int init_munin()
{
printf("Munin script-accessible storage module.\n");
REG_CLASS(L, rw);
return 1;
}
void register_brush_class(lua_State* L)
{
using Brush = BrushObj;
REG_CLASS(L, Brush);
REG_CLASS_NEW(L, Brush);
REG_CLASS_PROPERTIES(L, Brush);
}
void register_color_space_class(lua_State* L)
{
using ColorSpace = gfx::ColorSpace;
REG_CLASS(L, ColorSpace);
REG_CLASS_NEW(L, ColorSpace);
REG_CLASS_PROPERTIES(L, ColorSpace);
}
int init_gaia(void)
{
struct SDL_Surface *Z;
struct SDL_RWops *F;
Sint32 w;
int i, x=0;
if( (F = SDL_RWFromFile("data/hblk01.dat","r")) == NULL)
abend(0);
for(i=0; i < 256*6; i++) {
w = SDL_ReadLE32(F);
w = (w < 6144)? 0: (w - 6144) / 320;
subtile_table[i] = w;
x = (w > x)? w : x;
}
printf("Gaia tile module:\n + %d unique subtiles.\n", x);
x++;
if(!(Z = CreateZSurface(get_pal("data/hpal01.dat"), 32,16*x)) )
SDL_RWclose(F), abend(0);
load_subtiles(F, Z->pixels, x);
if(1) subtiles = Z;
else {
if( (subtiles = SDL_CreateRGBSurface(SDL_HWSURFACE,
32,16*x,32,
RR,GG,BB,AA)) )
SDL_BlitSurface(Z, NULL, subtiles, NULL);
SDL_FreeSurface(Z);
}
SDL_RWclose(F);
lua_pushnumber(L, SCALE); lua_setfield(L, LUA_GLOBALSINDEX, "scale");
lua_register(L, "s2m", s2m);
lua_register(L, "m2s", m2s);
REG_CLASS(L, map);
return subtiles != NULL;
}
COREARRAY_DLL_DEFAULT void RegisterClass()
{
if (CoreArray_ifRegClass) return;
#define REG_CLASS(T, CLASS, CType, Desp) \
dObjManager().AddClass(TdTraits< T >::StreamName(), \
OnObjCreate< CLASS >, CdObjClassMgr::CType, Desp)
#define REG_CLASS_EX(Name, CLASS, CType, Desp) \
dObjManager().AddClass(Name, OnObjCreate< CLASS >, \
CdObjClassMgr::CType, Desp)
// signed integer
#ifndef COREARRAY_NO_BIT_GDSCLASS
REG_CLASS(SBIT2, CdSBit2, ctArray, "signed integer of 2 bits");
REG_CLASS(SBIT3, CdSBit3, ctArray, "signed integer of 3 bits");
REG_CLASS(SBIT4, CdSBit4, ctArray, "signed integer of 4 bits");
REG_CLASS(SBIT5, CdSBit5, ctArray, "signed integer of 5 bits");
REG_CLASS(SBIT6, CdSBit6, ctArray, "signed integer of 6 bits");
REG_CLASS(SBIT7, CdSBit7, ctArray, "signed integer of 7 bits");
#endif
REG_CLASS(C_Int8, CdInt8, ctArray, "signed integer of 8 bits");
REG_CLASS_EX("dSBit8", CdSBit8, ctArray, "signed integer of 8 bits");
#ifndef COREARRAY_NO_BIT_GDSCLASS
REG_CLASS(SBIT9, CdSBit9, ctArray, "signed integer of 9 bits");
REG_CLASS(SBIT10, CdSBit10, ctArray, "signed integer of 10 bits");
REG_CLASS(SBIT11, CdSBit11, ctArray, "signed integer of 11 bits");
REG_CLASS(SBIT12, CdSBit12, ctArray, "signed integer of 12 bits");
REG_CLASS(SBIT13, CdSBit13, ctArray, "signed integer of 13 bits");
REG_CLASS(SBIT14, CdSBit14, ctArray, "signed integer of 14 bits");
REG_CLASS(SBIT15, CdSBit15, ctArray, "signed integer of 15 bits");
#endif
