v0.3.0-dev-9 #324
@ -85,7 +85,6 @@ public inline fun <R> BroadcastDoubleTensorAlgebra(block: BroadcastDoubleTensorA
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internal inline fun broadcastShapes(vararg shapes: IntArray): IntArray {
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internal inline fun broadcastShapes(vararg shapes: IntArray): IntArray {
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println(shapes)
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var totalDim = 0
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var totalDim = 0
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for (shape in shapes) {
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for (shape in shapes) {
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totalDim = max(totalDim, shape.size)
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totalDim = max(totalDim, shape.size)
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@ -179,5 +178,63 @@ internal inline fun broadcastTensors(vararg tensors: DoubleTensor): List<DoubleT
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res.add(resTensor)
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res.add(resTensor)
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}
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}
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return res
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}
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internal inline fun broadcastOuterTensors(vararg tensors: DoubleTensor): List<DoubleTensor> {
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var onlyTwoDims = true
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for (tensor in tensors) {
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if (tensor.shape.size < 2) {
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throw RuntimeException("Tensors must have at least 2 dimensions")
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}
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if (tensor.shape.size != 2) {
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onlyTwoDims = false
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}
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}
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if (onlyTwoDims) {
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return tensors.asList()
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}
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val totalShape = broadcastShapes(*(tensors.map { it.shape.sliceArray(0..it.shape.size - 3) }).toTypedArray())
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val n = totalShape.reduce { acc, i -> acc * i }
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val res = ArrayList<DoubleTensor>(0)
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for (tensor in tensors) {
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val matrixShape = tensor.shape.sliceArray(tensor.shape.size - 2 until tensor.shape.size).copyOf()
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val matrixSize = matrixShape[0] * matrixShape[1]
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val matrix = DoubleTensor(matrixShape, DoubleArray(matrixSize))
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val outerTensor = DoubleTensor(totalShape, DoubleArray(n))
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val resTensor = DoubleTensor(totalShape + matrixShape, DoubleArray(n * matrixSize))
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for (linearIndex in 0 until n) {
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val totalMultiIndex = outerTensor.linearStructure.index(linearIndex)
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var curMultiIndex = tensor.shape.sliceArray(0..tensor.shape.size - 3).copyOf()
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curMultiIndex = IntArray(totalMultiIndex.size - curMultiIndex.size) {1} + curMultiIndex
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val newTensor = DoubleTensor(curMultiIndex + matrixShape, tensor.buffer.array())
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for (i in curMultiIndex.indices) {
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if (curMultiIndex[i] != 1) {
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curMultiIndex[i] = totalMultiIndex[i]
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} else {
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curMultiIndex[i] = 0
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}
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}
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for (i in 0 until matrixSize) {
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val curLinearIndex = newTensor.linearStructure.offset(curMultiIndex +
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matrix.linearStructure.index(i))
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val newLinearIndex = resTensor.linearStructure.offset(totalMultiIndex +
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matrix.linearStructure.index(i))
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resTensor.buffer.array()[resTensor.bufferStart + newLinearIndex] =
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newTensor.buffer.array()[newTensor.bufferStart + curLinearIndex]
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}
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}
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res.add(resTensor)
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}
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return res
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return res
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}
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}
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@ -132,7 +132,7 @@ public open class DoubleTensorAlgebra : TensorPartialDivisionAlgebra<Double, Dou
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override fun DoubleTensor.times(other: DoubleTensor): DoubleTensor {
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override fun DoubleTensor.times(other: DoubleTensor): DoubleTensor {
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checkShapesCompatible(this, other)
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checkShapesCompatible(this, other)
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val resBuffer = DoubleArray(this.linearStructure.size) { i ->
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val resBuffer = DoubleArray(this.linearStructure.size) { i ->
