src/lstate.h - platform/external/lua - Git at Google

 /*
 ** $Id: lstate.h $
 ** Global State
 ** See Copyright Notice in lua.h
 */

 #ifndef lstate_h
 #define lstate_h

 #include "lua.h"

 #include "lobject.h"
 #include "ltm.h"
 #include "lzio.h"


 /*
 ** Some notes about garbage-collected objects: All objects in Lua must
 ** be kept somehow accessible until being freed, so all objects always
 ** belong to one (and only one) of these lists, using field 'next' of
 ** the 'CommonHeader' for the link:
 **
 ** 'allgc': all objects not marked for finalization;
 ** 'finobj': all objects marked for finalization;
 ** 'tobefnz': all objects ready to be finalized;
 ** 'fixedgc': all objects that are not to be collected (currently
 ** only small strings, such as reserved words).
 **
 ** For the generational collector, some of these lists have marks for
 ** generations. Each mark points to the first element in the list for
 ** that particular generation; that generation goes until the next mark.
 **
 ** 'allgc' -> 'survival': new objects;
 ** 'survival' -> 'old': objects that survived one collection;
 ** 'old1' -> 'reallyold': objects that became old in last collection;
 ** 'reallyold' -> NULL: objects old for more than one cycle.
 **
 ** 'finobj' -> 'finobjsur': new objects marked for finalization;
 ** 'finobjsur' -> 'finobjold1': survived   """";
 ** 'finobjold1' -> 'finobjrold': just old  """";
 ** 'finobjrold' -> NULL: really old       """".
 **
 ** All lists can contain elements older than their main ages, due
 ** to 'luaC_checkfinalizer' and 'udata2finalize', which move
 ** objects between the normal lists and the "marked for finalization"
 ** lists. Moreover, barriers can age young objects in young lists as
 ** OLD0, which then become OLD1. However, a list never contains
 ** elements younger than their main ages.
 **
 ** The generational collector also uses a pointer 'firstold1', which
 ** points to the first OLD1 object in the list. It is used to optimize
 ** 'markold'. (Potentially OLD1 objects can be anywhere between 'allgc'
 ** and 'reallyold', but often the list has no OLD1 objects or they are
 ** after 'old1'.) Note the difference between it and 'old1':
 ** 'firstold1': no OLD1 objects before this point; there can be all
 **   ages after it.
 ** 'old1': no objects younger than OLD1 after this point.
 */

 /*
 ** Moreover, there is another set of lists that control gray objects.
 ** These lists are linked by fields 'gclist'. (All objects that
 ** can become gray have such a field. The field is not the same
 ** in all objects, but it always has this name.)  Any gray object
 ** must belong to one of these lists, and all objects in these lists
 ** must be gray (with two exceptions explained below):
 **
 ** 'gray': regular gray objects, still waiting to be visited.
 ** 'grayagain': objects that must be revisited at the atomic phase.
 **   That includes
 **   - black objects got in a write barrier;
 **   - all kinds of weak tables during propagation phase;
 **   - all threads.
 ** 'weak': tables with weak values to be cleared;
 ** 'ephemeron': ephemeron tables with white->white entries;
 ** 'allweak': tables with weak keys and/or weak values to be cleared.
 **
 ** The exceptions to that "gray rule" are:
 ** - TOUCHED2 objects in generational mode stay in a gray list (because
 ** they must be visited again at the end of the cycle), but they are
 ** marked black because assignments to them must activate barriers (to
 ** move them back to TOUCHED1).
 ** - Open upvales are kept gray to avoid barriers, but they stay out
 ** of gray lists. (They don't even have a 'gclist' field.)
 */


 /*
 ** About 'nCcalls': each thread in Lua (a lua_State) keeps a count of
 ** how many "C calls" it still can do in the C stack, to avoid C-stack
 ** overflow.  This count is very rough approximation; it considers only
 ** recursive functions inside the interpreter, as non-recursive calls
 ** can be considered using a fixed (although unknown) amount of stack
 ** space.
 **
 ** The count has two parts: the lower part is the count itself; the
 ** higher part counts the number of non-yieldable calls in the stack.
 ** (They are together so that we can change both with one instruction.)
 **
 ** Because calls to external C functions can use an unknown amount
 ** of space (e.g., functions using an auxiliary buffer), calls
 ** to these functions add more than one to the count (see CSTACKCF).
 **
 ** The proper count excludes the number of CallInfo structures allocated
 ** by Lua, as a kind of "potential" calls. So, when Lua calls a function
 ** (and "consumes" one CallInfo), it needs neither to decrement nor to
 ** check 'nCcalls', as its use of C stack is already accounted for.
 */

