The original neural network from Torch7, nn, contains stable and widely used modules. 'nnx' contains more experimental, unproven modules, and optimizations. Modules that become stable and which are proven useful make their way into 'nn' (some already have).
This section includes documentation for the following objects:
- SoftMaxTree : a hierarchical log-softmax Module;
- TreeNLLCriterion : a negative log-likelihood Criterion for the SoftMaxTree;
- CTCCriterion : a Connectionist Temporal Classification Criterion based on warp-ctc;
- PushTable (and PullTable) : extracts a table element and inserts it later in the network;
- MultiSoftMax : performs a softmax over the last dimension of a 2D or 3D input;
- SpatialReSampling : performs bilinear resampling of a 3D or 4D input image;
- [QDRiemaNNLinear] (#nnx.QDRiemaNNLinear) : quasi-diagonal reduction for Riemannian gradient descent
- Recurrent : a generalized recurrent neural network container;
The constructor takes 2 mandatory and 4 optional arguments :
inputSize
: the number of units in the input embedding representation;hierarchy
: a Tensor mapping oneparent_id
to manychild_id
(a tree);rootId
: a number identifying the root node in the hierarchy. Defaults to-1
;accUpdate
: when the intent is to usebackwardUpdate
oraccUpdateGradParameters
, set this to true to save memory. Defaults to false;static
: when true (the defualt), returns parameters with keys that don't change from batch to batch;verbose
: prints some additional information concerning the hierarchy during construction.
The forward
method returns an output
Tensor of size 1D, while
backward
returns a table {gradInput, gradTarget}
. The second
variable is just a Tensor of zeros , such that the targets
can be
propagated through Containers
like ParallelTable.
> input = torch.randn(5,10)
> target = torch.IntTensor{20,24,27,10,12}
> gradOutput = torch.randn(5)
> root_id = 29
> input_size = 10
> hierarchy = {
>> [29]=torch.IntTensor{30,1,2}, [1]=torch.IntTensor{3,4,5},
>> [2]=torch.IntTensor{6,7,8}, [3]=torch.IntTensor{9,10,11},
>> [4]=torch.IntTensor{12,13,14}, [5]=torch.IntTensor{15,16,17},
>> [6]=torch.IntTensor{18,19,20}, [7]=torch.IntTensor{21,22,23},
>> [8]=torch.IntTensor{24,25,26,27,28}
>> }
> smt = nn.SoftMaxTree(input_size, hierarchy, root_id)
> smt:forward{input, target}
-3.5186
-3.8950
-3.7433
-3.3071
-3.0522
[torch.DoubleTensor of dimension 5]
> smt:backward({input, target}, gradOutput)
{
1 : DoubleTensor - size: 5x10
2 : IntTensor - size: 5
}
An example utilizing the above SoftMaxTree Module
and a Linear Module demonstrates how the PushTable can be used to
forward the target
Tensor without any other
Table Modules:
> mlp = nn.Sequential()
> linear = nn.Linear(50,100)
> push = nn.PushTable(2)
> pull = push:pull(2)
> mlp:add(push)
> mlp:add(nn.SelectTable(1))
> mlp:add(linear)
> mlp:add(pull)
> mlp:add(smt) --smt is a SoftMaxTree instance
> mlp:forward{input, target} -- input and target are defined above
-3.5186
-3.8950
-3.7433
-3.3071
-3.0522
[torch.DoubleTensor of dimension 5]
> mlp:backward({input, target}, gradOutput) -- so is gradOutput
{
1 : DoubleTensor - size: 5x10
2 : IntTensor - size: 5
}
The above code is equivalent to the following:
> mlp2 = nn.Sequential()
> para = nn.ParallelTable()
> para:add(linear)
> para:add(nn.Identity())
> mlp2:add(para)
> mlp2:add(smt)
> mlp2:forward{input, target}
-3.5186
-3.8950
-3.7433
-3.3071
-3.0522
[torch.DoubleTensor of dimension 5]
> mlp2:backward({input, target}, gradOutput)
{
1 : DoubleTensor - size: 5x10
2 : IntTensor - size: 5
}
In some cases, this can simplify the digraph of Modules. Note that a PushTable can be associated to many PullTables, but each PullTable is associated to only one PushTable.
