Criterions
are helpful to train a neural network. Given an input and a
target, they compute a gradient according to a given loss function.
- Classification criterions:
BCECriterion
: binary cross-entropy forSigmoid
(two-class version ofClassNLLCriterion
);ClassNLLCriterion
: negative log-likelihood forLogSoftMax
(multi-class);CrossEntropyCriterion
: combinesLogSoftMax
andClassNLLCriterion
;ClassSimplexCriterion
: A simplex embedding criterion for classification.MarginCriterion
: two class margin-based loss;SoftMarginCriterion
: two class softmargin-based loss;MultiMarginCriterion
: multi-class margin-based loss;MultiLabelMarginCriterion
: multi-class multi-classification margin-based loss;MultiLabelSoftMarginCriterion
: multi-class multi-classification loss based on binary cross-entropy;
- Regression criterions:
AbsCriterion
: measures the mean absolute value of the element-wise difference between input;SmoothL1Criterion
: a smooth version of the AbsCriterion;MSECriterion
: mean square error (a classic);SpatialAutoCropMSECriterion
: Spatial mean square error when the input is spatially smaller than the target, by only comparing their spatial overlap;DistKLDivCriterion
: Kullback–Leibler divergence (for fitting continuous probability distributions);
- Embedding criterions (measuring whether two inputs are similar or dissimilar):
HingeEmbeddingCriterion
: takes a distance as input;L1HingeEmbeddingCriterion
: L1 distance between two inputs;CosineEmbeddingCriterion
: cosine distance between two inputs;DistanceRatioCriterion
: Probabilistic criterion for training siamese model with triplets.
- Miscelaneus criterions:
MultiCriterion
: a weighted sum of other criterions each applied to the same input and target;ParallelCriterion
: a weighted sum of other criterions each applied to a different input and target;MarginRankingCriterion
: ranks two inputs;ModuleCriterion
: adds an optionalinputModule
andtargetModule
before a decorated criterion;
This is an abstract class which declares methods defined in all criterions. This class is serializable.
Given an input
and a target
, compute the loss function associated to the criterion and return the result.
In general input
and target
are Tensor
s, but some specific criterions might require some other type of object.
The output
returned should be a scalar in general.
The state variable self.output
should be updated after a call to forward()
.
Given an input
and a target
, compute the gradients of the loss function associated to the criterion and return the result.
In general input
, target
and gradInput
are Tensor
s, but some specific criterions might require some other type of object.
The state variable self.gradInput
should be updated after a call to backward()
.
State variable which contains the result of the last forward(input, target)
call.
State variable which contains the result of the last backward(input, target)
call.
criterion = nn.AbsCriterion()
Creates a criterion that measures the mean absolute value of the element-wise difference between input x
and target y
:
loss(x, y) = 1/n \sum |x_i - y_i|
If x
and y
are d
-dimensional Tensor
s with a total of n
elements, the sum operation still operates over all the elements, and divides by n
.
The division by n
can be avoided if one sets the internal variable sizeAverage
to false
:
criterion = nn.AbsCriterion()
criterion.sizeAverage = false
criterion = nn.ClassNLLCriterion([weights, sizeAverage, ignoreIndex])
The negative log likelihood (NLL) criterion. It is useful to train a classification problem with n
classes.
If provided, the optional argument weights
should be a 1D Tensor
assigning weight to each of the classes.
This is particularly useful when you have an unbalanced training set.
The input
given through a forward()
is expected to contain log-probabilities of each class: input
has to be a 1D Tensor
of size n
.
Obtaining log-probabilities in a neural network is easily achieved by adding a LogSoftMax
layer in the last layer of your neural network.
You may use CrossEntropyCriterion
instead, if you prefer not to add an extra layer to your network.
This criterion expects a class index (1 to the number of class) as target
when calling forward(input, target
) and backward(input, target)
.
The loss can be described as:
loss(x, class) = -x[class]
or in the case of the weights
argument, it is specified as follows:
loss(x, class) = -weights[class] * x[class]
or in the case of the ignoreIndex
argument:
loss(x, class) = class != ignoreIndex ? -weights[class] * x[class] : 0
Indeed, the ignoreIndex
(defaults to -100) specifies a value for targets to be ignored.
