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+LZMA specification (DRAFT version)

+----------------------------------

+

+Author: Igor Pavlov

+Date: 2015-06-14

+

+This specification defines the format of LZMA compressed data and lzma file format.

+

+Notation 

+--------

+

+We use the syntax of C++ programming language.

+We use the following types in C++ code:

+  unsigned - unsigned integer, at least 16 bits in size

+  int      - signed integer, at least 16 bits in size

+  UInt64   - 64-bit unsigned integer

+  UInt32   - 32-bit unsigned integer

+  UInt16   - 16-bit unsigned integer

+  Byte     - 8-bit unsigned integer

+  bool     - boolean type with two possible values: false, true

+

+

+lzma file format

+================

+

+The lzma file contains the raw LZMA stream and the header with related properties.

+

+The files in that format use ".lzma" extension.

+

+The lzma file format layout:

+

+Offset Size Description

+

+  0     1   LZMA model properties (lc, lp, pb) in encoded form

+  1     4   Dictionary size (32-bit unsigned integer, little-endian)

+  5     8   Uncompressed size (64-bit unsigned integer, little-endian)

+ 13         Compressed data (LZMA stream)

+

+LZMA properties:

+

+    name  Range          Description

+

+      lc  [0, 8]         the number of "literal context" bits

+      lp  [0, 4]         the number of "literal pos" bits

+      pb  [0, 4]         the number of "pos" bits

+dictSize  [0, 2^32 - 1]  the dictionary size 

+

+The following code encodes LZMA properties:

+

+void EncodeProperties(Byte *properties)

+{

+  properties[0] = (Byte)((pb * 5 + lp) * 9 + lc);

+  Set_UInt32_LittleEndian(properties + 1, dictSize);

+}

+

+If the value of dictionary size in properties is smaller than (1 << 12),

+the LZMA decoder must set the dictionary size variable to (1 << 12).

+

+#define LZMA_DIC_MIN (1 << 12)

+

+  unsigned lc, pb, lp;

+  UInt32 dictSize;

+  UInt32 dictSizeInProperties;

+

+  void DecodeProperties(const Byte *properties)

+  {

+    unsigned d = properties[0];

+    if (d >= (9 * 5 * 5))

+      throw "Incorrect LZMA properties";

+    lc = d % 9;

+    d /= 9;

+    pb = d / 5;

+    lp = d % 5;

+    dictSizeInProperties = 0;

+    for (int i = 0; i < 4; i++)

+      dictSizeInProperties |= (UInt32)properties[i + 1] << (8 * i);

+    dictSize = dictSizeInProperties;

+    if (dictSize < LZMA_DIC_MIN)

+      dictSize = LZMA_DIC_MIN;

+  }

+

+If "Uncompressed size" field contains ones in all 64 bits, it means that

+uncompressed size is unknown and there is the "end marker" in stream,

+that indicates the end of decoding point.

+In opposite case, if the value from "Uncompressed size" field is not

+equal to ((2^64) - 1), the LZMA stream decoding must be finished after

+specified number of bytes (Uncompressed size) is decoded. And if there 

+is the "end marker", the LZMA decoder must read that marker also.

+

+

+The new scheme to encode LZMA properties

+----------------------------------------

+

+If LZMA compression is used for some another format, it's recommended to

+use a new improved scheme to encode LZMA properties. That new scheme was

+used in xz format that uses the LZMA2 compression algorithm.

+The LZMA2 is a new compression algorithm that is based on the LZMA algorithm.

+

+The dictionary size in LZMA2 is encoded with just one byte and LZMA2 supports

+only reduced set of dictionary sizes:

+  (2 << 11), (3 << 11),

+  (2 << 12), (3 << 12),

+  ...

+  (2 << 30), (3 << 30),

+  (2 << 31) - 1

+

+The dictionary size can be extracted from encoded value with the following code:

+

+  dictSize = (p == 40) ? 0xFFFFFFFF : (((UInt32)2 | ((p) & 1)) << ((p) / 2 + 11));

+

+Also there is additional limitation (lc + lp <= 4) in LZMA2 for values of 

+"lc" and "lp" properties:

+

+  if (lc + lp > 4)

+    throw "Unsupported properties: (lc + lp) > 4";

+

+There are some advantages for LZMA decoder with such (lc + lp) value

+limitation. It reduces the maximum size of tables allocated by decoder.

+And it reduces the complexity of initialization procedure, that can be 

+important to keep high speed of decoding of big number of small LZMA streams.

+

+It's recommended to use that limitation (lc + lp <= 4) for any new format

+that uses LZMA compression. Note that the combinations of "lc" and "lp" 

+parameters, where (lc + lp > 4), can provide significant improvement in 

+compression ratio only in some rare cases.

+

+The LZMA properties can be encoded into two bytes in new scheme:

+

+Offset Size Description

+

+  0     1   The dictionary size encoded with LZMA2 scheme

+  1     1   LZMA model properties (lc, lp, pb) in encoded form

+

+

+The RAM usage 

+=============

+

+The RAM usage for LZMA decoder is determined by the following parts:

+

+1) The Sliding Window (from 4 KiB to 4 GiB).

