TRSGeneticProgrammingVariant Class

Create(TComponent)

Initializes a new instance of the TRSCustomGeneticProgramming<T> class. (Overrides RSGeneticBase.TRSCustomGeneticComponent.Create(TComponent).)

AvgFitness

Returns the average fitness level of the   Population.
 (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

AvgProgramDepth

Returns the average program depth of the current   Population (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

AvgProgramSize

Returns the average program size of the current   Population (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

AvgWeightedFitness

Returns the average weighted fitness level of the   Population.
 (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

BloatLimit

Represents property BloatLimit.

BloatStrategy

Represents property BloatStrategy.

CrossoverMethod

Represents property CrossoverMethod.

CrossoverProbability

Represents property CrossoverProbability.

CumNormFitnesses

Contains the cumulative normalized fitnesses of the current generation (   Population) (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

Diversity

Returns the genetic diversity of the current Population, which is the   AvgFitness /   MaxFitness. In other words, how different (based upon fitness) are the individuals in the population from each other? If the population is not diverse enough, it is hard to breed a solution as everyone is alike. The genetic component can use the Diversity with the   DiversityLimit to automatically abort evolution if the diversity indicates we are in an evolutionary dead-end.
 (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

DiversityLimit

Represents property DiversityLimit.

ElitistPct

Represents property ElitistPct.

FitnessCutoff

Represents property FitnessCutoff.

FitnessMethod

Represents property FitnessMethod.

FitnessSum

Contains the sum of all fitness values for the entire population (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

FittestIndividual

Returns the fittest individual in the Population. The individual is chosen based on the FitnessMethod and the Fitness evaluations of all the individuals in the population. The FittestIndividual is chosen every time the population is evolved.
 

This property is nil if the component is not  Initialized.

FunctionsCount

Returns the number of   Instructions that are not terminals (i.e., functions of arity > 0) (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

Functions[Integer]

Returns a non-terminal function (Instructions that are functions of arity > 0) in the list of functions (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

Generation

Represents property Generation.

GenerationLimit

Represents property GenerationLimit.

Halt

Controls   Evolve method execution. Set Halt to true to stop evolution (useful for multi-threading) (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

InitialDuplicatesRetries

Represents property InitialDuplicatesRetries.

InitializationDepth

Represents property InitializationDepth.

InitializationMethod

Represents property InitializationMethod.

Initialized

Returns true if the genetic component has been initialized (and initial population has been created and evaluated for fitness) (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

InitialPopulation

Represents property InitialPopulation.

Instructions

Represents property Instructions.

InversionProbability

Represents property InversionProbability.

MaxFitness

Returns the highest fitness level of the   Population.
 
 (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

MaxProgramDepth

Returns the maximum program depth of the current   Population (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

MaxProgramSize

Returns the maximum program size of the current   Population (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

MaxWeightedFitness

Returns the highest weighted fitness level of the   Population.
 (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

MinFitness

Returns the lowest fitness level of the   Population.
 (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

MinProgramDepth

Returns the minimum program depth of the current   Population (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

MinProgramSize

Returns the minimum program size of the current   Population (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

MinWeightedFitness

Returns the lowest weighted fitness level of the   Population.
 (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

MutateConstantWeight

Represents property MutateConstantWeight.

MutateHoistWeight

Represents property MutateHoistWeight.

MutatePointWeight

Represents property MutatePointWeight.

MutateReplacementWeight

Represents property MutateReplacementWeight.

MutateShrinkWeight

Represents property MutateShrinkWeight.

MutateSubtreeWeight

Represents property MutateSubtreeWeight.

MutationProbability

Represents property MutationProbability.

MutationWeights

Defines the weights or probabilities that particular mutation methods will be chosen over the other genetic programming mutation methods. When mutation is selected to occur (see MutationProbability ), the genetic programming component chooses a mutation method using the weights you supply. (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

MutationWeightSum

Returns the sum of all the   MutationWeights (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

OnConstantMutation

Represents property OnConstantMutation.

