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scanwidget: add from current git

This commit is contained in:
Robert Jördens 2016-02-25 20:34:04 +01:00
parent 51e831cec5
commit 3ed8288601
3 changed files with 752 additions and 0 deletions

545
artiq/gui/scanwidget.py Normal file
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from PyQt5 import QtGui, QtCore, QtWidgets
from .ticker import Ticker
class ScanAxis(QtWidgets.QWidget):
sigZoom = QtCore.pyqtSignal(float, int)
def __init__(self, zoomFactor):
QtWidgets.QWidget.__init__(self)
self.proxy = None
self.sizePolicy().setControlType(QtWidgets.QSizePolicy.ButtonBox)
self.ticker = Ticker()
self.zoomFactor = zoomFactor
def paintEvent(self, ev):
painter = QtGui.QPainter(self)
font = painter.font()
avgCharWidth = QtGui.QFontMetrics(font).averageCharWidth()
painter.setRenderHint(QtGui.QPainter.Antialiasing)
# The center of the slider handles should reflect what's displayed
# on the spinboxes.
painter.translate(self.proxy.slider.handleWidth()/2, self.height() - 5)
painter.drawLine(0, 0, self.width(), 0)
realMin = self.proxy.pixelToReal(0)
realMax = self.proxy.pixelToReal(self.width())
ticks, prefix, labels = self.ticker(realMin, realMax)
for t, l in zip(ticks, labels):
t = self.proxy.realToPixel(t)
textCenter = (len(l)/2.0)*avgCharWidth
painter.drawLine(t, 5, t, -5)
painter.drawText(t - textCenter, -10, l)
painter.resetTransform()
painter.drawText(0, 10, prefix)
# TODO:
# QtWidgets.QWidget.paintEvent(self, ev)?
# ev.accept() ?
def wheelEvent(self, ev):
y = ev.angleDelta().y()
if y:
z = self.zoomFactor**(y / 120.)
# Remove the slider-handle shift correction, b/c none of the other
# widgets know about it. If we have the mouse directly over a tick
# during a zoom, it should appear as if we are doing zoom relative
# to the ticks which live in axis pixel-space, not slider
# pixel-space.
self.sigZoom.emit(z, ev.x() - self.proxy.slider.handleWidth()/2)
self.update()
ev.accept()
# Basic ideas from https://gist.github.com/Riateche/27e36977f7d5ea72cf4f
class ScanSlider(QtWidgets.QSlider):
sigMinMoved = QtCore.pyqtSignal(int)
sigMaxMoved = QtCore.pyqtSignal(int)
noSlider, minSlider, maxSlider = range(3)
maxStyle = "QSlider::handle {background:red}"
minStyle = "QSlider::handle {background:blue}"
def __init__(self):
QtWidgets.QSlider.__init__(self, QtCore.Qt.Horizontal)
self.minPos = 0 # Pos and Val can differ in event handling.
# perhaps prevPos and currPos is more accurate.
self.maxPos = 99
self.minVal = 0 # lower
self.maxVal = 99 # upper
self.offset = 0
self.position = 0
self.lastPressed = ScanSlider.noSlider
self.selectedHandle = ScanSlider.minSlider
self.upperPressed = QtWidgets.QStyle.SC_None
self.lowerPressed = QtWidgets.QStyle.SC_None
self.firstMovement = False # State var for handling slider overlap.
