dota_factory/src/lib/sim/Simulation.cpp

#include "Simulation.h"

#include <cassert>

#include "AiSystem.h"
#include "BuildingSystem.h"
#include "CombatSystem.h"
#include "DynamicBodySystem.h"
#include "FactionComponent.h"
#include "EventManager.h"
#include "HealthComponent.h"
#include "ModuleOwnerComponent.h"
#include "MovementIntentSystem.h"
#include "PositionComponent.h"
#include "ScrapSystem.h"
#include "ShipIdentityComponent.h"
#include "ShipSystem.h"
#include "StationBodyComponent.h"
#include "SurfaceMask.h"
#include "tracing.h"
#include "WaveSystem.h"
#include "WeaponComponent.h"

Simulation::Simulation(GameConfig config, unsigned int seed)
    : m_config(std::move(config))
    , m_rng(seed)
    , m_currentTick(0)
    , m_nextDepartureTick(secondsToTicks(m_config.world.departureIntervalSeconds))
    , m_nextBuildingId(1)
    , m_buildingBlocksStock(m_config.world.startingBuildingBlocks)
    , m_gameOver(false)
    , m_hqBuildingId(kInvalidBuildingId)
    , m_hqProxyEntity(entt::null)
    , m_playerStation1Entity(entt::null)
    , m_playerStation2Entity(entt::null)
    , m_beltSystem(m_config.world.beltSpeed_tps)
{
    m_currentEnemyStationEntities[0] = entt::null;
    m_currentEnemyStationEntities[1] = entt::null;

    m_buildingSystem = std::make_unique<BuildingSystem>(
        m_config,
        m_beltSystem,
        [this]() { return allocateBuildingId(); },
        [this](int amount) { m_buildingBlocksStock += amount; },
        [this](const std::string& id, QVector2D pos,
               const std::optional<ShipLayoutConfig>& layout) {
            const std::map<std::string, SchematicState>::const_iterator it =
                m_schematicLevels.find(id);
            if (it == m_schematicLevels.end() || !it->second.unlocked)
            {
                return;
            }
            std::map<std::string, int> moduleLevels;
            for (const auto& [mId, mState] : m_moduleSchematicLevels)
            {
                moduleLevels[mId] = mState.level;
            }
            m_shipSystem->spawn(id, it->second.level, pos, /*isEnemy=*/false, layout,
                                moduleLevels);
        },
        [this](const std::string& itemId) -> bool { return isItemUnlocked(itemId); },
        m_rng);
    m_shipSystem     = std::make_unique<ShipSystem>(m_config, m_admin);
    m_aiSystem       = std::make_unique<AiSystem>();
    m_movementIntentSystem = std::make_unique<MovementIntentSystem>();
    m_dynamicBodySystem    = std::make_unique<DynamicBodySystem>();
    m_scrapSystem    = std::make_unique<ScrapSystem>(m_admin);
    m_waveSystem     = std::make_unique<WaveSystem>(m_config, m_rng);
    m_combatSystem   = std::make_unique<CombatSystem>(m_config);

    // Initialize ship schematic unlock state.
    for (const ShipDef& def : m_config.ships.ships)
    {
        SchematicState state;
        state.unlocked = (def.unlockAtStationLevel == -1);
        state.level    = (def.unlockAtStationLevel == -1) ? def.schematic.playerProductionLevel : 0;
        m_schematicLevels[def.id] = state;
    }

    // Initialize module schematic unlock state.
    for (const ModuleDef& def : m_config.modules.modules)
    {
        SchematicState state;
        state.unlocked = (def.unlockAtStationLevel == -1);
        state.level    = (def.unlockAtStationLevel == -1) ? def.playerProductionLevel : 0;
        m_moduleSchematicLevels[def.id] = state;
    }

