我在Windows下使用纯霍夫曼代码实现了一个简单的压缩器.但我不太了解如何快速解码压缩文件,我的错误算法是:
枚举代码表中的所有霍夫曼代码,然后将其与压缩文件中的位进行比较.结果是可怕的结果:解压缩3MB文件需要6个小时.
你能提供更高效的算法吗?我应该使用Hash还是什么?
更新:根据我朋友Lin的建议,我已经用状态表实现了解码器.我认为这种方法应该优于travesal huffman tree,6s内3MB.
谢谢.
优化二叉树方法的一种方法是使用查找表.您可以对表进行排列,以便直接查找特定的编码位模式,从而允许任何代码的最大可能位宽.
由于大多数代码不使用完整的最大宽度,因此它们包含在表中的多个位置 - 每个未使用位组合的一个位置.该表指示从输入丢弃的位数以及解码的输出.
如果最长的代码太长,那么该表是不切实际的,折衷方案是使用较小的固定宽度下标查找树.例如,您可以使用256项表来处理一个字节.如果输入代码超过8位,则表条目指示解码不完整,并将您引导至处理下一个最多8位的表.较大的表交换内存以获得速度 - 256项可能太小.
我相信这种通用方法称为"前缀表",是BobMcGees引用的代码所做的.一个可能的区别是一些压缩算法要求在解压缩期间更新前缀表 - 这对于简单的霍夫曼来说不是必需的.IIRC,我在一本关于位图图形文件格式的书中首次看到它,其中包括GIF,这是专利恐慌之前的一段时间.
从二叉树模型中预先计算完整查找表,哈希表等效项或小树表应该很容易.二叉树仍然是代码的关键表示 - 这个查找表只是优化.
为什么不看看GZIP源如何做到这一点,特别是具体的unpack.c中的Huffman解压缩代码?它正是你正在做的事情,除了它做得更快,更快.
据我所知,它使用查找数组和对整个单词进行操作的移位/掩码操作来运行得更快.虽然相当密集的代码.
编辑:这是完整的来源
/* unpack.c -- decompress files in pack format. * Copyright (C) 1992-1993 Jean-loup Gailly * This is free software; you can redistribute it and/or modify it under the * terms of the GNU General Public License, see the file COPYING. */ #ifdef RCSID static char rcsid[] = "$Id: unpack.c,v 1.4 1993/06/11 19:25:36 jloup Exp $"; #endif #include "tailor.h" #include "gzip.h" #include "crypt.h" #define MIN(a,b) ((a) <= (b) ? (a) : (b)) /* The arguments must not have side effects. */ #define MAX_BITLEN 25 /* Maximum length of Huffman codes. (Minor modifications to the code * would be needed to support 32 bits codes, but pack never generates * more than 24 bits anyway.) */ #define LITERALS 256 /* Number of literals, excluding the End of Block (EOB) code */ #define MAX_PEEK 12 /* Maximum number of 'peek' bits used to optimize traversal of the * Huffman tree. */ local ulg orig_len; /* original uncompressed length */ local int max_len; /* maximum bit length of Huffman codes */ local uch literal[LITERALS]; /* The literal bytes present in the Huffman tree. The EOB code is not * represented. */ local int lit_base[MAX_BITLEN+1]; /* All literals of a given bit length are contiguous in literal[] and * have contiguous codes. literal[code+lit_base[len]] is the literal * for a code of len bits. */ local int leaves [MAX_BITLEN+1]; /* Number of leaves for each bit length */ local int parents[MAX_BITLEN+1]; /* Number of parents for each bit length */ local int peek_bits; /* Number of peek bits currently used */ /* local uch prefix_len[1 << MAX_PEEK]; */ #define prefix_len outbuf /* For each bit pattern b of peek_bits bits, prefix_len[b] is the length * of the Huffman code starting with a prefix of b (upper bits), or 0 * if all codes of prefix b have more than peek_bits bits. It is not * necessary to have a huge table (large MAX_PEEK) because most of the * codes encountered in the input stream are short codes (by construction). * So for most codes a single lookup will be necessary. */ #if (1<OUTBUFSIZ error cannot overlay prefix_len and outbuf #endif local ulg bitbuf; /* Bits are added on the low part of bitbuf and read from the high part. */ local int valid; /* number of valid bits in bitbuf */ /* all bits above the last valid bit are always zero */ /* Set code to the next 'bits' input bits without skipping them. code * must be the name of a simple variable and bits must not have side effects. * IN assertions: bits <= 25 (so that we still have room for an extra byte * when valid is only 24), and mask = (1< > (valid-(bits))) & (mask); \ } /* Skip the given number of bits (after having peeked at them): */ #define skip_bits(bits) (valid -= (bits)) #define clear_bitbuf() (valid = 0, bitbuf = 0) /* Local functions */ local void read_tree OF((void)); local void build_tree OF((void)); /* =========================================================================== * Read the Huffman tree. */ local void read_tree() { int len; /* bit length */ int base; /* base offset for a sequence of leaves */ int n; /* Read the original input size, MSB first */ orig_len = 0; for (n = 1; n <= 4; n++) orig_len = (orig_len << 8) | (ulg)get_byte(); max_len = (int)get_byte(); /* maximum bit length of Huffman codes */ if (max_len > MAX_BITLEN) { error("invalid compressed data -- Huffman code > 32 bits"); } /* Get the number of leaves at each bit length */ n = 0; for (len = 1; len <= max_len; len++) { leaves[len] = (int)get_byte(); n += leaves[len]; } if (n > LITERALS) { error("too many leaves in Huffman tree"); } Trace((stderr, "orig_len %ld, max_len %d, leaves %d\n", orig_len, max_len, n)); /* There are at least 2 and at most 256 leaves of length max_len. * (Pack arbitrarily rejects empty files and files consisting of * a single byte even repeated.) To fit the last leaf count in a * byte, it is offset by 2. However, the last literal is the EOB * code, and is not transmitted explicitly in the tree, so we must * adjust here by one only. */ leaves[max_len]++; /* Now read the leaves themselves */ base = 0; for (len = 1; len <= max_len; len++) { /* Remember where the literals of this length start in literal[] : */ lit_base[len] = base; /* And read the literals: */ for (n = leaves[len]; n > 0; n--) { literal[base++] = (uch)get_byte(); } } leaves[max_len]++; /* Now include the EOB code in the Huffman tree */ } /* =========================================================================== * Build the Huffman tree and the prefix table. */ local void build_tree() { int nodes = 0; /* number of nodes (parents+leaves) at current bit length */ int len; /* current bit length */ uch *prefixp; /* pointer in prefix_len */ for (len = max_len; len >= 1; len--) { /* The number of parent nodes at this level is half the total * number of nodes at parent level: */ nodes >>= 1; parents[len] = nodes; /* Update lit_base by the appropriate bias to skip the parent nodes * (which are not represented in the literal array): */ lit_base[len] -= nodes; /* Restore nodes to be parents+leaves: */ nodes += leaves[len]; } /* Construct the prefix table, from shortest leaves to longest ones. * The shortest code is all ones, so we start at the end of the table. */ peek_bits = MIN(max_len, MAX_PEEK); prefixp = &prefix_len[1< prefix_len) *--prefixp = 0; } /* =========================================================================== * Unpack in to out. This routine does not support the old pack format * with magic header \037\037. * * IN assertions: the buffer inbuf contains already the beginning of * the compressed data, from offsets inptr to insize-1 included. * The magic header has already been checked. The output buffer is cleared. */ int unpack(in, out) int in, out; /* input and output file descriptors */ { int len; /* Bit length of current code */ unsigned eob; /* End Of Block code */ register unsigned peek; /* lookahead bits */ unsigned peek_mask; /* Mask for peek_bits bits */ ifd = in; ofd = out; read_tree(); /* Read the Huffman tree */ build_tree(); /* Build the prefix table */ clear_bitbuf(); /* Initialize bit input */ peek_mask = (1< 0) { peek >>= peek_bits - len; /* discard the extra bits */ } else { /* Code of more than peek_bits bits, we must traverse the tree */ ulg mask = peek_mask; len = peek_bits; do { len++, mask = (mask<<1)+1; look_bits(peek, len, mask); } while (peek < (unsigned)parents[len]); /* loop as long as peek is a parent node */ } /* At this point, peek is the next complete code, of len bits */ if (peek == eob && len == max_len) break; /* end of file? */ put_ubyte(literal[peek+lit_base[len]]); Tracev((stderr,"%02d %04x %c\n", len, peek, literal[peek+lit_base[len]])); skip_bits(len); } /* for (;;) */ flush_window(); Trace((stderr, "bytes_out %ld\n", bytes_out)); if (orig_len != (ulg)bytes_out) { error("invalid compressed data--length error"); } return OK; }