261 lines
9.9 KiB
C++
261 lines
9.9 KiB
C++
/* ******************************************************************************
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*
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*
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* This program and the accompanying materials are made available under the
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* terms of the Apache License, Version 2.0 which is available at
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* https://www.apache.org/licenses/LICENSE-2.0.
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*
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* See the NOTICE file distributed with this work for additional
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* information regarding copyright ownership.
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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, WITHOUT
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* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
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* License for the specific language governing permissions and limitations
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* under the License.
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*
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* SPDX-License-Identifier: Apache-2.0
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******************************************************************************/
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//
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// @author raver119@gmail.com
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//
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#ifndef LIBND4J_HEADERS_NN_H
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#define LIBND4J_HEADERS_NN_H
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#include <ops/declarable/headers/common.h>
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namespace sd {
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namespace ops {
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#if NOT_EXCLUDED(OP_softmax)
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DECLARE_CONFIGURABLE_OP(softmax, 1, 1, true, 0, 0);
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DECLARE_CONFIGURABLE_OP(softmax_bp, 2, 1, true, 0, 0);
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#endif
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/**
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* Local response normalization implementation as TF.
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* input: 4D array
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*
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* T args:
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*
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* 0: bias
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* 1: alpha
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* 2: beta
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*
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* Int arg: depth - optional local radius
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*
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* output - 4D array
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*/
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#if NOT_EXCLUDED(OP_lrn)
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DECLARE_CONFIGURABLE_OP(lrn, 1, 1, true, 3, 0);
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#endif
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/**
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* Local response normalization - backprop variant.
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* input:
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* 0 - 4D array of data
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* 1 - epsilon - 4D array of approximation
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*
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* T args:
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*
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* 0: bias
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* 1: alpha
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* 2: beta
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*
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* Int arg: depth - optional local radius
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*
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* output - next approximation as 4D array
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*/
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#if NOT_EXCLUDED(OP_lrn)
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DECLARE_CONFIGURABLE_OP(lrn_bp, 2, 1, true, 3, 0);
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#endif
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/**
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* Batch normalization implementation.
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* Reference: https://arxiv.org/abs/1502.03167v3
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*
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* Expected arguments:
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* input: input array (any number of dimensions)
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* mean:
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* variance:
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* gamma:
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* beta:
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*
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* Int args:
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* 0: apply scale
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* 1: apply offset
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*
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*
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* T args:
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* 0: epsilon
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*/
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#if NOT_EXCLUDED(OP_batchnorm)
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DECLARE_CUSTOM_OP(batchnorm, 3, 1, false, 1, 2);
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#endif
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/**
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* back prop in batch normalization
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*
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* Expected arguments:
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* input: input array (any number of dimensions)
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* mean:
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* variance:
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* gamma: optional
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* beta: optional
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* dLdOut: next epsilon
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*
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* Int args:
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* 0: apply scale
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* 1: apply offset
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*
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* T args:
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* 0: epsilon
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*
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* output arrays:
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* dL/dInput
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* dL/dMean
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* dL/dVariance
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* dL/dGamma, optional
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* dL/dBeta, optional
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*/
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#if NOT_EXCLUDED(OP_batchnorm)
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DECLARE_CUSTOM_OP(batchnorm_bp, 4, 3, false, 1, 2);
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#endif
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/**
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* This operation updates parameters with provided gradients, wrt learning rate
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* Expected arguments:
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* x: parameters, any shape
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* y: gradients. same shape as x
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* lr: optional, learning rate
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*
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* T args:
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* 0: optional, learning rate
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*/
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#if NOT_EXCLUDED(OP_apply_sgd)
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DECLARE_CONFIGURABLE_OP(apply_sgd, 2, 1, true, -2, 0);
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#endif
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/**
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* This operation performs batch normalization of layer, it is based on following article https://arxiv.org/abs/1502.03167.
