public abstract class Graphics2D extends Graphics
Graphics2D
class extends the
Graphics
class to provide more sophisticated
control over geometry, coordinate transformations, color management,
and text layout. This is the fundamental class for rendering
2-dimensional shapes, text and images on the Java(tm) platform.
Graphics2D
object are specified
in a device-independent coordinate system called User Space, which is
used by applications. The Graphics2D
object contains
an AffineTransform
object as part of its rendering state
that defines how to convert coordinates from user space to
device-dependent coordinates in Device Space.
Coordinates in device space usually refer to individual device pixels
and are aligned on the infinitely thin gaps between these pixels.
Some Graphics2D
objects can be used to capture rendering
operations for storage into a graphics metafile for playback on a
concrete device of unknown physical resolution at a later time. Since
the resolution might not be known when the rendering operations are
captured, the Graphics2D
Transform
is set up
to transform user coordinates to a virtual device space that
approximates the expected resolution of the target device. Further
transformations might need to be applied at playback time if the
estimate is incorrect.
Some of the operations performed by the rendering attribute objects
occur in the device space, but all Graphics2D
methods take
user space coordinates.
Every Graphics2D
object is associated with a target that
defines where rendering takes place. A
GraphicsConfiguration
object defines the characteristics
of the rendering target, such as pixel format and resolution.
The same rendering target is used throughout the life of a
Graphics2D
object.
When creating a Graphics2D
object, the
GraphicsConfiguration
specifies the default transform for
the target of the Graphics2D
(a
Component
or Image
). This default transform maps the
user space coordinate system to screen and printer device coordinates
such that the origin maps to the upper left hand corner of the
target region of the device with increasing X coordinates extending
to the right and increasing Y coordinates extending downward.
The scaling of the default transform is set to identity for those devices
that are close to 72 dpi, such as screen devices.
The scaling of the default transform is set to approximately 72 user
space coordinates per square inch for high resolution devices, such as
printers. For image buffers, the default transform is the
Identity
transform.
Graphics2D
rendering attributes.
The renderer can optimize many of these steps, either by caching the
results for future calls, by collapsing multiple virtual steps into
a single operation, or by recognizing various attributes as common
simple cases that can be eliminated by modifying other parts of the
operation.
The steps in the rendering process are:
Clip
.
The Clip
is specified by a Shape
in user
space and is controlled by the program using the various clip
manipulation methods of Graphics
and
Graphics2D
. This user clip
is transformed into device space by the current
Transform
and combined with the
device clip, which is defined by the visibility of windows and
device extents. The combination of the user clip and device clip
defines the composite clip, which determines the final clipping
region. The user clip is not modified by the rendering
system to reflect the resulting composite clip.
Composite
attribute in the Graphics2D
context.
Shape
operations
draw(Shape)
operation, then
the createStrokedShape
method on the current Stroke
attribute in the
Graphics2D
context is used to construct a new
Shape
object that contains the outline of the specified
Shape
.
Shape
is transformed from user space to device space
using the current Transform
in the Graphics2D
context.
Shape
is extracted using the
getPathIterator
method of
Shape
, which returns a
PathIterator
object that iterates along the boundary of the Shape
.
Graphics2D
object cannot handle the curved segments
that the PathIterator
object returns then it can call the
alternate
getPathIterator
method of Shape
, which flattens the Shape
.
Paint
in the Graphics2D
context
is queried for a PaintContext
, which specifies the
colors to render in device space.
String
:
String
, then the current
Font
in the Graphics2D
context is asked to
convert the Unicode characters in the String
into a set of
glyphs for presentation with whatever basic layout and shaping
algorithms the font implements.
AttributedCharacterIterator
,
the iterator is asked to convert itself to a
TextLayout
using its embedded font attributes. The TextLayout
implements more sophisticated glyph layout algorithms that
perform Unicode bi-directional layout adjustments automatically
for multiple fonts of differing writing directions.
GlyphVector
, then the
GlyphVector
object already contains the appropriate
font-specific glyph codes with explicit coordinates for the position of
each glyph.
Font
is queried to obtain outlines for the
indicated glyphs. These outlines are treated as shapes in user space
relative to the position of each glyph that was determined in step 1.
Shape
operations.
Paint
is queried for a
PaintContext
, which specifies
the colors to render in device space.
Image
Operations
Image
.
This bounding box is specified in Image Space, which is the
Image
object's local coordinate system.
AffineTransform
is passed to
drawImage(Image, AffineTransform, ImageObserver)
,
the AffineTransform
is used to transform the bounding
box from image space to user space. If no AffineTransform
is supplied, the bounding box is treated as if it is already in user space.
Image
is transformed from user
space into device space using the current Transform
.
Note that the result of transforming the bounding box does not
necessarily result in a rectangular region in device space.
