2 * Copyright (C) 2013-2023 Free Software Foundation, Inc.
4 * This file is part of GNU lightning.
6 * GNU lightning is free software; you can redistribute it and/or modify it
7 * under the terms of the GNU Lesser General Public License as published
8 * by the Free Software Foundation; either version 3, or (at your option)
11 * GNU lightning is distributed in the hope that it will be useful, but
12 * WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
13 * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public
14 * License for more details.
17 * Paulo Cesar Pereira de Andrade
22 # define ldr(r0,r1) ldr_i(r0,r1)
23 # define ldxr(r0,r1,r2) ldxr_i(r0,r1,r2)
24 # define ldxi(r0,r1,i0) ldxi_i(r0,r1,i0)
25 # define stxi(i0,r0,r1) stxi_i(i0,r0,r1)
27 # define ldr(r0,r1) ldr_l(r0,r1)
28 # define ldxr(r0,r1,r2) ldxr_l(r0,r1,r2)
29 # define ldxi(r0,r1,i0) ldxi_l(r0,r1,i0)
30 # define stxi(i0,r0,r1) stxi_l(i0,r0,r1)
32 # define is(i) *_jit->pc.us++ = i
34 # define stack_framesize 96
36 # define stack_framesize 160
41 # define _R13_REGNO 13
42 # define _FP_REGNO _R13_REGNO
43 # define _R14_REGNO 14
44 # define _R15_REGNO 15
45 # define u12_p(i0) ((i0) >= 0 && (i0) <= 4095)
46 # define s16_p(i0) ((i0) >= -32768 && (i0) <= 32767)
47 # define x16(i0) ((i0) & 0xffff)
48 # define s20_p(i0) ((i0) >= -524288 && (i0) <= 524287)
49 # define x20(i0) ((i0) & 0xfffff)
54 ((i0) >= -2147483648L && (i0) < 2147483647L)
58 Condition Code Instruction (Mask) Bit Mask Value
71 14 -> no overflow CC_NO
89 14 -> no overflow CC_NO
117 # define _us jit_uint16_t
118 # define _ui jit_uint32_t
119 # define E_(Op) _E(_jit,Op)
120 static void _E(jit_state_t*,_ui);
121 # define I_(Op,I) _I(_jit,Op,I)
122 static void _I(jit_state_t*,_ui,_ui);
123 # define RR_(Op,R1,R2) _RR(_jit,Op,R1,R2)
124 static void _RR(jit_state_t*,_ui,_ui,_ui);
125 # define RRE_(Op,R1,R2) _RRE(_jit,Op,R1,R2)
126 static void _RRE(jit_state_t*,_ui,_ui,_ui);
127 # define RRF_(Op,R3,M4,R1,R2) _RRF(_jit,Op,R3,M4,R1,R2)
128 static void _RRF(jit_state_t*,_ui,_ui,_ui,_ui,_ui);
129 # define RX_(Op,R1,X2,B2,D2) _RX(_jit,Op,R1,X2,B2,D2)
130 static void _RX(jit_state_t*,_ui,_ui,_ui,_ui,_ui);
131 # define RXE_(Op,R1,X2,B2,D2,Op2) _RXE(_jit,Op,R1,X2,B2,D2,Op2)
132 static void _RXE(jit_state_t*,_ui,_ui,_ui,_ui,_ui,_ui);
133 # define RXF_(Op,R3,X2,B2,D2,R1,Op2) _RXF(_jit,Op,R3,X2,B2,D2,R1,Op2)
134 static void _RXF(jit_state_t*,_ui,_ui,_ui,_ui,_ui,_ui,_ui);
135 # define RXY_(Op,R1,X2,B2,D2,Op2) _RXY(_jit,Op,R1,X2,B2,D2,Op2)
136 static void _RXY(jit_state_t*,_ui,_ui,_ui,_ui,_ui,_ui);
137 # define RS_(Op,R1,R3,B2,D2) _RS(_jit,Op,R1,R3,B2,D2)
138 static void _RS(jit_state_t*,_ui,_ui,_ui,_ui,_ui);
139 # define RSY_(Op,R1,R3,B2,D2,Op2) RXY_(Op,R1,R3,B2,D2,Op2)
140 # define RSL_(Op,L1,B1,D1,Op2) _RSL(_jit,Op,L1,B1,D1,Op2)
141 static void _RSL(jit_state_t*,_ui,_ui,_ui,_ui,_ui);
142 # define RSI_(Op,R1,R3,I2) _RSI(_jit,Op,R1,R3,I2)
143 static void _RSI(jit_state_t*,_ui,_ui,_ui,_ui);
144 # define RI_(Op,R1,Op2,I2) RSI_(Op,R1,Op2,I2)
145 # define RIE_(Op,R1,R3,I2,Op2) _RIE(_jit,Op,R1,R3,I2,Op2)
146 static void _RIE(jit_state_t*,_ui,_ui,_ui,_ui,_ui);
147 # define RIL_(Op,R1,Op2,I2) _RIL(_jit,Op,R1,Op2,I2)
148 static void _RIL(jit_state_t*,_ui,_ui,_ui,_ui);
149 # define SI_(Op,I2,B1,D1) _SI(_jit,Op,I2,B1,D1)
150 static void _SI(jit_state_t*,_ui,_ui,_ui,_ui);
151 # define SIY_(Op,I2,B1,D1,Op2) _SIY(_jit,Op,I2,B1,D1,Op2)
152 static void _SIY(jit_state_t*,_ui,_ui,_ui,_ui,_ui);
153 # define S_(Op,B2,D2) _S(_jit,Op,B2,D2)
154 static void _S(jit_state_t*,_ui,_ui,_ui);
155 # define SSL_(Op,L,B1,D1,B2,D2) SS_(Op,(L)>>4,(L)&0xF,B1,D1,B2,D2)
156 # define SS_(Op,LL,LH,B1,D1,B2,D2) _SS(_jit,Op,LL,LH,B1,D1,B2,D2)
157 static void _SS(jit_state_t*,_ui,_ui,_ui,_ui,_ui,_ui,_ui);
158 # define SSE_(Op,B1,D1,B2,D2) _SSE(_jit,Op,B1,D1,B2,D2)
159 static void _SSE(jit_state_t*,_ui,_ui,_ui,_ui,_ui);
162 # define nop(c) _nop(_jit,c)
163 static void _nop(jit_state_t*,jit_int32_t);
164 # if __WORDSIZE == 32
165 # define ADD_(r0,r1) AR(r0,r1)
166 # define ADDI_(r0,i0) AHI(r0,i0)
167 # define ADDC_(r0,r1) ALR(r0,r1)
168 # define ADDX_(r0,r1) ALCR(r0,r1)
169 # define AND_(r0,r1) NR(r0,r1)
170 # define CMP_(r0,r1) CR(r0,r1)
171 # define CMPU_(r0,r1) CLR(r0,r1)
172 # define DIVREM_(r0,r1) DR(r0,r1)
173 # define DIVREMU_(r0,r1) DLR(r0,r1)
174 # define OR_(r0,r1) OR(r0,r1)
175 # define MUL_(r0,r1) MSR(r0,r1)
176 # define MULI_(r0,i0) MHI(r0,i0)
177 # define MULU_(r0,r1) MLR(r0,r1)
178 # define SUB_(r0,r1) SR(r0,r1)
179 # define SUBC_(r0,r1) SLR(r0,r1)
180 # define SUBX_(r0,r1) SLBR(r0,r1)
181 # define TEST_(r0,r1) LTR(r0,r1)
182 # define XOR_(r0,r1) XR(r0,r1)
184 # define ADD_(r0,r1) AGR(r0,r1)
185 # define ADDI_(r0,i0) AGHI(r0,i0)
186 # define ADDC_(r0,r1) ALGR(r0,r1)
187 # define ADDX_(r0,r1) ALCGR(r0,r1)
188 # define AND_(r0,r1) NGR(r0,r1)
189 # define CMP_(r0,r1) CGR(r0,r1)
190 # define CMPU_(r0,r1) CLGR(r0,r1)
191 # define DIVREM_(r0,r1) DSGR(r0,r1)
192 # define DIVREMU_(r0,r1) DLGR(r0,r1)
193 # define MUL_(r0,r1) MSGR(r0,r1)
194 # define MULI_(r0,i0) MGHI(r0,i0)
195 # define MULU_(r0,r1) MLGR(r0,r1)
196 # define OR_(r0,r1) OGR(r0,r1)
197 # define SUB_(r0,r1) SGR(r0,r1)
198 # define SUBC_(r0,r1) SLGR(r0,r1)
199 # define SUBX_(r0,r1) SLBGR(r0,r1)
200 # define TEST_(r0,r1) LTGR(r0,r1)
201 # define XOR_(r0,r1) XGR(r0,r1)
203 /****************************************************************
204 * General Instructions *
205 ****************************************************************/
207 # define AR(R1,R2) RR_(0x1A,R1,R2)
208 # define AGR(R1,R2) RRE_(0xB908,R1,R2)
209 # define AGFR(R1,R2) RRE_(0xB918,R1,R2)
210 # define A(R1,D2,X2,B2) RX_(0x5A,R1,X2,B2,D2)
211 # define AY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x5A)
212 # define AG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x08)
213 # define AGF(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x18)
215 # define AH(R1,D2,X2,B2) RX_(0x4A,R1,X2,B2,D2)
216 # define AHY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x7A)
217 /* ADD HALFWORD IMMEDIATE */
218 # define AHI(R1,I2) RI_(0xA7,R1,0xA,I2)
219 # define AGHI(R1,I2) RI_(0xA7,R1,0xB,I2)
221 # define ALR(R1,R2) RR_(0x1E,R1,R2)
222 # define ALGR(R1,R2) RRE_(0xB90A,R1,R2)
223 # define ALGFR(R1,R2) RRE_(0xB91A,R1,R2)
224 # define AL(R1,D2,X2,B2) RX_(0x5E,R1,X2,B2,D2)
225 # define ALY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x5E)
226 # define ALG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x0A)
227 # define ALGF(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x1A)
228 /* ADD LOGICAL WITH CARRY */
229 # define ALCR(R1,R2) RRE_(0xB998,R1,R2)
230 # define ALCGR(R1,R2) RRE_(0xB988,R1,R2)
231 # define ALC(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x98)
232 # define ALCG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x88)
234 # define NR(R1,R2) RR_(0x14,R1,R2)
235 # define NGR(R1,R2) RRE_(0xB980,R1,R2)
236 # define N(R1,D2,X2,B2) RX_(0x54,R1,X2,B2,D2)
237 # define NY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x54)
238 # define NG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x80)
239 # define NI(D1,B1,I2) SI_(0x94,I2,B1,D1)
240 # define NIY(D1,B1,I2) SIY_(0xEB,I2,B1,D1,0x54)
241 # define NC(D1,L,B1,D2,B2) SSL_(0xD4,L,B1,D1,B2,D2)
243 # define NIHH(R1,I2) RI_(0xA5,R1,0x4,I2)
244 # define NIHL(R1,I2) RI_(0xA5,R1,0x5,I2)
245 # define NILH(R1,I2) RI_(0xA5,R1,0x6,I2)
246 # define NILL(R1,I2) RI_(0xA5,R1,0x7,I2)
247 /* BRANCH AND LINK */
248 # define BALR(R1,R2) RR_(0x05,R1,R2)
249 # define BAL(R1,D2,X2,B2) RX_(0x45,R1,X2,B2,D2)
250 /* BRANCH AND SAVE */
251 # define BASR(R1,R2) RR_(0x0D,R1,R2)
252 # define BAS(R1,D2,X2,B2) RX_(0x4D,R1,X2,B2,D2)
253 /* BRANCH AND SAVE AND SET MODE */
254 # define BASSM(R1,R2) RR_(0x0C,R1,R2)
255 /* BRANCH AND SET MODE */
256 # define BSM(R1,R2) RR_(0x0B,R1,R2)
257 /* BRANCH ON CONDITION */
258 # define BCR(M1,R2) RR_(0x07,M1,R2)
259 # define BR(R2) BCR(CC_AL,R2)
260 # define NOPR(R2) BCR(CC_NV,R2)
261 # define BC(M1,D2,X2,B2) RX_(0x47,M1,X2,B2,D2)
262 /* BRANCH ON COUNT */
263 # define BCTR(R1,R2) RR_(0x06,R1,R2)
264 # define BCTGR(R1,R2) RRE_(0xB946,R1,R2)
265 # define BCT(R1,D2,X2,B2) RX_(0x46,R1,X2,B2,D2)
266 # define BCTG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x46)
267 /* BRANCH ON INDEX HIGH */
268 # define BXH(R1,R3,D2,B2) RS_(0x86,R1,R3,B2,D2)
269 # define BXHG(R1,R3,B2,D2) RSY_(0xEB,R1,R3,B2,D2,0x44)
270 /* BRANCH ON INDEX LOW OR EQUAL */
271 # define BXLE(R1,R3,D2,B2) RS_(0x87,R1,R3,B2,D2)
272 # define BXLEG(R1,R3,B2,D2) RSY_(0xEB,R1,R3,B2,D2,0x45)
273 /* BRANCH RELATIVE AND SAVE */
274 # define BRAS(R1,I2) RI_(0xA7,R1,0x5,I2)
275 /* BRANCH RELATIVE AND SAVE LONG */
276 # define BRASL(R1,I2) RIL_(0xC0,R1,0x5,I2)
277 /* BRANCH RELATIVE ON CONDITION */
278 # define BRC(M1,I2) RI_(0xA7,M1,0x4,I2)
279 # define J(I2) BRC(CC_AL,I2)
280 /* BRANCH RELATIVE ON CONDITION LONG */
281 # define BRCL(M1,I2) RIL_(0xC0,M1,0x4,I2)
282 # define BRL(I2) BRCL(CC_AL,I2)
283 /* BRANCH RELATIVE ON COUNT */
284 # define BRCT(M1,I2) RI_(0xA7,M1,0x6,I2)
285 # define BRCTG(M1,I2) RI_(0xA7,M1,0x7,I2)
286 /* BRANCH RELATIVE ON INDEX HIGH */
287 # define BRXH(R1,R3,I2) RSI_(0x84,R1,R3,I2)
288 # define BRXHG(R1,R3,I2) RIE_(0xEC,R1,R3,I2,0x44)
289 /* BRANCH RELATIVE ON INDEX LOW OR EQUAL */
290 # define BRXLE(R1,R3,I2) RSI_(0x85,R1,R3,I2)
291 # define BRXLEG(R1,R3,I2) RIE_(0xEC,R1,R3,I2,0x45)
293 # define CKSUM(R1,R2) RRE_(0xB241,R1,R2)
294 /* CIPHER MESAGE (KM) */
295 # define KM(R1,R2) RRE_(0xB92E,R1,R2)
296 /* CIPHER MESAGE WITH CHAINING (KMC) */
297 # define KMC(R1,R2) RRE_(0xB92F,R1,R2)
299 # define CR(R1,R2) RR_(0x19,R1,R2)
300 # define CGR(R1,R2) RRE_(0xB920,R1,R2)
301 # define CGFR(R1,R2) RRE_(0xB930,R1,R2)
302 # define C(R1,D2,X2,B2) RX_(0x59,R1,X2,B2,D2)
303 # define CY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x59)
304 # define CG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x20)
305 # define CGF(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x30)
306 /* COMPARE AND FORM CODEWORD */
307 # define CFC(D2,B2) S_(0xB21A,B2,D2)
308 /* COMPARE AND SWAP */
309 # define CS(R1,R3,D2,B2) RS_(0xBA,R1,R3,B2,D2)
310 # define CSY(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x14)
311 # define CSG(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x30)
312 /* COMPARE DOUBLE AND SWAP */
313 # define CDS(R1,R3,D2,B2) RS_(0xBB,R1,R3,B2,D2)
314 # define CSDY(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x31)
315 # define CSDG(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x3E)
316 /* COMPARE HALFWORD */
317 # define CH(R1,D2,X2,B2) RX_(0x49,R1,X2,B2,D2)
318 # define CHY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x79)
319 /* COMPARE HALFWORD IMMEDIATE */
320 # define CHI(R1,I2) RI_(0xA7,R1,0xE,I2)
321 # define CGHI(R1,I2) RI_(0xA7,R1,0xF,I2)
322 /* COMPARE LOGICAL */
323 # define CLR(R1,R2) RR_(0x15,R1,R2)
324 # define CLGR(R1,R2) RRE_(0xB921,R1,R2)
325 # define CLGFR(R1,R2) RRE_(0xB931,R1,R2)
326 # define CL(R1,D2,X2,B2) RX_(0x55,R1,X2,B2,D2)
327 # define CLY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x55)
328 # define CLG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x21)
329 # define CLGF(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x31)
330 # define CLI(D1,B1,I2) SI_(0x95,I2,B1,D1)
331 # define CLIY(D1,B1,I2) SIY_(0xEB,I2,B1,D1,0x55)
332 # define CLC(D1,L,B1,D2,B2) SSL_(0xD5,L,B1,D1,B2,D2)
333 /* COMPARE LOGICAL CHARACTERS UNDER MASK */
334 # define CLM(R1,M3,D2,B2) RS_(0xBD,R1,M3,B2,D2)
335 # define CLMY(R1,M3,D2,B2) RSY_(0xEB,R1,M3,B2,D2,0x21)
336 # define CLMH(R1,M3,D2,B2) RSY_(0xEB,R1,M3,B2,D2,0x20)
