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timing_util.lua
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timing_util.lua
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-- Copyright 2016 Anurag Ranjan and the Max Planck Gesellschaft.
-- All rights reserved.
-- This software is provided for research purposes only.
-- By using this software you agree to the terms of the license file
-- in the root folder.
-- For commercial use, please contact [email protected].
require 'image'
local TF = require 'transforms'
require 'cutorch'
require 'nn'
require 'cunn'
require 'cudnn'
require 'nngraph'
require 'stn'
require 'spy'
local flowX = require 'flowExtensions'
local M = {}
local eps = 1e-6
local meanstd = {
mean = { 0.485, 0.456, 0.406 },
std = { 0.229, 0.224, 0.225 },
}
local pca = {
eigval = torch.Tensor{ 0.2175, 0.0188, 0.0045 },
eigvec = torch.Tensor{
{ -0.5675, 0.7192, 0.4009 },
{ -0.5808, -0.0045, -0.8140 },
{ -0.5836, -0.6948, 0.4203 },
},
}
local mean = meanstd.mean
local std = meanstd.std
------------------------------------------
local function createWarpModel()
local imgData = nn.Identity()()
local floData = nn.Identity()()
local imgOut = nn.Transpose({2,3},{3,4})(imgData)
local floOut = nn.Transpose({2,3},{3,4})(floData)
local warpImOut = nn.Transpose({3,4},{2,3})(nn.BilinearSamplerBHWD()({imgOut, floOut}))
local model = nn.gModule({imgData, floData}, {warpImOut})
return model
end
local down2 = nn.SpatialAveragePooling(2,2,2,2):cuda()
local down3 = nn.SpatialAveragePooling(2,2,2,2):cuda()
local down4 = nn.SpatialAveragePooling(2,2,2,2):cuda()
local down5 = nn.SpatialAveragePooling(2,2,2,2):cuda()
local up2 = nn.Sequential():add(nn.Transpose({2,3},{3,4})):add(nn.ScaleBHWD(2)):add(nn.Transpose({3,4},{2,3})):cuda()
local up3 = nn.Sequential():add(nn.Transpose({2,3},{3,4})):add(nn.ScaleBHWD(2)):add(nn.Transpose({3,4},{2,3})):cuda()
local up4 = nn.Sequential():add(nn.Transpose({2,3},{3,4})):add(nn.ScaleBHWD(2)):add(nn.Transpose({3,4},{2,3})):cuda()
local up5 = nn.Sequential():add(nn.Transpose({2,3},{3,4})):add(nn.ScaleBHWD(2)):add(nn.Transpose({3,4},{2,3})):cuda()
local warpmodel2 = createWarpModel():cuda()
local warpmodel3 = createWarpModel():cuda()
local warpmodel4 = createWarpModel():cuda()
local warpmodel5 = createWarpModel():cuda()
down2:evaluate()
down3:evaluate()
down4:evaluate()
down5:evaluate()
up2:evaluate()
up3:evaluate()
up4:evaluate()
up5:evaluate()
warpmodel2:evaluate()
warpmodel3:evaluate()
warpmodel4:evaluate()
warpmodel5:evaluate()
-------------------------------------------------
local modelL0, modelL1, modelL2, modelL3, modelL4, modelL5
local modelL1path, modelL2path, modelL3path, modelL4path, modelL5path
modelL1path = paths.concat('models', 'modelL1_4.t7')
modelL2path = paths.concat('models', 'modelL2_4.t7')
modelL3path = paths.concat('models', 'modelL3_4.t7')
modelL4path = paths.concat('models', 'modelL4_4.t7')
modelL5path = paths.concat('models', 'modelL5_4.t7')
modelL1 = torch.load(modelL1path)
if torch.type(modelL1) == 'nn.DataParallelTable' then
modelL1 = modelL1:get(1)
end
modelL1:evaluate()
modelL2 = torch.load(modelL2path)
if torch.type(modelL2) == 'nn.DataParallelTable' then
modelL2 = modelL2:get(1)
end
modelL2:evaluate()
modelL3 = torch.load(modelL3path)
if torch.type(modelL3) == 'nn.DataParallelTable' then
modelL3 = modelL3:get(1)
end
modelL3:evaluate()
modelL4 = torch.load(modelL4path)
if torch.type(modelL4) == 'nn.DataParallelTable' then
modelL4 = modelL4:get(1)
end
modelL4:evaluate()
modelL5 = torch.load(modelL5path)
if torch.type(modelL5) == 'nn.DataParallelTable' then
modelL5 = modelL5:get(1)
end
modelL5:evaluate()
local function getTrainValidationSplits(path)
local numSamples = sys.fexecute( "ls " .. opt.data .. "| wc -l")/3
local ff = torch.DiskFile(path, 'r')
local trainValidationSamples = torch.IntTensor(numSamples)
ff:readInt(trainValidationSamples:storage())
ff:close()
local train_samples = trainValidationSamples:eq(1):nonzero()
local validation_samples = trainValidationSamples:eq(2):nonzero()
return train_samples, validation_samples
-- body
end
M.getTrainValidationSplits = getTrainValidationSplits
local function loadImage(path)
local input = image.load(path, 3, 'float')
return input
end
M.loadImage = loadImage
local function loadFlow(filename)
TAG_FLOAT = 202021.25
local ff = torch.DiskFile(filename):binary()
local tag = ff:readFloat()
if tag ~= TAG_FLOAT then
xerror('unable to read '..filename..
