Intelegentny_Pszczelarz/.venv/Lib/site-packages/scipy/datasets/_fetchers.py

from numpy import array, frombuffer, load
from ._registry import registry, registry_urls

try:
    import pooch
except ImportError:
    pooch = None
    data_fetcher = None
else:
    data_fetcher = pooch.create(
        # Use the default cache folder for the operating system
        # Pooch uses appdirs (https://github.com/ActiveState/appdirs) to
        # select an appropriate directory for the cache on each platform.
        path=pooch.os_cache("scipy-data"),

        # The remote data is on Github
        # base_url is a required param, even though we override this
        # using individual urls in the registry.
        base_url="https://github.com/scipy/",
        registry=registry,
        urls=registry_urls
    )


def fetch_data(dataset_name, data_fetcher=data_fetcher):
    if data_fetcher is None:
        raise ImportError("Missing optional dependency 'pooch' required "
                          "for scipy.datasets module. Please use pip or "
                          "conda to install 'pooch'.")
    # The "fetch" method returns the full path to the downloaded data file.
    return data_fetcher.fetch(dataset_name)


def ascent():
    """
    Get an 8-bit grayscale bit-depth, 512 x 512 derived image for easy
    use in demos.

    The image is derived from accent-to-the-top.jpg at
    http://www.public-domain-image.com/people-public-domain-images-pictures/

    Parameters
    ----------
    None

    Returns
    -------
    ascent : ndarray
       convenient image to use for testing and demonstration

    Examples
    --------
    >>> import scipy.datasets
    >>> ascent = scipy.datasets.ascent()
    >>> ascent.shape
    (512, 512)
    >>> ascent.max()
    255

    >>> import matplotlib.pyplot as plt
    >>> plt.gray()
    >>> plt.imshow(ascent)
    >>> plt.show()

    """
    import pickle

    # The file will be downloaded automatically the first time this is run,
    # returning the path to the downloaded file. Afterwards, Pooch finds
    # it in the local cache and doesn't repeat the download.
    fname = fetch_data("ascent.dat")
    # Now we just need to load it with our standard Python tools.
    with open(fname, 'rb') as f:
        ascent = array(pickle.load(f))
    return ascent


def electrocardiogram():
    """
    Load an electrocardiogram as an example for a 1-D signal.

    The returned signal is a 5 minute long electrocardiogram (ECG), a medical
    recording of the heart's electrical activity, sampled at 360 Hz.

    Returns
    -------
    ecg : ndarray
        The electrocardiogram in millivolt (mV) sampled at 360 Hz.

    Notes
    -----
    The provided signal is an excerpt (19:35 to 24:35) from the `record 208`_
    (lead MLII) provided by the MIT-BIH Arrhythmia Database [1]_ on
    PhysioNet [2]_. The excerpt includes noise induced artifacts, typical
    heartbeats as well as pathological changes.

    .. _record 208: https://physionet.org/physiobank/database/html/mitdbdir/records.htm#208

    .. versionadded:: 1.1.0

    References
    ----------
    .. [1] Moody GB, Mark RG. The impact of the MIT-BIH Arrhythmia Database.
           IEEE Eng in Med and Biol 20(3):45-50 (May-June 2001).
           (PMID: 11446209); :doi:`10.13026/C2F305`
    .. [2] Goldberger AL, Amaral LAN, Glass L, Hausdorff JM, Ivanov PCh,
           Mark RG, Mietus JE, Moody GB, Peng C-K, Stanley HE. PhysioBank,
           PhysioToolkit, and PhysioNet: Components of a New Research Resource
           for Complex Physiologic Signals. Circulation 101(23):e215-e220;
           :doi:`10.1161/01.CIR.101.23.e215`

    Examples
    --------
    >>> from scipy.datasets import electrocardiogram
    >>> ecg = electrocardiogram()
    >>> ecg
    array([-0.245, -0.215, -0.185, ..., -0.405, -0.395, -0.385])
    >>> ecg.shape, ecg.mean(), ecg.std()
    ((108000,), -0.16510875, 0.5992473991177294)

    As stated the signal features several areas with a different morphology.
    E.g., the first few seconds show the electrical activity of a heart in
    normal sinus rhythm as seen below.

