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;
import java.text.NumberFormat;
import java.awt.geom.*;
import static x30_pkg.x30_util.DynamicObject;
import java.nio.charset.Charset;
import java.text.*;
import java.util.TimeZone;

class main {

static class TickerSequences implements ByteIO, IntSize, Iterable<TickerSequence>  {
  TickerSequences() {}
   final public String getMarket(){ return market(); }
public String market() { return market; }
 String market; // e.g. "TRBUSDT"
  
   final public List<TickerSequence> getTickers(){ return tickers(); }
public List<TickerSequence> tickers() { return tickers; }
 List<TickerSequence> tickers = new ArrayList();
  
  TickerSequences(Iterable<TickerSequence> sequences) {
    main.addAll(tickers, sequences);
  }
  
  TickerSequences(TickerSequence... sequences) {
    main.addAll(tickers, sequences);
  }
  
  void add(TickerSequence ticker) {
    tickers.add(ticker);
  }
  
  TickerSequence get(int i) { return tickers.get(i); }
  
  void sort() {
    sortInPlaceByCalculatedField(tickers, __1 -> __1.startTime());
  }
  
  public int size() { return tickers.size(); }
  
  public String toString() {
    return commaCombine(
      spaceCombine(
        n2(tickers, " ticker sequence"),
        empty(market) ? null : "for " + market),
      formatDays(totalTime()),
      n2(nPricePoints(), "price point")
    );
  }
  
  long nPricePoints() {
    return longSum(map(tickers, t -> (long) t.size()));
  }
  
  long totalTime() {
    return longSum(map(tickers, ticker -> { var tr = ticker.timeRange(); return tr == null ? 0 : tr.length(); }));
  }
  
  TickerSequences dropOverlaps() {
    sort();
    
    for (int i = 0; i+1 < l(tickers); i++) {
      var t1 = tickers.get(i);
      var t2 = tickers.get(i+1);
      long time2 = t2.startTime();
      while (!t1.isEmpty() && t1.endTime() >= time2)
        t1.dropLastPricePoint();
      t1.trimToSize();
    }
    
    return this;
  }
  
  TickerSequences merge() { return merge(120); }
TickerSequences merge(double maximumGapSeconds) {
    sort();
    
    for (int i = 0; i+1 < l(tickers); i++) {
      var t1 = tickers.get(i);
      var t2 = tickers.get(i+1);
      if (t2.startTime()-t1.endTime() <= fromSeconds(maximumGapSeconds)) {
        t1.add(t2);
        tickers.remove(i+1);
        --i;
      }
    }
    
    return this;
  }
  
  double firstPrice() {
    var ticker = first(tickers);
    return ticker == null ? Double.NaN : ticker.firstPrice();
  }
  
  IterableIterator<Double> prices() {
    return nestedIterator(tickers, ticker -> ticker.prices.iterator());
  }
  
    
  long startTime() { return empty(tickers) ? null : first(tickers).startTime(); }
  long endTime() { return empty(tickers) ? null : last(tickers).endTime(); }
  
  TickerSequence longest() {
    return highestBy(tickers(), ticker -> duration(ticker.timeRange()));
  }
  
  TickerSequences mapTickers(IF1<TickerSequence, TickerSequence> f) {
    TickerSequences ts = new TickerSequences();
    for (var t : tickers())
      ts.add(f.get(t));
    return ts;
  }
  
  TickerSequences filterTickers(IF1<TickerSequence, Boolean> pred) {
    TickerSequences ts = new TickerSequences();
    for (var t : tickers())
      if (pred.get(t))
        ts.add(t);
    return ts;
  }
  
  /*TickerSequences digitizeToPercent(double basePrice, double cellSizeInPercent) {
    ret mapTickers(ts -> ts.digitizeToPercent(basePrice, cellSizeInPercent));
  }*/
  
  TickerSequences marketIfEmpty(String market) {
    if (empty(this.market)) market(market);
    return this;
  }
  
  TickerSequences market(String market) {
    this.market = market;
    for (var t : tickers)
      t.market(market);
    return this;
  }
  
  public void write(ByteHead head) {
    for (var t : tickers)
      t.write(head);
  }
  
  public void read(ByteHead head) {
    TickerSequence t;
    while ((t = TickerSequence.read(head)) != null)
      add(t);
    if (empty(market) && nempty(tickers))
      market(first(tickers).market);
  }
  
  public void readWrite(ByteHead head) {
    if (head.readMode()) read(head);
    if (head.writeMode()) write(head);
  }
  
  public Iterator<TickerSequence> iterator() {
    return tickers.iterator();
  }
}
static <A, B extends A> void addAll(Collection<A> c, Iterable<B> b) {
  if (c != null && b != null) for (A a : b) c.add(a);
}

static <A, B extends A> boolean addAll(Collection<A> c, Collection<B> b) {
  return c != null && b != null && c.addAll(b);
}

static <A, B extends A> boolean addAll(Collection<A> c, B... b) {
  return c != null && b != null && c.addAll(Arrays.asList(b));
}



static <A, B> Map<A, B> addAll(Map<A, B> a, Map<? extends A,? extends B> b) {
  if (a != null && b != null) a.putAll(b);
  return a;
}

static <A extends Container> A addAll(A c, Collection<? extends Component> components) {
  return addComponents(c, components);
}

static <A extends Container> A addAll(A c, Component... components) {
  return addComponents(c, components);
}


// f: A -> Comparable
static <A> List<A> sortInPlaceByCalculatedField(List<A> l, final F1<A, ?> f) {
  sort(l, new Comparator<A>() {
    public int compare(A a, A b) {
      return stdcompare(f.get(a), f.get(b));
    }
  });
  return l;
}

static <A> List<A> sortInPlaceByCalculatedField(List<A> l, final IF1<A, ?> f) {
  sort(l, new Comparator<A>() {
    public int compare(A a, A b) {
      return stdcompare(f.get(a), f.get(b));
    }
  });
  return l;
}


static String commaCombine(Object... l) {
  return joinNemptiesWithComma(flattenCollectionsAndArrays(l));
}


static String spaceCombine(Object... l) {
  return joinNemptiesWithSpace(flattenCollections(ll(l)));
}


static String n2(long l) { return formatWithThousands(l); }
static String n2(AtomicLong l) { return n2(l.get()); }
static String n2(Collection l) { return n2(l(l)); }
static String n2(Map map) { return n2(l(map)); }

static String n2_getPlural(String singular) {
  //ret singular + "s";
  return plural(singular);
}

static String n2(double l, String singular) {
  return empty(singular) ? str(l) : n2(l, singular, n2_getPlural(singular));
}

static String n2(double l, String singular, String plural) {
  if (fraction(l) == 0)
    return n2((long) l, singular, plural);
  else
    return l + " " + plural;
}

static String n2(long l, String singular, String plural) {
  return n_fancy2(l, singular, plural);
}

static String n2(long l, String singular) {
  return empty(singular) ? n2(l) : n_fancy2(l, singular, n2_getPlural(singular));
}

static String n2(Collection l, String singular) {
  return n2(l(l), singular);
}

static String n2(Collection l, String singular, String plural) {
  return n_fancy2(l, singular, plural);
}

static String n2(Map m, String singular, String plural) {
  return n_fancy2(m, singular, plural);
}

static String n2(Map m, String singular) {
  return n2(l(m), singular);
}

static String n2(long[] a, String singular) { return n2(l(a), singular); }

static String n2(Object[] a, String singular) { return n2(l(a), singular); }
static String n2(Object[] a, String singular, String plural) { return n_fancy2(a, singular, plural); }




  static String n2(IMultiMap mm, String singular) { return n2(mm, singular, n2_getPlural(singular)); }
static String n2(IMultiMap mm, String singular, String plural) {
    return n_fancy2(l(mm), singular, plural);
  }



static boolean empty(Collection c) { return c == null || c.isEmpty(); }
static boolean empty(Iterable c) { return c == null || !c.iterator().hasNext(); }
static boolean empty(CharSequence s) { return s == null || s.length() == 0; }
static boolean empty(Map map) { return map == null || map.isEmpty(); }
static boolean empty(Object[] o) { return o == null || o.length == 0; }
static boolean empty(BitSet bs) { return bs == null || bs.isEmpty(); }


static boolean empty(Object o) {
  if (o instanceof Collection) return empty((Collection) o);
  if (o instanceof String) return empty((String) o);
  if (o instanceof Map) return empty((Map) o);
  if (o instanceof Object[]) return empty((Object[]) o);
  if (o instanceof byte[]) return empty((byte[]) o);
  if (o == null) return true;
  throw fail("unknown type for 'empty': " + getType(o));
}


static boolean empty(Iterator i) { return i == null || !i.hasNext(); }

static boolean empty(double[] a) { return a == null || a.length == 0; }
static boolean empty(float[] a) { return a == null || a.length == 0; }
static boolean empty(int[] a) { return a == null || a.length == 0; }
static boolean empty(long[] a) { return a == null || a.length == 0; }
static boolean empty(byte[] a) { return a == null || a.length == 0; }
static boolean empty(short[] a) { return a == null || a.length == 0; }




static boolean empty(IMultiMap mm) { return mm == null || mm.size() == 0; }


static boolean empty(File f) { return getFileSize(f) == 0; }


static boolean empty(IntRange r) { return r == null || r.empty(); }



static boolean empty(DoubleRange r) { return r == null || r.isEmpty(); }







static boolean empty(SynchronizedLongBuffer b) { return b == null || b.isEmpty(); }



static boolean empty(DoubleBuffer b) { return b == null || b.isEmpty(); }





static boolean empty(SynchronizedFloatBufferPresentingAsDoubles b) { return b == null || b.isEmpty(); }



static boolean empty(IDoubleBuffer b) { return b == null || b.isEmpty(); }



static boolean empty(ILongBuffer b) { return b == null || b.isEmpty(); }



static boolean empty(Rect r) { return !(r != null && r.w != 0 && r.h != 0); }



static boolean empty(Chain c) { return c == null; }



static boolean empty(AppendableChain c) { return c == null; }


static boolean empty(IntSize l) { return l == null || l.size() == 0; }


static String formatDays(Duration d) { return formatDays(d, 1); }
static String formatDays(Duration d, int decimals) {
  return formatDays(toMS(d), decimals);
}

static String formatDays(long ms) { return formatDays(ms, 1); }
static String formatDays(long ms, int decimals) {
  return formatDays(toDays(ms), decimals);
}
  
static String formatDays(double days) { return formatDays(days, 1); }
static String formatDays(double days, int decimals) {
  String formatted = formatDouble(days, decimals);
  return eq(formatted, "1") ? "1 day" : formatted + " days";
}


static long longSum(Iterable<Long> l) {
  long sum = 0;
  for (Long i : unnull(l))
    if (i != null) sum += i;
  return sum;
}

static <A> long longSum(IF1<A, Long> f, Iterable<A> l) {
  return longSum(mapI(f, l));
}



static List map(Iterable l, Object f) { return map(f, l); }

static List map(Object f, Iterable l) {
  List x = emptyList(l);
  if (l != null) for  (Object o : l)
    { ping(); x.add(callF(f, o)); }
  return x;
}

// map: func(key, value) -> list element
static List map(Map map, Object f) {
  List x = new ArrayList();
  if (map != null) for  (Object _e : map.entrySet()) { ping(); 
    Map.Entry e = (Map.Entry) _e;
    x.add(callF(f, e.getKey(), e.getValue()));
  }
  return x;
}

static List map(Object f, Object[] l) { return map(f, asList(l)); }
static List map(Object[] l, Object f) { return map(f, l); }

static List map(Object f, Map map) {
  return map(map, f);
}




  static <A, B> List<B> map(Iterable<A> l, F1<A, B> f) { return map(f, l); }

  static <A, B> List<B> map(F1<A, B> f, Iterable<A> l) {
    List x = emptyList(l);
    if (l != null) for  (A o : l)
      { ping(); x.add(callF(f, o)); }
    return x;
  }


static <A, B> List<B> map(IF1<A, B> f, Iterable<A> l) { return map(l, f); }
static <A, B> List<B> map(Iterable<A> l, IF1<A, B> f) {
  List x = emptyList(l);
  if (l != null) {
    var it = l.iterator();
    if (it.hasNext()) {
      var pingSource = pingSource();
      do {
        ping(pingSource);
        x.add(f.get(it.next()));
      } while (it.hasNext());
    }
  }
  return x;
}
  
static <A, B> List<B> map(IF1<A, B> f, A[] l) { return map(l, f); }
static <A, B> List<B> map(A[] l, IF1<A, B> f) {
  List x = emptyList(l);
  if (l != null) for  (A o : l)
    { ping(); x.add(f.get(o)); }
  return x;
}
  
static <A, B, C> List<C> map(Map<A, B> map, IF2<A, B, C> f) {
  List x = new ArrayList();
  if (map != null) for  (Map.Entry<A, B> e : map.entrySet()) { ping(); 
    x.add(f.get(e.getKey(), e.getValue()));
  }
  return x;
}

// new magic alias for mapLL - does it conflict?

static <A, B> List<A> map(IF1<A, B> f, A data1, A... moreData) {
  List x = emptyList(l(moreData)+1);
  x.add(f.get(data1));
  if (moreData != null) for  (A o : moreData)
    { ping(); x.add(f.get(o)); }
  return x;
}


static <T> void sort(T[] a, Comparator<? super T> c) {
  if (a != null) Arrays.sort(a, c);
}

static <T> void sort(T[] a) {
  if (a != null) Arrays.sort(a);
}

static void sort(int[] a) { if (a != null) Arrays.sort(a); }

static <T> void sort(List<T> a, Comparator<? super T> c) {
  if (a != null) Collections.sort(a, c);
}

static void sort(List a) {
  if (a != null) Collections.sort(a);
}


static int l(Object[] a) { return a == null ? 0 : a.length; }
static int l(boolean[] a) { return a == null ? 0 : a.length; }
static int l(byte[] a) { return a == null ? 0 : a.length; }
static int l(short[] a) { return a == null ? 0 : a.length; }
static int l(long[] a) { return a == null ? 0 : a.length; }
static int l(int[] a) { return a == null ? 0 : a.length; }
static int l(float[] a) { return a == null ? 0 : a.length; }
static int l(double[] a) { return a == null ? 0 : a.length; }
static int l(char[] a) { return a == null ? 0 : a.length; }
static int l(Collection c) { return c == null ? 0 : c.size(); }

static int l(Iterator i) { return iteratorCount_int_close(i); } // consumes the iterator && closes it if possible

static int l(Map m) { return m == null ? 0 : m.size(); }
static int l(CharSequence s) { return s == null ? 0 : s.length(); }
static long l(File f) { return f == null ? 0 : f.length(); }






  static int l(IMultiMap mm) { return mm == null ? 0 : mm.size(); }





  static int l(IntRange r) { return r == null ? 0 : r.length(); }





  static double l(DoubleRange r) { return r == null ? 0 : r.length(); }











  static int l(IntSize o) { return o == null ? 0 : o.size(); }




static long fromSeconds(double seconds) {
  return toMS(seconds);
}



static Object first(Object list) {
  return first((Iterable) list);
}


static <A> A first(List<A> list) {
  return empty(list) ? null : list.get(0);
}

static <A> A first(A[] bla) {
  return bla == null || bla.length == 0 ? null : bla[0];
}

static <A, B> Pair<A, B> first(Map<A, B> map) {
  return mapEntryToPair(first(entrySet(map)));
}

static <A, B> Pair<A, B> first(MultiMap<A, B> mm) {
  if (mm == null) return null;
  var e = first(mm.data.entrySet());
  if (e == null) return null;
  return pair(e.getKey(), first(e.getValue()));
}


static <A> A first(IterableIterator<A> i) {
  return first((Iterator<A>) i);
}


static <A> A first(Iterator<A> i) {
  return i == null || !i.hasNext() ? null : i.next();
}

static <A> A first(Iterable<A> i) {
  if (i == null) return null;
  Iterator<A> it = i.iterator();
  return it.hasNext() ? it.next() : null;
}

static Character first(String s) { return empty(s) ? null : s.charAt(0); }
static Character first(CharSequence s) { return empty(s) ? null : s.charAt(0); }


static <A, B> A first(Pair<A, B> p) {
  return p == null ? null : p.a;
}




static Byte first(byte[] l) { return empty(l) ? null : l[0]; }
static Double first(double[] l) { return empty(l) ? null : l[0]; }




static byte first(ByteBuffer buf) {
  return buf.get(0);
}


static <A> A first(A[] l, IF1<A, Boolean> pred) {
  return firstThat(l, pred);
}

static <A> A first(Iterable<A> l, IF1<A, Boolean> pred) {
  return firstThat(l, pred);
}

static <A> A first(IF1<A, Boolean> pred, Iterable<A> l) {
  return firstThat(pred, l);
}


static <A> A first(AppendableChain<A> a) {
  return a == null ? null : a.element;
}




// TODO: clean up these type signatures?

static <A, B, C extends Iterator<B>> IterableIterator<B> nestedIterator(Iterable<A> c, final F1<A, C> makeInnerIterator) {
  return nestedIterator(iterator(c), makeInnerIterator);
}

static <A, B, C extends Iterator<B>> IterableIterator<B> nestedIterator(Iterable<A> c, IF1<A, C> makeInnerIterator) {
  return nestedIterator(iterator(c), makeInnerIterator);
}

static <A, B, C extends Iterator<B>> IterableIterator<B> nestedIterator(IterableIterator<A> c, IF1<A, C> makeInnerIterator) {
  return nestedIterator((Iterator<A>) c, makeInnerIterator);
}

static <A, B, C extends Iterator<B>> IterableIterator<B> nestedIterator(Iterator<A> it1, IF1<A, C> makeInnerIterator) {
  if (it1 == null || !it1.hasNext()) return emptyItIt();
  return iff(new F0() {
    A a;
    Iterator<B> innerIterator;
    
    { nextOuter(); }
    
    void nextOuter() {
      a = it1.next();
      innerIterator = makeInnerIterator.get(a);
    }
    
    public Object get() {
      while (true) { ping();
        if (innerIterator != null && innerIterator.hasNext())
          return innerIterator.next();
        if (!it1.hasNext()) return endMarker();
        nextOuter();
      }
    }
  });
}

static <A, B, C extends Iterator<B>> IterableIterator<B> nestedIterator(final Iterator<A> it1, F1<A, C> makeInnerIterator) {
  if (it1 == null || !it1.hasNext()) return emptyItIt();
  return iff(new F0() {
    A a;
    Iterator<B> innerIterator;
    
    { nextOuter(); }
    
    void nextOuter() {
      a = it1.next();
      innerIterator = makeInnerIterator.get(a);
    }
    
    public Object get() {
      while (true) { ping();
        if (innerIterator != null && innerIterator.hasNext())
          return innerIterator.next();
        if (!it1.hasNext()) return endMarker();
        nextOuter();
      }
    }
  });
}

static <A, B, C extends Iterator<B>> IterableIterator<B> nestedIterator(IF1<A, C> makeInnerIterator, Iterator<A> it1) {
  return nestedIterator(it1, makeInnerIterator);
}

static <A, B, C extends Iterator<B>> IterableIterator<B> nestedIterator(IF1<A, C> makeInnerIterator, Collection<A> l) {
  return nestedIterator(l, makeInnerIterator);
}


static <A> A last(List<A> l) {
  return empty(l) ? null : l.get(l.size()-1);
}

static char last(String s) {
  return empty(s) ? '#' : s.charAt(l(s)-1);
}

static byte last(byte[] a) {
  return l(a) != 0 ? a[l(a)-1] : 0;
}


  static int last(int[] a) {
    return l(a) != 0 ? a[l(a)-1] : 0;
  }


  static long last(long[] a) {
    return l(a) != 0 ? a[l(a)-1] : 0;
  }



static double last(double[] a) {
  return l(a) != 0 ? a[l(a)-1] : 0;
}

static <A> A last(A[] a) {
  return l(a) != 0 ? a[l(a)-1] : null;
}

static <A> A last(Iterator<A> it) {
  A a = null;
  while  (it.hasNext()) { ping(); a = it.next(); }
  return a;
}

static <A> A last(Collection<A> l) {
  if (l == null) return null;
  if (l instanceof List) return (A) last((List) l);
  if (l instanceof SortedSet) return (A) last((SortedSet) l);
  Iterator<A> it = iterator(l);
  A a = null;
  while  (it.hasNext()) { ping(); a = it.next(); }
  return a;
}

static <A> A last(SortedSet<A> l) {
  return l == null ? null : l.last();
}


static <A> A last(ReverseChain<A> l) {
  return l == null ? null : l.element;
}





static byte last(ByteBuffer buf) {
  return buf.get(buf.size()-1);
}



static double last(DoubleBuffer l) {
  return l.last();
}



static double last(IDoubleBuffer l) {
  return l.last();
}



static long last(ILongBuffer l) {
  return l.last();
}







static long last(SynchronizedLongBuffer l) {
  return l.last();
}



static <A> A last(CompactLinkedHashSet<A> set) {
  return set == null ? null : set.last();
}



static <A> A highestBy(Iterable<A> l, Object f) {
  return highestByFunction(l, f);
}



static <A> A highestBy(Object f, Iterable<A> l) {
  return highestByFunction(f, l);
}

static <A> A highestBy(Iterable<A> l, IF1<A, ? extends Comparable> f) {
  return highestByFunction(f, l);
}

static <A> A highestBy(IF1<A, ? extends Comparable> f, Iterable<A> l) {
  return highestByFunction(f, l);
}

static <A> A highestBy(IF1<A, ? extends Comparable> f, A[] l) {
  return highestByFunction(f, wrapAsList(l));
}


static Duration duration(TimestampRange r) {
  return r == null ? Duration.ZERO : r.duration();
}


static void add(BitSet bs, int i) {
  bs.set(i);
}

static <A> boolean add(Collection<A> c, A a) {
  return c != null && c.add(a);
}


static void add(Container c, Component x) {
  addToContainer(c, x);
}


static long add(AtomicLong l, long b) {
  return l.addAndGet(b);
}


static boolean nempty(Collection c) {
  return !empty(c);
}

static boolean nempty(CharSequence s) {
  return !empty(s);
}

static boolean nempty(Object[] o) { return !empty(o); }
static boolean nempty(byte[] o) { return !empty(o); }
static boolean nempty(int[] o) { return !empty(o); }

static boolean nempty(BitSet bs) { return !empty(bs); }

static boolean nempty(Map m) {
  return !empty(m);
}

static boolean nempty(Iterator i) {
  return i != null && i.hasNext();
}


static boolean nempty(IMultiMap mm) { return mm != null && mm.size() != 0; }



static boolean nempty(Object o) { return !empty(o); }



static boolean nempty(IntRange r) { return !empty(r); }







static boolean nempty(Rect r) { return r != null && r.w != 0 && r.h != 0; }






static boolean nempty(IntSize l) { return l != null && l.size() != 0; }


static <A> Iterator<A> iterator(Iterable<A> c) {
  return c == null ? emptyIterator() : c.iterator();
}




static <A extends Container> A addComponents(A c, Collection<? extends Component> components) {
  if (nempty(components)) { swing(() -> { 
    for (Component comp : components)
      if (comp != null)
        c.add(comp);
    revalidate(c);
  }); }
  return c;
}

static <A extends Container> A addComponents(A c, Component... components) {
  return addComponents(c, asList(components));
}


static int stdcompare(Number a, Number b) {
  return cmp(a, b);
}

static int stdcompare(String a, String b) {
  return cmp(a, b);
}

static int stdcompare(long a, long b) {
  return a < b ? -1 : a > b ? 1 : 0;
}

static int stdcompare(Object a, Object b) {
  return cmp(a, b);
}



static String joinNemptiesWithComma(Object... strings) {
  return joinNempties(", ", strings);
}

static String joinNemptiesWithComma(Iterable strings) {
  return joinNempties(", ", strings);
}


static List flattenCollectionsAndArrays(Iterable a) {
  List l = new ArrayList();
  for (Object x : a)
    if (x instanceof Collection)
      l.addAll(flattenCollectionsAndArrays((Collection) x));
    else if (x instanceof Object[])
      l.addAll(flattenCollectionsAndArrays(asList((Object[]) x)));
    else
      l.add(x);
  return l;
}

static List flattenCollectionsAndArrays(Object... whatever) {
  return flattenCollectionsAndArrays(ll(whatever));
}


static String joinNemptiesWithSpace(String... strings) {
  return joinNempties(" ", strings);
}

static String joinNemptiesWithSpace(Collection<String> strings) {
  return joinNempties(" ", strings);
}


static List flattenCollections(Iterable a) {
  List l = new ArrayList();
  for (Object x : a)
    if (x instanceof Collection)
      l.addAll(flattenCollections((Collection) x));
    else
      l.add(x);
  return l;
}


static <A> List<A> ll(A... a) {
  ArrayList l = new ArrayList(a.length);
  if (a != null) for (A x : a) l.add(x);
  return l;
}


static String formatWithThousands(long l) {
  return formatWithThousandsSeparator(l);
}


static String plural(String s) {
  return getPlural(s);
}


static String str(Object o) {
  return o == null ? "null" : o.toString();
}

static String str(char[] c) {
  return c == null ? "null" : new String(c);
}

static String str(char[] c, int offset, int count) {
  return new String(c, offset, count);
}


static double fraction(double d) {
  return d % 1;
}


static String n_fancy2(long l, String singular, String plural) {
  return formatWithThousandsSeparator(l) + " " + trim(l == 1 ? singular : plural);
}

static String n_fancy2(Collection l, String singular, String plural) {
  return n_fancy2(l(l), singular, plural);
}

static String n_fancy2(Map m, String singular, String plural) {
  return n_fancy2(l(m), singular, plural);
}

static String n_fancy2(Object[] a, String singular, String plural) {
  return n_fancy2(l(a), singular, plural);
}




static RuntimeException fail() { throw new RuntimeException("fail"); }
static RuntimeException fail(Throwable e) { throw asRuntimeException(e); }
static RuntimeException fail(Object msg) { throw new RuntimeException(String.valueOf(msg)); }


static RuntimeException fail(Object... objects) { throw new Fail(objects); }


static RuntimeException fail(String msg) { throw new RuntimeException(msg == null ? "" : msg); }
static RuntimeException fail(String msg, Throwable innerException) { throw new RuntimeException(msg, innerException); }



static String getType(Object o) {
  return getClassName(o);
}


static long getFileSize(String path) {
  return path == null ? 0 : new File(path).length();
}

static long getFileSize(File f) {
  return f == null ? 0 : f.length();
}


static long toMS(double seconds) {
  return (long) (seconds*1000);
}

static long toMS(Duration d) {
  return d == null ? 0 : d.toMillis();
}


static double toDays(long ms) {
  return ms/(60000.0*60*24);
}


static String formatDouble(double d, int digits) {
  String format = digits <= 0 ? "0" : "0." + rep(digits, '#');
  return decimalFormatEnglish(format, d);
}

static String formatDouble(double d) {
  return str(d);
}


static String formatDouble(DoubleRange r, int digits) {
  return r == null ? "null" : "[" + formatDouble(r.start, digits)
    + ";" + formatDouble(r.end, digits) + "]";
}



static boolean eq(Object a, Object b) {
  return a == b || a != null && b != null && a.equals(b);
}


// a little kludge for stuff like eq(symbol, "$X")
static boolean eq(Symbol a, String b) {
  return eq(str(a), b);
}



static String unnull(String s) {
  return s == null ? "" : s;
}

static <A> Collection<A> unnull(Collection<A> l) {
  return l == null ? emptyList() : l;
}

static <A> List<A> unnull(List<A> l) { return l == null ? emptyList() : l; }
static int[] unnull(int[] l) { return l == null ? emptyIntArray() : l; }
static char[] unnull(char[] l) { return l == null ? emptyCharArray() : l; }
static double[] unnull(double[] l) { return l == null ? emptyDoubleArray() : l; }
static float[] unnull(float[] l) { return l == null ? emptyFloatArray() : l; }

static <A, B> Map<A, B> unnull(Map<A, B> l) {
  return l == null ? emptyMap() : l;
}

static <A> Iterable<A> unnull(Iterable<A> i) {
  return i == null ? emptyList() : i;
}

static <A> A[] unnull(A[] a) {
  return a == null ? (A[]) emptyObjectArray() : a;
}

static BitSet unnull(BitSet b) {
  return b == null ? new BitSet() : b;
}


static Pt unnull(Pt p) {
  return p == null ? new Pt() : p;
}


//ifclass Symbol

static Symbol unnull(Symbol s) {
  return s == null ? emptySymbol() : s;
}
//endif



static <A, B> Pair<A, B> unnull(Pair<A, B> p) {
  return p != null ? p : new Pair(null, null);
}


static int unnull(Integer i) { return i == null ? 0 : i; }
static long unnull(Long l) { return l == null ? 0L : l; }
static double unnull(Double l) { return l == null ? 0.0 : l; }


static class mapI_It extends IterableIterator {
  Object f;
  Iterator i;
  
  mapI_It() {}
  mapI_It(Object f, Iterator i) {
  this.i = i;
  this.f = f;}
  
  public boolean hasNext() {
    return i.hasNext();
  }
  
  public Object next() {
    return callF(f, i.next());
  }
  
  public String toString() {
    return formatFunctionCall("mapI", f, i);
  }
}


// apply a function to an iterator
static IterableIterator mapI(final Object f, final Iterator i) {
  return new mapI_It(f, i);
}


static IterableIterator mapI(IterableIterator i, Object f) {
  return mapI((Iterator) i, f);
}

static IterableIterator mapI(Object f, IterableIterator i) {
  return mapI((Iterator) i, f);
}


static IterableIterator mapI(Iterator i, Object f) {
  return mapI(f, i);
}

static <A, B> IterableIterator<B> mapI(Iterable<A> i, IF1<A, B> f) {
  return new MapI(f, iterator(i));
}

static <A, B> IterableIterator<B> mapI(Iterator<A> i, IF1<A, B> f) {
  return new MapI(f, i);
}

static <A, B> IterableIterator<B> mapI(IterableIterator<A> i, IF1<A, B> f) {
  return new MapI(f, i);
}

static <A, B> IterableIterator<B> mapI(IF1<A, B> f, Iterable<A> i) {
  return new MapI(f, iterator(i));
}

static IterableIterator mapI(Iterable i, Object f) {
  return mapI(f, i.iterator());
}

static IterableIterator mapI(Object f, Iterable i) {
  return mapI(i, f);
}



static ArrayList emptyList() {
  return new ArrayList();
  //ret Collections.emptyList();
}

static ArrayList emptyList(int capacity) {
  return new ArrayList(max(0, capacity));
}

// Try to match capacity
static ArrayList emptyList(Iterable l) {
  return l instanceof Collection ? emptyList(((Collection) l).size()) : emptyList();
}

static ArrayList emptyList(Object[] l) {
  return emptyList(l(l));
}

// get correct type at once
static <A> ArrayList<A> emptyList(Class<A> c) {
  return new ArrayList();
}




// legacy mode





//sbool ping_actions_shareable = true;
static volatile boolean ping_pauseAll = false;
static int ping_sleep = 100; // poll pauseAll flag every 100
static volatile boolean ping_anyActions = false;
static Map<Thread, Object> ping_actions = newWeakHashMap();
static ThreadLocal<Boolean> ping_isCleanUpThread = new ThreadLocal();

// ignore pingSource if not PingV3
static boolean ping(PingSource pingSource) { return ping(); }

// always returns true
static boolean ping() {
  //ifdef useNewPing
  newPing();
  //endifdef
  if (ping_pauseAll || ping_anyActions) ping_impl(true /* XXX */);
  //ifndef LeanMode ping_impl(); endifndef
  return true;
}

// returns true when it slept
static boolean ping_impl(boolean okInCleanUp) { try {
  if (ping_pauseAll && !isAWTThread()) {
    do
      Thread.sleep(ping_sleep);
    while (ping_pauseAll);
    return true;
  }
  
  if (ping_anyActions) { // don't allow sharing ping_actions
    if (!okInCleanUp && !isTrue(ping_isCleanUpThread.get()))
      failIfUnlicensed();
    Object action = null;
    synchronized(ping_actions) {
      if (!ping_actions.isEmpty()) {
        action = ping_actions.get(currentThread());
        if (action instanceof Runnable)
          ping_actions.remove(currentThread());
        if (ping_actions.isEmpty()) ping_anyActions = false;
      }
    }
    
    if (action instanceof Runnable)
      ((Runnable) action).run();
    else if (eq(action, "cancelled"))
      throw fail("Thread cancelled.");
  }

  return false;
} catch (Exception __e) { throw rethrow(__e); } }





static Map<Class, ArrayList<Method>> callF_cache = newDangerousWeakHashMap();



  static <A> A callF(F0<A> f) {
    return f == null ? null : f.get();
  }



  static <A, B> B callF(F1<A, B> f, A a) {
    return f == null ? null : f.get(a);
  }



  static <A> A callF(IF0<A> f) {
    return f == null ? null : f.get();
  }



  static <A, B> B callF(IF1<A, B> f, A a) {
    return f == null ? null : f.get(a);
  }


static <A, B> B callF(A a, IF1<A, B> f) {
  return f == null ? null : f.get(a);
}




  static <A, B, C> C callF(IF2<A, B, C> f, A a, B b) {
    return f == null ? null : f.get(a, b);
  }



  static <A> void callF(VF1<A> f, A a) {
    if (f != null) f.get(a);
  }


static <A> void callF(A a, IVF1<A> f) {
  if (f != null) f.get(a);
}

static <A> void callF(IVF1<A> f, A a) {
  if (f != null) f.get(a);
}


static Object callF(Runnable r) { { if (r != null) r.run(); } return null; }


static Object callF(Object f, Object... args) {
  
    
  return safeCallF(f, args);
}

static Object safeCallF(Object f, Object... args) {
  if (f instanceof Runnable) {
    ((Runnable) f).run();
    return null;
  }
  if (f == null) return null;
  
  Class c = f.getClass();
  ArrayList<Method> methods;
  synchronized(callF_cache) {
    methods = callF_cache.get(c);
    if (methods == null)
      methods = callF_makeCache(c);
  }
  
  int n = l(methods);
  if (n == 0) {
    
    
    if (f instanceof String)
      throw fail("Legacy call: " + f);
    
    throw fail("No get method in " + getClassName(c));
  }
  if (n == 1) return invokeMethod(methods.get(0), f, args);
  for (int i = 0; i < n; i++) {
    Method m = methods.get(i);
    if (call_checkArgs(m, args, false))
      return invokeMethod(m, f, args);
  }
  throw fail("No matching get method in " + getClassName(c));
}

// used internally
static ArrayList<Method> callF_makeCache(Class c) {
  ArrayList<Method> l = new ArrayList();
  Class _c = c;
  do {
    for (Method m : _c.getDeclaredMethods())
      if (m.getName().equals("get")) {
        makeAccessible(m);
        l.add(m);
      }
    if (!l.isEmpty()) break;
    _c = _c.getSuperclass();
  } while (_c != null);
  callF_cache.put(c, l);
  return l;
}





// unclear semantics as to whether return null on null

static <A> ArrayList<A> asList(A[] a) {
  return a == null ? new ArrayList<A>() : new ArrayList<A>(Arrays.asList(a));
}

static ArrayList<Character> asList(char[] a) {
  if (a == null) return null;
  ArrayList<Character> l = emptyList(a.length);
  for (var i : a) l.add(i);
  return l;
}

static ArrayList<Byte> asList(byte[] a) {
  if (a == null) return null;
  ArrayList<Byte> l = emptyList(a.length);
  for (var i : a) l.add(i);
  return l;
}

static ArrayList<Integer> asList(int[] a) {
  if (a == null) return null;
  ArrayList<Integer> l = emptyList(a.length);
  for (int i : a) l.add(i);
  return l;
}

static ArrayList<Long> asList(long[] a) {
  if (a == null) return null;
  ArrayList<Long> l = emptyList(a.length);
  for (long i : a) l.add(i);
  return l;
}

static ArrayList<Float> asList(float[] a) {
  if (a == null) return null;
  ArrayList<Float> l = emptyList(a.length);
  for (float i : a) l.add(i);
  return l;
}

static ArrayList<Double> asList(double[] a) {
  if (a == null) return null;
  ArrayList<Double> l = emptyList(a.length);
  for (double i : a) l.add(i);
  return l;
}

static ArrayList<Short> asList(short[] a) {
  if (a == null) return null;
  ArrayList<Short> l = emptyList(a.length);
  for (short i : a) l.add(i);
  return l;
}

static <A> ArrayList<A> asList(Iterator<A> it) {
  ArrayList l = new ArrayList();
  if (it != null)
    while (it.hasNext())
      l.add(it.next());
  return l;  
}

// disambiguation
static <A> ArrayList<A> asList(IterableIterator<A> s) {
  return asList((Iterator) s);
}

static <A> ArrayList<A> asList(Iterable<A> s) {
  if (s instanceof ArrayList) return (ArrayList) s;
  ArrayList l = new ArrayList();
  if (s != null)
    for (A a : s)
      l.add(a);
  return l;
}


static <A> ArrayList<A> asList(Producer<A> p) {
  ArrayList l = new ArrayList();
  A a;
  if (p != null) while ((a = p.next()) != null)
    l.add(a);
  return l;
}


static <A> ArrayList<A> asList(Enumeration<A> e) {
  ArrayList l = new ArrayList();
  if (e != null)
    while (e.hasMoreElements())
      l.add(e.nextElement());
  return l;
}


static <A> ArrayList<A> asList(ReverseChain<A> c) {
  return c == null ? emptyList() : c.toList();
}



static <A> List<A> asList(Pair<A, A> p) {
  return p == null ? null : ll(p.a, p.b);
}



// assumptions:
// -pingSource() stays constant within a stack frame (so you can cache it)
// -all changes happen with tempSetPingSource
// -multiple threads can share a PingSource
static PingSource pingSource() {
  return pingSource_tl().get();
}

static PingSource pingSource(Thread thread) {
  return pingSource_tl().get(thread);
}


static <A> int iteratorCount_int_close(Iterator<A> i) { try {
  int n = 0;
  if (i != null) while (i.hasNext()) { i.next(); ++n; }
  if (i instanceof AutoCloseable) ((AutoCloseable) i).close();
  return n;
} catch (Exception __e) { throw rethrow(__e); } }


static <A, B> Pair<A, B> mapEntryToPair(Map.Entry<A, B> e) {
  return e == null ? null : pair(e.getKey(), e.getValue());
}


static <A, B> Set<Map.Entry<A,B>> entrySet(Map<A, B> map) {
  return _entrySet(map);
}


static <A, B> Pair<A, B> pair(A a, B b) {
  return new Pair(a, b);
}

static <A> Pair<A, A> pair(A a) {
  return new Pair(a, a);
}


static <A> A firstThat(Iterable<A> l, IF1<A, Boolean> pred) {
  for (A a : unnullForIteration(l))
    if (pred.get(a))
      return a;
  return null;
}

static <A> A firstThat(A[] l, IF1<A, Boolean> pred) {
  for (A a : unnullForIteration(l))
    if (pred.get(a))
      return a;
  return null;
}

static <A> A firstThat(IF1<A, Boolean> pred, Iterable<A> l) {
  return firstThat(l, pred);
}

static <A> A firstThat(IF1<A, Boolean> pred, A[] l) {
  return firstThat(l, pred);
}





static <A> IterableIterator<A> emptyItIt() {
  return emptyIterableIterator();
}


// f: func -> A | endMarker
static <A> IterableIterator<A> iff(Object f) {
  return iteratorFromFunction_withEndMarker(f);
}

// can't use type parameter because end marker
static IterableIterator iff(F0 f) {
  return iteratorFromFunction_withEndMarker(f);
}

static <A> IterableIterator iff(IF0 f) {
  return iteratorFromFunction_withEndMarker(f);
}


static Object endMarker() {
  return iteratorFromFunction_endMarker;
}


static <A> A highestByFunction(Iterable<A> l, Object f) {
  A best = null;
  Object bestValue = null;
  if (l != null) for (A a : l) {
    Object val = callF(f, a);
    if (best == null || cmp(val, bestValue) > 0) {
      best = a;
      bestValue = val;
    }
  }
  return best;
}

static <A> A highestByFunction(Object f, Iterable<A> l) {
  return highestByFunction(l, f);
}

static <A> A highestByFunction(IF1<A, ? extends Comparable> f, Iterable<A> l) {
  return highestByFunction(l, (Object) f);
}

static <A> A highestByFunction(Iterable<A> l, IF1<A, ? extends Comparable> f) {
  return highestByFunction(f, l);
}


static <A> List<A> wrapAsList(A[] a) {
  return wrapArrayAsList(a);
}


static void addToContainer(Container a, Component... b) {
  if (a == null) return;
  { swing(() -> { 
    for (Component c : unnullForIteration(b))
      if (c != null) 
        a.add(c);
  }); }
}


static Iterator emptyIterator() {
  return Collections.emptyIterator();
}




// requires ugly casting when used (O -> A)
static Object iteratorFromFunction_endMarker = new Object();

// f: func -> A | endMarker
static <A> IterableIterator<A> iteratorFromFunction_withEndMarker(final Object f) {
  class IFF extends IterableIterator<A> {
    A a;
    boolean have, done;
    
    public boolean hasNext() {
      getNext();
      return !done;
    }
    
    public A next() {
      getNext();
      if (done) throw fail();
      A _a = a;
      a = null;
      have = false;
      return _a;
    }
    
    void getNext() {
      if (done || have) return;
      Object o = callF(f);
      if (o == iteratorFromFunction_endMarker)
        { done = true; return; }
      a = (A) o;
      have = true;
    }
  };
  return new IFF();
}

// optimized version for F0 argument; TODO: do same for IF0
static <A> IterableIterator<A> iteratorFromFunction_withEndMarker(final F0 f) {
  return iteratorFromFunction_withEndMarker_f0(f);
}


static Object swing(Object f) {
  return swingAndWait(f);
}

static void swing(Runnable f) {
  swingAndWait(f);
}

static <A> A swing(F0<A> f) {
  return (A) swingAndWait(f);
}

static <A> A swing(IF0<A> f) {
  return (A) swingAndWait(f);
}


static <A extends Component> A revalidate(final A c) {
  if (c == null || !c.isShowing()) return c;
  { swing(() -> { 
    // magic combo to actually relayout and repaint
    c.revalidate();
    c.repaint();
  }); }
  return c;
}

static void revalidate(JFrame f) { revalidate((Component) f); }
static void revalidate(JInternalFrame f) { revalidate((Component) f); }


static int cmp(Number a, Number b) {
  return a == null ? b == null ? 0 : -1 : cmp(a.doubleValue(), b.doubleValue());
}

static int cmp(double a, double b) {
  return a < b ? -1 : a == b ? 0 : 1;
}

static int cmp(int a, int b) {
  return a < b ? -1 : a == b ? 0 : 1;
}

static int cmp(long a, long b) {
  return a < b ? -1 : a == b ? 0 : 1;
}

static int cmp(Object a, Object b) {
  if (a == null) return b == null ? 0 : -1;
  if (b == null) return 1;
  return ((Comparable) a).compareTo(b);
}


static String joinNempties(String sep, Object... strings) {
  return joinStrings(sep, strings);
}

static String joinNempties(String sep, Iterable strings) {
  return joinStrings(sep, strings);
}




static String formatWithThousandsSeparator(long l) {
  return NumberFormat.getInstance(new Locale("en_US")).format(l);
}


static Set<String> getPlural_specials = litciset("sheep", "fish");

static String getPlural(String s) {
  if (contains(getPlural_specials, s)) return s;
  if (ewic(s, "y")) return dropSuffixIgnoreCase("y", s) + "ies";
  if (ewicOneOf(s, "ss", "ch")) return s + "es";
  if (ewic(s, "s")) return s;
  return s + "s";
}


static String trim(String s) { return s == null ? null : s.trim(); }
static String trim(StringBuilder buf) { return buf.toString().trim(); }
static String trim(StringBuffer buf) { return buf.toString().trim(); }


static RuntimeException asRuntimeException(Throwable t) {
  
  if (t instanceof Error)
    _handleError((Error) t);
  
  return t instanceof RuntimeException ? (RuntimeException) t : new RuntimeException(t);
}


static String getClassName(Object o) {
  return o == null ? "null" : o instanceof Class ? ((Class) o).getName() : o.getClass().getName();
}


static String rep(int n, char c) {
  return repeat(c, n);
}

static String rep(char c, int n) {
  return repeat(c, n);
}

static <A> List<A> rep(A a, int n) {
  return repeat(a, n);
}

static <A> List<A> rep(int n, A a) {
  return repeat(n, a);
}



static String decimalFormatEnglish(String format, double d) {
  return decimalFormatEnglish(format).format(d);
}

static java.text.DecimalFormat decimalFormatEnglish(String format) {
  return new java.text.DecimalFormat(format, new java.text.DecimalFormatSymbols(Locale.ENGLISH));
}


static int[] emptyIntArray_a = new int[0];
static int[] emptyIntArray() { return emptyIntArray_a; }


static char[] emptyCharArray = new char[0];
static char[] emptyCharArray() { return emptyCharArray; }


static double[] emptyDoubleArray = new double[0];
static double[] emptyDoubleArray() { return emptyDoubleArray; }


static float[] emptyFloatArray = new float[0];
static float[] emptyFloatArray() { return emptyFloatArray; }


static Map emptyMap() {
  return new HashMap();
}


static Object[] emptyObjectArray_a = new Object[0];
static Object[] emptyObjectArray() { return emptyObjectArray_a; }


static Symbol emptySymbol_value;

static Symbol emptySymbol() {
  if (emptySymbol_value == null) emptySymbol_value = symbol("");
  return emptySymbol_value;
}


// binary legacy syntax
static String formatFunctionCall(String fname, Object... args) {
  return formatFunctionCall((Object) fname, args);
}
  
static String formatFunctionCall(Object fname, Object... args) {
  return fname + "(" + joinWithComma(allToString(args)) + ")";
}

static String formatFunctionCall(String fname, Iterable args) {
  return formatFunctionCall((Object) fname, args);
}

static String formatFunctionCall(Object fname, Iterable args) {
  return formatFunctionCall(fname, toObjectArray(args));
}


static int max(int a, int b) { return Math.max(a, b); }
static int max(int a, int b, int c) { return max(max(a, b), c); }
static long max(int a, long b) { return Math.max((long) a, b); }
static long max(long a, long b) { return Math.max(a, b); }
static double max(int a, double b) { return Math.max((double) a, b); }
static float max(float a, float b) { return Math.max(a, b); }
static double max(double a, double b) { return Math.max(a, b); }

static <A extends Comparable<A>> A max (Iterable<A> l) {
  A max = null;
  var it = iterator(l);
  if (it.hasNext()) {
    max = it.next();
    while (it.hasNext()) {
      A a = it.next();
      if (cmp(a, max) > 0)
        max = a;
    }
  }
  return max;
}

/*Nah.
static int max(Collection<Integer> c) {
  int x = Integer.MIN_VALUE;
  for (int i : c) x = max(x, i);
  ret x;
}*/

static double max(double[] c) {
  if (c.length == 0) return Double.MIN_VALUE;
  double x = c[0];
  for (int i = 1; i < c.length; i++) x = Math.max(x, c[i]);
  return x;
}

static float max(float[] c) {
  if (c.length == 0) return Float.MAX_VALUE;
  float x = c[0];
  for (int i = 1; i < c.length; i++) x = Math.max(x, c[i]);
  return x;
}

static byte max(byte[] c) {
  byte x = -128;
  for (byte d : c) if (d > x) x = d;
  return x;
}

static short max(short[] c) {
  short x = -0x8000;
  for (short d : c) if (d > x) x = d;
  return x;
}

static int max(int[] c) {
  int x = Integer.MIN_VALUE;
  for (int d : c) if (d > x) x = d;
  return x;
}

static <A extends Comparable<A>> A max(A a, A b) {
  return cmp(a, b) >= 0 ? a : b;
}


static <A, B> Map<A, B> newWeakHashMap() {
  return _registerWeakMap(synchroMap(new WeakHashMap()));
}


static void newPing() {
  var tl = newPing_actionTL();
  Runnable action = tl == null ? null : tl.get();
  { if (action != null) action.run(); }
}


// TODO: test if android complains about this
static boolean isAWTThread() {
  if (isAndroid()) return false;
  if (isHeadless()) return false;
  return isAWTThread_awt();
}

static boolean isAWTThread_awt() {
  return SwingUtilities.isEventDispatchThread();
}


static boolean isTrue(Object o) {
  if (o instanceof Boolean)
    return ((Boolean) o).booleanValue();
  if (o == null) return false;
  if (o instanceof ThreadLocal) // TODO: remove this
    return isTrue(((ThreadLocal) o).get());
  throw fail(getClassName(o));
}

static boolean isTrue(Boolean b) {
  return b != null && b.booleanValue();
}


static void failIfUnlicensed() {
  assertTrue("license off", licensed());
}


static Thread currentThread() {
  return Thread.currentThread();
}


static RuntimeException rethrow(Throwable t) {
  
  if (t instanceof Error)
    _handleError((Error) t);
  
  throw t instanceof RuntimeException ? (RuntimeException) t : new RuntimeException(t);
}

static RuntimeException rethrow(String msg, Throwable t) {
  throw new RuntimeException(msg, t);
}


static <A, B> Map<A, B> newDangerousWeakHashMap() {
  return _registerDangerousWeakMap(synchroMap(new WeakHashMap()));
}

// initFunction: voidfunc(Map) - is called initially, and after clearing the map
static <A, B> Map<A, B> newDangerousWeakHashMap(Object initFunction) {
  return _registerDangerousWeakMap(synchroMap(new WeakHashMap()), initFunction);
}


static Object invokeMethod(Method m, Object o, Object... args) { try {
  try {
    return m.invoke(o, args);
  } catch (InvocationTargetException e) {
    throw rethrow(getExceptionCause(e));
  } catch (IllegalArgumentException e) {
    throw new IllegalArgumentException(e.getMessage() + " - was calling: " + m + ", args: " + joinWithSpace(classNames(args)));
  }
} catch (Exception __e) { throw rethrow(__e); } }


static boolean call_checkArgs(Method m, Object[] args, boolean debug) {
  Class<?>[] types = m.getParameterTypes();
  if (types.length != l(args)) {
    if (debug)
      print("Bad parameter length: " + args.length + " vs " + types.length);
    return false;
  }
  for (int i = 0; i < types.length; i++) {
    Object arg = args[i];
    if (!(arg == null ? !types[i].isPrimitive()
      : isInstanceX(types[i], arg))) {
      if (debug)
        print("Bad parameter " + i + ": " + arg + " vs " + types[i]);
      return false;
    }
  }
  return true;
}


static Field makeAccessible(Field f) {
  try {
    f.setAccessible(true);
  } catch (Throwable e) {
    // Note: The error reporting only works with Java VM option --illegal-access=deny
    
    vmBus_send("makeAccessible_error", e, f);
    
  }
  return f;
}

static Method makeAccessible(Method m) {
  try {
    m.setAccessible(true);
  } catch (Throwable e) {
    
    vmBus_send("makeAccessible_error", e, m);
    
  }
  return m;
}

static Constructor makeAccessible(Constructor c) {
  try {
    c.setAccessible(true);
  } catch (Throwable e) {
    
    vmBus_send("makeAccessible_error", e, c);
    
  }
  return c;
}




static BetterThreadLocal<PingSource> pingSource_tl_var = new BetterThreadLocal<PingSource>() {
  @Override
  public PingSource initialValue() {
    return ping_v3_pingSourceMaker().get(); 
  }
};

static BetterThreadLocal<PingSource> pingSource_tl() {
  return pingSource_tl_var;
}


static <A, B> Set<Map.Entry<A,B>> _entrySet(Map<A, B> map) {
  return map == null ? Collections.EMPTY_SET : map.entrySet();
}


static String unnullForIteration(String s) {
  return s == null ? "" : s;
}

static <A> Collection<A> unnullForIteration(Collection<A> l) {
  return l == null ? immutableEmptyList() : l;
}

static <A> List<A> unnullForIteration(List<A> l) { return l == null ? immutableEmptyList() : l; }
static byte[] unnullForIteration(byte[] l) { return l == null ? emptyByteArray() : l; }
static int[] unnullForIteration(int[] l) { return l == null ? emptyIntArray() : l; }
static char[] unnullForIteration(char[] l) { return l == null ? emptyCharArray() : l; }
static double[] unnullForIteration(double[] l) { return l == null ? emptyDoubleArray() : l; }
static short[] unnullForIteration(short[] l) { return l == null ? emptyShortArray() : l; }

static <A, B> Map<A, B> unnullForIteration(Map<A, B> l) {
  return l == null ? immutableEmptyMap() : l;
}

static <A> Iterable<A> unnullForIteration(Iterable<A> i) {
  return i == null ? immutableEmptyList() : i;
}

static <A> A[] unnullForIteration(A[] a) {
  return a == null ? (A[]) emptyObjectArray() : a;
}

static BitSet unnullForIteration(BitSet b) {
  return b == null ? new BitSet() : b;
}


static Pt unnullForIteration(Pt p) {
  return p == null ? new Pt() : p;
}


//ifclass Symbol

static Symbol unnullForIteration(Symbol s) {
  return s == null ? emptySymbol() : s;
}
//endif



static <A, B> Pair<A, B> unnullForIteration(Pair<A, B> p) {
  return p != null ? p : new Pair(null, null);
}


static long unnullForIteration(Long l) { return l == null ? 0L : l; }


static IterableIterator emptyIterableIterator_instance = new IterableIterator() {
  public Object next() { throw fail(); }
  public boolean hasNext() { return false; }
};

static <A> IterableIterator<A> emptyIterableIterator() {
  return emptyIterableIterator_instance; 
}


static <A> List<A> wrapArrayAsList(A[] a) {
  return a == null ? null : Arrays.asList(a);
}




static <A> IterableIterator<A> iteratorFromFunction_withEndMarker_f0(final F0<A> f) {
  class IFF2 extends IterableIterator<A> {
    A a;
    boolean have, done;
    
    public boolean hasNext() {
      getNext();
      return !done;
    }
    
    public A next() {
      getNext();
      if (done) throw fail();
      A _a = a;
      a = null;
      have = false;
      return _a;
    }
    
    void getNext() {
      if (done || have) return;
      Object o = f.get();
      if (o == iteratorFromFunction_endMarker)
        { done = true; return; }
      a = (A) o;
      have = true;
    }
  };
  return new IFF2();
}


static void swingAndWait(Runnable r) { try {
  if (isAWTThread())
    r.run();
  else {
    r = addThreadInfoToRunnable(r);
    executingSwingCode(r);
    EventQueue.invokeAndWait(r);
  }
} catch (Exception __e) { throw rethrow(__e); } }

static Object swingAndWait(Object f) {
  if (isAWTThread())
    return callF(f);
  else {
    Var result = new Var();
    swingAndWait(new Runnable() {  public void run() { try { 
      result.set(callF(f));
    