OnCrossover

Represents property OnCrossover.

OnEvaluateFitness

Represents property OnEvaluateFitness.

OnEvolve

Represents property OnEvolve.

OnInitialization

Represents property OnInitialization.

OnInitializeChild

Represents property OnInitializeChild.

OnMutation

Represents property OnMutation.

OnReproduction

Represents property OnReproduction.

OnSelection

Represents property OnSelection.

Operations

Returns a list of the   Instructions that are functions with arity > 0 (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

ParsimonyCoefficient

Represents property ParsimonyCoefficient.

PointMutationMethod

Represents property PointMutationMethod.

PointMutationProbability

Represents property PointMutationProbability.

Population

Represents the entire population of candidate individuals (TRSIndividual) in the current Generation, including the     FittestIndividual. The TRSCustomGeneticProgramming<T> component seeks to solve your optimization or search problems by evolving a group or population of candidate individuals through successive generations, selecting fitter (or better) child individuals for each generation, until a solution is found.

After every call to  Evolve, the Population property contains the next generation of individuals (the children), with the     PreviousGeneration property holding the previous generation (the parents, what was the Population before the Evolve call).
 

PreviousGeneration

Contains the parents of the current generation, which is represented by the   Population property. After every call to  Evolve, the Population property contains the next generation of individuals (the children), with the PreviousGeneration property holding the previous generation (the parents, what was the Population before the Evolve call).
 (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

PriorityQueue

Returns the population sorted by fitness (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

RouletteIndex

Index of the individual next up in Elitist selection method or index of winner of roulette wheel selection method (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

SelectionMethod

Represents property SelectionMethod.

SelectionNonTerminalsProbability

Represents property SelectionNonTerminalsProbability.

TarpeianProbability

Specifies the probability that an individual's  Fitness will be set to UnfitFitness when its genetic program     Size or     Depth exceeds the average size or depth. The Tarpeian anti-bloat strategy has the advantage that the individual is judged before evaluating fitness which can significantly reduce computation.

This property is used when the BloatStrategy is bsTarpeianDepth or bsTarpeianSize.

Terminals

Returns a list of the   Instructions that are terminals: constants, variables, and functions of arity 0. (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

TerminalsCount

Returns the number of   Instructions that are terminals (i.e., constants, variables, and functions of arity = 0) (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

Terminal[Integer]

Returns a terminal (   Instructions that are constants, variables or functions of arity = 0) in the list of terminals (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

TournamentField

Represents property TournamentField.

UseDiversityLimit

Represents property UseDiversityLimit.

UseFitnessCutoff

Represents property UseFitnessCutoff.

UseGenerationLimit

Represents property UseGenerationLimit.

WeightedFitnessSum

Contains the sum of all weighted fitness values for the entire population (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

Assign(TPersistent)

Represents method Assign(TPersistent). (Overrides RSGeneticBase.TRSCustomGeneticComponent.Assign(TPersistent).)

AssignAll(TPersistent)

Represents method AssignAll(TPersistent). (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

CalculateCumulativeNormalizedFitnesses

Calculates the cumulative normalized fitness values of the   Population (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

CompareFitness(TRSIndividual,TRSIndividual,Boolean)

Compares the two individuals and returns an evaluation of who is fitter. If the result is -1, Parent1 is fitter. If the result is 1, Parent2 is fitter. If the two individuals are equally fit, the function returns 0.

The function uses the RSGeneticBase.TRSIndividual.Fitness property or RSGeneticBase.TRSIndividual.WeightedFitness to determine which parent is fitter. The     FitnessMethod controls the interpretation of the fitness.

The UsePureFitness parameter tells the function if it should ignore WeightedFitness or not.

CreateInstructions(TCollectionItemClass)

Creates the instructions collection (Overrides RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.CreateInstructions(TCollectionItemClass).)

