BST_CHECKED); }
if (TempOptions.LogPRDirectMemLoads) { CheckDlgButton(hDlg,IDC_DIRECT_WRITE,BST_CHECKED); }
if (TempOptions.LogPRDMAMemLoads) { CheckDlgButton(hDlg,IDC_DMA_WRITE,BST_CHECKED); }
if (TempOptions.LogPRDirectMemStores) { CheckDlgButton(hDlg,IDC_DIRECT_READ,BST_CHECKED); }
if (TempOptions.LogPRDMAMemStores) { CheckDlgButton(hDlg,IDC_DMA_READ,BST_CHECKED); }
if (TempOptions.LogControllerPak) { CheckDlgButton(hDlg,IDC_CONT_PAK,BST_CHECKED); }
break;
case WM_NOTIFY:
if (((NMHDR FAR *) lParam)->code != PSN_APPLY)
{
break;
}
TempOptions.LogPRDMAOperations = IsDlgButtonChecked(hDlg,IDC_SI_DMA) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogPRDirectMemLoads = IsDlgButtonChecked(hDlg,IDC_DIRECT_WRITE) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogPRDMAMemLoads = IsDlgButtonChecked(hDlg,IDC_DMA_WRITE) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogPRDirectMemStores = IsDlgButtonChecked(hDlg,IDC_DIRECT_READ) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogPRDMAMemStores = IsDlgButtonChecked(hDlg,IDC_DMA_READ) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogControllerPak = IsDlgButtonChecked(hDlg,IDC_CONT_PAK) == BST_CHECKED?TRUE:FALSE;
break;
default:
return FALSE;
}
return TRUE;
}
LRESULT CALLBACK LogRegProc (HWND hDlg, UINT uMsg, WPARAM /*wParam*/, LPARAM lParam)
{
switch (uMsg)
{
case WM_INITDIALOG:
if (TempOptions.LogRDRamRegisters) { CheckDlgButton(hDlg,IDC_RDRAM,BST_CHECKED); }
if (TempOptions.LogSPRegisters) { CheckDlgButton(hDlg,IDC_SP_REG,BST_CHECKED); }
if (TempOptions.LogDPCRegisters) { CheckDlgButton(hDlg,IDC_DPC_REG,BST_CHECKED); }
if (TempOptions.LogDPSRegisters) { CheckDlgButton(hDlg,IDC_DPS_REG,BST_CHECKED); }
if (TempOptions.LogMIPSInterface) { CheckDlgButton(hDlg,IDC_MI_REG,BST_CHECKED); }
if (TempOptions.LogVideoInterface) { CheckDlgButton(hDlg,IDC_VI_REG,BST_CHECKED); }
if (TempOptions.LogAudioInterface) { CheckDlgButton(hDlg,IDC_AI_REG,BST_CHECKED); }
if (TempOptions.LogPerInterface) { CheckDlgButton(hDlg,IDC_PI_REG,BST_CHECKED); }
if (TempOptions.LogRDRAMInterface) { CheckDlgButton(hDlg,IDC_RI_REG,BST_CHECKED); }
if (TempOptions.LogSerialInterface) { CheckDlgButton(hDlg,IDC_SI_REG,BST_CHECKED); }
break;
case WM_NOTIFY:
if (((NMHDR FAR *) lParam)->code != PSN_APPLY)
{
break;
}
TempOptions.LogRDRamRegisters = IsDlgButtonChecked(hDlg,IDC_RDRAM) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogSPRegisters = IsDlgButtonChecked(hDlg,IDC_SP_REG) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogDPCRegisters = IsDlgButtonChecked(hDlg,IDC_DPC_REG) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogDPSRegisters = IsDlgButtonChecked(hDlg,IDC_DPS_REG) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogMIPSInterface = IsDlgButtonChecked(hDlg,IDC_MI_REG) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogVideoInterface = IsDlgButtonChecked(hDlg,IDC_VI_REG) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogAudioInterface = IsDlgButtonChecked(hDlg,IDC_AI_REG) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogPerInterface = IsDlgButtonChecked(hDlg,IDC_PI_REG) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogRDRAMInterface = IsDlgButtonChecked(hDlg,IDC_RI_REG) == BST_CHECKED?TRUE:FALSE;
TempOptions.LogSerialInterface = IsDlgButtonChecked(hDlg,IDC_SI_REG) == BST_CHECKED?TRUE:FALSE;
