/************************************************************************* * Name: huffman.c * Author: Marcus Geelnard * Description: Huffman coder/decoder implementation. * Reentrant: Yes * * This is a very straight forward implementation of a Huffman coder and * decoder. * * Primary flaws with this primitive implementation are: * - Slow bit stream implementation * - Maximum tree depth of 32 (the coder aborts if any code exceeds a * size of 32 bits). If I'm not mistaking, this should not be possible * unless the input buffer is larger than 2^32 bytes, which is not * supported by the coder anyway (max 2^32-1 bytes can be specified with * an unsigned 32-bit integer). * * On the other hand, there are a few advantages of this implementation: * - The Huffman tree is stored in a very compact form, requiring only * 10 bits per symbol (for 8 bit symbols), meaning a maximum of 320 * bytes overhead. * - The code should be fairly easy to follow, if you are familiar with * how the Huffman compression algorithm works. * * Possible improvements (probably not worth it): * - Partition the input data stream into blocks, where each block has * its own Huffman tree. With variable block sizes, it should be * possible to find locally optimal Huffman trees, which in turn could * reduce the total size. * - Allow for a few different predefined Huffman trees, which could * reduce the size of a block even further. *------------------------------------------------------------------------- * Copyright (c) 2003-2006 Marcus Geelnard * * This software is provided 'as-is', without any express or implied * warranty. In no event will the authors be held liable for any damages * arising from the use of this software. * * Permission is granted to anyone to use this software for any purpose, * including commercial applications, and to alter it and redistribute it * freely, subject to the following restrictions: * * 1. The origin of this software must not be misrepresented; you must not * claim that you wrote the original software. If you use this software * in a product, an acknowledgment in the product documentation would * be appreciated but is not required. * * 2. Altered source versions must be plainly marked as such, and must not * be misrepresented as being the original software. * * 3. This notice may not be removed or altered from any source * distribution. * * Marcus Geelnard * marcus.geelnard at home.se *************************************************************************/ /************************************************************************* * Types used for Huffman coding *************************************************************************/ typedef struct { unsigned char *BytePtr; unsigned int BitPos; } huff_bitstream_t; typedef struct { int Symbol; unsigned int Count; unsigned int Code; unsigned int Bits; } huff_sym_t; typedef struct huff_encodenode_struct huff_encodenode_t; struct huff_encodenode_struct { huff_encodenode_t *ChildA, *ChildB; int Count; int Symbol; }; typedef struct huff_decodenode_struct huff_decodenode_t; struct huff_decodenode_struct { huff_decodenode_t *ChildA, *ChildB; int Symbol; }; /************************************************************************* * Constants for Huffman decoding *************************************************************************/ /* The maximum number of nodes in the Huffman tree is 2^(8+1)-1 = 511 */ #define MAX_TREE_NODES 511 /************************************************************************* * _Huffman_InitBitstream() - Initialize a bitstream. *************************************************************************/ static void _Huffman_InitBitstream( huff_bitstream_t *stream, unsigned char *buf ) { stream->BytePtr = buf; stream->BitPos = 0; } /************************************************************************* * _Huffman_ReadBit() - Read one bit from a bitstream. *************************************************************************/ static unsigned int _Huffman_ReadBit( huff_bitstream_t *stream ) { unsigned int x, bit; unsigned char *buf; /* Get current stream state */ buf = stream->BytePtr; bit = stream->BitPos; /* Extract bit */ x = (*buf & (1<<(7-bit))) ? 