public void DéfinirUneClasseRealisantUneMultiplication()
{
var multiplication = new Multiplication();
Check.That(multiplication.PeutCalculer("2*3")).IsTrue();
Check.That(multiplication.PeutCalculer("2+3")).IsFalse();
Check.That(multiplication.Calculer("2*3")).IsEqualTo(6);
}
public void Multiplication_Works()
{
var multiplication = new Multiplication();
var result = multiplication.Execute(3,4);
Assert.AreEqual(12, result);
}
public override TreeNodeBase DeepCopy()
{
TreeNodeBase left = LeftOperand.DeepCopy();
TreeNodeBase right = RightOperand.DeepCopy();
Multiplication node = new Multiplication
{
LeftOperand = left,
RightOperand = right
};
return node;
}
private IExpression GetAdd(ParserContext ctx)
{
skipWhiteSpace(ctx);
var t = GetMul(ctx);
skipWhiteSpace(ctx);
while (skipCharacter('*', ctx))
{
t = new Multiplication(t, GetMul(ctx));
skipWhiteSpace(ctx);
}
return(t);
}
public void DéfinirUneInterfaceStrategieAvec2ImplémentationsPrécédentesPasséesEnParamètreDUneClasseCliente()
{
var multiplication = new Multiplication();
var somme = new Somme();
// La classe Calculatrice ne doit pas analyser l'opération reçue dans la méthode Calculer, elle doit s'appuyer sur les 2 implémentations passées en paramètre du constructeur
var calculatrice = new Calculatrice(new IOperation[] { multiplication, somme });
var resultatSomme = calculatrice.Calculer("1+2");
var resultatProduit = calculatrice.Calculer("2*3");
Check.That(resultatProduit).IsEqualTo(6);
Check.That(resultatSomme).IsEqualTo(3);
}
public Operation Optimize(Operation operation, IFunctionRegistry functionRegistry)
{
if (!operation.DependsOnVariables && operation.GetType() != typeof(UnitNumberConstant) &&
operation.GetType() != typeof(FloatingPointConstant))
{
var result = executor.Execute(operation, functionRegistry);
if (result.DataType == DataType.Number)
{
return(new FloatingPointConstant((double)result.Value));
}
else
{
return(new UnitNumberConstant((UnitNumber)result.Value));
}
}
else
{
if (operation.GetType() == typeof(Addition))
{
Addition addition = (Addition)operation;
addition.Argument1 = Optimize(addition.Argument1, functionRegistry);
addition.Argument2 = Optimize(addition.Argument2, functionRegistry);
}
else if (operation.GetType() == typeof(Subtraction))
{
Subtraction substraction = (Subtraction)operation;
substraction.Argument1 = Optimize(substraction.Argument1, functionRegistry);
substraction.Argument2 = Optimize(substraction.Argument2, functionRegistry);
}
else if (operation.GetType() == typeof(Multiplication))
{
Multiplication multiplication = (Multiplication)operation;
multiplication.Argument1 = Optimize(multiplication.Argument1, functionRegistry);
multiplication.Argument2 = Optimize(multiplication.Argument2, functionRegistry);
}
else if (operation.GetType() == typeof(Division))
{
Division division = (Division)operation;
division.Dividend = Optimize(division.Dividend, functionRegistry);
division.Divisor = Optimize(division.Divisor, functionRegistry);
}
else if (operation.GetType() == typeof(Exponentiation))
{
Exponentiation division = (Exponentiation)operation;
division.Base = Optimize(division.Base, functionRegistry);
division.Exponent = Optimize(division.Exponent, functionRegistry);
}
return(operation);
}
}
/// <summary>
/// Builds an expression from its prefix notation.
/// </summary>
///
/// <param name="prefixNotation">The prefix notation of the expression.</param>
///
/// <returns>
/// The abstract syntax tree representing the expression.
/// </returns>
static Expression buildExpressionFromPrefixNotation(string[] prefixNotation)
{
// The stack is used to build the abstract syntax tree of the expression.
