1 # SPDX-License-Identifier: LGPLv3+
2 # Copyright (C) 2021 Luke Kenneth Casson Leighton <lkcl@lkcl.net>
3 # Funded by NLnet http://nlnet.nl
5 """SVP64 OpenPOWER v3.0B assembly translator
7 This class takes raw svp64 assembly mnemonics (aliases excluded) and creates
8 an EXT001-encoded "svp64 prefix" (as a .long) followed by a v3.0B opcode.
10 It is very simple and straightforward, the only weirdness being the
11 extraction of the register information and conversion to v3.0B numbering.
13 Encoding format of svp64: https://libre-soc.org/openpower/sv/svp64/
14 Encoding format of arithmetic: https://libre-soc.org/openpower/sv/normal/
15 Encoding format of LDST: https://libre-soc.org/openpower/sv/ldst/
16 **TODO format of branches: https://libre-soc.org/openpower/sv/branches/**
17 **TODO format of CRs: https://libre-soc.org/openpower/sv/cr_ops/**
18 Bugtracker: https://bugs.libre-soc.org/show_bug.cgi?id=578
24 from collections
import OrderedDict
26 from openpower
.decoder
.isa
.caller
import (SVP64PrefixFields
, SV64P_MAJOR_SIZE
,
27 SV64P_PID_SIZE
, SVP64RMFields
,
28 SVP64RM_EXTRA2_SPEC_SIZE
,
29 SVP64RM_EXTRA3_SPEC_SIZE
,
37 from openpower
.decoder
.pseudo
.pagereader
import ISA
38 from openpower
.decoder
.power_svp64
import SVP64RM
, get_regtype
, decode_extra
39 from openpower
.decoder
.selectable_int
import SelectableInt
40 from openpower
.consts
import SVP64MODE
43 from openpower
.util
import log
46 def instruction(*fields
):
47 def instruction(insn
, desc
):
48 (value
, start
, end
) = desc
49 bits
= ((1,) * ((end
+ 1) - start
))
52 mask
= ((mask
<< 1) | bit
)
53 return (insn |
((value
& mask
) << (31 - end
)))
55 return functools
.reduce(instruction
, fields
, 0)
58 def setvl(fields
, Rc
):
60 setvl is a *32-bit-only* instruction. It controls SVSTATE.
61 It is *not* a 64-bit-prefixed Vector instruction (no sv.setvl, yet),
62 it is a Vector *control* instruction.
64 * setvl RT,RA,SVi,vf,vs,ms
66 1.6.28 SVL-FORM - from fields.txt
67 |0 |6 |11 |16 |23 |24 |25 |26 |31 |
68 | PO | RT | RA | SVi |ms |vs |vf | XO |Rc |
72 # ARRRGH these are in a non-obvious order in openpower/isa/simplev.mdwn
73 # compared to the SVL-Form above. sigh
74 # setvl RT,RA,SVi,vf,vs,ms
75 (RT
, RA
, SVi
, vf
, vs
, ms
) = fields
90 def svstep(fields
, Rc
):
92 svstep is a 32-bit instruction. It updates SVSTATE.
93 It *can* be SVP64-prefixed, to indicate that its registers
98 # 1.6.28 SVL-FORM - from fields.txt
99 # |0 |6 |11 |16 |23 |24 |25 |26 |31 |
100 # | PO | RT | / | SVi |/ |/ |vf | XO |Rc |
105 (RT
, SVi
, vf
) = fields
122 svshape is a *32-bit-only* instruction. It updates SVSHAPE and SVSTATE.
123 It is *not* a 64-bit-prefixed Vector instruction (no sv.svshape, yet),
124 it is a Vector *control* instruction.
126 * svshape SVxd,SVyd,SVzd,SVrm,vf
128 # 1.6.33 SVM-FORM from fields.txt
129 # |0 |6 |11 |16 |21 |25 |26 |31 |
130 # | PO | SVxd | SVyd | SVzd | SVrm |vf | XO |
135 (SVxd
, SVyd
, SVzd
, SVrm
, vf
) = fields
152 svindex is a *32-bit-only* instruction. It is a convenience
153 instruction that reduces instruction count for Indexed REMAP
155 It is *not* a 64-bit-prefixed Vector instruction (no sv.svindex, yet),
156 it is a Vector *control* instruction.
159 |0 |6 |11 |16 |21 |23|24|25|26 31|
160 | PO | RS |rmm | SVd |ew |yx|mm|sk| XO |
162 # note that the dimension field one subtracted
165 (RS
, rmm
, SVd
, ew
, yx
, mm
, sk
) = fields
182 this is a *32-bit-only* instruction. It updates the SVSHAPE SPR
183 it is *not* a 64-bit-prefixed Vector instruction (no sv.svremap),
184 it is a Vector *control* instruction.
186 * svremap SVme,mi0,mi1,mi2,mo0,mo1,pst
189 |0 |6 |11 |13 |15 |17 |19 |21 |22 |26 |31 |
190 | PO | SVme |mi0 | mi1 | mi2 | mo0 | mo1 |pst |/// | XO |
195 (SVme
, mi0
, mi1
, mi2
, mo0
, mo1
, pst
) = fields
210 # ok from here-on down these are added as 32-bit instructions
211 # and are here only because binutils (at present) doesn't have
212 # them (that's being fixed!)
