countgd / util /utils.py
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from collections import OrderedDict
from copy import deepcopy
import json
import warnings
import torch
import numpy as np
def slprint(x, name='x'):
if isinstance(x, (torch.Tensor, np.ndarray)):
print(f'{name}.shape:', x.shape)
elif isinstance(x, (tuple, list)):
print('type x:', type(x))
for i in range(min(10, len(x))):
slprint(x[i], f'{name}[{i}]')
elif isinstance(x, dict):
for k,v in x.items():
slprint(v, f'{name}[{k}]')
else:
print(f'{name}.type:', type(x))
def clean_state_dict(state_dict):
new_state_dict = OrderedDict()
for k, v in state_dict.items():
if k[:7] == 'module.':
k = k[7:] # remove `module.`
new_state_dict[k] = v
return new_state_dict
def renorm(img: torch.FloatTensor, mean=[0.485, 0.456, 0.406], std=[0.229, 0.224, 0.225]) \
-> torch.FloatTensor:
# img: tensor(3,H,W) or tensor(B,3,H,W)
# return: same as img
assert img.dim() == 3 or img.dim() == 4, "img.dim() should be 3 or 4 but %d" % img.dim()
if img.dim() == 3:
assert img.size(0) == 3, 'img.size(0) shoule be 3 but "%d". (%s)' % (img.size(0), str(img.size()))
img_perm = img.permute(1,2,0)
mean = torch.Tensor(mean)
std = torch.Tensor(std)
img_res = img_perm * std + mean
return img_res.permute(2,0,1)
else: # img.dim() == 4
assert img.size(1) == 3, 'img.size(1) shoule be 3 but "%d". (%s)' % (img.size(1), str(img.size()))
img_perm = img.permute(0,2,3,1)
mean = torch.Tensor(mean)
std = torch.Tensor(std)
img_res = img_perm * std + mean
return img_res.permute(0,3,1,2)
class CocoClassMapper():
def __init__(self) -> None:
self.category_map_str = {"1": 1, "2": 2, "3": 3, "4": 4, "5": 5, "6": 6, "7": 7, "8": 8, "9": 9, "10": 10, "11": 11, "13": 12, "14": 13, "15": 14, "16": 15, "17": 16, "18": 17, "19": 18, "20": 19, "21": 20, "22": 21, "23": 22, "24": 23, "25": 24, "27": 25, "28": 26, "31": 27, "32": 28, "33": 29, "34": 30, "35": 31, "36": 32, "37": 33, "38": 34, "39": 35, "40": 36, "41": 37, "42": 38, "43": 39, "44": 40, "46": 41, "47": 42, "48": 43, "49": 44, "50": 45, "51": 46, "52": 47, "53": 48, "54": 49, "55": 50, "56": 51, "57": 52, "58": 53, "59": 54, "60": 55, "61": 56, "62": 57, "63": 58, "64": 59, "65": 60, "67": 61, "70": 62, "72": 63, "73": 64, "74": 65, "75": 66, "76": 67, "77": 68, "78": 69, "79": 70, "80": 71, "81": 72, "82": 73, "84": 74, "85": 75, "86": 76, "87": 77, "88": 78, "89": 79, "90": 80}
self.origin2compact_mapper = {int(k):v-1 for k,v in self.category_map_str.items()}
self.compact2origin_mapper = {int(v-1):int(k) for k,v in self.category_map_str.items()}
def origin2compact(self, idx):
return self.origin2compact_mapper[int(idx)]
def compact2origin(self, idx):
return self.compact2origin_mapper[int(idx)]
def to_device(item, device):
if isinstance(item, torch.Tensor):
return item.to(device)
elif isinstance(item, list):
return [to_device(i, device) for i in item]
elif isinstance(item, dict):
return {k: to_device(v, device) for k,v in item.items()}
else:
raise NotImplementedError("Call Shilong if you use other containers! type: {}".format(type(item)))
#
def get_gaussian_mean(x, axis, other_axis, softmax=True):
"""
Args:
x (float): Input images(BxCxHxW)
axis (int): The index for weighted mean
other_axis (int): The other index
Returns: weighted index for axis, BxC
"""
mat2line = torch.sum(x, axis=other_axis)
# mat2line = mat2line / mat2line.mean() * 10
if softmax:
u = torch.softmax(mat2line, axis=2)
else:
u = mat2line / (mat2line.sum(2, keepdim=True) + 1e-6)
size = x.shape[axis]
ind = torch.linspace(0, 1, size).to(x.device)
batch = x.shape[0]
channel = x.shape[1]
index = ind.repeat([batch, channel, 1])
mean_position = torch.sum(index * u, dim=2)
return mean_position
def get_expected_points_from_map(hm, softmax=True):
"""get_gaussian_map_from_points
B,C,H,W -> B,N,2 float(0, 1) float(0, 1)
softargmax function
Args:
hm (float): Input images(BxCxHxW)
Returns:
weighted index for axis, BxCx2. float between 0 and 1.
