xref: /openbmc/qemu/target/arm/tcg/a64.decode (revision afb81fe8)
1# AArch64 A64 allowed instruction decoding
2#
3#  Copyright (c) 2023 Linaro, Ltd
4#
5# This library is free software; you can redistribute it and/or
6# modify it under the terms of the GNU Lesser General Public
7# License as published by the Free Software Foundation; either
8# version 2.1 of the License, or (at your option) any later version.
9#
10# This library is distributed in the hope that it will be useful,
11# but WITHOUT ANY WARRANTY; without even the implied warranty of
12# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
13# Lesser General Public License for more details.
14#
15# You should have received a copy of the GNU Lesser General Public
16# License along with this library; if not, see <http://www.gnu.org/licenses/>.
17
18#
19# This file is processed by scripts/decodetree.py
20#
21
22&r               rn
23&ri              rd imm
24&rri_sf          rd rn imm sf
25&i               imm
26
27
28### Data Processing - Immediate
29
30# PC-rel addressing
31
32%imm_pcrel      5:s19 29:2
33@pcrel          . .. ..... ................... rd:5     &ri imm=%imm_pcrel
34
35ADR             0 .. 10000 ................... .....    @pcrel
36ADRP            1 .. 10000 ................... .....    @pcrel
37
38# Add/subtract (immediate)
39
40%imm12_sh12     10:12 !function=shl_12
41@addsub_imm     sf:1 .. ...... . imm:12 rn:5 rd:5
42@addsub_imm12   sf:1 .. ...... . ............ rn:5 rd:5 imm=%imm12_sh12
43
44ADD_i           . 00 100010 0 ............ ..... .....  @addsub_imm
45ADD_i           . 00 100010 1 ............ ..... .....  @addsub_imm12
46ADDS_i          . 01 100010 0 ............ ..... .....  @addsub_imm
47ADDS_i          . 01 100010 1 ............ ..... .....  @addsub_imm12
48
49SUB_i           . 10 100010 0 ............ ..... .....  @addsub_imm
50SUB_i           . 10 100010 1 ............ ..... .....  @addsub_imm12
51SUBS_i          . 11 100010 0 ............ ..... .....  @addsub_imm
52SUBS_i          . 11 100010 1 ............ ..... .....  @addsub_imm12
53
54# Add/subtract (immediate with tags)
55
56&rri_tag        rd rn uimm6 uimm4
57@addsub_imm_tag . .. ...... . uimm6:6 .. uimm4:4 rn:5 rd:5 &rri_tag
58
59ADDG_i          1 00 100011 0 ...... 00 .... ..... ..... @addsub_imm_tag
60SUBG_i          1 10 100011 0 ...... 00 .... ..... ..... @addsub_imm_tag
61
62# Logical (immediate)
63
64&rri_log        rd rn sf dbm
65@logic_imm_64   1 .. ...... dbm:13 rn:5 rd:5            &rri_log sf=1
66@logic_imm_32   0 .. ...... 0 dbm:12 rn:5 rd:5          &rri_log sf=0
67
68AND_i           . 00 100100 . ...... ...... ..... ..... @logic_imm_64
69AND_i           . 00 100100 . ...... ...... ..... ..... @logic_imm_32
70ORR_i           . 01 100100 . ...... ...... ..... ..... @logic_imm_64
71ORR_i           . 01 100100 . ...... ...... ..... ..... @logic_imm_32
72EOR_i           . 10 100100 . ...... ...... ..... ..... @logic_imm_64
73EOR_i           . 10 100100 . ...... ...... ..... ..... @logic_imm_32
74ANDS_i          . 11 100100 . ...... ...... ..... ..... @logic_imm_64
75ANDS_i          . 11 100100 . ...... ...... ..... ..... @logic_imm_32
76
77# Move wide (immediate)
78
79&movw           rd sf imm hw
80@movw_64        1 .. ...... hw:2   imm:16 rd:5          &movw sf=1
81@movw_32        0 .. ...... 0 hw:1 imm:16 rd:5          &movw sf=0
82
83MOVN            . 00 100101 .. ................ .....   @movw_64
84MOVN            . 00 100101 .. ................ .....   @movw_32
85MOVZ            . 10 100101 .. ................ .....   @movw_64
86MOVZ            . 10 100101 .. ................ .....   @movw_32
87MOVK            . 11 100101 .. ................ .....   @movw_64
88MOVK            . 11 100101 .. ................ .....   @movw_32
89
90# Bitfield
91
92&bitfield       rd rn sf immr imms
93@bitfield_64    1 .. ...... 1 immr:6 imms:6 rn:5 rd:5      &bitfield sf=1
94@bitfield_32    0 .. ...... 0 0 immr:5 0 imms:5 rn:5 rd:5  &bitfield sf=0
95
96SBFM            . 00 100110 . ...... ...... ..... ..... @bitfield_64
97SBFM            . 00 100110 . ...... ...... ..... ..... @bitfield_32
98BFM             . 01 100110 . ...... ...... ..... ..... @bitfield_64
99BFM             . 01 100110 . ...... ...... ..... ..... @bitfield_32
100UBFM            . 10 100110 . ...... ...... ..... ..... @bitfield_64