    // Initialize assembler recipe schematic unlock state.
    for (const RecipeDef& def : m_config.recipes.recipes)
    {
        if (def.building == BuildingType::Assembler
            && def.unlockAtStationLevel.has_value()
            && def.unlockAtStationLevel.value() == -1)
        {
            m_unlockedRecipeSchematicIds.insert(def.id);
        }
    }

    recomputeUnlocked();
    placeInitialStructures();
	registerForEvents();
}

Simulation::~Simulation()
{
	unregisterForEvents();
}

const GameConfig& Simulation::config() const
{
    return m_config;
}

void Simulation::reset(GameConfig newConfig, unsigned int seed)
{
    m_config = std::move(newConfig);
    reset(seed);
}

void Simulation::reset(unsigned int seed)
{
	EventManager::getInstance()->clearEvents();
    m_rng.seed(seed);
    m_currentTick              = 0;
    m_nextDepartureTick        = secondsToTicks(m_config.world.departureIntervalSeconds);
    m_nextBuildingId                   = 1;
    m_buildingBlocksStock      = m_config.world.startingBuildingBlocks;
    m_gameOver                      = false;
    m_hqBuildingId                  = kInvalidBuildingId;
    m_hqProxyEntity                 = entt::null;
    m_playerStation1Entity          = entt::null;
    m_playerStation2Entity          = entt::null;
    m_currentEnemyStationEntities[0] = entt::null;
    m_currentEnemyStationEntities[1] = entt::null;
    m_fireEvents.clear();
    m_schematicDropEvents.clear();

    m_admin.clear();
    m_beltSystem = BeltSystem(m_config.world.beltSpeed_tps);
    m_buildingSystem = std::make_unique<BuildingSystem>(
        m_config,
        m_beltSystem,
        [this]() { return allocateBuildingId(); },
        [this](int amount) { m_buildingBlocksStock += amount; },
        [this](const std::string& id, QVector2D pos,
               const std::optional<ShipLayoutConfig>& layout) {
            const std::map<std::string, SchematicState>::const_iterator it =
                m_schematicLevels.find(id);
            if (it == m_schematicLevels.end() || !it->second.unlocked)
            {
                return;
            }
            std::map<std::string, int> moduleLevels;
            for (const auto& [mId, mState] : m_moduleSchematicLevels)
            {
                moduleLevels[mId] = mState.level;
            }
            m_shipSystem->spawn(id, it->second.level, pos, /*isEnemy=*/false, layout,
                                moduleLevels);
        },
        [this](const std::string& itemId) -> bool { return isItemUnlocked(itemId); },
        m_rng);
    m_shipSystem     = std::make_unique<ShipSystem>(m_config, m_admin);
    m_aiSystem       = std::make_unique<AiSystem>();
    m_movementIntentSystem = std::make_unique<MovementIntentSystem>();
    m_dynamicBodySystem    = std::make_unique<DynamicBodySystem>();
    m_scrapSystem    = std::make_unique<ScrapSystem>(m_admin);
    m_waveSystem     = std::make_unique<WaveSystem>(m_config, m_rng);
    m_combatSystem   = std::make_unique<CombatSystem>(m_config);

    m_schematicLevels.clear();
    for (const ShipDef& def : m_config.ships.ships)
    {
        SchematicState state;
        state.unlocked = (def.unlockAtStationLevel == -1);
        state.level    = (def.unlockAtStationLevel == -1) ? def.schematic.playerProductionLevel : 0;
        m_schematicLevels[def.id] = state;
    }

    m_moduleSchematicLevels.clear();
    for (const ModuleDef& def : m_config.modules.modules)
    {
        SchematicState state;
        state.unlocked = (def.unlockAtStationLevel == -1);
        state.level    = (def.unlockAtStationLevel == -1) ? def.playerProductionLevel : 0;
        m_moduleSchematicLevels[def.id] = state;
    }

    m_unlockedRecipeSchematicIds.clear();
    for (const RecipeDef& def : m_config.recipes.recipes)
    {
        if (def.building == BuildingType::Assembler
            && def.unlockAtStationLevel.has_value()
            && def.unlockAtStationLevel.value() == -1)
        {
            m_unlockedRecipeSchematicIds.insert(def.id);
        }
    }

    recomputeUnlocked();
    placeInitialStructures();
}

// ---------------------------------------------------------------------------
// tick
// ---------------------------------------------------------------------------

void Simulation::tick()
{
	EventManager::getInstance()->processEvents();

