[mirror_edk2.git] / AppPkg / Applications / Lua / src / lopcodes.h

/*
** $Id: lopcodes.h,v 1.142.1.1 2013/04/12 18:48:47 roberto Exp $
** Opcodes for Lua virtual machine
** See Copyright Notice in lua.h
*/

#ifndef lopcodes_h
#define lopcodes_h

#include "llimits.h"


/*===========================================================================
  We assume that instructions are unsigned numbers.
  All instructions have an opcode in the first 6 bits.
  Instructions can have the following fields:
	`A' : 8 bits
	`B' : 9 bits
	`C' : 9 bits
	'Ax' : 26 bits ('A', 'B', and 'C' together)
	`Bx' : 18 bits (`B' and `C' together)
	`sBx' : signed Bx

  A signed argument is represented in excess K; that is, the number
  value is the unsigned value minus K. K is exactly the maximum value
  for that argument (so that -max is represented by 0, and +max is
  represented by 2*max), which is half the maximum for the corresponding
  unsigned argument.
===========================================================================*/


enum OpMode {iABC, iABx, iAsBx, iAx};  /* basic instruction format */


/*
** size and position of opcode arguments.
*/
#define SIZE_C		9
#define SIZE_B		9
#define SIZE_Bx		(SIZE_C + SIZE_B)
#define SIZE_A		8
#define SIZE_Ax		(SIZE_C + SIZE_B + SIZE_A)

#define SIZE_OP		6

#define POS_OP		0
#define POS_A		(POS_OP + SIZE_OP)
#define POS_C		(POS_A + SIZE_A)
#define POS_B		(POS_C + SIZE_C)
#define POS_Bx		POS_C
#define POS_Ax		POS_A


/*
** limits for opcode arguments.
** we use (signed) int to manipulate most arguments,
** so they must fit in LUAI_BITSINT-1 bits (-1 for sign)
*/
#if SIZE_Bx < LUAI_BITSINT-1
#define MAXARG_Bx        ((1<<SIZE_Bx)-1)
#define MAXARG_sBx        (MAXARG_Bx>>1)         /* `sBx' is signed */
#else
#define MAXARG_Bx        MAX_INT
#define MAXARG_sBx        MAX_INT
#endif

#if SIZE_Ax < LUAI_BITSINT-1
#define MAXARG_Ax	((1<<SIZE_Ax)-1)
#else
#define MAXARG_Ax	MAX_INT
#endif


#define MAXARG_A        ((1<<SIZE_A)-1)
#define MAXARG_B        ((1<<SIZE_B)-1)
#define MAXARG_C        ((1<<SIZE_C)-1)


/* creates a mask with `n' 1 bits at position `p' */
#define MASK1(n,p)	((~((~(Instruction)0)<<(n)))<<(p))

/* creates a mask with `n' 0 bits at position `p' */
#define MASK0(n,p)	(~MASK1(n,p))

/*
** the following macros help to manipulate instructions
*/

#define GET_OPCODE(i)	(cast(OpCode, ((i)>>POS_OP) & MASK1(SIZE_OP,0)))
#define SET_OPCODE(i,o)	((i) = (((i)&MASK0(SIZE_OP,POS_OP)) | \
		((cast(Instruction, o)<<POS_OP)&MASK1(SIZE_OP,POS_OP))))

#define getarg(i,pos,size)	(cast(int, ((i)>>pos) & MASK1(size,0)))
#define setarg(i,v,pos,size)	((i) = (((i)&MASK0(size,pos)) | \
                ((cast(Instruction, v)<<pos)&MASK1(size,pos))))

#define GETARG_A(i)	getarg(i, POS_A, SIZE_A)
#define SETARG_A(i,v)	setarg(i, v, POS_A, SIZE_A)

#define GETARG_B(i)	getarg(i, POS_B, SIZE_B)
#define SETARG_B(i,v)	setarg(i, v, POS_B, SIZE_B)

#define GETARG_C(i)	getarg(i, POS_C, SIZE_C)
#define SETARG_C(i,v)	setarg(i, v, POS_C, SIZE_C)

#define GETARG_Bx(i)	getarg(i, POS_Bx, SIZE_Bx)
#define SETARG_Bx(i,v)	setarg(i, v, POS_Bx, SIZE_Bx)