337 /* COMPARE LOGICAL LONG */
338 # define CLCL(R1,R2) RR_(0x0F,R1,R2)
339 /* COMPARE LOGICAL LONG EXTENDED */
340 # define CLCLE(R1,R3,D2,B2) RS_(0xA9,R1,R3,B2,D2)
341 /* COMPARE LOGICAL LONG UNICODE */
342 # define CLCLU(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x8F)
343 /* COMPARE LOGICAL STRING */
344 # define CLST(R1,R2) RRE_(0xB25D,R1,R2)
345 /* COMPARE UNTIL SUBSTRING EQUAL */
346 # define CUSE(R1,R2) RRE_(0xB257,R1,R2)
347 /* COMPRESSION CALL */
348 # define CMPSC(R1,R2) RRE_(0xB263,R1,R2)
349 /* COMPUTE INTERMEDIATE MESSAGE DIGEST (KIMD) */
350 # define KIMD(R1,R2) RRE_(0xB93E,R1,R2)
351 /* COMPUTE LAST MESSAGE DIGEST (KIMD) */
352 # define KLMD(R1,R2) RRE_(0xB93F,R1,R2)
353 /* COMPUTE MESSAGE AUTHENTICATION CODE (KMAC) */
354 # define KMAC(R1,R2) RRE_(0xB91E,R1,R2)
355 /* CONVERT TO BINARY */
356 # define CVB(R1,D2,X2,B2) RX_(0x4F,R1,X2,B2,D2)
357 # define CVBY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x06)
358 # define CVBG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x0e)
359 /* CONVERT TO DECIMAL */
360 # define CVD(R1,D2,X2,B2) RX_(0x4E,R1,X2,B2,D2)
361 # define CVDY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x26)
362 # define CVDG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x2E)
363 /* CONVERT UNICODE TO UTF-8 */
364 # define CUUTF(R1,R2) RRE_(0xB2A6,R1,R2)
365 /* CONVERT UTF-8 TO UNICODE */
366 # define CUTFU(R1,R2) RRE_(0xB2A7,R1,R2)
368 # define CPYA(R1,R2) RRE_(0xB24D,R1,R2)
370 # define DR(R1,R2) RR_(0x1D,R1,R2)
371 # define D(R1,D2,X2,B2) RX_(0x5D,R1,X2,B2,D2)
373 # define DLR(R1,R2) RRE_(0xB997,R1,R2)
374 # define DLGR(R1,R2) RRE_(0xB987,R1,R2)
375 # define DL(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x97)
376 # define DLG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x87)
378 # define DSGR(R1,R2) RRE_(0xB90D,R1,R2)
379 # define DSGFR(R1,R2) RRE_(0xB91D,R1,R2)
380 # define DSG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x0D)
381 # define DSGF(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x1D)
383 # define XR(R1,R2) RR_(0x17,R1,R2)
384 # define XGR(R1,R2) RRE_(0xB982,R1,R2)
385 # define X(R1,D2,X2,B2) RX_(0x57,R1,X2,B2,D2)
386 # define XY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x57)
387 # define XG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x82)
388 # define XI(D1,B1,I2) SI_(0x97,I2,B1,D1)
389 # define XIY(D1,B1,I2) SIY_(0xEB,I2,B1,D1,0x57)
390 # define XC(D1,L,B1,D2,B2) SSL_(0xD7,L,B1,D1,B2,D2)
392 # define EX(R1,D2,X2,B2) RX_(0x44,R1,X2,B2,D2)
394 # define EAR(R1,R2) RRE_(0xB24F,R1,R2)
396 # define EPSW(R1,R2) RRE_(0xB98D,R1,R2)
397 /* FIND LEFTMOST ONE */
398 # define FLOGR(R1,R2) RRE_(0xB983,R1,R2)
399 /* INSERT CHARACTER */
400 # define IC(R1,D2,X2,B2) RX_(0x43,R1,X2,B2,D2)
401 # define ICY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x73)
402 /* INSERT CHARACTERS UNDER MASK */
403 # define ICM(R1,M3,D2,B2) RS_(0xBF,R1,M3,B2,D2)
404 # define ICMY(R1,M3,D2,B2) RSY_(0xEB,R1,M3,B2,D2,0x81)
405 # define ICMH(R1,M3,D2,B2) RSY_(0xEB,R1,M3,B2,D2,0x80)
406 /* INSERT IMMEDIATE */
407 # define IIHH(R1,I2) RI_(0xA5,R1,0x0,I2)
408 # define IIHL(R1,I2) RI_(0xA5,R1,0x1,I2)
409 # define IILH(R1,I2) RI_(0xA5,R1,0x2,I2)
410 # define IILL(R1,I2) RI_(0xA5,R1,0x3,I2)
411 /* INSERT PROGRAM MASK */
412 # define IPM(R1) RRE_(0xB222,R1,0)
414 # define LR(R1,R2) RR_(0x18,R1,R2)
415 # define LGR(R1,R2) RRE_(0xB904,R1,R2)
416 # define LGFR(R1,R2) RRE_(0xB914,R1,R2)
417 # define L(R1,D2,X2,B2) RX_(0x58,R1,X2,B2,D2)
418 # define LY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x58)
419 # define LG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x04)
420 # define LGF(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x14)
421 /* LOAD ACCESS MULTIPLE */
422 # define LAM(R1,R3,D2,B2) RS_(0x9A,R1,R3,B2,D2)
423 # define LAMY(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x9A)
425 # define LA(R1,D2,X2,B2) RX_(0x41,R1,X2,B2,D2)
426 # define LAY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x71)
427 /* LOAD ADDRESS EXTENDED */
428 # define LAE(R1,D2,X2,B2) RX_(0x51,R1,X2,B2,D2)
429 /* LOAD ADDRESS RELATIVE LONG */
430 # define LARL(R1,I2) RIL_(0xC0,R1,0x0,I2)
432 # define LTR(R1,R2) RR_(0x12,R1,R2)
433 # define LTGR(R1,R2) RRE_(0xB902,R1,R2)
434 # define LTGFR(R1,R2) RRE_(0xB912,R1,R2)
436 # define LGBR(R1,R2) RRE_(0xB906,R1,R2) /* disasm */
437 # define LB(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x76)
438 # define LGB(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x77)
439 /* LOAD COMPLEMENT */
440 # define LCR(R1,R2) RR_(0x13,R1,R2)
441 # define LCGR(R1,R2) RRE_(0xB903,R1,R2)
442 # define LCGFR(R1,R2) RRE_(0xB913,R1,R2)
444 # define LH(R1,D2,X2,B2) RX_(0x48,R1,X2,B2,D2)
445 # define LHY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x78)
446 # define LGHR(R1,R2) RRE_(0xB907,R1,R2) /* disasm */
447 # define LGH(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x15)
448 /* LOAD HALFWORD IMMEDIATE */
449 # define LHI(R1,I2) RI_(0xA7,R1,0x8,I2)
450 # define LGHI(R1,I2) RI_(0xA7,R1,0x9,I2)
452 # define LLGFR(R1,R2) RRE_(0xB916,R1,R2)
453 # define LLGF(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x16)
454 /* LOAD LOGICAL CHARACTER */
455 # define LLGCR(R1,R2) RRE_(0xB984,R1,R2) /* disasm */
456 # define LLGC(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x90)
457 /* LOAD LOGICAL HALFWORD */
458 # define LLGHR(R1,R2) RRE_(0xB985,R1,R2) /* disasm */
459 # define LLGH(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x91)
460 /* LOAD LOGICAL IMMEDIATE */
461 # define LLIHH(R1,I2) RI_(0xA5,R1,0xC,I2)
462 # define LLIHL(R1,I2) RI_(0xA5,R1,0xD,I2)
463 # define LLILH(R1,I2) RI_(0xA5,R1,0xE,I2)
464 # define LLILL(R1,I2) RI_(0xA5,R1,0xF,I2)
465 /* LOAD LOGICAL THIRTY ONE BITS */
466 # define LLGTR(R1,R2) RRE_(0xB917,R1,R2)
467 # define LLGT(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x17)
469 # define LM(R1,R3,D2,B2) RS_(0x98,R1,R3,B2,D2)
470 # define LMY(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x98)
471 # define LMG(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x04)
472 /* LOAD MULTIPLE DISJOINT */
473 # define LMD(R1,R3,D2,B2,D4,B4) SS_(0xEF,R1,R3,B2,D2,B4,D4)
474 /* LOAD MULTIPLE HIGH */
475 # define LMH(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x96)
477 # define LNR(R1,R2) RR_(0x11,R1,R2)
478 # define LNGR(R1,R2) RRE_(0xB901,R1,R2)
479 # define LNGFR(R1,R2) RRE_(0xB911,R1,R2)
480 /* LOAD PAIR FROM QUADWORD */
481 # define LPQ(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x8F)
483 # define LPR(R1,R2) RR_(0x10,R1,R2)
484 # define LPGR(R1,R2) RRE_(0xB900,R1,R2)
485 # define LPGFR(R1,R2) RRE_(0xB910,R1,R2)
487 # define LRVR(R1,R2) RRE_(0xB91F,R1,R2)
488 # define LRVGR(R1,R2) RRE_(0xB90F,R1,R2)
489 # define LRVH(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x1F)
490 # define LRV(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x1E)
491 # define LRVG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x0F)
493 # define MC(D1,B1,I2) SI_(0xAF,I2,B1,D1)
495 # define MVI(D1,B1,I2) SI_(0x92,I2,B1,D1)
496 # define MVIY(D1,B1,I2) SIY_(0xEB,I2,B1,D1,0x52)
497 # define MVC(D1,L,B1,D2,B2) SSL_(0xD2,L,B1,D1,B2,D2)
499 # define MVCIN(D1,L,B1,D2,B2) SSL_(0xE8,L,B1,D1,B2,D2)
501 # define MVCL(R1,R2) RR_(0x0E,R1,R2)
502 /* MOVE LONG EXTENDED */
503 # define MVCLE(R1,R3,D2,B2) RS_(0xA8,R1,R3,B2,D2)
504 /* MOVE LONG UNICODE */
505 # define MVCLU(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x8E)
507 # define MVN(D1,L,B1,D2,B2) SSL_(0xD1,L,B1,D1,B2,D2)
509 # define MVST(R1,R2) RRE_(0xB255,R1,R2)
510 /* MOVE WITH OFFSET */
511 # define MVO(D1,L1,B1,D2,L2,B2) SS_(0xF1,L1,L2,B1,D1,B2,D2)
513 # define MVZ(D1,L,B1,D2,B2) SSL_(0xD3,L,B1,D1,B2,D2)
515 # define MR(R1,R2) RR_(0x1C,R1,R2)
516 # define M(R1,D2,X2,B2) RX_(0x5C,R1,X2,B2,D2)
517 /* MULTIPLY HALFWORD */
518 # define MH(R1,D2,X2,B2) RX_(0x4C,R1,X2,B2,D2)
519 /* MULTIPLY HALFWORD IMMEDIATE */
520 # define MHI(R1,I2) RI_(0xA7,R1,0xC,I2)
521 # define MGHI(R1,I2) RI_(0xA7,R1,0xD,I2)
522 /* MULTIPLY LOGICAL */
523 # define MLR(R1,R2) RRE_(0xB996,R1,R2)
524 # define MLGR(R1,R2) RRE_(0xB986,R1,R2)
525 # define ML(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x96)
526 # define MLG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x86)
527 /* MULTIPLY SINGLE */
528 # define MSR(R1,R2) RRE_(0xB252,R1,R2)
529 # define MSGR(R1,R2) RRE_(0xB90C,R1,R2)
530 # define MSGFR(R1,R2) RRE_(0xB91C,R1,R2)
531 # define MS(R1,D2,X2,B2) RX_(0x71,R1,X2,B2,D2)
532 # define MSY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x51)
533 # define MSG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x0C)
534 # define MSGF(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x1C)
536 # define OR(R1,R2) RR_(0x16,R1,R2)
537 # define OGR(R1,R2) RRE_(0xB981,R1,R2)
538 # define O(R1,D2,X2,B2) RX_(0x56,R1,X2,B2,D2)
539 # define OY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x56)
540 # define OG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x81)
541 # define OI(D1,B1,I2) SI_(0x96,I2,B1,D1)
542 # define OIY(D1,B1,I2) SIY_(0xEB,I2,B1,D1,0x56)
543 # define OC(D1,L,B1,D2,B2) SSL_(0xD6,L,B1,D1,B2,D2)
545 # define OIHH(R1,I2) RI_(0xA5,R1,0x8,I2)
546 # define OIHL(R1,I2) RI_(0xA5,R1,0x9,I2)
547 # define OILH(R1,I2) RI_(0xA5,R1,0xA,I2)
548 # define OILL(R1,I2) RI_(0xA5,R1,0xB,I2)
550 # define PACK(D1,L1,B1,D2,L2,B2) SS_(0xF2,L1,L2,B1,D1,B2,D2)
552 # define PKA(D1,B1,D2,L2,B2) SSL_(0xE9,L2,B1,D1,B2,D2)
554 # define PKU(D1,B1,D2,L2,B2) SSL_(0xE1,L2,B1,D1,B2,D2)
555 /* PERFORM LOCKED OPERATION */
556 # define PLO(R1,D2,B2,R3,D4,B4) SS_(0xEE,R1,R3,B2,D2,B4,D4)
557 /* ROTATE LEFT SINGLE LOGICAL */
558 # define RLL(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x1D)
559 # define RLLG(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x1C)
561 # define SRST(R1,R2) RRE_(0xB25E,R1,R2)
563 # define SAR(R1,R2) RRE_(0xB24E,R1,R2)
564 /* SET ADDRESSING MODE */
565 # define SAM24() E_(0x10C)
566 # define SAM31() E_(0x10D)
567 # define SAM64() E_(0x10E)
568 /* SET PROGRAM MASK */
569 # define SPM(R1) RR_(0x04,R1,0)
570 /* SHIFT LEFT DOUBLE */
571 # define SLDA(R1,D2,B2) RS_(0x8F,R1,0,B2,D2)
572 /* SHIFT LEFT DOUBLE LOGICAL */
573 # define SLDL(R1,D2,B2) RS_(0x8D,R1,0,B2,D2)
574 /* SHIFT LEFT SINGLE */
575 # define SLA(R1,D2,B2) RS_(0x8B,R1,0,B2,D2)
576 # define SLAG(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x0B)
577 /* SHIFT LEFT SINGLE LOGICAL */
578 # define SLL(R1,D2,B2) RS_(0x89,R1,0,B2,D2)
579 # define SLLG(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x0D)
580 /* SHIFT RIGHT DOUBLE */
581 # define SRDA(R1,D2,B2) RS_(0x8E,R1,0,B2,D2)
582 /* SHIFT RIGHT DOUBLE LOGICAL */
583 # define SRDL(R1,D2,B2) RS_(0x8C,R1,0,B2,D2)
584 /* SHIFT RIGHT SINGLE */
585 # define SRA(R1,D2,B2) RS_(0x8A,R1,0,B2,D2)
586 # define SRAG(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x0A)
587 /* SHIFT RIGHT SINGLE LOGICAL */
588 # define SRL(R1,D2,B2) RS_(0x88,R1,0,B2,D2)
589 # define SRLG(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x0C)
591 # define ST(R1,D2,X2,B2) RX_(0x50,R1,X2,B2,D2)
592 # define STY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x50)
593 # define STG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x24)
594 /* STORE ACCESS MULTIPLE */
595 # define STAM(R1,R3,D2,B2) RS_(0x9B,R1,R3,B2,D2)
596 # define STAMY(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x9B)
597 /* STORE CHARACTER */
598 # define STC(R1,D2,X2,B2) RX_(0x42,R1,X2,B2,D2)
599 # define STCY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x72)
600 /* STORE CHARACTERS UNDER MASK */
601 # define STCM(R1,M3,D2,B2) RS_(0xBE,R1,M3,B2,D2)
