最近用到了上采样下采样操作,pytorch中使用interpolate可以很轻松的完成
def interpolate(input, size=None, scale_factor=None, mode='nearest', align_corners=None): r""" 根据给定 size 或 scale_factor,上采样或下采样输入数据input. 当前支持 temporal, spatial 和 volumetric 输入数据的上采样,其shape 分别为:3-D, 4-D 和 5-D. 输入数据的形式为:mini-batch x channels x [optional depth] x [optional height] x width. 上采样算法有:nearest, linear(3D-only), bilinear(4D-only), trilinear(5D-only). 参数: - input (Tensor): input tensor - size (int or Tuple[int] or Tuple[int, int] or Tuple[int, int, int]):输出的 spatial 尺寸. - scale_factor (float or Tuple[float]): spatial 尺寸的缩放因子. - mode (string): 上采样算法:nearest, linear, bilinear, trilinear, area. 默认为 nearest. - align_corners (bool, optional): 如果 align_corners=True,则对齐 input 和 output 的角点像素(corner pixels),保持在角点像素的值. 只会对 mode=linear, bilinear 和 trilinear 有作用. 默认是 False. """ from numbers import Integral from .modules.utils import _ntuple def _check_size_scale_factor(dim): if size is None and scale_factor is None: raise ValueError('either size or scale_factor should be defined') if size is not None and scale_factor is not None: raise ValueError('only one of size or scale_factor should be defined') if scale_factor is not None and isinstance(scale_factor, tuple) and len(scale_factor) != dim: raise ValueError('scale_factor shape must match input shape. ' 'Input is {}D, scale_factor size is {}'.format(dim, len(scale_factor))) def _output_size(dim): _check_size_scale_factor(dim) if size is not None: return size scale_factors = _ntuple(dim)(scale_factor) # math.floor might return float in py2.7 return [int(math.floor(input.size(i + 2) * scale_factors[i])) for i in range(dim)] if mode in ('nearest', 'area'): if align_corners is not None: raise ValueError("align_corners option can only be set with the " "interpolating modes: linear | bilinear | trilinear") else: if align_corners is None: warnings.warn("Default upsampling behavior when mode={} is changed " "to align_corners=False since 0.4.0. Please specify " "align_corners=True if the old behavior is desired. " "See the documentation of nn.Upsample for details.".format(mode)) align_corners = False if input.dim() == 3 and mode == 'nearest': return torch._C._nn.upsample_nearest1d(input, _output_size(1)) elif input.dim() == 4 and mode == 'nearest': return torch._C._nn.upsample_nearest2d(input, _output_size(2)) elif input.dim() == 5 and mode == 'nearest': return torch._C._nn.upsample_nearest3d(input, _output_size(3)) elif input.dim() == 3 and mode == 'area': return adaptive_avg_pool1d(input, _output_size(1)) elif input.dim() == 4 and mode == 'area': return adaptive_avg_pool2d(input, _output_size(2)) elif input.dim() == 5 and mode == 'area': return adaptive_avg_pool3d(input, _output_size(3)) elif input.dim() == 3 and mode == 'linear': return torch._C._nn.upsample_linear1d(input, _output_size(1), align_corners) elif input.dim() == 3 and mode == 'bilinear': raise NotImplementedError("Got 3D input, but bilinear mode needs 4D input") elif input.dim() == 3 and mode == 'trilinear': raise NotImplementedError("Got 3D input, but trilinear mode needs 5D input") elif input.dim() == 4 and mode == 'linear': raise NotImplementedError("Got 4D input, but linear mode needs 3D input") elif input.dim() == 4 and mode == 'bilinear': return torch._C._nn.upsample_bilinear2d(input, _output_size(2), align_corners) elif