piwalker/dolphin
1
0
Fork 0
mirror of https://github.com/dolphin-emu/dolphin.git synced 2025-07-29 00:59:44 -06:00
Code Issues Packages Projects Releases Wiki Activity

Remove unnecessary Src/ folders

Browse Source
This commit is contained in:
Jasper St. Pierre
2013-12-07 15:14:29 -05:00
parent 43e618682e
commit 34692ab826
1026 changed files with 37648 additions and 37646 deletions
Download Patch File Download Diff File Expand all files Collapse all files

578
Source/Core/Core/HW/Memmap.cpp Normal file
View File

@ -0,0 +1,578 @@
// Copyright 2013 Dolphin Emulator Project
// Licensed under GPLv2
// Refer to the license.txt file included.
// NOTE:
// These functions are primarily used by the interpreter versions of the LoadStore instructions.
// However, if a JITed instruction (for example lwz) wants to access a bad memory area that call
// may be redirected here (for example to Read_U32()).
#include "Common.h"
#include "MemoryUtil.h"
#include "MemArena.h"
#include "ChunkFile.h"
#include "Memmap.h"
#include "../Core.h"
#include "../PowerPC/PowerPC.h"
#include "../PowerPC/JitCommon/JitBase.h"
#include "../HLE/HLE.h"
#include "CPU.h"
#include "ProcessorInterface.h"
#include "DSP.h"
#include "DVDInterface.h"
#include "GPFifo.h"
#include "VideoInterface.h"
#include "SI.h"
#include "EXI.h"
#include "AudioInterface.h"
#include "MemoryInterface.h"
#include "WII_IOB.h"
#include "WII_IPC.h"
#include "../ConfigManager.h"
#include "../Debugger/Debugger_SymbolMap.h"
#include "VideoBackendBase.h"
namespace Memory
{
// =================================
// LOCAL SETTINGS
// ----------------
/* Enable the Translation Lookaside Buffer functions. TLBHack = 1 in Dolphin.ini or a
<GameID>.ini file will set this to true */
bool bFakeVMEM = false;
bool bMMU = false;
// ==============
// =================================
// Init() declarations
// ----------------
// Store the MemArena here
u8* base = NULL;
// The MemArena class
MemArena g_arena;
// ==============
// STATE_TO_SAVE
bool m_IsInitialized = false; // Save the Init(), Shutdown() state
// END STATE_TO_SAVE
// 64-bit: Pointers to low-mem (sub-0x10000000) mirror
// 32-bit: Same as the corresponding physical/virtual pointers.
u8 *m_pRAM;
u8 *m_pL1Cache;
u8 *m_pEXRAM;
u8 *m_pFakeVMEM;
//u8 *m_pEFB;
// 64-bit: Pointers to high-mem mirrors
// 32-bit: Same as above
u8 *m_pPhysicalRAM;
u8 *m_pVirtualCachedRAM;
u8 *m_pVirtualUncachedRAM;
u8 *m_pPhysicalEXRAM; // wii only
u8 *m_pVirtualCachedEXRAM; // wii only
u8 *m_pVirtualUncachedEXRAM; // wii only
//u8 *m_pVirtualEFB;