101UBFM            . 10 100110 . ...... ...... ..... ..... @bitfield_32
102
103# Extract
104
105&extract        rd rn rm imm sf
106
107EXTR            1 00 100111 1 0 rm:5 imm:6 rn:5 rd:5     &extract sf=1
108EXTR            0 00 100111 0 0 rm:5 0 imm:5 rn:5 rd:5   &extract sf=0
109
110# Branches
111
112%imm26   0:s26 !function=times_4
113@branch         . ..... .......................... &i imm=%imm26
114
115B               0 00101 .......................... @branch
116BL              1 00101 .......................... @branch
117
118%imm19   5:s19 !function=times_4
119&cbz     rt imm sf nz
120
121CBZ             sf:1 011010 nz:1 ................... rt:5 &cbz imm=%imm19
122
123%imm14     5:s14 !function=times_4
124%imm31_19  31:1 19:5
125&tbz       rt imm nz bitpos
126
127TBZ             . 011011 nz:1 ..... .............. rt:5 &tbz  imm=%imm14 bitpos=%imm31_19
128
129# B.cond and BC.cond
130B_cond          0101010 0 ................... c:1 cond:4 imm=%imm19
131
132BR              1101011 0000 11111 000000 rn:5 00000 &r
133BLR             1101011 0001 11111 000000 rn:5 00000 &r
134RET             1101011 0010 11111 000000 rn:5 00000 &r
135
136&braz       rn m
137BRAZ            1101011 0000 11111 00001 m:1 rn:5 11111 &braz   # BRAAZ, BRABZ
138BLRAZ           1101011 0001 11111 00001 m:1 rn:5 11111 &braz   # BLRAAZ, BLRABZ
139
140&reta       m
141RETA            1101011 0010 11111 00001 m:1 11111 11111 &reta  # RETAA, RETAB
142
143&bra        rn rm m
144BRA             1101011 1000 11111 00001 m:1 rn:5 rm:5 &bra # BRAA, BRAB
145BLRA            1101011 1001 11111 00001 m:1 rn:5 rm:5 &bra # BLRAA, BLRAB
146
147ERET            1101011 0100 11111 000000 11111 00000
148ERETA           1101011 0100 11111 00001 m:1 11111 11111 &reta  # ERETAA, ERETAB
149
150# We don't need to decode DRPS because it always UNDEFs except when
151# the processor is in halting debug state (which we don't implement).
152# The pattern is listed here as documentation.
153# DRPS            1101011 0101 11111 000000 11111 00000
154
155# Hint instruction group
156{
157  [
158    YIELD       1101 0101 0000 0011 0010 0000 001 11111
159    WFE         1101 0101 0000 0011 0010 0000 010 11111
160    WFI         1101 0101 0000 0011 0010 0000 011 11111
161    # We implement WFE to never block, so our SEV/SEVL are NOPs
162    # SEV       1101 0101 0000 0011 0010 0000 100 11111
163    # SEVL      1101 0101 0000 0011 0010 0000 101 11111
164    # Our DGL is a NOP because we don't merge memory accesses anyway.
165    # DGL       1101 0101 0000 0011 0010 0000 110 11111
166    XPACLRI     1101 0101 0000 0011 0010 0000 111 11111
167    PACIA1716   1101 0101 0000 0011 0010 0001 000 11111
168    PACIB1716   1101 0101 0000 0011 0010 0001 010 11111
169    AUTIA1716   1101 0101 0000 0011 0010 0001 100 11111
170    AUTIB1716   1101 0101 0000 0011 0010 0001 110 11111
171    ESB         1101 0101 0000 0011 0010 0010 000 11111
172    PACIAZ      1101 0101 0000 0011 0010 0011 000 11111
173    PACIASP     1101 0101 0000 0011 0010 0011 001 11111
174    PACIBZ      1101 0101 0000 0011 0010 0011 010 11111
175    PACIBSP     1101 0101 0000 0011 0010 0011 011 11111
176    AUTIAZ      1101 0101 0000 0011 0010 0011 100 11111
177    AUTIASP     1101 0101 0000 0011 0010 0011 101 11111
178    AUTIBZ      1101 0101 0000 0011 0010 0011 110 11111
179    AUTIBSP     1101 0101 0000 0011 0010 0011 111 11111
180  ]
181  # The canonical NOP has CRm == op2 == 0, but all of the space
182  # that isn't specifically allocated to an instruction must NOP
183  NOP           1101 0101 0000 0011 0010 ---- --- 11111
184}
185
186# Barriers
187
188CLREX           1101 0101 0000 0011 0011 ---- 010 11111
189DSB_DMB         1101 0101 0000 0011 0011 domain:2 types:2 10- 11111
190ISB             1101 0101 0000 0011 0011 ---- 110 11111
191SB              1101 0101 0000 0011 0011 0000 111 11111
192
193# PSTATE
194
195CFINV           1101 0101 0000 0 000 0100 0000 000 11111
196XAFLAG          1101 0101 0000 0 000 0100 0000 001 11111
197AXFLAG          1101 0101 0000 0 000 0100 0000 010 11111
198
199# These are architecturally all "MSR (immediate)"; we decode the destination
200# register too because there is no commonality in our implementation.
201@msr_i          .... .... .... . ... .... imm:4 ... .....
