/** * Return a Comparator that will order the specified units in preferred unload order. If needed it * may also inspect the transport holding the units. */ public static Comparator<Unit> getUnloadableUnitsComparator( final List<Unit> units, final Route route, final PlayerID player) { // compare transports final Comparator<Unit> unloadableTransportsComparator = getUnloadableTransportsComparator(units, route, player, false); // if noTies is set, sort by hashcode so that result is deterministic final Comparator<Unit> movableUnitsComparator = getMovableUnitsComparator(units, route); return (u1, u2) -> { final Unit t1 = TripleAUnit.get(u1).getTransportedBy(); final Unit t2 = TripleAUnit.get(u2).getTransportedBy(); // check if unloadable units are in a transport if (t1 != null && t2 == null) { return -1; } if (t1 == null && t2 != null) { return 1; } if (t1 != null && t2 != null) { final int compareTransports = unloadableTransportsComparator.compare(t1, t2); if (compareTransports != 0) { return compareTransports; } } // we are sorting air units, or no difference found yet // if noTies is set, sort by hashcode so that result is deterministic return movableUnitsComparator.compare(u1, u2); }; }
public static Comparator<Unit> getHighestToLowestMovementComparator() { return (u1, u2) -> { final int left1 = TripleAUnit.get(u1).getMovementLeft(); final int left2 = TripleAUnit.get(u2).getMovementLeft(); if (left1 == left2) { return 0; } if (left1 < left2) { return 1; } return -1; }; }
/** Return a Comparator that will order the specified transports in preferred unload order. */ public static Comparator<Unit> getUnloadableTransportsComparator( final List<Unit> transports, final Route route, final PlayerID player, final boolean noTies) { final Comparator<Unit> decreasingCapacityComparator = getDecreasingCapacityComparator(transports); final Match<Unit> incapableTransportMatch = Matches.transportCannotUnload(route.getEnd()); return (t1, t2) -> { // Check if transport is incapable due to game state final boolean isIncapable1 = incapableTransportMatch.match(t1); final boolean isIncapable2 = incapableTransportMatch.match(t2); if (!isIncapable1 && isIncapable2) { return -1; } if (isIncapable1 && !isIncapable2) { return 1; } // Prioritize allied transports final boolean isAlliedTrn1 = !t1.getOwner().equals(player); final boolean isAlliedTrn2 = !t2.getOwner().equals(player); if (isAlliedTrn1 && !isAlliedTrn2) { return -1; } if (!isAlliedTrn1 && isAlliedTrn2) { return 1; } // Sort by decreasing transport capacity final int compareCapacity = decreasingCapacityComparator.compare(t1, t2); if (compareCapacity != 0) { return compareCapacity; } // Sort by increasing movement final int left1 = TripleAUnit.get(t1).getMovementLeft(); final int left2 = TripleAUnit.get(t2).getMovementLeft(); if (left1 != left2) { return left1 - left2; } // If noTies is set, sort by hashcode so that result is deterministic if (noTies) { return Integer.compare(t1.hashCode(), t2.hashCode()); } else { return 0; } }; }
/** Return a Comparator that will order the specified transports in preferred load order. */ public static Comparator<Unit> getLoadableTransportsComparator( final List<Unit> transports, final Route route, final PlayerID player) { final Comparator<Unit> decreasingCapacityComparator = getDecreasingCapacityComparator(transports); final Match<Unit> incapableTransportMatch = Matches.transportCannotUnload(route.getEnd()); return (u1, u2) -> { final TripleAUnit t1 = TripleAUnit.get(u1); final TripleAUnit t2 = TripleAUnit.get(u2); // Check if transport is incapable due to game state final boolean isIncapable1 = incapableTransportMatch.match(t1); final boolean isIncapable2 = incapableTransportMatch.match(t2); if (!isIncapable1 && isIncapable2) { return -1; } if (isIncapable1 && !isIncapable2) { return 1; } // Use allied transports as a last resort final boolean isAlliedTrn1 = !t1.getOwner().equals(player); final boolean isAlliedTrn2 = !t2.getOwner().equals(player); if (!isAlliedTrn1 && isAlliedTrn2) { return -1; } if (isAlliedTrn1 && !isAlliedTrn2) { return 1; } // Sort by decreasing transport capacity final int compareCapacity = decreasingCapacityComparator.compare(t1, t2); if (compareCapacity != 0) { return compareCapacity; } // Sort by decreasing movement final int left1 = t1.getMovementLeft(); final int left2 = t1.getMovementLeft(); if (left1 != left2) { return left2 - left1; } return Integer.compare(t1.hashCode(), t2.hashCode()); }; }
/** Return a Comparator that will order the specified units in preferred move order. */ public static Comparator<Unit> getMovableUnitsComparator( final List<Unit> units, final Route route) { final Comparator<Unit> decreasingCapacityComparator = getDecreasingCapacityComparator(units); return (u1, u2) -> { // Ensure units have enough movement final int left1 = TripleAUnit.get(u1).getMovementLeft(); final int left2 = TripleAUnit.get(u2).getMovementLeft(); if (route != null) { if (left1 >= route.getMovementCost(u1) && left2 < route.getMovementCost(u2)) { return -1; } if (left1 < route.getMovementCost(u1) && left2 >= route.getMovementCost(u2)) { return 1; } } // Prefer transports for which dependents are also selected final Collection<Unit> transporting1 = TripleAUnit.get(u1).getTransporting(); final Collection<Unit> transporting2 = TripleAUnit.get(u2).getTransporting(); final int hasDepends1 = units.containsAll(transporting1) ? 1 : 0; final int hasDepends2 = units.containsAll(transporting2) ? 1 : 0; if (hasDepends1 != hasDepends2) { return hasDepends1 - hasDepends2; } // Sort by decreasing transport capacity (only valid for transports) final int compareCapacity = decreasingCapacityComparator.compare(u1, u2); if (compareCapacity != 0) { return compareCapacity; } // Sort by increasing movement normally, but by decreasing movement during loading if (left1 != left2) { if (route != null && route.isLoad()) { return left2 - left1; } else { return left1 - left2; } } return Integer.compare(u1.hashCode(), u2.hashCode()); }; }
private static Comparator<Unit> getCapacityComparator( final List<Unit> transports, final boolean increasing) { // this makes it more efficient final IntegerMap<Unit> capacityMap = new IntegerMap<>(transports.size() + 1, 1); for (final Unit transport : transports) { final Collection<Unit> transporting = TripleAUnit.get(transport).getTransporting(); capacityMap.add(transport, TransportUtils.getTransportCost(transporting)); } return (t1, t2) -> { final int cost1 = capacityMap.getInt(t1); final int cost2 = capacityMap.getInt(t2); if (increasing) { return cost1 - cost2; } else { return cost2 - cost1; } }; }