Play-/Source/ee/IPU.cpp

1890 lines
38 KiB
C++

#include <stdio.h>
#include <exception>
#include <functional>
#include "IPU.h"
#include "IPU_MacroblockAddressIncrementTable.h"
#include "IPU_MacroblockTypeITable.h"
#include "IPU_MacroblockTypePTable.h"
#include "IPU_MacroblockTypeBTable.h"
#include "IPU_MotionCodeTable.h"
#include "IPU_DmVectorTable.h"
#include "mpeg2/DcSizeLuminanceTable.h"
#include "mpeg2/DcSizeChrominanceTable.h"
#include "mpeg2/DctCoefficientTable0.h"
#include "mpeg2/DctCoefficientTable1.h"
#include "mpeg2/CodedBlockPatternTable.h"
#include "mpeg2/QuantiserScaleTable.h"
#include "mpeg2/InverseScanTable.h"
#include "idct/TrivialC.h"
#include "idct/IEEE1180.h"
#include "../Log.h"
#include "DMAC.h"
#define LOG_NAME ("ipu")
//#define _DECODE_LOGGING
#define DECODE_LOG_NAME ("ipu_decode")
using namespace IPU;
using namespace MPEG2;
static CVLCTable::DECODE_STATUS FilterSymbolError(CVLCTable::DECODE_STATUS result)
{
switch(result)
{
case CVLCTable::DECODE_STATUS_SYMBOLNOTFOUND:
throw CVLCTable::CVLCTableException();
break;
default:
return result;
break;
}
}
CIPU::CIPU()
: m_IPU_CTRL(0)
, m_isBusy(false)
, m_currentCmd(nullptr)
{
}
CIPU::~CIPU()
{
}
void CIPU::Reset()
{
m_IPU_CTRL = 0;
m_IPU_CMD[0] = 0;
m_IPU_CMD[1] = 0;
m_nTH0 = 0;
m_nTH1 = 0;
m_isBusy = false;
m_currentCmd = nullptr;
m_IN_FIFO.Reset();
m_OUT_FIFO.Reset();
}
uint32 CIPU::GetRegister(uint32 nAddress)
{
#ifdef _DEBUG
// DisassembleGet(nAddress);
#endif
switch(nAddress)
{
case IPU_CMD + 0x0:
return m_IPU_CMD[0];
break;
case IPU_CMD + 0x4:
return GetBusyBit(m_isBusy);
break;
case IPU_CMD + 0x8:
case IPU_CMD + 0xC:
break;
case IPU_CTRL + 0x0:
return m_IPU_CTRL | GetBusyBit(m_isBusy) | (m_IN_FIFO.GetSize() / 0x10);
break;
case IPU_CTRL + 0x4:
case IPU_CTRL + 0x8:
case IPU_CTRL + 0xC:
break;
case IPU_BP + 0x0:
return ((m_IN_FIFO.GetSize() / 0x10) << 8) | (m_IN_FIFO.GetBitIndex());
break;
case IPU_BP + 0x4:
case IPU_BP + 0x8:
case IPU_BP + 0xC:
break;
case IPU_TOP + 0x0:
if(!m_isBusy)
{
unsigned int availableSize = std::min<unsigned int>(32, m_IN_FIFO.GetAvailableBits());
//If no bits are available, return zero immediately, shift below won't have any effect
if(availableSize == 0) return 0;
uint32 result = m_IN_FIFO.PeekBits_MSBF(availableSize);
result <<= (32 - availableSize);
return result;
}
else
{
return 0;
}
break;
case IPU_TOP + 0x4:
{
//Not quite sure about this... are we really busy if there's no data in the FIFO?
//This was needed to fix Timesplitters
unsigned int availableSize = std::min<unsigned int>(32, m_IN_FIFO.GetAvailableBits());
return GetBusyBit(m_isBusy) | GetBusyBit(availableSize != 32);
}
break;
case IPU_TOP + 0x8:
case IPU_TOP + 0xC:
break;
default:
CLog::GetInstance().Print(LOG_NAME, "Reading an unhandled register (0x%0.8X).\r\n", nAddress);
break;
}
return 0;
}
void CIPU::SetRegister(uint32 nAddress, uint32 nValue)
{
#ifdef _DEBUG
DisassembleSet(nAddress, nValue);
#endif
switch(nAddress)
{
case IPU_CMD + 0x0:
//Set BUSY states
{
assert(m_isBusy == false);
if(m_currentCmd != NULL)
{
assert(m_IPU_CTRL & IPU_CTRL_ECD);
}
m_IPU_CTRL &= ~IPU_CTRL_ECD;
m_IPU_CTRL &= ~IPU_CTRL_SCD;
InitializeCommand(nValue);
m_isBusy = true;
}
#ifdef _DEBUG
DisassembleCommand(nValue);
#endif
break;
case IPU_CMD + 0x4:
case IPU_CMD + 0x8:
case IPU_CMD + 0xC:
break;
case IPU_CTRL + 0x0:
if(nValue & IPU_CTRL_RST)
{
m_isBusy = false;
m_currentCmd = nullptr;
m_IN_FIFO.Reset();
m_OUT_FIFO.Reset();
}
nValue &= 0x3FFF0000;
m_IPU_CTRL &= ~0x3FFF0000;
m_IPU_CTRL |= nValue;
break;
case IPU_CTRL + 0x4:
case IPU_CTRL + 0x8:
case IPU_CTRL + 0xC:
break;
case IPU_IN_FIFO + 0x0:
case IPU_IN_FIFO + 0x4:
case IPU_IN_FIFO + 0x8:
case IPU_IN_FIFO + 0xC:
m_IN_FIFO.Write(&nValue, 4);
break;
default:
CLog::GetInstance().Print(LOG_NAME, "Writing 0x%0.8X to an unhandled register (0x%0.8X).\r\n", nValue, nAddress);
break;
}
}
void CIPU::CountTicks(uint32 ticks)
{
if(m_currentCmd)
{
m_currentCmd->CountTicks(ticks);
}
}
bool CIPU::IsCommandDelayed() const
{
if(m_currentCmd)
{
return m_currentCmd->IsDelayed();
}
return false;
}
void CIPU::ExecuteCommand()
{
assert(WillExecuteCommand());
try
{
assert(m_currentCmd != NULL);
bool result = m_currentCmd->Execute();
if(!result)
{
return;
}
m_currentCmd = nullptr;
//Clear BUSY states
m_isBusy = false;
}
catch(const Framework::CBitStream::CBitStreamException&)
{
}
catch(const CStartCodeException&)
{