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* Expected arguments:
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* x: input 4D array of shape [bS,iH,iW,iD] (data format = NHWC) or [bS,iD,iH,iW] (data format = NCHW), where
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* bS - batch size
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* iH - input height
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* iW - input width
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* iD - input depth (or number of channels)
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* scale: 1D input array of scale factors, shape [iD]
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* offset: 1D input array of offsets (shifts), shape [iD]
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* mean: 1D input array of population mean used for inference, shape [iD], this array is required only if isTraining = false
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* variance: 1D input array of population mean used for inference, shape [iD], this array is required only if isTraining = false
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*
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* T input arguments:
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* 0: epsilon, it is optional argument, default value is 0.001, this is small number to be added to the variance of x
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*
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* integer input arguments:
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* 0: dataFormat, may have two values: zero -> NHWC, unity -> NCHW
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* 1: isTraining, may have two values: zero -> inference, unity -> training
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*/
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#if NOT_EXCLUDED(OP_fused_batch_norm)
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DECLARE_CUSTOM_OP(fused_batch_norm, 3, 1, false, 0, 2);
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#endif
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#if NOT_EXCLUDED(OP_log_softmax)
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DECLARE_CONFIGURABLE_OP(log_softmax, 1, 1, true, 0, 0);
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DECLARE_CONFIGURABLE_OP(log_softmax_bp, 2, 1, true, 0, 0);
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#endif
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/**
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* relu_layer = relu(x*w + b)
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*/
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DECLARE_CUSTOM_OP(relu_layer, 3, 1, false, 0, 0);
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/**
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* applies layer normalization to input
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* y = g * standardize(x) + b
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*
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* see sd::ops::standardize
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*
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*/
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#if NOT_EXCLUDED(OP_layer_norm)
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DECLARE_CONFIGURABLE_OP(layer_norm, 3, 1, true, 0, -2);
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DECLARE_CUSTOM_OP(layer_norm_bp, 4, 1, false, 0, -2);
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#endif
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/**
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* This operation performs dot product attention on the given timeseries input with the given queries
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* out = sum(similarity(k_i, q) * v_i)
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*
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* similarity(k, q) = softmax(k * q) where x * q is the dot product of x and q
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*
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* Optionally with normalization step:
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* similarity(k, q) = softmax(k * q / sqrt(size(q))
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*
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* See also "Attention is all you need" (https://arxiv.org/abs/1706.03762, p. 4, eq. 1)
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*
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* Note: This supports multiple queries at once, if only one query is available the queries vector still has to
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* be 3D but can have queryCount = 1
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*
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* Note: keys and values usually is the same array. If you want to use it as the same array, simply pass it for
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* both.
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*
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* Expected arguments:
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* q: input 3D array "queries" of shape [batchSize, featureKeys, queryCount] or 4D array of shape [batchSize, numHeads, featureKeys, queryCount]
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* k: input 3D array "keys" of shape [batchSize, featureKeys, timesteps] or 4D array of shape [batchSize, numHeads, featureKeys, timesteps]
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* v: input 3D array "values" of shape [batchSize, featureValues, timesteps] or 4D array of shape [batchSize, numHeads, featureValues, timesteps]
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* mask: OPTIONAL; array that defines which values should be skipped of shape [batchSize, timesteps]
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*
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* integer input arguments:
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* 0: normalization, may have two values: zero -> do not apply normalization, one -> apply normalization
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* 1: withWeights, may have two values: zero -> do not return weights, one -> return weights
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*
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* Output Arrays:
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* 0: Attention result arrays of shape [batchSize, featureValues, queryCount] or [batchSize, numHeads, featureValues, queryCount]
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* 1: OPTIONAL; Attention weights of shape [batchSize, timesteps, queryCount] or [batchSize, numHeads, timesteps, queryCount]
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*/
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#if NOT_EXCLUDED(OP_dot_product_attention)
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DECLARE_CUSTOM_OP(dot_product_attention, 3, -1, false, 0, 2);
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DECLARE_CUSTOM_OP(dot_product_attention_bp, 4, 3, false, 0, 1);
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#endif
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/**
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* This performs multi-headed dot product attention on the given timeseries input
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* out = concat(head_1, head_2, ..., head_n) * Wo
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* head_i = dot_product_attention(Wq_i*q, Wk_i*k, Wv_i*v)
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*
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* Optionally with normalization when calculating the attention for each head.
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*
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* See also "Attention is all you need" (https://arxiv.org/abs/1706.03762, pp. 4,5, "3.2.2 Multi-Head Attention")
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*
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* This makes use of dot_product_attention OP support for rank 4 inputs.
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*
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* Expected arguments:
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* q: input 3D array "queries" of shape [batchSize, featureKeys, queryCount]
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* k: input 3D array "keys" of shape [batchSize, featureKeys, timesteps]
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* v: input 3D array "values" of shape [batchSize, featureValues, timesteps]
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* Wq: input query projection weights of shape [numHeads, projectedKeys, featureKeys]
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* Wk: input key projection weights of shape [numHeads, projectedKeys, featureKeys]
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* Wv: input value projection weights of shape [numHeads, projectedValues, featureValues]
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* Wo: output projection weights of shape [numHeads * projectedValues, outSize]
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* mask: OPTIONAL; array that defines which values should be skipped of shape [batchSize, timesteps]
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*
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* integer input arguments:
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* 0: normalization, may have two values: zero -> do not apply normalization, one -> apply normalization
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* 1: withWeights, may have two values: zero -> do not return weights, one -> return weights
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*
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* Output Arrays:
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* 0: Attention result arrays of shape [batchSize, outSize, queryCount]
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* 1: OPTIONAL; Attention weights of shape [batchSize, numHeads, timesteps, queryCount]
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*/
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#if NOT_EXCLUDED(OP_multi_head_dot_product_attention)
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DECLARE_CUSTOM_OP(multi_head_dot_product_attention, 7, -1, false, 0, 2);
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DECLARE_CUSTOM_OP(multi_head_dot_product_attention_bp, 8, 7, false, 0, 1);
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#endif
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}
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}
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#endif |