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Batching
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Batching
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<h1>
<a class="nav-anchor" id="Batching-1" href="#Batching-1">
Batching
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<h2>
<a class="nav-anchor" id="Basics-1" href="#Basics-1">
Basics
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<p>
Existing machine learning frameworks and libraries represent batching, and other properties of data, only implicitly. Your machine learning data is a large
<code>N</code>
-dimensional array, which may have a shape like:
</p>
<pre><code class="language-julia">100 × 50 × 256 × 256</code></pre>
<p>
Typically, this might represent that you have (say) a batch of 100 samples, where each sample is a 50-long sequence of 256×256 images. This is great for performance, but array operations often become much more cumbersome as a result. Especially if you manipulate dimensions at runtime as an optimisation, debugging models can become extremely fiddly, with a proliferation of
<code>X × Y × Z</code>
arrays and no information about where they came from.
</p>
<p>
Flux introduces a new approach where the batch dimension is represented explicitly as part of the data. For example:
</p>
<pre><code class="language-julia">julia&gt; xs = Batch([[1,2,3], [4,5,6]])
2-element Batch of Vector{Int64}:
[1,2,3]
[4,5,6]</code></pre>
<p>
Batches are represented the way we
<em>
think
</em>
about them; as an list of data points. We can do all the usual array operations with them, including getting the first with
<code>xs[1]</code>
, iterating over them and so on. The trick is that under the hood, the data is batched into a single array:
</p>
<pre><code class="language-julia">julia&gt; rawbatch(xs)
2×3 Array{Int64,2}:
1 2 3
4 5 6</code></pre>
<p>
When we put a
<code>Batch</code>
object into a model, the model is ultimately working with a single array, which means there&#39;s no performance overhead and we get the full benefit of standard batching.
</p>
<p>
Turning a set of vectors into a matrix is fairly easy anyway, so what&#39;s the big deal? Well, it gets more interesting as we start working with more complex data. Say we were working with 4×4 images:
</p>
<pre><code class="language-julia">julia&gt; xs = Batch([[1 2; 3 4], [5 6; 7 8]])
2-element Flux.Batch of Array{Int64,2}:
[1 2; 3 4]
[5 6; 7 8]</code></pre>
<p>
The raw batch array is much messier, and harder to recognise:
</p>
<pre><code class="language-julia">julia&gt; rawbatch(xs)
2×2×2 Array{Int64,3}:
[:, :, 1] =
1 3
5 7
[:, :, 2] =
2 4
6 8</code></pre>
<p>
Furthermore, because the batches acts like a list of arrays, we can use simple and familiar operations on it:
</p>
<pre><code class="language-julia">julia&gt; map(flatten, xs)
2-element Array{Array{Int64,1},1}:
[1,3,2,4]
[5,7,6,8]</code></pre>
<p>
<code>flatten</code>
is simple enough over a single data point, but flattening a batched data set is more complex and you end up needing arcane array operations like
<code>mapslices</code>
. A
<code>Batch</code>
can just handle this for you for free, and more importantly it ensures that your operations are
<em>
correct
</em>
that you haven&#39;t mixed up your batch and data dimensions, or used the wrong array op, and so on.