    // Step 1: wave scheduler
    m_waveSystem->tickWaveScheduler(m_currentTick, *m_shipSystem,
                                    m_config.world.heightTiles);

    // Step 2: threat accumulation
    m_waveSystem->tickThreatAccumulation();

    // Construction + production pipeline
    m_buildingSystem->tickConstruction(m_currentTick);
    m_buildingSystem->tickBeltPull();                    // step 3
    m_buildingSystem->tickProduction(m_currentTick);     // step 4
    m_buildingSystem->tickShipyardProduction(m_currentTick); // step 4b
    m_buildingSystem->tickBeltPush();                    // step 5
    m_beltSystem.tick();                                 // step 6

    // Step 7: ship behavior systems (movement arbitration via intent priority)

    // Departure timer: release gathered combat ships on a fixed interval (REQ-SHP-RALLY).
    if (m_currentTick >= m_nextDepartureTick)
    {
        m_shipSystem->triggerRallyDeparture();
        m_nextDepartureTick += secondsToTicks(m_config.world.departureIntervalSeconds);
    }

    m_shipSystem->clearMovementIntents();
    m_aiSystem->tickHomeReturnBehavior(m_admin);                                          // priority 4
    m_aiSystem->tickThreatResponseBehavior(m_admin, *m_buildingSystem);                  // priority 3
    m_aiSystem->tickRepairBehavior(m_admin, *m_buildingSystem);                          // priority 2
    m_aiSystem->tickRepairTools(m_admin);
    m_aiSystem->tickSalvageBehavior(m_admin, *m_scrapSystem, *m_buildingSystem);         // priority 1

    // Step 8: combat resolution
    m_combatSystem->tick(m_currentTick, m_admin,
                         *m_buildingSystem, m_fireEvents);

    // Step 8b: deferred damage whose impact tick has arrived
    m_combatSystem->applyPendingDamage(m_currentTick, m_admin);

    // Step 9: deaths & loot
    if (!m_gameOver)
    {
        tickDeathsAndLoot();
    }

    // Step 10: advance ship positions
    m_movementIntentSystem->tick(m_admin);
    m_dynamicBodySystem->tick(m_admin);

    // Step 11: scrap despawn
    m_scrapSystem->tickDespawn(m_currentTick);

    ++m_currentTick;
}

// ---------------------------------------------------------------------------
// Pre-placement
// ---------------------------------------------------------------------------

void Simulation::placeInitialStructures()
{
    // HQ — right edge of asteroid (rightmost asteroid tile is x = -1).
    // Placed as a Building (for belt input) plus an ECS proxy (for HP/targeting).
    const ParsedSurfaceMask hqParsed =
        parseSurfaceMask(m_config.stations.hq.surfaceMask, Rotation::East);
    const int hqAnchorX = -hqParsed.footprint.width();
    const int hqAnchorY =
        (m_config.world.heightTiles - hqParsed.footprint.height()) / 2;
    const float hqHp =
        static_cast<float>(m_config.stations.hq.hpFormula.evaluate(0.0));
    m_hqBuildingId = m_buildingSystem->placeImmediate(
        BuildingType::Hq,
        m_config.stations.hq.surfaceMask,
        QPoint(hqAnchorX, hqAnchorY),
        Rotation::East);

    const QVector2D hqCenter(
        hqAnchorX + hqParsed.footprint.width() / 2.0f,
        hqAnchorY + hqParsed.footprint.height() / 2.0f);
    m_hqProxyEntity = m_admin.spawnHqProxy(hqCenter, hqHp, hqHp);

