# https://pyrocko.org - GPLv3
#
# The Pyrocko Developers, 21st Century
# ---|P------/S----------~Lg----------
import sys
import math
import time
import numpy as num
import logging
import enum
import calendar
import signal
import weakref
from matplotlib.colors import Normalize
from .qt_compat import qc, qg, qw
from .snuffler.marker import Marker, PhaseMarker, EventMarker # noqa
from .snuffler.marker import MarkerParseError, MarkerOneNSLCRequired # noqa
from .snuffler.marker import load_markers, save_markers # noqa
from pyrocko import plot, util
from pyrocko.squirrel import join_coverages
logger = logging.getLogger('pyrocko.gui.util')
class _Getch:
'''
Gets a single character from standard input.
Does not echo to the screen.
https://stackoverflow.com/questions/510357/how-to-read-a-single-character-from-the-user
'''
def __init__(self):
try:
self.impl = _GetchWindows()
except ImportError:
self.impl = _GetchUnix()
def __call__(self): return self.impl()
class _GetchUnix:
def __init__(self):
import tty, sys # noqa
def __call__(self):
import sys
import tty
import termios
fd = sys.stdin.fileno()
old_settings = termios.tcgetattr(fd)
try:
tty.setraw(fd)
ch = sys.stdin.read(1)
finally:
termios.tcsetattr(fd, termios.TCSADRAIN, old_settings)
return ch
class _GetchWindows:
def __init__(self):
import msvcrt # noqa
def __call__(self):
import msvcrt
return msvcrt.getch()
getch = _Getch()
class PyrockoQApplication(qw.QApplication):
def __init__(self):
qw.QApplication.__init__(self, [])
self._main_window = None
self._slow_operations_disabled = 0
def install_sigint_handler(self):
self._old_signal_handler = signal.signal(
signal.SIGINT,
self.request_close_all_windows)
def uninstall_sigint_handler(self):
signal.signal(signal.SIGINT, self._old_signal_handler)
def set_main_window(self, win):
self._main_window = win
name = win.windowTitle() if win is not None else ''
self.setApplicationName(name)
self.setApplicationDisplayName(name)
self.setDesktopFileName(name)
def unset_main_window(self):
self.set_main_window(None)
def get_main_window(self):
return self._main_window
def get_main_windows(self):
return [self.get_main_window()]
def status(self, message, duration=None):
win = self.get_main_window()
if not win:
print(' - %s' % message, file=sys.stderr)
else:
win.statusBar().showMessage(
message, int((duration or 0) * 1000))
def event(self, e):
if isinstance(e, qg.QFileOpenEvent):
path = str(e.file())
if path != sys.argv[0]:
wins = self.get_main_windows()
if wins:
if hasattr(wins[0], 'get_view'):
wins[0].get_view().load_soon([path])
return True
else:
return qw.QApplication.event(self, e)
def request_close_all_windows(self, *args):
def confirm():
try:
print(
'\nQuit %s? [y/n]' % self.applicationName(),
file=sys.stderr)
confirmed = getch() == 'y'
if not confirmed:
print(
'Continuing.',
file=sys.stderr)
else:
print(
'Quitting %s.' % self.applicationName(),
file=sys.stderr)
return confirmed
except Exception:
return False
windows = self.get_main_windows()
instant_close = all(win.instant_close for win in windows)
if instant_close or confirm():
for win in windows:
win.instant_close = True
self.closeAllWindows()
def disable_slow_operations(self):
self._slow_operations_disabled += 1
def enable_slow_operations(self):
self._slow_operations_disabled -= 1
if self._slow_operations_disabled < 0:
self._slow_operations_disabled = 0
def slow_operations_enabled(self):
return self._slow_operations_disabled == 0
app = None
def get_app():
from .qt_compat import qg
try:
global app
if app is None:
qg.QSurfaceFormat.setDefaultFormat(qg.QSurfaceFormat())
app = PyrockoQApplication()
return app
except NameError: # can happen during shutdown
return None
def rint(x):
return int(round(x))
def make_QPolygonF(xdata, ydata):
assert len(xdata) == len(ydata)
n = len(xdata)
qpoints = qg.QPolygonF(n)
vptr = qpoints.data()
vptr.setsize(n*8*2)
aa = num.ndarray(
shape=(n, 2),
dtype=num.float64,
buffer=memoryview(vptr))
aa.setflags(write=True)
aa[:, 0] = xdata
aa[:, 1] = ydata
return qpoints
def get_colormap_qimage(cmap_name, vmin=None, vmax=None):
NCOLORS = 512
norm = Normalize()
norm.vmin = vmin
norm.vmax = vmax
return qg.QImage(
plot.mpl_get_cmap(cmap_name)(
norm(num.linspace(0., 1., NCOLORS)),
alpha=None, bytes=True),
NCOLORS, 1, qg.QImage.Format_RGBX8888)
class Label(object):
def __init__(
self, p, x, y, label_str,
label_bg=None,
anchor='BL',
outline=False,
font=None,
color=None):
text = qg.QTextDocument()
if font:
text.setDefaultFont(font)
text.setDefaultStyleSheet('span { color: %s; }' % color.name())
text.setHtml('<span>%s</span>' % label_str)
s = text.size()
rect = qc.QRect(0, 0, int(s.width()), int(s.height()))
tx, ty = x, y
if 'B' in anchor:
ty -= rect.height()
if 'R' in anchor:
tx -= rect.width()
if 'M' in anchor:
ty -= rect.height() // 2
if 'C' in anchor:
tx -= rect.width() // 2
rect.translate(int(tx), int(ty))
self.rect = rect
self.text = text
self.outline = outline
self.label_bg = label_bg
self.color = color
self.p = p
def draw(self):
p = self.p
rect = self.rect
tx = rect.left()
ty = rect.top()
if self.outline:
oldpen = p.pen()
oldbrush = p.brush()
p.setBrush(self.label_bg)
rect.adjust(-2, 0, 2, 0)
p.drawRect(rect)
p.setPen(oldpen)
p.setBrush(oldbrush)
else:
if self.label_bg:
p.fillRect(rect, self.label_bg)
p.translate(int(tx), int(ty))
self.text.drawContents(p)
p.translate(-int(tx), -int(ty))
def draw_label(p, x, y, label_str, label_bg, anchor='BL', outline=False):
fm = p.fontMetrics()
label = label_str
rect = fm.boundingRect(label)
tx, ty = x, y
if 'T' in anchor:
ty += rect.height()
if 'R' in anchor:
tx -= rect.width()
if 'M' in anchor:
ty += rect.height() // 2
if 'C' in anchor:
tx -= rect.width() // 2
rect.translate(int(tx), int(ty))
if outline:
oldpen = p.pen()
oldbrush = p.brush()
p.setBrush(label_bg)
rect.adjust(-2, 0, 2, 0)
p.drawRect(rect)
p.setPen(oldpen)
p.setBrush(oldbrush)
else:
p.fillRect(rect, label_bg)
p.drawText(int(tx), int(ty), label)
def get_err_palette():
err_palette = qg.QPalette()
err_palette.setColor(qg.QPalette.Base, qg.QColor(255, 200, 200))
return err_palette
class QSliderNoWheel(qw.QSlider):
def wheelEvent(self, ev):
''
ev.ignore()
def keyPressEvent(self, ev):
''
ev.ignore()
class QSliderFloat(qw.QSlider):
sliderMovedFloat = qc.pyqtSignal(float)
valueChangedFloat = qc.pyqtSignal(float)
rangeChangedFloat = qc.pyqtSignal(float, float)
def __init__(self, *args, **kwargs):
qw.QSlider.__init__(self, *args, **kwargs)
self.setMinimum(0)
self.setMaximum(1000)
self.setSingleStep(10)
self.setPageStep(100)
self._fmin = 0.