202MSR_i_UAO       1101 0101 0000 0 000 0100 .... 011 11111 @msr_i
203MSR_i_PAN       1101 0101 0000 0 000 0100 .... 100 11111 @msr_i
204MSR_i_SPSEL     1101 0101 0000 0 000 0100 .... 101 11111 @msr_i
205MSR_i_SBSS      1101 0101 0000 0 011 0100 .... 001 11111 @msr_i
206MSR_i_DIT       1101 0101 0000 0 011 0100 .... 010 11111 @msr_i
207MSR_i_TCO       1101 0101 0000 0 011 0100 .... 100 11111 @msr_i
208MSR_i_DAIFSET   1101 0101 0000 0 011 0100 .... 110 11111 @msr_i
209MSR_i_DAIFCLEAR 1101 0101 0000 0 011 0100 .... 111 11111 @msr_i
210MSR_i_SVCR      1101 0101 0000 0 011 0100 0 mask:2 imm:1 011 11111
211
212# MRS, MSR (register), SYS, SYSL. These are all essentially the
213# same instruction as far as QEMU is concerned.
214# NB: op0 is bits [20:19], but op0=0b00 is other insns, so we have
215# to hand-decode it.
216SYS             1101 0101 00 l:1 01 op1:3 crn:4 crm:4 op2:3 rt:5 op0=1
217SYS             1101 0101 00 l:1 10 op1:3 crn:4 crm:4 op2:3 rt:5 op0=2
218SYS             1101 0101 00 l:1 11 op1:3 crn:4 crm:4 op2:3 rt:5 op0=3
219
220# Exception generation
221
222@i16            .... .... ... imm:16           ... .. &i
223SVC             1101 0100 000 ................ 000 01 @i16
224HVC             1101 0100 000 ................ 000 10 @i16
225SMC             1101 0100 000 ................ 000 11 @i16
226BRK             1101 0100 001 ................ 000 00 @i16
227HLT             1101 0100 010 ................ 000 00 @i16
228# These insns always UNDEF unless in halting debug state, which
229# we don't implement. So we don't need to decode them. The patterns
230# are listed here as documentation.
231# DCPS1         1101 0100 101 ................ 000 01 @i16
232# DCPS2         1101 0100 101 ................ 000 10 @i16
233# DCPS3         1101 0100 101 ................ 000 11 @i16
234
235# Loads and stores
236
237&stxr           rn rt rt2 rs sz lasr
238&stlr           rn rt sz lasr
239@stxr           sz:2 ...... ... rs:5 lasr:1 rt2:5 rn:5 rt:5 &stxr
240@stlr           sz:2 ...... ... ..... lasr:1 ..... rn:5 rt:5 &stlr
241%imm1_30_p2 30:1 !function=plus_2
242@stxp           .. ...... ... rs:5 lasr:1 rt2:5 rn:5 rt:5 &stxr sz=%imm1_30_p2
243STXR            .. 001000 000 ..... . ..... ..... ..... @stxr  # inc STLXR
244LDXR            .. 001000 010 ..... . ..... ..... ..... @stxr  # inc LDAXR
245STLR            .. 001000 100 11111 . 11111 ..... ..... @stlr  # inc STLLR
246LDAR            .. 001000 110 11111 . 11111 ..... ..... @stlr  # inc LDLAR
247
248STXP            1 . 001000 001 ..... . ..... ..... ..... @stxp # inc STLXP
249LDXP            1 . 001000 011 ..... . ..... ..... ..... @stxp # inc LDAXP
250
251# CASP, CASPA, CASPAL, CASPL (we don't decode the bits that determine
252# acquire/release semantics because QEMU's cmpxchg always has those)
253CASP            0 . 001000 0 - 1 rs:5 - 11111 rn:5 rt:5 sz=%imm1_30_p2
254# CAS, CASA, CASAL, CASL
255CAS             sz:2 001000 1 - 1 rs:5 - 11111 rn:5 rt:5
256
257&ldlit          rt imm sz sign
258@ldlit          .. ... . .. ................... rt:5 &ldlit imm=%imm19
259
260LD_lit          00 011 0 00 ................... ..... @ldlit sz=2 sign=0
261LD_lit          01 011 0 00 ................... ..... @ldlit sz=3 sign=0
262LD_lit          10 011 0 00 ................... ..... @ldlit sz=2 sign=1
263LD_lit_v        00 011 1 00 ................... ..... @ldlit sz=2 sign=0
264LD_lit_v        01 011 1 00 ................... ..... @ldlit sz=3 sign=0
265LD_lit_v        10 011 1 00 ................... ..... @ldlit sz=4 sign=0
266
267# PRFM
268NOP             11 011 0 00 ------------------- -----
269
270&ldstpair       rt2 rt rn imm sz sign w p
271@ldstpair       .. ... . ... . imm:s7 rt2:5 rn:5 rt:5 &ldstpair
272
273# STNP, LDNP: Signed offset, non-temporal hint. We don't emulate caches
274# so we ignore hints about data access patterns, and handle these like
275# plain signed offset.
