project64/Source/Project64/UserInterface/Debugger/Debugger.cpp

757 lines
21 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 "DebuggerUI.h"
#include "ScriptHook.h"
#include "DMALog.h"
#include "Symbols.h"
CPj64Module _Module;
CDebuggerUI::CDebuggerUI() :
m_MemoryDump(NULL),
m_MemoryView(NULL),
m_MemorySearch(NULL),
m_DebugTLB(NULL),
m_CommandsView(NULL),
m_Scripts(NULL),
m_Symbols(NULL),
m_Breakpoints(NULL),
m_ScriptSystem(NULL),
m_StackTrace(NULL),
m_StackView(NULL),
m_DMALogView(NULL),
m_DMALog(NULL),
m_StepEvent(false)
{
g_Debugger = this;
m_Breakpoints = new CBreakpoints();
m_ScriptSystem = new CScriptSystem(this);
m_DMALog = new CDMALog();
CSymbols::InitializeCriticalSection();
g_Settings->RegisterChangeCB(GameRunning_InReset, this, (CSettings::SettingChangedFunc)GameReset);
g_Settings->RegisterChangeCB(Debugger_SteppingOps, this, (CSettings::SettingChangedFunc)SteppingOpsChanged);
}
CDebuggerUI::~CDebuggerUI(void)
{
g_Settings->UnregisterChangeCB(Debugger_SteppingOps, this, (CSettings::SettingChangedFunc)SteppingOpsChanged);
g_Settings->UnregisterChangeCB(GameRunning_InReset, this, (CSettings::SettingChangedFunc)GameReset);
Debug_Reset();
delete m_MemoryView;
delete m_CommandsView;
delete m_Scripts;
delete m_ScriptSystem;
delete m_Breakpoints;
delete m_Symbols;
delete m_MemorySearch;
delete m_StackTrace;
delete m_DMALogView;
delete m_DMALog;
CSymbols::DeleteCriticalSection();
}
void CDebuggerUI::SteppingOpsChanged(CDebuggerUI * _this)
{
if (g_Settings->LoadBool(Debugger_SteppingOps))
{
_this->OpenCommandWindow();
}
}
void CDebuggerUI::GameReset(CDebuggerUI * _this)
{
if (!g_Settings->LoadBool(GameRunning_InReset))
{
return;
}
if (_this->m_CommandsView)
{
_this->m_CommandsView->Reset();
}
if (_this->m_DMALog)
{
_this->m_DMALog->ClearEntries();
}
if (_this->m_StackTrace)
{
_this->m_StackTrace->ClearEntries();
}
CSymbols::EnterCriticalSection();
CSymbols::Load();
CSymbols::LeaveCriticalSection();
if (_this->m_Symbols)
{
_this->m_Symbols->Refresh();
}
}
void CDebuggerUI::Debug_Reset(void)
{
if (m_MemoryDump)
{
m_MemoryDump->HideWindow();
delete m_MemoryDump;
m_MemoryDump = NULL;
}
if (m_MemorySearch)
{
m_MemorySearch->HideWindow();
delete m_MemorySearch;
m_MemorySearch = NULL;
}
if (m_DebugTLB)
{
m_DebugTLB->HideWindow();
delete m_DebugTLB;
m_DebugTLB = NULL;
}
if (m_MemoryView)
{
m_MemoryView->HideWindow();
delete m_MemoryView;
m_MemoryView = NULL;
}
if (m_CommandsView)
{
m_CommandsView->HideWindow();
delete m_CommandsView;
m_CommandsView = NULL;
}
if (m_Scripts)
{
m_Scripts->HideWindow();
delete m_Scripts;
m_Scripts = NULL;
}
if (m_Symbols)
{
m_Symbols->HideWindow();
delete m_Symbols;
m_Symbols = NULL;
}
if (m_DMALogView)
{
m_DMALogView->HideWindow();
delete m_DMALogView;
m_DMALogView = NULL;
}
if (m_StackTrace)
{
m_StackTrace->HideWindow();
delete m_StackTrace;
m_StackTrace = NULL;
}
if (m_StackView)
{
m_StackView->HideWindow();
delete m_StackView;
m_StackView = NULL;
}
}
void CDebuggerUI::OpenMemoryDump()
{
