1/*
2 * RISC-V translation routines for the RVV Standard Extension.
3 *
4 * Copyright (c) 2020 T-Head Semiconductor Co., Ltd. All rights reserved.
5 *
6 * This program is free software; you can redistribute it and/or modify it
7 * under the terms and conditions of the GNU General Public License,
8 * version 2 or later, as published by the Free Software Foundation.
9 *
10 * This program is distributed in the hope it will be useful, but WITHOUT
11 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
12 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License for
13 * more details.
14 *
15 * You should have received a copy of the GNU General Public License along with
16 * this program.  If not, see <http://www.gnu.org/licenses/>.
17 */
18#include "tcg/tcg-op-gvec.h"
19#include "tcg/tcg-gvec-desc.h"
20#include "internals.h"
21
22static inline bool is_overlapped(const int8_t astart, int8_t asize,
23                                 const int8_t bstart, int8_t bsize)
24{
25    const int8_t aend = astart + asize;
26    const int8_t bend = bstart + bsize;
27
28    return MAX(aend, bend) - MIN(astart, bstart) < asize + bsize;
29}
30
31static bool require_rvv(DisasContext *s)
32{
33    return s->mstatus_vs != 0;
34}
35
36static bool require_rvf(DisasContext *s)
37{
38    if (s->mstatus_fs == 0) {
39        return false;
40    }
41
42    switch (s->sew) {
43    case MO_16:
44    case MO_32:
45        return has_ext(s, RVF);
46    case MO_64:
47        return has_ext(s, RVD);
48    default:
49        return false;
50    }
51}
52
53static bool require_scale_rvf(DisasContext *s)
54{
55    if (s->mstatus_fs == 0) {
56        return false;
57    }
58
59    switch (s->sew) {
60    case MO_8:
61    case MO_16:
62        return has_ext(s, RVF);
63    case MO_32:
64        return has_ext(s, RVD);
65    default:
66        return false;
67    }
68}
69
70/* Destination vector register group cannot overlap source mask register. */
71static bool require_vm(int vm, int vd)
72{
73    return (vm != 0 || vd != 0);
74}
75
76static bool require_nf(int vd, int nf, int lmul)
77{
78    int size = nf << MAX(lmul, 0);
79    return size <= 8 && vd + size <= 32;
80}
81
82/*
83 * Vector register should aligned with the passed-in LMUL (EMUL).
84 * If LMUL < 0, i.e. fractional LMUL, any vector register is allowed.
85 */
86static bool require_align(const int8_t val, const int8_t lmul)
87{
88    return lmul <= 0 || extract32(val, 0, lmul) == 0;
89}
90
91/*
92 * A destination vector register group can overlap a source vector
93 * register group only if one of the following holds:
94 *  1. The destination EEW equals the source EEW.
95 *  2. The destination EEW is smaller than the source EEW and the overlap
96 *     is in the lowest-numbered part of the source register group.
97 *  3. The destination EEW is greater than the source EEW, the source EMUL
98 *     is at least 1, and the overlap is in the highest-numbered part of
99 *     the destination register group.
100 * (Section 5.2)
101 *
102 * This function returns true if one of the following holds:
103 *  * Destination vector register group does not overlap a source vector
104 *    register group.
105 *  * Rule 3 met.
106 * For rule 1, overlap is allowed so this function doesn't need to be called.
107 * For rule 2, (vd == vs). Caller has to check whether: (vd != vs) before
108 * calling this function.
109 */
110static bool require_noover(const int8_t dst, const int8_t dst_lmul,
111                           const int8_t src, const int8_t src_lmul)
112{
113    int8_t dst_size = dst_lmul <= 0 ? 1 : 1 << dst_lmul;
114    int8_t src_size = src_lmul <= 0 ? 1 : 1 << src_lmul;
115
116    /* Destination EEW is greater than the source EEW, check rule 3. */
117    if (dst_size > src_size) {
118        if (dst < src &&
119            src_lmul >= 0 &&
120            is_overlapped(dst, dst_size, src, src_size) &&
121            !is_overlapped(dst, dst_size, src + src_size, src_size)) {
122            return true;
123        }
124    }
125
126    return !is_overlapped(dst, dst_size, src, src_size);
127}
128
129static bool do_vsetvl(DisasContext *s, int rd, int rs1, TCGv s2)
130{
131    TCGv s1, dst;
132
133    if (!require_rvv(s) || !has_ext(s, RVV)) {
134        return false;
135    }
136
137    dst = dest_gpr(s, rd);
138
139    if (rd == 0 && rs1 == 0) {
140        s1 = tcg_temp_new();
141        tcg_gen_mov_tl(s1, cpu_vl);
142    } else if (rs1 == 0) {
143        /* As the mask is at least one bit, RV_VLEN_MAX is >= VLMAX */
144        s1 = tcg_constant_tl(RV_VLEN_MAX);
145    } else {
146        s1 = get_gpr(s, rs1, EXT_ZERO);
147    }
148
149    gen_helper_vsetvl(dst, cpu_env, s1, s2);
150    gen_set_gpr(s, rd, dst);
151    mark_vs_dirty(s);
152
153    tcg_gen_movi_tl(cpu_pc, s->pc_succ_insn);
154    tcg_gen_lookup_and_goto_ptr();
155    s->base.is_jmp = DISAS_NORETURN;
156
157    if (rd == 0 && rs1 == 0) {
158        tcg_temp_free(s1);
159    }
160
161    return true;
162}
163
164static bool trans_vsetvl(DisasContext *s, arg_vsetvl *a)
165{
166    TCGv s2 = get_gpr(s, a->rs2, EXT_ZERO);
167    return do_vsetvl(s, a->rd, a->rs1, s2);
168}
169
170static bool trans_vsetvli(DisasContext *s, arg_vsetvli *a)
171{
172    TCGv s2 = tcg_constant_tl(a->zimm);
173    return do_vsetvl(s, a->rd, a->rs1, s2);
174}
175
176/* vector register offset from env */
177static uint32_t vreg_ofs(DisasContext *s, int reg)
178{
179    return offsetof(CPURISCVState, vreg) + reg * s->vlen / 8;
180}
181
182/* check functions */
183
184/*
185 * Vector unit-stride, strided, unit-stride segment, strided segment
186 * store check function.
187 *
188 * Rules to be checked here:
189 *   1. EMUL must within the range: 1/8 <= EMUL <= 8. (Section 7.3)
190 *   2. Destination vector register number is multiples of EMUL.
191 *      (Section 3.4.2, 7.3)
192 *   3. The EMUL setting must be such that EMUL * NFIELDS ≤ 8. (Section 7.8)
193 *   4. Vector register numbers accessed by the segment load or store
194 *      cannot increment past 31. (Section 7.8)
195 */
196static bool vext_check_store(DisasContext *s, int vd, int nf, uint8_t eew)
197{
198    int8_t emul = eew - s->sew + s->lmul;
199    return (emul >= -3 && emul <= 3) &&
200            require_align(vd, emul) &&
201            require_nf(vd, nf, emul);
202}
203
204/*
205 * Vector unit-stride, strided, unit-stride segment, strided segment
206 * load check function.
207 *
208 * Rules to be checked here:
209 *   1. All rules applies to store instructions are applies
210 *      to load instructions.
211 *   2. Destination vector register group for a masked vector
212 *      instruction cannot overlap the source mask register (v0).
213 *      (Section 5.3)
214 */
215static bool vext_check_load(DisasContext *s, int vd, int nf, int vm,
216                            uint8_t eew)
217{
218    return vext_check_store(s, vd, nf, eew) && require_vm(vm, vd);
219}
220
221/*
222 * Vector indexed, indexed segment store check function.
223 *
224 * Rules to be checked here:
225 *   1. EMUL must within the range: 1/8 <= EMUL <= 8. (Section 7.3)
226 *   2. Index vector register number is multiples of EMUL.
227 *      (Section 3.4.2, 7.3)
228 *   3. Destination vector register number is multiples of LMUL.
229 *      (Section 3.4.2, 7.3)
230 *   4. The EMUL setting must be such that EMUL * NFIELDS ≤ 8. (Section 7.8)
231 *   5. Vector register numbers accessed by the segment load or store
232 *      cannot increment past 31. (Section 7.8)
233 */
234static bool vext_check_st_index(DisasContext *s, int vd, int vs2, int nf,
235                                uint8_t eew)
236{
237    int8_t emul = eew - s->sew + s->lmul;
238    return (emul >= -3 && emul <= 3) &&
239            require_align(vs2, emul) &&
240            require_align(vd, s->lmul) &&
241            require_nf(vd, nf, s->lmul);
242}
243
244/*
245 * Vector indexed, indexed segment load check function.
246 *
247 * Rules to be checked here:
248 *   1. All rules applies to store instructions are applies
249 *      to load instructions.
250 *   2. Destination vector register group for a masked vector
251 *      instruction cannot overlap the source mask register (v0).
252 *      (Section 5.3)
253 *   3. Destination vector register cannot overlap a source vector
254 *      register (vs2) group.
255 *      (Section 5.2)
256 *   4. Destination vector register groups cannot overlap
257 *      the source vector register (vs2) group for
258 *      indexed segment load instructions. (Section 7.8.3)
259 */
260static bool vext_check_ld_index(DisasContext *s, int vd, int vs2,
261                                int nf, int vm, uint8_t eew)
262{
263    int8_t seg_vd;
264    int8_t emul = eew - s->sew + s->lmul;
265    bool ret = vext_check_st_index(s, vd, vs2, nf, eew) &&
266        require_vm(vm, vd);
267
268    /* Each segment register group has to follow overlap rules. */
269    for (int i = 0; i < nf; ++i) {
270        seg_vd = vd + (1 << MAX(s->lmul, 0)) * i;
271
272        if (eew > s->sew) {
273            if (seg_vd != vs2) {
274                ret &= require_noover(seg_vd, s->lmul, vs2, emul);
275            }
276        } else if (eew < s->sew) {
277            ret &= require_noover(seg_vd, s->lmul, vs2, emul);
278        }
279
280        /*
281         * Destination vector register groups cannot overlap
282         * the source vector register (vs2) group for
283         * indexed segment load instructions.
284         */
285        if (nf > 1) {
286            ret &= !is_overlapped(seg_vd, 1 << MAX(s->lmul, 0),
287                                  vs2, 1 << MAX(emul, 0));
288        }
289    }
290    return ret;
291}
292
293static bool vext_check_ss(DisasContext *s, int vd, int vs, int vm)
294{
295    return require_vm(vm, vd) &&
296        require_align(vd, s->lmul) &&
297        require_align(vs, s->lmul);
298}
299
300/*
301 * Check function for vector instruction with format:
302 * single-width result and single-width sources (SEW = SEW op SEW)
303 *
304 * Rules to be checked here:
305 *   1. Destination vector register group for a masked vector
306 *      instruction cannot overlap the source mask register (v0).
307 *      (Section 5.3)
308 *   2. Destination vector register number is multiples of LMUL.
309 *      (Section 3.4.2)
310 *   3. Source (vs2, vs1) vector register number are multiples of LMUL.
311 *      (Section 3.4.2)
312 */
313static bool vext_check_sss(DisasContext *s, int vd, int vs1, int vs2, int vm)
314{
315    return vext_check_ss(s, vd, vs2, vm) &&
316        require_align(vs1, s->lmul);
317}
318
319static bool vext_check_ms(DisasContext *s, int vd, int vs)
320{
321    bool ret = require_align(vs, s->lmul);
322    if (vd != vs) {
323        ret &= require_noover(vd, 0, vs, s->lmul);
324    }
325    return ret;
326}
327
328/*
329 * Check function for maskable vector instruction with format:
330 * single-width result and single-width sources (SEW = SEW op SEW)
331 *
332 * Rules to be checked here:
333 *   1. Source (vs2, vs1) vector register number are multiples of LMUL.
334 *      (Section 3.4.2)
335 *   2. Destination vector register cannot overlap a source vector
336 *      register (vs2, vs1) group.
337 *      (Section 5.2)
338 *   3. The destination vector register group for a masked vector
339 *      instruction cannot overlap the source mask register (v0),
340 *      unless the destination vector register is being written
341 *      with a mask value (e.g., comparisons) or the scalar result
342 *      of a reduction. (Section 5.3)
343 */
344static bool vext_check_mss(DisasContext *s, int vd, int vs1, int vs2)
345{
346    bool ret = vext_check_ms(s, vd, vs2) &&
347        require_align(vs1, s->lmul);
348    if (vd != vs1) {
349        ret &= require_noover(vd, 0, vs1, s->lmul);
350    }
351    return ret;
352}
353
354/*
355 * Common check function for vector widening instructions
356 * of double-width result (2*SEW).
357 *
358 * Rules to be checked here:
359 *   1. The largest vector register group used by an instruction
360 *      can not be greater than 8 vector registers (Section 5.2):
361 *      => LMUL < 8.
362 *      => SEW < 64.
363 *   2. Destination vector register number is multiples of 2 * LMUL.
364 *      (Section 3.4.2)
365 *   3. Destination vector register group for a masked vector
366 *      instruction cannot overlap the source mask register (v0).
367 *      (Section 5.3)
368 */
369static bool vext_wide_check_common(DisasContext *s, int vd, int vm)
370{
371    return (s->lmul <= 2) &&
372           (s->sew < MO_64) &&
373           require_align(vd, s->lmul + 1) &&
374           require_vm(vm, vd);
375}
376
377/*
378 * Common check function for vector narrowing instructions
379 * of single-width result (SEW) and double-width source (2*SEW).
380 *
381 * Rules to be checked here:
382 *   1. The largest vector register group used by an instruction
383 *      can not be greater than 8 vector registers (Section 5.2):
384 *      => LMUL < 8.
385 *      => SEW < 64.
386 *   2. Source vector register number is multiples of 2 * LMUL.
387 *      (Section 3.4.2)
388 *   3. Destination vector register number is multiples of LMUL.
389 *      (Section 3.4.2)
390 *   4. Destination vector register group for a masked vector
391 *      instruction cannot overlap the source mask register (v0).
392 *      (Section 5.3)
393 */
394static bool vext_narrow_check_common(DisasContext *s, int vd, int vs2,
395                                     int vm)
396{
397    return (s->lmul <= 2) &&
398           (s->sew < MO_64) &&
399           require_align(vs2, s->lmul + 1) &&
400           require_align(vd, s->lmul) &&
401           require_vm(vm, vd);
402}
403
404static bool vext_check_ds(DisasContext *s, int vd, int vs, int vm)
405{
406    return vext_wide_check_common(s, vd, vm) &&
407        require_align(vs, s->lmul) &&
408        require_noover(vd, s->lmul + 1, vs, s->lmul);
409}
410
411static bool vext_check_dd(DisasContext *s, int vd, int vs, int vm)
412{
413    return vext_wide_check_common(s, vd, vm) &&
414        require_align(vs, s->lmul + 1);
415}
416
417/*
418 * Check function for vector instruction with format:
419 * double-width result and single-width sources (2*SEW = SEW op SEW)
420 *
421 * Rules to be checked here:
422 *   1. All rules in defined in widen common rules are applied.
423 *   2. Source (vs2, vs1) vector register number are multiples of LMUL.
424 *      (Section 3.4.2)
425 *   3. Destination vector register cannot overlap a source vector
426 *      register (vs2, vs1) group.
427 *      (Section 5.2)
428 */
429static bool vext_check_dss(DisasContext *s, int vd, int vs1, int vs2, int vm)
430{
431    return vext_check_ds(s, vd, vs2, vm) &&
432        require_align(vs1, s->lmul) &&
433        require_noover(vd, s->lmul + 1, vs1, s->lmul);
434}
435
436/*
437 * Check function for vector instruction with format:
438 * double-width result and double-width source1 and single-width
439 * source2 (2*SEW = 2*SEW op SEW)
440 *
441 * Rules to be checked here:
442 *   1. All rules in defined in widen common rules are applied.
443 *   2. Source 1 (vs2) vector register number is multiples of 2 * LMUL.
444 *      (Section 3.4.2)
445 *   3. Source 2 (vs1) vector register number is multiples of LMUL.
446 *      (Section 3.4.2)
447 *   4. Destination vector register cannot overlap a source vector
448 *      register (vs1) group.
449 *      (Section 5.2)
450 */
451static bool vext_check_dds(DisasContext *s, int vd, int vs1, int vs2, int vm)
452{
453    return vext_check_ds(s, vd, vs1, vm) &&
454        require_align(vs2, s->lmul + 1);
455}
456
457static bool vext_check_sd(DisasContext *s, int vd, int vs, int vm)
458{
459    bool ret = vext_narrow_check_common(s, vd, vs, vm);
460    if (vd != vs) {
461        ret &= require_noover(vd, s->lmul, vs, s->lmul + 1);
462    }
463    return ret;
464}
465
466/*
467 * Check function for vector instruction with format:
468 * single-width result and double-width source 1 and single-width
469 * source 2 (SEW = 2*SEW op SEW)
470 *
471 * Rules to be checked here:
472 *   1. All rules in defined in narrow common rules are applied.
473 *   2. Destination vector register cannot overlap a source vector
474 *      register (vs2) group.
475 *      (Section 5.2)
476 *   3. Source 2 (vs1) vector register number is multiples of LMUL.
477 *      (Section 3.4.2)
478 */
479static bool vext_check_sds(DisasContext *s, int vd, int vs1, int vs2, int vm)
480{
481    return vext_check_sd(s, vd, vs2, vm) &&
482        require_align(vs1, s->lmul);
483}
484
485/*
486 * Check function for vector reduction instructions.
487 *
488 * Rules to be checked here:
489 *   1. Source 1 (vs2) vector register number is multiples of LMUL.
490 *      (Section 3.4.2)
491 */
492static bool vext_check_reduction(DisasContext *s, int vs2)
493{
494    return require_align(vs2, s->lmul);
495}
496
497/*
498 * Check function for vector slide instructions.
499 *
500 * Rules to be checked here:
501 *   1. Source 1 (vs2) vector register number is multiples of LMUL.
502 *      (Section 3.4.2)
503 *   2. Destination vector register number is multiples of LMUL.
504 *      (Section 3.4.2)
505 *   3. Destination vector register group for a masked vector
506 *      instruction cannot overlap the source mask register (v0).
507 *      (Section 5.3)
508 *   4. The destination vector register group for vslideup, vslide1up,
509 *      vfslide1up, cannot overlap the source vector register (vs2) group.
