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// PiecePool.h
// Declares the cPiecePool class representing a pool of cPieces - "parts" of a structure, used in piece-generators
#pragma once
#include "ComposableGenerator.h"
#include "../Defines.h"
#include "../Cuboid.h"
/** Represents a single piece. Can have multiple connectors of different types where other pieces can connect. */
class cPiece
{
public:
// Force a virtual destructor in all descendants
virtual ~cPiece() {}
struct cConnector
{
enum eDirection
{
// The following values correspond to equivalent eBlockFace values:
dirXM = BLOCK_FACE_XM, // Pointing towards the X- side of the prefab
dirXP = BLOCK_FACE_XP, // Pointing towards the X+ side of the prefab
dirYM = BLOCK_FACE_YM, // Pointing towards the Y- side of the prefab, doesn't change with rotation around the Y axis
dirYP = BLOCK_FACE_YP, // Pointing towards the Y+ side of the prefab, doesn't change with rotation around the Y axis
dirZM = BLOCK_FACE_ZM, // Pointing towards the Z- side of the prefab
dirZP = BLOCK_FACE_ZP, // Pointing towards the Z+ side of the prefab
// Special kind of the vertical connectors (changes with rotation around the Y axis)
dirYM_XM_ZM = BLOCK_FACE_MAX + 1, // Pointing towards the Y- side of the prefab, conceptually at the X- Z- corner of the block
dirYM_XM_ZP, // Pointing towards the Y- side of the prefab, conceptually at the X- Z+ corner of the block
dirYM_XP_ZM, // Pointing towards the Y- side of the prefab, conceptually at the X+ Z- corner of the block
dirYM_XP_ZP, // Pointing towards the Y- side of the prefab, conceptually at the X+ Z+ corner of the block
dirYP_XM_ZM, // Pointing towards the Y+ side of the prefab, conceptually at the X- Z- corner of the block
dirYP_XM_ZP, // Pointing towards the Y+ side of the prefab, conceptually at the X- Z+ corner of the block
dirYP_XP_ZM, // Pointing towards the Y+ side of the prefab, conceptually at the X+ Z- corner of the block
dirYP_XP_ZP, // Pointing towards the Y+ side of the prefab, conceptually at the X+ Z+ corner of the block
};
/** Position relative to the piece */
Vector3i m_Pos;
/** Type of the connector. Any arbitrary number; the generator connects only connectors of opposite
(negative) types. */
int m_Type;
/** Direction in which the connector is facing.
Will be matched by the opposite direction for the connecting connector. */
eDirection m_Direction;
cConnector(int a_X, int a_Y, int a_Z, int a_Type, eDirection a_Direction);
cConnector(const Vector3i & a_Pos, int a_Type, eDirection a_Direction);
/** Returns the position of the block that has the specified direction from the specified position.
Similar to ::AddFaceDirection() */
static Vector3i AddDirection(const Vector3i & a_Pos, eDirection a_Direction);
/** Returns the string representation of the direction.
For debugging purposes. */
static const char * DirectionToString(eDirection a_Direction);
/** Returns true if the specified number corresponds to a valid eDirection. */
static bool IsValidDirection(int a_Direction);
/** Returns the direction corresponding to the given direction rotated 180 degrees around the Y axis. */
static eDirection RotateDirection(eDirection a_Direction);
/** Returns the direction corresponding to the given direction rotated 90 degrees CCW around the Y axis. */
static eDirection RotateDirectionCCW(eDirection a_Direction);
/** Returns the direction corresponding to the given direction rotated 90 degrees CW around the Y axis. */
static eDirection RotateDirectionCW(eDirection a_Direction);
/** Returns the number of CCW rotations that a_RotatingDir requires in order to be the counter-direction of a_FixedDir.
Ie. if you have a connector with a_FixedDir and you're rotating a piece that has a connector with a_RotatingDir,
how many CCW rotations it needs to make the connectors compatible.
Returns -1 if it is impossible to fit the two directions. */
static int GetNumCCWRotationsToFit(eDirection a_FixedDir, eDirection a_RotatingDir);
/** Converts the string representation of a direction into the eDirection enum value.
Returns true if successful, false on failure.
Accepts both numbers and string representations such as "x+" or "Y+X-Z+". */
static bool StringToDirection(const AString & a_Value, eDirection & a_Out);
};
typedef std::vector<cConnector> cConnectors;
/** Base class (interface) for strategies for placing the starting pieces vertically.
Descendants can override the GetVerticalPlacement() method to provide custom placement decisions. */
class cVerticalStrategy
{
public:
// Force a virtual destructor in descendants
virtual ~cVerticalStrategy() {}
/** Returns the Y coord of the piece */
virtual int GetVerticalPlacement(int a_BlockX, int a_BlockZ) = 0;
/** Initializes the strategy's parameters from the string representation.
a_Params is the string containing only the parameters (substring after the first pipe character in the strategy description string).
