xref: /freebsd/contrib/llvm-project/llvm/lib/Target/ARM/ARMInstrMVE.td (revision 02e9120893770924227138ba49df1edb3896112a)
1//===-- ARMInstrMVE.td - MVE support for ARM ---------------*- 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// This file describes the ARM MVE instruction set.
10//
11//===----------------------------------------------------------------------===//
12
13// VPT condition mask
14def vpt_mask : Operand<i32> {
15  let PrintMethod = "printVPTMask";
16  let ParserMatchClass = it_mask_asmoperand;
17  let EncoderMethod = "getVPTMaskOpValue";
18  let DecoderMethod = "DecodeVPTMaskOperand";
19}
20
21// VPT/VCMP restricted predicate for sign invariant types
22def pred_restricted_i_asmoperand : AsmOperandClass {
23  let Name = "CondCodeRestrictedI";
24  let RenderMethod = "addITCondCodeOperands";
25  let PredicateMethod = "isITCondCodeRestrictedI";
26  let ParserMethod = "parseITCondCode";
27  let DiagnosticString = "condition code for sign-independent integer "#
28                         "comparison must be EQ or NE";
29}
30
31// VPT/VCMP restricted predicate for signed types
32def pred_restricted_s_asmoperand : AsmOperandClass {
33  let Name = "CondCodeRestrictedS";
34  let RenderMethod = "addITCondCodeOperands";
35  let PredicateMethod = "isITCondCodeRestrictedS";
36  let ParserMethod = "parseITCondCode";
37  let DiagnosticString = "condition code for signed integer "#
38                         "comparison must be EQ, NE, LT, GT, LE or GE";
39}
40
41// VPT/VCMP restricted predicate for unsigned types
42def pred_restricted_u_asmoperand : AsmOperandClass {
43  let Name = "CondCodeRestrictedU";
44  let RenderMethod = "addITCondCodeOperands";
45  let PredicateMethod = "isITCondCodeRestrictedU";
46  let ParserMethod = "parseITCondCode";
47  let DiagnosticString = "condition code for unsigned integer "#
48                         "comparison must be EQ, NE, HS or HI";
49}
50
51// VPT/VCMP restricted predicate for floating point
52def pred_restricted_fp_asmoperand : AsmOperandClass {
53  let Name = "CondCodeRestrictedFP";
54  let RenderMethod = "addITCondCodeOperands";
55  let PredicateMethod = "isITCondCodeRestrictedFP";
56  let ParserMethod = "parseITCondCode";
57  let DiagnosticString = "condition code for floating-point "#
58                         "comparison must be EQ, NE, LT, GT, LE or GE";
59}
60
61class VCMPPredicateOperand : Operand<i32>;
62
63def pred_basic_i : VCMPPredicateOperand {
64  let PrintMethod = "printMandatoryRestrictedPredicateOperand";
65  let ParserMatchClass = pred_restricted_i_asmoperand;
66  let DecoderMethod = "DecodeRestrictedIPredicateOperand";
67  let EncoderMethod = "getRestrictedCondCodeOpValue";
68}
69
70def pred_basic_u : VCMPPredicateOperand {
71  let PrintMethod = "printMandatoryRestrictedPredicateOperand";
72  let ParserMatchClass = pred_restricted_u_asmoperand;
73  let DecoderMethod = "DecodeRestrictedUPredicateOperand";
74  let EncoderMethod = "getRestrictedCondCodeOpValue";
75}
76
77def pred_basic_s : VCMPPredicateOperand {
78  let PrintMethod = "printMandatoryRestrictedPredicateOperand";
79  let ParserMatchClass = pred_restricted_s_asmoperand;
80  let DecoderMethod = "DecodeRestrictedSPredicateOperand";
81  let EncoderMethod = "getRestrictedCondCodeOpValue";
82}
83
84def pred_basic_fp : VCMPPredicateOperand {
85  let PrintMethod = "printMandatoryRestrictedPredicateOperand";
86  let ParserMatchClass = pred_restricted_fp_asmoperand;
87  let DecoderMethod = "DecodeRestrictedFPPredicateOperand";
88  let EncoderMethod = "getRestrictedCondCodeOpValue";
89}
90
91// Register list operands for interleaving load/stores
92def VecList2QAsmOperand : AsmOperandClass {
93  let Name = "VecListTwoMQ";
94  let ParserMethod = "parseVectorList";
95  let RenderMethod = "addMVEVecListOperands";
96  let DiagnosticString = "operand must be a list of two consecutive "#
97                         "q-registers in range [q0,q7]";
98}
99
100def VecList2Q : RegisterOperand<MQQPR, "printMVEVectorListTwoQ"> {
101  let ParserMatchClass = VecList2QAsmOperand;
102  let PrintMethod = "printMVEVectorList<2>";
103}
104
105def VecList4QAsmOperand : AsmOperandClass {
106  let Name = "VecListFourMQ";
107  let ParserMethod = "parseVectorList";
108  let RenderMethod = "addMVEVecListOperands";
109  let DiagnosticString = "operand must be a list of four consecutive "#
110                         "q-registers in range [q0,q7]";
111}
112
113def VecList4Q : RegisterOperand<MQQQQPR, "printMVEVectorListFourQ"> {
114  let ParserMatchClass = VecList4QAsmOperand;
115  let PrintMethod = "printMVEVectorList<4>";
116}
117
118// taddrmode_imm7  := reg[r0-r7] +/- (imm7 << shift)
119class TMemImm7ShiftOffsetAsmOperand<int shift> : AsmOperandClass {
120  let Name = "TMemImm7Shift"#shift#"Offset";
121  let PredicateMethod = "isMemImm7ShiftedOffset<"#shift#",ARM::tGPRRegClassID>";
122  let RenderMethod = "addMemImmOffsetOperands";
123}
124
125class taddrmode_imm7<int shift> : MemOperand,
126    ComplexPattern<i32, 2, "SelectTAddrModeImm7<"#shift#">", []>  {
127  let ParserMatchClass = TMemImm7ShiftOffsetAsmOperand<shift>;
128  // They are printed the same way as the T2 imm8 version
129  let PrintMethod = "printT2AddrModeImm8Operand<false>";
130  // This can also be the same as the T2 version.
131  let EncoderMethod = "getT2AddrModeImmOpValue<7,"#shift#">";
132  let DecoderMethod = "DecodeTAddrModeImm7<"#shift#">";
133  let MIOperandInfo = (ops tGPR:$base, i32imm:$offsimm);
134}
135
136// t2addrmode_imm7  := reg +/- (imm7)
137class MemImm7ShiftOffsetAsmOperand<int shift> : AsmOperandClass {
138  let Name = "MemImm7Shift"#shift#"Offset";
139  let PredicateMethod = "isMemImm7ShiftedOffset<" # shift #
140                        ",ARM::GPRnopcRegClassID>";
141  let RenderMethod = "addMemImmOffsetOperands";
142}
143
144def MemImm7Shift0OffsetAsmOperand : MemImm7ShiftOffsetAsmOperand<0>;
145def MemImm7Shift1OffsetAsmOperand : MemImm7ShiftOffsetAsmOperand<1>;
146def MemImm7Shift2OffsetAsmOperand : MemImm7ShiftOffsetAsmOperand<2>;
147class T2AddrMode_Imm7<int shift> : MemOperand,
148      ComplexPattern<i32, 2, "SelectT2AddrModeImm7<"#shift#">", []> {
149  let EncoderMethod = "getT2AddrModeImmOpValue<7,"#shift#">";
150  let DecoderMethod = "DecodeT2AddrModeImm7<"#shift#", 0>";
151  let ParserMatchClass =
152    !cast<AsmOperandClass>("MemImm7Shift"#shift#"OffsetAsmOperand");
153  let MIOperandInfo = (ops GPRnopc:$base, i32imm:$offsimm);
154}
155
156class t2addrmode_imm7<int shift> : T2AddrMode_Imm7<shift> {
157  // They are printed the same way as the imm8 version
158  let PrintMethod = "printT2AddrModeImm8Operand<false>";
159}
160
161class MemImm7ShiftOffsetWBAsmOperand<int shift> : AsmOperandClass {
162  let Name = "MemImm7Shift"#shift#"OffsetWB";
163  let PredicateMethod = "isMemImm7ShiftedOffset<" # shift #
164                        ",ARM::rGPRRegClassID>";
165  let RenderMethod = "addMemImmOffsetOperands";
166}
167
168def MemImm7Shift0OffsetWBAsmOperand : MemImm7ShiftOffsetWBAsmOperand<0>;
169def MemImm7Shift1OffsetWBAsmOperand : MemImm7ShiftOffsetWBAsmOperand<1>;
170def MemImm7Shift2OffsetWBAsmOperand : MemImm7ShiftOffsetWBAsmOperand<2>;
171
172class t2addrmode_imm7_pre<int shift> : T2AddrMode_Imm7<shift> {
173  // They are printed the same way as the imm8 version
174  let PrintMethod = "printT2AddrModeImm8Operand<true>";
175  let ParserMatchClass =
176    !cast<AsmOperandClass>("MemImm7Shift"#shift#"OffsetWBAsmOperand");
177  let DecoderMethod = "DecodeT2AddrModeImm7<"#shift#", 1>";
178  let MIOperandInfo = (ops rGPR:$base, i32imm:$offsim);
179}
180
181class t2am_imm7shiftOffsetAsmOperand<int shift>
182  : AsmOperandClass { let Name = "Imm7Shift"#shift; }
183def t2am_imm7shift0OffsetAsmOperand : t2am_imm7shiftOffsetAsmOperand<0>;
184def t2am_imm7shift1OffsetAsmOperand : t2am_imm7shiftOffsetAsmOperand<1>;
185def t2am_imm7shift2OffsetAsmOperand : t2am_imm7shiftOffsetAsmOperand<2>;
186
187class t2am_imm7_offset<int shift> : MemOperand,
188      ComplexPattern<i32, 1, "SelectT2AddrModeImm7Offset<"#shift#">",
189                     [], [SDNPWantRoot]> {
190  // They are printed the same way as the imm8 version
191  let PrintMethod = "printT2AddrModeImm8OffsetOperand";
192  let ParserMatchClass =
193    !cast<AsmOperandClass>("t2am_imm7shift"#shift#"OffsetAsmOperand");
194  let EncoderMethod = "getT2ScaledImmOpValue<7,"#shift#">";
195  let DecoderMethod = "DecodeT2Imm7<"#shift#">";
196}
197
198// Operands for gather/scatter loads of the form [Rbase, Qoffsets]
199class MemRegRQOffsetAsmOperand<int shift> : AsmOperandClass {
200  let Name = "MemRegRQS"#shift#"Offset";
201  let PredicateMethod = "isMemRegRQOffset<"#shift#">";
202  let RenderMethod = "addMemRegRQOffsetOperands";
203}
204
205def MemRegRQS0OffsetAsmOperand : MemRegRQOffsetAsmOperand<0>;
206def MemRegRQS1OffsetAsmOperand : MemRegRQOffsetAsmOperand<1>;
207def MemRegRQS2OffsetAsmOperand : MemRegRQOffsetAsmOperand<2>;
208def MemRegRQS3OffsetAsmOperand : MemRegRQOffsetAsmOperand<3>;
209
210// mve_addr_rq_shift  := reg + vreg{ << UXTW #shift}
211class mve_addr_rq_shift<int shift> : MemOperand {
212  let EncoderMethod = "getMveAddrModeRQOpValue";
213  let PrintMethod = "printMveAddrModeRQOperand<"#shift#">";
214  let ParserMatchClass =
215    !cast<AsmOperandClass>("MemRegRQS"#shift#"OffsetAsmOperand");
216  let DecoderMethod = "DecodeMveAddrModeRQ";
217  let MIOperandInfo = (ops GPRnopc:$base, MQPR:$offsreg);
218}
219
220class MemRegQOffsetAsmOperand<int shift> : AsmOperandClass {
221  let Name = "MemRegQS"#shift#"Offset";
222  let PredicateMethod = "isMemRegQOffset<"#shift#">";
223  let RenderMethod = "addMemImmOffsetOperands";
224}
225
226def MemRegQS2OffsetAsmOperand : MemRegQOffsetAsmOperand<2>;
227def MemRegQS3OffsetAsmOperand : MemRegQOffsetAsmOperand<3>;
228
229// mve_addr_q_shift  := vreg {+ #imm7s2/4}
230class mve_addr_q_shift<int shift> : MemOperand {
231  let EncoderMethod = "getMveAddrModeQOpValue<"#shift#">";
232  // Can be printed same way as other reg + imm operands
233  let PrintMethod = "printT2AddrModeImm8Operand<false>";
234  let ParserMatchClass =
235    !cast<AsmOperandClass>("MemRegQS"#shift#"OffsetAsmOperand");
236  let DecoderMethod = "DecodeMveAddrModeQ<"#shift#">";
237  let MIOperandInfo = (ops MQPR:$base, i32imm:$imm);
238}
239
240// A family of classes wrapping up information about the vector types
241// used by MVE.
242class MVEVectorVTInfo<ValueType vec, ValueType dblvec,
243                      ValueType pred, ValueType dblpred,
244                      bits<2> size, string suffixletter, bit unsigned> {
245  // The LLVM ValueType representing the vector, so we can use it in
246  // ISel patterns.
247  ValueType Vec = vec;
248
249  // The LLVM ValueType representing a vector with elements double the size
250  // of those in Vec, so we can use it in ISel patterns. It is up to the
251  // invoker of this class to ensure that this is a correct choice.
252  ValueType DblVec = dblvec;
253
254  // An LLVM ValueType representing a corresponding vector of
255  // predicate bits, for use in ISel patterns that handle an IR
256  // intrinsic describing the predicated form of the instruction.
257  ValueType Pred = pred;
258
259  // Same as Pred but for DblVec rather than Vec.
260  ValueType DblPred = dblpred;
261
262  // The most common representation of the vector element size in MVE
263  // instruction encodings: a 2-bit value V representing an (8<<V)-bit
264  // vector element.
265  bits<2> Size = size;
266
267  // For vectors explicitly mentioning a signedness of integers: 0 for
268  // signed and 1 for unsigned. For anything else, undefined.
269  bit Unsigned = unsigned;
270
271  // The number of bits in a vector element, in integer form.
272  int LaneBits = !shl(8, Size);
273
274  // The suffix used in assembly language on an instruction operating
275  // on this lane if it only cares about number of bits.
276  string BitsSuffix = !if(!eq(suffixletter, "p"),
277                          !if(!eq(unsigned, 0b0), "8", "16"),
278                          !cast<string>(LaneBits));
279
280  // The suffix used on an instruction that mentions the whole type.
281  string Suffix = suffixletter # BitsSuffix;
282
283  // The letter part of the suffix only.
284  string SuffixLetter = suffixletter;
285}
286
287// Integer vector types that don't treat signed and unsigned differently.
288def MVE_v16i8 : MVEVectorVTInfo<v16i8, v8i16, v16i1, v8i1, 0b00, "i", ?>;
289def MVE_v8i16 : MVEVectorVTInfo<v8i16, v4i32, v8i1,  v4i1, 0b01, "i", ?>;
290def MVE_v4i32 : MVEVectorVTInfo<v4i32, v2i64, v4i1,  v2i1, 0b10, "i", ?>;
291def MVE_v2i64 : MVEVectorVTInfo<v2i64, ?,     v2i1,  ?,    0b11, "i", ?>;
292
293// Explicitly signed and unsigned integer vectors. They map to the
294// same set of LLVM ValueTypes as above, but are represented
295// differently in assembly and instruction encodings.
296def MVE_v16s8 : MVEVectorVTInfo<v16i8, v8i16, v16i1, v8i1, 0b00, "s", 0b0>;
297def MVE_v8s16 : MVEVectorVTInfo<v8i16, v4i32, v8i1,  v4i1, 0b01, "s", 0b0>;
298def MVE_v4s32 : MVEVectorVTInfo<v4i32, v2i64, v4i1,  v2i1, 0b10, "s", 0b0>;
299def MVE_v2s64 : MVEVectorVTInfo<v2i64, ?,     v2i1,  ?,    0b11, "s", 0b0>;
300def MVE_v16u8 : MVEVectorVTInfo<v16i8, v8i16, v16i1, v8i1, 0b00, "u", 0b1>;
301def MVE_v8u16 : MVEVectorVTInfo<v8i16, v4i32, v8i1,  v4i1, 0b01, "u", 0b1>;
302def MVE_v4u32 : MVEVectorVTInfo<v4i32, v2i64, v4i1,  v2i1, 0b10, "u", 0b1>;
303def MVE_v2u64 : MVEVectorVTInfo<v2i64, ?,     v2i1,  ?,    0b11, "u", 0b1>;
304
305// FP vector types.
306def MVE_v8f16 : MVEVectorVTInfo<v8f16, v4f32, v8i1,  v4i1, 0b01, "f", ?>;
307def MVE_v4f32 : MVEVectorVTInfo<v4f32, v2f64, v4i1,  v2i1, 0b10, "f", ?>;
308def MVE_v2f64 : MVEVectorVTInfo<v2f64, ?,     v2i1,  ?,    0b11, "f", ?>;
309
310// Polynomial vector types.
311def MVE_v16p8 : MVEVectorVTInfo<v16i8, v8i16, v16i1, v8i1, 0b11, "p", 0b0>;
312def MVE_v8p16 : MVEVectorVTInfo<v8i16, v4i32, v8i1,  v4i1, 0b11, "p", 0b1>;
313
314multiclass MVE_TwoOpPattern<MVEVectorVTInfo VTI, SDPatternOperator Op, Intrinsic PredInt,
315                            dag PredOperands, Instruction Inst,
316                            SDPatternOperator IdentityVec = null_frag> {
317  // Unpredicated
318  def : Pat<(VTI.Vec (Op (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn))),
319            (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn)))>;
320
321  // Predicated with select
322  if !ne(VTI.Size, 0b11) then {
323    def : Pat<(VTI.Vec (vselect (VTI.Pred VCCR:$mask),
324                                (VTI.Vec (Op (VTI.Vec MQPR:$Qm),
325                                             (VTI.Vec MQPR:$Qn))),
326                                (VTI.Vec MQPR:$inactive))),
327              (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
328                              ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
329                              (VTI.Vec MQPR:$inactive)))>;
330
331    // Optionally with the select folded through the op
332    def : Pat<(VTI.Vec (Op (VTI.Vec MQPR:$Qm),
333                           (VTI.Vec (vselect (VTI.Pred VCCR:$mask),
334                                             (VTI.Vec MQPR:$Qn),
335                                             (VTI.Vec IdentityVec))))),
336              (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
337                              ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
338                              (VTI.Vec MQPR:$Qm)))>;
339  }
340
341  // Predicated with intrinsic
342  def : Pat<(VTI.Vec !con((PredInt (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn)),
343                          PredOperands,
344                          (? (VTI.Pred VCCR:$mask), (VTI.Vec MQPR:$inactive)))),
345            (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
346                            ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
347                            (VTI.Vec MQPR:$inactive)))>;
348}
349
350multiclass MVE_TwoOpPatternDup<MVEVectorVTInfo VTI, SDPatternOperator Op, Intrinsic PredInt,
351                               dag PredOperands, Instruction Inst,
352                               SDPatternOperator IdentityVec = null_frag> {
353  // Unpredicated
354  def : Pat<(VTI.Vec (Op (VTI.Vec MQPR:$Qm), (VTI.Vec (ARMvdup rGPR:$Rn)))),
355            (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), rGPR:$Rn))>;
356
357  // Predicated with select
358  if !ne(VTI.Size, 0b11) then {
359    def : Pat<(VTI.Vec (vselect (VTI.Pred VCCR:$mask),
360                                (VTI.Vec (Op (VTI.Vec MQPR:$Qm),
361                                             (VTI.Vec (ARMvdup rGPR:$Rn)))),
362                                (VTI.Vec MQPR:$inactive))),
363              (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), rGPR:$Rn,
364                              ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
365                              (VTI.Vec MQPR:$inactive)))>;
366
367    // Optionally with the select folded through the op
368    def : Pat<(VTI.Vec (Op (VTI.Vec MQPR:$Qm),
369                           (VTI.Vec (vselect (VTI.Pred VCCR:$mask),
370                                             (ARMvdup rGPR:$Rn),
371                                             (VTI.Vec IdentityVec))))),
372              (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), rGPR:$Rn,
373                              ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
374                              (VTI.Vec MQPR:$Qm)))>;
375  }
376
377  // Predicated with intrinsic
378  def : Pat<(VTI.Vec !con((PredInt (VTI.Vec MQPR:$Qm), (VTI.Vec (ARMvdup rGPR:$Rn))),
379                          PredOperands,
380                          (? (VTI.Pred VCCR:$mask), (VTI.Vec MQPR:$inactive)))),
381            (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), rGPR:$Rn,
382                            ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
383                            (VTI.Vec MQPR:$inactive)))>;
384}
385
386// --------- Start of base classes for the instructions themselves
387
388class MVE_MI<dag oops, dag iops, InstrItinClass itin, string asm,
389             string ops, string cstr, bits<2> vecsize, list<dag> pattern>
390  : Thumb2XI<oops, iops, AddrModeNone, 4, itin, !strconcat(asm, "\t", ops), cstr,
391             pattern>,
392    Requires<[HasMVEInt]> {
393  let D = MVEDomain;
394  let DecoderNamespace = "MVE";
395  let VecSize = vecsize;
396}
397
398// MVE_p is used for most predicated instructions, to add the cluster
399// of input operands that provides the VPT suffix (none, T or E) and
400// the input predicate register.
401class MVE_p<dag oops, dag iops, InstrItinClass itin, string iname,
402            string suffix, string ops, vpred_ops vpred, string cstr,
403            bits<2> vecsize, list<dag> pattern=[]>
404  : MVE_MI<oops, !con(iops, (ins vpred:$vp)), itin,
405           // If the instruction has a suffix, like vadd.f32, then the
406           // VPT predication suffix goes before the dot, so the full
407           // name has to be "vadd${vp}.f32".
408           !strconcat(iname, "${vp}",
409                      !if(!eq(suffix, ""), "", !strconcat(".", suffix))),
410           ops, !strconcat(cstr, vpred.vpred_constraint), vecsize, pattern> {
411  let Inst{31-29} = 0b111;
412  let Inst{27-26} = 0b11;
413}
414
415class MVE_f<dag oops, dag iops, InstrItinClass itin, string iname,
416            string suffix, string ops, vpred_ops vpred, string cstr,
417            bits<2> vecsize, list<dag> pattern=[]>
418  : MVE_p<oops, iops, itin, iname, suffix, ops, vpred, cstr, vecsize, pattern> {
419  let Predicates = [HasMVEFloat];
420}
421
422class MVE_MI_with_pred<dag oops, dag iops, InstrItinClass itin, string asm,
423                       string ops, string cstr, list<dag> pattern>
424  : Thumb2I<oops, iops, AddrModeNone, 4, itin, asm, !strconcat("\t", ops), cstr,
425             pattern>,
426    Requires<[HasV8_1MMainline, HasMVEInt]> {
427  let D = MVEDomain;
428  let DecoderNamespace = "MVE";
429}
430
431class MVE_VMOV_lane_base<dag oops, dag iops, InstrItinClass itin, string asm,
432                         string suffix, string ops, string cstr,
433                         list<dag> pattern>
434  : Thumb2I<oops, iops, AddrModeNone, 4, itin, asm,
435            !if(!eq(suffix, ""), "", "." # suffix) # "\t" # ops,
436            cstr, pattern>,
437    Requires<[HasV8_1MMainline, HasMVEInt]> {
438  let D = MVEDomain;
439  let DecoderNamespace = "MVE";
440}
441
442class MVE_ScalarShift<string iname, dag oops, dag iops, string asm, string cstr,
443            list<dag> pattern=[]>
444  : MVE_MI_with_pred<oops, iops, NoItinerary, iname, asm, cstr, pattern> {
445  let Inst{31-20} = 0b111010100101;
446  let Inst{8} = 0b1;
447  let validForTailPredication=1;
448}
449
450class MVE_ScalarShiftSingleReg<string iname, dag iops, string asm, string cstr,
451                    list<dag> pattern=[]>
452  : MVE_ScalarShift<iname, (outs rGPR:$RdaDest), iops, asm, cstr, pattern> {
453  bits<4> RdaDest;
454
455  let Inst{19-16} = RdaDest{3-0};
456}
457
458class MVE_ScalarShiftSRegImm<string iname, bits<2> op5_4>
459  : MVE_ScalarShiftSingleReg<iname, (ins rGPR:$RdaSrc, long_shift:$imm),
460                     "$RdaSrc, $imm", "$RdaDest = $RdaSrc",
461                     [(set rGPR:$RdaDest,
462                          (i32 (!cast<Intrinsic>("int_arm_mve_" # iname)
463                                    (i32 rGPR:$RdaSrc), (i32 imm:$imm))))]> {
464  bits<5> imm;
465
466  let Inst{15} = 0b0;
467  let Inst{14-12} = imm{4-2};
468  let Inst{11-8} = 0b1111;
469  let Inst{7-6} = imm{1-0};
470  let Inst{5-4} = op5_4{1-0};
471  let Inst{3-0} = 0b1111;
472}
473
474def MVE_SQSHL : MVE_ScalarShiftSRegImm<"sqshl", 0b11>;
475def MVE_SRSHR : MVE_ScalarShiftSRegImm<"srshr", 0b10>;
476def MVE_UQSHL : MVE_ScalarShiftSRegImm<"uqshl", 0b00>;
477def MVE_URSHR : MVE_ScalarShiftSRegImm<"urshr", 0b01>;
478
479class MVE_ScalarShiftSRegReg<string iname, bits<2> op5_4>
480  : MVE_ScalarShiftSingleReg<iname, (ins rGPR:$RdaSrc, rGPR:$Rm),
481                     "$RdaSrc, $Rm", "$RdaDest = $RdaSrc",
482                     [(set rGPR:$RdaDest,
483                         (i32 (!cast<Intrinsic>("int_arm_mve_" # iname)
484                                   (i32 rGPR:$RdaSrc), (i32 rGPR:$Rm))))]> {
485  bits<4> Rm;
486
487  let Inst{15-12} = Rm{3-0};
488  let Inst{11-8} = 0b1111;
489  let Inst{7-6} = 0b00;
490  let Inst{5-4} = op5_4{1-0};
491  let Inst{3-0} = 0b1101;
492
493  let Unpredictable{8-6} = 0b111;
494}
495
496def MVE_SQRSHR : MVE_ScalarShiftSRegReg<"sqrshr", 0b10>;
497def MVE_UQRSHL : MVE_ScalarShiftSRegReg<"uqrshl", 0b00>;
498
499class MVE_ScalarShiftDoubleReg<string iname, dag iops, string asm,
500                               string cstr, list<dag> pattern=[]>
501  : MVE_ScalarShift<iname, (outs tGPREven:$RdaLo, tGPROdd:$RdaHi),
502                    iops, asm, cstr, pattern> {
503  bits<4> RdaLo;
504  bits<4> RdaHi;
505
506  let Inst{19-17} = RdaLo{3-1};
507  let Inst{11-9} = RdaHi{3-1};
508
509  let hasSideEffects = 0;
510}
511
512class MVE_ScalarShiftDRegImm<string iname, bits<2> op5_4, bit op16,
513                             list<dag> pattern=[]>
514  : MVE_ScalarShiftDoubleReg<
515      iname, (ins tGPREven:$RdaLo_src, tGPROdd:$RdaHi_src, long_shift:$imm),
516      "$RdaLo, $RdaHi, $imm", "$RdaLo = $RdaLo_src,$RdaHi = $RdaHi_src",
517      pattern> {
518  bits<5> imm;
519
520  let Inst{16} = op16;
521  let Inst{15} = 0b0;
522  let Inst{14-12} = imm{4-2};
523  let Inst{7-6} = imm{1-0};
524  let Inst{5-4} = op5_4{1-0};
525  let Inst{3-0} = 0b1111;
526}
527
528class MVE_ScalarShiftDRegRegBase<string iname, dag iops, string asm,
529                                 bit op5, bit op16, list<dag> pattern=[]>
530  : MVE_ScalarShiftDoubleReg<
531     iname, iops, asm, "@earlyclobber $RdaHi,@earlyclobber $RdaLo,"
532                       "$RdaLo = $RdaLo_src,$RdaHi = $RdaHi_src",
533     pattern> {
534  bits<4> Rm;
535
536  let Inst{16} = op16;
537  let Inst{15-12} = Rm{3-0};
538  let Inst{6} = 0b0;
539  let Inst{5} = op5;
540  let Inst{4} = 0b0;
541  let Inst{3-0} = 0b1101;
542
543  // Custom decoder method because of the following overlapping encodings:
544  // ASRL and SQRSHR
545  // LSLL and UQRSHL
546  // SQRSHRL and SQRSHR
547  // UQRSHLL and UQRSHL
548  let DecoderMethod = "DecodeMVEOverlappingLongShift";
549}
550
551class MVE_ScalarShiftDRegReg<string iname, bit op5, list<dag> pattern=[]>
552  : MVE_ScalarShiftDRegRegBase<
553     iname, (ins tGPREven:$RdaLo_src, tGPROdd:$RdaHi_src, rGPR:$Rm),
554     "$RdaLo, $RdaHi, $Rm", op5, 0b0, pattern> {
555
556  let Inst{7} = 0b0;
557}
558
559class MVE_ScalarShiftDRegRegWithSat<string iname, bit op5, list<dag> pattern=[]>
560  : MVE_ScalarShiftDRegRegBase<
561     iname, (ins tGPREven:$RdaLo_src, tGPROdd:$RdaHi_src, rGPR:$Rm, saturateop:$sat),
562     "$RdaLo, $RdaHi, $sat, $Rm", op5, 0b1, pattern> {
563  bit sat;
564
565  let Inst{7} = sat;
566}
567
568def MVE_ASRLr   : MVE_ScalarShiftDRegReg<"asrl",    0b1,  [(set tGPREven:$RdaLo, tGPROdd:$RdaHi,
569                                        (ARMasrl tGPREven:$RdaLo_src,
570                                        tGPROdd:$RdaHi_src, rGPR:$Rm))]>;
571def MVE_ASRLi   : MVE_ScalarShiftDRegImm<"asrl",    0b10, ?, [(set tGPREven:$RdaLo, tGPROdd:$RdaHi,
572                                        (ARMasrl tGPREven:$RdaLo_src,
573                                        tGPROdd:$RdaHi_src, (i32 long_shift:$imm)))]>;
574def MVE_LSLLr   : MVE_ScalarShiftDRegReg<"lsll",    0b0,  [(set tGPREven:$RdaLo, tGPROdd:$RdaHi,
575                                        (ARMlsll tGPREven:$RdaLo_src,
576                                        tGPROdd:$RdaHi_src, rGPR:$Rm))]>;
577def MVE_LSLLi   : MVE_ScalarShiftDRegImm<"lsll",    0b00, ?, [(set tGPREven:$RdaLo, tGPROdd:$RdaHi,
578                                        (ARMlsll tGPREven:$RdaLo_src,
579                                        tGPROdd:$RdaHi_src, (i32 long_shift:$imm)))]>;
580def MVE_LSRL    : MVE_ScalarShiftDRegImm<"lsrl",    0b01, ?, [(set tGPREven:$RdaLo, tGPROdd:$RdaHi,
581                                        (ARMlsrl tGPREven:$RdaLo_src,
582                                        tGPROdd:$RdaHi_src, (i32 long_shift:$imm)))]>;
583
584def MVE_SQRSHRL : MVE_ScalarShiftDRegRegWithSat<"sqrshrl", 0b1>;
585def MVE_SQSHLL  : MVE_ScalarShiftDRegImm<"sqshll",  0b11, 0b1>;
586def MVE_SRSHRL  : MVE_ScalarShiftDRegImm<"srshrl",  0b10, 0b1>;
587
588def MVE_UQRSHLL : MVE_ScalarShiftDRegRegWithSat<"uqrshll", 0b0>;
589def MVE_UQSHLL  : MVE_ScalarShiftDRegImm<"uqshll",  0b00, 0b1>;
590def MVE_URSHRL  : MVE_ScalarShiftDRegImm<"urshrl",  0b01, 0b1>;
591
592// start of mve_rDest instructions
593
594class MVE_rDest<dag oops, dag iops, InstrItinClass itin,
595                string iname, string suffix,
596                string ops, string cstr, bits<2> vecsize, list<dag> pattern=[]>
597// Always use vpred_n and not vpred_r: with the output register being
598// a GPR and not a vector register, there can't be any question of
599// what to put in its inactive lanes.
600  : MVE_p<oops, iops, itin, iname, suffix, ops, vpred_n, cstr, vecsize, pattern> {
601
602  let Inst{25-23} = 0b101;
603  let Inst{11-9} = 0b111;
604  let Inst{4} = 0b0;
605}
606
607class MVE_VABAV<string suffix, bit U, bits<2> size>
608  : MVE_rDest<(outs rGPR:$Rda), (ins rGPR:$Rda_src, MQPR:$Qn, MQPR:$Qm),
609              NoItinerary, "vabav", suffix, "$Rda, $Qn, $Qm", "$Rda = $Rda_src",
610              size, []> {
611  bits<4> Qm;
612  bits<4> Qn;
613  bits<4> Rda;
614
615  let Inst{28} = U;
616  let Inst{22} = 0b0;
617  let Inst{21-20} = size{1-0};
618  let Inst{19-17} = Qn{2-0};
619  let Inst{16} = 0b0;
620  let Inst{15-12} = Rda{3-0};
621  let Inst{8} = 0b1;
622  let Inst{7} = Qn{3};
623  let Inst{6} = 0b0;
624  let Inst{5} = Qm{3};
625  let Inst{3-1} = Qm{2-0};
626  let Inst{0} = 0b1;
627  let horizontalReduction = 1;
628}
629
630multiclass MVE_VABAV_m<MVEVectorVTInfo VTI> {
631  def "" : MVE_VABAV<VTI.Suffix, VTI.Unsigned, VTI.Size>;
632  defvar Inst = !cast<Instruction>(NAME);
633
634  let Predicates = [HasMVEInt] in {
635    def : Pat<(i32 (int_arm_mve_vabav
636                         (i32 VTI.Unsigned),
637                         (i32 rGPR:$Rda_src),
638                         (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm))),
639              (i32 (Inst (i32 rGPR:$Rda_src),
640                         (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm)))>;
641
642    def : Pat<(i32 (int_arm_mve_vabav_predicated
643                         (i32 VTI.Unsigned),
644                         (i32 rGPR:$Rda_src),
645                         (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
646                         (VTI.Pred VCCR:$mask))),
647              (i32 (Inst (i32 rGPR:$Rda_src),
648                         (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
649                         ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg))>;
650  }
651}
652
653defm MVE_VABAVs8  : MVE_VABAV_m<MVE_v16s8>;
654defm MVE_VABAVs16 : MVE_VABAV_m<MVE_v8s16>;
655defm MVE_VABAVs32 : MVE_VABAV_m<MVE_v4s32>;
656defm MVE_VABAVu8  : MVE_VABAV_m<MVE_v16u8>;
657defm MVE_VABAVu16 : MVE_VABAV_m<MVE_v8u16>;
658defm MVE_VABAVu32 : MVE_VABAV_m<MVE_v4u32>;
659
660class MVE_VADDV<string iname, string suffix, dag iops, string cstr,
661              bit A, bit U, bits<2> size, list<dag> pattern=[]>
662  : MVE_rDest<(outs tGPREven:$Rda), iops, NoItinerary,
663              iname, suffix, "$Rda, $Qm", cstr, size, pattern> {
664  bits<3> Qm;
665  bits<4> Rda;
666
667  let Inst{28} = U;
668  let Inst{22-20} = 0b111;
669  let Inst{19-18} = size{1-0};
670  let Inst{17-16} = 0b01;
671  let Inst{15-13} = Rda{3-1};
672  let Inst{12} = 0b0;
673  let Inst{8-6} = 0b100;
674  let Inst{5} = A;
675  let Inst{3-1} = Qm{2-0};
676  let Inst{0} = 0b0;
677  let horizontalReduction = 1;
678  let validForTailPredication = 1;
679}
680
681def SDTVecReduceP : SDTypeProfile<1, 2, [    // VADDLVp
682  SDTCisInt<0>, SDTCisVec<1>, SDTCisVec<2>
683]>;
684def ARMVADDVs       : SDNode<"ARMISD::VADDVs", SDTVecReduce>;
685def ARMVADDVu       : SDNode<"ARMISD::VADDVu", SDTVecReduce>;
686def ARMVADDVps      : SDNode<"ARMISD::VADDVps", SDTVecReduceP>;
687def ARMVADDVpu      : SDNode<"ARMISD::VADDVpu", SDTVecReduceP>;
688
689multiclass MVE_VADDV_A<MVEVectorVTInfo VTI> {
690  def acc    : MVE_VADDV<"vaddva", VTI.Suffix,
691                         (ins tGPREven:$Rda_src, MQPR:$Qm), "$Rda = $Rda_src",
692                         0b1, VTI.Unsigned, VTI.Size>;
693  def no_acc : MVE_VADDV<"vaddv", VTI.Suffix,
694                         (ins MQPR:$Qm), "",
695                         0b0, VTI.Unsigned, VTI.Size>;
696
697  defvar InstA = !cast<Instruction>(NAME # "acc");
698  defvar InstN = !cast<Instruction>(NAME # "no_acc");
699
700  let Predicates = [HasMVEInt] in {
701    if VTI.Unsigned then {
702      def : Pat<(i32 (vecreduce_add (VTI.Vec MQPR:$vec))),
703                (i32 (InstN $vec))>;
704      def : Pat<(i32 (vecreduce_add (VTI.Vec (vselect (VTI.Pred VCCR:$pred),
705                                                      (VTI.Vec MQPR:$vec),
706                                                      (VTI.Vec ARMimmAllZerosV))))),
707                (i32 (InstN $vec, ARMVCCThen, $pred, zero_reg))>;
708      def : Pat<(i32 (ARMVADDVu (VTI.Vec MQPR:$vec))),
709                (i32 (InstN $vec))>;
710      def : Pat<(i32 (ARMVADDVpu (VTI.Vec MQPR:$vec), (VTI.Pred VCCR:$pred))),
711                (i32 (InstN $vec, ARMVCCThen, $pred, zero_reg))>;
712      def : Pat<(i32 (add (i32 (vecreduce_add (VTI.Vec MQPR:$vec))),
713                          (i32 tGPREven:$acc))),
714                (i32 (InstA $acc, $vec))>;
715      def : Pat<(i32 (add (i32 (vecreduce_add (VTI.Vec (vselect (VTI.Pred VCCR:$pred),
716                                                                (VTI.Vec MQPR:$vec),
717                                                                (VTI.Vec ARMimmAllZerosV))))),
718                          (i32 tGPREven:$acc))),
719                (i32 (InstA $acc, $vec, ARMVCCThen, $pred, zero_reg))>;
720      def : Pat<(i32 (add (i32 (ARMVADDVu (VTI.Vec MQPR:$vec))),
721                          (i32 tGPREven:$acc))),
722                (i32 (InstA $acc, $vec))>;
723      def : Pat<(i32 (add (i32 (ARMVADDVpu (VTI.Vec MQPR:$vec), (VTI.Pred VCCR:$pred))),
724                          (i32 tGPREven:$acc))),
725                (i32 (InstA $acc, $vec, ARMVCCThen, $pred, zero_reg))>;
726    } else {
727      def : Pat<(i32 (ARMVADDVs (VTI.Vec MQPR:$vec))),
728                (i32 (InstN $vec))>;
729      def : Pat<(i32 (add (i32 (ARMVADDVs (VTI.Vec MQPR:$vec))),
730                          (i32 tGPREven:$acc))),
731                (i32 (InstA $acc, $vec))>;
732      def : Pat<(i32 (ARMVADDVps (VTI.Vec MQPR:$vec), (VTI.Pred VCCR:$pred))),
733                (i32 (InstN $vec, ARMVCCThen, $pred, zero_reg))>;
734      def : Pat<(i32 (add (i32 (ARMVADDVps (VTI.Vec MQPR:$vec), (VTI.Pred VCCR:$pred))),
735                          (i32 tGPREven:$acc))),
736                (i32 (InstA $acc, $vec, ARMVCCThen, $pred, zero_reg))>;
737    }
738
739    def : Pat<(i32 (int_arm_mve_addv_predicated (VTI.Vec MQPR:$vec),
740                                                (i32 VTI.Unsigned),
741                                                (VTI.Pred VCCR:$pred))),
742              (i32 (InstN $vec, ARMVCCThen, $pred, zero_reg))>;
743    def : Pat<(i32 (add (int_arm_mve_addv_predicated (VTI.Vec MQPR:$vec),
744                                                     (i32 VTI.Unsigned),
745                                                     (VTI.Pred VCCR:$pred)),
746                        (i32 tGPREven:$acc))),
747              (i32 (InstA $acc, $vec, ARMVCCThen, $pred, zero_reg))>;
748  }
749}
750
751defm MVE_VADDVs8  : MVE_VADDV_A<MVE_v16s8>;
752defm MVE_VADDVs16 : MVE_VADDV_A<MVE_v8s16>;
753defm MVE_VADDVs32 : MVE_VADDV_A<MVE_v4s32>;
754defm MVE_VADDVu8  : MVE_VADDV_A<MVE_v16u8>;
755defm MVE_VADDVu16 : MVE_VADDV_A<MVE_v8u16>;
756defm MVE_VADDVu32 : MVE_VADDV_A<MVE_v4u32>;
757
758class MVE_VADDLV<string iname, string suffix, dag iops, string cstr,
759               bit A, bit U, list<dag> pattern=[]>
760  : MVE_rDest<(outs tGPREven:$RdaLo, tGPROdd:$RdaHi), iops, NoItinerary, iname,
761              suffix, "$RdaLo, $RdaHi, $Qm", cstr, 0b10, pattern> {
762  bits<3> Qm;
763  bits<4> RdaLo;
764  bits<4> RdaHi;
765
766  let Inst{28} = U;
767  let Inst{22-20} = RdaHi{3-1};
768  let Inst{19-18} = 0b10;
769  let Inst{17-16} = 0b01;
770  let Inst{15-13} = RdaLo{3-1};
771  let Inst{12} = 0b0;
772  let Inst{8-6} = 0b100;
773  let Inst{5} = A;
774  let Inst{3-1} = Qm{2-0};
775  let Inst{0} = 0b0;
776  let horizontalReduction = 1;
777}
778
779def SDTVecReduceL : SDTypeProfile<2, 1, [    // VADDLV
780  SDTCisInt<0>, SDTCisInt<1>, SDTCisVec<2>
781]>;
782def SDTVecReduceLA : SDTypeProfile<2, 3, [    // VADDLVA
783  SDTCisInt<0>, SDTCisInt<1>, SDTCisInt<2>, SDTCisInt<3>,
784  SDTCisVec<4>
785]>;
786def SDTVecReduceLP : SDTypeProfile<2, 2, [    // VADDLVp
787  SDTCisInt<0>, SDTCisInt<1>, SDTCisVec<2>, SDTCisVec<2>
788]>;
789def SDTVecReduceLPA : SDTypeProfile<2, 4, [    // VADDLVAp
790  SDTCisInt<0>, SDTCisInt<1>, SDTCisInt<2>, SDTCisInt<3>,
791  SDTCisVec<4>, SDTCisVec<5>
792]>;
793
794multiclass MVE_VADDLV_A<MVEVectorVTInfo VTI> {
795  def acc    : MVE_VADDLV<"vaddlva", VTI.Suffix,
796                        (ins tGPREven:$RdaLo_src, tGPROdd:$RdaHi_src, MQPR:$Qm),
797                        "$RdaLo = $RdaLo_src,$RdaHi = $RdaHi_src",
798                        0b1, VTI.Unsigned>;
799  def no_acc : MVE_VADDLV<"vaddlv", VTI.Suffix,
800                        (ins MQPR:$Qm), "",
801                        0b0, VTI.Unsigned>;
802
803  defvar InstA = !cast<Instruction>(NAME # "acc");
804  defvar InstN = !cast<Instruction>(NAME # "no_acc");
805
806  defvar letter = VTI.SuffixLetter;
807  defvar ARMVADDLV = SDNode<"ARMISD::VADDLV" # letter, SDTVecReduceL>;
808  defvar ARMVADDLVA = SDNode<"ARMISD::VADDLVA" # letter, SDTVecReduceLA>;
809  defvar ARMVADDLVp = SDNode<"ARMISD::VADDLVp" # letter, SDTVecReduceLP>;
810  defvar ARMVADDLVAp = SDNode<"ARMISD::VADDLVAp" # letter, SDTVecReduceLPA>;
811
812  let Predicates = [HasMVEInt] in {
813    def : Pat<(ARMVADDLV (v4i32 MQPR:$vec)),
814              (InstN (v4i32 MQPR:$vec))>;
815    def : Pat<(ARMVADDLVA tGPREven:$acclo, tGPROdd:$acchi, (v4i32 MQPR:$vec)),
816              (InstA tGPREven:$acclo, tGPROdd:$acchi, (v4i32 MQPR:$vec))>;
817    def : Pat<(ARMVADDLVp (v4i32 MQPR:$vec), (VTI.Pred VCCR:$pred)),
818              (InstN (v4i32 MQPR:$vec), ARMVCCThen, (VTI.Pred VCCR:$pred), zero_reg)>;
819    def : Pat<(ARMVADDLVAp tGPREven:$acclo, tGPROdd:$acchi, (v4i32 MQPR:$vec),
820                           (VTI.Pred VCCR:$pred)),
821              (InstA tGPREven:$acclo, tGPROdd:$acchi, (v4i32 MQPR:$vec),
822                     ARMVCCThen, (VTI.Pred VCCR:$pred), zero_reg)>;
823  }
824}
825
826defm MVE_VADDLVs32 : MVE_VADDLV_A<MVE_v4s32>;
827defm MVE_VADDLVu32 : MVE_VADDLV_A<MVE_v4u32>;
828
829class MVE_VMINMAXNMV<string iname, string suffix, bit sz,
830                     bit bit_17, bit bit_7, list<dag> pattern=[]>
831  : MVE_rDest<(outs rGPR:$RdaDest), (ins rGPR:$RdaSrc, MQPR:$Qm),
832              NoItinerary, iname, suffix, "$RdaSrc, $Qm",
833              "$RdaDest = $RdaSrc", !if(sz, 0b01, 0b10), pattern> {
834  bits<3> Qm;
835  bits<4> RdaDest;
836
837  let Inst{28} = sz;
838  let Inst{22-20} = 0b110;
839  let Inst{19-18} = 0b11;
840  let Inst{17} = bit_17;
841  let Inst{16} = 0b0;
842  let Inst{15-12} = RdaDest{3-0};
843  let Inst{8} = 0b1;
844  let Inst{7} = bit_7;
845  let Inst{6-5} = 0b00;
846  let Inst{3-1} = Qm{2-0};
847  let Inst{0} = 0b0;
848  let horizontalReduction = 1;
849
850  let Predicates = [HasMVEFloat];
851  let hasSideEffects = 0;
852}
853
854multiclass MVE_VMINMAXNMV_p<string iname, bit notAbs, bit isMin,
855                            MVEVectorVTInfo VTI, string intrBaseName,
856                            ValueType Scalar, RegisterClass ScalarReg> {
857  def "": MVE_VMINMAXNMV<iname, VTI.Suffix, VTI.Size{0}, notAbs, isMin>;
858  defvar Inst        = !cast<Instruction>(NAME);
859  defvar unpred_intr = !cast<Intrinsic>(intrBaseName);
860  defvar pred_intr   = !cast<Intrinsic>(intrBaseName#"_predicated");
861
862  let Predicates = [HasMVEFloat] in {
863    def : Pat<(Scalar (unpred_intr (Scalar ScalarReg:$prev),
864                                   (VTI.Vec MQPR:$vec))),
865           (COPY_TO_REGCLASS (Inst (COPY_TO_REGCLASS ScalarReg:$prev, rGPR),
866                                   (VTI.Vec MQPR:$vec)),
867                              ScalarReg)>;
868    def : Pat<(Scalar (pred_intr   (Scalar ScalarReg:$prev),
869                                   (VTI.Vec MQPR:$vec),
870                                   (VTI.Pred VCCR:$pred))),
871           (COPY_TO_REGCLASS (Inst (COPY_TO_REGCLASS ScalarReg:$prev, rGPR),
872                                   (VTI.Vec MQPR:$vec),
873                                   ARMVCCThen, (VTI.Pred VCCR:$pred), zero_reg),
874                              ScalarReg)>;
875  }
876}
877
878multiclass MVE_VMINMAXNMV_fty<string iname, bit notAbs, bit isMin,
879                              string intrBase> {
880  defm f32 : MVE_VMINMAXNMV_p<iname, notAbs, isMin, MVE_v4f32, intrBase,
881                              f32, SPR>;
882  defm f16 : MVE_VMINMAXNMV_p<iname, notAbs, isMin, MVE_v8f16, intrBase,
883                              f16, HPR>;
884}
885
886defm MVE_VMINNMV : MVE_VMINMAXNMV_fty<"vminnmv",  1, 1, "int_arm_mve_minnmv">;
887defm MVE_VMAXNMV : MVE_VMINMAXNMV_fty<"vmaxnmv",  1, 0, "int_arm_mve_maxnmv">;
888defm MVE_VMINNMAV: MVE_VMINMAXNMV_fty<"vminnmav", 0, 1, "int_arm_mve_minnmav">;
889defm MVE_VMAXNMAV: MVE_VMINMAXNMV_fty<"vmaxnmav", 0, 0, "int_arm_mve_maxnmav">;
890
891class MVE_VMINMAXV<string iname, string suffix, bit U, bits<2> size,
892                 bit bit_17, bit bit_7, list<dag> pattern=[]>
893  : MVE_rDest<(outs rGPR:$RdaDest), (ins rGPR:$RdaSrc, MQPR:$Qm), NoItinerary,
894              iname, suffix, "$RdaSrc, $Qm", "$RdaDest = $RdaSrc", size, pattern> {
895  bits<3> Qm;
896  bits<4> RdaDest;
897
898  let Inst{28} = U;
899  let Inst{22-20} = 0b110;
900  let Inst{19-18} = size{1-0};
901  let Inst{17} = bit_17;
902  let Inst{16} = 0b0;
903  let Inst{15-12} = RdaDest{3-0};
904  let Inst{8} = 0b1;
905  let Inst{7} = bit_7;
906  let Inst{6-5} = 0b00;
907  let Inst{3-1} = Qm{2-0};
908  let Inst{0} = 0b0;
909  let horizontalReduction = 1;
910}
911
912multiclass MVE_VMINMAXV_p<string iname, bit notAbs, bit isMin,
913                          MVEVectorVTInfo VTI, string intrBaseName> {
914  def "": MVE_VMINMAXV<iname, VTI.Suffix, VTI.Unsigned, VTI.Size,
915                       notAbs, isMin>;
916  defvar Inst        = !cast<Instruction>(NAME);
917  defvar unpred_intr = !cast<Intrinsic>(intrBaseName);
918  defvar pred_intr   = !cast<Intrinsic>(intrBaseName#"_predicated");
919  defvar base_args   = (? (i32 rGPR:$prev), (VTI.Vec MQPR:$vec));
920  defvar args        = !if(notAbs, !con(base_args, (? (i32 VTI.Unsigned))),
921                           base_args);
922
923  let Predicates = [HasMVEInt] in {
924    def : Pat<(i32 !con(args, (unpred_intr))),
925              (i32 (Inst (i32 rGPR:$prev), (VTI.Vec MQPR:$vec)))>;
926    def : Pat<(i32 !con(args, (pred_intr (VTI.Pred VCCR:$pred)))),
927              (i32 (Inst (i32 rGPR:$prev), (VTI.Vec MQPR:$vec),
928                         ARMVCCThen, (VTI.Pred VCCR:$pred), zero_reg))>;
929  }
930}
931
932multiclass MVE_VMINMAXV_ty<string iname, bit isMin, string intrBaseName> {
933  defm s8 : MVE_VMINMAXV_p<iname, 1, isMin, MVE_v16s8, intrBaseName>;
934  defm s16: MVE_VMINMAXV_p<iname, 1, isMin, MVE_v8s16, intrBaseName>;
935  defm s32: MVE_VMINMAXV_p<iname, 1, isMin, MVE_v4s32, intrBaseName>;
936  defm u8 : MVE_VMINMAXV_p<iname, 1, isMin, MVE_v16u8, intrBaseName>;
937  defm u16: MVE_VMINMAXV_p<iname, 1, isMin, MVE_v8u16, intrBaseName>;
938  defm u32: MVE_VMINMAXV_p<iname, 1, isMin, MVE_v4u32, intrBaseName>;
939}
940
941def SDTVecReduceR : SDTypeProfile<1, 2, [   // Reduction of an integer and vector into an integer
942  SDTCisInt<0>, SDTCisInt<1>, SDTCisVec<2>
943]>;
944def ARMVMINVu       : SDNode<"ARMISD::VMINVu", SDTVecReduceR>;
945def ARMVMINVs       : SDNode<"ARMISD::VMINVs", SDTVecReduceR>;
946def ARMVMAXVu       : SDNode<"ARMISD::VMAXVu", SDTVecReduceR>;
947def ARMVMAXVs       : SDNode<"ARMISD::VMAXVs", SDTVecReduceR>;
948
949defm MVE_VMINV : MVE_VMINMAXV_ty<"vminv", 1, "int_arm_mve_minv">;
950defm MVE_VMAXV : MVE_VMINMAXV_ty<"vmaxv", 0, "int_arm_mve_maxv">;
951
952let Predicates = [HasMVEInt] in {
953  def : Pat<(i32 (vecreduce_smax (v16i8 MQPR:$src))),
954            (i32 (MVE_VMAXVs8 (t2MVNi (i32 127)), $src))>;
955  def : Pat<(i32 (vecreduce_smax (v8i16 MQPR:$src))),
956            (i32 (MVE_VMAXVs16 (t2MOVi32imm (i32 -32768)), $src))>;
957  def : Pat<(i32 (vecreduce_smax (v4i32 MQPR:$src))),
958            (i32 (MVE_VMAXVs32 (t2MOVi (i32 -2147483648)), $src))>;
959  def : Pat<(i32 (vecreduce_umax (v16i8 MQPR:$src))),
960            (i32 (MVE_VMAXVu8 (t2MOVi (i32 0)), $src))>;
961  def : Pat<(i32 (vecreduce_umax (v8i16 MQPR:$src))),
962            (i32 (MVE_VMAXVu16 (t2MOVi (i32 0)), $src))>;
963  def : Pat<(i32 (vecreduce_umax (v4i32 MQPR:$src))),
964            (i32 (MVE_VMAXVu32 (t2MOVi (i32 0)), $src))>;
965
966  def : Pat<(i32 (vecreduce_smin (v16i8 MQPR:$src))),
967            (i32 (MVE_VMINVs8 (t2MOVi (i32 127)), $src))>;
968  def : Pat<(i32 (vecreduce_smin (v8i16 MQPR:$src))),
969            (i32 (MVE_VMINVs16 (t2MOVi16 (i32 32767)), $src))>;
970  def : Pat<(i32 (vecreduce_smin (v4i32 MQPR:$src))),
971            (i32 (MVE_VMINVs32 (t2MVNi (i32 -2147483648)), $src))>;
972  def : Pat<(i32 (vecreduce_umin (v16i8 MQPR:$src))),
973            (i32 (MVE_VMINVu8 (t2MOVi (i32 255)), $src))>;
974  def : Pat<(i32 (vecreduce_umin (v8i16 MQPR:$src))),
975            (i32 (MVE_VMINVu16 (t2MOVi16 (i32 65535)), $src))>;
976  def : Pat<(i32 (vecreduce_umin (v4i32 MQPR:$src))),
977            (i32 (MVE_VMINVu32 (t2MOVi (i32 4294967295)), $src))>;
978
979  def : Pat<(i32 (ARMVMINVu (i32 rGPR:$x), (v16i8 MQPR:$src))),
980            (i32 (MVE_VMINVu8 $x, $src))>;
981  def : Pat<(i32 (ARMVMINVu (i32 rGPR:$x), (v8i16 MQPR:$src))),
982            (i32 (MVE_VMINVu16 $x, $src))>;
983  def : Pat<(i32 (ARMVMINVu (i32 rGPR:$x), (v4i32 MQPR:$src))),
984            (i32 (MVE_VMINVu32 $x, $src))>;
985  def : Pat<(i32 (ARMVMINVs (i32 rGPR:$x), (v16i8 MQPR:$src))),
986            (i32 (MVE_VMINVs8 $x, $src))>;
987  def : Pat<(i32 (ARMVMINVs (i32 rGPR:$x), (v8i16 MQPR:$src))),
988            (i32 (MVE_VMINVs16 $x, $src))>;
989  def : Pat<(i32 (ARMVMINVs (i32 rGPR:$x), (v4i32 MQPR:$src))),
990            (i32 (MVE_VMINVs32 $x, $src))>;
991
992  def : Pat<(i32 (ARMVMAXVu (i32 rGPR:$x), (v16i8 MQPR:$src))),
993            (i32 (MVE_VMAXVu8 $x, $src))>;
994  def : Pat<(i32 (ARMVMAXVu (i32 rGPR:$x), (v8i16 MQPR:$src))),
995            (i32 (MVE_VMAXVu16 $x, $src))>;
996  def : Pat<(i32 (ARMVMAXVu (i32 rGPR:$x), (v4i32 MQPR:$src))),
997            (i32 (MVE_VMAXVu32 $x, $src))>;
998  def : Pat<(i32 (ARMVMAXVs (i32 rGPR:$x), (v16i8 MQPR:$src))),
999            (i32 (MVE_VMAXVs8 $x, $src))>;
1000  def : Pat<(i32 (ARMVMAXVs (i32 rGPR:$x), (v8i16 MQPR:$src))),
1001            (i32 (MVE_VMAXVs16 $x, $src))>;
1002  def : Pat<(i32 (ARMVMAXVs (i32 rGPR:$x), (v4i32 MQPR:$src))),
1003            (i32 (MVE_VMAXVs32 $x, $src))>;
1004
1005}
1006
1007multiclass MVE_VMINMAXAV_ty<string iname, bit isMin, string intrBaseName> {
1008  defm s8 : MVE_VMINMAXV_p<iname, 0, isMin, MVE_v16s8, intrBaseName>;
1009  defm s16: MVE_VMINMAXV_p<iname, 0, isMin, MVE_v8s16, intrBaseName>;
1010  defm s32: MVE_VMINMAXV_p<iname, 0, isMin, MVE_v4s32, intrBaseName>;
1011}
1012
1013defm MVE_VMINAV : MVE_VMINMAXAV_ty<"vminav", 1, "int_arm_mve_minav">;
1014defm MVE_VMAXAV : MVE_VMINMAXAV_ty<"vmaxav", 0, "int_arm_mve_maxav">;
1015
1016class MVE_VMLAMLSDAV<string iname, string suffix, dag iops, string cstr,
1017                   bit sz, bit bit_28, bit A, bit X, bit bit_8, bit bit_0,
1018                   bits<2> vecsize>
1019  : MVE_rDest<(outs tGPREven:$RdaDest), iops, NoItinerary, iname, suffix,
1020              "$RdaDest, $Qn, $Qm", cstr, vecsize, []> {
1021  bits<4> RdaDest;
1022  bits<3> Qm;
1023  bits<3> Qn;
1024
1025  let Inst{28} = bit_28;
1026  let Inst{22-20} = 0b111;
1027  let Inst{19-17} = Qn{2-0};
1028  let Inst{16} = sz;
1029  let Inst{15-13} = RdaDest{3-1};
1030  let Inst{12} = X;
1031  let Inst{8} = bit_8;
1032  let Inst{7-6} = 0b00;
1033  let Inst{5} = A;
1034  let Inst{3-1} = Qm{2-0};
1035  let Inst{0} = bit_0;
1036  let horizontalReduction = 1;
1037  // Allow tail predication for non-exchanging versions. As this is also a
1038  // horizontalReduction, ARMLowOverheadLoops will also have to check that
1039  // the vector operands contain zeros in their false lanes for the instruction
1040  // to be properly valid.
