AbstractModule

Instance Constructors

new AbstractModule()(implicit arg0: ClassTag[A], arg1: ClassTag[B], arg2: ClassTag[T], ev: TensorNumeric[T])

Abstract Value Members

abstract def updateGradInput(input: A, gradOutput: B): A

Computing the gradient of the module with respect to its own input.
Computing the gradient of the module with respect to its own input. This is returned in gradInput. Also, the gradInput state variable is updated accordingly.
abstract def updateOutput(input: A): B

Computes the output using the current parameter set of the class and input.
Computes the output using the current parameter set of the class and input. This function returns the result which is stored in the output field.

Concrete Value Members

final def !=(arg0: Any): Boolean

Definition Classes
AnyRef → Any
final def ##(): Int

Definition Classes
AnyRef → Any
final def ==(arg0: Any): Boolean

Definition Classes
AnyRef → Any
def accGradParameters(input: A, gradOutput: B): Unit

Computing the gradient of the module with respect to its own parameters.
Computing the gradient of the module with respect to its own parameters. Many modules do not perform this step as they do not have any parameters. The state variable name for the parameters is module dependent. The module is expected to accumulate the gradients with respect to the parameters in some variable.
def apply(name: String): Option[AbstractModule[Activity, Activity, T]]

Find a module with given name.
Find a module with given name. If there is no module with given name, it will return None. If there are multiple modules with the given name, an exception will be thrown.
final def asInstanceOf[T0]: T0

Definition Classes
Any
def backward(input: A, gradOutput: B): A

Performs a back-propagation step through the module, with respect to the given input.
Performs a back-propagation step through the module, with respect to the given input. In general this method makes the assumption forward(input) has been called before, with the same input. This is necessary for optimization reasons. If you do not respect this rule, backward() will compute incorrect gradients.
input
input data
gradOutput
gradient of next layer
returns
gradient corresponding to input data
var backwardTime: Long

Attributes
protected
def clearState(): AbstractModule.this.type

Clear cached activities to save storage space or network bandwidth.
Clear cached activities to save storage space or network bandwidth. Note that we use Tensor.set to keep some information like tensor share
The subclass should override this method if it allocate some extra resource, and call the super.clearState in the override method
final def clone(deepCopy: Boolean): AbstractModule[A, B, T]

Clone the module, deep or shallow copy
def clone(): AnyRef

Attributes
protected[java.lang]
Definition Classes
AnyRef
Annotations
@throws( ... )
final def cloneModule(): AbstractModule.this.type

Clone the model
final def eq(arg0: AnyRef): Boolean

Definition Classes
AnyRef
def equals(other: Any): Boolean

Definition Classes
AbstractModule → AnyRef → Any
final def evaluate(dataSet: LocalDataSet[MiniBatch[T]], vMethods: Array[_ <: ValidationMethod[T]]): Array[(ValidationResult, ValidationMethod[T])]

use ValidationMethod to evaluate module on the given local dataset
final def evaluate(dataset: RDD[MiniBatch[T]], vMethods: Array[_ <: ValidationMethod[T]]): Array[(ValidationResult, ValidationMethod[T])]

use ValidationMethod to evaluate module on the given rdd dataset
final def evaluate(dataset: RDD[Sample[T]], vMethods: Array[_ <: ValidationMethod[T]], batchSize: Option[Int] = None): Array[(ValidationResult, ValidationMethod[T])]

use ValidationMethod to evaluate module on the given rdd dataset
use ValidationMethod to evaluate module on the given rdd dataset
dataset
dataset for test
vMethods
validation methods
batchSize
total batchsize of all partitions, optional param and default 4 * partitionNum of dataset
def evaluate(): AbstractModule.this.type

Set the module to evaluate mode
final def evaluateImage(imageFrame: ImageFrame, vMethods: Array[_ <: ValidationMethod[T]], batchSize: Option[Int] = None): Array[(ValidationResult, ValidationMethod[T])]

use ValidationMethod to evaluate module on the given ImageFrame
use ValidationMethod to evaluate module on the given ImageFrame
imageFrame
ImageFrame for valudation
vMethods
validation methods
batchSize
total batch size of all partitions
def finalize(): Unit

Attributes
protected[java.lang]
Definition Classes
AnyRef
Annotations
@throws( classOf[java.lang.Throwable] )
final def forward(input: A): B

