pcsx2/pcsx2/vtlb.h

249 lines
9.8 KiB
C++

// SPDX-FileCopyrightText: 2002-2023 PCSX2 Dev Team
// SPDX-License-Identifier: LGPL-3.0+
#pragma once
#include "MemoryTypes.h"
#include "common/HostSys.h"
#include "common/SingleRegisterTypes.h"
static const uptr VTLB_AllocUpperBounds = _1gb * 2;
// Specialized function pointers for each read type
typedef mem8_t vtlbMemR8FP(u32 addr);
typedef mem16_t vtlbMemR16FP(u32 addr);
typedef mem32_t vtlbMemR32FP(u32 addr);
typedef mem64_t vtlbMemR64FP(u32 addr);
typedef RETURNS_R128 vtlbMemR128FP(u32 addr);
// Specialized function pointers for each write type
typedef void vtlbMemW8FP(u32 addr,mem8_t data);
typedef void vtlbMemW16FP(u32 addr,mem16_t data);
typedef void vtlbMemW32FP(u32 addr,mem32_t data);
typedef void vtlbMemW64FP(u32 addr,mem64_t data);
typedef void TAKES_R128 vtlbMemW128FP(u32 addr,r128 data);
template <size_t Width, bool Write> struct vtlbMemFP;
template<> struct vtlbMemFP< 8, false> { typedef vtlbMemR8FP fn; static const uptr Index = 0; };
template<> struct vtlbMemFP< 16, false> { typedef vtlbMemR16FP fn; static const uptr Index = 1; };
template<> struct vtlbMemFP< 32, false> { typedef vtlbMemR32FP fn; static const uptr Index = 2; };
template<> struct vtlbMemFP< 64, false> { typedef vtlbMemR64FP fn; static const uptr Index = 3; };
template<> struct vtlbMemFP<128, false> { typedef vtlbMemR128FP fn; static const uptr Index = 4; };
template<> struct vtlbMemFP< 8, true> { typedef vtlbMemW8FP fn; static const uptr Index = 0; };
template<> struct vtlbMemFP< 16, true> { typedef vtlbMemW16FP fn; static const uptr Index = 1; };
template<> struct vtlbMemFP< 32, true> { typedef vtlbMemW32FP fn; static const uptr Index = 2; };
template<> struct vtlbMemFP< 64, true> { typedef vtlbMemW64FP fn; static const uptr Index = 3; };
template<> struct vtlbMemFP<128, true> { typedef vtlbMemW128FP fn; static const uptr Index = 4; };
typedef u32 vtlbHandler;
extern bool vtlb_Core_Alloc();
extern void vtlb_Core_Free();
extern void vtlb_Alloc_Ppmap();
extern void vtlb_Init();
extern void vtlb_Shutdown();
extern void vtlb_Reset();
extern void vtlb_ResetFastmem();
extern vtlbHandler vtlb_NewHandler();
extern vtlbHandler vtlb_RegisterHandler(
vtlbMemR8FP* r8,vtlbMemR16FP* r16,vtlbMemR32FP* r32,vtlbMemR64FP* r64,vtlbMemR128FP* r128,
vtlbMemW8FP* w8,vtlbMemW16FP* w16,vtlbMemW32FP* w32,vtlbMemW64FP* w64,vtlbMemW128FP* w128
);
extern void vtlb_ReassignHandler( vtlbHandler rv,
vtlbMemR8FP* r8,vtlbMemR16FP* r16,vtlbMemR32FP* r32,vtlbMemR64FP* r64,vtlbMemR128FP* r128,
vtlbMemW8FP* w8,vtlbMemW16FP* w16,vtlbMemW32FP* w32,vtlbMemW64FP* w64,vtlbMemW128FP* w128
);
extern void vtlb_MapHandler(vtlbHandler handler,u32 start,u32 size);
extern void vtlb_MapBlock(void* base,u32 start,u32 size,u32 blocksize=0);
extern void* vtlb_GetPhyPtr(u32 paddr);
//extern void vtlb_Mirror(u32 new_region,u32 start,u32 size); // -> not working yet :(
extern u32 vtlb_V2P(u32 vaddr);
extern void vtlb_DynV2P();
//virtual mappings
extern void vtlb_VMap(u32 vaddr,u32 paddr,u32 sz);
extern void vtlb_VMapBuffer(u32 vaddr,void* buffer,u32 sz);
extern void vtlb_VMapUnmap(u32 vaddr,u32 sz);
extern bool vtlb_ResolveFastmemMapping(uptr* addr);
extern bool vtlb_GetGuestAddress(uptr host_addr, u32* guest_addr);
