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#include "StarTileDamage.hpp"
#include "StarDataStreamExtra.hpp"
#include "StarRoot.hpp"
#include "StarJsonExtra.hpp"
#include "StarAssets.hpp"
namespace Star {
List<Vec2I> tileAreaBrush(float range, Vec2F const& centerOffset, bool squareMode) {
if (range == 0)
return {};
List<Vec2I> result;
float workingRange = range * (squareMode ? 1 : 2) + (squareMode ? 0 : 1);
Vec2F offset = Vec2F::filled(-workingRange / 2.0f);
Vec2I intOffset = Vec2I::round(offset + centerOffset);
for (int x = 0; x < workingRange; ++x) {
for (int y = 0; y < workingRange; ++y) {
Vec2F fromCenter = Vec2F(x, y) + Vec2F(0.5, 0.5) + offset; // distance to the center of the tile
Vec2I intPos = Vec2I(x, y);
if (squareMode || fromCenter.magnitude() <= range) {
result.append(intPos + intOffset);
}
}
}
sort(result, [](Vec2I const& a, Vec2I const& b) {
auto ams = a.magnitudeSquared();
auto bms = b.magnitudeSquared();
return std::tie(ams, a) < std::tie(bms, b);
});
return result;
}
EnumMap<TileDamageType> const TileDamageTypeNames{
{TileDamageType::Protected, "protected"},
{TileDamageType::Plantish, "plantish"},
{TileDamageType::Blockish, "blockish"},
{TileDamageType::Beamish, "beamish"},
{TileDamageType::Explosive, "explosive"},
{TileDamageType::Fire, "fire"},
{TileDamageType::Tilling, "tilling"}
};
bool tileDamageIsPenetrating(TileDamageType damageType) {
return damageType == TileDamageType::Explosive;
}
TileDamage::TileDamage() : type(), amount(), harvestLevel() {}
TileDamage::TileDamage(TileDamageType type, float amount, unsigned harvestLevel)
: type(type), amount(amount), harvestLevel(harvestLevel) {}
DataStream& operator>>(DataStream& ds, TileDamage& tileDamage) {
ds.read(tileDamage.type);
ds.read(tileDamage.amount);
ds.read(tileDamage.harvestLevel);
return ds;
}
DataStream& operator<<(DataStream& ds, TileDamage const& tileDamage) {
ds.write(tileDamage.type);
ds.write(tileDamage.amount);
ds.write(tileDamage.harvestLevel);
return ds;
}
TileDamageParameters::TileDamageParameters()
: m_damageRecoveryPerSecond(0.0f), m_maximumEffectTime(0.0f), m_totalHealth(0), m_requiredHarvestLevel(0) {}
TileDamageParameters::TileDamageParameters(Json config, Maybe<float> healthOverride, Maybe<unsigned> harvestLevelOverride) {
if (config.type() == Json::Type::String)
config = Root::singleton().assets()->json(config.toString());
for (auto const& pair : config.getObject("damageFactors"))
m_damages[TileDamageTypeNames.getLeft(pair.first)] = pair.second.toFloat();
m_damageRecoveryPerSecond = config.getFloat("damageRecovery");
m_requiredHarvestLevel = config.getUInt("harvestLevel", 1);
m_maximumEffectTime = config.getFloat("maximumEffectTime", 1.5);
m_totalHealth = config.getFloat("totalHealth", 1.0f);
if (healthOverride)
m_totalHealth = *healthOverride;
if (harvestLevelOverride)
m_requiredHarvestLevel = *harvestLevelOverride;
}
float TileDamageParameters::damageDone(TileDamage const& damage) const {
return m_damages.value(damage.type) * damage.amount;
}
float TileDamageParameters::recoveryPerSecond() const {
return m_damageRecoveryPerSecond;
}
unsigned TileDamageParameters::requiredHarvestLevel() const {
return m_requiredHarvestLevel;
}
float TileDamageParameters::maximumEffectTime() const {
return m_maximumEffectTime;
}
float TileDamageParameters::totalHealth() const {
return m_totalHealth;
}
TileDamageParameters TileDamageParameters::sum(TileDamageParameters const& other) const {
TileDamageParameters result;
