hashcat/deps/unrar/unpack20.cpp

#include "rar.hpp"

void Unpack::CopyString20(uint Length,uint Distance)
{
  LastDist=OldDist[OldDistPtr++]=Distance;
  OldDistPtr = OldDistPtr & 3; // Needed if RAR 1.5 file is called after RAR 2.0.
  LastLength=Length;
  DestUnpSize-=Length;
  CopyString(Length,Distance);
}


void Unpack::Unpack20(bool Solid)
{
  static unsigned char LDecode[]={0,1,2,3,4,5,6,7,8,10,12,14,16,20,24,28,32,40,48,56,64,80,96,112,128,160,192,224};
  static unsigned char LBits[]=  {0,0,0,0,0,0,0,0,1, 1, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3, 4, 4, 4,  4,  5,  5,  5,  5};
  static uint DDecode[]={0,1,2,3,4,6,8,12,16,24,32,48,64,96,128,192,256,384,512,768,1024,1536,2048,3072,4096,6144,8192,12288,16384,24576,32768U,49152U,65536,98304,131072,196608,262144,327680,393216,458752,524288,589824,655360,720896,786432,851968,917504,983040};
  static unsigned char DBits[]=  {0,0,0,0,1,1,2, 2, 3, 3, 4, 4, 5, 5,  6,  6,  7,  7,  8,  8,   9,   9,  10,  10,  11,  11,  12,   12,   13,   13,    14,    14,   15,   15,    16,    16,    16,    16,    16,    16,    16,    16,    16,    16,    16,    16,    16,    16};
  static unsigned char SDDecode[]={0,4,8,16,32,64,128,192};
  static unsigned char SDBits[]=  {2,2,3, 4, 5, 6,  6,  6};
  uint Bits;

  if (Suspended)
    UnpPtr=WrPtr;
  else
  {
    UnpInitData(Solid);
    if (!UnpReadBuf())
      return;
    if ((!Solid || !TablesRead2) && !ReadTables20())
      return;
    --DestUnpSize;
  }

  while (DestUnpSize>=0)
  {
    UnpPtr&=MaxWinMask;

    if (Inp.InAddr>ReadTop-30)
      if (!UnpReadBuf())
        break;
    if (((WrPtr-UnpPtr) & MaxWinMask)<270 && WrPtr!=UnpPtr)
    {
      UnpWriteBuf20();
      if (Suspended)
        return;
    }
    if (UnpAudioBlock)
    {
      uint AudioNumber=DecodeNumber(Inp,&MD[UnpCurChannel]);

      if (AudioNumber==256)
      {
        if (!ReadTables20())
          break;
        continue;
      }
      Window[UnpPtr++]=DecodeAudio((int)AudioNumber);
      if (++UnpCurChannel==UnpChannels)
        UnpCurChannel=0;
      --DestUnpSize;
      continue;
    }

    uint Number=DecodeNumber(Inp,&BlockTables.LD);
    if (Number<256)
    {
      Window[UnpPtr++]=(byte)Number;
      --DestUnpSize;
      continue;
    }
    if (Number>269)
    {
      uint Length=LDecode[Number-=270]+3;
      if ((Bits=LBits[Number])>0)
      {
        Length+=Inp.getbits()>>(16-Bits);
        Inp.addbits(Bits);
      }

      uint DistNumber=DecodeNumber(Inp,&BlockTables.DD);
      uint Distance=DDecode[DistNumber]+1;
      if ((Bits=DBits[DistNumber])>0)
      {
        Distance+=Inp.getbits()>>(16-Bits);
        Inp.addbits(Bits);
      }

      if (Distance>=0x2000)
      {
        Length++;
        if (Distance>=0x40000L)
          Length++;
      }