Takes an input object, and computes the corresponding output of the module.
Takes an input object, and computes the corresponding output of the module. After a forward, the output state variable should have been updated to the new value.
input
input data
returns
output data
var forwardTime: Long

Attributes
protected
def freeze(names: String*): AbstractModule.this.type

freeze the module, i.e.
freeze the module, i.e. their parameters(weight/bias, if exists) are not changed in training process if names is not empty, set an array of layers that match the given names to be "freezed",
names
an array of layer names
returns
current graph model
final def getClass(): Class[_]

Definition Classes
AnyRef → Any
def getExtraParameter(): Array[Tensor[T]]

Get extra parameter in this module.
Get extra parameter in this module. Extra parameter means the trainable parameters beside weight and bias. Such as runningMean and runningVar in BatchNormalization.
The subclass should override this method if it has some parameters besides weight and bias.
returns
an array of tensor
final def getInputShape(): Shape

Return the inputShape for the current Layer and the first dim is batch.
Return the inputShape for the current Layer and the first dim is batch.

Definition Classes
InferShape
final def getName(): String

Get the module name, default name is className@namePostfix
final def getNumericType(): TensorDataType

Get numeric type of module parameters
final def getOutputShape(): Shape

Return the outputShape for the current Layer and the first dim is batch.
Return the outputShape for the current Layer and the first dim is batch.

Definition Classes
InferShape
def getParametersTable(): Table

This function returns a table contains ModuleName, the parameter names and parameter value in this module.
This function returns a table contains ModuleName, the parameter names and parameter value in this module.
The result table is a structure of Table(ModuleName -> Table(ParameterName -> ParameterValue)), and the type is Table[String, Table[String, Tensor[T]]].
For example, get the weight of a module named conv1: table[Table]("conv1")[Tensor[T]]("weight").
The names of the parameters follow such convention:
1. If there's one parameter, the parameter is named as "weight", the gradient is named as "gradWeight"
2. If there're two parameters, the first parameter is named as "weight", the first gradient is named as "gradWeight"; the second parameter is named as "bias", the seconcd gradient is named as "gradBias"
3. If there're more parameters, the weight is named as "weight" with a seq number as suffix, the gradient is named as "gradient" with a seq number as suffix
Custom modules should override this function the default impl if the convention doesn't meet the requirement.
returns
Table
final def getPrintName(): String

Attributes
protected
final def getScaleB(): Double

Get the scale of gradientBias
final def getScaleW(): Double

Get the scale of gradientWeight
def getTimes(): Array[(AbstractModule[_ <: Activity, _ <: Activity, T], Long, Long)]

Get the forward/backward cost time for the module or its submodules
final def getTimesGroupByModuleType(): Array[(String, Long, Long)]

Get the forward/backward cost time for the module or its submodules and group by module type.
Get the forward/backward cost time for the module or its submodules and group by module type.
returns
(module type name, forward time, backward time)
final def getWeightsBias(): Array[Tensor[T]]

Get weight and bias for the module
Get weight and bias for the module
returns
array of weights and bias
var gradInput: A

The cached gradient of activities.
The cached gradient of activities. So we don't compute it again when need it
final def hasName: Boolean

Whether user set a name to the module before
def hashCode(): Int

Definition Classes
AbstractModule → AnyRef → Any
def inputs(first: (ModuleNode[T], Int), nodesWithIndex: (ModuleNode[T], Int)*): ModuleNode[T]

Build graph: some other modules point to current module
Build graph: some other modules point to current module
first
distinguish from another inputs when input parameter list is empty
nodesWithIndex
upstream module nodes and the output tensor index. The start index is 1.
returns
node containing current module
def inputs(nodes: Array[ModuleNode[T]]): ModuleNode[T]

Build graph: some other modules point to current module
Build graph: some other modules point to current module
nodes
upstream module nodes in an array
returns
node containing current module
def inputs(nodes: ModuleNode[T]*): ModuleNode[T]

Build graph: some other modules point to current module
Build graph: some other modules point to current module
nodes
upstream module nodes
returns
node containing current module
var inputsFormats: Seq[Int]

Attributes
protected
final def isInstanceOf[T0]: Boolean

Definition Classes
Any
final def isTraining(): Boolean

Check if the model is in training mode
var line: String

Attributes
protected
final def loadModelWeights(srcModel: Module[Float], matchAll: Boolean = true): AbstractModule.this.type

copy weights from another model, mapping by layer name
copy weights from another model, mapping by layer name
srcModel
model to copy from
matchAll
whether to match all layers' weights and bias,
returns
current module
final def loadWeights(weightPath: String, matchAll: Boolean = true): AbstractModule.this.type

load pretrained weights and bias to current module
load pretrained weights and bias to current module
weightPath
file to store weights and bias
matchAll
whether to match all layers' weights and bias, if not, only load existing pretrained weights and bias
returns
current module
final def ne(arg0: AnyRef): Boolean