213 # they can - if implementations then choose - be Vectorised
214 # because they are general-purpose scalar instructions
218 |0 |6 |11 |16 |21 |26 |27 31|
219 | PO | RT | RA | RB |bm |L | XO |
223 (RT
, RA
, RB
, bm
, L
) = fields
235 def fsins(fields
, Rc
):
236 # XXX WARNING THESE ARE NOT APPROVED BY OPF ISA WG
237 # however we are out of space with opcode 22
239 # |0 |6 |7|8|9 |10 |11|12|13 |15|16|17 |20|21 |31 |
240 # | PO | FRT | /// | FRB | XO |Rc |
254 def fcoss(fields
, Rc
):
255 # XXX WARNING THESE ARE NOT APPROVED BY OPF ISA WG
256 # however we are out of space with opcode 22
258 # |0 |6 |7|8|9 |10 |11|12|13 |15|16|17 |20|21 |31 |
259 # | PO | FRT | /// | FRB | XO |Rc |
273 def ternlogi(fields
, Rc
):
274 # XXX WARNING THESE ARE NOT APPROVED BY OPF ISA WG
275 # however we are out of space with opcode 22
277 # |0 |6 |11 |16 |21 |29 |31 |
278 # | PO | RT | RA | RB | TLI | XO |Rc |
281 (RT
, RA
, RB
, TLI
) = fields
293 def grev(fields
, Rc
, imm
, wide
):
294 # XXX WARNING THESE ARE NOT APPROVED BY OPF ISA WG
295 # however we are out of space with opcode 22
297 # _ matches fields in table at:
298 # https://libre-soc.org/openPOwer/sv/bitmanip/
304 (RT
, RA
, XBI
) = fields
305 insn
= (insn
<< 5) | RT
306 insn
= (insn
<< 5) | RA
309 insn
= (insn
<< 6) | XBI
310 insn
= (insn
<< 9) | XO
313 insn
= (insn
<< 5) | XBI
314 insn
= (insn
<< 10) | XO
315 insn
= (insn
<< 1) | Rc
319 def av(fields
, XO
, Rc
):
321 # |0 |6 |7|8|9 |10 |11|12|13 |15|16|17 |20|21 |31 |
322 # | PO | RT | RA | RB | XO |Rc |
324 (RT
, RA
, RB
) = fields
336 for (name
, hook
) in (
341 ("ternlogi", ternlogi
),
343 CUSTOM_INSNS
[name
] = functools
.partial(hook
, Rc
=False)
344 CUSTOM_INSNS
[f
"{name}."] = functools
.partial(hook
, Rc
=True)
345 CUSTOM_INSNS
["bmask"] = bmask
346 CUSTOM_INSNS
["svshape"] = svshape
347 CUSTOM_INSNS
["svindex"] = svindex
348 CUSTOM_INSNS
["svremap"] = svremap
350 for (name
, imm
, wide
) in (
351 ("grev", False, False),
352 ("grevi", True, False),
353 ("grevw", False, True),
354 ("grevwi", True, True),
356 CUSTOM_INSNS
[name
] = functools
.partial(grev
,
357 imm
=("i" in name
), wide
=("w" in name
), Rc
=False)
358 CUSTOM_INSNS
[f
"{name}."] = functools
.partial(grev
,
359 imm
=("i" in name
), wide
=("w" in name
), Rc
=True)
362 ("maxs" , 0b0111001110),
363 ("maxu" , 0b0011001110),
364 ("minu" , 0b0001001110),
365 ("mins" , 0b0101001110),
366 ("absdu" , 0b1011110110),
367 ("absds" , 0b1001110110),
368 ("avgadd" , 0b1101001110),
369 ("absdacu", 0b1111110110),
370 ("absdacs", 0b0111110110),
371 ("cprop" , 0b0110001110),
373 CUSTOM_INSNS
[name
] = functools
.partial(av
, XO
=XO
, Rc
=False)
374 CUSTOM_INSNS
[f
"{name}."] = functools
.partial(av
, XO
=XO
, Rc
=True)
377 # decode GPR into sv extra
378 def get_extra_gpr(etype
, regmode
, field
):
379 if regmode
== 'scalar':
380 # cut into 2-bits 5-bits SS FFFFF
381 sv_extra
= field
>> 5
382 field
= field
& 0b11111
384 # cut into 5-bits 2-bits FFFFF SS
385 sv_extra
= field
& 0b11
387 return sv_extra
, field
390 # decode 3-bit CR into sv extra
391 def get_extra_cr_3bit(etype
, regmode
, field
):
392 if regmode
== 'scalar':
393 # cut into 2-bits 3-bits SS FFF
394 sv_extra
= field
>> 3
395 field
= field
& 0b111
397 # cut into 3-bits 4-bits FFF SSSS but will cut 2 zeros off later
398 sv_extra
= field
& 0b1111
400 return sv_extra
, field
404 def decode_subvl(encoding
):
405 pmap
= {'2': 0b01, '3': 0b10, '4': 0b11}
406 assert encoding
in pmap
, \
407 "encoding %s for SUBVL not recognised" % encoding
408 return pmap
[encoding
]
412 def decode_elwidth(encoding
):
413 pmap
= {'8': 0b11, '16': 0b10, '32': 0b01}
414 assert encoding
in pmap
, \
415 "encoding %s for elwidth not recognised" % encoding
416 return pmap
[encoding
]
419 # decodes predicate register encoding
420 def decode_predicate(encoding
):
431 'nl': (1, 0b001), 'ge': (1, 0b001), # same value
433 'ng': (1, 0b011), 'le': (1, 0b011), # same value
436 'so': (1, 0b110), 'un': (1, 0b110), # same value
437 'ns': (1, 0b111), 'nu': (1, 0b111), # same value
439 assert encoding
in pmap
, \
440 "encoding %s for predicate not recognised" % encoding
441 return pmap
[encoding
]
444 # decodes "Mode" in similar way to BO field (supposed to, anyway)
445 def decode_bo(encoding
):
446 pmap
= { # TODO: double-check that these are the same as Branch BO
448 'nl': 0b001, 'ge': 0b001, # same value
450 'ng': 0b011, 'le': 0b011, # same value
453 'so': 0b110, 'un': 0b110, # same value
454 'ns': 0b111, 'nu': 0b111, # same value
456 assert encoding
in pmap
, \
457 "encoding %s for BO Mode not recognised" % encoding
458 return pmap
[encoding
]
460 # partial-decode fail-first mode
463 def decode_ffirst(encoding
):
464 if encoding
in ['RC1', '~RC1']:
466 return decode_bo(encoding
)
469 def decode_reg(field
):
470 # decode the field number. "5.v" or "3.s" or "9"
471 # and now also "*0", and "*%0". note: *NOT* to add "*%rNNN" etc.
472 # https://bugs.libre-soc.org/show_bug.cgi?id=884#c0
473 if field
.startswith("*%"):
474 return "vector", int(field
[2:]) # actual register number
475 if field
.startswith("*"):
476 return "vector", int(field
[1:]) # actual register number
477 # try old convention (to be retired)
478 field
= field
.split(".")
479 regmode
= 'scalar' # default
483 elif field
[1] == 'v':
485 field
= int(field
[0]) # actual register number
486 return field
, regmode
489 def decode_imm(field
):
490 ldst_imm
= "(" in field
and field
[-1] == ')'
492 return field
[:-1].split("(")
497 def crf_extra(etype
, regmode
, field
, extras
):
498 """takes a CR Field number (CR0-CR127), splits into EXTRA2/3 and v3.0
499 the scalar/vector mode (crNN.v or crNN.s) changes both the format
500 of the EXTRA2/3 encoding as well as what range of registers is possible.
