Exemple #1
0
class SlotIndexRegister(RestrictionRegister):
    """
    Class which implements common functionality for all
    registers, which track indices of occupied slots and
    disallow multiple holders reside within slot with the
    same index.
    """

    def __init__(self, slotIndexAttr, restrictionType):
        # This attribute's value on holder
        # represents their index of slot
        self.__slotIndexAttr = slotIndexAttr
        self.__restrictionType = restrictionType
        # All holders which possess index of slot
        # are stored in this container
        # Format: {slot index: {holders}}
        self.__slottedHolders = KeyedSet()

    def registerHolder(self, holder):
        # Skip items which don't have index specifier
        try:
            slotIndex = holder.item.attributes[self.__slotIndexAttr]
        except KeyError:
            return
        self.__slottedHolders.addData(slotIndex, holder)

    def unregisterHolder(self, holder):
        try:
            slotIndex = holder.item.attributes[self.__slotIndexAttr]
        except KeyError:
            return
        self.__slottedHolders.rmData(slotIndex, holder)

    def validate(self):
        taintedHolders = {}
        for slotIndex in self.__slottedHolders:
            slotIndexHolders = self.__slottedHolders[slotIndex]
            # If more than one item occupies the same slot, all
            # holders in this slot are tainted
            if len(slotIndexHolders) > 1:
                for holder in slotIndexHolders:
                    taintedHolders[holder] = SlotIndexErrorData(holderSlotIndex=slotIndex)
        if taintedHolders:
            raise RegisterValidationError(taintedHolders)

    @property
    def restrictionType(self):
        return self.__restrictionType
Exemple #2
0
class SlotIndexRegister(RestrictionRegister):
    """
    Class which implements common functionality for all
    registers, which track indices of occupied slots and
    disallow multiple holders reside within slot with the
    same index.
    """
    def __init__(self, slotIndexAttr, restrictionType):
        # This attribute's value on holder
        # represents their index of slot
        self.__slotIndexAttr = slotIndexAttr
        self.__restrictionType = restrictionType
        # All holders which possess index of slot
        # are stored in this container
        # Format: {slot index: {holders}}
        self.__slottedHolders = KeyedSet()

    def registerHolder(self, holder):
        # Skip items which don't have index specifier
        try:
            slotIndex = holder.item.attributes[self.__slotIndexAttr]
        except KeyError:
            return
        self.__slottedHolders.addData(slotIndex, holder)

    def unregisterHolder(self, holder):
        try:
            slotIndex = holder.item.attributes[self.__slotIndexAttr]
        except KeyError:
            return
        self.__slottedHolders.rmData(slotIndex, holder)

    def validate(self):
        taintedHolders = {}
        for slotIndex in self.__slottedHolders:
            slotIndexHolders = self.__slottedHolders[slotIndex]
            # If more than one item occupies the same slot, all
            # holders in this slot are tainted
            if len(slotIndexHolders) > 1:
                for holder in slotIndexHolders:
                    taintedHolders[holder] = SlotIndexErrorData(
                        holderSlotIndex=slotIndex)
        if taintedHolders:
            raise RegisterValidationError(taintedHolders)

    @property
    def restrictionType(self):
        return self.__restrictionType
Exemple #3
0
class SkillUniquenessRegister(RestrictionRegister):
    """
    Implements restriction:
    Fit can't have more than one skill based on the same type.

    Details:
    Only holders having level attribute and item typeID other
    than None are tracked.
    """

    def __init__(self):
        # Container for skill holders
        # Format: {holder id: {holders}}
        self.__skillHolders = KeyedSet()

    def registerHolder(self, holder):
        # Only holders which have level attribute are tracked as skills
        if hasattr(holder, "level") is True and holder.item.id is not None:
            self.__skillHolders.addData(holder.item.id, holder)

    def unregisterHolder(self, holder):
        self.__skillHolders.rmData(holder.item.id, holder)

    def validate(self):
        taintedHolders = {}
        # Go through all skill IDs
        for skillId in self.__skillHolders:
            skillHolders = self.__skillHolders[skillId]
            # If there's at least two skills with the same ID,
            # taint these holders
            if len(skillHolders) > 1:
                for holder in skillHolders:
                    taintedHolders[holder] = SkillUniquenessErrorData(skill=skillId)
        if taintedHolders:
            raise RegisterValidationError(taintedHolders)

    @property
    def restrictionType(self):
        return Restriction.skillUniqueness
Exemple #4
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class SkillUniquenessRegister(RestrictionRegister):
    """
    Implements restriction:
    Fit can't have more than one skill based on the same type.

