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Chapter    2

Rendering with Graphics2D

Graphics2D extends java.awt.Graphics to provide more sophisticated control over the presentation of shapes, text, and images. The Java 2D™ rendering process is controlled through the Graphics2D object and its state attributes.

The Graphics2D state attributes, such as line styles and transformations, are applied to graphic objects when they are rendered. The collection of state attributes associated with a Graphics2D is referred to as the Graphics2D context. To render text, shapes, or images, you set up the Graphics2D context and then call one of the Graphics2D rendering methods, such as draw or fill.

2.1 Interfaces and Classes

The following tables list the interfaces and classes used in conjunction with the Graphics2D context, including the classes that represent state attributes. Most of these classes are part of the java.awt package.

Interface
Description
Composite
Defines methods to compose a draw primitive with the underlying graphics area. Implemented by AlphaComposite.
CompositeContext
Defines the encapsulated and optimized environment for a composite operation. Used by programmers implementing custom compositing rules.
Paint
Extends: Transparency
Defines colors for a draw or fill operation. Implemented by Color, GradientPaint and TexturePaint.
PaintContext
Defines the encapsulated and optimized environment for a paint operation. Used by programmers implementing custom paint operations.
Stroke
Generates a Shape that encloses the outline of the Shape to be rendered. Implemented by BasicStroke.
Class
Description
AffineTransform
(java.awt.geom)
Represents a 2D affine transform, which performs a linear mapping from 2D coordinates to other 2D coordinates.
AlphaComposite
Implements: Composite
Implements basic alpha composite rules for shapes, text, and images.
BasicStroke
Implements: Stroke
Defines the “pen style” to be applied to the outline of a Shape.
Color
Implements: Paint
Defines a solid color fill for a Shape.
GradientPaint
Implements: Paint
Defines a linear color gradient fill pattern for a Shape. This fill pattern changes from color C1 at point P1 to color C2 at point P2.
Graphics2D
Extends: Graphics
Fundamental class for 2D rendering. Extends the original java.awt.Graphics class.
TexturePaint
Implements: Paint
Defines a texture or pattern fill for a Shape. The texture or pattern is generated from a BufferedImage.

2.2 Rendering Concepts

To render a graphic object using the Java 2D™ API, you set up the Graphics2D context and pass the graphic object to one of the Graphics2D rendering methods.

You can modify the state attributes that form the Graphics2D context to:

  • Vary the stroke width.
  • Change how strokes are joined together.
  • Set a clipping path to limit the area that is rendered.
  • Translate, rotate, scale, or shear objects when they are rendered.
  • Define colors and patterns to fill shapes with.
  • Specify how multiple graphics objects should be composed.

Graphics2D defines several methods for adding and changing attributes in the graphics context. Most of these methods take an object that represents a particular attribute, such as a Paint or Stroke object.

The Graphics2D context holds references to these attribute objects: they are not cloned. If you alter an attribute object that is part of the Graphics2D context, you need to call the appropriate set method to notify the context. Modifying an attribute object during a rendering operation will cause unpredictable and possibly unstable behavior.

2.2.1 Rendering Process

When a graphic object is rendered, the geometry, image, and attribute information are combined to calculate which pixel values must be changed on the display.

The rendering process for a Shape can be broken down into four steps:

  • If the Shape is to be stroked, the Stroke attribute in the Graphics2D context is used to generate a new Shape that encompasses the stroked path.
  • The coordinates of the Shape’s path are transformed from user space into device space according to the transform attribute in the Graphics2D context.
  • The Shape’s path is clipped using the clip attribute in the Graphics2D context.
  • The remaining Shape, if any, is filled using the Paint and Composite attributes in the Graphics2D context.

Rendering text is similar to rendering a Shape, since the text is rendered as individual glyphs and each glyph is a Shape. The only difference is that the Java 2D API must determine what Font to apply to the text and get the appropriate glyphs from the Font before rendering.

Images are handled differently, transformations and clipping operations are performed on the image’s bounding box. The color information is taken from the image itself and its alpha channel is used in conjunction with the current Composite attribute when the image pixels are composited onto the rendering surface.

2.2.2 Controlling Rendering Quality

The Java 2D API lets you indicate whether you want objects to be rendered as quickly as possible, or whether you prefer that the rendering quality be as high as possible. Your preferences are specified as hints through the RenderingHints attribute in the Graphics2D context. Not all platforms support modification of the rendering mode so specifying rendering hints does not guarantee that they will be used.

The RenderingHints class supports the following types of hints:

  • Alpha interpolation—can be set to default, quality, or speed.
  • Antialiasing—can be set to default, on, or off.
  • Color Rendering–can be set to default, quality, or speed.
  • Dithering—can be set to default, disable, or enable.
  • Fractional Metrics—can be set to default, on, or off.
  • Interpolation—can be set to nearest-neighbor, bilinear, or bicubic.
  • Rendering—can be set to default, quality, or speed.
  • Text antialiasing—can be set to default, on, or off.

