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custom_css = """ | |
<style> | |
.container { | |
max-width: 100% !important; | |
padding-left: 0 !important; | |
padding-right: 0 !important; | |
} | |
.header { | |
padding: 30px; | |
margin-bottom: 30px; | |
text-align: center; | |
font-family: 'Helvetica Neue', Arial, sans-serif; | |
box-shadow: 0 2px 4px rgba(0,0,0,0.1); | |
} | |
.header h1 { | |
font-size: 36px; | |
margin-bottom: 15px; | |
font-weight: bold; | |
color: #333333; /* Explicitly set heading color */ | |
} | |
.header h2 { | |
font-size: 24px; | |
margin-bottom: 10px; | |
color: #333333; /* Explicitly set subheading color */ | |
} | |
.header p { | |
font-size: 18px; | |
margin: 5px 0; | |
color: #666666; | |
} | |
.blue-text { | |
color: #4a90e2; | |
} | |
/* Custom styles for slider container */ | |
.slider-container { | |
background-color: white !important; | |
padding-top: 0.9em; | |
padding-bottom: 0.9em; | |
} | |
/* Add gap before examples */ | |
.examples-holder { | |
margin-top: 2em; | |
} | |
/* Set fixed size for example videos */ | |
.gradio-container .gradio-examples .gr-sample { | |
width: 240px !important; | |
height: 135px !important; | |
object-fit: cover; | |
display: inline-block; | |
margin-right: 10px; | |
} | |
.gradio-container .gradio-examples { | |
display: flex; | |
flex-wrap: wrap; | |
gap: 10px; | |
} | |
/* Ensure the parent container does not stretch */ | |
.gradio-container .gradio-examples { | |
max-width: 100%; | |
overflow: hidden; | |
} | |
/* Additional styles to ensure proper sizing in Safari */ | |
.gradio-container .gradio-examples .gr-sample img { | |
width: 240px !important; | |
height: 135px !important; | |
object-fit: cover; | |
} | |
</style> | |
""" | |
custom_html = custom_css + """ | |
<div class="header"> | |
<h1><span class="blue-text">The Sound of Water</span>: Inferring Physical Properties from Pouring Liquids</h1> | |
<p><a href='https://bpiyush.github.io/pouring-water-website/'>Project Page</a> | | |
<a href='https://github.com/bpiyush/SoundOfWater'>Github</a> | | |
<a href='#'>Paper</a> | | |
<a href='https://huggingface.co/datasets/bpiyush/sound-of-water'>Data</a> | |
<a href='https://huggingface.co/bpiyush/sound-of-water-models'>Models</a></p> | |
</div> | |
""" | |
tips = """ | |
<div> | |
<br><br> | |
Please give us a π on <a href='https://github.com/bpiyush/SoundOfWater'>Github</a> if you like our work! | |
Tips to get better results: | |
<ul> | |
<li>Make sure there is not too much noise such that the pouring is audible.</li> | |
<li>The video is not used during the inference.</li> | |
</ul> | |
</div> | |
""" | |
import os | |
import sys | |
import gradio as gr | |
import torch | |
import numpy as np | |
import matplotlib.pyplot as plt | |
plt.rcParams["font.family"] = "serif" | |
import decord | |
import PIL, PIL.Image | |
import librosa | |
from IPython.display import Markdown, display | |
import pandas as pd | |
import shared.utils as su | |
import sound_of_water.audio_pitch.model as audio_models | |
import sound_of_water.data.audio_loader as audio_loader | |
import sound_of_water.data.audio_transforms as at | |
import sound_of_water.data.csv_loader as csv_loader | |
def read_html_file(file): | |
with open(file) as f: | |
return f.read() | |
def define_axes(figsize=(13, 4), width_ratios=[0.22, 0.78]): | |
fig, axes = plt.subplots( | |
1, 2, figsize=figsize, width_ratios=width_ratios, | |
layout="constrained", | |
) | |
return fig, axes | |
def show_frame_and_spectrogram(frame, spectrogram, visualise_args, axes=None): | |
"""Shows the frame and spectrogram side by side.""" | |
if axes is None: | |
