// Decompiled with JetBrains decompiler // Type: SevenZip.Compression.LZMA.Encoder // Assembly: crypted, Version=1.0.0.0, Culture=neutral, PublicKeyToken=null // MVID: 316F25AB-9DC5-41B1-B1CB-0BB9D97AEA6A // Assembly location: C:\Users\Administrateur\Downloads\Virusshare-00000-msil\Trojan-Ransom.Win32.Gimemo.ayt-7cb020d260d835f80919399a58563918f73757689e39ba851e89cc00a05535da.exe using SevenZip.Compression.LZ; using SevenZip.Compression.RangeCoder; using System; using System.IO; namespace SevenZip.Compression.LZMA { public class Encoder : ICoder, ISetCoderProperties, IWriteCoderProperties { private const uint kIfinityPrice = 268435455; private const int kDefaultDictionaryLogSize = 22; private const uint kNumFastBytesDefault = 32; private const uint kNumLenSpecSymbols = 16; private const uint kNumOpts = 4096; private const int kPropSize = 5; private static byte[] g_FastPos = new byte[2048]; private Base.State _state = new Base.State(); private byte _previousByte; private uint[] _repDistances = new uint[new IntPtr(4)]; private Encoder.Optimal[] _optimum = new Encoder.Optimal[new IntPtr(4096)]; private IMatchFinder _matchFinder; private SevenZip.Compression.RangeCoder.Encoder _rangeEncoder = new SevenZip.Compression.RangeCoder.Encoder(); private BitEncoder[] _isMatch = new BitEncoder[new IntPtr(192)]; private BitEncoder[] _isRep = new BitEncoder[new IntPtr(12)]; private BitEncoder[] _isRepG0 = new BitEncoder[new IntPtr(12)]; private BitEncoder[] _isRepG1 = new BitEncoder[new IntPtr(12)]; private BitEncoder[] _isRepG2 = new BitEncoder[new IntPtr(12)]; private BitEncoder[] _isRep0Long = new BitEncoder[new IntPtr(192)]; private BitTreeEncoder[] _posSlotEncoder = new BitTreeEncoder[new IntPtr(4)]; private BitEncoder[] _posEncoders = new BitEncoder[new IntPtr(114)]; private BitTreeEncoder _posAlignEncoder = new BitTreeEncoder(4); private Encoder.LenPriceTableEncoder _lenEncoder = new Encoder.LenPriceTableEncoder(); private Encoder.LenPriceTableEncoder _repMatchLenEncoder = new Encoder.LenPriceTableEncoder(); private Encoder.LiteralEncoder _literalEncoder = new Encoder.LiteralEncoder(); private uint[] _matchDistances = new uint[new IntPtr(548)]; private uint _numFastBytes = 32; private uint _longestMatchLength; private uint _numDistancePairs; private uint _additionalOffset; private uint _optimumEndIndex; private uint _optimumCurrentIndex; private bool _longestMatchWasFound; private uint[] _posSlotPrices = new uint[256]; private uint[] _distancesPrices = new uint[new IntPtr(512)]; private uint[] _alignPrices = new uint[new IntPtr(16)]; private uint _alignPriceCount; private uint _distTableSize = 44; private int _posStateBits = 2; private uint _posStateMask = 3; private int _numLiteralPosStateBits; private int _numLiteralContextBits = 3; private uint _dictionarySize = 4194304; private uint _dictionarySizePrev = uint.MaxValue; private uint _numFastBytesPrev = uint.MaxValue; private long nowPos64; private bool _finished; private Stream _inStream; private Encoder.EMatchFinderType _matchFinderType = Encoder.EMatchFinderType.BT4; private bool _writeEndMark; private bool _needReleaseMFStream; private uint[] reps = new uint[new IntPtr(4)]; private uint[] repLens = new uint[new IntPtr(4)]; private byte[] properties = new byte[5]; private uint[] tempPrices = new uint[new IntPtr(128)]; private uint _matchPriceCount; private static string[] kMatchFinderIDs = new string[2] { "BT2", "BT4" }; private uint _trainSize; static Encoder() { int index1 = 2; Encoder.g_FastPos[0] = (byte) 0; Encoder.g_FastPos[1] = (byte) 1; for (byte index2 = 2; index2 < (byte) 22; ++index2) { uint num1 = (uint) (1 << ((int) index2 >> 1) - 1); uint num2 = 0; while (num2 < num1) { Encoder.g_FastPos[index1] = index2; ++num2; ++index1; } } } private static uint GetPosSlot(uint pos) { if (pos < 2048U) return (uint) Encoder.g_FastPos[(IntPtr) pos]; return pos < 2097152U ? (uint) Encoder.g_FastPos[(IntPtr) (pos >> 10)] + 20U : (uint) Encoder.g_FastPos[(IntPtr) (pos >> 20)] + 40U; } private static uint GetPosSlot2(uint pos) { if (pos < 131072U) return (uint) Encoder.g_FastPos[(IntPtr) (pos >> 6)] + 12U; return pos < 134217728U ? (uint) Encoder.g_FastPos[(IntPtr) (pos >> 16)] + 32U : (uint) Encoder.g_FastPos[(IntPtr) (pos >> 26)] + 52U; } private void BaseInit() { this._state.Init(); this._previousByte = (byte) 0; for (uint index = 0; index < 4U; ++index) this._repDistances[(IntPtr) index] = 0U; } private void Create() { if (this._matchFinder == null) { BinTree binTree = new BinTree(); int numHashBytes = 4; if (this._matchFinderType == Encoder.EMatchFinderType.BT2) numHashBytes = 2; binTree.SetType(numHashBytes); this._matchFinder = (IMatchFinder) binTree; } this._literalEncoder.Create(this._numLiteralPosStateBits, this._numLiteralContextBits); if ((int) this._dictionarySize == (int) this._dictionarySizePrev && (int) this._numFastBytesPrev == (int) this._numFastBytes) return; this._matchFinder.Create(this._dictionarySize, 4096U, this._numFastBytes, 274U); this._dictionarySizePrev = this._dictionarySize; this._numFastBytesPrev = this._numFastBytes; } public Encoder() { for (int index = 0; index < 4096; ++index) this._optimum[index] = new Encoder.Optimal(); for (int index = 0; index < 4; ++index) this._posSlotEncoder[index] = new BitTreeEncoder(6); } private void SetWriteEndMarkerMode(bool writeEndMarker) => this._writeEndMark = writeEndMarker; private void Init() { this.BaseInit(); this._rangeEncoder.Init(); for (uint index1 = 0; index1 < 12U; ++index1) { for (uint index2 = 0; index2 <= this._posStateMask; ++index2) { uint index3 = (index1 << 4) + index2; this._isMatch[(IntPtr) index3].Init(); this._isRep0Long[(IntPtr) index3].Init(); } this._isRep[(IntPtr) index1].Init(); this._isRepG0[(IntPtr) index1].Init(); this._isRepG1[(IntPtr) index1].Init(); this._isRepG2[(IntPtr) index1].Init(); } this._literalEncoder.Init(); for (uint index = 0; index < 4U; ++index) this._posSlotEncoder[(IntPtr) index].Init(); for (uint index = 0; index < 114U; ++index) this._posEncoders[(IntPtr) index].Init(); this._lenEncoder.Init((uint) (1 << this._posStateBits)); this._repMatchLenEncoder.Init((uint) (1 << this._posStateBits)); this._posAlignEncoder.Init(); this._longestMatchWasFound = false; this._optimumEndIndex = 0U; this._optimumCurrentIndex = 0U; this._additionalOffset = 0U; } private void ReadMatchDistances(out uint lenRes, out uint numDistancePairs) { lenRes = 0U; numDistancePairs = this._matchFinder.GetMatches(this._matchDistances); if (numDistancePairs > 0U) { lenRes = this._matchDistances[(IntPtr) (numDistancePairs - 2U)]; if ((int) lenRes == (int) this._numFastBytes) lenRes += this._matchFinder.GetMatchLen((int) lenRes - 1, this._matchDistances[(IntPtr) (numDistancePairs - 1U)], 273U - lenRes); } ++this._additionalOffset; } private void MovePos(uint num) { if (num <= 0U) return; this._matchFinder.Skip(num); this._additionalOffset += num; } private uint GetRepLen1Price(Base.State state, uint posState) => this._isRepG0[(IntPtr) state.Index].GetPrice0() + this._isRep0Long[(IntPtr) ((state.Index << 4) + posState)].GetPrice0(); private uint GetPureRepPrice(uint repIndex, Base.State state, uint posState) { uint pureRepPrice; if (repIndex == 0U) { pureRepPrice = this._isRepG0[(IntPtr) state.Index].GetPrice0() + this._isRep0Long[(IntPtr) ((state.Index << 4) + posState)].GetPrice1(); } else { uint price1 = this._isRepG0[(IntPtr) state.Index].GetPrice1(); pureRepPrice = repIndex != 1U ? price1 + this._isRepG1[(IntPtr) state.Index].GetPrice1() + this._isRepG2[(IntPtr) state.Index].GetPrice(repIndex - 2U) : price1 + this._isRepG1[(IntPtr) state.Index].GetPrice0(); } return pureRepPrice; } private uint GetRepPrice(uint repIndex, uint len, Base.State state, uint posState) => this._repMatchLenEncoder.GetPrice(len - 2U, posState) + this.GetPureRepPrice(repIndex, state, posState); private uint GetPosLenPrice(uint pos, uint len, uint posState) { uint lenToPosState = Base.GetLenToPosState(len); return (pos >= 128U ? this._posSlotPrices[(IntPtr) ((lenToPosState << 6) + Encoder.GetPosSlot2(pos))] + this._alignPrices[(IntPtr) (pos & 15U)] : this._distancesPrices[(IntPtr) (lenToPosState * 128U + pos)]) + this._lenEncoder.GetPrice(len - 2U, posState); } private uint Backward(out uint backRes, uint cur) { this._optimumEndIndex = cur; uint posPrev = this._optimum[(IntPtr) cur].PosPrev; uint backPrev = this._optimum[(IntPtr) cur].BackPrev; do { if (this._optimum[(IntPtr) cur].Prev1IsChar) { this._optimum[(IntPtr) posPrev].MakeAsChar(); this._optimum[(IntPtr) posPrev].PosPrev = posPrev - 1U; if (this._optimum[(IntPtr) cur].Prev2) { this._optimum[(IntPtr) (posPrev - 1U)].Prev1IsChar = false; this._optimum[(IntPtr) (posPrev - 1U)].PosPrev = this._optimum[(IntPtr) cur].PosPrev2; this._optimum[(IntPtr) (posPrev - 1U)].BackPrev = this._optimum[(IntPtr) cur].BackPrev2; } } uint index = posPrev; uint num = backPrev; backPrev = this._optimum[(IntPtr) index].BackPrev; posPrev = this._optimum[(IntPtr) index].PosPrev; this._optimum[(IntPtr) index].BackPrev = num; this._optimum[(IntPtr) index].PosPrev = cur; cur = index; } while (cur > 0U); backRes = this._optimum[0].BackPrev; this._optimumCurrentIndex = this._optimum[0].PosPrev; return this._optimumCurrentIndex; } private uint GetOptimum(uint position, out uint backRes) { if ((int) this._optimumEndIndex != (int) this._optimumCurrentIndex) { uint optimum = this._optimum[(IntPtr) this._optimumCurrentIndex].PosPrev - this._optimumCurrentIndex; backRes = this._optimum[(IntPtr) this._optimumCurrentIndex].BackPrev; this._optimumCurrentIndex = this._optimum[(IntPtr) this._optimumCurrentIndex].PosPrev; return optimum; } this._optimumCurrentIndex = this._optimumEndIndex = 0U; uint lenRes1; uint numDistancePairs; if (!this._longestMatchWasFound) { this.ReadMatchDistances(out lenRes1, out numDistancePairs); } else { lenRes1 = this._longestMatchLength; numDistancePairs = this._numDistancePairs; this._longestMatchWasFound = false; } uint num1 = this._matchFinder.GetNumAvailableBytes() + 1U; if (num1 < 2U) { backRes = uint.MaxValue; return 1; } if (num1 > 273U) ; uint index1 = 0; for (uint index2 = 0; index2 < 