#define GETARG_Ax(i)	getarg(i, POS_Ax, SIZE_Ax)
#define SETARG_Ax(i,v)	setarg(i, v, POS_Ax, SIZE_Ax)

#define GETARG_sBx(i)	(GETARG_Bx(i)-MAXARG_sBx)
#define SETARG_sBx(i,b)	SETARG_Bx((i),cast(unsigned int, (b)+MAXARG_sBx))


#define CREATE_ABC(o,a,b,c)	((cast(Instruction, o)<<POS_OP) \
			| (cast(Instruction, a)<<POS_A) \
			| (cast(Instruction, b)<<POS_B) \
			| (cast(Instruction, c)<<POS_C))

#define CREATE_ABx(o,a,bc)	((cast(Instruction, o)<<POS_OP) \
			| (cast(Instruction, a)<<POS_A) \
			| (cast(Instruction, bc)<<POS_Bx))

#define CREATE_Ax(o,a)		((cast(Instruction, o)<<POS_OP) \
			| (cast(Instruction, a)<<POS_Ax))


/*
** Macros to operate RK indices
*/

/* this bit 1 means constant (0 means register) */
#define BITRK		(1 << (SIZE_B - 1))

/* test whether value is a constant */
#define ISK(x)		((x) & BITRK)

/* gets the index of the constant */
#define INDEXK(r)	((int)(r) & ~BITRK)

#define MAXINDEXRK	(BITRK - 1)

/* code a constant index as a RK value */
#define RKASK(x)	((x) | BITRK)


/*
** invalid register that fits in 8 bits
*/
#define NO_REG		MAXARG_A


/*
** R(x) - register
** Kst(x) - constant (in constant table)
** RK(x) == if ISK(x) then Kst(INDEXK(x)) else R(x)
*/


/*
** grep "ORDER OP" if you change these enums
*/

typedef enum {
/*----------------------------------------------------------------------
name		args	description
------------------------------------------------------------------------*/
OP_MOVE,/*	A B	R(A) := R(B)					*/
OP_LOADK,/*	A Bx	R(A) := Kst(Bx)					*/
OP_LOADKX,/*	A 	R(A) := Kst(extra arg)				*/
OP_LOADBOOL,/*	A B C	R(A) := (Bool)B; if (C) pc++			*/
OP_LOADNIL,/*	A B	R(A), R(A+1), ..., R(A+B) := nil		*/
OP_GETUPVAL,/*	A B	R(A) := UpValue[B]				*/

OP_GETTABUP,/*	A B C	R(A) := UpValue[B][RK(C)]			*/
OP_GETTABLE,/*	A B C	R(A) := R(B)[RK(C)]				*/

OP_SETTABUP,/*	A B C	UpValue[A][RK(B)] := RK(C)			*/
OP_SETUPVAL,/*	A B	UpValue[B] := R(A)				*/
OP_SETTABLE,/*	A B C	R(A)[RK(B)] := RK(C)				*/

OP_NEWTABLE,/*	A B C	R(A) := {} (size = B,C)				*/

OP_SELF,/*	A B C	R(A+1) := R(B); R(A) := R(B)[RK(C)]		*/

OP_ADD,/*	A B C	R(A) := RK(B) + RK(C)				*/
OP_SUB,/*	A B C	R(A) := RK(B) - RK(C)				*/
OP_MUL,/*	A B C	R(A) := RK(B) * RK(C)				*/
OP_DIV,/*	A B C	R(A) := RK(B) / RK(C)				*/
OP_MOD,/*	A B C	R(A) := RK(B) % RK(C)				*/
OP_POW,/*	A B C	R(A) := RK(B) ^ RK(C)				*/
OP_UNM,/*	A B	R(A) := -R(B)					*/
OP_NOT,/*	A B	R(A) := not R(B)				*/
OP_LEN,/*	A B	R(A) := length of R(B)				*/

OP_CONCAT,/*	A B C	R(A) := R(B).. ... ..R(C)			*/

OP_JMP,/*	A sBx	pc+=sBx; if (A) close all upvalues >= R(A) + 1	*/
OP_EQ,/*	A B C	if ((RK(B) == RK(C)) ~= A) then pc++		*/
OP_LT,/*	A B C	if ((RK(B) <  RK(C)) ~= A) then pc++		*/
OP_LE,/*	A B C	if ((RK(B) <= RK(C)) ~= A) then pc++		*/

