- class QPainterPath#
The
QPainterPath
class provides a container for painting operations, enabling graphical shapes to be constructed and reused. More…Synopsis#
Methods#
def
__init__()
def
addEllipse()
def
addPath()
def
addPolygon()
def
addRect()
def
addRegion()
def
addRoundedRect()
def
addText()
def
angleAtPercent()
def
arcMoveTo()
def
arcTo()
def
boundingRect()
def
capacity()
def
clear()
def
closeSubpath()
def
connectPath()
def
contains()
def
cubicTo()
def
elementAt()
def
elementCount()
def
fillRule()
def
intersected()
def
intersects()
def
isEmpty()
def
length()
def
lineTo()
def
moveTo()
def
__ne__()
def
__and__()
def
__iand__()
def
__mul__()
def
__add__()
def
__iadd__()
def
__sub__()
def
__isub__()
def
__eq__()
def
__or__()
def
__ior__()
def
pointAtPercent()
def
quadTo()
def
reserve()
def
setFillRule()
def
simplified()
def
slopeAtPercent()
def
subtracted()
def
swap()
def
toFillPolygon()
def
toFillPolygons()
def
toReversed()
def
translate()
def
translated()
def
united()
Note
This documentation may contain snippets that were automatically translated from C++ to Python. We always welcome contributions to the snippet translation. If you see an issue with the translation, you can also let us know by creating a ticket on https:/bugreports.qt.io/projects/PYSIDE
Detailed Description#
Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
A painter path is an object composed of a number of graphical building blocks, such as rectangles, ellipses, lines, and curves. Building blocks can be joined in closed subpaths, for example as a rectangle or an ellipse. A closed path has coinciding start and end points. Or they can exist independently as unclosed subpaths, such as lines and curves.
A
QPainterPath
object can be used for filling, outlining, and clipping. To generate fillable outlines for a given painter path, use theQPainterPathStroker
class. The main advantage of painter paths over normal drawing operations is that complex shapes only need to be created once; then they can be drawn many times using only calls to thedrawPath()
function.QPainterPath
provides a collection of functions that can be used to obtain information about the path and its elements. In addition it is possible to reverse the order of the elements using thetoReversed()
function. There are also several functions to convert this painter path object into a polygon representation.Composing a QPainterPath#
A
QPainterPath
object can be constructed as an empty path, with a given start point, or as a copy of anotherQPainterPath
object. Once created, lines and curves can be added to the path using thelineTo()
,arcTo()
,cubicTo()
andquadTo()
functions. The lines and curves stretch from thecurrentPosition()
to the position passed as argument.The
currentPosition()
of theQPainterPath
object is always the end position of the last subpath that was added (or the initial start point). Use themoveTo()
function to move thecurrentPosition()
without adding a component. ThemoveTo()
function implicitly starts a new subpath, and closes the previous one. Another way of starting a new subpath is to call thecloseSubpath()
function which closes the current path by adding a line from thecurrentPosition()
back to the path’s start position. Note that the new path will have (0, 0) as its initialcurrentPosition()
.QPainterPath
class also provides several convenience functions to add closed subpaths to a painter path:addEllipse()
,addPath()
,addRect()
,addRegion()
andaddText()
. TheaddPolygon()
function adds an unclosed subpath. In fact, these functions are all collections ofmoveTo()
,lineTo()
andcubicTo()
operations.In addition, a path can be added to the current path using the
connectPath()
function. But note that this function will connect the last element of the current path to the first element of given one by adding a line.Below is a code snippet that shows how a
QPainterPath
object can be used:path = QPainterPath() path.addRect(20, 20, 60, 60) path.moveTo(0, 0) path.cubicTo(99, 0, 50, 50, 99, 99) path.cubicTo(0, 99, 50, 50, 0, 0) painter = QPainter(self) painter.fillRect(0, 0, 100, 100, Qt.white) painter.setPen(QPen(QColor(79, 106, 25), 1, Qt.SolidLine, Qt.FlatCap, Qt.MiterJoin)) painter.setBrush(QColor(122, 163, 39)) painter.drawPath(path)
The painter path is initially empty when constructed. We first add a rectangle, which is a closed subpath. Then we add two bezier curves which together form a closed subpath even though they are not closed individually. Finally we draw the entire path. The path is filled using the default fill rule, Qt::OddEvenFill. Qt provides two methods for filling paths:
Qt::OddEvenFill
Qt::WindingFill
See the Qt::FillRule documentation for the definition of the rules. A painter path’s currently set fill rule can be retrieved using the
fillRule()
function, and altered using thesetFillRule()
function.QPainterPath Information#
The
QPainterPath
class provides a collection of functions that returns information about the path and its elements.The
currentPosition()
function returns the end point of the last subpath that was added (or the initial start point). TheelementAt()
function can be used to retrieve the various subpath elements, the number of elements can be retrieved using theelementCount()
function, and theisEmpty()
function tells whether thisQPainterPath
object contains any elements at all.The
controlPointRect()
function returns the rectangle containing all the points and control points in this path. This function is significantly faster to compute than the exactboundingRect()
which returns the bounding rectangle of this painter path with floating point precision.Finally,
QPainterPath
provides thecontains()
function which can be used to determine whether a given point or rectangle is inside the path, and theintersects()
function which determines if any of the points inside a given rectangle also are inside this path.QPainterPath Conversion#
For compatibility reasons, it might be required to simplify the representation of a painter path:
QPainterPath
provides thetoFillPolygon()
,toFillPolygons()
andtoSubpathPolygons()
functions which convert the painter path into a polygon. ThetoFillPolygon()
returns the painter path as one single polygon, while the two latter functions return a list of polygons.The
toFillPolygons()
andtoSubpathPolygons()
functions are provided because it is usually faster to draw several small polygons than to draw one large polygon, even though the total number of points drawn is the same. The difference between the two is the number of polygons they return: ThetoSubpathPolygons()
creates one polygon for each subpath regardless of intersecting subpaths (i.e. overlapping bounding rectangles), while thetoFillPolygons()
functions creates only one polygon for overlapping subpaths.The
toFillPolygon()
andtoFillPolygons()
functions first convert all the subpaths to polygons, then uses a rewinding technique to make sure that overlapping subpaths can be filled using the correct fill rule. Note that rewinding inserts additional lines in the polygon so the outline of the fill polygon does not match the outline of the path.Examples#
Qt provides the Painter Paths Example and the Vector Deformation example which are located in Qt’s example directory.
The Painter Paths Example shows how painter paths can be used to build complex shapes for rendering and lets the user experiment with the filling and stroking. The Vector Deformation Example shows how to use
QPainterPath
to draw text.Painter Paths Example
Vector Deformation Example
See also
QPainterPathStroker
QPainter
QRegion
Painter Paths Example
- class ElementType#
This enum describes the types of elements used to connect vertices in subpaths.
Note that elements added as closed subpaths using the
addEllipse()
,addPath()
,addPolygon()
,addRect()
,addRegion()
andaddText()
convenience functions, is actually added to the path as a collection of separate elements using themoveTo()
,lineTo()
andcubicTo()
functions.
- __init__(other)#
- Parameters:
other –
QPainterPath
Creates a
QPainterPath
object that is a copy of the givenpath
.See also
operator=()
- __init__()
Constructs an empty
QPainterPath
object.- __init__(startPoint)
- Parameters:
startPoint –
QPointF
Creates a
QPainterPath
object with the givenstartPoint
as its current position.This is an overloaded function.
Creates an ellipse positioned at
center
with radiirx
andry
, and adds it to the painter path as a closed subpath.- addEllipse(x, y, w, h)
- Parameters:
x – float
y – float
w – float
h – float
This is an overloaded function.
Creates an ellipse within the bounding rectangle defined by its top-left corner at (
x
,y
),width
andheight
, and adds it to the painter path as a closed subpath.- addEllipse(rect)
- Parameters:
rect –
QRectF
Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
Creates an ellipse within the specified
boundingRectangle
and adds it to the painter path as a closed subpath.The ellipse is composed of a clockwise curve, starting and finishing at zero degrees (the 3 o’clock position).
