torchvision库简介(翻译)

部分跟新于:4.24日    torchvision 0.2.2.post3

torchvision是独立于pytorch的关于图像操作的一些方便工具库。

torchvision的详细介绍在:https://pypi.org/project/torchvision/

torchvision主要包括一下几个包:

  • vision.datasets : 几个常用视觉数据集,可以下载和加载,这里主要的高级用法就是可以看源码如何自己写自己的Dataset的子类
  • vision.models : 流行的模型,例如 AlexNet, VGG, ResNet 和 Densenet 以及 与训练好的参数。
  • vision.transforms : 常用的图像操作,例如:随机切割,旋转,数据类型转换,图像到tensor ,numpy 数组到tensor , tensor 到 图像等。
  • vision.utils : 用于把形似 (3 x H x W) 的张量保存到硬盘中,给一个mini-batch的图像可以产生一个图像格网。

安装

Anaconda:

conda install torchvision -c pytorch

pip:

pip install torchvision

由于此包是配合pytorch的对于图像处理来说必不可少的,
对于以后要用的torch来说一站式的anaconda是首选,毕竟人生苦短。
(anaconda + vscode +pytorch 非常好用) 值得推荐!


以下翻译自 : https://pytorch.org/docs/master/torchvision/

数据集 torchvision.datasets

包括以下数据集:

数据集有 API: - __getitem__ - __len__ 他们都是 torch.utils.data.Dataset的子类。这样我们在实现我们自己的Dataset数据集的时候至少要实现上边两个方法。

因此, 他们可以使用torch.utils.data.DataLoader里的多线程 (python multiprocessing) 。

例如:

torch.utils.data.DataLoader(coco_cap, batch_size=args.batchSize, shuffle=True, num_workers=args.nThreads)

在构造上每个数据集的API有一些轻微的差异,但是都包含以下参数:

  • transform - 接受一个图像返回变换后的图像的函数
  • 常用的操作如 ToTensor, RandomCrop等. 他们可以通过transforms.Compose被组合在一起。 (见以下transforms 章节)
  • target_transform - 一个对目标值进行变换的函数。例如,输入一个图片描述,返回一个编码后的张量(a tensor of word indices)。
每个数据集都有类似参数,所以很容易通过一个掌握其他全部。

MNIST

dset.MNIST(root, train=True, transform=None, target_transform=None, download=False)

root:数据的目录,里边有 processed/training.pt 和processed/test.pt 的内容

train: True -使用训练集, False -使用测试集.

transform: 给输入图像施加变换

target_transform:给目标值(类别标签)施加的变换

download: 是否下载mnist数据集

COCO

This requires the COCO API to be installed

Captions:

dset.CocoCaptions(root="dir where images are", annFile="json annotation file", [transform, target_transform])

Example:

import torchvision.datasets as dset
import torchvision.transforms as transforms
cap = dset.CocoCaptions(root = 'dir where images are',
                        annFile = 'json annotation file',
                        transform=transforms.ToTensor())

print('Number of samples: ', len(cap))
img, target = cap[3] # load 4th sample

print("Image Size: ", img.size())
print(target)

Output:

Number of samples: 82783
Image Size: (3L, 427L, 640L)
[u'A plane emitting smoke stream flying over a mountain.',
u'A plane darts across a bright blue sky behind a mountain covered in snow',
u'A plane leaves a contrail above the snowy mountain top.',
u'A mountain that has a plane flying overheard in the distance.',
u'A mountain view with a plume of smoke in the background']

Detection:

dset.CocoDetection(root="dir where images are", annFile="json annotation file", [transform, target_transform])

LSUN

dset.LSUN(db_path, classes='train', [transform, target_transform])

  • db_path = root directory for the database files
  • classes =
  • 'train' - all categories, training set
  • 'val' - all categories, validation set
  • 'test' - all categories, test set
  • ['bedroom_train', 'church_train', …] : a list of categories to load

CIFAR

dset.CIFAR10(root, train=True, transform=None, target_transform=None, download=False)

dset.CIFAR100(root, train=True, transform=None, target_transform=None, download=False)

  • root : root directory of dataset where there is folder cifar-10-batches-py
  • train : True = Training set, False = Test set
  • download : True = downloads the dataset from the internet and puts it in root directory. If dataset is already downloaded, does not do anything.