self.blockTracking = False
# We need fake sliders to keep around so that we can dynamically
# set the stylesheets for drawing each slider later. See paintEvent.
self.dummyMinSlider = QtWidgets.QSlider()
self.dummyMaxSlider = QtWidgets.QSlider()
self.dummyMinSlider.setStyleSheet(ScanSlider.minStyle)
self.dummyMaxSlider.setStyleSheet(ScanSlider.maxStyle)
# We basically superimpose two QSliders on top of each other, discarding
# the state that remains constant between the two when drawing.
# Everything except the handles remain constant.
def initHandleStyleOption(self, opt, handle):
self.initStyleOption(opt)
if handle == ScanSlider.minSlider:
opt.sliderPosition = self.minPos
opt.sliderValue = self.minVal
elif handle == ScanSlider.maxSlider:
opt.sliderPosition = self.maxPos
opt.sliderValue = self.maxVal
else:
pass # AssertionErrors
# We get the range of each slider separately.
def pixelPosToRangeValue(self, pos):
opt = QtWidgets.QStyleOptionSlider()
self.initStyleOption(opt)
gr = self.style().subControlRect(QtWidgets.QStyle.CC_Slider, opt,
QtWidgets.QStyle.SC_SliderGroove,
self)
sr = self.style().subControlRect(QtWidgets.QStyle.CC_Slider, opt,
QtWidgets.QStyle.SC_SliderHandle,
self)
sliderLength = sr.width()
sliderMin = gr.x()
# For historical reasons right() returns left()+width() - 1
# x() is equivalent to left().
sliderMax = gr.right() - sliderLength + 1
return QtWidgets.QStyle.sliderValueFromPosition(
self.minimum(), self.maximum(), pos - sliderMin,
sliderMax - sliderMin, opt.upsideDown)
def rangeValueToPixelPos(self, val):
opt = QtWidgets.QStyleOptionSlider()
self.initStyleOption(opt)
gr = self.style().subControlRect(QtWidgets.QStyle.CC_Slider, opt,
QtWidgets.QStyle.SC_SliderGroove,
self)
sr = self.style().subControlRect(QtWidgets.QStyle.CC_Slider, opt,
QtWidgets.QStyle.SC_SliderHandle,
self)
sliderLength = sr.width()
sliderMin = gr.x()
sliderMax = gr.right() - sliderLength + 1
pixel = QtWidgets.QStyle.sliderPositionFromValue(
self.minimum(), self.maximum(), val, sliderMax - sliderMin,
opt.upsideDown)
return pixel
# When calculating conversions to/from pixel space, not all of the slider's
# width is actually usable, because the slider handle has a nonzero width.
# We use this function as a helper when the axis needs slider information.
def handleWidth(self):
opt = QtWidgets.QStyleOptionSlider()
self.initStyleOption(opt)
sr = self.style().subControlRect(QtWidgets.QStyle.CC_Slider, opt,
QtWidgets.QStyle.SC_SliderHandle,
self)
return sr.width()
def effectiveWidth(self):
opt = QtWidgets.QStyleOptionSlider()
self.initStyleOption(opt)
gr = self.style().subControlRect(QtWidgets.QStyle.CC_Slider, opt,
QtWidgets.QStyle.SC_SliderGroove,
self)
sliderLength = self.handleWidth()
sliderMin = gr.x()
sliderMax = gr.right() - sliderLength + 1
return sliderMax - sliderMin
# If groove and axis are not aligned (and they should be), we can use
# this function to calculate the offset between them.
def grooveX(self):
opt = QtWidgets.QStyleOptionSlider()
self.initStyleOption(opt)
gr = self.style().subControlRect(QtWidgets.QStyle.CC_Slider, opt,
QtWidgets.QStyle.SC_SliderGroove,
self)
return gr.x()
def handleMousePress(self, pos, control, val, handle):
opt = QtWidgets.QStyleOptionSlider()
self.initHandleStyleOption(opt, handle)
oldControl = control
control = self.style().hitTestComplexControl(
QtWidgets.QStyle.CC_Slider, opt, pos, self)
sr = self.style().subControlRect(QtWidgets.QStyle.CC_Slider, opt,
QtWidgets.QStyle.SC_SliderHandle,
self)
if control == QtWidgets.QStyle.SC_SliderHandle:
# no pick()- slider orientation static
self.offset = pos.x() - sr.topLeft().x()
self.lastPressed = handle
self.setSliderDown(True)