1041  let validForTailPredication = !eq(X, 0);
1042}
1043
1044multiclass MVE_VMLAMLSDAV_A<string iname, string x, MVEVectorVTInfo VTI,
1045                            bit sz, bit bit_28, bit X, bit bit_8, bit bit_0> {
1046  def ""#x#VTI.Suffix : MVE_VMLAMLSDAV<iname # x, VTI.Suffix,
1047                                   (ins MQPR:$Qn, MQPR:$Qm), "",
1048                                   sz, bit_28, 0b0, X, bit_8, bit_0, VTI.Size>;
1049  def "a"#x#VTI.Suffix : MVE_VMLAMLSDAV<iname # "a" # x, VTI.Suffix,
1050                                    (ins tGPREven:$RdaSrc, MQPR:$Qn, MQPR:$Qm),
1051                                    "$RdaDest = $RdaSrc",
1052                                    sz, bit_28, 0b1, X, bit_8, bit_0, VTI.Size>;
1053  let Predicates = [HasMVEInt] in {
1054    def : Pat<(i32 (int_arm_mve_vmldava
1055                            (i32 VTI.Unsigned),
1056                            (i32 bit_0) /* subtract */,
1057                            (i32 X) /* exchange */,
1058                            (i32 0) /* accumulator */,
1059                            (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm))),
1060              (i32 (!cast<Instruction>(NAME # x # VTI.Suffix)
1061                            (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm)))>;
1062
1063    def : Pat<(i32 (int_arm_mve_vmldava_predicated
1064                            (i32 VTI.Unsigned),
1065                            (i32 bit_0) /* subtract */,
1066                            (i32 X) /* exchange */,
1067                            (i32 0) /* accumulator */,
1068                            (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
1069                            (VTI.Pred VCCR:$mask))),
1070              (i32 (!cast<Instruction>(NAME # x # VTI.Suffix)
1071                            (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
1072                             ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg))>;
1073
1074    def : Pat<(i32 (int_arm_mve_vmldava
1075                            (i32 VTI.Unsigned),
1076                            (i32 bit_0) /* subtract */,
1077                            (i32 X) /* exchange */,
1078                            (i32 tGPREven:$RdaSrc),
1079                            (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm))),
1080              (i32 (!cast<Instruction>(NAME # "a" # x # VTI.Suffix)
1081                            (i32 tGPREven:$RdaSrc),
1082                            (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm)))>;
1083
1084    def : Pat<(i32 (int_arm_mve_vmldava_predicated
1085                            (i32 VTI.Unsigned),
1086                            (i32 bit_0) /* subtract */,
1087                            (i32 X) /* exchange */,
1088                            (i32 tGPREven:$RdaSrc),
1089                            (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
1090                            (VTI.Pred VCCR:$mask))),
1091              (i32 (!cast<Instruction>(NAME # "a" # x # VTI.Suffix)
1092                            (i32 tGPREven:$RdaSrc),
1093                            (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
1094                             ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg))>;
1095  }
1096}
1097
1098multiclass MVE_VMLAMLSDAV_AX<string iname, MVEVectorVTInfo VTI, bit sz,
1099                             bit bit_28, bit bit_8, bit bit_0> {
1100  defm "" : MVE_VMLAMLSDAV_A<iname, "", VTI, sz, bit_28,
1101                             0b0, bit_8, bit_0>;
1102  defm "" : MVE_VMLAMLSDAV_A<iname, "x", VTI, sz, bit_28,
1103                             0b1, bit_8, bit_0>;
1104}
1105
1106multiclass MVE_VMLADAV_multi<MVEVectorVTInfo SVTI, MVEVectorVTInfo UVTI,
1107                             bit sz, bit bit_8> {
1108  defm "" : MVE_VMLAMLSDAV_AX<"vmladav", SVTI,
1109                              sz, 0b0, bit_8, 0b0>;
1110  defm "" : MVE_VMLAMLSDAV_A<"vmladav", "", UVTI,
1111                             sz, 0b1, 0b0, bit_8, 0b0>;
1112}
1113
1114multiclass MVE_VMLSDAV_multi<MVEVectorVTInfo VTI, bit sz, bit bit_28> {
1115  defm "" : MVE_VMLAMLSDAV_AX<"vmlsdav", VTI,
1116                              sz, bit_28, 0b0, 0b1>;
1117}
1118
1119defm MVE_VMLADAV : MVE_VMLADAV_multi<MVE_v16s8, MVE_v16u8, 0b0, 0b1>;
1120defm MVE_VMLADAV : MVE_VMLADAV_multi<MVE_v8s16, MVE_v8u16, 0b0, 0b0>;
1121defm MVE_VMLADAV : MVE_VMLADAV_multi<MVE_v4s32, MVE_v4u32, 0b1, 0b0>;
1122
1123defm MVE_VMLSDAV : MVE_VMLSDAV_multi<MVE_v16s8, 0b0, 0b1>;
1124defm MVE_VMLSDAV : MVE_VMLSDAV_multi<MVE_v8s16, 0b0, 0b0>;
1125defm MVE_VMLSDAV : MVE_VMLSDAV_multi<MVE_v4s32, 0b1, 0b0>;
1126
1127def SDTVecReduce2 : SDTypeProfile<1, 2, [    // VMLAV
1128  SDTCisInt<0>, SDTCisVec<1>, SDTCisVec<2>
1129]>;
1130def SDTVecReduce2L : SDTypeProfile<2, 2, [    // VMLALV
1131  SDTCisInt<0>, SDTCisInt<1>, SDTCisVec<2>, SDTCisVec<3>
1132]>;
1133def SDTVecReduce2LA : SDTypeProfile<2, 4, [    // VMLALVA
1134  SDTCisInt<0>, SDTCisInt<1>, SDTCisInt<2>, SDTCisInt<3>,
1135  SDTCisVec<4>, SDTCisVec<5>
1136]>;
1137def SDTVecReduce2P : SDTypeProfile<1, 3, [    // VMLAV
1138  SDTCisInt<0>, SDTCisVec<1>, SDTCisVec<2>, SDTCisVec<3>
1139]>;
1140def SDTVecReduce2LP : SDTypeProfile<2, 3, [    // VMLALV
1141  SDTCisInt<0>, SDTCisInt<1>, SDTCisVec<2>, SDTCisVec<3>, SDTCisVec<4>
1142]>;
1143def SDTVecReduce2LAP : SDTypeProfile<2, 5, [    // VMLALVA
1144  SDTCisInt<0>, SDTCisInt<1>, SDTCisInt<2>, SDTCisInt<3>,
1145  SDTCisVec<4>, SDTCisVec<5>, SDTCisVec<6>
1146]>;
1147def ARMVMLAVs       : SDNode<"ARMISD::VMLAVs", SDTVecReduce2>;
1148def ARMVMLAVu       : SDNode<"ARMISD::VMLAVu", SDTVecReduce2>;
1149def ARMVMLALVs      : SDNode<"ARMISD::VMLALVs", SDTVecReduce2L>;
1150def ARMVMLALVu      : SDNode<"ARMISD::VMLALVu", SDTVecReduce2L>;
1151def ARMVMLALVAs     : SDNode<"ARMISD::VMLALVAs", SDTVecReduce2LA>;
1152def ARMVMLALVAu     : SDNode<"ARMISD::VMLALVAu", SDTVecReduce2LA>;
1153def ARMVMLAVps      : SDNode<"ARMISD::VMLAVps", SDTVecReduce2P>;
1154def ARMVMLAVpu      : SDNode<"ARMISD::VMLAVpu", SDTVecReduce2P>;
1155def ARMVMLALVps     : SDNode<"ARMISD::VMLALVps", SDTVecReduce2LP>;
1156def ARMVMLALVpu     : SDNode<"ARMISD::VMLALVpu", SDTVecReduce2LP>;
1157def ARMVMLALVAps    : SDNode<"ARMISD::VMLALVAps", SDTVecReduce2LAP>;
1158def ARMVMLALVApu    : SDNode<"ARMISD::VMLALVApu", SDTVecReduce2LAP>;
1159
1160let Predicates = [HasMVEInt] in {
1161  def : Pat<(i32 (vecreduce_add (mul (v4i32 MQPR:$src1), (v4i32 MQPR:$src2)))),
1162            (i32 (MVE_VMLADAVu32 $src1, $src2))>;
1163  def : Pat<(i32 (vecreduce_add (mul (v8i16 MQPR:$src1), (v8i16 MQPR:$src2)))),
1164            (i32 (MVE_VMLADAVu16 $src1, $src2))>;
1165  def : Pat<(i32 (ARMVMLAVs (v8i16 MQPR:$val1), (v8i16 MQPR:$val2))),
1166            (i32 (MVE_VMLADAVs16 (v8i16 MQPR:$val1), (v8i16 MQPR:$val2)))>;
1167  def : Pat<(i32 (ARMVMLAVu (v8i16 MQPR:$val1), (v8i16 MQPR:$val2))),
1168            (i32 (MVE_VMLADAVu16 (v8i16 MQPR:$val1), (v8i16 MQPR:$val2)))>;
1169  def : Pat<(i32 (vecreduce_add (mul (v16i8 MQPR:$src1), (v16i8 MQPR:$src2)))),
1170            (i32 (MVE_VMLADAVu8 $src1, $src2))>;
1171  def : Pat<(i32 (ARMVMLAVs (v16i8 MQPR:$val1), (v16i8 MQPR:$val2))),
1172            (i32 (MVE_VMLADAVs8 (v16i8 MQPR:$val1), (v16i8 MQPR:$val2)))>;
1173  def : Pat<(i32 (ARMVMLAVu (v16i8 MQPR:$val1), (v16i8 MQPR:$val2))),
1174            (i32 (MVE_VMLADAVu8 (v16i8 MQPR:$val1), (v16i8 MQPR:$val2)))>;
1175
1176  def : Pat<(i32 (add (i32 (vecreduce_add (mul (v4i32 MQPR:$src1), (v4i32 MQPR:$src2)))),
1177                      (i32 tGPREven:$src3))),
1178            (i32 (MVE_VMLADAVau32 $src3, $src1, $src2))>;
1179  def : Pat<(i32 (add (i32 (vecreduce_add (mul (v8i16 MQPR:$src1), (v8i16 MQPR:$src2)))),
1180                      (i32 tGPREven:$src3))),
1181            (i32 (MVE_VMLADAVau16 $src3, $src1, $src2))>;
1182  def : Pat<(i32 (add (ARMVMLAVs (v8i16 MQPR:$val1), (v8i16 MQPR:$val2)), tGPREven:$Rd)),
1183            (i32 (MVE_VMLADAVas16 tGPREven:$Rd, (v8i16 MQPR:$val1), (v8i16 MQPR:$val2)))>;
1184  def : Pat<(i32 (add (ARMVMLAVu (v8i16 MQPR:$val1), (v8i16 MQPR:$val2)), tGPREven:$Rd)),
1185            (i32 (MVE_VMLADAVau16 tGPREven:$Rd, (v8i16 MQPR:$val1), (v8i16 MQPR:$val2)))>;
1186  def : Pat<(i32 (add (i32 (vecreduce_add (mul (v16i8 MQPR:$src1), (v16i8 MQPR:$src2)))),
1187                      (i32 tGPREven:$src3))),
1188            (i32 (MVE_VMLADAVau8 $src3, $src1, $src2))>;
1189  def : Pat<(i32 (add (ARMVMLAVs (v16i8 MQPR:$val1), (v16i8 MQPR:$val2)), tGPREven:$Rd)),
1190            (i32 (MVE_VMLADAVas8 tGPREven:$Rd, (v16i8 MQPR:$val1), (v16i8 MQPR:$val2)))>;
1191  def : Pat<(i32 (add (ARMVMLAVu (v16i8 MQPR:$val1), (v16i8 MQPR:$val2)), tGPREven:$Rd)),
1192            (i32 (MVE_VMLADAVau8 tGPREven:$Rd, (v16i8 MQPR:$val1), (v16i8 MQPR:$val2)))>;
1193
1194  // Predicated
1195  def : Pat<(i32 (vecreduce_add (vselect (v4i1 VCCR:$pred),
1196                                         (mul (v4i32 MQPR:$src1), (v4i32 MQPR:$src2)),
1197                                         (v4i32 ARMimmAllZerosV)))),
1198            (i32 (MVE_VMLADAVu32 $src1, $src2, ARMVCCThen, $pred, zero_reg))>;
1199  def : Pat<(i32 (vecreduce_add (vselect (v8i1 VCCR:$pred),
1200                                         (mul (v8i16 MQPR:$src1), (v8i16 MQPR:$src2)),
1201                                         (v8i16 ARMimmAllZerosV)))),
1202            (i32 (MVE_VMLADAVu16 $src1, $src2, ARMVCCThen, $pred, zero_reg))>;
1203  def : Pat<(i32 (ARMVMLAVps (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), (v8i1 VCCR:$pred))),
1204            (i32 (MVE_VMLADAVs16 (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), ARMVCCThen, $pred, zero_reg))>;
1205  def : Pat<(i32 (ARMVMLAVpu (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), (v8i1 VCCR:$pred))),
1206            (i32 (MVE_VMLADAVu16 (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), ARMVCCThen, $pred, zero_reg))>;
1207  def : Pat<(i32 (vecreduce_add (vselect (v16i1 VCCR:$pred),
1208                                         (mul (v16i8 MQPR:$src1), (v16i8 MQPR:$src2)),
1209                                         (v16i8 ARMimmAllZerosV)))),
1210            (i32 (MVE_VMLADAVu8 $src1, $src2, ARMVCCThen, $pred, zero_reg))>;
1211  def : Pat<(i32 (ARMVMLAVps (v16i8 MQPR:$val1), (v16i8 MQPR:$val2), (v16i1 VCCR:$pred))),
1212            (i32 (MVE_VMLADAVs8 (v16i8 MQPR:$val1), (v16i8 MQPR:$val2), ARMVCCThen, $pred, zero_reg))>;
1213  def : Pat<(i32 (ARMVMLAVpu (v16i8 MQPR:$val1), (v16i8 MQPR:$val2), (v16i1 VCCR:$pred))),
1214            (i32 (MVE_VMLADAVu8 (v16i8 MQPR:$val1), (v16i8 MQPR:$val2), ARMVCCThen, $pred, zero_reg))>;
1215
1216  def : Pat<(i32 (add (i32 (vecreduce_add (vselect (v4i1 VCCR:$pred),
1217                                                   (mul (v4i32 MQPR:$src1), (v4i32 MQPR:$src2)),
1218                                                   (v4i32 ARMimmAllZerosV)))),
1219                      (i32 tGPREven:$src3))),
1220            (i32 (MVE_VMLADAVau32 $src3, $src1, $src2, ARMVCCThen, $pred, zero_reg))>;
1221  def : Pat<(i32 (add (i32 (vecreduce_add (vselect (v8i1 VCCR:$pred),
1222                                                   (mul (v8i16 MQPR:$src1), (v8i16 MQPR:$src2)),
1223                                                   (v8i16 ARMimmAllZerosV)))),
1224                      (i32 tGPREven:$src3))),
1225            (i32 (MVE_VMLADAVau16 $src3, $src1, $src2, ARMVCCThen, $pred, zero_reg))>;
1226  def : Pat<(i32 (add (ARMVMLAVps (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), (v8i1 VCCR:$pred)), tGPREven:$Rd)),
1227            (i32 (MVE_VMLADAVas16 tGPREven:$Rd, (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), ARMVCCThen, $pred, zero_reg))>;
1228  def : Pat<(i32 (add (ARMVMLAVpu (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), (v8i1 VCCR:$pred)), tGPREven:$Rd)),
1229            (i32 (MVE_VMLADAVau16 tGPREven:$Rd, (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), ARMVCCThen, $pred, zero_reg))>;
1230  def : Pat<(i32 (add (i32 (vecreduce_add (vselect (v16i1 VCCR:$pred),
1231                                                   (mul (v16i8 MQPR:$src1), (v16i8 MQPR:$src2)),
1232                                                   (v16i8 ARMimmAllZerosV)))),
1233                      (i32 tGPREven:$src3))),
1234            (i32 (MVE_VMLADAVau8 $src3, $src1, $src2, ARMVCCThen, $pred, zero_reg))>;
1235  def : Pat<(i32 (add (ARMVMLAVps (v16i8 MQPR:$val1), (v16i8 MQPR:$val2), (v16i1 VCCR:$pred)), tGPREven:$Rd)),
1236            (i32 (MVE_VMLADAVas8 tGPREven:$Rd, (v16i8 MQPR:$val1), (v16i8 MQPR:$val2), ARMVCCThen, $pred, zero_reg))>;
1237  def : Pat<(i32 (add (ARMVMLAVpu (v16i8 MQPR:$val1), (v16i8 MQPR:$val2), (v16i1 VCCR:$pred)), tGPREven:$Rd)),
1238            (i32 (MVE_VMLADAVau8 tGPREven:$Rd, (v16i8 MQPR:$val1), (v16i8 MQPR:$val2), ARMVCCThen, $pred, zero_reg))>;
1239}
1240
1241// vmlav aliases vmladav
1242foreach acc = ["", "a"] in {
1243  foreach suffix = ["s8", "s16", "s32", "u8", "u16", "u32"] in {
1244    def : MVEInstAlias<"vmlav"#acc#"${vp}."#suffix#"\t$RdaDest, $Qn, $Qm",
1245                       (!cast<Instruction>("MVE_VMLADAV"#acc#suffix)
1246                        tGPREven:$RdaDest, MQPR:$Qn, MQPR:$Qm, vpred_n:$vp)>;
1247  }
1248}
1249
1250// Base class for VMLALDAV and VMLSLDAV, VRMLALDAVH, VRMLSLDAVH
1251class MVE_VMLALDAVBase<string iname, string suffix, dag iops, string cstr,
1252                       bit sz, bit bit_28, bit A, bit X, bit bit_8, bit bit_0,
1253                       bits<2> vecsize, list<dag> pattern=[]>
1254  : MVE_rDest<(outs tGPREven:$RdaLoDest, tGPROdd:$RdaHiDest), iops, NoItinerary,
1255              iname, suffix, "$RdaLoDest, $RdaHiDest, $Qn, $Qm", cstr, vecsize, pattern> {
1256  bits<4> RdaLoDest;
1257  bits<4> RdaHiDest;
1258  bits<3> Qm;
1259  bits<3> Qn;
1260
1261  let Inst{28} = bit_28;
1262  let Inst{22-20} = RdaHiDest{3-1};
1263  let Inst{19-17} = Qn{2-0};
1264  let Inst{16} = sz;
1265  let Inst{15-13} = RdaLoDest{3-1};
1266  let Inst{12} = X;
1267  let Inst{8} = bit_8;
1268  let Inst{7-6} = 0b00;
1269  let Inst{5} = A;
1270  let Inst{3-1} = Qm{2-0};
1271  let Inst{0} = bit_0;
1272  let horizontalReduction = 1;
1273  // Allow tail predication for non-exchanging versions. As this is also a
1274  // horizontalReduction, ARMLowOverheadLoops will also have to check that
1275  // the vector operands contain zeros in their false lanes for the instruction
1276  // to be properly valid.
1277  let validForTailPredication = !eq(X, 0);
1278
1279  let hasSideEffects = 0;
1280}
1281
1282multiclass MVE_VMLALDAVBase_A<string iname, string x, string suffix,
1283                              bit sz, bit bit_28, bit X, bit bit_8, bit bit_0,
1284                              bits<2> vecsize, list<dag> pattern=[]> {
1285  def ""#x#suffix : MVE_VMLALDAVBase<
1286     iname # x, suffix, (ins MQPR:$Qn, MQPR:$Qm), "",
1287     sz, bit_28, 0b0, X, bit_8, bit_0, vecsize, pattern>;
1288  def "a"#x#suffix : MVE_VMLALDAVBase<
1289     iname # "a" # x, suffix,
1290     (ins tGPREven:$RdaLoSrc, tGPROdd:$RdaHiSrc, MQPR:$Qn, MQPR:$Qm),
1291     "$RdaLoDest = $RdaLoSrc,$RdaHiDest = $RdaHiSrc",
1292     sz, bit_28, 0b1, X, bit_8, bit_0, vecsize, pattern>;
1293}
1294
1295
1296multiclass MVE_VMLALDAVBase_AX<string iname, string suffix, bit sz, bit bit_28,
1297                               bit bit_8, bit bit_0, bits<2> vecsize, list<dag> pattern=[]> {
1298  defm "" : MVE_VMLALDAVBase_A<iname, "", suffix, sz,
1299                               bit_28, 0b0, bit_8, bit_0, vecsize, pattern>;
1300  defm "" : MVE_VMLALDAVBase_A<iname, "x", suffix, sz,
1301                               bit_28, 0b1, bit_8, bit_0, vecsize, pattern>;
1302}
1303
1304multiclass MVE_VRMLALDAVH_multi<MVEVectorVTInfo VTI, list<dag> pattern=[]> {
1305  defm "" : MVE_VMLALDAVBase_AX<"vrmlaldavh", "s"#VTI.BitsSuffix,
1306                                0b0, 0b0, 0b1, 0b0, VTI.Size, pattern>;
1307  defm "" : MVE_VMLALDAVBase_A<"vrmlaldavh", "", "u"#VTI.BitsSuffix,
1308                               0b0, 0b1, 0b0, 0b1, 0b0, VTI.Size, pattern>;
1309}
1310
1311defm MVE_VRMLALDAVH : MVE_VRMLALDAVH_multi<MVE_v4i32>;
1312
1313// vrmlalvh aliases for vrmlaldavh
1314def : MVEInstAlias<"vrmlalvh${vp}.s32\t$RdaLo, $RdaHi, $Qn, $Qm",
1315                  (MVE_VRMLALDAVHs32
1316                   tGPREven:$RdaLo, tGPROdd:$RdaHi,
1317                   MQPR:$Qn, MQPR:$Qm, vpred_n:$vp)>;
1318def : MVEInstAlias<"vrmlalvha${vp}.s32\t$RdaLo, $RdaHi, $Qn, $Qm",
1319                  (MVE_VRMLALDAVHas32
1320                   tGPREven:$RdaLo, tGPROdd:$RdaHi,
1321                   MQPR:$Qn, MQPR:$Qm, vpred_n:$vp)>;
1322def : MVEInstAlias<"vrmlalvh${vp}.u32\t$RdaLo, $RdaHi, $Qn, $Qm",
1323                  (MVE_VRMLALDAVHu32
1324                   tGPREven:$RdaLo, tGPROdd:$RdaHi,
1325                   MQPR:$Qn, MQPR:$Qm, vpred_n:$vp)>;
1326def : MVEInstAlias<"vrmlalvha${vp}.u32\t$RdaLo, $RdaHi, $Qn, $Qm",
1327                  (MVE_VRMLALDAVHau32
1328                   tGPREven:$RdaLo, tGPROdd:$RdaHi,
1329                   MQPR:$Qn, MQPR:$Qm, vpred_n:$vp)>;
1330
1331multiclass MVE_VMLALDAV_multi<MVEVectorVTInfo VTI, list<dag> pattern=[]> {
1332  defm "" : MVE_VMLALDAVBase_AX<"vmlaldav", "s"#VTI.BitsSuffix,
1333                                VTI.Size{1}, 0b0, 0b0, 0b0, VTI.Size, pattern>;
1334  defm "" : MVE_VMLALDAVBase_A<"vmlaldav", "", "u"#VTI.BitsSuffix,
1335                               VTI.Size{1}, 0b1, 0b0, 0b0, 0b0, VTI.Size, pattern>;
1336}
1337
1338defm MVE_VMLALDAV : MVE_VMLALDAV_multi<MVE_v8i16>;
1339defm MVE_VMLALDAV : MVE_VMLALDAV_multi<MVE_v4i32>;
1340
1341let Predicates = [HasMVEInt] in {
1342  def : Pat<(ARMVMLALVs (v4i32 MQPR:$val1), (v4i32 MQPR:$val2)),
1343            (MVE_VMLALDAVs32 (v4i32 MQPR:$val1), (v4i32 MQPR:$val2))>;
1344  def : Pat<(ARMVMLALVu (v4i32 MQPR:$val1), (v4i32 MQPR:$val2)),
1345            (MVE_VMLALDAVu32 (v4i32 MQPR:$val1), (v4i32 MQPR:$val2))>;
1346  def : Pat<(ARMVMLALVs (v8i16 MQPR:$val1), (v8i16 MQPR:$val2)),
1347            (MVE_VMLALDAVs16 (v8i16 MQPR:$val1), (v8i16 MQPR:$val2))>;
1348  def : Pat<(ARMVMLALVu (v8i16 MQPR:$val1), (v8i16 MQPR:$val2)),
1349            (MVE_VMLALDAVu16 (v8i16 MQPR:$val1), (v8i16 MQPR:$val2))>;
1350
1351  def : Pat<(ARMVMLALVAs tGPREven:$Rda, tGPROdd:$Rdb, (v4i32 MQPR:$val1), (v4i32 MQPR:$val2)),
1352            (MVE_VMLALDAVas32 tGPREven:$Rda, tGPROdd:$Rdb, (v4i32 MQPR:$val1), (v4i32 MQPR:$val2))>;
1353  def : Pat<(ARMVMLALVAu tGPREven:$Rda, tGPROdd:$Rdb, (v4i32 MQPR:$val1), (v4i32 MQPR:$val2)),
1354            (MVE_VMLALDAVau32 tGPREven:$Rda, tGPROdd:$Rdb, (v4i32 MQPR:$val1), (v4i32 MQPR:$val2))>;
1355  def : Pat<(ARMVMLALVAs tGPREven:$Rda, tGPROdd:$Rdb, (v8i16 MQPR:$val1), (v8i16 MQPR:$val2)),
1356            (MVE_VMLALDAVas16 tGPREven:$Rda, tGPROdd:$Rdb, (v8i16 MQPR:$val1), (v8i16 MQPR:$val2))>;
1357  def : Pat<(ARMVMLALVAu tGPREven:$Rda, tGPROdd:$Rdb, (v8i16 MQPR:$val1), (v8i16 MQPR:$val2)),
1358            (MVE_VMLALDAVau16 tGPREven:$Rda, tGPROdd:$Rdb, (v8i16 MQPR:$val1), (v8i16 MQPR:$val2))>;
1359
1360  // Predicated
1361  def : Pat<(ARMVMLALVps (v4i32 MQPR:$val1), (v4i32 MQPR:$val2), (v4i1 VCCR:$pred)),
1362            (MVE_VMLALDAVs32 (v4i32 MQPR:$val1), (v4i32 MQPR:$val2), ARMVCCThen, $pred, zero_reg)>;
1363  def : Pat<(ARMVMLALVpu (v4i32 MQPR:$val1), (v4i32 MQPR:$val2), (v4i1 VCCR:$pred)),
1364            (MVE_VMLALDAVu32 (v4i32 MQPR:$val1), (v4i32 MQPR:$val2), ARMVCCThen, $pred, zero_reg)>;
1365  def : Pat<(ARMVMLALVps (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), (v8i1 VCCR:$pred)),
1366            (MVE_VMLALDAVs16 (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), ARMVCCThen, $pred, zero_reg)>;
1367  def : Pat<(ARMVMLALVpu (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), (v8i1 VCCR:$pred)),
1368            (MVE_VMLALDAVu16 (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), ARMVCCThen, $pred, zero_reg)>;
1369
1370  def : Pat<(ARMVMLALVAps tGPREven:$Rda, tGPROdd:$Rdb, (v4i32 MQPR:$val1), (v4i32 MQPR:$val2), (v4i1 VCCR:$pred)),
1371            (MVE_VMLALDAVas32 tGPREven:$Rda, tGPROdd:$Rdb, (v4i32 MQPR:$val1), (v4i32 MQPR:$val2), ARMVCCThen, $pred, zero_reg)>;
1372  def : Pat<(ARMVMLALVApu tGPREven:$Rda, tGPROdd:$Rdb, (v4i32 MQPR:$val1), (v4i32 MQPR:$val2), (v4i1 VCCR:$pred)),
1373            (MVE_VMLALDAVau32 tGPREven:$Rda, tGPROdd:$Rdb, (v4i32 MQPR:$val1), (v4i32 MQPR:$val2), ARMVCCThen, $pred, zero_reg)>;
1374  def : Pat<(ARMVMLALVAps tGPREven:$Rda, tGPROdd:$Rdb, (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), (v8i1 VCCR:$pred)),
1375            (MVE_VMLALDAVas16 tGPREven:$Rda, tGPROdd:$Rdb, (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), ARMVCCThen, $pred, zero_reg)>;
1376  def : Pat<(ARMVMLALVApu tGPREven:$Rda, tGPROdd:$Rdb, (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), (v8i1 VCCR:$pred)),
1377            (MVE_VMLALDAVau16 tGPREven:$Rda, tGPROdd:$Rdb, (v8i16 MQPR:$val1), (v8i16 MQPR:$val2), ARMVCCThen, $pred, zero_reg)>;
1378}
1379
1380// vmlalv aliases vmlaldav
1381foreach acc = ["", "a"] in {
1382  foreach suffix = ["s16", "s32", "u16", "u32"] in {
1383    def : MVEInstAlias<"vmlalv" # acc # "${vp}." # suffix #
1384                          "\t$RdaLoDest, $RdaHiDest, $Qn, $Qm",
1385                       (!cast<Instruction>("MVE_VMLALDAV"#acc#suffix)
1386                       tGPREven:$RdaLoDest, tGPROdd:$RdaHiDest,
1387                       MQPR:$Qn, MQPR:$Qm, vpred_n:$vp)>;
1388  }
1389}
1390
1391multiclass MVE_VMLSLDAV_multi<string iname, string suffix, bit sz,
1392                              bit bit_28, bits<2> vecsize, list<dag> pattern=[]> {
1393  defm "" : MVE_VMLALDAVBase_AX<iname, suffix, sz, bit_28, 0b0, 0b1, vecsize, pattern>;
1394}
1395
1396defm MVE_VMLSLDAV   : MVE_VMLSLDAV_multi<"vmlsldav", "s16", 0b0, 0b0, 0b01>;
1397defm MVE_VMLSLDAV   : MVE_VMLSLDAV_multi<"vmlsldav", "s32", 0b1, 0b0, 0b10>;
1398defm MVE_VRMLSLDAVH : MVE_VMLSLDAV_multi<"vrmlsldavh", "s32", 0b0, 0b1, 0b10>;
1399
1400// end of mve_rDest instructions
1401
1402// start of mve_comp instructions
1403
1404class MVE_comp<InstrItinClass itin, string iname, string suffix,
1405               string cstr, bits<2> vecsize, list<dag> pattern=[]>
1406  : MVE_p<(outs MQPR:$Qd), (ins MQPR:$Qn, MQPR:$Qm), itin, iname, suffix,
1407           "$Qd, $Qn, $Qm", vpred_r, cstr, vecsize, pattern> {
1408  bits<4> Qd;
1409  bits<4> Qn;
1410  bits<4> Qm;
1411
1412  let Inst{22} = Qd{3};
1413  let Inst{19-17} = Qn{2-0};
1414  let Inst{16} = 0b0;
1415  let Inst{15-13} = Qd{2-0};
1416  let Inst{12} = 0b0;
1417  let Inst{10-9} = 0b11;
1418  let Inst{7} = Qn{3};
1419  let Inst{5} = Qm{3};
1420  let Inst{3-1} = Qm{2-0};
1421  let Inst{0} = 0b0;
1422}
1423
1424class MVE_VMINMAXNM<string iname, string suffix, bits<2> sz, bit bit_21,
1425                    list<dag> pattern=[]>
1426  : MVE_comp<NoItinerary, iname, suffix, "", sz, pattern> {
1427
1428  let Inst{28} = 0b1;
1429  let Inst{25-24} = 0b11;
1430  let Inst{23} = 0b0;
1431  let Inst{21} = bit_21;
1432  let Inst{20} = sz{0};
1433  let Inst{11} = 0b1;
1434  let Inst{8} = 0b1;
1435  let Inst{6} = 0b1;
1436  let Inst{4} = 0b1;
1437
1438  let Predicates = [HasMVEFloat];
1439  let validForTailPredication = 1;
1440}
1441
1442multiclass MVE_VMINMAXNM_m<string iname, bit bit_4, MVEVectorVTInfo VTI, SDNode Op, Intrinsic PredInt> {
1443  def "" : MVE_VMINMAXNM<iname, VTI.Suffix, VTI.Size, bit_4>;
1444
1445  let Predicates = [HasMVEFloat] in {
1446    defm : MVE_TwoOpPattern<VTI, Op, PredInt, (? (i32 0)), !cast<Instruction>(NAME)>;
1447  }
1448}
1449
1450defm MVE_VMAXNMf32 : MVE_VMINMAXNM_m<"vmaxnm", 0b0, MVE_v4f32, fmaxnum, int_arm_mve_max_predicated>;
1451defm MVE_VMAXNMf16 : MVE_VMINMAXNM_m<"vmaxnm", 0b0, MVE_v8f16, fmaxnum, int_arm_mve_max_predicated>;
1452defm MVE_VMINNMf32 : MVE_VMINMAXNM_m<"vminnm", 0b1, MVE_v4f32, fminnum, int_arm_mve_min_predicated>;
1453defm MVE_VMINNMf16 : MVE_VMINMAXNM_m<"vminnm", 0b1, MVE_v8f16, fminnum, int_arm_mve_min_predicated>;
1454
1455
1456class MVE_VMINMAX<string iname, string suffix, bit U, bits<2> size,
1457              bit bit_4, list<dag> pattern=[]>
1458  : MVE_comp<NoItinerary, iname, suffix, "", size, pattern> {
1459
1460  let Inst{28} = U;
1461  let Inst{25-24} = 0b11;
1462  let Inst{23} = 0b0;
1463  let Inst{21-20} = size{1-0};
1464  let Inst{11} = 0b0;
1465  let Inst{8} = 0b0;
1466  let Inst{6} = 0b1;
1467  let Inst{4} = bit_4;
1468  let validForTailPredication = 1;
1469}
1470
1471multiclass MVE_VMINMAX_m<string iname, bit bit_4, MVEVectorVTInfo VTI,
1472                      SDNode Op, Intrinsic PredInt> {
1473  def "" : MVE_VMINMAX<iname, VTI.Suffix, VTI.Unsigned, VTI.Size, bit_4>;
1474
1475  let Predicates = [HasMVEInt] in {
1476    defm : MVE_TwoOpPattern<VTI, Op, PredInt, (? (i32 VTI.Unsigned)), !cast<Instruction>(NAME)>;
1477  }
1478}
1479
1480multiclass MVE_VMAX<MVEVectorVTInfo VTI>
1481  : MVE_VMINMAX_m<"vmax", 0b0, VTI, !if(VTI.Unsigned, umax, smax), int_arm_mve_max_predicated>;
1482multiclass MVE_VMIN<MVEVectorVTInfo VTI>
1483  : MVE_VMINMAX_m<"vmin", 0b1, VTI, !if(VTI.Unsigned, umin, smin), int_arm_mve_min_predicated>;
1484
1485defm MVE_VMINs8   : MVE_VMIN<MVE_v16s8>;
1486defm MVE_VMINs16  : MVE_VMIN<MVE_v8s16>;
1487defm MVE_VMINs32  : MVE_VMIN<MVE_v4s32>;
1488defm MVE_VMINu8   : MVE_VMIN<MVE_v16u8>;
1489defm MVE_VMINu16  : MVE_VMIN<MVE_v8u16>;
1490defm MVE_VMINu32  : MVE_VMIN<MVE_v4u32>;
1491
1492defm MVE_VMAXs8   : MVE_VMAX<MVE_v16s8>;
1493defm MVE_VMAXs16  : MVE_VMAX<MVE_v8s16>;
1494defm MVE_VMAXs32  : MVE_VMAX<MVE_v4s32>;
1495defm MVE_VMAXu8   : MVE_VMAX<MVE_v16u8>;
1496defm MVE_VMAXu16  : MVE_VMAX<MVE_v8u16>;
1497defm MVE_VMAXu32  : MVE_VMAX<MVE_v4u32>;
1498
1499// end of mve_comp instructions
1500
1501// start of mve_bit instructions
1502
1503class MVE_bit_arith<dag oops, dag iops, string iname, string suffix,
1504                    string ops, string cstr, bits<2> vecsize, list<dag> pattern=[]>
1505  : MVE_p<oops, iops, NoItinerary, iname, suffix, ops, vpred_r, cstr, vecsize, pattern> {
1506  bits<4> Qd;
1507  bits<4> Qm;
1508
1509  let Inst{22} = Qd{3};
1510  let Inst{15-13} = Qd{2-0};
1511  let Inst{5} = Qm{3};
1512  let Inst{3-1} = Qm{2-0};
1513}
1514
1515def MVE_VBIC : MVE_bit_arith<(outs MQPR:$Qd), (ins MQPR:$Qn, MQPR:$Qm),
1516                             "vbic", "", "$Qd, $Qn, $Qm", "", 0b00> {
1517  bits<4> Qn;
1518
1519  let Inst{28} = 0b0;
1520  let Inst{25-23} = 0b110;
1521  let Inst{21-20} = 0b01;
1522  let Inst{19-17} = Qn{2-0};
1523  let Inst{16} = 0b0;
1524  let Inst{12-8} = 0b00001;
1525  let Inst{7} = Qn{3};
1526  let Inst{6} = 0b1;
1527  let Inst{4} = 0b1;
1528  let Inst{0} = 0b0;
1529  let validForTailPredication = 1;
1530}
1531
1532class MVE_VREV<string iname, string suffix, bits<2> size, bits<2> bit_8_7,
1533               bits<2> vecsize, string cstr="">
1534  : MVE_bit_arith<(outs MQPR:$Qd), (ins MQPR:$Qm), iname,
1535                  suffix, "$Qd, $Qm", cstr, vecsize> {
1536
1537  let Inst{28} = 0b1;
1538  let Inst{25-23} = 0b111;
1539  let Inst{21-20} = 0b11;
1540  let Inst{19-18} = size;
1541  let Inst{17-16} = 0b00;
1542  let Inst{12-9} = 0b0000;
1543  let Inst{8-7} = bit_8_7;
1544  let Inst{6} = 0b1;
1545  let Inst{4} = 0b0;
1546  let Inst{0} = 0b0;
1547}
1548
1549def MVE_VREV64_8  : MVE_VREV<"vrev64", "8", 0b00, 0b00, 0b11, "@earlyclobber $Qd">;
1550def MVE_VREV64_16 : MVE_VREV<"vrev64", "16", 0b01, 0b00, 0b11, "@earlyclobber $Qd">;
1551def MVE_VREV64_32 : MVE_VREV<"vrev64", "32", 0b10, 0b00, 0b11, "@earlyclobber $Qd">;
1552
1553def MVE_VREV32_8  : MVE_VREV<"vrev32", "8", 0b00, 0b01, 0b10>;
1554def MVE_VREV32_16 : MVE_VREV<"vrev32", "16", 0b01, 0b01, 0b10>;
1555
1556def MVE_VREV16_8  : MVE_VREV<"vrev16", "8", 0b00, 0b10, 0b01>;
1557
1558let Predicates = [HasMVEInt] in {
1559  def : Pat<(v8i16 (bswap (v8i16 MQPR:$src))),
1560            (v8i16 (MVE_VREV16_8 (v8i16 MQPR:$src)))>;
1561  def : Pat<(v4i32 (bswap (v4i32 MQPR:$src))),
1562            (v4i32 (MVE_VREV32_8 (v4i32 MQPR:$src)))>;
1563}
1564
1565multiclass MVE_VREV_basic_patterns<int revbits, list<MVEVectorVTInfo> VTIs,
1566                                   Instruction Inst> {
1567  defvar unpred_op = !cast<SDNode>("ARMvrev" # revbits);
1568
1569  foreach VTI = VTIs in {
1570    def : Pat<(VTI.Vec (unpred_op (VTI.Vec MQPR:$src))),
1571              (VTI.Vec (Inst (VTI.Vec MQPR:$src)))>;
1572    def : Pat<(VTI.Vec (int_arm_mve_vrev_predicated (VTI.Vec MQPR:$src),
1573                  revbits, (VTI.Pred VCCR:$pred), (VTI.Vec MQPR:$inactive))),
1574              (VTI.Vec (Inst (VTI.Vec MQPR:$src), ARMVCCThen,
1575                  (VTI.Pred VCCR:$pred), zero_reg, (VTI.Vec MQPR:$inactive)))>;
1576  }
1577}
1578
1579let Predicates = [HasMVEInt] in {
1580  defm: MVE_VREV_basic_patterns<64, [MVE_v4i32, MVE_v4f32], MVE_VREV64_32>;
1581  defm: MVE_VREV_basic_patterns<64, [MVE_v8i16, MVE_v8f16], MVE_VREV64_16>;
1582  defm: MVE_VREV_basic_patterns<64, [MVE_v16i8           ], MVE_VREV64_8>;
1583
1584  defm: MVE_VREV_basic_patterns<32, [MVE_v8i16, MVE_v8f16], MVE_VREV32_16>;
1585  defm: MVE_VREV_basic_patterns<32, [MVE_v16i8           ], MVE_VREV32_8>;
1586
1587  defm: MVE_VREV_basic_patterns<16, [MVE_v16i8           ], MVE_VREV16_8>;
1588}
1589
1590def MVE_VMVN : MVE_bit_arith<(outs MQPR:$Qd), (ins MQPR:$Qm),
1591                             "vmvn", "", "$Qd, $Qm", "", 0b00> {
1592  let Inst{28} = 0b1;
1593  let Inst{25-23} = 0b111;
1594  let Inst{21-16} = 0b110000;
1595  let Inst{12-6} = 0b0010111;
1596  let Inst{4} = 0b0;
1597  let Inst{0} = 0b0;
1598  let validForTailPredication = 1;
1599}
1600
1601let Predicates = [HasMVEInt] in {
1602  foreach VTI = [ MVE_v16i8, MVE_v8i16, MVE_v4i32, MVE_v2i64 ] in {
1603    def : Pat<(VTI.Vec (vnotq    (VTI.Vec MQPR:$val1))),
1604              (VTI.Vec (MVE_VMVN (VTI.Vec MQPR:$val1)))>;
1605    def : Pat<(VTI.Vec (int_arm_mve_mvn_predicated (VTI.Vec MQPR:$val1),
1606                       (VTI.Pred VCCR:$pred), (VTI.Vec MQPR:$inactive))),
1607              (VTI.Vec (MVE_VMVN (VTI.Vec MQPR:$val1), ARMVCCThen,
1608                       (VTI.Pred VCCR:$pred), zero_reg, (VTI.Vec MQPR:$inactive)))>;
1609  }
1610}
1611
1612class MVE_bit_ops<string iname, bits<2> bit_21_20, bit bit_28>
1613  : MVE_bit_arith<(outs MQPR:$Qd), (ins MQPR:$Qn, MQPR:$Qm),
1614                  iname, "", "$Qd, $Qn, $Qm", "", 0b00> {
1615  bits<4> Qn;
1616
1617  let Inst{28} = bit_28;
1618  let Inst{25-23} = 0b110;
1619  let Inst{21-20} = bit_21_20;
1620  let Inst{19-17} = Qn{2-0};
1621  let Inst{16} = 0b0;
1622  let Inst{12-8} = 0b00001;
1623  let Inst{7} = Qn{3};
1624  let Inst{6} = 0b1;
1625  let Inst{4} = 0b1;
1626  let Inst{0} = 0b0;
1627  let validForTailPredication = 1;
1628}
1629
1630def MVE_VEOR : MVE_bit_ops<"veor", 0b00, 0b1>;
1631def MVE_VORN : MVE_bit_ops<"vorn", 0b11, 0b0>;
1632def MVE_VORR : MVE_bit_ops<"vorr", 0b10, 0b0>;
1633def MVE_VAND : MVE_bit_ops<"vand", 0b00, 0b0>;
1634
1635// add ignored suffixes as aliases
1636
1637foreach s=["s8", "s16", "s32", "u8", "u16", "u32", "i8", "i16", "i32", "f16", "f32"] in {
1638  def : MVEInstAlias<"vbic${vp}." # s # "\t$QdSrc, $QnSrc, $QmSrc",
1639        (MVE_VBIC MQPR:$QdSrc, MQPR:$QnSrc, MQPR:$QmSrc, vpred_r:$vp)>;
1640  def : MVEInstAlias<"veor${vp}." # s # "\t$QdSrc, $QnSrc, $QmSrc",
1641        (MVE_VEOR MQPR:$QdSrc, MQPR:$QnSrc, MQPR:$QmSrc, vpred_r:$vp)>;
1642  def : MVEInstAlias<"vorn${vp}." # s # "\t$QdSrc, $QnSrc, $QmSrc",
1643        (MVE_VORN MQPR:$QdSrc, MQPR:$QnSrc, MQPR:$QmSrc, vpred_r:$vp)>;
1644  def : MVEInstAlias<"vorr${vp}." # s # "\t$QdSrc, $QnSrc, $QmSrc",
1645        (MVE_VORR MQPR:$QdSrc, MQPR:$QnSrc, MQPR:$QmSrc, vpred_r:$vp)>;
1646  def : MVEInstAlias<"vand${vp}." # s # "\t$QdSrc, $QnSrc, $QmSrc",
1647        (MVE_VAND MQPR:$QdSrc, MQPR:$QnSrc, MQPR:$QmSrc, vpred_r:$vp)>;
1648}
1649
1650let Predicates = [HasMVEInt] in {
1651  defm : MVE_TwoOpPattern<MVE_v16i8, and, int_arm_mve_and_predicated, (? ), MVE_VAND, ARMimmAllOnesV>;
1652  defm : MVE_TwoOpPattern<MVE_v8i16, and, int_arm_mve_and_predicated, (? ), MVE_VAND, ARMimmAllOnesV>;
1653  defm : MVE_TwoOpPattern<MVE_v4i32, and, int_arm_mve_and_predicated, (? ), MVE_VAND, ARMimmAllOnesV>;
1654  defm : MVE_TwoOpPattern<MVE_v2i64, and, int_arm_mve_and_predicated, (? ), MVE_VAND, ARMimmAllOnesV>;
1655
1656  defm : MVE_TwoOpPattern<MVE_v16i8, or, int_arm_mve_orr_predicated, (? ), MVE_VORR, ARMimmAllZerosV>;
1657  defm : MVE_TwoOpPattern<MVE_v8i16, or, int_arm_mve_orr_predicated, (? ), MVE_VORR, ARMimmAllZerosV>;
1658  defm : MVE_TwoOpPattern<MVE_v4i32, or, int_arm_mve_orr_predicated, (? ), MVE_VORR, ARMimmAllZerosV>;
1659  defm : MVE_TwoOpPattern<MVE_v2i64, or, int_arm_mve_orr_predicated, (? ), MVE_VORR, ARMimmAllZerosV>;
1660
1661  defm : MVE_TwoOpPattern<MVE_v16i8, xor, int_arm_mve_eor_predicated, (? ), MVE_VEOR, ARMimmAllZerosV>;
1662  defm : MVE_TwoOpPattern<MVE_v8i16, xor, int_arm_mve_eor_predicated, (? ), MVE_VEOR, ARMimmAllZerosV>;
1663  defm : MVE_TwoOpPattern<MVE_v4i32, xor, int_arm_mve_eor_predicated, (? ), MVE_VEOR, ARMimmAllZerosV>;
1664  defm : MVE_TwoOpPattern<MVE_v2i64, xor, int_arm_mve_eor_predicated, (? ), MVE_VEOR, ARMimmAllZerosV>;
1665
1666  defm : MVE_TwoOpPattern<MVE_v16i8, BinOpFrag<(and node:$LHS, (vnotq node:$RHS))>,
1667                          int_arm_mve_bic_predicated, (? ), MVE_VBIC>;
1668  defm : MVE_TwoOpPattern<MVE_v8i16, BinOpFrag<(and node:$LHS, (vnotq node:$RHS))>,
1669                          int_arm_mve_bic_predicated, (? ), MVE_VBIC>;
1670  defm : MVE_TwoOpPattern<MVE_v4i32, BinOpFrag<(and node:$LHS, (vnotq node:$RHS))>,
1671                          int_arm_mve_bic_predicated, (? ), MVE_VBIC>;
1672  defm : MVE_TwoOpPattern<MVE_v2i64, BinOpFrag<(and node:$LHS, (vnotq node:$RHS))>,
1673                          int_arm_mve_bic_predicated, (? ), MVE_VBIC>;
1674
1675  defm : MVE_TwoOpPattern<MVE_v16i8, BinOpFrag<(or node:$LHS, (vnotq node:$RHS))>,
1676                          int_arm_mve_orn_predicated, (? ), MVE_VORN>;
1677  defm : MVE_TwoOpPattern<MVE_v8i16, BinOpFrag<(or node:$LHS, (vnotq node:$RHS))>,
1678                          int_arm_mve_orn_predicated, (? ), MVE_VORN>;
1679  defm : MVE_TwoOpPattern<MVE_v4i32, BinOpFrag<(or node:$LHS, (vnotq node:$RHS))>,
1680                          int_arm_mve_orn_predicated, (? ), MVE_VORN>;
1681  defm : MVE_TwoOpPattern<MVE_v2i64, BinOpFrag<(or node:$LHS, (vnotq node:$RHS))>,
1682                          int_arm_mve_orn_predicated, (? ), MVE_VORN>;
1683}
1684
1685class MVE_bit_cmode<string iname, string suffix, bit halfword, dag inOps, bits<2> vecsize>
1686  : MVE_p<(outs MQPR:$Qd), inOps, NoItinerary,
1687          iname, suffix, "$Qd, $imm", vpred_n, "$Qd = $Qd_src", vecsize> {
1688  bits<12> imm;
1689  bits<4> Qd;
1690
1691  let Inst{28} = imm{7};
1692  let Inst{27-23} = 0b11111;
1693  let Inst{22} = Qd{3};
1694  let Inst{21-19} = 0b000;
1695  let Inst{18-16} = imm{6-4};
1696  let Inst{15-13} = Qd{2-0};
1697  let Inst{12} = 0b0;
1698  let Inst{11} = halfword;
1699  let Inst{10} = !if(halfword, 0, imm{10});
1700  let Inst{9} = imm{9};
1701  let Inst{8} = 0b1;
1702  let Inst{7-6} = 0b01;
1703  let Inst{4} = 0b1;
1704  let Inst{3-0} = imm{3-0};
1705}
1706
1707multiclass MVE_bit_cmode_p<string iname, bit opcode,
1708                           MVEVectorVTInfo VTI, Operand imm_type, SDNode op> {
1709  def "" : MVE_bit_cmode<iname, VTI.Suffix, VTI.Size{0},
1710                         (ins MQPR:$Qd_src, imm_type:$imm), VTI.Size> {
1711    let Inst{5} = opcode;
1712    let validForTailPredication = 1;
1713  }
1714
1715  defvar Inst = !cast<Instruction>(NAME);
1716  defvar UnpredPat = (VTI.Vec (op (VTI.Vec MQPR:$src), timm:$simm));
1717
1718  let Predicates = [HasMVEInt] in {
1719    def : Pat<UnpredPat,
1720              (VTI.Vec (Inst (VTI.Vec MQPR:$src), imm_type:$simm))>;
1721    def : Pat<(VTI.Vec (vselect (VTI.Pred VCCR:$pred),
1722                          UnpredPat, (VTI.Vec MQPR:$src))),
1723              (VTI.Vec (Inst (VTI.Vec MQPR:$src), imm_type:$simm,
1724                             ARMVCCThen, (VTI.Pred VCCR:$pred), zero_reg))>;
1725  }
1726}
1727
1728multiclass MVE_VORRimm<MVEVectorVTInfo VTI, Operand imm_type> {
1729  defm "": MVE_bit_cmode_p<"vorr", 0, VTI, imm_type, ARMvorrImm>;
1730}
1731multiclass MVE_VBICimm<MVEVectorVTInfo VTI, Operand imm_type> {
1732  defm "": MVE_bit_cmode_p<"vbic", 1, VTI, imm_type, ARMvbicImm>;
1733}
1734
1735defm MVE_VORRimmi16 : MVE_VORRimm<MVE_v8i16, nImmSplatI16>;
1736defm MVE_VORRimmi32 : MVE_VORRimm<MVE_v4i32, nImmSplatI32>;
1737defm MVE_VBICimmi16 : MVE_VBICimm<MVE_v8i16, nImmSplatI16>;
1738defm MVE_VBICimmi32 : MVE_VBICimm<MVE_v4i32, nImmSplatI32>;
1739
1740def MVE_VORNimmi16 : MVEInstAlias<"vorn${vp}.i16\t$Qd, $imm",
1741    (MVE_VORRimmi16 MQPR:$Qd, nImmSplatNotI16:$imm, vpred_n:$vp), 0>;
1742def MVE_VORNimmi32 : MVEInstAlias<"vorn${vp}.i32\t$Qd, $imm",
1743    (MVE_VORRimmi32 MQPR:$Qd, nImmSplatNotI32:$imm, vpred_n:$vp), 0>;
1744
1745def MVE_VANDimmi16 : MVEInstAlias<"vand${vp}.i16\t$Qd, $imm",
1746    (MVE_VBICimmi16 MQPR:$Qd, nImmSplatNotI16:$imm, vpred_n:$vp), 0>;
1747def MVE_VANDimmi32 : MVEInstAlias<"vand${vp}.i32\t$Qd, $imm",
1748    (MVE_VBICimmi32 MQPR:$Qd, nImmSplatNotI32:$imm, vpred_n:$vp), 0>;
1749
1750def MVE_VMOV : MVEInstAlias<"vmov${vp}\t$Qd, $Qm",
1751    (MVE_VORR MQPR:$Qd, MQPR:$Qm, MQPR:$Qm, vpred_r:$vp)>;
1752
1753class MVE_VMOV_lane_direction {
1754  bit bit_20;
1755  dag oops;
1756  dag iops;
1757  string ops;
1758  string cstr;
1759}
1760def MVE_VMOV_from_lane : MVE_VMOV_lane_direction {
1761  let bit_20 = 0b1;
1762  let oops = (outs rGPR:$Rt);
1763  let iops = (ins MQPR:$Qd);
1764  let ops = "$Rt, $Qd$Idx";
1765  let cstr = "";
1766}
1767def MVE_VMOV_to_lane : MVE_VMOV_lane_direction {
1768  let bit_20 = 0b0;
1769  let oops = (outs MQPR:$Qd);
1770  let iops = (ins MQPR:$Qd_src, rGPR:$Rt);
1771  let ops = "$Qd$Idx, $Rt";
1772  let cstr = "$Qd = $Qd_src";
1773}
1774
1775class MVE_VMOV_lane<string suffix, bit U, dag indexop,
1776                    MVE_VMOV_lane_direction dir>
1777  : MVE_VMOV_lane_base<dir.oops, !con(dir.iops, indexop), NoItinerary,
1778                       "vmov", suffix, dir.ops, dir.cstr, []> {
1779  bits<4> Qd;
1780  bits<4> Rt;
1781
1782  let Inst{31-24} = 0b11101110;
1783  let Inst{23} = U;
1784  let Inst{20} = dir.bit_20;
1785  let Inst{19-17} = Qd{2-0};
1786  let Inst{15-12} = Rt{3-0};
1787  let Inst{11-8} = 0b1011;
1788  let Inst{7} = Qd{3};
1789  let Inst{4-0} = 0b10000;
1790
1791  let hasSideEffects = 0;
1792}
1793
1794class MVE_VMOV_lane_32<MVE_VMOV_lane_direction dir>
1795    : MVE_VMOV_lane<"32", 0b0, (ins MVEVectorIndex<4>:$Idx), dir> {
1796  bits<2> Idx;
1797  let Inst{22} = 0b0;
1798  let Inst{6-5} = 0b00;
1799  let Inst{16} = Idx{1};
1800  let Inst{21} = Idx{0};
1801
1802  let VecSize = 0b10;
1803  let Predicates = [HasFPRegsV8_1M];
1804}
1805
1806class MVE_VMOV_lane_16<string suffix, bit U, MVE_VMOV_lane_direction dir>
1807  : MVE_VMOV_lane<suffix, U, (ins MVEVectorIndex<8>:$Idx), dir> {
1808  bits<3> Idx;
1809  let Inst{22} = 0b0;
1810  let Inst{5} = 0b1;
1811  let Inst{16} = Idx{2};
1812  let Inst{21} = Idx{1};
1813  let Inst{6} = Idx{0};
1814
1815  let VecSize = 0b01;
1816}
1817
1818class MVE_VMOV_lane_8<string suffix, bit U, MVE_VMOV_lane_direction dir>
1819  : MVE_VMOV_lane<suffix, U, (ins MVEVectorIndex<16>:$Idx), dir> {
1820  bits<4> Idx;
1821  let Inst{22} = 0b1;
1822  let Inst{16} = Idx{3};
1823  let Inst{21} = Idx{2};
1824  let Inst{6} = Idx{1};
1825  let Inst{5} = Idx{0};
1826
1827  let VecSize = 0b00;
1828}
1829
1830def MVE_VMOV_from_lane_32  : MVE_VMOV_lane_32<            MVE_VMOV_from_lane>;
1831def MVE_VMOV_from_lane_s16 : MVE_VMOV_lane_16<"s16", 0b0, MVE_VMOV_from_lane>;
1832def MVE_VMOV_from_lane_u16 : MVE_VMOV_lane_16<"u16", 0b1, MVE_VMOV_from_lane>;
1833def MVE_VMOV_from_lane_s8  : MVE_VMOV_lane_8 < "s8", 0b0, MVE_VMOV_from_lane>;
1834def MVE_VMOV_from_lane_u8  : MVE_VMOV_lane_8 < "u8", 0b1, MVE_VMOV_from_lane>;
1835let isInsertSubreg = 1 in
1836def MVE_VMOV_to_lane_32    : MVE_VMOV_lane_32<            MVE_VMOV_to_lane>;
1837def MVE_VMOV_to_lane_16    : MVE_VMOV_lane_16< "16", 0b0, MVE_VMOV_to_lane>;
1838def MVE_VMOV_to_lane_8     : MVE_VMOV_lane_8 <  "8", 0b0, MVE_VMOV_to_lane>;
1839
1840// This is the same as insertelt but allows the inserted value to be an i32 as
1841// will be used when it is the only legal type.
1842def ARMVecInsert : SDTypeProfile<1, 3, [
1843  SDTCisVT<2, i32>, SDTCisSameAs<0, 1>, SDTCisPtrTy<3>
1844]>;
1845def ARMinsertelt  : SDNode<"ISD::INSERT_VECTOR_ELT", ARMVecInsert>;
1846
1847let Predicates = [HasMVEInt] in {
1848  def : Pat<(extractelt (v2f64 MQPR:$src), imm:$lane),
1849            (f64 (EXTRACT_SUBREG MQPR:$src, (DSubReg_f64_reg imm:$lane)))>;
1850  def : Pat<(insertelt (v2f64 MQPR:$src1), DPR:$src2, imm:$lane),
1851            (INSERT_SUBREG (v2f64 (COPY_TO_REGCLASS MQPR:$src1, MQPR)), DPR:$src2, (DSubReg_f64_reg imm:$lane))>;
1852
1853  def : Pat<(extractelt (v4i32 MQPR:$src), imm:$lane),
1854            (COPY_TO_REGCLASS
1855              (i32 (EXTRACT_SUBREG MQPR:$src, (SSubReg_f32_reg imm:$lane))), rGPR)>;
1856  def : Pat<(insertelt (v4i32 MQPR:$src1), rGPR:$src2, imm:$lane),
1857            (MVE_VMOV_to_lane_32 MQPR:$src1, rGPR:$src2, imm:$lane)>;
1858  // This tries to copy from one lane to another, without going via GPR regs
1859  def : Pat<(insertelt (v4i32 MQPR:$src1), (extractelt (v4i32 MQPR:$src2), imm:$extlane), imm:$inslane),
1860            (v4i32 (COPY_TO_REGCLASS
1861                     (INSERT_SUBREG (v4f32 (COPY_TO_REGCLASS (v4i32 MQPR:$src1), MQPR)),
1862                                    (f32 (EXTRACT_SUBREG (v4f32 (COPY_TO_REGCLASS (v4i32 MQPR:$src2), MQPR)),
1863                                                         (SSubReg_f32_reg imm:$extlane))),
1864                                    (SSubReg_f32_reg imm:$inslane)),
1865                      MQPR))>;
1866
1867  def : Pat<(vector_insert (v16i8 MQPR:$src1), rGPR:$src2, imm:$lane),
1868            (MVE_VMOV_to_lane_8  MQPR:$src1, rGPR:$src2, imm:$lane)>;
1869  def : Pat<(vector_insert (v8i16 MQPR:$src1), rGPR:$src2, imm:$lane),
1870            (MVE_VMOV_to_lane_16 MQPR:$src1, rGPR:$src2, imm:$lane)>;
1871
1872  def : Pat<(ARMvgetlanes (v16i8 MQPR:$src), imm:$lane),
1873            (MVE_VMOV_from_lane_s8 MQPR:$src, imm:$lane)>;
1874  def : Pat<(ARMvgetlanes (v8i16 MQPR:$src), imm:$lane),
1875            (MVE_VMOV_from_lane_s16 MQPR:$src, imm:$lane)>;
1876  def : Pat<(ARMvgetlanes (v8f16 MQPR:$src), imm:$lane),
1877            (MVE_VMOV_from_lane_s16 MQPR:$src, imm:$lane)>;
1878  def : Pat<(ARMvgetlaneu (v16i8 MQPR:$src), imm:$lane),
1879            (MVE_VMOV_from_lane_u8 MQPR:$src, imm:$lane)>;
1880  def : Pat<(ARMvgetlaneu (v8i16 MQPR:$src), imm:$lane),
1881            (MVE_VMOV_from_lane_u16 MQPR:$src, imm:$lane)>;
1882  def : Pat<(ARMvgetlaneu (v8f16 MQPR:$src), imm:$lane),
1883            (MVE_VMOV_from_lane_u16 MQPR:$src, imm:$lane)>;
1884  // For i16's inserts being extracted from low lanes, then may use VINS.