self._fmax = 1.
self.valueChanged.connect(self._handleValueChanged)
self.sliderMoved.connect(self._handleSliderMoved)
def _f_to_i(self, fval):
fval = float(fval)
imin = self.minimum()
imax = self.maximum()
return max(
imin,
imin + min(
int(round(
(fval-self._fmin) * (imax - imin)
/ (self._fmax-self._fmin))),
imax))
def _i_to_f(self, ival):
imin = self.minimum()
imax = self.maximum()
return self._fmin + (ival - imin) * (self._fmax - self._fmin) \
/ (imax - imin)
def minimumFloat(self):
return self._fmin
def setMinimumFloat(self, fval):
self._fmin = float(fval)
self.rangeChangedFloat.emit(self._fmin, self._fmax)
def maximumFloat(self):
return self._fmax
def setMaximumFloat(self, fval):
self._fmax = float(fval)
self.rangeChangedFloat.emit(self._fmin, self._fmax)
def setRangeFloat(self, fmin, fmax):
self._fmin = float(fmin)
self._fmax = float(fmax)
self.rangeChangedFloat.emit(self._fmin, self._fmax)
def valueFloat(self):
return self._i_to_f(self.value())
def setValueFloat(self, fval):
qw.QSlider.setValue(self, self._f_to_i(fval))
def _handleValueChanged(self, ival):
self.valueChangedFloat.emit(self._i_to_f(ival))
def _handleSliderMoved(self, ival):
self.sliderMovedFloat.emit(self._i_to_f(ival))
class MyValueEdit(qw.QLineEdit):
edited = qc.pyqtSignal(float)
def __init__(
self,
low_is_none=False,
high_is_none=False,
low_is_zero=False,
*args, **kwargs):
qw.QLineEdit.__init__(self, *args, **kwargs)
self.value = 0.
self.mi = 0.
self.ma = 1.
self.low_is_none = low_is_none
self.high_is_none = high_is_none
self.low_is_zero = low_is_zero
self.editingFinished.connect(
self.myEditingFinished)
self.lock = False
def setRange(self, mi, ma):
self.mi = mi
self.ma = ma
def setValue(self, value):
if not self.lock:
self.value = value
self.setPalette(qw.QApplication.palette())
self.adjust_text()
def myEditingFinished(self):
try:
t = str(self.text()).strip()
if self.low_is_none and t in ('off', 'below'):
value = self.mi
elif self.high_is_none and t in ('off', 'above'):
value = self.ma
elif self.low_is_zero and float(t) == 0.0:
value = self.mi
else:
value = float(t)
if not (self.mi <= value <= self.ma):
raise Exception('out of range')
if value != self.value:
self.value = value
self.lock = True
self.edited.emit(value)
self.setPalette(qw.QApplication.palette())
except Exception:
self.setPalette(get_err_palette())
self.lock = False
def adjust_text(self):
t = ('%8.5g' % self.value).strip()
if self.low_is_zero and self.value == self.mi:
t = '0'
if self.low_is_none and self.value == self.mi:
if self.high_is_none:
t = 'below'
else:
t = 'off'
if self.high_is_none and self.value == self.ma:
if self.low_is_none:
t = 'above'
else:
t = 'off'
if t in ('off', 'below', 'above'):
self.setStyleSheet('font-style: italic;')
else:
self.setStyleSheet(None)
self.setText(t)
class ValControl(qw.QWidget):
valchange = qc.pyqtSignal(object, int)
def __init__(
self,
low_is_none=False,
high_is_none=False,
low_is_zero=False,
type=float,
*args):
qc.QObject.__init__(self, *args)
self.lname = qw.QLabel('name')
self.lname.setSizePolicy(
qw.QSizePolicy(qw.QSizePolicy.Minimum, qw.QSizePolicy.Minimum))
self.lvalue = MyValueEdit(
low_is_none=low_is_none,
high_is_none=high_is_none,
low_is_zero=low_is_zero)
self.lvalue.setFixedWidth(100)
self.slider = QSliderNoWheel(qc.Qt.Horizontal)
self.slider.setSizePolicy(
qw.QSizePolicy(qw.QSizePolicy.Expanding, qw.QSizePolicy.Minimum))
self.slider.setMaximum(10000)
self.slider.setSingleStep(100)
self.slider.setPageStep(1000)
self.slider.setTickPosition(qw.QSlider.NoTicks)
self.slider.setFocusPolicy(qc.Qt.ClickFocus)
self.low_is_none = low_is_none
self.high_is_none = high_is_none
self.low_is_zero = low_is_zero
self.slider.valueChanged.connect(
self.slided)
self.lvalue.edited.connect(
self.edited)
self.type = type
self.mute = False
def widgets(self):
return self.lname, self.lvalue, self.slider
def s2v(self, svalue):
if self.ma == 0 or self.mi == 0:
return 0
a = math.log(self.ma/self.mi) / 10000.
value = self.mi*math.exp(a*svalue)
value = self.type(value)
return value
def v2s(self, value):
value = self.type(value)
if value == 0 or self.mi == 0:
return 0
a = math.log(self.ma/self.mi) / 10000.
