internal static Component ToComponent(Evaluatable thing) { if (thing is Expression) { return ToComponent((Expression)thing); } if (thing is Component) { return ToComponent((Component)thing); } if (thing is Factor) { return ToComponent((Factor)thing); } if (thing is ComponentListFactor) { var clf = (ComponentListFactor)thing; if (clf.IsInNumerator) { return ToComponent(clf.Factor); } return new SingleFactorComponent(new ExpressionFactor(new SingleComponentExpression(new ComponentList(new List<ComponentListFactor> { clf })))); } throw new UnexpectedTypeException(thing.GetType()); }
public override bool Equals(Evaluatable other) { var clf = other as ComponentListFactor; if (clf != null) { return IsInNumerator == clf.IsInNumerator && Factor.Equals(clf.Factor); } return false; }
public QueryBrowser(IHandlerRegistry handlerRegistry, Evaluatable evaluatable) { InitializeComponent(); _handlerRegistry = handlerRegistry; _evaluatable = evaluatable; evaluatableBrowser.Evaluatable = evaluatable; evaluatableBrowser.SelectedItemChanged += evaluatableBrowser_SelectedItemChanged; Application.Idle += Application_OnIdle; }
public override bool Equals(Evaluatable other) { var componentList = other as ComponentList; if (componentList != null) { if (Factors.Count < componentList.Factors.Count || Factors.Count > componentList.Factors.Count) return false; return !Factors.Where((t, i) => !t.Equals(componentList.Factors[i])).Any(); } return false; }
public override bool Equals(Evaluatable other) { var fc = other as FunctionComponent; if (fc != null) { return Function.Name == fc.Function.Name && !fc.Operands.Where((t, i) => !t.Equals(fc.Operands[i])).Any(); } return false; }
internal static bool IsFunction(Evaluatable evaluatable, out FunctionComponent function) { var component = Componentizer.ToComponent(evaluatable); if (component is FunctionComponent) { function = (FunctionComponent)component; return true; } function = null; return false; }
public override bool Equals(Evaluatable other) { var dfc = other as DualFactorComponent; if (dfc != null) { return LeftFactor.Equals(dfc.LeftFactor) && RightFactor.Equals(dfc.RightFactor) && IsMultiply == dfc.IsMultiply; } return false; }
internal static bool IsList(Evaluatable input, out ExpressionList output) { var factor = Factorizer.ToFactor(input); if (factor is ExpressionList) { output = (ExpressionList)factor; return true; } output = null; return false; }
internal static bool IsConstant(Evaluatable expression, out Number value) { var factor = Factorizer.ToFactor(expression); if (factor is AlphabeticFactor) { var name = ((AlphabeticFactor)factor).Value; if (Constants.IsNamedConstant(name)) { value = new Float(Constants.Get(name)); return true; } } value = Integer.Zero; return false; }
internal static bool IsIntegerFraction(Evaluatable evaluatable, out IntegerFraction fraction) { var component = Componentizer.ToComponent(evaluatable); if (component is IntegerFraction) { fraction = (IntegerFraction)component; return true; } var factor = Factorizer.ToFactor(evaluatable); if (factor is NumericFactor) { var number = ((NumericFactor)factor).Number; if (number is Integer) { fraction = new IntegerFraction((Integer)number); return true; } } fraction = null; return false; }
public override bool Equals(Evaluatable other) { var sf = other as StringFactor; return sf != null && _value == sf._value; }
public override bool Equals(Evaluatable other) { throw new System.NotImplementedException(); }
private static Expression Evaluate(ExpressionList leftNumber, Evaluatable right, bool isMultiply) { return Expressionizer.ToExpression(new ExpressionList(leftNumber.Expressions.Select(e => new DualFactorComponent(Factorizer.ToFactor(e), Factorizer.ToFactor(right), isMultiply).Evaluate()).ToList())); }
private Expression EvaluateExponent(Evaluatable left, Evaluatable right) { // ln(a ^ b) = b * ln(a) return new DualFactorComponent( Factorizer.ToFactor(right.Evaluate()), Factorizer.ToFactor(new FunctionComponent(Name, new List<Expression> { left.Evaluate() })), true).Evaluate(); }
