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vcmi/lib/HeroBonus.cpp
Konstantin a0987313ba vcmi: convert intelligence
Intelligence is converted to both global effect and skill bonus

Bonus name HERO_MANA_PER_TEN_KNOWLEDGE is a little weird, but works
like old SECONDARY_SKILL_PREMY bonus
2023-03-16 16:46:41 +03:00

2623 lines
68 KiB
C++

/*
* HeroBonus.cpp, part of VCMI engine
*
* Authors: listed in file AUTHORS in main folder
*
* License: GNU General Public License v2.0 or later
* Full text of license available in license.txt file, in main folder
*
*/
#include "StdInc.h"
#include "HeroBonus.h"
#include "VCMI_Lib.h"
#include "spells/CSpellHandler.h"
#include "CCreatureHandler.h"
#include "CCreatureSet.h"
#include "CHeroHandler.h"
#include "CTownHandler.h"
#include "CGeneralTextHandler.h"
#include "CSkillHandler.h"
#include "CStack.h"
#include "CArtHandler.h"
#include "CModHandler.h"
#include "TerrainHandler.h"
#include "StringConstants.h"
#include "battle/BattleInfo.h"
VCMI_LIB_NAMESPACE_BEGIN
#define FOREACH_PARENT(pname) TNodes lparents; getParents(lparents); for(CBonusSystemNode *pname : lparents)
#define FOREACH_RED_CHILD(pname) TNodes lchildren; getRedChildren(lchildren); for(CBonusSystemNode *pname : lchildren)
#define BONUS_NAME(x) { #x, Bonus::x },
const std::map<std::string, Bonus::BonusType> bonusNameMap = {
BONUS_LIST
{"SIGHT_RADIOUS", Bonus::SIGHT_RADIUS} /*the correct word is RADIUS, but this one's already used in mods. Deprecated. */
};
#undef BONUS_NAME
#define BONUS_VALUE(x) { #x, Bonus::x },
const std::map<std::string, Bonus::ValueType> bonusValueMap = { BONUS_VALUE_LIST };
#undef BONUS_VALUE
#define BONUS_SOURCE(x) { #x, Bonus::x },
const std::map<std::string, Bonus::BonusSource> bonusSourceMap = { BONUS_SOURCE_LIST };
#undef BONUS_SOURCE
#define BONUS_ITEM(x) { #x, Bonus::x },
const std::map<std::string, ui16> bonusDurationMap =
{
BONUS_ITEM(PERMANENT)
BONUS_ITEM(ONE_BATTLE)
BONUS_ITEM(ONE_DAY)
BONUS_ITEM(ONE_WEEK)
BONUS_ITEM(N_TURNS)
BONUS_ITEM(N_DAYS)
BONUS_ITEM(UNTIL_BEING_ATTACKED)
BONUS_ITEM(UNTIL_ATTACK)
BONUS_ITEM(STACK_GETS_TURN)
BONUS_ITEM(COMMANDER_KILLED)
{ "UNITL_BEING_ATTACKED", Bonus::UNTIL_BEING_ATTACKED }//typo, but used in some mods
};
const std::map<std::string, Bonus::LimitEffect> bonusLimitEffect =
{
BONUS_ITEM(NO_LIMIT)
BONUS_ITEM(ONLY_DISTANCE_FIGHT)
BONUS_ITEM(ONLY_MELEE_FIGHT)
BONUS_ITEM(ONLY_ENEMY_ARMY)
};
const std::map<std::string, TLimiterPtr> bonusLimiterMap =
{
{"SHOOTER_ONLY", std::make_shared<HasAnotherBonusLimiter>(Bonus::SHOOTER)},
{"DRAGON_NATURE", std::make_shared<HasAnotherBonusLimiter>(Bonus::DRAGON_NATURE)},
{"IS_UNDEAD", std::make_shared<HasAnotherBonusLimiter>(Bonus::UNDEAD)},
{"CREATURE_NATIVE_TERRAIN", std::make_shared<CreatureTerrainLimiter>()},
{"CREATURE_FACTION", std::make_shared<CreatureFactionLimiter>()},
{"OPPOSITE_SIDE", std::make_shared<OppositeSideLimiter>()}
};
const std::map<std::string, TPropagatorPtr> bonusPropagatorMap =
{
{"BATTLE_WIDE", std::make_shared<CPropagatorNodeType>(CBonusSystemNode::BATTLE)},
{"VISITED_TOWN_AND_VISITOR", std::make_shared<CPropagatorNodeType>(CBonusSystemNode::TOWN_AND_VISITOR)},
{"PLAYER_PROPAGATOR", std::make_shared<CPropagatorNodeType>(CBonusSystemNode::PLAYER)},
{"HERO", std::make_shared<CPropagatorNodeType>(CBonusSystemNode::HERO)},
{"TEAM_PROPAGATOR", std::make_shared<CPropagatorNodeType>(CBonusSystemNode::TEAM)}, //untested
{"GLOBAL_EFFECT", std::make_shared<CPropagatorNodeType>(CBonusSystemNode::GLOBAL_EFFECTS)},
{"ALL_CREATURES", std::make_shared<CPropagatorNodeType>(CBonusSystemNode::ALL_CREATURES)}
}; //untested
const std::map<std::string, TUpdaterPtr> bonusUpdaterMap =
{
{"TIMES_HERO_LEVEL", std::make_shared<TimesHeroLevelUpdater>()},
{"TIMES_STACK_LEVEL", std::make_shared<TimesStackLevelUpdater>()}
};
///CBonusProxy
CBonusProxy::CBonusProxy(const IBonusBearer * Target, CSelector Selector)
: bonusListCachedLast(0),
target(Target),
selector(Selector),
bonusList(),
currentBonusListIndex(0),
swapGuard()
{
}
CBonusProxy::CBonusProxy(const CBonusProxy & other)
: bonusListCachedLast(other.bonusListCachedLast),
target(other.target),
selector(other.selector),
currentBonusListIndex(other.currentBonusListIndex),
swapGuard()
{
bonusList[currentBonusListIndex] = other.bonusList[currentBonusListIndex];
}
CBonusProxy::CBonusProxy(CBonusProxy && other)
: bonusListCachedLast(0),
target(other.target),
selector(),
bonusList(),
currentBonusListIndex(0),
swapGuard()
{
std::swap(bonusListCachedLast, other.bonusListCachedLast);
std::swap(selector, other.selector);
std::swap(bonusList, other.bonusList);
std::swap(currentBonusListIndex, other.currentBonusListIndex);
}
CBonusProxy & CBonusProxy::operator=(const CBonusProxy & other)
{
boost::lock_guard<boost::mutex> lock(swapGuard);
selector = other.selector;
swapBonusList(other.bonusList[other.currentBonusListIndex]);
bonusListCachedLast = other.bonusListCachedLast;
return *this;
}
CBonusProxy & CBonusProxy::operator=(CBonusProxy && other)
{
std::swap(bonusListCachedLast, other.bonusListCachedLast);
std::swap(selector, other.selector);
std::swap(bonusList, other.bonusList);
std::swap(currentBonusListIndex, other.currentBonusListIndex);
return *this;
}
void CBonusProxy::swapBonusList(TConstBonusListPtr other) const
{
// The idea here is to avoid changing active bonusList while it can be read by a different thread.