return int(round(math.log(value/self.mi) / a))
def setup(self, name, mi, ma, cur, ind):
self.lname.setText(name)
self.mi = mi
self.ma = ma
self.ind = ind
self.lvalue.setRange(self.s2v(0), self.s2v(10000))
self.set_value(cur)
def set_range(self, mi, ma):
if self.mi == mi and self.ma == ma:
return
vput = None
if self.cursl == 0:
vput = mi
if self.cursl == 10000:
vput = ma
self.mi = mi
self.ma = ma
self.lvalue.setRange(self.s2v(0), self.s2v(10000))
if vput is not None:
self.set_value(vput)
else:
if self.cur < mi:
self.set_value(mi)
if self.cur > ma:
self.set_value(ma)
def set_value(self, cur):
if cur is None:
if self.low_is_none:
cur = self.mi
elif self.high_is_none:
cur = self.ma
if cur == 0.0:
if self.low_is_zero:
cur = self.mi
self.mute = True
self.cur = cur
self.cursl = self.v2s(cur)
self.slider.blockSignals(True)
self.slider.setValue(self.cursl)
self.slider.blockSignals(False)
self.lvalue.blockSignals(True)
if self.cursl in (0, 10000):
self.lvalue.setValue(self.s2v(self.cursl))
else:
self.lvalue.setValue(self.cur)
self.lvalue.blockSignals(False)
self.mute = False
def set_tracking(self, tracking):
self.slider.setTracking(tracking)
def get_value(self):
return self.cur
def slided(self, val):
if self.cursl != val:
self.cursl = val
cur = self.s2v(self.cursl)
if cur != self.cur:
self.cur = cur
self.lvalue.blockSignals(True)
self.lvalue.setValue(self.cur)
self.lvalue.blockSignals(False)
self.fire_valchange()
def edited(self, val):
if self.cur != val:
self.cur = val
cursl = self.v2s(val)
if (cursl != self.cursl):
self.slider.blockSignals(True)
self.slider.setValue(cursl)
self.slider.blockSignals(False)
self.cursl = cursl
self.fire_valchange()
def fire_valchange(self):
if self.mute:
return
cur = self.cur
if self.cursl == 0:
if self.low_is_none:
cur = None
elif self.low_is_zero:
cur = 0.0
if self.cursl == 10000 and self.high_is_none:
cur = None
self.valchange.emit(cur, int(self.ind))
class LinValControl(ValControl):
def s2v(self, svalue):
value = svalue/10000. * (self.ma-self.mi) + self.mi
value = self.type(value)
return value
def v2s(self, value):
value = self.type(value)
if self.ma == self.mi:
return 0
return int(round((value-self.mi)/(self.ma-self.mi) * 10000.))
class ColorbarControl(qw.QWidget):
AVAILABLE_CMAPS = (
'viridis',
'plasma',
'magma',
'binary',
'Reds',
'copper',
'seismic',
'RdBu',
'YlGn',
)
DEFAULT_CMAP = 'viridis'
cmap_changed = qc.pyqtSignal(str)
show_absolute_toggled = qc.pyqtSignal(bool)
show_integrate_toggled = qc.pyqtSignal(bool)
def __init__(self, *args, **kwargs):
super().__init__(*args, **kwargs)
self.lname = qw.QLabel('Colormap')
self.lname.setSizePolicy(
qw.QSizePolicy(qw.QSizePolicy.Minimum, qw.QSizePolicy.Minimum))
self.cmap_options = qw.QComboBox()
self.cmap_options.setIconSize(qc.QSize(64, 12))
for ic, cmap in enumerate(self.AVAILABLE_CMAPS):
pixmap = qg.QPixmap.fromImage(
get_colormap_qimage(cmap))
icon = qg.QIcon(pixmap.scaled(64, 12))
self.cmap_options.addItem(icon, '', cmap)
self.cmap_options.setItemData(ic, cmap, qc.Qt.ToolTipRole)
# self.cmap_options.setCurrentIndex(self.cmap_name)
self.cmap_options.currentIndexChanged.connect(self.set_cmap)
self.cmap_options.setSizePolicy(
qw.QSizePolicy(qw.QSizePolicy.Minimum, qw.QSizePolicy.Minimum))
self.colorslider = ColorbarSlider(self)
self.colorslider.setSizePolicy(
qw.QSizePolicy.MinimumExpanding | qw.QSizePolicy.ExpandFlag,
qw.QSizePolicy.MinimumExpanding | qw.QSizePolicy.ExpandFlag
)
self.clip_changed = self.colorslider.clip_changed
btn_size = qw.QSizePolicy(
qw.QSizePolicy.Maximum | qw.QSizePolicy.ShrinkFlag,
qw.QSizePolicy.Maximum | qw.QSizePolicy.ShrinkFlag)
self.symetry_toggle = qw.QPushButton()
self.symetry_toggle.setIcon(
qg.QIcon.fromTheme('object-flip-horizontal'))
self.symetry_toggle.setToolTip('Symetric clip values')
self.symetry_toggle.setSizePolicy(btn_size)
self.symetry_toggle.setCheckable(True)
self.symetry_toggle.toggled.connect(self.toggle_symetry)
self.symetry_toggle.setChecked(True)
self.reverse_toggle = qw.QPushButton()
self.reverse_toggle.setIcon(
qg.QIcon.fromTheme('object-rotate-right'))
self.reverse_toggle.setToolTip('Reverse the colormap')
self.reverse_toggle.setSizePolicy(btn_size)
self.reverse_toggle.setCheckable(True)
self.reverse_toggle.toggled.connect(self.toggle_reverse_cmap)
self.abs_toggle = qw.QPushButton()
self.abs_toggle.setIcon(
qg.QIcon.fromTheme('go-bottom'))
self.abs_toggle.setToolTip('Show absolute values')
self.abs_toggle.setSizePolicy(btn_size)
self.abs_toggle.setCheckable(True)
self.abs_toggle.toggled.connect(self.toggle_absolute)
self.int_toggle = qw.QPushButton()
self.int_toggle.setText('∫')
self.int_toggle.setToolTip(
u'Integrate traces (e.g. strain rate → strain)')
self.int_toggle.setSizePolicy(btn_size)
self.int_toggle.setCheckable(True)
self.int_toggle.setMaximumSize(
24,
self.int_toggle.maximumSize().height())
self.int_toggle.toggled.connect(self.show_integrate_toggled.emit)
v_splitter = qw.QFrame()
v_splitter.setFrameShape(qw.QFrame.VLine)
v_splitter.setFrameShadow(qw.QFrame.Sunken)
self.controls = qw.QWidget()
layout = qw.QHBoxLayout()
layout.addWidget(self.colorslider)
layout.addWidget(self.symetry_toggle)
layout.addWidget(self.reverse_toggle)
layout.addWidget(v_splitter)
layout.addWidget(self.abs_toggle)
layout.addWidget(self.int_toggle)
self.controls.setLayout(layout)
self.set_cmap_name(self.DEFAULT_CMAP)
def set_cmap(self, idx):
self.set_cmap_name(self.cmap_options.itemData(idx))
def set_cmap_name(self, cmap_name):
self.cmap_name = cmap_name
self.colorslider.set_cmap_name(cmap_name)
self.cmap_changed.emit(cmap_name)
def get_cmap(self):
return self.cmap_name
def toggle_symetry(self, toggled):
self.colorslider.set_symetry(toggled)
def toggle_reverse_cmap(self):
cmap = self.get_cmap()
if cmap.endswith('_r'):
r_cmap = cmap.rstrip('_r')
else:
r_cmap = cmap + '_r'
self.set_cmap_name(r_cmap)
def toggle_absolute(self, toggled):
self.symetry_toggle.setChecked(not toggled)
self.show_absolute_toggled.emit(toggled)
def widgets(self):
return (self.lname, self.cmap_options, self.controls)
class ColorbarSlider(qw.QWidget):
DEFAULT_CMAP = 'viridis'
CORNER_THRESHOLD = 10
MIN_WIDTH = .05
clip_changed = qc.pyqtSignal(float, float)
class COMPONENTS(enum.Enum):
LeftLine = 1
RightLine = 2
Center = 3
def __init__(self, *args, cmap_name=None):
super().__init__()
self.cmap_name = cmap_name or self.DEFAULT_CMAP
self.clip_min = 0.