510 *      (Section 5.2, 16.3.1, 16.3.3)
511 */
512static bool vext_check_slide(DisasContext *s, int vd, int vs2,
513                             int vm, bool is_over)
514{
515    bool ret = require_align(vs2, s->lmul) &&
516               require_align(vd, s->lmul) &&
517               require_vm(vm, vd);
518    if (is_over) {
519        ret &= (vd != vs2);
520    }
521    return ret;
522}
523
524/*
525 * In cpu_get_tb_cpu_state(), set VILL if RVV was not present.
526 * So RVV is also be checked in this function.
527 */
528static bool vext_check_isa_ill(DisasContext *s)
529{
530    return !s->vill;
531}
532
533/* common translation macro */
534#define GEN_VEXT_TRANS(NAME, EEW, ARGTYPE, OP, CHECK)        \
535static bool trans_##NAME(DisasContext *s, arg_##ARGTYPE * a) \
536{                                                            \
537    if (CHECK(s, a, EEW)) {                                  \
538        return OP(s, a, EEW);                                \
539    }                                                        \
540    return false;                                            \
541}
542
543static uint8_t vext_get_emul(DisasContext *s, uint8_t eew)
544{
545    int8_t emul = eew - s->sew + s->lmul;
546    return emul < 0 ? 0 : emul;
547}
548
549/*
550 *** unit stride load and store
551 */
552typedef void gen_helper_ldst_us(TCGv_ptr, TCGv_ptr, TCGv,
553                                TCGv_env, TCGv_i32);
554
555static bool ldst_us_trans(uint32_t vd, uint32_t rs1, uint32_t data,
556                          gen_helper_ldst_us *fn, DisasContext *s,
557                          bool is_store)
558{
559    TCGv_ptr dest, mask;
560    TCGv base;
561    TCGv_i32 desc;
562
563    TCGLabel *over = gen_new_label();
564    tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
565
566    dest = tcg_temp_new_ptr();
567    mask = tcg_temp_new_ptr();
568    base = get_gpr(s, rs1, EXT_NONE);
569
570    /*
571     * As simd_desc supports at most 256 bytes, and in this implementation,
572     * the max vector group length is 2048 bytes. So split it into two parts.
573     *
574     * The first part is vlen in bytes, encoded in maxsz of simd_desc.
575     * The second part is lmul, encoded in data of simd_desc.
576     */
577    desc = tcg_constant_i32(simd_desc(s->vlen / 8, s->vlen / 8, data));
578
579    tcg_gen_addi_ptr(dest, cpu_env, vreg_ofs(s, vd));
580    tcg_gen_addi_ptr(mask, cpu_env, vreg_ofs(s, 0));
581
582    fn(dest, mask, base, cpu_env, desc);
583
584    tcg_temp_free_ptr(dest);
585    tcg_temp_free_ptr(mask);
586
587    if (!is_store) {
588        mark_vs_dirty(s);
589    }
590
591    gen_set_label(over);
592    return true;
593}
594
595static bool ld_us_op(DisasContext *s, arg_r2nfvm *a, uint8_t eew)
596{
597    uint32_t data = 0;
598    gen_helper_ldst_us *fn;
599    static gen_helper_ldst_us * const fns[2][4] = {
600        /* masked unit stride load */
601        { gen_helper_vle8_v_mask, gen_helper_vle16_v_mask,
602          gen_helper_vle32_v_mask, gen_helper_vle64_v_mask },
603        /* unmasked unit stride load */
604        { gen_helper_vle8_v, gen_helper_vle16_v,
605          gen_helper_vle32_v, gen_helper_vle64_v }
606    };
607
608    fn =  fns[a->vm][eew];
609    if (fn == NULL) {
610        return false;
611    }
612
613    /*
614     * Vector load/store instructions have the EEW encoded
615     * directly in the instructions. The maximum vector size is
616     * calculated with EMUL rather than LMUL.
617     */
618    uint8_t emul = vext_get_emul(s, eew);
619    data = FIELD_DP32(data, VDATA, VM, a->vm);
620    data = FIELD_DP32(data, VDATA, LMUL, emul);
621    data = FIELD_DP32(data, VDATA, NF, a->nf);
622    return ldst_us_trans(a->rd, a->rs1, data, fn, s, false);
623}
624
625static bool ld_us_check(DisasContext *s, arg_r2nfvm* a, uint8_t eew)
626{
627    return require_rvv(s) &&
628           vext_check_isa_ill(s) &&
629           vext_check_load(s, a->rd, a->nf, a->vm, eew);
630}
631
632GEN_VEXT_TRANS(vle8_v,  MO_8,  r2nfvm, ld_us_op, ld_us_check)
633GEN_VEXT_TRANS(vle16_v, MO_16, r2nfvm, ld_us_op, ld_us_check)
634GEN_VEXT_TRANS(vle32_v, MO_32, r2nfvm, ld_us_op, ld_us_check)
635GEN_VEXT_TRANS(vle64_v, MO_64, r2nfvm, ld_us_op, ld_us_check)
636
637static bool st_us_op(DisasContext *s, arg_r2nfvm *a, uint8_t eew)
638{
639    uint32_t data = 0;
640    gen_helper_ldst_us *fn;
641    static gen_helper_ldst_us * const fns[2][4] = {
642        /* masked unit stride store */
643        { gen_helper_vse8_v_mask, gen_helper_vse16_v_mask,
644          gen_helper_vse32_v_mask, gen_helper_vse64_v_mask },
645        /* unmasked unit stride store */
646        { gen_helper_vse8_v, gen_helper_vse16_v,
647          gen_helper_vse32_v, gen_helper_vse64_v }
648    };
649
650    fn =  fns[a->vm][eew];
651    if (fn == NULL) {
652        return false;
653    }
654
655    uint8_t emul = vext_get_emul(s, eew);
656    data = FIELD_DP32(data, VDATA, VM, a->vm);
657    data = FIELD_DP32(data, VDATA, LMUL, emul);
658    data = FIELD_DP32(data, VDATA, NF, a->nf);
659    return ldst_us_trans(a->rd, a->rs1, data, fn, s, true);
660}
661
662static bool st_us_check(DisasContext *s, arg_r2nfvm* a, uint8_t eew)
663{
664    return require_rvv(s) &&
665           vext_check_isa_ill(s) &&
666           vext_check_store(s, a->rd, a->nf, eew);
667}
668
669GEN_VEXT_TRANS(vse8_v,  MO_8,  r2nfvm, st_us_op, st_us_check)
670GEN_VEXT_TRANS(vse16_v, MO_16, r2nfvm, st_us_op, st_us_check)
671GEN_VEXT_TRANS(vse32_v, MO_32, r2nfvm, st_us_op, st_us_check)
672GEN_VEXT_TRANS(vse64_v, MO_64, r2nfvm, st_us_op, st_us_check)
673
674/*
675 *** stride load and store
676 */
677typedef void gen_helper_ldst_stride(TCGv_ptr, TCGv_ptr, TCGv,
678                                    TCGv, TCGv_env, TCGv_i32);
679
680static bool ldst_stride_trans(uint32_t vd, uint32_t rs1, uint32_t rs2,
681                              uint32_t data, gen_helper_ldst_stride *fn,
682                              DisasContext *s, bool is_store)
683{
684    TCGv_ptr dest, mask;
685    TCGv base, stride;
686    TCGv_i32 desc;
687
688    TCGLabel *over = gen_new_label();
689    tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
690
691    dest = tcg_temp_new_ptr();
692    mask = tcg_temp_new_ptr();
693    base = get_gpr(s, rs1, EXT_NONE);
694    stride = get_gpr(s, rs2, EXT_NONE);
695    desc = tcg_constant_i32(simd_desc(s->vlen / 8, s->vlen / 8, data));
696
697    tcg_gen_addi_ptr(dest, cpu_env, vreg_ofs(s, vd));
698    tcg_gen_addi_ptr(mask, cpu_env, vreg_ofs(s, 0));
699
700    fn(dest, mask, base, stride, cpu_env, desc);
701
702    tcg_temp_free_ptr(dest);
703    tcg_temp_free_ptr(mask);
704
705    if (!is_store) {
706        mark_vs_dirty(s);
707    }
708
709    gen_set_label(over);
710    return true;
711}
712
713static bool ld_stride_op(DisasContext *s, arg_rnfvm *a, uint8_t eew)
714{
715    uint32_t data = 0;
716    gen_helper_ldst_stride *fn;
717    static gen_helper_ldst_stride * const fns[4] = {
718        gen_helper_vlse8_v, gen_helper_vlse16_v,
719        gen_helper_vlse32_v, gen_helper_vlse64_v
720    };
721
722    fn = fns[eew];
723    if (fn == NULL) {
724        return false;
725    }
726
727    uint8_t emul = vext_get_emul(s, eew);
728    data = FIELD_DP32(data, VDATA, VM, a->vm);
729    data = FIELD_DP32(data, VDATA, LMUL, emul);
730    data = FIELD_DP32(data, VDATA, NF, a->nf);
731    return ldst_stride_trans(a->rd, a->rs1, a->rs2, data, fn, s, false);
732}
733
734static bool ld_stride_check(DisasContext *s, arg_rnfvm* a, uint8_t eew)
735{
736    return require_rvv(s) &&
737           vext_check_isa_ill(s) &&
738           vext_check_load(s, a->rd, a->nf, a->vm, eew);
739}
740
741GEN_VEXT_TRANS(vlse8_v,  MO_8,  rnfvm, ld_stride_op, ld_stride_check)
742GEN_VEXT_TRANS(vlse16_v, MO_16, rnfvm, ld_stride_op, ld_stride_check)
743GEN_VEXT_TRANS(vlse32_v, MO_32, rnfvm, ld_stride_op, ld_stride_check)
744GEN_VEXT_TRANS(vlse64_v, MO_64, rnfvm, ld_stride_op, ld_stride_check)
745
746static bool st_stride_op(DisasContext *s, arg_rnfvm *a, uint8_t eew)
747{
748    uint32_t data = 0;
749    gen_helper_ldst_stride *fn;
750    static gen_helper_ldst_stride * const fns[4] = {
751        /* masked stride store */
752        gen_helper_vsse8_v,  gen_helper_vsse16_v,
753        gen_helper_vsse32_v,  gen_helper_vsse64_v
754    };
755
756    uint8_t emul = vext_get_emul(s, eew);
757    data = FIELD_DP32(data, VDATA, VM, a->vm);
758    data = FIELD_DP32(data, VDATA, LMUL, emul);
759    data = FIELD_DP32(data, VDATA, NF, a->nf);
760    fn = fns[eew];
761    if (fn == NULL) {
762        return false;
763    }
764
765    return ldst_stride_trans(a->rd, a->rs1, a->rs2, data, fn, s, true);
766}
767
768static bool st_stride_check(DisasContext *s, arg_rnfvm* a, uint8_t eew)
769{
770    return require_rvv(s) &&
771           vext_check_isa_ill(s) &&
772           vext_check_store(s, a->rd, a->nf, eew);
773}
774
775GEN_VEXT_TRANS(vsse8_v,  MO_8,  rnfvm, st_stride_op, st_stride_check)
776GEN_VEXT_TRANS(vsse16_v, MO_16, rnfvm, st_stride_op, st_stride_check)
777GEN_VEXT_TRANS(vsse32_v, MO_32, rnfvm, st_stride_op, st_stride_check)
778GEN_VEXT_TRANS(vsse64_v, MO_64, rnfvm, st_stride_op, st_stride_check)
779
780/*
781 *** index load and store
782 */
783typedef void gen_helper_ldst_index(TCGv_ptr, TCGv_ptr, TCGv,
784                                   TCGv_ptr, TCGv_env, TCGv_i32);
785
786static bool ldst_index_trans(uint32_t vd, uint32_t rs1, uint32_t vs2,
787                             uint32_t data, gen_helper_ldst_index *fn,
788                             DisasContext *s, bool is_store)
789{
790    TCGv_ptr dest, mask, index;
791    TCGv base;
792    TCGv_i32 desc;
793
794    TCGLabel *over = gen_new_label();
795    tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
796
797    dest = tcg_temp_new_ptr();
798    mask = tcg_temp_new_ptr();
799    index = tcg_temp_new_ptr();
800    base = get_gpr(s, rs1, EXT_NONE);
801    desc = tcg_constant_i32(simd_desc(s->vlen / 8, s->vlen / 8, data));
802
803    tcg_gen_addi_ptr(dest, cpu_env, vreg_ofs(s, vd));
804    tcg_gen_addi_ptr(index, cpu_env, vreg_ofs(s, vs2));
805    tcg_gen_addi_ptr(mask, cpu_env, vreg_ofs(s, 0));
806
807    fn(dest, mask, base, index, cpu_env, desc);
808
809    tcg_temp_free_ptr(dest);
810    tcg_temp_free_ptr(mask);
811    tcg_temp_free_ptr(index);
812
813    if (!is_store) {
814        mark_vs_dirty(s);
815    }
816
817    gen_set_label(over);
818    return true;
819}
820
821static bool ld_index_op(DisasContext *s, arg_rnfvm *a, uint8_t eew)
822{
823    uint32_t data = 0;
824    gen_helper_ldst_index *fn;
825    static gen_helper_ldst_index * const fns[4][4] = {
826        /*
827         * offset vector register group EEW = 8,
828         * data vector register group EEW = SEW
829         */
830        { gen_helper_vlxei8_8_v,  gen_helper_vlxei8_16_v,
831          gen_helper_vlxei8_32_v, gen_helper_vlxei8_64_v },
832        /*
833         * offset vector register group EEW = 16,
834         * data vector register group EEW = SEW
835         */
836        { gen_helper_vlxei16_8_v, gen_helper_vlxei16_16_v,
837          gen_helper_vlxei16_32_v, gen_helper_vlxei16_64_v },
838        /*
839         * offset vector register group EEW = 32,
840         * data vector register group EEW = SEW
841         */
842        { gen_helper_vlxei32_8_v, gen_helper_vlxei32_16_v,
843          gen_helper_vlxei32_32_v, gen_helper_vlxei32_64_v },
844        /*
845         * offset vector register group EEW = 64,
846         * data vector register group EEW = SEW
847         */
848        { gen_helper_vlxei64_8_v, gen_helper_vlxei64_16_v,
849          gen_helper_vlxei64_32_v, gen_helper_vlxei64_64_v }
850    };
851
852    fn = fns[eew][s->sew];
853
854    uint8_t emul = vext_get_emul(s, s->sew);
855    data = FIELD_DP32(data, VDATA, VM, a->vm);
856    data = FIELD_DP32(data, VDATA, LMUL, emul);
857    data = FIELD_DP32(data, VDATA, NF, a->nf);
858    return ldst_index_trans(a->rd, a->rs1, a->rs2, data, fn, s, false);
859}
860
861static bool ld_index_check(DisasContext *s, arg_rnfvm* a, uint8_t eew)
862{
863    return require_rvv(s) &&
864           vext_check_isa_ill(s) &&
865           vext_check_ld_index(s, a->rd, a->rs2, a->nf, a->vm, eew);
866}
867
868GEN_VEXT_TRANS(vlxei8_v,  MO_8,  rnfvm, ld_index_op, ld_index_check)
869GEN_VEXT_TRANS(vlxei16_v, MO_16, rnfvm, ld_index_op, ld_index_check)
870GEN_VEXT_TRANS(vlxei32_v, MO_32, rnfvm, ld_index_op, ld_index_check)
871GEN_VEXT_TRANS(vlxei64_v, MO_64, rnfvm, ld_index_op, ld_index_check)
872
873static bool st_index_op(DisasContext *s, arg_rnfvm *a, uint8_t eew)
874{
875    uint32_t data = 0;
876    gen_helper_ldst_index *fn;
877    static gen_helper_ldst_index * const fns[4][4] = {
878        /*
879         * offset vector register group EEW = 8,
880         * data vector register group EEW = SEW
881         */
882        { gen_helper_vsxei8_8_v,  gen_helper_vsxei8_16_v,
883          gen_helper_vsxei8_32_v, gen_helper_vsxei8_64_v },
884        /*
885         * offset vector register group EEW = 16,
886         * data vector register group EEW = SEW
887         */
888        { gen_helper_vsxei16_8_v, gen_helper_vsxei16_16_v,
889          gen_helper_vsxei16_32_v, gen_helper_vsxei16_64_v },
890        /*
891         * offset vector register group EEW = 32,
892         * data vector register group EEW = SEW
893         */
894        { gen_helper_vsxei32_8_v, gen_helper_vsxei32_16_v,
895          gen_helper_vsxei32_32_v, gen_helper_vsxei32_64_v },
896        /*
897         * offset vector register group EEW = 64,
898         * data vector register group EEW = SEW
899         */
900        { gen_helper_vsxei64_8_v, gen_helper_vsxei64_16_v,
901          gen_helper_vsxei64_32_v, gen_helper_vsxei64_64_v }
902    };
903
904    fn = fns[eew][s->sew];
905
906    uint8_t emul = vext_get_emul(s, s->sew);
907    data = FIELD_DP32(data, VDATA, VM, a->vm);
908    data = FIELD_DP32(data, VDATA, LMUL, emul);
909    data = FIELD_DP32(data, VDATA, NF, a->nf);
910    return ldst_index_trans(a->rd, a->rs1, a->rs2, data, fn, s, true);
911}
912
913static bool st_index_check(DisasContext *s, arg_rnfvm* a, uint8_t eew)
914{
915    return require_rvv(s) &&
916           vext_check_isa_ill(s) &&
917           vext_check_st_index(s, a->rd, a->rs2, a->nf, eew);
918}
919
920GEN_VEXT_TRANS(vsxei8_v,  MO_8,  rnfvm, st_index_op, st_index_check)
921GEN_VEXT_TRANS(vsxei16_v, MO_16, rnfvm, st_index_op, st_index_check)
922GEN_VEXT_TRANS(vsxei32_v, MO_32, rnfvm, st_index_op, st_index_check)
923GEN_VEXT_TRANS(vsxei64_v, MO_64, rnfvm, st_index_op, st_index_check)
924
925/*
926 *** unit stride fault-only-first load
927 */
928static bool ldff_trans(uint32_t vd, uint32_t rs1, uint32_t data,
929                       gen_helper_ldst_us *fn, DisasContext *s)
930{
931    TCGv_ptr dest, mask;
932    TCGv base;
933    TCGv_i32 desc;
934
935    TCGLabel *over = gen_new_label();
936    tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
937
938    dest = tcg_temp_new_ptr();
939    mask = tcg_temp_new_ptr();
940    base = get_gpr(s, rs1, EXT_NONE);
941    desc = tcg_constant_i32(simd_desc(s->vlen / 8, s->vlen / 8, data));
942
943    tcg_gen_addi_ptr(dest, cpu_env, vreg_ofs(s, vd));
944    tcg_gen_addi_ptr(mask, cpu_env, vreg_ofs(s, 0));
945
946    fn(dest, mask, base, cpu_env, desc);
947
948    tcg_temp_free_ptr(dest);
949    tcg_temp_free_ptr(mask);
950    mark_vs_dirty(s);
951    gen_set_label(over);
952    return true;
953}
954
955static bool ldff_op(DisasContext *s, arg_r2nfvm *a, uint8_t eew)
956{
957    uint32_t data = 0;
958    gen_helper_ldst_us *fn;
959    static gen_helper_ldst_us * const fns[4] = {
960        gen_helper_vle8ff_v, gen_helper_vle16ff_v,
961        gen_helper_vle32ff_v, gen_helper_vle64ff_v
962    };
963
964    fn = fns[eew];
965    if (fn == NULL) {
966        return false;
967    }
968
969    uint8_t emul = vext_get_emul(s, eew);
970    data = FIELD_DP32(data, VDATA, VM, a->vm);
971    data = FIELD_DP32(data, VDATA, LMUL, emul);
972    data = FIELD_DP32(data, VDATA, NF, a->nf);
973    return ldff_trans(a->rd, a->rs1, data, fn, s);
974}
975
976GEN_VEXT_TRANS(vle8ff_v,  MO_8,  r2nfvm, ldff_op, ld_us_check)
977GEN_VEXT_TRANS(vle16ff_v, MO_16, r2nfvm, ldff_op, ld_us_check)
978GEN_VEXT_TRANS(vle32ff_v, MO_32, r2nfvm, ldff_op, ld_us_check)
979GEN_VEXT_TRANS(vle64ff_v, MO_64, r2nfvm, ldff_op, ld_us_check)
980
981/*
982 * load and store whole register instructions
983 */
984typedef void gen_helper_ldst_whole(TCGv_ptr, TCGv, TCGv_env, TCGv_i32);
985
986static bool ldst_whole_trans(uint32_t vd, uint32_t rs1, uint32_t nf,
987                             gen_helper_ldst_whole *fn, DisasContext *s,
988                             bool is_store)
989{
990    TCGv_ptr dest;
991    TCGv base;
992    TCGv_i32 desc;
993
994    uint32_t data = FIELD_DP32(0, VDATA, NF, nf);
995    dest = tcg_temp_new_ptr();
996    desc = tcg_constant_i32(simd_desc(s->vlen / 8, s->vlen / 8, data));
997
998    base = get_gpr(s, rs1, EXT_NONE);
999    tcg_gen_addi_ptr(dest, cpu_env, vreg_ofs(s, vd));
1000
1001    fn(dest, base, cpu_env, desc);
1002
1003    tcg_temp_free_ptr(dest);
1004
1005    if (!is_store) {
1006        mark_vs_dirty(s);
1007    }
1008
1009    return true;
1010}
1011
1012/*
1013 * load and store whole register instructions ignore vtype and vl setting.