OP_TEST,/*	A C	if not (R(A) <=> C) then pc++			*/
OP_TESTSET,/*	A B C	if (R(B) <=> C) then R(A) := R(B) else pc++	*/

OP_CALL,/*	A B C	R(A), ... ,R(A+C-2) := R(A)(R(A+1), ... ,R(A+B-1)) */
OP_TAILCALL,/*	A B C	return R(A)(R(A+1), ... ,R(A+B-1))		*/
OP_RETURN,/*	A B	return R(A), ... ,R(A+B-2)	(see note)	*/

OP_FORLOOP,/*	A sBx	R(A)+=R(A+2);
			if R(A) <?= R(A+1) then { pc+=sBx; R(A+3)=R(A) }*/
OP_FORPREP,/*	A sBx	R(A)-=R(A+2); pc+=sBx				*/

OP_TFORCALL,/*	A C	R(A+3), ... ,R(A+2+C) := R(A)(R(A+1), R(A+2));	*/
OP_TFORLOOP,/*	A sBx	if R(A+1) ~= nil then { R(A)=R(A+1); pc += sBx }*/

OP_SETLIST,/*	A B C	R(A)[(C-1)*FPF+i] := R(A+i), 1 <= i <= B	*/

OP_CLOSURE,/*	A Bx	R(A) := closure(KPROTO[Bx])			*/

OP_VARARG,/*	A B	R(A), R(A+1), ..., R(A+B-2) = vararg		*/

OP_EXTRAARG/*	Ax	extra (larger) argument for previous opcode	*/
} OpCode;


#define NUM_OPCODES	(cast(int, OP_EXTRAARG) + 1)


/*===========================================================================
  Notes:
  (*) In OP_CALL, if (B == 0) then B = top. If (C == 0), then `top' is
  set to last_result+1, so next open instruction (OP_CALL, OP_RETURN,
  OP_SETLIST) may use `top'.

  (*) In OP_VARARG, if (B == 0) then use actual number of varargs and
  set top (like in OP_CALL with C == 0).

  (*) In OP_RETURN, if (B == 0) then return up to `top'.

  (*) In OP_SETLIST, if (B == 0) then B = `top'; if (C == 0) then next
  'instruction' is EXTRAARG(real C).

  (*) In OP_LOADKX, the next 'instruction' is always EXTRAARG.

  (*) For comparisons, A specifies what condition the test should accept
  (true or false).

  (*) All `skips' (pc++) assume that next instruction is a jump.

===========================================================================*/


/*
** masks for instruction properties. The format is:
** bits 0-1: op mode
** bits 2-3: C arg mode
** bits 4-5: B arg mode
** bit 6: instruction set register A
** bit 7: operator is a test (next instruction must be a jump)
*/

enum OpArgMask {
  OpArgN,  /* argument is not used */
  OpArgU,  /* argument is used */
  OpArgR,  /* argument is a register or a jump offset */
  OpArgK   /* argument is a constant or register/constant */
};

LUAI_DDEC const lu_byte luaP_opmodes[NUM_OPCODES];

#define getOpMode(m)	(cast(enum OpMode, luaP_opmodes[m] & 3))
#define getBMode(m)	(cast(enum OpArgMask, (luaP_opmodes[m] >> 4) & 3))
#define getCMode(m)	(cast(enum OpArgMask, (luaP_opmodes[m] >> 2) & 3))
#define testAMode(m)	(luaP_opmodes[m] & (1 << 6))
#define testTMode(m)	(luaP_opmodes[m] & (1 << 7))


LUAI_DDEC const char *const luaP_opnames[NUM_OPCODES+1];  /* opcode names */


/* number of list items to accumulate before a SETLIST instruction */
#define LFIELDS_PER_FLUSH	50