fig, axes = define_axes() | |
else: | |
assert len(axes) == 2 | |
ax = axes[0] | |
ax.imshow(frame, aspect="auto") | |
ax.set_title("Example frame") | |
ax.set_xticks([]) | |
ax.set_yticks([]) | |
ax = axes[1] | |
audio_loader.show_logmelspectrogram( | |
S=spectrogram, | |
ax=ax, | |
show=False, | |
sr=visualise_args["sr"], | |
n_fft=visualise_args["n_fft"], | |
hop_length=visualise_args["hop_length"], | |
) | |
def scatter_pitch(ax, t, f, s=60, marker="o", color="limegreen", label="Pitch"): | |
"""Scatter plot of pitch.""" | |
ax.scatter(t, f, color=color, label=label, s=s, marker=marker) | |
ax.set_xlabel("Time (s)") | |
ax.set_ylabel("Frequency (Hz)") | |
ax.legend(loc="upper left") | |
def load_frame(video_path, video_backend="decord"): | |
if video_backend == "decord": | |
vr = decord.VideoReader(video_path, num_threads=1) | |
frame = PIL.Image.fromarray(vr[0].asnumpy()) | |
elif video_backend == "torchvision": | |
import torchvision.io as tio | |
video, _, _ = tio.read_video(video_path, pts_unit="sec") | |
frame = video[0] | |
frame = PIL.Image.fromarray(frame.numpy()) | |
else: | |
raise ValueError(f"Unknown video backend: {video_backend}") | |
frame = audio_loader.crop_or_pad_to_size(frame, size=(270, 480)) | |
return frame | |
def load_spectrogram(video_path): | |
y = audio_loader.load_audio_clips( | |
audio_path=video_path, | |
clips=None, | |
load_entire=True, | |
cut_to_clip_len=False, | |
**aload_args, | |
)[0] | |
S = audio_loader.librosa_harmonic_spectrogram_db( | |
y, | |
sr=visualise_args["sr"], | |
n_fft=visualise_args["n_fft"], | |
hop_length=visualise_args["hop_length"], | |
n_mels=visualise_args['n_mels'], | |
) | |
return S | |
# Load audio | |
visualise_args = { | |
"sr": 16000, | |
"n_fft": 400, | |
"hop_length": 320, | |
"n_mels": 64, | |
"margin": 16., | |
"C": 340 * 100., | |
"audio_output_fps": 49., | |
"w_max": 100., | |
"n_bins": 64, | |
} | |
aload_args = { | |
"sr": 16000, | |
"clip_len": None, | |
"backend": "decord", | |
} | |
cfg_backbone = { | |
"name": "Wav2Vec2WithTimeEncoding", | |
"args": dict(), | |
} | |
backbone = getattr(audio_models, cfg_backbone["name"])( | |
**cfg_backbone["args"], | |
) | |
cfg_model = { | |
"name": "WavelengthWithTime", | |
"args": { | |
"axial": True, | |
"axial_bins": 64, | |
"radial": True, | |
"radial_bins": 64, | |
"freeze_backbone": True, | |
"train_backbone_modules": [6, 7, 8, 9, 10, 11], | |
"act": "softmax", | |
"criterion": "kl_div", | |
} | |
} | |
def load_model(): | |
model = getattr(audio_models, cfg_model["name"])( | |
backbone=backbone, **cfg_model["args"], | |
) | |
su.misc.num_params(model) | |
# Load the model weights from trained checkpoint | |
# NOTE: Be sure to set the correct path to the checkpoint | |
su.log.print_update("[:::] Loading checkpoint ", color="cyan", fillchar=".", pos="left") | |
# ckpt_dir = "/work/piyush/pretrained_checkpoints/SoundOfWater" | |
ckpt_dir = "./checkpoints" | |
ckpt_path = os.path.join( | |
ckpt_dir, | |
"dsr9mf13_ep100_step12423_real_finetuned_with_cosupervision.pth", | |
) | |
assert os.path.exists(ckpt_path), \ | |
f"Checkpoint not found at {ckpt_path}." | |
print("Loading checkpoint from: ", ckpt_path) | |
ckpt = torch.load(ckpt_path, map_location="cpu") | |
msg = model.load_state_dict(ckpt) | |
print(msg) | |
return model | |
# Define audio transforms | |
cfg_transform = { | |
"audio": { | |
"wave": [ | |
{ | |
"name": "AddNoise", | |
"args": { | |
"noise_level": 0.001 | |
}, | |
"augmentation": True, | |
}, | |
{ | |
"name": "ChangeVolume", | |
"args": { | |
"volume_factor": [0.8, 1.2] | |
}, | |
"augmentation": True, | |
}, | |
{ | |
