xref: /freebsd/contrib/llvm-project/llvm/lib/Target/M68k/M68kInstrArithmetic.td (revision 0ad011ececb978e22a9bff2acf76633b094f1ff6)
1//===-- M68kInstrArithmetic.td - Integer Arith Instrs ------*- tablegen -*-===//
2//
3// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4// See https://llvm.org/LICENSE.txt for license information.
5// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6//
7//===----------------------------------------------------------------------===//
8///
9/// \file
10/// This file describes the integer arithmetic instructions in the M68k
11/// architecture. Here is the current status of the file:
12///
13///  Machine:
14///
15///    ADD       [~]   ADDA      [~]   ADDI        [~]   ADDQ [ ]   ADDX [~]
16///    CLR       [ ]   CMP       [~]   CMPA        [~]   CMPI [~]   CMPM [ ]
17///    CMP2      [ ]   DIVS/DIVU [~]   DIVSL/DIVUL [ ]   EXT  [~]   EXTB [ ]
18///    MULS/MULU [~]   NEG       [~]   NEGX        [~]   SUB  [~]   SUBA [~]
19///    SUBI      [~]   SUBQ      [ ]   SUBX        [~]
20///
21///  Map:
22///
23///   [ ] - was not touched at all
24///   [!] - requires extarnal stuff implemented
25///   [~] - functional implementation
26///   [X] - complete implementation
27///
28//===----------------------------------------------------------------------===//
29
30//===----------------------------------------------------------------------===//
31// OPMODE Encoding
32//===----------------------------------------------------------------------===//
33class MxOpModeEncoding<bits<3> encoding> {
34  bits<3> Value = encoding;
35}
36
37// op EA, Dn
38def MxOpMode8_d_EA  : MxOpModeEncoding<0b000>;
39def MxOpMode16_d_EA : MxOpModeEncoding<0b001>;
40def MxOpMode32_d_EA : MxOpModeEncoding<0b010>;
41
42// op Dn, EA
43def MxOpMode8_EA_d  : MxOpModeEncoding<0b100>;
44def MxOpMode16_EA_d : MxOpModeEncoding<0b101>;
45def MxOpMode32_EA_d : MxOpModeEncoding<0b110>;
46
47// op EA, An
48def MxOpMode16_a_EA : MxOpModeEncoding<0b011>;
49def MxOpMode32_a_EA : MxOpModeEncoding<0b111>;
50
51
52//===----------------------------------------------------------------------===//
53// Encoding
54//===----------------------------------------------------------------------===//
55
56let Defs = [CCR] in {
57let Constraints = "$src = $dst" in {
58
59/// Encoding for Normal forms
60/// ----------------------------------------------------
61///  F  E  D  C | B  A  9 | 8  7  6 | 5  4  3 | 2  1  0
62/// ----------------------------------------------------
63///             |         |         | EFFECTIVE ADDRESS
64///  x  x  x  x |   REG   | OP MODE |   MODE  |   REG
65/// ----------------------------------------------------
66
67// $reg, $ccr <- $reg op $reg
68class MxBiArOp_R_RR_xEA<string MN, SDNode NODE, MxType DST_TYPE, MxType SRC_TYPE,
69                        bits<4> CMD>
70    : MxInst<(outs DST_TYPE.ROp:$dst), (ins DST_TYPE.ROp:$src, SRC_TYPE.ROp:$opd),
71             MN#"."#DST_TYPE.Prefix#"\t$opd, $dst",
72             [(set DST_TYPE.VT:$dst, CCR, (NODE DST_TYPE.VT:$src, SRC_TYPE.VT:$opd))]> {
73  let Inst = (descend
74    CMD, (operand "$dst", 3),
75    !cast<MxOpModeEncoding>("MxOpMode"#DST_TYPE.Size#"_"#DST_TYPE.RLet#"_EA").Value,
76    !cond(
77      !eq(SRC_TYPE.RLet, "r") : (descend 0b00, (operand "$opd", 4)),
78      !eq(SRC_TYPE.RLet, "d") : (descend 0b000, (operand "$opd", 3))
79    )
80  );
81}
82
83/// This Op is similar to the one above except it uses reversed opmode, some
84/// commands(e.g. eor) do not support dEA or rEA modes and require EAd for
85/// register only operations.
86/// NOTE when using dd commands it is irrelevant which opmode to use(as it seems)
87/// but some opcodes support address register and some do not which creates this
88/// mess.
89class MxBiArOp_R_RR_EAd<string MN, SDNode NODE, MxType TYPE, bits<4> CMD>
90    : MxInst<(outs TYPE.ROp:$dst), (ins TYPE.ROp:$src, TYPE.ROp:$opd),
91             MN#"."#TYPE.Prefix#"\t$opd, $dst",
92             [(set TYPE.VT:$dst, CCR, (NODE TYPE.VT:$src, TYPE.VT:$opd))]> {
93  let Inst = (descend
94    CMD, (operand "$opd", 3),
95    !cast<MxOpModeEncoding>("MxOpMode"#TYPE.Size#"_EA_"#TYPE.RLet).Value,
96    /*Destination can only be a data register*/
97    /*MODE*/0b000,
98    /*REGISTER*/(operand "$dst", 3));
99}
100
101let mayLoad = 1 in
102class MxBiArOp_R_RM<string MN, SDNode NODE, MxType TYPE, MxOperand OPD, ComplexPattern PAT,
103                    bits<4> CMD, MxEncMemOp SRC_ENC>
104    : MxInst<(outs TYPE.ROp:$dst), (ins TYPE.ROp:$src, OPD:$opd),
105             MN#"."#TYPE.Prefix#"\t$opd, $dst",
106             [(set TYPE.VT:$dst, CCR, (NODE TYPE.VT:$src, (TYPE.Load PAT:$opd)))]> {
107  let Inst = (ascend
108    (descend CMD, (operand "$dst", 3),
109             !cast<MxOpModeEncoding>("MxOpMode"#TYPE.Size#"_"#TYPE.RLet#"_EA").Value,
110             SRC_ENC.EA),
111    SRC_ENC.Supplement
112  );
113}
114
115/// Encoding for Immediate forms
116/// ---------------------------------------------------
117///  F  E  D  C  B  A  9  8 | 7  6 | 5  4  3 | 2  1  0
118/// ---------------------------------------------------
119///                         |      | EFFECTIVE ADDRESS
120///  x  x  x  x  x  x  x  x | SIZE |   MODE  |   REG
121/// ---------------------------------------------------
122///     16-BIT WORD DATA    |     8-BIT BYTE DATA
123/// ---------------------------------------------------
124///                 32-BIT LONG DATA
125/// ---------------------------------------------------
126/// NOTE It is used to store an immediate to memory, imm-to-reg are handled with
127/// normal version
128
129// $reg <- $reg op $imm
130class MxBiArOp_R_RI_xEA<string MN, SDNode NODE, MxType TYPE, bits<4> CMD>
131    : MxInst<(outs TYPE.ROp:$dst), (ins TYPE.ROp:$src, TYPE.IOp:$opd),
132             MN#"."#TYPE.Prefix#"\t$opd, $dst",
133             [(set TYPE.VT:$dst, CCR, (NODE TYPE.VT:$src, TYPE.IPat:$opd))]> {
134  let Inst = (ascend
135    (descend CMD, (operand "$dst", 3),
136             !cast<MxOpModeEncoding>("MxOpMode"#TYPE.Size#"_"#TYPE.RLet#"_EA").Value,
137             MxEncAddrMode_i<"opd", TYPE.Size>.EA),
138    MxEncAddrMode_i<"opd", TYPE.Size>.Supplement
139  );
140}
141
142// Again, there are two ways to write an immediate to Dn register either dEA
143// opmode or using *I encoding, and again some instructions also support address
144// registers some do not.
