/**
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* @license
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* Copyright 2017 Google Inc. All Rights Reserved.
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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* =============================================================================
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*/
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import { Conv2DInfo, Conv3DInfo } from '../../ops/conv_util';
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import { FusedBatchMatMulConfig, FusedConv2DConfig } from '../../ops/fused_util';
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import { DataId, Scalar, Tensor, Tensor1D, Tensor2D, Tensor3D, Tensor4D, Tensor5D } from '../../tensor';
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import { BackendValues, DataType, Rank, ShapeMap } from '../../types';
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import { BackendTimingInfo, DataStorage, KernelBackend } from '../backend';
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export interface TensorData<D extends DataType> {
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values?: BackendValues;
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dtype: D;
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complexTensors?: {
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real: Tensor;
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imag: Tensor;
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};
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}
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export declare class MathBackendCPU extends KernelBackend {
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blockSize: number;
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data: DataStorage<TensorData<DataType>>;
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private firstUse;
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constructor();
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write(values: BackendValues, shape: number[], dtype: DataType): DataId;
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move(dataId: DataId, values: BackendValues, shape: number[], dtype: DataType): void;
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numDataIds(): number;
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read(dataId: DataId): Promise<BackendValues>;
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readSync(dataId: DataId): BackendValues;
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private bufferSync;
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private makeOutput;
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disposeData(dataId: DataId): void;
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time(f: () => void): Promise<BackendTimingInfo>;
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memory(): {
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unreliable: boolean;
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reasons: string[];
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};
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complex<T extends Tensor>(real: T, imag: T): T;
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real<T extends Tensor>(input: T): T;
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imag<T extends Tensor>(input: T): T;
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slice<T extends Tensor>(x: T, begin: number[], size: number[]): T;
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stridedSlice<T extends Tensor>(x: T, begin: number[], end: number[], strides: number[]): T;
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diag(x: Tensor): Tensor;
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unstack(x: Tensor, axis: number): Tensor[];
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reverse<T extends Tensor>(x: T, axis: number[]): T;
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concat(tensors: Tensor[], axis: number): Tensor;
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neg<T extends Tensor>(x: T): T;
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add(a: Tensor, b: Tensor): Tensor;
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addN<T extends Tensor>(tensors: T[]): T;
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softmax<T extends Tensor>(logits: T, dim: number): T;
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subtract(a: Tensor, b: Tensor): Tensor;
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pow<T extends Tensor>(a: T, b: Tensor): T;
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batchMatMul(a: Tensor3D, b: Tensor3D, transposeA: boolean, transposeB: boolean): Tensor3D;
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fusedBatchMatMul({ a, b, transposeA, transposeB, bias, activation, preluActivationWeights }: FusedBatchMatMulConfig): Tensor3D;
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multiply(a: Tensor, b: Tensor): Tensor;
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realDivide(a: Tensor, b: Tensor): Tensor;
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floorDiv(a: Tensor, b: Tensor): Tensor;
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sum(x: Tensor, axes: number[]): Tensor;
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prod(x: Tensor, axes: number[]): Tensor;
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unsortedSegmentSum<T extends Tensor>(x: T, segmentIds: Tensor1D, numSegments: number): Tensor;
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argMin(x: Tensor, axis: number): Tensor;
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argMax(x: Tensor, axis: number): Tensor;
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cumsum(x: Tensor, axis: number, exclusive: boolean, reverse: boolean): Tensor;
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equal(a: Tensor, b: Tensor): Tensor;
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notEqual(a: Tensor, b: Tensor): Tensor;
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less(a: Tensor, b: Tensor): Tensor;
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lessEqual(a: Tensor, b: Tensor): Tensor;
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greater(a: Tensor, b: Tensor): Tensor;
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greaterEqual(a: Tensor, b: Tensor): Tensor;
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logicalNot<T extends Tensor>(x: T): T;