REG_CLASS(C_Int16, CdInt16, ctArray, "signed integer of 16 bits");
REG_CLASS_EX("dSBit16", CdSBit16, ctArray, "signed integer of 16 bits");
#ifndef COREARRAY_NO_BIT_GDSCLASS
REG_CLASS(SBIT17, CdSBit17, ctArray, "signed integer of 17 bits");
REG_CLASS(SBIT18, CdSBit18, ctArray, "signed integer of 18 bits");
REG_CLASS(SBIT19, CdSBit19, ctArray, "signed integer of 19 bits");
REG_CLASS(SBIT20, CdSBit20, ctArray, "signed integer of 20 bits");
REG_CLASS(SBIT21, CdSBit21, ctArray, "signed integer of 21 bits");
REG_CLASS(SBIT22, CdSBit22, ctArray, "signed integer of 22 bits");
REG_CLASS(SBIT23, CdSBit23, ctArray, "signed integer of 23 bits");
#endif
REG_CLASS(SBIT24, CdSBit24, ctArray, "signed integer of 24 bits");
REG_CLASS_EX("dSBit24", CdSBit24, ctArray, "signed integer of 24 bits");
#ifndef COREARRAY_NO_BIT_GDSCLASS
REG_CLASS(SBIT25, CdSBit25, ctArray, "signed integer of 25 bits");
REG_CLASS(SBIT26, CdSBit26, ctArray, "signed integer of 26 bits");
REG_CLASS(SBIT27, CdSBit27, ctArray, "signed integer of 27 bits");
REG_CLASS(SBIT28, CdSBit28, ctArray, "signed integer of 28 bits");
REG_CLASS(SBIT29, CdSBit29, ctArray, "signed integer of 29 bits");
REG_CLASS(SBIT30, CdSBit30, ctArray, "signed integer of 30 bits");
REG_CLASS(SBIT31, CdSBit31, ctArray, "signed integer of 31 bits");
#endif
REG_CLASS(C_Int32, CdInt32, ctArray, "signed integer of 32 bits");
REG_CLASS_EX("dSBit32", CdSBit32, ctArray, "signed integer of 32 bits");
REG_CLASS(C_Int64, CdInt64, ctArray, "signed integer of 64 bits");
REG_CLASS_EX("dSBit64", CdInt64, ctArray, "signed integer of 64 bits");
// unsigned integer
#ifndef COREARRAY_NO_BIT_GDSCLASS
REG_CLASS(BIT1, CdBit1, ctArray, "unsigned integer of 1 bit");
REG_CLASS(BIT2, CdBit2, ctArray, "unsigned integer of 2 bits");
REG_CLASS(BIT3, CdBit3, ctArray, "unsigned integer of 3 bits");
REG_CLASS(BIT4, CdBit4, ctArray, "unsigned integer of 4 bits");
REG_CLASS(BIT5, CdBit5, ctArray, "unsigned integer of 5 bits");
REG_CLASS(BIT6, CdBit6, ctArray, "unsigned integer of 6 bits");
REG_CLASS(BIT7, CdBit7, ctArray, "unsigned integer of 7 bits");
#endif
REG_CLASS(C_UInt8, CdUInt8, ctArray, "unsigned integer of 8 bits");
REG_CLASS_EX("dBit8", CdBit8, ctArray, "unsigned integer of 8 bits");
#ifndef COREARRAY_NO_BIT_GDSCLASS
REG_CLASS(BIT9, CdBit9, ctArray, "unsigned integer of 9 bits");
REG_CLASS(BIT10, CdBit10, ctArray, "unsigned integer of 10 bits");
REG_CLASS(BIT11, CdBit11, ctArray, "unsigned integer of 11 bits");
REG_CLASS(BIT12, CdBit12, ctArray, "unsigned integer of 12 bits");
REG_CLASS(BIT13, CdBit13, ctArray, "unsigned integer of 13 bits");
REG_CLASS(BIT14, CdBit14, ctArray, "unsigned integer of 14 bits");
REG_CLASS(BIT15, CdBit15, ctArray, "unsigned integer of 15 bits");
#endif
