Mercurial > repos > SharpZipLib
view Zip/Compression/DeflaterHuffman.cs @ 1:94e25b786321
Re #311: can't read ZIP file packed by Linux app Archive Manager/File Roller
Initial commit of clean SharpZipLib 0860 source. Only change is build paths.
| author | IBBoard <dev@ibboard.co.uk> |
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| date | Sat, 30 Oct 2010 14:03:17 +0000 |
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// DeflaterHuffman.cs // // Copyright (C) 2001 Mike Krueger // Copyright (C) 2004 John Reilly // // This file was translated from java, it was part of the GNU Classpath // Copyright (C) 2001 Free Software Foundation, Inc. // // This program is free software; you can redistribute it and/or // modify it under the terms of the GNU General Public License // as published by the Free Software Foundation; either version 2 // of the License, or (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program; if not, write to the Free Software // Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. // // Linking this library statically or dynamically with other modules is // making a combined work based on this library. Thus, the terms and // conditions of the GNU General Public License cover the whole // combination. // // As a special exception, the copyright holders of this library give you // permission to link this library with independent modules to produce an // executable, regardless of the license terms of these independent // modules, and to copy and distribute the resulting executable under // terms of your choice, provided that you also meet, for each linked // independent module, the terms and conditions of the license of that // module. An independent module is a module which is not derived from // or based on this library. If you modify this library, you may extend // this exception to your version of the library, but you are not // obligated to do so. If you do not wish to do so, delete this // exception statement from your version. using System; namespace ICSharpCode.SharpZipLib.Zip.Compression { /// <summary> /// This is the DeflaterHuffman class. /// /// This class is <i>not</i> thread safe. This is inherent in the API, due /// to the split of Deflate and SetInput. /// /// author of the original java version : Jochen Hoenicke /// </summary> public class DeflaterHuffman { const int BUFSIZE = 1 << (DeflaterConstants.DEFAULT_MEM_LEVEL + 6); const int LITERAL_NUM = 286; // Number of distance codes const int DIST_NUM = 30; // Number of codes used to transfer bit lengths const int BITLEN_NUM = 19; // repeat previous bit length 3-6 times (2 bits of repeat count) const int REP_3_6 = 16; // repeat a zero length 3-10 times (3 bits of repeat count) const int REP_3_10 = 17; // repeat a zero length 11-138 times (7 bits of repeat count) const int REP_11_138 = 18; const int EOF_SYMBOL = 256; // The lengths of the bit length codes are sent in order of decreasing // probability, to avoid transmitting the lengths for unused bit length codes. static readonly int[] BL_ORDER = { 16, 17, 18, 0, 8, 7, 9, 6, 10, 5, 11, 4, 12, 3, 13, 2, 14, 1, 15 }; static readonly byte[] bit4Reverse = { 0, 8, 4, 12, 2, 10, 6, 14, 1, 9, 5, 13, 3, 11, 7, 15 }; static short[] staticLCodes; static byte[] staticLLength; static short[] staticDCodes; static byte[] staticDLength; class Tree { #region Instance Fields public short[] freqs; public byte[] length; public int minNumCodes; public int numCodes; short[] codes; int[] bl_counts; int maxLength; DeflaterHuffman dh; #endregion #region