The commensurate gradInput
for that target will be zero.
When sizeAverage=true
(the default), the gradInput
and output
are averaged over non-ignored targets.
Due to the behaviour of the backend code, it is necessary to set sizeAverage
to false when calculating losses in non-batch mode.
The following is a code fragment showing how to make a gradient step given an input x
, a desired output y
(an integer 1
to n
, in this case n = 2
classes), a network mlp
and a learning rate learningRate
:
function gradUpdate(mlp, x, y, learningRate)
local criterion = nn.ClassNLLCriterion()
local pred = mlp:forward(x)
local err = criterion:forward(pred, y)
mlp:zeroGradParameters()
local t = criterion:backward(pred, y)
mlp:backward(x, t)
mlp:updateParameters(learningRate)
end
By default, the losses are averaged over observations for each minibatch. However, if the argument sizeAverage
is set to false
, the losses are instead summed for each minibatch.
criterion = nn.CrossEntropyCriterion([weights])
This criterion combines LogSoftMax
and ClassNLLCriterion
in one single class.
It is useful to train a classification problem with n
classes.
If provided, the optional argument weights
should be a 1D Tensor
assigning weight to each of the classes. This is particularly useful when you have an unbalanced training set.
The input
given through a forward()
is expected to contain scores for each class: input
has to be a 1D Tensor
of size n
.
This criterion expect a class index (1 to the number of class) as target
when calling forward(input, target)
and backward(input, target)
.
The loss can be described as:
loss(x, class) = -log(exp(x[class]) / (\sum_j exp(x[j])))
= -x[class] + log(\sum_j exp(x[j]))
or in the case of the weights
argument being specified:
loss(x, class) = weights[class] * (-x[class] + log(\sum_j exp(x[j])))
Due to the behaviour of the backend code, it is necessary to set sizeAverage to false when calculating losses in non-batch mode.
crit = nn.CrossEntropyCriterion(weights)
crit.nll.sizeAverage = false
The losses are averaged across observations for each minibatch.
criterion = nn.ClassSimplexCriterion(nClasses)
ClassSimplexCriterion implements a criterion for classification. It learns an embedding per class, where each class' embedding is a point on an (N-1)-dimensional simplex, where N is the number of classes.
The input
given through a forward()
is expected to be the output of a Normalized Linear layer with no bias:
input
has to be a 1DTensor
of sizen
for a single sample- a 2D
Tensor
of sizebatchSize x n
for a mini-batch of samples
This Criterion is best used in combination with a neural network where the last layers are:
- a weight-normalized bias-less Linear layer. Example source code
- followed by an output normalization layer (nn.Normalize).
The loss is described in detail in the paper Scale-invariant learning and convolutional networks.
The following is a code fragment showing how to make a gradient step given an input x
, a desired output y
(an integer 1
to n
, in this case n = 30
classes), a network mlp
and a learning rate learningRate
:
nInput = 10
nClasses = 30
nHidden = 100
mlp = nn.Sequential()
mlp:add(nn.Linear(nInput, nHidden)):add(nn.ReLU())
mlp:add(nn.NormalizedLinearNoBias(nHidden, nClasses))
mlp:add(nn.Normalize(2))
criterion = nn.ClassSimplexCriterion(nClasses)
function gradUpdate(mlp, x, y, learningRate)
pred = mlp:forward(x)
local err = criterion:forward(pred, y)
mlp:zeroGradParameters()
local t = criterion:backward(pred, y)
mlp:backward(x, t)
mlp:updateParameters(learningRate)
end
This criterion also provides two helper functions getPredictions(input)
and getTopPrediction(input)
that return the raw predictions and the top prediction index respectively, given an input sample.
criterion = nn.DistKLDivCriterion()
The Kullback–Leibler divergence criterion.
KL divergence is a useful distance measure for continuous distributions and is often useful when performing direct regression over the space of (discretely sampled) continuous output distributions.
As with ClassNLLCriterion, the input
given through a forward()
is expected to contain log-probabilities, however unlike ClassNLLCriterion, input
is not restricted to a 1D or 2D vector (as the criterion is applied element-wise).