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logicalAnd(a: Tensor, b: Tensor): Tensor;
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logicalOr(a: Tensor, b: Tensor): Tensor;
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select(condition: Tensor, a: Tensor, b: Tensor): Tensor;
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where(condition: Tensor): Tensor2D;
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topk<T extends Tensor>(x: T, k: number, sorted: boolean): [T, T];
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min(x: Tensor, axes: number[]): Tensor;
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minimum(a: Tensor, b: Tensor): Tensor;
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mod(a: Tensor, b: Tensor): Tensor;
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max(x: Tensor, axes: number[]): Tensor;
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maximum(a: Tensor, b: Tensor): Tensor;
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all(x: Tensor, axes: number[]): Tensor;
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any(x: Tensor, axes: number[]): Tensor;
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squaredDifference(a: Tensor, b: Tensor): Tensor;
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ceil<T extends Tensor>(x: T): T;
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floor<T extends Tensor>(x: T): T;
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sign<T extends Tensor>(x: T): T;
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isNaN<T extends Tensor>(x: T): T;
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isInf<T extends Tensor>(x: T): T;
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isFinite<T extends Tensor>(x: T): T;
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round<T extends Tensor>(x: T): T;
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exp<T extends Tensor>(x: T): T;
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expm1<T extends Tensor>(x: T): T;
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log<T extends Tensor>(x: T): T;
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log1p<T extends Tensor>(x: T): T;
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sqrt<T extends Tensor>(x: T): T;
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rsqrt<T extends Tensor>(x: T): T;
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reciprocal<T extends Tensor>(x: T): T;
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linear<T extends Tensor>(x: T): T;
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relu<T extends Tensor>(x: T): T;
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relu6<T extends Tensor>(x: T): T;
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prelu<T extends Tensor>(x: T, a: T): T;
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elu<T extends Tensor>(x: T): T;
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eluDer<T extends Tensor>(dy: T, y: T): T;
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selu<T extends Tensor>(x: T): T;
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clip<T extends Tensor>(x: T, min: number, max: number): T;
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abs<T extends Tensor>(x: T): T;
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complexAbs<T extends Tensor>(x: T): T;
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int<T extends Tensor>(x: T): T;
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sigmoid<T extends Tensor>(x: T): T;
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softplus<T extends Tensor>(x: T): T;
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sin<T extends Tensor>(x: T): T;
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cos<T extends Tensor>(x: T): T;
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tan<T extends Tensor>(x: T): T;
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asin<T extends Tensor>(x: T): T;
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acos<T extends Tensor>(x: T): T;
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atan<T extends Tensor>(x: T): T;
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atan2<T extends Tensor>(a: T, b: T): T;
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sinh<T extends Tensor>(x: T): T;
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cosh<T extends Tensor>(x: T): T;
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tanh<T extends Tensor>(x: T): T;
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asinh<T extends Tensor>(x: T): T;
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acosh<T extends Tensor>(x: T): T;
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atanh<T extends Tensor>(x: T): T;
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erf<T extends Tensor>(x: T): T;
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step<T extends Tensor>(x: T, alpha?: number): T;
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fusedConv2d({ input, filter, convInfo, bias, activation, preluActivationWeights }: FusedConv2DConfig): Tensor4D;
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conv2d(x: Tensor4D, filter: Tensor4D, convInfo: Conv2DInfo): Tensor4D;
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conv3d(x: Tensor5D, filter: Tensor5D, convInfo: Conv3DInfo): Tensor5D;
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conv2dDerInput(dy: Tensor4D, filter: Tensor4D, convInfo: Conv2DInfo): Tensor4D;
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conv3dDerInput(dy: Tensor5D, filter: Tensor5D, convInfo: Conv3DInfo): Tensor5D;
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conv2dDerFilter(x: Tensor4D, dy: Tensor4D, convInfo: Conv2DInfo): Tensor4D;
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conv3dDerFilter(x: Tensor5D, dy: Tensor5D, convInfo: Conv3DInfo): Tensor5D;
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fusedDepthwiseConv2D({ input, filter, convInfo, bias, activation, preluActivationWeights }: FusedConv2DConfig): Tensor4D;
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depthwiseConv2D(x: Tensor4D, filter: Tensor4D, convInfo: Conv2DInfo): Tensor4D;
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depthwiseConv2DDerInput(dy: Tensor4D, filter: Tensor4D, convInfo: Conv2DInfo): Tensor4D;
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depthwiseConv2DDerFilter(x: Tensor4D, dy: Tensor4D, convInfo: Conv2DInfo): Tensor4D;
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tile<T extends Tensor>(x: T, reps: number[]): T;