602 # define STCMY(R1,M3,D2,B2) RSY_(0xEB,R1,M3,B2,D2,0x2D)
603 # define STCMH(R1,M3,D2,B2) RSY_(0xEB,R1,M3,B2,D2,0x2C)
605 # define STCK(D2,B2) S_(0xB205,B2,D2)
606 /* STORE CLOCK EXTENDED */
607 # define STCKE(D2,B2) S_(0xB278,B2,D2)
609 # define STH(R1,D2,X2,B2) RX_(0x40,R1,X2,B2,D2)
610 # define STHY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x70)
612 # define STM(R1,R3,D2,B2) RS_(0x90,R1,R3,B2,D2)
613 # define STMY(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x90)
614 # define STMG(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x24)
615 /* STORE MULTIPLE HIGH */
616 # define STMH(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x26)
617 /* STORE PAIR TO QUADWORD */
618 # define STPQ(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x8E)
620 # define STRVH(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x3F)
621 # define STRV(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x3E)
622 # define STRVG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x2F)
624 # define SR(R1,R2) RR_(0x1B,R1,R2)
625 # define SGR(R1,R2) RRE_(0xB909,R1,R2)
626 # define SGFR(R1,R2) RRE_(0xB919,R1,R2)
627 # define S(R1,D2,X2,B2) RX_(0x5B,R1,X2,B2,D2)
628 # define SY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x5B)
629 # define SG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x09)
630 # define SGF(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x19)
631 /* SUBTRACT HALFWORD */
632 # define SH(R1,D2,X2,B2) RX_(0x4B,R1,X2,B2,D2)
633 # define SHY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x7B)
634 /* SUBTRACT LOGICAL */
635 # define SLR(R1,R2) RR_(0x1F,R1,R2)
636 # define SLGR(R1,R2) RRE_(0xB90B,R1,R2)
637 # define SLGFR(R1,R2) RRE_(0xB91B,R1,R2)
638 # define SL(R1,D2,X2,B2) RX_(0x5F,R1,X2,B2,D2)
639 # define SLY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x5F)
640 # define SLG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x0B)
641 # define SLGF(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x1B)
642 /* SUBTRACT LOGICAL WITH BORROW */
643 # define SLBR(R1,R2) RRE_(0xB999,R1,R2)
644 # define SLBGR(R1,R2) RRE_(0xB989,R1,R2)
645 # define SLB(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x99)
646 # define SLBG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x89)
647 /* SUPERVISOR CALL */
648 # define SVC(I) I_(0xA,I)
649 /* TEST ADDRESSING MODE */
650 # define TAM() E_(0x10B)
652 # define TS(D2,B2) RS_(0x93,0,0,B2,D2)
653 /* TEST UNDER MASK (TEST UNDER MASK HIGH, TEST UNDER MASK LOW) */
654 # define TM(D1,B1,I2) SI_(0x91,I2,B1,D1)
655 # define TMY(D1,B1,I2) SIY_(0xEB,I2,B1,D1,0x51)
656 # define TMHH(R1,I2) RI_(0xA7,R1,0x2,I2)
657 # define TMHL(R1,I2) RI_(0xA7,R1,0x3,I2)
658 # define TMLH(R1,I2) RI_(0xA7,R1,0x0,I2)
659 # define TMH(R1,I2) TMLH(R1,I2)
660 # define TMLL(R1,I2) RI_(0xA7,R1,0x1,I2)
661 # define TML(R1,I2) TMLL(R1,I2)
663 # define TR(D1,L,B1,D2,B2) SSL_(0xDC,L,B1,D1,B2,D2)
664 /* TRANSLATE AND TEST */
665 # define TRT(D1,L,B1,D2,B2) SSL_(0xDD,L,B1,D1,B2,D2)
666 /* TRANSLATE EXTENDED */
667 # define TRE(R1,R2) RRE_(0xB2A5,R1,R2)
668 /* TRANSLATE ONE TO ONE */
669 # define TROO(R1,R2) RRE_(0xB993,R1,R2)
670 /* TRANSLATE ONE TO TWO */
671 # define TROT(R1,R2) RRE_(0xB992,R1,R2)
672 /* TRANSLATE TWO TO ONE */
673 # define TRTO(R1,R2) RRE_(0xB991,R1,R2)
674 /* TRANSLATE TWO TO TWO */
675 # define TRTT(R1,R2) RRE_(0xB990,R1,R2)
677 # define UNPK(D1,L1,B1,D2,L2,B2) SS_(0xF3,L1,L2,B1,D1,B2,D2)
679 # define UNPKA(D1,L1,B1,D2,L2,B2) SS_(0xEA,L1,L2,B1,D1,B2,D2)
681 # define UNPKU(D1,L1,B1,D2,L2,B2) SS_(0xE2,L1,L2,B1,D1,B2,D2)
683 # define UPT() E_(0x0102)
684 /****************************************************************
685 * Decimal Instructions *
686 ****************************************************************/
688 # define AP(D1,L1,B1,D2,L2,B2) SS_(0xFA,L1,L2,B1,D1,B2,D2)
689 /* COMPARE DECIMAL */
690 # define CP(D1,L1,B1,D2,L2,B2) SS_(0xF9,L1,L2,B1,D1,B2,D2)
692 # define DP(D1,L1,B1,D2,L2,B2) SS_(0xFD,L1,L2,B1,D1,B2,D2)
694 # define ED(D1,L,B1,D2,B2) SSL_(0xDE,L,B1,D1,B2,D2)
696 # define EDMK(D1,L,B1,D2,B2) SSL_(0xDE,L,B1,D1,B2,D2)
697 /* MULTIPLY DECIMAL */
698 # define MP(D1,L1,B1,D2,L2,B2) SS_(0xFC,L1,L2,B1,D1,B2,D2)
699 /* SHIFT AND ROUND DECIMAL */
700 # define SRP(D1,L1,B1,D2,L2,B2) SS_(0xF0,L1,L2,B1,D1,B2,D2)
701 /* SUBTRACE DECIMAL */
702 # define SP(D1,L1,B1,D2,L2,B2) SS_(0xFB,L1,L2,B1,D1,B2,D2)
704 # define TP(D1,L1,B1) RSL_(0xEB,L1,B1,D1,0xC0)
706 # define ZAP(D1,L1,B1,D2,L2,B2) SS_(0xF8,L1,L2,B1,D1,B2,D2)
707 /****************************************************************
708 * Control Instructions *
709 ****************************************************************/
710 /* BRANCH AND SET AUTHORITY */
711 # define BSA(R1,R2) RRE_(0xB25A,R1,R2)
712 /* BRANCH AND STACK */
713 # define BAKR(R1,R2) RRE_(0xB240,R1,R2)
714 /* BRANCH IN SUBSPACE GROUP */
715 # define BSG(R1,R2) RRE_(0xB258,R1,R2)
716 /* COMPARE AND SWAP AND PURGE */
717 # define CSP(R1,R2) RRE_(0xB250,R1,R2)
718 # define CSPG(R1,R2) RRE_(0xB98A,R1,R2)
720 # define DIAG() SI_(0x83,0,0,0)
721 /* EXTRACT AND SET EXTENDED AUTHORITY */
722 # define ESEA(R1) RRE_(0xB99D,R1,0)
723 /* EXTRACT PRIMARY ASN */
724 # define EPAR(R1) RRE_(0xB226,R1,0)
725 /* EXTRACT SECONDARY ASN */
726 # define ESAR(R1) RRE_(0xB227,R1,0)
727 /* EXTRACT STACKED REGISTERS */
728 # define EREG(R1,R2) RRE_(0xB249,R1,R2)
729 # define EREGG(R1,R2) RRE_(0xB90E,R1,R2)
730 /* EXTRACT STACKED STATE */
731 # define ESTA(R1,R2) RRE_(0xB24A,R1,R2)
732 /* INSERT ADDRESS SPACE CONTROL */
733 # define IAC(R1) RRE_(0xB224,R1,0)
735 # define IPK() S_(0xB20B,0,0)
736 /* INSERT STORAGE KEY EXTENDED */
737 # define ISKE(R1,R2) RRE_(0xB229,R1,R2)
738 /* INSERT VIRTUAL STORAGE KEY */
739 # define IVSK(R1,R2) RRE_(0xB223,R1,R2)
740 /* INVALIDATE DAT TABLE ENTRY */
741 # define IDTE(R1,R2,R3) RRF_(0xB98E,R3,0,R1,R2)
742 /* INVALIDATE PAGE TABLE ENTRY */
743 # define IPTE(R1,R2) RRE_(0xB221,R1,R2)
744 /* LOAD ADDRESS SPACE PARAMETER */
745 # define LASP(D1,B1,D2,B2) SSE_(0xE500,B1,D1,B2,D2)
747 # define LCTL(R1,R3,D2,B2) RS_(0xB7,R1,R3,B2,D2)
748 # define LCTLG(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x2F)
750 # define LPSW(D2,B2) SI_(0x82,0,B2,D2)
751 /* LOAD PSW EXTENDED */
752 # define LPSWE(D2,B2) S_(0xB2B2,B2,D2)
753 /* LOAD REAL ADDRESS */
754 # define LRA(R1,D2,X2,B2) RX_(0xB1,R1,X2,B2,D2)
755 # define LRAY(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x13)
756 # define LRAG(R1,D2,X2,B2) RXY_(0xE3,R1,X2,B2,D2,0x03)
757 /* LOAD USING REAL ADDRESS */
758 # define LURA(R1,R2) RRE_(0xB24B,R1,R2)
759 # define LURAG(R1,R2) RRE_(0xB905,R1,R2)
760 /* MODIFY STACKED STATE */
761 # define MSTA(R1) RRE_(0xB247,R1,0)
763 # define MVPG(R1,R2) RRE_(0xB254,R1,R2)
764 /* MOVE TO PRIMARY */
765 # define MVCP(D1,R1,B1,D2,B2,R3) SS_(0xDA,R1,R3,B1,D1,B2,D2)
766 /* MOVE TO SECONDARY */
767 # define MVCS(D1,R1,B1,D2,B2,R3) SS_(0xDB,R1,R3,B1,D1,B2,D2)
768 /* MOVE WITH DESTINATION KEY */
769 # define MVCDK(D1,B1,D2,B2) SSE_(0xE50F,B1,D1,B2,D2)
771 # define MVCK(D1,R1,B1,D2,B2,R3) SS_(0xD9,R1,R3,B1,D1,B2,D2)
772 /* MOVE WITH SOURCE KEY */
773 # define MVCSK(D1,B1,D2,B2) SSE_(0xE50E,B1,D1,B2,D2)
775 # define PGIN(R1,R2) RRE_(0xB22E,R1,R2)
777 # define PGOUT(R1,R2) RRE_(0xB22F,R1,R2)
779 # define PC(D2,B2) S_(0xB218,B2,D2)
781 # define PR() E_(0x0101)
782 /* PROGRAM TRANSFER */
783 # define PT(R1,R2) RRE_(0xB228,R1,R2)
785 # define PALB() RRE_(0xB248,0,0)
787 # define PTLB() S_(0xB20D,0,0)
788 /* RESET REFERENCE BIT EXTENDED */
789 # define RRBE(R1,R2) RRE_(0xB22A,R1,R2)
791 # define RP(D2,B2) S_(0xB277,B2,D2)
792 /* SET ADDRESS SPACE CONTROL */
793 # define SAC(D2,B2) S_(0xB219,B2,D2)
794 /* SET ADDRESS SPACE CONTROL FAST */
795 # define SACF(D2,B2) S_(0xB279,B2,D2)
797 # define SCK(D2,B2) S_(0xB204,B2,D2)
798 /* SET CLOCK COMPARATOR */
799 # define SCKC(D2,B2) S_(0xB206,B2,D2)
800 /* SET CLOCK PROGRAMMABLE FIELD */
801 # define SCKPF() E_(0x0107)
803 # define SPT(D2,B2) S_(0xB208,B2,D2)
805 # define SPX(D2,B2) S_(0xB210,B2,D2)
806 /* SET PSW FROM ADDRESS */
807 # define SPKA(D2,B2) S_(0xB20A,B2,D2)
808 /* SET SECONDARY ASN */
809 # define SSAR(R1) RRE_(0xB225,R1,0)
810 /* SET STORAGE KEY EXTENDED */
811 # define SSKE(R1,R2) RRE_(0xB22B,R1,R2)
812 /* SET SYSTEM MASK */
813 # define SSM(D2,B2) SI_(0x80,0,B2,D2)
814 /* SIGNAL PROCESSOR */
815 # define SIGP(R1,R3,D2,B2) RS_(0xAE,R1,R3,B2,D2)
816 /* STORE CLOCK COMPARATOR */
817 # define STCKC(D2,B2) S_(0xB207,B2,D2)
819 # define STCTL(R1,R3,D2,B2) RS_(0xB6,R1,R3,B2,D2)
820 # define STCTG(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x25)
821 /* STORE CPU ADDRESS */
822 # define STAP(D2,B2) S_(0xB212,B2,D2)
824 # define STIDP(D2,B2) S_(0xB202,B2,D2)
825 /* STORE CPU TIMER */
826 # define STPT(D2,B2) S_(0xB209,B2,D2)
827 /* STORE FACILITY LIST */
828 # define STFL(D2,B2) S_(0xB2B1,B2,D2)
830 # define STPX(D2,B2) S_(0xB211,B2,D2)
831 /* STORE REAL ADDRES */
832 # define STRAG(D1,B1,D2,B2) SSE_(0xE502,B1,D1,B2,D2)
833 /* STORE SYSTEM INFORMATION */
834 # define STSI(D2,B2) S_(0xB27D,B2,D2)
835 /* STORE THEN AND SYSTEM MASK */
836 # define STNSM(D1,B1,I2) SI_(0xAC,I2,B1,D1)
837 /* STORE THEN OR SYSTEM MASK */
838 # define STOSM(D1,B1,I2) SI_(0xAD,I2,B1,D1)
839 /* STORE USING REAL ADDRESS */
840 # define STURA(R1,R2) RRE_(0xB246,R1,R2)
841 # define STURG(R1,R2) RRE_(0xB925,R1,R2)
843 # define TAR(R1,R2) RRE_(0xB24C,R1,R2)
845 # define TB(R1,R2) RRE_(0xB22C,R1,R2)
846 /* TEST PROTECTION */
847 # define TPROT(D1,B1,D2,B2) SSE_(0xE501,B1,D1,B2,D2)
849 # define TRACE(R1,R3,D2,B2) RS_(0x99,R1,R3,B2,D2)
850 # define TRACG(R1,R3,D2,B2) RSY_(0xEB,R1,R3,B2,D2,0x0F)
852 # define TRAP2() E_(0x01FF)
853 # define TRAP4(D2,B2) S_(0xB2FF,B2,D2)
854 /****************************************************************
856 ****************************************************************/
857 /* CANCEL SUBCHANNEL */
858 # define XSCH() S_(0xB276,0,0)
859 /* CLEAR SUBCHANNEL */
860 # define CSCH() S_(0xB230,0,0)
861 /* HALT SUBCHANNEL */
862 # define HSCH() S_(0xB231,0,0)
863 /* MODIFY SUBCHANNEL */
864 # define MSCH(D2,B2) S_(0xB232,B2,D2)
865 /* RESET CHANNEL PATH */
866 # define RCHP() S_(0xB23B,0,0)
867 /* RESUME SUBCHANNEL */
868 # define RSCH() S_(0xB238,0,0)
869 /* SET ADDRESS LIMIT */
870 # define SAL() S_(0xB237,0,0)
871 /* SET CHANNEL MONITOR */
872 # define SCHM() S_(0xB23C,0,0)
873 /* START SUBCHANNEL */
874 # define SSCH(D2,B2) S_(0xB233,B2,D2)
875 /* STORE CHANNEL PATH STATUS */
876 # define STCPS(D2,B2) S_(0xB23A,B2,D2)
877 /* STORE CHANNEL REPORT WORD */
878 # define STCRW(D2,B2) S_(0xB239,B2,D2)
879 /* STORE SUBCHANNEL */
880 # define STSCH(D2,B2) S_(0xB234,B2,D2)
881 /* TEST PENDING INTERRUPTION */
882 # define TPI(D2,B2) S_(0xB236,B2,D2)
883 /* TEST SUBCHANNEL */
884 # define TSCH(D2,B2) S_(0xB235,B2,D2)
885 # define xdivr(r0,r1) _xdivr(_jit,r0,r1)
886 static jit_int32_t _xdivr(jit_state_t*,jit_int32_t,jit_int32_t);
887 # define xdivr_u(r0,r1) _xdivr_u(_jit,r0,r1)
888 static jit_int32_t _xdivr_u(jit_state_t*,jit_int32_t,jit_int32_t);
889 # define xdivi(r0,i0) _xdivi(_jit,r0,i0)
890 static jit_int32_t _xdivi(jit_state_t*,jit_int32_t,jit_word_t);
891 # define xdivi_u(r0,i0) _xdivi_u(_jit,r0,i0)
892 static jit_int32_t _xdivi_u(jit_state_t*,jit_int32_t,jit_word_t);
893 # define crr(cc,r0,r1,r2) _crr(_jit,cc,r0,r1,r2)
894 static void _crr(jit_state_t*,
895 jit_int32_t,jit_int32_t,jit_int32_t,jit_int32_t);
896 # define cri(cc,r0,r1,i0) _cri(_jit,cc,r0,r1,i0)
897 static void _cri(jit_state_t*,
898 jit_int32_t,jit_int32_t,jit_int32_t,jit_word_t);
899 # define crr_u(cc,r0,r1,r2) _crr_u(_jit,cc,r0,r1,r2)
