#ifdef TEST_GLOBALS
#include "TestGlobals.h"
#else
#include "Globals.h"
#endif
#include "ChunkData.h"
cChunkData::cChunkData(cAllocationPool<cChunkData::sChunkSection, 1600>& a_Pool) :
#if __cplusplus < 201103L
// auto_ptr style interface for memory management
IsOwner(true),
#endif
m_Pool(a_Pool)
{
memset(m_Sections, 0, sizeof(m_Sections));
}
cChunkData::~cChunkData()
{
#if __cplusplus < 201103L
// auto_ptr style interface for memory management
if (!IsOwner)
{
return;
}
#endif
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
if (m_Sections[i] == NULL) Free(m_Sections[i]);;
}
}
#if __cplusplus < 201103L
// auto_ptr style interface for memory management
cChunkData::cChunkData(const cChunkData& other) :
IsOwner(true),
m_Pool(other.m_Pool)
{
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
m_Sections[i] = other.m_Sections[i];
}
other.IsOwner = false;
}
cChunkData& cChunkData::operator=(const cChunkData& other)
{
if (&other != this)
{
if (IsOwner)
{
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
if (m_Sections[i]) Free(m_Sections[i]);;
}
}
IsOwner = true;
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
m_Sections[i] = other.m_Sections[i];
}
other.IsOwner = false;
ASSERT(&m_Pool == &other.m_Pool);
}
return *this;
}
#else
// unique_ptr style interface for memory management
cChunkData::cChunkData(cChunkData&& other) :
m_Pool(other.m_Pool)
{
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
m_Sections[i] = other.m_Sections[i];
other.m_Sections[i] = NULL;
}
}
cChunkData& cChunkData::operator=(cChunkData&& other)
{
if (&other != this)
{
ASSERT(&m_Pool == &other.m_Pool);
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
Free(m_Sections[i]);;
m_Sections[i] = other.m_Sections[i];
other.m_Sections[i] = NULL;
}
}
return *this;
}
#endif
BLOCKTYPE cChunkData::GetBlock(int a_X, int a_Y, int a_Z) const
{
ASSERT((a_X >= 0) && (a_X < cChunkDef::Width));
ASSERT((a_Y >= 0) && (a_Y < cChunkDef::Height));
ASSERT((a_Z >= 0) && (a_Z < cChunkDef::Width));
int Section = a_Y / CHUNK_SECTION_HEIGHT;
if (m_Sections[Section] != NULL)
{
int Index = cChunkDef::MakeIndexNoCheck(a_X, a_Y - (Section * CHUNK_SECTION_HEIGHT), a_Z);
return m_Sections[Section]->m_BlockTypes[Index];
}
else
{
return 0;
}
}
void cChunkData::SetBlock(int a_RelX, int a_RelY, int a_RelZ, BLOCKTYPE a_Block)
{
if (
(a_RelX >= cChunkDef::Width) || (a_RelX < 0) ||
(a_RelY >= cChunkDef::Height) || (a_RelY < 0) ||
(a_RelZ >= cChunkDef::Width) || (a_RelZ < 0)
)
{
ASSERT(!"cChunkData::SetMeta(): index out of range!");
return;
}
int Section = a_RelY / CHUNK_SECTION_HEIGHT;
if (m_Sections[Section] == NULL)
{
if (a_Block == 0x00)
{
return;
}
m_Sections[Section] = Allocate();
if (m_Sections[Section] == NULL)
{
ASSERT(!"Failed to allocate a new section in Chunkbuffer");
return;
}
ZeroSection(m_Sections[Section]);
}
int Index = cChunkDef::MakeIndexNoCheck(a_RelX, a_RelY - (Section * CHUNK_SECTION_HEIGHT), a_RelZ);
m_Sections[Section]->m_BlockTypes[Index] = a_Block;
}