    Details:
    Only holders having level attribute and item typeID other
    than None are tracked.
    """

    def __init__(self):
        # Container for skill holders
        # Format: {holder id: {holders}}
        self.__skillHolders = KeyedSet()

    def registerHolder(self, holder):
        # Only holders which have level attribute are tracked as skills
        if hasattr(holder, 'level') is True and holder.item.id is not None:
            self.__skillHolders.addData(holder.item.id, holder)

    def unregisterHolder(self, holder):
        self.__skillHolders.rmData(holder.item.id, holder)

    def validate(self):
        taintedHolders = {}
        # Go through all skill IDs
        for skillId in self.__skillHolders:
            skillHolders = self.__skillHolders[skillId]
            # If there's at least two skills with the same ID,
            # taint these holders
            if len(skillHolders) > 1:
                for holder in skillHolders:
                    taintedHolders[holder] = SkillUniquenessErrorData(skill=skillId)
        if taintedHolders:
            raise RegisterValidationError(taintedHolders)

    @property
    def restrictionType(self):
        return Restriction.skillUniqueness
Exemple #5
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class MaxGroupRegister(RestrictionRegister):
    """
    Class which implements common functionality for all
    registers, which track maximum number of belonging to
    ship holders in certain state on per-group basis.
    """

    def __init__(self, maxGroupAttr, restrictionType):
        # Attribute ID whose value contains group restriction
        # of holder
        self.__maxGroupAttr = maxGroupAttr
        self.__restrictionType = restrictionType
        # Container for all tracked holders, keyed
        # by their group ID
        # Format: {group ID: {holders}}
        self.__groupAll = KeyedSet()
        # Container for holders, which have max group
        # restriction to become operational
        # Format: {holders}
        self.__maxGroupRestricted = set()

    def registerHolder(self, holder):
        # Ignore holders which do not belong to ship
        if holder._location != Location.ship:
            return
        groupId = holder.item.groupId
        # Ignore holders, whose item isn't assigned
        # to any group
        if groupId is None:
            return
        # Having group ID is enough condition
        # to enter container of all fitted holders
        self.__groupAll.addData(groupId, holder)
        # To enter restriction container, original
        # item must have restriction attribute
        if self.__maxGroupAttr not in holder.item.attributes:
            return
        self.__maxGroupRestricted.add(holder)

    def unregisterHolder(self, holder):
        # Just clear data containers
        groupId = holder.item.groupId
        self.__groupAll.rmData(groupId, holder)
        self.__maxGroupRestricted.discard(holder)

    def validate(self):
        # Container for tainted holders
        taintedHolders = {}
        # Go through all restricted holders
        for holder in self.__maxGroupRestricted:
            # Get number of registered holders, assigned to group of current
            # restricted holder, and holder's restriction value
            groupId = holder.item.groupId
            groupHolders = len(self.__groupAll.get(groupId) or ())
            maxGroupRestriction = holder.item.attributes[self.__maxGroupAttr]
            # If number of registered holders from this group is bigger,
            # then current holder is tainted
            if groupHolders > maxGroupRestriction:
                taintedHolders[holder] = MaxGroupErrorData(maxGroup=maxGroupRestriction,
                                                           holderGroup=groupId,
                                                           groupHolders=groupHolders)
        # Raise error if we detected any tainted holders
        if taintedHolders:
            raise RegisterValidationError(taintedHolders)

