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util.py
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util.py
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import math
from urllib.request import urlretrieve
import torch
from PIL import Image
from tqdm import tqdm
import numpy as np
import random
import torch.nn.functional as F
class Warp(object):
def __init__(self, size, interpolation=Image.BILINEAR):
self.size = int(size)
self.interpolation = interpolation
def __call__(self, img):
return img.resize((self.size, self.size), self.interpolation)
def __str__(self):
return self.__class__.__name__ + ' (size={size}, interpolation={interpolation})'.format(size=self.size,
interpolation=self.interpolation)
class MultiScaleCrop(object):
def __init__(self, input_size, scales=None, max_distort=1, fix_crop=True, more_fix_crop=True):
self.scales = scales if scales is not None else [1, 875, .75, .66]
self.max_distort = max_distort
self.fix_crop = fix_crop
self.more_fix_crop = more_fix_crop
self.input_size = input_size if not isinstance(input_size, int) else [input_size, input_size]
self.interpolation = Image.BILINEAR
def __call__(self, img):
im_size = img.size
crop_w, crop_h, offset_w, offset_h = self._sample_crop_size(im_size)
crop_img_group = img.crop((offset_w, offset_h, offset_w + crop_w, offset_h + crop_h))
ret_img_group = crop_img_group.resize((self.input_size[0], self.input_size[1]), self.interpolation)
return ret_img_group
def _sample_crop_size(self, im_size):
image_w, image_h = im_size[0], im_size[1]
# find a crop size
base_size = min(image_w, image_h)
crop_sizes = [int(base_size * x) for x in self.scales]
crop_h = [self.input_size[1] if abs(x - self.input_size[1]) < 3 else x for x in crop_sizes]
crop_w = [self.input_size[0] if abs(x - self.input_size[0]) < 3 else x for x in crop_sizes]
pairs = []
for i, h in enumerate(crop_h):
for j, w in enumerate(crop_w):
if abs(i - j) <= self.max_distort:
pairs.append((w, h))
crop_pair = random.choice(pairs)
if not self.fix_crop:
w_offset = random.randint(0, image_w - crop_pair[0])
h_offset = random.randint(0, image_h - crop_pair[1])
else:
w_offset, h_offset = self._sample_fix_offset(image_w, image_h, crop_pair[0], crop_pair[1])
return crop_pair[0], crop_pair[1], w_offset, h_offset
def _sample_fix_offset(self, image_w, image_h, crop_w, crop_h):
offsets = self.fill_fix_offset(self.more_fix_crop, image_w, image_h, crop_w, crop_h)
return random.choice(offsets)
@staticmethod
def fill_fix_offset(more_fix_crop, image_w, image_h, crop_w, crop_h):
w_step = (image_w - crop_w) // 4
h_step = (image_h - crop_h) // 4
ret = list()
ret.append((0, 0)) # upper left
ret.append((4 * w_step, 0)) # upper right
ret.append((0, 4 * h_step)) # lower left
ret.append((4 * w_step, 4 * h_step)) # lower right
ret.append((2 * w_step, 2 * h_step)) # center
if more_fix_crop:
ret.append((0, 2 * h_step)) # center left
ret.append((4 * w_step, 2 * h_step)) # center right
ret.append((2 * w_step, 4 * h_step)) # lower center
ret.append((2 * w_step, 0 * h_step)) # upper center
ret.append((1 * w_step, 1 * h_step)) # upper left quarter
ret.append((3 * w_step, 1 * h_step)) # upper right quarter
ret.append((1 * w_step, 3 * h_step)) # lower left quarter
ret.append((3 * w_step, 3 * h_step)) # lower righ quarter
return ret
def __str__(self):
return self.__class__.__name__
def download_url(url, destination=None, progress_bar=True):
"""Download a URL to a local file.
Parameters
----------
url : str
The URL to download.
destination : str, None
The destination of the file. If None is given the file is saved to a temporary directory.
progress_bar : bool
Whether to show a command-line progress bar while downloading.
Returns
-------
filename : str
The location of the downloaded file.
Notes
-----
Progress bar use/example adapted from tqdm documentation: https://github.com/tqdm/tqdm
"""
def my_hook(t):
last_b = [0]
def inner(b=1, bsize=1, tsize=None):
if tsize is not None:
t.total = tsize
if b > 0:
t.update((b - last_b[0]) * bsize)
last_b[0] = b
return inner
if progress_bar:
with tqdm(unit='B', unit_scale=True, miniters=1, desc=url.split('/')[-1]) as t:
filename, _ = urlretrieve(url, filename=destination, reporthook=my_hook(t))
else:
filename, _ = urlretrieve(url, filename=destination)
class AveragePrecisionMeter(object):
"""
The APMeter measures the average precision per class.
The APMeter is designed to operate on `NxK` Tensors `output` and
`target`, and optionally a `Nx1` Tensor weight where (1) the `output`
contains model output scores for `N` examples and `K` classes that ought to
be higher when the model is more convinced that the example should be
positively labeled, and smaller when the model believes the example should
be negatively labeled (for instance, the output of a sigmoid function); (2)
the `target` contains only values 0 (for negative examples) and 1
(for positive examples); and (3) the `weight` ( > 0) represents weight for
each sample.
