# Set k-largest elements of a tensor to zero in TensorFlow

I want to find k largest elements of each row of h and set zero value to those maximum elements.

I could be able to select the indexes of top most value of each row by using top_k function like:

``````top_k = tf.nn.top_k(h, 1)
``````

But I could not use the indexes returned by top_k to update tensor.

How can I do that? Thanks in advance...

This is a bit tricky, maybe there is a better solution. `tf.scatter_update()` doesn't work here because it can only modify parts of tensor along the first dimension (not an element in first row and second column for instance).

You have to get the `values` and `indices` from `tf.nn.top_k()` to create a sparse Tensor and subtract it to the initial Tensor `x`:

``````x = tf.constant([[6., 2., 0.], [0., 4., 5.]])  # of type tf.float32

k = 2
values, indices = tf.nn.top_k(x, k, sorted=False)  # indices will be [[0, 1], [1, 2]], values will be [[6., 2.], [4., 5.]]

# We need to create full indices like [[0, 0], [0, 1], [1, 2], [1, 1]]
my_range = tf.expand_dims(tf.range(0, indices.get_shape()[0]), 1)  # will be [[0], [1]]
my_range_repeated = tf.tile(my_range, [1, k])  # will be [[0, 0], [1, 1]]

# change shapes to [N, k, 1] and [N, k, 1], to concatenate into [N, k, 2]
full_indices = tf.concat([tf.expand_dims(my_range_repeated, 2), tf.expand_dims(indices, 2)], axis=2)
full_indices = tf.reshape(full_indices, [-1, 2])

to_substract = tf.sparse_to_dense(full_indices, x.get_shape(), tf.reshape(values, [-1]), default_value=0.)

res = x - to_substract  # res should be all 0.
``````
• My bad, I didn't read well enough the question. I will update my answer in a minute. Jun 2 '16 at 14:39
• Thank you Oliver, I got the idea. But when I tried it for k > 1, sparse_to_dense could not generate the tensor. I think, I need to play with tensorflow to be able to understand it. Numpy/tensorflow coding style gets difficult for me, because I have a Java mindset :-) Jun 3 '16 at 12:08
• Sorry for late response. Thanks it worked. I had to set validate_indices to false to disable checking indice orders. Oct 8 '16 at 14:31
• For unknown sizes, I had to change `indices.get_shape()[0]` to `tf.shape(indices)[0]`. Oct 22 '16 at 6:48
• Syntax of tf.concat has changed. So in the code from the answer arguments should be flipped, or passed by name: `full_indices = tf.concat(axis=2, values=[tf.expand_dims(my_range_repeated, 2), tf.expand_dims(indices, 2)])`
– mc2
Nov 30 '17 at 12:19

I was facing the opposite problem and wanted a operation which supported gradients. `top_k` does not support gradient propagation and hence a good way will be to implement the function in c++.

`top_k` c++ code is found here.

Your operation's kernel will look look like this:

``````template <typename T>
class MakeSparseOp : public OpKernel {
public:
explicit MakeSparseOp(OpKernelConstruction *context) : OpKernel(context) {}

void Compute(OpKernelContext *context) override {
// Grab the input tensors
const auto &k_in = context->input(1);

OP_REQUIRES(context, TensorShapeUtils::IsScalar(k_in.shape()),
errors::InvalidArgument("k must be scalar, got shape ",
k_in.shape().DebugString()));

int k = k_in.scalar<int32>()();
OP_REQUIRES(context, k >= 0,
errors::InvalidArgument("Need k >= 0, got ", k));

const Tensor &x_in = context->input(0);
OP_REQUIRES(context, x_in.dims() >= 1,
errors::InvalidArgument("input must be >= 1-D, got shape ",
x_in.shape().DebugString()));
OP_REQUIRES(
context, x_in.dim_size(x_in.dims() - 1) >= k,
errors::InvalidArgument("input must have at least k columns"));

// Flattening the input tensor
const auto &x = x_in.flat_inner_dims<T>();

const auto num_rows = x.dimension(0);
const auto num_cols = x.dimension(1);

TensorShape output_shape = x_in.shape();

// Create an output tensor
Tensor *x_out = nullptr;
OP_REQUIRES_OK(context,
context->allocate_output(0, output_shape, &x_out));

/*
* Get the top k values along the first dimension for input
*/

auto x_sparse = x_out->flat_inner_dims<T>();

if (k == 0) return;  // Nothing to do

// Using TopN to get the k max element
gtl::TopN<std::pair<T, int32>> filter(k);

x_sparse = x; // Copy all elements

for (int r = 0; r < num_rows; r++) {
// Processing a row at a time
for (int32 c = 0; c < num_cols; c++) {
// The second element is the negated index, so that lower-index
// elements
// are considered larger than higher-index elements in case of
// ties.
filter.push(std::make_pair(x(r, c), -c));

}

for (auto top_k_it = filter.unsorted_begin();
top_k_it != filter.unsorted_end(); ++top_k_it) {
x_sparse(r, -top_k_it->second) = 0; // Set max k to zero
}

filter.Reset();
}
}
};
``````

My implementation for a related problem is here.

With recent availability of `scatter_nd_update` function in tensorflow, here is a modified version of the answer from Oliver.

``````k = 2
val_to_replace_with = -333
x = tf.Variable([[6., 2., 0.], [0., 4., 5.]])  # of type tf.float32

values, indices = tf.nn.top_k(x, k, sorted=False)  # indices will be [[0, 1], [1, 2]], values will be [[6., 2.], [4., 5.]]
# We need to create full indices like [[0, 0], [0, 1], [1, 2], [1, 1]]
my_range = tf.expand_dims(tf.range(0, tf.shape(indices)[0]), 1)  # will be [[0], [1]]
my_range_repeated = tf.tile(my_range, [1, k])  # will be [[0, 0], [1, 1]]
# change shapes to [N, k, 1] and [N, k, 1], to concatenate into [N, k, 2]
full_indices = tf.concat([tf.expand_dims(my_range_repeated, -1), tf.expand_dims(indices, -1)], axis=2)
full_indices = tf.reshape(full_indices, [-1, 2])

# only significant modification -----------------------------------------------------------------
updates = val_to_replace_with + tf.zeros([tf.size(indices)], dtype=tf.float32)