// Because such use of shared ptr is not thread safe
// So to avoid this we change the second offline instance and swap active index
auto newCurrent = 1 - currentBonusListIndex;
bonusList[newCurrent] = other;
currentBonusListIndex = newCurrent;
}
TConstBonusListPtr CBonusProxy::getBonusList() const
{
auto needUpdateBonusList = [&]() -> bool
{
return target->getTreeVersion() != bonusListCachedLast || !bonusList[currentBonusListIndex];
};
// avoid locking if everything is up-to-date
if(needUpdateBonusList())
{
boost::lock_guard<boost::mutex>lock(swapGuard);
if(needUpdateBonusList())
{
//TODO: support limiters
swapBonusList(target->getAllBonuses(selector, Selector::all));
bonusListCachedLast = target->getTreeVersion();
}
}
return bonusList[currentBonusListIndex];
}
const BonusList * CBonusProxy::operator->() const
{
return getBonusList().get();
}
CTotalsProxy::CTotalsProxy(const IBonusBearer * Target, CSelector Selector, int InitialValue)
: CBonusProxy(Target, Selector),
initialValue(InitialValue),
meleeCachedLast(0),
meleeValue(0),
rangedCachedLast(0),
rangedValue(0),
value(0),
valueCachedLast(0)
{
}
CTotalsProxy::CTotalsProxy(const CTotalsProxy & other)
: CBonusProxy(other),
initialValue(other.initialValue),
meleeCachedLast(other.meleeCachedLast),
meleeValue(other.meleeValue),
rangedCachedLast(other.rangedCachedLast),
rangedValue(other.rangedValue)
{
}
CTotalsProxy & CTotalsProxy::operator=(const CTotalsProxy & other)
{
CBonusProxy::operator=(other);
initialValue = other.initialValue;
meleeCachedLast = other.meleeCachedLast;
meleeValue = other.meleeValue;
rangedCachedLast = other.rangedCachedLast;
rangedValue = other.rangedValue;
value = other.value;
valueCachedLast = other.valueCachedLast;
return *this;
}
int CTotalsProxy::getValue() const
{
const auto treeVersion = target->getTreeVersion();
if(treeVersion != valueCachedLast)
{
auto bonuses = getBonusList();
value = initialValue + bonuses->totalValue();
valueCachedLast = treeVersion;
}
return value;
}
int CTotalsProxy::getValueAndList(TConstBonusListPtr & outBonusList) const
{
const auto treeVersion = target->getTreeVersion();
outBonusList = getBonusList();
if(treeVersion != valueCachedLast)
{
value = initialValue + outBonusList->totalValue();
valueCachedLast = treeVersion;
}
return value;
}
int CTotalsProxy::getMeleeValue() const
{
static const auto limit = Selector::effectRange()(Bonus::NO_LIMIT).Or(Selector::effectRange()(Bonus::ONLY_MELEE_FIGHT));
const auto treeVersion = target->getTreeVersion();
if(treeVersion != meleeCachedLast)
{
auto bonuses = target->getBonuses(selector, limit);
meleeValue = initialValue + bonuses->totalValue();
meleeCachedLast = treeVersion;
}
return meleeValue;
}
int CTotalsProxy::getRangedValue() const
{
static const auto limit = Selector::effectRange()(Bonus::NO_LIMIT).Or(Selector::effectRange()(Bonus::ONLY_DISTANCE_FIGHT));
const auto treeVersion = target->getTreeVersion();
if(treeVersion != rangedCachedLast)
{
auto bonuses = target->getBonuses(selector, limit);
rangedValue = initialValue + bonuses->totalValue();
rangedCachedLast = treeVersion;
}
return rangedValue;
}
///CCheckProxy
CCheckProxy::CCheckProxy(const IBonusBearer * Target, CSelector Selector)
: target(Target),
selector(Selector),
cachedLast(0),
hasBonus(false)
{
}
CCheckProxy::CCheckProxy(const CCheckProxy & other)
: target(other.target),
selector(other.selector),
cachedLast(other.cachedLast),
hasBonus(other.hasBonus)
{
}
bool CCheckProxy::getHasBonus() const
{
const auto treeVersion = target->getTreeVersion();
if(treeVersion != cachedLast)
{
hasBonus = target->hasBonus(selector);
cachedLast = treeVersion;
}
return hasBonus;
}
CAddInfo::CAddInfo()
{
}
CAddInfo::CAddInfo(si32 value)
{
if(value != CAddInfo::NONE)
push_back(value);
}
bool CAddInfo::operator==(si32 value) const
{
switch(size())
{
case 0:
return value == CAddInfo::NONE;
case 1:
return operator[](0) == value;
default:
return false;
}
}
bool CAddInfo::operator!=(si32 value) const
{
return !operator==(value);
}
si32 & CAddInfo::operator[](size_type pos)
{
if(pos >= size())
resize(pos + 1, CAddInfo::NONE);
return vector::operator[](pos);
}
si32 CAddInfo::operator[](size_type pos) const
{
return pos < size() ? vector::operator[](pos) : CAddInfo::NONE;
}
std::string CAddInfo::toString() const
{
return toJsonNode().toJson(true);
}
JsonNode CAddInfo::toJsonNode() const
{
if(size() < 2)
{
return JsonUtils::intNode(operator[](0));
}
else
{
JsonNode node(JsonNode::JsonType::DATA_VECTOR);
for(si32 value : *this)
node.Vector().push_back(JsonUtils::intNode(value));
return node;
}
}
std::atomic<int32_t> CBonusSystemNode::treeChanged(1);
const bool CBonusSystemNode::cachingEnabled = true;
BonusList::BonusList(bool BelongsToTree) : belongsToTree(BelongsToTree)
{
}
BonusList::BonusList(const BonusList &bonusList)
{
bonuses.resize(bonusList.size());
std::copy(bonusList.begin(), bonusList.end(), bonuses.begin());
belongsToTree = false;
}
BonusList::BonusList(BonusList&& other):
belongsToTree(false)
{
std::swap(belongsToTree, other.belongsToTree);
std::swap(bonuses, other.bonuses);
}
BonusList& BonusList::operator=(const BonusList &bonusList)
{
bonuses.resize(bonusList.size());
std::copy(bonusList.begin(), bonusList.end(), bonuses.begin());
belongsToTree = false;
return *this;
}
void BonusList::changed()
{
if(belongsToTree)
CBonusSystemNode::treeHasChanged();
}
void BonusList::stackBonuses()
{
boost::sort(bonuses, [](std::shared_ptr<Bonus> b1, std::shared_ptr<Bonus> b2) -> bool
{
if(b1 == b2)
return false;
#define COMPARE_ATT(ATT) if(b1->ATT != b2->ATT) return b1->ATT < b2->ATT
COMPARE_ATT(stacking);
COMPARE_ATT(type);
COMPARE_ATT(subtype);
COMPARE_ATT(valType);
#undef COMPARE_ATT
return b1->val > b2->val;
});
// remove non-stacking
size_t next = 1;
while(next < bonuses.size())
{
bool remove;
std::shared_ptr<Bonus> last = bonuses[next-1];
std::shared_ptr<Bonus> current = bonuses[next];
if(current->stacking.empty())
remove = current == last;
else if(current->stacking == "ALWAYS")
remove = false;
else
remove = current->stacking == last->stacking
&& current->type == last->type
&& current->subtype == last->subtype
&& current->valType == last->valType;
if(remove)
bonuses.erase(bonuses.begin() + next);
else
next++;
}
}
int BonusList::totalValue() const
{
struct BonusCollection
{
int base = 0;
int percentToBase = 0;
int percentToAll = 0;
int additive = 0;
int percentToSource;
int indepMin = std::numeric_limits<int>::max();
int indepMax = std::numeric_limits<int>::min();
};
auto percent = [](int base, int percent) -> int {return (base * (100 + percent)) / 100; };
std::array <BonusCollection, Bonus::BonusSource::NUM_BONUS_SOURCE> sources = {};
BonusCollection any;
bool hasIndepMax = false;
bool hasIndepMin = false;
for(std::shared_ptr<Bonus> b : bonuses)
{
switch(b->valType)
{
case Bonus::BASE_NUMBER:
sources[b->source].base += b->val;
break;
case Bonus::PERCENT_TO_ALL:
sources[b->source].percentToAll += b->val;
break;
case Bonus::PERCENT_TO_BASE:
sources[b->source].percentToBase += b->val;
break;
case Bonus::PERCENT_TO_SOURCE:
sources[b->source].percentToSource += b->val;
break;
case Bonus::PERCENT_TO_TARGET_TYPE:
sources[b->targetSourceType].percentToSource += b->val;
break;
case Bonus::ADDITIVE_VALUE:
sources[b->source].additive += b->val;
break;
case Bonus::INDEPENDENT_MAX:
hasIndepMax = true;
vstd::amax(sources[b->source].indepMax, b->val);
break;
case Bonus::INDEPENDENT_MIN:
hasIndepMin = true;
vstd::amin(sources[b->source].indepMin, b->val);
break;
}
}
for(auto src : sources)
{
any.base += percent(src.base ,src.percentToSource);
any.percentToBase += percent(src.percentToBase, src.percentToSource);
any.percentToAll += percent(src.percentToAll, src.percentToSource);
any.additive += percent(src.additive, src.percentToSource);
if(hasIndepMin)
vstd::amin(any.indepMin, percent(src.indepMin, src.percentToSource));
if(hasIndepMax)
vstd::amax(any.indepMax, percent(src.indepMin, src.percentToSource));
}
any.base = percent(any.base, any.percentToBase);
any.base += any.additive;
auto valFirst = percent(any.base ,any.percentToAll);
if(hasIndepMin && hasIndepMax)
assert(any.indepMin < any.indepMax);
const int notIndepBonuses = (int)std::count_if(bonuses.cbegin(), bonuses.cend(), [](const std::shared_ptr<Bonus>& b)
{
return b->valType != Bonus::INDEPENDENT_MAX && b->valType != Bonus::INDEPENDENT_MIN;
});
if (hasIndepMax)
{
if(notIndepBonuses)
vstd::amax(valFirst, any.indepMax);
else
valFirst = any.indepMax;
}
if (hasIndepMin)
{
if(notIndepBonuses)
vstd::amin(valFirst, any.indepMin);
else
valFirst = any.indepMin;
}
return valFirst;
}
std::shared_ptr<Bonus> BonusList::getFirst(const CSelector &select)
{
for (auto & b : bonuses)
{
if(select(b.get()))
return b;
}
return nullptr;
}
std::shared_ptr<const Bonus> BonusList::getFirst(const CSelector &selector) const
{
for (auto & b : bonuses)
{
if(selector(b.get()))
return b;
}
return nullptr;
}
void BonusList::getBonuses(BonusList & out, const CSelector &selector) const
{
getBonuses(out, selector, nullptr);
}
void BonusList::getBonuses(BonusList & out, const CSelector &selector, const CSelector &limit) const
{
out.reserve(bonuses.size());
for (auto & b : bonuses)
{
//add matching bonuses that matches limit predicate or have NO_LIMIT if no given predicate
auto noFightLimit = b->effectRange == Bonus::NO_LIMIT || b->effectRange == Bonus::ONLY_ENEMY_ARMY;
if(selector(b.get()) && ((!limit && noFightLimit) || ((bool)limit && limit(b.get()))))
out.push_back(b);
}
}
void BonusList::getAllBonuses(BonusList &out) const
{
for(auto & b : bonuses)
out.push_back(b);
}
int BonusList::valOfBonuses(const CSelector &select) const
{
BonusList ret;
CSelector limit = nullptr;
getBonuses(ret, select, limit);
return ret.totalValue();
}
JsonNode BonusList::toJsonNode() const
{
JsonNode node(JsonNode::JsonType::DATA_VECTOR);
for(std::shared_ptr<Bonus> b : bonuses)
node.Vector().push_back(b->toJsonNode());
return node;
}
void BonusList::push_back(std::shared_ptr<Bonus> x)
{
bonuses.push_back(x);
changed();
}
BonusList::TInternalContainer::iterator BonusList::erase(const int position)
{
changed();
return bonuses.erase(bonuses.begin() + position);
}
void BonusList::clear()
{
bonuses.clear();
changed();
}
std::vector<BonusList*>::size_type BonusList::operator-=(std::shared_ptr<Bonus> const &i)
{
auto itr = std::find(bonuses.begin(), bonuses.end(), i);
if(itr == bonuses.end())
return false;
bonuses.erase(itr);
changed();
return true;
}
void BonusList::resize(BonusList::TInternalContainer::size_type sz, std::shared_ptr<Bonus> c )
{
bonuses.resize(sz, c);
changed();
}
void BonusList::reserve(TInternalContainer::size_type sz)