    @property
    def restrictionType(self):
        return self.__restrictionType
Exemple #6
0
class MaxGroupRegister(RestrictionRegister):
    """
    Class which implements common functionality for all
    registers, which track maximum number of belonging to
    ship holders in certain state on per-group basis.
    """
    def __init__(self, maxGroupAttr, restrictionType):
        # Attribute ID whose value contains group restriction
        # of holder
        self.__maxGroupAttr = maxGroupAttr
        self.__restrictionType = restrictionType
        # Container for all tracked holders, keyed
        # by their group ID
        # Format: {group ID: {holders}}
        self.__groupAll = KeyedSet()
        # Container for holders, which have max group
        # restriction to become operational
        # Format: {holders}
        self.__maxGroupRestricted = set()

    def registerHolder(self, holder):
        # Ignore holders which do not belong to ship
        if holder._location != Location.ship:
            return
        groupId = holder.item.groupId
        # Ignore holders, whose item isn't assigned
        # to any group
        if groupId is None:
            return
        # Having group ID is enough condition
        # to enter container of all fitted holders
        self.__groupAll.addData(groupId, holder)
        # To enter restriction container, original
        # item must have restriction attribute
        if self.__maxGroupAttr not in holder.item.attributes:
            return
        self.__maxGroupRestricted.add(holder)

    def unregisterHolder(self, holder):
        # Just clear data containers
        groupId = holder.item.groupId
        self.__groupAll.rmData(groupId, holder)
        self.__maxGroupRestricted.discard(holder)

    def validate(self):
        # Container for tainted holders
        taintedHolders = {}
        # Go through all restricted holders
        for holder in self.__maxGroupRestricted:
            # Get number of registered holders, assigned to group of current
            # restricted holder, and holder's restriction value
            groupId = holder.item.groupId
            groupHolders = len(self.__groupAll.get(groupId) or ())
            maxGroupRestriction = holder.item.attributes[self.__maxGroupAttr]
            # If number of registered holders from this group is bigger,
            # then current holder is tainted
            if groupHolders > maxGroupRestriction:
                taintedHolders[holder] = MaxGroupErrorData(
                    maxGroup=maxGroupRestriction,
                    holderGroup=groupId,
                    groupHolders=groupHolders)
        # Raise error if we detected any tainted holders
        if taintedHolders:
            raise RegisterValidationError(taintedHolders)

    @property
    def restrictionType(self):
        return self.__restrictionType
Exemple #7
0
class MutableAttributeMap:
    """
    Calculate, store and provide access to modified attribute values.

    Positional arguments:
    holder -- holder, to which this map is assigned
    """

    __slots__ = ("__holder", "__modifiedAttributes", "_capMap")

    def __init__(self, holder):
        # Reference to holder for internal needs
        self.__holder = holder
        # Actual container of calculated attributes
        # Format: {attribute ID: value}
        self.__modifiedAttributes = {}
        # This variable stores map of attributes which cap
        # something, and attributes capped by them. Initialized
        # to None to not waste memory, will be changed to dict
        # when needed.
        # Format {capping attribute ID: {capped attribute IDs}}
        self._capMap = None

    def __getitem__(self, attrId):
        # Special handling for skill level attribute
        if attrId == Attribute.skillLevel:
            # Attempt to return level attribute of holder
            try:
                val = self.__holder.level
            # Try regular way of getting attribute, if accessing
            # level attribute failed
            except AttributeError:
                pass
            else:
                return val
        # If carrier holder isn't assigned to any fit, then
        # we can use just item's original attributes
        if self.__holder.fit is None:
            val = self.__holder.item.attributes[attrId]
            return val
        # If value is stored, it's considered valid
        try:
            val = self.__modifiedAttributes[attrId]
        # Else, we have to run full calculation process
        except KeyError:
            try:
                val = self.__modifiedAttributes[attrId] = self.__calculate(attrId)
            except BaseValueError as e:
                msg = "unable to find base value for attribute {} on item {}".format(e.args[0], self.__holder.item.id)
                signature = (type(e), self.__holder.item.id, e.args[0])
                self.__holder.fit._eos._logger.warning(msg, childName="attributeCalculator", signature=signature)
                raise KeyError(attrId) from e
            except AttributeMetaError as e:
                msg = "unable to fetch metadata for attribute {}, requested for item {}".format(e.args[0], self.__holder.item.id)
                signature = (type(e), self.__holder.item.id, e.args[0])
                self.__holder.fit._eos._logger.error(msg, childName="attributeCalculator", signature=signature)
                raise KeyError(attrId) from e
            self.__holder.fit._linkTracker.clearHolderAttributeDependents(self.__holder, attrId)
        return val