#endif
Commit	Line	Data
16a5fed6	1	/*
	2	** $Id: lopcodes.h,v 1.142.1.1 2013/04/12 18:48:47 roberto Exp $
	3	** Opcodes for Lua virtual machine
	4	** See Copyright Notice in lua.h
	5	*/
	6
	7	#ifndef lopcodes_h
	8	#define lopcodes_h
	9
	10	#include "llimits.h"
	11
	12
	13	/*===========================================================================
	14	We assume that instructions are unsigned numbers.
	15	All instructions have an opcode in the first 6 bits.
	16	Instructions can have the following fields:
	17	`A' : 8 bits
	18	`B' : 9 bits
	19	`C' : 9 bits
	20	'Ax' : 26 bits ('A', 'B', and 'C' together)
	21	`Bx' : 18 bits (`B' and `C' together)
	22	`sBx' : signed Bx
	23
	24	A signed argument is represented in excess K; that is, the number
	25	value is the unsigned value minus K. K is exactly the maximum value
	26	for that argument (so that -max is represented by 0, and +max is
	27	represented by 2*max), which is half the maximum for the corresponding
	28	unsigned argument.
	29	===========================================================================*/
	30
	31
	32	enum OpMode {iABC, iABx, iAsBx, iAx}; /* basic instruction format */
	33
	34
	35	/*
	36	** size and position of opcode arguments.
	37	*/
	38	#define SIZE_C 9
	39	#define SIZE_B 9
	40	#define SIZE_Bx (SIZE_C + SIZE_B)
	41	#define SIZE_A 8
	42	#define SIZE_Ax (SIZE_C + SIZE_B + SIZE_A)
	43
	44	#define SIZE_OP 6
	45
	46	#define POS_OP 0
	47	#define POS_A (POS_OP + SIZE_OP)
	48	#define POS_C (POS_A + SIZE_A)
	49	#define POS_B (POS_C + SIZE_C)
	50	#define POS_Bx POS_C
	51	#define POS_Ax POS_A
	52
	53
	54	/*
	55	** limits for opcode arguments.
	56	** we use (signed) int to manipulate most arguments,
	57	** so they must fit in LUAI_BITSINT-1 bits (-1 for sign)
	58	*/
	59	#if SIZE_Bx < LUAI_BITSINT-1
	60	#define MAXARG_Bx ((1<<SIZE_Bx)-1)
	61	#define MAXARG_sBx (MAXARG_Bx>>1) /* `sBx' is signed */
	62	#else
	63	#define MAXARG_Bx MAX_INT
	64	#define MAXARG_sBx MAX_INT
65	#endif
66
67	#if SIZE_Ax < LUAI_BITSINT-1
68	#define MAXARG_Ax ((1<<SIZE_Ax)-1)
69	#else
70	#define MAXARG_Ax MAX_INT
71	#endif
72
73
74	#define MAXARG_A ((1<<SIZE_A)-1)
75	#define MAXARG_B ((1<<SIZE_B)-1)
76	#define MAXARG_C ((1<<SIZE_C)-1)
77
78
79	/* creates a mask with `n' 1 bits at position `p' */
80	#define MASK1(n,p) ((~((~(Instruction)0)<<(n)))<<(p))
81
82	/* creates a mask with `n' 0 bits at position `p' */
83	#define MASK0(n,p) (~MASK1(n,p))
84
85	/*
86	** the following macros help to manipulate instructions
87	*/
88
89	#define GET_OPCODE(i) (cast(OpCode, ((i)>>POS_OP) & MASK1(SIZE_OP,0)))
90	#define SET_OPCODE(i,o) ((i) = (((i)&MASK0(SIZE_OP,POS_OP)) \| \
91	((cast(Instruction, o)<<POS_OP)&MASK1(SIZE_OP,POS_OP))))
92
93	#define getarg(i,pos,size) (cast(int, ((i)>>pos) & MASK1(size,0)))
94	#define setarg(i,v,pos,size) ((i) = (((i)&MASK0(size,pos)) \| \
95	((cast(Instruction, v)<<pos)&MASK1(size,pos))))
96
97	#define GETARG_A(i) getarg(i, POS_A, SIZE_A)
98	#define SETARG_A(i,v) setarg(i, v, POS_A, SIZE_A)
99
100	#define GETARG_B(i) getarg(i, POS_B, SIZE_B)
101	#define SETARG_B(i,v) setarg(i, v, POS_B, SIZE_B)
102