Image
object determines what colors to render,
sampled according to the source to destination
coordinate mapping specified by the current Transform
and the
optional image transform.
Graphics2D
rendering attributes are:
Paint
Component
.
Font
Font
of the Component
.
Stroke
Transform
getDefaultTransform
for the GraphicsConfiguration
of the Component
.
Composite
AlphaComposite.SRC_OVER
rule.
Clip
Clip
, the output is clipped to the
Component
.
The Java 2D(tm) (Java(tm) 2 platform) API supports antialiasing renderers.
A pen with a width of one pixel does not need to fall
completely on pixel N as opposed to pixel N+1. The pen can fall
partially on both pixels. It is not necessary to choose a bias
direction for a wide pen since the blending that occurs along the
pen traversal edges makes the sub-pixel position of the pen
visible to the user. On the other hand, when antialiasing is
turned off by setting the
KEY_ANTIALIASING
hint key
to the
VALUE_ANTIALIAS_OFF
hint value, the renderer might need
to apply a bias to determine which pixel to modify when the pen
is straddling a pixel boundary, such as when it is drawn
along an integer coordinate in device space. While the capabilities
of an antialiasing renderer make it no longer necessary for the
rendering model to specify a bias for the pen, it is desirable for the
antialiasing and non-antialiasing renderers to perform similarly for
the common cases of drawing one-pixel wide horizontal and vertical
lines on the screen. To ensure that turning on antialiasing by
setting the
KEY_ANTIALIASING
hint
key to
VALUE_ANTIALIAS_ON
does not cause such lines to suddenly become twice as wide and half
as opaque, it is desirable to have the model specify a path for such
lines so that they completely cover a particular set of pixels to help
increase their crispness.
Java 2D API maintains compatibility with JDK 1.1 rendering
behavior, such that legacy operations and existing renderer
behavior is unchanged under Java 2D API. Legacy
methods that map onto general draw
and
fill
methods are defined, which clearly indicates
how Graphics2D
extends Graphics
based
on settings of Stroke
and Transform
attributes and rendering hints. The definition
performs identically under default attribute settings.
For example, the default Stroke
is a
BasicStroke
with a width of 1 and no dashing and the
default Transform for screen drawing is an Identity transform.
The following two rules provide predictable rendering behavior whether aliasing or antialiasing is being used.
BasicStroke
object may be "normalized" to provide consistent rendering of the
outlines when positioned at various points on the drawable and
whether drawn with aliased or antialiased rendering. This
normalization process is controlled by the
KEY_STROKE_CONTROL
hint.
The exact normalization algorithm is not specified, but the goals
of this normalization are to ensure that lines are rendered with
consistent visual appearance regardless of how they fall on the
pixel grid and to promote more solid horizontal and vertical
lines in antialiased mode so that they resemble their non-antialiased
counterparts more closely. A typical normalization step might
promote antialiased line endpoints to pixel centers to reduce the
amount of blending or adjust the subpixel positioning of
non-antialiased lines so that the floating point line widths
round to even or odd pixel counts with equal likelihood. This
process can move endpoints by up to half a pixel (usually towards
positive infinity along both axes) to promote these consistent
results.
The following definitions of general legacy methods perform identically to previously specified behavior under default attribute settings:
fill
operations, including fillRect
,
fillRoundRect
, fillOval
,
fillArc
, fillPolygon
, and
clearRect
, fill
can now be called
with the desired Shape
. For example, when filling a
rectangle:
fill(new Rectangle(x, y, w, h));is called.
drawLine
,
drawRect
, drawRoundRect
,
drawOval
, drawArc
, drawPolyline
,
and drawPolygon
, draw
can now be
called with the desired Shape
. For example, when drawing a
rectangle:
draw(new Rectangle(x, y, w, h));is called.
draw3DRect
and fill3DRect
methods were
implemented in terms of the drawLine
and
fillRect
methods in the Graphics
class which
would predicate their behavior upon the current Stroke
and Paint
objects in a Graphics2D
context.
This class overrides those implementations with versions that use
the current Color
exclusively, overriding the current
Paint
and which uses fillRect
to describe
the exact same behavior as the preexisting methods regardless of the
setting of the current Stroke
.
Graphics
class defines only the setColor
method to control the color to be painted. Since the Java 2D API extends
the Color
object to implement the new Paint
interface, the existing
setColor
method is now a convenience method for setting the
current Paint
attribute to a Color
object.
setColor(c)
is equivalent to setPaint(c)
.
