540 lines
25 KiB
C++
540 lines
25 KiB
C++
#ifndef STAR_WORLD_IMPL_HPP
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#define STAR_WORLD_IMPL_HPP
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#include "StarIterator.hpp"
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#include "StarEntityMap.hpp"
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#include "StarWorldTiles.hpp"
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#include "StarBlocksAlongLine.hpp"
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#include "StarBiome.hpp"
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#include "StarSky.hpp"
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#include "StarWorldTemplate.hpp"
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#include "StarLiquidsDatabase.hpp"
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#include "StarCellularLighting.hpp"
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#include "StarRoot.hpp"
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#include "StarMaterialDatabase.hpp"
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#include "StarAssets.hpp"
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#include "StarJsonExtra.hpp"
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#include "StarTileModification.hpp"
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namespace Star {
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namespace WorldImpl {
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template <typename TileSectorArray>
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bool tileIsOccupied(shared_ptr<TileSectorArray> const& tileSectorArray, EntityMapPtr const& entityMap,
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Vec2I const& pos, TileLayer layer, bool includeEphemeral, bool checkCollision = false);
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template <typename TileSectorArray>
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CollisionKind tileCollisionKind(shared_ptr<TileSectorArray> const& tileSectorArray, EntityMapPtr const& entityMap,
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Vec2I const& pos);
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template <typename TileSectorArray>
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bool rectTileCollision(shared_ptr<TileSectorArray> const& tileSectorArray, RectI const& region, bool solidCollision);
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template <typename TileSectorArray>
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bool lineTileCollision(WorldGeometry const& worldGeometry, shared_ptr<TileSectorArray> const& tileSectorArray, Vec2F const& begin, Vec2F const& end, CollisionSet const& collisionSet);
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template <typename TileSectorArray>
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Maybe<pair<Vec2F, Vec2I>> lineTileCollisionPoint(WorldGeometry const& worldGeometry, shared_ptr<TileSectorArray> const& tileSectorArray, Vec2F const& begin, Vec2F const& end, CollisionSet const& collisionSet);
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template <typename TileSectorArray>
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List<Vec2I> collidingTilesAlongLine(WorldGeometry const& worldGeometry, shared_ptr<TileSectorArray> const& tileSectorArray,
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Vec2F const& begin, Vec2F const& end, CollisionSet const& collisionSet, size_t maxSize, bool includeEdges);
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template <typename GetTileFunction>
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bool canPlaceMaterial(EntityMapPtr const& entityMap,
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Vec2I const& pos, TileLayer layer, MaterialId material, bool allowEntityOverlap, bool allowTileOverlap, GetTileFunction& getTile);
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// returns true if this material could be placed if in the same batch other
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// tiles can be placed
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// that connect to it
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template <typename GetTileFunction>
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bool perhapsCanPlaceMaterial(EntityMapPtr const& entityMap,
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Vec2I const& pos, TileLayer layer, MaterialId material, bool allowEntityOverlap, bool allowTileOverlap, GetTileFunction& getTile);
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template <typename GetTileFunction>
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bool canPlaceMaterialColorVariant(Vec2I const& pos, TileLayer layer, MaterialColorVariant color, GetTileFunction& getTile);
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template <typename GetTileFunction>
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bool canPlaceMod(Vec2I const& pos, TileLayer layer, ModId mod, GetTileFunction& getTile);
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template <typename GetTileFunction>
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pair<bool, bool> validateTileModification(EntityMapPtr const& entityMap, Vec2I const& pos, TileModification const& modification, bool allowEntityOverlap, GetTileFunction& getTile);
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// Split modification list into good and bad
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template <typename GetTileFunction>
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pair<TileModificationList, TileModificationList> splitTileModifications(EntityMapPtr const& entityMap, TileModificationList const& modificationList,
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bool allowEntityOverlap, GetTileFunction& getTile, function<bool(Vec2I pos, TileModification modification)> extraCheck = {});
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template <typename TileSectorArray>
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float windLevel(shared_ptr<TileSectorArray> const& tileSectorArray, Vec2F const& position, float weatherWindLevel);
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template <typename TileSectorArray>
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float temperature(shared_ptr<TileSectorArray> const& tileSectorArray, WorldTemplateConstPtr const& worldTemplate,
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SkyConstPtr const& sky, Vec2F const& pos);
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template <typename TileSectorArray>
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bool breathable(World const* world, shared_ptr<TileSectorArray> const& tileSectorArray, WorldTemplateConstPtr const& worldTemplate, Vec2F const& pos);
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template <typename TileSectorArray>
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float lightLevel(shared_ptr<TileSectorArray> const& tileSectorArray, EntityMapPtr const& entityMap, WorldGeometry const& worldGeometry,
