lopcodes.h source code [Aseprite/third_party/lua/lopcodes.h]

1	/*
2	** $Id: lopcodes.h $
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 32-bit integers.
15	All instructions have an opcode in the first 7 bits.
16	Instructions can have the following formats:
17
18	3 3 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 0 0
19	1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
20	iABC C(8) \| B(8) \|k\| A(8) \| Op(7) \|
21	iABx Bx(17) \| A(8) \| Op(7) \|
22	iAsBx sBx (signed)(17) \| A(8) \| Op(7) \|
23	iAx Ax(25) \| Op(7) \|
24	isJ sJ(25) \| Op(7) \|
25
26	A signed argument is represented in excess K: the represented value is
27	the written unsigned value minus K, where K is half the maximum for the
28	corresponding unsigned argument.
29	===========================================================================/*
30
31
32	enum OpMode {iABC, iABx, iAsBx, iAx, isJ}; / basic instruction formats /
33
34
35	/*
36	** size and position of opcode arguments.
37	*/
38	#define SIZE_C 8
39	#define SIZE_B 8
40	#define SIZE_Bx (SIZE_C + SIZE_B + 1)
41	#define SIZE_A 8
42	#define SIZE_Ax (SIZE_Bx + SIZE_A)
43	#define SIZE_sJ (SIZE_Bx + SIZE_A)
44
45	#define SIZE_OP 7
46
47	#define POS_OP 0
48
49	#define POS_A (POS_OP + SIZE_OP)
50	#define POS_k (POS_A + SIZE_A)
51	#define POS_B (POS_k + 1)
52	#define POS_C (POS_B + SIZE_B)
53
54	#define POS_Bx POS_k
55
56	#define POS_Ax POS_A
57
58	#define POS_sJ POS_A
59
60
61	/*
62	** limits for opcode arguments.
63	** we use (signed) 'int' to manipulate most arguments,
64	** so they must fit in ints.
65	*/
66
67	/ Check whether type 'int' has at least 'b' bits ('b' < 32) /
68	#define L_INTHASBITS(b) ((UINT_MAX >> ((b) - 1)) >= 1)
69
70
71	#if L_INTHASBITS(SIZE_Bx)
72	#define MAXARG_Bx ((1<<SIZE_Bx)-1)
73	#else
74	#define MAXARG_Bx MAX_INT
75	#endif
76
77	#define OFFSET_sBx (MAXARG_Bx>>1) /* 'sBx' is signed */
78
79
80	#if L_INTHASBITS(SIZE_Ax)
81	#define MAXARG_Ax ((1<<SIZE_Ax)-1)
82	#else
83	#define MAXARG_Ax MAX_INT
84	#endif
85
86	#if L_INTHASBITS(SIZE_sJ)
87	#define MAXARG_sJ ((1 << SIZE_sJ) - 1)
88	#else
89	#define MAXARG_sJ MAX_INT
90	#endif
91
92	#define OFFSET_sJ (MAXARG_sJ >> 1)
93
94
95	#define MAXARG_A ((1<<SIZE_A)-1)
96	#define MAXARG_B ((1<<SIZE_B)-1)
97	#define MAXARG_C ((1<<SIZE_C)-1)
98	#define OFFSET_sC (MAXARG_C >> 1)
99
100	#define int2sC(i) ((i) + OFFSET_sC)
101	#define sC2int(i) ((i) - OFFSET_sC)
102
103
104	/ creates a mask with 'n' 1 bits at position 'p' /
105	#define MASK1(n,p) ((~((~(Instruction)0)<<(n)))<<(p))
106
107	/ creates a mask with 'n' 0 bits at position 'p' /
108	#define MASK0(n,p) (~MASK1(n,p))