myGradient = QLinearGradient() myPen = QPen() boundingRectangle = QRectF() myPath = QPainterPath() myPath.addEllipse(boundingRectangle) painter = QPainter(self) painter.setBrush(myGradient) painter.setPen(myPen) painter.drawPath(myPath)
See also
arcTo()
drawEllipse()
Composing a QPainterPath
- addPath(path)#
- Parameters:
path –
QPainterPath
Adds the given
path
to this path as a closed subpath.See also
connectPath()
Composing a QPainterPath
Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
Adds the given
polygon
to the path as an (unclosed) subpath.Note that the current position after the polygon has been added, is the last point in
polygon
. To draw a line back to the first point, use thecloseSubpath()
function.myGradient = QLinearGradient() myPen = QPen() myPolygon = QPolygonF() myPath = QPainterPath() myPath.addPolygon(myPolygon) painter = QPainter(self) painter.setBrush(myGradient) painter.setPen(myPen) painter.drawPath(myPath)
See also
lineTo()
Composing a QPainterPath
Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
Adds the given
rectangle
to this path as a closed subpath.The
rectangle
is added as a clockwise set of lines. The painter path’s current position after therectangle
has been added is at the top-left corner of the rectangle.myGradient = QLinearGradient() myPen = QPen() myRectangle = QRectF() myPath = QPainterPath() myPath.addRect(myRectangle) painter = QPainter(self) painter.setBrush(myGradient) painter.setPen(myPen) painter.drawPath(myPath)
See also
addRegion()
lineTo()
Composing a QPainterPath
- addRect(x, y, w, h)
- Parameters:
x – float
y – float
w – float
h – float
This is an overloaded function.
Adds a rectangle at position (
x
,y
), with the givenwidth
andheight
, as a closed subpath.Adds the given
region
to the path by adding each rectangle in the region as a separate closed subpath.See also
addRect()
Composing a QPainterPath
- addRoundedRect(rect, xRadius, yRadius[, mode=Qt.AbsoluteSize])#
Adds the given rectangle
rect
with rounded corners to the path.The
xRadius
andyRadius
arguments specify the radii of the ellipses defining the corners of the rounded rectangle. Whenmode
is Qt::RelativeSize,xRadius
andyRadius
are specified in percentage of half the rectangle’s width and height respectively, and should be in the range 0.0 to 100.0.See also
- addRoundedRect(x, y, w, h, xRadius, yRadius[, mode=Qt.AbsoluteSize])
- Parameters:
x – float
y – float
w – float
h – float
xRadius – float
yRadius – float
mode –
SizeMode
This is an overloaded function.
Adds the given rectangle
x
,y
,w
,h
with rounded corners to the path.Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
Adds the given
text
to this path as a set of closed subpaths created from thefont
supplied. The subpaths are positioned so that the left end of the text’s baseline lies at the specifiedpoint
.Some fonts may yield overlapping subpaths and will require the
Qt::WindingFill
fill rule for correct rendering.myGradient = QLinearGradient() myPen = QPen() myFont = QFont() baseline = QPointF(x, y) myPath = QPainterPath() myPath.addText(baseline, myFont, tr("Qt")) painter = QPainter(self) painter.setBrush(myGradient) painter.setPen(myPen) painter.drawPath(myPath)
See also
drawText()
Composing a QPainterPath
setFillRule()
- addText(x, y, f, text)
- Parameters:
x – float
y – float
f –
QFont
text – str
This is an overloaded function.
Adds the given
text
to this path as a set of closed subpaths created from thefont
supplied. The subpaths are positioned so that the left end of the text’s baseline lies at the point specified by (x
,y
).- angleAtPercent(t)#
- Parameters:
t – float
- Return type:
float
Returns the angle of the path tangent at the percentage
t
. The argumentt
has to be between 0 and 1.Positive values for the angles mean counter-clockwise while negative values mean the clockwise direction. Zero degrees is at the 3 o’clock position.
Note that similarly to the other percent methods, the percentage measurement is not linear with regards to the length if curves are present in the path. When curves are present the percentage argument is mapped to the t parameter of the Bezier equations.
Creates a move to that lies on the arc that occupies the given
rectangle
atangle
.Angles are specified in degrees. Clockwise arcs can be specified using negative angles.
- arcMoveTo(x, y, w, h, angle)
- Parameters:
x – float
y – float
w – float
h – float
angle – float
This is an overloaded function.
Creates a move to that lies on the arc that occupies the QRectF(
x
,y
,width
,height
) atangle
.- arcTo(x, y, w, h, startAngle, arcLength)#
- Parameters:
x – float
y – float
w – float
h – float
startAngle – float
arcLength – float
This is an overloaded function.