To set or change the RenderingHints attribute in the Graphics2D context, you call setRenderingHints. When a hint is set to default, the platform rendering default is used is used.

Antialiasing

When graphics primitives are rendered on raster-graphics display devices, their edges can appear jagged because of aliasing. Arcs and diagonal lines take on a jagged appearance because they are approximated by turning on the pixels that are closest to the path of the line or curve. This is particularly noticeable on low-resolution devices, where the jagged edges appear in stark contrast to the smooth edges of horizontal or vertical lines.

Antialiasing is a technique used to render objects with smoother-appearing edges. Instead of simply turning on the pixel that is closest to the line or curve, the intensity of surrounding pixels is set in proportion to the amount of area covered by the geometry being rendered. This softens the edges and spreads the on-off transition over multiple pixels. However, antialiasing requires additional computing resources and can reduce rendering speed

.

This graphic shows examples of aliased and antialiased graphics as described in the previous context.

2.2.3 Stroke Attributes

Stroking a Shape such as a GeneralPath object is equivalent to running a logical pen along the segments of the GeneralPath. The Graphics2D Stroke attribute defines the characteristics of the mark drawn by the pen.

A BasicStroke object is used to define the stroke attributes for a Graphics2D context. BasicStroke defines characteristics such as the line width, endcap style, segment join-style, and the dashing pattern. To set or change the Stroke attribute in the Graphics2D context, you call setStroke.

This graphics shows endcap styles supported by BasicStroke including chopped, round and squared.

Figure 2-1 endcap styles supported by BasicStroke

This graphic shows join styles supported by BasicStroke including bevel, round and miter.

Figure 2-2 Join styles supported by BasicStroke

For example, the first image in Figure 2-3 uses the miter join-style; the second image uses a round join-style, a round endcap style, and a dashing pattern.

The previous context describes this graphic

Figure 2-3 Stroke Styles

The Graphics2D rendering methods that use the Stroke attribute are draw, drawArc, drawLine, drawOval, drawPolygon, drawPolyline, drawRect, and drawRoundRect.When one of these methods is called, the outline of the specified Shape is rendered. The Stroke attribute defines the line characteristics and the Paint attribute defines the color or pattern of the mark drawn by the pen.

For example, when draw(myRectangle) is called:

  • The Stroke is applied to the rectangle’s outline.
  • The stroked outline is converted to a Shape object.
  • The Paint is applied to the pixels that lie within the contour of the outline Shape.

This process is illustrated in Figure 2-4:

The previous context describes this graphic.

Figure 2-4 Stroking a Shape

2.2.4 Fill Attributes

The fill attribute in the Graphics2D context is represented by a Paint object. You add a Paint to the Graphics2D context by calling setPaint.

When a Shape or glyph is drawn (Graphics2D.draw, Graphics2D.drawString), the Paint is applied to all of the pixels that lie inside of the Shape that represents the object’s stroked outline. When a Shape is filled (Graphics2D.fill), the Paint is applied to all of the pixels that lie within the Shapes contour.

Simple solid color fills can be set with the setColor method. Color is the simplest implementation of the Paint interface.

To fill Shapes with more complex paint styles such as gradients and textures, you use the Java 2D Paint classes GradientPaint and TexturePaint. These classes eliminate the time-consuming task of creating complex fills using simple solid-color paints. Figure 2-5 illustrates two fills that could easily be defined by GradientPaint and TexturePaint.

The previous context describes this graphic.

Figure 2-5 Complex Fill Styles

When fill is called to render a Shape, the system:

  • Determines what pixels comprise the Shape.
  • Gets the color of each pixel from the Paint object.
  • Converts the color to an appropriate pixel value for the output device.
  • Writes the pixel to that device.
Batch Processing

To streamline the processing of pixels, the Java 2D API processes them in batches. A batch can be either a contiguous set of pixels on a given scanline or a block of pixels. This batch processing is done in two steps:

  • The Paint object’s createContext method is called to create a PaintContext. The PaintContext stores the contextual information about the current rendering operation and the information necessary to generate the colors. The createContext method is passed the bounding boxes of the graphics object being filled in user space and in device space, the ColorModel in which the colors should be generated, and the transform used to map user space into device space. The ColorModel is treated as a hint because not all Paint objects can support an arbitrary ColorModel. (For more information about ColorModels, see “Color” on page 89.”)
  • The getColorModel method is called to get the ColorModel of the generated paint color from the PaintContext.

The getRaster method is then called repeatedly to get the Raster that contains the actual color data for each batch. This information is passed to the next stage in the rendering pipeline, which draws the generated color using the current Composite object.