The Graphics
class defines two methods for controlling
how colors are applied to the destination.
setPaintMode
method is implemented as a convenience
method to set the default Composite
, equivalent to
setComposite(new AlphaComposite.SrcOver)
.
setXORMode(Color xorcolor)
method is implemented
as a convenience method to set a special Composite
object that
ignores the Alpha
components of source colors and sets the
destination color to the value:
dstpixel = (PixelOf(srccolor) ^ PixelOf(xorcolor) ^ dstpixel);
RenderingHints
Modifier | Constructor and Description |
---|---|
protected |
Graphics2D()
Constructs a new
Graphics2D object. |
Modifier and Type | Method and Description |
---|---|
abstract void |
addRenderingHints(Map<?,?> hints)
Sets the values of an arbitrary number of preferences for the
rendering algorithms.
|
abstract void |
clip(Shape s)
Intersects the current
Clip with the interior of the
specified Shape and sets the Clip to the
resulting intersection. |
abstract void |
draw(Shape s)
Strokes the outline of a
Shape using the settings of the
current Graphics2D context. |
void |
draw3DRect(int x,
int y,
int width,
int height,
boolean raised)
Draws a 3-D highlighted outline of the specified rectangle.
|
abstract void |
drawGlyphVector(GlyphVector g,
float x,
float y)
Renders the text of the specified
GlyphVector using
the Graphics2D context's rendering attributes. |
abstract void |
drawImage(BufferedImage img,
BufferedImageOp op,
int x,
int y)
Renders a
BufferedImage that is
filtered with a
BufferedImageOp . |
abstract boolean |
drawImage(Image img,
AffineTransform xform,
ImageObserver obs)
Renders an image, applying a transform from image space into user space
before drawing.
|
abstract void |
drawRenderableImage(RenderableImage img,
AffineTransform xform)
Renders a
RenderableImage ,
applying a transform from image space into user space before drawing. |
abstract void |
drawRenderedImage(RenderedImage img,
AffineTransform xform)
Renders a
RenderedImage ,
applying a transform from image
space into user space before drawing. |
abstract void |
drawString(AttributedCharacterIterator iterator,
float x,
float y)
Renders the text of the specified iterator applying its attributes
in accordance with the specification of the
TextAttribute class. |
abstract void |
drawString(AttributedCharacterIterator iterator,
int x,
int y)
Renders the text of the specified iterator applying its attributes
in accordance with the specification of the
TextAttribute class. |
abstract void |
drawString(String str,
float x,
float y)
Renders the text specified by the specified
String ,
using the current text attribute state in the Graphics2D context. |
abstract void |
drawString(String str,
int x,
int y)
Renders the text of the specified
String , using the
current text attribute state in the Graphics2D context. |
abstract void |
fill(Shape s)
Fills the interior of a
Shape using the settings of the
Graphics2D context. |
void |
fill3DRect(int x,
int y,
int width,
int height,
boolean raised)
Paints a 3-D highlighted rectangle filled with the current color.
|
abstract Color |
getBackground()
Returns the background color used for clearing a region.
|
abstract Composite |
getComposite()
Returns the current
Composite in the
Graphics2D context. |
abstract GraphicsConfiguration |
getDeviceConfiguration()
Returns the device configuration associated with this
Graphics2D . |
abstract FontRenderContext |
getFontRenderContext()
Get the rendering context of the
Font within this
Graphics2D context. |
abstract Paint |
getPaint()
Returns the current
Paint of the
Graphics2D context. |
abstract Object |
getRenderingHint(RenderingHints.Key hintKey)
Returns the value of a single preference for the rendering algorithms.
|
abstract RenderingHints |
getRenderingHints()
Gets the preferences for the rendering algorithms.
|
abstract Stroke |
getStroke()
Returns the current
Stroke in the
Graphics2D context. |
abstract AffineTransform |
getTransform()
Returns a copy of the current
Transform in the
Graphics2D context. |
abstract boolean |
hit(Rectangle rect,
Shape s,
boolean onStroke)
Checks whether or not the specified
Shape intersects
the specified Rectangle , which is in device
space. |
abstract void |
rotate(double theta)
Concatenates the current
Graphics2D
Transform with a rotation transform. |
abstract void |
rotate(double theta,
double x,
double y)
Concatenates the current
Graphics2D
Transform with a translated rotation
transform. |
abstract void |
scale(double sx,
double sy)
Concatenates the current
Graphics2D
Transform with a scaling transformation
Subsequent rendering is resized according to the specified scaling
factors relative to the previous scaling. |
abstract void |
setBackground(Color color)
Sets the background color for the
Graphics2D context. |
abstract void |
setComposite(Composite comp)
Sets the
Composite for the Graphics2D context. |
abstract void |
setPaint(Paint paint)
Sets the
Paint attribute for the
Graphics2D context. |
abstract void |
setRenderingHint(RenderingHints.Key hintKey,
Object hintValue)
Sets the value of a single preference for the rendering algorithms.