+2) The probability model counter arrays (arrays of 16-bit variables).

+3) Some additional state variables (about 10 variables of 32-bit integers).

+

+

+The RAM usage for Sliding Window

+--------------------------------

+

+There are two main scenarios of decoding:

+

+1) The decoding of full stream to one RAM buffer.

+

+  If we decode full LZMA stream to one output buffer in RAM, the decoder 

+  can use that output buffer as sliding window. So the decoder doesn't 

+  need additional buffer allocated for sliding window.

+

+2) The decoding to some external storage.

+

+  If we decode LZMA stream to external storage, the decoder must allocate

+  the buffer for sliding window. The size of that buffer must be equal 

+  or larger than the value of dictionary size from properties of LZMA stream.

+

+In this specification we describe the code for decoding to some external

+storage. The optimized version of code for decoding of full stream to one

+output RAM buffer can require some minor changes in code.

+

+

+The RAM usage for the probability model counters

+------------------------------------------------

+

+The size of the probability model counter arrays is calculated with the 

+following formula:

+

+size_of_prob_arrays = 1846 + 768 * (1 << (lp + lc))

+

+Each probability model counter is 11-bit unsigned integer.

+If we use 16-bit integer variables (2-byte integers) for these probability 

+model counters, the RAM usage required by probability model counter arrays 

+can be estimated with the following formula:

+

+  RAM = 4 KiB + 1.5 KiB * (1 << (lp + lc))

+

+For example, for default LZMA parameters (lp = 0 and lc = 3), the RAM usage is

+

+  RAM_lc3_lp0 = 4 KiB + 1.5 KiB * 8 = 16 KiB

+

+The maximum RAM state usage is required for decoding the stream with lp = 4 

+and lc = 8:

+

+  RAM_lc8_lp4 = 4 KiB + 1.5 KiB * 4096 = 6148 KiB

+

+If the decoder uses LZMA2's limited property condition 

+(lc + lp <= 4), the RAM usage will be not larger than

+

+  RAM_lc_lp_4 = 4 KiB + 1.5 KiB * 16 = 28 KiB

+

+

+The RAM usage for encoder

+-------------------------

+

+There are many variants for LZMA encoding code.

+These variants have different values for memory consumption.

+Note that memory consumption for LZMA Encoder can not be 

+smaller than memory consumption of LZMA Decoder for same stream.

+

+The RAM usage required by modern effective implementation of 

+LZMA Encoder can be estimated with the following formula:

+

+  Encoder_RAM_Usage = 4 MiB + 11 * dictionarySize.

+

+But there are some modes of the encoder that require less memory.

+

+

+LZMA Decoding

+=============

+

+The LZMA compression algorithm uses LZ-based compression with Sliding Window

+and Range Encoding as entropy coding method.

+

+

+Sliding Window

+--------------

+

+LZMA uses Sliding Window compression similar to LZ77 algorithm.

+

+LZMA stream must be decoded to the sequence that consists

+of MATCHES and LITERALS:

+  

+  - a LITERAL is a 8-bit character (one byte).

+    The decoder just puts that LITERAL to the uncompressed stream.

+  

+  - a MATCH is a pair of two numbers (DISTANCE-LENGTH pair).

+    The decoder takes one byte exactly "DISTANCE" characters behind

+    current position in the uncompressed stream and puts it to 

+    uncompressed stream. The decoder must repeat it "LENGTH" times.

+

+The "DISTANCE" can not be larger than dictionary size.

+And the "DISTANCE" can not be larger than the number of bytes in

+the uncompressed stream that were decoded before that match.

+

+In this specification we use cyclic buffer to implement Sliding Window

+for LZMA decoder:

+

+class COutWindow

+{

+  Byte *Buf;

+  UInt32 Pos;

+  UInt32 Size;

+  bool IsFull;

+

+public:

+  unsigned TotalPos;

+  COutStream OutStream;

+

+  COutWindow(): Buf(NULL) {}

+  ~COutWindow() { delete []Buf; }

+ 

+  void Create(UInt32 dictSize)

+  {

+    Buf = new Byte[dictSize];

+    Pos = 0;

+    Size = dictSize;

+    IsFull = false;

+    TotalPos = 0;

+  }

+

+  void PutByte(Byte b)

+  {

+    TotalPos++;

+    Buf[Pos++] = b;

+    if (Pos == Size)

+    {

+      Pos = 0;

+      IsFull = true;

+    }

+    OutStream.WriteByte(b);

+  }

+

+  Byte GetByte(UInt32 dist) const

+  {

+    return Buf[dist <= Pos ? Pos - dist : Size - dist + Pos];

+  }

+

+  void CopyMatch(UInt32 dist, unsigned len)

+  {

+    for (; len > 0; len--)

+      PutByte(GetByte(dist));

+  }

+

+  bool CheckDistance(UInt32 dist) const

+  {

+    return dist <= Pos || IsFull;

+  }

+

+  bool IsEmpty() const

+  {

+    return Pos == 0 && !IsFull;

+  }

+};

+

+

+In another implementation it's possible to use one buffer that contains 

+Sliding Window and the whole data stream after uncompressing.