extern void vtlb_UpdateFastmemProtection(u32 paddr, u32 size, PageProtectionMode prot);
extern bool vtlb_BackpatchLoadStore(uptr code_address, uptr fault_address);
extern void vtlb_ClearLoadStoreInfo();
extern void vtlb_AddLoadStoreInfo(uptr code_address, u32 code_size, u32 guest_pc, u32 gpr_bitmask, u32 fpr_bitmask, u8 address_register, u8 data_register, u8 size_in_bits, bool is_signed, bool is_load, bool is_fpr);
extern void vtlb_DynBackpatchLoadStore(uptr code_address, u32 code_size, u32 guest_pc, u32 guest_addr, u32 gpr_bitmask, u32 fpr_bitmask, u8 address_register, u8 data_register, u8 size_in_bits, bool is_signed, bool is_load, bool is_fpr);
extern bool vtlb_IsFaultingPC(u32 guest_pc);
//Memory functions
template< typename DataType >
extern DataType vtlb_memRead(u32 mem);
extern RETURNS_R128 vtlb_memRead128(u32 mem);
template< typename DataType >
extern void vtlb_memWrite(u32 mem, DataType value);
extern void TAKES_R128 vtlb_memWrite128(u32 mem, r128 value);
// "Safe" variants of vtlb, designed for external tools.
// These routines only access the various RAM, and will not call handlers
// which has the potential to change hardware state.
template <typename DataType>
extern DataType vtlb_ramRead(u32 mem);
template <typename DataType>
extern bool vtlb_ramWrite(u32 mem, const DataType& value);
// NOTE: Does not call MMIO handlers.
extern int vtlb_memSafeCmpBytes(u32 mem, const void* src, u32 size);
extern bool vtlb_memSafeReadBytes(u32 mem, void* dst, u32 size);
extern bool vtlb_memSafeWriteBytes(u32 mem, const void* src, u32 size);
using vtlb_ReadRegAllocCallback = int(*)();
extern int vtlb_DynGenReadNonQuad(u32 bits, bool sign, bool xmm, int addr_reg, vtlb_ReadRegAllocCallback dest_reg_alloc = nullptr);
extern int vtlb_DynGenReadNonQuad_Const(u32 bits, bool sign, bool xmm, u32 addr_const, vtlb_ReadRegAllocCallback dest_reg_alloc = nullptr);
extern int vtlb_DynGenReadQuad(u32 bits, int addr_reg, vtlb_ReadRegAllocCallback dest_reg_alloc = nullptr);
extern int vtlb_DynGenReadQuad_Const(u32 bits, u32 addr_const, vtlb_ReadRegAllocCallback dest_reg_alloc = nullptr);
extern void vtlb_DynGenWrite(u32 sz, bool xmm, int addr_reg, int value_reg);
extern void vtlb_DynGenWrite_Const(u32 bits, bool xmm, u32 addr_const, int value_reg);
extern void vtlb_DynGenDispatchers();
namespace vtlb_private
{
static const uint VTLB_PAGE_BITS = 12;
static const uint VTLB_PAGE_MASK = 4095;
static const uint VTLB_PAGE_SIZE = 4096;
static const uint VTLB_PMAP_SZ = _1mb * 512;
static const uint VTLB_PMAP_ITEMS = VTLB_PMAP_SZ / VTLB_PAGE_SIZE;
static const uint VTLB_VMAP_ITEMS = _4gb / VTLB_PAGE_SIZE;
static const uint VTLB_HANDLER_ITEMS = 128;
static const uptr POINTER_SIGN_BIT = 1ULL << (sizeof(uptr) * 8 - 1);
struct VTLBPhysical
{
private:
sptr value;
explicit VTLBPhysical(sptr value): value(value) { }
public:
VTLBPhysical(): value(0) {}
/// Create from a pointer to raw memory
static VTLBPhysical fromPointer(void *ptr) { return fromPointer((sptr)ptr); }
/// Create from an integer representing a pointer to raw memory
static VTLBPhysical fromPointer(sptr ptr);
/// Create from a handler and address
static VTLBPhysical fromHandler(vtlbHandler handler);
/// Get the raw value held by the entry
uptr raw() const { return value; }