276STP             00 101 0 000 0 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=0 w=0
277LDP             00 101 0 000 1 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=0 w=0
278STP             10 101 0 000 0 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=0
279LDP             10 101 0 000 1 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=0
280STP_v           00 101 1 000 0 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=0 w=0
281LDP_v           00 101 1 000 1 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=0 w=0
282STP_v           01 101 1 000 0 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=0
283LDP_v           01 101 1 000 1 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=0
284STP_v           10 101 1 000 0 ....... ..... ..... ..... @ldstpair sz=4 sign=0 p=0 w=0
285LDP_v           10 101 1 000 1 ....... ..... ..... ..... @ldstpair sz=4 sign=0 p=0 w=0
286
287# STP and LDP: post-indexed
288STP             00 101 0 001 0 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=1 w=1
289LDP             00 101 0 001 1 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=1 w=1
290LDP             01 101 0 001 1 ....... ..... ..... ..... @ldstpair sz=2 sign=1 p=1 w=1
291STP             10 101 0 001 0 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=1 w=1
292LDP             10 101 0 001 1 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=1 w=1
293STP_v           00 101 1 001 0 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=1 w=1
294LDP_v           00 101 1 001 1 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=1 w=1
295STP_v           01 101 1 001 0 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=1 w=1
296LDP_v           01 101 1 001 1 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=1 w=1
297STP_v           10 101 1 001 0 ....... ..... ..... ..... @ldstpair sz=4 sign=0 p=1 w=1
298LDP_v           10 101 1 001 1 ....... ..... ..... ..... @ldstpair sz=4 sign=0 p=1 w=1
299
300# STP and LDP: offset
301STP             00 101 0 010 0 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=0 w=0
302LDP             00 101 0 010 1 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=0 w=0
303LDP             01 101 0 010 1 ....... ..... ..... ..... @ldstpair sz=2 sign=1 p=0 w=0
304STP             10 101 0 010 0 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=0
305LDP             10 101 0 010 1 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=0
306STP_v           00 101 1 010 0 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=0 w=0
307LDP_v           00 101 1 010 1 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=0 w=0
308STP_v           01 101 1 010 0 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=0
309LDP_v           01 101 1 010 1 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=0
310STP_v           10 101 1 010 0 ....... ..... ..... ..... @ldstpair sz=4 sign=0 p=0 w=0
311LDP_v           10 101 1 010 1 ....... ..... ..... ..... @ldstpair sz=4 sign=0 p=0 w=0
312
313# STP and LDP: pre-indexed
314STP             00 101 0 011 0 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=0 w=1
315LDP             00 101 0 011 1 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=0 w=1
316LDP             01 101 0 011 1 ....... ..... ..... ..... @ldstpair sz=2 sign=1 p=0 w=1
317STP             10 101 0 011 0 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=1
318LDP             10 101 0 011 1 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=1
319STP_v           00 101 1 011 0 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=0 w=1
320LDP_v           00 101 1 011 1 ....... ..... ..... ..... @ldstpair sz=2 sign=0 p=0 w=1
321STP_v           01 101 1 011 0 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=1
322LDP_v           01 101 1 011 1 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=1
323STP_v           10 101 1 011 0 ....... ..... ..... ..... @ldstpair sz=4 sign=0 p=0 w=1
324LDP_v           10 101 1 011 1 ....... ..... ..... ..... @ldstpair sz=4 sign=0 p=0 w=1
325
326# STGP: store tag and pair
327STGP            01 101 0 001 0 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=1 w=1
328STGP            01 101 0 010 0 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=0
329STGP            01 101 0 011 0 ....... ..... ..... ..... @ldstpair sz=3 sign=0 p=0 w=1
330
331# Load/store register (unscaled immediate)
332&ldst_imm       rt rn imm sz sign w p unpriv ext
333@ldst_imm       .. ... . .. .. . imm:s9 .. rn:5 rt:5 &ldst_imm unpriv=0 p=0 w=0
334@ldst_imm_pre   .. ... . .. .. . imm:s9 .. rn:5 rt:5 &ldst_imm unpriv=0 p=0 w=1
335@ldst_imm_post  .. ... . .. .. . imm:s9 .. rn:5 rt:5 &ldst_imm unpriv=0 p=1 w=1
336@ldst_imm_user  .. ... . .. .. . imm:s9 .. rn:5 rt:5 &ldst_imm unpriv=1 p=0 w=0
337
338STR_i           sz:2 111 0 00 00 0 ......... 00 ..... ..... @ldst_imm sign=0 ext=0
339LDR_i           00 111 0 00 01 0 ......... 00 ..... ..... @ldst_imm sign=0 ext=1 sz=0