4U; ++index2) { this.reps[(IntPtr) index2] = this._repDistances[(IntPtr) index2]; this.repLens[(IntPtr) index2] = this._matchFinder.GetMatchLen(-1, this.reps[(IntPtr) index2], 273U); if (this.repLens[(IntPtr) index2] > this.repLens[(IntPtr) index1]) index1 = index2; } if (this.repLens[(IntPtr) index1] >= this._numFastBytes) { backRes = index1; uint repLen = this.repLens[(IntPtr) index1]; this.MovePos(repLen - 1U); return repLen; } if (lenRes1 >= this._numFastBytes) { backRes = this._matchDistances[(IntPtr) (numDistancePairs - 1U)] + 4U; this.MovePos(lenRes1 - 1U); return lenRes1; } byte indexByte1 = this._matchFinder.GetIndexByte(-1); byte indexByte2 = this._matchFinder.GetIndexByte(-(int) this._repDistances[0] - 1 - 1); if (lenRes1 < 2U && (int) indexByte1 != (int) indexByte2 && this.repLens[(IntPtr) index1] < 2U) { backRes = uint.MaxValue; return 1; } this._optimum[0].State = this._state; uint posState1 = position & this._posStateMask; Encoder.Optimal optimal1 = this._optimum[1]; int price0 = (int) this._isMatch[(IntPtr) ((this._state.Index << 4) + posState1)].GetPrice0(); Encoder.LiteralEncoder.Encoder2 subCoder = this._literalEncoder.GetSubCoder(position, this._previousByte); int price1 = (int) subCoder.GetPrice(!this._state.IsCharState(), indexByte2, indexByte1); int num2 = price0 + price1; optimal1.Price = (uint) num2; this._optimum[1].MakeAsChar(); uint price1_1 = this._isMatch[(IntPtr) ((this._state.Index << 4) + posState1)].GetPrice1(); uint num3 = price1_1 + this._isRep[(IntPtr) this._state.Index].GetPrice1(); if ((int) indexByte2 == (int) indexByte1) { uint num4 = num3 + this.GetRepLen1Price(this._state, posState1); if (num4 < this._optimum[1].Price) { this._optimum[1].Price = num4; this._optimum[1].MakeAsShortRep(); } } uint num5 = lenRes1 >= this.repLens[(IntPtr) index1] ? lenRes1 : this.repLens[(IntPtr) index1]; if (num5 < 2U) { backRes = this._optimum[1].BackPrev; return 1; } this._optimum[1].PosPrev = 0U; this._optimum[0].Backs0 = this.reps[0]; this._optimum[0].Backs1 = this.reps[1]; this._optimum[0].Backs2 = this.reps[2]; this._optimum[0].Backs3 = this.reps[3]; uint num6 = num5; do { this._optimum[(IntPtr) num6--].Price = 268435455U; } while (num6 >= 2U); for (uint repIndex = 0; repIndex < 4U; ++repIndex) { uint repLen = this.repLens[(IntPtr) repIndex]; if (repLen >= 2U) { uint num7 = num3 + this.GetPureRepPrice(repIndex, this._state, posState1); do { uint num8 = num7 + this._repMatchLenEncoder.GetPrice(repLen - 2U, posState1); Encoder.Optimal optimal2 = this._optimum[(IntPtr) repLen]; if (num8 < optimal2.Price) { optimal2.Price = num8; optimal2.PosPrev = 0U; optimal2.BackPrev = repIndex; optimal2.Prev1IsChar = false; } } while (--repLen >= 2U); } } uint num9 = price1_1 + this._isRep[(IntPtr) this._state.Index].GetPrice0(); uint len = this.repLens[0] >= 2U ? this.repLens[0] + 1U : 2U; if (len <= lenRes1) { uint index3 = 0; while (len > this._matchDistances[(IntPtr) index3]) index3 += 2U; while (true) { uint matchDistance = this._matchDistances[(IntPtr) (index3 + 1U)]; uint num10 = num9 + this.GetPosLenPrice(matchDistance, len, posState1); Encoder.Optimal optimal3 = this._optimum[(IntPtr) len]; if (num10 < optimal3.Price) { optimal3.Price = num10; optimal3.PosPrev = 0U; optimal3.BackPrev = matchDistance + 4U; optimal3.Prev1IsChar = false; } if ((int) len == (int) this._matchDistances[(IntPtr) index3]) { index3 += 2U; if ((int) index3 == (int) numDistancePairs) break; } ++len; } } uint cur = 0; label_45: uint lenRes2; Base.State state1; uint posState2; uint num11; uint num12; uint num13; do { byte indexByte3; byte indexByte4; uint num14; bool flag; uint num15; uint limit1; do { ++cur; if ((int) cur == (int) num5) return this.Backward(out backRes, cur); this.ReadMatchDistances(out lenRes2, out numDistancePairs); if (lenRes2 >= this._numFastBytes) { this._numDistancePairs = numDistancePairs; this._longestMatchLength = lenRes2; this._longestMatchWasFound = true; return this.Backward(out backRes, cur); } ++position; uint index4 = this._optimum[(IntPtr) cur].PosPrev; if (this._optimum[(IntPtr) cur].Prev1IsChar) { --index4; if (this._optimum[(IntPtr) cur].Prev2) { state1 = this._optimum[(IntPtr) this._optimum[(IntPtr) cur].PosPrev2].State; if (this._optimum[(IntPtr) cur].BackPrev2 < 4U) state1.UpdateRep(); else state1.UpdateMatch(); } else state1 = this._optimum[(IntPtr) index4].State; state1.UpdateChar(); } else state1 = this._optimum[(IntPtr) index4].State; if ((int) index4 == (int) cur - 1) { if (this._optimum[(IntPtr) cur].IsShortRep()) state1.UpdateShortRep(); else state1.UpdateChar(); } else { uint num16; if (this._optimum[(IntPtr) cur].Prev1IsChar && this._optimum[(IntPtr) cur].Prev2) { index4 = this._optimum[(IntPtr) cur].PosPrev2; num16 = this._optimum[(IntPtr) cur].BackPrev2; state1.UpdateRep(); } else { num16 = this._optimum[(IntPtr) cur].BackPrev; if (num16 < 4U) state1.UpdateRep(); else state1.UpdateMatch(); } Encoder.Optimal optimal4 = this._optimum[(IntPtr) index4]; if (num16 < 4U) { switch (num16) { case 0: this.reps[0] = optimal4.Backs0; this.reps[1] = optimal4.Backs1; this.reps[2] = optimal4.Backs2; this.reps[3] = optimal4.Backs3; break; case 1: this.reps[0] = optimal4.Backs1; this.reps[1] = optimal4.Backs0; this.reps[2] = optimal4.Backs2; this.reps[3] = optimal4.Backs3; break; case 2: this.reps[0] = optimal4.Backs2; this.reps[1] = optimal4.Backs0; this.reps[2] = optimal4.Backs1; this.reps[3] = optimal4.Backs3; break; default: this.reps[0] = optimal4.Backs3; this.reps[1] = optimal4.Backs0; this.reps[2] = optimal4.Backs1; this.reps[3] = optimal4.Backs2; break; } } else { this.reps[0] = num16 - 4U; this.reps[1] = optimal4.Backs0; this.reps[2] = optimal4.Backs1; this.reps[3] = optimal4.Backs2; } } this._optimum[(IntPtr) cur].State = state1; this._optimum[(IntPtr) cur].Backs0 = this.reps[0]; this._optimum[(IntPtr) cur].Backs1 = this.reps[1]; this._optimum[(IntPtr) cur].Backs2 = this.reps[2]; this._optimum[(IntPtr) cur].Backs3 = this.reps[3]; uint price2 = this._optimum[(IntPtr) cur].Price; indexByte3 = this._matchFinder.GetIndexByte(-1); indexByte4 = this._matchFinder.GetIndexByte(-(int) this.reps[0] - 1 - 1); posState2 = position & this._posStateMask; int num17 = (int) price2 + (int) this._isMatch[(IntPtr) ((state1.Index << 4) + posState2)].GetPrice0(); subCoder = this._literalEncoder.GetSubCoder(position, this._matchFinder.GetIndexByte(-2)); int price3 = (int) subCoder.GetPrice(!state1.IsCharState(), indexByte4, indexByte3); num14 = (uint) (num17 + price3); Encoder.Optimal optimal5 = this._optimum[(IntPtr) (cur + 1U)]; flag = false; if (num14 < optimal5.Price) { optimal5.Price = num14; optimal5.PosPrev = cur; optimal5.MakeAsChar(); flag = true; } num11 = price2 + this._isMatch[(IntPtr) ((state1.Index << 4) + posState2)].GetPrice1(); num15 = num11 + this._isRep[(IntPtr) state1.Index].GetPrice1(); if ((int) indexByte4 == (int) indexByte3 && (optimal5.PosPrev >= cur || optimal5.BackPrev != 0U)) { uint num18 = num15 + this.GetRepLen1Price(state1, posState2); if (num18 <= optimal5.Price) { optimal5.Price = num18; optimal5.PosPrev = cur; optimal5.MakeAsShortRep(); flag = true; } } uint val2 = this._matchFinder.GetNumAvailableBytes() + 1U; num12 = Math.Min(4095U - cur, val2); limit1 = num12; } while (limit1 < 2U); if (limit1 > this._numFastBytes) limit1 = this._numFastBytes; if (!flag && (int) indexByte4 != (int) indexByte3) { uint matchLen = this._matchFinder.GetMatchLen(0, this.reps[0], Math.Min(num12 - 1U, this._numFastBytes)); if (matchLen >= 2U) { Base.State state2 = state1; state2.UpdateChar(); uint posState3 = position + 1U & this._posStateMask; uint num19 = num14 + this._isMatch[(IntPtr) ((state2.Index << 4) + posState3)].GetPrice1() + this._isRep[(IntPtr) state2.Index].GetPrice1(); uint index5 = cur + 1U + matchLen; while (num5 < index5) this._optimum[(IntPtr) ++num5].Price = 268435455U; uint num20 = num19 + this.GetRepPrice(0U, matchLen, state2, posState3); Encoder.Optimal optimal6 = this._optimum[(IntPtr) index5]; if (num20 < optimal6.Price) { optimal6.Price = num20; optimal6.PosPrev = cur + 1U; optimal6.BackPrev = 0U; optimal6.Prev1IsChar = true; optimal6.Prev2 = false; } } } num13 = 2U; for (uint repIndex = 0; repIndex < 4U; ++repIndex) { uint matchLen1 = this._matchFinder.GetMatchLen(-1, this.reps[(IntPtr) repIndex], limit1); if (matchLen1 >= 2U) { uint num21 = matchLen1; do { while (num5 < cur + matchLen1) this._optimum[(IntPtr) ++num5].Price = 268435455U; uint num22 = num15 + this.GetRepPrice(repIndex, matchLen1, state1, posState2); Encoder.Optimal optimal7 = this._optimum[(IntPtr) (cur + matchLen1)]; if (num22 < optimal7.Price) { optimal7.Price = num22; optimal7.PosPrev = cur; optimal7.BackPrev = repIndex; optimal7.Prev1IsChar = false; } } while (--matchLen1 >= 2U); uint num23 = num21; if (repIndex == 0U) num13 = num23 + 1U; if (num23 < num12) { uint limit2 = Math.Min(num12 - 1U - num23, this._numFastBytes); uint matchLen2 = this._matchFinder.GetMatchLen((int) num23, this.reps[(IntPtr) repIndex], limit2); if (matchLen2 >= 2U) { Base.State state3 = state1; state3.UpdateRep(); uint num24 = position + num23 & this._posStateMask; int num25 = (int) num15 + (int) this.GetRepPrice(repIndex, num23, state1, posState2) + (int) this._isMatch[(IntPtr) ((state3.Index << 4) + num24)].GetPrice0(); subCoder = this._literalEncoder.GetSubCoder(position + num23, this._matchFinder.GetIndexByte((int) num23 - 1 - 1)); int price4 = (int) subCoder.GetPrice(true, this._matchFinder.GetIndexByte((int) num23 - 1 - ((int) this.reps[(IntPtr) repIndex] + 1)), this._matchFinder.GetIndexByte((int) num23 - 1)); uint num26 = (uint) (num25 + price4); state3.UpdateChar(); uint posState4 = (uint) ((int) position + (int) num23 + 1) & this._posStateMask; uint num27 = num26 + this._isMatch[(IntPtr) ((state3.Index << 4) + posState4)].GetPrice1() + this._isRep[(IntPtr) state3.Index].GetPrice1(); uint num28 = num23 + 1U + matchLen2; while (num5 < cur + num28) this._optimum[(IntPtr) ++num5].Price = 268435455U; uint num29 = num27 + this.GetRepPrice(0U, matchLen2, state3, posState4); Encoder.Optimal optimal8 = this._optimum[(IntPtr) (cur + num28)]; if (num29 < optimal8.Price) { optimal8.Price = num29; optimal8.PosPrev = (uint) ((int) cur + (int) num23 + 1); optimal8.BackPrev = 0U; optimal8.Prev1IsChar = true; optimal8.Prev2 = true; optimal8.PosPrev2 = cur; optimal8.BackPrev2 = repIndex; } } } } } if (lenRes2 > limit1) { lenRes2 = limit1; uint index6 = 0; while (lenRes2 > this._matchDistances[(IntPtr) index6]) index6 += 2U; this._matchDistances[(IntPtr) index6] = lenRes2; numDistancePairs = index6 + 2U; } } while (lenRes2 < num13); uint num30 = num11 + this._isRep[(IntPtr) state1.Index].GetPrice0(); while (num5 < cur + lenRes2) this._optimum[(IntPtr) ++num5].Price = 268435455U; uint index7 = 0; while (num13 > this._matchDistances[(IntPtr) index7]) index7 += 2U; uint num31 = num13; while (true) { uint matchDistance = this._matchDistances[(IntPtr) (index7 + 1U)]; uint num32 = num30 + this.GetPosLenPrice(matchDistance, num31, posState2); Encoder.Optimal optimal9 = this._optimum[(IntPtr) (cur + num31)]; if (num32 < optimal9.Price) { optimal9.Price = num32; optimal9.PosPrev = cur; optimal9.BackPrev = matchDistance + 4U; optimal9.Prev1IsChar = false; } if ((int) num31 == (int) this._matchDistances[(IntPtr) index7]) { if (num31 < num12) { uint limit = Math.Min(num12 - 1U - num31, this._numFastBytes); uint matchLen = this._matchFinder.GetMatchLen((int) num31, matchDistance, limit); if (matchLen >= 2U) { Base.State state4 = state1; state4.UpdateMatch(); uint num33 = position + num31 & this._posStateMask; int num34 = (int) num32 + (int) this._isMatch[(IntPtr) ((state4.Index << 4) + num33)].GetPrice0(); subCoder = this._literalEncoder.GetSubCoder(position + num31, this._matchFinder.GetIndexByte((int) num31 - 1 - 1)); int price5 = (int) subCoder.GetPrice(true, this._matchFinder.GetIndexByte((int) num31 - ((int) matchDistance + 1) - 1), this._matchFinder.GetIndexByte((int) num31 - 1)); uint num35 = (uint) (num34 + price5); state4.UpdateChar(); uint posState5 = (uint) ((int) position + (int) num31 + 1) & this._posStateMask; uint num36 = num35 + this._isMatch[(IntPtr) ((state4.Index << 4) + posState5)].GetPrice1() + this._isRep[(IntPtr) state4.Index].GetPrice1(); uint num37 = num31 + 1U + matchLen; while (num5 < cur + num37) this._optimum[(IntPtr) ++num5].Price = 268435455U; uint num38 = num36 + this.GetRepPrice(0U, matchLen, state4, posState5); Encoder.Optimal optimal10 = this._optimum[(IntPtr) (cur + num37)]; if (num38 < optimal10.Price) { optimal10.Price = num38; optimal10.PosPrev = (uint) ((int) cur + (int) num31 + 1); optimal10.BackPrev = 0U; optimal10.Prev1IsChar = true; optimal10.Prev2 = true; optimal10.PosPrev2 = cur; optimal10.BackPrev2 = matchDistance + 4U; } } } index7 += 2U; if ((int) index7 == (int) numDistancePairs) goto label_45; } ++num31; } } private bool ChangePair(uint smallDist, uint bigDist) => smallDist < 33554432U && bigDist >= smallDist << 7; private void WriteEndMarker(uint posState) { if (!this._writeEndMark) return; this._isMatch[(IntPtr) ((this._state.Index << 4) + posState)].Encode(this._rangeEncoder, 1U); this._isRep[(IntPtr) this._state.Index].Encode(this._rangeEncoder, 0U); this._state.UpdateMatch(); uint len = 2; this._lenEncoder.Encode(this._rangeEncoder, len - 2U, posState); uint symbol = 63; this._posSlotEncoder[(IntPtr) Base.GetLenToPosState(len)].Encode(this._rangeEncoder, symbol); int num1 = 30; uint num2 = (uint) ((1 << num1) - 1); this._rangeEncoder.EncodeDirectBits(num2 >> 4, num1 - 4); this._posAlignEncoder.ReverseEncode(this._rangeEncoder, num2 & 15U); } private void Flush(uint nowPos) { this.ReleaseMFStream(); this.WriteEndMarker(nowPos & this._posStateMask); this._rangeEncoder.FlushData(); this._rangeEncoder.FlushStream(); } public void CodeOneBlock(out long inSize, out long outSize, out bool finished) { inSize = 0L; outSize = 0L; finished = true; if (this._inStream != null) { this._matchFinder.SetStream(this._inStream); this._matchFinder.Init(); this._needReleaseMFStream = true; this._inStream = (Stream) null; if (this._trainSize > 0U) this._matchFinder.Skip(this._trainSize); } if (this._finished) return; this._finished = true; long nowPos64 = this.nowPos64; if (this.nowPos64 == 0L) { if (this._matchFinder.GetNumAvailableBytes() == 0U) { this.Flush((uint) this.nowPos64); return; } this.ReadMatchDistances(out uint _, out uint _); this._isMatch[(IntPtr) ((this._state.Index << 4) + ((uint) this.nowPos64 & this._posStateMask))].Encode(this._rangeEncoder, 0U); this._state.UpdateChar(); byte indexByte = this._matchFinder.GetIndexByte(-(int) this._additionalOffset); this._literalEncoder.GetSubCoder((uint) this.nowPos64, this._previousByte).Encode(this._rangeEncoder, indexByte); this._previousByte = indexByte; --this._additionalOffset; ++this.nowPos64; } if (this._matchFinder.GetNumAvailableBytes() == 0U) { this.Flush((uint) this.nowPos64); } else { do { do { uint backRes; uint optimum = this.GetOptimum((uint) this.nowPos64, out backRes); uint posState = (uint) this.nowPos64 & this._posStateMask; uint index1 = (this._state.Index << 4) + posState; if (optimum == 1U && backRes == uint.MaxValue) { this._isMatch[(IntPtr) index1].Encode(this._rangeEncoder, 