} catch (Exception __e) { throw rethrow(__e); } }  public String toString() { return "result.set(callF(f));"; }});
    return result.get();
  }
}


static String joinStrings(String sep, Object... strings) {
  return joinStrings(sep, Arrays.asList(strings));
}

static String joinStrings(String sep, Iterable strings) {
  StringBuilder buf = new StringBuilder();
  for (Object o : unnull(strings)) { 
    String s = strOrNull(o);
    if (nempty(s)) {
      if (nempty(buf)) buf.append(sep);
      buf.append(s);
    }
  }
  return str(buf);
}


static TreeSet<String> litciset(String... items) {
  TreeSet<String> set = caseInsensitiveSet();
  for (String a : items) set.add(a);
  return set;
}


static TreeSet<Symbol> litciset(Symbol... items) {
  TreeSet<Symbol> set = treeSet(); // HashSet would also do, but we might have the return type fixed somewhere, and they might want a NavigableMap.
  for (Symbol a : items) set.add(a);
  return set;
}



static boolean contains(Collection c, Object o) {
  return c != null && c.contains(o);
}

static boolean contains(Iterable it, Object a) {
  if (it != null)
    for (Object o : it)
      if (eq(a, o))
        return true;
  return false;
}

static boolean contains(Object[] x, Object o) {
  if (x != null)
    for (Object a : x)
      if (eq(a, o))
        return true;
  return false;
}

static boolean contains(String s, char c) {
  return s != null && s.indexOf(c) >= 0;
}

static boolean contains(String s, String b) {
  return s != null && s.indexOf(b) >= 0;
}

static boolean contains(BitSet bs, int i) {
  return bs != null && bs.get(i);
}


static <A> boolean contains(Producer<A> p, A a) {
  if (p != null && a != null) while (true) {
    A x = p.next();
    if (x == null) break;
    if (eq(x, a)) return true;
  }
  return false;
}



static boolean contains(Rect r, Pt p) { return rectContains(r, p); }



static boolean ewic(String a, String b) {
  return endsWithIgnoreCase(a, b);
}


static boolean ewic(String a, String b, Matches m) {
  return endsWithIgnoreCase(a, b, m);
}



static String dropSuffixIgnoreCase(String suffix, String s) {
  return ewic(s, suffix) ? s.substring(0, l(s)-l(suffix)) : s;
}


static boolean ewicOneOf(String s, String... l) {
  if (s != null) for (String x : l) if (ewic(s, x)) return true; return false;
}


static void _handleError(Error e) {
  //call(javax(), '_handleError, e);
}


static String repeat(char c, int n) {
  n = Math.max(n, 0);
  char[] chars = new char[n];
  for (int i = 0; i < n; i++)
    chars[i] = c;
  return new String(chars);
}

static <A> List<A> repeat(A a, int n) {
  n = Math.max(n, 0);
  List<A> l = new ArrayList(n);
  for (int i = 0; i < n; i++)
    l.add(a);
  return l;
}

static <A> List<A> repeat(int n, A a) {
  return repeat(a, n);
}




static WeakHasherMap<Symbol, Boolean> symbol_map = new WeakHasherMap(new Hasher<Symbol>() {
  public int hashCode(Symbol symbol) { return symbol.text.hashCode(); }
  public boolean equals(Symbol a, Symbol b) {
    if (a == null) return b == null;
    return b != null && eq(a.text, b.text);
  }
});



static Symbol symbol(String s) {
  
  
  if (s == null) return null;
  synchronized(symbol_map) {
    // TODO: avoid object creation by passing the string to findKey
    Symbol symbol = new Symbol(s, true);
    Symbol existingSymbol = symbol_map.findKey(symbol);
    if (existingSymbol == null)
      symbol_map.put(existingSymbol = symbol, true);
    
      
    return existingSymbol;
  }
  
}

static Symbol symbol(CharSequence s) {
  if (s == null) return null;
  
  
  if (s instanceof Symbol) return (Symbol) s;
  if (s instanceof String) return symbol((String) s);
  return symbol(str(s));
  
}

static Symbol symbol(Object o) {
  return symbol((CharSequence) o);
}


static <A> String joinWithComma(Iterable<A> c) {
  return join(", ", c);
}

static String joinWithComma(Object... c) {
  return join(", ", c);
}

static String joinWithComma(String... c) {
  return join(", ", c);
}


static String joinWithComma(Pair p) {
  return p == null ? "" : joinWithComma(str(p.a), str(p.b));
}



static List<String> allToString(Iterable c) {
  List<String> l = new ArrayList();
  for (Object o : unnull(c)) l.add(str(o));
  return l;
}

static List<String> allToString(Object[] c) {
  List<String> l = new ArrayList();
  for (Object o : unnull(c)) l.add(str(o));
  return l;
}


// binary legacy signature
static Object[] toObjectArray(Collection c) {
  return toObjectArray((Iterable) c);
}

static Object[] toObjectArray(Iterable c) {
  List l = asList(c);
  return l.toArray(new Object[l.size()]);
}



static List _registerWeakMap_preList;

static <A> A _registerWeakMap(A map) {
  if (javax() == null) {
    // We're in class init
    if (_registerWeakMap_preList == null) _registerWeakMap_preList = synchroList();
    _registerWeakMap_preList.add(map);
    return map;
  }
  
  try {
    call(javax(), "_registerWeakMap", map);
  } catch (Throwable e) {
    printException(e);
    print("Upgrade JavaX!!");
  }
  return map;
}

static void _onLoad_registerWeakMap() {
  assertNotNull(javax());
  if (_registerWeakMap_preList == null) return;
  for (Object o : _registerWeakMap_preList)
    _registerWeakMap(o);
  _registerWeakMap_preList = null;
}


static Map synchroMap() {
  return synchroHashMap();
}

static <A, B> Map<A, B> synchroMap(Map<A, B> map) {
  
  
    return Collections.synchronizedMap(map);
  
}


static x30_pkg.x30_util.BetterThreadLocal<Runnable> newPing_actionTL;

static x30_pkg.x30_util.BetterThreadLocal<Runnable> newPing_actionTL() {
  if (newPing_actionTL == null)
    newPing_actionTL = vm_generalMap_getOrCreate("newPing_actionTL",
      () -> {
        Runnable value =  (Runnable) (callF_gen(vm_generalMap_get("newPing_valueForNewThread")));
        var tl = new x30_pkg.x30_util.BetterThreadLocal<Runnable>();
        tl.set(value);
        return tl;
      });
  return newPing_actionTL;
}



static int isAndroid_flag;

static boolean isAndroid() {
  if (isAndroid_flag == 0)
    isAndroid_flag = System.getProperty("java.vendor").toLowerCase().indexOf("android") >= 0 ? 1 : -1;
  return isAndroid_flag > 0;
}



static Boolean isHeadless_cache;

static boolean isHeadless() {
  if (isHeadless_cache != null) return isHeadless_cache;
  if (isAndroid()) return isHeadless_cache = true;
  if (GraphicsEnvironment.isHeadless()) return isHeadless_cache = true;
  
  // Also check if AWT actually works.
  // If DISPLAY variable is set but no X server up, this will notice.
  
  try {
    SwingUtilities.isEventDispatchThread();
    return isHeadless_cache = false;
  } catch (Throwable e) { return isHeadless_cache = true; }
}


static void assertTrue(Object o) {
  if (!(eq(o, true) /*|| isTrue(pcallF(o))*/))
    throw fail(str(o));
}
  
static boolean assertTrue(String msg, boolean b) {
  if (!b)
    throw fail(msg);
  return b;
}

static boolean assertTrue(boolean b) {
  if (!b)
    throw fail("oops");
  return b;
}

static boolean assertTrue(Scorer scorer, boolean b) {
  scorer.add(b);
  return b;
}


static volatile boolean licensed_yes = true;

static boolean licensed() {
  if (!licensed_yes) return false;
  ping_okInCleanUp();
  return true;
}

static void licensed_off() {
  licensed_yes = false;
}


static List<Pair> _registerDangerousWeakMap_preList;

static <A> A _registerDangerousWeakMap(A map) {
  return _registerDangerousWeakMap(map, null);
}

static <A> A _registerDangerousWeakMap(A map, Object init) {
  
  callF(init, map);
  
  if (init instanceof String) {
    final String f =  (String) init;
    init = new VF1<Map>() { public void get(Map map) { try {  callMC(f, map) ; } catch (Exception __e) { throw rethrow(__e); } }
  public String toString() { return "callMC(f, map)"; }};
  }
    
  if (javax() == null) {
    // We're in class init
    if (_registerDangerousWeakMap_preList == null) _registerDangerousWeakMap_preList = synchroList();
    _registerDangerousWeakMap_preList.add(pair(map, init));
    return map;
  }
  
  call(javax(), "_registerDangerousWeakMap", map, init);
  
  return map;
}

static void _onLoad_registerDangerousWeakMap() {
  
  assertNotNull(javax());
  if (_registerDangerousWeakMap_preList == null) return;
  for (Pair p : _registerDangerousWeakMap_preList)
    _registerDangerousWeakMap(p.a, p.b);
  _registerDangerousWeakMap_preList = null;
  
}


static Throwable getExceptionCause(Throwable e) {
  Throwable c = e.getCause();
  return c != null ? c : e;
}


static String joinWithSpace(Iterable c) {
  return join(" ", c);
}

static String joinWithSpace(Object... c) {
  return join(" ", c);
}



static List<String> classNames(Collection l) {
  return getClassNames(l);
}

static List<String> classNames(Object[] l) {
  return getClassNames(asList(l));
}


static volatile StringBuffer local_log = new StringBuffer(); // not redirected




static boolean printAlsoToSystemOut = true;

static volatile Appendable print_log = local_log; // might be redirected, e.g. to main bot

// in bytes - will cut to half that
static volatile int print_log_max = 1024*1024;
static volatile int local_log_max = 100*1024;

static boolean print_silent = false; // total mute if set

static Object print_byThread_lock = new Object();
static volatile ThreadLocal<Object> print_byThread; // special handling by thread - prefers F1<S, Bool>
static volatile Object print_allThreads;
static volatile Object print_preprocess;

static void print() {
  print("");
}

static <A> A print(String s, A o) {
  print(combinePrintParameters(s, o));
  return o;
}

// slightly overblown signature to return original object...
static <A> A print(A o) {
  ping_okInCleanUp();
  if (print_silent) return o;
  String s = o + "\n";
  print_noNewLine(s);
  return o;
}

static void print_noNewLine(String s) {
  
  try {
    Object f = getThreadLocal(print_byThread_dontCreate());
    if (f == null) f = print_allThreads;
      if (f != null)
        // We do need the general callF machinery here as print_byThread is sometimes shared between modules
        if (isFalse(
          
            f instanceof F1 ? ((F1) f).get(s) :
          
          callF(f, s))) return;
  } catch (Throwable e) {
    System.out.println(getStackTrace(e));
  }
  

  print_raw(s);
}

static void print_raw(String s) {
  
  if (print_preprocess != null) s = (String) callF(print_preprocess, s);
  s = fixNewLines(s);
  
  Appendable loc = local_log;
  Appendable buf = print_log;
  int loc_max = print_log_max;
  if (buf != loc && buf != null) {
    print_append(buf, s, print_log_max);
    loc_max = local_log_max;
  }
  if (loc != null) 
    print_append(loc, s, loc_max);
  
  
  if (printAlsoToSystemOut)
    System.out.print(s);
  
  
  vmBus_send("printed", mc(), s);
  
}

static void print_autoRotate() {
  
}


static boolean isInstanceX(Class type, Object arg) {
  if (type == boolean.class) return arg instanceof Boolean;
  if (type == int.class) return arg instanceof Integer;
  if (type == long.class) return arg instanceof Long;
  if (type == float.class) return arg instanceof Float;
  if (type == short.class) return arg instanceof Short;
  if (type == char.class) return arg instanceof Character;
  if (type == byte.class) return arg instanceof Byte;
  if (type == double.class) return arg instanceof Double;
  return type.isInstance(arg);
}


static void vmBus_send(String msg, Object... args) {
  Object arg = vmBus_wrapArgs(args);
  pcallFAll_minimalExceptionHandling(vm_busListeners_live(), msg, arg);
  pcallFAll_minimalExceptionHandling(vm_busListenersByMessage_live().get(msg), msg, arg);
}

static void vmBus_send(String msg) {
  vmBus_send(msg, (Object) null);
}


static IF0<PingSource> ping_v3_pingSourceMaker_cache;
static IF0<PingSource> ping_v3_pingSourceMaker() { if (ping_v3_pingSourceMaker_cache == null) ping_v3_pingSourceMaker_cache = ping_v3_pingSourceMaker_load(); return ping_v3_pingSourceMaker_cache;}

static IF0<PingSource> ping_v3_pingSourceMaker_load() {
  return or((IF0) vm_generalMap_get("ping_v3_pingSourceMaker"), () -> null);
}



static <A> List<A> immutableEmptyList() {
  return Collections.emptyList();
}


static byte[] emptyByteArray_a = new byte[0];
static byte[] emptyByteArray() { return emptyByteArray_a; }


static short[] emptyShortArray = new short[0];
static short[] emptyShortArray() { return emptyShortArray; }


static <A, B> Map<A, B> immutableEmptyMap() {
  return Collections.emptyMap();
}




static AutoCloseable tempInterceptPrintIfNotIntercepted(F1<String, Boolean> f) {
  return print_byThread().get() == null ? tempInterceptPrint(f) : null;
}


static Runnable addThreadInfoToRunnable(final Object r) {
  final Object info = _threadInfo();
  return info == null ? asRunnable(r) : new Runnable() {  public void run() { try {  _inheritThreadInfo(info); callF(r); 
} catch (Exception __e) { throw rethrow(__e); } }  public String toString() { return "_inheritThreadInfo(info); callF(r);"; }};
}


//static event executingSwingCode(Runnable code);

static transient Set<IVF1<Runnable>> onExecutingSwingCode;
public static void onExecutingSwingCode(IVF1<Runnable> f) { onExecutingSwingCode = createOrAddToSyncLinkedHashSet(onExecutingSwingCode, f); }
public static void removeExecutingSwingCodeListener(IVF1<Runnable> f) { main.remove(onExecutingSwingCode, f); }
public static void executingSwingCode(Runnable code) {  if (onExecutingSwingCode != null) for (var listener : onExecutingSwingCode) pcallF_typed(listener, code); }


static String strOrNull(Object o) {
  return o == null ? null : str(o);
}


static TreeSet<String> caseInsensitiveSet() {
  return caseInsensitiveSet_treeSet();
}

static TreeSet<String> caseInsensitiveSet(Collection<String> c) {
  return caseInsensitiveSet_treeSet(c);
}


static <A> TreeSet<A> treeSet() {
  return new TreeSet();
}


static boolean rectContains(int x1, int y1, int w, int h, Pt p) {
  return p.x >= x1 && p.y >= y1 && p.x < x1+w && p.y < y1+h;
}

static boolean rectContains(Rect a, Rect b) {
  return b.x >= a.x && b.y >= a.y && b.x2() <= a.x2() && b.y2() <= a.y2();
}

static boolean rectContains(Rect a, Rectangle b) {
  return rectContains(a, toRect(b));
}

static boolean rectContains(Rect a, int x, int y) {
  return a != null && a.contains(x, y);
}

static boolean rectContains(Rect a, Pt p) {
  return a != null && p != null && a.contains(p);
}


static boolean endsWithIgnoreCase(String a, String b) {
  int la = l(a), lb = l(b);
  return la >= lb && regionMatchesIC(a, la-lb, b, 0, lb);
}


static boolean endsWithIgnoreCase(String a, String b, Matches m) {
  if (!endsWithIgnoreCase(a, b)) return false;
  if (m != null)
    m.m = new String[] { substring(a, 0, l(a)-l(b)) };
  return true;
}



public static <A> String join(String glue, Iterable<A> strings) {
  if (strings == null) return "";
  if (strings instanceof Collection) {
    if (((Collection) strings).size() == 1) return strOrEmpty(first((Collection) strings));
  }
  StringBuilder buf = new StringBuilder();
  Iterator<A> i = strings.iterator();
  if (i.hasNext()) {
    buf.append(strOrEmpty(i.next()));
    while (i.hasNext())
      buf.append(glue).append(strOrEmpty(i.next()));
  }
  return buf.toString();
}

public static String join(String glue, String... strings) {
  return join(glue, Arrays.asList(strings));
}

public static String join(String glue, Object... strings) {
  return join(glue, Arrays.asList(strings));
}

static <A> String join(Iterable<A> strings) {
  return join("", strings);
}

static <A> String join(Iterable<A> strings, String glue) {
  return join(glue, strings);
}

public static String join(String[] strings) {
  return join("", strings);
}


static String join(String glue, Pair p) {
  return p == null ? "" : str(p.a) + glue + str(p.b);
}



static Class javax() {
  return getJavaX();
}


static <A> List<A> synchroList() {
  return synchroList(new ArrayList<A>());
}

static <A> List<A> synchroList(List<A> l) {
  
  
    return Collections.synchronizedList(l);
  
}



static Object call(Object o) {
  return callF(o);
}

// varargs assignment fixer for a single string array argument
static Object call(Object o, String method, String[] arg) {
  return call(o, method, new Object[] {arg});
}

static Object call(Object o, String method, Object... args) {
  //ret call_cached(o, method, args);
  return call_withVarargs(o, method, args);
}


static <A extends Throwable> A printException(A e) {
  printStackTrace(e);
  return e;
}


static <A> A assertNotNull(A a) {
  assertTrue(a != null);
  return a;
}

static <A> A assertNotNull(String msg, A a) {
  assertTrue(msg, a != null);
  return a;
}


static <A> A assertNotNull(Scorer scorer, String msg, A a) {
  if (scorer == null) return assertNotNull(msg, a);
  if (a == null) {
    print("BAD - " + msg + " is null: " + a);
    scorer.add(false);
  } else {
    print("OK, " + msg + " not null: " + a);
    scorer.add(true);
  }
  return a;
}



static Map synchroHashMap() {
  return synchronizedMap(new HashMap());
}



static <A> A vm_generalMap_getOrCreate(Object key, F0<A> create) {
  return vm_generalMap_getOrCreate(key, f0ToIF0(create));
}

static <A> A vm_generalMap_getOrCreate(Object key, IF0<A> create) {
  Map generalMap = vm_generalMap();
  if (generalMap == null) return null; // must be x30 init
  
  synchronized(generalMap) { // should switch to locks here
    A a =  (A) (vm_generalMap_get(key));
    if (a == null)
      vm_generalMap_put(key, a = create == null ? null : create.get());
    return a;
  }
}




  static <A> A callF_gen(F0<A> f) {
    return f == null ? null : f.get();
  }



  static <A, B> B callF_gen(F1<A, B> f, A a) {
    return f == null ? null : f.get(a);
  }



  static <A> A callF_gen(IF0<A> f) {
    return f == null ? null : f.get();
  }



  static <A, B> B callF_gen(IF1<A, B> f, A a) {
    return f == null ? null : f.get(a);
  }


static <A, B> B callF_gen(A a, IF1<A, B> f) {
  return f == null ? null : f.get(a);
}




  static <A, B, C> C callF_gen(IF2<A, B, C> f, A a, B b) {
    return f == null ? null : f.get(a, b);
  }



  static <A> void callF_gen(VF1<A> f, A a) {
    { if (f != null) f.get(a); }
  }


static <A> void callF_gen(A a, IVF1<A> f) {
  { if (f != null) f.get(a); }
}

static <A> void callF_gen(IVF1<A> f, A a) {
  { if (f != null) f.get(a); }
}

static Object callF_gen(Runnable r) { { if (r != null) r.run(); } return null; }

static Object callF_gen(Object f, Object... args) {
  return callF(f, args);
}


static Object vm_generalMap_get(Object key) {
  return vm_generalMap().get(key);
}


static void ping_okInCleanUp() {


  if (ping_pauseAll || ping_anyActions)
    ping_impl(true);


}


static HashMap<String, List<Method>> callMC_cache = new HashMap();
static String callMC_key;
static Method callMC_value;

// varargs assignment fixer for a single string array argument
static Object callMC(String method, String[] arg) {
  return callMC(method, new Object[] {arg});
}

static Object callMC(String method, Object... args) { try {
  Method me;
  if (callMC_cache == null) callMC_cache = new HashMap(); // initializer time workaround
  synchronized(callMC_cache) {
    me = method == callMC_key ? callMC_value : null;
  }
  if (me != null) try {
    return invokeMethod(me, null, args);
  } catch (IllegalArgumentException e) {
    throw new RuntimeException("Can't call " + me + " with arguments " + classNames(args), e);
  }

  List<Method> m;
  synchronized(callMC_cache) {
    m = callMC_cache.get(method);
  }
  if (m == null) {
    if (callMC_cache.isEmpty()) {
      callMC_makeCache();
      m = callMC_cache.get(method);
    }
    if (m == null) throw fail("Method named " + method + " not found in main");
  }
  int n = m.size();
  if (n == 1) {
    me = m.get(0);
    synchronized(callMC_cache) {
      callMC_key = method;
      callMC_value = me;
    }
    try {
      return invokeMethod(me, null, args);
    } catch (IllegalArgumentException e) {
      throw new RuntimeException("Can't call " + me + " with arguments " + classNames(args), e);
    }
  }
  for (int i = 0; i < n; i++) {
    me = m.get(i);
    if (call_checkArgs(me, args, false))
      return invokeMethod(me, null, args);
  }
  throw fail("No method called " + method + " with arguments (" + joinWithComma(getClasses(args)) + ") found in main");
} catch (Exception __e) { throw rethrow(__e); } }

static void callMC_makeCache() {
  synchronized(callMC_cache) {
    callMC_cache.clear();
    Class _c = (Class) mc(), c = _c;
    while (c != null) {
      for (Method m : c.getDeclaredMethods())
        if ((m.getModifiers() & java.lang.reflect.Modifier.STATIC) != 0) {
          makeAccessible(m);
          multiMapPut(callMC_cache, m.getName(), m);
        }
      c = c.getSuperclass();
    }
  }
}


static List<String> getClassNames(Collection l) {
  List<String> out = new ArrayList();
  if (l != null) for (Object o : l)
    out.add(o == null ? null : getClassName(o));
  return out;
}


static String combinePrintParameters(String s, Object o) {
  return (endsWithLetterOrDigit(s) ? s + ": " : s) + o;
}


// this syntax should be removed...
static Object getThreadLocal(Object o, String name) {
  ThreadLocal t =  (ThreadLocal) (getOpt(o, name));
  return t != null ? t.get() : null;
}

static <A> A getThreadLocal(ThreadLocal<A> tl) {
  return tl == null ? null : tl.get();
}

static <A> A getThreadLocal(ThreadLocal<A> tl, A defaultValue) {
  return or(getThreadLocal(tl), defaultValue);
}


static ThreadLocal<Object> print_byThread_dontCreate() {
  return print_byThread;
}


static boolean isFalse(Object o) {
  return eq(false, o);
}


static String getStackTrace(Throwable throwable) {
  lastException(throwable);
  return getStackTrace_noRecord(throwable);
}

static String getStackTrace_noRecord(Throwable throwable) {
  StringWriter writer = new StringWriter();
  throwable.printStackTrace(new PrintWriter(writer));
  return hideCredentials(writer.toString());
}

static String getStackTrace() {
  return getStackTrace_noRecord(new Throwable());
}

static String getStackTrace(String msg) {
  return getStackTrace_noRecord(new Throwable(msg));
}


static String fixNewLines(String s) {
  int i = indexOf(s, '\r');
  if (i < 0) return s;
  int l = s.length();
  StringBuilder out = new StringBuilder(l);
  out.append(s, 0, i);
  for (; i < l; i++) {
    char c = s.charAt(i);
    if (c != '\r')
      out.append(c);
    else {
      out.append('\n');
      if (i+1 < l && s.charAt(i+1) == '\n') ++i;
    }
  }
  return out.toString();
}


static void print_append(Appendable buf, String s, int max) { try {
  synchronized(buf) {
    buf.append(s);
    if (buf instanceof StringBuffer)
      rotateStringBuffer(((StringBuffer) buf), max);
    else if (buf instanceof StringBuilder)
      rotateStringBuilder(((StringBuilder) buf), max);
  }
} catch (Exception __e) { throw rethrow(__e); } }


static Class mc() {
  return main.class;
}


static Object vmBus_wrapArgs(Object... args) {
  return empty(args) ? null
    : l(args) == 1 ? args[0]
    : args;
}


static void pcallFAll_minimalExceptionHandling(Collection l, Object... args) {
  if (l != null) for  (Object f : cloneList(l)) { ping(); pcallF_minimalExceptionHandling(f, args); }
}

static void pcallFAll_minimalExceptionHandling(Iterator it, Object... args) {
  while  (it.hasNext()) { ping(); pcallF_minimalExceptionHandling(it.next(), args); }
}


static Set vm_busListeners_live_cache;
static Set vm_busListeners_live() { if (vm_busListeners_live_cache == null) vm_busListeners_live_cache = vm_busListeners_live_load(); return vm_busListeners_live_cache;}

static Set vm_busListeners_live_load() {
  return vm_generalIdentityHashSet("busListeners");
}


static Map<String, Set> vm_busListenersByMessage_live_cache;
static Map<String, Set> vm_busListenersByMessage_live() { if (vm_busListenersByMessage_live_cache == null) vm_busListenersByMessage_live_cache = vm_busListenersByMessage_live_load(); return vm_busListenersByMessage_live_cache;}

static Map<String, Set> vm_busListenersByMessage_live_load() {
  return vm_generalHashMap("busListenersByMessage");
}


static <A> A or(A a, A b) {
  return a != null ? a : b;
}




static ThreadLocal<Object> print_byThread() {
  synchronized(print_byThread_lock) {
    if (print_byThread == null)
      print_byThread = new ThreadLocal();
  }
  return print_byThread;
}


// f can return false to suppress regular printing
// call print_raw within f to actually print something
static AutoCloseable tempInterceptPrint(F1<String, Boolean> f) {
  return tempSetThreadLocal(print_byThread(), f);
}


static List<VF1<Map>> _threadInfo_makers = synchroList();

static Object _threadInfo() {
  if (empty(_threadInfo_makers)) return null;
  HashMap map = new HashMap();
  pcallFAll(_threadInfo_makers, map);
  return map;
}


static Runnable asRunnable(Object o) {
  return toRunnable(o);
}




static void _inheritThreadInfo(Object info) {
  _threadInheritInfo(info);
}


static <A> Set<A> createOrAddToSyncLinkedHashSet(Set<A> set, A a) {
  if (set == null) set = syncLinkedHashSet();
  set.add(a);
  return set;
}


static Class main() {
  return getMainClass();
}


static <A> void remove(List<A> l, int i) {
  if (l != null && i >= 0 && i < l(l))
    l.remove(i);
}

static <A> void remove(Collection<A> l, A a) {
  if (l != null) l.remove(a);
}

static <A, B> B remove(Map<A, B> map, Object a) {
  return map == null ? null : map.remove(a);
}

static void remove(BitSet bs, int i) {
  bs.clear(i);
}



static <A> A pcallF_typed(F0<A> f) {
  try { return f == null ? null : f.get(); } catch (Throwable __e) { pcallFail(__e); } return null;
}



static <A, B> B pcallF_typed(F1<A, B> f, A a) {
  try { return f == null ? null : f.get(a); } catch (Throwable __e) { pcallFail(__e); } return null;
}



static <A> void pcallF_typed(VF1<A> f, A a) {
  try {
    { if (f != null) f.get(a); }
  } catch (Throwable __e) { pcallFail(__e); }
}


static <A> void pcallF_typed(IVF1<A> f, A a) {
  try {
    { if (f != null) f.get(a); }
  } catch (Throwable __e) { pcallFail(__e); }
}

static <A, B> void pcallF_typed(IVF2<A, B> f, A a, B b) {
  try {
    { if (f != null) f.get(a, b); }
  } catch (Throwable __e) { pcallFail(__e); }
}

static Object pcallF_typed(Runnable r) {
  try { { if (r != null) r.run(); } } catch (Throwable __e) { pcallFail(__e); } return null;
}

static <A> A pcallF_typed(IF0<A> f) {
  try { return f == null ? null : f.get(); } catch (Throwable __e) { pcallFail(__e); } return null;
}

static <A, B> B pcallF_typed(IF1<A, B> f, A a) {
  try { return f == null ? null : f.get(a); } catch (Throwable __e) { pcallFail(__e); } return null;
}



static TreeSet<String> caseInsensitiveSet_treeSet() {
  return new TreeSet(caseInsensitiveComparator());
}

static TreeSet<String> caseInsensitiveSet_treeSet(Collection<String> c) {
  return toCaseInsensitiveSet_treeSet(c);
}




static Rect toRect(Rectangle r) {
  return r == null ? null : new Rect(r);
}

static Rect toRect(RectangularShape r) {
  return r == null ? null : toRect(r.getBounds());
}



static Rect toRect(Rect r) { return r; }


static boolean regionMatchesIC(String a, int offsetA, String b, int offsetB, int len) {
  
  
    return a != null && a.regionMatches(true, offsetA, b, offsetB, len);
  
}


static String substring(String s, int x) {
  return substring(s, x, strL(s));
}

static String substring(String s, int x, int y) {
  if (s == null) return null;
  if (x < 0) x = 0;
  int n = s.length();
  if (y < x) y = x;
  if (y > n) y = n;
  if (x >= y) return "";
  return s.substring(x, y);
}


static String substring(String s, IntRange r) {
  return r == null ? null : substring(s, r.start, r.end);
}


// convenience method for quickly dropping a prefix
static String substring(String s, CharSequence l) {
  return substring(s, lCharSequence(l));
}


static String strOrEmpty(Object o) {
  return o == null ? "" : str(o);
}


static Class __javax;

static Class getJavaX() { try {
  
  return __javax;
} catch (Exception __e) { throw rethrow(__e); } }

static void __setJavaX(Class j) {
  __javax = j;
  _onJavaXSet();
}


static Object call_withVarargs(Object o, String methodName, Object... args) { try {
  if (o == null) return null;
  
  if (o instanceof Class) {
    Class c = (Class) o;
    _MethodCache cache = callOpt_getCache(c);
    
    Method me = cache.findStaticMethod(methodName, args);
    if (me != null)
      return invokeMethod(me, null, args);
      
    // try varargs
    List<Method> methods = cache.cache.get(methodName);
    if (methods != null) methodSearch: for (Method m : methods) {
      { if (!(m.isVarArgs())) continue; }
      { if (!(isStaticMethod(m))) continue; }
      Object[] newArgs = massageArgsForVarArgsCall(m, args);
      if (newArgs != null)
        return invokeMethod(m, null, newArgs);
    }
    
    throw fail("Method " + c.getName() + "." + methodName + "(" + formatArgumentClasses(args) + ") not found");
  } else {
    Class c = o.getClass();
    _MethodCache cache = callOpt_getCache(c);

    Method me = cache.findMethod(methodName, args);
    if (me != null)
      return invokeMethod(me, o, args);
      
    // try varargs
    List<Method> methods = cache.cache.get(methodName);
    if (methods != null) methodSearch: for (Method m : methods) {
      { if (!(m.isVarArgs())) continue; }
      Object[] newArgs = massageArgsForVarArgsCall(m, args);
      if (newArgs != null)
        return invokeMethod(m, o, newArgs);
    }
    
    throw fail("Method " + c.getName() + "." + methodName + "(" + formatArgumentClasses(args) + ") not found");
  }
} catch (Exception __e) { throw rethrow(__e); } }


static <A extends Throwable> A printStackTrace(A e) {
  // we go to system.out now - system.err is nonsense
  if (e != null) print(getStackTrace(e));
  return e;
}

static void printStackTrace() {
  printStackTrace(new Throwable());
}

static void printStackTrace(String msg) {
  printStackTrace(new Throwable(msg));
}

static void printStackTrace(String msg, Throwable e) {
  printStackTrace(new Throwable(msg, e));
}


static Map synchronizedMap() {
  return synchroMap();
}

static <A, B> Map<A, B> synchronizedMap(Map<A, B> map) {
  return synchroMap(map);
}


static <A> IF0<A> f0ToIF0(F0<A> f) {
  return f == null ? null : () -> f.get();
}


static Map vm_generalMap_map;

static Map vm_generalMap() {
  if (vm_generalMap_map == null)
    
    
    
    vm_generalMap_map = (Map) get(javax(), "generalMap");
    
    
  return vm_generalMap_map;
}


static Object vm_generalMap_put(Object key, Object value) {
  return mapPutOrRemove(vm_generalMap(), key, value);
}


static List<Class> getClasses(Object[] array) {
  List<Class> l = emptyList(l(array));
  for (Object o : array) l.add(_getClass(o));
  return l;
}


static <A, B> void multiMapPut(Map<A, List<B>> map, A a, B b) {
  List<B> l = map.get(a);
  if (l == null)
    map.put(a, l = new ArrayList());
  l.add(b);
}


static <A, B> void multiMapPut(MultiMap<A, B> mm, A key, B value) {
  if (mm != null && key != null && value != null) mm.put(key, value);
}



static boolean endsWithLetterOrDigit(String s) {
  return s != null && s.length() > 0 && Character.isLetterOrDigit(s.charAt(s.length()-1));
}


static Object getOpt(Object o, String field) {
  return getOpt_cached(o, field);
}

static Object getOpt(String field, Object o) {
  return getOpt_cached(o, field);
}

static Object getOpt_raw(Object o, String field) { try {
  Field f = getOpt_findField(o.getClass(), field);
  if (f == null) return null;
  makeAccessible(f);
  return f.get(o);
} catch (Exception __e) { throw rethrow(__e); } }

// access of static fields is not yet optimized
static Object getOpt(Class c, String field) { try {
  if (c == null) return null;
  Field f = getOpt_findStaticField(c, field);
  if (f == null) return null;
  makeAccessible(f);
  return f.get(null);
} catch (Exception __e) { throw rethrow(__e); } }

static Field getOpt_findStaticField(Class<?> c, String field) {
  Class _c = c;
  do {
    for (Field f : _c.getDeclaredFields())
      if (f.getName().equals(field) && (f.getModifiers() & java.lang.reflect.Modifier.STATIC) != 0)
        return f;
    _c = _c.getSuperclass();
  } while (_c != null);
  return null;
}



// PersistableThrowable doesn't hold GC-disturbing class references in backtrace
static volatile PersistableThrowable lastException_lastException;

static PersistableThrowable lastException() {
  return lastException_lastException;
}

static void lastException(Throwable e) {
  lastException_lastException = persistableThrowable(e);
}


static String hideCredentials(URL url) { return url == null ? null : hideCredentials(str(url)); }

static String hideCredentials(String url) {
  try {
    if (startsWithOneOf(url, "http://", "https://") && isAGIBlueDomain(hostNameFromURL(url))) return url;
  } catch (Throwable e) {
    print("HideCredentials", e);
  }
  return url.replaceAll("([&?])(_pass|key|cookie)=[^&\\s\"]*", "$1$2=<hidden>");
}

static String hideCredentials(Object o) {
  return hideCredentials(str(o));
}


static <A> int indexOf(List<A> l, A a, int startIndex) {
  if (l == null) return -1;
  int n = l(l);
  for (int i = startIndex; i < n; i++)
    if (eq(l.get(i), a))
      return i;
  return -1;
}

static <A> int indexOf(List<A> l, int startIndex, A a) {
  return indexOf(l, a, startIndex);
}

static <A> int indexOf(List<A> l, A a) {
  if (l == null) return -1;
  return l.indexOf(a);
}

static int indexOf(String a, String b) {
  return a == null || b == null ? -1 : a.indexOf(b);
}

static int indexOf(String a, String b, int i) {
  return a == null || b == null ? -1 : a.indexOf(b, i);
}

static int indexOf(String a, char b) {
  return a == null ? -1 : a.indexOf(b);
}

static int indexOf(String a, int i, char b) {
  return indexOf(a, b, i);
}

static int indexOf(String a, char b, int i) {
  return a == null ? -1 : a.indexOf(b, i);
}

static int indexOf(String a, int i, String b) {
  return a == null || b == null ? -1 : a.indexOf(b, i);
}

static <A> int indexOf(A[] x, A a) {
  int n = l(x);
  for (int i = 0; i < n; i++)
    if (eq(x[i], a))
      return i;
  return -1;
}

static <A> int indexOf(Iterable<A> l, A a) {
  if (l == null) return -1;
  int i = 0;
  for (A x : l) {
    if (eq(x, a))
      return i;
    i++;
  }
  return -1;
}



static void rotateStringBuffer(StringBuffer buf, int max) { try {
  if (buf == null) return;
  synchronized(buf) {
    if (buf.length() <= max) return;
    
    try {
      int newLength = max/2;
      int ofs = buf.length()-newLength;
      String newString = buf.substring(ofs);
      buf.setLength(0);
      buf.append("[...] ").append(newString);
    } catch (Exception e) {
      buf.setLength(0);
    }
    buf.trimToSize();
  }
} catch (Exception __e) { throw rethrow(__e); } }


static void rotateStringBuilder(StringBuilder buf, int max) { try {
  if (buf == null) return;
  synchronized(buf) {
    if (buf.length() <= max) return;
    
    try {
      int newLength = max/2;
      int ofs = buf.length()-newLength;
      String newString = buf.substring(ofs);
      buf.setLength(0);
      buf.append("[...] ").append(newString);
    } catch (Exception e) {
      buf.setLength(0);
    }
    buf.trimToSize();
  }
} catch (Exception __e) { throw rethrow(__e); } }


static <A> ArrayList<A> cloneList(Iterable<A> l) {
  return l instanceof Collection ? cloneList((Collection) l) : asList(l);
}

static <A> ArrayList<A> cloneList(Collection<A> l) {
  if (l == null) return new ArrayList();
  synchronized(collectionMutex(l)) {
    return new ArrayList<A>(l);
  }
}


static Object pcallF_minimalExceptionHandling(Object f, Object... args) {
  try {
    return callFunction(f, args);
  } catch (Throwable e) {
    System.out.println(getStackTrace(e));
    _storeException(e);
  }
  return null;
}


static Set vm_generalIdentityHashSet(Object name) {
  synchronized(vm_generalMap()) {
    Set set =  (Set) (vm_generalMap_get(name));
    if (set == null)
      vm_generalMap_put(name, set = syncIdentityHashSet());
    return set;
  }
}



static Map vm_generalHashMap(Object name) {
  synchronized(vm_generalMap()) {
    Map m =  (Map) (vm_generalMap_get(name));
    if (m == null)
      vm_generalMap_put(name, m = syncHashMap());
    return m;
  }
}





static <A> AutoCloseable tempSetThreadLocal(final ThreadLocal<A> tl, A a) {
  if (tl == null) return null;
  final A prev = setThreadLocal(tl, a);
  return new AutoCloseable() { public String toString() { return "tl.set(prev);"; } public void close() throws Exception { tl.set(prev); }};
}


static void pcallFAll(Collection l, Object... args) {
  if (l != null) for (Object f : cloneList(l)) pcallF(f, args);
}

static void pcallFAll(Iterator it, Object... args) {
  while (it.hasNext()) pcallF(it.next(), args);
}


static Runnable toRunnable(final Object o) {
  if (o == null) return null;
  if (o instanceof Runnable) return (Runnable) o;
  
  if (o instanceof String) throw fail("callF_legacy");
  
  return new Runnable() {  public void run() { try {  callF(o) ;
} catch (Exception __e) { throw rethrow(__e); } }  public String toString() { return "callF(o)"; }};
}


static List<VF1<Map>> _threadInheritInfo_retrievers = synchroList();

static void _threadInheritInfo(Object info) {
  if (info == null) return;
  pcallFAll(_threadInheritInfo_retrievers, (Map) info);
}


static <A> Set<A> syncLinkedHashSet() {
  return synchroLinkedHashSet();
}


static Class getMainClass() {
  return mc();
}

static Class getMainClass(Object o) { try {
  if (o == null) return null;
  if (o instanceof Class && eq(((Class) o).getName(), "x30")) return (Class) o;
  ClassLoader cl = (o instanceof Class ? (Class) o : o.getClass()).getClassLoader();
  if (cl == null) return null;
  String name = mainClassNameForClassLoader(cl);
  return loadClassFromClassLoader_orNull(cl, name);
} catch (Exception __e) { throw rethrow(__e); } }


static void pcallFail(Throwable e) {
  pcallPolicyForThread().handlePcallFail(e);
}

static void pcallFail(String msg) {
  pcallFail(new Throwable(msg));
}


static Comparator<String> caseInsensitiveComparator() {
  
  
  return betterCIComparator();
  
}


static TreeSet<String> toCaseInsensitiveSet_treeSet(Iterable<String> c) {
  if (isCISet(c)) return (TreeSet) c;
  TreeSet<String> set = caseInsensitiveSet_treeSet();
  addAll(set, c);
  return set;
}

static TreeSet<String> toCaseInsensitiveSet_treeSet(String... x) {
  TreeSet<String> set = caseInsensitiveSet_treeSet();
  addAll(set, x);
  return set;
}


static int iround(double d) {
  return (int) Math.round(d);
}


static int iround(Number n) {
  return iround(toDouble(n));
}



static int strL(String s) {
  return s == null ? 0 : s.length();
}


static int lCharSequence(CharSequence s) {
  return s == null ? 0 : s.length();
}


static void _onJavaXSet() {}


static final Map<Class, _MethodCache> callOpt_cache = newDangerousWeakHashMap();

static Object callOpt_cached(Object o, String methodName, Object... args) { try {
  if (o == null) return null;
  
  if (o instanceof Class) {
    Class c = (Class) o;
    _MethodCache cache = callOpt_getCache(c);
    
    // TODO: (super-rare) case where method exists static and non-static
    // with different args
    
    Method me = cache.findMethod(methodName, args);
    if (me == null || (me.getModifiers() & Modifier.STATIC) == 0) return null;
    return invokeMethod(me, null, args);
  } else {
    Class c = o.getClass();
    _MethodCache cache = callOpt_getCache(c);

    Method me = cache.findMethod(methodName, args);
    if (me == null) return null;
    return invokeMethod(me, o, args);
  }
} catch (Exception __e) { throw rethrow(__e); } }

// no longer synchronizes! (see #1102990)
static _MethodCache callOpt_getCache(Class c) {
  _MethodCache cache = callOpt_cache.get(c);
  if (cache == null)
    callOpt_cache.put(c, cache = new _MethodCache(c));
  return cache;
}


static boolean isStaticMethod(Method m) {
  return methodIsStatic(m);
}


static Object[] massageArgsForVarArgsCall(Executable m, Object[] args) {
  Class<?>[] types = m.getParameterTypes();
  int n = types.length-1, nArgs = l(args);
  if (nArgs < n) return null;
  for (int i = 0; i < n; i++)
    if (!argumentCompatibleWithType(args[i], types[i]))
      return null;
  Class varArgType = types[n].getComponentType();
  for (int i = n; i < nArgs; i++)
    if (!argumentCompatibleWithType(args[i], varArgType))
      return null;
  Object[] newArgs = new Object[n+1];
  arraycopy(args, 0, newArgs, 0, n);
  
  // TODO: optimize
  
  int nVarArgs = nArgs-n;
  Object varArgs = Array.newInstance(varArgType, nVarArgs);
  for (int i = 0; i < nVarArgs; i++)
    Array.set(varArgs, i, args[n+i]);
    
  newArgs[n] = varArgs;
  return newArgs;
}


static String formatArgumentClasses(Object[] args) {
  return joinWithComma(map(__18 -> getClassName(__18), args));
}


// get purpose 1: access a list/array/map (safer version of x.get(y))

static <A> A get(List<A> l, int idx) {
  return l != null && idx >= 0 && idx < l(l) ? l.get(idx) : null;
}

// seems to conflict with other signatures
/*static <A, B> B get(Map<A, B> map, A key) {
  ret map != null ? map.get(key) : null;
}*/

static <A> A get(A[] l, int idx) {
  return idx >= 0 && idx < l(l) ? l[idx] : null;
}

// default to false
static boolean get(boolean[] l, int idx) {
  return idx >= 0 && idx < l(l) ? l[idx] : false;
}

// get purpose 2: access a field by reflection or a map

static Object get(Object o, String field) {
  try {
    if (o == null) return null;
    if (o instanceof Class) return get((Class) o, field);
    
    if (o instanceof Map)
      return ((Map) o).get(field);
      
    Field f = getOpt_findField(o.getClass(), field);
    if (f != null) {
      makeAccessible(f);
      return f.get(o);
    }
      
    
      if (o instanceof DynamicObject)
        return getOptDynOnly(((DynamicObject) o), field);
    
  } catch (Exception e) {
    throw asRuntimeException(e);
  }
  throw new RuntimeException("Field '" + field + "' not found in " + o.getClass().getName());
}

static Object get_raw(String field, Object o) {
  return get_raw(o, field);
}

static Object get_raw(Object o, String field) { try {
  if (o == null) return null;
  Field f = get_findField(o.getClass(), field);
  makeAccessible(f);
  return f.get(o);
} catch (Exception __e) { throw rethrow(__e); } }

static Object get(Class c, String field) {
  try {
    Field f = get_findStaticField(c, field);
    makeAccessible(f);
    return f.get(null);
  } catch (Exception e) {
    throw new RuntimeException(e);
  }
}

static Field get_findStaticField(Class<?> c, String field) {
  Class _c = c;
  do {
    for (Field f : _c.getDeclaredFields())
      if (f.getName().equals(field) && (f.getModifiers() & java.lang.reflect.Modifier.STATIC) != 0)
        return f;
    _c = _c.getSuperclass();
  } while (_c != null);
  throw new RuntimeException("Static field '" + field + "' not found in " + c.getName());
}

static Field get_findField(Class<?> c, String field) {
  Class _c = c;
  do {
    for (Field f : _c.getDeclaredFields())
      if (f.getName().equals(field))
        return f;
    _c = _c.getSuperclass();
  } while (_c != null);
  throw new RuntimeException("Field '" + field + "' not found in " + c.getName());
}

static Object get(String field, Object o) {
  return get(o, field);
}

static boolean get(BitSet bs, int idx) {
  return bs != null && bs.get(idx);
}


static <A, B> B mapPutOrRemove(Map<A, B> map, A key, B value) {
  if (map != null && key != null)
    if (value != null) return map.put(key, value);
    else return map.remove(key);
  return null;
}


static Class<?> _getClass(String name) {
  try {
    return Class.forName(name);
  } catch (ClassNotFoundException e) {
    return null; // could optimize this
  }
}

static Class _getClass(Object o) {
  return o == null ? null
    : o instanceof Class ? (Class) o : o.getClass();
}

static Class _getClass(Object realm, String name) {
  try {
    return classLoaderForObject(realm).loadClass(classNameToVM(name));
  } catch (ClassNotFoundException e) {
    return null; // could optimize this
  }
}


//static final Map<Class, HashMap<S, Field>> getOpt_cache = newDangerousWeakHashMap(f getOpt_special_init);

static class getOpt_Map extends WeakHashMap {
  getOpt_Map() {
    if (getOpt_special == null) getOpt_special = new HashMap();
    clear();
  }
  
  public void clear() {
    super.clear();
    //print("getOpt clear");
    put(Class.class, getOpt_special);
    put(String.class, getOpt_special);
  }
}

static final Map<Class, HashMap<String, Field>> getOpt_cache = 
  
  
    _registerDangerousWeakMap(synchroMap(new getOpt_Map()));
  
  
static HashMap getOpt_special; // just a marker

/*static void getOpt_special_init(Map map) {
  map.put(Class.class, getOpt_special);
  map.put(S.class, getOpt_special);
}*/

static Map<String, Field> getOpt_getFieldMap(Object o) {
  Class c = _getClass(o);
  HashMap<String, Field> map = getOpt_cache.get(c);
  if (map == null)
    map = getOpt_makeCache(c);
  return map;
}

static Object getOpt_cached(Object o, String field) { try {
  if (o == null) return null;

  Map<String, Field> map = getOpt_getFieldMap(o);

  if (map == getOpt_special) {
    if (o instanceof Class)
      return getOpt((Class) o, field);
    /*if (o instanceof S)
      ret getOpt(getBot((S) o), field);*/
    if (o instanceof Map)
      return ((Map) o).get(field);
  }
    
  Field f = map.get(field);
  if (f != null) return f.get(o);
  
    if (o instanceof DynamicObject)
      return syncMapGet2(((DynamicObject) o).fieldValues, field);
  
  return null;
} catch (Exception __e) { throw rethrow(__e); } }

// used internally - we are in synchronized block
static HashMap<String, Field> getOpt_makeCache(Class c) {
  HashMap<String, Field> map;
  if (isSubtypeOf(c, Map.class))
    map = getOpt_special;
  else {
    map = new HashMap();
    if (!reflection_classesNotToScan().contains(c.getName())) {
      Class _c = c;
      do {
        for (Field f : _c.getDeclaredFields()) {
          makeAccessible(f);
          String name = f.getName();
          if (!map.containsKey(name))
            map.put(name, f);
        }
        _c = _c.getSuperclass();
      } while (_c != null);
    }
  }
  if (getOpt_cache != null) getOpt_cache.put(c, map);
  return map;
}


static Field getOpt_findField(Class<?> c, String field) {
  Class _c = c;
  do {
    for (Field f : _c.getDeclaredFields())
      if (f.getName().equals(field))
        return f;
    _c = _c.getSuperclass();
  } while (_c != null);
  return null;
}


static PersistableThrowable persistableThrowable(Throwable e) {
  return e == null ? null : new PersistableThrowable(e);
}


static boolean startsWithOneOf(String s, String... l) {
  for (String x : l) if (startsWith(s, x)) return true; return false;
}

static boolean startsWithOneOf(String s, Matches m, String... l) {
  for (String x : l) if (startsWith(s, x, m)) return true; return false;
}


static boolean isAGIBlueDomain(String domain) {
  return domainIsUnder(domain, theAGIBlueDomain());
}


static String hostNameFromURL(String url) { try {
  return empty(url) ? null : new URL(url).getHost();
} catch (Exception __e) { throw rethrow(__e); } }


// TODO: JDK 17!! ?? No! Yes? Yes!!

static Object collectionMutex(List l) {
  return l;
}

static Object collectionMutex(Object o) {
  

  if (o instanceof List) return o;
  
  // TODO: actually use our own maps so we can get the mutex properly
  
  String c = className(o);
  
    
  
    
  
  return o;
}


static Object callFunction(Object f, Object... args) {
  return callF(f, args);
}


static Throwable _storeException_value;

static void _storeException(Throwable e) {
  _storeException_value = e;
}


static <A> Set<A> syncIdentityHashSet() {
  return (Set) synchronizedSet(identityHashSet());
}


static Map syncHashMap() {
  return synchroHashMap();
}




static <A> A setThreadLocal(ThreadLocal<A> tl, A value) {
  if (tl == null) return null;
  A old = tl.get();
  tl.set(value);
  return old;
}


static Object pcallF(Object f, Object... args) {
  return pcallFunction(f, args);
}


static <A> A pcallF(F0<A> f) {
  try { return f == null ? null : f.get(); } catch (Throwable __e) { pcallFail(__e); } return null;
}



static <A, B> B pcallF(F1<A, B> f, A a) {
  try { return f == null ? null : f.get(a); } catch (Throwable __e) { pcallFail(__e); } return null;
}



static <A> void pcallF(VF1<A> f, A a) {
  try {
    { if (f != null) f.get(a); }
  } catch (Throwable __e) { pcallFail(__e); }
}


static Object pcallF(Runnable r) {
  try { { if (r != null) r.run(); } } catch (Throwable __e) { pcallFail(__e); } return null;
}

static <A> A pcallF(IF0<A> f) {
  try { return f == null ? null : f.get(); } catch (Throwable __e) { pcallFail(__e); } return null;
}

static <A, B> B pcallF(IF1<A, B> f, A a) {
  try { return f == null ? null : f.get(a); } catch (Throwable __e) { pcallFail(__e); } return null;
}



// BREAKING CHANGE!
// Also NOTE: Iterators of these sync-wrapped collections
// after generally NOT thread-safe!
// TODO: change that?
static <A> Set<A> synchroLinkedHashSet() {
  
  
  return synchronizedSet(new CompactLinkedHashSet());
  
}


static String mainClassNameForClassLoader(ClassLoader cl) {
  return or((String) callOpt(cl, "mainClassName"), "main");
}


static Class loadClassFromClassLoader_orNull(ClassLoader cl, String name) {
  try {
    return cl == null ? null : cl.loadClass(name);
  } catch (ClassNotFoundException e) {
    return null;
  }
}


static PCallPolicy pcallPolicyForThread() {
  var policy = pcallPolicyForThread_tl().get();
  if (policy != null) return policy;
  return defaultPCallPolicy();
}


static betterCIComparator_C betterCIComparator_instance;

static betterCIComparator_C betterCIComparator() {
  if (betterCIComparator_instance == null)
    betterCIComparator_instance = new betterCIComparator_C();
  return betterCIComparator_instance;
}

final static class betterCIComparator_C implements Comparator<String> {
  public int compare(String s1, String s2) {
    if (s1 == null) return s2 == null ? 0 : -1;
    if (s2 == null) return 1;
  
    int n1 = s1.length();
    int n2 = s2.length();
    int min = Math.min(n1, n2);
    for (int i = 0; i < min; i++) {
        char c1 = s1.charAt(i);
        char c2 = s2.charAt(i);
        if (c1 != c2) {
            c1 = Character.toUpperCase(c1);
            c2 = Character.toUpperCase(c2);
            if (c1 != c2) {
                c1 = Character.toLowerCase(c1);
                c2 = Character.toLowerCase(c2);
                if (c1 != c2) {
                    // No overflow because of numeric promotion
                    return c1 - c2;
                }
            }
        }
    }
    return n1 - n2;
  }
}


static boolean isCISet(Iterable<String> l) {
  return l instanceof TreeSet && ((TreeSet) l).comparator() == caseInsensitiveComparator();
}


static double toDouble(Object o) {
  if (o instanceof Number)
    return ((Number) o).doubleValue();
  if (o instanceof BigInteger)
    return ((BigInteger) o).doubleValue();
  if (o instanceof String)
    return parseDouble((String) o);
  if (o == null) return 0.0;
  throw fail(o);
}


static boolean methodIsStatic(Method m) {
  return (m.getModifiers() & Modifier.STATIC) != 0;
}


static boolean argumentCompatibleWithType(Object arg, Class type) {
  return arg == null ? !type.isPrimitive() : isInstanceX(type, arg);
}


static void arraycopy(Object[] a, Object[] b) {
  if (a != null && b != null)
    arraycopy(a, 0, b, 0, Math.min(a.length, b.length));
}

static void arraycopy(Object src, int srcPos, int destPos, int n) { arraycopy(src, srcPos, src, destPos, n); }
static void arraycopy(Object src, int srcPos, Object dest, int destPos, int n) {
  if (n != 0)
    System.arraycopy(src, srcPos, dest, destPos, n);
}


static Object getOptDynOnly(DynamicObject o, String field) {
  if (o == null || o.fieldValues == null) return null;
  return o.fieldValues.get(field);
}


static ClassLoader classLoaderForObject(Object o) {
  if (o instanceof ClassLoader) return ((ClassLoader) o);
  if (o == null) return null;
  return _getClass(o).getClassLoader();
}


// Note: This is actually broken. Inner classes must stay with a $ separator
static String classNameToVM(String name) {
  return name.replace(".", "$");
}


static void clear(Collection c) {
  if (c != null) c.clear();
}

static void clear(Map map) {
  if (map != null) map.clear();
}


static <A, B> void put(Map<A, B> map, A a, B b) {
  if (map != null) map.put(a, b);
}

static <A> void put(List<A> l, int i, A a) {
  if (l != null && i >= 0 && i < l(l)) l.set(i, a);
}


static <A, B> B syncMapGet2(Map<A, B> map, A a) {
  if (map == null) return null;
  synchronized(collectionMutex(map)) {
    return map.get(a);
  }
}

static <A, B> B syncMapGet2(A a, Map<A, B> map) {
  return syncMapGet2(map, a);
}


static boolean isSubtypeOf(Class a, Class b) {
  return a != null && b != null && b.isAssignableFrom(a); // << always hated that method, let's replace it!
}


static Set<String> reflection_classesNotToScan_value = litset(
  "jdk.internal.loader.URLClassPath"
);

static Set<String> reflection_classesNotToScan() {
  return reflection_classesNotToScan_value;
}


static boolean startsWith(String a, String b) {
  return a != null && a.startsWith(unnull(b));
}

static boolean startsWith(String a, char c) {
  return nemptyString(a) && a.charAt(0) == c;
}


  static boolean startsWith(String a, String b, Matches m) {
    if (!startsWith(a, b)) return false;
    if (m != null) m.m = new String[] {substring(a, strL(b))};
    return true;
  }


static boolean startsWith(List a, List b) {
  if (a == null || listL(b) > listL(a)) return false;
  for (int i = 0; i < listL(b); i++)
    if (neq(a.get(i), b.get(i)))
      return false;
  return true;
}




static boolean domainIsUnder(String domain, String mainDomain) {
  return eqic(domain, mainDomain) || ewic(domain, "." + mainDomain);
}


static String theAGIBlueDomain() {
  return "agi.blue";
}


static String className(Object o) {
  return getClassName(o);
}


static <A> Set<A> synchronizedSet() {
  return synchroHashSet();
}

static <A> Set<A> synchronizedSet(Set<A> set) {
  
  
    return Collections.synchronizedSet(set);
  
}


static <A> Set<A> identityHashSet() {
  return Collections.newSetFromMap(new IdentityHashMap());
}




static Object pcallFunction(Object f, Object... args) {
  try { return callFunction(f, args); } catch (Throwable __e) { pcallFail(__e); }
  return null;
}


static Object callOpt(Object o) {
  return callF(o);
}

static Object callOpt(Object o, String method, Object... args) {
  return callOpt_withVarargs(o, method, args);
}




static ThreadLocal<PCallPolicy> pcallPolicyForThread_tl_tl = new ThreadLocal();

static ThreadLocal<PCallPolicy> pcallPolicyForThread_tl() {
  return pcallPolicyForThread_tl_tl;
}


static PCallPolicy defaultPCallPolicy = __1 -> printStackTrace(__1);

static PCallPolicy defaultPCallPolicy() {
  return defaultPCallPolicy;
}

static void defaultPCallPolicy_set(PCallPolicy policy) {
  defaultPCallPolicy = policy;
}


static double parseDouble(String s) {
  return empty(s) ? 0.0 : Double.parseDouble(s);
}


static <A> HashSet<A> litset(A... items) {
  return lithashset(items);
}


static boolean nemptyString(String s) {
  return s != null && s.length() > 0;
}


static int listL(Collection l) {
  return l == null ? 0 : l.size();
}


static boolean neq(Object a, Object b) {
  return !eq(a, b);
}


static boolean eqic(String a, String b) {
  
  
    if ((a == null) != (b == null)) return false;
    if (a == null) return true;
    return a.equalsIgnoreCase(b);
  