This criterion expect a target
Tensor
of the same size as the input
Tensor
when calling forward(input, target)
and backward(input, target)
.
The loss can be described as:
loss(x, target) = 1/n \sum(target_i * (log(target_i) - x_i))
By default, the losses are averaged for each minibatch over observations as well as over dimensions. However, if the field sizeAverage
is set to false
, the losses are instead summed.
criterion = nn.BCECriterion([weights])
Creates a criterion that measures the Binary Cross Entropy between the target and the output:
loss(o, t) = - 1/n sum_i (t[i] * log(o[i]) + (1 - t[i]) * log(1 - o[i]))
or in the case of the weights argument being specified:
loss(o, t) = - 1/n sum_i weights[i] * (t[i] * log(o[i]) + (1 - t[i]) * log(1 - o[i]))
This is used for measuring the error of a reconstruction in for example an auto-encoder. Note that the outputs o[i]
should be numbers between 0 and 1, for instance, the output of an nn.Sigmoid
layer and should be interpreted as the probability of predicting t[i] = 1
. Note t[i]
can be either 0 or 1.
By default, the losses are averaged for each minibatch over observations as well as over dimensions. However, if the field sizeAverage
is set to false
, the losses are instead summed.
criterion = nn.MarginCriterion([margin])
Creates a criterion that optimizes a two-class classification hinge loss (margin-based loss) between input x
(a Tensor
of dimension 1
) and output y
(which is a tensor containing either 1
s or -1
s).
margin
, if unspecified, is by default 1
.
loss(x, y) = sum_i (max(0, margin - y[i]*x[i])) / x:nElement()
The normalization by the number of elements in the input can be disabled by
setting self.sizeAverage
to false
.
function gradUpdate(mlp, x, y, criterion, learningRate)
local pred = mlp:forward(x)
local err = criterion:forward(pred, y)
local gradCriterion = criterion:backward(pred, y)
mlp:zeroGradParameters()
mlp:backward(x, gradCriterion)
mlp:updateParameters(learningRate)
end
mlp = nn.Sequential()
mlp:add(nn.Linear(5, 1))
x1 = torch.rand(5)
x1_target = torch.Tensor{1}
x2 = torch.rand(5)
x2_target = torch.Tensor{-1}
criterion=nn.MarginCriterion(1)
for i = 1, 1000 do
gradUpdate(mlp, x1, x1_target, criterion, 0.01)
gradUpdate(mlp, x2, x2_target, criterion, 0.01)
end
print(mlp:forward(x1))
print(mlp:forward(x2))
print(criterion:forward(mlp:forward(x1), x1_target))
print(criterion:forward(mlp:forward(x2), x2_target))
gives the output:
1.0043
[torch.Tensor of dimension 1]
-1.0061
[torch.Tensor of dimension 1]
0
0
i.e. the mlp successfully separates the two data points such that they both have a margin
of 1
, and hence a loss of 0
.
By default, the losses are averaged over observations for each minibatch. However, if the field sizeAverage
is set to false
, the losses are instead summed.
criterion = nn.SoftMarginCriterion()
Creates a criterion that optimizes a two-class classification logistic loss between input x
(a Tensor
of dimension 1
) and output y
(which is a tensor containing either 1
s or -1
s).
loss(x, y) = sum_i (log(1 + exp(-y[i]*x[i]))) / x:nElement()
The normalization by the number of elements in the input can be disabled by
setting self.sizeAverage
to false
.
function gradUpdate(mlp, x, y, criterion, learningRate)
local pred = mlp:forward(x)
local err = criterion:forward(pred, y)
local gradCriterion = criterion:backward(pred, y)
mlp:zeroGradParameters()
mlp:backward(x, gradCriterion)
mlp:updateParameters(learningRate)
end
mlp = nn.Sequential()
mlp:add(nn.Linear(5, 1))
x1 = torch.rand(5)
x1_target = torch.Tensor{1}
x2 = torch.rand(5)
x2_target = torch.Tensor{-1}
criterion=nn.SoftMarginCriterion(1)
for i = 1, 1000 do
gradUpdate(mlp, x1, x1_target, criterion, 0.01)
gradUpdate(mlp, x2, x2_target, criterion, 0.01)
end
print(mlp:forward(x1))
print(mlp:forward(x2))
print(criterion:forward(mlp:forward(x1), x1_target))
print(criterion:forward(mlp:forward(x2), x2_target))
gives the output:
0.7471
[torch.DoubleTensor of size 1]
-0.9607
[torch.DoubleTensor of size 1]
0.38781049558836
0.32399356957564
i.e. the mlp successfully separates the two data points.
