agi.foundation.numericalmethods

(agi.foundation.core-2024r2.jar)

Class InequalityConstraintSettings

java.lang.Object

agi.foundation.infrastructure.DefinitionalObject

agi.foundation.numericalmethods.InequalityConstraintSettings

All Implemented Interfaces:

ICloneWithContext, IEnumerateDependencies, IEquatableDefinition, IFreezable, IThreadAware

public class InequalityConstraintSettings
extends DefinitionalObject
implements IThreadAware

The settings for an inequality constraint used by an OptimizerMultivariableFunction.

Constructor Summary

Constructors

Modifier	Constructor and Description
	InequalityConstraintSettings(InequalityBoundType boundType, double boundValue, double tolerance) Initializes a new instance with no scaling.
	InequalityConstraintSettings(InequalityBoundType boundType, double boundValue, double tolerance, InequalityConstraintScaling scaling) Initializes a new instance.
	InequalityConstraintSettings(InequalityBoundType boundType, double boundValue, double tolerance, InequalityConstraintScaling scaling, String name) Initializes a new instance.
	InequalityConstraintSettings(InequalityBoundType boundType, double boundValue, double tolerance, InequalityConstraintScaling scaling, String name, double weight) Initializes a new instance.
protected	InequalityConstraintSettings(InequalityConstraintSettings existingInstance, CopyContext context) Initializes a new instance as a copy of an existing instance.

Method Summary

Modifier and Type	Method and Description
protected boolean	checkForSameDefinition(DefinitionalObject other) Checks to determine if another instance has the same definition as this instance and returns true if it does.
protected boolean	checkForSameDefinition(InequalityConstraintSettings other) Checks to determine if another instance has the same definition as this instance and returns true if it does.
Object	clone(CopyContext context) Clones this object using the specified context.
protected int	computeCurrentDefinitionHashCode() Computes a hash code based on the current properties of this object.
void	enumerateDependencies(DependencyEnumerator enumerator) Enumerates the dependencies of this object by calling DependencyEnumerator#enumerate(T) for each object that this object directly depends upon.
InequalityBoundType	getBoundType() Gets a value indicating whether the inequality represents an upper bound or a lower bound.
double	getBoundValue() Gets the value of the upper or lower bound that defines the inequality.
boolean	getIsThreadSafe() Gets a value indicating whether the methods on this instance are safe to call from multiple threads simultaneously.
String	getName() Gets an optional name for this constraint.
InequalityConstraintScaling	getScaling() Gets the type of scaling applied to the constraint.
double	getTolerance() Gets a value indicating how close the evaluated value must get to the BoundValue (get / set) to consider this inequality to be on the bound.
double	getWeight() Gets a value multiplied by the constraint error to prioritize or de-prioritize it with respect to other constraints or the cost function.
boolean	inequalitySatisfied(double currentInequalityValue) Determines if the current inequality value satisfies the inequality defined by the BoundType (get / set) and BoundValue (get / set).
boolean	inequalitySatisfiedAndWithinTolerance(double currentInequalityValue) Calculates if the current constraint value both satisfies the inequality and is within tolerance of the bound value (on the feasible side of the inequality).
boolean	inequalityWithinTolerance(double currentInequalityValue) Calculates if the absolute value of the current constraint value minus the BoundValue (get / set) is smaller than the Tolerance (get / set).
void	setBoundType(InequalityBoundType value) Sets a value indicating whether the inequality represents an upper bound or a lower bound.
void	setBoundValue(double value) Sets the value of the upper or lower bound that defines the inequality.
void	setName(String value) Sets an optional name for this constraint.
void	setScaling(InequalityConstraintScaling value) Sets the type of scaling applied to the constraint.
void	setTolerance(double value) Sets a value indicating how close the evaluated value must get to the BoundValue (get / set) to consider this inequality to be on the bound.
void	setWeight(double value) Sets a value multiplied by the constraint error to prioritize or de-prioritize it with respect to other constraints or the cost function.

