image-handler/image-handler10.0/venv/lib/site-packages/torch/_numpy/random.py

# mypy: ignore-errors

"""Wrapper to mimic (parts of) np.random API surface.

NumPy has strict guarantees on reproducibility etc; here we don't give any.

Q: default dtype is float64 in numpy

"""
from __future__ import annotations

import functools
from math import sqrt
from typing import Optional

import torch

from . import _dtypes_impl, _util
from ._normalizations import array_or_scalar, ArrayLike, normalizer


__all__ = [
    "seed",
    "random_sample",
    "sample",
    "random",
    "rand",
    "randn",
    "normal",
    "choice",
    "randint",
    "shuffle",
    "uniform",
]


def use_numpy_random():
    # local import to avoid ref cycles
    import torch._dynamo.config as config

    return config.use_numpy_random_stream


def deco_stream(func):
    @functools.wraps(func)
    def inner(*args, **kwds):
        if not use_numpy_random():
            return func(*args, **kwds)
        else:
            import numpy

            from ._ndarray import ndarray

            f = getattr(numpy.random, func.__name__)

            # numpy funcs accept numpy ndarrays, unwrap
            args = tuple(
                arg.tensor.numpy() if isinstance(arg, ndarray) else arg for arg in args
            )
            kwds = {
                key: val.tensor.numpy() if isinstance(val, ndarray) else val
                for key, val in kwds.items()
            }

            value = f(*args, **kwds)

            # `value` can be either numpy.ndarray or python scalar (or None)
            if isinstance(value, numpy.ndarray):
                value = ndarray(torch.as_tensor(value))

            return value

    return inner


@deco_stream
def seed(seed=None):
    if seed is not None:
        torch.random.manual_seed(seed)


@deco_stream
def random_sample(size=None):
    if size is None:
        size = ()
    dtype = _dtypes_impl.default_dtypes().float_dtype
    values = torch.empty(size, dtype=dtype).uniform_()
    return array_or_scalar(values, return_scalar=size == ())


def rand(*size):
    if size == ():
        size = None
    return random_sample(size)


sample = random_sample
random = random_sample


@deco_stream
def uniform(low=0.0, high=1.0, size=None):
    if size is None:
        size = ()
    dtype = _dtypes_impl.default_dtypes().float_dtype
    values = torch.empty(size, dtype=dtype).uniform_(low, high)
    return array_or_scalar(values, return_scalar=size == ())


@deco_stream
def randn(*size):
    dtype = _dtypes_impl.default_dtypes().float_dtype
    values = torch.randn(size, dtype=dtype)
    return array_or_scalar(values, return_scalar=size == ())


@deco_stream
def normal(loc=0.0, scale=1.0, size=None):
    if size is None:
        size = ()
    dtype = _dtypes_impl.default_dtypes().float_dtype
    values = torch.empty(size, dtype=dtype).normal_(loc, scale)
    return array_or_scalar(values, return_scalar=size == ())


@deco_stream
def shuffle(x):
    # no @normalizer because we do not cast e.g. lists to tensors
    from ._ndarray import ndarray

    if isinstance(x, torch.Tensor):
        tensor = x
    elif isinstance(x, ndarray):
        tensor = x.tensor
    else:
        raise NotImplementedError("We do not random.shuffle lists in-place")

    perm = torch.randperm(tensor.shape[0])
    xp = tensor[perm]
    tensor.copy_(xp)


@deco_stream
def randint(low, high=None, size=None):
    if size is None:
        size = ()
    if not isinstance(size, (tuple, list)):
        size = (size,)
    if high is None:
        low, high = 0, low
    values = torch.randint(low, high, size=size)
    return array_or_scalar(values, int, return_scalar=size == ())


@deco_stream
@normalizer
def choice(a: ArrayLike, size=None, replace=True, p: Optional[ArrayLike] = None):
    # https://stackoverflow.com/questions/59461811/random-choice-with-pytorch
    if a.numel() == 1:
        a = torch.arange(a)

    # TODO: check a.dtype is integer -- cf np.random.choice(3.4) which raises

    # number of draws
    if size is None:
        num_el = 1
    elif _util.is_sequence(size):
        num_el = 1
        for el in size:
            num_el *= el
    else:
        num_el = size

    # prepare the probabilities
    if p is None:
        p = torch.ones_like(a) / a.shape[0]

    # cf https://github.com/numpy/numpy/blob/main/numpy/random/mtrand.pyx#L973
    atol = sqrt(torch.finfo(p.dtype).eps)
    if abs(p.sum() - 1.0) > atol:
        raise ValueError("probabilities do not sum to 1.")