self.selectedHandle = handle
# emit
# Needed?
if control != oldControl:
self.update(sr)
return control
def drawHandle(self, painter, handle):
opt = QtWidgets.QStyleOptionSlider()
self.initStyleOption(opt)
self.initHandleStyleOption(opt, handle)
opt.subControls = QtWidgets.QStyle.SC_SliderHandle
painter.drawComplexControl(QtWidgets.QStyle.CC_Slider, opt)
# def triggerAction(self, action, slider):
# if action == QtWidgets.QAbstractSlider.SliderSingleStepAdd:
# if
def setLowerValue(self, val):
self.setSpan(val, self.maxVal)
def setUpperValue(self, val):
self.setSpan(self.minVal, val)
def setSpan(self, lower, upper):
def bound(min, curr, max):
if curr < min:
return min
elif curr > max:
return max
else:
return curr
low = bound(self.minimum(), lower, self.maximum())
high = bound(self.minimum(), upper, self.maximum())
if low != self.minVal or high != self.maxVal:
if low != self.minVal:
self.minVal = low
self.minPos = low
# emit
if high != self.maxVal:
self.maxVal = high
self.maxPos = high
# emit
# emit spanChanged
self.update()
def setLowerPosition(self, val):
if val != self.minPos:
self.minPos = val
if not self.hasTracking():
self.update()
if self.isSliderDown():
self.sigMinMoved.emit(self.minPos)
if self.hasTracking() and not self.blockTracking:
self.setLowerValue(val)
def setUpperPosition(self, val):
if val != self.maxPos:
self.maxPos = val
if not self.hasTracking():
self.update()
if self.isSliderDown():
self.sigMaxMoved.emit(self.maxPos)
if self.hasTracking() and not self.blockTracking:
self.setUpperValue(val)
def mousePressEvent(self, ev):
if self.minimum() == self.maximum() or (ev.buttons() ^ ev.button()):
ev.ignore()
return
# Prefer maxVal in the default case.
self.upperPressed = self.handleMousePress(
ev.pos(), self.upperPressed, self.maxVal, ScanSlider.maxSlider)
if self.upperPressed != QtWidgets.QStyle.SC_SliderHandle:
self.lowerPressed = self.handleMousePress(
ev.pos(), self.upperPressed, self.minVal, ScanSlider.minSlider)
# State that is needed to handle the case where two sliders are equal.
self.firstMovement = True
ev.accept()
def mouseMoveEvent(self, ev):
if (self.lowerPressed != QtWidgets.QStyle.SC_SliderHandle and
self.upperPressed != QtWidgets.QStyle.SC_SliderHandle):
ev.ignore()
return
opt = QtWidgets.QStyleOptionSlider()
self.initStyleOption(opt)
# This code seems to be needed so that returning the slider to the
# previous position is honored if a drag distance is exceeded.
m = self.style().pixelMetric(QtWidgets.QStyle.PM_MaximumDragDistance,
opt, self)
newPos = self.pixelPosToRangeValue(ev.pos().x() - self.offset)
if m >= 0:
r = self.rect().adjusted(-m, -m, m, m)
if not r.contains(ev.pos()):
newPos = self.position
if self.firstMovement:
if self.minPos == self.maxPos:
# MaxSlider is preferred, except in the case where min == max
# possible value the slider can take.
if self.minPos == self.maximum():
self.lowerPressed = QtWidgets.QStyle.SC_SliderHandle
self.upperPressed = QtWidgets.QStyle.SC_None
self.firstMovement = False
if self.lowerPressed == QtWidgets.QStyle.SC_SliderHandle:
newPos = min(newPos, self.maxVal)
self.setLowerPosition(newPos)
if self.upperPressed == QtWidgets.QStyle.SC_SliderHandle:
newPos = max(newPos, self.minVal)
self.setUpperPosition(newPos)
ev.accept()
def mouseReleaseEvent(self, ev):
QtWidgets.QSlider.mouseReleaseEvent(self, ev)
self.setSliderDown(False) # AbstractSlider needs this
self.lowerPressed = QtWidgets.QStyle.SC_None
self.upperPressed = QtWidgets.QStyle.SC_None
def paintEvent(self, ev):