Constructors public Tree(DeflaterHuffman dh, int elems, int minCodes, int maxLength) { this.dh = dh; this.minNumCodes = minCodes; this.maxLength = maxLength; freqs = new short[elems]; bl_counts = new int[maxLength]; } #endregion /// <summary> /// Resets the internal state of the tree /// </summary> public void Reset() { for (int i = 0; i < freqs.Length; i++) { freqs[i] = 0; } codes = null; length = null; } public void WriteSymbol(int code) { // if (DeflaterConstants.DEBUGGING) { // freqs[code]--; // // Console.Write("writeSymbol("+freqs.length+","+code+"): "); // } dh.pending.WriteBits(codes[code] & 0xffff, length[code]); } /// <summary> /// Check that all frequencies are zero /// </summary> /// <exception cref="SharpZipBaseException"> /// At least one frequency is non-zero /// </exception> public void CheckEmpty() { bool empty = true; for (int i = 0; i < freqs.Length; i++) { if (freqs[i] != 0) { //Console.WriteLine("freqs[" + i + "] == " + freqs[i]); empty = false; } } if (!empty) { throw new SharpZipBaseException("!Empty"); } } /// <summary> /// Set static codes and length /// </summary> /// <param name="staticCodes">new codes</param> /// <param name="staticLengths">length for new codes</param> public void SetStaticCodes(short[] staticCodes, byte[] staticLengths) { codes = staticCodes; length = staticLengths; } /// <summary> /// Build dynamic codes and lengths /// </summary> public void BuildCodes() { int numSymbols = freqs.Length; int[] nextCode = new int[maxLength]; int code = 0; codes = new short[freqs.Length]; // if (DeflaterConstants.DEBUGGING) { // //Console.WriteLine("buildCodes: "+freqs.Length); // } for (int bits = 0; bits < maxLength; bits++) { nextCode[bits] = code; code += bl_counts[bits] << (15 - bits); // if (DeflaterConstants.DEBUGGING) { // //Console.WriteLine("bits: " + ( bits + 1) + " count: " + bl_counts[bits] // +" nextCode: "+code); // } } #if DebugDeflation if ( DeflaterConstants.DEBUGGING && (code != 65536) ) { throw new SharpZipBaseException("Inconsistent bl_counts!"); } #endif for (int i=0; i < numCodes; i++) { int bits = length[i]; if (bits > 0) { // if (DeflaterConstants.DEBUGGING) { // //Console.WriteLine("codes["+i+"] = rev(" + nextCode[bits-1]+"), // +bits); // } codes[i] = BitReverse(nextCode[bits-1]); nextCode[bits-1] += 1 << (16 - bits); } } } public void BuildTree() { int numSymbols = freqs.Length; /* heap is a priority queue, sorted by frequency, least frequent * nodes first. The heap is a binary tree, with the property, that * the parent node is smaller than both child nodes. This assures * that the smallest node is the first parent. * * The binary tree is encoded in an array: 0 is root node and * the nodes 2*n+1, 2*n+2 are the child nodes of node n. */ int[] heap = new int[numSymbols]; int heapLen = 0; int maxCode = 0; for (int n = 0; n < numSymbols; n++) { int freq = freqs[n]; if (freq != 0) { // Insert n into heap int pos = heapLen++; int ppos; while (pos > 0 && freqs[heap[ppos = (pos - 1) / 2]] > freq) { heap[pos] = heap[ppos]; pos = ppos; } heap[pos] = n; maxCode = n; } } /* We could encode a single literal with 0 bits but then we * don't see the literals. Therefore we force at least two * literals to avoid this case. We don't care about order in * this case, both literals get a 1 bit code. */ while (heapLen < 2) { int node = maxCode < 2 ? ++maxCode : 0; heap[heapLen++] = node; } numCodes = Math.Max(maxCode + 1, minNumCodes); int numLeafs = heapLen; int[] childs = new int[4 * heapLen - 2]; int[] values = new int[2 * heapLen - 1]; int