{
bonuses.reserve(sz);
}
void BonusList::insert(BonusList::TInternalContainer::iterator position, BonusList::TInternalContainer::size_type n, std::shared_ptr<Bonus> const &x)
{
bonuses.insert(position, n, x);
changed();
}
CSelector IBonusBearer::anaffectedByMoraleSelector =
Selector::type()(Bonus::NON_LIVING)
.Or(Selector::type()(Bonus::UNDEAD))
.Or(Selector::type()(Bonus::SIEGE_WEAPON))
.Or(Selector::type()(Bonus::NO_MORALE))
.Or(Selector::type()(Bonus::BLOCK_MORALE));
CSelector IBonusBearer::moraleSelector = Selector::type()(Bonus::MORALE);
CSelector IBonusBearer::luckSelector = Selector::type()(Bonus::LUCK);
CSelector IBonusBearer::selfMoraleSelector = Selector::type()(Bonus::SELF_MORALE);
CSelector IBonusBearer::selfLuckSelector = Selector::type()(Bonus::SELF_LUCK);
IBonusBearer::IBonusBearer()
:anaffectedByMorale(this, anaffectedByMoraleSelector),
moraleValue(this, moraleSelector, 0),
luckValue(this, luckSelector, 0),
selfMorale(this, selfMoraleSelector),
selfLuck(this, selfLuckSelector)
{
}
int IBonusBearer::valOfBonuses(Bonus::BonusType type, const CSelector &selector) const
{
return valOfBonuses(Selector::type()(type).And(selector));
}
int IBonusBearer::valOfBonuses(Bonus::BonusType type, int subtype) const
{
//This part is performance-critical
std::string cachingStr = "type_" + std::to_string(int(type)) + "_" + std::to_string(subtype);
CSelector s = Selector::type()(type);
if(subtype != -1)
s = s.And(Selector::subtype()(subtype));
return valOfBonuses(s, cachingStr);
}
int IBonusBearer::valOfBonuses(const CSelector &selector, const std::string &cachingStr) const
{
CSelector limit = nullptr;
TConstBonusListPtr hlp = getAllBonuses(selector, limit, nullptr, cachingStr);
return hlp->totalValue();
}
bool IBonusBearer::hasBonus(const CSelector &selector, const std::string &cachingStr) const
{
//TODO: We don't need to count all bonuses and could break on first matching
return getBonuses(selector, cachingStr)->size() > 0;
}
bool IBonusBearer::hasBonus(const CSelector &selector, const CSelector &limit, const std::string &cachingStr) const
{
return getBonuses(selector, limit, cachingStr)->size() > 0;
}
bool IBonusBearer::hasBonusOfType(Bonus::BonusType type, int subtype) const
{
//This part is performance-ciritcal
std::string cachingStr = "type_" + std::to_string(int(type)) + "_" + std::to_string(subtype);
CSelector s = Selector::type()(type);
if(subtype != -1)
s = s.And(Selector::subtype()(subtype));
return hasBonus(s, cachingStr);
}
TConstBonusListPtr IBonusBearer::getBonuses(const CSelector &selector, const std::string &cachingStr) const
{
return getAllBonuses(selector, nullptr, nullptr, cachingStr);
}
TConstBonusListPtr IBonusBearer::getBonuses(const CSelector &selector, const CSelector &limit, const std::string &cachingStr) const
{
return getAllBonuses(selector, limit, nullptr, cachingStr);
}
bool IBonusBearer::hasBonusFrom(Bonus::BonusSource source, ui32 sourceID) const
{
boost::format fmt("source_%did_%d");
fmt % (int)source % sourceID;
return hasBonus(Selector::source(source,sourceID), fmt.str());
}
int IBonusBearer::MoraleVal() const
{
if(anaffectedByMorale.getHasBonus())
return 0;
int ret = moraleValue.getValue();
if(selfMorale.getHasBonus()) //eg. minotaur
vstd::amax(ret, +1);
return vstd::abetween(ret, -3, +3);
}
int IBonusBearer::LuckVal() const
{
if(hasBonusOfType(Bonus::NO_LUCK))
return 0;
int ret = luckValue.getValue();
if(selfLuck.getHasBonus()) //eg. halfling
vstd::amax(ret, +1);
return vstd::abetween(ret, -3, +3);
}
int IBonusBearer::MoraleValAndBonusList(TConstBonusListPtr & bonusList) const
{
if(anaffectedByMorale.getHasBonus())
{
if(!bonusList->empty())
bonusList = std::make_shared<const BonusList>();
return 0;
}
int ret = moraleValue.getValueAndList(bonusList);
if(selfMorale.getHasBonus()) //eg. minotaur
vstd::amax(ret, +1);
return vstd::abetween(ret, -3, +3);
}
int IBonusBearer::LuckValAndBonusList(TConstBonusListPtr & bonusList) const
{
if(hasBonusOfType(Bonus::NO_LUCK))
{
if(!bonusList->empty())
bonusList = std::make_shared<const BonusList>();
return 0;
}
int ret = luckValue.getValueAndList(bonusList);
if(selfLuck.getHasBonus()) //eg. halfling
vstd::amax(ret, +1);
return vstd::abetween(ret, -3, +3);
}
ui32 IBonusBearer::MaxHealth() const
{
const std::string cachingStr = "type_STACK_HEALTH";
static const auto selector = Selector::type()(Bonus::STACK_HEALTH);
auto value = valOfBonuses(selector, cachingStr);
return std::max(1, value); //never 0
}
int IBonusBearer::getAttack(bool ranged) const
{
const std::string cachingStr = "type_PRIMARY_SKILLs_ATTACK";
static const auto selector = Selector::typeSubtype(Bonus::PRIMARY_SKILL, PrimarySkill::ATTACK);
return getBonuses(selector, nullptr, cachingStr)->totalValue();
}
int IBonusBearer::getDefense(bool ranged) const
{
const std::string cachingStr = "type_PRIMARY_SKILLs_DEFENSE";
static const auto selector = Selector::typeSubtype(Bonus::PRIMARY_SKILL, PrimarySkill::DEFENSE);
return getBonuses(selector, nullptr, cachingStr)->totalValue();
}
int IBonusBearer::getMinDamage(bool ranged) const
{
const std::string cachingStr = "type_CREATURE_DAMAGEs_0Otype_CREATURE_DAMAGEs_1";
static const auto selector = Selector::typeSubtype(Bonus::CREATURE_DAMAGE, 0).Or(Selector::typeSubtype(Bonus::CREATURE_DAMAGE, 1));
return valOfBonuses(selector, cachingStr);
}
int IBonusBearer::getMaxDamage(bool ranged) const
{
const std::string cachingStr = "type_CREATURE_DAMAGEs_0Otype_CREATURE_DAMAGEs_2";
static const auto selector = Selector::typeSubtype(Bonus::CREATURE_DAMAGE, 0).Or(Selector::typeSubtype(Bonus::CREATURE_DAMAGE, 2));
return valOfBonuses(selector, cachingStr);
}
si32 IBonusBearer::manaLimit() const
{
return 0;
}
int IBonusBearer::getPrimSkillLevel(PrimarySkill::PrimarySkill id) const
{
static const CSelector selectorAllSkills = Selector::type()(Bonus::PRIMARY_SKILL);
static const std::string keyAllSkills = "type_PRIMARY_SKILL";
auto allSkills = getBonuses(selectorAllSkills, keyAllSkills);
auto ret = allSkills->valOfBonuses(Selector::subtype()(id));
auto minSkillValue = (id == PrimarySkill::SPELL_POWER || id == PrimarySkill::KNOWLEDGE) ? 1 : 0;
vstd::amax(ret, minSkillValue); //otherwise, some artifacts may cause negative skill value effect
return ret; //sp=0 works in old saves
}
si32 IBonusBearer::magicResistance() const
{
return valOfBonuses(Bonus::MAGIC_RESISTANCE);
}
ui32 IBonusBearer::Speed(int turn, bool useBind) const
{
//war machines cannot move
if(hasBonus(Selector::type()(Bonus::SIEGE_WEAPON).And(Selector::turns(turn))))
{
return 0;
}
//bind effect check - doesn't influence stack initiative
if(useBind && hasBonus(Selector::type()(Bonus::BIND_EFFECT).And(Selector::turns(turn))))
{
return 0;
}
return valOfBonuses(Selector::type()(Bonus::STACKS_SPEED).And(Selector::turns(turn)));
}
bool IBonusBearer::isLiving() const //TODO: theoreticaly there exists "LIVING" bonus in stack experience documentation
{
static const std::string cachingStr = "IBonusBearer::isLiving";
static const CSelector selector = Selector::type()(Bonus::UNDEAD)
.Or(Selector::type()(Bonus::NON_LIVING))
.Or(Selector::type()(Bonus::GARGOYLE))
.Or(Selector::type()(Bonus::SIEGE_WEAPON));
return !hasBonus(selector, cachingStr);
}
std::shared_ptr<const Bonus> IBonusBearer::getBonus(const CSelector &selector) const
{
auto bonuses = getAllBonuses(selector, Selector::all);
return bonuses->getFirst(Selector::all);
}
const CStack * retrieveStackBattle(const CBonusSystemNode * node)
{
switch(node->getNodeType())
{
case CBonusSystemNode::STACK_BATTLE:
return static_cast<const CStack*>(node);
default:
return nullptr;
}
}
const CStackInstance * retrieveStackInstance(const CBonusSystemNode * node)
{
switch(node->getNodeType())
{
case CBonusSystemNode::STACK_INSTANCE:
return (static_cast<const CStackInstance *>(node));
case CBonusSystemNode::STACK_BATTLE:
return (static_cast<const CStack*>(node))->base;
default:
return nullptr;
}
}
PlayerColor CBonusSystemNode::retrieveNodeOwner(const CBonusSystemNode * node)
{
return node ? node->getOwner() : PlayerColor::CANNOT_DETERMINE;
}
std::shared_ptr<Bonus> CBonusSystemNode::getBonusLocalFirst(const CSelector & selector)
{
auto ret = bonuses.getFirst(selector);
if(ret)
return ret;
FOREACH_PARENT(pname)
{
ret = pname->getBonusLocalFirst(selector);
if (ret)
return ret;
}
return nullptr;
}
std::shared_ptr<const Bonus> CBonusSystemNode::getBonusLocalFirst(const CSelector & selector) const
{
return (const_cast<CBonusSystemNode*>(this))->getBonusLocalFirst(selector);
}
void CBonusSystemNode::getParents(TCNodes & out) const /*retrieves list of parent nodes (nodes to inherit bonuses from) */
{
for (auto & elem : parents)
{
const CBonusSystemNode *parent = elem;
out.insert(parent);
}
}
void CBonusSystemNode::getParents(TNodes &out)
{
for (auto & elem : parents)
{
const CBonusSystemNode *parent = elem;
out.insert(const_cast<CBonusSystemNode*>(parent));
}
}
void CBonusSystemNode::getAllParents(TCNodes & out) const //retrieves list of parent nodes (nodes to inherit bonuses from)
{
for(auto parent : parents)
{
out.insert(parent);
parent->getAllParents(out);
}
}
void CBonusSystemNode::getAllBonusesRec(BonusList &out) const
{
//out has been reserved sufficient capacity at getAllBonuses() call
BonusList beforeUpdate;
TCNodes lparents;
getAllParents(lparents);
if (lparents.size())
{
//estimate on how many bonuses are missing yet - must be positive
beforeUpdate.reserve(std::max(out.capacity() - out.size(), bonuses.size()));
}
else
{
beforeUpdate.reserve(bonuses.size()); //at most all local bonuses
}
for (auto parent : lparents)
{
parent->getAllBonusesRec(beforeUpdate);
}
bonuses.getAllBonuses(beforeUpdate);
for(const auto & b : beforeUpdate)
{
auto updated = b->updater
? getUpdatedBonus(b, b->updater)
: b;
//do not add bonus with updater
bool bonusExists = false;
for (auto const & bonus : out )
{
if (bonus == updated)
bonusExists = true;
if (bonus->updater && bonus->updater == updated->updater)
bonusExists = true;
}
if (!bonusExists)
out.push_back(updated);
}
}
TConstBonusListPtr CBonusSystemNode::getAllBonuses(const CSelector &selector, const CSelector &limit, const CBonusSystemNode *root, const std::string &cachingStr) const
{
bool limitOnUs = (!root || root == this); //caching won't work when we want to limit bonuses against an external node
if (CBonusSystemNode::cachingEnabled && limitOnUs)
{
// Exclusive access for one thread
boost::lock_guard<boost::mutex> lock(sync);
// If the bonus system tree changes(state of a single node or the relations to each other) then
// cache all bonus objects. Selector objects doesn't matter.