1885  let Predicates = [HasFullFP16] in {
1886  def : Pat<(ARMinsertelt (v8i16 MQPR:$src1),
1887                          (ARMvgetlaneu (v8i16 MQPR:$src2), imm_even:$extlane),
1888                          imm_odd:$inslane),
1889            (COPY_TO_REGCLASS (INSERT_SUBREG (v4f32 (COPY_TO_REGCLASS MQPR:$src1, MQPR)),
1890                                (VINSH (EXTRACT_SUBREG MQPR:$src1, (SSubReg_f16_reg imm_odd:$inslane)),
1891                                       (EXTRACT_SUBREG MQPR:$src2, (SSubReg_f16_reg imm_even:$extlane))),
1892                                (SSubReg_f16_reg imm_odd:$inslane)), MQPR)>;
1893  }
1894
1895  def : Pat<(v16i8 (scalar_to_vector GPR:$src)),
1896            (MVE_VMOV_to_lane_8  (v16i8 (IMPLICIT_DEF)), rGPR:$src, (i32 0))>;
1897  def : Pat<(v8i16 (scalar_to_vector GPR:$src)),
1898            (MVE_VMOV_to_lane_16 (v8i16 (IMPLICIT_DEF)), rGPR:$src, (i32 0))>;
1899  def : Pat<(v4i32 (scalar_to_vector GPR:$src)),
1900            (MVE_VMOV_to_lane_32 (v4i32 (IMPLICIT_DEF)), rGPR:$src, (i32 0))>;
1901
1902  // Floating point patterns, still enabled under HasMVEInt
1903  def : Pat<(extractelt (v4f32 MQPR:$src), imm:$lane),
1904            (COPY_TO_REGCLASS (f32 (EXTRACT_SUBREG MQPR:$src, (SSubReg_f32_reg imm:$lane))), SPR)>;
1905  def : Pat<(insertelt (v4f32 MQPR:$src1), (f32 SPR:$src2), imm:$lane),
1906            (INSERT_SUBREG (v4f32 (COPY_TO_REGCLASS MQPR:$src1, MQPR)), SPR:$src2, (SSubReg_f32_reg imm:$lane))>;
1907
1908  def : Pat<(insertelt (v8f16 MQPR:$src1), (f16 HPR:$src2), imm_even:$lane),
1909            (MVE_VMOV_to_lane_16 MQPR:$src1, (COPY_TO_REGCLASS (f16 HPR:$src2), rGPR), imm:$lane)>;
1910  let Predicates = [HasFullFP16] in {
1911  def : Pat<(insertelt (v8f16 MQPR:$src1), (f16 HPR:$src2), imm_odd:$lane),
1912            (COPY_TO_REGCLASS (INSERT_SUBREG (v4f32 (COPY_TO_REGCLASS MQPR:$src1, MQPR)),
1913                                (VINSH (EXTRACT_SUBREG MQPR:$src1, (SSubReg_f16_reg imm_odd:$lane)),
1914                                       (COPY_TO_REGCLASS HPR:$src2, SPR)),
1915                                (SSubReg_f16_reg imm_odd:$lane)), MQPR)>;
1916  }
1917  def : Pat<(extractelt (v8f16 MQPR:$src), imm_even:$lane),
1918            (EXTRACT_SUBREG MQPR:$src, (SSubReg_f16_reg imm_even:$lane))>;
1919  let Predicates = [HasFullFP16] in {
1920  def : Pat<(extractelt (v8f16 MQPR:$src), imm_odd:$lane),
1921            (COPY_TO_REGCLASS
1922              (VMOVH (EXTRACT_SUBREG MQPR:$src, (SSubReg_f16_reg imm_odd:$lane))),
1923              HPR)>;
1924  }
1925
1926  def : Pat<(v2f64 (scalar_to_vector (f64 DPR:$src))),
1927            (INSERT_SUBREG (v2f64 (IMPLICIT_DEF)), DPR:$src, dsub_0)>;
1928  def : Pat<(v4f32 (scalar_to_vector SPR:$src)),
1929            (INSERT_SUBREG (v4f32 (IMPLICIT_DEF)), SPR:$src, ssub_0)>;
1930  def : Pat<(v4f32 (scalar_to_vector GPR:$src)),
1931            (MVE_VMOV_to_lane_32 (v4f32 (IMPLICIT_DEF)), rGPR:$src, (i32 0))>;
1932  def : Pat<(v8f16 (scalar_to_vector (f16 HPR:$src))),
1933            (INSERT_SUBREG (v8f16 (IMPLICIT_DEF)), (f16 HPR:$src), ssub_0)>;
1934  def : Pat<(v8f16 (scalar_to_vector GPR:$src)),
1935            (MVE_VMOV_to_lane_16 (v8f16 (IMPLICIT_DEF)), rGPR:$src, (i32 0))>;
1936}
1937
1938// end of mve_bit instructions
1939
1940// start of MVE Integer instructions
1941
1942class MVE_int<string iname, string suffix, bits<2> size, list<dag> pattern=[]>
1943  : MVE_p<(outs MQPR:$Qd), (ins MQPR:$Qn, MQPR:$Qm), NoItinerary,
1944          iname, suffix, "$Qd, $Qn, $Qm", vpred_r, "", size, pattern> {
1945  bits<4> Qd;
1946  bits<4> Qn;
1947  bits<4> Qm;
1948
1949  let Inst{22} = Qd{3};
1950  let Inst{21-20} = size;
1951  let Inst{19-17} = Qn{2-0};
1952  let Inst{15-13} = Qd{2-0};
1953  let Inst{7} = Qn{3};
1954  let Inst{6} = 0b1;
1955  let Inst{5} = Qm{3};
1956  let Inst{3-1} = Qm{2-0};
1957}
1958
1959class MVE_VMULt1<string iname, string suffix, bits<2> size,
1960                   list<dag> pattern=[]>
1961  : MVE_int<iname, suffix, size, pattern> {
1962
1963  let Inst{28} = 0b0;
1964  let Inst{25-23} = 0b110;
1965  let Inst{16} = 0b0;
1966  let Inst{12-8} = 0b01001;
1967  let Inst{4} = 0b1;
1968  let Inst{0} = 0b0;
1969  let validForTailPredication = 1;
1970}
1971
1972multiclass MVE_VMUL_m<MVEVectorVTInfo VTI> {
1973  def "" : MVE_VMULt1<"vmul", VTI.Suffix, VTI.Size>;
1974
1975  let Predicates = [HasMVEInt] in {
1976    defm : MVE_TwoOpPattern<VTI, mul, int_arm_mve_mul_predicated, (? ),
1977                            !cast<Instruction>(NAME), ARMimmOneV>;
1978  }
1979}
1980
1981defm MVE_VMULi8  : MVE_VMUL_m<MVE_v16i8>;
1982defm MVE_VMULi16 : MVE_VMUL_m<MVE_v8i16>;
1983defm MVE_VMULi32 : MVE_VMUL_m<MVE_v4i32>;
1984
1985class MVE_VQxDMULH_Base<string iname, string suffix, bits<2> size, bit rounding,
1986                  list<dag> pattern=[]>
1987  : MVE_int<iname, suffix, size, pattern> {
1988
1989  let Inst{28} = rounding;
1990  let Inst{25-23} = 0b110;
1991  let Inst{16} = 0b0;
1992  let Inst{12-8} = 0b01011;
1993  let Inst{4} = 0b0;
1994  let Inst{0} = 0b0;
1995  let validForTailPredication = 1;
1996}
1997
1998def MVEvqdmulh : SDNode<"ARMISD::VQDMULH", SDTIntBinOp>;
1999
2000multiclass MVE_VQxDMULH_m<string iname, MVEVectorVTInfo VTI,
2001                      SDNode Op, Intrinsic unpred_int, Intrinsic pred_int,
2002                      bit rounding> {
2003  def "" : MVE_VQxDMULH_Base<iname, VTI.Suffix, VTI.Size, rounding>;
2004  defvar Inst = !cast<Instruction>(NAME);
2005
2006  let Predicates = [HasMVEInt] in {
2007    defm : MVE_TwoOpPattern<VTI, Op, pred_int, (? ), Inst>;
2008
2009    // Extra unpredicated multiply intrinsic patterns
2010    def : Pat<(VTI.Vec (unpred_int (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn))),
2011              (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn)))>;
2012  }
2013}
2014
2015multiclass MVE_VQxDMULH<string iname, MVEVectorVTInfo VTI, bit rounding>
2016  : MVE_VQxDMULH_m<iname, VTI, !if(rounding, null_frag,
2017                                             MVEvqdmulh),
2018                               !if(rounding, int_arm_mve_vqrdmulh,
2019                                             int_arm_mve_vqdmulh),
2020                               !if(rounding, int_arm_mve_qrdmulh_predicated,
2021                                             int_arm_mve_qdmulh_predicated),
2022                   rounding>;
2023
2024defm MVE_VQDMULHi8  : MVE_VQxDMULH<"vqdmulh", MVE_v16s8, 0b0>;
2025defm MVE_VQDMULHi16 : MVE_VQxDMULH<"vqdmulh", MVE_v8s16, 0b0>;
2026defm MVE_VQDMULHi32 : MVE_VQxDMULH<"vqdmulh", MVE_v4s32, 0b0>;
2027
2028defm MVE_VQRDMULHi8  : MVE_VQxDMULH<"vqrdmulh", MVE_v16s8, 0b1>;
2029defm MVE_VQRDMULHi16 : MVE_VQxDMULH<"vqrdmulh", MVE_v8s16, 0b1>;
2030defm MVE_VQRDMULHi32 : MVE_VQxDMULH<"vqrdmulh", MVE_v4s32, 0b1>;
2031
2032class MVE_VADDSUB<string iname, string suffix, bits<2> size, bit subtract,
2033                    list<dag> pattern=[]>
2034  : MVE_int<iname, suffix, size, pattern> {
2035
2036  let Inst{28} = subtract;
2037  let Inst{25-23} = 0b110;
2038  let Inst{16} = 0b0;
2039  let Inst{12-8} = 0b01000;
2040  let Inst{4} = 0b0;
2041  let Inst{0} = 0b0;
2042  let validForTailPredication = 1;
2043}
2044
2045multiclass MVE_VADDSUB_m<string iname, MVEVectorVTInfo VTI, bit subtract,
2046                         SDNode Op, Intrinsic PredInt> {
2047  def "" : MVE_VADDSUB<iname, VTI.Suffix, VTI.Size, subtract>;
2048  defvar Inst = !cast<Instruction>(NAME);
2049
2050  let Predicates = [HasMVEInt] in {
2051    defm : MVE_TwoOpPattern<VTI, Op, PredInt, (? ), !cast<Instruction>(NAME), ARMimmAllZerosV>;
2052  }
2053}
2054
2055multiclass MVE_VADD<MVEVectorVTInfo VTI>
2056  : MVE_VADDSUB_m<"vadd", VTI, 0b0, add, int_arm_mve_add_predicated>;
2057multiclass MVE_VSUB<MVEVectorVTInfo VTI>
2058  : MVE_VADDSUB_m<"vsub", VTI, 0b1, sub, int_arm_mve_sub_predicated>;
2059
2060defm MVE_VADDi8  : MVE_VADD<MVE_v16i8>;
2061defm MVE_VADDi16 : MVE_VADD<MVE_v8i16>;
2062defm MVE_VADDi32 : MVE_VADD<MVE_v4i32>;
2063
2064defm MVE_VSUBi8  : MVE_VSUB<MVE_v16i8>;
2065defm MVE_VSUBi16 : MVE_VSUB<MVE_v8i16>;
2066defm MVE_VSUBi32 : MVE_VSUB<MVE_v4i32>;
2067
2068class MVE_VQADDSUB<string iname, string suffix, bit U, bit subtract,
2069                   bits<2> size>
2070  : MVE_int<iname, suffix, size, []> {
2071
2072  let Inst{28} = U;
2073  let Inst{25-23} = 0b110;
2074  let Inst{16} = 0b0;
2075  let Inst{12-10} = 0b000;
2076  let Inst{9} = subtract;
2077  let Inst{8} = 0b0;
2078  let Inst{4} = 0b1;
2079  let Inst{0} = 0b0;
2080  let validForTailPredication = 1;
2081}
2082
2083class MVE_VQADD_<string suffix, bit U, bits<2> size>
2084  : MVE_VQADDSUB<"vqadd", suffix, U, 0b0, size>;
2085class MVE_VQSUB_<string suffix, bit U, bits<2> size>
2086  : MVE_VQADDSUB<"vqsub", suffix, U, 0b1, size>;
2087
2088multiclass MVE_VQADD_m<MVEVectorVTInfo VTI,
2089                      SDNode Op, Intrinsic PredInt> {
2090  def "" : MVE_VQADD_<VTI.Suffix, VTI.Unsigned, VTI.Size>;
2091  defvar Inst = !cast<Instruction>(NAME);
2092
2093  let Predicates = [HasMVEInt] in {
2094    defm : MVE_TwoOpPattern<VTI, Op, PredInt, (? (i32 VTI.Unsigned)),
2095                            !cast<Instruction>(NAME)>;
2096  }
2097}
2098
2099multiclass MVE_VQADD<MVEVectorVTInfo VTI, SDNode unpred_op>
2100  : MVE_VQADD_m<VTI, unpred_op, int_arm_mve_qadd_predicated>;
2101
2102defm MVE_VQADDs8  : MVE_VQADD<MVE_v16s8, saddsat>;
2103defm MVE_VQADDs16 : MVE_VQADD<MVE_v8s16, saddsat>;
2104defm MVE_VQADDs32 : MVE_VQADD<MVE_v4s32, saddsat>;
2105defm MVE_VQADDu8  : MVE_VQADD<MVE_v16u8, uaddsat>;
2106defm MVE_VQADDu16 : MVE_VQADD<MVE_v8u16, uaddsat>;
2107defm MVE_VQADDu32 : MVE_VQADD<MVE_v4u32, uaddsat>;
2108
2109multiclass MVE_VQSUB_m<MVEVectorVTInfo VTI,
2110                      SDNode Op, Intrinsic PredInt> {
2111  def "" : MVE_VQSUB_<VTI.Suffix, VTI.Unsigned, VTI.Size>;
2112  defvar Inst = !cast<Instruction>(NAME);
2113
2114  let Predicates = [HasMVEInt] in {
2115    defm : MVE_TwoOpPattern<VTI, Op, PredInt, (? (i32 VTI.Unsigned)),
2116                            !cast<Instruction>(NAME)>;
2117  }
2118}
2119
2120multiclass MVE_VQSUB<MVEVectorVTInfo VTI, SDNode unpred_op>
2121  : MVE_VQSUB_m<VTI, unpred_op, int_arm_mve_qsub_predicated>;
2122
2123defm MVE_VQSUBs8  : MVE_VQSUB<MVE_v16s8, ssubsat>;
2124defm MVE_VQSUBs16 : MVE_VQSUB<MVE_v8s16, ssubsat>;
2125defm MVE_VQSUBs32 : MVE_VQSUB<MVE_v4s32, ssubsat>;
2126defm MVE_VQSUBu8  : MVE_VQSUB<MVE_v16u8, usubsat>;
2127defm MVE_VQSUBu16 : MVE_VQSUB<MVE_v8u16, usubsat>;
2128defm MVE_VQSUBu32 : MVE_VQSUB<MVE_v4u32, usubsat>;
2129
2130class MVE_VABD_int<string suffix, bit U, bits<2> size,
2131                     list<dag> pattern=[]>
2132  : MVE_int<"vabd", suffix, size, pattern> {
2133
2134  let Inst{28} = U;
2135  let Inst{25-23} = 0b110;
2136  let Inst{16} = 0b0;
2137  let Inst{12-8} = 0b00111;
2138  let Inst{4} = 0b0;
2139  let Inst{0} = 0b0;
2140  let validForTailPredication = 1;
2141}
2142
2143multiclass MVE_VABD_m<MVEVectorVTInfo VTI, SDNode Op,
2144                      Intrinsic unpred_int, Intrinsic PredInt> {
2145  def "" : MVE_VABD_int<VTI.Suffix, VTI.Unsigned, VTI.Size>;
2146  defvar Inst = !cast<Instruction>(NAME);
2147
2148  let Predicates = [HasMVEInt] in {
2149    defm : MVE_TwoOpPattern<VTI, Op, PredInt, (? (i32 VTI.Unsigned)),
2150                            !cast<Instruction>(NAME)>;
2151
2152    // Unpredicated absolute difference
2153    def : Pat<(VTI.Vec (unpred_int (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
2154                            (i32 VTI.Unsigned))),
2155              (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn)))>;
2156  }
2157}
2158
2159multiclass MVE_VABD<MVEVectorVTInfo VTI, SDNode Op>
2160  : MVE_VABD_m<VTI, Op, int_arm_mve_vabd, int_arm_mve_abd_predicated>;
2161
2162defm MVE_VABDs8  : MVE_VABD<MVE_v16s8, abds>;
2163defm MVE_VABDs16 : MVE_VABD<MVE_v8s16, abds>;
2164defm MVE_VABDs32 : MVE_VABD<MVE_v4s32, abds>;
2165defm MVE_VABDu8  : MVE_VABD<MVE_v16u8, abdu>;
2166defm MVE_VABDu16 : MVE_VABD<MVE_v8u16, abdu>;
2167defm MVE_VABDu32 : MVE_VABD<MVE_v4u32, abdu>;
2168
2169class MVE_VRHADD_Base<string suffix, bit U, bits<2> size, list<dag> pattern=[]>
2170  : MVE_int<"vrhadd", suffix, size, pattern> {
2171
2172  let Inst{28} = U;
2173  let Inst{25-23} = 0b110;
2174  let Inst{16} = 0b0;
2175  let Inst{12-8} = 0b00001;
2176  let Inst{4} = 0b0;
2177  let Inst{0} = 0b0;
2178  let validForTailPredication = 1;
2179}
2180
2181def addnuw : PatFrag<(ops node:$lhs, node:$rhs),
2182                     (add node:$lhs, node:$rhs), [{
2183  return N->getFlags().hasNoUnsignedWrap();
2184}]>;
2185
2186def addnsw : PatFrag<(ops node:$lhs, node:$rhs),
2187                     (add node:$lhs, node:$rhs), [{
2188  return N->getFlags().hasNoSignedWrap();
2189}]>;
2190
2191def subnuw : PatFrag<(ops node:$lhs, node:$rhs),
2192                     (sub node:$lhs, node:$rhs), [{
2193  return N->getFlags().hasNoUnsignedWrap();
2194}]>;
2195
2196def subnsw : PatFrag<(ops node:$lhs, node:$rhs),
2197                     (sub node:$lhs, node:$rhs), [{
2198  return N->getFlags().hasNoSignedWrap();
2199}]>;
2200
2201multiclass MVE_VRHADD_m<MVEVectorVTInfo VTI, SDNode Op,
2202                      SDNode unpred_op, Intrinsic PredInt> {
2203  def "" : MVE_VRHADD_Base<VTI.Suffix, VTI.Unsigned, VTI.Size>;
2204  defvar Inst = !cast<Instruction>(NAME);
2205  defm : MVE_TwoOpPattern<VTI, Op, PredInt, (? (i32 VTI.Unsigned)), !cast<Instruction>(NAME)>;
2206
2207  let Predicates = [HasMVEInt] in {
2208    // Unpredicated rounding add-with-divide-by-two intrinsic
2209    def : Pat<(VTI.Vec (unpred_op (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
2210                            (i32 VTI.Unsigned))),
2211              (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn)))>;
2212  }
2213}
2214
2215multiclass MVE_VRHADD<MVEVectorVTInfo VTI, SDNode rhadd>
2216  : MVE_VRHADD_m<VTI, rhadd, int_arm_mve_vrhadd, int_arm_mve_rhadd_predicated>;
2217
2218defm MVE_VRHADDs8  : MVE_VRHADD<MVE_v16s8, avgceils>;
2219defm MVE_VRHADDs16 : MVE_VRHADD<MVE_v8s16, avgceils>;
2220defm MVE_VRHADDs32 : MVE_VRHADD<MVE_v4s32, avgceils>;
2221defm MVE_VRHADDu8  : MVE_VRHADD<MVE_v16u8, avgceilu>;
2222defm MVE_VRHADDu16 : MVE_VRHADD<MVE_v8u16, avgceilu>;
2223defm MVE_VRHADDu32 : MVE_VRHADD<MVE_v4u32, avgceilu>;
2224
2225// Rounding Halving Add perform the arithemtic operation with an extra bit of
2226// precision, before performing the shift, to void clipping errors. We're not
2227// modelling that here with these patterns, but we're using no wrap forms of
2228// add to ensure that the extra bit of information is not needed for the
2229// arithmetic or the rounding.
2230let Predicates = [HasMVEInt] in {
2231  def : Pat<(v16i8 (ARMvshrsImm (addnsw (addnsw (v16i8 MQPR:$Qm), (v16i8 MQPR:$Qn)),
2232                                        (v16i8 (ARMvmovImm (i32 3585)))),
2233                                (i32 1))),
2234            (MVE_VRHADDs8 MQPR:$Qm, MQPR:$Qn)>;
2235  def : Pat<(v8i16 (ARMvshrsImm (addnsw (addnsw (v8i16 MQPR:$Qm), (v8i16 MQPR:$Qn)),
2236                                        (v8i16 (ARMvmovImm (i32 2049)))),
2237                                (i32 1))),
2238            (MVE_VRHADDs16 MQPR:$Qm, MQPR:$Qn)>;
2239  def : Pat<(v4i32 (ARMvshrsImm (addnsw (addnsw (v4i32 MQPR:$Qm), (v4i32 MQPR:$Qn)),
2240                                        (v4i32 (ARMvmovImm (i32 1)))),
2241                                (i32 1))),
2242            (MVE_VRHADDs32 MQPR:$Qm, MQPR:$Qn)>;
2243  def : Pat<(v16i8 (ARMvshruImm (addnuw (addnuw (v16i8 MQPR:$Qm), (v16i8 MQPR:$Qn)),
2244                                        (v16i8 (ARMvmovImm (i32 3585)))),
2245                                (i32 1))),
2246            (MVE_VRHADDu8 MQPR:$Qm, MQPR:$Qn)>;
2247  def : Pat<(v8i16 (ARMvshruImm (addnuw (addnuw (v8i16 MQPR:$Qm), (v8i16 MQPR:$Qn)),
2248                                        (v8i16 (ARMvmovImm (i32 2049)))),
2249                                (i32 1))),
2250            (MVE_VRHADDu16 MQPR:$Qm, MQPR:$Qn)>;
2251  def : Pat<(v4i32 (ARMvshruImm (addnuw (addnuw (v4i32 MQPR:$Qm), (v4i32 MQPR:$Qn)),
2252                                        (v4i32 (ARMvmovImm (i32 1)))),
2253                                (i32 1))),
2254            (MVE_VRHADDu32 MQPR:$Qm, MQPR:$Qn)>;
2255
2256  def : Pat<(v16i8 (ARMvshrsImm (addnsw (addnsw (v16i8 MQPR:$Qm), (v16i8 MQPR:$Qn)),
2257                                        (v16i8 (ARMvdup (i32 1)))),
2258                                (i32 1))),
2259            (MVE_VRHADDs8 MQPR:$Qm, MQPR:$Qn)>;
2260  def : Pat<(v8i16 (ARMvshrsImm (addnsw (addnsw (v8i16 MQPR:$Qm), (v8i16 MQPR:$Qn)),
2261                                        (v8i16 (ARMvdup (i32 1)))),
2262                                (i32 1))),
2263            (MVE_VRHADDs16 MQPR:$Qm, MQPR:$Qn)>;
2264  def : Pat<(v4i32 (ARMvshrsImm (addnsw (addnsw (v4i32 MQPR:$Qm), (v4i32 MQPR:$Qn)),
2265                                        (v4i32 (ARMvdup (i32 1)))),
2266                                (i32 1))),
2267            (MVE_VRHADDs32 MQPR:$Qm, MQPR:$Qn)>;
2268  def : Pat<(v16i8 (ARMvshruImm (addnuw (addnuw (v16i8 MQPR:$Qm), (v16i8 MQPR:$Qn)),
2269                                        (v16i8 (ARMvdup (i32 1)))),
2270                                (i32 1))),
2271            (MVE_VRHADDu8 MQPR:$Qm, MQPR:$Qn)>;
2272  def : Pat<(v8i16 (ARMvshruImm (addnuw (addnuw (v8i16 MQPR:$Qm), (v8i16 MQPR:$Qn)),
2273                                        (v8i16 (ARMvdup (i32 1)))),
2274                                (i32 1))),
2275            (MVE_VRHADDu16 MQPR:$Qm, MQPR:$Qn)>;
2276  def : Pat<(v4i32 (ARMvshruImm (addnuw (addnuw (v4i32 MQPR:$Qm), (v4i32 MQPR:$Qn)),
2277                                        (v4i32 (ARMvdup (i32 1)))),
2278                                (i32 1))),
2279            (MVE_VRHADDu32 MQPR:$Qm, MQPR:$Qn)>;
2280}
2281
2282
2283class MVE_VHADDSUB<string iname, string suffix, bit U, bit subtract,
2284                   bits<2> size, list<dag> pattern=[]>
2285  : MVE_int<iname, suffix, size, pattern> {
2286
2287  let Inst{28} = U;
2288  let Inst{25-23} = 0b110;
2289  let Inst{16} = 0b0;
2290  let Inst{12-10} = 0b000;
2291  let Inst{9} = subtract;
2292  let Inst{8} = 0b0;
2293  let Inst{4} = 0b0;
2294  let Inst{0} = 0b0;
2295  let validForTailPredication = 1;
2296}
2297
2298class MVE_VHADD_<string suffix, bit U, bits<2> size,
2299              list<dag> pattern=[]>
2300  : MVE_VHADDSUB<"vhadd", suffix, U, 0b0, size, pattern>;
2301class MVE_VHSUB_<string suffix, bit U, bits<2> size,
2302              list<dag> pattern=[]>
2303  : MVE_VHADDSUB<"vhsub", suffix, U, 0b1, size, pattern>;
2304
2305multiclass MVE_VHADD_m<MVEVectorVTInfo VTI, SDNode Op,
2306                      SDNode unpred_op, Intrinsic PredInt, PatFrag add_op,
2307                      SDNode shift_op> {
2308  def "" : MVE_VHADD_<VTI.Suffix, VTI.Unsigned, VTI.Size>;
2309  defvar Inst = !cast<Instruction>(NAME);
2310  defm : MVE_TwoOpPattern<VTI, Op, PredInt, (? (i32 VTI.Unsigned)), !cast<Instruction>(NAME)>;
2311
2312  let Predicates = [HasMVEInt] in {
2313    // Unpredicated add-and-divide-by-two
2314    def : Pat<(VTI.Vec (unpred_op (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn), (i32 VTI.Unsigned))),
2315              (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn)))>;
2316
2317    def : Pat<(VTI.Vec (shift_op (add_op (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn)), (i32 1))),
2318              (Inst MQPR:$Qm, MQPR:$Qn)>;
2319  }
2320}
2321
2322multiclass MVE_VHADD<MVEVectorVTInfo VTI, SDNode Op, PatFrag add_op, SDNode shift_op>
2323  : MVE_VHADD_m<VTI, Op, int_arm_mve_vhadd, int_arm_mve_hadd_predicated, add_op,
2324                shift_op>;
2325
2326// Halving add/sub perform the arithemtic operation with an extra bit of
2327// precision, before performing the shift, to void clipping errors. We're not
2328// modelling that here with these patterns, but we're using no wrap forms of
2329// add/sub to ensure that the extra bit of information is not needed.
2330defm MVE_VHADDs8  : MVE_VHADD<MVE_v16s8, avgfloors, addnsw, ARMvshrsImm>;
2331defm MVE_VHADDs16 : MVE_VHADD<MVE_v8s16, avgfloors, addnsw, ARMvshrsImm>;
2332defm MVE_VHADDs32 : MVE_VHADD<MVE_v4s32, avgfloors, addnsw, ARMvshrsImm>;
2333defm MVE_VHADDu8  : MVE_VHADD<MVE_v16u8, avgflooru, addnuw, ARMvshruImm>;
2334defm MVE_VHADDu16 : MVE_VHADD<MVE_v8u16, avgflooru, addnuw, ARMvshruImm>;
2335defm MVE_VHADDu32 : MVE_VHADD<MVE_v4u32, avgflooru, addnuw, ARMvshruImm>;
2336
2337multiclass MVE_VHSUB_m<MVEVectorVTInfo VTI,
2338                      SDNode unpred_op, Intrinsic pred_int, PatFrag sub_op,
2339                      SDNode shift_op> {
2340  def "" : MVE_VHSUB_<VTI.Suffix, VTI.Unsigned, VTI.Size>;
2341  defvar Inst = !cast<Instruction>(NAME);
2342
2343  let Predicates = [HasMVEInt] in {
2344    // Unpredicated subtract-and-divide-by-two
2345    def : Pat<(VTI.Vec (unpred_op (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
2346                            (i32 VTI.Unsigned))),
2347              (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn)))>;
2348
2349    def : Pat<(VTI.Vec (shift_op (sub_op (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn)), (i32 1))),
2350              (Inst MQPR:$Qm, MQPR:$Qn)>;
2351
2352
2353    // Predicated subtract-and-divide-by-two
2354    def : Pat<(VTI.Vec (pred_int (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
2355                            (i32 VTI.Unsigned), (VTI.Pred VCCR:$mask),
2356                            (VTI.Vec MQPR:$inactive))),
2357              (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
2358                             ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
2359                             (VTI.Vec MQPR:$inactive)))>;
2360  }
2361}
2362
2363multiclass MVE_VHSUB<MVEVectorVTInfo VTI, PatFrag sub_op, SDNode shift_op>
2364  : MVE_VHSUB_m<VTI, int_arm_mve_vhsub, int_arm_mve_hsub_predicated, sub_op,
2365                shift_op>;
2366
2367defm MVE_VHSUBs8  : MVE_VHSUB<MVE_v16s8, subnsw, ARMvshrsImm>;
2368defm MVE_VHSUBs16 : MVE_VHSUB<MVE_v8s16, subnsw, ARMvshrsImm>;
2369defm MVE_VHSUBs32 : MVE_VHSUB<MVE_v4s32, subnsw, ARMvshrsImm>;
2370defm MVE_VHSUBu8  : MVE_VHSUB<MVE_v16u8, subnuw, ARMvshruImm>;
2371defm MVE_VHSUBu16 : MVE_VHSUB<MVE_v8u16, subnuw, ARMvshruImm>;
2372defm MVE_VHSUBu32 : MVE_VHSUB<MVE_v4u32, subnuw, ARMvshruImm>;
2373
2374class MVE_VDUP<string suffix, bit B, bit E, bits<2> vecsize, list<dag> pattern=[]>
2375  : MVE_p<(outs MQPR:$Qd), (ins rGPR:$Rt), NoItinerary,
2376          "vdup", suffix, "$Qd, $Rt", vpred_r, "", vecsize, pattern> {
2377  bits<4> Qd;
2378  bits<4> Rt;
2379
2380  let Inst{28} = 0b0;
2381  let Inst{25-23} = 0b101;
2382  let Inst{22} = B;
2383  let Inst{21-20} = 0b10;
2384  let Inst{19-17} = Qd{2-0};
2385  let Inst{16} = 0b0;
2386  let Inst{15-12} = Rt;
2387  let Inst{11-8} = 0b1011;
2388  let Inst{7} = Qd{3};
2389  let Inst{6} = 0b0;
2390  let Inst{5} = E;
2391  let Inst{4-0} = 0b10000;
2392  let validForTailPredication = 1;
2393}
2394
2395def MVE_VDUP32 : MVE_VDUP<"32", 0b0, 0b0, 0b10>;
2396def MVE_VDUP16 : MVE_VDUP<"16", 0b0, 0b1, 0b01>;
2397def MVE_VDUP8  : MVE_VDUP<"8",  0b1, 0b0, 0b00>;
2398
2399let Predicates = [HasMVEInt] in {
2400  def : Pat<(v16i8 (ARMvdup (i32 rGPR:$elem))),
2401            (MVE_VDUP8  rGPR:$elem)>;
2402  def : Pat<(v8i16 (ARMvdup (i32 rGPR:$elem))),
2403            (MVE_VDUP16 rGPR:$elem)>;
2404  def : Pat<(v4i32 (ARMvdup (i32 rGPR:$elem))),
2405            (MVE_VDUP32 rGPR:$elem)>;
2406
2407  def : Pat<(v8f16 (ARMvdup (i32 rGPR:$elem))),
2408            (MVE_VDUP16 rGPR:$elem)>;
2409  def : Pat<(v4f32 (ARMvdup (i32 rGPR:$elem))),
2410            (MVE_VDUP32 rGPR:$elem)>;
2411
2412  // Match a vselect with an ARMvdup as a predicated MVE_VDUP
2413  def : Pat<(v16i8 (vselect (v16i1 VCCR:$pred),
2414                            (v16i8 (ARMvdup (i32 rGPR:$elem))),
2415                            (v16i8 MQPR:$inactive))),
2416            (MVE_VDUP8  rGPR:$elem, ARMVCCThen, (v16i1 VCCR:$pred), zero_reg,
2417                        (v16i8 MQPR:$inactive))>;
2418  def : Pat<(v8i16 (vselect (v8i1 VCCR:$pred),
2419                            (v8i16 (ARMvdup (i32 rGPR:$elem))),
2420                            (v8i16 MQPR:$inactive))),
2421            (MVE_VDUP16 rGPR:$elem, ARMVCCThen, (v8i1 VCCR:$pred), zero_reg,
2422                            (v8i16 MQPR:$inactive))>;
2423  def : Pat<(v4i32 (vselect (v4i1 VCCR:$pred),
2424                            (v4i32 (ARMvdup (i32 rGPR:$elem))),
2425                            (v4i32 MQPR:$inactive))),
2426            (MVE_VDUP32 rGPR:$elem, ARMVCCThen, (v4i1 VCCR:$pred), zero_reg,
2427                            (v4i32 MQPR:$inactive))>;
2428  def : Pat<(v4f32 (vselect (v4i1 VCCR:$pred),
2429                            (v4f32 (ARMvdup (i32 rGPR:$elem))),
2430                            (v4f32 MQPR:$inactive))),
2431            (MVE_VDUP32 rGPR:$elem, ARMVCCThen, (v4i1 VCCR:$pred), zero_reg,
2432                            (v4f32 MQPR:$inactive))>;
2433  def : Pat<(v8f16 (vselect (v8i1 VCCR:$pred),
2434                            (v8f16 (ARMvdup (i32 rGPR:$elem))),
2435                            (v8f16 MQPR:$inactive))),
2436            (MVE_VDUP16 rGPR:$elem, ARMVCCThen, (v8i1 VCCR:$pred), zero_reg,
2437                            (v8f16 MQPR:$inactive))>;
2438}
2439
2440
2441class MVEIntSingleSrc<string iname, string suffix, bits<2> size,
2442                         list<dag> pattern=[]>
2443  : MVE_p<(outs MQPR:$Qd), (ins MQPR:$Qm), NoItinerary,
2444          iname, suffix, "$Qd, $Qm", vpred_r, "", size, pattern> {
2445  bits<4> Qd;
2446  bits<4> Qm;
2447
2448  let Inst{22} = Qd{3};
2449  let Inst{19-18} = size{1-0};
2450  let Inst{15-13} = Qd{2-0};
2451  let Inst{5} = Qm{3};
2452  let Inst{3-1} = Qm{2-0};
2453}
2454
2455class MVE_VCLSCLZ<string iname, string suffix, bits<2> size,
2456                   bit count_zeroes, list<dag> pattern=[]>
2457  : MVEIntSingleSrc<iname, suffix, size, pattern> {
2458
2459  let Inst{28} = 0b1;
2460  let Inst{25-23} = 0b111;
2461  let Inst{21-20} = 0b11;
2462  let Inst{17-16} = 0b00;
2463  let Inst{12-8} = 0b00100;
2464  let Inst{7} = count_zeroes;
2465  let Inst{6} = 0b1;
2466  let Inst{4} = 0b0;
2467  let Inst{0} = 0b0;
2468  let validForTailPredication = 1;
2469}
2470
2471multiclass MVE_VCLSCLZ_p<string opname, bit opcode, MVEVectorVTInfo VTI,
2472                         SDPatternOperator unpred_op> {
2473  def "": MVE_VCLSCLZ<"v"#opname, VTI.Suffix, VTI.Size, opcode>;
2474
2475  defvar Inst     = !cast<Instruction>(NAME);
2476  defvar pred_int = !cast<Intrinsic>("int_arm_mve_"#opname#"_predicated");
2477
2478  let Predicates = [HasMVEInt] in {
2479    def : Pat<(VTI.Vec (unpred_op (VTI.Vec MQPR:$val))),
2480              (VTI.Vec (Inst (VTI.Vec MQPR:$val)))>;
2481    def : Pat<(VTI.Vec (pred_int (VTI.Vec MQPR:$val), (VTI.Pred VCCR:$pred),
2482                                 (VTI.Vec MQPR:$inactive))),
2483              (VTI.Vec (Inst (VTI.Vec MQPR:$val), ARMVCCThen,
2484                             (VTI.Pred VCCR:$pred), zero_reg, (VTI.Vec MQPR:$inactive)))>;
2485  }
2486}
2487
2488defm MVE_VCLSs8  : MVE_VCLSCLZ_p<"cls", 0, MVE_v16s8, int_arm_mve_vcls>;
2489defm MVE_VCLSs16 : MVE_VCLSCLZ_p<"cls", 0, MVE_v8s16, int_arm_mve_vcls>;
2490defm MVE_VCLSs32 : MVE_VCLSCLZ_p<"cls", 0, MVE_v4s32, int_arm_mve_vcls>;
2491
2492defm MVE_VCLZs8  : MVE_VCLSCLZ_p<"clz", 1, MVE_v16i8, ctlz>;
2493defm MVE_VCLZs16 : MVE_VCLSCLZ_p<"clz", 1, MVE_v8i16, ctlz>;
2494defm MVE_VCLZs32 : MVE_VCLSCLZ_p<"clz", 1, MVE_v4i32, ctlz>;
2495
2496class MVE_VABSNEG_int<string iname, string suffix, bits<2> size, bit negate,
2497                      bit saturate, list<dag> pattern=[]>
2498  : MVEIntSingleSrc<iname, suffix, size, pattern> {
2499
2500  let Inst{28} = 0b1;
2501  let Inst{25-23} = 0b111;
2502  let Inst{21-20} = 0b11;
2503  let Inst{17} = 0b0;
2504  let Inst{16} = !eq(saturate, 0);
2505  let Inst{12-11} = 0b00;
2506  let Inst{10} = saturate;
2507  let Inst{9-8} = 0b11;
2508  let Inst{7} = negate;
2509  let Inst{6} = 0b1;
2510  let Inst{4} = 0b0;
2511  let Inst{0} = 0b0;
2512  let validForTailPredication = 1;
2513}
2514
2515multiclass MVE_VABSNEG_int_m<string iname, bit negate, bit saturate,
2516                             SDPatternOperator unpred_op, Intrinsic pred_int,
2517                             MVEVectorVTInfo VTI> {
2518  def "" : MVE_VABSNEG_int<iname, VTI.Suffix, VTI.Size, negate, saturate>;
2519  defvar Inst = !cast<Instruction>(NAME);
2520
2521  let Predicates = [HasMVEInt] in {
2522    // VQABS and VQNEG have more difficult isel patterns defined elsewhere
2523    if !not(saturate) then {
2524      def : Pat<(VTI.Vec (unpred_op (VTI.Vec MQPR:$v))),
2525                (VTI.Vec (Inst $v))>;
2526    }
2527
2528    def : Pat<(VTI.Vec (pred_int  (VTI.Vec MQPR:$v), (VTI.Pred VCCR:$mask),
2529                                  (VTI.Vec MQPR:$inactive))),
2530              (VTI.Vec (Inst $v, ARMVCCThen, $mask, zero_reg, $inactive))>;
2531  }
2532}
2533
2534foreach VTI = [ MVE_v16s8, MVE_v8s16, MVE_v4s32 ] in {
2535  defm "MVE_VABS" # VTI.Suffix : MVE_VABSNEG_int_m<
2536     "vabs",  0, 0, abs,   int_arm_mve_abs_predicated,  VTI>;
2537  defm "MVE_VQABS" # VTI.Suffix : MVE_VABSNEG_int_m<
2538     "vqabs", 0, 1, ?,     int_arm_mve_qabs_predicated, VTI>;
2539  defm "MVE_VNEG" # VTI.Suffix : MVE_VABSNEG_int_m<
2540     "vneg",  1, 0, vnegq, int_arm_mve_neg_predicated,  VTI>;
2541  defm "MVE_VQNEG" # VTI.Suffix : MVE_VABSNEG_int_m<
2542     "vqneg", 1, 1, ?,     int_arm_mve_qneg_predicated, VTI>;
2543}
2544
2545// int_min/int_max: vector containing INT_MIN/INT_MAX VTI.Size times
2546// zero_vec: v4i32-initialized zero vector, potentially wrapped in a bitconvert
2547multiclass vqabsneg_pattern<MVEVectorVTInfo VTI, dag int_min, dag int_max,
2548                         dag zero_vec,  MVE_VABSNEG_int vqabs_instruction,
2549                         MVE_VABSNEG_int vqneg_instruction> {
2550  let Predicates = [HasMVEInt] in {
2551    // The below tree can be replaced by a vqabs instruction, as it represents
2552    // the following vectorized expression (r being the value in $reg):
2553    // r > 0 ? r : (r == INT_MIN ? INT_MAX : -r)
2554    def : Pat<(VTI.Vec (vselect
2555                      (VTI.Pred (ARMvcmpz (VTI.Vec MQPR:$reg), ARMCCgt)),
2556                      (VTI.Vec MQPR:$reg),
2557                      (VTI.Vec (vselect
2558                                (VTI.Pred (ARMvcmp (VTI.Vec MQPR:$reg), int_min, ARMCCeq)),
2559                                int_max,
2560                                (sub (VTI.Vec zero_vec), (VTI.Vec MQPR:$reg)))))),
2561            (VTI.Vec (vqabs_instruction (VTI.Vec MQPR:$reg)))>;
2562    // Similarly, this tree represents vqneg, i.e. the following vectorized expression:
2563    // r == INT_MIN ? INT_MAX : -r
2564    def : Pat<(VTI.Vec (vselect
2565                        (VTI.Pred (ARMvcmp (VTI.Vec MQPR:$reg), int_min, ARMCCeq)),
2566                        int_max,
2567                        (sub (VTI.Vec zero_vec), (VTI.Vec MQPR:$reg)))),
2568               (VTI.Vec (vqneg_instruction (VTI.Vec MQPR:$reg)))>;
2569  }
2570}
2571
2572defm MVE_VQABSNEG_Ps8  : vqabsneg_pattern<MVE_v16i8,
2573                                    (v16i8 (ARMvmovImm (i32 3712))),
2574                                    (v16i8 (ARMvmovImm (i32 3711))),
2575                                    (bitconvert (v4i32 (ARMvmovImm (i32 0)))),
2576                                    MVE_VQABSs8, MVE_VQNEGs8>;
2577defm MVE_VQABSNEG_Ps16 : vqabsneg_pattern<MVE_v8i16,
2578                                    (v8i16 (ARMvmovImm (i32 2688))),
2579                                    (v8i16 (ARMvmvnImm (i32 2688))),
2580                                    (bitconvert (v4i32 (ARMvmovImm (i32 0)))),
2581                                    MVE_VQABSs16, MVE_VQNEGs16>;
2582defm MVE_VQABSNEG_Ps32 : vqabsneg_pattern<MVE_v4i32,
2583                                    (v4i32 (ARMvmovImm (i32 1664))),
2584                                    (v4i32 (ARMvmvnImm (i32 1664))),
2585                                    (ARMvmovImm (i32 0)),
2586                                    MVE_VQABSs32, MVE_VQNEGs32>;
2587
2588class MVE_mod_imm<string iname, string suffix, bits<4> cmode, bit op,
2589                  dag iops, bits<2> vecsize, list<dag> pattern=[]>
2590  : MVE_p<(outs MQPR:$Qd), iops, NoItinerary, iname, suffix, "$Qd, $imm",
2591          vpred_r, "", vecsize, pattern> {
2592  bits<13> imm;
2593  bits<4> Qd;
2594
2595  let Inst{28} = imm{7};
2596  let Inst{25-23} = 0b111;
2597  let Inst{22} = Qd{3};
2598  let Inst{21-19} = 0b000;
2599  let Inst{18-16} = imm{6-4};
2600  let Inst{15-13} = Qd{2-0};
2601  let Inst{12} = 0b0;
2602  let Inst{11-8} = cmode{3-0};
2603  let Inst{7-6} = 0b01;
2604  let Inst{5} = op;
2605  let Inst{4} = 0b1;
2606  let Inst{3-0} = imm{3-0};
2607
2608  let DecoderMethod = "DecodeMVEModImmInstruction";
2609  let validForTailPredication = 1;
2610}
2611
2612let isReMaterializable = 1 in {
2613let isAsCheapAsAMove = 1 in {
2614def MVE_VMOVimmi8  : MVE_mod_imm<"vmov", "i8",  {1,1,1,0}, 0b0, (ins nImmSplatI8:$imm), 0b00>;
2615def MVE_VMOVimmi16 : MVE_mod_imm<"vmov", "i16", {1,0,?,0}, 0b0, (ins nImmSplatI16:$imm), 0b01> {
2616  let Inst{9} = imm{9};
2617}
2618def MVE_VMOVimmi32 : MVE_mod_imm<"vmov", "i32", {?,?,?,?}, 0b0, (ins nImmVMOVI32:$imm), 0b10> {
2619  let Inst{11-8} = imm{11-8};
2620}
2621def MVE_VMOVimmi64 : MVE_mod_imm<"vmov", "i64", {1,1,1,0}, 0b1, (ins nImmSplatI64:$imm), 0b11>;
2622def MVE_VMOVimmf32 : MVE_mod_imm<"vmov", "f32", {1,1,1,1}, 0b0, (ins nImmVMOVF32:$imm), 0b10>;
2623} // let isAsCheapAsAMove = 1
2624
2625def MVE_VMVNimmi16 : MVE_mod_imm<"vmvn", "i16", {1,0,?,0}, 0b1, (ins nImmSplatI16:$imm), 0b01> {
2626  let Inst{9} = imm{9};
2627}
2628def MVE_VMVNimmi32 : MVE_mod_imm<"vmvn", "i32", {?,?,?,?}, 0b1, (ins nImmVMOVI32:$imm), 0b10> {
2629  let Inst{11-8} = imm{11-8};
2630}
2631} // let isReMaterializable = 1
2632
2633let Predicates = [HasMVEInt] in {
2634  def : Pat<(v16i8 (ARMvmovImm timm:$simm)),
2635            (v16i8 (MVE_VMOVimmi8  nImmSplatI8:$simm))>;
2636  def : Pat<(v8i16 (ARMvmovImm timm:$simm)),
2637            (v8i16 (MVE_VMOVimmi16 nImmSplatI16:$simm))>;
2638  def : Pat<(v4i32 (ARMvmovImm timm:$simm)),
2639            (v4i32 (MVE_VMOVimmi32 nImmVMOVI32:$simm))>;
2640  def : Pat<(v2i64 (ARMvmovImm timm:$simm)),
2641            (v2i64 (MVE_VMOVimmi64 nImmSplatI64:$simm))>;
2642
2643  def : Pat<(v8i16 (ARMvmvnImm timm:$simm)),
2644            (v8i16 (MVE_VMVNimmi16 nImmSplatI16:$simm))>;
2645  def : Pat<(v4i32 (ARMvmvnImm timm:$simm)),
2646            (v4i32 (MVE_VMVNimmi32 nImmVMOVI32:$simm))>;
2647
2648  def : Pat<(v4f32 (ARMvmovFPImm timm:$simm)),
2649            (v4f32 (MVE_VMOVimmf32 nImmVMOVF32:$simm))>;
2650
2651  def : Pat<(v8i16 (vselect (v8i1 VCCR:$pred), (ARMvmvnImm timm:$simm),
2652                            MQPR:$inactive)),
2653            (v8i16 (MVE_VMVNimmi16 nImmSplatI16:$simm,
2654                            ARMVCCThen, VCCR:$pred, zero_reg, MQPR:$inactive))>;
2655  def : Pat<(v4i32 (vselect (v4i1 VCCR:$pred), (ARMvmvnImm timm:$simm),
2656                            MQPR:$inactive)),
2657            (v4i32 (MVE_VMVNimmi32 nImmSplatI32:$simm,
2658                            ARMVCCThen, VCCR:$pred, zero_reg, MQPR:$inactive))>;
2659}
2660
2661class MVE_VMINMAXA<string iname, string suffix, bits<2> size,
2662                   bit bit_12, list<dag> pattern=[]>
2663  : MVE_p<(outs MQPR:$Qd), (ins MQPR:$Qd_src, MQPR:$Qm),
2664          NoItinerary, iname, suffix, "$Qd, $Qm", vpred_n, "$Qd = $Qd_src",
2665          size, pattern> {
2666  bits<4> Qd;
2667  bits<4> Qm;
2668
2669  let Inst{28} = 0b0;
2670  let Inst{25-23} = 0b100;
2671  let Inst{22} = Qd{3};
2672  let Inst{21-20} = 0b11;
2673  let Inst{19-18} = size;
2674  let Inst{17-16} = 0b11;
2675  let Inst{15-13} = Qd{2-0};
2676  let Inst{12} = bit_12;
2677  let Inst{11-6} = 0b111010;
2678  let Inst{5} = Qm{3};
2679  let Inst{4} = 0b0;
2680  let Inst{3-1} = Qm{2-0};
2681  let Inst{0} = 0b1;
2682  let validForTailPredication = 1;
2683}
2684
2685multiclass MVE_VMINMAXA_m<string iname, MVEVectorVTInfo VTI,
2686                      SDNode unpred_op, Intrinsic pred_int, bit bit_12> {
2687  def "" : MVE_VMINMAXA<iname, VTI.Suffix, VTI.Size, bit_12>;
2688  defvar Inst = !cast<Instruction>(NAME);
2689
2690  let Predicates = [HasMVEInt] in {
2691    // Unpredicated v(min|max)a
2692    def : Pat<(VTI.Vec (unpred_op (VTI.Vec MQPR:$Qd), (abs (VTI.Vec MQPR:$Qm)))),
2693              (VTI.Vec (Inst (VTI.Vec MQPR:$Qd), (VTI.Vec MQPR:$Qm)))>;
2694
2695    // Predicated v(min|max)a
2696    def : Pat<(VTI.Vec (pred_int (VTI.Vec MQPR:$Qd), (VTI.Vec MQPR:$Qm),
2697                            (VTI.Pred VCCR:$mask))),
2698              (VTI.Vec (Inst (VTI.Vec MQPR:$Qd), (VTI.Vec MQPR:$Qm),
2699                            ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg))>;
2700  }
2701}
2702
2703multiclass MVE_VMINA<MVEVectorVTInfo VTI>
2704  : MVE_VMINMAXA_m<"vmina", VTI, umin, int_arm_mve_vmina_predicated, 0b1>;
2705
2706defm MVE_VMINAs8  : MVE_VMINA<MVE_v16s8>;
2707defm MVE_VMINAs16 : MVE_VMINA<MVE_v8s16>;
2708defm MVE_VMINAs32 : MVE_VMINA<MVE_v4s32>;
2709
2710multiclass MVE_VMAXA<MVEVectorVTInfo VTI>
2711  : MVE_VMINMAXA_m<"vmaxa", VTI, umax, int_arm_mve_vmaxa_predicated, 0b0>;
2712
2713defm MVE_VMAXAs8  : MVE_VMAXA<MVE_v16s8>;
2714defm MVE_VMAXAs16 : MVE_VMAXA<MVE_v8s16>;
2715defm MVE_VMAXAs32 : MVE_VMAXA<MVE_v4s32>;
2716
2717// end of MVE Integer instructions
2718
2719// start of mve_imm_shift instructions
2720
2721def MVE_VSHLC : MVE_p<(outs rGPR:$RdmDest, MQPR:$Qd),
2722                      (ins MQPR:$QdSrc, rGPR:$RdmSrc, long_shift:$imm),
2723                      NoItinerary, "vshlc", "", "$QdSrc, $RdmSrc, $imm",
2724                      vpred_n, "$RdmDest = $RdmSrc,$Qd = $QdSrc", 0b10> {
2725  bits<5> imm;
2726  bits<4> Qd;
2727  bits<4> RdmDest;
2728
2729  let Inst{28} = 0b0;
2730  let Inst{25-23} = 0b101;
2731  let Inst{22} = Qd{3};
2732  let Inst{21} = 0b1;
2733  let Inst{20-16} = imm{4-0};
2734  let Inst{15-13} = Qd{2-0};
2735  let Inst{12-4} = 0b011111100;
2736  let Inst{3-0} = RdmDest{3-0};
2737}
2738
2739class MVE_shift_imm<dag oops, dag iops, string iname, string suffix,
2740                    string ops, vpred_ops vpred, string cstr,
2741                    bits<2> vecsize, list<dag> pattern=[]>
2742  : MVE_p<oops, iops, NoItinerary, iname, suffix, ops, vpred, cstr, vecsize, pattern> {
2743  bits<4> Qd;
2744  bits<4> Qm;
2745
2746  let Inst{22} = Qd{3};
2747  let Inst{15-13} = Qd{2-0};
2748  let Inst{5} = Qm{3};
2749  let Inst{3-1} = Qm{2-0};
2750}
2751
2752class MVE_VMOVL<string iname, string suffix, bits<2> sz, bit U, bit top,
2753              list<dag> pattern=[]>
2754  : MVE_shift_imm<(outs MQPR:$Qd), (ins MQPR:$Qm),
2755                  iname, suffix, "$Qd, $Qm", vpred_r, "",
2756                  sz, pattern> {
2757  let Inst{28} = U;
2758  let Inst{25-23} = 0b101;
2759  let Inst{21} = 0b1;
2760  let Inst{20-19} = sz{1-0};
2761  let Inst{18-16} = 0b000;
2762  let Inst{12} = top;
2763  let Inst{11-6} = 0b111101;
2764  let Inst{4} = 0b0;
2765  let Inst{0} = 0b0;
2766  let doubleWidthResult = 1;
2767}
2768
2769multiclass MVE_VMOVL_m<bit top, string chr, MVEVectorVTInfo OutVTI,
2770                       MVEVectorVTInfo InVTI> {
2771  def "": MVE_VMOVL<"vmovl" # chr, InVTI.Suffix, OutVTI.Size,
2772                    InVTI.Unsigned, top>;
2773  defvar Inst = !cast<Instruction>(NAME);
2774
2775  def : Pat<(OutVTI.Vec (int_arm_mve_vmovl_predicated (InVTI.Vec MQPR:$src),
2776                            (i32 InVTI.Unsigned), (i32 top),
2777                            (OutVTI.Pred VCCR:$pred),
2778                            (OutVTI.Vec MQPR:$inactive))),
2779            (OutVTI.Vec (Inst (InVTI.Vec MQPR:$src), ARMVCCThen,
2780                            (OutVTI.Pred VCCR:$pred), zero_reg,
2781                            (OutVTI.Vec MQPR:$inactive)))>;
2782}
2783
2784defm MVE_VMOVLs8bh  : MVE_VMOVL_m<0, "b", MVE_v8s16, MVE_v16s8>;
2785defm MVE_VMOVLs8th  : MVE_VMOVL_m<1, "t", MVE_v8s16, MVE_v16s8>;
2786defm MVE_VMOVLu8bh  : MVE_VMOVL_m<0, "b", MVE_v8u16, MVE_v16u8>;
2787defm MVE_VMOVLu8th  : MVE_VMOVL_m<1, "t", MVE_v8u16, MVE_v16u8>;
2788defm MVE_VMOVLs16bh : MVE_VMOVL_m<0, "b", MVE_v4s32, MVE_v8s16>;
2789defm MVE_VMOVLs16th : MVE_VMOVL_m<1, "t", MVE_v4s32, MVE_v8s16>;
2790defm MVE_VMOVLu16bh : MVE_VMOVL_m<0, "b", MVE_v4s32, MVE_v8u16>;
2791defm MVE_VMOVLu16th : MVE_VMOVL_m<1, "t", MVE_v4s32, MVE_v8u16>;
2792
2793let Predicates = [HasMVEInt] in {
2794  def : Pat<(sext_inreg (v4i32 MQPR:$src), v4i16),
2795            (MVE_VMOVLs16bh MQPR:$src)>;
2796  def : Pat<(sext_inreg (v8i16 MQPR:$src), v8i8),
2797            (MVE_VMOVLs8bh MQPR:$src)>;
2798  def : Pat<(sext_inreg (v4i32 MQPR:$src), v4i8),
2799            (MVE_VMOVLs16bh (MVE_VMOVLs8bh MQPR:$src))>;
2800
2801  def : Pat<(sext_inreg (v8i16 (ARMVectorRegCast (ARMvrev16 (v16i8 MQPR:$src)))), v8i8),
2802            (MVE_VMOVLs8th MQPR:$src)>;
2803  def : Pat<(sext_inreg (v4i32 (ARMVectorRegCast (ARMvrev32 (v8i16 MQPR:$src)))), v4i16),
2804            (MVE_VMOVLs16th MQPR:$src)>;
2805
2806  // zext_inreg 8 -> 16
2807  def : Pat<(ARMvbicImm (v8i16 MQPR:$src), (i32 0xAFF)),
2808            (MVE_VMOVLu8bh MQPR:$src)>;
2809  // zext_inreg 16 -> 32
2810  def : Pat<(and (v4i32 MQPR:$src), (v4i32 (ARMvmovImm (i32 0xCFF)))),
2811            (MVE_VMOVLu16bh MQPR:$src)>;
2812  // Same zext_inreg with vrevs, picking the top half
2813  def : Pat<(ARMvbicImm (v8i16 (ARMVectorRegCast (ARMvrev16 (v16i8 MQPR:$src)))), (i32 0xAFF)),
2814            (MVE_VMOVLu8th MQPR:$src)>;
2815  def : Pat<(and (v4i32 (ARMVectorRegCast (ARMvrev32 (v8i16 MQPR:$src)))),
2816                 (v4i32 (ARMvmovImm (i32 0xCFF)))),
2817            (MVE_VMOVLu16th MQPR:$src)>;
2818}
2819
2820
2821class MVE_VSHLL_imm<string iname, string suffix, bit U, bit th,
2822                    Operand immtype, bits<2> vecsize, list<dag> pattern=[]>
2823  : MVE_shift_imm<(outs MQPR:$Qd), (ins MQPR:$Qm, immtype:$imm),
2824                  iname, suffix, "$Qd, $Qm, $imm", vpred_r, "", vecsize, pattern> {
2825  let Inst{28} = U;
2826  let Inst{25-23} = 0b101;
2827  let Inst{21} = 0b1;
2828  let Inst{12} = th;
2829  let Inst{11-6} = 0b111101;
2830  let Inst{4} = 0b0;
2831  let Inst{0} = 0b0;
2832
2833  // For the MVE_VSHLL_patterns multiclass to refer to
2834  Operand immediateType = immtype;
2835
2836  let doubleWidthResult = 1;
2837}
2838
2839// The immediate VSHLL instructions accept shift counts from 1 up to
2840// the lane width (8 or 16), but the full-width shifts have an
2841// entirely separate encoding, given below with 'lw' in the name.