"""
# hm = 10*hm
B,C,H,W = hm.shape
y_mean = get_gaussian_mean(hm, 2, 3, softmax=softmax) # B,C
x_mean = get_gaussian_mean(hm, 3, 2, softmax=softmax) # B,C
# return torch.cat((x_mean.unsqueeze(-1), y_mean.unsqueeze(-1)), 2)
return torch.stack([x_mean, y_mean], dim=2)
# Positional encoding (section 5.1)
# borrow from nerf
class Embedder:
def __init__(self, **kwargs):
self.kwargs = kwargs
self.create_embedding_fn()
def create_embedding_fn(self):
embed_fns = []
d = self.kwargs['input_dims']
out_dim = 0
if self.kwargs['include_input']:
embed_fns.append(lambda x : x)
out_dim += d
max_freq = self.kwargs['max_freq_log2']
N_freqs = self.kwargs['num_freqs']
if self.kwargs['log_sampling']:
freq_bands = 2.**torch.linspace(0., max_freq, steps=N_freqs)
else:
freq_bands = torch.linspace(2.**0., 2.**max_freq, steps=N_freqs)
for freq in freq_bands:
for p_fn in self.kwargs['periodic_fns']:
embed_fns.append(lambda x, p_fn=p_fn, freq=freq : p_fn(x * freq))
out_dim += d
self.embed_fns = embed_fns
self.out_dim = out_dim
def embed(self, inputs):
return torch.cat([fn(inputs) for fn in self.embed_fns], -1)
def get_embedder(multires, i=0):
import torch.nn as nn
if i == -1:
return nn.Identity(), 3
embed_kwargs = {
'include_input' : True,
'input_dims' : 3,
'max_freq_log2' : multires-1,
'num_freqs' : multires,
'log_sampling' : True,
'periodic_fns' : [torch.sin, torch.cos],
}
embedder_obj = Embedder(**embed_kwargs)
embed = lambda x, eo=embedder_obj : eo.embed(x)
return embed, embedder_obj.out_dim
class APOPMeter():
def __init__(self) -> None:
self.tp = 0
self.fp = 0
self.tn = 0
self.fn = 0
def update(self, pred, gt):
"""
Input:
pred, gt: Tensor()
"""
assert pred.shape == gt.shape
self.tp += torch.logical_and(pred == 1, gt == 1).sum().item()
self.fp += torch.logical_and(pred == 1, gt == 0).sum().item()
self.tn += torch.logical_and(pred == 0, gt == 0).sum().item()
self.tn += torch.logical_and(pred == 1, gt == 0).sum().item()
def update_cm(self, tp, fp, tn, fn):
self.tp += tp
self.fp += fp
self.tn += tn
self.tn += fn
def inverse_sigmoid(x, eps=1e-5):
x = x.clamp(min=0, max=1)
x1 = x.clamp(min=eps)
x2 = (1 - x).clamp(min=eps)
return torch.log(x1/x2)
import argparse
from util.slconfig import SLConfig
def get_raw_dict(args):
"""
return the dicf contained in args.