900 static void _crr_u(jit_state_t*,
901 jit_int32_t,jit_int32_t,jit_int32_t,jit_int32_t);
902 # define cri_u(cc,r0,r1,i0) _cri_u(_jit,cc,r0,r1,i0)
903 static void _cri_u(jit_state_t*,
904 jit_int32_t,jit_int32_t,jit_int32_t,jit_word_t);
905 # define brr(cc,i0,r0,r1) _brr(_jit,cc,i0,r0,r1)
906 static void _brr(jit_state_t*,jit_int32_t,
907 jit_word_t,jit_int32_t,jit_int32_t);
908 # define brr_p(cc,i0,r0,r1) _brr_p(_jit,cc,i0,r0,r1)
909 static jit_word_t _brr_p(jit_state_t*,jit_int32_t,
910 jit_word_t,jit_int32_t,jit_int32_t);
911 # define bri(cc,i0,r0,i1) _bri(_jit,cc,i0,r0,i1)
912 static void _bri(jit_state_t*,jit_int32_t,
913 jit_word_t,jit_int32_t,jit_word_t);
914 # define bri_p(cc,i0,r0,i1) _bri_p(_jit,cc,i0,r0,i1)
915 static jit_word_t _bri_p(jit_state_t*,jit_int32_t,
916 jit_word_t,jit_int32_t,jit_word_t);
917 # define brr_u(cc,i0,r0,r1) _brr_u(_jit,cc,i0,r0,r1)
918 static void _brr_u(jit_state_t*,jit_int32_t,
919 jit_word_t,jit_int32_t,jit_int32_t);
920 # define brr_u_p(cc,i0,r0,r1) _brr_u_p(_jit,cc,i0,r0,r1)
921 static jit_word_t _brr_u_p(jit_state_t*,jit_int32_t,
922 jit_word_t,jit_int32_t,jit_int32_t);
923 # define bri_u(cc,i0,r0,i1) _bri_u(_jit,cc,i0,r0,i1)
924 static void _bri_u(jit_state_t*,jit_int32_t,
925 jit_word_t,jit_int32_t,jit_word_t);
926 # define bri_u_p(cc,i0,r0,i1) _bri_u_p(_jit,cc,i0,r0,i1)
927 static jit_word_t _bri_u_p(jit_state_t*,jit_int32_t,
928 jit_word_t,jit_int32_t,jit_word_t);
929 # define baddr(c,s,i0,r0,r1) _baddr(_jit,c,s,i0,r0,r1)
930 static void _baddr(jit_state_t*,jit_int32_t,jit_bool_t,
931 jit_word_t,jit_int32_t,jit_int32_t);
932 # define baddr_p(c,s,i0,r0,r1) _baddr_p(_jit,c,s,i0,r0,r1)
933 static jit_word_t _baddr_p(jit_state_t*,jit_int32_t,jit_bool_t,
934 jit_word_t,jit_int32_t,jit_int32_t);
935 # define baddi(c,s,i0,r0,i1) _baddi(_jit,c,s,i0,r0,i1)
936 static void _baddi(jit_state_t*,jit_int32_t,jit_bool_t,
937 jit_word_t,jit_int32_t,jit_word_t);
938 # define baddi_p(c,s,i0,r0,i1) _baddi_p(_jit,c,s,i0,r0,i1)
939 static jit_word_t _baddi_p(jit_state_t*,jit_int32_t,jit_bool_t,
940 jit_word_t,jit_int32_t,jit_word_t);
941 # define bsubr(c,s,i0,r0,r1) _bsubr(_jit,c,s,i0,r0,r1)
942 static void _bsubr(jit_state_t*,jit_int32_t,jit_bool_t,
943 jit_word_t,jit_int32_t,jit_int32_t);
944 # define bsubr_p(c,s,i0,r0,r1) _bsubr_p(_jit,c,s,i0,r0,r1)
945 static jit_word_t _bsubr_p(jit_state_t*,jit_int32_t,jit_bool_t,
946 jit_word_t,jit_int32_t,jit_int32_t);
947 # define bsubi(c,s,i0,r0,i1) _bsubi(_jit,c,s,i0,r0,i1)
948 static void _bsubi(jit_state_t*,jit_int32_t,jit_bool_t,
949 jit_word_t,jit_int32_t,jit_word_t);
950 # define bsubi_p(c,s,i0,r0,i1) _bsubi_p(_jit,c,s,i0,r0,i1)
951 static jit_word_t _bsubi_p(jit_state_t*,jit_int32_t,jit_bool_t,
952 jit_word_t,jit_int32_t,jit_word_t);
953 # define bmxr(cc,i0,r0,r1) _bmxr(_jit,cc,i0,r0,r1)
954 static void _bmxr(jit_state_t*,jit_int32_t,
955 jit_word_t,jit_int32_t,jit_int32_t);
956 # define bmxr_p(cc,i0,r0,r1) _bmxr_p(_jit,cc,i0,r0,r1)
957 static jit_word_t _bmxr_p(jit_state_t*,jit_int32_t,
958 jit_word_t,jit_int32_t,jit_int32_t);
959 # define bmxi(cc,i0,r0,i1) _bmxi(_jit,cc,i0,r0,i1)
960 static void _bmxi(jit_state_t*,jit_int32_t,
961 jit_word_t,jit_int32_t,jit_word_t);
962 # define bmxi_p(cc,i0,r0,i1) _bmxi_p(_jit,cc,i0,r0,i1)
963 static jit_word_t _bmxi_p(jit_state_t*,jit_int32_t,
964 jit_word_t,jit_int32_t,jit_word_t);
965 # define movr(r0,r1) _movr(_jit,r0,r1)
966 static void _movr(jit_state_t*,jit_int32_t,jit_int32_t);
967 # define movi(r0,i0) _movi(_jit,r0,i0)
968 static void _movi(jit_state_t*,jit_int32_t,jit_word_t);
969 # define movi_p(r0,i0) _movi_p(_jit,r0,i0)
970 static jit_word_t _movi_p(jit_state_t*,jit_int32_t,jit_word_t);
971 # define bswapr_us(r0, r1) _bswapr_us(_jit, r0, r1)
972 static void _bswapr_us(jit_state_t*,jit_int32_t,jit_int32_t);
973 # define bswapr_ui(r0, r1) _bswapr_ui(_jit, r0, r1)
974 static void _bswapr_ui(jit_state_t*,jit_int32_t,jit_int32_t);
975 # if __WORDSIZE == 64
976 #define bswapr_ul(r0, r1) _bswapr_ul(_jit, r0, r1)
977 static void _bswapr_ul(jit_state_t*,jit_int32_t,jit_int32_t);
979 # define movnr(r0,r1,r2) _movnr(_jit,r0,r1,r2)
980 static void _movnr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
981 # define movzr(r0,r1,r2) _movzr(_jit,r0,r1,r2)
982 static void _movzr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
983 # define casx(r0, r1, r2, r3, i0) _casx(_jit, r0, r1, r2, r3, i0)
984 static void _casx(jit_state_t *_jit,jit_int32_t,jit_int32_t,
985 jit_int32_t,jit_int32_t,jit_word_t);
986 #define casr(r0, r1, r2, r3) casx(r0, r1, r2, r3, 0)
987 #define casi(r0, i0, r1, r2) casx(r0, _NOREG, r1, r2, i0)
988 # define addr(r0,r1,r2) _addr(_jit,r0,r1,r2)
989 static void _addr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
990 # define addi(r0,r1,i0) _addi(_jit,r0,r1,i0)
991 static void _addi(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
992 # define addcr(r0,r1,r2) _addcr(_jit,r0,r1,r2)
993 static void _addcr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
994 # define addci(r0,r1,i0) _addci(_jit,r0,r1,i0)
995 static void _addci(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
996 # define addxr(r0,r1,r2) _addxr(_jit,r0,r1,r2)
997 static void _addxr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
998 # define addxi(r0,r1,i0) _addxi(_jit,r0,r1,i0)
999 static void _addxi(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1000 # define subr(r0,r1,r2) _subr(_jit,r0,r1,r2)
1001 static void _subr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1002 # define subi(r0,r1,i0) _subi(_jit,r0,r1,i0)
1003 static void _subi(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1004 # define subcr(r0,r1,r2) _subcr(_jit,r0,r1,r2)
1005 static void _subcr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1006 # define subci(r0,r1,i0) _subci(_jit,r0,r1,i0)
1007 static void _subci(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1008 # define subxr(r0,r1,r2) _subxr(_jit,r0,r1,r2)
1009 static void _subxr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1010 # define subxi(r0,r1,i0) _subxi(_jit,r0,r1,i0)
1011 static void _subxi(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1012 # define rsbi(r0, r1, i0) _rsbi(_jit, r0, r1, i0)
1013 static void _rsbi(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1014 # define mulr(r0,r1,r2) _mulr(_jit,r0,r1,r2)
1015 static void _mulr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1016 # define muli(r0,r1,i0) _muli(_jit,r0,r1,i0)
1017 static void _muli(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1018 # define qmulr(r0,r1,r2,r3) _qmulr(_jit,r0,r1,r2,r3)
1019 static void _qmulr(jit_state_t*,jit_int32_t,
1020 jit_int32_t,jit_int32_t,jit_int32_t);
1021 # define qmuli(r0,r1,r2,i0) _qmuli(_jit,r0,r1,r2,i0)
1022 static void _qmuli(jit_state_t*,jit_int32_t,
1023 jit_int32_t,jit_int32_t,jit_word_t);
1024 # define qmulr_u(r0,r1,r2,r3) _qmulr_u(_jit,r0,r1,r2,r3)
1025 static void _qmulr_u(jit_state_t*,jit_int32_t,
1026 jit_int32_t,jit_int32_t,jit_int32_t);
1027 # define qmuli_u(r0,r1,r2,i0) _qmuli_u(_jit,r0,r1,r2,i0)
1028 static void _qmuli_u(jit_state_t*,jit_int32_t,
1029 jit_int32_t,jit_int32_t,jit_word_t);
1030 # define divr(r0,r1,r2) _divr(_jit,r0,r1,r2)
1031 static void _divr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1032 # define divi(r0,r1,i0) _divi(_jit,r0,r1,i0)
1033 static void _divi(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1034 # define divr_u(r0,r1,r2) _divr_u(_jit,r0,r1,r2)
1035 static void _divr_u(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1036 # define divi_u(r0,r1,i0) _divi_u(_jit,r0,r1,i0)
1037 static void _divi_u(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1038 # define remr(r0,r1,r2) _remr(_jit,r0,r1,r2)
1039 static void _remr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1040 # define remi(r0,r1,i0) _remi(_jit,r0,r1,i0)
1041 static void _remi(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1042 # define remr_u(r0,r1,r2) _remr_u(_jit,r0,r1,r2)
1043 static void _remr_u(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1044 # define remi_u(r0,r1,i0) _remi_u(_jit,r0,r1,i0)
1045 static void _remi_u(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1046 # define qdivr(r0,r1,r2,r3) _qdivr(_jit,r0,r1,r2,r3)
1047 static void _qdivr(jit_state_t*,jit_int32_t,
1048 jit_int32_t,jit_int32_t,jit_int32_t);
1049 # define qdivi(r0,r1,r2,i0) _qdivi(_jit,r0,r1,r2,i0)
1050 static void _qdivi(jit_state_t*,jit_int32_t,
1051 jit_int32_t,jit_int32_t,jit_word_t);
1052 # define qdivr_u(r0,r1,r2,r3) _qdivr_u(_jit,r0,r1,r2,r3)
1053 static void _qdivr_u(jit_state_t*,jit_int32_t,
1054 jit_int32_t,jit_int32_t,jit_int32_t);
1055 # define qdivi_u(r0,r1,r2,i0) _qdivi_u(_jit,r0,r1,r2,i0)
1056 static void _qdivi_u(jit_state_t*,jit_int32_t,
1057 jit_int32_t,jit_int32_t,jit_word_t);
1058 # if __WORDSIZE == 32
1059 # define lshr(r0,r1,r2) _lshr(_jit,r0,r1,r2)
1060 static void _lshr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1061 # define lshi(r0,r1,i0) _lshi(_jit,r0,r1,i0)
1062 static void _lshi(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1063 # define rshr(r0,r1,r2) _rshr(_jit,r0,r1,r2)
1064 static void _rshr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1065 # define rshi(r0,r1,i0) _rshi(_jit,r0,r1,i0);
1066 static void _rshi(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1067 # define rshr_u(r0,r1,r2) _rshr_u(_jit,r0,r1,r2)
1068 static void _rshr_u(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1069 # define rshi_u(r0,r1,i0) _rshi_u(_jit,r0,r1,i0)
1070 static void _rshi_u(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1072 # define lshr(r0,r1,r2) SLLG(r0,r1,0,r2)
1073 # define lshi(r0,r1,i0) SLLG(r0,r1,i0,0)
1074 # define rshr(r0,r1,r2) SRAG(r0,r1,0,r2)
1075 # define rshi(r0,r1,i0) SRAG(r0,r1,i0,0)
1076 # define rshr_u(r0,r1,r2) SRLG(r0,r1,0,r2)
1077 # define rshi_u(r0,r1,i0) SRLG(r0,r1,i0,0)
1079 # if __WORDSIZE == 32
1080 # define negr(r0,r1) LCR(r0,r1)
1082 # define negr(r0,r1) LCGR(r0,r1)
1084 # define bitswap(r0, r1) _bitswap(_jit, r0, r1)
1085 static void _bitswap(jit_state_t*, jit_int32_t, jit_int32_t);
1086 # define clor(r0, r1) _clor(_jit, r0, r1)
1087 static void _clor(jit_state_t*, jit_int32_t, jit_int32_t);
1088 # define clzr(r0, r1) _clzr(_jit, r0, r1)
1089 static void _clzr(jit_state_t*, jit_int32_t, jit_int32_t);
1090 # define ctor(r0, r1) _ctor(_jit, r0, r1)
1091 static void _ctor(jit_state_t*, jit_int32_t, jit_int32_t);
1092 # define ctzr(r0, r1) _ctzr(_jit, r0, r1)
1093 static void _ctzr(jit_state_t*, jit_int32_t, jit_int32_t);
1094 # define comr(r0,r1) _comr(_jit,r0,r1)
1095 static void _comr(jit_state_t*,jit_int32_t,jit_int32_t);
1096 # define andr(r0,r1,r2) _andr(_jit,r0,r1,r2)
1097 static void _andr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1098 # define andi(r0,r1,i0) _andi(_jit,r0,r1,i0)
1099 static void _andi(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1100 # define orr(r0,r1,r2) _orr(_jit,r0,r1,r2)
1101 static void _orr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1102 # define ori(r0,r1,i0) _ori(_jit,r0,r1,i0)
1103 static void _ori(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1104 # define xorr(r0,r1,r2) _xorr(_jit,r0,r1,r2)
1105 static void _xorr(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1106 # define xori(r0,r1,i0) _xori(_jit,r0,r1,i0)
1107 static void _xori(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1108 # define extr_c(r0,r1) LGBR(r0,r1)
1109 # define extr_uc(r0,r1) LLGCR(r0,r1)
1110 # define extr_s(r0,r1) LGHR(r0,r1)
1111 # define extr_us(r0,r1) LLGHR(r0,r1)
1112 # if __WORDSIZE == 64