u8 *m_pVirtualL1Cache;
u8 *m_pVirtualFakeVMEM;
// =================================
// Read and write shortcuts
// ----------------
writeFn8 hwWrite8 [NUMHWMEMFUN];
writeFn16 hwWrite16[NUMHWMEMFUN];
writeFn32 hwWrite32[NUMHWMEMFUN];
writeFn64 hwWrite64[NUMHWMEMFUN];
readFn8 hwRead8 [NUMHWMEMFUN];
readFn16 hwRead16[NUMHWMEMFUN];
readFn32 hwRead32[NUMHWMEMFUN];
readFn64 hwRead64[NUMHWMEMFUN];
writeFn8 hwWriteWii8 [NUMHWMEMFUN];
writeFn16 hwWriteWii16[NUMHWMEMFUN];
writeFn32 hwWriteWii32[NUMHWMEMFUN];
writeFn64 hwWriteWii64[NUMHWMEMFUN];
readFn8 hwReadWii8 [NUMHWMEMFUN];
readFn16 hwReadWii16[NUMHWMEMFUN];
readFn32 hwReadWii32[NUMHWMEMFUN];
readFn64 hwReadWii64[NUMHWMEMFUN];
// Default read and write functions
template <class T>
void HW_Default_Write(const T _Data, const u32 _Address){ ERROR_LOG(MASTER_LOG, "Illegal HW Write%lu %08x", (unsigned long)sizeof(T)*8, _Address);_dbg_assert_(MEMMAP, 0);}
template <class T>
void HW_Default_Read(T _Data, const u32 _Address){ ERROR_LOG(MASTER_LOG, "Illegal HW Read%lu %08x", (unsigned long)sizeof(T)*8, _Address); _dbg_assert_(MEMMAP, 0);}
#define HW_PAGE_SHIFT 10
#define HW_PAGE_SIZE (1 << HW_PAGE_SHIFT)
#define HW_PAGE_MASK (HW_PAGE_SHIFT - 1)
template <class T, u8 *P> void HW_Read_Memory(T &_Data, const u32 _Address)
{
_Data = *(T *)&P[_Address & HW_PAGE_MASK];
}
template <class T, u8 *P> void HW_Write_Memory(T _Data, const u32 _Address)
{
*(T *)&P[_Address & HW_PAGE_MASK] = _Data;
}
// Create shortcuts to the hardware devices' read and write functions.
// This can be seen as an alternative to a switch() or if() table.
#define BLOCKSIZE 4
#define CP_START 0x00 //0x0000 >> 10
#define WII_IPC_START 0x00 //0x0000 >> 10
#define PE_START 0x04 //0x1000 >> 10
#define VI_START 0x08 //0x2000 >> 10
#define PI_START 0x0C //0x3000 >> 10
#define MI_START 0x10 //0x4000 >> 10
#define DSP_START 0x14 //0x5000 >> 10
#define DVD_START 0x18 //0x6000 >> 10
#define SI_START 0x19 //0x6400 >> 10
#define EI_START 0x1A //0x6800 >> 10
#define AUDIO_START 0x1B //0x6C00 >> 10
#define GP_START 0x20 //0x8000 >> 10
void InitHWMemFuncs()
{
for (int i = 0; i < NUMHWMEMFUN; i++)
{
hwWrite8 [i] = HW_Default_Write<u8>;
hwWrite16[i] = HW_Default_Write<u16>;
hwWrite32[i] = HW_Default_Write<u32>;
hwWrite64[i] = HW_Default_Write<u64>;
hwRead8 [i] = HW_Default_Read<u8&>;
hwRead16 [i] = HW_Default_Read<u16&>;
hwRead32 [i] = HW_Default_Read<u32&>;
hwRead64 [i] = HW_Default_Read<u64&>;
// To prevent Dolphin from crashing when accidentally running Wii
// executables in GC mode (or running malicious GC executables...)
