public ModelPPM()
{
InitBlock();
minContext = null;
maxContext = null;
//medContext = null;
}
public ModelPPM()
{
InitBlock();
minContext = null;
maxContext = null;
//medContext = null;
}
private SEE2Context makeEscFreq2(ModelPPM model, int Diff)
{
SEE2Context psee2c;
int numStats = NumStats;
if (numStats != 256)
{
PPMContext suff = getTempPPMContext(model.Heap);
suff.Address = getSuffix();
int idx1 = model.getNS2Indx()[Diff - 1];
int idx2 = 0;
idx2 += ((Diff < suff.NumStats - numStats) ? 1 : 0);
idx2 += 2 * ((freqData.SummFreq < 11 * numStats) ? 1 : 0);
idx2 += 4 * ((model.NumMasked > Diff) ? 1 : 0);
idx2 += model.HiBitsFlag;
psee2c = model.getSEE2Cont()[idx1][idx2];
model.Coder.SubRange.Scale = psee2c.Mean;
}
else
{
psee2c = model.DummySEE2Cont;
model.Coder.SubRange.Scale = 1;
}
return(psee2c);
}
private PPMContext getTempPPMContext(byte[] Memory)
{
if (tempPPMContext == null)
{
tempPPMContext = new PPMContext(null);
}
return(tempPPMContext.Initialize(Memory));
}
internal bool decodeInit(Unpack unpackRead, int escChar)
{
int MaxOrder = unpackRead.Char & 0xff;
bool reset = ((MaxOrder & 0x20) != 0);
int MaxMB = 0;
if (reset)
{
MaxMB = unpackRead.Char;
}
else
{
if (subAlloc.GetAllocatedMemory() == 0)
{
return(false);
}
}
if ((MaxOrder & 0x40) != 0)
{
escChar = unpackRead.Char;
unpackRead.PpmEscChar = escChar;
}
coder = new RangeCoder(unpackRead);
if (reset)
{
MaxOrder = (MaxOrder & 0x1f) + 1;
if (MaxOrder > 16)
{
MaxOrder = 16 + (MaxOrder - 16) * 3;
}
if (MaxOrder == 1)
{
subAlloc.stopSubAllocator();
return(false);
}
subAlloc.startSubAllocator(MaxMB + 1);
minContext = new PPMContext(Heap);
//medContext = new PPMContext(Heap);
maxContext = new PPMContext(Heap);
foundState = new State(Heap);
dummySEE2Cont = new SEE2Context();
for (int i = 0; i < 25; i++)
{
for (int j = 0; j < 16; j++)
{
SEE2Cont[i][j] = new SEE2Context();
}
}
startModelRare(MaxOrder);
}
return(minContext.Address != 0);
}
private int getArrayIndex(ModelPPM Model, State rs)
{
PPMContext tempSuffix = getTempPPMContext(Model.SubAlloc.Heap);
tempSuffix.Address = getSuffix();
int ret = 0;
ret += Model.PrevSuccess;
ret += Model.getNS2BSIndx()[tempSuffix.NumStats - 1];
ret += Model.HiBitsFlag + 2 * Model.getHB2Flag()[rs.Symbol];
ret += ((Utility.URShift(Model.RunLength, 26)) & 0x20);
return(ret);
}
internal int createChild(ModelPPM model, State pStats, StateRef firstState)
{
PPMContext pc = getTempPPMContext(model.SubAlloc.Heap);
pc.Address = model.SubAlloc.allocContext();
if (pc != null)
{
pc.NumStats = 1;
pc.setOneState(firstState);
pc.setSuffix(this);
pStats.SetSuccessor(pc);
}
return(pc.Address);
}
public virtual void SetSuccessor(PPMContext successor)
{
SetSuccessor(successor.Address);
}
internal void SetSuccessor(PPMContext successor)
{
SetSuccessor(successor.Address);
}
internal bool decodeInit(Unpack unpackRead, int escChar)
{
int MaxOrder = unpackRead.Char & 0xff;
bool reset = ((MaxOrder & 0x20) != 0);
int MaxMB = 0;
if (reset)
{
MaxMB = unpackRead.Char;
}
else
{
if (subAlloc.GetAllocatedMemory() == 0)
{
return (false);
}
}
if ((MaxOrder & 0x40) != 0)
{
escChar = unpackRead.Char;
unpackRead.PpmEscChar = escChar;
}
coder = new RangeCoder(unpackRead);
if (reset)
{
MaxOrder = (MaxOrder & 0x1f) + 1;
if (MaxOrder > 16)
{
MaxOrder = 16 + (MaxOrder - 16) * 3;
}
if (MaxOrder == 1)
{
subAlloc.stopSubAllocator();
return (false);
}
subAlloc.startSubAllocator(MaxMB + 1);