Definition Classes
AnyRef
final def notify(): Unit

Definition Classes
AnyRef
final def notifyAll(): Unit

Definition Classes
AnyRef
var output: B

The cached output.
The cached output. So we don't compute it again when need it
var outputsFormats: Seq[Int]

Attributes
protected
def parameters(): (Array[Tensor[T]], Array[Tensor[T]])

This function returns two arrays.
This function returns two arrays. One for the weights and the other the gradients Custom modules should override this function if they have parameters
returns
(Array of weights, Array of grad)
final def predict(dataset: RDD[Sample[T]], batchSize: Int = 1, shareBuffer: Boolean = false): RDD[Activity]

module predict, return the probability distribution
module predict, return the probability distribution
dataset
dataset for prediction
batchSize
total batchSize for all partitions. if -1, default is 4 * partitionNumber of datatset
shareBuffer
whether to share same memory for each batch predict results
final def predictClass(dataset: RDD[Sample[T]], batchSize: Int = 1): RDD[Int]

module predict, return the predict label
module predict, return the predict label
dataset
dataset for prediction
batchSize
total batchSize for all partitions. if -1, default is 4 * partitionNumber of dataset
final def predictImage(imageFrame: ImageFrame, outputLayer: String = null, shareBuffer: Boolean = false, batchPerPartition: Int = 4, predictKey: String = ImageFeature.predict, featurePaddingParam: Option[PaddingParam[T]] = None): ImageFrame

model predict images, return imageFrame with predicted tensor, if you want to call predictImage multiple times, it is recommended to use Predictor for DistributedImageFrame or LocalPredictor for LocalImageFrame
model predict images, return imageFrame with predicted tensor, if you want to call predictImage multiple times, it is recommended to use Predictor for DistributedImageFrame or LocalPredictor for LocalImageFrame
imageFrame
imageFrame that contains images
outputLayer
if outputLayer is not null, the output of layer that matches outputLayer will be used as predicted output
shareBuffer
whether to share same memory for each batch predict results
batchPerPartition
batch size per partition, default is 4
predictKey
key to store predicted result
featurePaddingParam
featurePaddingParam if the inputs have variant size
def processInputs(first: (ModuleNode[T], Int), nodesWithIndex: (ModuleNode[T], Int)*): ModuleNode[T]

Attributes
protected
def processInputs(nodes: Seq[ModuleNode[T]]): ModuleNode[T]

Attributes
protected
final def quantize(): Module[T]

Quantize this module, which reduces the precision of the parameter.
Quantize this module, which reduces the precision of the parameter. Get a higher speed with a little accuracy cost.
def release(): Unit

if the model contains native resources such as aligned memory, we should release it by manual.
if the model contains native resources such as aligned memory, we should release it by manual. JVM GC can't release them reliably.
def reset(): Unit

Reset module parameters, which is re-initialize the parameter with given initMethod
def resetTimes(): Unit

Reset the forward/backward record time for the module or its submodules
final def saveCaffe(prototxtPath: String, modelPath: String, useV2: Boolean = true, overwrite: Boolean = false): AbstractModule.this.type

Save this module to path in caffe readable format
final def saveDefinition(path: String, overWrite: Boolean = false): AbstractModule.this.type

Save this module definition to path.
Save this module definition to path.
path
path to save module, local file system, HDFS and Amazon S3 is supported. HDFS path should be like "hdfs://[host]:[port]/xxx" Amazon S3 path should be like "s3a://bucket/xxx"
overWrite
if overwrite
returns
self
final def saveModule(path: String, weightPath: String = null, overWrite: Boolean = false): AbstractModule.this.type

Save this module to path with protobuf format
Save this module to path with protobuf format
path
path to save module, local file system, HDFS and Amazon S3 is supported. HDFS path should be like "hdfs://[host]:[port]/xxx" Amazon S3 path should be like "s3a://bucket/xxx"
weightPath
where to store weight
overWrite
if overwrite
returns
self
final def saveTF(inputs: Seq[(String, Seq[Int])], path: String, byteOrder: ByteOrder = ByteOrder.LITTLE_ENDIAN, dataFormat: TensorflowDataFormat = TensorflowDataFormat.NHWC): AbstractModule.this.type