if (g_MMU == NULL)
{
return;
}
if (m_MemoryDump == NULL)
{
m_MemoryDump = new CDumpMemory(this);
}
if (m_MemoryDump)
{
m_MemoryDump->ShowWindow();
}
}
void CDebuggerUI::OpenMemoryWindow(void)
{
if (g_MMU == NULL)
{
return;
}
if (m_MemoryView == NULL)
{
m_MemoryView = new CDebugMemoryView(this);
}
if (m_MemoryView)
{
m_MemoryView->ShowWindow();
}
}
void CDebuggerUI::Debug_ShowMemoryLocation(uint32_t Address, bool VAddr)
{
OpenMemoryWindow();
if (m_MemoryView)
{
m_MemoryView->ShowAddress(Address, VAddr);
}
}
void CDebuggerUI::OpenTLBWindow(void)
{
if (g_MMU == NULL)
{
return;
}
if (m_DebugTLB == NULL)
{
m_DebugTLB = new CDebugTlb(this);
}
if (m_DebugTLB)
{
m_DebugTLB->ShowWindow();
}
}
void CDebuggerUI::Debug_RefreshTLBWindow(void)
{
if (m_DebugTLB)
{
m_DebugTLB->RefreshTLBWindow();
}
}
void CDebuggerUI::OpenMemorySearch()
{
if (m_MemorySearch == NULL)
{
m_MemorySearch = new CDebugMemorySearch(this);
}
if (m_MemorySearch)
{
m_MemorySearch->ShowWindow();
}
}
void CDebuggerUI::OpenCommandWindow()
{
if (m_CommandsView == NULL)
{
m_CommandsView = new CDebugCommandsView(this, m_StepEvent);
}
m_CommandsView->ShowWindow();
}
void CDebuggerUI::Debug_ShowCommandsLocation(uint32_t address, bool top)
{
OpenCommandWindow();
if (m_CommandsView)
{
m_CommandsView->ShowAddress(address, top);
}
}
void CDebuggerUI::OpenScriptsWindow()
{
if (m_Scripts == NULL)
{
m_Scripts = new CDebugScripts(this);
}
m_Scripts->ShowWindow();
}
void CDebuggerUI::Debug_RefreshScriptsWindow()
{
if (m_Scripts != NULL)
{
m_Scripts->RefreshList();
}
}
void CDebuggerUI::Debug_LogScriptsWindow(const char* text)
{
if (m_Scripts != NULL)
{
m_Scripts->ConsolePrint(text);
}
}
void CDebuggerUI::Debug_ClearScriptsWindow()
{
if (m_Scripts != NULL)
{
m_Scripts->ConsoleClear();
}
}
void CDebuggerUI::OpenSymbolsWindow()
{
if (m_Symbols == NULL)
{
m_Symbols = new CDebugSymbols(this);
}
m_Symbols->ShowWindow();
}
void CDebuggerUI::Debug_RefreshSymbolsWindow()
{
if (m_Symbols != NULL)
{
m_Symbols->Refresh();
}
}
void CDebuggerUI::OpenDMALogWindow(void)
{
if (m_DMALogView == NULL)
{
m_DMALogView = new CDebugDMALogView(this);
}
m_DMALogView->ShowWindow();
}
void CDebuggerUI::OpenStackTraceWindow(void)
{
if (m_StackTrace == NULL)
{
m_StackTrace = new CDebugStackTrace(this);
}
m_StackTrace->ShowWindow();
}
void CDebuggerUI::OpenStackViewWindow(void)
{
if (m_StackView == NULL)
{
m_StackView = new CDebugStackView(this);
}
m_StackView->ShowWindow();
}
void CDebuggerUI::Debug_RefreshStackWindow(void)
{
if (m_StackView != NULL)
{
m_StackView->Refresh();
}
}
void CDebuggerUI::Debug_RefreshStackTraceWindow(void)
{
if (m_StackTrace != NULL && m_StackTrace->m_hWnd != NULL)
{
m_StackTrace->Refresh();
}
}
CBreakpoints* CDebuggerUI::Breakpoints()
{
return m_Breakpoints;
}
CScriptSystem* CDebuggerUI::ScriptSystem()
{
return m_ScriptSystem;
}
CDebugScripts* CDebuggerUI::ScriptConsole()
{
return m_Scripts;
}
CDMALog* CDebuggerUI::DMALog()
{
return m_DMALog;
}
// thread safe LW_PAddr