340LDR_i           01 111 0 00 01 0 ......... 00 ..... ..... @ldst_imm sign=0 ext=1 sz=1
341LDR_i           10 111 0 00 01 0 ......... 00 ..... ..... @ldst_imm sign=0 ext=1 sz=2
342LDR_i           11 111 0 00 01 0 ......... 00 ..... ..... @ldst_imm sign=0 ext=0 sz=3
343LDR_i           00 111 0 00 10 0 ......... 00 ..... ..... @ldst_imm sign=1 ext=0 sz=0
344LDR_i           01 111 0 00 10 0 ......... 00 ..... ..... @ldst_imm sign=1 ext=0 sz=1
345LDR_i           10 111 0 00 10 0 ......... 00 ..... ..... @ldst_imm sign=1 ext=0 sz=2
346LDR_i           00 111 0 00 11 0 ......... 00 ..... ..... @ldst_imm sign=1 ext=1 sz=0
347LDR_i           01 111 0 00 11 0 ......... 00 ..... ..... @ldst_imm sign=1 ext=1 sz=1
348
349STR_i           sz:2 111 0 00 00 0 ......... 01 ..... ..... @ldst_imm_post sign=0 ext=0
350LDR_i           00 111 0 00 01 0 ......... 01 ..... ..... @ldst_imm_post sign=0 ext=1 sz=0
351LDR_i           01 111 0 00 01 0 ......... 01 ..... ..... @ldst_imm_post sign=0 ext=1 sz=1
352LDR_i           10 111 0 00 01 0 ......... 01 ..... ..... @ldst_imm_post sign=0 ext=1 sz=2
353LDR_i           11 111 0 00 01 0 ......... 01 ..... ..... @ldst_imm_post sign=0 ext=0 sz=3
354LDR_i           00 111 0 00 10 0 ......... 01 ..... ..... @ldst_imm_post sign=1 ext=0 sz=0
355LDR_i           01 111 0 00 10 0 ......... 01 ..... ..... @ldst_imm_post sign=1 ext=0 sz=1
356LDR_i           10 111 0 00 10 0 ......... 01 ..... ..... @ldst_imm_post sign=1 ext=0 sz=2
357LDR_i           00 111 0 00 11 0 ......... 01 ..... ..... @ldst_imm_post sign=1 ext=1 sz=0
358LDR_i           01 111 0 00 11 0 ......... 01 ..... ..... @ldst_imm_post sign=1 ext=1 sz=1
359
360STR_i           sz:2 111 0 00 00 0 ......... 10 ..... ..... @ldst_imm_user sign=0 ext=0
361LDR_i           00 111 0 00 01 0 ......... 10 ..... ..... @ldst_imm_user sign=0 ext=1 sz=0
362LDR_i           01 111 0 00 01 0 ......... 10 ..... ..... @ldst_imm_user sign=0 ext=1 sz=1
363LDR_i           10 111 0 00 01 0 ......... 10 ..... ..... @ldst_imm_user sign=0 ext=1 sz=2
364LDR_i           11 111 0 00 01 0 ......... 10 ..... ..... @ldst_imm_user sign=0 ext=0 sz=3
365LDR_i           00 111 0 00 10 0 ......... 10 ..... ..... @ldst_imm_user sign=1 ext=0 sz=0
366LDR_i           01 111 0 00 10 0 ......... 10 ..... ..... @ldst_imm_user sign=1 ext=0 sz=1
367LDR_i           10 111 0 00 10 0 ......... 10 ..... ..... @ldst_imm_user sign=1 ext=0 sz=2
368LDR_i           00 111 0 00 11 0 ......... 10 ..... ..... @ldst_imm_user sign=1 ext=1 sz=0
369LDR_i           01 111 0 00 11 0 ......... 10 ..... ..... @ldst_imm_user sign=1 ext=1 sz=1
370
371STR_i           sz:2 111 0 00 00 0 ......... 11 ..... ..... @ldst_imm_pre sign=0 ext=0
372LDR_i           00 111 0 00 01 0 ......... 11 ..... ..... @ldst_imm_pre sign=0 ext=1 sz=0
373LDR_i           01 111 0 00 01 0 ......... 11 ..... ..... @ldst_imm_pre sign=0 ext=1 sz=1
374LDR_i           10 111 0 00 01 0 ......... 11 ..... ..... @ldst_imm_pre sign=0 ext=1 sz=2
375LDR_i           11 111 0 00 01 0 ......... 11 ..... ..... @ldst_imm_pre sign=0 ext=0 sz=3
376LDR_i           00 111 0 00 10 0 ......... 11 ..... ..... @ldst_imm_pre sign=1 ext=0 sz=0
377LDR_i           01 111 0 00 10 0 ......... 11 ..... ..... @ldst_imm_pre sign=1 ext=0 sz=1
378LDR_i           10 111 0 00 10 0 ......... 11 ..... ..... @ldst_imm_pre sign=1 ext=0 sz=2
379LDR_i           00 111 0 00 11 0 ......... 11 ..... ..... @ldst_imm_pre sign=1 ext=1 sz=0
380LDR_i           01 111 0 00 11 0 ......... 11 ..... ..... @ldst_imm_pre sign=1 ext=1 sz=1
381
382# PRFM : prefetch memory: a no-op for QEMU
383NOP             11 111 0 00 10 0 --------- 00 ----- -----
384
385STR_v_i         sz:2 111 1 00 00 0 ......... 00 ..... ..... @ldst_imm sign=0 ext=0
386STR_v_i         00 111 1 00 10 0 ......... 00 ..... ..... @ldst_imm sign=0 ext=0 sz=4
387LDR_v_i         sz:2 111 1 00 01 0 ......... 00 ..... ..... @ldst_imm sign=0 ext=0
388LDR_v_i         00 111 1 00 11 0 ......... 00 ..... ..... @ldst_imm sign=0 ext=0 sz=4
389
390STR_v_i         sz:2 111 1 00 00 0 ......... 01 ..... ..... @ldst_imm_post sign=0 ext=0
391STR_v_i         00 111 1 00 10 0 ......... 01 ..... ..... @ldst_imm_post sign=0 ext=0 sz=4
392LDR_v_i         sz:2 111 1 00 01 0 ......... 01 ..... ..... @ldst_imm_post sign=0 ext=0
393LDR_v_i         00 111 1 00 11 0 ......... 01 ..... ..... @ldst_imm_post sign=0 ext=0 sz=4
394
395STR_v_i         sz:2 111 1 00 00 0 ......... 11 ..... ..... @ldst_imm_pre sign=0 ext=0
396STR_v_i         00 111 1 00 10 0 ......... 11 ..... ..... @ldst_imm_pre sign=0 ext=0 sz=4
397LDR_v_i         sz:2 111 1 00 01 0 ......... 11 ..... ..... @ldst_imm_pre sign=0 ext=0
398LDR_v_i         00 111 1 00 11 0 ......... 11 ..... ..... @ldst_imm_pre sign=0 ext=0 sz=4
399
400# Load/store with an unsigned 12 bit immediate, which is scaled by the
401# element size. The function gets the sz:imm and returns the scaled immediate.