}


static boolean eqic(Symbol a, Symbol b) {
  return eq(a, b);
}

static boolean eqic(Symbol a, String b) {
  return eqic(asString(a), b);
}


static boolean eqic(char a, char b) {
  if (a == b) return true;
  
    char u1 = Character.toUpperCase(a);
    char u2 = Character.toUpperCase(b);
    if (u1 == u2) return true;
  
  return Character.toLowerCase(u1) == Character.toLowerCase(u2);
}


static <A> Set<A> synchroHashSet() {
  return synchronizedSet(new HashSet<A>());
}





static Object callOpt_withVarargs(Object o, String method, Object... args) { try {
  if (o == null) return null;
  
  if (o instanceof Class) {
    Class c = (Class) o;
    _MethodCache cache = callOpt_getCache(c);
    
    Method me = cache.findMethod(method, args);
    if (me == null) {
      // TODO: varargs
      return null;
    }
    if ((me.getModifiers() & Modifier.STATIC) == 0)
      return null;
    return invokeMethod(me, null, args);
  } else {
    Class c = o.getClass();
    _MethodCache cache = callOpt_getCache(c);

    Method me = cache.findMethod(method, args);
    if (me != null)
      return invokeMethod(me, o, args);
      
    // try varargs
    List<Method> methods = cache.cache.get(method);
    if (methods != null) methodSearch: for (Method m : methods) {
      { if (!(m.isVarArgs())) continue; }
      Object[] newArgs = massageArgsForVarArgsCall(m, args);
      if (newArgs != null)
        return invokeMethod(m, o, newArgs);
    }
    
    return null;
  }
} catch (Exception __e) { throw rethrow(__e); } }


static <A> HashSet<A> lithashset(A... items) {
  HashSet<A> set = new HashSet();
  for (A a : items) set.add(a);
  return set;
}


static String asString(Object o) {
  return o == null ? null : o.toString();
}




static class TickerSequence implements IntSize {
  TickerSequence() {}
   final public TickerSequence setMarket(String market){ return market(market); }
public TickerSequence market(String market) { this.market = market; return this; }  final public String getMarket(){ return market(); }
public String market() { return market; }
 String market; // e.g. "TRBUSDT"
  
  // in case the sequence is digitized
   final public TickerSequence setPriceCells(PriceCells priceCells){ return priceCells(priceCells); }
public TickerSequence priceCells(PriceCells priceCells) { this.priceCells = priceCells; return this; }  final public PriceCells getPriceCells(){ return priceCells(); }
public PriceCells priceCells() { return priceCells; }
 PriceCells priceCells;
  
  // are we live?
   final public TickerSequence setLive(boolean live){ return live(live); }
public TickerSequence live(boolean live) { this.live = live; return this; }  final public boolean getLive(){ return live(); }
public boolean live() { return live; }
 boolean live = false;
  
  // Is the data incomplete (still loading)?
   final public TickerSequence setLoading(boolean loading){ return loading(loading); }
public TickerSequence loading(boolean loading) { this.loading = loading; return this; }  final public boolean getLoading(){ return loading(); }
public boolean loading() { return loading; }
 boolean loading = false;
  
  ILongBuffer timestamps = new SynchronizedLongBuffer();
  IDoubleBuffer prices = new SynchronizedFloatBufferPresentingAsDoubles();
  
  // timestamp of last ticker event even though price may not
  // have changed
   final public TickerSequence setLastTickerEvent(long lastTickerEvent){ return lastTickerEvent(lastTickerEvent); }
public TickerSequence lastTickerEvent(long lastTickerEvent) { this.lastTickerEvent = lastTickerEvent; return this; }  final public long getLastTickerEvent(){ return lastTickerEvent(); }
public long lastTickerEvent() { return lastTickerEvent; }
 long lastTickerEvent;
  
   final public TickerSequence setEpsilon(double epsilon){ return epsilon(epsilon); }
public TickerSequence epsilon(double epsilon) { this.epsilon = epsilon; return this; }  final public double getEpsilon(){ return epsilon(); }
public double epsilon() { return epsilon; }
 double epsilon = 1e-6;
  
   transient Set<IVF1<Long>> onPricePointAdded;
public  TickerSequence onPricePointAdded(IVF1<Long> f) { onPricePointAdded = createOrAddToSyncLinkedHashSet(onPricePointAdded, f); return this; }
public  TickerSequence removePricePointAddedListener(IVF1<Long> f) { main.remove(onPricePointAdded, f); return this; }
public   void pricePointAdded(long timestamp) {  if (onPricePointAdded != null) for (var listener : onPricePointAdded) pcallF_typed(listener, timestamp); }
   transient Set<Runnable> onNewTickerEvent;
public  TickerSequence onNewTickerEvent(Runnable r) { onNewTickerEvent = createOrAddToSyncLinkedHashSet(onNewTickerEvent, r); return this; }
public  TickerSequence removeNewTickerEventListener(Runnable r) { main.remove(onNewTickerEvent, r); return this; }
public   void newTickerEvent() {  if (onNewTickerEvent != null) for (var listener : onNewTickerEvent) pcallF_typed(listener); }
  
  TickerSequence(String market) {
  this.market = market;}
  
  synchronized void addIfPriceChanged(double price, long timestamp) {
    if (isEmpty() || differentByEpsilonRatio(prices.last(), price, epsilon))
      add(price, timestamp);
      
    updateTickerEvent(timestamp);
  }
  
  void updateTickerEvent(long timestamp) {
    if (timestamp > lastTickerEvent) {
      lastTickerEvent(timestamp);
      newTickerEvent();
    }
  }
  
  final  void addPrice(double price, long timestamp){ add(price, timestamp); }
synchronized void add(double price, long timestamp) {
    timestamps.add(timestamp);
    prices.add(price);
    pricePointAdded(timestamp);
    updateTickerEvent(timestamp);
  }
  
  synchronized void add(double[] prices, long[] timestamps) {
    assertEquals(l(prices), l(timestamps));
    if (empty(prices)) return;
    
    // TODO: call pricePointAdded?
    this.prices.addAll(asList(prices));
    this.timestamps.addAll(asList(timestamps));
    lastTickerEvent = max(lastTickerEvent, endTime());
  }
  
  synchronized void add(TickerSequence ticker) {
    add(ticker.prices.toArray(), ticker.timestamps.toArray());
  }
  
  synchronized public String toString() {
    return commaCombine(
      spaceCombine(
        "Ticker",
        market,
        priceCells == null ? null : roundBracket(priceCells)),
      formatDays(duration()),
      n2(l(prices), "price point"),
      timeRange()
    );
  }
  
  public synchronized TickerSequence clone() {
    return subSequence(0, size());
  }
  
  TickerSequence emptyClone() {
    return new TickerSequence().market(market);
  }
  
  synchronized TickerSequence subSequence(int start) { return subSequence(start, size()); }
synchronized TickerSequence subSequence(int start, int end) {
    var s = emptyClone();
    s.add(
      cloneSubDoubleArray(prices.toArray(), start, end),
      cloneSubLongArray(timestamps.toArray(), start, end));
    return s;
  }
  
  synchronized TickerSequence cutOffAfterSeconds(double seconds) {
    int idx = indexOfTimestamp(startTime()+secondsToMS(seconds));
    return subSequence(0, idx);
  }

  TickerSequence dropFirstDays(double days) {
    return subSequenceFromTimestamp(startTime()+daysToMS(days));
  }

  TickerSequence takeFirstDays(double days) {
    return cutOffAfterSeconds(daysToSeconds(days));
  }

  TickerSequence takeLastDays(double days) {
    return subSequenceFromTimestamp(endTime()-daysToMS(days));
  }

  TickerSequence takeLastHours(double hours) {
    return takeLastDays(hoursToDays(hours));
  }

  TickerSequence takeLastMinutes(double minutes) {
    return takeLastDays(minutesToDays(minutes));
  }

  synchronized TickerSequence subSequenceByTimestamps(long from, long to) {
    int idx1 = indexOfTimestamp(from);
    int idx2 = indexOfTimestamp(to);
    return subSequence(idx1, idx2);
  }
  
  synchronized TickerSequence subSequenceFromTimestamp(long from) {
    return subSequence(indexOfTimestamp(from));
  }
  
  synchronized TickerSequence subSequenceToTimestamp(long to) {
    return subSequence(0, indexOfTimestamp(to));
  }
  
  // TODO: shouldn't we subtract one here?
  synchronized int indexOfTimestamp(double ts) {
    return binarySearch_insertionPoint(timestamps.asVirtualList(), lround(ts));
  }
  
  synchronized long nextTimestamp(double ts) {
    return getTimestamp(indexOfTimestamp(ts)+1);
  }
  
  synchronized double priceAtTimestamp(double ts) {
    return getPrice(indexOfTimestamp(ts));
  }

  public int size() { return l(prices); }
  public boolean isEmpty() { return size() == 0; }
  
  synchronized TimestampRange timeRange() {
    return isEmpty() ? null : new TimestampRange(startTime(), endTime());
  }
  
  Duration duration() {
    return main.duration(timeRange());
  }
  
  synchronized long startTime() { return empty(timestamps) ? 0 : first(timestamps); }
  synchronized long endTime() { return empty(timestamps) ? 0 : last(timestamps); }
  
  synchronized double getPrice(int i) {
    return isEmpty() ? Double.NaN : prices.get(clampToLength(size(), i));
  }
  
  synchronized long getTimestamp(int i) {
    return isEmpty() ? 0 : timestamps.get(clampToLength(size(), i));
  }
  
  synchronized TickerSequence removePlateaus() {
    var seq = emptyClone();
    int n = size();
    
    for (int i = 0; i < n; i++) {
      var value = getPrice(i);
      seq.prices.add(value);
      seq.timestamps.add(getTimestamp(i));
      
      while (i+1 < n && getPrice(i+1) == value) ++i;
    }
    
    return seq.trimToSize();
  }
  
  synchronized TickerSequence removeZeros() {
    if (!prices.contains(0)) return this;
    var seq = emptyClone();
    int n = size();
    for (int i = 0; i < n; i++) {
      var value = getPrice(i);
      if (value != 0) {
        seq.prices.add(value);
        seq.timestamps.add(getTimestamp(i));
      }
    }
    return seq.trimToSize();
  }
  
  synchronized TickerSequence alignTimestamps(int interval) {
    var seq = emptyClone();
    int n = size();
    
    for (int i = 0; i < n; i++) {
      var value = getPrice(i);
      long time = roundDownTo(interval, getTimestamp(i));
      if (time != seq.endTime())
        seq.addIfPriceChanged(value, time);
    }
      
    return seq.trimToSize();
  }
  
  TickerSequence trimToSize() {
    prices.trimToSize();
    timestamps.trimToSize();
    return this;
  }
  
  double minPrice() { return doubleMin(prices.toArray()); }
  double maxPrice() { return doubleMax(prices.toArray()); }
  DoubleRange priceRange() { return doubleRange(minPrice(), maxPrice()); }
  
  synchronized double firstPrice() { return empty(prices) ? Double.NaN : prices.first(); }
  synchronized double lastPrice() { return empty(prices) ? Double.NaN : prices.last(); }
  
  synchronized TickerPoint lastPoint() {
    return new TickerPoint(this, endTime());
  }
  
  static Pattern reBestAsk = regexp("\"bestAsk\":([0-9\\.]+)");
  static Pattern reSystemTime = regexp("\"systemTime\":(\\d+)");
  
  // parse line from a .ticker file
  synchronized void addJSONLine_fast(String line) {
    long time = toLong(regexpFirstGroup(reSystemTime, line));
    if (time > lastTickerEvent) {
      double price = toDouble(regexpFirstGroup(reBestAsk, line));
      if (price != 0)
        addIfPriceChanged(price, time);
    }
  }
  
  transient  IVF1<String> addJSONLine;
void addJSONLine(String line) { if (addJSONLine != null) addJSONLine.get(line); else addJSONLine_base(line); }
final void addJSONLine_fallback(IVF1<String> _f, String line) { if (_f != null) _f.get(line); else addJSONLine_base(line); }
void addJSONLine_base(String line) {
    addJSONLine_fast(line);
  }
  
  synchronized void addJSONLine_slow(String line) {
    Map data = parseJSONMap(line);
    double price = toDouble(data.get("bestAsk"));
    long time = toLong(data.get("systemTime"));
    if (time > lastTickerEvent) 
      addIfPriceChanged(price, time);
  }
  
  final UpDownSequence upDownSequence(){ return toUpDownSequence(); }
UpDownSequence toUpDownSequence() { return toUpDownSequence(priceCells); }
final UpDownSequence upDownSequence(PriceCells cells){ return toUpDownSequence(cells); }
UpDownSequence toUpDownSequence(PriceCells cells) {
    if (cells == null) return null;
    var dig = digitize(new PriceDigitizer2(cells));
    List<Integer> cellNumbers = dig.roundedCellNumbers();
    return UpDownSequence.fromInts(cellNumbers);
  }
  
  TickerSequence digitizeToPercent(double cellSizeInPercent) { return digitizeToPercent(firstPrice(), cellSizeInPercent); }
TickerSequence digitizeToPercent(double basePrice, double cellSizeInPercent) {
    if (isEmpty()) return this;
    return digitize(geometricPriceDigitizer(basePrice, cellSizeInPercent));
  }
  
  TickerSequence digitize(PriceDigitizer2 digitizer) {
    var seq = emptyClone();
    seq.priceCells(digitizer.priceCells());
    int n = size();
    
    for (int i = 0; i < n; i++) {
      seq.addIfPriceChanged(digitizer.digitize(getPrice(i)), getTimestamp(i));
    }
    
    return seq.trimToSize();
  }
  
  List<PricePoint> pricePoints() {
    return listFromFunction(__39 -> getPricePoint(__39), size());
  }
  
  synchronized PricePoint getPricePoint(int idx) {
    return idx >= 0 && idx < size() ? new PricePoint(timestamps.get(idx), prices.get(idx)) : null;
  }
  
  PricePoint firstPricePoint() { return getPricePoint(0); }
  synchronized PricePoint lastPricePoint() { return getPricePoint(size()-1); }
  
  List<Integer> roundedCellNumbers() {
    return map(__19 -> iround(__19), cellNumbers());
  }
  
  List<Double> cellNumbers() {
    if (priceCells == null) return null;
    int n = size();
    DoubleBuffer buf = new DoubleBuffer(n);
    for (int i = 0; i < n; i++)
      buf.add(priceCells.toCellNumber(getPrice(i)));
    return buf.asVirtualList();
  }
  
  TickerSequence toCellNumbers() {
    if (priceCells == null) return null;
    TickerSequence seq = new TickerSequence();
    seq.market(market + " cell numbers " + roundBracket(priceCells));
    int n = size();
    
    for (int i = 0; i < n; i++)
      seq.add(priceCells.toCellNumber(getPrice(i)), getTimestamp(i));

    return seq.trimToSize();
  }
  
  void dropLastPricePoint() {
    if (isEmpty()) return;
    prices.popLast();
    timestamps.popLast();
    lastTickerEvent = endTime();
    newTickerEvent();
  }
  
  TickerSequence marketIfEmpty(String market) {
    if (empty(this.market)) market(market);
    return this;
  }
  
  TickerSequence legacyCompact() {
    if (!(prices instanceof SynchronizedFloatBufferPresentingAsDoubles))
      prices = new SynchronizedFloatBufferPresentingAsDoubles(prices.toArray());
    return this;
  }
  
  // msUnit = how many milliseconds to group into one
  boolean compactTimestamps() { return compactTimestamps(20); }
boolean compactTimestamps(long msUnit) {
    if (!(timestamps instanceof SynchronizedLongBufferStoredAsLinearInts)) {
      timestamps = new SynchronizedLongBufferStoredAsLinearInts(roundDownTo(msUnit, startTime()), msUnit, timestamps);
      return true;
    }
    return false;
  }
  
  double averageTimeStep() {
    return doubleRatio(endTime()-startTime(), size()-1);
  }
  
  public void write(ByteHead head) {
    head.writeString(market);
    SynchronizedLongBufferStoredAsLinearInts timestamps =  (SynchronizedLongBufferStoredAsLinearInts) (this.timestamps);
    head.writeLong(timestamps.base);
    head.writeLong(timestamps.factor);
    
    int n = size();
    head.writeInt(n);

    for (int i = 0; i < n; i++) {
      head.writeInt(timestamps.getRaw(i));
      head.writeFloat((float) prices.get(i));
    }
  }
  
  static TickerSequence read(ByteHead head) {
    TickerSequence t = new TickerSequence();
    t.market = head.readString();
    if (head.eof()) return null;
    long base = head.readLong();
    long factor = head.readLong();
    //printVars(market := t.market, +base, +factor);
    SynchronizedLongBufferStoredAsLinearInts timestamps = new SynchronizedLongBufferStoredAsLinearInts(base, factor);
    t.timestamps = timestamps;
    
    int n = head.readInt();
    for (int i = 0; i < n; i++) {
      int time = head.readInt();
      if (head.eof()) break;
      timestamps.addRaw(time);
      t.prices.add(head.readFloat());
    }
    return t;
  }
  
  TickerSequence loadJSONFile(File f) {
     var it = linesFromFile(f); try {
    for (var line : it) { try { addJSONLine(line); } catch (Throwable __e) { pcallFail(__e); }}
    return this;
  } finally { _close(it); }}
  
  synchronized void insertAt(int idx, TickerSequence ticker) {
    prices.insertAt(idx, ticker.prices.toArray());
    timestamps.insertAt(idx, ticker.timestamps.toArray());
  }
}
static abstract class VF1<A> implements IVF1<A> {
  public abstract void get(A a);
}
// immutable, has strong refs
// Do not run in a synchronized block - it goes wrong in the presence
// of elaborate classloaders (like in Gazelle BEA)
// see #1102990 and #1102991

final static class _MethodCache {
  final Class c;
  final HashMap<String, List<Method>> cache = new HashMap();
  
  _MethodCache(Class c) {
  this.c = c; _init(); }
  
  void _init() {
    Class _c = c;
    java.lang.Module myModule = getClass().getModule();
    boolean anyHiddenClasses = false;
    
    while (_c != null) {
      boolean exported = classIsExportedTo(_c, myModule);
       
      
      if (!exported)
        anyHiddenClasses = true;
      else
        for (Method m : _c.getDeclaredMethods())
          if ((anyHiddenClasses || !isAbstract(m))
            && !reflection_isForbiddenMethod(m))
            multiMapPut(cache, m.getName(), makeAccessible(m));

      _c = _c.getSuperclass();
    }
    
    // add default methods - this might lead to a duplication
    // because the overridden method is also added, but it's not
    // a problem except for minimal performance loss.
    // If any classes in the hierarchy were inaccessible, we add
    // all interface methods (see test_callForbiddenMethodByReflection for a test)
    
    for (Class intf : allInterfacesImplementedBy(c))
      for (Method m : intf.getDeclaredMethods())
        if ((anyHiddenClasses || m.isDefault()) && !reflection_isForbiddenMethod(m))
          multiMapPut(cache, m.getName(), makeAccessible(m));

     
  }
  
  // Returns only matching methods
  Method findMethod(String method, Object[] args) { try {
    List<Method> m = cache.get(method);
     
    if (m == null) return null;
    int n = m.size();
    for (int i = 0; i < n; i++) {
      Method me = m.get(i);
      if (call_checkArgs(me, args, false))
        return me;
    }
    return null;
  } catch (Exception __e) { throw rethrow(__e); } }
  
  Method findStaticMethod(String method, Object[] args) { try {
    List<Method> m = cache.get(method);
    if (m == null) return null;
    int n = m.size();
    for (int i = 0; i < n; i++) {
      Method me = m.get(i);
      if (isStaticMethod(me) && call_checkArgs(me, args, false))
        return me;
    }
    return null;
  } catch (Exception __e) { throw rethrow(__e); } }
  
  //Cl<Method> allMethods() { ret allValues(cache); }
}
static class Matches {
  String[] m;
  
  Matches() {}
  Matches(String... m) {
  this.m = m;}
  
  String get(int i) { return i < m.length ? m[i] : null; }
  String unq(int i) { return unquote(get(i)); }
  
  String tlc(int i) { return unq(i).toLowerCase(); }
  boolean bool(int i) { return "true".equals(unq(i)); }
  String rest() { return m[m.length-1]; } // for matchStart
  int psi(int i) { return Integer.parseInt(unq(i)); }
  
  public String toString() { return "Matches(" + joinWithComma(quoteAll(asList(m))) + ")"; }
  
  public int hashCode() { return _hashCode(toList(m)); }
  public boolean equals(Object o) { return o instanceof Matches && arraysEqual(m, ((Matches) o).m); }
}

// for the version with MasterSymbol (used WAY back in "Smart Bot"!) see #1010608

static class Symbol implements CharSequence {
  String text;
  
  Symbol() {}
  Symbol(String text, boolean dummy) {
  this.text = text;} // weird signature to prevent accidental calling
  
  public int hashCode() { return _hashCode(text); }
  public String toString() { return text; }
  public boolean equals(Object o) {
    return this == o;
  }

  // implementation of CharSequence methods
  
  public int length() { return text.length(); }
  public char charAt(int index) { return text.charAt(index); }
  public CharSequence subSequence(int start, int end) {
    return text.substring(start, end);
  }
}
static class Var<A> implements IVar<A>, ISetter<A> {
  Var() {}
  Var(A v) {
  this.v = v;}

  
  
A v; // you can access this directly if you use one thread

public synchronized void set(A a) {
  if (v != a) {
    v = a;
    notifyAll();
  }
}

public synchronized A get() { return v; }
public synchronized boolean has() { return v != null; }
public void clear() { set(null); }

public synchronized A getAndSet(A a) {
  var value = v;
  set(a);
  return value;
}

public IF0<A> getter() { return () -> get(); }
public IVF1<A> setter() { return __33 -> set(__33); }
public String toString() { return str(this.get()); }
}
static class Scorer<A> {
  double score, total;
  List<A> successes, errors; // set to non-null if you want them filled
  boolean verboseFailures, verboseAll;
  
  final void add(double score){ addZeroToOne(score); }
void addZeroToOne(double score) {
    ++total;
    this.score += clamp(score, 0, 1);
  }
  
  void addZeroToOneError(double error) {
    addZeroToOne(1-error);
  }
  
  void addError() { add(false); }
  void addError(A info) { add(false, info); }
  void error(A info) { addError(info); }
  void addOK() { add(true); }
  void addOK(A info) { add(true, info); }
  void ok() { addOK(); }
  void ok(A info) { addOK(info); }
  
  boolean add(boolean correct) {
    ++total;
    if (correct) ++score;
    return correct;
  }
  
  boolean add(boolean correct, A info) {
    main.add(correct ? successes : errors, info);
    if (verboseAll || verboseFailures && !correct)
      _print((correct ? "[GOOD] " : "[BAD] ") + info);
    return add(correct);
  }
  
  // works if you use Scorer or Scorer<S>
  void eq(Object a, Object b) {
    if (_eq(a, b))
      add(true);
    else
      add(false, (A) (a + " != " + b));
  }
  
  void print() {
    main.print(toString());
  }
  
  public String toString() {
    return formatDouble(ratioToPercent(score, total), 1) + "% correct (n=" + formatDouble(total, 1) + ")";
  }
  
  double get() {
    return ratioToPercent(score, total);
  }
  
  double percentScore() { return get(); }
  double score() { return get(); }
  
  boolean allCorrect() {
    return score == total;
  }
  
  void add(Scorer scorer) {
    if (scorer == null) return;
    total += scorer.total;
    score += scorer.score;
    addAll(successes, scorer.successes);
    addAll(errors, scorer.errors);
  }
  
  void collectErrors() {
    errors = new ArrayList();
  }
  
  void collectSuccesses() {
    successes = new ArrayList();
  }
}
// In the newest pinging system (with flag PingV3), a ping source
// is the object that "allows" some code to run.
// When that code calls ping(), the ping source's action (if defined)
// is triggered.

// This allows randomly interrupting code execution, for example.

static class PingSource {
  // returns true if it slept
   final public PingSource setAction(IF0<Boolean> action){ return action(action); }
public PingSource action(IF0<Boolean> action) { this.action = action; return this; }  final public IF0<Boolean> getAction(){ return action(); }
public IF0<Boolean> action() { return action; }
volatile IF0<Boolean> action;
  
  // optional description of this ping source
  String text;
  
  // optional thread pool that this ping source likes to run in
  ThreadPool threadPool;
  
  PingSource() {}
  PingSource(ThreadPool threadPool) {
  this.threadPool = threadPool;}
  PingSource(ThreadPool threadPool, String text) {
  this.text = text;
  this.threadPool = threadPool;}
  PingSource(IF0<Boolean> action) {
  this.action = action;}

  // returns true if it slept
  final boolean get() {
    var a = action;
    return a != null && a.get();
  }
  
  final void ping() { 
    var a = action;
    if (a != null) a.get();
  }
  
  void cancel() {
    action = new Cancelled();
  }
  
  class Cancelled implements IF0<Boolean> {
    public Boolean get() { throw new PingSourceCancelledException(PingSource.this); }
  }
  
  class Encapsulated implements Runnable , IFieldsToList{
  Runnable r;
  Encapsulated() {}
  Encapsulated(Runnable r) {
  this.r = r;}public Object[] _fieldsToList() { return new Object[] {r}; }

    public void run() { try {
      //System.out.println("Encapsulated running: " + r);
      try {
        pingSource_tl().set(PingSource.this);
        //System.out.println("Ping source set");
        ping();
        r.run();
        //System.out.println("Done running");
      } finally {
        //System.out.println("Finally");
        pingSource_tl().set(null);
      }
    } catch (Exception __e) { throw rethrow(__e); } }
    
    public String toString() { return PingSource.this + ": " + r; }
  }
  
  void dO(Runnable r) {
    if (r == null) return;
    threadPool.acquireThreadOrQueue(new Encapsulated(r));
  }
  
  public String toString() { String t = text; return nempty(t) ? t : super.toString(); }
  
  ISleeper_v2 sleeper() { return threadPool.sleeper(); }
}
// records its full size (total value count) in a field now
static class MultiMap<A,B> implements IMultiMap<A, B> {
  Map<A, List<B>> data = new HashMap<A, List<B>>();
  int fullSize;
  
  MultiMap() {}
  MultiMap(boolean useTreeMap) { if (useTreeMap) data = new TreeMap(); }
  MultiMap(MultiMap<A, B> map) { putAll(map); }
  MultiMap(Map<A, List<B>> data) {
  this.data = data;}

  void put(A key, B value) { synchronized(data) {
    List<B> list = data.get(key);
    if (list == null)
      data.put(key, list = _makeEmptyList());
    list.add(value);
    ++fullSize;
  }}

  void add(A key, B value) { put(key, value); }

  void addAll(A key, Collection<B> values) { putAll(key, values); }
  
  void addAllIfNotThere(A key, Collection<B> values) { synchronized(data) {
    for (B value : values)
      setPut(key, value);
  }}
  
  void setPut(A key, B value) { synchronized(data) {
    if (!containsPair(key, value))
      put(key, value);
  }}
  
  boolean containsPair(A key, B value) { synchronized(data) {
    return get(key).contains(value);
  }}
  
  void putAll(Collection<A> keys, B value) { synchronized(data) {
    for (A key : unnullForIteration(keys))
      put(key, value);
  }}

  void putAll(A key, Collection<B> values) { synchronized(data) {
    if (nempty(values)) getActual(key).addAll(values);
  }}

  void putAll(Iterable<Pair<A, B>> pairs) { synchronized(data) {
    for (Pair<A, B> p : unnullForIteration(pairs))
      put(p.a, p.b);
  }}
  
  void removeAll(A key, Collection<B> values) { synchronized(data) {
    for (B value : values)
      remove(key, value);
  }}
  
  public List<B> get(A key) { synchronized(data) {
    List<B> list = data.get(key);
    return list == null ? Collections.<B> emptyList() : list;
  }}
  
  List<B> getOpt(A key) { synchronized(data) {
    return data.get(key);
  }}

  List<B> getAndClear(A key) { synchronized(data) {
    List<B> l = cloneList(data.get(key));
    remove(key);
    return l;
  }}
  
  // returns actual mutable live list
  // creates the list if not there
  List<B> getActual(A key) { synchronized(data) {
    List<B> list = data.get(key);
    if (list == null)
      data.put(key, list = _makeEmptyList());
    return list;
  }}
 
  void clean(A key) { synchronized(data) {
    List<B> list = data.get(key);
    if (list != null && list.isEmpty()) {
      fullSize -= l(list);
      data.remove(key);
    }
  }}

  final public Set<A> keys(){ return keySet(); }
public Set<A> keySet() { synchronized(data) {
    return data.keySet();
  }}

  void remove(A key) { synchronized(data) {
    fullSize -= l(this.getOpt(key));
    data.remove(key);
  }}
  
  final void remove(Pair<A, B> p){ removePair(p); }
void removePair(Pair<A, B> p) {
    if (p != null) remove(p.a, p.b);
  }

  void remove(A key, B value) { synchronized(data) {
    List<B> list = data.get(key);
    if (list != null) {
      if (list.remove(value))
        fullSize--;
      if (list.isEmpty())
        data.remove(key);
    }
  }}

  void clear() { synchronized(data) {
    data.clear();
  }}

  boolean containsKey(A key) { synchronized(data) {
    return data.containsKey(key);
  }}

  B getFirst(A key) { synchronized(data) {
    List<B> list = get(key);
    return list.isEmpty() ? null : list.get(0);
  }}
  
  void addAll(MultiMap<A, B> map) { putAll(map); }
  
  void putAll(MultiMap<A, B> map) { synchronized(data) {
    for (A key : map.keySet())
      putAll(key, map.get(key));
  }}
  
  void putAll(Map<A, B> map) { synchronized(data) {
    if (map != null) for (Map.Entry<A, B> e : map.entrySet())
      put(e.getKey(), e.getValue());
  }}
  
  final public int keyCount(){ return keysSize(); }
public int keysSize() { synchronized(data) { return l(data); }}
  
  final public int fullSize(){ return size(); }
public int size() { synchronized(data) {
    return fullSize;
  }}
  
  // expensive operation
  List<A> reverseGet(B b) { synchronized(data) {
    List<A> l = new ArrayList();
    for (A key : data.keySet())
      if (data.get(key).contains(b))
        l.add(key);
    return l;
  }}
  
  Map<A, List<B>> asMap() { synchronized(data) {
    return cloneMap(data);
  }}
  
  boolean isEmpty() { synchronized(data) { return data.isEmpty(); }}
  
  // override in subclasses
  List<B> _makeEmptyList() {
    return new ArrayList();
  }
  
  // returns live lists
  Collection<List<B>> allLists() {
    synchronized(data) {
      return new ArrayList(data.values());
    }
  }
  Collection<List<B>> values() { return allLists(); }
  
  List<B> allValues() {
    return concatLists(data.values());
  }
  
  Object mutex() { return data; }
  
  public String toString() { return "mm" + str(data); }
  
  Map<A, List<B>> innerMap() { return data; }
}
// Note: This does have the values problem (complicated values can cause memory leaks)
static class BetterThreadLocal<A> {
  Map<Thread, A> map = newWeakHashMap();
  
  BetterThreadLocal() {}
  BetterThreadLocal(A value) { set(value); }
  
  boolean isSet() { return map.containsKey(currentThread()); }
  
  A get() {
    if (map.containsKey(currentThread()))
      return map.get(currentThread());
    A value = initialValue();
    set(value);
    return value;
  }
  
  A get(Thread thread) {
    return thread == null ? null : map.get(thread);
  }
  
  void set(A a) {
    map.put(currentThread(), a);
  }
  
  public A initialValue() { return null; }
}
interface IntSize {
  int size();
  
  default boolean isEmpty() { return size() == 0; }
}
/*
 * @(#)WeakHashMap.java 1.5 98/09/30
 *
 * Copyright 1998 by Sun Microsystems, Inc.,
 * 901 San Antonio Road, Palo Alto, California, 94303, U.S.A.
 * All rights reserved.
 *
 * This software is the confidential and proprietary information
 * of Sun Microsystems, Inc. ("Confidential Information").  You
 * shall not disclose such Confidential Information and shall use
 * it only in accordance with the terms of the license agreement
 * you entered into with Sun.
 */
 
// From https://github.com/mernst/plume-lib/blob/df0bfafc3c16848d88f4ea0ef3c8bf3367ae085e/java/src/plume/WeakHasherMap.java

static final class WeakHasherMap<K,V> extends AbstractMap<K,V> implements Map<K,V> {

    private Hasher hasher = null;
    /*@Pure*/
    private boolean keyEquals(Object k1, Object k2) {
  return (hasher==null ? k1.equals(k2)
           : hasher.equals(k1, k2));
    }
    /*@Pure*/
    private int keyHashCode(Object k1) {
  return (hasher==null ? k1.hashCode()
           : hasher.hashCode(k1));
    }

    // The WeakKey class can't be static because it depends on the hasher.
    // That in turn means that its methods can't be static.
    // However, I need to be able to call the methods such as create() that
    // were static in the original version of this code.
    // This finesses that.

    private /*@Nullable*/ WeakKey WeakKeyCreate(K k) {
  if (k == null) return null;
  else return new WeakKey(k);
    }
    private /*@Nullable*/ WeakKey WeakKeyCreate(K k, ReferenceQueue<? super K> q) {
  if (k == null) return null;
  else return new WeakKey(k, q);
    }

    // Cannot be a static class: uses keyHashCode() and keyEquals()
    private final class WeakKey extends WeakReference<K> {
  private int hash; /* Hashcode of key, stored here since the key
           may be tossed by the GC */

  private WeakKey(K k) {
      super(k);
      hash = keyHashCode(k);
  }

  private /*@Nullable*/ WeakKey create(K k) {
      if (k == null) return null;
      else return new WeakKey(k);
  }

  private WeakKey(K k, ReferenceQueue<? super K> q) {
      super(k, q);
      hash = keyHashCode(k);
  }

  private /*@Nullable*/ WeakKey create(K k, ReferenceQueue<? super K> q) {
      if (k == null) return null;
      else return new WeakKey(k, q);
  }

        /* A WeakKey is equal to another WeakKey iff they both refer to objects
     that are, in turn, equal according to their own equals methods */
  /*@Pure*/
  @Override
  public boolean equals(/*@Nullable*/ Object o) {
            if (o == null) return false; // never happens
      if (this == o) return true;
            // This test is illegal because WeakKey is a generic type,
            // so use the getClass hack below instead.
      // if (!(o instanceof WeakKey)) return false;
            if (!(o.getClass().equals(WeakKey.class))) return false;
      Object t = this.get();
            @SuppressWarnings("unchecked")
      Object u = ((WeakKey)o).get();
      if ((t == null) || (u == null)) return false;
      if (t == u) return true;
      return keyEquals(t, u);
  }

  /*@Pure*/
  @Override
  public int hashCode() {
      return hash;
  }

    }


    /* Hash table mapping WeakKeys to values */
    private HashMap<WeakKey,V> hash;

    /* Reference queue for cleared WeakKeys */
    private ReferenceQueue<? super K> queue = new ReferenceQueue<K>();


    /* Remove all invalidated entries from the map, that is, remove all entries
       whose keys have been discarded.  This method should be invoked once by
       each public mutator in this class.  We don't invoke this method in
       public accessors because that can lead to surprising
       ConcurrentModificationExceptions. */
    @SuppressWarnings("unchecked")
    private void processQueue() {
  WeakKey wk;
  while ((wk = (WeakKey)queue.poll()) != null) { // unchecked cast
      hash.remove(wk);
  }
    }


    /* -- Constructors -- */

    /**
     * Constructs a new, empty <code>WeakHashMap</code> with the given
     * initial capacity and the given load factor.
     *
     * @param  initialCapacity  the initial capacity of the
     *                          <code>WeakHashMap</code>
     *
     * @param  loadFactor       the load factor of the <code>WeakHashMap</code>
     *
     * @throws IllegalArgumentException  If the initial capacity is less than
     *                                   zero, or if the load factor is
     *                                   nonpositive
     */
    public WeakHasherMap(int initialCapacity, float loadFactor) {
  hash = new HashMap<WeakKey,V>(initialCapacity, loadFactor);
    }

    /**
     * Constructs a new, empty <code>WeakHashMap</code> with the given
     * initial capacity and the default load factor, which is
     * <code>0.75</code>.
     *
     * @param  initialCapacity  the initial capacity of the
     *                          <code>WeakHashMap</code>
     *
     * @throws IllegalArgumentException  If the initial capacity is less than
     *                                   zero
     */
    public WeakHasherMap(int initialCapacity) {
  hash = new HashMap<WeakKey,V>(initialCapacity);
    }

    /**
     * Constructs a new, empty <code>WeakHashMap</code> with the default
     * capacity and the default load factor, which is <code>0.75</code>.
     */
    public WeakHasherMap() {
  hash = new HashMap<WeakKey,V>();
    }

    /**
     * Constructs a new, empty <code>WeakHashMap</code> with the default
     * capacity and the default load factor, which is <code>0.75</code>.
     * The <code>WeakHashMap</code> uses the specified hasher for hashing
     * keys and comparing them for equality.
     * @param h the Hasher to use when hashing values for this map
     */
    public WeakHasherMap(Hasher h) {
  hash = new HashMap<WeakKey,V>();
  hasher = h;
    }


    /* -- Simple queries -- */

    /**
     * Returns the number of key-value mappings in this map.
     * <strong>Note:</strong> <em>In contrast to most implementations of the
     * <code>Map</code> interface, the time required by this operation is
     * linear in the size of the map.</em>
     */
    /*@Pure*/
    @Override
    public int size() {
  return entrySet().size();
    }

    /**
     * Returns <code>true</code> if this map contains no key-value mappings.
     */
    /*@Pure*/
    @Override
    public boolean isEmpty() {
  return entrySet().isEmpty();
    }

    /**
     * Returns <code>true</code> if this map contains a mapping for the
     * specified key.
     *
     * @param   key   the key whose presence in this map is to be tested
     */
    /*@Pure*/
    @Override
    public boolean containsKey(Object key) {
        @SuppressWarnings("unchecked")
        K kkey = (K) key;
  return hash.containsKey(WeakKeyCreate(kkey));
    }


    /* -- Lookup and modification operations -- */

    /**
     * Returns the value to which this map maps the specified <code>key</code>.
     * If this map does not contain a value for this key, then return
     * <code>null</code>.
     *
     * @param  key  the key whose associated value, if any, is to be returned
     */
    /*@Pure*/
    @Override
    public /*@Nullable*/ V get(Object key) {  // type of argument is Object, not K
        @SuppressWarnings("unchecked")
        K kkey = (K) key;
  return hash.get(WeakKeyCreate(kkey));
    }

    /**
     * Updates this map so that the given <code>key</code> maps to the given
     * <code>value</code>.  If the map previously contained a mapping for
     * <code>key</code> then that mapping is replaced and the previous value is
     * returned.
     *
     * @param  key    the key that is to be mapped to the given
     *                <code>value</code>
     * @param  value  the value to which the given <code>key</code> is to be
     *                mapped
     *
     * @return  the previous value to which this key was mapped, or
     *          <code>null</code> if if there was no mapping for the key
     */
    @Override
    public V put(K key, V value) {
  processQueue();
  return hash.put(WeakKeyCreate(key, queue), value);
    }

    /**
     * Removes the mapping for the given <code>key</code> from this map, if
     * present.
     *
     * @param  key  the key whose mapping is to be removed
     *
     * @return  the value to which this key was mapped, or <code>null</code> if
     *          there was no mapping for the key
     */
    @Override
    public V remove(Object key) { // type of argument is Object, not K
  processQueue();
        @SuppressWarnings("unchecked")
        K kkey = (K) key;
  return hash.remove(WeakKeyCreate(kkey));
    }

    /**
     * Removes all mappings from this map.
     */
    @Override
    public void clear() {
  processQueue();
  hash.clear();
    }


    /* -- Views -- */


    /* Internal class for entries */
    // This can't be static, again because of dependence on hasher.
    @SuppressWarnings("TypeParameterShadowing")
    private final class Entry<K,V> implements Map.Entry<K,V> {
  private Map.Entry<WeakKey,V> ent;
  private K key;  /* Strong reference to key, so that the GC
           will leave it alone as long as this Entry
           exists */

  Entry(Map.Entry<WeakKey,V> ent, K key) {
      this.ent = ent;
      this.key = key;
  }

  /*@Pure*/
  @Override
  public K getKey() {
      return key;
  }

  /*@Pure*/
  @Override
  public V getValue() {
      return ent.getValue();
  }

  @Override
  public V setValue(V value) {
      return ent.setValue(value);
  }

        /*@Pure*/
        private boolean keyvalEquals(K o1, K o2) {
      return (o1 == null) ? (o2 == null) : keyEquals(o1, o2);
  }

        /*@Pure*/
        private boolean valEquals(V o1, V o2) {
      return (o1 == null) ? (o2 == null) : o1.equals(o2);
  }

        /*@Pure*/
        @SuppressWarnings("NonOverridingEquals")
        public boolean equals(Map.Entry<K,V> e /* Object o*/) {
            // if (! (o instanceof Map.Entry)) return false;
            // Map.Entry<K,V> e = (Map.Entry<K,V>)o;
      return (keyvalEquals(key, e.getKey())
        && valEquals(getValue(), e.getValue()));
  }

  /*@Pure*/
  @Override
  public int hashCode() {
      V v;
      return (((key == null) ? 0 : keyHashCode(key))
        ^ (((v = getValue()) == null) ? 0 : v.hashCode()));
  }

    }


    /* Internal class for entry sets */
    private final class EntrySet extends AbstractSet<Map.Entry<K,V>> {
  Set<Map.Entry<WeakKey,V>> hashEntrySet = hash.entrySet();

  @Override
  public Iterator<Map.Entry<K,V>> iterator() {

      return new Iterator<Map.Entry<K,V>>() {
    Iterator<Map.Entry<WeakKey,V>> hashIterator = hashEntrySet.iterator();
    Map.Entry<K,V> next = null;

    @Override
    public boolean hasNext() {
        while (hashIterator.hasNext()) {
      Map.Entry<WeakKey,V> ent = hashIterator.next();
      WeakKey wk = ent.getKey();
      K k = null;
      if ((wk != null) && ((k = wk.get()) == null)) {
          /* Weak key has been cleared by GC */
          continue;
      }
      next = new Entry<K,V>(ent, k);
      return true;
        }
        return false;
    }

    @Override
    public Map.Entry<K,V> next() {
        if ((next == null) && !hasNext())
      throw new NoSuchElementException();
        Map.Entry<K,V> e = next;
        next = null;
        return e;
    }

    @Override
    public void remove() {
        hashIterator.remove();
    }

      };
  }

  /*@Pure*/
  @Override
  public boolean isEmpty() {
      return !(iterator().hasNext());
  }

  /*@Pure*/
  @Override
  public int size() {
      int j = 0;
      for (Iterator<Map.Entry<K,V>> i = iterator(); i.hasNext(); i.next()) j++;
      return j;
  }

  @Override
  public boolean remove(Object o) {
      processQueue();
      if (!(o instanceof Map.Entry<?,?>)) return false;
            @SuppressWarnings("unchecked")
      Map.Entry<K,V> e = (Map.Entry<K,V>)o; // unchecked cast
      Object ev = e.getValue();
      WeakKey wk = WeakKeyCreate(e.getKey());
      Object hv = hash.get(wk);
      if ((hv == null)
    ? ((ev == null) && hash.containsKey(wk)) : hv.equals(ev)) {
    hash.remove(wk);
    return true;
      }
      return false;
  }

  /*@Pure*/
  @Override
  public int hashCode() {
      int h = 0;
      for (Iterator<Map.Entry<WeakKey,V>> i = hashEntrySet.iterator(); i.hasNext(); ) {
    Map.Entry<WeakKey,V> ent = i.next();
    WeakKey wk = ent.getKey();
    Object v;
    if (wk == null) continue;
    h += (wk.hashCode()
          ^ (((v = ent.getValue()) == null) ? 0 : v.hashCode()));
      }
      return h;
  }

    }


    private /*@Nullable*/ Set<Map.Entry<K,V>> entrySet = null;

    /**
     * Returns a <code>Set</code> view of the mappings in this map.
     */
    /*@SideEffectFree*/
    @Override
    public Set<Map.Entry<K,V>> entrySet() {
  if (entrySet == null) entrySet = new EntrySet();
  return entrySet;
    }

    // find matching key
    K findKey(Object key) {
      processQueue();
      K kkey = (K) key;
      // TODO: use replacement for HashMap to avoid reflection
      WeakKey wkey = WeakKeyCreate(kkey);
      WeakKey found = hashMap_findKey(hash, wkey);
      return found == null ? null : found.get();
    }
}
// -has fast nextElement() and prevElement()
// -design allows for more functions like reordering the list
// -Saves up to 34% in space over LinkedHashSet
//    (e.g. 22% for a set of 1,000 Ints)
static class CompactLinkedHashSet<A> extends AbstractSet<A> {
  UnsynchronizedCompactHashSet<Entry<A>> entries = new UnsynchronizedCompactHashSet();
  Entry<A> head, tail;
  
  static class Entry<A> {
    A value;
    Entry<A> prev, next;
    
    public int hashCode() {
      return _hashCode(value);
    }
    
    // "magic" equals function for CompactHashSet lookup without temp object
    public boolean equals(Object o) {
      return o == this || eq(value, o);
    }
  }
  
  public boolean add(A a) {
    if (entries.contains(a)) return false;
    Entry<A> n = new Entry();
    n.value = a;
    n.prev = tail;
    if (tail != null) tail.next = n;
    tail = n;
    if (head == null) head = n;
    entries.add(n);
    return true;
  }
  
  public boolean remove(Object a) {
    return remove(entries.find(a));
  }
  
  public boolean remove(Entry<A> node) {
    if (node == null) return false;
    if (node.next != null) node.next.prev = node.prev; else tail = node.prev;
    if (node.prev != null) node.prev.next = node.next; else head = node.next;
    entries.remove(node);
    return true;
  }
  
  public int size() { return entries.size(); }
  
  public IterableIterator<A> iterator() {
    return new IterableIterator<A>() {
      Entry<A> entry = head, prev = null;
      public boolean hasNext() { return entry != null; }
      public A next() {
        A a = entry.value;
        prev = entry;
        entry = entry.next;
        return a;
      }
      
      // untested
      public void remove() {
        if (prev == null) throw new IllegalStateException();
        CompactLinkedHashSet.this.remove(prev);
        prev = null;
      }
    };
  }
  
  public void clear() {
    entries.clear();
    head = tail = null;
  }
  
  public boolean contains(Object a) {
    return entries.contains(a);
  }
  
  public A find(Object o) {
    Entry<A> e = entries.find(o);
    return e == null ? null : e.value;
  }
  
  public A prevElement(A a) {
    Entry<A> e = entries.find(a);
    if (e == null || e.prev == null) return null;
    return e.prev.value;
  }
  
  public A nextElement(A a) {
    Entry<A> e = entries.find(a);
    if (e == null || e.next == null) return null;
    return e.next.value;
  }
  
  public A first() { return head == null ? null : head.value; }
  public A last() { return tail == null ? null : tail.value; }
  
  boolean removeIfSame(Object o) {
    A value = find(o);
    if (value == o) {
      remove(value);
      return true;
    }
    return false;
  }
}
static class Pair<A, B> implements Comparable<Pair<A, B>> {
   final public Pair<A, B> setA(A a){ return a(a); }
public Pair<A, B> a(A a) { this.a = a; return this; }  final public A getA(){ return a(); }
public A a() { return a; }
 A a;
   final public Pair<A, B> setB(B b){ return b(b); }
public Pair<A, B> b(B b) { this.b = b; return this; }  final public B getB(){ return b(); }
public B b() { return b; }
 B b;

  Pair() {}
  Pair(A a, B b) {
  this.b = b;
  this.a = a;}
  
  public int hashCode() {
    return hashCodeFor(a) + 2*hashCodeFor(b);
  }
  
  public boolean equals(Object o) {
    if (o == this) return true;
    if (!(o instanceof Pair)) return false;
    Pair t = (Pair) o;
    return eq(a, t.a) && eq(b, t.b);
  }
  
  public String toString() {
    return "<" + a + ", " + b + ">";
  }
  
  public int compareTo(Pair<A, B> p) {
    if (p == null) return 1;
    int i = ((Comparable<A>) a).compareTo(p.a);
    if (i != 0) return i;
    return ((Comparable<B>) b).compareTo(p.b);
  }
}
static class Fail extends RuntimeException implements IFieldsToList{
  Object[] objects;
  Fail() {}
  Fail(Object... objects) {
  this.objects = objects;}public Object[] _fieldsToList() { return new Object[] {objects}; }

  Fail(Throwable cause, Object... objects) {
    super(cause);
  this.objects = objects;
  }
  
  public String toString() { return joinNemptiesWithColon("Fail", getMessage()); }
  
  public String getMessage() { return commaCombine(getCause(), objects); }
}
static class Rect implements WidthAndHeight , IFieldsToList{
  static final String _fieldOrder = "x y w h";
  int x;
  int y;
  int w;
  int h;
  Rect() {}
  Rect(int x, int y, int w, int h) {
  this.h = h;
  this.w = w;
  this.y = y;
  this.x = x;}

public boolean equals(Object o) {
if (!(o instanceof Rect)) return false;
    Rect __1 =  (Rect) o;
    return x == __1.x && y == __1.y && w == __1.w && h == __1.h;
}

  public int hashCode() {
    int h = 2543108;
    h = boostHashCombine(h, _hashCode(x));
    h = boostHashCombine(h, _hashCode(y));
    h = boostHashCombine(h, _hashCode(w));
    h = boostHashCombine(h, _hashCode(h));
    return h;
  }
  public Object[] _fieldsToList() { return new Object[] {x, y, w, h}; }

  Rect(Rectangle r) {
    x = r.x;
    y = r.y;
    w = r.width;
    h = r.height;
  }
  
  Rect(Pt p, int w, int h) {
  this.h = h;
  this.w = w; x = p.x; y = p.y; }
  Rect(Rect r) { x = r.x; y = r.y; w = r.w; h = r.h; }
  
  final Rectangle getRectangle() {
    return new Rectangle(x, y, w, h);
  }
  
  public String toString() {
    return x + "," + y + " / " + w + "," + h;
  }
  
  final int x1() { return x; }
  final int y1() { return y; }
  final int x2() { return x + w; }
  final int y2() { return y + h; }
  
  final boolean contains(Pt p) {
    return contains(p.x, p.y);
  }
  
  final boolean contains(int _x, int _y) {
    return _x >= x && _y >= y && _x < x+w && _y < y+h;
  }
  
  final boolean contains(Rectangle r) {
    return rectContains(this, r);
  }
  
  final boolean empty() { return w <= 0 || h <= 0; }
  
  final public int getWidth() { return w; }
  final public int getHeight() { return h; }
  
  final public int area() { return w*h; }
  
  final public int x() { return x; }
  final public int y() { return y; }
  
  WidthAndHeight widthAndHeight() { return main.widthAndHeight(w, h); }
}
static class Pt implements Comparable<Pt>, IDoublePt {
  int x, y;
  
  Pt() {}
  Pt(Point p) {
    x = p.x;
    y = p.y;
  }
  Pt(int x, int y) {
  this.y = y;
  this.x = x;}
  
  Point getPoint() {
    return new Point(x, y);
  }
  
  public boolean equals(Object o) {
    return o instanceof Pt && x == ((Pt) o).x && y == ((Pt) o).y;
  }
  
  public int hashCode() {
    return boostHashCombine(x, y);
  }
  
  // compare in scan order
  public int compareTo(Pt p) {
    if (y != p.y) return cmp(y, p.y);
    return cmp(x, p.x);
  }
  
  public String toString() {
    return x + ", " + y;
  }
  
  double length() { return sqrt(x*x+y*y); }
  
  public Pt minus(Pt p) { return ptMinus(this, p); }
  
  public double x_double() { return x; }
  public double y_double() { return y; }
}
static class MapI<A, B> extends IterableIterator<B> {
  IF1<A, B> f;
  Iterator<A> it;
  
  MapI(IF1<A, B> f, Iterator<A> it) {
  this.it = it;
  this.f = f;}
  
  public boolean hasNext() {
    return it.hasNext();
  }
  
  public B next() {
    return f.get(it.next());
  }
}

static abstract class F0<A> {
  abstract A get();
}
// We use big-endian as DataOutputStream does
static class ByteHead /*is DataOutput*/ implements AutoCloseable {
   final public ByteHead setReadMode(boolean readMode){ return readMode(readMode); }
public ByteHead readMode(boolean readMode) { this.readMode = readMode; return this; }  final public boolean getReadMode(){ return readMode(); }
public boolean readMode() { return readMode; }
 boolean readMode = false;
   final public ByteHead setWriteMode(boolean writeMode){ return writeMode(writeMode); }
public ByteHead writeMode(boolean writeMode) { this.writeMode = writeMode; return this; }  final public boolean getWriteMode(){ return writeMode(); }
public boolean writeMode() { return writeMode; }
 boolean writeMode = false;
   final public InputStream getInputStream(){ return inputStream(); }
public InputStream inputStream() { return inputStream; }
 InputStream inputStream;
   final public OutputStream getOutputStream(){ return outputStream(); }
public OutputStream outputStream() { return outputStream; }
 OutputStream outputStream;
   final public ByteHead setByteCounter(long byteCounter){ return byteCounter(byteCounter); }
public ByteHead byteCounter(long byteCounter) { this.byteCounter = byteCounter; return this; }  final public long getByteCounter(){ return byteCounter(); }
public long byteCounter() { return byteCounter; }
 long byteCounter;
   final public boolean getEof(){ return eof(); }
public boolean eof() { return eof; }
 boolean eof = false;
  
  ByteHead() {}
  ByteHead(InputStream inputStream) { inputStream(inputStream); }
  ByteHead(OutputStream outputStream) { outputStream(outputStream); }
  
  ByteHead inputStream(InputStream inputStream) { this.inputStream = inputStream; readMode(true); return this; }
  ByteHead outputStream(OutputStream outputStream) { this.outputStream = outputStream; writeMode(true); return this; }
  
  void write(byte[] data) { try {
    ensureWriteMode();
    { if (outputStream != null) outputStream.write(data); }
    byteCounter += data.length;
  } catch (Exception __e) { throw rethrow(__e); } }
  
  void writeFloat(float f) {
    writeInt(Float.floatToIntBits(f));
  }
  
  void writeLong(long l) {
    writeInt((int) (l >> 32));
    writeInt((int) l);
  }
  
  void writeInt(int i) {
    write(i >> 24);
    write(i >> 16);
    write(i >> 8);
    write(i);
  }
  
  void writeShort(int i) {
    write(i >> 8);
    write(i);
  }
  
  final void write(int i){ writeByte(i); }
void writeByte(int i) { try {
    ensureWriteMode();
    { if (outputStream != null) outputStream.write(i); }
    byteCounter++;
  } catch (Exception __e) { throw rethrow(__e); } }
  
  void writeASCII(char c) {
    write(toASCII(c));
  }
  
  void writeASCII(String s) {
    write(toASCII(s));
  }
  
  // write/verify constant ASCII text
  void exchangeASCII(String s) {
    exchangeConstantBytes(toASCII(s));
  }
  
  void exchangeConstantBytes(byte[] data) {
    for (int i = 0; i < l(data); i++)
      exchangeByte(data[i]);
  }
  
  long readLong() {
    long i = ((long) readInt()) << 32;
    return i | (readInt() & 0xFFFFFFFFL);
  }
  
  float readFloat() {
    return Float.intBitsToFloat(readInt());
  }
  
  int readInt() {
    int i = read() << 24;
    i |= read() << 16;
    i |= read() << 8;
    return i | read();
  }
  
  short readShort() {
    int i = read() << 8;
    return (short) (i | read());
  }
  
  byte[] readBytes(int n) {
    byte[] data = new byte[n];
    for (int i = 0; i < n; i++) {
      int b = read();
      if (b < 0)
        throw fail("EOF");
      data[i] = (byte) b; 
    }
    return data;
  }
  