self.clip_max = 1.
self._sym_locked = True
self._mouse_inside = False
self._window = None
self._old_pos = None
self._component_grabbed = None
self.setMouseTracking(True)
def set_cmap_name(self, cmap_name):
self.cmap_name = cmap_name
self.repaint()
def get_cmap_name(self):
return self.cmap_name
def set_symetry(self, symetry):
self._sym_locked = symetry
if self._sym_locked:
clip_max = 1. - min(self.clip_min, 1.-self.clip_max)
clip_min = 1. - clip_max
self.set_clip(clip_min, clip_max)
def _set_window(self, window):
self._window = window
def _get_left_line(self):
rect = self._get_active_rect()
if not rect:
return
return qc.QLineF(rect.left(), 0, rect.left(), rect.height())
def _get_right_line(self):
rect = self._get_active_rect()
if not rect:
return
return qc.QLineF(rect.right(), 0, rect.right(), rect.height())
def _get_active_rect(self):
if not self._window:
return
rect = qc.QRect(self._window)
width = rect.width()
rect.setLeft(int(width * self.clip_min))
rect.setRight(int(width * self.clip_max))
return rect
def set_clip(self, clip_min, clip_max):
if clip_min < 0. or clip_max > 1.:
return
if clip_max - clip_min < self.MIN_WIDTH:
return
self.clip_min = clip_min
self.clip_max = clip_max
self.repaint()
self.clip_changed.emit(self.clip_min, self.clip_max)
def mousePressEvent(self, event):
''
act_rect = self._get_active_rect()
if event.buttons() != qc.Qt.MouseButton.LeftButton:
self._component_grabbed = None
return
dist_left = abs(event.pos().x() - act_rect.left())
dist_right = abs(event.pos().x() - act_rect.right())
if 0 < dist_left < self.CORNER_THRESHOLD:
self._component_grabbed = self.COMPONENTS.LeftLine
self.setCursor(qg.QCursor(qc.Qt.CursorShape.SizeHorCursor))
elif 0 < dist_right < self.CORNER_THRESHOLD:
self._component_grabbed = self.COMPONENTS.RightLine
self.setCursor(qg.QCursor(qc.Qt.CursorShape.SizeHorCursor))
else:
self.setCursor(qg.QCursor())
def mouseReleaseEvent(self, event):
''
self._component_grabbed = None
self.repaint()
def mouseDoubleClickEvent(self, event):
''
self.set_clip(0., 1.)
def wheelEvent(self, event):
''
event.accept()
if not self._sym_locked:
return
delta = event.angleDelta().y()
delta = -delta / 5e3
clip_min_new = max(self.clip_min + delta, 0.)
clip_max_new = min(self.clip_max - delta, 1.)
self._mouse_inside = True
self.set_clip(clip_min_new, clip_max_new)
def mouseMoveEvent(self, event):
''
act_rect = self._get_active_rect()
if not self._component_grabbed:
dist_left = abs(event.pos().x() - act_rect.left())
dist_right = abs(event.pos().x() - act_rect.right())
if 0 <= dist_left < self.CORNER_THRESHOLD or \
0 <= dist_right < self.CORNER_THRESHOLD:
self.setCursor(qg.QCursor(qc.Qt.CursorShape.SizeHorCursor))
else:
self.setCursor(qg.QCursor())
if self._old_pos and self._component_grabbed:
shift = (event.pos() - self._old_pos).x() / self._window.width()
if self._component_grabbed is self.COMPONENTS.LeftLine:
clip_min_new = max(self.clip_min + shift, 0.)
clip_max_new = \
min(self.clip_max - shift, 1.) \
if self._sym_locked else self.clip_max
elif self._component_grabbed is self.COMPONENTS.RightLine:
clip_max_new = min(self.clip_max + shift, 1.)
clip_min_new = \
max(self.clip_min - shift, 0.) \
if self._sym_locked else self.clip_min
self.set_clip(clip_min_new, clip_max_new)
self._old_pos = event.pos()
def enterEvent(self, e):
''
self._mouse_inside = True
self.repaint()
def leaveEvent(self, e):
''
self._mouse_inside = False
self.repaint()
def paintEvent(self, e):
''
p = qg.QPainter(self)
self._set_window(p.window())
p.drawImage(
p.window(),
get_colormap_qimage(self.cmap_name, self.clip_min, self.clip_max))
left_line = self._get_left_line()
right_line = self._get_right_line()
pen = qg.QPen()
pen.setWidth(2)
pen.setStyle(qc.Qt.DotLine)
pen.setBrush(qc.Qt.white)
p.setPen(pen)
p.setCompositionMode(
qg.QPainter.CompositionMode.CompositionMode_Difference)
p.drawLine(left_line)
p.drawLine(right_line)
label_rect = self._get_active_rect()
label_rect.setLeft(label_rect.left() + 5)
label_rect.setRight(label_rect.right() - 5)
label_left_rect = qc.QRectF(label_rect)
label_right_rect = qc.QRectF(label_rect)
label_left_align = qc.Qt.AlignLeft
label_right_align = qc.Qt.AlignRight
if label_rect.left() > 50:
label_left_rect.setRight(label_rect.left() - 10)
label_left_rect.setLeft(0)
label_left_align = qc.Qt.AlignRight
if self._window.right() - label_rect.right() > 50:
label_right_rect.setLeft(label_rect.right() + 10)
label_right_rect.setRight(self._window.right())
label_right_align = qc.Qt.AlignLeft
if self._mouse_inside or self._component_grabbed:
p.drawText(
label_left_rect,
label_left_align | qc.Qt.AlignVCenter,
'%d%%' % round(self.clip_min * 100))
p.drawText(
label_right_rect,
label_right_align | qc.Qt.AlignVCenter,
'%d%%' % round(self.clip_max * 100))
class Progressbar(object):
def __init__(self, parent, name, can_abort=True):
self.parent = parent
self.name = name
self.label = qw.QLabel(name, parent)
self.pbar = qw.QProgressBar(parent)
self.aborted = False
self.time_last_update = 0.
if can_abort:
self.abort_button = qw.QPushButton('Abort', parent)
self.abort_button.clicked.connect(
self.abort)
else:
self.abort_button = None
def widgets(self):
widgets = [self.label, self.bar()]
if self.abort_button:
widgets.append(self.abort_button)
return widgets
def bar(self):
return self.pbar
def abort(self):
self.aborted = True
class Progressbars(qw.QFrame):
def __init__(self, parent):
qw.QFrame.__init__(self, parent)
self.layout = qw.QGridLayout()
self.setLayout(self.layout)
self.bars = {}
self.start_times = {}
self.hide()
def set_status(self, name, value, can_abort=True, force=False):
value = int(round(value))
now = time.time()
if name not in self.start_times:
self.start_times[name] = now
if not force:
return False
else:
if now < self.start_times[name] + 1.0:
if value == 100:
del self.start_times[name]
if not force:
return False
self.start_times.get(name, 0.0)
if name not in self.bars:
if value == 100:
return False
self.bars[name] = Progressbar(self, name, can_abort=can_abort)
self.make_layout()
bar = self.bars[name]
if bar.time_last_update < now - 0.1 or value == 100:
bar.bar().setValue(value)
bar.time_last_update = now
if value == 100:
del self.bars[name]
if name in self.start_times:
del self.start_times[name]
self.make_layout()
for w in bar.widgets():
w.setParent(None)
return bar.aborted
def make_layout(self):
while True:
c = self.layout.takeAt(0)
if c is None:
break
for ibar, bar in enumerate(self.bars.values()):
for iw, w in enumerate(bar.widgets()):
self.layout.addWidget(w, ibar, iw)
if not self.bars:
self.hide()
else:
self.show()
def tohex(c):
return '%02x%02x%02x' % c
def to01(c):
return c[0]/255., c[1]/255., c[2]/255.
