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import future
import builtins
import past
import six
import inspect
import os
import torch
import torch.nn as nn
import torch.nn.functional as F
import torch.optim as optim
import numpy as np
import argparse
import decimal
import PIL
from torchvision import datasets, transforms
from datetime import datetime
from forbiddenfruit import curse
#from torch.autograd import Variable
from timeit import default_timer as timer
class Timer:
def __init__(self, activity = None, units = 1, shouldPrint = True, f = None):
self.activity = activity
self.units = units
self.shouldPrint = shouldPrint
self.f = f
def __enter__(self):
self.start = timer()
return self
def getUnitTime(self):
return (self.end - self.start) / self.units
def __str__(self):
return "Avg time to " + self.activity + ": "+str(self.getUnitTime())
def __exit__(self, *args):
self.end = timer()
if self.shouldPrint:
printBoth(self, f = self.f)
def cudify(x):
if use_cuda:
return x.cuda(async=True)
return x
def pyval(a, **kargs):
return dten([a], **kargs)
def ifThenElse(cond, a, b):
cond = cond.to_dtype()
return cond * a + (1 - cond) * b
def ifThenElseL(cond, a, b):
return cond * a + (1 - cond) * b
def product(it):
if isinstance(it,int):
return it
product = 1
for x in it:
if x >= 0:
product *= x
return product
def getEi(batches, num_elem):
return eye(num_elem).expand(batches, num_elem,num_elem).permute(1,0,2)
def one_hot(batch,d):
bs = batch.size()[0]
indexes = [ list(range(bs)), batch]
values = [ 1 for _ in range(bs) ]
return cudify(torch.sparse.FloatTensor(ltenCPU(indexes), ftenCPU(values), torch.Size([bs,d])))
def seye(n, m = None):
if m is None:
m = n
mn = n if n < m else m
indexes = [[ i for i in range(mn) ], [ i for i in range(mn) ] ]
values = [1 for i in range(mn) ]
return cudify(torch.sparse.ByteTensor(ltenCPU(indexes), dtenCPU(values), torch.Size([n,m])))
dtype = torch.float32
ftype = torch.float32
ltype = torch.int64
btype = torch.uint8
torch.set_default_dtype(dtype)
cpu = torch.device("cpu")
cuda_async = True
ftenCPU = lambda *args, **kargs: torch.tensor(*args, dtype=ftype, device=cpu, **kargs)
dtenCPU = lambda *args, **kargs: torch.tensor(*args, dtype=dtype, device=cpu, **kargs)
ltenCPU = lambda *args, **kargs: torch.tensor(*args, dtype=ltype, device=cpu, **kargs)
btenCPU = lambda *args, **kargs: torch.tensor(*args, dtype=btype, device=cpu, **kargs)
if torch.cuda.is_available() and not 'NOCUDA' in os.environ:
print("using cuda")
device = torch.device("cuda")
ften = lambda *args, **kargs: torch.tensor(*args, dtype=ftype, device=device, **kargs).cuda(non_blocking=cuda_async)
dten = lambda *args, **kargs: torch.tensor(*args, dtype=dtype, device=device, **kargs).cuda(non_blocking=cuda_async)
lten = lambda *args, **kargs: torch.tensor(*args, dtype=ltype, device=device, **kargs).cuda(non_blocking=cuda_async)
bten = lambda *args, **kargs: torch.tensor(*args, dtype=btype, device=device, **kargs).cuda(non_blocking=cuda_async)
ones = lambda *args, **cargs: torch.ones(*args, **cargs).cuda(non_blocking=cuda_async)
zeros = lambda *args, **cargs: torch.zeros(*args, **cargs).cuda(non_blocking=cuda_async)
eye = lambda *args, **cargs: torch.eye(*args, **cargs).cuda(non_blocking=cuda_async)
use_cuda = True
print("set up cuda")
else:
print("not using cuda")
ften = ftenCPU
dten = dtenCPU
lten = ltenCPU
bten = btenCPU
ones = torch.ones
zeros = torch.zeros
eye = torch.eye
use_cuda = False
device = cpu
def smoothmax(x, alpha, dim = 0):
return x.mul(F.softmax(x * alpha, dim)).sum(dim + 1)
def str2bool(v):
if v.lower() in ('yes', 'true', 't', 'y', '1'):
return True
elif v.lower() in ('no', 'false', 'f', 'n', '0'):
return False
else:
raise argparse.ArgumentTypeError('Boolean value expected.')
def flat(lst):
lst_ = []
for l in lst:
lst_ += l
return lst_
def printBoth(*st, f = None):
print(*st)
if not f is None:
print(*st, file=f)
def hasMethod(cl, mt):
return callable(getattr(cl, mt, None))
def getMethodNames(Foo):
return [func for func in dir(Foo) if callable(getattr(Foo, func)) and not func.startswith("__")]
def getMethods(Foo):
return [getattr(Foo, m) for m in getMethodNames(Foo)]
max_c_for_norm = 10000
def numel(arr):
return product(arr.size())
def chunks(l, n):
"""Yield successive n-sized chunks from l."""