109
110	/*
111	** the following macros help to manipulate instructions
112	*/
113
114	#define GET_OPCODE(i) (cast(OpCode, ((i)>>POS_OP) & MASK1(SIZE_OP,0)))
115	#define SET_OPCODE(i,o) ((i) = (((i)&MASK0(SIZE_OP,POS_OP)) \| \
116	((cast(Instruction, o)<<POS_OP)&MASK1(SIZE_OP,POS_OP))))
117
118	#define checkopm(i,m) (getOpMode(GET_OPCODE(i)) == m)
119
120
121	#define getarg(i,pos,size) (cast_int(((i)>>(pos)) & MASK1(size,0)))
122	#define setarg(i,v,pos,size) ((i) = (((i)&MASK0(size,pos)) \| \
123	((cast(Instruction, v)<<pos)&MASK1(size,pos))))
124
125	#define GETARG_A(i) getarg(i, POS_A, SIZE_A)
126	#define SETARG_A(i,v) setarg(i, v, POS_A, SIZE_A)
127
128	#define GETARG_B(i) check_exp(checkopm(i, iABC), getarg(i, POS_B, SIZE_B))
129	#define GETARG_sB(i) sC2int(GETARG_B(i))
130	#define SETARG_B(i,v) setarg(i, v, POS_B, SIZE_B)
131
132	#define GETARG_C(i) check_exp(checkopm(i, iABC), getarg(i, POS_C, SIZE_C))
133	#define GETARG_sC(i) sC2int(GETARG_C(i))
134	#define SETARG_C(i,v) setarg(i, v, POS_C, SIZE_C)
135
136	#define TESTARG_k(i) check_exp(checkopm(i, iABC), (cast_int(((i) & (1u << POS_k)))))
137	#define GETARG_k(i) check_exp(checkopm(i, iABC), getarg(i, POS_k, 1))
138	#define SETARG_k(i,v) setarg(i, v, POS_k, 1)
139
140	#define GETARG_Bx(i) check_exp(checkopm(i, iABx), getarg(i, POS_Bx, SIZE_Bx))
141	#define SETARG_Bx(i,v) setarg(i, v, POS_Bx, SIZE_Bx)
142
143	#define GETARG_Ax(i) check_exp(checkopm(i, iAx), getarg(i, POS_Ax, SIZE_Ax))
144	#define SETARG_Ax(i,v) setarg(i, v, POS_Ax, SIZE_Ax)
145
146	#define GETARG_sBx(i) \
147	check_exp(checkopm(i, iAsBx), getarg(i, POS_Bx, SIZE_Bx) - OFFSET_sBx)
148	#define SETARG_sBx(i,b) SETARG_Bx((i),cast_uint((b)+OFFSET_sBx))
149
150	#define GETARG_sJ(i) \
151	check_exp(checkopm(i, isJ), getarg(i, POS_sJ, SIZE_sJ) - OFFSET_sJ)
152	#define SETARG_sJ(i,j) \
153	setarg(i, cast_uint((j)+OFFSET_sJ), POS_sJ, SIZE_sJ)
154
155
156	#define CREATE_ABCk(o,a,b,c,k) ((cast(Instruction, o)<<POS_OP) \
157	\| (cast(Instruction, a)<<POS_A) \
158	\| (cast(Instruction, b)<<POS_B) \
159	\| (cast(Instruction, c)<<POS_C) \
160	\| (cast(Instruction, k)<<POS_k))
161
162	#define CREATE_ABx(o,a,bc) ((cast(Instruction, o)<<POS_OP) \
163	\| (cast(Instruction, a)<<POS_A) \
164	\| (cast(Instruction, bc)<<POS_Bx))
165
166	#define CREATE_Ax(o,a) ((cast(Instruction, o)<<POS_OP) \
167	\| (cast(Instruction, a)<<POS_Ax))
168
169	#define CREATE_sJ(o,j,k) ((cast(Instruction, o) << POS_OP) \
170	\| (cast(Instruction, j) << POS_sJ) \
171	\| (cast(Instruction, k) << POS_k))
172
173
174	#if !defined(MAXINDEXRK) /* (for debugging only) */
175	#define MAXINDEXRK MAXARG_B