1014 * Thus, we don't need to check vill bit. (Section 7.9)
1015 */
1016#define GEN_LDST_WHOLE_TRANS(NAME, ARG_NF, IS_STORE)                      \
1017static bool trans_##NAME(DisasContext *s, arg_##NAME * a)                 \
1018{                                                                         \
1019    if (require_rvv(s) &&                                                 \
1020        QEMU_IS_ALIGNED(a->rd, ARG_NF)) {                                 \
1021        return ldst_whole_trans(a->rd, a->rs1, ARG_NF, gen_helper_##NAME, \
1022                                s, IS_STORE);                             \
1023    }                                                                     \
1024    return false;                                                         \
1025}
1026
1027GEN_LDST_WHOLE_TRANS(vl1re8_v,  1, false)
1028GEN_LDST_WHOLE_TRANS(vl1re16_v, 1, false)
1029GEN_LDST_WHOLE_TRANS(vl1re32_v, 1, false)
1030GEN_LDST_WHOLE_TRANS(vl1re64_v, 1, false)
1031GEN_LDST_WHOLE_TRANS(vl2re8_v,  2, false)
1032GEN_LDST_WHOLE_TRANS(vl2re16_v, 2, false)
1033GEN_LDST_WHOLE_TRANS(vl2re32_v, 2, false)
1034GEN_LDST_WHOLE_TRANS(vl2re64_v, 2, false)
1035GEN_LDST_WHOLE_TRANS(vl4re8_v,  4, false)
1036GEN_LDST_WHOLE_TRANS(vl4re16_v, 4, false)
1037GEN_LDST_WHOLE_TRANS(vl4re32_v, 4, false)
1038GEN_LDST_WHOLE_TRANS(vl4re64_v, 4, false)
1039GEN_LDST_WHOLE_TRANS(vl8re8_v,  8, false)
1040GEN_LDST_WHOLE_TRANS(vl8re16_v, 8, false)
1041GEN_LDST_WHOLE_TRANS(vl8re32_v, 8, false)
1042GEN_LDST_WHOLE_TRANS(vl8re64_v, 8, false)
1043
1044GEN_LDST_WHOLE_TRANS(vs1r_v, 1, true)
1045GEN_LDST_WHOLE_TRANS(vs2r_v, 2, true)
1046GEN_LDST_WHOLE_TRANS(vs4r_v, 4, true)
1047GEN_LDST_WHOLE_TRANS(vs8r_v, 8, true)
1048
1049/*
1050 *** Vector Integer Arithmetic Instructions
1051 */
1052
1053/*
1054 * MAXSZ returns the maximum vector size can be operated in bytes,
1055 * which is used in GVEC IR when vl_eq_vlmax flag is set to true
1056 * to accerlate vector operation.
1057 */
1058static inline uint32_t MAXSZ(DisasContext *s)
1059{
1060    int scale = s->lmul - 3;
1061    return scale < 0 ? s->vlen >> -scale : s->vlen << scale;
1062}
1063
1064static bool opivv_check(DisasContext *s, arg_rmrr *a)
1065{
1066    return require_rvv(s) &&
1067           vext_check_isa_ill(s) &&
1068           vext_check_sss(s, a->rd, a->rs1, a->rs2, a->vm);
1069}
1070
1071typedef void GVecGen3Fn(unsigned, uint32_t, uint32_t,
1072                        uint32_t, uint32_t, uint32_t);
1073
1074static inline bool
1075do_opivv_gvec(DisasContext *s, arg_rmrr *a, GVecGen3Fn *gvec_fn,
1076              gen_helper_gvec_4_ptr *fn)
1077{
1078    TCGLabel *over = gen_new_label();
1079    if (!opivv_check(s, a)) {
1080        return false;
1081    }
1082
1083    tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
1084
1085    if (a->vm && s->vl_eq_vlmax) {
1086        gvec_fn(s->sew, vreg_ofs(s, a->rd),
1087                vreg_ofs(s, a->rs2), vreg_ofs(s, a->rs1),
1088                MAXSZ(s), MAXSZ(s));
1089    } else {
1090        uint32_t data = 0;
1091
1092        data = FIELD_DP32(data, VDATA, VM, a->vm);
1093        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);
1094        tcg_gen_gvec_4_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),
1095                           vreg_ofs(s, a->rs1), vreg_ofs(s, a->rs2),
1096                           cpu_env, s->vlen / 8, s->vlen / 8, data, fn);
1097    }
1098    mark_vs_dirty(s);
1099    gen_set_label(over);
1100    return true;
1101}
1102
1103/* OPIVV with GVEC IR */
1104#define GEN_OPIVV_GVEC_TRANS(NAME, SUF) \
1105static bool trans_##NAME(DisasContext *s, arg_rmrr *a)             \
1106{                                                                  \
1107    static gen_helper_gvec_4_ptr * const fns[4] = {                \
1108        gen_helper_##NAME##_b, gen_helper_##NAME##_h,              \
1109        gen_helper_##NAME##_w, gen_helper_##NAME##_d,              \
1110    };                                                             \
1111    return do_opivv_gvec(s, a, tcg_gen_gvec_##SUF, fns[s->sew]);   \
1112}
1113
1114GEN_OPIVV_GVEC_TRANS(vadd_vv, add)
1115GEN_OPIVV_GVEC_TRANS(vsub_vv, sub)
1116
1117typedef void gen_helper_opivx(TCGv_ptr, TCGv_ptr, TCGv, TCGv_ptr,
1118                              TCGv_env, TCGv_i32);
1119
1120static bool opivx_trans(uint32_t vd, uint32_t rs1, uint32_t vs2, uint32_t vm,
1121                        gen_helper_opivx *fn, DisasContext *s)
1122{
1123    TCGv_ptr dest, src2, mask;
1124    TCGv src1;
1125    TCGv_i32 desc;
1126    uint32_t data = 0;
1127
1128    TCGLabel *over = gen_new_label();
1129    tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
1130
1131    dest = tcg_temp_new_ptr();
1132    mask = tcg_temp_new_ptr();
1133    src2 = tcg_temp_new_ptr();
1134    src1 = get_gpr(s, rs1, EXT_NONE);
1135
1136    data = FIELD_DP32(data, VDATA, VM, vm);
1137    data = FIELD_DP32(data, VDATA, LMUL, s->lmul);
1138    desc = tcg_constant_i32(simd_desc(s->vlen / 8, s->vlen / 8, data));
1139
1140    tcg_gen_addi_ptr(dest, cpu_env, vreg_ofs(s, vd));
1141    tcg_gen_addi_ptr(src2, cpu_env, vreg_ofs(s, vs2));
1142    tcg_gen_addi_ptr(mask, cpu_env, vreg_ofs(s, 0));
1143
1144    fn(dest, mask, src1, src2, cpu_env, desc);
1145
1146    tcg_temp_free_ptr(dest);
1147    tcg_temp_free_ptr(mask);
1148    tcg_temp_free_ptr(src2);
1149    mark_vs_dirty(s);
1150    gen_set_label(over);
1151    return true;
1152}
1153
1154static bool opivx_check(DisasContext *s, arg_rmrr *a)
1155{
1156    return require_rvv(s) &&
1157           vext_check_isa_ill(s) &&
1158           vext_check_ss(s, a->rd, a->rs2, a->vm);
1159}
1160
1161typedef void GVecGen2sFn(unsigned, uint32_t, uint32_t, TCGv_i64,
1162                         uint32_t, uint32_t);
1163
1164static inline bool
1165do_opivx_gvec(DisasContext *s, arg_rmrr *a, GVecGen2sFn *gvec_fn,
1166              gen_helper_opivx *fn)
1167{
1168    if (!opivx_check(s, a)) {
1169        return false;
1170    }
1171
1172    if (a->vm && s->vl_eq_vlmax) {
1173        TCGv_i64 src1 = tcg_temp_new_i64();
1174
1175        tcg_gen_ext_tl_i64(src1, get_gpr(s, a->rs1, EXT_SIGN));
1176        gvec_fn(s->sew, vreg_ofs(s, a->rd), vreg_ofs(s, a->rs2),
1177                src1, MAXSZ(s), MAXSZ(s));
1178
1179        tcg_temp_free_i64(src1);
1180        mark_vs_dirty(s);
1181        return true;
1182    }
1183    return opivx_trans(a->rd, a->rs1, a->rs2, a->vm, fn, s);
1184}
1185
1186/* OPIVX with GVEC IR */
1187#define GEN_OPIVX_GVEC_TRANS(NAME, SUF) \
1188static bool trans_##NAME(DisasContext *s, arg_rmrr *a)             \
1189{                                                                  \
1190    static gen_helper_opivx * const fns[4] = {                     \
1191        gen_helper_##NAME##_b, gen_helper_##NAME##_h,              \
1192        gen_helper_##NAME##_w, gen_helper_##NAME##_d,              \
1193    };                                                             \
1194    return do_opivx_gvec(s, a, tcg_gen_gvec_##SUF, fns[s->sew]);   \
1195}
1196
1197GEN_OPIVX_GVEC_TRANS(vadd_vx, adds)
1198GEN_OPIVX_GVEC_TRANS(vsub_vx, subs)
1199
1200static void gen_vec_rsub8_i64(TCGv_i64 d, TCGv_i64 a, TCGv_i64 b)
1201{
1202    tcg_gen_vec_sub8_i64(d, b, a);
1203}
1204
1205static void gen_vec_rsub16_i64(TCGv_i64 d, TCGv_i64 a, TCGv_i64 b)
1206{
1207    tcg_gen_vec_sub16_i64(d, b, a);
1208}
1209
1210static void gen_rsub_i32(TCGv_i32 ret, TCGv_i32 arg1, TCGv_i32 arg2)
1211{
1212    tcg_gen_sub_i32(ret, arg2, arg1);
1213}
1214
1215static void gen_rsub_i64(TCGv_i64 ret, TCGv_i64 arg1, TCGv_i64 arg2)
1216{
1217    tcg_gen_sub_i64(ret, arg2, arg1);
1218}
1219
1220static void gen_rsub_vec(unsigned vece, TCGv_vec r, TCGv_vec a, TCGv_vec b)
1221{
1222    tcg_gen_sub_vec(vece, r, b, a);
1223}
1224
1225static void tcg_gen_gvec_rsubs(unsigned vece, uint32_t dofs, uint32_t aofs,
1226                               TCGv_i64 c, uint32_t oprsz, uint32_t maxsz)
1227{
1228    static const TCGOpcode vecop_list[] = { INDEX_op_sub_vec, 0 };
1229    static const GVecGen2s rsub_op[4] = {
1230        { .fni8 = gen_vec_rsub8_i64,
1231          .fniv = gen_rsub_vec,
1232          .fno = gen_helper_vec_rsubs8,
1233          .opt_opc = vecop_list,
1234          .vece = MO_8 },
1235        { .fni8 = gen_vec_rsub16_i64,
1236          .fniv = gen_rsub_vec,
1237          .fno = gen_helper_vec_rsubs16,
1238          .opt_opc = vecop_list,
1239          .vece = MO_16 },
1240        { .fni4 = gen_rsub_i32,
1241          .fniv = gen_rsub_vec,
1242          .fno = gen_helper_vec_rsubs32,
1243          .opt_opc = vecop_list,
1244          .vece = MO_32 },
1245        { .fni8 = gen_rsub_i64,
1246          .fniv = gen_rsub_vec,
1247          .fno = gen_helper_vec_rsubs64,
1248          .opt_opc = vecop_list,
1249          .prefer_i64 = TCG_TARGET_REG_BITS == 64,
1250          .vece = MO_64 },
1251    };
1252
1253    tcg_debug_assert(vece <= MO_64);
1254    tcg_gen_gvec_2s(dofs, aofs, oprsz, maxsz, c, &rsub_op[vece]);
1255}
1256
1257GEN_OPIVX_GVEC_TRANS(vrsub_vx, rsubs)
1258
1259typedef enum {
1260    IMM_ZX,         /* Zero-extended */
1261    IMM_SX,         /* Sign-extended */
1262    IMM_TRUNC_SEW,  /* Truncate to log(SEW) bits */
1263    IMM_TRUNC_2SEW, /* Truncate to log(2*SEW) bits */
1264} imm_mode_t;
1265
1266static int64_t extract_imm(DisasContext *s, uint32_t imm, imm_mode_t imm_mode)
1267{
1268    switch (imm_mode) {
1269    case IMM_ZX:
1270        return extract64(imm, 0, 5);
1271    case IMM_SX:
1272        return sextract64(imm, 0, 5);
1273    case IMM_TRUNC_SEW:
1274        return extract64(imm, 0, s->sew + 3);
1275    case IMM_TRUNC_2SEW:
1276        return extract64(imm, 0, s->sew + 4);
1277    default:
1278        g_assert_not_reached();
1279    }
1280}
1281
1282static bool opivi_trans(uint32_t vd, uint32_t imm, uint32_t vs2, uint32_t vm,
1283                        gen_helper_opivx *fn, DisasContext *s,
1284                        imm_mode_t imm_mode)
1285{
1286    TCGv_ptr dest, src2, mask;
1287    TCGv src1;
1288    TCGv_i32 desc;
1289    uint32_t data = 0;
1290
1291    TCGLabel *over = gen_new_label();
1292    tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
1293
1294    dest = tcg_temp_new_ptr();
1295    mask = tcg_temp_new_ptr();
1296    src2 = tcg_temp_new_ptr();
1297    src1 = tcg_constant_tl(extract_imm(s, imm, imm_mode));
1298
1299    data = FIELD_DP32(data, VDATA, VM, vm);
1300    data = FIELD_DP32(data, VDATA, LMUL, s->lmul);
1301    desc = tcg_constant_i32(simd_desc(s->vlen / 8, s->vlen / 8, data));
1302
1303    tcg_gen_addi_ptr(dest, cpu_env, vreg_ofs(s, vd));
1304    tcg_gen_addi_ptr(src2, cpu_env, vreg_ofs(s, vs2));
1305    tcg_gen_addi_ptr(mask, cpu_env, vreg_ofs(s, 0));
1306
1307    fn(dest, mask, src1, src2, cpu_env, desc);
1308
1309    tcg_temp_free_ptr(dest);
1310    tcg_temp_free_ptr(mask);
1311    tcg_temp_free_ptr(src2);
1312    mark_vs_dirty(s);
1313    gen_set_label(over);
1314    return true;
1315}
1316
1317typedef void GVecGen2iFn(unsigned, uint32_t, uint32_t, int64_t,
1318                         uint32_t, uint32_t);
1319
1320static inline bool
1321do_opivi_gvec(DisasContext *s, arg_rmrr *a, GVecGen2iFn *gvec_fn,
1322              gen_helper_opivx *fn, imm_mode_t imm_mode)
1323{
1324    if (!opivx_check(s, a)) {
1325        return false;
1326    }
1327
1328    if (a->vm && s->vl_eq_vlmax) {
1329        gvec_fn(s->sew, vreg_ofs(s, a->rd), vreg_ofs(s, a->rs2),
1330                extract_imm(s, a->rs1, imm_mode), MAXSZ(s), MAXSZ(s));
1331        mark_vs_dirty(s);
1332        return true;
1333    }
1334    return opivi_trans(a->rd, a->rs1, a->rs2, a->vm, fn, s, imm_mode);
1335}
1336
1337/* OPIVI with GVEC IR */
1338#define GEN_OPIVI_GVEC_TRANS(NAME, IMM_MODE, OPIVX, SUF) \
1339static bool trans_##NAME(DisasContext *s, arg_rmrr *a)             \
1340{                                                                  \
1341    static gen_helper_opivx * const fns[4] = {                     \
1342        gen_helper_##OPIVX##_b, gen_helper_##OPIVX##_h,            \
1343        gen_helper_##OPIVX##_w, gen_helper_##OPIVX##_d,            \
1344    };                                                             \
1345    return do_opivi_gvec(s, a, tcg_gen_gvec_##SUF,                 \
1346                         fns[s->sew], IMM_MODE);                   \
1347}
1348
1349GEN_OPIVI_GVEC_TRANS(vadd_vi, IMM_SX, vadd_vx, addi)
1350
1351static void tcg_gen_gvec_rsubi(unsigned vece, uint32_t dofs, uint32_t aofs,
1352                               int64_t c, uint32_t oprsz, uint32_t maxsz)
1353{
1354    TCGv_i64 tmp = tcg_constant_i64(c);
1355    tcg_gen_gvec_rsubs(vece, dofs, aofs, tmp, oprsz, maxsz);
1356}
1357
1358GEN_OPIVI_GVEC_TRANS(vrsub_vi, IMM_SX, vrsub_vx, rsubi)
1359
1360/* Vector Widening Integer Add/Subtract */
1361
1362/* OPIVV with WIDEN */
1363static bool opivv_widen_check(DisasContext *s, arg_rmrr *a)
1364{
1365    return require_rvv(s) &&
1366           vext_check_isa_ill(s) &&
1367           vext_check_dss(s, a->rd, a->rs1, a->rs2, a->vm);
1368}
1369
1370static bool do_opivv_widen(DisasContext *s, arg_rmrr *a,
1371                           gen_helper_gvec_4_ptr *fn,
1372                           bool (*checkfn)(DisasContext *, arg_rmrr *))
1373{
1374    if (checkfn(s, a)) {
1375        uint32_t data = 0;
1376        TCGLabel *over = gen_new_label();
1377        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
1378
1379        data = FIELD_DP32(data, VDATA, VM, a->vm);
1380        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);
1381        tcg_gen_gvec_4_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),
1382                           vreg_ofs(s, a->rs1),
1383                           vreg_ofs(s, a->rs2),
1384                           cpu_env, s->vlen / 8, s->vlen / 8,
1385                           data, fn);
1386        mark_vs_dirty(s);
1387        gen_set_label(over);
1388        return true;
1389    }
1390    return false;
1391}
1392
1393#define GEN_OPIVV_WIDEN_TRANS(NAME, CHECK) \
1394static bool trans_##NAME(DisasContext *s, arg_rmrr *a)       \
1395{                                                            \
1396    static gen_helper_gvec_4_ptr * const fns[3] = {          \
1397        gen_helper_##NAME##_b,                               \
1398        gen_helper_##NAME##_h,                               \
1399        gen_helper_##NAME##_w                                \
1400    };                                                       \
1401    return do_opivv_widen(s, a, fns[s->sew], CHECK);         \
1402}
1403
1404GEN_OPIVV_WIDEN_TRANS(vwaddu_vv, opivv_widen_check)
1405GEN_OPIVV_WIDEN_TRANS(vwadd_vv, opivv_widen_check)
1406GEN_OPIVV_WIDEN_TRANS(vwsubu_vv, opivv_widen_check)
1407GEN_OPIVV_WIDEN_TRANS(vwsub_vv, opivv_widen_check)
1408
1409/* OPIVX with WIDEN */
1410static bool opivx_widen_check(DisasContext *s, arg_rmrr *a)
1411{
1412    return require_rvv(s) &&
1413           vext_check_isa_ill(s) &&
1414           vext_check_ds(s, a->rd, a->rs2, a->vm);
1415}
1416
1417static bool do_opivx_widen(DisasContext *s, arg_rmrr *a,
1418                           gen_helper_opivx *fn)
1419{
1420    if (opivx_widen_check(s, a)) {
1421        return opivx_trans(a->rd, a->rs1, a->rs2, a->vm, fn, s);
1422    }
1423    return false;
1424}
1425
1426#define GEN_OPIVX_WIDEN_TRANS(NAME) \
1427static bool trans_##NAME(DisasContext *s, arg_rmrr *a)       \
1428{                                                            \
1429    static gen_helper_opivx * const fns[3] = {               \
1430        gen_helper_##NAME##_b,                               \
1431        gen_helper_##NAME##_h,                               \
1432        gen_helper_##NAME##_w                                \
1433    };                                                       \
1434    return do_opivx_widen(s, a, fns[s->sew]);                \
1435}
1436
1437GEN_OPIVX_WIDEN_TRANS(vwaddu_vx)
1438GEN_OPIVX_WIDEN_TRANS(vwadd_vx)
1439GEN_OPIVX_WIDEN_TRANS(vwsubu_vx)
1440GEN_OPIVX_WIDEN_TRANS(vwsub_vx)
1441
1442/* WIDEN OPIVV with WIDEN */
1443static bool opiwv_widen_check(DisasContext *s, arg_rmrr *a)
