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Amphion Evaluation Recipe

Supported Evaluation Metrics

Until now, Amphion Evaluation has supported the following objective metrics:

  • F0 Modeling:
    • F0 Pearson Coefficients (FPC)
    • F0 Periodicity Root Mean Square Error (PeriodicityRMSE)
    • F0 Root Mean Square Error (F0RMSE)
    • Voiced/Unvoiced F1 Score (V/UV F1)
  • Energy Modeling:
    • Energy Root Mean Square Error (EnergyRMSE)
    • Energy Pearson Coefficients (EnergyPC)
  • Intelligibility:
    • Character Error Rate (CER) based on Whipser
    • Word Error Rate (WER) based on Whipser
  • Spectrogram Distortion:
    • Frechet Audio Distance (FAD)
    • Mel Cepstral Distortion (MCD)
    • Multi-Resolution STFT Distance (MSTFT)
    • Perceptual Evaluation of Speech Quality (PESQ)
    • Short Time Objective Intelligibility (STOI)
    • Scale Invariant Signal to Distortion Ratio (SISDR)
    • Scale Invariant Signal to Noise Ratio (SISNR)
  • Speaker Similarity:

We provide a recipe to demonstrate how to objectively evaluate your generated audios. There are three steps in total:

  1. Pretrained Models Preparation
  2. Audio Data Preparation
  3. Evaluation

1. Pretrained Models Preparation

If you want to calculate RawNet3 based speaker similarity, you need to download the pretrained model first, as illustrated here.

2. Audio Data Preparation

Prepare reference audios and generated audios in two folders, the ref_dir contains the reference audio and the gen_dir contains the generated audio. Here is an example.

 ┣ {ref_dir}
 ┃ ┣ sample1.wav
 ┃ ┣ sample2.wav
 ┣ {gen_dir}
 ┃ ┣ sample1.wav
 ┃ ┣ sample2.wav

You have to make sure that the pairwise reference audio and generated audio are named the same, as illustrated above (sample1 to sample1, sample2 to sample2).

3. Evaluation

Run the run.sh with specified refenrece folder, generated folder, dump folder and metrics.

cd Amphion
sh egs/metrics/run.sh \
    --reference_folder [Your path to the reference audios] \
    --generated_folder [Your path to the generated audios] \
    --dump_folder [Your path to dump the objective results] \
    --metrics [The metrics you need] \
    --fs [Optional. To calculate all metrics in the specified sampling rate] \
    --similarity_model [Optional. To choose the model for calculating the speaker similarity. Currently "rawnet", "wavlm" and "resemblyzer" are available. Default to "wavlm"] \
    --similarity_mode [Optional. To choose the mode for calculating the speaker similarity. "pairwith" for calculating a series of ground truth / prediction audio pairs to obtain the speaker similarity, and "overall" for computing the average score with all possible pairs between the refernece folder and generated folder. Default to "pairwith"] \
    --intelligibility_mode [Optionoal. To choose the mode for computing CER and WER. "gt_audio" means selecting the recognition content of the reference audio as the target, "gt_content" means using transcription as the target. Default to "gt_audio"] \
    --ltr_path [Optional. Path to the transcription file] \
    --language [Optional. Language for computing CER and WER. Default to "english"]

As for the metrics, an example is provided below:

--metrics "mcd pesq fad"

All currently available metrics keywords are listed below:

Keys Description
fpc F0 Pearson Coefficients
f0_periodicity_rmse F0 Periodicity Root Mean Square Error
f0rmse F0 Root Mean Square Error
v_uv_f1 Voiced/Unvoiced F1 Score
energy_rmse Energy Root Mean Square Error
energy_pc Energy Pearson Coefficients
cer Character Error Rate
wer Word Error Rate
similarity Speaker Similarity
fad Frechet Audio Distance
mcd Mel Cepstral Distortion
mstft Multi-Resolution STFT Distance
pesq Perceptual Evaluation of Speech Quality
si_sdr Scale Invariant Signal to Distortion Ratio
si_snr Scale Invariant Signal to Noise Ratio
stoi Short Time Objective Intelligibility

For example, if want to calculate the speaker similarity between the synthesized audio and the reference audio with the same content, run:

sh egs/metrics/run.sh \
    --reference_folder [Your path to the reference audios] \
    --generated_folder [Your path to the generated audios] \
    --dump_folder [Your path to dump the objective results] \
    --metrics "similarity" \
    --similarity_model [Optional. To choose the model for calculating the speaker similarity. Currently "rawnet", "wavlm" and "resemblyzer" are available. Default to "wavlm"] \
    --similarity_mode "pairwith" \

If you don't have the reference audio with the same content, run the following to get the conteng-free similarity score:

sh egs/metrics/run.sh \
    --reference_folder [Your path to the reference audios] \
    --generated_folder [Your path to the generated audios] \
    --dump_folder [Your path to dump the objective results] \
    --metrics "similarity" \
    --similarity_model [Optional. To choose the model for calculating the speaker similarity. Currently "rawnet", "wavlm" and "resemblyzer" are available. Default to "wavlm"] \
    --similarity_mode "overall" \

Troubleshooting

FAD (Using Offline Models)

If your system is unable to access huggingface.co from the terminal, you might run into an error like "OSError: Can't load tokenizer for ...". To work around this, follow these steps to use local models:

  1. Download the bert-base-uncased, roberta-base, and facebook/bart-base models from huggingface.co. Ensure that the models are complete and uncorrupted. Place these directories within Amphion/pretrained. For a detailed file structure reference, see This README under Amphion/pretrained.
  2. Inside the Amphion/pretrained directory, create a bash script with the content outlined below. This script will automatically update the tokenizer paths used by your system:
#!/bin/bash

BERT_DIR="bert-base-uncased"
ROBERTA_DIR="roberta-base"
BART_DIR="facebook/bart-base"
PYTHON_SCRIPT="[YOUR ENV PATH]/lib/python3.9/site-packages/laion_clap/training/data.py"

update_tokenizer_path() {
    local dir_name=$1
    local tokenizer_variable=$2
    local full_path

    if [ -d "$dir_name" ]; then
        full_path=$(realpath "$dir_name")
        if [ -f "$PYTHON_SCRIPT" ]; then
            sed -i "s|${tokenizer_variable}.from_pretrained(\".*\")|${tokenizer_variable}.from_pretrained(\"$full_path\")|" "$PYTHON_SCRIPT"
            echo "Updated ${tokenizer_variable} path to $full_path."
        else
            echo "Error: The specified Python script does not exist."
            exit 1
        fi
    else
        echo "Error: The directory $dir_name does not exist in the current directory."
        exit 1
    fi
}

update_tokenizer_path "$BERT_DIR" "BertTokenizer"
update_tokenizer_path "$ROBERTA_DIR" "RobertaTokenizer"
update_tokenizer_path "$BART_DIR" "BartTokenizer"

echo "BERT, BART and RoBERTa Python script paths have been updated."
  1. The script provided is intended to adjust the tokenizer paths in the data.py file, found under /lib/python3.9/site-packages/laion_clap/training/, within your specific environment. For those utilizing conda, you can determine your environment path by running conda info --envs. Then, substitute [YOUR ENV PATH] in the script with this path. If your environment is configured differently, you'll need to update the PYTHON_SCRIPT variable to correctly point to the data.py file.
  2. Run the script. If it executes successfully, the tokenizer paths will be updated, allowing them to be loaded locally.

WavLM-based Speaker Similarity (Using Offline Models)

If your system is unable to access huggingface.co from the terminal and you want to calculate WavLM based speaker similarity, you need to download the pretrained model first, as illustrated here.