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*
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* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
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package sun.java2d.loops;
import java.awt.AlphaComposite;
import java.util.HashMap;
/**
* A CompositeType object provides a chained description of a type of
* algorithm for color compositing. The object will provide a single
* String constant descriptor which is one way of describing a particular
* compositing algorithm as well as a pointer to another CompositeType
* which describes a more general algorithm for achieving the same result.
* <p>
* A description of a more specific algorithm is considered a "subtype"
* and a description of a more general algorithm is considered a "supertype".
* Thus, the deriveSubType method provides a way to create a new CompositeType
* that is related to but more specific than an existing CompositeType and
* the getSuperType method provides a way to ask a given CompositeType
* for a more general algorithm to achieve the same result.
* <p>
* Note that you cannot construct a brand new root for a chain since
* the constructor is private. Every chain of types must at some point
* derive from the Any node provided here using the deriveSubType()
* method. The presence of this common Any node on every chain
* ensures that all chains end with the DESC_ANY descriptor so that
* a suitable General GraphicsPrimitive object can be obtained for
* the indicated algorithm if all of the more specific searches fail.
*/
public final class CompositeType {
private static int unusedUID = 1;
private static final HashMap<String,Integer> compositeUIDMap =
new HashMap<String,Integer>(100);
/*
* CONSTANTS USED BY ALL PRIMITIVES TO DESCRIBE THE COMPOSITING
* ALGORITHMS THEY CAN PERFORM
*/
/**
* algorithm is a general algorithm that uses a CompositeContext
* to do the rendering.
*/
public static final String DESC_ANY = "Any CompositeContext";
/**
* constant used to describe the Graphics.setXORMode() algorithm
*/
public static final String DESC_XOR = "XOR mode";
/**
* constants used to describe the various AlphaComposite
* algorithms.
*/
public static final String DESC_CLEAR = "Porter-Duff Clear";
public static final String DESC_SRC = "Porter-Duff Src";
public static final String DESC_DST = "Porter-Duff Dst";
public static final String DESC_SRC_OVER = "Porter-Duff Src Over Dst";
public static final String DESC_DST_OVER = "Porter-Duff Dst Over Src";
public static final String DESC_SRC_IN = "Porter-Duff Src In Dst";
public static final String DESC_DST_IN = "Porter-Duff Dst In Src";
public static final String DESC_SRC_OUT = "Porter-Duff Src HeldOutBy Dst";
public static final String DESC_DST_OUT = "Porter-Duff Dst HeldOutBy Src";
public static final String DESC_SRC_ATOP = "Porter-Duff Src Atop Dst";
public static final String DESC_DST_ATOP = "Porter-Duff Dst Atop Src";
public static final String DESC_ALPHA_XOR = "Porter-Duff Xor";
/**
* constants used to describe the two common cases of
* AlphaComposite algorithms that are simpler if there
* is not extraAlpha.
*/
public static final String
DESC_SRC_NO_EA = "Porter-Duff Src, No Extra Alpha";
public static final String
DESC_SRC_OVER_NO_EA = "Porter-Duff SrcOverDst, No Extra Alpha";
/**
* constant used to describe an algorithm that implements all 8 of
* the Porter-Duff rules in one Primitive.
*/
public static final String DESC_ANY_ALPHA = "Any AlphaComposite Rule";
/*
* END OF COMPOSITE ALGORITHM TYPE CONSTANTS
*/
/**
* The root CompositeType object for all chains of algorithm descriptions.
