Package org.assertj.core.api

Class AbstractDoubleAssert<SELF extends AbstractDoubleAssert<SELF>>

java.lang.Object
org.assertj.core.api.AbstractAssert<SELF,Double>
org.assertj.core.api.AbstractObjectAssert<SELF,Double>
org.assertj.core.api.AbstractComparableAssert<SELF,Double>
org.assertj.core.api.AbstractDoubleAssert<SELF>
Type Parameters:
SELF - the "self" type of this assertion class. Please read "Emulating 'self types' using Java Generics to simplify fluent API implementation" for more details.
All Implemented Interfaces:
Assert<SELF,Double>, ComparableAssert<SELF,Double>, Descriptable<SELF>, ExtensionPoints<SELF,Double>, FloatingPointNumberAssert<SELF,Double>, NumberAssert<SELF,Double>
Direct Known Subclasses:
DoubleAssert
public abstract class AbstractDoubleAssert<SELF extends AbstractDoubleAssert<SELF>> extends AbstractComparableAssert<SELF,Double> implements FloatingPointNumberAssert<SELF,Double>
Base class for all implementations of assertions for Doubles.
Author:
Drummond Dawson, Yvonne Wang, David DIDIER, Alex Ruiz, Ansgar Konermann, Joel Costigliola, Mikhail Mazursky, Nicolas François, Jack Gough

  • Constructor Details

    • AbstractDoubleAssert

      protected AbstractDoubleAssert(Double actual, Class<?> selfType)

    • AbstractDoubleAssert

      public AbstractDoubleAssert(double actual, Class<?> selfType)

  • Method Details

    • isNaN

      public SELF isNaN()
      Verifies that the actual value is equal to NaN.

      Example: 

       // assertions succeed
 assertThat(Double.NaN).isNaN();
 assertThat(0.0 / 0.0).isNaN();
 assertThat(0.0F * Float.POSITIVE_INFINITY).isNaN();

 // assertions fail
 assertThat(1.0).isNaN();
 assertThat(-1.0F).isNaN();
      Specified by:
      isNaN in interface FloatingPointNumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.

    • isNotNaN

      public SELF isNotNaN()
      Verifies that the actual value is not equal to NaN.

      Example: 

       // assertions succeed
 assertThat(1.0).isNotNaN();
 assertThat(-1.0F).isNotNaN();

 // assertions fail
 assertThat(Double.NaN).isNotNaN();
 assertThat(0.0 / 0.0).isNotNaN();
 assertThat(0.0F * Float.POSITIVE_INFINITY).isNotNaN();
      Specified by:
      isNotNaN in interface FloatingPointNumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.

    • isZero

      public SELF isZero()
      Verifies that the actual value is equal to zero.

      Although 0.0 == -0.0 (primitives), Double(-0.0) is not zero as Double.doubleToRawLongBits(0.0) == Double.doubleToRawLongBits(-0.0) is false.

      Examples: 

       // assertions will pass
 assertThat(0.0).isZero();
 assertThat(-0.0).isZero();

 // assertions will fail
 assertThat(new Double(-0.0)).isZero();
 assertThat(3.142).isZero();
      Specified by:
      isZero in interface NumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is null.
      AssertionError - if the actual value is not equal to zero.

    • isNotZero

      public SELF isNotZero()
      Verifies that the actual value is not equal to zero.

      Although 0.0 == -0.0 (primitives), Double(-0.0) is not zero as Double.doubleToRawLongBits(0.0) == Double.doubleToRawLongBits(-0.0) is false.

      Examples: 

       // assertions will pass
 assertThat(3.142).isNotZero();
 assertThat(new Double(-0.0)).isNotZero();

 // assertions will fail
 assertThat(0.0).isNotZero();
 assertThat(new Double(0.0)).isNotZero();
 assertThat(-0.0).isNotZero();
      Specified by:
      isNotZero in interface NumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is null.
      AssertionError - if the actual value is equal to zero.

    • isOne

      public SELF isOne()
      Verifies that the actual value is equal to one.

      Example: 

       // assertions will pass
 assertThat(1).isOne();
 assertThat(1.0).isOne();

 // assertions will fail
 assertThat(42).isOne();
 assertThat(3.142).isOne();
      Specified by:
      isOne in interface NumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.

