void CCOLEntry::parseCollisionMeshVertices(void)
{
CDataReader *pDataReader = CDataReader::getInstance();
eCOLVersion eCOLVersionValue = getCOLVersion() == nullptr ? COL_UNKNOWN : getCOLVersion()->getVersionId();
vector<TVertex>& vecVertices = getCollisionMeshVertices();
for (uint32 i = 0, j = getCollisionMeshVertexCount(); i < j; i++)
{
char szText1[500];
TVertex vertex;
if (eCOLVersionValue == COL_1)
{
vertex.m_x = pDataReader->readFloat32();
vertex.m_y = pDataReader->readFloat32();
vertex.m_z = pDataReader->readFloat32();
}
else
{
vertex.m_x = ((float32) pDataReader->readInt16()) / 128.0f;
vertex.m_y = ((float32) pDataReader->readInt16()) / 128.0f;
vertex.m_z = ((float32) pDataReader->readInt16()) / 128.0f;
}
vecVertices.push_back(vertex);
}
}
void CCOLEntry::parseShadowMeshVertices(void)
{
CDataReader *pDataReader = CDataReader::getInstance();
vector<TVertex>& vecVertices = getShadowMeshVertices();
for (uint32 i = 0, j = getShadowMeshVertexCount(); i < j; i++)
{
TVertex vertex;
vertex.m_x = ((float32) pDataReader->readInt16()) / 128.0f;
vertex.m_y = ((float32) pDataReader->readInt16()) / 128.0f;
vertex.m_z = ((float32) pDataReader->readInt16()) / 128.0f;
vecVertices.push_back(vertex);
}
}