    def __len__(self):
        return len(self.keys())

    def __contains__(self, attrId):
        # Seek for attribute in both modified attribute container
        # and original item attributes
        result = attrId in self.__modifiedAttributes or attrId in self.__holder.item.attributes
        return result

    def __iter__(self):
        for k in self.keys():
            yield k

    def __delitem__(self, attrId):
        # Clear the value in our calculated attributes dictionary
        try:
            del self.__modifiedAttributes[attrId]
        # Do nothing if it wasn't calculated
        except KeyError:
            pass
        # And make sure all other attributes relying on it
        # are cleared too
        else:
            self.__holder.fit._linkTracker.clearHolderAttributeDependents(self.__holder, attrId)

    def __setitem__(self, attrId, value):
        # Write value and clear all attributes relying on it
        self.__modifiedAttributes[attrId] = value
        self.__holder.fit._linkTracker.clearHolderAttributeDependents(self.__holder, attrId)

    def get(self, attrId, default=None):
        try:
            return self[attrId]
        except KeyError:
            return default

    def keys(self):
        # Return union of both keys which are already calculated in
        return self.__modifiedAttributes.keys() | self.__holder.item.attributes.keys()

    def clear(self):
        self.__modifiedAttributes.clear()

    def __calculate(self, attrId):
        """
        Run calculations to find the actual value of attribute.

        Positional arguments:
        attrId -- ID of attribute to be calculated

        Return value:
        Calculated attribute value

        Possible exceptions:
        BaseValueError -- attribute cannot be calculated, as its
        base value is not available
        """
        # Attribute object for attribute being calculated
        try:
            attrMeta = self.__holder.item._cacheHandler.getAttribute(attrId)
        # Raise error if we can't get to getAttribute method
        # or it can't find requested attribute
        except (AttributeError, AttributeFetchError) as e:
            raise AttributeMetaError(attrId) from e
        # Base attribute value which we'll use for modification
        try:
            result = self.__holder.item.attributes[attrId]
        # If attribute isn't available on base item,
        # base off its default value
        except KeyError:
            result = attrMeta.defaultValue
            # If original attribute is not specified and default
            # value isn't available, raise error - without valid
            # base we can't go on
            if result is None:
                raise BaseValueError(attrId)
        # Container for non-penalized modifiers
        # Format: {operator: [values]}
        normalMods = {}
        # Container for penalized modifiers
        # Format: {operator: [values]}
        penalizedMods = {}
        # Now, go through all affectors affecting our holder
        for affector in self.__holder.fit._linkTracker.getAffectors(self.__holder, attrId=attrId):
            try:
                sourceHolder, modifier = affector
                operator = modifier.operator
                # Decide if it should be stacking penalized or not, based on stackable property,
                # source item category and operator
                penalize = (attrMeta.stackable is False and not sourceHolder.item.categoryId in penaltyImmuneCategories
                            and operator in penalizableOperators)
                try:
                    modValue = sourceHolder.attributes[modifier.sourceAttributeId]
                # Silently skip current affector: error should already
                # be logged by map before it raised KeyError
                except KeyError:
                    continue
                # Normalize operations to just three types:
                # assignments, additions, multiplications
                try:
                    normalizationFunc = normalizationMap[operator]
                # Raise error on any unknown operator types
                except KeyError as e:
                    raise OperatorError(operator) from e
                modValue = normalizationFunc(modValue)
                # Add value to appropriate dictionary
                if penalize is True:
                    try:
                        modList = penalizedMods[operator]
                    except KeyError:
                        modList = penalizedMods[operator] = []
                else:
                    try:
                        modList = normalMods[operator]
                    except KeyError:
                        modList = normalMods[operator] = []
                modList.append(modValue)
            # Handle operator type failure
            except OperatorError as e:
                msg = "malformed modifier on item {}: unknown operator {}".format(sourceHolder.item.id, e.args[0])
                signature = (type(e), sourceHolder.item.id, e.args[0])
                self.__holder.fit._eos._logger.warning(msg, childName="attributeCalculator", signature=signature)
                continue
        # When data gathering is complete, process penalized modifiers
        # They are penalized on per-operator basis
        for operator, modList in penalizedMods.items():
            penalizedValue = self.__penalizeValues(modList)
            try:
                modList = normalMods[operator]
            except KeyError:
                modList = normalMods[operator] = []
            modList.append(penalizedValue)
        # Calculate result of normal dictionary, according to operator order
        for operator in sorted(normalMods):
            modList = normalMods[operator]
            # Pick best modifier for assignments, based on highIsGood value
            if operator in assignments:
                result = max(modList) if attrMeta.highIsGood is True else min(modList)
            elif operator in additions:
                for modVal in modList:
                    result += modVal
            elif operator in multiplications:
                for modVal in modList:
                    result *= modVal
        # If attribute has upper cap, do not let
        # its value to grow above it
        if attrMeta.maxAttributeId is not None:
            try:
                maxValue = self[attrMeta.maxAttributeId]
            # If max value isn't available, don't
            # cap anything
            except KeyError:
                pass
            else:
                result = min(result, maxValue)
                # Let map know that capping attribute
                # restricts current attribute
                if self._capMap is None:
                    self._capMap = KeyedSet()
                # Fill cap map with data: capping attribute and capped attribute
                self._capMap.addData(attrMeta.maxAttributeId, attrId)
        return result

