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MV.lua
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MV.lua
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--[[ Module to perform matrix vector multiplication on two minibatch inputs,
producing a minibatch.
]]
local MV, parent = torch.class('nn.MV', 'nn.Module')
-- Backward compatibility
local unpack = unpack or table.unpack
function MV:__init(trans)
parent.__init(self)
self.trans = trans or false
assert(type(self.trans) == 'boolean', "argument must be a boolean, matrix transpose before multiplication")
self.gradInput = {torch.Tensor(), torch.Tensor()}
end
function MV:updateOutput(input)
assert(#input == 2, 'input must be a pair of minibatch matrices')
local M, v = unpack(input)
assert(M:nDimension() == 2 or M:nDimension() == 3, 'input matrix must be 2D or 3D')
assert(v:nDimension() == 1 or v:nDimension() == 2, 'input vector must be 1D or 2D')
if M:nDimension() == 2 then
assert(v:nDimension() == 1, 'vector must be 1D')
if self.trans then M = M:transpose(1,2) end
assert(M:size(2) == v:size(1), 'matrix row count and vector length do not match')
self.output:resize(M:size(1))
self.output:mv(M, v)
else
assert(v:nDimension() == 2, 'vector must be 2D (batch dimension)')
assert(M:size(1) == v:size(1), 'inputs must contain the same number of minibatches')
if self.trans then M = M:transpose(2,3) end
assert(M:size(3) == v:size(2), 'matrix row count and vector length do not match')
self.output:resize(M:size(1), M:size(2), 1)
self.output:bmm(M, v:view(v:size(1), v:size(2), 1)):resize(M:size(1), M:size(2))
end
return self.output
end
function MV:updateGradInput(input, gradOutput)
assert(#input == 2, 'input must be a pair of tensors')
local M, v = unpack(input)
self.gradInput[1]:resizeAs(M)
self.gradInput[2]:resizeAs(v)
assert(gradOutput:nDimension() == 1 or gradOutput:nDimension() == 2, 'arguments must be a 1D or 2D Tensor')
if gradOutput:nDimension() == 2 then
assert(M:nDimension() == 3, 'matrix must must be 3D (batched)')
assert(v:nDimension() == 2, 'vector must be 2D (batched)')
local bdim = M:size(1)
local odim = M:size(2)
local idim = M:size(3)
if self.trans then
self.gradInput[1]:bmm(v:view(bdim, odim, 1), gradOutput:view(bdim, 1, idim))
self.gradInput[2]:view(bdim, odim, 1):bmm(M, gradOutput:view(bdim, idim, 1))
else
self.gradInput[1]:bmm(gradOutput:view(bdim, odim, 1), v:view(bdim, 1, idim))
self.gradInput[2]:view(bdim, idim, 1):bmm(M:transpose(2,3), gradOutput:view(bdim, odim, 1))
end
else
assert(M:nDimension() == 2, 'matrix must be 2D')
assert(v:nDimension() == 1, 'vector must be 1D')
if self.trans then
self.gradInput[1]:ger(v, gradOutput)
self.gradInput[2] = M * gradOutput
else
self.gradInput[1]:ger(gradOutput, v)
self.gradInput[2] = M:t() * gradOutput
end
end
return self.gradInput
end