// does not trigger application breakpoint if paddr is invalid
bool CDebuggerUI::DebugLW_PAddr(uint32_t paddr, uint32_t& value)
{
if (g_MMU == NULL)
{
return false;
}
if ((paddr < g_MMU->RdramSize()) || // RDRAM
(paddr >= 0x04000000 && paddr <= 0x04001FFF)) // DMEM/IMEM
{
value = *(uint32_t*)(g_MMU->Rdram() + paddr);
return true;
}
else if (paddr >= 0x05000000 && paddr <= 0x050004FF) // 64DD buffer
{
// todo
return false;
}
else if (paddr >= 0x06000000 && paddr <= 0x06FFFFFF) // Cartridge Domain 1 (Address 1) (64DD IPL ROM)
{
uint32_t iplRomOffset = paddr - 0x06000000;
if (g_DDRom != NULL && iplRomOffset < g_DDRom->GetRomSize())
{
value = *(uint32_t*)(g_MMU->Rdram() + paddr);
return true;
}
}
else if (paddr >= 0x08000000 && paddr < 0x08FFFFFF) // Cartridge Domain 2 (Address 2)
{
uint32_t saveOffset = paddr & 0x000FFFFF;
if (g_System->m_SaveUsing == SaveChip_Sram && saveOffset <= 0x7FFF) // sram
{
uint8_t tmp[4] = "";
CSram *sram = g_MMU->GetSram();
sram->DmaFromSram(tmp, paddr - 0x08000000, 4);
value = tmp[3] << 24 | tmp[2] << 16 | tmp[1] << 8 | tmp[0];
return true;
}
else if (g_System->m_SaveUsing == SaveChip_FlashRam && saveOffset == 0) // flash ram status
{
CFlashram* flashRam = g_MMU->GetFlashram();
value = flashRam->ReadFromFlashStatus(0x08000000);
return true;
}
}
else if (paddr >= 0x10000000 && paddr <= 0x15FFFFFF) // Cartridge ROM
{
uint32_t cartRomOffset = paddr - 0x10000000;
if (g_Rom != NULL && paddr < g_Rom->GetRomSize())
{
value = *(uint32_t*)(g_Rom->GetRomAddress() + cartRomOffset);
return true;
}
}
else if (paddr >= 0x1FC00000 && paddr <= 0x1FC007BF) // PIF ROM
{
return false;
}
else if (paddr >= 0x1FC007C0 && paddr <= 0x1FC007FF) // PIF RAM
{
uint32_t pifRamOffset = paddr - 0x1FC007C0;
value = *(uint32_t*)(g_MMU->PifRam() + pifRamOffset);
return true;
}
// note: write-only registers are excluded
switch (paddr)
{
case 0x03F00000: value = g_Reg->RDRAM_CONFIG_REG; return true;
case 0x03F00004: value = g_Reg->RDRAM_DEVICE_ID_REG; return true;
case 0x03F00008: value = g_Reg->RDRAM_DELAY_REG; return true;
case 0x03F0000C: value = g_Reg->RDRAM_MODE_REG; return true;
case 0x03F00010: value = g_Reg->RDRAM_REF_INTERVAL_REG; return true;
case 0x03F00014: value = g_Reg->RDRAM_REF_ROW_REG; return true;
case 0x03F00018: value = g_Reg->RDRAM_RAS_INTERVAL_REG; return true;
case 0x03F0001C: value = g_Reg->RDRAM_MIN_INTERVAL_REG; return true;
case 0x03F00020: value = g_Reg->RDRAM_ADDR_SELECT_REG; return true;
case 0x03F00024: value = g_Reg->RDRAM_DEVICE_MANUF_REG; return true;
case 0x04040010: value = g_Reg->SP_STATUS_REG; return true;
case 0x04040014: value = g_Reg->SP_DMA_FULL_REG; return true;
case 0x04040018: value = g_Reg->SP_DMA_BUSY_REG; return true;
case 0x0404001C: value = g_Reg->SP_SEMAPHORE_REG; return true;
case 0x04080000: value = g_Reg->SP_PC_REG; return true;
case 0x0410000C: value = g_Reg->DPC_STATUS_REG; return true;
case 0x04100010: value = g_Reg->DPC_CLOCK_REG; return true;
case 0x04100014: value = g_Reg->DPC_BUFBUSY_REG; return true;
