private bool conjunct_sempred(ConjunctContext _localctx, int predIndex) {
		switch (predIndex) {
		case 1: return Precpred(Context, 1);
		}
		return true;
	}
	private ConjunctContext conjunct(int _p) {
		ParserRuleContext _parentctx = Context;
		int _parentState = State;
		ConjunctContext _localctx = new ConjunctContext(Context, _parentState);
		ConjunctContext _prevctx = _localctx;
		int _startState = 10;
		EnterRecursionRule(_localctx, 10, RULE_conjunct, _p);
		try {
			int _alt;
			EnterOuterAlt(_localctx, 1);
			{
			{
			State = 60; term();
			}
			Context.Stop = TokenStream.Lt(-1);
			State = 67;
			ErrorHandler.Sync(this);
			_alt = Interpreter.AdaptivePredict(TokenStream,5,Context);
			while ( _alt!=2 && _alt!=global::Antlr4.Runtime.Atn.ATN.InvalidAltNumber ) {
				if ( _alt==1 ) {
					if ( ParseListeners!=null )
						TriggerExitRuleEvent();
					_prevctx = _localctx;
					{
					{
					_localctx = new ConjunctContext(_parentctx, _parentState);
					PushNewRecursionContext(_localctx, _startState, RULE_conjunct);
					State = 62;
					if (!(Precpred(Context, 1))) throw new FailedPredicateException(this, "Precpred(Context, 1)");
					State = 63; Match(T__5);
					State = 64; term();
					}
					} 
				}
				State = 69;
				ErrorHandler.Sync(this);
				_alt = Interpreter.AdaptivePredict(TokenStream,5,Context);
			}
			}
		}
		catch (RecognitionException re) {
			_localctx.exception = re;
			ErrorHandler.ReportError(this, re);
			ErrorHandler.Recover(this, re);
		}
		finally {
			UnrollRecursionContexts(_parentctx);
		}
		return _localctx;
	}