+

+

+Range Decoder

+-------------

+

+LZMA algorithm uses Range Encoding (1) as entropy coding method.

+

+LZMA stream contains just one very big number in big-endian encoding.

+LZMA decoder uses the Range Decoder to extract a sequence of binary

+symbols from that big number.

+

+The state of the Range Decoder:

+

+struct CRangeDecoder

+{

+  UInt32 Range; 

+  UInt32 Code;

+  InputStream *InStream;

+

+  bool Corrupted;

+}

+

+The notes about UInt32 type for the "Range" and "Code" variables:

+

+  It's possible to use 64-bit (unsigned or signed) integer type

+  for the "Range" and the "Code" variables instead of 32-bit unsigned,

+  but some additional code must be used to truncate the values to 

+  low 32-bits after some operations.

+

+  If the programming language does not support 32-bit unsigned integer type 

+  (like in case of JAVA language), it's possible to use 32-bit signed integer, 

+  but some code must be changed. For example, it's required to change the code

+  that uses comparison operations for UInt32 variables in this specification.

+

+The Range Decoder can be in some states that can be treated as 

+"Corruption" in LZMA stream. The Range Decoder uses the variable "Corrupted":

+

+  (Corrupted == false), if the Range Decoder has not detected any corruption.

+  (Corrupted == true), if the Range Decoder has detected some corruption.

+

+The reference LZMA Decoder ignores the value of the "Corrupted" variable.

+So it continues to decode the stream, even if the corruption can be detected

+in the Range Decoder. To provide the full compatibility with output of the 

+reference LZMA Decoder, another LZMA Decoder implementations must also 

+ignore the value of the "Corrupted" variable.

+

+The LZMA Encoder is required to create only such LZMA streams, that will not 

+lead the Range Decoder to states, where the "Corrupted" variable is set to true.

+

+The Range Decoder reads first 5 bytes from input stream to initialize

+the state:

+

+bool CRangeDecoder::Init()

+{

+  Corrupted = false;

+  Range = 0xFFFFFFFF;

+  Code = 0;

+

+  Byte b = InStream->ReadByte();

+  

+  for (int i = 0; i < 4; i++)

+    Code = (Code << 8) | InStream->ReadByte();

+  

+  if (b != 0 || Code == Range)

+    Corrupted = true;

+  return b == 0;

+}

+

+The LZMA Encoder always writes ZERO in initial byte of compressed stream.

+That scheme allows to simplify the code of the Range Encoder in the 

+LZMA Encoder. If initial byte is not equal to ZERO, the LZMA Decoder must

+stop decoding and report error.

+

+After the last bit of data was decoded by Range Decoder, the value of the

+"Code" variable must be equal to 0. The LZMA Decoder must check it by 

+calling the IsFinishedOK() function:

+

+  bool IsFinishedOK() const { return Code == 0; }

+

+If there is corruption in data stream, there is big probability that

+the "Code" value will be not equal to 0 in the Finish() function. So that

+check in the IsFinishedOK() function provides very good feature for 

+corruption detection.

+

+The value of the "Range" variable before each bit decoding can not be smaller 

+than ((UInt32)1 << 24). The Normalize() function keeps the "Range" value in 

+described range.

+

+#define kTopValue ((UInt32)1 << 24)

+

+void CRangeDecoder::Normalize()

+{

+  if (Range < kTopValue)

+  {

+    Range <<= 8;

+    Code = (Code << 8) | InStream->ReadByte();

+  }

+}

+

+Notes: if the size of the "Code" variable is larger than 32 bits, it's

+required to keep only low 32 bits of the "Code" variable after the change

+in Normalize() function.

+

+If the LZMA Stream is not corrupted, the value of the "Code" variable is

+always smaller than value of the "Range" variable.

+But the Range Decoder ignores some types of corruptions, so the value of

+the "Code" variable can be equal or larger than value of the "Range" variable

+for some "Corrupted" archives.

+

+

+LZMA uses Range Encoding only with binary symbols of two types:

+  1) binary symbols with fixed and equal probabilities (direct bits)

+  2) binary symbols with predicted probabilities

+

+The DecodeDirectBits() function decodes the sequence of direct bits:

+

+UInt32 CRangeDecoder::DecodeDirectBits(unsigned numBits)

+{

+  UInt32 res = 0;

+  do

+  {

+    Range >>= 1;

+    Code -= Range;

+    UInt32 t = 0 - ((UInt32)Code >> 31);

+    Code += Range & t;

+    

+    if (Code == Range)

+      Corrupted = true;

+    

+    Normalize();

+    res <<= 1;

+    res += t + 1;

+  }

+  while (--numBits);

+  return res;

+}

+

+

+The Bit Decoding with Probability Model

+---------------------------------------

+

+The task of Bit Probability Model is to estimate probabilities of binary

+symbols. And then it provides the Range Decoder with that information.

+The better prediction provides better compression ratio.

+The Bit Probability Model uses statistical data of previous decoded

+symbols.

