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ppcls/data/preprocess/ops/autoaugment.py 0 → 100644
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# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# This code is based on https://github.com/DeepVoltaire/AutoAugment/blob/master/autoaugment.py
from PIL import Image, ImageEnhance, ImageOps
import numpy as np
import random
class ImageNetPolicy(object):
""" Randomly choose one of the best 24 Sub-policies on ImageNet.
Example:
>>> policy = ImageNetPolicy()
>>> transformed = policy(image)
Example as a PyTorch Transform:
>>> transform=transforms.Compose([
>>> transforms.Resize(256),
>>> ImageNetPolicy(),
>>> transforms.ToTensor()])
"""
def __init__(self, fillcolor=(128, 128, 128)):
self.policies = [
SubPolicy(0.4, "posterize", 8, 0.6, "rotate", 9, fillcolor),
SubPolicy(0.6, "solarize", 5, 0.6, "autocontrast", 5, fillcolor),
SubPolicy(0.8, "equalize", 8, 0.6, "equalize", 3, fillcolor),
SubPolicy(0.6, "posterize", 7, 0.6, "posterize", 6, fillcolor),
SubPolicy(0.4, "equalize", 7, 0.2, "solarize", 4, fillcolor),
SubPolicy(0.4, "equalize", 4, 0.8, "rotate", 8, fillcolor),
SubPolicy(0.6, "solarize", 3, 0.6, "equalize", 7, fillcolor),
SubPolicy(0.8, "posterize", 5, 1.0, "equalize", 2, fillcolor),
SubPolicy(0.2, "rotate", 3, 0.6, "solarize", 8, fillcolor),
SubPolicy(0.6, "equalize", 8, 0.4, "posterize", 6, fillcolor),
SubPolicy(0.8, "rotate", 8, 0.4, "color", 0, fillcolor),
SubPolicy(0.4, "rotate", 9, 0.6, "equalize", 2, fillcolor),
SubPolicy(0.0, "equalize", 7, 0.8, "equalize", 8, fillcolor),
SubPolicy(0.6, "invert", 4, 1.0, "equalize", 8, fillcolor),
SubPolicy(0.6, "color", 4, 1.0, "contrast", 8, fillcolor),
SubPolicy(0.8, "rotate", 8, 1.0, "color", 2, fillcolor),
SubPolicy(0.8, "color", 8, 0.8, "solarize", 7, fillcolor),
SubPolicy(0.4, "sharpness", 7, 0.6, "invert", 8, fillcolor),
SubPolicy(0.6, "shearX", 5, 1.0, "equalize", 9, fillcolor),
SubPolicy(0.4, "color", 0, 0.6, "equalize", 3, fillcolor),
SubPolicy(0.4, "equalize", 7, 0.2, "solarize", 4, fillcolor),
SubPolicy(0.6, "solarize", 5, 0.6, "autocontrast", 5, fillcolor),
SubPolicy(0.6, "invert", 4, 1.0, "equalize", 8, fillcolor),
SubPolicy(0.6, "color", 4, 1.0, "contrast", 8, fillcolor),
SubPolicy(0.8, "equalize", 8, 0.6, "equalize", 3, fillcolor)
]
def __call__(self, img, policy_idx=None):
if policy_idx is None or not isinstance(policy_idx, int):
policy_idx = random.randint(0, len(self.policies) - 1)
else:
policy_idx = policy_idx % len(self.policies)
return self.policies[policy_idx](img)
def __repr__(self):
return "AutoAugment ImageNet Policy"
class CIFAR10Policy(object):
""" Randomly choose one of the best 25 Sub-policies on CIFAR10.
Example:
>>> policy = CIFAR10Policy()
>>> transformed = policy(image)
Example as a PyTorch Transform:
>>> transform=transforms.Compose([
>>> transforms.Resize(256),
>>> CIFAR10Policy(),
>>> transforms.ToTensor()])
"""
def __init__(self, fillcolor=(128, 128, 128)):
self.policies = [
SubPolicy(0.1, "invert", 7, 0.2, "contrast", 6, fillcolor),
SubPolicy(0.7, "rotate", 2, 0.3, "translateX", 9, fillcolor),
SubPolicy(0.8, "sharpness", 1, 0.9, "sharpness", 3, fillcolor),
SubPolicy(0.5, "shearY", 8, 0.7, "translateY", 9, fillcolor),
SubPolicy(0.5, "autocontrast", 8, 0.9, "equalize", 2, fillcolor),
SubPolicy(0.2, "shearY", 7, 0.3, "posterize", 7, fillcolor),
SubPolicy(0.4, "color", 3, 0.6, "brightness", 7, fillcolor),
SubPolicy(0.3, "sharpness", 9, 0.7, "brightness", 9, fillcolor),
SubPolicy(0.6, "equalize", 5, 0.5, "equalize", 1, fillcolor),
SubPolicy(0.6, "contrast", 7, 0.6, "sharpness", 5, fillcolor),
SubPolicy(0.7, "color", 7, 0.5, "translateX", 8, fillcolor),
SubPolicy(0.3, "equalize", 7, 0.4, "autocontrast", 8, fillcolor),
SubPolicy(0.4, "translateY", 3, 0.2, "sharpness", 6, fillcolor),
SubPolicy(0.9, "brightness", 6, 0.2, "color", 8, fillcolor),
SubPolicy(0.5, "solarize", 2, 0.0, "invert", 3, fillcolor),
SubPolicy(0.2, "equalize", 0, 0.6, "autocontrast", 0, fillcolor),
SubPolicy(0.2, "equalize", 8, 0.8, "equalize", 4, fillcolor),