Creates an arc that occupies the rectangle QRectF(
x
,y
,width
,height
), beginning at the specifiedstartAngle
and extendingsweepLength
degrees counter-clockwise.- arcTo(rect, startAngle, arcLength)
- Parameters:
rect –
QRectF
startAngle – float
arcLength – float
Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
Creates an arc that occupies the given
rectangle
, beginning at the specifiedstartAngle
and extendingsweepLength
degrees counter-clockwise.Angles are specified in degrees. Clockwise arcs can be specified using negative angles.
Note that this function connects the starting point of the arc to the current position if they are not already connected. After the arc has been added, the current position is the last point in arc. To draw a line back to the first point, use the
closeSubpath()
function.myPath = QPainterPath() myPath.moveTo(center) myPath.arcTo(boundingRect, startAngle, sweepLength) painter = QPainter(self) painter.setBrush(myGradient) painter.setPen(myPen) painter.drawPath(myPath)
See also
arcMoveTo()
addEllipse()
drawArc()
drawPie()
Composing a QPainterPath
Returns the bounding rectangle of this painter path as a rectangle with floating point precision.
See also
- capacity()#
- Return type:
int
Returns the number of elements allocated by the
QPainterPath
.- clear()#
Clears the path elements stored.
This allows the path to reuse previous memory allocations.
See also
- closeSubpath()#
Closes the current subpath by drawing a line to the beginning of the subpath, automatically starting a new path. The current point of the new path is (0, 0).
If the subpath does not contain any elements, this function does nothing.
See also
moveTo()
Composing a QPainterPath
- connectPath(path)#
- Parameters:
path –
QPainterPath
Connects the given
path
to this path by adding a line from the last element of this path to the first element of the given path.See also
addPath()
Composing a QPainterPath
- contains(p)#
- Parameters:
p –
QPainterPath
- Return type:
bool
Returns
true
if the given pathp
is contained within the current path. Returnsfalse
if any edges of the current path andp
intersect.Set operations on paths will treat the paths as areas. Non-closed paths will be treated as implicitly closed.
See also
- contains(pt)
- Parameters:
pt –
QPointF
- Return type:
bool
Returns
true
if the givenpoint
is inside the path, otherwise returnsfalse
.See also
- contains(rect)
- Parameters:
rect –
QRectF
- Return type:
bool
Returns
true
if the givenrectangle
is inside the path, otherwise returnsfalse
.Returns the rectangle containing all the points and control points in this path.
This function is significantly faster to compute than the exact
boundingRect()
, and the returned rectangle is always a superset of the rectangle returned byboundingRect()
.See also
Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
Adds a cubic Bezier curve between the current position and the given
endPoint
using the control points specified byc1
, andc2
.After the curve is added, the current position is updated to be at the end point of the curve.
myGradient = QLinearGradient() myPen = QPen() myPath = QPainterPath() myPath.cubicTo(c1, c2, endPoint) painter = QPainter(self) painter.setBrush(myGradient) painter.setPen(myPen) painter.drawPath(myPath)
See also
quadTo()
Composing a QPainterPath
- cubicTo(ctrlPt1x, ctrlPt1y, ctrlPt2x, ctrlPt2y, endPtx, endPty)
- Parameters:
ctrlPt1x – float
ctrlPt1y – float
ctrlPt2x – float
ctrlPt2y – float
endPtx – float
endPty – float
This is an overloaded function.
Adds a cubic Bezier curve between the current position and the end point (
endPointX
,endPointY
) with control points specified by (c1X
,c1Y
) and (c2X
,c2Y
).Returns the current position of the path.
- elementAt(i)#
- Parameters:
i – int
- Return type:
Element
Returns the element at the given
index
in the painter path.See also
- elementCount()#
- Return type:
int
Returns the number of path elements in the painter path.
See also
Returns the painter path’s currently set fill rule.
See also
- intersected(r)#
- Parameters:
r –
QPainterPath
- Return type:
Returns a path which is the intersection of this path’s fill area and
p
's fill area. Bezier curves may be flattened to line segments due to numerical instability of doing bezier curve intersections.Returns
true
if any point in the givenrectangle
intersects the path; otherwise returnsfalse
.There is an intersection if any of the lines making up the rectangle crosses a part of the path or if any part of the rectangle overlaps with any area enclosed by the path. This function respects the current
fillRule
to determine what is considered inside the path.See also
- intersects(p)
- Parameters:
p –
QPainterPath
- Return type:
bool
Returns
true
if the current path intersects at any point the given pathp
. Also returnstrue
if the current path contains or is contained by any part ofp
.Set operations on paths will treat the paths as areas. Non-closed paths will be treated as implicitly closed.