402%uimm_scaled   10:12 sz:3 !function=uimm_scaled
403
404@ldst_uimm      .. ... . .. .. ............ rn:5 rt:5 &ldst_imm unpriv=0 p=0 w=0 imm=%uimm_scaled
405
406STR_i           sz:2 111 0 01 00 ............ ..... ..... @ldst_uimm sign=0 ext=0
407LDR_i           00 111 0 01 01 ............ ..... ..... @ldst_uimm sign=0 ext=1 sz=0
408LDR_i           01 111 0 01 01 ............ ..... ..... @ldst_uimm sign=0 ext=1 sz=1
409LDR_i           10 111 0 01 01 ............ ..... ..... @ldst_uimm sign=0 ext=1 sz=2
410LDR_i           11 111 0 01 01 ............ ..... ..... @ldst_uimm sign=0 ext=0 sz=3
411LDR_i           00 111 0 01 10 ............ ..... ..... @ldst_uimm sign=1 ext=0 sz=0
412LDR_i           01 111 0 01 10 ............ ..... ..... @ldst_uimm sign=1 ext=0 sz=1
413LDR_i           10 111 0 01 10 ............ ..... ..... @ldst_uimm sign=1 ext=0 sz=2
414LDR_i           00 111 0 01 11 ............ ..... ..... @ldst_uimm sign=1 ext=1 sz=0
415LDR_i           01 111 0 01 11 ............ ..... ..... @ldst_uimm sign=1 ext=1 sz=1
416
417# PRFM
418NOP             11 111 0 01 10 ------------ ----- -----
419
420STR_v_i         sz:2 111 1 01 00 ............ ..... ..... @ldst_uimm sign=0 ext=0
421STR_v_i         00 111 1 01 10 ............ ..... ..... @ldst_uimm sign=0 ext=0 sz=4
422LDR_v_i         sz:2 111 1 01 01 ............ ..... ..... @ldst_uimm sign=0 ext=0
423LDR_v_i         00 111 1 01 11 ............ ..... ..... @ldst_uimm sign=0 ext=0 sz=4
424
425# Load/store with register offset
426&ldst rm rn rt sign ext sz opt s
427@ldst           .. ... . .. .. . rm:5 opt:3 s:1 .. rn:5 rt:5 &ldst
428STR             sz:2 111 0 00 00 1 ..... ... . 10 ..... ..... @ldst sign=0 ext=0
429LDR             00 111 0 00 01 1 ..... ... . 10 ..... ..... @ldst sign=0 ext=1 sz=0
430LDR             01 111 0 00 01 1 ..... ... . 10 ..... ..... @ldst sign=0 ext=1 sz=1
431LDR             10 111 0 00 01 1 ..... ... . 10 ..... ..... @ldst sign=0 ext=1 sz=2
432LDR             11 111 0 00 01 1 ..... ... . 10 ..... ..... @ldst sign=0 ext=0 sz=3
433LDR             00 111 0 00 10 1 ..... ... . 10 ..... ..... @ldst sign=1 ext=0 sz=0
434LDR             01 111 0 00 10 1 ..... ... . 10 ..... ..... @ldst sign=1 ext=0 sz=1
435LDR             10 111 0 00 10 1 ..... ... . 10 ..... ..... @ldst sign=1 ext=0 sz=2
436LDR             00 111 0 00 11 1 ..... ... . 10 ..... ..... @ldst sign=1 ext=1 sz=0
437LDR             01 111 0 00 11 1 ..... ... . 10 ..... ..... @ldst sign=1 ext=1 sz=1
438
439# PRFM
440NOP             11 111 0 00 10 1 ----- -1- - 10 ----- -----
441
442STR_v           sz:2 111 1 00 00 1 ..... ... . 10 ..... ..... @ldst sign=0 ext=0
443STR_v           00 111 1 00 10 1 ..... ... . 10 ..... ..... @ldst sign=0 ext=0 sz=4
444LDR_v           sz:2 111 1 00 01 1 ..... ... . 10 ..... ..... @ldst sign=0 ext=0
445LDR_v           00 111 1 00 11 1 ..... ... . 10 ..... ..... @ldst sign=0 ext=0 sz=4
446
447# Atomic memory operations
448&atomic         rs rn rt a r sz
449@atomic         sz:2 ... . .. a:1 r:1 . rs:5 . ... .. rn:5 rt:5 &atomic
450LDADD           .. 111 0 00 . . 1 ..... 0000 00 ..... ..... @atomic
451LDCLR           .. 111 0 00 . . 1 ..... 0001 00 ..... ..... @atomic
452LDEOR           .. 111 0 00 . . 1 ..... 0010 00 ..... ..... @atomic
453LDSET           .. 111 0 00 . . 1 ..... 0011 00 ..... ..... @atomic
454LDSMAX          .. 111 0 00 . . 1 ..... 0100 00 ..... ..... @atomic
455LDSMIN          .. 111 0 00 . . 1 ..... 0101 00 ..... ..... @atomic
456LDUMAX          .. 111 0 00 . . 1 ..... 0110 00 ..... ..... @atomic
457LDUMIN          .. 111 0 00 . . 1 ..... 0111 00 ..... ..... @atomic
458SWP             .. 111 0 00 . . 1 ..... 1000 00 ..... ..... @atomic
459