By default, the losses are averaged over observations for each minibatch. However, if the field sizeAverage
is set to false
, the losses are instead summed.
criterion = nn.MultiMarginCriterion(p, [weights], [margin])
Creates a criterion that optimizes a multi-class classification hinge loss (margin-based loss) between input x
(a Tensor
of dimension 1) and output y
(which is a target class index, 1
<= y
<= x:size(1)
):
loss(x, y) = sum_i(max(0, (margin - x[y] + x[i]))^p) / x:size(1)
where i == 1
to x:size(1)
and i ~= y
.
Note that this criterion also works with 2D inputs and 1D targets.
Optionally, you can give non-equal weighting on the classes by passing a 1D weights
tensor into the constructor.
The loss function then becomes:
loss(x, y) = sum_i(max(0, w[y] * (margin - x[y] + x[i]))^p) / x:size(1)
This criterion is especially useful for classification when used in conjunction with a module ending in the following output layer:
mlp = nn.Sequential()
mlp:add(nn.Euclidean(n, m)) -- outputs a vector of distances
mlp:add(nn.MulConstant(-1)) -- distance to similarity
By default, the losses are averaged over observations for each minibatch. However, if the field sizeAverage
is set to false
, the losses are instead summed.
criterion = nn.MultiLabelMarginCriterion()
Creates a criterion that optimizes a multi-class multi-classification hinge loss (margin-based loss) between input x
(a 1D Tensor
) and output y
(which is a 1D Tensor
of target class indices):
loss(x, y) = sum_ij(max(0, 1 - (x[y[j]] - x[i]))) / x:size(1)
where i == 1
to x:size(1)
, j == 1
to y:size(1)
, y[j] ~= 0
, and i ~= y[j]
for all i
and j
.
Note that this criterion also works with 2D inputs and targets.
y
and x
must have the same size.
The criterion only considers the first non zero y[j]
targets.
This allows for different samples to have variable amounts of target classes:
criterion = nn.MultiLabelMarginCriterion()
input = torch.randn(2, 4)
target = torch.Tensor{{1, 3, 0, 0}, {4, 0, 0, 0}} -- zero-values are ignored
criterion:forward(input, target)
criterion = nn.MultiLabelSoftMarginCriterion()
Creates a criterion that optimizes a multi-label one-versus-all loss based on max-entropy, between input x
(a 1D Tensor
) and target y
(a binary 1D Tensor
):
loss(x, y) = - sum_i (y[i] log( exp(x[i]) / (1 + exp(x[i]))) + (1-y[i]) log(1/(1+exp(x[i])))) / x:nElement()
where i == 1
to x:nElement()
, y[i] in {0,1}
.
Note that this criterion also works with 2D inputs and targets.
y
and x
must have the same size.
criterion = nn.MSECriterion()
Creates a criterion that measures the mean squared error between n
elements in the input x
and output y
:
loss(x, y) = 1/n \sum |x_i - y_i|^2 .
If x
and y
are d
-dimensional Tensor
s with a total of n
elements, the sum operation still operates over all the elements, and divides by n
.
The two Tensor
s must have the same number of elements (but their sizes might be different).
The division by n
can be avoided if one sets the internal variable sizeAverage
to false
:
criterion = nn.MSECriterion()
criterion.sizeAverage = false
By default, the losses are averaged over observations for each minibatch. However, if the field sizeAverage
is set to false
, the losses are instead summed.
criterion = nn.SpatialAutoCropMSECriterion()
Creates a criterion that measures the mean squared error between the input and target, even if the target is spatially larger than the input. It achieves this by center-cropping the target to the same spatial resolution as the input, the mean squared error is then calculated between the input and this cropped target.