145class MxBiArOp_R_RI<string MN, SDNode NODE, MxType TYPE, bits<4> CMD>
146    : MxInst<(outs TYPE.ROp:$dst), (ins TYPE.ROp:$src, TYPE.IOp:$opd),
147             MN#"i."#TYPE.Prefix#"\t$opd, $dst",
148             [(set TYPE.VT:$dst, CCR, (NODE TYPE.VT:$src, TYPE.IPat:$opd))]> {
149  let Inst = (ascend
150    (descend 0b0000, CMD,
151             !cast<MxEncSize>("MxEncSize"#TYPE.Size).Value,
152             // The destination cannot be address register, so it's always
153             // the MODE for data register direct mode.
154             /*MODE*/0b000,
155             /*REGISTER*/(operand "$dst", 3)),
156    // Source (i.e. immediate value) encoding
157    MxEncAddrMode_i<"opd", TYPE.Size>.Supplement
158  );
159}
160} // Constraints
161
162let mayLoad = 1, mayStore = 1 in {
163
164// FIXME MxBiArOp_FMR/FMI cannot consume CCR from MxAdd/MxSub which leads for
165// MxAdd to survive the match and subsequent mismatch.
166class MxBiArOp_MR<string MN, MxType TYPE,
167                  MxOperand MEMOpd, bits<4> CMD, MxEncMemOp DST_ENC>
168    : MxInst<(outs), (ins MEMOpd:$dst, TYPE.ROp:$opd),
169             MN#"."#TYPE.Prefix#"\t$opd, $dst", []> {
170  let Inst = (ascend
171    (descend CMD, (operand "$opd", 3),
172             !cast<MxOpModeEncoding>("MxOpMode"#TYPE.Size#"_EA_"#TYPE.RLet).Value,
173             DST_ENC.EA),
174    DST_ENC.Supplement
175  );
176}
177
178class MxBiArOp_MI<string MN, MxType TYPE,
179                  MxOperand MEMOpd, bits<4> CMD, MxEncMemOp DST_ENC>
180    : MxInst<(outs), (ins MEMOpd:$dst, TYPE.IOp:$opd),
181             MN#"."#TYPE.Prefix#"\t$opd, $dst", []> {
182  let Inst = (ascend
183    (descend 0b0000, CMD,
184             !cast<MxEncSize>("MxEncSize"#TYPE.Size).Value,
185             DST_ENC.EA),
186    // Source (i.e. immediate value) encoding
187    MxEncAddrMode_i<"opd", TYPE.Size>.Supplement,
188    // Destination encoding
189    DST_ENC.Supplement
190  );
191}
192} // mayLoad, mayStore
193} // Defs = [CCR]
194
195multiclass MxBiArOp_DF<string MN, SDNode NODE, bit isComm,
196                       bits<4> CMD, bits<4> CMDI> {
197
198  foreach SZ = [8, 16, 32] in {
199    // op $mem, $reg
200    def NAME#SZ#"dk"  : MxBiArOp_R_RM<MN, NODE,
201                                      !cast<MxType>("MxType"#SZ#"d"),
202                                      !cast<MxType>("MxType"#SZ).KOp,
203                                      !cast<MxType>("MxType"#SZ).KPat,
204                                      CMD, MxEncAddrMode_k<"opd">>;
205
206    def NAME#SZ#"dq"  : MxBiArOp_R_RM<MN, NODE,
207                                      !cast<MxType>("MxType"#SZ#"d"),
208                                      !cast<MxType>("MxType"#SZ).QOp,
209                                      !cast<MxType>("MxType"#SZ).QPat,
210                                      CMD, MxEncAddrMode_q<"opd">>;
211
212    def NAME#SZ#"dp"  : MxBiArOp_R_RM<MN, NODE,
213                                      !cast<MxType>("MxType"#SZ#"d"),
214                                      !cast<MxType>("MxType"#SZ).POp,
215                                      !cast<MxType>("MxType"#SZ).PPat,
216                                      CMD, MxEncAddrMode_p<"opd">>;
217
218    def NAME#SZ#"df"  : MxBiArOp_R_RM<MN, NODE,
219                                      !cast<MxType>("MxType"#SZ#"d"),
220                                      !cast<MxType>("MxType"#SZ).FOp,
221                                      !cast<MxType>("MxType"#SZ).FPat,
222                                      CMD, MxEncAddrMode_f<"opd">>;
223
224    def NAME#SZ#"dj"  : MxBiArOp_R_RM<MN, NODE,
225                                      !cast<MxType>("MxType"#SZ#"d"),
226                                      !cast<MxType>("MxType"#SZ).JOp,
227                                      !cast<MxType>("MxType"#SZ).JPat,
228                                      CMD, MxEncAddrMode_j<"opd">>;
229    // op $imm, $reg
230    def NAME#SZ#"di"  : MxBiArOp_R_RI_xEA<MN, NODE,
231                                          !cast<MxType>("MxType"#SZ#"d"),
232                                          CMD>;
233    // op $reg, $mem
234    def NAME#SZ#"pd"  : MxBiArOp_MR<MN,
235                                    !cast<MxType>("MxType"#SZ#"d"),
236                                    !cast<MxType>("MxType"#SZ).POp,
237                                    CMD, MxEncAddrMode_p<"dst">>;
238
239    def NAME#SZ#"fd"  : MxBiArOp_MR<MN,
240                                    !cast<MxType>("MxType"#SZ#"d"),
241                                    !cast<MxType>("MxType"#SZ).FOp,
242                                    CMD, MxEncAddrMode_f<"dst">>;
243
244    def NAME#SZ#"jd"  : MxBiArOp_MR<MN,
245                                    !cast<MxType>("MxType"#SZ#"d"),
246                                    !cast<MxType>("MxType"#SZ).JOp,
247                                    CMD, MxEncAddrMode_j<"dst">>;
248    // op $imm, $mem
249    def NAME#SZ#"pi"  : MxBiArOp_MI<MN,
250                                    !cast<MxType>("MxType"#SZ),
251                                    !cast<MxType>("MxType"#SZ).POp,
252                                    CMDI, MxEncAddrMode_p<"dst">>;
253
254    def NAME#SZ#"fi"  : MxBiArOp_MI<MN,
255                                    !cast<MxType>("MxType"#SZ),
256                                    !cast<MxType>("MxType"#SZ).FOp,
257                                    CMDI, MxEncAddrMode_f<"dst">>;
258
259    def NAME#SZ#"ji"  : MxBiArOp_MI<MN,
260                                    !cast<MxType>("MxType"#SZ),
261                                    !cast<MxType>("MxType"#SZ).JOp,
262                                    CMDI, MxEncAddrMode_j<"dst">>;
263    // op $reg, $reg
264    let isCommutable = isComm in
265    def NAME#SZ#"dd" : MxBiArOp_R_RR_xEA<MN, NODE,
266                                         !cast<MxType>("MxType"#SZ#"d"),
267                                         !cast<MxType>("MxType"#SZ#"d"),
268                                         CMD>;
269  } // foreach SZ
270
271  foreach SZ = [16, 32] in
272  def NAME#SZ#"dr" : MxBiArOp_R_RR_xEA<MN, NODE,
273                                       !cast<MxType>("MxType"#SZ#"d"),
274                                       !cast<MxType>("MxType"#SZ#"r"),
275                                       CMD>;
276
277} // MxBiArOp_DF
278
279
280// These special snowflakes allowed to match address registers but since *A
281// operations do not produce CCR we should not match them against Mx nodes that
282// produce it.