"""
def __init__(self, difficult_examples=False):
super(AveragePrecisionMeter, self).__init__()
self.reset()
self.difficult_examples = difficult_examples
def reset(self):
"""Resets the meter with empty member variables"""
self.scores = torch.FloatTensor(torch.FloatStorage())
self.targets = torch.LongTensor(torch.LongStorage())
def add(self, output, target):
"""
Args:
output (Tensor): NxK tensor that for each of the N examples
indicates the probability of the example belonging to each of
the K classes, according to the model. The probabilities should
sum to one over all classes
target (Tensor): binary NxK tensort that encodes which of the K
classes are associated with the N-th input
(eg: a row [0, 1, 0, 1] indicates that the example is
associated with classes 2 and 4)
weight (optional, Tensor): Nx1 tensor representing the weight for
each example (each weight > 0)
"""
if not torch.is_tensor(output):
output = torch.from_numpy(output)
if not torch.is_tensor(target):
target = torch.from_numpy(target)
if output.dim() == 1:
output = output.view(-1, 1)
else:
assert output.dim() == 2, \
'wrong output size (should be 1D or 2D with one column \
per class)'
if target.dim() == 1:
target = target.view(-1, 1)
else:
assert target.dim() == 2, \
'wrong target size (should be 1D or 2D with one column \
per class)'
if self.scores.numel() > 0:
assert target.size(1) == self.targets.size(1), \
'dimensions for output should match previously added examples.'
# make sure storage is of sufficient size
if self.scores.storage().size() < self.scores.numel() + output.numel():
new_size = math.ceil(self.scores.storage().size() * 1.5)
self.scores.storage().resize_(int(new_size + output.numel()))
self.targets.storage().resize_(int(new_size + output.numel()))
# store scores and targets
offset = self.scores.size(0) if self.scores.dim() > 0 else 0
self.scores.resize_(offset + output.size(0), output.size(1))
self.targets.resize_(offset + target.size(0), target.size(1))
self.scores.narrow(0, offset, output.size(0)).copy_(output)
self.targets.narrow(0, offset, target.size(0)).copy_(target)
def value(self):
"""Returns the model's average precision for each class
Return:
ap (FloatTensor): 1xK tensor, with avg precision for each class k
"""
if self.scores.numel() == 0:
return 0
ap = torch.zeros(self.scores.size(1))
rg = torch.arange(1, self.scores.size(0)).float()
# compute average precision for each class
for k in range(self.scores.size(1)):
# sort scores
scores = self.scores[:, k]
targets = self.targets[:, k]
# compute average precision
ap[k] = AveragePrecisionMeter.average_precision(scores, targets, self.difficult_examples)
return ap
@staticmethod
def average_precision(output, target, difficult_examples=True):
# sort examples
sorted, indices = torch.sort(output, dim=0, descending=True)
# Computes prec@i
pos_count = 0.
total_count = 0.
precision_at_i = 0.
for i in indices:
label = target[i]
if difficult_examples and label == 0:
continue
if label == 1:
pos_count += 1
total_count += 1
if label == 1:
precision_at_i += pos_count / total_count
precision_at_i /= pos_count
return precision_at_i
def overall(self):
if self.scores.numel() == 0:
return 0
scores = self.scores.cpu().numpy()
targets = self.targets.cpu().numpy()
targets[targets == -1] = 0
return self.evaluation(scores, targets)
def overall_topk(self, k):
targets = self.targets.cpu().numpy()
targets[targets == -1] = 0
n, c = self.scores.size()
scores = np.zeros((n, c)) - 1
index = self.scores.topk(k, 1, True, True)[1].cpu().numpy()
tmp = self.scores.cpu().numpy()
for i in range(n):
for ind in index[i]:
scores[i, ind] = 1 if tmp[i, ind] >= 0 else -1
return self.evaluation(scores, targets)
def evaluation(self, scores_, targets_):
n, n_class = scores_.shape
Nc, Np, Ng = np.zeros(n_class), np.zeros(n_class), np.zeros(n_class)
for k in range(n_class):
scores = scores_[:, k]
targets = targets_[:, k]
targets[targets == -1] = 0
Ng[k] = np.sum(targets == 1)
Np[k] = np.sum(scores >= 0)
Nc[k] = np.sum(targets * (scores >= 0))
Np[Np == 0] = 1
OP = np.sum(Nc) / np.sum(Np)
OR = np.sum(Nc) / np.sum(Ng)
OF1 = (2 * OP * OR) / (OP + OR)
CP = np.sum(Nc / Np) / n_class
CR = np.sum(Nc / Ng) / n_class
CF1 = (2 * CP * CR) / (CP + CR)
return OP, OR, OF1, CP, CR, CF1
def gen_A(num_classes, t, adj_file):
import pickle
result = pickle.load(open(adj_file, 'rb'))
_adj = result['adj']
_nums = result['nums']
_nums = _nums[:, np.newaxis]
_adj = _adj / _nums
_adj[_adj < t] = 0
_adj[_adj >= t] = 1
_adj = _adj * 0.25 / (_adj.sum(0, keepdims=True) + 1e-6)
_adj = _adj + np.identity(num_classes, np.int)
return _adj
def gen_adj(A):
D = torch.pow(A.sum(1).float(), -0.5)
D = torch.diag(D)
adj = torch.matmul(torch.matmul(A, D).t(), D)
return adj