Stack <Expression> stack = new Stack <Expression>();
Expression expression = null;
// Process all tokens of the expression.
foreach (String token in prefixNotation)
{
// Determine and create the expression.
switch (token)
{
case "+":
expression = new Plus();
break;
case "-":
expression = new Minus();
break;
case "*":
expression = new Multiplication();
break;
case "/":
expression = new Division();
break;
default:
int value = Int32.Parse(token);
expression = new Operand(value);
break;
}
// Push the expression onto the stack.
stack.Push(expression);
if (expression is Operand)
{
processStack(stack);
}
}
// Return the top of the stack.
return(stack.Peek());
}
static void Main(string[] args)
{
/// Expression: 1 + 5 * (4 - 3) * (2 + 1 / 2)
/// Composite 1: 1 + 5 * (4 - 3) * (2 + 1 / 2)
/// Number 1: 1
/// Operator 1: +
/// Composite 2: 5 * (4 - 3) * (2 + 1 / 2)
/// Number 2: 5
/// Operator 2: *
/// Composite 3: (4 - 3) * (2 + 1 / 2)
/// Composite 4: 4 - 3
/// Number 3: 4
/// Operator 3: -
/// Number 4: 3
/// Operator 4: *
/// Composite 5: 2 + 1 / 2
/// Number 5: 2
/// Operator 5: +
/// Composite 6: 1 / 2
/// Number 6: 1
/// Operator 6: /
/// Number 7: 2
NumbericOperand number7 = new NumbericOperand(2);
Operator operator6 = new Division();
NumbericOperand number6 = new NumbericOperand(1);
CompositeOperand composite6 = new CompositeOperand(number6, number7, operator6);
NumbericOperand number5 = new NumbericOperand(2);
Operator operator5 = new Summation();
CompositeOperand composite5 = new CompositeOperand(number5, composite6, operator5);
NumbericOperand number3 = new NumbericOperand(4);
Operator operator3 = new Subtraction();
NumbericOperand number4 = new NumbericOperand(3);
CompositeOperand composite4 = new CompositeOperand(number3, number4, operator3);
Operator operator4 = new Multiplication();
CompositeOperand composite3 = new CompositeOperand(composite4, composite5, operator4);
NumbericOperand number2 = new NumbericOperand(5);
Operator operator2 = new Multiplication();
CompositeOperand composite2 = new CompositeOperand(number2, composite3, operator2);
NumbericOperand number1 = new NumbericOperand(1);
Operator operator1 = new Summation();
CompositeOperand composite1 = new CompositeOperand(number1, composite2, operator1);
Console.WriteLine("1 + 5 * (4 - 3) * (2 + 1 / 2) = " + composite1.Calculate());
}
static void Main(string[] args)
{
Multiplication _multiplication = new Multiplication();
BigInteger test = _multiplication.Multiply("3141592653589793238462643383279502884197169399375105820974944592", "2718281828459045235360287471352662497757247093699959574966967627");
Console.WriteLine(test);
using (StreamWriter sw = new StreamWriter("answer.txt"))
{
sw.WriteLine(test);
}
Console.ReadKey();
}
public void MultiplicationZerosMatrixDouble()
{
var a = Matrix <double> .CreateZeroMatrix(3, 7);
var b = Matrix <double> .CreateZeroMatrix(7, 5);
var resultMatr = Matrix <double> .CreateZeroMatrix(3, 5);
var mult = new Multiplication <double>(a, b);
var c = mult.Calculate();
Assert.AreEqual(resultMatr, c);
}
public void TestBuildFormula1()
{
IFunctionRegistry registry = new MockFunctionRegistry();
AstBuilder builder = new AstBuilder(registry);
Operation operation = builder.Build(new List <Token>()
{
new Token()
{
Value = '(', TokenType = TokenType.LeftBracket
},
new Token()
{
Value = 42, TokenType = TokenType.Integer
},
new Token()
{
Value = '+', TokenType = TokenType.Operation
},
new Token()
{
Value = 8, TokenType = TokenType.Integer
},
new Token()
{
Value = ')', TokenType = TokenType.RightBracket
},
new Token()
{
Value = '*', TokenType = TokenType.Operation
},
new Token()
{
Value = 2, TokenType = TokenType.Integer
}
});
Multiplication multiplication = (Multiplication)operation;
Addition addition = (Addition)multiplication.Argument1;
#if !NETCORE
Assert.AreEqual(42, ((Constant <int>)addition.Argument1).Value);
Assert.AreEqual(8, ((Constant <int>)addition.Argument2).Value);
Assert.AreEqual(2, ((Constant <int>)multiplication.Argument2).Value);
#else
Assert.Equal(42, ((Constant <int>)addition.Argument1).Value);
Assert.Equal(8, ((Constant <int>)addition.Argument2).Value);
Assert.Equal(2, ((Constant <int>)multiplication.Argument2).Value);
#endif
}
public void TestSinFunction3()
{