NIBBLETYPE cChunkData::GetMeta(int a_RelX, int a_RelY, int a_RelZ) const
{
if (
(a_RelX < cChunkDef::Width) && (a_RelX > -1) &&
(a_RelY < cChunkDef::Height) && (a_RelY > -1) &&
(a_RelZ < cChunkDef::Width) && (a_RelZ > -1))
{
int Section = a_RelY / CHUNK_SECTION_HEIGHT;
if (m_Sections[Section] != NULL)
{
int Index = cChunkDef::MakeIndexNoCheck(a_RelX, a_RelY - (Section * CHUNK_SECTION_HEIGHT), a_RelZ);
return (m_Sections[Section]->m_BlockMeta[Index / 2] >> ((Index & 1) * 4)) & 0x0f;
}
else
{
return 0;
}
}
ASSERT(!"cChunkData::GetMeta(): coords out of chunk range!");
return 0;
}
bool cChunkData::SetMeta(int a_RelX, int a_RelY, int a_RelZ, NIBBLETYPE a_Nibble)
{
if (
(a_RelX >= cChunkDef::Width) || (a_RelX < 0) ||
(a_RelY >= cChunkDef::Height) || (a_RelY < 0) ||
(a_RelZ >= cChunkDef::Width) || (a_RelZ < 0)
)
{
ASSERT(!"cChunkData::SetMeta(): index out of range!");
return false;
}
int Section = a_RelY / CHUNK_SECTION_HEIGHT;
if (m_Sections[Section] == NULL)
{
if ((a_Nibble & 0xf) == 0x00)
{
return false;
}
m_Sections[Section] = Allocate();
if (m_Sections[Section] == NULL)
{
ASSERT(!"Failed to allocate a new section in Chunkbuffer");
return false;
}
ZeroSection(m_Sections[Section]);
}
int Index = cChunkDef::MakeIndexNoCheck(a_RelX, a_RelY - (Section * CHUNK_SECTION_HEIGHT), a_RelZ);
NIBBLETYPE oldval = m_Sections[Section]->m_BlockMeta[Index / 2] >> ((Index & 1) * 4) & 0xf;
m_Sections[Section]->m_BlockMeta[Index / 2] = static_cast<NIBBLETYPE>(
(m_Sections[Section]->m_BlockMeta[Index / 2] & (0xf0 >> ((Index & 1) * 4))) | // The untouched nibble
((a_Nibble & 0x0f) << ((Index & 1) * 4)) // The nibble being set
);
return oldval == a_Nibble;
}
NIBBLETYPE cChunkData::GetBlockLight(int a_RelX, int a_RelY, int a_RelZ) const
{
if ((a_RelX < cChunkDef::Width) && (a_RelX > -1) && (a_RelY < cChunkDef::Height) && (a_RelY > -1) && (a_RelZ < cChunkDef::Width) && (a_RelZ > -1))
{
int Section = a_RelY / CHUNK_SECTION_HEIGHT;
if (m_Sections[Section] != NULL)
{
int Index = cChunkDef::MakeIndexNoCheck(a_RelX, a_RelY - (Section * CHUNK_SECTION_HEIGHT), a_RelZ);
return (m_Sections[Section]->m_BlockLight[Index / 2] >> ((Index & 1) * 4)) & 0x0f;
}
else
{
return 0;
}
}
ASSERT(!"cChunkData::GetMeta(): coords out of chunk range!");
return 0;
}
NIBBLETYPE cChunkData::GetSkyLight(int a_RelX, int a_RelY, int a_RelZ) const
{
if ((a_RelX < cChunkDef::Width) && (a_RelX > -1) && (a_RelY < cChunkDef::Height) && (a_RelY > -1) && (a_RelZ < cChunkDef::Width) && (a_RelZ > -1))
{
int Section = a_RelY / CHUNK_SECTION_HEIGHT;
if (m_Sections[Section] != NULL)
{
int Index = cChunkDef::MakeIndexNoCheck(a_RelX, a_RelY - (Section * CHUNK_SECTION_HEIGHT), a_RelZ);
return (m_Sections[Section]->m_BlockLight[Index / 2] >> ((Index & 1) * 4)) & 0x0f;
}
else
{
return 0xF;
}
}
ASSERT(!"cChunkData::GetMeta(): coords out of chunk range!");
return 0;
}
cChunkData cChunkData::Copy() const
{
cChunkData copy(m_Pool);
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
if (m_Sections[i] != NULL)
{
copy.m_Sections[i] = Allocate();
*copy.m_Sections[i] = *m_Sections[i];