1444{
1445    return require_rvv(s) &&
1446           vext_check_isa_ill(s) &&
1447           vext_check_dds(s, a->rd, a->rs1, a->rs2, a->vm);
1448}
1449
1450static bool do_opiwv_widen(DisasContext *s, arg_rmrr *a,
1451                           gen_helper_gvec_4_ptr *fn)
1452{
1453    if (opiwv_widen_check(s, a)) {
1454        uint32_t data = 0;
1455        TCGLabel *over = gen_new_label();
1456        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
1457
1458        data = FIELD_DP32(data, VDATA, VM, a->vm);
1459        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);
1460        tcg_gen_gvec_4_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),
1461                           vreg_ofs(s, a->rs1),
1462                           vreg_ofs(s, a->rs2),
1463                           cpu_env, s->vlen / 8, s->vlen / 8, data, fn);
1464        mark_vs_dirty(s);
1465        gen_set_label(over);
1466        return true;
1467    }
1468    return false;
1469}
1470
1471#define GEN_OPIWV_WIDEN_TRANS(NAME) \
1472static bool trans_##NAME(DisasContext *s, arg_rmrr *a)       \
1473{                                                            \
1474    static gen_helper_gvec_4_ptr * const fns[3] = {          \
1475        gen_helper_##NAME##_b,                               \
1476        gen_helper_##NAME##_h,                               \
1477        gen_helper_##NAME##_w                                \
1478    };                                                       \
1479    return do_opiwv_widen(s, a, fns[s->sew]);                \
1480}
1481
1482GEN_OPIWV_WIDEN_TRANS(vwaddu_wv)
1483GEN_OPIWV_WIDEN_TRANS(vwadd_wv)
1484GEN_OPIWV_WIDEN_TRANS(vwsubu_wv)
1485GEN_OPIWV_WIDEN_TRANS(vwsub_wv)
1486
1487/* WIDEN OPIVX with WIDEN */
1488static bool opiwx_widen_check(DisasContext *s, arg_rmrr *a)
1489{
1490    return require_rvv(s) &&
1491           vext_check_isa_ill(s) &&
1492           vext_check_dd(s, a->rd, a->rs2, a->vm);
1493}
1494
1495static bool do_opiwx_widen(DisasContext *s, arg_rmrr *a,
1496                           gen_helper_opivx *fn)
1497{
1498    if (opiwx_widen_check(s, a)) {
1499        return opivx_trans(a->rd, a->rs1, a->rs2, a->vm, fn, s);
1500    }
1501    return false;
1502}
1503
1504#define GEN_OPIWX_WIDEN_TRANS(NAME) \
1505static bool trans_##NAME(DisasContext *s, arg_rmrr *a)       \
1506{                                                            \
1507    static gen_helper_opivx * const fns[3] = {               \
1508        gen_helper_##NAME##_b,                               \
1509        gen_helper_##NAME##_h,                               \
1510        gen_helper_##NAME##_w                                \
1511    };                                                       \
1512    return do_opiwx_widen(s, a, fns[s->sew]);                \
1513}
1514
1515GEN_OPIWX_WIDEN_TRANS(vwaddu_wx)
1516GEN_OPIWX_WIDEN_TRANS(vwadd_wx)
1517GEN_OPIWX_WIDEN_TRANS(vwsubu_wx)
1518GEN_OPIWX_WIDEN_TRANS(vwsub_wx)
1519
1520/* Vector Integer Add-with-Carry / Subtract-with-Borrow Instructions */
1521/* OPIVV without GVEC IR */
1522#define GEN_OPIVV_TRANS(NAME, CHECK)                               \
1523static bool trans_##NAME(DisasContext *s, arg_rmrr *a)             \
1524{                                                                  \
1525    if (CHECK(s, a)) {                                             \
1526        uint32_t data = 0;                                         \
1527        static gen_helper_gvec_4_ptr * const fns[4] = {            \
1528            gen_helper_##NAME##_b, gen_helper_##NAME##_h,          \
1529            gen_helper_##NAME##_w, gen_helper_##NAME##_d,          \
1530        };                                                         \
1531        TCGLabel *over = gen_new_label();                          \
1532        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);          \
1533                                                                   \
1534        data = FIELD_DP32(data, VDATA, VM, a->vm);                 \
1535        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);             \
1536        tcg_gen_gvec_4_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),     \
1537                           vreg_ofs(s, a->rs1),                    \
1538                           vreg_ofs(s, a->rs2), cpu_env,           \
1539                           s->vlen / 8, s->vlen / 8, data,         \
1540                           fns[s->sew]);                           \
1541        mark_vs_dirty(s);                                          \
1542        gen_set_label(over);                                       \
1543        return true;                                               \
1544    }                                                              \
1545    return false;                                                  \
1546}
1547
1548/*
1549 * For vadc and vsbc, an illegal instruction exception is raised if the
1550 * destination vector register is v0 and LMUL > 1. (Section 12.3)
1551 */
1552static bool opivv_vadc_check(DisasContext *s, arg_rmrr *a)
1553{
1554    return require_rvv(s) &&
1555           vext_check_isa_ill(s) &&
1556           (a->rd != 0) &&
1557           vext_check_sss(s, a->rd, a->rs1, a->rs2, a->vm);
1558}
1559
1560GEN_OPIVV_TRANS(vadc_vvm, opivv_vadc_check)
1561GEN_OPIVV_TRANS(vsbc_vvm, opivv_vadc_check)
1562
1563/*
1564 * For vmadc and vmsbc, an illegal instruction exception is raised if the
1565 * destination vector register overlaps a source vector register group.
1566 */
1567static bool opivv_vmadc_check(DisasContext *s, arg_rmrr *a)
1568{
1569    return require_rvv(s) &&
1570           vext_check_isa_ill(s) &&
1571           vext_check_mss(s, a->rd, a->rs1, a->rs2);
1572}
1573
1574GEN_OPIVV_TRANS(vmadc_vvm, opivv_vmadc_check)
1575GEN_OPIVV_TRANS(vmsbc_vvm, opivv_vmadc_check)
1576
1577static bool opivx_vadc_check(DisasContext *s, arg_rmrr *a)
1578{
1579    return require_rvv(s) &&
1580           vext_check_isa_ill(s) &&
1581           (a->rd != 0) &&
1582           vext_check_ss(s, a->rd, a->rs2, a->vm);
1583}
1584
1585/* OPIVX without GVEC IR */
1586#define GEN_OPIVX_TRANS(NAME, CHECK)                                     \
1587static bool trans_##NAME(DisasContext *s, arg_rmrr *a)                   \
1588{                                                                        \
1589    if (CHECK(s, a)) {                                                   \
1590        static gen_helper_opivx * const fns[4] = {                       \
1591            gen_helper_##NAME##_b, gen_helper_##NAME##_h,                \
1592            gen_helper_##NAME##_w, gen_helper_##NAME##_d,                \
1593        };                                                               \
1594                                                                         \
1595        return opivx_trans(a->rd, a->rs1, a->rs2, a->vm, fns[s->sew], s);\
1596    }                                                                    \
1597    return false;                                                        \
1598}
1599
1600GEN_OPIVX_TRANS(vadc_vxm, opivx_vadc_check)
1601GEN_OPIVX_TRANS(vsbc_vxm, opivx_vadc_check)
1602
1603static bool opivx_vmadc_check(DisasContext *s, arg_rmrr *a)
1604{
1605    return require_rvv(s) &&
1606           vext_check_isa_ill(s) &&
1607           vext_check_ms(s, a->rd, a->rs2);
1608}
1609
1610GEN_OPIVX_TRANS(vmadc_vxm, opivx_vmadc_check)
1611GEN_OPIVX_TRANS(vmsbc_vxm, opivx_vmadc_check)
1612
1613/* OPIVI without GVEC IR */
1614#define GEN_OPIVI_TRANS(NAME, IMM_MODE, OPIVX, CHECK)                    \
1615static bool trans_##NAME(DisasContext *s, arg_rmrr *a)                   \
1616{                                                                        \
1617    if (CHECK(s, a)) {                                                   \
1618        static gen_helper_opivx * const fns[4] = {                       \
1619            gen_helper_##OPIVX##_b, gen_helper_##OPIVX##_h,              \
1620            gen_helper_##OPIVX##_w, gen_helper_##OPIVX##_d,              \
1621        };                                                               \
1622        return opivi_trans(a->rd, a->rs1, a->rs2, a->vm,                 \
1623                           fns[s->sew], s, IMM_MODE);                    \
1624    }                                                                    \
1625    return false;                                                        \
1626}
1627
1628GEN_OPIVI_TRANS(vadc_vim, IMM_SX, vadc_vxm, opivx_vadc_check)
1629GEN_OPIVI_TRANS(vmadc_vim, IMM_SX, vmadc_vxm, opivx_vmadc_check)
1630
1631/* Vector Bitwise Logical Instructions */
1632GEN_OPIVV_GVEC_TRANS(vand_vv, and)
1633GEN_OPIVV_GVEC_TRANS(vor_vv,  or)
1634GEN_OPIVV_GVEC_TRANS(vxor_vv, xor)
1635GEN_OPIVX_GVEC_TRANS(vand_vx, ands)
1636GEN_OPIVX_GVEC_TRANS(vor_vx,  ors)
1637GEN_OPIVX_GVEC_TRANS(vxor_vx, xors)
1638GEN_OPIVI_GVEC_TRANS(vand_vi, IMM_SX, vand_vx, andi)
1639GEN_OPIVI_GVEC_TRANS(vor_vi, IMM_SX, vor_vx,  ori)
1640GEN_OPIVI_GVEC_TRANS(vxor_vi, IMM_SX, vxor_vx, xori)
1641
1642/* Vector Single-Width Bit Shift Instructions */
1643GEN_OPIVV_GVEC_TRANS(vsll_vv,  shlv)
1644GEN_OPIVV_GVEC_TRANS(vsrl_vv,  shrv)
1645GEN_OPIVV_GVEC_TRANS(vsra_vv,  sarv)
1646
1647typedef void GVecGen2sFn32(unsigned, uint32_t, uint32_t, TCGv_i32,
1648                           uint32_t, uint32_t);
1649
1650static inline bool
1651do_opivx_gvec_shift(DisasContext *s, arg_rmrr *a, GVecGen2sFn32 *gvec_fn,
1652                    gen_helper_opivx *fn)
1653{
1654    if (!opivx_check(s, a)) {
1655        return false;
1656    }
1657
1658    if (a->vm && s->vl_eq_vlmax) {
1659        TCGv_i32 src1 = tcg_temp_new_i32();
1660
1661        tcg_gen_trunc_tl_i32(src1, get_gpr(s, a->rs1, EXT_NONE));
1662        tcg_gen_extract_i32(src1, src1, 0, s->sew + 3);
1663        gvec_fn(s->sew, vreg_ofs(s, a->rd), vreg_ofs(s, a->rs2),
1664                src1, MAXSZ(s), MAXSZ(s));
1665
1666        tcg_temp_free_i32(src1);
1667        mark_vs_dirty(s);
1668        return true;
1669    }
1670    return opivx_trans(a->rd, a->rs1, a->rs2, a->vm, fn, s);
1671}
1672
1673#define GEN_OPIVX_GVEC_SHIFT_TRANS(NAME, SUF) \
1674static bool trans_##NAME(DisasContext *s, arg_rmrr *a)                    \
1675{                                                                         \
1676    static gen_helper_opivx * const fns[4] = {                            \
1677        gen_helper_##NAME##_b, gen_helper_##NAME##_h,                     \
1678        gen_helper_##NAME##_w, gen_helper_##NAME##_d,                     \
1679    };                                                                    \
1680                                                                          \
1681    return do_opivx_gvec_shift(s, a, tcg_gen_gvec_##SUF, fns[s->sew]);    \
1682}
1683
1684GEN_OPIVX_GVEC_SHIFT_TRANS(vsll_vx,  shls)
1685GEN_OPIVX_GVEC_SHIFT_TRANS(vsrl_vx,  shrs)
1686GEN_OPIVX_GVEC_SHIFT_TRANS(vsra_vx,  sars)
1687
1688GEN_OPIVI_GVEC_TRANS(vsll_vi, IMM_ZX, vsll_vx, shli)
1689GEN_OPIVI_GVEC_TRANS(vsrl_vi, IMM_ZX, vsrl_vx, shri)
1690GEN_OPIVI_GVEC_TRANS(vsra_vi, IMM_ZX, vsra_vx, sari)
1691
1692/* Vector Narrowing Integer Right Shift Instructions */
1693static bool opivv_narrow_check(DisasContext *s, arg_rmrr *a)
1694{
1695    return require_rvv(s) &&
1696           vext_check_isa_ill(s) &&
1697           vext_check_sds(s, a->rd, a->rs1, a->rs2, a->vm);
1698}
1699
1700/* OPIVV with NARROW */
1701#define GEN_OPIVV_NARROW_TRANS(NAME)                               \
1702static bool trans_##NAME(DisasContext *s, arg_rmrr *a)             \
1703{                                                                  \
1704    if (opivv_narrow_check(s, a)) {                                \
1705        uint32_t data = 0;                                         \
1706        static gen_helper_gvec_4_ptr * const fns[3] = {            \
1707            gen_helper_##NAME##_b,                                 \
1708            gen_helper_##NAME##_h,                                 \
1709            gen_helper_##NAME##_w,                                 \
1710        };                                                         \
1711        TCGLabel *over = gen_new_label();                          \
1712        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);          \
1713                                                                   \
1714        data = FIELD_DP32(data, VDATA, VM, a->vm);                 \
1715        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);             \
1716        tcg_gen_gvec_4_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),     \
1717                           vreg_ofs(s, a->rs1),                    \
1718                           vreg_ofs(s, a->rs2), cpu_env,           \
1719                           s->vlen / 8, s->vlen / 8, data,         \
1720                           fns[s->sew]);                           \
1721        mark_vs_dirty(s);                                          \
1722        gen_set_label(over);                                       \
1723        return true;                                               \
1724    }                                                              \
1725    return false;                                                  \
1726}
1727GEN_OPIVV_NARROW_TRANS(vnsra_vv)
1728GEN_OPIVV_NARROW_TRANS(vnsrl_vv)
1729
1730static bool opivx_narrow_check(DisasContext *s, arg_rmrr *a)
1731{
1732    return require_rvv(s) &&
1733           vext_check_isa_ill(s) &&
1734           vext_check_sd(s, a->rd, a->rs2, a->vm);
1735}
1736
1737/* OPIVX with NARROW */
1738#define GEN_OPIVX_NARROW_TRANS(NAME)                                     \
1739static bool trans_##NAME(DisasContext *s, arg_rmrr *a)                   \
1740{                                                                        \
1741    if (opivx_narrow_check(s, a)) {                                      \
1742        static gen_helper_opivx * const fns[3] = {                       \
1743            gen_helper_##NAME##_b,                                       \
1744            gen_helper_##NAME##_h,                                       \
1745            gen_helper_##NAME##_w,                                       \
1746        };                                                               \
1747        return opivx_trans(a->rd, a->rs1, a->rs2, a->vm, fns[s->sew], s);\
1748    }                                                                    \
1749    return false;                                                        \
1750}
1751
1752GEN_OPIVX_NARROW_TRANS(vnsra_vx)
1753GEN_OPIVX_NARROW_TRANS(vnsrl_vx)
1754
1755/* OPIVI with NARROW */
1756#define GEN_OPIVI_NARROW_TRANS(NAME, IMM_MODE, OPIVX)                    \
1757static bool trans_##NAME(DisasContext *s, arg_rmrr *a)                   \
1758{                                                                        \
1759    if (opivx_narrow_check(s, a)) {                                      \
1760        static gen_helper_opivx * const fns[3] = {                       \
1761            gen_helper_##OPIVX##_b,                                      \
1762            gen_helper_##OPIVX##_h,                                      \
1763            gen_helper_##OPIVX##_w,                                      \
1764        };                                                               \
1765        return opivi_trans(a->rd, a->rs1, a->rs2, a->vm,                 \
1766                           fns[s->sew], s, IMM_MODE);                    \
1767    }                                                                    \
1768    return false;                                                        \
1769}
1770
1771GEN_OPIVI_NARROW_TRANS(vnsra_vi, IMM_ZX, vnsra_vx)
1772GEN_OPIVI_NARROW_TRANS(vnsrl_vi, IMM_ZX, vnsrl_vx)
1773
1774/* Vector Integer Comparison Instructions */
1775/*
1776 * For all comparison instructions, an illegal instruction exception is raised
1777 * if the destination vector register overlaps a source vector register group
1778 * and LMUL > 1.
