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ConvolutionTBC.cpp
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ConvolutionTBC.cpp
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#include "ATen/ATen.h"
#include "ATen/NativeFunctions.h"
#include <tuple>
namespace at {
namespace native {
Tensor conv_tbc(const Tensor& self, const Tensor& weight, const Tensor& bias, int64_t pad) {
AT_CHECK(self.dim() == 3, "Input must have 3 dims: time, batch, "
"in_channel");
AT_CHECK(weight.dim() == 3, "Weight tensor must have 3 dims: kernel_width,"
" in_channels, out_channels.");
AT_CHECK(bias.dim() == 1, "Bias must be 1-D");
auto input_size = self.sizes();
auto weight_size = weight.sizes();
auto ilen = input_size[0];
auto batchSize = input_size[1];
auto inputPlanes = input_size[2];
auto outputPlanes = weight_size[2];
auto kw = weight_size[0];
auto olen = input_size[0] - kw + 1 + pad * 2;
auto real_pad = (olen - ilen + kw - 1) / 2;
// Make sure shapes are correct.
// Input = (time, batch, in_channels)
// Weight = (kernel_width, in_channels, out_channels)
// Bias = (out_channels)
AT_CHECK(inputPlanes == weight_size[1], "Input dim 2 (input channels) "
"is not == dim 1 in the weight tensor");
AT_CHECK(weight_size[2] == bias.sizes()[0], "Bias size must equal dim 2 in "
"the weight tensor (output channels).");
// input * weights + bias -> output_features
Tensor output = at::empty({
olen,
input_size[1],
weight_size[2],
}, self.options());
output.copy_(bias.expand(output.sizes()));
for (int k = 0; k < kw; k++) {
int iShift = std::max(0, static_cast<int>(k - real_pad));
int oShift = std::max(0, static_cast<int>(real_pad - k));
int t = std::min(ilen + real_pad - k, olen) - oShift;
// Note: gemm assumes column-major matrices
// input is l*m (row-major)
// weight is m*r (row-major)
// output is l*r (row-major)
if (t > 0) {
auto W = weight[k];
auto I = self.narrow(0, iShift, t).view({t * batchSize, inputPlanes});
auto O = output.narrow(0, oShift, t).view({t * batchSize, outputPlanes});
O.addmm_(I, W);
}
}
return output;
}
std::tuple<Tensor, Tensor, Tensor> conv_tbc_backward(const Tensor& dOutput, const Tensor& input, const Tensor& weight, const Tensor& bias, int64_t pad) {
auto input_size = input.sizes();
auto weight_size = weight.sizes();
auto ilen = input_size[0];
auto batchSize = input_size[1];
auto inputPlanes = input_size[2];
auto outputPlanes = weight_size[2];
auto kw = weight.sizes()[0];
auto olen = input_size[0] - kw + 1 + pad * 2;
int real_pad = (olen - ilen + kw - 1) / 2;
Tensor dInput = at::zeros_like(input);
for (int k = 0; k < kw; k++) {
int iShift = std::max(0, k - real_pad);
int oShift = std::max(0, real_pad - k);
int t = std::min(ilen + real_pad - k, olen) - oShift;
// dOutput * T(weight) -> dInput
if (t > 0) {
auto dO = dOutput.narrow(0, oShift, t).view({t * batchSize, outputPlanes});
auto dI = dInput.narrow(0, iShift, t).view({t * batchSize, inputPlanes});
dI.addmm_(dO, weight[k].t());
}
}
Tensor dWeight = at::zeros_like(weight);
for (int k = 0; k < kw; k++) {
int iShift = std::max(0, k - real_pad);
int oShift = std::max(0, real_pad - k);
int t = std::min(ilen + real_pad - k, olen) - oShift;
// T(input) * dOutput -> dWeight
if (t > 0) {
auto dW = dWeight[k];
auto dO = dOutput.narrow(0, oShift, t).view({t * batchSize, outputPlanes});
auto I = input.narrow(0, iShift, t).view({t * batchSize, inputPlanes}).t();
dW.addmm_(I, dO);
}
}
Tensor dBias = at::zeros_like(bias);
auto tmp = dOutput.sum(0, false);
dBias.copy_(tmp.sum(0));
return std::make_tuple(dInput, dWeight, dBias);
}
}
}