SubPolicy(0.9, "color", 9, 0.6, "equalize", 6, fillcolor),
SubPolicy(0.8, "autocontrast", 4, 0.2, "solarize", 8, fillcolor),
SubPolicy(0.1, "brightness", 3, 0.7, "color", 0, fillcolor),
SubPolicy(0.4, "solarize", 5, 0.9, "autocontrast", 3, fillcolor),
SubPolicy(0.9, "translateY", 9, 0.7, "translateY", 9, fillcolor),
SubPolicy(0.9, "autocontrast", 2, 0.8, "solarize", 3, fillcolor),
SubPolicy(0.8, "equalize", 8, 0.1, "invert", 3, fillcolor),
SubPolicy(0.7, "translateY", 9, 0.9, "autocontrast", 1, fillcolor)
]
def __call__(self, img, policy_idx=None):
if policy_idx is None or not isinstance(policy_idx, int):
policy_idx = random.randint(0, len(self.policies) - 1)
else:
policy_idx = policy_idx % len(self.policies)
return self.policies[policy_idx](img)
def __repr__(self):
return "AutoAugment CIFAR10 Policy"
class SVHNPolicy(object):
""" Randomly choose one of the best 25 Sub-policies on SVHN.
Example:
>>> policy = SVHNPolicy()
>>> transformed = policy(image)
Example as a PyTorch Transform:
>>> transform=transforms.Compose([
>>> transforms.Resize(256),
>>> SVHNPolicy(),
>>> transforms.ToTensor()])
"""
def __init__(self, fillcolor=(128, 128, 128)):
self.policies = [
SubPolicy(0.9, "shearX", 4, 0.2, "invert", 3, fillcolor),
SubPolicy(0.9, "shearY", 8, 0.7, "invert", 5, fillcolor),
SubPolicy(0.6, "equalize", 5, 0.6, "solarize", 6, fillcolor),
SubPolicy(0.9, "invert", 3, 0.6, "equalize", 3, fillcolor),
SubPolicy(0.6, "equalize", 1, 0.9, "rotate", 3, fillcolor),
SubPolicy(0.9, "shearX", 4, 0.8, "autocontrast", 3, fillcolor),
SubPolicy(0.9, "shearY", 8, 0.4, "invert", 5, fillcolor),
SubPolicy(0.9, "shearY", 5, 0.2, "solarize", 6, fillcolor),
SubPolicy(0.9, "invert", 6, 0.8, "autocontrast", 1, fillcolor),
SubPolicy(0.6, "equalize", 3, 0.9, "rotate", 3, fillcolor),
SubPolicy(0.9, "shearX", 4, 0.3, "solarize", 3, fillcolor),
SubPolicy(0.8, "shearY", 8, 0.7, "invert", 4, fillcolor),
SubPolicy(0.9, "equalize", 5, 0.6, "translateY", 6, fillcolor),
SubPolicy(0.9, "invert", 4, 0.6, "equalize", 7, fillcolor),
SubPolicy(0.3, "contrast", 3, 0.8, "rotate", 4, fillcolor),
SubPolicy(0.8, "invert", 5, 0.0, "translateY", 2, fillcolor),
SubPolicy(0.7, "shearY", 6, 0.4, "solarize", 8, fillcolor),
SubPolicy(0.6, "invert", 4, 0.8, "rotate", 4, fillcolor),
SubPolicy(
0.3, "shearY", 7, 0.9, "translateX", 3, fillcolor), SubPolicy(
0.1, "shearX", 6, 0.6, "invert", 5, fillcolor), SubPolicy(
0.7, "solarize", 2, 0.6, "translateY", 7,
fillcolor), SubPolicy(0.8, "shearY", 4, 0.8, "invert",
8, fillcolor), SubPolicy(
0.7, "shearX", 9, 0.8,
"translateY", 3,
fillcolor), SubPolicy(
0.8, "shearY", 5, 0.7,
"autocontrast", 3,
fillcolor),
SubPolicy(0.7, "shearX", 2, 0.1, "invert", 5, fillcolor)
]
def __call__(self, img, policy_idx=None):
if policy_idx is None or not isinstance(policy_idx, int):
policy_idx = random.randint(0, len(self.policies) - 1)
else:
policy_idx = policy_idx % len(self.policies)
return self.policies[policy_idx](img)
def __repr__(self):
return "AutoAugment SVHN Policy"
class SubPolicy(object):
def __init__(self,
p1,
operation1,
magnitude_idx1,
p2,
operation2,
magnitude_idx2,
fillcolor=(128, 128, 128)):
ranges = {
"shearX": np.linspace(0, 0.3, 10),
"shearY": np.linspace(0, 0.3, 10),
"translateX": np.linspace(0, 150 / 331, 10),
"translateY": np.linspace(0, 150 / 331, 10),
"rotate": np.linspace(0, 30, 10),
"color": np.linspace(0.0, 0.9, 10),
"posterize": np.round(np.linspace(8, 4, 10), 0).astype(np.int),
"solarize": np.linspace(256, 0, 10),
"contrast": np.linspace(0.0, 0.9, 10),
"sharpness": np.linspace(0.0, 0.9, 10),
"brightness": np.linspace(0.0, 0.9, 10),
"autocontrast": [0] * 10,
"equalize": [0] * 10,
"invert": [0] * 10
}
# from https://stackoverflow.com/questions/5252170/specify-image-filling-color-when-rotating-in-python-with-pil-and-setting-expand
def rotate_with_fill(img, magnitude):
rot = img.convert("RGBA").rotate(magnitude)
return Image.composite(rot,
Image.new("RGBA", rot.size, (128, ) * 4),
rot).convert(img.mode)
func = {