result.m_damageRecoveryPerSecond = m_damageRecoveryPerSecond + other.m_damageRecoveryPerSecond;
result.m_totalHealth = m_totalHealth + other.m_totalHealth;
result.m_requiredHarvestLevel = max(m_requiredHarvestLevel, other.m_requiredHarvestLevel);
result.m_maximumEffectTime = max(m_maximumEffectTime, other.m_maximumEffectTime);
for (auto key : m_damages.keys()) {
if (other.m_damages.contains(key))
result.m_damages[key] = result.m_totalHealth / ((m_totalHealth / m_damages.value(key, 0)) + (other.m_totalHealth / other.m_damages.value(key, 0)));
else
result.m_damages[key] = m_damages.value(key, 0);
}
for (auto key : m_damages.keys()) {
if (m_damages.contains(key))
result.m_damages[key] = result.m_totalHealth / ((m_totalHealth / m_damages.value(key, 0)) + (other.m_totalHealth / other.m_damages.value(key, 0)));
else
result.m_damages[key] = other.m_damages.value(key, 0);
}
return result;
}
Json TileDamageParameters::toJson() const {
return JsonObject{
{"damageFactors", jsonFromMapK<Map<TileDamageType, float>>(m_damages, [](TileDamageType a) {
return TileDamageTypeNames.getRight(a);
})},
{"damageRecovery", m_damageRecoveryPerSecond},
{"requiredHarvestLevel", m_requiredHarvestLevel},
{"maximumEffectTime", m_maximumEffectTime},
{"totalHealth", m_totalHealth}
};
}
DataStream& operator>>(DataStream& ds, TileDamageParameters& tileDamage) {
ds.readMapContainer(tileDamage.m_damages);
ds.read(tileDamage.m_damageRecoveryPerSecond);
ds.read(tileDamage.m_requiredHarvestLevel);
ds.read(tileDamage.m_maximumEffectTime);
ds.read(tileDamage.m_totalHealth);
return ds;
}
DataStream& operator<<(DataStream& ds, TileDamageParameters const& tileDamage) {
ds.writeMapContainer(tileDamage.m_damages);
ds.write(tileDamage.m_damageRecoveryPerSecond);
ds.write(tileDamage.m_requiredHarvestLevel);
ds.write(tileDamage.m_maximumEffectTime);
ds.write(tileDamage.m_totalHealth);
return ds;
}
TileDamageStatus::TileDamageStatus() {
reset();
}
void TileDamageStatus::reset() {
m_damagePercentage = 0.0f;
m_damageEffectTimeFactor = 0.0f;
m_harvested = false;
m_damageSourcePosition = Vec2F();
m_damageType = TileDamageType::Protected;
m_damageEffectPercentage = 0.0f;
}
void TileDamageStatus::damage(TileDamageParameters const& damageParameters, Vec2F const& sourcePosition, TileDamage const& damage) {
auto percentageDelta = damageParameters.damageDone(damage) / damageParameters.totalHealth();
m_damagePercentage = min(1.0f, m_damagePercentage + percentageDelta);
m_harvested = damage.harvestLevel >= damageParameters.requiredHarvestLevel();
m_damageSourcePosition = sourcePosition;
m_damageType = damage.type;
if (percentageDelta > 0)
m_damageEffectTimeFactor = damageParameters.maximumEffectTime();
updateDamageEffectPercentage();
}
void TileDamageStatus::recover(TileDamageParameters const& damageParameters, float dt) {
// Once the tile becomes dead, it should not recover from it
if (healthy() || dead())
return;
m_damagePercentage -= damageParameters.recoveryPerSecond() * dt / damageParameters.totalHealth();
m_damageEffectTimeFactor -= dt;
if (m_damagePercentage <= 0.0f) {
m_damagePercentage = 0.0f;
m_damageEffectTimeFactor = 0.0f;
m_damageType = TileDamageType::Protected;
}
updateDamageEffectPercentage();
}
bool TileDamageStatus::healthy() const {
return m_damagePercentage <= 0.0f;
}
bool TileDamageStatus::damaged() const {
return m_damagePercentage > 0.0f;
}
bool TileDamageStatus::damageProtected() const {
return m_damageType == TileDamageType::Protected;
}
bool TileDamageStatus::dead() const {