for i in range(0, len(l), n):
yield l[i:i + n]
def loadDataset(dataset, batch_size, train, transform = True):
oargs = {}
if dataset in ["MNIST", "CIFAR10", "CIFAR100", "FashionMNIST", "PhotoTour"]:
oargs['train'] = train
elif dataset in ["STL10", "SVHN"] :
oargs['split'] = 'train' if train else 'test'
elif dataset in ["LSUN"]:
oargs['classes'] = 'train' if train else 'test'
elif dataset in ["Imagenet12"]:
pass
else:
raise Exception(dataset + " is not yet supported")
if dataset in ["MNIST"]:
transformer = transforms.Compose([ transforms.ToTensor()]
+ ([transforms.Normalize((0.1307,), (0.3081,))] if transform else []))
elif dataset in ["CIFAR10", "CIFAR100"]:
transformer = transforms.Compose(([ #transforms.RandomCrop(32, padding=4),
transforms.RandomAffine(0, (0.125, 0.125), resample=PIL.Image.BICUBIC) ,
transforms.RandomHorizontalFlip(),
#transforms.RandomRotation(15, resample = PIL.Image.BILINEAR)
] if train else [])
+ [transforms.ToTensor()]
+ ([transforms.Normalize((0.4914, 0.4822, 0.4465), (0.2023, 0.1994, 0.2010))] if transform else []))
elif dataset in ["SVHN"]:
transformer = transforms.Compose([
transforms.RandomHorizontalFlip(),
transforms.ToTensor(),
transforms.Normalize((0.5,0.5,0.5), (0.2,0.2,0.2))])
else:
transformer = transforms.ToTensor()
if dataset in ["Imagenet12"]:
# https://github.com/facebook/fb.resnet.torch/blob/master/INSTALL.md#download-the-imagenet-dataset
train_set = datasets.ImageFolder(
'../data/Imagenet12/train' if train else '../data/Imagenet12/val',
transforms.Compose([
transforms.RandomResizedCrop(224),
transforms.RandomHorizontalFlip(),
normalize,
]))
else:
train_set = getattr(datasets, dataset)('../data', download=True, transform=transformer, **oargs)
return torch.utils.data.DataLoader(
train_set
, batch_size=batch_size
, shuffle=True,
**({'num_workers': 1, 'pin_memory': True} if use_cuda else {}))
def variable(Pt):
class Point:
def isSafe(self,target):
pred = self.max(1, keepdim=True)[1] # get the index of the max log-probability
return pred.eq(target.data.view_as(pred))
def isPoint(self):
return True
def labels(self):
return [self[0].max(1)[1]] # get the index of the max log-probability
def softplus(self):
return F.softplus(self)
def elu(self):
return F.elu(self)
def selu(self):
return F.selu(self)
def sigm(self):
return F.sigmoid(self)
def conv3d(self, *args, **kargs):
return F.conv3d(self, *args, **kargs)
def conv2d(self, *args, **kargs):
return F.conv2d(self, *args, **kargs)
def conv1d(self, *args, **kargs):
return F.conv1d(self, *args, **kargs)
def conv_transpose3d(self, *args, **kargs):
return F.conv_transpose3d(self, *args, **kargs)
def conv_transpose2d(self, *args, **kargs):
return F.conv_transpose2d(self, *args, **kargs)
def conv_transpose1d(self, *args, **kargs):
return F.conv_transpose1d(self, *args, **kargs)
def max_pool2d(self, *args, **kargs):
return F.max_pool2d(self, *args, **kargs)
def avg_pool2d(self, *args, **kargs):
return F.avg_pool2d(self, *args, **kargs)
def adaptive_avg_pool2d(self, *args, **kargs):
return F.adaptive_avg_pool2d(self, *args, **kargs)
def cat(self, other, dim = 0, **kargs):
return torch.cat((self, other), dim = dim, **kargs)
def addPar(self, a, b):
return a + b
def abstractApplyLeaf(self, foo, *args, **kargs):
return self
def diameter(self):
return pyval(0)
def to_dtype(self):
return self.type(dtype=dtype, non_blocking=cuda_async)
def loss(self, target, **kargs):
if torch.__version__[0] == "0":
return F.cross_entropy(self, target, reduce = False)
else:
return F.cross_entropy(self, target, reduction='none')
def deep_loss(self, *args, **kargs):
return 0
def merge(self, *args, **kargs):
return self
def splitRelu(self, *args, **kargs):
return self
def lb(self):
return self
def vanillaTensorPart(self):
return self
def center(self):
return self
def ub(self):
return self
def cudify(self, cuda_async = True):
return self.cuda(non_blocking=cuda_async) if use_cuda else self
def log_softmax(self, *args, dim = 1, **kargs):
return F.log_softmax(self, *args,dim = dim, **kargs)
if torch.__version__[0] == "0" and torch.__version__ != "0.4.1":
Point.log_softmax = log_softmax
def log_softmax(self, *args, dim = 1, **kargs):
return F.log_softmax(self, *args,dim = dim, **kargs)
if torch.__version__[0] == "0" and torch.__version__ != "0.4.1":
Point.log_softmax = log_softmax
for nm in getMethodNames(Point):
curse(Pt, nm, getattr(Point, nm))
variable(torch.autograd.Variable)
variable(torch.cuda.DoubleTensor)
variable(torch.DoubleTensor)
variable(torch.cuda.FloatTensor)
variable(torch.FloatTensor)
variable(torch.ByteTensor)
variable(torch.Tensor)
def default(dic, nm, d):
if dic is not None and nm in dic:
return dic[nm]
return d
def softmaxBatchNP(x, epsilon, subtract = False):
"""Compute softmax values for each sets of scores in x."""
