forked from kscience/kmath
Reformat code and change some name
This commit is contained in:
Mikhail Zelenyy
parent
f0e380304e
commit
1b411872ef
@ -1,11 +1,10 @@
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package scientifik.kmath.structures
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import scientifik.kmath.operations.RealField
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import scientifik.kmath.operations.RealField.power
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import kotlin.math.*
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object RealFactories{
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object RealFactory {
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/**
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* Create a NDArray filled with ones
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*/
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@ -16,7 +15,8 @@ object RealFactories{
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*
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* @param offset Index of the diagonal: 0 (the default) refers to the main diagonal, a positive value refers to an upper diagonal, and a negative value to a lower diagonal.
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*/
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fun eye(dim1: Int, dim2: Int, offset : Int = 0) = NDElement.real2D(dim1, dim2){i, j -> if (i == j + offset) 1.0 else 0.0}
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fun eye(dim1: Int, dim2: Int, offset: Int = 0) =
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NDElement.real2D(dim1, dim2) { i, j -> if (i == j + offset) 1.0 else 0.0 }
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/**
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* An array with ones at and below the given diagonal and zeros elsewhere.
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@ -24,7 +24,8 @@ object RealFactories{
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*
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* @param offset Index of the diagonal: 0 (the default) refers to the main diagonal, a positive value refers to an upper diagonal, and a negative value to a lower diagonal.
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*/
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fun triangle(dim1: Int, dim2: Int, offset : Int = 0) = NDElement.real2D(dim1, dim2){i, j -> if (i <= j + offset) 1.0 else 0.0}
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fun triangle(dim1: Int, dim2: Int, offset: Int = 0) =
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NDElement.real2D(dim1, dim2) { i, j -> if (i <= j + offset) 1.0 else 0.0 }
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/**
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* Return evenly spaced values within a given interval.
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@ -33,7 +34,8 @@ object RealFactories{
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* @param range use it like:
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* (start..stop) to step
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*/
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fun range(range : Pair<ClosedFloatingPointRange<Double>,Double>) = NDElement.real1D(ceil((range.first.endInclusive - range.first.start)/range.second).toInt()){i-> range.first.start + i*range.second}
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fun range(range: Pair<ClosedFloatingPointRange<Double>, Double>) =
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NDElement.real1D(ceil((range.first.endInclusive - range.first.start) / range.second).toInt()) { i -> range.first.start + i * range.second }
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/**
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* Return evenly spaced numbers over a specified interval.
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@ -42,19 +44,25 @@ object RealFactories{
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* start is starting value, finaly value depend from endPoint parameter
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* @param endPoint If True, right boundary of range is the last sample. Otherwise, it is not included.
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*/
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fun linspace(range : Pair<ClosedFloatingPointRange<Double>,Int>, endPoint: Boolean = true): Pair<RealNDElement, Double> {
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fun linSpace(
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range: Pair<ClosedFloatingPointRange<Double>, Int>,
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endPoint: Boolean = true
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): Pair<RealNDElement, Double> {
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val div = if (endPoint) (range.second - 1) else range.second
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val delta = range.first.start - range.first.endInclusive
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if (range.second > 1) {
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val step = delta / div
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if (step == 0.0){ error("Bad ranges: step = $step")}
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if (step == 0.0) {
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error("Bad ranges: step = $step")
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}
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val result = NDElement.real1D(range.second) {
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if ( endPoint and (it == range.second - 1) ){ range.first.endInclusive}
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if (endPoint and (it == range.second - 1)) {
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range.first.endInclusive
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}
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range.first.start + it * step
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}
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return result to step
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}
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else{
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} else {
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val step = Double.NaN
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return NDElement.real1D(1) { range.first.start } to step
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}
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@ -69,21 +77,26 @@ object RealFactories{
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* @param endPoint If True, power(base,stop) is the last sample. Otherwise, it is not included.
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* @param base - The base of the log space.
