minipyrelacs/pyrelacs/app.py

import pathlib
from PyQt6.QtGui import QAction
import sys

from PyQt6.QtCore import QSize, QThreadPool, QSettings
from PyQt6.QtWidgets import (
    QApplication,
    QGridLayout,
    QPushButton,
    QToolBar,
    QWidget,
    QMainWindow,
    QPlainTextEdit,
)
import pyqtgraph as pg
import uldaq
from IPython import embed
from scipy.signal import welch, find_peaks
import numpy as np
import nixio as nix

from pyrelacs.util.logging import config_logging
import pyrelacs.info as info
from pyrelacs.worker import Worker
from pyrelacs.repros.repros import Repro

log = config_logging()


class PyRelacs(QMainWindow):
    def __init__(self):
        super().__init__()
        self.setWindowTitle("PyRelacs")
        self.beat_plot = pg.PlotWidget()
        self.power_plot = pg.PlotWidget()

        self.threadpool = QThreadPool()
        self.repros = Repro()

        self.daq_connect_button = QPushButton("Connect Daq")
        self.daq_connect_button.setCheckable(True)
        self.daq_connect_button.clicked.connect(self.connect_dac)

        self.daq_disconnect_button = QPushButton("Disconnect Daq")
        self.daq_disconnect_button.setCheckable(True)
        self.daq_disconnect_button.clicked.connect(self.disconnect_dac)

        self.plot_calibration_button = QPushButton("Plot Calibration")
        self.plot_calibration_button.setCheckable(True)
        self.plot_calibration_button.clicked.connect(self.plot_calibration)

        layout = QGridLayout()
        layout.addWidget(self.plot_calibration_button, 0, 0)
        layout.addWidget(self.daq_disconnect_button, 0, 1)
        layout.addWidget(self.beat_plot, 2, 0, 1, 2)
        layout.addWidget(self.power_plot, 3, 0, 1, 2)

        self.toolbar = QToolBar("Repros")
        self.addToolBar(self.toolbar)
        self.repros_to_toolbar()

        # self.setFixedSize(QSize(400, 300))
        widget = QWidget()
        widget.setLayout(layout)
        self.setCentralWidget(widget)

        self.nix_file = nix.File.open(
            str(pathlib.Path(__file__).parent / "data"), nix.FileMode.ReadOnly
        )

    def plot_calibration(self):
        def decibel(power, ref_power=1.0, min_power=1e-20):
            """Transform power to decibel relative to ref_power.

            \\[ decibel = 10 \\cdot \\log_{10}(power/ref\\_power) \\]
            Power values smaller than `min_power` are set to `-np.inf`.

            Parameters
            ----------
            power: float or array
                Power values, for example from a power spectrum or spectrogram.
            ref_power: float or None or 'peak'
                Reference power for computing decibel.
                If set to `None` or 'peak', the maximum power is used.
            min_power: float
                Power values smaller than `min_power` are set to `-np.inf`.

            Returns
            -------
            decibel_psd: array
                Power values in decibel relative to `ref_power`.
            """
            if np.isscalar(power):
                tmp_power = np.array([power])
                decibel_psd = np.array([power])
            else:
                tmp_power = power
                decibel_psd = power.copy()
            if ref_power is None or ref_power == "peak":
                ref_power = np.max(decibel_psd)
            decibel_psd[tmp_power <= min_power] = float("-inf")
            decibel_psd[tmp_power > min_power] = 10.0 * np.log10(
                decibel_psd[tmp_power > min_power] / ref_power
            )
            if np.isscalar(power):
                return decibel_psd[0]
            else:
                return decibel_psd

        block = self.nix_file.blocks[0]
        colors = ["red", "green", "blue", "black", "yellow"]
        for i, (stim, fish) in enumerate(
            zip(list(block.data_arrays)[::2], list(block.data_arrays)[1::2])
        ):
            beat = stim[:] + fish[:]
            beat_squared = beat**2

            f, powerspec = welch(beat, fs=40_000.0)
            # powerspec = decibel(powerspec)

            f_sq, powerspec_sq = welch(beat_squared, fs=40_000.0)
            powerspec_sq = decibel(powerspec_sq)
            peaks = find_peaks(powerspec_sq, prominence=20)[0]
            pen = pg.mkPen(colors[i])
            self.beat_plot.plot(
                np.arange(0, len(beat)) / 40_000.0,
                beat,
                pen=pen,
                # name=stim.name,
            )
            self.power_plot.plot(f, powerspec, pen=pen)
            # self.power_plot.plot(f[peaks], powerspec_sq[peaks], pen=None, symbol="x")

    def connect_dac(self):
        devices = uldaq.get_daq_device_inventory(uldaq.InterfaceType.USB)
        try:
            self.daq_device = uldaq.DaqDevice(devices[0])
            log.debug(f"Found daq devices {len(devices)}, connecting to the first one")
            self.daq_device.connect()
            log.debug("Connected")
        except IndexError:
            log.debug("DAQ is not connected, closing")
            QApplication.quit()
        self.daq_connect_button.setDisabled(True)

    def disconnect_dac(self):
        try:
            log.debug(f"{self.daq_device}")
            self.daq_device.disconnect()
            self.daq_device.release()
            log.debug(f"{self.daq_device}")
            self.daq_disconnect_button.setDisabled(True)
            self.daq_connect_button.setEnabled(True)
        except AttributeError:
            log.debug("DAQ was not connected")

    def repros_to_toolbar(self):
        repro_names, file_names = self.repros.names_of_repros()
        for rep, fn in zip(repro_names, file_names):
            individual_repro_button = QAction(rep, self)
            individual_repro_button.setStatusTip("Button")
            individual_repro_button.triggered.connect(
                lambda checked, n=rep, f=fn: self.run_repro(n, f)
            )
            self.toolbar.addAction(individual_repro_button)

    def run_repro(self, n, fn):
        log.debug(f"Running repro {n} in the file {fn}")
        worker = Worker(self.repros.run_repro, self.nix_file, n, fn)
        worker.signals.result.connect(self.print_output)
        worker.signals.finished.connect(self.thread_complete)
        worker.signals.progress.connect(self.progress_fn)

        self.threadpool.start(worker)

    def print_output(self, s):
        print(s)

    def thread_complete(self):
        print("THREAD COMPLETE!")

    def progress_fn(self, n):
        print("%d%% done" % n)


def main():
    app = QApplication(sys.argv)
    app.setApplicationName(info.NAME)
    app.setApplicationVersion(str(info.VERSION))
    app.setOrganizationDomain(info.ORGANIZATION)

    # read window settings
    settings = QSettings(info.ORGANIZATION, info.NAME)
    width = int(settings.value("app/width", 1024))
    height = int(settings.value("app/height", 768))
    x = int(settings.value("app/pos_x", 100))
    y = int(settings.value("app/pos_y", 100))

    window = PyRelacs()
    window.setMinimumWidth(200)
    window.setMinimumHeight(200)
    window.resize(width, height)
    window.move(x, y)
    window.show()
    exit_code = app.exec()

    # store window position and size
    pos = window.pos()
    settings.setValue("app/width", window.width())
    settings.setValue("app/height", window.height())
    settings.setValue("app/pos_x", pos.x())
    settings.setValue("app/pos_y", pos.y())
    sys.exit(exit_code)


if __name__ == "__main__":
    main()