return m_damagePercentage >= 1.0f && m_damageType != TileDamageType::Protected;
}
bool TileDamageStatus::harvested() const {
return m_harvested;
}
DataStream& operator>>(DataStream& ds, TileDamageStatus& tileDamageStatus) {
ds.read(tileDamageStatus.m_damagePercentage);
ds.read(tileDamageStatus.m_damageEffectTimeFactor);
ds.read(tileDamageStatus.m_harvested);
ds.read(tileDamageStatus.m_damageSourcePosition);
ds.read(tileDamageStatus.m_damageType);
tileDamageStatus.updateDamageEffectPercentage();
return ds;
}
DataStream& operator<<(DataStream& ds, TileDamageStatus const& tileDamageStatus) {
ds.write(tileDamageStatus.m_damagePercentage);
ds.write(tileDamageStatus.m_damageEffectTimeFactor);
ds.write(tileDamageStatus.m_harvested);
ds.write(tileDamageStatus.m_damageSourcePosition);
ds.write(tileDamageStatus.m_damageType);
return ds;
}
void TileDamageStatus::updateDamageEffectPercentage() {
m_damageEffectPercentage = clamp(m_damageEffectTimeFactor, 0.0f, 1.0f) * m_damagePercentage;
}
EntityTileDamageStatus::EntityTileDamageStatus() {
m_damagePercentage.setFixedPointBase(0.001f);
m_damageEffectTimeFactor.setFixedPointBase(0.001f);
m_damagePercentage.setInterpolator(lerp<float, float>);
m_damageEffectTimeFactor.setInterpolator(lerp<float, float>);
addNetElement(&m_damagePercentage);
addNetElement(&m_damageEffectTimeFactor);
addNetElement(&m_damageHarvested);
addNetElement(&m_damageType);
}
float EntityTileDamageStatus::damagePercentage() const {
return m_damagePercentage.get();
}
float EntityTileDamageStatus::damageEffectPercentage() const {
return clamp(m_damageEffectTimeFactor.get(), 0.0f, 1.0f) * m_damagePercentage.get();
}
TileDamageType EntityTileDamageStatus::damageType() const {
return m_damageType.get();
}
void EntityTileDamageStatus::reset() {
m_damagePercentage.set(0.0f);
m_damageEffectTimeFactor.set(0.0f);
m_damageHarvested.set(false);
}
void EntityTileDamageStatus::damage(TileDamageParameters const& damageParameters, TileDamage const& damage) {
auto percentageDelta = damageParameters.damageDone(damage) / damageParameters.totalHealth();
m_damagePercentage.set(min(1.0f, m_damagePercentage.get() + percentageDelta));
m_damageHarvested.set(damage.harvestLevel >= damageParameters.requiredHarvestLevel());
m_damageType.set(damage.type);
if (percentageDelta > 0)
m_damageEffectTimeFactor.set(damageParameters.maximumEffectTime());
}
void EntityTileDamageStatus::recover(TileDamageParameters const& damageParameters, float dt) {
// Once the tile becomes dead, it should not recover from it
if (healthy() || dead())
return;
m_damagePercentage.set(m_damagePercentage.get() - damageParameters.recoveryPerSecond() * dt / damageParameters.totalHealth());
m_damageEffectTimeFactor.set(m_damageEffectTimeFactor.get() - dt);
if (m_damagePercentage.get() <= 0.0f) {
m_damagePercentage.set(0.0f);
m_damageEffectTimeFactor.set(0.0f);
m_damageType.set(TileDamageType::Protected);
}
}
bool EntityTileDamageStatus::healthy() const {
return m_damagePercentage.get() <= 0.0f;
}
bool EntityTileDamageStatus::damaged() const {
return m_damagePercentage.get() > 0.0f;
}
bool EntityTileDamageStatus::damageProtected() const {
return m_damageType.get() == TileDamageType::Protected;
}
bool EntityTileDamageStatus::dead() const {
return m_damagePercentage.get() >= 1.0f && m_damageType.get() != TileDamageType::Protected;
}
bool EntityTileDamageStatus::harvested() const {
return m_damageHarvested.get();
}
}
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