*/
public static final CompositeType
Any = new CompositeType(null, DESC_ANY);
/*
* START OF CompositeeType OBJECTS FOR THE VARIOUS CONSTANTS
*/
public static final CompositeType
General = Any;
public static final CompositeType
AnyAlpha = General.deriveSubType(DESC_ANY_ALPHA);
public static final CompositeType
Xor = General.deriveSubType(DESC_XOR);
public static final CompositeType
Clear = AnyAlpha.deriveSubType(DESC_CLEAR);
public static final CompositeType
Src = AnyAlpha.deriveSubType(DESC_SRC);
public static final CompositeType
Dst = AnyAlpha.deriveSubType(DESC_DST);
public static final CompositeType
SrcOver = AnyAlpha.deriveSubType(DESC_SRC_OVER);
public static final CompositeType
DstOver = AnyAlpha.deriveSubType(DESC_DST_OVER);
public static final CompositeType
SrcIn = AnyAlpha.deriveSubType(DESC_SRC_IN);
public static final CompositeType
DstIn = AnyAlpha.deriveSubType(DESC_DST_IN);
public static final CompositeType
SrcOut = AnyAlpha.deriveSubType(DESC_SRC_OUT);
public static final CompositeType
DstOut = AnyAlpha.deriveSubType(DESC_DST_OUT);
public static final CompositeType
SrcAtop = AnyAlpha.deriveSubType(DESC_SRC_ATOP);
public static final CompositeType
DstAtop = AnyAlpha.deriveSubType(DESC_DST_ATOP);
public static final CompositeType
AlphaXor = AnyAlpha.deriveSubType(DESC_ALPHA_XOR);
public static final CompositeType
SrcNoEa = Src.deriveSubType(DESC_SRC_NO_EA);
public static final CompositeType
SrcOverNoEa = SrcOver.deriveSubType(DESC_SRC_OVER_NO_EA);
/*
* A special CompositeType for the case where we are filling in
* SrcOverNoEa mode with an opaque color. In that case then the
* best loop for us to use would be a SrcNoEa loop, but what if
* there is no such loop? In that case then we would end up
* backing off to a Src loop (which should still be fine) or an
* AnyAlpha loop which would be slower than a SrcOver loop in
* most cases.
* The fix is to use the following chain which looks for loops
* in the following order:
* SrcNoEa, Src, SrcOverNoEa, SrcOver, AnyAlpha
*/
public static final CompositeType
OpaqueSrcOverNoEa = SrcOverNoEa.deriveSubType(DESC_SRC)
.deriveSubType(DESC_SRC_NO_EA);
/*
* END OF CompositeType OBJECTS FOR THE VARIOUS CONSTANTS
*/
/**
* Return a new CompositeType object which uses this object as its
* more general "supertype" descriptor. If no operation can be
* found that implements the algorithm described more exactly
* by desc, then this object will define the more general
* compositing algorithm that can be used instead.
*/
public CompositeType deriveSubType(String desc) {
return new CompositeType(this, desc);
}
/**
* Return a CompositeType object for the specified AlphaComposite
* rule.
*/
public static CompositeType forAlphaComposite(AlphaComposite ac) {
switch (ac.getRule()) {
case AlphaComposite.CLEAR:
return Clear;
case AlphaComposite.SRC:
if (ac.getAlpha() >= 1.0f) {
return SrcNoEa;
} else {
return Src;
}
case AlphaComposite.DST:
return Dst;
case AlphaComposite.SRC_OVER:
if (ac.getAlpha() >= 1.0f) {
return SrcOverNoEa;
} else {
return SrcOver;
}
case AlphaComposite.DST_OVER:
return DstOver;
case AlphaComposite.SRC_IN:
return SrcIn;
case AlphaComposite.DST_IN:
return DstIn;
case AlphaComposite.SRC_OUT:
return SrcOut;
case AlphaComposite.DST_OUT:
return DstOut;
case AlphaComposite.SRC_ATOP:
return SrcAtop;
case AlphaComposite.DST_ATOP:
return DstAtop;
case AlphaComposite.XOR:
return AlphaXor;
default:
throw new InternalError("Unrecognized alpha rule");
}
}
private int uniqueID;
private String desc;
private CompositeType next;
private CompositeType(CompositeType parent, String desc) {
next = parent;
this.desc = desc;
this.uniqueID = makeUniqueID(desc);
}
public static synchronized int makeUniqueID(String desc) {
Integer i = compositeUIDMap.get(desc);
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