def beautify_axes(axes):
try:
from cycler import cycler
axes.set_prop_cycle(
cycler('color', [to01(x) for x in plot.graph_colors]))
except (ImportError, KeyError):
axes.set_color_cycle(list(map(to01, plot.graph_colors)))
xa = axes.get_xaxis()
ya = axes.get_yaxis()
for attr in ('labelpad', 'LABELPAD'):
if hasattr(xa, attr):
setattr(xa, attr, xa.get_label().get_fontsize())
setattr(ya, attr, ya.get_label().get_fontsize())
break
[docs]class SmartplotFrame(FigureFrame):
'''
A widget to present a :py:mod:`pyrocko.plot.smartplot` figure.
'''
def __init__(
self, parent=None, plot_args=[], plot_kwargs={}, plot_cls=None):
from pyrocko.plot import smartplot
FigureFrame.__init__(
self,
parent=parent,
figure_cls=smartplot.SmartplotFigure)
if plot_cls is None:
plot_cls = smartplot.Plot
self.plot = plot_cls(
*plot_args,
fig=self.figure,
call_mpl_init=False,
**plot_kwargs)
[docs]class WebKitFrame(qw.QFrame):
'''
A widget to present a html page using WebKit.
'''
def __init__(self, url=None, parent=None):
from pyrocko.deps import require
require('PyQt5.QtWebEngine')
from PyQt5.QtWebEngineWidgets import QWebEngineView as WebView
qw.QFrame.__init__(self, parent)
layout = qw.QGridLayout()
layout.setContentsMargins(0, 0, 0, 0)
layout.setSpacing(0)
self.setLayout(layout)
self.web_widget = WebView()
layout.addWidget(self.web_widget, 0, 0)
if url:
self.web_widget.load(qc.QUrl(url))
[docs]class VTKFrame(qw.QFrame):
'''
A widget to present a VTK visualization.
'''
def __init__(self, actors=None, parent=None):
import vtk
from vtk.qt.QVTKRenderWindowInteractor import \
QVTKRenderWindowInteractor
qw.QFrame.__init__(self, parent)
layout = qw.QGridLayout()
layout.setContentsMargins(0, 0, 0, 0)
layout.setSpacing(0)
self.setLayout(layout)
self.vtk_widget = QVTKRenderWindowInteractor(self)
layout.addWidget(self.vtk_widget, 0, 0)
self.renderer = vtk.vtkRenderer()
self.vtk_widget.GetRenderWindow().AddRenderer(self.renderer)
self.iren = self.vtk_widget.GetRenderWindow().GetInteractor()
if actors:
for a in actors:
self.renderer.AddActor(a)
def init(self):
self.iren.Initialize()
def add_actor(self, actor):
self.renderer.AddActor(actor)
[docs]class PixmapFrame(qw.QLabel):
'''
A widget to preset a pixmap image.
'''
def __init__(self, filename=None, parent=None):
qw.QLabel.__init__(self, parent)
self.setAlignment(qc.Qt.AlignCenter)
self.setContentsMargins(0, 0, 0, 0)
self.menu = qw.QMenu(self)
action = qw.QAction('Save as', self.menu)
action.triggered.connect(self.save_pixmap)
self.menu.addAction(action)
if filename:
self.load_pixmap(filename)
def contextMenuEvent(self, event):
self.menu.popup(qg.QCursor.pos())
def load_pixmap(self, filename):
self.pixmap = qg.QPixmap(filename)
self.setPixmap(self.pixmap)
def save_pixmap(self, filename=None):
if not filename:
filename, _ = qw.QFileDialog.getSaveFileName(
self.parent(), caption='save as')
self.pixmap.save(filename)
class Projection(object):
def __init__(self):
self.xr = 0., 1.
self.ur = 0., 1.
def set_in_range(self, xmin, xmax):
if xmax == xmin:
xmax = xmin + 1.
self.xr = xmin, xmax
def get_in_range(self):
return self.xr
def set_out_range(self, umin, umax):
if umax == umin:
umax = umin + 1.
self.ur = umin, umax
def get_out_range(self):
return self.ur
def __call__(self, x):
umin, umax = self.ur
xmin, xmax = self.xr
return umin + (x-xmin)*((umax-umin)/(xmax-xmin))
def clipped(self, x):
umin, umax = self.ur
xmin, xmax = self.xr
return min(
umax-1,
max(umin, umin + (x-xmin)*((umax-umin)/(xmax-xmin))))
def rev(self, u):
umin, umax = self.ur
xmin, xmax = self.xr
return xmin + (u-umin)*((xmax-xmin)/(umax-umin))
class NoData(Exception):
pass
g_working_system_time_range = util.get_working_system_time_range()
g_initial_time_range = []
try:
g_initial_time_range.append(
calendar.timegm((1950, 1, 1, 0, 0, 0)))
except Exception:
g_initial_time_range.append(g_working_system_time_range[0])
try:
g_initial_time_range.append(
calendar.timegm((time.gmtime().tm_year + 1, 1, 1, 0, 0, 0)))
except Exception:
g_initial_time_range.append(g_working_system_time_range[1])
def four_way_arrow(position, size):
r = 5.
w = 1.