hwWriteWii8 [i] = HW_Default_Write<u8>;
hwWriteWii16[i] = HW_Default_Write<u16>;
hwWriteWii32[i] = HW_Default_Write<u32>;
hwWriteWii64[i] = HW_Default_Write<u64>;
hwReadWii8 [i] = HW_Default_Read<u8&>;
hwReadWii16 [i] = HW_Default_Read<u16&>;
hwReadWii32 [i] = HW_Default_Read<u32&>;
hwReadWii64 [i] = HW_Default_Read<u64&>;
}
for (int i = 0; i < BLOCKSIZE; i++)
{
hwRead16 [CP_START+i] = g_video_backend->Video_CPRead16();
hwWrite16[CP_START+i] = g_video_backend->Video_CPWrite16();
hwRead16 [PE_START+i] = g_video_backend->Video_PERead16();
hwWrite16[PE_START+i] = g_video_backend->Video_PEWrite16();
hwWrite32[PE_START+i] = g_video_backend->Video_PEWrite32();
hwRead8 [VI_START+i] = VideoInterface::Read8;
hwRead16 [VI_START+i] = VideoInterface::Read16;
hwRead32 [VI_START+i] = VideoInterface::Read32;
hwWrite16[VI_START+i] = VideoInterface::Write16;
hwWrite32[VI_START+i] = VideoInterface::Write32;
hwRead16 [PI_START+i] = ProcessorInterface::Read16;
hwRead32 [PI_START+i] = ProcessorInterface::Read32;
hwWrite32[PI_START+i] = ProcessorInterface::Write32;
hwRead16 [MI_START+i] = MemoryInterface::Read16;
hwRead32 [MI_START+i] = MemoryInterface::Read32;
hwWrite32[MI_START+i] = MemoryInterface::Write32;
hwWrite16[MI_START+i] = MemoryInterface::Write16;
hwRead16 [DSP_START+i] = DSP::Read16;
hwWrite16[DSP_START+i] = DSP::Write16;
hwRead32 [DSP_START+i] = DSP::Read32;
hwWrite32[DSP_START+i] = DSP::Write32;
}
hwRead32 [DVD_START] = DVDInterface::Read32;
hwWrite32[DVD_START] = DVDInterface::Write32;
hwRead32 [SI_START] = SerialInterface::Read32;
hwWrite32[SI_START] = SerialInterface::Write32;
hwRead32 [EI_START] = ExpansionInterface::Read32;
hwWrite32[EI_START] = ExpansionInterface::Write32;
hwRead32 [AUDIO_START] = AudioInterface::Read32;
hwWrite32[AUDIO_START] = AudioInterface::Write32;
hwWrite8 [GP_START] = GPFifo::Write8;
hwWrite16[GP_START] = GPFifo::Write16;
hwWrite32[GP_START] = GPFifo::Write32;
hwWrite64[GP_START] = GPFifo::Write64;
}
void InitHWMemFuncsWii()
{
for (int i = 0; i < NUMHWMEMFUN; i++)
{
hwWrite8 [i] = HW_Default_Write<u8>;
hwWrite16[i] = HW_Default_Write<u16>;
hwWrite32[i] = HW_Default_Write<u32>;
hwWrite64[i] = HW_Default_Write<u64>;
hwRead8 [i] = HW_Default_Read<u8&>;
hwRead16 [i] = HW_Default_Read<u16&>;
hwRead32 [i] = HW_Default_Read<u32&>;
hwRead64 [i] = HW_Default_Read<u64&>;
hwWriteWii8 [i] = HW_Default_Write<u8>;
hwWriteWii16[i] = HW_Default_Write<u16>;
hwWriteWii32[i] = HW_Default_Write<u32>;
hwWriteWii64[i] = HW_Default_Write<u64>;
hwReadWii8 [i] = HW_Default_Read<u8&>;
hwReadWii16 [i] = HW_Default_Read<u16&>;
hwReadWii32 [i] = HW_Default_Read<u32&>;
hwReadWii64 [i] = HW_Default_Read<u64&>;
}
// MI, PI, DSP are still mapped to 0xCCxxxxxx
for (int i = 0; i < BLOCKSIZE; i++)
{
