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I'm trying to detect lung cancer nodules using DICOM files. The main steps in cancer detection included following steps.

1) Preprocessing
  * Converting the pixel values to Hounsfield Units (HU)
  * Resampling to an isomorphic resolution to remove variance in scanner resolution
  *Lung segmentation
2) Training the data set using preprocessed images in Tensorflow CNN
3) Testing and validation

I followed few online tutorials to do this.

I need to combine the given solutions in

1) https://www.kaggle.com/gzuidhof/full-preprocessing-tutorial
2) https://www.kaggle.com/sentdex/first-pass-through-data-w-3d-convnet.

I could implement the example in link two. But since it is lack ok lung segmentation and few other preprocessing steps I need to combine the steps in link one with link two. But I'm getting number of errors while doing it. Since I'm new to python can someone please help me in solving it.

There are 20 patient folders and each patient folder has number of slices, which are dicom files.

For the process_data method , slices_path of each patient and patient number was sent.

def process_data(slices,patient,labels_df,img_px_size,hm_slices):

try:
    label=labels_df.get_value(patient,'cancer')

    patient_pixels = get_pixels_hu(slices)

    segmented_lungs2, spacing = resample(patient_pixels, slices, [1,1,1])

    new_slices=[]

    segmented_lung = segment_lung_mask(segmented_lungs2, False)
    segmented_lungs_fill = segment_lung_mask(segmented_lungs2, True)
    segmented_lungs=segmented_lungs_fill-segmented_lung


    #This method returns smallest integer not less than x.
    chunk_sizes =math.ceil(len(segmented_lungs)/HM_SLICES)


    for slice_chunk in chunks(segmented_lungs,chunk_sizes):

            slice_chunk=list(map(mean,zip(*slice_chunk))) #list - []

            #print (slice_chunk)
            new_slices.append(slice_chunk)

    print(len(segmented_lungs), len(new_slices))

    if len(new_slices)==HM_SLICES-1:
            new_slices.append(new_slices[-1])

    if len(new_slices)==HM_SLICES-2:
            new_slices.append(new_slices[-1])
            new_slices.append(new_slices[-1])


    if len(new_slices)==HM_SLICES+2:
            new_val =list(map(mean, zip(*[new_slices[HM_SLICES-1],new_slices[HM_SLICES],])))
            del new_slices[HM_SLICES]
            new_slices[HM_SLICES-1]=new_val

    if len(new_slices)==HM_SLICES+1:
            new_val =list(map(mean, zip(*[new_slices[HM_SLICES-1],new_slices[HM_SLICES],])))
            del new_slices[HM_SLICES]
            new_slices[HM_SLICES-1]=new_val

    print('LENGTH ',len(segmented_lungs), len(new_slices))    
except Exception as e:
    # again, some patients are not labeled, but JIC we still want the error if something
    # else is wrong with our code
    print(str(e))


#print(len(new_slices))   

if label==1: label=np.array([0,1])
elif label==0: label=np.array([1,0])
return np.array(new_slices),label

Main method

    # Some constants 
    #data_dir = '../../CT_SCAN_IMAGE_SET/IMAGES/'
    #patients = os.listdir(data_dir)
    #labels_df=pd.read_csv('../../CT_SCAN_IMAGE_SET/stage1_labels.csv',index_col=0)
    #patients.sort()
    #print (labels_df.head())

    much_data=[]
    much_data2=[]
    for num,patient in enumerate(patients):
        if num%100==0:
            print (num)

        try:

            slices = load_scan(data_dir + patients[num])
            img_data,label=process_data(slices,patients[num],labels_df,IMG_PX_SIZE,HM_SLICES)
            much_data.append([img_data,label])
            #much_data2.append([processed,label])
        except:
            print ('This is unlabeled data')

    np.save('muchdata-{}-{}-{}.npy'.format(IMG_PX_SIZE,IMG_PX_SIZE,HM_SLICES),much_data)
    #np.save('muchdata-{}-{}-{}.npy'.format(IMG_PX_SIZE,IMG_PX_SIZE,HM_SLICES),much_data2)

The preprocessing part works fine but when I'm trying to enter the final out put to a Convolutional NN and train the data set , Following is the error I'm receiving including some of the comments that I had put