# Use QStylePainters to make redrawing as painless as possible.
painter = QtWidgets.QStylePainter(self)
# Paint on the custom widget, using the attributes of the fake
# slider references we keep around. setStyleSheet within paintEvent
# leads to heavy performance penalties (and recursion?).
# QPalettes would be nicer to use, since palette entries can be set
# individually for each slider handle, but Windows 7 does not
# use them. This seems to be the only way to override the colors
# regardless of platform.
minPainter = QtWidgets.QStylePainter(self, self.dummyMinSlider)
maxPainter = QtWidgets.QStylePainter(self, self.dummyMaxSlider)
# Groove
opt = QtWidgets.QStyleOptionSlider()
self.initStyleOption(opt)
opt.sliderValue = 0
opt.sliderPosition = 0
opt.subControls = QtWidgets.QStyle.SC_SliderGroove
painter.drawComplexControl(QtWidgets.QStyle.CC_Slider, opt)
# Handles
self.drawHandle(minPainter, ScanSlider.minSlider)
self.drawHandle(maxPainter, ScanSlider.maxSlider)
# real (Sliders) => pixel (one pixel movement of sliders would increment by X)
# => range (minimum granularity that sliders understand).
class ScanProxy(QtCore.QObject):
sigMinMoved = QtCore.pyqtSignal(float)
sigMaxMoved = QtCore.pyqtSignal(float)
def __init__(self, slider, axis, rangeFactor):
QtCore.QObject.__init__(self)
self.axis = axis
self.slider = slider
self.realMin = 0
self.realMax = 0
self.numPoints = 10
self.rangeFactor = rangeFactor
# Transform that maps the spinboxes to a pixel position on the
# axis. 0 to axis.width() exclusive indicate positions which will be
# displayed on the axis.
# Because the axis's width will change when placed within a layout,
# the realToPixelTransform will initially be invalid. It will be set
# properly during the first resizeEvent, with the below transform.
self.realToPixelTransform = self.calculateNewRealToPixel(
-self.axis.width()/2, 1.0)
self.invalidOldSizeExpected = True
self.axis.installEventFilter(self)
# What real value should map to the axis/slider left? This doesn't depend
# on any public members so we can make decisions about centering during
# resize and zoom events.
def calculateNewRealToPixel(self, targetLeft, targetScale):
return QtGui.QTransform.fromScale(targetScale, 1).translate(
-targetLeft, 0)
# pixel vals for sliders: 0 to slider_width - 1
def realToPixel(self, val):
return (QtCore.QPointF(val, 0) * self.realToPixelTransform).x()