2842
2843class MVE_VSHLL_imm8<string iname, string suffix,
2844                     bit U, bit th, list<dag> pattern=[]>
2845  : MVE_VSHLL_imm<iname, suffix, U, th, mve_shift_imm1_7, 0b01, pattern> {
2846  bits<3> imm;
2847  let Inst{20-19} = 0b01;
2848  let Inst{18-16} = imm;
2849}
2850
2851class MVE_VSHLL_imm16<string iname, string suffix,
2852                      bit U, bit th, list<dag> pattern=[]>
2853  : MVE_VSHLL_imm<iname, suffix, U, th, mve_shift_imm1_15, 0b10, pattern> {
2854  bits<4> imm;
2855  let Inst{20} = 0b1;
2856  let Inst{19-16} = imm;
2857}
2858
2859def MVE_VSHLL_imms8bh  : MVE_VSHLL_imm8 <"vshllb", "s8", 0b0, 0b0>;
2860def MVE_VSHLL_imms8th  : MVE_VSHLL_imm8 <"vshllt", "s8", 0b0, 0b1>;
2861def MVE_VSHLL_immu8bh  : MVE_VSHLL_imm8 <"vshllb", "u8", 0b1, 0b0>;
2862def MVE_VSHLL_immu8th  : MVE_VSHLL_imm8 <"vshllt", "u8", 0b1, 0b1>;
2863def MVE_VSHLL_imms16bh : MVE_VSHLL_imm16<"vshllb", "s16", 0b0, 0b0>;
2864def MVE_VSHLL_imms16th : MVE_VSHLL_imm16<"vshllt", "s16", 0b0, 0b1>;
2865def MVE_VSHLL_immu16bh : MVE_VSHLL_imm16<"vshllb", "u16", 0b1, 0b0>;
2866def MVE_VSHLL_immu16th : MVE_VSHLL_imm16<"vshllt", "u16", 0b1, 0b1>;
2867
2868class MVE_VSHLL_by_lane_width<string iname, string suffix, bits<2> size,
2869                              bit U, string ops, list<dag> pattern=[]>
2870  : MVE_shift_imm<(outs MQPR:$Qd), (ins MQPR:$Qm),
2871                  iname, suffix, ops, vpred_r, "", !if(size, 0b10, 0b01), pattern> {
2872  let Inst{28} = U;
2873  let Inst{25-23} = 0b100;
2874  let Inst{21-20} = 0b11;
2875  let Inst{19-18} = size{1-0};
2876  let Inst{17-16} = 0b01;
2877  let Inst{11-6} = 0b111000;
2878  let Inst{4} = 0b0;
2879  let Inst{0} = 0b1;
2880  let doubleWidthResult = 1;
2881}
2882
2883multiclass MVE_VSHLL_lw<string iname, string suffix, bits<2> sz, bit U,
2884                              string ops, list<dag> pattern=[]> {
2885  def bh : MVE_VSHLL_by_lane_width<iname#"b", suffix, sz, U, ops, pattern> {
2886    let Inst{12} = 0b0;
2887  }
2888  def th : MVE_VSHLL_by_lane_width<iname#"t", suffix, sz, U, ops, pattern> {
2889    let Inst{12} = 0b1;
2890  }
2891}
2892
2893defm MVE_VSHLL_lws8  : MVE_VSHLL_lw<"vshll", "s8",  0b00, 0b0, "$Qd, $Qm, #8">;
2894defm MVE_VSHLL_lws16 : MVE_VSHLL_lw<"vshll", "s16", 0b01, 0b0, "$Qd, $Qm, #16">;
2895defm MVE_VSHLL_lwu8  : MVE_VSHLL_lw<"vshll", "u8",  0b00, 0b1, "$Qd, $Qm, #8">;
2896defm MVE_VSHLL_lwu16 : MVE_VSHLL_lw<"vshll", "u16", 0b01, 0b1, "$Qd, $Qm, #16">;
2897
2898multiclass MVE_VSHLL_patterns<MVEVectorVTInfo VTI, int top> {
2899  defvar suffix     = !strconcat(VTI.Suffix, !if(top, "th", "bh"));
2900  defvar inst_imm   = !cast<MVE_VSHLL_imm>("MVE_VSHLL_imm" # suffix);
2901  defvar inst_lw    = !cast<MVE_VSHLL_by_lane_width>("MVE_VSHLL_lw" # suffix);
2902  defvar unpred_int = int_arm_mve_vshll_imm;
2903  defvar pred_int   = int_arm_mve_vshll_imm_predicated;
2904  defvar imm        = inst_imm.immediateType;
2905
2906  def : Pat<(VTI.DblVec (unpred_int (VTI.Vec MQPR:$src), imm:$imm,
2907                                    (i32 VTI.Unsigned), (i32 top))),
2908            (VTI.DblVec (inst_imm   (VTI.Vec MQPR:$src), imm:$imm))>;
2909  def : Pat<(VTI.DblVec (unpred_int (VTI.Vec MQPR:$src), (i32 VTI.LaneBits),
2910                                    (i32 VTI.Unsigned), (i32 top))),
2911            (VTI.DblVec (inst_lw    (VTI.Vec MQPR:$src)))>;
2912
2913  def : Pat<(VTI.DblVec (pred_int   (VTI.Vec MQPR:$src), imm:$imm,
2914                                    (i32 VTI.Unsigned), (i32 top),
2915                                    (VTI.DblPred VCCR:$mask),
2916                                    (VTI.DblVec MQPR:$inactive))),
2917            (VTI.DblVec (inst_imm   (VTI.Vec MQPR:$src), imm:$imm,
2918                                    ARMVCCThen, (VTI.DblPred VCCR:$mask), zero_reg,
2919                                    (VTI.DblVec MQPR:$inactive)))>;
2920  def : Pat<(VTI.DblVec (pred_int   (VTI.Vec MQPR:$src), (i32 VTI.LaneBits),
2921                                    (i32 VTI.Unsigned), (i32 top),
2922                                    (VTI.DblPred VCCR:$mask),
2923                                    (VTI.DblVec MQPR:$inactive))),
2924            (VTI.DblVec (inst_lw    (VTI.Vec MQPR:$src), ARMVCCThen,
2925                                    (VTI.DblPred VCCR:$mask), zero_reg,
2926                                    (VTI.DblVec MQPR:$inactive)))>;
2927}
2928
2929foreach VTI = [MVE_v16s8, MVE_v8s16, MVE_v16u8, MVE_v8u16] in
2930  foreach top = [0, 1] in
2931    defm : MVE_VSHLL_patterns<VTI, top>;
2932
2933class MVE_shift_imm_partial<Operand imm, string iname, string suffix, bits<2> vecsize>
2934  : MVE_shift_imm<(outs MQPR:$Qd), (ins MQPR:$QdSrc, MQPR:$Qm, imm:$imm),
2935                  iname, suffix, "$Qd, $Qm, $imm", vpred_n, "$Qd = $QdSrc", vecsize> {
2936  Operand immediateType = imm;
2937}
2938
2939class MVE_VxSHRN<string iname, string suffix, bit bit_12, bit bit_28,
2940                 Operand imm, bits<2> vecsize>
2941  : MVE_shift_imm_partial<imm, iname, suffix, vecsize> {
2942  bits<5> imm;
2943
2944  let Inst{28} = bit_28;
2945  let Inst{25-23} = 0b101;
2946  let Inst{21} = 0b0;
2947  let Inst{20-16} = imm{4-0};
2948  let Inst{12} = bit_12;
2949  let Inst{11-6} = 0b111111;
2950  let Inst{4} = 0b0;
2951  let Inst{0} = 0b1;
2952  let validForTailPredication = 1;
2953  let retainsPreviousHalfElement = 1;
2954}
2955
2956def MVE_VRSHRNi16bh : MVE_VxSHRN<"vrshrnb", "i16", 0b0, 0b1, shr_imm8, 0b01> {
2957  let Inst{20-19} = 0b01;
2958}
2959def MVE_VRSHRNi16th : MVE_VxSHRN<"vrshrnt", "i16", 0b1, 0b1, shr_imm8, 0b01> {
2960  let Inst{20-19} = 0b01;
2961}
2962def MVE_VRSHRNi32bh : MVE_VxSHRN<"vrshrnb", "i32", 0b0, 0b1, shr_imm16, 0b10> {
2963  let Inst{20} = 0b1;
2964}
2965def MVE_VRSHRNi32th : MVE_VxSHRN<"vrshrnt", "i32", 0b1, 0b1, shr_imm16, 0b10> {
2966  let Inst{20} = 0b1;
2967}
2968
2969def MVE_VSHRNi16bh : MVE_VxSHRN<"vshrnb", "i16", 0b0, 0b0, shr_imm8, 0b01> {
2970  let Inst{20-19} = 0b01;
2971}
2972def MVE_VSHRNi16th : MVE_VxSHRN<"vshrnt", "i16", 0b1, 0b0, shr_imm8, 0b01> {
2973  let Inst{20-19} = 0b01;
2974}
2975def MVE_VSHRNi32bh : MVE_VxSHRN<"vshrnb", "i32", 0b0, 0b0, shr_imm16, 0b10> {
2976  let Inst{20} = 0b1;
2977}
2978def MVE_VSHRNi32th : MVE_VxSHRN<"vshrnt", "i32", 0b1, 0b0, shr_imm16, 0b10> {
2979  let Inst{20} = 0b1;
2980}
2981
2982class MVE_VxQRSHRUN<string iname, string suffix, bit bit_28, bit bit_12,
2983                    Operand imm, bits<2> vecsize>
2984  : MVE_shift_imm_partial<imm, iname, suffix, vecsize> {
2985  bits<5> imm;
2986
2987  let Inst{28} = bit_28;
2988  let Inst{25-23} = 0b101;
2989  let Inst{21} = 0b0;
2990  let Inst{20-16} = imm{4-0};
2991  let Inst{12} = bit_12;
2992  let Inst{11-6} = 0b111111;
2993  let Inst{4} = 0b0;
2994  let Inst{0} = 0b0;
2995  let validForTailPredication = 1;
2996  let retainsPreviousHalfElement = 1;
2997}
2998
2999def MVE_VQRSHRUNs16bh : MVE_VxQRSHRUN<
3000    "vqrshrunb", "s16", 0b1, 0b0, shr_imm8, 0b01> {
3001  let Inst{20-19} = 0b01;
3002}
3003def MVE_VQRSHRUNs16th : MVE_VxQRSHRUN<
3004    "vqrshrunt", "s16", 0b1, 0b1, shr_imm8, 0b01> {
3005  let Inst{20-19} = 0b01;
3006}
3007def MVE_VQRSHRUNs32bh : MVE_VxQRSHRUN<
3008    "vqrshrunb", "s32", 0b1, 0b0, shr_imm16, 0b10> {
3009  let Inst{20} = 0b1;
3010}
3011def MVE_VQRSHRUNs32th : MVE_VxQRSHRUN<
3012    "vqrshrunt", "s32", 0b1, 0b1, shr_imm16, 0b10> {
3013  let Inst{20} = 0b1;
3014}
3015
3016def MVE_VQSHRUNs16bh : MVE_VxQRSHRUN<
3017    "vqshrunb", "s16", 0b0, 0b0, shr_imm8, 0b01> {
3018  let Inst{20-19} = 0b01;
3019}
3020def MVE_VQSHRUNs16th : MVE_VxQRSHRUN<
3021    "vqshrunt", "s16", 0b0, 0b1, shr_imm8, 0b01> {
3022  let Inst{20-19} = 0b01;
3023}
3024def MVE_VQSHRUNs32bh : MVE_VxQRSHRUN<
3025    "vqshrunb", "s32", 0b0, 0b0, shr_imm16, 0b10> {
3026  let Inst{20} = 0b1;
3027}
3028def MVE_VQSHRUNs32th : MVE_VxQRSHRUN<
3029    "vqshrunt", "s32", 0b0, 0b1, shr_imm16, 0b10> {
3030  let Inst{20} = 0b1;
3031}
3032
3033class MVE_VxQRSHRN<string iname, string suffix, bit bit_0, bit bit_12,
3034                   Operand imm, bits<2> vecsize>
3035  : MVE_shift_imm_partial<imm, iname, suffix, vecsize> {
3036  bits<5> imm;
3037
3038  let Inst{25-23} = 0b101;
3039  let Inst{21} = 0b0;
3040  let Inst{20-16} = imm{4-0};
3041  let Inst{12} = bit_12;
3042  let Inst{11-6} = 0b111101;
3043  let Inst{4} = 0b0;
3044  let Inst{0} = bit_0;
3045  let validForTailPredication = 1;
3046  let retainsPreviousHalfElement = 1;
3047}
3048
3049multiclass MVE_VxQRSHRN_types<string iname, bit bit_0, bit bit_12> {
3050  def s16 : MVE_VxQRSHRN<iname, "s16", bit_0, bit_12, shr_imm8, 0b01> {
3051    let Inst{28} = 0b0;
3052    let Inst{20-19} = 0b01;
3053  }
3054  def u16 : MVE_VxQRSHRN<iname, "u16", bit_0, bit_12, shr_imm8, 0b01> {
3055    let Inst{28} = 0b1;
3056    let Inst{20-19} = 0b01;
3057  }
3058  def s32 : MVE_VxQRSHRN<iname, "s32", bit_0, bit_12, shr_imm16, 0b10> {
3059    let Inst{28} = 0b0;
3060    let Inst{20} = 0b1;
3061  }
3062  def u32 : MVE_VxQRSHRN<iname, "u32", bit_0, bit_12, shr_imm16, 0b10> {
3063    let Inst{28} = 0b1;
3064    let Inst{20} = 0b1;
3065  }
3066}
3067
3068defm MVE_VQRSHRNbh : MVE_VxQRSHRN_types<"vqrshrnb", 0b1, 0b0>;
3069defm MVE_VQRSHRNth : MVE_VxQRSHRN_types<"vqrshrnt", 0b1, 0b1>;
3070defm MVE_VQSHRNbh  : MVE_VxQRSHRN_types<"vqshrnb", 0b0, 0b0>;
3071defm MVE_VQSHRNth  : MVE_VxQRSHRN_types<"vqshrnt", 0b0, 0b1>;
3072
3073multiclass MVE_VSHRN_patterns<MVE_shift_imm_partial inst,
3074                              MVEVectorVTInfo OutVTI, MVEVectorVTInfo InVTI,
3075                              bit q, bit r, bit top> {
3076  defvar inparams = (? (OutVTI.Vec MQPR:$QdSrc), (InVTI.Vec MQPR:$Qm),
3077                       (inst.immediateType:$imm), (i32 q), (i32 r),
3078                       (i32 OutVTI.Unsigned), (i32 InVTI.Unsigned), (i32 top));
3079  defvar outparams = (inst (OutVTI.Vec MQPR:$QdSrc), (InVTI.Vec MQPR:$Qm),
3080                           (imm:$imm));
3081
3082  def : Pat<(OutVTI.Vec !setdagop(inparams, int_arm_mve_vshrn)),
3083            (OutVTI.Vec outparams)>;
3084  def : Pat<(OutVTI.Vec !con(inparams, (int_arm_mve_vshrn_predicated
3085                                           (InVTI.Pred VCCR:$pred)))),
3086            (OutVTI.Vec !con(outparams, (? ARMVCCThen, VCCR:$pred, zero_reg)))>;
3087}
3088
3089defm : MVE_VSHRN_patterns<MVE_VSHRNi16bh,    MVE_v16s8, MVE_v8s16, 0,0,0>;
3090defm : MVE_VSHRN_patterns<MVE_VSHRNi16th,    MVE_v16s8, MVE_v8s16, 0,0,1>;
3091defm : MVE_VSHRN_patterns<MVE_VSHRNi32bh,    MVE_v8s16, MVE_v4s32, 0,0,0>;
3092defm : MVE_VSHRN_patterns<MVE_VSHRNi32th,    MVE_v8s16, MVE_v4s32, 0,0,1>;
3093defm : MVE_VSHRN_patterns<MVE_VSHRNi16bh,    MVE_v16u8, MVE_v8u16, 0,0,0>;
3094defm : MVE_VSHRN_patterns<MVE_VSHRNi16th,    MVE_v16u8, MVE_v8u16, 0,0,1>;
3095defm : MVE_VSHRN_patterns<MVE_VSHRNi32bh,    MVE_v8u16, MVE_v4u32, 0,0,0>;
3096defm : MVE_VSHRN_patterns<MVE_VSHRNi32th,    MVE_v8u16, MVE_v4u32, 0,0,1>;
3097defm : MVE_VSHRN_patterns<MVE_VRSHRNi16bh,   MVE_v16s8, MVE_v8s16, 0,1,0>;
3098defm : MVE_VSHRN_patterns<MVE_VRSHRNi16th,   MVE_v16s8, MVE_v8s16, 0,1,1>;
3099defm : MVE_VSHRN_patterns<MVE_VRSHRNi32bh,   MVE_v8s16, MVE_v4s32, 0,1,0>;
3100defm : MVE_VSHRN_patterns<MVE_VRSHRNi32th,   MVE_v8s16, MVE_v4s32, 0,1,1>;
3101defm : MVE_VSHRN_patterns<MVE_VRSHRNi16bh,   MVE_v16u8, MVE_v8u16, 0,1,0>;
3102defm : MVE_VSHRN_patterns<MVE_VRSHRNi16th,   MVE_v16u8, MVE_v8u16, 0,1,1>;
3103defm : MVE_VSHRN_patterns<MVE_VRSHRNi32bh,   MVE_v8u16, MVE_v4u32, 0,1,0>;
3104defm : MVE_VSHRN_patterns<MVE_VRSHRNi32th,   MVE_v8u16, MVE_v4u32, 0,1,1>;
3105defm : MVE_VSHRN_patterns<MVE_VQSHRNbhs16,   MVE_v16s8, MVE_v8s16, 1,0,0>;
3106defm : MVE_VSHRN_patterns<MVE_VQSHRNths16,   MVE_v16s8, MVE_v8s16, 1,0,1>;
3107defm : MVE_VSHRN_patterns<MVE_VQSHRNbhs32,   MVE_v8s16, MVE_v4s32, 1,0,0>;
3108defm : MVE_VSHRN_patterns<MVE_VQSHRNths32,   MVE_v8s16, MVE_v4s32, 1,0,1>;
3109defm : MVE_VSHRN_patterns<MVE_VQSHRNbhu16,   MVE_v16u8, MVE_v8u16, 1,0,0>;
3110defm : MVE_VSHRN_patterns<MVE_VQSHRNthu16,   MVE_v16u8, MVE_v8u16, 1,0,1>;
3111defm : MVE_VSHRN_patterns<MVE_VQSHRNbhu32,   MVE_v8u16, MVE_v4u32, 1,0,0>;
3112defm : MVE_VSHRN_patterns<MVE_VQSHRNthu32,   MVE_v8u16, MVE_v4u32, 1,0,1>;
3113defm : MVE_VSHRN_patterns<MVE_VQRSHRNbhs16,  MVE_v16s8, MVE_v8s16, 1,1,0>;
3114defm : MVE_VSHRN_patterns<MVE_VQRSHRNths16,  MVE_v16s8, MVE_v8s16, 1,1,1>;
3115defm : MVE_VSHRN_patterns<MVE_VQRSHRNbhs32,  MVE_v8s16, MVE_v4s32, 1,1,0>;
3116defm : MVE_VSHRN_patterns<MVE_VQRSHRNths32,  MVE_v8s16, MVE_v4s32, 1,1,1>;
3117defm : MVE_VSHRN_patterns<MVE_VQRSHRNbhu16,  MVE_v16u8, MVE_v8u16, 1,1,0>;
3118defm : MVE_VSHRN_patterns<MVE_VQRSHRNthu16,  MVE_v16u8, MVE_v8u16, 1,1,1>;
3119defm : MVE_VSHRN_patterns<MVE_VQRSHRNbhu32,  MVE_v8u16, MVE_v4u32, 1,1,0>;
3120defm : MVE_VSHRN_patterns<MVE_VQRSHRNthu32,  MVE_v8u16, MVE_v4u32, 1,1,1>;
3121defm : MVE_VSHRN_patterns<MVE_VQSHRUNs16bh,  MVE_v16u8, MVE_v8s16, 1,0,0>;
3122defm : MVE_VSHRN_patterns<MVE_VQSHRUNs16th,  MVE_v16u8, MVE_v8s16, 1,0,1>;
3123defm : MVE_VSHRN_patterns<MVE_VQSHRUNs32bh,  MVE_v8u16, MVE_v4s32, 1,0,0>;
3124defm : MVE_VSHRN_patterns<MVE_VQSHRUNs32th,  MVE_v8u16, MVE_v4s32, 1,0,1>;
3125defm : MVE_VSHRN_patterns<MVE_VQRSHRUNs16bh, MVE_v16u8, MVE_v8s16, 1,1,0>;
3126defm : MVE_VSHRN_patterns<MVE_VQRSHRUNs16th, MVE_v16u8, MVE_v8s16, 1,1,1>;
3127defm : MVE_VSHRN_patterns<MVE_VQRSHRUNs32bh, MVE_v8u16, MVE_v4s32, 1,1,0>;
3128defm : MVE_VSHRN_patterns<MVE_VQRSHRUNs32th, MVE_v8u16, MVE_v4s32, 1,1,1>;
3129
3130// end of mve_imm_shift instructions
3131
3132// start of mve_shift instructions
3133
3134class MVE_shift_by_vec<string iname, string suffix, bit U,
3135                       bits<2> size, bit bit_4, bit bit_8>
3136  : MVE_p<(outs MQPR:$Qd), (ins MQPR:$Qm, MQPR:$Qn), NoItinerary,
3137           iname, suffix, "$Qd, $Qm, $Qn", vpred_r, "", size, []> {
3138  // Shift instructions which take a vector of shift counts
3139  bits<4> Qd;
3140  bits<4> Qm;
3141  bits<4> Qn;
3142
3143  let Inst{28} = U;
3144  let Inst{25-24} = 0b11;
3145  let Inst{23} = 0b0;
3146  let Inst{22} = Qd{3};
3147  let Inst{21-20} = size;
3148  let Inst{19-17} = Qn{2-0};
3149  let Inst{16} = 0b0;
3150  let Inst{15-13} = Qd{2-0};
3151  let Inst{12-9} = 0b0010;
3152  let Inst{8} = bit_8;
3153  let Inst{7} = Qn{3};
3154  let Inst{6} = 0b1;
3155  let Inst{5} = Qm{3};
3156  let Inst{4} = bit_4;
3157  let Inst{3-1} = Qm{2-0};
3158  let Inst{0} = 0b0;
3159  let validForTailPredication = 1;
3160}
3161
3162multiclass MVE_shift_by_vec_p<string iname, MVEVectorVTInfo VTI, bit q, bit r> {
3163  def "" : MVE_shift_by_vec<iname, VTI.Suffix, VTI.Unsigned, VTI.Size, q, r>;
3164  defvar Inst = !cast<Instruction>(NAME);
3165
3166  def : Pat<(VTI.Vec (int_arm_mve_vshl_vector
3167                         (VTI.Vec MQPR:$in), (VTI.Vec MQPR:$sh),
3168                         (i32 q), (i32 r), (i32 VTI.Unsigned))),
3169            (VTI.Vec (Inst (VTI.Vec MQPR:$in), (VTI.Vec MQPR:$sh)))>;
3170
3171  def : Pat<(VTI.Vec (int_arm_mve_vshl_vector_predicated
3172                         (VTI.Vec MQPR:$in), (VTI.Vec MQPR:$sh),
3173                         (i32 q), (i32 r), (i32 VTI.Unsigned),
3174                         (VTI.Pred VCCR:$mask), (VTI.Vec MQPR:$inactive))),
3175            (VTI.Vec (Inst (VTI.Vec MQPR:$in), (VTI.Vec MQPR:$sh),
3176                           ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
3177                           (VTI.Vec MQPR:$inactive)))>;
3178}
3179
3180multiclass mve_shift_by_vec_multi<string iname, bit bit_4, bit bit_8> {
3181  defm s8  : MVE_shift_by_vec_p<iname, MVE_v16s8, bit_4, bit_8>;
3182  defm s16 : MVE_shift_by_vec_p<iname, MVE_v8s16, bit_4, bit_8>;
3183  defm s32 : MVE_shift_by_vec_p<iname, MVE_v4s32, bit_4, bit_8>;
3184  defm u8  : MVE_shift_by_vec_p<iname, MVE_v16u8, bit_4, bit_8>;
3185  defm u16 : MVE_shift_by_vec_p<iname, MVE_v8u16, bit_4, bit_8>;
3186  defm u32 : MVE_shift_by_vec_p<iname, MVE_v4u32, bit_4, bit_8>;
3187}
3188
3189defm MVE_VSHL_by_vec   : mve_shift_by_vec_multi<"vshl",   0b0, 0b0>;
3190defm MVE_VQSHL_by_vec  : mve_shift_by_vec_multi<"vqshl",  0b1, 0b0>;
3191defm MVE_VQRSHL_by_vec : mve_shift_by_vec_multi<"vqrshl", 0b1, 0b1>;
3192defm MVE_VRSHL_by_vec  : mve_shift_by_vec_multi<"vrshl",  0b0, 0b1>;
3193
3194let Predicates = [HasMVEInt] in {
3195  defm : MVE_TwoOpPattern<MVE_v16i8, ARMvshlu, int_arm_mve_vshl_vector_predicated,
3196                          (? (i32 0), (i32 0), (i32 1)), MVE_VSHL_by_vecu8, null_frag>;
3197  defm : MVE_TwoOpPattern<MVE_v8i16, ARMvshlu, int_arm_mve_vshl_vector_predicated,
3198                          (? (i32 0), (i32 0), (i32 1)), MVE_VSHL_by_vecu16, null_frag>;
3199  defm : MVE_TwoOpPattern<MVE_v4i32, ARMvshlu, int_arm_mve_vshl_vector_predicated,
3200                          (? (i32 0), (i32 0), (i32 1)), MVE_VSHL_by_vecu32, null_frag>;
3201  defm : MVE_TwoOpPattern<MVE_v16i8, ARMvshls, int_arm_mve_vshl_vector_predicated,
3202                          (? (i32 0), (i32 0), (i32 0)), MVE_VSHL_by_vecs8, null_frag>;
3203  defm : MVE_TwoOpPattern<MVE_v8i16, ARMvshls, int_arm_mve_vshl_vector_predicated,
3204                          (? (i32 0), (i32 0), (i32 0)), MVE_VSHL_by_vecs16, null_frag>;
3205  defm : MVE_TwoOpPattern<MVE_v4i32, ARMvshls, int_arm_mve_vshl_vector_predicated,
3206                          (? (i32 0), (i32 0), (i32 0)), MVE_VSHL_by_vecs32, null_frag>;
3207}
3208
3209class MVE_shift_with_imm<string iname, string suffix, dag oops, dag iops,
3210                         string ops, vpred_ops vpred, string cstr,
3211                         bits<2> vecsize, list<dag> pattern=[]>
3212  : MVE_p<oops, iops, NoItinerary, iname, suffix, ops, vpred, cstr, vecsize, pattern> {
3213  bits<4> Qd;
3214  bits<4> Qm;
3215
3216  let Inst{23} = 0b1;
3217  let Inst{22} = Qd{3};
3218  let Inst{15-13} = Qd{2-0};
3219  let Inst{12-11} = 0b00;
3220  let Inst{7-6} = 0b01;
3221  let Inst{5} = Qm{3};
3222  let Inst{4} = 0b1;
3223  let Inst{3-1} = Qm{2-0};
3224  let Inst{0} = 0b0;
3225  let validForTailPredication = 1;
3226
3227  // For the MVE_shift_imm_patterns multiclass to refer to
3228  MVEVectorVTInfo VTI;
3229  Operand immediateType;
3230  Intrinsic unpred_int;
3231  Intrinsic pred_int;
3232  dag unsignedFlag = (?);
3233}
3234
3235class MVE_VSxI_imm<string iname, string suffix, bit bit_8, Operand immType, bits<2> vecsize>
3236  : MVE_shift_with_imm<iname, suffix, (outs MQPR:$Qd),
3237                       (ins MQPR:$Qd_src, MQPR:$Qm, immType:$imm),
3238                       "$Qd, $Qm, $imm", vpred_n, "$Qd = $Qd_src", vecsize> {
3239  bits<6> imm;
3240  let Inst{28} = 0b1;
3241  let Inst{25-24} = 0b11;
3242  let Inst{21-16} = imm;
3243  let Inst{10-9} = 0b10;
3244  let Inst{8} = bit_8;
3245  let validForTailPredication = 1;
3246
3247  Operand immediateType = immType;
3248}
3249
3250def MVE_VSRIimm8 : MVE_VSxI_imm<"vsri", "8", 0b0, shr_imm8, 0b00> {
3251  let Inst{21-19} = 0b001;
3252}
3253
3254def MVE_VSRIimm16 : MVE_VSxI_imm<"vsri", "16", 0b0, shr_imm16, 0b01> {
3255  let Inst{21-20} = 0b01;
3256}
3257
3258def MVE_VSRIimm32 : MVE_VSxI_imm<"vsri", "32", 0b0, shr_imm32, 0b10> {
3259  let Inst{21} = 0b1;
3260}
3261
3262def MVE_VSLIimm8 : MVE_VSxI_imm<"vsli", "8", 0b1, imm0_7, 0b00> {
3263  let Inst{21-19} = 0b001;
3264}
3265
3266def MVE_VSLIimm16 : MVE_VSxI_imm<"vsli", "16", 0b1, imm0_15, 0b01> {
3267  let Inst{21-20} = 0b01;
3268}
3269
3270def MVE_VSLIimm32 : MVE_VSxI_imm<"vsli", "32", 0b1,imm0_31, 0b10> {
3271  let Inst{21} = 0b1;
3272}
3273
3274multiclass MVE_VSxI_patterns<MVE_VSxI_imm inst, string name,
3275                              MVEVectorVTInfo VTI> {
3276  defvar inparams = (? (VTI.Vec MQPR:$QdSrc), (VTI.Vec MQPR:$Qm),
3277                       (inst.immediateType:$imm));
3278  defvar outparams = (inst (VTI.Vec MQPR:$QdSrc), (VTI.Vec MQPR:$Qm),
3279                           (inst.immediateType:$imm));
3280  defvar unpred_int = !cast<Intrinsic>("int_arm_mve_" # name);
3281  defvar pred_int = !cast<Intrinsic>("int_arm_mve_" # name # "_predicated");
3282
3283  def : Pat<(VTI.Vec !setdagop(inparams, unpred_int)),
3284            (VTI.Vec outparams)>;
3285  def : Pat<(VTI.Vec !con(inparams, (pred_int (VTI.Pred VCCR:$pred)))),
3286            (VTI.Vec !con(outparams, (? ARMVCCThen, VCCR:$pred, zero_reg)))>;
3287}
3288
3289defm : MVE_VSxI_patterns<MVE_VSLIimm8,  "vsli", MVE_v16i8>;
3290defm : MVE_VSxI_patterns<MVE_VSLIimm16, "vsli", MVE_v8i16>;
3291defm : MVE_VSxI_patterns<MVE_VSLIimm32, "vsli", MVE_v4i32>;
3292defm : MVE_VSxI_patterns<MVE_VSRIimm8,  "vsri", MVE_v16i8>;
3293defm : MVE_VSxI_patterns<MVE_VSRIimm16, "vsri", MVE_v8i16>;
3294defm : MVE_VSxI_patterns<MVE_VSRIimm32, "vsri", MVE_v4i32>;
3295
3296class MVE_VQSHL_imm<MVEVectorVTInfo VTI_, Operand immType>
3297  : MVE_shift_with_imm<"vqshl", VTI_.Suffix, (outs MQPR:$Qd),
3298                       (ins MQPR:$Qm, immType:$imm), "$Qd, $Qm, $imm",
3299                       vpred_r, "", VTI_.Size> {
3300  bits<6> imm;
3301
3302  let Inst{28} = VTI_.Unsigned;
3303  let Inst{25-24} = 0b11;
3304  let Inst{21-16} = imm;
3305  let Inst{10-8} = 0b111;
3306
3307  let VTI = VTI_;
3308  let immediateType = immType;
3309  let unsignedFlag = (? (i32 VTI.Unsigned));
3310}
3311
3312let unpred_int = int_arm_mve_vqshl_imm,
3313    pred_int = int_arm_mve_vqshl_imm_predicated in {
3314  def MVE_VQSHLimms8 : MVE_VQSHL_imm<MVE_v16s8, imm0_7> {
3315    let Inst{21-19} = 0b001;
3316  }
3317  def MVE_VQSHLimmu8 : MVE_VQSHL_imm<MVE_v16u8, imm0_7> {
3318    let Inst{21-19} = 0b001;
3319  }
3320
3321  def MVE_VQSHLimms16 : MVE_VQSHL_imm<MVE_v8s16, imm0_15> {
3322    let Inst{21-20} = 0b01;
3323  }
3324  def MVE_VQSHLimmu16 : MVE_VQSHL_imm<MVE_v8u16, imm0_15> {
3325    let Inst{21-20} = 0b01;
3326  }
3327
3328  def MVE_VQSHLimms32 : MVE_VQSHL_imm<MVE_v4s32, imm0_31> {
3329    let Inst{21} = 0b1;
3330  }
3331  def MVE_VQSHLimmu32 : MVE_VQSHL_imm<MVE_v4u32, imm0_31> {
3332    let Inst{21} = 0b1;
3333  }
3334}
3335
3336class MVE_VQSHLU_imm<MVEVectorVTInfo VTI_, Operand immType>
3337  : MVE_shift_with_imm<"vqshlu", VTI_.Suffix, (outs MQPR:$Qd),
3338                       (ins MQPR:$Qm, immType:$imm), "$Qd, $Qm, $imm",
3339                       vpred_r, "", VTI_.Size> {
3340  bits<6> imm;
3341
3342  let Inst{28} = 0b1;
3343  let Inst{25-24} = 0b11;
3344  let Inst{21-16} = imm;
3345  let Inst{10-8} = 0b110;
3346
3347  let VTI = VTI_;
3348  let immediateType = immType;
3349}
3350
3351let unpred_int = int_arm_mve_vqshlu_imm,
3352    pred_int = int_arm_mve_vqshlu_imm_predicated in {
3353  def MVE_VQSHLU_imms8 : MVE_VQSHLU_imm<MVE_v16s8, imm0_7> {
3354    let Inst{21-19} = 0b001;
3355  }
3356
3357  def MVE_VQSHLU_imms16 : MVE_VQSHLU_imm<MVE_v8s16, imm0_15> {
3358    let Inst{21-20} = 0b01;
3359  }
3360
3361  def MVE_VQSHLU_imms32 : MVE_VQSHLU_imm<MVE_v4s32, imm0_31> {
3362    let Inst{21} = 0b1;
3363  }
3364}
3365
3366class MVE_VRSHR_imm<MVEVectorVTInfo VTI_, Operand immType>
3367  : MVE_shift_with_imm<"vrshr", VTI_.Suffix, (outs MQPR:$Qd),
3368                       (ins MQPR:$Qm, immType:$imm), "$Qd, $Qm, $imm",
3369                       vpred_r, "", VTI_.Size> {
3370  bits<6> imm;
3371
3372  let Inst{28} = VTI_.Unsigned;
3373  let Inst{25-24} = 0b11;
3374  let Inst{21-16} = imm;
3375  let Inst{10-8} = 0b010;
3376
3377  let VTI = VTI_;
3378  let immediateType = immType;
3379  let unsignedFlag = (? (i32 VTI.Unsigned));
3380}
3381
3382let unpred_int = int_arm_mve_vrshr_imm,
3383    pred_int = int_arm_mve_vrshr_imm_predicated in {
3384  def MVE_VRSHR_imms8 : MVE_VRSHR_imm<MVE_v16s8, shr_imm8> {
3385    let Inst{21-19} = 0b001;
3386  }
3387
3388  def MVE_VRSHR_immu8 : MVE_VRSHR_imm<MVE_v16u8, shr_imm8> {
3389    let Inst{21-19} = 0b001;
3390  }
3391
3392  def MVE_VRSHR_imms16 : MVE_VRSHR_imm<MVE_v8s16, shr_imm16> {
3393    let Inst{21-20} = 0b01;
3394  }
3395
3396  def MVE_VRSHR_immu16 : MVE_VRSHR_imm<MVE_v8u16, shr_imm16> {
3397    let Inst{21-20} = 0b01;
3398  }
3399
3400  def MVE_VRSHR_imms32 : MVE_VRSHR_imm<MVE_v4s32, shr_imm32> {
3401    let Inst{21} = 0b1;
3402  }
3403
3404  def MVE_VRSHR_immu32 : MVE_VRSHR_imm<MVE_v4u32, shr_imm32> {
3405    let Inst{21} = 0b1;
3406  }
3407}
3408
3409multiclass MVE_shift_imm_patterns<MVE_shift_with_imm inst> {
3410  def : Pat<(inst.VTI.Vec !con((inst.unpred_int (inst.VTI.Vec MQPR:$src),
3411                                                inst.immediateType:$imm),
3412                               inst.unsignedFlag)),
3413            (inst.VTI.Vec (inst (inst.VTI.Vec MQPR:$src),
3414                                inst.immediateType:$imm))>;
3415
3416  def : Pat<(inst.VTI.Vec !con((inst.pred_int (inst.VTI.Vec MQPR:$src),
3417                                              inst.immediateType:$imm),
3418                               inst.unsignedFlag,
3419                               (? (inst.VTI.Pred VCCR:$mask),
3420                                  (inst.VTI.Vec MQPR:$inactive)))),
3421            (inst.VTI.Vec (inst (inst.VTI.Vec MQPR:$src),
3422                                inst.immediateType:$imm,
3423                                ARMVCCThen, (inst.VTI.Pred VCCR:$mask), zero_reg,
3424                                (inst.VTI.Vec MQPR:$inactive)))>;
3425}
3426
3427defm : MVE_shift_imm_patterns<MVE_VQSHLimms8>;
3428defm : MVE_shift_imm_patterns<MVE_VQSHLimmu8>;
3429defm : MVE_shift_imm_patterns<MVE_VQSHLimms16>;
3430defm : MVE_shift_imm_patterns<MVE_VQSHLimmu16>;
3431defm : MVE_shift_imm_patterns<MVE_VQSHLimms32>;
3432defm : MVE_shift_imm_patterns<MVE_VQSHLimmu32>;
3433defm : MVE_shift_imm_patterns<MVE_VQSHLU_imms8>;
3434defm : MVE_shift_imm_patterns<MVE_VQSHLU_imms16>;
3435defm : MVE_shift_imm_patterns<MVE_VQSHLU_imms32>;
3436defm : MVE_shift_imm_patterns<MVE_VRSHR_imms8>;
3437defm : MVE_shift_imm_patterns<MVE_VRSHR_immu8>;
3438defm : MVE_shift_imm_patterns<MVE_VRSHR_imms16>;
3439defm : MVE_shift_imm_patterns<MVE_VRSHR_immu16>;
3440defm : MVE_shift_imm_patterns<MVE_VRSHR_imms32>;
3441defm : MVE_shift_imm_patterns<MVE_VRSHR_immu32>;
3442
3443class MVE_VSHR_imm<string suffix, dag imm, bits<2> vecsize>
3444  : MVE_shift_with_imm<"vshr", suffix, (outs MQPR:$Qd),
3445                       !con((ins MQPR:$Qm), imm), "$Qd, $Qm, $imm",
3446                       vpred_r, "", vecsize> {
3447  bits<6> imm;
3448
3449  let Inst{25-24} = 0b11;
3450  let Inst{21-16} = imm;
3451  let Inst{10-8} = 0b000;
3452}
3453
3454def MVE_VSHR_imms8 : MVE_VSHR_imm<"s8", (ins shr_imm8:$imm), 0b00> {
3455  let Inst{28} = 0b0;
3456  let Inst{21-19} = 0b001;
3457}
3458
3459def MVE_VSHR_immu8 : MVE_VSHR_imm<"u8", (ins shr_imm8:$imm), 0b00> {
3460  let Inst{28} = 0b1;
3461  let Inst{21-19} = 0b001;
3462}
3463
3464def MVE_VSHR_imms16 : MVE_VSHR_imm<"s16", (ins shr_imm16:$imm), 0b01> {
3465  let Inst{28} = 0b0;
3466  let Inst{21-20} = 0b01;
3467}
3468
3469def MVE_VSHR_immu16 : MVE_VSHR_imm<"u16", (ins shr_imm16:$imm), 0b01> {
3470  let Inst{28} = 0b1;
3471  let Inst{21-20} = 0b01;
3472}
3473
3474def MVE_VSHR_imms32 : MVE_VSHR_imm<"s32", (ins shr_imm32:$imm), 0b10> {
3475  let Inst{28} = 0b0;
3476  let Inst{21} = 0b1;
3477}
3478
3479def MVE_VSHR_immu32 : MVE_VSHR_imm<"u32", (ins shr_imm32:$imm), 0b10> {
3480  let Inst{28} = 0b1;
3481  let Inst{21} = 0b1;
3482}
3483
3484class MVE_VSHL_imm<string suffix, dag imm, bits<2> vecsize>
3485  : MVE_shift_with_imm<"vshl", suffix, (outs MQPR:$Qd),
3486                       !con((ins MQPR:$Qm), imm), "$Qd, $Qm, $imm",
3487                       vpred_r, "", vecsize> {
3488  bits<6> imm;
3489
3490  let Inst{28} = 0b0;
3491  let Inst{25-24} = 0b11;
3492  let Inst{21-16} = imm;
3493  let Inst{10-8} = 0b101;
3494}
3495
3496def MVE_VSHL_immi8 : MVE_VSHL_imm<"i8", (ins imm0_7:$imm), 0b00> {
3497  let Inst{21-19} = 0b001;
3498}
3499
3500def MVE_VSHL_immi16 : MVE_VSHL_imm<"i16", (ins imm0_15:$imm), 0b01> {
3501  let Inst{21-20} = 0b01;
3502}
3503
3504def MVE_VSHL_immi32 : MVE_VSHL_imm<"i32", (ins imm0_31:$imm), 0b10> {
3505  let Inst{21} = 0b1;
3506}
3507
3508multiclass MVE_immediate_shift_patterns_inner<
3509    MVEVectorVTInfo VTI, Operand imm_operand_type, SDNode unpred_op,
3510    Intrinsic pred_int, Instruction inst, list<int> unsignedFlag = []> {
3511
3512  def : Pat<(VTI.Vec (unpred_op (VTI.Vec MQPR:$src), imm_operand_type:$imm)),
3513            (VTI.Vec (inst (VTI.Vec MQPR:$src), imm_operand_type:$imm))>;
3514
3515  def : Pat<(VTI.Vec !con((pred_int (VTI.Vec MQPR:$src), imm_operand_type:$imm),
3516                          !dag(pred_int, unsignedFlag, ?),
3517                          (pred_int (VTI.Pred VCCR:$mask),
3518                                   (VTI.Vec MQPR:$inactive)))),
3519            (VTI.Vec (inst (VTI.Vec MQPR:$src), imm_operand_type:$imm,
3520                           ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
3521                           (VTI.Vec MQPR:$inactive)))>;
3522}
3523
3524multiclass MVE_immediate_shift_patterns<MVEVectorVTInfo VTI,
3525                                        Operand imm_operand_type> {
3526  defm : MVE_immediate_shift_patterns_inner<VTI, imm_operand_type,
3527      ARMvshlImm, int_arm_mve_shl_imm_predicated,
3528      !cast<Instruction>("MVE_VSHL_immi" # VTI.BitsSuffix)>;
3529  defm : MVE_immediate_shift_patterns_inner<VTI, imm_operand_type,
3530      ARMvshruImm, int_arm_mve_shr_imm_predicated,
3531      !cast<Instruction>("MVE_VSHR_immu" # VTI.BitsSuffix), [1]>;
3532  defm : MVE_immediate_shift_patterns_inner<VTI, imm_operand_type,
3533      ARMvshrsImm, int_arm_mve_shr_imm_predicated,
3534      !cast<Instruction>("MVE_VSHR_imms" # VTI.BitsSuffix), [0]>;
3535}
3536
3537let Predicates = [HasMVEInt] in {
3538  defm : MVE_immediate_shift_patterns<MVE_v16i8, imm0_7>;
3539  defm : MVE_immediate_shift_patterns<MVE_v8i16, imm0_15>;
3540  defm : MVE_immediate_shift_patterns<MVE_v4i32, imm0_31>;
3541}
3542
3543// end of mve_shift instructions
3544
3545// start of MVE Floating Point instructions
3546
3547class MVE_float<string iname, string suffix, dag oops, dag iops, string ops,
3548                vpred_ops vpred, string cstr, bits<2> vecsize, list<dag> pattern=[]>
3549  : MVE_f<oops, iops, NoItinerary, iname, suffix, ops, vpred, cstr, vecsize, pattern> {
3550  bits<4> Qm;
3551
3552  let Inst{12} = 0b0;
3553  let Inst{6} = 0b1;
3554  let Inst{5} = Qm{3};
3555  let Inst{3-1} = Qm{2-0};
3556  let Inst{0} = 0b0;
3557}
3558
3559class MVE_VRINT<string rmode, bits<3> op, string suffix, bits<2> size,
3560                list<dag> pattern=[]>
3561  : MVE_float<!strconcat("vrint", rmode), suffix, (outs MQPR:$Qd),
3562              (ins MQPR:$Qm), "$Qd, $Qm", vpred_r, "", size, pattern> {
3563  bits<4> Qd;
3564
3565  let Inst{28} = 0b1;
3566  let Inst{25-23} = 0b111;
3567  let Inst{22} = Qd{3};
3568  let Inst{21-20} = 0b11;
3569  let Inst{19-18} = size;
3570  let Inst{17-16} = 0b10;
3571  let Inst{15-13} = Qd{2-0};
3572  let Inst{11-10} = 0b01;
3573  let Inst{9-7} = op{2-0};
3574  let Inst{4} = 0b0;
3575  let validForTailPredication = 1;
3576
3577}
3578
3579multiclass MVE_VRINT_m<MVEVectorVTInfo VTI, string suffix, bits<3> opcode,
3580                       SDPatternOperator unpred_op> {
3581  def "": MVE_VRINT<suffix, opcode, VTI.Suffix, VTI.Size>;
3582  defvar Inst = !cast<Instruction>(NAME);
3583  defvar pred_int = !cast<Intrinsic>("int_arm_mve_vrint"#suffix#"_predicated");
3584
3585  let Predicates = [HasMVEFloat] in {
3586    def : Pat<(VTI.Vec (unpred_op (VTI.Vec MQPR:$val))),
3587              (VTI.Vec (Inst (VTI.Vec MQPR:$val)))>;
3588    def : Pat<(VTI.Vec (pred_int (VTI.Vec MQPR:$val), (VTI.Pred VCCR:$pred),
3589                                 (VTI.Vec MQPR:$inactive))),
3590              (VTI.Vec (Inst (VTI.Vec MQPR:$val), ARMVCCThen,
3591                             (VTI.Pred VCCR:$pred), zero_reg, (VTI.Vec MQPR:$inactive)))>;
3592  }
3593}
3594
3595multiclass MVE_VRINT_ops<MVEVectorVTInfo VTI> {
3596  defm N : MVE_VRINT_m<VTI, "n", 0b000, int_arm_mve_vrintn>;
3597  defm X : MVE_VRINT_m<VTI, "x", 0b001, frint>;
3598  defm A : MVE_VRINT_m<VTI, "a", 0b010, fround>;
3599  defm Z : MVE_VRINT_m<VTI, "z", 0b011, ftrunc>;
3600  defm M : MVE_VRINT_m<VTI, "m", 0b101, ffloor>;
3601  defm P : MVE_VRINT_m<VTI, "p", 0b111, fceil>;
3602}
3603
3604defm MVE_VRINTf16 : MVE_VRINT_ops<MVE_v8f16>;
3605defm MVE_VRINTf32 : MVE_VRINT_ops<MVE_v4f32>;
3606
3607class MVEFloatArithNeon<string iname, string suffix, bit size,
3608                           dag oops, dag iops, string ops,
3609                           vpred_ops vpred, string cstr, bits<2> vecsize, list<dag> pattern=[]>
3610  : MVE_float<iname, suffix, oops, iops, ops, vpred, cstr, vecsize, pattern> {
3611  let Inst{20} = size;
3612  let Inst{16} = 0b0;
3613}
3614
3615class MVE_VMUL_fp<string iname, string suffix, bits<2> size, list<dag> pattern=[]>
3616  : MVEFloatArithNeon<iname, suffix, size{0}, (outs MQPR:$Qd),
3617                      (ins MQPR:$Qn, MQPR:$Qm), "$Qd, $Qn, $Qm", vpred_r, "",
3618                      size, pattern> {
3619  bits<4> Qd;
3620  bits<4> Qn;
3621
3622  let Inst{28} = 0b1;
3623  let Inst{25-23} = 0b110;
3624  let Inst{22} = Qd{3};
3625  let Inst{21} = 0b0;
3626  let Inst{19-17} = Qn{2-0};
3627  let Inst{15-13} = Qd{2-0};
3628  let Inst{12-8} = 0b01101;
3629  let Inst{7} = Qn{3};
3630  let Inst{4} = 0b1;
3631  let validForTailPredication = 1;
3632}
3633
3634multiclass MVE_VMULT_fp_m<string iname, MVEVectorVTInfo VTI, SDNode Op,
3635                          Intrinsic PredInt, SDPatternOperator IdentityVec> {
3636  def "" : MVE_VMUL_fp<iname, VTI.Suffix, VTI.Size>;
3637  defvar Inst = !cast<Instruction>(NAME);
3638
3639  let Predicates = [HasMVEFloat] in {
3640    defm : MVE_TwoOpPattern<VTI, Op, PredInt, (? ), !cast<Instruction>(NAME), IdentityVec>;
3641  }
3642}
3643
3644multiclass MVE_VMUL_fp_m<MVEVectorVTInfo VTI, SDPatternOperator IdentityVec>
3645  : MVE_VMULT_fp_m<"vmul", VTI, fmul, int_arm_mve_mul_predicated, IdentityVec>;
3646
3647def ARMimmOneF: PatLeaf<(bitconvert (v4f32 (ARMvmovFPImm (i32 112))))>; // 1.0 float
3648def ARMimmOneH: PatLeaf<(bitconvert (v8i16 (ARMvmovImm (i32 2620))))>; // 1.0 half
3649
3650defm MVE_VMULf32 : MVE_VMUL_fp_m<MVE_v4f32, ARMimmOneF>;
3651defm MVE_VMULf16 : MVE_VMUL_fp_m<MVE_v8f16, ARMimmOneH>;
3652
3653class MVE_VCMLA<string suffix, bits<2> size>
3654  : MVEFloatArithNeon<"vcmla", suffix, size{1}, (outs MQPR:$Qd),
3655                         (ins MQPR:$Qd_src, MQPR:$Qn, MQPR:$Qm, complexrotateop:$rot),
3656                         "$Qd, $Qn, $Qm, $rot", vpred_n, "$Qd = $Qd_src", size, []> {
3657  bits<4> Qd;
3658  bits<4> Qn;
3659  bits<2> rot;
3660
3661  let Inst{28} = 0b1;
3662  let Inst{25} = 0b0;
3663  let Inst{24-23} = rot;
3664  let Inst{22} = Qd{3};
3665  let Inst{21} = 0b1;
3666  let Inst{19-17} = Qn{2-0};
3667  let Inst{15-13} = Qd{2-0};
3668  let Inst{12-8} = 0b01000;
3669  let Inst{7} = Qn{3};
3670  let Inst{4} = 0b0;
3671}
3672
3673multiclass MVE_VCMLA_m<MVEVectorVTInfo VTI> {
3674  def "" : MVE_VCMLA<VTI.Suffix, VTI.Size>;
3675  defvar Inst = !cast<Instruction>(NAME);
3676
3677  let Predicates = [HasMVEFloat] in {
3678    def : Pat<(VTI.Vec (int_arm_mve_vcmlaq
3679                            imm:$rot, (VTI.Vec MQPR:$Qd_src),
3680                            (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm))),
3681              (VTI.Vec (Inst (VTI.Vec MQPR:$Qd_src),
3682                             (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
3683                             imm:$rot))>;
3684
3685    def: Pat<(VTI.Vec (fadd_contract MQPR:$Qd_src,
3686                            (int_arm_mve_vcmulq imm:$rot,
3687                              (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm)))),
3688              (VTI.Vec (Inst (VTI.Vec MQPR:$Qd_src),
3689                             (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
3690                             imm:$rot))>;
3691
3692    def : Pat<(VTI.Vec (int_arm_mve_vcmlaq_predicated
3693                            imm:$rot, (VTI.Vec MQPR:$Qd_src),
3694                            (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
3695                            (VTI.Pred VCCR:$mask))),
3696              (VTI.Vec (Inst (VTI.Vec MQPR:$Qd_src), (VTI.Vec MQPR:$Qn),
3697                             (VTI.Vec MQPR:$Qm), imm:$rot,
3698                             ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg))>;
3699  }
3700}
3701
3702defm MVE_VCMLAf16 : MVE_VCMLA_m<MVE_v8f16>;
3703defm MVE_VCMLAf32 : MVE_VCMLA_m<MVE_v4f32>;
3704
3705class MVE_VADDSUBFMA_fp<string iname, string suffix, bits<2> size, bit bit_4,
3706                        bit bit_8, bit bit_21, dag iops=(ins),
3707                        vpred_ops vpred=vpred_r, string cstr="",
3708                        list<dag> pattern=[]>
3709  : MVEFloatArithNeon<iname, suffix, size{0}, (outs MQPR:$Qd),
3710                      !con(iops, (ins MQPR:$Qn, MQPR:$Qm)), "$Qd, $Qn, $Qm",
3711                      vpred, cstr, size, pattern> {
3712  bits<4> Qd;
3713  bits<4> Qn;
3714
3715  let Inst{28} = 0b0;
3716  let Inst{25-23} = 0b110;
3717  let Inst{22} = Qd{3};
3718  let Inst{21} = bit_21;
3719  let Inst{19-17} = Qn{2-0};
3720  let Inst{15-13} = Qd{2-0};
3721  let Inst{11-9} = 0b110;
3722  let Inst{8} = bit_8;
3723  let Inst{7} = Qn{3};
3724  let Inst{4} = bit_4;
3725  let validForTailPredication = 1;
3726}
3727
3728multiclass MVE_VFMA_fp_multi<string iname, bit fms, MVEVectorVTInfo VTI> {
3729  def "" : MVE_VADDSUBFMA_fp<iname, VTI.Suffix, VTI.Size, 0b1, 0b0, fms,
3730                             (ins MQPR:$Qd_src), vpred_n, "$Qd = $Qd_src">;
3731  defvar Inst = !cast<Instruction>(NAME);
3732  defvar pred_int = int_arm_mve_fma_predicated;
3733  defvar m1   = (VTI.Vec MQPR:$m1);
3734  defvar m2   = (VTI.Vec MQPR:$m2);
3735  defvar add  = (VTI.Vec MQPR:$add);
3736  defvar pred = (VTI.Pred VCCR:$pred);
3737
3738  let Predicates = [HasMVEFloat] in {
3739    if fms then {
3740      def : Pat<(VTI.Vec (fma (fneg m1), m2, add)),
3741                (Inst $add, $m1, $m2)>;
3742      def : Pat<(VTI.Vec (vselect (VTI.Pred VCCR:$pred),
3743                                  (VTI.Vec (fma (fneg m1), m2, add)),
3744                                  add)),
3745                (Inst $add, $m1, $m2, ARMVCCThen, $pred, zero_reg)>;
3746      def : Pat<(VTI.Vec (pred_int (fneg m1), m2, add, pred)),
3747                (Inst $add, $m1, $m2, ARMVCCThen, $pred, zero_reg)>;
3748      def : Pat<(VTI.Vec (pred_int m1, (fneg m2), add, pred)),
3749                (Inst $add, $m1, $m2, ARMVCCThen, $pred, zero_reg)>;
3750    } else {
3751      def : Pat<(VTI.Vec (fma m1, m2, add)),
3752                (Inst $add, $m1, $m2)>;
3753      def : Pat<(VTI.Vec (vselect (VTI.Pred VCCR:$pred),
3754                                  (VTI.Vec (fma m1, m2, add)),
3755                                  add)),
3756                (Inst $add, $m1, $m2, ARMVCCThen, $pred, zero_reg)>;
3757      def : Pat<(VTI.Vec (pred_int m1, m2, add, pred)),
3758                (Inst $add, $m1, $m2, ARMVCCThen, $pred, zero_reg)>;
3759    }
3760  }
3761}
3762
3763defm MVE_VFMAf32 : MVE_VFMA_fp_multi<"vfma", 0, MVE_v4f32>;
3764defm MVE_VFMAf16 : MVE_VFMA_fp_multi<"vfma", 0, MVE_v8f16>;
3765defm MVE_VFMSf32 : MVE_VFMA_fp_multi<"vfms", 1, MVE_v4f32>;
3766defm MVE_VFMSf16 : MVE_VFMA_fp_multi<"vfms", 1, MVE_v8f16>;
3767
3768multiclass MVE_VADDSUB_fp_m<string iname, bit bit_21, MVEVectorVTInfo VTI,
3769                            SDNode Op, Intrinsic PredInt, SDPatternOperator IdentityVec> {
3770  def "" : MVE_VADDSUBFMA_fp<iname, VTI.Suffix, VTI.Size, 0, 1, bit_21> {
3771    let validForTailPredication = 1;
3772  }
3773  defvar Inst = !cast<Instruction>(NAME);
3774
3775  let Predicates = [HasMVEFloat] in {
3776    defm : MVE_TwoOpPattern<VTI, Op, PredInt, (? ), !cast<Instruction>(NAME), IdentityVec>;
3777  }
3778}
3779
3780multiclass MVE_VADD_fp_m<MVEVectorVTInfo VTI, SDPatternOperator IdentityVec>
3781  : MVE_VADDSUB_fp_m<"vadd", 0, VTI, fadd, int_arm_mve_add_predicated, IdentityVec>;
3782multiclass MVE_VSUB_fp_m<MVEVectorVTInfo VTI, SDPatternOperator IdentityVec>
3783  : MVE_VADDSUB_fp_m<"vsub", 1, VTI, fsub, int_arm_mve_sub_predicated, IdentityVec>;
3784
3785def ARMimmMinusZeroF: PatLeaf<(bitconvert (v4i32 (ARMvmovImm (i32 1664))))>; // -0.0 float
3786def ARMimmMinusZeroH: PatLeaf<(bitconvert (v8i16 (ARMvmovImm (i32 2688))))>; // -0.0 half
3787
3788defm MVE_VADDf32 : MVE_VADD_fp_m<MVE_v4f32, ARMimmMinusZeroF>;
3789defm MVE_VADDf16 : MVE_VADD_fp_m<MVE_v8f16, ARMimmMinusZeroH>;
3790
3791defm MVE_VSUBf32 : MVE_VSUB_fp_m<MVE_v4f32, ARMimmAllZerosV>;
3792defm MVE_VSUBf16 : MVE_VSUB_fp_m<MVE_v8f16, ARMimmAllZerosV>;
3793
3794class MVE_VCADD<string suffix, bits<2> size, string cstr="">
3795  : MVEFloatArithNeon<"vcadd", suffix, size{1}, (outs MQPR:$Qd),
3796                         (ins MQPR:$Qn, MQPR:$Qm, complexrotateopodd:$rot),
3797                         "$Qd, $Qn, $Qm, $rot", vpred_r, cstr, size, []> {
3798  bits<4> Qd;
3799  bits<4> Qn;
3800  bit rot;
3801
3802  let Inst{28} = 0b1;
3803  let Inst{25} = 0b0;
3804  let Inst{24} = rot;
3805  let Inst{23} = 0b1;
3806  let Inst{22} = Qd{3};
3807  let Inst{21} = 0b0;
3808  let Inst{19-17} = Qn{2-0};
3809  let Inst{15-13} = Qd{2-0};
3810  let Inst{12-8} = 0b01000;
3811  let Inst{7} = Qn{3};
3812  let Inst{4} = 0b0;
3813}
3814
3815multiclass MVE_VCADD_m<MVEVectorVTInfo VTI, string cstr=""> {
3816  def "" : MVE_VCADD<VTI.Suffix, VTI.Size, cstr>;
3817  defvar Inst = !cast<Instruction>(NAME);
3818
3819  let Predicates = [HasMVEFloat] in {
3820    def : Pat<(VTI.Vec (int_arm_mve_vcaddq (i32 1),
3821                            imm:$rot, (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm))),
3822              (VTI.Vec (Inst (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
3823                             imm:$rot))>;
3824
3825    def : Pat<(VTI.Vec (int_arm_mve_vcaddq_predicated (i32 1),
3826                            imm:$rot, (VTI.Vec MQPR:$inactive),
3827                            (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
3828                            (VTI.Pred VCCR:$mask))),
3829              (VTI.Vec (Inst (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
3830                             imm:$rot, ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
3831                             (VTI.Vec MQPR:$inactive)))>;
3832
3833  }
3834}
3835
3836defm MVE_VCADDf16 : MVE_VCADD_m<MVE_v8f16>;
3837defm MVE_VCADDf32 : MVE_VCADD_m<MVE_v4f32, "@earlyclobber $Qd">;
3838
3839class MVE_VABD_fp<string suffix, bits<2> size>
3840  : MVE_float<"vabd", suffix, (outs MQPR:$Qd), (ins MQPR:$Qn, MQPR:$Qm),
3841              "$Qd, $Qn, $Qm", vpred_r, "", size> {
3842  bits<4> Qd;
3843  bits<4> Qn;
3844
3845  let Inst{28} = 0b1;
3846  let Inst{25-23} = 0b110;
3847  let Inst{22} = Qd{3};
3848  let Inst{21} = 0b1;
3849  let Inst{20} = size{0};
3850  let Inst{19-17} = Qn{2-0};
3851  let Inst{16} = 0b0;
3852  let Inst{15-13} = Qd{2-0};
3853  let Inst{11-8} = 0b1101;
3854  let Inst{7} = Qn{3};
3855  let Inst{4} = 0b0;
3856  let validForTailPredication = 1;
3857}
3858
3859multiclass MVE_VABDT_fp_m<MVEVectorVTInfo VTI,
3860                            Intrinsic unpred_int, Intrinsic pred_int> {
3861  def "" : MVE_VABD_fp<VTI.Suffix, VTI.Size>;
3862  defvar Inst = !cast<Instruction>(NAME);
3863
3864  let Predicates = [HasMVEFloat] in {
3865    def : Pat<(VTI.Vec (unpred_int (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
3866                            (i32 0))),
3867              (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn)))>;
3868    def : Pat<(VTI.Vec (pred_int (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
3869                            (i32 0), (VTI.Pred VCCR:$mask),
3870                            (VTI.Vec MQPR:$inactive))),
3871              (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
3872                             ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
3873                             (VTI.Vec MQPR:$inactive)))>;
3874  }
3875}
3876
3877multiclass MVE_VABD_fp_m<MVEVectorVTInfo VTI>
3878  : MVE_VABDT_fp_m<VTI, int_arm_mve_vabd, int_arm_mve_abd_predicated>;
3879
3880defm MVE_VABDf32 : MVE_VABD_fp_m<MVE_v4f32>;
3881defm MVE_VABDf16 : MVE_VABD_fp_m<MVE_v8f16>;
3882
3883let Predicates = [HasMVEFloat] in {
3884  def : Pat<(v8f16 (fabs (fsub (v8f16 MQPR:$Qm), (v8f16 MQPR:$Qn)))),
3885            (MVE_VABDf16 MQPR:$Qm, MQPR:$Qn)>;
3886  def : Pat<(v4f32 (fabs (fsub (v4f32 MQPR:$Qm), (v4f32 MQPR:$Qn)))),
3887            (MVE_VABDf32 MQPR:$Qm, MQPR:$Qn)>;
3888}
3889
3890class MVE_VCVT_fix<string suffix, bit fsi, bit U, bit op,
3891                   Operand imm_operand_type>
3892  : MVE_float<"vcvt", suffix,
3893              (outs MQPR:$Qd), (ins MQPR:$Qm, imm_operand_type:$imm6),
3894              "$Qd, $Qm, $imm6", vpred_r, "", !if(fsi, 0b10, 0b01), []> {
3895  bits<4> Qd;
3896  bits<6> imm6;
3897
3898  let Inst{28} = U;
3899  let Inst{25-23} = 0b111;
3900  let Inst{22} = Qd{3};
3901  let Inst{21} = 0b1;
3902  let Inst{19-16} = imm6{3-0};
3903  let Inst{15-13} = Qd{2-0};
3904  let Inst{11-10} = 0b11;
3905  let Inst{9} = fsi;
3906  let Inst{8} = op;
3907  let Inst{7} = 0b0;
3908  let Inst{4} = 0b1;
3909
3910  let DecoderMethod = "DecodeMVEVCVTt1fp";
3911  let validForTailPredication = 1;
3912}
3913
3914class MVE_VCVT_imm_asmop<int Bits> : AsmOperandClass {
3915  let PredicateMethod = "isImmediate<1," # Bits # ">";
3916  let DiagnosticString =
3917      "MVE fixed-point immediate operand must be between 1 and " # Bits;
3918  let Name = "MVEVcvtImm" # Bits;
3919  let RenderMethod = "addImmOperands";
3920}
3921class MVE_VCVT_imm<int Bits>: Operand<i32> {
3922  let ParserMatchClass = MVE_VCVT_imm_asmop<Bits>;
3923  let EncoderMethod = "getNEONVcvtImm32OpValue";
3924  let DecoderMethod = "DecodeVCVTImmOperand";
3925}
3926
3927class MVE_VCVT_fix_f32<string suffix, bit U, bit op>
3928    : MVE_VCVT_fix<suffix, 0b1, U, op, MVE_VCVT_imm<32>> {
3929  let Inst{20} = imm6{4};
3930}
3931class MVE_VCVT_fix_f16<string suffix, bit U, bit op>
3932    : MVE_VCVT_fix<suffix, 0b0, U, op, MVE_VCVT_imm<16>> {
3933  let Inst{20} = 0b1;
3934}
3935
3936multiclass MVE_VCVT_fix_patterns<Instruction Inst, bit U, MVEVectorVTInfo DestVTI,
3937                                 MVEVectorVTInfo SrcVTI> {
3938  let Predicates = [HasMVEFloat] in {
3939    def : Pat<(DestVTI.Vec (int_arm_mve_vcvt_fix
3940                              (i32 U), (SrcVTI.Vec MQPR:$Qm), imm:$scale)),
3941              (DestVTI.Vec (Inst (SrcVTI.Vec MQPR:$Qm), imm:$scale))>;
3942    def : Pat<(DestVTI.Vec (int_arm_mve_vcvt_fix_predicated (i32 U),
3943                              (DestVTI.Vec MQPR:$inactive),
3944                              (SrcVTI.Vec MQPR:$Qm),
3945                              imm:$scale,
3946                              (DestVTI.Pred VCCR:$mask))),
3947              (DestVTI.Vec (Inst (SrcVTI.Vec MQPR:$Qm), imm:$scale,
3948                             ARMVCCThen, (DestVTI.Pred VCCR:$mask), zero_reg,
3949                             (DestVTI.Vec MQPR:$inactive)))>;
3950  }
3951}
3952
3953multiclass MVE_VCVT_fix_f32_m<bit U, bit op,
3954                              MVEVectorVTInfo DestVTI, MVEVectorVTInfo SrcVTI> {
3955  def "" : MVE_VCVT_fix_f32<DestVTI.Suffix#"."#SrcVTI.Suffix, U, op>;
3956  defm : MVE_VCVT_fix_patterns<!cast<Instruction>(NAME), U, DestVTI, SrcVTI>;
3957}
3958
3959multiclass MVE_VCVT_fix_f16_m<bit U, bit op,
3960                              MVEVectorVTInfo DestVTI, MVEVectorVTInfo SrcVTI> {
3961  def "" : MVE_VCVT_fix_f16<DestVTI.Suffix#"."#SrcVTI.Suffix, U, op>;
3962  defm : MVE_VCVT_fix_patterns<!cast<Instruction>(NAME), U, DestVTI, SrcVTI>;
3963}
3964
3965defm MVE_VCVTf16s16_fix : MVE_VCVT_fix_f16_m<0b0, 0b0, MVE_v8f16, MVE_v8s16>;
3966defm MVE_VCVTs16f16_fix : MVE_VCVT_fix_f16_m<0b0, 0b1, MVE_v8s16, MVE_v8f16>;
3967defm MVE_VCVTf16u16_fix : MVE_VCVT_fix_f16_m<0b1, 0b0, MVE_v8f16, MVE_v8u16>;
3968defm MVE_VCVTu16f16_fix : MVE_VCVT_fix_f16_m<0b1, 0b1, MVE_v8u16, MVE_v8f16>;
3969defm MVE_VCVTf32s32_fix : MVE_VCVT_fix_f32_m<0b0, 0b0, MVE_v4f32, MVE_v4s32>;
3970defm MVE_VCVTs32f32_fix : MVE_VCVT_fix_f32_m<0b0, 0b1, MVE_v4s32, MVE_v4f32>;
3971defm MVE_VCVTf32u32_fix : MVE_VCVT_fix_f32_m<0b1, 0b0, MVE_v4f32, MVE_v4u32>;
3972defm MVE_VCVTu32f32_fix : MVE_VCVT_fix_f32_m<0b1, 0b1, MVE_v4u32, MVE_v4f32>;
3973
3974class MVE_VCVT_fp_int_anpm<string suffix, bits<2> size, bit op, string anpm,
3975                bits<2> rm, list<dag> pattern=[]>
3976  : MVE_float<!strconcat("vcvt", anpm), suffix, (outs MQPR:$Qd),
3977              (ins MQPR:$Qm), "$Qd, $Qm", vpred_r, "", size, pattern> {
3978  bits<4> Qd;
3979
3980  let Inst{28} = 0b1;
3981  let Inst{25-23} = 0b111;
3982  let Inst{22} = Qd{3};
3983  let Inst{21-20} = 0b11;
3984  let Inst{19-18} = size;
3985  let Inst{17-16} = 0b11;
3986  let Inst{15-13} = Qd{2-0};
3987  let Inst{12-10} = 0b000;
3988  let Inst{9-8} = rm;
3989  let Inst{7} = op;
3990  let Inst{4} = 0b0;
3991  let validForTailPredication = 1;
3992}
3993
3994multiclass MVE_VCVT_fp_int_anpm_inner<MVEVectorVTInfo Int, MVEVectorVTInfo Flt,
3995                                      string anpm, bits<2> rm> {
3996  def "": MVE_VCVT_fp_int_anpm<Int.Suffix # "." # Flt.Suffix, Int.Size,
3997                               Int.Unsigned, anpm, rm>;
3998
3999  defvar Inst         = !cast<Instruction>(NAME);
4000  defvar IntrBaseName = "int_arm_mve_vcvt" # anpm;
4001  defvar UnpredIntr   = !cast<Intrinsic>(IntrBaseName);
4002  defvar PredIntr     = !cast<Intrinsic>(IntrBaseName # "_predicated");
4003
4004  let Predicates = [HasMVEFloat] in {
4005    def : Pat<(Int.Vec (UnpredIntr (i32 Int.Unsigned), (Flt.Vec MQPR:$in))),
4006              (Int.Vec (Inst (Flt.Vec MQPR:$in)))>;
4007
4008    def : Pat<(Int.Vec (PredIntr (i32 Int.Unsigned), (Int.Vec MQPR:$inactive),
4009                                 (Flt.Vec MQPR:$in), (Flt.Pred VCCR:$pred))),
4010              (Int.Vec (Inst (Flt.Vec MQPR:$in), ARMVCCThen,
4011                             (Flt.Pred VCCR:$pred), zero_reg, (Int.Vec MQPR:$inactive)))>;
4012  }
4013}
4014
4015multiclass MVE_VCVT_fp_int_anpm_outer<MVEVectorVTInfo Int,
4016                                      MVEVectorVTInfo Flt> {
4017  defm a : MVE_VCVT_fp_int_anpm_inner<Int, Flt, "a", 0b00>;
4018  defm n : MVE_VCVT_fp_int_anpm_inner<Int, Flt, "n", 0b01>;
4019  defm p : MVE_VCVT_fp_int_anpm_inner<Int, Flt, "p", 0b10>;
4020  defm m : MVE_VCVT_fp_int_anpm_inner<Int, Flt, "m", 0b11>;
4021}
4022
4023// This defines instructions such as MVE_VCVTu16f16a, with an explicit
4024// rounding-mode suffix on the mnemonic. The class below will define
4025// the bare MVE_VCVTu16f16 (with implied rounding toward zero).