    • isPositive

      public SELF isPositive()
      Verifies that the actual value is positive.

      Example: 

       // assertions will pass
 assertThat(42).isPositive();
 assertThat(3.142).isPositive();

 // assertions will fail
 assertThat(0).isPositive();
 assertThat(-42).isPositive();
      Specified by:
      isPositive in interface NumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.

    • isNegative

      public SELF isNegative()
      Verifies that the actual value is negative.

      Example: 

       // assertions will pass
 assertThat(-42).isNegative();
 assertThat(-3.124).isNegative();

 // assertions will fail
 assertThat(0).isNegative();
 assertThat(42).isNegative();
      Specified by:
      isNegative in interface NumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.

    • isNotNegative

      public SELF isNotNegative()
      Verifies that the actual value is non negative (positive or equal zero).

      Example: 

       // assertions will pass
 assertThat(42).isNotNegative();
 assertThat(0).isNotNegative();

 // assertions will fail
 assertThat(-42).isNotNegative();
 assertThat(-3.124).isNotNegative();
      Specified by:
      isNotNegative in interface NumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.

    • isNotPositive

      public SELF isNotPositive()
      Verifies that the actual value is non positive (negative or equal zero).

      Example: 

       // assertions will pass
 assertThat(-42).isNotPositive();
 assertThat(0).isNotPositive();

 // assertions will fail
 assertThat(42).isNotPositive();
 assertThat(3.124).isNotPositive();
      Specified by:
      isNotPositive in interface NumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.

    • isCloseTo

      public SELF isCloseTo(double expected, Offset<Double> offset)
      Verifies that the actual number is close to the given one within the given offset value.

      When abs(actual - expected) == offset value, the assertion:

      Breaking change since 2.9.0/3.9.0: using Assertions.byLessThan(Double) implies a strict comparison, use Assertions.within(Double) to get the old behavior.

      Examples: 

       // assertions succeed
 assertThat(8.1).isCloseTo(8.0, within(0.2));
 assertThat(8.1).isCloseTo(8.0, offset(0.2)); // alias of within
 assertThat(8.1).isCloseTo(8.0, byLessThan(0.2)); // strict

 // assertions succeed when the difference == offset value ...
 assertThat(8.1).isCloseTo(8.0, within(0.1));
 assertThat(8.1).isCloseTo(8.0, offset(0.1));
 // ... except when using byLessThan which implies a strict comparison
 assertThat(0.1).isCloseTo(0.0, byLessThan(0.1)); // strict => fail

 // this assertion also fails
 assertThat(8.1).isCloseTo(8.0, within(0.001));
      Parameters:
      expected - the given number to compare the actual value to.
      offset - the given positive offset.
      Returns:
      this assertion object.
      Throws:
      NullPointerException - if the given offset is null.
      NullPointerException - if the expected number is null.
      AssertionError - if the actual value is not close to the given one.

    • isNotCloseTo

      public SELF isNotCloseTo(double expected, Offset<Double> offset)
      Verifies that the actual number is not close to the given one by less than the given offset.

      When abs(actual - expected) == offset value, the assertion:

      Breaking change since 2.9.0/3.9.0: using Assertions.byLessThan(Double) implies a strict comparison, use Assertions.within(Double) to get the old behavior.

      Examples: 

       // assertions succeed
 assertThat(8.1).isNotCloseTo(8.0, byLessThan(0.01));
 assertThat(8.1).isNotCloseTo(8.0, within(0.01));
 assertThat(8.1).isNotCloseTo(8.0, offset(0.01));
 // diff == offset but isNotCloseTo succeeds as we use byLessThan
 assertThat(0.1).isNotCloseTo(0.0, byLessThan(0.1));

 // assertions fail
 assertThat(0.1).isNotCloseTo(0.0, within(0.1));
 assertThat(0.1).isNotCloseTo(0.0, offset(0.1));
 assertThat(8.1).isNotCloseTo(8.0, within(0.2));
 assertThat(8.1).isNotCloseTo(8.0, offset(0.2));
 assertThat(8.1).isNotCloseTo(8.0, byLessThan(0.2));
      Parameters:
      expected - the given number to compare the actual value to.
      offset - the given positive offset.
      Returns:
      this assertion object.
      Throws:
      NullPointerException - if the given offset is null.
      NullPointerException - if the expected number is null.
      AssertionError - if the actual value is close to the given one.
      Since:
      2.6.0 / 3.6.0
      See Also:

    • isCloseTo

      public SELF isCloseTo(Double expected, Offset<Double> offset)
      Verifies that the actual number is close to the given one within the given offset value.