283let Pattern = [(null_frag)] in
284multiclass MxBiArOp_AF<string MN, SDNode NODE, bits<4> CMD> {
285
286  def NAME#"32ak" : MxBiArOp_R_RM<MN, NODE, MxType32a, MxType32.KOp, MxType32.KPat,
287                                  CMD, MxEncAddrMode_k<"opd">>;
288  def NAME#"32aq" : MxBiArOp_R_RM<MN, NODE, MxType32a, MxType32.QOp, MxType32.QPat,
289                                  CMD, MxEncAddrMode_q<"opd">>;
290  def NAME#"32af" : MxBiArOp_R_RM<MN, NODE, MxType32a, MxType32.FOp, MxType32.FPat,
291                                  CMD, MxEncAddrMode_f<"opd">>;
292  def NAME#"32ap" : MxBiArOp_R_RM<MN, NODE, MxType32a, MxType32.POp, MxType32.PPat,
293                                  CMD, MxEncAddrMode_p<"opd">>;
294  def NAME#"32aj" : MxBiArOp_R_RM<MN, NODE, MxType32a, MxType32.JOp, MxType32.JPat,
295                                  CMD, MxEncAddrMode_j<"opd">>;
296  def NAME#"32ab" : MxBiArOp_R_RM<MN, NODE, MxType32a, MxType32.BOp, MxType32.BPat,
297                                  CMD, MxEncAddrMode_abs<"opd", true>>;
298  def NAME#"32ai" : MxBiArOp_R_RI_xEA<MN, NODE, MxType32a, CMD>;
299
300  def NAME#"32ar" : MxBiArOp_R_RR_xEA<MN, NODE, MxType32a, MxType32r, CMD>;
301
302} // MxBiArOp_AF
303
304// NOTE These naturally produce CCR
305
306//===----------------------------------------------------------------------===//
307// Add/Sub
308//===----------------------------------------------------------------------===//
309
310defm ADD : MxBiArOp_DF<"add",  MxAdd, 1, 0xD, 0x6>;
311defm ADD : MxBiArOp_AF<"adda", MxAdd, 0xD>;
312defm SUB : MxBiArOp_DF<"sub",  MxSub, 0, 0x9, 0x4>;
313defm SUB : MxBiArOp_AF<"suba", MxSub, 0x9>;
314
315// This pattern is used to enable the instruction selector to select ADD32ab
316// for global values that are allocated in thread-local storage, i.e.:
317//   t8: i32 = ISD::ADD GLOBAL_OFFSET_TABLE, TargetGlobalTLSAddress:i32<ptr @myvar>
318//     ====>
319//   t8: i32,i8 = ADD32ab GLOBAL_OFFSET_TABLE, TargetGlobalTLSAddress:i32<ptr @myvar>
320def : Pat<(add MxARD32:$src, tglobaltlsaddr:$opd), (ADD32ab MxARD32:$src, MxAL32:$opd)>;
321
322let Uses = [CCR], Defs = [CCR] in {
323let Constraints = "$src = $dst" in {
324
325/// Encoding for Extended forms
326/// ------------------------------------------------------
327///  F  E  D  C | B  A  9 | 8 | 7  6 | 5  4 | 3 | 2  1  0
328/// ------------------------------------------------------
329///  x  x  x  x |  REG Rx | 1 | SIZE | 0  0 | M |  REG Ry
330/// ------------------------------------------------------
331/// Rx - destination
332/// Ry - source
333/// M  - address mode switch
334
335// $reg, ccr <- $reg op $reg op ccr
336class MxBiArOp_R_RRX<string MN, SDNode NODE, MxType TYPE, bits<4> CMD>
337    : MxInst<(outs TYPE.ROp:$dst), (ins TYPE.ROp:$src, TYPE.ROp:$opd),
338             MN#"."#TYPE.Prefix#"\t$opd, $dst",
339             [(set TYPE.VT:$dst, CCR, (NODE TYPE.VT:$src, TYPE.VT:$opd, CCR))]> {
340  let Inst = (descend CMD,
341    // Destination register
342    (operand "$dst", 3),
343    0b1,
344    // SIZE
345    !cond(!eq(TYPE.Size, 8): 0b00,
346          !eq(TYPE.Size, 16): 0b01,
347          !eq(TYPE.Size, 32): 0b10),
348    0b00, /*R/M*/0b0,
349    // Source register
350    (operand "$opd", 3)
351  );
352}
353} // Constraints
354} // Uses, Defs
355
356multiclass MxBiArOp_RFF<string MN, SDNode NODE, bit isComm, bits<4> CMD> {
357
358let isCommutable = isComm in {
359  foreach SZ = [8, 16, 32] in
360  def NAME#SZ#"dd"  : MxBiArOp_R_RRX<MN, NODE, !cast<MxType>("MxType"#SZ#"d"), CMD>;
361} // isComm
362
363} // MxBiArOp_RFF
364
365// NOTE These consume and produce CCR
366defm ADDX : MxBiArOp_RFF<"addx", MxAddX, 1, 0xD>;
367defm SUBX : MxBiArOp_RFF<"subx", MxSubX, 0, 0x9>;
368
369
370//===----------------------------------------------------------------------===//
371// And/Xor/Or
372//===----------------------------------------------------------------------===//
373
374defm AND : MxBiArOp_DF<"and", MxAnd, 1, 0xC, 0x2>;
375defm OR  : MxBiArOp_DF<"or",  MxOr,  1, 0x8, 0x0>;
376
377multiclass MxBiArOp_DF_EAd<string MN, SDNode NODE, bits<4> CMD, bits<4> CMDI> {
378  foreach SZ = [8, 16, 32] in {
379    let isCommutable = 1 in
380    def NAME#SZ#"dd"  : MxBiArOp_R_RR_EAd<MN, NODE,
381                                          !cast<MxType>("MxType"#SZ#"d"),
382                                          CMD>;
383
384    def NAME#SZ#"di"  : MxBiArOp_R_RI<MN, NODE,
385                                      !cast<MxType>("MxType"#SZ#"d"),
386                                      CMDI>;
387  } // foreach SZ
388} // MxBiArOp_DF_EAd
389
390defm XOR : MxBiArOp_DF_EAd<"eor", MxXor, 0xB, 0xA>;
391
392
393//===----------------------------------------------------------------------===//
394// CMP
395//===----------------------------------------------------------------------===//
396
397let Defs = [CCR] in {
398class MxCmp_RR<MxType LHS_TYPE, MxType RHS_TYPE = LHS_TYPE>
399    : MxInst<(outs), (ins LHS_TYPE.ROp:$lhs, RHS_TYPE.ROp:$rhs),
400             "cmp."#RHS_TYPE.Prefix#"\t$lhs, $rhs",
401             [(set CCR, (MxCmp LHS_TYPE.VT:$lhs, RHS_TYPE.VT:$rhs))]> {
402  let Inst = (descend 0b1011,
403    // REGISTER
404    (operand "$rhs", 3),
405    // OPMODE
406    !cast<MxOpModeEncoding>("MxOpMode"#RHS_TYPE.Size#"_"#RHS_TYPE.RLet#"_EA").Value,
407    // MODE without last bit
408    0b00,
409    // REGISTER prefixed by D/A bit
410    (operand "$lhs", 4)
411  );
412}
413
414class MxCmp_RI<MxType TYPE>
415    : MxInst<(outs), (ins TYPE.IOp:$imm, TYPE.ROp:$reg),
416             "cmpi."#TYPE.Prefix#"\t$imm, $reg",
417             [(set CCR, (MxCmp TYPE.IPat:$imm, TYPE.VT:$reg))]> {
418  let Inst = (ascend
419    (descend 0b00001100,
420             !cast<MxEncSize>("MxEncSize"#TYPE.Size).Value,
421             // The destination cannot be address register, so it's always
422             // the MODE for data register direct mode.
