import java.util.*;
import java.util.zip.*;
import java.util.List;
import java.util.regex.*;
import java.util.concurrent.*;
import java.util.concurrent.atomic.*;
import java.util.concurrent.locks.*;
import java.util.function.*;
import javax.swing.*;
import javax.swing.event.*;
import javax.swing.text.*;
import javax.swing.table.*;
import java.io.*;
import java.net.*;
import java.lang.reflect.*;
import java.lang.ref.*;
import java.lang.management.*;
import java.security.*;
import java.security.spec.*;
import java.awt.*;
import java.awt.event.*;
import java.awt.image.*;
import java.awt.geom.*;
import javax.imageio.*;
import java.math.*;
import java.time.Duration;
import java.lang.invoke.VarHandle;
import java.lang.invoke.MethodHandles;
// undefined color, seems to be all black in practice
// This is without alpha?
import static x30_pkg.x30_util.DynamicObject;
import java.text.*;
import java.text.NumberFormat;
import java.util.TimeZone;
import java.awt.geom.*;
class main {
static BufferedImage newBufferedImage(int w, int h) {
return new BufferedImage(w, h, BufferedImage.TYPE_INT_RGB);
}
static BufferedImage newBufferedImage(int w, int h, Color color) {
BufferedImage img = newBufferedImage(w, h);
Graphics2D g = img.createGraphics();
g.setColor(or(color, Color.white));
g.fillRect(0, 0, w, h);
return img;
}
static BufferedImage newBufferedImage(Pt p, Color color) {
return newBufferedImage(p.x, p.y, color);
}
static BufferedImage newBufferedImage(WidthAndHeight size, Color color) {
return newBufferedImage(size.w(), size.h(), color);
}
// This one is with alpha...
static BufferedImage newBufferedImage(int w, int h, int[] pixels) {
return intArrayToBufferedImage(pixels, w, h);
}
static A or(A a, A b) {
return a != null ? a : b;
}
// from: https://stackoverflow.com/questions/14416107/int-array-to-bufferedimage
// pixels are RGB pixels
static BufferedImageWithMeta intArrayToBufferedImage(int[] pixels, int w) { return intArrayToBufferedImage(pixels, w, pixels.length/w); }
static BufferedImageWithMeta intArrayToBufferedImage(int[] pixels, int w, int h) {
if (w == 0 || h == 0) return null;
int[] bitMasks = new int[]{0xFF0000, 0xFF00, 0xFF, 0xFF000000};
SinglePixelPackedSampleModel sm = new SinglePixelPackedSampleModel(DataBuffer.TYPE_INT, w, h, bitMasks);
DataBufferInt db = new DataBufferInt(pixels, pixels.length);
WritableRaster wr = Raster.createWritableRaster(sm, db, new Point());
return new BufferedImageWithMeta(ColorModel.getRGBdefault(), wr, false, null);
}
static BufferedImageWithMeta intArrayToBufferedImage(int w, int... pixels) {
return intArrayToBufferedImage(pixels, w);
}
static class BufferedImageWithMeta extends BufferedImage implements IMeta {
BufferedImageWithMeta(ColorModel cm,
WritableRaster raster,
boolean isRasterPremultiplied,
Hashtable,?> properties) {
super(cm, raster, isRasterPremultiplied, properties);
}
// Meta - a "minimal" approach to adding meta-level to Java objects
// (implementing the interface IMeta)
// We allocate one extra field for each Java object to make it
// reasoning-compatible (reasoning-compatible = extensible with
// fields of any name at runtime).
//
// We couldn't go for 0 extra fields (meta values must be linked
// directly from the object) and there are no half fields in
// Java... so there you go.
//
// Also, if you don't use any meta data, you are probably not
// reasoning about anything. The point of reasoning in JavaX is
// to attach information to objects directly used in the program.
// Possible information contained in the meta field:
// Origin, destination, security level, sender, cost center,
// purpose, list of reifications, ...