input.dim() == 4 and mode == 'trilinear': raise NotImplementedError("Got 4D input, but trilinear mode needs 5D input") elif input.dim() == 5 and mode == 'linear': raise NotImplementedError("Got 5D input, but linear mode needs 3D input") elif input.dim() == 5 and mode == 'bilinear': raise NotImplementedError("Got 5D input, but bilinear mode needs 4D input") elif input.dim() == 5 and mode == 'trilinear': return torch._C._nn.upsample_trilinear3d(input, _output_size(3), align_corners) else: raise NotImplementedError("Input Error: Only 3D, 4D and 5D input Tensors supported" " (got {}D) for the modes: nearest | linear | bilinear | trilinear" " (got {})".format(input.dim(), mode))
举个例子:
x = Variable(torch.randn([1, 3, 64, 64])) y0 = F.interpolate(x, scale_factor=0.5) y1 = F.interpolate(x, size=[32, 32]) y2 = F.interpolate(x, size=[128, 128], mode="bilinear") print(y0.shape) print(y1.shape) print(y2.shape)
这里注意上采样的时候mode默认是“nearest”,这里指定双线性插值“bilinear”
得到结果
torch.Size([1, 3, 32, 32]) torch.Size([1, 3, 32, 32]) torch.Size([1, 3, 128, 128])
补充知识:pytorch插值函数interpolate——图像上采样-下采样,scipy插值函数zoom
在训练过程中,需要对图像数据进行插值,如果此时数据是numpy数据,那么可以使用scipy中的zoom函数:
from scipy.ndimage.interpolation import zoom
def zoom(input, zoom, output=None, order=3, mode='constant', cval=0.0, prefilter=True): """ Zoom an array. The array is zoomed using spline interpolation of the requested order. Parameters ---------- %(input)s zoom : float or sequence The zoom factor along the axes. If a float, `zoom` is the same for each axis. If a sequence, `zoom` should contain one value for each axis. %(output)s order : int, optional The order of the spline interpolation, default is 3. The order has to be in the range 0-5. %(mode)s %(cval)s %(prefilter)s Returns ------- zoom : ndarray The zoomed input. Examples -------- > from scipy import ndimage, misc > import matplotlib.pyplot as plt > fig = plt.figure() > ax1 = fig.add_subplot(121) # left side > ax2 = fig.add_subplot(122) # right side > ascent = misc.ascent() > result = ndimage.zoom(ascent, 3.0) > ax1.imshow(ascent) > ax2.imshow(result) > plt.show() > print(ascent.shape) (512, 512) > print(result.shape) (1536, 1536) """ if order < 0 or order > 5: raise RuntimeError('spline order not supported') input = numpy.asarray(input) if numpy.iscomplexobj(input): raise TypeError('Complex type not supported') if input.ndim < 1: raise RuntimeError('input and output rank must be > 0') mode = _ni_support._extend_mode_to_code(mode) if prefilter and order > 1: filtered = spline_filter(input, order, output=numpy.float64) else: filtered = input zoom = _ni_support._normalize_sequence(zoom, input.ndim) output_shape = tuple( [int(round(ii * jj)) for ii, jj in zip(input.shape, zoom)]) output_shape_old = tuple( [int(ii * jj) for ii, jj in zip(input.shape, zoom)]) if output_shape != output_shape_old: warnings.warn( "From scipy 0.13.0, the output shape of zoom() is calculated " "with round() instead of int() - for these inputs the size of " "the returned array has changed.", UserWarning) zoom_div = numpy.array(output_shape, float) - 1 # Zooming to infinite values is unpredictable, so just choose # zoom factor 1 instead zoom = numpy.divide(numpy.array(input.shape) - 1, zoom_div, out=numpy.ones_like(input.shape, dtype=numpy.float64), where=zoom_div != 0) output = _ni_support._get_output(output, input, shape=output_shape) zoom = numpy.ascontiguousarray(zoom) _nd_image.zoom_shift(filtered, zoom, None, output, order, mode, cval) return output
