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nmt_l5.lua
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nmt_l5.lua
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-- Network: Google MAchine Translation
-- Application: Language-Language modelling (english-french)
-- Dataset: WMT15
-- Number of parameters: 130 Million (for 5 layers)
-- Reference: Google's machine translation
-- How to interpret I/O data sizes?
-- batchsize * sequence_length * word/char_lnegth
-- A batch - sequence of words
-- A sequence consists of multiple words
-- A word, with nn.Lookup, forms an embeddeding (vector) taht is fed as input to network
torch.setdefaulttensortype('torch.FloatTensor')
require 'xlua'
require 'sys'
cmd = torch.CmdLine()
cmd:option('-gpu', 0, 'Run on CPU/GPU')
cmd:option('-threads', 2, 'Number of threads for CPU')
cmd:option('-batch', 1, 'Number of batches')
cmd:option('-gpusample', 500, 'Sampling rate in ms')
cmd:option('-gputype','nvidia','Type of Nvidia GPU')
opt = cmd:parse(arg or {})
torch.setnumthreads(opt.threads)
-- dnn hyper-parameters
batchsize = opt.batch
seqlen = 50 -- sequence length
hiddensize = 1024
inputsize = 1024 -- inputsize is the length of vector produced after embedding (here would be for english language)
numlayers = 5
vocabsize = 40000 -- for decoder language (here french)
gpusample = opt.gpusample
gputype = opt.gputype
-- build dnn
require 'rnn'
--Forward coupling: Copy encoder cell and output to decoder LSTM
function forwardConnect(enc, dec)
for i=1,#enc.lstmLayers do
dec.lstmLayers[i].userPrevOutput = enc.lstmLayers[i].output[seqlen]
dec.lstmLayers[i].userPrevCell = enc.lstmLayers[i].cell[seqen]
end
end
-- Encoder
local enc_num_params = 0
local enc = nn.Sequential()
enc.lstmLayers = {}
for i=1,numlayers do
enc.lstmLayers[i] = nn.SeqLSTM(hiddensize, hiddensize)
enc:add(enc.lstmLayers[i])
enc_num_params = enc_num_params + 4*((hiddensize+1)*hiddensize + hiddensize^2)
end
-- Decoder
local dec_num_params = 0
local dec = nn.Sequential()
dec.lstmLayers = {}
for i=1,numlayers do
dec.lstmLayers[i] = nn.SeqLSTM(hiddensize, hiddensize)
dec:add(dec.lstmLayers[i])
dec_num_params = dec_num_params + 4*((hiddensize+1)*hiddensize + hiddensize^2)
end
dec:add(nn.Sequencer(nn.Linear(hiddensize, vocabsize), 1))
dec_num_params = dec_num_params + (hiddensize+1)*vocabsize
print ('Number of parameters', enc_num_params+dec_num_params)
print(enc)
print(dec)
-- create input and output sequences
enc_input = torch.Tensor(seqlen, batchsize, inputsize)
dec_input = torch.Tensor(seqlen, batchsize, inputsize)
output = torch.zeros(seqlen, batchsize, vocabsize)
-- dnn inference model
local run_dnn = function()
print('==> Type is '..enc_input:type())
-- forward sequence through machine-translation model
for step=1,seqlen do
enc:forward(enc_input)
forwardConnect (enc, dec)
output[{{step}, {}, {}}] = dec:forward(dec_input[{{step},{},{}}])
end
end
-- for running on GPU/CPU
if (opt.gpu == 1) then -- GPU run
require 'cunn'
enc = enc:cuda() -- move the model, i/o data to gpu memory
dec = dec:cuda()
enc_input = enc_input:cuda()
dec_input = dec_input:cuda()
output = output:cuda()
cmdstring1="nvidia-smi -i 0 --query-gpu=power.limit,power.draw,utilization.gpu,utilization.memory,memory.total,memory.used,memory.free --format=csv,nounits --loop-ms=%d >" %(gpusample)
cmdstring2=" gpu_profile_data/nmt_l5_gpulog_batchsize_%d" %(batchsize)
cmdstring3="_sample_ms_%d" %(gpusample)
cmdstring4="_%s.txt &" %(gputype)
cmdstring=cmdstring1 .. cmdstring2 .. cmdstring3 .. cmdstring4
os.execute(cmdstring)
-- measure gpu time
gputime0 = sys.clock()
run_dnn()
gputime1 = sys.clock()
gputime = gputime1 - gputime0
print('GPU Time: '.. (gputime*1000) .. 'ms')
os.execute('kill -9 `pidof nvidia-smi`')
else -- CPU run
-- measure CPU latency
cputime0 = sys.clock()
run_dnn()
cputime1 = sys.clock()
cputime = cputime1 - cputime0
print('CPU Time: '.. (cputime*1000) .. 'ms')
end