460LDAPR           sz:2 111 0 00 1 0 1 11111 1100 00 rn:5 rt:5
461
462# Load/store register (pointer authentication)
463
464# LDRA immediate is 10 bits signed and scaled, but the bits aren't all contiguous
465%ldra_imm       22:s1 12:9 !function=times_2
466
467LDRA            11 111 0 00 m:1 . 1 ......... w:1 1 rn:5 rt:5 imm=%ldra_imm
468
469&ldapr_stlr_i   rn rt imm sz sign ext
470@ldapr_stlr_i   .. ...... .. . imm:9 .. rn:5 rt:5 &ldapr_stlr_i
471STLR_i          sz:2 011001 00 0 ......... 00 ..... ..... @ldapr_stlr_i sign=0 ext=0
472LDAPR_i         sz:2 011001 01 0 ......... 00 ..... ..... @ldapr_stlr_i sign=0 ext=0
473LDAPR_i         00 011001 10 0 ......... 00 ..... ..... @ldapr_stlr_i sign=1 ext=0 sz=0
474LDAPR_i         01 011001 10 0 ......... 00 ..... ..... @ldapr_stlr_i sign=1 ext=0 sz=1
475LDAPR_i         10 011001 10 0 ......... 00 ..... ..... @ldapr_stlr_i sign=1 ext=0 sz=2
476LDAPR_i         00 011001 11 0 ......... 00 ..... ..... @ldapr_stlr_i sign=1 ext=1 sz=0
477LDAPR_i         01 011001 11 0 ......... 00 ..... ..... @ldapr_stlr_i sign=1 ext=1 sz=1
478
479# Load/store multiple structures
480# The 4-bit opcode in [15:12] encodes repeat count and structure elements
481&ldst_mult      rm rn rt sz q p rpt selem
482@ldst_mult      . q:1 ...... p:1 . . rm:5 .... sz:2 rn:5 rt:5 &ldst_mult
483ST_mult         0 . 001100 . 0 0 ..... 0000 .. ..... ..... @ldst_mult rpt=1 selem=4
484ST_mult         0 . 001100 . 0 0 ..... 0010 .. ..... ..... @ldst_mult rpt=4 selem=1
485ST_mult         0 . 001100 . 0 0 ..... 0100 .. ..... ..... @ldst_mult rpt=1 selem=3
486ST_mult         0 . 001100 . 0 0 ..... 0110 .. ..... ..... @ldst_mult rpt=3 selem=1
487ST_mult         0 . 001100 . 0 0 ..... 0111 .. ..... ..... @ldst_mult rpt=1 selem=1
488ST_mult         0 . 001100 . 0 0 ..... 1000 .. ..... ..... @ldst_mult rpt=1 selem=2
489ST_mult         0 . 001100 . 0 0 ..... 1010 .. ..... ..... @ldst_mult rpt=2 selem=1
490
491LD_mult         0 . 001100 . 1 0 ..... 0000 .. ..... ..... @ldst_mult rpt=1 selem=4
492LD_mult         0 . 001100 . 1 0 ..... 0010 .. ..... ..... @ldst_mult rpt=4 selem=1
493LD_mult         0 . 001100 . 1 0 ..... 0100 .. ..... ..... @ldst_mult rpt=1 selem=3
494LD_mult         0 . 001100 . 1 0 ..... 0110 .. ..... ..... @ldst_mult rpt=3 selem=1
495LD_mult         0 . 001100 . 1 0 ..... 0111 .. ..... ..... @ldst_mult rpt=1 selem=1
496LD_mult         0 . 001100 . 1 0 ..... 1000 .. ..... ..... @ldst_mult rpt=1 selem=2
497LD_mult         0 . 001100 . 1 0 ..... 1010 .. ..... ..... @ldst_mult rpt=2 selem=1
498
499# Load/store single structure
500&ldst_single    rm rn rt p selem index scale
501
502%ldst_single_selem 13:1 21:1 !function=plus_1
503
504%ldst_single_index_b  30:1 10:3
505%ldst_single_index_h  30:1 11:2
506%ldst_single_index_s  30:1 12:1
507
508@ldst_single_b     .. ...... p:1 .. rm:5 ...... rn:5 rt:5 \
509                   &ldst_single scale=0 selem=%ldst_single_selem \
510                   index=%ldst_single_index_b
511@ldst_single_h     .. ...... p:1 .. rm:5 ...... rn:5 rt:5 \
512                   &ldst_single scale=1 selem=%ldst_single_selem \
513                   index=%ldst_single_index_h
514@ldst_single_s     .. ...... p:1 .. rm:5 ...... rn:5 rt:5 \
515                   &ldst_single scale=2 selem=%ldst_single_selem \
516                   index=%ldst_single_index_s
517@ldst_single_d     . index:1 ...... p:1 .. rm:5 ...... rn:5 rt:5 \
518                   &ldst_single scale=3 selem=%ldst_single_selem
519
520ST_single          0 . 001101 . 0 . ..... 00 . ... ..... .....  @ldst_single_b
521ST_single          0 . 001101 . 0 . ..... 01 . ..0 ..... .....  @ldst_single_h
522ST_single          0 . 001101 . 0 . ..... 10 . .00 ..... .....  @ldst_single_s