501 this function can be used for both BF/BFA and BA/BB/BT by first removing
502 the bottom 2 bits of BA/BB/BT then re-instating them after encoding.
503 see https://libre-soc.org/openpower/sv/svp64/appendix/#cr_extra
506 sv_extra
, field
= get_extra_cr_3bit(etype
, regmode
, field
)
507 # now sanity-check (and shrink afterwards)
508 if etype
== 'EXTRA2':
509 # 3-bit CR Field (BF, BFA) EXTRA2 encoding
510 if regmode
== 'scalar':
511 # range is CR0-CR15 in increments of 1
512 assert (sv_extra
>> 1) == 0, \
513 "scalar CR %s cannot fit into EXTRA2 %s" % \
514 (rname
, str(extras
[extra_idx
]))
515 # all good: encode as scalar
516 sv_extra
= sv_extra
& 0b01
518 # range is CR0-CR127 in increments of 16
519 assert sv_extra
& 0b111 == 0, \
520 "vector CR %s cannot fit into EXTRA2 %s" % \
521 (rname
, str(extras
[extra_idx
]))
522 # all good: encode as vector (bit 2 set)
523 sv_extra
= 0b10 |
(sv_extra
>> 3)
525 # 3-bit CR Field (BF, BFA) EXTRA3 encoding
526 if regmode
== 'scalar':
527 # range is CR0-CR31 in increments of 1
528 assert (sv_extra
>> 2) == 0, \
529 "scalar CR %s cannot fit into EXTRA3 %s" % \
530 (rname
, str(extras
[extra_idx
]))
531 # all good: encode as scalar
532 sv_extra
= sv_extra
& 0b11
534 # range is CR0-CR127 in increments of 8
535 assert sv_extra
& 0b11 == 0, \
536 "vector CR %s cannot fit into EXTRA3 %s" % \
537 (rname
, str(extras
[extra_idx
]))
538 # all good: encode as vector (bit 3 set)
539 sv_extra
= 0b100 |
(sv_extra
>> 2)
540 return sv_extra
, field
543 # decodes svp64 assembly listings and creates EXT001 svp64 prefixes
545 def __init__(self
, lst
, bigendian
=False, macros
=None):
550 self
.trans
= self
.translate(lst
)
551 self
.isa
= ISA() # reads the v3.0B pseudo-code markdown files
552 self
.svp64
= SVP64RM() # reads the svp64 Remap entries for registers
553 assert bigendian
== False, "error, bigendian not supported yet"
556 yield from self
.trans
558 def translate_one(self
, insn
, macros
=None):
561 macros
.update(self
.macros
)
564 # find first space, to get opcode
567 # now find opcode fields
568 fields
= ''.join(ls
[1:]).split(',')
569 mfields
= list(map(str.strip
, fields
))
570 log("opcode, fields", ls
, opcode
, mfields
)
573 for field
in mfields
:
574 fields
.append(macro_subst(macros
, field
))
575 log("opcode, fields substed", ls
, opcode
, fields
)
577 # identify if it is a special instruction
578 custom_insn_hook
= CUSTOM_INSNS
.get(opcode
)
579 if custom_insn_hook
is not None:
580 fields
= tuple(map(int, fields
))
581 insn
= custom_insn_hook(fields
)
582 log(opcode
, bin(insn
))
583 yield ".long 0x%x" % insn
586 # identify if is a svp64 mnemonic
587 if not opcode
.startswith('sv.'):
588 yield insn
# unaltered
590 opcode
= opcode
[3:] # strip leading "sv"
592 # start working on decoding the svp64 op: sv.basev30Bop/vec2/mode
593 opmodes
= opcode
.split("/") # split at "/"
594 v30b_op
= opmodes
.pop(0) # first is the v3.0B
595 # check instruction ends with dot
596 rc_mode
= v30b_op
.endswith('.')
598 v30b_op
= v30b_op
[:-1]
600 # sigh again, have to recognised LD/ST bit-reverse instructions
601 # this has to be "processed" to fit into a v3.0B without the "sh"
602 # e.g. ldsh is actually ld
603 ldst_shift
= v30b_op
.startswith("l") and v30b_op
.endswith("sh")
605 if v30b_op
not in isa
.instr
:
606 raise Exception("opcode %s of '%s' not supported" %
610 # okaay we need to process the fields and make this:
611 # ldsh RT, SVD(RA), RC - 11 bits for SVD, 5 for RC
613 # ld RT, D(RA) - 16 bits
614 # likewise same for SVDS (9 bits for SVDS, 5 for RC, 14 bits for DS)
615 form
= isa
.instr
[v30b_op
].form
# get form (SVD-Form, SVDS-Form)
619 # identify if this is a ld/st immediate(reg) thing
620 ldst_imm
= "(" in field
and field
[-1] == ')'
622 newfields
.append(field
[:-1].split("("))
624 newfields
.append(field
)
626 immed
, RA
= newfields
[1]
628 RC
= int(newfields
.pop(2)) # better be an integer number!
629 if form
== 'SVD': # 16 bit: immed 11 bits, RC shift up 11
630 immed
= (immed
& 0b11111111111) |
(RC
<< 11)
631 if immed
& (1 << 15): # should be negative
633 if form
== 'SVDS': # 14 bit: immed 9 bits, RC shift up 9
634 immed
= (immed
& 0b111111111) |
(RC
<< 9)
635 if immed
& (1 << 13): # should be negative
637 newfields
[1] = "%d(%s)" % (immed
, RA
)
640 # and strip off "sh" from end, and add "sh" to opmodes, instead
641 v30b_op
= v30b_op
[:-2]
643 log("rewritten", v30b_op
, opmodes
, fields
)
645 if v30b_op
not in svp64
.instrs
:
646 raise Exception("opcode %s of '%s' not an svp64 instruction" %
648 v30b_regs
= isa
.instr
[v30b_op
].regs
[0] # get regs info "RT, RA, RB"
649 rm
= svp64
.instrs
[v30b_op
] # one row of the svp64 RM CSV
650 log("v3.0B op", v30b_op
, "Rc=1" if rc_mode
else '')
651 log("v3.0B regs", opcode
, v30b_regs
)
654 # right. the first thing to do is identify the ordering of
655 # the registers, by name. the EXTRA2/3 ordering is in
656 # rm['0']..rm['3'] but those fields contain the names RA, BB
657 # etc. we have to read the pseudocode to understand which
658 # reg is which in our instruction. sigh.