/// Returns whether or not this entry is a handler
bool isHandler() const { return value < 0; }
/// Assumes the entry is a pointer, giving back its value
uptr assumePtr() const { return value; }
/// Assumes the entry is a handler, and gets the raw handler ID
u8 assumeHandler() const { return value; }
};
struct VTLBVirtual
{
private:
uptr value;
explicit VTLBVirtual(uptr value): value(value) { }
public:
VTLBVirtual(): value(0) {}
VTLBVirtual(VTLBPhysical phys, u32 paddr, u32 vaddr);
static VTLBVirtual fromPointer(uptr ptr, u32 vaddr) {
return VTLBVirtual(VTLBPhysical::fromPointer(ptr), 0, vaddr);
}
/// Get the raw value held by the entry
uptr raw() const { return value; }
/// Returns whether or not this entry is a handler
bool isHandler(u32 vaddr) const { return (sptr)(value + vaddr) < 0; }
/// Assumes the entry is a pointer, giving back its value
uptr assumePtr(u32 vaddr) const { return value + vaddr; }
/// Assumes the entry is a handler, and gets the raw handler ID
u8 assumeHandlerGetID() const { return value; }
/// Assumes the entry is a handler, and gets the physical address
u32 assumeHandlerGetPAddr(u32 vaddr) const { return (value + vaddr - assumeHandlerGetID()) & ~POINTER_SIGN_BIT; }
/// Assumes the entry is a handler, returning it as a void*
void *assumeHandlerGetRaw(int index, bool write) const;
/// Assumes the entry is a handler, returning it
template <size_t Width, bool Write>
typename vtlbMemFP<Width, Write>::fn *assumeHandler() const;
};
struct MapData
{
// first indexer -- 8/16/32/64/128 bit tables [values 0-4]
// second indexer -- read/write [0 or 1]
// third indexer -- 128 possible handlers!
void* RWFT[5][2][VTLB_HANDLER_ITEMS];
VTLBPhysical pmap[VTLB_PMAP_ITEMS]; //512KB // PS2 physical to x86 physical
VTLBVirtual* vmap; //4MB (allocated by vtlb_init) // PS2 virtual to x86 physical
u32* ppmap; //4MB (allocated by vtlb_init) // PS2 virtual to PS2 physical
uptr fastmem_base;
MapData()
{
vmap = NULL;
ppmap = NULL;
fastmem_base = 0;
}
};
alignas(64) extern MapData vtlbdata;
inline void *VTLBVirtual::assumeHandlerGetRaw(int index, bool write) const
{
return vtlbdata.RWFT[index][write][assumeHandlerGetID()];
}
template <size_t Width, bool Write>
typename vtlbMemFP<Width, Write>::fn *VTLBVirtual::assumeHandler() const
{
using FP = vtlbMemFP<Width, Write>;
return (typename FP::fn *)assumeHandlerGetRaw(FP::Index, Write);
}
}
enum vtlb_ProtectionMode
{
ProtMode_None = 0, // page is 'unaccounted' -- neither protected nor unprotected
ProtMode_Write, // page is under write protection (exception handler)
ProtMode_Manual, // page is under manual protection (self-checked at execution)
ProtMode_NotRequired // page doesn't require any protection
};
extern vtlb_ProtectionMode mmap_GetRamPageInfo(u32 paddr);
extern void mmap_MarkCountedRamPage(u32 paddr);
extern void mmap_ResetBlockTracking();
// --------------------------------------------------------------------------------------
// Goemon game fix
// --------------------------------------------------------------------------------------
struct GoemonTlb {
u32 valid;
u32 unk1; // could be physical address also
u32 unk2;
u32 low_add;
u32 physical_add;
u32 unk3; // likely the size
u32 high_add;
u32 key; // uniq number attached to an allocation
u32 unk5;
};