1113 # define extr_i(r0,r1) LGFR(r0,r1)
1114 # define extr_ui(r0,r1) LLGFR(r0,r1)
1116 # define ldr_c(r0,r1) LGB(r0,0,0,r1)
1117 # define ldi_c(r0,i0) _ldi_c(_jit,r0,i0)
1118 static void _ldi_c(jit_state_t*,jit_int32_t,jit_word_t);
1119 # define ldxr_c(r0,r1,r2) _ldxr_c(_jit,r0,r1,r2)
1120 static void _ldxr_c(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1121 # define ldxi_c(r0,r1,i0) _ldxi_c(_jit,r0,r1,i0)
1122 static void _ldxi_c(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1123 # define ldr_uc(r0,r1) LLGC(r0,0,0,r1)
1124 # define ldi_uc(r0,i0) _ldi_uc(_jit,r0,i0)
1125 static void _ldi_uc(jit_state_t*,jit_int32_t,jit_word_t);
1126 # define ldxr_uc(r0,r1,r2) _ldxr_uc(_jit,r0,r1,r2)
1127 static void _ldxr_uc(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1128 # define ldxi_uc(r0,r1,i0) _ldxi_uc(_jit,r0,r1,i0)
1129 static void _ldxi_uc(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1130 # if __WORDSIZE == 32
1131 # define ldr_s(r0,r1) LH(r0,0,0,r1)
1133 # define ldr_s(r0,r1) LGH(r0,0,0,r1)
1135 # define ldi_s(r0,i0) _ldi_s(_jit,r0,i0)
1136 static void _ldi_s(jit_state_t*,jit_int32_t,jit_word_t);
1137 # define ldxr_s(r0,r1,r2) _ldxr_s(_jit,r0,r1,r2)
1138 static void _ldxr_s(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1139 # define ldxi_s(r0,r1,i0) _ldxi_s(_jit,r0,r1,i0)
1140 static void _ldxi_s(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1141 # define ldr_us(r0,r1) LLGH(r0,0,0,r1)
1142 # define ldi_us(r0,i0) _ldi_us(_jit,r0,i0)
1143 static void _ldi_us(jit_state_t*,jit_int32_t,jit_word_t);
1144 # define ldxr_us(r0,r1,r2) _ldxr_us(_jit,r0,r1,r2)
1145 static void _ldxr_us(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1146 # define ldxi_us(r0,r1,i0) _ldxi_us(_jit,r0,r1,i0)
1147 static void _ldxi_us(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1148 # if __WORDSIZE == 32
1149 # define ldr_i(r0,r1) LLGF(r0,0,0,r1)
1151 # define ldr_i(r0,r1) LGF(r0,0,0,r1)
1153 # define ldi_i(r0,i0) _ldi_i(_jit,r0,i0)
1154 static void _ldi_i(jit_state_t*,jit_int32_t,jit_word_t);
1155 # define ldxr_i(r0,r1,r2) _ldxr_i(_jit,r0,r1,r2)
1156 static void _ldxr_i(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1157 # define ldxi_i(r0,r1,i0) _ldxi_i(_jit,r0,r1,i0)
1158 static void _ldxi_i(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1159 # if __WORDSIZE == 64
1160 # define ldr_ui(r0,r1) LLGF(r0,0,0,r1)
1161 # define ldi_ui(r0,i0) _ldi_ui(_jit,r0,i0)
1162 static void _ldi_ui(jit_state_t*,jit_int32_t,jit_word_t);
1163 # define ldxr_ui(r0,r1,r2) _ldxr_ui(_jit,r0,r1,r2)
1164 static void _ldxr_ui(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1165 # define ldxi_ui(r0,r1,i0) _ldxi_ui(_jit,r0,r1,i0)
1166 static void _ldxi_ui(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1167 # define ldr_l(r0,r1) LG(r0,0,0,r1)
1168 # define ldi_l(r0,i0) _ldi_l(_jit,r0,i0)
1169 static void _ldi_l(jit_state_t*,jit_int32_t,jit_word_t);
1170 # define ldxr_l(r0,r1,r2) _ldxr_l(_jit,r0,r1,r2)
1171 static void _ldxr_l(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1172 # define ldxi_l(r0,r1,i0) _ldxi_l(_jit,r0,r1,i0)
1173 static void _ldxi_l(jit_state_t*,jit_int32_t,jit_int32_t,jit_word_t);
1175 # define str_c(r0,r1) STC(r1,0,0,r0)
1176 # define sti_c(i0,r0) _sti_c(_jit,i0,r0)
1177 static void _sti_c(jit_state_t*,jit_word_t,jit_int32_t);
1178 # define stxr_c(r0,r1,r2) _stxr_c(_jit,r0,r1,r2)
1179 static void _stxr_c(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1180 # define stxi_c(i0,r0,r1) _stxi_c(_jit,i0,r0,r1)
1181 static void _stxi_c(jit_state_t*,jit_word_t,jit_int32_t,jit_int32_t);
1182 # define str_s(r0,r1) STH(r1,0,0,r0)
1183 # define sti_s(i0,r0) _sti_s(_jit,i0,r0)
1184 static void _sti_s(jit_state_t*,jit_word_t,jit_int32_t);
1185 # define stxr_s(r0,r1,r2) _stxr_s(_jit,r0,r1,r2)
1186 static void _stxr_s(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1187 # define stxi_s(i0,r0,r1) _stxi_s(_jit,i0,r0,r1)
1188 static void _stxi_s(jit_state_t*,jit_word_t,jit_int32_t,jit_int32_t);
1189 # define str_i(r0,r1) ST(r1,0,0,r0)
1190 # define sti_i(i0,r0) _sti_i(_jit,i0,r0)
1191 static void _sti_i(jit_state_t*,jit_word_t,jit_int32_t);
1192 # define stxr_i(r0,r1,r2) _stxr_i(_jit,r0,r1,r2)
1193 static void _stxr_i(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1194 # define stxi_i(i0,r0,r1) _stxi_i(_jit,i0,r0,r1)
1195 static void _stxi_i(jit_state_t*,jit_word_t,jit_int32_t,jit_int32_t);
1196 # if __WORDSIZE == 64
1197 # define str_l(r0,r1) STG(r1,0,0,r0)
1198 # define sti_l(i0,r0) _sti_l(_jit,i0,r0)
1199 static void _sti_l(jit_state_t*,jit_word_t,jit_int32_t);
1200 # define stxr_l(r0,r1,r2) _stxr_l(_jit,r0,r1,r2)
1201 static void _stxr_l(jit_state_t*,jit_int32_t,jit_int32_t,jit_int32_t);
1202 # define stxi_l(i0,r0,r1) _stxi_l(_jit,i0,r0,r1)
1203 static void _stxi_l(jit_state_t*,jit_word_t,jit_int32_t,jit_int32_t);
1205 # define ltr(r0,r1,r2) crr(CC_L,r0,r1,r2)
1206 # define lti(r0,r1,i0) cri(CC_L,r0,r1,i0)
1207 # define ltr_u(r0,r1,r2) crr_u(CC_L,r0,r1,r2)
1208 # define lti_u(r0,r1,i0) cri_u(CC_L,r0,r1,i0)
1209 # define ler(r0,r1,r2) crr(CC_LE,r0,r1,r2)
1210 # define lei(r0,r1,i0) cri(CC_LE,r0,r1,i0)
1211 # define ler_u(r0,r1,r2) crr_u(CC_LE,r0,r1,r2)
1212 # define lei_u(r0,r1,i0) cri_u(CC_LE,r0,r1,i0)
1213 # define eqr(r0,r1,r2) crr(CC_E,r0,r1,r2)
1214 # define eqi(r0,r1,i0) cri(CC_E,r0,r1,i0)
1215 # define ger(r0,r1,r2) crr(CC_HE,r0,r1,r2)
1216 # define gei(r0,r1,i0) cri(CC_HE,r0,r1,i0)
1217 # define ger_u(r0,r1,r2) crr_u(CC_HE,r0,r1,r2)
1218 # define gei_u(r0,r1,i0) cri_u(CC_HE,r0,r1,i0)
1219 # define gtr(r0,r1,r2) crr(CC_H,r0,r1,r2)
1220 # define gti(r0,r1,i0) cri(CC_H,r0,r1,i0)
1221 # define gtr_u(r0,r1,r2) crr_u(CC_H,r0,r1,r2)
1222 # define gti_u(r0,r1,i0) cri_u(CC_H,r0,r1,i0)
1223 # define ner(r0,r1,r2) crr(CC_NE,r0,r1,r2)
1224 # define nei(r0,r1,i0) cri(CC_NE,r0,r1,i0)
1225 # define bltr(i0,r0,r1) brr(CC_L,i0,r0,r1)
1226 # define bltr_p(i0,r0,r1) brr_p(CC_L,i0,r0,r1)
1227 # define blti(i0,r0,i1) bri(CC_L,i0,r0,i1)
1228 # define blti_p(i0,r0,i1) bri_p(CC_L,i0,r0,i1)
1229 # define bltr_u(i0,r0,r1) brr_u(CC_L,i0,r0,r1)
1230 # define bltr_u_p(i0,r0,r1) brr_u_p(CC_L,i0,r0,r1)
1231 # define blti_u(i0,r0,i1) bri_u(CC_L,i0,r0,i1)
1232 # define blti_u_p(i0,r0,i1) bri_u_p(CC_L,i0,r0,i1)
1233 # define bler(i0,r0,r1) brr(CC_LE,i0,r0,r1)
1234 # define bler_p(i0,r0,r1) brr_p(CC_LE,i0,r0,r1)
1235 # define blei(i0,r0,i1) bri(CC_LE,i0,r0,i1)
1236 # define blei_p(i0,r0,i1) bri_p(CC_LE,i0,r0,i1)
1237 # define bler_u(i0,r0,r1) brr_u(CC_LE,i0,r0,r1)
1238 # define bler_u_p(i0,r0,r1) brr_u_p(CC_LE,i0,r0,r1)
1239 # define blei_u(i0,r0,i1) bri_u(CC_LE,i0,r0,i1)
1240 # define blei_u_p(i0,r0,i1) bri_u_p(CC_LE,i0,r0,i1)
1241 # define beqr(i0,r0,r1) brr(CC_E,i0,r0,r1)
1242 # define beqr_p(i0,r0,r1) brr_p(CC_E,i0,r0,r1)
1243 # define beqi(i0,r0,i1) bri(CC_E,i0,r0,i1)
1244 # define beqi_p(i0,r0,i1) bri_p(CC_E,i0,r0,i1)
1245 # define bger(i0,r0,r1) brr(CC_HE,i0,r0,r1)
1246 # define bger_p(i0,r0,r1) brr_p(CC_HE,i0,r0,r1)
1247 # define bgei(i0,r0,i1) bri(CC_HE,i0,r0,i1)
1248 # define bgei_p(i0,r0,i1) bri_p(CC_HE,i0,r0,i1)
1249 # define bger_u(i0,r0,r1) brr_u(CC_HE,i0,r0,r1)
1250 # define bger_u_p(i0,r0,r1) brr_u_p(CC_HE,i0,r0,r1)
1251 # define bgei_u(i0,r0,i1) bri_u(CC_HE,i0,r0,i1)
1252 # define bgei_u_p(i0,r0,i1) bri_u_p(CC_HE,i0,r0,i1)
1253 # define bgtr(i0,r0,r1) brr(CC_H,i0,r0,r1)
1254 # define bgtr_p(i0,r0,r1) brr_p(CC_H,i0,r0,r1)
1255 # define bgti(i0,r0,i1) bri(CC_H,i0,r0,i1)
1256 # define bgti_p(i0,r0,i1) bri_p(CC_H,i0,r0,i1)
1257 # define bgtr_u(i0,r0,r1) brr_u(CC_H,i0,r0,r1)
1258 # define bgtr_u_p(i0,r0,r1) brr_u_p(CC_H,i0,r0,r1)
1259 # define bgti_u(i0,r0,i1) bri_u(CC_H,i0,r0,i1)
1260 # define bgti_u_p(i0,r0,i1) bri_u_p(CC_H,i0,r0,i1)
1261 # define bner(i0,r0,r1) brr(CC_NE,i0,r0,r1)
1262 # define bner_p(i0,r0,r1) brr_p(CC_NE,i0,r0,r1)
1263 # define bnei(i0,r0,i1) bri(CC_NE,i0,r0,i1)
1264 # define bnei_p(i0,r0,i1) bri_p(CC_NE,i0,r0,i1)
1265 # define boaddr(i0,r0,r1) baddr(CC_O,1,i0,r0,r1)
1266 # define boaddr_p(i0,r0,r1) baddr_p(CC_O,1,i0,r0,r1)
1267 # define boaddi(i0,r0,i1) baddi(CC_O,1,i0,r0,i1)
1268 # define boaddi_p(i0,r0,i1) baddi_p(CC_O,1,i0,r0,i1)
1269 # define boaddr_u(i0,r0,r1) baddr(CC_NLE,0,i0,r0,r1)
1270 # define boaddr_u_p(i0,r0,r1) baddr_p(CC_NLE,0,i0,r0,r1)
1271 # define boaddi_u(i0,r0,i1) baddi(CC_NLE,0,i0,r0,i1)
1272 # define boaddi_u_p(i0,r0,i1) baddi_p(CC_NLE,0,i0,r0,i1)
1273 # define bxaddr(i0,r0,r1) baddr(CC_NO,1,i0,r0,r1)
1274 # define bxaddr_p(i0,r0,r1) baddr_p(CC_NO,1,i0,r0,r1)
1275 # define bxaddi(i0,r0,i1) baddi(CC_NO,1,i0,r0,i1)
1276 # define bxaddi_p(i0,r0,i1) baddi_p(CC_NO,1,i0,r0,i1)
1277 # define bxaddr_u(i0,r0,r1) baddr(CC_LE,0,i0,r0,r1)
1278 # define bxaddr_u_p(i0,r0,r1) baddr_p(CC_LE,0,i0,r0,r1)
1279 # define bxaddi_u(i0,r0,i1) baddi(CC_LE,0,i0,r0,i1)
1280 # define bxaddi_u_p(i0,r0,i1) baddi_p(CC_LE,0,i0,r0,i1)
1281 # define bosubr(i0,r0,r1) bsubr(CC_O,1,i0,r0,r1)
1282 # define bosubr_p(i0,r0,r1) bsubr_p(CC_O,1,i0,r0,r1)
1283 # define bosubi(i0,r0,i1) bsubi(CC_O,1,i0,r0,i1)
1284 # define bosubi_p(i0,r0,i1) bsubi_p(CC_O,1,i0,r0,i1)
1285 # define bosubr_u(i0,r0,r1) bsubr(CC_L,0,i0,r0,r1)
1286 # define bosubr_u_p(i0,r0,r1) bsubr_p(CC_L,0,i0,r0,r1)
1287 # define bosubi_u(i0,r0,i1) bsubi(CC_L,0,i0,r0,i1)
1288 # define bosubi_u_p(i0,r0,i1) bsubi_p(CC_L,0,i0,r0,i1)
1289 # define bxsubr(i0,r0,r1) bsubr(CC_NO,1,i0,r0,r1)
1290 # define bxsubr_p(i0,r0,r1) bsubr_p(CC_NO,1,i0,r0,r1)
1291 # define bxsubi(i0,r0,i1) bsubi(CC_NO,1,i0,r0,i1)
1292 # define bxsubi_p(i0,r0,i1) bsubi_p(CC_NO,1,i0,r0,i1)
1293 # define bxsubr_u(i0,r0,r1) bsubr(CC_NL,0,i0,r0,r1)
1294 # define bxsubr_u_p(i0,r0,r1) bsubr_p(CC_NL,0,i0,r0,r1)
1295 # define bxsubi_u(i0,r0,i1) bsubi(CC_NL,0,i0,r0,i1)
1296 # define bxsubi_u_p(i0,r0,i1) bsubi_p(CC_NL,0,i0,r0,i1)
1297 # define bmsr(i0,r0,r1) bmxr(CC_NE,i0,r0,r1)
1298 # define bmsr_p(i0,r0,r1) bmxr_p(CC_NE,i0,r0,r1)
1299 # define bmsi(i0,r0,i1) bmxi(CC_NE,i0,r0,i1)
1300 # define bmsi_p(i0,r0,i1) bmxi_p(CC_NE,i0,r0,i1)
1301 # define bmcr(i0,r0,r1) bmxr(CC_E,i0,r0,r1)
1302 # define bmcr_p(i0,r0,r1) bmxr_p(CC_E,i0,r0,r1)
1303 # define bmci(i0,r0,i1) bmxi(CC_E,i0,r0,i1)
1304 # define bmci_p(i0,r0,i1) bmxi_p(CC_E,i0,r0,i1)
1305 # define jmpr(r0) BR(r0)
1306 # define jmpi(i0,i1) _jmpi(_jit,i0,i1)
1307 static jit_word_t _jmpi(jit_state_t*,jit_word_t, jit_bool_t);
1308 # define jmpi_p(i0) _jmpi_p(_jit,i0)
1309 static jit_word_t _jmpi_p(jit_state_t*,jit_word_t);
1310 # define callr(r0) BALR(_R14_REGNO,r0)
1311 # define calli(i0,i1) _calli(_jit,i0,i1)
1312 static jit_word_t _calli(jit_state_t*,jit_word_t, jit_bool_t);
1313 # define calli_p(i0) _calli_p(_jit,i0)
1314 static jit_word_t _calli_p(jit_state_t*,jit_word_t);
1315 # define prolog(i0) _prolog(_jit,i0)
1316 static void _prolog(jit_state_t*,jit_node_t*);
1317 # define epilog(i0) _epilog(_jit,i0)
1318 static void _epilog(jit_state_t*,jit_node_t*);
1319 # define vastart(r0) _vastart(_jit, r0)
1320 static void _vastart(jit_state_t*, jit_int32_t);
1321 # define vaarg(r0, r1) _vaarg(_jit, r0, r1)
1322 static void _vaarg(jit_state_t*, jit_int32_t, jit_int32_t);
1323 # define patch_at(instr,label) _patch_at(_jit,instr,label)
1324 static void _patch_at(jit_state_t*,jit_word_t,jit_word_t);
1328 # define _us jit_uint16_t
1329 # define _ui jit_uint32_t
1331 _E(jit_state_t *_jit, _ui Op)
1340 assert(i0.b.op == Op);
1345 _I(jit_state_t *_jit, _ui Op, _ui I)
1356 assert(i0.b.op == Op);
1357 assert(i0.b.i == I);
1362 _RR(jit_state_t *_jit, _ui Op, _ui R1, _ui R2)
1375 assert(i0.b.op == Op);
1376 assert(i0.b.r1 == R1);
1377 assert(i0.b.r2 == R2);
