Supermodel/Src/Debugger/CPU/Turbo68KDebug.cpp
Nik Henson e8e02ba685 Changes to debugger classes:
- updated debugger classes to compile again with all recent changes.
- improved debugger classes to allow them to work in multi-threaded emulator and be able to handle CPUs on different threads.
- added debug classes for new Z80 and Musashi 68K CPU cores.
- added logging of cycle counts and frames.
- moved all Supermodel specific code & configuration to CSupermodelDebugger.
- added all Model 3 CPUs (PPC, sound board 68K, DSB 68K/Z80 and drive board Z80) to CSupermodelDebugger.
- added persisting of custom entry points in saved debug state to CCodeAnalyser.
- fixed bug with listing I/O ports in CConsoleDebugger and added displaying of cycle counts and CPU speeds when listing CPUs.
2011-09-18 21:59:23 +00:00

258 lines
7.1 KiB
C++

#ifdef SUPERMODEL_DEBUGGER
#include "Turbo68KDebug.h"
#include <string.h>
#include <ctype.h>
namespace Debugger
{
UINT32 GetSpecialReg(CCPUDebug *cpu, unsigned id)
{
switch (id)
{
case TBO68K_REG_SP: return (UINT32)turbo68kcontext_68000.a[7];
case TBO68K_REG_SR: return (UINT32)turbo68kcontext_68000.sr;
default: return 0;
}
}
bool SetSpecialReg(CCPUDebug *cpu, unsigned id, UINT32 data)
{
switch (id)
{
case TBO68K_REG_SP: turbo68kcontext_68000.a[7] = data; return true;
case TBO68K_REG_SR: turbo68kcontext_68000.sr = data; return true;
default: return false;
}
}
UINT32 GetDataReg(CCPUDebug *cpu, unsigned id)
{
return (UINT32)turbo68kcontext_68000.d[id];
}
bool SetDataReg(CCPUDebug *cpu, unsigned id, UINT32 data)
{
turbo68kcontext_68000.d[id] = data;
return true;
}
UINT32 GetAddressReg(CCPUDebug *cpu, unsigned id)
{
return (UINT32)turbo68kcontext_68000.a[id];
}
bool SetAddressReg(CCPUDebug *cpu, unsigned id, UINT32 data)
{
turbo68kcontext_68000.a[id] = data;
return true;
}
static const char *srGroup = "Special Registers";
static const char *drGroup = "Data Registers";
static const char *arGroup = "Address Regsters";
CTurbo68KDebug::CTurbo68KDebug(const char *name) : C68KDebug(name), m_resetAddr(0)
{
// Special registers
AddPCRegister ("PC", srGroup);
AddAddrRegister ("SP", srGroup, TBO68K_REG_SP, GetSpecialReg, SetSpecialReg);
AddStatus32Register("SR", srGroup, TBO68K_REG_SR, "TtSM.210...XNZVC", GetSpecialReg, SetSpecialReg);
// Data registers
for (unsigned id = 0; id < 8; id++)
{
sprintf(m_drNames[id], "D%u", id);
AddInt32Register(m_drNames[id], drGroup, id, GetDataReg, SetDataReg);
}
// Address registers
for (unsigned id = 0; id < 8; id++)
{
sprintf(m_arNames[id], "A%u", id);
AddInt32Register(m_arNames[id], arGroup, id, GetAddressReg, SetAddressReg);
}
}
CTurbo68KDebug::~CTurbo68KDebug()
{
DetachFromCPU();
}
bool __cdecl DebugHandler(TURBO68K_INT32 pc, TURBO68K_INT32 opcode)
{
// Return true to let Turbo68K know if PC was changed by user
return debug->CPUExecute((UINT32)pc, (UINT32)opcode, 1); // TODO - lastCycles
}
void __cdecl InterruptHandler(TURBO68K_UINT32 intVec)
{
// TODO - is following correct handling of interrupts? - need to check readme file
if (intVec > 47)
return;
else if (intVec >= 25 || intVec < 32)
{
debug->CPUException(25);
debug->CPUInterrupt((UINT16)intVec - 25);
}
else
debug->CPUException((UINT16)intVec);
if (origIntAckPtr != NULL)
origIntAckPtr(intVec);
}
void CTurbo68KDebug::AttachToCPU()
{
if (debug != NULL)
DetachFromCPU();
debug = this;
origDebugPtr = (DebugPtr)turbo68kcontext_68000.Debug;
origIntAckPtr = (IntAckPtr)turbo68kcontext_68000.InterruptAcknowledge;
origRead8Regions = (TURBO68K_DATAREGION*)Turbo68KGetReadByte(TURBO68K_NULL);
origRead16Regions = (TURBO68K_DATAREGION*)Turbo68KGetReadWord(TURBO68K_NULL);
origRead32Regions = (TURBO68K_DATAREGION*)Turbo68KGetReadLong(TURBO68K_NULL);
