323 lines
9.3 KiB
Python
323 lines
9.3 KiB
Python
"""
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Discrete Fourier Transforms - helper.py
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"""
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from __future__ import division, absolute_import, print_function
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import collections
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import threading
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from numpy.compat import integer_types
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from numpy.core import (
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asarray, concatenate, arange, take, integer, empty
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)
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# Created by Pearu Peterson, September 2002
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__all__ = ['fftshift', 'ifftshift', 'fftfreq', 'rfftfreq']
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integer_types = integer_types + (integer,)
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def fftshift(x, axes=None):
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"""
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Shift the zero-frequency component to the center of the spectrum.
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This function swaps half-spaces for all axes listed (defaults to all).
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Note that ``y[0]`` is the Nyquist component only if ``len(x)`` is even.
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Parameters
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----------
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x : array_like
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Input array.
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axes : int or shape tuple, optional
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Axes over which to shift. Default is None, which shifts all axes.
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Returns
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-------
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y : ndarray
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The shifted array.
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See Also
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--------
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ifftshift : The inverse of `fftshift`.
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Examples
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--------
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>>> freqs = np.fft.fftfreq(10, 0.1)
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>>> freqs
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array([ 0., 1., 2., 3., 4., -5., -4., -3., -2., -1.])
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>>> np.fft.fftshift(freqs)
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array([-5., -4., -3., -2., -1., 0., 1., 2., 3., 4.])
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Shift the zero-frequency component only along the second axis:
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>>> freqs = np.fft.fftfreq(9, d=1./9).reshape(3, 3)
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>>> freqs
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array([[ 0., 1., 2.],
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[ 3., 4., -4.],
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[-3., -2., -1.]])
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>>> np.fft.fftshift(freqs, axes=(1,))
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array([[ 2., 0., 1.],
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[-4., 3., 4.],
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[-1., -3., -2.]])
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"""
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tmp = asarray(x)
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ndim = tmp.ndim
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if axes is None:
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axes = list(range(ndim))
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elif isinstance(axes, integer_types):
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axes = (axes,)
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y = tmp
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for k in axes:
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n = tmp.shape[k]
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p2 = (n+1)//2
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mylist = concatenate((arange(p2, n), arange(p2)))
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y = take(y, mylist, k)
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return y
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def ifftshift(x, axes=None):
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"""
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The inverse of `fftshift`. Although identical for even-length `x`, the
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functions differ by one sample for odd-length `x`.
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Parameters
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----------
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x : array_like
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Input array.
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axes : int or shape tuple, optional
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Axes over which to calculate. Defaults to None, which shifts all axes.
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Returns
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-------
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y : ndarray
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The shifted array.
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See Also
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--------
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fftshift : Shift zero-frequency component to the center of the spectrum.
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Examples
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--------
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>>> freqs = np.fft.fftfreq(9, d=1./9).reshape(3, 3)
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>>> freqs
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array([[ 0., 1., 2.],
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[ 3., 4., -4.],
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[-3., -2., -1.]])
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>>> np.fft.ifftshift(np.fft.fftshift(freqs))
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array([[ 0., 1., 2.],
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[ 3., 4., -4.],
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[-3., -2., -1.]])
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"""
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tmp = asarray(x)
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ndim = tmp.ndim
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if axes is None:
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axes = list(range(ndim))
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elif isinstance(axes, integer_types):
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axes = (axes,)
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y = tmp
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for k in axes:
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n = tmp.shape[k]
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p2 = n-(n+1)//2
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mylist = concatenate((arange(p2, n), arange(p2)))
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y = take(y, mylist, k)
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return y
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def fftfreq(n, d=1.0):
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"""
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Return the Discrete Fourier Transform sample frequencies.
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The returned float array `f` contains the frequency bin centers in cycles
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per unit of the sample spacing (with zero at the start). For instance, if
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the sample spacing is in seconds, then the frequency unit is cycles/second.
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Given a window length `n` and a sample spacing `d`::
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f = [0, 1, ..., n/2-1, -n/2, ..., -1] / (d*n) if n is even
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f = [0, 1, ..., (n-1)/2, -(n-1)/2, ..., -1] / (d*n) if n is odd
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Parameters
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----------
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n : int
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Window length.
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d : scalar, optional
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Sample spacing (inverse of the sampling rate). Defaults to 1.
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Returns
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-------
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f : ndarray
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Array of length `n` containing the sample frequencies.