m_currentCmd = nullptr;
m_isBusy = false;
m_IPU_CTRL |= IPU_CTRL_SCD;
CLog::GetInstance().Print(LOG_NAME, "Start code encountered.\r\n");
}
catch(const CVLCTable::CVLCTableException&)
{
m_currentCmd = nullptr;
m_isBusy = false;
m_IPU_CTRL |= IPU_CTRL_ECD;
CLog::GetInstance().Print(LOG_NAME, "VLC error encountered.\r\n");
}
}
bool CIPU::WillExecuteCommand() const
{
return m_isBusy && ((m_IPU_CTRL & IPU_CTRL_ECD) == 0);
}
bool CIPU::HasPendingOUTFIFOData() const
{
return m_OUT_FIFO.GetSize() != 0;
}
void CIPU::InitializeCommand(uint32 value)
{
unsigned int nCmd = (value >> 28);
switch(nCmd)
{
case IPU_CMD_BCLR:
{
m_BCLRCommand.Initialize(&m_IN_FIFO, value);
m_currentCmd = &m_BCLRCommand;
}
break;
case IPU_CMD_IDEC:
{
m_IDECCommand.Initialize(&m_BDECCommand, &m_CSCCommand, &m_IN_FIFO, &m_OUT_FIFO, value, GetDecoderContext(), m_nTH0, m_nTH1);
m_currentCmd = &m_IDECCommand;
}
break;
case IPU_CMD_BDEC:
{
m_BDECCommand.Initialize(&m_IN_FIFO, &m_OUT_FIFO, value, true, GetDecoderContext());
m_currentCmd = &m_BDECCommand;
}
break;
case IPU_CMD_VDEC:
{
m_VDECCommand.Initialize(&m_IN_FIFO, value, GetPictureType(), &m_IPU_CMD[0]);
m_currentCmd = &m_VDECCommand;
}
break;
case IPU_CMD_FDEC:
{
m_FDECCommand.Initialize(&m_IN_FIFO, value, &m_IPU_CMD[0]);
m_currentCmd = &m_FDECCommand;
}
break;
case IPU_CMD_SETIQ:
{
uint8* matrix = (value & 0x08000000) ? m_nNonIntraIQ : m_nIntraIQ;
m_SETIQCommand.Initialize(&m_IN_FIFO, matrix);
m_currentCmd = &m_SETIQCommand;
}
break;
case IPU_CMD_SETVQ:
{
m_SETVQCommand.Initialize(&m_IN_FIFO, m_nVQCLUT);
m_currentCmd = &m_SETVQCommand;
}
break;
case IPU_CMD_CSC:
{
m_CSCCommand.Initialize(&m_IN_FIFO, &m_OUT_FIFO, value, m_nTH0, m_nTH1);
m_currentCmd = &m_CSCCommand;
}
break;
case IPU_CMD_SETTH:
{
m_SETTHCommand.Initialize(value, &m_nTH0, &m_nTH1);
m_currentCmd = &m_SETTHCommand;
}
break;
default:
assert(0);
CLog::GetInstance().Print(LOG_NAME, "Unhandled command execution requested (%d).\r\n", value >> 28);
break;
}
}
void CIPU::SetDMA3ReceiveHandler(const Dma3ReceiveHandler& receiveHandler)
{
m_OUT_FIFO.SetReceiveHandler(receiveHandler);
}
uint32 CIPU::ReceiveDMA4(uint32 nAddress, uint32 nQWC, bool nTagIncluded, uint8* ram)
{
assert(nTagIncluded == false);
uint32 availableFifoSize = CINFIFO::BUFFERSIZE - m_IN_FIFO.GetSize();
uint32 nSize = std::min<uint32>(nQWC * 0x10, availableFifoSize);
assert((nSize & 0xF) == 0);
if(nSize != 0)
{
m_IN_FIFO.Write(ram + nAddress, nSize);
}
return nSize / 0x10;
}
CIPU::DECODER_CONTEXT CIPU::GetDecoderContext()
{
DECODER_CONTEXT context;
context.isMpeg1CoeffVLCTable = GetIsMPEG1CoeffVLCTable();
context.isMpeg2 = GetIsMPEG2();
context.isZigZag = GetIsZigZagScan();
context.isLinearQScale = GetIsLinearQScale();
context.dcPrecision = GetDcPrecision();
context.intraIq = m_nIntraIQ;
context.nonIntraIq = m_nNonIntraIQ;
context.dcPredictor = m_nDcPredictor;
return context;
}
uint32 CIPU::GetPictureType()
{
return (m_IPU_CTRL >> 24) & 0x7;
}
uint32 CIPU::GetDcPrecision()
{
return (m_IPU_CTRL >> 16) & 0x3;
}
bool CIPU::GetIsMPEG2()
{
return (m_IPU_CTRL & 0x00800000) == 0;
}
bool CIPU::GetIsLinearQScale()
{
return (m_IPU_CTRL & 0x00400000) == 0;
}
bool CIPU::GetIsMPEG1CoeffVLCTable()
{
return (m_IPU_CTRL & 0x00200000) == 0;
}
bool CIPU::GetIsZigZagScan()
{
return (m_IPU_CTRL & 0x00100000) == 0;
}
void CIPU::DequantiseBlock(int16* pBlock, uint8 nMBI, uint8 nQSC, bool isLinearQScale, uint32 dcPrecision, uint8* intraIq, uint8* nonIntraIq)
{
int16 nQuantScale;
if(isLinearQScale)
{
nQuantScale = (int16)CQuantiserScaleTable::m_nTable0[nQSC];
}
else
{
nQuantScale = (int16)CQuantiserScaleTable::m_nTable1[nQSC];
}
if(nMBI == 1)
{
int16 nIntraDcMult = 0;
switch(dcPrecision)
{
case 0:
nIntraDcMult = 8;
break;
case 1:
nIntraDcMult = 4;
break;
case 2:
nIntraDcMult = 2;
break;
}
pBlock[0] = nIntraDcMult * pBlock[0];
for(unsigned int i = 1; i < 64; i++)
{
int16 nSign = 0;
if(pBlock[i] == 0)
{
nSign = 0;
}
else
{
nSign = (pBlock[i] > 0) ? 0x0001 : 0xFFFF;
}
pBlock[i] = (pBlock[i] * static_cast<int16>(intraIq[i]) * nQuantScale * 2) / 32;
if(nSign != 0)
{
if((pBlock[i] & 1) == 0)
{
pBlock[i] = (pBlock[i] - nSign) | 1;
}
}
}
}
else
{
for(unsigned int i = 0; i < 64; i++)
{
int16 nSign = 0;
if(pBlock[i] == 0)
{
nSign = 0;
}
else
{
nSign = (pBlock[i] > 0) ? 0x0001 : 0xFFFF;
}
pBlock[i] = (((pBlock[i] * 2) + nSign) * static_cast<int16>(nonIntraIq[i]) * nQuantScale) / 32;
if(nSign != 0)