      When abs(actual - expected) == offset value, the assertion:

      Breaking change since 2.9.0/3.9.0: using Assertions.byLessThan(Double) implies a strict comparison, use Assertions.within(Double) to get the old behavior.

      Examples: 

       // assertions succeed
 assertThat(8.1).isCloseTo(8.0, within(0.2));
 assertThat(8.1).isCloseTo(8.0, offset(0.2)); // alias of within
 assertThat(8.1).isCloseTo(8.0, byLessThan(0.2)); // strict

 // assertions succeed when the difference == offset value ...
 assertThat(8.1).isCloseTo(8.0, within(0.1));
 assertThat(8.1).isCloseTo(8.0, offset(0.1));
 // ... except when using byLessThan which implies a strict comparison
 assertThat(0.1).isCloseTo(0.0, byLessThan(0.1)); // strict => fail

 // this assertion also fails
 assertThat(8.1).isCloseTo(8.0, within(0.001));
      Specified by:
      isCloseTo in interface FloatingPointNumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Specified by:
      isCloseTo in interface NumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Parameters:
      expected - the given number to compare the actual value to.
      offset - the given positive offset.
      Returns:
      this assertion object.
      Throws:
      NullPointerException - if the given offset is null.
      NullPointerException - if the expected number is null.
      AssertionError - if the actual value is not close to the given one.

    • isNotCloseTo

      public SELF isNotCloseTo(Double expected, Offset<Double> offset)
      Verifies that the actual number is not close to the given one by less than the given offset.

      When abs(actual - expected) == offset value, the assertion:

      Breaking change since 2.9.0/3.9.0: using Assertions.byLessThan(Double) implies a strict comparison, use Assertions.within(Double) to get the old behavior.

      Examples: 

       // assertions succeed
 assertThat(8.1).isNotCloseTo(8.0, byLessThan(0.01));
 assertThat(8.1).isNotCloseTo(8.0, within(0.01));
 assertThat(8.1).isNotCloseTo(8.0, offset(0.01));
 // diff == offset but isNotCloseTo succeeds as we use byLessThan
 assertThat(0.1).isNotCloseTo(0.0, byLessThan(0.1));

 // assertions fail
 assertThat(8.1).isNotCloseTo(8.0, within(0.1));
 assertThat(8.1).isNotCloseTo(8.0, offset(0.1));
 assertThat(8.1).isNotCloseTo(8.0, within(0.2));
 assertThat(8.1).isNotCloseTo(8.0, offset(0.2));
 assertThat(8.1).isNotCloseTo(8.0, byLessThan(0.2));
      Specified by:
      isNotCloseTo in interface FloatingPointNumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Specified by:
      isNotCloseTo in interface NumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Parameters:
      expected - the given number to compare the actual value to.
      offset - the given positive offset.
      Returns:
      this assertion object.
      Throws:
      NullPointerException - if the given offset is null.
      NullPointerException - if the expected number is null.
      AssertionError - if the actual value is close to the given one.
      Since:
      2.6.0 / 3.6.0
      See Also:

    • isCloseTo

      public SELF isCloseTo(Double expected, Percentage percentage)
      Verifies that the actual number is close to the given one within the given percentage.
      If difference is equal to the percentage value, assertion is considered valid.

      Example with double: 

       // assertions will pass:
 assertThat(11.0).isCloseTo(Double.valueOf(10.0), withinPercentage(20d));

 // if difference is exactly equals to the computed offset (1.0), it's ok
 assertThat(11.0).isCloseTo(Double.valueOf(10.0), withinPercentage(10d));

 // assertion will fail
 assertThat(11.0).isCloseTo(Double.valueOf(10.0), withinPercentage(5d));
      Specified by:
      isCloseTo in interface NumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Parameters:
      expected - the given number to compare the actual value to.
      percentage - the given positive percentage.
      Returns:
      this assertion object.
      Throws:
      NullPointerException - if the given offset is null.
      NullPointerException - if the expected number is null.
      AssertionError - if the actual value is not close to the given one.