423             /*MODE*/0b000,
424             /*REGISTER*/(operand "$reg", 3)),
425    // Source (i.e. immediate value) encoding
426    MxEncAddrMode_i<"imm", TYPE.Size>.Supplement
427  );
428}
429
430let mayLoad = 1 in {
431
432class MxCmp_MI<MxType TYPE, MxOperand MEMOpd, ComplexPattern MEMPat,
433               MxEncMemOp MEM_ENC>
434    : MxInst<(outs), (ins TYPE.IOp:$imm, MEMOpd:$mem),
435             "cmpi."#TYPE.Prefix#"\t$imm, $mem",
436             [(set CCR, (MxCmp TYPE.IPat:$imm, (load MEMPat:$mem)))]> {
437  let Inst = (ascend
438    (descend 0b00001100,
439             !cast<MxEncSize>("MxEncSize"#TYPE.Size).Value,
440             MEM_ENC.EA),
441    // Source (i.e. immediate value) encoding
442    MxEncAddrMode_i<"imm", TYPE.Size>.Supplement,
443    // Destination (i.e. memory operand) encoding
444    MEM_ENC.Supplement
445  );
446}
447
448// FIXME: What about abs.W?
449class MxCmp_BI<MxType TYPE>
450    : MxInst<(outs), (ins TYPE.IOp:$imm, MxAL32:$abs),
451             "cmpi."#TYPE.Prefix#"\t$imm, $abs",
452             [(set CCR, (MxCmp TYPE.IPat:$imm,
453                               (load (i32 (MxWrapper tglobaladdr:$abs)))))]> {
454  defvar AbsEncoding = MxEncAddrMode_abs<"abs", true>;
455  let Inst = (ascend
456    (descend 0b00001100,
457             !cast<MxEncSize>("MxEncSize"#TYPE.Size).Value,
458             AbsEncoding.EA),
459    // Source (i.e. immediate value) encoding
460    MxEncAddrMode_i<"imm", TYPE.Size>.Supplement,
461    // Destination (i.e. memory operand) encoding
462    AbsEncoding.Supplement
463  );
464}
465
466class MxCmp_RM<MxType TYPE, MxOperand MEMOpd, ComplexPattern MEMPat,
467               MxEncMemOp MEM_ENC>
468    : MxInst<(outs), (ins TYPE.ROp:$reg, MEMOpd:$mem),
469             "cmp."#TYPE.Prefix#"\t$mem, $reg",
470             [(set CCR, (MxCmp (load MEMPat:$mem), TYPE.ROp:$reg))]> {
471  let Inst = (ascend
472    (descend 0b1011,
473      // REGISTER
474      (operand "$reg", 3),
475      // OPMODE
476      !cast<MxOpModeEncoding>("MxOpMode"#TYPE.Size#"_d_EA").Value,
477      MEM_ENC.EA),
478    MEM_ENC.Supplement
479  );
480}
481} // let mayLoad = 1
482
483} // let Defs = [CCR]
484
485multiclass MMxCmp_RM<MxType TYPE> {
486  def NAME#TYPE.KOp.Letter : MxCmp_RM<TYPE, TYPE.KOp, TYPE.KPat, MxEncAddrMode_k<"mem">>;
487  def NAME#TYPE.QOp.Letter : MxCmp_RM<TYPE, TYPE.QOp, TYPE.QPat, MxEncAddrMode_q<"mem">>;
488  def NAME#TYPE.POp.Letter : MxCmp_RM<TYPE, TYPE.POp, TYPE.PPat, MxEncAddrMode_p<"mem">>;
489  def NAME#TYPE.FOp.Letter : MxCmp_RM<TYPE, TYPE.FOp, TYPE.FPat, MxEncAddrMode_f<"mem">>;
490  def NAME#TYPE.JOp.Letter : MxCmp_RM<TYPE, TYPE.JOp, TYPE.JPat, MxEncAddrMode_j<"mem">>;
491}
492
493multiclass MMxCmp_MI<MxType TYPE> {
494  def NAME#TYPE.KOp.Letter#"i" : MxCmp_MI<TYPE, TYPE.KOp, TYPE.KPat,
495                                          MxEncAddrMode_k<"mem">>;
496  def NAME#TYPE.QOp.Letter#"i" : MxCmp_MI<TYPE, TYPE.QOp, TYPE.QPat,
497                                          MxEncAddrMode_q<"mem">>;
498  def NAME#TYPE.POp.Letter#"i" : MxCmp_MI<TYPE, TYPE.POp, TYPE.PPat,
499                                          MxEncAddrMode_p<"mem">>;
500  def NAME#TYPE.FOp.Letter#"i" : MxCmp_MI<TYPE, TYPE.FOp, TYPE.FPat,
501                                          MxEncAddrMode_f<"mem">>;
502  def NAME#TYPE.JOp.Letter#"i" : MxCmp_MI<TYPE, TYPE.JOp, TYPE.JPat,
503                                          MxEncAddrMode_j<"mem">>;
504}
505
506foreach S = [8, 16, 32] in {
507  def CMP#S#di : MxCmp_RI<!cast<MxType>("MxType"#S#"d")>;
508  def CMP#S#bi : MxCmp_BI<!cast<MxType>("MxType"#S#"d")>;
509} // foreach
510
511def CMP8dd : MxCmp_RR<MxType8d>;
512foreach S = [16, 32] in {
513  def CMP#S#dr : MxCmp_RR<!cast<MxType>("MxType"#S#"r"),
514                          !cast<MxType>("MxType"#S#"d")>;
515}
516
517// cmp mem, Dn
518defm CMP8d  : MMxCmp_RM<MxType8d>;
519defm CMP16d : MMxCmp_RM<MxType16d>;
520defm CMP32d : MMxCmp_RM<MxType32d>;
521
522// cmp #imm, mem
523defm CMP8  : MMxCmp_MI<MxType8d>;
524defm CMP16 : MMxCmp_MI<MxType16d>;
525defm CMP32 : MMxCmp_MI<MxType32d>;
526
527
528//===----------------------------------------------------------------------===//
529// EXT
530//===----------------------------------------------------------------------===//
531
532/// ---------------------------------------------------
533///  F  E  D  C  B  A  9 | 8  7  6 | 5  4  3 | 2  1  0
534/// ---------------------------------------------------
535///  0  1  0  0  1  0  0 |  OPMODE | 0  0  0 |   REG
536/// ---------------------------------------------------
537let Defs = [CCR] in
538let Constraints = "$src = $dst" in
539class MxExt<MxType TO, MxType FROM>
540    : MxInst<(outs TO.ROp:$dst), (ins TO.ROp:$src),
541             "ext."#TO.Prefix#"\t$src", []> {
542  let Inst = (descend 0b0100100,
543    // OPMODE
544    !cond(
545      // byte -> word
546      !and(!eq(FROM.Size, 8), !eq(TO.Size, 16)): 0b010,
547      // word -> long
548      !and(!eq(FROM.Size, 16), !eq(TO.Size, 32)): 0b011,
549      // byte -> long
550      !and(!eq(FROM.Size, 8), !eq(TO.Size, 32)): 0b111
551    ),
552    0b000,
553    // REGISTER
554    (operand "$src", 3)
555  );
556}
557
558def EXT16 : MxExt<MxType16d, MxType8d>;
559def EXT32 : MxExt<MxType32d, MxType16d>;
560