    // Player defence stations — ECS entities with tile occupancy.
    const ParsedSurfaceMask psParsed =
        parseSurfaceMask(m_config.stations.playerStation.surfaceMask, Rotation::East);
    const int psAnchorX =
        m_config.world.regions.playerBufferWidth_tiles - psParsed.footprint.width();
    const double psLevel = static_cast<double>(m_config.stations.playerStation.level);
    const float psHp = static_cast<float>(
        m_config.stations.playerStation.hpFormula.evaluate(psLevel));

    const float tileSize = static_cast<float>(m_config.world.tileSize_m);

    WeaponComponent psWeapon;
    psWeapon.damage        = static_cast<float>(
        m_config.stations.playerStation.damageFormula.evaluate(psLevel));
    psWeapon.range_tiles   = static_cast<float>(
        m_config.stations.playerStation.rangeFormula.evaluate(psLevel)) / tileSize;
    psWeapon.fireRateHz    = static_cast<float>(
        m_config.stations.playerStation.fireRateFormula.evaluate(psLevel));
    psWeapon.cooldownTicks  = 0.0f;
    psWeapon.currentTarget  = std::nullopt;

    const int ps1Y = m_config.world.heightTiles / 4;
    const int ps2Y = 3 * m_config.world.heightTiles / 4;

    {
        const QPoint anchor(psAnchorX, ps1Y);
        std::vector<QPoint> absCells;
        for (const QPoint& rel : psParsed.bodyCells)
        {
            absCells.push_back(QPoint(anchor.x() + rel.x(), anchor.y() + rel.y()));
        }
        m_playerStation1Entity = m_admin.spawnStation(
            anchor, psParsed.footprint, absCells, psHp, psHp, false);
        {
            entt::entity wChild = m_admin.createModuleEntity();
            m_admin.addComponent<WeaponComponent>(wChild, psWeapon);
            m_admin.addComponent<ModuleOwnerComponent>(wChild,
                ModuleOwnerComponent{m_playerStation1Entity});
        }
        m_buildingSystem->registerTileOccupancy(absCells, allocateBuildingId());
    }
    {
        const QPoint anchor(psAnchorX, ps2Y);
        std::vector<QPoint> absCells;
        for (const QPoint& rel : psParsed.bodyCells)
        {
            absCells.push_back(QPoint(anchor.x() + rel.x(), anchor.y() + rel.y()));
        }
        m_playerStation2Entity = m_admin.spawnStation(
            anchor, psParsed.footprint, absCells, psHp, psHp, false);
        {
            entt::entity wChild = m_admin.createModuleEntity();
            m_admin.addComponent<WeaponComponent>(wChild, psWeapon);
            m_admin.addComponent<ModuleOwnerComponent>(wChild,
                ModuleOwnerComponent{m_playerStation2Entity});
        }
        m_buildingSystem->registerTileOccupancy(absCells, allocateBuildingId());
    }

    // Rally point: center of the player defence stations' X column, world vertical midpoint.
    const float rallyX = static_cast<float>(psAnchorX) + psParsed.footprint.width() / 2.0f;
    const float rallyY = static_cast<float>(m_config.world.heightTiles) / 2.0f;
    m_shipSystem->setRallyPoint(QVector2D(rallyX, rallyY));

    // Enemy defence stations — generation 0 (initial set).
    placeEnemyStationSet(0);
}

void Simulation::placeEnemyStationSet(int generation)
{
    const float tileSize = static_cast<float>(m_config.world.tileSize_m);
    const ParsedSurfaceMask esParsed =
        parseSurfaceMask(m_config.stations.enemyStation.surfaceMask, Rotation::East);

    const int rightEdgeX = m_config.world.regions.playerBufferWidth_tiles
                         + m_config.world.regions.contestZoneWidth_tiles
                         + generation * m_config.world.push.pushExpandColumns_tiles;
    const int anchorX = rightEdgeX - esParsed.footprint.width();

    const double genD = static_cast<double>(generation);
    const float esHp  = static_cast<float>(
        m_config.stations.enemyStation.hpFormula.evaluate(genD));