中的zoom函数进行插值,
但是,如果此时的数据是tensor(张量)的时候,使用zoom函数的时候需要将tensor数据转为numpy,将GPU数据转换为CPU数据等,过程比较繁琐,可以使用pytorch自带的函数进行插值操作,interpolate函数有几个参数:size表示输出大小,scale_factor表示缩放倍数,mode表示插值方式,align_corners是bool类型,表示输入和输出中心是否对齐:
from torch.nn.functional import interpolate
def interpolate(input, size=None, scale_factor=None, mode='nearest', align_corners=None): r"""Down/up samples the input to either the given :attr:`size` or the given :attr:`scale_factor` The algorithm used for interpolation is determined by :attr:`mode`. Currently temporal, spatial and volumetric sampling are supported, i.e. expected inputs are 3-D, 4-D or 5-D in shape. The input dimensions are interpreted in the form: `mini-batch x channels x [optional depth] x [optional height] x width`. The modes available for resizing are: `nearest`, `linear` (3D-only), `bilinear`, `bicubic` (4D-only), `trilinear` (5D-only), `area` Args: input (Tensor): the input tensor size (int or Tuple[int] or Tuple[int, int] or Tuple[int, int, int]): output spatial size. scale_factor (float or Tuple[float]): multiplier for spatial size. Has to match input size if it is a tuple. mode (str): algorithm used for upsampling: ``'nearest'`` | ``'linear'`` | ``'bilinear'`` | ``'bicubic'`` | ``'trilinear'`` | ``'area'``. Default: ``'nearest'`` align_corners (bool, optional): Geometrically, we consider the pixels of the input and output as squares rather than points. If set to ``True``, the input and output tensors are aligned by the center points of their corner pixels. If set to ``False``, the input and output tensors are aligned by the corner points of their corner pixels, and the interpolation uses edge value padding for out-of-boundary values. This only has effect when :attr:`mode` is ``'linear'``, ``'bilinear'``, ``'bicubic'``, or ``'trilinear'``. Default: ``False`` .. warning:: With ``align_corners = True``, the linearly interpolating modes (`linear`, `bilinear`, and `trilinear`) don't proportionally align the output and input pixels, and thus the output values can depend on the input size. This was the default behavior for these modes up to version 0.3.1. Since then, the default behavior is ``align_corners = False``. See :class:`~torch.nn.Upsample` for concrete examples on how this affects the outputs. .. include:: cuda_deterministic_backward.rst """ from .modules.utils import _ntuple def _check_size_scale_factor(dim): if size is None and scale_factor is None: raise ValueError('either size or scale_factor should be defined') if size is not None and scale_factor is not None: raise ValueError('only one of size or scale_factor should be defined') if scale_factor is not None and isinstance(scale_factor, tuple) and len(scale_factor) != dim: raise ValueError('scale_factor shape must match input shape. ' 'Input is {}D, scale_factor size is {}'.format(dim, len(scale_factor))) def _output_size(dim): _check_size_scale_factor(dim) if size is not None: return size scale_factors = _ntuple(dim)(scale_factor) # math.floor might return float in py2.7 # make scale_factor a tensor in tracing so constant doesn't get baked in if torch._C._get_tracing_state(): return [(torch.floor(input.size(i + 