660 # first turn the svp64 rm into a "by name" dict, recording
661 # which position in the RM EXTRA it goes into
662 # also: record if the src or dest was a CR, for sanity-checking
663 # (elwidth overrides on CRs are banned)
664 decode
= decode_extra(rm
)
665 dest_reg_cr
, src_reg_cr
, svp64_src
, svp64_dest
= decode
667 log("EXTRA field index, src", svp64_src
)
668 log("EXTRA field index, dest", svp64_dest
)
670 # okaaay now we identify the field value (opcode N,N,N) with
671 # the pseudo-code info (opcode RT, RA, RB)
672 assert len(fields
) == len(v30b_regs
), \
673 "length of fields %s must match insn `%s` fields %s" % \
674 (str(v30b_regs
), insn
, str(fields
))
675 opregfields
= zip(fields
, v30b_regs
) # err that was easy
677 # now for each of those find its place in the EXTRA encoding
678 # note there is the possibility (for LD/ST-with-update) of
679 # RA occurring **TWICE**. to avoid it getting added to the
680 # v3.0B suffix twice, we spot it as a duplicate, here
681 extras
= OrderedDict()
682 for idx
, (field
, regname
) in enumerate(opregfields
):
683 imm
, regname
= decode_imm(regname
)
684 rtype
= get_regtype(regname
)
685 log(" idx find", rtype
, idx
, field
, regname
, imm
)
687 # probably an immediate field, append it straight
688 extras
[('imm', idx
, False)] = (idx
, field
, None, None, None)
690 extra
= svp64_src
.get(regname
, None)
691 if extra
is not None:
692 extra
= ('s', extra
, False) # not a duplicate
693 extras
[extra
] = (idx
, field
, regname
, rtype
, imm
)
694 log(" idx src", idx
, extra
, extras
[extra
])
695 dextra
= svp64_dest
.get(regname
, None)
696 log("regname in", regname
, dextra
)
697 if dextra
is not None:
698 is_a_duplicate
= extra
is not None # duplicate spotted
699 dextra
= ('d', dextra
, is_a_duplicate
)
700 extras
[dextra
] = (idx
, field
, regname
, rtype
, imm
)
701 log(" idx dst", idx
, extra
, extras
[dextra
])
703 # great! got the extra fields in their associated positions:
704 # also we know the register type. now to create the EXTRA encodings
705 etype
= rm
['Etype'] # Extra type: EXTRA3/EXTRA2
706 ptype
= rm
['Ptype'] # Predication type: Twin / Single
709 for extra_idx
, (idx
, field
, rname
, rtype
, iname
) in extras
.items():
710 # is it a field we don't alter/examine? if so just put it
713 v30b_newfields
.append(field
)
716 # identify if this is a ld/st immediate(reg) thing
717 ldst_imm
= "(" in field
and field
[-1] == ')'
719 immed
, field
= field
[:-1].split("(")
721 field
, regmode
= decode_reg(field
)
722 log(" ", extra_idx
, rname
, rtype
,
723 regmode
, iname
, field
, end
=" ")
725 # see Mode field https://libre-soc.org/openpower/sv/svp64/
726 # XXX TODO: the following is a bit of a laborious repeated
727 # mess, which could (and should) easily be parameterised.
728 # XXX also TODO: the LD/ST modes which are different
729 # https://libre-soc.org/openpower/sv/ldst/
731 # rright. SVP64 register numbering is from 0 to 127
732 # for GPRs, FPRs *and* CR Fields, where for v3.0 the GPRs and RPFs
733 # are 0-31 and CR Fields are only 0-7. the SVP64 RM "Extra"
734 # area is used to extend the numbering from the 32-bit
735 # instruction, and also to record whether the register
736 # is scalar or vector. on a per-operand basis. this
737 # results in a slightly finnicky encoding: here we go...
739 # encode SV-GPR and SV-FPR field into extra, v3.0field
740 if rtype
in ['GPR', 'FPR']:
741 sv_extra
, field
= get_extra_gpr(etype
, regmode
, field
)
742 # now sanity-check. EXTRA3 is ok, EXTRA2 has limits
743 # (and shrink to a single bit if ok)
744 if etype
== 'EXTRA2':
745 if regmode
== 'scalar':
746 # range is r0-r63 in increments of 1
747 assert (sv_extra
>> 1) == 0, \
748 "scalar GPR %s cannot fit into EXTRA2 %s" % \
749 (rname
, str(extras
[extra_idx
]))
750 # all good: encode as scalar
751 sv_extra
= sv_extra
& 0b01
753 # range is r0-r127 in increments of 2 (r0 r2 ... r126)
754 assert sv_extra
& 0b01 == 0, \
755 "%s: vector field %s cannot fit " \
757 (insn
, rname
, str(extras
[extra_idx
]))
758 # all good: encode as vector (bit 2 set)
759 sv_extra
= 0b10 |
(sv_extra
>> 1)
760 elif regmode
== 'vector':
761 # EXTRA3 vector bit needs marking
764 # encode SV-CR 3-bit field into extra, v3.0field.
765 # 3-bit is for things like BF and BFA
766 elif rtype
== 'CR_3bit':
767 sv_extra
, field
= crf_extra(etype
, regmode
, field
, extras
)
769 # encode SV-CR 5-bit field into extra, v3.0field
770 # 5-bit is for things like BA BB BC BT etc.
771 # *sigh* this is the same as 3-bit except the 2 LSBs of the
772 # 5-bit field are passed through unaltered.
773 elif rtype
== 'CR_5bit':
774 cr_subfield
= field
& 0b11 # record bottom 2 bits for later
775 field
= field
>> 2 # strip bottom 2 bits
776 # use the exact same 3-bit function for the top 3 bits
777 sv_extra
, field
= crf_extra(etype
, regmode
, field
, extras
)
778 # reconstruct the actual 5-bit CR field (preserving the
779 # bottom 2 bits, unaltered)
780 field
= (field
<< 2) | cr_subfield
783 raise Exception("no type match: %s" % rtype
)
785 # capture the extra field info
786 log("=>", "%5s" % bin(sv_extra
), field
)
787 extras
[extra_idx
] = sv_extra
789 # append altered field value to v3.0b, differs for LDST
790 # note that duplicates are skipped e.g. EXTRA2 contains
791 # *BOTH* s:RA *AND* d:RA which happens on LD/ST-with-update
792 srcdest
, idx
, duplicate
= extra_idx
793 if duplicate
: # skip adding to v3.0b fields, already added
796 v30b_newfields
.append(("%s(%s)" % (immed
, str(field
))))
798 v30b_newfields
.append(str(field
))
800 log("new v3.0B fields", v30b_op
, v30b_newfields
)
801 log("extras", extras
)
803 # rright. now we have all the info. start creating SVP64 RM
804 svp64_rm
= SVP64RMFields()
806 # begin with EXTRA fields
807 for idx
, sv_extra
in extras
.items():
813 srcdest
, idx
, duplicate
= idx
814 if etype
== 'EXTRA2':
815 svp64_rm
.extra2
[idx
].eq(
816 SelectableInt(sv_extra
, SVP64RM_EXTRA2_SPEC_SIZE
))
818 svp64_rm
.extra3
[idx
].eq(
819 SelectableInt(sv_extra
, SVP64RM_EXTRA3_SPEC_SIZE
))
821 # identify if the op is a LD/ST. the "blegh" way. copied
822 # from power_enums. TODO, split the list _insns down.