Save this module to path in tensorflow readable format
final def saveTorch(path: String, overWrite: Boolean = false): AbstractModule.this.type

Save this module to path in torch7 readable format
final def saveWeights(path: String, overWrite: Boolean): Unit

save weights and bias to file
save weights and bias to file
path
file to save
overWrite
whether to overwrite or not
var scaleB: Double

Attributes
protected
var scaleW: Double

The scale of gradient weight and gradient bias before gradParameters being accumulated.
The scale of gradient weight and gradient bias before gradParameters being accumulated.

Attributes
protected
def setExtraParameter(extraParam: Array[Tensor[T]]): AbstractModule.this.type

Set extra parameter to this module.
Set extra parameter to this module. Extra parameter means the trainable parameters beside weight and bias. Such as runningMean and runningVar in BatchNormalization.
returns
this
def setInputFormats(formats: Seq[Int]): AbstractModule.this.type

set input formats for graph
final def setLine(line: String): AbstractModule.this.type

Set the line separator when print the module
final def setName(name: String): AbstractModule.this.type

Set the module name
def setOutputFormats(formats: Seq[Int]): AbstractModule.this.type

set output formats for graph
def setScaleB(b: Double): AbstractModule.this.type

Set the scale of gradientBias
Set the scale of gradientBias
b
the value of the scale of gradientBias
returns
this
def setScaleW(w: Double): AbstractModule.this.type

Set the scale of gradientWeight
Set the scale of gradientWeight
w
the value of the scale of gradientWeight
returns
this
final def setWeightsBias(newWeights: Array[Tensor[T]]): AbstractModule.this.type

Set weight and bias for the module
Set weight and bias for the module
newWeights
array of weights and bias
final def synchronized[T0](arg0: ⇒ T0): T0

Definition Classes
AnyRef
def toGraph(startNodes: ModuleNode[T]*): Graph[T]

Generate graph module with start nodes
def toString(): String

Definition Classes
AbstractModule → AnyRef → Any
var train: Boolean

Module status.
Module status. It is useful for modules like dropout/batch normalization

Attributes
protected
def training(): AbstractModule.this.type

Set the module to training mode
def unFreeze(names: String*): AbstractModule.this.type

"unfreeze" module, i.e.
"unfreeze" module, i.e. make the module parameters(weight/bias, if exists) to be trained(updated) in training process if names is not empty, unfreeze layers that match given names
names
array of module names to unFreeze
final def wait(): Unit

Definition Classes
AnyRef
Annotations
@throws( ... )
final def wait(arg0: Long, arg1: Int): Unit

Definition Classes
AnyRef
Annotations
@throws( ... )
final def wait(arg0: Long): Unit

Definition Classes
AnyRef
Annotations
@throws( ... )
def zeroGradParameters(): Unit

If the module has parameters, this will zero the accumulation of the gradients with respect to these parameters.
If the module has parameters, this will zero the accumulation of the gradients with respect to these parameters. Otherwise, it does nothing.

Deprecated Value Members

def save(path: String, overWrite: Boolean = false): AbstractModule.this.type

Save this module to path.
Save this module to path.
path
path to save module, local file system, HDFS and Amazon S3 is supported. HDFS path should be like "hdfs://[host]:[port]/xxx" Amazon S3 path should be like "s3a://bucket/xxx"
overWrite
if overwrite
returns
self

Annotations
@deprecated
Deprecated
(Since version 0.3.0) please use recommended saveModule(path, overWrite)

Related Doc: package abstractnn

abstract class AbstractModule[A <: Activity, B <: Activity, T] extends Serializable with InferShape

Instance Constructors

new AbstractModule()(implicit arg0: ClassTag[A], arg1: ClassTag[B], arg2: ClassTag[T], ev: TensorNumeric[T])