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this.buffer.array()[other.bufferStart + i] *
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this.buffer.array()[this.bufferStart + i] *
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other.buffer.array()[other.bufferStart + i]
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other.buffer.array()[other.bufferStart + i]
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}
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}
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return DoubleTensor(this.shape, resBuffer)
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return DoubleTensor(this.shape, resBuffer)
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@ -241,8 +241,84 @@ public open class DoubleTensorAlgebra : TensorPartialDivisionAlgebra<Double, Dou
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TODO("Not yet implemented")
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TODO("Not yet implemented")
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}
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}
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private fun DoubleTensor.dotTwoDimensionalTensors(other: DoubleTensor): DoubleTensor {
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if (this.shape.size > 2 || other.shape.size > 2) {
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throw RuntimeException("Both tensors must have a maximum of 2 dimensions")
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}
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if (this.shape[1] != other.shape[0]) {
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throw RuntimeException("Tensors dot operation dimension mismatch: " +
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"(${this.shape[0]}, ${this.shape[1]}) x (${other.shape[0]}, ${other.shape[1]})")
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}
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val l = this.shape[0]
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val m = this.shape[1]
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val n = other.shape[1]
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val res = DoubleTensor(intArrayOf(l, n), DoubleArray(l * n))
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for (i in 0 until l) {
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for (j in 0 until n) {
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var curr = 0.0
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for (k in 0 until m) {
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val ik = this.linearStructure.offset(intArrayOf(i, k))
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val kj = other.linearStructure.offset(intArrayOf(k, j))
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curr += this.buffer.array()[ik] * other.buffer.array()[kj]
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}
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val linearIndex = res.linearStructure.offset(intArrayOf(i, j))
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res.buffer.array()[linearIndex] = curr
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}
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}
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return res
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}
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override fun DoubleTensor.dot(other: DoubleTensor): DoubleTensor {
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override fun DoubleTensor.dot(other: DoubleTensor): DoubleTensor {
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TODO("Alya")
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if (this.shape.size == 1 && other.shape.size == 1) {
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return DoubleTensor(intArrayOf(1), doubleArrayOf(this.times(other).buffer.array().sum()))
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}
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var newThis = this.copy()
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var newOther = other.copy()
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if (this.shape.size == 1) {
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newThis = this.view(intArrayOf(1) + this.shape)
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}
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if (other.shape.size == 1) {
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newOther = other.view(other.shape + intArrayOf(1) )
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}
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val broadcastTensors = broadcastOuterTensors(newThis, newOther)
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newThis = broadcastTensors[0]
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newOther = broadcastTensors[1]
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val l = newThis.shape[newThis.shape.size - 2]
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val m1= newThis.shape[newThis.shape.size - 1]
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val m2 = newOther.shape[newOther.shape.size - 2]
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val n = newOther.shape[newOther.shape.size - 1]
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if (m1 != m2) {
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throw RuntimeException("Tensors dot operation dimension mismatch: ($l, $m1) x ($m2, $n)")
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}
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val m = m1
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var resShape = newThis.shape.sliceArray(0..(newThis.shape.size - 2)) + intArrayOf(newOther.shape.last())
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val resSize = resShape.reduce { acc, i -> acc * i }
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val resTensor = DoubleTensor(resShape, DoubleArray(resSize))
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for ((res, ab) in resTensor.matrixSequence().zip(newThis.matrixSequence().zip(newOther.matrixSequence()))) {
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val a = ab.first
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val b = ab.second
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for (i in 0 until l) {
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for (j in 0 until n) {
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var curr = 0.0
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for (k in 0 until m) {
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curr += a[i, k] * b[k, j]