{
if((pBlock[i] & 1) == 0)
{
pBlock[i] = (pBlock[i] - nSign) | 1;
}
}
}
}
//Saturate
int16 nSum = 0;
for(unsigned int i = 0; i < 64; i++)
{
if(pBlock[i] > 2047)
{
pBlock[i] = 2047;
}
if(pBlock[i] < -2048)
{
pBlock[i] = -2048;
}
nSum += pBlock[i];
}
if(nSum & 1)
{
}
}
void CIPU::InverseScan(int16* pBlock, bool isZigZag)
{
int16 nTemp[0x40];
memcpy(nTemp, pBlock, sizeof(int16) * 0x40);
unsigned int* pTable = isZigZag ? CInverseScanTable::m_nTable0 : CInverseScanTable::m_nTable1;
for(unsigned int i = 0; i < 64; i++)
{
pBlock[i] = nTemp[pTable[i]];
}
}
uint32 CIPU::GetBusyBit(bool condition) const
{
return condition ? 0x80000000 : 0x00000000;
}
void CIPU::DisassembleGet(uint32 nAddress)
{
switch(nAddress)
{
case IPU_CMD:
CLog::GetInstance().Print(LOG_NAME, "IPU_CMD\r\n");
break;
case IPU_CTRL:
CLog::GetInstance().Print(LOG_NAME, "IPU_CTRL\r\n");
break;
case IPU_BP:
CLog::GetInstance().Print(LOG_NAME, "IPU_BP\r\n");
break;
case IPU_TOP:
CLog::GetInstance().Print(LOG_NAME, "IPU_TOP\r\n");
break;
}
}
void CIPU::DisassembleSet(uint32 nAddress, uint32 nValue)
{
switch(nAddress)
{
case IPU_CMD + 0x0:
CLog::GetInstance().Print(LOG_NAME, "IPU_CMD = 0x%0.8X\r\n", nValue);
break;
case IPU_CMD + 0x4:
case IPU_CMD + 0x8:
case IPU_CMD + 0xC:
break;
case IPU_CTRL + 0x0:
CLog::GetInstance().Print(LOG_NAME, "IPU_CTRL = 0x%0.8X\r\n", nValue);
break;
case IPU_CTRL + 0x4:
case IPU_CTRL + 0x8:
case IPU_CTRL + 0xC:
break;
case IPU_IN_FIFO + 0x0:
case IPU_IN_FIFO + 0x4:
case IPU_IN_FIFO + 0x8:
case IPU_IN_FIFO + 0xC:
CLog::GetInstance().Print(LOG_NAME, "IPU_IN_FIFO = 0x%0.8X\r\n", nValue);
break;
}
}
void CIPU::DisassembleCommand(uint32 nValue)
{
switch(nValue >> 28)
{
case 0:
CLog::GetInstance().Print(LOG_NAME, "BCLR(bp = %i);\r\n", nValue & 0x7F);
break;
case 2:
CLog::GetInstance().Print(LOG_NAME, "BDEC(mbi = %i, dcr = %i, dt = %i, qsc = %i, fb = %i);\r\n", \
(nValue >> 27) & 1, \
(nValue >> 26) & 1, \
(nValue >> 25) & 1, \
(nValue >> 16) & 0x1F, \
nValue & 0x3F);
break;
case 3:
{
uint32 tbl = (nValue >> 26) & 0x3;
const char* tblName = NULL;
switch(tbl)
{
case 0:
//Macroblock Address Increment
tblName = "MBI";
break;
case 1:
//Macroblock Type
switch(GetPictureType())
{
case 1:
//I Picture
tblName = "MB Type (I)";
break;
case 2:
//P Picture
tblName = "MB Type (P)";
break;
case 3:
//B Picture
tblName = "MB Type (B)";
break;
default:
assert(0);
return;
break;
}
break;
case 2:
tblName = "Motion Type";
break;
case 3:
tblName = "DM Vector";
break;
}
CLog::GetInstance().Print(LOG_NAME, "VDEC(tbl = %i (%s), bp = %i);\r\n", tbl, tblName, nValue & 0x3F);
}
break;
case 4:
CLog::GetInstance().Print(LOG_NAME, "FDEC(bp = %i);\r\n", nValue & 0x3F);
break;
case 5:
CLog::GetInstance().Print(LOG_NAME, "SETIQ(iqm = %i, bp = %i);\r\n", (nValue & 0x08000000) != 0 ? 1 : 0, nValue & 0x7F);
break;
case 6:
CLog::GetInstance().Print(LOG_NAME, "SETVQ();\r\n");
break;
case 7:
CLog::GetInstance().Print(LOG_NAME, "CSC(ofm = %i, dte = %i, mbc = %i);\r\n", \
(nValue >> 27) & 1, \
(nValue >> 26) & 1, \
(nValue >> 0) & 0x7FF);
break;
case 9:
CLog::GetInstance().Print(LOG_NAME, "SETTH(th0 = 0x%0.4X, th1 = 0x%0.4X);\r\n", nValue & 0x1FF, (nValue >> 16) & 0x1FF);
break;
}
}
/////////////////////////////////////////////
//OUT FIFO class implementation
/////////////////////////////////////////////
CIPU::COUTFIFO::COUTFIFO()
: m_buffer(nullptr)
, m_alloc(0)
, m_size(0)
{
}
CIPU::COUTFIFO::~COUTFIFO()
{
free(m_buffer);
}
void CIPU::COUTFIFO::SetReceiveHandler(const Dma3ReceiveHandler& handler)
{
m_receiveHandler = handler;
}
uint32 CIPU::COUTFIFO::GetSize() const
{
return m_size;
}
void CIPU::COUTFIFO::Write(const void* data, unsigned int size)
{
RequestGrow(size);
memcpy(m_buffer + m_size, data, size);
m_size += size;
}
void CIPU::COUTFIFO::Flush()
{
//Write to memory through DMA channel 3
assert((m_size & 0x0F) == 0);
uint32 copied = m_receiveHandler(m_buffer, m_size / 0x10);
copied *= 0x10;
if(copied == 0) return;
memmove(m_buffer, m_buffer + copied, m_size - copied);
m_size -= copied;
}
void CIPU::COUTFIFO::Reset()
{
m_size = 0;
}
void CIPU::COUTFIFO::RequestGrow(unsigned int size)
{
while(m_alloc <= (size + m_size))
{
m_alloc += GROWSIZE;
m_buffer = reinterpret_cast<uint8*>(realloc(m_buffer, m_alloc));
}
}
/////////////////////////////////////////////
//IN FIFO class implementation
/////////////////////////////////////////////
CIPU::CINFIFO::CINFIFO()
