I keep getting an error ValueError: perm should have the same length as rank(x): 3 != 2 when trying to convert my model using coremltools.

From my understanding the most common case for this is when your input shape that you pass into coremltools doesn’t match your model input shape. However, as far as I can tell in my code it does match. I also added an input layer, and that didn’t help either.

I have put a lot of effort into reducing my code as much as possible while still giving a minimal complete verifiable example. However, I’m aware that the code is still a lot. Starting at line 60 of my code is where I create my model, and train it.

I’m running this on Ubuntu, with NVIDIA setup with Docker.

Any ideas what I’m doing wrong?


from typing import TypedDict, Optional, List
import tensorflow as tf
import json
from tensorflow.keras.optimizers import Adam
import numpy as np
from sklearn.utils import resample
import keras
import coremltools as ct

# Simple tokenizer function
word_index = {}
index = 1
def tokenize(text: str) -> list:
    global word_index
    global index
    words = text.lower().split()
    sequences = []
    for word in words:
        if word not in word_index:
            word_index[word] = index
            index += 1
        sequences.append(word_index[word])
    return sequences

def detokenize(sequence: list) -> str:
    global word_index
    # Filter sequence to remove all 0s
    sequence = [int(index) for index in sequence if index != 0.0]
    words = [word for word, index in word_index.items() if index in sequence]
    return ' '.join(words)

# Pad sequences to the same length
def pad_sequences(sequences: list, max_len: int) -> list:
    padded_sequences = []
    for seq in sequences:
        if len(seq) > max_len:
            padded_sequences.append(seq[:max_len])
        else:
            padded_sequences.append(seq + [0] * (max_len - len(seq)))
    return padded_sequences

class PreprocessDataResult(TypedDict):
    inputs: tf.Tensor
    labels: tf.Tensor
    max_len: int

def preprocess_data(texts: List[str], labels: List[int], max_len: Optional[int] = None) -> PreprocessDataResult:
    tokenized_texts = [tokenize(text) for text in texts]
    if max_len is None:
        max_len = max(len(seq) for seq in tokenized_texts)
    padded_texts = pad_sequences(tokenized_texts, max_len)

    return PreprocessDataResult({
        'inputs': tf.convert_to_tensor(np.array(padded_texts, dtype=np.float32)),
        'labels': tf.convert_to_tensor(np.array(labels, dtype=np.int32)),
        'max_len': max_len
    })

# Define your model architecture
def create_model(input_shape: int) -> keras.models.Sequential:
    model = keras.models.Sequential()

    model.add(keras.layers.Input(shape=(input_shape,), dtype='int32', name='embedding_input'))
    model.add(keras.layers.Embedding(input_dim=10000, output_dim=128)) # `input_dim` represents the size of the vocabulary (i.e. the number of unique words in the dataset).
    model.add(keras.layers.Bidirectional(keras.layers.LSTM(units=64, return_sequences=True)))
    model.add(keras.layers.Bidirectional(keras.layers.LSTM(units=32)))
    model.add(keras.layers.Dense(units=64, activation='relu'))
    model.add(keras.layers.Dropout(rate=0.5))
    model.add(keras.layers.Dense(units=1, activation='sigmoid')) # Output layer, binary classification (meaning it outputs a 0 or 1, false or true). The sigmoid function outputs a value between 0 and 1, which can be interpreted as a probability.

    model.compile(
        optimizer=Adam(),
        loss='binary_crossentropy',
        metrics=['accuracy']
    )

    return model

# Train the model
def train_model(
    model: tf.keras.models.Sequential,
    train_data: tf.Tensor,
    train_labels: tf.Tensor,
    epochs: int,
    batch_size: int
) -> tf.keras.callbacks.History:
    return model.fit(
        train_data,
        train_labels,
        epochs=epochs,
        batch_size=batch_size,
        callbacks=[
            keras.callbacks.EarlyStopping(monitor='val_accuracy', patience=5),
            keras.callbacks.TensorBoard(log_dir='./logs', histogram_freq=1),
            # When downgrading from TensorFlow 2.18.0 to 2.12.0 I had to change this from `./best_model.keras` to `./best_model.tf`
            keras.callbacks.ModelCheckpoint(filepath='./best_model.tf', monitor='val_accuracy', save_best_only=True)
        ]
    )

# Example usage
if __name__ == "__main__":
    # Check available devices
    print("Num GPUs Available: ", len(tf.config.experimental.list_physical_devices('GPU')))

    with tf.device('/GPU:0'):
        print("Loading data...")
        data = (["I love this!", "I hate this!"], [0, 1])
        rawTexts = data[0]
        rawLabels = data[1]

        # Preprocess data
        processedData = preprocess_data(rawTexts, rawLabels)
        inputs = processedData['inputs']
        labels = processedData['labels']
        max_len = processedData['max_len']

        print("Data loaded. Max length: ", max_len)

        # Save word_index to a file
        with open('./word_index.json', 'w') as file:
            json.dump(word_index, file)

        model = create_model(max_len)

        print('Training model...')
        train_model(model, inputs, labels, epochs=1, batch_size=32)
        print('Model trained.')

        # When downgrading from TensorFlow 2.18.0 to 2.12.0 I had to change this from `./best_model.keras` to `./best_model.tf`
        model.load_weights('./best_model.tf')
        print('Best model weights loaded.')

        # Save model
        # I think that .h5 extension allows for converting to CoreML, whereas .keras file extension does not
        model.save('./toxic_comment_analysis_model.h5')
        print('Model saved.')

        my_saved_model = tf.keras.models.load_model('./toxic_comment_analysis_model.h5')
        print('Model loaded.')

        print("Making prediction...")
        test_string = "Thank you. I really appreciate it."
        tokenized_string = tokenize(test_string)
        padded_texts = pad_sequences([tokenized_string], max_len)
        tensor = tf.convert_to_tensor(np.array(padded_texts, dtype=np.float32))
        predictions = my_saved_model.predict(tensor)
        print(predictions)
        print("Prediction made.")


        # Convert the Keras model to Core ML
        coreml_model = ct.convert(
            my_saved_model,
            inputs=[ct.TensorType(shape=(max_len,), name="embedding_input", dtype=np.int32)],
            source="tensorflow"
        )

        # Save the Core ML model
        coreml_model.save('toxic_comment_analysis_model.mlmodel')
        print("Model successfully converted to Core ML format.")

Code including Dockerfile & start script as GitHub Gist: https://gist.github.com/fishcharlie/af74d767a3ba1ffbf18cbc6d6a131089

  • Charlie FishOPMA
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    2 months ago

    This worked!!! However it now looks like I have to pass in 32 (batch size) comments in order to run a prediction in Core ML now? Kinda strange when I could pass in a single string to TensorFlow to run a prediction on.

    Also it seems to be much slower than my Create ML model I was playing with. Went from 0.05 ms on average for the Create ML model to 0.47 ms on average for this TensorFlow model. Looks like this TensorFlow model also is running 100% on the CPU (not taking advantage of GPU or Neural Engine).

    Obviously there are some major advantages to using TensorFlow (ie. I can run on a server environment, I can better control stopping training early based on that val_accuracy metric, etc). But Create ML seems to really win in other areas like being able to pass in a simple string (and not having to worry about tokenization), not having to pass in 32 strings in a single prediction, and the performance.

    Maybe I should lower my batch_size? I’ve heard there are pros and cons to lowering & increasing batch_size. Haven’t played around with it too much yet.

    Am I just missing something in this analysis?

    I really appreciate your help and advice!