|
abstract void |
setRenderingHints(Map<?,?> hints)
Replaces the values of all preferences for the rendering
algorithms with the specified
hints . |
abstract void |
setStroke(Stroke s)
Sets the
Stroke for the Graphics2D context. |
abstract void |
setTransform(AffineTransform Tx)
Overwrites the Transform in the
Graphics2D context. |
abstract void |
shear(double shx,
double shy)
Concatenates the current
Graphics2D
Transform with a shearing transform. |
abstract void |
transform(AffineTransform Tx)
Composes an
AffineTransform object with the
Transform in this Graphics2D according
to the rule last-specified-first-applied. |
abstract void |
translate(double tx,
double ty)
Concatenates the current
Graphics2D Transform
with a translation transform. |
abstract void |
translate(int x,
int y)
Translates the origin of the
Graphics2D context to the
point (x, y) in the current coordinate system. |
clearRect, clipRect, copyArea, create, create, dispose, drawArc, drawBytes, drawChars, drawImage, drawImage, drawImage, drawImage, drawImage, drawImage, drawLine, drawOval, drawPolygon, drawPolygon, drawPolyline, drawRect, drawRoundRect, fillArc, fillOval, fillPolygon, fillPolygon, fillRect, fillRoundRect, finalize, getClip, getClipBounds, getClipBounds, getClipRect, getColor, getFont, getFontMetrics, getFontMetrics, hitClip, setClip, setClip, setColor, setFont, setPaintMode, setXORMode, toString
protected Graphics2D()
Graphics2D
object. Since
Graphics2D
is an abstract class, and since it must be
customized by subclasses for different output devices,
Graphics2D
objects cannot be created directly.
Instead, Graphics2D
objects must be obtained from another
Graphics2D
object, created by a
Component
, or obtained from images such as
BufferedImage
objects.Component.getGraphics()
,
Graphics.create()
public void draw3DRect(int x, int y, int width, int height, boolean raised)
The colors used for the highlighting effect are determined
based on the current color.
The resulting rectangle covers an area that is
width + 1
pixels wide
by height + 1
pixels tall. This method
uses the current Color
exclusively and ignores
the current Paint
.
draw3DRect
in class Graphics
x
- the x coordinate of the rectangle to be drawn.y
- the y coordinate of the rectangle to be drawn.width
- the width of the rectangle to be drawn.height
- the height of the rectangle to be drawn.raised
- a boolean that determines whether the rectangle
appears to be raised above the surface
or sunk into the surface.Graphics.fill3DRect(int, int, int, int, boolean)
public void fill3DRect(int x, int y, int width, int height, boolean raised)
Color
. This method uses
the current Color
exclusively and ignores the current
Paint
.fill3DRect
in class Graphics
x
- the x coordinate of the rectangle to be filled.y
- the y coordinate of the rectangle to be filled.width
- the width of the rectangle to be filled.height
- the height of the rectangle to be filled.raised
- a boolean value that determines whether the
rectangle appears to be raised above the surface
or etched into the surface.Graphics.draw3DRect(int, int, int, int, boolean)
public abstract void draw(Shape s)
Shape
using the settings of the
current Graphics2D
context. The rendering attributes
applied include the Clip
, Transform
,
Paint
, Composite
and
Stroke
attributes.s
- the Shape
to be renderedsetStroke(java.awt.Stroke)
,
setPaint(java.awt.Paint)
,
Graphics.setColor(java.awt.Color)
,
transform(java.awt.geom.AffineTransform)
,
setTransform(java.awt.geom.AffineTransform)
,
clip(java.awt.Shape)
,
Graphics.setClip(int, int, int, int)
,
setComposite(java.awt.Composite)
public abstract boolean drawImage(Image img, AffineTransform xform, ImageObserver obs)
Transform
in the Graphics2D
.
The specified transformation is applied to the image before the
transform attribute in the Graphics2D
context is applied.
The rendering attributes applied include the Clip
,
Transform
, and Composite
attributes.
Note that no rendering is done if the specified transform is
noninvertible.img
- the specified image to be rendered.
This method does nothing if img
is null.xform
- the transformation from image space into user spaceobs
- the ImageObserver
to be notified as more of the Image
is convertedtrue
if the Image
is
fully loaded and completely rendered, or if it's null;
false
if the Image
is still being loaded.transform(java.awt.geom.AffineTransform)
,
setTransform(java.awt.geom.AffineTransform)
,
setComposite(java.awt.Composite)
,
clip(java.awt.Shape)
,
Graphics.setClip(int, int, int, int)
public abstract void drawImage(BufferedImage img, BufferedImageOp op, int x, int y)
BufferedImage
that is
filtered with a
BufferedImageOp
.
