cuberite-2a/src/ChunkDef.h

// ChunkDef.h

// Interfaces to helper types for chunk definitions. Most modules want to include this instead of cChunk.h





#pragma once

#include "Vector3.h"
#include "BiomeDef.h"





/** This is really only a placeholder to be used in places where we need to "make up" a chunk's Y coord.
It will help us when the new chunk format comes out and we need to patch everything up for compatibility.
*/
#define ZERO_CHUNK_Y 0

// Used to smoothly convert to new axis ordering. One will be removed when deemed stable.
#define AXIS_ORDER_YZX 1  // Original (1.1-)
#define AXIS_ORDER_XZY 2  // New (1.2+)
#define AXIS_ORDER AXIS_ORDER_XZY





// fwd
class cBlockEntity;
class cEntity;
class cClientHandle;
class cBlockEntity;

typedef std::list<cEntity *>        cEntityList;
typedef std::list<cBlockEntity *>   cBlockEntityList;




// tolua_begin

/// The datatype used by blockdata
typedef unsigned char BLOCKTYPE;

/// The datatype used by nibbledata (meta, light, skylight)
typedef unsigned char NIBBLETYPE;

/// The type used by the heightmap
typedef unsigned char HEIGHTTYPE;

// tolua_end




/// Constants used throughout the code, useful typedefs and utility functions
class cChunkDef
{
public:
	// Chunk dimensions:
	static const int Width = 16;
	static const int Height = 256;
	static const int NumBlocks = Width * Height * Width;
	/// If the data is collected into a single buffer, how large it needs to be:
	static const int BlockDataSize = cChunkDef::NumBlocks * 2 + (cChunkDef::NumBlocks / 2);  // 2.5 * numblocks

	/// The type used for any heightmap operations and storage; idx = x + Width * z; Height points to the highest non-air block in the column
	typedef HEIGHTTYPE HeightMap[Width * Width];
	
	/** The type used for any biomemap operations and storage inside MCServer,
	using MCServer biomes (need not correspond to client representation!)
	idx = x + Width * z  // Need to verify this with the protocol spec, currently unknown!
	*/
	typedef EMCSBiome BiomeMap[Width * Width];

	/// The type used for block type operations and storage, AXIS_ORDER ordering
	typedef BLOCKTYPE BlockTypes[NumBlocks];

	/// The type used for block data in nibble format, AXIS_ORDER ordering
	typedef NIBBLETYPE BlockNibbles[NumBlocks / 2];

	/** The storage wrapper used for compressed blockdata residing in RAMz */
	typedef std::vector<BLOCKTYPE> COMPRESSED_BLOCKTYPE;

	/** The storage wrapper used for compressed nibbledata residing in RAMz */
	typedef std::vector<NIBBLETYPE> COMPRESSED_NIBBLETYPE;


	/// Converts absolute block coords into relative (chunk + block) coords:
	inline static void AbsoluteToRelative(/* in-out */ int & a_X, int & a_Y, int & a_Z, /* out */ int & a_ChunkX, int & a_ChunkZ)
	{
		UNUSED(a_Y);
		BlockToChunk(a_X, a_Z, a_ChunkX, a_ChunkZ);

		a_X = a_X - a_ChunkX * Width;
		a_Z = a_Z - a_ChunkZ * Width;
	}
	
	
	/// Converts absolute block coords to chunk coords:
	inline static void BlockToChunk(int a_X, int a_Z, int & a_ChunkX, int & a_ChunkZ)
	{
		a_ChunkX = a_X / Width;
		if ((a_X < 0) && (a_X % Width != 0))
		{
			a_ChunkX--;
		}
		a_ChunkZ = a_Z / cChunkDef::Width;
		if ((a_Z < 0) && (a_Z % Width != 0))
		{
			a_ChunkZ--;
		}
	}


	inline static int MakeIndex(int x, int y, int z)
	{
		if (
			(x < Width)  && (x > -1) &&
			(y < Height) && (y > -1) &&
			(z < Width)  && (z > -1)
		)
		{
			return MakeIndexNoCheck(x, y, z);
		}
		LOGERROR("cChunkDef::MakeIndex(): coords out of range: {%d, %d, %d}; returning fake index 0", x, y, z);
		ASSERT(!"cChunkDef::MakeIndex(): coords out of chunk range!");
		return 0;
	}