CreateNode(TRSGPInstruction<Variant>,TRSGPNode<Variant>)

Represents method CreateNode(TRSGPInstruction<Variant>,TRSGPNode<Variant>). (Inherited from RSGeneticProgramming.TRSCustomGeneticProgrammingVariant.)

CreatePopulation(TRSIndividualClass)

Creates the population collection (Overrides RSGeneticBase.TRSCustomGeneticComponent.CreatePopulation(TRSIndividualClass).)

Crossover(TRSIndividual,TRSIndividual,TRSIndividual)

Overloaded.  Combines the DNA of the two parents to make the DNA of the children. Note that crossover is not guaranteed to occur but is dependent on the     CrossoverProbability. The function calls the     OnCrossover event and then  DoCrossover method.

The Crossover method is called by the     Reproduce method. The function returns true if crossover occurred.
 

Crossover(TRSIndividual,TRSIndividual,TRSIndividual,TRSIndividual)

Overloaded.  Combines the DNA of the two parents to make the DNA of the children. Note that crossover is not guaranteed to occur but is dependent on the     CrossoverProbability. The function calls the     OnCrossover event and then  DoCrossover method.

The Crossover method is called by the     Reproduce method. The function returns true if crossover occurred.
 

DefineProperties(TFiler)

Represents method DefineProperties(TFiler). (Overrides RSGeneticBase.TRSCustomGeneticComponent.DefineProperties(TFiler).)

Describe(TStrings,String)

Provides a description of the genetic programming component and its important properties. The description is added to the Strings parameter. The TabStr parameter specifies the indentation to use when adding sub-strings. (Overrides RSGeneticBase.TRSCustomGeneticComponent.Describe(TStrings,String).)

DoAntiBloating(TRSIndividual,TRSIndividual,TRSIndividual,Boolean)

Performs the actual anti-bloating strategy after the new child has been created. The IsChildModified parameter indicates if the child was mutated or inverted

DoCalculateFitnessStatistics

Calculates the fitness statistics (max, min, avg) for one generation. The method accesses each individual's Fitness property which may force a fitness evaulation to occur. (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

DoCalculateWeightedFitnessStatistics

Calculates the weighted fitness statistics (max, min, avg) for one generation. The method accesses each individual's WeightedFitness property which may force a fitness evaulation to occur. (Overrides RSGeneticBase.TRSCustomGeneticComponent.DoCalculateWeightedFitnessStatistics.)

DoConstantMutation(TIndividual)

Performs a constant mutation (changes the constant of a tree node) (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

DoCrossover(TRSIndividual,TRSIndividual,TRSIndividual,TRSIndividual)

Performs the actual crossover operation. The decision to crossover has already been decided by the time this method is called. (Overrides RSGeneticBase.TRSCustomGeneticComponent.DoCrossover(TRSIndividual,TRSIndividual,TRSIndividual,TRSIndividual).)

DoEvaluateWeightedFitness(TRSIndividual)

Calls the OnEvaluateWeightedFitness event and returns the result. If the event handler has not been defined, this method returns the regular fitness (Overrides RSGeneticBase.TRSCustomGeneticComponent.DoEvaluateWeightedFitness(TRSIndividual).)

DoEvolve

Performs the actual evolve for one generation with each new pair of children being created in sequence (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

DoEvolveOneStep(Integer)

Performs the actual evolve for one pair of children (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

DoFairCrossover(TRSIndividual,TRSIndividual,TRSIndividual)

Represents method DoFairCrossover(TRSIndividual,TRSIndividual,TRSIndividual). (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

DoFinishEvolve

Performs final steps for one evolution phase. Called by DoEvolve. (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

DoHoistMutation(TIndividual)

Performs a hoist mutation. Hoist mutation replaces the entire child program tree with a subtree from the child (the subtree becomes the root node). This has the effect of reducing the complexity of the child. (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

DoInitialize

Performs the actual initialization of the Population before evolution occurs.

The method returns number of duplicates fixed.