The rendering attributes applied include the Clip
,
Transform
and Composite
attributes. This is equivalent to:
img1 = op.filter(img, null); drawImage(img1, new AffineTransform(1f,0f,0f,1f,x,y), null);
op
- the filter to be applied to the image before renderingimg
- the specified BufferedImage
to be rendered.
This method does nothing if img
is null.x
- the x coordinate of the location in user space where
the upper left corner of the image is renderedy
- the y coordinate of the location in user space where
the upper left corner of the image is renderedtransform(java.awt.geom.AffineTransform)
,
setTransform(java.awt.geom.AffineTransform)
,
setComposite(java.awt.Composite)
,
clip(java.awt.Shape)
,
Graphics.setClip(int, int, int, int)
public abstract void drawRenderedImage(RenderedImage img, AffineTransform xform)
RenderedImage
,
applying a transform from image
space into user space before drawing.
The transformation from user space into device space is done with
the current Transform
in the Graphics2D
.
The specified transformation is applied to the image before the
transform attribute in the Graphics2D
context is applied.
The rendering attributes applied include the Clip
,
Transform
, and Composite
attributes. Note
that no rendering is done if the specified transform is
noninvertible.img
- the image to be rendered. This method does
nothing if img
is null.xform
- the transformation from image space into user spacetransform(java.awt.geom.AffineTransform)
,
setTransform(java.awt.geom.AffineTransform)
,
setComposite(java.awt.Composite)
,
clip(java.awt.Shape)
,
Graphics.setClip(int, int, int, int)
public abstract void drawRenderableImage(RenderableImage img, AffineTransform xform)
RenderableImage
,
applying a transform from image space into user space before drawing.
The transformation from user space into device space is done with
the current Transform
in the Graphics2D
.
The specified transformation is applied to the image before the
transform attribute in the Graphics2D
context is applied.
The rendering attributes applied include the Clip
,
Transform
, and Composite
attributes. Note
that no rendering is done if the specified transform is
noninvertible.
Rendering hints set on the Graphics2D
object might
be used in rendering the RenderableImage
.
If explicit control is required over specific hints recognized by a
specific RenderableImage
, or if knowledge of which hints
are used is required, then a RenderedImage
should be
obtained directly from the RenderableImage
and rendered using
drawRenderedImage
.
img
- the image to be rendered. This method does
nothing if img
is null.xform
- the transformation from image space into user spacetransform(java.awt.geom.AffineTransform)
,
setTransform(java.awt.geom.AffineTransform)
,
setComposite(java.awt.Composite)
,
clip(java.awt.Shape)
,
Graphics.setClip(int, int, int, int)
,
drawRenderedImage(java.awt.image.RenderedImage, java.awt.geom.AffineTransform)
public abstract void drawString(String str, int x, int y)
String
, using the
current text attribute state in the Graphics2D
context.
The baseline of the
first character is at position (x, y) in
the User Space.
The rendering attributes applied include the Clip
,
Transform
, Paint
, Font
and
Composite
attributes. For characters in script
systems such as Hebrew and Arabic, the glyphs can be rendered from
right to left, in which case the coordinate supplied is the
location of the leftmost character on the baseline.drawString
in class Graphics
str
- the string to be renderedx
- the x coordinate of the location where the
String
should be renderedy
- the y coordinate of the location where the
String
should be renderedNullPointerException
- if str
is
null
Graphics.drawBytes(byte[], int, int, int, int)
,
Graphics.drawChars(char[], int, int, int, int)
public abstract void drawString(String str, float x, float y)
String
,
using the current text attribute state in the Graphics2D
context.
The baseline of the first character is at position
(x, y) in the User Space.
The rendering attributes applied include the Clip
,
Transform
, Paint
, Font
and
Composite
attributes. For characters in script systems
such as Hebrew and Arabic, the glyphs can be rendered from right to
left, in which case the coordinate supplied is the location of the
leftmost character on the baseline.str
- the String
to be renderedx
- the x coordinate of the location where the
String
should be renderedy
- the y coordinate of the location where the
String
should be renderedNullPointerException
- if str
is
null
setPaint(java.awt.Paint)
,
Graphics.setColor(java.awt.Color)
,
Graphics.setFont(java.awt.Font)
,
setTransform(java.awt.geom.AffineTransform)
,
setComposite(java.awt.Composite)
,
Graphics.setClip(int, int, int, int)
public abstract void drawString(AttributedCharacterIterator iterator, int x, int y)
TextAttribute
class.