    0
    shape hu
    (113, 512, 512)
    Resize factor
    [ 2.49557522  0.6015625   0.6015625 ]
    shape
    (282, 308, 308)
    chunk size 
    15
    282 19
    LENGTH  282 20
    Tensor("Placeholder:0", dtype=float32)
    ..........1.........
    ..........2.........
    ..........3.........
    ..........4.........
    WARNING:tensorflow:From C:\Research\Python_installation\lib\site-packages\tensorflow\python\util\tf_should_use.py:170: initialize_all_variables (from tensorflow.python.ops.variables) is deprecated and will be removed after 2017-03-02.
    Instructions for updating:
    Use `tf.global_variables_initializer` instead.
    ..........5.........
    ..........6.........
    Epoch 1 completed out of 20 loss: 0
    ..........7.........
    Traceback (most recent call last):
    File "C:\Research\LungCancerDetaction\sendbox2.py", line 436, in <module>
    train_neural_network(x)
    File "C:\Research\LungCancerDetaction\sendbox2.py", line 424, in train_neural_network
    print('Accuracy:',accuracy.eval({x:[i[0] for i in validation_data], y:[i[1] for i in validation_data]}))
    File "C:\Research\Python_installation\lib\site-packages\tensorflow\python\framework\ops.py", line 606, in eval
    return _eval_using_default_session(self, feed_dict, self.graph, session)
    File "C:\Research\Python_installation\lib\site-packages\tensorflow\python\framework\ops.py", line 3928, in _eval_using_default_session
    return session.run(tensors, feed_dict)
    File "C:\Research\Python_installation\lib\site-packages\tensorflow\python\client\session.py", line 789, in run
    run_metadata_ptr)
    File "C:\Research\Python_installation\lib\site-packages\tensorflow\python\client\session.py", line 968, in _run
    np_val = np.asarray(subfeed_val, dtype=subfeed_dtype)
    File "C:\Research\Python_installation\lib\site-packages\numpy\core\numeric.py", line 531, in asarray
    return array(a, dtype, copy=False, order=order)
    ValueError: could not broadcast input array from shape (20,310,310) into shape (20)

I think it is the issue with the 'segmented_lungs=segmented_lungs_fill-segmented_lung'

In the working example,

segmented_lungs=[cv2.resize(each_slice,(IMG_PX_SIZE,IMG_PX_SIZE)) for each_slice in patient_pixels]

Please help me in solving this. I'm unable to proceed since some time. If anything is not clear please let me know.

Following is the whole code that had tried.

    import numpy as np # linear algebra
    import pandas as pd # data processing, CSV file I/O (e.g. pd.read_csv)
    import dicom
    import os
    import scipy.ndimage
    import matplotlib.pyplot as plt
    import cv2
    import math
    import tensorflow as tf


    from skimage import measure, morphology
    from mpl_toolkits.mplot3d.art3d import Poly3DCollection

     # Some constants 
    data_dir = '../../CT_SCAN_IMAGE_SET/IMAGES/'
    patients = os.listdir(data_dir)
    labels_df=pd.read_csv('../../CT_SCAN_IMAGE_SET/stage1_labels.csv',index_col=0)
    patients.sort()
    print (labels_df.head())

    #Image pixel array watching

    for patient in patients[:10]:
        #label is to get the label  of the patient. This is what done in the .get_value method.
        label=labels_df.get_value(patient,'cancer')
        path=data_dir+patient
        slices = [dicom.read_file(path + '/' + s) for s in os.listdir(path)]
        #You have dicom files and they have attributes. 
        slices.sort(key = lambda x: float(x.ImagePositionPatient[2]))
        print (len(slices),slices[0].pixel_array.shape)

    #If u need to see many slices and resize the large pixelated 2D images into 150*150 pixelated images

    IMG_PX_SIZE=50
    HM_SLICES=20

    for patient in patients[:1]:
        #label is to get the label of the patient. This is what done in the .get_value method.
        label=labels_df.get_value(patient,'cancer')
        path=data_dir+patient
        slices = [dicom.read_file(path + '/' + s) for s in os.listdir(path)]
        #You have dicom files and they have attributes. 
        slices.sort(key = lambda x: float(x.ImagePositionPatient[2]))
        #This shows the pixel arrayed image related to the second slice of each patient

