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I am using tensorflow 1.10 Python 3.6

My code is based in the premade iris classification model provided by TensorFlow. This means, I am using a Tensorflow DNN premade classifier, with the following difference:

  • 10 features instead 4.
  • 5 classes instead 3.

The test and training files can be downloaded from the following link: https://www.dropbox.com/sh/nmu8i2i8xe6hvfq/AADQEOIHH8e-kUHQf8zmmDMDa?dl=0

I have made a code to export this classifier to a tflite format, however the accuracy in the python model is higher than 75% but when exported the accuracy decrease approximately to 45% this means approximately 30% Accuracy is lost (This is too much). I have tried the code with different set of data and in all of them the accuracy after exporting decrease a lot! This made me think that something is going wrong with the TocoConverter function or that maybe I am exporting to tflite incorrectly, missing a parameter or something like that.

This is the way I generate the model:

classifier = tf.estimator.DNNClassifier(
        feature_columns=my_feature_columns,
        hidden_units=[100, 500],
        optimizer=tf.train.AdagradOptimizer(learning_rate=0.003),
        n_classes=num_labels,
        model_dir="myModel")

And this is the function I am using to convert to tflite:

converter = tf.contrib.lite.TocoConverter.from_frozen_graph(final_model_path, input_arrays, output_arrays, input_shapes={"dnn/input_from_feature_columns/input_layer/concat": [1, 10]})
        tflite_model = converter.convert()

I share the complete code in which I also calculate the accuracy of the resulting .tflite file.

import argparse
import tensorflow as tf

import pandas as pd
import csv

from tensorflow.python.tools import freeze_graph
from tensorflow.python.tools import optimize_for_inference_lib
import numpy as np


parser = argparse.ArgumentParser()
parser.add_argument('--batch_size', default=100, type=int, help='batch size')
parser.add_argument('--train_steps', default=1000, type=int,
                    help='number of training steps')

features_global = None
feature_spec = None

MODEL_NAME = 'myModel'

def load_data(train_path, test_path):
    """Returns the iris dataset as (train_x, train_y), (test_x, test_y)."""

    with open(train_path, newline='') as f:
        reader = csv.reader(f)
        column_names = next(reader)

    y_name = column_names[-1]

    train = pd.read_csv(train_path, names=column_names, header=0)
    train_x, train_y = train, train.pop(y_name)

    test = pd.read_csv(test_path, names=column_names, header=0)
    test_x, test_y = test, test.pop(y_name)

    return (train_x, train_y), (test_x, test_y)


def train_input_fn(features, labels, batch_size):
    """An input function for training"""
    # Convert the inputs to a Dataset.
    dataset = tf.data.Dataset.from_tensor_slices((dict(features), labels))

    # Shuffle, repeat, and batch the examples.
    dataset = dataset.shuffle(1000).repeat().batch(batch_size)

    # Return the dataset.
    return dataset


def eval_input_fn(features, labels, batch_size):
    """An input function for evaluation or prediction"""
    features=dict(features)
    if labels is None:
        # No labels, use only features.
        inputs = features
    else:
        inputs = (features, labels)

    # Convert the inputs to a Dataset.
    dataset = tf.data.Dataset.from_tensor_slices(inputs)

    # Batch the examples
    assert batch_size is not None, "batch_size must not be None"
    dataset = dataset.batch(batch_size)

    # Return the dataset.
    return dataset


def main(argv):
    args = parser.parse_args(argv[1:])

    train_path = "trainData.csv"
    test_path = "testData.csv"

    # Fetch the data
    (train_x, train_y), (test_x, test_y) = load_data(train_path, test_path)

    # Load labels
    num_labels = 5

    # Feature columns describe how to use the input.
    my_feature_columns = []
    for key in train_x.keys():
        my_feature_columns.append(tf.feature_column.numeric_column(key=key))