 /* number of "C stack slots" used by an external C function */
 #define CSTACKCF	10


 /*
 ** The C-stack size is sliced in the following zones:
 ** - larger than CSTACKERR: normal stack;
 ** - [CSTACKMARK, CSTACKERR]: buffer zone to signal a stack overflow;
 ** - [CSTACKCF, CSTACKERRMARK]: error-handling zone;
 ** - below CSTACKERRMARK: buffer zone to signal overflow during overflow;
 ** (Because the counter can be decremented CSTACKCF at once, we need
 ** the so called "buffer zones", with at least that size, to properly
 ** detect a change from one zone to the next.)
 */
 #define CSTACKERR	(8 * CSTACKCF)
 #define CSTACKMARK	(CSTACKERR - (CSTACKCF + 2))
 #define CSTACKERRMARK	(CSTACKCF + 2)


 /* initial limit for the C-stack of threads */
 #define CSTACKTHREAD	(2 * CSTACKERR)


 /* true if this thread does not have non-yieldable calls in the stack */
 #define yieldable(L)		(((L)->nCcalls & 0xffff0000) == 0)

 /* real number of C calls */
 #define getCcalls(L)	((L)->nCcalls & 0xffff)


 /* Increment the number of non-yieldable calls */
 #define incnny(L)	((L)->nCcalls += 0x10000)

 /* Decrement the number of non-yieldable calls */
 #define decnny(L)	((L)->nCcalls -= 0x10000)

 /* Increment the number of non-yieldable calls and decrement nCcalls */
 #define incXCcalls(L)	((L)->nCcalls += 0x10000 - CSTACKCF)

 /* Decrement the number of non-yieldable calls and increment nCcalls */
 #define decXCcalls(L)	((L)->nCcalls -= 0x10000 - CSTACKCF)


 struct lua_longjmp;  /* defined in ldo.c */


 /*
 ** Atomic type (relative to signals) to better ensure that 'lua_sethook'
 ** is thread safe
 */
 #if !defined(l_signalT)
 #include <signal.h>
 #define l_signalT	sig_atomic_t
 #endif


 /* extra stack space to handle TM calls and some other extras */
 #define EXTRA_STACK   5


 #define BASIC_STACK_SIZE        (2*LUA_MINSTACK)


 /* kinds of Garbage Collection */
 #define KGC_INC		0	/* incremental gc */
 #define KGC_GEN		1	/* generational gc */


 typedef struct stringtable {
   TString **hash;
   int nuse;  /* number of elements */
   int size;
 } stringtable;


 /*
 ** Information about a call.
 */
 typedef struct CallInfo {
   StkId func;  /* function index in the stack */
   StkId	top;  /* top for this function */
   struct CallInfo *previous, *next;  /* dynamic call link */
   union {
     struct {  /* only for Lua functions */
       const Instruction *savedpc;
       volatile l_signalT trap;
       int nextraargs;  /* # of extra arguments in vararg functions */
     } l;
     struct {  /* only for C functions */
       lua_KFunction k;  /* continuation in case of yields */
       ptrdiff_t old_errfunc;
       lua_KContext ctx;  /* context info. in case of yields */
     } c;
   } u;
   union {
     int funcidx;  /* called-function index */
     int nyield;  /* number of values yielded */
     struct {  /* info about transferred values (for call/return hooks) */
       unsigned short ftransfer;  /* offset of first value transferred */
       unsigned short ntransfer;  /* number of values transferred */
     } transferinfo;
   } u2;
   short nresults;  /* expected number of results from this function */
   unsigned short callstatus;
 } CallInfo;