DoInitializeFull(TNode,Integer,Integer)

Initializes a genetic program tree to the full depth.

The Full method creates trees that all equal the     InitializationDepth (think full, bushy trees). There are not necessarily all the same size (number of nodes) as they depends on the arity of the instructions, but the same initial depth. The Full method creates trees by selecting only functions with arity greater than 0 until the initialization depth is reached; after which only terminals are selected.
 

DoInitializeGrow(TNode,Integer,Integer)

Initializes a genetic program tree by growing to the depth indicated.

The Grow method creates trees of a wider variety of shapes and sizes than the full method. In the Grow method, nodes for the trees are selected from the full set of primitives (functions, constants, and variables) until the initialization depth is reached. Since an early node could select a terminal (constant, variable, or function of arity = 0), that node's subtree stops growing before the initialization depth.
 

DoInvert(TRSIndividual)

Performs the actual inversion of the individual. The decision to invert the individual has already been made before calling this method. (Overrides RSGeneticBase.TRSCustomGeneticComponent.DoInvert(TRSIndividual).)

DoMutate(TRSIndividual)

Performs the actual mutation of the individual. The decision to mutat the individual has already been made before calling this method. (Overrides RSGeneticBase.TRSCustomGeneticComponent.DoMutate(TRSIndividual).)

DoParallelEvolveOneStep(Integer)

Performs the actual evolve for one pair of children (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

DoPointMutation(TIndividual)

Overloaded. Performs point mutation. A random node is selected and the primitive
stored there is replaced with a different random primitive of the same arity taken from the primitive set
 (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

DoPointMutation(TIndividual,TNode)

Overloaded.  Performs point mutation on the tree. A random node is selected and the primitive stored there is replaced with a different random primitive of the same arity taken from the primitive set

Returns true if a point mutation occurred. Point mutation can occur more than once based on     PointMutationMethod.
 

DoReplacementMutation(TIndividual)

Performs a replacement mutation (replace a subtree of the individual with another subtree that starts with the same arity) (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

DoReproduce(TRSIndividual,TRSIndividual,TRSIndividual)

Performs the actual reproduction operation by combining the two parents to make the new Child. The Child must already exist but may be uninitialized. (Overrides RSGeneticBase.TRSCustomGeneticComponent.DoReproduce(TRSIndividual,TRSIndividual,TRSIndividual).)

DoReproduce(TRSIndividual,TRSIndividual,TRSIndividual,TRSIndividual)

Performs the actual reproduction operation by combining the two parents to make two new children. The children must already exist but may be uninitialized. (Overrides RSGeneticBase.TRSCustomGeneticComponent.DoReproduce(TRSIndividual,TRSIndividual,TRSIndividual,TRSIndividual).)

DoSelectionPreparation

Performs any steps necessary for selecting parents in the newly evolved Population.

This method is called when evaluating fitness for everyone.
 

DoSelectParent(TRSPopulation)

Performs the selection of a parent from the Population. This method is only called if the   SelectionMethod is Custom. (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

DoShrinkMutation(TIndividual)

Performs a shrink mutation. Shrink mutation replaces a subtree of the child with a terminal. This has the effect of reducing the complexity of the child. (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

DoStartEvolve

Performs initial steps for one evolution phase. Called by DoEvolve. (Overrides RSGeneticBase.TRSCustomGeneticComponent.DoStartEvolve.)

DoSubtreeMutation(TIndividual)

Performs a subtree mutation (replace a subtree of the individual with another subtree) (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

EvaluateFitness

Overloaded.  Evaluates the fitness for every individual of the Population (and calculates the     MaxFitness,     MinFitness, and     AvgFitness). It calculates a fitness estimation for every RSGeneticBase.TRSIndividual by calling the overloaded     EvaluateFitness method. It uses your     OnEvaluateFitness event handler to calculate values. After every individual is evaluated, it sets the MaxFitness, MinFitness, and AvgFitness values and sets the     FittestIndividual property.