: m_size(0)
, m_bitPosition(0)
{
}
CIPU::CINFIFO::~CINFIFO()
{
}
void CIPU::CINFIFO::Write(void* data, unsigned int size)
{
if((size + m_size) > BUFFERSIZE)
{
assert(0);
return;
}
memcpy(m_buffer + m_size, data, size);
m_size += size;
m_lookupBitsDirty = true;
}
bool CIPU::CINFIFO::TryPeekBits_LSBF(uint8 nBits, uint32& result)
{
//Shouldn't be used
return false;
}
bool CIPU::CINFIFO::TryPeekBits_MSBF(uint8 size, uint32& result)
{
assert(size != 0);
assert(size <= 32);
int bitsAvailable = (m_size * 8) - m_bitPosition;
int bitsNeeded = size;
assert(bitsAvailable >= 0);
if(bitsAvailable < bitsNeeded)
{
return false;
}
if(m_lookupBitsDirty)
{
SyncLookupBits();
m_lookupBitsDirty = false;
}
uint8 shift = 64 - (m_bitPosition % 32) - size;
uint64 mask = ~0ULL >> (64 - size);
result = static_cast<uint32>((m_lookupBits >> shift) & mask);
return true;
}
void CIPU::CINFIFO::Advance(uint8 bits)
{
if(bits == 0) return;
if((m_bitPosition + bits) > (m_size * 8))
{
throw CBitStreamException();
}
uint32 wordsBefore = m_bitPosition / 32;
uint32 wordsAfter = (m_bitPosition + bits) / 32;
m_lookupBitsDirty |= (wordsBefore != wordsAfter);
m_bitPosition += bits;
while(m_bitPosition >= 128)
{
if(m_size == 0)
{
assert(0);
}
if((m_size == 0) && (m_bitPosition != 0))
{
//Humm, this seems to happen when the DMA4 has done the transfer
//but we need more data...
assert(0);
}
//Discard the read bytes
memmove(m_buffer, m_buffer + 16, m_size - 16);
m_size -= 16;
m_bitPosition -= 128;
m_lookupBitsDirty = true;
}
}
uint8 CIPU::CINFIFO::GetBitIndex() const
{
return m_bitPosition;
}
void CIPU::CINFIFO::SetBitPosition(unsigned int position)
{
m_bitPosition = position;
}
unsigned int CIPU::CINFIFO::GetSize()
{
return m_size;
}
unsigned int CIPU::CINFIFO::GetAvailableBits()
{
return (m_size * 8) - m_bitPosition;
}
void CIPU::CINFIFO::Reset()
{
m_bitPosition = 0;
m_size = 0;
m_lookupBits = 0;
m_lookupBitsDirty = false;
}
void CIPU::CINFIFO::SyncLookupBits()
{
unsigned int lookupPosition = (m_bitPosition & ~0x1F) / 8;
uint8 lookupBytes[8];
for(unsigned int i = 0; i < 8; i++)
{
lookupBytes[7 - i] = m_buffer[lookupPosition + i];
}
m_lookupBits = *reinterpret_cast<uint64*>(lookupBytes);
}
/////////////////////////////////////////////
//BCLR command implementation
/////////////////////////////////////////////
CIPU::CBCLRCommand::CBCLRCommand()
: m_IN_FIFO(NULL)
, m_commandCode(0)
{
}
void CIPU::CBCLRCommand::Initialize(CINFIFO* fifo, uint32 commandCode)
{
m_IN_FIFO = fifo;
m_commandCode = commandCode;
}
bool CIPU::CBCLRCommand::Execute()
{
m_IN_FIFO->Reset();
m_IN_FIFO->SetBitPosition(m_commandCode & 0x7F);
return true;
}
/////////////////////////////////////////////
//IDEC command implementation
/////////////////////////////////////////////
CIPU::CIDECCommand::CIDECCommand()
{
m_temp_OUT_FIFO.SetReceiveHandler(
[&] (const void* data, uint32 size)
{
m_blockStream.Write(data, size * 0x10);
return size;
}
);
}
void CIPU::CIDECCommand::Initialize(CBDECCommand* BDECCommand, CCSCCommand* CSCCommand, CINFIFO* inFifo, COUTFIFO* outFifo,
uint32 commandCode, const DECODER_CONTEXT& context, uint16 TH0, uint16 TH1)
{
m_command <<= commandCode;
assert(m_command.cmdId == IPU_CMD_IDEC);
m_IN_FIFO = inFifo;
m_OUT_FIFO = outFifo;
m_BDECCommand = BDECCommand;
m_CSCCommand = CSCCommand;
m_state = STATE_DELAY;
m_mbType = 0;
m_qsc = m_command.qsc;
m_context = context;
m_TH0 = TH0;
m_TH1 = TH1;
m_mbCount = 0;
m_delayTicks = 1000;
}
bool CIPU::CIDECCommand::Execute()
{
while(1)
{
switch(m_state)
{
case STATE_DELAY:
{
//We need to induce a delay here because some games (Gust games) will issue a command
//and restart an already active DMA3 transfer
if(m_delayTicks > 0)
{
return false;
}
m_state = STATE_ADVANCE;
}
break;
case STATE_ADVANCE:
{
m_IN_FIFO->Advance(m_command.fb);
m_state = STATE_READMBTYPE;
}
break;
case STATE_READMBTYPE:
{
if(CMacroblockTypeITable::GetInstance()->TryGetSymbol(m_IN_FIFO, m_mbType) != CVLCTable::DECODE_STATUS_SUCCESS)
{
return false;
}
assert(m_mbType & 0x1); //Must always be intra block
m_state = STATE_READDCTTYPE;
}
break;
case STATE_READDCTTYPE:
assert(m_command.dtd == 0);
m_state = STATE_READQSC;
break;
case STATE_READQSC:
if(m_mbType & 0x10) //QSC flag
{
if(!m_IN_FIFO->TryGetBits_MSBF(5, m_qsc))
{
return false;
}
}
m_state = STATE_INITREADBLOCK;
break;
case STATE_INITREADBLOCK:
{
auto bdecCommand = make_convertible<CMD_BDEC>(0);