"shearX": lambda img, magnitude: img.transform(
img.size, Image.AFFINE, (1, magnitude * random.choice([-1, 1]), 0, 0, 1, 0),
Image.BICUBIC, fillcolor=fillcolor),
"shearY": lambda img, magnitude: img.transform(
img.size, Image.AFFINE, (1, 0, 0, magnitude * random.choice([-1, 1]), 1, 0),
Image.BICUBIC, fillcolor=fillcolor),
"translateX": lambda img, magnitude: img.transform(
img.size, Image.AFFINE, (1, 0, magnitude * img.size[0] * random.choice([-1, 1]), 0, 1, 0),
fillcolor=fillcolor),
"translateY": lambda img, magnitude: img.transform(
img.size, Image.AFFINE, (1, 0, 0, 0, 1, magnitude * img.size[1] * random.choice([-1, 1])),
fillcolor=fillcolor),
"rotate": lambda img, magnitude: rotate_with_fill(img, magnitude),
# "rotate": lambda img, magnitude: img.rotate(magnitude * random.choice([-1, 1])),
"color": lambda img, magnitude: ImageEnhance.Color(img).enhance(1 + magnitude * random.choice([-1, 1])),
"posterize": lambda img, magnitude: ImageOps.posterize(img, magnitude),
"solarize": lambda img, magnitude: ImageOps.solarize(img, magnitude),
"contrast": lambda img, magnitude: ImageEnhance.Contrast(img).enhance(
1 + magnitude * random.choice([-1, 1])),
"sharpness": lambda img, magnitude: ImageEnhance.Sharpness(img).enhance(
1 + magnitude * random.choice([-1, 1])),
"brightness": lambda img, magnitude: ImageEnhance.Brightness(img).enhance(
1 + magnitude * random.choice([-1, 1])),
"autocontrast": lambda img, magnitude: ImageOps.autocontrast(img),
"equalize": lambda img, magnitude: ImageOps.equalize(img),
"invert": lambda img, magnitude: ImageOps.invert(img)
}
self.p1 = p1
self.operation1 = func[operation1]
self.magnitude1 = ranges[operation1][magnitude_idx1]
self.p2 = p2
self.operation2 = func[operation2]
self.magnitude2 = ranges[operation2][magnitude_idx2]
def __call__(self, img):
if random.random() < self.p1:
img = self.operation1(img, self.magnitude1)
if random.random() < self.p2:
img = self.operation2(img, self.magnitude2)
return img
ppcls/data/preprocess/ops/cutout.py 0 → 100644
浏览文件 @ 1d9c5710
# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# This code is based on https://github.com/uoguelph-mlrg/Cutout
import numpy as np
import random
class Cutout(object):
def __init__(self, n_holes=1, length=112):
self.n_holes = n_holes
self.length = length
def __call__(self, img):
""" cutout_image """
h, w = img.shape[:2]
mask = np.ones((h, w), np.float32)
for n in range(self.n_holes):
y = np.random.randint(h)
x = np.random.randint(w)
y1 = np.clip(y - self.length // 2, 0, h)
y2 = np.clip(y + self.length // 2, 0, h)
x1 = np.clip(x - self.length // 2, 0, w)
x2 = np.clip(x + self.length // 2, 0, w)
img[y1:y2, x1:x2] = 0
return img
ppcls/data/preprocess/ops/fmix.py 0 → 100644
浏览文件 @ 1d9c5710
# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import math
import random
import numpy as np
from scipy.stats import beta
def fftfreqnd(h, w=None, z=None):
""" Get bin values for discrete fourier transform of size (h, w, z)
:param h: Required, first dimension size
:param w: Optional, second dimension size
:param z: Optional, third dimension size
"""
fz = fx = 0
fy = np.fft.fftfreq(h)
if w is not None:
fy = np.expand_dims(fy, -1)
if w % 2 == 1:
fx = np.fft.fftfreq(w)[:w // 2 + 2]
else:
fx = np.fft.fftfreq(w)[:w // 2 + 1]
if z is not None:
fy = np.expand_dims(fy, -1)
if z % 2 == 1:
fz = np.fft.fftfreq(z)[:, None]
else:
fz = np.fft.fftfreq(z)[:, None]
return np.sqrt(fx * fx + fy * fy + fz * fz)
def get_spectrum(freqs, decay_power, ch, h, w=0, z=0):
""" Samples a fourier image with given size and frequencies decayed by decay power
:param freqs: Bin values for the discrete fourier transform
:param decay_power: Decay power for frequency decay prop 1/f**d
:param ch: Number of channels for the resulting mask
:param h: Required, first dimension size
:param w: Optional, second dimension size
:param z: Optional, third dimension size
"""
scale = np.ones(1) / (np.maximum(freqs, np.array([1. / max(w, h, z)]))
**decay_power)
param_size = [ch] + list(freqs.shape) + [2]
param = np.random.randn(*param_size)