numNodes = numLeafs; for (int i = 0; i < heapLen; i++) { int node = heap[i]; childs[2 * i] = node; childs[2 * i + 1] = -1; values[i] = freqs[node] << 8; heap[i] = i; } /* Construct the Huffman tree by repeatedly combining the least two * frequent nodes. */ do { int first = heap[0]; int last = heap[--heapLen]; // Propagate the hole to the leafs of the heap int ppos = 0; int path = 1; while (path < heapLen) { if (path + 1 < heapLen && values[heap[path]] > values[heap[path+1]]) { path++; } heap[ppos] = heap[path]; ppos = path; path = path * 2 + 1; } /* Now propagate the last element down along path. Normally * it shouldn't go too deep. */ int lastVal = values[last]; while ((path = ppos) > 0 && values[heap[ppos = (path - 1)/2]] > lastVal) { heap[path] = heap[ppos]; } heap[path] = last; int second = heap[0]; // Create a new node father of first and second last = numNodes++; childs[2 * last] = first; childs[2 * last + 1] = second; int mindepth = Math.Min(values[first] & 0xff, values[second] & 0xff); values[last] = lastVal = values[first] + values[second] - mindepth + 1; // Again, propagate the hole to the leafs ppos = 0; path = 1; while (path < heapLen) { if (path + 1 < heapLen && values[heap[path]] > values[heap[path+1]]) { path++; } heap[ppos] = heap[path]; ppos = path; path = ppos * 2 + 1; } // Now propagate the new element down along path while ((path = ppos) > 0 && values[heap[ppos = (path - 1)/2]] > lastVal) { heap[path] = heap[ppos]; } heap[path] = last; } while (heapLen > 1); if (heap[0] != childs.Length / 2 - 1) { throw new SharpZipBaseException("Heap invariant violated"); } BuildLength(childs); } /// <summary> /// Get encoded length /// </summary> /// <returns>Encoded length, the sum of frequencies * lengths</returns> public int GetEncodedLength() { int len = 0; for (int i = 0; i < freqs.Length; i++) { len += freqs[i] * length[i]; } return len; } /// <summary> /// Scan a literal or distance tree to determine the frequencies of the codes /// in the bit length tree. /// </summary> public void CalcBLFreq(Tree blTree) { int max_count; /* max repeat count */ int min_count; /* min repeat count */ int count; /* repeat count of the current code */ int curlen = -1; /* length of current code */ int i = 0; while (i < numCodes) { count = 1; int nextlen = length[i]; if (nextlen == 0) { max_count = 138; min_count = 3; } else { max_count = 6; min_count = 3; if (curlen != nextlen) { blTree.freqs[nextlen]++; count = 0; } } curlen = nextlen; i++; while (i < numCodes && curlen == length[i]) { i++; if (++count >= max_count) { break; } } if (count < min_count) { blTree.freqs[curlen] += (short)count; } else if (curlen != 0) { blTree.freqs[REP_3_6]++; } else if (count <= 10) { blTree.freqs[REP_3_10]++; } else { blTree.freqs[REP_11_138]++; } } } /// <summary> /// Write tree values /// </summary> /// <param name="blTree">Tree to write</param> public void WriteTree(Tree blTree) { int max_count; // max repeat count int min_count; // min repeat count int count; // repeat count of the current code int curlen = -1; // length of current code int i = 0; while (i < numCodes) { count = 1; int nextlen = length[i]; if (nextlen == 0) { max_count = 138; min_count = 3; } else { max_count = 6; min_count = 3; if (curlen != nextlen) { blTree.WriteSymbol(nextlen); count = 0; } } curlen = nextlen; i++; while (i < numCodes && curlen == length[i]) { i++; if (++count >= max_count) { break; } } if (count < min_count) { while (count-- > 0) { blTree.WriteSymbol(curlen); } } else if (curlen != 