    • isNotCloseTo

      public SELF isNotCloseTo(Double expected, Percentage percentage)
      Verifies that the actual number is close to the given one within the given percentage.
      If difference is equal to the percentage value, the assertion fails.

      Example with double: 

       // assertion will pass:
 assertThat(11.0).isNotCloseTo(Double.valueOf(10.0), withinPercentage(5d));

 // assertions will fail
 assertThat(11.0).isNotCloseTo(Double.valueOf(10.0), withinPercentage(10d));
 assertThat(11.0).isNotCloseTo(Double.valueOf(10.0), withinPercentage(20d));
      Specified by:
      isNotCloseTo in interface NumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Parameters:
      expected - the given number to compare the actual value to.
      percentage - the given positive percentage.
      Returns:
      this assertion object.
      Throws:
      NullPointerException - if the given offset is null.
      NullPointerException - if the expected number is null.
      AssertionError - if the actual value is close to the given one.
      Since:
      2.6.0 / 3.6.0

    • isCloseTo

      public SELF isCloseTo(double expected, Percentage percentage)
      Verifies that the actual number is close to the given one within the given percentage.
      If difference is equal to the percentage value, assertion is considered valid.

      Example with double: 

       // assertions will pass:
 assertThat(11.0).isCloseTo(10.0, withinPercentage(20d));

 // if difference is exactly equals to the computed offset (1.0), it's ok
 assertThat(11.0).isCloseTo(10.0, withinPercentage(10d));

 // assertion will fail
 assertThat(11.0).isCloseTo(10.0, withinPercentage(5d));
      Parameters:
      expected - the given number to compare the actual value to.
      percentage - the given positive percentage.
      Returns:
      this assertion object.
      Throws:
      NullPointerException - if the given offset is null.
      NullPointerException - if the expected number is null.
      AssertionError - if the actual value is not close to the given one.

    • isNotCloseTo

      public SELF isNotCloseTo(double expected, Percentage percentage)
      Verifies that the actual number is not close to the given one within the given percentage.
      If difference is equal to the percentage value, the assertion fails.

      Example with double: 

       // assertion will pass:
 assertThat(11.0).isNotCloseTo(10.0, withinPercentage(5d));

 // assertions will fail
 assertThat(11.0).isNotCloseTo(10.0, withinPercentage(10d));
 assertThat(11.0).isNotCloseTo(10.0, withinPercentage(20d));
      Parameters:
      expected - the given number to compare the actual value to.
      percentage - the given positive percentage.
      Returns:
      this assertion object.
      Throws:
      NullPointerException - if the given offset is null.
      NullPointerException - if the expected number is null.
      AssertionError - if the actual value is close to the given one.
      Since:
      2.6.0 / 3.6.0

    • isEqualTo

      public SELF isEqualTo(double expected)
      Verifies that the actual value is equal to the given one.

      Unless a specific comparator has been set (with usingComparator) the equality is performed with == which is slightly different from Double.equals(Object) - notably:

      • 0.0 == -0.0 but Double.valueOf(0.0).equals(-0.0) == false
      • Double.NaN != Double.NaN but Double.valueOf(Double.NaN).equals(Double.NaN) == true

      Examples: 

       // assertions will pass:
 assertThat(1.0).isEqualTo(1.0);
 assertThat(1D).isEqualTo(1.0);
 assertThat(-0.0).isEqualTo(0.0);

 // assertions will fail:
 assertThat(0.0).isEqualTo(1.0);
 assertThat(Double.NaN).isEqualTo(Double.NaN);
 assertThat(-1.0).isEqualTo(1.0);

      Note that this assertion behaves slightly differently from isEqualTo(Double).

      Parameters:
      expected - the given value to compare the actual value to.
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is null.
      AssertionError - if the actual value is not equal to the given one.

