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mirror of https://github.com/RPCS3/rpcs3.git synced 2024-11-22 10:42:36 +01:00

Added Virtual Memory Block for the IO Address Space

Started implementing some the memory mapping functions of libgcm
This commit is contained in:
elisha464 2014-01-17 18:56:03 +02:00
parent 40f2e679ec
commit 509d46a544
4 changed files with 406 additions and 57 deletions

View File

@ -509,3 +509,186 @@ template<> __forceinline u64 MemoryBase::ReverseData<1>(u64 val) { return val; }
template<> __forceinline u64 MemoryBase::ReverseData<2>(u64 val) { return Reverse16(val); }
template<> __forceinline u64 MemoryBase::ReverseData<4>(u64 val) { return Reverse32(val); }
template<> __forceinline u64 MemoryBase::ReverseData<8>(u64 val) { return Reverse64(val); }
VirtualMemoryBlock::VirtualMemoryBlock() : MemoryBlock()
{
}
bool VirtualMemoryBlock::IsInMyRange(const u64 addr)
{
return addr >= GetStartAddr() && addr < GetStartAddr() + GetSize();
}
bool VirtualMemoryBlock::IsInMyRange(const u64 addr, const u32 size)
{
return IsInMyRange(addr) && IsInMyRange(addr + size - 1);
}
bool VirtualMemoryBlock::IsMyAddress(const u64 addr)
{
for(u32 i=0; i<m_mapped_memory.GetCount(); ++i)
{
if(addr >= m_mapped_memory[i].addr && addr < m_mapped_memory[i].addr + m_mapped_memory[i].size)
{
return true;
}
}
return false;
}
u64 VirtualMemoryBlock::Map(u64 realaddr, u32 size, u64 addr)
{
if(addr)
{
if(!IsInMyRange(addr, size) && (IsMyAddress(addr) || IsMyAddress(addr + size - 1)))
return 0;
m_mapped_memory.Move(new VirtualMemInfo(addr, realaddr, size));
return addr;
}
else
{
for(u64 addr = GetStartAddr(); addr <= GetEndAddr() - size;)
{
bool is_good_addr = true;
for(u32 i=0; i<m_mapped_memory.GetCount(); ++i)
{
if((addr >= m_mapped_memory[i].addr && addr < m_mapped_memory[i].addr + m_mapped_memory[i].size) ||
(m_mapped_memory[i].addr >= addr && m_mapped_memory[i].addr < addr + size))
{
is_good_addr = false;
addr = m_mapped_memory[i].addr + m_mapped_memory[i].size;
break;
}
}
if(!is_good_addr) continue;
m_mapped_memory.Move(new VirtualMemInfo(addr, realaddr, size));
return addr;
}
return 0;
}
}
bool VirtualMemoryBlock::UnmapRealAddress(u64 realaddr)
{
for(u32 i=0; i<m_mapped_memory.GetCount(); ++i)
{
if(m_mapped_memory[i].realAddress == realaddr)
{
m_mapped_memory.RemoveAt(i);
return true;
}
}
return false;
}
bool VirtualMemoryBlock::UnmapAddress(u64 addr)
{
for(u32 i=0; i<m_mapped_memory.GetCount(); ++i)
{
if(m_mapped_memory[i].addr == addr)
{
m_mapped_memory.RemoveAt(i);
return true;
}
}
return false;
}
bool VirtualMemoryBlock::Read8(const u64 addr, u8* value)
{
u64 realAddr;
*value = Memory.Read8(realAddr = getRealAddr(addr));
return realAddr != 0;
}
bool VirtualMemoryBlock::Read16(const u64 addr, u16* value)
{
u64 realAddr;
*value = Memory.Read16(realAddr = getRealAddr(addr));
return realAddr != 0;
}
bool VirtualMemoryBlock::Read32(const u64 addr, u32* value)
{
u64 realAddr;
*value = Memory.Read32(realAddr = getRealAddr(addr));
return realAddr != 0;
}
bool VirtualMemoryBlock::Read64(const u64 addr, u64* value)
{
u64 realAddr;
*value = Memory.Read64(realAddr = getRealAddr(addr));
return realAddr != 0;
}
bool VirtualMemoryBlock::Read128(const u64 addr, u128* value)
{
u64 realAddr;
*value = Memory.Read128(realAddr = getRealAddr(addr));
return realAddr != 0;
}
bool VirtualMemoryBlock::Write8(const u64 addr, const u8 value)
{
u64 realAddr;
Memory.Write8(realAddr = getRealAddr(addr), value);
return realAddr != 0;
}
bool VirtualMemoryBlock::Write16(const u64 addr, const u16 value)
{
u64 realAddr;
Memory.Write16(realAddr = getRealAddr(addr), value);
return realAddr != 0;
}
bool VirtualMemoryBlock::Write32(const u64 addr, const u32 value)
{
u64 realAddr;
Memory.Write32(realAddr = getRealAddr(addr), value);
return realAddr != 0;
}
bool VirtualMemoryBlock::Write64(const u64 addr, const u64 value)
{
u64 realAddr;
Memory.Write64(realAddr = getRealAddr(addr), value);
return realAddr != 0;
}
bool VirtualMemoryBlock::Write128(const u64 addr, const u128 value)
{
u64 realAddr;
Memory.Write128(realAddr = getRealAddr(addr), value);
return realAddr != 0;
}
u64 VirtualMemoryBlock::getRealAddr(u64 addr)
{
for(u32 i=0; i<m_mapped_memory.GetCount(); ++i)
{
if(addr >= m_mapped_memory[i].addr && addr < m_mapped_memory[i].addr + m_mapped_memory[i].size)
{
return m_mapped_memory[i].realAddress + (addr - m_mapped_memory[i].addr);
}
}
return 0;
}
void VirtualMemoryBlock::Delete()
{
m_mapped_memory.Clear();
MemoryBlock::Delete();
}

