# Double.CompareTo Method (Double)

**.NET Framework 4.6 and 4.5**

Compares this instance to a specified double-precision floating-point number and returns an integer that indicates whether the value of this instance is less than, equal to, or greater than the value of the specified double-precision floating-point number.

**Namespace:**System

**Assembly:**mscorlib (in mscorlib.dll)

#### Parameters

- value
- Type: System.Double
A double-precision floating-point number to compare.

#### Return Value

Type: System.Int32A signed number indicating the relative values of this instance and value.

Return Value | Description |
---|---|

Less than zero | This instance is less than value. -or- This instance is not a number (NaN) and value is a number. |

Zero | This instance is equal to value. -or- Both this instance and value are not a number (NaN), PositiveInfinity, or NegativeInfinity. |

Greater than zero | This instance is greater than value. -or- This instance is a number and value is not a number (NaN). |

#### Implements

IComparable<T>.CompareTo(T)Values must be identical to be considered equal. Particularly when floating-point values depend on multiple mathematical operations, it is common for them to lose precision and for their values to be nearly identical except for their least significant digits. Because of this, the return value of the CompareTo method at times may seem surprising. For example, multiplication by a particular value followed by division by the same value should produce the original value. In the following example, however, the computed value turns out to be greater than the original value. Showing all significant digits of the two values by using the "R" standard numeric format string indicates that the computed value differs from the original value in its least significant digits. For information on handling such comparisons, see the Remarks section of the Equals(Double) method.

using System; public class Example { public static void Main() { double value1 = 6.185; double value2 = value1 * .1 / .1; Console.WriteLine("Comparing {0} and {1}: {2}\n", value1, value2, value1.CompareTo(value2)); Console.WriteLine("Comparing {0:R} and {1:R}: {2}", value1, value2, value1.CompareTo(value2)); } } // The example displays the following output: // Comparing 6.185 and 6.185: -1 // // Comparing 6.185 and 6.1850000000000005: -1

This method implements the System.IComparable<T> interface and performs slightly better than the Double.CompareTo method because it does not have to convert the value parameter to an object.

Note that, although an object whose value is NaN is not considered equal to another object whose value is NaN (even itself), the IComparable<T> interface requires that A.CompareTo(A) return zero.

### Widening Conversions

Depending on your programming language, it might be possible to code a CompareTo method where the parameter type has fewer bits (is narrower) than the instance type. This is possible because some programming languages perform an implicit widening conversion that represents the parameter as a type with as many bits as the instance.

For example, suppose the instance type is Double and the parameter type is Int32. The Microsoft C# compiler generates instructions to represent the value of the parameter as a Double object, then generates a Double.CompareTo(Double) method that compares the values of the instance and the widened representation of the parameter.

Consult your programming language's documentation to determine if its compiler performs implicit widening conversions of numeric types. For more information, see the Type Conversion Tables in the .NET Framework topic.

### Precision in Comparisons

The precision of floating-point numbers beyond the documented precision is specific to the implementation and version of the .NET Framework. Consequently, a comparison of two particular numbers might change between versions of the .NET Framework because the precision of the numbers' internal representation might change.

The following code example demonstrates generic and nongeneric versions of the CompareTo method for several value and reference types.