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}
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res[i, j] = curr
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}
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}
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}
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return resTensor
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}
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}
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override fun diagonalEmbedding(diagonalEntries: DoubleTensor, offset: Int, dim1: Int, dim2: Int): DoubleTensor {
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override fun diagonalEmbedding(diagonalEntries: DoubleTensor, offset: Int, dim1: Int, dim2: Int): DoubleTensor {
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@ -47,6 +47,36 @@ class TestBroadcasting {
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assertTrue(res[2].buffer.array() contentEquals doubleArrayOf(500.0, 500.0, 500.0, 500.0, 500.0, 500.0))
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assertTrue(res[2].buffer.array() contentEquals doubleArrayOf(500.0, 500.0, 500.0, 500.0, 500.0, 500.0))
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}
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}
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@Test
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fun broadcastOuterTensors() = DoubleTensorAlgebra {
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val tensor1 = fromArray(intArrayOf(2, 3), doubleArrayOf(1.0, 2.0, 3.0, 4.0, 5.0, 6.0))
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val tensor2 = fromArray(intArrayOf(1, 3), doubleArrayOf(10.0, 20.0, 30.0))
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val tensor3 = fromArray(intArrayOf(1, 1, 1), doubleArrayOf(500.0))
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val res = broadcastOuterTensors(tensor1, tensor2, tensor3)
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assertTrue(res[0].shape contentEquals intArrayOf(1, 2, 3))
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assertTrue(res[1].shape contentEquals intArrayOf(1, 1, 3))
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assertTrue(res[2].shape contentEquals intArrayOf(1, 1, 1))
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assertTrue(res[0].buffer.array() contentEquals doubleArrayOf(1.0, 2.0, 3.0, 4.0, 5.0, 6.0))
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assertTrue(res[1].buffer.array() contentEquals doubleArrayOf(10.0, 20.0, 30.0))
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assertTrue(res[2].buffer.array() contentEquals doubleArrayOf(500.0))
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}
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@Test
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fun broadcastOuterTensorsShapes() = DoubleTensorAlgebra {
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val tensor1 = fromArray(intArrayOf(2, 1, 3, 2, 3), DoubleArray(2 * 1 * 3 * 2 * 3) {0.0})
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val tensor2 = fromArray(intArrayOf(4, 2, 5, 1, 3, 3), DoubleArray(4 * 2 * 5 * 1 * 3 * 3) {0.0})
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val tensor3 = fromArray(intArrayOf(1, 1), doubleArrayOf(500.0))
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val res = broadcastOuterTensors(tensor1, tensor2, tensor3)
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assertTrue(res[0].shape contentEquals intArrayOf(4, 2, 5, 3, 2, 3))
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assertTrue(res[1].shape contentEquals intArrayOf(4, 2, 5, 3, 3, 3))
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assertTrue(res[2].shape contentEquals intArrayOf(4, 2, 5, 3, 1, 1))
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}
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@Test
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@Test
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fun minusTensor() = BroadcastDoubleTensorAlgebra {
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fun minusTensor() = BroadcastDoubleTensorAlgebra {
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val tensor1 = fromArray(intArrayOf(2, 3), doubleArrayOf(1.0, 2.0, 3.0, 4.0, 5.0, 6.0))
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val tensor1 = fromArray(intArrayOf(2, 3), doubleArrayOf(1.0, 2.0, 3.0, 4.0, 5.0, 6.0))
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@ -79,6 +79,20 @@ class TestDoubleTensorAlgebra {
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assertTrue(expected.buffer.array() contentEquals assignResult.buffer.array())
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assertTrue(expected.buffer.array() contentEquals assignResult.buffer.array())
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}
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}
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@Test
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fun dot() = DoubleTensorAlgebra {
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val tensor1 = fromArray(intArrayOf(2, 3), doubleArrayOf(1.0, 2.0, 3.0, 4.0, 5.0, 6.0))
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val tensor2 = fromArray(intArrayOf(3), doubleArrayOf(10.0, 20.0, 30.0))
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val res12 = tensor1.dot(tensor2)
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assertTrue(res12.buffer.array() contentEquals doubleArrayOf(140.0, 320.0))
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assertTrue(res12.shape contentEquals intArrayOf(2, 1))
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val tensor4 = fromArray(intArrayOf(10, 3, 4), DoubleArray(10 * 3 * 4) {0.0})
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val tensor5 = fromArray(intArrayOf(10, 4, 5), DoubleArray(10 * 4 * 5) {0.0})
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assertTrue(tensor4.dot(tensor5).shape contentEquals intArrayOf(10, 3, 5))
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}
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@Test
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@Test
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fun testContentEqual() = DoubleTensorAlgebra {
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fun testContentEqual() = DoubleTensorAlgebra {
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//TODO()
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//TODO()
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Block a user