    def __penalizeValues(self, modList):
        """
        Calculate aggregated factor of passed factors, taking into
        consideration stacking penalty.

        Positional argument:
        modList -- list of factors

        Return value:
        Final aggregated factor of passed modList
        """
        # Gather positive modifiers into one chain, negative
        # into another
        chainPositive = []
        chainNegative = []
        for modVal in modList:
            # Transform value into form of multiplier - 1 for ease of
            # stacking chain calculation
            modVal -= 1
            if modVal >= 0:
                chainPositive.append(modVal)
            else:
                chainNegative.append(modVal)
        # Strongest modifiers always go first
        chainPositive.sort(reverse=True)
        chainNegative.sort()
        # Base final multiplier on 1
        listResult = 1
        for chain in (chainPositive, chainNegative):
            # Same for intermediate per-chain result
            chainResult = 1
            for position, modifier in enumerate(chain):
                # Ignore 12th modifier and further as non-significant
                if position > 10:
                    break
                # Apply stacking penalty based on modifier position
                chainResult *= 1 + modifier * penaltyBase ** (position ** 2)
            listResult *= chainResult
        return listResult
Exemple #8
0
class SkillRequirementRegister(RestrictionRegister):
    """
    Implements restriction:
    To use holder, all its skill requirements must be met.

    Details:
    Only holders having level attribute are tracked.
    Original item attributes are taken to determine skill and
    skill level requirements.
    If corresponding skill is found, but its skill level is None,
    check for holder is failed.
    """

    def __init__(self):
        # Container for skill holders, for ease of
        # access
        # Format: {holder id: {holders}}
        self.__skillHolders = KeyedSet()
        # Set with holders which have any skill requirements
        # Format: {holders}
        self.__restrictedHolders = set()

    def registerHolder(self, holder):
        # Only holders which belong to character and have
        # level attribute are tracked as skills
        if hasattr(holder, "level") is True:
            self.__skillHolders.addData(holder.item.id, holder)
        # Holders which have any skill requirement are tracked
        if holder.item.requiredSkills:
            self.__restrictedHolders.add(holder)

    def unregisterHolder(self, holder):
        self.__skillHolders.rmData(holder.item.id, holder)
        self.__restrictedHolders.discard(holder)