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WorldTemplateConstPtr const& worldTemplate, SkyConstPtr const& sky, CellularLightIntensityCalculator& lighting, Vec2F pos);
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InteractiveEntityPtr getInteractiveInRange(WorldGeometry const& geometry, EntityMapPtr const& entityMap,
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Vec2F const& targetPosition, Vec2F const& sourcePosition, float maxRange);
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bool isTileEntityInRange(WorldGeometry const& geometry, EntityMapPtr const& entityMap,
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EntityId targetEntity, Vec2F const& sourcePosition, float maxRange);
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template <typename TileSectorArray>
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bool canReachEntity(WorldGeometry const& geometry, shared_ptr<TileSectorArray> const& tileSectorArray,
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EntityMapPtr const& entityMap, Vec2F const& sourcePosition, float maxRange, EntityId targetEntity, bool preferInteractive = true);
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template <typename TileSectorArray>
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bool tileIsOccupied(shared_ptr<TileSectorArray> const& tileSectorArray, EntityMapPtr const& entityMap,
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Vec2I const& pos, TileLayer layer, bool includeEphemeral, bool checkCollision) {
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auto& tile = tileSectorArray->tile(pos);
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if (layer == TileLayer::Foreground)
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return (checkCollision ? tile.collision >= CollisionKind::Dynamic : tile.foreground != EmptyMaterialId) || entityMap->tileIsOccupied(pos, includeEphemeral);
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else
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return tile.background != EmptyMaterialId;
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}
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template <typename TileSectorArray>
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CollisionKind tileCollisionKind(shared_ptr<TileSectorArray> const& tileSectorArray, EntityMapPtr const& entityMap,
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Vec2I const& pos) {
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return tileSectorArray->tile(pos).collision;
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}
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template <typename TileSectorArray>
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bool rectTileCollision(shared_ptr<TileSectorArray> const& tileSectorArray, RectI const& region, CollisionSet const& collisionSet) {
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return tileSectorArray->tileSatisfies(region, [&collisionSet](Vec2I const&, typename TileSectorArray::Tile const& tile) {
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return isColliding(tile.collision, collisionSet);
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});
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}
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template <typename TileSectorArray>
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bool lineTileCollision(WorldGeometry const& worldGeometry, shared_ptr<TileSectorArray> const& tileSectorArray,
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Vec2F const& begin, Vec2F const& end, CollisionSet const& collisionSet) {
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return !forBlocksAlongLine<float>(begin, worldGeometry.diff(end, begin), [=](int x, int y) -> bool {
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return !tileSectorArray->tile({x, y}).isColliding(collisionSet);
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});
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}
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template <typename TileSectorArray>
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Maybe<pair<Vec2F, Vec2I>> lineTileCollisionPoint(WorldGeometry const& worldGeometry, shared_ptr<TileSectorArray> const& tileSectorArray,
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Vec2F const& begin, Vec2F const& end, CollisionSet const& collisionSet) {
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Maybe<Vec2I> collidingBlock;
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auto clear = forBlocksAlongLine<float>(begin, worldGeometry.diff(end, begin), [=, &collidingBlock](int x, int y) -> bool {
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if (tileSectorArray->tile({x, y}).isColliding(collisionSet)) {
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collidingBlock = Vec2I(x, y);
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return false;
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} else {
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return true;
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}
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});
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if (clear)
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return {}; // no colliding blocks along the line
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Vec2F direction = worldGeometry.diff(end, begin).normalized();
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Vec2F blockPosition = Vec2F(*collidingBlock);
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// find the position of intersecting sides
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if (direction[0] < 0) blockPosition[0] = blockPosition[0] + 1;
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if (direction[1] < 0) blockPosition[1] = blockPosition[1] + 1;
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Vec2F blockDistance = worldGeometry.diff(blockPosition, begin);
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// exclude edges which are in the opposite direction of the line
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if (direction[0] * blockDistance[0] < 0) blockDistance[0] = 0.0f;
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if (direction[1] * blockDistance[1] < 0) blockDistance[1] = 0.0f;
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// line length per block in each axis, don't divide by 0
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float deltaDistX = direction[0] == 0 ? 0.0f : 1.0f / abs(direction[0]);
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float deltaDistY = direction[1] == 0 ? 0.0f : 1.0f / abs(direction[1]);
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// distance to each edge of the intersect
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Vec2F intersectDist = Vec2F(abs(blockDistance[0]) * deltaDistX, abs(blockDistance[1]) * deltaDistY);
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Vec2I normal = Vec2I(intersectDist[0] > intersectDist[1] ? 1 : 0, intersectDist[1] > intersectDist[0] ? 1 : 0);