+

+That estimated probability is presented as 11-bit unsigned integer value

+that represents the probability of symbol "0".

+

+#define kNumBitModelTotalBits 11

+

+Mathematical probabilities can be presented with the following formulas:

+     probability(symbol_0) = prob / 2048.

+     probability(symbol_1) =  1 - Probability(symbol_0) =  

+                           =  1 - prob / 2048 =  

+                           =  (2048 - prob) / 2048

+where the "prob" variable contains 11-bit integer probability counter.

+

+It's recommended to use 16-bit unsigned integer type, to store these 11-bit

+probability values:

+

+typedef UInt16 CProb;

+

+Each probability value must be initialized with value ((1 << 11) / 2),

+that represents the state, where probabilities of symbols 0 and 1 

+are equal to 0.5:

+

+#define PROB_INIT_VAL ((1 << kNumBitModelTotalBits) / 2)

+

+The INIT_PROBS macro is used to initialize the array of CProb variables:

+

+#define INIT_PROBS(p) \

+ { for (unsigned i = 0; i < sizeof(p) / sizeof(p[0]); i++) p[i] = PROB_INIT_VAL; }

+

+

+The DecodeBit() function decodes one bit.

+The LZMA decoder provides the pointer to CProb variable that contains 

+information about estimated probability for symbol 0 and the Range Decoder 

+updates that CProb variable after decoding. The Range Decoder increases 

+estimated probability of the symbol that was decoded:

+

+#define kNumMoveBits 5

+

+unsigned CRangeDecoder::DecodeBit(CProb *prob)

+{

+  unsigned v = *prob;

+  UInt32 bound = (Range >> kNumBitModelTotalBits) * v;

+  unsigned symbol;

+  if (Code < bound)

+  {

+    v += ((1 << kNumBitModelTotalBits) - v) >> kNumMoveBits;

+    Range = bound;

+    symbol = 0;

+  }

+  else

+  {

+    v -= v >> kNumMoveBits;

+    Code -= bound;

+    Range -= bound;

+    symbol = 1;

+  }

+  *prob = (CProb)v;

+  Normalize();

+  return symbol;

+}

+

+

+The Binary Tree of bit model counters

+-------------------------------------

+

+LZMA uses a tree of Bit model variables to decode symbol that needs

+several bits for storing. There are two versions of such trees in LZMA:

+  1) the tree that decodes bits from high bit to low bit (the normal scheme).

+  2) the tree that decodes bits from low bit to high bit (the reverse scheme).

+

+Each binary tree structure supports different size of decoded symbol

+(the size of binary sequence that contains value of symbol).

+If that size of decoded symbol is "NumBits" bits, the tree structure 

+uses the array of (2 << NumBits) counters of CProb type. 

+But only ((2 << NumBits) - 1) items are used by encoder and decoder.

+The first item (the item with index equal to 0) in array is unused.

+That scheme with unused array's item allows to simplify the code.

+

+unsigned BitTreeReverseDecode(CProb *probs, unsigned numBits, CRangeDecoder *rc)

+{

+  unsigned m = 1;

+  unsigned symbol = 0;

+  for (unsigned i = 0; i < numBits; i++)

+  {

+    unsigned bit = rc->DecodeBit(&probs[m]);

+    m <<= 1;

+    m += bit;

+    symbol |= (bit << i);

+  }

+  return symbol;

+}

+

+template <unsigned NumBits>

+class CBitTreeDecoder

+{

+  CProb Probs[(unsigned)1 << NumBits];

+

+public:

+

+  void Init()

+  {

+    INIT_PROBS(Probs);

+  }

+

+  unsigned Decode(CRangeDecoder *rc)

+  {

+    unsigned m = 1;

+    for (unsigned i = 0; i < NumBits; i++)

+      m = (m << 1) + rc->DecodeBit(&Probs[m]);

+    return m - ((unsigned)1 << NumBits);

+  }

+

+  unsigned ReverseDecode(CRangeDecoder *rc)

+  {

+    return BitTreeReverseDecode(Probs, NumBits, rc);

+  }

+};

+

+

+LZ part of LZMA 

+---------------

+

+LZ part of LZMA describes details about the decoding of MATCHES and LITERALS.

+

+

+The Literal Decoding

+--------------------

+

+The LZMA Decoder uses (1 << (lc + lp)) tables with CProb values, where 

+each table contains 0x300 CProb values:

+

+  CProb *LitProbs;

+

+  void CreateLiterals()

+  {

+    LitProbs = new CProb[(UInt32)0x300 << (lc + lp)];

+  }

+  

+  void InitLiterals()

+  {

+    UInt32 num = (UInt32)0x300 << (lc + lp);

+    for (UInt32 i = 0; i < num; i++)

+      LitProbs[i] = PROB_INIT_VAL;

+  }

+

+To select the table for decoding it uses the context that consists of

+(lc) high bits from previous literal and (lp) low bits from value that

+represents current position in outputStream.

+

+If (State > 7), the Literal Decoder also uses "matchByte" that represents 

+the byte in OutputStream at position the is the DISTANCE bytes before 

+current position, where the DISTANCE is the distance in DISTANCE-LENGTH pair

+of latest decoded match.