// This example demonstrates the generic and non-generic versions of the // CompareTo method for several base types. // The non-generic version takes a parameter of type Object, while the generic // version takes a type-specific parameter, such as Boolean, Int32, or Double. using System; class Sample { public static void Main() { string nl = Environment.NewLine; string msg = "{0}The following is the result of using the generic and non-generic{0}" + "versions of the CompareTo method for several base types:{0}"; DateTime now = DateTime.Now; // Time span = 11 days, 22 hours, 33 minutes, 44 seconds TimeSpan tsX = new TimeSpan(11, 22, 33, 44); // Version = 1.2.333.4 Version versX = new Version("1.2.333.4"); // Guid = CA761232-ED42-11CE-BACD-00AA0057B223 Guid guidX = new Guid("{CA761232-ED42-11CE-BACD-00AA0057B223}"); Boolean a1 = true, a2 = true; Byte b1 = 1, b2 = 1; Int16 c1 = -2, c2 = 2; Int32 d1 = 3, d2 = 3; Int64 e1 = 4, e2 = -4; Decimal f1 = -5.5m, f2 = 5.5m; Single g1 = 6.6f, g2 = 6.6f; Double h1 = 7.7d, h2 = -7.7d; Char i1 = 'A', i2 = 'A'; String j1 = "abc", j2 = "abc"; DateTime k1 = now, k2 = now; TimeSpan l1 = tsX, l2 = tsX; Version m1 = versX, m2 = new Version("2.0"); Guid n1 = guidX, n2 = guidX; // The following types are not CLS-compliant. SByte w1 = 8, w2 = 8; UInt16 x1 = 9, x2 = 9; UInt32 y1 = 10, y2 = 10; UInt64 z1 = 11, z2 = 11; // Console.WriteLine(msg, nl); try { // The second and third Show method call parameters are automatically boxed because // the second and third Show method declaration arguments expect type Object. Show("Boolean: ", a1, a2, a1.CompareTo(a2), a1.CompareTo((Object)a2)); Show("Byte: ", b1, b2, b1.CompareTo(b2), b1.CompareTo((Object)b2)); Show("Int16: ", c1, c2, c1.CompareTo(c2), c1.CompareTo((Object)c2)); Show("Int32: ", d1, d2, d1.CompareTo(d2), d1.CompareTo((Object)d2)); Show("Int64: ", e1, e2, e1.CompareTo(e2), e1.CompareTo((Object)e2)); Show("Decimal: ", f1, f2, f1.CompareTo(f2), f1.CompareTo((Object)f2)); Show("Single: ", g1, g2, g1.CompareTo(g2), g1.CompareTo((Object)g2)); Show("Double: ", h1, h2, h1.CompareTo(h2), h1.CompareTo((Object)h2)); Show("Char: ", i1, i2, i1.CompareTo(i2), i1.CompareTo((Object)i2)); Show("String: ", j1, j2, j1.CompareTo(j2), j1.CompareTo((Object)j2)); Show("DateTime: ", k1, k2, k1.CompareTo(k2), k1.CompareTo((Object)k2)); Show("TimeSpan: ", l1, l2, l1.CompareTo(l2), l1.CompareTo((Object)l2)); Show("Version: ", m1, m2, m1.CompareTo(m2), m1.CompareTo((Object)m2)); Show("Guid: ", n1, n2, n1.CompareTo(n2), n1.CompareTo((Object)n2)); // Console.WriteLine("{0}The following types are not CLS-compliant:", nl); Show("SByte: ", w1, w2, w1.CompareTo(w2), w1.CompareTo((Object)w2)); Show("UInt16: ", x1, x2, x1.CompareTo(x2), x1.CompareTo((Object)x2)); Show("UInt32: ", y1, y2, y1.CompareTo(y2), y1.CompareTo((Object)y2)); Show("UInt64: ", z1, z2, z1.CompareTo(z2), z1.CompareTo((Object)z2)); } catch (Exception e) { Console.WriteLine(e); } } public static void Show(string caption, Object var1, Object var2, int resultGeneric, int resultNonGeneric) { string relation; Console.Write(caption); if (resultGeneric == resultNonGeneric) { if (resultGeneric < 0) relation = "less than"; else if (resultGeneric > 0) relation = "greater than"; else relation = "equal to"; Console.WriteLine("{0} is {1} {2}", var1, relation, var2); } // The following condition will never occur because the generic and non-generic // CompareTo methods are equivalent. else { Console.WriteLine("Generic CompareTo = {0}; non-generic CompareTo = {1}", resultGeneric, resultNonGeneric); } } } /* This example produces the following results: The following is the result of using the generic and non-generic versions of the CompareTo method for several base types: Boolean: True is equal to True Byte: 1 is equal to 1 Int16: -2 is less than 2 Int32: 3 is equal to 3 Int64: 4 is greater than -4 Decimal: -5.5 is less than 5.5 Single: 6.6 is equal to 6.6 Double: 7.7 is greater than -7.7 Char: A is equal to A String: abc is equal to abc DateTime: 12/1/2003 5:37:46 PM is equal to 12/1/2003 5:37:46 PM TimeSpan: 11.22:33:44 is equal to 11.22:33:44 Version: 1.2.333.4 is less than 2.0 Guid: ca761232-ed42-11ce-bacd-00aa0057b223 is equal to ca761232-ed42-11ce-bacd-00 aa0057b223 The following types are not CLS-compliant: SByte: 8 is equal to 8 UInt16: 9 is equal to 9 UInt32: 10 is equal to 10 UInt64: 11 is equal to 11 */