  String readString() {
    int n = readInt();
    if (eof()) return null;
    return fromUtf8(readBytes(n));
  }
  
  // null is written as empty string
  // writes UTF8 length (4 bytes) plus string as UTF8
  void writeString(String s) {
    byte[] utf8 = toUtf8(unnull(s));
    writeInt(l(utf8));
    write(utf8);
  }
  
  // -1 for EOF
  final int read(){ return readByte(); }
int readByte() { try {
    ensureReadMode();
    ++byteCounter;
    int b = inputStream.read();
    if (b < 0) eof = true;
    return b;
  } catch (Exception __e) { throw rethrow(__e); } }
  
  void ensureReadMode() {
    if (!readMode) throw fail("Not in read mode");
  }
  
  void ensureWriteMode() {
    if (!writeMode) throw fail("Not in write mode");
  }
  
  // exchange = read or write depending on mode
  
  void exchangeByte(byte getter, IVF1<Byte> setter) {
    exchangeByte(() -> getter, setter);
  }
  
  void exchangeByte(IF0<Byte> getter, IVF1<Byte> setter) {
    if (writeMode())
      writeByte(getter.get());
    
    if (readMode())
      setter.get(toUByte(readByte()));
  }
  
  void exchangeShort(IF0<Short> getter, IVF1<Short> setter) {
    if (writeMode())
      writeShort(getter.get());
    
    if (readMode())
      setter.get(readShort());
  }
  
  void exchangeLong(IVar<Long> var) {
    exchangeLong(var.getter(), var.setter());
  }
  
  void exchangeLong(IF0<Long> getter, IVF1<Long> setter) {
    if (writeMode())
      writeLong(getter.get());

    if (readMode())
      setter.get(readLong());
  }
  
  void exchangeByte(byte i) {
    exchangeByte(() -> i, j -> assertEquals(i, j));
  }
  
  void exchangeInt(int i) {
    exchangeInt(() -> i, j -> assertEquals(i, j));
  }
  
  void exchangeInt(IF0<Integer> getter, IVF1<Integer> setter) {
    if (writeMode())
      writeInt(getter.get());

    if (readMode())
      setter.get(readInt());
  }
  
  void exchange(ByteIO writable) {
    if (writable != null) writable.readWrite(this);
  }
  
  void exchangeAll(Iterable<? extends ByteIO> writables) {  
    if (writables != null)
      for (var writable : writables)
        exchange(writable);
  }
  
  // write size in bytes of element first (as int),
  // then the element itself.
  // upon reading, size is actually ignored.
  void exchangeWithSize(ByteIO writable) {
    if (writeMode()) {
      byte[] data = writable.saveToByteArray();
      writeInt(l(data));
      write(data);
    }
    
    if (readMode()) {
      int n = readInt();
      writable.readWrite(this);
    }
  }
  
  void finish() {}
  
  public void close() {
    main.close(inputStream);
    main.close(outputStream);
    finish();
  }
}
static abstract class F1<A, B> {
  abstract B get(A a);
}
// you still need to implement hasNext() and next()
static abstract class IterableIterator<A> implements Iterator<A>, Iterable<A> {
  public Iterator<A> iterator() {
    return this;
  }
  
  public void remove() {
    unsupportedOperation();
  }
}
static class TimestampRange implements Comparable<TimestampRange> , IFieldsToList{
  static final String _fieldOrder = "start end";
  Timestamp start;
  Timestamp end;
  TimestampRange() {}
  TimestampRange(Timestamp start, Timestamp end) {
  this.end = end;
  this.start = start;}

public boolean equals(Object o) {
if (!(o instanceof TimestampRange)) return false;
    TimestampRange __1 =  (TimestampRange) o;
    return eq(start, __1.start) && eq(end, __1.end);
}

  public int hashCode() {
    int h = -2020922905;
    h = boostHashCombine(h, _hashCode(start));
    h = boostHashCombine(h, _hashCode(end));
    return h;
  }
  public Object[] _fieldsToList() { return new Object[] {start, end}; }

  TimestampRange(long start, long end) {
    this(new Timestamp(start), new Timestamp(end));
  }
  
  final Timestamp startTime(){ return start(); }
Timestamp start() { return start; }
  final Timestamp endTime(){ return end(); }
Timestamp end() { return end; }
  
  final TimestampRange startTime(Timestamp start){ return start(start); }
TimestampRange start(Timestamp start) { this.start = start; return this; }
  final TimestampRange endTime(Timestamp end){ return end(end); }
TimestampRange end(Timestamp end) { this.end = end; return this; }
  
  boolean complete() { return start != null && end != null; }
  
  Duration duration() { return !complete() ? null : end.minusAsDuration(start); }
  
  long length() { return !complete() ? 0 : end.unixDate()-start.unixDate(); }
  
  public String toString() { return start + " to " + end; }
  
  public int compareTo(TimestampRange r) {
    return cmp(start, r.start);
  }
  
  List<Timestamp> toList() { return ll(start, end); }
}
interface PCallPolicy {
  void handlePcallFail(Throwable e);
}
/*
Typical way to implement (from WidthAndHeightImpl):
ifclass ByteHead
  public void readWrite(ByteHead head) {
    head.exchangeInt(l0 width, w -> width = w);
    head.exchangeInt(l0 height, h -> height = h);
  }
endif
*/

interface ByteIO {
  
  
  
void readWrite(ByteHead head);

default byte[] saveAsByteArray(){ return saveToByteArray(); }
default byte[] toByteArray(){ return saveToByteArray(); }
default byte[] saveToByteArray() { return saveToByteArray(new ByteHead()); }
default byte[] saveAsByteArray(ByteHead head){ return saveToByteArray(head); }
default byte[] toByteArray(ByteHead head){ return saveToByteArray(head); }
default byte[] saveToByteArray(ByteHead head) {
  var baos = byteArrayOutputStream();
  head.outputStream(baos);
  readWrite(head);
  head.finish();
  return baos.toByteArray();
}

default String toHexString() {
  return main.toHexString(toByteArray());
}

default File saveToFile(File file) {
   OutputStream out = bufferedFileOutputStream(file); try {
  var head = new ByteHead(out);
  readWrite(head);
  head.finish();
  return file;
} finally { _close(out); }}

default ByteIO fromByteArray(byte[] data){ return load(data); }
default ByteIO load(byte[] data) {
  readWrite(new ByteHead(new ByteArrayInputStream(data)));
  return this;
}

default ByteIO load(File file) {
   InputStream in = bufferedInputStream(file); try {
  readWrite(new ByteHead(in));
  return this;
} finally { _close(in); }}

default long byteIOLength() {
  JustCountingOutputStream out = new JustCountingOutputStream();
  var head = new ByteHead(out);
  readWrite(head);
  head.finish();
  return out.get();
}

}
public static interface IF0<A> {
  A get();
}
static interface Hasher<A> {
  int hashCode(A a);
  boolean equals(A a, A b);
}

static interface IF2<A, B, C> {
  C get(A a, B b);
}
static interface IF1<A, B> {
  B get(A a);
}
// TODO: subclass RuntimeException and use Meta instead of DynamicObject
static class PersistableThrowable extends DynamicObject {
  String className;
  String msg;
  String stacktrace;
   final public PersistableThrowable setActualThrowable(Throwable actualThrowable){ return actualThrowable(actualThrowable); }
public PersistableThrowable actualThrowable(Throwable actualThrowable) { this.actualThrowable = actualThrowable; return this; }  final public Throwable getActualThrowable(){ return actualThrowable(); }
public Throwable actualThrowable() { return actualThrowable; }
transient Throwable actualThrowable;
  
  PersistableThrowable() {}
  PersistableThrowable(Throwable e) {
    actualThrowable = e;
    if (e == null)
      className = "Crazy Null Error";
    else {
      className = getClassName(e).replace('/', '.');
      msg = e.getMessage();
      stacktrace = getStackTrace_noRecord(e);
    }
  }
  
  public String toString() {
    return nempty(msg) ? className + ": " + msg : className;
  }
  
  RuntimeException asRuntimeException() {
    if (actualThrowable != null)
      return main.asRuntimeException(actualThrowable);
    return new Fail(this);
  }
}
static interface IVF1<A> {
  void get(A a);
}
static interface IVF2<A, B> {
  void get(A a, B b);
}


static class DoubleBuffer implements Iterable<Double>, IntSize {
  double[] data;
  int size;
  
  DoubleBuffer() {}
  DoubleBuffer(int size) { if (size != 0) data = new double[size]; }
  DoubleBuffer(Iterable<Double> l) { addAll(l); }
  DoubleBuffer(Collection<Double> l) { this(l(l)); addAll(l); }
  DoubleBuffer(double... data) { this.data = data; size = l(data); }
  
  void add(double i) {
    if (size >= lDoubleArray(data)) {
      data = resizeDoubleArray(data, Math.max(1, toInt(Math.min(maximumSafeArraySize(), lDoubleArray(data)*2L))));
      if (size >= data.length) throw fail("DoubleBuffer too large: " + size);
    }
    data[size++] = i;
  }
  
  void addAll(Iterable<Double> l) {
    if (l != null) for (double i : l) add(i);
  }
  
  double[] toArray() {
    return size == 0 ? null : resizeDoubleArray(data, size);
  }
  
  double[] toArrayNonNull() {
    return unnull(toArray());
  }
  
  List<Double> toList() {
    return doubleArrayToList(data, 0, size);
  }

  List<Double> asVirtualList() {
    return new RandomAccessAbstractList<Double>() {
      public int size() { return size; }
      public Double get(int i) { return DoubleBuffer.this.get(i); }
      public Double set(int i, Double val) {
        Double a = get(i);
        data[i] = val;
        return a;
      }
    };
  }
  
  void reset() { size = 0; }
  void clear() { reset(); }
  
  public int size() { return size; }

  double get(int idx) {
    if (idx >= size) throw fail("Index out of range: " + idx + "/" + size);
    return data[idx];
  }
  
  void set(int idx, double value) {
    if (idx >= size) throw fail("Index out of range: " + idx + "/" + size);
    data[idx] = value;
  }
  
  double popLast() {
    if (size == 0) throw fail("empty buffer");
    return data[--size];
  }
  
  double last() { return data[size-1]; }
  double nextToLast() { return data[size-2]; }
  
  public String toString() { return squareBracket(joinWithSpace(toList())); }
  
  public Iterator<Double> iterator() {
    return new IterableIterator<Double>() {
      int i = 0;
      
      public boolean hasNext() { return i < size; }
      public Double next() {
        //if (!hasNext()) fail("Index out of bounds: " + i);
        return data[i++];
      }
    };
  }
  
  /*public DoubleIterator doubleIterator() {
    ret new DoubleIterator {
      int i = 0;
      
      public bool hasNext() { ret i < size; }
      public int next() {
        //if (!hasNext()) fail("Index out of bounds: " + i);
        ret data[i++];
      }
      toString { ret "Iterator@" + i + " over " + DoubleBuffer.this; }
    };
  }*/
  
  void trimToSize() {
    data = resizeDoubleArray(data, size);
  }
  
  int indexOf(double b) {
    for (int i = 0; i < size; i++)
      if (data[i] == b)
        return i;
    return -1;
  }
  
  double[] subArray(int start, int end) {
    return subDoubleArray(data, start, min(end, size));
  }
}
static class PricePoint implements IFieldsToList{
  static final String _fieldOrder = "timestamp price";
  long timestamp;
  double price;
  PricePoint() {}
  PricePoint(long timestamp, double price) {
  this.price = price;
  this.timestamp = timestamp;}

public boolean equals(Object o) {
if (!(o instanceof PricePoint)) return false;
    PricePoint __1 =  (PricePoint) o;
    return timestamp == __1.timestamp && price == __1.price;
}

  public int hashCode() {
    int h = 516290023;
    h = boostHashCombine(h, _hashCode(timestamp));
    h = boostHashCombine(h, _hashCode(price));
    return h;
  }
  public Object[] _fieldsToList() { return new Object[] {timestamp, price}; }

  public String toString() {
    return formatPrice(price) + " @ " + formatLocalDateWithSeconds(timestamp);
  }
  
  final long timestamp(){ return time(); }
long time() { return timestamp; }
  double price() { return price; }
}
interface PriceCells {
  boolean isCellLimit(double price);
  
  // next-higher cell limit or NaN if no more cells
  double nextCellLimit(double price);
  
  // next-lower cell limit or NaN if no more cells
  double previousCellLimit(double price);
  
  // go n steps down
  double nCellLimitsDown(double price, int n);
  
  // go n steps up
  double nCellLimitsUp(double price, int n);
  
  // convert to "cell space" (0=first cell limit, 1=next cell limit, -1=previous cell limit etc)
  default double toCellNumber(double price){ return priceToCellNumber(price); }
double priceToCellNumber(double price);
  
  default double fromCellNumber(double cellNumber){ return cellNumberToPrice(cellNumber); }
double cellNumberToPrice(double cellNumber);
  
  default double basePrice() { return cellNumberToPrice(0); }
}
static class PingSourceCancelledException extends RuntimeException implements IFieldsToList{
  PingSource pingSource;
  PingSourceCancelledException() {}
  PingSourceCancelledException(PingSource pingSource) {
  this.pingSource = pingSource;}
  public String toString() { return shortClassName_dropNumberPrefix(this) + "(" + pingSource + ")"; }public Object[] _fieldsToList() { return new Object[] {pingSource}; }

}
static interface ISetter<A> {
 void set(A a);
}

static class JustCountingOutputStream extends OutputStream {
  long counter;
  
  @Override
  public void write(int b) throws IOException {
    ++counter;
  }

  @Override
  public void write(byte[] b) throws IOException {
    counter += b.length;
  }

  @Override
  public void write(byte[] b, int off, int len) throws IOException {
    counter += len;
  }
  
  final long get(){ return getFilePointer(); }
long getFilePointer() { return counter; }
}
static class SynchronizedLongBuffer implements ILongBuffer {
  long[] data;
  int size;
  
  SynchronizedLongBuffer() {}
  SynchronizedLongBuffer(int size) { if (size != 0) data = new long[size]; }
  SynchronizedLongBuffer(Iterable<Long> l) {
    if (l instanceof Collection) allocate(((Collection) l).size());
    addAll(l);
  }
  
  public synchronized void add(long i) {
    if (size >= lLongArray(data)) {
      data = resizeLongArray(data, Math.max(1, toInt(Math.min(maximumSafeArraySize(), lLongArray(data)*2L))));
      if (size >= data.length) throw fail("LongBuffer too large: " + size);
    }
    data[size++] = i;
  }
  
  synchronized void allocate(int n) {
    data = resizeLongArray(data, max(n, size()));
  }
  
  public synchronized void addAll(Iterable<Long> l) {
    if (l != null) for (long i : l) add(i);
  }
  
  public synchronized long[] toArray() {
    return size == 0 ? null : resizeLongArray(data, size);
  }
  
  synchronized List<Long> toList() {
    return longArrayToList(data, 0, size);
  }
  
  public synchronized List<Long> asVirtualList() {
    return listFromFunction(__40 -> get(__40), size);
  }
  
  synchronized void reset() { size = 0; }
  void clear() { reset(); }
  
  synchronized public int size() { return size; }
  public synchronized boolean isEmpty() { return size == 0; }
  
  public synchronized long get(int idx) {
    if (idx >= size) throw fail("Index out of range: " + idx + "/" + size);
    return data[idx];
  }
  
  synchronized void set(int idx, long value) {
    if (idx >= size) throw fail("Index out of range: " + idx + "/" + size);
    data[idx] = value;
  }
  
  public synchronized long popLast() {
    if (size == 0) throw fail("empty buffer");
    return data[--size];
  }
  
  public synchronized long last() { return data[size-1]; }
  synchronized long nextToLast() { return data[size-2]; }
  
  public String toString() { return squareBracket(joinWithSpace(toList())); }
  
  public synchronized Iterator<Long> iterator() {
    return new IterableIterator<Long>() {
      int i = 0;
      
      public boolean hasNext() { return i < size(); }
      public Long next() {
        synchronized(SynchronizedLongBuffer.this) {
          if (!hasNext()) throw fail("Index out of bounds: " + i);
          return data[i++];
        }
      }
    };
  }
  
  public synchronized void trimToSize() {
    data = resizeLongArray(data, size);
  }
  
  synchronized void remove(int idx) {
    arraycopy(data, idx+1, data, idx, size-1-idx);
    --size;
  }
  
  // don't rely on return value if buffer is empty
  public synchronized long poll() { 
    return size == 0 ? -1 : data[--size];
  }
  
  public synchronized void insertAt(int idx, long[] l) {
    int n = l(l);
    if (n == 0) return;
    long[] newData = new long[size+n];
    arraycopy(data, 0, newData, 0, idx);
    arraycopy(l, 0, newData, idx, n);
    arraycopy(data, idx, newData, idx+n, size-idx);
    data = newData;
    size = newData.length;
  }
}
// The idea is to leave max as the actual number of cores the system
// has (numberOfCores()), and in case of being fully booked, raise an
// alert (customerMustWaitAlert) which can be handled by a strategy
// object (different reactions are possible).
// If nothing is done in such an event, clients are processed serially
// (no guarantees of order), split up among the available threads.

/* SYNChronisation order:
      1. PooledThread
      2. ThreadPool */

static class ThreadPool implements AutoCloseable {
  int max = numberOfCores();
  List<PooledThread> all = new ArrayList();
  Set<PooledThread> used = new HashSet();
  Set<PooledThread> free = new HashSet();
  boolean verbose, retired;
  
  // our own ping surce so we can start threads & keep them running
  class InternalPingSource extends PingSource {}
  InternalPingSource internalPingSource = new InternalPingSource();
  
  MultiSleeper sleeper = new MultiSleeper();
  
  ThreadPool() {}
  ThreadPool(int max) {
  this.max = max;}
  
  synchronized int maxSize() { return max; }
  synchronized int total() { return l(used)+l(free); }
  
   transient Set<Runnable> onCustomerMustWaitAlert;
public  ThreadPool onCustomerMustWaitAlert(Runnable r) { onCustomerMustWaitAlert = createOrAddToSyncLinkedHashSet(onCustomerMustWaitAlert, r); return this; }
public  ThreadPool removeCustomerMustWaitAlertListener(Runnable r) { main.remove(onCustomerMustWaitAlert, r); return this; }
public   void customerMustWaitAlert() {  if (onCustomerMustWaitAlert != null) for (var listener : onCustomerMustWaitAlert) pcallF_typed(listener); }
  
  void fireCustomerMustWaitAlert() {
    vmBus_send("customerMustWaitAlert", this, currentThread());
    customerMustWaitAlert();
  }

  // DOESN'T WAIT. adds action to a thread's queue if nothing is
  // available immediately.
  PooledThread acquireThreadOrQueue(Runnable action) {
    if (action == null) return null;
    PooledThread t;
    synchronized(this) {
      if (_hasFreeAfterCreating()) {
        t = _firstFreeThread();
        markUsed(t);
      } else
        t = _anyThread();
    }
    
    t.addWork(action); // will move it from free to used
    return t;
  }
  
  // run in synchronized block
  boolean _hasFreeAfterCreating() {
    checkNotRetired();
    if (nempty(free)) return true;
    if (total() < max) {
      PooledThread t = newThread();
      all.add(t);
      free.add(t);
      return true;
    }
    return false;
  }
  
  // WAITS until thread is available
  PooledThread acquireThreadOrWait(Runnable action) { try {
    if (action == null) return null;
    PooledThread t;
    while (true) {
      synchronized(this) {
        if (_hasFreeAfterCreating()) {
          t = _firstFreeThread();
          break;
        } else
          _waitWaitWait();
      }
    }
    t.addWork(action);
    return t;
  } catch (Exception __e) { throw rethrow(__e); } }
  
  PooledThread _firstFreeThread() {
    return first(free);
  }
  
  PooledThread _anyThread() {
    return random(used);
  }
  
  class PooledThread extends Thread {
    PooledThread(String name) { super(name); }
    
    AppendableChain<Runnable> q;
    
    synchronized Runnable _grabWorkOrSleep() { try {
      Runnable r = first(q);
      if (r == null) {
        markFree(this);
        if (verbose) print("Thread sleeps");
        synchronized(this) { wait(); }
        if (verbose) print("Thread woke up");
        return null;
      }
      q = popFirst(q);
      return r;
    } catch (Exception __e) { throw rethrow(__e); } }
    
    public void run() { try {
      pingSource_tl().set(internalPingSource);
      while  (!retired()) { ping(); 
        Runnable r = _grabWorkOrSleep();
        if (verbose) print(this + " work: " + r);
        if (r != null)
          try {
            if (verbose) print(this + " running: " + r);
            r.run();
            pingSource_tl().set(internalPingSource);
            if (verbose) print(this + " done");
          } catch (Throwable e) {
            pingSource_tl().set(internalPingSource);
            if (verbose) print(this + " error");
            printStackTrace(e);
          } finally {
            pingSource_tl().set(internalPingSource);          
            if (verbose) print("ThreadPool finally");
          }
      }
    } catch (Exception __e) { throw rethrow(__e); } }
    
    synchronized boolean isEmpty() { return empty(q); }
    
    // append to q (do later)
    void addWork(Runnable r) {
      if (verbose) print("Added work to " + this + ": " + r);
      synchronized(this) {
        q = chainPlus(q, r);
        notifyAll();
      }
    }  
  }
  
  PooledThread newThread() {
    PooledThread t = new PooledThread("Thread Pool Inhabitant " + n2(total()+1));
    t.start();
    return t;
  }
  
  synchronized void markFree(PooledThread t) {
    used.remove(t);
    free.add(t);
    notifyAll();
  }
  
  synchronized void markUsed(PooledThread t) {
    free.remove(t);
    used.add(t);
  }
  
  synchronized public String toString() {
    return retired()
      ? "Retired ThreadPool"
      : "ThreadPool " + roundBracket(commaCombine(
        n2(used) + " used out of " + n2(total()),
        max <= total() ? null : "could grow to " + n2(max)));
  }
  
  synchronized boolean retired() { return retired; }
  synchronized void retire() {
    if (verbose) print("ThreadPool Retiring");
    retired = true;
    for (var thread : free) syncNotifyAll(thread); // wake it up so it exits
  }
  void checkNotRetired() {   
    if (retired()) throw fail("retired");
  }
 
  // We could do a soft-close here (stop the idle threads, let running threads finish, then end those too, stop accepting new orders)
  // or a hard close (interrupt all threads, stop accepting new orders)
  synchronized public void close() { try {
    retire();
  } catch (Exception __e) { throw rethrow(__e); } }
  
  // run in synchronized block
  void _waitWaitWait() { try {
    do {
      fireCustomerMustWaitAlert();
      wait();
      checkNotRetired();
    } while (empty(free));
  } catch (Exception __e) { throw rethrow(__e); } }
  
  void dO(String text, Runnable r) {
    if (r == null) return;
    new PingSource(this, text).dO(r);
  }
  
  ISleeper_v2 sleeper() { return sleeper; }
}
static class SynchronizedFloatBufferPresentingAsDoubles implements IDoubleBuffer {
  float[] data;
  int size;
  
  SynchronizedFloatBufferPresentingAsDoubles() {}
  SynchronizedFloatBufferPresentingAsDoubles(int size) { if (size != 0) data = new float[size]; }
  SynchronizedFloatBufferPresentingAsDoubles(Iterable<Double> l) { addAll(l); }
  SynchronizedFloatBufferPresentingAsDoubles(Collection<Double> l) { this(l(l)); addAll(l); }
  SynchronizedFloatBufferPresentingAsDoubles(double... data) { this.data = doubleArrayToFloatArray(data); size = l(data); }
  
  public synchronized void add(double i) {
    if (size >= lFloatArray(data)) {
      data = resizeFloatArray(data, Math.max(1, toInt(Math.min(maximumSafeArraySize(), lFloatArray(data)*2L))));
      if (size >= data.length) throw fail(shortClassName(this) + " too large: " + size);
    }
    data[size++] = (float) i;
  }
  
  public synchronized void addAll(Iterable<Double> l) {
    if (l != null) for (double i : l) add(i);
  }
  
  public synchronized double[] toArray() {
    return size == 0 ? null : takeFirstFromFloatArrayAsDoubleArray(data, size);
  }
  
  double[] toArrayNonNull() {
    return unnull(toArray());
  }
  
  synchronized List<Double> toList() {
    return floatArrayToDoubleList(data, 0, size);
  }

  synchronized List<Double> asVirtualList() {
    return new RandomAccessAbstractList<Double>() {
      public int size() { return SynchronizedFloatBufferPresentingAsDoubles.this.size(); }
      public Double get(int i) { return SynchronizedFloatBufferPresentingAsDoubles.this.get(i); }
      public Double set(int i, Double val) {
        synchronized(SynchronizedFloatBufferPresentingAsDoubles.this) {
          Double a = get(i);
          data[i] = val.floatValue();
          return a;
        }
      }
    };
  }
  
  synchronized void reset() { size = 0; }
  void clear() { reset(); }
  
  public synchronized int size() { return size; }
  public synchronized boolean isEmpty() { return size == 0; }
  
  public synchronized double get(int idx) {
    if (idx >= size) throw fail("Index out of range: " + idx + "/" + size);
    return data[idx];
  }
  
  synchronized void set(int idx, double value) {
    if (idx >= size) throw fail("Index out of range: " + idx + "/" + size);
    data[idx] = (float) value;
  }
  
  public synchronized double popLast() {
    if (size == 0) throw fail("empty buffer");
    return data[--size];
  }
  
  public synchronized double first() { return data[0]; }
  public synchronized double last() { return data[size-1]; }
  synchronized double nextToLast() { return data[size-2]; }
  
  public String toString() { return squareBracket(joinWithSpace(toList())); }
  
  public Iterator<Double> iterator() {
    return new IterableIterator<Double>() {
      int i = 0;
      
      public boolean hasNext() { return i < size(); }
      public Double next() {
        synchronized(SynchronizedFloatBufferPresentingAsDoubles.this) {
          //if (!hasNext()) fail("Index out of bounds: " + i);
          return (double) data[i++];
        }
      }
    };
  }
  
  /*public DoubleIterator doubleIterator() {
    ret new DoubleIterator {
      int i = 0;
      
      public bool hasNext() { ret i < size; }
      public int next() {
        //if (!hasNext()) fail("Index out of bounds: " + i);
        ret data[i++];
      }
      toString { ret "Iterator@" + i + " over " + DoubleBuffer.this; }
    };
  }*/
  
  public synchronized void trimToSize() {
    data = resizeFloatArray(data, size);
  }
  
  public synchronized int indexOf(double b) {
    for (int i = 0; i < size; i++)
      if (data[i] == (float) b)
        return i;
    return -1;
  }
  
  synchronized double[] subArray(int start, int end) {
    return subFloatArrayAsDoubleArray(data, start, min(end, size));
  }
  
  public synchronized void insertAt(int idx, double[] l) {
    int n = l(l);
    if (n == 0) return;
    float[] newData = new float[size+n];
    arraycopy(data, 0, newData, 0, idx);
    for (int i = 0; i < n; i++)
      newData[idx+i] = (float) l[i];
    arraycopy(data, idx, newData, idx+n, size-idx);
    data = newData;
    size = newData.length;
  }
}
/*
 * #!
 * Ontopia Engine
 * #-
 * Copyright (C) 2001 - 2013 The Ontopia Project
 * #-
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 * 
 *      http://www.apache.org/licenses/LICENSE-2.0
 * 
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 * !#
 */

// modified by Stefan Reich

// Implements the Set interface more compactly than
// java.util.HashSet by using a closed hashtable.

// Note: equals is always called on the _stored_ object, not the one
// passed as an argument to find(), contains() etc.
// (In case you want to put special magic in your equals() function)

static class UnsynchronizedCompactHashSet<A> extends java.util.AbstractSet<A> {
  protected final static int INITIAL_SIZE = 3;
  public final static double LOAD_FACTOR = 0.75;

  protected final static Object nullObject = new Object();
  protected final static Object deletedObject = new Object();
  protected int elements;
  protected int freecells;
  protected A[] objects;
  
  protected int modCount;
  
  
  UnsynchronizedCompactHashSet() {
    this(INITIAL_SIZE);
  }

  UnsynchronizedCompactHashSet(int size) {
    // NOTE: If array size is 0, we get a
    // "java.lang.ArithmeticException: / by zero" in add(Object).
    objects = (A[]) new Object[(size==0 ? 1 : size)];
    elements = 0;
    freecells = objects.length;
    
      modCount = 0;
    
  }

  UnsynchronizedCompactHashSet(Collection<A> c) {
    this(c.size());
    addAll(c);
  }

  @Override
  public Iterator<A> iterator() {
    return new CompactHashIterator<A>();
  }

  @Override
  public int size() {
    return elements;
  }

  @Override
  public boolean isEmpty() {
    return elements == 0;
  }

  @Override
  public boolean contains(Object o) {
    return find(o) != null;
  }
  
  A find(Object o) {
    if (o == null) o = nullObject;
    
    int hash = o.hashCode();
    int index = (hash & 0x7FFFFFFF) % objects.length;
    int offset = 1;

    // search for the object (continue while !null and !this object)
    while(objects[index] != null &&
          !(objects[index].hashCode() == hash &&
            objects[index].equals(o))) {
      index = ((index + offset) & 0x7FFFFFFF) % objects.length;
      offset = offset*2 + 1;

      if (offset == -1)
        offset = 2;
    }

    return objects[index];
  }
  
  boolean removeIfSame(Object o) {
    A value = find(o);
    if (value == o) {
      remove(value);
      return true;
    }
    return false;
  }

  @Override
  public boolean add(Object o) {
    if (o == null) o = nullObject;

    int hash = o.hashCode();
    int index = (hash & 0x7FFFFFFF) % objects.length;
    int offset = 1;
    int deletedix = -1;
    
    // search for the object (continue while !null and !this object)
    while(objects[index] != null &&
          !(objects[index].hashCode() == hash &&
            objects[index].equals(o))) {

      // if there's a deleted object here we can put this object here,
      // provided it's not in here somewhere else already
      if (objects[index] == deletedObject)
        deletedix = index;
      
      index = ((index + offset) & 0x7FFFFFFF) % objects.length;
      offset = offset*2 + 1;

      if (offset == -1)
        offset = 2;
    }
    
    if (objects[index] == null) { // wasn't present already
      if (deletedix != -1) // reusing a deleted cell
        index = deletedix;
      else
        freecells--;

      
        modCount++;
      
      elements++;

      // here we face a problem regarding generics:
      // add(A o) is not possible because of the null Object. We cant do 'new A()' or '(A) new Object()'
      // so adding an empty object is a problem here
      // If (! o instanceof A) : This will cause a class cast exception
      // If (o instanceof A) : This will work fine

      objects[index] = (A) o;
      
      // do we need to rehash?
      if (1 - (freecells / (double) objects.length) > LOAD_FACTOR)
        rehash();
      return true;
    } else // was there already 
      return false;
  }
  
  @Override
  public boolean remove(Object o) {
    if (o == null) o = nullObject;
    
    int hash = o.hashCode();
    int index = (hash & 0x7FFFFFFF) % objects.length;
    int offset = 1;
    
    // search for the object (continue while !null and !this object)
    while(objects[index] != null &&
          !(objects[index].hashCode() == hash &&
            objects[index].equals(o))) {
      index = ((index + offset) & 0x7FFFFFFF) % objects.length;
      offset = offset*2 + 1;

      if (offset == -1)
        offset = 2;
    }

    // we found the right position, now do the removal
    if (objects[index] != null) {
      // we found the object

      // same problem here as with add
      objects[index] = (A) deletedObject;
      
        modCount++;
      
      elements--;
      return true;
    } else
      // we did not find the object
      return false;
  }
  
  @Override
  public void clear() {
    elements = 0;
    for (int ix = 0; ix < objects.length; ix++)
      objects[ix] = null;
    freecells = objects.length;
    
      modCount++;
    
  }

  @Override
  public Object[] toArray() {
    Object[] result = new Object[elements];
    Object[] objects = this.objects;
    int pos = 0;
    for (int i = 0; i < objects.length; i++)
      if (objects[i] != null && objects[i] != deletedObject) {
        if (objects[i] == nullObject)
          result[pos++] = null;
        else
          result[pos++] = objects[i];
      }
    // unchecked because it should only contain A
    return result;
  }

  // not sure if this needs to have generics
  @Override
  public <T> T[] toArray(T[] a) {
    int size = elements;
    if (a.length < size)
      a = (T[])java.lang.reflect.Array.newInstance(
                                 a.getClass().getComponentType(), size);
    A[] objects = this.objects;
    int pos = 0;
    for (int i = 0; i < objects.length; i++)
      if (objects[i] != null && objects[i] != deletedObject) {
        if (objects[i] == nullObject)
          a[pos++] = null;
        else
          a[pos++] = (T) objects[i];
      }
    return a;
  }
  
  protected void rehash() {
    int garbagecells = objects.length - (elements + freecells);
    if (garbagecells / (double) objects.length > 0.05)
      // rehash with same size
      rehash(objects.length);
    else
      // rehash with increased capacity
      rehash(objects.length*2 + 1);
  }
  
  protected void rehash(int newCapacity) {
    int oldCapacity = objects.length;
    @SuppressWarnings("unchecked")
    A[] newObjects = (A[]) new Object[newCapacity];

    for (int ix = 0; ix < oldCapacity; ix++) {
      Object o = objects[ix];
      if (o == null || o == deletedObject)
        continue;
      
      int hash = o.hashCode();
      int index = (hash & 0x7FFFFFFF) % newCapacity;
      int offset = 1;

      // search for the object
      while(newObjects[index] != null) { // no need to test for duplicates
        index = ((index + offset) & 0x7FFFFFFF) % newCapacity;
        offset = offset*2 + 1;

        if (offset == -1)
          offset = 2;
      }

      newObjects[index] = (A) o;
    }

    objects = newObjects;
    freecells = objects.length - elements;
  }
  
  private class CompactHashIterator<T> implements Iterator<T> {
    private int index;
    private int lastReturned = -1;

    
      private int expectedModCount;
    

    @SuppressWarnings("empty-statement")
    public CompactHashIterator() {
        for (index = 0; index < objects.length &&
                        (objects[index] == null ||
                        objects[index] == deletedObject); index++)
          ;
        
          expectedModCount = modCount;
        
    }

    @Override
    public boolean hasNext() {
        return index < objects.length;
    }

    @SuppressWarnings("empty-statement")
    @Override
    public T next() {
        /*if (modCount != expectedModCount)
          throw new ConcurrentModificationException();*/
        int length = objects.length;
        if (index >= length) {
          lastReturned = -2;
          throw new NoSuchElementException();
        }
  
        lastReturned = index;
        for (index += 1; index < length &&
                         (objects[index] == null ||
                          objects[index] == deletedObject); index++)
          ;
        if (objects[lastReturned] == nullObject)
          return null;
        else
          return (T) objects[lastReturned];
    }

    @Override
    public void remove() {
        
          if (modCount != expectedModCount)
            throw new ConcurrentModificationException();
        
        if (lastReturned == -1 || lastReturned == -2)
          throw new IllegalStateException();
        // delete object
        if (objects[lastReturned] != null && objects[lastReturned] != deletedObject) {
          objects[lastReturned] = (A) deletedObject;
          elements--;
          
            modCount++;
            expectedModCount = modCount; // this is expected; we made the change
          
        }
    }
  }
  
  int capacity() { return objects.length; }
  
  // returns true if there was a shrink
  boolean shrinkToFactor(double factor) {
    if (factor > LOAD_FACTOR)
      throw fail("Shrink factor must be equal to or smaller than load factor: " + factor + " / " + LOAD_FACTOR);
    int newCapacity = max(INITIAL_SIZE, iround(size()/factor));
    if (newCapacity >= capacity()) return false;
    rehash(newCapacity);
    return true;
  }
}
static class Timestamp implements Comparable<Timestamp> , IFieldsToList{
  long date;
  Timestamp(long date) {
  this.date = date;}

public boolean equals(Object o) {
if (!(o instanceof Timestamp)) return false;
    Timestamp __1 =  (Timestamp) o;
    return date == __1.date;
}

  public int hashCode() {
    int h = 2059094262;
    h = boostHashCombine(h, _hashCode(date));
    return h;
  }
  public Object[] _fieldsToList() { return new Object[] {date}; }

  Timestamp() { date = now(); }
  Timestamp(Date date) { if (date != null) this.date = date.getTime(); }
  
  final long toLong(){ return unixDate(); }
long unixDate() { return date; }
  long unixSeconds() { return unixDate()/1000; }
  
  public String toString() { return formatLocalDateWithSeconds(date); }
  
  // Hmm. Should Timestamp(0) be equal to null? Question, questions...
  public int compareTo(Timestamp t) {
    return t == null ? 1 : cmp(date, t.date);
  }
  
  Timestamp plus(Seconds seconds) {
    return plus(seconds == null ? null : seconds.getDouble());
  }
  
  final Timestamp plusSeconds(double seconds){ return plus(seconds); }
Timestamp plus(double seconds) {
    return new Timestamp(date+toMS(seconds));
  }
  
  // returns milliseconds
  long minus(Timestamp ts) {
    return unixDate()-ts.unixDate();
  }
  
  long sysTime() {
    return clockTimeToSystemTime(date);
  }
  
  Duration minusAsDuration(Timestamp ts) {
    return Duration.ofMillis(minus(ts));
  }
}
interface ILongBuffer extends IntSize, Iterable<Long>, ILongQueue {
  void add(long d);
  void addAll(Iterable<Long> l);
  long[] toArray();
  long get(int idx);
  void trimToSize();
  long popLast();
  long last();
  boolean isEmpty();
  List<Long> asVirtualList();
  void insertAt(int idx, long[] l);
}
// a point in a ticker sequence
static class TickerPoint implements IFieldsToList{
  TickerSequence ticker;
  long currentTime;
  TickerPoint() {}
  TickerPoint(TickerSequence ticker, long currentTime) {
  this.currentTime = currentTime;
  this.ticker = ticker;}
  public String toString() { return shortClassName_dropNumberPrefix(this) + "(" + ticker + ", " + currentTime + ")"; }public Object[] _fieldsToList() { return new Object[] {ticker, currentTime}; }

  double currentPrice() { return lookback(0); }
  
  // time = ms to look back
  double lookback(long time) {
    return ticker.priceAtTimestamp(currentTime-time);
  }
  
  // false if looking back would require going outside of the time range
  boolean canLookback(long time) {
    return currentTime-time >= ticker.startTime();
  }
  
  TickerSequence ticker() { return ticker; }
  final long time(){ return currentTime(); }
long currentTime() { return currentTime; }
}
final static class DoubleRange implements Comparable<DoubleRange> {
   final public double getStart(){ return start(); }
public double start() { return start; }
 double start;
   final public double getEnd(){ return end(); }
public double end() { return end; }
 double end;
  
  DoubleRange() {}
  DoubleRange(double start, double end) {
  this.end = end;
  this.start = start;}
  
  public boolean equals(Object o) { return stdEq2(this, o); }
public int hashCode() { return stdHash2(this); }
  
  double length() { return end-start; }
  boolean isEmpty() { return start >= end; }
  double center() { return (start+end)/2; }
  
  static String _fieldOrder = "start end";
  
  public String toString() { return "[" + start + ";" + end + "]"; }
  
  @Override public int compareTo(DoubleRange r) {
    int c = cmp(start, r.start);
    if (c != 0) return c;
    return cmp(end, r.end);
  }
  
  boolean contains(double d) {
    return d >= start && d <= end;
  }
}
static interface IFieldsToList {
  Object[] _fieldsToList();
}
interface IDoubleBuffer extends IntSize, Iterable<Double> {
  void add(double d);
  void addAll(Iterable<Double> l);
  double[] toArray();
  double get(int idx);
  void trimToSize();
  double popLast();
  double first();
  double last();
  boolean isEmpty();
  void insertAt(int idx, double[] l);
  int indexOf(double d);
  default boolean contains(double d) { return indexOf(d) >= 0; }
}
interface ISleeper_v2 {
  default Sleeping doLater(long targetTime, Runnable r) {
    return doLater(sysTimeToTimestamp(targetTime), r);
  }
  
  Sleeping doLater(Timestamp targetTime, Runnable r);
  
  public default Sleeping doAfter(double seconds, Runnable r) {
    return doLater(tsNow().plusSeconds(seconds), r);
  }
}
static class SynchronizedLongBufferStoredAsLinearInts implements ILongBuffer {
  SynchronizedLongBufferStoredAsLinearInts() {}
  int[] data;
  int size;
  
  // affine conversion to long (long = int*factor+base)
  long base, factor;
  
  SynchronizedLongBufferStoredAsLinearInts(long base, long factor) {
  this.factor = factor;
  this.base = base;}
  SynchronizedLongBufferStoredAsLinearInts(long base, long factor, int size) {
  this.factor = factor;
  this.base = base; if (size != 0) data = new int[size]; }
  SynchronizedLongBufferStoredAsLinearInts(long base, long factor, Iterable<Long> l) {
  this.factor = factor;
  this.base = base;
    if (l instanceof Collection) allocate(((Collection) l).size());
    addAll(l);
  }
  
  public synchronized void addRaw(int i) {
    if (size >= lIntArray(data)) {
      data = resizeIntArray(data, Math.max(1, toInt(Math.min(maximumSafeArraySize(), lIntArray(data)*2L))));
      if (size >= data.length) throw fail(shortClassName(this) + " too large: " + size);
    }
    data[size++] = i;
  }
  
  public synchronized void add(long i) {
    addRaw(compress(i));
  }
  
  synchronized void allocate(int n) {
    data = resizeIntArray(data, max(n, size()));
  }
  
  public synchronized void addAll(Iterable<Long> l) {
    if (l != null) for (long i : l) add(i);
  }
  
  public synchronized long[] toArray() {
    if (size == 0) return null;
    long[] out = new long[size];
    for (int i = 0; i < size; i++)
      out[i] = expand(data[i]);
    return out;
  }
  
  /*synchronized L<Long> toList() {
    ret longArrayToList(data, 0, size);
  }*/
  
  public synchronized List<Long> asVirtualList() {
    return listFromFunction(__41 -> get(__41), size);
  }
  
  synchronized void reset() { size = 0; }
  void clear() { reset(); }
  
  synchronized public int size() { return size; }
  public synchronized boolean isEmpty() { return size == 0; }
  
  public synchronized int getRaw(int idx) {
    if (idx >= size) throw fail("Index out of range: " + idx + "/" + size);
    return data[idx];
  }
  
  public synchronized long get(int idx) {
    if (idx >= size) throw fail("Index out of range: " + idx + "/" + size);
    return expand(data[idx]);
  }
  
  synchronized void set(int idx, long value) {
    if (idx >= size) throw fail("Index out of range: " + idx + "/" + size);
    data[idx] = compress(value);
  }
  
  public synchronized long popLast() {
    if (size == 0) throw fail("empty buffer");
    return expand(data[--size]);
  }
  
  public synchronized long last() { return expand(data[size-1]); }
  synchronized long nextToLast() { return expand(data[size-2]); }
  
  public String toString() { return squareBracket(joinWithSpace(asVirtualList())); }
  
  public synchronized Iterator<Long> iterator() {
    return new IterableIterator<Long>() {
      int i = 0;
      
      public boolean hasNext() { return i < size(); }
      public Long next() {
        synchronized(SynchronizedLongBufferStoredAsLinearInts.this) {
          if (!hasNext()) throw fail("Index out of bounds: " + i);
          return expand(data[i++]);
        }
      }
    };
  }
  
  public synchronized void trimToSize() {
    data = resizeIntArray(data, size);
  }
  
  synchronized void remove(int idx) {
    arraycopy(data, idx+1, data, idx, size-1-idx);
    --size;
  }
  
  // don't rely on return value if buffer is empty
  public synchronized long poll() { 
    return size == 0 ? -1 : expand(data[--size]);
  }
  
  long expand(int value) { return base+value*factor; }
  int compress(long value) { return toInt(ldiv_round(value-base, factor)); }
  
  public synchronized void insertAt(int idx, long[] l) {
    int n = l(l);
    if (n == 0) return;
    int[] newData = new int[size+n];
    arraycopy(data, 0, newData, 0, idx);
    for (int i = 0; i < n; i++)
      newData[idx+i] = compress(l[i]);
    arraycopy(data, idx, newData, idx+n, size-idx);
    data = newData;
    size = newData.length;
  }
}
static class UpDownSequence extends RandomAccessAbstractList<UpDown> {
  UpDownSequence() {}
  BitBuffer moves = new BitBuffer(); // up is true
  
  UpDownSequence(String s) {
    for (var c : characters(upper(s)))
      if (c == 'U') add(UpDown.up);
      else if (c == 'D') add(UpDown.down);
  }
  
  public UpDown get(int i) {
    return UpDown.fromBool(moves.get(i));
  }
  
  public boolean add(UpDown move) {
    moves.add(move.bit);
    return true;
  }
  
  public String toString() { return join(countIterator(__42 -> moveChar(__42), size())); }
  
  String moveChar(int i) { return moves.get(i) ? "U" : "D"; }
  
  public int size() { return moves.size(); }
  
  void addUp() { add(UpDown.up); }
  void addDown() { add(UpDown.down); }
  
  final static UpDownSequence fromInts(List<Integer> cellNumbers){ return fromCellNumbers(cellNumbers); }
static UpDownSequence fromCellNumbers(List<Integer> cellNumbers) {
    UpDownSequence seq = new UpDownSequence();
    if (nempty(cellNumbers)) {
      int cn = first(cellNumbers);
      for (int i = 1; i < l(cellNumbers); i++) {
        int cn2 = cellNumbers.get(i);
        int cn3 = clamp(cn2, cn-10, cn+10);
        while (cn3 > cn) {
          ping();
          ++cn;
          seq.addUp();
        }
        while (cn3 < cn) {
          ping();
          --cn;
          seq.addDown();
        }
        cn = cn2;
      }
    }
    return seq;
  }
}

interface IMultiMap<A, B> {
  public Set<A> keySet();
  public Collection<B> get(A a);
  public int size();
  public int keyCount();
}
interface IDoublePt {
  public double x_double();
  public double y_double();
}
static interface IVar<A> extends IF0<A> {
  void set(A a);
  A get();
  
  // reified type of value (if available)
  default Class<A> getType() { return null; }
  
  default IF0<A> getter() { return () -> get(); }
  default IVF1<A> setter() { return __1 -> set(__1); }
  
  
  default boolean has() { return get() != null; }
  default void clear() { set(null); }
  
}
static interface WidthAndHeight {
  default int w(){ return getWidth(); }
default int width(){ return getWidth(); }
int getWidth();
  default int h(){ return getHeight(); }
default int height(){ return getHeight(); }
int getHeight();
  
  public default Rect bounds() { return rect(0, 0, getWidth(), getHeight()); }
  
  default int area() { return toInt(areaAsLong()); }
  default long areaAsLong() { return longMul(w(), h()); }
}


abstract static class Sleeping implements AutoCloseable , IFieldsToList{
  Timestamp targetTime;
  Runnable action;
  Sleeping() {}
  Sleeping(Timestamp targetTime, Runnable action) {
  this.action = action;
  this.targetTime = targetTime;}
  public String toString() { return shortClassName_dropNumberPrefix(this) + "(" + targetTime + ", " + action + ")"; }public Object[] _fieldsToList() { return new Object[] {targetTime, action}; }

  long remainingMS() { return targetTime.minus(tsNow()); }
}
// AppendableChain has one "smart" head element (with size counter
// and pointer to the chain's last element), all the other nodes are
// maximally simple (MinimalChain).
// This allows O(1) front insertion, front removal and back insertion
// (not removal at the back though) which is fine for what I need this
// for (event queues).
//
// Stefan Reich, Oct 21

static class AppendableChain<A> extends MinimalChain<A> implements Iterable<A>, IntSize {
  MinimalChain<A> last; // pointer to last element in chain (which may be us)
   final public int getSize(){ return size(); }
public int size() { return size; }
 int size; // total length of chain

  AppendableChain() {} // only used internally
  AppendableChain(A element) {
  this.element = element; size = 1; last = this; }
  
  // intermediate constructor called by itemPlusChain()
  AppendableChain(A element, AppendableChain<A> next) {
  this.next = next;
  this.element = element;
    if (next == null) return;
    
    MinimalChain<A> b = new MinimalChain();
    b.element = next.element;
    b.next = next.next;
    this.next = b;
    last = next.last;
    size = next.size+1;
  }
  
  public String toString() { return str(toList()); }
  
  // append at the end
  boolean add(A a) {
    MinimalChain newLast = new MinimalChain(a);
    last.next = newLast;
    last = newLast;
    ++size;
    return true;
  }
  
  // drop first element
  AppendableChain<A> popFirst() {
    if (next == null) return null;
    element = next.element;
    if (last == next) last = this;
    next = next.next;
    --size;
    return this;
  }
  
  ArrayList<A> toList() {
    ArrayList<A> l = emptyList(size);
    MinimalChain<A> c = this;
    while (c != null) {
      l.add(c.element);
      c = c.next;
    }
    return l;
  }
  
  //public Iterator<A> iterator() { ret toList().iterator(); }
  
  class ACIt extends IterableIterator  < A > {
    MinimalChain<A> c = AppendableChain.this;
    
    public boolean hasNext() {
      return c != null;
    }
    
    public A next() {
      var a = c.element;
      c = c.next;
      return a;
    }
  }
  
  public IterableIterator<A> iterator() {
    return new ACIt();
  }
}
static class MultiSleeper extends RestartableCountdown implements ISleeper_v2 {
  MultiSetMap<Timestamp, Runnable> entries = treeMultiSetMap();
  
  void check() {
    var time = nextWakeUpTime();
    var action = firstValue(entries);
    setTargetTime(time == null ? 0 : time.sysTime(), new Runnable() {  public void run() { try { 
      Set<Runnable> toCall;
      synchronized(MultiSleeper.this) {
        toCall = entries.get(time);
        entries.remove(time);
        check();
      }
      pcallFAll(toCall);
    
} catch (Exception __e) { throw rethrow(__e); } }  public String toString() { return "Set<Runnable> toCall;\r\n      synchronized(MultiSleeper.this) {\r\n        toCal..."; }});
  }
  
  synchronized void removeEntry(Timestamp targetTime, Runnable action) {
    entries.remove(targetTime, action);
  }
  
  // API
  
  synchronized Timestamp nextWakeUpTime() {
    return firstKey(entries);
  }
  
  public synchronized Sleeping doLater(Timestamp targetTime, Runnable r) {
    if (r == null || targetTime == null) return null;
    targetTime = max(targetTime, tsNow());
    entries.put(targetTime, r);
    check();
    return new Sleeping(targetTime, r) {
      public void close() { try {
        removeEntry(targetTime, r);
      } catch (Exception __e) { throw rethrow(__e); } }
    };
  }
}
static class Seconds implements Comparable<Seconds> , IFieldsToList{
  double seconds;
  Seconds() {}
  Seconds(double seconds) {
  this.seconds = seconds;}

public boolean equals(Object o) {
if (!(o instanceof Seconds)) return false;
    Seconds __1 =  (Seconds) o;
    return seconds == __1.seconds;
}

  public int hashCode() {
    int h = -660217249;
    h = boostHashCombine(h, _hashCode(seconds));
    return h;
  }
  public Object[] _fieldsToList() { return new Object[] {seconds}; }

  final double get(){ return seconds(); }
final double getDouble(){ return seconds(); }
double seconds() { return seconds; }
  
  public String toString() { return formatDouble(seconds, 3) + " s"; }
  
  public int compareTo(Seconds s) {
    return cmp(seconds, s.seconds);
  }
  
  Seconds div(double x) { return new Seconds(get()/x); }
  Seconds minus(Seconds x) { return new Seconds(get()-x.get()); }
}
enum UpDown {
  up(true), down(false);
  
  boolean bit = false;
  
  private UpDown(boolean bit) {
  this.bit = bit;}
  
  static UpDown fromBool(boolean bit) { return bit ? up : down; }
  
  boolean isUp() { return bit; }
  boolean isDown() { return !bit; }
  
  int direction() { return isUp() ? 1 : -1; }
}
abstract static class RandomAccessAbstractList<A> extends AbstractList<A> implements RandomAccess {
}
static interface ILongQueue {
  public boolean isEmpty();
  public void add(long element);
  
  // return value is undefined if queue is empty
  public long poll();
}
static class PriceDigitizer2 implements IFieldsToList{
  PriceCells cells;
  PriceDigitizer2() {}
  PriceDigitizer2(PriceCells cells) {
  this.cells = cells;}
  public String toString() { return shortClassName_dropNumberPrefix(this) + "(" + cells + ")"; }public Object[] _fieldsToList() { return new Object[] {cells}; }

   final public PriceDigitizer2 setCellNumber(int cellNumber){ return cellNumber(cellNumber); }
public PriceDigitizer2 cellNumber(int cellNumber) { this.cellNumber = cellNumber; return this; }  final public int getCellNumber(){ return cellNumber(); }
public int cellNumber() { return cellNumber; }
 int cellNumber = Integer.MIN_VALUE;
   final public PriceDigitizer2 setLastCellNumber(int lastCellNumber){ return lastCellNumber(lastCellNumber); }
public PriceDigitizer2 lastCellNumber(int lastCellNumber) { this.lastCellNumber = lastCellNumber; return this; }  final public int getLastCellNumber(){ return lastCellNumber(); }
public int lastCellNumber() { return lastCellNumber; }
 int lastCellNumber = Integer.MIN_VALUE;
   final public PriceDigitizer2 setVerbose(boolean verbose){ return verbose(verbose); }
public PriceDigitizer2 verbose(boolean verbose) { this.verbose = verbose; return this; }  final public boolean getVerbose(){ return verbose(); }
public boolean verbose() { return verbose; }
 boolean verbose = false;
   final public PriceDigitizer2 setUpDownSequence(UpDownSequence upDownSequence){ return upDownSequence(upDownSequence); }
public PriceDigitizer2 upDownSequence(UpDownSequence upDownSequence) { this.upDownSequence = upDownSequence; return this; }  final public UpDownSequence getUpDownSequence(){ return upDownSequence(); }
public UpDownSequence upDownSequence() { return upDownSequence; }
 UpDownSequence upDownSequence = new UpDownSequence();
  
  // returns new digitized price
  double digitize(double price) {
    double cn = cells.toCellNumber(price);
    if (cellNumber == Integer.MIN_VALUE) {
      cellNumber = lastCellNumber = iround(cn);
    } else {
      lastCellNumber = cellNumber;
      cellNumber = iroundTowardsWithOutwardEpsilon(cn, cellNumber, epsilon());
      
      // TODO: assuming there are only 1-steps
      if (cellNumber > lastCellNumber)
        { if (upDownSequence != null) upDownSequence.addUp(); }
      else if (cellNumber < lastCellNumber)
        { if (upDownSequence != null) upDownSequence.addDown(); }
    }
    return digitizedPrice();
  }
  
  double epsilon() { return 1e-4; }
  
  double digitizedPrice() { return cells.fromCellNumber(cellNumber); }
  double lastDigitizedPrice() { return cells.fromCellNumber(lastCellNumber); }
  
  // digitize price without looking at history
  double digitizeIndividually(double price) {
    double cn = cells.toCellNumber(price);
    return cells.fromCellNumber(round(cn));
  }
  
  PriceCells priceCells() { return cells; }
  
  // brave
  void swapPriceCells(PriceCells newPriceCells) {
    cells = newPriceCells;
  }
}
// little-endian
static class BitBuffer implements IntSize {
  BitBuffer() {}
  ByteBuffer byteBuffer = new ByteBuffer(); // TODO (optimization): use a growing circular buffer
  int currentByte, currentBit;
  
  void add(int b) {
    add(odd(b));
  }
  
  void add(boolean b) {
    if (b) currentByte |= 1 << currentBit;
    if (currentBit == 7) {
      byteBuffer.add((byte) currentByte);
      currentByte = 0;
      currentBit = 0;
    } else
      ++currentBit;
  }
  
  boolean get(int iBit) {
    int iByte = iBit >> 3;
    int theByte = iByte == byteBuffer.size()
      ? currentByte 
      : byteBuffer.get(iByte);
    return (theByte & (1 << (iBit & 7))) != 0;
  }
  
  boolean hasFullByte() {
    return !byteBuffer.isEmpty();
  }
  
  byte popFullByte() {
    return byteBuffer.popFirst();
  }
  
  public int size() {
    return byteBuffer.size()*8 + currentBit;
  }
  
  // TODO: optimize void writeBits(int data, int nBits)
}


// uses hash sets as inner sets unless subclassed
// uses a hash map as the outer map by default
static class MultiSetMap<A, B>implements IMultiMap<A, B> {
  Map<A, Set<B>> data = new HashMap<A, Set<B>>();
  int size; // number of values
  