	inline static int MakeIndexNoCheck(int x, int y, int z)
	{
		#if AXIS_ORDER == AXIS_ORDER_XZY
			// For some reason, NOT using the Horner schema is faster. Weird.
			return x + (z * cChunkDef::Width) + (y * cChunkDef::Width * cChunkDef::Width);   // 1.2 uses XZY
		#elif AXIS_ORDER == AXIS_ORDER_YZX
			return y + (z * cChunkDef::Width) + (x * cChunkDef::Height * cChunkDef::Width);  // 1.1 uses YZX
		#endif
	}


	inline static Vector3i IndexToCoordinate( unsigned int index)
	{
		#if AXIS_ORDER == AXIS_ORDER_XZY
			return Vector3i(  // 1.2
				index % cChunkDef::Width,                       // X
				index / (cChunkDef::Width * cChunkDef::Width),  // Y
				(index / cChunkDef::Width) % cChunkDef::Width   // Z
			);
		#elif AXIS_ORDER == AXIS_ORDER_YZX
			return Vector3i(  // 1.1
				index / (cChunkDef::Height * cChunkDef::Width),  // X
				index % cChunkDef::Height,                       // Y
				(index / cChunkDef::Height) % cChunkDef::Width   // Z
			);
		#endif
	}


	inline static void SetBlock(BLOCKTYPE * a_BlockTypes, int a_X, int a_Y, int a_Z, BLOCKTYPE a_Type)
	{
		ASSERT((a_X >= 0) && (a_X < Width));
		ASSERT((a_Y >= 0) && (a_Y < Height));
		ASSERT((a_Z >= 0) && (a_Z < Width));
		a_BlockTypes[MakeIndexNoCheck(a_X, a_Y, a_Z)] = a_Type;
	}
	
	
	inline static void SetBlock(BLOCKTYPE * a_BlockTypes, int a_Index, BLOCKTYPE a_Type)
	{
		ASSERT((a_Index >= 0) && (a_Index <= NumBlocks));
		a_BlockTypes[a_Index] = a_Type;
	}
	
	
	inline static BLOCKTYPE GetBlock(const BLOCKTYPE * a_BlockTypes, int a_X, int a_Y, int a_Z)
	{
		ASSERT((a_X >= 0) && (a_X < Width));
		ASSERT((a_Y >= 0) && (a_Y < Height));
		ASSERT((a_Z >= 0) && (a_Z < Width));
		return a_BlockTypes[MakeIndexNoCheck(a_X, a_Y, a_Z)];
	}
	
	
	inline static BLOCKTYPE GetBlock(const BLOCKTYPE * a_BlockTypes, int a_Idx)
	{
		ASSERT((a_Idx >= 0) && (a_Idx < NumBlocks));
		return a_BlockTypes[a_Idx];
	}
	
	
	inline static int GetHeight(const HeightMap & a_HeightMap, int a_X, int a_Z)
	{
		ASSERT((a_X >= 0) && (a_X <= Width));
		ASSERT((a_Z >= 0) && (a_Z <= Width));
		return a_HeightMap[a_X + Width * a_Z];
	}
	
	
	inline static void SetHeight(HeightMap & a_HeightMap, int a_X, int a_Z, unsigned char a_Height)
	{
		ASSERT((a_X >= 0) && (a_X <= Width));
		ASSERT((a_Z >= 0) && (a_Z <= Width));
		a_HeightMap[a_X + Width * a_Z] = a_Height;
	}
	
	
	inline static EMCSBiome GetBiome(const BiomeMap & a_BiomeMap, int a_X, int a_Z)
	{
		ASSERT((a_X >= 0) && (a_X <= Width));
		ASSERT((a_Z >= 0) && (a_Z <= Width));
		return a_BiomeMap[a_X + Width * a_Z];
	}
	
	
	inline static void SetBiome(BiomeMap & a_BiomeMap, int a_X, int a_Z, EMCSBiome a_Biome)
	{
		ASSERT((a_X >= 0) && (a_X <= Width));
		ASSERT((a_Z >= 0) && (a_Z <= Width));
		a_BiomeMap[a_X + Width * a_Z] = a_Biome;
	}


