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#!/usr/bin/env python3
# Portions Copyright (c) Meta Platforms, Inc. and affiliates.
# All rights reserved.
# This source code is licensed under the license found in the
# LICENSE file in the root directory of this source tree.
import logging
import math
import torch
import torch.nn as nn
import torchaudio
from PIL import Image
from pytorchvideo import transforms as pv_transforms
from pytorchvideo.data.clip_sampling import ConstantClipsPerVideoSampler
from pytorchvideo.data.encoded_video import EncodedVideo
from torchvision import transforms
from torchvision.transforms._transforms_video import NormalizeVideo
from models.multimodal_preprocessors import SimpleTokenizer
DEFAULT_AUDIO_FRAME_SHIFT_MS = 10 # in milliseconds
BPE_PATH = "bpe/bpe_simple_vocab_16e6.txt.gz"
def waveform2melspec(waveform, sample_rate, num_mel_bins, target_length):
# Based on https://github.com/YuanGongND/ast/blob/d7d8b4b8e06cdaeb6c843cdb38794c1c7692234c/src/dataloader.py#L102
waveform -= waveform.mean()
fbank = torchaudio.compliance.kaldi.fbank(
waveform,
htk_compat=True,
sample_frequency=sample_rate,
use_energy=False,
window_type="hanning",
num_mel_bins=num_mel_bins,
dither=0.0,
frame_length=25,
frame_shift=DEFAULT_AUDIO_FRAME_SHIFT_MS,
)
# Convert to [mel_bins, num_frames] shape
fbank = fbank.transpose(0, 1)
# Pad to target_length
n_frames = fbank.size(1)
p = target_length - n_frames
# if p is too large (say >20%), flash a warning
if abs(p) / n_frames > 0.2:
logging.warning(
"Large gap between audio n_frames(%d) and "
"target_length (%d). Is the audio_target_length "
"setting correct?",
n_frames,
target_length,
)
# cut and pad
if p > 0:
fbank = torch.nn.functional.pad(fbank, (0, p), mode="constant", value=0)
elif p < 0:
fbank = fbank[:, 0:target_length]
# Convert to [1, mel_bins, num_frames] shape, essentially like a 1
# channel image
fbank = fbank.unsqueeze(0)
return fbank
def get_clip_timepoints(clip_sampler, duration):
# Read out all clips in this video
all_clips_timepoints = []
is_last_clip = False
end = 0.0
while not is_last_clip:
start, end, _, _, is_last_clip = clip_sampler(end, duration, annotation=None)
all_clips_timepoints.append((start, end))
return all_clips_timepoints
def load_and_transform_vision_data(image_paths, device):
if image_paths is None:
return None
image_outputs = []
for image_path in image_paths:
data_transform = transforms.Compose(
[
transforms.Resize(
224, interpolation=transforms.InterpolationMode.BICUBIC
),
transforms.CenterCrop(224),
transforms.ToTensor(),
transforms.Normalize(
mean=(0.48145466, 0.4578275, 0.40821073),
std=(0.26862954, 0.26130258, 0.27577711),
),
]
)
with open(image_path, "rb") as fopen:
image = Image.open(fopen).convert("RGB")
image = data_transform(image).to(device)
image_outputs.append(image)
return torch.stack(image_outputs, dim=0)
def load_and_transform_text(text, device):
if text is None:
return None
tokenizer = SimpleTokenizer(bpe_path=BPE_PATH)
tokens = [tokenizer(t).unsqueeze(0).to(device) for t in text]
tokens = torch.cat(tokens, dim=0)
return tokens
def load_and_transform_audio_data(
audio_paths,
device,
num_mel_bins=128,
target_length=204,
sample_rate=16000,
clip_duration=2,
clips_per_video=3,
mean=-4.268,
std=9.138,
):
if audio_paths is None:
return None
audio_outputs = []
clip_sampler = ConstantClipsPerVideoSampler(
clip_duration=clip_duration, clips_per_video=clips_per_video
)
for audio_path in audio_paths:
waveform, sr = torchaudio.load(audio_path)
if sample_rate != sr:
waveform = torchaudio.functional.resample(
waveform, orig_freq=sr, new_freq=sample_rate
)
all_clips_timepoints = get_clip_timepoints(
clip_sampler, waveform.size(1) / sample_rate
)
all_clips = []
for clip_timepoints in all_clips_timepoints:
waveform_clip = waveform[
:,
int(clip_timepoints[0] * sample_rate) : int(
clip_timepoints[1] * sample_rate
),
]
waveform_melspec = waveform2melspec(
waveform_clip, sample_rate, num_mel_bins, target_length
)
all_clips.append(waveform_melspec)
normalize = transforms.Normalize(mean=mean, std=std)
all_clips = [normalize(ac).to(device) for ac in all_clips]
all_clips = torch.stack(all_clips, dim=0)
audio_outputs.append(all_clips)
return torch.stack(audio_outputs, dim=0)
def crop_boxes(boxes, x_offset, y_offset):
"""
Perform crop on the bounding boxes given the offsets.
Args:
boxes (ndarray or None): bounding boxes to perform crop. The dimension
is `num boxes` x 4.
x_offset (int): cropping offset in the x axis.
y_offset (int): cropping offset in the y axis.
