/* ** $Id: ltable.h $ ** Lua tables (hash) ** See Copyright Notice in lua.h */ #ifndef ltable_h #define ltable_h #include "lobject.h" #define gnode(t,i) (&(t)->node[i]) #define gval(n) (&(n)->i_val) #define gnext(n) ((n)->u.next) /* ** Clear all bits of fast-access metamethods, which means that the table ** may have any of these metamethods. (First access that fails after the ** clearing will set the bit again.) */ #define invalidateTMcache(t) ((t)->flags &= ~maskflags) /* ** Bit BITDUMMY set in 'flags' means the table is using the dummy node ** for its hash part. */ #define BITDUMMY (1 << 6) #define NOTBITDUMMY cast_byte(~BITDUMMY) #define isdummy(t) ((t)->flags & BITDUMMY) #define setnodummy(t) ((t)->flags &= NOTBITDUMMY) #define setdummy(t) ((t)->flags |= BITDUMMY) /* allocated size for hash nodes */ #define allocsizenode(t) (isdummy(t) ? 0 : sizenode(t)) /* returns the Node, given the value of a table entry */ #define nodefromval(v) cast(Node *, (v)) #define luaH_fastgeti(t,k,res,tag) \ { Table *h = t; lua_Unsigned u = l_castS2U(k) - 1u; \ if ((u < h->alimit)) { \ tag = *getArrTag(h, u); \ if (!tagisempty(tag)) { farr2val(h, u, tag, res); }} \ else { tag = luaH_getint(h, (k), res); }} #define luaH_fastseti(t,k,val,hres) \ { Table *h = t; lua_Unsigned u = l_castS2U(k) - 1u; \ if ((u < h->alimit)) { \ lu_byte *tag = getArrTag(h, u); \ if (tagisempty(*tag)) hres = ~cast_int(u); \ else { fval2arr(h, u, tag, val); hres = HOK; }} \ else { hres = luaH_psetint(h, k, val); }} /* results from pset */ #define HOK 0 #define HNOTFOUND 1 #define HNOTATABLE 2 #define HFIRSTNODE 3 /* ** 'luaH_get*' operations set 'res', unless the value is absent, and ** return the tag of the result. ** The 'luaH_pset*' (pre-set) operations set the given value and return ** HOK, unless the original value is absent. In that case, if the key ** is really absent, they return HNOTFOUND. Otherwise, if there is a ** slot with that key but with no value, 'luaH_pset*' return an encoding ** of where the key is (usually called 'hres'). (pset cannot set that ** value because there might be a metamethod.) If the slot is in the ** hash part, the encoding is (HFIRSTNODE + hash index); if the slot is ** in the array part, the encoding is (~array index), a negative value. ** The value HNOTATABLE is used by the fast macros to signal that the ** value being indexed is not a table. ** (The size for the array part is limited by the maximum power of two ** that fits in an unsigned integer; that is INT_MAX+1. So, the C-index ** ranges from 0, which encodes to -1, to INT_MAX, which encodes to ** INT_MIN. The size of the hash part is limited by the maximum power of ** two that fits in a signed integer; that is (INT_MAX+1)/2. So, it is ** safe to add HFIRSTNODE to any index there.) */ /* ** The array part of a table is represented by an inverted array of ** values followed by an array of tags, to avoid wasting space with ** padding. The 'array' pointer points to the junction of the two ** arrays, so that values are indexed with negative indices and tags ** with non-negative indices. Values Tags -------------------------------------------------------- ... | Value 1 | Value 0 |0|1|... -------------------------------------------------------- ^ t->array ** All accesses to 't->array' should be through the macros 'getArrTag' ** and 'getArrVal'. */ /* Computes the address of the tag for the abstract C-index 'k' */ #define getArrTag(t,k) (cast(lu_byte*, (t)->array) + (k)) /* Computes the address of the value for the abstract C-index 'k' */ #define getArrVal(t,k) ((t)->array - 1 - (k)) /* ** Move TValues to/from arrays, using C indices */ #define arr2obj(h,k,val) \ ((val)->tt_ = *getArrTag(h,(k)), (val)->value_ = *getArrVal(h,(k))) #define obj2arr(h,k,val) \ (*getArrTag(h,(k)) = (val)->tt_, *getArrVal(h,(k)) = (val)->value_) /* ** Often, we need to check the tag of a value before moving it. The ** following macros also move TValues to/from arrays, but receive the ** precomputed tag value or address as an extra argument. */ #define farr2val(h,k,tag,res) \ ((res)->tt_ = tag, (res)->value_ = *getArrVal(h,(k))) #define fval2arr(h,k,tag,val) \ (*tag = (val)->tt_, *getArrVal(h,(k)) = (val)->value_) LUAI_FUNC int luaH_get (Table *t, const TValue *key, TValue *res); LUAI_FUNC int luaH_getshortstr (Table *t, TString *key, TValue *res); LUAI_FUNC int luaH_getstr (Table *t, TString *key, TValue *res); LUAI_FUNC int luaH_getint (Table *t, lua_Integer key, TValue *res); /* Special get for metamethods */ LUAI_FUNC const TValue *luaH_Hgetshortstr (Table *t, TString *key); LUAI_FUNC TString *luaH_getstrkey (Table *t, TString *key); LUAI_FUNC int luaH_psetint (Table *t, lua_Integer key, TValue *val); LUAI_FUNC int luaH_psetshortstr (Table *t, TString *key, TValue *val); LUAI_FUNC int luaH_psetstr (Table *t, TString *key, TValue *val); LUAI_FUNC int luaH_pset (Table *t, const TValue *key, TValue *val); LUAI_FUNC void luaH_setint (lua_State *L, Table *t, lua_Integer key, TValue *value); LUAI_FUNC void luaH_set (lua_State *L, Table *t, const TValue *key, TValue *value); LUAI_FUNC void luaH_finishset (lua_State *L, Table *t, const TValue *key, TValue *value, int hres); LUAI_FUNC Table *luaH_new (lua_State *L); LUAI_FUNC void luaH_resize (lua_State *L, Table *t, unsigned nasize, unsigned nhsize); LUAI_FUNC void luaH_resizearray (lua_State *L, Table *t, unsigned nasize); LUAI_FUNC void luaH_free (lua_State *L, Table *t); LUAI_FUNC int luaH_next (lua_State *L, Table *t, StkId key); LUAI_FUNC lua_Unsigned luaH_getn (Table *t); LUAI_FUNC unsigned luaH_realasize (const Table *t); #if defined(LUA_DEBUG) LUAI_FUNC Node *luaH_mainposition (const Table *t, const TValue *key); #endif #endif