scale = np.expand_dims(scale, -1)[None, :]
return scale * param
def make_low_freq_image(decay, shape, ch=1):
""" Sample a low frequency image from fourier space
:param decay_power: Decay power for frequency decay prop 1/f**d
:param shape: Shape of desired mask, list up to 3 dims
:param ch: Number of channels for desired mask
"""
freqs = fftfreqnd(*shape)
spectrum = get_spectrum(freqs, decay, ch,
*shape) #.reshape((1, *shape[:-1], -1))
spectrum = spectrum[:, 0] + 1j * spectrum[:, 1]
mask = np.real(np.fft.irfftn(spectrum, shape))
if len(shape) == 1:
mask = mask[:1, :shape[0]]
if len(shape) == 2:
mask = mask[:1, :shape[0], :shape[1]]
if len(shape) == 3:
mask = mask[:1, :shape[0], :shape[1], :shape[2]]
mask = mask
mask = (mask - mask.min())
mask = mask / mask.max()
return mask
def sample_lam(alpha, reformulate=False):
""" Sample a lambda from symmetric beta distribution with given alpha
:param alpha: Alpha value for beta distribution
:param reformulate: If True, uses the reformulation of [1].
"""
if reformulate:
lam = beta.rvs(alpha + 1, alpha)
else:
lam = beta.rvs(alpha, alpha)
return lam
def binarise_mask(mask, lam, in_shape, max_soft=0.0):
""" Binarises a given low frequency image such that it has mean lambda.
:param mask: Low frequency image, usually the result of `make_low_freq_image`
:param lam: Mean value of final mask
:param in_shape: Shape of inputs
:param max_soft: Softening value between 0 and 0.5 which smooths hard edges in the mask.
:return:
"""
idx = mask.reshape(-1).argsort()[::-1]
mask = mask.reshape(-1)
num = math.ceil(lam * mask.size) if random.random() > 0.5 else math.floor(
lam * mask.size)
eff_soft = max_soft
if max_soft > lam or max_soft > (1 - lam):
eff_soft = min(lam, 1 - lam)
soft = int(mask.size * eff_soft)
num_low = int(num - soft)
num_high = int(num + soft)
mask[idx[:num_high]] = 1
mask[idx[num_low:]] = 0
mask[idx[num_low:num_high]] = np.linspace(1, 0, (num_high - num_low))
mask = mask.reshape((1, 1, in_shape[0], in_shape[1]))
return mask
def sample_mask(alpha, decay_power, shape, max_soft=0.0, reformulate=False):
""" Samples a mean lambda from beta distribution parametrised by alpha, creates a low frequency image and binarises
it based on this lambda
:param alpha: Alpha value for beta distribution from which to sample mean of mask
:param decay_power: Decay power for frequency decay prop 1/f**d
:param shape: Shape of desired mask, list up to 3 dims
:param max_soft: Softening value between 0 and 0.5 which smooths hard edges in the mask.
:param reformulate: If True, uses the reformulation of [1].
"""
if isinstance(shape, int):
shape = (shape, )
# Choose lambda
lam = sample_lam(alpha, reformulate)
# Make mask, get mean / std
mask = make_low_freq_image(decay_power, shape)
mask = binarise_mask(mask, lam, shape, max_soft)
return float(lam), mask
def sample_and_apply(x,
alpha,
decay_power,
shape,
max_soft=0.0,
reformulate=False):
"""
:param x: Image batch on which to apply fmix of shape [b, c, shape*]
:param alpha: Alpha value for beta distribution from which to sample mean of mask
:param decay_power: Decay power for frequency decay prop 1/f**d
:param shape: Shape of desired mask, list up to 3 dims
:param max_soft: Softening value between 0 and 0.5 which smooths hard edges in the mask.
:param reformulate: If True, uses the reformulation of [1].
:return: mixed input, permutation indices, lambda value of mix,
"""
lam, mask = sample_mask(alpha, decay_power, shape, max_soft, reformulate)
index = np.random.permutation(x.shape[0])
x1, x2 = x * mask, x[index] * (1 - mask)
return x1 + x2, index, lam
class FMixBase:
""" FMix augmentation
Args:
decay_power (float): Decay power for frequency decay prop 1/f**d
alpha (float): Alpha value for beta distribution from which to sample mean of mask
size ([int] | [int, int] | [int, int, int]): Shape of desired mask, list up to 3 dims
max_soft (float): Softening value between 0 and 0.5 which smooths hard edges in the mask.
reformulate (bool): If True, uses the reformulation of [1].