    def validate(self):
        taintedHolders = {}
        # Go through restricted holders
        for holder in self.__restrictedHolders:
            # Container for skill requirement errors
            skillRequirementErrors = []
            # Check each skill requirement
            for requiredSkillId in holder.item.requiredSkills:
                requiredSkillLevel = holder.item.requiredSkills[requiredSkillId]
                skillHolders = self.__skillHolders.get(requiredSkillId) or ()
                # Pick max level of all skill holders, absence of skill
                # is considered as skill level set to None
                skillLevel = None
                for skillHolder in skillHolders:
                    skillHolderLevel = skillHolder.level
                    if skillLevel is None:
                        skillLevel = skillHolderLevel
                    elif skillHolderLevel is not None:
                        skillLevel = max(skillLevel, skillHolderLevel)
                # Last check - if skill level is lower than expected, current holder
                # is tainted; mark it so and move to the next one
                if skillLevel is None or skillLevel < requiredSkillLevel:
                    skillRequirementError = SkillRequirementErrorData(skill=requiredSkillId,
                                                                      level=skillLevel,
                                                                      requiredLevel=requiredSkillLevel)
                    skillRequirementErrors.append(skillRequirementError)
            if skillRequirementErrors:
                taintedHolders[holder] = tuple(skillRequirementErrors)
        if taintedHolders:
            raise RegisterValidationError(taintedHolders)

    @property
    def restrictionType(self):
        return Restriction.skillRequirement
Exemple #9
0
class SkillRequirementRegister(RestrictionRegister):
    """
    Implements restriction:
    To use holder, all its skill requirements must be met.

    Details:
    Only holders having level attribute are tracked.
    Original item attributes are taken to determine skill and
    skill level requirements.
    If corresponding skill is found, but its skill level is None,
    check for holder is failed.
    """
    def __init__(self):
        # Container for skill holders, for ease of
        # access
        # Format: {holder id: {holders}}
        self.__skillHolders = KeyedSet()
        # Set with holders which have any skill requirements
        # Format: {holders}
        self.__restrictedHolders = set()

    def registerHolder(self, holder):
        # Only holders which belong to character and have
        # level attribute are tracked as skills
        if hasattr(holder, 'level') is True:
            self.__skillHolders.addData(holder.item.id, holder)
        # Holders which have any skill requirement are tracked
        if holder.item.requiredSkills:
            self.__restrictedHolders.add(holder)

    def unregisterHolder(self, holder):
        self.__skillHolders.rmData(holder.item.id, holder)
        self.__restrictedHolders.discard(holder)

    def validate(self):
        taintedHolders = {}
        # Go through restricted holders
        for holder in self.__restrictedHolders:
            # Container for skill requirement errors
            skillRequirementErrors = []
            # Check each skill requirement
            for requiredSkillId in holder.item.requiredSkills:
                requiredSkillLevel = holder.item.requiredSkills[
                    requiredSkillId]
                skillHolders = self.__skillHolders.get(requiredSkillId) or ()
                # Pick max level of all skill holders, absence of skill
                # is considered as skill level set to None
                skillLevel = None
                for skillHolder in skillHolders:
                    skillHolderLevel = skillHolder.level
                    if skillLevel is None:
                        skillLevel = skillHolderLevel
                    elif skillHolderLevel is not None:
                        skillLevel = max(skillLevel, skillHolderLevel)
                # Last check - if skill level is lower than expected, current holder
                # is tainted; mark it so and move to the next one
                if skillLevel is None or skillLevel < requiredSkillLevel:
                    skillRequirementError = SkillRequirementErrorData(
                        skill=requiredSkillId,
                        level=skillLevel,
                        requiredLevel=requiredSkillLevel)
                    skillRequirementErrors.append(skillRequirementError)
            if skillRequirementErrors:
                taintedHolders[holder] = tuple(skillRequirementErrors)
        if taintedHolders:
            raise RegisterValidationError(taintedHolders)

    @property
    def restrictionType(self):
        return Restriction.skillRequirement
Exemple #10
0
class MutableAttributeMap:
    """
    Calculate, store and provide access to modified attribute values.