### CTCCriterion ### ``` criterion = nn.CTCCriterion() ``` Creates a Criterion based on Baidus' [warp-ctc](https://github.com/baidu-research/warp-ctc) implementation. This Module measures the loss between a 3D output of (batch x time x inputdim) and a target without needing alignment of inputs and labels. Must have installed warp-ctc which can be installed via luarocks: ``` luarocks install http://raw.githubusercontent.com/baidu-research/warp-ctc/master/torch_binding/rocks/warp-ctc-scm-1.rockspec ``` Supports cuda via: ``` criterion = nn.CTCCriterion():cuda() ``` Example: ``` output = torch.Tensor({{{1,2,3,4,5},{6,7,8,9,10}}}) -- Tensor of size 1x1x5 (batch x time x inputdim). label = {{1,3}} sizes = torch.Tensor({2}) -- Size of each sequence (sequence-length) in the batch as a tensor ctcCriterion = nn.CTCCriterion()err = ctcCriterion:forward(output,label,sizes) gradOut = ctcCriterion:backward(output,label) print("----CPU----") print("Error : " .. err) print("Gradients :") print(gradOut)
ctcCriterion = ctcCriterion:cuda() -- Switch to cuda implementation. output = output:cuda()
err = ctcCriterion:forward(output,label,sizes) gradOut = ctcCriterion:backward(output,label) print("----GPU----") print("Error : " .. err) print("Gradients :") print(gradOut)
gives the output:
----CPU---- Error : 4.9038286209106 Gradients : (1,.,.) = 0.0117 -0.9683 0.0861 0.2341 0.6364 0.0117 0.0317 0.0861 -0.7659 0.6364 [torch.FloatTensor of size 1x2x5]
----GPU---- Error : 4.9038290977478 Gradients : (1,.,.) = 0.0117 -0.9683 0.0861 0.2341 0.6364 0.0117 0.0317 0.0861 -0.7659 0.6364 [torch.CudaTensor of size 1x2x5]
<a name='nnx.MultiSoftMax'/>
### MultiSoftMax ###
This Module takes 2D or 3D input and performs a softmax over the last dimension.
It uses the existing [SoftMax](https://github.com/torch/nn/blob/master/doc/transfer.md#nn.SoftMax)
CUDA/C code to do so such that the Module can be used on both GPU and CPU.
This can be useful for [keypoint detection](https://github.com/nicholas-leonard/dp/blob/master/doc/facialkeypointstutorial.md#multisoftmax).
<a name='nnx.SpatialReSampling'/>
### SpatialReSampling ###
Applies a 2D re-sampling over an input image composed of
several input planes (or channels, colors). The input tensor in `forward(input)` is
expected to be a 3D or 4D tensor of size : `[batchSize x] nInputPlane x width x height`.
The number of output planes will be the same as the number of input
planes.
The re-sampling is done using [bilinear interpolation](http://en.wikipedia.org/wiki/Bilinear_interpolation).
For a simple nearest-neihbor upsampling, use `nn.SpatialUpSampling()`,
and for a simple average-based down-sampling, use
`nn.SpatialDownSampling()`.
If the input image is a 3D tensor of size `nInputPlane x height x width`,
the output image size will be `nInputPlane x oheight x owidth` where
`owidth` and `oheight` are given to the constructor.
Instead of `owidth` and `oheight`, one can provide `rwidth` and `rheight`,
such that `owidth = iwidth*rwidth` and `oheight = iheight*rheight`.
As an example, we can run the following code on the famous Lenna image:
```lua
require 'image'
require 'nnx'
input = image.loadPNG('doc/image/Lenna.png')
l = nn.SpatialReSampling{owidth=150,oheight=150}
output = l:forward(input)
image.save('doc/image/Lenna-150x150-bilinear.png', output)
The input:
The re-sampled output:
### QDRiemaNNLinear ### The Quasi-Diagonal Riemannian Neural Network Linear (QDRiemaNNLinear) module is an implementation of the quasi-diagonal reduction of metrics, used for Riemannian gradient descent. The algorithm is defined in Riemannian metrics for neural networks I: feedforward networks by Yann Ollivier (http://arxiv.org/abs/1303.0818) and an efficient implementation is described in Practical Riemannian Neural Networks by Yann Ollivier and Gaetan Marceau-Caron (http://arxiv.org/abs/1602.08007). To use this module, simply replace `nn.Linear(ninput,noutput)` with `nnx.QDRiemaNNLinear(ninput,noutput)`. As always, the step-size must be chosen accordingly. Two additional arguments are also possible: * gamma (default=0.01): determine the update rate of the metric for a minibatch setting, i.e., (1-gamma) * oldMetric + gamma newMetric. Smaller minibatches require a smaller gamma. A default value depending on the size of the minibatches is `gamma = 1. - torch.pow(1.-1./nTraining,miniBatchSize)` where `nTraining` is the number of training examples of the dataset and `miniBatchSize` is the number of training examples per minibatch. * qdFlag (default=true): Whether to use the quasi-diagonal reduction (true) or only the diagonal (false). The former should be better.This module is a straightforward implementation of the outer product gradient descent.
- Torch7 (www.torch.ch)
- Install Torch7 (refer to its own documentation).
- clone this project into dev directory of Torch7.
- Rebuild torch, it will include new projects too.
First run torch, and load nnx:
$ torch
> require 'nnx'
Once loaded, tab-completion will help you navigate through the library (note that most function are added directly to nn):
> nnx. + TAB
...
> nn. + TAB
In particular, it's good to verify that all modules provided pass their tests:
> nnx.test_all()
> nnx.test_omp()
DEPRECATED July 6th, 2015. Use rnn instead.