"""
def __init__(self,
decay_power=3,
alpha=1,
size=(32, 32),
max_soft=0.0,
reformulate=False):
super().__init__()
self.decay_power = decay_power
self.reformulate = reformulate
self.size = size
self.alpha = alpha
self.max_soft = max_soft
self.index = None
self.lam = None
def __call__(self, x):
raise NotImplementedError
def loss(self, *args, **kwargs):
raise NotImplementedError
ppcls/data/preprocess/ops/functional.py 0 → 100644
浏览文件 @ 1d9c5710
# encoding: utf-8
import numpy as np
from PIL import Image, ImageOps, ImageEnhance
def int_parameter(level, maxval):
"""Helper function to scale `val` between 0 and maxval .
Args:
level: Level of the operation that will be between [0, `PARAMETER_MAX`].
maxval: Maximum value that the operation can have. This will be scaled to
level/PARAMETER_MAX.
Returns:
An int that results from scaling `maxval` according to `level`.
"""
return int(level * maxval / 10)
def float_parameter(level, maxval):
"""Helper function to scale `val` between 0 and maxval.
Args:
level: Level of the operation that will be between [0, `PARAMETER_MAX`].
maxval: Maximum value that the operation can have. This will be scaled to
level/PARAMETER_MAX.
Returns:
A float that results from scaling `maxval` according to `level`.
"""
return float(level) * maxval / 10.
def sample_level(n):
return np.random.uniform(low=0.1, high=n)
def autocontrast(pil_img, *args):
return ImageOps.autocontrast(pil_img)
def equalize(pil_img, *args):
return ImageOps.equalize(pil_img)
def posterize(pil_img, level, *args):
level = int_parameter(sample_level(level), 4)
return ImageOps.posterize(pil_img, 4 - level)
def rotate(pil_img, level, *args):
degrees = int_parameter(sample_level(level), 30)
if np.random.uniform() > 0.5:
degrees = -degrees
return pil_img.rotate(degrees, resample=Image.BILINEAR)
def solarize(pil_img, level, *args):
level = int_parameter(sample_level(level), 256)
return ImageOps.solarize(pil_img, 256 - level)
def shear_x(pil_img, level):
level = float_parameter(sample_level(level), 0.3)
if np.random.uniform() > 0.5:
level = -level
return pil_img.transform(pil_img.size,
Image.AFFINE, (1, level, 0, 0, 1, 0),
resample=Image.BILINEAR)
def shear_y(pil_img, level):
level = float_parameter(sample_level(level), 0.3)
if np.random.uniform() > 0.5:
level = -level
return pil_img.transform(pil_img.size,
Image.AFFINE, (1, 0, 0, level, 1, 0),
resample=Image.BILINEAR)
def translate_x(pil_img, level):
level = int_parameter(sample_level(level), pil_img.size[0] / 3)
if np.random.random() > 0.5:
level = -level
return pil_img.transform(pil_img.size,
Image.AFFINE, (1, 0, level, 0, 1, 0),
resample=Image.BILINEAR)
def translate_y(pil_img, level):
level = int_parameter(sample_level(level), pil_img.size[1] / 3)
if np.random.random() > 0.5:
level = -level
return pil_img.transform(pil_img.size,
Image.AFFINE, (1, 0, 0, 0, 1, level),
resample=Image.BILINEAR)
# operation that overlaps with ImageNet-C's test set
def color(pil_img, level, *args):
level = float_parameter(sample_level(level), 1.8) + 0.1
return ImageEnhance.Color(pil_img).enhance(level)
# operation that overlaps with ImageNet-C's test set
def contrast(pil_img, level, *args):
level = float_parameter(sample_level(level), 1.8) + 0.1
return ImageEnhance.Contrast(pil_img).enhance(level)
# operation that overlaps with ImageNet-C's test set
def brightness(pil_img, level, *args):
level = float_parameter(sample_level(level), 1.8) + 0.1
return ImageEnhance.Brightness(pil_img).enhance(level)
# operation that overlaps with ImageNet-C's test set
def sharpness(pil_img, level, *args):
level = float_parameter(sample_level(level), 1.8) + 0.1
return ImageEnhance.Sharpness(pil_img).enhance(level)
augmentations = [
autocontrast, equalize, posterize, rotate, solarize, shear_x, shear_y,
translate_x, translate_y
]
\ No newline at end of file
ppcls/data/preprocess/ops/grid.py 0 → 100644
浏览文件 @ 1d9c5710
# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# This code is based on https://github.com/akuxcw/GridMask
import numpy as np
from PIL import Image
import pdb
# curr
CURR_EPOCH = 0
# epoch for the prob to be the upper limit
NUM_EPOCHS = 240
class GridMask(object):
def __init__(self, d1=96, d2=224, rotate=1, ratio=0.5, mode=0, prob=1.):
self.d1 = d1
self.d2 = d2
self.rotate = rotate
self.ratio = ratio
self.mode = mode
self.st_prob = prob
self.prob = prob
self.last_prob = -1
def set_prob(self):
global CURR_EPOCH
global NUM_EPOCHS
self.prob = self.st_prob * min(1, 1.0 * CURR_EPOCH / NUM_EPOCHS)
def __call__(self, img):
self.set_prob()
if abs(self.last_prob - self.prob) > 1e-10:
global CURR_EPOCH
global NUM_EPOCHS
print(
"self.prob is updated, self.prob={}, CURR_EPOCH: {}, NUM_EPOCHS: {}".