}
}
return copy;
}
void cChunkData::CopyBlocks (BLOCKTYPE * a_dest, size_t a_Idx, size_t length) const
{
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
const size_t segment_length = CHUNK_SECTION_HEIGHT * 16 * 16;
if (a_Idx > 0)
{
a_Idx = std::max(a_Idx - length, (size_t) 0);
}
if (a_Idx == 0)
{
size_t tocopy = std::min(segment_length, length);
length -= tocopy;
if (m_Sections[i] != NULL)
{
memcpy(
&a_dest[i * segment_length],
&m_Sections[i]->m_BlockTypes,
sizeof(BLOCKTYPE) * tocopy
);
}
else
{
memset(
&a_dest[i * segment_length],
0,
sizeof(BLOCKTYPE) * tocopy
);
}
}
}
}
void cChunkData::CopyMeta(NIBBLETYPE * a_dest) const
{
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
const size_t segment_length = CHUNK_SECTION_HEIGHT * 16 * 16 / 2;
if (m_Sections[i] != NULL)
{
memcpy(
&a_dest[i * segment_length],
&m_Sections[i]->m_BlockMeta,
sizeof(NIBBLETYPE) * segment_length
);
}
else
{
memset(
&a_dest[i * segment_length],
0,
sizeof(BLOCKTYPE) * segment_length
);
}
}
}
void cChunkData::CopyBlockLight(NIBBLETYPE * a_dest) const
{
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
const size_t segment_length = CHUNK_SECTION_HEIGHT * 16 * 16 / 2;
if (m_Sections[i] != NULL)
{
memcpy(
&a_dest[i * segment_length],
&m_Sections[i]->m_BlockLight,
sizeof(NIBBLETYPE) * segment_length
);
}
else
{
memset(
&a_dest[i * segment_length],
0,
sizeof(BLOCKTYPE) * segment_length
);
}
}
}
void cChunkData::CopySkyLight(NIBBLETYPE * a_dest) const
{
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
const size_t segment_length = CHUNK_SECTION_HEIGHT * 16 * 16 / 2;
if (m_Sections[i] != NULL)
{
memcpy(
&a_dest[i * segment_length],
&m_Sections[i]->m_BlockSkyLight,
sizeof(NIBBLETYPE) * segment_length
);
}
else
{
memset(
&a_dest[i * segment_length],
0xFF,
sizeof(BLOCKTYPE) * segment_length
);
}
}
}
void cChunkData::SetBlocks(const BLOCKTYPE * a_src)
{
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
const size_t segment_length = CHUNK_SECTION_HEIGHT * 16 * 16;
if (m_Sections[i] != NULL)
{
memcpy(
&m_Sections[i]->m_BlockTypes,
&a_src[i * segment_length],
sizeof(BLOCKTYPE) * segment_length
);
}
else
{
// j counts how many of leading zeros the buffer has
// if j == segment_length then the buffer is all zeros so there is no point
// creating the buffer.
size_t j = 0;
// do nothing whilst 0
for (; j < segment_length && a_src[i * segment_length + j] == 0; j++);
if (j != segment_length)
{
m_Sections[i] = Allocate();
memcpy(
&m_Sections[i]->m_BlockTypes,
&a_src[i * segment_length],
sizeof(BLOCKTYPE) * segment_length
);
memset(
m_Sections[i]->m_BlockMeta,
0x00,
sizeof(m_Sections[i]->m_BlockMeta)
);
memset(
m_Sections[i]->m_BlockLight,
0x00,
sizeof(m_Sections[i]->m_BlockLight)
);
memset(
m_Sections[i]->m_BlockSkyLight,
0xFF,
sizeof(m_Sections[i]->m_BlockSkyLight)
);
}
}
}
}
void cChunkData::SetMeta(const NIBBLETYPE * a_src)
{
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
const size_t segment_length = CHUNK_SECTION_HEIGHT * 16 * 16 / 2;
if (m_Sections[i] != NULL)