    Positional arguments:
    holder -- holder, to which this map is assigned
    """

    __slots__ = ('__holder', '__modifiedAttributes', '_capMap')

    def __init__(self, holder):
        # Reference to holder for internal needs
        self.__holder = holder
        # Actual container of calculated attributes
        # Format: {attribute ID: value}
        self.__modifiedAttributes = {}
        # This variable stores map of attributes which cap
        # something, and attributes capped by them. Initialized
        # to None to not waste memory, will be changed to dict
        # when needed.
        # Format {capping attribute ID: {capped attribute IDs}}
        self._capMap = None

    def __getitem__(self, attrId):
        # Special handling for skill level attribute
        if attrId == Attribute.skillLevel:
            # Attempt to return level attribute of holder
            try:
                val = self.__holder.level
            # Try regular way of getting attribute, if accessing
            # level attribute failed
            except AttributeError:
                pass
            else:
                return val
        # If carrier holder isn't assigned to any fit, then
        # we can use just item's original attributes
        if self.__holder._fit is None:
            val = self.__holder.item.attributes[attrId]
            return val
        # If value is stored, it's considered valid
        try:
            val = self.__modifiedAttributes[attrId]
        # Else, we have to run full calculation process
        except KeyError:
            try:
                val = self.__modifiedAttributes[attrId] = self.__calculate(
                    attrId)
            except BaseValueError as e:
                msg = 'unable to find base value for attribute {} on item {}'.format(
                    e.args[0], self.__holder.item.id)
                signature = (type(e), self.__holder.item.id, e.args[0])
                self.__holder._fit.eos._logger.warning(
                    msg, childName='attributeCalculator', signature=signature)
                raise KeyError(attrId) from e
            except AttributeMetaError as e:
                msg = 'unable to fetch metadata for attribute {}, requested for item {}'.format(
                    e.args[0], self.__holder.item.id)
                signature = (type(e), self.__holder.item.id, e.args[0])
                self.__holder._fit.eos._logger.error(
                    msg, childName='attributeCalculator', signature=signature)
                raise KeyError(attrId) from e
            self.__holder._fit._linkTracker.clearHolderAttributeDependents(
                self.__holder, attrId)
        return val

    def __len__(self):
        return len(self.keys())

    def __contains__(self, attrId):
        # Seek for attribute in both modified attribute container
        # and original item attributes
        result = attrId in self.__modifiedAttributes or attrId in self.__holder.item.attributes
        return result

    def __iter__(self):
        for k in self.keys():
            yield k

    def __delitem__(self, attrId):
        # Clear the value in our calculated attributes dictionary
        try:
            del self.__modifiedAttributes[attrId]
        # Do nothing if it wasn't calculated
        except KeyError:
            pass
        # And make sure all other attributes relying on it
        # are cleared too
        else:
            self.__holder._fit._linkTracker.clearHolderAttributeDependents(
                self.__holder, attrId)

    def __setitem__(self, attrId, value):
        # Write value and clear all attributes relying on it
        self.__modifiedAttributes[attrId] = value
        self.__holder._fit._linkTracker.clearHolderAttributeDependents(
            self.__holder, attrId)

    def get(self, attrId, default=None):
        try:
            return self[attrId]
        except KeyError:
            return default

    def keys(self):
        # Return union of both keys which are already calculated in
        return self.__modifiedAttributes.keys(
        ) | self.__holder.item.attributes.keys()

    def clear(self):
        """Reset map to its initial state."""
        self.__modifiedAttributes.clear()
        self._capMap = None

    def __calculate(self, attrId):
        """
        Run calculations to find the actual value of attribute.