        #subplot
        fig=plt.figure()
        for num,each_slice in enumerate(slices[:16]):
            print (num)
            y=fig.add_subplot(4,4,num+1)
            #down sizing everything. Resize the imag size as their pixel values are 512*512
            new_image=cv2.resize(np.array(each_slice.pixel_array),(IMG_PX_SIZE,IMG_PX_SIZE))
            y.imshow(new_image)
        plt.show()

    print (len(patients))

    ###################################################################################

    def get_pixels_hu(slices):
        image = np.array([s.pixel_array for s in slices])
        # Convert to int16 (from sometimes int16), 
        # should be possible as values should always be low enough (<32k)
        image = image.astype(np.int16)

        # Set outside-of-scan pixels to 0
        # The intercept is usually -1024, so air is approximately 0
        image[image == -2000] = 0

        # Convert to Hounsfield units (HU)
        for slice_number in range(len(slices)):

            intercept = slices[slice_number].RescaleIntercept
            slope = slices[slice_number].RescaleSlope

            if slope != 1:
                image[slice_number] = slope * image[slice_number].astype(np.float64)
                image[slice_number] = image[slice_number].astype(np.int16)

            image[slice_number] += np.int16(intercept)

        return np.array(image, dtype=np.int16)


    #The next problem is each patient is got different number of slices . This is a performance issue.
    # Take the slices and put that into a list of slices and chunk that list of slices into fixed numer of
    #chunk of slices and averaging those chunks.

    #yield is like 'return'. It returns a generator

    def chunks(l,n):
        for i in range(0,len(l),n):
            #print ('Inside yield')
            #print (i)
            yield l[i:i+n]

    def mean(l):
        return sum(l)/len(l)


    def largest_label_volume(im, bg=-1):
        vals, counts = np.unique(im, return_counts=True)

        counts = counts[vals != bg]
        vals = vals[vals != bg]

        if len(counts) > 0:
            return vals[np.argmax(counts)]
        else:
            return None


    def segment_lung_mask(image, fill_lung_structures=True):

        # not actually binary, but 1 and 2. 
        # 0 is treated as background, which we do not want
        binary_image = np.array(image > -320, dtype=np.int8)+1
        labels = measure.label(binary_image)


        # Pick the pixel in the very corner to determine which label is air.
        #   Improvement: Pick multiple background labels from around the patient
        #   More resistant to "trays" on which the patient lays cutting the air 
        #   around the person in half
        background_label = labels[0,0,0]
        #Fill the air around the person
        binary_image[background_label == labels] = 2

        # Method of filling the lung structures (that is superior to something like 
        # morphological closing)

        if fill_lung_structures:
            # For every slice we determine the largest solid structure

            for i, axial_slice in enumerate(binary_image):
                axial_slice = axial_slice - 1
                labeling = measure.label(axial_slice)
                l_max = largest_label_volume(labeling, bg=0)

                if l_max is not None: #This slice contains some lung
                    binary_image[i][labeling != l_max] = 1

        binary_image -= 1 #Make the image actual binary
        binary_image = 1-binary_image # Invert it, lungs are now 1
        # Remove other air pockets insided body
        labels = measure.label(binary_image, background=0)
        l_max = largest_label_volume(labels, bg=0)

        if l_max is not None: # There are air pockets
            binary_image[labels != l_max] = 0

        return binary_image


    #Loading the files
    #Load the scans in given folder path
    def load_scan(path):
        slices = [dicom.read_file(path + '/' + s) for s in os.listdir(path)]
        slices.sort(key = lambda x: float(x.ImagePositionPatient[2]))
        try:
            slice_thickness = np.abs(slices[0].ImagePositionPatient[2] - slices[1].ImagePositionPatient[2])
        except:
            slice_thickness = np.abs(slices[0].SliceLocation - slices[1].SliceLocation)

        for s in slices:
            s.SliceThickness = slice_thickness

        return slices



    def resample(image, scan, new_spacing=[1,1,1]):
        # Determine current pixel spacing