 /*
 ** Bits in CallInfo status
 */
 #define CIST_OAH	(1<<0)	/* original value of 'allowhook' */
 #define CIST_C		(1<<1)	/* call is running a C function */
 #define CIST_HOOKED	(1<<2)	/* call is running a debug hook */
 #define CIST_YPCALL	(1<<3)	/* call is a yieldable protected call */
 #define CIST_TAIL	(1<<4)	/* call was tail called */
 #define CIST_HOOKYIELD	(1<<5)	/* last hook called yielded */
 #define CIST_FIN	(1<<6)  /* call is running a finalizer */
 #define CIST_TRAN	(1<<7)	/* 'ci' has transfer information */
 #if defined(LUA_COMPAT_LT_LE)
 #define CIST_LEQ	(1<<8)  /* using __lt for __le */
 #endif

 /* active function is a Lua function */
 #define isLua(ci)	(!((ci)->callstatus & CIST_C))

 /* call is running Lua code (not a hook) */
 #define isLuacode(ci)	(!((ci)->callstatus & (CIST_C | CIST_HOOKED)))

 /* assume that CIST_OAH has offset 0 and that 'v' is strictly 0/1 */
 #define setoah(st,v)	((st) = ((st) & ~CIST_OAH) | (v))
 #define getoah(st)	((st) & CIST_OAH)


 /*
 ** 'global state', shared by all threads of this state
 */
 typedef struct global_State {
   lua_Alloc frealloc;  /* function to reallocate memory */
   void *ud;         /* auxiliary data to 'frealloc' */
   l_mem totalbytes;  /* number of bytes currently allocated - GCdebt */
   l_mem GCdebt;  /* bytes allocated not yet compensated by the collector */
   lu_mem GCestimate;  /* an estimate of the non-garbage memory in use */
   lu_mem lastatomic;  /* see function 'genstep' in file 'lgc.c' */
   stringtable strt;  /* hash table for strings */
   TValue l_registry;
   TValue nilvalue;  /* a nil value */
   unsigned int seed;  /* randomized seed for hashes */
   lu_byte currentwhite;
   lu_byte gcstate;  /* state of garbage collector */
   lu_byte gckind;  /* kind of GC running */
   lu_byte genminormul;  /* control for minor generational collections */
   lu_byte genmajormul;  /* control for major generational collections */
   lu_byte gcrunning;  /* true if GC is running */
   lu_byte gcemergency;  /* true if this is an emergency collection */
   lu_byte gcpause;  /* size of pause between successive GCs */
   lu_byte gcstepmul;  /* GC "speed" */
   lu_byte gcstepsize;  /* (log2 of) GC granularity */
   GCObject *allgc;  /* list of all collectable objects */
   GCObject **sweepgc;  /* current position of sweep in list */
   GCObject *finobj;  /* list of collectable objects with finalizers */
   GCObject *gray;  /* list of gray objects */
   GCObject *grayagain;  /* list of objects to be traversed atomically */
   GCObject *weak;  /* list of tables with weak values */
   GCObject *ephemeron;  /* list of ephemeron tables (weak keys) */
   GCObject *allweak;  /* list of all-weak tables */
   GCObject *tobefnz;  /* list of userdata to be GC */
   GCObject *fixedgc;  /* list of objects not to be collected */
   /* fields for generational collector */
   GCObject *survival;  /* start of objects that survived one GC cycle */
   GCObject *old1;  /* start of old1 objects */
   GCObject *reallyold;  /* objects more than one cycle old ("really old") */
   GCObject *firstold1;  /* first OLD1 object in the list (if any) */
   GCObject *finobjsur;  /* list of survival objects with finalizers */
   GCObject *finobjold1;  /* list of old1 objects with finalizers */
   GCObject *finobjrold;  /* list of really old objects with finalizers */
   struct lua_State *twups;  /* list of threads with open upvalues */
   lua_CFunction panic;  /* to be called in unprotected errors */
   struct lua_State *mainthread;
   TString *memerrmsg;  /* message for memory-allocation errors */
   TString *tmname[TM_N];  /* array with tag-method names */
   struct Table *mt[LUA_NUMTAGS];  /* metatables for basic types */
   TString *strcache[STRCACHE_N][STRCACHE_M];  /* cache for strings in API */
   lua_WarnFunction warnf;  /* warning function */
   void *ud_warn;         /* auxiliary data to 'warnf' */
   unsigned int Cstacklimit;  /* current limit for the C stack */
 } global_State;