    • isEqualTo

      public SELF isEqualTo(Double expected)
      Verifies that the actual value is equal to the given one using Double.equals(Object) semantics where:
      • Double.valueOf(Double.NaN).equals(Double.NaN) == true but Double.NaN != Double.NaN
      • Double.valueOf(0.0).equals(-0.0) == false but 0.0 == -0.0

      Examples: 

       // assertions will pass:
 assertThat(1.0).isEqualTo(Double.valueOf(1.0));
 assertThat(1D).isEqualTo(Double.valueOf(1.0));
 assertThat(Double.NaN).isEqualTo(Double.valueOf(Double.NaN));

 // assertions will fail:
 assertThat(0.0).isEqualTo(Double.valueOf(1.0));
 assertThat(-1.0).isEqualTo(Double.valueOf(1.0));
 assertThat(-0.0).isEqualTo(Double.valueOf(0.0));

      Note that this assertion behaves slightly differently from isEqualTo(double).

      Parameters:
      expected - the given value to compare the actual value to.
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is null.
      AssertionError - if the actual value is not equal to the given one.

    • isEqualTo

      public SELF isEqualTo(Double expected, Offset<Double> offset)
      Verifies that the actual number is close to the given one within the given offset value.

      This assertion is the same as FloatingPointNumberAssert.isCloseTo(Number, Offset).

      When abs(actual - expected) == offset value, the assertion:

      Examples: 

       // assertions succeed
 assertThat(8.1).isEqualTo(8.0, within(0.2));
 assertThat(8.1).isEqualTo(8.0, offset(0.2)); // alias of within
 assertThat(8.1).isEqualTo(8.0, byLessThan(0.2)); // strict

 // assertions succeed when the difference == offset value ...
 assertThat(8.1).isEqualTo(8.0, within(0.1));
 assertThat(8.1).isEqualTo(8.0, offset(0.1));
 // ... except when using byLessThan which is strict
 assertThat(8.1).isEqualTo(8.0, byLessThan(0.1)); // strict => fail

 // this assertions also fails
 assertThat(8.1).isEqualTo(8.0, within(0.001));
      Specified by:
      isEqualTo in interface FloatingPointNumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Parameters:
      expected - the given value to compare the actual value to.
      offset - the given positive offset.
      Returns:
      this assertion object.

    • isEqualTo

      public SELF isEqualTo(double expected, Offset<Double> offset)
      Verifies that the actual number is close to the given one within the given offset value.

      This assertion is the same as isCloseTo(double, Offset).

      When abs(actual - expected) == offset value, the assertion:

      Examples: 

       // assertions will pass
 assertThat(8.1).isEqualTo(8.0, within(0.2));
 assertThat(8.1).isEqualTo(8.0, offset(0.2)); // alias of within
 assertThat(8.1).isEqualTo(8.0, byLessThan(0.2)); // strict

 // assertions succeed when the difference == offset value ...
 assertThat(8.1).isEqualTo(8.0, within(0.1));
 assertThat(8.1).isEqualTo(8.0, offset(0.1));
 // ... except when using byLessThan which implies a strict comparison
 assertThat(0.1).isEqualTo(0.0, byLessThan(0.1)); // strict => fail

 // this assertion also fails
 assertThat(8.1).isEqualTo(8.0, within(0.001));
      Parameters:
      expected - the given value to compare the actual value to.
      offset - the given positive offset.
      Returns:
      this assertion object.
      Throws:
      NullPointerException - if the given offset is null.
      NullPointerException - if the expected number is null.
      AssertionError - if the actual value is not equal to the given one.

    • isNotEqualTo

      public SELF isNotEqualTo(double other)
      Verifies that the actual value is not equal to the given one.

      Unless a specific comparator has been set (with usingComparator) the equality is performed with != which is slightly different from Double.equals(Object) - notably:

      • Double.NaN != Double.NaN but Double.valueOf(Double.NaN).equals(Double.NaN) == true
      • 0.0 == -0.0 but Double.valueOf(0.0).equals(-0.0) == false

      Examples: 

       // assertions will pass:
 assertThat(0.0).isNotEqualTo(1.0);
 assertThat(-1.0).isNotEqualTo(1.0);
 assertThat(Double.NaN).isNotEqualTo(Double.NaN);

 // assertions will fail:
 assertThat(1.0).isNotEqualTo(1.0);
 assertThat(0.0).isNotEqualTo(-0.0);
 assertThat(1D).isNotEqualTo(1.0);

      Note that this assertion behaves slightly differently from isNotEqualTo(Double).

      Parameters:
      other - the given value to compare the actual value to.
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is null.
      AssertionError - if the actual value is == to the given one.