2.2.5 Clipping Paths

A clipping path identifies the portion of a Shape or Image that needs to be rendered. When a clipping path is part of the Graphics2D context, only those parts of a Shape or Image that lie within the path are rendered.

To add a clipping path to the Graphics2D context, you call setClip. Any Shape can be used to define the clipping path.

To change the clipping path, you can either use setClip to specify a new path or call clip to change the clipping path to the intersection of the old clipping path and a new Shape.

2.2.6 Transformations

The Graphics2D context contains a transform that is used to transform objects from user space to device space during rendering. To perform additional transformations, such as rotation or scaling, you can add other transforms to the Graphics2D context. These additional transforms become part of the pipeline of transformations applied during rendering.

Graphics2D provides several different ways to modify the transform in the Graphics2D context. The simplest is to call one of the Graphics2D transformation methods: rotate, scale, shear, or translate. You specify the characteristics of the transform that you want to be applied during rendering, and Graphics2D automatically makes the appropriate changes.

You can also explicitly concatenate an AffineTransform with the current Graphics2D transform. An AffineTransform performs a linear transformation such as translation, scaling, rotation, or shearing on a set of graphics primitives. When a transform is concatenated with an existing transform, the last transform specified is the first to be applied. To concatenate a transform with the current transform, you pass an AffineTransform to Graphics2D.transform.

The Graphics2D class also contains a setTransform method, but this method should never be used to concatenate another coordinate transform onto of an existing transform. The setTransform method overwrites the Graphics2D object’s current transform, which is needed for other purposes, such as:

  • Applying a scaling transform to adjust for printer resolution.
  • Painting a JComponent at non-zero translation from its parent’s origin
  • Scaling up a component for easier viewing.
  • Any other situation in which the supplier of a Graphics2D object might want to transform the rendering for effect .

The setTransform method is intended for setting the Graphics2D object back to the original transform after rendering the transformed graphics, text or images:

AffineTransform aT = g2d.getTransform(); 
g2d.transform(...);g2d.draw(...); 
g2d.setTransform(aT); 

Graphics2D also provides a version of drawImage that takes an AffineTransform as a parameter. This enables you to apply a transformation to an image object when it is drawn without permanently modifying the transformation pipeline. The image is drawn as if you had concatenated the transform with the current transform in the Graphics2D context.

Affine Transforms

The Java 2D API provides one transform class, AffineTransform. AffineTransforms are used to transform text, shapes, and images when they are rendered. You can also apply transforms to Font objects to create new font derivations, as discussed in “Creating Font Derivations” on page 65.

An affine transformation performs a linear transformation on a set of graphics primitives. It always transforms straight lines into straight lines and parallel lines into parallel lines; however, the distance between points and the angles between nonparallel lines might be altered.

Affine transformations are based on two-dimensional matrices of the following form:

 

A 2 by 3 matrix with the top row containing a, c and t sub x. The second row contains b, d and t sub y. where x prime equals a x plus c y plus t sub x and y prime equals b x plus d y plus t sub y

 

Transforms can be combined, effectively creating a series or pipeline of transformations that can be applied to an object. This combination is referred to as concatenation. When a transform is concatenated with an existing transform, such as with AffineTransform.concatenate, the last transform specified is the first to be applied. A transform can also be pre-concatenated with an existing transform. In this case, the last transform specified is the last to be applied.

Pre-concatenation is used to perform transformations relative to device space instead of user space. For example, you could use AffineTransform.preConcatenate to perform a translation relative to absolute pixel space.

2.2.6.1 Constructing an AffineTransform

AffineTransform provides a set of convenience methods for constructing AffineTransform objects:

  • getTranslateInstance
  • getRotateInstance
  • getScaleInstance
  • getShearInstance

To use these methods, you specify the characteristics of the transform you want to create and AffineTransform generates the appropriate transform matrix. You can also construct an AffineTransform by directly specifying the elements of the transformation matrix.

2.2.7 Composite Attributes

When two graphic objects overlap, it is necessary to determine what colors to render the overlapping pixels. For example, if a red rectangle and a blue rectangle overlap, the pixels that they share could be rendered red, blue, or some combination of the two. The color of the pixels in the overlapping area will determine which rectangle appears to be on top and how transparent it looks. The process of determining what color to render pixels shared by overlapping objects is called compositing.

Two interfaces form the basis of the Java 2D compositing model: Composite and CompositeContext.

To specify the compositing style that should be used, you add an AlphaComposite object to the Graphics2D context by calling setComposite. AlphaComposite, an implementation of the Composite interface, supports a number of different compositing styles. Instances of this class embody a compositing rule that describes how to blend a new color with an existing one.

One of the most commonly used compositing rules in the AlphaComposite class is SRC_OVER, which indicates that the new color (the source color) should be blended over the existing color (the destination color).