The baseline of the first character is at position (x, y) in User Space. For characters in script systems such as Hebrew and Arabic, the glyphs can be rendered from right to left, in which case the coordinate supplied is the location of the leftmost character on the baseline.
drawString
in class Graphics
iterator
- the iterator whose text is to be renderedx
- the x coordinate where the iterator's text is to be
renderedy
- the y coordinate where the iterator's text is to be
renderedNullPointerException
- if iterator
is
null
setPaint(java.awt.Paint)
,
Graphics.setColor(java.awt.Color)
,
setTransform(java.awt.geom.AffineTransform)
,
setComposite(java.awt.Composite)
,
Graphics.setClip(int, int, int, int)
public abstract void drawString(AttributedCharacterIterator iterator, float x, float y)
TextAttribute
class.
The baseline of the first character is at position (x, y) in User Space. For characters in script systems such as Hebrew and Arabic, the glyphs can be rendered from right to left, in which case the coordinate supplied is the location of the leftmost character on the baseline.
iterator
- the iterator whose text is to be renderedx
- the x coordinate where the iterator's text is to be
renderedy
- the y coordinate where the iterator's text is to be
renderedNullPointerException
- if iterator
is
null
setPaint(java.awt.Paint)
,
Graphics.setColor(java.awt.Color)
,
setTransform(java.awt.geom.AffineTransform)
,
setComposite(java.awt.Composite)
,
Graphics.setClip(int, int, int, int)
public abstract void drawGlyphVector(GlyphVector g, float x, float y)
GlyphVector
using
the Graphics2D
context's rendering attributes.
The rendering attributes applied include the Clip
,
Transform
, Paint
, and
Composite
attributes. The GlyphVector
specifies individual glyphs from a Font
.
The GlyphVector
can also contain the glyph positions.
This is the fastest way to render a set of characters to the
screen.g
- the GlyphVector
to be renderedx
- the x position in User Space where the glyphs should
be renderedy
- the y position in User Space where the glyphs should
be renderedNullPointerException
- if g
is null
.Font.createGlyphVector(java.awt.font.FontRenderContext, java.lang.String)
,
GlyphVector
,
setPaint(java.awt.Paint)
,
Graphics.setColor(java.awt.Color)
,
setTransform(java.awt.geom.AffineTransform)
,
setComposite(java.awt.Composite)
,
Graphics.setClip(int, int, int, int)
public abstract void fill(Shape s)
Shape
using the settings of the
Graphics2D
context. The rendering attributes applied
include the Clip
, Transform
,
Paint
, and Composite
.s
- the Shape
to be filledsetPaint(java.awt.Paint)
,
Graphics.setColor(java.awt.Color)
,
transform(java.awt.geom.AffineTransform)
,
setTransform(java.awt.geom.AffineTransform)
,
setComposite(java.awt.Composite)
,
clip(java.awt.Shape)
,
Graphics.setClip(int, int, int, int)
public abstract boolean hit(Rectangle rect, Shape s, boolean onStroke)
Shape
intersects
the specified Rectangle
, which is in device
space. If onStroke
is false, this method checks
whether or not the interior of the specified Shape
intersects the specified Rectangle
. If
onStroke
is true
, this method checks
whether or not the Stroke
of the specified
Shape
outline intersects the specified
Rectangle
.
The rendering attributes taken into account include the
Clip
, Transform
, and Stroke
attributes.rect
- the area in device space to check for a hits
- the Shape
to check for a hitonStroke
- flag used to choose between testing the
stroked or the filled shape. If the flag is true
, the
Stroke
outline is tested. If the flag is
false
, the filled Shape
is tested.true
if there is a hit; false
otherwise.setStroke(java.awt.Stroke)
,
fill(java.awt.Shape)
,
draw(java.awt.Shape)
,
transform(java.awt.geom.AffineTransform)
,
setTransform(java.awt.geom.AffineTransform)
,
clip(java.awt.Shape)
,
Graphics.setClip(int, int, int, int)
public abstract GraphicsConfiguration getDeviceConfiguration()
Graphics2D
.Graphics2D
.public abstract void setComposite(Composite comp)
Composite
for the Graphics2D
context.
The Composite
is used in all drawing methods such as
drawImage
, drawString
, draw
,
and fill
. It specifies how new pixels are to be combined
with the existing pixels on the graphics device during the rendering
process.