break;
default:
return FALSE;
}
return TRUE;
}
void SaveLogSetting (HKEY hKey,char * String, BOOL Value)
{
DWORD StoreValue = Value;
RegSetValueEx(hKey,String,0,REG_DWORD,(CONST BYTE *)&StoreValue,sizeof(DWORD));
}
void SaveLogOptions (void)
{
long lResult;
HKEY hKeyResults = 0;
DWORD Disposition = 0;
char String[200];
sprintf(String,"Software\\N64 Emulation\\%s\\Logging",g_Settings->LoadStringVal(Setting_ApplicationName).c_str());
lResult = RegCreateKeyEx( HKEY_CURRENT_USER,String,0,"", REG_OPTION_NON_VOLATILE,
KEY_ALL_ACCESS,NULL,&hKeyResults,&Disposition);
SaveLogSetting(hKeyResults,"Log RDRAM",TempOptions.LogRDRamRegisters);
SaveLogSetting(hKeyResults,"Log SP",TempOptions.LogSPRegisters);
SaveLogSetting(hKeyResults,"Log DP Command",TempOptions.LogDPCRegisters);
SaveLogSetting(hKeyResults,"Log DP Span",TempOptions.LogDPSRegisters);
SaveLogSetting(hKeyResults,"Log MIPS Interface (MI)",TempOptions.LogMIPSInterface);
SaveLogSetting(hKeyResults,"Log Video Interface (VI)",TempOptions.LogVideoInterface);
SaveLogSetting(hKeyResults,"Log Audio Interface (AI)",TempOptions.LogAudioInterface);
SaveLogSetting(hKeyResults,"Log Peripheral Interface (PI)",TempOptions.LogPerInterface);
SaveLogSetting(hKeyResults,"Log RDRAM Interface (RI)",TempOptions.LogRDRAMInterface);
SaveLogSetting(hKeyResults,"Log Serial Interface (SI)",TempOptions.LogSerialInterface);
SaveLogSetting(hKeyResults,"Log PifRam DMA Operations",TempOptions.LogPRDMAOperations);
SaveLogSetting(hKeyResults,"Log PifRam Direct Memory Loads",TempOptions.LogPRDirectMemLoads);
SaveLogSetting(hKeyResults,"Log PifRam DMA Memory Loads",TempOptions.LogPRDMAMemLoads);
SaveLogSetting(hKeyResults,"Log PifRam Direct Memory Stores",TempOptions.LogPRDirectMemStores);
SaveLogSetting(hKeyResults,"Log PifRam DMA Memory Stores",TempOptions.LogPRDMAMemStores);
SaveLogSetting(hKeyResults,"Log Controller Pak",TempOptions.LogControllerPak);
SaveLogSetting(hKeyResults,"Log CP0 changes",TempOptions.LogCP0changes);
SaveLogSetting(hKeyResults,"Log CP0 reads",TempOptions.LogCP0reads);
SaveLogSetting(hKeyResults,"Log Exceptions",TempOptions.LogExceptions);
SaveLogSetting(hKeyResults,"No Interrupts",TempOptions.NoInterrupts);
SaveLogSetting(hKeyResults,"Log TLB",TempOptions.LogTLB);
SaveLogSetting(hKeyResults,"Log Cache Operations",TempOptions.LogCache);
SaveLogSetting(hKeyResults,"Log Rom Header",TempOptions.LogRomHeader);
SaveLogSetting(hKeyResults,"Log Unknown access",TempOptions.LogUnknown);
RegCloseKey(hKeyResults);
}
void LogMessage (const char * Message, ...)
{
DWORD dwWritten;
char Msg[400];
va_list ap;
if (!g_Settings->LoadBool(Debugger_Enabled))
{
return;
}
if (g_hLogFile == NULL)
{
return;
}
va_start( ap, Message );
vsprintf( Msg, Message, ap );
va_end( ap );
strcat(Msg,"\r\n");
WriteFile( g_hLogFile,Msg,strlen(Msg),&dwWritten,NULL );
}
void StartLog (void)
{
if (!g_LogOptions.GenerateLog)
{
StopLog();
return;
}
if (g_hLogFile)
{
return;
}
CPath LogFile(CPath::MODULE_DIRECTORY);
LogFile.AppendDirectory("Logs");
LogFile.SetNameExtension("cpudebug.log");
g_hLogFile = CreateFile(LogFile,GENERIC_WRITE, FILE_SHARE_READ,NULL,CREATE_ALWAYS, FILE_ATTRIBUTE_NORMAL | FILE_FLAG_SEQUENTIAL_SCAN, NULL);
SetFilePointer(g_hLogFile,0,NULL,FILE_BEGIN);
}
void StopLog (void)
{
if (g_hLogFile)
{
CloseHandle(g_hLogFile);
}
g_hLogFile = NULL;
}