AlphaComposite Composition Rule
Description
Example
CLEAR
Clear
 
DEST_IN
Destination In
 
DEST_OUT
Destination Out
 
DEST_OVER
Destination Over
 
SRC
Source
 
SRC_IN
Source In
 
SRC_OUT
Source Out
 
SRC_OVER
Source Over
 

2.2.7.1 Managing Transparency

A color’s alpha value is a measure of its transparency: it indicates, as a percentage, how much of a previously rendered color should show through when colors overlap. Opaque colors (alpha=1.0) don’t allow any of the underlying color to show through, while transparent colors (alpha=0.0) let all of it show through.

When text and Shapes are rendered, the alpha value is derived from the Paint attribute in the Graphics2D context. When Shapes and text are antialiased, the alpha value from the Paint in the Graphics2D context is combined with pixel coverage information from the rasterized path. Images maintain their own alpha information—see “Transparency and Images” on page 26 for more information.

When you construct an AlphaComposite object, you can specify an additional alpha value. When you add this AlphaComposite object to the Graphics2D context, this extra alpha value increases the transparency of any graphic objects that are rendered—the alpha value of each graphic object is multiplied by the AlphaComposite’s alpha value.

2.2.7.2 Transparency and Images

Images can carry transparency information for each pixel in the image. This information, called an alpha channel, is used in conjunction with the Composite object in the Graphics2D context to blend the image with existing drawings.

For example, Figure 2-6 contains three images with different transparency information. In each case, the image is displayed over a blue rectangle. This example assumes that the Graphics2D context contains an AlphaComposite object that uses SRC_OVER as the compositing operation.

The following context describes this graphic.

Figure 2-6 Transparency and Images

In the first image, all of the pixels are either fully opaque (the dog’s body) or fully transparent (the background). This effect is often used on Web pages. In the second image, all of the pixels in the dog’s body are rendered using a uniform, non-opaque alpha value, allowing the blue background to show through. In the third image, the pixels around the dogs face are fully opaque (alpha=1.0), but as the distance from its face increases, the alpha values for the pixels decrease.

2.3 Setting Up the Graphics2D Context

To configure the Graphics2D context for rendering, you use the Graphics2D set methods to specify attributes such as the RenderingHints, Stroke, Paint, clipping path, Composite, and Transform.

2.3.1 Setting Rendering Hints

A RenderingHints object encapsulates all of your preferences concerning how an object is rendered. To set the rendering hints in the Graphics2D context, you create a RenderingHints object and pass it into Graphics2D.setRenderingHints.

Setting a rendering hint does not guarantee that a particular rendering algorithm will be used: not all platforms support modification of the rendering mode.

In the following example, antialiasing is enabled and the rendering preference is set to quality:

qualityHints = new               RenderingHints(RenderingHints.KEY_ANTIALIASING,               RenderingHints.VALUE_ANTIALIAS_ON); 
qualityHints.put(RenderingHints.KEY_RENDERING,               RenderingHints.VALUE_RENDER_QUALITY); 
g2.setRenderingHints(qualityHints); 

2.3.2 Specifying Stroke Attributes

A BasicStroke defines the characteristics applied to a Shape’s outline, including its width and dashing pattern, how line segments are joined together, and the decoration (if any) applied to the end of a line. To set the stroke attributes in the Graphics2D context, you create a BasicStroke object and pass it into setStroke.

2.3.2.1 Setting the Stroke Width

To set the stroke width, you create a BasicStroke object with the desired width and call setStroke.

In the following example, the stroke width is set to twelve points and the defaults are used for the join and endcap decorations:

wideStroke = new BasicStroke(12.0f); 
g2.setStroke(wideStroke); 

2.3.2.2 Specifying Join and Endcap Styles

To set the join and endcap styles, you create a BasicStroke object with the desired attributes.

In the following example, the stroke width is set to twelve points and the round join and endcap styles are used instead of the defaults:

roundStroke = new BasicStroke(4.0f, BasicStroke.CAP_ROUND,              BasicStroke.JOIN_ROUND); 
g2.setStroke(roundStroke); 

2.3.2.3 Setting the Dashing Pattern

Complex dashing patterns can easily be defined with a BasicStroke object. When you create a BasicStroke object, you can specify two parameters that control the dashing pattern:

  • dash—an array that represents the dashing pattern. Alternating elements in the array represent the dash size and the size of the space between dashes. Element 0 represents the first dash, element 1 represents the first space.
  • dash_phase—an offset that defines where the dashing pattern starts.