bdecCommand.cmdId = IPU_CMD_BDEC;
bdecCommand.fb = 0;
bdecCommand.mbi = 1;
bdecCommand.dt = 0;
bdecCommand.dcr = (m_mbCount == 0) ? 1 : 0;
bdecCommand.qsc = m_qsc;
m_BDECCommand->Initialize(m_IN_FIFO, &m_temp_OUT_FIFO, bdecCommand, false, m_context);
m_state = STATE_READBLOCK;
m_blockStream.ResetBuffer();
}
break;
case STATE_READBLOCK:
{
if(!m_BDECCommand->Execute())
{
return false;
}
m_state = STATE_CSCINIT;
m_mbCount++;
}
break;
case STATE_CSCINIT:
{
auto cscCommand = make_convertible<CMD_CSC>(0);
cscCommand.cmdId = IPU_CMD_CSC;
cscCommand.mbc = 1;
cscCommand.dte = m_command.dte;
cscCommand.ofm = m_command.ofm;
m_CSCCommand->Initialize(&m_temp_IN_FIFO, m_OUT_FIFO, cscCommand, m_TH0, m_TH1);
m_state = STATE_CSC;
m_blockStream.Seek(0, Framework::STREAM_SEEK_SET);
}
break;
case STATE_CSC:
while(1)
{
uint8 readBuffer[CINFIFO::BUFFERSIZE];
auto readSize = CINFIFO::BUFFERSIZE - m_temp_IN_FIFO.GetSize();
if(readSize != 0)
{
readSize = m_blockStream.Read(readBuffer, readSize);
m_temp_IN_FIFO.Write(readBuffer, readSize);
}
if(m_CSCCommand->Execute())
{
m_state = STATE_CHECKSTARTCODE;
break;
}
if(m_OUT_FIFO->GetSize() != 0)
{
//We assume that DMA3 didn't proceed and that we need to wait
//for CPU to accept the data
return false;
}
}
break;
case STATE_CHECKSTARTCODE:
{
uint32 startCode = 0;
if(!m_IN_FIFO->TryPeekBits_MSBF(23, startCode))
{
return false;
}
if(startCode == 0)
{
m_state = STATE_DONE;
}
else
{
m_state = STATE_READMBINCREMENT;
}
}
break;
case STATE_READMBINCREMENT:
{
uint32 mbIncrement = 0;
if(CMacroblockAddressIncrementTable::GetInstance()->TryGetSymbol(m_IN_FIFO, mbIncrement) != CVLCTable::DECODE_STATUS_SUCCESS)
{
return false;
}
assert((mbIncrement & 0xFFFF) == 1);
m_state = STATE_READMBTYPE;
}
break;
case STATE_DONE:
return true;
break;
default:
assert(false);
break;
}
}
return false;
}
void CIPU::CIDECCommand::CountTicks(uint32 ticks)
{
m_delayTicks -= ticks;
}
bool CIPU::CIDECCommand::IsDelayed() const
{
return (m_state == STATE_DELAY);
}
/////////////////////////////////////////////
//BDEC command implementation
/////////////////////////////////////////////
CIPU::CBDECCommand::CBDECCommand()
{
m_blocks[0].block = m_yBlock[0]; m_blocks[0].channel = 0;
m_blocks[1].block = m_yBlock[1]; m_blocks[1].channel = 0;
m_blocks[2].block = m_yBlock[2]; m_blocks[2].channel = 0;
m_blocks[3].block = m_yBlock[3]; m_blocks[3].channel = 0;
m_blocks[4].block = m_cbBlock; m_blocks[4].channel = 1;
m_blocks[5].block = m_crBlock; m_blocks[5].channel = 2;
}
void CIPU::CBDECCommand::Initialize(CINFIFO* inFifo, COUTFIFO* outFifo, uint32 commandCode, bool checkStartCode, const DECODER_CONTEXT& context)
{
m_command <<= commandCode;
assert(m_command.cmdId == IPU_CMD_BDEC);
m_checkStartCode = checkStartCode;
m_context = context;
m_IN_FIFO = inFifo;
m_OUT_FIFO = outFifo;
m_state = STATE_ADVANCE;
m_codedBlockPattern = 0;
m_currentBlockIndex = 0;
}
bool CIPU::CBDECCommand::Execute()
{
while(1)
{
switch(m_state)
{
case STATE_ADVANCE:
{
m_IN_FIFO->Advance(m_command.fb);
m_state = STATE_READCBP;
}
break;
case STATE_READCBP:
{
if(!m_command.mbi)
{
//Not an Intra Macroblock, so we need to fetch the pattern code
m_codedBlockPattern = static_cast<uint8>(CCodedBlockPatternTable::GetInstance()->GetSymbol(m_IN_FIFO));
}
else
{
m_codedBlockPattern = 0x3F;
}
m_state = STATE_RESETDC;
}
break;
case STATE_RESETDC:
{
#ifdef _DECODE_LOGGING
static int currentMbIndex = 0;
CLog::GetInstance().Print(DECODE_LOG_NAME, "Macroblock(%d, CBP: 0x%0.2X)\r\n",
currentMbIndex++, m_codedBlockPattern);
#endif
if(m_command.dcr)
{
int16 resetValue = 0;
//Reset the DC prediction values
switch(m_context.dcPrecision)
{
case 0:
resetValue = 128;
break;
case 1:
resetValue = 256;
break;
case 2:
resetValue = 512;
break;
default:
resetValue = 0;
assert(0);
break;
}
m_context.dcPredictor[0] = resetValue;
m_context.dcPredictor[1] = resetValue;
m_context.dcPredictor[2] = resetValue;
}
m_state = STATE_DECODEBLOCK_BEGIN;
}
break;
case STATE_DECODEBLOCK_BEGIN:
{
BLOCKENTRY& blockInfo(m_blocks[m_currentBlockIndex]);
memset(blockInfo.block, 0, sizeof(int16) * 64);
if((m_codedBlockPattern & (1 << (5 - m_currentBlockIndex))))
{
m_readDctCoeffsCommand.Initialize(m_IN_FIFO,
blockInfo.block, blockInfo.channel,
m_context.dcPredictor, (m_command.mbi != 0), m_context.isMpeg1CoeffVLCTable, m_context.isMpeg2);
m_state = STATE_DECODEBLOCK_READCOEFFS;
}
else
{
