Chamfer distance between two point clouds in tensorflow

I am trying to implement chamfer distance in tensorflow.

But, my code is taking input as numpy array. To convert a numpy into a tensor, we need to run a session, but the process is already in another session. I think two sessions can't run in parallel.

So, can anyone help me with the implementation of chamfer distance in tensorflow or help me with this problem of two simultaneous sessions?

my code is:

``````def chamfer_distance(array1,array2):
# final = 0
# final = tf.cast(final,tf.float32)
batch_size = array1.get_shape()[0].value
num_point = array1.get_shape()[1].value
sess = tf.Session()
arr1,arr2 = sess.run([array1,array2])
del sess
dist = 0
for i in range(batch_size):
tree1 = KDTree(arr1[i], leafsize=num_point+1)
tree2 = KDTree(arr2[i], leafsize=num_point+1)
distances1, _ = tree1.query(arr2[i])
distances2, _ = tree2.query(arr1[i])
distances1 = tf.convert_to_tensor(distances1)
distances2 = tf.convert_to_tensor(distances2)
av_dist1 = tf.reduce_mean(distances1)
av_dist2 = tf.reduce_mean(distances2)
dist = dist + (av_dist1+av_dist2)/batch_size
return dist
``````
• can you specify the error ? Nov 2, 2017 at 12:28
• @krammer InvalidArgumentError (see above for traceback): Cannot assign a device for operation 'deconv5/bn/deconv5/bn/moments/Squeeze_1/ExponentialMovingAverage': Operation was explicitly assigned to /device:GPU:0 but available devices are [ /job:localhost/replica:0/task:0/cpu:0 ]. Make sure the device specification refers to a valid device. [[Node: deconv5/bn/deconv5/bn/moments/Squeeze_1/ExponentialMovingAverage = VariableV2[_class=["loc:@deconv5/bn/deconv5/bn/moments/Squeeze_1/ExponentialMovingAverage"], container="", dtype=DT_FLOAT, shape=[1], shared_name="", _device="/device:GPU:0"]()] Nov 2, 2017 at 12:47
• your code seems to run on a cpu while you are trying to run on GPU Nov 4, 2017 at 16:45

I've implemented TF version of chamfer distance:

``````def distance_matrix(array1, array2):
"""
arguments:
array1: the array, size: (num_point, num_feature)
array2: the samples, size: (num_point, num_feature)
returns:
distances: each entry is the distance from a sample to array1
, it's size: (num_point, num_point)
"""
num_point, num_features = array1.shape
expanded_array1 = tf.tile(array1, (num_point, 1))
expanded_array2 = tf.reshape(
tf.tile(tf.expand_dims(array2, 1),
(1, num_point, 1)),
(-1, num_features))
distances = tf.norm(expanded_array1-expanded_array2, axis=1)
distances = tf.reshape(distances, (num_point, num_point))
return distances

def av_dist(array1, array2):
"""
arguments:
array1, array2: both size: (num_points, num_feature)
returns:
distances: size: (1,)
"""
distances = distance_matrix(array1, array2)
distances = tf.reduce_min(distances, axis=1)
distances = tf.reduce_mean(distances)
return distances

def av_dist_sum(arrays):
"""
arguments:
arrays: array1, array2
returns:
sum of av_dist(array1, array2) and av_dist(array2, array1)
"""
array1, array2 = arrays
av_dist1 = av_dist(array1, array2)
av_dist2 = av_dist(array2, array1)
return av_dist1+av_dist2

def chamfer_distance_tf(array1, array2):
batch_size, num_point, num_features = array1.shape
dist = tf.reduce_mean(
tf.map_fn(av_dist_sum, elems=(array1, array2), dtype=tf.float64)
)
return dist
``````

And for validation purpose, I also implemented a sklearn version:

``````def chamfer_distance_sklearn(array1,array2):
batch_size, num_point = array1.shape[:2]
dist = 0
for i in range(batch_size):
tree1 = KDTree(array1[i], leaf_size=num_point+1)
tree2 = KDTree(array2[i], leaf_size=num_point+1)
distances1, _ = tree1.query(array2[i])
distances2, _ = tree2.query(array1[i])
av_dist1 = np.mean(distances1)
av_dist2 = np.mean(distances2)
dist = dist + (av_dist1+av_dist2)/batch_size
return dist
``````

Also a numpy version:

``````def array2samples_distance(array1, array2):
"""
arguments:
array1: the array, size: (num_point, num_feature)
array2: the samples, size: (num_point, num_feature)
returns:
distances: each entry is the distance from a sample to array1
"""
num_point, num_features = array1.shape
expanded_array1 = np.tile(array1, (num_point, 1))
expanded_array2 = np.reshape(
np.tile(np.expand_dims(array2, 1),
(1, num_point, 1)),
(-1, num_features))
distances = LA.norm(expanded_array1-expanded_array2, axis=1)
distances = np.reshape(distances, (num_point, num_point))
distances = np.min(distances, axis=1)
distances = np.mean(distances)
return distances

def chamfer_distance_numpy(array1, array2):
batch_size, num_point, num_features = array1.shape
dist = 0
for i in range(batch_size):
av_dist1 = array2samples_distance(array1[i], array2[i])
av_dist2 = array2samples_distance(array2[i], array1[i])
dist = dist + (av_dist1+av_dist2)/batch_size
return dist
``````

You can validate the result using following script:

``````batch_size = 8
num_point = 20
num_features = 4
np.random.seed(1)
array1 = np.random.randint(0, high=4, size=(batch_size, num_point, num_features))
array2 = np.random.randint(0, high=4, size=(batch_size, num_point, num_features))

print('sklearn: ', chamfer_distance_sklearn(array1, array2))
print('numpy: ', chamfer_distance_numpy(array1, array2))

array1_tf = tf.constant(array1, dtype=tf.float64)
array2_tf = tf.constant(array2, dtype=tf.float64)
dist_tf = chamfer_distance_tf(array1_tf, array2_tf)

with tf.Session() as sess:
print('tf: ', sess.run(dist_tf))
``````