176	#endif
177
178
179	/*
180	** invalid register that fits in 8 bits
181	*/
182	#define NO_REG MAXARG_A
183
184
185	/*
186	** R[x] - register
187	** K[x] - constant (in constant table)
188	** RK(x) == if k(i) then K[x] else R[x]
189	*/
190
191
192	/*
193	** grep "ORDER OP" if you change these enums
194	*/
195
196	typedef enum {
197	/----------------------------------------------------------------------*
198	name args description
199	------------------------------------------------------------------------/*
200	OP_MOVE,/ A B R[A] := R[B] /
201	OP_LOADI,/ A sBx R[A] := sBx /
202	OP_LOADF,/ A sBx R[A] := (lua_Number)sBx /
203	OP_LOADK,/ A Bx R[A] := K[Bx] /
204	OP_LOADKX,/ A R[A] := K[extra arg] /
205	OP_LOADFALSE,/ A R[A] := false /
206	OP_LFALSESKIP,/A R[A] := false; pc++ /
207	OP_LOADTRUE,/ A R[A] := true /
208	OP_LOADNIL,/ A B R[A], R[A+1], ..., R[A+B] := nil /
209	OP_GETUPVAL,/ A B R[A] := UpValue[B] /
210	OP_SETUPVAL,/ A B UpValue[B] := R[A] /
211
212	OP_GETTABUP,/ A B C R[A] := UpValue[B][K[C]:string] /
213	OP_GETTABLE,/ A B C R[A] := R[B][R[C]] /
214	OP_GETI,/ A B C R[A] := R[B][C] /
215	OP_GETFIELD,/ A B C R[A] := R[B][K[C]:string] /
216
217	OP_SETTABUP,/ A B C UpValue[A][K[B]:string] := RK(C) /
218	OP_SETTABLE,/ A B C R[A][R[B]] := RK(C) /
219	OP_SETI,/ A B C R[A][B] := RK(C) /
220	OP_SETFIELD,/ A B C R[A][K[B]:string] := RK(C) /
221
222	OP_NEWTABLE,/ A B C k R[A] := {} /
223
224	OP_SELF,/ A B C R[A+1] := R[B]; R[A] := R[B][RK(C):string] /
225
226	OP_ADDI,/ A B sC R[A] := R[B] + sC /
227
228	OP_ADDK,/ A B C R[A] := R[B] + K[C]:number /
229	OP_SUBK,/ A B C R[A] := R[B] - K[C]:number /
230	OP_MULK,/ A B C R[A] := R[B] * K[C]:number /
231	OP_MODK,/ A B C R[A] := R[B] % K[C]:number /
232	OP_POWK,/ A B C R[A] := R[B] ^ K[C]:number /
233	OP_DIVK,/ A B C R[A] := R[B] / K[C]:number /
234	OP_IDIVK,/ A B C R[A] := R[B] // K[C]:number /
235
236	OP_BANDK,/ A B C R[A] := R[B] & K[C]:integer /
237	OP_BORK,/ A B C R[A] := R[B] \| K[C]:integer /
238	OP_BXORK,/ A B C R[A] := R[B] ~ K[C]:integer /
239
240	OP_SHRI,/ A B sC R[A] := R[B] >> sC /
241	OP_SHLI,/ A B sC R[A] := sC << R[B] /
242
243	OP_ADD,/ A B C R[A] := R[B] + R[C] /
244	OP_SUB,/ A B C R[A] := R[B] - R[C] /
245	OP_MUL,/ A B C R[A] := R[B] * R[C] /
246	OP_MOD,/ A B C R[A] := R[B] % R[C] /
247	OP_POW,/ A B C R[A] := R[B] ^ R[C] /
248	OP_DIV,/ A B C R[A] := R[B] / R[C] /
249	OP_IDIV,/ A B C R[A] := R[B] // R[C] /
250
251	OP_BAND,/ A B C R[A] := R[B] & R[C] /
252	OP_BOR,/ A B C R[A] := R[B] \| R[C] /
253	OP_BXOR,/ A B C R[A] := R[B] ~ R[C] /
254	OP_SHL,/ A B C R[A] := R[B] << R[C] /