"name": "Wav2Vec2WaveformProcessor", | |
"args": { | |
"model_name": "facebook/wav2vec2-base-960h", | |
"sr": 16000 | |
} | |
} | |
], | |
"spec": None, | |
} | |
} | |
audio_transform = at.define_audio_transforms( | |
cfg_transform, augment=False, | |
) | |
# Define audio pipeline arguments | |
apipe_args = { | |
"spec_args": None, | |
"stack": True, | |
} | |
def load_audio_tensor(video_path): | |
# Load and transform input audio | |
audio = audio_loader.load_and_process_audio( | |
audio_path=video_path, | |
clips=None, | |
load_entire=True, | |
cut_to_clip_len=False, | |
audio_transform=audio_transform, | |
aload_args=aload_args, | |
apipe_args=apipe_args, | |
)[0] | |
return audio | |
def get_model_output(audio, model): | |
with torch.no_grad(): | |
NS = audio.shape[-1] | |
duration = NS / 16000 | |
t = torch.tensor([[0, duration]]).unsqueeze(0) | |
x = audio.unsqueeze(0) | |
z_audio = model.backbone(x, t)[0][0].cpu() | |
y_audio = model(x, t)["axial"][0][0].cpu() | |
return z_audio, y_audio | |
def show_output(frame, S, y_audio, z_audio): | |
# duration = S.shape[-1] / visualise_args["sr"] | |
# print(S.shape, y_audio.shape, z_audio.shape) | |
duration = librosa.get_duration( | |
S=S, | |
sr=visualise_args["sr"], | |
n_fft=visualise_args["n_fft"], | |
hop_length=visualise_args["hop_length"], | |
) | |
timestamps = np.linspace(0., duration, 25) | |
# Get timestamps at evaluation frames | |
n_frames = len(y_audio) | |
timestamps_eval = librosa.frames_to_time( | |
np.arange(n_frames), | |
sr=visualise_args['sr'], | |
n_fft=visualise_args['n_fft'], | |
hop_length=visualise_args['hop_length'], | |
) | |
# Get predicted frequencies at these times | |
wavelengths = y_audio @ torch.linspace( | |
0, visualise_args['w_max'], visualise_args['n_bins'], | |
) | |
f_pred = visualise_args['C'] / wavelengths | |
# Pick only those timestamps where we define the true pitch | |
indices = su.misc.find_nearest_indices(timestamps_eval, timestamps) | |
f_pred = f_pred[indices] | |
# print(timestamps, f_pred) | |
# Show the true/pref pitch overlaid on the spectrogram | |
fig, axes = define_axes() | |
show_frame_and_spectrogram(frame, S, visualise_args, axes=axes) | |
scatter_pitch(axes[1], timestamps, f_pred, color="white", label="Estimated pitch", marker="o", s=70) | |
axes[1].set_title("True and predicted pitch overlaid on the spectrogram") | |
# plt.show() | |
# Convert to PIL Image and return the Image | |
from PIL import Image | |
# Draw the figure to a canvas | |
canvas = fig.canvas | |
canvas.draw() | |
# Get the RGBA buffer from the figure | |
w, h = fig.canvas.get_width_height() | |
buf = canvas.tostring_rgb() | |
# Create a PIL image from the RGB data | |
image = Image.frombytes("RGB", (w, h), buf) | |
# Get physical properties | |
l_pred = su.physics.estimate_length_of_air_column(wavelengths) | |
l_pred_mean = l_pred.mean().item() | |
l_pred_mean = np.round(l_pred_mean, 2) | |
H_pred = su.physics.estimate_cylinder_height(wavelengths) | |
H_pred = np.round(H_pred, 2) | |
R_pred = su.physics.estimate_cylinder_radius(wavelengths) | |
R_pred = np.round(R_pred, 2) | |
# print(f"Estimated length: {l_pred_mean} cm, Estimated height: {H_pred} cm, Estimated radius: {R_pred} cm") | |
df_show = pd.DataFrame({ | |
"Physical Property": ["Container height", "Container radius", "Length of air column (mean)"], | |
"Estimated Value (in cms)": [H_pred, R_pred, l_pred_mean], | |
}) | |
tsne_image = su.visualize.show_temporal_tsne( | |
z_audio.detach().numpy(), timestamps_eval, show=False, | |
figsize=(6, 5), title="Temporal t-SNE of latent features", | |
return_as_pil = True, | |
) | |
return image, df_show, tsne_image | |