// Copyright (C) 2003 Dolphin Project / 2012 PPSSPP Project. // This program 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, version 2.0 or later versions. // This program 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 2.0 for more details. // A copy of the GPL 2.0 should have been included with the program. // If not, see http://www.gnu.org/licenses/ // Official SVN repository and contact information can be found at // http://code.google.com/p/dolphin-emu/ #ifndef _MEMMAP_H #define _MEMMAP_H // Includes #include #include "Common.h" #include "CommonTypes.h" // Enable memory checks in the Debug/DebugFast builds, but NOT in release #if defined(_DEBUG) || defined(DEBUGFAST) #define ENABLE_MEM_CHECK #endif // PPSSPP is very aggressive about trying to do memory accesses directly, for speed. // This can be a problem when debugging though, as stray memory reads and writes will // crash the whole emulator. // If safe memory is enabled and JIT is disabled, all memory access will go through the proper // memory access functions, and thus won't crash the emu when they go out of bounds. #if defined(_DEBUG) //#define SAFE_MEMORY #endif // Required for UNUSABLE_MMAP. Can define this in cmake instead later #ifdef __SYMBIAN32__ #define SAFE_MEMORY #endif // Global declarations class PointerWrap; typedef void (*writeFn8 )(const u8, const u32); typedef void (*writeFn16)(const u16,const u32); typedef void (*writeFn32)(const u32,const u32); typedef void (*writeFn64)(const u64,const u32); typedef void (*readFn8 )(u8&, const u32); typedef void (*readFn16)(u16&, const u32); typedef void (*readFn32)(u32&, const u32); typedef void (*readFn64)(u64&, const u32); inline u32 PSP_GetKernelMemoryBase() { return 0x08000000;} inline u32 PSP_GetKernelMemoryEnd() { return 0x08400000;} // "Volatile" RAM is between 0x08400000 and 0x08800000, can be requested by the // game through sceKernelVolatileMemTryLock. inline u32 PSP_GetUserMemoryBase() { return 0x08800000;} inline u32 PSP_GetUserMemoryEnd() { return 0x0A000000;} inline u32 PSP_GetDefaultLoadAddress() { return 0x08800000;} //inline u32 PSP_GetDefaultLoadAddress() { return 0x0898dab0;} inline u32 PSP_GetVidMemBase() { return 0x04000000;} namespace Memory { // Base is a pointer to the base of the memory map. Yes, some MMU tricks // are used to set up a full GC or Wii memory map in process memory. on // 32-bit, you have to mask your offsets with 0x3FFFFFFF. This means that // some things are mirrored too many times, but eh... it works. // In 64-bit, this might point to "high memory" (above the 32-bit limit), // so be sure to load it into a 64-bit register. extern u8 *base; // These are guaranteed to point to "low memory" addresses (sub-32-bit). // 64-bit: Pointers to low-mem (sub-0x10000000) mirror // 32-bit: Same as the corresponding physical/virtual pointers. extern u8 *m_pRAM; extern u8 *m_pScratchPad; extern u8 *m_pVRAM; // 64-bit: Pointers to high-mem mirrors // 32-bit: Same as above extern u8 *m_pPhysicalRAM; extern u8 *m_pUncachedRAM; extern u8 *m_pPhysicalVRAM; extern u8 *m_pUncachedVRAM; // TODO: Later PSP models got more RAM. enum { RAM_SIZE = 0x2000000, // 32 MB - although only the upper 24 are available for the user. RAM_MASK = RAM_SIZE - 1, VRAM_SIZE = 0x200000, VRAM_MASK = VRAM_SIZE - 1, SCRATCHPAD_SIZE = 0x4000, SCRATCHPAD_MASK = SCRATCHPAD_SIZE - 1, #if defined(_M_IX86) || defined(_M_ARM32) // This wraparound should work for PSP too. MEMVIEW32_MASK = 0x3FFFFFFF, #endif }; // Init and Shutdown void Init(); void Shutdown(); void DoState(PointerWrap &p); void Clear(); bool AreMemoryBreakpointsActivated(); inline u8* GetMainRAMPtr() {return m_pRAM;} // used by interpreter to read instructions, uses iCache u32 Read_Opcode(const u32 _Address); // used by JIT to read instructions