// FastNBT.cpp
// Implements the fast NBT parser and writer
#include "Globals.h"
#include "FastNBT.h"
#define RETURN_FALSE_IF_FALSE(X) do { if (!X) return false; } while (0)
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// cFastNBTParser:
#define NEEDBYTES(N) \
if (m_Length - m_Pos < N) \
{ \
return false; \
}
cParsedNBT::cParsedNBT(const char * a_Data, int a_Length) :
m_Data(a_Data),
m_Length(a_Length),
m_Pos(0)
{
m_IsValid = Parse();
}
bool cParsedNBT::Parse(void)
{
if (m_Length < 3)
{
// Data too short
return false;
}
if (m_Data[0] != TAG_Compound)
{
// The top-level tag must be a Compound
return false;
}
m_Tags.reserve(200);
m_Tags.push_back(cFastNBTTag(TAG_Compound, -1));
m_Pos = 1;
RETURN_FALSE_IF_FALSE(ReadString(m_Tags.back().m_NameStart, m_Tags.back().m_NameLength));
RETURN_FALSE_IF_FALSE(ReadCompound());
return true;
}
bool cParsedNBT::ReadString(int & a_StringStart, int & a_StringLen)
{
NEEDBYTES(2);
a_StringStart = m_Pos + 2;
a_StringLen = ntohs(*((short *)(m_Data + m_Pos)));
if (a_StringLen < 0)
{
// Invalid string length
return false;
}
m_Pos += 2 + a_StringLen;
return true;
}
bool cParsedNBT::ReadCompound(void)
{
// Reads the latest tag as a compound
int ParentIdx = m_Tags.size() - 1;
int PrevSibling = -1;
while (true)
{
NEEDBYTES(1);
eTagType TagType = (eTagType)(m_Data[m_Pos]);
m_Pos++;
if (TagType == TAG_End)
{
break;
}
m_Tags.push_back(cFastNBTTag(TagType, ParentIdx, PrevSibling));
if (PrevSibling >= 0)
{
m_Tags[PrevSibling].m_NextSibling = m_Tags.size() - 1;
}
else
{
m_Tags[ParentIdx].m_FirstChild = m_Tags.size() - 1;
}
PrevSibling = m_Tags.size() - 1;
RETURN_FALSE_IF_FALSE(ReadString(m_Tags.back().m_NameStart, m_Tags.back().m_NameLength));
RETURN_FALSE_IF_FALSE(ReadTag());
} // while (true)
m_Tags[ParentIdx].m_LastChild = PrevSibling;
return true;
}
bool cParsedNBT::ReadList(eTagType a_ChildrenType)
{
// Reads the latest tag as a list of items of type a_ChildrenType
// Read the count:
NEEDBYTES(4);
int Count = ntohl(*((int *)(m_Data + m_Pos)));
m_Pos += 4;
if (Count < 0)
{
return false;
}
// Read items:
int ParentIdx = m_Tags.size() - 1;
int PrevSibling = -1;
for (int i = 0; i < Count; i++)
{
m_Tags.push_back(cFastNBTTag(a_ChildrenType, ParentIdx, PrevSibling));
if (PrevSibling >= 0)
{
m_Tags[PrevSibling].m_NextSibling = m_Tags.size() - 1;
}
else
{
m_Tags[ParentIdx].m_FirstChild = m_Tags.size() - 1;
}
PrevSibling = m_Tags.size() - 1;
RETURN_FALSE_IF_FALSE(ReadTag());
} // for (i)
m_Tags[ParentIdx].m_LastChild = PrevSibling;
return true;
}
#define CASE_SIMPLE_TAG(TAGTYPE, LEN) \
case TAG_##TAGTYPE: \
{ \
NEEDBYTES(LEN); \
Tag.m_DataStart = m_Pos; \
Tag.m_DataLength = LEN; \
m_Pos += LEN; \
return true; \
}
bool cParsedNBT::ReadTag(void)
{
cFastNBTTag & Tag = m_Tags.back();
switch (Tag.m_Type)
{
CASE_SIMPLE_TAG(Byte, 1)
CASE_SIMPLE_TAG(Short, 2)
CASE_SIMPLE_TAG(Int, 4)
CASE_SIMPLE_TAG(Long, 8)
CASE_SIMPLE_TAG(Float, 4)
CASE_SIMPLE_TAG(Double, 8)
case TAG_String:
{
return ReadString(Tag.m_DataStart, Tag.m_DataLength);
}
case TAG_ByteArray:
{
NEEDBYTES(4);
int len = ntohl(*((int *)(m_Data + m_Pos)));
m_Pos += 4;
if (len < 0)
{
// Invalid length
return false;
}
NEEDBYTES(len);
Tag.m_DataLength = len;
Tag.m_DataStart = m_Pos;
m_Pos += len;
return true;
}
case TAG_List:
{
NEEDBYTES(1);
eTagType ItemType = (eTagType)m_Data[m_Pos];
m_Pos++;
RETURN_FALSE_IF_FALSE(ReadList(ItemType));
return true;
}
case TAG_Compound:
{
RETURN_FALSE_IF_FALSE(ReadCompound());
return true;
}
case TAG_IntArray:
{
NEEDBYTES(4);
int len = ntohl(*((int *)(m_Data + m_Pos)));
m_Pos += 4;
if (len < 0)
{
// Invalid length
return false;
}
len *= 4;
NEEDBYTES(len);
Tag.m_DataLength = len;
Tag.m_DataStart = m_Pos;
m_Pos += len;
return true;
}
default:
{
ASSERT(!"Unhandled NBT tag type");
return false;
}
} // switch (iType)
}
#undef CASE_SIMPLE_TAG
int cParsedNBT::FindChildByName(int a_Tag, const char * a_Name, size_t a_NameLength) const
{
if (a_Tag < 0)
{
return -1;
}
if (m_Tags[a_Tag].m_Type != TAG_Compound)
{
return -1;
}
if (a_NameLength == 0)
{
a_NameLength = strlen(a_Name);
}
for (int Child = m_Tags[a_Tag].m_FirstChild; Child != -1; Child = m_Tags[Child].m_NextSibling)
{
if (
(m_Tags[Child].m_NameLength == a_NameLength) &&
(memcmp(m_Data + m_Tags[Child].m_NameStart, a_Name, a_NameLength) == 0)
)
{
return Child;
}
} // for Child - children of a_Tag
return -1;
}
int cParsedNBT::FindTagByPath(int a_Tag, const AString & a_Path) const
{
if (a_Tag < 0)
{
return -1;
}
size_t Begin = 0;
size_t Length = a_Path.length();
int Tag = a_Tag;
for (size_t i = 0; i < Length; i++)
{
if (a_Path[i] != '\\')
{
continue;
}
Tag = FindChildByName(Tag, a_Path.c_str() + Begin, i - Begin - 1);
if (Tag < 0)
{
return -1;
}
Begin = i + 1;
} // for i - a_Path[]
if (Begin < Length)
{
Tag = FindChildByName(Tag, a_Path.c_str() + Begin, Length - Begin);
}
return Tag;
}