  MultiSetMap() {}
  MultiSetMap(boolean useTreeMap) { if (useTreeMap) data = new TreeMap(); }
  MultiSetMap(MultiSetMap<A, B> map) { putAll(map); }
  MultiSetMap(Map<A, Set<B>> data) {
  this.data = data;}

  boolean put(A key, B value) { synchronized(data) {
    Set<B> set = data.get(key);
    if (set == null)
      data.put(key, set = _makeEmptySet());
    if (!set.add(value)) return false;
    { ++size; return true; }
  }}

  boolean add(A key, B value) { return put(key, value); }

  void addAll(A key, Collection<B> values) { synchronized(data) {
    putAll(key, values);
  }}
  
  void addAllIfNotThere(A key, Collection<B> values) { synchronized(data) {
    for (B value : values)
      setPut(key, value);
  }}
  
  void setPut(A key, B value) { synchronized(data) {
    if (!containsPair(key, value))
      put(key, value);
  }}
  
  final boolean contains(A key, B value){ return containsPair(key, value); }
boolean containsPair(A key, B value) { synchronized(data) {
    return get(key).contains(value);
  }}
  
  void putAll(A key, Collection<B> values) { synchronized(data) {
    for (B value : values)
      put(key, value);
  }}

  void removeAll(A key, Collection<B> values) { synchronized(data) {
    for (B value : values)
      remove(key, value);
  }}
  
  public Set<B> get(A key) { synchronized(data) {
    Set<B> set = data.get(key);
    return set == null ? Collections.<B> emptySet() : set;
  }}
  
  List<B> getAndClear(A key) { synchronized(data) {
    List<B> l = cloneList(data.get(key));
    remove(key);
    return l;
  }}

  // return null if empty
  Set<B> getOpt(A key) { synchronized(data) {
    return data.get(key);
  }}

  // returns actual mutable live set
  // creates the set if not there
  Set<B> getActual(A key) { synchronized(data) {
    Set<B> set = data.get(key);
    if (set == null)
      data.put(key, set = _makeEmptySet());
    return set;
  }}
 
  // TODO: this looks unnecessary
  void clean(A key) { synchronized(data) {
    Set<B> list = data.get(key);
    if (list != null && list.isEmpty())
      data.remove(key);
  }}

  final public Set<A> keys(){ return keySet(); }
public Set<A> keySet() { synchronized(data) {
    return data.keySet();
  }}

  void remove(A key) { synchronized(data) {
    size -= l(data.get(key));
    data.remove(key);
  }}

  void remove(A key, B value) { synchronized(data) {
    Set<B> set = data.get(key);
    if (set != null) {
      if (set.remove(value)) {
        --size;
        if (set.isEmpty())
          data.remove(key);
      }
    }
  }}

  void clear() { synchronized(data) {
    data.clear();
    size = 0;
  }}

  boolean containsKey(A key) { synchronized(data) {
    return data.containsKey(key);
  }}

  B getFirst(A key) { synchronized(data) {
    return first(get(key));
  }}
  
  void addAll(MultiSetMap<A, B> map) { putAll(map); }
  
  void putAll(MultiSetMap<A, B> map) { synchronized(data) {
    for (A key : map.keySet())
      putAll(key, map.get(key));
  }}
  
  void putAll(Map<A, B> map) { synchronized(data) {
    if (map != null) for (Map.Entry<A, B> e : map.entrySet())
      put(e.getKey(), e.getValue());
  }}
  
  final public int keyCount(){ return keysSize(); }
public int keysSize() { synchronized(data) { return l(data); }}
  
  // full size
  public int size() { synchronized(data) {
    return size;
  }}
  
  // count values for key
  int getSize(A key) { return l(data.get(key)); }
  int count(A key) { return getSize(key); }
  
  // expensive operation
  Set<A> reverseGet(B b) { synchronized(data) {
    Set<A> l = new HashSet();
    for (A key : data.keySet())
      if (data.get(key).contains(b))
        l.add(key);
    return l;
  }}
  
  // expensive operation
  A keyForValue(B b) { synchronized(data) {
    for (A key : data.keySet())
      if (data.get(key).contains(b))
        return key;
    return null;
  }}
  
  Map<A, Set<B>> asMap() { synchronized(data) {
    return cloneMap(data);
  }}
  
  boolean isEmpty() { synchronized(data) { return data.isEmpty(); }}
  
  // override in subclasses
  Set<B> _makeEmptySet() {
    return new HashSet();
  }
  
  Collection<Set<B>> allLists() {
    synchronized(data) {
      return new HashSet(data.values());
    }
  }
  
  List<B> allValues() {
    return concatLists(values(data));
  }
  
  List<Pair<A, B>> allEntries() { synchronized(data) {
    List<Pair<A, B>> l = emptyList(size);
    for (Map.Entry<? extends A, ? extends Set<B>> __0 : _entrySet( data))
      { A a = __0.getKey(); Set<B> set = __0.getValue();  for (B b : set)
        l.add(pair(a, b)); }
    return l;
  }}
  
  Object mutex() { return data; }
  
  public String toString() { return "mm" + str(data); }
  
  Pair<A, B> firstEntry() { synchronized(data) {
    if (empty(data)) return null;
    Map.Entry<A, Set<B>> entry = data.entrySet().iterator().next();
    return pair(entry.getKey(), first(entry.getValue()));
  }}
  
  A firstKey() { synchronized(data) { return main.firstKey(data); }}
  A lastKey() { synchronized(data) { return (A) ((NavigableMap) data).lastKey(); }}
  
  A higherKey(Object a) { synchronized(data) { return (A) ((NavigableMap) data).higherKey(a); }}
}
static class MinimalChain<A> implements Iterable<A> {
  A element;
  MinimalChain<A> next;

  MinimalChain() {}
  MinimalChain(A element) {
  this.element = element;}
  MinimalChain(A element, MinimalChain<A> next) {
  this.next = next;
  this.element = element;}
  
  public String toString() { return str(toList()); }
  
  ArrayList<A> toList() {
    ArrayList<A> l = new ArrayList();
    MinimalChain<A> c = this;
    while (c != null) {
      l.add(c.element);
      c = c.next;
    }
    return l;
  }
  
  void setElement(A a) { element = a; }
  void setNext(MinimalChain<A> next) { this.next = next; }
  
  // TODO: optimize
  public Iterator<A> iterator() { return toList().iterator(); }
  
  A get() { return element; }
}
static class RestartableCountdown implements AutoCloseable {
  java.util.Timer timer;
  long targetTime; // in sys time

  
  long /*firings,*/ totalSleepTime; // stats
  
  
  synchronized void setTargetTime(long targetTime, Runnable action) {
    if (targetTime <= 0)
      stop();
    else if (targetTime != this.targetTime) {
      start(targetTime-sysNow(), action);
      this.targetTime = targetTime;
    }
  }
  
  // stops the countdown and restarts it
  synchronized void start(long delayMS, Object action) {
    stop();
    if (delayMS <= 0)
      { startThread(new Runnable() {  public void run() { try {  callF(action); 
} catch (Exception __e) { throw rethrow(__e); } }  public String toString() { return "callF(action);"; }}); }
    else {
      
        totalSleepTime += delayMS;
      
      timer = doLater_daemon(delayMS, action);
      targetTime = sysNow()+delayMS;
    }
  }
  
  void start(double delaySeconds, Object action) {
    start(toMS(delaySeconds), action);
  }
  
  synchronized void stop() {
    cancelTimer(timer);
    timer = null;
    targetTime = 0;
  }
  
  public void close() { stop(); }
}
static class ByteBuffer implements Iterable<Byte> {
  byte[] data;
  int size;
  
  ByteBuffer() {}
  ByteBuffer(int size) { if (size != 0) data = new byte[size]; }
  ByteBuffer(Iterable<Byte> l) {
    if (l instanceof Collection) allocate(((Collection) l).size());
    addAll(l);
  }
  ByteBuffer(byte[] data) { this.data = data; size = l(data); }
  // TODO *(ByteBuffer buf) { ... }
  
  void add(int idx, int i) {
    add(0);
    arraycopy(data, idx, data, idx+1, size-(idx+1));
    data[idx] = (byte) i;
  }
  
  void add(int i) { add((byte) i); }
  
  void add(byte i) {
    if (size >= lByteArray(data)) {
      allocate(Math.max(1, toInt(Math.min(maximumSafeArraySize(), lByteArray(data)*2L))));
      if (size >= data.length) throw fail("ByteBuffer too large: " + size);
    }
    data[size++] = i;
  }
  
  void allocate(int n) {
    data = resizeByteArray(data, max(n, size()));
  }
  
  void addAll(Iterable<Byte> l) {
    if (l != null) for (byte i : l) add(i);
  }
  
  final byte[] toByteArray(){ return toArray(); }
byte[] toArray() {
    return size == 0 ? null : resizeByteArray(data, size);
  }
  
  List<Byte> toList() {
    return byteArrayToList(data, 0, size);
  }

  List<Byte> asVirtualList() {
    return new RandomAccessAbstractList<Byte>() {
      public int size() { return size; }
      public Byte get(int i) { return ByteBuffer.this.get(i); }
      public Byte set(int i, Byte val) {
        Byte a = get(i);
        data[i] = val;
        return a;
      }
    };
  }
  
  void reset() { size = 0; }
  void clear() { reset(); }
  
  int size() { return size; }
  boolean isEmpty() { return size == 0; }
  
  byte get(int idx) {
    if (idx >= size) throw fail("Index out of range: " + idx + "/" + size);
    return data[idx];
  }
  
  void set(int idx, byte value) {
    if (idx >= size) throw fail("Index out of range: " + idx + "/" + size);
    data[idx] = value;
  }
  
  byte popLast() {
    if (size == 0) throw fail("empty buffer");
    return data[--size];
  }
  
  // unefficient
  byte popFirst() {
    if (size == 0) throw fail("empty buffer");
    byte b = data[0];
    arraycopy(data, 1, 0, --size);
    return b;
  }
  
  byte last() { return data[size-1]; }
  byte nextToLast() { return data[size-2]; }
  
  public String toString() { return squareBracket(joinWithSpace(toList())); }
  
  public Iterator<Byte> iterator() {
    return new IterableIterator<Byte>() {
      int i = 0;
      
      public boolean hasNext() { return i < size; }
      public Byte next() {
        //if (!hasNext()) fail("Index out of bounds: " + i);
        return data[i++];
      }
    };
  }
  
  /*public ByteIterator byteIterator() {
    ret new ByteIterator {
      int i = 0;
      
      public bool hasNext() { ret i < size; }
      public int next() {
        //if (!hasNext()) fail("Index out of bounds: " + i);
        ret data[i++];
      }
      toString { ret "Iterator@" + i + " over " + ByteBuffer.this; }
    };
  }*/
  
  void trimToSize() {
    data = resizeByteArray(data, size);
  }
  
  int indexOf(byte b) {
    for (int i = 0; i < size; i++)
      if (data[i] == b)
        return i;
    return -1;
  }
  
  byte[] subArray(int start, int end) {
    return subByteArray(data, start, min(end, size));
  }
}
/*sinterface ISleeper extends ISleeper_v2, AutoCloseable {
  void doLater(long targetSysTime, Runnable r); // call only once
}*/



volatile static boolean loading_value = true;

static boolean loading() {
  return loading_value;
}



static boolean isEmpty(Collection c) {
  return c == null || c.isEmpty();
}

static boolean isEmpty(File f) {
  return f == null || f.length() == 0;
}

static boolean isEmpty(CharSequence s) {
  return s == null || s.length() == 0;
}

static boolean isEmpty(Object[] a) { return a == null || a.length == 0; }
static boolean isEmpty(byte[] a) { return a == null || a.length == 0; }

static boolean isEmpty(Map map) {
  return map == null || map.isEmpty();
}


static boolean isEmpty(DoubleRange r) { return r == null || r.isEmpty(); }



static boolean isEmpty(AppendableChain c) { return c == null; }


static boolean isEmpty(IntSize l) { return l == null || l.size() == 0; }


static boolean differentByEpsilonRatio(double a, double b, double epsilon) {
  return sign(a) != sign(b) || diffRatio(abs(a), abs(b)) > epsilon;
}


static <A> A assertEquals(Object x, A y) {
  return assertEquals("", x, y);
}

static <A> A assertEquals(String msg, Object x, A y) {
  if (assertVerbose()) return assertEqualsVerbose(msg, x, y);
  if (!(x == null ? y == null : x.equals(y)))
    throw fail((msg != null ? msg + ": " : "") + y + " != " + x);
  return y;
}


  static void assertEquals(Scorer scorer, Object x, Object y) {
    assertEquals(scorer, "", x, y);
  }
  
  static void assertEquals(Scorer scorer, String msg, Object x, Object y) {
    if (scorer == null) { assertEquals(msg, x, y); return; }
    scorer.add(eq(x, y), nullIfEmpty(msg));
  }



static String roundBracket(String s) {
  return "(" + s + ")";
}

static String roundBracket(Object s) {
  return roundBracket(str(s));
}


static double[] cloneSubDoubleArray(double[] b, int start, int end) {
  start = max(start, 0); end = min(end, l(b));
  if (start >= end) return new double[0];
  double[] x = new double[end-start];
  System.arraycopy(b, start, x, 0, end-start);
  return x;
}


static long[] cloneSubLongArray(long[] b, int start, int end) {
  start = max(start, 0); end = min(end, l(b));
  if (start >= end) return new long[0];
  long[] x = new long[end-start];
  System.arraycopy(b, start, x, 0, end-start);
  return x;
}


static long secondsToMS(double seconds) {
  return toMS(seconds);
}


static long daysToMS(double days) {
  return round(days*24*60*60*1000);
}


static double daysToSeconds(double days) {
  return round(days*24*60*60);
}


static double hoursToDays(double hours) {
  return hours/24;
}


static double minutesToDays(double minutes) {
  return minutes/(60*24);
}


static <A extends Comparable<? super A>> int binarySearch_insertionPoint(List<A> l, A a) {
  int i = Collections.binarySearch(l, a);
  return i < 0 ? -i-1 : i;
}


static long lround(double d) {
  return Math.round(d);
}

static long lround(Number n) {
  return lround(toDouble(n));
}


static int clampToLength(int length, int i) {
  return clamp(i, 0, length-1);
}


// TODO: optimize to x-(x%n) in case that's the same thing
// (or x-mod(x,n)?)
static int roundDownTo(int n, int x) {
  return x/n*n;
}

static long roundDownTo(long n, long x) {
  return x/n*n;
}

static double roundDownTo(double n, double x) {
  return floor(x/n)*n;
}


static double doubleMin(Iterable<Double> l) {
  double min = infinity();
  for (double d : unnullForIteration(l))
    min = Math.min(min, d);
  return min;
}

static double doubleMin(double... l) {
  double min = infinity();
  for (double d : unnullForIteration(l))
    min = Math.min(min, d);
  return min;
}


static double doubleMax(Iterable<Double> l) {
  double max = negativeInfinity();
  for (double d : unnullForIteration(l))
    max = Math.max(max, d);
  return max;
}

static double doubleMax(double[] l) {
  double max = negativeInfinity();
  for (double d : unnullForIteration(l))
    max = Math.max(max, d);
  return max;
}

static double doubleMax(double[] l, int from, int to) {
  double max = negativeInfinity();
  for (int i = from; i < to; i++)
    max = Math.max(max, l[i]);
  return max;
}


static DoubleRange doubleRange(double start, double end) {
  return new DoubleRange(start, end);
}


static Matcher regexp(String pat, String s) {
  return regexp(compileRegexp(pat), unnull(s));
}

static Matcher regexp(java.util.regex.Pattern pat, String s) {
  return pat.matcher(unnull(s));
}

static java.util.regex.Pattern regexp(String pat) {
  return compileRegexp(pat);
}


static long toLong(Object o) {
  if (o instanceof Number)
    return ((Number) o).longValue();
  if (o instanceof String)
    return parseLong((String) o);
  return 0;
}

static long toLong(Timestamp ts) {
  return ts == null ? 0 : ts.unixDate();
}


static String regexpFirstGroup(String pat, String s) {
  Matcher m = regexpMatcher(pat, s);
  if (m.find()) return m.group(1); else return null;
}

static String regexpFirstGroup(java.util.regex.Pattern pat, String s) {
  Matcher m = regexpMatcher(pat, s);
  if (m.find()) return m.group(1); else return null;
}

static String regexpFirstGroup(String pat, Iterable<String> strings) {
  var compiled = compileRegexp(pat);
  for (String s : unnullForIteration(strings))
    { String group = regexpFirstGroup(compiled, s); if (group != null) return group; }
  return null;
}


static Map parseJSONMap(String s) {
  return jsonDecodeMap(s);
}


static PriceDigitizer2 geometricPriceDigitizer(double c0, double cellSizeInPercent) {
  return new PriceDigitizer2(new GeometricPriceCells(c0, cellSizeInPercent));
}


static class ListFromFunction<A> extends RandomAccessAbstractList<A> implements IFieldsToList{
  int n;
  IF1<Integer, A> f;
  ListFromFunction() {}
  ListFromFunction(int n, IF1<Integer, A> f) {
  this.f = f;
  this.n = n;}
  public String toString() { return shortClassName_dropNumberPrefix(this) + "(" + n + ", " + f + ")"; }public Object[] _fieldsToList() { return new Object[] {n, f}; }

  public int size() { return n; }
  public A get(int i) { return f.get(i); }
}

static <A> List<A> listFromFunction(int n, IF1<Integer, A> f) {
  return new ListFromFunction<A>(n, f);
}

static <A> List<A> listFromFunction(IF1<Integer, A> f, int n) {
  return new ListFromFunction<A>(n, f);
}


static double doubleRatio(double x, double y) {
  return y == 0 ? 0 : x/y;
}


static double doubleRatio(Seconds x, Seconds y) {
  return doubleRatio(x.get(), y.get());
}



static CloseableIterableIterator<String> linesFromFile(File f) { return linesFromFile(f, null); }
static CloseableIterableIterator<String> linesFromFile(File f, IResourceHolder resourceHolder) { try {
  if (!fileExists(f)) return emptyCloseableIterableIterator();
  
  if (ewic(f.getName(), ".gz"))
    return linesFromReader(utf8bufferedReader(newGZIPInputStream(f)), resourceHolder);
  
  return linesFromReader(utf8bufferedReader(f), resourceHolder);
} catch (Exception __e) { throw rethrow(__e); } }

static CloseableIterableIterator<String> linesFromFile(String path) { return linesFromFile(path, null); }
static CloseableIterableIterator<String> linesFromFile(String path, IResourceHolder resourceHolder) {
  return linesFromFile(newFile(path), resourceHolder);
}


static void _close(AutoCloseable c) {
  if (c != null) try {
    c.close();
  } catch (Throwable e) {
    // Some classes stupidly throw an exception on double-closing
    if (c instanceof javax.imageio.stream.ImageOutputStream)
      return;
    else throw rethrow(e);
  }
}


static Class<?> getClass(String name) {
  return _getClass(name);
}

static Class getClass(Object o) {
  return _getClass(o);
}

static Class getClass(Object realm, String name) {
  return _getClass(realm, name);
}


static boolean classIsExportedTo(Class c, java.lang.Module destModule) {
  if (c == null || destModule == null) return false;
  
  java.lang.Module srcModule = c.getModule();
  String packageName = c.getPackageName();
  return srcModule.isExported(packageName, destModule);
}


static boolean isAbstract(Class c) {
  return (c.getModifiers() & Modifier.ABSTRACT) != 0;
}

static boolean isAbstract(Method m) {
  return (m.getModifiers() & Modifier.ABSTRACT) != 0;
}


static boolean reflection_isForbiddenMethod(Method m) {
  return m.getDeclaringClass() == Object.class
    && eqOneOf(m.getName(), "finalize", "clone", "registerNatives");
}


static Set<Class> allInterfacesImplementedBy(Object o) {
  return allInterfacesImplementedBy(_getClass(o));
}

static Set<Class> allInterfacesImplementedBy(Class c) {
  if (c == null) return null;
  HashSet<Class> set = new HashSet();
  allInterfacesImplementedBy_find(c, set);
  return set;
}

static void allInterfacesImplementedBy_find(Class c, Set<Class> set) {
  if (c.isInterface() && !set.add(c)) return;
  do {
    for (Class intf : c.getInterfaces())
      allInterfacesImplementedBy_find(intf, set);
  } while ((c = c.getSuperclass()) != null);
}


static Method findMethod(Object o, String method, Object... args) {
  return findMethod_cached(o, method, args);
}

static boolean findMethod_checkArgs(Method m, Object[] args, boolean debug) {
  Class<?>[] types = m.getParameterTypes();
  if (types.length != args.length) {
    if (debug)
      System.out.println("Bad parameter length: " + args.length + " vs " + types.length);
    return false;
  }
  for (int i = 0; i < types.length; i++)
    if (!(args[i] == null || isInstanceX(types[i], args[i]))) {
      if (debug)
        System.out.println("Bad parameter " + i + ": " + args[i] + " vs " + types[i]);
      return false;
    }
  return true;
}


static Method findStaticMethod(Class c, String method, Object... args) {
  Class _c = c;
  while (c != null) {
    for (Method m : c.getDeclaredMethods()) {
      if (!m.getName().equals(method))
        continue;

      if ((m.getModifiers() & Modifier.STATIC) == 0 || !findStaticMethod_checkArgs(m, args))
        continue;

      return m;
    }
    c = c.getSuperclass();
  }
  return null;
}

static boolean findStaticMethod_checkArgs(Method m, Object[] args) {
  Class<?>[] types = m.getParameterTypes();
  if (types.length != args.length)
    return false;
  for (int i = 0; i < types.length; i++)
    if (!(args[i] == null || isInstanceX(types[i], args[i])))
      return false;
  return true;
}



static String unquote(String s) {
  if (s == null) return null;
  if (startsWith(s, '[')) {
    int i = 1;
    while (i < s.length() && s.charAt(i) == '=') ++i;
    if (i < s.length() && s.charAt(i) == '[') {
      String m = s.substring(1, i);
      if (s.endsWith("]" + m + "]"))
        return s.substring(i+1, s.length()-i-1);
    }
  }
  return unquoteSingleOrDoubleQuotes(s);
}


static List<String> quoteAll(String[] l) {
  return quoteAll(asList(l));
}

static List<String> quoteAll(Collection<String> l) {
  List<String> x = new ArrayList();
  for (String s : l)
    x.add(quote(s));
  return x;
}


static int _hashCode(Object a) {
  return a == null ? 0 : a.hashCode();
}


static <A> ArrayList<A> toList(A[] a) { return asList(a); }
static ArrayList<Integer> toList(int[] a) { return asList(a); }
static ArrayList<Short> toList(short[] a) { return asList(a); }
static ArrayList<Long> toList(long[] a) { return asList(a); }
static <A> ArrayList<A> toList(Set<A> s) { return asList(s); }
static <A> ArrayList<A> toList(Iterable<A> s) { return asList(s); }


static boolean arraysEqual(Object[] a, Object[] b) {
  if (a.length != b.length) return false;
  for (int i = 0; i < a.length; i++)
    if (neq(a[i], b[i])) return false;
  return true;
}


static float clamp(float x, float a, float b) {
  return x < a ? a : x > b ? b : x;
}

static double clamp(double x, double a, double b) {
  return x < a ? a : x > b ? b : x;
}

static int clamp(int x, int a, int b) {
  return x < a ? a : x > b ? b : x;
}

static long clamp(long x, long a, long b) {
  return x < a ? a : x > b ? b : x;
}


static <A> A _print(String s, A a) {
  return print(s, a);
}

static <A> A _print(A a) {
  return print(a);
}

static void _print() {
  print();
}


static boolean _eq(Object a, Object b) {
  return eq(a, b);
}


static String toString(Object o) {
  return strOrNull(o);
}


static double ratioToPercent(double x, double y) {
  return x*100/y;
}


static <A, B> Map<A, B> putAll(Map<A, B> a, Map<? extends A,? extends B> b) {
  if (a != null && b != null) a.putAll(b);
  return a;
}


static <A, B> MultiMap<A, B> putAll(MultiMap<A, B> a, Map<? extends A,? extends B> b) {
  if (a != null) a.putAll((Map) b);
  return a;
}


static <A, B> Map<A, B> putAll(Map<A, B> a, Object... b) {
  if (a != null)
    litmap_impl(a, b);
  return a;
}



static <A> A getAndClear(IVar<A> v) {
  A a = v.get();
  v.set(null);
  return a;
}


static <A, B> Set<A> keys(Map<A, B> map) {
  return map == null ? new HashSet() : map.keySet();
}

// convenience shortcut for keys_gen
static Set keys(Object map) {
  return keys((Map) map);
}




  static <A, B> Set<A> keys(IMultiMap<A, B> mm) {
    return mm.keySet();
  }





static <A, B> Set<A> keySet(Map<A, B> map) {
  return map == null ? new HashSet() : map.keySet();
}

static Set keySet(Object map) {
  return keys((Map) map);
}




  static <A, B> Set<A> keySet(MultiMap<A, B> mm) {
    return mm.keySet();
  }





static <A, B> int keysSize(MultiMap<A, B> mm) {
  return lKeys(mm);
}


static <A> A reverseGet(List<A> l, int idx) {
  if (l == null || idx < 0) return null;
  int n = l(l);
  return idx < n ? l.get(n-1-idx) : null;
}


static <A, B> Map<A, B> cloneMap(Map<A, B> map) {
  if (map == null) return new HashMap();
  // assume mutex is equal to map
  synchronized(map) {
    return map instanceof TreeMap ? new TreeMap((TreeMap) map) // copies comparator
      : map instanceof LinkedHashMap ? new LinkedHashMap(map)
      : new HashMap(map);
  }
}

static <A, B> List<B> cloneMap(Iterable<A> l, IF1<A, B> f) {
  List x = emptyList(l);
  if (l != null) for (A o : cloneList(l))
    x.add(f.get(o));
  return x;
}


static <A, B> Collection<B> values(Map<A, B> map) {
  return map == null ? emptyList() : map.values();
}

// convenience shortcut for values_gen
static Collection values(Object map) {
  return values((Map) map);
}


static <A, B> Collection<B> values(MultiMap<A, B> mm) {
  return mm == null ? emptyList() : concatLists(values(mm.data));
}





static <A, B, C extends Collection<B>> List<B> allValues(Map<A, C> map) {
  List<B> out = new ArrayList();
  for (var l : values(map))
    addAll(out, l);
  return out;
}


static <A> List<A> concatLists(Iterable<A>... lists) {
  List<A> l = new ArrayList();
  if (lists != null) for (Iterable<A> list : lists)
    addAll(l, list);
  return l;
}

static <A> List<A> concatLists(Collection<? extends Iterable<A>> lists) {
  List<A> l = new ArrayList();
  if (lists != null) for (Iterable<A> list : lists)
    addAll(l, list);
  return l;
}



static <A> A set(A o, String field, Object value) {
  if (o == null) return null;
  if (o instanceof Class) set((Class) o, field, value);
  else try {
    Field f = set_findField(o.getClass(), field);
    makeAccessible(f);
    smartSet(f, o, value);
  } catch (Exception e) {
    throw new RuntimeException(e);
  }
  return o;
}

static void set(Class c, String field, Object value) {
  if (c == null) return;
  try {
    Field f = set_findStaticField(c, field);
    makeAccessible(f);
    smartSet(f, null, value);
  } catch (Exception e) {
    throw new RuntimeException(e);
  }
}
  
static Field set_findStaticField(Class<?> c, String field) {
  Class _c = c;
  do {
    for (Field f : _c.getDeclaredFields())
      if (f.getName().equals(field) && (f.getModifiers() & java.lang.reflect.Modifier.STATIC) != 0)
        return f;
    _c = _c.getSuperclass();
  } while (_c != null);
  throw new RuntimeException("Static field '" + field + "' not found in " + c.getName());
}

static Field set_findField(Class<?> c, String field) {
  Class _c = c;
  do {
    for (Field f : _c.getDeclaredFields())
      if (f.getName().equals(field))
        return f;
    _c = _c.getSuperclass();
  } while (_c != null);
  throw new RuntimeException("Field '" + field + "' not found in " + c.getName());
}

static void set(BitSet bs, int idx) {
  { if (bs != null) bs.set(idx); }
}


static boolean hasNext(Iterator it) {
  return it != null && it.hasNext();
}


static Method hashMap_findKey_method;

static <A, B> A hashMap_findKey(HashMap<A, B> map, Object key) { try {
  if (hashMap_findKey_method == null)
    hashMap_findKey_method = findMethodNamed(HashMap.class, "getNode");
  Map.Entry<A, B> entry = (Map.Entry) hashMap_findKey_method.invoke(map, hashMap_internalHash(key), key);
  // java.util.Map.Entry<A, B> entry = (java.util.Map.Entry) call(hash, 'getNode, hashMap_internalHash(key), wkey);
  return entry == null ? null : entry.getKey();
} catch (Exception __e) { throw rethrow(__e); } }


static String find(String pattern, String text) {
  Matcher matcher = Pattern.compile(pattern).matcher(text);
  if (matcher.find())
    return matcher.group(1);
  return null;
}

static <A> A find(Collection<A> c, Object... data) {
  for (A x : c)
    if (checkFields(x, data))
      return x;
  return null;
}


static String a(String noun) {
  if (eq(noun, "")) return "?";
  return ("aeiou".indexOf(noun.charAt(0)) >= 0 ? "an " : "a ") + noun;
}

static String a(String contents, Object... params) {
  return hfulltag("a", contents, params);
}



static String b(Object contents, Object... params) {
  return fulltag("b", contents, params);
}


static int hashCodeFor(Object a) {
  return a == null ? 0 : a.hashCode();
}


static String joinNemptiesWithColon(String... strings) {
  return joinNempties(": ", strings);
}

static String joinNemptiesWithColon(Collection<String> strings) {
  return joinNempties(": ", strings);
}


static int boostHashCombine(int a, int b) {
  return a ^ (b + 0x9e3779b9 + (a << 6) + (a >>> 2));
  
  // OLD (changed) 2022/3/10: ret a ^ (b + 0x9e3779b9 + (a << 6) + (a >> 2));
}


static WidthAndHeight widthAndHeight(BufferedImage image) {
  return image == null ? null : widthAndHeight(image.getWidth(), image.getHeight());
}

static WidthAndHeight widthAndHeight(int w) { return widthAndHeight(w, w); }
static WidthAndHeight widthAndHeight(int w, int h) {
  return new WidthAndHeightFinal(w, h);
}


static double sqrt(double x) {
  return Math.sqrt(x);
}


static Pt ptMinus(Pt a, Pt b) {
  if (b == null) return a;
  return new Pt(a.x-b.x, a.y-b.y);
}


static byte[] toASCII(String s) {
  return s.getBytes(java.nio.charset.StandardCharsets.US_ASCII);
}

static byte toASCII(char c) {
  return toASCII(str(new char[] {c}))[0];
}


static String fromUtf8(byte[] bytes) { try {
  return bytes == null ? null : new String(bytes, utf8charset());
} catch (Exception __e) { throw rethrow(__e); } }


static byte[] toUtf8(String s) { try {
  return s.getBytes(utf8charset());
} catch (Exception __e) { throw rethrow(__e); } }


static byte toUByte(int i) {
  if (!isUByte(i))
    throw fail("Not a u-byte: " + i);
  return (byte) i;
}


static void close(AutoCloseable c) {
  _close(c);
}


static UnsupportedOperationException unsupportedOperation() {
  throw new UnsupportedOperationException();
}


static ByteArrayOutputStream byteArrayOutputStream() {
  return new ByteArrayOutputStream();
}


static String toHexString(byte[] a) {
  return bytesToHex(a);
}

static String toHexString(List<Byte> a) {
  return bytesToHex(byteListToArray(a));
}


static byte[] toByteArray(ByteArrayOutputStream baos) {
  return baos == null ? null : baos.toByteArray();
}

static byte[] toByteArray(Iterator<? extends Number> it) {
  ByteBuffer buf = new ByteBuffer();
  while (it.hasNext())
    buf.add((byte) it.next().intValue());
  return buf.toByteArray();
}

static byte[] toByteArray(Collection<? extends Number> it) {
  int n = l(it), i = 0;
  byte[] a = new byte[n];
  for (var x : it)
    a[i++] = (byte) x.intValue();
  return a;
}

static byte[] toByteArray(Object o) {
  if (o == null) return null;
  if (o instanceof byte[]) return ((byte[]) o);
  if (o instanceof Iterator)
    return toByteArray((Iterator<Number>) o);
  if (o instanceof Collection)
    return toByteArray((Collection<Number>) ((Collection) o));
  // not sure what else to put here
  throw fail("toByteArray", o);
}


static BufferedOutputStream bufferedFileOutputStream(File f) { try {
  return bufferedOutputStream(newFileOutputStream(f));
} catch (Exception __e) { throw rethrow(__e); } }


static Object load(String varName) {
  readLocally(varName);
  return get(mc(), varName);
}

static Object load(String progID, String varName) {
  readLocally(progID, varName);
  return get(mc(), varName);
}


static int bufferedInputStream_bufferSize = 65536;

static BufferedInputStream bufferedInputStream(int bufSize, File f) { try {
  return bufferedInputStream(bufSize, newFileInputStream(f));
} catch (Exception __e) { throw rethrow(__e); } }

static BufferedInputStream bufferedInputStream(File f) { try {
  return bufferedInputStream(newFileInputStream(f));
} catch (Exception __e) { throw rethrow(__e); } }

static BufferedInputStream bufferedInputStream(InputStream in) {
  return new BufferedInputStream(in, bufferedInputStream_bufferSize);
}

static BufferedInputStream bufferedInputStream(int bufSize, InputStream in) {
  return new BufferedInputStream(in, bufSize);
}


static int lDoubleArray(double[] a) {
  return a == null ? 0 : a.length;
}


static double[] resizeDoubleArray(double[] a, int n) {
  if (n == l(a)) return a;
  double[] b = new double[n];
  arraycopy(a, 0, b, 0, min(l(a), n));
  return b;
}


static int toInt(Object o) {
  if (o == null) return 0;
  if (o instanceof Number)
    return ((Number) o).intValue();
  if (o instanceof String)
    return parseInt((String) o);
  if (o instanceof Boolean)
    return boolToInt((Boolean) o);
  throw fail("woot not int: " + getClassName(o));
}

static int toInt(long l) {
  if (l != (int) l) throw fail("Too large for int: " + l);
  return (int) l;
}


static int maximumSafeArraySize() {
  return Integer.MAX_VALUE-8;
}


static Object[] toArray(Collection c) {
  return toObjectArray(c);
}

static <A> A[] toArray(Class<A> type, Iterable<A> c) {
  return toArray(c, type);
}

static <A> A[] toArray(Class<A> type, Collection<A> c) {
  return toArray(c, type);
}

static <A> A[] toArray(Collection<A> c, Class<A> type) {
  A[] a = arrayOfType(l(c), type);
  if (a.length == 0) return a;
  asList(c).toArray(a);
  return a;
}

static <A> A[] toArray(Iterable<A> c, Class<A> type) {
  var c2 = asList(c);
  A[] a = arrayOfType(l(c2), type);
  if (a.length == 0) return a;
  c2.toArray(a);
  return a;
}

// array must have correct length and will be filled
static <A> A[] toArray(A[] array, Collection c) {
  if (array == null || c == null) return null;
  asList(c).toArray(array);
  return array;
}


static <A> ArrayList<Double> doubleArrayToList(double[] a) {
  if (a == null) return null;
  return doubleArrayToList(a, 0, a.length);
}

// no range checking on from/to in the interest of speed
static <A> ArrayList<Double> doubleArrayToList(double[] a, int from, int to) {
  if (a == null) return null;
  ArrayList < Double > l = new ArrayList<>(to-from);
  for (int i = from; i < to; i++) l.add(a[i]);
  return l;
}


static <A> List<A> asVirtualList(A[] a) {
  return wrapArrayAsList(a);
}


static String squareBracket(String s) {
  return "[" + s + "]";
}


static double[] subDoubleArray(double[] b, int start) { return subDoubleArray(b, start, l(b)); }
static double[] subDoubleArray(double[] b, int start, int end) {
  start = max(start, 0); end = min(end, l(b));
  if (start == 0 && end == l(b)) return b;
  if (start >= end) return new double[0];
  double[] x = new double[end-start];
  System.arraycopy(b, start, x, 0, end-start);
  return x;
}


static int min(int a, int b) {
  return Math.min(a, b);
}

static long min(long a, long b) {
  return Math.min(a, b);
}

static float min(float a, float b) { return Math.min(a, b); }
static float min(float a, float b, float c) { return min(min(a, b), c); }

static double min(double a, double b) {
  return Math.min(a, b);
}

static double min(double[] c) {
  double x = Double.MAX_VALUE;
  for (double d : c) x = Math.min(x, d);
  return x;
}

static float min(float[] c) {
  float x = Float.MAX_VALUE;
  for (float d : c) x = Math.min(x, d);
  return x;
}

static byte min(byte[] c) {
  byte x = 127;
  for (byte d : c) if (d < x) x = d;
  return x;
}

static short min(short[] c) {
  short x = 0x7FFF;
  for (short d : c) if (d < x) x = d;
  return x;
}

static int min(int[] c) {
  int x = Integer.MAX_VALUE;
  for (int d : c) if (d < x) x = d;
  return x;
}

static <A extends Comparable<A>> A min(A a, A b) {
  return cmp(a, b) <= 0 ? a : b;
}


static String formatPrice(double price) {
  //ret formatDouble2(price);
  return formatDouble_significant(price, 6);
}




static String formatLocalDateWithSeconds(long time) {
  return localDateWithSeconds(time);
}



static String formatLocalDateWithSeconds() {
  return localDateWithSeconds();
}


static Object time(Object f) {
  long time = sysNow();
  Object o = callF(f);
  done2_always(str(f), time);
  return o;
}

static <A> A time(F0<A> f) {
  return (A) time((Object) f);
}

static <A> A time(IF0<A> f) {
  return (A) time((Object) f);
}

static <A> A time(String msg, IF0<A> f) {
  long time = sysNow();
  A o = f.get();
  done2_always(msg, time);
  return o;
}

static void time(Runnable f) { time(str(f), f); }
static void time(String msg, Runnable f) {
  time(msg, runnableToIF0(f));
}


static String shortClassName_dropNumberPrefix(Object o) {
  return dropNumberPrefix(shortClassName(o));
}


static int lLongArray(long[] a) {
  return a == null ? 0 : a.length;
}


static long[] resizeLongArray(long[] a, int n) {
  if (n == lLongArray(a)) return a;
  long[] b = new long[n];
  arraycopy(a, 0, b, 0, Math.min(lLongArray(a), n));
  return b;
}


static <A> ArrayList<Long> longArrayToList(long[] a) {
  if (a == null) return null;
  return longArrayToList(a, 0, a.length);
}

// no range checking on from/to in the interest of S P E E E E E EEED
static <A> ArrayList<Long> longArrayToList(long[] a, int from, int to) {
  if (a == null) return null;
  ArrayList < Long > l = new ArrayList<>(to-from);
  for (int i = from; i < to; i++) l.add(a[i]);
  return l;
}


static volatile int numberOfCores_value;

static int numberOfCores() {
  if (numberOfCores_value == 0)
    numberOfCores_value = Runtime.getRuntime().availableProcessors();
  return numberOfCores_value;
}


// runnable = Runnable or String (method name)
static Thread newThread(Object runnable) {
  return new BetterThread(_topLevelErrorHandling(toRunnable(runnable)));
}

static Thread newThread(Object runnable, String name) {
  if (name == null) name = defaultThreadName();
  return new BetterThread(_topLevelErrorHandling(toRunnable(runnable)), name);
}

static Thread newThread(String name, Object runnable) {
  return newThread(runnable, name);
}


static int random(int n) { return random(n, defaultRandomGenerator()); }
static int random(int n, Random r) {
  return random(r, n);
}

static long random(long n) { return random(n, defaultRandomGenerator()); }
static long random(long n, Random r) {
  return random(r, n);
}

static int random(Random r, int n) {
  return n <= 0 ? 0 : getRandomizer(r).nextInt(n);
}

static long random(Random r, long n) {
  return n <= 0 ? 0 : getRandomizer(r).nextLong(n);
}

static double random(double max) {
  return random()*max;
}

static double random() {
  return defaultRandomGenerator().nextInt(100001)/100000.0;
}

static double random(double min, double max) {
  return min+random()*(max-min);
}

// min <= value < max
static int random(int min, int max) {
  return min+random(max-min);
}

// min <= value < max
static long random(long min, long max) {
  return min+random(max-min);
}

static int random(int min, int max, Random r) {
  return random(r, min, max);
}

static int random(Random r, int min, int max) {
  return min+random(r, max-min);
}

static <A> A random(List<A> l) {
  return oneOf(l);
}

static <A> A random(Collection<A> c) {
  if (c instanceof List) return random((List<A>) c);
  int i = random(l(c));
  return collectionGet(c, i);
}


static int random(IntRange r) {
  return random(r.start, r.end);
}



static double random(DoubleRange r) {
  return random(r.start, r.end);
}



static Timestamp random(TimestampRange r) {
  return r == null ? null : new Timestamp(random(r.startTime().unixDate(),
    r.endTime().unixDate()));
}


static <A, B> Pair<A, B> random(Map<A, B> map) {
  return entryToPair(random(entries(map)));
}


static <A> A popFirst(List<A> l) {
  if (empty(l)) return null;
  A a = first(l);
  l.remove(0);
  return a;
}

static <A> A popFirst(Collection<A> l) {
  if (empty(l)) return null;
  A a = first(l);
  l.remove(a);
  return a;
}

static <A, B> Pair<A, B> popFirst(Map<A, B> map) {
  if (map == null) return null;
  var it = map.entrySet().iterator();
  if (!it.hasNext()) return null;
  var p = mapEntryToPair(it.next());
  it.remove();
  return p;
}

static <A> List<A> popFirst(int n, List<A> l) {
  List<A> part = cloneSubList(l, 0, n);
  removeSubList(l, 0, n);
  return part;
}

static <A> AppendableChain<A> popFirst(AppendableChain<A> a) {
  return a == null ? null : a.popFirst();
}


// Yes the nomenclature is a bit illogical

static <A> Chain<A> chainPlus(Chain<A> chain, A a) {
  return new Chain<A>(a, chain);
}

static <A> Chain<A> chainPlus(Chain<A> chain, A... l) {
  for (A a : unnullForIteration(l))
    chain = chainPlus(chain, a);
  return chain;
}

static <A> ReverseChain<A> chainPlus(ReverseChain<A> chain, A a) {
  return new ReverseChain<A>(chain, a);
}

static <A> ReverseChain<A> chainPlus(ReverseChain<A> chain, A... l) {
  for (A a : unnullForIteration(l))
    chain = chainPlus(chain, a);
  return chain;
}


static <A> AppendableChain<A> chainPlus(AppendableChain<A> chain, A a) {
  if (chain == null) return new AppendableChain<A>(a);
  chain.add(a);
  return chain;
}

static <A> AppendableChain<A> chainPlus(AppendableChain<A> chain, A... l) {
  for (A a : unnullForIteration(l))
    chain = chainPlus(chain, a);
  return chain;
}




static void syncNotifyAll(Object o) {
  if (o != null) synchronized(o) { o.notifyAll(); }
}


static float[] doubleArrayToFloatArray(double[] a) {
  int n = lDoubleArray(a);
  float[] b = new float[n];
  for (int i = 0; i < n; i++)
    b[i] = (float) a[i];
  return b;
}


static int lFloatArray(float[] a) {
  return a == null ? 0 : a.length;
}


static float[] resizeFloatArray(float[] a, int n) {
  return resizeArray(a, n);
}


static String shortClassName(Object o) {
  if (o == null) return null;
  Class c = o instanceof Class ? (Class) o : o.getClass();
  String name = c.getName();
  return shortenClassName(name);
}


static double[] takeFirstFromFloatArrayAsDoubleArray(float[] a, int n) {
  double[] b = new double[n];
  for (int i = 0; i < n; i++)
    b[i] = a[i];
  return b;
}


static <A> ArrayList<Double> floatArrayToDoubleList(float[] a) {
  if (a == null) return null;
  return floatArrayToDoubleList(a, 0, a.length);
}

// no range checking on from/to in the interest of speed
static <A> ArrayList<Double> floatArrayToDoubleList(float[] a, int from, int to) {
  if (a == null) return null;
  ArrayList < Double > l = new ArrayList<>(to-from);
  for (int i = from; i < to; i++) l.add((double) a[i]);
  return l;
}


static double[] subFloatArrayAsDoubleArray(float[] b, int start) { return subFloatArrayAsDoubleArray(b, start, l(b)); }
static double[] subFloatArrayAsDoubleArray(float[] b, int start, int end) {
  start = max(start, 0); end = min(end, l(b));
  if (start >= end) return new double[0];
  double[] x = new double[end-start];
  for (int i = start; i < end; i++)
    x[i-start] = b[i];
  return x;
}


static long now_virtualTime;
static long now() {
  return now_virtualTime != 0 ? now_virtualTime : System.currentTimeMillis();
}



static BigInteger plus(BigInteger a, BigInteger b) {
  return a.add(b);
}

static BigInteger plus(BigInteger a, long b) {
  return a.add(bigint(b));
}

static long plus(long a, long b) { return a+b; }
static int plus(int a, int b) { return a+b; }
static float plus(float a, float b) { return a+b; }
static double plus(double a, double b) { return a+b; }


static long clockTimeToSystemTime(long now) {
  return now == 0 ? 0 : now + clockToSysTimeDiff();
}


static <A> List<A> minus(Collection<A> a, Object... b) {
  Set set = asSet(b);
  List l = new ArrayList();
  for (Object s : unnull(a))
    if (!set.contains(s))
      l.add(s);
  return l;
}

static BigInteger minus(BigInteger a, BigInteger b) {
  return a.subtract(b);
}


static Complex minus(Complex c) {
  return c == null ? null : complex(-c.re(), -c.im());
}



  static int minus(int a, int b) {
    return a-b;
  }
  
  static int minus(int a) {
    return -a;
  }


  static double minus(double a, double b) {
    return a-b;
  }
  
  static double minus(double a) {
    return -a;
  }


  static long minus(long a, long b) {
    return a-b;
  }
  
  static long minus(long a) {
    return -a;
  }




static boolean stdEq2(Object a, Object b) {
  if (a == null) return b == null;
  if (b == null) return false;
  if (a.getClass() != b.getClass()) return false;
  for (String field : allFields(a))
    if (neq(getOpt(a, field), getOpt(b, field)))
      return false;
  return true;
}


static int stdHash2(Object a) {
  if (a == null) return 0;
  return stdHash(a, toStringArray(allFields(a)));
}


static java.util.Timer doLater(long delay, final Object r) {
  ping();
  final java.util.Timer timer = new java.util.Timer();
  timer.schedule(timerTask(r, timer), delay);
  return vmBus_timerStarted(timer);
}

static java.util.Timer doLater(double delaySeconds, final Object r) {
  return doLater(toMS(delaySeconds), r);
}


static Timestamp sysTimeToTimestamp(long now) {
  return now == 0 ? null : new Timestamp(now - clockToSysTimeDiff());
}


static Timestamp tsNow() {
  return new Timestamp();
}


static int lIntArray(int[] a) {
  return a == null ? 0 : a.length;
}


static int[] resizeIntArray(int[] a, int n) {
  if (n == lIntArray(a)) return a;
  int[] b = new int[n];
  arraycopy(a, 0, b, 0, Math.min(lIntArray(a), n));
  return b;
}


static long ldiv_round(long a, long b) {
  return (a+b/2)/b;
}

static long ldiv_round(double a, double b) {
  return lround(a/b);
}


static List<Character> characters(final String s) {
  return stringAsCharacterList(s);
}


static String upper(String s) {
  return s == null ? null : s.toUpperCase();
}

static char upper(char c) {
  return Character.toUpperCase(c);
}


static IterableIterator<Integer> countIterator(int b) { return countIterator(0, b); }
static IterableIterator<Integer> countIterator(int a, int b) {
  return countIterator_exclusive(a, b);
}



static <A> IterableIterator<A> countIterator(int b, IF1<Integer, A> f) { return countIterator(0, b, f); }
static <A> IterableIterator<A> countIterator(int a, int b, IF1<Integer, A> f) {
  return countIterator_exclusive(a, b, f);
}

static IterableIterator<Integer> countIterator(int a, int b, int step) {
  return countIterator_exclusive_step(a, b, step);
}

static <A> IterableIterator<A> countIterator(double a, double b, double step, IF1<Double, A> f) {
  return countIterator_exclusive_step(a, b, step, f);
}

static <A> IterableIterator<Double> countIterator(double a, double b, double step) {
  return countIterator_exclusive_step(a, b, step);
}

static <A> IterableIterator<A> countIterator(IF1<Double, A> f, double a, double b, double step) {
  return countIterator(a, b, step, f);
}

static <A> IterableIterator<A> countIterator(IF1<Integer, A> f, int b) { return countIterator(f, 0, b); }
static <A> IterableIterator<A> countIterator(IF1<Integer, A> f, int a, int b) {
  return countIterator_exclusive(a, b, f);
}

static <A> IterableIterator<Integer> countIterator(List l) {
  return countIterator(l(l));
}



static int getWidth(Component c) {
  return c == null ? 0 : (int) swingCall(c, "getWidth");
}


static int getHeight(Component c) {
  return c == null ? 0 : (int) swingCall(c, "getHeight");
}


static Rect rect(int x, int y, int w, int h) {
  return new Rect(x, y, w, h);
}

static Rect rect(Pt p, int w, int h) {
  return new Rect(p.x, p.y, w, h);
}

static Rect rect(int w, int h) {
  return new Rect(0, 0, w, h);
}




static long longMul(long a, long b) {
  return a*b;
}


static <A, B> MultiSetMap<A, B> treeMultiSetMap() {
  return new MultiSetMap(true);
}

static <A, B> MultiSetMap<A, B> treeMultiSetMap(Comparator<A> comparator) {
  return new MultiSetMap(new TreeMap<A, Set<B>>(comparator));
}


static <A, B> B firstValue(Map<A, B> map) {
  return first(values(map));
}


static <A, B> B firstValue(MultiSetMap<A, B> map) {
  return map == null ? null : first(firstValue(map.data));
}



static <A, B> B firstValue(MultiMap<A, B> map) {
  return map == null ? null : first(firstValue(map.data));
}



static <A, B> A firstKey(Map<A, B> map) {
  return first(keys(map));
}


static <A, B> A firstKey(IMultiMap<A, B> map) {
  return map == null ? null : first(map.keySet());
}



static int seconds() {
  return seconds(java.util.Calendar.getInstance());
}

static int seconds(java.util.Calendar c) {
  return c.get(java.util.Calendar.SECOND);
}


static int iroundTowardsWithOutwardEpsilon(double a, double b, double epsilon) {
  return a > b ? ifloor(a+epsilon) : iceil(a-epsilon);
}


static long round(double d) {
  return Math.round(d);
}

static String round(String s) {
  return roundBracket(s);
}


static Complex round(Complex c) {
  return new Complex(round(c.re), round(c.im));
}



static boolean odd(int i) {
  return (i & 1) != 0;
}

static boolean odd(long i) {
  return (i & 1) != 0;
}

static boolean odd(BigInteger i) { return odd(toInt(i)); }


static Set emptySet() {
  return new HashSet();
}


static <A, B> Map.Entry<A, B> firstEntry(Map<A, B> map) {
  return empty(map) ? null : first(map.entrySet());
}


static long sysNow() {
  ping();
  return System.nanoTime()/1000000;
}


static Thread startThread(Object runnable) {
  return startThread(defaultThreadName(), runnable);
}

static Thread startThread(String name, Runnable runnable) {
  runnable = wrapAsActivity(runnable);
  return startThread(newThread(runnable, name));
}

static Thread startThread(String name, Object runnable) {
  runnable = wrapAsActivity(runnable);
  return startThread(newThread(toRunnable(runnable), name));
}

static Thread startThread(Thread t) {
  
  _registerThread(t);
  
  t.start();
  return t;
}


static java.util.Timer doLater_daemon(long delay, final Object r) {
  final java.util.Timer timer = new java.util.Timer(true);
  timer.schedule(timerTask(r, timer), delay);
  return timer;
}

static java.util.Timer doLater_daemon(double delaySeconds, final Object r) {
  return doLater_daemon(toMS(delaySeconds), r);
}



static void cancelTimer(javax.swing.Timer timer) {
  if (timer != null) timer.stop();
}


static void cancelTimer(java.util.Timer timer) {
  if (timer != null) timer.cancel();
}

static void cancelTimer(Object o) {
  if (o instanceof java.util.Timer) cancelTimer((java.util.Timer) o);
  
  else if (o instanceof javax.swing.Timer) cancelTimer((javax.swing.Timer) o);
  
  else if (o instanceof AutoCloseable) { try { ((AutoCloseable) o).close(); } catch (Throwable __e) { pcallFail(__e); }}
}


static int lByteArray(byte[] a) {
  return a == null ? 0 : a.length;
}


static byte[] resizeByteArray(byte[] a, int n) {
  if (n == l(a)) return a;
  byte[] b = new byte[n];
  arraycopy(a, 0, b, 0, min(l(a), n));
  return b;
}


static <A> ArrayList<Byte> byteArrayToList(byte[] a) {
  if (a == null) return null;
  return byteArrayToList(a, 0, a.length);
}

// no range checking on from/to in the interest of speed
static <A> ArrayList<Byte> byteArrayToList(byte[] a, int from, int to) {
  if (a == null) return null;
  ArrayList < Byte > l = new ArrayList<>(to-from);
  for (int i = from; i < to; i++) l.add(a[i]);
  return l;
}


static <A> A popLast(List<A> l) {
  return liftLast(l);
}

static <A> List<A> popLast(int n, List<A> l) {
  return liftLast(n, l);
}


static double popLast(DoubleBuffer l) {
  return l.popLast();
}



static <A> A nextToLast(List<A> l) {
  return get(l, l(l)-2);
}


static byte[] subByteArray(byte[] b, int start) {
  return subByteArray(b, start, l(b));
}
  
static byte[] subByteArray(byte[] b, int start, int end) {
  start = max(start, 0); end = min(end, l(b));
  if (start == 0 && end == l(b)) return b;
  if (start >= end) return new byte[0];
  byte[] x = new byte[end-start];
  System.arraycopy(b, start, x, 0, end-start);
  return x;
}


static byte[] subByteArray(byte[] b, IntRange r) {
  return r == null ? null : subByteArray(b, r.start, r.end);
}





static int sign(double x) {
  return x == 0.0 ? 0 : x < 0 ? -1 : 1;
}

static int sign(long x) {
  return x == 0 ? 0 : x < 0 ? -1 : 1;
}

static int sign(int x) {
  return x == 0 ? 0 : x < 0 ? -1 : 1;
}


static double diffRatio(double a, double b) {
  return 1-doubleRatio(min(a, b), max(a, b));
}



  static int abs(int i) { return Math.abs(i); }


  static long abs(long i) { return Math.abs(i); }


  static float abs(float i) { return Math.abs(i); }


  static double abs(double i) { return Math.abs(i); }




static double abs(Complex c) { return c.abs(); }



static ThreadLocal<Boolean> assertVerbose_value = new ThreadLocal();

static void assertVerbose(boolean b) {
  assertVerbose_value.set(b);
}

static boolean assertVerbose() { return isTrue(assertVerbose_value.get()); }


static <A> A assertEqualsVerbose(Object x, A y) {
  assertEqualsVerbose((String) null, x, y);
  return y;
}