1779 */
1780static bool opivv_cmp_check(DisasContext *s, arg_rmrr *a)
1781{
1782    return require_rvv(s) &&
1783           vext_check_isa_ill(s) &&
1784           vext_check_mss(s, a->rd, a->rs1, a->rs2);
1785}
1786
1787GEN_OPIVV_TRANS(vmseq_vv, opivv_cmp_check)
1788GEN_OPIVV_TRANS(vmsne_vv, opivv_cmp_check)
1789GEN_OPIVV_TRANS(vmsltu_vv, opivv_cmp_check)
1790GEN_OPIVV_TRANS(vmslt_vv, opivv_cmp_check)
1791GEN_OPIVV_TRANS(vmsleu_vv, opivv_cmp_check)
1792GEN_OPIVV_TRANS(vmsle_vv, opivv_cmp_check)
1793
1794static bool opivx_cmp_check(DisasContext *s, arg_rmrr *a)
1795{
1796    return require_rvv(s) &&
1797           vext_check_isa_ill(s) &&
1798           vext_check_ms(s, a->rd, a->rs2);
1799}
1800
1801GEN_OPIVX_TRANS(vmseq_vx, opivx_cmp_check)
1802GEN_OPIVX_TRANS(vmsne_vx, opivx_cmp_check)
1803GEN_OPIVX_TRANS(vmsltu_vx, opivx_cmp_check)
1804GEN_OPIVX_TRANS(vmslt_vx, opivx_cmp_check)
1805GEN_OPIVX_TRANS(vmsleu_vx, opivx_cmp_check)
1806GEN_OPIVX_TRANS(vmsle_vx, opivx_cmp_check)
1807GEN_OPIVX_TRANS(vmsgtu_vx, opivx_cmp_check)
1808GEN_OPIVX_TRANS(vmsgt_vx, opivx_cmp_check)
1809
1810GEN_OPIVI_TRANS(vmseq_vi, IMM_SX, vmseq_vx, opivx_cmp_check)
1811GEN_OPIVI_TRANS(vmsne_vi, IMM_SX, vmsne_vx, opivx_cmp_check)
1812GEN_OPIVI_TRANS(vmsleu_vi, IMM_ZX, vmsleu_vx, opivx_cmp_check)
1813GEN_OPIVI_TRANS(vmsle_vi, IMM_SX, vmsle_vx, opivx_cmp_check)
1814GEN_OPIVI_TRANS(vmsgtu_vi, IMM_ZX, vmsgtu_vx, opivx_cmp_check)
1815GEN_OPIVI_TRANS(vmsgt_vi, IMM_SX, vmsgt_vx, opivx_cmp_check)
1816
1817/* Vector Integer Min/Max Instructions */
1818GEN_OPIVV_GVEC_TRANS(vminu_vv, umin)
1819GEN_OPIVV_GVEC_TRANS(vmin_vv,  smin)
1820GEN_OPIVV_GVEC_TRANS(vmaxu_vv, umax)
1821GEN_OPIVV_GVEC_TRANS(vmax_vv,  smax)
1822GEN_OPIVX_TRANS(vminu_vx, opivx_check)
1823GEN_OPIVX_TRANS(vmin_vx,  opivx_check)
1824GEN_OPIVX_TRANS(vmaxu_vx, opivx_check)
1825GEN_OPIVX_TRANS(vmax_vx,  opivx_check)
1826
1827/* Vector Single-Width Integer Multiply Instructions */
1828GEN_OPIVV_GVEC_TRANS(vmul_vv,  mul)
1829GEN_OPIVV_TRANS(vmulh_vv, opivv_check)
1830GEN_OPIVV_TRANS(vmulhu_vv, opivv_check)
1831GEN_OPIVV_TRANS(vmulhsu_vv, opivv_check)
1832GEN_OPIVX_GVEC_TRANS(vmul_vx,  muls)
1833GEN_OPIVX_TRANS(vmulh_vx, opivx_check)
1834GEN_OPIVX_TRANS(vmulhu_vx, opivx_check)
1835GEN_OPIVX_TRANS(vmulhsu_vx, opivx_check)
1836
1837/* Vector Integer Divide Instructions */
1838GEN_OPIVV_TRANS(vdivu_vv, opivv_check)
1839GEN_OPIVV_TRANS(vdiv_vv, opivv_check)
1840GEN_OPIVV_TRANS(vremu_vv, opivv_check)
1841GEN_OPIVV_TRANS(vrem_vv, opivv_check)
1842GEN_OPIVX_TRANS(vdivu_vx, opivx_check)
1843GEN_OPIVX_TRANS(vdiv_vx, opivx_check)
1844GEN_OPIVX_TRANS(vremu_vx, opivx_check)
1845GEN_OPIVX_TRANS(vrem_vx, opivx_check)
1846
1847/* Vector Widening Integer Multiply Instructions */
1848GEN_OPIVV_WIDEN_TRANS(vwmul_vv, opivv_widen_check)
1849GEN_OPIVV_WIDEN_TRANS(vwmulu_vv, opivv_widen_check)
1850GEN_OPIVV_WIDEN_TRANS(vwmulsu_vv, opivv_widen_check)
1851GEN_OPIVX_WIDEN_TRANS(vwmul_vx)
1852GEN_OPIVX_WIDEN_TRANS(vwmulu_vx)
1853GEN_OPIVX_WIDEN_TRANS(vwmulsu_vx)
1854
1855/* Vector Single-Width Integer Multiply-Add Instructions */
1856GEN_OPIVV_TRANS(vmacc_vv, opivv_check)
1857GEN_OPIVV_TRANS(vnmsac_vv, opivv_check)
1858GEN_OPIVV_TRANS(vmadd_vv, opivv_check)
1859GEN_OPIVV_TRANS(vnmsub_vv, opivv_check)
1860GEN_OPIVX_TRANS(vmacc_vx, opivx_check)
1861GEN_OPIVX_TRANS(vnmsac_vx, opivx_check)
1862GEN_OPIVX_TRANS(vmadd_vx, opivx_check)
1863GEN_OPIVX_TRANS(vnmsub_vx, opivx_check)
1864
1865/* Vector Widening Integer Multiply-Add Instructions */
1866GEN_OPIVV_WIDEN_TRANS(vwmaccu_vv, opivv_widen_check)
1867GEN_OPIVV_WIDEN_TRANS(vwmacc_vv, opivv_widen_check)
1868GEN_OPIVV_WIDEN_TRANS(vwmaccsu_vv, opivv_widen_check)
1869GEN_OPIVX_WIDEN_TRANS(vwmaccu_vx)
1870GEN_OPIVX_WIDEN_TRANS(vwmacc_vx)
1871GEN_OPIVX_WIDEN_TRANS(vwmaccsu_vx)
1872GEN_OPIVX_WIDEN_TRANS(vwmaccus_vx)
1873
1874/* Vector Integer Merge and Move Instructions */
1875static bool trans_vmv_v_v(DisasContext *s, arg_vmv_v_v *a)
1876{
1877    if (require_rvv(s) &&
1878        vext_check_isa_ill(s) &&
1879        /* vmv.v.v has rs2 = 0 and vm = 1 */
1880        vext_check_sss(s, a->rd, a->rs1, 0, 1)) {
1881        if (s->vl_eq_vlmax) {
1882            tcg_gen_gvec_mov(s->sew, vreg_ofs(s, a->rd),
1883                             vreg_ofs(s, a->rs1),
1884                             MAXSZ(s), MAXSZ(s));
1885        } else {
1886            uint32_t data = FIELD_DP32(0, VDATA, LMUL, s->lmul);
1887            static gen_helper_gvec_2_ptr * const fns[4] = {
1888                gen_helper_vmv_v_v_b, gen_helper_vmv_v_v_h,
1889                gen_helper_vmv_v_v_w, gen_helper_vmv_v_v_d,
1890            };
1891            TCGLabel *over = gen_new_label();
1892            tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
1893
1894            tcg_gen_gvec_2_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, a->rs1),
1895                               cpu_env, s->vlen / 8, s->vlen / 8, data,
1896                               fns[s->sew]);
1897            gen_set_label(over);
1898        }
1899        mark_vs_dirty(s);
1900        return true;
1901    }
1902    return false;
1903}
1904
1905typedef void gen_helper_vmv_vx(TCGv_ptr, TCGv_i64, TCGv_env, TCGv_i32);
1906static bool trans_vmv_v_x(DisasContext *s, arg_vmv_v_x *a)
1907{
1908    if (require_rvv(s) &&
1909        vext_check_isa_ill(s) &&
1910        /* vmv.v.x has rs2 = 0 and vm = 1 */
1911        vext_check_ss(s, a->rd, 0, 1)) {
1912        TCGv s1;
1913        TCGLabel *over = gen_new_label();
1914        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
1915
1916        s1 = get_gpr(s, a->rs1, EXT_SIGN);
1917
1918        if (s->vl_eq_vlmax) {
1919            tcg_gen_gvec_dup_tl(s->sew, vreg_ofs(s, a->rd),
1920                                MAXSZ(s), MAXSZ(s), s1);
1921        } else {
1922            TCGv_i32 desc;
1923            TCGv_i64 s1_i64 = tcg_temp_new_i64();
1924            TCGv_ptr dest = tcg_temp_new_ptr();
1925            uint32_t data = FIELD_DP32(0, VDATA, LMUL, s->lmul);
1926            static gen_helper_vmv_vx * const fns[4] = {
1927                gen_helper_vmv_v_x_b, gen_helper_vmv_v_x_h,
1928                gen_helper_vmv_v_x_w, gen_helper_vmv_v_x_d,
1929            };
1930
1931            tcg_gen_ext_tl_i64(s1_i64, s1);
1932            desc = tcg_constant_i32(simd_desc(s->vlen / 8, s->vlen / 8, data));
1933            tcg_gen_addi_ptr(dest, cpu_env, vreg_ofs(s, a->rd));
1934            fns[s->sew](dest, s1_i64, cpu_env, desc);
1935
1936            tcg_temp_free_ptr(dest);
1937            tcg_temp_free_i64(s1_i64);
1938        }
1939
1940        mark_vs_dirty(s);
1941        gen_set_label(over);
1942        return true;
1943    }
1944    return false;
1945}
1946
1947static bool trans_vmv_v_i(DisasContext *s, arg_vmv_v_i *a)
1948{
1949    if (require_rvv(s) &&
1950        vext_check_isa_ill(s) &&
1951        /* vmv.v.i has rs2 = 0 and vm = 1 */
1952        vext_check_ss(s, a->rd, 0, 1)) {
1953        int64_t simm = sextract64(a->rs1, 0, 5);
1954        if (s->vl_eq_vlmax) {
1955            tcg_gen_gvec_dup_imm(s->sew, vreg_ofs(s, a->rd),
1956                                 MAXSZ(s), MAXSZ(s), simm);
1957            mark_vs_dirty(s);
1958        } else {
1959            TCGv_i32 desc;
1960            TCGv_i64 s1;
1961            TCGv_ptr dest;
1962            uint32_t data = FIELD_DP32(0, VDATA, LMUL, s->lmul);
1963            static gen_helper_vmv_vx * const fns[4] = {
1964                gen_helper_vmv_v_x_b, gen_helper_vmv_v_x_h,
1965                gen_helper_vmv_v_x_w, gen_helper_vmv_v_x_d,
1966            };
1967            TCGLabel *over = gen_new_label();
1968            tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
1969
1970            s1 = tcg_constant_i64(simm);
1971            dest = tcg_temp_new_ptr();
1972            desc = tcg_constant_i32(simd_desc(s->vlen / 8, s->vlen / 8, data));
1973            tcg_gen_addi_ptr(dest, cpu_env, vreg_ofs(s, a->rd));
1974            fns[s->sew](dest, s1, cpu_env, desc);
1975
1976            tcg_temp_free_ptr(dest);
1977            mark_vs_dirty(s);
1978            gen_set_label(over);
1979        }
1980        return true;
1981    }
1982    return false;
1983}
1984
1985GEN_OPIVV_TRANS(vmerge_vvm, opivv_vadc_check)
1986GEN_OPIVX_TRANS(vmerge_vxm, opivx_vadc_check)
1987GEN_OPIVI_TRANS(vmerge_vim, IMM_SX, vmerge_vxm, opivx_vadc_check)
1988
1989/*
1990 *** Vector Fixed-Point Arithmetic Instructions
1991 */
1992
1993/* Vector Single-Width Saturating Add and Subtract */
1994GEN_OPIVV_TRANS(vsaddu_vv, opivv_check)
1995GEN_OPIVV_TRANS(vsadd_vv,  opivv_check)
1996GEN_OPIVV_TRANS(vssubu_vv, opivv_check)
1997GEN_OPIVV_TRANS(vssub_vv,  opivv_check)
1998GEN_OPIVX_TRANS(vsaddu_vx,  opivx_check)
1999GEN_OPIVX_TRANS(vsadd_vx,  opivx_check)
2000GEN_OPIVX_TRANS(vssubu_vx,  opivx_check)
2001GEN_OPIVX_TRANS(vssub_vx,  opivx_check)
2002GEN_OPIVI_TRANS(vsaddu_vi, IMM_ZX, vsaddu_vx, opivx_check)
2003GEN_OPIVI_TRANS(vsadd_vi, IMM_SX, vsadd_vx, opivx_check)
2004
2005/* Vector Single-Width Averaging Add and Subtract */
2006GEN_OPIVV_TRANS(vaadd_vv, opivv_check)
2007GEN_OPIVV_TRANS(vasub_vv, opivv_check)
2008GEN_OPIVX_TRANS(vaadd_vx,  opivx_check)
2009GEN_OPIVX_TRANS(vasub_vx,  opivx_check)
2010GEN_OPIVI_TRANS(vaadd_vi, 0, vaadd_vx, opivx_check)
2011
2012/* Vector Single-Width Fractional Multiply with Rounding and Saturation */
2013GEN_OPIVV_TRANS(vsmul_vv, opivv_check)
2014GEN_OPIVX_TRANS(vsmul_vx,  opivx_check)
2015
2016/* Vector Widening Saturating Scaled Multiply-Add */
2017GEN_OPIVV_WIDEN_TRANS(vwsmaccu_vv, opivv_widen_check)
2018GEN_OPIVV_WIDEN_TRANS(vwsmacc_vv, opivv_widen_check)
2019GEN_OPIVV_WIDEN_TRANS(vwsmaccsu_vv, opivv_widen_check)
2020GEN_OPIVX_WIDEN_TRANS(vwsmaccu_vx)
2021GEN_OPIVX_WIDEN_TRANS(vwsmacc_vx)
2022GEN_OPIVX_WIDEN_TRANS(vwsmaccsu_vx)
2023GEN_OPIVX_WIDEN_TRANS(vwsmaccus_vx)
2024
2025/* Vector Single-Width Scaling Shift Instructions */
2026GEN_OPIVV_TRANS(vssrl_vv, opivv_check)
2027GEN_OPIVV_TRANS(vssra_vv, opivv_check)
2028GEN_OPIVX_TRANS(vssrl_vx,  opivx_check)
2029GEN_OPIVX_TRANS(vssra_vx,  opivx_check)
2030GEN_OPIVI_TRANS(vssrl_vi, IMM_ZX, vssrl_vx, opivx_check)
2031GEN_OPIVI_TRANS(vssra_vi, IMM_SX, vssra_vx, opivx_check)
2032
2033/* Vector Narrowing Fixed-Point Clip Instructions */
2034GEN_OPIVV_NARROW_TRANS(vnclipu_vv)
2035GEN_OPIVV_NARROW_TRANS(vnclip_vv)
2036GEN_OPIVX_NARROW_TRANS(vnclipu_vx)
2037GEN_OPIVX_NARROW_TRANS(vnclip_vx)
2038GEN_OPIVI_NARROW_TRANS(vnclipu_vi, IMM_ZX, vnclipu_vx)
2039GEN_OPIVI_NARROW_TRANS(vnclip_vi, IMM_ZX, vnclip_vx)
2040
2041/*
2042 *** Vector Float Point Arithmetic Instructions
2043 */
2044
2045/*
2046 * As RVF-only cpus always have values NaN-boxed to 64-bits,
2047 * RVF and RVD can be treated equally.
