Dynamic placeholders
Tensorflow allows to have multiple dynamic (a.k.a. None
) dimensions in placeholders. The engine won't be able to ensure correctness while the graph is built, hence the client is responsible for feeding the correct input, but it provides a lot of flexibility.
So I'm going from...
x = tf.placeholder(tf.float32, shape=[None, N*M*P])
y_ = tf.placeholder(tf.float32, shape=[None, N*M*P, 3])
...
x_image = tf.reshape(x, [-1, N, M, P, 1])
to...
# Nearly all dimensions are dynamic
x_image = tf.placeholder(tf.float32, shape=[None, None, None, None, 1])
label = tf.placeholder(tf.float32, shape=[None, None, 3])
Since you intend to reshape the input to 5D anyway, so why don't use 5D in x_image
right from the start. At this point, the second dimension of label
is arbitrary, but we promise tensorflow that it will match with x_image
.
Dynamic shapes in deconvolution
Next, the nice thing about tf.nn.conv3d_transpose
is that its output shape can be dynamic. So instead of this:
# Hard-coded output shape
DeConnv1 = tf.nn.conv3d_transpose(layer1, w, output_shape=[1,32,32,7,1], ...)
... you can do this:
# Dynamic output shape
DeConnv1 = tf.nn.conv3d_transpose(layer1, w, output_shape=tf.shape(x_image), ...)
This way the transpose convolution can be applied to any image and the result will take the shape of x_image
that was actually passed in at runtime.
Note that static shape of x_image
is (?, ?, ?, ?, 1)
.
All-Convolutional network
Final and most important piece of the puzzle is to make the whole network convolutional, and that includes your final dense layer too. Dense layer must define its dimensions statically, which forces the whole neural network fix input image dimensions.
Luckily for us, Springenberg at al describe a way to replace an FC layer with a CONV layer in "Striving for Simplicity: The All Convolutional Net" paper. I'm going to use a convolution with 3 1x1x1
filters (see also this question):
final_conv = conv3d_s1(final, weight_variable([1, 1, 1, 1, 3]))
y = tf.reshape(final_conv, [-1, 3])
If we ensure that final
has the same dimensions as DeConnv1
(and others), it'll make y
right the shape we want: [-1, N * M * P, 3]
.
Combining it all together
Your network is pretty large, but all deconvolutions basically follow the same pattern, so I've simplified my proof-of-concept code to just one deconvolution. The goal is just to show what kind of network is able to handle images of arbitrary size. Final remark: image dimensions can vary between batches, but within one batch they have to be the same.
The full code:
sess = tf.InteractiveSession()
def conv3d_dilation(tempX, tempFilter):
return tf.layers.conv3d(tempX, filters=tempFilter, kernel_size=[3, 3, 1], strides=1, padding='SAME', dilation_rate=2)
def conv3d(tempX, tempW):
return tf.nn.conv3d(tempX, tempW, strides=[1, 2, 2, 2, 1], padding='SAME')
def conv3d_s1(tempX, tempW):
return tf.nn.conv3d(tempX, tempW, strides=[1, 1, 1, 1, 1], padding='SAME')
def weight_variable(shape):
initial = tf.truncated_normal(shape, stddev=0.1)
return tf.Variable(initial)
def bias_variable(shape):
initial = tf.constant(0.1, shape=shape)
return tf.Variable(initial)
def max_pool_3x3(x):
return tf.nn.max_pool3d(x, ksize=[1, 3, 3, 3, 1], strides=[1, 2, 2, 2, 1], padding='SAME')
x_image = tf.placeholder(tf.float32, shape=[None, None, None, None, 1])
label = tf.placeholder(tf.float32, shape=[None, None, 3])
W_conv1 = weight_variable([3, 3, 1, 1, 32])
h_conv1 = conv3d(x_image, W_conv1)
# second convolution
W_conv2 = weight_variable([3, 3, 4, 32, 64])
h_conv2 = conv3d_s1(h_conv1, W_conv2)
# third convolution path 1
W_conv3_A = weight_variable([1, 1, 1, 64, 64])
h_conv3_A = conv3d_s1(h_conv2, W_conv3_A)
# third convolution path 2
W_conv3_B = weight_variable([1, 1, 1, 64, 64])
h_conv3_B = conv3d_s1(h_conv2, W_conv3_B)
# fourth convolution path 1
W_conv4_A = weight_variable([3, 3, 1, 64, 96])
h_conv4_A = conv3d_s1(h_conv3_A, W_conv4_A)
# fourth convolution path 2
W_conv4_B = weight_variable([1, 7, 1, 64, 64])
h_conv4_B = conv3d_s1(h_conv3_B, W_conv4_B)
# fifth convolution path 2
W_conv5_B = weight_variable([1, 7, 1, 64, 64])
h_conv5_B = conv3d_s1(h_conv4_B, W_conv5_B)
# sixth convolution path 2
W_conv6_B = weight_variable([3, 3, 1, 64, 96])
h_conv6_B = conv3d_s1(h_conv5_B, W_conv6_B)
# concatenation
layer1 = tf.concat([h_conv4_A, h_conv6_B], 4)
w = tf.Variable(tf.constant(1., shape=[2, 2, 4, 1, 192]))
DeConnv1 = tf.nn.conv3d_transpose(layer1, filter=w, output_shape=tf.shape(x_image), strides=[1, 2, 2, 2, 1], padding='SAME')
final = DeConnv1
final_conv = conv3d_s1(final, weight_variable([1, 1, 1, 1, 3]))
y = tf.reshape(final_conv, [-1, 3])
cross_entropy = tf.reduce_mean(tf.nn.softmax_cross_entropy_with_logits(labels=label, logits=y))
print('x_image:', x_image)
print('DeConnv1:', DeConnv1)
print('final_conv:', final_conv)
def try_image(N, M, P, B=1):
batch_x = np.random.normal(size=[B, N, M, P, 1])
batch_y = np.ones([B, N * M * P, 3]) / 3.0
deconv_val, final_conv_val, loss = sess.run([DeConnv1, final_conv, cross_entropy],
feed_dict={x_image: batch_x, label: batch_y})
print(deconv_val.shape)
print(final_conv.shape)
print(loss)
print()
tf.global_variables_initializer().run()
try_image(32, 32, 7)
try_image(16, 16, 3)
try_image(16, 16, 3, 2)