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normal[0] *= copysign(1.0f, direction[0]);
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normal[1] *= copysign(1.0f, direction[1]);
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Vec2F position = begin + (direction * max(intersectDist[0], intersectDist[1]));
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// HACK: Keeps the end position from being right on a tile border, making line check
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// *from* this end position from colliding with the first tile
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if (intersectDist[0] > intersectDist[1])
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position[0] = blockPosition[0] + (normal[0] * -0.0001f);
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else
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position[1] = blockPosition[1] + (normal[1] * -0.0001f);
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return pair<Vec2F, Vec2I>(position, normal);
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}
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template <typename TileSectorArray>
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inline LiquidLevel liquidLevel(shared_ptr<TileSectorArray> const& tileSectorArray, RectF const& region) {
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if (region.isEmpty())
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return LiquidLevel();
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RectI sampleRect = RectI::integral(region);
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// This is not entirely accurate, even though all liquid types in the
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// region count towards the grand total liquid percentage, only the most
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// common liquid is reported.
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float totalSpace = 0;
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Map<LiquidId, float> totals;
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tileSectorArray->tileEach(sampleRect, [®ion, &totalSpace, &totals](Vec2I const& pos, typename TileSectorArray::Tile const& tile) {
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float blockIncidence = RectF(pos[0], pos[1], pos[0] + 1, pos[1] + 1).overlap(region).volume();
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totalSpace += blockIncidence;
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auto liquidLevel = tile.liquid;
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if (liquidLevel.liquid != EmptyLiquidId)
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totals[liquidLevel.liquid] += min(1.0f, liquidLevel.level) * blockIncidence;
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});
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float totalLiquidLevel = 0.0f;
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float maximumLiquidLevel = 0.0f;
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LiquidId maximumLiquidId = EmptyLiquidId;
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for (auto const& p : totals) {
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totalLiquidLevel += p.second;
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if (p.second > maximumLiquidLevel) {
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maximumLiquidLevel = p.second;
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maximumLiquidId = p.first;
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}
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}
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return LiquidLevel(maximumLiquidId, totalLiquidLevel / totalSpace);
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}
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template <typename TileSectorArray>
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List<Vec2I> collidingTilesAlongLine(WorldGeometry const& worldGeometry, shared_ptr<TileSectorArray> const& tileSectorArray,
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Vec2F const& begin, Vec2F const& end, CollisionSet const& collisionSet, size_t maxSize, bool includeEdges) {
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List<Vec2I> res;
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forBlocksAlongLine<float>(begin, worldGeometry.diff(end, begin), [&](int x, int y) {
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if (res.size() >= maxSize)
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return false;
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if (tileSectorArray->tile({x, y}).isColliding(collisionSet))
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res.append({x, y});
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return true;
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});
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if (includeEdges)
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return res;
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SMutableIterator<List<Vec2I>> tileIt{res};
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while (tileIt.hasNext()) {
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auto tileRect = RectF::withSize(Vec2F(worldGeometry.xwrap(tileIt.next())), Vec2F::filled(1.0f));
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Line2F line{worldGeometry.xwrap(begin), worldGeometry.xwrap(end)};
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auto lineSet = worldGeometry.splitLine(line);
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if (any(lineSet, [&](Line2F const& line) { return tileRect.edgeIntersection(line).glances; }))
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tileIt.remove();
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}
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return res;
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}
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template <typename GetTileFunction>
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bool canPlaceMaterial(EntityMapPtr const& entityMap,
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Vec2I const& pos, TileLayer layer, MaterialId material, bool allowEntityOverlap, bool allowTileOverlap, GetTileFunction& getTile) {
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auto materialDatabase = Root::singleton().materialDatabase();
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if (!isRealMaterial(material))
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return false;
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auto isAdjacentToConnectable = [&](Vec2I const& pos, unsigned distance, bool foreground) {
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if (pos.y() - distance < 0)
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return true;
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int maxY = pos.y() + distance + 1;
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int maxX = pos.x() + distance + 1;
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for (int y = pos.y() - distance; y != maxY; ++y) {