View File

@ -24,6 +24,7 @@ public:
DynamicMemoryBlock StackMem;
MemoryBlock SpuRawMem;
MemoryBlock SpuThrMem;
VirtualMemoryBlock RSXIOMem;
struct
{

View File

@ -40,6 +40,23 @@ struct MemBlockInfo : public MemInfo
}
};
struct VirtualMemInfo : public MemInfo
{
u64 realAddress;
VirtualMemInfo(u64 _addr, u64 _realaddr, u32 _size)
: MemInfo(_addr, _size)
, realAddress(_realaddr)
{
}
VirtualMemInfo()
: MemInfo(0, 0)
, realAddress(0)
{
}
};
class MemoryBlock
{
protected:
@ -206,6 +223,44 @@ private:
void AppendLockedMem(u64 addr, u32 size);
};
class VirtualMemoryBlock : public MemoryBlock
{
Array<VirtualMemInfo> m_mapped_memory;
public:
VirtualMemoryBlock();
virtual bool IsInMyRange(const u64 addr);
virtual bool IsInMyRange(const u64 addr, const u32 size);
virtual bool IsMyAddress(const u64 addr);
virtual void Delete();
// maps real address to virtual address space, returns the mapped address or 0 on failure (if no address is specified the
// first mappable space is used)
virtual u64 Map(u64 realaddr, u32 size, u64 addr = 0);
// Unmap real address (please specify only starting point, no midway memory will be unmapped)
virtual bool UnmapRealAddress(u64 realaddr);
// Unmap address (please specify only starting point, no midway memory will be unmapped)
virtual bool UnmapAddress(u64 addr);
virtual bool Read8(const u64 addr, u8* value);
virtual bool Read16(const u64 addr, u16* value);
virtual bool Read32(const u64 addr, u32* value);
virtual bool Read64(const u64 addr, u64* value);
virtual bool Read128(const u64 addr, u128* value);
virtual bool Write8(const u64 addr, const u8 value);
virtual bool Write16(const u64 addr, const u16 value);
virtual bool Write32(const u64 addr, const u32 value);
virtual bool Write64(const u64 addr, const u64 value);
virtual bool Write128(const u64 addr, const u128 value);
// return the real address given a mapped address, if not mapped return 0
u64 getRealAddr(u64 addr);
};
#include "DynamicMemoryBlockBase.inl"
typedef DynamicMemoryBlockBase<MemoryBlock> DynamicMemoryBlock;

