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FastLSTM.lua
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FastLSTM.lua
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------------------------------------------------------------------------
--[[ LSTM ]]--
-- Long Short Term Memory architecture.
-- Ref. A.: http://arxiv.org/pdf/1303.5778v1 (blueprint for this module)
-- B. http://web.eecs.utk.edu/~itamar/courses/ECE-692/Bobby_paper1.pdf
-- C. http://arxiv.org/pdf/1503.04069v1.pdf
-- D. https://github.com/wojzaremba/lstm
-- Expects 1D or 2D input.
-- The first input in sequence uses zero value for cell and hidden state
-- For p > 0, it becomes Bayesian GRUs [Gal, 2015].
-- In this case, please do not dropout on input as BGRUs handle the input with
-- its own dropouts. First, try 0.25 for p as Gal (2016) suggested,
-- presumably, because of summations of two parts in GRUs connections.
------------------------------------------------------------------------
local FastLSTM, parent = torch.class("nn.FastLSTM", "nn.LSTM")
-- set this to true to have it use nngraph instead of nn
-- setting this to true can make your next FastLSTM significantly faster
FastLSTM.usenngraph = false
FastLSTM.bn = false
function FastLSTM:__init(inputSize, outputSize, rho, eps, momentum, affine, p, mono)
-- when FastLSTM.bn=true, the default values of eps and momentum are set by nn.BatchNormalization
self.eps = eps
self.momentum = momentum
self.affine = affine == nil and true or affine
self.p = p or 0
if p and p ~= 0 then
assert(nn.Dropout(p,false,false,true).lazy, 'only work with Lazy Dropout!')
end
self.mono = mono or false
parent.__init(self, inputSize, outputSize, rho, nil, p, mono)
end
function FastLSTM:buildModel()
-- input : {input, prevOutput, prevCell}
-- output : {output, cell}
-- Calculate all four gates in one go : input, hidden, forget, output
if self.p ~= 0 then
self.i2g = nn.Sequential()
:add(nn.ConcatTable()
:add(nn.Dropout(self.p,false,false,true,self.mono))
:add(nn.Dropout(self.p,false,false,true,self.mono))
:add(nn.Dropout(self.p,false,false,true,self.mono))
:add(nn.Dropout(self.p,false,false,true,self.mono)))
:add(nn.ParallelTable()
:add(nn.Linear(self.inputSize, self.outputSize))
:add(nn.Linear(self.inputSize, self.outputSize))
:add(nn.Linear(self.inputSize, self.outputSize))
:add(nn.Linear(self.inputSize, self.outputSize)))
:add(nn.JoinTable(2))
self.o2g = nn.Sequential()
:add(nn.ConcatTable()
:add(nn.Dropout(self.p,false,false,true,self.mono))
:add(nn.Dropout(self.p,false,false,true,self.mono))
:add(nn.Dropout(self.p,false,false,true,self.mono))
:add(nn.Dropout(self.p,false,false,true,self.mono)))
:add(nn.ParallelTable()
:add(nn.LinearNoBias(self.outputSize, self.outputSize))
:add(nn.LinearNoBias(self.outputSize, self.outputSize))
:add(nn.LinearNoBias(self.outputSize, self.outputSize))
:add(nn.LinearNoBias(self.outputSize, self.outputSize)))
:add(nn.JoinTable(2))
else
self.i2g = nn.Linear(self.inputSize, 4*self.outputSize)
self.o2g = nn.LinearNoBias(self.outputSize, 4*self.outputSize)
end
if self.usenngraph or self.bn then
require 'nngraph'
return self:nngraphModel()
end
local para = nn.ParallelTable():add(self.i2g):add(self.o2g)
local gates = nn.Sequential()
gates:add(nn.NarrowTable(1,2))
gates:add(para)
gates:add(nn.CAddTable())
-- Reshape to (batch_size, n_gates, hid_size)
-- Then slize the n_gates dimension, i.e dimension 2
gates:add(nn.Reshape(4,self.outputSize))
gates:add(nn.SplitTable(1,2))
local transfer = nn.ParallelTable()
transfer:add(nn.Sigmoid()):add(nn.Tanh()):add(nn.Sigmoid()):add(nn.Sigmoid())
gates:add(transfer)
local concat = nn.ConcatTable()
concat:add(gates):add(nn.SelectTable(3))
local seq = nn.Sequential()
seq:add(concat)
seq:add(nn.FlattenTable()) -- input, hidden, forget, output, cell
-- input gate * hidden state
local hidden = nn.Sequential()
hidden:add(nn.NarrowTable(1,2))
hidden:add(nn.CMulTable())
-- forget gate * cell
local cell = nn.Sequential()
local concat = nn.ConcatTable()
concat:add(nn.SelectTable(3)):add(nn.SelectTable(5))
cell:add(concat)
cell:add(nn.CMulTable())
local nextCell = nn.Sequential()
local concat = nn.ConcatTable()
concat:add(hidden):add(cell)
nextCell:add(concat)
nextCell:add(nn.CAddTable())
local concat = nn.ConcatTable()
concat:add(nextCell):add(nn.SelectTable(4))
seq:add(concat)
seq:add(nn.FlattenTable()) -- nextCell, outputGate
local cellAct = nn.Sequential()
cellAct:add(nn.SelectTable(1))
cellAct:add(nn.Tanh())
local concat = nn.ConcatTable()
concat:add(cellAct):add(nn.SelectTable(2))
local output = nn.Sequential()
output:add(concat)
output:add(nn.CMulTable())
local concat = nn.ConcatTable()
concat:add(output):add(nn.SelectTable(1))
seq:add(concat)
return seq
end
function FastLSTM:nngraphModel()
assert(nngraph, "Missing nngraph package")
local inputs = {}
table.insert(inputs, nn.Identity()()) -- x
table.insert(inputs, nn.Identity()()) -- prev_h[L]
table.insert(inputs, nn.Identity()()) -- prev_c[L]
local x, prev_h, prev_c = unpack(inputs)
local bn_wx, bn_wh, bn_c
local i2h, h2h
if self.bn then
-- apply recurrent batch normalization
-- http://arxiv.org/pdf/1502.03167v3.pdf
-- normalize recurrent terms W_h*h_{t-1} and W_x*x_t separately
-- Olalekan Ogunmolu <[email protected]>
bn_wx = nn.BatchNormalization(4*self.outputSize, self.eps, self.momentum, self.affine)
bn_wh = nn.BatchNormalization(4*self.outputSize, self.eps, self.momentum, self.affine)
bn_c = nn.BatchNormalization(self.outputSize, self.eps, self.momentum, self.affine)
-- initialize gamma (the weight) to the recommended value
-- (https://github.com/torch/nn/blob/master/lib/THNN/generic/BatchNormalization.c#L61)
bn_wx.weight:fill(0.1)
bn_wh.weight:fill(0.1)
bn_c.weight:fill(0.1)
-- evaluate the input sums at once for efficiency
i2h = bn_wx(self.i2g(x):annotate{name='i2h'}):annotate {name='bn_wx'}
h2h = bn_wh(self.o2g(prev_h):annotate{name='h2h'}):annotate {name = 'bn_wh'}
-- add bias after BN as per paper
h2h = nn.Add(4*self.outputSize)(h2h)
else
-- evaluate the input sums at once for efficiency
i2h = self.i2g(x):annotate{name='i2h'}
h2h = self.o2g(prev_h):annotate{name='h2h'}
end
local all_input_sums = nn.CAddTable()({i2h, h2h})
local reshaped = nn.Reshape(4, self.outputSize)(all_input_sums)
-- input, hidden, forget, output
local n1, n2, n3, n4 = nn.SplitTable(2)(reshaped):split(4)
local in_gate = nn.Sigmoid()(n1)
local in_transform = nn.Tanh()(n2)
local forget_gate = nn.Sigmoid()(n3)
local out_gate = nn.Sigmoid()(n4)
-- perform the LSTM update
local next_c = nn.CAddTable()({
nn.CMulTable()({forget_gate, prev_c}),
nn.CMulTable()({in_gate, in_transform})
})
local next_h
if self.bn then
-- gated cells form the output
next_h = nn.CMulTable()({out_gate, nn.Tanh()(bn_c(next_c):annotate {name = 'bn_c'}) })
else
-- gated cells form the output
next_h = nn.CMulTable()({out_gate, nn.Tanh()(next_c)})
end
local outputs = {next_h, next_c}
nngraph.annotateNodes()
return nn.gModule(inputs, outputs)
end
function FastLSTM:buildGate()
error"Not Implemented"
end
function FastLSTM:buildInputGate()
error"Not Implemented"
end
function FastLSTM:buildForgetGate()
error"Not Implemented"
end
function FastLSTM:buildHidden()
error"Not Implemented"
end
function FastLSTM:buildCell()
error"Not Implemented"
end
function FastLSTM:buildOutputGate()
error"Not Implemented"
end