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Vec2I tPos = { 0, y };
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for (int x = pos.x() - distance; x != maxX; ++x) {
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tPos[0] = x;
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if (tPos != pos) {
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auto& tile = getTile(tPos);
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if (isConnectableMaterial(foreground ? tile.foreground : tile.background))
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return true;
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}
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}
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}
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return false;
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};
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if (!materialDatabase->canPlaceInLayer(material, layer))
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return false;
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auto& tile = getTile(pos);
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if (layer == TileLayer::Background) {
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if (tile.background != EmptyMaterialId && tile.background != ObjectPlatformMaterialId)
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return false;
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// Can attach background blocks to other background blocks, *or* the
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// foreground block in front of it.
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if (!isAdjacentToConnectable(pos, 1, false) && !isConnectableMaterial(tile.foreground))
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return false;
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} else {
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if (tile.foreground != EmptyMaterialId && tile.foreground != ObjectPlatformMaterialId)
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return false;
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if (!allowTileOverlap && entityMap->tileIsOccupied(pos))
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return false;
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if (!allowEntityOverlap && entityMap->spaceIsOccupied(RectF::withSize(Vec2F(pos), Vec2F(0.999f, 0.999f))))
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return false;
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if (!isAdjacentToConnectable(pos, 1, true) && !isConnectableMaterial(tile.background))
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return false;
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}
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return true;
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}
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template <typename GetTileFunction>
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bool perhapsCanPlaceMaterial(EntityMapPtr const& entityMap,
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Vec2I const& pos, TileLayer layer, MaterialId material, bool allowEntityOverlap, bool allowTileOverlap, GetTileFunction& getTile) {
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auto materialDatabase = Root::singleton().materialDatabase();
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if (!isRealMaterial(material))
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return false;
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if (!materialDatabase->canPlaceInLayer(material, layer))
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return false;
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auto& tile = getTile(pos);
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if (layer == TileLayer::Background) {
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if (tile.background != EmptyMaterialId && tile.background != ObjectPlatformMaterialId)
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return false;
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} else {
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if (tile.foreground != EmptyMaterialId && tile.foreground != ObjectPlatformMaterialId)
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return false;
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if (!allowTileOverlap && entityMap->tileIsOccupied(pos))
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return false;
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if (!allowEntityOverlap && entityMap->spaceIsOccupied(RectF::withSize(Vec2F(pos), Vec2F(0.999f, 0.999f))))
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return false;
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}
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return true;
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}
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template <typename GetTileFunction>
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bool canPlaceMaterialColorVariant(Vec2I const& pos, TileLayer layer, MaterialColorVariant color, GetTileFunction& getTile) {
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auto materialDatabase = Root::singleton().materialDatabase();
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auto& tile = getTile(pos);
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auto mat = tile.material(layer);
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auto existingColor = tile.materialColor(layer);
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auto existingHue = layer == TileLayer::Foreground ? tile.foregroundHueShift : tile.backgroundHueShift;
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return existingHue != 0 || (existingColor != color && materialDatabase->isMultiColor(mat));
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}
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template <typename GetTileFunction>
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bool canPlaceMod(Vec2I const& pos, TileLayer layer, ModId mod, GetTileFunction& getTile) {
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if (!isRealMod(mod))
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return false;
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auto materialDatabase = Root::singleton().materialDatabase();
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auto mat = getTile(pos).material(layer);
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auto existingMod = getTile(pos).mod(layer);
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return existingMod != mod && materialDatabase->supportsMod(mat, mod);
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}
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template <typename GetTileFunction>
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pair<bool, bool> validateTileModification(EntityMapPtr const& entityMap, Vec2I const& pos, TileModification const& modification, bool allowEntityOverlap, GetTileFunction& getTile) {
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bool good = false;