2048 * We don't have to deal with the cases of: SEW > FLEN.
2049 *
2050 * If SEW < FLEN, check whether input fp register is a valid
2051 * NaN-boxed value, in which case the least-significant SEW bits
2052 * of the f regsiter are used, else the canonical NaN value is used.
2053 */
2054static void do_nanbox(DisasContext *s, TCGv_i64 out, TCGv_i64 in)
2055{
2056    switch (s->sew) {
2057    case 1:
2058        gen_check_nanbox_h(out, in);
2059        break;
2060    case 2:
2061        gen_check_nanbox_s(out, in);
2062        break;
2063    case 3:
2064        tcg_gen_mov_i64(out, in);
2065        break;
2066    default:
2067        g_assert_not_reached();
2068    }
2069}
2070
2071/* Vector Single-Width Floating-Point Add/Subtract Instructions */
2072
2073/*
2074 * If the current SEW does not correspond to a supported IEEE floating-point
2075 * type, an illegal instruction exception is raised.
2076 */
2077static bool opfvv_check(DisasContext *s, arg_rmrr *a)
2078{
2079    return require_rvv(s) &&
2080           require_rvf(s) &&
2081           vext_check_isa_ill(s) &&
2082           vext_check_sss(s, a->rd, a->rs1, a->rs2, a->vm);
2083}
2084
2085/* OPFVV without GVEC IR */
2086#define GEN_OPFVV_TRANS(NAME, CHECK)                               \
2087static bool trans_##NAME(DisasContext *s, arg_rmrr *a)             \
2088{                                                                  \
2089    if (CHECK(s, a)) {                                             \
2090        uint32_t data = 0;                                         \
2091        static gen_helper_gvec_4_ptr * const fns[3] = {            \
2092            gen_helper_##NAME##_h,                                 \
2093            gen_helper_##NAME##_w,                                 \
2094            gen_helper_##NAME##_d,                                 \
2095        };                                                         \
2096        TCGLabel *over = gen_new_label();                          \
2097        gen_set_rm(s, 7);                                          \
2098        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);          \
2099                                                                   \
2100        data = FIELD_DP32(data, VDATA, VM, a->vm);                 \
2101        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);             \
2102        tcg_gen_gvec_4_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),     \
2103                           vreg_ofs(s, a->rs1),                    \
2104                           vreg_ofs(s, a->rs2), cpu_env,           \
2105                           s->vlen / 8, s->vlen / 8, data,         \
2106                           fns[s->sew - 1]);                       \
2107        mark_vs_dirty(s);                                          \
2108        gen_set_label(over);                                       \
2109        return true;                                               \
2110    }                                                              \
2111    return false;                                                  \
2112}
2113GEN_OPFVV_TRANS(vfadd_vv, opfvv_check)
2114GEN_OPFVV_TRANS(vfsub_vv, opfvv_check)
2115
2116typedef void gen_helper_opfvf(TCGv_ptr, TCGv_ptr, TCGv_i64, TCGv_ptr,
2117                              TCGv_env, TCGv_i32);
2118
2119static bool opfvf_trans(uint32_t vd, uint32_t rs1, uint32_t vs2,
2120                        uint32_t data, gen_helper_opfvf *fn, DisasContext *s)
2121{
2122    TCGv_ptr dest, src2, mask;
2123    TCGv_i32 desc;
2124    TCGv_i64 t1;
2125
2126    TCGLabel *over = gen_new_label();
2127    tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
2128
2129    dest = tcg_temp_new_ptr();
2130    mask = tcg_temp_new_ptr();
2131    src2 = tcg_temp_new_ptr();
2132    desc = tcg_constant_i32(simd_desc(s->vlen / 8, s->vlen / 8, data));
2133
2134    tcg_gen_addi_ptr(dest, cpu_env, vreg_ofs(s, vd));
2135    tcg_gen_addi_ptr(src2, cpu_env, vreg_ofs(s, vs2));
2136    tcg_gen_addi_ptr(mask, cpu_env, vreg_ofs(s, 0));
2137
2138    /* NaN-box f[rs1] */
2139    t1 = tcg_temp_new_i64();
2140    do_nanbox(s, t1, cpu_fpr[rs1]);
2141
2142    fn(dest, mask, t1, src2, cpu_env, desc);
2143
2144    tcg_temp_free_ptr(dest);
2145    tcg_temp_free_ptr(mask);
2146    tcg_temp_free_ptr(src2);
2147    tcg_temp_free_i64(t1);
2148    mark_vs_dirty(s);
2149    gen_set_label(over);
2150    return true;
2151}
2152
2153/*
2154 * If the current SEW does not correspond to a supported IEEE floating-point
2155 * type, an illegal instruction exception is raised
2156 */
2157static bool opfvf_check(DisasContext *s, arg_rmrr *a)
2158{
2159    return require_rvv(s) &&
2160           require_rvf(s) &&
2161           vext_check_isa_ill(s) &&
2162           vext_check_ss(s, a->rd, a->rs2, a->vm);
2163}
2164
2165/* OPFVF without GVEC IR */
2166#define GEN_OPFVF_TRANS(NAME, CHECK)                              \
2167static bool trans_##NAME(DisasContext *s, arg_rmrr *a)            \
2168{                                                                 \
2169    if (CHECK(s, a)) {                                            \
2170        uint32_t data = 0;                                        \
2171        static gen_helper_opfvf *const fns[3] = {                 \
2172            gen_helper_##NAME##_h,                                \
2173            gen_helper_##NAME##_w,                                \
2174            gen_helper_##NAME##_d,                                \
2175        };                                                        \
2176        gen_set_rm(s, 7);                                         \
2177        data = FIELD_DP32(data, VDATA, VM, a->vm);                \
2178        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);            \
2179        return opfvf_trans(a->rd, a->rs1, a->rs2, data,           \
2180                           fns[s->sew - 1], s);                   \
2181    }                                                             \
2182    return false;                                                 \
2183}
2184
2185GEN_OPFVF_TRANS(vfadd_vf,  opfvf_check)
2186GEN_OPFVF_TRANS(vfsub_vf,  opfvf_check)
2187GEN_OPFVF_TRANS(vfrsub_vf,  opfvf_check)
2188
2189/* Vector Widening Floating-Point Add/Subtract Instructions */
2190static bool opfvv_widen_check(DisasContext *s, arg_rmrr *a)
2191{
2192    return require_rvv(s) &&
2193           require_rvf(s) &&
2194           vext_check_isa_ill(s) &&
2195           vext_check_dss(s, a->rd, a->rs1, a->rs2, a->vm);
2196}
2197
2198/* OPFVV with WIDEN */
2199#define GEN_OPFVV_WIDEN_TRANS(NAME, CHECK)                       \
2200static bool trans_##NAME(DisasContext *s, arg_rmrr *a)           \
2201{                                                                \
2202    if (CHECK(s, a)) {                                           \
2203        uint32_t data = 0;                                       \
2204        static gen_helper_gvec_4_ptr * const fns[2] = {          \
2205            gen_helper_##NAME##_h, gen_helper_##NAME##_w,        \
2206        };                                                       \
2207        TCGLabel *over = gen_new_label();                        \
2208        gen_set_rm(s, 7);                                        \
2209        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);        \
2210                                                                 \
2211        data = FIELD_DP32(data, VDATA, VM, a->vm);               \
2212        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);           \
2213        tcg_gen_gvec_4_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),   \
2214                           vreg_ofs(s, a->rs1),                  \
2215                           vreg_ofs(s, a->rs2), cpu_env,         \
2216                           s->vlen / 8, s->vlen / 8, data,       \
2217                           fns[s->sew - 1]);                     \
2218        mark_vs_dirty(s);                                        \
2219        gen_set_label(over);                                     \
2220        return true;                                             \
2221    }                                                            \
2222    return false;                                                \
2223}
2224
2225GEN_OPFVV_WIDEN_TRANS(vfwadd_vv, opfvv_widen_check)
2226GEN_OPFVV_WIDEN_TRANS(vfwsub_vv, opfvv_widen_check)
2227
2228static bool opfvf_widen_check(DisasContext *s, arg_rmrr *a)
2229{
2230    return require_rvv(s) &&
2231           require_rvf(s) &&
2232           vext_check_isa_ill(s) &&
2233           vext_check_ds(s, a->rd, a->rs2, a->vm);
2234}
2235
2236/* OPFVF with WIDEN */
2237#define GEN_OPFVF_WIDEN_TRANS(NAME)                              \
2238static bool trans_##NAME(DisasContext *s, arg_rmrr *a)           \
2239{                                                                \
2240    if (opfvf_widen_check(s, a)) {                               \
2241        uint32_t data = 0;                                       \
2242        static gen_helper_opfvf *const fns[2] = {                \
2243            gen_helper_##NAME##_h, gen_helper_##NAME##_w,        \
2244        };                                                       \
2245        gen_set_rm(s, 7);                                        \
2246        data = FIELD_DP32(data, VDATA, VM, a->vm);               \
2247        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);           \
2248        return opfvf_trans(a->rd, a->rs1, a->rs2, data,          \
2249                           fns[s->sew - 1], s);                  \
2250    }                                                            \
2251    return false;                                                \
2252}
2253
2254GEN_OPFVF_WIDEN_TRANS(vfwadd_vf)
2255GEN_OPFVF_WIDEN_TRANS(vfwsub_vf)
2256
2257static bool opfwv_widen_check(DisasContext *s, arg_rmrr *a)
2258{
2259    return require_rvv(s) &&
2260           require_rvf(s) &&
2261           vext_check_isa_ill(s) &&
2262           vext_check_dds(s, a->rd, a->rs1, a->rs2, a->vm);
2263}
2264
2265/* WIDEN OPFVV with WIDEN */
2266#define GEN_OPFWV_WIDEN_TRANS(NAME)                                \
2267static bool trans_##NAME(DisasContext *s, arg_rmrr *a)             \
2268{                                                                  \
2269    if (opfwv_widen_check(s, a)) {                                 \
2270        uint32_t data = 0;                                         \
2271        static gen_helper_gvec_4_ptr * const fns[2] = {            \
2272            gen_helper_##NAME##_h, gen_helper_##NAME##_w,          \
2273        };                                                         \
2274        TCGLabel *over = gen_new_label();                          \
2275        gen_set_rm(s, 7);                                          \
2276        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);          \
2277                                                                   \
2278        data = FIELD_DP32(data, VDATA, VM, a->vm);                 \
2279        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);             \
2280        tcg_gen_gvec_4_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),     \
2281                           vreg_ofs(s, a->rs1),                    \
2282                           vreg_ofs(s, a->rs2), cpu_env,           \
2283                           s->vlen / 8, s->vlen / 8, data,         \
2284                           fns[s->sew - 1]);                       \
2285        mark_vs_dirty(s);                                          \
2286        gen_set_label(over);                                       \
2287        return true;                                               \
2288    }                                                              \
2289    return false;                                                  \
2290}
2291
2292GEN_OPFWV_WIDEN_TRANS(vfwadd_wv)
2293GEN_OPFWV_WIDEN_TRANS(vfwsub_wv)
2294
2295static bool opfwf_widen_check(DisasContext *s, arg_rmrr *a)
2296{
2297    return require_rvv(s) &&
2298           require_rvf(s) &&
2299           vext_check_isa_ill(s) &&
2300           vext_check_dd(s, a->rd, a->rs2, a->vm);
2301}
2302
2303/* WIDEN OPFVF with WIDEN */
2304#define GEN_OPFWF_WIDEN_TRANS(NAME)                              \
2305static bool trans_##NAME(DisasContext *s, arg_rmrr *a)           \
2306{                                                                \
2307    if (opfwf_widen_check(s, a)) {                               \
2308        uint32_t data = 0;                                       \
2309        static gen_helper_opfvf *const fns[2] = {                \
2310            gen_helper_##NAME##_h, gen_helper_##NAME##_w,        \
2311        };                                                       \
2312        gen_set_rm(s, 7);                                        \
2313        data = FIELD_DP32(data, VDATA, VM, a->vm);               \
2314        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);           \
2315        return opfvf_trans(a->rd, a->rs1, a->rs2, data,          \
2316                           fns[s->sew - 1], s);                  \
2317    }                                                            \
2318    return false;                                                \
2319}
2320
2321GEN_OPFWF_WIDEN_TRANS(vfwadd_wf)
2322GEN_OPFWF_WIDEN_TRANS(vfwsub_wf)
2323
2324/* Vector Single-Width Floating-Point Multiply/Divide Instructions */
2325GEN_OPFVV_TRANS(vfmul_vv, opfvv_check)
2326GEN_OPFVV_TRANS(vfdiv_vv, opfvv_check)
2327GEN_OPFVF_TRANS(vfmul_vf,  opfvf_check)
2328GEN_OPFVF_TRANS(vfdiv_vf,  opfvf_check)
2329GEN_OPFVF_TRANS(vfrdiv_vf,  opfvf_check)
2330
2331/* Vector Widening Floating-Point Multiply */
2332GEN_OPFVV_WIDEN_TRANS(vfwmul_vv, opfvv_widen_check)
2333GEN_OPFVF_WIDEN_TRANS(vfwmul_vf)
2334
2335/* Vector Single-Width Floating-Point Fused Multiply-Add Instructions */
2336GEN_OPFVV_TRANS(vfmacc_vv, opfvv_check)
2337GEN_OPFVV_TRANS(vfnmacc_vv, opfvv_check)
2338GEN_OPFVV_TRANS(vfmsac_vv, opfvv_check)
2339GEN_OPFVV_TRANS(vfnmsac_vv, opfvv_check)
2340GEN_OPFVV_TRANS(vfmadd_vv, opfvv_check)
2341GEN_OPFVV_TRANS(vfnmadd_vv, opfvv_check)
2342GEN_OPFVV_TRANS(vfmsub_vv, opfvv_check)
2343GEN_OPFVV_TRANS(vfnmsub_vv, opfvv_check)
2344GEN_OPFVF_TRANS(vfmacc_vf, opfvf_check)
2345GEN_OPFVF_TRANS(vfnmacc_vf, opfvf_check)
2346GEN_OPFVF_TRANS(vfmsac_vf, opfvf_check)
2347GEN_OPFVF_TRANS(vfnmsac_vf, opfvf_check)
2348GEN_OPFVF_TRANS(vfmadd_vf, opfvf_check)
2349GEN_OPFVF_TRANS(vfnmadd_vf, opfvf_check)
2350GEN_OPFVF_TRANS(vfmsub_vf, opfvf_check)
2351GEN_OPFVF_TRANS(vfnmsub_vf, opfvf_check)
2352
2353/* Vector Widening Floating-Point Fused Multiply-Add Instructions */
2354GEN_OPFVV_WIDEN_TRANS(vfwmacc_vv, opfvv_widen_check)
2355GEN_OPFVV_WIDEN_TRANS(vfwnmacc_vv, opfvv_widen_check)
2356GEN_OPFVV_WIDEN_TRANS(vfwmsac_vv, opfvv_widen_check)
2357GEN_OPFVV_WIDEN_TRANS(vfwnmsac_vv, opfvv_widen_check)
2358GEN_OPFVF_WIDEN_TRANS(vfwmacc_vf)
2359GEN_OPFVF_WIDEN_TRANS(vfwnmacc_vf)
2360GEN_OPFVF_WIDEN_TRANS(vfwmsac_vf)
2361GEN_OPFVF_WIDEN_TRANS(vfwnmsac_vf)
2362
2363/* Vector Floating-Point Square-Root Instruction */
2364
2365/*
2366 * If the current SEW does not correspond to a supported IEEE floating-point
2367 * type, an illegal instruction exception is raised
2368 */
2369static bool opfv_check(DisasContext *s, arg_rmr *a)
2370{
2371    return require_rvv(s) &&
2372           require_rvf(s) &&
2373           vext_check_isa_ill(s) &&
2374           /* OPFV instructions ignore vs1 check */
2375           vext_check_ss(s, a->rd, a->rs2, a->vm);
2376}
2377
2378#define GEN_OPFV_TRANS(NAME, CHECK)                                \
2379static bool trans_##NAME(DisasContext *s, arg_rmr *a)              \
2380{                                                                  \
2381    if (CHECK(s, a)) {                                             \
2382        uint32_t data = 0;                                         \
2383        static gen_helper_gvec_3_ptr * const fns[3] = {            \
2384            gen_helper_##NAME##_h,                                 \
2385            gen_helper_##NAME##_w,                                 \
2386            gen_helper_##NAME##_d,                                 \
2387        };                                                         \
2388        TCGLabel *over = gen_new_label();                          \
2389        gen_set_rm(s, 7);                                          \
2390        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);          \
2391                                                                   \