e.g:
>>> with open(path, 'w') as f:
json.dump(get_raw_dict(args), f, indent=2)
"""
if isinstance(args, argparse.Namespace):
return vars(args)
elif isinstance(args, dict):
return args
elif isinstance(args, SLConfig):
return args._cfg_dict
else:
raise NotImplementedError("Unknown type {}".format(type(args)))
def stat_tensors(tensor):
assert tensor.dim() == 1
tensor_sm = tensor.softmax(0)
entropy = (tensor_sm * torch.log(tensor_sm + 1e-9)).sum()
return {
'max': tensor.max(),
'min': tensor.min(),
'mean': tensor.mean(),
'var': tensor.var(),
'std': tensor.var() ** 0.5,
'entropy': entropy
}
class NiceRepr:
"""Inherit from this class and define ``__nice__`` to "nicely" print your
objects.
Defines ``__str__`` and ``__repr__`` in terms of ``__nice__`` function
Classes that inherit from :class:`NiceRepr` should redefine ``__nice__``.
If the inheriting class has a ``__len__``, method then the default
``__nice__`` method will return its length.
Example:
>>> class Foo(NiceRepr):
... def __nice__(self):
... return 'info'
>>> foo = Foo()
>>> assert str(foo) == '<Foo(info)>'
>>> assert repr(foo).startswith('<Foo(info) at ')
Example:
>>> class Bar(NiceRepr):
... pass
>>> bar = Bar()
>>> import pytest
>>> with pytest.warns(None) as record:
>>> assert 'object at' in str(bar)
>>> assert 'object at' in repr(bar)
Example:
>>> class Baz(NiceRepr):
... def __len__(self):
... return 5
>>> baz = Baz()
>>> assert str(baz) == '<Baz(5)>'
"""
def __nice__(self):
"""str: a "nice" summary string describing this module"""
if hasattr(self, '__len__'):
# It is a common pattern for objects to use __len__ in __nice__
# As a convenience we define a default __nice__ for these objects
return str(len(self))
else:
# In all other cases force the subclass to overload __nice__
raise NotImplementedError(
f'Define the __nice__ method for {self.__class__!r}')
def __repr__(self):
"""str: the string of the module"""
try:
nice = self.__nice__()
classname = self.__class__.__name__
return f'<{classname}({nice}) at {hex(id(self))}>'
except NotImplementedError as ex:
warnings.warn(str(ex), category=RuntimeWarning)
return object.__repr__(self)
def __str__(self):
"""str: the string of the module"""
try:
classname = self.__class__.__name__
nice = self.__nice__()
return f'<{classname}({nice})>'
except NotImplementedError as ex:
warnings.warn(str(ex), category=RuntimeWarning)
return object.__repr__(self)
def ensure_rng(rng=None):
"""Coerces input into a random number generator.
If the input is None, then a global random state is returned.
If the input is a numeric value, then that is used as a seed to construct a
random state. Otherwise the input is returned as-is.
Adapted from [1]_.
Args:
rng (int | numpy.random.RandomState | None):
if None, then defaults to the global rng. Otherwise this can be an
integer or a RandomState class
Returns:
(numpy.random.RandomState) : rng -
a numpy random number generator
References:
.. [1] https://gitlab.kitware.com/computer-vision/kwarray/blob/master/kwarray/util_random.py#L270 # noqa: E501
"""
if rng is None:
rng = np.random.mtrand._rand
elif isinstance(rng, int):
rng = np.random.RandomState(rng)
else:
rng = rng
return rng
def random_boxes(num=1, scale=1, rng=None):
"""Simple version of ``kwimage.Boxes.random``
Returns:
Tensor: shape (n, 4) in x1, y1, x2, y2 format.