# Get a point from pixel units to what the sliders display.
def pixelToReal(self, val):
(revXform, invertible) = self.realToPixelTransform.inverted()
if not invertible:
revXform = (QtGui.QTransform.fromTranslate(
-self.realToPixelTransform.dx(), 0) *
QtGui.QTransform.fromScale(
1/self.realToPixelTransform.m11(), 0))
realPoint = QtCore.QPointF(val, 0) * revXform
return realPoint.x()
def rangeToReal(self, val):
# gx = self.slider.grooveX()
# ax = self.axis.x()
# assert gx == ax, "gx: {}, ax: {}".format(gx, ax)
pixelVal = self.slider.rangeValueToPixelPos(val)
return self.pixelToReal(pixelVal)
def realToRange(self, val):
pixelVal = self.realToPixel(val)
return self.slider.pixelPosToRangeValue(pixelVal)
def moveMax(self, val):
sliderX = self.realToRange(val)
self.slider.setUpperPosition(sliderX)
self.realMax = val
def moveMin(self, val):
sliderX = self.realToRange(val)
self.slider.setLowerPosition(sliderX)
self.realMin = val
def handleMaxMoved(self, rangeVal):
self.sigMaxMoved.emit(self.rangeToReal(rangeVal))
def handleMinMoved(self, rangeVal):
self.sigMinMoved.emit(self.rangeToReal(rangeVal))
def handleZoom(self, zoomFactor, mouseXPos):
newScale = self.realToPixelTransform.m11() * zoomFactor
refReal = self.pixelToReal(mouseXPos)
newLeft = refReal - mouseXPos/newScale
self.realToPixelTransform = self.calculateNewRealToPixel(
newLeft, newScale)
self.moveMax(self.realMax)
self.moveMin(self.realMin)
def zoomToFit(self):
currRangeReal = abs(self.realMax - self.realMin)
assert self.rangeFactor > 2
proportion = self.rangeFactor/(self.rangeFactor - 2)
newScale = self.slider.effectiveWidth()/(proportion*currRangeReal)
newLeft = self.realMin - self.slider.effectiveWidth() \
/ (self.rangeFactor*newScale)
self.realToPixelTransform = self.calculateNewRealToPixel(
newLeft, newScale)
self.printTransform()
self.moveMax(self.realMax)
self.moveMin(self.realMin)
self.axis.update()
def fitToView(self):
lowRange = 1.0/self.rangeFactor
highRange = (self.rangeFactor - 1)/self.rangeFactor
newMin = self.pixelToReal(lowRange * self.slider.effectiveWidth())
newMax = self.pixelToReal(highRange * self.slider.effectiveWidth())
sliderRange = self.slider.maximum() - self.slider.minimum()
assert sliderRange > 0
self.moveMin(newMin)
self.moveMax(newMax)
# Signals won't fire unless slider was actually grabbed, so
# manually update so the spinboxes know that knew values were set.
# self.realMax/Min will be updated as a consequence of ValueChanged
# signal in spinboxes.
self.sigMaxMoved.emit(newMax)
self.sigMinMoved.emit(newMin)
def eventFilter(self, obj, ev):
if obj != self.axis:
return False
if ev.type() != QtCore.QEvent.Resize:
return False
oldLeft = self.pixelToReal(0)
if ev.oldSize().isValid():
refWidth = ev.oldSize().width() - self.slider.handleWidth()
refRight = self.pixelToReal(refWidth)
newWidth = ev.size().width() - self.slider.handleWidth()
assert refRight > oldLeft
newScale = newWidth/(refRight - oldLeft)
else:
# TODO: self.axis.width() is invalid during object
# construction. The width will change when placed in a
# layout WITHOUT a resizeEvent. Why?
oldLeft = -ev.size().width()/2
newScale = 1.0
self.invalidOldSizeExpected = False
self.realToPixelTransform = self.calculateNewRealToPixel(
oldLeft, newScale)
# assert self.pixelToReal(0) == oldLeft, \
# "{}, {}".format(self.pixelToReal(0), oldLeft)
# Slider will update independently, making sure that the old
# slider positions are preserved. Because of this, we can be
# confident that the new slider position will still map to the
# same positions in the new axis-space.
return False
def printTransform(self):
print("m11: {}, dx: {}".format(
self.realToPixelTransform.m11(), self.realToPixelTransform.dx()))
(inverted, invertible) = self.realToPixelTransform.inverted()
print("m11: {}, dx: {}, singular: {}".format(
inverted.m11(), inverted.dx(), not invertible))
class ScanWidget(QtWidgets.QWidget):
sigMinMoved = QtCore.pyqtSignal(float)
sigMaxMoved = QtCore.pyqtSignal(float)
def __init__(self, zoomFactor=1.05, rangeFactor=6):
QtWidgets.QWidget.__init__(self)
slider = ScanSlider()
axis = ScanAxis(zoomFactor)
zoomFitButton = QtWidgets.QPushButton("View Range")
fitViewButton = QtWidgets.QPushButton("Snap Range")
self.proxy = ScanProxy(slider, axis, rangeFactor)