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*/
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fun logspace(range : Pair<ClosedFloatingPointRange<Double>,Int>, endPoint: Boolean = true, base : Double = 10.0) : RealNDElement {
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val lin = linspace(range, endPoint).first
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val fun_ = {x: Double -> power(base, x)}
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return fun_(lin) // FIXME: RealNDElement.map return not suitable type ( `linspace(range, endPoint).first.map{power(base, it}`)
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fun logSpace(
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range: Pair<ClosedFloatingPointRange<Double>, Int>,
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endPoint: Boolean = true,
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base: Double = 10.0
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): RealNDElement {
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val lin = linSpace(range, endPoint).first
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val tempFun = { x: Double -> power(base, x) }
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return tempFun(lin) // FIXME: RealNDElement.map return not suitable type ( `linSpace(range, endPoint).first.map{power(base, it}`)
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}
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/**
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* Return numbers spaced evenly on a log scale (a geometric progression).
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*
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* This is similar to [logspace], but with endpoints specified directly. Each output sample is a constant multiple of the previous.
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* This is similar to [logSpace], but with endpoints specified directly. Each output sample is a constant multiple of the previous.
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* @param range use it like:
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* (start..stop) to number
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* start is starting value, finaly value depend from endPoint parameter
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* @param endPoint If True, right boundary of range is the last sample. Otherwise, it is not included.
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*/
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fun geomspace(range : Pair<ClosedFloatingPointRange<Double>,Int>, endPoint: Boolean = true) : RealNDElement{
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fun geomSpace(range: Pair<ClosedFloatingPointRange<Double>, Int>, endPoint: Boolean = true): RealNDElement {
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var start = range.first.start
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var stop = range.first.endInclusive
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val num = range.second
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@ -97,9 +110,9 @@ object RealFactories{
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outSign = -outSign
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}
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val log_ = logspace((log(start, 10.0)..log(stop, 10.0) to num), endPoint=endPoint)
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val fun_ = {x:Double -> outSign*x}
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return fun_(log_) // FIXME: `outSign*log_` --- don't define times operator
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val logRange = logSpace((log(start, 10.0)..log(stop, 10.0) to num), endPoint = endPoint)
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val function = { x: Double -> outSign * x }
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return function(logRange) // FIXME: `outSign*log_` --- don't define times operator
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}
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@ -110,12 +123,12 @@ object RealFactories{
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*/
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fun extractDiagonal(array: RealNDElement, offset: Int = 0): RealNDElement {
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if (array.dimension != 2) {
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error("Input must be 2D NDArray")}
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error("Input must be 2D NDArray")
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}
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val size = min(array.shape[0], array.shape[0])
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if (offset >= 0) {
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return NDElement.real1D(size) { i -> array[i, i + offset] }
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}
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else{
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} else {
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return NDElement.real1D(size) { i -> array[i - offset, i] }
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}
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@ -128,16 +141,16 @@ object RealFactories{
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*/
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fun fromDiagonal(array: RealNDElement, offset: Int = 0): RealNDElement {
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if (array.dimension != 1) {
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error("Input must be 1D NDArray")}
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error("Input must be 1D NDArray")
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}
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val size = array.shape[0]
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if (offset >= 0) {
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return NDElement.real2D(size, size+offset){
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i, j -> if (i == j+offset) array[i] else 0.0
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return NDElement.real2D(size, size + offset) { i, j ->
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if (i == j + offset) array[i] else 0.0
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}
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}
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else{
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return NDElement.real2D(size-offset, size){
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i, j -> if (i-offset == j) array[j] else 0.0
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} else {
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return NDElement.real2D(size - offset, size) { i, j ->
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if (i - offset == j) array[j] else 0.0
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}
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}
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}
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@ -150,15 +163,16 @@ object RealFactories{
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*/
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fun vandermonde(array: RealNDElement, nCols: Int = 0, increasing: Boolean = false): RealNDElement {
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if (array.dimension != 1) {
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error("Input must be 1D NDArray")}
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var size = if (nCols ==0) array.shape[0] else nCols
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error("Input must be 1D NDArray")
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}
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val size = if (nCols == 0) array.shape[0] else nCols
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if (increasing) {
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return NDElement.real2D(array.shape[0], size){
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i, j -> power(array[i], j)
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return NDElement.real2D(array.shape[0], size) { i, j ->
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power(array[i], j)
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}
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} else {
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return NDElement.real2D(array.shape[0], size){
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i, j -> power(array[i], size - j - 1)
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return NDElement.real2D(array.shape[0], size) { i, j ->
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power(array[i], size - j - 1)
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}
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}
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