0U); byte indexByte1 = this._matchFinder.GetIndexByte(-(int) this._additionalOffset); Encoder.LiteralEncoder.Encoder2 subCoder = this._literalEncoder.GetSubCoder((uint) this.nowPos64, this._previousByte); if (!this._state.IsCharState()) { byte indexByte2 = this._matchFinder.GetIndexByte(-(int) this._repDistances[0] - 1 - (int) this._additionalOffset); subCoder.EncodeMatched(this._rangeEncoder, indexByte2, indexByte1); } else subCoder.Encode(this._rangeEncoder, indexByte1); this._previousByte = indexByte1; this._state.UpdateChar(); } else { this._isMatch[(IntPtr) index1].Encode(this._rangeEncoder, 1U); if (backRes < 4U) { this._isRep[(IntPtr) this._state.Index].Encode(this._rangeEncoder, 1U); if (backRes == 0U) { this._isRepG0[(IntPtr) this._state.Index].Encode(this._rangeEncoder, 0U); if (optimum == 1U) this._isRep0Long[(IntPtr) index1].Encode(this._rangeEncoder, 0U); else this._isRep0Long[(IntPtr) index1].Encode(this._rangeEncoder, 1U); } else { this._isRepG0[(IntPtr) this._state.Index].Encode(this._rangeEncoder, 1U); if (backRes == 1U) { this._isRepG1[(IntPtr) this._state.Index].Encode(this._rangeEncoder, 0U); } else { this._isRepG1[(IntPtr) this._state.Index].Encode(this._rangeEncoder, 1U); this._isRepG2[(IntPtr) this._state.Index].Encode(this._rangeEncoder, backRes - 2U); } } if (optimum == 1U) { this._state.UpdateShortRep(); } else { this._repMatchLenEncoder.Encode(this._rangeEncoder, optimum - 2U, posState); this._state.UpdateRep(); } uint repDistance = this._repDistances[(IntPtr) backRes]; if (backRes != 0U) { for (uint index2 = backRes; index2 >= 1U; --index2) this._repDistances[(IntPtr) index2] = this._repDistances[(IntPtr) (index2 - 1U)]; this._repDistances[0] = repDistance; } } else { this._isRep[(IntPtr) this._state.Index].Encode(this._rangeEncoder, 0U); this._state.UpdateMatch(); this._lenEncoder.Encode(this._rangeEncoder, optimum - 2U, posState); backRes -= 4U; uint posSlot = Encoder.GetPosSlot(backRes); this._posSlotEncoder[(IntPtr) Base.GetLenToPosState(optimum)].Encode(this._rangeEncoder, posSlot); if (posSlot >= 4U) { int NumBitLevels = (int) (posSlot >> 1) - 1; uint num = (uint) ((2 | (int) posSlot & 1) << NumBitLevels); uint symbol = backRes - num; if (posSlot < 14U) { BitTreeEncoder.ReverseEncode(this._posEncoders, (uint) ((int) num - (int) posSlot - 1), this._rangeEncoder, NumBitLevels, symbol); } else { this._rangeEncoder.EncodeDirectBits(symbol >> 4, NumBitLevels - 4); this._posAlignEncoder.ReverseEncode(this._rangeEncoder, symbol & 15U); ++this._alignPriceCount; } } uint num1 = backRes; for (uint index3 = 3; index3 >= 1U; --index3) this._repDistances[(IntPtr) index3] = this._repDistances[(IntPtr) (index3 - 1U)]; this._repDistances[0] = num1; ++this._matchPriceCount; } this._previousByte = this._matchFinder.GetIndexByte((int) optimum - 1 - (int) this._additionalOffset); } this._additionalOffset -= optimum; this.nowPos64 += (long) optimum; } while (this._additionalOffset != 0U); if (this._matchPriceCount >= 128U) this.FillDistancesPrices(); if (this._alignPriceCount >= 16U) this.FillAlignPrices(); inSize = this.nowPos64; outSize = this._rangeEncoder.GetProcessedSizeAdd(); if (this._matchFinder.GetNumAvailableBytes() == 0U) { this.Flush((uint) this.nowPos64); return; } } while (this.nowPos64 - nowPos64 < 4096L); this._finished = false; finished = false; } } private void ReleaseMFStream() { if (this._matchFinder == null || !this._needReleaseMFStream) return; this._matchFinder.ReleaseStream(); this._needReleaseMFStream = false; } private void SetOutStream(Stream outStream) => this._rangeEncoder.SetStream(outStream); private void ReleaseOutStream() => this._rangeEncoder.ReleaseStream(); private void ReleaseStreams() { this.ReleaseMFStream(); this.ReleaseOutStream(); } private void SetStreams(Stream inStream, Stream outStream, long inSize, long outSize) { this._inStream = inStream; this._finished = false; this.Create(); this.SetOutStream(outStream); this.Init(); this.FillDistancesPrices(); this.FillAlignPrices(); this._lenEncoder.SetTableSize((uint) ((int) this._numFastBytes + 1 - 2)); this._lenEncoder.UpdateTables((uint) (1 << this._posStateBits)); this._repMatchLenEncoder.SetTableSize((uint) ((int) this._numFastBytes + 1 - 2)); this._repMatchLenEncoder.UpdateTables((uint) (1 << this._posStateBits)); this.nowPos64 = 0L; } public void Code( Stream inStream, Stream outStream, long inSize, long outSize, ICodeProgress progress) { this._needReleaseMFStream = false; try { this.SetStreams(inStream, outStream, inSize, outSize); while (true) { long inSize1; long outSize1; do { bool finished; this.CodeOneBlock(out inSize1, out outSize1, out finished); if (finished) goto label_3; } while (progress == null); progress.SetProgress(inSize1, outSize1); } label_3:; } finally { this.ReleaseStreams(); } } public void WriteCoderProperties(Stream outStream) { this.properties[0] = (byte) ((this._posStateBits * 5 + this._numLiteralPosStateBits) * 9 + this._numLiteralContextBits); for (int index = 0; index < 4; ++index) this.properties[1 + index] = (byte) (this._dictionarySize >> 8 * index & (uint) byte.MaxValue); outStream.Write(this.properties, 0, 5); } private void FillDistancesPrices() { for (uint pos = 4; pos < 128U; ++pos) { uint posSlot = Encoder.GetPosSlot(pos); int NumBitLevels = (int) (posSlot >> 1) - 1; uint num = (uint) ((2 | (int) posSlot & 1) << NumBitLevels); this.tempPrices[(IntPtr) pos] = BitTreeEncoder.ReverseGetPrice(this._posEncoders, (uint) ((int) num - (int) posSlot - 1), NumBitLevels, pos - num); } for (uint index1 = 0; index1 < 4U; ++index1) { BitTreeEncoder bitTreeEncoder = this._posSlotEncoder[(IntPtr) index1]; uint num1 = index1 << 6; for (uint symbol = 0; symbol < this._distTableSize; ++symbol) this._posSlotPrices[(IntPtr) (num1 + symbol)] = bitTreeEncoder.GetPrice(symbol); for (uint index2 = 14; index2 < this._distTableSize; ++index2) this._posSlotPrices[(IntPtr) (num1 + index2)] += (uint) ((int) (index2 >> 1) - 1 - 4 << 6); uint num2 = index1 * 128U; uint pos; for (pos = 0U; pos < 4U; ++pos) this._distancesPrices[(IntPtr) (num2 + pos)] = this._posSlotPrices[(IntPtr) (num1 + pos)]; for (; pos < 128U; ++pos) this._distancesPrices[(IntPtr) (num2 + pos)] = this._posSlotPrices[(IntPtr) (num1 + Encoder.GetPosSlot(pos))] + this.tempPrices[(IntPtr) pos]; } this._matchPriceCount = 0U; } private void FillAlignPrices() { for (uint symbol = 0; symbol < 16U; ++symbol) this._alignPrices[(IntPtr) symbol] = this._posAlignEncoder.ReverseGetPrice(symbol); this._alignPriceCount = 0U; } private static int FindMatchFinder(string s) { for (int matchFinder = 0; matchFinder < Encoder.kMatchFinderIDs.Length; ++matchFinder) { if (s == Encoder.kMatchFinderIDs[matchFinder]) return matchFinder; } return -1; } public void SetCoderProperties(CoderPropID[] propIDs, object[] properties) { for (uint index = 0; (long) index < (long) properties.Length; ++index) { object property = properties[(IntPtr) index]; switch (propIDs[(IntPtr) index]) { case CoderPropID.DictionarySize: if (!(property is int num1)) throw new InvalidParamException(); this._dictionarySize = num1 >= 1 && num1 <= 1073741824 ? (uint) num1 : throw new InvalidParamException(); int num2 = 0; while (num2 < 30 && (long) num1 > (long) (uint) (1 << num2)) ++num2; this._distTableSize = (uint) (num2 * 2); continue; case CoderPropID.PosStateBits: if (!(property is int num3)) throw new InvalidParamException(); this._posStateBits = num3 >= 0 && num3 <= 4 ? num3 : throw new InvalidParamException(); this._posStateMask = (uint) ((1 << this._posStateBits) - 1); continue; case CoderPropID.LitContextBits: if (!(property is int num4)) throw new InvalidParamException(); this._numLiteralContextBits = num4 >= 0 && num4 <= 8 ? num4 : throw new InvalidParamException(); continue; case CoderPropID.LitPosBits: if (!(property is int num5)) throw new InvalidParamException(); this._numLiteralPosStateBits = num5 >= 0 && num5 <= 4 ? num5 : throw new InvalidParamException(); continue; case CoderPropID.NumFastBytes: if (!(property is int num6)) throw new InvalidParamException(); this._numFastBytes = num6 >= 5 && num6 <= 273 ? (uint) num6 : throw new InvalidParamException(); continue; case CoderPropID.MatchFinder: if (!(property is string)) throw new InvalidParamException(); Encoder.EMatchFinderType matchFinderType = this._matchFinderType; int matchFinder = Encoder.FindMatchFinder(((string) property).ToUpper()); this._matchFinderType = matchFinder >= 0 ? (Encoder.EMatchFinderType) matchFinder : throw new InvalidParamException(); if (this._matchFinder != null && matchFinderType != this._matchFinderType) { this._dictionarySizePrev = uint.MaxValue; this._matchFinder = (IMatchFinder) null; continue; } continue; case CoderPropID.Algorithm: continue; case CoderPropID.EndMarker: if (!(property is bool writeEndMarker)) throw new InvalidParamException(); this.SetWriteEndMarkerMode(writeEndMarker); continue; default: throw new InvalidParamException(); } } } public void SetTrainSize(uint trainSize) => this._trainSize = trainSize; private enum EMatchFinderType { BT2, BT4, } private class LiteralEncoder { private Encoder.LiteralEncoder.Encoder2[] m_Coders; private int m_NumPrevBits; private int m_NumPosBits; private uint m_PosMask; public void Create(int numPosBits, int numPrevBits) { if (this.m_Coders != null && this.m_NumPrevBits == numPrevBits && this.m_NumPosBits == numPosBits) return; this.m_NumPosBits = numPosBits; this.m_PosMask = (uint) ((1 << numPosBits) - 1); this.m_NumPrevBits = numPrevBits; uint length = (uint) (1 << this.m_NumPrevBits + this.m_NumPosBits); this.m_Coders = new Encoder.LiteralEncoder.Encoder2[(IntPtr) length]; for (uint index = 0; index < length; ++index) this.m_Coders[(IntPtr) index].Create(); } public void Init() { uint num = (uint) (1 << this.m_NumPrevBits + this.m_NumPosBits); for (uint index = 0; index < num; ++index) this.m_Coders[(IntPtr) index].Init(); } public Encoder.LiteralEncoder.Encoder2 GetSubCoder(uint pos, byte prevByte) => this.m_Coders[(IntPtr) (uint) ((((int) pos & (int) this.m_PosMask) << this.m_NumPrevBits) + ((int) prevByte >> 8 - this.m_NumPrevBits))]; public