m_state = STATE_DECODEBLOCK_GOTONEXT;
}
}
break;
case STATE_DECODEBLOCK_READCOEFFS:
{
if(!m_readDctCoeffsCommand.Execute())
{
return false;
}
BLOCKENTRY& blockInfo(m_blocks[m_currentBlockIndex]);
int16 blockTemp[0x40];
InverseScan(blockInfo.block, m_context.isZigZag);
DequantiseBlock(blockInfo.block, (m_command.mbi != 0), m_command.qsc,
m_context.isLinearQScale, m_context.dcPrecision, m_context.intraIq, m_context.nonIntraIq);
memcpy(blockTemp, blockInfo.block, sizeof(int16) * 0x40);
IDCT::CIEEE1180::GetInstance()->Transform(blockTemp, blockInfo.block);
m_state = STATE_DECODEBLOCK_GOTONEXT;
}
break;
case STATE_DECODEBLOCK_GOTONEXT:
{
m_currentBlockIndex++;
if(m_currentBlockIndex == 6)
{
m_state = STATE_DONE;
}
else
{
m_state = STATE_DECODEBLOCK_BEGIN;
}
}
break;
case STATE_DONE:
{
//Write blocks into out FIFO
for(unsigned int i = 0; i < 8; i++)
{
m_OUT_FIFO->Write(m_blocks[0].block + (i * 8), sizeof(int16) * 0x8);
m_OUT_FIFO->Write(m_blocks[1].block + (i * 8), sizeof(int16) * 0x8);
}
for(unsigned int i = 0; i < 8; i++)
{
m_OUT_FIFO->Write(m_blocks[2].block + (i * 8), sizeof(int16) * 0x8);
m_OUT_FIFO->Write(m_blocks[3].block + (i * 8), sizeof(int16) * 0x8);
}
m_OUT_FIFO->Write(m_blocks[4].block, sizeof(int16) * 0x40);
m_OUT_FIFO->Write(m_blocks[5].block, sizeof(int16) * 0x40);
m_OUT_FIFO->Flush();
//Check if there's more than 7 zero bits after this and set "start code detected"
if(m_checkStartCode)
{
uint32 nextBits = 0;
if(m_IN_FIFO->TryPeekBits_MSBF(8, nextBits))
{
if(nextBits == 0)
{
throw CStartCodeException();
}
}
}
}
return true;
break;
}
}
}
/////////////////////////////////////////////
//BDEC ReadDct subcommand implementation
/////////////////////////////////////////////
CIPU::CBDECCommand_ReadDct::CBDECCommand_ReadDct()
: m_state(STATE_INIT)
, m_IN_FIFO(NULL)
, m_coeffTable(NULL)
, m_block(NULL)
, m_dcPredictor(NULL)
, m_dcDiff(0)
, m_channelId(0)
, m_mbi(false)
, m_isMpeg1CoeffVLCTable(false)
, m_isMpeg2(true)
, m_blockIndex(0)
{
}
void CIPU::CBDECCommand_ReadDct::Initialize(CINFIFO* fifo, int16* block, unsigned int channelId, int16* dcPredictor, bool mbi, bool isMpeg1CoeffVLCTable, bool isMpeg2)
{
m_state = STATE_INIT;
m_IN_FIFO = fifo;
m_block = block;
m_dcPredictor = dcPredictor;
m_channelId = channelId;
m_mbi = mbi;
m_isMpeg1CoeffVLCTable = isMpeg1CoeffVLCTable;
m_isMpeg2 = isMpeg2;
m_coeffTable = NULL;
m_blockIndex = 0;
m_dcDiff = 0;
if(m_mbi && !m_isMpeg1CoeffVLCTable)
{
m_coeffTable = &CDctCoefficientTable1::GetInstance();
}
else
{
m_coeffTable = &CDctCoefficientTable0::GetInstance();
}
}
bool CIPU::CBDECCommand_ReadDct::Execute()
{
while(1)
{
switch(m_state)
{
case STATE_INIT:
{
#ifdef _DECODE_LOGGING
static int currentBlockIndex = 0;
CLog::GetInstance().Print(DECODE_LOG_NAME, "Block(%d) = ", currentBlockIndex++);
#endif
if(m_mbi)
{
m_readDcDiffCommand.Initialize(m_IN_FIFO, m_channelId, &m_dcDiff);
m_state = STATE_READDCDIFF;
}
else
{
m_state = STATE_CHECKEOB;
}
}
break;
case STATE_READDCDIFF:
{
if(!m_readDcDiffCommand.Execute())
{
return false;
}
m_block[0] = static_cast<int16>(m_dcPredictor[m_channelId] + m_dcDiff);
m_dcPredictor[m_channelId] = m_block[0];
#ifdef _DECODE_LOGGING
CLog::GetInstance().Print(DECODE_LOG_NAME, "[%d]: %d ", 0, m_block[0]);
#endif
m_blockIndex = 1;
m_state = STATE_CHECKEOB;
}
break;
case STATE_CHECKEOB:
{
bool isEob = false;
if(m_coeffTable->TryIsEndOfBlock(m_IN_FIFO, isEob) != CVLCTable::DECODE_STATUS_SUCCESS)
{
return false;
}
if((m_blockIndex != 0) && isEob)
{
m_state = STATE_SKIPEOB;
}
else
{
m_state = STATE_READCOEFF;
}
}
break;
case STATE_READCOEFF:
{
MPEG2::RUNLEVELPAIR runLevelPair;
if(m_blockIndex == 0)
{
if(FilterSymbolError(m_coeffTable->TryGetRunLevelPairDc(m_IN_FIFO, &runLevelPair, m_isMpeg2)) != CVLCTable::DECODE_STATUS_SUCCESS)
{
return false;
}
}
else
{
if(FilterSymbolError(m_coeffTable->TryGetRunLevelPair(m_IN_FIFO, &runLevelPair, m_isMpeg2)) != CVLCTable::DECODE_STATUS_SUCCESS)
{
return false;
}
}
m_blockIndex += runLevelPair.run;
if(m_blockIndex < 0x40)
{
m_block[m_blockIndex] = static_cast<int16>(runLevelPair.level);
#ifdef _DECODE_LOGGING
CLog::GetInstance().Print(DECODE_LOG_NAME, "[%d]: %d ", m_blockIndex, runLevelPair.level);
#endif
}
else
{
throw CVLCTable::CVLCTableException();
}
m_blockIndex++;
m_state = STATE_CHECKEOB;
}
break;
case STATE_SKIPEOB:
if(m_coeffTable->TrySkipEndOfBlock(m_IN_FIFO) != CVLCTable::DECODE_STATUS_SUCCESS)
{