 /*
 ** 'per thread' state
 */
 struct lua_State {
   CommonHeader;
   lu_byte status;
   lu_byte allowhook;
   unsigned short nci;  /* number of items in 'ci' list */
   StkId top;  /* first free slot in the stack */
   global_State *l_G;
   CallInfo *ci;  /* call info for current function */
   StkId stack_last;  /* last free slot in the stack */
   StkId stack;  /* stack base */
   UpVal *openupval;  /* list of open upvalues in this stack */
   GCObject *gclist;
   struct lua_State *twups;  /* list of threads with open upvalues */
   struct lua_longjmp *errorJmp;  /* current error recover point */
   CallInfo base_ci;  /* CallInfo for first level (C calling Lua) */
   volatile lua_Hook hook;
   ptrdiff_t errfunc;  /* current error handling function (stack index) */
   l_uint32 nCcalls;  /* number of allowed nested C calls - 'nci' */
   int oldpc;  /* last pc traced */
   int stacksize;
   int basehookcount;
   int hookcount;
   volatile l_signalT hookmask;
 };


 #define G(L)	(L->l_G)


 /*
 ** Union of all collectable objects (only for conversions)
 ** ISO C99, 6.5.2.3 p.5:
 ** "if a union contains several structures that share a common initial
 ** sequence [...], and if the union object currently contains one
 ** of these structures, it is permitted to inspect the common initial
 ** part of any of them anywhere that a declaration of the complete type
 ** of the union is visible."
 */
 union GCUnion {
   GCObject gc;  /* common header */
   struct TString ts;
   struct Udata u;
   union Closure cl;
   struct Table h;
   struct Proto p;
   struct lua_State th;  /* thread */
   struct UpVal upv;
 };


 /*
 ** ISO C99, 6.7.2.1 p.14:
 ** "A pointer to a union object, suitably converted, points to each of
 ** its members [...], and vice versa."
 */
 #define cast_u(o)	cast(union GCUnion *, (o))

 /* macros to convert a GCObject into a specific value */
 #define gco2ts(o)  \
 	check_exp(novariant((o)->tt) == LUA_TSTRING, &((cast_u(o))->ts))
 #define gco2u(o)  check_exp((o)->tt == LUA_VUSERDATA, &((cast_u(o))->u))
 #define gco2lcl(o)  check_exp((o)->tt == LUA_VLCL, &((cast_u(o))->cl.l))
 #define gco2ccl(o)  check_exp((o)->tt == LUA_VCCL, &((cast_u(o))->cl.c))
 #define gco2cl(o)  \
 	check_exp(novariant((o)->tt) == LUA_TFUNCTION, &((cast_u(o))->cl))
 #define gco2t(o)  check_exp((o)->tt == LUA_VTABLE, &((cast_u(o))->h))
 #define gco2p(o)  check_exp((o)->tt == LUA_VPROTO, &((cast_u(o))->p))
 #define gco2th(o)  check_exp((o)->tt == LUA_VTHREAD, &((cast_u(o))->th))
 #define gco2upv(o)	check_exp((o)->tt == LUA_VUPVAL, &((cast_u(o))->upv))


 /*
 ** macro to convert a Lua object into a GCObject
 ** (The access to 'tt' tries to ensure that 'v' is actually a Lua object.)
 */
 #define obj2gco(v)	check_exp((v)->tt >= LUA_TSTRING, &(cast_u(v)->gc))


 /* actual number of total bytes allocated */
 #define gettotalbytes(g)	cast(lu_mem, (g)->totalbytes + (g)->GCdebt)

 LUAI_FUNC void luaE_setdebt (global_State *g, l_mem debt);
 LUAI_FUNC void luaE_freethread (lua_State *L, lua_State *L1);
 LUAI_FUNC CallInfo *luaE_extendCI (lua_State *L);
 LUAI_FUNC void luaE_freeCI (lua_State *L);
 LUAI_FUNC void luaE_shrinkCI (lua_State *L);
 LUAI_FUNC void luaE_enterCcall (lua_State *L);
 LUAI_FUNC void luaE_warning (lua_State *L, const char *msg, int tocont);
 LUAI_FUNC void luaE_warnerror (lua_State *L, const char *where);