minContext = new PPMContext(Heap);
//medContext = new PPMContext(Heap);
maxContext = new PPMContext(Heap);
foundState = new State(Heap);
dummySEE2Cont = new SEE2Context();
for (int i = 0; i < 25; i++)
{
for (int j = 0; j < 16; j++)
{
SEE2Cont[i][j] = new SEE2Context();
}
}
startModelRare(MaxOrder);
}
return (minContext.Address != 0);
}
private PPMContext getTempPPMContext(byte[] Memory)
{
if (tempPPMContext == null)
{
tempPPMContext = new PPMContext(null);
}
return tempPPMContext.Initialize(Memory);
}
internal void setSuffix(PPMContext suffix)
{
setSuffix(suffix.Address);
}
private int createSuccessors(bool Skip, State p1)
{
//State upState = tempState1.Initialize(null);
StateRef upState = tempStateRef2;
State tempState = tempState1.Initialize(Heap);
// PPM_CONTEXT* pc=MinContext, * UpBranch=FoundState->Successor;
PPMContext pc = tempPPMContext1.Initialize(Heap);
pc.Address = minContext.Address;
PPMContext upBranch = tempPPMContext2.Initialize(Heap);
upBranch.Address = foundState.GetSuccessor();
// STATE * p, * ps[MAX_O], ** pps=ps;
State p = tempState2.Initialize(Heap);
int pps = 0;
bool noLoop = false;
if (!Skip)
{
ps[pps++] = foundState.Address; // *pps++ = FoundState;
if (pc.getSuffix() == 0)
{
noLoop = true;
}
}
if (!noLoop)
{
bool loopEntry = false;
if (p1.Address != 0)
{
p.Address = p1.Address;
pc.Address = pc.getSuffix(); // =pc->Suffix;
loopEntry = true;
}
do
{
if (!loopEntry)
{
pc.Address = pc.getSuffix(); // pc=pc->Suffix;
if (pc.NumStats != 1)
{
p.Address = pc.FreqData.GetStats(); // p=pc->U.Stats
if (p.Symbol != foundState.Symbol)
{
do
{
p.IncrementAddress();
}while (p.Symbol != foundState.Symbol);
}
}
else
{
p.Address = pc.getOneState().Address; // p=&(pc->OneState);
}
} // LOOP_ENTRY:
loopEntry = false;
if (p.GetSuccessor() != upBranch.Address)
{
pc.Address = p.GetSuccessor(); // =p->Successor;
break;
}
ps[pps++] = p.Address;
}while (pc.getSuffix() != 0);
} // NO_LOOP:
if (pps == 0)
{
return(pc.Address);
}
upState.Symbol = Heap[upBranch.Address]; // UpState.Symbol=*(byte*)
// UpBranch;
// UpState.Successor=(PPM_CONTEXT*) (((byte*) UpBranch)+1);
upState.SetSuccessor(upBranch.Address + 1); //TODO check if +1 necessary
if (pc.NumStats != 1)
{
if (pc.Address <= subAlloc.PText)
{
return(0);
}
p.Address = pc.FreqData.GetStats();
if (p.Symbol != upState.Symbol)
{
do
{
p.IncrementAddress();
}while (p.Symbol != upState.Symbol);
}
int cf = p.Freq - 1;
int s0 = pc.FreqData.SummFreq - pc.NumStats - cf;
// UpState.Freq=1+((2*cf <= s0)?(5*cf > s0):((2*cf+3*s0-1)/(2*s0)));
upState.Freq = 1 + ((2 * cf <= s0) ? (5 * cf > s0 ? 1 : 0) : ((2 * cf + 3 * s0 - 1) / (2 * s0)));
}
else
{
upState.Freq = pc.getOneState().Freq; // UpState.Freq=pc->OneState.Freq;
}
do
{
// pc = pc->createChild(this,*--pps,UpState);
tempState.Address = ps[--pps];
pc.Address = pc.createChild(this, tempState, upState);
if (pc.Address == 0)
{
return(0);
}
}while (pps != 0);
return(pc.Address);
}
internal void SetSuccessor(PPMContext successor)
{
SetSuccessor(successor.Address);
}
private void updateModel()
{
//System.out.println("ModelPPM.updateModel()");
// STATE fs = *FoundState, *p = NULL;
StateRef fs = tempStateRef1;
fs.Values = foundState;
State p = tempState3.Initialize(Heap);
State tempState = tempState4.Initialize(Heap);
PPMContext pc = tempPPMContext3.Initialize(Heap);
PPMContext successor = tempPPMContext4.Initialize(Heap);
int ns1, ns, cf, sf, s0;