    • isNotEqualTo

      public SELF isNotEqualTo(Double other)
      Verifies that the actual value is not equal to the given Double using Double.equals(Object) semantics where
      • Double.valueOf(Double.NaN).equals(Double.NaN) == true but Double.NaN != Double.NaN
      • Double.valueOf(0.0).equals(-0.0) == false but 0.0 == -0.0

      Examples: 

       // assertions will pass:
 assertThat(0.0).isNotEqualTo(Double.valueOf(1.0));
 assertThat(-1.0).isNotEqualTo(Double.valueOf(1.0));
 assertThat(0.0).isNotEqualTo(Double.valueOf(-0.0));

 // assertions will fail:
 assertThat(1.0).isNotEqualTo(Double.valueOf(1.0));
 assertThat(0.0).isNotEqualTo(Double.valueOf(0.0));
 assertThat(Double.NaN).isNotEqualTo(Double.valueOf(Double.NaN));

      Note that this assertion behaves slightly differently from isNotEqualTo(double).

      Parameters:
      other - the given value to compare the actual value to.
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is null.
      AssertionError - if the actual value is equal to the given one.

    • isLessThan

      public SELF isLessThan(double other)
      Verifies that the actual value is less than the given one.

      Examples: 

       // assertion will pass:
 assertThat(1.0).isLessThan(2.0);

 // assertions will fail:
 assertThat(2.0).isLessThan(1.0);
 assertThat(1.0).isLessThan(1.0);
      Parameters:
      other - the given value to compare the actual value to.
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is null.
      AssertionError - if the actual value is equal to or greater than the given one.

    • isLessThanOrEqualTo

      public SELF isLessThanOrEqualTo(double other)
      Verifies that the actual value is less than or equal to the given one.

      Unless a specific comparator has been set (with usingComparator) this assertion will use <= semantics where notably 0.0 == -0.0.

      Examples: 

       // assertions will pass:
 assertThat(-1.0).isLessThanOrEqualTo(1.0);
 assertThat(1.0).isLessThanOrEqualTo(1.0);
 // 0.0 == -0.0
 assertThat(-0.0).isLessThanOrEqualTo(0.0);
 assertThat(0.0).isLessThanOrEqualTo(-0.0);

 // assertion will fail:
 assertThat(2.0).isLessThanOrEqualTo(1.0);

      Note that this assertion behaves differently from isLessThanOrEqualTo(Double) which uses Double.compareTo(Double) semantics.

      Parameters:
      other - the given value to compare the actual value to.
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is null.
      AssertionError - if the actual value is greater than the given one.

    • isLessThanOrEqualTo

      public SELF isLessThanOrEqualTo(Double other)
      Verifies that the actual value is less than or equal to the given one using Double.compareTo(Double) semantics where notably -0.0 is strictly less than 0.0.

      Examples: 

       // assertions will pass:
 assertThat(-1.0).isLessThanOrEqualTo(Double.valueOf(1.0));
 assertThat(1.0).isLessThanOrEqualTo(Double.valueOf(1.0));
 assertThat(-0.0).isLessThanOrEqualTo(Double.valueOf(0.0));

 // assertions will fail:
 assertThat(2.0).isLessThanOrEqualTo(Double.valueOf(1.0));
 // 0.0 is not considered equal to -0.0
 assertThat(0.0).isLessThanOrEqualTo(Double.valueOf(-0.0));

      Note that this assertion behaves differently from isLessThanOrEqualTo(double) which uses Double.compareTo(Double) semantics.

      Specified by:
      isLessThanOrEqualTo in interface ComparableAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Overrides:
      isLessThanOrEqualTo in class AbstractComparableAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Parameters:
      other - the given value to compare the actual value to.
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is null.
      AssertionError - if the actual value is greater than the given one.

    • isGreaterThan

      public SELF isGreaterThan(double other)
      Verifies that the actual value is greater than the given one.

      Examples: 

       // assertion will pass:
 assertThat(2.0).isGreaterThan(1.0);

 // assertions will fail:
 assertThat(1.0).isGreaterThan(1.0);
 assertThat(1.0).isGreaterThan(2.0);
      Parameters:
      other - the given value to compare the actual value to.
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is null.
      AssertionError - if the actual value is equal to or less than the given one.