In the following example, two different dashing patterns are applied to a line. In the first, the size of the dashes and the space between them is constant. The second dashing pattern is more complex, using a six-element array to define the dashing pattern.

float dash1[] = {10.0f}; 
BasicStroke bs = new BasicStroke(5.0f, BasicStroke.CAP_BUTT,  
                 BasicStroke.JOIN_MITER, 10.0f, dash1, 0.0f); 
g2.setStroke(bs); 
Line2D line = new Line2D.Float(20.0f, 10.0f, 100.0f, 10.0f); 
g2.draw(line); 
 
float[] dash2 = {6.0f, 4.0f, 2.0f, 4.0f, 2.0f, 4.0f}; 
bs = new BasicStroke(5.0f, BasicStroke.CAP_BUTT,  
     BasicStroke.JOIN_MITER, 10.0f, dash2, 0.0f); 
g2.setStroke(bs); 
g2.draw(line); 

Both dashing patterns use a dash phase of zero, causing the dashes to be drawn starting at the beginning of the dashing pattern. The two dashing patterns are shown in Figure Figure 2-7

.

The previous context describes this graphic.

Figure 2-7 Dashing Patterns

2.3.3 Specifying Fill Attributes

The Paint attribute in the Graphics2D context determines the fill color or pattern that is used when text and Shapes are rendered.

2.3.3.1 Filling a Shape with a Gradient

The GradientPaint class provides an easy way to fill a shape with a gradient of one color to another. When you create a GradientPaint, you specify a beginning position and color, and an ending position and color. The fill color changes proportionally from one color to the other along the line connecting the two positions, as shown in Figure 2-8.

The previous context describes this graphic.

Figure 2-8 Creating Gradient Fills

In the third star in Figure 2-8, both points lie within the shape. All of the points along the gradient line extending beyond P1 take the beginning color, and the points along the gradient line extending beyond P2 take the ending color.

To fill a shape with a gradient of one color to another:

  • Create a GradientPaint object.
  • Call Graphics2D.setPaint.
  • Create the Shape.
  • Call Graphics2D.fill(shape).

In the following example, a rectangle is filled with a blue-green gradient.

GradientPaint gp = new GradientPaint(50.0f, 50.0f, Color.blue 
                   50.0f, 250.0f, Color.green); 
g2.setPaint(gp); 
g2.fillRect(50, 50, 200, 200); 

2.3.3.2 Filling a Shape with a Texture

The TexturePaint class provides an easy way to fill a shape with a repeating pattern. When you create a TexturePaint, you specify a BufferedImage to use as the pattern. You also pass the constructor a rectangle to define the repetition frequency of the pattern, as shown in Figure 2-9.

The previous context describes this graphic.

Figure 2-9 Creating Texture Paints

To fill a shape with a texture:

  • Create a TexturePaint object.
  • Call Graphics2D.setPaint.
  • Create the Shape.
  • Call Graphics2D.fill(shape).

In the following example, a rectangle is filled with a simple texture created from a buffered image.

// Create a buffered image texture patch of size 5x5 
BufferedImage bi = new BufferedImage(5, 5,    
                       BufferedImage.TYPE_INT_RGB); 
Graphics2D big = bi.createGraphics(); 
// Render into the BufferedImage graphics to create the texture 
big.setColor(Color.green); 
big.fillRect(0,0,5,5); 
big.setColor(Color.lightGray); 
big.fillOval(0,0,5,5); 
 
// Create a texture paint from the buffered image 
Rectangle r = new Rectangle(0,0,5,5); 
TexturePaint tp = new TexturePaint(bi,r,TexturePaint.NEAREST_NEIGHBOR); 
 
// Add the texture paint to the graphics context. 
g2.setPaint(tp); 
 
// Create and render a rectangle filled with the texture. 
g2.fillRect(0,0,200,200); 
} 

2.3.4 Setting the Clipping Path

To define a clipping path:

  • Create a Shape that represents the area you want to render.
  • Call Graphics2D.setClip to use the shape as the clipping path for the Graphics2D context.

To shrink the clipping path:

  • Create a Shape that intersects the current clipping path.
  • Call clip to change the clipping path to the intersection of the current clipping path and the new Shape.

In the following example, a clipping path is created from an ellipse and then modified by calling clip.

public void paint(Graphics g) { 
  Graphics2D g2 = (Graphics2D) g; 
 
// The width and height of the canvas 
  int w = getSize().width; 
  int h = getSize().height; 
  // Create an ellipse and use it as the clipping path 
  Ellipse2D e = new Ellipse2D.Float(w/4.0f,h/4.0f, 
                                    w/2.0f,h/2.0f); 
  g2.setClip(e); 
 
  // Fill the canvas. Only the area within the clip is rendered 
  g2.setColor(Color.cyan); 
  g2.fillRect(0,0,w,h); 
 
  // Change the clipping path, setting it to the intersection of  
  // the current clip and a new rectangle. 
  Rectangle r = new Rectangle(w/4+10,h/4+10,w/2-20,h/2-20); 
  g2.clip(r); 
 
  // Fill the canvas. Only the area within the new clip  
  // is rendered 
  g2.setColor(Color.magenta); 
  g2.fillRect(0,0,w,h); 
} 

2.3.5 Setting the Graphics2D Transform

To transform a Shape, text string, or Image you add a new AffineTransform to the transformation pipeline in the Graphics2D context before rendering. The transformation is applied when the graphic object is rendered.