View File

@ -6,6 +6,9 @@
void cellGcmSys_init();
Module cellGcmSys(0x0010, cellGcmSys_init);
u32 local_size = 0;
u32 local_addr = NULL;
enum
{
CELL_GCM_ERROR_FAILURE = 0x802100ff,
@ -19,10 +22,12 @@ CellGcmContextData current_context;
gcmInfo gcm_info;
struct gcm_offset
{
u16 ea;
u16 offset;
mem_ptr_t<u16> io;
mem_ptr_t<u16> ea;
};
//gcm_offset offsetTable;
u32 map_offset_addr = 0;
u32 map_offset_pos = 0;
@ -42,6 +47,9 @@ int cellGcmMapMainMemory(u32 address, u32 size, mem32_t offset)
int cellGcmMapEaIoAddress(const u32 ea, const u32 io, const u32 size)
{
cellGcmSys.Warning("cellGcmMapEaIoAddress(ea=0x%x, io=0x%x, size=0x%x)", ea, io, size);
if(io % 0x100000 != 0 || size % 0x100000 != 0) return CELL_GCM_ERROR_FAILURE;
//Memory.Map(io, ea, size);
//Emu.GetGSManager().GetRender().m_ioAddress = io;
Emu.GetGSManager().GetRender().m_report_main_addr = ea;
@ -52,8 +60,12 @@ int cellGcmInit(u32 context_addr, u32 cmdSize, u32 ioSize, u32 ioAddress)
{
cellGcmSys.Warning("cellGcmInit(context_addr=0x%x,cmdSize=0x%x,ioSize=0x%x,ioAddress=0x%x)", context_addr, cmdSize, ioSize, ioAddress);
const u32 local_size = 0xf900000; //TODO
const u32 local_addr = Memory.RSXFBMem.GetStartAddr();
if(!local_size && !local_addr)
{
u32 local_size = 0xf900000; //TODO
u32 local_addr = Memory.RSXFBMem.GetStartAddr();
Memory.RSXFBMem.Alloc(local_size);
}
cellGcmSys.Warning("*** local memory(addr=0x%x, size=0x%x)", local_addr, local_size);
@ -66,8 +78,9 @@ int cellGcmInit(u32 context_addr, u32 cmdSize, u32 ioSize, u32 ioAddress)
current_config.memoryFrequency = re32(650000000);
current_config.coreFrequency = re32(500000000);
Memory.RSXFBMem.Alloc(local_size);
Memory.RSXCMDMem.Alloc(cmdSize);
Memory.MemoryBlocks.Add(Memory.RSXIOMem.SetRange(0xD0000000, 0x10000000/*256MB*/));
Memory.RSXIOMem.Map(ioAddress, ioSize);
u32 ctx_begin = ioAddress/* + 0x1000*/;
u32 ctx_size = 0x6ffc;
@ -112,57 +125,6 @@ int cellGcmGetConfiguration(mem_ptr_t<CellGcmConfig> config)
return CELL_OK;
}
int cellGcmAddressToOffset(u32 address, mem32_t offset)
{
cellGcmSys.Log("cellGcmAddressToOffset(address=0x%x,offset_addr=0x%x)", address, offset.GetAddr());
if(!offset.IsGood()) return CELL_EFAULT;
if(!map_offset_addr)
{
map_offset_addr = Memory.Alloc(4*50, 4);
}
u32 sa;
bool is_main_mem = false;
const auto& main_mem_info = Emu.GetGSManager().GetRender().m_main_mem_info;
for(u32 i=0; i<Emu.GetGSManager().GetRender().m_main_mem_info.GetCount(); ++i)
{
//main memory
if(address >= main_mem_info[i].addr && address < main_mem_info[i].addr + main_mem_info[i].size)
{
is_main_mem = true;
break;
}
}
if(is_main_mem)
{
//main