format(self.prob, CURR_EPOCH, NUM_EPOCHS))
self.last_prob = self.prob
# print("CURR_EPOCH: {}, NUM_EPOCHS: {}, self.prob is set as: {}".format(CURR_EPOCH, NUM_EPOCHS, self.prob) )
if np.random.rand() > self.prob:
return img
_, h, w = img.shape
hh = int(1.5 * h)
ww = int(1.5 * w)
d = np.random.randint(self.d1, self.d2)
#d = self.d
self.l = int(d * self.ratio + 0.5)
mask = np.ones((hh, ww), np.float32)
st_h = np.random.randint(d)
st_w = np.random.randint(d)
for i in range(-1, hh // d + 1):
s = d * i + st_h
t = s + self.l
s = max(min(s, hh), 0)
t = max(min(t, hh), 0)
mask[s:t, :] *= 0
for i in range(-1, ww // d + 1):
s = d * i + st_w
t = s + self.l
s = max(min(s, ww), 0)
t = max(min(t, ww), 0)
mask[:, s:t] *= 0
r = np.random.randint(self.rotate)
mask = Image.fromarray(np.uint8(mask))
mask = mask.rotate(r)
mask = np.asarray(mask)
mask = mask[(hh - h) // 2:(hh - h) // 2 + h, (ww - w) // 2:(ww - w) //
2 + w]
if self.mode == 1:
mask = 1 - mask
mask = np.expand_dims(mask, axis=0)
img = (img * mask).astype(img.dtype)
return img
ppcls/data/preprocess/ops/hide_and_seek.py 0 → 100644
浏览文件 @ 1d9c5710
# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# This code is based on https://github.com/kkanshul/Hide-and-Seek
import numpy as np
import random
class HideAndSeek(object):
def __init__(self):
# possible grid size, 0 means no hiding
self.grid_sizes = [0, 16, 32, 44, 56]
# hiding probability
self.hide_prob = 0.5
def __call__(self, img):
# randomly choose one grid size
grid_size = np.random.choice(self.grid_sizes)
_, h, w = img.shape
# hide the patches
if grid_size == 0:
return img
for x in range(0, w, grid_size):
for y in range(0, h, grid_size):
x_end = min(w, x + grid_size)
y_end = min(h, y + grid_size)
if (random.random() <= self.hide_prob):
img[:, x:x_end, y:y_end] = 0
return img
ppcls/data/preprocess/ops/operators.py 0 → 100644
浏览文件 @ 1d9c5710
"""
# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
from __future__ import unicode_literals
import six
import math
import random
import cv2
import numpy as np
from PIL import Image
from .autoaugment import ImageNetPolicy
from .functional import augmentations
class OperatorParamError(ValueError):
""" OperatorParamError
"""
pass
class DecodeImage(object):
""" decode image """
def __init__(self, to_rgb=True, to_np=False, channel_first=False):
self.to_rgb = to_rgb
self.to_np = to_np # to numpy
self.channel_first = channel_first # only enabled when to_np is True
def __call__(self, img):
if six.PY2:
assert type(img) is str and len(
img) > 0, "invalid input 'img' in DecodeImage"
else:
assert type(img) is bytes and len(
img) > 0, "invalid input 'img' in DecodeImage"
data = np.frombuffer(img, dtype='uint8')
img = cv2.imdecode(data, 1)
if self.to_rgb:
assert img.shape[2] == 3, 'invalid shape of image[%s]' % (
img.shape)
img = img[:, :, ::-1]
if self.channel_first:
img = img.transpose((2, 0, 1))
return img
class ResizeImage(object):
""" resize image """
def __init__(self, size=None, resize_short=None, interpolation=-1):
self.interpolation = interpolation if interpolation >= 0 else None
if resize_short is not None and resize_short > 0:
self.resize_short = resize_short
self.w = None
self.h = None
elif size is not None:
self.resize_short = None
self.w = size if type(size) is int else size[0]
self.h = size if type(size) is int else size[1]
else:
raise OperatorParamError("invalid params for ReisizeImage for '\
'both 'size' and 'resize_short' are None")
def __call__(self, img):
img_h, img_w = img.shape[:2]
if self.resize_short is not None:
percent = float(self.resize_short) / min(img_w, img_h)
w = int(round(img_w * percent))
h = int(round(img_h * percent))
else:
w = self.w
h = self.h
if self.interpolation is None:
return cv2.resize(img, (w, h))
else:
return cv2.resize(img, (w, h), interpolation=self.interpolation)
class CropImage(object):
""" crop image """
def __init__(self, size):