AstBuilder builder = new AstBuilder();
Operation operation = builder.Build(new List <Token>()
{
new Token()
{
Value = "sin", TokenType = TokenType.Text
},
new Token()
{
Value = '(', TokenType = TokenType.LeftBracket
},
new Token()
{
Value = 2, TokenType = TokenType.Integer
},
new Token()
{
Value = '+', TokenType = TokenType.Operation
},
new Token()
{
Value = 3, TokenType = TokenType.Integer
},
new Token()
{
Value = ')', TokenType = TokenType.RightBracket
},
new Token()
{
Value = '*', TokenType = TokenType.Operation
},
new Token()
{
Value = 4.9, TokenType = TokenType.FloatingPoint
}
});
Multiplication multiplication = (Multiplication)operation;
Function sineFunction = (Function)multiplication.Argument1;
Addition addition = (Addition)sineFunction.Arguments.Single();
Assert.AreEqual(new IntegerConstant(2), addition.Argument1);
Assert.AreEqual(new IntegerConstant(3), addition.Argument2);
Assert.AreEqual(new FloatingPointConstant(4.9), multiplication.Argument2);
}
public void TestMultiplication_DecimalInt32()
{
ComplexField multiplication = new Multiplication();
Field operand1 = new LiteralField("Decimal", "operand1", "3000");
Field operand2 = new LiteralField("Int32", "operand2", "-1");
Field operand3 = new LiteralField("Decimal", "operand3", "3");
multiplication.AddField(operand1).AddField(operand2).AddField(operand3);
Decimal multiplicationResult = (Decimal)multiplication.GetValue(null);
Decimal expected = new Decimal(-9000);
Assert.AreEqual <Decimal>(expected, multiplicationResult);
}
public static void CanReduceOneTimesXToJustX()
{
var transform = GenerateOneTimesXToXTransform();
var input = new Multiplication(
Numbers.One,
Operations.AdditionWithVariable
);
var expected = Operations.AdditionWithVariable;
var result = transform.Transform(input);
Assert.AreEqual(expected, result);
Assert.AreNotEqual(input, result);
}
public void PowerSimplifier_Changes_Multiplication_To_Power_If_Multiplication_Sides_Are_Of_Same_Value()
{
var input = new Multiplication {
Left = new Constant {
Value = 13
}, Right = new Constant {
Value = 13
}
};
var result = mUnderTest.Simplify(input);
result.Should().BeOfType <Power>().Which.Left.Should().BeOfType <Constant>().Which.Value.Should().Be(13);
result.Should().BeOfType <Power>().Which.Right.Should().BeOfType <Constant>().Which.Value.Should().Be(2);
}
public RSA()
{
var primeNumbers = SieveAtkin.GetPrimeNumbers(limit: 10000000U).ToArray();
var random = new Random();
var p = GetRandomPrime(primeNumbers, random);
var q = GetRandomPrime(primeNumbers, random);
var modulus = Multiplication.Karatsuba(p, q);
var totient = modulus - (p + q - 1); // Euler`s function
var publicExponent = GetRandomPrime(primeNumbers, random);
var privateExponent = GetModularMultiplicativeInverse(publicExponent, totient);
PrivateKey = new Key(modulus, privateExponent);
PublicKey = new Key(modulus, publicExponent);
}
public void Visit(Multiplication multiplication)
{
var leftConstant = multiplication.Left as Constant;
var rightConstant = multiplication.Right as Constant;
if (leftConstant != null && leftConstant.Value == 0M)
{
mNeedsToBeSetToZero = multiplication;
}
else if (rightConstant != null && rightConstant.Value == 0M)
{
mNeedsToBeSetToZero = multiplication;
}
CheckForParentsAndReplaceIfNecessary();
}
public async Task TestPostingNewMultiplyBatch()
{
var jsonInString = "{\"BatchCount\":5,\"NumberPerBatch\": 2}";
var postResponse = await _client.PostAsync("api/orders/", new StringContent(jsonInString, Encoding.UTF8, "application/json"));
postResponse.EnsureSuccessStatusCode();
var body = postResponse.Content.ReadAsStringAsync().Result;
var jObject = JObject.Parse(body);
var batch = new Multiplication((Guid)jObject["orderId"], "1", 123, 222);
var jsonBody = JsonConvert.SerializeObject(batch);
var response = await _client.PostAsync("api/Multiply", new StringContent(jsonBody, Encoding.UTF8, "application/json"));
response.EnsureSuccessStatusCode();
}
private void GetVariables(Operation operation, List <Variable> variables)
{
if (operation.DependsOnVariables)
{
if (operation.GetType() == typeof(Variable))
{
variables.Add((Variable)operation);
}
else if (operation.GetType() == typeof(Addition))
{
Addition addition = (Addition)operation;
GetVariables(addition.Argument1, variables);