pc.Address = minContext.getSuffix();
if (fs.Freq < MAX_FREQ / 4 && pc.Address != 0)
{
if (pc.NumStats != 1)
{
p.Address = pc.FreqData.GetStats();
if (p.Symbol != fs.Symbol)
{
do
{
p.IncrementAddress();
}while (p.Symbol != fs.Symbol);
tempState.Address = p.Address - State.Size;
if (p.Freq >= tempState.Freq)
{
State.PPMDSwap(p, tempState);
p.DecrementAddress();
}
}
if (p.Freq < MAX_FREQ - 9)
{
p.IncrementFreq(2);
pc.FreqData.IncrementSummFreq(2);
}
}
else
{
p.Address = pc.getOneState().Address;
if (p.Freq < 32)
{
p.IncrementFreq(1);
}
}
}
if (orderFall == 0)
{
foundState.SetSuccessor(createSuccessors(true, p));
minContext.Address = foundState.GetSuccessor();
maxContext.Address = foundState.GetSuccessor();
if (minContext.Address == 0)
{
updateModelRestart();
return;
}
return;
}
subAlloc.Heap[subAlloc.PText] = (byte)fs.Symbol;
subAlloc.incPText();
successor.Address = subAlloc.PText;
if (subAlloc.PText >= subAlloc.FakeUnitsStart)
{
updateModelRestart();
return;
}
// // Debug
// subAlloc.dumpHeap();
if (fs.GetSuccessor() != 0)
{
if (fs.GetSuccessor() <= subAlloc.PText)
{
fs.SetSuccessor(createSuccessors(false, p));
if (fs.GetSuccessor() == 0)
{
updateModelRestart();
return;
}
}
if (--orderFall == 0)
{
successor.Address = fs.GetSuccessor();
if (maxContext.Address != minContext.Address)
{
subAlloc.decPText(1);
}
}
}
else
{
foundState.SetSuccessor(successor.Address);
fs.SetSuccessor(minContext);
}
// // Debug
// subAlloc.dumpHeap();
ns = minContext.NumStats;
s0 = minContext.FreqData.SummFreq - (ns) - (fs.Freq - 1);
for (pc.Address = maxContext.Address; pc.Address != minContext.Address; pc.Address = pc.getSuffix())
{
if ((ns1 = pc.NumStats) != 1)
{
if ((ns1 & 1) == 0)
{
//System.out.println(ns1);
pc.FreqData.SetStats(subAlloc.expandUnits(pc.FreqData.GetStats(), Utility.URShift(ns1, 1)));
if (pc.FreqData.GetStats() == 0)
{
updateModelRestart();
return;
}
}
// bug fixed
// int sum = ((2 * ns1 < ns) ? 1 : 0) +
// 2 * ((4 * ((ns1 <= ns) ? 1 : 0)) & ((pc.getFreqData()
// .getSummFreq() <= 8 * ns1) ? 1 : 0));
int sum = ((2 * ns1 < ns) ? 1 : 0) + 2 * (((4 * ns1 <= ns) ? 1 : 0) & ((pc.FreqData.SummFreq <= 8 * ns1) ? 1 : 0));
pc.FreqData.IncrementSummFreq(sum);
}
else
{
p.Address = subAlloc.allocUnits(1);
if (p.Address == 0)
{
updateModelRestart();
return;
}
p.SetValues(pc.getOneState());
pc.FreqData.SetStats(p);
if (p.Freq < MAX_FREQ / 4 - 1)
{
p.IncrementFreq(p.Freq);
}
else
{
p.Freq = MAX_FREQ - 4;
}
pc.FreqData.SummFreq = (p.Freq + initEsc + (ns > 3 ? 1 : 0));
}
cf = 2 * fs.Freq * (pc.FreqData.SummFreq + 6);
sf = s0 + pc.FreqData.SummFreq;
if (cf < 6 * sf)
{
cf = 1 + (cf > sf ? 1 : 0) + (cf >= 4 * sf ? 1 : 0);
pc.FreqData.IncrementSummFreq(3);
}
else
{
cf = 4 + (cf >= 9 * sf ? 1 : 0) + (cf >= 12 * sf ? 1 : 0) + (cf >= 15 * sf ? 1 : 0);
pc.FreqData.IncrementSummFreq(cf);
}
p.Address = pc.FreqData.GetStats() + ns1 * State.Size;
p.SetSuccessor(successor);
p.Symbol = fs.Symbol;
p.Freq = cf;
pc.NumStats = ++ns1;
}
int address = fs.GetSuccessor();
maxContext.Address = address;
minContext.Address = address;
//TODO-----debug
// int pos = minContext.getFreqData().getStats();
// State a = new State(getHeap());
// a.Address=pos);
// pos+=State.size;
// a.Address=pos);
//--dbg end
return;
}
public virtual void SetSuccessor(PPMContext successor)
{
SetSuccessor(successor.Address);
}
internal void setSuffix(PPMContext suffix)
{
setSuffix(suffix.Address);
}