Defining your fitness function is a highly important part of defining a genetic algorithm or genetic program. The fitness function returns a floating point value that specifies the correctness of the individual solution. The fitness function needs to be able to allow the genetic component to decide which solution is better than another. The genetic component will seek to either maximize the solution (e.g., keep evolving for individuals whose fitness are greater than other individuals in the population) or to minimize the solution (e.g., find the individuals whose fitness are less than other individuals). Note you can specify which direction to evolve towards with the     FitnessMethod property.
 

EvaluateFitness(TRSIndividual,Boolean)

Returns a fitness estimation of the passed in RSGeneticBase.TRSIndividual . It uses your     OnEvaluateFitness event handler to return the value.

Defining your fitness function is a highly important part of defining a genetic algorithm or genetic program. The fitness function returns a floating point value that specifies the correctness of the individual solution. The fitness function needs to be able to allow the genetic component to decide which solution is better than another. The genetic component will seek to either maximize the solution (e.g., keep evolving for individuals whose fitness are greater than other individuals in the population) or to minimize the solution (e.g., find the individuals whose fitness are less than other individuals). Note you can specify which direction to evolve towards with the     FitnessMethod property.

The overloaded     EvaluateFitness method evaluates the fitness for every individual of the Population (and calculates the     MaxFitness,     MinFitness, and     AvgFitness).
 

Evolve

Overloaded.  The Evolve method is the heart of the genetic component. The Evolve method is responsible for "breeding" the     Population towards an answer for your goal. Each generation, the Evolve method selects parents and then     Reproduces children for the new generation by using the genetic operations: first crossover, then mutation, and finally inversion. Each call to Evolve with breed one new generation. If you want to evolve many new generations at once (perhaps with a cutoff using the     FitnessCutoff,     GenerationLimit and     DiversityLimit properties), use the overloaded Evolve method. Successive calls to the Evolve method continues the evolutionary process from where the Evolve method stopped (use     Initialize to reset the process). If this is your first call to Evolve, it automatically calls the Initialize method.

Specify the     Operations to control which operations are performed while evolving: crossover, mutation, and inversion operations. You can also specify the chances of each operation occurring every generation using the     CrossoverProbability,     MutationProbability, and     InversionProbability properties.

The     SelectionMethod property (or     OnSelection event) specifies how the genetic component selects individuals from the current generation to be used as parents of the next generation.

The FitnessCutoff property aborts the evolutionary process when any child meets or exceeds (if FitnessMethod is fmMaximize) or is less than (if FitnessMethod is fmMinimize) the cutoff value. The     UseFitnessCutoff property must be true to use the fitness cutoff.

The DiversityLimit property aborts the evolutionary process when the diversity of the children falls below the DiversityLimit, e.g., all the children are too alike to go any further. The     UseDiversityLimit property must be true to use the diversity limit.

The GenerationLimit property aborts the evolutionary process when the required number of generations have been evolved. The     UseGenerationLimit property must be true to use the generation limit.
 
 

Evolve(Integer)

Overloaded.  The Evolve method is the heart of the genetic component. The Evolve method is responsible for "breeding" the     Population towards an answer for your goal. Each generation, the Evolve method selects parents and then     Reproduces children for the new generation by using the genetic operations: first crossover, then mutation, and finally inversion. You can specify the number of generations to evolve or use the     FitnessCutoff,     GenerationLimit and     DiversityLimit properties to automatically stop the genetic process. Successive calls to the Evolve method continues the evolutionary process from where the Evolve method stopped (use     Initialize to reset the process). If this is your first call to Evolve, it automatically calls the Initialize method.

Specify the     Operations to control which operations are performed while evolving: crossover, mutation, and inversion operations. You can also specify the chances of each operation occurring every generation using the     CrossoverProbability,     MutationProbability, and     InversionProbability properties.

The     SelectionMethod property (or     OnSelection event) specifies how the genetic component selects individuals from the current generation to be used as parents of the next generation.