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pad<T extends Tensor>(x: T, paddings: Array<[number, number]>, constantValue: number): T;
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transpose<T extends Tensor>(x: T, perm: number[]): T;
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gather<T extends Tensor>(x: T, indices: Tensor1D, axis: number): T;
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batchToSpaceND<T extends Tensor>(x: T, blockShape: number[], crops: number[][]): T;
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spaceToBatchND<T extends Tensor>(x: T, blockShape: number[], paddings: Array<[number, number]>): T;
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private pool;
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maxPool(x: Tensor4D, convInfo: Conv2DInfo): Tensor4D;
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private maxPoolPositions;
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maxPoolBackprop(dy: Tensor4D, x: Tensor4D, y: Tensor4D, convInfo: Conv2DInfo): Tensor4D;
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avgPoolBackprop(dy: Tensor4D, x: Tensor4D, convInfo: Conv2DInfo): Tensor4D;
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private pool3d;
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avgPool3d(x: Tensor5D, convInfo: Conv3DInfo): Tensor5D;
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avgPool3dBackprop(dy: Tensor5D, x: Tensor5D, convInfo: Conv3DInfo): Tensor5D;
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maxPool3d(x: Tensor5D, convInfo: Conv3DInfo): Tensor5D;
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private maxPool3dPositions;
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maxPool3dBackprop(dy: Tensor5D, x: Tensor5D, y: Tensor5D, convInfo: Conv3DInfo): Tensor5D;
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cast<T extends Tensor>(x: T, dtype: DataType): T;
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reshape<R extends Rank>(x: Tensor, shape: ShapeMap[R]): Tensor<R>;
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avgPool(x: Tensor4D, convInfo: Conv2DInfo): Tensor4D;
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resizeBilinear(x: Tensor4D, newHeight: number, newWidth: number, alignCorners: boolean): Tensor4D;
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resizeBilinearBackprop(dy: Tensor4D, x: Tensor4D, alignCorners: boolean): Tensor<Rank.R4>;
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resizeNearestNeighbor(x: Tensor4D, newHeight: number, newWidth: number, alignCorners: boolean): Tensor4D;
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resizeNearestNeighborBackprop(dy: Tensor4D, x: Tensor4D, alignCorners: boolean): Tensor<Rank.R4>;
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batchNormalization(x: Tensor4D, mean: Tensor4D | Tensor1D, variance: Tensor4D | Tensor1D, varianceEpsilon: number, scale?: Tensor4D | Tensor1D, offset?: Tensor4D | Tensor1D): Tensor4D;
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localResponseNormalization4D(x: Tensor4D, depthRadius: number, bias: number, alpha: number, beta: number): Tensor4D;
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LRNGrad(dy: Tensor4D, inputImage: Tensor4D, outputImage: Tensor4D, depthRadius: number, bias: number, alpha: number, beta: number): Tensor4D;
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multinomial(logits: Tensor2D, normalized: boolean, numSamples: number, seed: number): Tensor2D;
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oneHot(indices: Tensor1D, depth: number, onValue: number, offValue: number): Tensor2D;
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nonMaxSuppression(boxes: Tensor2D, scores: Tensor1D, maxOutputSize: number, iouThreshold: number, scoreThreshold: number): Tensor1D;
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fft(x: Tensor2D): Tensor2D;
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ifft(x: Tensor2D): Tensor2D;
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/**
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* Calculate FFT of inner most elements of batch tensor.
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*/
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private fftBatch;
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private fftImpl;
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private isExponentOf2;
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private fftRadix2;
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private fourierTransformByMatmul;
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depthToSpace(x: Tensor4D, blockSize: number, dataFormat: 'NHWC' | 'NCHW'): Tensor4D;
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private broadcastedBinaryOp;
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private broadcastedBinaryComplexOp;
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split<T extends Tensor>(x: T, sizeSplits: number[], axis: number): T[];
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dispose(): void;
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floatPrecision(): 16 | 32;
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/** Returns the smallest representable number. */
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epsilon(): number;
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cropAndResize(images: Tensor4D, boxes: Tensor2D, boxIndex: Tensor1D, cropSize: [number, number], method: string, extrapolationValue: number): Tensor<Rank.R4>;
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sparseToDense<R extends Rank>(sparseIndices: Tensor, sparseValues: Tensor, outputShape: ShapeMap[R], defaultValue: Scalar): Tensor<R>;
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gatherND(x: Tensor, indices: Tensor): Tensor;
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scatterND<R extends Rank>(indices: Tensor, updates: Tensor, shape: ShapeMap[R]): Tensor<R>;
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fill<R extends Rank>(shape: ShapeMap[R], value: number | string, dtype?: DataType): Tensor<R>;
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onesLike<R extends Rank>(x: Tensor<R>): Tensor<R>;
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zerosLike<R extends Rank>(x: Tensor<R>): Tensor<R>;
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linspace(start: number, stop: number, num: number): Tensor1D;
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private scatter;
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}
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