case 0x04100018: value = g_Reg->DPC_PIPEBUSY_REG; return true;
case 0x0410001C: value = g_Reg->DPC_TMEM_REG; return true;
case 0x04300000: value = g_Reg->MI_MODE_REG; return true;
case 0x04300004: value = g_Reg->MI_VERSION_REG; return true;
case 0x04300008: value = g_Reg->MI_INTR_REG; return true;
case 0x0430000C: value = g_Reg->MI_INTR_MASK_REG; return true;
case 0x04400000: value = g_Reg->VI_STATUS_REG; return true;
case 0x04400004: value = g_Reg->VI_ORIGIN_REG; return true;
case 0x04400008: value = g_Reg->VI_WIDTH_REG; return true;
case 0x0440000C: value = g_Reg->VI_INTR_REG; return true;
case 0x04400010: value = g_Reg->VI_V_CURRENT_LINE_REG; return true;
case 0x04400014: value = g_Reg->VI_BURST_REG; return true;
case 0x04400018: value = g_Reg->VI_V_SYNC_REG; return true;
case 0x0440001C: value = g_Reg->VI_H_SYNC_REG; return true;
case 0x04400020: value = g_Reg->VI_LEAP_REG; return true;
case 0x04400024: value = g_Reg->VI_H_START_REG; return true;
case 0x04400028: value = g_Reg->VI_V_START_REG; return true;
case 0x0440002C: value = g_Reg->VI_V_BURST_REG; return true;
case 0x04400030: value = g_Reg->VI_X_SCALE_REG; return true;
case 0x04400034: value = g_Reg->VI_Y_SCALE_REG; return true;
case 0x04600000: value = g_Reg->PI_DRAM_ADDR_REG; return true;
case 0x04600004: value = g_Reg->PI_CART_ADDR_REG; return true;
case 0x04600008: value = g_Reg->PI_RD_LEN_REG; return true;
case 0x0460000C: value = g_Reg->PI_WR_LEN_REG; return true;
case 0x04600010: value = g_Reg->PI_STATUS_REG; return true;
case 0x04600014: value = g_Reg->PI_DOMAIN1_REG; return true;
case 0x04600018: value = g_Reg->PI_BSD_DOM1_PWD_REG; return true;
case 0x0460001C: value = g_Reg->PI_BSD_DOM1_PGS_REG; return true;
case 0x04600020: value = g_Reg->PI_BSD_DOM1_RLS_REG; return true;
case 0x04600024: value = g_Reg->PI_DOMAIN2_REG; return true;
case 0x04600028: value = g_Reg->PI_BSD_DOM2_PWD_REG; return true;
case 0x0460002C: value = g_Reg->PI_BSD_DOM2_PGS_REG; return true;
case 0x04600030: value = g_Reg->PI_BSD_DOM2_RLS_REG; return true;
case 0x04700000: value = g_Reg->RI_MODE_REG; return true;
case 0x04700004: value = g_Reg->RI_CONFIG_REG; return true;
case 0x04700008: value = g_Reg->RI_CURRENT_LOAD_REG; return true;
case 0x0470000C: value = g_Reg->RI_SELECT_REG; return true;
case 0x04700010: value = g_Reg->RI_REFRESH_REG; return true;
case 0x04700014: value = g_Reg->RI_LATENCY_REG; return true;
case 0x04700018: value = g_Reg->RI_RERROR_REG; return true;
case 0x0470001C: value = g_Reg->RI_WERROR_REG; return true;
case 0x04800018: value = g_Reg->SI_STATUS_REG; return true;
case 0x05000500: value = g_Reg->ASIC_DATA; return true;
case 0x05000504: value = g_Reg->ASIC_MISC_REG; return true;
case 0x05000508: value = g_Reg->ASIC_STATUS; return true;
case 0x0500050C: value = g_Reg->ASIC_CUR_TK; return true;
case 0x05000510: value = g_Reg->ASIC_BM_STATUS; return true;
case 0x05000514: value = g_Reg->ASIC_ERR_SECTOR; return true;
case 0x05000518: value = g_Reg->ASIC_SEQ_STATUS; return true;