sa = Emu.GetGSManager().GetRender().m_main_mem_addr;
//ConLog.Warning("cellGcmAddressToOffset: main memory: offset = 0x%x - 0x%x = 0x%x", address, sa, address - sa);
}
else if(Memory.RSXFBMem.IsMyAddress(address))
{
//local
sa = Emu.GetGSManager().GetRender().m_local_mem_addr;
//ConLog.Warning("cellGcmAddressToOffset: local memory: offset = 0x%x - 0x%x = 0x%x", address, sa, address - sa);
}
else
{
//io
sa = Emu.GetGSManager().GetRender().m_ioAddress;
//ConLog.Warning("cellGcmAddressToOffset: io memory: offset = 0x%x - 0x%x = 0x%x", address, sa, address - sa);
}
offset = address - sa;
//ConLog.Warning("Address To Offset: 0x%x -> 0x%x", address, address - sa);
//Memory.Write16(map_offset_addr + map_offset_pos + 0, ea);
//Memory.Write16(map_offset_addr + map_offset_pos + 2, offset);
//map_offset_pos += 4;
return CELL_OK;
}
int cellGcmSetDisplayBuffer(u32 id, u32 offset, u32 pitch, u32 width, u32 height)
{
cellGcmSys.Warning("cellGcmSetDisplayBuffer(id=0x%x,offset=0x%x,pitch=%d,width=%d,height=%d)",
@ -573,13 +535,154 @@ int cellGcmSetSecondVFrequency (u32 freq)
return CELL_OK;
}
/*------------------------------------------------------------
Memory Mapping
------------------------------------------------------------*/
int cellGcmAddressToOffset(u32 address, mem32_t offset)
{
cellGcmSys.Log("cellGcmAddressToOffset(address=0x%x,offset_addr=0x%x)", address, offset.GetAddr());
if(!offset.IsGood()) return CELL_EFAULT;
if(!map_offset_addr)
{
map_offset_addr = Memory.Alloc(4*50, 4);
}
u32 sa;
bool is_main_mem = false;
const auto& main_mem_info = Emu.GetGSManager().GetRender().m_main_mem_info;
for(u32 i=0; i<Emu.GetGSManager().GetRender().m_main_mem_info.GetCount(); ++i)
{
//main memory
if(address >= main_mem_info[i].addr && address < main_mem_info[i].addr + main_mem_info[i].size)
{
is_main_mem = true;
break;
}
}
if(is_main_mem)
{
//main
sa = Emu.GetGSManager().GetRender().m_main_mem_addr;
//ConLog.Warning("cellGcmAddressToOffset: main memory: offset = 0x%x - 0x%x = 0x%x", address, sa, address - sa);
}
else if(Memory.RSXFBMem.IsMyAddress(address))
{
//local
sa = Emu.GetGSManager().GetRender().m_local_mem_addr;
//ConLog.Warning("cellGcmAddressToOffset: local memory: offset = 0x%x - 0x%x = 0x%x", address, sa, address - sa);
}
else
{
//io
sa = Emu.GetGSManager().GetRender().m_ioAddress;
//ConLog.Warning("cellGcmAddressToOffset: io memory: offset = 0x%x - 0x%x = 0x%x", address, sa, address - sa);
}
offset = address - sa;
//ConLog.Warning("Address To Offset: 0x%x -> 0x%x", address, address - sa);
//Memory.Write16(map_offset_addr + map_offset_pos + 0, ea);
//Memory.Write16(map_offset_addr + map_offset_pos + 2, offset);