        Positional arguments:
        attrId -- ID of attribute to be calculated

        Return value:
        Calculated attribute value

        Possible exceptions:
        BaseValueError -- attribute cannot be calculated, as its
        base value is not available
        """
        # Attribute object for attribute being calculated
        try:
            attrMeta = self.__holder._fit.eos._cacheHandler.getAttribute(
                attrId)
        # Raise error if we can't get to getAttribute method
        # or it can't find requested attribute
        except (AttributeError, AttributeFetchError) as e:
            raise AttributeMetaError(attrId) from e
        # Base attribute value which we'll use for modification
        try:
            result = self.__holder.item.attributes[attrId]
        # If attribute isn't available on base item,
        # base off its default value
        except KeyError:
            result = attrMeta.defaultValue
            # If original attribute is not specified and default
            # value isn't available, raise error - without valid
            # base we can't go on
            if result is None:
                raise BaseValueError(attrId)
        # Container for non-penalized modifiers
        # Format: {operator: [values]}
        normalMods = {}
        # Container for penalized modifiers
        # Format: {operator: [values]}
        penalizedMods = {}
        # Now, go through all affectors affecting our holder
        for affector in self.__holder._fit._linkTracker.getAffectors(
                self.__holder, attrId=attrId):
            try:
                sourceHolder, modifier = affector
                operator = modifier.operator
                # Decide if it should be stacking penalized or not, based on stackable property,
                # source item category and operator
                penalize = (attrMeta.stackable is False
                            and sourceHolder.item.categoryId
                            not in penaltyImmuneCategories
                            and operator in penalizableOperators)
                try:
                    modValue = sourceHolder.attributes[
                        modifier.sourceAttributeId]
                # Silently skip current affector: error should already
                # be logged by map before it raised KeyError
                except KeyError:
                    continue
                # Normalize operations to just three types:
                # assignments, additions, multiplications
                try:
                    normalizationFunc = normalizationMap[operator]
                # Raise error on any unknown operator types
                except KeyError as e:
                    raise OperatorError(operator) from e
                modValue = normalizationFunc(modValue)
                # Add value to appropriate dictionary
                if penalize is True:
                    modList = penalizedMods.setdefault(operator, [])
                else:
                    modList = normalMods.setdefault(operator, [])
                modList.append(modValue)
            # Handle operator type failure
            except OperatorError as e:
                msg = 'malformed modifier on item {}: unknown operator {}'.format(
                    sourceHolder.item.id, e.args[0])
                signature = (type(e), sourceHolder.item.id, e.args[0])
                self.__holder._fit.eos._logger.warning(
                    msg, childName='attributeCalculator', signature=signature)
                continue
        # When data gathering is complete, process penalized modifiers
        # They are penalized on per-operator basis
        for operator, modList in penalizedMods.items():
            penalizedValue = self.__penalizeValues(modList)
            modList = normalMods.setdefault(operator, [])
            modList.append(penalizedValue)
        # Calculate result of normal dictionary, according to operator order
        for operator in sorted(normalMods):
            modList = normalMods[operator]
            # Pick best modifier for assignments, based on highIsGood value
            if operator in assignments:
                result = max(modList) if attrMeta.highIsGood is True else min(
                    modList)
            elif operator in additions:
                for modVal in modList:
                    result += modVal
            elif operator in multiplications:
                for modVal in modList:
                    result *= modVal
        # If attribute has upper cap, do not let
        # its value to grow above it
        if attrMeta.maxAttributeId is not None:
            try:
                maxValue = self[attrMeta.maxAttributeId]
            # If max value isn't available, don't
            # cap anything
            except KeyError:
                pass
            else:
                result = min(result, maxValue)
                # Let map know that capping attribute
                # restricts current attribute
                if self._capMap is None:
                    self._capMap = KeyedSet()
                # Fill cap map with data: capping attribute and capped attribute
                self._capMap.addData(attrMeta.maxAttributeId, attrId)
        return result

    def __penalizeValues(self, modList):
        """
        Calculate aggregated factor of passed factors, taking into
        consideration stacking penalty.

        Positional argument:
        modList -- list of factors

        Return value:
        Final aggregated factor of passed modList
        """
        # Gather positive modifiers into one chain, negative
        # into another
        chainPositive = []
        chainNegative = []
        for modVal in modList:
            # Transform value into form of multiplier - 1 for ease of
            # stacking chain calculation
            modVal -= 1
            if modVal >= 0:
                chainPositive.append(modVal)
            else:
                chainNegative.append(modVal)
        # Strongest modifiers always go first
        chainPositive.sort(reverse=True)
        chainNegative.sort()
        # Base final multiplier on 1
        listResult = 1
        for chain in (chainPositive, chainNegative):
            # Same for intermediate per-chain result
            chainResult = 1
            for position, modifier in enumerate(chain):
                # Ignore 12th modifier and further as non-significant
                if position > 10:
                    break
                # Apply stacking penalty based on modifier position
                chainResult *= 1 + modifier * penaltyBase**(position**2)
            listResult *= chainResult
        return listResult