For example, to draw a rectangle that is rotated 45 degrees:

  • Get the current Graphics2D transform before performing any transformations. Always call getTransform on the Graphics2D before adding a transform to the graphics context because the graphics context might already have a transform that is needed for other reasons, such as positioning Swing and lightweight components within a window.
  • Get a rotation transform by calling AffineTransform. getRotateInstance.
  • Call Graphics2D.transform to add the new transform to the transformation pipeline. Never use the setTransform method to add a new coordinate transform because setTransform will overwrite the current transform in the graphics context.
  • Create a Rectangle2D.Float object.
  • Call Graphics2D.draw to render the rectangle.
  • After you have rendered your transformed rectangle, reset the transform of the Graphics2D back to the original transform that you saved in Step 1 by calling setTransform with the original transform.

In the following example, an instance of AffineTransform is used to rotate a rectangle 45 degrees when it is rendered.

AffineTransform aT = g2.getTransform();Rectangle2D rect = new Rectangle2D.Float(1.0,1.0,2.0,3.0); 
AffineTransform rotate45 =    
  AffineTransform.getRotateInstance(Math.PI/4.0,0.0,0.0) 
g2.transform(rotate45); 
g2.draw(rect);g2.setTransform(aT); 

In this example, an AffineTransform is used to rotate a text string around a center point:

// Define the rendering transform 
AffineTransform at = new AffineTransform(); 
// Apply a translation transform to make room for the 
// rotated text. 
at.setToTranslation(400.0, 400.0); 
g2.transform(at); 
// Create a rotation transform to rotate the text 
at.setToRotation(Math.PI / 2.0); 
// Render four copies of the string “Java” at 90 degree angles 
for (int i = 0; i < 4; i++) { 
    g2.drawString(“Java”, 0.0f, 0.0f); 
    g2.transform(at); 
} 

You can transform an image in the same way—the transform in the Graphics2D context is applied during rendering regardless of the type of graphic object being rendered.

To apply a transform to an image without changing the transform in the Graphics2D context, you can pass an AffineTransform to drawImage:

AffineTransform rotate45 =    
  AffineTransform.getRotateInstance(Math.PI/4.0,0.0,0.0) 
g2.drawImage(myImage, rotate45); 

Transforms can also be applied to a Font to create a modified version of the Font, for more information see “Creating Font Derivations” on page 65.

2.3.6 Specifying a Composition Style

An AlphaComposite encapsulates composition rules that determine how colors should be rendered when one object overlaps another. To specify the composition style for the Graphics2D context, you create an AlphaComposite and pass it into setComposite. The most commonly used is composition style is SRC_OVER.

2.3.6.1 Using the Source Over Compositing Rule

The SRC_OVER compositing rule composites the source pixel over the destination pixel such that the shared pixel takes the color of the source pixel. For example, if you render a blue rectangle and then render a red rectangle that partially overlaps it, the overlapping area will be red. In other words, the object that is rendered last will appear to be on top.

To use the SRC_OVER composition rule:

  • Create an AlphaComposite object by calling getInstance and specifying the SRC_OVER rule.
AlphaComposite ac = AlphaComposite.getInstance(AlphaComposite.SRC_OVER); 
  • Call setComposite to add the AlphaComposite object to the Graphics2D context.

    g2.setComposite(ac);

Once the composite object is set, overlapping objects will be rendered using the specified composition rule.

2.3.6.2 Increasing the Transparency of Composited Objects

AlphaComposite allows you to specify an additional constant alpha value that is multiplied with the alpha of the source pixels to increase transparency.

For example, to create an AlphaComposite object that renders the source object 50% transparent, specify an alpha of .5:

AlphaComposite ac = AlphaComposite.getInstance(AlphaComposite.SRC_OVER, .5f); 

In the following example, a source over alpha composite object is created with an alpha of .5 and added to the graphics context, causing subsequent shapes to be rendered 50% transparent.

public void paint(Graphics g) { 
  Graphics2D g2 = (Graphics2D) g; 
 
  g2.setColor(Color.red); 
  g2.translate(100,50); 
  // radians=degree * pie / 180 
  g2.rotate((45*java.lang.Math.PI)/180);  
  g2.fillRect(0,0,100,100); 
  g2.setTransform(new AffineTransform());  // set to identity 
  // Create a new alpha composite 
  AlphaComposite ac = 
      AlphaComposite.getInstance(AlphaComposite.SRC_OVER,0.5f); 
  g2.setComposite(ac); 
  g2.setColor(Color.green); 
  g2.fillRect(50,0,100,100); 
  g2.setColor(Color.blue); 
  g2.fillRect(125,75,100,100); 
  g2.setColor(Color.yellow); 
  g2.fillRect(50,125,100,100); 
  g2.setColor(Color.pink); 
  g2.fillRect(-25,75,100,100); 
} 

2.4 Rendering Graphics Primitives

Graphics2D provides rendering methods for Shapes, Text, and Images:

  • draw—strokes a Shape’s path using the Stroke and Paint objects in the Graphics2D context.
  • fill—fills a Shape using the Paint in the Graphics2D context.
  • drawString—renders the specified text string using the Paint in the Graphics2D context.
  • drawImage—renders the specified image.