References:
https://gitlab.kitware.com/computer-vision/kwimage/blob/master/kwimage/structs/boxes.py#L1390
Example:
>>> num = 3
>>> scale = 512
>>> rng = 0
>>> boxes = random_boxes(num, scale, rng)
>>> print(boxes)
tensor([[280.9925, 278.9802, 308.6148, 366.1769],
[216.9113, 330.6978, 224.0446, 456.5878],
[405.3632, 196.3221, 493.3953, 270.7942]])
"""
rng = ensure_rng(rng)
tlbr = rng.rand(num, 4).astype(np.float32)
tl_x = np.minimum(tlbr[:, 0], tlbr[:, 2])
tl_y = np.minimum(tlbr[:, 1], tlbr[:, 3])
br_x = np.maximum(tlbr[:, 0], tlbr[:, 2])
br_y = np.maximum(tlbr[:, 1], tlbr[:, 3])
tlbr[:, 0] = tl_x * scale
tlbr[:, 1] = tl_y * scale
tlbr[:, 2] = br_x * scale
tlbr[:, 3] = br_y * scale
boxes = torch.from_numpy(tlbr)
return boxes
class ModelEma(torch.nn.Module):
def __init__(self, model, decay=0.9997, device=None):
super(ModelEma, self).__init__()
# make a copy of the model for accumulating moving average of weights
self.module = deepcopy(model)
self.module.eval()
self.decay = decay
self.device = device # perform ema on different device from model if set
if self.device is not None:
self.module.to(device=device)
def _update(self, model, update_fn):
with torch.no_grad():
for ema_v, model_v in zip(self.module.state_dict().values(), model.state_dict().values()):
if self.device is not None:
model_v = model_v.to(device=self.device)
ema_v.copy_(update_fn(ema_v, model_v))
def update(self, model):
self._update(model, update_fn=lambda e, m: self.decay * e + (1. - self.decay) * m)
def set(self, model):
self._update(model, update_fn=lambda e, m: m)
class BestMetricSingle():
def __init__(self, init_res=0.0, better='large') -> None:
self.init_res = init_res
self.best_res = init_res
self.best_ep = -1
self.better = better
assert better in ['large', 'small']
def isbetter(self, new_res, old_res):
if self.better == 'large':
return new_res > old_res
if self.better == 'small':
return new_res < old_res
def update(self, new_res, ep):
if self.isbetter(new_res, self.best_res):
self.best_res = new_res
self.best_ep = ep
return True
return False
def __str__(self) -> str:
return "best_res: {}\t best_ep: {}".format(self.best_res, self.best_ep)
def __repr__(self) -> str:
return self.__str__()
def summary(self) -> dict:
return {
'best_res': self.best_res,
'best_ep': self.best_ep,
}
class BestMetricHolder():
def __init__(self, init_res=0.0, better='large', use_ema=False) -> None:
self.best_all = BestMetricSingle(init_res, better)
self.use_ema = use_ema
if use_ema:
self.best_ema = BestMetricSingle(init_res, better)
self.best_regular = BestMetricSingle(init_res, better)
def update(self, new_res, epoch, is_ema=False):
"""
return if the results is the best.
"""
if not self.use_ema:
return self.best_all.update(new_res, epoch)
else:
if is_ema:
self.best_ema.update(new_res, epoch)
return self.best_all.update(new_res, epoch)
else:
self.best_regular.update(new_res, epoch)
return self.best_all.update(new_res, epoch)
def summary(self):
if not self.use_ema:
return self.best_all.summary()
res = {}
res.update({f'all_{k}':v for k,v in self.best_all.summary().items()})
res.update({f'regular_{k}':v for k,v in self.best_regular.summary().items()})
res.update({f'ema_{k}':v for k,v in self.best_ema.summary().items()})
return res
def __repr__(self) -> str:
return json.dumps(self.summary(), indent=2)
def __str__(self) -> str:
return self.__repr__()