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bool perhaps = false;
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if (auto placeMaterial = modification.ptr<PlaceMaterial>()) {
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bool allowTileOverlap = placeMaterial->collisionOverride != TileCollisionOverride::None && collisionKindFromOverride(placeMaterial->collisionOverride) < CollisionKind::Dynamic;
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perhaps = WorldImpl::perhapsCanPlaceMaterial(entityMap, pos, placeMaterial->layer, placeMaterial->material, allowEntityOverlap, allowTileOverlap, getTile);
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if (perhaps)
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good = WorldImpl::canPlaceMaterial(entityMap, pos, placeMaterial->layer, placeMaterial->material, allowEntityOverlap, allowTileOverlap, getTile);
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} else if (auto placeMod = modification.ptr<PlaceMod>()) {
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good = WorldImpl::canPlaceMod(pos, placeMod->layer, placeMod->mod, getTile);
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} else if (auto placeMaterialColor = modification.ptr<PlaceMaterialColor>()) {
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good = WorldImpl::canPlaceMaterialColorVariant(pos, placeMaterialColor->layer, placeMaterialColor->color, getTile);
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} else if (modification.is<PlaceLiquid>()) {
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good = getTile(pos).collision == CollisionKind::None;
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} else {
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good = false;
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}
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return { good, perhaps };
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}
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template <typename GetTileFunction>
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pair<TileModificationList, TileModificationList> splitTileModifications(EntityMapPtr const& entityMap, TileModificationList const& modificationList,
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bool allowEntityOverlap, GetTileFunction& getTile, function<bool(Vec2I pos, TileModification modification)> extraCheck) {
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TileModificationList success;
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TileModificationList unknown;
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TileModificationList failures;
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for (auto const& pair : modificationList) {
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bool good = false, perhaps = false;
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if (!extraCheck || extraCheck(pair.first, pair.second))
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std::tie(good, perhaps) = validateTileModification(entityMap, pair.first, pair.second, allowEntityOverlap, getTile);
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if (good)
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success.append(pair);
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else if (perhaps)
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unknown.append(pair);
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else
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failures.append(pair);
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}
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if (!success.empty())
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success.appendAll(unknown);
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else
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failures.appendAll(unknown);
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return {success, failures};
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}
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template <typename TileSectorArray>
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float windLevel(shared_ptr<TileSectorArray> const& tileSectorArray, Vec2F const& position, float weatherWindLevel) {
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auto const& tile = tileSectorArray->tile(Vec2I::floor(position));
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if (tile.material(TileLayer::Background) != EmptyMaterialId)
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return 0.0f;
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if (tile.material(TileLayer::Foreground) != EmptyMaterialId)
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return 0.0f;
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return weatherWindLevel;
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}
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template <typename TileSectorArray>
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bool breathable(World const* world, shared_ptr<TileSectorArray> const& tileSectorArray, HashMap<DungeonId, bool> const& breathableMap,
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WorldTemplateConstPtr const& worldTemplate, Vec2F const& pos) {
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Vec2I ipos = Vec2I::floor(pos);
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float remainder = pos[1] - ipos[1];
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auto materialDatabase = Root::singleton().materialDatabase();
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auto liquidsDatabase = Root::singleton().liquidsDatabase();
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auto tile = tileSectorArray->tile(ipos);
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bool environmentBreathable = breathableMap.maybe(tile.dungeonId).value(worldTemplate->breathable(ipos[0], ipos[1]));
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bool liquidBreathable = remainder >= tile.liquid.level;
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bool foregroundBreathable = tile.collision != CollisionKind::Block || !world->pointCollision(pos);
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return environmentBreathable && foregroundBreathable && liquidBreathable;
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}
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template <typename TileSectorArray>
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float lightLevel(shared_ptr<TileSectorArray> const& tileSectorArray, EntityMapPtr const& entityMap, WorldGeometry const& worldGeometry,
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WorldTemplateConstPtr const& worldTemplate, SkyConstPtr const& sky, CellularLightIntensityCalculator& lighting, Vec2F pos) {
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if (pos[1] < 0 || pos[1] >= worldGeometry.height())
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return 0;
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// tileEach can't handle rects that are WAY out of range.