+

+The following code decodes one literal and puts it to Sliding Window buffer:

+

+  void DecodeLiteral(unsigned state, UInt32 rep0)

+  {

+    unsigned prevByte = 0;

+    if (!OutWindow.IsEmpty())

+      prevByte = OutWindow.GetByte(1);

+    

+    unsigned symbol = 1;

+    unsigned litState = ((OutWindow.TotalPos & ((1 << lp) - 1)) << lc) + (prevByte >> (8 - lc));

+    CProb *probs = &LitProbs[(UInt32)0x300 * litState];

+    

+    if (state >= 7)

+    {

+      unsigned matchByte = OutWindow.GetByte(rep0 + 1);

+      do

+      {

+        unsigned matchBit = (matchByte >> 7) & 1;

+        matchByte <<= 1;

+        unsigned bit = RangeDec.DecodeBit(&probs[((1 + matchBit) << 8) + symbol]);

+        symbol = (symbol << 1) | bit;

+        if (matchBit != bit)

+          break;

+      }

+      while (symbol < 0x100);

+    }

+    while (symbol < 0x100)

+      symbol = (symbol << 1) | RangeDec.DecodeBit(&probs[symbol]);

+    OutWindow.PutByte((Byte)(symbol - 0x100));

+  }

+

+

+The match length decoding

+-------------------------

+

+The match length decoder returns normalized (zero-based value) 

+length of match. That value can be converted to real length of the match 

+with the following code:

+

+#define kMatchMinLen 2

+

+    matchLen = len + kMatchMinLen;

+

+The match length decoder can return the values from 0 to 271.

+And the corresponded real match length values can be in the range 

+from 2 to 273.

+

+The following scheme is used for the match length encoding:

+

+  Binary encoding    Binary Tree structure    Zero-based match length 

+  sequence                                    (binary + decimal):

+

+  0 xxx              LowCoder[posState]       xxx

+  1 0 yyy            MidCoder[posState]       yyy + 8

+  1 1 zzzzzzzz       HighCoder                zzzzzzzz + 16

+

+LZMA uses bit model variable "Choice" to decode the first selection bit.

+

+If the first selection bit is equal to 0, the decoder uses binary tree 

+  LowCoder[posState] to decode 3-bit zero-based match length (xxx).

+

+If the first selection bit is equal to 1, the decoder uses bit model 

+  variable "Choice2" to decode the second selection bit.

+

+  If the second selection bit is equal to 0, the decoder uses binary tree 

+    MidCoder[posState] to decode 3-bit "yyy" value, and zero-based match

+    length is equal to (yyy + 8).

+

+  If the second selection bit is equal to 1, the decoder uses binary tree 

+    HighCoder to decode 8-bit "zzzzzzzz" value, and zero-based 

+    match length is equal to (zzzzzzzz + 16).

+

+LZMA uses "posState" value as context to select the binary tree 

+from LowCoder and MidCoder binary tree arrays:

+

+    unsigned posState = OutWindow.TotalPos & ((1 << pb) - 1);

+

+The full code of the length decoder:

+

+class CLenDecoder

+{

+  CProb Choice;

+  CProb Choice2;

+  CBitTreeDecoder<3> LowCoder[1 << kNumPosBitsMax];

+  CBitTreeDecoder<3> MidCoder[1 << kNumPosBitsMax];

+  CBitTreeDecoder<8> HighCoder;

+

+public:

+

+  void Init()

+  {

+    Choice = PROB_INIT_VAL;

+    Choice2 = PROB_INIT_VAL;

+    HighCoder.Init();

+    for (unsigned i = 0; i < (1 << kNumPosBitsMax); i++)

+    {

+      LowCoder[i].Init();

+      MidCoder[i].Init();

+    }

+  }

+

+  unsigned Decode(CRangeDecoder *rc, unsigned posState)

+  {

+    if (rc->DecodeBit(&Choice) == 0)

+      return LowCoder[posState].Decode(rc);

+    if (rc->DecodeBit(&Choice2) == 0)

+      return 8 + MidCoder[posState].Decode(rc);

+    return 16 + HighCoder.Decode(rc);

+  }

+};

+

+The LZMA decoder uses two instances of CLenDecoder class.

+The first instance is for the matches of "Simple Match" type,

+and the second instance is for the matches of "Rep Match" type:

+

+  CLenDecoder LenDecoder;

+  CLenDecoder RepLenDecoder;

+

+

+The match distance decoding

+---------------------------

+

+LZMA supports dictionary sizes up to 4 GiB minus 1.

+The value of match distance (decoded by distance decoder) can be 

+from 1 to 2^32. But the distance value that is equal to 2^32 is used to

+indicate the "End of stream" marker. So real largest match distance 

+that is used for LZ-window match is (2^32 - 1).