0) { blTree.WriteSymbol(REP_3_6); dh.pending.WriteBits(count - 3, 2); } else if (count <= 10) { blTree.WriteSymbol(REP_3_10); dh.pending.WriteBits(count - 3, 3); } else { blTree.WriteSymbol(REP_11_138); dh.pending.WriteBits(count - 11, 7); } } } void BuildLength(int[] childs) { this.length = new byte [freqs.Length]; int numNodes = childs.Length / 2; int numLeafs = (numNodes + 1) / 2; int overflow = 0; for (int i = 0; i < maxLength; i++) { bl_counts[i] = 0; } // First calculate optimal bit lengths int[] lengths = new int[numNodes]; lengths[numNodes-1] = 0; for (int i = numNodes - 1; i >= 0; i--) { if (childs[2 * i + 1] != -1) { int bitLength = lengths[i] + 1; if (bitLength > maxLength) { bitLength = maxLength; overflow++; } lengths[childs[2 * i]] = lengths[childs[2 * i + 1]] = bitLength; } else { // A leaf node int bitLength = lengths[i]; bl_counts[bitLength - 1]++; this.length[childs[2*i]] = (byte) lengths[i]; } } // if (DeflaterConstants.DEBUGGING) { // //Console.WriteLine("Tree "+freqs.Length+" lengths:"); // for (int i=0; i < numLeafs; i++) { // //Console.WriteLine("Node "+childs[2*i]+" freq: "+freqs[childs[2*i]] // + " len: "+length[childs[2*i]]); // } // } if (overflow == 0) { return; } int incrBitLen = maxLength - 1; do { // Find the first bit length which could increase: while (bl_counts[--incrBitLen] == 0) ; // Move this node one down and remove a corresponding // number of overflow nodes. do { bl_counts[incrBitLen]--; bl_counts[++incrBitLen]++; overflow -= 1 << (maxLength - 1 - incrBitLen); } while (overflow > 0 && incrBitLen < maxLength - 1); } while (overflow > 0); /* We may have overshot above. Move some nodes from maxLength to * maxLength-1 in that case. */ bl_counts[maxLength-1] += overflow; bl_counts[maxLength-2] -= overflow; /* Now recompute all bit lengths, scanning in increasing * frequency. It is simpler to reconstruct all lengths instead of * fixing only the wrong ones. This idea is taken from 'ar' * written by Haruhiko Okumura. * * The nodes were inserted with decreasing frequency into the childs * array. */ int nodePtr = 2 * numLeafs; for (int bits = maxLength; bits != 0; bits--) { int n = bl_counts[bits-1]; while (n > 0) { int childPtr = 2*childs[nodePtr++]; if (childs[childPtr + 1] == -1) { // We found another leaf length[childs[childPtr]] = (byte) bits; n--; } } } // if (DeflaterConstants.DEBUGGING) { // //Console.WriteLine("*** After overflow elimination. ***"); // for (int i=0; i < numLeafs; i++) { // //Console.WriteLine("Node "+childs[2*i]+" freq: "+freqs[childs[2*i]] // + " len: "+length[childs[2*i]]); // } // } } } #region Instance Fields /// <summary> /// Pending buffer to use /// </summary> public DeflaterPending pending; Tree literalTree; Tree distTree; Tree blTree; // Buffer for distances short[] d_buf; byte[] l_buf; int last_lit; int extra_bits; #endregion static DeflaterHuffman() { // See RFC 1951 3.2.6 // Literal codes staticLCodes = new short[LITERAL_NUM]; staticLLength = new byte[LITERAL_NUM]; int i = 0; while (i < 144) { staticLCodes[i] = BitReverse((0x030 + i) << 8); staticLLength[i++] = 8; } while (i < 256) { staticLCodes[i] = BitReverse((0x190 - 144 + i) << 7); staticLLength[i++] = 9; } while (i < 280) { staticLCodes[i] = BitReverse((0x000 - 256 + i) << 9); staticLLength[i++] = 7; } while (i < LITERAL_NUM) { staticLCodes[i] = BitReverse((0x0c0 - 280 + i) << 8); staticLLength[i++] = 8; } // Distance codes staticDCodes = new short[DIST_NUM]; staticDLength = new byte[DIST_NUM]; for (i = 0; i < DIST_NUM; i++) { staticDCodes[i] = BitReverse(i << 11); staticDLength[i] = 5; } } /// <summary> /// Construct instance with pending buffer /// </summary> /// <param name="pending">Pending buffer to use</param> public DeflaterHuffman(DeflaterPending pending) { this.pending = pending; literalTree = new Tree(this, LITERAL_NUM, 257, 15); distTree = new Tree(this, DIST_NUM, 1, 15); blTree = new Tree(this, BITLEN_NUM, 4, 7); d_buf = new short[BUFSIZE]; l_buf = new byte [BUFSIZE]; } /// <summary> /// Reset internal state /// </summary> public void Reset() { last_lit = 0; extra_bits = 0; literalTree.Reset(); distTree.Reset(); blTree.Reset(); } /// <summary> /// Write all trees to pending buffer /// </summary> /// <param name="blTreeCodes">The number/rank of treecodes to send.</param> public void SendAllTrees(int blTreeCodes) { blTree.BuildCodes(); literalTree.BuildCodes(); distTree.BuildCodes(); pending.WriteBits(literalTree.numCodes - 257, 5); pending.WriteBits(distTree.numCodes - 1, 5); pending.WriteBits(blTreeCodes - 4, 4); for (int rank = 0; rank < blTreeCodes; rank++) { pending.WriteBits(blTree.length[BL_ORDER[rank]], 3); } literalTree.WriteTree(blTree); distTree.WriteTree(blTree); #if DebugDeflation if (DeflaterConstants.DEBUGGING) { blTree.CheckEmpty(); } #endif } /// <summary> /// Compress current buffer writing data to pending buffer /// </summary> public void CompressBlock() { for (int i = 0; i < last_lit; i++) { int litlen = l_buf[i] & 0xff; int dist = d_buf[i]; if (dist-- != 0) { // if (DeflaterConstants.DEBUGGING) { // Console.Write("["+(dist+1)+","+(litlen+3)+"]: "); // } int lc = Lcode(litlen); literalTree.WriteSymbol(lc); int bits = (lc - 261) / 4; if (bits > 0 && bits <= 5) { pending.WriteBits(litlen & ((1 << bits) - 1), bits); } int dc = Dcode(dist); distTree.WriteSymbol(dc); bits = dc / 2 - 1; if (bits > 0) { pending.WriteBits(dist & ((1 << bits) - 1), bits); } } else { // if (DeflaterConstants.DEBUGGING) { // if (litlen > 32 && litlen < 127) { // Console.Write("("+(char)litlen+"): "); // } else { // Console.Write("{"+litlen+"}: "); // } // } literalTree.WriteSymbol(litlen); } } #if DebugDeflation if (DeflaterConstants.DEBUGGING) { Console.Write("EOF: "); } #endif literalTree.WriteSymbol(EOF_SYMBOL); #if DebugDeflation if (DeflaterConstants.DEBUGGING) { literalTree.CheckEmpty(); distTree.CheckEmpty(); } #endif } /// <summary> /// Flush block to output with no compression /// </summary> /// <param name="stored">Data to write</param> /// <param name="storedOffset">Index of first byte to write</param> /// <param name="storedLength">Count of bytes to write</param> /// <param name="lastBlock">True if this is the last block</param> public void FlushStoredBlock(byte[] stored, int storedOffset, int storedLength, bool lastBlock) { #if DebugDeflation // if (DeflaterConstants.DEBUGGING) { // //Console.WriteLine("Flushing stored block "+ storedLength); // } #endif pending.WriteBits((DeflaterConstants.STORED_BLOCK << 1) + (lastBlock ? 1 : 0), 3); pending.AlignToByte(); pending.WriteShort(storedLength); pending.WriteShort(~storedLength); pending.WriteBlock(stored, storedOffset, storedLength); Reset(); } /// <summary> /// Flush block to output with compression /// </summary> /// <param name="stored">Data to flush</param> /// <param name="storedOffset">Index of first byte to flush</param> /// <param name="storedLength">Count of bytes to flush</param> /// <param name="lastBlock">True if this is the last block</param> public void FlushBlock(byte[] stored, int storedOffset, int storedLength, bool lastBlock) { literalTree.freqs[EOF_SYMBOL]++; // Build trees literalTree.BuildTree(); distTree.BuildTree(); // Calculate bitlen frequency literalTree.CalcBLFreq(blTree); distTree.CalcBLFreq(blTree); // Build bitlen tree blTree.BuildTree(); int blTreeCodes = 4; for (int i = 18; i > blTreeCodes; i--) { if (blTree.length[BL_ORDER[i]] > 0) { blTreeCodes = i+1; } } int opt_len = 14 + blTreeCodes * 3 + blTree.GetEncodedLength() + literalTree.GetEncodedLength() + distTree.GetEncodedLength() + extra_bits; int static_len = extra_bits; for (int i = 0; i < LITERAL_NUM; i++) { static_len += literalTree.freqs[i] * staticLLength[i]; } for (int i = 0; i < DIST_NUM; i++) { static_len += distTree.freqs[i] * staticDLength[i]; } if (opt_len >= static_len) { // Force static trees opt_len = static_len; } if (storedOffset >= 0 && storedLength + 4 < opt_len >> 3) { // Store Block // if (DeflaterConstants.DEBUGGING) { // //Console.WriteLine("Storing, since " + storedLength + " < " + opt_len // + " <= " + static_len); // } FlushStoredBlock(stored, storedOffset, storedLength, lastBlock); } else if (opt_len == static_len) { // Encode with static tree pending.WriteBits((DeflaterConstants.STATIC_TREES << 1) + (lastBlock ? 1 : 0), 3); literalTree.SetStaticCodes(staticLCodes, staticLLength); distTree.SetStaticCodes(staticDCodes, staticDLength); CompressBlock(); Reset(); } else { // Encode with dynamic tree pending.WriteBits((DeflaterConstants.DYN_TREES << 1) + (lastBlock ? 1 : 0), 3); SendAllTrees(blTreeCodes); CompressBlock(); Reset(); } } /// <summary> /// Get value indicating if internal buffer is full /// </summary> /// <returns>true if buffer is full</returns> public bool IsFull() { return last_lit >= BUFSIZE; } /// <summary> /// Add literal to buffer /// </summary> /// <param name="literal">Literal value to add to buffer.</param> /// <returns>Value indicating internal buffer is full</returns> public bool TallyLit(int literal) { // if (DeflaterConstants.DEBUGGING) { // if (lit > 32 && lit < 127) { // //Console.WriteLine("("+(char)lit+")"); // } else { // //Console.WriteLine("{"+lit+"}"); // } // } d_buf[last_lit] = 0; l_buf[last_lit++] = (byte)literal; literalTree.freqs[literal]++; return IsFull(); } /// <summary> /// Add distance code and length to literal and distance trees /// </summary> /// <param name="distance">Distance code</param> /// <param name="length">Length</param> /// <returns>Value indicating if internal buffer is full</returns> public bool TallyDist(int distance, int length) { // if (DeflaterConstants.DEBUGGING) { // //Console.WriteLine("[" + distance + "," + length + "]"); // } d_buf[last_lit] = (short)distance; l_buf[last_lit++] = (byte)(length - 3); int lc = Lcode(length - 3); literalTree.freqs[lc]++; if (lc >= 265 && lc < 285) { extra_bits += (lc - 261) / 4; } int dc = Dcode(distance - 1); distTree.freqs[dc]++; if (dc >= 4) { extra_bits += dc / 2 - 1; } return IsFull(); } /// <summary> /// Reverse the bits of a 16 bit value. /// </summary> /// <param name="toReverse">Value to reverse bits</param> /// <returns>Value with bits reversed</returns> public static short BitReverse(int toReverse) { return (short) (bit4Reverse[toReverse & 0xF] << 12 | bit4Reverse[(toReverse >> 4) & 0xF] << 8 | bit4Reverse[(toReverse >> 8) & 0xF] << 4 | bit4Reverse[toReverse >> 12]); } static int Lcode(int length) { if (length == 255) { return 285; } int code = 257; while (length >= 8) { code += 4; length >>= 1; } return code + length; } static int Dcode(int distance) { int code = 0; while (distance >= 4) { code += 2; distance >>= 1; } return code + distance; } } }