      CopyString20(Length,Distance);
      continue;
    }
    if (Number==269)
    {
      if (!ReadTables20())
        break;
      continue;
    }
    if (Number==256)
    {
      CopyString20(LastLength,LastDist);
      continue;
    }
    if (Number<261)
    {
      uint Distance=OldDist[(OldDistPtr-(Number-256)) & 3];
      uint LengthNumber=DecodeNumber(Inp,&BlockTables.RD);
      uint Length=LDecode[LengthNumber]+2;
      if ((Bits=LBits[LengthNumber])>0)
      {
        Length+=Inp.getbits()>>(16-Bits);
        Inp.addbits(Bits);
      }
      if (Distance>=0x101)
      {
        Length++;
        if (Distance>=0x2000)
        {
          Length++;
          if (Distance>=0x40000)
            Length++;
        }
      }
      CopyString20(Length,Distance);
      continue;
    }
    if (Number<270)
    {
      uint Distance=SDDecode[Number-=261]+1;
      if ((Bits=SDBits[Number])>0)
      {
        Distance+=Inp.getbits()>>(16-Bits);
        Inp.addbits(Bits);
      }
      CopyString20(2,Distance);
      continue;
   }
  }
  ReadLastTables();
  UnpWriteBuf20();
}


void Unpack::UnpWriteBuf20()
{
  if (UnpPtr!=WrPtr)
    UnpSomeRead=true;
  if (UnpPtr<WrPtr)
  {
    UnpIO->UnpWrite(&Window[WrPtr],-(int)WrPtr & MaxWinMask);
    UnpIO->UnpWrite(Window,UnpPtr);
    UnpAllBuf=true;
  }
  else
    UnpIO->UnpWrite(&Window[WrPtr],UnpPtr-WrPtr);
  WrPtr=UnpPtr;
}


bool Unpack::ReadTables20()
{
  byte BitLength[BC20];
  byte Table[MC20*4];
  if (Inp.InAddr>ReadTop-25)
    if (!UnpReadBuf())
      return false;
  uint BitField=Inp.getbits();
  UnpAudioBlock=(BitField & 0x8000)!=0;

  if (!(BitField & 0x4000))
    memset(UnpOldTable20,0,sizeof(UnpOldTable20));
  Inp.addbits(2);

  uint TableSize;
  if (UnpAudioBlock)
  {
    UnpChannels=((BitField>>12) & 3)+1;
    if (UnpCurChannel>=UnpChannels)
      UnpCurChannel=0;
    Inp.addbits(2);
    TableSize=MC20*UnpChannels;
  }
  else
    TableSize=NC20+DC20+RC20;

  for (uint I=0;I<BC20;I++)
  {
    BitLength[I]=(byte)(Inp.getbits() >> 12);
    Inp.addbits(4);
  }
  MakeDecodeTables(BitLength,&BlockTables.BD,BC20);
  for (uint I=0;I<TableSize;)
  {
    if (Inp.InAddr>ReadTop-5)
      if (!UnpReadBuf())
        return false;
    uint Number=DecodeNumber(Inp,&BlockTables.BD);
    if (Number<16)
    {
      Table[I]=(Number+UnpOldTable20[I]) & 0xf;
      I++;
    }
    else
      if (Number==16)
      {
        uint N=(Inp.getbits() >> 14)+3;
        Inp.addbits(2);
        if (I==0)
          return false; // We cannot have "repeat previous" code at the first position.
        else
          while (N-- > 0 && I<TableSize)
          {
            Table[I]=Table[I-1];
            I++;
          }
      }
      else
      {
        uint N;
        if (Number==17)
        {
          N=(Inp.getbits() >> 13)+3;
          Inp.addbits(3);
        }
        else
        {
          N=(Inp.getbits() >> 9)+11;
          Inp.addbits(7);
        }
        while (N-- > 0 && I<TableSize)
          Table[I++]=0;
      }
  }
  TablesRead2=true;
  if (Inp.InAddr>ReadTop)
    return true;
  if (UnpAudioBlock)
    for (uint I=0;I<UnpChannels;I++)
      MakeDecodeTables(&Table[I*MC20],&MD[I],MC20);
  else
  {
    MakeDecodeTables(&Table[0],&BlockTables.LD,NC20);
    MakeDecodeTables(&Table[NC20],&BlockTables.DD,DC20);
    MakeDecodeTables(&Table[NC20+DC20],&BlockTables.RD,RC20);
  }
  memcpy(UnpOldTable20,Table,TableSize);
  return true;
}