4026defm MVE_VCVTs16f16 : MVE_VCVT_fp_int_anpm_outer<MVE_v8s16, MVE_v8f16>;
4027defm MVE_VCVTu16f16 : MVE_VCVT_fp_int_anpm_outer<MVE_v8u16, MVE_v8f16>;
4028defm MVE_VCVTs32f32 : MVE_VCVT_fp_int_anpm_outer<MVE_v4s32, MVE_v4f32>;
4029defm MVE_VCVTu32f32 : MVE_VCVT_fp_int_anpm_outer<MVE_v4u32, MVE_v4f32>;
4030
4031class MVE_VCVT_fp_int<string suffix, bits<2> size, bit toint, bit unsigned,
4032                      list<dag> pattern=[]>
4033  : MVE_float<"vcvt", suffix, (outs MQPR:$Qd),
4034              (ins MQPR:$Qm), "$Qd, $Qm", vpred_r, "", size, pattern> {
4035  bits<4> Qd;
4036
4037  let Inst{28} = 0b1;
4038  let Inst{25-23} = 0b111;
4039  let Inst{22} = Qd{3};
4040  let Inst{21-20} = 0b11;
4041  let Inst{19-18} = size;
4042  let Inst{17-16} = 0b11;
4043  let Inst{15-13} = Qd{2-0};
4044  let Inst{12-9} = 0b0011;
4045  let Inst{8} = toint;
4046  let Inst{7} = unsigned;
4047  let Inst{4} = 0b0;
4048  let validForTailPredication = 1;
4049}
4050
4051multiclass MVE_VCVT_fp_int_m<MVEVectorVTInfo Dest, MVEVectorVTInfo Src,
4052                             SDNode unpred_op> {
4053  defvar Unsigned = !or(!eq(Dest.SuffixLetter,"u"), !eq(Src.SuffixLetter,"u"));
4054  defvar ToInt = !eq(Src.SuffixLetter,"f");
4055
4056  def "" : MVE_VCVT_fp_int<Dest.Suffix # "." # Src.Suffix, Dest.Size,
4057                           ToInt, Unsigned>;
4058  defvar Inst = !cast<Instruction>(NAME);
4059
4060  let Predicates = [HasMVEFloat] in {
4061    def : Pat<(Dest.Vec (unpred_op (Src.Vec MQPR:$src))),
4062              (Dest.Vec (Inst (Src.Vec MQPR:$src)))>;
4063    def : Pat<(Dest.Vec (int_arm_mve_vcvt_fp_int_predicated
4064                             (Src.Vec MQPR:$src), (i32 Unsigned),
4065                             (Src.Pred VCCR:$mask), (Dest.Vec MQPR:$inactive))),
4066              (Dest.Vec (Inst (Src.Vec MQPR:$src), ARMVCCThen,
4067                              (Src.Pred VCCR:$mask), zero_reg,
4068                              (Dest.Vec MQPR:$inactive)))>;
4069  }
4070}
4071// The unsuffixed VCVT for float->int implicitly rounds toward zero,
4072// which I reflect here in the llvm instruction names
4073defm MVE_VCVTs16f16z : MVE_VCVT_fp_int_m<MVE_v8s16, MVE_v8f16, fp_to_sint>;
4074defm MVE_VCVTu16f16z : MVE_VCVT_fp_int_m<MVE_v8u16, MVE_v8f16, fp_to_uint>;
4075defm MVE_VCVTs32f32z : MVE_VCVT_fp_int_m<MVE_v4s32, MVE_v4f32, fp_to_sint>;
4076defm MVE_VCVTu32f32z : MVE_VCVT_fp_int_m<MVE_v4u32, MVE_v4f32, fp_to_uint>;
4077// Whereas VCVT for int->float rounds to nearest
4078defm MVE_VCVTf16s16n : MVE_VCVT_fp_int_m<MVE_v8f16, MVE_v8s16, sint_to_fp>;
4079defm MVE_VCVTf16u16n : MVE_VCVT_fp_int_m<MVE_v8f16, MVE_v8u16, uint_to_fp>;
4080defm MVE_VCVTf32s32n : MVE_VCVT_fp_int_m<MVE_v4f32, MVE_v4s32, sint_to_fp>;
4081defm MVE_VCVTf32u32n : MVE_VCVT_fp_int_m<MVE_v4f32, MVE_v4u32, uint_to_fp>;
4082
4083let Predicates = [HasMVEFloat] in {
4084  def : Pat<(v4i32 (fp_to_sint_sat v4f32:$src, i32)),
4085            (MVE_VCVTs32f32z v4f32:$src)>;
4086  def : Pat<(v4i32 (fp_to_uint_sat v4f32:$src, i32)),
4087            (MVE_VCVTu32f32z v4f32:$src)>;
4088  def : Pat<(v8i16 (fp_to_sint_sat v8f16:$src, i16)),
4089            (MVE_VCVTs16f16z v8f16:$src)>;
4090  def : Pat<(v8i16 (fp_to_uint_sat v8f16:$src, i16)),
4091            (MVE_VCVTu16f16z v8f16:$src)>;
4092}
4093
4094class MVE_VABSNEG_fp<string iname, string suffix, bits<2> size, bit negate,
4095                   list<dag> pattern=[]>
4096  : MVE_float<iname, suffix, (outs MQPR:$Qd),
4097              (ins MQPR:$Qm), "$Qd, $Qm", vpred_r, "", size, pattern> {
4098  bits<4> Qd;
4099
4100  let Inst{28} = 0b1;
4101  let Inst{25-23} = 0b111;
4102  let Inst{22} = Qd{3};
4103  let Inst{21-20} = 0b11;
4104  let Inst{19-18} = size;
4105  let Inst{17-16} = 0b01;
4106  let Inst{15-13} = Qd{2-0};
4107  let Inst{11-8} = 0b0111;
4108  let Inst{7} = negate;
4109  let Inst{4} = 0b0;
4110  let validForTailPredication = 1;
4111}
4112
4113multiclass MVE_VABSNEG_fp_m<string iname, SDNode unpred_op, Intrinsic pred_int,
4114                            MVEVectorVTInfo VTI, bit opcode> {
4115  def "" : MVE_VABSNEG_fp<iname, VTI.Suffix, VTI.Size, opcode>;
4116  defvar Inst = !cast<Instruction>(NAME);
4117
4118  let Predicates = [HasMVEInt] in {
4119    def : Pat<(VTI.Vec (unpred_op (VTI.Vec MQPR:$v))),
4120              (VTI.Vec (Inst $v))>;
4121    def : Pat<(VTI.Vec (pred_int  (VTI.Vec MQPR:$v), (VTI.Pred VCCR:$mask),
4122                                  (VTI.Vec MQPR:$inactive))),
4123              (VTI.Vec (Inst $v, ARMVCCThen, $mask, zero_reg, $inactive))>;
4124  }
4125}
4126
4127defm MVE_VABSf16 : MVE_VABSNEG_fp_m<"vabs", fabs, int_arm_mve_abs_predicated,
4128                                    MVE_v8f16, 0>;
4129defm MVE_VABSf32 : MVE_VABSNEG_fp_m<"vabs", fabs, int_arm_mve_abs_predicated,
4130                                    MVE_v4f32, 0>;
4131defm MVE_VNEGf16 : MVE_VABSNEG_fp_m<"vneg", fneg, int_arm_mve_neg_predicated,
4132                                    MVE_v8f16, 1>;
4133defm MVE_VNEGf32 : MVE_VABSNEG_fp_m<"vneg", fneg, int_arm_mve_neg_predicated,
4134                                    MVE_v4f32, 1>;
4135
4136class MVE_VMAXMINNMA<string iname, string suffix, bits<2> size, bit bit_12,
4137                     list<dag> pattern=[]>
4138  : MVE_f<(outs MQPR:$Qd), (ins MQPR:$Qd_src, MQPR:$Qm),
4139          NoItinerary, iname, suffix, "$Qd, $Qm", vpred_n, "$Qd = $Qd_src",
4140          size, pattern> {
4141  bits<4> Qd;
4142  bits<4> Qm;
4143
4144  let Inst{28} = size{0};
4145  let Inst{25-23} = 0b100;
4146  let Inst{22} = Qd{3};
4147  let Inst{21-16} = 0b111111;
4148  let Inst{15-13} = Qd{2-0};
4149  let Inst{12} = bit_12;
4150  let Inst{11-6} = 0b111010;
4151  let Inst{5} = Qm{3};
4152  let Inst{4} = 0b0;
4153  let Inst{3-1} = Qm{2-0};
4154  let Inst{0} = 0b1;
4155
4156  let isCommutable = 1;
4157  let validForTailPredication = 1;
4158}
4159
4160multiclass MVE_VMAXMINNMA_m<string iname, MVEVectorVTInfo VTI,
4161                      SDNode unpred_op, Intrinsic pred_int,
4162                      bit bit_12> {
4163  def "" : MVE_VMAXMINNMA<iname, VTI.Suffix, VTI.Size, bit_12>;
4164  defvar Inst = !cast<Instruction>(NAME);
4165
4166  let Predicates = [HasMVEInt] in {
4167    // Unpredicated v(max|min)nma
4168    def : Pat<(VTI.Vec (unpred_op (fabs (VTI.Vec MQPR:$Qd)),
4169                                  (fabs (VTI.Vec MQPR:$Qm)))),
4170              (VTI.Vec (Inst (VTI.Vec MQPR:$Qd), (VTI.Vec MQPR:$Qm)))>;
4171
4172    // Predicated v(max|min)nma
4173    def : Pat<(VTI.Vec (pred_int (VTI.Vec MQPR:$Qd), (VTI.Vec MQPR:$Qm),
4174                            (VTI.Pred VCCR:$mask))),
4175              (VTI.Vec (Inst (VTI.Vec MQPR:$Qd), (VTI.Vec MQPR:$Qm),
4176                            ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg))>;
4177  }
4178}
4179
4180multiclass MVE_VMAXNMA<MVEVectorVTInfo VTI, bit bit_12>
4181  : MVE_VMAXMINNMA_m<"vmaxnma", VTI, fmaxnum, int_arm_mve_vmaxnma_predicated, bit_12>;
4182
4183defm MVE_VMAXNMAf32 : MVE_VMAXNMA<MVE_v4f32, 0b0>;
4184defm MVE_VMAXNMAf16 : MVE_VMAXNMA<MVE_v8f16, 0b0>;
4185
4186multiclass MVE_VMINNMA<MVEVectorVTInfo VTI, bit bit_12>
4187  : MVE_VMAXMINNMA_m<"vminnma", VTI, fminnum, int_arm_mve_vminnma_predicated, bit_12>;
4188
4189defm MVE_VMINNMAf32 : MVE_VMINNMA<MVE_v4f32, 0b1>;
4190defm MVE_VMINNMAf16 : MVE_VMINNMA<MVE_v8f16, 0b1>;
4191
4192// end of MVE Floating Point instructions
4193
4194// start of MVE compares
4195
4196class MVE_VCMPqq<string suffix, bit bit_28, bits<2> bits_21_20,
4197                 VCMPPredicateOperand predtype, bits<2> vecsize, list<dag> pattern=[]>
4198  : MVE_p<(outs VCCR:$P0), (ins MQPR:$Qn, MQPR:$Qm, predtype:$fc),
4199           NoItinerary, "vcmp", suffix, "$fc, $Qn, $Qm", vpred_n, "", vecsize, pattern> {
4200  // Base class for comparing two vector registers
4201  bits<3> fc;
4202  bits<4> Qn;
4203  bits<4> Qm;
4204
4205  let Inst{28} = bit_28;
4206  let Inst{25-22} = 0b1000;
4207  let Inst{21-20} = bits_21_20;
4208  let Inst{19-17} = Qn{2-0};
4209  let Inst{16-13} = 0b1000;
4210  let Inst{12} = fc{2};
4211  let Inst{11-8} = 0b1111;
4212  let Inst{7} = fc{0};
4213  let Inst{6} = 0b0;
4214  let Inst{5} = Qm{3};
4215  let Inst{4} = 0b0;
4216  let Inst{3-1} = Qm{2-0};
4217  let Inst{0} = fc{1};
4218
4219  let Constraints = "";
4220
4221  // We need a custom decoder method for these instructions because of
4222  // the output VCCR operand, which isn't encoded in the instruction
4223  // bits anywhere (there is only one choice for it) but has to be
4224  // included in the MC operands so that codegen will be able to track
4225  // its data flow between instructions, spill/reload it when
4226  // necessary, etc. There seems to be no way to get the Tablegen
4227  // decoder to emit an operand that isn't affected by any instruction
4228  // bit.
4229  let DecoderMethod = "DecodeMVEVCMP<false," # predtype.DecoderMethod # ">";
4230  let validForTailPredication = 1;
4231}
4232
4233class MVE_VCMPqqf<string suffix, bit size>
4234    : MVE_VCMPqq<suffix, size, 0b11, pred_basic_fp, !if(size, 0b01, 0b10)> {
4235  let Predicates = [HasMVEFloat];
4236}
4237
4238class MVE_VCMPqqi<string suffix, bits<2> size>
4239    : MVE_VCMPqq<suffix, 0b1, size, pred_basic_i, size> {
4240  let Inst{12} = 0b0;
4241  let Inst{0} = 0b0;
4242}
4243
4244class MVE_VCMPqqu<string suffix, bits<2> size>
4245    : MVE_VCMPqq<suffix, 0b1, size, pred_basic_u, size> {
4246  let Inst{12} = 0b0;
4247  let Inst{0} = 0b1;
4248}
4249
4250class MVE_VCMPqqs<string suffix, bits<2> size>
4251    : MVE_VCMPqq<suffix, 0b1, size, pred_basic_s, size> {
4252  let Inst{12} = 0b1;
4253}
4254
4255def MVE_VCMPf32 : MVE_VCMPqqf<"f32", 0b0>;
4256def MVE_VCMPf16 : MVE_VCMPqqf<"f16", 0b1>;
4257
4258def MVE_VCMPi8  : MVE_VCMPqqi<"i8",  0b00>;
4259def MVE_VCMPi16 : MVE_VCMPqqi<"i16", 0b01>;
4260def MVE_VCMPi32 : MVE_VCMPqqi<"i32", 0b10>;
4261
4262def MVE_VCMPu8  : MVE_VCMPqqu<"u8",  0b00>;
4263def MVE_VCMPu16 : MVE_VCMPqqu<"u16", 0b01>;
4264def MVE_VCMPu32 : MVE_VCMPqqu<"u32", 0b10>;
4265
4266def MVE_VCMPs8  : MVE_VCMPqqs<"s8",  0b00>;
4267def MVE_VCMPs16 : MVE_VCMPqqs<"s16", 0b01>;
4268def MVE_VCMPs32 : MVE_VCMPqqs<"s32", 0b10>;
4269
4270class MVE_VCMPqr<string suffix, bit bit_28, bits<2> bits_21_20,
4271                 VCMPPredicateOperand predtype, bits<2> vecsize, list<dag> pattern=[]>
4272  : MVE_p<(outs VCCR:$P0), (ins MQPR:$Qn, GPRwithZR:$Rm, predtype:$fc),
4273           NoItinerary, "vcmp", suffix, "$fc, $Qn, $Rm", vpred_n, "", vecsize, pattern> {
4274  // Base class for comparing a vector register with a scalar
4275  bits<3> fc;
4276  bits<4> Qn;
4277  bits<4> Rm;
4278
4279  let Inst{28} = bit_28;
4280  let Inst{25-22} = 0b1000;
4281  let Inst{21-20} = bits_21_20;
4282  let Inst{19-17} = Qn{2-0};
4283  let Inst{16-13} = 0b1000;
4284  let Inst{12} = fc{2};
4285  let Inst{11-8} = 0b1111;
4286  let Inst{7} = fc{0};
4287  let Inst{6} = 0b1;
4288  let Inst{5} = fc{1};
4289  let Inst{4} = 0b0;
4290  let Inst{3-0} = Rm{3-0};
4291
4292  let Constraints = "";
4293  // Custom decoder method, for the same reason as MVE_VCMPqq
4294  let DecoderMethod = "DecodeMVEVCMP<true," # predtype.DecoderMethod # ">";
4295  let validForTailPredication = 1;
4296}
4297
4298class MVE_VCMPqrf<string suffix, bit size>
4299    : MVE_VCMPqr<suffix, size, 0b11, pred_basic_fp, !if(size, 0b01, 0b10)> {
4300  let Predicates = [HasMVEFloat];
4301}
4302
4303class MVE_VCMPqri<string suffix, bits<2> size>
4304    : MVE_VCMPqr<suffix, 0b1, size, pred_basic_i, size> {
4305  let Inst{12} = 0b0;
4306  let Inst{5} = 0b0;
4307}
4308
4309class MVE_VCMPqru<string suffix, bits<2> size>
4310    : MVE_VCMPqr<suffix, 0b1, size, pred_basic_u, size> {
4311  let Inst{12} = 0b0;
4312  let Inst{5} = 0b1;
4313}
4314
4315class MVE_VCMPqrs<string suffix, bits<2> size>
4316    : MVE_VCMPqr<suffix, 0b1, size, pred_basic_s, size> {
4317  let Inst{12} = 0b1;
4318}
4319
4320def MVE_VCMPf32r : MVE_VCMPqrf<"f32", 0b0>;
4321def MVE_VCMPf16r : MVE_VCMPqrf<"f16", 0b1>;
4322
4323def MVE_VCMPi8r  : MVE_VCMPqri<"i8",  0b00>;
4324def MVE_VCMPi16r : MVE_VCMPqri<"i16", 0b01>;
4325def MVE_VCMPi32r : MVE_VCMPqri<"i32", 0b10>;
4326
4327def MVE_VCMPu8r  : MVE_VCMPqru<"u8",  0b00>;
4328def MVE_VCMPu16r : MVE_VCMPqru<"u16", 0b01>;
4329def MVE_VCMPu32r : MVE_VCMPqru<"u32", 0b10>;
4330
4331def MVE_VCMPs8r  : MVE_VCMPqrs<"s8",  0b00>;
4332def MVE_VCMPs16r : MVE_VCMPqrs<"s16", 0b01>;
4333def MVE_VCMPs32r : MVE_VCMPqrs<"s32", 0b10>;
4334
4335multiclass unpred_vcmp_z<string suffix, PatLeaf fc> {
4336  def i8  : Pat<(v16i1 (ARMvcmpz (v16i8 MQPR:$v1), fc)),
4337                (v16i1 (!cast<Instruction>("MVE_VCMP"#suffix#"8r") (v16i8 MQPR:$v1), ZR, fc))>;
4338  def i16 : Pat<(v8i1 (ARMvcmpz (v8i16 MQPR:$v1), fc)),
4339                (v8i1 (!cast<Instruction>("MVE_VCMP"#suffix#"16r") (v8i16 MQPR:$v1), ZR, fc))>;
4340  def i32 : Pat<(v4i1 (ARMvcmpz (v4i32 MQPR:$v1), fc)),
4341                (v4i1 (!cast<Instruction>("MVE_VCMP"#suffix#"32r") (v4i32 MQPR:$v1), ZR, fc))>;
4342
4343  def : Pat<(v16i1 (and (v16i1 VCCR:$p1), (v16i1 (ARMvcmpz (v16i8 MQPR:$v1), fc)))),
4344            (v16i1 (!cast<Instruction>("MVE_VCMP"#suffix#"8r") (v16i8 MQPR:$v1), ZR, fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4345  def : Pat<(v8i1 (and (v8i1 VCCR:$p1), (v8i1 (ARMvcmpz (v8i16 MQPR:$v1), fc)))),
4346            (v8i1 (!cast<Instruction>("MVE_VCMP"#suffix#"16r") (v8i16 MQPR:$v1), ZR, fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4347  def : Pat<(v4i1 (and (v4i1 VCCR:$p1), (v4i1 (ARMvcmpz (v4i32 MQPR:$v1), fc)))),
4348            (v4i1 (!cast<Instruction>("MVE_VCMP"#suffix#"32r") (v4i32 MQPR:$v1), ZR, fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4349}
4350
4351multiclass unpred_vcmp_r<string suffix, PatLeaf fc> {
4352  def i8  : Pat<(v16i1 (ARMvcmp (v16i8 MQPR:$v1), (v16i8 MQPR:$v2), fc)),
4353                (v16i1 (!cast<Instruction>("MVE_VCMP"#suffix#"8") (v16i8 MQPR:$v1), (v16i8 MQPR:$v2), fc))>;
4354  def i16 : Pat<(v8i1 (ARMvcmp (v8i16 MQPR:$v1), (v8i16 MQPR:$v2), fc)),
4355                (v8i1 (!cast<Instruction>("MVE_VCMP"#suffix#"16") (v8i16 MQPR:$v1), (v8i16 MQPR:$v2), fc))>;
4356  def i32 : Pat<(v4i1 (ARMvcmp (v4i32 MQPR:$v1), (v4i32 MQPR:$v2), fc)),
4357                (v4i1 (!cast<Instruction>("MVE_VCMP"#suffix#"32") (v4i32 MQPR:$v1), (v4i32 MQPR:$v2), fc))>;
4358
4359  def i8r  : Pat<(v16i1 (ARMvcmp (v16i8 MQPR:$v1), (v16i8 (ARMvdup rGPR:$v2)), fc)),
4360                 (v16i1 (!cast<Instruction>("MVE_VCMP"#suffix#"8r") (v16i8 MQPR:$v1), (i32 rGPR:$v2), fc))>;
4361  def i16r : Pat<(v8i1 (ARMvcmp (v8i16 MQPR:$v1), (v8i16 (ARMvdup rGPR:$v2)), fc)),
4362                 (v8i1 (!cast<Instruction>("MVE_VCMP"#suffix#"16r") (v8i16 MQPR:$v1), (i32 rGPR:$v2), fc))>;
4363  def i32r : Pat<(v4i1 (ARMvcmp (v4i32 MQPR:$v1), (v4i32 (ARMvdup rGPR:$v2)), fc)),
4364                 (v4i1 (!cast<Instruction>("MVE_VCMP"#suffix#"32r") (v4i32 MQPR:$v1), (i32 rGPR:$v2), fc))>;
4365
4366  def : Pat<(v16i1 (and (v16i1 VCCR:$p1), (v16i1 (ARMvcmp (v16i8 MQPR:$v1), (v16i8 MQPR:$v2), fc)))),
4367            (v16i1 (!cast<Instruction>("MVE_VCMP"#suffix#"8") (v16i8 MQPR:$v1), (v16i8 MQPR:$v2), fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4368  def : Pat<(v8i1 (and (v8i1 VCCR:$p1), (v8i1 (ARMvcmp (v8i16 MQPR:$v1), (v8i16 MQPR:$v2), fc)))),
4369            (v8i1 (!cast<Instruction>("MVE_VCMP"#suffix#"16") (v8i16 MQPR:$v1), (v8i16 MQPR:$v2), fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4370  def : Pat<(v4i1 (and (v4i1 VCCR:$p1), (v4i1 (ARMvcmp (v4i32 MQPR:$v1), (v4i32 MQPR:$v2), fc)))),
4371            (v4i1 (!cast<Instruction>("MVE_VCMP"#suffix#"32") (v4i32 MQPR:$v1), (v4i32 MQPR:$v2), fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4372
4373  def : Pat<(v16i1 (and (v16i1 VCCR:$p1), (v16i1 (ARMvcmp (v16i8 MQPR:$v1), (v16i8 (ARMvdup rGPR:$v2)), fc)))),
4374            (v16i1 (!cast<Instruction>("MVE_VCMP"#suffix#"8r") (v16i8 MQPR:$v1), (i32 rGPR:$v2), fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4375  def : Pat<(v8i1 (and (v8i1 VCCR:$p1), (v8i1 (ARMvcmp (v8i16 MQPR:$v1), (v8i16 (ARMvdup rGPR:$v2)), fc)))),
4376            (v8i1 (!cast<Instruction>("MVE_VCMP"#suffix#"16r") (v8i16 MQPR:$v1), (i32 rGPR:$v2), fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4377  def : Pat<(v4i1 (and (v4i1 VCCR:$p1), (v4i1 (ARMvcmp (v4i32 MQPR:$v1), (v4i32 (ARMvdup rGPR:$v2)), fc)))),
4378            (v4i1 (!cast<Instruction>("MVE_VCMP"#suffix#"32r") (v4i32 MQPR:$v1), (i32 rGPR:$v2), fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4379}
4380
4381multiclass unpred_vcmpf_z<PatLeaf fc> {
4382  def f16 : Pat<(v8i1 (ARMvcmpz (v8f16 MQPR:$v1), fc)),
4383                (v8i1 (MVE_VCMPf16r (v8f16 MQPR:$v1), ZR, fc))>;
4384  def f32 : Pat<(v4i1 (ARMvcmpz (v4f32 MQPR:$v1), fc)),
4385                (v4i1 (MVE_VCMPf32r (v4f32 MQPR:$v1), ZR, fc))>;
4386
4387  def : Pat<(v8i1 (and (v8i1 VCCR:$p1), (v8i1 (ARMvcmpz (v8f16 MQPR:$v1), fc)))),
4388            (v8i1 (MVE_VCMPf16r (v8f16 MQPR:$v1), ZR, fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4389  def : Pat<(v4i1 (and (v4i1 VCCR:$p1), (v4i1 (ARMvcmpz (v4f32 MQPR:$v1), fc)))),
4390            (v4i1 (MVE_VCMPf32r (v4f32 MQPR:$v1), ZR, fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4391}
4392
4393multiclass unpred_vcmpf_r<PatLeaf fc> {
4394  def : Pat<(v8i1 (ARMvcmp (v8f16 MQPR:$v1), (v8f16 MQPR:$v2), fc)),
4395            (v8i1 (MVE_VCMPf16 (v8f16 MQPR:$v1), (v8f16 MQPR:$v2), fc))>;
4396  def : Pat<(v4i1 (ARMvcmp (v4f32 MQPR:$v1), (v4f32 MQPR:$v2), fc)),
4397            (v4i1 (MVE_VCMPf32 (v4f32 MQPR:$v1), (v4f32 MQPR:$v2), fc))>;
4398
4399  def : Pat<(v8i1 (ARMvcmp (v8f16 MQPR:$v1), (v8f16 (ARMvdup rGPR:$v2)), fc)),
4400            (v8i1 (MVE_VCMPf16r (v8f16 MQPR:$v1), (i32 rGPR:$v2), fc))>;
4401  def : Pat<(v4i1 (ARMvcmp (v4f32 MQPR:$v1), (v4f32 (ARMvdup rGPR:$v2)), fc)),
4402            (v4i1 (MVE_VCMPf32r (v4f32 MQPR:$v1), (i32 rGPR:$v2), fc))>;
4403
4404  def : Pat<(v8i1 (and (v8i1 VCCR:$p1), (v8i1 (ARMvcmp (v8f16 MQPR:$v1), (v8f16 MQPR:$v2), fc)))),
4405            (v8i1 (MVE_VCMPf16 (v8f16 MQPR:$v1), (v8f16 MQPR:$v2), fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4406  def : Pat<(v4i1 (and (v4i1 VCCR:$p1), (v4i1 (ARMvcmp (v4f32 MQPR:$v1), (v4f32 MQPR:$v2), fc)))),
4407            (v4i1 (MVE_VCMPf32 (v4f32 MQPR:$v1), (v4f32 MQPR:$v2), fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4408
4409  def : Pat<(v8i1 (and (v8i1 VCCR:$p1), (v8i1 (ARMvcmp (v8f16 MQPR:$v1), (v8f16 (ARMvdup rGPR:$v2)), fc)))),
4410            (v8i1 (MVE_VCMPf16r (v8f16 MQPR:$v1), (i32 rGPR:$v2), fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4411  def : Pat<(v4i1 (and (v4i1 VCCR:$p1), (v4i1 (ARMvcmp (v4f32 MQPR:$v1), (v4f32 (ARMvdup rGPR:$v2)), fc)))),
4412            (v4i1 (MVE_VCMPf32r (v4f32 MQPR:$v1), (i32 rGPR:$v2), fc, ARMVCCThen, VCCR:$p1, zero_reg))>;
4413}
4414
4415let Predicates = [HasMVEInt] in {
4416  defm MVE_VCEQZ  : unpred_vcmp_z<"i", ARMCCeq>;
4417  defm MVE_VCNEZ  : unpred_vcmp_z<"i", ARMCCne>;
4418  defm MVE_VCGEZ  : unpred_vcmp_z<"s", ARMCCge>;
4419  defm MVE_VCLTZ  : unpred_vcmp_z<"s", ARMCClt>;
4420  defm MVE_VCGTZ  : unpred_vcmp_z<"s", ARMCCgt>;
4421  defm MVE_VCLEZ  : unpred_vcmp_z<"s", ARMCCle>;
4422  defm MVE_VCGTUZ : unpred_vcmp_z<"u", ARMCChi>;
4423  defm MVE_VCGEUZ : unpred_vcmp_z<"u", ARMCChs>;
4424
4425  defm MVE_VCEQ   : unpred_vcmp_r<"i", ARMCCeq>;
4426  defm MVE_VCNE   : unpred_vcmp_r<"i", ARMCCne>;
4427  defm MVE_VCGE   : unpred_vcmp_r<"s", ARMCCge>;
4428  defm MVE_VCLT   : unpred_vcmp_r<"s", ARMCClt>;
4429  defm MVE_VCGT   : unpred_vcmp_r<"s", ARMCCgt>;
4430  defm MVE_VCLE   : unpred_vcmp_r<"s", ARMCCle>;
4431  defm MVE_VCGTU  : unpred_vcmp_r<"u", ARMCChi>;
4432  defm MVE_VCGEU  : unpred_vcmp_r<"u", ARMCChs>;
4433}
4434
4435let Predicates = [HasMVEFloat] in {
4436  defm MVE_VFCEQZ  : unpred_vcmpf_z<ARMCCeq>;
4437  defm MVE_VFCNEZ  : unpred_vcmpf_z<ARMCCne>;
4438  defm MVE_VFCGEZ  : unpred_vcmpf_z<ARMCCge>;
4439  defm MVE_VFCLTZ  : unpred_vcmpf_z<ARMCClt>;
4440  defm MVE_VFCGTZ  : unpred_vcmpf_z<ARMCCgt>;
4441  defm MVE_VFCLEZ  : unpred_vcmpf_z<ARMCCle>;
4442
4443  defm MVE_VFCEQ   : unpred_vcmpf_r<ARMCCeq>;
4444  defm MVE_VFCNE   : unpred_vcmpf_r<ARMCCne>;
4445  defm MVE_VFCGE   : unpred_vcmpf_r<ARMCCge>;
4446  defm MVE_VFCLT   : unpred_vcmpf_r<ARMCClt>;
4447  defm MVE_VFCGT   : unpred_vcmpf_r<ARMCCgt>;
4448  defm MVE_VFCLE   : unpred_vcmpf_r<ARMCCle>;
4449}
4450
4451
4452// Extra "worst case" and/or/xor patterns, going into and out of GRP
4453multiclass two_predops<SDPatternOperator opnode, Instruction insn> {
4454  def v16i1 : Pat<(v16i1 (opnode (v16i1 VCCR:$p1), (v16i1 VCCR:$p2))),
4455                  (v16i1 (COPY_TO_REGCLASS
4456                           (insn (i32 (COPY_TO_REGCLASS (v16i1 VCCR:$p1), rGPR)),
4457                                 (i32 (COPY_TO_REGCLASS (v16i1 VCCR:$p2), rGPR))),
4458                           VCCR))>;
4459  def v8i1  : Pat<(v8i1 (opnode (v8i1 VCCR:$p1), (v8i1 VCCR:$p2))),
4460                  (v8i1 (COPY_TO_REGCLASS
4461                          (insn (i32 (COPY_TO_REGCLASS (v8i1 VCCR:$p1), rGPR)),
4462                                (i32 (COPY_TO_REGCLASS (v8i1 VCCR:$p2), rGPR))),
4463                          VCCR))>;
4464  def v4i1  : Pat<(v4i1 (opnode (v4i1 VCCR:$p1), (v4i1 VCCR:$p2))),
4465                  (v4i1 (COPY_TO_REGCLASS
4466                          (insn (i32 (COPY_TO_REGCLASS (v4i1 VCCR:$p1), rGPR)),
4467                                (i32 (COPY_TO_REGCLASS (v4i1 VCCR:$p2), rGPR))),
4468                          VCCR))>;
4469  def v2i1  : Pat<(v2i1 (opnode (v2i1 VCCR:$p1), (v2i1 VCCR:$p2))),
4470                  (v2i1 (COPY_TO_REGCLASS
4471                          (insn (i32 (COPY_TO_REGCLASS (v2i1 VCCR:$p1), rGPR)),
4472                                (i32 (COPY_TO_REGCLASS (v2i1 VCCR:$p2), rGPR))),
4473                          VCCR))>;
4474}
4475
4476let Predicates = [HasMVEInt] in {
4477  defm POR    : two_predops<or,  t2ORRrr>;
4478  defm PAND   : two_predops<and, t2ANDrr>;
4479  defm PEOR   : two_predops<xor, t2EORrr>;
4480}
4481
4482// Occasionally we need to cast between a i32 and a boolean vector, for
4483// example when moving between rGPR and VPR.P0 as part of predicate vector
4484// shuffles. We also sometimes need to cast between different predicate
4485// vector types (v4i1<>v8i1, etc.) also as part of lowering vector shuffles.
4486def predicate_cast : SDNode<"ARMISD::PREDICATE_CAST", SDTUnaryOp>;
4487
4488def load_align4 : PatFrag<(ops node:$ptr), (load node:$ptr), [{
4489  return cast<LoadSDNode>(N)->getAlign() >= 4;
4490}]>;
4491
4492let Predicates = [HasMVEInt] in {
4493  foreach VT = [ v2i1, v4i1, v8i1, v16i1 ] in {
4494    def : Pat<(i32 (predicate_cast (VT VCCR:$src))),
4495              (i32 (COPY_TO_REGCLASS (VT VCCR:$src), VCCR))>;
4496    def : Pat<(VT  (predicate_cast (i32 VCCR:$src))),
4497              (VT  (COPY_TO_REGCLASS (i32 VCCR:$src), VCCR))>;
4498
4499    foreach VT2 = [ v2i1, v4i1, v8i1, v16i1 ] in
4500      def : Pat<(VT  (predicate_cast (VT2 VCCR:$src))),
4501                (VT  (COPY_TO_REGCLASS (VT2 VCCR:$src), VCCR))>;
4502  }
4503
4504  // If we happen to be casting from a load we can convert that straight
4505  // into a predicate load, so long as the load is of the correct type.
4506  foreach VT = [ v2i1, v4i1, v8i1, v16i1 ] in {
4507    def : Pat<(VT (predicate_cast (i32 (load_align4 taddrmode_imm7<2>:$addr)))),
4508              (VT (VLDR_P0_off taddrmode_imm7<2>:$addr))>;
4509  }
4510
4511  // Here we match the specific SDNode type 'ARMVectorRegCastImpl'
4512  // rather than the more general 'ARMVectorRegCast' which would also
4513  // match some bitconverts. If we use the latter in cases where the
4514  // input and output types are the same, the bitconvert gets elided
4515  // and we end up generating a nonsense match of nothing.
4516
4517  foreach VT = [ v16i8, v8i16, v8f16, v4i32, v4f32, v2i64, v2f64 ] in
4518    foreach VT2 = [ v16i8, v8i16, v8f16, v4i32, v4f32, v2i64, v2f64 ] in
4519      def : Pat<(VT (ARMVectorRegCastImpl (VT2 MQPR:$src))),
4520                (VT MQPR:$src)>;
4521}
4522
4523// end of MVE compares
4524
4525// start of MVE_qDest_qSrc
4526
4527class MVE_qDest_qSrc<string iname, string suffix, dag oops, dag iops,
4528                     string ops, vpred_ops vpred, string cstr,
4529                     bits<2> vecsize, list<dag> pattern=[]>
4530  : MVE_p<oops, iops, NoItinerary, iname, suffix,
4531          ops, vpred, cstr, vecsize, pattern> {
4532  bits<4> Qd;
4533  bits<4> Qm;
4534
4535  let Inst{25-23} = 0b100;
4536  let Inst{22} = Qd{3};
4537  let Inst{15-13} = Qd{2-0};
4538  let Inst{11-9} = 0b111;
4539  let Inst{6} = 0b0;
4540  let Inst{5} = Qm{3};
4541  let Inst{4} = 0b0;
4542  let Inst{3-1} = Qm{2-0};
4543}
4544
4545class MVE_VQxDMLxDH<string iname, bit exch, bit round, bit subtract,
4546                    string suffix, bits<2> size, string cstr="",
4547                    list<dag> pattern=[]>
4548  : MVE_qDest_qSrc<iname, suffix, (outs MQPR:$Qd),
4549                   (ins MQPR:$Qd_src, MQPR:$Qn, MQPR:$Qm), "$Qd, $Qn, $Qm",
4550                   vpred_n, "$Qd = $Qd_src"#cstr, size, pattern> {
4551  bits<4> Qn;
4552
4553  let Inst{28} = subtract;
4554  let Inst{21-20} = size;
4555  let Inst{19-17} = Qn{2-0};
4556  let Inst{16} = 0b0;
4557  let Inst{12} = exch;
4558  let Inst{8} = 0b0;
4559  let Inst{7} = Qn{3};
4560  let Inst{0} = round;
4561}
4562
4563multiclass MVE_VQxDMLxDH_p<string iname, bit exch, bit round, bit subtract,
4564                           MVEVectorVTInfo VTI> {
4565  def "": MVE_VQxDMLxDH<iname, exch, round, subtract, VTI.Suffix, VTI.Size,
4566                        !if(!eq(VTI.LaneBits, 32), ",@earlyclobber $Qd", "")>;
4567  defvar Inst = !cast<Instruction>(NAME);
4568  defvar ConstParams = (? (i32 exch), (i32 round), (i32 subtract));
4569  defvar unpred_intr = int_arm_mve_vqdmlad;
4570  defvar pred_intr = int_arm_mve_vqdmlad_predicated;
4571
4572  def : Pat<(VTI.Vec !con((unpred_intr (VTI.Vec MQPR:$a), (VTI.Vec MQPR:$b),
4573                                       (VTI.Vec MQPR:$c)), ConstParams)),
4574            (VTI.Vec (Inst (VTI.Vec MQPR:$a), (VTI.Vec MQPR:$b),
4575                           (VTI.Vec MQPR:$c)))>;
4576  def : Pat<(VTI.Vec !con((pred_intr (VTI.Vec MQPR:$a), (VTI.Vec MQPR:$b),
4577                                     (VTI.Vec MQPR:$c)), ConstParams,
4578                          (? (VTI.Pred VCCR:$pred)))),
4579            (VTI.Vec (Inst (VTI.Vec MQPR:$a), (VTI.Vec MQPR:$b),
4580                           (VTI.Vec MQPR:$c),
4581                           ARMVCCThen, (VTI.Pred VCCR:$pred), zero_reg))>;
4582}
4583
4584multiclass MVE_VQxDMLxDH_multi<string iname, bit exch,
4585                               bit round, bit subtract> {
4586  defm s8  : MVE_VQxDMLxDH_p<iname, exch, round, subtract, MVE_v16s8>;
4587  defm s16 : MVE_VQxDMLxDH_p<iname, exch, round, subtract, MVE_v8s16>;
4588  defm s32 : MVE_VQxDMLxDH_p<iname, exch, round, subtract, MVE_v4s32>;
4589}
4590
4591defm MVE_VQDMLADH   : MVE_VQxDMLxDH_multi<"vqdmladh",   0b0, 0b0, 0b0>;
4592defm MVE_VQDMLADHX  : MVE_VQxDMLxDH_multi<"vqdmladhx",  0b1, 0b0, 0b0>;
4593defm MVE_VQRDMLADH  : MVE_VQxDMLxDH_multi<"vqrdmladh",  0b0, 0b1, 0b0>;
4594defm MVE_VQRDMLADHX : MVE_VQxDMLxDH_multi<"vqrdmladhx", 0b1, 0b1, 0b0>;
4595defm MVE_VQDMLSDH   : MVE_VQxDMLxDH_multi<"vqdmlsdh",   0b0, 0b0, 0b1>;
4596defm MVE_VQDMLSDHX  : MVE_VQxDMLxDH_multi<"vqdmlsdhx",  0b1, 0b0, 0b1>;
4597defm MVE_VQRDMLSDH  : MVE_VQxDMLxDH_multi<"vqrdmlsdh",  0b0, 0b1, 0b1>;
4598defm MVE_VQRDMLSDHX : MVE_VQxDMLxDH_multi<"vqrdmlsdhx", 0b1, 0b1, 0b1>;
4599
4600class MVE_VCMUL<string iname, string suffix, bits<2> size, string cstr="">
4601  : MVE_qDest_qSrc<iname, suffix, (outs MQPR:$Qd),
4602                   (ins MQPR:$Qn, MQPR:$Qm, complexrotateop:$rot),
4603                   "$Qd, $Qn, $Qm, $rot", vpred_r, cstr, size,
4604                   []> {
4605  bits<4> Qn;
4606  bits<2> rot;
4607
4608  let Inst{28} = size{1};
4609  let Inst{21-20} = 0b11;
4610  let Inst{19-17} = Qn{2-0};
4611  let Inst{16} = 0b0;
4612  let Inst{12} = rot{1};
4613  let Inst{8} = 0b0;
4614  let Inst{7} = Qn{3};
4615  let Inst{0} = rot{0};
4616
4617  let Predicates = [HasMVEFloat];
4618}
4619
4620multiclass MVE_VCMUL_m<string iname, MVEVectorVTInfo VTI,
4621                       string cstr=""> {
4622  def "" : MVE_VCMUL<iname, VTI.Suffix, VTI.Size, cstr>;
4623  defvar Inst = !cast<Instruction>(NAME);
4624
4625  let Predicates = [HasMVEFloat] in {
4626    def : Pat<(VTI.Vec (int_arm_mve_vcmulq
4627                            imm:$rot, (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm))),
4628              (VTI.Vec (Inst (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
4629                             imm:$rot))>;
4630
4631    def : Pat<(VTI.Vec (int_arm_mve_vcmulq_predicated
4632                            imm:$rot, (VTI.Vec MQPR:$inactive),
4633                            (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
4634                            (VTI.Pred VCCR:$mask))),
4635              (VTI.Vec (Inst (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
4636                             imm:$rot, ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
4637                             (VTI.Vec MQPR:$inactive)))>;
4638
4639  }
4640}
4641
4642defm MVE_VCMULf16 : MVE_VCMUL_m<"vcmul", MVE_v8f16>;
4643defm MVE_VCMULf32 : MVE_VCMUL_m<"vcmul", MVE_v4f32, "@earlyclobber $Qd">;
4644
4645class MVE_VMULL<string iname, string suffix, bit bit_28, bits<2> bits_21_20,
4646                bit T, string cstr, bits<2> vecsize, list<dag> pattern=[]>
4647  : MVE_qDest_qSrc<iname, suffix, (outs MQPR:$Qd),
4648                   (ins MQPR:$Qn, MQPR:$Qm), "$Qd, $Qn, $Qm",
4649                   vpred_r, cstr, vecsize, pattern> {
4650  bits<4> Qd;
4651  bits<4> Qn;
4652  bits<4> Qm;
4653
4654  let Inst{28} = bit_28;
4655  let Inst{21-20} = bits_21_20;
4656  let Inst{19-17} = Qn{2-0};
4657  let Inst{16} = 0b1;
4658  let Inst{12} = T;
4659  let Inst{8} = 0b0;
4660  let Inst{7} = Qn{3};
4661  let Inst{0} = 0b0;
4662  let validForTailPredication = 1;
4663  let doubleWidthResult = 1;
4664}
4665
4666multiclass MVE_VMULL_m<MVEVectorVTInfo VTI,
4667                       SDPatternOperator unpred_op, Intrinsic pred_int,
4668                       bit Top, bits<2> vecsize, string cstr=""> {
4669  def "" : MVE_VMULL<"vmull" # !if(Top, "t", "b"), VTI.Suffix, VTI.Unsigned,
4670                     VTI.Size, Top, cstr, vecsize>;
4671  defvar Inst = !cast<Instruction>(NAME);
4672
4673  let Predicates = [HasMVEInt] in {
4674    defvar uflag = !if(!eq(VTI.SuffixLetter, "p"), (?), (? (i32 VTI.Unsigned)));
4675
4676    // Unpredicated multiply
4677    def : Pat<(VTI.DblVec !con((unpred_op (VTI.Vec MQPR:$Qm),
4678                                          (VTI.Vec MQPR:$Qn)),
4679                               uflag, (? (i32 Top)))),
4680              (VTI.DblVec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn)))>;
4681
4682    // Predicated multiply
4683    def : Pat<(VTI.DblVec !con((pred_int (VTI.Vec MQPR:$Qm),
4684                                         (VTI.Vec MQPR:$Qn)),
4685                               uflag, (? (i32 Top), (VTI.DblPred VCCR:$mask),
4686                                         (VTI.DblVec MQPR:$inactive)))),
4687              (VTI.DblVec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
4688                                ARMVCCThen, (VTI.DblPred VCCR:$mask), zero_reg,
4689                                (VTI.DblVec MQPR:$inactive)))>;
4690  }
4691}
4692
4693// For polynomial multiplies, the size bits take the unused value 0b11, and
4694// the unsigned bit switches to encoding the size.
4695
4696defm MVE_VMULLBs8  : MVE_VMULL_m<MVE_v16s8, int_arm_mve_vmull,
4697                                 int_arm_mve_mull_int_predicated, 0b0, 0b01>;
4698defm MVE_VMULLTs8  : MVE_VMULL_m<MVE_v16s8, int_arm_mve_vmull,
4699                                 int_arm_mve_mull_int_predicated, 0b1, 0b01>;
4700defm MVE_VMULLBs16 : MVE_VMULL_m<MVE_v8s16, int_arm_mve_vmull,
4701                                 int_arm_mve_mull_int_predicated, 0b0, 0b10>;
4702defm MVE_VMULLTs16 : MVE_VMULL_m<MVE_v8s16, int_arm_mve_vmull,
4703                                 int_arm_mve_mull_int_predicated, 0b1, 0b10>;
4704defm MVE_VMULLBs32 : MVE_VMULL_m<MVE_v4s32, int_arm_mve_vmull,
4705                                 int_arm_mve_mull_int_predicated, 0b0, 0b11,
4706                                 "@earlyclobber $Qd">;
4707defm MVE_VMULLTs32 : MVE_VMULL_m<MVE_v4s32, int_arm_mve_vmull,
4708                                 int_arm_mve_mull_int_predicated, 0b1, 0b11,
4709                                 "@earlyclobber $Qd">;
4710
4711defm MVE_VMULLBu8  : MVE_VMULL_m<MVE_v16u8, int_arm_mve_vmull,
4712                                 int_arm_mve_mull_int_predicated, 0b0, 0b01>;
4713defm MVE_VMULLTu8  : MVE_VMULL_m<MVE_v16u8, int_arm_mve_vmull,
4714                                 int_arm_mve_mull_int_predicated, 0b1, 0b01>;
4715defm MVE_VMULLBu16 : MVE_VMULL_m<MVE_v8u16, int_arm_mve_vmull,
4716                                 int_arm_mve_mull_int_predicated, 0b0, 0b10>;
4717defm MVE_VMULLTu16 : MVE_VMULL_m<MVE_v8u16, int_arm_mve_vmull,
4718                                 int_arm_mve_mull_int_predicated, 0b1, 0b10>;
4719defm MVE_VMULLBu32 : MVE_VMULL_m<MVE_v4u32, int_arm_mve_vmull,
4720                                 int_arm_mve_mull_int_predicated, 0b0, 0b11,
4721                                 "@earlyclobber $Qd">;
4722defm MVE_VMULLTu32 : MVE_VMULL_m<MVE_v4u32, int_arm_mve_vmull,
4723                                 int_arm_mve_mull_int_predicated, 0b1, 0b11,
4724                                 "@earlyclobber $Qd">;
4725
4726defm MVE_VMULLBp8  : MVE_VMULL_m<MVE_v16p8, int_arm_mve_vmull_poly,
4727                                 int_arm_mve_mull_poly_predicated, 0b0, 0b01>;
4728defm MVE_VMULLTp8  : MVE_VMULL_m<MVE_v16p8, int_arm_mve_vmull_poly,
4729                                 int_arm_mve_mull_poly_predicated, 0b1, 0b01>;
4730defm MVE_VMULLBp16 : MVE_VMULL_m<MVE_v8p16, int_arm_mve_vmull_poly,
4731                                 int_arm_mve_mull_poly_predicated, 0b0, 0b10>;
4732defm MVE_VMULLTp16 : MVE_VMULL_m<MVE_v8p16, int_arm_mve_vmull_poly,
4733                                 int_arm_mve_mull_poly_predicated, 0b1, 0b10>;
4734
4735let Predicates = [HasMVEInt] in {
4736  def : Pat<(v2i64 (ARMvmulls (v4i32 MQPR:$src1), (v4i32 MQPR:$src2))),
4737            (MVE_VMULLBs32 MQPR:$src1, MQPR:$src2)>;
4738  def : Pat<(v2i64 (ARMvmulls (v4i32 (ARMvrev64 (v4i32 MQPR:$src1))),
4739                              (v4i32 (ARMvrev64 (v4i32 MQPR:$src2))))),
4740            (MVE_VMULLTs32 MQPR:$src1, MQPR:$src2)>;
4741
4742  def : Pat<(mul (sext_inreg (v4i32 MQPR:$src1), v4i16),
4743                 (sext_inreg (v4i32 MQPR:$src2), v4i16)),
4744            (MVE_VMULLBs16 MQPR:$src1, MQPR:$src2)>;
4745  def : Pat<(mul (sext_inreg (v4i32 (ARMVectorRegCast (ARMvrev32 (v8i16 MQPR:$src1)))), v4i16),
4746                 (sext_inreg (v4i32 (ARMVectorRegCast (ARMvrev32 (v8i16 MQPR:$src2)))), v4i16)),
4747            (MVE_VMULLTs16 MQPR:$src1, MQPR:$src2)>;
4748
4749  def : Pat<(mul (sext_inreg (v8i16 MQPR:$src1), v8i8),
4750                 (sext_inreg (v8i16 MQPR:$src2), v8i8)),
4751            (MVE_VMULLBs8 MQPR:$src1, MQPR:$src2)>;
4752  def : Pat<(mul (sext_inreg (v8i16 (ARMVectorRegCast (ARMvrev16 (v16i8 MQPR:$src1)))), v8i8),
4753                 (sext_inreg (v8i16 (ARMVectorRegCast (ARMvrev16 (v16i8 MQPR:$src2)))), v8i8)),
4754            (MVE_VMULLTs8 MQPR:$src1, MQPR:$src2)>;
4755
4756  def : Pat<(v2i64 (ARMvmullu (v4i32 MQPR:$src1), (v4i32 MQPR:$src2))),
4757            (MVE_VMULLBu32 MQPR:$src1, MQPR:$src2)>;
4758  def : Pat<(v2i64 (ARMvmullu (v4i32 (ARMvrev64 (v4i32 MQPR:$src1))),
4759                              (v4i32 (ARMvrev64 (v4i32 MQPR:$src2))))),
4760            (MVE_VMULLTu32 MQPR:$src1, MQPR:$src2)>;
4761
4762  def : Pat<(mul (and (v4i32 MQPR:$src1), (v4i32 (ARMvmovImm (i32 0xCFF)))),
4763                 (and (v4i32 MQPR:$src2), (v4i32 (ARMvmovImm (i32 0xCFF))))),
4764            (MVE_VMULLBu16 MQPR:$src1, MQPR:$src2)>;
4765  def : Pat<(mul (and (v4i32 (ARMVectorRegCast (ARMvrev32 (v8i16 MQPR:$src1)))),
4766                      (v4i32 (ARMvmovImm (i32 0xCFF)))),
4767                 (and (v4i32 (ARMVectorRegCast (ARMvrev32 (v8i16 MQPR:$src2)))),
4768                      (v4i32 (ARMvmovImm (i32 0xCFF))))),
4769            (MVE_VMULLTu16 MQPR:$src1, MQPR:$src2)>;
4770
4771  def : Pat<(mul (ARMvbicImm (v8i16 MQPR:$src1), (i32 0xAFF)),
4772                 (ARMvbicImm (v8i16 MQPR:$src2), (i32 0xAFF))),
4773            (MVE_VMULLBu8 MQPR:$src1, MQPR:$src2)>;
4774  def : Pat<(mul (ARMvbicImm (v8i16 (ARMVectorRegCast (ARMvrev16 (v16i8 MQPR:$src1)))), (i32 0xAFF)),
4775                 (ARMvbicImm (v8i16 (ARMVectorRegCast (ARMvrev16 (v16i8 MQPR:$src2)))), (i32 0xAFF))),
4776            (MVE_VMULLTu8 MQPR:$src1, MQPR:$src2)>;
4777}
4778
4779class MVE_VxMULH<string iname, string suffix, bit U, bits<2> size, bit round,
4780                 list<dag> pattern=[]>
4781  : MVE_qDest_qSrc<iname, suffix, (outs MQPR:$Qd),
4782                   (ins MQPR:$Qn, MQPR:$Qm), "$Qd, $Qn, $Qm",
4783                   vpred_r, "", size, pattern> {
4784  bits<4> Qn;
4785
4786  let Inst{28} = U;
4787  let Inst{21-20} = size;
4788  let Inst{19-17} = Qn{2-0};
4789  let Inst{16} = 0b1;
4790  let Inst{12} = round;
4791  let Inst{8} = 0b0;
4792  let Inst{7} = Qn{3};
4793  let Inst{0} = 0b1;
4794  let validForTailPredication = 1;
4795}
4796
4797multiclass MVE_VxMULH_m<string iname, MVEVectorVTInfo VTI, SDNode unpred_op,
4798                        Intrinsic PredInt, bit round> {
4799  def "" : MVE_VxMULH<iname, VTI.Suffix, VTI.Unsigned, VTI.Size, round>;
4800  defvar Inst = !cast<Instruction>(NAME);
4801
4802  let Predicates = [HasMVEInt] in {
4803    if !eq(round, 0b0) then {
4804      defvar mulh = !if(VTI.Unsigned, mulhu, mulhs);
4805      defm : MVE_TwoOpPattern<VTI, mulh, PredInt, (? (i32 VTI.Unsigned)),
4806                              !cast<Instruction>(NAME)>;
4807    } else {
4808      // Predicated multiply returning high bits
4809      def : Pat<(VTI.Vec (PredInt (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
4810                              (i32 VTI.Unsigned), (VTI.Pred VCCR:$mask),
4811                              (VTI.Vec MQPR:$inactive))),
4812                (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
4813                              ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
4814                              (VTI.Vec MQPR:$inactive)))>;
4815    }
4816
4817    // Unpredicated intrinsic
4818    def : Pat<(VTI.Vec (unpred_op (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
4819                            (i32 VTI.Unsigned))),
4820              (VTI.Vec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn)))>;
4821  }
4822}
4823
4824multiclass MVE_VMULT<string iname, MVEVectorVTInfo VTI, bit round>
4825  : MVE_VxMULH_m<iname, VTI, !if(round, int_arm_mve_vrmulh, int_arm_mve_vmulh),
4826                 !if(round, int_arm_mve_rmulh_predicated,
4827                            int_arm_mve_mulh_predicated),
4828                 round>;
4829
4830defm MVE_VMULHs8   : MVE_VMULT<"vmulh",  MVE_v16s8, 0b0>;
4831defm MVE_VMULHs16  : MVE_VMULT<"vmulh",  MVE_v8s16, 0b0>;
4832defm MVE_VMULHs32  : MVE_VMULT<"vmulh",  MVE_v4s32, 0b0>;
4833defm MVE_VMULHu8   : MVE_VMULT<"vmulh",  MVE_v16u8, 0b0>;
4834defm MVE_VMULHu16  : MVE_VMULT<"vmulh",  MVE_v8u16, 0b0>;
4835defm MVE_VMULHu32  : MVE_VMULT<"vmulh",  MVE_v4u32, 0b0>;
4836
4837defm MVE_VRMULHs8  : MVE_VMULT<"vrmulh", MVE_v16s8, 0b1>;
4838defm MVE_VRMULHs16 : MVE_VMULT<"vrmulh", MVE_v8s16, 0b1>;
4839defm MVE_VRMULHs32 : MVE_VMULT<"vrmulh", MVE_v4s32, 0b1>;
4840defm MVE_VRMULHu8  : MVE_VMULT<"vrmulh", MVE_v16u8, 0b1>;
4841defm MVE_VRMULHu16 : MVE_VMULT<"vrmulh", MVE_v8u16, 0b1>;
4842defm MVE_VRMULHu32 : MVE_VMULT<"vrmulh", MVE_v4u32, 0b1>;
4843
4844class MVE_VxMOVxN<string iname, string suffix, bit bit_28, bit bit_17,
4845                  bits<2> size, bit T, list<dag> pattern=[]>
4846  : MVE_qDest_qSrc<iname, suffix, (outs MQPR:$Qd),
4847                   (ins MQPR:$Qd_src, MQPR:$Qm), "$Qd, $Qm",
4848                   vpred_n, "$Qd = $Qd_src", !if(size, 0b10, 0b01), pattern> {
4849
4850  let Inst{28} = bit_28;
4851  let Inst{21-20} = 0b11;
4852  let Inst{19-18} = size;
4853  let Inst{17} = bit_17;
4854  let Inst{16} = 0b1;
4855  let Inst{12} = T;
4856  let Inst{8} = 0b0;
4857  let Inst{7} = !not(bit_17);
4858  let Inst{0} = 0b1;
4859  let validForTailPredication = 1;
4860  let retainsPreviousHalfElement = 1;
4861}
4862
4863multiclass MVE_VxMOVxN_halves<string iname, string suffix,
4864                              bit bit_28, bit bit_17, bits<2> size> {
4865  def bh : MVE_VxMOVxN<iname # "b", suffix, bit_28, bit_17, size, 0b0>;
4866  def th : MVE_VxMOVxN<iname # "t", suffix, bit_28, bit_17, size, 0b1>;
4867}
4868
4869defm MVE_VMOVNi16   : MVE_VxMOVxN_halves<"vmovn",   "i16", 0b1, 0b0, 0b00>;
4870defm MVE_VMOVNi32   : MVE_VxMOVxN_halves<"vmovn",   "i32", 0b1, 0b0, 0b01>;
4871defm MVE_VQMOVNs16  : MVE_VxMOVxN_halves<"vqmovn",  "s16", 0b0, 0b1, 0b00>;
4872defm MVE_VQMOVNs32  : MVE_VxMOVxN_halves<"vqmovn",  "s32", 0b0, 0b1, 0b01>;
4873defm MVE_VQMOVNu16  : MVE_VxMOVxN_halves<"vqmovn",  "u16", 0b1, 0b1, 0b00>;
4874defm MVE_VQMOVNu32  : MVE_VxMOVxN_halves<"vqmovn",  "u32", 0b1, 0b1, 0b01>;
4875defm MVE_VQMOVUNs16 : MVE_VxMOVxN_halves<"vqmovun", "s16", 0b0, 0b0, 0b00>;
4876defm MVE_VQMOVUNs32 : MVE_VxMOVxN_halves<"vqmovun", "s32", 0b0, 0b0, 0b01>;
4877
4878def MVEvmovn       : SDNode<"ARMISD::VMOVN", SDTARMVEXT>;
4879
4880multiclass MVE_VMOVN_p<Instruction Inst, bit top,
4881                       MVEVectorVTInfo VTI, MVEVectorVTInfo InVTI> {
4882  // Match the most obvious MVEvmovn(a,b,t), which overwrites the odd or even
4883  // lanes of a (depending on t) with the even lanes of b.