The FitnessCutoff property aborts the evolutionary process when any child meets or exceeds (if FitnessMethod is fmMaximize) or is less than (if FitnessMethod is fmMinimize) the cutoff value. The     UseFitnessCutoff property must be true to use the fitness cutoff.

The DiversityLimit property aborts the evolutionary process when the diversity of the children falls below the DiversityLimit, e.g., all the children are too alike to go any further. The     UseDiversityLimit property must be true to use the diversity limit.

The GenerationLimit property aborts the evolutionary process when the required number of generations have been evolved. The     UseGenerationLimit property must be true to use the generation limit.
 
 
 

Fittest(TRSIndividual,TRSIndividual,Boolean)

Returns the "fitter" of the two parent individuals. It compares the Fitness properties (or WeightedFitness) of both individuals, and, based on the FitnessMethod, selects the better individual. (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

GetAdjustedFitness(TGAFitness)

Calculates the adjusted fitness, a value between 0 and 1, where a bigger value (closer to 1) represents better individuals.

The adjusted fitness equals 1/(1 + StandardizedFitness) when minimizing, and 1/(1+(MaxFitness - StandardizedFitness)) when maximizing.
 

GetNode(TNode,Integer)

Overloaded. Creates and returns a node for the specified parent node. The node may be a function, constant, or variable node (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

GetNode(TNode,TNode,Integer)

Overloaded. Creates and returns a node for the specified parent node. The node is similar (of the same type and arity of the Similar node parameter) (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

GetNormalizedFitness(TGAFitness)

Calculates the normalized fitness, a value between 0 and 1.

The normalized fitness equals Fitness / Sum of All Fitness

GetNormalizedWeightedFitness(TGAFitness)

Calculates the normalized weighted fitness, a value between 0 and 1.

The normalized fitness equals Fitness / Sum of All Weighted Fitness

GetOperationNode(TNode,Integer)

Creates and returns a function node for the specified parent node from the list of   Operations (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

GetSimilarInstruction(TInstruction)

Returns an instruction that is similar (of same type and arity) (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

GetTerminalNode(TNode,Integer)

Creates and returns a terminal (constants, variables, and functions of arity=0) node for the specified parent node from the list of   Terminals (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

Initialize

Prepares the genetic component for evolution (or resets the genetic population to start over). On calling the Initialization method, the Population is set to the   InitialPopulation size. The   OnInitialization method is called. Then, the Population's DNA are randomized and each individual's fitness is evaluated. (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

InitializeChild(TRSIndividual,TRSIndividual,TRSIndividual)

Initializes the Child with the two parents (usually just a copy of the first parent) (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

InstructionNotify(TInstruction,Classes)

Called when an instruction is added or removed from the   Instructions (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

InstructionOperationUpdate(TInstruction)

Called when an instruction's Operation is changed (i.e., it changes from a function to a constant or a variable to a function, etc) (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

InstructionUpdate(TInstruction)

Called when an instruction is changed (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

Invert(TRSIndividual)

Inverts the DNA of the individual. Inversion for genetic algorithms means flipping the bits of the chromosome. For genetic programs, inversion means a point mutation (replacing a node with another node of the same arity in the tree).

Note that inversion is not guaranteed to occur but is dependent on the     InversionProbability. The function calls the     OnInversion event and then DoInvert method.
 
The Invert method is called by the     Reproduce method. The function returns true if inversion occurred.
 

IsCustomSelection

Returns true if   SelectionMethod is custom (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

IsFinished

Returns true if the evolution process is complete. The process is complete if the Fitness meets the   FitnessCutoff (if   UseFitnessCutoff is true) or the population diversity meets the   DiversityLimit (if   UseDiversityLimit is true) or the   Generation exceeds the   GenerationLimit (if   UseGenerationLimit is true). (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

LoadFromFile(string)

Loads the entire genetic component from the XML file specified by the Filename parameter, including the Genes (genetic algorithms) or Instructions (genetic programming) and the Population. Use the LoadFromFile and SaveToFile methods to stream in and out the genetic component in XML format. The format of the XML is defined in the GeneticAlgorithm.xsd and GeneticProgramming.xsd schema files. (Overrides RSGeneticBase.TRSCustomGeneticComponent.LoadFromFile(string).)