+

+LZMA uses normalized match length (zero-based length) 

+to calculate the context state "lenState" do decode the distance value:

+

+#define kNumLenToPosStates 4

+

+    unsigned lenState = len;

+    if (lenState > kNumLenToPosStates - 1)

+      lenState = kNumLenToPosStates - 1;

+

+The distance decoder returns the "dist" value that is zero-based value 

+of match distance. The real match distance can be calculated with the

+following code:

+  

+  matchDistance = dist + 1; 

+

+The state of the distance decoder and the initialization code: 

+

+  #define kEndPosModelIndex 14

+  #define kNumFullDistances (1 << (kEndPosModelIndex >> 1))

+  #define kNumAlignBits 4

+

+  CBitTreeDecoder<6> PosSlotDecoder[kNumLenToPosStates];

+  CProb PosDecoders[1 + kNumFullDistances - kEndPosModelIndex];

+  CBitTreeDecoder<kNumAlignBits> AlignDecoder;

+

+  void InitDist()

+  {

+    for (unsigned i = 0; i < kNumLenToPosStates; i++)

+      PosSlotDecoder[i].Init();

+    AlignDecoder.Init();

+    INIT_PROBS(PosDecoders);

+  }

+

+At first stage the distance decoder decodes 6-bit "posSlot" value with bit

+tree decoder from PosSlotDecoder array. It's possible to get 2^6=64 different 

+"posSlot" values.

+

+    unsigned posSlot = PosSlotDecoder[lenState].Decode(&RangeDec);

+

+The encoding scheme for distance value is shown in the following table:

+

+posSlot (decimal) /

+      zero-based distance (binary)

+ 0    0

+ 1    1

+ 2    10

+ 3    11

+

+ 4    10 x

+ 5    11 x

+ 6    10 xx

+ 7    11 xx

+ 8    10 xxx

+ 9    11 xxx

+10    10 xxxx

+11    11 xxxx

+12    10 xxxxx

+13    11 xxxxx

+

+14    10 yy zzzz

+15    11 yy zzzz

+16    10 yyy zzzz

+17    11 yyy zzzz

+...

+62    10 yyyyyyyyyyyyyyyyyyyyyyyyyy zzzz

+63    11 yyyyyyyyyyyyyyyyyyyyyyyyyy zzzz

+

+where 

+  "x ... x" means the sequence of binary symbols encoded with binary tree and 

+      "Reverse" scheme. It uses separated binary tree for each posSlot from 4 to 13.

+  "y" means direct bit encoded with range coder.

+  "zzzz" means the sequence of four binary symbols encoded with binary

+      tree with "Reverse" scheme, where one common binary tree "AlignDecoder"

+      is used for all posSlot values.

+

+If (posSlot < 4), the "dist" value is equal to posSlot value.

+

+If (posSlot >= 4), the decoder uses "posSlot" value to calculate the value of

+  the high bits of "dist" value and the number of the low bits.

+

+  If (4 <= posSlot < kEndPosModelIndex), the decoder uses bit tree decoders.

+    (one separated bit tree decoder per one posSlot value) and "Reverse" scheme.

+    In this implementation we use one CProb array "PosDecoders" that contains 

+    all CProb variables for all these bit decoders.

+  

+  if (posSlot >= kEndPosModelIndex), the middle bits are decoded as direct 

+    bits from RangeDecoder and the low 4 bits are decoded with a bit tree 

+    decoder "AlignDecoder" with "Reverse" scheme.

+

+The code to decode zero-based match distance:

+  

+  unsigned DecodeDistance(unsigned len)

+  {

+    unsigned lenState = len;

+    if (lenState > kNumLenToPosStates - 1)

+      lenState = kNumLenToPosStates - 1;

+    

+    unsigned posSlot = PosSlotDecoder[lenState].Decode(&RangeDec);

+    if (posSlot < 4)

+      return posSlot;

+    

+    unsigned numDirectBits = (unsigned)((posSlot >> 1) - 1);

+    UInt32 dist = ((2 | (posSlot & 1)) << numDirectBits);

+    if (posSlot < kEndPosModelIndex)

+      dist += BitTreeReverseDecode(PosDecoders + dist - posSlot, numDirectBits, &RangeDec);

+    else

+    {

+      dist += RangeDec.DecodeDirectBits(numDirectBits - kNumAlignBits) << kNumAlignBits;

+      dist += AlignDecoder.ReverseDecode(&RangeDec);

+    }

+    return dist;

+  }

+

+

+

+LZMA Decoding modes

+-------------------

+

+There are 2 types of LZMA streams:

+

+1) The stream with "End of stream" marker.

+2) The stream without "End of stream" marker.

+

+And the LZMA Decoder supports 3 modes of decoding:

+

+1) The unpack size is undefined. The LZMA decoder stops decoding after 

+   getting "End of stream" marker. 

+   The input variables for that case:

+    

+      markerIsMandatory = true

+      unpackSizeDefined = false

+      unpackSize contains any value

+

+2) The unpack size is defined and LZMA decoder supports both variants, 

+   where the stream can contain "End of stream" marker or the stream is

+   finished without "End of stream" marker. The LZMA decoder must detect 

+   any of these situations.