 #define luaE_exitCcall(L)	((L)->nCcalls++)

 #endif
	/*
	** $Id: lstate.h $
	** Global State
	** See Copyright Notice in lua.h
	*/

	#ifndef lstate_h
	#define lstate_h

	#include "lua.h"

	#include "lobject.h"
	#include "ltm.h"
	#include "lzio.h"


	/*
	** Some notes about garbage-collected objects: All objects in Lua must
	** be kept somehow accessible until being freed, so all objects always
	** belong to one (and only one) of these lists, using field 'next' of
	** the 'CommonHeader' for the link:
	**
	** 'allgc': all objects not marked for finalization;
	** 'finobj': all objects marked for finalization;
	** 'tobefnz': all objects ready to be finalized;
	** 'fixedgc': all objects that are not to be collected (currently
	** only small strings, such as reserved words).
	**
	** For the generational collector, some of these lists have marks for
	** generations. Each mark points to the first element in the list for
	** that particular generation; that generation goes until the next mark.
	**
	** 'allgc' -> 'survival': new objects;
	** 'survival' -> 'old': objects that survived one collection;
	** 'old1' -> 'reallyold': objects that became old in last collection;
	** 'reallyold' -> NULL: objects old for more than one cycle.
	**
	** 'finobj' -> 'finobjsur': new objects marked for finalization;
	** 'finobjsur' -> 'finobjold1': survived """";
	** 'finobjold1' -> 'finobjrold': just old """";
	** 'finobjrold' -> NULL: really old """".
	**
	** All lists can contain elements older than their main ages, due
	** to 'luaC_checkfinalizer' and 'udata2finalize', which move
	** objects between the normal lists and the "marked for finalization"
	** lists. Moreover, barriers can age young objects in young lists as
	** OLD0, which then become OLD1. However, a list never contains
	** elements younger than their main ages.
	**
	** The generational collector also uses a pointer 'firstold1', which
	** points to the first OLD1 object in the list. It is used to optimize
	** 'markold'. (Potentially OLD1 objects can be anywhere between 'allgc'
	** and 'reallyold', but often the list has no OLD1 objects or they are
	** after 'old1'.) Note the difference between it and 'old1':
	** 'firstold1': no OLD1 objects before this point; there can be all
	** ages after it.
	** 'old1': no objects younger than OLD1 after this point.
	*/

	/*
	** Moreover, there is another set of lists that control gray objects.
	** These lists are linked by fields 'gclist'. (All objects that
	** can become gray have such a field. The field is not the same
	** in all objects, but it always has this name.) Any gray object
	** must belong to one of these lists, and all objects in these lists
	** must be gray (with two exceptions explained below):
	**
	** 'gray': regular gray objects, still waiting to be visited.
	** 'grayagain': objects that must be revisited at the atomic phase.
	** That includes
	** - black objects got in a write barrier;
	** - all kinds of weak tables during propagation phase;
	** - all threads.
	** 'weak': tables with weak values to be cleared;
	** 'ephemeron': ephemeron tables with white->white entries;
	** 'allweak': tables with weak keys and/or weak values to be cleared.
	**
	** The exceptions to that "gray rule" are:
	** - TOUCHED2 objects in generational mode stay in a gray list (because
	** they must be visited again at the end of the cycle), but they are
	** marked black because assignments to them must activate barriers (to
	** move them back to TOUCHED1).
	** - Open upvales are kept gray to avoid barriers, but they stay out
	** of gray lists. (They don't even have a 'gclist' field.)
	*/