4884  def : Pat<(VTI.Vec (MVEvmovn (VTI.Vec MQPR:$Qd_src),
4885                               (VTI.Vec MQPR:$Qm), (i32 top))),
4886            (VTI.Vec (Inst (VTI.Vec MQPR:$Qd_src), (VTI.Vec MQPR:$Qm)))>;
4887
4888  if !not(top) then {
4889    // If we see MVEvmovn(a,ARMvrev(b),1), that wants to overwrite the odd
4890    // lanes of a with the odd lanes of b. In other words, the lanes we're
4891    // _keeping_ from a are the even ones. So we can flip it round and say that
4892    // this is the same as overwriting the even lanes of b with the even lanes
4893    // of a, i.e. it's a VMOVNB with the operands reversed.
4894    defvar vrev = !cast<SDNode>("ARMvrev" # InVTI.LaneBits);
4895    def : Pat<(VTI.Vec (MVEvmovn (VTI.Vec MQPR:$Qm),
4896                                 (VTI.Vec (vrev MQPR:$Qd_src)), (i32 1))),
4897              (VTI.Vec (Inst (VTI.Vec MQPR:$Qd_src), (VTI.Vec MQPR:$Qm)))>;
4898  }
4899
4900  // Match the IR intrinsic for a predicated VMOVN. This regards the Qm input
4901  // as having wider lanes that we're narrowing, instead of already-narrow
4902  // lanes that we're taking every other one of.
4903  def : Pat<(VTI.Vec (int_arm_mve_vmovn_predicated (VTI.Vec MQPR:$Qd_src),
4904                                  (InVTI.Vec MQPR:$Qm), (i32 top),
4905                                  (InVTI.Pred VCCR:$pred))),
4906            (VTI.Vec (Inst (VTI.Vec MQPR:$Qd_src),
4907                              (InVTI.Vec MQPR:$Qm),
4908                              ARMVCCThen, (InVTI.Pred VCCR:$pred), zero_reg))>;
4909}
4910
4911defm : MVE_VMOVN_p<MVE_VMOVNi32bh, 0, MVE_v8i16, MVE_v4i32>;
4912defm : MVE_VMOVN_p<MVE_VMOVNi32th, 1, MVE_v8i16, MVE_v4i32>;
4913defm : MVE_VMOVN_p<MVE_VMOVNi16bh, 0, MVE_v16i8, MVE_v8i16>;
4914defm : MVE_VMOVN_p<MVE_VMOVNi16th, 1, MVE_v16i8, MVE_v8i16>;
4915
4916multiclass MVE_VQMOVN_p<Instruction Inst, bit outU, bit inU, bit top,
4917                        MVEVectorVTInfo VTI, MVEVectorVTInfo InVTI> {
4918  def : Pat<(VTI.Vec (int_arm_mve_vqmovn (VTI.Vec MQPR:$Qd_src),
4919                                  (InVTI.Vec MQPR:$Qm),
4920                                  (i32 outU), (i32 inU), (i32 top))),
4921            (VTI.Vec (Inst (VTI.Vec MQPR:$Qd_src),
4922                              (InVTI.Vec MQPR:$Qm)))>;
4923
4924  def : Pat<(VTI.Vec (int_arm_mve_vqmovn_predicated (VTI.Vec MQPR:$Qd_src),
4925                                  (InVTI.Vec MQPR:$Qm),
4926                                  (i32 outU), (i32 inU), (i32 top),
4927                                  (InVTI.Pred VCCR:$pred))),
4928            (VTI.Vec (Inst (VTI.Vec MQPR:$Qd_src),
4929                              (InVTI.Vec MQPR:$Qm),
4930                              ARMVCCThen, (InVTI.Pred VCCR:$pred), zero_reg))>;
4931}
4932
4933defm : MVE_VQMOVN_p<MVE_VQMOVNs32bh,  0, 0, 0, MVE_v8i16, MVE_v4i32>;
4934defm : MVE_VQMOVN_p<MVE_VQMOVNs32th,  0, 0, 1, MVE_v8i16, MVE_v4i32>;
4935defm : MVE_VQMOVN_p<MVE_VQMOVNs16bh,  0, 0, 0, MVE_v16i8, MVE_v8i16>;
4936defm : MVE_VQMOVN_p<MVE_VQMOVNs16th,  0, 0, 1, MVE_v16i8, MVE_v8i16>;
4937defm : MVE_VQMOVN_p<MVE_VQMOVNu32bh,  1, 1, 0, MVE_v8i16, MVE_v4i32>;
4938defm : MVE_VQMOVN_p<MVE_VQMOVNu32th,  1, 1, 1, MVE_v8i16, MVE_v4i32>;
4939defm : MVE_VQMOVN_p<MVE_VQMOVNu16bh,  1, 1, 0, MVE_v16i8, MVE_v8i16>;
4940defm : MVE_VQMOVN_p<MVE_VQMOVNu16th,  1, 1, 1, MVE_v16i8, MVE_v8i16>;
4941defm : MVE_VQMOVN_p<MVE_VQMOVUNs32bh, 1, 0, 0, MVE_v8i16, MVE_v4i32>;
4942defm : MVE_VQMOVN_p<MVE_VQMOVUNs32th, 1, 0, 1, MVE_v8i16, MVE_v4i32>;
4943defm : MVE_VQMOVN_p<MVE_VQMOVUNs16bh, 1, 0, 0, MVE_v16i8, MVE_v8i16>;
4944defm : MVE_VQMOVN_p<MVE_VQMOVUNs16th, 1, 0, 1, MVE_v16i8, MVE_v8i16>;
4945
4946def SDTARMVMOVNQ : SDTypeProfile<1, 3, [SDTCisVec<0>, SDTCisSameAs<0, 1>,
4947                                        SDTCisVec<2>, SDTCisVT<3, i32>]>;
4948def MVEvqmovns   : SDNode<"ARMISD::VQMOVNs", SDTARMVMOVNQ>;
4949def MVEvqmovnu   : SDNode<"ARMISD::VQMOVNu", SDTARMVMOVNQ>;
4950
4951let Predicates = [HasMVEInt] in {
4952  def : Pat<(v8i16 (MVEvqmovns (v8i16 MQPR:$Qd_src), (v4i32 MQPR:$Qm), (i32 0))),
4953            (v8i16 (MVE_VQMOVNs32bh (v8i16 MQPR:$Qd_src), (v4i32 MQPR:$Qm)))>;
4954  def : Pat<(v8i16 (MVEvqmovns (v8i16 MQPR:$Qd_src), (v4i32 MQPR:$Qm), (i32 1))),
4955            (v8i16 (MVE_VQMOVNs32th (v8i16 MQPR:$Qd_src), (v4i32 MQPR:$Qm)))>;
4956  def : Pat<(v16i8 (MVEvqmovns (v16i8 MQPR:$Qd_src), (v8i16 MQPR:$Qm), (i32 0))),
4957            (v16i8 (MVE_VQMOVNs16bh (v16i8 MQPR:$Qd_src), (v8i16 MQPR:$Qm)))>;
4958  def : Pat<(v16i8 (MVEvqmovns (v16i8 MQPR:$Qd_src), (v8i16 MQPR:$Qm), (i32 1))),
4959            (v16i8 (MVE_VQMOVNs16th (v16i8 MQPR:$Qd_src), (v8i16 MQPR:$Qm)))>;
4960
4961  def : Pat<(v8i16 (MVEvqmovnu (v8i16 MQPR:$Qd_src), (v4i32 MQPR:$Qm), (i32 0))),
4962            (v8i16 (MVE_VQMOVNu32bh (v8i16 MQPR:$Qd_src), (v4i32 MQPR:$Qm)))>;
4963  def : Pat<(v8i16 (MVEvqmovnu (v8i16 MQPR:$Qd_src), (v4i32 MQPR:$Qm), (i32 1))),
4964            (v8i16 (MVE_VQMOVNu32th (v8i16 MQPR:$Qd_src), (v4i32 MQPR:$Qm)))>;
4965  def : Pat<(v16i8 (MVEvqmovnu (v16i8 MQPR:$Qd_src), (v8i16 MQPR:$Qm), (i32 0))),
4966            (v16i8 (MVE_VQMOVNu16bh (v16i8 MQPR:$Qd_src), (v8i16 MQPR:$Qm)))>;
4967  def : Pat<(v16i8 (MVEvqmovnu (v16i8 MQPR:$Qd_src), (v8i16 MQPR:$Qm), (i32 1))),
4968            (v16i8 (MVE_VQMOVNu16th (v16i8 MQPR:$Qd_src), (v8i16 MQPR:$Qm)))>;
4969
4970  def : Pat<(v8i16 (MVEvqmovns (v8i16 MQPR:$Qd_src), (v4i32 (ARMvshrsImm (v4i32 MQPR:$Qm), imm0_31:$imm)), (i32 0))),
4971            (v8i16 (MVE_VQSHRNbhs32 (v8i16 MQPR:$Qd_src), (v4i32 MQPR:$Qm), imm0_31:$imm))>;
4972  def : Pat<(v16i8 (MVEvqmovns (v16i8 MQPR:$Qd_src), (v8i16 (ARMvshrsImm (v8i16 MQPR:$Qm), imm0_15:$imm)), (i32 0))),
4973            (v16i8 (MVE_VQSHRNbhs16 (v16i8 MQPR:$Qd_src), (v8i16 MQPR:$Qm), imm0_15:$imm))>;
4974  def : Pat<(v8i16 (MVEvqmovns (v8i16 MQPR:$Qd_src), (v4i32 (ARMvshrsImm (v4i32 MQPR:$Qm), imm0_31:$imm)), (i32 1))),
4975            (v8i16 (MVE_VQSHRNths32 (v8i16 MQPR:$Qd_src), (v4i32 MQPR:$Qm), imm0_31:$imm))>;
4976  def : Pat<(v16i8 (MVEvqmovns (v16i8 MQPR:$Qd_src), (v8i16 (ARMvshrsImm (v8i16 MQPR:$Qm), imm0_15:$imm)), (i32 1))),
4977            (v16i8 (MVE_VQSHRNths16 (v16i8 MQPR:$Qd_src), (v8i16 MQPR:$Qm), imm0_15:$imm))>;
4978
4979  def : Pat<(v8i16 (MVEvqmovnu (v8i16 MQPR:$Qd_src), (v4i32 (ARMvshruImm (v4i32 MQPR:$Qm), imm0_31:$imm)), (i32 0))),
4980            (v8i16 (MVE_VQSHRNbhu32 (v8i16 MQPR:$Qd_src), (v4i32 MQPR:$Qm), imm0_31:$imm))>;
4981  def : Pat<(v16i8 (MVEvqmovnu (v16i8 MQPR:$Qd_src), (v8i16 (ARMvshruImm (v8i16 MQPR:$Qm), imm0_15:$imm)), (i32 0))),
4982            (v16i8 (MVE_VQSHRNbhu16 (v16i8 MQPR:$Qd_src), (v8i16 MQPR:$Qm), imm0_15:$imm))>;
4983  def : Pat<(v8i16 (MVEvqmovnu (v8i16 MQPR:$Qd_src), (v4i32 (ARMvshruImm (v4i32 MQPR:$Qm), imm0_31:$imm)), (i32 1))),
4984            (v8i16 (MVE_VQSHRNthu32 (v8i16 MQPR:$Qd_src), (v4i32 MQPR:$Qm), imm0_31:$imm))>;
4985  def : Pat<(v16i8 (MVEvqmovnu (v16i8 MQPR:$Qd_src), (v8i16 (ARMvshruImm (v8i16 MQPR:$Qm), imm0_15:$imm)), (i32 1))),
4986            (v16i8 (MVE_VQSHRNthu16 (v16i8 MQPR:$Qd_src), (v8i16 MQPR:$Qm), imm0_15:$imm))>;
4987}
4988
4989class MVE_VCVT_ff<string iname, string suffix, bit op, bit T,
4990                  dag iops_extra, vpred_ops vpred, string cstr>
4991  : MVE_qDest_qSrc<iname, suffix, (outs MQPR:$Qd),
4992                   !con(iops_extra, (ins MQPR:$Qm)), "$Qd, $Qm",
4993                   vpred, cstr, 0b10, []> {
4994  let Inst{28} = op;
4995  let Inst{21-16} = 0b111111;
4996  let Inst{12} = T;
4997  let Inst{8-7} = 0b00;
4998  let Inst{0} = 0b1;
4999
5000  let Predicates = [HasMVEFloat];
5001  let retainsPreviousHalfElement = 1;
5002}
5003
5004def SDTARMVCVTL    : SDTypeProfile<1, 2, [SDTCisVec<0>, SDTCisVec<1>,
5005                                         SDTCisVT<2, i32>]>;
5006def MVEvcvtn       : SDNode<"ARMISD::VCVTN", SDTARMVMOVNQ>;
5007def MVEvcvtl       : SDNode<"ARMISD::VCVTL", SDTARMVCVTL>;
5008
5009multiclass MVE_VCVT_f2h_m<string iname, int half> {
5010  def "": MVE_VCVT_ff<iname, "f16.f32", 0b0, half,
5011                      (ins MQPR:$Qd_src), vpred_n, "$Qd = $Qd_src">;
5012  defvar Inst = !cast<Instruction>(NAME);
5013
5014  let Predicates = [HasMVEFloat] in {
5015    def : Pat<(v8f16 (int_arm_mve_vcvt_narrow
5016                         (v8f16 MQPR:$Qd_src), (v4f32 MQPR:$Qm), (i32 half))),
5017              (v8f16 (Inst (v8f16 MQPR:$Qd_src), (v4f32 MQPR:$Qm)))>;
5018    def : Pat<(v8f16 (int_arm_mve_vcvt_narrow_predicated
5019                         (v8f16 MQPR:$Qd_src), (v4f32 MQPR:$Qm), (i32 half),
5020                         (v4i1 VCCR:$mask))),
5021              (v8f16 (Inst (v8f16 MQPR:$Qd_src), (v4f32 MQPR:$Qm),
5022                           ARMVCCThen, (v4i1 VCCR:$mask), zero_reg))>;
5023
5024    def : Pat<(v8f16 (MVEvcvtn (v8f16 MQPR:$Qd_src), (v4f32 MQPR:$Qm), (i32 half))),
5025              (v8f16 (Inst (v8f16 MQPR:$Qd_src), (v4f32 MQPR:$Qm)))>;
5026  }
5027}
5028
5029multiclass MVE_VCVT_h2f_m<string iname, int half> {
5030  def "": MVE_VCVT_ff<iname, "f32.f16", 0b1, half, (ins), vpred_r, "">;
5031  defvar Inst = !cast<Instruction>(NAME);
5032
5033  let Predicates = [HasMVEFloat] in {
5034    def : Pat<(v4f32 (int_arm_mve_vcvt_widen (v8f16 MQPR:$Qm), (i32 half))),
5035              (v4f32 (Inst (v8f16 MQPR:$Qm)))>;
5036    def : Pat<(v4f32 (int_arm_mve_vcvt_widen_predicated
5037                         (v4f32 MQPR:$inactive), (v8f16 MQPR:$Qm), (i32 half),
5038                         (v4i1 VCCR:$mask))),
5039              (v4f32 (Inst (v8f16 MQPR:$Qm), ARMVCCThen,
5040                           (v4i1 VCCR:$mask), zero_reg, (v4f32 MQPR:$inactive)))>;
5041
5042    def : Pat<(v4f32 (MVEvcvtl (v8f16 MQPR:$Qm), (i32 half))),
5043              (v4f32 (Inst (v8f16 MQPR:$Qm)))>;
5044  }
5045}
5046
5047defm MVE_VCVTf16f32bh : MVE_VCVT_f2h_m<"vcvtb", 0b0>;
5048defm MVE_VCVTf16f32th : MVE_VCVT_f2h_m<"vcvtt", 0b1>;
5049defm MVE_VCVTf32f16bh : MVE_VCVT_h2f_m<"vcvtb", 0b0>;
5050defm MVE_VCVTf32f16th : MVE_VCVT_h2f_m<"vcvtt", 0b1>;
5051
5052class MVE_VxCADD<string iname, string suffix, bits<2> size, bit halve,
5053                 string cstr="">
5054  : MVE_qDest_qSrc<iname, suffix, (outs MQPR:$Qd),
5055                   (ins MQPR:$Qn, MQPR:$Qm, complexrotateopodd:$rot),
5056                   "$Qd, $Qn, $Qm, $rot", vpred_r, cstr, size, []> {
5057  bits<4> Qn;
5058  bit rot;
5059
5060  let Inst{28} = halve;
5061  let Inst{21-20} = size;
5062  let Inst{19-17} = Qn{2-0};
5063  let Inst{16} = 0b0;
5064  let Inst{12} = rot;
5065  let Inst{8} = 0b1;
5066  let Inst{7} = Qn{3};
5067  let Inst{0} = 0b0;
5068}
5069
5070multiclass MVE_VxCADD_m<string iname, MVEVectorVTInfo VTI,
5071                        bit halve, string cstr=""> {
5072  def "" : MVE_VxCADD<iname, VTI.Suffix, VTI.Size, halve, cstr>;
5073  defvar Inst = !cast<Instruction>(NAME);
5074
5075  let Predicates = [HasMVEInt] in {
5076    def : Pat<(VTI.Vec (int_arm_mve_vcaddq halve,
5077                            imm:$rot, (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm))),
5078              (VTI.Vec (Inst (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
5079                             imm:$rot))>;
5080
5081    def : Pat<(VTI.Vec (int_arm_mve_vcaddq_predicated halve,
5082                            imm:$rot, (VTI.Vec MQPR:$inactive),
5083                            (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
5084                            (VTI.Pred VCCR:$mask))),
5085              (VTI.Vec (Inst (VTI.Vec MQPR:$Qn), (VTI.Vec MQPR:$Qm),
5086                             imm:$rot, ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
5087                             (VTI.Vec MQPR:$inactive)))>;
5088
5089  }
5090}
5091
5092defm MVE_VCADDi8   : MVE_VxCADD_m<"vcadd", MVE_v16i8, 0b1>;
5093defm MVE_VCADDi16  : MVE_VxCADD_m<"vcadd", MVE_v8i16, 0b1>;
5094defm MVE_VCADDi32  : MVE_VxCADD_m<"vcadd", MVE_v4i32, 0b1, "@earlyclobber $Qd">;
5095
5096defm MVE_VHCADDs8  : MVE_VxCADD_m<"vhcadd", MVE_v16s8, 0b0>;
5097defm MVE_VHCADDs16 : MVE_VxCADD_m<"vhcadd", MVE_v8s16, 0b0>;
5098defm MVE_VHCADDs32 : MVE_VxCADD_m<"vhcadd", MVE_v4s32, 0b0, "@earlyclobber $Qd">;
5099
5100class MVE_VADCSBC<string iname, bit I, bit subtract,
5101                  dag carryin, list<dag> pattern=[]>
5102  : MVE_qDest_qSrc<iname, "i32", (outs MQPR:$Qd, cl_FPSCR_NZCV:$carryout),
5103                   !con((ins MQPR:$Qn, MQPR:$Qm), carryin),
5104                   "$Qd, $Qn, $Qm", vpred_r, "", 0b10, pattern> {
5105  bits<4> Qn;
5106
5107  let Inst{28} = subtract;
5108  let Inst{21-20} = 0b11;
5109  let Inst{19-17} = Qn{2-0};
5110  let Inst{16} = 0b0;
5111  let Inst{12} = I;
5112  let Inst{8} = 0b1;
5113  let Inst{7} = Qn{3};
5114  let Inst{0} = 0b0;
5115
5116  // Custom decoder method in order to add the FPSCR operand(s), which
5117  // Tablegen won't do right
5118  let DecoderMethod = "DecodeMVEVADCInstruction";
5119}
5120
5121def MVE_VADC  : MVE_VADCSBC<"vadc",  0b0, 0b0, (ins cl_FPSCR_NZCV:$carryin)>;
5122def MVE_VADCI : MVE_VADCSBC<"vadci", 0b1, 0b0, (ins)>;
5123
5124def MVE_VSBC  : MVE_VADCSBC<"vsbc",  0b0, 0b1, (ins cl_FPSCR_NZCV:$carryin)>;
5125def MVE_VSBCI : MVE_VADCSBC<"vsbci", 0b1, 0b1, (ins)>;
5126
5127class MVE_VQDMULL<string iname, string suffix, bit size, bit T,
5128                  string cstr="", list<dag> pattern=[]>
5129  : MVE_qDest_qSrc<iname, suffix, (outs MQPR:$Qd),
5130                   (ins MQPR:$Qn, MQPR:$Qm), "$Qd, $Qn, $Qm",
5131                   vpred_r, cstr, !if(size, 0b10, 0b01), pattern> {
5132  bits<4> Qn;
5133
5134  let Inst{28} = size;
5135  let Inst{21-20} = 0b11;
5136  let Inst{19-17} = Qn{2-0};
5137  let Inst{16} = 0b0;
5138  let Inst{12} = T;
5139  let Inst{8} = 0b1;
5140  let Inst{7} = Qn{3};
5141  let Inst{0} = 0b1;
5142  let validForTailPredication = 1;
5143  let doubleWidthResult = 1;
5144}
5145
5146multiclass MVE_VQDMULL_m<string iname, MVEVectorVTInfo VTI, bit size, bit T,
5147                         string cstr> {
5148  def "" : MVE_VQDMULL<iname, VTI.Suffix, size, T, cstr>;
5149  defvar Inst = !cast<Instruction>(NAME);
5150
5151  let Predicates = [HasMVEInt] in {
5152    // Unpredicated saturating multiply
5153    def : Pat<(VTI.DblVec (int_arm_mve_vqdmull (VTI.Vec MQPR:$Qm),
5154                                               (VTI.Vec MQPR:$Qn), (i32 T))),
5155              (VTI.DblVec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn)))>;
5156    // Predicated saturating multiply
5157    def : Pat<(VTI.DblVec (int_arm_mve_vqdmull_predicated
5158                                    (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
5159                                    (i32 T), (VTI.DblPred VCCR:$mask),
5160                                    (VTI.DblVec MQPR:$inactive))),
5161              (VTI.DblVec (Inst (VTI.Vec MQPR:$Qm), (VTI.Vec MQPR:$Qn),
5162                                ARMVCCThen, (VTI.DblPred VCCR:$mask), zero_reg,
5163                                (VTI.DblVec MQPR:$inactive)))>;
5164  }
5165}
5166
5167multiclass MVE_VQDMULL_halves<MVEVectorVTInfo VTI, bit size, string cstr=""> {
5168  defm bh : MVE_VQDMULL_m<"vqdmullb", VTI, size, 0b0, cstr>;
5169  defm th : MVE_VQDMULL_m<"vqdmullt", VTI, size, 0b1, cstr>;
5170}
5171
5172defm MVE_VQDMULLs16 : MVE_VQDMULL_halves<MVE_v8s16, 0b0>;
5173defm MVE_VQDMULLs32 : MVE_VQDMULL_halves<MVE_v4s32, 0b1, "@earlyclobber $Qd">;
5174
5175// end of mve_qDest_qSrc
5176
5177// start of mve_qDest_rSrc
5178
5179class MVE_qr_base<dag oops, dag iops, string iname, string suffix, string ops,
5180                  vpred_ops vpred, string cstr, bits<2> vecsize, list<dag> pattern=[]>
5181   : MVE_p<oops, iops, NoItinerary, iname, suffix, ops, vpred, cstr, vecsize, pattern> {
5182  bits<4> Qd;
5183  bits<4> Qn;
5184  bits<4> Rm;
5185
5186  let Inst{25-23} = 0b100;
5187  let Inst{22} = Qd{3};
5188  let Inst{19-17} = Qn{2-0};
5189  let Inst{15-13} = Qd{2-0};
5190  let Inst{11-9} = 0b111;
5191  let Inst{7} = Qn{3};
5192  let Inst{6} = 0b1;
5193  let Inst{4} = 0b0;
5194  let Inst{3-0} = Rm{3-0};
5195}
5196
5197class MVE_qDest_rSrc<string iname, string suffix, string cstr="", bits<2> vecsize, list<dag> pattern=[]>
5198  : MVE_qr_base<(outs MQPR:$Qd), (ins MQPR:$Qn, rGPR:$Rm),
5199                 iname, suffix, "$Qd, $Qn, $Rm", vpred_r, cstr,
5200                 vecsize, pattern>;
5201
5202class MVE_qDestSrc_rSrc<string iname, string suffix, bits<2> vecsize, list<dag> pattern=[]>
5203  : MVE_qr_base<(outs MQPR:$Qd), (ins MQPR:$Qd_src, MQPR:$Qn, rGPR:$Rm),
5204                 iname, suffix, "$Qd, $Qn, $Rm", vpred_n, "$Qd = $Qd_src",
5205                 vecsize, pattern>;
5206
5207class MVE_qDest_single_rSrc<string iname, string suffix, bits<2> vecsize, list<dag> pattern=[]>
5208  : MVE_p<(outs MQPR:$Qd), (ins MQPR:$Qd_src, rGPR:$Rm), NoItinerary, iname,
5209          suffix, "$Qd, $Rm", vpred_n, "$Qd = $Qd_src", vecsize, pattern> {
5210  bits<4> Qd;
5211  bits<4> Rm;
5212
5213  let Inst{22} = Qd{3};
5214  let Inst{15-13} = Qd{2-0};
5215  let Inst{3-0} = Rm{3-0};
5216}
5217
5218// Patterns for vector-scalar instructions with integer operands
5219multiclass MVE_vec_scalar_int_pat_m<Instruction inst, MVEVectorVTInfo VTI,
5220                                    SDPatternOperator unpred_op,
5221                                    SDPatternOperator pred_op,
5222                                    bit unpred_has_sign = 0,
5223                                    bit pred_has_sign = 0> {
5224  defvar UnpredSign = !if(unpred_has_sign, (? (i32 VTI.Unsigned)), (?));
5225  defvar PredSign = !if(pred_has_sign, (? (i32 VTI.Unsigned)), (?));
5226
5227  let Predicates = [HasMVEInt] in {
5228    // Unpredicated version
5229    def : Pat<(VTI.Vec !con((unpred_op (VTI.Vec MQPR:$Qm),
5230                                       (VTI.Vec (ARMvdup rGPR:$val))),
5231                            UnpredSign)),
5232              (VTI.Vec (inst (VTI.Vec MQPR:$Qm), (i32 rGPR:$val)))>;
5233    // Predicated version
5234    def : Pat<(VTI.Vec !con((pred_op (VTI.Vec MQPR:$Qm),
5235                                     (VTI.Vec (ARMvdup rGPR:$val))),
5236                            PredSign,
5237                            (pred_op (VTI.Pred VCCR:$mask),
5238                                     (VTI.Vec MQPR:$inactive)))),
5239              (VTI.Vec (inst (VTI.Vec MQPR:$Qm), (i32 rGPR:$val),
5240                             ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
5241                             (VTI.Vec MQPR:$inactive)))>;
5242  }
5243}
5244
5245class MVE_VADDSUB_qr<string iname, string suffix, bits<2> size,
5246                     bit bit_5, bit bit_12, bit bit_16, bit bit_28>
5247  : MVE_qDest_rSrc<iname, suffix, "", size> {
5248
5249  let Inst{28} = bit_28;
5250  let Inst{21-20} = size;
5251  let Inst{16} = bit_16;
5252  let Inst{12} = bit_12;
5253  let Inst{8} = 0b1;
5254  let Inst{5} = bit_5;
5255  let validForTailPredication = 1;
5256}
5257
5258// Vector-scalar add/sub
5259multiclass MVE_VADDSUB_qr_m<string iname, MVEVectorVTInfo VTI, bit subtract,
5260                            SDNode Op, Intrinsic PredInt> {
5261  def "" : MVE_VADDSUB_qr<iname, VTI.Suffix, VTI.Size, 0b0, subtract, 0b1, 0b0>;
5262  let Predicates = [HasMVEInt] in {
5263    defm : MVE_TwoOpPatternDup<VTI, Op, PredInt, (? ), !cast<Instruction>(NAME), ARMimmAllZerosV>;
5264  }
5265}
5266
5267multiclass MVE_VADD_qr_m<MVEVectorVTInfo VTI>
5268  : MVE_VADDSUB_qr_m<"vadd", VTI, 0b0, add, int_arm_mve_add_predicated>;
5269
5270multiclass MVE_VSUB_qr_m<MVEVectorVTInfo VTI>
5271  : MVE_VADDSUB_qr_m<"vsub", VTI, 0b1, sub, int_arm_mve_sub_predicated>;
5272
5273defm MVE_VADD_qr_i8  : MVE_VADD_qr_m<MVE_v16i8>;
5274defm MVE_VADD_qr_i16 : MVE_VADD_qr_m<MVE_v8i16>;
5275defm MVE_VADD_qr_i32 : MVE_VADD_qr_m<MVE_v4i32>;
5276
5277defm MVE_VSUB_qr_i8  : MVE_VSUB_qr_m<MVE_v16i8>;
5278defm MVE_VSUB_qr_i16 : MVE_VSUB_qr_m<MVE_v8i16>;
5279defm MVE_VSUB_qr_i32 : MVE_VSUB_qr_m<MVE_v4i32>;
5280
5281// Vector-scalar saturating add/sub
5282multiclass MVE_VQADDSUB_qr_m<string iname, MVEVectorVTInfo VTI, bit subtract,
5283                             SDNode Op, Intrinsic PredInt> {
5284  def "" : MVE_VADDSUB_qr<iname, VTI.Suffix, VTI.Size, 0b1, subtract,
5285                          0b0, VTI.Unsigned>;
5286
5287  let Predicates = [HasMVEInt] in {
5288    defm : MVE_TwoOpPatternDup<VTI, Op, PredInt, (? (i32 VTI.Unsigned)),
5289                               !cast<Instruction>(NAME)>;
5290  }
5291}
5292
5293multiclass MVE_VQADD_qr_m<MVEVectorVTInfo VTI, SDNode Op>
5294  : MVE_VQADDSUB_qr_m<"vqadd", VTI, 0b0, Op, int_arm_mve_qadd_predicated>;
5295
5296multiclass MVE_VQSUB_qr_m<MVEVectorVTInfo VTI, SDNode Op>
5297  : MVE_VQADDSUB_qr_m<"vqsub", VTI, 0b1, Op, int_arm_mve_qsub_predicated>;
5298
5299defm MVE_VQADD_qr_s8  : MVE_VQADD_qr_m<MVE_v16s8, saddsat>;
5300defm MVE_VQADD_qr_s16 : MVE_VQADD_qr_m<MVE_v8s16, saddsat>;
5301defm MVE_VQADD_qr_s32 : MVE_VQADD_qr_m<MVE_v4s32, saddsat>;
5302defm MVE_VQADD_qr_u8  : MVE_VQADD_qr_m<MVE_v16u8, uaddsat>;
5303defm MVE_VQADD_qr_u16 : MVE_VQADD_qr_m<MVE_v8u16, uaddsat>;
5304defm MVE_VQADD_qr_u32 : MVE_VQADD_qr_m<MVE_v4u32, uaddsat>;
5305
5306defm MVE_VQSUB_qr_s8  : MVE_VQSUB_qr_m<MVE_v16s8, ssubsat>;
5307defm MVE_VQSUB_qr_s16 : MVE_VQSUB_qr_m<MVE_v8s16, ssubsat>;
5308defm MVE_VQSUB_qr_s32 : MVE_VQSUB_qr_m<MVE_v4s32, ssubsat>;
5309defm MVE_VQSUB_qr_u8  : MVE_VQSUB_qr_m<MVE_v16u8, usubsat>;
5310defm MVE_VQSUB_qr_u16 : MVE_VQSUB_qr_m<MVE_v8u16, usubsat>;
5311defm MVE_VQSUB_qr_u32 : MVE_VQSUB_qr_m<MVE_v4u32, usubsat>;
5312
5313class MVE_VQDMULL_qr<string iname, string suffix, bit size,
5314                     bit T, string cstr="", list<dag> pattern=[]>
5315  : MVE_qDest_rSrc<iname, suffix, cstr, !if(size, 0b10, 0b01), pattern> {
5316
5317  let Inst{28} = size;
5318  let Inst{21-20} = 0b11;
5319  let Inst{16} = 0b0;
5320  let Inst{12} = T;
5321  let Inst{8} = 0b1;
5322  let Inst{5} = 0b1;
5323  let validForTailPredication = 1;
5324  let doubleWidthResult = 1;
5325}
5326
5327multiclass MVE_VQDMULL_qr_m<string iname, MVEVectorVTInfo VTI, bit size,
5328                            bit T, string cstr> {
5329  def "" : MVE_VQDMULL_qr<iname, VTI.Suffix, size, T, cstr>;
5330  defvar Inst = !cast<Instruction>(NAME);
5331
5332  let Predicates = [HasMVEInt] in {
5333    // Unpredicated saturating multiply
5334    def : Pat<(VTI.DblVec (int_arm_mve_vqdmull (VTI.Vec MQPR:$Qm),
5335                                               (VTI.Vec (ARMvdup rGPR:$val)),
5336                                               (i32 T))),
5337              (VTI.DblVec (Inst (VTI.Vec MQPR:$Qm), (i32 rGPR:$val)))>;
5338    // Predicated saturating multiply
5339    def : Pat<(VTI.DblVec (int_arm_mve_vqdmull_predicated
5340                                    (VTI.Vec MQPR:$Qm),
5341                                    (VTI.Vec (ARMvdup rGPR:$val)),
5342                                    (i32 T),
5343                                    (VTI.DblPred VCCR:$mask),
5344                                    (VTI.DblVec MQPR:$inactive))),
5345              (VTI.DblVec (Inst (VTI.Vec MQPR:$Qm), (i32 rGPR:$val),
5346                             ARMVCCThen, (VTI.DblPred VCCR:$mask), zero_reg,
5347                             (VTI.DblVec MQPR:$inactive)))>;
5348  }
5349}
5350
5351multiclass MVE_VQDMULL_qr_halves<MVEVectorVTInfo VTI, bit size, string cstr=""> {
5352  defm bh : MVE_VQDMULL_qr_m<"vqdmullb", VTI, size, 0b0, cstr>;
5353  defm th : MVE_VQDMULL_qr_m<"vqdmullt", VTI, size, 0b1, cstr>;
5354}
5355
5356defm MVE_VQDMULL_qr_s16 : MVE_VQDMULL_qr_halves<MVE_v8s16, 0b0>;
5357defm MVE_VQDMULL_qr_s32 : MVE_VQDMULL_qr_halves<MVE_v4s32, 0b1, "@earlyclobber $Qd">;
5358
5359class MVE_VxADDSUB_qr<string iname, string suffix,
5360                      bit bit_28, bits<2> size, bit subtract,
5361                      bits<2> vecsize, list<dag> pattern=[]>
5362  : MVE_qDest_rSrc<iname, suffix, "", vecsize, pattern> {
5363
5364  let Inst{28} = bit_28;
5365  let Inst{21-20} = size;
5366  let Inst{16} = 0b0;
5367  let Inst{12} = subtract;
5368  let Inst{8} = 0b1;
5369  let Inst{5} = 0b0;
5370  let validForTailPredication = 1;
5371}
5372
5373multiclass MVE_VHADDSUB_qr_m<string iname, MVEVectorVTInfo VTI, bit subtract, SDNode Op,
5374                             Intrinsic unpred_int, Intrinsic pred_int, PatFrag add_op, PatFrag shift_op> {
5375  def "" : MVE_VxADDSUB_qr<iname, VTI.Suffix, VTI.Unsigned, VTI.Size, subtract, VTI.Size>;
5376  defm : MVE_TwoOpPatternDup<VTI, Op, pred_int, (? (i32 VTI.Unsigned)), !cast<Instruction>(NAME)>;
5377  defm : MVE_vec_scalar_int_pat_m<!cast<Instruction>(NAME),
5378                                  VTI, unpred_int, pred_int, 1, 1>;
5379  defvar Inst = !cast<Instruction>(NAME);
5380
5381  let Predicates = [HasMVEInt] in {
5382    def : Pat<(VTI.Vec (shift_op (add_op (VTI.Vec MQPR:$Qm), (VTI.Vec (ARMvdup rGPR:$Rn))), (i32 1))),
5383              (Inst MQPR:$Qm, rGPR:$Rn)>;
5384  }
5385}
5386
5387multiclass MVE_VHADD_qr_m<MVEVectorVTInfo VTI, PatFrag add_op, SDNode shift_op, SDNode Op> :
5388  MVE_VHADDSUB_qr_m<"vhadd", VTI, 0b0, Op, int_arm_mve_vhadd,
5389                    int_arm_mve_hadd_predicated, add_op, shift_op>;
5390
5391multiclass MVE_VHSUB_qr_m<MVEVectorVTInfo VTI, PatFrag add_op, SDNode shift_op> :
5392  MVE_VHADDSUB_qr_m<"vhsub", VTI, 0b1, null_frag, int_arm_mve_vhsub,
5393                    int_arm_mve_hsub_predicated, add_op, shift_op>;
5394
5395defm MVE_VHADD_qr_s8  : MVE_VHADD_qr_m<MVE_v16s8, addnsw, ARMvshrsImm, avgfloors>;
5396defm MVE_VHADD_qr_s16 : MVE_VHADD_qr_m<MVE_v8s16, addnsw, ARMvshrsImm, avgfloors>;
5397defm MVE_VHADD_qr_s32 : MVE_VHADD_qr_m<MVE_v4s32, addnsw, ARMvshrsImm, avgfloors>;
5398defm MVE_VHADD_qr_u8  : MVE_VHADD_qr_m<MVE_v16u8, addnuw, ARMvshruImm, avgflooru>;
5399defm MVE_VHADD_qr_u16 : MVE_VHADD_qr_m<MVE_v8u16, addnuw, ARMvshruImm, avgflooru>;
5400defm MVE_VHADD_qr_u32 : MVE_VHADD_qr_m<MVE_v4u32, addnuw, ARMvshruImm, avgflooru>;
5401
5402defm MVE_VHSUB_qr_s8  : MVE_VHSUB_qr_m<MVE_v16s8, subnsw, ARMvshrsImm>;
5403defm MVE_VHSUB_qr_s16 : MVE_VHSUB_qr_m<MVE_v8s16, subnsw, ARMvshrsImm>;
5404defm MVE_VHSUB_qr_s32 : MVE_VHSUB_qr_m<MVE_v4s32, subnsw, ARMvshrsImm>;
5405defm MVE_VHSUB_qr_u8  : MVE_VHSUB_qr_m<MVE_v16u8, subnuw, ARMvshruImm>;
5406defm MVE_VHSUB_qr_u16 : MVE_VHSUB_qr_m<MVE_v8u16, subnuw, ARMvshruImm>;
5407defm MVE_VHSUB_qr_u32 : MVE_VHSUB_qr_m<MVE_v4u32, subnuw, ARMvshruImm>;
5408
5409multiclass MVE_VADDSUB_qr_f<string iname, MVEVectorVTInfo VTI, bit subtract,
5410                            SDNode Op, Intrinsic PredInt, SDPatternOperator IdentityVec> {
5411  def "" : MVE_VxADDSUB_qr<iname, VTI.Suffix, VTI.Size{0}, 0b11, subtract, VTI.Size>;
5412  defm : MVE_TwoOpPatternDup<VTI, Op, PredInt, (? ),
5413                              !cast<Instruction>(NAME), IdentityVec>;
5414}
5415
5416let Predicates = [HasMVEFloat] in {
5417  defm MVE_VADD_qr_f32 : MVE_VADDSUB_qr_f<"vadd", MVE_v4f32, 0b0, fadd,
5418                                          int_arm_mve_add_predicated, ARMimmMinusZeroF>;
5419  defm MVE_VADD_qr_f16 : MVE_VADDSUB_qr_f<"vadd", MVE_v8f16, 0b0, fadd,
5420                                          int_arm_mve_add_predicated, ARMimmMinusZeroH>;
5421
5422  defm MVE_VSUB_qr_f32 : MVE_VADDSUB_qr_f<"vsub", MVE_v4f32, 0b1, fsub,
5423                                          int_arm_mve_sub_predicated, ARMimmAllZerosV>;
5424  defm MVE_VSUB_qr_f16 : MVE_VADDSUB_qr_f<"vsub", MVE_v8f16, 0b1, fsub,
5425                                          int_arm_mve_sub_predicated, ARMimmAllZerosV>;
5426}
5427
5428class MVE_VxSHL_qr<string iname, string suffix, bit U, bits<2> size,
5429                   bit bit_7, bit bit_17, list<dag> pattern=[]>
5430  : MVE_qDest_single_rSrc<iname, suffix, size, pattern> {
5431
5432  let Inst{28} = U;
5433  let Inst{25-23} = 0b100;
5434  let Inst{21-20} = 0b11;
5435  let Inst{19-18} = size;
5436  let Inst{17} = bit_17;
5437  let Inst{16} = 0b1;
5438  let Inst{12-8} = 0b11110;
5439  let Inst{7} = bit_7;
5440  let Inst{6-4} = 0b110;
5441  let validForTailPredication = 1;
5442}
5443
5444multiclass MVE_VxSHL_qr_p<string iname, MVEVectorVTInfo VTI, bit q, bit r> {
5445  def "" : MVE_VxSHL_qr<iname, VTI.Suffix, VTI.Unsigned, VTI.Size, q, r>;
5446  defvar Inst = !cast<Instruction>(NAME);
5447
5448  def : Pat<(VTI.Vec (int_arm_mve_vshl_scalar
5449                         (VTI.Vec MQPR:$in), (i32 rGPR:$sh),
5450                         (i32 q), (i32 r), (i32 VTI.Unsigned))),
5451            (VTI.Vec (Inst (VTI.Vec MQPR:$in), (i32 rGPR:$sh)))>;
5452
5453  def : Pat<(VTI.Vec (int_arm_mve_vshl_scalar_predicated
5454                         (VTI.Vec MQPR:$in), (i32 rGPR:$sh),
5455                         (i32 q), (i32 r), (i32 VTI.Unsigned),
5456                         (VTI.Pred VCCR:$mask))),
5457            (VTI.Vec (Inst (VTI.Vec MQPR:$in), (i32 rGPR:$sh),
5458                           ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg))>;
5459}
5460
5461multiclass MVE_VxSHL_qr_types<string iname, bit bit_7, bit bit_17> {
5462  defm s8  : MVE_VxSHL_qr_p<iname, MVE_v16s8, bit_7, bit_17>;
5463  defm s16 : MVE_VxSHL_qr_p<iname, MVE_v8s16, bit_7, bit_17>;
5464  defm s32 : MVE_VxSHL_qr_p<iname, MVE_v4s32, bit_7, bit_17>;
5465  defm u8  : MVE_VxSHL_qr_p<iname, MVE_v16u8, bit_7, bit_17>;
5466  defm u16 : MVE_VxSHL_qr_p<iname, MVE_v8u16, bit_7, bit_17>;
5467  defm u32 : MVE_VxSHL_qr_p<iname, MVE_v4u32, bit_7, bit_17>;
5468}
5469
5470defm MVE_VSHL_qr   : MVE_VxSHL_qr_types<"vshl",   0b0, 0b0>;
5471defm MVE_VRSHL_qr  : MVE_VxSHL_qr_types<"vrshl",  0b0, 0b1>;
5472defm MVE_VQSHL_qr  : MVE_VxSHL_qr_types<"vqshl",  0b1, 0b0>;
5473defm MVE_VQRSHL_qr : MVE_VxSHL_qr_types<"vqrshl", 0b1, 0b1>;
5474
5475let Predicates = [HasMVEInt] in {
5476  def : Pat<(v4i32 (ARMvshlu (v4i32 MQPR:$Qm), (v4i32 (ARMvdup rGPR:$Rm)))),
5477            (v4i32 (MVE_VSHL_qru32 (v4i32 MQPR:$Qm), rGPR:$Rm))>;
5478  def : Pat<(v8i16 (ARMvshlu (v8i16 MQPR:$Qm), (v8i16 (ARMvdup rGPR:$Rm)))),
5479            (v8i16 (MVE_VSHL_qru16 (v8i16 MQPR:$Qm), rGPR:$Rm))>;
5480  def : Pat<(v16i8 (ARMvshlu (v16i8 MQPR:$Qm), (v16i8 (ARMvdup rGPR:$Rm)))),
5481            (v16i8 (MVE_VSHL_qru8 (v16i8 MQPR:$Qm), rGPR:$Rm))>;
5482
5483  def : Pat<(v4i32 (ARMvshls (v4i32 MQPR:$Qm), (v4i32 (ARMvdup rGPR:$Rm)))),
5484            (v4i32 (MVE_VSHL_qrs32 (v4i32 MQPR:$Qm), rGPR:$Rm))>;
5485  def : Pat<(v8i16 (ARMvshls (v8i16 MQPR:$Qm), (v8i16 (ARMvdup rGPR:$Rm)))),
5486            (v8i16 (MVE_VSHL_qrs16 (v8i16 MQPR:$Qm), rGPR:$Rm))>;
5487  def : Pat<(v16i8 (ARMvshls (v16i8 MQPR:$Qm), (v16i8 (ARMvdup rGPR:$Rm)))),
5488            (v16i8 (MVE_VSHL_qrs8 (v16i8 MQPR:$Qm), rGPR:$Rm))>;
5489}
5490
5491class MVE_VBRSR<string iname, string suffix, bits<2> size, list<dag> pattern=[]>
5492  : MVE_qDest_rSrc<iname, suffix, "", size, pattern> {
5493
5494  let Inst{28} = 0b1;
5495  let Inst{21-20} = size;
5496  let Inst{16} = 0b1;
5497  let Inst{12} = 0b1;
5498  let Inst{8} = 0b0;
5499  let Inst{5} = 0b1;
5500  let validForTailPredication = 1;
5501}
5502
5503def MVE_VBRSR8  : MVE_VBRSR<"vbrsr", "8", 0b00>;
5504def MVE_VBRSR16 : MVE_VBRSR<"vbrsr", "16", 0b01>;
5505def MVE_VBRSR32 : MVE_VBRSR<"vbrsr", "32", 0b10>;
5506
5507multiclass MVE_VBRSR_pat_m<MVEVectorVTInfo VTI, Instruction Inst> {
5508  // Unpredicated
5509  def : Pat<(VTI.Vec (int_arm_mve_vbrsr (VTI.Vec MQPR:$Qn), (i32 rGPR:$Rm))),
5510            (VTI.Vec (Inst (VTI.Vec MQPR:$Qn), (i32 rGPR:$Rm)))>;
5511  // Predicated
5512  def : Pat<(VTI.Vec (int_arm_mve_vbrsr_predicated
5513                          (VTI.Vec MQPR:$inactive),
5514                          (VTI.Vec MQPR:$Qn), (i32 rGPR:$Rm),
5515                          (VTI.Pred VCCR:$mask))),
5516            (VTI.Vec (Inst (VTI.Vec MQPR:$Qn), (i32 rGPR:$Rm),
5517                          ARMVCCThen, (VTI.Pred VCCR:$mask), zero_reg,
5518                          (VTI.Vec MQPR:$inactive)))>;
5519}
5520
5521let Predicates = [HasMVEInt] in {
5522  def : Pat<(v16i8 ( bitreverse (v16i8 MQPR:$val1))),
5523            (v16i8 ( MVE_VBRSR8 (v16i8 MQPR:$val1), (t2MOVi (i32 8)) ))>;
5524
5525  def : Pat<(v4i32 ( bitreverse (v4i32 MQPR:$val1))),
5526            (v4i32 ( MVE_VBRSR32 (v4i32 MQPR:$val1), (t2MOVi (i32 32)) ))>;
5527
5528  def : Pat<(v8i16 ( bitreverse (v8i16 MQPR:$val1))),
5529            (v8i16 ( MVE_VBRSR16 (v8i16 MQPR:$val1), (t2MOVi (i32 16)) ))>;
5530
5531  defm : MVE_VBRSR_pat_m<MVE_v16i8, MVE_VBRSR8>;
5532  defm : MVE_VBRSR_pat_m<MVE_v8i16, MVE_VBRSR16>;
5533  defm : MVE_VBRSR_pat_m<MVE_v4i32, MVE_VBRSR32>;
5534}
5535
5536let Predicates = [HasMVEFloat] in {
5537  defm : MVE_VBRSR_pat_m<MVE_v8f16, MVE_VBRSR16>;
5538  defm : MVE_VBRSR_pat_m<MVE_v4f32, MVE_VBRSR32>;
5539}
5540
5541class MVE_VMUL_qr_int<string iname, string suffix, bits<2> size>
5542  : MVE_qDest_rSrc<iname, suffix, "", size> {
5543
5544  let Inst{28} = 0b0;
5545  let Inst{21-20} = size;
5546  let Inst{16} = 0b1;
5547  let Inst{12} = 0b1;
5548  let Inst{8} = 0b0;
5549  let Inst{5} = 0b1;
5550  let validForTailPredication = 1;
5551}
5552
5553multiclass MVE_VMUL_qr_int_m<MVEVectorVTInfo VTI> {
5554  def "" : MVE_VMUL_qr_int<"vmul", VTI.Suffix, VTI.Size>;
5555  let Predicates = [HasMVEInt] in {
5556    defm : MVE_TwoOpPatternDup<VTI, mul, int_arm_mve_mul_predicated, (? ),
5557                               !cast<Instruction>(NAME), ARMimmOneV>;
5558  }
5559}
5560
5561defm MVE_VMUL_qr_i8  : MVE_VMUL_qr_int_m<MVE_v16i8>;
5562defm MVE_VMUL_qr_i16 : MVE_VMUL_qr_int_m<MVE_v8i16>;
5563defm MVE_VMUL_qr_i32 : MVE_VMUL_qr_int_m<MVE_v4i32>;
5564
5565class MVE_VxxMUL_qr<string iname, string suffix,
5566                    bit bit_28, bits<2> size, bits<2> vecsize, list<dag> pattern=[]>
5567  : MVE_qDest_rSrc<iname, suffix, "", vecsize, pattern> {
5568
5569  let Inst{28} = bit_28;
5570  let Inst{21-20} = size;
5571  let Inst{16} = 0b1;
5572  let Inst{12} = 0b0;
5573  let Inst{8} = 0b0;
5574  let Inst{5} = 0b1;
5575  let validForTailPredication = 1;
5576}
5577
5578multiclass MVE_VxxMUL_qr_m<string iname, MVEVectorVTInfo VTI, bit bit_28,
5579                           PatFrag Op, Intrinsic int_unpred, Intrinsic int_pred> {
5580  def "" : MVE_VxxMUL_qr<iname, VTI.Suffix, bit_28, VTI.Size, VTI.Size>;
5581
5582  let Predicates = [HasMVEInt] in {
5583    defm : MVE_TwoOpPatternDup<VTI, Op, int_pred, (? ), !cast<Instruction>(NAME)>;
5584  }
5585  defm : MVE_vec_scalar_int_pat_m<!cast<Instruction>(NAME), VTI, int_unpred, int_pred>;
5586}
5587
5588multiclass MVE_VQDMULH_qr_m<MVEVectorVTInfo VTI> :
5589  MVE_VxxMUL_qr_m<"vqdmulh", VTI, 0b0, MVEvqdmulh,
5590                  int_arm_mve_vqdmulh, int_arm_mve_qdmulh_predicated>;
5591
5592multiclass MVE_VQRDMULH_qr_m<MVEVectorVTInfo VTI> :
5593  MVE_VxxMUL_qr_m<"vqrdmulh", VTI, 0b1, null_frag,
5594                  int_arm_mve_vqrdmulh, int_arm_mve_qrdmulh_predicated>;
5595
5596defm MVE_VQDMULH_qr_s8    : MVE_VQDMULH_qr_m<MVE_v16s8>;
5597defm MVE_VQDMULH_qr_s16   : MVE_VQDMULH_qr_m<MVE_v8s16>;
5598defm MVE_VQDMULH_qr_s32   : MVE_VQDMULH_qr_m<MVE_v4s32>;
5599
5600defm MVE_VQRDMULH_qr_s8   : MVE_VQRDMULH_qr_m<MVE_v16s8>;
5601defm MVE_VQRDMULH_qr_s16  : MVE_VQRDMULH_qr_m<MVE_v8s16>;
5602defm MVE_VQRDMULH_qr_s32  : MVE_VQRDMULH_qr_m<MVE_v4s32>;
5603
5604multiclass MVE_VxxMUL_qr_f_m<MVEVectorVTInfo VTI, SDPatternOperator IdentityVec> {
5605  let validForTailPredication = 1 in
5606  def "" : MVE_VxxMUL_qr<"vmul", VTI.Suffix, VTI.Size{0}, 0b11, VTI.Size>;
5607  defm : MVE_TwoOpPatternDup<VTI, fmul, int_arm_mve_mul_predicated, (? ),
5608                             !cast<Instruction>(NAME), IdentityVec>;
5609}
5610
5611let Predicates = [HasMVEFloat] in {
5612  defm MVE_VMUL_qr_f16   : MVE_VxxMUL_qr_f_m<MVE_v8f16, ARMimmOneH>;
5613  defm MVE_VMUL_qr_f32   : MVE_VxxMUL_qr_f_m<MVE_v4f32, ARMimmOneF>;
5614}
5615
5616class MVE_VFMAMLA_qr<string iname, string suffix,
5617                     bit bit_28, bits<2> bits_21_20, bit S,
5618                     bits<2> vecsize, list<dag> pattern=[]>
5619  : MVE_qDestSrc_rSrc<iname, suffix, vecsize, pattern> {
5620
5621  let Inst{28} = bit_28;
5622  let Inst{21-20} = bits_21_20;
5623  let Inst{16} = 0b1;
5624  let Inst{12} = S;
5625  let Inst{8} = 0b0;
5626  let Inst{5} = 0b0;
5627  let validForTailPredication = 1;
5628  let hasSideEffects = 0;
5629}
5630
5631multiclass MVE_VMLA_qr_multi<string iname, MVEVectorVTInfo VTI,
5632                             bit scalar_addend> {
5633  def "": MVE_VFMAMLA_qr<iname, VTI.Suffix, 0b0, VTI.Size,
5634                         scalar_addend, VTI.Size>;
5635  defvar Inst = !cast<Instruction>(NAME);
5636  defvar pred_int = !cast<Intrinsic>("int_arm_mve_" # iname # "_n_predicated");
5637  defvar v1   = (VTI.Vec MQPR:$v1);
5638  defvar v2   = (VTI.Vec MQPR:$v2);
5639  defvar vs   = (VTI.Vec (ARMvdup rGPR:$s));
5640  defvar s    = (i32 rGPR:$s);
5641  defvar pred = (VTI.Pred VCCR:$pred);
5642
5643  let Predicates = [HasMVEInt] in {
5644    if scalar_addend then {
5645      def : Pat<(VTI.Vec (add (mul v1, v2), vs)),
5646                (VTI.Vec (Inst v1, v2, s))>;
5647    } else {
5648      def : Pat<(VTI.Vec (add (mul v2, vs), v1)),
5649                (VTI.Vec (Inst v1, v2, s))>;
5650    }
5651
5652    def : Pat<(VTI.Vec (pred_int v1, v2, s, pred)),
5653              (VTI.Vec (Inst v1, v2, s, ARMVCCThen, pred, zero_reg))>;
5654  }
5655}
5656
5657defm MVE_VMLA_qr_i8   : MVE_VMLA_qr_multi<"vmla", MVE_v16i8, 0b0>;
5658defm MVE_VMLA_qr_i16  : MVE_VMLA_qr_multi<"vmla", MVE_v8i16, 0b0>;
5659defm MVE_VMLA_qr_i32  : MVE_VMLA_qr_multi<"vmla", MVE_v4i32, 0b0>;
5660
5661defm MVE_VMLAS_qr_i8  : MVE_VMLA_qr_multi<"vmlas", MVE_v16i8, 0b1>;
5662defm MVE_VMLAS_qr_i16 : MVE_VMLA_qr_multi<"vmlas", MVE_v8i16, 0b1>;
5663defm MVE_VMLAS_qr_i32 : MVE_VMLA_qr_multi<"vmlas", MVE_v4i32, 0b1>;
5664
5665multiclass MVE_VFMA_qr_multi<string iname, MVEVectorVTInfo VTI,
5666                             bit scalar_addend> {
5667  def "": MVE_VFMAMLA_qr<iname, VTI.Suffix, VTI.Size{0}, 0b11, scalar_addend, VTI.Size>;
5668  defvar Inst = !cast<Instruction>(NAME);
5669  defvar pred_int = int_arm_mve_fma_predicated;
5670  defvar v1   = (VTI.Vec MQPR:$v1);
5671  defvar v2   = (VTI.Vec MQPR:$v2);
5672  defvar vs   = (VTI.Vec (ARMvdup (i32 rGPR:$s)));
5673  defvar is   = (i32 rGPR:$s);
5674  defvar pred = (VTI.Pred VCCR:$pred);
5675
5676  let Predicates = [HasMVEFloat] in {
5677    if scalar_addend then {
5678      def : Pat<(VTI.Vec (fma v1, v2, vs)),
5679                (VTI.Vec (Inst v1, v2, is))>;
5680      def : Pat<(VTI.Vec (vselect (VTI.Pred VCCR:$pred),
5681                                  (VTI.Vec (fma v1, v2, vs)),
5682                                  v1)),
5683                (VTI.Vec (Inst v1, v2, is, ARMVCCThen, $pred, zero_reg))>;
5684      def : Pat<(VTI.Vec (pred_int v1, v2, vs, pred)),
5685                (VTI.Vec (Inst v1, v2, is, ARMVCCThen, pred, zero_reg))>;
5686    } else {
5687      def : Pat<(VTI.Vec (fma v1, vs, v2)),
5688                (VTI.Vec (Inst v2, v1, is))>;
5689      def : Pat<(VTI.Vec (fma vs, v1, v2)),
5690                (VTI.Vec (Inst v2, v1, is))>;
5691      def : Pat<(VTI.Vec (vselect (VTI.Pred VCCR:$pred),
5692                                  (VTI.Vec (fma vs, v2, v1)),
5693                                  v1)),
5694                (VTI.Vec (Inst v1, v2, is, ARMVCCThen, $pred, zero_reg))>;
5695      def : Pat<(VTI.Vec (vselect (VTI.Pred VCCR:$pred),
5696                                  (VTI.Vec (fma v2, vs, v1)),
5697                                  v1)),
5698                (VTI.Vec (Inst v1, v2, is, ARMVCCThen, $pred, zero_reg))>;
5699      def : Pat<(VTI.Vec (pred_int v1, vs, v2, pred)),
5700                (VTI.Vec (Inst v2, v1, is, ARMVCCThen, pred, zero_reg))>;
5701      def : Pat<(VTI.Vec (pred_int vs, v1, v2, pred)),
5702                (VTI.Vec (Inst v2, v1, is, ARMVCCThen, pred, zero_reg))>;
5703    }
5704  }
5705}
5706
5707let Predicates = [HasMVEFloat] in {
5708  defm MVE_VFMA_qr_f16  : MVE_VFMA_qr_multi<"vfma",  MVE_v8f16, 0>;
5709  defm MVE_VFMA_qr_f32  : MVE_VFMA_qr_multi<"vfma",  MVE_v4f32, 0>;
5710  defm MVE_VFMA_qr_Sf16 : MVE_VFMA_qr_multi<"vfmas", MVE_v8f16, 1>;
5711  defm MVE_VFMA_qr_Sf32 : MVE_VFMA_qr_multi<"vfmas", MVE_v4f32, 1>;
5712}
5713
5714class MVE_VQDMLAH_qr<string iname, string suffix, bit U, bits<2> size,
5715                     bit bit_5, bit bit_12, list<dag> pattern=[]>
5716  : MVE_qDestSrc_rSrc<iname, suffix, size, pattern> {
5717
5718  let Inst{28} = U;
5719  let Inst{21-20} = size;
5720  let Inst{16} = 0b0;
5721  let Inst{12} = bit_12;
5722  let Inst{8} = 0b0;
5723  let Inst{5} = bit_5;
5724}
5725
5726multiclass MVE_VQDMLAH_qr_multi<string iname, MVEVectorVTInfo VTI,
5727                                bit bit_5, bit bit_12> {
5728  def "": MVE_VQDMLAH_qr<iname, VTI.Suffix, 0b0, VTI.Size, bit_5, bit_12>;
5729  defvar Inst = !cast<Instruction>(NAME);
5730  defvar unpred_int = !cast<Intrinsic>("int_arm_mve_" # iname);
5731  defvar pred_int = !cast<Intrinsic>("int_arm_mve_" # iname # "_predicated");
5732
5733  let Predicates = [HasMVEInt] in {
5734    def : Pat<(VTI.Vec (unpred_int (VTI.Vec MQPR:$v1), (VTI.Vec MQPR:$v2),
5735                                   (i32 rGPR:$s))),
5736              (VTI.Vec (Inst       (VTI.Vec MQPR:$v1), (VTI.Vec MQPR:$v2),
5737                                   (i32 rGPR:$s)))>;
5738    def : Pat<(VTI.Vec (pred_int   (VTI.Vec MQPR:$v1), (VTI.Vec MQPR:$v2),
5739                                   (i32 rGPR:$s), (VTI.Pred VCCR:$pred))),
5740              (VTI.Vec (Inst       (VTI.Vec MQPR:$v1), (VTI.Vec MQPR:$v2),
5741                                   (i32 rGPR:$s), ARMVCCThen,
5742                                   (VTI.Pred VCCR:$pred), zero_reg))>;
5743  }
5744}
5745
5746multiclass MVE_VQDMLAH_qr_types<string iname, bit bit_5, bit bit_12> {
5747  defm s8  : MVE_VQDMLAH_qr_multi<iname, MVE_v16s8, bit_5, bit_12>;
5748  defm s16 : MVE_VQDMLAH_qr_multi<iname, MVE_v8s16, bit_5, bit_12>;
5749  defm s32 : MVE_VQDMLAH_qr_multi<iname, MVE_v4s32, bit_5, bit_12>;
5750}
5751
5752defm MVE_VQDMLAH_qr   : MVE_VQDMLAH_qr_types<"vqdmlah",   0b1, 0b0>;
5753defm MVE_VQRDMLAH_qr  : MVE_VQDMLAH_qr_types<"vqrdmlah",  0b0, 0b0>;
5754defm MVE_VQDMLASH_qr  : MVE_VQDMLAH_qr_types<"vqdmlash",  0b1, 0b1>;
5755defm MVE_VQRDMLASH_qr : MVE_VQDMLAH_qr_types<"vqrdmlash", 0b0, 0b1>;
5756
5757class MVE_VxDUP<string iname, string suffix, bits<2> size, bit bit_12,
5758                ValueType VT, SDPatternOperator vxdup>
5759  : MVE_p<(outs MQPR:$Qd, tGPREven:$Rn),
5760          (ins tGPREven:$Rn_src, MVE_VIDUP_imm:$imm), NoItinerary,
5761          iname, suffix, "$Qd, $Rn, $imm", vpred_r, "$Rn = $Rn_src", size,
5762          [(set (VT MQPR:$Qd), (i32 tGPREven:$Rn),
5763              (vxdup (i32 tGPREven:$Rn_src), (i32 imm:$imm)))]> {
5764  bits<4> Qd;
5765  bits<4> Rn;
5766  bits<2> imm;
5767
5768  let Inst{28} = 0b0;
5769  let Inst{25-23} = 0b100;
5770  let Inst{22} = Qd{3};
5771  let Inst{21-20} = size;
5772  let Inst{19-17} = Rn{3-1};
5773  let Inst{16} = 0b1;
5774  let Inst{15-13} = Qd{2-0};
5775  let Inst{12} = bit_12;
5776  let Inst{11-8} = 0b1111;
5777  let Inst{7} = imm{1};
5778  let Inst{6-1} = 0b110111;
5779  let Inst{0} = imm{0};
5780  let validForTailPredication = 1;
5781  let hasSideEffects = 0;
5782}
5783
5784def MVE_VIDUPu8  : MVE_VxDUP<"vidup", "u8",  0b00, 0b0, v16i8, ARMvidup>;
5785def MVE_VIDUPu16 : MVE_VxDUP<"vidup", "u16", 0b01, 0b0, v8i16, ARMvidup>;
5786def MVE_VIDUPu32 : MVE_VxDUP<"vidup", "u32", 0b10, 0b0, v4i32, ARMvidup>;
5787
5788def MVE_VDDUPu8  : MVE_VxDUP<"vddup", "u8",  0b00, 0b1, v16i8, null_frag>;
5789def MVE_VDDUPu16 : MVE_VxDUP<"vddup", "u16", 0b01, 0b1, v8i16, null_frag>;
5790def MVE_VDDUPu32 : MVE_VxDUP<"vddup", "u32", 0b10, 0b1, v4i32, null_frag>;
5791
5792class MVE_VxWDUP<string iname, string suffix, bits<2> size, bit bit_12,
5793                 list<dag> pattern=[]>
5794  : MVE_p<(outs MQPR:$Qd, tGPREven:$Rn),
5795          (ins tGPREven:$Rn_src, tGPROdd:$Rm, MVE_VIDUP_imm:$imm), NoItinerary,
5796          iname, suffix, "$Qd, $Rn, $Rm, $imm", vpred_r, "$Rn = $Rn_src", size,
5797          pattern> {
5798  bits<4> Qd;
5799  bits<4> Rm;
5800  bits<4> Rn;
5801  bits<2> imm;
5802
5803  let Inst{28} = 0b0;
5804  let Inst{25-23} = 0b100;
5805  let Inst{22} = Qd{3};
5806  let Inst{21-20} = size;
5807  let Inst{19-17} = Rn{3-1};
5808  let Inst{16} = 0b1;
5809  let Inst{15-13} = Qd{2-0};
5810  let Inst{12} = bit_12;
5811  let Inst{11-8} = 0b1111;
5812  let Inst{7} = imm{1};
5813  let Inst{6-4} = 0b110;
5814  let Inst{3-1} = Rm{3-1};
5815  let Inst{0} = imm{0};
5816  let validForTailPredication = 1;
5817  let hasSideEffects = 0;
5818}
5819
5820def MVE_VIWDUPu8  : MVE_VxWDUP<"viwdup", "u8",  0b00, 0b0>;
5821def MVE_VIWDUPu16 : MVE_VxWDUP<"viwdup", "u16", 0b01, 0b0>;
5822def MVE_VIWDUPu32 : MVE_VxWDUP<"viwdup", "u32", 0b10, 0b0>;
5823
5824def MVE_VDWDUPu8  : MVE_VxWDUP<"vdwdup", "u8",  0b00, 0b1>;
5825def MVE_VDWDUPu16 : MVE_VxWDUP<"vdwdup", "u16", 0b01, 0b1>;
5826def MVE_VDWDUPu32 : MVE_VxWDUP<"vdwdup", "u32", 0b10, 0b1>;
5827
5828let isReMaterializable = 1 in
5829class MVE_VCTPInst<string suffix, bits<2> size, list<dag> pattern=[]>
5830  : MVE_p<(outs VCCR:$P0), (ins rGPR:$Rn), NoItinerary, "vctp", suffix,
5831          "$Rn", vpred_n, "", size, pattern> {
5832  bits<4> Rn;
5833
5834  let Inst{28-27} = 0b10;
5835  let Inst{26-22} = 0b00000;
5836  let Inst{21-20} = size;
5837  let Inst{19-16} = Rn{3-0};
5838  let Inst{15-11} = 0b11101;
5839  let Inst{10-0}  = 0b00000000001;
5840  let Unpredictable{10-0} = 0b11111111111;
5841
5842  let Constraints = "";
5843  let DecoderMethod = "DecodeMveVCTP";
5844  let validForTailPredication = 1;
5845}
5846
5847multiclass MVE_VCTP<MVEVectorVTInfo VTI, Intrinsic intr> {
5848  def "": MVE_VCTPInst<VTI.BitsSuffix, VTI.Size>;
5849  defvar Inst = !cast<Instruction>(NAME);
5850
5851  let Predicates = [HasMVEInt] in {
5852    def : Pat<(intr rGPR:$Rn),
5853              (VTI.Pred (Inst rGPR:$Rn))>;
5854    def : Pat<(and (intr rGPR:$Rn), (VTI.Pred VCCR:$mask)),
5855              (VTI.Pred (Inst rGPR:$Rn, ARMVCCThen, VCCR:$mask, zero_reg))>;
5856  }
5857}
5858
5859defm MVE_VCTP8  : MVE_VCTP<MVE_v16i8, int_arm_mve_vctp8>;
5860defm MVE_VCTP16 : MVE_VCTP<MVE_v8i16, int_arm_mve_vctp16>;
5861defm MVE_VCTP32 : MVE_VCTP<MVE_v4i32, int_arm_mve_vctp32>;
5862defm MVE_VCTP64 : MVE_VCTP<MVE_v2i64, int_arm_mve_vctp64>;
5863
5864// end of mve_qDest_rSrc
5865
5866// start of coproc mov
5867
5868class MVE_VMOV_64bit<dag oops, dag iops, bit to_qreg, string ops, string cstr>
5869  : MVE_VMOV_lane_base<oops, !con(iops, (ins MVEPairVectorIndex2:$idx,
5870                                             MVEPairVectorIndex0:$idx2)),
5871                       NoItinerary, "vmov", "", ops, cstr, []> {
5872  bits<5> Rt;
5873  bits<5> Rt2;
5874  bits<4> Qd;
5875  bit idx;
5876  bit idx2;
5877
5878  let Inst{31-23} = 0b111011000;
5879  let Inst{22} = Qd{3};
5880  let Inst{21} = 0b0;
5881  let Inst{20} = to_qreg;
5882  let Inst{19-16} = Rt2{3-0};
5883  let Inst{15-13} = Qd{2-0};
5884  let Inst{12-5} = 0b01111000;
5885  let Inst{4} = idx2;
5886  let Inst{3-0} = Rt{3-0};
5887
5888  let VecSize = 0b10;
5889  let hasSideEffects = 0;
5890}
5891
5892// The assembly syntax for these instructions mentions the vector
5893// register name twice, e.g.