    >>> import numpy as np
    >>> import matplotlib.pyplot as plt
    >>> fs = 360
    >>> time = np.arange(ecg.size) / fs
    >>> plt.plot(time, ecg)
    >>> plt.xlabel("time in s")
    >>> plt.ylabel("ECG in mV")
    >>> plt.xlim(9, 10.2)
    >>> plt.ylim(-1, 1.5)
    >>> plt.show()

    After second 16, however, the first premature ventricular contractions,
    also called extrasystoles, appear. These have a different morphology
    compared to typical heartbeats. The difference can easily be observed
    in the following plot.

    >>> plt.plot(time, ecg)
    >>> plt.xlabel("time in s")
    >>> plt.ylabel("ECG in mV")
    >>> plt.xlim(46.5, 50)
    >>> plt.ylim(-2, 1.5)
    >>> plt.show()

    At several points large artifacts disturb the recording, e.g.:

    >>> plt.plot(time, ecg)
    >>> plt.xlabel("time in s")
    >>> plt.ylabel("ECG in mV")
    >>> plt.xlim(207, 215)
    >>> plt.ylim(-2, 3.5)
    >>> plt.show()

    Finally, examining the power spectrum reveals that most of the biosignal is
    made up of lower frequencies. At 60 Hz the noise induced by the mains
    electricity can be clearly observed.

    >>> from scipy.signal import welch
    >>> f, Pxx = welch(ecg, fs=fs, nperseg=2048, scaling="spectrum")
    >>> plt.semilogy(f, Pxx)
    >>> plt.xlabel("Frequency in Hz")
    >>> plt.ylabel("Power spectrum of the ECG in mV**2")
    >>> plt.xlim(f[[0, -1]])
    >>> plt.show()
    """
    fname = fetch_data("ecg.dat")
    with load(fname) as file:
        ecg = file["ecg"].astype(int)  # np.uint16 -> int
    # Convert raw output of ADC to mV: (ecg - adc_zero) / adc_gain
    ecg = (ecg - 1024) / 200.0
    return ecg


def face(gray=False):
    """
    Get a 1024 x 768, color image of a raccoon face.

    raccoon-procyon-lotor.jpg at http://www.public-domain-image.com

    Parameters
    ----------
    gray : bool, optional
        If True return 8-bit grey-scale image, otherwise return a color image

    Returns
    -------
    face : ndarray
        image of a racoon face

    Examples
    --------
    >>> import scipy.datasets
    >>> face = scipy.datasets.face()
    >>> face.shape
    (768, 1024, 3)
    >>> face.max()
    255
    >>> face.dtype
    dtype('uint8')

    >>> import matplotlib.pyplot as plt
    >>> plt.gray()
    >>> plt.imshow(face)
    >>> plt.show()

    """
    import bz2
    fname = fetch_data("face.dat")
    with open(fname, 'rb') as f:
        rawdata = f.read()
    face_data = bz2.decompress(rawdata)
    face = frombuffer(face_data, dtype='uint8')
    face.shape = (768, 1024, 3)
    if gray is True:
        face = (0.21 * face[:, :, 0] + 0.71 * face[:, :, 1] +
                0.07 * face[:, :, 2]).astype('uint8')
    return face
feature: "ANN commit 2" 2023-06-19 00:49:18 +02:00			`from numpy import array, frombuffer, load`
			`from ._registry import registry, registry_urls`

			`try:`
			`import pooch`
			`except ImportError:`
			`pooch = None`
			`data_fetcher = None`
			`else:`
			`data_fetcher = pooch.create(`
			`# Use the default cache folder for the operating system`
			`# Pooch uses appdirs (https://github.com/ActiveState/appdirs) to`
			`# select an appropriate directory for the cache on each platform.`
			`path=pooch.os_cache("scipy-data"),`

