/* * bsearch.c * * Binary search for optimal encoder */ #include "encoder.h" #define left context->enc_Left #define right context->enc_Right /* * Define this to force checking that all search locations visited * are valid. * * For debugging purposes only. */ #ifdef _DEBUG #define VERIFY_SEARCHES #endif #define VERIFY_SEARCH_CODE(routine_name) \ { \ int debug_search; \ for (debug_search = 0; debug_search < clen; debug_search++) \ { \ _ASSERTE( context->enc_MemWindow[ptr+debug_search] == context->enc_MemWindow[BufPos+debug_search]); \ } \ } #define VERIFY_MULTI_TREE_SEARCH_CODE(routine_name) \ _ASSERTE (context->enc_MemWindow[BufPos] == context->enc_MemWindow[ptr]); \ _ASSERTE (context->enc_MemWindow[BufPos+1] == context->enc_MemWindow[ptr+1]); /* * Finds the closest matches of all possible lengths, MIN_MATCH <= x <= MAX_MATCH, * at position BufPos. * * The positions of each match location are stored in context->enc_matchpos_table[] * * Returns the longest such match length found, or zero if no matches found. */ #ifndef ASM_BSEARCH_FINDMATCH long binary_search_findmatch(t_encoder_context *context, long BufPos) { ulong ptr; ulong a, b; ulong *small_ptr, *big_ptr; ulong end_pos; int val; /* must be signed */ int bytes_to_boundary; int clen; int same; int match_length; int small_len, big_len; int i, best_repeated_offset; #ifdef MULTIPLE_SEARCH_TREES ushort tree_to_use; /* * Retrieve root node of tree to search, and insert current node at * the root. */ tree_to_use = *((ushort UNALIGNED *) &context->enc_MemWindow[BufPos]); ptr = context->enc_tree_root[tree_to_use]; context->enc_tree_root[tree_to_use] = BufPos; #else ptr = context->enc_single_tree_root; context->enc_single_tree_root = BufPos; #endif /* * end_pos is the furthest location back we will search for matches * * Remember that our window size is reduced by 3 bytes because of * our repeated offset codes. * * Since BufPos starts at context->enc_window_size when compression begins, * end_pos will never become negative. */ end_pos = BufPos - (context->enc_window_size-4); /* * Root node is either NULL, or points to a really distant position. */ if (ptr <= end_pos) { left[BufPos] = right[BufPos] = 0; return 0; } #ifdef MULTIPLE_SEARCH_TREES /* * confirmed length (no need to check the first clen chars in a search) * * note: clen is always equal to min(small_len, big_len) */ clen = 2; /* * current best match length */ match_length = 2; /* * longest match which is < our string */ small_len = 2; /* * longest match which is > our string */ big_len = 2; /* * record match position for match length 2 */ context->enc_matchpos_table[2] = BufPos - ptr + 2; #ifdef VERIFY_SEARCHES VERIFY_MULTI_TREE_SEARCH_CODE("binary_search_findmatch()"); #endif #else /* !MULTIPLE_SEARCH_TREES */ clen = 0; match_length = 0; small_len = 0; big_len = 0; #endif /* MULTIPLE_SEARCH_TREES */ /* * pointers to nodes to check */ small_ptr = &left[BufPos]; big_ptr = &right[BufPos]; do { /* compare bytes at current node */ same = clen; #ifdef VERIFY_SEARCHES VERIFY_SEARCH_CODE("binary_search_findmatch()") #endif /* don't need to check first clen characters */ a = ptr + clen; b = BufPos + clen; while ((val = ((int) context->enc_MemWindow[a++]) - ((int) context->enc_MemWindow[b++])) == 0) { /* don't exceed MAX_MATCH */ if (++same >= MAX_MATCH) goto long_match; } if (val < 0) { if (same > big_len) { if (same > match_length) { long_match: do { context->enc_matchpos_table[++match_length] = BufPos-ptr+(NUM_REPEATED_OFFSETS-1); } while (match_length < same); if (same >= BREAK_LENGTH) { *small_ptr = left[ptr]; *big_ptr = right[ptr]; goto end_bsearch; } } big_len = same; clen = min(small_len, big_len); } *big_ptr = ptr; big_ptr = &left[ptr]; ptr = *big_ptr; } else { if (same > small_len) { if (same > match_length) { do { context->enc_matchpos_table[++match_length] = BufPos-ptr+(NUM_REPEATED_OFFSETS-1); } while (match_length < same); if (same >= BREAK_LENGTH) { *small_ptr = left[ptr]; *big_ptr = right[ptr]; goto end_bsearch; } } small_len = same; clen = min(small_len, big_len); } *small_ptr = ptr; small_ptr = &right[ptr]; ptr = *small_ptr; } } while (ptr > end_pos); /* while we don't go too far backwards */ *small_ptr = 0; *big_ptr = 0; end_bsearch: /* * If we have multiple search trees, we are already guaranteed * a minimum match length of 2 when we reach here. * * If we only have one tree, then we're not guaranteed anything. */ #ifndef MULTIPLE_SEARCH_TREES if (match_length < MIN_MATCH) return 0; #endif /* * Check to see if any of our match lengths can * use repeated offsets. */ /* * repeated offset 1 */ for (i = 0; i < match_length; i++) { if (context->enc_MemWindow[BufPos+i] != context->enc_MemWindow[BufPos-context->enc_last_matchpos_offset[0]+i]) break; } /* * the longest repeated offset */ best_repeated_offset = i; if (i >= MIN_MATCH) { /* * Yes, we can do a repeated offset for some match lengths; replace * their positions with the repeated offset position */ do { context->enc_matchpos_table[i] = 0; /* first repeated offset position */ } while (--i >= MIN_MATCH); /* A speed optimization to cope with long runs of bytes */ if (best_repeated_offset > BREAK_LENGTH) goto quick_return; } /* * repeated offset 2 */ for (i = 0; i < match_length; i++) { if (context->enc_MemWindow[BufPos+i] != context->enc_MemWindow[BufPos-context->enc_last_matchpos_offset[1]+i]) break; } /* * Does the second repeated offset provide a longer match? * * If so, leave the first repeated offset alone, but fill out the * difference in match lengths in the table with repeated offset 1. */ if (i > best_repeated_offset) { do { context->enc_matchpos_table[++best_repeated_offset] = 1; } while (best_repeated_offset < i); } /* * repeated offset 3 */ for (i = 0; i < match_length; i++) { if (context->enc_MemWindow[BufPos+i] != context->enc_MemWindow[BufPos-context->enc_last_matchpos_offset[2]+i]) break; } /* * Does the third repeated offset provide a longer match? */ if (i > best_repeated_offset) { do { context->enc_matchpos_table[++best_repeated_offset] = 2; } while (best_repeated_offset < i); } quick_return: /* * Don't let a match cross a 32K boundary */ bytes_to_boundary = (CHUNK_SIZE-1) - ((int) BufPos & (CHUNK_SIZE-1)); if (match_length > bytes_to_boundary) { match_length = bytes_to_boundary; if (match_length < MIN_MATCH) match_length = 0; } return (long) match_length; } #endif /* * Inserts the string at the current BufPos into the tree. * * Does not record all the best match lengths or otherwise attempt * to search for matches * * Similar to the above function. */ #ifndef ASM_QUICK_INSERT_BSEARCH_FINDMATCH void quick_insert_bsearch_findmatch(t_encoder_context *context, long BufPos, long end_pos) { long ptr; ulong a,b; ulong *small_ptr, *big_ptr; int val; int small_len, big_len; int same; int clen; #ifdef MULTIPLE_SEARCH_TREES ushort tree_to_use; tree_to_use = *((ushort UNALIGNED *) &context->enc_MemWindow[BufPos]); ptr = context->enc_tree_root[tree_to_use]; context->enc_tree_root[tree_to_use] = BufPos; #else ptr = context->enc_single_tree_root; context->enc_single_tree_root = BufPos; #endif if (ptr <= end_pos) { left[BufPos] = right[BufPos] = 0; return; } #ifdef MULTIPLE_SEARCH_TREES clen = 2; small_len = 2; big_len = 2; #ifdef VERIFY_SEARCHES