{
memcpy(
&m_Sections[i]->m_BlockMeta,
&a_src[i * segment_length],
sizeof(NIBBLETYPE) * segment_length
);
}
else
{
size_t j = 0;
// do nothing whilst 0
for (; j < segment_length && a_src[i * segment_length + j] == 0; j++);
if (j != segment_length)
{
m_Sections[i] = Allocate();
memcpy(
&m_Sections[i]->m_BlockMeta,
&a_src[i * segment_length],
sizeof(BLOCKTYPE) * segment_length
);
memset(
m_Sections[i]->m_BlockTypes,
0x00,
sizeof(m_Sections[i]->m_BlockTypes)
);
memset(
m_Sections[i]->m_BlockLight,
0x00,
sizeof(m_Sections[i]->m_BlockLight)
);
memset(
m_Sections[i]->m_BlockSkyLight,
0xFF,
sizeof(m_Sections[i]->m_BlockSkyLight)
);
}
else
{
Free(m_Sections[i]);
m_Sections[i] = 0;
}
}
}
}
void cChunkData::SetBlockLight(const NIBBLETYPE * a_src)
{
if (!a_src) return;
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
const size_t segment_length = CHUNK_SECTION_HEIGHT * 16 * 16 / 2;
if (m_Sections[i] != NULL)
{
memcpy(
&m_Sections[i]->m_BlockLight,
&a_src[i * segment_length],
sizeof(NIBBLETYPE) * segment_length
);
}
else
{
size_t j = 0;
// do nothing whilst 0
for (; j < segment_length && a_src[i * segment_length + j] == 0; j++);
if (j != segment_length)
{
m_Sections[i] = Allocate();
memcpy(
&m_Sections[i]->m_BlockLight,
&a_src[i * segment_length],
sizeof(BLOCKTYPE) * segment_length
);
memset(
m_Sections[i]->m_BlockTypes,
0x00,
sizeof(m_Sections[i]->m_BlockTypes)
);
memset(
m_Sections[i]->m_BlockMeta,
0x00,
sizeof(m_Sections[i]->m_BlockMeta)
);
memset(
m_Sections[i]->m_BlockSkyLight,
0xFF,
sizeof(m_Sections[i]->m_BlockSkyLight)
);
}
else
{
Free(m_Sections[i]);
m_Sections[i] = 0;
}
}
}
}
void cChunkData::SetSkyLight (const NIBBLETYPE * a_src)
{
if (!a_src) return;
for (size_t i = 0; i < CHUNK_SECTION_COUNT; i++)
{
const size_t segment_length = CHUNK_SECTION_HEIGHT * 16 * 16 / 2;
if (m_Sections[i] != NULL)
{
memcpy(
&m_Sections[i]->m_BlockSkyLight,
&a_src[i * segment_length],
sizeof(NIBBLETYPE) * segment_length
);
}
else
{
size_t j = 0;
// do nothing whilst 0
for (; j < segment_length && a_src[i * segment_length + j] == 0xFF; j++);
if (j != segment_length)
{
m_Sections[i] = Allocate();
memcpy(
&m_Sections[i]->m_BlockSkyLight,
&a_src[i * segment_length],
sizeof(BLOCKTYPE) * segment_length
);
memset(
m_Sections[i]->m_BlockTypes,
0x00,
sizeof(m_Sections[i]->m_BlockTypes)
);
memset(
m_Sections[i]->m_BlockMeta,
0x00,
sizeof(m_Sections[i]->m_BlockMeta)
);
memset(
m_Sections[i]->m_BlockLight,
0x00,
sizeof(m_Sections[i]->m_BlockLight)
);
}
}
}
}
cChunkData::sChunkSection * cChunkData::Allocate() const
{
// TODO: use a allocation pool
return m_Pool.Allocate();
}
void cChunkData::Free(cChunkData::sChunkSection * ptr) const
{
m_Pool.Free(ptr);
}
void cChunkData::ZeroSection(cChunkData::sChunkSection * ptr) const
{
memset(
ptr->m_BlockTypes,
0x00,
sizeof(ptr->m_BlockTypes)
);
memset(
ptr->m_BlockMeta,
0x00,
sizeof(ptr->m_BlockMeta)
);
memset(
ptr->m_BlockLight,
0x00,
sizeof(ptr->m_BlockLight)
);
memset(
ptr->m_BlockSkyLight,
0xFF,
sizeof(ptr->m_BlockSkyLight)
);
}