Methods inherited from class agi.foundation.infrastructure.DefinitionalObject

areSameDefinition, areSameDefinition, areSameDefinition, areSameDefinition, areSameDefinition, collectionItemsAreSameDefinition, collectionItemsAreSameDefinition, collectionItemsAreSameDefinition, dictionaryItemsAreSameDefinition, freeze, freezeAggregatedObjects, getCollectionHashCode, getCollectionHashCode, getCollectionHashCode, getDefinitionHashCode, getDefinitionHashCode, getDefinitionHashCode, getDefinitionHashCode, getDefinitionHashCode, getDefinitionHashCode, getDictionaryHashCode, getIsFrozen, isSameDefinition, throwIfFrozen

Methods inherited from class java.lang.Object

clone, equals, finalize, getClass, hashCode, notify, notifyAll, toString, wait, wait, wait

Constructor Detail

InequalityConstraintSettings

public InequalityConstraintSettings(@Nonnull
                                    InequalityBoundType boundType,
                                    double boundValue,
                                    double tolerance)

Initializes a new instance with no scaling.

An upper bound occurs if the inequality function must be less than or equal to the bound value to be satisfied. A lower bound occurs if the inequality function must be greater than or equal to the bound value to be satisfied.

Parameters:

boundType - Whether the inequality represents an upper bound or a lower bound.

boundValue - The value of the upper or lower bound that defines the inequality.

tolerance - How close the evaluated value must get to the BoundValue (get / set) to consider this inequality to be on the bound.

InequalityConstraintSettings

public InequalityConstraintSettings(@Nonnull
                                    InequalityBoundType boundType,
                                    double boundValue,
                                    double tolerance,
                                    InequalityConstraintScaling scaling)

Initializes a new instance.

An upper bound occurs if the inequality function must be less than or equal to the bound value to be satisfied. A lower bound occurs if the inequality function must be greater than or equal to the bound value to be satisfied.

Parameters:

boundType - Whether the inequality represents an upper bound or a lower bound.

boundValue - The value of the upper or lower bound that defines the inequality.

tolerance - How close the evaluated value must get to the BoundValue (get / set) to consider this inequality to be on the bound.

scaling - Sets the type of scaling to be used on this constraint.

InequalityConstraintSettings

public InequalityConstraintSettings(@Nonnull
                                    InequalityBoundType boundType,
                                    double boundValue,
                                    double tolerance,
                                    InequalityConstraintScaling scaling,
                                    String name)

Initializes a new instance.

An upper bound occurs if the inequality function must be less than or equal to the bound value to be satisfied. A lower bound occurs if the inequality function must be greater than or equal to the bound value to be satisfied.

Parameters:

boundType - Whether the inequality represents an upper bound or a lower bound.

boundValue - The value of the upper or lower bound that defines the inequality.

tolerance - How close the evaluated value must get to the BoundValue (get / set) to consider this inequality to be on the bound.

scaling - Sets the type of scaling to be used on this constraint.

name - An optional name for the constraint settings.

InequalityConstraintSettings

public InequalityConstraintSettings(@Nonnull
                                    InequalityBoundType boundType,
                                    double boundValue,
                                    double tolerance,
                                    @Nonnull
                                    InequalityConstraintScaling scaling,
                                    String name,
                                    double weight)

Initializes a new instance.

An upper bound occurs if the inequality function must be less than or equal to the bound value to be satisfied. A lower bound occurs if the inequality function must be greater than or equal to the bound value to be satisfied.

Parameters:

boundType - Whether the inequality represents an upper bound or a lower bound.

boundValue - The value of the upper or lower bound that defines the inequality.

tolerance - How close the evaluated value must get to the BoundValue (get / set) to consider this inequality to be on the bound.

scaling - Sets the type of scaling to be used on this constraint.

name - An optional name for the constraint settings.

weight - A value multiplied by the constraint error to prioritize or de-prioritize it with respect to other constraints or the cost function.

InequalityConstraintSettings

protected InequalityConstraintSettings(@Nonnull
                                       InequalityConstraintSettings existingInstance,
                                       @Nonnull
                                       CopyContext context)

Initializes a new instance as a copy of an existing instance.

See ICloneWithContext.clone(CopyContext) for more information about how to implement this constructor in a derived class.

Parameters:

existingInstance - The existing instance to copy.

context - A CopyContext that controls the depth of the copy.

Throws:

ArgumentNullException - Thrown when existingInstance or context is null.

Method Detail

clone

public Object clone(CopyContext context)

Clones this object using the specified context.

This method should be implemented to call a copy constructor on the class of the object being cloned. The copy constructor should take the CopyContext as a parameter in addition to the existing instance to copy. The copy constructor should first call CopyContext.addObjectMapping(T, T) to identify the newly constructed instance as a copy of the existing instance. It should then copy all fields, using CopyContext.updateReference(T) to copy any reference fields.