    • isGreaterThanOrEqualTo

      public SELF isGreaterThanOrEqualTo(double other)
      Verifies that the actual value is greater than or equal to the given one.

      Unless a specific comparator has been set (with usingComparator) this assertion will use >= semantics where notably 0.0 == -0.0.

      Examples: 

       // assertions will pass:
 assertThat(2.0).isGreaterThanOrEqualTo(1.0);
 assertThat(1.0).isGreaterThanOrEqualTo(1.0);
 // 0.0 == -0.0
 assertThat(-0.0).isGreaterThanOrEqualTo(0.0);
 assertThat(0.0).isGreaterThanOrEqualTo(-0.0);

 // assertion will fail:
 assertThat(1.0).isGreaterThanOrEqualTo(2.0);

      Note that this assertion behaves differently from isGreaterThanOrEqualTo(Double) which uses Double.compareTo(Double) semantics.

      Parameters:
      other - the given value to compare the actual value to.
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is null.
      AssertionError - if the actual value is less than the given one.

    • isGreaterThanOrEqualTo

      public SELF isGreaterThanOrEqualTo(Double other)
      Verifies that the actual value is greater than or equal to the given one using Double.compareTo(Double) semantics where notably 0.0 is strictly greater than -0.0.

      Examples: 

       // assertions will pass:
 assertThat(2.0).isGreaterThanOrEqualTo(Double.valueOf(1.0));
 assertThat(1.0).isGreaterThanOrEqualTo(Double.valueOf(1.0));
 assertThat(0.0).isGreaterThanOrEqualTo(Double.valueOf(-0.0));

 // assertions will fail:
 assertThat(1.0).isGreaterThanOrEqualTo(Double.valueOf(2.0));
 // 0.0 is not considered equal to -0.0
 assertThat(-0.0).isGreaterThanOrEqualTo(Double.valueOf(0.0));

      Note that this assertion behaves differently from isGreaterThanOrEqualTo(double) which uses >= semantics.

      Specified by:
      isGreaterThanOrEqualTo in interface ComparableAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Overrides:
      isGreaterThanOrEqualTo in class AbstractComparableAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Parameters:
      other - the given value to compare the actual value to.
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is null.
      AssertionError - if the actual value is less than the given one.

    • isBetween

      public SELF isBetween(Double start, Double end)
      Verifies that the actual value is in [start, end] range (start included, end included).

      Examples: 

       // assertions will pass
 assertThat(1d).isBetween(-1d, 2d);
 assertThat(1d).isBetween(1d, 2d);
 assertThat(1d).isBetween(0d, 1d);

 // assertion will fail
 assertThat(1d).isBetween(2d, 3d);
      Specified by:
      isBetween in interface ComparableAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Specified by:
      isBetween in interface NumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Overrides:
      isBetween in class AbstractComparableAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Parameters:
      start - the start value (inclusive), expected not to be null.
      end - the end value (inclusive), expected not to be null.
      Returns:
      this assertion object.

    • isStrictlyBetween

      public SELF isStrictlyBetween(Double start, Double end)
      Verifies that the actual value is in ]start, end[ range (start excluded, end excluded).

      Examples: 

       // assertion will pass
 assertThat(1d).isStrictlyBetween(-1d, 2d);

 // assertions will fail
 assertThat(1d).isStrictlyBetween(1d, 2d);
 assertThat(1d).isStrictlyBetween(0d, 1d);
 assertThat(1d).isStrictlyBetween(2d, 3d);
      Specified by:
      isStrictlyBetween in interface ComparableAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Specified by:
      isStrictlyBetween in interface NumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Overrides:
      isStrictlyBetween in class AbstractComparableAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Parameters:
      start - the start value (exclusive), expected not to be null.
      end - the end value (exclusive), expected not to be null.
      Returns:
      this assertion object.

    • usingComparator

      public SELF usingComparator(Comparator<? super Double> customComparator)
      Description copied from class: AbstractAssert
      Use the given custom comparator instead of relying on actual type A equals method for incoming assertion checks.

      The custom comparator is bound to assertion instance, meaning that if a new assertion instance is created, the default comparison strategy will be used.

