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import torch |
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import torch.nn as nn |
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from torch.distributions.normal import Normal |
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from copy import deepcopy |
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import numpy as np |
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from libs import Mlp as MLP |
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class SparseDispatcher(object): |
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"""Helper for implementing a mixture of experts. |
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The purpose of this class is to create input minibatches for the |
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experts and to combine the results of the experts to form a unified |
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output tensor. |
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There are two functions: |
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dispatch - take an input Tensor and create input Tensors for each expert. |
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combine - take output Tensors from each expert and form a combined output |
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Tensor. Outputs from different experts for the same batch element are |
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summed together, weighted by the provided "gates". |
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The class is initialized with a "gates" Tensor, which specifies which |
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batch elements go to which experts, and the weights to use when combining |
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the outputs. Batch element b is sent to expert e iff gates[b, e] != 0. |
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The inputs and outputs are all two-dimensional [batch, depth]. |
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Caller is responsible for collapsing additional dimensions prior to |
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calling this class and reshaping the output to the original shape. |
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See common_layers.reshape_like(). |
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Example use: |
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gates: a float32 `Tensor` with shape `[batch_size, num_experts]` |
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inputs: a float32 `Tensor` with shape `[batch_size, input_size]` |
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experts: a list of length `num_experts` containing sub-networks. |
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dispatcher = SparseDispatcher(num_experts, gates) |
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expert_inputs = dispatcher.dispatch(inputs) |
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expert_outputs = [experts[i](expert_inputs[i]) for i in range(num_experts)] |
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outputs = dispatcher.combine(expert_outputs) |
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The preceding code sets the output for a particular example b to: |
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output[b] = Sum_i(gates[b, i] * experts[i](inputs[b])) |
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This class takes advantage of sparsity in the gate matrix by including in the |
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`Tensor`s for expert i only the batch elements for which `gates[b, i] > 0`. |
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""" |
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def __init__(self, num_experts, gates): |
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"""Create a SparseDispatcher.""" |
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self._gates = gates |
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self._num_experts = num_experts |
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sorted_experts, index_sorted_experts = torch.nonzero(gates).sort(0) |
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_, self._expert_index = sorted_experts.split(1, dim=1) |
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self._batch_index = torch.nonzero(gates)[index_sorted_experts[:, 1], 0] |
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self._part_sizes = (gates > 0).sum(0).tolist() |
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gates_exp = gates[self._batch_index.flatten()] |
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self._nonzero_gates = torch.gather(gates_exp, 1, self._expert_index) |
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def dispatch(self, inp): |
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"""Create one input Tensor for each expert. |
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The `Tensor` for a expert `i` contains the slices of `inp` corresponding |
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to the batch elements `b` where `gates[b, i] > 0`. |
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Args: |
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inp: a `Tensor` of shape "[batch_size, <extra_input_dims>]` |
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Returns: |
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a list of `num_experts` `Tensor`s with shapes |
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`[expert_batch_size_i, <extra_input_dims>]`. |
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""" |
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inp_exp = inp[self._batch_index].squeeze(1) |
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return torch.split(inp_exp, self._part_sizes, dim=0) |
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def combine(self, expert_out, multiply_by_gates=True, cnn_combine=None): |
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"""Sum together the expert output, weighted by the gates. |
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The slice corresponding to a particular batch element `b` is computed |
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as the sum over all experts `i` of the expert output, weighted by the |
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corresponding gate values. If `multiply_by_gates` is set to False, the |
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gate values are ignored. |
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Args: |
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expert_out: a list of `num_experts` `Tensor`s, each with shape |
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`[expert_batch_size_i, <extra_output_dims>]`. |
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multiply_by_gates: a boolean |
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Returns: |
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a `Tensor` with shape `[batch_size, <extra_output_dims>]`. |
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""" |
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stitched = torch.cat(expert_out, 0) |
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if multiply_by_gates: |
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stitched = stitched.mul(self._nonzero_gates.unsqueeze(1)) |
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zeros = torch.zeros((self._gates.size(0),) + expert_out[-1].shape[1:], |
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requires_grad=True, device=stitched.device) |
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if cnn_combine is not None: |
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return self.smartly_combine(stitched, cnn_combine) |
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combined = zeros.index_add(0, self._batch_index, stitched.float()) |
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return combined |
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def smartly_combine(self, stitched, cnn_combine): |