824 "lbarx", "lbz", "lbzu", "lbzux", "lbzx", # load byte
825 "ld", "ldarx", "ldbrx", "ldu", "ldux", "ldx", # load double
826 "lfs", "lfsx", "lfsu", "lfsux", # FP load single
827 "lfd", "lfdx", "lfdu", "lfdux", "lfiwzx", "lfiwax", # FP load dbl
828 "lha", "lharx", "lhau", "lhaux", "lhax", # load half
829 "lhbrx", "lhz", "lhzu", "lhzux", "lhzx", # more load half
830 "lwa", "lwarx", "lwaux", "lwax", "lwbrx", # load word
831 "lwz", "lwzcix", "lwzu", "lwzux", "lwzx", # more load word
834 "stb", "stbcix", "stbcx", "stbu", "stbux", "stbx",
835 "std", "stdbrx", "stdcx", "stdu", "stdux", "stdx",
836 "stfs", "stfsx", "stfsu", "stfux", # FP store sgl
837 "stfd", "stfdx", "stfdu", "stfdux", "stfiwx", # FP store dbl
838 "sth", "sthbrx", "sthcx", "sthu", "sthux", "sthx",
839 "stw", "stwbrx", "stwcx", "stwu", "stwux", "stwx",
841 # use this to determine if the SVP64 RM format is different.
842 # see https://libre-soc.org/openpower/sv/ldst/
843 is_ldst
= is_ld
or is_st
845 # branch-conditional detection
853 destwid
= 0 # bits 4-5
854 srcwid
= 0 # bits 6-7
856 smask
= 0 # bits 16-18 but only for twin-predication
857 mode
= 0 # bits 19-23
859 mask_m_specified
= False
870 mapreduce_crm
= False
871 mapreduce_svm
= False
877 # branch-conditional bits
887 # ok let's start identifying opcode augmentation fields
888 for encmode
in opmodes
:
889 # predicate mask (src and dest)
890 if encmode
.startswith("m="):
892 pmmode
, pmask
= decode_predicate(encmode
[2:])
893 smmode
, smask
= pmmode
, pmask
895 mask_m_specified
= True
896 # predicate mask (dest)
897 elif encmode
.startswith("dm="):
899 pmmode
, pmask
= decode_predicate(encmode
[3:])
902 # predicate mask (src, twin-pred)
903 elif encmode
.startswith("sm="):
905 smmode
, smask
= decode_predicate(encmode
[3:])
909 elif encmode
.startswith("sh"):
912 elif encmode
.startswith("vec"):
913 subvl
= decode_subvl(encmode
[3:])
915 elif encmode
.startswith("ew="):
916 destwid
= decode_elwidth(encmode
[3:])
917 elif encmode
.startswith("sw="):
918 srcwid
= decode_elwidth(encmode
[3:])
919 # element-strided LD/ST
920 elif encmode
== 'els':
923 elif encmode
== 'sats':
924 assert sv_mode
is None
927 elif encmode
== 'satu':
928 assert sv_mode
is None
932 elif encmode
== 'sz':
934 elif encmode
== 'dz':
937 elif encmode
.startswith("ff="):
938 assert sv_mode
is None
940 failfirst
= decode_ffirst(encmode
[3:])
941 # predicate-result, interestingly same as fail-first
942 elif encmode
.startswith("pr="):
943 assert sv_mode
is None
945 predresult
= decode_ffirst(encmode
[3:])
946 # map-reduce mode, reverse-gear
947 elif encmode
== 'mrr':
948 assert sv_mode
is None
953 elif encmode
== 'mr':
954 assert sv_mode
is None
957 elif encmode
== 'crm': # CR on map-reduce
958 assert sv_mode
is None
961 elif encmode
== 'svm': # sub-vector mode
966 elif encmode
== 'st': # svstep mode
968 elif encmode
== 'sr': # svstep BRc mode
971 elif encmode
== 'vs': # VLSET mode
973 elif encmode
== 'vsi': # VLSET mode with VLI (VL inclusives)
976 elif encmode
== 'vsb': # VLSET mode with VSb
979 elif encmode
== 'vsbi': # VLSET mode with VLI and VSb
983 elif encmode
== 'snz': # sz (only) already set above
986 elif encmode
== 'lu': # LR update mode
989 raise AssertionError("unknown encmode %s" % encmode
)
991 raise AssertionError("unknown encmode %s" % encmode
)
994 # since m=xx takes precedence (overrides) sm=xx and dm=xx,
995 # treat them as mutually exclusive
997 assert not has_smask
,\
998 "cannot have both source-mask and predicate mask"
999 assert not has_pmask
,\
1000 "cannot have both dest-mask and predicate mask"
1001 # since the default is INT predication (ALWAYS), if you
1002 # specify one CR mask, you must specify both, to avoid
1003 # mixing INT and CR reg types
1004 if has_pmask
and pmmode
== 1:
1006 "need explicit source-mask in CR twin predication"
1007 if has_smask
and smmode
== 1:
1009 "need explicit dest-mask in CR twin predication"
1010 # sanity-check that 2Pred mask is same mode
1011 if has_pmask
and has_smask