hwRead16 [CP_START+i] = g_video_backend->Video_CPRead16();
hwWrite16[CP_START+i] = g_video_backend->Video_CPWrite16();
hwRead16 [PE_START+i] = g_video_backend->Video_PERead16();
hwWrite16[PE_START+i] = g_video_backend->Video_PEWrite16();
hwWrite32[PE_START+i] = g_video_backend->Video_PEWrite32();
hwRead16 [PI_START+i] = ProcessorInterface::Read16;
hwRead32 [PI_START+i] = ProcessorInterface::Read32;
hwWrite32[PI_START+i] = ProcessorInterface::Write32;
hwRead8 [VI_START+i] = VideoInterface::Read8;
hwRead16 [VI_START+i] = VideoInterface::Read16;
hwRead32 [VI_START+i] = VideoInterface::Read32;
hwWrite16[VI_START+i] = VideoInterface::Write16;
hwWrite32[VI_START+i] = VideoInterface::Write32;
hwRead16 [MI_START+i] = MemoryInterface::Read16;
hwRead32 [MI_START+i] = MemoryInterface::Read32;
hwWrite32[MI_START+i] = MemoryInterface::Write32;
hwWrite16[MI_START+i] = MemoryInterface::Write16;
hwRead16 [DSP_START+i] = DSP::Read16;
hwWrite16[DSP_START+i] = DSP::Write16;
hwRead32 [DSP_START+i] = DSP::Read32;
hwWrite32[DSP_START+i] = DSP::Write32;
}
hwWrite8 [GP_START] = GPFifo::Write8;
hwWrite16[GP_START] = GPFifo::Write16;
hwWrite32[GP_START] = GPFifo::Write32;
hwWrite64[GP_START] = GPFifo::Write64;
for (int i = 0; i < BLOCKSIZE; i++)
{
hwReadWii32[WII_IPC_START+i] = WII_IPCInterface::Read32;
hwWriteWii32[WII_IPC_START+i] = WII_IPCInterface::Write32;
}
hwRead32 [DVD_START] = DVDInterface::Read32;
hwReadWii32 [DVD_START] = DVDInterface::Read32;
hwWrite32 [DVD_START] = DVDInterface::Write32;
hwWriteWii32[DVD_START] = DVDInterface::Write32;
hwRead32 [SI_START] = SerialInterface::Read32;
hwReadWii32 [SI_START] = SerialInterface::Read32;
hwWrite32 [SI_START] = SerialInterface::Write32;
hwWriteWii32[SI_START] = SerialInterface::Write32;
hwRead32 [EI_START] = ExpansionInterface::Read32;
hwReadWii32 [EI_START] = ExpansionInterface::Read32;
hwWrite32 [EI_START] = ExpansionInterface::Write32;
hwWriteWii32[EI_START] = ExpansionInterface::Write32;
// [F|RES] i thought this doesn't exist anymore
hwRead32 [AUDIO_START] = AudioInterface::Read32;
hwReadWii32 [AUDIO_START] = AudioInterface::Read32;
hwWrite32 [AUDIO_START] = AudioInterface::Write32;
hwWriteWii32[AUDIO_START] = AudioInterface::Write32;
}
writeFn32 GetHWWriteFun32(const u32 _Address)
{
return hwWrite32[(_Address >> HWSHIFT) & (NUMHWMEMFUN-1)];
}
bool IsInitialized()
{
return m_IsInitialized;
}
// We don't declare the IO region in here since its handled by other means.
static const MemoryView views[] =
{
{&m_pRAM, &m_pPhysicalRAM, 0x00000000, RAM_SIZE, 0},
{NULL, &m_pVirtualCachedRAM, 0x80000000, RAM_SIZE, MV_MIRROR_PREVIOUS},
{NULL, &m_pVirtualUncachedRAM, 0xC0000000, RAM_SIZE, MV_MIRROR_PREVIOUS},
// Don't map any memory for the EFB. We want all access to this area to go
// through the hardware access handlers.
