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Module.lua
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Module.lua
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local Module = torch.class('nn.Module')
function Module:__init()
self.gradInput = torch.Tensor()
self.output = torch.Tensor()
self._type = self.output:type()
end
function Module:parameters()
if self.weight and self.bias then
return {self.weight, self.bias}, {self.gradWeight, self.gradBias}
elseif self.weight then
return {self.weight}, {self.gradWeight}
elseif self.bias then
return {self.bias}, {self.gradBias}
else
return
end
end
function Module:updateOutput(input)
return self.output
end
function Module:forward(input)
return self:updateOutput(input)
end
function Module:backward(input, gradOutput, scale)
scale = scale or 1
self:updateGradInput(input, gradOutput)
self:accGradParameters(input, gradOutput, scale)
return self.gradInput
end
function Module:backwardUpdate(input, gradOutput, lr)
self:updateGradInput(input, gradOutput)
self:accUpdateGradParameters(input, gradOutput, lr)
return self.gradInput
end
function Module:updateGradInput(input, gradOutput)
return self.gradInput
end
function Module:accGradParameters(input, gradOutput, scale)
end
function Module:accUpdateGradParameters(input, gradOutput, lr)
local gradWeight = self.gradWeight
local gradBias = self.gradBias
self.gradWeight = self.weight
self.gradBias = self.bias
self:accGradParameters(input, gradOutput, -lr)
self.gradWeight = gradWeight
self.gradBias = gradBias
end
function Module:sharedAccUpdateGradParameters(input, gradOutput, lr)
if self:parameters() then
self:zeroGradParameters()
self:accGradParameters(input, gradOutput, 1)
self:updateParameters(lr)
end
end
function Module:zeroGradParameters()
local _,gradParams = self:parameters()
if gradParams then
for i=1,#gradParams do
gradParams[i]:zero()
end
end
end
function Module:updateParameters(learningRate)
local params, gradParams = self:parameters()
if params then
for i=1,#params do
params[i]:add(-learningRate, gradParams[i])
end
end
end
function Module:training()
self.train = true
end
function Module:evaluate()
self.train = false
end
function Module:share(mlp, ...)
local arg = {...}
for i,v in ipairs(arg) do
if self[v] ~= nil then
self[v]:set(mlp[v])
self.accUpdateGradParameters = self.sharedAccUpdateGradParameters
mlp.accUpdateGradParameters = mlp.sharedAccUpdateGradParameters
end
end
return self
end
function Module:clone(...)
local f = torch.MemoryFile("rw"):binary()
f:writeObject(self)
f:seek(1)
local clone = f:readObject()
f:close()
if select('#',...) > 0 then
clone:share(self,...)
end
return clone
end
function Module:type(type, tensorCache)
if not type then
return self._type
end
tensorCache = tensorCache or {}
-- find all tensors and convert them
for key,param in pairs(self) do
self[key] = nn.utils.recursiveType(param, type, tensorCache)
end
self._type = type
return self
end
function Module:float(...)
return self:type('torch.FloatTensor',...)
end
function Module:double(...)
return self:type('torch.DoubleTensor',...)
end
function Module:cuda(...)
return self:type('torch.CudaTensor',...)
end
function Module:reset()
end
function Module:write(file)
-- Write all values in the object as a table.
local object = {}
for k, v in pairs(self) do
object[k] = v
end
file:writeObject(object)
end
function Module:read(file)
local object = file:readObject()
for k, v in pairs(object) do
self[k] = v
end
end
-- This function is not easy to understand. It works as follows:
--
-- - gather all parameter tensors for this module (and children);
-- count all parameter values (floats)
-- - create one ginormous memory area (Storage object) with room for all
-- parameters
-- - remap each parameter tensor to point to an area within the ginormous
-- Storage, and copy it there
--
-- It has the effect of making all parameters point to the same memory area,
-- which is then returned.
--
-- The purpose is to allow operations over all parameters (such as momentum
-- updates and serialization), but it assumes that all parameters are of
-- the same type (and, in the case of CUDA, on the same device), which
-- is not always true. Use for_each() to iterate over this module and
-- children instead.
--
-- Module._flattenTensorBuffer can be used by other packages (e.g. cunn)
-- to specify the type of temporary buffers. For example, the temporary
-- buffers for CudaTensor could be FloatTensor, to avoid GPU memory usage.
--
-- TODO: This logically belongs to torch.Tensor, not nn.