	/*
	** About 'nCcalls': each thread in Lua (a lua_State) keeps a count of
	** how many "C calls" it still can do in the C stack, to avoid C-stack
	** overflow. This count is very rough approximation; it considers only
	** recursive functions inside the interpreter, as non-recursive calls
	** can be considered using a fixed (although unknown) amount of stack
	** space.
	**
	** The count has two parts: the lower part is the count itself; the
	** higher part counts the number of non-yieldable calls in the stack.
	** (They are together so that we can change both with one instruction.)
	**
	** Because calls to external C functions can use an unknown amount
	** of space (e.g., functions using an auxiliary buffer), calls
	** to these functions add more than one to the count (see CSTACKCF).
	**
	** The proper count excludes the number of CallInfo structures allocated
	** by Lua, as a kind of "potential" calls. So, when Lua calls a function
	** (and "consumes" one CallInfo), it needs neither to decrement nor to
	** check 'nCcalls', as its use of C stack is already accounted for.
	*/

	/* number of "C stack slots" used by an external C function */
	#define CSTACKCF 10


	/*
	** The C-stack size is sliced in the following zones:
	** - larger than CSTACKERR: normal stack;
	** - [CSTACKMARK, CSTACKERR]: buffer zone to signal a stack overflow;
	** - [CSTACKCF, CSTACKERRMARK]: error-handling zone;
	** - below CSTACKERRMARK: buffer zone to signal overflow during overflow;
	** (Because the counter can be decremented CSTACKCF at once, we need
	** the so called "buffer zones", with at least that size, to properly
	** detect a change from one zone to the next.)
	*/
	#define CSTACKERR (8 * CSTACKCF)
	#define CSTACKMARK (CSTACKERR - (CSTACKCF + 2))
	#define CSTACKERRMARK (CSTACKCF + 2)


	/* initial limit for the C-stack of threads */
	#define CSTACKTHREAD (2 * CSTACKERR)


	/* true if this thread does not have non-yieldable calls in the stack */
	#define yieldable(L) (((L)->nCcalls & 0xffff0000) == 0)

	/* real number of C calls */
	#define getCcalls(L) ((L)->nCcalls & 0xffff)


	/* Increment the number of non-yieldable calls */
	#define incnny(L) ((L)->nCcalls += 0x10000)

	/* Decrement the number of non-yieldable calls */
	#define decnny(L) ((L)->nCcalls -= 0x10000)

	/* Increment the number of non-yieldable calls and decrement nCcalls */
	#define incXCcalls(L) ((L)->nCcalls += 0x10000 - CSTACKCF)

	/* Decrement the number of non-yieldable calls and increment nCcalls */
	#define decXCcalls(L) ((L)->nCcalls -= 0x10000 - CSTACKCF)






	struct lua_longjmp; /* defined in ldo.c */


	/*
	** Atomic type (relative to signals) to better ensure that 'lua_sethook'
	** is thread safe
	*/
	#if !defined(l_signalT)
	#include <signal.h>
	#define l_signalT sig_atomic_t
	#endif


	/* extra stack space to handle TM calls and some other extras */
	#define EXTRA_STACK 5


	#define BASIC_STACK_SIZE (2*LUA_MINSTACK)


	/* kinds of Garbage Collection */
	#define KGC_INC 0 /* incremental gc */
	#define KGC_GEN 1 /* generational gc */


	typedef struct stringtable {
	TString **hash;
	int nuse; /* number of elements */
	int size;
	} stringtable;


	/*
	** Information about a call.
	*/
	typedef struct CallInfo {
	StkId func; /* function index in the stack */
	StkId top; /* top for this function */
	struct CallInfo previous, next; /* dynamic call link */
	union {
	struct { /* only for Lua functions */
	const Instruction *savedpc;
	volatile l_signalT trap;
	int nextraargs; /* # of extra arguments in vararg functions */
	} l;
	struct { /* only for C functions */
	lua_KFunction k; /* continuation in case of yields */
	ptrdiff_t old_errfunc;
	lua_KContext ctx; /* context info. in case of yields */
	} c;
	} u;
	union {
	int funcidx; /* called-function index */
	int nyield; /* number of values yielded */
	struct { /* info about transferred values (for call/return hooks) */
	unsigned short ftransfer; /* offset of first value transferred */
	unsigned short ntransfer; /* number of values transferred */
	} transferinfo;
	} u2;
	short nresults; /* expected number of results from this function */
	unsigned short callstatus;
	} CallInfo;


