protected Frag build() { Frag f = pattern.build(); if (minMatch == 1 && maxMatch == 1) { return f; } else if (minMatch <= 10 && maxMatch <= 10 && greedyMatch) { // Make copies if number of matches is low // Doesn't handle nongreedy matches yet // For non greedy match need to move curOut before the recursive connect // Create NFA fragment that // have child pattern repeating for minMatch times if (minMatch > 0) { // frag.start -> pattern NFA -> pattern NFA -> for (int i = 0; i < minMatch - 1; i++) { Frag f2 = pattern.build(); f.connect(f2); } } else { // minMatch is 0 // frag.start -> f = new Frag(new State()); } if (maxMatch < 0) { // Unlimited (loop back to self) // -------- // \|/ | // ---> pattern NFA ---> Set<State> curOut = f.out; Frag f2 = pattern.build(); f2.connect(f2); f.connect(f2); f.add(curOut); } else { // Limited number of times this pattern repeat, // just keep add pattern (with option of being done) until maxMatch reached // ----> pattern NFA ----> pattern NFA ---> // | | // --> ---> for (int i = minMatch; i < maxMatch; i++) { Set<State> curOut = f.out; Frag f2 = pattern.build(); f.connect(f2); f.add(curOut); } } return f; } else { // More general but more expensive matching (when branching, need to keep state explicitly) State s = new RepeatState(f.start, minMatch, maxMatch, greedyMatch); f.connect(s); return new Frag(s); } }
protected Frag build() { Frag frag = null; if (patterns.size() > 0) { PatternExpr first = patterns.get(0); frag = first.build(); for (int i = 1; i < patterns.size(); i++) { PatternExpr pattern = patterns.get(i); Frag f = pattern.build(); frag.connect(f); } } return frag; }
protected Frag build() { Frag frag = new Frag(); frag.start = new State(); // Create NFA fragment that // have one starting state that branches out to NFAs created by the children expressions // ---> pattern 1 ---> // | // ---> pattern 2 ---> // ... for (PatternExpr pattern : patterns) { // Build child NFA Frag f = pattern.build(); // Add child NFA to next states of fragment start frag.start.add(f.start); // Add child NFA out (unlinked) states to out (unlinked) states of this fragment frag.add(f.out); } return frag; }
protected Frag build() { ConjStartState conjStart = new ConjStartState(patterns.size()); Frag frag = new Frag(); frag.start = conjStart; // Create NFA fragment that // have one starting state that branches out to NFAs created by the children expressions // AND START ---> pattern 1 ---> AND END (0/n) // | // ---> pattern 2 ---> AND END (1/n) // ... for (int i = 0; i < patterns.size(); i++) { PatternExpr pattern = patterns.get(i); // Build child NFA Frag f = pattern.build(); // Add child NFA to next states of fragment start frag.start.add(f.start); f.connect(new ConjEndState(conjStart, i)); // Add child NFA out (unlinked) states to out (unlinked) states of this fragment frag.add(f.out); } return frag; }
protected Frag build() { Frag f = pattern.build(); Frag frag = new Frag(new GroupStartState(captureGroupId, f.start), f.out); frag.connect(new GroupEndState(captureGroupId)); return frag; }