    # Build 2 hidden layer DNN
    classifier = tf.estimator.DNNClassifier(
        feature_columns=my_feature_columns,
        hidden_units=[100, 500],
        optimizer=tf.train.AdagradOptimizer(learning_rate=0.003),
        # The model must choose between 'num_labels' classes.
        n_classes=num_labels,
        model_dir="myModel")

    # Train the Model
    classifier.train(
        input_fn=lambda:train_input_fn(train_x, train_y,
                                                args.batch_size),
        steps=args.train_steps)

    # Evaluate the model.
    eval_result = classifier.evaluate(
        input_fn=lambda:eval_input_fn(test_x, test_y,
                                                args.batch_size))

    print('\nTest set accuracy: {accuracy:0.3f}\n'.format(**eval_result))

    # Export model
    feature_spec = tf.feature_column.make_parse_example_spec(my_feature_columns)
    serve_input_fun = tf.estimator.export.build_parsing_serving_input_receiver_fn(feature_spec)
    saved_model_path = classifier.export_savedmodel(
            export_dir_base="out",
            serving_input_receiver_fn=serve_input_fun,
            as_text=True,
            checkpoint_path=classifier.latest_checkpoint(),
        )
    tf.reset_default_graph()
    var = tf.Variable(0)
    with tf.Session() as sess:
        # First let's load meta graph and restore weights
        sess.run(tf.global_variables_initializer())
        latest_checkpoint_path = classifier.latest_checkpoint()
        saver = tf.train.import_meta_graph(latest_checkpoint_path + '.meta')
        saver.restore(sess, latest_checkpoint_path)

        input_arrays = ["dnn/input_from_feature_columns/input_layer/concat"]
        output_arrays = ["dnn/logits/BiasAdd"]

        frozen_graph_def = tf.graph_util.convert_variables_to_constants(
            sess, sess.graph_def,
            output_node_names=["dnn/logits/BiasAdd"])

        frozen_graph = "out/frozen_graph.pb"

        with tf.gfile.FastGFile(frozen_graph, "wb") as f:
                f.write(frozen_graph_def.SerializeToString())

        # save original graphdef to text file
        with open("estimator_graph.pbtxt", "w") as fp:
            fp.write(str(sess.graph_def))
        # save frozen graph def to text file
        with open("estimator_frozen_graph.pbtxt", "w") as fp:
            fp.write(str(frozen_graph_def))

        input_node_names = input_arrays
        output_node_name = output_arrays
        output_graph_def = optimize_for_inference_lib.optimize_for_inference(
                frozen_graph_def, input_node_names, output_node_name,
                tf.float32.as_datatype_enum)

        final_model_path = 'out/opt_' + MODEL_NAME + '.pb'
        with tf.gfile.FastGFile(final_model_path, "wb") as f:
            f.write(output_graph_def.SerializeToString())

        tflite_file = "out/iris.tflite"

        converter = tf.contrib.lite.TocoConverter.from_frozen_graph(final_model_path, input_arrays, output_arrays, input_shapes={"dnn/input_from_feature_columns/input_layer/concat": [1, 10]})
        tflite_model = converter.convert()
        open(tflite_file, "wb").write(tflite_model)

        interpreter = tf.contrib.lite.Interpreter(model_path=tflite_file)
        interpreter.allocate_tensors()

        # Get input and output tensors.
        input_details = interpreter.get_input_details()
        output_details = interpreter.get_output_details()

        # Test model on random input data.
        input_shape = input_details[0]['shape']
        # change the following line to feed into your own data.
        input_data = np.array(np.random.random_sample(input_shape), dtype=np.float32)
        resultlist = list()
        df = pd.read_csv(test_path)
        expected = df.iloc[:, -1].values.tolist()
        with open(test_path, newline='') as f:
            reader = csv.reader(f)
            column_names = next(reader)
            for x in range(0, len(expected)):
                linea = next(reader)
                linea = linea[:len(linea) - 1]
                input_data2 = np.array(linea, dtype=np.float32)
                interpreter.set_tensor(input_details[0]['index'], [input_data2])
                interpreter.invoke()
                output_data = interpreter.get_tensor(output_details[0]['index'])
                #print(output_data)
                max = 0;
                longitud = len(output_data[0])