    # actually sample
    indices = torch.multinomial(p, num_el, replacement=replace)

    if _util.is_sequence(size):
        indices = indices.reshape(size)

    samples = a[indices]

    return samples
first commit 5 months ago			`# mypy: ignore-errors`

			`"""Wrapper to mimic (parts of) np.random API surface.`

			`NumPy has strict guarantees on reproducibility etc; here we don't give any.`

			`Q: default dtype is float64 in numpy`

			`"""`
			`from __future__ import annotations`

			`import functools`
			`from math import sqrt`
			`from typing import Optional`

			`import torch`

			`from . import _dtypes_impl, _util`
			`from ._normalizations import array_or_scalar, ArrayLike, normalizer`


			`__all__ = [`
			`"seed",`
			`"random_sample",`
			`"sample",`
			`"random",`
			`"rand",`
			`"randn",`
			`"normal",`
			`"choice",`
			`"randint",`
			`"shuffle",`
			`"uniform",`
			`]`


			`def use_numpy_random():`
			`# local import to avoid ref cycles`
			`import torch._dynamo.config as config`

			`return config.use_numpy_random_stream`


			`def deco_stream(func):`
			`@functools.wraps(func)`
			`def inner(args, *kwds):`
			`if not use_numpy_random():`
			`return func(args, *kwds)`
			`else:`
			`import numpy`

			`from ._ndarray import ndarray`

			`f = getattr(numpy.random, func.__name__)`

			`# numpy funcs accept numpy ndarrays, unwrap`
			`args = tuple(`
			`arg.tensor.numpy() if isinstance(arg, ndarray) else arg for arg in args`
			`)`
			`kwds = {`
			`key: val.tensor.numpy() if isinstance(val, ndarray) else val`
			`for key, val in kwds.items()`
			`}`

			`value = f(args, *kwds)`

			# `value` can be either numpy.ndarray or python scalar (or None)
			`if isinstance(value, numpy.ndarray):`
			`value = ndarray(torch.as_tensor(value))`

			`return value`

			`return inner`


			`@deco_stream`
			`def seed(seed=None):`
			`if seed is not None:`
			`torch.random.manual_seed(seed)`


			`@deco_stream`
			`def random_sample(size=None):`
			`if size is None:`
			`size = ()`
			`dtype = _dtypes_impl.default_dtypes().float_dtype`
			`values = torch.empty(size, dtype=dtype).uniform_()`
			`return array_or_scalar(values, return_scalar=size == ())`


			`def rand(*size):`
			`if size == ():`
			`size = None`
			`return random_sample(size)`


			`sample = random_sample`
			`random = random_sample`


			`@deco_stream`
			`def uniform(low=0.0, high=1.0, size=None):`
			`if size is None:`
			`size = ()`
			`dtype = _dtypes_impl.default_dtypes().float_dtype`
			`values = torch.empty(size, dtype=dtype).uniform_(low, high)`
			`return array_or_scalar(values, return_scalar=size == ())`


			`@deco_stream`
			`def randn(*size):`
			`dtype = _dtypes_impl.default_dtypes().float_dtype`
			`values = torch.randn(size, dtype=dtype)`
			`return array_or_scalar(values, return_scalar=size == ())`


			`@deco_stream`
			`def normal(loc=0.0, scale=1.0, size=None):`
			`if size is None:`
			`size = ()`
			`dtype = _dtypes_impl.default_dtypes().float_dtype`
			`values = torch.empty(size, dtype=dtype).normal_(loc, scale)`
			`return array_or_scalar(values, return_scalar=size == ())`


			`@deco_stream`
			`def shuffle(x):`
			`# no @normalizer because we do not cast e.g. lists to tensors`
			`from ._ndarray import ndarray`

			`if isinstance(x, torch.Tensor):`
			`tensor = x`
			`elif isinstance(x, ndarray):`
			`tensor = x.tensor`
			`else:`
			`raise NotImplementedError("We do not random.shuffle lists in-place")`

			`perm = torch.randperm(tensor.shape[0])`
			`xp = tensor[perm]`
			`tensor.copy_(xp)`


			`@deco_stream`
			`def randint(low, high=None, size=None):`
			`if size is None:`
			`size = ()`
			`if not isinstance(size, (tuple, list)):`
			`size = (size,)`
			`if high is None:`
			`low, high = 0, low`
			`values = torch.randint(low, high, size=size)`
			`return array_or_scalar(values, int, return_scalar=size == ())`


			`@deco_stream`
			`@normalizer`
			`def choice(a: ArrayLike, size=None, replace=True, p: Optional[ArrayLike] = None):`
			`# https://stackoverflow.com/questions/59461811/random-choice-with-pytorch`
			`if a.numel() == 1:`
			`a = torch.arange(a)`

			`# TODO: check a.dtype is integer -- cf np.random.choice(3.4) which raises`

			`# number of draws`
			`if size is None:`
			`num_el = 1`
			`elif _util.is_sequence(size):`
			`num_el = 1`
			`for el in size:`
			`num_el *= el`
			`else:`
			`num_el = size`

			`# prepare the probabilities`
			`if p is None:`
			`p = torch.ones_like(a) / a.shape[0]`

			`# cf https://github.com/numpy/numpy/blob/main/numpy/random/mtrand.pyx#L973`
			`atol = sqrt(torch.finfo(p.dtype).eps)`
			`if abs(p.sum() - 1.0) > atol:`
			`raise ValueError("probabilities do not sum to 1.")`

			`# actually sample`
			`indices = torch.multinomial(p, num_el, replacement=replace)`

			`if _util.is_sequence(size):`
			`indices = indices.reshape(size)`

			`samples = a[indices]`

			`return samples`