2392        data = FIELD_DP32(data, VDATA, VM, a->vm);                 \
2393        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);             \
2394        tcg_gen_gvec_3_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),     \
2395                           vreg_ofs(s, a->rs2), cpu_env,           \
2396                           s->vlen / 8, s->vlen / 8, data,         \
2397                           fns[s->sew - 1]);                       \
2398        mark_vs_dirty(s);                                          \
2399        gen_set_label(over);                                       \
2400        return true;                                               \
2401    }                                                              \
2402    return false;                                                  \
2403}
2404
2405GEN_OPFV_TRANS(vfsqrt_v, opfv_check)
2406
2407/* Vector Floating-Point MIN/MAX Instructions */
2408GEN_OPFVV_TRANS(vfmin_vv, opfvv_check)
2409GEN_OPFVV_TRANS(vfmax_vv, opfvv_check)
2410GEN_OPFVF_TRANS(vfmin_vf, opfvf_check)
2411GEN_OPFVF_TRANS(vfmax_vf, opfvf_check)
2412
2413/* Vector Floating-Point Sign-Injection Instructions */
2414GEN_OPFVV_TRANS(vfsgnj_vv, opfvv_check)
2415GEN_OPFVV_TRANS(vfsgnjn_vv, opfvv_check)
2416GEN_OPFVV_TRANS(vfsgnjx_vv, opfvv_check)
2417GEN_OPFVF_TRANS(vfsgnj_vf, opfvf_check)
2418GEN_OPFVF_TRANS(vfsgnjn_vf, opfvf_check)
2419GEN_OPFVF_TRANS(vfsgnjx_vf, opfvf_check)
2420
2421/* Vector Floating-Point Compare Instructions */
2422static bool opfvv_cmp_check(DisasContext *s, arg_rmrr *a)
2423{
2424    return require_rvv(s) &&
2425           require_rvf(s) &&
2426           vext_check_isa_ill(s) &&
2427           vext_check_mss(s, a->rd, a->rs1, a->rs2);
2428}
2429
2430GEN_OPFVV_TRANS(vmfeq_vv, opfvv_cmp_check)
2431GEN_OPFVV_TRANS(vmfne_vv, opfvv_cmp_check)
2432GEN_OPFVV_TRANS(vmflt_vv, opfvv_cmp_check)
2433GEN_OPFVV_TRANS(vmfle_vv, opfvv_cmp_check)
2434GEN_OPFVV_TRANS(vmford_vv, opfvv_cmp_check)
2435
2436static bool opfvf_cmp_check(DisasContext *s, arg_rmrr *a)
2437{
2438    return require_rvv(s) &&
2439           require_rvf(s) &&
2440           vext_check_isa_ill(s) &&
2441           vext_check_ms(s, a->rd, a->rs2);
2442}
2443
2444GEN_OPFVF_TRANS(vmfeq_vf, opfvf_cmp_check)
2445GEN_OPFVF_TRANS(vmfne_vf, opfvf_cmp_check)
2446GEN_OPFVF_TRANS(vmflt_vf, opfvf_cmp_check)
2447GEN_OPFVF_TRANS(vmfle_vf, opfvf_cmp_check)
2448GEN_OPFVF_TRANS(vmfgt_vf, opfvf_cmp_check)
2449GEN_OPFVF_TRANS(vmfge_vf, opfvf_cmp_check)
2450GEN_OPFVF_TRANS(vmford_vf, opfvf_cmp_check)
2451
2452/* Vector Floating-Point Classify Instruction */
2453GEN_OPFV_TRANS(vfclass_v, opfv_check)
2454
2455/* Vector Floating-Point Merge Instruction */
2456GEN_OPFVF_TRANS(vfmerge_vfm,  opfvf_check)
2457
2458static bool trans_vfmv_v_f(DisasContext *s, arg_vfmv_v_f *a)
2459{
2460    if (require_rvv(s) &&
2461        require_rvf(s) &&
2462        vext_check_isa_ill(s) &&
2463        require_align(a->rd, s->lmul)) {
2464        if (s->vl_eq_vlmax) {
2465            tcg_gen_gvec_dup_i64(s->sew, vreg_ofs(s, a->rd),
2466                                 MAXSZ(s), MAXSZ(s), cpu_fpr[a->rs1]);
2467            mark_vs_dirty(s);
2468        } else {
2469            TCGv_ptr dest;
2470            TCGv_i32 desc;
2471            uint32_t data = FIELD_DP32(0, VDATA, LMUL, s->lmul);
2472            static gen_helper_vmv_vx * const fns[3] = {
2473                gen_helper_vmv_v_x_h,
2474                gen_helper_vmv_v_x_w,
2475                gen_helper_vmv_v_x_d,
2476            };
2477            TCGLabel *over = gen_new_label();
2478            tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
2479
2480            dest = tcg_temp_new_ptr();
2481            desc = tcg_constant_i32(simd_desc(s->vlen / 8, s->vlen / 8, data));
2482            tcg_gen_addi_ptr(dest, cpu_env, vreg_ofs(s, a->rd));
2483            fns[s->sew - 1](dest, cpu_fpr[a->rs1], cpu_env, desc);
2484
2485            tcg_temp_free_ptr(dest);
2486            mark_vs_dirty(s);
2487            gen_set_label(over);
2488        }
2489        return true;
2490    }
2491    return false;
2492}
2493
2494/* Single-Width Floating-Point/Integer Type-Convert Instructions */
2495GEN_OPFV_TRANS(vfcvt_xu_f_v, opfv_check)
2496GEN_OPFV_TRANS(vfcvt_x_f_v, opfv_check)
2497GEN_OPFV_TRANS(vfcvt_f_xu_v, opfv_check)
2498GEN_OPFV_TRANS(vfcvt_f_x_v, opfv_check)
2499
2500/* Widening Floating-Point/Integer Type-Convert Instructions */
2501
2502/*
2503 * If the current SEW does not correspond to a supported IEEE floating-point
2504 * type, an illegal instruction exception is raised
2505 */
2506static bool opfv_widen_check(DisasContext *s, arg_rmr *a)
2507{
2508    return require_rvv(s) &&
2509           require_scale_rvf(s) &&
2510           (s->sew != MO_8) &&
2511           vext_check_isa_ill(s) &&
2512           vext_check_ds(s, a->rd, a->rs2, a->vm);
2513}
2514
2515#define GEN_OPFV_WIDEN_TRANS(NAME)                                 \
2516static bool trans_##NAME(DisasContext *s, arg_rmr *a)              \
2517{                                                                  \
2518    if (opfv_widen_check(s, a)) {                                  \
2519        uint32_t data = 0;                                         \
2520        static gen_helper_gvec_3_ptr * const fns[2] = {            \
2521            gen_helper_##NAME##_h,                                 \
2522            gen_helper_##NAME##_w,                                 \
2523        };                                                         \
2524        TCGLabel *over = gen_new_label();                          \
2525        gen_set_rm(s, 7);                                          \
2526        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);          \
2527                                                                   \
2528        data = FIELD_DP32(data, VDATA, VM, a->vm);                 \
2529        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);             \
2530        tcg_gen_gvec_3_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),     \
2531                           vreg_ofs(s, a->rs2), cpu_env,           \
2532                           s->vlen / 8, s->vlen / 8, data,         \
2533                           fns[s->sew - 1]);                       \
2534        mark_vs_dirty(s);                                          \
2535        gen_set_label(over);                                       \
2536        return true;                                               \
2537    }                                                              \
2538    return false;                                                  \
2539}
2540
2541GEN_OPFV_WIDEN_TRANS(vfwcvt_xu_f_v)
2542GEN_OPFV_WIDEN_TRANS(vfwcvt_x_f_v)
2543GEN_OPFV_WIDEN_TRANS(vfwcvt_f_xu_v)
2544GEN_OPFV_WIDEN_TRANS(vfwcvt_f_x_v)
2545GEN_OPFV_WIDEN_TRANS(vfwcvt_f_f_v)
2546
2547/* Narrowing Floating-Point/Integer Type-Convert Instructions */
2548
2549/*
2550 * If the current SEW does not correspond to a supported IEEE floating-point
2551 * type, an illegal instruction exception is raised
2552 */
2553static bool opfv_narrow_check(DisasContext *s, arg_rmr *a)
2554{
2555    return require_rvv(s) &&
2556           require_rvf(s) &&
2557           (s->sew != MO_64) &&
2558           vext_check_isa_ill(s) &&
2559           /* OPFV narrowing instructions ignore vs1 check */
2560           vext_check_sd(s, a->rd, a->rs2, a->vm);
2561}
2562
2563#define GEN_OPFV_NARROW_TRANS(NAME)                                \
2564static bool trans_##NAME(DisasContext *s, arg_rmr *a)              \
2565{                                                                  \
2566    if (opfv_narrow_check(s, a)) {                                 \
2567        uint32_t data = 0;                                         \
2568        static gen_helper_gvec_3_ptr * const fns[2] = {            \
2569            gen_helper_##NAME##_h,                                 \
2570            gen_helper_##NAME##_w,                                 \
2571        };                                                         \
2572        TCGLabel *over = gen_new_label();                          \
2573        gen_set_rm(s, 7);                                          \
2574        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);          \
2575                                                                   \
2576        data = FIELD_DP32(data, VDATA, VM, a->vm);                 \
2577        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);             \
2578        tcg_gen_gvec_3_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),     \
2579                           vreg_ofs(s, a->rs2), cpu_env,           \
2580                           s->vlen / 8, s->vlen / 8, data,         \
2581                           fns[s->sew - 1]);                       \
2582        mark_vs_dirty(s);                                          \
2583        gen_set_label(over);                                       \
2584        return true;                                               \
2585    }                                                              \
2586    return false;                                                  \
2587}
2588
2589GEN_OPFV_NARROW_TRANS(vfncvt_xu_f_v)
2590GEN_OPFV_NARROW_TRANS(vfncvt_x_f_v)
2591GEN_OPFV_NARROW_TRANS(vfncvt_f_xu_v)
2592GEN_OPFV_NARROW_TRANS(vfncvt_f_x_v)
2593GEN_OPFV_NARROW_TRANS(vfncvt_f_f_v)
2594
2595/*
2596 *** Vector Reduction Operations
2597 */
2598/* Vector Single-Width Integer Reduction Instructions */
2599static bool reduction_check(DisasContext *s, arg_rmrr *a)
2600{
2601    return require_rvv(s) &&
2602           vext_check_isa_ill(s) &&
2603           vext_check_reduction(s, a->rs2);
2604}
2605
2606GEN_OPIVV_TRANS(vredsum_vs, reduction_check)
2607GEN_OPIVV_TRANS(vredmaxu_vs, reduction_check)
2608GEN_OPIVV_TRANS(vredmax_vs, reduction_check)
2609GEN_OPIVV_TRANS(vredminu_vs, reduction_check)
2610GEN_OPIVV_TRANS(vredmin_vs, reduction_check)
2611GEN_OPIVV_TRANS(vredand_vs, reduction_check)
2612GEN_OPIVV_TRANS(vredor_vs, reduction_check)
2613GEN_OPIVV_TRANS(vredxor_vs, reduction_check)
2614
2615/* Vector Widening Integer Reduction Instructions */
2616static bool reduction_widen_check(DisasContext *s, arg_rmrr *a)
2617{
2618    return reduction_check(s, a) && (s->sew < MO_64);
2619}
2620
2621GEN_OPIVV_WIDEN_TRANS(vwredsum_vs, reduction_widen_check)
2622GEN_OPIVV_WIDEN_TRANS(vwredsumu_vs, reduction_widen_check)
2623
2624/* Vector Single-Width Floating-Point Reduction Instructions */
2625GEN_OPFVV_TRANS(vfredsum_vs, reduction_check)
2626GEN_OPFVV_TRANS(vfredmax_vs, reduction_check)
2627GEN_OPFVV_TRANS(vfredmin_vs, reduction_check)
2628
2629/* Vector Widening Floating-Point Reduction Instructions */
2630GEN_OPFVV_WIDEN_TRANS(vfwredsum_vs, reduction_check)
2631
2632/*
2633 *** Vector Mask Operations
2634 */
2635
2636/* Vector Mask-Register Logical Instructions */
2637#define GEN_MM_TRANS(NAME)                                         \
2638static bool trans_##NAME(DisasContext *s, arg_r *a)                \
2639{                                                                  \
2640    if (vext_check_isa_ill(s)) {                                   \
2641        uint32_t data = 0;                                         \
2642        gen_helper_gvec_4_ptr *fn = gen_helper_##NAME;             \
2643        TCGLabel *over = gen_new_label();                          \
2644        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);          \
2645                                                                   \
2646        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);             \
2647        tcg_gen_gvec_4_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),     \
2648                           vreg_ofs(s, a->rs1),                    \
2649                           vreg_ofs(s, a->rs2), cpu_env,           \
2650                           s->vlen / 8, s->vlen / 8, data, fn);    \
2651        mark_vs_dirty(s);                                          \
2652        gen_set_label(over);                                       \
2653        return true;                                               \
2654    }                                                              \
2655    return false;                                                  \
2656}
2657
2658GEN_MM_TRANS(vmand_mm)
2659GEN_MM_TRANS(vmnand_mm)
2660GEN_MM_TRANS(vmandnot_mm)
2661GEN_MM_TRANS(vmxor_mm)
2662GEN_MM_TRANS(vmor_mm)
2663GEN_MM_TRANS(vmnor_mm)
2664GEN_MM_TRANS(vmornot_mm)
2665GEN_MM_TRANS(vmxnor_mm)
2666
2667/* Vector count population in mask vcpop */
2668static bool trans_vcpop_m(DisasContext *s, arg_rmr *a)
2669{
2670    if (require_rvv(s) &&
2671        vext_check_isa_ill(s)) {
2672        TCGv_ptr src2, mask;
2673        TCGv dst;
2674        TCGv_i32 desc;
2675        uint32_t data = 0;
2676        data = FIELD_DP32(data, VDATA, VM, a->vm);
2677        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);
2678
2679        mask = tcg_temp_new_ptr();
2680        src2 = tcg_temp_new_ptr();
2681        dst = dest_gpr(s, a->rd);
2682        desc = tcg_constant_i32(simd_desc(s->vlen / 8, s->vlen / 8, data));
2683
2684        tcg_gen_addi_ptr(src2, cpu_env, vreg_ofs(s, a->rs2));
2685        tcg_gen_addi_ptr(mask, cpu_env, vreg_ofs(s, 0));
2686
2687        gen_helper_vcpop_m(dst, mask, src2, cpu_env, desc);
2688        gen_set_gpr(s, a->rd, dst);
2689
2690        tcg_temp_free_ptr(mask);
2691        tcg_temp_free_ptr(src2);
2692
2693        return true;
2694    }
2695    return false;
2696}
2697
2698/* vmfirst find-first-set mask bit */
2699static bool trans_vfirst_m(DisasContext *s, arg_rmr *a)
2700{
2701    if (require_rvv(s) &&
2702        vext_check_isa_ill(s)) {
2703        TCGv_ptr src2, mask;
2704        TCGv dst;
2705        TCGv_i32 desc;
2706        uint32_t data = 0;
2707        data = FIELD_DP32(data, VDATA, VM, a->vm);
2708        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);
2709
2710        mask = tcg_temp_new_ptr();
2711        src2 = tcg_temp_new_ptr();
2712        dst = dest_gpr(s, a->rd);
2713        desc = tcg_constant_i32(simd_desc(s->vlen / 8, s->vlen / 8, data));
2714
2715        tcg_gen_addi_ptr(src2, cpu_env, vreg_ofs(s, a->rs2));
2716        tcg_gen_addi_ptr(mask, cpu_env, vreg_ofs(s, 0));
2717
2718        gen_helper_vfirst_m(dst, mask, src2, cpu_env, desc);
2719        gen_set_gpr(s, a->rd, dst);
2720
2721        tcg_temp_free_ptr(mask);
2722        tcg_temp_free_ptr(src2);
2723        return true;
2724    }
2725    return false;
2726}
2727
2728/* vmsbf.m set-before-first mask bit */
2729/* vmsif.m set-includ-first mask bit */
2730/* vmsof.m set-only-first mask bit */
2731#define GEN_M_TRANS(NAME)                                          \
2732static bool trans_##NAME(DisasContext *s, arg_rmr *a)              \
2733{                                                                  \
2734    if (require_rvv(s) &&                                          \
2735        vext_check_isa_ill(s) &&                                   \
2736        require_vm(a->vm, a->rd) &&                                \
2737        (a->rd != a->rs2)) {                                       \
2738        uint32_t data = 0;                                         \
2739        gen_helper_gvec_3_ptr *fn = gen_helper_##NAME;             \
2740        TCGLabel *over = gen_new_label();                          \
2741        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);          \
2742                                                                   \
2743        data = FIELD_DP32(data, VDATA, VM, a->vm);                 \
2744        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);             \
2745        tcg_gen_gvec_3_ptr(vreg_ofs(s, a->rd),                     \
2746                           vreg_ofs(s, 0), vreg_ofs(s, a->rs2),    \
2747                           cpu_env, s->vlen / 8, s->vlen / 8,      \
2748                           data, fn);                              \
2749        mark_vs_dirty(s);                                          \
2750        gen_set_label(over);                                       \
2751        return true;                                               \
2752    }                                                              \
2753    return false;                                                  \
2754}
2755
2756GEN_M_TRANS(vmsbf_m)
2757GEN_M_TRANS(vmsif_m)
2758GEN_M_TRANS(vmsof_m)
2759
2760/*
2761 * Vector Iota Instruction
2762 *
2763 * 1. The destination register cannot overlap the source register.
2764 * 2. If masked, cannot overlap the mask register ('v0').
2765 * 3. An illegal instruction exception is raised if vstart is non-zero.