LoadFromStream(TStream)

Loads the entire genetic component from the XML stream specified by the stream parameter, including the Genes (genetic algorithms) or Instructions (genetic programming) and the Population. Use the LoadFromStream and SaveToStream methods to stream in and out the genetic component in XML format. The format of the XML is defined in the GeneticAlgorithm.xsd and GeneticProgramming.xsd schema files. (Overrides RSGeneticBase.TRSCustomGeneticComponent.LoadFromStream(TStream).)

LoadFromXML(IXMLGeneticProgram)

Overloaded. Load the entire genetic programming scenario from the XML

LoadFromXML(IXMLGPDomainType)

Overloaded. Load the genetic programming domain ( instructions, fittest individual, population) from the XML

LoadFromXML(IXMLGPInstructions)

Overloaded. Load the genetic programming instructions from the XML

MaxNodeArity

Returns the maximum number of children and node ( RSGenerics.GeneticProgramEngine.TRSGPNode<T> ) in the component can accept (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

Mutate(TIndividual,TGPMutationMethod)

Overloaded.  Mutates the DNA of the individual using the Mutation method. The mutation method controls how the genetic program tree is modified.

This method is called by the overloaded Mutate method when mutation is found to have occurred by its probability.
 

PopulationNotify(TRSIndividual,TCollectionNotification)

Called when an individual is added or removed from the   Population (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

PopulationUpdate(TRSIndividual)

Called when an individual has changed (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

PrioritizePopulation

Prioritizes or sorts the population based on Fitness or WeightedFitness and the   FitnessMethod. (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

Reproduce(TRSIndividual,TRSIndividual,TRSIndividual)

Overloaded.  The Reproduce method takes the two Parents and "mates" them to create the new Children. The Child parameters must exist but all of their information will be overwritten by the Parents. The New Child is copied from its first parent and then     Crossover,     Mutate, and     Invert are called according to the Operations property and the respective probability of the operation. Finally, an     OnReproduction event occurs.

The Evolve method calls the Reproduce methods.
 

Reproduce(TRSIndividual,TRSIndividual,TRSIndividual,TRSIndividual)

Overloaded.  The Reproduce method takes the two Parents and "mates" them to create the new Children. The Child parameters must exist but all of their information will be overwritten by the Parents. Child1 is copied from the first parent and Child2 is copied from the second parent, and then     Crossover,     Mutate, and     Invert are called according to the Operations property and the respective probability of the operation. Finally, an     OnReproduction event occurs.

The Evolve method calls the Reproduce methods.
 

SaveToFile(string)

Saves the entire genetic component to the XML file specified by the Filename parameter, including the Genes (genetic algorithms) or Instructions (genetic programming) and the Population. Use the LoadFromFile and SaveToFile methods to stream in and out the genetic component in XML format. The format of the XML is defined in the GeneticAlgorithm.xsd and GeneticProgramming.xsd schema files. (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

SaveToStream(TStream)

Saves the entire genetic component to the XML stream specified by the stream parameter, including the Genes (genetic algorithms) or Instructions (genetic programming) and the Population. Use the LoadFromFile and SaveToFile methods to stream in and out the genetic component in XML format. The format of the XML is defined in the GeneticAlgorithm.xsd and GeneticProgramming.xsd schema files. (Overrides RSGeneticBase.TRSCustomGeneticComponent.SaveToStream(TStream).)