+   The input variables for that case:

+    

+      markerIsMandatory = false

+      unpackSizeDefined = true

+      unpackSize contains unpack size

+

+3) The unpack size is defined and the LZMA stream must contain 

+   "End of stream" marker

+   The input variables for that case:

+    

+      markerIsMandatory = true

+      unpackSizeDefined = true

+      unpackSize contains unpack size

+

+

+The main loop of decoder

+------------------------

+

+The main loop of LZMA decoder:

+

+Initialize the LZMA state.

+loop

+{

+  // begin of loop

+  Check "end of stream" conditions.

+  Decode Type of MATCH / LITERAL. 

+    If it's LITERAL, decode LITERAL value and put the LITERAL to Window.

+    If it's MATCH, decode the length of match and the match distance. 

+        Check error conditions, check end of stream conditions and copy

+        the sequence of match bytes from sliding window to current position

+        in window.

+  Go to begin of loop

+}

+

+The reference implementation of LZMA decoder uses "unpackSize" variable

+to keep the number of remaining bytes in output stream. So it reduces 

+"unpackSize" value after each decoded LITERAL or MATCH.

+

+The following code contains the "end of stream" condition check at the start

+of the loop:

+

+    if (unpackSizeDefined && unpackSize == 0 && !markerIsMandatory)

+      if (RangeDec.IsFinishedOK())

+        return LZMA_RES_FINISHED_WITHOUT_MARKER;

+

+LZMA uses three types of matches:

+

+1) "Simple Match" -     the match with distance value encoded with bit models.

+

+2) "Rep Match" -        the match that uses the distance from distance

+                        history table.

+

+3) "Short Rep Match" -  the match of single byte length, that uses the latest 

+                        distance from distance history table.

+

+The LZMA decoder keeps the history of latest 4 match distances that were used 

+by decoder. That set of 4 variables contains zero-based match distances and 

+these variables are initialized with zero values:

+

+  UInt32 rep0 = 0, rep1 = 0, rep2 = 0, rep3 = 0;

+

+The LZMA decoder uses binary model variables to select type of MATCH or LITERAL:

+

+#define kNumStates 12

+#define kNumPosBitsMax 4

+

+  CProb IsMatch[kNumStates << kNumPosBitsMax];

+  CProb IsRep[kNumStates];

+  CProb IsRepG0[kNumStates];

+  CProb IsRepG1[kNumStates];

+  CProb IsRepG2[kNumStates];

+  CProb IsRep0Long[kNumStates << kNumPosBitsMax];

+

+The decoder uses "state" variable value to select exact variable 

+from "IsRep", "IsRepG0", "IsRepG1" and "IsRepG2" arrays.

+The "state" variable can get the value from 0 to 11.

+Initial value for "state" variable is zero:

+

+  unsigned state = 0;

+

+The "state" variable is updated after each LITERAL or MATCH with one of the

+following functions:

+

+unsigned UpdateState_Literal(unsigned state)

+{

+  if (state < 4) return 0;

+  else if (state < 10) return state - 3;

+  else return state - 6;

+}

+unsigned UpdateState_Match   (unsigned state) { return state < 7 ? 7 : 10; }

+unsigned UpdateState_Rep     (unsigned state) { return state < 7 ? 8 : 11; }

+unsigned UpdateState_ShortRep(unsigned state) { return state < 7 ? 9 : 11; }

+

+The decoder calculates "state2" variable value to select exact variable from 

+"IsMatch" and "IsRep0Long" arrays:

+

+unsigned posState = OutWindow.TotalPos & ((1 << pb) - 1);

+unsigned state2 = (state << kNumPosBitsMax) + posState;

+

+The decoder uses the following code flow scheme to select exact 

+type of LITERAL or MATCH:

+

+IsMatch[state2] decode

+  0 - the Literal

+  1 - the Match

+    IsRep[state] decode

+      0 - Simple Match

+      1 - Rep Match

+        IsRepG0[state] decode

+          0 - the distance is rep0

+            IsRep0Long[state2] decode

+              0 - Short Rep Match

+              1 - Rep Match 0

+          1 - 

+            IsRepG1[state] decode

+              0 - Rep Match 1

+              1 - 

+                IsRepG2[state] decode

+                  0 - Rep Match 2

+                  1 - Rep Match 3

+

+

+LITERAL symbol

+--------------

+If the value "0" was decoded with IsMatch[state2] decoding, we have "LITERAL" type.

+

+At first the LZMA decoder must check that it doesn't exceed 

+specified uncompressed size:

+

+      if (unpackSizeDefined && unpackSize == 0)

+        return LZMA_RES_ERROR;

+

+Then it decodes literal value and puts it to sliding window:

+

+      DecodeLiteral(state, rep0);

+

+Then the decoder must update the "state" value and "unpackSize" value;

+

+      state = UpdateState_Literal(state);

+      unpackSize--;

+

+Then the decoder must go to the begin of main loop to decode next Match or Literal.

+

+

+Simple Match

+------------

+

+If the value "1" was decoded with IsMatch[state2] decoding,

+we have the "Simple Match" type.