If a_LogWarnings is true, logs any problems to the console.
Returns true if successful, false if the string parsing failed.
Used when loading the strategy from a file. */
virtual bool InitializeFromString(const AString & a_Params, bool a_LogWarnings) = 0;
/** Called when the piece pool is assigned to a generator,
so that the strategies may bind to the underlying subgenerators. */
virtual void AssignGens(int a_Seed, cBiomeGenPtr & a_BiomeGen, cTerrainHeightGenPtr & a_TerrainHeightGen, int a_SeaLevel) {}
};
typedef std::shared_ptr<cVerticalStrategy> cVerticalStrategyPtr;
/** Base class (interface) for the vertical limit of piece placement.
Each placed piece can have a limit, represented by this class, that gets queried for validity of the placement. */
class cVerticalLimit
{
public:
virtual ~cVerticalLimit() {}
/** Called to inquire whether the specified piece can be placed at the specified height.
a_BlockX, a_BlockZ is the column of the connector that is being queried.
a_Height is the requested height of the piece's lowest block. */
virtual bool CanBeAtHeight(int a_BlockX, int a_BlockZ, int a_Height) = 0;
/** Initializes the limit's parameters from the string representation.
a_Params is the string containing only the parameters (substring after the first pipe character in the limit description string).
Returns true if successful, false if the string parsing failed.
If a_LogWarnings is true, any error while parsing the string is output to the server console.
Used when loading the limit from a file. */
virtual bool InitializeFromString(const AString & a_Params, bool a_LogWarnings) = 0;
/** Called when the piece pool is assigned to a generator,
so that the limits may bind to the underlying subgenerators. */
virtual void AssignGens(int a_Seed, cBiomeGenPtr & a_BiomeGen, cTerrainHeightGenPtr & a_TerrainHeightGen, int a_SeaLevel) {}
};
typedef std::shared_ptr<cVerticalLimit> cVerticalLimitPtr;
/** The strategy used for vertical placement of this piece when it is used as a starting piece. */
cVerticalStrategyPtr m_VerticalStrategy;
/** The checker that verifies each placement's vertical position. */
cVerticalLimitPtr m_VerticalLimit;
/** Returns all of the available connectors that the piece has.
Each connector has a (relative) position in the piece, and a type associated with it. */
virtual cConnectors GetConnectors(void) const = 0;
/** Returns the dimensions of this piece.
The dimensions cover the entire piece, there is no block that the piece generates outside of this size. */
virtual Vector3i GetSize(void) const = 0;
/** Returns the "hitbox" of this piece.
A hitbox is what is compared and must not intersect other pieces' hitboxes when generating. */
virtual cCuboid GetHitBox(void) const = 0;
/** Returns true if the piece can be rotated CCW the specific number of 90-degree turns. */
virtual bool CanRotateCCW(int a_NumRotations) const = 0;
/** Returns the height, based on m_VerticalStrategy, for this piece when used as the starting piece.
If there's no strategy assigned to this piece, returns -1. */
int GetStartingPieceHeight(int a_BlockX, int a_BlockZ)
{
if (m_VerticalStrategy != nullptr)
{
return m_VerticalStrategy->GetVerticalPlacement(a_BlockX, a_BlockZ);
}
return -1;
}
void SetVerticalStrategy(cVerticalStrategyPtr a_VerticalStrategy)
{
m_VerticalStrategy = std::move(a_VerticalStrategy);
}
cVerticalStrategyPtr GetVerticalStrategy(void) const
{
return m_VerticalStrategy;
}
cVerticalLimitPtr GetVerticalLimit(void) const
{
return m_VerticalLimit;
}
/** Sets the vertical strategy based on the description in the string.
If a_LogWarnings is true, logs the parsing problems into the server console.
Returns true if successful, false if strategy parsing failed (no strategy assigned). */
bool SetVerticalStrategyFromString(const AString & a_StrategyDesc, bool a_LogWarnings);
/** Sets the vertical limit based on the description string.
Returns true if successful, false if limit parsing failed (no limit assigned).