1382 _RRE(jit_state_t *_jit, _ui Op, _ui R1, _ui R2)
1402 assert(i0.b.op == Op);
1403 assert(i1.b.r1 == R1);
1404 assert(i1.b.r2 == R2);
1410 _RRF(jit_state_t *_jit, _ui Op, _ui R3, _ui M4, _ui R1, _ui R2)
1432 assert(i0.b.op == Op);
1433 assert(i1.b.r3 == R3);
1434 assert(i1.b.m4 == M4);
1435 assert(i1.b.r1 == R1);
1436 assert(i1.b.r2 == R2);
1442 _RX(jit_state_t *_jit, _ui Op, _ui R1, _ui X2, _ui B2, _ui D2)
1464 assert(i0.b.op == Op);
1465 assert(i0.b.r1 == R1);
1466 assert(i0.b.x2 == X2);
1467 assert(i1.b.b2 == B2);
1468 assert(i1.b.d2 == D2);
1474 _RXE(jit_state_t *_jit, _ui Op, _ui R1, _ui X2, _ui B2, _ui D2, _ui Op2)
1505 assert(i0.b.op == Op);
1506 assert(i0.b.r1 == R1);
1507 assert(i0.b.x2 == X2);
1508 assert(i1.b.b2 == B2);
1509 assert(i1.b.d2 == D2);
1510 assert(i2.b.op == Op2);
1517 _RXF(jit_state_t *_jit, _ui Op, _ui R3, _ui X2, _ui B2, _ui D2, _ui R1, _ui Op2)
1550 assert(i0.b.op == Op);
1551 assert(i0.b.r3 == R3);
1552 assert(i0.b.x2 == X2);
1553 assert(i1.b.b2 == B2);
1554 assert(i1.b.d2 == D2);
1555 assert(i2.b.r1 == R1);
1556 assert(i2.b.op == Op2);
1563 _RXY(jit_state_t *_jit, _ui Op, _ui R1, _ui X2, _ui B2, _ui D2, _ui Op2)
1587 i0.s = i1.s = i2.s = 0;
1592 i1.b.dl = D2 & 0xfff;
1595 assert(i0.b.op == Op);
1596 assert(i0.b.r1 == R1);
1597 assert(i0.b.x2 == X2);
1598 assert(i1.b.b2 == B2);
1599 assert(i2.b.dh == D2 >> 12);
1600 assert(i2.b.op == Op2);
1607 _RS(jit_state_t *_jit, _ui Op, _ui R1, _ui R3, _ui B2, _ui D2)
1630 assert(i0.b.op == Op);
1631 assert(i0.b.r1 == R1);
1632 assert(i0.b.r3 == R3);
1633 assert(i1.b.b2 == B2);
1634 assert(i1.b.d2 == D2);
1640 _RSL(jit_state_t *_jit, _ui Op, _ui L1, _ui B1, _ui D1, _ui Op2)
1671 assert(i0.b.op == Op);
1672 assert(i0.b.l1 == L1);
1673 assert(i1.b.b1 == B1);
1674 assert(i1.b.d1 == D1);
1675 assert(i2.b.op == Op2);
1682 _RSI(jit_state_t *_jit, _ui Op, _ui R1, _ui R3, _ui I2)
1702 assert(i0.b.op == Op);
1703 assert(i0.b.r1 == R1);
1704 assert(i0.b.r3 == R3);
1705 assert(i1.b.i2 == I2);
1711 _RIE(jit_state_t *_jit, _ui Op, _ui R1, _ui R3, _ui I2, _ui Op2)
1740 assert(i0.b.op == Op);
1741 assert(i0.b.r1 == R1);
1742 assert(i0.b.r3 == R3);
1743 assert(i1.b.i2 == I2);
1744 assert(i2.b.op == Op2);
1751 _RIL(jit_state_t *_jit, _ui Op, _ui R1, _ui Op2, _ui I2)
1772 assert(i0.b.o1 == Op);
1773 assert(i0.b.r1 == R1);
1774 assert(i0.b.o2 == Op2);
1781 _SI(jit_state_t *_jit, _ui Op, _ui I2, _ui B1, _ui D1)
1801 assert(i0.b.op == Op);
1802 assert(i0.b.i2 == I2);
1803 assert(i1.b.b1 == B1);
1804 assert(i1.b.d1 == D1);
1810 _SIY(jit_state_t *_jit, _ui Op, _ui I2, _ui B1, _ui D1, _ui Op2)
1836 i1.b.dl = D1 & 0xfff;
1839 assert(i0.b.op == Op);
1840 assert(i0.b.i2 == I2);
1841 assert(i1.b.b1 == B1);
1842 assert(i2.b.dh == D1 >> 8);
1843 assert(i2.b.op == Op2);
1850 _S(jit_state_t *_jit, _ui Op, _ui B2, _ui D2)
1868 assert(i0.b.op == Op);
1869 assert(i1.b.b2 == B2);
1870 assert(i1.b.d2 == D2);
1876 _SS(jit_state_t *_jit, _ui Op, _ui LL, _ui LH, _ui B1, _ui D1, _ui B2, _ui D2)
1907 assert(i0.b.op == Op);
1908 assert(i0.b.ll == LL);
1909 assert(i0.b.lh == LH);
1910 assert(i1.b.b1 == B1);
1911 assert(i1.b.d1 == D1);
1912 assert(i2.b.b2 == B2);
1913 assert(i2.b.d2 == D2);
1920 _SSE(jit_state_t *_jit, _ui Op, _ui B1, _ui D1, _ui B2, _ui D2)
1947 assert(i0.b.op == Op);
1948 assert(i1.b.b1 == B1);
1949 assert(i1.b.d1 == D1);
1950 assert(i2.b.b2 == B2);
1951 assert(i2.b.d2 == D2);
1960 _nop(jit_state_t *_jit, jit_int32_t c)
1962 assert(c >= 0 && !(c & 1));
1970 _xdivr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1)
1973 regno = jit_get_reg_pair();
1974 #if __WORDSIZE == 32
1975 movr(rn(regno), r0);
1976 SRDA(rn(regno), 32, 0);
1978 movr(rn(regno) + 1, r0);
1980 DIVREM_(rn(regno), r1);
1981 jit_unget_reg_pair(regno);
1986 _xdivr_u(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1)
1989 regno = jit_get_reg_pair();
1990 #if __WORDSIZE == 32
1991 movr(rn(regno), r0);
1992 SRDL(rn(regno), 32, 0);
1994 movr(rn(regno) + 1, r0);
1997 DIVREMU_(rn(regno), r1);
1998 jit_unget_reg_pair(regno);
2003 _xdivi(jit_state_t *_jit, jit_int32_t r0, jit_word_t i0)
2005 jit_int32_t imm, regno;
2006 regno = jit_get_reg_pair();
2007 imm = jit_get_reg(jit_class_gpr);
2008 #if __WORDSIZE == 32
2009 movr(rn(regno), r0);
2010 SRDA(rn(regno), 32, 0);
2012 movr(rn(regno) + 1, r0);
2015 DIVREM_(rn(regno), rn(imm));
2017 jit_unget_reg_pair(regno);
2022 _xdivi_u(jit_state_t *_jit, jit_int32_t r0, jit_word_t i0)
2024 /* cannot overlap because operand is 128-bit */
2025 jit_int32_t imm, regno;
2026 regno = jit_get_reg_pair();
2027 imm = jit_get_reg(jit_class_gpr);
2028 #if __WORDSIZE == 32
2029 movr(rn(regno), r0);
2030 SRDL(rn(regno), 32, 0);
2032 movr(rn(regno) + 1, r0);
2036 DIVREMU_(rn(regno), rn(imm));
2038 jit_unget_reg_pair(regno);
2043 _crr(jit_state_t *_jit, jit_int32_t cc,
2044 jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2047 jit_int32_t reg, rg;
2048 if (r0 == r1 || r0 == r2) {
2049 reg = jit_get_reg(jit_class_gpr);
2059 patch_at(w, _jit->pc.w);
2060 if (r0 == r1 || r0 == r2) {
2067 _cri(jit_state_t *_jit, jit_int32_t cc,
2068 jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2071 reg = jit_get_reg(jit_class_gpr);
2073 crr(cc, r0, r1, rn(reg));
2078 _crr_u(jit_state_t *_jit, jit_int32_t cc,
2079 jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2082 jit_int32_t reg, rg;
2083 if (r0 == r1 || r0 == r2) {
2084 reg = jit_get_reg(jit_class_gpr);
2094 patch_at(w, _jit->pc.w);
2095 if (r0 == r1 || r0 == r2) {
2102 _cri_u(jit_state_t *_jit, jit_int32_t cc,
2103 jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2106 reg = jit_get_reg(jit_class_gpr);
2108 crr_u(cc, r0, r1, rn(reg));
2113 _brr(jit_state_t *_jit, jit_int32_t cc,
2114 jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
2118 d = (i0 - _jit->pc.w) >> 1;
2128 _brr_p(jit_state_t *_jit, jit_int32_t cc,
2129 jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
2139 _bri(jit_state_t *_jit, jit_int32_t cc,
2140 jit_word_t i0, jit_int32_t r0, jit_word_t i1)
2143 reg = jit_get_reg(jit_class_gpr|jit_class_nospill);
2145 brr(cc, i0, r0, rn(reg));
2150 _bri_p(jit_state_t *_jit, jit_int32_t cc,
2151 jit_word_t i0, jit_int32_t r0, jit_word_t i1)
2155 reg = jit_get_reg(jit_class_gpr|jit_class_nospill);
2157 w = brr_p(cc, i0, r0, rn(reg));
2163 _brr_u(jit_state_t *_jit, jit_int32_t cc,
2164 jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
2168 d = (i0 - _jit->pc.w) >> 1;
2178 _brr_u_p(jit_state_t *_jit, jit_int32_t cc,
2179 jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
2189 _bri_u(jit_state_t *_jit, jit_int32_t cc,
2190 jit_word_t i0, jit_int32_t r0, jit_word_t i1)
2193 reg = jit_get_reg(jit_class_gpr|jit_class_nospill);
2195 brr_u(cc, i0, r0, rn(reg));
2200 _bri_u_p(jit_state_t *_jit, jit_int32_t cc,
2201 jit_word_t i0, jit_int32_t r0, jit_word_t i1)
2205 reg = jit_get_reg(jit_class_gpr|jit_class_nospill);
2207 w = brr_u_p(cc, i0, r0, rn(reg));
2213 _baddr(jit_state_t *_jit, jit_int32_t c, jit_bool_t s,
2214 jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
2217 if (s) addr(r0, r0, r1);
2218 else addcr(r0, r0, r1);
2219 d = (i0 - _jit->pc.w) >> 1;
2229 _baddi(jit_state_t *_jit, jit_int32_t c, jit_bool_t s,
2230 jit_word_t i0, jit_int32_t r0, jit_word_t i1)
2233 reg = jit_get_reg(jit_class_gpr|jit_class_nospill);
2235 baddr(c, s, i0, r0, rn(reg));
2240 _baddr_p(jit_state_t *_jit, jit_int32_t c, jit_bool_t s,
2241 jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
2244 if (s) addr(r0, r0, r1);
2245 else addcr(r0, r0, r1);
2246 d = (i0 - _jit->pc.w) >> 1;
2253 _baddi_p(jit_state_t *_jit, jit_int32_t c, jit_bool_t s,
2254 jit_word_t i0, jit_int32_t r0, jit_word_t i1)
2258 reg = jit_get_reg(jit_class_gpr|jit_class_nospill);
2260 w = baddr_p(c, s, i0, r0, rn(reg));
2266 _bsubr(jit_state_t *_jit, jit_int32_t c, jit_bool_t s,
2267 jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
2270 if (s) subr(r0, r0, r1);
2271 else subcr(r0, r0, r1);
2272 d = (i0 - _jit->pc.w) >> 1;
2282 _bsubi(jit_state_t *_jit, jit_int32_t c, jit_bool_t s,
2283 jit_word_t i0, jit_int32_t r0, jit_word_t i1)
2286 reg = jit_get_reg(jit_class_gpr|jit_class_nospill);
2288 bsubr(c, s, i0, r0, rn(reg));
2293 _bsubr_p(jit_state_t *_jit, jit_int32_t c, jit_bool_t s,
2294 jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
2297 if (s) subr(r0, r0, r1);
2298 else subcr(r0, r0, r1);
2299 d = (i0 - _jit->pc.w) >> 1;
2306 _bsubi_p(jit_state_t *_jit, jit_int32_t c, jit_bool_t s,
2307 jit_word_t i0, jit_int32_t r0, jit_word_t i1)
2311 reg = jit_get_reg(jit_class_gpr|jit_class_nospill);
2313 w = bsubr_p(c, s, i0, r0, rn(reg));
2319 _bmxr(jit_state_t *_jit, jit_int32_t cc,
2320 jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
2324 reg = jit_get_reg(jit_class_gpr);
2326 andr(rn(reg), rn(reg), r1);
2327 TEST_(rn(reg), rn(reg));
2329 d = (i0 - _jit->pc.w) >> 1;
2339 _bmxr_p(jit_state_t *_jit, jit_int32_t cc,
2340 jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
2344 reg = jit_get_reg(jit_class_gpr);
2346 andr(rn(reg), rn(reg), r1);
2347 TEST_(rn(reg), rn(reg));
2355 _bmxi(jit_state_t *_jit, jit_int32_t cc,
2356 jit_word_t i0, jit_int32_t r0, jit_word_t i1)
2360 reg = jit_get_reg(jit_class_gpr);
2362 andr(rn(reg), rn(reg), r0);
2363 TEST_(rn(reg), rn(reg));
2365 d = (i0 - _jit->pc.w) >> 1;
2375 _bmxi_p(jit_state_t *_jit, jit_int32_t cc,
2376 jit_word_t i0, jit_int32_t r0, jit_word_t i1)
2380 reg = jit_get_reg(jit_class_gpr);
2382 andr(rn(reg), rn(reg), r0);
2383 TEST_(rn(reg), rn(reg));
2391 _movr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1)
2393 #if __WORDSIZE == 32
2403 _movi(jit_state_t *_jit, jit_int32_t r0, jit_word_t i0)
2406 #if __WORDSIZE == 64
2409 d = (i0 - _jit->pc.w) >> 1;
2411 #if __WORDSIZE == 32
2417 /* easy way of loading a large amount of 32 bit values and
2418 * usually address of constants */
2419 else if (!(i0 & 1) &&
2420 #if __WORDSIZE == 32
2428 #if __WORDSIZE == 32
2430 IILH(r0, x16((jit_uword_t)i0 >> 16));
2433 if (i0 & 0xffffL) bits |= 1;
2434 if (i0 & 0xffff0000L) bits |= 2;
2435 if (i0 & 0xffff00000000L) bits |= 4;
2436 if (i0 & 0xffff000000000000L) bits |= 8;
2437 if (bits != 15) LGHI(r0, 0);
2438 if (bits & 1) IILL(r0, x16(i0));
2439 if (bits & 2) IILH(r0, x16((jit_uword_t)i0 >> 16));
2440 if (bits & 4) IIHL(r0, x16((jit_uword_t)i0 >> 32));
2441 if (bits & 8) IIHH(r0, x16((jit_uword_t)i0 >> 48));
2447 _movi_p(jit_state_t *_jit, jit_int32_t r0, jit_word_t i0)
2451 #if __WORDSIZE == 32
2456 IILH(r0, x16((jit_uword_t)i0 >> 16));
2457 #if __WORDSIZE == 64
2458 IIHL(r0, x16((jit_uword_t)i0 >> 32));
2459 IIHH(r0, x16((jit_uword_t)i0 >> 48));
2465 _movnr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2468 w = beqi_p(_jit->pc.w, r2, 0);
2469 #if __WORDSIZE == 32
2474 patch_at(w, _jit->pc.w);
2478 _movzr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2481 w = bnei_p(_jit->pc.w, r2, 0);
2482 #if __WORDSIZE == 32
2487 patch_at(w, _jit->pc.w);
2491 _bswapr_us(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1)
2499 _bswapr_ui(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1)
2502 # if __WORDSIZE == 64
2507 #if __WORDSIZE == 64
2509 _bswapr_ul(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1)
2516 _casx(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1,
2517 jit_int32_t r2, jit_int32_t r3, jit_word_t i0)
2519 jit_int32_t iscasi, r1_reg;
2520 if ((iscasi = (r1 == _NOREG))) {
2521 r1_reg = jit_get_reg_but_zero(0);
2525 /* Do not clobber r2 */
2527 /* The CS and CSG instructions below effectively do atomically:
2532 * So, we do not need to check cpu flags to know if it did work,
2533 * just compare if values are different.