if type(size) is int:
self.size = (size, size)
else:
self.size = size # (h, w)
def __call__(self, img):
w, h = self.size
img_h, img_w = img.shape[:2]
w_start = (img_w - w) // 2
h_start = (img_h - h) // 2
w_end = w_start + w
h_end = h_start + h
return img[h_start:h_end, w_start:w_end, :]
class RandCropImage(object):
""" random crop image """
def __init__(self, size, scale=None, ratio=None, interpolation=-1):
self.interpolation = interpolation if interpolation >= 0 else None
if type(size) is int:
self.size = (size, size) # (h, w)
else:
self.size = size
self.scale = [0.08, 1.0] if scale is None else scale
self.ratio = [3. / 4., 4. / 3.] if ratio is None else ratio
def __call__(self, img):
size = self.size
scale = self.scale
ratio = self.ratio
aspect_ratio = math.sqrt(random.uniform(*ratio))
w = 1. * aspect_ratio
h = 1. / aspect_ratio
img_h, img_w = img.shape[:2]
bound = min((float(img_w) / img_h) / (w**2),
(float(img_h) / img_w) / (h**2))
scale_max = min(scale[1], bound)
scale_min = min(scale[0], bound)
target_area = img_w * img_h * random.uniform(scale_min, scale_max)
target_size = math.sqrt(target_area)
w = int(target_size * w)
h = int(target_size * h)
i = random.randint(0, img_w - w)
j = random.randint(0, img_h - h)
img = img[j:j + h, i:i + w, :]
if self.interpolation is None:
return cv2.resize(img, size)
else:
return cv2.resize(img, size, interpolation=self.interpolation)
class RandFlipImage(object):
""" random flip image
flip_code:
1: Flipped Horizontally
0: Flipped Vertically
-1: Flipped Horizontally & Vertically
"""
def __init__(self, flip_code=1):
assert flip_code in [-1, 0, 1
], "flip_code should be a value in [-1, 0, 1]"
self.flip_code = flip_code
def __call__(self, img):
if random.randint(0, 1) == 1:
return cv2.flip(img, self.flip_code)
else:
return img
class AutoAugment(object):
def __init__(self):
self.policy = ImageNetPolicy()
def __call__(self, img):
from PIL import Image
img = np.ascontiguousarray(img)
img = Image.fromarray(img)
img = self.policy(img)
img = np.asarray(img)
class NormalizeImage(object):
""" normalize image such as substract mean, divide std
"""
def __init__(self, scale=None, mean=None, std=None, order='chw'):
if isinstance(scale, str):
scale = eval(scale)
self.scale = np.float32(scale if scale is not None else 1.0 / 255.0)
mean = mean if mean is not None else [0.485, 0.456, 0.406]
std = std if std is not None else [0.229, 0.224, 0.225]
shape = (3, 1, 1) if order == 'chw' else (1, 1, 3)
self.mean = np.array(mean).reshape(shape).astype('float32')
self.std = np.array(std).reshape(shape).astype('float32')
def __call__(self, img):
from PIL import Image
if isinstance(img, Image.Image):
img = np.array(img)
assert isinstance(img,
np.ndarray), "invalid input 'img' in NormalizeImage"
return (img.astype('float32') * self.scale - self.mean) / self.std
class ToCHWImage(object):
""" convert hwc image to chw image
"""
def __init__(self):
pass
def __call__(self, img):
from PIL import Image
if isinstance(img, Image.Image):
img = np.array(img)
return img.transpose((2, 0, 1))
class AugMix(object):
""" Perform AugMix augmentation and compute mixture.
"""
def __init__(self, prob=0.5, aug_prob_coeff=0.1, mixture_width=3, mixture_depth=1, aug_severity=1):
"""
Args:
prob: Probability of taking augmix
aug_prob_coeff: Probability distribution coefficients.
mixture_width: Number of augmentation chains to mix per augmented example.
mixture_depth: Depth of augmentation chains. -1 denotes stochastic depth in [1, 3]'
aug_severity: Severity of underlying augmentation operators (between 1 to 10).
"""
# fmt: off
self.prob = prob
self.aug_prob_coeff = aug_prob_coeff
self.mixture_width = mixture_width
self.mixture_depth = mixture_depth
self.aug_severity = aug_severity
self.augmentations = augmentations
# fmt: on
def __call__(self, image):
"""Perform AugMix augmentations and compute mixture.
Returns:
mixed: Augmented and mixed image.