REG_CLASS(C_UInt16, CdUInt16, ctArray, "unsigned integer of 16 bits");
REG_CLASS_EX("dBit16", CdBit16, ctArray, "unsigned integer of 16 bits");
#ifndef COREARRAY_NO_BIT_GDSCLASS
REG_CLASS(BIT17, CdBit17, ctArray, "unsigned integer of 17 bits");
REG_CLASS(BIT18, CdBit18, ctArray, "unsigned integer of 18 bits");
REG_CLASS(BIT19, CdBit19, ctArray, "unsigned integer of 19 bits");
REG_CLASS(BIT20, CdBit20, ctArray, "unsigned integer of 20 bits");
REG_CLASS(BIT21, CdBit21, ctArray, "unsigned integer of 21 bits");
REG_CLASS(BIT22, CdBit22, ctArray, "unsigned integer of 22 bits");
REG_CLASS(BIT23, CdBit23, ctArray, "unsigned integer of 23 bits");
#endif
REG_CLASS(BIT24, CdBit24, ctArray, "unsigned integer of 24 bits");
REG_CLASS_EX("dBit24", CdBit24, ctArray, "unsigned integer of 24 bits");
#ifndef COREARRAY_NO_BIT_GDSCLASS
REG_CLASS(BIT25, CdBit25, ctArray, "unsigned integer of 25 bits");
REG_CLASS(BIT26, CdBit26, ctArray, "unsigned integer of 26 bits");
REG_CLASS(BIT27, CdBit27, ctArray, "unsigned integer of 27 bits");
REG_CLASS(BIT28, CdBit28, ctArray, "unsigned integer of 28 bits");
REG_CLASS(BIT29, CdBit29, ctArray, "unsigned integer of 29 bits");
REG_CLASS(BIT30, CdBit30, ctArray, "unsigned integer of 30 bits");
REG_CLASS(BIT31, CdBit31, ctArray, "unsigned integer of 31 bits");
#endif
REG_CLASS(C_UInt32, CdUInt32, ctArray, "unsigned integer of 32 bits");
REG_CLASS_EX("dBit32", CdBit32, ctArray, "unsigned integer of 32 bits");
REG_CLASS(C_UInt64, CdUInt64, ctArray, "unsigned integer of 64 bits");
REG_CLASS_EX("dBit64", CdUInt64, ctArray, "unsigned integer of 64 bits");
// real number
REG_CLASS(C_Float32, CdFloat32, ctArray, "floating-point number (32 bits)");
REG_CLASS(C_Float64, CdFloat64, ctArray, "floating-point number (64 bits)");
REG_CLASS(TREAL8, CdPackedReal8, ctArray, "packed real number ( 8 bits)");
REG_CLASS(TREAL16, CdPackedReal16, ctArray, "packed real number (16 bits)");
REG_CLASS(TREAL32, CdPackedReal32, ctArray, "packed real number (32 bits)");
// fixed-length string
REG_CLASS(FIXED_LENGTH<C_UTF8>, CdFStr8, ctArray, "fixed-length UTF-8 string");
REG_CLASS(FIXED_LENGTH<C_UTF16>, CdFStr16, ctArray, "fixed-length UTF-16 string");
REG_CLASS(FIXED_LENGTH<C_UTF32>, CdFStr32, ctArray, "fixed-length UTF-32 string");
// variable-length string
REG_CLASS(VARIABLE_LENGTH<C_UTF8>, CdVStr8, ctArray, "variable-length UTF-8 string");
REG_CLASS(VARIABLE_LENGTH<C_UTF16>, CdVStr16, ctArray, "variable-length UTF-16 string");
REG_CLASS(VARIABLE_LENGTH<C_UTF32>, CdVStr32, ctArray, "variable-length UTF-32 string");
// stream container
dObjManager().AddClass("dStream", OnObjCreate<CdGDSStreamContainer>,
CdObjClassMgr::ctStream, "stream container");
CoreArray_ifRegClass = true;
#undef REG_CLASS
#undef REG_CLASS_EX
}
