@Override public IndexIterator iter(final IndexToken tok) { final byte k = tok.type() == IndexType.TEXT ? Data.TEXT : Data.ATTR; final int i = id(tok.get()); if (i > 0) { final int[] pres = ids[i]; final int s = len[i]; if (s > 0) { return new IndexIterator() { int p; @Override public boolean more() { return p < s; } @Override public int next() { while (more() && data.kind(pres[p++]) != k) ; return pres[p - 1]; } }; } } return IndexIterator.EMPTY; }
@Override public IndexIterator iter(final IndexToken token) { final int id = values.id(token.get()); if (id == 0) return IndexIterator.EMPTY; final int len = lenList.get(id); final int[] ids = idsList.get(id), pres; if (data.meta.updindex) { final IntList tmp = new IntList(); for (int i = 0; i < len; ++i) tmp.add(data.pre(ids[i])); pres = tmp.sort().finish(); } else { pres = ids; } return new IndexIterator() { int p; @Override public boolean more() { return p < len; } @Override public int pre() { return pres[p++]; } @Override public int size() { return len; } }; }
@Override public synchronized int costs(final IndexToken it) { final byte[] tok = it.get(); if (tok.length > data.meta.maxlen) return Integer.MAX_VALUE; // estimate costs for queries which stretch over multiple index entries final FTOpt opt = ((FTLexer) it).ftOpt(); if (opt.is(FZ) || opt.is(WC)) return Math.max(1, data.meta.size >> 4); return entry(tok).size; }
@Override public synchronized IndexIterator iter(final IndexToken it) { final byte[] tok = it.get(); // wildcard search final FTLexer lexer = (FTLexer) it; final FTOpt opt = lexer.ftOpt(); if (opt.is(WC)) return wc(tok); // fuzzy search if (opt.is(FZ)) return fuzzy(tok, lexer.lserror(tok)); // return cached or new result final IndexEntry e = entry(tok); return e.size > 0 ? iter(e.offset, e.size, inZ, tok) : FTIndexIterator.FTEMPTY; }
@Override public int costs(final IndexToken it) { return lenList.get(values.id(it.get())); }
@Override public int count(final IndexToken it) { final int i = id(it.get()); return i == 0 ? 0 : len[i]; }