The tfds.decode
API 允许您覆盖默认的特征解码。主要用例是跳过图像解码以提高性能。
使用示例
跳过图像解码
为了完全控制解码管道,或者在图像解码之前应用过滤器(以提高性能),您可以完全跳过图像解码。这适用于 tfds.features.Image
和 tfds.features.Video
。
ds = tfds.load('imagenet2012', split='train', decoders={
'image': tfds.decode.SkipDecoding(),
})
for example in ds.take(1):
assert example['image'].dtype == tf.string # Images are not decoded
在图像解码之前过滤/洗牌数据集
与前面的示例类似,您可以使用 tfds.decode.SkipDecoding()
在解码图像之前插入额外的 tf.data
管道自定义。这样,过滤后的图像将不会被解码,您可以使用更大的洗牌缓冲区。
# Load the base dataset without decoding
ds, ds_info = tfds.load(
'imagenet2012',
split='train',
decoders={
'image': tfds.decode.SkipDecoding(), # Image won't be decoded here
},
as_supervised=True,
with_info=True,
)
# Apply filter and shuffle
ds = ds.filter(lambda image, label: label != 10)
ds = ds.shuffle(10000)
# Then decode with ds_info.features['image']
ds = ds.map(
lambda image, label: ds_info.features['image'].decode_example(image), label)
同时裁剪和解码
要覆盖默认的 tf.io.decode_image
操作,您可以使用 tfds.decode.Decoder
对象,使用 tfds.decode.make_decoder()
装饰器。
@tfds.decode.make_decoder()
def decode_example(serialized_image, feature):
crop_y, crop_x, crop_height, crop_width = 10, 10, 64, 64
return tf.image.decode_and_crop_jpeg(
serialized_image,
[crop_y, crop_x, crop_height, crop_width],
channels=feature.feature.shape[-1],
)
ds = tfds.load('imagenet2012', split='train', decoders={
# With video, decoders are applied to individual frames
'image': decode_example(),
})
等效于
def decode_example(serialized_image, feature):
crop_y, crop_x, crop_height, crop_width = 10, 10, 64, 64
return tf.image.decode_and_crop_jpeg(
serialized_image,
[crop_y, crop_x, crop_height, crop_width],
channels=feature.shape[-1],
)
ds, ds_info = tfds.load(
'imagenet2012',
split='train',
with_info=True,
decoders={
'image': tfds.decode.SkipDecoding(), # Skip frame decoding
},
)
ds = ds.map(functools.partial(decode_example, feature=ds_info.features['image']))
自定义视频解码
视频是 Sequence(Image())
。当应用自定义解码器时,它们将应用于单个帧。这意味着图像解码器自动与视频兼容。
@tfds.decode.make_decoder()
def decode_example(serialized_image, feature):
crop_y, crop_x, crop_height, crop_width = 10, 10, 64, 64
return tf.image.decode_and_crop_jpeg(
serialized_image,
[crop_y, crop_x, crop_height, crop_width],
channels=feature.feature.shape[-1],
)
ds = tfds.load('ucf101', split='train', decoders={
# With video, decoders are applied to individual frames
'video': decode_example(),
})
等效于
def decode_frame(serialized_image):
"""Decodes a single frame."""
crop_y, crop_x, crop_height, crop_width = 10, 10, 64, 64
return tf.image.decode_and_crop_jpeg(
serialized_image,
[crop_y, crop_x, crop_height, crop_width],
channels=ds_info.features['video'].shape[-1],
)
def decode_video(example):
"""Decodes all individual frames of the video."""
video = example['video']
video = tf.map_fn(
decode_frame,
video,
dtype=ds_info.features['video'].dtype,
parallel_iterations=10,
)
example['video'] = video
return example
ds, ds_info = tfds.load('ucf101', split='train', with_info=True, decoders={
'video': tfds.decode.SkipDecoding(), # Skip frame decoding
})
ds = ds.map(decode_video) # Decode the video
仅解码特征的子集。
还可以通过仅指定所需的特征来完全跳过某些特征。所有其他特征将被忽略/跳过。
builder = tfds.builder('my_dataset')
builder.as_dataset(split='train', decoders=tfds.decode.PartialDecoding({
'image': True,
'metadata': {'num_objects', 'scene_name'},
'objects': {'label'},
})
TFDS 将选择与给定 tfds.decode.PartialDecoding
结构匹配的 builder.info.features
子集。
在上面的代码中,特征被隐式提取以匹配 builder.info.features
。也可以显式定义特征。上面的代码等效于
builder = tfds.builder('my_dataset')
builder.as_dataset(split='train', decoders=tfds.decode.PartialDecoding({
'image': tfds.features.Image(),
'metadata': {
'num_objects': tf.int64,
'scene_name': tfds.features.Text(),
},
'objects': tfds.features.Sequence({
'label': tfds.features.ClassLabel(names=[]),
}),
})
原始元数据(标签名称、图像形状等)会自动重复使用,因此不需要提供它们。
tfds.decode.SkipDecoding
可以通过 PartialDecoding(..., decoders={})
关键字参数传递给 tfds.decode.PartialDecoding
。