u32 Read_Opcode_JIT(const u32 _Address); // used by JIT. uses iCacheJIT. Reads in the "Locked cache" mode void Write_Opcode_JIT(const u32 _Address, const u32 _Value); // this is used by Debugger a lot. // For now, just reads from memory! u32 Read_Instruction(const u32 _Address); // For use by emulator // Read and write functions #define NUMHWMEMFUN 64 #define HWSHIFT 10 #define HW_MASK 0x3FF u8 Read_U8(const u32 _Address); u16 Read_U16(const u32 _Address); u32 Read_U32(const u32 _Address); u64 Read_U64(const u32 _Address); #if (defined(ARM) || defined(_ARM)) && !defined(_M_ARM) #define _M_ARM #endif #ifdef SAFE_MEMORY u32 ReadUnchecked_U32(const u32 _Address); // ONLY for use by GUI and fast interpreter u8 ReadUnchecked_U8(const u32 _Address); u16 ReadUnchecked_U16(const u32 _Address); void WriteUnchecked_U8(const u8 _Data, const u32 _Address); void WriteUnchecked_U16(const u16 _Data, const u32 _Address); void WriteUnchecked_U32(const u32 _Data, const u32 _Address); #else inline u32 ReadUnchecked_U32(const u32 address) { #if defined(_M_IX86) || defined(_M_ARM32) return (*(u32 *)(base + (address & MEMVIEW32_MASK))); #else return (*(u32 *)(base + address)); #endif } inline u16 ReadUnchecked_U16(const u32 address) { #if defined(_M_IX86) || defined(_M_ARM32) return (*(u16 *)(base + (address & MEMVIEW32_MASK))); #else return (*(u16 *)(base + address)); #endif } inline u8 ReadUnchecked_U8(const u32 address) { #if defined(_M_IX86) || defined(_M_ARM32) return (*(u8 *)(base + (address & MEMVIEW32_MASK))); #else return (*(u8 *)(base + address)); #endif } inline void WriteUnchecked_U32(u32 data, u32 address) { #if defined(_M_IX86) || defined(_M_ARM32) (*(u32 *)(base + (address & MEMVIEW32_MASK))) = data; #else (*(u32 *)(base + address)) = data; #endif } inline void WriteUnchecked_U16(u16 data, u32 address) { #if defined(_M_IX86) || defined(_M_ARM32) (*(u16 *)(base + (address & MEMVIEW32_MASK))) = data; #else (*(u16 *)(base + address)) = data; #endif } inline void WriteUnchecked_U8(u8 data, u32 address) { #if defined(_M_IX86) || defined(_M_ARM32) (*(u8 *)(base + (address & MEMVIEW32_MASK))) = data; #else (*(u8 *)(base + address)) = data; #endif } #endif inline float Read_Float(u32 address) { u32 ifloat = Read_U32(address); float f; memcpy(&f, &ifloat, sizeof(float)); return f; } // used by JIT. Return zero-extended 32bit values u32 Read_U8_ZX(const u32 address); u32 Read_U16_ZX(const u32 address); // used by JIT (Jit64::lXz) u32 EFB_Read(const u32 addr); void Write_U8(const u8 data, const u32 address); void Write_U16(const u16 data, const u32 address); void Write_U32(const u32 data, const u32 address); void Write_U64(const u64 data, const u32 address); void Write_U16_Swap(const u16 data, const u32 address); void Write_U32_Swap(const u32 data, const u32 address); void Write_U64_Swap(const u64 data, const u32 address); void WriteHW_U32(const u32 data, const u32 address); inline void Write_Float(float f, u32 address) { u32 u; memcpy(&u, &f, sizeof(float)); Write_U32(u, address); } // Reads a zero-terminated string from memory at the address. void GetString(std::string& _string, const u32 _Address); u8* GetPointer(const u32 address); bool IsValidAddress(const u32 address); inline const char* GetCharPointer(const u32 address) { return (const char *)GetPointer(address); } void Memset(const u32 _Address, const u8 _Data, const u32 _iLength); void Memcpy(const u32 _Address, const void *_Data, const u32 _iLength); void Memcpy(void *data, const u32 address, const u32 len); template void ReadStruct(u32 address, T *ptr) { size_t sz = sizeof(*ptr); memcpy(ptr, GetPointer(address), sz); } template void WriteStruct(u32 address, T *ptr) { size_t sz = sizeof(*ptr); memcpy(GetPointer(address), ptr, sz); } const char *GetAddressName(u32 address); }; #endif