if (cachedLast != treeChanged)
{
BonusList allBonuses;
allBonuses.reserve(cachedBonuses.capacity()); //we assume we'll get about the same number of bonuses
cachedBonuses.clear();
cachedRequests.clear();
getAllBonusesRec(allBonuses);
limitBonuses(allBonuses, cachedBonuses);
cachedBonuses.stackBonuses();
cachedLast = treeChanged;
}
// If a bonus system request comes with a caching string then look up in the map if there are any
// pre-calculated bonus results. Limiters can't be cached so they have to be calculated.
if(!cachingStr.empty())
{
auto it = cachedRequests.find(cachingStr);
if(it != cachedRequests.end())
{
//Cached list contains bonuses for our query with applied limiters
return it->second;
}
}
//We still don't have the bonuses (didn't returned them from cache)
//Perform bonus selection
auto ret = std::make_shared<BonusList>();
cachedBonuses.getBonuses(*ret, selector, limit);
// Save the results in the cache
if(!cachingStr.empty())
cachedRequests[cachingStr] = ret;
return ret;
}
else
{
return getAllBonusesWithoutCaching(selector, limit, root);
}
}
TConstBonusListPtr CBonusSystemNode::getAllBonusesWithoutCaching(const CSelector &selector, const CSelector &limit, const CBonusSystemNode *root) const
{
auto ret = std::make_shared<BonusList>();
// Get bonus results without caching enabled.
BonusList beforeLimiting, afterLimiting;
getAllBonusesRec(beforeLimiting);
if(!root || root == this)
{
limitBonuses(beforeLimiting, afterLimiting);
}
else if(root)
{
//We want to limit our query against an external node. We get all its bonuses,
// add the ones we're considering and see if they're cut out by limiters
BonusList rootBonuses, limitedRootBonuses;
getAllBonusesRec(rootBonuses);
for(auto b : beforeLimiting)
rootBonuses.push_back(b);
root->limitBonuses(rootBonuses, limitedRootBonuses);
for(auto b : beforeLimiting)
if(vstd::contains(limitedRootBonuses, b))
afterLimiting.push_back(b);
}
afterLimiting.getBonuses(*ret, selector, limit);
ret->stackBonuses();
return ret;
}
std::shared_ptr<Bonus> CBonusSystemNode::getUpdatedBonus(const std::shared_ptr<Bonus> & b, const TUpdaterPtr updater) const
{
assert(updater);
return updater->createUpdatedBonus(b, * this);
}
CBonusSystemNode::CBonusSystemNode()
:CBonusSystemNode(false)
{
}
CBonusSystemNode::CBonusSystemNode(bool isHypotetic)
: bonuses(true),
exportedBonuses(true),
nodeType(UNKNOWN),
cachedLast(0),
sync(),
isHypotheticNode(isHypotetic)
{
}
CBonusSystemNode::CBonusSystemNode(ENodeTypes NodeType)
: bonuses(true),
exportedBonuses(true),
nodeType(NodeType),
cachedLast(0),
sync(),
isHypotheticNode(false)
{
}
CBonusSystemNode::CBonusSystemNode(CBonusSystemNode && other):
bonuses(std::move(other.bonuses)),
exportedBonuses(std::move(other.exportedBonuses)),
nodeType(other.nodeType),
description(other.description),
cachedLast(0),
sync(),
isHypotheticNode(other.isHypotheticNode)
{
std::swap(parents, other.parents);
std::swap(children, other.children);
//fixing bonus tree without recalculation
if(!isHypothetic())
{
for(CBonusSystemNode * n : parents)
{
n->children -= &other;
n->children.push_back(this);
}
}
for(CBonusSystemNode * n : children)
{
n->parents -= &other;
n->parents.push_back(this);
}
//cache ignored
//cachedBonuses
//cachedRequests
}
CBonusSystemNode::~CBonusSystemNode()
{
detachFromAll();
if(children.size())
{
while(children.size())
children.front()->detachFrom(*this);
}
}
void CBonusSystemNode::attachTo(CBonusSystemNode & parent)
{
assert(!vstd::contains(parents, &parent));
parents.push_back(&parent);
if(!isHypothetic())
{
if(parent.actsAsBonusSourceOnly())
parent.newRedDescendant(*this);
else
newRedDescendant(parent);
parent.newChildAttached(*this);
}
CBonusSystemNode::treeHasChanged();
}
void CBonusSystemNode::detachFrom(CBonusSystemNode & parent)
{
assert(vstd::contains(parents, &parent));
if(!isHypothetic())
{
if(parent.actsAsBonusSourceOnly())
parent.removedRedDescendant(*this);
else
removedRedDescendant(parent);
}
if (vstd::contains(parents, &parent))
{
parents -= &parent;
}
else
{
logBonus->error("Error on Detach. Node %s (nodeType=%d) has not parent %s (nodeType=%d)"
, nodeShortInfo(), nodeType, parent.nodeShortInfo(), parent.nodeType);
}
if(!isHypothetic())
{
parent.childDetached(*this);
}
CBonusSystemNode::treeHasChanged();
}
void CBonusSystemNode::removeBonusesRecursive(const CSelector & s)
{
removeBonuses(s);
for(CBonusSystemNode * child : children)
child->removeBonusesRecursive(s);
}
void CBonusSystemNode::reduceBonusDurations(const CSelector &s)
{
BonusList bl;
exportedBonuses.getBonuses(bl, s, Selector::all);
for(auto b : bl)
{
b->turnsRemain--;
if(b->turnsRemain <= 0)
removeBonus(b);
}
for(CBonusSystemNode *child : children)
child->reduceBonusDurations(s);
}
void CBonusSystemNode::addNewBonus(const std::shared_ptr<Bonus>& b)
{
//turnsRemain shouldn't be zero for following durations
if(Bonus::NTurns(b.get()) || Bonus::NDays(b.get()) || Bonus::OneWeek(b.get()))
{
assert(b->turnsRemain);
}
assert(!vstd::contains(exportedBonuses, b));
exportedBonuses.push_back(b);
exportBonus(b);
CBonusSystemNode::treeHasChanged();
}
void CBonusSystemNode::accumulateBonus(const std::shared_ptr<Bonus>& b)
{
auto bonus = exportedBonuses.getFirst(Selector::typeSubtype(b->type, b->subtype)); //only local bonuses are interesting //TODO: what about value type?