return false;
}
#ifdef _DECODE_LOGGING
CLog::GetInstance().Print(DECODE_LOG_NAME, "\r\n");
#endif
return true;
break;
}
}
}
/////////////////////////////////////////////
//BDEC ReadDcDiff subcommand implementation
/////////////////////////////////////////////
CIPU::CBDECCommand_ReadDcDiff::CBDECCommand_ReadDcDiff()
: m_state(STATE_READSIZE)
, m_result(NULL)
, m_IN_FIFO(NULL)
, m_channelId(0)
, m_dcSize(0)
{
}
void CIPU::CBDECCommand_ReadDcDiff::Initialize(CINFIFO* fifo, unsigned int channelId, int16* result)
{
m_IN_FIFO = fifo;
m_channelId = channelId;
m_state = STATE_READSIZE;
m_dcSize = 0;
m_result = result;
}
bool CIPU::CBDECCommand_ReadDcDiff::Execute()
{
while(1)
{
switch(m_state)
{
case STATE_READSIZE:
{
uint32 dcSize = 0;
switch(m_channelId)
{
case 0:
if(CDcSizeLuminanceTable::GetInstance()->TryGetSymbol(m_IN_FIFO, dcSize) != CVLCTable::DECODE_STATUS_SUCCESS)
{
return false;
}
break;
case 1:
case 2:
if(CDcSizeChrominanceTable::GetInstance()->TryGetSymbol(m_IN_FIFO, dcSize) != CVLCTable::DECODE_STATUS_SUCCESS)
{
return false;
}
break;
}
m_dcSize = dcSize;
m_state = STATE_READDIFF;
}
break;
case STATE_READDIFF:
{
int16 result = 0;
if(m_dcSize == 0)
{
result = 0;
}
else
{
uint32 diffValue = 0;
if(!m_IN_FIFO->TryGetBits_MSBF(m_dcSize, diffValue))
{
return false;
}
int16 halfRange = (1 << (m_dcSize - 1));
result = static_cast<int16>(diffValue);
if(result < halfRange)
{
result = (result + 1) - (2 * halfRange);
}
}
(*m_result) = result;
m_state = STATE_DONE;
}
break;
case STATE_DONE:
return true;
break;
}
}
}
/////////////////////////////////////////////
//VDEC command implementation
/////////////////////////////////////////////
CIPU::CVDECCommand::CVDECCommand()
: m_IN_FIFO(NULL)
, m_state(STATE_ADVANCE)
, m_commandCode(0)
, m_result(NULL)
, m_table(NULL)
{
}
void CIPU::CVDECCommand::Initialize(CINFIFO* fifo, uint32 commandCode, uint32 pictureType, uint32* result)
{
m_IN_FIFO = fifo;
m_commandCode = commandCode;
m_state = STATE_ADVANCE;
m_result = result;
uint32 tbl = (commandCode >> 26) & 0x03;
switch(tbl)
{
case 0:
//Macroblock Address Increment
m_table = CMacroblockAddressIncrementTable::GetInstance();
break;
case 1:
//Macroblock Type
switch(pictureType)
{
case 1:
//I Picture
m_table = CMacroblockTypeITable::GetInstance();
break;
case 2:
//P Picture
m_table = CMacroblockTypePTable::GetInstance();
break;
case 3:
//B Picture
m_table = CMacroblockTypeBTable::GetInstance();
break;
default:
assert(0);
return;
break;
}
break;
case 2:
m_table = CMotionCodeTable::GetInstance();
break;
case 3:
m_table = CDmVectorTable::GetInstance();
break;
default:
assert(0);
return;
break;
}
}
bool CIPU::CVDECCommand::Execute()
{
while(1)
{
switch(m_state)
{
case STATE_ADVANCE:
{
m_IN_FIFO->Advance(static_cast<uint8>(m_commandCode & 0x3F));
m_state = STATE_DECODE;
}
break;
case STATE_DECODE:
{
(*m_result) = m_table->GetSymbol(m_IN_FIFO);
m_state = STATE_DONE;
}
break;
case STATE_DONE:
#ifdef _DECODE_LOGGING
const char* tableName = "unknown";
if(m_table == CMacroblockAddressIncrementTable::GetInstance())
{
tableName = "mb increment";
}
else if(
(m_table == CMacroblockTypeITable::GetInstance()) ||
(m_table == CMacroblockTypePTable::GetInstance()) ||
(m_table == CMacroblockTypeBTable::GetInstance())
)
{
tableName = "mb type";
}
else if(m_table == CMotionCodeTable::GetInstance())
{
tableName = "motion code";
}
else if(m_table == CDmVectorTable::GetInstance())
{
tableName = "dm vector";
}
static unsigned int currentVdec = 0;
CLog::GetInstance().Print(DECODE_LOG_NAME, "Symbol(%d, '%s') = %d\r\n",
currentVdec++, tableName, static_cast<int16>((*m_result) & 0xFFFF));
#endif
return true;
break;
}
}
}
/////////////////////////////////////////////
//FDEC command implementation
/////////////////////////////////////////////
CIPU::CFDECCommand::CFDECCommand()
: m_IN_FIFO(NULL)
, m_state(STATE_ADVANCE)
, m_commandCode(0)
, m_result(NULL)
{
}
void CIPU::CFDECCommand::Initialize(CINFIFO* fifo, uint32 commandCode, uint32* result)
{
m_IN_FIFO = fifo;
m_commandCode = commandCode;
m_state = STATE_ADVANCE;
m_result = result;
}
bool CIPU::CFDECCommand::Execute()
{
while(1)
{
switch(m_state)
{
case STATE_ADVANCE:
{
m_IN_FIFO->Advance(static_cast<uint8>(m_commandCode & 0x3F));
m_state = STATE_DECODE;
}
break;
case STATE_DECODE:
{
if(!m_IN_FIFO->TryPeekBits_MSBF(32, *m_result))
{
return false;
}
m_state = STATE_DONE;
}
break;
case STATE_DONE:
return true;
break;
}
}
}
/////////////////////////////////////////////
//SETIQ command implementation
/////////////////////////////////////////////
CIPU::CSETIQCommand::CSETIQCommand()
: m_IN_FIFO(NULL)
, m_matrix(NULL)
, m_currentIndex(0)
{
}
void CIPU::CSETIQCommand::Initialize(CINFIFO* fifo, uint8* matrix)
{
m_IN_FIFO = fifo;
m_matrix = matrix;
m_currentIndex = 0;
}
bool CIPU::CSETIQCommand::Execute()
{
while(m_currentIndex != 0x40)
{
m_matrix[m_currentIndex] = static_cast<uint8>(m_IN_FIFO->GetBits_MSBF(8));
m_currentIndex++;
}
return true;
}
/////////////////////////////////////////////
//SETVQ command implementation
/////////////////////////////////////////////
CIPU::CSETVQCommand::CSETVQCommand()
: m_IN_FIFO(NULL)
, m_clut(NULL)
, m_currentIndex(0)
{
}
void CIPU::CSETVQCommand::Initialize(CINFIFO* fifo, uint16* clut)
{
m_IN_FIFO = fifo;
m_clut = clut;
m_currentIndex = 0;
}
bool CIPU::CSETVQCommand::Execute()
{
while(m_currentIndex != 0x10)
{
m_clut[m_currentIndex] = static_cast<uint16>(m_IN_FIFO->GetBits_MSBF(16));
m_currentIndex++;
}
return true;
}
/////////////////////////////////////////////
//CSC command implementation
/////////////////////////////////////////////
CIPU::CCSCCommand::CCSCCommand()
{
GenerateCbCrMap();
}
void CIPU::CCSCCommand::Initialize(CINFIFO* input, COUTFIFO* output, uint32 commandCode, uint16 TH0, uint16 TH1)
{
m_command <<= commandCode;
assert(m_command.cmdId == IPU_CMD_CSC);
m_state = STATE_READBLOCKSTART;
m_IN_FIFO = input;
m_OUT_FIFO = output;
m_TH0 = TH0;
m_TH1 = TH1;
m_currentIndex = 0;
m_mbCount = m_command.mbc;
}
bool CIPU::CCSCCommand::Execute()
{
while(1)
{
switch(m_state)
{
case STATE_READBLOCKSTART:
{
if(m_mbCount == 0)
{
m_state = STATE_DONE;
}
else
{
m_state = STATE_READBLOCK;
m_currentIndex = 0;
}
}
break;
case STATE_READBLOCK:
{
if(m_currentIndex == BLOCK_SIZE)
{
m_state = STATE_CONVERTBLOCK;
}
else
{
uint32 blockValue = 0;
if(!m_IN_FIFO->TryGetBits_MSBF(8, blockValue))
{
return false;
}
m_block[m_currentIndex] = static_cast<uint8>(blockValue);
m_currentIndex++;
}
}
break;
case STATE_CONVERTBLOCK:
{
uint32 nPixel[0x100];
uint8* pY = m_block;
uint8* nBlockCb = m_block + 0x100;
uint8* nBlockCr = m_block + 0x140;
uint32* pPixel = nPixel;
unsigned int* pCbCrMap = m_nCbCrMap;
uint32 alphaTh0 = (m_TH0 & 0xFF) | ((m_TH0 & 0xFF) << 8) | ((m_TH0 & 0xFF) << 16);
uint32 alphaTh1 = (m_TH1 & 0xFF) | ((m_TH1 & 0xFF) << 8) | ((m_TH1 & 0xFF) << 16);
for(unsigned int i = 0; i < 16; i++)
{
for(unsigned int j = 0; j < 16; j++)
{
float nY = pY[j];
float nCb = nBlockCb[pCbCrMap[j]];
float nCr = nBlockCr[pCbCrMap[j]];
//nY = nBlockCb[pCbCrMap[j]];
//nCb = 128;
//nCr = 128;
float nR = nY + 1.402f * (nCr - 128);
float nG = nY - 0.34414f * (nCb - 128) - 0.71414f * (nCr - 128);
float nB = nY + 1.772f * (nCb - 128);
if(nR < 0) { nR = 0; } if(nR > 255) { nR = 255; }
if(nG < 0) { nG = 0; } if(nG > 255) { nG = 255; }
if(nB < 0) { nB = 0; } if(nB > 255) { nB = 255; }
uint8 a = 0;
uint32 rgb = (static_cast<uint8>(nB) << 16) | (static_cast<uint8>(nG) << 8) | (static_cast<uint8>(nR) << 0);
if(rgb < alphaTh0)
{
a = 0;
}
else if(rgb < alphaTh1)
{
a = 0x40;
}
else
{
a = 0x80;
}
pPixel[j] = (a << 24) | rgb;
}
pY += 0x10;
pCbCrMap += 0x10;
pPixel += 0x10;
}
m_OUT_FIFO->Write(nPixel, sizeof(uint32) * 0x100);
m_mbCount--;
m_state = STATE_FLUSHBLOCK;
}
break;
case STATE_FLUSHBLOCK:
{
m_OUT_FIFO->Flush();
if(m_OUT_FIFO->GetSize() != 0)
{
return false;
}
m_state = STATE_READBLOCKSTART;
}
break;
case STATE_DONE:
return true;
break;
}
}
}
void CIPU::CCSCCommand::GenerateCbCrMap()
{
unsigned int* pCbCrMap = m_nCbCrMap;
for(unsigned int i = 0; i < 0x40; i += 0x8)
{
for(unsigned int j = 0; j < 0x10; j += 2)
{
pCbCrMap[j + 0x00] = (j / 2) + i;
pCbCrMap[j + 0x01] = (j / 2) + i;
pCbCrMap[j + 0x10] = (j / 2) + i;
pCbCrMap[j + 0x11] = (j / 2) + i;
}
pCbCrMap += 0x20;
}
}
/////////////////////////////////////////////
//SETTH command implementation
/////////////////////////////////////////////
CIPU::CSETTHCommand::CSETTHCommand()
: m_commandCode(0)
, m_TH0(NULL)
, m_TH1(NULL)
{
}
void CIPU::CSETTHCommand::Initialize(uint32 commandCode, uint16* TH0, uint16* TH1)
{
m_commandCode = commandCode;
m_TH0 = TH0;
m_TH1 = TH1;
}
bool CIPU::CSETTHCommand::Execute()
{
(*m_TH0) = static_cast<uint16>((m_commandCode >> 0) & 0x1FF);
(*m_TH1) = static_cast<uint16>((m_commandCode >> 16) & 0x1FF);
return true;
}