        spacing = np.array([scan[0].SliceThickness] + scan[0].PixelSpacing, dtype=np.float32)


        resize_factor = spacing / new_spacing
        new_real_shape = image.shape * resize_factor
        new_shape = np.round(new_real_shape)
        real_resize_factor = new_shape / image.shape
        new_spacing = spacing / real_resize_factor

        print ('Resize factor')
        print (real_resize_factor)

        image = scipy.ndimage.interpolation.zoom(image, real_resize_factor, mode='nearest')
        print ('shape')
        print (image.shape)

        return image, new_spacing

    '''def chunks(l,n):
        for i in range(0,len(l),n):
            #print ('Inside yield')
            #print (i)
            yield l[i:i+n]

    def mean(l):
        return sum(l)/len(l)'''

    #processing data
    def process_data(slices,patient,labels_df,img_px_size,hm_slices):
         #for patient in patients[:10]:
                #label is to get the label of the patient. This is what done in the .get_value method.
        try:
            label=labels_df.get_value(patient,'cancer')
            print ('label process data')
            print (label)
            #path=data_dir+patient
            #slices = [dicom.read_file(path + '/' + s) for s in os.listdir(path)]
            #You have dicom files and they have attributes. 
            slices.sort(key = lambda x: float(x.ImagePositionPatient[2]))
            #This shows the pixel arrayed image related to the second slice of each patient
            patient_pixels = get_pixels_hu(slices)
            print ('shape hu')
            print (patient_pixels.shape)
            segmented_lungs2, spacing = resample(patient_pixels, slices, [1,1,1])
            #print ('Pix shape')
            #print (segmented_lungs2.shape)

            #segmented_lungs=np.array(segmented_lungs2).tolist()

            new_slices=[]

            segmented_lung = segment_lung_mask(segmented_lungs2, False)
            segmented_lungs_fill = segment_lung_mask(segmented_lungs2, True)
            segmented_lungs=segmented_lungs_fill-segmented_lung


            #print ('length of segmented lungs')
            #print (len(segmented_lungs))
            #print ('Shape of segmented lungs......................................')
            #print (segmented_lungs.shape)
            #print ('hiiii')
            #segmented_lungs=[cv2.resize(each_slice,(IMG_PX_SIZE,IMG_PX_SIZE)) for each_slice in segmented_lungs3]
            #print ('bye')
            #print ('length of slices')
            #print (len(slices))
            #print ('shape of slices')
            #print (slices.shape)


            #print (each_slice.pixel_array)

            #This method returns smallest integer not less than x.
            chunk_sizes =math.ceil(len(segmented_lungs)/HM_SLICES)

            print ('chunk size ')
            print (chunk_sizes)

            for slice_chunk in chunks(segmented_lungs,chunk_sizes):

                    slice_chunk=list(map(mean,zip(*slice_chunk))) #list - []

                    #print (slice_chunk)
                    new_slices.append(slice_chunk)

            print(len(segmented_lungs), len(new_slices))

            if len(new_slices)==HM_SLICES-1:
                    new_slices.append(new_slices[-1])

            if len(new_slices)==HM_SLICES-2:
                    new_slices.append(new_slices[-1])
                    new_slices.append(new_slices[-1])

            if len(new_slices)==HM_SLICES-3:
                    new_slices.append(new_slices[-1])
                    new_slices.append(new_slices[-1])
                    new_slices.append(new_slices[-1])

            if len(new_slices)==HM_SLICES+2:
                    new_val =list(map(mean, zip(*[new_slices[HM_SLICES-1],new_slices[HM_SLICES],])))
                    del new_slices[HM_SLICES]
                    new_slices[HM_SLICES-1]=new_val

            if len(new_slices)==HM_SLICES+1:
                    new_val =list(map(mean, zip(*[new_slices[HM_SLICES-1],new_slices[HM_SLICES],])))
                    del new_slices[HM_SLICES]
                    new_slices[HM_SLICES-1]=new_val

            if len(new_slices)==HM_SLICES+3:
                    new_val =list(map(mean, zip(*[new_slices[HM_SLICES-1],new_slices[HM_SLICES],])))
                    del new_slices[HM_SLICES]
                    new_slices[HM_SLICES-1]=new_val

            print('LENGTH ',len(segmented_lungs), len(new_slices))    
        except Exception as e:
            # again, some patients are not labeled, but JIC we still want the error if something
            # else is wrong with our code
            print(str(e))