A typical implementation of ICloneWithContext:

public static class MyClass implements ICloneWithContext {
    public MyClass(MyClass existingInstance, CopyContext context) {
        context.addObjectMapping(existingInstance, this);
        someReference = context.updateReference(existingInstance.someReference);
    }

    @Override
    public final Object clone(CopyContext context) {
        return new MyClass(this, context);
    }

    private Object someReference;
}

In general, all fields that are reference types should be copied with a call to CopyContext.updateReference(T). There are a couple of exceptions:

1. Fields that are aggregate parts of the object should always be copied. A referenced object is an aggregate if properties or methods on the object being copied can modify the externally-visible value of the referenced object.
2. If the semantics of the referenced object require that it have a single parent, owner, context, etc., and the object being copied is that parent, owner, or context, then the referenced object should always be copied.

If one of these exceptions applies, the CopyContext should be given an opportunity to update the reference before the reference is copied explicitly. Use CopyContext.updateReference(T) to update the reference. If CopyContext.updateReference(T) returns the original object, indicating that the context does not have a replacement registered, then copy the object manually by invoking a Clone method, a copy constructor, or by manually constructing a new instance and copying the values.

alwaysCopy = context.updateReference(existingInstance.alwaysCopy);
if (existingInstance.alwaysCopy != null && alwaysCopy == existingInstance.alwaysCopy) {
    alwaysCopy = (AlwaysCopy) existingInstance.alwaysCopy.clone(context);
}

If you are implementing an evaluator (a class that implements IEvaluator), the IEvaluator.updateEvaluatorReferences(agi.foundation.infrastructure.CopyContext) method shares some responsibilities with the copy context constructor. Code duplication can be avoided by doing the following:

1. For references to other evaluators ONLY, simply assign the reference in the constructor instead of calling CopyContext.updateReference(T). You should still call CopyContext.updateReference(T) on any references to non-evaluators.
2. Call IEvaluator.updateEvaluatorReferences(agi.foundation.infrastructure.CopyContext) as the last line in the constructor and pass it the same CopyContext passed to the constructor.
3. Implement IEvaluator.updateEvaluatorReferences(agi.foundation.infrastructure.CopyContext) as normal. See the reference documentation for IEvaluator.updateEvaluatorReferences(agi.foundation.infrastructure.CopyContext) for more information on implementing that method.

public MyClass(MyClass existingInstance, CopyContext context) {
    super(existingInstance, context);
    someReference = context.updateReference(existingInstance.someReference);
    evaluatorReference = existingInstance.evaluatorReference;
    updateEvaluatorReferences(context);
}

@Override
public void updateEvaluatorReferences(CopyContext context) {
    evaluatorReference = context.updateReference(evaluatorReference);
}

@Override
public Object clone(CopyContext context) {
    return new MyClass(this, context);
}

private Object someReference;
private IEvaluator evaluatorReference;

Specified by:

clone in interface ICloneWithContext

Specified by:

clone in class DefinitionalObject

Parameters:

context - The context to use to perform the copy.

Returns:

A new instance which is a copy of this object.

checkForSameDefinition

protected final boolean checkForSameDefinition(DefinitionalObject other)

Checks to determine if another instance has the same definition as this instance and returns true if it does. Derived classes MUST override this method and check all new fields introduced by the derived class for definitional equivalence. It is NOT necessary to check base class fields because the base class will already have done that. When overriding this method, you should NOT call the base implementation because it will return false for all derived-class instances. Derived classes should check the type of other to preserve the symmetric nature of IEquatableDefinition.isSameDefinition(java.lang.Object).

Specified by:

checkForSameDefinition in class DefinitionalObject

Parameters:

other - The other instance to compare to this one.

Returns:

true if the two objects are defined equivalently; otherwise false.

checkForSameDefinition

protected boolean checkForSameDefinition(@Nullable
                                         InequalityConstraintSettings other)

Checks to determine if another instance has the same definition as this instance and returns true if it does. Derived classes MUST override this method and check all new fields introduced by the derived class for definitional equivalence. It is NOT necessary to check base class fields because the base class will already have done that. When overriding this method, you should NOT call the base implementation because it will return false for all derived-class instances. Derived classes should check the type of other to preserve the symmetric nature of IEquatableDefinition.isSameDefinition(java.lang.Object).

Parameters:

other - The other instance to compare to this one.