561def : Pat<(sext_inreg i16:$src, i8),  (EXT16 $src)>;
562def : Pat<(sext_inreg i32:$src, i16), (EXT32 $src)>;
563def : Pat<(sext_inreg i32:$src, i8),
564          (EXT32 (MOVXd32d16 (EXT16 (EXTRACT_SUBREG $src, MxSubRegIndex16Lo))))>;
565
566
567//===----------------------------------------------------------------------===//
568// DIV/MUL
569//===----------------------------------------------------------------------===//
570
571/// Word operation:
572/// ----------------------------------------------------
573///  F  E  D  C | B  A  9 | 8  7  6 | 5  4  3 | 2  1  0
574/// ----------------------------------------------------
575///             |         |         | EFFECTIVE ADDRESS
576///  x  x  x  x |   REG   | OP MODE |   MODE  |   REG
577/// ----------------------------------------------------
578let Defs = [CCR] in {
579let Constraints = "$src = $dst" in {
580// $dreg <- $dreg op $dreg
581class MxDiMuOp_DD<string MN, bits<4> CMD, bit SIGNED = false,
582                  MxOperand DST, MxOperand OPD>
583    : MxInst<(outs DST:$dst), (ins DST:$src, OPD:$opd), MN#"\t$opd, $dst", []> {
584  let Inst = (descend CMD,
585    // REGISTER
586    (operand "$dst", 3),
587    !if(SIGNED, 0b111, 0b011),
588    /*MODE*/0b000, /*REGISTER*/(operand "$opd", 3)
589  );
590}
591
592// $dreg <- $dreg op $dreg
593class MxDiMuOp_DD_Long<string MN, bits<10> CMD, bit SIGNED = false>
594    : MxInst<(outs MxDRD32:$dst), (ins MxDRD32:$src, MxDRD32:$opd), MN#"\t$opd, $dst", []> {
595  let Inst = (ascend
596    (descend CMD,
597      /*MODE*/0b000, /*REGISTER*/(operand "$opd", 3)),
598    (descend 0b0,
599      // REGISTER
600      (operand "$dst", 3),
601      !if(SIGNED, 0b1, 0b0),
602      /*SIZE*/0b0, 0b0000000,
603      // Dr REGISTER
604      0b000)
605  );
606}
607
608// $reg <- $reg op $imm
609class MxDiMuOp_DI<string MN, bits<4> CMD, bit SIGNED = false,
610                  MxOperand DST, MxOperand OPD>
611    : MxInst<(outs DST:$dst), (ins DST:$src, OPD:$opd), MN#"\t$opd, $dst", []> {
612  // FIXME: Support immediates with different widths.
613  defvar ImmEnc = MxEncAddrMode_i<"opd", 16>;
614  let Inst = (ascend
615    (descend CMD,
616      // REGISTER
617      (operand "$dst", 3),
618      !if(SIGNED, 0b111, 0b011), ImmEnc.EA),
619    ImmEnc.Supplement
620  );
621}
622} // let Constraints
623} // Defs = [CCR]
624
625multiclass MxDiMuOp<string MN, bits<4> CMD, bit isComm = 0> {
626  let isCommutable = isComm in {
627    def "S"#NAME#"d32d16" : MxDiMuOp_DD<MN#"s", CMD, /*SIGNED*/true, MxDRD32, MxDRD16>;
628    def "U"#NAME#"d32d16" : MxDiMuOp_DD<MN#"u", CMD, /*SIGNED*/false, MxDRD32, MxDRD16>;
629  }
630
631  def "S"#NAME#"d32i16" : MxDiMuOp_DI<MN#"s", CMD, /*SIGNED*/true, MxDRD32, Mxi16imm>;
632  def "U"#NAME#"d32i16" : MxDiMuOp_DI<MN#"u", CMD, /*SIGNED*/false, MxDRD32, Mxi16imm>;
633}
634
635defm DIV : MxDiMuOp<"div", 0x8>;
636
637def SDIVd32d32 : MxDiMuOp_DD_Long<"divs.l", 0x131, /*SIGNED*/true>;
638def UDIVd32d32 : MxDiMuOp_DD_Long<"divu.l", 0x131, /*SIGNED*/false>;
639
640// This is used to cast immediates to 16-bits for operations which don't
641// support smaller immediate sizes.
642def as_i16imm : SDNodeXForm<imm, [{
643  return CurDAG->getTargetConstant(N->getSExtValue(), SDLoc(N), MVT::i16);
644}]>;
645
646// RR i8
647def : Pat<(sdiv i8:$dst, i8:$opd),
648          (EXTRACT_SUBREG
649            (SDIVd32d16 (MOVSXd32d8 $dst), (MOVSXd16d8 $opd)),
650             MxSubRegIndex8Lo)>;
651
652def : Pat<(udiv i8:$dst, i8:$opd),
653          (EXTRACT_SUBREG
654            (UDIVd32d16 (MOVZXd32d8 $dst), (MOVZXd16d8 $opd)),
655             MxSubRegIndex8Lo)>;
656
657def : Pat<(srem i8:$dst, i8:$opd),
658          (EXTRACT_SUBREG
659            (ASR32di (ASR32di (SDIVd32d16 (MOVSXd32d8 $dst), (MOVSXd16d8 $opd)), 8), 8),
660             MxSubRegIndex8Lo)>;
661
662def : Pat<(urem i8:$dst, i8:$opd),
663          (EXTRACT_SUBREG
664            (LSR32di (LSR32di (UDIVd32d16 (MOVZXd32d8 $dst), (MOVZXd16d8 $opd)), 8), 8),
665             MxSubRegIndex8Lo)>;
666
667// RR i16
668def : Pat<(sdiv i16:$dst, i16:$opd),
669          (EXTRACT_SUBREG
670            (SDIVd32d16 (MOVSXd32d16 $dst), $opd),
671             MxSubRegIndex16Lo)>;
672
673def : Pat<(udiv i16:$dst, i16:$opd),
674          (EXTRACT_SUBREG
675            (UDIVd32d16 (MOVZXd32d16 $dst), $opd),
676             MxSubRegIndex16Lo)>;
677
678def : Pat<(srem i16:$dst, i16:$opd),
679          (EXTRACT_SUBREG
680            (ASR32di (ASR32di (SDIVd32d16 (MOVSXd32d16 $dst), $opd), 8), 8),
681             MxSubRegIndex16Lo)>;
682
683def : Pat<(urem i16:$dst, i16:$opd),
684          (EXTRACT_SUBREG
685            (LSR32di (LSR32di (UDIVd32d16 (MOVZXd32d16 $dst), $opd), 8), 8),
686             MxSubRegIndex16Lo)>;
687
688
689// RR i32
690def : Pat<(sdiv i32:$dst, i32:$opd), (SDIVd32d32 $dst, $opd)>;
691
692def : Pat<(udiv i32:$dst, i32:$opd), (UDIVd32d32 $dst, $opd)>;
693
694
695// RI i8
696def : Pat<(sdiv i8:$dst, MximmSExt8:$opd),
697          (EXTRACT_SUBREG
698            (SDIVd32i16 (MOVSXd32d8 $dst), (as_i16imm $opd)),
699             MxSubRegIndex8Lo)>;
700
701def : Pat<(udiv i8:$dst, MximmSExt8:$opd),
702          (EXTRACT_SUBREG
703            (UDIVd32i16 (MOVZXd32d8 $dst), (as_i16imm $opd)),
704             MxSubRegIndex8Lo)>;
705
706def : Pat<(srem i8:$dst, MximmSExt8:$opd),