	/*
	** Bits in CallInfo status
	*/
	#define CIST_OAH (1<<0) /* original value of 'allowhook' */
	#define CIST_C (1<<1) /* call is running a C function */
	#define CIST_HOOKED (1<<2) /* call is running a debug hook */
	#define CIST_YPCALL (1<<3) /* call is a yieldable protected call */
	#define CIST_TAIL (1<<4) /* call was tail called */
	#define CIST_HOOKYIELD (1<<5) /* last hook called yielded */
	#define CIST_FIN (1<<6) /* call is running a finalizer */
	#define CIST_TRAN (1<<7) /* 'ci' has transfer information */
	#if defined(LUA_COMPAT_LT_LE)
	#define CIST_LEQ (1<<8) /* using __lt for __le */
	#endif

	/* active function is a Lua function */
	#define isLua(ci) (!((ci)->callstatus & CIST_C))

	/* call is running Lua code (not a hook) */
	#define isLuacode(ci) (!((ci)->callstatus & (CIST_C \| CIST_HOOKED)))

	/* assume that CIST_OAH has offset 0 and that 'v' is strictly 0/1 */
	#define setoah(st,v) ((st) = ((st) & ~CIST_OAH) \| (v))
	#define getoah(st) ((st) & CIST_OAH)


	/*
	** 'global state', shared by all threads of this state
	*/
	typedef struct global_State {
	lua_Alloc frealloc; /* function to reallocate memory */
	void ud; / auxiliary data to 'frealloc' */
	l_mem totalbytes; /* number of bytes currently allocated - GCdebt */
	l_mem GCdebt; /* bytes allocated not yet compensated by the collector */
	lu_mem GCestimate; /* an estimate of the non-garbage memory in use */
	lu_mem lastatomic; /* see function 'genstep' in file 'lgc.c' */
	stringtable strt; /* hash table for strings */
	TValue l_registry;
	TValue nilvalue; /* a nil value */
	unsigned int seed; /* randomized seed for hashes */
	lu_byte currentwhite;
	lu_byte gcstate; /* state of garbage collector */
	lu_byte gckind; /* kind of GC running */
	lu_byte genminormul; /* control for minor generational collections */
	lu_byte genmajormul; /* control for major generational collections */
	lu_byte gcrunning; /* true if GC is running */
	lu_byte gcemergency; /* true if this is an emergency collection */
	lu_byte gcpause; /* size of pause between successive GCs */
	lu_byte gcstepmul; /* GC "speed" */
	lu_byte gcstepsize; /* (log2 of) GC granularity */
	GCObject allgc; / list of all collectable objects */
	GCObject *sweepgc; / current position of sweep in list */
	GCObject finobj; / list of collectable objects with finalizers */
	GCObject gray; / list of gray objects */
	GCObject grayagain; / list of objects to be traversed atomically */
	GCObject weak; / list of tables with weak values */
	GCObject ephemeron; / list of ephemeron tables (weak keys) */
	GCObject allweak; / list of all-weak tables */
	GCObject tobefnz; / list of userdata to be GC */
	GCObject fixedgc; / list of objects not to be collected */
	/* fields for generational collector */
	GCObject survival; / start of objects that survived one GC cycle */
	GCObject old1; / start of old1 objects */
	GCObject reallyold; / objects more than one cycle old ("really old") */
	GCObject firstold1; / first OLD1 object in the list (if any) */
	GCObject finobjsur; / list of survival objects with finalizers */
	GCObject finobjold1; / list of old1 objects with finalizers */
	GCObject finobjrold; / list of really old objects with finalizers */
	struct lua_State twups; / list of threads with open upvalues */
	lua_CFunction panic; /* to be called in unprotected errors */
	struct lua_State *mainthread;
	TString memerrmsg; / message for memory-allocation errors */
	TString tmname[TM_N]; / array with tag-method names */
	struct Table mt[LUA_NUMTAGS]; / metatables for basic types */
	TString strcache[STRCACHE_N][STRCACHE_M]; / cache for strings in API */
	lua_WarnFunction warnf; /* warning function */
	void ud_warn; / auxiliary data to 'warnf' */
	unsigned int Cstacklimit; /* current limit for the C stack */
	} global_State;