if(bonus)
bonus->val += b->val;
else
addNewBonus(std::make_shared<Bonus>(*b)); //duplicate needed, original may get destroyed
}
void CBonusSystemNode::removeBonus(const std::shared_ptr<Bonus>& b)
{
exportedBonuses -= b;
if(b->propagator)
unpropagateBonus(b);
else
bonuses -= b;
CBonusSystemNode::treeHasChanged();
}
void CBonusSystemNode::removeBonuses(const CSelector & selector)
{
BonusList toRemove;
exportedBonuses.getBonuses(toRemove, selector, Selector::all);
for(auto bonus : toRemove)
removeBonus(bonus);
}
bool CBonusSystemNode::actsAsBonusSourceOnly() const
{
switch(nodeType)
{
case CREATURE:
case ARTIFACT:
case ARTIFACT_INSTANCE:
return true;
default:
return false;
}
}
void CBonusSystemNode::propagateBonus(std::shared_ptr<Bonus> b, const CBonusSystemNode & source)
{
if(b->propagator->shouldBeAttached(this))
{
auto propagated = b->propagationUpdater
? source.getUpdatedBonus(b, b->propagationUpdater)
: b;
bonuses.push_back(propagated);
logBonus->trace("#$# %s #propagated to# %s", propagated->Description(), nodeName());
}
FOREACH_RED_CHILD(child)
child->propagateBonus(b, source);
}
void CBonusSystemNode::unpropagateBonus(std::shared_ptr<Bonus> b)
{
if(b->propagator->shouldBeAttached(this))
{
bonuses -= b;
logBonus->trace("#$# %s #is no longer propagated to# %s", b->Description(), nodeName());
}
FOREACH_RED_CHILD(child)
child->unpropagateBonus(b);
}
void CBonusSystemNode::newChildAttached(CBonusSystemNode & child)
{
assert(!vstd::contains(children, &child));
children.push_back(&child);
}
void CBonusSystemNode::childDetached(CBonusSystemNode & child)
{
if(vstd::contains(children, &child))
children -= &child;
else
{
logBonus->error("Error on Detach. Node %s (nodeType=%d) is not a child of %s (nodeType=%d)"
, child.nodeShortInfo(), child.nodeType, nodeShortInfo(), nodeType);
}
}
void CBonusSystemNode::detachFromAll()
{
while(parents.size())
detachFrom(*parents.front());
}
bool CBonusSystemNode::isIndependentNode() const
{
return parents.empty() && children.empty();
}
std::string CBonusSystemNode::nodeName() const
{
return description.size()
? description
: std::string("Bonus system node of type ") + typeid(*this).name();
}
std::string CBonusSystemNode::nodeShortInfo() const
{
std::ostringstream str;
str << "'" << typeid(* this).name() << "'";
description.length() > 0
? str << " (" << description << ")"
: str << " (no description)";
return str.str();
}
void CBonusSystemNode::deserializationFix()
{
exportBonuses();
}
void CBonusSystemNode::getRedParents(TNodes & out)
{
FOREACH_PARENT(pname)
{
if(pname->actsAsBonusSourceOnly())
{
out.insert(pname);
}
}
if(!actsAsBonusSourceOnly())
{
for(CBonusSystemNode *child : children)
{
out.insert(child);
}
}
}
void CBonusSystemNode::getRedChildren(TNodes &out)
{
FOREACH_PARENT(pname)
{
if(!pname->actsAsBonusSourceOnly())
{
out.insert(pname);
}
}
if(actsAsBonusSourceOnly())
{
for(CBonusSystemNode *child : children)
{
out.insert(child);
}
}
}
void CBonusSystemNode::newRedDescendant(CBonusSystemNode & descendant)
{
for(auto b : exportedBonuses)
{
if(b->propagator)
descendant.propagateBonus(b, *this);
}
TNodes redParents;
getRedAncestors(redParents); //get all red parents recursively
for(auto parent : redParents)
{
for(auto b : parent->exportedBonuses)
{
if(b->propagator)
descendant.propagateBonus(b, *this);
}
}
}
void CBonusSystemNode::removedRedDescendant(CBonusSystemNode & descendant)
{
for(auto b : exportedBonuses)
if(b->propagator)
descendant.unpropagateBonus(b);
TNodes redParents;
getRedAncestors(redParents); //get all red parents recursively
for(auto parent : redParents)
{
for(auto b : parent->exportedBonuses)
if(b->propagator)
descendant.unpropagateBonus(b);
}
}
void CBonusSystemNode::getRedAncestors(TNodes &out)
{
getRedParents(out);
TNodes redParents;
getRedParents(redParents);
for(CBonusSystemNode * parent : redParents)
parent->getRedAncestors(out);
}
void CBonusSystemNode::getRedDescendants(TNodes &out)
{
getRedChildren(out);
FOREACH_RED_CHILD(c)
c->getRedChildren(out);
}
void CBonusSystemNode::exportBonus(std::shared_ptr<Bonus> b)
{
if(b->propagator)
propagateBonus(b, *this);
else
bonuses.push_back(b);
CBonusSystemNode::treeHasChanged();
}
void CBonusSystemNode::exportBonuses()
{
for(auto b : exportedBonuses)
exportBonus(b);
}
CBonusSystemNode::ENodeTypes CBonusSystemNode::getNodeType() const
{
return nodeType;
}
const BonusList& CBonusSystemNode::getBonusList() const
{
return bonuses;
}
const TNodesVector& CBonusSystemNode::getParentNodes() const
{
return parents;
}
const TNodesVector& CBonusSystemNode::getChildrenNodes() const
{
return children;
}
void CBonusSystemNode::setNodeType(CBonusSystemNode::ENodeTypes type)
{
nodeType = type;
}
BonusList & CBonusSystemNode::getExportedBonusList()
{
return exportedBonuses;
}
const BonusList & CBonusSystemNode::getExportedBonusList() const
{
return exportedBonuses;
}
const std::string& CBonusSystemNode::getDescription() const
{
return description;
}
void CBonusSystemNode::setDescription(const std::string &description)
{
this->description = description;
}
void CBonusSystemNode::limitBonuses(const BonusList &allBonuses, BonusList &out) const
{
assert(&allBonuses != &out); //todo should it work in-place?
BonusList undecided = allBonuses,
&accepted = out;
while(true)
{
int undecidedCount = static_cast<int>(undecided.size());
for(int i = 0; i < undecided.size(); i++)
{
auto b = undecided[i];
BonusLimitationContext context = {b, *this, out, undecided};
int decision = b->limiter ? b->limiter->limit(context) : ILimiter::ACCEPT; //bonuses without limiters will be accepted by default
if(decision == ILimiter::DISCARD)
{
undecided.erase(i);
i--; continue;
}
else if(decision == ILimiter::ACCEPT)
{
accepted.push_back(b);
undecided.erase(i);
i--; continue;
}
else
assert(decision == ILimiter::NOT_SURE);
}
if(undecided.size() == undecidedCount) //we haven't moved a single bonus -> limiters reached a stable state
return;
}
}
TBonusListPtr CBonusSystemNode::limitBonuses(const BonusList &allBonuses) const
{
auto ret = std::make_shared<BonusList>();
limitBonuses(allBonuses, *ret);
return ret;
}
void CBonusSystemNode::treeHasChanged()
{
treeChanged++;
}
int64_t CBonusSystemNode::getTreeVersion() const
{
int64_t ret = treeChanged;
return ret << 32;
}
int NBonus::valOf(const CBonusSystemNode *obj, Bonus::BonusType type, int subtype)
{
if(obj)
return obj->valOfBonuses(type, subtype);
return 0;
}
bool NBonus::hasOfType(const CBonusSystemNode *obj, Bonus::BonusType type, int subtype)
{
if(obj)
return obj->hasBonusOfType(type, subtype);
return false;
}
std::string Bonus::Description(boost::optional<si32> customValue) const
{
std::ostringstream str;
if(description.empty())
{
if(stacking.empty() || stacking == "ALWAYS")
{
switch(source)
{
case ARTIFACT:
str << ArtifactID(sid).toArtifact(VLC->artifacts())->getNameTranslated();
break;
case SPELL_EFFECT:
str << SpellID(sid).toSpell(VLC->spells())->getNameTranslated();
break;
case CREATURE_ABILITY:
str << VLC->creh->objects[sid]->getNamePluralTranslated();
break;
case SECONDARY_SKILL:
str << VLC->skillh->getByIndex(sid)->getNameTranslated();
break;
case HERO_SPECIAL:
str << VLC->heroh->objects[sid]->getNameTranslated();
break;
default:
//todo: handle all possible sources
str << "Unknown";
break;
}
}
else
str << stacking;
}
else
{
str << description;
}
if(auto value = customValue.value_or(val))
str << " " << std::showpos << value;
return str.str();
}
JsonNode subtypeToJson(Bonus::BonusType type, int subtype)
{
switch(type)
{
case Bonus::PRIMARY_SKILL:
return JsonUtils::stringNode("primSkill." + PrimarySkill::names[subtype]);
case Bonus::SECONDARY_SKILL_PREMY:
return JsonUtils::stringNode(CSkillHandler::encodeSkillWithType(subtype));
case Bonus::SPECIAL_SPELL_LEV:
case Bonus::SPECIFIC_SPELL_DAMAGE:
case Bonus::SPELL:
case Bonus::SPECIAL_PECULIAR_ENCHANT:
case Bonus::SPECIAL_ADD_VALUE_ENCHANT:
case Bonus::SPECIAL_FIXED_VALUE_ENCHANT:
return JsonUtils::stringNode(CModHandler::makeFullIdentifier("", "spell", SpellID::encode(subtype)));
case Bonus::IMPROVED_NECROMANCY:
case Bonus::SPECIAL_UPGRADE:
return JsonUtils::stringNode(CModHandler::makeFullIdentifier("", "creature", CreatureID::encode(subtype)));
case Bonus::GENERATE_RESOURCE:
return JsonUtils::stringNode("resource." + GameConstants::RESOURCE_NAMES[subtype]);
default:
return JsonUtils::intNode(subtype);
}
}
JsonNode additionalInfoToJson(Bonus::BonusType type, CAddInfo addInfo)
{
switch(type)
{
case Bonus::SPECIAL_UPGRADE:
return JsonUtils::stringNode(CModHandler::makeFullIdentifier("", "creature", CreatureID::encode(addInfo[0])));
default:
return addInfo.toJsonNode();
}
}
JsonNode durationToJson(ui16 duration)
{
std::vector<std::string> durationNames;
for(ui16 durBit = 1; durBit; durBit = durBit << 1)
{
if(duration & durBit)
durationNames.push_back(vstd::findKey(bonusDurationMap, durBit));
}
if(durationNames.size() == 1)
{
return JsonUtils::stringNode(durationNames[0]);
}
else
{
JsonNode node(JsonNode::JsonType::DATA_VECTOR);
for(std::string dur : durationNames)
node.Vector().push_back(JsonUtils::stringNode(dur));
return node;
}
}
JsonNode Bonus::toJsonNode() const
{
JsonNode root(JsonNode::JsonType::DATA_STRUCT);
// only add values that might reasonably be found in config files
root["type"].String() = vstd::findKey(bonusNameMap, type);
if(subtype != -1)
root["subtype"] = subtypeToJson(type, subtype);
if(additionalInfo != CAddInfo::NONE)
root["addInfo"] = additionalInfoToJson(type, additionalInfo);
if(duration != 0)
{
JsonNode durationVec(JsonNode::JsonType::DATA_VECTOR);
for(auto & kv : bonusDurationMap)
{
if(duration & kv.second)
durationVec.Vector().push_back(JsonUtils::stringNode(kv.first));
}
root["duration"] = durationVec;
}
if(turnsRemain != 0)
root["turns"].Integer() = turnsRemain;
if(source != OTHER)
root["sourceType"].String() = vstd::findKey(bonusSourceMap, source);
if(targetSourceType != OTHER)
root["targetSourceType"].String() = vstd::findKey(bonusSourceMap, targetSourceType);
if(sid != 0)
root["sourceID"].Integer() = sid;
if(val != 0)
root["val"].Integer() = val;
if(valType != ADDITIVE_VALUE)
root["valueType"].String() = vstd::findKey(bonusValueMap, valType);
if(!stacking.empty())
root["stacking"].String() = stacking;
if(!description.empty())
root["description"].String() = description;
if(effectRange != NO_LIMIT)
root["effectRange"].String() = vstd::findKey(bonusLimitEffect, effectRange);
if(duration != PERMANENT)
root["duration"] = durationToJson(duration);
if(turnsRemain)
root["turns"].Integer() = turnsRemain;
if(limiter)
root["limiters"] = limiter->toJsonNode();
if(updater)
root["updater"] = updater->toJsonNode();
if(propagator)
root["propagator"].String() = vstd::findKey(bonusPropagatorMap, propagator);
return root;
}
std::string Bonus::nameForBonus() const
{
switch(type)
{
case Bonus::PRIMARY_SKILL:
return PrimarySkill::names[subtype];
case Bonus::SECONDARY_SKILL_PREMY:
return CSkillHandler::encodeSkill(subtype);
case Bonus::SPECIAL_SPELL_LEV:
case Bonus::SPECIFIC_SPELL_DAMAGE:
case Bonus::SPELL:
case Bonus::SPECIAL_PECULIAR_ENCHANT:
case Bonus::SPECIAL_ADD_VALUE_ENCHANT:
case Bonus::SPECIAL_FIXED_VALUE_ENCHANT:
return (*VLC->spellh)[SpellID::ESpellID(subtype)]->identifier;
case Bonus::SPECIAL_UPGRADE:
return CreatureID::encode(subtype) + "2" + CreatureID::encode(additionalInfo[0]);
case Bonus::GENERATE_RESOURCE:
return GameConstants::RESOURCE_NAMES[subtype];
case Bonus::STACKS_SPEED:
return "speed";
default:
return vstd::findKey(bonusNameMap, type);
}
}
Bonus::Bonus(Bonus::BonusDuration Duration, BonusType Type, BonusSource Src, si32 Val, ui32 ID, std::string Desc, si32 Subtype)
: duration((ui16)Duration), type(Type), subtype(Subtype), source(Src), val(Val), sid(ID), description(Desc)
{
turnsRemain = 0;
valType = ADDITIVE_VALUE;
effectRange = NO_LIMIT;
boost::algorithm::trim(description);
targetSourceType = OTHER;
}
Bonus::Bonus(Bonus::BonusDuration Duration, BonusType Type, BonusSource Src, si32 Val, ui32 ID, si32 Subtype, ValueType ValType)
: duration((ui16)Duration), type(Type), subtype(Subtype), source(Src), val(Val), sid(ID), valType(ValType)
{
turnsRemain = 0;
effectRange = NO_LIMIT;
targetSourceType = OTHER;
}
Bonus::Bonus()
{
duration = PERMANENT;
turnsRemain = 0;
type = NONE;
subtype = -1;
valType = ADDITIVE_VALUE;
effectRange = NO_LIMIT;
val = 0;
source = OTHER;
sid = 0;
targetSourceType = OTHER;
}
std::shared_ptr<Bonus> Bonus::addPropagator(TPropagatorPtr Propagator)
{
propagator = Propagator;
return this->shared_from_this();
}
namespace Selector
{
DLL_LINKAGE CSelectFieldEqual<Bonus::BonusType> & type()
{
static CSelectFieldEqual<Bonus::BonusType> stype(&Bonus::type);
return stype;
}
DLL_LINKAGE CSelectFieldEqual<TBonusSubtype> & subtype()
{
static CSelectFieldEqual<TBonusSubtype> ssubtype(&Bonus::subtype);
return ssubtype;
}
DLL_LINKAGE CSelectFieldEqual<CAddInfo> & info()
{
static CSelectFieldEqual<CAddInfo> sinfo(&Bonus::additionalInfo);
return sinfo;
}
DLL_LINKAGE CSelectFieldEqual<Bonus::BonusSource> & sourceType()
{
static CSelectFieldEqual<Bonus::BonusSource> ssourceType(&Bonus::source);
return ssourceType;
}
DLL_LINKAGE CSelectFieldEqual<Bonus::BonusSource> & targetSourceType()
{
static CSelectFieldEqual<Bonus::BonusSource> ssourceType(&Bonus::targetSourceType);
return ssourceType;
}
DLL_LINKAGE CSelectFieldEqual<Bonus::LimitEffect> & effectRange()
{
static CSelectFieldEqual<Bonus::LimitEffect> seffectRange(&Bonus::effectRange);
return seffectRange;
}
DLL_LINKAGE CWillLastTurns turns;
DLL_LINKAGE CWillLastDays days;
CSelector DLL_LINKAGE typeSubtype(Bonus::BonusType Type, TBonusSubtype Subtype)
{
return type()(Type).And(subtype()(Subtype));
}
CSelector DLL_LINKAGE typeSubtypeInfo(Bonus::BonusType type, TBonusSubtype subtype, CAddInfo info)
{
return CSelectFieldEqual<Bonus::BonusType>(&Bonus::type)(type)
.And(CSelectFieldEqual<TBonusSubtype>(&Bonus::subtype)(subtype))
.And(CSelectFieldEqual<CAddInfo>(&Bonus::additionalInfo)(info));
}
CSelector DLL_LINKAGE source(Bonus::BonusSource source, ui32 sourceID)
{
return CSelectFieldEqual<Bonus::BonusSource>(&Bonus::source)(source)
.And(CSelectFieldEqual<ui32>(&Bonus::sid)(sourceID));
}
CSelector DLL_LINKAGE sourceTypeSel(Bonus::BonusSource source)
{
return CSelectFieldEqual<Bonus::BonusSource>(&Bonus::source)(source);
}
CSelector DLL_LINKAGE valueType(Bonus::ValueType valType)
{
return CSelectFieldEqual<Bonus::ValueType>(&Bonus::valType)(valType);
}
DLL_LINKAGE CSelector all([](const Bonus * b){return true;});
DLL_LINKAGE CSelector none([](const Bonus * b){return false;});
bool DLL_LINKAGE matchesType(const CSelector &sel, Bonus::BonusType type)
{
Bonus dummy;
dummy.type = type;
return sel(&dummy);
}
bool DLL_LINKAGE matchesTypeSubtype(const CSelector &sel, Bonus::BonusType type, TBonusSubtype subtype)
{
Bonus dummy;
dummy.type = type;
dummy.subtype = subtype;
return sel(&dummy);
}
}
const CCreature * retrieveCreature(const CBonusSystemNode *node)
{
switch(node->getNodeType())
{
case CBonusSystemNode::CREATURE:
return (static_cast<const CCreature *>(node));
case CBonusSystemNode::STACK_BATTLE:
return (static_cast<const CStack*>(node))->type;
default:
const CStackInstance * csi = retrieveStackInstance(node);
if(csi)
return csi->type;
return nullptr;
}
}
DLL_LINKAGE std::ostream & operator<<(std::ostream &out, const BonusList &bonusList)
{
for (ui32 i = 0; i < bonusList.size(); i++)
{
auto b = bonusList[i];
out << "Bonus " << i << "\n" << *b << std::endl;
}
return out;
}
DLL_LINKAGE std::ostream & operator<<(std::ostream &out, const Bonus &bonus)
{
for(auto i = bonusNameMap.cbegin(); i != bonusNameMap.cend(); i++)
if(i->second == bonus.type)
out << "\tType: " << i->first << " \t";
#define printField(field) out << "\t" #field ": " << (int)bonus.field << "\n"
printField(val);
printField(subtype);
printField(duration);
printField(source);
printField(sid);
if(bonus.additionalInfo != CAddInfo::NONE)
out << "\taddInfo: " << bonus.additionalInfo.toString() << "\n";
printField(turnsRemain);
printField(valType);
if(!bonus.stacking.empty())
out << "\tstacking: \"" << bonus.stacking << "\"\n";
printField(effectRange);
#undef printField
if(bonus.limiter)
out << "\tLimiter: " << bonus.limiter->toString() << "\n";
if(bonus.updater)
out << "\tUpdater: " << bonus.updater->toString() << "\n";
return out;
}
std::shared_ptr<Bonus> Bonus::addLimiter(TLimiterPtr Limiter)
{
if (limiter)
{
//If we already have limiter list, retrieve it
auto limiterList = std::dynamic_pointer_cast<AllOfLimiter>(limiter);