255	OP_SHR,/ A B C R[A] := R[B] >> R[C] /
256
257	OP_MMBIN,/ A B C call C metamethod over R[A] and R[B] /
258	OP_MMBINI,/ A sB C k call C metamethod over R[A] and sB /
259	OP_MMBINK,/ A B C k call C metamethod over R[A] and K[B] /
260
261	OP_UNM,/ A B R[A] := -R[B] /
262	OP_BNOT,/ A B R[A] := ~R[B] /
263	OP_NOT,/ A B R[A] := not R[B] /
264	OP_LEN,/ A B R[A] := #R[B] (length operator) /
265
266	OP_CONCAT,/ A B R[A] := R[A].. ... ..R[A + B - 1] /
267
268	OP_CLOSE,/ A close all upvalues >= R[A] /
269	OP_TBC,/ A mark variable A "to be closed" /
270	OP_JMP,/ sJ pc += sJ /
271	OP_EQ,/ A B k if ((R[A] == R[B]) ~= k) then pc++ /
272	OP_LT,/ A B k if ((R[A] < R[B]) ~= k) then pc++ /
273	OP_LE,/ A B k if ((R[A] <= R[B]) ~= k) then pc++ /
274
275	OP_EQK,/ A B k if ((R[A] == K[B]) ~= k) then pc++ /
276	OP_EQI,/ A sB k if ((R[A] == sB) ~= k) then pc++ /
277	OP_LTI,/ A sB k if ((R[A] < sB) ~= k) then pc++ /
278	OP_LEI,/ A sB k if ((R[A] <= sB) ~= k) then pc++ /
279	OP_GTI,/ A sB k if ((R[A] > sB) ~= k) then pc++ /
280	OP_GEI,/ A sB k if ((R[A] >= sB) ~= k) then pc++ /
281
282	OP_TEST,/ A k if (not R[A] == k) then pc++ /
283	OP_TESTSET,/ A B k if (not R[B] == k) then pc++ else R[A] := R[B] /
284
285	OP_CALL,/ A B C R[A], ... ,R[A+C-2] := R[A](R[A+1], ... ,R[A+B-1]) /
286	OP_TAILCALL,/ A B C k return R[A](R[A+1], ... ,R[A+B-1]) /
287
288	OP_RETURN,/ A B C k return R[A], ... ,R[A+B-2] (see note) /
289	OP_RETURN0,/ return /
290	OP_RETURN1,/ A return R[A] /
291
292	OP_FORLOOP,/ A Bx update counters; if loop continues then pc-=Bx; /
293	OP_FORPREP,/ A Bx <check values and prepare counters>;*
294	if not to run then pc+=Bx+1; /*
295
296	OP_TFORPREP,/ A Bx create upvalue for R[A + 3]; pc+=Bx /
297	OP_TFORCALL,/ A C R[A+4], ... ,R[A+3+C] := R[A](R[A+1], R[A+2]); /
298	OP_TFORLOOP,/ A Bx if R[A+2] ~= nil then { R[A]=R[A+2]; pc -= Bx } /
299
300	OP_SETLIST,/ A B C k R[A][C+i] := R[A+i], 1 <= i <= B /
301
302	OP_CLOSURE,/ A Bx R[A] := closure(KPROTO[Bx]) /
303
304	OP_VARARG,/ A C R[A], R[A+1], ..., R[A+C-2] = vararg /
305
306	OP_VARARGPREP,/A (adjust vararg parameters) /
307
308	OP_EXTRAARG/* Ax extra (larger) argument for previous opcode */
309	} OpCode;
310
311
312	#define NUM_OPCODES ((int)(OP_EXTRAARG) + 1)
313
314
315
316	/===========================================================================*
317	Notes:
318	() In OP_CALL, if (B == 0) then B = top - A. If (C == 0), then*
319	'top' is set to last_result+1, so next open instruction (OP_CALL,
320	OP_RETURN, OP_SETLIST) may use 'top'.*
321
322	() In OP_VARARG, if (C == 0) then use actual number of varargs and*
323	set top (like in OP_CALL with C == 0).
