/* * output.c * * General outputting routines */ #include "deflate.h" #include #include #include // // Output an element from the pre-tree // #define OUTPUT_PRETREE_ELEMENT(element) \ _ASSERT(pretree_len[element] != 0); \ outputBits(context, pretree_len[element], pretree_code[element]); // // Output the tree structure for a dynamic block // void outputTreeStructure(t_encoder_context *context, const BYTE *literal_tree_len, const BYTE *dist_tree_len) { int hdist, hlit, combined_tree_elements, i, pass; USHORT pretree_freq[NUM_PRETREE_ELEMENTS*2]; USHORT pretree_code[NUM_PRETREE_ELEMENTS]; byte pretree_len[NUM_PRETREE_ELEMENTS]; // // combined literal + distance length code array for outputting the trees // in compressed form // // +3 is so we can overflow the array when performing run length encoding // (dummy values are inserted at the end so that run length encoding fails // before falling off the end of the array) // BYTE lens[MAX_LITERAL_TREE_ELEMENTS + MAX_DIST_TREE_ELEMENTS + 3]; // // Calculate HDIST // for (hdist = MAX_DIST_TREE_ELEMENTS - 1; hdist >= 1; hdist--) { if (dist_tree_len[hdist] != 0) break; } hdist++; // // Calculate HLIT // for (hlit = MAX_LITERAL_TREE_ELEMENTS - 1; hlit >= 257; hlit--) { if (literal_tree_len[hlit] != 0) break; } hlit++; // // Now initialise the array to have all of the hlit and hdist codes // in it // combined_tree_elements = hdist + hlit; memcpy(lens, literal_tree_len, hlit); memcpy(&lens[hlit], dist_tree_len, hdist); // // Stick in some dummy values at the end so that we don't overflow the // array when comparing // for (i = combined_tree_elements; i < sizeof(lens); i++) lens[i] = -1; for (i = 0; i < NUM_PRETREE_ELEMENTS; i++) pretree_freq[i] = 0; // // Output the bitlengths in compressed (run length encoded) form. // // Make two passes; on the first pass count the various codes, create // the tree and output it, on the second pass output the codes using // the tree. // for (pass = 0; pass < 2; pass++) { int cur_element; // are we outputting during this pass? BOOL outputting = (pass == 1); cur_element = 0; while (cur_element < combined_tree_elements) { int curlen = lens[cur_element]; int run_length; // // See how many consecutive elements have the same value // // This won't run off the end of the array; it will hit the -1's // we stored there // for (run_length = cur_element+1; lens[run_length] == curlen; run_length++) ; run_length -= cur_element; // // For non-zero codes need 4 identical in a row (original code // plus 3 repeats). We decrement the run_length by one if the // code is not zero, since we don't count the first (original) // code in this case. // // For zero codes, need 3 zeroes in a row. // if (curlen != 0) run_length--; if (run_length < 3) { if (outputting) { OUTPUT_PRETREE_ELEMENT(curlen); } else pretree_freq[curlen]++; cur_element++; } else { // // Elements with zero values are encoded specially // if (curlen == 0) { // // Do we use code 17 (3-10 repeated zeroes) or // code 18 (11-138 repeated zeroes)? // if (run_length <= 10) { // code 17 if (outputting) { OUTPUT_PRETREE_ELEMENT(17); outputBits(context, 3, run_length - 3); } else { pretree_freq[17]++; } } else { // code 18 if (run_length > 138) run_length = 138; if (outputting) { OUTPUT_PRETREE_ELEMENT(18); outputBits(context, 7, run_length - 11); } else { pretree_freq[18]++; } } cur_element += run_length; } else { // // Number of lengths actually encoded. This may end up // being less than run_length if we have a run length of // 7 (6 + 1 [which cannot be encoded with a code 16]) // int run_length_encoded = 0; // curlen != 0 // can output 3...6 repeats of a non-zero code, so split // longer runs into short ones (if possible) // remember to output the code itself first! if (outputting) { OUTPUT_PRETREE_ELEMENT(curlen); while (run_length >= 3) { int this_run = (run_length <= 6) ? run_length : 6; OUTPUT_PRETREE_ELEMENT(16); outputBits(context, 2, this_run - 3); run_length_encoded += this_run; run_length -= this_run; } } else { pretree_freq[curlen]++; while (run_length >= 3) { int this_run = (run_length <= 6) ? run_length : 6; pretree_freq[16]++; run_length_encoded += this_run; run_length -= this_run; } } // +1 for the original code itself cur_element += (run_length_encoded+1); } } } // // If this is the first pass, create the pretree from the // frequency data and output it, as well as the values of // HLIT, HDIST, HDCLEN (# pretree codes used) // if (pass == 0) { int hclen, i; makeTree( NUM_PRETREE_ELEMENTS, 7, pretree_freq, pretree_code, pretree_len ); // // Calculate HCLEN // for (hclen = NUM_PRETREE_ELEMENTS-1; hclen >= 4; hclen--) { if (pretree_len[ g_CodeOrder[hclen] ] != 0) break; } hclen++; // // Dynamic block header // outputBits(context, 5, hlit - 257); outputBits(context, 5, hdist - 1); outputBits(context, 4, hclen - 4); for (i = 0; i < hclen; i++) { outputBits(context, 3, pretree_len[g_CodeOrder[i]]); } } } } // // bitwise i/o // void flushOutputBitBuffer(t_encoder_context *context) { if (context->bitcount > 0) { int prev_bitcount = context->bitcount; outputBits(context, 16 - context->bitcount, 0); // backtrack if we have to; ZIP is byte aligned, not 16-bit word aligned if (prev_bitcount <= 8) context->output_curpos--; } } // // Does not check for output overflow, so make sure to call checkOutputOverflow() // often enough! // void outputBits(t_encoder_context *context, int n, int x) { _ASSERT(context->output_curpos < context->output_endpos-1); _ASSERT(n > 0 && n <= 16); context->bitbuf |= (x << context->bitcount); context->bitcount += n; if (context->bitcount >= 16) { *context->output_curpos++ = (BYTE) context->bitbuf; *context->output_curpos++ = (BYTE) (context->bitbuf >> 8); context->bitbuf >>= 16; context->bitcount -= 16; } } // initialise the bit buffer void InitBitBuffer(t_encoder_context *context) { context->bitbuf = 0; context->bitcount = 0; } void OutputBlock(t_encoder_context *context) { _ASSERT(context->std_encoder != NULL || context->optimal_encoder != NULL); // we never call OutputBlock() with the fast encoder _ASSERT(context->fast_encoder == NULL); if (context->std_encoder != NULL) StdEncoderOutputBlock(context); else if (context->optimal_encoder != NULL) OptimalEncoderOutputBlock(context); } void FlushRecordingBuffer(t_encoder_context *context) { _ASSERT(context->std_encoder != NULL || context->optimal_encoder != NULL); _ASSERT(context->fast_encoder == NULL); // fast encoder does not record if (context->std_encoder != NULL) { *context->std_encoder->recording_bufptr++ = (BYTE) context->std_encoder->recording_bitbuf; *context->std_encoder->recording_bufptr++ = (BYTE) (context->std_encoder->recording_bitbuf >> 8); } else if (context->optimal_encoder != NULL) { *context->optimal_encoder->recording_bufptr++ = (BYTE) context->optimal_encoder->recording_bitbuf; *context->optimal_encoder->recording_bufptr++ = (BYTE) (context->optimal_encoder->recording_bitbuf >> 8); } }