If this Graphics2D
context is drawing to a
Component
on the display screen and the
Composite
is a custom object rather than an
instance of the AlphaComposite
class, and if
there is a security manager, its checkPermission
method is called with an AWTPermission("readDisplayPixels")
permission.
comp
- the Composite
object to be used for renderingSecurityException
- if a custom Composite
object is being
used to render to the screen and a security manager
is set and its checkPermission
method
does not allow the operation.Graphics.setXORMode(java.awt.Color)
,
Graphics.setPaintMode()
,
getComposite()
,
AlphaComposite
,
SecurityManager.checkPermission(java.security.Permission)
,
AWTPermission
public abstract void setPaint(Paint paint)
Paint
attribute for the
Graphics2D
context. Calling this method
with a null
Paint
object does
not have any effect on the current Paint
attribute
of this Graphics2D
.paint
- the Paint
object to be used to generate
color during the rendering process, or null
Graphics.setColor(java.awt.Color)
,
getPaint()
,
GradientPaint
,
TexturePaint
public abstract void setStroke(Stroke s)
Stroke
for the Graphics2D
context.s
- the Stroke
object to be used to stroke a
Shape
during the rendering processBasicStroke
,
getStroke()
public abstract void setRenderingHint(RenderingHints.Key hintKey, Object hintValue)
RenderingHints
class for definitions of some common
keys and values.hintKey
- the key of the hint to be set.hintValue
- the value indicating preferences for the specified
hint category.getRenderingHint(RenderingHints.Key)
,
RenderingHints
public abstract Object getRenderingHint(RenderingHints.Key hintKey)
RenderingHints
class for definitions of some common
keys and values.hintKey
- the key corresponding to the hint to get.RenderingHints
class.RenderingHints
,
setRenderingHint(RenderingHints.Key, Object)
public abstract void setRenderingHints(Map<?,?> hints)
hints
.
The existing values for all rendering hints are discarded and
the new set of known hints and values are initialized from the
specified Map
object.
Hint categories include controls for rendering quality and
overall time/quality trade-off in the rendering process.
Refer to the RenderingHints
class for definitions of
some common keys and values.hints
- the rendering hints to be setgetRenderingHints()
,
RenderingHints
public abstract void addRenderingHints(Map<?,?> hints)
Map
object are modified.
All other preferences not present in the specified
object are left unmodified.
Hint categories include controls for rendering quality and
overall time/quality trade-off in the rendering process.
Refer to the RenderingHints
class for definitions of
some common keys and values.hints
- the rendering hints to be setRenderingHints
public abstract RenderingHints getRenderingHints()
RenderingHints
class for definitions of some common
keys and values.RenderingHints
that contains the current preferences.RenderingHints
,
setRenderingHints(Map)
public abstract void translate(int x, int y)
Graphics2D
context to the
point (x, y) in the current coordinate system.
Modifies the Graphics2D
context so that its new origin
corresponds to the point (x, y) in the
Graphics2D
context's former coordinate system. All
coordinates used in subsequent rendering operations on this graphics
context are relative to this new origin.public abstract void translate(double tx, double ty)
Graphics2D
Transform
with a translation transform.
Subsequent rendering is translated by the specified
distance relative to the previous position.
This is equivalent to calling transform(T), where T is an
AffineTransform
represented by the following matrix:
[ 1 0 tx ] [ 0 1 ty ] [ 0 0 1 ]
tx
- the distance to translate along the x-axisty
- the distance to translate along the y-axispublic abstract void rotate(double theta)
Graphics2D
Transform
with a rotation transform.
Subsequent rendering is rotated by the specified radians relative
to the previous origin.
This is equivalent to calling transform(R)
, where R is an
AffineTransform
represented by the following matrix:
[ cos(theta) -sin(theta) 0 ] [ sin(theta) cos(theta) 0 ] [ 0 0 1 ]Rotating with a positive angle theta rotates points on the positive x axis toward the positive y axis.
theta
- the angle of rotation in radianspublic abstract void rotate(double theta, double x, double y)
Graphics2D
Transform
with a translated rotation
transform. Subsequent rendering is transformed by a transform
which is constructed by translating to the specified location,
rotating by the specified radians, and translating back by the same
amount as the original translation. This is equivalent to the
following sequence of calls:
translate(x, y); rotate(theta); translate(-x, -y);Rotating with a positive angle theta rotates points on the positive x axis toward the positive y axis.
theta
- the angle of rotation in radiansx
- the x coordinate of the origin of the rotationy
- the y coordinate of the origin of the rotationpublic abstract void scale(double sx, double sy)
Graphics2D
Transform
with a scaling transformation
Subsequent rendering is resized according to the specified scaling
factors relative to the previous scaling.
This is equivalent to calling transform(S)
, where S is an
AffineTransform
represented by the following matrix:
[ sx 0 0 ] [ 0 sy 0 ] [ 0 0 1 ]
sx
- the amount by which X coordinates in subsequent
rendering operations are multiplied relative to previous
rendering operations.sy
- the amount by which Y coordinates in subsequent
rendering operations are multiplied relative to previous
rendering operations.public abstract void shear(double shx, double shy)
Graphics2D
Transform
with a shearing transform.
Subsequent renderings are sheared by the specified
multiplier relative to the previous position.