    WeaponComponent esWeapon;
    esWeapon.damage        = static_cast<float>(
        m_config.stations.enemyStation.damageFormula.evaluate(genD));
    esWeapon.range_tiles   = static_cast<float>(
        m_config.stations.enemyStation.rangeFormula.evaluate(genD)) / tileSize;
    esWeapon.fireRateHz    = static_cast<float>(
        m_config.stations.enemyStation.fireRateFormula.evaluate(genD));
    esWeapon.cooldownTicks  = 0.0f;
    esWeapon.currentTarget  = std::nullopt;

    const int y1 = m_config.world.heightTiles / 4;
    const int y2 = 3 * m_config.world.heightTiles / 4;

    {
        const QPoint anchor(anchorX, y1);
        std::vector<QPoint> absCells;
        for (const QPoint& rel : esParsed.bodyCells)
        {
            absCells.push_back(QPoint(anchor.x() + rel.x(), anchor.y() + rel.y()));
        }
        m_currentEnemyStationEntities[0] = m_admin.spawnStation(
            anchor, esParsed.footprint, absCells, esHp, esHp, true);
        {
            entt::entity wChild = m_admin.createModuleEntity();
            m_admin.addComponent<WeaponComponent>(wChild, esWeapon);
            m_admin.addComponent<ModuleOwnerComponent>(wChild,
                ModuleOwnerComponent{m_currentEnemyStationEntities[0]});
        }
        m_buildingSystem->registerTileOccupancy(absCells, allocateBuildingId());
    }
    {
        const QPoint anchor(anchorX, y2);
        std::vector<QPoint> absCells;
        for (const QPoint& rel : esParsed.bodyCells)
        {
            absCells.push_back(QPoint(anchor.x() + rel.x(), anchor.y() + rel.y()));
        }
        m_currentEnemyStationEntities[1] = m_admin.spawnStation(
            anchor, esParsed.footprint, absCells, esHp, esHp, true);
        {
            entt::entity wChild = m_admin.createModuleEntity();
            m_admin.addComponent<WeaponComponent>(wChild, esWeapon);
            m_admin.addComponent<ModuleOwnerComponent>(wChild,
                ModuleOwnerComponent{m_currentEnemyStationEntities[1]});
        }
        m_buildingSystem->registerTileOccupancy(absCells, allocateBuildingId());
    }
}

// ---------------------------------------------------------------------------
// Deaths & loot (tick step 9)
// ---------------------------------------------------------------------------

void Simulation::tickDeathsAndLoot()
{
	TRACE();
    // --- Dead ships ---
    std::vector<entt::entity> deadShips;
    m_admin.forEach<ShipIdentityComponent, HealthComponent>(
        [&deadShips](entt::entity e, const ShipIdentityComponent& /*si*/,
                     const HealthComponent& h)
        {
            if (h.hp <= 0.0f)
            {
                deadShips.push_back(e);
            }
        });

    for (entt::entity deadEntity : deadShips)
    {
        const ShipIdentityComponent& si = m_admin.get<ShipIdentityComponent>(deadEntity);
        const PositionComponent& pos    = m_admin.get<PositionComponent>(deadEntity);
        for (const ShipDef& def : m_config.ships.ships)
        {
            if (def.id == si.schematicId && def.loot.scrapDrop > 0)
            {
                const Tick despawnAt = m_currentTick
                    + secondsToTicks(m_config.world.scrapDespawnSeconds);
                m_scrapSystem->spawn(pos.value, def.loot.scrapDrop, despawnAt);
                break;
            }
        }
        m_shipSystem->despawn(deadEntity);
    }