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pos = worldGeometry.xwrap(pos);
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Vec3F environmentLight = sky->environmentLight().toRgbF();
|
|
float undergroundLevel = worldTemplate->undergroundLevel();
|
|
auto materialDatabase = Root::singleton().materialDatabase();
|
|
auto liquidsDatabase = Root::singleton().liquidsDatabase();
|
|
|
|
lighting.begin(pos);
|
|
|
|
// Each column in tileEvalColumns is guaranteed to be no larger than the
|
|
// sector size.
|
|
CellularLightIntensityCalculator::Cell lightingCellColumn[WorldSectorSize];
|
|
tileSectorArray->tileEvalColumns(lighting.calculationRegion(), [&](Vec2I const& pos, typename TileSectorArray::Tile const* column, size_t ySize) {
|
|
for (size_t y = 0; y < ySize; ++y) {
|
|
auto& tile = column[y];
|
|
auto& cell = lightingCellColumn[y];
|
|
|
|
bool backgroundTransparent = materialDatabase->backgroundLightTransparent(tile.background);
|
|
bool foregroundTransparent = materialDatabase->foregroundLightTransparent(tile.foreground)
|
|
&& tile.collision != CollisionKind::Dynamic;
|
|
|
|
cell = {materialDatabase->radiantLight(tile.foreground, tile.foregroundMod).sum() / 3.0f, !foregroundTransparent};
|
|
cell.light += liquidsDatabase->radiantLight(tile.liquid).sum() / 3.0f;
|
|
if (foregroundTransparent) {
|
|
cell.light += materialDatabase->radiantLight(tile.background, tile.backgroundMod).sum() / 3.0f;
|
|
if (backgroundTransparent && pos[1] > undergroundLevel)
|
|
cell.light += environmentLight.sum() / 3.0f;
|
|
}
|
|
}
|
|
lighting.setCellColumn(pos, lightingCellColumn, ySize);
|
|
});
|
|
|
|
for (auto const& entity : entityMap->entityQuery(RectF(lighting.calculationRegion()))) {
|
|
for (auto const& light : entity->lightSources()) {
|
|
Vec2F position = worldGeometry.nearestTo(Vec2F(lighting.calculationRegion().min()), light.position);
|
|
if (light.pointLight)
|
|
lighting.addPointLight(position, Color::v3bToFloat(light.color).sum() / 3.0f, light.pointBeam, light.beamAngle, light.beamAmbience);
|
|
else
|
|
lighting.addSpreadLight(position, Color::v3bToFloat(light.color).sum() / 3.0f);
|
|
}
|
|
}
|
|
|
|
return lighting.calculate();
|
|
}
|
|
|
|
inline InteractiveEntityPtr getInteractiveInRange(WorldGeometry const& geometry, EntityMapPtr const& entityMap,
|
|
Vec2F const& targetPosition, Vec2F const& sourcePosition, float maxRange) {
|
|
if (auto entity = entityMap->interactiveEntityNear(targetPosition, maxRange)) {
|
|
if (auto tileEntity = as<TileEntity>(entity)) {
|
|
if (isTileEntityInRange(geometry, entityMap, tileEntity->entityId(), sourcePosition, maxRange))
|
|
return entity;
|
|
} else {
|
|
if (geometry.diffToNearestCoordInBox(entity->interactiveBoundBox().translated(entity->position()), sourcePosition) .magnitude() <= maxRange)
|
|
return entity;
|
|
}
|
|
}
|
|
|
|
return {};
|
|
}
|
|
|
|
inline bool isTileEntityInRange(WorldGeometry const& geometry, EntityMapPtr const& entityMap, EntityId targetEntity,
|
|
Vec2F const& sourcePosition, float maxRange) {
|
|