"""
if random.random() > self.prob:
# Avoid the warning: the given NumPy array is not writeable
return np.asarray(image).copy()
ws = np.float32(
np.random.dirichlet([self.aug_prob_coeff] * self.mixture_width))
m = np.float32(np.random.beta(self.aug_prob_coeff, self.aug_prob_coeff))
# image = Image.fromarray(image)
mix = np.zeros([image.shape[1], image.shape[0], 3])
for i in range(self.mixture_width):
image_aug = image.copy()
image_aug = Image.fromarray(image_aug)
depth = self.mixture_depth if self.mixture_depth > 0 else np.random.randint(1, 4)
for _ in range(depth):
op = np.random.choice(self.augmentations)
image_aug = op(image_aug, self.aug_severity)
mix += ws[i] * np.asarray(image_aug)
mixed = (1 - m) * image + m * mix
return mixed.astype(np.uint8)
ppcls/data/preprocess/ops/randaugment.py 0 → 100644
浏览文件 @ 1d9c5710
# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# This code is based on https://github.com/heartInsert/randaugment
from PIL import Image, ImageEnhance, ImageOps
import numpy as np
import random
class RandAugment(object):
def __init__(self, num_layers=2, magnitude=5, fillcolor=(128, 128, 128)):
self.num_layers = num_layers
self.magnitude = magnitude
self.max_level = 10
abso_level = self.magnitude / self.max_level
self.level_map = {
"shearX": 0.3 * abso_level,
"shearY": 0.3 * abso_level,
"translateX": 150.0 / 331 * abso_level,
"translateY": 150.0 / 331 * abso_level,
"rotate": 30 * abso_level,
"color": 0.9 * abso_level,
"posterize": int(4.0 * abso_level),
"solarize": 256.0 * abso_level,
"contrast": 0.9 * abso_level,
"sharpness": 0.9 * abso_level,
"brightness": 0.9 * abso_level,
"autocontrast": 0,
"equalize": 0,
"invert": 0
}
# from https://stackoverflow.com/questions/5252170/
# specify-image-filling-color-when-rotating-in-python-with-pil-and-setting-expand
def rotate_with_fill(img, magnitude):
rot = img.convert("RGBA").rotate(magnitude)
return Image.composite(rot,
Image.new("RGBA", rot.size, (128, ) * 4),
rot).convert(img.mode)
rnd_ch_op = random.choice
self.func = {
"shearX": lambda img, magnitude: img.transform(
img.size,
Image.AFFINE,
(1, magnitude * rnd_ch_op([-1, 1]), 0, 0, 1, 0),
Image.BICUBIC,
fillcolor=fillcolor),
"shearY": lambda img, magnitude: img.transform(
img.size,
Image.AFFINE,
(1, 0, 0, magnitude * rnd_ch_op([-1, 1]), 1, 0),
Image.BICUBIC,
fillcolor=fillcolor),
"translateX": lambda img, magnitude: img.transform(
img.size,
Image.AFFINE,
(1, 0, magnitude * img.size[0] * rnd_ch_op([-1, 1]), 0, 1, 0),
fillcolor=fillcolor),
"translateY": lambda img, magnitude: img.transform(
img.size,
Image.AFFINE,
(1, 0, 0, 0, 1, magnitude * img.size[1] * rnd_ch_op([-1, 1])),
fillcolor=fillcolor),
"rotate": lambda img, magnitude: rotate_with_fill(img, magnitude),
"color": lambda img, magnitude: ImageEnhance.Color(img).enhance(
1 + magnitude * rnd_ch_op([-1, 1])),
"posterize": lambda img, magnitude:
ImageOps.posterize(img, magnitude),
"solarize": lambda img, magnitude:
ImageOps.solarize(img, magnitude),
"contrast": lambda img, magnitude:
ImageEnhance.Contrast(img).enhance(
1 + magnitude * rnd_ch_op([-1, 1])),
"sharpness": lambda img, magnitude:
ImageEnhance.Sharpness(img).enhance(
1 + magnitude * rnd_ch_op([-1, 1])),
"brightness": lambda img, magnitude:
ImageEnhance.Brightness(img).enhance(
1 + magnitude * rnd_ch_op([-1, 1])),
"autocontrast": lambda img, magnitude:
ImageOps.autocontrast(img),
"equalize": lambda img, magnitude: ImageOps.equalize(img),
"invert": lambda img, magnitude: ImageOps.invert(img)
}
def __call__(self, img):
avaiable_op_names = list(self.level_map.keys())
for layer_num in range(self.num_layers):
op_name = np.random.choice(avaiable_op_names)
img = self.func[op_name](img, self.level_map[op_name])
return img
ppcls/data/preprocess/ops/random_erasing.py 0 → 100644
浏览文件 @ 1d9c5710
# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
#This code is based on https://github.com/zhunzhong07/Random-Erasing
import math
import random
import numpy as np
class RandomErasing(object):
def __init__(self,
EPSILON=0.5,
sl=0.02,
sh=0.4,
r1=0.3,
mean=[0., 0., 0.]):
self.EPSILON = EPSILON
self.mean = mean
self.sl = sl
self.sh = sh
self.r1 = r1
def __call__(self, img):
if random.uniform(0, 1) > self.EPSILON:
return img
for attempt in range(100):
area = img.shape[1] * img.shape[2]
target_area = random.uniform(self.sl, self.sh) * area
aspect_ratio = random.uniform(self.r1, 1 / self.r1)
h = int(round(math.sqrt(target_area * aspect_ratio)))
w = int(round(math.sqrt(target_area / aspect_ratio)))
if w < img.shape[2] and h < img.shape[1]:
x1 = random.randint(0, img.shape[1] - h)
y1 = random.randint(0, img.shape[2] - w)
if img.shape[0] == 3:
img[0, x1:x1 + h, y1:y1 + w] = self.mean[0]
img[1, x1:x1 + h, y1:y1 + w] = self.mean[1]
img[2, x1:x1 + h, y1:y1 + w] = self.mean[2]
else:
img[0, x1:x1 + h, y1:y1 + w] = self.mean[1]
return img
return img
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