Module._flattenTensorBuffer = {}
function Module.flatten(parameters)
-- returns true if tensor occupies a contiguous region of memory (no holes)
local function isCompact(tensor)
local sortedStride, perm = torch.sort(
torch.LongTensor(tensor:nDimension()):set(tensor:stride()), 1, true)
local sortedSize = torch.LongTensor(tensor:nDimension()):set(
tensor:size()):index(1, perm)
local nRealDim = torch.clamp(sortedStride, 0, 1):sum()
sortedStride = sortedStride:narrow(1, 1, nRealDim):clone()
sortedSize = sortedSize:narrow(1, 1, nRealDim):clone()
local t = tensor.new():set(tensor:storage(), 1,
sortedSize:storage(),
sortedStride:storage())
return t:isContiguous()
end
if not parameters or #parameters == 0 then
return torch.Tensor()
end
local Tensor = parameters[1].new
local TmpTensor = Module._flattenTensorBuffer[torch.type(parameters[1])] or Tensor
-- 1. construct the set of all unique storages referenced by parameter tensors
local storages = {}
local nParameters = 0
local parameterMeta = {}
for k = 1,#parameters do
local param = parameters[k]
local storage = parameters[k]:storage()
local storageKey = torch.pointer(storage)
if not storages[storageKey] then
storages[storageKey] = {storage, nParameters}
nParameters = nParameters + storage:size()
end
parameterMeta[k] = {storageOffset = param:storageOffset() +
storages[storageKey][2],
size = param:size(),
stride = param:stride()}
end
-- 2. construct a single tensor that will hold all the parameters
local flatParameters = TmpTensor(nParameters):zero()
-- 3. determine if there are elements in the storage that none of the
-- parameter tensors reference ('holes')
local tensorsCompact = true
for k = 1,#parameters do
local meta = parameterMeta[k]
local tmp = TmpTensor():set(
flatParameters:storage(), meta.storageOffset, meta.size, meta.stride)
tmp:fill(1)
tensorsCompact = tensorsCompact and isCompact(tmp)
end
local maskParameters = flatParameters:byte():clone()
local compactOffsets = flatParameters:long():cumsum(1)
local nUsedParameters = compactOffsets[-1]
-- 4. copy storages into the flattened parameter tensor
for _, storageAndOffset in pairs(storages) do
local storage, offset = table.unpack(storageAndOffset)
flatParameters[{{offset+1,offset+storage:size()}}]:copy(Tensor():set(storage))
end
-- 5. allow garbage collection
storages = nil
for k = 1,#parameters do
parameters[k]:set(Tensor())
end
-- 6. compact the flattened parameters if there were holes
if nUsedParameters ~= nParameters then
assert(tensorsCompact,
"Cannot gather tensors that are not compact")
flatParameters = TmpTensor(nUsedParameters):copy(
flatParameters:maskedSelect(maskParameters))
for k = 1,#parameters do
parameterMeta[k].storageOffset =
compactOffsets[parameterMeta[k].storageOffset]
end
end
if TmpTensor ~= Tensor then
flatParameters = Tensor(flatParameters:nElement()):copy(flatParameters)
end
-- 7. fix up the parameter tensors to point at the flattened parameters
for k = 1,#parameters do
parameters[k]:set(flatParameters:storage(),
parameterMeta[k].storageOffset,
parameterMeta[k].size,
parameterMeta[k].stride)
end
return flatParameters
end
function Module:getParameters()
-- get parameters
local parameters,gradParameters = self:parameters()
local p, g = Module.flatten(parameters), Module.flatten(gradParameters)
assert(p:nElement() == g:nElement(),
'check that you are sharing parameters and gradParameters')
if parameters then
for i=1,#parameters do
assert(parameters[i]:storageOffset() == gradParameters[i]:storageOffset(),
'misaligned parameter at ' .. tostring(i))
end
end
return p, g
end
function Module:__call__(input, gradOutput)
self:forward(input)
if gradOutput then
self:backward(input, gradOutput)
return self.output, self.gradInput
else
return self.output
end
end
-- Run a callback (called with the module as an argument) in preorder over this
-- module and its children.
--
function Module:apply(callback)
callback(self)
if self.modules then
for _, module in ipairs(self.modules) do
module:apply(callback)
end
end
end
function Module:findModules(typename, container)
container = container or self
local nodes = {}
local containers = {}
local mod_type = torch.typename(self)
if mod_type == typename then
nodes[#nodes+1] = self
containers[#containers+1] = container
end
-- Recurse on nodes with 'modules'
if (self.modules ~= nil) then
if (torch.type(self.modules) == 'table') then
for i = 1, #self.modules do
local child = self.modules[i]
local cur_nodes, cur_containers =
child:findModules(typename, self)
assert(#cur_nodes == #cur_containers,
'Internal error: incorrect return length') -- This shouldn't happen
-- add the list items from our child to our list (ie return a
-- flattened table of the return nodes).
for j = 1, #cur_nodes do
nodes[#nodes+1] = cur_nodes[j]
containers[#containers+1] = cur_containers[j]
end
end
end
end
return nodes, containers
end
-- returns a list of modules
function Module:listModules()
local function tinsert(to, from)
if torch.type(from) == 'table' then
for i=1,#from do
tinsert(to,from[i])
end
else
table.insert(to,from)
end
end
-- include self first
local modules = {self}
if self.modules then
for i=1,#self.modules do
local modulas = self.modules[i]:listModules()
if modulas then
tinsert(modules,modulas)
end
end
end
return modules
end
function Module:clearState()
return nn.utils.clear(self, 'output', 'gradInput')
end
-- similar to apply, recursively goes over network and calls
-- a callback function which returns a new module replacing the old one
function nn.Module:replace(callback)
local out = callback(self)
if self.modules then
for i, module in ipairs(self.modules) do
self.modules[i] = module:replace(callback)
end
end
return out
end