103	#define GETARG_C(i) getarg(i, POS_C, SIZE_C)
104	#define SETARG_C(i,v) setarg(i, v, POS_C, SIZE_C)
105
106	#define GETARG_Bx(i) getarg(i, POS_Bx, SIZE_Bx)
107	#define SETARG_Bx(i,v) setarg(i, v, POS_Bx, SIZE_Bx)
108
109	#define GETARG_Ax(i) getarg(i, POS_Ax, SIZE_Ax)
110	#define SETARG_Ax(i,v) setarg(i, v, POS_Ax, SIZE_Ax)
111
112	#define GETARG_sBx(i) (GETARG_Bx(i)-MAXARG_sBx)
113	#define SETARG_sBx(i,b) SETARG_Bx((i),cast(unsigned int, (b)+MAXARG_sBx))
114
115
116	#define CREATE_ABC(o,a,b,c) ((cast(Instruction, o)<<POS_OP) \
117	\| (cast(Instruction, a)<<POS_A) \
118	\| (cast(Instruction, b)<<POS_B) \
119	\| (cast(Instruction, c)<<POS_C))
120
121	#define CREATE_ABx(o,a,bc) ((cast(Instruction, o)<<POS_OP) \
122	\| (cast(Instruction, a)<<POS_A) \
123	\| (cast(Instruction, bc)<<POS_Bx))
124
125	#define CREATE_Ax(o,a) ((cast(Instruction, o)<<POS_OP) \
126	\| (cast(Instruction, a)<<POS_Ax))
127
128
129	/*
130	** Macros to operate RK indices
131	*/
132
133	/* this bit 1 means constant (0 means register) */
134	#define BITRK (1 << (SIZE_B - 1))
135
136	/* test whether value is a constant */
137	#define ISK(x) ((x) & BITRK)
138
139	/* gets the index of the constant */
140	#define INDEXK(r) ((int)(r) & ~BITRK)
141
142	#define MAXINDEXRK (BITRK - 1)
143
144	/* code a constant index as a RK value */
145	#define RKASK(x) ((x) \| BITRK)
146
147
148	/*
149	** invalid register that fits in 8 bits
150	*/
151	#define NO_REG MAXARG_A
152
153
154	/*
155	** R(x) - register
156	** Kst(x) - constant (in constant table)
157	** RK(x) == if ISK(x) then Kst(INDEXK(x)) else R(x)
158	*/
159
160
161	/*
162	** grep "ORDER OP" if you change these enums
163	*/
164
165	typedef enum {
166	/*----------------------------------------------------------------------
167	name args description
168	------------------------------------------------------------------------*/
169	OP_MOVE,/* A B R(A) := R(B) */
170	OP_LOADK,/* A Bx R(A) := Kst(Bx) */
171	OP_LOADKX,/* A R(A) := Kst(extra arg) */
172	OP_LOADBOOL,/* A B C R(A) := (Bool)B; if (C) pc++ */
173	OP_LOADNIL,/* A B R(A), R(A+1), ..., R(A+B) := nil */
174	OP_GETUPVAL,/* A B R(A) := UpValue[B] */
175
176	OP_GETTABUP,/* A B C R(A) := UpValue[B][RK(C)] */
177	OP_GETTABLE,/* A B C R(A) := R(B)[RK(C)] */
178
179	OP_SETTABUP,/* A B C UpValue[A][RK(B)] := RK(C) */
180	OP_SETUPVAL,/* A B UpValue[B] := R(A) */
181	OP_SETTABLE,/* A B C R(A)[RK(B)] := RK(C) */
182
183	OP_NEWTABLE,/* A B C R(A) := {} (size = B,C) */
184
185	OP_SELF,/* A B C R(A+1) := R(B); R(A) := R(B)[RK(C)] */
186
187	OP_ADD,/* A B C R(A) := RK(B) + RK(C) */
188	OP_SUB,/* A B C R(A) := RK(B) - RK(C) */
189	OP_MUL,/* A B C R(A) := RK(B) * RK(C) */
190	OP_DIV,/* A B C R(A) := RK(B) / RK(C) */
191	OP_MOD,/* A B C R(A) := RK(B) % RK(C) */
192	OP_POW,/* A B C R(A) := RK(B) ^ RK(C) */
193	OP_UNM,/* A B R(A) := -R(B) */
194	OP_NOT,/* A B R(A) := not R(B) */
195	OP_LEN,/* A B R(A) := length of R(B) */
196
197	OP_CONCAT,/* A B C R(A) := R(B).. ... ..R(C) */
198
199	OP_JMP,/* A sBx pc+=sBx; if (A) close all upvalues >= R(A) + 1 */
200	OP_EQ,/* A B C if ((RK(B) == RK(C)) ~= A) then pc++ */