2766 */
2767static bool trans_viota_m(DisasContext *s, arg_viota_m *a)
2768{
2769    if (require_rvv(s) &&
2770        vext_check_isa_ill(s) &&
2771        !is_overlapped(a->rd, 1 << MAX(s->lmul, 0), a->rs2, 1) &&
2772        require_vm(a->vm, a->rd) &&
2773        require_align(a->rd, s->lmul)) {
2774        uint32_t data = 0;
2775        TCGLabel *over = gen_new_label();
2776        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
2777
2778        data = FIELD_DP32(data, VDATA, VM, a->vm);
2779        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);
2780        static gen_helper_gvec_3_ptr * const fns[4] = {
2781            gen_helper_viota_m_b, gen_helper_viota_m_h,
2782            gen_helper_viota_m_w, gen_helper_viota_m_d,
2783        };
2784        tcg_gen_gvec_3_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),
2785                           vreg_ofs(s, a->rs2), cpu_env,
2786                           s->vlen / 8, s->vlen / 8, data, fns[s->sew]);
2787        mark_vs_dirty(s);
2788        gen_set_label(over);
2789        return true;
2790    }
2791    return false;
2792}
2793
2794/* Vector Element Index Instruction */
2795static bool trans_vid_v(DisasContext *s, arg_vid_v *a)
2796{
2797    if (require_rvv(s) &&
2798        vext_check_isa_ill(s) &&
2799        require_align(a->rd, s->lmul) &&
2800        require_vm(a->vm, a->rd)) {
2801        uint32_t data = 0;
2802        TCGLabel *over = gen_new_label();
2803        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
2804
2805        data = FIELD_DP32(data, VDATA, VM, a->vm);
2806        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);
2807        static gen_helper_gvec_2_ptr * const fns[4] = {
2808            gen_helper_vid_v_b, gen_helper_vid_v_h,
2809            gen_helper_vid_v_w, gen_helper_vid_v_d,
2810        };
2811        tcg_gen_gvec_2_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),
2812                           cpu_env, s->vlen / 8, s->vlen / 8,
2813                           data, fns[s->sew]);
2814        mark_vs_dirty(s);
2815        gen_set_label(over);
2816        return true;
2817    }
2818    return false;
2819}
2820
2821/*
2822 *** Vector Permutation Instructions
2823 */
2824
2825/* Integer Extract Instruction */
2826
2827static void load_element(TCGv_i64 dest, TCGv_ptr base,
2828                         int ofs, int sew, bool sign)
2829{
2830    switch (sew) {
2831    case MO_8:
2832        if (!sign) {
2833            tcg_gen_ld8u_i64(dest, base, ofs);
2834        } else {
2835            tcg_gen_ld8s_i64(dest, base, ofs);
2836        }
2837        break;
2838    case MO_16:
2839        if (!sign) {
2840            tcg_gen_ld16u_i64(dest, base, ofs);
2841        } else {
2842            tcg_gen_ld16s_i64(dest, base, ofs);
2843        }
2844        break;
2845    case MO_32:
2846        if (!sign) {
2847            tcg_gen_ld32u_i64(dest, base, ofs);
2848        } else {
2849            tcg_gen_ld32s_i64(dest, base, ofs);
2850        }
2851        break;
2852    case MO_64:
2853        tcg_gen_ld_i64(dest, base, ofs);
2854        break;
2855    default:
2856        g_assert_not_reached();
2857        break;
2858    }
2859}
2860
2861/* offset of the idx element with base regsiter r */
2862static uint32_t endian_ofs(DisasContext *s, int r, int idx)
2863{
2864#ifdef HOST_WORDS_BIGENDIAN
2865    return vreg_ofs(s, r) + ((idx ^ (7 >> s->sew)) << s->sew);
2866#else
2867    return vreg_ofs(s, r) + (idx << s->sew);
2868#endif
2869}
2870
2871/* adjust the index according to the endian */
2872static void endian_adjust(TCGv_i32 ofs, int sew)
2873{
2874#ifdef HOST_WORDS_BIGENDIAN
2875    tcg_gen_xori_i32(ofs, ofs, 7 >> sew);
2876#endif
2877}
2878
2879/* Load idx >= VLMAX ? 0 : vreg[idx] */
2880static void vec_element_loadx(DisasContext *s, TCGv_i64 dest,
2881                              int vreg, TCGv idx, int vlmax)
2882{
2883    TCGv_i32 ofs = tcg_temp_new_i32();
2884    TCGv_ptr base = tcg_temp_new_ptr();
2885    TCGv_i64 t_idx = tcg_temp_new_i64();
2886    TCGv_i64 t_vlmax, t_zero;
2887
2888    /*
2889     * Mask the index to the length so that we do
2890     * not produce an out-of-range load.
2891     */
2892    tcg_gen_trunc_tl_i32(ofs, idx);
2893    tcg_gen_andi_i32(ofs, ofs, vlmax - 1);
2894
2895    /* Convert the index to an offset. */
2896    endian_adjust(ofs, s->sew);
2897    tcg_gen_shli_i32(ofs, ofs, s->sew);
2898
2899    /* Convert the index to a pointer. */
2900    tcg_gen_ext_i32_ptr(base, ofs);
2901    tcg_gen_add_ptr(base, base, cpu_env);
2902
2903    /* Perform the load. */
2904    load_element(dest, base,
2905                 vreg_ofs(s, vreg), s->sew, false);
2906    tcg_temp_free_ptr(base);
2907    tcg_temp_free_i32(ofs);
2908
2909    /* Flush out-of-range indexing to zero.  */
2910    t_vlmax = tcg_constant_i64(vlmax);
2911    t_zero = tcg_constant_i64(0);
2912    tcg_gen_extu_tl_i64(t_idx, idx);
2913
2914    tcg_gen_movcond_i64(TCG_COND_LTU, dest, t_idx,
2915                        t_vlmax, dest, t_zero);
2916
2917    tcg_temp_free_i64(t_idx);
2918}
2919
2920static void vec_element_loadi(DisasContext *s, TCGv_i64 dest,
2921                              int vreg, int idx, bool sign)
2922{
2923    load_element(dest, cpu_env, endian_ofs(s, vreg, idx), s->sew, sign);
2924}
2925
2926static bool trans_vext_x_v(DisasContext *s, arg_r *a)
2927{
2928    TCGv_i64 tmp = tcg_temp_new_i64();
2929    TCGv dest = dest_gpr(s, a->rd);
2930
2931    if (a->rs1 == 0) {
2932        /* Special case vmv.x.s rd, vs2. */
2933        vec_element_loadi(s, tmp, a->rs2, 0, false);
2934    } else {
2935        /* This instruction ignores LMUL and vector register groups */
2936        int vlmax = s->vlen >> (3 + s->sew);
2937        vec_element_loadx(s, tmp, a->rs2, cpu_gpr[a->rs1], vlmax);
2938    }
2939
2940    tcg_gen_trunc_i64_tl(dest, tmp);
2941    gen_set_gpr(s, a->rd, dest);
2942
2943    tcg_temp_free_i64(tmp);
2944    return true;
2945}
2946
2947/* Integer Scalar Move Instruction */
2948
2949static void store_element(TCGv_i64 val, TCGv_ptr base,
2950                          int ofs, int sew)
2951{
2952    switch (sew) {
2953    case MO_8:
2954        tcg_gen_st8_i64(val, base, ofs);
2955        break;
2956    case MO_16:
2957        tcg_gen_st16_i64(val, base, ofs);
2958        break;
2959    case MO_32:
2960        tcg_gen_st32_i64(val, base, ofs);
2961        break;
2962    case MO_64:
2963        tcg_gen_st_i64(val, base, ofs);
2964        break;
2965    default:
2966        g_assert_not_reached();
2967        break;
2968    }
2969}
2970
2971/*
2972 * Store vreg[idx] = val.
2973 * The index must be in range of VLMAX.
2974 */
2975static void vec_element_storei(DisasContext *s, int vreg,
2976                               int idx, TCGv_i64 val)
2977{
2978    store_element(val, cpu_env, endian_ofs(s, vreg, idx), s->sew);
2979}
2980
2981/* vmv.x.s rd, vs2 # x[rd] = vs2[0] */
2982static bool trans_vmv_x_s(DisasContext *s, arg_vmv_x_s *a)
2983{
2984    if (require_rvv(s) &&
2985        vext_check_isa_ill(s)) {
2986        TCGv_i64 t1;
2987        TCGv dest;
2988
2989        t1 = tcg_temp_new_i64();
2990        dest = tcg_temp_new();
2991        /*
2992         * load vreg and sign-extend to 64 bits,
2993         * then truncate to XLEN bits before storing to gpr.
2994         */
2995        vec_element_loadi(s, t1, a->rs2, 0, true);
2996        tcg_gen_trunc_i64_tl(dest, t1);
2997        gen_set_gpr(s, a->rd, dest);
2998        tcg_temp_free_i64(t1);
2999        tcg_temp_free(dest);
3000
3001        return true;
3002    }
3003    return false;
3004}
3005
3006/* vmv.s.x vd, rs1 # vd[0] = rs1 */
3007static bool trans_vmv_s_x(DisasContext *s, arg_vmv_s_x *a)
3008{
3009    if (require_rvv(s) &&
3010        vext_check_isa_ill(s)) {
3011        /* This instruction ignores LMUL and vector register groups */
3012        TCGv_i64 t1;
3013        TCGv s1;
3014        TCGLabel *over = gen_new_label();
3015
3016        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
3017
3018        t1 = tcg_temp_new_i64();
3019
3020        /*
3021         * load gpr and sign-extend to 64 bits,
3022         * then truncate to SEW bits when storing to vreg.
3023         */
3024        s1 = get_gpr(s, a->rs1, EXT_NONE);
3025        tcg_gen_ext_tl_i64(t1, s1);
3026        vec_element_storei(s, a->rd, 0, t1);
3027        tcg_temp_free_i64(t1);
3028        mark_vs_dirty(s);
3029        gen_set_label(over);
3030        return true;
3031    }
3032    return false;
3033}
3034
3035/* Floating-Point Scalar Move Instructions */
3036static bool trans_vfmv_f_s(DisasContext *s, arg_vfmv_f_s *a)
3037{
3038    if (!s->vill && has_ext(s, RVF) &&
3039        (s->mstatus_fs != 0) && (s->sew != 0)) {
3040        unsigned int len = 8 << s->sew;
3041
3042        vec_element_loadi(s, cpu_fpr[a->rd], a->rs2, 0, false);
3043        if (len < 64) {
3044            tcg_gen_ori_i64(cpu_fpr[a->rd], cpu_fpr[a->rd],
3045                            MAKE_64BIT_MASK(len, 64 - len));
3046        }
3047
3048        mark_fs_dirty(s);
3049        return true;
3050    }
3051    return false;
3052}
3053
3054/* vfmv.s.f vd, rs1 # vd[0] = rs1 (vs2=0) */
3055static bool trans_vfmv_s_f(DisasContext *s, arg_vfmv_s_f *a)
3056{
3057    if (!s->vill && has_ext(s, RVF) && (s->sew != 0)) {
3058        TCGv_i64 t1;
3059        /* The instructions ignore LMUL and vector register group. */
3060        uint32_t vlmax = s->vlen >> 3;
3061
3062        /* if vl == 0, skip vector register write back */
3063        TCGLabel *over = gen_new_label();
3064        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
3065
3066        /* zeroed all elements */
3067        tcg_gen_gvec_dup_imm(SEW64, vreg_ofs(s, a->rd), vlmax, vlmax, 0);
3068
3069        /* NaN-box f[rs1] as necessary for SEW */
3070        t1 = tcg_temp_new_i64();
3071        if (s->sew == MO_64 && !has_ext(s, RVD)) {
3072            tcg_gen_ori_i64(t1, cpu_fpr[a->rs1], MAKE_64BIT_MASK(32, 32));
3073        } else {
3074            tcg_gen_mov_i64(t1, cpu_fpr[a->rs1]);
3075        }
3076        vec_element_storei(s, a->rd, 0, t1);
3077        tcg_temp_free_i64(t1);
3078        mark_vs_dirty(s);
3079        gen_set_label(over);
3080        return true;
3081    }
3082    return false;
3083}
3084
3085/* Vector Slide Instructions */
3086static bool slideup_check(DisasContext *s, arg_rmrr *a)
3087{
3088    return require_rvv(s) &&
3089           vext_check_isa_ill(s) &&
3090           vext_check_slide(s, a->rd, a->rs2, a->vm, true);
3091}
3092
3093GEN_OPIVX_TRANS(vslideup_vx, slideup_check)
3094GEN_OPIVX_TRANS(vslide1up_vx, slideup_check)
3095GEN_OPIVI_TRANS(vslideup_vi, IMM_ZX, vslideup_vx, slideup_check)
3096
3097static bool slidedown_check(DisasContext *s, arg_rmrr *a)
3098{
3099    return require_rvv(s) &&
3100           vext_check_isa_ill(s) &&
3101           vext_check_slide(s, a->rd, a->rs2, a->vm, false);
3102}
3103
3104GEN_OPIVX_TRANS(vslidedown_vx, slidedown_check)
3105GEN_OPIVX_TRANS(vslide1down_vx, slidedown_check)
3106GEN_OPIVI_TRANS(vslidedown_vi, IMM_ZX, vslidedown_vx, slidedown_check)
3107
3108/* Vector Register Gather Instruction */
3109static bool vrgather_vv_check(DisasContext *s, arg_rmrr *a)
3110{
3111    return require_rvv(s) &&
3112           vext_check_isa_ill(s) &&
3113           require_align(a->rd, s->lmul) &&
3114           require_align(a->rs1, s->lmul) &&
3115           require_align(a->rs2, s->lmul) &&
3116           (a->rd != a->rs2 && a->rd != a->rs1) &&
3117           require_vm(a->vm, a->rd);
3118}
3119
3120static bool vrgatherei16_vv_check(DisasContext *s, arg_rmrr *a)
3121{
3122    int8_t emul = MO_16 - s->sew + s->lmul;
3123    return require_rvv(s) &&
3124           vext_check_isa_ill(s) &&
3125           (emul >= -3 && emul <= 3) &&
3126           require_align(a->rd, s->lmul) &&
3127           require_align(a->rs1, emul) &&
3128           require_align(a->rs2, s->lmul) &&
3129           (a->rd != a->rs2 && a->rd != a->rs1) &&
3130           !is_overlapped(a->rd, 1 << MAX(s->lmul, 0),
3131                          a->rs1, 1 << MAX(emul, 0)) &&
3132           !is_overlapped(a->rd, 1 << MAX(s->lmul, 0),
3133                          a->rs2, 1 << MAX(s->lmul, 0)) &&
3134           require_vm(a->vm, a->rd);
3135}
3136
3137GEN_OPIVV_TRANS(vrgather_vv, vrgather_vv_check)
3138GEN_OPIVV_TRANS(vrgatherei16_vv, vrgatherei16_vv_check)
3139
3140static bool vrgather_vx_check(DisasContext *s, arg_rmrr *a)
3141{
3142    return require_rvv(s) &&
3143           vext_check_isa_ill(s) &&
3144           require_align(a->rd, s->lmul) &&
3145           require_align(a->rs2, s->lmul) &&
3146           (a->rd != a->rs2) &&
3147           require_vm(a->vm, a->rd);
3148}
3149
3150/* vrgather.vx vd, vs2, rs1, vm # vd[i] = (x[rs1] >= VLMAX) ? 0 : vs2[rs1] */
3151static bool trans_vrgather_vx(DisasContext *s, arg_rmrr *a)
3152{
3153    if (!vrgather_vx_check(s, a)) {
3154        return false;
3155    }
3156
3157    if (a->vm && s->vl_eq_vlmax) {
3158        int scale = s->lmul - (s->sew + 3);
3159        int vlmax = scale < 0 ? s->vlen >> -scale : s->vlen << scale;
3160        TCGv_i64 dest = tcg_temp_new_i64();
3161
3162        if (a->rs1 == 0) {
3163            vec_element_loadi(s, dest, a->rs2, 0, false);
3164        } else {
3165            vec_element_loadx(s, dest, a->rs2, cpu_gpr[a->rs1], vlmax);
3166        }
3167
3168        tcg_gen_gvec_dup_i64(s->sew, vreg_ofs(s, a->rd),
3169                             MAXSZ(s), MAXSZ(s), dest);
3170        tcg_temp_free_i64(dest);
3171        mark_vs_dirty(s);
3172    } else {
3173        static gen_helper_opivx * const fns[4] = {
3174            gen_helper_vrgather_vx_b, gen_helper_vrgather_vx_h,
3175            gen_helper_vrgather_vx_w, gen_helper_vrgather_vx_d
3176        };
3177        return opivx_trans(a->rd, a->rs1, a->rs2, a->vm, fns[s->sew], s);
3178    }
3179    return true;
3180}
3181
3182/* vrgather.vi vd, vs2, imm, vm # vd[i] = (imm >= VLMAX) ? 0 : vs2[imm] */
3183static bool trans_vrgather_vi(DisasContext *s, arg_rmrr *a)
3184{
3185    if (!vrgather_vx_check(s, a)) {
3186        return false;
3187    }
3188
3189    if (a->vm && s->vl_eq_vlmax) {
3190        int scale = s->lmul - (s->sew + 3);
3191        int vlmax = scale < 0 ? s->vlen >> -scale : s->vlen << scale;
3192        if (a->rs1 >= vlmax) {
3193            tcg_gen_gvec_dup_imm(MO_64, vreg_ofs(s, a->rd),
3194                                 MAXSZ(s), MAXSZ(s), 0);
3195        } else {
3196            tcg_gen_gvec_dup_mem(s->sew, vreg_ofs(s, a->rd),
3197                                 endian_ofs(s, a->rs2, a->rs1),
3198                                 MAXSZ(s), MAXSZ(s));
3199        }
3200        mark_vs_dirty(s);
3201    } else {
3202        static gen_helper_opivx * const fns[4] = {
3203            gen_helper_vrgather_vx_b, gen_helper_vrgather_vx_h,
3204            gen_helper_vrgather_vx_w, gen_helper_vrgather_vx_d
3205        };
3206        return opivi_trans(a->rd, a->rs1, a->rs2, a->vm, fns[s->sew],
3207                           s, IMM_ZX);
3208    }
3209    return true;
3210}
3211
3212/*
3213 * Vector Compress Instruction
3214 *
3215 * The destination vector register group cannot overlap the
3216 * source vector register group or the source mask register.
3217 */
3218static bool vcompress_vm_check(DisasContext *s, arg_r *a)
3219{
3220    return require_rvv(s) &&
3221           vext_check_isa_ill(s) &&
3222           require_align(a->rd, s->lmul) &&
3223           require_align(a->rs2, s->lmul) &&
3224           (a->rd != a->rs2) &&
3225           !is_overlapped(a->rd, 1 << MAX(s->lmul, 0), a->rs1, 1);
3226}
3227
3228static bool trans_vcompress_vm(DisasContext *s, arg_r *a)
3229{
3230    if (vcompress_vm_check(s, a)) {
3231        uint32_t data = 0;
3232        static gen_helper_gvec_4_ptr * const fns[4] = {
3233            gen_helper_vcompress_vm_b, gen_helper_vcompress_vm_h,
3234            gen_helper_vcompress_vm_w, gen_helper_vcompress_vm_d,
3235        };
3236        TCGLabel *over = gen_new_label();
3237        tcg_gen_brcondi_tl(TCG_COND_EQ, cpu_vl, 0, over);
3238
3239        data = FIELD_DP32(data, VDATA, LMUL, s->lmul);
3240        tcg_gen_gvec_4_ptr(vreg_ofs(s, a->rd), vreg_ofs(s, 0),
3241                           vreg_ofs(s, a->rs1), vreg_ofs(s, a->rs2),
3242                           cpu_env, s->vlen / 8, s->vlen / 8, data,
3243                           fns[s->sew]);
3244        mark_vs_dirty(s);
3245        gen_set_label(over);
3246        return true;
3247    }
3248    return false;
3249}
3250