VERIFY_MULTI_TREE_SEARCH_CODE("quick_insert_bsearch_findmatch()"); #endif #else clen = 0; small_len = 0; big_len = 0; #endif small_ptr = &left[BufPos]; big_ptr = &right[BufPos]; do { _ASSERTE ((ulong) ptr >= (ulong) (context->enc_RealLeft - context->enc_Left)); same = clen; a = ptr+clen; b = BufPos+clen; #ifdef VERIFY_SEARCHES VERIFY_SEARCH_CODE("quick_insert_bsearch_findmatch()") #endif while ((val = ((int) context->enc_MemWindow[a++]) - ((int) context->enc_MemWindow[b++])) == 0) { /* * Here we break on BREAK_LENGTH, not MAX_MATCH */ if (++same >= BREAK_LENGTH) break; } if (val < 0) { if (same > big_len) { if (same >= BREAK_LENGTH) { *small_ptr = left[ptr]; *big_ptr = right[ptr]; return; } big_len = same; clen = min(small_len, big_len); } *big_ptr = ptr; big_ptr = &left[ptr]; ptr = *big_ptr; } else { if (same > small_len) { if (same >= BREAK_LENGTH) { *small_ptr = left[ptr]; *big_ptr = right[ptr]; return; } small_len = same; clen = min(small_len, big_len); } *small_ptr = ptr; small_ptr = &right[ptr]; ptr = *small_ptr; } } while (ptr > end_pos); *small_ptr = 0; *big_ptr = 0; } #endif /* * Remove a node from the search tree; this is ONLY done for the last * BREAK_LENGTH symbols (see optenc.c). This is because we will have * inserted strings that contain undefined data (e.g. we're at the 4th * last byte from the file and binary_search_findmatch() a string into * the tree - everything from the 4th symbol onwards is invalid, and * would cause problems if it remained in the tree, so we have to * remove it). */ void binary_search_remove_node(t_encoder_context *context, long BufPos, ulong end_pos) { ulong ptr; ulong left_node_pos; ulong right_node_pos; ulong *link; #ifdef MULTIPLE_SEARCH_TREES ushort tree_to_use; /* * The root node of tree_to_use should equal BufPos, since that is * the most recent insertion into that tree - but if we never * inserted this string (because it was a near match or a long * string of zeroes), then we can't remove it. */ tree_to_use = *((ushort UNALIGNED *) &context->enc_MemWindow[BufPos]); /* * If we never inserted this string, do not attempt to remove it */ if (context->enc_tree_root[tree_to_use] != (ulong) BufPos) return; link = &context->enc_tree_root[tree_to_use]; #else if (context->enc_single_tree_root != (ulong) BufPos) return; link = &context->enc_single_tree_root; #endif /* * If the last occurence was too far away */ if (*link <= end_pos) { *link = 0; left[BufPos] = right[BufPos] = 0; return; } /* * Most recent location of these chars */ ptr = BufPos; /* * Most recent location of a string which is "less than" it */ left_node_pos = left[ptr]; if (left_node_pos <= end_pos) left_node_pos = left[ptr] = 0; /* * Most recent location of a string which is "greater than" it */ right_node_pos = right[ptr]; if (right_node_pos <= end_pos) right_node_pos = right[ptr] = 0; while (1) { #ifdef VERIFY_SEARCHES _ASSERTE (left_node_pos < (ulong) BufPos); _ASSERTE (right_node_pos < (ulong) BufPos); #endif /* * If left node position is greater than right node position * then follow the left node, since that is the more recent * insertion into the tree. Otherwise follow the right node. */ if (left_node_pos > right_node_pos) { /* * If it's too far away, then store that it never happened */ if (left_node_pos <= end_pos) left_node_pos = 0; ptr = *link = left_node_pos; if (!ptr) break; left_node_pos = right[ptr]; link = &right[ptr]; } else { /* * If it's too far away, then store that it never happened */ if (right_node_pos <= end_pos) right_node_pos = 0; ptr = *link = right_node_pos; if (!ptr) break; right_node_pos = left[ptr]; link = &left[ptr]; } } }