    // --- Dead stations ---
    std::vector<entt::entity> deadStations;
    m_admin.forEach<StationBodyComponent, HealthComponent>(
        [&deadStations](entt::entity e, const StationBodyComponent& /*sb*/,
                        const HealthComponent& h)
        {
            if (h.hp <= 0.0f)
            {
                deadStations.push_back(e);
            }
        });

    for (entt::entity deadEntity : deadStations)
    {
        const StationBodyComponent& sb = m_admin.get<StationBodyComponent>(deadEntity);
        const PositionComponent& pos   = m_admin.get<PositionComponent>(deadEntity);
        const FactionComponent& fac    = m_admin.get<FactionComponent>(deadEntity);

        const Tick despawnAt = m_currentTick
            + secondsToTicks(m_config.world.scrapDespawnSeconds);
        int scrap = 0;
        if (!fac.isEnemy)
        {
            const double lv = static_cast<double>(
                m_config.stations.playerStation.level);
            scrap = static_cast<int>(
                m_config.stations.playerStation.scrapDropFormula.evaluate(lv));
        }
        else
        {
            const double genD = static_cast<double>(m_waveSystem->generation());
            scrap = static_cast<int>(
                m_config.stations.enemyStation.scrapDropFormula.evaluate(genD));
        }
        if (scrap > 0)
        {
            m_scrapSystem->spawn(pos.value, scrap, despawnAt);
        }
        m_buildingSystem->unregisterTileOccupancy(sb.bodyCells);
        {
            std::vector<entt::entity> stationChildren;
            m_admin.forEach<ModuleOwnerComponent>(
                [&](entt::entity ce, const ModuleOwnerComponent& o)
                {
                    if (o.owner == deadEntity) { stationChildren.push_back(ce); }
                });
            for (entt::entity ce : stationChildren) { m_admin.destroy(ce); }
        }
        m_admin.destroy(deadEntity);
    }

    // --- HQ death check ---
    if (m_admin.isValid(m_hqProxyEntity))
    {
        const HealthComponent& hqHealth = m_admin.get<HealthComponent>(m_hqProxyEntity);
        if (hqHealth.hp <= 0.0f)
        {
            m_gameOver = true;
        }
    }

    // --- Push check: if both current enemy stations are gone, trigger push ---
    const bool es0Gone = !m_admin.isValid(m_currentEnemyStationEntities[0])
        || m_admin.get<HealthComponent>(m_currentEnemyStationEntities[0]).hp <= 0.0f;
    const bool es1Gone = !m_admin.isValid(m_currentEnemyStationEntities[1])
        || m_admin.get<HealthComponent>(m_currentEnemyStationEntities[1]).hp <= 0.0f;

    if (es0Gone && es1Gone &&
        m_currentEnemyStationEntities[0] != entt::null)
    {
        const int destroyedLevel = m_waveSystem->generation();
        m_waveSystem->onEnemyStationsDestroyed();
        placeEnemyStationSet(m_waveSystem->generation());
        awardSchematicDrop(destroyedLevel);
    }
}

void Simulation::awardSchematicDrop(int destroyedStationLevel)
{
    enum class DropType { Ship, Module, Recipe };
    struct PoolEntry { std::string id; DropType type; };
    std::vector<PoolEntry> pool;

    for (const ShipDef& def : m_config.ships.ships)
    {
        if (def.unlockAtStationLevel == -1 || def.unlockAtStationLevel <= destroyedStationLevel)
        {
            pool.push_back({def.id, DropType::Ship});
        }
    }
    for (const ModuleDef& def : m_config.modules.modules)
    {
        if (def.unlockAtStationLevel == -1 || def.unlockAtStationLevel <= destroyedStationLevel)
        {
            pool.push_back({def.id, DropType::Module});
        }
    }
    for (const RecipeDef& def : m_config.recipes.recipes)
    {
        if (def.building != BuildingType::Assembler) { continue; }
        if (!def.unlockAtStationLevel.has_value()) { continue; }
        const int level = def.unlockAtStationLevel.value();
        if (level < 0 || level > destroyedStationLevel) { continue; }
        if (m_unlockedRecipeSchematicIds.count(def.id) > 0) { continue; }
        bool outputUnlocked = false;
        for (const RecipeOutput& out : def.outputs)
        {
            if (m_unlockedItemIds.count(out.item) > 0) { outputUnlocked = true; break; }
        }
        if (!outputUnlocked) { continue; }
        pool.push_back({def.id, DropType::Recipe});
    }