if(!limiterList)
{
//Create a new limiter list with old limiter and the new one will be pushed later
limiterList = std::make_shared<AllOfLimiter>();
limiterList->add(limiter);
limiter = limiterList;
}
limiterList->add(Limiter);
}
else
{
limiter = Limiter;
}
return this->shared_from_this();
}
ILimiter::~ILimiter()
{
}
int ILimiter::limit(const BonusLimitationContext &context) const /*return true to drop the bonus */
{
return false;
}
std::string ILimiter::toString() const
{
return typeid(*this).name();
}
JsonNode ILimiter::toJsonNode() const
{
JsonNode root(JsonNode::JsonType::DATA_STRUCT);
root["type"].String() = toString();
return root;
}
int CCreatureTypeLimiter::limit(const BonusLimitationContext &context) const
{
const CCreature *c = retrieveCreature(&context.node);
if(!c)
return true;
return c->getId() != creature->getId() && (!includeUpgrades || !creature->isMyUpgrade(c));
//drop bonus if it's not our creature and (we don`t check upgrades or its not our upgrade)
}
CCreatureTypeLimiter::CCreatureTypeLimiter(const CCreature & creature_, bool IncludeUpgrades)
: creature(&creature_), includeUpgrades(IncludeUpgrades)
{
}
CCreatureTypeLimiter::CCreatureTypeLimiter()
{
creature = nullptr;
includeUpgrades = false;
}
void CCreatureTypeLimiter::setCreature (CreatureID id)
{
creature = VLC->creh->objects[id];
}
std::string CCreatureTypeLimiter::toString() const
{
boost::format fmt("CCreatureTypeLimiter(creature=%s, includeUpgrades=%s)");
fmt % creature->getJsonKey() % (includeUpgrades ? "true" : "false");
return fmt.str();
}
JsonNode CCreatureTypeLimiter::toJsonNode() const
{
JsonNode root(JsonNode::JsonType::DATA_STRUCT);
root["type"].String() = "CREATURE_TYPE_LIMITER";
root["parameters"].Vector().push_back(JsonUtils::stringNode(creature->getJsonKey()));
root["parameters"].Vector().push_back(JsonUtils::boolNode(includeUpgrades));
return root;
}
HasAnotherBonusLimiter::HasAnotherBonusLimiter( Bonus::BonusType bonus )
: type(bonus), subtype(0), isSubtypeRelevant(false), isSourceRelevant(false), isSourceIDRelevant(false)
{
}
HasAnotherBonusLimiter::HasAnotherBonusLimiter( Bonus::BonusType bonus, TBonusSubtype _subtype )
: type(bonus), subtype(_subtype), isSubtypeRelevant(true), isSourceRelevant(false), isSourceIDRelevant(false)
{
}
HasAnotherBonusLimiter::HasAnotherBonusLimiter(Bonus::BonusType bonus, Bonus::BonusSource src)
: type(bonus), source(src), isSubtypeRelevant(false), isSourceRelevant(true), isSourceIDRelevant(false)
{
}
HasAnotherBonusLimiter::HasAnotherBonusLimiter(Bonus::BonusType bonus, TBonusSubtype _subtype, Bonus::BonusSource src)
: type(bonus), subtype(_subtype), isSubtypeRelevant(true), source(src), isSourceRelevant(true), isSourceIDRelevant(false)
{
}
int HasAnotherBonusLimiter::limit(const BonusLimitationContext &context) const
{
//TODO: proper selector config with parsing of JSON
auto mySelector = Selector::type()(type);
if(isSubtypeRelevant)
mySelector = mySelector.And(Selector::subtype()(subtype));
if(isSourceRelevant && isSourceIDRelevant)
mySelector = mySelector.And(Selector::source(source, sid));
else if (isSourceRelevant)
mySelector = mySelector.And(Selector::sourceTypeSel(source));
//if we have a bonus of required type accepted, limiter should accept also this bonus
if(context.alreadyAccepted.getFirst(mySelector))
return ACCEPT;
//if there are no matching bonuses pending, we can (and must) reject right away
if(!context.stillUndecided.getFirst(mySelector))
return DISCARD;
//do not accept for now but it may change if more bonuses gets included
return NOT_SURE;
}
std::string HasAnotherBonusLimiter::toString() const
{
std::string typeName = vstd::findKey(bonusNameMap, type);
if(isSubtypeRelevant)
{
boost::format fmt("HasAnotherBonusLimiter(type=%s, subtype=%d)");
fmt % typeName % subtype;
return fmt.str();
}
else
{
boost::format fmt("HasAnotherBonusLimiter(type=%s)");
fmt % typeName;
return fmt.str();
}
}
JsonNode HasAnotherBonusLimiter::toJsonNode() const
{
JsonNode root(JsonNode::JsonType::DATA_STRUCT);
std::string typeName = vstd::findKey(bonusNameMap, type);
auto sourceTypeName = vstd::findKey(bonusSourceMap, source);
root["type"].String() = "HAS_ANOTHER_BONUS_LIMITER";
root["parameters"].Vector().push_back(JsonUtils::stringNode(typeName));
if(isSubtypeRelevant)
root["parameters"].Vector().push_back(JsonUtils::intNode(subtype));
if(isSourceRelevant)
root["parameters"].Vector().push_back(JsonUtils::stringNode(sourceTypeName));
return root;
}
IPropagator::~IPropagator()
{
}
bool IPropagator::shouldBeAttached(CBonusSystemNode *dest)
{
return false;
}
CBonusSystemNode::ENodeTypes IPropagator::getPropagatorType() const
{
return CBonusSystemNode::ENodeTypes::NONE;
}
CPropagatorNodeType::CPropagatorNodeType()
:nodeType(CBonusSystemNode::ENodeTypes::UNKNOWN)
{
}
CPropagatorNodeType::CPropagatorNodeType(CBonusSystemNode::ENodeTypes NodeType)
: nodeType(NodeType)
{
}
CBonusSystemNode::ENodeTypes CPropagatorNodeType::getPropagatorType() const
{
return nodeType;
}
bool CPropagatorNodeType::shouldBeAttached(CBonusSystemNode *dest)
{
return nodeType == dest->getNodeType();
}
CreatureTerrainLimiter::CreatureTerrainLimiter()
: terrainType(ETerrainId::NATIVE_TERRAIN)
{
}
CreatureTerrainLimiter::CreatureTerrainLimiter(TerrainId terrain):
terrainType(terrain)
{
}
int CreatureTerrainLimiter::limit(const BonusLimitationContext &context) const
{
const CStack *stack = retrieveStackBattle(&context.node);
if(stack)
{
if (terrainType == ETerrainId::NATIVE_TERRAIN)//terrainType not specified = native
{
return !stack->isOnNativeTerrain();
}
else
{
return !stack->isOnTerrain(terrainType);
}
}
return true;
//TODO neutral creatues
}
std::string CreatureTerrainLimiter::toString() const
{
boost::format fmt("CreatureTerrainLimiter(terrainType=%s)");
auto terrainName = VLC->terrainTypeHandler->getById(terrainType)->getJsonKey();
fmt % (terrainType == ETerrainId::NATIVE_TERRAIN ? "native" : terrainName);
return fmt.str();
}
JsonNode CreatureTerrainLimiter::toJsonNode() const
{
JsonNode root(JsonNode::JsonType::DATA_STRUCT);
root["type"].String() = "CREATURE_TERRAIN_LIMITER";
auto terrainName = VLC->terrainTypeHandler->getById(terrainType)->getJsonKey();
root["parameters"].Vector().push_back(JsonUtils::stringNode(terrainName));
return root;
}
CreatureFactionLimiter::CreatureFactionLimiter(TFaction creatureFaction)
: faction(creatureFaction)
{
}
CreatureFactionLimiter::CreatureFactionLimiter()
: faction((TFaction)-1)
{
}
int CreatureFactionLimiter::limit(const BonusLimitationContext &context) const
{
const CCreature *c = retrieveCreature(&context.node);
return !c || c->faction != faction; //drop bonus for non-creatures or non-native residents
}
std::string CreatureFactionLimiter::toString() const
{
boost::format fmt("CreatureFactionLimiter(faction=%s)");
fmt % VLC->factions()->getByIndex(faction)->getJsonKey();
return fmt.str();
}
JsonNode CreatureFactionLimiter::toJsonNode() const
{
JsonNode root(JsonNode::JsonType::DATA_STRUCT);
root["type"].String() = "CREATURE_FACTION_LIMITER";
root["parameters"].Vector().push_back(JsonUtils::stringNode(VLC->factions()->getByIndex(faction)->getJsonKey()));
return root;
}
CreatureAlignmentLimiter::CreatureAlignmentLimiter()
: alignment(-1)
{
}
CreatureAlignmentLimiter::CreatureAlignmentLimiter(si8 Alignment)
: alignment(Alignment)
{
}
int CreatureAlignmentLimiter::limit(const BonusLimitationContext &context) const
{
const CCreature *c = retrieveCreature(&context.node);
if(!c)
return true;
switch(alignment)
{
case EAlignment::GOOD:
return !c->isGood(); //if not good -> return true (drop bonus)
case EAlignment::NEUTRAL:
return c->isEvil() || c->isGood();
case EAlignment::EVIL:
return !c->isEvil();
default:
logBonus->warn("Warning: illegal alignment in limiter!");
return true;
}
}
std::string CreatureAlignmentLimiter::toString() const
{
boost::format fmt("CreatureAlignmentLimiter(alignment=%s)");
fmt % EAlignment::names[alignment];
return fmt.str();
}
JsonNode CreatureAlignmentLimiter::toJsonNode() const
{
JsonNode root(JsonNode::JsonType::DATA_STRUCT);
root["type"].String() = "CREATURE_ALIGNMENT_LIMITER";
root["parameters"].Vector().push_back(JsonUtils::stringNode(EAlignment::names[alignment]));
return root;
}
RankRangeLimiter::RankRangeLimiter(ui8 Min, ui8 Max)