axis.proxy = self.proxy
# Layout.
layout = QtWidgets.QGridLayout()
# Default size will cause axis to disappear otherwise.
layout.setRowMinimumHeight(0, 40)
layout.addWidget(axis, 0, 0, 1, -1)
layout.addWidget(slider, 1, 0, 1, -1)
layout.addWidget(zoomFitButton, 2, 0)
layout.addWidget(fitViewButton, 2, 1)
self.setLayout(layout)
# Connect signals
slider.sigMaxMoved.connect(self.proxy.handleMaxMoved)
slider.sigMinMoved.connect(self.proxy.handleMinMoved)
self.proxy.sigMaxMoved.connect(self.sigMaxMoved)
self.proxy.sigMinMoved.connect(self.sigMinMoved)
axis.sigZoom.connect(self.proxy.handleZoom)
fitViewButton.clicked.connect(self.fitToView)
zoomFitButton.clicked.connect(self.zoomToFit)
# Connect event observers.
# Spinbox and button slots. Any time the spinboxes change, ScanWidget
# mirrors it and passes the information to the proxy.
def setMax(self, val):
self.proxy.moveMax(val)
def setMin(self, val):
self.proxy.moveMin(val)
def setNumPoints(self, val):
pass
def zoomToFit(self):
self.proxy.zoomToFit()
def fitToView(self):
self.proxy.fitToView()
def reset(self):
self.proxy.reset()

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import re
from PyQt5 import QtGui, QtWidgets
# after
# http://jdreaver.com/posts/2014-07-28-scientific-notation-spin-box-pyside.html
_inf = float("inf")
# Regular expression to find floats. Match groups are the whole string, the
# whole coefficient, the decimal part of the coefficient, and the exponent
# part.
_float_re = re.compile(r"(([+-]?\d+(\.\d*)?|\.\d+)([eE][+-]?\d+)?)")
def valid_float_string(string):
match = _float_re.search(string)
if match:
return match.groups()[0] == string
return False
class FloatValidator(QtGui.QValidator):
def validate(self, string, position):
if valid_float_string(string):
return self.Acceptable, string, position
if string == "" or string[position-1] in "eE.-+":
return self.Intermediate, string, position
return self.Invalid, string, position
def fixup(self, text):
match = _float_re.search(text)
if match:
return match.groups()[0]
return ""
class ScientificSpinBox(QtWidgets.QDoubleSpinBox):
def __init__(self, *args, **kwargs):
super().__init__(*args, **kwargs)
self.setMinimum(-_inf)
self.setMaximum(_inf)
self.validator = FloatValidator()
self.setDecimals(20)
def validate(self, text, position):
return self.validator.validate(text, position)
def fixup(self, text):
return self.validator.fixup(text)
def valueFromText(self, text):
return float(text)
def textFromValue(self, value):
return format_float(value)
def stepBy(self, steps):
text = self.cleanText()
groups = _float_re.search(text).groups()
decimal = float(groups[1])
decimal += steps
new_string = "{:g}".format(decimal) + (groups[3] if groups[3] else "")
self.lineEdit().setText(new_string)
def format_float(value):
"""Modified form of the 'g' format specifier."""
string = "{:g}".format(value)
string = string.replace("e+", "e")
string = re.sub("e(-?)0*(\d+)", r"e\1\2", string)
return string

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# Robert Jordens <rj@m-labs.hk>, 2016
import numpy as np
class Ticker:
# TODO: if this turns out to be computationally expensive, then refactor
# such that the log()s and intermediate values are reused. But
# probably the string formatting itself is the limiting factor here.
def __init__(self, min_ticks=3, precision=3, steps=(5, 2, 1, .5)):
"""
min_ticks: minimum number of ticks to generate
The maximum number of ticks is
max(consecutive ratios in steps)*min_ticks
thus 5/2*min_ticks for default steps.
precision: maximum number of significant digits in labels
Also extract common offset and magnitude from ticks
if dynamic range exceeds precision number of digits
(small range on top of large offset).
steps: tick increments at a given magnitude
The .5 catches rounding errors where the calculation
of step_magnitude falls into the wrong exponent bin.