STL10

dset.STL10(root, split='train', transform=None, target_transform=None, download=False)

  • root : root directory of dataset where there is folder stl10_binary

  • split : 'train' = Training set, 'test' = Test set, 'unlabeled' = Unlabeled set,

    'train+unlabeled' = Training + Unlabeled set (missing label marked as -1)

  • download : True = downloads the dataset from the internet and

    puts it in root directory. If dataset is already downloaded, does not do anything.

SVHN

dset.SVHN(root, split='train', transform=None, target_transform=None, download=False)

  • root : root directory of dataset where there is folder SVHN

  • split : 'train' = Training set, 'test' = Test set, 'extra' = Extra training set

  • download : True = downloads the dataset from the internet and

    puts it in root directory. If dataset is already downloaded, does not do anything.

ImageFolder

一个通用的数据加载器,图像应该按照以下方式放置:

root/dog/xxx.png
root/dog/xxy.png
root/dog/xxz.png

root/cat/123.png
root/cat/nsdf3.png
root/cat/asd932_.png

dset.ImageFolder(root="root folder path", [transform, target_transform])

ImageFolder有以下成员:

  • self.classes - 类别名列表
  • self.class_to_idx - 类别名到标签,例如 “狗”-->[1,0,0]
  • self.imgs - 一个包括 (image path, class-index) 元组的列表。

Imagenet-12

This is simply implemented with an ImageFolder dataset.

The data is preprocessed as described here

Here is an example.

PhotoTour

Learning Local Image Descriptors Data http://phototour.cs.washington.edu/patches/default.htm

import torchvision.datasets as dset
import torchvision.transforms as transforms
dataset = dset.PhotoTour(root = 'dir where images are',
                         name = 'name of the dataset to load',
                         transform=transforms.ToTensor())

print('Loaded PhotoTour: {} with {} images.'
      .format(dataset.name, len(dataset.data)))

模型

models 子包含了以下的模型框架:

这里对于每种模型里可能包含很多子模型,比如Resnet就有 34,51,101,152不同层数。

这些成熟的模型的意义就是你可以在torchvision的安装路径下找到 可以通过命令 print(torchvision.models.__file__)   #'d:\\Anaconda3\\lib\\site-packages\\torchvision\\models\\__init__.py'

学习这些优秀的模型是如何搭建的。

你可以用随机参数初始化一个模型:

import torchvision.models as models
resnet18 = models.resnet18()
alexnet = models.alexnet()
vgg16 = models.vgg16()
squeezenet = models.squeezenet1_0()

我们提供了预训练的ResNet的模型参数,以及 SqueezeNet 1.0 and 1.1, and AlexNet, 使用 PyTorch model zoo. 可以在构造函数里添加 pretrained=True:

import torchvision.models as models
resnet18 = models.resnet18(pretrained=True)
alexnet = models.alexnet(pretrained=True)
squeezenet = models.squeezenet1_0(pretrained=True)

所有的预训练模型期待输入同样标准化的数据,例如mini-baches 包括形似(3*H*W)的3通道的RGB图像,H,W最少是224。

图像的范围必须在[0,1]之间,然后使用 mean=[0.485, 0.456, 0.406] and std=[0.229, 0.224, 0.225]  进行标准化。

相关的例子在: the imagenet example here <https://github.com/pytorch/examples/blob/42e5b996718797e45c46a25c55b031e6768f8440/imagenet/main.py#L89-L101>

变换

变换(Transforms)是常用的图像变换。可以通过 transforms.Compose进行连续操作:

transforms.Compose

你可以组合几个变换在一起,例如:

transform = transforms.Compose([
    transforms.RandomSizedCrop(224),
    transforms.RandomHorizontalFlip(),
    transforms.ToTensor(),
    transforms.Normalize(mean = [ 0.485, 0.456, 0.406 ],
                          std = [ 0.229, 0.224, 0.225 ]),
])

PIL.Image支持的变换

Scale(size, interpolation=Image.BILINEAR)

缩放输入的 PIL.Image到给定的“尺寸”。 ‘尺寸’ 指的是较短边的尺寸.