	static NIBBLETYPE GetNibble(const COMPRESSED_NIBBLETYPE & a_Buffer, int a_BlockIdx, bool a_IsSkyLightNibble = false)
	{
		if ((a_BlockIdx > -1) && (a_BlockIdx < NumBlocks))
		{
			if ((size_t)(a_BlockIdx / 2) >= a_Buffer.size())
			{
				return (a_IsSkyLightNibble ? 0xff : 0);
			}
			return (a_Buffer[(size_t)(a_BlockIdx / 2)] >> ((a_BlockIdx & 1) * 4)) & 0x0f;
		}
		ASSERT(!"cChunkDef::GetNibble(): index out of chunk range!");
		return 0;
	}


	static NIBBLETYPE GetNibble(const COMPRESSED_NIBBLETYPE & a_Buffer, int x, int y, int z, bool a_IsSkyLightNibble = false)
	{
		if ((x < Width) && (x > -1) && (y < Height) && (y > -1) && (z < Width) && (z > -1))
		{
			size_t Index = (size_t)MakeIndexNoCheck(x, y, z);
			if ((Index / 2) >= a_Buffer.size())
			{
				return (a_IsSkyLightNibble ? 0xff : 0);
			}
			return ExpandNibble(a_Buffer, Index);
		}
		ASSERT(!"cChunkDef::GetNibble(): coords out of chunk range!");
		return 0;
	}


	static NIBBLETYPE GetNibble(const NIBBLETYPE * a_Buffer, int x, int y, int z)
	{
		if ((x < Width) && (x > -1) && (y < Height) && (y > -1) && (z < Width) && (z > -1))
		{
			int Index = MakeIndexNoCheck(x, y, z);
			return (a_Buffer[(size_t)(Index / 2)] >> ((Index & 1) * 4)) & 0x0f;
		}
		ASSERT(!"cChunkDef::GetNibble(): coords out of chunk range!");
		return 0;
	}


	static void SetNibble(COMPRESSED_NIBBLETYPE & a_Buffer, int a_BlockIdx, NIBBLETYPE a_Nibble)
	{
		if ((a_BlockIdx < 0) || (a_BlockIdx >= NumBlocks))
		{
			ASSERT(!"cChunkDef::SetNibble(): index out of range!");
			return;
		}
		if ((size_t)(a_BlockIdx / 2) >= a_Buffer.size())
		{
			a_Buffer.resize((size_t)((a_BlockIdx / 2) + 1));
		}
		a_Buffer[(size_t)(a_BlockIdx / 2)] = PackNibble(a_Buffer, (size_t)a_BlockIdx, a_Nibble);
	}


	static void SetNibble(COMPRESSED_NIBBLETYPE & a_Buffer, int x, int y, int z, NIBBLETYPE a_Nibble)
	{
		if (
			(x >= Width)  || (x < 0) ||
			(y >= Height) || (y < 0) ||
			(z >= Width)  || (z < 0)
		)
		{
			ASSERT(!"cChunkDef::SetNibble(): index out of range!");
			return;
		}

		size_t Index = (size_t)MakeIndexNoCheck(x, y, z);
		if ((Index / 2) >= a_Buffer.size())
		{
			a_Buffer.resize(((Index / 2) + 1));
		}
		a_Buffer[(Index / 2)] = PackNibble(a_Buffer, Index, a_Nibble);
	}


private:


	inline static NIBBLETYPE PackNibble(const COMPRESSED_NIBBLETYPE & a_Buffer, size_t a_Index, NIBBLETYPE a_Nibble)
	{
		return static_cast<NIBBLETYPE>(
			(a_Buffer[a_Index / 2] & (0xf0 >> ((a_Index & 1) * 4))) |  // The untouched nibble
			((a_Nibble & 0x0f) << ((a_Index & 1) * 4))  // The nibble being set
		);
	}


	inline static NIBBLETYPE ExpandNibble(const COMPRESSED_NIBBLETYPE & a_Buffer, size_t a_Index)
	{
		return (a_Buffer[a_Index / 2] >> ((a_Index & 1) * 4)) & 0x0f;
	}


