niklas88 · March 23, 2018 12:54
diff --git a/min-byte-rnn.py b/min-byte-rnn.py
 #!/usr/bin/env python3
 """
 Minimal character-level Vanilla RNN model. Written by Andrej Karpathy (@karpathy)
 BSD License
 """
 import numpy as np
 import sys
 import time

 # data I/O
 data = open(sys.argv[1], 'rb').read(100000) # should be simple plain text file
 data_size, vocab_size = len(data), 256

 # hyperparameters
 hidden_size = 100 # size of hidden layer of neurons
 seq_length = 25 # number of steps to unroll the RNN for
 learning_rate = 1e-1

 # model parameters
 Wxh = np.random.randn(hidden_size, vocab_size)*0.01 # input to hidden
 Whh = np.random.randn(hidden_size, hidden_size)*0.01 # hidden to hidden
 Why = np.random.randn(vocab_size, hidden_size)*0.01 # hidden to output
 bh = np.zeros((hidden_size, 1)) # hidden bias
 by = np.zeros((vocab_size, 1)) # output bias

 def lossFun(inputs, targets, hprev):
  """
  inputs,targets are both list of integers.
  hprev is Hx1 array of initial hidden state
  returns the loss, gradients on model parameters, and last hidden state
  """
  xs, hs, ys, ps = {}, {}, {}, {}
  hs[-1] = np.copy(hprev)
  loss = 0
  # forward pass
  for t in range(len(inputs)):
    xs[t] = np.zeros((vocab_size,1)) # encode in 1-of-k representation
    xs[t][inputs[t]] = 1
    hs[t] = np.tanh(np.dot(Wxh, xs[t]) + np.dot(Whh, hs[t-1]) + bh) # hidden state
    ys[t] = np.dot(Why, hs[t]) + by # unnormalized log probabilities for next chars
    ps[t] = np.exp(ys[t]) / np.sum(np.exp(ys[t])) # probabilities for next chars
    loss += -np.log(ps[t][targets[t],0]) # softmax (cross-entropy loss)
  # backward pass: compute gradients going backwards
  dWxh, dWhh, dWhy = np.zeros_like(Wxh), np.zeros_like(Whh), np.zeros_like(Why)
  dbh, dby = np.zeros_like(bh), np.zeros_like(by)
  dhnext = np.zeros_like(hs[0])
  for t in reversed(range(len(inputs))):
    dy = np.copy(ps[t])
    dy[targets[t]] -= 1 # backprop into y. see http://cs231n.github.io/neural-networks-case-study/#grad if confused here
    dWhy += np.dot(dy, hs[t].T)
    dby += dy
    dh = np.dot(Why.T, dy) + dhnext # backprop into h
    dhraw = (1 - hs[t] * hs[t]) * dh # backprop through tanh nonlinearity
    dbh += dhraw
    dWxh += np.dot(dhraw, xs[t].T)
    dWhh += np.dot(dhraw, hs[t-1].T)
    dhnext = np.dot(Whh.T, dhraw)
  for dparam in [dWxh, dWhh, dWhy, dbh, dby]:
    np.clip(dparam, -5, 5, out=dparam) # clip to mitigate exploding gradients
  return loss, dWxh, dWhh, dWhy, dbh, dby, hs[len(inputs)-1]

 def sample(h, seed_ix, n):
  """ 
  sample a sequence of integers from the model 
  h is memory state, seed_ix is seed letter for first time step
  """
  x = np.zeros((vocab_size, 1))
  x[seed_ix] = 1
  ixes = []
  for t in range(n):
    h = np.tanh(np.dot(Wxh, x) + np.dot(Whh, h) + bh)
    y = np.dot(Why, h) + by
    p = np.exp(y) / np.sum(np.exp(y))
    ix = np.random.choice(list(range(vocab_size)), p=p.ravel())
    x = np.zeros((vocab_size, 1))
    x[ix] = 1
    ixes.append(bytes([ix]))
  return ixes

 n, p = 0, 0
 mWxh, mWhh, mWhy = np.zeros_like(Wxh), np.zeros_like(Whh), np.zeros_like(Why)
 mbh, mby = np.zeros_like(bh), np.zeros_like(by) # memory variables for Adagrad
 smooth_loss = -np.log(1.0/vocab_size)*seq_length # loss at iteration 0
 while True:
  start = time.time()
  for _ in range(100):
    # prepare inputs (we're sweeping from left to right in steps seq_length long)
    if p+seq_length+1 >= len(data) or n == 0: 
      hprev = np.zeros((hidden_size,1)) # reset RNN memory
      p = 0 # go from start of data
    inputs = data[p:p+seq_length]
    targets = data[p+1:p+seq_length+1]


    # forward seq_length characters through the net and fetch gradient
    loss, dWxh, dWhh, dWhy, dbh, dby, hprev = lossFun(inputs, targets, hprev)
    smooth_loss = smooth_loss * 0.999 + loss * 0.001

    # perform parameter update with Adagrad
    for param, dparam, mem in zip([Wxh, Whh, Why, bh, by], 
                                  [dWxh, dWhh, dWhy, dbh, dby], 
                                  [mWxh, mWhh, mWhy, mbh, mby]):
      mem += dparam * dparam
      param += -learning_rate * dparam / np.sqrt(mem + 1e-8) # adagrad update
    p += seq_length # move data pointer
    n += 1 # iteration counter 

  end = time.time()
  # sample from the model now and then
  print('iter %d, loss: %f, avg time: %f ms/batch, throughput: %f bytes/s' % (
    n, smooth_loss, (end-start)*10, (100*seq_length)/(end-start))) # print progress
  sample_ix = sample(hprev, inputs[0], 200)
  txt = b''.join(ix for ix in sample_ix)
  print('----\n %s \n----' % (txt, ))
	#!/usr/bin/env python3
	"""
	Minimal character-level Vanilla RNN model. Written by Andrej Karpathy (@karpathy)
	BSD License
	"""
	import numpy as np
	import sys
	import time