private Expression EvaluateMultiplication(Evaluatable left, Evaluatable right) { // ln(a * b) = ln(a) + ln(b) return new DualComponentExpression( Componentizer.ToComponent(new FunctionComponent(Name, new List<Expression> { left.Evaluate() }).Evaluate()), Componentizer.ToComponent(new FunctionComponent(Name, new List<Expression> { right.Evaluate() }).Evaluate()), true).Evaluate(); }
public Boolean_FlipFlopT(Evaluatable <bool> toggle) => Toggle = toggle;
public static OverrideLogicBuilder EnabledWhen(Evaluatable <bool> condition) { return(new OverrideLogicBuilder().SetDynamicBoolean("_Enabled", condition)); }
internal static bool IsFloat(Evaluatable evaluatable, out Number number) { return IsNumber(evaluatable, out number) && number is Float; }
internal static bool IsNumber(Evaluatable evaluatable, out Number number) { return IsNumber(Componentizer.ToComponent(evaluatable), out number); }
public FunctionInstance(Robot robot, Evaluatable eval, FunctionInstance[] functionArgs) { this.robot = robot; this.eval = eval; this.functionArgs = functionArgs; }
public override bool Equals(Evaluatable other) { return other is UndefinedExpression; }
public override bool Equals(Evaluatable other) { var af = other as AlphabeticFactor; return af != null && Value == af.Value; }
private static string ToString(Evaluatable expression, bool isBase) { var asFactor = Factorizer.ToFactor(expression); if (expression is DualComponentExpression || (isBase && (asFactor as NumericFactor)?.Number is Float)) { return string.Format("({0})", expression); } var component = Componentizer.ToComponent(expression); if (component is DualFactorComponent || component is ComponentList) { var output = expression.ToString(); if (output.Contains("(")) { return string.Format("({0})", expression); } } return expression.ToString(); }
public DelayString(Evaluatable <string> source, double delay) : base(source, delay) { }
public override bool Equals(Evaluatable other) { var sfc = other as SingleFactorComponent; return sfc != null && Factor.Equals(sfc.Factor); }
public override bool Equals(Evaluatable other) { var sce = other as SingleComponentExpression; return sce != null && Component.Equals(sce.Component); }
private Expression EvaluateDivision(Evaluatable left, Evaluatable right) { // ln(a / b) = ln(a) - ln(b) return new DualComponentExpression( Componentizer.ToComponent(new FunctionComponent(Name, new List<Expression> { left.Evaluate() }).Evaluate()), Componentizer.ToComponent(new FunctionComponent(Name, new List<Expression> { right.Evaluate() }).Evaluate()), false).Evaluate(); }
protected internal override void Deserialize(BinaryReaderEx br, List <string> classNames) { StateIndex = br.ReadInt32(); Evaluator = Evaluatable.Read(br, classNames); }
public override bool Equals(Evaluatable other) { var frac = other as IntegerFraction; if (frac != null) { } return false; }
private static Expression Evaluate(ExpressionList leftNumber, Evaluatable right) { return Expressionizer.ToExpression(new ExpressionList(leftNumber.Expressions.Select(e => new Exponent().Evaluate(e, Expressionizer.ToExpression(right)).Evaluate()).ToList())); }
public DelayBoolean(Evaluatable <bool> source, double delay) : base(source, delay) { }
public override bool Equals(Evaluatable other) { var nf = other as NumericFactor; return nf != null && Number.Equals(nf.Number); }
public override bool Equals(Evaluatable other) { var ef = other as ExpressionFactor; return ef != null && Expression.Equals(ef.Expression); }
public DelayNumeric(Evaluatable <double> source, double delay) : base(source, delay) { }
protected internal override void Deserialize(BinaryReaderEx br, List <string> classNames) { base.Deserialize(br, classNames); Right = Evaluatable.Read(br, classNames); Left = Evaluatable.Read(br, classNames); }
public override bool Equals(Evaluatable other) { var dce = other as DualComponentExpression; if (dce != null) { return _leftComponent.Equals(dce._leftComponent) && _rightComponent.Equals(dce._rightComponent) && _isAdd == dce._isAdd; } return false; }