:minRank(Min), maxRank(Max)
{
}
RankRangeLimiter::RankRangeLimiter()
{
minRank = maxRank = -1;
}
int RankRangeLimiter::limit(const BonusLimitationContext &context) const
{
const CStackInstance * csi = retrieveStackInstance(&context.node);
if(csi)
{
if (csi->getNodeType() == CBonusSystemNode::COMMANDER) //no stack exp bonuses for commander creatures
return true;
return csi->getExpRank() < minRank || csi->getExpRank() > maxRank;
}
return true;
}
int StackOwnerLimiter::limit(const BonusLimitationContext &context) const
{
const CStack * s = retrieveStackBattle(&context.node);
if(s)
return s->owner != owner;
const CStackInstance * csi = retrieveStackInstance(&context.node);
if(csi && csi->armyObj)
return csi->armyObj->tempOwner != owner;
return true;
}
StackOwnerLimiter::StackOwnerLimiter()
: owner(-1)
{
}
StackOwnerLimiter::StackOwnerLimiter(PlayerColor Owner)
: owner(Owner)
{
}
OppositeSideLimiter::OppositeSideLimiter()
: owner(PlayerColor::CANNOT_DETERMINE)
{
}
OppositeSideLimiter::OppositeSideLimiter(PlayerColor Owner)
: owner(Owner)
{
}
int OppositeSideLimiter::limit(const BonusLimitationContext & context) const
{
auto contextOwner = CBonusSystemNode::retrieveNodeOwner(& context.node);
auto decision = (owner == contextOwner || owner == PlayerColor::CANNOT_DETERMINE) ? ILimiter::DISCARD : ILimiter::ACCEPT;
return decision;
}
// Aggregate/Boolean Limiters
void AggregateLimiter::add(TLimiterPtr limiter)
{
if(limiter)
limiters.push_back(limiter);
}
JsonNode AggregateLimiter::toJsonNode() const
{
JsonNode result(JsonNode::JsonType::DATA_VECTOR);
result.Vector().push_back(JsonUtils::stringNode(getAggregator()));
for(auto l : limiters)
result.Vector().push_back(l->toJsonNode());
return result;
}
const std::string AllOfLimiter::aggregator = "allOf";
const std::string & AllOfLimiter::getAggregator() const
{
return aggregator;
}
int AllOfLimiter::limit(const BonusLimitationContext & context) const
{
bool wasntSure = false;
for(auto limiter : limiters)
{
auto result = limiter->limit(context);
if(result == ILimiter::DISCARD)
return result;
if(result == ILimiter::NOT_SURE)
wasntSure = true;
}
return wasntSure ? ILimiter::NOT_SURE : ILimiter::ACCEPT;
}
const std::string AnyOfLimiter::aggregator = "anyOf";
const std::string & AnyOfLimiter::getAggregator() const
{
return aggregator;
}
int AnyOfLimiter::limit(const BonusLimitationContext & context) const
{
bool wasntSure = false;
for(auto limiter : limiters)
{
auto result = limiter->limit(context);
if(result == ILimiter::ACCEPT)
return result;
if(result == ILimiter::NOT_SURE)
wasntSure = true;
}
return wasntSure ? ILimiter::NOT_SURE : ILimiter::DISCARD;
}
const std::string NoneOfLimiter::aggregator = "noneOf";
const std::string & NoneOfLimiter::getAggregator() const
{
return aggregator;
}
int NoneOfLimiter::limit(const BonusLimitationContext & context) const
{
bool wasntSure = false;
for(auto limiter : limiters)
{
auto result = limiter->limit(context);
if(result == ILimiter::ACCEPT)
return ILimiter::DISCARD;
if(result == ILimiter::NOT_SURE)
wasntSure = true;
}
return wasntSure ? ILimiter::NOT_SURE : ILimiter::ACCEPT;
}
// Updaters
std::shared_ptr<Bonus> Bonus::addUpdater(TUpdaterPtr Updater)
{
updater = Updater;
return this->shared_from_this();
}
// Update ONLY_ENEMY_ARMY bonuses from old saves to make them workable.
// Also, we should foreseen possible errors in bonus configuration and fix them.
void Bonus::updateOppositeBonuses()
{
if(effectRange != Bonus::ONLY_ENEMY_ARMY)
return;
if(propagator)
{
if(propagator->getPropagatorType() != CBonusSystemNode::BATTLE)
{
logMod->error("Wrong Propagator will be ignored: The 'ONLY_ENEMY_ARMY' effectRange is only compatible with the 'BATTLE_WIDE' propagator.");
propagator.reset(new CPropagatorNodeType(CBonusSystemNode::BATTLE));
}
}
else
{
propagator = std::make_shared<CPropagatorNodeType>(CBonusSystemNode::BATTLE);
}
if(limiter)
{
if(!dynamic_cast<OppositeSideLimiter*>(limiter.get()))
{
logMod->error("Wrong Limiter will be ignored: The 'ONLY_ENEMY_ARMY' effectRange is only compatible with the 'OPPOSITE_SIDE' limiter.");
limiter.reset(new OppositeSideLimiter());
}
}
else
{
limiter = std::make_shared<OppositeSideLimiter>();
}
propagationUpdater = std::make_shared<OwnerUpdater>();
}
IUpdater::~IUpdater()
{
}
std::shared_ptr<Bonus> IUpdater::createUpdatedBonus(const std::shared_ptr<Bonus> & b, const CBonusSystemNode & context) const
{
return b;
}
std::string IUpdater::toString() const
{
return typeid(*this).name();
}
JsonNode IUpdater::toJsonNode() const
{
return JsonNode(JsonNode::JsonType::DATA_NULL);
}
GrowsWithLevelUpdater::GrowsWithLevelUpdater() : valPer20(0), stepSize(1)
{
}
GrowsWithLevelUpdater::GrowsWithLevelUpdater(int valPer20, int stepSize) : valPer20(valPer20), stepSize(stepSize)
{
}
std::shared_ptr<Bonus> GrowsWithLevelUpdater::createUpdatedBonus(const std::shared_ptr<Bonus> & b, const CBonusSystemNode & context) const
{
if(context.getNodeType() == CBonusSystemNode::HERO)
{
int level = static_cast<const CGHeroInstance &>(context).level;
int steps = stepSize ? level / stepSize : level;
//rounding follows format for HMM3 creature specialty bonus
int newVal = (valPer20 * steps + 19) / 20;
//return copy of bonus with updated val
std::shared_ptr<Bonus> newBonus = std::make_shared<Bonus>(*b);
newBonus->val = newVal;
return newBonus;
}
return b;
}
std::string GrowsWithLevelUpdater::toString() const
{
return boost::str(boost::format("GrowsWithLevelUpdater(valPer20=%d, stepSize=%d)") % valPer20 % stepSize);
}
JsonNode GrowsWithLevelUpdater::toJsonNode() const
{
JsonNode root(JsonNode::JsonType::DATA_STRUCT);
root["type"].String() = "GROWS_WITH_LEVEL";
root["parameters"].Vector().push_back(JsonUtils::intNode(valPer20));
if(stepSize > 1)
root["parameters"].Vector().push_back(JsonUtils::intNode(stepSize));
return root;
}
TimesHeroLevelUpdater::TimesHeroLevelUpdater()
{
}
std::shared_ptr<Bonus> TimesHeroLevelUpdater::createUpdatedBonus(const std::shared_ptr<Bonus> & b, const CBonusSystemNode & context) const
{
if(context.getNodeType() == CBonusSystemNode::HERO)
{
int level = static_cast<const CGHeroInstance &>(context).level;
std::shared_ptr<Bonus> newBonus = std::make_shared<Bonus>(*b);
newBonus->val *= level;
return newBonus;
}
return b;
}
std::string TimesHeroLevelUpdater::toString() const
{
return "TimesHeroLevelUpdater";
}
JsonNode TimesHeroLevelUpdater::toJsonNode() const
{
return JsonUtils::stringNode("TIMES_HERO_LEVEL");
}
TimesStackLevelUpdater::TimesStackLevelUpdater()
{
}
std::shared_ptr<Bonus> TimesStackLevelUpdater::createUpdatedBonus(const std::shared_ptr<Bonus> & b, const CBonusSystemNode & context) const
{
if(context.getNodeType() == CBonusSystemNode::STACK_INSTANCE)
{
int level = static_cast<const CStackInstance &>(context).getLevel();
std::shared_ptr<Bonus> newBonus = std::make_shared<Bonus>(*b);
newBonus->val *= level;
return newBonus;
}
else if(context.getNodeType() == CBonusSystemNode::STACK_BATTLE)
{
const CStack & stack = static_cast<const CStack &>(context);
//only update if stack doesn't have an instance (summons, war machines)
//otherwise we'd end up multiplying twice
if(stack.base == nullptr)
{
int level = stack.type->level;
std::shared_ptr<Bonus> newBonus = std::make_shared<Bonus>(*b);
newBonus->val *= level;
return newBonus;
}
}
return b;
}
std::string TimesStackLevelUpdater::toString() const
{
return "TimesStackLevelUpdater";
}
JsonNode TimesStackLevelUpdater::toJsonNode() const
{
return JsonUtils::stringNode("TIMES_STACK_LEVEL");
}
OwnerUpdater::OwnerUpdater()
{
}
std::string OwnerUpdater::toString() const
{
return "OwnerUpdater";
}
JsonNode OwnerUpdater::toJsonNode() const
{
return JsonUtils::stringNode("BONUS_OWNER_UPDATER");
}
std::shared_ptr<Bonus> OwnerUpdater::createUpdatedBonus(const std::shared_ptr<Bonus> & b, const CBonusSystemNode & context) const
{
auto owner = CBonusSystemNode::retrieveNodeOwner(&context);
if(owner == PlayerColor::UNFLAGGABLE)
owner = PlayerColor::NEUTRAL;
std::shared_ptr<Bonus> updated = std::make_shared<Bonus>(
(Bonus::BonusDuration)b->duration, b->type, b->source, b->val, b->sid, b->subtype, b->valType);
updated->limiter = std::make_shared<OppositeSideLimiter>(owner);
return updated;
}
VCMI_LIB_NAMESPACE_END