:
1012 assert smmode
== pmmode
, \
1013 "predicate masks %s and %s must be same reg type" % \
1016 # sanity-check that twin-predication mask only specified in 2P mode
1018 assert not has_smask
, \
1019 "source-mask can only be specified on Twin-predicate ops"
1020 assert not has_pmask
, \
1021 "dest-mask can only be specified on Twin-predicate ops"
1023 # construct the mode field, doing sanity-checking along the way
1025 assert sv_mode
== 0b00, "sub-vector mode in mapreduce only"
1026 assert subvl
!= 0, "sub-vector mode not possible on SUBVL=1"
1029 assert has_smask
or mask_m_specified
, \
1030 "src zeroing requires a source predicate"
1032 assert has_pmask
or mask_m_specified
, \
1033 "dest zeroing requires a dest predicate"
1035 # check LDST shifted, only available in "normal" mode
1036 if is_ldst
and ldst_shift
:
1037 assert sv_mode
is None, \
1038 "LD shift cannot have modes (%s) applied" % sv_mode
1040 # okaaay, so there are 4 different modes, here, which will be
1041 # partly-merged-in: is_ldst is merged in with "normal", but
1042 # is_bc is so different it's done separately. likewise is_cr
1043 # (when it is done). here are the maps:
1045 # for "normal" arithmetic: https://libre-soc.org/openpower/sv/normal/
1047 | 0-1 | 2 | 3 4 | description |
1048 | --- | --- |---------|-------------------------- |
1049 | 00 | 0 | dz sz | normal mode |
1050 | 00 | 1 | 0 RG | scalar reduce mode (mapreduce), SUBVL=1 |
1051 | 00 | 1 | 1 / | parallel reduce mode (mapreduce), SUBVL=1 |
1052 | 00 | 1 | SVM RG | subvector reduce mode, SUBVL>1 |
1053 | 01 | inv | CR-bit | Rc=1: ffirst CR sel |
1054 | 01 | inv | VLi RC1 | Rc=0: ffirst z/nonz |
1055 | 10 | N | dz sz | sat mode: N=0/1 u/s |
1056 | 11 | inv | CR-bit | Rc=1: pred-result CR sel |
1057 | 11 | inv | dz RC1 | Rc=0: pred-result z/nonz |
1060 # https://libre-soc.org/openpower/sv/ldst/
1061 # for LD/ST-immediate:
1063 | 0-1 | 2 | 3 4 | description |
1064 | --- | --- |---------|--------------------------- |
1065 | 00 | 0 | dz els | normal mode |
1066 | 00 | 1 | dz shf | shift mode |
1067 | 01 | inv | CR-bit | Rc=1: ffirst CR sel |
1068 | 01 | inv | els RC1 | Rc=0: ffirst z/nonz |
1069 | 10 | N | dz els | sat mode: N=0/1 u/s |
1070 | 11 | inv | CR-bit | Rc=1: pred-result CR sel |
1071 | 11 | inv | els RC1 | Rc=0: pred-result z/nonz |
1074 # for LD/ST-indexed (RA+RB):
1076 | 0-1 | 2 | 3 4 | description |
1077 | --- | --- |---------|-------------------------- |
1078 | 00 | SEA | dz sz | normal mode |
1079 | 01 | SEA | dz sz | Strided (scalar only source) |
1080 | 10 | N | dz sz | sat mode: N=0/1 u/s |
1081 | 11 | inv | CR-bit | Rc=1: pred-result CR sel |
1082 | 11 | inv | dz RC1 | Rc=0: pred-result z/nonz |
1085 # and leaving out branches and cr_ops for now because they're
1087 """ TODO branches and cr_ops
1090 # now create mode and (overridden) src/dst widths
1091 # XXX TODO: sanity-check bc modes
1093 sv_mode
= ((bc_svstep
<< SVP64MODE
.MOD2_MSB
) |
1094 (bc_vlset
<< SVP64MODE
.MOD2_LSB
) |
1095 (bc_snz
<< SVP64MODE
.BC_SNZ
))
1096 srcwid
= (bc_vsb
<< 1) | bc_lru
1097 destwid
= (bc_lru
<< 1) | bc_all
1101 ######################################
1104 mode |
= src_zero
<< SVP64MODE
.SZ
# predicate zeroing
1105 mode |
= dst_zero
<< SVP64MODE
.DZ
# predicate zeroing
1107 # TODO: for now, LD/ST-indexed is ignored.
1108 mode |
= ldst_elstride
<< SVP64MODE
.ELS_NORMAL
# el-strided
1111 mode |
= 1 << SVP64MODE
.LDST_SHIFT
1113 # TODO, reduce and subvector mode
1114 # 00 1 dz CRM reduce mode (mapreduce), SUBVL=1
1115 # 00 1 SVM CRM subvector reduce mode, SUBVL>1
1119 ######################################
1121 elif sv_mode
== 0b00:
1122 mode |
= (0b1 << SVP64MODE
.REDUCE
) # sets mapreduce
1123 assert dst_zero
== 0, "dest-zero not allowed in mapreduce mode"
1125 mode |
= (0b1 << SVP64MODE
.RG
) # sets Reverse-gear mode
1127 mode |
= (0b1 << SVP64MODE
.CRM
) # sets CRM mode
1128 assert rc_mode
, "CRM only allowed when Rc=1"
1129 # bit of weird encoding to jam zero-pred or SVM mode in.