    std::uniform_int_distribution<int> dist(0, static_cast<int>(pool.size()) - 1);
    const PoolEntry& chosen = pool[static_cast<std::size_t>(dist(m_rng))];

    if (chosen.type == DropType::Recipe)
    {
        m_unlockedRecipeSchematicIds.insert(chosen.id);
        recomputeUnlocked();
    }
    else
    {
        SchematicState& state = (chosen.type == DropType::Module)
            ? m_moduleSchematicLevels.at(chosen.id)
            : m_schematicLevels.at(chosen.id);
        const bool wasNew = !state.unlocked;
        state.unlocked = true;
        state.level   += 1;

        SchematicDropEvent evt;
        evt.schematicId       = chosen.id;
        evt.newLevel          = state.level;
        evt.wasNewUnlock      = wasNew;
        evt.isModuleSchematic = (chosen.type == DropType::Module);
        m_schematicDropEvents.push_back(evt);

        recomputeUnlocked();
    }
}

// ---------------------------------------------------------------------------
// Implicit unlock computation (REQ-LOCK-IMPLICIT)
// ---------------------------------------------------------------------------

void Simulation::recomputeUnlocked()
{
    m_unlockedItemIds.clear();
    m_unlockedRecipeIds.clear();

    for (const ShipDef& def : m_config.ships.ships)
    {
        if (!isSchematicUnlocked(def.id)) { continue; }
        for (const RecipeIngredient& mat : def.schematic.materials)
        {
            m_unlockedItemIds.insert(mat.item);
        }
    }
    for (const ModuleDef& def : m_config.modules.modules)
    {
        if (!isModuleSchematicUnlocked(def.id)) { continue; }
        for (const RecipeIngredient& mat : def.materials)
        {
            m_unlockedItemIds.insert(mat.item);
        }
    }
    for (const RecipeDef& def : m_config.recipes.recipes)
    {
        if (def.building == BuildingType::Assembler
            && def.unlockAtStationLevel.has_value()
            && m_unlockedRecipeSchematicIds.count(def.id) > 0)
        {
            for (const RecipeOutput& out : def.outputs)
            {
                m_unlockedItemIds.insert(out.item);
            }
        }
    }

    bool changed = true;
    while (changed)
    {
        changed = false;
        for (const RecipeDef& recipe : m_config.recipes.recipes)
        {
            if (recipe.building != BuildingType::Miner
                && recipe.building != BuildingType::Smelter
                && recipe.building != BuildingType::Assembler)
            {
                continue;
            }
            if (recipe.building == BuildingType::Assembler
                && recipe.unlockAtStationLevel.has_value()
                && m_unlockedRecipeSchematicIds.count(recipe.id) == 0)
            {
                continue;
            }
            bool producesUnlocked = false;
            for (const RecipeOutput& out : recipe.outputs)
            {
                if (m_unlockedItemIds.count(out.item) > 0)
                {
                    producesUnlocked = true;
                    break;
                }
            }
            if (!producesUnlocked) { continue; }

            if (recipe.building == BuildingType::Miner
                || recipe.building == BuildingType::Assembler)
            {
                m_unlockedRecipeIds.insert(recipe.id);
            }
            for (const RecipeIngredient& ing : recipe.inputs)
            {
                if (m_unlockedItemIds.insert(ing.item).second)
                {
                    changed = true;
                }
            }
        }
    }
}

bool Simulation::isRecipeUnlocked(const std::string& recipeId) const
{
    return m_unlockedRecipeIds.count(recipeId) > 0;
}

bool Simulation::isItemUnlocked(const std::string& itemId) const
{
    return m_unlockedItemIds.count(itemId) > 0;
}