This is equivalent to calling transform(SH)
, where SH
is an AffineTransform
represented by the following
matrix:
[ 1 shx 0 ] [ shy 1 0 ] [ 0 0 1 ]
shx
- the multiplier by which coordinates are shifted in
the positive X axis direction as a function of their Y coordinateshy
- the multiplier by which coordinates are shifted in
the positive Y axis direction as a function of their X coordinatepublic abstract void transform(AffineTransform Tx)
AffineTransform
object with the
Transform
in this Graphics2D
according
to the rule last-specified-first-applied. If the current
Transform
is Cx, the result of composition
with Tx is a new Transform
Cx'. Cx' becomes the
current Transform
for this Graphics2D
.
Transforming a point p by the updated Transform
Cx' is
equivalent to first transforming p by Tx and then transforming
the result by the original Transform
Cx. In other
words, Cx'(p) = Cx(Tx(p)). A copy of the Tx is made, if necessary,
so further modifications to Tx do not affect rendering.Tx
- the AffineTransform
object to be composed with
the current Transform
setTransform(java.awt.geom.AffineTransform)
,
AffineTransform
public abstract void setTransform(AffineTransform Tx)
Graphics2D
context.
WARNING: This method should never be used to apply a new
coordinate transform on top of an existing transform because the
Graphics2D
might already have a transform that is
needed for other purposes, such as rendering Swing
components or applying a scaling transformation to adjust for the
resolution of a printer.
To add a coordinate transform, use the
transform
, rotate
, scale
,
or shear
methods. The setTransform
method is intended only for restoring the original
Graphics2D
transform after rendering, as shown in this
example:
// Get the current transform AffineTransform saveAT = g2.getTransform(); // Perform transformation g2d.transform(...); // Render g2d.draw(...); // Restore original transform g2d.setTransform(saveAT);
Tx
- the AffineTransform
that was retrieved
from the getTransform
methodtransform(java.awt.geom.AffineTransform)
,
getTransform()
,
AffineTransform
public abstract AffineTransform getTransform()
Transform
in the
Graphics2D
context.AffineTransform
in the
Graphics2D
context.transform(java.awt.geom.AffineTransform)
,
setTransform(java.awt.geom.AffineTransform)
public abstract Paint getPaint()
Paint
of the
Graphics2D
context.Graphics2D
Paint
,
which defines a color or pattern.setPaint(java.awt.Paint)
,
Graphics.setColor(java.awt.Color)
public abstract Composite getComposite()
Composite
in the
Graphics2D
context.Graphics2D
Composite
,
which defines a compositing style.setComposite(java.awt.Composite)
public abstract void setBackground(Color color)
Graphics2D
context.
The background color is used for clearing a region.
When a Graphics2D
is constructed for a
Component
, the background color is
inherited from the Component
. Setting the background color
in the Graphics2D
context only affects the subsequent
clearRect
calls and not the background color of the
Component
. To change the background
of the Component
, use appropriate methods of
the Component
.color
- the background color that is used in
subsequent calls to clearRect
getBackground()
,
Graphics.clearRect(int, int, int, int)
public abstract Color getBackground()
Graphics2D
Color
,
which defines the background color.setBackground(java.awt.Color)
public abstract Stroke getStroke()
Stroke
in the
Graphics2D
context.Graphics2D
Stroke
,
which defines the line style.setStroke(java.awt.Stroke)
public abstract void clip(Shape s)
Clip
with the interior of the
specified Shape
and sets the Clip
to the
resulting intersection. The specified Shape
is
transformed with the current Graphics2D
Transform
before being intersected with the current
Clip
. This method is used to make the current
Clip
smaller.
To make the Clip
larger, use setClip
.
The user clip modified by this method is independent of the
clipping associated with device bounds and visibility. If no clip has
previously been set, or if the clip has been cleared using
setClip
with a null
argument, the specified Shape
becomes the new
user clip.s
- the Shape
to be intersected with the current
Clip
. If s
is null
,
this method clears the current Clip
.public abstract FontRenderContext getFontRenderContext()
Font
within this
Graphics2D
context.
The FontRenderContext
encapsulates application hints such as anti-aliasing and
fractional metrics, as well as target device specific information
such as dots-per-inch. This information should be provided by the
application when using objects that perform typographical
formatting, such as Font
and
TextLayout
. This information should also be provided
by applications that perform their own layout and need accurate
measurements of various characteristics of glyphs such as advance
and line height when various rendering hints have been applied to
the text rendering.FontRenderContext
,
Font.createGlyphVector(java.awt.font.FontRenderContext, java.lang.String)
,
TextLayout
Submit a bug or feature
For further API reference and developer documentation, see Java SE Documentation. That documentation contains more detailed, developer-targeted descriptions, with conceptual overviews, definitions of terms, workarounds, and working code examples.
Copyright © 1993, 2014, Oracle and/or its affiliates. All rights reserved.