1130 # SVM mode can be enabled only when SUBVL=2/3/4 (vec2/3/4)
1132 mode |
= dst_zero
<< SVP64MODE
.DZ
# predicate zeroing
1134 mode |
= (0b1 << SVP64MODE
.SVM
) # sets SVM mode
1136 ######################################
1138 elif sv_mode
== 0b01:
1139 assert src_zero
== 0, "dest-zero not allowed in failfirst mode"
1140 if failfirst
== 'RC1':
1141 mode |
= (0b1 << SVP64MODE
.RC1
) # sets RC1 mode
1142 mode |
= (dst_zero
<< SVP64MODE
.DZ
) # predicate dst-zeroing
1143 assert rc_mode
== False, "ffirst RC1 only ok when Rc=0"
1144 elif failfirst
== '~RC1':
1145 mode |
= (0b1 << SVP64MODE
.RC1
) # sets RC1 mode
1146 mode |
= (dst_zero
<< SVP64MODE
.DZ
) # predicate dst-zeroing
1147 mode |
= (0b1 << SVP64MODE
.INV
) # ... with inversion
1148 assert rc_mode
== False, "ffirst RC1 only ok when Rc=0"
1150 assert dst_zero
== 0, "dst-zero not allowed in ffirst BO"
1151 assert rc_mode
, "ffirst BO only possible when Rc=1"
1152 mode |
= (failfirst
<< SVP64MODE
.BO_LSB
) # set BO
1154 ######################################
1155 # "saturation" modes
1156 elif sv_mode
== 0b10:
1157 mode |
= src_zero
<< SVP64MODE
.SZ
# predicate zeroing
1158 mode |
= dst_zero
<< SVP64MODE
.DZ
# predicate zeroing
1159 mode |
= (saturation
<< SVP64MODE
.N
) # signed/us saturation
1161 ######################################
1162 # "predicate-result" modes. err... code-duplication from ffirst
1163 elif sv_mode
== 0b11:
1164 assert src_zero
== 0, "dest-zero not allowed in predresult mode"
1165 if predresult
== 'RC1':
1166 mode |
= (0b1 << SVP64MODE
.RC1
) # sets RC1 mode
1167 mode |
= (dst_zero
<< SVP64MODE
.DZ
) # predicate dst-zeroing
1168 assert rc_mode
== False, "pr-mode RC1 only ok when Rc=0"
1169 elif predresult
== '~RC1':
1170 mode |
= (0b1 << SVP64MODE
.RC1
) # sets RC1 mode
1171 mode |
= (dst_zero
<< SVP64MODE
.DZ
) # predicate dst-zeroing
1172 mode |
= (0b1 << SVP64MODE
.INV
) # ... with inversion
1173 assert rc_mode
== False, "pr-mode RC1 only ok when Rc=0"
1175 assert dst_zero
== 0, "dst-zero not allowed in pr-mode BO"
1176 assert rc_mode
, "pr-mode BO only possible when Rc=1"
1177 mode |
= (predresult
<< SVP64MODE
.BO_LSB
) # set BO
1179 # whewww.... modes all done :)
1180 # now put into svp64_rm
1183 svp64_rm
.mode
.eq(SelectableInt(mode
, SVP64RM_MODE_SIZE
))
1185 # put in predicate masks into svp64_rm
1187 # source pred: bits 16-18
1188 svp64_rm
.smask
.eq(SelectableInt(smask
, SVP64RM_SMASK_SIZE
))
1190 svp64_rm
.mmode
.eq(SelectableInt(mmode
, SVP64RM_MMODE_SIZE
))
1192 svp64_rm
.mask
.eq(SelectableInt(pmask
, SVP64RM_MASK_SIZE
))
1194 # and subvl: bits 8-9
1195 svp64_rm
.subvl
.eq(SelectableInt(subvl
, SVP64RM_SUBVL_SIZE
))
1199 svp64_rm
.ewsrc
.eq(SelectableInt(srcwid
, SVP64RM_EWSRC_SIZE
))
1201 svp64_rm
.elwidth
.eq(SelectableInt(destwid
, SVP64RM_ELWIDTH_SIZE
))
1203 # nice debug printout. (and now for something completely different)
1204 # https://youtu.be/u0WOIwlXE9g?t=146
1205 svp64_rm_value
= svp64_rm
.spr
.value
1206 log("svp64_rm", hex(svp64_rm_value
), bin(svp64_rm_value
))
1207 log(" mmode 0 :", bin(mmode
))
1208 log(" pmask 1-3 :", bin(pmask
))
1209 log(" dstwid 4-5 :", bin(destwid
))
1210 log(" srcwid 6-7 :", bin(srcwid
))
1211 log(" subvl 8-9 :", bin(subvl
))
1212 log(" mode 19-23:", bin(mode
))
1213 offs
= 2 if etype
== 'EXTRA2' else 3 # 2 or 3 bits
1214 for idx
, sv_extra
in extras
.items():
1219 srcdest
, idx
, duplicate
= idx
1220 start
= (10+idx
*offs
)
1221 end
= start
+ offs
-1
1222 log(" extra%d %2d-%2d:" % (idx
, start
, end
),
1225 log(" smask 16-17:", bin(smask
))
1228 # first, construct the prefix from its subfields
1229 svp64_prefix
= SVP64PrefixFields()
1230 svp64_prefix
.major
.eq(SelectableInt(0x1, SV64P_MAJOR_SIZE
))
1231 svp64_prefix
.pid
.eq(SelectableInt(0b11, SV64P_PID_SIZE
))
1232 svp64_prefix
.rm
.eq(svp64_rm
.spr
)
1234 # fiinally yield the svp64 prefix and the thingy. v3.0b opcode
1235 rc
= '.' if rc_mode
else ''
1236 yield ".long 0x%08x" % svp64_prefix
.insn
.value
1237 log(v30b_op
, v30b_newfields
)
1238 # argh, sv.fmadds etc. need to be done manually
1239 if v30b_op
== 'ffmadds':
1240 opcode
= 59 << (32-6) # bits 0..6 (MSB0)
1241 opcode |
= int(v30b_newfields
[0]) << (32-11) # FRT
1242 opcode |
= int(v30b_newfields
[1]) << (32-16) # FRA
1243 opcode |
= int(v30b_newfields
[2]) << (32-21) # FRB
1244 opcode |
= int(v30b_newfields
[3]) << (32-26) # FRC
1245 opcode |
= 0b00101 << (32-31) # bits 26-30
1247 opcode |
= 1 # Rc, bit 31.
1248 yield ".long 0x%x" % opcode
1249 # argh, sv.fdmadds need to be done manually
1250 elif v30b_op
== 'fdmadds':
1251 opcode
= 59 << (32-6) # bits 0..6 (MSB0)
1252 opcode |
= int(v30b_newfields
[0]) << (32-11) # FRT
1253 opcode |
= int(v30b_newfields
[1]) << (32-16) # FRA
1254 opcode |
= int(v30b_newfields
[2]) << (32-21) # FRB
1255 opcode |
= int(v30b_newfields
[3]) << (32-26) # FRC
1256 opcode |
= 0b01111 << (32-31) # bits 26-30
1258 opcode |
= 1 # Rc, bit 31.
1259 yield ".long 0x%x" % opcode
1260 # argh, sv.ffadds etc. need to be done manually
1261 elif v30b_op
== 'ffadds':
1262 opcode
= 59 << (32-6) # bits 0..6 (MSB0)
1263 opcode |
= int(v30b_newfields
[0]) << (32-11) # FRT
1264 opcode |
= int(v30b_newfields
[1]) << (32-16) # FRA
1265 opcode |
= int(v30b_newfields
[2]) << (32-21) # FRB
1266 opcode |
= 0b01101 << (32-31) # bits 26-30
1268 opcode |
= 1 # Rc, bit 31.
1269 yield ".long 0x%x" % opcode
1270 # sigh have to do svstep here manually for now...