If the input and cropped target tensors are d
-dimensional Tensor
s with a total of n
elements, the sum operation operates over all the elements, and divides by n
.
The division by n
can be avoided if one sets the internal variable sizeAverage
to false
:
criterion = nn.SpatialAutoCropMSECriterion()
criterion.sizeAverage = false
criterion = nn.MultiCriterion()
This returns a Criterion which is a weighted sum of other Criterion. Criterions are added using the method:
criterion:add(singleCriterion [, weight])
where weight
is a scalar (default 1). Each criterion is applied to the same input
and target
.
Example :
input = torch.rand(2,10)
target = torch.IntTensor{1,8}
nll = nn.ClassNLLCriterion()
nll2 = nn.CrossEntropyCriterion()
mc = nn.MultiCriterion():add(nll, 0.5):add(nll2)
output = mc:forward(input, target)
criterion = nn.ParallelCriterion([repeatTarget])
This returns a Criterion which is a weighted sum of other Criterion. Criterions are added using the method:
criterion:add(singleCriterion [, weight])
where weight
is a scalar (default 1). The criterion expects an input
and target
table.
Each criterion is applied to the commensurate input
and target
element in the tables.
However, if repeatTarget=true
, the target
is repeatedly presented to each criterion (with a different input
).
Example :
input = {torch.rand(2,10), torch.randn(2,10)}
target = {torch.IntTensor{1,8}, torch.randn(2,10)}
nll = nn.ClassNLLCriterion()
mse = nn.MSECriterion()
pc = nn.ParallelCriterion():add(nll, 0.5):add(mse)
output = pc:forward(input, target)
criterion = nn.SmoothL1Criterion()
Creates a criterion that can be thought of as a smooth version of the AbsCriterion
. It uses a squared term if the absolute element-wise error falls below 1. It is less sensitive to outliers than the MSECriterion
and in some cases prevents exploding gradients (e.g. see "Fast R-CNN" paper by Ross Girshick).
⎧ 0.5 * (x_i - y_i)^2, if |x_i - y_i| < 1
loss(x, y) = 1/n \sum ⎨
⎩ |x_i - y_i| - 0.5, otherwise
If x
and y
are d
-dimensional Tensor
s with a total of n
elements, the sum operation still operates over all the elements, and divides by n
.
The division by n
can be avoided if one sets the internal variable sizeAverage
to false
:
criterion = nn.SmoothL1Criterion()
criterion.sizeAverage = false
By default, the losses are averaged over observations for each minibatch. However, if the field sizeAverage
is set to false
, the losses are instead summed.
criterion = nn.HingeEmbeddingCriterion([margin])
Creates a criterion that measures the loss given an input x
which is a 1-dimensional vector and a label y
(1
or -1
).
This is usually used for measuring whether two inputs are similar or dissimilar, e.g. using the L1 pairwise distance, and is typically used for learning nonlinear embeddings or semi-supervised learning.
⎧ x_i, if y_i == 1
loss(x, y) = 1/n ⎨
⎩ max(0, margin - x_i), if y_i == -1
If x
and y
are n
-dimensional Tensor
s, the sum operation still operates over all the elements, and divides by n
(this can be avoided if one sets the internal variable sizeAverage
to false
). The margin
has a default value of 1
, or can be set in the constructor.
-- imagine we have one network we are interested in, it is called "p1_mlp"
p1_mlp = nn.Sequential(); p1_mlp:add(nn.Linear(5, 2))
-- But we want to push examples towards or away from each other so we make another copy
-- of it called p2_mlp; this *shares* the same weights via the set command, but has its
-- own set of temporary gradient storage that's why we create it again (so that the gradients
-- of the pair don't wipe each other)
p2_mlp = nn.Sequential(); p2_mlp:add(nn.Linear(5, 2))
p2_mlp:get(1).weight:set(p1_mlp:get(1).weight)
p2_mlp:get(1).bias:set(p1_mlp:get(1).bias)
-- we make a parallel table that takes a pair of examples as input.