' perhaps bigendian error','readflo()')
end
local w = ff:readInt()
local h = ff:readInt()
local nbands = 2
local tf = torch.FloatTensor(h, w, nbands)
ff:readFloat(tf:storage())
ff:close()
local flow = tf:permute(3,1,2)
return flow
end
M.loadFlow = loadFlow
local function computeInitFlowL1(imagesL1)
local h = imagesL1:size(3)
local w = imagesL1:size(4)
local _flowappend = torch.zeros(opt.batchSize, 2, h, w):cuda()
local images_in = torch.cat(imagesL1, _flowappend, 2)
local flow_est = modelL1:forward(images_in)
return flow_est
end
M.computeInitFlowL1 = computeInitFlowL1
local function computeInitFlowL2(imagesL2)
local imagesL1 = down2:forward(imagesL2:clone())
local _flowappend = up2:forward(computeInitFlowL1(imagesL1))*2
local _img2 = imagesL2[{{},{4,6},{},{}}]
imagesL2[{{},{4,6},{},{}}]:copy(warpmodel2:forward({_img2, _flowappend}))
local images_in = torch.cat(imagesL2, _flowappend, 2)
local flow_est = modelL2:forward(images_in)
return flow_est:add(_flowappend)
end
M.computeInitFlowL2 = computeInitFlowL2
local function computeInitFlowL3(imagesL3)
local imagesL2 = down3:forward(imagesL3:clone())
local _flowappend = up3:forward(computeInitFlowL2(imagesL2))*2
local _img2 = imagesL3[{{},{4,6},{},{}}]
imagesL3[{{},{4,6},{},{}}]:copy(warpmodel3:forward({_img2, _flowappend}))
local images_in = torch.cat(imagesL3, _flowappend, 2)
local flow_est = modelL3:forward(images_in)
return flow_est:add(_flowappend)
end
M.computeInitFlowL3 = computeInitFlowL3
local function computeInitFlowL4(imagesL4)
local imagesL3 = down4:forward(imagesL4)
local _flowappend = up4:forward(computeInitFlowL3(imagesL3))*2
local _img2 = imagesL4[{{},{4,6},{},{}}]
imagesL4[{{},{4,6},{},{}}]:copy(warpmodel4:forward({_img2, _flowappend}))
local images_in = torch.cat(imagesL4, _flowappend, 2)
local flow_est = modelL4:forward(images_in)
return flow_est:add(_flowappend)
end
M.computeInitFlowL4 = computeInitFlowL4
local function computeInitFlowL5(imagesL5)
local imagesL4 = down5:forward(imagesL5)
local _flowappend = up5:forward(computeInitFlowL4(imagesL4))*2
local _img2 = imagesL5[{{},{4,6},{},{}}]
imagesL5[{{},{4,6},{},{}}]:copy(warpmodel5:forward({_img2, _flowappend}))
local images_in = torch.cat(imagesL5, _flowappend, 2)
local flow_est = modelL5:forward(images_in)
return flow_est:add(_flowappend)
end
M.computeInitFlowL5 = computeInitFlowL5
local function getRawData(id)
local path1 = paths.concat(opt.data, (string.format("%05i", id) .."_img1.ppm"))
local path2 = paths.concat(opt.data, (string.format("%05i", id) .."_img2.ppm"))
local img1 = loadImage(path1)
local img2 = loadImage(path2)
local pathF = paths.concat(opt.data, (string.format("%05i", id) .."_flow.flo"))
local flow = loadFlow(pathF)
return img1, img2, flow
end
M.getRawData = getRawData
local testHook = function(id)
local path1 = paths.concat(opt.data, (string.format("%05i", id) .."_img1.ppm"))
local path2 = paths.concat(opt.data, (string.format("%05i", id) .."_img2.ppm"))
local img1 = loadImage(path1)
local img2 = loadImage(path2)
local images = torch.cat(img1, img2, 1)
local pathF = paths.concat(opt.data, (string.format("%05i", id) .."_flow.flo"))
local flow = loadFlow(pathF)
images = TF.ColorNormalize(meanstd)(images)
return images, flow
end
M.testHook = testHook
return M