1271 elif v30b_op
in ["svstep", "svstep."]:
1272 insn
= 22 << (31-5) # opcode 22, bits 0-5
1273 insn |
= int(v30b_newfields
[0]) << (31-10) # RT , bits 6-10
1274 insn |
= int(v30b_newfields
[1]) << (31-22) # SVi , bits 16-22
1275 insn |
= int(v30b_newfields
[2]) << (31-25) # vf , bit 25
1276 insn |
= 0b10011 << (31-30) # XO , bits 26..30
1277 if opcode
== 'svstep.':
1278 insn |
= 1 << (31-31) # Rc=1 , bit 31
1279 log("svstep", bin(insn
))
1280 yield ".long 0x%x" % insn
1281 # argh, sv.fcoss etc. need to be done manually
1282 elif v30b_op
in ["fcoss", "fcoss."]:
1283 insn
= 59 << (31-5) # opcode 59, bits 0-5
1284 insn |
= int(v30b_newfields
[0]) << (31-10) # RT , bits 6-10
1285 insn |
= int(v30b_newfields
[1]) << (31-20) # RB , bits 16-20
1286 insn |
= 0b1000101110 << (31-30) # XO , bits 21..30
1287 if opcode
== 'fcoss.':
1288 insn |
= 1 << (31-31) # Rc=1 , bit 31
1289 log("fcoss", bin(insn
))
1290 yield ".long 0x%x" % insn
1293 yield "%s %s" % (v30b_op
+rc
, ", ".join(v30b_newfields
))
1294 log("new v3.0B fields", v30b_op
, v30b_newfields
)
1296 def translate(self
, lst
):
1298 yield from self
.translate_one(insn
)
1301 def macro_subst(macros
, txt
):
1303 log("subst", txt
, macros
)
1306 for macro
, value
in macros
.items():
1309 replaced
= txt
.replace(macro
, value
)
1310 log("macro", txt
, "replaced", replaced
, macro
, value
)
1313 toreplace
= '%s.s' % macro
1314 if toreplace
== txt
:
1316 replaced
= txt
.replace(toreplace
, "%s.s" % value
)
1317 log("macro", txt
, "replaced", replaced
, toreplace
, value
)
1320 toreplace
= '%s.v' % macro
1321 if toreplace
== txt
:
1323 replaced
= txt
.replace(toreplace
, "%s.v" % value
)
1324 log("macro", txt
, "replaced", replaced
, toreplace
, value
)
1327 toreplace
= '(%s)' % macro
1328 if toreplace
in txt
:
1330 replaced
= txt
.replace(toreplace
, '(%s)' % value
)
1331 log("macro", txt
, "replaced", replaced
, toreplace
, value
)
1334 log(" processed", txt
)
1342 if not line
[0].isspace():
1350 # get an input file and an output file
1354 outfile
= sys
.stdout
1355 # read the whole lot in advance in case of in-place
1356 lines
= list(infile
.readlines())
1357 elif len(args
) != 2:
1358 print("pysvp64asm [infile | -] [outfile | -]", file=sys
.stderr
)
1364 infile
= open(args
[0], "r")
1365 # read the whole lot in advance in case of in-place overwrite
1366 lines
= list(infile
.readlines())
1369 outfile
= sys
.stdout
1371 outfile
= open(args
[1], "w")
1373 # read the line, look for custom insn, process it
1374 macros
= {} # macros which start ".set"
1377 op
= line
.split("#")[0].strip()
1379 if op
.startswith(".set"):
1380 macro
= op
[4:].split(",")
1381 (macro
, value
) = map(str.strip
, macro
)
1382 macros
[macro
] = value
1383 if not op
.startswith('sv.') and not op
.startswith(tuple(CUSTOM_INSNS
)):
1387 (ws
, line
) = get_ws(line
)
1388 lst
= isa
.translate_one(op
, macros
)
1389 lst
= '; '.join(lst
)
1390 outfile
.write("%s%s # %s\n" % (ws
, lst
, op
))
1393 if __name__
== '__main__':
1394 lst
= ['slw 3, 1, 4',
1397 'sv.cmpi 5, 1, 3, 2',
1399 'sv.isel 64.v, 3, 2, 65.v',
1400 'sv.setb/dm=r3/sm=1<<r3 5, 31',
1401 'sv.setb/m=r3 5, 31',
1402 'sv.setb/vec2 5, 31',
1403 'sv.setb/sw=8/ew=16 5, 31',
1404 'sv.extsw./ff=eq 5, 31',
1405 'sv.extsw./satu/sz/dz/sm=r3/dm=r3 5, 31',
1406 'sv.extsw./pr=eq 5.v, 31',
1407 'sv.add. 5.v, 2.v, 1.v',
1408 'sv.add./m=r3 5.v, 2.v, 1.v',
1411 'sv.stw 5.v, 4(1.v)',
1412 'sv.ld 5.v, 4(1.v)',
1413 'setvl. 2, 3, 4, 0, 1, 1',
1414 'sv.setvl. 2, 3, 4, 0, 1, 1',
1417 "sv.stfsu 0.v, 16(4.v)",
1420 "sv.stfsu/els 0.v, 16(4)",
1423 'sv.add./mr 5.v, 2.v, 1.v',
1425 macros
= {'win2': '50', 'win': '60'}
1427 'sv.addi win2.v, win.v, -1',
1428 'sv.add./mrr 5.v, 2.v, 1.v',
1429 #'sv.lhzsh 5.v, 11(9.v), 15',
1430 #'sv.lwzsh 5.v, 11(9.v), 15',
1431 'sv.ffmadds 6.v, 2.v, 4.v, 6.v',
1434 #'sv.fmadds 0.v, 8.v, 16.v, 4.v',
1435 #'sv.ffadds 0.v, 8.v, 4.v',
1436 'svremap 11, 0, 1, 2, 3, 2, 1',
1437 'svshape 8, 1, 1, 1, 0',
1438 'svshape 8, 1, 1, 1, 1',
1441 #'sv.lfssh 4.v, 11(8.v), 15',
1442 #'sv.lwzsh 4.v, 11(8.v), 15',
1443 #'sv.svstep. 2.v, 4, 0',
1444 #'sv.fcfids. 48.v, 64.v',
1445 'sv.fcoss. 80.v, 0.v',
1446 'sv.fcoss. 20.v, 0.v',
1449 'sv.bc/all 3,12,192',
1450 'sv.bclr/vsbi 3,81.v,192',
1451 'sv.ld 5.v, 4(1.v)',
1452 'sv.svstep. 2.v, 4, 0',
1463 'svindex 0,0,1,0,0,0,0',
1466 'sv.svstep./m=r3 2.v, 4, 0',
1468 isa
= SVP64Asm(lst
, macros
=macros
)
1469 log("list", list(isa
))