Returns:
cropped_boxes (ndarray or None): the cropped boxes with dimension of
`num boxes` x 4.
"""
cropped_boxes = boxes.copy()
cropped_boxes[:, [0, 2]] = boxes[:, [0, 2]] - x_offset
cropped_boxes[:, [1, 3]] = boxes[:, [1, 3]] - y_offset
return cropped_boxes
def uniform_crop(images, size, spatial_idx, boxes=None, scale_size=None):
"""
Perform uniform spatial sampling on the images and corresponding boxes.
Args:
images (tensor): images to perform uniform crop. The dimension is
`num frames` x `channel` x `height` x `width`.
size (int): size of height and weight to crop the images.
spatial_idx (int): 0, 1, or 2 for left, center, and right crop if width
is larger than height. Or 0, 1, or 2 for top, center, and bottom
crop if height is larger than width.
boxes (ndarray or None): optional. Corresponding boxes to images.
Dimension is `num boxes` x 4.
scale_size (int): optinal. If not None, resize the images to scale_size before
performing any crop.
Returns:
cropped (tensor): images with dimension of
`num frames` x `channel` x `size` x `size`.
cropped_boxes (ndarray or None): the cropped boxes with dimension of
`num boxes` x 4.
"""
assert spatial_idx in [0, 1, 2]
ndim = len(images.shape)
if ndim == 3:
images = images.unsqueeze(0)
height = images.shape[2]
width = images.shape[3]
if scale_size is not None:
if width <= height:
width, height = scale_size, int(height / width * scale_size)
else:
width, height = int(width / height * scale_size), scale_size
images = torch.nn.functional.interpolate(
images,
size=(height, width),
mode="bilinear",
align_corners=False,
)
y_offset = int(math.ceil((height - size) / 2))
x_offset = int(math.ceil((width - size) / 2))
if height > width:
if spatial_idx == 0:
y_offset = 0
elif spatial_idx == 2:
y_offset = height - size
else:
if spatial_idx == 0:
x_offset = 0
elif spatial_idx == 2:
x_offset = width - size
cropped = images[:, :, y_offset : y_offset + size, x_offset : x_offset + size]
cropped_boxes = crop_boxes(boxes, x_offset, y_offset) if boxes is not None else None
if ndim == 3:
cropped = cropped.squeeze(0)
return cropped, cropped_boxes
class SpatialCrop(nn.Module):
"""
Convert the video into 3 smaller clips spatially. Must be used after the
temporal crops to get spatial crops, and should be used with
-2 in the spatial crop at the slowfast augmentation stage (so full
frames are passed in here). Will return a larger list with the
3x spatial crops as well.
"""
def __init__(self, crop_size: int = 224, num_crops: int = 3):
super().__init__()
self.crop_size = crop_size
if num_crops == 3:
self.crops_to_ext = [0, 1, 2]
self.flipped_crops_to_ext = []
elif num_crops == 1:
self.crops_to_ext = [1]
self.flipped_crops_to_ext = []
else:
raise NotImplementedError("Nothing else supported yet")
def forward(self, videos):
"""
Args:
videos: A list of C, T, H, W videos.
Returns:
videos: A list with 3x the number of elements. Each video converted
to C, T, H', W' by spatial cropping.
"""
assert isinstance(videos, list), "Must be a list of videos after temporal crops"
assert all([video.ndim == 4 for video in videos]), "Must be (C,T,H,W)"
res = []
for video in videos:
for spatial_idx in self.crops_to_ext:
res.append(uniform_crop(video, self.crop_size, spatial_idx)[0])
if not self.flipped_crops_to_ext:
continue
flipped_video = transforms.functional.hflip(video)
for spatial_idx in self.flipped_crops_to_ext:
res.append(uniform_crop(flipped_video, self.crop_size, spatial_idx)[0])
return res
def load_and_transform_video_data(
video_paths,
device,
clip_duration=2,
clips_per_video=5,
sample_rate=16000,
):
if video_paths is None:
return None
video_outputs = []
video_transform = transforms.Compose(
[
pv_transforms.ShortSideScale(224),
NormalizeVideo(
mean=(0.48145466, 0.4578275, 0.40821073),
std=(0.26862954, 0.26130258, 0.27577711),
),
]
)
clip_sampler = ConstantClipsPerVideoSampler(
clip_duration=clip_duration, clips_per_video=clips_per_video
)
frame_sampler = pv_transforms.UniformTemporalSubsample(num_samples=clip_duration)
for video_path in video_paths:
video = EncodedVideo.from_path(
video_path,
decoder="decord",
decode_audio=False,
**{"sample_rate": sample_rate},
)
all_clips_timepoints = get_clip_timepoints(clip_sampler, video.duration)
all_video = []
for clip_timepoints in all_clips_timepoints:
# Read the clip, get frames
clip = video.get_clip(clip_timepoints[0], clip_timepoints[1])
if clip is None:
raise ValueError("No clip found")
video_clip = frame_sampler(clip["video"])
video_clip = video_clip / 255.0 # since this is float, need 0-1
all_video.append(video_clip)
all_video = [video_transform(clip) for clip in all_video]
all_video = SpatialCrop(224, num_crops=3)(all_video)
all_video = torch.stack(all_video, dim=0)
video_outputs.append(all_video)
return torch.stack(video_outputs, dim=0).to(device)