      Examples : 

       // frodo and sam are instances of Character with Hobbit race (obviously :).
 // raceComparator implements Comparator<Character>
 assertThat(frodo).usingComparator(raceComparator).isEqualTo(sam);
      Specified by:
      usingComparator in interface Assert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Overrides:
      usingComparator in class AbstractComparableAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Parameters:
      customComparator - the comparator to use for the incoming assertion checks.
      Returns:
      this assertion object.

    • usingComparator

      public SELF usingComparator(Comparator<? super Double> customComparator, String customComparatorDescription)
      Description copied from class: AbstractAssert
      Use the given custom comparator instead of relying on actual type A equals method for incoming assertion checks.

      The custom comparator is bound to the current assertion chain, meaning that if a new assertion instance is created, the default comparison strategy will be used.

      Examples : 

       // frodo and sam are instances of Character with Hobbit race (obviously :).
 // raceComparator implements Comparator<Character>
 assertThat(frodo).usingComparator(raceComparator, "Hobbit Race Comparator").isEqualTo(sam);
      Specified by:
      usingComparator in interface Assert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Overrides:
      usingComparator in class AbstractComparableAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Parameters:
      customComparator - the comparator to use for the incoming assertion checks.
      customComparatorDescription - comparator description to be used in assertion error messages
      Returns:
      this assertion object.

    • usingDefaultComparator

      public SELF usingDefaultComparator()
      Description copied from class: AbstractAssert
      Revert to standard comparison for the incoming assertion checks.

      This method should be used to disable a custom comparison strategy set by calling usingComparator.

      Specified by:
      usingDefaultComparator in interface Assert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Overrides:
      usingDefaultComparator in class AbstractComparableAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.

    • isFinite

      public SELF isFinite()
      Verifies that the double value is a finite floating-point value.

      Example: 

       // assertion succeeds
 assertThat(1.0d).isFinite();

 // assertions fail
 assertThat(Double.NaN).isFinite();
 assertThat(Double.NEGATIVE_INFINITY).isFinite();
 assertThat(Double.POSITIVE_INFINITY).isFinite();
      Specified by:
      isFinite in interface FloatingPointNumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is not a finite floating-point value.
      AssertionError - if the actual value is null.
      Since:
      3.19.0
      See Also:

    • isNotFinite

      public SELF isNotFinite()
      Verifies that the double value is not a finite floating-point value.

      Note that 'not finite' is not equivalent to infinite as `NaN` is neither finite or infinite.

      Example: 

       // assertions succeed
 assertThat(Double.POSITIVE_INFINITY).isNotFinite();
 assertThat(Double.NEGATIVE_INFINITY).isNotFinite();
 assertThat(Double.NaN).isNotFinite();

 // assertion fails
 assertThat(1.0).isNotFinite();
      Specified by:
      isNotFinite in interface FloatingPointNumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value is a finite floating-point value.
      AssertionError - if the actual value is null.
      Since:
      3.20.0
      See Also:

    • isInfinite

      public SELF isInfinite()
      Verifies that the double value represents positive infinity or negative infinity.

      Examples: 

       // assertions succeed
 assertThat(Double.NEGATIVE_INFINITY).isInfinite();
 assertThat(Double.POSITIVE_INFINITY).isInfinite();

 // assertions fail
 assertThat(1.0d).isInfinite();
 assertThat(Double.NaN).isInfinite();
      Specified by:
      isInfinite in interface FloatingPointNumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value represents neither positive infinity nor negative infinity.
      AssertionError - if the actual value is null.
      Since:
      3.19.0
      See Also:

    • isNotInfinite

      public SELF isNotInfinite()
      Verifies that the double value represents neither positive infinity nor negative infinity.

      Examples: 

       // assertions succeed
 assertThat(1.0).isNotInfinite();
 assertThat(Double.NaN).isNotInfinite();

 // assertions fail
 assertThat(Double.POSITIVE_INFINITY).isNotInfinite();
 assertThat(Double.NEGATIVE_INFINITY).isNotInfinite();
      Specified by:
      isNotInfinite in interface FloatingPointNumberAssert<SELF extends AbstractDoubleAssert<SELF>,Double>
      Returns:
      this assertion object.
      Throws:
      AssertionError - if the actual value represents positive infinity or negative infinity.
      AssertionError - if the actual value is null.
      Since:
      3.20.0
      See Also: