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IndexLinear.lua
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IndexLinear.lua
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local ffi = require 'ffi'
local IndexLinear, parent = torch.class('nn.IndexLinear', 'nn.Module')
function IndexLinear:__init(inputSize, outputSize, doGradInput, keysOffset, weight, bias, normalize)
parent.__init(self)
-- We need for 3 extra parameters per feature
-- if we normalize:
-- * The max-abs value
-- * The inverse of the max-abs value
-- * The per-feature bias
-- We keep an extra placeholder for further per learning rate feature manipulation.
-- So it's 4 total.
self.normalize = normalize and 4 or 0
-- This is important to keep the possibility of sharing a weight
-- directly, without having to allocate it first.
-- The reason is these weights can be very large.
self.weight = weight or torch.Tensor(inputSize, outputSize + self.normalize):zero()
self.bias = bias or torch.Tensor(outputSize):zero()
self.inputSize = self.weight and self.weight:size(1) or inputSize
self.outputSize = self.weight and (self.weight:size(2)-self.normalize) or outputSize
-- gradWeight is not initialized as we're doing dense gradient accumulation
-- This is more efficient and avoids allocating a giant useless gradWeight
self.gradWeight = torch.Tensor()
-- gradBias still works the same as it's already dense
self.gradBias = torch.Tensor(self.outputSize):zero()
-- Buffers
self.gradWeightBuffer = torch.Tensor()
self.valuesBuffer = torch.Tensor()
self.normalizedValues = torch.Tensor()
-- That is used to accumulate keys and gradWeight
-- when doing gradients accumulations
self.running = {
cumSumSizes = {},
keys = {},
gradWeight = {},
counter = 1,
}
-- self.sizes, self.cumSumSizes are calculated on the CPU even when using CUDA.
-- These two tables make it easier to resize these buffers instead of re-allocating them.
-- self.*Cache[1] always contains values on CPU.
-- If CUDA is being used, self.*Cache[2] contains values on GPU.
self.sizesCache = {}
self.cumSumSizesCache = {}
-- A few options
self.weightDecay = 0
self.doGradInput = doGradInput or false
self.offset = keysOffset and keysOffset-1 or -1 -- if this adds self.offset to indices
end
-- Reset all the parameters needed
-- for normalization to 0
function IndexLinear:reset(stdv)
if stdv then
stdv = stdv * math.sqrt(3)
else
stdv = 1./math.sqrt(self.weight:size(2))
end
self.weight:uniform(-stdv, stdv)
self.bias:uniform(-stdv, stdv):mul(0.000001)
if self.normalize and self.normalize > 0 then
self.weight[{{}, {1,self.normalize}}]:zero()
end
end
function IndexLinear:reshapeInput(input)
assert(torch.type(input) == 'table')
local ninputs = 0
for _, v in ipairs(input) do
ninputs = ninputs + 1
end
assert(ninputs == 2 or ninputs == 3)
-- If format is:
-- {
-- torch.LongTensor(size1+size2+...+sizeN), -- concatenated batch of keys
-- torch.Tensor(size1+size2+...+sizeN), -- concatenated batch of values
-- torch.LongTensor(N), -- keys/values sizes (values are {size1, ..., sizeN})
-- }
if ninputs == 3 then
local fkeys = input[1]
local fvals = input[2]
local fsizes = torch.isTensor(input[3]) and input[3] or fkeys.new{input[3]}
assert(fkeys:nElement() == fvals:nElement(), 'Keys and values should be of same size')
assert(fkeys:dim() == 1, 'Keys and values should be 1D')
self.isFlat = true
self.noBatch = false
return fkeys, fvals, fsizes
end
local keys = input[1]
local values = input[2]
local lkeys, lvalues
-- If format is:
-- {
-- { torch.LongTensor(size1), torch.LongTensor(size2), ..., torch.LongTensor(sizeN) }, -- batch of keys
-- { torch.Tensor(size1), torch.Tensor(size2), ..., torch.Tensor(sizeN) }, -- batch of values,
-- }
if torch.type(keys) == 'table' and torch.type(values) == 'table' then
lkeys, lvalues = keys, values
self.isFlat = false
self.noBatch = false
-- If format is not a batch:
-- {
-- torch.LongTensor(size1), -- keys
-- torch.Tensor(size1), -- values,
-- }
elseif torch.isTensor(keys) and torch.isTensor(values) then
lkeys, lvalues = {keys}, {values}
self.isFlat = false
self.noBatch = true
else
error('Wrong input format.')
end
for i=1,#lkeys do
assert(lvalues[i]:dim() == 1 and lkeys[i]:dim() == 1, "keys and values should be 1D")
end
return lkeys, lvalues
end
function IndexLinear:longTensor(...)
if (self:type() == 'torch.CudaTensor') then
return torch.CudaLongTensor(...)
else
return torch.LongTensor(...)
end
end
function IndexLinear:flattenInputs(input)
local lkeys, lvalues, sizes = self:reshapeInput(input)
local counter = self.running.counter
-- Ensure everything is of the right type
local isCuda = (self:type() == 'torch.CudaTensor')
self.running.keys[counter] = self.running.keys[counter] or self:longTensor()
self.keys = self.running.keys[counter]
if self.isFlat then
self.values = self.values or lvalues.new()
self.sizes = self.sizes or self:longTensor()
self.keys:resize(lkeys:size()):copy(lkeys)
self.values:resize(lvalues:size()):copy(lvalues)
self.sizes = sizes
self.cumSumSizes = self.cumSumSizes or self.sizes.new()
self.cumSumSizes:cumsum(self.sizes)
else
self.values = self.values or lvalues[1].new()
self.lkeys = lkeys
self.lvalues = lvalues
local batchSize = #self.lkeys
self.sizesCache[1] = self.sizesCache[1] or torch.LongTensor(batchSize)
self.cumSumSizesCache[1] = self.cumSumSizesCache[1] or torch.LongTensor(batchSize)
self.sizes = self.sizesCache[1]
self.cumSumSizes = self.cumSumSizesCache[1]
self.sizes:resize(batchSize)
self.cumSumSizes:resize(batchSize)
for i = 1,batchSize do
self.sizes[i] = self.lkeys[i]:size(1)
end
self.cumSumSizes:cumsum(self.sizes)
self.keys:cat(self.lkeys, 1)
self.values:cat(self.lvalues, 1)
if isCuda then
-- Get the GPU cache
self.sizesCache[2] = self.sizesCache[2] or torch.CudaLongTensor()
self.cumSumSizesCache[2] = self.cumSumSizesCache[2] or torch.CudaLongTensor()
self.sizes = self.sizesCache[2]
self.cumSumSizes = self.cumSumSizesCache[2]
-- Resize and copy to GPU
self.sizes:resize(batchSize):copy(self.sizesCache[1])
self.cumSumSizes:resize(batchSize):copy(self.cumSumSizesCache[1])
end
end
self.running.cumSumSizes[counter] = self.cumSumSizes
end
function IndexLinear:updateOutput(input)
self:flattenInputs(input)
self.values.THNN.IndexLinear_updateOutput(
self.keys:cdata(),
self.offset,
self.values:cdata(),
self.sizes:cdata(),
self.cumSumSizes:cdata(),
self.output:cdata(),
self.weight:cdata(),
self.bias:cdata(),
self.normalizedValues:cdata(),
self.train and 1 or 0
)
if self.noBatch then
self.output:resize(self.output:size(2))
end
return self.output
end
function IndexLinear:accUpdateGradParameters(input, gradOutput, scale)
self.values.THNN.IndexLinear_accUpdateGradParameters(
self.keys:cdata(),
self.offset,
self.normalize > 0 and self.normalizedValues:cdata() or self.values:cdata(),
self.sizes:cdata(),
self.cumSumSizes:cdata(),
gradOutput:cdata(),
self.weight:cdata(),
self.bias:cdata(),
self.weightDecay or 0,
scale or 1
)
end
function IndexLinear:accGradParameters(input, gradOutput, scale)
local counter = self.running.counter
-- Same as the running.keys in the updateOutput function,
-- get a table of dense running.gradWeight
self.running.gradWeight[counter] = self.running.gradWeight[counter] or self.values.new()
self.values.THNN.IndexLinear_accGradParameters(
self.keys:cdata(),
self.offset,
self.normalize > 0 and self.normalizedValues:cdata() or self.values:cdata(),
self.sizes:cdata(),
self.cumSumSizes:cdata(),
gradOutput:cdata(),
self.running.gradWeight[counter]:cdata(),
self.gradBias:cdata(),
self.weight:cdata(),
self.bias:cdata(),
self.valuesBuffer:cdata(),
self.weightDecay or 0,
scale or 1
)
-- Increment the running counter to create a new buffer
-- if we don't flush them in zerogradParamters
self.running.counter = self.running.counter + 1
end
function IndexLinear:updateGradInput(input, gradOutput)
self.gradInput = {}
-- Revamped from nn.SparseLinear.updateGradInput
if self.doGradInput and self.normalize > 0 then
error('updateGradInput is not implemented in max-normalize mode')
end
local ini = self.weight:size(1)
if self.doGradInput then
local gi = gradOutput.new()
if gradOutput:dim() == 1 then
gi:resize(self.weight:size(1))
gi:mv(self.weight,gradOutput)
gi:resize(1, self.weight:size(1))
elseif gradOutput:dim() == 2 then
gi:resize(gradOutput:size(1), self.weight:size(1))
gi:mm(gradOutput, self.weight:t())
end
local indices = self.running.keys[1].new(ini):range(1, ini)
if self.isFlat then
self.gradInput[1] = torch.repeatTensor(indices, gi:size(1), 1)
self.gradInput[2] = gi
else
self.gradInput[1] = {}
self.gradInput[2] = {}
for i = 1,gi:size(1) do
self.gradInput[1][i] = self.running.keys[1].new(ini)
self.gradInput[1][i]:copy(indices)
self.gradInput[2][i] = gradOutput.new(ini)
self.gradInput[2][i]:copy(gi[i])
end
end
end
if self.noBatch then
if self.isFlat then
self.gradInput = {self.gradInput[1]:resize(ini), self.gradInput[2]:resize(ini)}
else
self.gradInput = {self.gradInput[1][1], self.gradInput[2][1]}
end
end
return self.gradInput
end
function IndexLinear:updateParameters(lr)
local counter = self.running.counter
if counter > 1 then
if counter == 2 then
self.updateKeys = self.running.keys[1]
self.gradWeight = self.running.gradWeight[1]
else
self.updateKeysBuffer = self.updateKeysBuffer or self:longTensor()
local lkeys = {}
local lgweights = {}
local totalSize = 0
local lCumSumSizes = {}
for i=1,counter-1 do
lkeys[i] = self.running.keys[i]
-- Change layout to take advantage of the 1-D contiguous torch.cat
lgweights[i] = self.running.gradWeight[i]:contiguous()
lgweights[i]:resize(lgweights[i]:nElement())
lCumSumSizes[i] = totalSize + self.running.cumSumSizes[i]
totalSize = totalSize + lkeys[i]:size(1)
end
self.updateKeysBuffer:cat(lkeys, 1)
self.gradWeightBuffer:cat(lgweights, 1)
self.cumSumSizes:cat(lCumSumSizes, 1)
self.gradWeightBuffer:resize(totalSize, self.outputSize)
self.gradWeight = self.gradWeightBuffer
self.updateKeys = self.updateKeysBuffer
end
self.values.THNN.IndexLinear_updateParameters(
self.gradWeight:cdata(),
self.gradBias:cdata(),
self.weight:cdata(),
self.bias:cdata(),
self.updateKeys:cdata(),
self.cumSumSizes:cdata(),
self.offset,
self.weightDecay or 0,
lr or error('You must specify a learning rate')
)
end
end
function IndexLinear:zeroGradParameters()
-- No need to do anything here as gradWeight is dense
self.gradBias:zero()
-- The below piece of code would reset
-- the smart scaling parameters for each features
-- each time we call zeroGradParameters
-- TODO: decide what to do with that piece of code.
-- NB: this should be commented along with the corresponding
-- piece of code in lib/THNN/generic/IndexLinear.c, in the accUpdateGradParameters function.
--[[
local w = self.weight:select(2, 3)
if self.updateKeys and self.updateKeys:nElement() > 0 then
self.updateKeysBuffer:resizeAs(self.updateKeys):copy(self.updateKeys):add(self.offset+1)
w:indexFill(1, self.updateKeysBuffer, 0)
end
]]--
self.running.counter = 1
end
function IndexLinear:parameters()
return {self.weight, self.bias}, {self.running, self.gradBias}
end
function IndexLinear:clearState()
self.running.keys = {}
self.running.gradWeight = {}
self.keys = nil
self.zerokeys = nil
self.updateKeys = nil
self.values = nil
self.sizes = nil
self.lkeys = {}
self.lvalues = {}
self.gradWeightBuffer = self.gradWeightBuffer.new()
self.valuesBuffer = self.valuesBuffer.new()
self.updateKeysBuffer = nil
self.values = nil
return parent.clearState(self)
end