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idxes = [] |
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for i in self._batch_index.unique(): |
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idx = (self._batch_index == i).nonzero().squeeze(1) |
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idxes.append(idx) |
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idxes = torch.stack(idxes) |
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return cnn_combine(stitched[idxes]).squeeze(1) |
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def expert_to_gates(self): |
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"""Gate values corresponding to the examples in the per-expert `Tensor`s. |
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Returns: |
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a list of `num_experts` one-dimensional `Tensor`s with type `tf.float32` |
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and shapes `[expert_batch_size_i]` |
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""" |
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return torch.split(self._nonzero_gates, self._part_sizes, dim=0) |
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def build_experts(experts_cfg, default_cfg, num_experts): |
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experts_cfg = deepcopy(experts_cfg) |
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if experts_cfg is None: |
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return nn.ModuleList([ |
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MLP(*default_cfg) |
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for i in range(num_experts)]) |
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experts = [] |
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for e_cfg in experts_cfg: |
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type_ = e_cfg.pop('type') |
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if type_ == 'mlp': |
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experts.append(MLP(*default_cfg)) |
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return nn.ModuleList(experts) |
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class MoE(nn.Module): |
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"""Call a Sparsely gated mixture of experts layer with 1-layer |
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Feed-Forward networks as experts. |
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Args: |
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input_size: integer - size of the input |
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output_size: integer - size of the input |
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num_experts: an integer - number of experts |
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hidden_size: an integer - hidden size of the experts |
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noisy_gating: a boolean |
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k: an integer - how many experts to use for each batch element |
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""" |
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def __init__(self, input_size, output_size, num_experts, hidden_size, |
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experts=None, noisy_gating=True, k=4, |
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x_gating=None, with_noise=True, with_smart_merger=None): |
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super(MoE, self).__init__() |
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self.noisy_gating = noisy_gating |
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self.num_experts = num_experts |
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self.output_size = output_size |
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self.input_size = input_size |
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self.hidden_size = hidden_size |
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self.k = k |
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self.with_noise = with_noise |
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self.experts = build_experts( |
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experts, |
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(self.input_size, self.hidden_size, self.output_size), |
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num_experts) |
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self.w_gate = nn.Parameter(torch.zeros(input_size, num_experts), requires_grad=True) |
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self.w_noise = nn.Parameter(torch.zeros(input_size, num_experts), requires_grad=True) |
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self.x_gating = x_gating |
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if self.x_gating == 'conv1d': |
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self.x_gate = nn.Conv1d(4096, 1, kernel_size=3, padding=1) |
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self.softplus = nn.Softplus() |
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self.softmax = nn.Softmax(1) |
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self.register_buffer("mean", torch.tensor([0.0])) |
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self.register_buffer("std", torch.tensor([1.0])) |
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assert(self.k <= self.num_experts) |
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self.cnn_combine = None |
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if with_smart_merger == 'v1': |
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print('with SMART MERGER') |
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self.cnn_combine = nn.Conv2d(self.k, 1, kernel_size=3, padding=1) |
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def cv_squared(self, x): |
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"""The squared coefficient of variation of a sample. |
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Useful as a loss to encourage a positive distribution to be more uniform. |
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Epsilons added for numerical stability. |
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Returns 0 for an empty Tensor. |
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Args: |
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x: a `Tensor`. |
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Returns: |
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a `Scalar`. |
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""" |
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eps = 1e-10 |
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if x.shape[0] == 1: |
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return torch.tensor([0], device=x.device, dtype=x.dtype) |
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return x.float().var() / (x.float().mean()**2 + eps) |
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def _gates_to_load(self, gates): |
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"""Compute the true load per expert, given the gates. |
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The load is the number of examples for which the corresponding gate is >0. |
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Args: |
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gates: a `Tensor` of shape [batch_size, n] |
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Returns: |
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a float32 `Tensor` of shape [n] |
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""" |
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return (gates > 0).sum(0) |
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def _prob_in_top_k(self, clean_values, noisy_values, noise_stddev, noisy_top_values): |
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"""Helper function to NoisyTopKGating. |
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Computes the probability that value is in top k, given different random noise. |