// x = expected, y = actual
static <A> A assertEqualsVerbose(String msg, Object x, A y) {
  if (!eq(x, y)) {
    

    throw fail((nempty(msg) ? msg + ": " : "") + "expected: "+ x + ", got: " + y);
  } else
    print("OK" + (empty(msg) ? "" : " " + msg) + ": " + /*sfu*/(x));
  return y;
}


static void assertEqualsVerbose(Scorer scorer, Object x, Object y) { assertEqualsVerbose(scorer, "", x, y); }
static void assertEqualsVerbose(Scorer scorer, String msg, Object x, Object y) {
  if (scorer == null) { assertEqualsVerbose(x, y); return; }
  if (!eq(x, y)) {
    print(appendColonIfNempty(msg) + y + " != " + x);
    scorer.add(false);
  } else {
    print("OK: " + appendColonIfNempty(msg) + x);
    scorer.add(true);
  }
}



static String nullIfEmpty(String s) {
  return isEmpty(s) ? null : s;
}

static <A, B> Map<A, B> nullIfEmpty(Map<A, B> map) {
  return isEmpty(map) ? null : map;
}

static <A> List<A> nullIfEmpty(List<A> l) {
  return isEmpty(l) ? null : l;
}


static double floor(double d) {
  return Math.floor(d);
}


static double infinity() {
  return positiveInfinity();
}


static double negativeInfinity() {
  return Double.NEGATIVE_INFINITY;
}


static Map<String, java.util.regex.Pattern> compileRegexp_cache = syncMRUCache(10);

static java.util.regex.Pattern compileRegexp(String pat) {
  java.util.regex.Pattern p = compileRegexp_cache.get(pat);
  if (p == null) {
    
    compileRegexp_cache.put(pat, p = java.util.regex.Pattern.compile(pat));
  }
  return p;
}


static long parseLong(String s) {
  if (empty(s)) return 0;
  return Long.parseLong(dropSuffix("L", s));
}

static long parseLong(Object s) {
  return Long.parseLong((String) s);
}


static Matcher regexpMatcher(String pat, String s) {
  return compileRegexp(pat).matcher(unnull(s));
}

static Matcher regexpMatcher(java.util.regex.Pattern pat, String s) {
  return pat.matcher(unnull(s));
}


static Map jsonDecodeMap(String s) {
  Object o = jsonDecode(s);
  if (o instanceof List && empty((List) o))
    return new HashMap();
  if (o instanceof Map)
    return (Map) o;
  else
    throw fail("Not a JSON map: " + s);
}


static boolean fileExists(String path) {
  return path != null && new File(path).exists();
}

static boolean fileExists(File f) {
  return f != null && f.exists();
}


static CloseableIterableIterator emptyCloseableIterableIterator_instance = new CloseableIterableIterator() {
  public Object next() { throw fail(); }
  public boolean hasNext() { return false; }
};

static <A> CloseableIterableIterator<A> emptyCloseableIterableIterator() {
  return emptyCloseableIterableIterator_instance; 
}


static CloseableIterableIterator<String> linesFromReader(Reader r) { return linesFromReader(r, null); }
static CloseableIterableIterator<String> linesFromReader(Reader r, IResourceHolder resourceHolder) {
  final BufferedReader br = bufferedReader(r);
  return holdResource(resourceHolder, iteratorFromFunction_f0_autoCloseable(new F0<String>() { public String get() { try {  return readLineFromReaderWithClose(br);  } catch (Exception __e) { throw rethrow(__e); } }
  public String toString() { return "return readLineFromReaderWithClose(br);"; }}, _wrapIOCloseable(r)));
}


static BufferedReader utf8bufferedReader(InputStream in) { try {
  return in == null ? null : bufferedReader(_registerIOWrap(new InputStreamReader(in, "UTF-8"), in));
} catch (Exception __e) { throw rethrow(__e); } }

static BufferedReader utf8bufferedReader(File f) { try {
  return utf8bufferedReader(newFileInputStream(f));
} catch (Exception __e) { throw rethrow(__e); } }


static GZIPInputStream newGZIPInputStream(File f) {
  return gzInputStream(f);
}

static GZIPInputStream newGZIPInputStream(InputStream in) {
  return gzInputStream(in);
}


static File newFile(File base, String... names) {
  for (String name : names) base = new File(base, name);
  return base;
}

static File newFile(String name) {
  return name == null ? null : new File(name);
}

static File newFile(String base, String... names) {
  return newFile(newFile(base), names);
}


static boolean eqOneOf(Object o, Object... l) {
  if (l != null) for (Object x : l) if (eq(o, x)) return true; return false;
}


static Method findMethod_cached(Object o, String method, Object... args) { try {
  if (o == null) return null;
  if (o instanceof Class) {
    _MethodCache cache = callOpt_getCache((Class) o);
    List<Method> methods = cache.cache.get(method);
    if (methods != null) for (Method m : methods)
      if (isStaticMethod(m) && findMethod_checkArgs(m, args, false))
        return m;
    return null;
  } else {
    _MethodCache cache = callOpt_getCache(o.getClass());
    List<Method> methods = cache.cache.get(method);
    if (methods != null) for (Method m : methods)
      if (findMethod_checkArgs(m, args, false))
        return m;
    return null;
  }
} catch (Exception __e) { throw rethrow(__e); } }



static String unquoteSingleOrDoubleQuotes(String s) {
  if (s == null) return null;
  if (s.length() > 1) {
    char c = s.charAt(0);
    if (c == '\"' || c == '\'') {
      int l = endsWith(s, c) ? s.length()-1 : s.length();
      StringBuilder sb = new StringBuilder(l-1);
  
      for (int i = 1; i < l; i++) {
        char ch = s.charAt(i);
        if (ch == '\\') {
          char nextChar = (i == l - 1) ? '\\' : s.charAt(i + 1);
          // Octal escape?
          if (nextChar >= '0' && nextChar <= '7') {
              String code = "" + nextChar;
              i++;
              if ((i < l - 1) && s.charAt(i + 1) >= '0'
                      && s.charAt(i + 1) <= '7') {
                  code += s.charAt(i + 1);
                  i++;
                  if ((i < l - 1) && s.charAt(i + 1) >= '0'
                          && s.charAt(i + 1) <= '7') {
                      code += s.charAt(i + 1);
                      i++;
                  }
              }
              sb.append((char) Integer.parseInt(code, 8));
              continue;
          }
          switch (nextChar) {
          case '\"': ch = '\"'; break;
          case '\\': ch = '\\'; break;
          case 'b': ch = '\b'; break;
          case 'f': ch = '\f'; break;
          case 'n': ch = '\n'; break;
          case 'r': ch = '\r'; break;
          case 't': ch = '\t'; break;
          case '\'': ch = '\''; break;
          // Hex Unicode: u????
          case 'u':
              if (i >= l - 5) {
                  ch = 'u';
                  break;
              }
              int code = Integer.parseInt(
                      "" + s.charAt(i + 2) + s.charAt(i + 3)
                         + s.charAt(i + 4) + s.charAt(i + 5), 16);
              sb.append(Character.toChars(code));
              i += 5;
              continue;
          default:
            ch = nextChar; // added by Stefan
          }
          i++;
        }
        sb.append(ch);
      }
      return sb.toString();
    }
  }
    
  return s; // not quoted - return original
}


static String quote(Object o) {
  if (o == null) return "null";
  return quote(str(o));
}

static String quote(String s) {
  if (s == null) return "null";
  StringBuilder out = new StringBuilder((int) (l(s)*1.5+2));
  quote_impl(s, out);
  return out.toString();
}
  
static void quote_impl(String s, StringBuilder out) {
  out.append('"');
  int l = s.length();
  for (int i = 0; i < l; i++) {
    char c = s.charAt(i);
    if (c == '\\' || c == '"')
      out.append('\\').append(c);
    else if (c == '\r')
      out.append("\\r");
    else if (c == '\n')
      out.append("\\n");
    else if (c == '\t')
      out.append("\\t");
    else if (c == '\0')
      out.append("\\0");
    else
      out.append(c);
  }
  out.append('"');
}


static HashMap litmap(Object... x) {
  HashMap map = new HashMap();
  litmap_impl(map, x);
  return map;
}

static void litmap_impl(Map map, Object... x) {
  if (x != null) for (int i = 0; i < x.length-1; i += 2)
    if (x[i+1] != null)
      map.put(x[i], x[i+1]);
}


static <A, B> int lKeys(MultiMap<A, B> mm) {
  return mm == null ? 0 : mm.keysSize();
}


static void smartSet(Field f, Object o, Object value) throws Exception {
  try {
    f.set(o, value);
  } catch (Exception e) {
    Class type = f.getType();
    
    // take care of common case (long to int)
    if (type == int.class && value instanceof Long)
      { f.set(o, ((Long) value).intValue()); return; }
      
    if (type == boolean.class && value instanceof String)
      { f.set(o, isTrueOrYes(((String) value))); return; }
    
    if (type == LinkedHashMap.class && value instanceof Map)
      { f.set(o, asLinkedHashMap((Map) value)); return; }
    
    
    throw e;
  }
}


// This is a bit rough... finds static and non-static methods.

static Method findMethodNamed(Object obj, String method) {
  if (obj == null) return null;
  if (obj instanceof Class)
    return findMethodNamed((Class) obj, method);
  return findMethodNamed(obj.getClass(), method);
}

static Method findMethodNamed(Class c, String method) {
  while (c != null) {
    for (Method m : c.getDeclaredMethods())
      if (m.getName().equals(method)) {
        makeAccessible(m);
        return m;
      }
    c = c.getSuperclass();
  }
  return null;
}


static int hashMap_internalHash(Object key) {
  int h;
  return (key == null) ? 0 : (h = key.hashCode()) ^ (h >>> 16);
}


static boolean checkFields(Object x, Object... data) {
  for (int i = 0; i < l(data); i += 2)
    if (neq(getOpt(x, (String) data[i]), data[i+1]))
      return false;
  return true;
}


static String hfulltag(String tag) {
  return hfulltag(tag, "");
}

static String hfulltag(String tag, Object contents, Object... params) {
  return hopeningTag(tag, params) + str(contents) + "</" + tag + ">";
}


static String fulltag(String tag) {
  return hfulltag(tag);
}



static String fulltag(String tag, Object contents, Object... params) {
  return hfulltag(tag, contents, params);
}




static Charset utf8charset_cache;
static Charset utf8charset() { if (utf8charset_cache == null) utf8charset_cache = utf8charset_load(); return utf8charset_cache;}

static Charset utf8charset_load() {
  return Charset.forName("UTF-8");
}


static boolean isUByte(int i) {
  return (i & 0xFF) == i;
}


  public static String bytesToHex(byte[] bytes) {
    return bytesToHex(bytes, 0, bytes.length);
  }

  public static String bytesToHex(byte[] bytes, int ofs, int len) {
    StringBuilder stringBuilder = new StringBuilder(len*2);
    for (int i = 0; i < len; i++) {
      String s = "0" + Integer.toHexString(bytes[ofs+i]);
      stringBuilder.append(s.substring(s.length()-2, s.length()));
    }
    return stringBuilder.toString();
  }



static byte[] byteListToArray(List<Byte> l) {
  if (l == null) return null;
  int n = l(l), i = 0;
  byte[] a = new byte[n];
  for (var x : l)
    a[i++] = x;
  return a;
}


static BufferedOutputStream bufferedOutputStream(OutputStream out) {
  if (out == null) return null;
  if (out instanceof BufferedOutputStream) return ((BufferedOutputStream) out);
  return new BufferedOutputStream(out, defaultBufferedOutputStreamSize());
}

static BufferedOutputStream bufferedOutputStream(File f) {
  return bufferedOutputStream(fileOutputStream(f));
}


static FileOutputStream newFileOutputStream(File path) throws IOException {
  return newFileOutputStream(path.getPath());
}

static FileOutputStream newFileOutputStream(String path) throws IOException {
  return newFileOutputStream(path, false);
}

static FileOutputStream newFileOutputStream(File path, boolean append) throws IOException {
  return newFileOutputStream(path.getPath(), append);
}

static FileOutputStream newFileOutputStream(String path, boolean append) throws IOException {
  mkdirsForFile(path);
  FileOutputStream f = new FileOutputStream(path, append);
  
  _registerIO(f, path, true);
  
  return f;
}


static void readLocally(String progID, String varNames) {
  readLocally2(mc(), progID, varNames);
}

static void readLocally(String varNames) {
  readLocally2(mc(), programID(), varNames);
}

static void readLocally2(Object obj, String varNames) {
  readLocally2(obj, programID(), varNames);
}

static int readLocally_stringLength;

static ThreadLocal<Boolean> readLocally2_allDynamic = new ThreadLocal();
static ThreadLocal readLocally2_classFinder = new ThreadLocal();

// read a string variable from standard storage
// does not overwrite variable contents if there is no file
static void readLocally2(Object obj, String progID, String varNames) { try {
  boolean allDynamic = isTrue(getAndClearThreadLocal(readLocally2_allDynamic));
  for (String variableName : javaTokC(varNames)) {
    File textFile = new File(programDir(progID), variableName + ".text");
    
    String value = loadTextFile(textFile);
    if (value != null)
      set(main.class, variableName, value);
    else {
      File structureFile = new File(programDir(progID), variableName + ".structure");
      value = loadTextFile(structureFile);
      
      if (value == null) {
        File structureGZFile = new File(programDir(progID), variableName + ".structure.gz");
        if (!structureGZFile.isFile()) return;
        //value = loadGZTextFile(structureGZFile);
         InputStream fis = new FileInputStream(structureGZFile); try {
        GZIPInputStream gis = newGZIPInputStream(fis);
        InputStreamReader reader = new InputStreamReader(gis, "UTF-8");
        BufferedReader bufferedReader = new BufferedReader(reader);
        //O o = unstructure_reader(bufferedReader);
        Object o = unstructure_tok(javaTokC_noMLS_onReader(bufferedReader), allDynamic, readLocally2_classFinder.get());
        readLocally_set(obj, variableName, o);
        return;
      } finally { _close(fis); }}
      
      readLocally_stringLength = l(value);
      if (nempty(value))
        readLocally_set(obj, variableName, unstructure(value, allDynamic, readLocally2_classFinder.get()));
    }
  }
} catch (Exception __e) { throw rethrow(__e); } }

static void readLocally_set(Object c, String varName, Object value) {
  Object oldValue = get(c, varName);
  if (oldValue instanceof List && !(oldValue instanceof ArrayList) && value != null) {
    // Assume it's a synchroList.
    value = synchroList((List) value);
  }
  set(c, varName, value);
}



static FileInputStream newFileInputStream(File path) throws IOException {
  return newFileInputStream(path.getPath());
}

static FileInputStream newFileInputStream(String path) throws IOException {
  FileInputStream f = new FileInputStream(path);
  _registerIO(f, path, true);
  return f;
}


static int parseInt(String s) {
  return emptyString(s) ? 0 : Integer.parseInt(s);
}

static int parseInt(char c) {
  return Integer.parseInt(str(c));
}


static int boolToInt(boolean b) {
  return b ? 1 : 0;
}


static <A> A[] arrayOfType(Class<A> type, int n) {
  return makeArray(type, n);
}

static <A> A[] arrayOfType(int n, Class<A> type) {
  return arrayOfType(type, n);
}


static String formatDouble_significant(double d, int digits) {
  return formatDouble_significant2(d, digits);
}




static String localDateWithSeconds(long time) {
  SimpleDateFormat format = simpleDateFormat_local("yyyy/MM/dd HH:mm:ss");
  return format.format(time);
}

static String localDateWithSeconds() {
  return localDateWithSeconds(now());
}


static long done2_always(long startTime, String desc) {
  long time = sysNow()-startTime;
  
  // BREAKING CHANGE: Now stores result for lastTiming()
  saveTiming_noPrint(time);
  
  print(desc + " [" + time + " ms]");
  return time;
}

static long done2_always(String desc, long startTime) {
  return done2_always(startTime, desc);
}

static long done2_always(long startTime) {
  return done2_always(startTime, "");
}


static IF0 runnableToIF0(Runnable r) {
  return r == null ? null : () -> { r.run(); return null; };
}


static String dropNumberPrefix(String s) {
  return dropFirst(s, indexOfNonDigit(s));
}


static Runnable _topLevelErrorHandling(Runnable r) {


  if (r == null) return null;
  
  // maybe we don't want this anymore. just dm_current_generic()
  Object info = _threadInfo();
  Object mod = dm_current_generic();
  Runnable r2 = r;
  
  if (info != null || mod == null)
    r2 = new Runnable() {  public void run() { try { 
       AutoCloseable __1 =  (AutoCloseable) (rcall("enter", mod)); try {
      _threadInheritInfo(info);
      r.run();
    
} finally { _close(__1); }} catch (Exception __e) { throw rethrow(__e); } }  public String toString() { return "temp (AutoCloseable) rcall enter(mod);\r\n      _threadInheritInfo(info);\r\n    ..."; }};
  r2 = rPcall(r2);
  return r2;

}


static String defaultThreadName_name;

static String defaultThreadName() {
  if (defaultThreadName_name == null)
    defaultThreadName_name = "A thread by " + programID();
  return defaultThreadName_name;
}


static Random defaultRandomGenerator() {
  { Random r = customRandomizerForThisThread(); if (r != null) return r; }
  return ThreadLocalRandom.current();
}


static Random getRandomizer(Random r) {
  return r != null ? r : defaultRandomGenerator();
}


static <A> A oneOf(List<A> l) {
  if (empty(l)) return null;
  int n = l.size();
  return n == 1 ? first(l) : l.get(defaultRandomizer().nextInt(n));
}

static char oneOf(String s) {
  return empty(s) ? '?' : s.charAt(random(l(s)));
}

static <A> A oneOf(A... l) {
  return oneOf(asList(l));
}


static <A> A collectionGet(Collection<A> c, int idx) {
  if (c == null || idx < 0 || idx >= l(c)) return null;
  if (c instanceof List) return listGet((List<A>) c, idx);
  Iterator<A> it = c.iterator();
  for (int i = 0; i < idx; i++) if (it.hasNext()) it.next(); else return null;
  return it.hasNext() ? it.next() : null;
}


static <A, B> Pair<A, B> entryToPair(Map.Entry<A, B> e) {
  return mapEntryToPair(e);
}


static <A, B> Set<Map.Entry<A,B>> entries(Map<A, B> map) {
  return _entrySet(map);
}


static <A> List<A> cloneSubList(List<A> l, int startIndex, int endIndex) {
  return newSubList(l, startIndex, endIndex);
}

static <A> List<A> cloneSubList(List<A> l, int startIndex) {
  return newSubList(l, startIndex);
}


static void removeSubList(List l, int from, int to) {
  if (l != null) subList(l, from, to).clear();
}

static void removeSubList(List l, int from) {
  if (l != null) subList(l, from).clear();
}



  static Object[] resizeArray(Object[] a, int n) {
    if (n == l(a)) return a;
    Object[] b = new Object[n];
    arraycopy(a, 0, b, 0, min(l(a), n));
    return b;
  }


  static double[] resizeArray(double[] a, int n) {
    if (n == l(a)) return a;
    double[] b = new double[n];
    arraycopy(a, 0, b, 0, min(l(a), n));
    return b;
  }


  static float[] resizeArray(float[] a, int n) {
    if (n == l(a)) return a;
    float[] b = new float[n];
    arraycopy(a, 0, b, 0, min(l(a), n));
    return b;
  }


  static long[] resizeArray(long[] a, int n) {
    if (n == l(a)) return a;
    long[] b = new long[n];
    arraycopy(a, 0, b, 0, min(l(a), n));
    return b;
  }




static String shortenClassName(String name) {
  if (name == null) return null;
  int i = lastIndexOf(name, "$");
  if (i < 0) i = lastIndexOf(name, ".");
  return i < 0 ? name : substring(name, i+1);
}


static BigInteger bigint(String s) {
  return new BigInteger(s);
}

static BigInteger bigint(long l) {
  return BigInteger.valueOf(l);
}


static long clockToSysTimeDiff() {
  return sysNow()-now();
}


static Set asSet(Object[] array) {
  HashSet set = new HashSet();
  for (Object o : array)
    if (o != null)
      set.add(o);
  return set;
}

static Set<String> asSet(String[] array) {
  TreeSet<String> set = new TreeSet();
  for (String o : array)
    if (o != null)
      set.add(o);
  return set;
}

static <A> Set<A> asSet(Iterable<A> l) {
  if (l instanceof Set) return (Set) l;
  HashSet<A> set = new HashSet();
  for (A o : unnull(l))
    if (o != null)
      set.add(o);
  return set;
}




static Complex complex(double re, double im) {
  return new Complex(re, im);
}

static Complex complex(double re) {
  return new Complex(re, 0.0);
}

static Complex complex(double[] reIm) {
  if (empty(reIm)) return null;
  if (l(reIm) != 2) throw fail("Need 2 doubles to make complex number");
  return complex(reIm[0], reIm[1]);
}


static Map<Class, Set<String>> allFields_cache = weakHashMap();

static Set<String> allFields(Object o) {
  if (o == null) return emptySet();
  Class _c = _getClass(o);
  Set<String> fields = allFields_cache.get(_c);
  if (fields == null)
    allFields_cache.put(_c, fields = asTreeSet(keys(getOpt_getFieldMap(o))));
  return fields;
}


static int stdHash(Object a, String... fields) {
  if (a == null) return 0;
  int hash = getClassName(a).hashCode();
  for (String field : fields)
    hash = boostHashCombine(hash, hashCode(getOpt(a, field)));
  return hash;
}


static String[] toStringArray(Collection<String> c) {
  String[] a = new String[l(c)];
  Iterator<String> it = c.iterator();
  for (int i = 0; i < l(a); i++)
    a[i] = it.next();
  return a;
}

static String[] toStringArray(Object o) {
  if (o instanceof String[])
    return (String[]) o;
  else if (o instanceof Collection)
    return toStringArray((Collection<String>) o);
  else
    throw fail("Not a collection or array: " + getClassName(o));
}



static TimerTask timerTask(final Object r, final java.util.Timer timer) {
  return new TimerTask() {
    public void run() {
      
      if (!licensed())
        timer.cancel();
      else
        pcallF(r);
    }
  };
}


static <A> A vmBus_timerStarted(A timer) {
  vmBus_send("timerStarted", timer, costCenter());
  return timer;
}


static List<Character> stringAsCharacterList(final String s) {
  if (s == null) return null;
  return new RandomAccessAbstractList<Character>() {
    final int l = l(s);
    public int size() { return l; }
    public Character get(int i) { return s.charAt(i); }
  };
}


static IterableIterator<Integer> countIterator_exclusive(int b) { return countIterator_exclusive(0, b); }
static IterableIterator<Integer> countIterator_exclusive(int a, int b) {
  return new IterableIterator<Integer>() {
    int i = a;
    
    public boolean hasNext() { return i < b; }
    public Integer next() { return i++; }
  };
}

static <A> IterableIterator<A> countIterator_exclusive(int b, IF1<Integer, A> f) { return countIterator_exclusive(0, b, f); }
static <A> IterableIterator<A> countIterator_exclusive(int a, int b, IF1<Integer, A> f) {
  return mapI_if1(f, countIterator_exclusive(a, b));
}


static IterableIterator<Integer> countIterator_exclusive_step(final int a, final int b, final int step) {
  assertTrue("step > 0", step > 0);
  
  return new IterableIterator<Integer>() {
    int i = a;
    
    public boolean hasNext() { return i < b; }
    public Integer next() { var j = i; i += step; return j; }
  };
}

static IterableIterator<Double> countIterator_exclusive_step(double a, double b, double step) {
  assertTrue("step > 0", step > 0);
  
  return new IterableIterator<Double>() {
    double i = a;
    
    public boolean hasNext() { return i < b; }
    public Double next() { var j = i; i += step; return j; }
  };
}

static <A> IterableIterator<A> countIterator_exclusive_step(double a, double b, double step, IF1<Double, A> f) {
  return mapI_if1(f, countIterator_exclusive_step(a, b, step));
}



static Object swingCall(final Object o, final String method, final Object... args) {
  return swing(new F0<Object>() { public Object get() { try {  return call(o, method, args);  } catch (Exception __e) { throw rethrow(__e); } }
  public String toString() { return "return call(o, method, args);"; }});
}


static int ifloor(double d) {
  return (int) Math.floor(d);
}

static IntRange ifloor(DoubleRange r) {
  return r == null ? null : intRange(ifloor(r.start), ifloor(r.end));
}


static int iceil(double d) {
  return (int) Math.ceil(d);
}


static Runnable wrapAsActivity(Object r) {
  if (r == null) return null;
  Runnable r2 = toRunnable(r);


  Object mod = dm_current_generic();
  if (mod == null) return r2;
  return new Runnable() {  public void run() { try { 
    AutoCloseable c =  (AutoCloseable) (rcall("enter", mod));
     AutoCloseable __1 = c; try {
    r2.run();
  
} finally { _close(__1); }} catch (Exception __e) { throw rethrow(__e); } }  public String toString() { return "AutoCloseable c =  (AutoCloseable) (rcall enter(mod));\r\n    temp c;\r\n    r2.r..."; }};

}


static Map<Thread, Boolean> _registerThread_threads;
static Object _onRegisterThread; // voidfunc(Thread)

static Thread _registerThread(Thread t) {
  if (_registerThread_threads == null)
    _registerThread_threads = newWeakHashMap();
  _registerThread_threads.put(t, true);
  vm_generalWeakSubMap("thread2mc").put(t, weakRef(mc()));
  callF(_onRegisterThread, t);
  return t;
}

static void _registerThread() {
  _registerThread(Thread.currentThread());
}


static <A> A liftLast(List<A> l) {
  if (empty(l)) return null;
  int i = l(l)-1;
  A a = l.get(i);
  l.remove(i);
  return a;
}

static <A> List<A> liftLast(int n, List<A> l) {
  int i = l(l)-n;
  List<A> part = cloneSubList(l, i);
  removeSubList(l, i);
  return part;
}




static String appendColonIfNempty(String s) {
  return empty(s) ? "" : s + ": ";
}


static double positiveInfinity() {
  return Double.POSITIVE_INFINITY;
}


static <A, B> Map<A, B> syncMRUCache(int size) {
  return synchroMap(new MRUCache(size));
}


static String dropSuffix(String suffix, String s) {
  return nempty(suffix) && endsWith(s, suffix) ? s.substring(0, l(s)-l(suffix)) : s;
}




static Object jsonDecode(String text) {
  return new jsonDecode_Y(text).parse();
}

// the miraculous class Y
static class jsonDecode_Y {
  String text;
  List<String> tok;
  boolean useOrderedMaps = false;
  int i = 1;

  jsonDecode_Y(String text) {
  this.text = text;
    tok = jsonTok(text);
  }
  
  transient  IF1<String, RuntimeException> fail;
RuntimeException fail(String msg) { return fail != null ? fail.get(msg) : fail_base(msg); }
final RuntimeException fail_fallback(IF1<String, RuntimeException> _f, String msg) { return _f != null ? _f.get(msg) : fail_base(msg); }
RuntimeException fail_base(String msg) { return main.fail(msg); }
  
  Object parse() {
    if (l(tok) == 1) return null;
    return parseExpr();
  }
  
  Object parseExpr() {
    String t = tok.get(i);
    if (t.startsWith("\"") || t.startsWith("'")) {
      String s = unquote(tok.get(i));
      i += 2;
      return s;
    }
    if (t.equals("{"))
      return parseMap();
    if (t.equals("["))
      return this.parseList(); // avoid loading standard function "parseList"
    if (t.equals("null")) {
      i += 2; return null;
    }
    if (t.equals("false")) {
      i += 2; return false;
    }
    if (t.equals("true")) {
      i += 2; return true;
    }
    boolean minus = false;
    if (t.equals("-")) {
      minus = true;
      i += 2;
      t = get(tok, i);
    }
    if (isInteger(t)) {
      int j = i;
      i += 2;
      if (eqOneOf(get(tok, i), ".", "e", "E")) {
        // rough parsing for doubles
        while (isInteger(get(tok, i))
          || eqOneOf(get(tok, i), ".", "e", "E", "-"))
          i += 2;
        double d = parseDouble(joinSubList(tok, j, i-1));
        if (minus) d = -d;
        return d;
      } else {
        long l = parseLong(t);
        return boxedIntOrLong(minus ? -l : l);
      }
    }
    
    throw fail("Unknown token " + (i+1) + ": " + t + ": " + text);
  }
  
  Object parseList() {
    consume("[");
    List list = new ArrayList();
    while (!tok.get(i).equals("]")) {
      list.add(parseExpr());
      if (tok.get(i).equals(",")) i += 2;
    }
    consume("]");
    return list;
  }
  
  Object parseMap() {
    consume("{");
    Map map = useOrderedMaps ? new LinkedHashMap() : new TreeMap();
    while (!tok.get(i).equals("}")) {
      String key = unquote(tok.get(i));
      i += 2;
      consume(":");
      Object value = parseExpr();
      map.put(key, value);
      if (tok.get(i).equals(",")) i += 2;
    }
    consume("}");
    return map;
  }
  
  void consume(String s) {
    if (!tok.get(i).equals(s)) {
      String prevToken = i-2 >= 0 ? tok.get(i-2) : "";
      String nextTokens = join(tok.subList(i, Math.min(i+4, tok.size())));
      throw fail(quote(s) + " expected: " + prevToken + " " + nextTokens + " (" + i + "/" + tok.size() + ")");
    }
    i += 2;
  }
}


static BufferedReader bufferedReader(Reader r) { return bufferedReader(r, 8192); }
static BufferedReader bufferedReader(Reader r, int bufSize) {
  if (r == null) return null;
  return r instanceof BufferedReader ? (BufferedReader) r : _registerIOWrap(new BufferedReader(r, bufSize), r);
}

static BufferedReader bufferedReader(File f) {
  return utf8bufferedReader(f);
}


static <A extends AutoCloseable> A holdResource(IResourceHolder holder, A a) {
  { if (holder != null) holder.add(a); }
  return a;
}


static <A> CloseableIterableIterator<A> iteratorFromFunction_f0_autoCloseable(final F0<A> f, final AutoCloseable closeable) {
  class IFF2 extends CloseableIterableIterator<A> {
    A a;
    boolean done = false;
    
    public boolean hasNext() {
      getNext();
      return !done;
    }
    
    public A next() {
      getNext();
      if (done) throw fail();
      A _a = a;
      a = null;
      return _a;
    }
    
    void getNext() {
      if (done || a != null) return;
      a = f.get();
      done = a == null;
    }
    
    public void close() throws Exception {
      if (closeable != null) closeable.close();
    }
  };
  return new IFF2();
}


static String readLineFromReaderWithClose(BufferedReader r) { try {
  String s = r.readLine();
  if (s == null) r.close();
  return s;
} catch (Exception __e) { throw rethrow(__e); } }


static AutoCloseable _wrapIOCloseable(final AutoCloseable c) {
  return c == null ? null : new AutoCloseable() { public String toString() { return "c.close();\r\n    _registerIO(c, null, false);"; } public void close() throws Exception { c.close();
    _registerIO(c, null, false);
  }};
}



static <A> A _registerIOWrap(A wrapper, Object wrapped) {
  return wrapper;
}


static int gzInputStream_defaultBufferSize = 65536;

static GZIPInputStream gzInputStream(File f) { try {
  return gzInputStream(new FileInputStream(f));
} catch (Exception __e) { throw rethrow(__e); } }

static GZIPInputStream gzInputStream(File f, int bufferSize) { try {
  return gzInputStream(new FileInputStream(f), bufferSize);
} catch (Exception __e) { throw rethrow(__e); } }

static GZIPInputStream gzInputStream(InputStream in) {
  return gzInputStream(in, gzInputStream_defaultBufferSize);
}

static GZIPInputStream gzInputStream(InputStream in, int bufferSize) { try {
  return _registerIOWrap(new GZIPInputStream(in, gzInputStream_defaultBufferSize), in);
} catch (Exception __e) { throw rethrow(__e); } }


static boolean endsWith(String a, String b) {
  return a != null && a.endsWith(b);
}

static boolean endsWith(String a, char c) {
  return nempty(a) && lastChar(a) == c;
}


  static boolean endsWith(String a, String b, Matches m) {
    if (!endsWith(a, b)) return false;
    m.m = new String[] {dropLast(l(b), a)};
    return true;
  }




static boolean isTrueOrYes(Object o) {
  return isTrueOpt(o) || o instanceof String && (eqicOneOf(((String) o), "1", "t", "true") || isYes(((String) o)));
}


static <A, B> LinkedHashMap<A, B> asLinkedHashMap(Map<A, B> map) {
  if (map instanceof LinkedHashMap) return (LinkedHashMap) map;
  LinkedHashMap<A, B> m = new LinkedHashMap();
  if (map != null) synchronized(collectionMutex(map)) {
    m.putAll(map);
  }
  return m;
}


static String hopeningTag(String tag, Map params) {
  return hopeningTag(tag, mapToParams(params));
}

static String hopeningTag(String tag, Object... params) {
  StringBuilder buf = new StringBuilder();
  buf.append("<" + tag);
  params = unrollParams(params);
  for (int i = 0; i < l(params); i += 2) {
    String name = (String) get(params, i);
    Object val = get(params, i+1);
    if (nempty(name) && val != null) {
      if (eqOneOf(val, html_valueLessParam(), true))
        buf.append(" " + name);
      else {
        String s = str(val);
        if (!empty(s))
          buf.append(" " + name + "=" + htmlQuote(s));
      }
    }
  }
  buf.append(">");
  return str(buf);
}


// This seems like a sweet spot. Small values like 1024 slow things down
// noticeably, big values like 1 MB do too (probably due to GC).
static int defaultBufferedOutputStreamSize() {
  return 65536;
}


static FileOutputStream fileOutputStream(File path) { try {
  return newFileOutputStream(path);
} catch (Exception __e) { throw rethrow(__e); } }



static FileOutputStream fileOutputStream(String path) { try {
  return newFileOutputStream(path);
} catch (Exception __e) { throw rethrow(__e); } }



static FileOutputStream fileOutputStream(File path, boolean append) { try {
  return newFileOutputStream(path, append);
} catch (Exception __e) { throw rethrow(__e); } }



static FileOutputStream fileOutputStream(String path, boolean append) { try {
  return newFileOutputStream(path, append);
} catch (Exception __e) { throw rethrow(__e); } }


public static File mkdirsForFile(File file) {
  File dir = file.getParentFile();
  if (dir != null) { // is null if file is in current dir
    dir.mkdirs();
    if (!dir.isDirectory())
      if (dir.isFile()) throw fail("Please delete the file " + f2s(dir) + " - it is supposed to be a directory!");
      else throw fail("Unknown IO exception during mkdirs of " + f2s(file));
  }
  return file;
}

public static String mkdirsForFile(String path) {
  mkdirsForFile(new File(path));
  return path;
}


static void _registerIO(Object object, String path, boolean opened) {
}


static String programID() {
  return getProgramID();
}

static String programID(Object o) {
  return getProgramID(o);
}


static <A> A getAndClearThreadLocal(ThreadLocal<A> tl) {
  A a = tl.get();
  tl.set(null);
  return a;
}


static List<String> javaTokC(String s) {
  if (s == null) return null;
  int l = s.length();
  ArrayList<String> tok = new ArrayList();
  
  int i = 0;
  while (i < l) {
    int j = i;
    char c, d;
    
    // scan for whitespace
    while (j < l) {
      c = s.charAt(j);
      d = j+1 >= l ? '\0' : s.charAt(j+1);
      if (c == ' ' || c == '\t' || c == '\r' || c == '\n')
        ++j;
      else if (c == '/' && d == '*') {
        do ++j; while (j < l && !s.substring(j, Math.min(j+2, l)).equals("*/"));
        j = Math.min(j+2, l);
      } else if (c == '/' && d == '/') {
        do ++j; while (j < l && "\r\n".indexOf(s.charAt(j)) < 0);
      } else
        break;
    }
    
    i = j;
    if (i >= l) break;
    c = s.charAt(i);
    d = i+1 >= l ? '\0' : s.charAt(i+1);

    // scan for non-whitespace
    if (c == '\'' || c == '"') {
      char opener = c;
      ++j;
      while (j < l) {
        if (s.charAt(j) == opener || s.charAt(j) == '\n') { // end at \n to not propagate unclosed string literal errors
          ++j;
          break;
        } else if (s.charAt(j) == '\\' && j+1 < l)
          j += 2;
        else
          ++j;
      }
    } else if (Character.isJavaIdentifierStart(c))
      do ++j; while (j < l && (Character.isJavaIdentifierPart(s.charAt(j)) || "'".indexOf(s.charAt(j)) >= 0)); // for stuff like "don't"
    else if (Character.isDigit(c)) {
      do ++j; while (j < l && Character.isDigit(s.charAt(j)));
      if (j < l && s.charAt(j) == 'L') ++j; // Long constants like 1L
    } else if (c == '[' && d == '[') {
      do ++j; while (j+1 < l && !s.substring(j, j+2).equals("]]"));
      j = Math.min(j+2, l);
    } else if (c == '[' && d == '=' && i+2 < l && s.charAt(i+2) == '[') {
      do ++j; while (j+2 < l && !s.substring(j, j+3).equals("]=]"));
      j = Math.min(j+3, l);
    } else
      ++j;
      
    tok.add(javaTok_substringC(s, i, j));
    i = j;
  }
  
  return tok;
}


static File programDir_mine; // set this to relocate program's data

static File programDir() {
  return programDir(getProgramID());
}

static File programDir(String snippetID) {
  boolean me = sameSnippetID(snippetID, programID());
  if (programDir_mine != null && me)
    return programDir_mine;
  File dir = new File(javaxDataDir(), formatSnippetIDOpt(snippetID));
  if (me) {
    String c = caseID();
    if (nempty(c)) dir = newFile(dir, c);
  }
  return dir;
}

static File programDir(String snippetID, String subPath) {
  return new File(programDir(snippetID), subPath);
}


static String loadTextFile(String fileName) {
  return loadTextFile(fileName, null);
}

static String loadTextFile(File f, String defaultContents) { return loadTextFile(f, defaultContents, "UTF-8"); }
static String loadTextFile(File f, String defaultContents, String encoding) { try {
  
  checkFileNotTooBigToRead(f);
  
  if (f == null || !f.exists()) return defaultContents;

  FileInputStream fileInputStream = new FileInputStream(f);
  InputStreamReader inputStreamReader = new InputStreamReader(fileInputStream, encoding);
  return loadTextFile(inputStreamReader);
} catch (Exception __e) { throw rethrow(__e); } }

public static String loadTextFile(File fileName) {
  return loadTextFile(fileName, null);
}

static String loadTextFile(String fileName, String defaultContents) {
  return fileName == null ? defaultContents : loadTextFile(newFile(fileName), defaultContents);
}

static String loadTextFile(Reader reader) throws IOException {
  StringBuilder builder = new StringBuilder();
  try {
    char[] buffer = new char[1024];
    int n;
    while (-1 != (n = reader.read(buffer)))
      builder.append(buffer, 0, n);
  } finally {
    reader.close();
  }
  return str(builder);
}




// TODO: cyclic structures involving certain lists & sets



static Object unstructure(String text) {
  return unstructure(text, false);
}

static Object unstructure(String text, boolean allDynamic) {
  return unstructure(text, allDynamic, null);
}

static Object unstructure(String text, IF1<String, Class> classFinder) {
  return unstructure(text, false, classFinder);
}

static int structure_internStringsLongerThan = 50;
static int unstructure_unquoteBufSize = 100;

static int unstructure_tokrefs; // stats

abstract static class unstructure_Receiver {
  abstract void set(Object o);
}

// classFinder: func(name) -> class (optional)
static Object unstructure(String text, boolean allDynamic,
  Object classFinder) {
  if (text == null) return null;
  return unstructure_tok(javaTokC_noMLS_iterator(text), allDynamic, classFinder);
}

static Object unstructure_reader(BufferedReader reader) {
  return unstructure_tok(javaTokC_noMLS_onReader(reader), false, null);
}

interface unstructure_Handler {
  void parse(int refID, int tokIndex, unstructure_Receiver out);
}
  
static class Unstructurer {
   final public Unstructurer setTok(Producer<String> tok){ return tok(tok); }
public Unstructurer tok(Producer<String> tok) { this.tok = tok; return this; }  final public Producer<String> getTok(){ return tok(); }
public Producer<String> tok() { return tok; }
 Producer<String> tok;
   final public Unstructurer setAllDynamic(boolean allDynamic){ return allDynamic(allDynamic); }
public Unstructurer allDynamic(boolean allDynamic) { this.allDynamic = allDynamic; return this; }  final public boolean getAllDynamic(){ return allDynamic(); }
public boolean allDynamic() { return allDynamic; }
 boolean allDynamic = false;
  int i = -1;
  Object classFinder;
  String mcDollar = actualMCDollar();
  
  Unstructurer classFinder(Object _classFinder) {
    classFinder = _classFinder != null ? _classFinder : _defaultClassFinder();
    return this;
  }

  // use Eclipse primitive collection if possible (smaller & hopefully faster?)
  
  
  HashMap<Integer, Object> refs = new HashMap();
  HashMap<Integer, Object> tokrefs = new HashMap();
  
  
  HashSet<String> concepts = new HashSet();
  List<Runnable> stack = new ArrayList();
  Map<String, String> baseClassMap = new HashMap();
  HashMap<Class, Constructor> innerClassConstructors = new HashMap();
  String curT;
  char[] unquoteBuf = new char[unstructure_unquoteBufSize];
  
  // value is a class or a Handler
  final HashMap<String, Object> handlers = new HashMap();
  
  Unstructurer() {
    try {
      Class mc =  (Class) (callF(classFinder, "<main>"));
      if (mc != null) mcDollar = mc.getName() + "$";
    } catch (Throwable __e) { pcallFail(__e); }
    
    makeHandlers();
  }
  
  
  
  void makeHandlers() {
    unstructure_Handler h;
    
    handlers.put("bigint", (unstructure_Handler) (refID, tokIndex, out)
      -> out.set(parseBigInt()));
      
    handlers.put("d", (unstructure_Handler) (refID, tokIndex, out)
      -> out.set(parseDouble()));
      
    handlers.put("fl", (unstructure_Handler) (refID, tokIndex, out)
      -> out.set(parseFloat()));
      
    handlers.put("sh", (unstructure_Handler) (refID, tokIndex, out) -> {
      consume();
      String t = tpp();
      if (t.equals("-")) {
        t = tpp();
        out.set((short) (-parseInt(t))); return;
      }
      out.set((short) parseInt(t));
    });
    
    handlers.put("enum", (unstructure_Handler) (refID, tokIndex, out) -> {
      consume();
      String t = tpp();
      assertTrue(isJavaIdentifier(t));
      String fullClassName = mcDollar + t;
      Class _c = findAClass(fullClassName);
      if (_c == null) throw fail("Enum class not found: " + fullClassName);
      int ordinal = parseInt(tpp());
      out.set(_c.getEnumConstants()[ordinal]);
    });

    handlers.put("false", h = (unstructure_Handler) (refID, tokIndex, out) -> {
      consume(); out.set(false);
    });
    handlers.put("f", h);
    
    handlers.put("true", h = (unstructure_Handler) (refID, tokIndex, out) -> {
      consume(); out.set(true);
    });
    handlers.put("t", h);
    
    handlers.put("{", (unstructure_Handler) (refID, tokIndex, out) -> parseMap(out));
    
    handlers.put("[", (unstructure_Handler) (refID, tokIndex, out) -> {
      ArrayList l = new ArrayList();
      if (refID >= 0) refs.put(refID, l);
      this.parseList(l, out);
    });
    
    handlers.put("bitset", (unstructure_Handler) (refID, tokIndex, out) -> parseBitSet(out));
    
    handlers.put("array", h = (unstructure_Handler) (refID, tokIndex, out) -> parseArray(out));
    handlers.put("intarray", h);
    handlers.put("dblarray", h);
    
    handlers.put("shortarray", (unstructure_Handler) (refID, tokIndex, out) -> {
      consume();
      String hex = trivialUnquote(tpp());
      out.set(shortArrayFromBytes(hexToBytes(hex)));
    });
    
    handlers.put("longarray", (unstructure_Handler) (refID, tokIndex, out) -> {
      consume();
      String hex = trivialUnquote(tpp());
      out.set(longArrayFromBytes(hexToBytes(hex)));
    });
  } // end of makeHandlers - add more handlers here

  Class findAClass(String fullClassName) { try {
    return classFinder != null ? (Class) callF(classFinder, fullClassName) : findClass_fullName(fullClassName);
  } catch (Throwable __e) { return null; } }
  
  String unquote(String s) {
    return unquoteUsingCharArray(s, unquoteBuf); 
  }

  // look at current token
  String t() {
    return curT;
  }
  
  // get current token, move to next
  String tpp() {
    String t = curT;
    consume();
    return t;
  }
  
  void parse(final unstructure_Receiver out) {
    String t = t();
    
    int refID;
    if (structure_isMarker(t, 0, l(t))) {
      refID = parseInt(t.substring(1));
      consume();
    } else refID = -1;
    
    // if (debug) print("parse: " + quote(t));
    
    final int tokIndex = i;  
    parse_inner(refID, tokIndex, new unstructure_Receiver() {
      void set(Object o) {
        if (refID >= 0)
          refs.put(refID, o);
        if (o != null)
          tokrefs.put(tokIndex, o);
        out.set(o);
      }
    });
  }
  
  void parse_inner(int refID, int tokIndex, unstructure_Receiver out) {
    String t = t();
    
    // if (debug) print("parse_inner: " + quote(t));
    
    Object handler = handlers.get(t);
    if (handler instanceof unstructure_Handler)
      { ((unstructure_Handler) handler).parse(refID, tokIndex, out); return; }
      
    Class c =  (Class) handler;
    if (c == null) {
      if (t.startsWith("\"")) {
        String s = internIfLongerThan(unquote(tpp()), structure_internStringsLongerThan);
        out.set(s); return;
      }
      
      if (t.startsWith("'")) {
        out.set(unquoteCharacter(tpp())); return;
      }
      if (t.equals("-")) {
        consume();
        t = tpp();
        out.set(isLongConstant(t) ? (Object) (-parseLong(t)) : (Object) (-parseInt(t))); return;
      }
      if (isInteger(t) || isLongConstant(t)) {
        consume();
        //if (debug) print("isLongConstant " + quote(t) + " => " + isLongConstant(t));
        if (isLongConstant(t)) {
          out.set(parseLong(t)); return;
        }
        long l = parseLong(t);
        boolean isInt = l == (int) l;
        
        out.set(isInt ? (Object) Integer.valueOf((int) l) : (Object) Long.valueOf(l)); return;
      }
      if (t.equals("-")) {
        consume();
        t = tpp();
        out.set(isLongConstant(t) ? (Object) (-parseLong(t)) : (Object) (-parseInt(t))); return;
      }
      if (isInteger(t) || isLongConstant(t)) {
        consume();
        //if (debug) print("isLongConstant " + quote(t) + " => " + isLongConstant(t));
        if (isLongConstant(t)) {
          out.set(parseLong(t)); return;
        }
        long l = parseLong(t);
        boolean isInt = l == (int) l;
        
        out.set(isInt ? (Object) Integer.valueOf((int) l) : (Object) Long.valueOf(l)); return;
      }
      
      if (t.equals("File")) {
        consume();
        File f = new File(unquote(tpp()));
        out.set(f); return;
      }
      
      if (t.startsWith("r") && isInteger(t.substring(1))) {
        consume();
        int ref = Integer.parseInt(t.substring(1));
        Object o = refs.get(ref);
        if (o == null)
          warn("unsatisfied back reference " + ref);
        out.set(o); return;
      }
    
      if (t.startsWith("t") && isInteger(t.substring(1))) {
        consume();
        int ref = Integer.parseInt(t.substring(1));
        Object o = tokrefs.get(ref);
        if (o == null)
          warn("unsatisfied token reference " + ref + " at " + tokIndex);
        out.set(o); return;
      }
      
      if (t.equals("hashset")) { parseHashSet(out); return; }
      if (t.equals("lhs")) { parseLinkedHashSet(out); return; }
      if (t.equals("treeset")) { parseTreeSet(out); return; }
      if (t.equals("ciset")) { parseCISet(out); return; }
      
      if (eqOneOf(t, "hashmap", "hm")) {
        consume();
        parseMap(new HashMap(), out);
        return;
      }
      if (t.equals("lhm")) {
        consume();
        parseMap(new LinkedHashMap(), out);
        return;
      }
      if (t.equals("tm")) {
        consume();
        parseMap(new TreeMap(), out);
        return;
      }
      if (t.equals("cimap")) {
        consume();
        parseMap(ciMap(), out);
        return;
      }
      
      if (t.equals("ll")) {
        consume();
        LinkedList l = new LinkedList();
        if (refID >= 0) refs.put(refID, l);
        { parseList(l, out); return; }
      }

      if (t.equals("syncLL")) { // legacy
        consume();
        { parseList(synchroLinkedList(), out); return; }
      }

      if (t.equals("sync")) {
        consume();
        { parse(new unstructure_Receiver() {
          void set(Object value) {
            if (value instanceof Map) {
               // Java 7
              if (value instanceof NavigableMap)
                { out.set(synchroNavigableMap((NavigableMap) value)); return; }
              
              if (value instanceof SortedMap)
                { out.set(synchroSortedMap((SortedMap) value)); return; }
              { out.set(synchroMap((Map) value)); return; }
            } else
              { out.set(synchroList((List) value)); return; }
          }
        }); return; }
      }
      
      if (t.equals("ba")) {
        consume();
        String hex = trivialUnquote(tpp());
        out.set(hexToBytes(hex)); return;
      }
      if (t.equals("boolarray")) {
        consume();
        int n = parseInt(tpp());
        String hex = trivialUnquote(tpp());
        out.set(boolArrayFromBytes(hexToBytes(hex), n)); return;
      }
      if (t.equals("class")) {
        out.set(parseClass()); return;
      }
      if (t.equals("l")) {
        parseLisp(out); return;
      }
      if (t.equals("null")) {
        consume(); out.set(null); return;
      }
      
      if (eq(t, "c")) {
        consume();
        t = t();
        assertTrue(isJavaIdentifier(t));
        concepts.add(t);
      }
      
      // custom deserialization (new static method method)
      if (eq(t, "cu")) {
        consume();
        t = tpp();
        assertTrue(isJavaIdentifier(t));
        String fullClassName = mcDollar + t;
        Class _c = findAClass(fullClassName);
        if (_c == null) throw fail("Class not found: " + fullClassName);
        parse(new unstructure_Receiver() {
          void set(Object value) {
            
            out.set(call(_c, "_deserialize", value));
          }
        });
        return;
      }
    }
    
    if (eq(t, "j")) {
      consume();
      out.set(parseJava()); return;
    }
    
    if (eq(t, "bc")) {
      consume();
      String c1 = tpp();
      String c2 = tpp();
      baseClassMap.put(c1, c2);
      { parse_inner(refID, i, out); return; }
    }
    
    // add more tokens here

    // Now we want to find our target class c
    // Have we failed to look up the class before?
    //bool seenBefore = handlers.containsKey(cname);

    // If we have seen the class before, we skip all of this
    // and simply leave c as null
    // TODO - how do we fill className?
    //if (!seenBefore) {
      if (c == null && !isJavaIdentifier(t))
        throw new RuntimeException("Unknown token " + (i+1) + ": " + quote(t));
        
      // any other class name (or package name)
      consume();
      String className, fullClassName;
      
      // Is it a package name?
      if (eq(t(), ".")) {
        className = t;
        do {
          consume();
          className += "." + assertIdentifier(tpp());
        } while (eq(t(), "."));
        fullClassName = className;
      } else {
        className = t;
        fullClassName = mcDollar + t;
      }
      
      if (c == null && !allDynamic) {
        // First, find class
        c = findAClass(fullClassName);
        handlers.put(className, c);
      }
      
      // check for existing base class
      if (c == null && !allDynamic) {
        Set<String> seen = new HashSet();
        String parent = className;
        while (true) {
          String baseName = baseClassMap.get(parent);
          if (baseName == null)
            break;
          if (!seen.add(baseName))
            throw fail("Cyclic superclass info: " + baseName);
          c = findAClass(mcDollar + baseName);
          if (c == null)
            print("Base class " + baseName + " of " + parent +  " doesn't exist either");
          else if (isAbstract(c))
            print("Can't instantiate abstract base class: " + c);
          else {
            printVars_str("Reverting to base class", "className", className, "baseName", baseName, "c", c);
            handlers.put(className, c);
            break;
          }
          parent = baseName;
        }
      }
    //}
        
    // Check if it has an outer reference
    boolean hasBracket = eq(t(), "(");
    if (hasBracket) consume();
    boolean hasOuter = hasBracket && startsWith(t(), "this$");
    
    DynamicObject dO = null;
    Object o = null;
    final String thingName = t;
    try {
      if (c != null) {
        if (hasOuter) try {
          Constructor ctor = innerClassConstructors.get(c);
          if (ctor == null)
            innerClassConstructors.put(c, ctor = nuStubInnerObject_findConstructor(c, classFinder));
          o = ctor.newInstance(new Object[] {null});
        } catch (Exception e) {
          print("Error deserializing " + c + ": " + e);
          o = nuEmptyObject(c);
        } else
          o = nuEmptyObject(c);
        if (o instanceof DynamicObject) dO = (DynamicObject) o;
      } else {
        if (concepts.contains(t) && (c = findAClass(mcDollar + "Concept")) != null)
          o = dO = (DynamicObject) nuEmptyObject(c);
        else
          dO = new DynamicObject();
        dO.className = className;
        
      }
    } catch (Throwable __e) { pcallFail(__e); } // end of pcall
    
    // Creating instance failed? Use DynamicObject
    if (o == null && dO == null)
      dO = new DynamicObject();
    
    // Save in references list early because contents of object
    // might link back to main object
    
    if (refID >= 0)
      refs.put(refID, o != null ? o : dO);
    tokrefs.put(tokIndex, o != null ? o : dO);
    
    // NOW parse the fields!
    