2534 * Obviously it is somewhat of undefined behavior if old_value (r2)
2535 * and new_value (r3) have the same value, but should still work
2536 * as expected as a noop.
2538 # if __WORDSIZE == 32
2545 jit_unget_reg(r1_reg);
2549 _addr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2560 _addi(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2563 if (r0 == r1 && s16_p(i0))
2565 #if __WORDSIZE == 64
2567 LAY(r0, x20(i0), 0, r1);
2570 reg = jit_get_reg(jit_class_gpr);
2572 addr(r0, r1, rn(reg));
2578 _addcr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2589 _addci(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2592 reg = jit_get_reg(jit_class_gpr);
2594 addcr(r0, r1, rn(reg));
2599 _addxr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2610 _addxi(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2613 reg = jit_get_reg(jit_class_gpr);
2615 addxr(r0, r1, rn(reg));
2620 _subr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2624 reg = jit_get_reg(jit_class_gpr);
2637 _subi(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2640 if (r0 == r1 && s16_p(-i0))
2641 ADDI_(r0, x16(-i0));
2642 #if __WORDSIZE == 64
2643 else if (s20_p(-i0))
2644 LAY(r0, x20(-i0), 0, r1);
2647 reg = jit_get_reg(jit_class_gpr);
2649 subr(r0, r1, rn(reg));
2655 _subcr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2659 reg = jit_get_reg(jit_class_gpr);
2672 _subci(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2675 reg = jit_get_reg(jit_class_gpr);
2677 subcr(r0, r1, rn(reg));
2682 _subxr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2686 reg = jit_get_reg(jit_class_gpr);
2699 _subxi(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2702 reg = jit_get_reg(jit_class_gpr);
2704 subxr(r0, r1, rn(reg));
2709 _rsbi(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2716 _mulr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2727 _muli(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2735 reg = jit_get_reg(jit_class_gpr);
2737 mulr(r0, r1, rn(reg));
2743 _qmulr(jit_state_t *_jit,
2744 jit_int32_t r0, jit_int32_t r1, jit_int32_t r2, jit_int32_t r3)
2747 /* The only invalid condition is r0 == r1 */
2748 jit_int32_t t2, t3, s2, s3;
2749 if (r2 == r0 || r2 == r1) {
2750 s2 = jit_get_reg(jit_class_gpr);
2756 if (r3 == r0 || r3 == r1) {
2757 s3 = jit_get_reg(jit_class_gpr);
2763 qmulr_u(r0, r1, r2, r3);
2764 reg = jit_get_reg(jit_class_gpr);
2766 rshi(rn(reg), t2, 63);
2767 mulr(rn(reg), rn(reg), t3);
2768 addr(r1, r1, rn(reg));
2770 rshi(rn(reg), t3, 63);
2771 mulr(rn(reg), rn(reg), t2);
2772 addr(r1, r1, rn(reg));
2781 _qmuli(jit_state_t *_jit,
2782 jit_int32_t r0, jit_int32_t r1, jit_int32_t r2, jit_word_t i0)
2785 reg = jit_get_reg(jit_class_gpr);
2787 qmulr(r0, r1, r2, rn(reg));
2792 _qmulr_u(jit_state_t *_jit,
2793 jit_int32_t r0, jit_int32_t r1, jit_int32_t r2, jit_int32_t r3)
2796 regno = jit_get_reg_pair();
2797 movr(rn(regno) + 1, r2);
2798 MULU_(rn(regno), r3);
2799 movr(r0, rn(regno) + 1);
2800 movr(r1, rn(regno));
2801 jit_unget_reg_pair(regno);
2805 _qmuli_u(jit_state_t *_jit,
2806 jit_int32_t r0, jit_int32_t r1, jit_int32_t r2, jit_word_t i0)
2809 regno = jit_get_reg_pair();
2810 movr(rn(regno) + 1, r2);
2811 movi(rn(regno), i0);
2812 MULU_(rn(regno), rn(regno));
2813 movr(r0, rn(regno) + 1);
2814 movr(r1, rn(regno));
2815 jit_unget_reg_pair(regno);
2819 _divr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2822 regno = xdivr(r1, r2);
2823 movr(r0, rn(regno) + 1);
2827 _divi(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2830 regno = xdivi(r1, i0);
2831 movr(r0, rn(regno) + 1);
2835 _divr_u(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2838 regno = xdivr_u(r1, r2);
2839 movr(r0, rn(regno) + 1);
2843 _divi_u(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2846 regno = xdivi_u(r1, i0);
2847 movr(r0, rn(regno) + 1);
2851 _remr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2854 regno = xdivr(r1, r2);
2855 movr(r0, rn(regno));
2859 _remi(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2862 regno = xdivi(r1, i0);
2863 movr(r0, rn(regno));
2867 _remr_u(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2870 regno = xdivr_u(r1, r2);
2871 movr(r0, rn(regno));
2875 _remi_u(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2878 regno = xdivi_u(r1, i0);
2879 movr(r0, rn(regno));
2883 _qdivr(jit_state_t *_jit,
2884 jit_int32_t r0, jit_int32_t r1, jit_int32_t r2, jit_int32_t r3)
2887 regno = xdivr(r2, r3);
2888 movr(r0, rn(regno) + 1);
2889 movr(r1, rn(regno));
2893 _qdivi(jit_state_t *_jit,
2894 jit_int32_t r0, jit_int32_t r1, jit_int32_t r2, jit_word_t i0)
2897 regno = xdivi(r2, i0);
2898 movr(r0, rn(regno) + 1);
2899 movr(r1, rn(regno));
2903 _qdivr_u(jit_state_t *_jit,
2904 jit_int32_t r0, jit_int32_t r1, jit_int32_t r2, jit_int32_t r3)
2907 regno = xdivr_u(r2, r3);
2908 movr(r0, rn(regno) + 1);
2909 movr(r1, rn(regno));
2913 _qdivi_u(jit_state_t *_jit,
2914 jit_int32_t r0, jit_int32_t r1, jit_int32_t r2, jit_word_t i0)
2917 regno = xdivi_u(r2, i0);
2918 movr(r0, rn(regno) + 1);
2919 movr(r1, rn(regno));
2922 # if __WORDSIZE == 32
2924 _lshr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2928 reg = jit_get_reg_but_zero(0);
2931 SLL(r0, 0, rn(reg));
2932 jit_unget_reg_but_zero(reg);
2941 _lshi(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2948 _rshr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2952 reg = jit_get_reg_but_zero(0);
2955 SRA(r0, 0, rn(reg));
2956 jit_unget_reg_but_zero(reg);
2965 _rshi(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2972 _rshr_u(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
2976 reg = jit_get_reg_but_zero(0);
2979 SRL(r0, 0, rn(reg));
2980 jit_unget_reg_but_zero(reg);
2989 _rshi_u(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
2997 _bitswap(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1)
2999 jit_int32_t t0, t1, t2, t3, t4;
3001 t0 = jit_get_reg(jit_class_gpr);
3002 t1 = jit_get_reg(jit_class_gpr);
3003 t2 = jit_get_reg(jit_class_gpr);
3004 movi(rn(t0), __WORDSIZE == 32 ? 0x55555555L : 0x5555555555555555L);
3005 rshi_u(rn(t1), r0, 1); /* t1 = v >> 1 */
3006 andr(rn(t1), rn(t1), rn(t0)); /* t1 &= t0 */
3007 andr(rn(t2), r0, rn(t0)); /* t2 = v & t0*/
3008 lshi(rn(t2), rn(t2), 1); /* t2 <<= 1 */
3009 orr(r0, rn(t1), rn(t2)); /* v = t1 | t2 */
3010 movi(rn(t0), __WORDSIZE == 32 ? 0x33333333L : 0x3333333333333333L);
3011 rshi_u(rn(t1), r0, 2); /* t1 = v >> 2 */
3012 andr(rn(t1), rn(t1), rn(t0)); /* t1 &= t0 */
3013 andr(rn(t2), r0, rn(t0)); /* t2 = v & t0*/
3014 lshi(rn(t2), rn(t2), 2); /* t2 <<= 2 */
3015 orr(r0, rn(t1), rn(t2)); /* v = t1 | t2 */
3016 movi(rn(t0), __WORDSIZE == 32 ? 0x0f0f0f0fL : 0x0f0f0f0f0f0f0f0fL);
3017 rshi_u(rn(t1), r0, 4); /* t1 = v >> 4 */
3018 andr(rn(t1), rn(t1), rn(t0)); /* t1 &= t0 */
3019 andr(rn(t2), r0, rn(t0)); /* t2 = v & t0*/
3020 lshi(rn(t2), rn(t2), 4); /* t2 <<= 4 */
3021 orr(r0, rn(t1), rn(t2)); /* v = t1 | t2 */
3022 movi(rn(t0), __WORDSIZE == 32 ? 0x00ff00ffL : 0x00ff00ff00ff00ffL);
3023 rshi_u(rn(t1), r0, 8); /* t1 = v >> 8 */
3024 andr(rn(t1), rn(t1), rn(t0)); /* t1 &= t0 */
3025 andr(rn(t2), r0, rn(t0)); /* t2 = v & t0*/
3026 lshi(rn(t2), rn(t2), 8); /* t2 <<= 8 */
3027 orr(r0, rn(t1), rn(t2)); /* v = t1 | t2 */
3028 # if __WORDSIZE == 32
3029 rshi_u(rn(t1), r0, 16); /* t1 = v >> 16 */
3030 lshi(rn(t2), r0, 16); /* t2 = v << 16 */
3031 orr(r0, rn(t1), rn(t2)); /* v = t1 | t2 */
3033 movi(rn(t0), 0x0000ffff0000ffffL);
3034 rshi_u(rn(t1), r0, 16); /* t1 = v >> 16 */
3035 andr(rn(t1), rn(t1), rn(t0)); /* t1 &= t0 */
3036 andr(rn(t2), r0, rn(t0)); /* t2 = v & t0*/
3037 lshi(rn(t2), rn(t2), 16); /* t2 <<= 16 */
3038 orr(r0, rn(t1), rn(t2)); /* v = t1 | t2 */
3039 rshi_u(rn(t1), r0, 32); /* t1 = v >> 32 */
3040 lshi(rn(t2), r0, 32); /* t2 = v << 32 */
3041 orr(r0, rn(t1), rn(t2)); /* v = t1 | t2 */
3049 _clor(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1)
3052 if (jit_cpu.flogr) {
3059 fallback_clo(r0, r1);
3064 _clzr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1)
3067 if (jit_cpu.flogr) {
3069 #if __WORDSIZE == 32
3073 regno = jit_get_reg_pair();
3074 #if __WORDSIZE == 32
3075 SLLG(rn(regno), r1, 32, 0);
3077 movr(rn(regno), r1);
3079 FLOGR(rn(regno), rn(regno));
3080 movr(r0, rn(regno));
3081 #if __WORDSIZE == 32
3082 w = blei_p(_jit->pc.w, r0, 31);
3083 rshi(r0, r0, 1); /* r0 is 64 */
3084 patch_at(w, _jit->pc.w);
3086 jit_unget_reg_pair(regno);
3090 fallback_clz(r0, r1);
3095 _ctor(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1)
3098 if (jit_cpu.flogr) {
3105 fallback_cto(r0, r1);
3110 _ctzr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1)
3113 if (jit_cpu.flogr) {
3120 fallback_ctz(r0, r1);
3125 _comr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1)
3128 reg = jit_get_reg(jit_class_gpr);
3136 _andr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3147 _andi(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
3151 NILH(r0, x16((jit_uword_t)i0 >> 16));
3152 #if __WORDSIZE == 64
3153 NIHL(r0, x16((jit_uword_t)i0 >> 32));
3154 NIHH(r0, x16((jit_uword_t)i0 >> 48));
3159 _orr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3170 _ori(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
3174 OILH(r0, x16((jit_uword_t)i0 >> 16));
3175 #if __WORDSIZE == 64
3176 OIHL(r0, x16((jit_uword_t)i0 >> 32));
3177 OIHH(r0, x16((jit_uword_t)i0 >> 48));
3182 _xorr(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3193 _xori(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
3196 reg = jit_get_reg(jit_class_gpr);
3198 xorr(r0, r1, rn(reg));
3203 _ldi_c(jit_state_t *_jit, jit_int32_t r0, jit_word_t i0)
3210 _ldxr_c(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3224 _ldxi_c(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
3228 #if __WORDSIZE == 32
3229 LB(r0, x20(i0), 0, r1);
3231 LGB(r0, x20(i0), 0, r1);
3234 else if (r0 != r1) {
3240 reg = jit_get_reg_but_zero(0);
3242 addr(rn(reg), rn(reg), r1);
3244 jit_unget_reg_but_zero(reg);
3249 _ldi_uc(jit_state_t *_jit, jit_int32_t r0, jit_word_t i0)
3256 _ldxr_uc(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3270 _ldxi_uc(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
3274 LLGC(r0, x20(i0), 0, r1);
3275 else if (r0 != r1) {
3281 reg = jit_get_reg_but_zero(0);
3283 addr(rn(reg), rn(reg), r1);
3284 ldr_uc(r0, rn(reg));
3285 jit_unget_reg_but_zero(reg);
3290 _ldi_s(jit_state_t *_jit, jit_int32_t r0, jit_word_t i0)
3297 _ldxr_s(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3311 _ldxi_s(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
3314 #if __WORDSIZE == 32
3320 #if __WORDSIZE == 32
3321 LHY(r0, x20(i0), 0, r1);
3323 LGH(r0, x20(i0), 0, r1);
3326 else if (r0 != r1) {
3332 reg = jit_get_reg_but_zero(0);
3334 addr(rn(reg), rn(reg), r1);
3336 jit_unget_reg_but_zero(reg);
3341 _ldi_us(jit_state_t *_jit, jit_int32_t r0, jit_word_t i0)
3348 _ldxr_us(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3362 _ldxi_us(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
3366 LLGH(r0, x20(i0), 0, r1);
3367 else if (r0 != r1) {
3373 reg = jit_get_reg_but_zero(0);
3375 addr(rn(reg), rn(reg), r1);
3376 ldr_us(r0, rn(reg));
3377 jit_unget_reg_but_zero(reg);
3382 _ldi_i(jit_state_t *_jit, jit_int32_t r0, jit_word_t i0)
3389 _ldxr_i(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3403 _ldxi_i(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
3407 LGF(r0, x20(i0), 0, r1);
3408 else if (r0 != r1) {
3414 reg = jit_get_reg_but_zero(0);
3416 addr(rn(reg), rn(reg), r1);
3418 jit_unget_reg_but_zero(reg);
3422 #if __WORDSIZE == 64
3424 _ldi_ui(jit_state_t *_jit, jit_int32_t r0, jit_word_t i0)