例如,如果 height > width, 那么图像将被缩放为 (size * height / width, size) - size: 图像较短边的尺寸- interpolation: Default: PIL.Image.BILINEAR

CenterCrop(size) - 从中间裁剪图像到指定大小

从中间裁剪一个 PIL.Image 到给定尺寸. 尺寸可以是一个元组 (target_height, target_width) 或一个整数,整数将被认为是正方形的尺寸 (size, size)

RandomCrop(size, padding=0)

Crops the given PIL.Image at a random location to have a region of the given size. size can be a tuple (target_height, target_width) or an integer, in which case the target will be of a square shape (size, size) If padding is non-zero, then the image is first zero-padded on each side with padding pixels.

RandomHorizontalFlip()

随机进行PIL.Image图像的水平翻转,概率是0.5.

RandomSizedCrop(size, interpolation=Image.BILINEAR)

Random crop the given PIL.Image to a random size of (0.08 to 1.0) of the original size and and a random aspect ratio of 3/4 to 4/3 of the original aspect ratio

This is popularly used to train the Inception networks - size: size of the smaller edge - interpolation: Default: PIL.Image.BILINEAR

Pad(padding, fill=0)

Pads the given image on each side with padding number of pixels, and the padding pixels are filled with pixel value fill. If a 5x5 image is padded with padding=1 then it becomes 7x7

对于 torch.*Tensor 的变换

Normalize(mean, std)

Given mean: (R, G, B) and std: (R, G, B), will normalize each channel of the torch.*Tensor, i.e. channel = (channel - mean) / std

转换变换

  • ToTensor() - Converts a PIL.Image (RGB) or numpy.ndarray (H x W x C) in the range [0, 255] to a torch.FloatTensor of shape (C x H x W) in the range [0.0, 1.0]
  • ToPILImage() - Converts a torch.*Tensor of range [0, 1] and shape C x H x W or numpy ndarray of dtype=uint8, range[0, 255] and shape H x W x C to a PIL.Image of range [0, 255]

广义变换

Lambda(lambda)

Given a Python lambda, applies it to the input img and returns it. For example:

transforms.Lambda(lambda x: x.add(10))

便利函数

make_grid(tensor, nrow=8, padding=2, normalize=False, range=None, scale_each=False)

Given a 4D mini-batch Tensor of shape (B x C x H x W), or a list of images all of the same size, makes a grid of images

normalize=True will shift the image to the range (0, 1), by subtracting the minimum and dividing by the maximum pixel value.

if range=(min, max) where min and max are numbers, then these numbers are used to normalize the image.

scale_each=True will scale each image in the batch of images separately rather than computing the (min, max) over all images.

Example usage is given in this notebook <https://gist.github.com/anonymous/bf16430f7750c023141c562f3e9f2a91>

save_image(tensor, filename, nrow=8, padding=2, normalize=False, range=None, scale_each=False)

Saves a given Tensor into an image file.

If given a mini-batch tensor, will save the tensor as a grid of images.

All options after filename are passed through to make_grid. Refer to it’s documentation for more details

用以输出图像的拼接,很方便。





没想到这篇文章阅读量这么大,考虑跟新下。

图像引擎:由于需要读取处理图片所以需要相关的图像库。现在torchvision可以支持多个图像读取库,可以切换。

使用的函数是:

torchvision.get_image_backend()   #获取图像存取引擎

torchvision.set_image_backend(backend)   #改变图像读取引擎

#backend (string) –图像引擎的名字:是  {‘PIL’, ‘accimage’}其中之一。  accimage 包使用的是因特尔(Intel) IPP 库。它的速度快于PIL,但是并不支持很多的图像操作。

由于这个是后边的,普通用处不大,知道即可。

 

posted on 2018-10-11 16:37  看看完了  阅读(46844)  评论(0编辑  收藏  举报

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