case 0x0500051C: value = g_Reg->ASIC_CUR_SECTOR; return true;
case 0x05000520: value = g_Reg->ASIC_HARD_RESET; return true;
case 0x05000524: value = g_Reg->ASIC_C1_S0; return true;
case 0x05000528: value = g_Reg->ASIC_HOST_SECBYTE; return true;
case 0x0500052C: value = g_Reg->ASIC_C1_S2; return true;
case 0x05000530: value = g_Reg->ASIC_SEC_BYTE; return true;
case 0x05000534: value = g_Reg->ASIC_C1_S4; return true;
case 0x05000538: value = g_Reg->ASIC_C1_S6; return true;
case 0x0500053C: value = g_Reg->ASIC_CUR_ADDR; return true;
case 0x05000540: value = g_Reg->ASIC_ID_REG; return true;
case 0x05000544: value = g_Reg->ASIC_TEST_REG; return true;
case 0x05000548: value = g_Reg->ASIC_TEST_PIN_SEL; return true;
case 0x04500004:
if (g_System->bFixedAudio())
{
value = g_Audio->GetLength();
}
else
{
CAudioPlugin* audioPlg = g_Plugins->Audio();
value = (audioPlg->AiReadLength != NULL) ? audioPlg->AiReadLength() : 0;
}
return true;
case 0x0450000C:
value = g_System->bFixedAudio() ? g_Audio->GetStatus() : g_Reg->AI_STATUS_REG;
return true;
}
return false;
}
bool CDebuggerUI::DebugLW_VAddr(uint32_t vaddr, uint32_t& value)
{
if (vaddr <= 0x7FFFFFFF || vaddr >= 0xC0000000) // KUSEG, KSEG2 (TLB)
{
if (g_MMU == NULL)
{
return false;
}
return g_MMU->LW_VAddr(vaddr, value);
}
uint32_t paddr = vaddr & 0x1FFFFFFF;
return DebugLW_PAddr(paddr, value);
}
// CDebugger implementation
void CDebuggerUI::TLBChanged()
{
Debug_RefreshTLBWindow();
}
// Called from the interpreter core at the beginning of every CPU step
void CDebuggerUI::CPUStepStarted()
{
uint32_t PROGRAM_COUNTER = g_Reg->m_PROGRAM_COUNTER;
uint32_t JumpToLocation = R4300iOp::m_JumpToLocation;
m_ScriptSystem->HookCPUExec()->InvokeByParamInRange(PROGRAM_COUNTER);
m_ScriptSystem->HookCPUExecOpcode()->InvokeByParamInRangeWithMaskedValue(PROGRAM_COUNTER, R4300iOp::m_Opcode.Hex);
// Memory breakpoints
COpInfo opInfo(R4300iOp::m_Opcode);
if (opInfo.IsLoadStoreCommand()) // Read and write instructions
{
uint32_t memoryAddress = opInfo.GetLoadStoreAddress();
if (opInfo.IsLoadCommand()) // Read instructions
{
m_ScriptSystem->HookCPURead()->InvokeByParamInRange(memoryAddress);
}
else // Write instructions
{
m_ScriptSystem->HookCPUWrite()->InvokeByParamInRange(memoryAddress);
// Catch cart -> rdram dma
if (memoryAddress == 0xA460000C) // PI_WR_LEN_REG
{
uint32_t dmaRomAddr = g_Reg->PI_CART_ADDR_REG & 0x0FFFFFFF;
uint32_t dmaRamAddr = g_Reg->PI_DRAM_ADDR_REG | 0x80000000;
uint32_t dmaLen = opInfo.GetStoreValueUnsigned() + 1;
m_DMALog->AddEntry(dmaRomAddr, dmaRamAddr, dmaLen);
if (m_Breakpoints->WriteBPExistsInChunk(dmaRamAddr, dmaLen))
{
goto breakpoint_hit;
}
}
if (m_Breakpoints->MemLockExists(memoryAddress, opInfo.NumBytesToStore()))
{
g_Settings->SaveBool(Debugger_SkipOp, true);
}
}
}
if (!isStepping())
{
return;
}
if (R4300iOp::m_NextInstruction != JUMP)
{
goto breakpoint_hit;
}
if (JumpToLocation == PROGRAM_COUNTER + 4)
{
// Only pause on delay slots when branch isn't taken