+

+The distance history table is updated with the following scheme:

+    

+      rep3 = rep2;

+      rep2 = rep1;

+      rep1 = rep0;

+

+The zero-based length is decoded with "LenDecoder":

+

+      len = LenDecoder.Decode(&RangeDec, posState);

+

+The state is update with UpdateState_Match function:

+

+      state = UpdateState_Match(state);

+

+and the new "rep0" value is decoded with DecodeDistance:

+

+      rep0 = DecodeDistance(len);

+

+That "rep0" will be used as zero-based distance for current match.

+

+If the value of "rep0" is equal to 0xFFFFFFFF, it means that we have 

+"End of stream" marker, so we can stop decoding and check finishing 

+condition in Range Decoder:

+

+      if (rep0 == 0xFFFFFFFF)

+        return RangeDec.IsFinishedOK() ?

+            LZMA_RES_FINISHED_WITH_MARKER :

+            LZMA_RES_ERROR;

+

+If uncompressed size is defined, LZMA decoder must check that it doesn't 

+exceed that specified uncompressed size:

+

+      if (unpackSizeDefined && unpackSize == 0)

+        return LZMA_RES_ERROR;

+

+Also the decoder must check that "rep0" value is not larger than dictionary size

+and is not larger than the number of already decoded bytes:

+

+      if (rep0 >= dictSize || !OutWindow.CheckDistance(rep0))

+        return LZMA_RES_ERROR;

+

+Then the decoder must copy match bytes as described in 

+"The match symbols copying" section.

+

+

+Rep Match

+---------

+

+If the LZMA decoder has decoded the value "1" with IsRep[state] variable,

+we have "Rep Match" type.

+

+At first the LZMA decoder must check that it doesn't exceed 

+specified uncompressed size:

+

+      if (unpackSizeDefined && unpackSize == 0)

+        return LZMA_RES_ERROR;

+

+Also the decoder must return error, if the LZ window is empty:

+

+      if (OutWindow.IsEmpty())

+        return LZMA_RES_ERROR;

+

+If the match type is "Rep Match", the decoder uses one of the 4 variables of

+distance history table to get the value of distance for current match.

+And there are 4 corresponding ways of decoding flow. 

+

+The decoder updates the distance history with the following scheme 

+depending from type of match:

+

+- "Rep Match 0" or "Short Rep Match":

+      ; LZMA doesn't update the distance history    

+

+- "Rep Match 1":

+      UInt32 dist = rep1;

+      rep1 = rep0;

+      rep0 = dist;

+

+- "Rep Match 2":

+      UInt32 dist = rep2;

+      rep2 = rep1;

+      rep1 = rep0;

+      rep0 = dist;

+

+- "Rep Match 3":

+      UInt32 dist = rep3;

+      rep3 = rep2;

+      rep2 = rep1;

+      rep1 = rep0;

+      rep0 = dist;

+

+Then the decoder decodes exact subtype of "Rep Match" using "IsRepG0", "IsRep0Long",

+"IsRepG1", "IsRepG2".

+

+If the subtype is "Short Rep Match", the decoder updates the state, puts 

+the one byte from window to current position in window and goes to next 

+MATCH/LITERAL symbol (the begin of main loop):

+

+          state = UpdateState_ShortRep(state);

+          OutWindow.PutByte(OutWindow.GetByte(rep0 + 1));

+          unpackSize--;

+          continue;

+

+In other cases (Rep Match 0/1/2/3), it decodes the zero-based 

+length of match with "RepLenDecoder" decoder:

+

+      len = RepLenDecoder.Decode(&RangeDec, posState);

+

+Then it updates the state:

+

+      state = UpdateState_Rep(state);

+

+Then the decoder must copy match bytes as described in 

+"The Match symbols copying" section.

+

+

+The match symbols copying

+-------------------------

+

+If we have the match (Simple Match or Rep Match 0/1/2/3), the decoder must

+copy the sequence of bytes with calculated match distance and match length.

+If uncompressed size is defined, LZMA decoder must check that it doesn't 

+exceed that specified uncompressed size:

+

+    len += kMatchMinLen;

+    bool isError = false;

+    if (unpackSizeDefined && unpackSize < len)

+    {

+      len = (unsigned)unpackSize;

+      isError = true;

+    }

+    OutWindow.CopyMatch(rep0 + 1, len);

+    unpackSize -= len;

+    if (isError)

+      return LZMA_RES_ERROR;

+

+Then the decoder must go to the begin of main loop to decode next MATCH or LITERAL.

+

+

+

+NOTES

+-----

+

+This specification doesn't describe the variant of decoder implementation 

+that supports partial decoding. Such partial decoding case can require some 

+changes in "end of stream" condition checks code. Also such code 

+can use additional status codes, returned by decoder.

+

+This specification uses C++ code with templates to simplify describing.

+The optimized version of LZMA decoder doesn't need templates.

+Such optimized version can use just two arrays of CProb variables:

+  1) The dynamic array of CProb variables allocated for the Literal Decoder.

+  2) The one common array that contains all other CProb variables.

+

+

+References:      

+

+1. G. N. N. Martin, Range encoding: an algorithm for removing redundancy 

+   from a digitized message, Video & Data Recording Conference, 

+   Southampton, UK, July 24-27, 1979.