} ;





/** Interface class used for comparing clients of two chunks.
Used primarily for entity moving while both chunks are locked.
*/
class cClientDiffCallback
{
public:

	virtual ~cClientDiffCallback() {}

	/// Called for clients that are in Chunk1 and not in Chunk2,
	virtual void Removed(cClientHandle * a_Client) = 0;
	
	/// Called for clients that are in Chunk2 and not in Chunk1.
	virtual void Added(cClientHandle * a_Client) = 0;
} ;





struct sSetBlock
{
	int x, y, z;
	int ChunkX, ChunkZ;
	BLOCKTYPE BlockType;
	NIBBLETYPE BlockMeta;

	sSetBlock( int a_BlockX, int a_BlockY, int a_BlockZ, BLOCKTYPE a_BlockType, NIBBLETYPE a_BlockMeta);  // absolute block position
	sSetBlock(int a_ChunkX, int a_ChunkZ, int a_X, int a_Y, int a_Z, BLOCKTYPE a_BlockType, NIBBLETYPE a_BlockMeta) :
		x(a_X), y(a_Y), z(a_Z),
		ChunkX(a_ChunkX), ChunkZ(a_ChunkZ),
		BlockType(a_BlockType),
		BlockMeta(a_BlockMeta)
	{}
};

typedef std::list<sSetBlock> sSetBlockList;
typedef std::vector<sSetBlock> sSetBlockVector;





class cChunkCoords
{
public:
	int m_ChunkX;
	int m_ChunkY;
	int m_ChunkZ;
	
	cChunkCoords(int a_ChunkX, int a_ChunkY, int a_ChunkZ) : m_ChunkX(a_ChunkX), m_ChunkY(a_ChunkY), m_ChunkZ(a_ChunkZ) {}
	
	bool operator == (const cChunkCoords & a_Other) const
	{
		return ((m_ChunkX == a_Other.m_ChunkX) && (m_ChunkY == a_Other.m_ChunkY) && (m_ChunkZ == a_Other.m_ChunkZ));
	}
} ;

typedef std::list<cChunkCoords> cChunkCoordsList;
typedef std::vector<cChunkCoords> cChunkCoordsVector;





/// Interface class used as a callback for operations that involve chunk coords
class cChunkCoordCallback
{
public:

	virtual ~cChunkCoordCallback() {}

	virtual void Call(int a_ChunkX, int a_ChunkZ) = 0;
} ;





/** Generic template that can store any kind of data together with a triplet of 3 coords*/
template <typename X> class cCoordWithData
{
public:
	int x;
	int y;
	int z;
	X   Data;
	
	cCoordWithData(int a_X, int a_Y, int a_Z) :
		x(a_X), y(a_Y), z(a_Z)
	{
	}
	
	cCoordWithData(int a_X, int a_Y, int a_Z, const X & a_Data) :
		x(a_X), y(a_Y), z(a_Z), Data(a_Data)
	{
	}
} ;

typedef cCoordWithData<int>        cCoordWithInt;
typedef cCoordWithData<BLOCKTYPE>  cCoordWithBlock;

typedef std::list<cCoordWithInt>   cCoordWithIntList;
typedef std::vector<cCoordWithInt> cCoordWithIntVector;





/** Generic template that can store two types of any kind of data together with a triplet of 3 coords */
template <typename X, typename Z> class cCoordWithDoubleData
{
public:
	int x;
	int y;
	int z;
	X   Data;
	Z   DataTwo;

	cCoordWithDoubleData(int a_X, int a_Y, int a_Z) :
		x(a_X), y(a_Y), z(a_Z)
	{
	}

	cCoordWithDoubleData(int a_X, int a_Y, int a_Z, const X & a_Data, const Z & a_DataTwo) :
		x(a_X), y(a_Y), z(a_Z), Data(a_Data), DataTwo(a_DataTwo)
	{
	}
};

typedef cCoordWithDoubleData <BLOCKTYPE, bool> cCoordWithBlockAndBool;

typedef std::vector<cCoordWithBlockAndBool> cCoordWithBlockAndBoolVector;