// ---------------------------------------------------------------------------
// Drains
// ---------------------------------------------------------------------------

std::vector<FireEvent> Simulation::drainFireEvents()
{
    std::vector<FireEvent> result;
    result.swap(m_fireEvents);
    return result;
}

std::vector<SchematicDropEvent> Simulation::drainSchematicDropEvents()
{
    std::vector<SchematicDropEvent> result;
    result.swap(m_schematicDropEvents);
    return result;
}

// ---------------------------------------------------------------------------
// Accessors
// ---------------------------------------------------------------------------

Tick Simulation::currentTick() const
{
    return m_currentTick;
}

int Simulation::buildingBlocksStock() const
{
    return m_buildingBlocksStock;
}

bool Simulation::isGameOver() const
{
    return m_gameOver;
}

double Simulation::threatLevel() const
{
    return m_waveSystem->threatLevel();
}

int Simulation::bossWaveCounter() const
{
    return m_waveSystem->bossWaveCounter();
}

Tick Simulation::bossCountdownTicks() const
{
    return m_waveSystem->bossCountdownTicks();
}

Tick Simulation::normalGapRemainingTicks() const
{
    return m_waveSystem->normalGapRemainingTicks();
}

int Simulation::schematicLevel(const std::string& shipId) const
{
    const std::map<std::string, SchematicState>::const_iterator it =
        m_schematicLevels.find(shipId);
    if (it == m_schematicLevels.end())
    {
        return 0;
    }
    return it->second.level;
}

bool Simulation::isSchematicUnlocked(const std::string& shipId) const
{
    const std::map<std::string, SchematicState>::const_iterator it =
        m_schematicLevels.find(shipId);
    if (it == m_schematicLevels.end())
    {
        return false;
    }
    return it->second.unlocked;
}

int Simulation::moduleSchematicLevel(const std::string& moduleId) const
{
    const std::map<std::string, SchematicState>::const_iterator it =
        m_moduleSchematicLevels.find(moduleId);
    if (it == m_moduleSchematicLevels.end())
    {
        return 0;
    }
    return it->second.level;
}

bool Simulation::isModuleSchematicUnlocked(const std::string& moduleId) const
{
    const std::map<std::string, SchematicState>::const_iterator it =
        m_moduleSchematicLevels.find(moduleId);
    if (it == m_moduleSchematicLevels.end())
    {
        return false;
    }
    return it->second.unlocked;
}

BuildingId Simulation::tryPlaceBuilding(BuildingType type, QPoint anchor, Rotation rotation)
{
    int cost = 0;
    for (const BuildingDef& def : m_config.buildings.buildings)
    {
        if (def.type == type)
        {
            cost = def.cost;
            break;
        }
    }
    if (m_buildingBlocksStock < cost)
    {
        return kInvalidBuildingId;
    }
    m_buildingBlocksStock -= cost;
    return m_buildingSystem->place(type, anchor, rotation, m_currentTick);
}

void Simulation::demolish(BuildingId id)
{
    m_buildingBlocksStock += m_buildingSystem->demolish(id);
}

BuildingSystem& Simulation::buildings()
{
    return *m_buildingSystem;
}

const BuildingSystem& Simulation::buildings() const
{
    return *m_buildingSystem;
}

BeltSystem& Simulation::belts()
{
    return m_beltSystem;
}

const BeltSystem& Simulation::belts() const
{
    return m_beltSystem;
}

ShipSystem& Simulation::ships()
{
    return *m_shipSystem;
}

const ShipSystem& Simulation::ships() const
{
    return *m_shipSystem;
}

ScrapSystem& Simulation::scraps()
{
    return *m_scrapSystem;
}

const ScrapSystem& Simulation::scraps() const
{
    return *m_scrapSystem;
}

EntityAdmin& Simulation::admin()
{
    return m_admin;
}

const EntityAdmin& Simulation::admin() const
{
    return m_admin;
}

void Simulation::handleEvent(std::shared_ptr<const TracePrintRequestedEvent> event)
{
	PRINT_TRACES();
}

BuildingId Simulation::allocateBuildingId()
{
    return m_nextBuildingId++;
}