707          (EXTRACT_SUBREG
708            (ASR32di (ASR32di (SDIVd32i16 (MOVSXd32d8 $dst), (as_i16imm $opd)), 8), 8),
709             MxSubRegIndex8Lo)>;
710
711def : Pat<(urem i8:$dst, MximmSExt8:$opd),
712          (EXTRACT_SUBREG
713            (LSR32di (LSR32di (UDIVd32i16 (MOVZXd32d8 $dst), (as_i16imm $opd)), 8), 8),
714             MxSubRegIndex8Lo)>;
715
716// RI i16
717def : Pat<(sdiv i16:$dst, MximmSExt16:$opd),
718          (EXTRACT_SUBREG
719            (SDIVd32i16 (MOVSXd32d16 $dst), imm:$opd),
720             MxSubRegIndex16Lo)>;
721
722def : Pat<(udiv i16:$dst, MximmSExt16:$opd),
723          (EXTRACT_SUBREG
724            (UDIVd32i16 (MOVZXd32d16 $dst), imm:$opd),
725             MxSubRegIndex16Lo)>;
726
727def : Pat<(srem i16:$dst, MximmSExt16:$opd),
728          (EXTRACT_SUBREG
729            (ASR32di (ASR32di (SDIVd32i16 (MOVSXd32d16 $dst), imm:$opd), 8), 8),
730             MxSubRegIndex16Lo)>;
731
732def : Pat<(urem i16:$dst, MximmSExt16:$opd),
733          (EXTRACT_SUBREG
734            (LSR32di (LSR32di (UDIVd32i16 (MOVZXd32d16 $dst), imm:$opd), 8), 8),
735             MxSubRegIndex16Lo)>;
736
737
738defm MUL : MxDiMuOp<"mul", 0xC, 1>;
739
740def SMULd32d32 : MxDiMuOp_DD_Long<"muls.l", 0x130, /*SIGNED*/true>;
741def UMULd32d32 : MxDiMuOp_DD_Long<"mulu.l", 0x130, /*SIGNED*/false>;
742
743// RR
744def : Pat<(mul i16:$dst, i16:$opd),
745          (EXTRACT_SUBREG
746            (SMULd32d16 (MOVXd32d16 $dst), $opd),
747             MxSubRegIndex16Lo)>;
748
749def : Pat<(mulhs i16:$dst, i16:$opd),
750          (EXTRACT_SUBREG
751            (ASR32di (ASR32di (SMULd32d16 (MOVXd32d16 $dst), $opd), 8), 8),
752             MxSubRegIndex16Lo)>;
753
754def : Pat<(mulhu i16:$dst, i16:$opd),
755          (EXTRACT_SUBREG
756            (LSR32di (LSR32di (UMULd32d16 (MOVXd32d16 $dst), $opd), 8), 8),
757             MxSubRegIndex16Lo)>;
758
759def : Pat<(mul i32:$dst, i32:$opd), (SMULd32d32 $dst, $opd)>;
760
761
762// RI
763def : Pat<(mul i16:$dst, MximmSExt16:$opd),
764          (EXTRACT_SUBREG
765            (SMULd32i16 (MOVXd32d16 $dst), imm:$opd),
766             MxSubRegIndex16Lo)>;
767
768def : Pat<(mulhs i16:$dst, MximmSExt16:$opd),
769          (EXTRACT_SUBREG
770            (ASR32di (ASR32di (SMULd32i16 (MOVXd32d16 $dst), imm:$opd), 8), 8),
771             MxSubRegIndex16Lo)>;
772
773def : Pat<(mulhu i16:$dst, MximmSExt16:$opd),
774          (EXTRACT_SUBREG
775            (LSR32di (LSR32di (UMULd32i16 (MOVXd32d16 $dst), imm:$opd), 8), 8),
776             MxSubRegIndex16Lo)>;
777
778
779//===----------------------------------------------------------------------===//
780// NEG/NEGX
781//===----------------------------------------------------------------------===//
782
783/// ------------+------------+------+---------+---------
784///  F  E  D  C | B  A  9  8 | 7  6 | 5  4  3 | 2  1  0
785/// ------------+------------+------+-------------------
786///             |            |      | EFFECTIVE ADDRESS
787///  0  1  0  0 | x  x  x  x | SIZE |   MODE  |   REG
788/// ------------+------------+------+---------+---------
789let Defs = [CCR] in {
790let Constraints = "$src = $dst" in {
791
792class MxNeg_D<MxType TYPE>
793    : MxInst<(outs TYPE.ROp:$dst), (ins TYPE.ROp:$src),
794             "neg."#TYPE.Prefix#"\t$dst",
795             [(set TYPE.VT:$dst, (ineg TYPE.VT:$src))]> {
796  let Inst = (descend 0b01000100,
797    /*SIZE*/!cast<MxEncSize>("MxEncSize"#TYPE.Size).Value,
798    //MODE without last bit
799    0b00,
800    //REGISTER prefixed by D/A bit
801    (operand "$dst", 4)
802  );
803}
804
805let Uses = [CCR] in {
806class MxNegX_D<MxType TYPE>
807    : MxInst<(outs TYPE.ROp:$dst), (ins TYPE.ROp:$src),
808             "negx."#TYPE.Prefix#"\t$dst",
809             [(set TYPE.VT:$dst, (MxSubX 0, TYPE.VT:$src, CCR))]> {
810  let Inst = (descend 0b01000000,
811    /*SIZE*/!cast<MxEncSize>("MxEncSize"#TYPE.Size).Value,
812    //MODE without last bit
813    0b00,
814    //REGISTER prefixed by D/A bit
815    (operand "$dst", 4)
816  );
817}
818}
819
820} // let Constraints
821} // let Defs = [CCR]
822
823foreach S = [8, 16, 32] in {
824  def NEG#S#d  : MxNeg_D<!cast<MxType>("MxType"#S#"d")>;
825  def NEGX#S#d : MxNegX_D<!cast<MxType>("MxType"#S#"d")>;
826}
827
828def : Pat<(MxSub 0, i8 :$src), (NEG8d  MxDRD8 :$src)>;
829def : Pat<(MxSub 0, i16:$src), (NEG16d MxDRD16:$src)>;
830def : Pat<(MxSub 0, i32:$src), (NEG32d MxDRD32:$src)>;
831// SExt of i1 values.
832// Although we specify `ZeroOrOneBooleanContent` for boolean content,
833// we're still adding an AND here as we don't know the origin of the i1 value.
834def : Pat<(sext_inreg i8:$src,  i1), (NEG8d  (AND8di  MxDRD8:$src,  1))>;
835def : Pat<(sext_inreg i16:$src, i1), (NEG16d (AND16di MxDRD16:$src, 1))>;
836def : Pat<(sext_inreg i32:$src, i1), (NEG32d (AND32di MxDRD32:$src, 1))>;
837
838//===----------------------------------------------------------------------===//
839// no-CCR Patterns
840//===----------------------------------------------------------------------===//
841
842/// Basically the reason for this stuff is that add and addc share the same
843/// operand types constraints for whatever reasons and I had to define a common
844/// MxAdd and MxSub instructions that produce CCR and then pattern-map add and addc
845/// to it.