To stroke and fill a shape, you must call both the draw and fill methods.

Graphics2D also supports the draw and fill methods from previous versions of the JDK software, such as drawOval and fillRect.

2.4.1 Drawing a Shape

The outline of any Shape can be rendered with the Graphics2D.draw method. The draw methods from previous versions of the JDK software are also supported: drawLine, drawRect, drawRoundRect, drawOval, drawArc, drawPolyline, drawPolygon, draw3DRect.

When a Shape is drawn, its path is stroked with the Stroke object in the Graphics2D context. (See “Stroke Attributes” on page 19 for more information.) By setting an appropriate BasicStroke object in the Graphics2D context, you can draw lines of any width or pattern. The BasicStroke object also defines the line’s endcap and join attributes.

To render shape’s outline:

  • Create a BasicStroke object
  • Call Graphics2D.setStroke
  • Create the Shape.
  • Call Graphics2D.draw(shape).

In the following example, a GeneralPath object is used to define a star and a BasicStroke object is added to the Graphics2D context to define the star’s line with and join attributes.

public void paint(Graphics g) { 
  Graphics2D g2 = (Graphics2D) g; 
 
  // create and set the stroke 
  g2.setStroke(new BasicStroke(4.0f)); 
 
  // Create a star using a general path object 
  GeneralPath p = new GeneralPath(GeneralPath.NON_ZERO); 
  p.moveTo(- 100.0f, - 25.0f); 
  p.lineTo(+ 100.0f, - 25.0f); 
  p.lineTo(- 50.0f, + 100.0f); 
  p.lineTo(+ 0.0f, - 100.0f); 
  p.lineTo(+ 50.0f, + 100.0f); 
  p.closePath(); 
 
  // translate origin towards center of canvas 
  g2.translate(100.0f, 100.0f); 
   
  // render the star's path 
  g2.draw(p); 
} 

2.4.2 Filling a Shape

The Graphics2D.fill method can be used to fill any Shape. When a Shape is filled, the area within its path is rendered with the Graphics2D context’s current Paint attribute—a Color, TexturePaint, or GradientPaint.

The fill methods from previous versions of the JDK software are also supported: fillRect, fill3DRect, fillRoundRect, fillOval, fillArc, fillPolygon, clearRect.

To fill a Shape:

  • Set the fill color or pattern on the graphics context using
    Graphics2D.setColor or Graphics2D.setPaint.
  • Create the Shape.
  • Call Graphics2D.fill to render the Shape.

In the following example, setColor is called to define a green fill for a Rectangle2D.

public void paint(Graphics g) { 
  Graphics2D g2 = (Graphics2D) g; 
 
  g2.setPaint(Color.green); 
  Rectangle2D r2 = new Rectangle2D.Float(25,25,150,150); 
 
   g2.fill(r2); 
} 

2.4.3 Rendering Text

To render a text string, you call Graphics2D.drawString, passing in the string that you want to render. For more information about rendering text and selecting fonts, see “Fonts and Text Layout” on page 45.

2.4.4 Rendering Images

To render an Image, you create the Image and call Graphics2D.drawImage. For more information about processing and rendering images, see “Imaging” on page 67.

2.5 Defining Custom Composition Rules

You can create an entirely new type of compositing operation by implementing the Composite and CompositeContext interfaces. A Composite object provides a CompositeContext object that actually holds the state and performs the compositing work. Multiple CompositeContext objects can be created from one Composite object to maintain the separate states in a multithreaded environment.

2.6 Rendering in a Multi-Screen Environment

With the release of the JavaTM 2 SDK, version 1.3 and later versions, the Java 2DTM API supports three different multi-screen configurations that can possibly be configured by a native platform:

  • Two or more independent screens
  • Two or more screens where one screen is the primary screen and the other screens display copies of what appears on the primary screen.
  • Two or more screens that form a virtual desktop, which is also called a virtual device.

The Java 2D API enables you to create Frame, JFrame, Window, or JWindow objects with a GraphicsConfiguration to target a screen device for rendering.

In all three configurations, each screen device is represented by a GraphicsDevice. A GraphicsDevice can have multiple GraphicsConfiguration objects associated with it.