3431 _ldxr_ui(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3445 _ldxi_ui(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
3449 LLGF(r0, x20(i0), 0, r1);
3450 else if (r0 != r1) {
3456 reg = jit_get_reg_but_zero(0);
3458 addr(rn(reg), rn(reg), r1);
3459 ldr_ui(r0, rn(reg));
3460 jit_unget_reg_but_zero(reg);
3465 _ldi_l(jit_state_t *_jit, jit_int32_t r0, jit_word_t i0)
3472 _ldxr_l(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3486 _ldxi_l(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_word_t i0)
3490 LG(r0, x20(i0), 0, r1);
3491 else if (r0 != r1) {
3497 reg = jit_get_reg_but_zero(0);
3499 addr(rn(reg), rn(reg), r1);
3501 jit_unget_reg_but_zero(reg);
3507 _sti_c(jit_state_t *_jit, jit_word_t i0, jit_int32_t r0)
3510 reg = jit_get_reg_but_zero(0);
3513 jit_unget_reg_but_zero(reg);
3517 _stxr_c(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3520 reg = jit_get_reg_but_zero(0);
3522 addr(rn(reg), rn(reg), r1);
3524 jit_unget_reg_but_zero(reg);
3528 _stxi_c(jit_state_t *_jit, jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
3534 STCY(r1, x20(i0), 0, r0);
3536 reg = jit_get_reg_but_zero(0);
3537 addi(rn(reg), r0, i0);
3539 jit_unget_reg_but_zero(reg);
3544 _sti_s(jit_state_t *_jit, jit_word_t i0, jit_int32_t r0)
3547 reg = jit_get_reg_but_zero(0);
3550 jit_unget_reg_but_zero(reg);
3554 _stxr_s(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3557 reg = jit_get_reg_but_zero(0);
3559 addr(rn(reg), rn(reg), r1);
3561 jit_unget_reg_but_zero(reg);
3565 _stxi_s(jit_state_t *_jit, jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
3571 STHY(r1, x20(i0), 0, r0);
3573 reg = jit_get_reg_but_zero(0);
3574 addi(rn(reg), r0, i0);
3576 jit_unget_reg_but_zero(reg);
3581 _sti_i(jit_state_t *_jit, jit_word_t i0, jit_int32_t r0)
3584 reg = jit_get_reg_but_zero(0);
3587 jit_unget_reg_but_zero(reg);
3591 _stxr_i(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3594 reg = jit_get_reg_but_zero(0);
3596 addr(rn(reg), rn(reg), r1);
3598 jit_unget_reg_but_zero(reg);
3602 _stxi_i(jit_state_t *_jit, jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
3608 STY(r1, x20(i0), 0, r0);
3610 reg = jit_get_reg_but_zero(0);
3611 addi(rn(reg), r0, i0);
3613 jit_unget_reg_but_zero(reg);
3617 #if __WORDSIZE == 64
3619 _sti_l(jit_state_t *_jit, jit_word_t i0, jit_int32_t r0)
3622 reg = jit_get_reg_but_zero(0);
3625 jit_unget_reg_but_zero(reg);
3629 _stxr_l(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1, jit_int32_t r2)
3632 reg = jit_get_reg_but_zero(0);
3634 addr(rn(reg), rn(reg), r1);
3636 jit_unget_reg_but_zero(reg);
3640 _stxi_l(jit_state_t *_jit, jit_word_t i0, jit_int32_t r0, jit_int32_t r1)
3644 STG(r1, x20(i0), 0, r0);
3646 reg = jit_get_reg_but_zero(0);
3647 addi(rn(reg), r0, i0);
3649 jit_unget_reg_but_zero(reg);
3655 _jmpi(jit_state_t *_jit, jit_word_t i0, jit_bool_t i1)
3666 reg = jit_get_reg_but_zero(jit_class_nospill);
3669 jit_unget_reg_but_zero(reg);
3675 _jmpi_p(jit_state_t *_jit, jit_word_t i0)
3679 reg = jit_get_reg_but_zero(jit_class_nospill);
3680 w = movi_p(rn(reg), i0);
3682 jit_unget_reg_but_zero(reg);
3687 _calli(jit_state_t *_jit, jit_word_t i0, jit_bool_t i1)
3694 BRAS(_R14_REGNO, x16(d));
3696 BRASL(_R14_REGNO, d);
3698 reg = jit_get_reg_but_zero(0);
3701 jit_unget_reg_but_zero(reg);
3707 _calli_p(jit_state_t *_jit, jit_word_t i0)
3711 reg = jit_get_reg_but_zero(0);
3712 w = movi_p(rn(reg), i0);
3714 jit_unget_reg_but_zero(reg);
3718 static jit_int32_t gprs[] = {
3720 _R6, _R7, _R8, _R9, _R10, _R11, _R12, _R13
3724 _prolog(jit_state_t *_jit, jit_node_t *i0)
3726 jit_int32_t regno, offset;
3727 if (_jitc->function->define_frame || _jitc->function->assume_frame) {
3728 jit_int32_t frame = -_jitc->function->frame;
3729 assert(_jitc->function->self.aoff >= frame);
3730 if (_jitc->function->assume_frame)
3732 _jitc->function->self.aoff = frame;
3734 if (_jitc->function->allocar)
3735 _jitc->function->self.aoff &= -8;
3736 _jitc->function->stack = ((_jitc->function->self.alen -
3737 /* align stack at 8 bytes */
3738 _jitc->function->self.aoff) + 7) & -8;
3739 /* *IFF* a non variadic function,
3740 * Lightning does not reserve stack space for spilling arguments
3742 * S390x, as per gcc, has 8 stack slots for spilling arguments,
3743 * (%r6 is callee save) and uses an alloca like approach to save
3744 * callee save fpr registers.
3745 * Since argument registers are not saved in any lightning port,
3746 * use the 8 slots to spill any modified fpr register, and still
3747 * use the same stack frame logic as gcc.
3748 * Save at least %r13 to %r15, as %r13 is used as frame pointer.
3749 * *IFF* a variadic function, a "standard" stack frame, with
3750 * fpr registers saved in an alloca'ed area, is used.
3752 if ((_jitc->function->self.call & jit_call_varargs) &&
3753 jit_arg_reg_p(_jitc->function->vagp))
3754 regno = _jitc->function->vagp;
3756 for (regno = 4; regno < jit_size(gprs) - 1; regno++) {
3757 if (jit_regset_tstbit(&_jitc->function->regset, gprs[regno]))
3761 #if __WORDSIZE == 32
3762 # define FP_OFFSET 64
3763 if (_jitc->function->self.call & jit_call_varargs)
3764 offset = regno * 4 + 8;
3766 offset = (regno - 4) * 4 + 32;
3767 STM(rn(gprs[regno]), _R15_REGNO, x20(offset), _R15_REGNO);
3769 # define FP_OFFSET 128
3770 if (_jitc->function->self.call & jit_call_varargs)
3771 offset = regno * 8 + 16;
3773 offset = (regno - 4) * 8 + 48;
3774 STMG(rn(gprs[regno]), _R15_REGNO, x20(offset), _R15_REGNO);
3777 #define SPILL(R, O) \
3779 if (jit_regset_tstbit(&_jitc->function->regset, R)) \
3780 stxi_d(O, _R15_REGNO, rn(R)); \
3782 if (_jitc->function->self.call & jit_call_varargs) {
3783 for (regno = _jitc->function->vafp; jit_arg_f_reg_p(regno); ++regno)
3784 stxi_d(FP_OFFSET + regno * 8, _R15_REGNO, rn(_F0 - regno));
3785 SPILL(_F8, _jitc->function->vaoff + offsetof(jit_va_list_t, f8));
3786 SPILL(_F9, _jitc->function->vaoff + offsetof(jit_va_list_t, f9));
3787 SPILL(_F10, _jitc->function->vaoff + offsetof(jit_va_list_t, f10));
3788 SPILL(_F11, _jitc->function->vaoff + offsetof(jit_va_list_t, f11));
3789 SPILL(_F12, _jitc->function->vaoff + offsetof(jit_va_list_t, f12));
3790 SPILL(_F13, _jitc->function->vaoff + offsetof(jit_va_list_t, f13));
3791 SPILL(_F14, _jitc->function->vaoff + offsetof(jit_va_list_t, f14));
3794 /* First 4 in low address */
3795 #if __WORDSIZE == 32
3800 /* gpr registers here */
3809 /* Last 3 in high address */
3816 movr(_R13_REGNO, _R15_REGNO);
3817 subi(_R15_REGNO, _R15_REGNO, stack_framesize + _jitc->function->stack);
3818 if (_jitc->function->allocar) {
3819 regno = jit_get_reg(jit_class_gpr);
3820 movi(rn(regno), _jitc->function->self.aoff);
3821 stxi_i(_jitc->function->aoffoff, _R13_REGNO, rn(regno));
3822 jit_unget_reg(regno);
3827 _epilog(jit_state_t *_jit, jit_node_t *i0)
3829 jit_int32_t regno, offset;
3830 if (_jitc->function->assume_frame)
3832 if ((_jitc->function->self.call & jit_call_varargs) &&
3833 jit_arg_reg_p(_jitc->function->vagp))
3834 regno = _jitc->function->vagp;
3836 for (regno = 4; regno < jit_size(gprs) - 1; regno++) {
3837 if (jit_regset_tstbit(&_jitc->function->regset, gprs[regno]))
3841 #if __WORDSIZE == 32
3842 if (_jitc->function->self.call & jit_call_varargs)
3843 offset = regno * 4 + 8;
3845 offset = (regno - 4) * 4 + 32;
3847 if (_jitc->function->self.call & jit_call_varargs)
3848 offset = regno * 8 + 16;
3850 offset = (regno - 4) * 8 + 48;
3852 movr(_R15_REGNO, _R13_REGNO);
3854 #define LOAD(R, O) \
3856 if (jit_regset_tstbit(&_jitc->function->regset, R)) \
3857 ldxi_d(rn(R), _R15_REGNO, O); \
3859 if (_jitc->function->self.call & jit_call_varargs) {
3860 LOAD(_F8, _jitc->function->vaoff + offsetof(jit_va_list_t, f8));
3861 LOAD(_F9, _jitc->function->vaoff + offsetof(jit_va_list_t, f9));
3862 LOAD(_F10, _jitc->function->vaoff + offsetof(jit_va_list_t, f10));
3863 LOAD(_F11, _jitc->function->vaoff + offsetof(jit_va_list_t, f11));
3864 LOAD(_F12, _jitc->function->vaoff + offsetof(jit_va_list_t, f12));
3865 LOAD(_F13, _jitc->function->vaoff + offsetof(jit_va_list_t, f13));
3866 LOAD(_F14, _jitc->function->vaoff + offsetof(jit_va_list_t, f14));
3869 #if __WORDSIZE == 32
3888 #if __WORDSIZE == 32
3889 LM(rn(gprs[regno]), _R15_REGNO, x20(offset), _R15_REGNO);
3891 LMG(rn(gprs[regno]), _R15_REGNO, x20(offset), _R15_REGNO);
3897 _vastart(jit_state_t *_jit, jit_int32_t r0)
3901 assert(_jitc->function->self.call & jit_call_varargs);
3903 /* Return jit_va_list_t in the register argument */
3904 addi(r0, _R13_REGNO, _jitc->function->vaoff);
3905 reg = jit_get_reg(jit_class_gpr);
3907 /* Initialize gp offset in the save area. */
3908 movi(rn(reg), _jitc->function->vagp);
3909 stxi(offsetof(jit_va_list_t, gpoff), r0, rn(reg));
3911 /* Initialize fp offset in the save area. */
3912 movi(rn(reg), _jitc->function->vafp);
3913 stxi(offsetof(jit_va_list_t, fpoff), r0, rn(reg));
3915 /* Initialize overflow pointer to the first stack argument. */
3916 addi(rn(reg), _R13_REGNO, _jitc->function->self.size);
3917 stxi(offsetof(jit_va_list_t, over), r0, rn(reg));
3919 /* Initialize register save area pointer. */
3920 stxi(offsetof(jit_va_list_t, save), r0, _R13_REGNO);
3926 _vaarg(jit_state_t *_jit, jit_int32_t r0, jit_int32_t r1)
3934 assert(_jitc->function->self.call & jit_call_varargs);
3936 rg0 = jit_get_reg_but_zero(0);
3937 rg1 = jit_get_reg_but_zero(0);
3939 /* Load the gp offset in save area in the first temporary. */
3940 ldxi(rn(rg0), r1, offsetof(jit_va_list_t, gpoff));
3942 /* Jump over if there are no remaining arguments in the save area. */
3943 ge_code = bgei_p(_jit->pc.w, rn(rg0), 5);
3945 /* Load the save area pointer in the second temporary. */
3946 ldxi(rn(rg1), r1, offsetof(jit_va_list_t, save));
3949 rg2 = jit_get_reg_but_zero(0);
3950 lshi(rn(rg2), rn(rg0),
3951 #if __WORDSIZE == 32
3957 /* Add offset to saved area. */
3958 addi(rn(rg2), rn(rg2), 2 * sizeof(jit_word_t));
3960 /* Load the vararg argument in the first argument. */
3961 ldxr(r0, rn(rg1), rn(rg2));
3962 jit_unget_reg_but_zero(rg2);
3964 /* Update the gp offset. */
3965 addi(rn(rg0), rn(rg0), 1);
3966 stxi(offsetof(jit_va_list_t, gpoff), r1, rn(rg0));
3968 /* Will only need one temporary register below. */
3969 jit_unget_reg_but_zero(rg1);
3971 /* Jump over overflow code. */
3972 lt_code = jmpi_p(_jit->pc.w);
3974 /* Where to land if argument is in overflow area. */
3975 patch_at(ge_code, _jit->pc.w);
3977 /* Load overflow pointer. */
3978 ldxi(rn(rg0), r1, offsetof(jit_va_list_t, over));
3980 /* Load argument. */
3983 /* Update overflow pointer. */
3984 addi(rn(rg0), rn(rg0), sizeof(jit_word_t));
3985 stxi(offsetof(jit_va_list_t, over), r1, rn(rg0));
3987 /* Where to land if argument is in save area. */
3988 patch_at(lt_code, _jit->pc.w);
3990 jit_unget_reg_but_zero(rg0);
3994 _patch_at(jit_state_t *_jit, jit_word_t instr, jit_word_t label)
4004 jit_uint16_t op : 8;
4005 jit_uint16_t r1 : 4;
4006 jit_uint16_t r3 : 4;
4018 jit_uint32_t ih : 16;
4019 jit_uint32_t il : 16;
4026 #if __WORDSIZE == 32
4027 0xA7 && i0.b.r3 == 8
4032 #if __WORDSIZE == 64
4033 assert(i0.b.r3 == 3);
4035 i1.b.i2 = (jit_uword_t)label;
4038 assert(i0.b.op == 0xA5 && i0.b.r3 == 2);
4039 i1.b.i2 = (jit_uword_t)label >> 16;
4041 #if __WORDSIZE == 64
4043 assert(i0.b.op == 0xA5 && i0.b.r3 == 1);
4044 i1.b.i2 = (jit_uword_t)label >> 32;
4047 assert(i0.b.op == 0xA5 && i0.b.r3 == 0);
4048 i1.b.i2 = (jit_uword_t)label >> 48;
4053 else if (i0.b.op == 0xA7) {
4054 assert(i0.b.r3 == 0x4 || i0.b.r3 == 0x5);
4055 d = (label - instr) >> 1;
4061 else if (i0.b.op == 0xC0) {
4062 assert(i0.b.r3 == 0x4 || i0.b.r3 == 0x5);
4063 d = (label - instr) >> 1;