2) * torch.tensor(float(scale_factors[i])))) for i in range(dim)] else: return [int(math.floor(int(input.size(i + 2)) * scale_factors[i])) for i in range(dim)] if mode in ('nearest', 'area'): if align_corners is not None: raise ValueError("align_corners option can only be set with the " "interpolating modes: linear | bilinear | bicubic | trilinear") else: if align_corners is None: warnings.warn("Default upsampling behavior when mode={} is changed " "to align_corners=False since 0.4.0. Please specify " "align_corners=True if the old behavior is desired. " "See the documentation of nn.Upsample for details.".format(mode)) align_corners = False if input.dim() == 3 and mode == 'nearest': return torch._C._nn.upsample_nearest1d(input, _output_size(1)) elif input.dim() == 4 and mode == 'nearest': return torch._C._nn.upsample_nearest2d(input, _output_size(2)) elif input.dim() == 5 and mode == 'nearest': return torch._C._nn.upsample_nearest3d(input, _output_size(3)) elif input.dim() == 3 and mode == 'area': return adaptive_avg_pool1d(input, _output_size(1)) elif input.dim() == 4 and mode == 'area': return adaptive_avg_pool2d(input, _output_size(2)) elif input.dim() == 5 and mode == 'area': return adaptive_avg_pool3d(input, _output_size(3)) elif input.dim() == 3 and mode == 'linear': return torch._C._nn.upsample_linear1d(input, _output_size(1), align_corners) elif input.dim() == 3 and mode == 'bilinear': raise NotImplementedError("Got 3D input, but bilinear mode needs 4D input") elif input.dim() == 3 and mode == 'trilinear': raise NotImplementedError("Got 3D input, but trilinear mode needs 5D input") elif input.dim() == 4 and mode == 'linear': raise NotImplementedError("Got 4D input, but linear mode needs 3D input") elif input.dim() == 4 and mode == 'bilinear': return torch._C._nn.upsample_bilinear2d(input, _output_size(2), align_corners) elif input.dim() == 4 and mode == 'trilinear': raise NotImplementedError("Got 4D input, but trilinear mode needs 5D input") elif input.dim() == 5 and mode == 'linear': raise NotImplementedError("Got 5D input, but linear mode needs 3D input") elif input.dim() == 5 and mode == 'bilinear': raise NotImplementedError("Got 5D input, but bilinear mode needs 4D input") elif input.dim() == 5 and mode == 'trilinear': return torch._C._nn.upsample_trilinear3d(input, _output_size(3), align_corners) elif input.dim() == 4 and mode == 'bicubic': return torch._C._nn.upsample_bicubic2d(input, _output_size(2), align_corners) else: raise NotImplementedError("Input Error: Only 3D, 4D and 5D input Tensors supported" " (got {}D) for the modes: nearest | linear | bilinear | bicubic | trilinear" " (got {})".format(input.dim(), mode))
以上这篇Pytorch上下采样函数--interpolate用法就是小编分享给大家的全部内容了,希望能给大家一个参考,也希望大家多多支持。
免责声明:本站文章均来自网站采集或用户投稿,网站不提供任何软件下载或自行开发的软件! 如有用户或公司发现本站内容信息存在侵权行为,请邮件告知! 858582#qq.com
《魔兽世界》大逃杀!60人新游玩模式《强袭风暴》3月21日上线
暴雪近日发布了《魔兽世界》10.2.6 更新内容,新游玩模式《强袭风暴》即将于3月21 日在亚服上线,届时玩家将前往阿拉希高地展开一场 60 人大逃杀对战。
艾泽拉斯的冒险者已经征服了艾泽拉斯的大地及遥远的彼岸。他们在对抗世界上最致命的敌人时展现出过人的手腕,并且成功阻止终结宇宙等级的威胁。当他们在为即将于《魔兽世界》资料片《地心之战》中来袭的萨拉塔斯势力做战斗准备时,他们还需要在熟悉的阿拉希高地面对一个全新的敌人──那就是彼此。在《巨龙崛起》10.2.6 更新的《强袭风暴》中,玩家将会进入一个全新的海盗主题大逃杀式限时活动,其中包含极高的风险和史诗级的奖励。
《强袭风暴》不是普通的战场,作为一个独立于主游戏之外的活动,玩家可以用大逃杀的风格来体验《魔兽世界》,不分职业、不分装备(除了你在赛局中捡到的),光是技巧和战略的强弱之分就能决定出谁才是能坚持到最后的赢家。本次活动将会开放单人和双人模式,玩家在加入海盗主题的预赛大厅区域前,可以从强袭风暴角色画面新增好友。游玩游戏将可以累计名望轨迹,《巨龙崛起》和《魔兽世界:巫妖王之怒 经典版》的玩家都可以获得奖励。