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Examples
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--------
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>>> signal = np.array([-2, 8, 6, 4, 1, 0, 3, 5], dtype=float)
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>>> fourier = np.fft.fft(signal)
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>>> n = signal.size
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>>> timestep = 0.1
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>>> freq = np.fft.fftfreq(n, d=timestep)
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>>> freq
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array([ 0. , 1.25, 2.5 , 3.75, -5. , -3.75, -2.5 , -1.25])
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"""
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if not isinstance(n, integer_types):
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raise ValueError("n should be an integer")
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val = 1.0 / (n * d)
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results = empty(n, int)
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N = (n-1)//2 + 1
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p1 = arange(0, N, dtype=int)
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results[:N] = p1
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p2 = arange(-(n//2), 0, dtype=int)
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results[N:] = p2
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return results * val
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#return hstack((arange(0,(n-1)/2 + 1), arange(-(n/2),0))) / (n*d)
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def rfftfreq(n, d=1.0):
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"""
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Return the Discrete Fourier Transform sample frequencies
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(for usage with rfft, irfft).
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The returned float array `f` contains the frequency bin centers in cycles
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per unit of the sample spacing (with zero at the start). For instance, if
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the sample spacing is in seconds, then the frequency unit is cycles/second.
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Given a window length `n` and a sample spacing `d`::
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f = [0, 1, ..., n/2-1, n/2] / (d*n) if n is even
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f = [0, 1, ..., (n-1)/2-1, (n-1)/2] / (d*n) if n is odd
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Unlike `fftfreq` (but like `scipy.fftpack.rfftfreq`)
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the Nyquist frequency component is considered to be positive.
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Parameters
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----------
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n : int
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Window length.
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d : scalar, optional
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Sample spacing (inverse of the sampling rate). Defaults to 1.
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Returns
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-------
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f : ndarray
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Array of length ``n//2 + 1`` containing the sample frequencies.
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Examples
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--------
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>>> signal = np.array([-2, 8, 6, 4, 1, 0, 3, 5, -3, 4], dtype=float)
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>>> fourier = np.fft.rfft(signal)
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>>> n = signal.size
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>>> sample_rate = 100
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>>> freq = np.fft.fftfreq(n, d=1./sample_rate)
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>>> freq
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array([ 0., 10., 20., 30., 40., -50., -40., -30., -20., -10.])
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>>> freq = np.fft.rfftfreq(n, d=1./sample_rate)
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>>> freq
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array([ 0., 10., 20., 30., 40., 50.])
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"""
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if not isinstance(n, integer_types):
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raise ValueError("n should be an integer")
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val = 1.0/(n*d)
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N = n//2 + 1
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results = arange(0, N, dtype=int)
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return results * val
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class _FFTCache(object):
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"""
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Cache for the FFT twiddle factors as an LRU (least recently used) cache.
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Parameters
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----------
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max_size_in_mb : int
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Maximum memory usage of the cache before items are being evicted.
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max_item_count : int
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Maximum item count of the cache before items are being evicted.
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Notes
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-----
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Items will be evicted if either limit has been reached upon getting and
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setting. The maximum memory usages is not strictly the given
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``max_size_in_mb`` but rather
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``max(max_size_in_mb, 1.5 * size_of_largest_item)``. Thus the cache will
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never be completely cleared - at least one item will remain and a single
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large item can cause the cache to retain several smaller items even if the
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given maximum cache size has been exceeded.
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"""
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def __init__(self, max_size_in_mb, max_item_count):
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self._max_size_in_bytes = max_size_in_mb * 1024 ** 2
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self._max_item_count = max_item_count
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self._dict = collections.OrderedDict()
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self._lock = threading.Lock()
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def put_twiddle_factors(self, n, factors):
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"""
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Store twiddle factors for an FFT of length n in the cache.
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Putting multiple twiddle factors for a certain n will store it multiple
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times.
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Parameters
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----------
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n : int
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Data length for the FFT.
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factors : ndarray
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The actual twiddle values.
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"""
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with self._lock:
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# Pop + later add to move it to the end for LRU behavior.
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# Internally everything is stored in a dictionary whose values are
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# lists.
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try:
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value = self._dict.pop(n)
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except KeyError:
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value = []
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value.append(factors)
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self._dict[n] = value
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self._prune_cache()
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def pop_twiddle_factors(self, n):
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"""
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Pop twiddle factors for an FFT of length n from the cache.
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Will return None if the requested twiddle factors are not available in
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the cache.
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Parameters
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----------
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n : int
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Data length for the FFT.
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Returns
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-------
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out : ndarray or None
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The retrieved twiddle factors if available, else None.
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"""
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with self._lock:
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if n not in self._dict or not self._dict[n]:
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return None
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# Pop + later add to move it to the end for LRU behavior.
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all_values = self._dict.pop(n)
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value = all_values.pop()
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# Only put pack if there are still some arrays left in the list.
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if all_values:
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self._dict[n] = all_values
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return value
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def _prune_cache(self):
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# Always keep at least one item.
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while len(self._dict) > 1 and (
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len(self._dict) > self._max_item_count or self._check_size()):
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self._dict.popitem(last=False)
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def _check_size(self):
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item_sizes = [sum(_j.nbytes for _j in _i)
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for _i in self._dict.values() if _i]
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if not item_sizes:
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return False
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max_size = max(self._max_size_in_bytes, 1.5 * max(item_sizes))
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return sum(item_sizes) > max_size
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