        #print(len(new_slices))   

        if label==1: label=np.array([0,1])
        elif label==0: label=np.array([1,0])
        return np.array(new_slices),label



    # Some constants 
    #data_dir = '../../CT_SCAN_IMAGE_SET/IMAGES/'
    #patients = os.listdir(data_dir)
    #labels_df=pd.read_csv('../../CT_SCAN_IMAGE_SET/stage1_labels.csv',index_col=0)
    #patients.sort()
    #print (labels_df.head())

    much_data=[]
    much_data2=[]
    for num,patient in enumerate(patients):
        if num%100==0:
            print (num)

        try:

            slices = load_scan(data_dir + patients[num])
            img_data,label=process_data(slices,patients[num],labels_df,IMG_PX_SIZE,HM_SLICES)
            much_data.append([img_data,label])
            #much_data2.append([processed,label])
        except:
            print ('This is unlabeled data')

    np.save('muchdata-{}-{}-{}.npy'.format(IMG_PX_SIZE,IMG_PX_SIZE,HM_SLICES),much_data)
    #np.save('muchdata-{}-{}-{}.npy'.format(IMG_PX_SIZE,IMG_PX_SIZE,HM_SLICES),much_data2)

    IMG_SIZE_PX = 50
    SLICE_COUNT = 20

    n_classes=2
    batch_size=10

    x = tf.placeholder('float')
    y = tf.placeholder('float')

    keep_rate = 0.8

    def conv3d(x, W):
        return tf.nn.conv3d(x, W, strides=[1,1,1,1,1], padding='SAME')

    def maxpool3d(x):
        #                        size of window         movement of window as you slide about
        return tf.nn.max_pool3d(x, ksize=[1,2,2,2,1], strides=[1,2,2,2,1], padding='SAME')

    def convolutional_neural_network(x):
        #                # 5 x 5 x 5 patches, 1 channel, 32 features to compute.
        weights = {'W_conv1':tf.Variable(tf.random_normal([3,3,3,1,32])),
                   #       5 x 5 x 5 patches, 32 channels, 64 features to compute.
                   'W_conv2':tf.Variable(tf.random_normal([3,3,3,32,64])),
                   #                                  64 features
                   'W_fc':tf.Variable(tf.random_normal([54080,1024])),
                   'out':tf.Variable(tf.random_normal([1024, n_classes]))}

        biases = {'b_conv1':tf.Variable(tf.random_normal([32])),
                   'b_conv2':tf.Variable(tf.random_normal([64])),
                   'b_fc':tf.Variable(tf.random_normal([1024])),
                   'out':tf.Variable(tf.random_normal([n_classes]))}

        #                            image X      image Y        image Z
        x = tf.reshape(x, shape=[-1, IMG_SIZE_PX, IMG_SIZE_PX, SLICE_COUNT, 1])

        conv1 = tf.nn.relu(conv3d(x, weights['W_conv1']) + biases['b_conv1'])
        conv1 = maxpool3d(conv1)


        conv2 = tf.nn.relu(conv3d(conv1, weights['W_conv2']) + biases['b_conv2'])
        conv2 = maxpool3d(conv2)

        fc = tf.reshape(conv2,[-1, 54080])
        fc = tf.nn.relu(tf.matmul(fc, weights['W_fc'])+biases['b_fc'])
        fc = tf.nn.dropout(fc, keep_rate)

        output = tf.matmul(fc, weights['out'])+biases['out']

        return output


    much_data = np.load('muchdata-50-50-20.npy')
    # If you are working with the basic sample data, use maybe 2 instead of 100 here... you don't have enough data to really do this
    train_data = much_data[:-4]
    validation_data = much_data[-4:]