    HashMap<String, Object> fields = new HashMap(); // no longer preserving order (why did we do this?)
    Object _o = o;
    DynamicObject _dO = dO;
    if (hasBracket) {
      stack.add(new Runnable() {  public void run() { try { 
        
        if (eq(t(), ",")) consume();
        if (eq(t(), ")")) {
          consume(")");
          objRead(_o, _dO, fields, hasOuter);
          out.set(_o != null ? _o : _dO);
        } else {
          final String key = unquote(tpp());
          String t = tpp();
          if (!eq(t, "="))
            throw fail("= expected, got " + t + " after " + quote(key) + " in object " + thingName /*+ " " + sfu(fields)*/);
          stack.add(this);
          parse(new unstructure_Receiver() {
            void set(Object value) {
              fields.put(key, value);
              /*ifdef unstructure_debug
                print("Got field value " + value + ", next token: " + t());
              endifdef*/
              //if (eq(t(), ",")) consume();
            }
          });
        }
      
} catch (Exception __e) { throw rethrow(__e); } }  public String toString() { return "ifdef unstructure_debug\r\n          print(\"in object values, token: \" + t());\r..."; }});
    } else {
      objRead(o, dO, fields, hasOuter);
      out.set(o != null ? o : dO);
    }
  }
  
  void objRead(Object o, DynamicObject dO, Map<String, Object> fields, boolean hasOuter) {
    
    
    // translate between diferent compilers (this$0 vs this$1)
    Object outer = fields.get("this$0");
    if (outer != null) fields.put("this$1", outer);
    else {
      outer = fields.get("this$1");
      if (outer != null) fields.put("this$0", outer);
    }
    
    if (o != null) {
      if (dO != null) {
        
        setOptAllDyn_pcall(dO, fields);
      } else {
        setOptAll_pcall(o, fields);
        
      }
      if (hasOuter)
        fixOuterRefs(o);
    } else for (Map.Entry<String, Object> e : fields.entrySet())
      setDynObjectValue(dO, intern(e.getKey()), e.getValue());

    if (o != null)
      pcallOpt_noArgs(o, "_doneLoading");
  }
  
  void parseSet(final Set set, final unstructure_Receiver out) {
    this.parseList(new ArrayList(), new unstructure_Receiver() {
      void set(Object o) {
        set.addAll((List) o);
        out.set(set);
      }
    });
  }
  
  void parseLisp(final unstructure_Receiver out) {
    
    
    throw fail("class Lisp not included");
  }
  
  void parseBitSet(final unstructure_Receiver out) {
    consume("bitset");
    consume("{");
    final BitSet bs = new BitSet();
    stack.add(new Runnable() {  public void run() { try { 
      if (eq(t(), "}")) {
        consume("}");
        out.set(bs);
      } else {
        stack.add(this);
        parse(new unstructure_Receiver() {
          void set(Object o) {
            bs.set((Integer) o);
            if (eq(t(), ",")) consume();
          }
        });
      }
    
} catch (Exception __e) { throw rethrow(__e); } }  public String toString() { return "if (eq(t(), \"}\")) {\r\n        consume(\"}\");\r\n        out.set(bs);\r\n      } els..."; }});
  }
  
  void parseList(final List list, final unstructure_Receiver out) {
    tokrefs.put(i, list);
    consume("[");
    stack.add(new Runnable() {  public void run() { try { 
      if (eq(t(), "]")) {
        consume();
        
        out.set(list);
      } else {
        stack.add(this);
        parse(new unstructure_Receiver() {
          void set(Object o) {
            //if (debug) print("List element type: " + getClassName(o));
            list.add(o);
            if (eq(t(), ",")) consume();
          }
        });
      }
    
} catch (Exception __e) { throw rethrow(__e); } }  public String toString() { return "if (eq(t(), \"]\")) {\r\n        consume();\r\n        ifdef unstructure_debug\r\n   ..."; }});
  }
  
  void parseArray(unstructure_Receiver out) {
    String _type = tpp();
    int dims;

    if (eq(t(), "S")) { // string array
      _type = "S";
      consume();
    }
    
    if (eq(t(), "/")) { // multi-dimensional array
      consume();
      dims = parseInt(tpp());
    } else
      dims = 1;
    
    consume("{");
    List list = new ArrayList();
    String type = _type;
    
    stack.add(new Runnable() {  public void run() { try { 
      if (eq(t(), "}")) {
        consume("}");
        if (dims > 1) {
          Class atype;
          if (type.equals("intarray")) atype = int.class;
          else if (type.equals("S")) atype = String.class;
          else throw todo("multi-dimensional arrays of other types");
          
          out.set(list.toArray((Object[]) newMultiDimensionalOuterArray(atype, dims, l(list))));
        } else
          out.set(
            type.equals("intarray") ? toIntArray(list)
            : type.equals("dblarray") ? toDoubleArray(list)
            : type.equals("S") ? toStringArray(list)
            : list.toArray());
      } else {
        stack.add(this);
        parse(new unstructure_Receiver() {
          void set(Object o) {
            list.add(o);
            if (eq(t(), ",")) consume();
          }
        });
      }
    
} catch (Exception __e) { throw rethrow(__e); } }  public String toString() { return "if (eq(t(), \"}\")) {\r\n        consume(\"}\");\r\n        if (dims > 1) {\r\n        ..."; }});
  }
  
  Object parseClass() {
    consume("class");
    consume("(");
    String name = unquote(tpp());
    consume(")");
    Class c = allDynamic ? null : findAClass(name);
    if (c != null) return c;
    DynamicObject dO = new DynamicObject();
    dO.className = "java.lang.Class";
    name = dropPrefix(mcDollar, name);
    dynamicObject_setRawFieldValue(dO, "name", name);
    return dO;
  }
  
  Object parseBigInt() {
    consume("bigint");
    consume("(");
    String val = tpp();
    if (eq(val, "-"))
      val = "-" + tpp();
    consume(")");
    return new BigInteger(val);
  }
  
  Object parseDouble() {
    consume("d");
    consume("(");
    String val = unquote(tpp());
    consume(")");
    return Double.parseDouble(val);
  }
  
  Object parseFloat() {
    consume("fl");
    String val;
    if (eq(t(), "(")) {
      consume("(");
      val = unquote(tpp());
      consume(")");
    } else {
      val = unquote(tpp());
    }
    return Float.parseFloat(val);
  }
  
  void parseHashSet(unstructure_Receiver out) {
    consume("hashset");
    parseSet(new HashSet(), out);
  }
  
  void parseLinkedHashSet(unstructure_Receiver out) {
    consume("lhs");
    parseSet(new LinkedHashSet(), out);
  }
  
  void parseTreeSet(unstructure_Receiver out) {
    consume("treeset");
    parseSet(new TreeSet(), out);
  }
  
  void parseCISet(unstructure_Receiver out) {
    consume("ciset");
    parseSet(ciSet(), out);
  }
  
  void parseMap(unstructure_Receiver out) {
    parseMap(new TreeMap(), out);
  }
  
  Object parseJava() {
    String j = unquote(tpp());
    Matches m = new Matches();
    if (jmatch("java.awt.Color[r=*,g=*,b=*]", j, m))
      return nuObject("java.awt.Color", parseInt(m.unq(0)), parseInt(m.unq(1)), parseInt(m.unq(2)));
    else {
      warn("Unknown Java object: " + j);
      return null;
    }
  }
  
  void parseMap(final Map map, final unstructure_Receiver out) {
    consume("{");
    stack.add(new Runnable() {
      boolean v = false;
      Object key;
      
      public void run() { 
        if (v) {
          v = false;
          stack.add(this);
          if (!eq(tpp(), "="))
            throw fail("= expected, got " + t() + " in map of size " + l(map));

          parse(new unstructure_Receiver() {
            void set(Object value) {
              map.put(key, value);
              
              if (eq(t(), ",")) consume();
            }
          });
        } else {
          if (eq(t(), "}")) {
            consume("}");
            out.set(map);
          } else {
            v = true;
            stack.add(this);
            parse(new unstructure_Receiver() {
              void set(Object o) {
                key = o;
              }
            });
          }
        } // if v else
      } // run()
    });
  }
  
  /*void parseSub(unstructure_Receiver out) {
    int n = l(stack);
    parse(out);
    while (l(stack) > n)
      stack
  }*/
  
  void consume() { curT = tok.next(); ++i; }
  
  void consume(String s) {
    if (!eq(t(), s)) {
      /*S prevToken = i-1 >= 0 ? tok.get(i-1) : "";
      S nextTokens = join(tok.subList(i, Math.min(i+2, tok.size())));
      fail(quote(s) + " expected: " + prevToken + " " + nextTokens + " (" + i + "/" + tok.size() + ")");*/
      throw fail(quote(s) + " expected, got " + quote(t()));
    }
    consume();
  }
  
  // outer wrapper function getting first token and unwinding the stack
  void parse_initial(unstructure_Receiver out) {
    consume(); // get first token
    parse(out);
    while (nempty(stack))
      popLast(stack).run();
  }
}

static Object unstructure_tok(Producer<String> tok, boolean allDynamic, Object classFinder) {
  boolean debug = unstructure_debug;
   AutoCloseable __1 = tempSetTL(dynamicObjectIsLoading_threadLocal(), true); try {
  Var v = new Var();
  var unstructurer = new Unstructurer()
    .tok(tok)
    .allDynamic(allDynamic)
    .classFinder(classFinder);
  unstructurer.parse_initial(new unstructure_Receiver() {
    void set(Object o) { v.set(o); }
  });
  unstructure_tokrefs = unstructurer.tokrefs.size();
  return v.get();
} finally { _close(__1); }}

static boolean unstructure_debug = false;


static Producer<String> javaTokC_noMLS_onReader(final BufferedReader r) {
  final class X implements Producer<String> {
    StringBuilder buf = new StringBuilder(); // stores from "i"
    char c, d, e = 'x'; // just not '\0'
    
    X() {
      // fill c, d and e
      nc();
      nc();
      nc();
    }
    
    // get next character(s) into c, d and e
    void nc() { try {
      c = d;
      d = e;
      if (e == '\0') return;
      int i = r.read();
      e = i < 0 ? '\0'
        : i == '\0' ? '_' // shouldn't happen anymore
        : (char) i;
    } catch (Exception __e) { throw rethrow(__e); } }
    
    void ncSave() {
      if (c != '\0') {
        buf.append(c);
        nc();
      }
    }
    
    public String next() {
      // scan for whitespace
      while (c != '\0') {
        if (c == ' ' || c == '\t' || c == '\r' || c == '\n')
          nc();
        else if (c == '/' && d == '*') {
          do nc(); while (c != '\0' && !(c == '*' && d == '/'));
          nc(); nc();
        } else if (c == '/' && d == '/') {
          do nc(); while (c != '\0' && "\r\n".indexOf(c) < 0);
        } else
          break;
      }
      
      if (c == '\0') return null;

      // scan for non-whitespace
      if (c == '\'' || c == '"') {
        char opener = c;
        ncSave();
        while (c != '\0') {
          if (c == opener || c == '\n') { // end at \n to not propagate unclosed string literal errors
            ncSave();
            break;
          } else if (c == '\\') {
            ncSave();
            ncSave();
          } else
            ncSave();
        }
      } else if (Character.isJavaIdentifierStart(c))
        do ncSave(); while (Character.isJavaIdentifierPart(c) || c == '\''); // for stuff like "don't"
      else if (Character.isDigit(c)) {
        do ncSave(); while (Character.isDigit(c));
        if (c == 'L') ncSave(); // Long constants like 1L
      } else
        ncSave();
        
      String t = buf.toString();
      buf.setLength(0);
      return t;
    }
  }
  
  return new X();
}



static boolean emptyString(String s) {
  return s == null || s.length() == 0;
}


static <A> A[] makeArray(Class<A> type, int n) {
  return (A[]) Array.newInstance(type, n);
}


static String formatDouble_significant2(double d, int digits) {
  try {
    digits -= Math.floor(max(-10, Math.log10(abs(d))+1));
    return formatDouble(d, digits);
  } catch (Throwable _e) {
    print("Had number: " + d + ", digits: " + digits);
  
throw rethrow(_e); }
}




static SimpleDateFormat simpleDateFormat_local(String format) {
  SimpleDateFormat sdf = new SimpleDateFormat(format);
  sdf.setTimeZone(localTimeZone());
  return sdf;
}


static ThreadLocal<Long> saveTiming_last = new ThreadLocal();

static void saveTiming(long ms) {
  print(ms + " ms");
  saveTiming_noPrint(ms);
}

static void saveTiming_noPrint(long ms) {
  saveTiming_last.set(ms);
}

static ThreadLocal<Long> saveTiming_tl() {
  return saveTiming_last;
}


static String[] dropFirst(int n, String[] a) {
  return drop(n, a);
}

static String[] dropFirst(String[] a) {
  return drop(1, a);
}

static Object[] dropFirst(Object[] a) {
  return drop(1, a);
}

static <A> List<A> dropFirst(List<A> l) {
  return dropFirst(1, l);
}

static <A> List<A> dropFirst(int n, Iterable<A> i) { return dropFirst(n, toList(i)); }
static <A> List<A> dropFirst(Iterable<A> i) { return dropFirst(toList(i)); }

static <A> List<A> dropFirst(int n, List<A> l) {
  return n <= 0 ? l : new ArrayList(l.subList(Math.min(n, l.size()), l.size()));
}

static <A> List<A> dropFirst(List<A> l, int n) {
  return dropFirst(n, l);
}

static String dropFirst(int n, String s) { return substring(s, n); }
static String dropFirst(String s, int n) { return substring(s, n); }
static String dropFirst(String s) { return substring(s, 1); }


static <A> Chain<A> dropFirst(Chain<A> c) {
  return c == null ? null : c.next;
}



static int indexOfNonDigit(String s) {
  int n = l(s);
  for (int i = 0; i < n; i++)
    if (!isDigit(s.charAt(i)))
      return i;
  return -1;
}


static Object dm_current_generic() {
  return getWeakRef(dm_current_generic_tl().get());
}


static Object rcall(String method, Object o, Object... args) {
  return call_withVarargs(o, method, args);
}


static Runnable rPcall(Runnable r) {
  return r == null ? null : () -> { try { r.run(); } catch (Throwable __e) { pcallFail(__e); } };
}


static Random customRandomizerForThisThread() {
  return customRandomizerForThisThread_tl().get();
}


static Random defaultRandomizer() {
  return defaultRandomGenerator();
}


static <A> A listGet(List<A> l, int idx) {
  return l != null && idx >= 0 && idx < l.size() ? l.get(idx) : null;
}


static <A> List<A> newSubList(List<A> l, int startIndex, int endIndex) {
  return cloneList(subList(l, startIndex, endIndex));
}

static <A> List<A> newSubList(List<A> l, int startIndex) {
  return cloneList(subList(l, startIndex));
}


static <A> List<A> subList(List<A> l, int startIndex) {
  return subList(l, startIndex, l(l));
}

static <A> List<A> subList(int startIndex, List<A> l) {
  return subList(l, startIndex);
}

static <A> List<A> subList(int startIndex, int endIndex, List<A> l) {
  return subList(l, startIndex, endIndex);
}

static <A> List<A> subList(List<A> l, int startIndex, int endIndex) {
  if (l == null) return null;
  int n = l(l);
  startIndex = Math.max(0, startIndex);
  endIndex = Math.min(n, endIndex);
  if (startIndex > endIndex) return ll();
  if (startIndex == 0 && endIndex == n) return l;
  
  
    return l.subList(startIndex, endIndex);
  
}


static <A> List<A> subList(List<A> l, IntRange r) {
  return subList(l, r.start, r.end);
}



static int lastIndexOf(String a, String b) {
  return a == null || b == null ? -1 : a.lastIndexOf(b);
}

static int lastIndexOf(String a, char b) {
  return a == null ? -1 : a.lastIndexOf(b);
}

// starts searching from i-1
static <A> int lastIndexOf(List<A> l, int i, A a) {
  if (l == null) return -1;
  for (i = min(l(l), i)-1; i >= 0; i--)
    if (eq(l.get(i), a))
      return i;
  return -1;
}

static <A> int lastIndexOf(List<A> l, A a) {
  if (l == null) return -1;
  for (int i = l(l)-1; i >= 0; i--)
    if (eq(l.get(i), a))
      return i;
  return -1;
}


static <A, B> Map<A, B> weakHashMap() {
  return newWeakHashMap();
}


static <A> TreeSet<A> asTreeSet(Collection<A> set) {
  return set == null ? null : set instanceof TreeSet ? (TreeSet) set : new TreeSet(set);
}


static int hashCode(Object a) {
  return a == null ? 0 : a.hashCode();
}

static int hashCode(long l) {
  return Long.hashCode(l);
}

static int hashCode(double d) {
  return Double.hashCode(d);
}


static Object costCenter() { return mc(); }


static class mapI_if1_It<A, B> extends IterableIterator<B> {
  IF1<A, B> f;
  Iterator<A> i;
  
  mapI_if1_It() {}
  mapI_if1_It(IF1<A, B> f, Iterator<A> i) {
  this.i = i;
  this.f = f;}
  
  public boolean hasNext() {
    return i.hasNext();
  }
  
  public B next() {
    return f.get(i.next());
  }
  
  public String toString() {
    return formatFunctionCall("mapI_if1", f, i);
  }
}

static <A, B> IterableIterator<B> mapI_if1(IF1<A, B> f, Iterable<A> i) {
  return new mapI_if1_It(f, i.iterator());
}



static <A, B> IterableIterator<B> mapI_if1(Iterable<A> i, IF1<A, B> f) {
  return mapI_if1(f, i);
}


static IntRange intRange(int start, int end) {
  return new IntRange(start, end);
}


static Map vm_generalWeakSubMap(Object name) {
  synchronized(vm_generalMap()) {
    Map map =  (Map) (vm_generalMap_get(name));
    if (map == null)
      vm_generalMap_put(name, map = newWeakMap());
    return map;
  }
}



static <A> WeakReference<A> weakRef(A a) {
  return newWeakReference(a);
}




static List<String> jsonTok(String s) {
  List<String> tok = new ArrayList();
  int l = l(s);
  
  int i = 0;
  while (i < l) {
    int j = i;
    char c; String cc;
    
    // scan for whitespace
    while (j < l) {
      c = s.charAt(j);
      cc = s.substring(j, Math.min(j+2, l));
      if (c == ' ' || c == '\t' || c == '\r' || c == '\n')
        ++j;
      else if (cc.equals("/*")) {
        do ++j; while (j < l && !s.substring(j, Math.min(j+2, l)).equals("*/"));
        j = Math.min(j+2, l);
      } else if (cc.equals("//")) {
        do ++j; while (j < l && "\r\n".indexOf(s.charAt(j)) < 0);
      } else
        break;
    }
    
    tok.add(s.substring(i, j));
    i = j;
    if (i >= l) break;
    c = s.charAt(i); // cc is not needed in rest of loop body

    // scan for non-whitespace (json strings, "null" identifier, numbers. everything else automatically becomes a one character token.)
    if (c == '\'' || c == '"') {
      char opener = c;
      ++j;
      while (j < l) {
        if (s.charAt(j) == opener) {
          ++j;
          break;
        } else if (s.charAt(j) == '\\' && j+1 < l)
          j += 2;
        else
          ++j;
      }
    } else if (Character.isLetter(c))
      do ++j; while (j < l && Character.isLetter(s.charAt(j)));
    else if (Character.isDigit(c))
      do ++j; while (j < l && Character.isDigit(s.charAt(j)));
    else
      ++j;

    tok.add(s.substring(i, j));
    i = j;
  }
  
  if ((tok.size() % 2) == 0) tok.add("");
  return tok;
}



static boolean isInteger(String s) {
  int n = l(s);
  if (n == 0) return false;
  int i = 0;
  if (s.charAt(0) == '-')
    if (++i >= n) return false;
  while (i < n) {
    char c = s.charAt(i);
    if (c < '0' || c > '9') return false;
    ++i;
  }
  return true;
}


static String joinSubList(List<String> l, int i, int j) {
  return join(subList(l, i, j));
}

static String joinSubList(List<String> l, int i) {
  return join(subList(l, i));
}


static String joinSubList(List<String> l, IntRange r) {
  return r == null ? null : joinSubList(l, r.start, r.end);
}



static Number boxedIntOrLong(long l) {
  return l != (int) l ? boxed(l) : boxed((int) l);
}


static char lastChar(String s) {
  return empty(s) ? '\0' : s.charAt(l(s)-1);
}


static <A> A[] dropLast(A[] a) { return dropLast(a, 1); }
static <A> A[] dropLast(A[] a, int n) {
  if (a == null) return null;
  n = Math.min(n, a.length);
  A[] b = arrayOfSameType(a, a.length-n);
  System.arraycopy(a, 0, b, 0, b.length);
  return b;
}

static <A> List<A> dropLast(List<A> l) {
  return subList(l, 0, l(l)-1);
}

static <A> List<A> dropLast(int n, List<A> l) {
  return subList(l, 0, l(l)-n);
}

static <A> List<A> dropLast(Iterable<A> l) {
  return dropLast(asList(l));
}

static String dropLast(String s) {
  return substring(s, 0, l(s)-1);
}

static String dropLast(String s, int n) {
  return substring(s, 0, l(s)-n);
}

static String dropLast(int n, String s) {
  return dropLast(s, n);
}



static boolean isTrueOpt(Object o) {
  if (o instanceof Boolean)
    return ((Boolean) o).booleanValue();
  return false;
}

static boolean isTrueOpt(String field, Object o) {
  return isTrueOpt(getOpt(field, o));
}


static boolean eqicOneOf(String s, String... l) {
  for (String x : l) if (eqic(s, x)) return true; return false;
}


static List<String> isYes_yesses = litlist("y", "yes", "yeah", "y", "yup", "yo", "corect", "sure", "ok", "afirmative"); // << collapsed words, so "corect" means "correct"

static boolean isYes(String s) {
  return isYes_yesses.contains(collapseWord(toLowerCase(firstWord2(s))));
}


static Object[] mapToParams(Map map) {
  return mapToObjectArray(map);
}


static Object[] unrollParams(Object[] params) {
  if (l(params) == 1 && params[0] instanceof Map)
    return mapToParams((Map) params[0]);
  return params;
}


static Object html_valueLessParam_cache;
static Object html_valueLessParam() { if (html_valueLessParam_cache == null) html_valueLessParam_cache = html_valueLessParam_load(); return html_valueLessParam_cache;}

static Object html_valueLessParam_load() {
  return new Object();
}


static String htmlQuote(String s) {
  return "\"" + htmlencode_forParams(s) + "\"";
}


static String f2s(File f) {
  return f == null ? null : f.getAbsolutePath();
}

static String f2s(String s) { return f2s(newFile(s)); }


 static String f2s(java.nio.file.Path p) {
  return p == null ? null : f2s(p.toFile());
}




static String programID;
static String getProgramID() {
  return nempty(programID) ? formatSnippetIDOpt(programID) : "?";
}


// TODO: ask JavaX instead
static String getProgramID(Class c) {
  String id = (String) getOpt(c, "programID");
  if (nempty(id))
    return formatSnippetID(id);
  return "?";
}


static String getProgramID(Object o) {
  return getProgramID(getMainClass(o));
}


static String javaTok_substringC(String s, int i, int j) {
  return s.substring(i, j);
}


static boolean sameSnippetID(String a, String b) {
  if (!isSnippetID(a) || !isSnippetID(b)) return false;
  return parseSnippetID(a) == parseSnippetID(b);
}


static File javaxDataDir_dir; // can be set to work on different base dir

static File javaxDataDir() {
  return javaxDataDir_dir != null ? javaxDataDir_dir : new File(userHome(), "JavaX-Data");
}

static File javaxDataDir(String... subs) {
  return newFile(javaxDataDir(), subs);
}


static String formatSnippetIDOpt(String s) {
  return isSnippetID(s) ? formatSnippetID(s) : s;
}


static volatile String caseID_caseID;

static String caseID() { return caseID_caseID; }

static void caseID(String id) {
  caseID_caseID = id;
}


static ThreadLocal<VF1<File>> checkFileNotTooBigToRead_tl = new ThreadLocal();

static void checkFileNotTooBigToRead(File f) {
  callF(checkFileNotTooBigToRead_tl.get(), f);
}


static Producer<String> javaTokC_noMLS_iterator(final String s) {
  return javaTokC_noMLS_iterator(s, 0);
}

static Producer<String> javaTokC_noMLS_iterator(final String s, final int startIndex) {
  return new Producer<String>() {
    final int l = s.length();
    int i = startIndex;
    
    public String next() {
      if (i >= l) return null;
      
      int j = i;
      char c, d;
      
      // scan for whitespace
      while (j < l) {
        c = s.charAt(j);
        d = j+1 >= l ? '\0' : s.charAt(j+1);
        if (c == ' ' || c == '\t' || c == '\r' || c == '\n')
          ++j;
        else if (c == '/' && d == '*') {
          do ++j; while (j < l && !s.substring(j, Math.min(j+2, l)).equals("*/"));
          j = Math.min(j+2, l);
        } else if (c == '/' && d == '/') {
          do ++j; while (j < l && "\r\n".indexOf(s.charAt(j)) < 0);
        } else
          break;
      }
      
      i = j;
      if (i >= l) return null;
      c = s.charAt(i);
      d = i+1 >= l ? '\0' : s.charAt(i+1);
  
      // scan for non-whitespace
      if (c == '\'' || c == '"') {
        char opener = c;
        ++j;
        while (j < l) {
          if (s.charAt(j) == opener || s.charAt(j) == '\n') { // end at \n to not propagate unclosed string literal errors
            ++j;
            break;
          } else if (s.charAt(j) == '\\' && j+1 < l)
            j += 2;
          else
            ++j;
        }
      } else if (Character.isJavaIdentifierStart(c))
        do ++j; while (j < l && Character.isJavaIdentifierPart(s.charAt(j)));
      else if (Character.isDigit(c)) {
        do ++j; while (j < l && Character.isDigit(s.charAt(j)));
        if (j < l && s.charAt(j) == 'L') ++j; // Long constants like 1L
      } else
        ++j;
        
      String t = quickSubstring(s, i, j);
      i = j;
      return t;
    }
  };
}



static String actualMCDollar() {
  return actualMC().getName() + "$";
}


static Object _defaultClassFinder_value = defaultDefaultClassFinder();

static Object _defaultClassFinder() {
  return _defaultClassFinder_value;
}


static BigInteger parseBigInt(String s) {
  return new BigInteger(s);
}


static float parseFloat(String s) {
  return Float.parseFloat(s);
}


static boolean isJavaIdentifier(String s) {
  if (empty(s) || !Character.isJavaIdentifierStart(s.charAt(0)))
    return false;
  for (int i = 1; i < s.length(); i++)
    if (!Character.isJavaIdentifierPart(s.charAt(i)))
      return false;
  return true;
}


static String trivialUnquote(String s) {
  return dropPrefixSuffix("\"", s);
}


static short[] shortArrayFromBytes(byte[] a) {
  return shortArrayFromBytes(a, 0, l(a));
}

static short[] shortArrayFromBytes(byte[] a, int from, int to) {
  short[] b = new short[(to-from)/2];
  for (int i = 0; i < b.length; i++)
    b[i] = shortFromBytes(a, from+i*2);
  return b;
}


static byte[] hexToBytes(String s) {
  if (odd(l(s))) throw fail("Hex string has odd length: " + quote(shorten(10, s)));
  int n = l(s) / 2;
  byte[] bytes = new byte[n];
  for (int i = 0; i < n; i++) {
    int a = parseHexChar(s.charAt(i*2));
    int b = parseHexChar(s.charAt(i*2+1));
    if (a < 0 || b < 0)
      throw fail("Bad hex byte: " + quote(substring(s, i*2, i*2+2)) + " at " + i*2 + "/" + l(s));
    bytes[i] = (byte) ((a << 4) | b);
  }
  return bytes;
}


static long[] longArrayFromBytes(byte[] a) {
  return longArrayFromBytes(a, 0, l(a));
}

static long[] longArrayFromBytes(byte[] a, int from, int to) {
  long[] b = new long[(to-from)/8];
  for (int i = 0; i < b.length; i++)
    b[i] = longFromBytes_bigEndian(a, from+i*8);
  return b;
}


static HashMap<String, Class> findClass_fullName_cache = new HashMap();

// returns null on not found
// this is the simple version that is not case-tolerant
static Class findClass_fullName(String name) {
  synchronized(findClass_fullName_cache) {
    if (findClass_fullName_cache.containsKey(name))
      return findClass_fullName_cache.get(name);
      
    Class c;
    try {
      c = Class.forName(name);
    } catch (ClassNotFoundException e) {
      c = null;
    }
    findClass_fullName_cache.put(name, c);
    return c;
  }
}


static String unquoteUsingCharArray(String s, char[] buf) {
  if (s == null) return null;
  if (startsWith(s, '[')) {
    int i = 1;
    while (i < s.length() && s.charAt(i) == '=') ++i;
    if (i < s.length() && s.charAt(i) == '[') {
      String m = s.substring(1, i);
      if (s.endsWith("]" + m + "]"))
        return s.substring(i+1, s.length()-i-1);
    }
  }
  
  if (s.length() > 1) {
    char c = s.charAt(0);
    if (c == '\"' || c == '\'') {
      int l = endsWith(s, c) ? s.length()-1 : s.length();
      if (l > buf.length) return unquote(s); // fallback
      int n = 0;
  
      for (int i = 1; i < l; i++) {
        char ch = s.charAt(i);
        if (ch == '\\') {
          char nextChar = (i == l - 1) ? '\\' : s.charAt(i + 1);
          // Octal escape?
          if (nextChar >= '0' && nextChar <= '7') {
              String code = "" + nextChar;
              i++;
              if ((i < l - 1) && s.charAt(i + 1) >= '0'
                      && s.charAt(i + 1) <= '7') {
                  code += s.charAt(i + 1);
                  i++;
                  if ((i < l - 1) && s.charAt(i + 1) >= '0'
                          && s.charAt(i + 1) <= '7') {
                      code += s.charAt(i + 1);
                      i++;
                  }
              }
              buf[n++] = (char) Integer.parseInt(code, 8);
              continue;
          }
          switch (nextChar) {
          case '\"': ch = '\"'; break;
          case '\\': ch = '\\'; break;
          case 'b': ch = '\b'; break;
          case 'f': ch = '\f'; break;
          case 'n': ch = '\n'; break;
          case 'r': ch = '\r'; break;
          case 't': ch = '\t'; break;
          case '\'': ch = '\''; break;
          // Hex Unicode: u????
          case 'u':
              if (i >= l - 5) {
                  ch = 'u';
                  break;
              }
              int code = Integer.parseInt(
                      "" + s.charAt(i + 2) + s.charAt(i + 3)
                         + s.charAt(i + 4) + s.charAt(i + 5), 16);
              char[] x = Character.toChars(code);
              int lx = x.length;
              for (int j = 0; j < lx; j++)
                buf[n++] = x[j];
              i += 5;
              continue;
          default:
            ch = nextChar; // added by Stefan
          }
          i++;
        }
        buf[n++] = ch;
      }
      return new String(buf, 0, n);
    }
  }
    
  return s; // not quoted - return original
}


static boolean structure_isMarker(String s, int i, int j) {
  if (i >= j) return false;
  if (s.charAt(i) != 'm') return false;
  ++i;
  while (i < j) {
    char c = s.charAt(i);
    if (c < '0' || c > '9') return false;
    ++i;
  }
  return true;
}


static String internIfLongerThan(String s, int l) {
  return s == null ? null : l(s) >= l ? intern(s) : s;
}


static char unquoteCharacter(String s) {
  assertTrue(s.startsWith("'") && s.length() > 1);
  return unquote("\"" + s.substring(1, s.endsWith("'") ? s.length()-1 : s.length()) + "\"").charAt(0);
}


static boolean isLongConstant(String s) {
  if (!s.endsWith("L")) return false;
  s = s.substring(0, l(s)-1);
  return isInteger(s);
}


static boolean warn_on = true;
static ThreadLocal<List<String>> warn_warnings = new ThreadLocal();

static void warn(String s) {
  if (warn_on)
    print("Warning: " + s);
}

static void warn(String s, List<String> warnings) {
  warn(s);
  if (warnings != null)
    warnings.add(s);
  addToCollection(warn_warnings.get(), s);
}


static <A> TreeMap<String, A> ciMap() {
  return caseInsensitiveMap();
}


static List parseList(String s) {
  return (List) safeUnstructure(s);
}


static <A> List<A> synchroLinkedList() {
  return synchroList(new LinkedList<A>());
}



static <A, B> NavigableMap<A, B> synchroNavigableMap(NavigableMap<A, B> map) {
  
  
    return Collections.synchronizedNavigableMap(map);
  
}


static <A, B> SortedMap<A, B> synchroSortedMap(SortedMap<A, B> map) {
  
  
    return Collections.synchronizedSortedMap(map);
  
}


static boolean[] boolArrayFromBytes(byte[] a, int n) {
  boolean[] b = new boolean[n];
  int m = min(n, l(a)*8);
  for (int i = 0; i < m; i++)
    b[i] = (a[i/8] & 1 << (i & 7)) != 0;
  return b;
}


static String assertIdentifier(String s) {
  return assertIsIdentifier(s);
}

static String assertIdentifier(String msg, String s) {
  return assertIsIdentifier(msg, s);
}


// Use like this: printVars_str(+x, +y);
// Or: printVars("bla", +x);
// Or: printVars bla(+x);
static void printVars_str(Object... params) {
  print(renderVars_str(params));
}


static <A> Constructor nuStubInnerObject_findConstructor(Class<A> c) { return nuStubInnerObject_findConstructor(c, null); }
static <A> Constructor nuStubInnerObject_findConstructor(Class<A> c, Object classFinder) { try {
  Class outerType = getOuterClass(c, classFinder);
  Constructor m = c.getDeclaredConstructor(outerType);
  makeAccessible(m);
  return m;
} catch (Exception __e) { throw rethrow(__e); } }


static Map<Class, Constructor> nuEmptyObject_cache = newDangerousWeakHashMap();

static <A> A nuEmptyObject(Class<A> c) { try {
  Constructor ctr;
  
  synchronized(nuEmptyObject_cache) {
    ctr = nuEmptyObject_cache.get(c);
    if (ctr == null) {
      nuEmptyObject_cache.put(c, ctr = nuEmptyObject_findConstructor(c));
      makeAccessible(ctr);
    }
  }

  try {
    return (A) ctr.newInstance();
  } catch (InstantiationException e) {
    if (empty(e.getMessage()))
      if ((c.getModifiers() & Modifier.ABSTRACT) != 0)
        throw fail("Can't instantiate abstract class " + className(c), e);
      else
        throw fail("Can't instantiate " + className(c), e);  
    else throw rethrow(e);
  }
} catch (Exception __e) { throw rethrow(__e); } }

static Constructor nuEmptyObject_findConstructor(Class c) {
  for (Constructor m : getDeclaredConstructors_cached(c))
    if (m.getParameterTypes().length == 0)
      return m;
  throw fail("No default constructor declared in " + c.getName());
}



static void setOptAllDyn_pcall(DynamicObject o, Map<String, Object> fields) {
  if (fields == null || o == null) return;
  HashMap<String, Field> fieldMap = instanceFieldsMap(o);
  for (Map.Entry<String, Object> e : fields.entrySet()) { try {
    String field = e.getKey();
    Object val = e.getValue();
    Field f = fieldMap.get(field);
    if (f != null)
      smartSet(f, o, val);
    else {
      dynamicObject_setRawFieldValue(o, intern(field), val);
      
    }
  } catch (Throwable __e) { pcallFail(__e); }}
}


static void setOptAll_pcall(Object o, Map<String, Object> fields) {
  if (fields == null) return;
  for (String field : keys(fields))
    try { setOpt(o, field, fields.get(field)); } catch (Throwable __e) { print(exceptionToStringShort(__e)); }
}

static void setOptAll_pcall(Object o, Object... values) {
  //values = expandParams(c.getClass(), values);
  warnIfOddCount(values);
  for (int i = 0; i+1 < l(values); i += 2) {
    String field = (String) values[i];
    Object value = values[i+1];
    try { setOpt(o, field, value); } catch (Throwable __e) { print(exceptionToStringShort(__e)); }
  }
}


static void fixOuterRefs(Object o) { try {
  if (o == null) return;
  Field[] l = thisDollarOneFields(o.getClass());
  if (l.length <= 1) return;
  Object father = null;
  for (Field f : l) {
    father = f.get(o);
    if (father != null) break;
  }
  if (father == null) return;
  for (Field f : l)
    f.set(o, father);
} catch (Exception __e) { throw rethrow(__e); } }


static void setDynObjectValue(DynamicObject o, String field, Object value) {
  dynamicObject_setRawFieldValue(o, field, value);
}


static String intern(String s) {
  return fastIntern(s);
}


static void pcallOpt_noArgs(Object o, String method) {
  try { callOpt_noArgs(o, method); } catch (Throwable __e) { pcallFail(__e); }
}


  static RuntimeException todo() {
    throw new RuntimeException("TODO");
  }
  
  static RuntimeException todo(Object msg) {
    throw new RuntimeException("TODO: " + msg);
  }


static Object newMultiDimensionalOuterArray(Class elementType, int dimensions, int length) {
  int[] dims = new int[dimensions];
  dims[0] = length;
  return Array.newInstance(elementType, dims);
}


static int[] toIntArray(Collection<Integer> l) {
  int[] a = new int[l(l)];
  int i = 0;
  if (a.length != 0) for (int x : l)
    a[i++] = x;
  return a;
}


static double[] toDoubleArray(Collection<Double> l) {
  double[] a = new double[l(l)];
  int i = 0;
  if (a.length != 0) for (double x : l)
    a[i++] = x;
  return a;
}




  static double[] toDoubleArray(float... l) {
    double[] a = new double[l(l)];
    for (int i = 0; i < a.length; i++)
      a[i] = l[i];
    return a;
  }


  static double[] toDoubleArray(int... l) {
    double[] a = new double[l(l)];
    for (int i = 0; i < a.length; i++)
      a[i] = l[i];
    return a;
  }




static double[] toDoubleArray(IDoubleBuffer b) {
  int n = l(b);
  double[] a = new double[n];
  for (int i = 0; i < n; i++)
    a[i] = b.get(i);
  return a;
}



static String dropPrefix(String prefix, String s) {
  return s == null ? null : s.startsWith(prefix) ? s.substring(l(prefix)) : s;
}


static void dynamicObject_setRawFieldValue(DynamicObject o, Object key, Object value) {
  if (o == null) return;
  
  // double sync, but should be OK here because of locking order o > o.fieldValues
  synchronized(o) {
    o.fieldValues = syncMapPut2_createLinkedHashMap((LinkedHashMap) o.fieldValues, key, value);
  }
}


static TreeSet<String> ciSet() {
  return caseInsensitiveSet();
}


// DIFFERENCES to jfind: always ignores case, doesn't recognize <id> etc
// You probably want jmatch2

static boolean jmatch(String pat, String s) {
  return jmatch(pat, s, null);
}

static boolean jmatch(String pat, String s, Matches matches) {
  if (s == null) return false;
  return jmatch(pat, javaTok(s), matches);
}

static boolean jmatch(String pat, List<String> toks) {
  return jmatch(pat, toks, null);
}

static boolean jmatch(String pat, List<String> toks, Matches matches) {
  List<String> tokpat = javaTok(pat);
  String[] m = match2(tokpat, toks);
  //print(structure(tokpat) + " on " + structure(toks) + " => " + structure(m));
  if (m == null)
    return false;
  else {
    if (matches != null) matches.m = m;
    return true;
  }
}


static Object nuObject(String className, Object... args) { try {
  return nuObject(classForName(className), args);
} catch (Exception __e) { throw rethrow(__e); } }

// too ambiguous - maybe need to fix some callers
/*static O nuObject(O realm, S className, O... args) {
  ret nuObject(_getClass(realm, className), args);
}*/

static <A> A nuObject(Class<A> c, Object... args) { try {
  if (args == null || args.length == 0) return nuObjectWithoutArguments(c); // cached!
  
  Constructor m = nuObject_findConstructor(c, args);
  makeAccessible(m);
  return (A) m.newInstance(args);
} catch (Exception __e) { throw rethrow(__e); } }

static Constructor nuObject_findConstructor(Class c, Object... args) {
  for (Constructor m : getDeclaredConstructors_cached(c)) {
    if (!nuObject_checkArgs(m.getParameterTypes(), args, false))
      continue;
    return m;
  }
  throw fail("Constructor " + c.getName() + getClasses(args) + " not found"
    + (args.length == 0 && (c.getModifiers() & java.lang.reflect.Modifier.STATIC) == 0 ? " - hint: it's a non-static class!" : ""));
}

 static boolean nuObject_checkArgs(Class[] types, Object[] args, boolean debug) {
    if (types.length != args.length) {
      if (debug)
        System.out.println("Bad parameter length: " + args.length + " vs " + types.length);
      return false;
    }
    for (int i = 0; i < types.length; i++)
      if (!(args[i] == null || isInstanceX(types[i], args[i]))) {
        if (debug)
          System.out.println("Bad parameter " + i + ": " + args[i] + " vs " + types[i]);
        return false;
      }
    return true;
  }


static <A> AutoCloseable tempSetTL(ThreadLocal<A> tl, A a) {
  return tempSetThreadLocal(tl, a);
}


static <A> AutoCloseable tempSetTL(BetterThreadLocal<A> tl, A a) {
  return tempSetThreadLocalIfNecessary(tl, a);
}



static ThreadLocal<Boolean> DynamicObject_loading = or((ThreadLocal) get(getClass("x30_pkg.x30_util"), "DynamicObject_loading"), new ThreadLocal());

static ThreadLocal<Boolean> dynamicObjectIsLoading_threadLocal() { 
  return DynamicObject_loading;
}


static TimeZone localTimeZone() {
  return getTimeZone(standardTimeZone());
  // TimeZone.getDefault()?
}


static String[] drop(int n, String[] a) {
  n = Math.min(n, a.length);
  String[] b = new String[a.length-n];
  System.arraycopy(a, n, b, 0, b.length);
  return b;
}

static Object[] drop(int n, Object[] a) {
  n = Math.min(n, a.length);
  Object[] b = new Object[a.length-n];
  System.arraycopy(a, n, b, 0, b.length);
  return b;
}

static <A> List<A> drop(Iterable<A> c, Object pred) {
  return antiFilter(c, pred);
}



static List drop(Object pred, Iterable c) {
  return antiFilter(pred, c);
}



static List drop(Object pred, Object[] c) {
  return antiFilter(pred, c);
}



static <A, B extends A> List<B> drop(Iterable<B> c, F1<A, Boolean> pred) {
  return antiFilter(c, pred);
}



static <A, B extends A> List<B> drop(F1<A, Boolean> pred, Iterable<B> c) {
  return antiFilter(pred, c);
}



static <A, B extends A> List<B> drop(Iterable<B> c, IF1<A, Boolean> pred) {
  return antiFilter(c, pred);
}



static <A, B extends A> List<B> drop(IF1<A, Boolean> pred, Iterable<B> c) {
  return antiFilter(pred, c);
}


static boolean isDigit(char c) {
  return Character.isDigit(c);
}


static <A> A getWeakRef(Reference<A> ref) {
  return ref == null ? null : ref.get();
}


static x30_pkg.x30_util.BetterThreadLocal<WeakReference> dm_current_generic_tl;

static x30_pkg.x30_util.BetterThreadLocal<WeakReference> dm_current_generic_tl() {
  if (dm_current_generic_tl == null)
    dm_current_generic_tl = vm_generalMap_getOrCreate("currentModule", () -> new x30_pkg.x30_util.BetterThreadLocal());
  return dm_current_generic_tl;
}


static ThreadLocal<Random> customRandomizerForThisThread_tl = new ThreadLocal();

static ThreadLocal<Random> customRandomizerForThisThread_tl() {
  return customRandomizerForThisThread_tl;
}


static <A, B> Map<A, B> newWeakMap() {
  return newWeakHashMap();
}


static <A> WeakReference<A> newWeakReference(A a) {
  return a == null ? null : new WeakReference(a);
}




static Integer boxed(int i) { return i; }
static Long boxed(long l) { return l; }


static <A> A[] arrayOfSameType(A[] a, int n) {
  return newObjectArrayOfSameType(a, n);
}


static <A> ArrayList<A> litlist(A... a) {
  ArrayList l = new ArrayList(a.length);
  for (A x : a) l.add(x);
  return l;
}


static String collapseWord(String s) {
  if (s == null) return "";
  StringBuilder buf = new StringBuilder();
  for (int i = 0; i < l(s); i++)
    if (i == 0 || !charactersEqualIC(s.charAt(i), s.charAt(i-1)))
      buf.append(s.charAt(i));
  return buf.toString();
}


static List<String> toLowerCase(List<String> strings) {
  List<String> x = new ArrayList();
  for (String s : strings)
    x.add(s.toLowerCase());
  return x;
}

static String[] toLowerCase(String[] strings) {
  String[] x = new String[l(strings)];
  for (int i = 0; i < l(strings); i++)
    x[i] = strings[i].toLowerCase();
  return x;
}

static String toLowerCase(String s) {
  return s == null ? "" : s.toLowerCase();
}


static String firstWord2(String s) {
  s = xltrim(s);
  if (empty(s)) return "";
  if (isLetterOrDigit(first(s)))
    return takeCharsWhile(__43 -> isLetterOrDigit(__43), s);
  else return "" + first(s);
}


static Object[] mapToObjectArray(Map map) {
  List l = new ArrayList();
  for (Object o : keys(map)) {
    l.add(o);
    l.add(map.get(o));
  }
  return toObjectArray(l);
}

static Object[] mapToObjectArray(Object f, Collection l) {
  int n = l(l);
  Object[] array = new Object[n];
  if (n != 0) {
    Iterator it = iterator(l);
    for (int i = 0; i < n; i++)
      array[i] = callF(f, it.next());
  }
  return array;
}

static Object[] mapToObjectArray(Object f, Object[] l) {
  int n = l(l);
  Object[] array = new Object[n];
  for (int i = 0; i < n; i++)
    array[i] = callF(f, l[i]);
  return array;
}

static <A> Object[] mapToObjectArray(Collection<A> l, IF1<A, Object> f) {
  return mapToObjectArray(f, l);
}

static <A> Object[] mapToObjectArray(A[] l, IF1<A, Object> f) {
  return mapToObjectArray(f, l);
}

static <A> Object[] mapToObjectArray(IF1<A, Object> f, A[] l) {
  int n = l(l);
  Object[] array = new Object[n];
  for (int i = 0; i < n; i++)
    array[i] = f.get(l[i]);
  return array;
}

static <A> Object[] mapToObjectArray(IF1<A, Object> f, Collection<A> l) {
  int n = l(l);
  Object[] array = new Object[n];
  if (n != 0) {
    Iterator it = iterator(l);
    for (int i = 0; i < n; i++)
      array[i] = callF(f, it.next());
  }
  return array;
}


// this should be on by default now I think, but it may break
// legacy code...
static ThreadLocal<Boolean> htmlencode_forParams_useV2 = new ThreadLocal();

static String htmlencode_forParams(String s) {
  if (s == null) return "";
  if (isTrue(htmlencode_forParams_useV2.get()))
    return htmlencode_forParams_v2(s);
    
  StringBuilder out = new StringBuilder(Math.max(16, s.length()));
  for (int i = 0; i < s.length(); i++) {
      char c = s.charAt(i);
      if (c > 127 || c == '"' || c == '<' || c == '>') {
          out.append("&#");
          out.append((int) c);
          out.append(';');
      } else
          out.append(c);
  }
  return out.toString();
}


static String formatSnippetID(String id) {
  return "#" + parseSnippetID(id);
}

static String formatSnippetID(long id) {
  return "#" + id;
}


  public static boolean isSnippetID(String s) {
    try {
      parseSnippetID(s);
      return true;
    } catch (RuntimeException e) {
      return false;
    }
  }


public static long parseSnippetID(String snippetID) {
  long id = Long.parseLong(shortenSnippetID(snippetID));
  if (id == 0) throw fail("0 is not a snippet ID");
  return id;
}


static String _userHome;
static String userHome() {
  if (_userHome == null)
    return actualUserHome();
  return _userHome;
}

static File userHome(String path) {
  return new File(userDir(), path);
}


static String quickSubstring(String s, int i, int j) {
  if (i >= j) return "";
  return s.substring(i, j);
}


static Class actualMC() {
  return or((Class) realMC(), mc());
}


static Object defaultDefaultClassFinder() {
  return new F1<String, Class>() {
    public Class get(String name) {
      // Fix some buggy concepts files out there
      name = replacePrefix("main$main$", "main$", name);
      
      Class c = get2(name);
      
      return c;
    }
      
    Class get2(String name) {
      // special invocation to find main class irrelevant of name
      if (eq(name, "<main>")) return mc();
      
      { Class c = findClass_fullName(name); if (c != null) return c; }
      
      if (startsWithAny(name, "loadableUtils.utils$", "main$", mcDollar()))
        for (String pkg : ll("loadableUtils.utils$", mcDollar())) {
          String newName = pkg + afterDollar(name);
          
          { Class c = findClass_fullName(newName); if (c != null) return c; }
        }
      return null;
    }
  };
}


static String dropPrefixSuffix(String prefix, String s) { return dropPrefixSuffix(prefix, prefix, s); }
static String dropPrefixSuffix(String prefix, String suffix, String s) {
  return dropPrefix(prefix, dropSuffix(suffix, s));
}


static short shortFromBytes(byte[] a, int i) {
  return (short) (ubyteToInt(a[i]) << 8
    | ubyteToInt(a[i+1]));
}


static int shorten_default = 100;

static String shorten(CharSequence s) { return shorten(s, shorten_default); }

static String shorten(CharSequence s, int max) {
  return shorten(s, max, "...");
}

static String shorten(CharSequence s, int max, String shortener) {
  if (s == null) return "";
  if (max < 0) return str(s);
  return s.length() <= max ? str(s) : subCharSequence(s, 0, min(s.length(), max-l(shortener))) + shortener;
}

static String shorten(int max, CharSequence s) { return shorten(s, max); }


static int parseHexChar(char c) {
  if (c >= '0' && c <= '9') return charDiff(c, '0');
  if (c >= 'a' && c <= 'f') return charDiff(c, 'a')+10;
  if (c >= 'A' && c <= 'F') return charDiff(c, 'A')+10;
  return -1;
}


static long longFromBytes_bigEndian(byte[] a, int i) {
  return twoIntsToLong_bigEndian(
    intFromBytes_bigEndian(a, i),
    intFromBytes_bigEndian(a, i+4));
}


static <A> boolean addToCollection(Collection<A> c, A a) {
  return c != null && c.add(a);
}


static <A> TreeMap<String, A> caseInsensitiveMap() {
  return new TreeMap(caseInsensitiveComparator());
}


static Object safeUnstructure(String s) {
  return unstructure(s, true);
}

static Object safeUnstructure(File f) {
  return safeUnstructureGZFile(f);
}


static String assertIsIdentifier(String s) {
  if (!isIdentifier(s))
    throw fail("Not an identifier: " + quote(s));
  return s;
}

static String assertIsIdentifier(String msg, String s) {
  if (!isIdentifier(s))
    throw fail(msg + " - Not an identifier: " + quote(s));
  return s;
}


// Use like this: renderVars(+x, +y)
// Or like this: renderVars("bla", +x, +y)
static String renderVars_str(Object... params) {
  List<String> l = new ArrayList();
  int i = 0;
  if (odd(l(params))) {
    l.add(strOrNull(first(params)));
    ++i;
  }
  for (; i+1 < l(params); i += 2)
    l.add(params[i] + "=" + params[i+1]);
  return trim(joinWithComma(l));
}


static Class getOuterClass(Class c) { return getOuterClass(c, null); }
static Class getOuterClass(Class c, Object classFinder) { try {
  String s = c.getName();
  int i = s.lastIndexOf('$');
  String name = substring(s, 0, i);
  return classForName(name, classFinder);
} catch (Exception __e) { throw rethrow(__e); } }

static Class getOuterClass(Object o) { return getOuterClass(o, null); }
static Class getOuterClass(Object o, Object classFinder) {
  return getOuterClass(_getClass(o), classFinder);
}




// TODO: convert to regularly cleared normal map
static Map<Class, Constructor[]> getDeclaredConstructors_cached_cache = newDangerousWeakHashMap();

static Constructor[] getDeclaredConstructors_cached(Class c) {
  Constructor[] ctors;
  synchronized(getDeclaredConstructors_cached_cache) {
    ctors = getDeclaredConstructors_cached_cache.get(c);
    if (ctors == null) {
      getDeclaredConstructors_cached_cache.put(c, ctors = c.getDeclaredConstructors());
      for (var ctor : ctors)
        makeAccessible(ctor);
    }
  }
  return ctors;
}


static HashMap<String, Field> instanceFieldsMap(Object o) {
  return (HashMap) getOpt_getFieldMap(o);
}



static Field setOpt_findField(Class c, String field) {
  HashMap<String, Field> map;
  synchronized(getOpt_cache) {
    map = getOpt_cache.get(c);
    if (map == null)
      map = getOpt_makeCache(c);
  }
  return map.get(field);
}

static void setOpt(Object o, String field, Object value) { try {
  if (o == null) return;
  
  
  
  Class c = o.getClass();
  HashMap<String, Field> map;
  
  if (getOpt_cache == null)
    map = getOpt_makeCache(c); // in class init
  else synchronized(getOpt_cache) {
    map = getOpt_cache.get(c);
    if (map == null)
      map = getOpt_makeCache(c);
  }
  
  if (map == getOpt_special) {
    if (o instanceof Class) {
      setOpt((Class) o, field, value);
      return;
    }
    
    // It's probably a subclass of Map. Use raw method. TODO: huh?
    setOpt_raw(o, field, value);
    return;
  }
  
  Field f = map.get(field);
  
  if (f != null)
    { smartSet(f, o, value); return; } // possible improvement: skip setAccessible
  
    if (o instanceof DynamicObject)
      { setDyn(((DynamicObject) o), field, value); return; }
  
  if (o instanceof IMeta)
    setDyn(((IMeta) o), field, value);
} catch (Exception __e) { throw rethrow(__e); } }

static void setOpt(Class c, String field, Object value) {
  if (c == null) return;
  try {
    Field f = setOpt_findStaticField(c, field); // TODO: optimize
    if (f != null)
      smartSet(f, null, value);
  } catch (Exception e) {
    throw new RuntimeException(e);
  }
}
  
static Field setOpt_findStaticField(Class<?> c, String field) {
  Class _c = c;
  do {
    for (Field f : _c.getDeclaredFields())
      if (f.getName().equals(field) && (f.getModifiers() & java.lang.reflect.Modifier.STATIC) != 0) {
        makeAccessible(f);
        return f;
      }
    _c = _c.getSuperclass();
  } while (_c != null);
  return null;
}


static String exceptionToStringShort(Throwable e) {
  try {
    lastException(e);
    e = getInnerException(e);
    String msg = hideCredentials(unnull(e.getMessage()));
    if (msg.indexOf("Error") < 0 && msg.indexOf("Exception") < 0)
      return baseClassName(e) + prependIfNempty(": ", msg);
    else
      return msg;
  } catch (Throwable _e) { printStackTrace(_e);
    return "Error in exceptionToStringShort";
  }
}


static void warnIfOddCount(Object... list) {
  if (odd(l(list)))
    printStackTrace("Odd list size: " + list);
}




static Map<Class, Field[]> thisDollarOneFields_cache = newDangerousWeakHashMap();

static Field[] thisDollarOneFields(Class c) {
  synchronized(thisDollarOneFields_cache) {
    Field[] l = thisDollarOneFields_cache.get(c);
    if (l == null)
      thisDollarOneFields_cache.put(c, l = thisDollarOneFields_uncached(c));
    return l;
  }
}

static Field[] thisDollarOneFields_uncached(Class c) {
  List<Field> fields = new ArrayList();
  do {
    for (Field f : c.getDeclaredFields())
      if (f.getName().startsWith("this$"))
        fields.add(makeAccessible(f));
    c = c.getSuperclass();
  } while (c != null);
  return toArray(new Field[l(fields)], fields);
}




static Method fastIntern_method;

static String fastIntern(String s) { try {
  if (s == null) return null;
  if (fastIntern_method == null) {
    fastIntern_method = findMethodNamed(javax(), "internPerProgram");
    if (fastIntern_method == null) upgradeJavaXAndRestart();
  }
    
  return (String) fastIntern_method.invoke(null, s);
} catch (Exception __e) { throw rethrow(__e); } }


static Map<Class, HashMap<String, Method>> callOpt_noArgs_cache = newDangerousWeakHashMap();

static Object callOpt_noArgs(Object o, String method) { try {
  if (o == null) return null;
  if (o instanceof Class)
    return callOpt(o, method); // not optimized
  
  Class c = o.getClass();
  HashMap<String, Method> map;
  synchronized(callOpt_noArgs_cache) {
    map = callOpt_noArgs_cache.get(c);
    if (map == null)
      map = callOpt_noArgs_makeCache(c);
  }

  Method m = map.get(method);
  return m != null ? m.invoke(o) : null;
} catch (Exception __e) { throw rethrow(__e); } }

// used internally - we are in synchronized block
static HashMap<String, Method> callOpt_noArgs_makeCache(Class c) {
  HashMap<String, Method> map = new HashMap();
  Class _c = c;
  do {
    for (Method m : c.getDeclaredMethods())
      if (m.getParameterTypes().length == 0 
        && !reflection_isForbiddenMethod(m)) {
        makeAccessible(m);
        String name = m.getName();
        if (!map.containsKey(name))
          map.put(name, m);
      }
    _c = _c.getSuperclass();
  } while (_c != null);
  callOpt_noArgs_cache.put(c, map);
  return map;
}


static <A, B> LinkedHashMap<A, B> syncMapPut2_createLinkedHashMap(LinkedHashMap<A, B> map, A key, B value) {
  if (key != null)
    if (value != null) {
      if (map == null) map = new LinkedHashMap();
      synchronized(collectionMutex(map)) { map.put(key, value); }
    } else if (map != null) synchronized(collectionMutex(map)) { map.remove(key); }
  return map;
}


// TODO: extended multi-line strings

static int javaTok_n, javaTok_elements;
static boolean javaTok_opt = false;

static List<String> javaTok(String s) {
  ++javaTok_n;
  ArrayList<String> tok = new ArrayList();
  int l = s == null ? 0 : s.length();
  
  int i = 0;
  while (i < l) {
    int j = i;
    char c, d;
    
        // scan for whitespace
        while (j < l) {
          c = s.charAt(j);
          d = j+1 >= l ? '\0' : s.charAt(j+1);
          if (c == ' ' || c == '\t' || c == '\r' || c == '\n')
            ++j;
          else if (c == '/' && d == '*') {
            do ++j; while (j < l && !regionMatches(s, j, "*/"));
            j = Math.min(j+2, l);
          } else if (c == '/' && d == '/') {
            do ++j; while (j < l && "\r\n".indexOf(s.charAt(j)) < 0);
          } else
            break;
        }
        
        tok.add(javaTok_substringN(s, i, j));
        i = j;
        if (i >= l) break;
        c = s.charAt(i);
        d = i+1 >= l ? '\0' : s.charAt(i+1);
    