See also
- isEmpty()#
- Return type:
bool
Returns
true
if either there are no elements in this path, or if the only element is aMoveToElement
; otherwise returnsfalse
.See also
- length()#
- Return type:
float
Returns the length of the current path.
Adds a straight line from the current position to the given
endPoint
. After the line is drawn, the current position is updated to be at the end point of the line.See also
addPolygon()
addRect()
Composing a QPainterPath
- lineTo(x, y)
- Parameters:
x – float
y – float
This is an overloaded function.
Draws a line from the current position to the point (
x
,y
).Moves the current point to the given
point
, implicitly starting a new subpath and closing the previous one.See also
closeSubpath()
Composing a QPainterPath
- moveTo(x, y)
- Parameters:
x – float
y – float
This is an overloaded function.
Moves the current position to (
x
,y
) and starts a new subpath, implicitly closing the previous path.- __ne__(other)#
- Parameters:
other –
QPainterPath
- Return type:
bool
Returns
true
if this painter path differs from the givenpath
.Note that comparing paths may involve a per element comparison which can be slow for complex paths.
See also
operator==()
- __and__(other)#
- Parameters:
other –
QPainterPath
- Return type:
Returns the intersection of this path and the
other
path.See also
intersected()
operator&=()
united()
operator|()
- __iand__(other)#
- Parameters:
other –
QPainterPath
- Return type:
Intersects this path with
other
and returns a reference to this path.See also
intersected()
operator&()
operator|=()
- __mul__(m)#
- Parameters:
m –
QTransform
- Return type:
- __add__(other)#
- Parameters:
other –
QPainterPath
- Return type:
Returns the union of this path and the
other
path. This function is equivalent to operator|().See also
united()
operator+=()
operator-()
- __iadd__(other)#
- Parameters:
other –
QPainterPath
- Return type:
Unites this path with
other
, and returns a reference to this path. This is equivalent to operator|=().See also
united()
operator+()
operator-=()
- __sub__(other)#
- Parameters:
other –
QPainterPath
- Return type:
Subtracts the
other
path from a copy of this path, and returns the copy.See also
subtracted()
operator-=()
operator+()
- __isub__(other)#
- Parameters:
other –
QPainterPath
- Return type:
Subtracts
other
from this path, and returns a reference to this path.See also
subtracted()
operator-()
operator+=()
- __eq__(other)#
- Parameters:
other –
QPainterPath
- Return type:
bool
Returns
true
if this painterpath is equal to the givenpath
.Note that comparing paths may involve a per element comparison which can be slow for complex paths.
See also
operator!=()
- __or__(other)#
- Parameters:
other –
QPainterPath
- Return type:
Returns the union of this path and the
other
path.See also
united()
operator|=()
intersected()
operator&()
- __ior__(other)#
- Parameters:
other –
QPainterPath
- Return type:
Unites this path with
other
and returns a reference to this path.See also
united()
operator|()
operator&=()
- percentAtLength(t)#
- Parameters:
t – float
- Return type:
float
Returns percentage of the whole path at the specified length
len
.Note that similarly to other percent methods, the percentage measurement is not linear with regards to the length, if curves are present in the path. When curves are present the percentage argument is mapped to the t parameter of the Bezier equations.
Returns the point at at the percentage
t
of the current path. The argumentt
has to be between 0 and 1.Note that similarly to other percent methods, the percentage measurement is not linear with regards to the length, if curves are present in the path. When curves are present the percentage argument is mapped to the t parameter of the Bezier equations.
- quadTo(ctrlPtx, ctrlPty, endPtx, endPty)#
- Parameters:
ctrlPtx – float
ctrlPty – float
endPtx – float
endPty – float
This is an overloaded function.
Adds a quadratic Bezier curve between the current point and the endpoint (
endPointX
,endPointY
) with the control point specified by (cx
,cy
).Adds a quadratic Bezier curve between the current position and the given
endPoint
with the control point specified byc
.After the curve is added, the current point is updated to be at the end point of the curve.