			`# The remote data is on Github`
			`# base_url is a required param, even though we override this`
			`# using individual urls in the registry.`
			`base_url="https://github.com/scipy/",`
			`registry=registry,`
			`urls=registry_urls`
			`)`


			`def fetch_data(dataset_name, data_fetcher=data_fetcher):`
			`if data_fetcher is None:`
			`raise ImportError("Missing optional dependency 'pooch' required "`
			`"for scipy.datasets module. Please use pip or "`
			`"conda to install 'pooch'.")`
			`# The "fetch" method returns the full path to the downloaded data file.`
			`return data_fetcher.fetch(dataset_name)`


			`def ascent():`
			`"""`
			`Get an 8-bit grayscale bit-depth, 512 x 512 derived image for easy`
			`use in demos.`

			`The image is derived from accent-to-the-top.jpg at`
			`http://www.public-domain-image.com/people-public-domain-images-pictures/`

			`Parameters`
			`----------`
			`None`

			`Returns`
			`-------`
			`ascent : ndarray`
			`convenient image to use for testing and demonstration`

			`Examples`
			`--------`
			`>>> import scipy.datasets`
			`>>> ascent = scipy.datasets.ascent()`
			`>>> ascent.shape`
			`(512, 512)`
			`>>> ascent.max()`
			`255`

			`>>> import matplotlib.pyplot as plt`
			`>>> plt.gray()`
			`>>> plt.imshow(ascent)`
			`>>> plt.show()`

			`"""`
			`import pickle`

			`# The file will be downloaded automatically the first time this is run,`
			`# returning the path to the downloaded file. Afterwards, Pooch finds`
			`# it in the local cache and doesn't repeat the download.`
			`fname = fetch_data("ascent.dat")`
			`# Now we just need to load it with our standard Python tools.`
			`with open(fname, 'rb') as f:`
			`ascent = array(pickle.load(f))`
			`return ascent`


			`def electrocardiogram():`
			`"""`
			`Load an electrocardiogram as an example for a 1-D signal.`

			`The returned signal is a 5 minute long electrocardiogram (ECG), a medical`
			`recording of the heart's electrical activity, sampled at 360 Hz.`

			`Returns`
			`-------`
			`ecg : ndarray`
			`The electrocardiogram in millivolt (mV) sampled at 360 Hz.`

			`Notes`
			`-----`
			The provided signal is an excerpt (19:35 to 24:35) from the `record 208`_
			`(lead MLII) provided by the MIT-BIH Arrhythmia Database [1]_ on`
			`PhysioNet [2]_. The excerpt includes noise induced artifacts, typical`
			`heartbeats as well as pathological changes.`

			`.. _record 208: https://physionet.org/physiobank/database/html/mitdbdir/records.htm#208`

			`.. versionadded:: 1.1.0`

			`References`
			`----------`
			`.. [1] Moody GB, Mark RG. The impact of the MIT-BIH Arrhythmia Database.`
			`IEEE Eng in Med and Biol 20(3):45-50 (May-June 2001).`
			(PMID: 11446209); :doi:`10.13026/C2F305`
			`.. [2] Goldberger AL, Amaral LAN, Glass L, Hausdorff JM, Ivanov PCh,`
			`Mark RG, Mietus JE, Moody GB, Peng C-K, Stanley HE. PhysioBank,`
			`PhysioToolkit, and PhysioNet: Components of a New Research Resource`
			`for Complex Physiologic Signals. Circulation 101(23):e215-e220;`
			:doi:`10.1161/01.CIR.101.23.e215`

			`Examples`
			`--------`
			`>>> from scipy.datasets import electrocardiogram`
			`>>> ecg = electrocardiogram()`
			`>>> ecg`
			`array([-0.245, -0.215, -0.185, ..., -0.405, -0.395, -0.385])`
			`>>> ecg.shape, ecg.mean(), ecg.std()`
			`((108000,), -0.16510875, 0.5992473991177294)`