	# data I/O
	data = open(sys.argv[1], 'rb').read(100000) # should be simple plain text file
	data_size, vocab_size = len(data), 256

	# hyperparameters
	hidden_size = 100 # size of hidden layer of neurons
	seq_length = 25 # number of steps to unroll the RNN for
	learning_rate = 1e-1

	# model parameters
	Wxh = np.random.randn(hidden_size, vocab_size)*0.01 # input to hidden
	Whh = np.random.randn(hidden_size, hidden_size)*0.01 # hidden to hidden
	Why = np.random.randn(vocab_size, hidden_size)*0.01 # hidden to output
	bh = np.zeros((hidden_size, 1)) # hidden bias
	by = np.zeros((vocab_size, 1)) # output bias

	def lossFun(inputs, targets, hprev):
	"""
	inputs,targets are both list of integers.
	hprev is Hx1 array of initial hidden state
	returns the loss, gradients on model parameters, and last hidden state
	"""
	xs, hs, ys, ps = {}, {}, {}, {}
	hs[-1] = np.copy(hprev)
	loss = 0
	# forward pass
	for t in range(len(inputs)):
	xs[t] = np.zeros((vocab_size,1)) # encode in 1-of-k representation
	xs[t][inputs[t]] = 1
	hs[t] = np.tanh(np.dot(Wxh, xs[t]) + np.dot(Whh, hs[t-1]) + bh) # hidden state
	ys[t] = np.dot(Why, hs[t]) + by # unnormalized log probabilities for next chars
	ps[t] = np.exp(ys[t]) / np.sum(np.exp(ys[t])) # probabilities for next chars
	loss += -np.log(ps[t][targets[t],0]) # softmax (cross-entropy loss)
	# backward pass: compute gradients going backwards
	dWxh, dWhh, dWhy = np.zeros_like(Wxh), np.zeros_like(Whh), np.zeros_like(Why)
	dbh, dby = np.zeros_like(bh), np.zeros_like(by)
	dhnext = np.zeros_like(hs[0])
	for t in reversed(range(len(inputs))):
	dy = np.copy(ps[t])
	dy[targets[t]] -= 1 # backprop into y. see http://cs231n.github.io/neural-networks-case-study/#grad if confused here
	dWhy += np.dot(dy, hs[t].T)
	dby += dy
	dh = np.dot(Why.T, dy) + dhnext # backprop into h
	dhraw = (1 - hs[t] * hs[t]) * dh # backprop through tanh nonlinearity
	dbh += dhraw
	dWxh += np.dot(dhraw, xs[t].T)
	dWhh += np.dot(dhraw, hs[t-1].T)
	dhnext = np.dot(Whh.T, dhraw)
	for dparam in [dWxh, dWhh, dWhy, dbh, dby]:
	np.clip(dparam, -5, 5, out=dparam) # clip to mitigate exploding gradients
	return loss, dWxh, dWhh, dWhy, dbh, dby, hs[len(inputs)-1]

	def sample(h, seed_ix, n):
	"""
	sample a sequence of integers from the model
	h is memory state, seed_ix is seed letter for first time step
	"""
	x = np.zeros((vocab_size, 1))
	x[seed_ix] = 1
	ixes = []
	for t in range(n):
	h = np.tanh(np.dot(Wxh, x) + np.dot(Whh, h) + bh)
	y = np.dot(Why, h) + by
	p = np.exp(y) / np.sum(np.exp(y))
	ix = np.random.choice(list(range(vocab_size)), p=p.ravel())
	x = np.zeros((vocab_size, 1))
	x[ix] = 1
	ixes.append(bytes([ix]))
	return ixes

	n, p = 0, 0
	mWxh, mWhh, mWhy = np.zeros_like(Wxh), np.zeros_like(Whh), np.zeros_like(Why)
	mbh, mby = np.zeros_like(bh), np.zeros_like(by) # memory variables for Adagrad
	smooth_loss = -np.log(1.0/vocab_size)*seq_length # loss at iteration 0
	while True:
	start = time.time()
	for _ in range(100):
	# prepare inputs (we're sweeping from left to right in steps seq_length long)
	if p+seq_length+1 >= len(data) or n == 0:
	hprev = np.zeros((hidden_size,1)) # reset RNN memory
	p = 0 # go from start of data
	inputs = data[p:p+seq_length]
	targets = data[p+1:p+seq_length+1]


	# forward seq_length characters through the net and fetch gradient
	loss, dWxh, dWhh, dWhy, dbh, dby, hprev = lossFun(inputs, targets, hprev)
	smooth_loss = smooth_loss * 0.999 + loss * 0.001

	# perform parameter update with Adagrad
	for param, dparam, mem in zip([Wxh, Whh, Why, bh, by],
	[dWxh, dWhh, dWhy, dbh, dby],
	[mWxh, mWhh, mWhy, mbh, mby]):
	mem += dparam * dparam
	param += -learning_rate * dparam / np.sqrt(mem + 1e-8) # adagrad update
	p += seq_length # move data pointer
	n += 1 # iteration counter

	end = time.time()
	# sample from the model now and then
	print('iter %d, loss: %f, avg time: %f ms/batch, throughput: %f bytes/s' % (
	n, smooth_loss, (end-start)10, (100seq_length)/(end-start))) # print progress
	sample_ix = sample(hprev, inputs[0], 200)
	txt = b''.join(ix for ix in sample_ix)
	print('----\n %s \n----' % (txt, ))