See also
cubicTo()
Composing a QPainterPath
- reserve(size)#
- Parameters:
size – int
Reserves a given amount of elements in
QPainterPath
‘s internal memory.Attempts to allocate memory for at least
size
elements.See also
clear()
capacity()
reserve()
- setElementPositionAt(i, x, y)#
- Parameters:
i – int
x – float
y – float
Sets the x and y coordinate of the element at index
index
tox
andy
.Sets the fill rule of the painter path to the given
fillRule
. Qt provides two methods for filling paths:Qt::OddEvenFill (default)
Qt::WindingFill
See also
- simplified()#
- Return type:
Returns a simplified version of this path. This implies merging all subpaths that intersect, and returning a path containing no intersecting edges. Consecutive parallel lines will also be merged. The simplified path will always use the default fill rule, Qt::OddEvenFill. Bezier curves may be flattened to line segments due to numerical instability of doing bezier curve intersections.
- slopeAtPercent(t)#
- Parameters:
t – float
- Return type:
float
Returns the slope of the path at the percentage
t
. The argumentt
has to be between 0 and 1.Note that similarly to other percent methods, the percentage measurement is not linear with regards to the length, if curves are present in the path. When curves are present the percentage argument is mapped to the t parameter of the Bezier equations.
- subtracted(r)#
- Parameters:
r –
QPainterPath
- Return type:
Returns a path which is
p
's fill area subtracted from this path’s fill area.Set operations on paths will treat the paths as areas. Non-closed paths will be treated as implicitly closed. Bezier curves may be flattened to line segments due to numerical instability of doing bezier curve intersections.
- swap(other)#
- Parameters:
other –
QPainterPath
Swaps painter path
other
with this painter path. This operation is very fast and never fails.- toFillPolygon([matrix=QTransform()])#
- Parameters:
matrix –
QTransform
- Return type:
Converts the path into a polygon using the
QTransform
matrix
, and returns the polygon.The polygon is created by first converting all subpaths to polygons, then using a rewinding technique to make sure that overlapping subpaths can be filled using the correct fill rule.
Note that rewinding inserts addition lines in the polygon so the outline of the fill polygon does not match the outline of the path.
See also
toSubpathPolygons()
toFillPolygons()
QPainterPath Conversion
- toFillPolygons([matrix=QTransform()])#
- Parameters:
matrix –
QTransform
- Return type:
.list of QPolygonF
Converts the path into a list of polygons using the
QTransform
matrix
, and returns the list.The function differs from the
toFillPolygon()
function in that it creates several polygons. It is provided because it is usually faster to draw several small polygons than to draw one large polygon, even though the total number of points drawn is the same.The toFillPolygons() function differs from the
toSubpathPolygons()
function in that it create only polygon for subpaths that have overlapping bounding rectangles.Like the
toFillPolygon()
function, this function uses a rewinding technique to make sure that overlapping subpaths can be filled using the correct fill rule. Note that rewinding inserts addition lines in the polygons so the outline of the fill polygon does not match the outline of the path.See also
toSubpathPolygons()
toFillPolygon()
QPainterPath Conversion
- toReversed()#
- Return type:
Creates and returns a reversed copy of the path.
It is the order of the elements that is reversed: If a
QPainterPath
is composed by calling themoveTo()
,lineTo()
andcubicTo()
functions in the specified order, the reversed copy is composed by callingcubicTo()
,lineTo()
andmoveTo()
.- toSubpathPolygons([matrix=QTransform()])#
- Parameters:
matrix –
QTransform
- Return type:
.list of QPolygonF
Converts the path into a list of polygons using the
QTransform
matrix
, and returns the list.This function creates one polygon for each subpath regardless of intersecting subpaths (i.e. overlapping bounding rectangles). To make sure that such overlapping subpaths are filled correctly, use the
toFillPolygons()
function instead.See also
toFillPolygons()
toFillPolygon()
QPainterPath Conversion
This is an overloaded function.
Translates all elements in the path by the given
offset
.See also
- translate(dx, dy)
- Parameters:
dx – float
dy – float
Translates all elements in the path by (
dx
,dy
).See also
This is an overloaded function.
Returns a copy of the path that is translated by the given
offset
.See also
- translated(dx, dy)
- Parameters:
dx – float
dy – float
- Return type:
Returns a copy of the path that is translated by (
dx
,dy
).See also
- united(r)#
- Parameters:
r –
QPainterPath
- Return type:
Returns a path which is the union of this path’s fill area and
p
's fill area.Set operations on paths will treat the paths as areas. Non-closed paths will be treated as implicitly closed. Bezier curves may be flattened to line segments due to numerical instability of doing bezier curve intersections.
See also