If a_LogWarnings is true, any problem is reported into the server console. */
bool SetVerticalLimitFromString(const AString & a_LimitDesc, bool a_LogWarnings);
/** Returns a copy of the a_Pos after rotating the piece the specified number of CCW rotations. */
Vector3i RotatePos(const Vector3i & a_Pos, int a_NumCCWRotations) const;
/** Returns a copy of the connector that is rotated and then moved by the specified amounts. */
cConnector RotateMoveConnector(const cConnector & a_Connector, int a_NumCCWRotations, int a_MoveX, int a_MoveY, int a_MoveZ) const;
/** Returns the hitbox after the specified number of rotations and moved so that a_MyConnector is placed at a_ToConnectorPos. */
cCuboid RotateHitBoxToConnector(const cConnector & a_MyConnector, const Vector3i & a_ToConnectorPos, int a_NumCCWRotations) const;
/** Returns the hitbox after the specified number of CCW rotations and moved by the specified amounts. */
cCuboid RotateMoveHitBox(int a_NumCCWRotations, int a_MoveX, int a_MoveY, int a_MoveZ) const;
};
typedef std::vector<cPiece *> cPieces;
// fwd:
class cPlacedPiece;
/** This class is an interface that stores pieces for a generator.
Provides lists of pieces based on criteria (IsStarting, HasConnector).
Provides per-piece weights for random distribution of individual pieces. */
class cPiecePool
{
public:
// Force a virtual destructor in all descendants:
virtual ~cPiecePool() {}
/** Returns a list of pieces that contain the specified connector type.
The cPiece pointers returned are managed by the pool and the caller doesn't free them. */
virtual cPieces GetPiecesWithConnector(int a_ConnectorType) = 0;
/** Returns the pieces that should be used as the starting point.
Multiple starting points are supported, one of the returned piece will be chosen. */
virtual cPieces GetStartingPieces(void) = 0;
/** Returns the relative weight with which the a_NewPiece is to be selected for placing under a_PlacedPiece through a_ExistingConnector.
a_ExistingConnector is the original connector, before any movement or rotation is applied to it.
This allows the pool to tweak the piece's chances, based on the previous pieces in the tree and the connector used.
The higher the number returned, the higher the chance the piece will be chosen. 0 means the piece will never be chosen. */
virtual int GetPieceWeight(
const cPlacedPiece & a_PlacedPiece,
const cPiece::cConnector & a_ExistingConnector,
const cPiece & a_NewPiece
)
{
return 1;
}
/** Returns the relative weight with which the a_NewPiece is to be selected for placing as the first piece.
This allows the pool to tweak the piece's chances.
The higher the number returned, the higher the chance the piece will be chosen. 0 means the piece will not be chosen.
If all pieces return 0, a random piece is chosen, with all equal chances. */
virtual int GetStartingPieceWeight(const cPiece & a_NewPiece)
{
return 1;
}
/** Called after a piece is placed, to notify the pool that it has been used.
The pool may adjust the pieces it will return the next time. */
virtual void PiecePlaced(const cPiece & a_Piece) = 0;
/** Called when the pool has finished the current structure and should reset any piece-counters it has
for a new structure. */
virtual void Reset(void) = 0;
};
/** Represents a single piece that has been placed to specific coords in the world. */
class cPlacedPiece
{
public:
cPlacedPiece(const cPlacedPiece * a_Parent, const cPiece & a_Piece, const Vector3i & a_Coords, int a_NumCCWRotations);
const cPlacedPiece * GetParent (void) const { return m_Parent; }
const cPiece & GetPiece (void) const { return *m_Piece; }
const Vector3i & GetCoords (void) const { return m_Coords; }
int GetNumCCWRotations (void) const { return m_NumCCWRotations; }
const cCuboid & GetHitBox (void) const { return m_HitBox; }
int GetDepth (void) const { return m_Depth; }
bool HasBeenMovedToGround(void) const { return m_HasBeenMovedToGround; }
/** Returns the coords as a modifiable object. */
Vector3i & GetCoords(void) { return m_Coords; }
/** Returns the connector at the specified index, rotated in the actual placement.
Undefined behavior if a_Index is out of range. */
cPiece::cConnector GetRotatedConnector(size_t a_Index) const;
/** Returns a copy of the specified connector, modified to account for the translation and rotation for
this placement. */
cPiece::cConnector GetRotatedConnector(const cPiece::cConnector & a_Connector) const;
/** Moves the placed piece Y-wise by the specified offset.
Sets m_HasBeenMovedToGround to true, too.
Used eg. by village houses. */
void MoveToGroundBy(int a_OffsetY);
protected:
const cPlacedPiece * m_Parent;
const cPiece * m_Piece;
Vector3i m_Coords;
int m_NumCCWRotations;
cCuboid m_HitBox; // Hitbox of the placed piece, in world coords
int m_Depth; // Depth in the generated piece tree
/** Set to true once the piece has been moved Y-wise.
Used eg. by village houses. */
bool m_HasBeenMovedToGround;
};
typedef std::unique_ptr<cPlacedPiece> cPlacedPiecePtr;
typedef std::vector<cPlacedPiecePtr> cPlacedPieces;
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