                for k in range(0, longitud):
                    if (output_data[0][k] > output_data[0][max]):
                        max = k
                resultlist.append(max)
            print(resultlist)

        coincidences = 0
        for pred_dict, expec in zip(resultlist, expected):
            if pred_dict == expec:
                coincidences = coincidences + 1

        print("tflite Accuracy: " + str(coincidences / len(expected)))


if __name__ == '__main__':
    tf.logging.set_verbosity(tf.logging.INFO)
    tf.app.run(main)

I hope some of you can identify the error, or give a possible solution

5
  • 1
    Jorge Jiménez, we met the same problem. the converted tflite model perform different from the frozen pb model. The accuracy of tflite is lower than the pb file. any suggestions? – xhsoldier Aug 31 '18 at 9:25
  • how big is the Accuracy difference that you are facing? which function are you using tf.contrib.lite.TocoConverter.from_frozen_graph? or tf.contrib.lite.TocoConverter.from_saved_model? – Jorge Jiménez Sep 2 '18 at 16:20
  • When I ran the code you provided on a Python 3.6 virtualenv with TensorFlow 1.10, I got the error "ValueError: Please freeze the graph using freeze_graph.py." When I replaced the call to from_frozen_graph with from_saved_model (with input_arrays, output_arrays, and input_shapes passed in), I was able to run and produce an accuracy of 0.5045045045045045. Which function are you using? I recommend trying to use tflite_diff with the .pb and .tflite file to make sure there is an error for the same input. Feel free to create a GitHub issue in order to allow a deeper dive into the issue. – Nupur Garg Sep 11 '18 at 18:21
  • Hi, thank you for taking the time to run the code!. Yes that is the almost the maximum accuracy I reached (51.05), I really don't know what is happening, I supposed that is some bug in the premade classifiers or with the convertion functions – Jorge Jiménez Sep 11 '18 at 19:00
  • Can you show me how did you use the "from saved model" method, every time I use that I got that some operators are not yet implemented: Here is a list of operators for which you will need custom implementations: AsString, ParseExample stackoverflow.com/questions/51845395/… I have already created an issue in github: github.com/tensorflow/tensorflow/issues/… – Jorge Jiménez Sep 11 '18 at 19:01
2

This question is answered here might help.

As mentioned in the answer share, doing some

pre-processing

on the image before it is fed into "interpreter.invoke()" solves the issue if that was the problem in the first place.

To elaborate on that here is a block quote from the shared link:

The below code you see is what I meant by pre-processing:

test_image = cv2.imread(file_name)

test_image = cv2.resize(test_image,(299,299),cv2.INTER_AREA)

test_image = np.expand_dims((test_image)/255,axis=0).astype(np.float32)

interpreter.set_tensor(input_tensor_index, test_image)

interpreter.invoke()

digit = np.argmax(output()[0])

#print(digit)

prediction = result[digit]

As you can see there are two crucial commands/pre-processing done on the image once it is read using "imread()":

i) The image should be resized to the size that is the "input_height" and "input_width" values of the input image/tensor that was used during the training. In my case (inception-v3) this was 299 for both "input_height" and "input_width". (Read the documentation of the model for this value or look for this variable in the file that you used to train or retrain the model)

ii) The next command in the above code is:

test_image = np.expand_dims((test_image)/255,axis=0).astype(np.float32)

I got this from the "formulae"/model code:

test_image = np.expand_dims((test_image - input_mean)/input_std, axis=0).astype(np.float32)

Reading the documentation revealed that for my architecture input_mean = 0 and input_std = 255.

Hope this helps.

0
1

I have met the same problem. It seems to me that the accuracy problem is mainly caused by failure to detect overlapping objects. I couldn't figure out what part of the code is wrong though.

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