if (auto entity = entityMap->get<TileEntity>(targetEntity)) {
|
|
// If any of the entity spaces is within interaction range, then assume the
|
|
// whole entity is in interaction range
|
|
for (auto space : entity->spaces()) {
|
|
if (geometry.diff(entity->position() + centerOfTile(space), sourcePosition).magnitude() <= maxRange)
|
|
return true;
|
|
}
|
|
}
|
|
|
|
return false;
|
|
}
|
|
|
|
template <typename TileSectorArray>
|
|
bool canReachEntity(WorldGeometry const& geometry, shared_ptr<TileSectorArray> const& tileSectorArray,
|
|
EntityMapPtr const& entityMap, Vec2F const& sourcePosition, float maxRange, EntityId targetEntity, bool preferInteractive) {
|
|
auto entity = entityMap->entity(targetEntity);
|
|
if (!entity)
|
|
return false;
|
|
|
|
// exclude the final tile from the collision check since many targets will be collidable tile entities, e.g. doors
|
|
auto const canReachTile = [&](Vec2F const& end) -> bool {
|
|
Vec2I const& endTile = Vec2I::floor(end);
|
|
return forBlocksAlongLine<float>(sourcePosition, geometry.diff(end, sourcePosition), [=](int x, int y) -> bool {
|
|
Vec2I diff = geometry.diff(endTile, Vec2I(x, y));
|
|
if (diff[0] == 0 && diff[1] == 0)
|
|
return true;
|
|
return !tileSectorArray->tile({x, y}).isColliding(DefaultCollisionSet);
|
|
});
|
|
};
|
|
|
|
if (auto tileEntity = as<TileEntity>(entity)) {
|
|
for (auto space : preferInteractive ? tileEntity->interactiveSpaces() : tileEntity->spaces()) {
|
|
auto spacePosition = entity->position() + centerOfTile(space);
|
|
if (geometry.diff(spacePosition, sourcePosition).magnitude() <= maxRange) {
|
|
if (canReachTile(spacePosition))
|
|
return true;
|
|
}
|
|
}
|
|
} else if (preferInteractive && is<InteractiveEntity>(entity)) {
|
|
auto interactiveEntity = as<InteractiveEntity>(entity);
|
|
auto entityBounds = interactiveEntity->interactiveBoundBox().translated(entity->position());
|
|
if (geometry.rectContains(entityBounds, sourcePosition))
|
|
return true;
|
|
if (!geometry.rectIntersectsCircle(entityBounds, sourcePosition, maxRange))
|
|
return false;
|
|
|
|
return
|
|
!lineTileCollision(geometry, tileSectorArray, sourcePosition, entityBounds.nearestCoordTo(sourcePosition), DefaultCollisionSet) ||
|
|
!lineTileCollision(geometry, tileSectorArray, sourcePosition, Vec2F(entityBounds.xMin(), entityBounds.yMin()), DefaultCollisionSet) ||
|
|
!lineTileCollision(geometry, tileSectorArray, sourcePosition, Vec2F(entityBounds.xMin(), entityBounds.yMax()), DefaultCollisionSet) ||
|
|
!lineTileCollision(geometry, tileSectorArray, sourcePosition, Vec2F(entityBounds.xMax(), entityBounds.yMax()), DefaultCollisionSet) ||
|
|
!lineTileCollision(geometry, tileSectorArray, sourcePosition, Vec2F(entityBounds.xMax(), entityBounds.yMin()), DefaultCollisionSet);
|
|
} else {
|
|
if (geometry.diff(entity->position(), sourcePosition).magnitude() <= maxRange)
|
|
return !lineTileCollision(geometry, tileSectorArray, sourcePosition, entity->position(), DefaultCollisionSet);
|
|
}
|
|
|
|
return false;
|
|
}
|
|
}
|
|
|
|
}
|
|
|
|
#endif
|