// So here it is. THE FIELD YOU HAVE BEEN WAITING FOR!
// [We also have IMeta to retrofit foreign classes (rare but
// probably useful).]
//////////////////////
// The "meta" field //
//////////////////////
// Generic meta value of any kind, but the typical case is it's a
// Map with extra field values for the object etc.
// "meta" is volatile to avoid synchronization; but you can also synchronize on
// _tempMetaMutex() which is usually the object itself. Collections
// and maps are exempt from using the collections's monitor as the meta
// mutex because their monitor tends to be held for long operations
// (e.g. cloneList). For those we use a substantially more complex
// algorithm using a weakMap. Probably overkill. I may reconsider.
volatile Object meta;
// The meta field is not transient, thus by default it will be
// persisted like anything else unless you customize your object
// to suppress or modulate this.
// ...and the interface methods
public void _setMeta(Object meta) { this.meta = meta; }
public Object _getMeta() { return meta; }
// MOST functions are implemented in IMeta (default implementations)
// Scaffolding convenience functions
final boolean scaffolding(){ return scaffoldingEnabled(); }
boolean scaffoldingEnabled() { return main.scaffoldingEnabled(this); }
boolean scaffoldingEnabled(Object o) { return main.scaffoldingEnabled(o); }
}
static interface IMeta {
// see class "Meta" for the bla bla
public void _setMeta(Object meta);
public Object _getMeta();
default public IAutoCloseableF0 _tempMetaMutex() {
return new IAutoCloseableF0() {
public Object get() { return IMeta.this; }
public void close() {}
};
}
// actually query another object
default public Object getMeta(Object obj, Object key){ return metaGet(obj, key); }
default public Object metaGet(Object obj, Object key) {
// call global function
return metaMapGet(obj, key);
}
default public Object metaGet(String key, Object obj) {
// call global function
return metaMapGet(obj, key);
}
default public Object getMeta(Object key){ return metaGet(key); }
default public Object metaGet(Object key) {
if (key == null) return null;
Object meta = _getMeta();
if (meta instanceof Map) return ((Map) meta).get(key);
return null;
}
default public void metaSet(IMeta obj, Object key, Object value){ metaPut(obj, key, value); }
default public void metaPut(IMeta obj, Object key, Object value) {
// call global function
metaMapPut(obj, key, value);
}
default public void metaSet(Object key, Object value){ metaPut(key, value); }
default public void metaPut(Object key, Object value) {
if (key == null) return;
Map map = convertObjectMetaToMap(this);
syncMapPutOrRemove(map, key, value);
}
}
static interface IAutoCloseableF0 extends IF0, AutoCloseable {}
public static interface IF0 {
A get();
}
static Object metaGet(IMeta o, Object key) {
return metaMapGet(o, key);
}
static Object metaGet(Object o, Object key) {
return metaMapGet(o, key);
}
static Object metaGet(String key, IMeta o) {
return metaMapGet(o, key);
}
static Object metaGet(String key, Object o) {
return metaMapGet(o, key);
}
static Object metaMapGet(IMeta o, Object key) {
return o == null ? null : o.metaGet(key); // We now let the object itself do it (overridable!)
}
static Object metaMapGet(Object o, Object key) {
return metaMapGet(toIMeta(o), key);
}
static void metaPut(IMeta o, Object key, Object value) {
metaMapPut(o, key, value);
}
static void metaPut(Object o, Object key, Object value) {
metaMapPut(o, key, value);
}
static void metaMapPut(IMeta o, Object key, Object value) {
{ if (o != null) o.metaPut(key, value); }
}
static void metaMapPut(Object o, Object key, Object value) {
var meta = initIMeta(o);
{ if (meta != null) meta.metaPut(key, value); }
}
static Map convertObjectMetaToMap(IMeta o) { return convertObjectMetaToMap(o, () -> makeObjectMetaMap()); }
static Map convertObjectMetaToMap(IMeta o, IF0