        // scan for non-whitespace
        
        // Special JavaX syntax: 'identifier
        if (c == '\'' && Character.isJavaIdentifierStart(d) && i+2 < l && "'\\".indexOf(s.charAt(i+2)) < 0) {
          j += 2;
          while (j < l && Character.isJavaIdentifierPart(s.charAt(j)))
            ++j;
        } else if (c == '\'' || c == '"') {
          char opener = c;
          ++j;
          while (j < l) {
            int c2 = s.charAt(j);
            if (c2 == opener || c2 == '\n' && opener == '\'') { // allow multi-line strings, but not for '
              ++j;
              break;
            } else if (c2 == '\\' && j+1 < l)
              j += 2;
            else
              ++j;
          }
        } else if (Character.isJavaIdentifierStart(c))
          do ++j; while (j < l && (Character.isJavaIdentifierPart(s.charAt(j)) || s.charAt(j) == '\'')); // for stuff like "don't"
        else if (Character.isDigit(c)) {
          do ++j; while (j < l && Character.isDigit(s.charAt(j)));
          if (j < l && s.charAt(j) == 'L') ++j; // Long constants like 1L
        } else if (c == '[' && d == '[') {
          do ++j; while (j < l && !regionMatches(s, j, "]]"));
          j = Math.min(j+2, l);
        } else if (c == '[' && d == '=' && i+2 < l && s.charAt(i+2) == '[') {
          do ++j; while (j+2 < l && !regionMatches(s, j, "]=]"));
          j = Math.min(j+3, l);
        } else
          ++j;
      
    tok.add(javaTok_substringC(s, i, j));
    i = j;
  }
  
  if ((tok.size() % 2) == 0) tok.add("");
  javaTok_elements += tok.size();
  return tok;
}

static List<String> javaTok(List<String> tok) {
  return javaTokWithExisting(join(tok), tok);
}


// match2 matches multiple "*" (matches a single token) wildcards and zero or one "..." wildcards (matches multiple tokens)

static String[] match2(List<String> pat, List<String> tok) {
  // standard case (no ...)
  int i = pat.indexOf("...");
  if (i < 0) return match2_match(pat, tok);
  
  pat = new ArrayList<String>(pat); // We're modifying it, so copy first
  pat.set(i, "*");
  while (pat.size() < tok.size()) {
    pat.add(i, "*");
    pat.add(i+1, ""); // doesn't matter
  }
  
  return match2_match(pat, tok);
}

static String[] match2_match(List<String> pat, List<String> tok) {
  List<String> result = new ArrayList<String>();
  if (pat.size() != tok.size()) {
    
    return null;
  }
  for (int i = 1; i < pat.size(); i += 2) {
    String p = pat.get(i), t = tok.get(i);
    
    if (eq(p, "*"))
      result.add(t);
    else if (!equalsIgnoreCase(unquote(p), unquote(t))) // bold change - match quoted and unquoted now. TODO: should remove
      return null;
  }
  return result.toArray(new String[result.size()]);
}



static Map<String, Class> classForName_cache = synchroHashMap();

static Class classForName(String name) { return classForName(name, null); }
static Class classForName(String name, Object classFinder) {
  // first clause is when we're in class init
  if (classForName_cache == null || classFinder != null)
    return classForName_uncached(name, classFinder);
  Class c = classForName_cache.get(name);
  if (c == null)
    classForName_cache.put(name, c = classForName_uncached(name, null));
  return c;
}

static Class classForName_uncached(String name, Object classFinder) { try {
  if (classFinder != null) return (Class) callF(classFinder, name);
  return Class.forName(name);
} catch (Exception __e) { throw rethrow(__e); } }


static Map<Class, Constructor> nuObjectWithoutArguments_cache = newDangerousWeakHashMap();

static Object nuObjectWithoutArguments(String className) { try {
  return nuObjectWithoutArguments(classForName(className));
} catch (Exception __e) { throw rethrow(__e); } }

static <A> A nuObjectWithoutArguments(Class<A> c) { try {
  if (nuObjectWithoutArguments_cache == null)
    // in class init
    return (A) nuObjectWithoutArguments_findConstructor(c).newInstance();
    
  Constructor m = nuObjectWithoutArguments_cache.get(c);
  if (m == null)
    nuObjectWithoutArguments_cache.put(c, m = nuObjectWithoutArguments_findConstructor(c));
  return (A) m.newInstance();
} catch (Exception __e) { throw rethrow(__e); } }

static Constructor nuObjectWithoutArguments_findConstructor(Class c) {
  for (Constructor m : getDeclaredConstructors_cached(c))
    if (empty(m.getParameterTypes())) {
      makeAccessible(m);
      return m;
    }
  throw fail("No default constructor found in " + c.getName());
}



static <A> AutoCloseable tempSetThreadLocalIfNecessary(ThreadLocal<A> tl, A a) {
  if (tl == null) return null;
  A prev = tl.get();
  if (eq(prev, a)) return null;
  tl.set(a);
  return new AutoCloseable() { public String toString() { return "tl.set(prev);"; } public void close() throws Exception { tl.set(prev); }};
}


static <A> AutoCloseable tempSetThreadLocalIfNecessary(BetterThreadLocal<A> tl, A a) {
  if (tl == null) return null;
  A prev = tl.get();
  if (eq(prev, a)) return null;
  tl.set(a);
  return new AutoCloseable() { public String toString() { return "tl.set(prev);"; } public void close() throws Exception { tl.set(prev); }};
}





static TimeZone getTimeZone(String name) {
  return TimeZone.getTimeZone(name);
}


static String standardTimeZone_name = "Europe/Berlin";

static String standardTimeZone() {
  return standardTimeZone_name;
}


static <A> List<A> antiFilter(Iterable<A> c, Object pred) {
  if (pred instanceof F1) return antiFilter(c, (F1<A, Boolean>) pred);

  List x = new ArrayList();
  if (c != null) for (Object o : c)
    if (!isTrue(callF(pred, o)))
      x.add(o);
  return x;
}

static List antiFilter(Object pred, Iterable c) {
  return antiFilter(c, pred);
}

static List antiFilter(Object pred, Object[] c) {
  return antiFilter(pred, wrapArrayAsList(c));
}

static <A, B extends A> List<B> antiFilter(Iterable<B> c, F1<A, Boolean> pred) {
  List x = new ArrayList();
  if (c != null) for (B o : c)
    if (!pred.get(o).booleanValue())
      x.add(o);
  return x;
}

static <A, B extends A> List<B> antiFilter(F1<A, Boolean> pred, Iterable<B> c) {
  return antiFilter(c, pred);
}

static <A, B extends A> List<B> antiFilter(Iterable<B> c, IF1<A, Boolean> pred) {
  List x = new ArrayList();
  if (c != null) for (B o : c)
    if (!pred.get(o).booleanValue())
      x.add(o);
  return x;
}

static <A, B extends A> List<B> antiFilter(IF1<A, Boolean> pred, Iterable<B> c) {
  return antiFilter(c, pred);
}





static <A> A[] newObjectArrayOfSameType(A[] a) { return newObjectArrayOfSameType(a, a.length); }
static <A> A[] newObjectArrayOfSameType(A[] a, int n) {
  return (A[]) Array.newInstance(a.getClass().getComponentType(), n);
}


static boolean charactersEqualIC(char c1, char c2) {
  if (c1 == c2) return true;
  char u1 = Character.toUpperCase(c1);
  char u2 = Character.toUpperCase(c2);
  if (u1 == u2) return true;
  return Character.toLowerCase(u1) == Character.toLowerCase(u2);
}



static String xltrim(String s) {
  int i = 0, n = l(s);
  while (i < n && contains(" \t\r\n", s.charAt(i)))
    ++i;
  return substr(s, i);
}


static boolean isLetterOrDigit(char c) {
  return Character.isLetterOrDigit(c);
}


// pred: char -> bool
static String takeCharsWhile(String s, Object pred) {
  int i = 0;
  while (i < l(s) && isTrue(callF(pred, s.charAt(i)))) ++i;
  return substring(s, 0, i);
}

static String takeCharsWhile(IF1<Character, Boolean> f, String s) {
  return takeCharsWhile(s, f);
}


static String htmlencode_forParams_v2(String s) {
  if (s == null) return "";
  StringBuilder out = new StringBuilder(Math.max(16, s.length()));
  for (int i = 0; i < s.length(); i++) {
      char c = s.charAt(i);
      if (c > 127 || c == '"' || c == '<' || c == '>' || c == '&') {
          out.append("&#");
          out.append((int) c);
          out.append(';');
      } else
          out.append(c);
  }
  return out.toString();
}


static String shortenSnippetID(String snippetID) {
  if (snippetID.startsWith("#"))
    snippetID = snippetID.substring(1);
  String httpBlaBla = "http://tinybrain.de/";
  if (snippetID.startsWith(httpBlaBla))
    snippetID = snippetID.substring(httpBlaBla.length());
  return "" + parseLong(snippetID);
}


static String actualUserHome_value;
static String actualUserHome() {
  if (actualUserHome_value == null) {
    if (isAndroid())
      actualUserHome_value = "/storage/emulated/0/";
    else
      actualUserHome_value = System.getProperty("user.home");
  }
  return actualUserHome_value;
}

static File actualUserHome(String sub) {
  return newFile(new File(actualUserHome()), sub);
}


static File userDir() {
  return new File(userHome());
}

static File userDir(String path) {
  return new File(userHome(), path);
}


static Object realMC() {
  return getThreadLocal(realMC_tl());
}


static String replacePrefix(String prefix, String replacement, String s) {
  if (!startsWith(s, prefix)) return s;
  return replacement + substring(s, l(prefix));
}


static Object get2(Object o, String field1, String field2) {
  return get(get(o, field1), field2);
}


static boolean startsWithAny(String a, Collection<String> b) {
  for (String prefix : unnullForIteration(b))
    if (startsWith(a, prefix))
      return true;
  return false;
}

static boolean startsWithAny(String a, String... b) {
  if (b != null)
    for (String prefix : unnullForIteration(b))
      if (startsWith(a, prefix))
        return true;
  return false;
}


static boolean startsWithAny(String a, Collection<String> b, Matches m) {
  for (String prefix : unnullForIteration(b))
    if (startsWith(a, prefix, m))
      return true;
  return false;
}



static String mcDollar() {
  return mcName() + "$";
}


static String afterDollar(String s) {
  return substring(s, smartIndexOf(s, '$')+1);
}


static int ubyteToInt(byte b) {
  return b & 0x0FF;
}

static int ubyteToInt(char c) {
  return c & 0x0FF;
}


static CharSequence subCharSequence(CharSequence s, int x) {
  return subCharSequence(s, x, s == null ? 0 : s.length());
}

static CharSequence subCharSequence(CharSequence s, int x, int y) {
  if (s == null) return null;
  if (x < 0) x = 0;
  if (x >= s.length()) return "";
  if (y < x) y = x;
  if (y > s.length()) y = s.length();
  return s.subSequence(x, y);
}


static int charDiff(char a, char b) {
  return (int) a-(int) b;
}

static int charDiff(String a, char b) {
  return charDiff(stringToChar(a), b);
}


static long twoIntsToLong_bigEndian(int a, int b) {
  return twoIntsToLong(a, b);
}


static int intFromBytes_bigEndian(byte[] a, int i) {
  return intFromBytes(a, i);
}


static Object safeUnstructureGZFile(File f) { try {
  if (!fileExists(f)) return null;
  BufferedReader reader = utf8BufferedReader(gzInputStream(f));
  return unstructure_tok(javaTokC_noMLS_onReader(reader), true, null);
} catch (Exception __e) { throw rethrow(__e); } }


static boolean isIdentifier(String s) {
  return isJavaIdentifier(s);
}


// TODO: optimize (use getOpt_cache)
static void setOpt_raw(Object o, String field, Object value) { try {
  if (o == null) return;
  if (o instanceof Class) setOpt_raw((Class) o, field, value);
  else {
    Field f = setOpt_raw_findField(o.getClass(), field);
    if (f != null) {
      makeAccessible(f);
      smartSet(f, o, value);
    }
  }
} catch (Exception __e) { throw rethrow(__e); } }

static void setOpt_raw(Class c, String field, Object value) { try {
  if (c == null) return;
  Field f = setOpt_raw_findStaticField(c, field);
  if (f != null) {
    makeAccessible(f);
    smartSet(f, null, value);
  }
} catch (Exception __e) { throw rethrow(__e); } }
  
static Field setOpt_raw_findStaticField(Class<?> c, String field) {
  Class _c = c;
  do {
    for (Field f : _c.getDeclaredFields())
      if (f.getName().equals(field) && (f.getModifiers() & java.lang.reflect.Modifier.STATIC) != 0)
        return f;
    _c = _c.getSuperclass();
  } while (_c != null);
  return null;
}

static Field setOpt_raw_findField(Class<?> c, String field) {
  Class _c = c;
  do {
    for (Field f : _c.getDeclaredFields())
      if (f.getName().equals(field))
        return f;
    _c = _c.getSuperclass();
  } while (_c != null);
  return null;
}


static <A extends DynamicObject> A setDyn(A o, String key, Object value) {
  setDynObjectValue(o, key, value);
  return o;
}

static void setDyn(IMeta o, String key, Object value) {
  metaMapPut(o, key, value);
}


static Throwable getInnerException(Throwable e) {
  if (e == null) return null;
  while (e.getCause() != null)
    e = e.getCause();
  return e;
}

static Throwable getInnerException(Runnable r) {
  return getInnerException(getException(r));
}


static String baseClassName(String className) {
  return substring(className, className.lastIndexOf('.')+1);
}

static String baseClassName(Object o) {
  return baseClassName(getClassName(o));
}


static String prependIfNempty(String prefix, String s) {
  return empty(s) ? unnull(s) : prefix + s;
}


static void upgradeJavaXAndRestart() {
  
    run("#1001639");
    restart();
    sleep();
  
  
}


static boolean regionMatches(String a, int offsetA, String b, int offsetB, int len) {
  return a != null && b != null && a.regionMatches(offsetA, b, offsetB, len);
}

static boolean regionMatches(String a, int offsetA, String b) {
  return regionMatches(a, offsetA, b, 0, l(b));
}


static String javaTok_substringN(String s, int i, int j) {
  if (i == j) return "";
  if (j == i+1 && s.charAt(i) == ' ') return " ";
  return s.substring(i, j);
}


static List<String> javaTokWithExisting(String s, List<String> existing) {
  ++javaTok_n;
  int nExisting = javaTok_opt && existing != null ? existing.size() : 0;
  ArrayList<String> tok = existing != null ? new ArrayList(nExisting) : new ArrayList();
  int l = s.length();
  
  int i = 0, n = 0;
  while (i < l) {
    int j = i;
    char c, d;
    
    // scan for whitespace
    while (j < l) {
      c = s.charAt(j);
      d = j+1 >= l ? '\0' : s.charAt(j+1);
      if (c == ' ' || c == '\t' || c == '\r' || c == '\n')
        ++j;
      else if (c == '/' && d == '*') {
        do ++j; while (j < l && !s.substring(j, Math.min(j+2, l)).equals("*/"));
        j = Math.min(j+2, l);
      } else if (c == '/' && d == '/') {
        do ++j; while (j < l && "\r\n".indexOf(s.charAt(j)) < 0);
      } else
        break;
    }
    
    if (n < nExisting && javaTokWithExisting_isCopyable(existing.get(n), s, i, j))
      tok.add(existing.get(n));
    else
      tok.add(javaTok_substringN(s, i, j));
    ++n;
    i = j;
    if (i >= l) break;
    c = s.charAt(i);
    d = i+1 >= l ? '\0' : s.charAt(i+1);

    // scan for non-whitespace
    
    // Special JavaX syntax: 'identifier
    if (c == '\'' && Character.isJavaIdentifierStart(d) && i+2 < l && "'\\".indexOf(s.charAt(i+2)) < 0) {
      j += 2;
      while (j < l && Character.isJavaIdentifierPart(s.charAt(j)))
        ++j;
    } else if (c == '\'' || c == '"') {
      char opener = c;
      ++j;
      while (j < l) {
        if (s.charAt(j) == opener /*|| s.charAt(j) == '\n'*/) { // allow multi-line strings
          ++j;
          break;
        } else if (s.charAt(j) == '\\' && j+1 < l)
          j += 2;
        else
          ++j;
      }
    } else if (Character.isJavaIdentifierStart(c))
      do ++j; while (j < l && (Character.isJavaIdentifierPart(s.charAt(j)) || "'".indexOf(s.charAt(j)) >= 0)); // for stuff like "don't"
    else if (Character.isDigit(c)) {
      do ++j; while (j < l && Character.isDigit(s.charAt(j)));
      if (j < l && s.charAt(j) == 'L') ++j; // Long constants like 1L
    } else if (c == '[' && d == '[') {
      do ++j; while (j+1 < l && !s.substring(j, j+2).equals("]]"));
      j = Math.min(j+2, l);
    } else if (c == '[' && d == '=' && i+2 < l && s.charAt(i+2) == '[') {
      do ++j; while (j+2 < l && !s.substring(j, j+3).equals("]=]"));
      j = Math.min(j+3, l);
    } else
      ++j;
      
    if (n < nExisting && javaTokWithExisting_isCopyable(existing.get(n), s, i, j))
      tok.add(existing.get(n));
    else
      tok.add(javaTok_substringC(s, i, j));
    ++n;
    i = j;
  }
  
  if ((tok.size() % 2) == 0) tok.add("");
  javaTok_elements += tok.size();
  return tok;
}

static boolean javaTokWithExisting_isCopyable(String t, String s, int i, int j) {
  return t.length() == j-i
    && s.regionMatches(i, t, 0, j-i); // << could be left out, but that's brave
}


static boolean equalsIgnoreCase(String a, String b) {
  return eqic(a, b);
}

static boolean equalsIgnoreCase(char a, char b) {
  return eqic(a, b);
}




static String substr(String s, int x) {
  return substring(s, x);
}

static String substr(String s, int x, int y) {
  return substring(s, x, y);
}


static ThreadLocal realMC_tl_tl = new ThreadLocal();

static ThreadLocal realMC_tl() {
  return realMC_tl_tl;
}


static String mcName() {
  return mc().getName();
}


// returns l(s) if not found
static int smartIndexOf(String s, String sub, int i) {
  if (s == null) return 0;
  i = s.indexOf(sub, min(i, l(s)));
  return i >= 0 ? i : l(s);
}

static int smartIndexOf(String s, int i, char c) {
  return smartIndexOf(s, c, i);
}

static int smartIndexOf(String s, char c, int i) {
  if (s == null) return 0;
  i = s.indexOf(c, min(i, l(s)));
  return i >= 0 ? i : l(s);
}

static int smartIndexOf(String s, String sub) {
  return smartIndexOf(s, sub, 0);
}

static int smartIndexOf(String s, char c) {
  return smartIndexOf(s, c, 0);
}

static <A> int smartIndexOf(List<A> l, A sub) {
  return smartIndexOf(l, sub, 0);
}

static <A> int smartIndexOf(List<A> l, int start, A sub) {
  return smartIndexOf(l, sub, start);
}

static <A> int smartIndexOf(List<A> l, A sub, int start) {
  int i = indexOf(l, sub, start);
  return i < 0 ? l(l) : i;
}


static char stringToChar(String s) {
  if (l(s) != 1) throw fail("bad stringToChar: " + s);
  return firstChar(s);
}


static long twoIntsToLong(int a, int b) {
  return (((long) a) << 32) | (((long) b) & 0xFFFFFFFFL);
}


static int intFromBytes(byte[] a, int i) {
  return ubyteToInt(a[i]) << 24
    | ubyteToInt(a[i+1]) << 16
    | ubyteToInt(a[i+2]) << 8
    | ubyteToInt(a[i+3]);
}


static BufferedReader utf8BufferedReader(InputStream in) {
  return utf8bufferedReader(in);
}

static BufferedReader utf8BufferedReader(File f) {
  return utf8bufferedReader(f);
}


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 Throwable getException(Runnable r) {
  try {
    callF(r);
    return null;
  } catch (Throwable e) {
    return e;
  }
}


static Class run(String progID, String... args) {
  Class main = hotwire(progID);
  
  callMain(main, args);
  return main;
}


static void restart() {
  Object j = getJavaX();
  call(j, "cleanRestart", get(j, "fullArgs"));
}


static volatile boolean sleep_noSleep = false;

static void sleep(long ms) {
  ping();
  if (ms < 0) return;
  // allow spin locks
  if (isAWTThread() && ms > 100) throw fail("Should not sleep on AWT thread");
  try {
    Thread.sleep(ms);
  } catch (Exception e) { throw new RuntimeException(e); }
}

static void sleep() { try {
  if (sleep_noSleep) throw fail("nosleep");
  print("Sleeping.");
  sleepQuietly();
} catch (Exception __e) { throw rethrow(__e); } }




static char firstChar(String s) {
  return s.charAt(0);
}


static IMeta initIMeta(Object o) {
  if (o == null) return null;
  if (o instanceof IMeta) return ((IMeta) o);
  if (o instanceof JComponent) return initMetaOfJComponent((JComponent) o);
  
  // This is not really used. Try to use BufferedImageWithMeta instead
  if (o instanceof BufferedImage) return optCast(IMeta.class, ((BufferedImage) o).getProperty("meta"));
  return null;
}


// custom mainClass only works with hotwire_here
static Class<?> hotwire(String src) { return hotwire(src, __1 -> mainClassNameForClassLoader(__1)); }
static Class<?> hotwire(String src, IF1<ClassLoader, String> calculateMainClass) {
  assertFalse(_inCore());
  Class j = getJavaX();
  if (isAndroid()) {
    synchronized(j) { // hopefully this goes well...
      List<File> libraries = new ArrayList<File>();
      File srcDir = (File) call(j, "transpileMain", src, libraries);
      if (srcDir == null)
        throw fail("transpileMain returned null (src=" + quote(src) + ")");
    
      Object androidContext = get(j, "androidContext");
      return (Class) call(j, "loadx2android", srcDir, src);
    }
  } else {
    
    
    Class c =  (Class) (call(j, "hotwire", src));
    hotwire_copyOver(c);
    return c;
    
  }
}


static <A> A callMain(A c, String... args) {
  callOpt(c, "main", new Object[] {args});
  return c;
}

static void callMain() {
  callMain(mc());
}


static Object sleepQuietly_monitor = new Object();

static void sleepQuietly() { try {
  assertFalse(isAWTThread());
  synchronized(sleepQuietly_monitor) { sleepQuietly_monitor.wait(); }
} catch (Exception __e) { throw rethrow(__e); } }




static IMeta initMetaOfJComponent(JComponent c) {
  if (c == null) return null;
  IMeta meta =  (IMeta) (c.getClientProperty(IMeta.class));
  if (meta == null)
    c.putClientProperty(IMeta.class, meta = new Meta());
  
  return meta;
}


static <A> A optCast(Class<A> c, Object o) {
  return isInstance(c, o) ? (A) o : null;
}


static void assertFalse(Object o) {
  if (!(eq(o, false) /*|| isFalse(pcallF(o))*/))
    throw fail(str(o));
}
  
static boolean assertFalse(boolean b) {
  if (b) throw fail("oops");
  return b;
}

static boolean assertFalse(String msg, boolean b) {
  if (b) throw fail(msg);
  return b;
}



static boolean _inCore() {
  return false;
}


static List hotwire_copyOver_after = synchroList();

static void hotwire_copyOver(Class c) {
  // TODO: make a mechanism for making such "inheritable" fields
  for (String field : ll("print_log", "print_silent", "androidContext", "_userHome"))
    setOptIfNotNull(c, field, getOpt(mc(), field));
    
  
  
  setOptIfNotNull(c, "mainBot" , getMainBot());
  setOpt(c, "creator_class" , new WeakReference(mc()));
  pcallFAll(hotwire_copyOver_after, c);
}




static boolean isInstance(Class type, Object arg) {
  return type.isInstance(arg);
}


static void setOptIfNotNull(Object o, String field, Object value) {
  if (value != null) setOpt(o, field, value);
}


static Object mainBot;

static Object getMainBot() {
  return mainBot;
}




static interface IResourceHolder {
  <A extends AutoCloseable> A add(A a);
  Collection<AutoCloseable> takeAll();
}
static class Chain<A> implements Iterable<A> {
  A element;
  Chain<A> next;
  int size;
  
  Chain() {}
  Chain(A element) {
  this.element = element; size = 1; }
  Chain(A element, Chain<A> next) {
  this.next = next;
  this.element = element;
    size = next != null ? next.size+1 : 1;
  }
  
  public String toString() { return str(toList()); }
  
  ArrayList<A> toList() {
    ArrayList<A> l = emptyList(size);
    Chain<A> c = this;
    while (c != null) {
      l.add(c.element);
      c = c.next;
    }
    return l;
  }
  
  // TODO: optimize
  public Iterator<A> iterator() { return toList().iterator(); }
}
// Meta - a "minimal" approach to adding meta-level to Java objects

static class Meta implements IMeta {
  
// 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(); }
final boolean scaffolded(){ return scaffoldingEnabled(); }
boolean scaffoldingEnabled() { return main.scaffoldingEnabled(this); }
boolean scaffoldingEnabled(Object o) { return main.scaffoldingEnabled(o); }

// Implementing setMetaToString

String toString_base() { return super.toString(); }
public String toString() {
  Object o = metaGet("toString", this);
  if (o instanceof String) return ((String) o);
  if (o instanceof IF1) return str(((IF1) o).get(this));
  return toString_base();
}
}
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);
  }
}
// it's unclear whether the end is inclusive or exclusive
// (usually exclusive I guess)
static class IntRange {
  int start, end;
  
  IntRange() {}
  IntRange(int start, int end) {
  this.end = end;
  this.start = start;}
  IntRange(IntRange r) { start = r.start; end = r.end; }
  
  public boolean equals(Object o) { return stdEq2(this, o); }
public int hashCode() { return stdHash2(this); }
  
  final int length() { return end-start; }
  final boolean empty() { return start >= end; }
  final boolean isEmpty() { return start >= end; }
  
  static String _fieldOrder = "start end";
  
  public String toString() { return "[" + start + ";" + end + "]"; }
}
// a variant of thread where you can get the Runnable target later.
// Also notes its existence on the VM bus.
// We should use this exclusively instead of Thread.

static class BetterThread extends Thread {
  Runnable target;
  
  BetterThread(Runnable target) {
  this.target = target; _created(); }
  BetterThread(Runnable target, String name) { super(name);
  this.target = target; _created(); }
  
  void _created() { vmBus_send("threadCreated", this); }
  
  public void run() { try {
    try {
      vmBus_send("threadStarted", this);
      if (target != null) target.run();
    } finally {
      vmBus_send("threadEnded", this); 
    }
  } catch (Exception __e) { throw rethrow(__e); } }
  
  Runnable getTarget() { return target; }
}
static class Complex implements IFieldsToList{
  static final String _fieldOrder = "re im";
  double re;
  double im;
  Complex() {}
  Complex(double re, double im) {
  this.im = im;
  this.re = re;}

public boolean equals(Object o) {
if (!(o instanceof Complex)) return false;
    Complex __1 =  (Complex) o;
    return re == __1.re && im == __1.im;
}

  public int hashCode() {
    int h = -1679819632;
    h = boostHashCombine(h, _hashCode(re));
    h = boostHashCombine(h, _hashCode(im));
    return h;
  }
  public Object[] _fieldsToList() { return new Object[] {re, im}; }

  double abs() { return sqrt(re*re+im*im); }
  
  double re() { return re; }
  double im() { return im; }
  
  final double angle(){ return phase(); }
double phase() { return Math.atan2(im, re); }
  double fracAngle() { return fracNonNeg(angle()/twoPi()); } // angle as 0 to 1
  
  public String toString() {
    if (im != 0)
      return re == 0 ? im + "i" : re + plusPrefixUnlessMinus(str(im)) + "i";
    else
      return str(re);
  }
}
static final class WidthAndHeightFinal extends Meta implements WidthAndHeight
   , ByteIO  , IFieldsToList{
  static final String _fieldOrder = "width height";
  int width;
  int height;
  WidthAndHeightFinal() {}
  WidthAndHeightFinal(int width, int height) {
  this.height = height;
  this.width = width;}

public boolean equals(Object o) {
if (!(o instanceof WidthAndHeightFinal)) return false;
    WidthAndHeightFinal __0 =  (WidthAndHeightFinal) o;
    return width == __0.width && height == __0.height;
}

  public int hashCode() {
    int h = -1177452162;
    h = boostHashCombine(h, _hashCode(width));
    h = boostHashCombine(h, _hashCode(height));
    return h;
  }
  public Object[] _fieldsToList() { return new Object[] {width, height}; }

  public int getWidth() { return width; }
  public int getHeight() { return height; }
  
  WidthAndHeightFinal(int wAndH) { this(wAndH, wAndH); }
  
  public String toString() { return n2(width) + "*" + n2(height) + " px"; }
  
  
  public void readWrite(ByteHead head) {
    head.exchangeInt(() -> width(), w -> width = w);
    head.exchangeInt(() -> height(), h -> height = h);
  }
  
}
// elements are put to front when added (not when accessed)
static class MRUCache<A, B> extends LinkedHashMap<A, B> {
  int maxSize = 10;

  MRUCache() {}
  MRUCache(int maxSize) {
  this.maxSize = maxSize;}
  
  protected boolean removeEldestEntry(Map.Entry eldest) {
    return size() > maxSize;
  }
  
  Object _serialize() {
    return ll(maxSize, cloneLinkedHashMap(this));
  }
  
  static MRUCache _deserialize(List l) {
    MRUCache m = new MRUCache();
    m.maxSize = (int) first(l);
    m.putAll((LinkedHashMap) second(l));
    return m;
  }
}
static abstract class CloseableIterableIterator<A> extends IterableIterator<A> implements AutoCloseable {
  public void close() throws Exception {}
}
static interface Producer<A> {
  public A next(); // null when end
}
static class ReverseChain<A> implements Iterable<A> {
  A element;
  ReverseChain<A> prev;
  int size;
  
  ReverseChain() {}
  ReverseChain(ReverseChain<A> prev, A element) {
  this.element = element;
  this.prev = prev;
    if (prev == null) size = 1;
    else {
      prev.check();
      size = prev.size+1;
    }
  }
  
  void check() {
    if (size < 1) throw fail("You called the ReverseChain default constructor. Don't do that");
  }
  
  public String toString() {
    return str(toList());
  }
  
  ArrayList<A> toList() {
    check();
    ArrayList<A> l = emptyList(size);
    for (int i = 0; i < size; i++) l.add(null);
    int i = size;
    ReverseChain<A> c = this;
    while (c != null) {
      l.set(--i, c.element);
      c = c.prev;
    }
    return l;
  }
  
  public Iterator<A> iterator() { return toList().iterator(); }
}
static class GeometricPriceCells implements PriceCells {
  GeometricPriceCells() {}
  // cell size in percent
   final public GeometricPriceCells setCellSizeInPercent(double cellSizeInPercent){ return cellSizeInPercent(cellSizeInPercent); }
public GeometricPriceCells cellSizeInPercent(double cellSizeInPercent) { this.cellSizeInPercent = cellSizeInPercent; return this; }  final public double getCellSizeInPercent(){ return cellSizeInPercent(); }
public double cellSizeInPercent() { return cellSizeInPercent; }
 double cellSizeInPercent;
  
  // one of the cell limits
   final public GeometricPriceCells setBasePrice(double basePrice){ return basePrice(basePrice); }
public GeometricPriceCells basePrice(double basePrice) { this.basePrice = basePrice; return this; }  final public double getBasePrice(){ return basePrice(); }
public double basePrice() { return basePrice; }
 double basePrice = 1000;
  
  GeometricPriceCells(double cellSizeInPercent) {
  this.cellSizeInPercent = cellSizeInPercent;}
  GeometricPriceCells(double basePrice, double cellSizeInPercent) {
  this.cellSizeInPercent = cellSizeInPercent;
  this.basePrice = basePrice;}
  
  double ratio() {
    return 1+cellSizeInPercent/100;
  }

  double toLogScale(double price) {
    return log(price, ratio());
  }
  
  double fromLogScale(double logPrice) {
    return pow(ratio(), logPrice);
  }

  double logBasePrice() {
    return toLogScale(basePrice);
  }

  double remainder(double price) {
    return remainder(toLogScale(price));
  }

  double remainderLog(double logPrice) {
    return frac(logPrice-logBasePrice());
  }

  // TODO: fix this logic's rounding problems
  
  public boolean isCellLimit(double price) {
    return remainder(price) == 0;
  }
  
  public double nextCellLimitLog(double logPrice) {
    double r = remainderLog(logPrice);
    return logPrice + 1-r;
  }
  
  public double nextCellLimit(double price) {
    return fromLogScale(nextCellLimitLog(toLogScale(price)));
  }
  
  public double previousCellLimitLog(double logPrice) {
    double r = remainderLog(logPrice);
    return logPrice - (r == 0 ? 1 : r);
  }
  
  public double previousCellLimit(double price) {
    return fromLogScale(previousCellLimitLog(toLogScale(price)));
  }
  
  public double nCellLimitsDown(double price, int n) {
    double logPrice = toLogScale(price);
    logPrice = previousCellLimitLog(logPrice)-(n-1);
    return fromLogScale(logPrice);
  }
  
  public double nCellLimitsUp(double price, int n) {
    double logPrice = toLogScale(price);
    logPrice = nextCellLimitLog(logPrice)+n;
    return fromLogScale(logPrice);
  }
  
  public double priceToCellNumber(double price) {
    return toLogScale(price)-logBasePrice();
  } 
  
  public double cellNumberToPrice(double cellNumber) {
    return fromLogScale(cellNumber+logBasePrice());
  }
  
  public String toString() {
    return formatDouble2(cellSizeInPercent) + "% cells with C0=" + formatPrice(basePrice);
  }
}


static interface IAutoCloseableF0<A> extends IF0<A>, AutoCloseable {}


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 Map convertObjectMetaToMap(IMeta o) { return convertObjectMetaToMap(o, () -> makeObjectMetaMap()); }
static Map convertObjectMetaToMap(IMeta o, IF0<Map> createEmptyMap) {
  if (o == null) return null;
  
  // The following shortcut depends on the assumption that a meta field never reverts
  // to null when it was a map
  
    Object meta = o._getMeta();
    if (meta instanceof Map) return ((Map) meta);
  
  
  // non-shortcut path (create meta)
   var mutex = tempMetaMutex(o); try {
  var actualMutex = mutex.get();
  synchronized(actualMutex) {
    meta = o._getMeta();
    if (meta instanceof Map) return ((Map) meta);
    Map map = createEmptyMap.get();
    if (meta != null) map.put("previousMeta" , meta);
    o._setMeta(map);
    return map;
  }
} finally { _close(mutex); }}


static <A, B> void syncMapPutOrRemove(Map<A, B> map, A key, B value) {
  syncMapPut2(map, key, value);
}


static double fracNonNeg(double d) {
  return frac_nonNeg(d);
}


static double twoPi() {
  return Math.PI*2;
}


static String plusPrefixUnlessMinus(String s) {
  return startsWith(s, "-") ? s : "+" + s;
}


static <A, B> LinkedHashMap<A, B> cloneLinkedHashMap(Map<A, B> map) {
  return map == null ? new LinkedHashMap() : new LinkedHashMap(map);
}


static <A> A second(List<A> l) {
  return get(l, 1);
}

static <A> A second(Iterable<A> l) {
  if (l == null) return null;
  Iterator<A> it = iterator(l);
  if (!it.hasNext()) return null;
  it.next();
  return it.hasNext() ? it.next() : null;
}

static <A> A second(A[] bla) {
  return bla == null || bla.length <= 1 ? null : bla[1];
}


static <A, B> B second(Pair<A, B> p) {
  return p == null ? null : p.b;
}





static <A> A second(Producer<A> p) {
  if (p == null) return null;
  if (p.next() == null) return null;
  return p.next();
}


static char second(String s) {
  return charAt(s, 1);
}




static double log(double d) {
  return Math.log(d);
}

static double log(double d, double base) {
  return Math.log(d)/Math.log(base);
}



static long ratio(long x, long y) {
  return y == 0 ? 0 : x/y;
}


static double ratio(double x, double y) {
  return y == 0 ? 0 : x/y;
}


static double pow(double a, double b) {
  return Math.pow(a, b);
}

static float pow(float a, float b) {
  return (float) Math.pow(a, b);
}

static BigInteger pow(BigInteger a, int b) {
  return a.pow(b);
}


static double frac(double d) {
  return fraction(d);
}


static String formatDouble2(double d) {
  return formatDouble(d, 2);
}





static IMeta toIMeta(Object o) {
  return initIMeta(o);
}


static Map makeObjectMetaMap() {
  //ret synchroLinkedHashMap();
  return new CompactHashMap();
}


static IAutoCloseableF0 tempMetaMutex(IMeta o) {
  return o == null ? null : o._tempMetaMutex();
}


static <A, B> void syncMapPut2(Map<A, B> map, A key, B value) {
  if (map != null && key != null) synchronized(collectionMutex(map)) {
    if (value != null) map.put(key, value);
    else map.remove(key);
  }
}


static double frac_nonNeg(double d) {
  return mod(d, 1);
}


static char charAt(String s, int i) {
  return s != null && i >= 0 && i < s.length() ? s.charAt(i) : '\0';
}




// better modulo that gives positive numbers always
static int mod(int n, int m) {
  return (n % m + m) % m;
}

static long mod(long n, long m) {
  return (n % m + m) % m;
}

static BigInteger mod(BigInteger n, int m) {
  return n.mod(bigint(m));
}

static double mod(double n, double m) {
  return (n % m + m) % m;
}





// size:
// 64 bytes for 0 to 1 elements
// 96 bytes for 2 to 4 elements

/*
 * #!
 * Ontopia Engine
 * #-
 * Copyright (C) 2001 - 2013 The Ontopia Project
 * #-
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 * 
 *      http://www.apache.org/licenses/LICENSE-2.0
 * 
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 * !#
 */

static class CompactHashMap<K, V> extends CompactAbstractMap<K, V> {
  final static int INITIAL_SIZE = 3;
  final static double LOAD_FACTOR = 0.6;

  // This object is used to represent a null KEY (null value are kept as is)
  final static Object nullObject = new Object();
  
  /**
   * When a key is deleted this object is put into the hashtable in
   * its place, so that other entries with the same key (collisions)
   * further down the hashtable are not lost after we delete an object
   * in the collision chain.
   */
  final static Object deletedObject = new Object();
  int elements;
  int freecells;
  Object[] table; // key, value, key, value, ...
  //int modCount;

  CompactHashMap() {
    this(INITIAL_SIZE);
  }

  CompactHashMap(int size) {
    table = new Object[(size==0 ? 1 : size)*2];
    elements = 0;
    freecells = tableSize();
    //modCount = 0;
  }
  
  // TODO: allocate smarter
  CompactHashMap(Map<K, V> map) {
    this(0);
    if (map != null) putAll(map);
  }

  // ===== MAP IMPLEMENTATION =============================================

  /**
   * Returns the number of key/value mappings in this map.
   */
  public synchronized int size() {
    return elements;
  }
  
  /**
   * Returns <tt>true</tt> if this map contains no mappings.
   */
  public synchronized boolean isEmpty() {
    return elements == 0;
  }

  /**
   * Removes all key/value mappings in the map.
   */
  public synchronized void clear() {
    elements = 0;
    for (int ix = 0; ix < tableSize(); ix++) {
      key(ix, null);
      value(ix, null);
    }
    freecells = tableSize();
    //modCount++;
  }
  
  /**
   * Returns <tt>true</tt> if this map contains the specified key.
   */
  public synchronized boolean containsKey(Object k) {
    return key(findKeyIndex(k)) != null;
  }
  
  /**
   * Returns <tt>true</tt> if this map contains the specified value.
   */
  public synchronized boolean containsValue(Object v) {
    if (v == null)
      v = (V)nullObject;

    for (int ix = 0; ix < tableSize(); ix++)
      if (value(ix) != null && value(ix).equals(v))
        return true;

    return false;
  }

  /**
   * Returns a read-only set view of the map's keys.
   */
  public synchronized Set<Entry<K, V>> entrySet() {
    return new EntrySet();
  }

  /**
   * Removes the mapping with key k, if there is one, and returns its
   * value, if there is one, and null if there is none.
   */
  public synchronized V remove(Object k) {
    int index = findKeyIndex(k);

    // we found the right position, now do the removal
    if (key(index) != null) {
      // we found the object

      // same problem here as with put
      V v = value(index);
      key(index, deletedObject);
      value(index, deletedObject);
      //modCount++;
      elements--;
      return v;
    } else
      // we did not find the key
      return null;
  }

  /**
   * Adds the specified mapping to this map, returning the old value for
   * the mapping, if there was one.
   */
  public synchronized V put(K k, V v) {
    if (k == null)
      k = (K)nullObject;

    int hash = k.hashCode();
    int index = (hash & 0x7FFFFFFF) % tableSize();
    int offset = 1;
    int deletedix = -1;
    
    // search for the key (continue while !null and !this key)
    while(key(index) != null &&
          !(key(index).hashCode() == hash &&
            key(index).equals(k))) {

      // if there's a deleted mapping here we can put this mapping here,
      // provided it's not in here somewhere else already
      if (key(index) == deletedObject)
        deletedix = index;
      
      index = ((index + offset) & 0x7FFFFFFF) % tableSize();
      offset = offset*2 + 1;

      if (offset == -1)
        offset = 2;
    }
    
    if (key(index) == null) { // wasn't present already
      if (deletedix != -1) // reusing a deleted cell
        index = deletedix;
      else
        freecells--;

      //modCount++;
      elements++;

      key(index, k);
      value(index, v);
      
      // rehash with increased capacity
      if (1 - (freecells / (double) tableSize()) > LOAD_FACTOR)
        rehash(tableSize()*2 + 1);
      return null;
    } else { // was there already
      //modCount++;
      V oldv = value(index);
      value(index, v);
      return oldv;
    }
  }

  /**
   * INTERNAL: Rehashes the hashmap to a bigger size.
   */
  void rehash(int newCapacity) {
    int oldCapacity = tableSize();
    Object[] newTable = new Object[newCapacity*2];

    for (int ix = 0; ix < oldCapacity; ix++) {
      Object k = key(ix);
      if (k == null || k == deletedObject)
        continue;
      
      int hash = k.hashCode();
      int index = (hash & 0x7FFFFFFF) % newCapacity;
      int offset = 1;

      // search for the key
      while(newTable[index*2] != null) { // no need to test for duplicates
        index = ((index + offset) & 0x7FFFFFFF) % newCapacity;
        offset = offset*2 + 1;

        if (offset == -1)
          offset = 2;
      }

      newTable[index*2] = k;
      newTable[index*2+1] = value(ix);
    }

    table = newTable;
    freecells = tableSize() - elements;
  }

  /**
   * Returns the value for the key k, if there is one, and null if
   * there is none.
   */
  public synchronized V get(Object k) {
    return value(findKeyIndex(k));
  }

  /**
   * Returns a virtual read-only collection containing all the values
   * in the map.
   */
  public synchronized Collection<V> values() {
    return new ValueCollection();
  }

  /**
   * Returns a virtual read-only set of all the keys in the map.
   */
  public synchronized Set<K> keySet() {
    return new KeySet();
  }

  // --- Internal utilities

  final int findKeyIndex(Object k) {
    if (k == null)
      k = nullObject;

    int hash = k.hashCode();
    int index = (hash & 0x7FFFFFFF) % tableSize();
    int offset = 1;

    // search for the key (continue while !null and !this key)
    while(key(index) != null &&
          !(key(index).hashCode() == hash &&
            key(index).equals(k))) {
      index = ((index + offset) & 0x7FFFFFFF) % tableSize();
      offset = offset*2 + 1;

      if (offset == -1)
        offset = 2;
    }
    return index;
  }
  
  // --- Key set

  class KeySet extends AbstractSet<K> {
    public int size() { synchronized(CompactHashMap.this) {
      return elements;
    }}

    public boolean contains(Object k) { synchronized(CompactHashMap.this) {
      return containsKey(k);
    }}

    public Iterator<K> iterator() { synchronized(CompactHashMap.this) {
      return new KeyIterator();
    }}
  }

  class KeyIterator<K> implements Iterator<K> {
    private int ix;
    
    private KeyIterator() {
      synchronized(CompactHashMap.this) {
        // walk up to first value, so that hasNext() and next() return
        // correct results
        for (; ix < tableSize(); ix++)
          if (value(ix) != null && key(ix) != deletedObject)
            break;
      }
    }

    public boolean hasNext() { synchronized(CompactHashMap.this) {
      return ix < tableSize();
    }}

    public void remove() {
      throw new UnsupportedOperationException("Collection is read-only");
    }

    public K next() { synchronized(CompactHashMap.this) {
      if (ix >= tableSize())
        throw new NoSuchElementException();
      K key = (K) key(ix++);
      
      // walk up to next value
      for (; ix < tableSize(); ix++)
        if (key(ix) != null && key(ix) != deletedObject)
          break;
      
      // ix now either points to next key, or outside array (if no next)
      return key;
    }}
  }
  
  // --- Entry set
  
  class EntrySet extends AbstractSet<Map.Entry<K, V>> {
    public int size() { synchronized(CompactHashMap.this) {
      return elements;
    }}

    public boolean contains(Object o) { synchronized(CompactHashMap.this) {
      if (o instanceof Map.Entry) {
        Object key = ((Map.Entry) o).getKey();
        if (!containsKey((Map.Entry) o)) return false;
        return eq(((Map.Entry) o).getValue(), get(key));
      }
      return false;
    }}

    public Iterator<Map.Entry<K, V>> iterator() {
      return new EntryIterator();
    }
  }

  class EntryIterator implements Iterator<Map.Entry<K, V>> {
    private int ix;
    
    private EntryIterator() {
      synchronized(CompactHashMap.this) {
        // walk up to first value, so that hasNext() and next() return
        // correct results
        for (; ix < tableSize(); ix++)
          if (value(ix) != null && key(ix) != deletedObject)
            break;
      }
    }

    public boolean hasNext() { synchronized(CompactHashMap.this) {
      return ix < tableSize();
    }}

    public void remove() {
      throw new UnsupportedOperationException("Collection is read-only");
    }

    public Map.Entry<K, V> next() { synchronized(CompactHashMap.this) {
      if (ix >= tableSize())
        throw new NoSuchElementException();
      K key = key(ix);
      V val = value(ix);
      ++ix;
      
      // walk up to next value
      for (; ix < tableSize(); ix++)
        if (key(ix) != null && key(ix) != deletedObject)
          break;
      
      // ix now either points to next key, or outside array (if no next)
      return simpleMapEntry(key, val);
    }}
  }
  
  // --- Value collection

  class ValueCollection<V> extends AbstractCollection<V> {
    public int size() { synchronized(CompactHashMap.this) {
      return elements;
    }}

    public Iterator<V> iterator() {
      return new ValueIterator();
    }

    public boolean contains(Object v) {
      return containsValue(v);
    }
  }

  class ValueIterator<V> implements Iterator<V> {
    private int ix;
    
    private ValueIterator() {
      synchronized(CompactHashMap.this) {
        // walk up to first value, so that hasNext() and next() return
        // correct results
        for (; ix < table.length/2; ix++)
          if (value(ix) != null && value(ix) != deletedObject)
            break;
      }
    }

    public boolean hasNext() { synchronized(CompactHashMap.this) {
      return ix < tableSize();
    }}

    public void remove() {
      throw new UnsupportedOperationException("Collection is read-only");
    }

    public V next() { synchronized(CompactHashMap.this) {
      if (ix >= tableSize())
        throw new NoSuchElementException();
      V value = (V) value(ix++);
      
      // walk up to next value
      for (; ix < tableSize(); ix++)
        if (value(ix) != null && value(ix) != deletedObject)
          break;
      
      // ix now either points to next value, or outside array (if no next)
      return value;
    }}
  }
  
  K key(int i) { return (K) table[i*2]; }
  void key(int i, Object key) { table[i*2] = key; }
  V value(int i) { return (V) table[i*2+1]; }
  void value(int i, Object value) { table[i*2+1] = value; }
  
  int tableSize() { return table.length/2; }
}


abstract static class CompactAbstractMap<K, V> implements Map<K, V> {
  public int size() {
      return entrySet().size();
  }

  public boolean isEmpty() {
      return size() == 0;
  }

  public boolean containsValue(Object value) {
      Iterator<Entry<K, V>> i = entrySet().iterator();
      if (value == null) {
          while (i.hasNext()) {
              Entry<K, V> e = i.next();
              if (e.getValue() == null)
                  return true;
          }
      } else {
          while (i.hasNext()) {
              Entry<K, V> e = i.next();
              if (value.equals(e.getValue()))
                  return true;
          }
      }
      return false;
  }

  public boolean containsKey(Object key) {
      Iterator<Entry<K, V>> i = entrySet().iterator();
      if (key == null) {
          while (i.hasNext()) {
              Entry<K, V> e = i.next();
              if (e.getKey() == null)
                  return true;
          }
      } else {
          while (i.hasNext()) {
              Entry<K, V> e = i.next();
              if (key.equals(e.getKey()))
                  return true;
          }
      }
      return false;
  }

  public V get(Object key) {
      Iterator<Entry<K, V>> i = entrySet().iterator();
      if (key == null) {
          while (i.hasNext()) {
              Entry<K, V> e = i.next();
              if (e.getKey() == null)
                  return e.getValue();
          }
      } else {
          while (i.hasNext()) {
              Entry<K, V> e = i.next();
              if (key.equals(e.getKey()))
                  return e.getValue();
          }
      }
      return null;
  }

  public V put(K key, V value) {
      throw new UnsupportedOperationException();
  }

  public V remove(Object key) {
      Iterator<Entry<K, V>> i = entrySet().iterator();
      Entry<K, V> correctEntry = null;
      if (key == null) {
          while (correctEntry == null && i.hasNext()) {
              Entry<K, V> e = i.next();
              if (e.getKey() == null)
                  correctEntry = e;
          }
      } else {
          while (correctEntry == null && i.hasNext()) {
              Entry<K, V> e = i.next();
              if (key.equals(e.getKey()))
                  correctEntry = e;
          }
      }

      V oldValue = null;
      if (correctEntry != null) {
          oldValue = correctEntry.getValue();
          i.remove();
      }
      return oldValue;
  }

  public void putAll(Map<? extends K, ? extends V> m) {
      for (Entry<? extends K, ? extends V> e : m.entrySet())
          put(e.getKey(), e.getValue());
  }

  public void clear() {
      entrySet().clear();
  }

  public Set<K> keySet() {
      return new AbstractSet<K>() {
          public Iterator<K> iterator() {
              return new Iterator<K>() {
                  private Iterator<Entry<K, V>> i = entrySet().iterator();

                  public boolean hasNext() {
                      return i.hasNext();
                  }

                  public K next() {
                      return i.next().getKey();
                  }

                  public void remove() {
                      i.remove();
                  }
              };
          }

          public int size() {
              return CompactAbstractMap.this.size();
          }

          public boolean isEmpty() {
              return CompactAbstractMap.this.isEmpty();
          }

          public void clear() {
              CompactAbstractMap.this.clear();
          }

          public boolean contains(Object k) {
              return CompactAbstractMap.this.containsKey(k);
          }
      };
  }

  public Collection<V> values() {
      return new AbstractCollection<V>() {
          public Iterator<V> iterator() {
              return new Iterator<V>() {
                  private Iterator<Entry<K, V>> i = entrySet().iterator();

                  public boolean hasNext() {
                      return i.hasNext();
                  }

                  public V next() {
                      return i.next().getValue();
                  }

                  public void remove() {
                      i.remove();
                  }
              };
          }

          public int size() {
              return CompactAbstractMap.this.size();
          }

          public boolean isEmpty() {
              return CompactAbstractMap.this.isEmpty();
          }

          public void clear() {
              CompactAbstractMap.this.clear();
          }

          public boolean contains(Object v) {
              return CompactAbstractMap.this.containsValue(v);
          }
      };
  }

  public abstract Set<Entry<K, V>> entrySet();

  public boolean equals(Object o) {
      if (o == this)
          return true;

      if (!(o instanceof Map))
          return false;
      Map<?, ?> m = (Map<?, ?>) o;
      if (m.size() != size())
          return false;

      try {
          for (Entry<K, V> e : entrySet()) {
              K key = e.getKey();
              V value = e.getValue();
              if (value == null) {
                  if (!(m.get(key) == null && m.containsKey(key)))
                      return false;
              } else {
                  if (!value.equals(m.get(key)))
                      return false;
              }
          }
      } catch (ClassCastException unused) {
          return false;
      } catch (NullPointerException unused) {
          return false;
      }

      return true;
  }

  public int hashCode() {
      int h = 0;
      for (Entry<K, V> entry : entrySet())
          h += entry.hashCode();
      return h;
  }

  public String toString() {
      Iterator<Entry<K, V>> i = entrySet().iterator();
      if (!i.hasNext())
          return "{}";

      StringBuilder sb = new StringBuilder();
      sb.append('{');
      for (; ; ) {
          Entry<K, V> e = i.next();
          K key = e.getKey();
          V value = e.getValue();
          sb.append(key == this ? "(this Map)" : key);
          sb.append('=');
          sb.append(value == this ? "(this Map)" : value);
          if (!i.hasNext())
              return sb.append('}').toString();
          sb.append(',').append(' ');
      }
  }

  protected Object clone() throws CloneNotSupportedException {
      CompactAbstractMap<?, ?> result = (CompactAbstractMap<?, ?>) super.clone();
      return result;
  }

  public static class SimpleEntry<K, V>
          implements Entry<K, V>, java.io.Serializable {
      @java.io.Serial
      private static final long serialVersionUID = -8499721149061103585L;

      @SuppressWarnings("serial")
      private final K key;
      @SuppressWarnings("serial")
      private V value;

      public SimpleEntry(K key, V value) {
          this.key = key;
          this.value = value;
      }

      public SimpleEntry(Entry<? extends K, ? extends V> entry) {
          this.key = entry.getKey();
          this.value = entry.getValue();
      }

      public K getKey() {
          return key;
      }

      public V getValue() {
          return value;
      }

      public V setValue(V value) {
          V oldValue = this.value;
          this.value = value;
          return oldValue;
      }

      public boolean equals(Object o) {
          if (!(o instanceof Map.Entry))
              return false;
          Entry<?, ?> e = (Entry<?, ?>) o;
          return eq(key, e.getKey()) && eq(value, e.getValue());
      }

      public int hashCode() {
          return (key == null ? 0 : key.hashCode()) ^
                  (value == null ? 0 : value.hashCode());
      }

      public String toString() {
          return key + "=" + value;
      }

  }

  public static class SimpleImmutableEntry<K, V>
          implements Entry<K, V>, java.io.Serializable {
      @java.io.Serial
      private static final long serialVersionUID = 7138329143949025153L;

      @SuppressWarnings("serial")
      private final K key;
      @SuppressWarnings("serial")
      private final V value;

      public SimpleImmutableEntry(K key, V value) {
          this.key = key;
          this.value = value;
      }

      public SimpleImmutableEntry(Entry<? extends K, ? extends V> entry) {
          this.key = entry.getKey();
          this.value = entry.getValue();
      }

      public K getKey() {
          return key;
      }

      public V getValue() {
          return value;
      }

      public V setValue(V value) {
          throw new UnsupportedOperationException();
      }

      public boolean equals(Object o) {
          if (!(o instanceof Map.Entry))
              return false;
          Entry<?, ?> e = (Entry<?, ?>) o;
          return eq(key, e.getKey()) && eq(value, e.getValue());
      }

      public int hashCode() {
          return (key == null ? 0 : key.hashCode()) ^
                  (value == null ? 0 : value.hashCode());
      }

      public String toString() {
          return key + "=" + value;
      }
  }
}


static boolean scaffoldingEnabled(Object o) {
  return metaGet(o, "scaffolding") != null;
}


static <A> Value<A> value(A a) {
  return new Value<A>(a);
}


static <A, B> boolean containsKey(Map<A, B> map, A key) {
  return map != null && map.containsKey(key);
}


static <A, B> Map.Entry<A, B> simpleMapEntry(A key, B value) {
  return new Map.Entry<A, B>() {
    public A getKey() { return key; }
    public B getValue() { return value; }
    public B setValue(B newValue) { throw unimplemented(); }
  };
}




static RuntimeException unimplemented() {
  throw fail("TODO");
}

static RuntimeException unimplemented(String msg) {
  throw fail("TODO: " + msg);
}

static RuntimeException unimplemented(Object obj) {
  throw fail("TODO: implement method in " + className(obj));
}




static class Value<A> implements IF0<A> , IFieldsToList{
  A value;
  Value() {}
  Value(A value) {
  this.value = value;}

public boolean equals(Object o) {
if (!(o instanceof Value)) return false;
    Value __1 =  (Value) o;
    return eq(value, __1.value);
}

  public int hashCode() {
    int h = 82420049;
    h = boostHashCombine(h, _hashCode(value));
    return h;
  }
  public Object[] _fieldsToList() { return new Object[] {value}; }

  public A get() { return value; }
  
  public String toString() { return str(get()); }
}

}