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""" | |
Minimal character-level Vanilla RNN model. Written by Andrej Karpathy (@karpathy) | |
BSD License | |
""" | |
import numpy as np | |
# data I/O | |
data = open('input.txt', 'r').read() # should be simple plain text file | |
chars = list(set(data)) | |
data_size, vocab_size = len(data), len(chars) | |
print 'data has %d characters, %d unique.' % (data_size, vocab_size) | |
char_to_ix = { ch:i for i,ch in enumerate(chars) } | |
ix_to_char = { i:ch for i,ch in enumerate(chars) } | |
# 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 xrange(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(xrange(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 xrange(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(range(vocab_size), p=p.ravel()) | |
x = np.zeros((vocab_size, 1)) | |
x[ix] = 1 | |
ixes.append(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: | |
# 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 = [char_to_ix[ch] for ch in data[p:p+seq_length]] | |
targets = [char_to_ix[ch] for ch in data[p+1:p+seq_length+1]] | |
# sample from the model now and then | |
if n % 100 == 0: | |
sample_ix = sample(hprev, inputs[0], 200) | |
txt = ''.join(ix_to_char[ix] for ix in sample_ix) | |
print '----\n %s \n----' % (txt, ) | |
# 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 | |
if n % 100 == 0: print 'iter %d, loss: %f' % (n, smooth_loss) # print progress | |
# 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 |
Hi, can anyone explain the line where we pass in the gradient through the softmax function " dy [targets[t]] -=1 ". Why are we doing this operation ??
To anyone finding the code hard to understand, I provide detailed explanations here: https://mkffl.github.io/ Hope it helps
Good explanation for second part of lossFunction.
Could someone explain how to use this? I can't generate text. It is running though.
@pjoer, do you have an input.txt
file (really any text file) in the same directory of this file which you should be running like python min-char-rnn.py
It seems the above was written with python2 in mind, but I just updated a few lines and got it working on Python 3.9.6: https://gist.github.com/ijkilchenko/84be862a5e18240c59b4505177c9c34c
Good luck!
I have a problem in the code of line 58: dhnext = np.dot(Whh.T, dhraw)
. Could anyone tell me what it means?
The expression for forward propagation is:
Here is the gradients expression of weights that I derived:
It is easy to see that the red part is what dhraw
represents in the code. And we can get dWxh
and dWhh
from formula (b) and formula (c) without dhnext
. So what does dhnext
mean?
Stupid question : In which lines does the vanishing gradient problem manifest itself ?
It uses adaGrad optimization in the last few lines. Hence the gradient is always divided by the accumulate sum of each gradients' scaler .
mem += dparam*dparam
param += -learning_rate * dparam / np.sqrt(mem+1e-8)
However , I find that the mem and param are all local variables in the loop. Don't know if the implementation of adaGrad is correct.
I have a problem in the code of line 58:
dhnext = np.dot(Whh.T, dhraw)
. Could anyone tell me what it means?The expression for forward propagation is:
(1)zt=Whh⋅ht−1+Wxh⋅xt+bh(2)ht=Tanh(zt)(3)yt=Why⋅ht+by(4)ot=Softmax(yt)
Here is the gradients expression of weights that I derived:
(a)∂L∂Whh=∂L∂yt⊗htT(b)∂L∂Whh=WhyT⋅∂L∂yt⊙Tanh′(zt)⊗ht−1T(c)∂L∂Wxh=WhyT⋅∂L∂yt⊙Tanh′(zt)⊗xtT
It is easy to see that the red part is what
dhraw
represents in the code. And we can getdWxh
anddWhh
from formula (b) and formula (c) withoutdhnext
. So what doesdhnext
mean?
Since dh means the gradient of loss wrt the hidden state, there are two ways the gradients flow(back propogation). From the equation and rnn structure we learn that the hidden state feeds forward to a output and next hidden state. The dhnext represents the gradient update for current state from the next hidden state. Note that dhnext is zero at first iteration because for the last-layer (unrolled) of rnn , there 's not a gradient update flow from the next hidden state.
Hope this will help you .
I have a problem in the code of line 58:
dhnext = np.dot(Whh.T, dhraw)
. Could anyone tell me what it means?
The expression for forward propagation is:
(1)zt=Whh⋅ht−1+Wxh⋅xt+bh(2)ht=Tanh(zt)(3)yt=Why⋅ht+by(4)ot=Softmax(yt)
Here is the gradients expression of weights that I derived:
(a)∂L∂Whh=∂L∂yt⊗htT(b)∂L∂Whh=WhyT⋅∂L∂yt⊙Tanh′(zt)⊗ht−1T(c)∂L∂Wxh=WhyT⋅∂L∂yt⊙Tanh′(zt)⊗xtT
It is easy to see that the red part is whatdhraw
represents in the code. And we can getdWxh
anddWhh
from formula (b) and formula (c) withoutdhnext
. So what doesdhnext
mean?
Since dh means the gradient of loss wrt the hidden state, there are two ways the gradients flow(back propogation). From the equation and rnn structure we learn that the hidden state feeds forward to a output and next hidden state. The dhnext represents the gradient update for current state from the next hidden state. Note that dhnext is zero at first iteration because for the last-layer (unrolled) of rnn , there 's not a gradient update flow from the next hidden state. Hope this will help you .
Thank you so much for your replying. I missed the partial derivative wrt the next hidden state.
However , I find that the mem and param are all local variables in the loop. Don't know if the implementation of adaGrad is correct.
mem and param point to the numpy ndarrays from the zip, and += updates their values in-place.
Can somebody explain why we need to multiply 0.01 when initializing the weights ? Arent we already using np.random.randn to sample from a normal distribution? I am talking about this specific line of code Wxh = np.random.randn(hidden_size, vocab_size)*0.01
Thia is to keep weight matrix parameter to be small.
I made a two layer recurrent neural network based off of this and I am not sure why it does not work. So, if anyone could check out and make a PR if you find a problem?
https://github.com/lanttu1243/vanilla_recurrent_neural_network.git