523ST_single          0 . 001101 . 0 . ..... 10 . 001 ..... .....  @ldst_single_d
524
525LD_single          0 . 001101 . 1 . ..... 00 . ... ..... .....  @ldst_single_b
526LD_single          0 . 001101 . 1 . ..... 01 . ..0 ..... .....  @ldst_single_h
527LD_single          0 . 001101 . 1 . ..... 10 . .00 ..... .....  @ldst_single_s
528LD_single          0 . 001101 . 1 . ..... 10 . 001 ..... .....  @ldst_single_d
529
530# Replicating load case
531LD_single_repl  0 q:1 001101 p:1 1 . rm:5 11 . 0 scale:2 rn:5 rt:5 selem=%ldst_single_selem
532
533%tag_offset     12:s9 !function=scale_by_log2_tag_granule
534&ldst_tag       rn rt imm p w
535@ldst_tag       ........ .. . ......... .. rn:5 rt:5 &ldst_tag imm=%tag_offset
536@ldst_tag_mult  ........ .. . 000000000 .. rn:5 rt:5 &ldst_tag imm=0
537
538STZGM           11011001 00 1 ......... 00 ..... ..... @ldst_tag_mult p=0 w=0
539STG             11011001 00 1 ......... 01 ..... ..... @ldst_tag p=1 w=1
540STG             11011001 00 1 ......... 10 ..... ..... @ldst_tag p=0 w=0
541STG             11011001 00 1 ......... 11 ..... ..... @ldst_tag p=0 w=1
542
543LDG             11011001 01 1 ......... 00 ..... ..... @ldst_tag p=0 w=0
544STZG            11011001 01 1 ......... 01 ..... ..... @ldst_tag p=1 w=1
545STZG            11011001 01 1 ......... 10 ..... ..... @ldst_tag p=0 w=0
546STZG            11011001 01 1 ......... 11 ..... ..... @ldst_tag p=0 w=1
547
548STGM            11011001 10 1 ......... 00 ..... ..... @ldst_tag_mult p=0 w=0
549ST2G            11011001 10 1 ......... 01 ..... ..... @ldst_tag p=1 w=1
550ST2G            11011001 10 1 ......... 10 ..... ..... @ldst_tag p=0 w=0
551ST2G            11011001 10 1 ......... 11 ..... ..... @ldst_tag p=0 w=1
552
553LDGM            11011001 11 1 ......... 00 ..... ..... @ldst_tag_mult p=0 w=0
554STZ2G           11011001 11 1 ......... 01 ..... ..... @ldst_tag p=1 w=1
555STZ2G           11011001 11 1 ......... 10 ..... ..... @ldst_tag p=0 w=0
556STZ2G           11011001 11 1 ......... 11 ..... ..... @ldst_tag p=0 w=1
557
558# Memory operations (memset, memcpy, memmove)
559# Each of these comes in a set of three, eg SETP (prologue), SETM (main),
560# SETE (epilogue), and each of those has different flavours to
561# indicate whether memory accesses should be unpriv or non-temporal.
562# We don't distinguish temporal and non-temporal accesses, but we
563# do need to report it in syndrome register values.
564
565# Memset
566&set rs rn rd unpriv nontemp
567# op2 bit 1 is nontemporal bit
568@set         .. ......... rs:5 .. nontemp:1 unpriv:1 .. rn:5 rd:5 &set
569
570SETP            00 011001110 ..... 00 . . 01 ..... ..... @set
571SETM            00 011001110 ..... 01 . . 01 ..... ..... @set
572SETE            00 011001110 ..... 10 . . 01 ..... ..... @set
573
574# Like SET, but also setting MTE tags
575SETGP           00 011101110 ..... 00 . . 01 ..... ..... @set
576SETGM           00 011101110 ..... 01 . . 01 ..... ..... @set
577SETGE           00 011101110 ..... 10 . . 01 ..... ..... @set
578
579# Memmove/Memcopy: the CPY insns allow overlapping src/dest and
580# copy in the correct direction; the CPYF insns always copy forwards.
581#
582# options has the nontemporal and unpriv bits for src and dest
583&cpy rs rn rd options
584@cpy            .. ... . ..... rs:5 options:4 .. rn:5 rd:5 &cpy
585
586CPYFP           00 011 0 01000 ..... .... 01 ..... ..... @cpy
587CPYFM           00 011 0 01010 ..... .... 01 ..... ..... @cpy
588CPYFE           00 011 0 01100 ..... .... 01 ..... ..... @cpy
589CPYP            00 011 1 01000 ..... .... 01 ..... ..... @cpy
590CPYM            00 011 1 01010 ..... .... 01 ..... ..... @cpy
591CPYE            00 011 1 01100 ..... .... 01 ..... ..... @cpy
592