Returns:

true if the two objects are defined equivalently; otherwise false.

computeCurrentDefinitionHashCode

protected int computeCurrentDefinitionHashCode()

Computes a hash code based on the current properties of this object. Derived classes MUST override this method and compute a hash code that combines: a unique hash code seed, the base implementation result, and the hash codes of all new fields introduced by the derived class which are used in the InequalityConstraintSettings.checkForSameDefinition(agi.foundation.infrastructure.DefinitionalObject) method.

Overrides:

computeCurrentDefinitionHashCode in class DefinitionalObject

Returns:

The computed hash code.

enumerateDependencies

public void enumerateDependencies(DependencyEnumerator enumerator)

Enumerates the dependencies of this object by calling DependencyEnumerator#enumerate(T) for each object that this object directly depends upon. Derived classes which contain additional dependencies MUST override this method, call the base implementation, and enumerate dependencies introduced by the derived class.

Specified by:

enumerateDependencies in interface IEnumerateDependencies

Overrides:

enumerateDependencies in class DefinitionalObject

Parameters:

enumerator - The enumerator that is informed of the dependencies of this object.

getIsThreadSafe

public boolean getIsThreadSafe()

Gets a value indicating whether the methods on this instance are safe to call from multiple threads simultaneously.

If this property is true, all methods and properties are guaranteed to be thread safe. Conceptually, an object that returns true for this method acts as if there is a lock protecting each method and property such that only one thread at a time can be inside any method or property in the class. In reality, such locks are generally not used and are in fact discouraged. However, the user must not experience any exceptions or inconsistent behavior that would not be experienced if such locks were used.

If this property is false, the behavior when using this class from multiple threads simultaneously is undefined and may include inconsistent results and exceptions. Clients wishing to use multiple threads should call CopyForAnotherThread.copy(T) to get a separate instance of the object for each thread.

Specified by:

getIsThreadSafe in interface IThreadAware

getBoundValue

public final double getBoundValue()

Gets the value of the upper or lower bound that defines the inequality.

setBoundValue

public final void setBoundValue(double value)

Sets the value of the upper or lower bound that defines the inequality.

getTolerance

public final double getTolerance()

Gets a value indicating how close the evaluated value must get to the BoundValue (get / set) to consider this inequality to be on the bound.

setTolerance

public final void setTolerance(double value)

Sets a value indicating how close the evaluated value must get to the BoundValue (get / set) to consider this inequality to be on the bound.

getScaling

public final InequalityConstraintScaling getScaling()

Gets the type of scaling applied to the constraint.

setScaling

public final void setScaling(InequalityConstraintScaling value)

Sets the type of scaling applied to the constraint.

getName

public final String getName()

Gets an optional name for this constraint.

setName

public final void setName(String value)

Sets an optional name for this constraint.

getBoundType

@Nonnull
public final InequalityBoundType getBoundType()

Gets a value indicating whether the inequality represents an upper bound or a lower bound.

setBoundType

public final void setBoundType(@Nonnull
                               InequalityBoundType value)

Sets a value indicating whether the inequality represents an upper bound or a lower bound.

getWeight

public final double getWeight()

Gets a value multiplied by the constraint error to prioritize or de-prioritize it with respect to other constraints or the cost function.

setWeight

public final void setWeight(double value)

Sets a value multiplied by the constraint error to prioritize or de-prioritize it with respect to other constraints or the cost function.

inequalitySatisfied

public final boolean inequalitySatisfied(double currentInequalityValue)

Determines if the current inequality value satisfies the inequality defined by the BoundType (get / set) and BoundValue (get / set).

Parameters:

currentInequalityValue - The current value of the inequality constraint function.

Returns:

true if the value is within the inequality defined by the bound type and bound value; otherwise false.

inequalityWithinTolerance

public final boolean inequalityWithinTolerance(double currentInequalityValue)

Calculates if the absolute value of the current constraint value minus the BoundValue (get / set) is smaller than the Tolerance (get / set).

Parameters:

currentInequalityValue - The current value of the inequality constraint function.

Returns:

true if the current constraint value is within tolerance of the bound value; otherwise false.

inequalitySatisfiedAndWithinTolerance

public final boolean inequalitySatisfiedAndWithinTolerance(double currentInequalityValue)

Calculates if the current constraint value both satisfies the inequality and is within tolerance of the bound value (on the feasible side of the inequality).

Parameters:

currentInequalityValue - The current value of the inequality constraint function.

Returns:

true if the current constraint value is within tolerance of the bound value on the feasible side; otherwise false.