C# (CSharp) BabylonToHtml.SharpZipLib DeflaterHuffman示例

示例#1

文件： DeflaterHuffman.cs 项目： anasjaber/BabylonToHtml

 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];
 }

示例#2

文件： DeflaterEngine.cs 项目： anasjaber/BabylonToHtml

        /// <summary>
        /// Construct instance with pending buffer
        /// </summary>
        /// <param name="pending">
        /// Pending buffer to use
        /// </param>>
        public DeflaterEngine(DeflaterPending pending)
        {
            this.pending = pending;
            huffman = new DeflaterHuffman(pending);
            adler = new Adler32();

            window = new byte[2 * WSIZE];
            head = new short[HASH_SIZE];
            prev = new short[WSIZE];

            // We start at index 1, to avoid an implementation deficiency, that
            // we cannot build a repeat pattern at index 0.
            blockStart = strstart = 1;
        }

示例#3

        /// <summary>
        /// Construct instance with pending buffer
        /// </summary>
        /// <param name="pending">
        /// Pending buffer to use
        /// </param>>
        public DeflaterEngine(DeflaterPending pending)
        {
            this.pending = pending;
            huffman      = new DeflaterHuffman(pending);
            adler        = new Adler32();

            window = new byte[2 * WSIZE];
            head   = new short[HASH_SIZE];
            prev   = new short[WSIZE];

            // We start at index 1, to avoid an implementation deficiency, that
            // we cannot build a repeat pattern at index 0.
            blockStart = strstart = 1;
        }

示例#4

文件： InflaterHuffmanTree.cs 项目： yoandrygc/BabylonToHtml

        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));
            }
        }