1 : 0; bit = (bit+1) & 7; if ( !bit ) { ++ buf; } /* Store new stream state */ stream->BitPos = bit; stream->BytePtr = buf; return x; } /************************************************************************* * _Huffman_Read8Bits() - Read eight bits from a bitstream. *************************************************************************/ static unsigned int _Huffman_Read8Bits( huff_bitstream_t *stream ) { unsigned int x, bit; unsigned char *buf; /* Get current stream state */ buf = stream->BytePtr; bit = stream->BitPos; /* Extract byte */ x = (*buf << bit) | (buf[1] >> (8-bit)); ++ buf; /* Store new stream state */ stream->BytePtr = buf; return x; } /************************************************************************* * _Huffman_WriteBits() - Write bits to a bitstream. *************************************************************************/ #ifdef HUFFMAN_ENCODE static void _Huffman_WriteBits( huff_bitstream_t *stream, unsigned int x, unsigned int bits ) { unsigned int bit, count; unsigned char *buf; unsigned int mask; /* Get current stream state */ buf = stream->BytePtr; bit = stream->BitPos; /* Append bits */ mask = 1 << (bits-1); for ( count = 0; count < bits; ++ count ) { *buf = (unsigned char)((*buf & (0xff^(1<<(7-bit)))) + ((x & mask ? 1 : 0) << (7-bit))); x <<= 1; bit = (bit+1) & 7; if ( !bit ) { ++ buf; } } /* Store new stream state */ stream->BytePtr = buf; stream->BitPos = bit; } #endif /************************************************************************* * _Huffman_Hist() - Calculate (sorted) histogram for a block of data. *************************************************************************/ #ifdef HUFFMAN_ENCODE static void _Huffman_Hist( unsigned char *in, huff_sym_t *sym, unsigned int size ) { int k; /* Clear/init histogram */ for ( k = 0; k < 256; ++ k ) { sym[k].Symbol = k; sym[k].Count = 0; sym[k].Code = 0; sym[k].Bits = 0; } /* Build histogram */ for ( k = size; k; -- k ) { sym[*in ++].Count ++; } } #endif /************************************************************************* * _Huffman_StoreTree() - Store a Huffman tree in the output stream and * in a look-up-table (a symbol array). *************************************************************************/ #ifdef HUFFMAN_ENCODE static void _Huffman_StoreTree( huff_encodenode_t *node, huff_sym_t *sym, huff_bitstream_t *stream, unsigned int code, unsigned int bits ) { unsigned int sym_idx; /* Is this a leaf node? */ if ( node->Symbol >= 0 ) { /* Append symbol to tree description */ _Huffman_WriteBits( stream, 1, 1 ); _Huffman_WriteBits( stream, node->Symbol, 8 ); /* Find symbol index */ for ( sym_idx = 0; sym_idx < 256; ++ sym_idx ) { if ( sym[sym_idx].Symbol == node->Symbol ) break; } /* Store code info in symbol array */ sym[sym_idx].Code = code; sym[sym_idx].Bits = bits; return; } else { /* This was not a leaf node */ _Huffman_WriteBits( stream, 0, 1 ); } /* Branch A */ _Huffman_StoreTree( node->ChildA, sym, stream, (code<<1)+0, bits+1 ); /* Branch B */ _Huffman_StoreTree( node->ChildB, sym, stream, (code<<1)+1, bits+1 ); } #endif /************************************************************************* * _Huffman_MakeTree() - Generate a Huffman tree. *************************************************************************/ #ifdef HUFFMAN_ENCODE static void _Huffman_MakeTree( huff_sym_t *sym, huff_bitstream_t *stream ) { huff_encodenode_t nodes[MAX_TREE_NODES], *node_1, *node_2, *root; unsigned int k, num_symbols, nodes_left, next_idx; /* Initialize all leaf nodes */ num_symbols = 0; for ( k = 0; k < 256; ++ k ) { if ( sym[k].Count > 0 ) { nodes[num_symbols].Symbol = sym[k].Symbol; nodes[num_symbols].Count = sym[k].Count; nodes[num_symbols].ChildA = (huff_encodenode_t *) 0; nodes[num_symbols].ChildB = (huff_encodenode_t *) 0; ++ num_symbols; } } /* Build tree by joining the lightest nodes until there is only one node left (the root node). */ root = (huff_encodenode_t *) 0; nodes_left = num_symbols; next_idx = num_symbols; while( nodes_left > 1 ) { /* Find the two lightest nodes */ node_1 = (huff_encodenode_t *) 0; node_2 = (huff_encodenode_t *) 0; for ( k = 0; k < next_idx; ++ k ) { if ( nodes[k].Count > 0 ) { if ( !node_1 || (nodes[k].Count <= node_1->Count) ) { node_2 = node_1; node_1 = &nodes[k]; } else if ( !node_2 || (nodes[k].Count <= node_2->Count) ) { node_2 = &nodes[k]; } } } /* Join the two nodes into a new parent node */ root = &nodes[next_idx]; root->ChildA = node_1; root->ChildB = node_2; root->Count = node_1->Count + node_2->Count; root->Symbol = -1; node_1->Count = 0; node_2->Count = 0; ++ next_idx; -- nodes_left; } /* Store the tree in the output stream, and in the sym[] array (the latter is used as a look-up-table for faster encoding) */ if ( root ) { _Huffman_StoreTree( root, sym, stream, 0, 0 ); } else { /* Special case: only one symbol => no binary tree */ root = &nodes[0]; _Huffman_StoreTree( root, sym, stream, 0, 1 ); } } #endif /************************************************************************* * _Huffman_RecoverTree() - Recover a Huffman tree from a bitstream. *************************************************************************/ static huff_decodenode_t * _Huffman_RecoverTree( huff_decodenode_t *nodes, huff_bitstream_t *stream, unsigned int *nodenum ) { huff_decodenode_t * this_node; /* Pick a node from the node array */ this_node = &nodes[*nodenum]; *nodenum = *nodenum + 1; /* Clear the node */ this_node->Symbol = -1; this_node->ChildA = (huff_decodenode_t *) 0; this_node->ChildB = (huff_decodenode_t *) 0; /* Is this a leaf node? */ if ( _Huffman_ReadBit( stream ) ) { /* Get symbol from tree description and store in lead node */ this_node->Symbol = _Huffman_Read8Bits( stream ); return this_node; } /* Get branch A */ this_node->ChildA = _Huffman_RecoverTree( nodes, stream, nodenum ); /* Get branch B */ this_node->ChildB = _Huffman_RecoverTree( nodes, stream, nodenum ); return this_node; } /************************************************************************* * PUBLIC FUNCTIONS * *************************************************************************/ /************************************************************************* * Huffman_Compress() - Compress a block of data using a Huffman coder. * in - Input (uncompressed) buffer. * out - Output (compressed) buffer. This buffer must be 384 bytes * larger than the input buffer. * insize - Number of input bytes. * The function returns the size of the compressed data. *************************************************************************/ #ifdef HUFFMAN_ENCODE int Huffman_Compress( unsigned char *in, unsigned char *out, unsigned int insize ) { huff_sym_t sym[256], tmp; huff_bitstream_t stream; unsigned int k, total_bytes, swaps, symbol; /* Do we have anything to compress? */ if ( insize < 1 ) return 0; /* Initialize bitstream */ _Huffman_InitBitstream( &stream, out ); /* Calculate and sort histogram for input data */ _Huffman_Hist( in, sym, insize ); /* Build Huffman tree */ _Huffman_MakeTree( sym, &stream ); /* Sort histogram - first symbol first (bubble sort) */ do { swaps = 0; for ( k = 0; k < 255; ++ k ) { if ( sym[k].Symbol > sym[k+1].Symbol ) { tmp = sym[k]; sym[k] = sym[k+1]; sym[k+1] = tmp; swaps = 1; } } } while( swaps ); /* Encode input stream */ for ( k = 0; k < insize; ++ k ) { symbol = in[k]; _Huffman_WriteBits( &stream, sym[symbol].Code, sym[symbol].Bits ); } /* Calculate size of output data */ total_bytes = (int)(stream.BytePtr - out); if ( stream.BitPos > 0 ) { ++ total_bytes; } return total_bytes; } #endif /************************************************************************* * Huffman_Uncompress() - Uncompress a block of data using a Huffman * decoder. * in - Input (compressed) buffer. * out - Output (uncompressed) buffer. This buffer must be large * enough to hold the uncompressed data. * insize - Number of input bytes. * outsize - Number of output bytes. *************************************************************************/ void Huffman_Uncompress( unsigned char *in, unsigned char *out, unsigned int insize, unsigned int outsize ) { huff_decodenode_t nodes[MAX_TREE_NODES], *root, *node; huff_bitstream_t stream; unsigned int k, node_count; unsigned char *buf; /* Do we have anything to decompress? */ if ( insize < 1 ) return; /* Initialize bitstream */ _Huffman_InitBitstream( &stream, in ); /* Recover Huffman tree */ node_count = 0; root = _Huffman_RecoverTree( nodes, &stream, &node_count ); /* Decode input stream */ buf = out; for ( k = 0; k < outsize; ++ k ) { /* Traverse tree until we find a matching leaf node */ node = root; while( node->Symbol < 0 ) { /* Get next node */ if ( _Huffman_ReadBit( &stream ) ) node = node->ChildB; else node = node->ChildA; } /* We found the matching leaf node and have the symbol */ *buf ++ = (unsigned char) node->Symbol; } }