846/// NOTE On the other hand I see no reason why I cannot just drop explicit CCR
847/// result. Anyway works for now, hopefully I will better understand how this stuff
848/// is designed later
849foreach N = ["add", "addc"] in {
850
851  // add reg, reg
852  def : Pat<(!cast<SDNode>(N) i8 :$src, i8 :$opd),
853            (ADD8dd  MxDRD8 :$src, MxDRD8 :$opd)>;
854  def : Pat<(!cast<SDNode>(N) i16:$src, i16:$opd),
855            (ADD16dr MxXRD16:$src, MxDRD16:$opd)>;
856  def : Pat<(!cast<SDNode>(N) i32:$src, i32:$opd),
857            (ADD32dr MxXRD32:$src, MxDRD32:$opd)>;
858
859  // add (An), reg
860  def : Pat<(!cast<SDNode>(N) MxType8.VT:$src, (Mxloadi8 MxType8.JPat:$opd)),
861            (ADD8dj MxDRD8:$src, MxType8.JOp:$opd)>;
862  def : Pat<(!cast<SDNode>(N) MxType16.VT:$src, (Mxloadi16 MxType16.JPat:$opd)),
863            (ADD16dj MxDRD16:$src, MxType16.JOp:$opd)>;
864  def : Pat<(!cast<SDNode>(N) MxType32.VT:$src, (Mxloadi32 MxType32.JPat:$opd)),
865            (ADD32dj MxDRD32:$src, MxType32.JOp:$opd)>;
866
867  // add (i,An), reg
868  def : Pat<(!cast<SDNode>(N) MxType8.VT:$src, (Mxloadi8 MxType8.PPat:$opd)),
869            (ADD8dp MxDRD8:$src, MxType8.POp:$opd)>;
870  def : Pat<(!cast<SDNode>(N) MxType16.VT:$src, (Mxloadi16 MxType16.PPat:$opd)),
871            (ADD16dp MxDRD16:$src, MxType16.POp:$opd)>;
872  def : Pat<(!cast<SDNode>(N) MxType32.VT:$src, (Mxloadi32 MxType32.PPat:$opd)),
873            (ADD32dp MxDRD32:$src, MxType32.POp:$opd)>;
874
875  // add (i,An,Xn), reg
876  def : Pat<(!cast<SDNode>(N) MxType8.VT:$src, (Mxloadi8 MxType8.FPat:$opd)),
877            (ADD8df MxDRD8:$src, MxType8.FOp:$opd)>;
878  def : Pat<(!cast<SDNode>(N) MxType16.VT:$src, (Mxloadi16 MxType16.FPat:$opd)),
879            (ADD16df MxDRD16:$src, MxType16.FOp:$opd)>;
880  def : Pat<(!cast<SDNode>(N) MxType32.VT:$src, (Mxloadi32 MxType32.FPat:$opd)),
881            (ADD32df MxDRD32:$src, MxType32.FOp:$opd)>;
882
883  // add reg, imm
884  def : Pat<(!cast<SDNode>(N) i8: $src, MximmSExt8:$opd),
885            (ADD8di  MxDRD8 :$src, imm:$opd)>;
886  def : Pat<(!cast<SDNode>(N) i16:$src, MximmSExt16:$opd),
887            (ADD16di MxDRD16:$src, imm:$opd)>;
888
889  // LEAp is more complex and thus will be selected over normal ADD32ri but it cannot
890  // be used with data registers, here by adding complexity to a simple ADD32ri insts
891  // we make sure it will be selected over LEAp
892  let AddedComplexity = 15 in {
893  def : Pat<(!cast<SDNode>(N) i32:$src, MximmSExt32:$opd),
894            (ADD32di MxDRD32:$src, imm:$opd)>;
895  } // AddedComplexity = 15
896
897  // add imm, (An)
898  def : Pat<(store (!cast<SDNode>(N) (load MxType8.JPat:$dst), MxType8.IPat:$opd),
899                   MxType8.JPat:$dst),
900            (ADD8ji MxType8.JOp:$dst, imm:$opd)>;
901  def : Pat<(store (!cast<SDNode>(N) (load MxType16.JPat:$dst), MxType16.IPat:$opd),
902                   MxType16.JPat:$dst),
903            (ADD16ji MxType16.JOp:$dst, imm:$opd)>;
904  def : Pat<(store (!cast<SDNode>(N) (load MxType32.JPat:$dst), MxType32.IPat:$opd),
905                   MxType32.JPat:$dst),
906            (ADD32ji MxType32.JOp:$dst, imm:$opd)>;
907
908} // foreach add, addc
909
910def : Pat<(adde i8 :$src, i8 :$opd), (ADDX8dd  MxDRD8 :$src, MxDRD8 :$opd)>;
911def : Pat<(adde i16:$src, i16:$opd), (ADDX16dd MxDRD16:$src, MxDRD16:$opd)>;
912def : Pat<(adde i32:$src, i32:$opd), (ADDX32dd MxDRD32:$src, MxDRD32:$opd)>;
913
914
915
916foreach N = ["sub", "subc"] in {
917
918  // sub reg, reg
919  def : Pat<(!cast<SDNode>(N) i8 :$src, i8 :$opd),
920            (SUB8dd  MxDRD8 :$src, MxDRD8 :$opd)>;
921  def : Pat<(!cast<SDNode>(N) i16:$src, i16:$opd),
922            (SUB16dd MxDRD16:$src, MxDRD16:$opd)>;
923  def : Pat<(!cast<SDNode>(N) i32:$src, i32:$opd),
924            (SUB32dd MxDRD32:$src, MxDRD32:$opd)>;
925
926
927  // sub (An), reg
928  def : Pat<(!cast<SDNode>(N) MxType8.VT:$src, (Mxloadi8 MxType8.JPat:$opd)),
929            (SUB8dj MxDRD8:$src, MxType8.JOp:$opd)>;
930  def : Pat<(!cast<SDNode>(N) MxType16.VT:$src, (Mxloadi16 MxType16.JPat:$opd)),
931            (SUB16dj MxDRD16:$src, MxType16.JOp:$opd)>;
932  def : Pat<(!cast<SDNode>(N) MxType32.VT:$src, (Mxloadi32 MxType32.JPat:$opd)),
933            (SUB32dj MxDRD32:$src, MxType32.JOp:$opd)>;
934
935  // sub (i,An), reg
936  def : Pat<(!cast<SDNode>(N) MxType8.VT:$src, (Mxloadi8 MxType8.PPat:$opd)),
937            (SUB8dp MxDRD8:$src, MxType8.POp:$opd)>;
938  def : Pat<(!cast<SDNode>(N) MxType16.VT:$src, (Mxloadi16 MxType16.PPat:$opd)),
939            (SUB16dp MxDRD16:$src, MxType16.POp:$opd)>;
940  def : Pat<(!cast<SDNode>(N) MxType32.VT:$src, (Mxloadi32 MxType32.PPat:$opd)),
941            (SUB32dp MxDRD32:$src, MxType32.POp:$opd)>;
942
943  // sub (i,An,Xn), reg
944  def : Pat<(!cast<SDNode>(N) MxType8.VT:$src, (Mxloadi8 MxType8.FPat:$opd)),
945            (SUB8df MxDRD8:$src, MxType8.FOp:$opd)>;
946  def : Pat<(!cast<SDNode>(N) MxType16.VT:$src, (Mxloadi16 MxType16.FPat:$opd)),
947            (SUB16df MxDRD16:$src, MxType16.FOp:$opd)>;
948  def : Pat<(!cast<SDNode>(N) MxType32.VT:$src, (Mxloadi32 MxType32.FPat:$opd)),
949            (SUB32df MxDRD32:$src, MxType32.FOp:$opd)>;
950
951  // sub reg, imm
952  def : Pat<(!cast<SDNode>(N) i8 :$src, MximmSExt8 :$opd),
953            (SUB8di  MxDRD8 :$src, imm:$opd)>;
954  def : Pat<(!cast<SDNode>(N) i16:$src, MximmSExt16:$opd),
955            (SUB16di MxDRD16:$src, imm:$opd)>;
956  def : Pat<(!cast<SDNode>(N) i32:$src, MximmSExt32:$opd),
957            (SUB32di MxDRD32:$src, imm:$opd)>;
958
959  // sub imm, (An)
960  def : Pat<(store (!cast<SDNode>(N) (load MxType8.JPat:$dst), MxType8.IPat:$opd),
961                   MxType8.JPat:$dst),
962            (SUB8ji MxType8.JOp:$dst, imm:$opd)>;
963  def : Pat<(store (!cast<SDNode>(N) (load MxType16.JPat:$dst), MxType16.IPat:$opd),