#ifndef _M_X64
// {&m_pEFB, &m_pVirtualEFB, 0xC8000000, EFB_SIZE, 0},
#endif
{&m_pL1Cache, &m_pVirtualL1Cache, 0xE0000000, L1_CACHE_SIZE, 0},
{&m_pFakeVMEM, &m_pVirtualFakeVMEM, 0x7E000000, FAKEVMEM_SIZE, MV_FAKE_VMEM},
{&m_pEXRAM, &m_pPhysicalEXRAM, 0x10000000, EXRAM_SIZE, MV_WII_ONLY},
{NULL, &m_pVirtualCachedEXRAM, 0x90000000, EXRAM_SIZE, MV_WII_ONLY | MV_MIRROR_PREVIOUS},
{NULL, &m_pVirtualUncachedEXRAM, 0xD0000000, EXRAM_SIZE, MV_WII_ONLY | MV_MIRROR_PREVIOUS},
};
static const int num_views = sizeof(views) / sizeof(MemoryView);
void Init()
{
bool wii = SConfig::GetInstance().m_LocalCoreStartupParameter.bWii;
bFakeVMEM = SConfig::GetInstance().m_LocalCoreStartupParameter.bTLBHack == true;
bMMU = SConfig::GetInstance().m_LocalCoreStartupParameter.bMMU;
u32 flags = 0;
if (wii) flags |= MV_WII_ONLY;
if (bFakeVMEM) flags |= MV_FAKE_VMEM;
base = MemoryMap_Setup(views, num_views, flags, &g_arena);
if (wii)
InitHWMemFuncsWii();
else
InitHWMemFuncs();
INFO_LOG(MEMMAP, "Memory system initialized. RAM at %p (mirrors at 0 @ %p, 0x80000000 @ %p , 0xC0000000 @ %p)",
m_pRAM, m_pPhysicalRAM, m_pVirtualCachedRAM, m_pVirtualUncachedRAM);
m_IsInitialized = true;
}
void DoState(PointerWrap &p)
{
bool wii = SConfig::GetInstance().m_LocalCoreStartupParameter.bWii;
p.DoArray(m_pPhysicalRAM, RAM_SIZE);
// p.DoArray(m_pVirtualEFB, EFB_SIZE);
p.DoArray(m_pVirtualL1Cache, L1_CACHE_SIZE);
p.DoMarker("Memory RAM");
if (bFakeVMEM)
p.DoArray(m_pVirtualFakeVMEM, FAKEVMEM_SIZE);
p.DoMarker("Memory FakeVMEM");
if (wii)
p.DoArray(m_pEXRAM, EXRAM_SIZE);
p.DoMarker("Memory EXRAM");
}
void Shutdown()
{
m_IsInitialized = false;
u32 flags = 0;
if (SConfig::GetInstance().m_LocalCoreStartupParameter.bWii) flags |= MV_WII_ONLY;
if (bFakeVMEM) flags |= MV_FAKE_VMEM;
MemoryMap_Shutdown(views, num_views, flags, &g_arena);
g_arena.ReleaseSpace();
base = NULL;
INFO_LOG(MEMMAP, "Memory system shut down.");
}
void Clear()
{
if (m_pRAM)
memset(m_pRAM, 0, RAM_SIZE);
if (m_pL1Cache)
memset(m_pL1Cache, 0, L1_CACHE_SIZE);
if (SConfig::GetInstance().m_LocalCoreStartupParameter.bWii && m_pEXRAM)
memset(m_pEXRAM, 0, EXRAM_SIZE);
}
bool AreMemoryBreakpointsActivated()
{
#ifndef ENABLE_MEM_CHECK
return false;
#else
return true;
#endif
}
u32 Read_Instruction(const u32 em_address)
{
UGeckoInstruction inst = ReadUnchecked_U32(em_address);
return inst.hex;
}
void WriteBigEData(const u8 *_pData, const u32 _Address, const size_t _iSize)
{
memcpy(GetPointer(_Address), _pData, _iSize);
}
void Memset(const u32 _Address, const u8 _iValue, const u32 _iLength)
{
u8 *ptr = GetPointer(_Address);
if (ptr != NULL)
{
memset(ptr,_iValue,_iLength);
}
else
{
for (u32 i = 0; i < _iLength; i++)
Write_U8(_iValue, _Address + i);
}
}
void DMA_LCToMemory(const u32 _MemAddr, const u32 _CacheAddr, const u32 _iNumBlocks)
{
const u8 *src = GetCachePtr() + (_CacheAddr & 0x3FFFF);
u8 *dst = GetPointer(_MemAddr);
