using System; using ICSharpCode.SharpZipLib.Zip.Compression.Streams; namespace ICSharpCode.SharpZipLib.Zip.Compression { ///

/// Huffman tree used for inflation ///

public class InflaterHuffmanTree { #region Constants const int MAX_BITLEN = 15; #endregion #region Instance Fields short[] tree; #endregion ///

/// Literal length tree ///

public static InflaterHuffmanTree defLitLenTree; ///

/// Distance tree ///

public static InflaterHuffmanTree defDistTree; static InflaterHuffmanTree() { try { byte[] codeLengths = new byte[288]; int i = 0; while (i < 144) { codeLengths[i++] = 8; } while (i < 256) { codeLengths[i++] = 9; } while (i < 280) { codeLengths[i++] = 7; } while (i < 288) { codeLengths[i++] = 8; } defLitLenTree = new InflaterHuffmanTree(codeLengths); codeLengths = new byte[32]; i = 0; while (i < 32) { codeLengths[i++] = 5; } defDistTree = new InflaterHuffmanTree(codeLengths); } catch (Exception) { throw new SharpZipBaseException("InflaterHuffmanTree: static tree length illegal"); } } #region Constructors ///

/// Constructs a Huffman tree from the array of code lengths. ///

/// /// the array of code lengths /// public InflaterHuffmanTree(byte[] codeLengths) { BuildTree(codeLengths); } #endregion void BuildTree(byte[] codeLengths) { int[] blCount = new int[MAX_BITLEN + 1]; int[] nextCode = new int[MAX_BITLEN + 1]; for (int i = 0; i < codeLengths.Length; i++) { int bits = codeLengths[i]; if (bits > 0) { blCount[bits]++; } } int code = 0; int treeSize = 512; for (int bits = 1; bits <= MAX_BITLEN; bits++) { nextCode[bits] = code; code += blCount[bits] << (16 - bits); if (bits >= 10) { /* We need an extra table for bit lengths >= 10. */ int start = nextCode[bits] & 0x1ff80; int end = code & 0x1ff80; treeSize += (end - start) >> (16 - bits); } } /* -jr comment this out! doesnt work for dynamic trees and pkzip 2.04g if (code != 65536) { throw new SharpZipBaseException("Code lengths don't add up properly."); } */ /* Now create and fill the extra tables from longest to shortest * bit len. This way the sub trees will be aligned. */ tree = new short[treeSize]; int treePtr = 512; for (int bits = MAX_BITLEN; bits >= 10; bits--) { int end = code & 0x1ff80; code -= blCount[bits] << (16 - bits); int start = code & 0x1ff80; for (int i = start; i < end; i += 1 << 7) { tree[DeflaterHuffman.BitReverse(i)] = (short)((-treePtr << 4) | bits); treePtr += 1 << (bits - 9); } } for (int i = 0; i < codeLengths.Length; i++) { int bits = codeLengths[i]; if (bits == 0) { continue; } code = nextCode[bits]; int revcode = DeflaterHuffman.BitReverse(code); if (bits <= 9) { do { tree[revcode] = (short)((i << 4) | bits); revcode += 1 << bits; } while (revcode < 512); } else { int subTree = tree[revcode & 511]; int treeLen = 1 << (subTree & 15); subTree = -(subTree >> 4); do { tree[subTree | (revcode >> 9)] = (short)((i << 4) | bits); revcode += 1 << bits; } while (revcode < treeLen); } nextCode[bits] = code + (1 << (16 - bits)); } } ///

/// Reads the next symbol from input. The symbol is encoded using the /// huffman tree. ///

/// /// input the input source. /// /// /// the next symbol, or -1 if not enough input is available. /// public int GetSymbol(StreamManipulator input) { int lookahead, symbol; if ((lookahead = input.PeekBits(9)) >= 0) { if ((symbol = tree[lookahead]) >= 0) { input.DropBits(symbol & 15); return symbol >> 4; } int subtree = -(symbol >> 4); int bitlen = symbol & 15; if ((lookahead = input.PeekBits(bitlen)) >= 0) { symbol = tree[subtree | (lookahead >> 9)]; input.DropBits(symbol & 15); return symbol >> 4; } else { int bits = input.AvailableBits; lookahead = input.PeekBits(bits); symbol = tree[subtree | (lookahead >> 9)]; if ((symbol & 15) <= bits) { input.DropBits(symbol & 15); return symbol >> 4; } else { return -1; } } } else { int bits = input.AvailableBits; lookahead = input.PeekBits(bits); symbol = tree[lookahead]; if (symbol >= 0 && (symbol & 15) <= bits) { input.DropBits(symbol & 15); return symbol >> 4; } else { return -1; } } } } }