points = [
(position[0]+size*float(a), position[1]+size*float(b))
for (a, b) in [
(0, r),
(1.5*w, r-2*w),
(0.5*w, r-2*w),
(0.5*w, 0.5*w),
(r-2*w, 0.5*w),
(r-2*w, 1.5*w),
(r, 0),
(r-2*w, -1.5*w),
(r-2*w, -0.5*w),
(0.5*w, -0.5*w),
(0.5*w, -(r-2*w)),
(1.5*w, -(r-2*w)),
(0, -r),
(-1.5*w, -(r-2*w)),
(-0.5*w, -(r-2*w)),
(-0.5*w, -0.5*w),
(-(r-2*w), -0.5*w),
(-(r-2*w), -1.5*w),
(-r, 0),
(-(r-2*w), 1.5*w),
(-(r-2*w), 0.5*w),
(-0.5*w, 0.5*w),
(-0.5*w, r-2*w),
(-1.5*w, r-2*w)]]
poly = qg.QPolygon(len(points))
for ipoint, point in enumerate(points):
poly.setPoint(ipoint, *(int(round(v)) for v in point))
return poly
def tmin_effective(tmin, tmax, tduration, tposition):
if None in (tmin, tmax, tduration, tposition):
return tmin
else:
return tmin + (tmax - tmin) * tposition
def tmax_effective(tmin, tmax, tduration, tposition):
if None in (tmin, tmax, tduration, tposition):
return tmax
else:
return tmin + (tmax - tmin) * tposition + tduration
def xywh(rect):
return rect.x(), rect.y(), rect.width(), rect.height()
def farr(*vals):
return num.array(vals, dtype=float)
def flank(a, b, n):
cos = num.cos(num.linspace(0, num.pi, n))
return a + (b-a) * 0.5 * (1.0 - num.sign(cos) * num.abs(cos)**0.25)
def yflank(a, b, n):
flank = num.zeros(n*2)
flank[:n] = a + 0.5 * (b-a) * num.sin(
num.linspace(0., num.pi/2., n))
flank[-n:] = b - 0.5 * (b-a) * num.sin(
num.linspace(num.pi/2., 0., n))
return flank
def xflank(a, b, r, n):
flank = num.zeros(n*2)
flank[:n] = a + num.sign(b-a) * min(r, 0.5*abs(b-a)) * (1 - num.cos(
num.linspace(0., num.pi/2., n)))
flank[-n:] = b - num.sign(b-a) * min(r, 0.5*abs(b-a)) * (1 - num.cos(
num.linspace(num.pi/2., 0., n)))
return flank
def make_rect_merge_poly(focus_rect, lower_rect):
lx, ly, lw, lh = xywh(lower_rect)
fx, fy, fw, fh = xywh(focus_rect)
n = 20
r = 0.5 * (ly - (fy+fh))
return make_QPolygonF(
num.concatenate([
farr(lx, lx, lx+lw-1, lx+lw-1),
xflank(lx+lw-1, fx+fw, r, n),
farr(fx+fw, fx+fw, fx, fx),
xflank(fx, lx, r, n)]),
num.concatenate([
farr(ly, ly+lh-1, ly+lh-1, ly),
yflank(ly, fy+fh, n),
farr(fy+fh, fy, fy, fy+fh),
yflank(fy+fh, ly, n)]))
class RangeEdit(qw.QFrame):
rangeChanged = qc.pyqtSignal()
focusChanged = qc.pyqtSignal()
tcursorChanged = qc.pyqtSignal()
rangeEditPressed = qc.pyqtSignal()
rangeEditReleased = qc.pyqtSignal()
def __init__(self, parent=None):
qw.QFrame.__init__(self, parent)
self.setFrameStyle(qw.QFrame.StyledPanel | qw.QFrame.Plain)
# self.setBackgroundRole(qg.QPalette.Button)
# self.setAutoFillBackground(True)
self.setMouseTracking(True)
poli = qw.QSizePolicy(
qw.QSizePolicy.Expanding,
qw.QSizePolicy.Expanding)
self.setSizePolicy(poli)
self.setMinimumSize(100, 3*24)
self._size_hint = qw.QPushButton().sizeHint()
self._track_start = None
self._track_range = None
self._track_focus = None
self._track_what = None
self._tcursor = None
self._hover_point = None
self.tmin, self.tmax = None, None
self.tduration, self.tposition = None, 0.
self._data_provider = None
self._coverage_provider = None
self._range_limit = g_working_system_time_range[:2]
def set_range_limit(self, tmin, tmax):
self._range_limit = tmin, tmax
def set_data_provider(self, provider):
self._data_provider = provider
def set_coverage_provider(self, provider):
self._coverage_provider = provider
def set_data_name(self, name):
self._data_name = name
def sizeHint(self):
''
return self._size_hint
def get_data_range(self):
if self._data_provider:
vals = []
for data in self._data_provider.iter_data(self._data_name):
vals.append(data.min())
vals.append(data.max())
if vals:
return min(vals), max(vals)
return None, None
def get_histogram(self, projection, h):
h = int(h)
umin_w, umax_w = projection.get_out_range()
tmin_w, tmax_w = projection.get_in_range()
nbins = int(umax_w - umin_w)
counts = num.zeros(nbins, dtype=int)
if self._data_provider:
for data in self._data_provider.iter_data(self._data_name):
ibins = ((data - tmin_w) * (nbins / (tmax_w - tmin_w))) \
.astype(int)
num.clip(ibins, 0, nbins-1, ibins)
counts += num.bincount(ibins, minlength=nbins)
histogram = counts * h // (num.max(counts[1:-1]) or 1)
bitmap = num.zeros((h, nbins), dtype=bool)
for i in range(h):
bitmap[h-1-i, :] = histogram > i
try:
bitmap = num.packbits(bitmap, axis=1, bitorder='little')
except TypeError:
# numpy < 1.17.0 has no bitorder and default behaviour is 'big'
bitmap = num.packbits(
num.flip(bitmap.reshape((h*nbins//8, 8)), axis=1),
axis=1)
return qg.QBitmap.fromData(
qc.QSize(nbins, h),
bitmap.tobytes(),
qg.QImage.Format_MonoLSB)
def draw_coverage(self, painter, projection, rect):
from pyrocko.gui.pile_viewer import box_styles_coverage
from pyrocko.squirrel import to_kind
if not self._coverage_provider:
return
tmin, tmax = projection.get_in_range()
coverages = self._coverage_provider.get_coverage(tmin, tmax)
if not coverages:
return
coverage = join_coverages(coverages)
tmin = coverage.tmin
tmax = coverage.tmax
ymin, ymax = projection.get_out_range()
palette = self.palette()
alpha_brush = palette.highlight()
color = alpha_brush.color()
frame_pen = qg.QPen(color)
color.setAlpha(60)
alpha_brush.setColor(color)
painter.setPen(frame_pen)
painter.setBrush(alpha_brush)
def drawbox(tmin, tmax, style):
dtmin = projection.clipped(tmin)
dtmax = projection.clipped(tmax)
dvmin = rect.top() + 5
dvmax = rect.bottom() - 6
bar_rect = qc.QRectF(dtmin, dvmin, float(dtmax-dtmin), dvmax-dvmin)
painter.setBrush(style.fill_brush)
painter.setPen(style.frame_pen)
painter.drawRect(bar_rect)
if coverage.changes is None:
drawbox(
coverage.tmin, coverage.tmax,
box_styles_coverage[to_kind(coverage.kind_id)][0])
else:
t = None
pcount = 0
for tb, count in coverage.changes:
if t is not None and tb > t:
if pcount > 0 and (tb-t) > 0:
drawbox(
t, tb,
box_styles_coverage[to_kind(coverage.kind_id)][
min(len(box_styles_coverage)-1,
pcount)])
t = tb
pcount = count
def draw_time_ticks(self, painter, projection, rect, where):
palette = self.palette()
xpen_alpha_color = palette.color(qg.QPalette.ButtonText)
xpen_alpha_color.setAlpha(100)
xpen_alpha = qg.QPen(xpen_alpha_color)
painter.setPen(qg.QPen(xpen_alpha))
tmin, tmax = projection.get_in_range()
tinc, tinc_unit = plot.nice_time_tick_inc((tmax - tmin) / 7.)