-- They both go through the same (cloned) mlp
prl = nn.ParallelTable()
prl:add(p1_mlp)
prl:add(p2_mlp)
-- now we define our top level network that takes this parallel table
-- and computes the pairwise distance betweem the pair of outputs
mlp = nn.Sequential()
mlp:add(prl)
mlp:add(nn.PairwiseDistance(1))
-- and a criterion for pushing together or pulling apart pairs
crit = nn.HingeEmbeddingCriterion(1)
-- lets make two example vectors
x = torch.rand(5)
y = torch.rand(5)
-- Use a typical generic gradient update function
function gradUpdate(mlp, x, y, criterion, learningRate)
local pred = mlp:forward(x)
local err = criterion:forward(pred, y)
local gradCriterion = criterion:backward(pred, y)
mlp:zeroGradParameters()
mlp:backward(x, gradCriterion)
mlp:updateParameters(learningRate)
end
-- push the pair x and y together, notice how then the distance between them given
-- by print(mlp:forward({x, y})[1]) gets smaller
for i = 1, 10 do
gradUpdate(mlp, {x, y}, 1, crit, 0.01)
print(mlp:forward({x, y})[1])
end
-- pull apart the pair x and y, notice how then the distance between them given
-- by print(mlp:forward({x, y})[1]) gets larger
for i = 1, 10 do
gradUpdate(mlp, {x, y}, -1, crit, 0.01)
print(mlp:forward({x, y})[1])
end
By default, the losses are averaged over observations for each minibatch. However, if the field sizeAverage
is set to false
, the losses are instead summed.
criterion = nn.L1HingeEmbeddingCriterion([margin])
Creates a criterion that measures the loss given an input x
= {x1, x2}
, a table of two Tensor
s, and a label y
(1
or -1
): this is used for measuring whether two inputs are similar or dissimilar, using the L1 distance, and is typically used for learning nonlinear embeddings or semi-supervised learning.
⎧ ||x1 - x2||_1, if y == 1
loss(x, y) = ⎨
⎩ max(0, margin - ||x1 - x2||_1), if y == -1
The margin
has a default value of 1
, or can be set in the constructor.
criterion = nn.CosineEmbeddingCriterion([margin])
Creates a criterion that measures the loss given an input x
= {x1, x2}
, a table of two Tensor
s, and a Tensor
label y
with values 1 or -1.
This is used for measuring whether two inputs are similar or dissimilar, using the cosine distance, and is typically used for learning nonlinear embeddings or semi-supervised learning.
margin
should be a number from -1
to 1
, 0
to 0.5
is suggested.
Forward
and Backward
have to be used alternately. If margin
is missing, the default value is 0
.
The loss function for each sample is:
⎧ 1 - cos(x1, x2), if y == 1
loss(x, y) = ⎨
⎩ max(0, cos(x1, x2) - margin), if y == -1
For batched inputs, if the internal variable sizeAverage
is equal to true
, the loss function averages the loss over the batch samples; if sizeAverage
is false
, then the loss function sums over the batch samples. By default, sizeAverage
equals to true
.
By default, the losses are averaged over observations for each minibatch. However, if the field sizeAverage
is set to false
, the losses are instead summed.