//map_offset_pos += 4;
return CELL_OK;
}
u32 cellGcmGetMaxIoMapSize()
{
UNIMPLEMENTED_FUNC(cellGcmSys);
return 0x10000000;//256MB TODO
}
void cellGcmGetOffsetTable(mem_ptr_t<gcm_offset> table)
{
static gcm_offset temp = {NULL, NULL};
if(!temp.io.IsGood())
{
u32 mem = Memory.Alloc(sizeof(u16) * 0xBFF, 1);
for(int i=0; i<0xBFF; i++)
{
Memory.Write16(mem + i*sizeof(u16), 0xFFFF);
}
temp.io = re(mem);
}
if(!temp.ea.IsGood())
{
u32 mem = Memory.Alloc(sizeof(u16) * 511, 1);
for(int i=0; i<511; i++)
{
Memory.Write16(mem + i*sizeof(u16), 0xFFFF);
}
temp.ea = re(mem);
}
*table = temp;
if(!current_config.localAddress)
{
/*Memory.Write16((table->io), 0xFFFF);
Memory.Write16(table->io + (uint)2, 0xFFFF);*/
}
if(!current_config.ioAddress)
{
/*Memory.Write16(table->ea, 0xFFFF);
Memory.Write16(table->ea + (uint)2, 0xFFFF);*/
}
UNIMPLEMENTED_FUNC(cellGcmSys);
}
int32_t cellGcmIoOffsetToAddress(u32 ioOffset, mem_ptr_t<void*> address)
{
u64 realAddr;
realAddr = Memory.RSXIOMem.getRealAddr(Memory.RSXIOMem.GetStartAddr() + ioOffset);
if(!realAddr)
return CELL_GCM_ERROR_FAILURE;
Memory.Write64(address, realAddr);
return CELL_OK;
}
int32_t cellGcmMapLocalMemory(mem_ptr_t<void*> address, mem_ptr_t<uint32_t> size)
{
if(!local_size && !local_addr)
{
u32 local_size = 0xf900000; //TODO
u32 local_addr = Memory.RSXFBMem.GetStartAddr();
Memory.RSXFBMem.Alloc(local_size);
Memory.Write32(address.GetAddr(), local_addr);
Memory.Write32(size.GetAddr(), local_size);
}
else
{
printf("RSX local memory already mapped");
return CELL_GCM_ERROR_FAILURE;
}
return CELL_OK;
}
void cellGcmSys_init()
{
current_config.ioAddress = NULL;
current_config.localAddress = NULL;
cellGcmSys.AddFunc(0x055bd74d, cellGcmGetTiledPitchSize);
cellGcmSys.AddFunc(0x06edea9e, cellGcmSetUserHandler);
cellGcmSys.AddFunc(0x15bae46b, cellGcmInit);
cellGcmSys.AddFunc(0x21397818, cellGcmSetFlipCommand);
cellGcmSys.AddFunc(0x21ac3697, cellGcmAddressToOffset);
cellGcmSys.AddFunc(0x3a33c1fd, cellGcmFunc15);
cellGcmSys.AddFunc(0x4ae8d215, cellGcmSetFlipMode);
cellGcmSys.AddFunc(0x63441cb4, cellGcmMapEaIoAddress);
@ -622,4 +725,11 @@ void cellGcmSys_init()
cellGcmSys.AddFunc(0x4d7ce993, cellGcmSetSecondVFrequency);
cellGcmSys.AddFunc(0xdc09357e, cellGcmSetFlip);
cellGcmSys.AddFunc(0x983fb9aa, cellGcmSetWaitFlip);
cellGcmSys.AddFunc(0xdb769b32, cellGcmMapLocalMemory);
//Memory Mapping
cellGcmSys.AddFunc(0x21ac3697, cellGcmAddressToOffset);
cellGcmSys.AddFunc(0xfb81c03e, cellGcmGetMaxIoMapSize);
cellGcmSys.AddFunc(0x2922aed0, cellGcmGetOffsetTable);
cellGcmSys.AddFunc(0x2a6fba9c, cellGcmIoOffsetToAddress);
}