void Unpack::ReadLastTables()
{
  if (ReadTop>=Inp.InAddr+5)
    if (UnpAudioBlock)
    {
      if (DecodeNumber(Inp,&MD[UnpCurChannel])==256)
        ReadTables20();
    }
    else
      if (DecodeNumber(Inp,&BlockTables.LD)==269)
        ReadTables20();
}


void Unpack::UnpInitData20(int Solid)
{
  if (!Solid)
  {
    TablesRead2=false;
    UnpAudioBlock=false;
    UnpChannelDelta=0;
    UnpCurChannel=0;
    UnpChannels=1;

    memset(AudV,0,sizeof(AudV));
    memset(UnpOldTable20,0,sizeof(UnpOldTable20));
    memset(MD,0,sizeof(MD));
  }
}


byte Unpack::DecodeAudio(int Delta)
{
  struct AudioVariables *V=&AudV[UnpCurChannel];
  V->ByteCount++;
  V->D4=V->D3;
  V->D3=V->D2;
  V->D2=V->LastDelta-V->D1;
  V->D1=V->LastDelta;
  int PCh=8*V->LastChar+V->K1*V->D1+V->K2*V->D2+V->K3*V->D3+V->K4*V->D4+V->K5*UnpChannelDelta;
  PCh=(PCh>>3) & 0xFF;

  uint Ch=PCh-Delta;

  int D=(signed char)Delta;
  // Left shift of negative value is undefined behavior in C++,
  // so we cast it to unsigned to follow the standard.
  D=(uint)D<<3;

  V->Dif[0]+=abs(D);
  V->Dif[1]+=abs(D-V->D1);
  V->Dif[2]+=abs(D+V->D1);
  V->Dif[3]+=abs(D-V->D2);
  V->Dif[4]+=abs(D+V->D2);
  V->Dif[5]+=abs(D-V->D3);
  V->Dif[6]+=abs(D+V->D3);
  V->Dif[7]+=abs(D-V->D4);
  V->Dif[8]+=abs(D+V->D4);
  V->Dif[9]+=abs(D-UnpChannelDelta);
  V->Dif[10]+=abs(D+UnpChannelDelta);

  UnpChannelDelta=V->LastDelta=(signed char)(Ch-V->LastChar);
  V->LastChar=Ch;

  if ((V->ByteCount & 0x1F)==0)
  {
    uint MinDif=V->Dif[0],NumMinDif=0;
    V->Dif[0]=0;
    for (uint I=1;I<ASIZE(V->Dif);I++)
    {
      if (V->Dif[I]<MinDif)
      {
        MinDif=V->Dif[I];
        NumMinDif=I;
      }
      V->Dif[I]=0;
    }
    switch(NumMinDif)
    {
      case 1:
        if (V->K1>=-16)
          V->K1--;
        break;
      case 2:
        if (V->K1<16)
          V->K1++;
        break;
      case 3:
        if (V->K2>=-16)
          V->K2--;
        break;
      case 4:
        if (V->K2<16)
          V->K2++;
        break;
      case 5:
        if (V->K3>=-16)
          V->K3--;
        break;
      case 6:
        if (V->K3<16)
          V->K3++;
        break;
      case 7:
        if (V->K4>=-16)
          V->K4--;
        break;
      case 8:
        if (V->K4<16)
          V->K4++;
        break;
      case 9:
        if (V->K5>=-16)
          V->K5--;
        break;
      case 10:
        if (V->K5<16)
          V->K5++;
        break;
    }
  }
  return (byte)Ch;
}