if ((dst != NULL) && (src != NULL) && (_MemAddr & 3) == 0 && (_CacheAddr & 3) == 0)
{
memcpy(dst, src, 32 * _iNumBlocks);
}
else
{
for (u32 i = 0; i < 32 * _iNumBlocks; i++)
{
u8 Temp = Read_U8(_CacheAddr + i);
Write_U8(Temp, _MemAddr + i);
}
}
}
void DMA_MemoryToLC(const u32 _CacheAddr, const u32 _MemAddr, const u32 _iNumBlocks)
{
const u8 *src = GetPointer(_MemAddr);
u8 *dst = GetCachePtr() + (_CacheAddr & 0x3FFFF);
if ((dst != NULL) && (src != NULL) && (_MemAddr & 3) == 0 && (_CacheAddr & 3) == 0)
{
memcpy(dst, src, 32 * _iNumBlocks);
}
else
{
for (u32 i = 0; i < 32 * _iNumBlocks; i++)
{
u8 Temp = Read_U8(_MemAddr + i);
Write_U8(Temp, _CacheAddr + i);
}
}
}
void ReadBigEData(u8 *data, const u32 em_address, const u32 size)
{
u8 *src = GetPointer(em_address);
memcpy(data, src, size);
}
void GetString(std::string& _string, const u32 em_address)
{
char stringBuffer[2048];
char *string = stringBuffer;
char c;
u32 addr = em_address;
while ((c = Read_U8(addr)))
{
*string++ = c;
addr++;
}
*string++ = '\0';
_string = stringBuffer;
}
// GetPointer must always return an address in the bottom 32 bits of address space, so that 64-bit
// programs don't have problems directly addressing any part of memory.
// TODO re-think with respect to other BAT setups...
u8 *GetPointer(const u32 _Address)
{
switch (_Address >> 28)
{
case 0x0:
case 0x8:
if ((_Address & 0xfffffff) < REALRAM_SIZE)
return m_pPhysicalRAM + (_Address & RAM_MASK);
case 0xc:
switch (_Address >> 24)
{
case 0xcc:
case 0xcd:
_dbg_assert_msg_(MEMMAP, 0, "GetPointer from IO Bridge doesnt work");
case 0xc8:
// EFB. We don't want to return a pointer here since we have no memory mapped for it.
break;
default:
if ((_Address & 0xfffffff) < REALRAM_SIZE)
return m_pPhysicalRAM + (_Address & RAM_MASK);
}
case 0x1:
case 0x9:
case 0xd:
if (SConfig::GetInstance().m_LocalCoreStartupParameter.bWii)
{
if ((_Address & 0xfffffff) < EXRAM_SIZE)
return m_pPhysicalEXRAM + (_Address & EXRAM_MASK);
}
else
break;
case 0xe:
if (_Address < (0xE0000000 + L1_CACHE_SIZE))
return GetCachePtr() + (_Address & L1_CACHE_MASK);
else
break;
default:
if (bFakeVMEM)
return m_pVirtualFakeVMEM + (_Address & FAKEVMEM_MASK);
}
ERROR_LOG(MEMMAP, "Unknown Pointer %#8x PC %#8x LR %#8x", _Address, PC, LR);
return NULL;
}
bool IsRAMAddress(const u32 addr, bool allow_locked_cache, bool allow_fake_vmem)
{
switch ((addr >> 24) & 0xFC)
{
case 0x00:
case 0x80:
case 0xC0:
if ((addr & 0x1FFFFFFF) < RAM_SIZE)
return true;
else
return false;
case 0x10:
case 0x90:
case 0xD0:
if (SConfig::GetInstance().m_LocalCoreStartupParameter.bWii && (addr & 0x0FFFFFFF) < EXRAM_SIZE)
return true;
else
return false;
case 0xE0:
if (allow_locked_cache && addr - 0xE0000000 < L1_CACHE_SIZE)
return true;
else
return false;
case 0x7C:
if (allow_fake_vmem && bFakeVMEM && addr >= 0x7E000000)
return true;
else
return false;
default:
return false;
}
}
} // namespace