    def train_neural_network(x):
        print ('..........1.........')
        prediction = convolutional_neural_network(x)
        print ('..........2.........')
        #cost = tf.reduce_mean( tf.nn.softmax_cross_entropy_with_logits(prediction,y) )
        cost = tf.reduce_mean( tf.nn.softmax_cross_entropy_with_logits(logits=prediction,labels=y))
        print ('..........3.........')
        optimizer = tf.train.AdamOptimizer(learning_rate=1e-3).minimize(cost)
        print ('..........4.........')
        hm_epochs = 20
        with tf.Session() as sess:
            sess.run(tf.initialize_all_variables())

            successful_runs = 0
            total_runs = 0
            print ('..........5.........')
            for epoch in range(hm_epochs):
                epoch_loss = 0
                for data in train_data:
                    total_runs += 1
                    try:
                        X = data[0]
                        Y = data[1]
                        _, c = sess.run([optimizer, cost], feed_dict={x: X, y: Y})
                        epoch_loss += c
                        successful_runs += 1
                    except Exception as e:
                        # I am passing for the sake of notebook space, but we are getting 1 shaping issue from one 
                        # input tensor. Not sure why, will have to look into it. Guessing it's
                        # one of the depths that doesn't come to 20.
                        pass
                        #print(str(e))
                print ('..........6.........')
                print('Epoch', epoch+1, 'completed out of',hm_epochs,'loss:',epoch_loss)
                print ('..........7.........')
                correct = tf.equal(tf.argmax(prediction, 1), tf.argmax(y, 1))
                accuracy = tf.reduce_mean(tf.cast(correct, 'float'))

                print('Accuracy:',accuracy.eval({x:[i[0] for i in validation_data], y:[i[1] for i in validation_data]}))

            print('Done. Finishing accuracy:')
            print('Accuracy:',accuracy.eval({x:[i[0] for i in validation_data], y:[i[1] for i in validation_data]}))

            print('fitment percent:',successful_runs/total_runs)


    print (x)


    # Run this locally:
    train_neural_network(x)

P.S : resample() , segment_lung_mask() methods can be found from link 1.

  • Please include all of your code. In particular, we can't see the print statement which is causing your error. Although it certainly looks like the x:[i[0] for i in validation_data] is feeding in too much data at once. – Stephen Dec 6 '17 at 5:25
  • Hi Stephen.. I included the code. – user3789200 Dec 6 '17 at 6:12
  • What happens if you just run np.array(x) and np.array(y) without passing to TensorFlow? I suspect the Numpy shape information is invalid. – Allen Lavoie Dec 6 '17 at 18:01
4

For training you have

for data in train_data:
    total_runs += 1
    try:
        X = data[0]
        Y = data[1]
        _, c = sess.run([optimizer, cost], feed_dict={x: X, y: Y})

So x and y are, respectively, the first two elements of a single row of train_data.

However, when calculating the accuracy you have

print('Accuracy:',accuracy.eval({x:[i[0] for i in validation_data], y:[i[1] for i in validation_data]}))

So x is the first element of all rows of validation_data, which gives it dimensions of (20,310,310), which can't be broadcast to a placeholder of dimension (20). Ditto for y. (Broadcasting means that if you gave it a tensor of dimensions (20, 310) it would know to take each of the 310 columns and feed it to the placeholder separately. It can't figure out what to do with a tensor of (20, 310, 310).)

Incidentally, when you declare your placeholders it's a good idea to specify their dimensions, using None for the dimension depending on the number of separate examples. This way the program can warn you when dimensions don't match up.

  • Thanks a lot Stephan. Do you have any idea on how I can solve the issue from Tensorflow side. The working example's shape is like (20,50,50) in each and every patient. But in the existing example, the shape differs from patient to patient. Is there any way I can reshape each patient or adjust Tensorflow to allow to accept any dimensioned array. – user3789200 Dec 8 '17 at 21:23
  • 2
    There are some suggestions in stackoverflow.com/a/41916066/6504837 that might help. – Stephen Dec 10 '17 at 1:19
1

The error message seems to indicate that the placeholder tensors x and y have not been defined correctly. They should have the same shape as the input values X = data[0] and Y = data[1], such as

x = tf.placeholder(shape=[20,310,310], dtype=tf.float32)
# if y is a scalar:
y = tf.placeholder(shape=[], dtype=tf.float32)

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