tick_times, _ = plot.time_tick_labels(tmin, tmax, tinc, tinc_unit)
for tick_time in tick_times:
x = int(round(projection(tick_time)))
if where in ('top', 'both'):
painter.drawLine(x, rect.top(), x, rect.top() + 2)
if where in ('bottom', 'both'):
painter.drawLine(x, rect.bottom(), x, rect.bottom() - 2)
def drawit(self, painter):
palette = self.palette()
upper_projection = self.upper_projection()
lower_projection = self.lower_projection()
upper_rect = self.upper_rect()
lower_rect = self.lower_rect()
focus_rect = self.focus_rect(upper_projection)
fill_brush = palette.brush(qg.QPalette.Button)
painter.fillRect(upper_rect, fill_brush)
xpen_alpha_color = palette.color(qg.QPalette.ButtonText)
xpen_alpha_color.setAlpha(100)
xpen_alpha = qg.QPen(xpen_alpha_color)
if focus_rect:
poly = make_rect_merge_poly(focus_rect, lower_rect)
painter.setBrush(palette.light())
painter.setPen(xpen_alpha)
painter.drawPolygon(poly)
else:
fill_brush = palette.light()
painter.fillRect(upper_rect, fill_brush)
# painter.setBrush(palette.text())
# poly = four_way_arrow((self.width() / 2.0, self.height() / 2.0), 2.)
# painter.drawPolygon(poly)
self.draw_time_ticks(
painter, upper_projection, upper_rect, 'top')
if focus_rect and self.tduration:
self.draw_time_ticks(
painter, lower_projection, lower_rect, 'bottom')
xpen = qg.QPen(palette.color(qg.QPalette.ButtonText))
painter.setPen(xpen)
painter.drawPixmap(
0, upper_rect.x(),
self.get_histogram(upper_projection, upper_rect.height()))
if focus_rect and self.tduration:
painter.drawPixmap(
0, lower_rect.y(),
self.get_histogram(lower_projection, lower_rect.height()))
self.draw_coverage(painter, upper_projection, upper_rect)
if focus_rect and self.tduration:
self.draw_coverage(painter, lower_projection, lower_rect)
# frame_pen = qg.QPen(palette.color(qg.QPalette.ButtonText))
# painter.setPen(frame_pen)
# painter.drawRect(upper_rect)
# if self.tduration:
# painter.drawRect(lower_rect)
if self._tcursor is not None:
painter.setPen(xpen_alpha)
x = int(round(upper_projection(self._tcursor)))
painter.drawLine(x, upper_rect.top(), x, upper_rect.bottom())
if focus_rect and self.tduration and lower_projection:
x2 = int(round(lower_projection(self._tcursor)))
if lower_rect.left() < x2 and x2 < lower_rect.right():
# painter.drawLine(
# x, upper_rect.bottom(), x2, lower_rect.top())
painter.drawLine(
x2, lower_rect.top(), x2, lower_rect.bottom())
if self._hover_point and lower_rect.contains(self._hover_point) \
and not self.tduration and not self._track_start:
alpha_brush = palette.highlight()
color = alpha_brush.color()
color.setAlpha(30)
alpha_brush.setColor(color)
painter.fillRect(lower_rect, alpha_brush)
def upper_projection(self):
p = Projection()
if None in (self.tmin, self.tmax):
p.set_in_range(*g_initial_time_range)
else:
p.set_in_range(self.tmin, self.tmax)
p.set_out_range(0., self.width())
return p
def lower_projection(self):
tmin_eff = self.tmin_effective()
tmax_eff = self.tmax_effective()
if None in (tmin_eff, tmax_eff):
return None
p = Projection()
p.set_in_range(tmin_eff, tmax_eff)
p.set_out_range(0., self.width())
return p
def tmin_effective(self):
return tmin_effective(
self.tmin, self.tmax, self.tduration, self.tposition)
def tmax_effective(self):
return tmax_effective(
self.tmin, self.tmax, self.tduration, self.tposition)
def upper_rect(self):
vmin = 0
vmax = self.height() // 3
umin, umax = 0, self.width()
return qc.QRect(umin, vmin, umax-umin, vmax-vmin)
def lower_rect(self):
vmin = 2 * self.height() // 3
vmax = self.height()
umin, umax = 0, self.width()
return qc.QRect(umin, vmin, umax-umin, vmax-vmin)
def focus_rect(self, projection):
vmin = 0
vmax = self.height() // 3
tmin_eff = self.tmin_effective()
tmax_eff = self.tmax_effective()
if None in (tmin_eff, tmax_eff):
return None
umin = rint(projection.clipped(tmin_eff))
umax = rint(projection.clipped(tmax_eff))
return qc.QRect(umin, vmin, max(1, umax-umin), vmax-vmin)
def set_range(self, tmin, tmax, preserve_span=False):
if None in (tmin, tmax):
tmin = None
tmax = None
elif tmin == tmax:
tmin -= 0.5
tmax += 0.5
tmin_lim, tmax_lim = self._range_limit
if tmin is not None and tmin < tmin_lim:
if preserve_span:
tmax = min(tmax + (tmin_lim-tmin), tmax_lim)
tmin = tmin_lim
if tmax is not None and tmax_lim < tmax:
if preserve_span:
tmin = max(tmin - (tmax - tmax_lim), tmin_lim)
tmax = tmax_lim
self.tmin = tmin
self.tmax = tmax
self.rangeChanged.emit()
self.update()
def get_range(self):
return self.tmin, self.tmax
def set_focus(self, tduration, tposition):
self.tduration = tduration
self.tposition = tposition
self.focusChanged.emit()
self.update()
def get_focus(self):
return (self.tduration, self.tposition)
def get_tcursor(self):
return self._tcursor
def update_data_range(self):
self.set_range(*self.get_data_range())
def paintEvent(self, paint_ev):
''
painter = qg.QPainter(self)
painter.setRenderHint(qg.QPainter.Antialiasing)
self.drawit(painter)
qw.QFrame.paintEvent(self, paint_ev)
def mousePressEvent(self, mouse_ev):
''
if mouse_ev.button() == qc.Qt.LeftButton:
self.rangeEditPressed.emit()
if None in (self.tmin, self.tmax):
self.set_range(*g_initial_time_range)
self._track_start = mouse_ev.x(), mouse_ev.y()
self._track_range = self.get_range()
self._track_focus = self.get_focus()
# upper_projection = self.upper_projection()
# focus_rect = self.focus_rect(upper_projection)
upper_rect = self.upper_rect()
lower_rect = self.lower_rect()
if upper_rect.contains(mouse_ev.pos()):
self._track_what = 'global'
elif lower_rect.contains(mouse_ev.pos()):
self._track_what = 'focus'
if self.tduration is None:
frac = 0.02
tduration = (self.tmax - self.tmin) * (1.0 - frac)
tposition = 0.5*frac
self.set_focus(tduration, tposition)
else:
if self.tduration is not None:
self._track_what = 'focus_slide'
else:
self._track_what = 'global_slide'
self.update()
def enterEvent(self, ev):
''
self._tcursor = None # is set later by mouseMoveEvent
self._hover_point = None