x = x.astype(np.float64)
ex = x / epsilon if epsilon is not None else x
if subtract:
ex -= ex.max(axis=1)[:,np.newaxis]
e_x = np.exp(ex)
sm = (e_x / e_x.sum(axis=1)[:,np.newaxis])
am = np.argmax(x, axis=1)
bads = np.logical_not(np.isfinite(sm.sum(axis = 1)))
if epsilon is None:
sm[bads] = 0
sm[bads, am[bads]] = 1
else:
epsilon *= (x.shape[1] - 1) / x.shape[1]
sm[bads] = epsilon / (x.shape[1] - 1)
sm[bads, am[bads]] = 1 - epsilon
sm /= sm.sum(axis=1)[:,np.newaxis]
return sm
def cadd(a,b):
both = a.cat(b)
a, b = both.split(a.size()[0])
return a + b
def msum(a,b, l):
if a is None:
return b
if b is None:
return a
return l(a,b)
class SubAct(argparse.Action):
def __init__(self, sub_choices, *args, **kargs):
super(SubAct,self).__init__(*args, nargs='+', **kargs)
self.sub_choices = sub_choices
self.sub_choices_names = None if sub_choices is None else getMethodNames(sub_choices)
def __call__(self, parser, namespace, values, option_string=None):
if self.sub_choices_names is not None and not values[0] in self.sub_choices_names:
msg = 'invalid choice: %r (choose from %s)' % (values[0], self.sub_choices_names)
raise argparse.ArgumentError(self, msg)
prev = getattr(namespace, self.dest)
setattr(namespace, self.dest, prev + [values])
def catLists(val):
if isinstance(val, list):
v = []
for i in val:
v += catLists(i)
return v
return [val]
def sumStr(val):
s = ""
for v in val:
s += v
return s
def catStrs(val):
s = val[0]
if len(val) > 1:
s += "("
for v in val[1:2]:
s += v
for v in val[2:]:
s += ", "+v
if len(val) > 1:
s += ")"
return s
def printNumpy(x):
return "[" + sumStr([decimal.Decimal(float(v)).__format__("f") + ", " for v in x.data.cpu().numpy()])[:-2]+"]"
def printStrList(x):
return "[" + sumStr(v + ", " for v in x)[:-2]+"]"
def printListsNumpy(val):
if isinstance(val, list):
return printStrList(printListsNumpy(v) for v in val)
return printNumpy(val)
def parseValues(values, methods, *others):
if len(values) == 1 and values[0]:
x = eval(values[0], dict(pair for l in ([methods] + list(others)) for pair in l.__dict__.items()) )
return x() if inspect.isclass(x) else x
args = []
kargs = {}
for arg in values[1:]:
if '=' in arg:
k = arg.split('=')[0]
v = arg[len(k)+1:]
try:
kargs[k] = eval(v)
except:
kargs[k] = v
else:
args += [eval(arg)]
return getattr(methods, values[0])(*args, **kargs)
def preDomRes(outDom, target): # TODO: make faster again by keeping sparse tensors sparse
t = one_hot(target.long(), outDom.size()[1]).to_dense().to_dtype()
tmat = t.unsqueeze(2).matmul(t.unsqueeze(1))
tl = t.unsqueeze(2).expand(-1, -1, tmat.size()[1])
inv_t = eye(tmat.size()[1]).expand(tmat.size()[0], -1, -1)
inv_t = inv_t - tmat
tl = tl.bmm(inv_t)
fst = outDom.unsqueeze(1).matmul(tl).squeeze(1)
snd = outDom.unsqueeze(1).matmul(inv_t).squeeze(1)
return (fst - snd) + t
def mopen(shouldnt, *args, **kargs):
if shouldnt:
import contextlib
return contextlib.suppress()
return open(*args, **kargs)
def file_timestamp():
return str(datetime.now()).replace(":","").replace(" ", "")
def prepareDomainNameForFile(s):
return s.replace(" ", "_").replace(",", "").replace("(", "_").replace(")", "_").replace("=", "_")
# delimited only
def callCC(foo):
class RV(BaseException):
def __init__(self, v):
self.v = v
def cc(x):
raise RV(x)
try:
return foo(cc)
except RV as rv:
return rv.v
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