324
325	() In OP_RETURN, if (B == 0) then return up to 'top'.*
326
327	() In OP_LOADKX and OP_NEWTABLE, the next instruction is always*
328	OP_EXTRAARG.
329
330	() In OP_SETLIST, if (B == 0) then real B = 'top'; if k, then*
331	real C = EXTRAARG _ C (the bits of EXTRAARG concatenated with the
332	bits of C).
333
334	() In OP_NEWTABLE, B is log2 of the hash size (which is always a*
335	power of 2) plus 1, or zero for size zero. If not k, the array size
336	is C. Otherwise, the array size is EXTRAARG _ C.
337
338	() For comparisons, k specifies what condition the test should accept*
339	(true or false).
340
341	() In OP_MMBINI/OP_MMBINK, k means the arguments were flipped*
342	(the constant is the first operand).
343
344	() All 'skips' (pc++) assume that next instruction is a jump.*
345
346	() In instructions OP_RETURN/OP_TAILCALL, 'k' specifies that the*
347	function builds upvalues, which may need to be closed. C > 0 means
348	the function is vararg, so that its 'func' must be corrected before
349	returning; in this case, (C - 1) is its number of fixed parameters.
350
351	() In comparisons with an immediate operand, C signals whether the*
352	original operand was a float. (It must be corrected in case of
353	metamethods.)
354
355	===========================================================================/*
356
357
358	/*
359	** masks for instruction properties. The format is:
360	** bits 0-2: op mode
361	** bit 3: instruction set register A
362	** bit 4: operator is a test (next instruction must be a jump)
363	** bit 5: instruction uses 'L->top' set by previous instruction (when B == 0)
364	** bit 6: instruction sets 'L->top' for next instruction (when C == 0)
365	** bit 7: instruction is an MM instruction (call a metamethod)
366	*/
367
368	LUAI_DDEC(const lu_byte luaP_opmodes[NUM_OPCODES];)
369
370	#define getOpMode(m) (cast(enum OpMode, luaP_opmodes[m] & 7))
371	#define testAMode(m) (luaP_opmodes[m] & (1 << 3))
372	#define testTMode(m) (luaP_opmodes[m] & (1 << 4))
373	#define testITMode(m) (luaP_opmodes[m] & (1 << 5))
374	#define testOTMode(m) (luaP_opmodes[m] & (1 << 6))
375	#define testMMMode(m) (luaP_opmodes[m] & (1 << 7))
376
377	/ "out top" (set top for next instruction) /
378	#define isOT(i) \
379	((testOTMode(GET_OPCODE(i)) && GETARG_C(i) == 0) \|\| \
380	GET_OPCODE(i) == OP_TAILCALL)
381
382	/ "in top" (uses top from previous instruction) /
383	#define isIT(i) (testITMode(GET_OPCODE(i)) && GETARG_B(i) == 0)
384
385	#define opmode(mm,ot,it,t,a,m) \
386	(((mm) << 7) \| ((ot) << 6) \| ((it) << 5) \| ((t) << 4) \| ((a) << 3) \| (m))
387
388
389	/ number of list items to accumulate before a SETLIST instruction /
390	#define LFIELDS_PER_FLUSH 50
391
392	#endif
393

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