"""
self.min_ticks = min_ticks
self.precision = precision
self.steps = steps
def step(self, i):
"""
Return recommended step value for interval size `i`.
"""
if not i:
raise ValueError("Need a finite interval")
step = i/self.min_ticks # rational step size for min_ticks
step_magnitude = 10**np.floor(np.log10(step))
# underlying magnitude for steps
for m in self.steps:
good_step = m*step_magnitude
if good_step <= step:
return good_step
def ticks(self, a, b):
"""
Return recommended tick values for interval `[a, b[`.
"""
step = self.step(b - a)
a0 = np.ceil(a/step)*step
ticks = np.arange(a0, b, step)
return ticks
def offset(self, a, step):
"""
Find offset if dynamic range of the interval is large
(small range on large offset).
If offset is finite, show `offset + value`.
"""
if a == 0.:
return 0.
la = np.floor(np.log10(abs(a)))
lr = np.floor(np.log10(step))
if la - lr < self.precision:
return 0.
magnitude = 10**(lr - 1 + self.precision)
offset = np.floor(a/magnitude)*magnitude
return offset
def magnitude(self, a, b, step):
"""
Determine the scaling magnitude.
If magnitude differs from unity, show `magnitude * value`.
This depends on proper offsetting by `offset()`.
"""
v = np.floor(np.log10(max(abs(a), abs(b))))
w = np.floor(np.log10(step))
if v < self.precision and w > -self.precision:
return 1.
return 10**v
def fix_minus(self, s):
return s.replace("-", "") # unicode minus
def format(self, step):
"""
Determine format string to represent step sufficiently accurate.
"""
dynamic = -int(np.floor(np.log10(step)))
dynamic = min(max(0, dynamic), self.precision)
return "{{:1.{:d}f}}".format(dynamic)
def compact_exponential(self, v):
"""
Format `v` in in compact exponential, stripping redundant elements
(pluses, leading and trailing zeros and decimal point, trailing `e`).
"""
# this is after the matplotlib ScalarFormatter
# without any i18n
significand, exponent = "{:1.10e}".format(v).split("e")
significand = significand.rstrip("0").rstrip(".")
exponent_sign = exponent[0].replace("+", "")
exponent = exponent[1:].lstrip("0")
s = "{:s}e{:s}{:s}".format(significand, exponent_sign,
exponent).rstrip("e")
return self.fix_minus(s)
def prefix(self, offset, magnitude):
"""
Stringify `offset` and `magnitude`.
Expects the string to be shown top/left of the value it refers to.
"""
prefix = ""
if offset != 0.:
prefix += self.compact_exponential(offset) + " + "
if magnitude != 1.:
prefix += self.compact_exponential(magnitude) + " × "
return prefix
def __call__(self, a, b):
"""
Determine ticks, prefix and labels given the interval
`[a, b[`.
Return tick values, prefix string to be show to the left or
above the labels, and tick labels.
"""
ticks = self.ticks(a, b)
offset = self.offset(a, ticks[1] - ticks[0])
t = ticks - offset
magnitude = self.magnitude(t[0], t[-1], t[1] - t[0])
t /= magnitude
prefix = self.prefix(offset, magnitude)
format = self.format(t[1] - t[0])
labels = [self.fix_minus(format.format(t)) for t in t]
return ticks, prefix, labels