Abstract Value Members

abstract def updateGradInput(input: A, gradOutput: B): A

abstract def updateOutput(input: A): B

Concrete Value Members

final def !=(arg0: Any): Boolean

final def ##(): Int

final def ==(arg0: Any): Boolean

def accGradParameters(input: A, gradOutput: B): Unit

def apply(name: String): Option[AbstractModule[Activity, Activity, T]]

final def asInstanceOf[T0]: T0

def backward(input: A, gradOutput: B): A

var backwardTime: Long

def clearState(): AbstractModule.this.type

final def clone(deepCopy: Boolean): AbstractModule[A, B, T]

def clone(): AnyRef

final def cloneModule(): AbstractModule.this.type

final def eq(arg0: AnyRef): Boolean

def equals(other: Any): Boolean

final def evaluate(dataSet: LocalDataSet[MiniBatch[T]], vMethods: Array[_ <: ValidationMethod[T]]): Array[(ValidationResult, ValidationMethod[T])]

final def evaluate(dataset: RDD[MiniBatch[T]], vMethods: Array[_ <: ValidationMethod[T]]): Array[(ValidationResult, ValidationMethod[T])]

final def evaluate(dataset: RDD[Sample[T]], vMethods: Array[_ <: ValidationMethod[T]], batchSize: Option[Int] = None): Array[(ValidationResult, ValidationMethod[T])]

def evaluate(): AbstractModule.this.type

final def evaluateImage(imageFrame: ImageFrame, vMethods: Array[_ <: ValidationMethod[T]], batchSize: Option[Int] = None): Array[(ValidationResult, ValidationMethod[T])]

def finalize(): Unit

final def forward(input: A): B

var forwardTime: Long

def freeze(names: String*): AbstractModule.this.type

final def getClass(): Class[_]

def getExtraParameter(): Array[Tensor[T]]

final def getInputShape(): Shape

final def getName(): String

final def getNumericType(): TensorDataType

final def getOutputShape(): Shape

def getParametersTable(): Table

final def getPrintName(): String

final def getScaleB(): Double

final def getScaleW(): Double

def getTimes(): Array[(AbstractModule[_ <: Activity, _ <: Activity, T], Long, Long)]

final def getTimesGroupByModuleType(): Array[(String, Long, Long)]

final def getWeightsBias(): Array[Tensor[T]]

var gradInput: A

final def hasName: Boolean

def hashCode(): Int

def inputs(first: (ModuleNode[T], Int), nodesWithIndex: (ModuleNode[T], Int)*): ModuleNode[T]

def inputs(nodes: Array[ModuleNode[T]]): ModuleNode[T]

def inputs(nodes: ModuleNode[T]*): ModuleNode[T]

var inputsFormats: Seq[Int]

final def isInstanceOf[T0]: Boolean

final def isTraining(): Boolean

var line: String

final def loadModelWeights(srcModel: Module[Float], matchAll: Boolean = true): AbstractModule.this.type

final def loadWeights(weightPath: String, matchAll: Boolean = true): AbstractModule.this.type

final def ne(arg0: AnyRef): Boolean

final def notify(): Unit

final def notifyAll(): Unit

var output: B

var outputsFormats: Seq[Int]

def parameters(): (Array[Tensor[T]], Array[Tensor[T]])

final def predict(dataset: RDD[Sample[T]], batchSize: Int = 1, shareBuffer: Boolean = false): RDD[Activity]

final def predictClass(dataset: RDD[Sample[T]], batchSize: Int = 1): RDD[Int]

final def predictImage(imageFrame: ImageFrame, outputLayer: String = null, shareBuffer: Boolean = false, batchPerPartition: Int = 4, predictKey: String = ImageFeature.predict, featurePaddingParam: Option[PaddingParam[T]] = None): ImageFrame

def processInputs(first: (ModuleNode[T], Int), nodesWithIndex: (ModuleNode[T], Int)*): ModuleNode[T]

def processInputs(nodes: Seq[ModuleNode[T]]): ModuleNode[T]

final def quantize(): Module[T]

def release(): Unit

def reset(): Unit

def resetTimes(): Unit

final def saveCaffe(prototxtPath: String, modelPath: String, useV2: Boolean = true, overwrite: Boolean = false): AbstractModule.this.type

final def saveDefinition(path: String, overWrite: Boolean = false): AbstractModule.this.type

final def saveModule(path: String, weightPath: String = null, overWrite: Boolean = false): AbstractModule.this.type

final def saveTF(inputs: Seq[(String, Seq[Int])], path: String, byteOrder: ByteOrder = ByteOrder.LITTLE_ENDIAN, dataFormat: TensorflowDataFormat = TensorflowDataFormat.NHWC): AbstractModule.this.type

final def saveTorch(path: String, overWrite: Boolean = false): AbstractModule.this.type

final def saveWeights(path: String, overWrite: Boolean): Unit

var scaleB: Double

var scaleW: Double