SaveToXML(IXMLGeneticDocumentType)

Overloaded. Saves the entire genetic component to the XML specified by the parameter, including the Genes (genetic algorithms) or Instructions (genetic programming) and the Population. Use the LoadFromFile and SaveToFile methods to stream in and out the genetic component in XML format. The format of the XML is defined in the GeneticAlgorithm.xsd and GeneticProgramming.xsd schema files. (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

SaveToXML(IXMLGeneticProgram)

Overloaded. Saves the genetic programming scenario to XML

SaveToXML(IXMLGPDomainType)

Overloaded. Saves the genetic programming domain ( instructions, fittest individual, population) to XML

SaveToXML(IXMLGPInstructions)

Overloaded. Saves the genetic programming instructions to XML

SearchSpaceSize(Cardinal)

Returns the size of size of the total set of trees from one level of nodes up to a maximum size identified by the variable level. This space contains every combination of the functions and terminals, and the arity of each function arity for every tree of depth 1 up to the stated maximum depth. This number is useful for getting an idea of the size of the search space and may encourage you to reduce the number of functions, terminals, or arity of functions. (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

SelectElitist(TObject,TRSPopulation,TRSIndividual)

Selected a Parent individual from the Population using the Elitist method.

The top nth percentile parents are chosen (and re-chosen) using this method. Elitist is a heavy-weight selection algorithm (in our implementation at least) because we must figure out the top nth percentile population first
 

SelectParent(TRSPopulation)

Selects a parent for the new generation using the   SelectionMethod or the   OnSelection event. (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

SelectRandom(TObject,TRSPopulation,TRSIndividual)

Selected a Parent individual from the Population at random.
 (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

SelectRoulette(TObject,TRSPopulation,TRSIndividual)

Selected a Parent individual from the Population using the Roulette Wheel (fitness proportional) method.

The better "fit" parents are more likely to be chosen (and re-chosen), e.g., the probability of selection is proportional to the fitness of the parent. Also known as fitness proportionate selection.
 

SelectStochasticTournament(TObject,TRSPopulation,TRSIndividual)

Selected a Parent individual from the Population using the Elitist method.

Select "best" (in this case using roulette wheel) parents from a tournament field (size of tournament field is determined by the     TournamentField property), e.g., select the best parent by selecting better fit individuals proportionally TournamentField times and then choosing the "winner" of the tournament. Note: for speed purposes, this selection method does not ensure that the same individual cannot be picked twice
 

SelectTournament(TObject,TRSPopulation,TRSIndividual)

Selected a Parent individual from the Population using the Tournament method.

Select "best" parents from a tournament field (size of tournament field is determined by the     TournamentField property), e.g., select the best parent from randomly selecting individuals TournamentField times and then choosing the "winner" of the tournament. Note: for speed purposes, this selection method does not ensure that the same individual cannot be picked twice
 

SumOfWeights(TGPMutationMethodWeights)

Calculates the sum of all the   MutationWeights (Inherited from RSGenerics.GeneticProgramming.TRSCustomGeneticProgramming<T>.)

SwapGenerations

Swaps the Population and PreviousGeneration collections in preparation for evolving a new generation. (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

ToString

Provides a strings description of the genetic programming component and its important properties. The function uses the  Describe method to build the string. (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

UnfitFitness

Returns a value that represents extreme unfitness. Useful for breeding out an individual by settings its fitness to this value (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)

OnEvaluateWeightedFitness

Occurs when the genetic component needs to evaluate weighted fitness for an individual.

Weighted Fitness allows weighting the fitness for searching the solution space to guide the search. Fitness still evaluates if an individual solves the problem, but the weighted fitness can help constrain the search. For example, genetic programs can weight the fitness by reducing the fitness by the size of the program (limiting growth).

OnInversion

Occurs when two parents (TRSIndividual) have reproduced to create a new child and some portion of the child's DNA is about to be inverted. The DoMutation parameter controls whether the inversion will occur. It has already been set based on the   InversionProbability (and so sometimes will be True and sometimes will be False). Set the DoMutation parameter either to force the inversion to occur or to prohibit it from occurring. (Inherited from RSGeneticBase.TRSCustomGeneticComponent.)