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inference_for_voicemos.py
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inference_for_voicemos.py
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import argparse
import csv
import fnmatch
import os
import yaml
import numpy as np
import scipy
import torch
from tqdm import tqdm
from dataset import get_dataloader, get_dataset
from models.MBNet import MBNet
from models.LDNet import LDNet
import scipy.stats
import matplotlib
# Force matplotlib to not use any Xwindows backend.
matplotlib.use('Agg')
import matplotlib.pyplot as plt
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
MAX_FRAMES = 1250
def find_files(root_dir, query="*.wav", include_root_dir=True):
files = []
for root, dirnames, filenames in os.walk(root_dir, followlinks=True):
for filename in fnmatch.filter(filenames, query):
files.append(os.path.join(root, filename))
if not include_root_dir:
files = [file_.replace(root_dir + "/", "") for file_ in files]
return files
def save_results(ep, result, result_path):
if os.path.isfile(result_path):
with open(result_path, "r", newline='') as csvfile:
rows = list(csv.reader(csvfile))
data = {row[0]: row[1:] for row in rows}
else:
data = {}
data[str(ep)] = result
rows = [[k]+v for k, v in data.items()]
rows = sorted(rows, key=lambda x:int(x[0]))
with open(result_path, "w", newline='') as csvfile:
writer = csv.writer(csvfile)
writer.writerows(rows)
def inference(mode, model, ep, dataloader, systems, save_dir, name, dataset_name, return_posterior_scores=False):
if return_posterior_scores:
assert mode == "all_listeners"
ep_scores = []
predict_mean_scores = []
post_scores = []
true_mean_scores = []
predict_sys_mean_scores = {system:[] for system in systems}
true_sys_mean_scores = {system:[] for system in systems}
submission_scores = {}
for i, batch in enumerate(tqdm(dataloader)):
mag_sgrams_padded, avg_scores, sys_names, wav_names = batch
mag_sgrams_padded = mag_sgrams_padded.to(device)
# avoid OOM caused by long samples
mag_sgrams_padded = mag_sgrams_padded[:, :MAX_FRAMES]
# forward
with torch.no_grad():
if mode == "mean_net":
pred_mean_scores = model.only_mean_inference(spectrum = mag_sgrams_padded)
elif mode == "all_listeners":
pred_mean_scores, posterior_scores = model.average_inference(spectrum = mag_sgrams_padded, include_meanspk=return_posterior_scores)
posterior_scores = posterior_scores.cpu().detach().numpy()
post_scores.extend(posterior_scores.tolist())
elif mode == "mean_listener":
pred_mean_scores = model.mean_listener_inference(spectrum = mag_sgrams_padded)
else:
raise NotImplementedError
pred_mean_scores = pred_mean_scores.cpu().detach().numpy()
avg_scores = avg_scores.cpu().detach().numpy()
predict_mean_scores.extend(pred_mean_scores.tolist())
true_mean_scores.extend(avg_scores.tolist())
for j, sys_name in enumerate(sys_names):
predict_sys_mean_scores[sys_name].append(pred_mean_scores[j])
true_sys_mean_scores[sys_name].append(avg_scores[j])
for wav_name, pred_mean_score in zip(wav_names, list(pred_mean_scores)):
submission_scores[wav_name] = pred_mean_score
with torch.cuda.device(device):
torch.cuda.empty_cache()
with open(os.path.join(save_dir, dataset_name + "_" + mode + "_" + name, f"{ep}_answer.txt"), "w") as f:
for k, v in submission_scores.items():
f.write("{},{}\n".format(k, v))
predict_mean_scores = np.array(predict_mean_scores)
true_mean_scores = np.array(true_mean_scores)
predict_sys_mean_scores = np.array([np.mean(scores) for scores in predict_sys_mean_scores.values()])
true_sys_mean_scores = np.array([np.mean(scores) for scores in true_sys_mean_scores.values()])
# plot utterance-level histrogram
plt.style.use('seaborn-deep')
bins = np.linspace(1, 5, 40)
plt.figure(2)
plt.hist([true_mean_scores, predict_mean_scores], bins, label=['true_mos', 'predict_mos'])
plt.legend(loc='upper right')
plt.xlabel('MOS')
plt.ylabel('number')
plt.show()
plt.savefig(os.path.join(save_dir, dataset_name + "_" + mode + "_" + name, f'{ep}_distribution.png'), dpi=150)
plt.close()
# utterance level scores
MSE=np.mean((true_mean_scores-predict_mean_scores)**2)
LCC=np.corrcoef(true_mean_scores, predict_mean_scores)[0][1]
SRCC=scipy.stats.spearmanr(true_mean_scores, predict_mean_scores)[0]
KTAU=scipy.stats.kendalltau(true_mean_scores, predict_mean_scores)[0]
ep_scores += [MSE, LCC, SRCC, KTAU]