self.tcursorChanged.emit()
def leaveEvent(self, ev):
''
self._tcursor = None
self._hover_point = None
self.tcursorChanged.emit()
self.update()
def mouseReleaseEvent(self, mouse_ev):
''
if self._track_start:
self.rangeEditReleased.emit()
self.update()
self._track_start = None
self._track_range = None
self._track_focus = None
self._track_what = None
if self.tduration is not None:
if self.tduration >= self.tmax - self.tmin:
self.set_focus(None, 0.0)
elif self.tposition < 0.:
self.set_focus(self.tduration, 0.0)
elif self.tposition > 1.0 - self.tduration \
/ (self.tmax - self.tmin):
self.set_focus(
self.tduration, 1.0 - self.tduration
/ (self.tmax - self.tmin))
def mouseDoubleClickEvent(self, mouse_ev):
''
if mouse_ev.button() == qc.Qt.LeftButton:
lower_rect = self.lower_rect()
if lower_rect.contains(mouse_ev.pos()) \
and self.tduration is not None:
etmin = self.tmin_effective()
etmax = self.tmax_effective()
self.set_range(etmin, etmax)
self.set_focus(None, 0.0)
upper_rect = self.upper_rect()
if upper_rect.contains(mouse_ev.pos()) \
and self.tduration is not None:
self.set_focus(None, 0.0)
def mouseMoveEvent(self, mouse_ev):
''
point = self.mapFromGlobal(mouse_ev.globalPos())
self._hover_point = point
if self._track_start is not None:
x0, y0 = self._track_start
dx = (point.x() - x0)/float(self.width())
dy = (point.y() - y0)/float(self.height())
xfrac = x0/float(self.width())
tmin0, tmax0 = self._track_range
tduration0, tposition0 = self._track_focus
if self._track_what in ('global', 'global_slide'):
if self._track_what == 'global':
scale = math.exp(-dy)
else:
scale = 1.0
dtr = (tmax0-tmin0) * (scale - 1.0)
dt = dx*(tmax0-tmin0)*scale
tmin = tmin0 - dt - dtr*xfrac
tmax = tmax0 - dt + dtr*(1.-xfrac)
self.set_range(tmin, tmax, preserve_span=True)
tduration, tposition = self._track_focus
if tduration is not None:
etmin0 = tmin_effective(
tmin0, tmax0, tduration0, tposition0)
tposition = (etmin0 - tmin) / (tmax - tmin)
self.set_focus(tduration0, tposition)
elif self._track_what == 'focus':
if tduration0 is not None:
scale = math.exp(-dy)
dtr = tduration0 * (scale - 1.0)
dt = dx * tduration0 * scale
etmin0 = tmin_effective(
tmin0, tmax0, tduration0, tposition0)
etmax0 = tmax_effective(
tmin0, tmax0, tduration0, tposition0)
tmin = etmin0 - dt - dtr*xfrac
tmax = etmax0 - dt + dtr*(1.-xfrac)
tduration = tmax - tmin
tposition = (tmin - tmin0) / (tmax0 - tmin0)
tposition = min(
max(0., tposition),
1.0 - tduration / (tmax0 - tmin0))
if tduration < (tmax0 - tmin0):
self.set_focus(tduration, tposition)
else:
self.set_focus(None, tposition)
else:
tduration, tposition = tmax0 - tmin0, 0.0
self.set_focus(tduration, tposition)
self._track_focus = (tduration, tposition)
elif self._track_what == 'focus_slide':
if tduration0 is not None:
self.set_focus(
tduration0,
min(
max(0., tposition0 + dx),
1.0 - tduration0 / (tmax0 - tmin0)))
else:
upper_rect = self.upper_rect()
lower_rect = self.lower_rect()
upper_projection = self.upper_projection()
lower_projection = self.lower_projection()
app = get_app()
have_focus = lower_projection and self.tduration is not None
if upper_rect.contains(point):
self.setCursor(qg.QCursor(qc.Qt.CursorShape.CrossCursor))
self._tcursor = upper_projection.rev(point.x())
app.status(
'Click and drag to change global time interval. '
'Move up/down to zoom.' + (
' Double-click to clear focus time interval.'
if have_focus else ''))
elif lower_rect.contains(point):
self.setCursor(qg.QCursor(qc.Qt.CursorShape.CrossCursor))
if have_focus:
self._tcursor = lower_projection.rev(point.x())
app.status(
'Click and drag to change local time interval. '
'Double-click to set global time interval from focus.')
else:
app.status(
'Click to activate focus time window.')
else:
self.setCursor(qg.QCursor(qc.Qt.CursorShape.SizeHorCursor))
self._tcursor = None
if have_focus:
app.status('Move focus time interval with fixed length.')
else:
app.status('Move global time interval with fixed length.')
self.update()
self.tcursorChanged.emit()
class StatusMessages(qw.QLabel):
def __init__(self):
qw.QLabel.__init__(self)
self._messages = {}
self._timers = {}
def set(self, key, text, timeout=5.0):
self._messages[key] = text
timer = qc.QTimer()
timer.setSingleShot(True)
timer.setInterval(int(timeout*1000))
def clear():
self.clear(key)
timer.timeout.connect(clear)
timer.start()
if key in self._timers:
self._timers[key].stop()
self._timers[key] = timer
self.update_label()
def clear(self, key):
try:
del self._messages[key]
except KeyError:
pass
try:
del self._timers[key]
except KeyError:
pass
self.update_label()
def update_label(self):
messages = []
for key, text in self._messages.items():
messages.append(text)
if messages:
message = '\u29BF ' + ' - '.join(messages)
else:
message = ''
self.setText(message)
def errorize(widget):
widget.setStyleSheet('''
QLineEdit {
background: rgb(200, 150, 150);
}''')
def de_errorize(widget):
if isinstance(widget, qw.QWidget):
widget.setStyleSheet('')
_call_later_timers = {}
def _remove_call_later(ref):
del _call_later_timers[ref]
def call_later(method, delay=0):
ref = weakref.WeakMethod(method, _remove_call_later)
previous_timer = _call_later_timers.pop(ref, None)
if previous_timer is not None:
previous_timer.stop()
def call():
_remove_call_later(ref)
method = ref()
if method is not None:
method()
timer = qc.QTimer()
timer.setSingleShot(True)
timer.setInterval(delay)
timer.timeout.connect(call)
timer.start()
_call_later_timers[ref] = timer
def time_or_none_to_str(t):
if t is None:
return ''
else:
return util.time_to_str(t)
def time_to_lineedit(state, attribute, widget):
widget.setText(time_or_none_to_str(getattr(state, attribute)))
def lineedit_to_time(widget, state, attribute):
s = str(widget.text())
if not s.strip():
setattr(state, attribute, None)
else:
try:
setattr(state, attribute, util.str_to_time_fillup(s))
except Exception:
raise ValueError(
'Use time format: YYYY-MM-DD HH:MM:SS.FFF')