5894//
5895//    vmov q2[2], q2[0], r0, r1
5896//    vmov r0, r1, q2[2], q2[0]
5897//
5898// which needs a bit of juggling with MC operand handling.
5899//
5900// For the move _into_ a vector register, the MC operand list also has
5901// to mention the register name twice: once as the output, and once as
5902// an extra input to represent where the unchanged half of the output
5903// register comes from (when this instruction is used in code
5904// generation). So we arrange that the first mention of the vector reg
5905// in the instruction is considered by the AsmMatcher to be the output
5906// ($Qd), and the second one is the input ($QdSrc). Binding them
5907// together with the existing 'tie' constraint is enough to enforce at
5908// register allocation time that they have to be the same register.
5909//
5910// For the move _from_ a vector register, there's no way to get round
5911// the fact that both instances of that register name have to be
5912// inputs. They have to be the same register again, but this time, we
5913// can't use a tie constraint, because that has to be between an
5914// output and an input operand. So this time, we have to arrange that
5915// the q-reg appears just once in the MC operand list, in spite of
5916// being mentioned twice in the asm syntax - which needs a custom
5917// AsmMatchConverter.
5918
5919def MVE_VMOV_q_rr : MVE_VMOV_64bit<(outs MQPR:$Qd),
5920                                   (ins MQPR:$QdSrc, rGPR:$Rt, rGPR:$Rt2),
5921                                   0b1, "$Qd$idx, $QdSrc$idx2, $Rt, $Rt2",
5922                                   "$Qd = $QdSrc"> {
5923  let DecoderMethod = "DecodeMVEVMOVDRegtoQ";
5924}
5925
5926def MVE_VMOV_rr_q : MVE_VMOV_64bit<(outs rGPR:$Rt, rGPR:$Rt2), (ins MQPR:$Qd),
5927                                   0b0, "$Rt, $Rt2, $Qd$idx, $Qd$idx2", ""> {
5928  let DecoderMethod = "DecodeMVEVMOVQtoDReg";
5929  let AsmMatchConverter = "cvtMVEVMOVQtoDReg";
5930}
5931
5932let Predicates = [HasMVEInt] in {
5933  // Double lane moves. There are a number of patterns here. We know that the
5934  // insertelt's will be in descending order by index, and need to match the 5
5935  // patterns that might contain 2-0 or 3-1 pairs. These are:
5936  // 3 2 1 0    -> vmovqrr 31; vmovqrr 20
5937  // 3 2 1      -> vmovqrr 31; vmov 2
5938  // 3 1        -> vmovqrr 31
5939  // 2 1 0      -> vmovqrr 20; vmov 1
5940  // 2 0        -> vmovqrr 20
5941  // The other potential patterns will be handled by single lane inserts.
5942  def : Pat<(insertelt (insertelt (insertelt (insertelt (v4i32 MQPR:$src1),
5943                                                        rGPR:$srcA, (i32 0)),
5944                                             rGPR:$srcB, (i32 1)),
5945                                  rGPR:$srcC, (i32 2)),
5946                       rGPR:$srcD, (i32 3)),
5947            (MVE_VMOV_q_rr (MVE_VMOV_q_rr MQPR:$src1, rGPR:$srcA, rGPR:$srcC, (i32 2), (i32 0)),
5948                           rGPR:$srcB, rGPR:$srcD, (i32 3), (i32 1))>;
5949  def : Pat<(insertelt (insertelt (insertelt (v4i32 MQPR:$src1),
5950                                             rGPR:$srcB, (i32 1)),
5951                                  rGPR:$srcC, (i32 2)),
5952                       rGPR:$srcD, (i32 3)),
5953            (MVE_VMOV_q_rr (MVE_VMOV_to_lane_32 MQPR:$src1, rGPR:$srcC, (i32 2)),
5954                           rGPR:$srcB, rGPR:$srcD, (i32 3), (i32 1))>;
5955  def : Pat<(insertelt (insertelt (v4i32 MQPR:$src1), rGPR:$srcA, (i32 1)), rGPR:$srcB, (i32 3)),
5956            (MVE_VMOV_q_rr MQPR:$src1, rGPR:$srcA, rGPR:$srcB, (i32 3), (i32 1))>;
5957  def : Pat<(insertelt (insertelt (insertelt (v4i32 MQPR:$src1),
5958                                             rGPR:$srcB, (i32 0)),
5959                                  rGPR:$srcC, (i32 1)),
5960                       rGPR:$srcD, (i32 2)),
5961            (MVE_VMOV_q_rr (MVE_VMOV_to_lane_32 MQPR:$src1, rGPR:$srcC, (i32 1)),
5962                           rGPR:$srcB, rGPR:$srcD, (i32 2), (i32 0))>;
5963  def : Pat<(insertelt (insertelt (v4i32 MQPR:$src1), rGPR:$srcA, (i32 0)), rGPR:$srcB, (i32 2)),
5964            (MVE_VMOV_q_rr MQPR:$src1, rGPR:$srcA, rGPR:$srcB, (i32 2), (i32 0))>;
5965}
5966
5967// end of coproc mov
5968
5969// start of MVE interleaving load/store
5970
5971// Base class for the family of interleaving/deinterleaving
5972// load/stores with names like VLD20.8 and VST43.32.
5973class MVE_vldst24_base<bit writeback, bit fourregs, bits<2> stage, bits<2> size,
5974                       bit load, dag Oops, dag loadIops, dag wbIops,
5975                       string iname, string ops,
5976                       string cstr, list<dag> pattern=[]>
5977  : MVE_MI<Oops, !con(loadIops, wbIops), NoItinerary, iname, ops, cstr, size, pattern> {
5978  bits<4> VQd;
5979  bits<4> Rn;
5980
5981  let Inst{31-22} = 0b1111110010;
5982  let Inst{21} = writeback;
5983  let Inst{20} = load;
5984  let Inst{19-16} = Rn;
5985  let Inst{15-13} = VQd{2-0};
5986  let Inst{12-9} = 0b1111;
5987  let Inst{8-7} = size;
5988  let Inst{6-5} = stage;
5989  let Inst{4-1} = 0b0000;
5990  let Inst{0} = fourregs;
5991
5992  let mayLoad = load;
5993  let mayStore = !eq(load,0);
5994  let hasSideEffects = 0;
5995  let validForTailPredication = load;
5996}
5997
5998// A parameter class used to encapsulate all the ways the writeback
5999// variants of VLD20 and friends differ from the non-writeback ones.
6000class MVE_vldst24_writeback<bit b, dag Oo, dag Io,
6001                            string sy="", string c="", string n=""> {
6002  bit writeback = b;
6003  dag Oops = Oo;
6004  dag Iops = Io;
6005  string syntax = sy;
6006  string cstr = c;
6007  string id_suffix = n;
6008}
6009
6010// Another parameter class that encapsulates the differences between VLD2x
6011// and VLD4x.
6012class MVE_vldst24_nvecs<int n, list<int> s, bit b, RegisterOperand vl> {
6013  int nvecs = n;
6014  list<int> stages = s;
6015  bit bit0 = b;
6016  RegisterOperand VecList = vl;
6017}
6018
6019// A third parameter class that distinguishes VLDnn.8 from .16 from .32.
6020class MVE_vldst24_lanesize<int i, bits<2> b> {
6021  int lanesize = i;
6022  bits<2> sizebits = b;
6023}
6024
6025// A base class for each direction of transfer: one for load, one for
6026// store. I can't make these a fourth independent parametric tuple
6027// class, because they have to take the nvecs tuple class as a
6028// parameter, in order to find the right VecList operand type.
6029
6030class MVE_vld24_base<MVE_vldst24_nvecs n, bits<2> pat, bits<2> size,
6031                     MVE_vldst24_writeback wb, string iname,
6032                     list<dag> pattern=[]>
6033  : MVE_vldst24_base<wb.writeback, n.bit0, pat, size, 1,
6034                     !con((outs n.VecList:$VQd), wb.Oops),
6035                     (ins n.VecList:$VQdSrc), wb.Iops,
6036                     iname, "$VQd, $Rn" # wb.syntax,
6037                     wb.cstr # ",$VQdSrc = $VQd", pattern>;
6038
6039class MVE_vst24_base<MVE_vldst24_nvecs n, bits<2> pat, bits<2> size,
6040                     MVE_vldst24_writeback wb, string iname,
6041                     list<dag> pattern=[]>
6042  : MVE_vldst24_base<wb.writeback, n.bit0, pat, size, 0,
6043                     wb.Oops, (ins n.VecList:$VQd), wb.Iops,
6044                     iname, "$VQd, $Rn" # wb.syntax,
6045                     wb.cstr, pattern>;
6046
6047// Actually define all the interleaving loads and stores, by a series
6048// of nested foreaches over number of vectors (VLD2/VLD4); stage
6049// within one of those series (VLDx0/VLDx1/VLDx2/VLDx3); size of
6050// vector lane; writeback or no writeback.
6051foreach n = [MVE_vldst24_nvecs<2, [0,1],     0, VecList2Q>,
6052             MVE_vldst24_nvecs<4, [0,1,2,3], 1, VecList4Q>] in
6053foreach stage = n.stages in
6054foreach s = [MVE_vldst24_lanesize< 8, 0b00>,
6055             MVE_vldst24_lanesize<16, 0b01>,
6056             MVE_vldst24_lanesize<32, 0b10>] in
6057foreach wb = [MVE_vldst24_writeback<
6058                1, (outs rGPR:$wb), (ins t2_nosp_addr_offset_none:$Rn),
6059                "!", "$Rn.base = $wb", "_wb">,
6060              MVE_vldst24_writeback<0, (outs), (ins t2_addr_offset_none:$Rn)>] in {
6061
6062  // For each case within all of those foreaches, define the actual
6063  // instructions. The def names are made by gluing together pieces
6064  // from all the parameter classes, and will end up being things like
6065  // MVE_VLD20_8 and MVE_VST43_16_wb.
6066
6067  def "MVE_VLD" # n.nvecs # stage # "_" # s.lanesize # wb.id_suffix
6068    : MVE_vld24_base<n, stage, s.sizebits, wb,
6069                     "vld" # n.nvecs # stage # "." # s.lanesize>;
6070
6071  def "MVE_VST" # n.nvecs # stage # "_" # s.lanesize # wb.id_suffix
6072    : MVE_vst24_base<n, stage, s.sizebits, wb,
6073                     "vst" # n.nvecs # stage # "." # s.lanesize>;
6074}
6075
6076def SDTARMVST2    : SDTypeProfile<1, 5, [SDTCisPtrTy<0>, SDTCisPtrTy<1>, SDTCisVT<2, i32>, SDTCisVec<3>,
6077                                         SDTCisSameAs<3, 4>, SDTCisVT<5, i32>]>;
6078def SDTARMVST4    : SDTypeProfile<1, 7, [SDTCisPtrTy<0>, SDTCisPtrTy<1>, SDTCisVT<2, i32>, SDTCisVec<3>,
6079                                         SDTCisSameAs<3, 4>, SDTCisSameAs<3, 5>,
6080                                         SDTCisSameAs<3, 6>, SDTCisVT<7, i32>]>;
6081def MVEVST2UPD       : SDNode<"ARMISD::VST2_UPD", SDTARMVST2, [SDNPHasChain, SDNPMemOperand]>;
6082def MVEVST4UPD       : SDNode<"ARMISD::VST4_UPD", SDTARMVST4, [SDNPHasChain, SDNPMemOperand]>;
6083
6084multiclass MVE_vst24_patterns<int lanesize, ValueType VT> {
6085  foreach stage = [0,1] in
6086    def : Pat<(int_arm_mve_vst2q i32:$addr,
6087                (VT MQPR:$v0), (VT MQPR:$v1), (i32 stage)),
6088              (!cast<Instruction>("MVE_VST2"#stage#"_"#lanesize)
6089                (REG_SEQUENCE MQQPR, VT:$v0, qsub_0, VT:$v1, qsub_1),
6090                t2_addr_offset_none:$addr)>;
6091  foreach stage = [0,1] in
6092    def : Pat<(i32 (MVEVST2UPD i32:$addr, (i32 32),
6093                (VT MQPR:$v0), (VT MQPR:$v1), (i32 stage))),
6094              (i32 (!cast<Instruction>("MVE_VST2"#stage#"_"#lanesize#_wb)
6095                (REG_SEQUENCE MQQPR, VT:$v0, qsub_0, VT:$v1, qsub_1),
6096                t2_addr_offset_none:$addr))>;
6097
6098  foreach stage = [0,1,2,3] in
6099    def : Pat<(int_arm_mve_vst4q i32:$addr,
6100                (VT MQPR:$v0), (VT MQPR:$v1),
6101                (VT MQPR:$v2), (VT MQPR:$v3), (i32 stage)),
6102              (!cast<Instruction>("MVE_VST4"#stage#"_"#lanesize)
6103                (REG_SEQUENCE MQQQQPR, VT:$v0, qsub_0, VT:$v1, qsub_1,
6104                                       VT:$v2, qsub_2, VT:$v3, qsub_3),
6105                t2_addr_offset_none:$addr)>;
6106  foreach stage = [0,1,2,3] in
6107    def : Pat<(i32 (MVEVST4UPD i32:$addr, (i32 64),
6108                (VT MQPR:$v0), (VT MQPR:$v1),
6109                (VT MQPR:$v2), (VT MQPR:$v3), (i32 stage))),
6110              (i32 (!cast<Instruction>("MVE_VST4"#stage#"_"#lanesize#_wb)
6111                (REG_SEQUENCE MQQQQPR, VT:$v0, qsub_0, VT:$v1, qsub_1,
6112                                       VT:$v2, qsub_2, VT:$v3, qsub_3),
6113                t2_addr_offset_none:$addr))>;
6114}
6115defm : MVE_vst24_patterns<8, v16i8>;
6116defm : MVE_vst24_patterns<16, v8i16>;
6117defm : MVE_vst24_patterns<32, v4i32>;
6118defm : MVE_vst24_patterns<16, v8f16>;
6119defm : MVE_vst24_patterns<32, v4f32>;
6120
6121// end of MVE interleaving load/store
6122
6123// start of MVE predicable load/store
6124
6125// A parameter class for the direction of transfer.
6126class MVE_ldst_direction<bit b, dag Oo, dag Io, string c=""> {
6127  bit load = b;
6128  dag Oops = Oo;
6129  dag Iops = Io;
6130  string cstr = c;
6131}
6132def MVE_ld: MVE_ldst_direction<1, (outs MQPR:$Qd), (ins), ",@earlyclobber $Qd">;
6133def MVE_st: MVE_ldst_direction<0, (outs), (ins MQPR:$Qd)>;
6134
6135// A parameter class for the size of memory access in a load.
6136class MVE_memsz<bits<2> e, int s, AddrMode m, string mn, list<string> types> {
6137  bits<2> encoding = e;         // opcode bit(s) for encoding
6138  int shift = s;                // shift applied to immediate load offset
6139  AddrMode AM = m;
6140
6141  // For instruction aliases: define the complete list of type
6142  // suffixes at this size, and the canonical ones for loads and
6143  // stores.
6144  string MnemonicLetter = mn;
6145  int TypeBits = !shl(8, s);
6146  string CanonLoadSuffix = ".u" # TypeBits;
6147  string CanonStoreSuffix = "." # TypeBits;
6148  list<string> suffixes = !foreach(letter, types, "." # letter # TypeBits);
6149}
6150
6151// Instances of MVE_memsz.
6152//
6153// (memD doesn't need an AddrMode, because those are only for
6154// contiguous loads, and memD is only used by gather/scatters.)
6155def MVE_memB: MVE_memsz<0b00, 0, AddrModeT2_i7,   "b", ["", "u", "s"]>;
6156def MVE_memH: MVE_memsz<0b01, 1, AddrModeT2_i7s2, "h", ["", "u", "s", "f"]>;
6157def MVE_memW: MVE_memsz<0b10, 2, AddrModeT2_i7s4, "w", ["", "u", "s", "f"]>;
6158def MVE_memD: MVE_memsz<0b11, 3, ?,               "d", ["", "u", "s", "f"]>;
6159
6160// This is the base class for all the MVE loads and stores other than
6161// the interleaving ones. All the non-interleaving loads/stores share
6162// the characteristic that they operate on just one vector register,
6163// so they are VPT-predicable.
6164//
6165// The predication operand is vpred_n, for both loads and stores. For
6166// store instructions, the reason is obvious: if there is no output
6167// register, there can't be a need for an input parameter giving the
6168// output register's previous value. Load instructions also don't need
6169// that input parameter, because unlike MVE data processing
6170// instructions, predicated loads are defined to set the inactive
6171// lanes of the output register to zero, instead of preserving their
6172// input values.
6173class MVE_VLDRSTR_base<MVE_ldst_direction dir, bit U, bit P, bit W, bit opc,
6174                       dag oops, dag iops, string asm, string suffix,
6175                       string ops, string cstr, bits<2> vecsize, list<dag> pattern=[]>
6176 : MVE_p<oops, iops, NoItinerary, asm, suffix, ops, vpred_n, cstr, vecsize, pattern> {
6177  bits<3> Qd;
6178
6179  let Inst{28} = U;
6180  let Inst{25} = 0b0;
6181  let Inst{24} = P;
6182  let Inst{22} = 0b0;
6183  let Inst{21} = W;
6184  let Inst{20} = dir.load;
6185  let Inst{15-13} = Qd{2-0};
6186  let Inst{12} = opc;
6187  let Inst{11-9} = 0b111;
6188
6189  let mayLoad = dir.load;
6190  let mayStore = !eq(dir.load,0);
6191  let hasSideEffects = 0;
6192  let validForTailPredication = 1;
6193}
6194
6195// Contiguous load and store instructions. These come in two main
6196// categories: same-size loads/stores in which 128 bits of vector
6197// register is transferred to or from 128 bits of memory in the most
6198// obvious way, and widening loads / narrowing stores, in which the
6199// size of memory accessed is less than the size of a vector register,
6200// so the load instructions sign- or zero-extend each memory value
6201// into a wider vector lane, and the store instructions truncate
6202// correspondingly.
6203//
6204// The instruction mnemonics for these two classes look reasonably
6205// similar, but the actual encodings are different enough to need two
6206// separate base classes.
6207
6208// Contiguous, same size
6209class MVE_VLDRSTR_cs<MVE_ldst_direction dir, MVE_memsz memsz, bit P, bit W,
6210                     dag oops, dag iops, string asm, string suffix,
6211                     IndexMode im, string ops, string cstr>
6212  : MVE_VLDRSTR_base<dir, 0, P, W, 1, oops, iops, asm, suffix, ops, cstr, memsz.encoding> {
6213  bits<12> addr;
6214  let Inst{23} = addr{7};
6215  let Inst{19-16} = addr{11-8};
6216  let Inst{8-7} = memsz.encoding;
6217  let Inst{6-0} = addr{6-0};
6218
6219  let IM = im;
6220}
6221
6222// Contiguous, widening/narrowing
6223class MVE_VLDRSTR_cw<MVE_ldst_direction dir, MVE_memsz memsz, bit U,
6224                     bit P, bit W, bits<2> size, dag oops, dag iops,
6225                     string asm, string suffix, IndexMode im,
6226                     string ops, string cstr>
6227  : MVE_VLDRSTR_base<dir, U, P, W, 0, oops, iops, asm, suffix, ops, cstr, size> {
6228  bits<11> addr;
6229  let Inst{23} = addr{7};
6230  let Inst{19} = memsz.encoding{0}; // enough to tell 16- from 32-bit
6231  let Inst{18-16} = addr{10-8};
6232  let Inst{8-7} = size;
6233  let Inst{6-0} = addr{6-0};
6234
6235  let IM = im;
6236}
6237
6238// Multiclass wrapper on each of the _cw and _cs base classes, to
6239// generate three writeback modes (none, preindex, postindex).
6240
6241multiclass MVE_VLDRSTR_cw_m<MVE_ldst_direction dir, MVE_memsz memsz,
6242                            string asm, string suffix, bit U, bits<2> size> {
6243  let AM = memsz.AM in {
6244    def "" : MVE_VLDRSTR_cw<
6245        dir, memsz, U, 1, 0, size,
6246        dir.Oops, !con(dir.Iops, (ins taddrmode_imm7<memsz.shift>:$addr)),
6247        asm, suffix, IndexModeNone, "$Qd, $addr", "">;
6248
6249    def _pre : MVE_VLDRSTR_cw<
6250        dir, memsz, U, 1, 1, size,
6251        !con((outs tGPR:$wb), dir.Oops),
6252        !con(dir.Iops, (ins taddrmode_imm7<memsz.shift>:$addr)),
6253        asm, suffix, IndexModePre, "$Qd, $addr!", "$addr.base = $wb"> {
6254      let DecoderMethod = "DecodeMVE_MEM_1_pre<"#memsz.shift#">";
6255    }
6256
6257    def _post : MVE_VLDRSTR_cw<
6258        dir, memsz, U, 0, 1, size,
6259        !con((outs tGPR:$wb), dir.Oops),
6260        !con(dir.Iops, (ins t_addr_offset_none:$Rn,
6261                            t2am_imm7_offset<memsz.shift>:$addr)),
6262        asm, suffix, IndexModePost, "$Qd, $Rn$addr", "$Rn.base = $wb"> {
6263      bits<4> Rn;
6264      let Inst{18-16} = Rn{2-0};
6265    }
6266  }
6267}
6268
6269multiclass MVE_VLDRSTR_cs_m<MVE_ldst_direction dir, MVE_memsz memsz,
6270                            string asm, string suffix> {
6271  let AM = memsz.AM in {
6272    def "" : MVE_VLDRSTR_cs<
6273        dir, memsz, 1, 0,
6274        dir.Oops, !con(dir.Iops, (ins t2addrmode_imm7<memsz.shift>:$addr)),
6275        asm, suffix, IndexModeNone, "$Qd, $addr", "">;
6276
6277    def _pre : MVE_VLDRSTR_cs<
6278        dir, memsz, 1, 1,
6279        !con((outs rGPR:$wb), dir.Oops),
6280        !con(dir.Iops, (ins t2addrmode_imm7_pre<memsz.shift>:$addr)),
6281        asm, suffix, IndexModePre, "$Qd, $addr!", "$addr.base = $wb"> {
6282      let DecoderMethod = "DecodeMVE_MEM_2_pre<"#memsz.shift#">";
6283    }
6284
6285    def _post : MVE_VLDRSTR_cs<
6286        dir, memsz, 0, 1,
6287        !con((outs rGPR:$wb), dir.Oops),
6288        !con(dir.Iops, (ins t2_nosp_addr_offset_none:$Rn,
6289                            t2am_imm7_offset<memsz.shift>:$addr)),
6290        asm, suffix, IndexModePost, "$Qd, $Rn$addr", "$Rn.base = $wb"> {
6291      bits<4> Rn;
6292      let Inst{19-16} = Rn{3-0};
6293    }
6294  }
6295}
6296
6297// Now actually declare all the contiguous load/stores, via those
6298// multiclasses. The instruction ids coming out of this are the bare
6299// names shown in the defm, with _pre or _post appended for writeback,
6300// e.g. MVE_VLDRBS16, MVE_VSTRB16_pre, MVE_VSTRHU16_post.
6301
6302defm MVE_VLDRBS16: MVE_VLDRSTR_cw_m<MVE_ld, MVE_memB, "vldrb", "s16", 0, 0b01>;
6303defm MVE_VLDRBS32: MVE_VLDRSTR_cw_m<MVE_ld, MVE_memB, "vldrb", "s32", 0, 0b10>;
6304defm MVE_VLDRBU16: MVE_VLDRSTR_cw_m<MVE_ld, MVE_memB, "vldrb", "u16", 1, 0b01>;
6305defm MVE_VLDRBU32: MVE_VLDRSTR_cw_m<MVE_ld, MVE_memB, "vldrb", "u32", 1, 0b10>;
6306defm MVE_VLDRHS32: MVE_VLDRSTR_cw_m<MVE_ld, MVE_memH, "vldrh", "s32", 0, 0b10>;
6307defm MVE_VLDRHU32: MVE_VLDRSTR_cw_m<MVE_ld, MVE_memH, "vldrh", "u32", 1, 0b10>;
6308
6309defm MVE_VLDRBU8:  MVE_VLDRSTR_cs_m<MVE_ld, MVE_memB, "vldrb", "u8">;
6310defm MVE_VLDRHU16: MVE_VLDRSTR_cs_m<MVE_ld, MVE_memH, "vldrh", "u16">;
6311defm MVE_VLDRWU32: MVE_VLDRSTR_cs_m<MVE_ld, MVE_memW, "vldrw", "u32">;
6312
6313defm MVE_VSTRB16:  MVE_VLDRSTR_cw_m<MVE_st, MVE_memB, "vstrb", "16",  0, 0b01>;
6314defm MVE_VSTRB32:  MVE_VLDRSTR_cw_m<MVE_st, MVE_memB, "vstrb", "32",  0, 0b10>;
6315defm MVE_VSTRH32:  MVE_VLDRSTR_cw_m<MVE_st, MVE_memH, "vstrh", "32",  0, 0b10>;
6316
6317defm MVE_VSTRBU8 : MVE_VLDRSTR_cs_m<MVE_st, MVE_memB, "vstrb", "8">;
6318defm MVE_VSTRHU16: MVE_VLDRSTR_cs_m<MVE_st, MVE_memH, "vstrh", "16">;
6319defm MVE_VSTRWU32: MVE_VLDRSTR_cs_m<MVE_st, MVE_memW, "vstrw", "32">;
6320
6321// Gather loads / scatter stores whose address operand is of the form
6322// [Rn,Qm], i.e. a single GPR as the common base address, plus a
6323// vector of offset from it. ('Load/store this sequence of elements of
6324// the same array.')
6325//
6326// Like the contiguous family, these loads and stores can widen the
6327// loaded values / truncate the stored ones, or they can just
6328// load/store the same size of memory and vector lane. But unlike the
6329// contiguous family, there's no particular difference in encoding
6330// between those two cases.
6331//
6332// This family also comes with the option to scale the offset values
6333// in Qm by the size of the loaded memory (i.e. to treat them as array
6334// indices), or not to scale them (to treat them as plain byte offsets
6335// in memory, so that perhaps the loaded values are unaligned). The
6336// scaled instructions' address operand in assembly looks like
6337// [Rn,Qm,UXTW #2] or similar.
6338
6339// Base class.
6340class MVE_VLDRSTR_rq<MVE_ldst_direction dir, MVE_memsz memsz, bit U,
6341                     bits<2> size, bit os, string asm, string suffix, int shift>
6342  : MVE_VLDRSTR_base<dir, U, 0b0, 0b0, 0, dir.Oops,
6343                     !con(dir.Iops, (ins mve_addr_rq_shift<shift>:$addr)),
6344                     asm, suffix, "$Qd, $addr", dir.cstr, size> {
6345  bits<7> addr;
6346  let Inst{23} = 0b1;
6347  let Inst{19-16} = addr{6-3};
6348  let Inst{8-7} = size;
6349  let Inst{6} = memsz.encoding{1};
6350  let Inst{5} = 0;
6351  let Inst{4} = memsz.encoding{0};
6352  let Inst{3-1} = addr{2-0};
6353  let Inst{0} = os;
6354}
6355
6356// Multiclass that defines the scaled and unscaled versions of an
6357// instruction, when the memory size is wider than a byte. The scaled
6358// version gets the default name like MVE_VLDRBU16_rq; the unscaled /
6359// potentially unaligned version gets a "_u" suffix, e.g.
6360// MVE_VLDRBU16_rq_u.
6361multiclass MVE_VLDRSTR_rq_w<MVE_ldst_direction dir, MVE_memsz memsz,
6362                            string asm, string suffix, bit U, bits<2> size> {
6363  def _u : MVE_VLDRSTR_rq<dir, memsz, U, size, 0, asm, suffix, 0>;
6364  def "" : MVE_VLDRSTR_rq<dir, memsz, U, size, 1, asm, suffix, memsz.shift>;
6365}
6366
6367// Subclass of MVE_VLDRSTR_rq with the same API as that multiclass,
6368// for use when the memory size is one byte, so there's no 'scaled'
6369// version of the instruction at all. (This is encoded as if it were
6370// unscaled, but named in the default way with no _u suffix.)
6371class MVE_VLDRSTR_rq_b<MVE_ldst_direction dir, MVE_memsz memsz,
6372                       string asm, string suffix, bit U, bits<2> size>
6373  : MVE_VLDRSTR_rq<dir, memsz, U, size, 0, asm, suffix, 0>;
6374
6375// Multiclasses wrapping that to add ISel patterns for intrinsics.
6376multiclass MVE_VLDR_rq_w<MVE_memsz memsz, list<MVEVectorVTInfo> VTIs> {
6377  defm "": MVE_VLDRSTR_rq_w<MVE_ld, memsz, "vldr" # memsz.MnemonicLetter,
6378                            VTIs[0].Suffix, VTIs[0].Unsigned, VTIs[0].Size>;
6379  defvar Inst = !cast<Instruction>(NAME);
6380  defvar InstU = !cast<Instruction>(NAME # "_u");
6381
6382  foreach VTI = VTIs in
6383  foreach UnsignedFlag = !if(!eq(VTI.Size, memsz.encoding),
6384                             [0,1], [VTI.Unsigned]) in {
6385    def : Pat<(VTI.Vec (int_arm_mve_vldr_gather_offset GPR:$base, (VTIs[0].Vec MQPR:$offsets), memsz.TypeBits, 0, UnsignedFlag)),
6386              (VTI.Vec (InstU GPR:$base, MQPR:$offsets))>;
6387    def : Pat<(VTI.Vec (int_arm_mve_vldr_gather_offset GPR:$base, (VTIs[0].Vec MQPR:$offsets), memsz.TypeBits, memsz.shift, UnsignedFlag)),
6388              (VTI.Vec (Inst GPR:$base, MQPR:$offsets))>;
6389    def : Pat<(VTI.Vec (int_arm_mve_vldr_gather_offset_predicated GPR:$base, (VTIs[0].Vec MQPR:$offsets), memsz.TypeBits, 0, UnsignedFlag, (VTI.Pred VCCR:$pred))),
6390              (VTI.Vec (InstU GPR:$base, MQPR:$offsets, ARMVCCThen, VCCR:$pred, zero_reg))>;
6391    def : Pat<(VTI.Vec (int_arm_mve_vldr_gather_offset_predicated GPR:$base, (VTIs[0].Vec MQPR:$offsets), memsz.TypeBits, memsz.shift, UnsignedFlag, (VTI.Pred VCCR:$pred))),
6392              (VTI.Vec (Inst GPR:$base, MQPR:$offsets, ARMVCCThen, VCCR:$pred, zero_reg))>;
6393  }
6394}
6395multiclass MVE_VLDR_rq_b<list<MVEVectorVTInfo> VTIs> {
6396  def "": MVE_VLDRSTR_rq_b<MVE_ld, MVE_memB, "vldrb",
6397                           VTIs[0].Suffix, VTIs[0].Unsigned, VTIs[0].Size>;
6398  defvar Inst = !cast<Instruction>(NAME);
6399
6400  foreach VTI = VTIs in {
6401    def : Pat<(VTI.Vec (int_arm_mve_vldr_gather_offset GPR:$base, (VTIs[0].Vec MQPR:$offsets), 8, 0, VTI.Unsigned)),
6402              (VTI.Vec (Inst GPR:$base, MQPR:$offsets))>;
6403    def : Pat<(VTI.Vec (int_arm_mve_vldr_gather_offset_predicated GPR:$base, (VTIs[0].Vec MQPR:$offsets), 8, 0, VTI.Unsigned, (VTI.Pred VCCR:$pred))),
6404              (VTI.Vec (Inst GPR:$base, MQPR:$offsets, ARMVCCThen, VCCR:$pred, zero_reg))>;
6405  }
6406}
6407multiclass MVE_VSTR_rq_w<MVE_memsz memsz, list<MVEVectorVTInfo> VTIs> {
6408  defm "": MVE_VLDRSTR_rq_w<MVE_st, memsz, "vstr" # memsz.MnemonicLetter,
6409                            VTIs[0].BitsSuffix, 0, VTIs[0].Size>;
6410  defvar Inst = !cast<Instruction>(NAME);
6411  defvar InstU = !cast<Instruction>(NAME # "_u");
6412
6413  foreach VTI = VTIs in {
6414    def : Pat<(int_arm_mve_vstr_scatter_offset GPR:$base, (VTIs[0].Vec MQPR:$offsets), (VTI.Vec MQPR:$data), memsz.TypeBits, 0),
6415              (InstU MQPR:$data, GPR:$base, MQPR:$offsets)>;
6416    def : Pat<(int_arm_mve_vstr_scatter_offset GPR:$base, (VTIs[0].Vec MQPR:$offsets), (VTI.Vec MQPR:$data), memsz.TypeBits, memsz.shift),
6417              (Inst MQPR:$data, GPR:$base, MQPR:$offsets)>;
6418    def : Pat<(int_arm_mve_vstr_scatter_offset_predicated GPR:$base, (VTIs[0].Vec MQPR:$offsets), (VTI.Vec MQPR:$data), memsz.TypeBits, 0, (VTI.Pred VCCR:$pred)),
6419              (InstU MQPR:$data, GPR:$base, MQPR:$offsets, ARMVCCThen, VCCR:$pred, zero_reg)>;
6420    def : Pat<(int_arm_mve_vstr_scatter_offset_predicated GPR:$base, (VTIs[0].Vec MQPR:$offsets), (VTI.Vec MQPR:$data), memsz.TypeBits, memsz.shift, (VTI.Pred VCCR:$pred)),
6421              (Inst MQPR:$data, GPR:$base, MQPR:$offsets, ARMVCCThen, VCCR:$pred, zero_reg)>;
6422  }
6423}
6424multiclass MVE_VSTR_rq_b<list<MVEVectorVTInfo> VTIs> {
6425  def "": MVE_VLDRSTR_rq_b<MVE_st, MVE_memB, "vstrb",
6426                           VTIs[0].BitsSuffix, 0, VTIs[0].Size>;
6427  defvar Inst = !cast<Instruction>(NAME);
6428
6429  foreach VTI = VTIs in {
6430    def : Pat<(int_arm_mve_vstr_scatter_offset GPR:$base, (VTIs[0].Vec MQPR:$offsets), (VTI.Vec MQPR:$data), 8, 0),
6431              (Inst MQPR:$data, GPR:$base, MQPR:$offsets)>;
6432    def : Pat<(int_arm_mve_vstr_scatter_offset_predicated GPR:$base, (VTIs[0].Vec MQPR:$offsets), (VTI.Vec MQPR:$data), 8, 0, (VTI.Pred VCCR:$pred)),
6433              (Inst MQPR:$data, GPR:$base, MQPR:$offsets, ARMVCCThen, VCCR:$pred, zero_reg)>;
6434  }
6435}
6436
6437// Actually define all the loads and stores in this family.
6438
6439defm MVE_VLDRBU8_rq : MVE_VLDR_rq_b<[MVE_v16u8,MVE_v16s8]>;
6440defm MVE_VLDRBU16_rq: MVE_VLDR_rq_b<[MVE_v8u16]>;
6441defm MVE_VLDRBS16_rq: MVE_VLDR_rq_b<[MVE_v8s16]>;
6442defm MVE_VLDRBU32_rq: MVE_VLDR_rq_b<[MVE_v4u32]>;
6443defm MVE_VLDRBS32_rq: MVE_VLDR_rq_b<[MVE_v4s32]>;
6444
6445defm MVE_VLDRHU16_rq: MVE_VLDR_rq_w<MVE_memH, [MVE_v8u16,MVE_v8s16,MVE_v8f16]>;
6446defm MVE_VLDRHU32_rq: MVE_VLDR_rq_w<MVE_memH, [MVE_v4u32]>;
6447defm MVE_VLDRHS32_rq: MVE_VLDR_rq_w<MVE_memH, [MVE_v4s32]>;
6448defm MVE_VLDRWU32_rq: MVE_VLDR_rq_w<MVE_memW, [MVE_v4u32,MVE_v4s32,MVE_v4f32]>;
6449defm MVE_VLDRDU64_rq: MVE_VLDR_rq_w<MVE_memD, [MVE_v2u64,MVE_v2s64]>;
6450
6451defm MVE_VSTRB8_rq  : MVE_VSTR_rq_b<[MVE_v16i8]>;
6452defm MVE_VSTRB16_rq : MVE_VSTR_rq_b<[MVE_v8i16]>;
6453defm MVE_VSTRB32_rq : MVE_VSTR_rq_b<[MVE_v4i32]>;
6454
6455defm MVE_VSTRH16_rq : MVE_VSTR_rq_w<MVE_memH, [MVE_v8i16,MVE_v8f16]>;
6456defm MVE_VSTRH32_rq : MVE_VSTR_rq_w<MVE_memH, [MVE_v4i32]>;
6457defm MVE_VSTRW32_rq : MVE_VSTR_rq_w<MVE_memW, [MVE_v4i32,MVE_v4f32]>;
6458defm MVE_VSTRD64_rq : MVE_VSTR_rq_w<MVE_memD, [MVE_v2i64]>;
6459
6460// Gather loads / scatter stores whose address operand is of the form
6461// [Qm,#imm], i.e. a vector containing a full base address for each
6462// loaded item, plus an immediate offset applied consistently to all
6463// of them. ('Load/store the same field from this vector of pointers
6464// to a structure type.')
6465//
6466// This family requires the vector lane size to be at least 32 bits
6467// (so there's room for an address in each lane at all). It has no
6468// widening/narrowing variants. But it does support preindex
6469// writeback, in which the address vector is updated to hold the
6470// addresses actually loaded from.
6471
6472// Base class.
6473class MVE_VLDRSTR_qi<MVE_ldst_direction dir, MVE_memsz memsz, bit W, dag wbops,
6474                     string asm, string wbAsm, string suffix, string cstr = "">
6475  : MVE_VLDRSTR_base<dir, 1, 1, W, 1, !con(wbops, dir.Oops),
6476                     !con(dir.Iops, (ins mve_addr_q_shift<memsz.shift>:$addr)),
6477                     asm, suffix, "$Qd, $addr" # wbAsm, cstr # dir.cstr, memsz.encoding> {
6478  bits<11> addr;
6479  let Inst{23} = addr{7};
6480  let Inst{19-17} = addr{10-8};
6481  let Inst{16} = 0;
6482  let Inst{8} = memsz.encoding{0}; // enough to distinguish 32- from 64-bit
6483  let Inst{7} = 0;
6484  let Inst{6-0} = addr{6-0};
6485}
6486
6487// Multiclass that generates the non-writeback and writeback variants.
6488multiclass MVE_VLDRSTR_qi_m<MVE_ldst_direction dir, MVE_memsz memsz,
6489                            string asm, string suffix> {
6490  def ""   : MVE_VLDRSTR_qi<dir, memsz, 0, (outs),          asm, "",  suffix>;
6491  def _pre : MVE_VLDRSTR_qi<dir, memsz, 1, (outs MQPR:$wb), asm, "!", suffix,
6492                            "$addr.base = $wb"> {
6493    let DecoderMethod="DecodeMVE_MEM_3_pre<"#memsz.shift#">";
6494  }
6495}
6496
6497// Multiclasses wrapping that one, adding selection patterns for the
6498// non-writeback loads and all the stores. (The writeback loads must
6499// deliver multiple output values, so they have to be selected by C++
6500// code.)
6501multiclass MVE_VLDR_qi<MVE_memsz memsz, MVEVectorVTInfo AVTI,
6502                       list<MVEVectorVTInfo> DVTIs> {
6503  defm "" : MVE_VLDRSTR_qi_m<MVE_ld, memsz, "vldr" # memsz.MnemonicLetter,
6504                             "u" # memsz.TypeBits>;
6505  defvar Inst = !cast<Instruction>(NAME);
6506
6507  foreach DVTI = DVTIs in {
6508    def : Pat<(DVTI.Vec (int_arm_mve_vldr_gather_base
6509                 (AVTI.Vec MQPR:$addr), (i32 imm:$offset))),
6510              (DVTI.Vec (Inst (AVTI.Vec MQPR:$addr), (i32 imm:$offset)))>;
6511    def : Pat<(DVTI.Vec (int_arm_mve_vldr_gather_base_predicated
6512                 (AVTI.Vec MQPR:$addr), (i32 imm:$offset), (AVTI.Pred VCCR:$pred))),
6513              (DVTI.Vec (Inst (AVTI.Vec MQPR:$addr), (i32 imm:$offset),
6514                        ARMVCCThen, VCCR:$pred, zero_reg))>;
6515  }
6516}
6517multiclass MVE_VSTR_qi<MVE_memsz memsz, MVEVectorVTInfo AVTI,
6518                       list<MVEVectorVTInfo> DVTIs> {
6519  defm "" : MVE_VLDRSTR_qi_m<MVE_st, memsz, "vstr" # memsz.MnemonicLetter,
6520                             !cast<string>(memsz.TypeBits)>;
6521  defvar Inst = !cast<Instruction>(NAME);
6522  defvar InstPre = !cast<Instruction>(NAME # "_pre");
6523
6524  foreach DVTI = DVTIs in {
6525    def : Pat<(int_arm_mve_vstr_scatter_base
6526                (AVTI.Vec MQPR:$addr), (i32 imm:$offset), (DVTI.Vec MQPR:$data)),
6527              (Inst (DVTI.Vec MQPR:$data), (AVTI.Vec MQPR:$addr),
6528                    (i32 imm:$offset))>;
6529    def : Pat<(int_arm_mve_vstr_scatter_base_predicated
6530                (AVTI.Vec MQPR:$addr), (i32 imm:$offset), (DVTI.Vec MQPR:$data), (AVTI.Pred VCCR:$pred)),
6531              (Inst (DVTI.Vec MQPR:$data), (AVTI.Vec MQPR:$addr),
6532                    (i32 imm:$offset), ARMVCCThen, VCCR:$pred, zero_reg)>;
6533    def : Pat<(AVTI.Vec (int_arm_mve_vstr_scatter_base_wb
6534                (AVTI.Vec MQPR:$addr), (i32 imm:$offset), (DVTI.Vec MQPR:$data))),
6535              (AVTI.Vec (InstPre (DVTI.Vec MQPR:$data), (AVTI.Vec MQPR:$addr),
6536                                 (i32 imm:$offset)))>;
6537    def : Pat<(AVTI.Vec (int_arm_mve_vstr_scatter_base_wb_predicated
6538                (AVTI.Vec MQPR:$addr), (i32 imm:$offset), (DVTI.Vec MQPR:$data), (AVTI.Pred VCCR:$pred))),
6539              (AVTI.Vec (InstPre (DVTI.Vec MQPR:$data), (AVTI.Vec MQPR:$addr),
6540                                 (i32 imm:$offset), ARMVCCThen, VCCR:$pred, zero_reg))>;
6541  }
6542}
6543
6544// Actual instruction definitions.
6545defm MVE_VLDRWU32_qi: MVE_VLDR_qi<MVE_memW, MVE_v4i32, [MVE_v4i32,MVE_v4f32]>;
6546defm MVE_VLDRDU64_qi: MVE_VLDR_qi<MVE_memD, MVE_v2i64, [MVE_v2i64,MVE_v2f64]>;
6547defm MVE_VSTRW32_qi:  MVE_VSTR_qi<MVE_memW, MVE_v4i32, [MVE_v4i32,MVE_v4f32]>;
6548defm MVE_VSTRD64_qi:  MVE_VSTR_qi<MVE_memD, MVE_v2i64, [MVE_v2i64,MVE_v2f64]>;
6549
6550// Define aliases for all the instructions where memory size and
6551// vector lane size are the same. These are mnemonic aliases, so they
6552// apply consistently across all of the above families - contiguous
6553// loads, and both the rq and qi types of gather/scatter.
6554//
6555// Rationale: As long as you're loading (for example) 16-bit memory
6556// values into 16-bit vector lanes, you can think of them as signed or
6557// unsigned integers, fp16 or just raw 16-bit blobs and it makes no
6558// difference. So we permit all of vldrh.16, vldrh.u16, vldrh.s16,
6559// vldrh.f16 and treat them all as equivalent to the canonical
6560// spelling (which happens to be .u16 for loads, and just .16 for
6561// stores).
6562
6563foreach vpt_cond = ["", "t", "e"] in
6564foreach memsz = [MVE_memB, MVE_memH, MVE_memW, MVE_memD] in
6565foreach suffix = memsz.suffixes in {
6566  // Define an alias with every suffix in the list, except for the one
6567  // used by the real Instruction record (i.e. the one that all the
6568  // rest are aliases *for*).