</p>
<h2>
<a class="nav-anchor" id="Sequences-and-Nesting-1" href="#Sequences-and-Nesting-1">
Sequences and Nesting
</a>
</h2>
<p>
As well as
<code>Batch</code>
, there&#39;s a structure called
<code>Seq</code>
which behaves very similarly. Let&#39;s say we have two one-hot encoded DNA sequences:
</p>
<pre><code class="language-julia">julia&gt; x1 = Seq([[0,1,0,0], [1,0,0,0], [0,0,0,1]]) # [A, T, C, G]
julia&gt; x2 = Seq([[0,0,1,0], [0,0,0,1], [0,0,1,0]])
julia&gt; rawbatch(x1)
3×4 Array{Int64,2}:
0 1 0 0
1 0 0 0
0 0 0 1</code></pre>
<p>
This is identical to
<code>Batch</code>
so far; but where it gets interesting is that you can actually nest these types:
</p>
<pre><code class="language-julia">julia&gt; xs = Batch([x1, x2])
2-element Batch of Seq of Vector{Int64}:
[[0,1,0,0],[1,0,0,0],[0,0,0,1]]
[[0,0,1,0],[0,0,0,1],[0,0,1,0]]</code></pre>
<p>
Again, this represents itself intuitively as a list-of-lists-of-lists, but
<code>rawbatch</code>
shows that the real underlying value is an
<code>Array{Int64,3}</code>
of shape
<code>2×3×4</code>
.
</p>
<h2>
<a class="nav-anchor" id="Future-Work-1" href="#Future-Work-1">
Future Work
</a>
</h2>
<p>
The design of batching is still a fairly early work in progress, though it&#39;s used in a few places in the system. For example, all Flux models expect to be given
<code>Batch</code>
objects which are unwrapped into raw arrays for the computation. Models will convert their arguments if necessary, so it&#39;s convenient to call a model with a single data point like
<code>f([1,2,3])</code>
.
</p>
<p>
Right now, the
<code>Batch</code>
or
<code>Seq</code>
types always stack along the left-most dimension. In future, this will be customisable, and Flux will provide implementations of common functions that are generic across the batch dimension. This brings the following benefits:
</p>
<ul>
<li>
<p>
Code can be written in a batch-agnostic way or be generic across batching strategies.
</p>
</li>
<li>
<p>
Batching and optimisations, like switching batch dimensions, can be expressed by the programmer with compiler support; fewer code changes are required and optimisations are guaranteed not to break the model.
</p>
</li>
<li>
<p>
This also opens the door for more automatic optimisations, e.g. having the compiler explore the search base of possible batching combinations.
</p>
</li>
</ul>
<p>
Here&#39;s a more detailed illustration of how it might look for code to be &quot;generic across batching&quot;. Take for example a weight matrix
<code>W</code>
times a vector
<code>x</code>
, as used in a logistic regression or a simple neural network:
</p>
<pre><code class="language-julia"> W * x =&gt; y
(10×28) * (28) =&gt; (10)</code></pre>
<p>
If we want to work with a batch of 50
<code>x</code>
s, one option is to stack the data into a matrix of size
<code>28 × 50</code>
.
</p>
<pre><code class="language-julia"> W * x =&gt; y
(10×28) * (28×50) =&gt; (10×50)</code></pre>
<p>
This works, but we may find that it&#39;s slow or doesn&#39;t fit well with the rest of the model, which batches on the first dimension. For that reason we may instead want to put the data in a
<code>50 × 28</code>
matrix and alter the code as follows:
</p>
<pre><code class="language-julia"> x * W&#39; =&gt; y
(50×28) * (28×10) =&gt; (50×10)</code></pre>
<p>
to make the shapes work out. This code change is not ideal; in more complex cases it can become fiddly and error-prone, and it means that the code is less reusable, tied to a particular implementation strategy.
</p>
<p>
There&#39;s an alternative. We keep the same code, but represent the batched
<code>x</code>
s as either a
<code>Batch{Vector,1}</code>
or a
<code>Batch{Vector,2}</code>
, depending on how the data is stacked. Then we can simply overload
<code>*</code>
as follows:
</p>
<pre><code class="language-julia">*(W::Matrix, x::Batch{Vector,1}) = x * W&#39;
*(W::Matrix, x::Batch{Vector,2}) = W * x</code></pre>
<p>
This means that we can always write
<code>W*x</code>
, and the code is reusable in a larger network regardless of the overall batching approach. Moreover, Julia&#39;s type system ensures there&#39;s no runtime cost to doing this, and we can compile the code appropriately for backends like TensorFlow as well.
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