			`As stated the signal features several areas with a different morphology.`
			`E.g., the first few seconds show the electrical activity of a heart in`
			`normal sinus rhythm as seen below.`

			`>>> import numpy as np`
			`>>> import matplotlib.pyplot as plt`
			`>>> fs = 360`
			`>>> time = np.arange(ecg.size) / fs`
			`>>> plt.plot(time, ecg)`
			`>>> plt.xlabel("time in s")`
			`>>> plt.ylabel("ECG in mV")`
			`>>> plt.xlim(9, 10.2)`
			`>>> plt.ylim(-1, 1.5)`
			`>>> plt.show()`

			`After second 16, however, the first premature ventricular contractions,`
			`also called extrasystoles, appear. These have a different morphology`
			`compared to typical heartbeats. The difference can easily be observed`
			`in the following plot.`

			`>>> plt.plot(time, ecg)`
			`>>> plt.xlabel("time in s")`
			`>>> plt.ylabel("ECG in mV")`
			`>>> plt.xlim(46.5, 50)`
			`>>> plt.ylim(-2, 1.5)`
			`>>> plt.show()`

			`At several points large artifacts disturb the recording, e.g.:`

			`>>> plt.plot(time, ecg)`
			`>>> plt.xlabel("time in s")`
			`>>> plt.ylabel("ECG in mV")`
			`>>> plt.xlim(207, 215)`
			`>>> plt.ylim(-2, 3.5)`
			`>>> plt.show()`

			`Finally, examining the power spectrum reveals that most of the biosignal is`
			`made up of lower frequencies. At 60 Hz the noise induced by the mains`
			`electricity can be clearly observed.`

			`>>> from scipy.signal import welch`
			`>>> f, Pxx = welch(ecg, fs=fs, nperseg=2048, scaling="spectrum")`
			`>>> plt.semilogy(f, Pxx)`
			`>>> plt.xlabel("Frequency in Hz")`
			`>>> plt.ylabel("Power spectrum of the ECG in mV**2")`
			`>>> plt.xlim(f[[0, -1]])`
			`>>> plt.show()`
			`"""`
			`fname = fetch_data("ecg.dat")`
			`with load(fname) as file:`
			`ecg = file["ecg"].astype(int) # np.uint16 -> int`
			`# Convert raw output of ADC to mV: (ecg - adc_zero) / adc_gain`
			`ecg = (ecg - 1024) / 200.0`
			`return ecg`


			`def face(gray=False):`
			`"""`
			`Get a 1024 x 768, color image of a raccoon face.`

			`raccoon-procyon-lotor.jpg at http://www.public-domain-image.com`

			`Parameters`
			`----------`
			`gray : bool, optional`
			`If True return 8-bit grey-scale image, otherwise return a color image`

			`Returns`
			`-------`
			`face : ndarray`
			`image of a racoon face`

			`Examples`
			`--------`
			`>>> import scipy.datasets`
			`>>> face = scipy.datasets.face()`
			`>>> face.shape`
			`(768, 1024, 3)`
			`>>> face.max()`
			`255`
			`>>> face.dtype`
			`dtype('uint8')`

			`>>> import matplotlib.pyplot as plt`
			`>>> plt.gray()`
			`>>> plt.imshow(face)`
			`>>> plt.show()`

			`"""`
			`import bz2`
			`fname = fetch_data("face.dat")`
			`with open(fname, 'rb') as f:`
			`rawdata = f.read()`
			`face_data = bz2.decompress(rawdata)`
			`face = frombuffer(face_data, dtype='uint8')`
			`face.shape = (768, 1024, 3)`
			`if gray is True:`
			`face = (0.21 * face[:, :, 0] + 0.71 * face[:, :, 1] +`
			`0.07 * face[:, :, 2]).astype('uint8')`
			`return face`