201	OP_LT,/* A B C if ((RK(B) < RK(C)) ~= A) then pc++ */
202	OP_LE,/* A B C if ((RK(B) <= RK(C)) ~= A) then pc++ */
203
204	OP_TEST,/* A C if not (R(A) <=> C) then pc++ */
205	OP_TESTSET,/* A B C if (R(B) <=> C) then R(A) := R(B) else pc++ */
206
207	OP_CALL,/* A B C R(A), ... ,R(A+C-2) := R(A)(R(A+1), ... ,R(A+B-1)) */
208	OP_TAILCALL,/* A B C return R(A)(R(A+1), ... ,R(A+B-1)) */
209	OP_RETURN,/* A B return R(A), ... ,R(A+B-2) (see note) */
210
211	OP_FORLOOP,/* A sBx R(A)+=R(A+2);
212	if R(A) <?= R(A+1) then { pc+=sBx; R(A+3)=R(A) }*/
213	OP_FORPREP,/* A sBx R(A)-=R(A+2); pc+=sBx */
214
215	OP_TFORCALL,/* A C R(A+3), ... ,R(A+2+C) := R(A)(R(A+1), R(A+2)); */
216	OP_TFORLOOP,/* A sBx if R(A+1) ~= nil then { R(A)=R(A+1); pc += sBx }*/
217
218	OP_SETLIST,/* A B C R(A)[(C-1)FPF+i] := R(A+i), 1 <= i <= B /
219
220	OP_CLOSURE,/* A Bx R(A) := closure(KPROTO[Bx]) */
221
222	OP_VARARG,/* A B R(A), R(A+1), ..., R(A+B-2) = vararg */
223
224	OP_EXTRAARG/* Ax extra (larger) argument for previous opcode */
225	} OpCode;
226
227
228	#define NUM_OPCODES (cast(int, OP_EXTRAARG) + 1)
229
230
231
232	/*===========================================================================
233	Notes:
234	(*) In OP_CALL, if (B == 0) then B = top. If (C == 0), then `top' is
235	set to last_result+1, so next open instruction (OP_CALL, OP_RETURN,
236	OP_SETLIST) may use `top'.
237
238	(*) In OP_VARARG, if (B == 0) then use actual number of varargs and
239	set top (like in OP_CALL with C == 0).
240
241	(*) In OP_RETURN, if (B == 0) then return up to `top'.
242
243	(*) In OP_SETLIST, if (B == 0) then B = `top'; if (C == 0) then next
244	'instruction' is EXTRAARG(real C).
245
246	(*) In OP_LOADKX, the next 'instruction' is always EXTRAARG.
247
248	(*) For comparisons, A specifies what condition the test should accept
249	(true or false).
250
251	(*) All `skips' (pc++) assume that next instruction is a jump.
252
253	===========================================================================*/
254
255
256	/*
257	** masks for instruction properties. The format is:
258	** bits 0-1: op mode
259	** bits 2-3: C arg mode
260	** bits 4-5: B arg mode
261	** bit 6: instruction set register A
262	** bit 7: operator is a test (next instruction must be a jump)
263	*/
264
265	enum OpArgMask {
266	OpArgN, /* argument is not used */
267	OpArgU, /* argument is used */
268	OpArgR, /* argument is a register or a jump offset */
269	OpArgK /* argument is a constant or register/constant */
270	};
271
272	LUAI_DDEC const lu_byte luaP_opmodes[NUM_OPCODES];
273
274	#define getOpMode(m) (cast(enum OpMode, luaP_opmodes[m] & 3))
275	#define getBMode(m) (cast(enum OpArgMask, (luaP_opmodes[m] >> 4) & 3))
276	#define getCMode(m) (cast(enum OpArgMask, (luaP_opmodes[m] >> 2) & 3))
277	#define testAMode(m) (luaP_opmodes[m] & (1 << 6))
278	#define testTMode(m) (luaP_opmodes[m] & (1 << 7))
279
280
281	LUAI_DDEC const char const luaP_opnames[NUM_OPCODES+1]; / opcode names */
282
283
284	/* number of list items to accumulate before a SETLIST instruction */
285	#define LFIELDS_PER_FLUSH 50
286
287
288	#endif