print("[UTTERANCE] {} MSE: {:.3f}, LCC: {:.3f}, SRCC: {:.3f}, KTAU: {:.3f}".format(name, float(MSE), float(LCC), float(SRCC), float(KTAU)))
# plotting utterance-level scatter plot
M=np.max([np.max(predict_mean_scores),5])
plt.figure(3)
plt.scatter(true_mean_scores, predict_mean_scores, s =15, color='b', marker='o', edgecolors='b', alpha=.20)
plt.xlim([0.5,M])
plt.ylim([0.5,M])
plt.xlabel('True MOS')
plt.ylabel('Predicted MOS')
plt.title('Utt level LCC= {:.4f}, SRCC= {:.4f}, MSE= {:.4f}, KTAU= {:.4f}'.format(LCC, SRCC, MSE, KTAU))
plt.show()
plt.savefig(os.path.join(save_dir, dataset_name + "_" + mode + "_" + name, f'{ep}_utt_scatter_plot_utt.png'), dpi=150)
plt.close()
# system level scores
MSE=np.mean((true_sys_mean_scores-predict_sys_mean_scores)**2)
LCC=np.corrcoef(true_sys_mean_scores, predict_sys_mean_scores)[0][1]
SRCC=scipy.stats.spearmanr(true_sys_mean_scores, predict_sys_mean_scores)[0]
KTAU=scipy.stats.kendalltau(true_sys_mean_scores, predict_sys_mean_scores)[0]
ep_scores += [MSE, LCC, SRCC, KTAU]
print("[SYSTEM] {} MSE: {:.3f}, LCC: {:.3f}, SRCC: {:.3f}, KTAU: {:.3f}".format(name, float(MSE), float(LCC), float(SRCC), float(KTAU)))
# plotting utterance-level scatter plot
M=np.max([np.max(predict_sys_mean_scores),5])
plt.figure(3)
plt.scatter(true_sys_mean_scores, predict_sys_mean_scores, s =15, color='b', marker='o', edgecolors='b')
plt.xlim([0.5,M])
plt.ylim([0.5,M])
plt.xlabel('True MOS')
plt.ylabel('Predicted MOS')
plt.title('Sys level LCC= {:.4f}, SRCC= {:.4f}, MSE= {:.4f}, KTAU= {:.4f}'.format(LCC, SRCC, MSE, KTAU))
plt.show()
plt.savefig(os.path.join(save_dir, dataset_name + "_" + mode + "_" + name, f'{ep}_sys_scatter_plot_utt.png'), dpi=150)
plt.close()
if return_posterior_scores:
post_scores = np.array(post_scores)
return ep_scores, post_scores
else:
return ep_scores, None
def main():
parser = argparse.ArgumentParser()
parser.add_argument("--phase", type=str, default = "valid", choices = ["valid", "test"])
parser.add_argument("--dataset_name", type=str, default = "BVCC")
parser.add_argument("--data_dir", type=str, default = "data/phase1-main/DATA")
parser.add_argument("--exp_dir", type=str, default="exp")
parser.add_argument("--tag", type=str, required=True)
parser.add_argument("--config", type=str, default=None)
parser.add_argument("--ep", type=str, default=None, help="If not specified, evaluate all ckpts.")
parser.add_argument("--start_ep", type=int, default=0, help="Epoch to start evaluation")
parser.add_argument("--mode", type=str, required=True, choices=["mean_net", "all_listeners", "mean_listener"],
help="Inference mode.")
args = parser.parse_args()
# define dir
save_dir = os.path.join(args.exp_dir, args.tag)
os.makedirs(os.path.join(save_dir, args.dataset_name + "_" + args.mode + "_" + args.phase), exist_ok=True)
# read config
if args.config is not None:
print("[Warning] You would probably use the existing config in the exp folder")
config_path = args.config
else:
config_path = os.path.join(save_dir, "config.yml")
with open(config_path, 'r') as file:
config = yaml.load(file, Loader=yaml.FullLoader)
# read dataset (batch size is always 1 to avoid padding)
dataset = get_dataset(args.dataset_name, args.data_dir, args.phase)
dataloader = get_dataloader(dataset, batch_size=1, num_workers=1, shuffle=False)
print("[Info] Number of {} samples: {}".format(args.phase, len(dataset)))
# define model
if config["model"] == "MBNet":
model = MBNet(config).to(device)
elif config["model"] == "LDNet":
model = LDNet(config).to(device)
else:
raise NotImplementedError
print("[Info] Model parameters: {}".format(model.get_num_params()))
# either perform inference on one ep (specified by args.ep) or all ep in expdir
if args.ep is not None:
all_ckpts = [os.path.join(save_dir, f"model-{args.ep}.pt")]
else:
# get all ckpts
all_ckpts = find_files(save_dir, "model-*.pt")
# loop through all ckpts
for model_path in all_ckpts:
ep = os.path.basename(model_path).split(".")[0].split("-")[1]
if int(ep) < args.start_ep:
continue
print("=================================================")
print(f"[Info] Evaluating ep {ep}")
model.load_state_dict(torch.load(model_path), strict=False)
model.eval()
result, _ = inference(args.mode, model, ep, dataloader, dataset.systems,
save_dir, args.phase, args.dataset_name, return_posterior_scores=False)
save_results(ep, result, os.path.join(save_dir, args.dataset_name + "_" + args.mode + ".csv"))
if __name__ == "__main__":
main()