GetVariables(addition.Argument2, variables);
}
else if (operation.GetType() == typeof(Multiplication))
{
Multiplication multiplication = (Multiplication)operation;
GetVariables(multiplication.Argument1, variables);
GetVariables(multiplication.Argument2, variables);
}
else if (operation.GetType() == typeof(Subtraction))
{
Subtraction substraction = (Subtraction)operation;
GetVariables(substraction.Argument1, variables);
GetVariables(substraction.Argument2, variables);
}
else if (operation.GetType() == typeof(Division))
{
Division division = (Division)operation;
GetVariables(division.Dividend, variables);
GetVariables(division.Divisor, variables);
}
else if (operation.GetType() == typeof(Exponentiation))
{
Exponentiation exponentiation = (Exponentiation)operation;
GetVariables(exponentiation.Base, variables);
GetVariables(exponentiation.Exponent, variables);
}
else if (operation.GetType() == typeof(Function))
{
Function function = (Function)operation;
foreach (Operation argument in function.Arguments)
{
GetVariables(argument, variables);
}
}
}
}
public void Multiplication_By_One_With_One_As_Right_Side_Returns_Copy_Of_Left_Side()
{
var input = new Multiplication {
Right = new Constant {
Value = 1
}, Left = new Variable {
Name = "x"
}
};
var underTest = new NeutralElementEliminatingSimplifier();
var output = underTest.Simplify(input);
output.Should().BeOfType <Variable>().Which.Name.Should().Be("x");
output.Should().NotBeSameAs(input.Left);
}
public Node ExprMul()
{
Node expressionPow = ExprPow();
while (multiplicationOperators.Contains(CurrentToken))
{
Node expressionMul = new Multiplication()
{
AnchorToken = OpMul()
};
expressionMul.Add(expressionPow);
expressionMul.Add(ExprPow());
return(expressionMul);
}
return(expressionPow);
}
public void OperatorPrecedenceForMultiplicationAndDivisionShouldBeHigherThanAdditionAndSubtraction()
{
// ReSharper disable once HeapView.ObjectAllocation.Evident
var addition = new Addition();
// ReSharper disable once HeapView.ObjectAllocation.Evident
var subtraction = new Subtraction();
// ReSharper disable once HeapView.ObjectAllocation.Evident
var multiplication = new Multiplication();
// ReSharper disable once HeapView.ObjectAllocation.Evident
var division = new Division();
Assert.IsTrue(multiplication.GetPrecedence() > addition.GetPrecedence());
Assert.IsTrue(multiplication.GetPrecedence() > subtraction.GetPrecedence());
Assert.IsTrue(division.GetPrecedence() > addition.GetPrecedence());
Assert.IsTrue(division.GetPrecedence() > subtraction.GetPrecedence());
}
public Example MakeExample(int i)
{
Example ex = new Summ();
switch (i)
{
case 0: ex = new Summ(); break;
case 1: ex = new DifferenceEx(); break;
case 2: ex = new Multiplication(); break;
case 3: ex = new Division(); break;
}
return(ex);
}
/// <summary>
/// To find the percentage of a number
/// </summary>
/// <returns>
/// Percentage of number
/// </returns>
public double CalcPercentage(string currentNumber, string currentExpression)
{
//Calculating the number from which to find the percentage
this.currentExpression = currentExpression;
pos = 0;
UniversalOperation number = ParsingAnExpression_LowPriority();
//Calculate the percentage which to find
this.currentExpression = currentNumber;
pos = 0;
UniversalOperation percent = ParsingAnExpression_LowPriority();
//Calculating the percentage of a number
UniversalOperation result = new Multiplication(new Division(number, new Number(100)), percent);
return(result.Operation());
}
public override BaseExpression VisitMultiplication(Multiplication multiplication)
{
// f*g -> f*g` + f`*g
var f = multiplication.Lhs;
var g = multiplication.Rhs;
return(new Addition(
lhs: new Multiplication(
f,
this.VisitExpressionNode(g)
),
rhs: new Multiplication(
this.VisitExpressionNode(f),
g
)
));
}
//[TestMethod]
//[DataRow(5.0, 7.39, 36.95)]
public void MultiplicationDoubleTest(double num1, double num2, double expected)
{
//arrange:
double result = 0;
Multiplication obj = new Multiplication();
//act:
result = obj.Calculate(num1, num2);
//assert:
string strMessage = string.Format("Input: {0} * {1} = {2}. Expected: {3}",
num1, num2, result, expected
);
Assert.AreEqual(expected, result, strMessage);
}
public async Task MultiplyAsync(CancellationToken token, Guid orderId, string batchId, int generatedNumber)