When two or more screens are used to form a virtual device, a virtual coordinate system that exists outside of the physical screens is used to represent the virtual device. The bounds of each GraphicsConfiguration in this multi-screen configuration are relative to the virtual coordinate system. One screen in this environment is identified as the primary screen, which is located at (0, 0) in the virtual coordinate system. Depending on the location of the primary screen, the virtual device might have negative coordinates, as shown in Figure 2-10:

example of a virtual device environment

Figure 2-10 Example of a virtual device environment

To determine if your environment is a virtual device environment in which a Window or a Frame can span two or more physical screens, call getBounds on each GraphicsConfiguration in your system and check to see if the origin is something other than (0, 0). The getBounds method of a GraphicsConfiguration returns a Rectangle in the virtual coordinate system. So, if any of the origins are not (0, 0), your environment is a virtual device environment.

In a virtual device environment, the coordinates of the GraphicsConfiguration objects are relative to the virtual coordinate system. So, you must use virtual coordinates when calling the setLocation method of a Frame or Window. For example, this code sample gets the bounds of a GraphicsConfiguration and uses the bounds to set the location of a Frame at (10, 10) relative to the origin of the physical screen of the corresponding GraphicsConfiguration.

Frame f = new Frame(GraphicsConfiguration gc); 
Rectangle bounds = gc.getBounds(); 
f.setLocation(10 + bounds.x, 10 + bounds.y); 
 

If the bounds of the GraphicsConfiguration are not taken into account, the Frame is displayed at (10, 10) on the primary physical screen, which might be different from the physical screen of the specified GraphicsConfiguration.

The getBounds method can also be used to determine the bounds of the virtual device. Call getBounds on each GraphicsConfiguration in your system. To determine the bounds of the virtual device, calculate the union of all the bounds. This technique is used in the following sample.

Rectangle virtualBounds = new Rectangle(); 
GraphicsEnvironment ge = 
   GraphicsEnvironment.getLocalGraphicsEnvironment(); 
GraphicsDevice[] gs = ge.getScreenDevices(); 
for (int j = 0; j < gs.length; j++) { 
   GraphicsDevice gd = gs[j]; 
   GraphicsConfiguration[] gc = gd.getConfigurations(); 
   for (int i = 0; i < gc.length; i++) { 
      virtualBounds = virtualBounds.union(gc[i].getBounds()); 
   } 
} 
 

The following applet creates a JFrame with every GraphicsConfiguration of every GraphicsDevice in the GraphicsEnvironment. Each JFrame displays a set of red, green and blue stripes, the screen number, the GraphicsConfiguration number and the bounds of the GraphicsConfiguration. This code sample must be run with the JavaTM 2 SDK, version 1.3 or later.

 
import java.applet.Applet; 
import java.awt.*; 
import javax.swing.*; 
 
public class MultiFrameApplet extends Applet { 
     
    public MultiFrameApplet() { 
        main(null); 
    } 
 
    public static void main(String[] argv) { 
        GraphicsEnvironment ge =  
           GraphicsEnvironment.getLocalGraphicsEnvironment(); 
        GraphicsDevice[] gs = ge.getScreenDevices(); 
        for (int j = 0; j < gs.length; j++) { 
          GraphicsDevice gd = gs[j]; 
          GraphicsConfiguration[] gc =  
             gd.getConfigurations(); 
             for (int i=0; i < gc.length; i++) { 
               JFrame f =  
                  new JFrame(gs[j].getDefaultConfiguration()); 
               GCCanvas c = new GCCanvas(gc[i]); 
               Rectangle gcBounds = gc[i].getBounds(); 
               int xoffs = gcBounds.x; 
               int yoffs = gcBounds.y; 
               f.getContentPane().add(c); 
               f.setTitle("Screen# "+Integer.toString(j)+",  
                  GC# "+Integer.toString(i)); 
               f.setSize(300, 150); 
               f.setLocation((i*50)+xoffs, (i*60)+yoffs); 
               f.show(); 
             } 
        } 
    } 
} 
 
class GCCanvas extends Canvas { 
 
    GraphicsConfiguration gc; 
    Rectangle bounds; 
 
    public GCCanvas(GraphicsConfiguration gc) { 
        super(gc); 
        this.gc = gc; 
        bounds = gc.getBounds(); 
    } 
 
    public Dimension getPreferredSize() { 
        return new Dimension(300, 150); 
    } 
 
    public void paint(Graphics g) { 
        g.setColor(Color.red); 
        g.fillRect(0, 0, 100, 150); 
        g.setColor(Color.green); 
        g.fillRect(100, 0, 100, 150); 
        g.setColor(Color.blue); 
        g.fillRect(200, 0, 100, 150); 
        g.setColor(Color.black); 
        g.drawString("ScreenSize="+ 
           Integer.toString(bounds.width)+ 
           "X"+ Integer.toString(bounds.height), 10, 15); 
        g.drawString(gc.toString(), 10, 30); 
    } 
} 
 

 


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