struct Encoder2 { private BitEncoder[] m_Encoders; public void Create() => this.m_Encoders = new BitEncoder[768]; public void Init() { for (int index = 0; index < 768; ++index) this.m_Encoders[index].Init(); } public void Encode(SevenZip.Compression.RangeCoder.Encoder rangeEncoder, byte symbol) { uint index1 = 1; for (int index2 = 7; index2 >= 0; --index2) { uint symbol1 = (uint) ((int) symbol >> index2 & 1); this.m_Encoders[(IntPtr) index1].Encode(rangeEncoder, symbol1); index1 = index1 << 1 | symbol1; } } public void EncodeMatched(SevenZip.Compression.RangeCoder.Encoder rangeEncoder, byte matchByte, byte symbol) { uint num1 = 1; bool flag = true; for (int index1 = 7; index1 >= 0; --index1) { uint symbol1 = (uint) ((int) symbol >> index1 & 1); uint index2 = num1; if (flag) { uint num2 = (uint) ((int) matchByte >> index1 & 1); index2 += (uint) (1 + (int) num2 << 8); flag = (int) num2 == (int) symbol1; } this.m_Encoders[(IntPtr) index2].Encode(rangeEncoder, symbol1); num1 = num1 << 1 | symbol1; } } public uint GetPrice(bool matchMode, byte matchByte, byte symbol) { uint price = 0; uint index = 1; int num1 = 7; if (matchMode) { for (; num1 >= 0; --num1) { uint num2 = (uint) ((int) matchByte >> num1 & 1); uint symbol1 = (uint) ((int) symbol >> num1 & 1); price += this.m_Encoders[(IntPtr) ((uint) (1 + (int) num2 << 8) + index)].GetPrice(symbol1); index = index << 1 | symbol1; if ((int) num2 != (int) symbol1) { --num1; break; } } } for (; num1 >= 0; --num1) { uint symbol2 = (uint) ((int) symbol >> num1 & 1); price += this.m_Encoders[(IntPtr) index].GetPrice(symbol2); index = index << 1 | symbol2; } return price; } } } private class LenEncoder { private BitEncoder _choice = new BitEncoder(); private BitEncoder _choice2 = new BitEncoder(); private BitTreeEncoder[] _lowCoder = new BitTreeEncoder[new IntPtr(16)]; private BitTreeEncoder[] _midCoder = new BitTreeEncoder[new IntPtr(16)]; private BitTreeEncoder _highCoder = new BitTreeEncoder(8); public LenEncoder() { for (uint index = 0; index < 16U; ++index) { this._lowCoder[(IntPtr) index] = new BitTreeEncoder(3); this._midCoder[(IntPtr) index] = new BitTreeEncoder(3); } } public void Init(uint numPosStates) { this._choice.Init(); this._choice2.Init(); for (uint index = 0; index < numPosStates; ++index) { this._lowCoder[(IntPtr) index].Init(); this._midCoder[(IntPtr) index].Init(); } this._highCoder.Init(); } public void Encode(SevenZip.Compression.RangeCoder.Encoder rangeEncoder, uint symbol, uint posState) { if (symbol < 8U) { this._choice.Encode(rangeEncoder, 0U); this._lowCoder[(IntPtr) posState].Encode(rangeEncoder, symbol); } else { symbol -= 8U; this._choice.Encode(rangeEncoder, 1U); if (symbol < 8U) { this._choice2.Encode(rangeEncoder, 0U); this._midCoder[(IntPtr) posState].Encode(rangeEncoder, symbol); } else { this._choice2.Encode(rangeEncoder, 1U); this._highCoder.Encode(rangeEncoder, symbol - 8U); } } } public void SetPrices(uint posState, uint numSymbols, uint[] prices, uint st) { uint price0 = this._choice.GetPrice0(); uint price1 = this._choice.GetPrice1(); uint num1 = price1 + this._choice2.GetPrice0(); uint num2 = price1 + this._choice2.GetPrice1(); uint symbol; for (symbol = 0U; symbol < 8U; ++symbol) { if (symbol >= numSymbols) return; prices[(IntPtr) (st + symbol)] = price0 + this._lowCoder[(IntPtr) posState].GetPrice(symbol); } for (; symbol < 16U; ++symbol) { if (symbol >= numSymbols) return; prices[(IntPtr) (st + symbol)] = num1 + this._midCoder[(IntPtr) posState].GetPrice(symbol - 8U); } for (; symbol < numSymbols; ++symbol) prices[(IntPtr) (st + symbol)] = num2 + this._highCoder.GetPrice((uint) ((int) symbol - 8 - 8)); } } private class LenPriceTableEncoder : Encoder.LenEncoder { private uint[] _prices = new uint[new IntPtr(4352)]; private uint _tableSize; private uint[] _counters = new uint[new IntPtr(16)]; public void SetTableSize(uint tableSize) => this._tableSize = tableSize; public uint GetPrice(uint symbol, uint posState) => this._prices[(IntPtr) (posState * 272U + symbol)]; private void UpdateTable(uint posState) { this.SetPrices(posState, this._tableSize, this._prices, posState * 272U); this._counters[(IntPtr) posState] = this._tableSize; } public void UpdateTables(uint numPosStates) { for (uint posState = 0; posState < numPosStates; ++posState) this.UpdateTable(posState); } public new void Encode(SevenZip.Compression.RangeCoder.Encoder rangeEncoder, uint symbol, uint posState) { base.Encode(rangeEncoder, symbol, posState); if (--this._counters[(IntPtr) posState] != 0U) return; this.UpdateTable(posState); } } private class Optimal { public Base.State State; public bool Prev1IsChar; public bool Prev2; public uint PosPrev2; public uint BackPrev2; public uint Price; public uint PosPrev; public uint BackPrev; public uint Backs0; public uint Backs1; public uint Backs2; public uint Backs3; public void MakeAsChar() { this.BackPrev = uint.MaxValue; this.Prev1IsChar = false; } public void MakeAsShortRep() { this.BackPrev = 0U; this.Prev1IsChar = false; } public bool IsShortRep() => this.BackPrev == 0U; } } }