{
token.ThrowIfCancellationRequested();
_logger.Log(LogLevel.Information,
$"Started Multiply Simulated work, batch number:'{batchId}', generated number: '{generatedNumber} the order id is: '{orderId}'");
var factor = GenerateRandomInt(2, 4);
var delay = GenerateRandomInt(5, 10);
var multipliedNumber = factor * generatedNumber;
Thread.Sleep(delay * 1000);
var model = new Multiplication(orderId, batchId, generatedNumber, multipliedNumber);
var path = _section["MultiplyPath"];
_logger.Log(LogLevel.Information, $"Multiply work completed for batch Id '{batchId}', Multiplied number is:{multipliedNumber} the order id is: '{orderId}'");
_serverClient.PostAsync(token, model, path);
}
public void Multiplication_Of_Same_Variables_Is_Replaced_With_Square()
{
var input = new Multiplication()
{
Left = new Variable()
{
Name = "x"
}, Right = new Variable()
{
Name = "x"
}
};
var result = mUnderTest.Simplify(input);
result.Should().BeOfType <Power>().Which.Left.Should().BeOfType <Variable>().Which.Name.Should().Be("x");
result.Should().BeOfType <Power>().Which.Right.Should().BeOfType <Constant>().Which.Value.Should().Be(2);
}
public void Multiplication_With_Sinus_And_Cosine_Doesnt_Change_To_Power_Even_Though_The_Value_Is_The_Same()
{
var input = new Multiplication()
{
Left = new Sinus()
{
Value = 0
}, Right = new Cosine()
{
Value = 0
}
};
var result = mUnderTest.Simplify(input);
result.Should().BeOfType <Multiplication>().Which.Left.Should().BeOfType <Sinus>().Which.Value.Should().Be(0);
result.Should().BeOfType <Multiplication>().Which.Right.Should().BeOfType <Cosine>().Which.Value.Should().Be(0);
}
public void Multiplication_Of_Different_Variables_Is_Not_Replaced_With_Square()
{
var input = new Multiplication()
{
Left = new Variable()
{
Name = "x"
}, Right = new Variable()
{
Name = "y"
}
};
var result = mUnderTest.Simplify(input);
result.Should().BeOfType <Multiplication>().Which.Left.Should().BeOfType <Variable>().Which.Name.Should().Be("x");
result.Should().BeOfType <Multiplication>().Which.Right.Should().BeOfType <Variable>().Which.Name.Should().Be("y");
}
public void Simple_Case()
{
var input = new Multiplication
{
Left =
new ParenthesedExpression
{
Wrapped = new Addition {
Left = new Constant {
Value = 13
}, Right = new Constant {
Value = 17
}
}
},
Right = new Constant {
Value = 2
}
};
var result = mUnderTest.Simplify(input);
result.Should()
.BeOfType <Addition>()
.Which.Left.Should()
.BeOfType <Multiplication>()
.Which.Left.Should()
.BeOfType <Constant>().Which.Value.Should().Be(13);
result.Should()
.BeOfType <Addition>()
.Which.Left.Should()
.BeOfType <Multiplication>()
.Which.Right.Should()
.BeOfType <Constant>().Which.Value.Should().Be(2);
result.Should()
.BeOfType <Addition>()
.Which.Right.Should()
.BeOfType <Multiplication>()
.Which.Left.Should()
.BeOfType <Constant>().Which.Value.Should().Be(17);
result.Should()
.BeOfType <Addition>()
.Which.Right.Should()
.BeOfType <Multiplication>()
.Which.Right.Should()
.BeOfType <Constant>().Which.Value.Should().Be(2);
}
public void Multiplication_With_Tangents_Changes_To_Power_If_The_Value_Is_The_Same()
{
var input = new Multiplication()
{
Left = new Tangent()
{
Value = 13
}, Right = new Tangent()
{
Value = 13
}
};
var result = mUnderTest.Simplify(input);
result.Should().BeOfType <Power>().Which.Left.Should().BeOfType <Tangent>().Which.Value.Should().Be(13);
result.Should().BeOfType <Power>().Which.Right.Should().BeOfType <Constant>().Which.Value.Should().Be(2);
}
public void Multiplication_CheckResult()
{
//Arrange
decimal a = 4m;
decimal b = 2m;
decimal expectedResult = 8m;
Multiplication op = new Multiplication()
{
op1 = a, op2 = b
};
//Act
decimal response = op.CalculateResult();
//Assert
Assert.AreEqual(expectedResult, response);
}
// / A
// / |)
// / | )
// / | )
// Q------- O---X---) D
// \ | )
// \ | )
// \ |)
// \ C
//
// Inscribed Angle(AQC) -> Angle(AQC) = 2 * Arc(AC)
//
private static List <EdgeAggregator> InstantiateTheorem(Circle circle, Angle angle)
{
List <EdgeAggregator> newGrounded = new List <EdgeAggregator>();
// Acquire all circles in which the angle is inscribed
List <Circle> circles = Circle.IsInscribedAngle(angle);
//
// Get this particular inscribed circle.