goto breakpoint_hit;
}
return;
breakpoint_hit:
g_Settings->SaveBool(Debugger_SteppingOps, true);
}
void CDebuggerUI::CPUStep()
{
OPCODE Opcode = R4300iOp::m_Opcode;
uint32_t op = Opcode.op;
uint32_t funct = Opcode.funct;
if (m_StackTrace == NULL)
{
m_StackTrace = new CDebugStackTrace(this);
}
if (op == R4300i_JAL || ((op == R4300i_SPECIAL) && (funct == R4300i_SPECIAL_JALR) && (Opcode.rd == 31))) // JAL or JALR RA, x
{
m_StackTrace->PushEntry(R4300iOp::m_JumpToLocation, g_Reg->m_PROGRAM_COUNTER);
}
else if (funct == R4300i_SPECIAL_JR && Opcode.rs == 31) // JR RA
{
m_StackTrace->PopEntry();
}
else if (op == R4300i_CP0 && funct == R4300i_COP0_CO_ERET) // TODO may need more work
{
m_StackTrace->ClearEntries();
}
}
void CDebuggerUI::FrameDrawn()
{
static HWND hMainWnd = NULL;
static HFONT monoFont = CreateFont(-11, 0, 0, 0,
FW_DONTCARE, FALSE, FALSE, FALSE, DEFAULT_CHARSET,
OUT_TT_PRECIS, CLIP_DEFAULT_PRECIS,
PROOF_QUALITY, FF_DONTCARE, "Consolas"
);
if (hMainWnd == NULL)
{
RenderWindow* mainWindow = g_Plugins->MainWindow();
if (mainWindow == NULL)
{
return;
}
hMainWnd = (HWND)mainWindow->GetWindowHandle();
}
HDC hdc = GetDC(hMainWnd);
CRect rt;
GetClientRect(hMainWnd, &rt);
SetBkColor(hdc, RGB(0, 0, 0));
SelectObject(hdc, monoFont);
SetTextColor(hdc, RGB(255, 255, 255));
SetBkColor(hdc, RGB(0, 0, 0));
m_ScriptSystem->SetScreenDC(hdc);
m_ScriptSystem->HookFrameDrawn()->InvokeAll();
ReleaseDC(hMainWnd, hdc);
}
void CDebuggerUI::WaitForStep(void)
{
g_Settings->SaveBool(Debugger_WaitingForStep, true);
m_StepEvent.IsTriggered(SyncEvent::INFINITE_TIMEOUT);
g_Settings->SaveBool(Debugger_WaitingForStep, false);
}
bool CDebuggerUI::ExecutionBP(uint32_t address)
{
return m_Breakpoints != NULL && m_Breakpoints->ExecutionBPExists(address, true) != CBreakpoints::BP_NOT_SET;
}
bool CDebuggerUI::ReadBP8(uint32_t address)
{
return m_Breakpoints != NULL && m_Breakpoints->ReadBPExists8(address) != CBreakpoints::BP_NOT_SET;
}
bool CDebuggerUI::ReadBP16(uint32_t address)
{
return m_Breakpoints != NULL && m_Breakpoints->ReadBPExists16(address) != CBreakpoints::BP_NOT_SET;
}
bool CDebuggerUI::ReadBP32(uint32_t address)
{
return m_Breakpoints != NULL && m_Breakpoints->ReadBPExists32(address) != CBreakpoints::BP_NOT_SET;
}
bool CDebuggerUI::ReadBP64(uint32_t address)
{
return m_Breakpoints != NULL && m_Breakpoints->ReadBPExists64(address) != CBreakpoints::BP_NOT_SET;
}
bool CDebuggerUI::WriteBP8(uint32_t address)
{
return m_Breakpoints != NULL && m_Breakpoints->WriteBPExists8(address) != CBreakpoints::BP_NOT_SET;
}
bool CDebuggerUI::WriteBP16(uint32_t address)
{
return m_Breakpoints != NULL && m_Breakpoints->WriteBPExists16(address) != CBreakpoints::BP_NOT_SET;
}
bool CDebuggerUI::WriteBP32(uint32_t address)
{
return m_Breakpoints != NULL && m_Breakpoints->WriteBPExists32(address) != CBreakpoints::BP_NOT_SET;
}
bool CDebuggerUI::WriteBP64(uint32_t address)
{
return m_Breakpoints != NULL && m_Breakpoints->WriteBPExists64(address) != CBreakpoints::BP_NOT_SET;
}