using System;
namespace BinaryObjectScanner.Models.Compression.MSZIP
{
///
/// Compression with fixed Huffman codes (BTYPE=01)
///
///
///
public class FixedHuffmanCompressedBlockHeader
{
#region Properties
///
/// Huffman code lengths for the literal / length alphabet
///
public uint[] LiteralLengths
{
get
{
// If we have cached lengths, use those
if (_literalLengths != null)
return _literalLengths;
// Otherwise, build it from scratch
_literalLengths = new uint[288];
// Literal Value 0 - 143, 8 bits
for (int i = 0; i < 144; i++)
_literalLengths[i] = 8;
// Literal Value 144 - 255, 9 bits
for (int i = 144; i < 256; i++)
_literalLengths[i] = 9;
// Literal Value 256 - 279, 7 bits
for (int i = 256; i < 280; i++)
_literalLengths[i] = 7;
// Literal Value 280 - 287, 8 bits
for (int i = 280; i < 288; i++)
_literalLengths[i] = 8;
return _literalLengths;
}
set
{
throw new FieldAccessException();
}
}
///
/// Huffman distance codes for the literal / length alphabet
///
public uint[] DistanceCodes
{
get
{
// If we have cached distances, use those
if (_distanceCodes != null)
return _distanceCodes;
// Otherwise, build it from scratch
_distanceCodes = new uint[30];
// Fixed length, 5 bits
for (int i = 0; i < 30; i++)
_distanceCodes[i] = 5;
return _distanceCodes;
}
set
{
throw new FieldAccessException();
}
}
#endregion
#region Instance Variables
///
/// Huffman code lengths for the literal / length alphabet
///
private uint[] _literalLengths = null;
///
/// Huffman distance codes for the literal / length alphabet
///
private uint[] _distanceCodes = null;
#endregion
}
}