//
Circle inscribed = null;
foreach (Circle c in circles)
{
if (circle.StructurallyEquals(c))
{
inscribed = c;
}
}
if (inscribed == null)
{
return(newGrounded);
}
// Get the intercepted arc
Arc intercepted = Arc.GetInterceptedArc(inscribed, angle);
//
// Create the equation
//
Multiplication product = new Multiplication(new NumericValue(2), angle);
GeometricAngleArcEquation gaaeq = new GeometricAngleArcEquation(product, intercepted);
// For hypergraph
List <GroundedClause> antecedent = new List <GroundedClause>();
antecedent.Add(circle);
antecedent.Add(angle);
antecedent.Add(intercepted);
newGrounded.Add(new EdgeAggregator(antecedent, gaaeq, annotation));
return(newGrounded);
}
public virtual void Visit(Multiplication node)
{
}
private ISymbolicExpressionTreeNode MakeProduct(ConstantTreeNode c, double weight) {
var mul = new Multiplication();
var prod = mul.CreateTreeNode();
prod.AddSubtree(MakeConstantTreeNode(weight));
prod.AddSubtree(c);
return prod;
}
public void CalculateTest(double firstArgument, double secondArgument, double result)
{
var calculator = new Multiplication();
var testResult = calculator.Calculate(firstArgument,secondArgument);
Assert.AreEqual(result, testResult);
}
void MulDivMod(out Expression exp)
{
Expression second;
UnaryOperator(out exp);
while (la.kind == 42 || la.kind == 43 || la.kind == 44) {
if (la.kind == 42) {
Get();
} else if (la.kind == 43) {
Get();
} else {
Get();
}
Token tok = t;
UnaryOperator(out second);
if (!ExpectInt(exp, tok, false)) { return; }
if (!ExpectInt(second, tok, true)) { return; }
if (tok.val == "*") {
exp = new Multiplication((TypedExpression<int>)exp, (TypedExpression<int>)second);
} else if (tok.val == "/") {
exp = new Division((TypedExpression<int>)exp, (TypedExpression<int>)second);
} else if (tok.val == "%") {
exp = new Modulo((TypedExpression<int>)exp, (TypedExpression<int>)second);
}
}
}
private Expression ParseMultiplicativeExpression(TokenSet followers) {
TokenSet followerOrMultiplicative = followers|Token.Division|Token.Multiplication;
Expression result = this.ParseRaiseExpression(followerOrMultiplicative);
while (this.currentToken == Token.Division || this.currentToken == Token.Multiplication) {
SourceLocationBuilder slb = new SourceLocationBuilder(result.SourceLocation);
Token operatorToken = this.currentToken;
this.GetNextToken();
Expression operand2 = this.ParseRaiseExpression(followerOrMultiplicative);
slb.UpdateToSpan(operand2.SourceLocation);
switch (operatorToken) {
case Token.Division: result = new Division(result, operand2, slb); break;
case Token.Multiplication: result = new Multiplication(result, operand2, slb); break;
}
}
//^ assume followers[this.currentToken] || this.currentToken == Token.EndOfFile;
return result;
}
public void Visit(Multiplication visitable) =>
VisitBinary(visitable, "*");
