import numpy as np from PyQt5.QtWidgets import * from PyQt5.QtGui import * from PyQt5.QtCore import * from ui import GUI, Pens # the fuck class ExpandingSpacer(QSpacerItem): def __init__(self): super().__init__(0, 0, QSizePolicy.Minimum, \ QSizePolicy.Expanding) class MeinLabel(QLabel): def __init__(self, *args): QLabel.__init__(self, *args) self.setFont(GUI.monospace) class MeinGroßLabel(QLabel): def __init__(self, *args): QLabel.__init__(self, *args) self.setFont(GUI.bigfont) self.setAlignment(Qt.AlignHCenter) class EllipseWidget(QWidget): def __init__(self, pol): QWidget.__init__(self) self.pol = pol self.state = None self.ellipse = None self.is_used = True self.setSizePolicy(QSizePolicy(QSizePolicy.MinimumExpanding, \ QSizePolicy.MinimumExpanding)) def minimumSizeHint(self): return QSize(170, 170) def paintEvent(self, event): P = QPainter(self) w, h = self.frameSize().width(), self.frameSize().height() cx, cy = w / 2, h / 2 r = min(w, h) / 2 # background if self.is_used: background = Qt.white else: background = QColor(0, 0, 0, 100) P.fillRect(QRect(0, 0, w, h), background) # coordinate axes P.setPen(Pens.axes) P.drawLine(cx - 20 * r, cy, cx + 20 * r, cy) P.drawLine(cx, cy - 20 * r, cx, cy + 20 * r) # polarizer axes P.translate(cx, cy) P.rotate(- (self.pol.angle + self.pol.delta) * 180 / np.pi) if self.pol.type == "linear": P.setPen(Pens.axis_linear) P.drawLine(-20 * r, 0, 20 * r, 0) else: P.setPen(Pens.axis_fast) P.drawLine(-20 * r, 0, 20 * r, 0) P.drawText(0.92 * r, 0, "F") P.setPen(Pens.axis_slow) P.drawLine(0, -20 * r, 0, 20 * r) P.drawText(0, -0.92 * r, "S") if self.state is None: return if np.isnan(self.ellipse.a) or np.isnan(self.ellipse.b) \ or np.isnan(self.ellipse.alpha) or np.isnan(self.ellipse.theta): return P.resetTransform() r *= 0.88 P.translate(cx, cy) P.scale(1, -1) # radii P.setPen(Pens.radii) csa = np.array([np.cos(self.ellipse.alpha), np.sin(self.ellipse.alpha)]) xa = self.ellipse.a * r * csa P.drawLine(-xa[0], -xa[1], xa[0], xa[1]) csb = np.array([np.cos(self.ellipse.alpha + np.pi / 2), \ np.sin(self.ellipse.alpha + np.pi / 2)]) xb = self.ellipse.b * r * csb P.drawLine(-xb[0], -xb[1], xb[0], xb[1]) def arc(x, y, r, t1, t2): P.drawArc(x - r / 2, y - r / 2, r, r, \ -180 * 16 / np.pi * t1, \ -180 * 16 / np.pi * t2) # azimuth P.setPen(Pens.alpha) P.drawLine(0, 0, xa[0], xa[1]) arc(0, 0, self.ellipse.a * r, 0, self.ellipse.alpha) # ellipticity P.setPen(Pens.theta) P.drawLine(-xa[0], -xa[1], xb[0], xb[1]) arc(-xa[0], -xa[1], r / 2, self.ellipse.alpha, abs(self.ellipse.theta)) # the ellipse P.setPen(Pens.ellipse) path = QPainterPath() for i, t in enumerate(np.linspace(0, 2 * np.pi, 100)): x = r * np.real(np.exp(1j * t) * self.state) f = path.moveTo if t == 0 else path.lineTo # FML f(x[0], x[1]) # +Y should be upwards if abs(self.ellipse.theta) > 0.05 and i % 25 == 0: N = r * np.real(np.exp(1j * (t + 0.001)) * self.state) - x N /= np.linalg.norm(N) if np.any(np.isnan(N)): continue T = np.dot(np.array([[0, 1], [-1, 0]]), N) ax = x - N * 5 + T * 5 P.drawLine(x[0], x[1], ax[0], ax[1]) ax = x - N * 5 - T * 5 P.drawLine(x[0], x[1], ax[0], ax[1]) path.closeSubpath() P.drawPath(path) if abs(self.ellipse.theta) <= 0.05: x1 = xa - r / 20 * csb x2 = xa + r / 20 * csb P.drawLine(x1[0], x1[1], x2[0], x2[1]) x1 = -xa - r / 20 * csb x2 = -xa + r / 20 * csb P.drawLine(x1[0], x1[1], x2[0], x2[1]) class AngleSlider(QHBoxLayout): def __init__(self, label=None): super().__init__() self.angle = 0 if label: self.addWidget(QLabel(label)) self.slider = QSlider(Qt.Horizontal) self.slider.setMinimumWidth(100) self.slider.setMinimum(0) self.slider.setMaximum(180) self.slider.setTickPosition(QSlider.TicksBelow) self.slider.setTickInterval(45) self.slider.valueChanged.connect(\ lambda: AngleSlider.change(self, "bar")) self.addWidget(self.slider) self.edit = QLineEdit() self.edit.setText("0") self.edit.setFixedWidth(45) self.edit.textChanged.connect(\ lambda: AngleSlider.change(self, "edit")) self.addWidget(self.edit) self.addWidget(QLabel("°")) def setValue(self, angle): self.angle = angle self.slider.blockSignals(True) self.slider.setValue(angle) self.slider.blockSignals(False) self.edit.blockSignals(True) self.edit.setText("%g" % angle) self.edit.blockSignals(False) @staticmethod def change(self, source): if source == "edit": try: angle = float(self.edit.text()) except ValueError: return self.slider.blockSignals(True) self.slider.setValue(angle) self.slider.blockSignals(False) elif source == "bar": angle = self.slider.value() self.edit.blockSignals(True) self.edit.setText("%g" % angle) self.edit.blockSignals(False) self.angle = angle self.on_change() class Widocques(QWidget): image = None def __init__(self): QWidget.__init__(self) self.setSizePolicy(QSizePolicy(QSizePolicy.Expanding, QSizePolicy.Expanding)) self.intensity = 1 def minimumSizeHint(self): return QSize(100, 100) def paintEvent(self, event): P = QPainter(self) w, h = self.frameSize().width(), self.frameSize().height() ar = Widocques.image.width() \ / Widocques.image.height() if w / h > ar: # pad left/right w2 = h * ar pad = (w - w2) / 2 rect = QRect(pad, 0, w2, h) else: # pad top/bottom h2 = w / ar pad = (h - h2) / 2 rect = QRect(0, pad, w, h2) w2 = rect.width() h2 = rect.height() rect2 = QRect(rect.left() + 0.1 * w2, rect.top() + 0.1 * h2, \ w2 * 0.8, h2 * 0.8) P.fillRect(QRect(0, 0, w, h), Qt.black) P.drawImage(rect2, Widocques.image) P.fillRect(rect2, QColor(0, 0, 0, 255 * (1 - self.intensity)))