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This gives us a way of backpropagating from a loss that balances the number |
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of times each expert is in the top k experts per example. |
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In the case of no noise, pass in None for noise_stddev, and the result will |
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not be differentiable. |
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Args: |
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clean_values: a `Tensor` of shape [batch, n]. |
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noisy_values: a `Tensor` of shape [batch, n]. Equal to clean values plus |
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normally distributed noise with standard deviation noise_stddev. |
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noise_stddev: a `Tensor` of shape [batch, n], or None |
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noisy_top_values: a `Tensor` of shape [batch, m]. |
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"values" Output of tf.top_k(noisy_top_values, m). m >= k+1 |
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Returns: |
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a `Tensor` of shape [batch, n]. |
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""" |
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batch = clean_values.size(0) |
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m = noisy_top_values.size(1) |
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top_values_flat = noisy_top_values.flatten() |
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threshold_positions_if_in = torch.arange(batch, device=clean_values.device) * m + self.k |
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threshold_if_in = torch.unsqueeze(torch.gather(top_values_flat, 0, threshold_positions_if_in), 1) |
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is_in = torch.gt(noisy_values, threshold_if_in) |
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threshold_positions_if_out = threshold_positions_if_in - 1 |
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threshold_if_out = torch.unsqueeze(torch.gather(top_values_flat, 0, threshold_positions_if_out), 1) |
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normal = Normal(self.mean, self.std) |
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prob_if_in = normal.cdf((clean_values - threshold_if_in)/noise_stddev) |
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prob_if_out = normal.cdf((clean_values - threshold_if_out)/noise_stddev) |
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prob = torch.where(is_in, prob_if_in, prob_if_out) |
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return prob |
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def noisy_top_k_gating(self, x, train, noise_epsilon=1e-2): |
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"""Noisy top-k gating. |
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See paper: https://arxiv.org/abs/1701.06538. |
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Args: |
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x: input Tensor with shape [batch_size, input_size] |
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train: a boolean - we only add noise at training time. |
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noise_epsilon: a float |
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Returns: |
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gates: a Tensor with shape [batch_size, num_experts] |
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load: a Tensor with shape [num_experts] |
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""" |
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clean_logits = x @ self.w_gate |
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if self.noisy_gating and train: |
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raw_noise_stddev = x @ self.w_noise |
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noise_stddev = ((self.softplus(raw_noise_stddev) + noise_epsilon)) |
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noisy_logits = clean_logits + (torch.randn_like(clean_logits) * noise_stddev) |
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logits = noisy_logits |
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else: |
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logits = clean_logits |
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top_logits, top_indices = logits.topk(min(self.k + 1, self.num_experts), dim=1) |
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top_k_logits = top_logits[:, :self.k] |
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top_k_indices = top_indices[:, :self.k] |
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top_k_gates = self.softmax(top_k_logits) |
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zeros = torch.zeros_like(logits, requires_grad=True) |
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gates = zeros.scatter(1, top_k_indices, top_k_gates) |
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if self.noisy_gating and self.k < self.num_experts and train: |
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load = (self._prob_in_top_k(clean_logits, noisy_logits, noise_stddev, top_logits)).sum(0) |
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else: |
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load = self._gates_to_load(gates) |
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return gates, load |
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def forward(self, x, loss_coef=1e-2): |
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"""Args: |
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x: tensor shape [batch_size, input_size] |
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train: a boolean scalar. |
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loss_coef: a scalar - multiplier on load-balancing losses |
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Returns: |
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y: a tensor with shape [batch_size, output_size]. |
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extra_training_loss: a scalar. This should be added into the overall |
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training loss of the model. The backpropagation of this loss |
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encourages all experts to be approximately equally used across a batch. |
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""" |
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if self.x_gating is not None: |
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xg = self.x_gate(x).squeeze(1) |
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else: |
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xg = x.mean(1) |
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gates, load = self.noisy_top_k_gating( |
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xg, self.training and self.with_noise) |
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importance = gates.sum(0) |
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loss = self.cv_squared(importance) + self.cv_squared(load) |
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loss *= loss_coef |
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dispatcher = SparseDispatcher(self.num_experts, gates) |
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expert_inputs = dispatcher.dispatch(x) |
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gates = dispatcher.expert_to_gates() |
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expert_outputs = [self.experts[i](expert_inputs[i]) |
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for i in range(self.num_experts)] |
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y = dispatcher.combine(expert_outputs, cnn_combine=self.cnn_combine) |
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return y, loss |
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