origWrite8Regions = (TURBO68K_DATAREGION*)Turbo68KGetWriteByte(TURBO68K_NULL);
origWrite16Regions = (TURBO68K_DATAREGION*)Turbo68KGetWriteWord(TURBO68K_NULL);
origWrite32Regions = (TURBO68K_DATAREGION*)Turbo68KGetWriteLong(TURBO68K_NULL);
turbo68kcontext_68000.Debug = DebugHandler;
turbo68kcontext_68000.InterruptAcknowledge = InterruptHandler;
debugRead8Regions[0].handler = ReadByteDebug;
debugRead16Regions[0].handler = ReadWordDebug;
debugRead32Regions[0].handler = ReadLongDebug;
debugWrite8Regions[0].handler = WriteByteDebug;
debugWrite16Regions[0].handler = WriteWordDebug;
debugWrite32Regions[0].handler = WriteLongDebug;
Turbo68KSetReadByte(debugRead8Regions, TURBO68K_NULL);
Turbo68KSetReadWord(debugRead16Regions, TURBO68K_NULL);
Turbo68KSetReadLong(debugRead32Regions, TURBO68K_NULL);
Turbo68KSetWriteByte(debugWrite8Regions, TURBO68K_NULL);
Turbo68KSetWriteWord(debugWrite16Regions, TURBO68K_NULL);
Turbo68KSetWriteLong(debugWrite32Regions, TURBO68K_NULL);
// Reset address is held at 0x000004
m_resetAddr = ReadLongDirect(0x000004);
}
void CTurbo68KDebug::DetachFromCPU()
{
if (debug == NULL)
return;
turbo68kcontext_68000.Debug = origDebugPtr;
turbo68kcontext_68000.InterruptAcknowledge = origIntAckPtr;
Turbo68KSetReadByte(origRead8Regions, TURBO68K_NULL);
Turbo68KSetReadWord(origRead16Regions, TURBO68K_NULL);
Turbo68KSetReadLong(origRead32Regions, TURBO68K_NULL);
Turbo68KSetWriteByte(origWrite8Regions, TURBO68K_NULL);
Turbo68KSetWriteWord(origWrite16Regions, TURBO68K_NULL);
Turbo68KSetWriteLong(origWrite32Regions, TURBO68K_NULL);
debug = NULL;
}
UINT32 CTurbo68KDebug::GetResetAddr()
{
return m_resetAddr;
}
UINT32 CTurbo68KDebug::GetSP()
{
return (UINT32)turbo68kcontext_68000.a[7];
}
bool CTurbo68KDebug::UpdatePC(UINT32 newPC)
{
turbo68kcontext_68000.pc = newPC;
return true;
}
bool CTurbo68KDebug::ForceException(CException *ex)
{
//switch (ex->code)
//{
// TODO
//}
return false;
}
bool CTurbo68KDebug::ForceInterrupt(CInterrupt *in)
{
if (in->code > 6)
return false;
//Turbo68KInterrupt(in->code, TURBO64K_AUTOVECTOR);
//Turbo68KProcessInterrupts(); TODO - call this?
return false; // TODO
}
UINT64 CTurbo68KDebug::ReadMem(UINT32 addr, unsigned dataSize)
{
switch (dataSize)
{
case 1: return ReadByteDirect(addr);
case 2: return ReadWordDirect(addr);
case 4: return ReadLongDirect(addr);
default: return CCPUDebug::ReadMem(addr, dataSize);
}
}
bool CTurbo68KDebug::WriteMem(UINT32 addr, unsigned dataSize, UINT64 data)
{
switch (dataSize)
{
case 1: WriteByteDirect(addr, (TURBO68K_UINT8)data); return true;
case 2: WriteWordDirect(addr, (TURBO68K_UINT16)data); return true;
case 4: WriteLongDirect(addr, (TURBO68K_UINT32)data); return true;
default: return CCPUDebug::WriteMem(addr, dataSize, data);
}
}
TURBO68K_UINT8 __cdecl ReadByteDebug(TURBO68K_UINT32 addr)
{
TURBO68K_UINT8 data = ReadByteDirect(addr);
debug->CheckRead8((UINT32)addr, (UINT8)data);
return data;
}
TURBO68K_UINT16 __cdecl ReadWordDebug(TURBO68K_UINT32 addr)
{
TURBO68K_UINT16 data = ReadWordDirect(addr);
debug->CheckRead16((UINT32)addr, (UINT16)data);
return data;
}
TURBO68K_UINT32 __cdecl ReadLongDebug(TURBO68K_UINT32 addr)
{
TURBO68K_UINT32 data = ReadLongDirect(addr);
debug->CheckRead32((UINT32)addr, (UINT32)data);
return data;
}
void __cdecl WriteByteDebug(TURBO68K_UINT32 addr, TURBO68K_UINT8 data)
{
WriteByteDirect(addr, data);
debug->CheckWrite8((UINT32)addr, (UINT8)data);
}
void __cdecl WriteWordDebug(TURBO68K_UINT32 addr, TURBO68K_UINT16 data)
{
WriteWordDirect(addr, data);
debug->CheckWrite16((UINT32)addr, (UINT16)data);
}
void __cdecl WriteLongDebug(TURBO68K_UINT32 addr, TURBO68K_UINT32 data)
{
WriteLongDirect(addr, data);
debug->CheckWrite32((UINT32)addr, (UINT32)data);
}
}
#endif // SUPERMODEL_DEBUGGER