964                   MxType16.JPat:$dst),
965            (SUB16ji MxType16.JOp:$dst, imm:$opd)>;
966  def : Pat<(store (!cast<SDNode>(N) (load MxType32.JPat:$dst), MxType32.IPat:$opd),
967                   MxType32.JPat:$dst),
968            (SUB32ji MxType32.JOp:$dst, imm:$opd)>;
969
970} // foreach sub, subx
971
972def : Pat<(sube i8 :$src, i8 :$opd), (SUBX8dd  MxDRD8 :$src, MxDRD8 :$opd)>;
973def : Pat<(sube i16:$src, i16:$opd), (SUBX16dd MxDRD16:$src, MxDRD16:$opd)>;
974def : Pat<(sube i32:$src, i32:$opd), (SUBX32dd MxDRD32:$src, MxDRD32:$opd)>;
975
976multiclass BitwisePat<string INST, SDNode OP> {
977  // op reg, reg
978  def : Pat<(OP i8 :$src, i8 :$opd),
979            (!cast<MxInst>(INST#"8dd")  MxDRD8 :$src, MxDRD8 :$opd)>;
980  def : Pat<(OP i16:$src, i16:$opd),
981            (!cast<MxInst>(INST#"16dd") MxDRD16:$src, MxDRD16:$opd)>;
982  def : Pat<(OP i32:$src, i32:$opd),
983            (!cast<MxInst>(INST#"32dd") MxDRD32:$src, MxDRD32:$opd)>;
984  // op reg, imm
985  def : Pat<(OP i8: $src, MximmSExt8 :$opd),
986            (!cast<MxInst>(INST#"8di")  MxDRD8 :$src, imm:$opd)>;
987  def : Pat<(OP i16:$src, MximmSExt16:$opd),
988            (!cast<MxInst>(INST#"16di") MxDRD16:$src, imm:$opd)>;
989  def : Pat<(OP i32:$src, MximmSExt32:$opd),
990            (!cast<MxInst>(INST#"32di") MxDRD32:$src, imm:$opd)>;
991}
992
993defm : BitwisePat<"AND", and>;
994defm : BitwisePat<"OR",  or>;
995defm : BitwisePat<"XOR", xor>;
996
997//===----------------------------------------------------------------------===//
998// Floating point arithmetic instruction
999//===----------------------------------------------------------------------===//
1000
1001let Defs = [FPS] in
1002class MxFArithBase_FF<dag outs, dag ins, string asm, string rounding,
1003                      list<dag> patterns>
1004    : MxInst<outs, ins, asm, patterns> {
1005  let Uses = !if(!eq(rounding, ""), [FPC], []);
1006
1007  let Predicates = !if(!eq(rounding, ""), [AtLeastM68881], [AtLeastM68040]);
1008}
1009
1010class MxFPOpModeSelector<string rounding, bits<7> single, bits<7> double,
1011                         bits<7> extended> {
1012  bits<7> Mode = !cond(!eq(rounding, "s"): single,
1013                       !eq(rounding, "d"): double,
1014                       !eq(rounding, ""): extended);
1015}
1016
1017//===----------------------------------------------------------------------===//
1018// Unary floating point instruction
1019//===----------------------------------------------------------------------===//
1020
1021class MxFUnary_FF<MxOpBundle Opnd, string rounding,
1022                  string mnemonic, bits<7> opmode>
1023    : MxFArithBase_FF<(outs Opnd.Op:$dst), (ins Opnd.Op:$src),
1024                    "f"#rounding#mnemonic#".x\t$src, $dst", rounding, [(null_frag)]> {
1025  let Inst = (ascend
1026  (descend 0b1111,
1027    /*COPROCESSOR ID*/0b001,
1028    0b000,
1029    /*MODE+REGISTER*/0b000000),
1030  (descend 0b0, /* R/M */ 0b0, 0b0,
1031    /*SOURCE SPECIFIER*/
1032    (operand "$src", 3),
1033    /*DESTINATION*/
1034    (operand "$dst", 3),
1035    /*OPMODE*/
1036    opmode)
1037  );
1038}
1039
1040multiclass MxFUnaryOp<string mnemonic, bits<7> single, bits<7> double,
1041                      bits<7> extended> {
1042  foreach rounding = ["", "s", "d"] in {
1043    defvar opmode = MxFPOpModeSelector<rounding, single, double, extended>.Mode;
1044
1045    def F # !toupper(rounding) # !substr(NAME, 1) # "80fp_fp"
1046      : MxFUnary_FF<MxOp80AddrMode_fpr, rounding, mnemonic, opmode>;
1047
1048    let isCodeGenOnly = 1 in
1049    foreach size = [32, 64] in
1050      def F # !toupper(rounding) # !substr(NAME, 1) # size # "fp_fp"
1051        : MxFUnary_FF<!cast<MxOpBundle>("MxOp"#size#"AddrMode_fpr"),
1052                      rounding, mnemonic, opmode>;
1053  }
1054}
1055
1056defm FABS : MxFUnaryOp<"abs", 0b1011000, 0b1011100, 0b0011000>;
1057defm FNEG : MxFUnaryOp<"neg", 0b1011010, 0b1011110, 0b0011010>;
1058
1059//===----------------------------------------------------------------------===//
1060// Binary floating point instruction
1061//===----------------------------------------------------------------------===//
1062
1063let Constraints = "$src = $dst" in
1064class MxFBinary_FF<MxOpBundle Opnd, string rounding,
1065                   string mnemonic, bits<7> opmode>
1066    : MxFArithBase_FF<(outs Opnd.Op:$dst), (ins Opnd.Op:$src, Opnd.Op:$opd),
1067                      "f"#rounding#mnemonic#".x\t$opd, $dst", rounding, [(null_frag)]> {
1068  let Inst = (ascend
1069  (descend 0b1111,
1070    /*COPROCESSOR ID*/0b001,
1071    0b000,
1072    /*MODE+REGISTER*/0b000000),
1073  (descend 0b0, /* R/M */ 0b0, 0b0,
1074    /*SOURCE SPECIFIER*/
1075    (operand "$opd", 3),
1076    /*DESTINATION*/
1077    (operand "$dst", 3),
1078    /*OPMODE*/
1079    opmode)
1080  );
1081}
1082
1083multiclass MxFBinaryOp<string mnemonic, bits<7> single, bits<7> double,
1084                      bits<7> extended> {
1085  foreach rounding = ["", "s", "d"] in {
1086    defvar opmode = MxFPOpModeSelector<rounding, single, double, extended>.Mode;
1087
1088    def F # !toupper(rounding) # !substr(NAME, 1) # "80fp_fp"
1089      : MxFBinary_FF<MxOp80AddrMode_fpr, rounding, mnemonic, opmode>;
1090
1091    let isCodeGenOnly = 1 in
1092    foreach size = [32, 64] in
1093      def F # !toupper(rounding) # !substr(NAME, 1) # size # "fp_fp"
1094        : MxFBinary_FF<!cast<MxOpBundle>("MxOp"#size#"AddrMode_fpr"),
1095                        rounding, mnemonic, opmode>;
1096  }
1097}
1098
1099defm FADD : MxFBinaryOp<"add", 0b1100010, 0b1100110, 0b0100010>;
1100defm FSUB : MxFBinaryOp<"sub", 0b1101000, 0b1101100, 0b0101000>;
1101defm FMUL : MxFBinaryOp<"mul", 0b1100011, 0b1100111, 0b0100011>;
1102defm FDIV : MxFBinaryOp<"div", 0b1100000, 0b1100100, 0b0100000>;
1103