	/*
	** 'per thread' state
	*/
	struct lua_State {
	CommonHeader;
	lu_byte status;
	lu_byte allowhook;
	unsigned short nci; /* number of items in 'ci' list */
	StkId top; /* first free slot in the stack */
	global_State *l_G;
	CallInfo ci; / call info for current function */
	StkId stack_last; /* last free slot in the stack */
	StkId stack; /* stack base */
	UpVal openupval; / list of open upvalues in this stack */
	GCObject *gclist;
	struct lua_State twups; / list of threads with open upvalues */
	struct lua_longjmp errorJmp; / current error recover point */
	CallInfo base_ci; /* CallInfo for first level (C calling Lua) */
	volatile lua_Hook hook;
	ptrdiff_t errfunc; /* current error handling function (stack index) */
	l_uint32 nCcalls; /* number of allowed nested C calls - 'nci' */
	int oldpc; /* last pc traced */
	int stacksize;
	int basehookcount;
	int hookcount;
	volatile l_signalT hookmask;
	};


	#define G(L) (L->l_G)


	/*
	** Union of all collectable objects (only for conversions)
	** ISO C99, 6.5.2.3 p.5:
	** "if a union contains several structures that share a common initial
	** sequence [...], and if the union object currently contains one
	** of these structures, it is permitted to inspect the common initial
	** part of any of them anywhere that a declaration of the complete type
	** of the union is visible."
	*/
	union GCUnion {
	GCObject gc; /* common header */
	struct TString ts;
	struct Udata u;
	union Closure cl;
	struct Table h;
	struct Proto p;
	struct lua_State th; /* thread */
	struct UpVal upv;
	};


	/*
	** ISO C99, 6.7.2.1 p.14:
	** "A pointer to a union object, suitably converted, points to each of
	** its members [...], and vice versa."
	*/
	#define cast_u(o) cast(union GCUnion *, (o))

	/* macros to convert a GCObject into a specific value */
	#define gco2ts(o) \
	check_exp(novariant((o)->tt) == LUA_TSTRING, &((cast_u(o))->ts))
	#define gco2u(o) check_exp((o)->tt == LUA_VUSERDATA, &((cast_u(o))->u))
	#define gco2lcl(o) check_exp((o)->tt == LUA_VLCL, &((cast_u(o))->cl.l))
	#define gco2ccl(o) check_exp((o)->tt == LUA_VCCL, &((cast_u(o))->cl.c))
	#define gco2cl(o) \
	check_exp(novariant((o)->tt) == LUA_TFUNCTION, &((cast_u(o))->cl))
	#define gco2t(o) check_exp((o)->tt == LUA_VTABLE, &((cast_u(o))->h))
	#define gco2p(o) check_exp((o)->tt == LUA_VPROTO, &((cast_u(o))->p))
	#define gco2th(o) check_exp((o)->tt == LUA_VTHREAD, &((cast_u(o))->th))
	#define gco2upv(o) check_exp((o)->tt == LUA_VUPVAL, &((cast_u(o))->upv))


	/*
	** macro to convert a Lua object into a GCObject
	** (The access to 'tt' tries to ensure that 'v' is actually a Lua object.)
	*/
	#define obj2gco(v) check_exp((v)->tt >= LUA_TSTRING, &(cast_u(v)->gc))


	/* actual number of total bytes allocated */
	#define gettotalbytes(g) cast(lu_mem, (g)->totalbytes + (g)->GCdebt)

	LUAI_FUNC void luaE_setdebt (global_State *g, l_mem debt);
	LUAI_FUNC void luaE_freethread (lua_State L, lua_State L1);
	LUAI_FUNC CallInfo luaE_extendCI (lua_State L);
	LUAI_FUNC void luaE_freeCI (lua_State *L);
	LUAI_FUNC void luaE_shrinkCI (lua_State *L);
	LUAI_FUNC void luaE_enterCcall (lua_State *L);
	LUAI_FUNC void luaE_warning (lua_State L, const char msg, int tocont);
	LUAI_FUNC void luaE_warnerror (lua_State L, const char where);


	#define luaE_exitCcall(L) ((L)->nCcalls++)

	#endif