Ref A. Unsupervised Learning through Spatial Contrasting
criterion = nn.DistanceRatioCriterion(sizeAverage)
This criterion is probabilistic treatment of margin cost. The model is trained using sample triplets {Xs, Xa, Xd}
where Xa
is anchor sample, Xs
is sample similar to anchor sample and Xd
is a sample not similar to anchor sample. Let Ds
be distance between embeddings of {Xs, Xa}
and Dd
be distance between embeddings of {Xa, Xd}
then the loss is defined as follow
loss = -log( exp(-Ds) / ( exp(-Ds) + exp(-Dd) ) )
Sample example
torch.setdefaulttensortype("torch.FloatTensor")
require 'nn'
-- triplet : with batchSize of 32 and dimensionality 512
sample = {torch.rand(32, 512), torch.rand(32, 512), torch.rand(32, 512)}
embeddingModel = nn.Sequential()
embeddingModel:add(nn.Linear(512, 96)):add(nn.ReLU())
tripleModel = nn.ParallelTable()
tripleModel:add(embeddingModel)
tripleModel:add(embeddingModel:clone('weight', 'bias',
'gradWeight', 'gradBias'))
tripleModel:add(embeddingModel:clone('weight', 'bias',
'gradWeight', 'gradBias'))
-- Similar sample distance w.r.t anchor sample
posDistModel = nn.Sequential()
posDistModel:add(nn.NarrowTable(1,2)):add(nn.PairwiseDistance())
-- Different sample distance w.r.t anchor sample
negDistModel = nn.Sequential()
negDistModel:add(nn.NarrowTable(2,2)):add(nn.PairwiseDistance())
distanceModel = nn.ConcatTable():add(posDistModel):add(negDistModel)
-- Complete Model
model = nn.Sequential():add(tripleModel):add(distanceModel)
-- DistanceRatioCriterion
criterion = nn.DistanceRatioCriterion(true)
-- Forward & Backward
output = model:forward(sample)
loss = criterion:forward(output)
dLoss = criterion:backward(output)
model:backward(sample, dLoss)
criterion = nn.MarginRankingCriterion(margin)
Creates a criterion that measures the loss given an input x
= {x1, x2}
, a table of two Tensor
s of size 1 (they contain only scalars), and a label y
(1
or -1
).
In batch mode, x
is a table of two Tensor
s of size batchsize
, and y
is a Tensor
of size batchsize
containing 1
or -1
for each corresponding pair of elements in the input Tensor
.
If y == 1
then it assumed the first input should be ranked higher (have a larger value) than the second input, and vice-versa for y == -1
.
The loss function is:
loss(x, y) = max(0, -y * (x[1] - x[2]) + margin)
For batched inputs, if the internal variable sizeAverage
is equal to true
, the loss function averages the loss over the batch samples; if sizeAverage
is false
, then the loss function sums over the batch samples. By default, sizeAverage
equals to true
.
By default, the losses are averaged over observations for each minibatch. However, if the field sizeAverage
is set to false
, the losses are instead summed.
p1_mlp = nn.Linear(5, 2)
p2_mlp = p1_mlp:clone('weight', 'bias')
prl = nn.ParallelTable()
prl:add(p1_mlp)
prl:add(p2_mlp)
mlp1 = nn.Sequential()
mlp1:add(prl)
mlp1:add(nn.DotProduct())
mlp2 = mlp1:clone('weight', 'bias')
mlpa = nn.Sequential()
prla = nn.ParallelTable()
prla:add(mlp1)
prla:add(mlp2)
mlpa:add(prla)
crit = nn.MarginRankingCriterion(0.1)
x=torch.randn(5)
y=torch.randn(5)
z=torch.randn(5)
-- Use a typical generic gradient update function
function gradUpdate(mlp, x, y, criterion, learningRate)
local pred = mlp:forward(x)
local err = criterion:forward(pred, y)
local gradCriterion = criterion:backward(pred, y)
mlp:zeroGradParameters()
mlp:backward(x, gradCriterion)
mlp:updateParameters(learningRate)
end
for i = 1, 100 do
gradUpdate(mlpa, {{x, y}, {x, z}}, 1, crit, 0.01)
if true then
o1 = mlp1:forward{x, y}[1]
o2 = mlp2:forward{x, z}[1]
o = crit:forward(mlpa:forward{{x, y}, {x, z}}, 1)
print(o1, o2, o)
end
end
print "--"
for i = 1, 100 do
gradUpdate(mlpa, {{x, y}, {x, z}}, -1, crit, 0.01)
if true then
o1 = mlp1:forward{x, y}[1]
o2 = mlp2:forward{x, z}[1]
o = crit:forward(mlpa:forward{{x, y}, {x, z}}, -1)
print(o1, o2, o)
end
end
criterion = nn.ModuleCriterion(criterion [, inputModule, targetModule, castTarget])
This criterion decorates a criterion
by allowing the input
and target
to be
fed through an optional inputModule
and targetModule
before being passed to the
criterion
. The inputModule
must not contain parameters as these would not be updated.
When castTarget = true
(the default), the targetModule
is cast along with the inputModule
and
criterion
. Otherwise, the targetModule
isn't.