6569
6570  if !ne(suffix, memsz.CanonLoadSuffix) then {
6571    def : MnemonicAlias<
6572      "vldr" # memsz.MnemonicLetter # vpt_cond # suffix,
6573      "vldr" # memsz.MnemonicLetter # vpt_cond # memsz.CanonLoadSuffix>;
6574  }
6575
6576  if !ne(suffix, memsz.CanonStoreSuffix) then {
6577    def : MnemonicAlias<
6578      "vstr" # memsz.MnemonicLetter # vpt_cond # suffix,
6579      "vstr" # memsz.MnemonicLetter # vpt_cond # memsz.CanonStoreSuffix>;
6580  }
6581}
6582
6583// end of MVE predicable load/store
6584
6585class MVE_VPT<string suffix, bits<2> size, dag iops, string asm, list<dag> pattern=[]>
6586  : MVE_MI<(outs ), iops, NoItinerary, !strconcat("vpt", "${Mk}", ".", suffix), asm, "", size, pattern> {
6587  bits<3> fc;
6588  bits<4> Mk;
6589  bits<3> Qn;
6590
6591  let Inst{31-23} = 0b111111100;
6592  let Inst{22} = Mk{3};
6593  let Inst{21-20} = size;
6594  let Inst{19-17} = Qn{2-0};
6595  let Inst{16} = 0b1;
6596  let Inst{15-13} = Mk{2-0};
6597  let Inst{12} = fc{2};
6598  let Inst{11-8} = 0b1111;
6599  let Inst{7} = fc{0};
6600  let Inst{4} = 0b0;
6601
6602  let Defs = [VPR];
6603  let validForTailPredication=1;
6604}
6605
6606class MVE_VPTt1<string suffix, bits<2> size, dag iops>
6607  : MVE_VPT<suffix, size, iops, "$fc, $Qn, $Qm"> {
6608  bits<4> Qm;
6609  bits<4> Mk;
6610
6611  let Inst{6} = 0b0;
6612  let Inst{5} = Qm{3};
6613  let Inst{3-1} = Qm{2-0};
6614  let Inst{0} = fc{1};
6615}
6616
6617class MVE_VPTt1i<string suffix, bits<2> size>
6618 : MVE_VPTt1<suffix, size,
6619           (ins vpt_mask:$Mk, MQPR:$Qn, MQPR:$Qm, pred_basic_i:$fc)> {
6620  let Inst{12} = 0b0;
6621  let Inst{0} = 0b0;
6622}
6623
6624def MVE_VPTv4i32 : MVE_VPTt1i<"i32", 0b10>;
6625def MVE_VPTv8i16 : MVE_VPTt1i<"i16", 0b01>;
6626def MVE_VPTv16i8 : MVE_VPTt1i<"i8", 0b00>;
6627
6628class MVE_VPTt1u<string suffix, bits<2> size>
6629 : MVE_VPTt1<suffix, size,
6630           (ins vpt_mask:$Mk, MQPR:$Qn, MQPR:$Qm, pred_basic_u:$fc)> {
6631  let Inst{12} = 0b0;
6632  let Inst{0} = 0b1;
6633}
6634
6635def MVE_VPTv4u32 : MVE_VPTt1u<"u32", 0b10>;
6636def MVE_VPTv8u16 : MVE_VPTt1u<"u16", 0b01>;
6637def MVE_VPTv16u8 : MVE_VPTt1u<"u8", 0b00>;
6638
6639class MVE_VPTt1s<string suffix, bits<2> size>
6640 : MVE_VPTt1<suffix, size,
6641           (ins vpt_mask:$Mk, MQPR:$Qn, MQPR:$Qm, pred_basic_s:$fc)> {
6642  let Inst{12} = 0b1;
6643}
6644
6645def MVE_VPTv4s32 : MVE_VPTt1s<"s32", 0b10>;
6646def MVE_VPTv8s16 : MVE_VPTt1s<"s16", 0b01>;
6647def MVE_VPTv16s8 : MVE_VPTt1s<"s8", 0b00>;
6648
6649class MVE_VPTt2<string suffix, bits<2> size, dag iops>
6650  : MVE_VPT<suffix, size, iops,
6651          "$fc, $Qn, $Rm"> {
6652  bits<4> Rm;
6653  bits<3> fc;
6654  bits<4> Mk;
6655
6656  let Inst{6} = 0b1;
6657  let Inst{5} = fc{1};
6658  let Inst{3-0} = Rm{3-0};
6659}
6660
6661class MVE_VPTt2i<string suffix, bits<2> size>
6662  : MVE_VPTt2<suffix, size,
6663            (ins vpt_mask:$Mk, MQPR:$Qn, GPRwithZR:$Rm, pred_basic_i:$fc)> {
6664  let Inst{12} = 0b0;
6665  let Inst{5} = 0b0;
6666}
6667
6668def MVE_VPTv4i32r : MVE_VPTt2i<"i32", 0b10>;
6669def MVE_VPTv8i16r : MVE_VPTt2i<"i16", 0b01>;
6670def MVE_VPTv16i8r : MVE_VPTt2i<"i8", 0b00>;
6671
6672class MVE_VPTt2u<string suffix, bits<2> size>
6673  : MVE_VPTt2<suffix, size,
6674            (ins vpt_mask:$Mk, MQPR:$Qn, GPRwithZR:$Rm, pred_basic_u:$fc)> {
6675  let Inst{12} = 0b0;
6676  let Inst{5} = 0b1;
6677}
6678
6679def MVE_VPTv4u32r : MVE_VPTt2u<"u32", 0b10>;
6680def MVE_VPTv8u16r : MVE_VPTt2u<"u16", 0b01>;
6681def MVE_VPTv16u8r : MVE_VPTt2u<"u8", 0b00>;
6682
6683class MVE_VPTt2s<string suffix, bits<2> size>
6684  : MVE_VPTt2<suffix, size,
6685            (ins vpt_mask:$Mk, MQPR:$Qn, GPRwithZR:$Rm, pred_basic_s:$fc)> {
6686  let Inst{12} = 0b1;
6687}
6688
6689def MVE_VPTv4s32r : MVE_VPTt2s<"s32", 0b10>;
6690def MVE_VPTv8s16r : MVE_VPTt2s<"s16", 0b01>;
6691def MVE_VPTv16s8r : MVE_VPTt2s<"s8", 0b00>;
6692
6693
6694class MVE_VPTf<string suffix, bit size, dag iops, string asm, list<dag> pattern=[]>
6695  : MVE_MI<(outs ), iops, NoItinerary, !strconcat("vpt", "${Mk}", ".", suffix), asm,
6696            "", !if(size, 0b01, 0b10), pattern> {
6697  bits<3> fc;
6698  bits<4> Mk;
6699  bits<3> Qn;
6700
6701  let Inst{31-29} = 0b111;
6702  let Inst{28} = size;
6703  let Inst{27-23} = 0b11100;
6704  let Inst{22} = Mk{3};
6705  let Inst{21-20} = 0b11;
6706  let Inst{19-17} = Qn{2-0};
6707  let Inst{16} = 0b1;
6708  let Inst{15-13} = Mk{2-0};
6709  let Inst{12} = fc{2};
6710  let Inst{11-8} = 0b1111;
6711  let Inst{7} = fc{0};
6712  let Inst{4} = 0b0;
6713
6714  let Defs = [VPR];
6715  let Predicates = [HasMVEFloat];
6716  let validForTailPredication=1;
6717}
6718
6719class MVE_VPTft1<string suffix, bit size>
6720  : MVE_VPTf<suffix, size, (ins vpt_mask:$Mk, MQPR:$Qn, MQPR:$Qm, pred_basic_fp:$fc),
6721          "$fc, $Qn, $Qm"> {
6722  bits<3> fc;
6723  bits<4> Qm;
6724
6725  let Inst{6} = 0b0;
6726  let Inst{5} = Qm{3};
6727  let Inst{3-1} = Qm{2-0};
6728  let Inst{0} = fc{1};
6729}
6730
6731def MVE_VPTv4f32         : MVE_VPTft1<"f32", 0b0>;
6732def MVE_VPTv8f16         : MVE_VPTft1<"f16", 0b1>;
6733
6734class MVE_VPTft2<string suffix, bit size>
6735  : MVE_VPTf<suffix, size, (ins vpt_mask:$Mk, MQPR:$Qn, GPRwithZR:$Rm, pred_basic_fp:$fc),
6736          "$fc, $Qn, $Rm"> {
6737  bits<3> fc;
6738  bits<4> Rm;
6739
6740  let Inst{6} = 0b1;
6741  let Inst{5} = fc{1};
6742  let Inst{3-0} = Rm{3-0};
6743}
6744
6745def MVE_VPTv4f32r        : MVE_VPTft2<"f32", 0b0>;
6746def MVE_VPTv8f16r        : MVE_VPTft2<"f16", 0b1>;
6747
6748def MVE_VPST : MVE_MI<(outs ), (ins vpt_mask:$Mk), NoItinerary,
6749       !strconcat("vpst", "${Mk}"), "", "", 0b00, []> {
6750  bits<4> Mk;
6751
6752  let Inst{31-23} = 0b111111100;
6753  let Inst{22} = Mk{3};
6754  let Inst{21-16} = 0b110001;
6755  let Inst{15-13} = Mk{2-0};
6756  let Inst{12-0} = 0b0111101001101;
6757  let Unpredictable{12} = 0b1;
6758  let Unpredictable{7} = 0b1;
6759  let Unpredictable{5} = 0b1;
6760
6761  let Uses = [VPR];
6762  let validForTailPredication = 1;
6763}
6764
6765def MVE_VPSEL : MVE_p<(outs MQPR:$Qd), (ins MQPR:$Qn, MQPR:$Qm), NoItinerary,
6766                      "vpsel", "", "$Qd, $Qn, $Qm", vpred_n, "", 0b00, []> {
6767  bits<4> Qn;
6768  bits<4> Qd;
6769  bits<4> Qm;
6770
6771  let Inst{28} = 0b1;
6772  let Inst{25-23} = 0b100;
6773  let Inst{22} = Qd{3};
6774  let Inst{21-20} = 0b11;
6775  let Inst{19-17} = Qn{2-0};
6776  let Inst{16} = 0b1;
6777  let Inst{15-13} = Qd{2-0};
6778  let Inst{12-9} = 0b0111;
6779  let Inst{8} = 0b1;
6780  let Inst{7} = Qn{3};
6781  let Inst{6} = 0b0;
6782  let Inst{5} = Qm{3};
6783  let Inst{4} = 0b0;
6784  let Inst{3-1} = Qm{2-0};
6785  let Inst{0} = 0b1;
6786}
6787
6788foreach suffix = ["s8", "s16", "s32", "u8", "u16", "u32",
6789                  "i8", "i16", "i32",       "f16", "f32"] in
6790def : MVEInstAlias<"vpsel${vp}." # suffix # "\t$Qd, $Qn, $Qm",
6791                   (MVE_VPSEL MQPR:$Qd, MQPR:$Qn, MQPR:$Qm, vpred_n:$vp)>;
6792
6793let Predicates = [HasMVEInt] in {
6794  def : Pat<(v16i8 (vselect (v16i1 VCCR:$pred), (v16i8 MQPR:$v1), (v16i8 MQPR:$v2))),
6795            (v16i8 (MVE_VPSEL MQPR:$v1, MQPR:$v2, ARMVCCNone, VCCR:$pred, zero_reg))>;
6796  def : Pat<(v8i16 (vselect (v8i1 VCCR:$pred), (v8i16 MQPR:$v1), (v8i16 MQPR:$v2))),
6797            (v8i16 (MVE_VPSEL MQPR:$v1, MQPR:$v2, ARMVCCNone, VCCR:$pred, zero_reg))>;
6798  def : Pat<(v4i32 (vselect (v4i1 VCCR:$pred), (v4i32 MQPR:$v1), (v4i32 MQPR:$v2))),
6799            (v4i32 (MVE_VPSEL MQPR:$v1, MQPR:$v2, ARMVCCNone, VCCR:$pred, zero_reg))>;
6800  def : Pat<(v2i64 (vselect (v2i1 VCCR:$pred), (v2i64 MQPR:$v1), (v2i64 MQPR:$v2))),
6801            (v2i64 (MVE_VPSEL MQPR:$v1, MQPR:$v2, ARMVCCNone, VCCR:$pred, zero_reg))>;
6802
6803  def : Pat<(v8f16 (vselect (v8i1 VCCR:$pred), (v8f16 MQPR:$v1), (v8f16 MQPR:$v2))),
6804            (v8f16 (MVE_VPSEL MQPR:$v1, MQPR:$v2, ARMVCCNone, VCCR:$pred, zero_reg))>;
6805  def : Pat<(v4f32 (vselect (v4i1 VCCR:$pred), (v4f32 MQPR:$v1), (v4f32 MQPR:$v2))),
6806            (v4f32 (MVE_VPSEL MQPR:$v1, MQPR:$v2, ARMVCCNone, VCCR:$pred, zero_reg))>;
6807  def : Pat<(v2f64 (vselect (v2i1 VCCR:$pred), (v2f64 MQPR:$v1), (v2f64 MQPR:$v2))),
6808            (v2f64 (MVE_VPSEL MQPR:$v1, MQPR:$v2, ARMVCCNone, VCCR:$pred, zero_reg))>;
6809
6810  def : Pat<(v16i8 (vselect (v16i8 MQPR:$pred), (v16i8 MQPR:$v1), (v16i8 MQPR:$v2))),
6811            (v16i8 (MVE_VPSEL MQPR:$v1, MQPR:$v2, ARMVCCNone,
6812                              (MVE_VCMPi8 (v16i8 MQPR:$pred), (MVE_VMOVimmi8 0), ARMCCne), zero_reg))>;
6813  def : Pat<(v8i16 (vselect (v8i16 MQPR:$pred), (v8i16 MQPR:$v1), (v8i16 MQPR:$v2))),
6814            (v8i16 (MVE_VPSEL MQPR:$v1, MQPR:$v2, ARMVCCNone,
6815                              (MVE_VCMPi16 (v8i16 MQPR:$pred), (MVE_VMOVimmi16 0), ARMCCne), zero_reg))>;
6816  def : Pat<(v4i32 (vselect (v4i32 MQPR:$pred), (v4i32 MQPR:$v1), (v4i32 MQPR:$v2))),
6817            (v4i32 (MVE_VPSEL MQPR:$v1, MQPR:$v2, ARMVCCNone,
6818                              (MVE_VCMPi32 (v4i32 MQPR:$pred), (MVE_VMOVimmi32 0), ARMCCne), zero_reg))>;
6819
6820  def : Pat<(v8f16 (vselect (v8i16 MQPR:$pred), (v8f16 MQPR:$v1), (v8f16 MQPR:$v2))),
6821            (v8f16 (MVE_VPSEL MQPR:$v1, MQPR:$v2, ARMVCCNone,
6822                              (MVE_VCMPi16 (v8i16 MQPR:$pred), (MVE_VMOVimmi16 0), ARMCCne), zero_reg))>;
6823  def : Pat<(v4f32 (vselect (v4i32 MQPR:$pred), (v4f32 MQPR:$v1), (v4f32 MQPR:$v2))),
6824            (v4f32 (MVE_VPSEL MQPR:$v1, MQPR:$v2, ARMVCCNone,
6825                              (MVE_VCMPi32 (v4i32 MQPR:$pred), (MVE_VMOVimmi32 0), ARMCCne), zero_reg))>;
6826
6827  // Pred <-> Int
6828  def : Pat<(v16i8 (zext  (v16i1 VCCR:$pred))),
6829            (v16i8 (MVE_VPSEL (MVE_VMOVimmi8 1), (MVE_VMOVimmi8 0), ARMVCCNone, VCCR:$pred, zero_reg))>;
6830  def : Pat<(v8i16 (zext  (v8i1  VCCR:$pred))),
6831            (v8i16 (MVE_VPSEL (MVE_VMOVimmi16 1), (MVE_VMOVimmi16 0), ARMVCCNone, VCCR:$pred, zero_reg))>;
6832  def : Pat<(v4i32 (zext  (v4i1  VCCR:$pred))),
6833            (v4i32 (MVE_VPSEL (MVE_VMOVimmi32 1), (MVE_VMOVimmi32 0), ARMVCCNone, VCCR:$pred, zero_reg))>;
6834  def : Pat<(v2i64 (zext  (v2i1  VCCR:$pred))),
6835            (v2i64 (MVE_VPSEL (MVE_VMOVimmi64 1), (MVE_VMOVimmi32 0), ARMVCCNone, VCCR:$pred, zero_reg))>;
6836
6837  def : Pat<(v16i8 (sext  (v16i1 VCCR:$pred))),
6838            (v16i8 (MVE_VPSEL (MVE_VMOVimmi8 255), (MVE_VMOVimmi8 0), ARMVCCNone, VCCR:$pred, zero_reg))>;
6839  def : Pat<(v8i16 (sext  (v8i1  VCCR:$pred))),
6840            (v8i16 (MVE_VPSEL (MVE_VMOVimmi8 255), (MVE_VMOVimmi16 0), ARMVCCNone, VCCR:$pred, zero_reg))>;
6841  def : Pat<(v4i32 (sext  (v4i1  VCCR:$pred))),
6842            (v4i32 (MVE_VPSEL (MVE_VMOVimmi8 255), (MVE_VMOVimmi32 0), ARMVCCNone, VCCR:$pred, zero_reg))>;
6843  def : Pat<(v2i64 (sext  (v2i1  VCCR:$pred))),
6844            (v2i64 (MVE_VPSEL (MVE_VMOVimmi8 255), (MVE_VMOVimmi32 0), ARMVCCNone, VCCR:$pred, zero_reg))>;
6845
6846  def : Pat<(v16i8 (anyext  (v16i1 VCCR:$pred))),
6847            (v16i8 (MVE_VPSEL (MVE_VMOVimmi8 1), (MVE_VMOVimmi8 0), ARMVCCNone, VCCR:$pred, zero_reg))>;
6848  def : Pat<(v8i16 (anyext  (v8i1  VCCR:$pred))),
6849            (v8i16 (MVE_VPSEL (MVE_VMOVimmi16 1), (MVE_VMOVimmi16 0), ARMVCCNone, VCCR:$pred, zero_reg))>;
6850  def : Pat<(v4i32 (anyext  (v4i1  VCCR:$pred))),
6851            (v4i32 (MVE_VPSEL (MVE_VMOVimmi32 1), (MVE_VMOVimmi32 0), ARMVCCNone, VCCR:$pred, zero_reg))>;
6852  def : Pat<(v2i64 (anyext  (v2i1  VCCR:$pred))),
6853            (v2i64 (MVE_VPSEL (MVE_VMOVimmi64 1), (MVE_VMOVimmi32 0), ARMVCCNone, VCCR:$pred, zero_reg))>;
6854}
6855
6856let Predicates = [HasMVEFloat] in {
6857  // Pred <-> Float
6858  // 112 is 1.0 in float
6859  def : Pat<(v4f32 (uint_to_fp (v4i1 VCCR:$pred))),
6860            (v4f32 (MVE_VPSEL (v4f32 (MVE_VMOVimmf32 112)), (v4f32 (MVE_VMOVimmi32 0)), ARMVCCNone, VCCR:$pred, zero_reg))>;
6861  // 2620 in 1.0 in half
6862  def : Pat<(v8f16 (uint_to_fp (v8i1 VCCR:$pred))),
6863            (v8f16 (MVE_VPSEL (v8f16 (MVE_VMOVimmi16 2620)), (v8f16 (MVE_VMOVimmi16 0)), ARMVCCNone, VCCR:$pred, zero_reg))>;
6864  // 240 is -1.0 in float
6865  def : Pat<(v4f32 (sint_to_fp (v4i1 VCCR:$pred))),
6866            (v4f32 (MVE_VPSEL (v4f32 (MVE_VMOVimmf32 240)), (v4f32 (MVE_VMOVimmi32 0)), ARMVCCNone, VCCR:$pred, zero_reg))>;
6867  // 2748 is -1.0 in half
6868  def : Pat<(v8f16 (sint_to_fp (v8i1 VCCR:$pred))),
6869            (v8f16 (MVE_VPSEL (v8f16 (MVE_VMOVimmi16 2748)), (v8f16 (MVE_VMOVimmi16 0)), ARMVCCNone, VCCR:$pred, zero_reg))>;
6870
6871  def : Pat<(v4i1 (fp_to_uint (v4f32 MQPR:$v1))),
6872            (v4i1 (MVE_VCMPf32r (v4f32 MQPR:$v1), ZR, ARMCCne))>;
6873  def : Pat<(v8i1 (fp_to_uint (v8f16 MQPR:$v1))),
6874            (v8i1 (MVE_VCMPf16r (v8f16 MQPR:$v1), ZR, ARMCCne))>;
6875  def : Pat<(v4i1 (fp_to_sint (v4f32 MQPR:$v1))),
6876            (v4i1 (MVE_VCMPf32r (v4f32 MQPR:$v1), ZR, ARMCCne))>;
6877  def : Pat<(v8i1 (fp_to_sint (v8f16 MQPR:$v1))),
6878            (v8i1 (MVE_VCMPf16r (v8f16 MQPR:$v1), ZR, ARMCCne))>;
6879}
6880
6881def MVE_VPNOT : MVE_p<(outs VCCR:$P0), (ins VCCR:$P0_in), NoItinerary,
6882                      "vpnot", "", "", vpred_n, "", 0b00, []> {
6883  let Inst{31-0} = 0b11111110001100010000111101001101;
6884  let Unpredictable{19-17} = 0b111;
6885  let Unpredictable{12} = 0b1;
6886  let Unpredictable{7} = 0b1;
6887  let Unpredictable{5} = 0b1;
6888
6889  let Constraints = "";
6890  let DecoderMethod = "DecodeMVEVPNOT";
6891}
6892
6893let Predicates = [HasMVEInt] in {
6894  def : Pat<(v2i1 (xor (v2i1 VCCR:$pred), (v2i1 (predicate_cast (i32 65535))))),
6895            (v2i1 (MVE_VPNOT (v2i1 VCCR:$pred)))>;
6896  def : Pat<(v4i1 (xor (v4i1 VCCR:$pred), (v4i1 (predicate_cast (i32 65535))))),
6897            (v4i1 (MVE_VPNOT (v4i1 VCCR:$pred)))>;
6898  def : Pat<(v8i1 (xor (v8i1 VCCR:$pred), (v8i1 (predicate_cast (i32 65535))))),
6899            (v8i1 (MVE_VPNOT (v8i1 VCCR:$pred)))>;
6900  def : Pat<(v16i1 (xor (v16i1 VCCR:$pred), (v16i1 (predicate_cast (i32 65535))))),
6901            (v16i1 (MVE_VPNOT (v16i1 VCCR:$pred)))>;
6902}
6903
6904
6905class MVE_loltp_start<dag iops, string asm, string ops, bits<2> size>
6906  : t2LOL<(outs GPRlr:$LR), iops, asm, ops> {
6907  bits<4> Rn;
6908  let Predicates = [HasMVEInt];
6909  let Inst{22} = 0b0;
6910  let Inst{21-20} = size;
6911  let Inst{19-16} = Rn{3-0};
6912  let Inst{12} = 0b0;
6913}
6914
6915class MVE_DLSTP<string asm, bits<2> size>
6916  : MVE_loltp_start<(ins rGPR:$Rn), asm, "$LR, $Rn", size> {
6917  let Inst{13} = 0b1;
6918  let Inst{11-1} = 0b00000000000;
6919  let Unpredictable{10-1} = 0b1111111111;
6920}
6921
6922class MVE_WLSTP<string asm, bits<2> size>
6923  : MVE_loltp_start<(ins rGPR:$Rn, wlslabel_u11:$label),
6924                    asm, "$LR, $Rn, $label", size> {
6925  bits<11> label;
6926  let Inst{13} = 0b0;
6927  let Inst{11} = label{0};
6928  let Inst{10-1} = label{10-1};
6929  let isBranch = 1;
6930  let isTerminator = 1;
6931}
6932
6933def SDT_MVEMEMCPYLOOPNODE
6934    : SDTypeProfile<0, 3, [SDTCisPtrTy<0>, SDTCisPtrTy<1>, SDTCisVT<2, i32>]>;
6935def MVE_MEMCPYLOOPNODE : SDNode<"ARMISD::MEMCPYLOOP", SDT_MVEMEMCPYLOOPNODE,
6936                                [SDNPHasChain, SDNPMayStore, SDNPMayLoad]>;
6937
6938let usesCustomInserter = 1, hasNoSchedulingInfo = 1, Defs = [CPSR] in {
6939  def MVE_MEMCPYLOOPINST : PseudoInst<(outs),
6940        (ins rGPR:$dst, rGPR:$src, rGPR:$sz),
6941        NoItinerary,
6942        [(MVE_MEMCPYLOOPNODE rGPR:$dst, rGPR:$src, rGPR:$sz)]>;
6943}
6944
6945def SDT_MVEMEMSETLOOPNODE
6946    : SDTypeProfile<0, 3, [SDTCisPtrTy<0>, SDTCisVT<1, v16i8>, SDTCisVT<2, i32>]>;
6947def MVE_MEMSETLOOPNODE : SDNode<"ARMISD::MEMSETLOOP", SDT_MVEMEMSETLOOPNODE,
6948                                [SDNPHasChain, SDNPMayStore, SDNPMayLoad]>;
6949
6950let usesCustomInserter = 1, hasNoSchedulingInfo = 1, Defs = [CPSR] in {
6951  def MVE_MEMSETLOOPINST : PseudoInst<(outs),
6952        (ins rGPR:$dst, MQPR:$src, rGPR:$sz),
6953        NoItinerary,
6954        [(MVE_MEMSETLOOPNODE rGPR:$dst, MQPR:$src, rGPR:$sz)]>;
6955}
6956
6957def MVE_DLSTP_8  : MVE_DLSTP<"dlstp.8",  0b00>;
6958def MVE_DLSTP_16 : MVE_DLSTP<"dlstp.16", 0b01>;
6959def MVE_DLSTP_32 : MVE_DLSTP<"dlstp.32", 0b10>;
6960def MVE_DLSTP_64 : MVE_DLSTP<"dlstp.64", 0b11>;
6961
6962def MVE_WLSTP_8  : MVE_WLSTP<"wlstp.8",  0b00>;
6963def MVE_WLSTP_16 : MVE_WLSTP<"wlstp.16", 0b01>;
6964def MVE_WLSTP_32 : MVE_WLSTP<"wlstp.32", 0b10>;
6965def MVE_WLSTP_64 : MVE_WLSTP<"wlstp.64", 0b11>;
6966
6967class MVE_loltp_end<dag oops, dag iops, string asm, string ops>
6968  : t2LOL<oops, iops, asm, ops> {
6969  let Predicates = [HasMVEInt];
6970  let Inst{22-21} = 0b00;
6971  let Inst{19-16} = 0b1111;
6972  let Inst{12} = 0b0;
6973}
6974
6975def MVE_LETP : MVE_loltp_end<(outs GPRlr:$LRout),
6976                             (ins GPRlr:$LRin, lelabel_u11:$label),
6977                             "letp", "$LRin, $label"> {
6978  bits<11> label;
6979  let Inst{20} = 0b1;
6980  let Inst{13} = 0b0;
6981  let Inst{11} = label{0};
6982  let Inst{10-1} = label{10-1};
6983  let isBranch = 1;
6984  let isTerminator = 1;
6985}
6986
6987def MVE_LCTP : MVE_loltp_end<(outs), (ins pred:$p), "lctp${p}", ""> {
6988  let Inst{20} = 0b0;
6989  let Inst{13} = 0b1;
6990  let Inst{11-1} = 0b00000000000;
6991  let Unpredictable{21-20} = 0b11;
6992  let Unpredictable{11-1} = 0b11111111111;
6993}
6994
6995
6996// Pseudo instructions for lowering MQQPR and MQQQQPR stack spills and reloads.
6997// They are equivalent to VLDMDIA/VSTMDIA with a single reg, as opposed to multiple
6998// dreg subregs.
6999
7000let Predicates = [HasMVEInt], AM = AddrMode4 in {
7001let mayStore = 1, hasSideEffects = 0 in {
7002  def MQQPRStore : t2PseudoInst<(outs), (ins MQQPR:$val, GPRnopc:$ptr),
7003                                4, NoItinerary, []>;
7004  def MQQQQPRStore : t2PseudoInst<(outs), (ins MQQQQPR:$val, GPRnopc:$ptr),
7005                                  4, NoItinerary, []>;
7006}
7007let mayLoad = 1, hasSideEffects = 0 in {
7008  def MQQPRLoad : t2PseudoInst<(outs MQQPR:$val), (ins GPRnopc:$ptr),
7009                               4, NoItinerary, []>;
7010  def MQQQQPRLoad : t2PseudoInst<(outs MQQQQPR:$val), (ins GPRnopc:$ptr),
7011                                 4, NoItinerary, []>;
7012}
7013}
7014
7015// Pseudo for lowering MVE Q register COPYs. These will usually get converted
7016// to a "MVE_VORR dst, src, src", but may behave differently in tail predicated
7017// loops to ensure the whole register is copied, not a subset from a
7018// tail-predicated MVE_VORR. In the event we cannot prove a MVE_VORR is valid,
7019// it will become a pair of VMOVD instructions for each half of the Q register.
7020let Predicates = [HasMVEInt], hasSideEffects = 0, isMoveReg = 1,
7021    D = MVEDomain in {
7022  def MQPRCopy : t2PseudoInst<(outs MQPR:$dst), (ins MQPR:$src),
7023                              8, NoItinerary, []>;
7024}
7025
7026
7027//===----------------------------------------------------------------------===//
7028// Patterns
7029//===----------------------------------------------------------------------===//
7030
7031// PatFrags for loads and stores. Often trying to keep semi-consistent names.
7032
7033def aligned32_pre_store : PatFrag<(ops node:$val, node:$ptr, node:$offset),
7034                                  (pre_store node:$val, node:$ptr, node:$offset), [{
7035  return cast<StoreSDNode>(N)->getAlign() >= 4;
7036}]>;
7037def aligned32_post_store : PatFrag<(ops node:$val, node:$ptr, node:$offset),
7038                                   (post_store node:$val, node:$ptr, node:$offset), [{
7039  return cast<StoreSDNode>(N)->getAlign() >= 4;
7040}]>;
7041def aligned16_pre_store : PatFrag<(ops node:$val, node:$ptr, node:$offset),
7042                                  (pre_store node:$val, node:$ptr, node:$offset), [{
7043  return cast<StoreSDNode>(N)->getAlign() >= 2;
7044}]>;
7045def aligned16_post_store : PatFrag<(ops node:$val, node:$ptr, node:$offset),
7046                                   (post_store node:$val, node:$ptr, node:$offset), [{
7047  return cast<StoreSDNode>(N)->getAlign() >= 2;
7048}]>;
7049
7050
7051def aligned_maskedloadvi8 : PatFrag<(ops node:$ptr, node:$pred, node:$passthru),
7052                                    (masked_ld node:$ptr, undef, node:$pred, node:$passthru), [{
7053  auto *Ld = cast<MaskedLoadSDNode>(N);
7054  return Ld->getMemoryVT().getScalarType() == MVT::i8;
7055}]>;
7056def aligned_sextmaskedloadvi8 : PatFrag<(ops node:$ptr, node:$pred, node:$passthru),
7057                                        (aligned_maskedloadvi8 node:$ptr, node:$pred, node:$passthru), [{
7058  return cast<MaskedLoadSDNode>(N)->getExtensionType() == ISD::SEXTLOAD;
7059}]>;
7060def aligned_zextmaskedloadvi8 : PatFrag<(ops node:$ptr, node:$pred, node:$passthru),
7061                                        (aligned_maskedloadvi8 node:$ptr, node:$pred, node:$passthru), [{
7062  return cast<MaskedLoadSDNode>(N)->getExtensionType() == ISD::ZEXTLOAD;
7063}]>;
7064def aligned_extmaskedloadvi8 : PatFrag<(ops node:$ptr, node:$pred, node:$passthru),
7065                                       (aligned_maskedloadvi8 node:$ptr, node:$pred, node:$passthru), [{
7066  auto *Ld = cast<MaskedLoadSDNode>(N);
7067  EVT ScalarVT = Ld->getMemoryVT().getScalarType();
7068  return ScalarVT.isInteger() && Ld->getExtensionType() == ISD::EXTLOAD;
7069}]>;
7070def aligned_maskedloadvi16: PatFrag<(ops node:$ptr, node:$pred, node:$passthru),
7071                                    (masked_ld node:$ptr, undef, node:$pred, node:$passthru), [{
7072  auto *Ld = cast<MaskedLoadSDNode>(N);
7073  EVT ScalarVT = Ld->getMemoryVT().getScalarType();
7074  return (ScalarVT == MVT::i16 || ScalarVT == MVT::f16) && Ld->getAlign() >= 2;
7075}]>;
7076def aligned_sextmaskedloadvi16 : PatFrag<(ops node:$ptr, node:$pred, node:$passthru),
7077                                         (aligned_maskedloadvi16 node:$ptr, node:$pred, node:$passthru), [{
7078  return cast<MaskedLoadSDNode>(N)->getExtensionType() == ISD::SEXTLOAD;
7079}]>;
7080def aligned_zextmaskedloadvi16 : PatFrag<(ops node:$ptr, node:$pred, node:$passthru),
7081                                         (aligned_maskedloadvi16 node:$ptr, node:$pred, node:$passthru), [{
7082  return cast<MaskedLoadSDNode>(N)->getExtensionType() == ISD::ZEXTLOAD;
7083}]>;
7084def aligned_extmaskedloadvi16 : PatFrag<(ops node:$ptr, node:$pred, node:$passthru),
7085                                        (aligned_maskedloadvi16 node:$ptr, node:$pred, node:$passthru), [{
7086  auto *Ld = cast<MaskedLoadSDNode>(N);
7087  EVT ScalarVT = Ld->getMemoryVT().getScalarType();
7088  return ScalarVT.isInteger() && Ld->getExtensionType() == ISD::EXTLOAD;
7089}]>;
7090def aligned_maskedloadvi32: PatFrag<(ops node:$ptr, node:$pred, node:$passthru),
7091                                    (masked_ld node:$ptr, undef, node:$pred, node:$passthru), [{
7092  auto *Ld = cast<MaskedLoadSDNode>(N);
7093  EVT ScalarVT = Ld->getMemoryVT().getScalarType();
7094  return (ScalarVT == MVT::i32 || ScalarVT == MVT::f32) && Ld->getAlign() >= 4;
7095}]>;
7096
7097def aligned_maskedstvi8 : PatFrag<(ops node:$val, node:$ptr, node:$pred),
7098                                  (masked_st node:$val, node:$ptr, undef, node:$pred), [{
7099  return cast<MaskedStoreSDNode>(N)->getMemoryVT().getScalarType() == MVT::i8;
7100}]>;
7101def aligned_maskedstvi16 : PatFrag<(ops node:$val, node:$ptr, node:$pred),
7102                                   (masked_st node:$val, node:$ptr, undef, node:$pred), [{
7103  auto *St = cast<MaskedStoreSDNode>(N);
7104  EVT ScalarVT = St->getMemoryVT().getScalarType();
7105  return (ScalarVT == MVT::i16 || ScalarVT == MVT::f16) && St->getAlign() >= 2;
7106}]>;
7107def aligned_maskedstvi32 : PatFrag<(ops node:$val, node:$ptr, node:$pred),
7108                                   (masked_st node:$val, node:$ptr, undef, node:$pred), [{
7109  auto *St = cast<MaskedStoreSDNode>(N);
7110  EVT ScalarVT = St->getMemoryVT().getScalarType();
7111  return (ScalarVT == MVT::i32 || ScalarVT == MVT::f32) && St->getAlign() >= 4;
7112}]>;
7113
7114def pre_maskedstore : PatFrag<(ops node:$val, node:$base, node:$offset, node:$mask),
7115                              (masked_st node:$val, node:$base, node:$offset, node:$mask), [{
7116  ISD::MemIndexedMode AM = cast<MaskedStoreSDNode>(N)->getAddressingMode();
7117  return AM == ISD::PRE_INC || AM == ISD::PRE_DEC;
7118}]>;
7119def post_maskedstore : PatFrag<(ops node:$val, node:$base, node:$offset, node:$mask),
7120                               (masked_st node:$val, node:$base, node:$offset, node:$mask), [{
7121  ISD::MemIndexedMode AM = cast<MaskedStoreSDNode>(N)->getAddressingMode();
7122  return AM == ISD::POST_INC || AM == ISD::POST_DEC;
7123}]>;
7124def aligned_pre_maskedstorevi8 : PatFrag<(ops node:$val, node:$ptr, node:$offset, node:$mask),
7125                                         (pre_maskedstore node:$val, node:$ptr, node:$offset, node:$mask), [{
7126  return cast<MaskedStoreSDNode>(N)->getMemoryVT().getScalarType() == MVT::i8;
7127}]>;
7128def aligned_post_maskedstorevi8 : PatFrag<(ops node:$val, node:$ptr, node:$offset, node:$mask),
7129                                          (post_maskedstore node:$val, node:$ptr, node:$offset, node:$mask), [{
7130  return cast<MaskedStoreSDNode>(N)->getMemoryVT().getScalarType() == MVT::i8;
7131}]>;
7132def aligned_pre_maskedstorevi16 : PatFrag<(ops node:$val, node:$ptr, node:$offset, node:$mask),
7133                                          (pre_maskedstore node:$val, node:$ptr, node:$offset, node:$mask), [{
7134  auto *St = cast<MaskedStoreSDNode>(N);
7135  EVT ScalarVT = St->getMemoryVT().getScalarType();
7136  return (ScalarVT == MVT::i16 || ScalarVT == MVT::f16) && St->getAlign() >= 2;
7137}]>;
7138def aligned_post_maskedstorevi16 : PatFrag<(ops node:$val, node:$ptr, node:$offset, node:$mask),
7139                                           (post_maskedstore node:$val, node:$ptr, node:$offset, node:$mask), [{
7140  auto *St = cast<MaskedStoreSDNode>(N);
7141  EVT ScalarVT = St->getMemoryVT().getScalarType();
7142  return (ScalarVT == MVT::i16 || ScalarVT == MVT::f16) && St->getAlign() >= 2;
7143}]>;
7144def aligned_pre_maskedstorevi32 : PatFrag<(ops node:$val, node:$ptr, node:$offset, node:$mask),
7145                                          (pre_maskedstore node:$val, node:$ptr, node:$offset, node:$mask), [{
7146  auto *St = cast<MaskedStoreSDNode>(N);
7147  EVT ScalarVT = St->getMemoryVT().getScalarType();
7148  return (ScalarVT == MVT::i32 || ScalarVT == MVT::f32) && St->getAlign() >= 4;
7149}]>;
7150def aligned_post_maskedstorevi32 : PatFrag<(ops node:$val, node:$ptr, node:$offset, node:$mask),
7151                                           (post_maskedstore node:$val, node:$ptr, node:$offset, node:$mask), [{
7152  auto *St = cast<MaskedStoreSDNode>(N);
7153  EVT ScalarVT = St->getMemoryVT().getScalarType();
7154  return (ScalarVT == MVT::i32 || ScalarVT == MVT::f32) && St->getAlign() >= 4;
7155}]>;
7156
7157
7158// PatFrags for "Aligned" extending / truncating
7159
7160def aligned_extloadvi8  : PatFrag<(ops node:$ptr), (extloadvi8 node:$ptr)>;
7161def aligned_sextloadvi8 : PatFrag<(ops node:$ptr), (sextloadvi8 node:$ptr)>;
7162def aligned_zextloadvi8 : PatFrag<(ops node:$ptr), (zextloadvi8 node:$ptr)>;
7163
7164def aligned_truncstvi8 : PatFrag<(ops node:$val, node:$ptr),
7165                                 (truncstorevi8 node:$val, node:$ptr)>;
7166def aligned_post_truncstvi8 : PatFrag<(ops node:$val, node:$base, node:$offset),
7167                                      (post_truncstvi8 node:$val, node:$base, node:$offset)>;
7168def aligned_pre_truncstvi8 : PatFrag<(ops node:$val, node:$base, node:$offset),
7169                                     (pre_truncstvi8 node:$val, node:$base, node:$offset)>;
7170
7171let MinAlignment = 2 in {
7172  def aligned_extloadvi16  : PatFrag<(ops node:$ptr), (extloadvi16 node:$ptr)>;
7173  def aligned_sextloadvi16 : PatFrag<(ops node:$ptr), (sextloadvi16 node:$ptr)>;
7174  def aligned_zextloadvi16 : PatFrag<(ops node:$ptr), (zextloadvi16 node:$ptr)>;
7175
7176  def aligned_truncstvi16 : PatFrag<(ops node:$val, node:$ptr),
7177                                    (truncstorevi16 node:$val, node:$ptr)>;
7178  def aligned_post_truncstvi16 : PatFrag<(ops node:$val, node:$base, node:$offset),
7179                                         (post_truncstvi16 node:$val, node:$base, node:$offset)>;
7180  def aligned_pre_truncstvi16 : PatFrag<(ops node:$val, node:$base, node:$offset),
7181                                        (pre_truncstvi16 node:$val, node:$base, node:$offset)>;
7182}
7183
7184def truncmaskedst : PatFrag<(ops node:$val, node:$base, node:$pred),
7185                            (masked_st node:$val, node:$base, undef, node:$pred), [{
7186  return cast<MaskedStoreSDNode>(N)->isTruncatingStore();
7187}]>;
7188def aligned_truncmaskedstvi8 : PatFrag<(ops node:$val, node:$base, node:$pred),
7189                                       (truncmaskedst node:$val, node:$base, node:$pred), [{
7190  return cast<MaskedStoreSDNode>(N)->getMemoryVT().getScalarType() == MVT::i8;
7191}]>;
7192def aligned_truncmaskedstvi16 : PatFrag<(ops node:$val, node:$base, node:$pred),
7193                                        (truncmaskedst node:$val, node:$base, node:$pred), [{
7194  auto *St = cast<MaskedStoreSDNode>(N);
7195  EVT ScalarVT = St->getMemoryVT().getScalarType();
7196  return (ScalarVT == MVT::i16 || ScalarVT == MVT::f16) && St->getAlign() >= 2;
7197}]>;
7198def pre_truncmaskedst : PatFrag<(ops node:$val, node:$base, node:$offset, node:$pred),
7199                                (masked_st node:$val, node:$base, node:$offset, node:$pred), [{
7200  ISD::MemIndexedMode AM = cast<MaskedStoreSDNode>(N)->getAddressingMode();
7201  return cast<MaskedStoreSDNode>(N)->isTruncatingStore() && (AM == ISD::PRE_INC || AM == ISD::PRE_DEC);
7202}]>;
7203def aligned_pre_truncmaskedstvi8 : PatFrag<(ops node:$val, node:$base, node:$offset, node:$pred),
7204                                           (pre_truncmaskedst node:$val, node:$base, node:$offset, node:$pred), [{
7205  return cast<MaskedStoreSDNode>(N)->getMemoryVT().getScalarType() == MVT::i8;
7206}]>;
7207def aligned_pre_truncmaskedstvi16 : PatFrag<(ops node:$val, node:$base, node:$offset, node:$pred),
7208                                            (pre_truncmaskedst node:$val, node:$base, node:$offset, node:$pred), [{
7209  auto *St = cast<MaskedStoreSDNode>(N);
7210  EVT ScalarVT = St->getMemoryVT().getScalarType();
7211  return (ScalarVT == MVT::i16 || ScalarVT == MVT::f16) && St->getAlign() >= 2;
7212}]>;
7213def post_truncmaskedst : PatFrag<(ops node:$val, node:$base, node:$offset, node:$postd),
7214                                 (masked_st node:$val, node:$base, node:$offset, node:$postd), [{
7215  ISD::MemIndexedMode AM = cast<MaskedStoreSDNode>(N)->getAddressingMode();
7216  return cast<MaskedStoreSDNode>(N)->isTruncatingStore() && (AM == ISD::POST_INC || AM == ISD::POST_DEC);
7217}]>;
7218def aligned_post_truncmaskedstvi8 : PatFrag<(ops node:$val, node:$base, node:$offset, node:$postd),
7219                                            (post_truncmaskedst node:$val, node:$base, node:$offset, node:$postd), [{
7220  return cast<MaskedStoreSDNode>(N)->getMemoryVT().getScalarType() == MVT::i8;
7221}]>;
7222def aligned_post_truncmaskedstvi16 : PatFrag<(ops node:$val, node:$base, node:$offset, node:$postd),
7223                                             (post_truncmaskedst node:$val, node:$base, node:$offset, node:$postd), [{
7224  auto *St = cast<MaskedStoreSDNode>(N);
7225  EVT ScalarVT = St->getMemoryVT().getScalarType();
7226  return (ScalarVT == MVT::i16 || ScalarVT == MVT::f16) && St->getAlign() >= 2;
7227}]>;
7228
7229// Load/store patterns
7230
7231class MVE_vector_store_typed<ValueType Ty, Instruction RegImmInst,
7232                             PatFrag StoreKind, int shift>
7233  : Pat<(StoreKind (Ty MQPR:$val), t2addrmode_imm7<shift>:$addr),
7234        (RegImmInst (Ty MQPR:$val), t2addrmode_imm7<shift>:$addr)>;
7235
7236class MVE_vector_maskedstore_typed<ValueType Ty, Instruction RegImmInst,
7237                                   PatFrag StoreKind, int shift>
7238  : Pat<(StoreKind (Ty MQPR:$val), t2addrmode_imm7<shift>:$addr, VCCR:$pred),
7239        (RegImmInst (Ty MQPR:$val), t2addrmode_imm7<shift>:$addr, ARMVCCThen, VCCR:$pred, zero_reg)>;
7240
7241multiclass MVE_vector_store<Instruction RegImmInst, PatFrag StoreKind,
7242                            int shift> {
7243  def : MVE_vector_store_typed<v16i8, RegImmInst, StoreKind, shift>;
7244  def : MVE_vector_store_typed<v8i16, RegImmInst, StoreKind, shift>;
7245  def : MVE_vector_store_typed<v8f16, RegImmInst, StoreKind, shift>;
7246  def : MVE_vector_store_typed<v4i32, RegImmInst, StoreKind, shift>;
7247  def : MVE_vector_store_typed<v4f32, RegImmInst, StoreKind, shift>;
7248  def : MVE_vector_store_typed<v2i64, RegImmInst, StoreKind, shift>;
7249  def : MVE_vector_store_typed<v2f64, RegImmInst, StoreKind, shift>;
7250}
7251
7252class MVE_vector_load_typed<ValueType Ty, Instruction RegImmInst,
7253                            PatFrag LoadKind, int shift>
7254  : Pat<(Ty (LoadKind t2addrmode_imm7<shift>:$addr)),
7255        (Ty (RegImmInst t2addrmode_imm7<shift>:$addr))>;
7256
7257class MVE_vector_maskedload_typed<ValueType Ty, Instruction RegImmInst,
7258                                  PatFrag LoadKind, int shift>
7259  : Pat<(Ty (LoadKind t2addrmode_imm7<shift>:$addr, VCCR:$pred, (Ty (ARMvmovImm (i32 0))))),
7260        (Ty (RegImmInst t2addrmode_imm7<shift>:$addr, ARMVCCThen, VCCR:$pred, zero_reg))>;
7261
7262multiclass MVE_vector_load<Instruction RegImmInst, PatFrag LoadKind,
7263                           int shift> {
7264  def : MVE_vector_load_typed<v16i8, RegImmInst, LoadKind, shift>;
7265  def : MVE_vector_load_typed<v8i16, RegImmInst, LoadKind, shift>;
7266  def : MVE_vector_load_typed<v8f16, RegImmInst, LoadKind, shift>;
7267  def : MVE_vector_load_typed<v4i32, RegImmInst, LoadKind, shift>;
7268  def : MVE_vector_load_typed<v4f32, RegImmInst, LoadKind, shift>;
7269  def : MVE_vector_load_typed<v2i64, RegImmInst, LoadKind, shift>;
7270  def : MVE_vector_load_typed<v2f64, RegImmInst, LoadKind, shift>;
7271}
7272
7273class MVE_vector_offset_store_typed<ValueType Ty, Instruction Opcode,
7274                                    PatFrag StoreKind, int shift>
7275  : Pat<(StoreKind (Ty MQPR:$Rt), tGPR:$Rn, t2am_imm7_offset<shift>:$addr),
7276        (Opcode MQPR:$Rt, tGPR:$Rn, t2am_imm7_offset<shift>:$addr)>;
7277
7278class MVE_vector_offset_maskedstore_typed<ValueType Ty, Instruction Opcode,
7279                                          PatFrag StoreKind, int shift>
7280  : Pat<(StoreKind (Ty MQPR:$Rt), tGPR:$Rn, t2am_imm7_offset<shift>:$addr, VCCR:$pred),
7281        (Opcode MQPR:$Rt, tGPR:$Rn, t2am_imm7_offset<shift>:$addr, ARMVCCThen, VCCR:$pred, zero_reg)>;
7282
7283multiclass MVE_vector_offset_store<Instruction RegImmInst, PatFrag StoreKind,
7284                                   int shift> {
7285  def : MVE_vector_offset_store_typed<v16i8, RegImmInst, StoreKind, shift>;
7286  def : MVE_vector_offset_store_typed<v8i16, RegImmInst, StoreKind, shift>;
7287  def : MVE_vector_offset_store_typed<v8f16, RegImmInst, StoreKind, shift>;
7288  def : MVE_vector_offset_store_typed<v4i32, RegImmInst, StoreKind, shift>;
7289  def : MVE_vector_offset_store_typed<v4f32, RegImmInst, StoreKind, shift>;
7290  def : MVE_vector_offset_store_typed<v2i64, RegImmInst, StoreKind, shift>;
7291  def : MVE_vector_offset_store_typed<v2f64, RegImmInst, StoreKind, shift>;
7292}
7293
7294
7295let Predicates = [HasMVEInt, IsLE] in {
7296  // Stores
7297  defm : MVE_vector_store<MVE_VSTRBU8, byte_alignedstore, 0>;
7298  defm : MVE_vector_store<MVE_VSTRHU16, hword_alignedstore, 1>;
7299  defm : MVE_vector_store<MVE_VSTRWU32, alignedstore32, 2>;
7300
7301  // Loads
7302  defm : MVE_vector_load<MVE_VLDRBU8, byte_alignedload, 0>;
7303  defm : MVE_vector_load<MVE_VLDRHU16, hword_alignedload, 1>;
7304  defm : MVE_vector_load<MVE_VLDRWU32, alignedload32, 2>;
7305
7306  // Pre/post inc stores
7307  defm : MVE_vector_offset_store<MVE_VSTRBU8_pre, pre_store, 0>;
7308  defm : MVE_vector_offset_store<MVE_VSTRBU8_post, post_store, 0>;
7309  defm : MVE_vector_offset_store<MVE_VSTRHU16_pre, aligned16_pre_store, 1>;
7310  defm : MVE_vector_offset_store<MVE_VSTRHU16_post, aligned16_post_store, 1>;
7311  defm : MVE_vector_offset_store<MVE_VSTRWU32_pre, aligned32_pre_store, 2>;
7312  defm : MVE_vector_offset_store<MVE_VSTRWU32_post, aligned32_post_store, 2>;
7313}
7314
7315let Predicates = [HasMVEInt, IsBE] in {
7316  // Aligned Stores
7317  def : MVE_vector_store_typed<v16i8, MVE_VSTRBU8, store, 0>;
7318  def : MVE_vector_store_typed<v8i16, MVE_VSTRHU16, alignedstore16, 1>;
7319  def : MVE_vector_store_typed<v8f16, MVE_VSTRHU16, alignedstore16, 1>;
7320  def : MVE_vector_store_typed<v4i32, MVE_VSTRWU32, alignedstore32, 2>;
7321  def : MVE_vector_store_typed<v4f32, MVE_VSTRWU32, alignedstore32, 2>;
7322
7323  // Aligned Loads
7324  def : MVE_vector_load_typed<v16i8, MVE_VLDRBU8, load, 0>;
7325  def : MVE_vector_load_typed<v8i16, MVE_VLDRHU16, alignedload16, 1>;
7326  def : MVE_vector_load_typed<v8f16, MVE_VLDRHU16, alignedload16, 1>;
7327  def : MVE_vector_load_typed<v4i32, MVE_VLDRWU32, alignedload32, 2>;
7328  def : MVE_vector_load_typed<v4f32, MVE_VLDRWU32, alignedload32, 2>;
7329
7330  // Other unaligned loads/stores need to go though a VREV
7331  def : Pat<(v2f64 (load t2addrmode_imm7<0>:$addr)),
7332            (v2f64 (MVE_VREV64_8 (MVE_VLDRBU8 t2addrmode_imm7<0>:$addr)))>;
7333  def : Pat<(v2i64 (load t2addrmode_imm7<0>:$addr)),
7334            (v2i64 (MVE_VREV64_8 (MVE_VLDRBU8 t2addrmode_imm7<0>:$addr)))>;
7335  def : Pat<(v4i32 (load t2addrmode_imm7<0>:$addr)),
7336            (v4i32 (MVE_VREV32_8 (MVE_VLDRBU8 t2addrmode_imm7<0>:$addr)))>;
7337  def : Pat<(v4f32 (load t2addrmode_imm7<0>:$addr)),
7338            (v4f32 (MVE_VREV32_8 (MVE_VLDRBU8 t2addrmode_imm7<0>:$addr)))>;
7339  def : Pat<(v8i16 (load t2addrmode_imm7<0>:$addr)),
7340            (v8i16 (MVE_VREV16_8 (MVE_VLDRBU8 t2addrmode_imm7<0>:$addr)))>;
7341  def : Pat<(v8f16 (load t2addrmode_imm7<0>:$addr)),
7342            (v8f16 (MVE_VREV16_8 (MVE_VLDRBU8 t2addrmode_imm7<0>:$addr)))>;
7343  def : Pat<(store (v2f64 MQPR:$val), t2addrmode_imm7<0>:$addr),
7344            (MVE_VSTRBU8 (MVE_VREV64_8 MQPR:$val), t2addrmode_imm7<0>:$addr)>;
7345  def : Pat<(store (v2i64 MQPR:$val), t2addrmode_imm7<0>:$addr),
7346            (MVE_VSTRBU8 (MVE_VREV64_8 MQPR:$val), t2addrmode_imm7<0>:$addr)>;
7347  def : Pat<(store (v4i32 MQPR:$val), t2addrmode_imm7<0>:$addr),
7348            (MVE_VSTRBU8 (MVE_VREV32_8 MQPR:$val), t2addrmode_imm7<0>:$addr)>;
7349  def : Pat<(store (v4f32 MQPR:$val), t2addrmode_imm7<0>:$addr),
7350            (MVE_VSTRBU8 (MVE_VREV32_8 MQPR:$val), t2addrmode_imm7<0>:$addr)>;
7351  def : Pat<(store (v8i16 MQPR:$val), t2addrmode_imm7<0>:$addr),
7352            (MVE_VSTRBU8 (MVE_VREV16_8 MQPR:$val), t2addrmode_imm7<0>:$addr)>;
7353  def : Pat<(store (v8f16 MQPR:$val), t2addrmode_imm7<0>:$addr),
7354            (MVE_VSTRBU8 (MVE_VREV16_8 MQPR:$val), t2addrmode_imm7<0>:$addr)>;
7355
7356  // Pre/Post inc stores
7357  def : MVE_vector_offset_store_typed<v16i8, MVE_VSTRBU8_pre, pre_store, 0>;
7358  def : MVE_vector_offset_store_typed<v16i8, MVE_VSTRBU8_post, post_store, 0>;
7359  def : MVE_vector_offset_store_typed<v8i16, MVE_VSTRHU16_pre, aligned16_pre_store, 1>;
7360  def : MVE_vector_offset_store_typed<v8i16, MVE_VSTRHU16_post, aligned16_post_store, 1>;
7361  def : MVE_vector_offset_store_typed<v8f16, MVE_VSTRHU16_pre, aligned16_pre_store, 1>;
7362  def : MVE_vector_offset_store_typed<v8f16, MVE_VSTRHU16_post, aligned16_post_store, 1>;
7363  def : MVE_vector_offset_store_typed<v4i32, MVE_VSTRWU32_pre, aligned32_pre_store, 2>;
7364  def : MVE_vector_offset_store_typed<v4i32, MVE_VSTRWU32_post, aligned32_post_store, 2>;
7365  def : MVE_vector_offset_store_typed<v4f32, MVE_VSTRWU32_pre, aligned32_pre_store, 2>;
7366  def : MVE_vector_offset_store_typed<v4f32, MVE_VSTRWU32_post, aligned32_post_store, 2>;
7367}
7368
7369let Predicates = [HasMVEInt] in {
7370  // Aligned masked store, shared between LE and BE
7371  def : MVE_vector_maskedstore_typed<v16i8, MVE_VSTRBU8, aligned_maskedstvi8, 0>;
7372  def : MVE_vector_maskedstore_typed<v8i16, MVE_VSTRHU16, aligned_maskedstvi16, 1>;
7373  def : MVE_vector_maskedstore_typed<v8f16, MVE_VSTRHU16, aligned_maskedstvi16, 1>;
7374  def : MVE_vector_maskedstore_typed<v4i32, MVE_VSTRWU32, aligned_maskedstvi32, 2>;
7375  def : MVE_vector_maskedstore_typed<v4f32, MVE_VSTRWU32, aligned_maskedstvi32, 2>;
7376
7377  // Pre/Post inc masked stores
7378  def : MVE_vector_offset_maskedstore_typed<v16i8, MVE_VSTRBU8_pre, aligned_pre_maskedstorevi8, 0>;
7379  def : MVE_vector_offset_maskedstore_typed<v16i8, MVE_VSTRBU8_post, aligned_post_maskedstorevi8, 0>;
7380  def : MVE_vector_offset_maskedstore_typed<v8i16, MVE_VSTRHU16_pre, aligned_pre_maskedstorevi16, 1>;
7381  def : MVE_vector_offset_maskedstore_typed<v8i16, MVE_VSTRHU16_post, aligned_post_maskedstorevi16, 1>;
7382  def : MVE_vector_offset_maskedstore_typed<v8f16, MVE_VSTRHU16_pre, aligned_pre_maskedstorevi16, 1>;
7383  def : MVE_vector_offset_maskedstore_typed<v8f16, MVE_VSTRHU16_post, aligned_post_maskedstorevi16, 1>;
7384  def : MVE_vector_offset_maskedstore_typed<v4i32, MVE_VSTRWU32_pre, aligned_pre_maskedstorevi32, 2>;
7385  def : MVE_vector_offset_maskedstore_typed<v4i32, MVE_VSTRWU32_post, aligned_post_maskedstorevi32, 2>;
7386  def : MVE_vector_offset_maskedstore_typed<v4f32, MVE_VSTRWU32_pre, aligned_pre_maskedstorevi32, 2>;
7387  def : MVE_vector_offset_maskedstore_typed<v4f32, MVE_VSTRWU32_post, aligned_post_maskedstorevi32, 2>;
7388
7389  // Aligned masked loads
7390  def : MVE_vector_maskedload_typed<v16i8, MVE_VLDRBU8, aligned_maskedloadvi8, 0>;
7391  def : MVE_vector_maskedload_typed<v8i16, MVE_VLDRHU16, aligned_maskedloadvi16, 1>;
7392  def : MVE_vector_maskedload_typed<v8f16, MVE_VLDRHU16, aligned_maskedloadvi16, 1>;
7393  def : MVE_vector_maskedload_typed<v4i32, MVE_VLDRWU32, aligned_maskedloadvi32, 2>;
7394  def : MVE_vector_maskedload_typed<v4f32, MVE_VLDRWU32, aligned_maskedloadvi32, 2>;
7395}
7396
7397// Widening/Narrowing Loads/Stores
7398
7399multiclass MVEExtLoadStore<Instruction LoadSInst, Instruction LoadUInst, string StoreInst,
7400                         string Amble, ValueType VT, int Shift> {
7401  // Trunc stores
7402  def : Pat<(!cast<PatFrag>("aligned_truncst"#Amble) (VT MQPR:$val), taddrmode_imm7<Shift>:$addr),
7403            (!cast<Instruction>(StoreInst) MQPR:$val, taddrmode_imm7<Shift>:$addr)>;
7404  def : Pat<(!cast<PatFrag>("aligned_post_truncst"#Amble) (VT MQPR:$Rt), tGPR:$Rn, t2am_imm7_offset<Shift>:$addr),
7405            (!cast<Instruction>(StoreInst#"_post") MQPR:$Rt, tGPR:$Rn, t2am_imm7_offset<Shift>:$addr)>;
7406  def : Pat<(!cast<PatFrag>("aligned_pre_truncst"#Amble) (VT MQPR:$Rt), tGPR:$Rn, t2am_imm7_offset<Shift>:$addr),
7407            (!cast<Instruction>(StoreInst#"_pre") MQPR:$Rt, tGPR:$Rn, t2am_imm7_offset<Shift>:$addr)>;
7408
7409  // Masked trunc stores
7410  def : Pat<(!cast<PatFrag>("aligned_truncmaskedst"#Amble) (VT MQPR:$val), taddrmode_imm7<Shift>:$addr, VCCR:$pred),
7411            (!cast<Instruction>(StoreInst) MQPR:$val, taddrmode_imm7<Shift>:$addr, ARMVCCThen, VCCR:$pred, zero_reg)>;
7412  def : Pat<(!cast<PatFrag>("aligned_post_truncmaskedst"#Amble) (VT MQPR:$Rt), tGPR:$Rn, t2am_imm7_offset<Shift>:$addr, VCCR:$pred),
7413            (!cast<Instruction>(StoreInst#"_post") MQPR:$Rt, tGPR:$Rn, t2am_imm7_offset<Shift>:$addr, ARMVCCThen, VCCR:$pred, zero_reg)>;
7414  def : Pat<(!cast<PatFrag>("aligned_pre_truncmaskedst"#Amble) (VT MQPR:$Rt), tGPR:$Rn, t2am_imm7_offset<Shift>:$addr, VCCR:$pred),
7415            (!cast<Instruction>(StoreInst#"_pre") MQPR:$Rt, tGPR:$Rn, t2am_imm7_offset<Shift>:$addr, ARMVCCThen, VCCR:$pred, zero_reg)>;
7416
7417  // Ext loads
7418  def : Pat<(VT (!cast<PatFrag>("aligned_extload"#Amble) taddrmode_imm7<Shift>:$addr)),
7419            (VT (LoadUInst taddrmode_imm7<Shift>:$addr))>;
7420  def : Pat<(VT (!cast<PatFrag>("aligned_sextload"#Amble) taddrmode_imm7<Shift>:$addr)),
7421            (VT (LoadSInst taddrmode_imm7<Shift>:$addr))>;
7422  def : Pat<(VT (!cast<PatFrag>("aligned_zextload"#Amble) taddrmode_imm7<Shift>:$addr)),
7423            (VT (LoadUInst taddrmode_imm7<Shift>:$addr))>;
7424
7425  // Masked ext loads
7426  def : Pat<(VT (!cast<PatFrag>("aligned_extmaskedload"#Amble) taddrmode_imm7<Shift>:$addr, VCCR:$pred, (VT (ARMvmovImm (i32 0))))),
7427            (VT (LoadUInst taddrmode_imm7<Shift>:$addr, ARMVCCThen, VCCR:$pred, zero_reg))>;
7428  def : Pat<(VT (!cast<PatFrag>("aligned_sextmaskedload"#Amble) taddrmode_imm7<Shift>:$addr, VCCR:$pred, (VT (ARMvmovImm (i32 0))))),
7429            (VT (LoadSInst taddrmode_imm7<Shift>:$addr, ARMVCCThen, VCCR:$pred, zero_reg))>;
7430  def : Pat<(VT (!cast<PatFrag>("aligned_zextmaskedload"#Amble) taddrmode_imm7<Shift>:$addr, VCCR:$pred, (VT (ARMvmovImm (i32 0))))),
7431            (VT (LoadUInst taddrmode_imm7<Shift>:$addr, ARMVCCThen, VCCR:$pred, zero_reg))>;
7432}
7433
7434let Predicates = [HasMVEInt] in {
7435  defm : MVEExtLoadStore<MVE_VLDRBS16, MVE_VLDRBU16, "MVE_VSTRB16", "vi8", v8i16, 0>;
7436  defm : MVEExtLoadStore<MVE_VLDRBS32, MVE_VLDRBU32, "MVE_VSTRB32", "vi8", v4i32, 0>;
7437  defm : MVEExtLoadStore<MVE_VLDRHS32, MVE_VLDRHU32, "MVE_VSTRH32", "vi16", v4i32, 1>;
7438}
7439
7440
7441// Bit convert patterns
7442
7443let Predicates = [HasMVEInt] in {
7444  def : Pat<(v2f64 (bitconvert (v2i64 MQPR:$src))), (v2f64 MQPR:$src)>;
7445  def : Pat<(v2i64 (bitconvert (v2f64 MQPR:$src))), (v2i64 MQPR:$src)>;
7446
7447  def : Pat<(v4i32 (bitconvert (v4f32 MQPR:$src))), (v4i32 MQPR:$src)>;
7448  def : Pat<(v4f32 (bitconvert (v4i32 MQPR:$src))), (v4f32 MQPR:$src)>;
7449
7450  def : Pat<(v8i16 (bitconvert (v8f16 MQPR:$src))), (v8i16  MQPR:$src)>;
7451  def : Pat<(v8f16 (bitconvert (v8i16 MQPR:$src))), (v8f16  MQPR:$src)>;
7452}
7453
7454let Predicates = [IsLE,HasMVEInt] in {
7455  def : Pat<(v2f64 (bitconvert (v4f32 MQPR:$src))), (v2f64 MQPR:$src)>;
7456  def : Pat<(v2f64 (bitconvert (v4i32 MQPR:$src))), (v2f64 MQPR:$src)>;
7457  def : Pat<(v2f64 (bitconvert (v8f16 MQPR:$src))), (v2f64 MQPR:$src)>;
7458  def : Pat<(v2f64 (bitconvert (v8i16 MQPR:$src))), (v2f64 MQPR:$src)>;
7459  def : Pat<(v2f64 (bitconvert (v16i8 MQPR:$src))), (v2f64 MQPR:$src)>;
7460
7461  def : Pat<(v2i64 (bitconvert (v4f32 MQPR:$src))), (v2i64 MQPR:$src)>;
7462  def : Pat<(v2i64 (bitconvert (v4i32 MQPR:$src))), (v2i64 MQPR:$src)>;
7463  def : Pat<(v2i64 (bitconvert (v8f16 MQPR:$src))), (v2i64 MQPR:$src)>;
7464  def : Pat<(v2i64 (bitconvert (v8i16 MQPR:$src))), (v2i64 MQPR:$src)>;
7465  def : Pat<(v2i64 (bitconvert (v16i8 MQPR:$src))), (v2i64 MQPR:$src)>;
7466
7467  def : Pat<(v4f32 (bitconvert (v2f64 MQPR:$src))), (v4f32 MQPR:$src)>;
7468  def : Pat<(v4f32 (bitconvert (v2i64 MQPR:$src))), (v4f32 MQPR:$src)>;
7469  def : Pat<(v4f32 (bitconvert (v8f16 MQPR:$src))), (v4f32 MQPR:$src)>;
7470  def : Pat<(v4f32 (bitconvert (v8i16 MQPR:$src))), (v4f32 MQPR:$src)>;
7471  def : Pat<(v4f32 (bitconvert (v16i8 MQPR:$src))), (v4f32 MQPR:$src)>;
7472
7473  def : Pat<(v4i32 (bitconvert (v2f64 MQPR:$src))), (v4i32 MQPR:$src)>;
7474  def : Pat<(v4i32 (bitconvert (v2i64 MQPR:$src))), (v4i32 MQPR:$src)>;
7475  def : Pat<(v4i32 (bitconvert (v8f16 MQPR:$src))), (v4i32 MQPR:$src)>;
7476  def : Pat<(v4i32 (bitconvert (v8i16 MQPR:$src))), (v4i32 MQPR:$src)>;
7477  def : Pat<(v4i32 (bitconvert (v16i8 MQPR:$src))), (v4i32 MQPR:$src)>;
7478
7479  def : Pat<(v8f16 (bitconvert (v2f64 MQPR:$src))), (v8f16 MQPR:$src)>;
7480  def : Pat<(v8f16 (bitconvert (v2i64 MQPR:$src))), (v8f16 MQPR:$src)>;
7481  def : Pat<(v8f16 (bitconvert (v4f32 MQPR:$src))), (v8f16 MQPR:$src)>;
7482  def : Pat<(v8f16 (bitconvert (v4i32 MQPR:$src))), (v8f16 MQPR:$src)>;
7483  def : Pat<(v8f16 (bitconvert (v16i8 MQPR:$src))), (v8f16 MQPR:$src)>;
7484
7485  def : Pat<(v8i16 (bitconvert (v2f64 MQPR:$src))), (v8i16 MQPR:$src)>;
7486  def : Pat<(v8i16 (bitconvert (v2i64 MQPR:$src))), (v8i16 MQPR:$src)>;
7487  def : Pat<(v8i16 (bitconvert (v4f32 MQPR:$src))), (v8i16 MQPR:$src)>;
7488  def : Pat<(v8i16 (bitconvert (v4i32 MQPR:$src))), (v8i16 MQPR:$src)>;
7489  def : Pat<(v8i16 (bitconvert (v16i8 MQPR:$src))), (v8i16 MQPR:$src)>;
7490
7491  def : Pat<(v16i8 (bitconvert (v2f64 MQPR:$src))), (v16i8 MQPR:$src)>;
7492  def : Pat<(v16i8 (bitconvert (v2i64 MQPR:$src))), (v16i8 MQPR:$src)>;
7493  def : Pat<(v16i8 (bitconvert (v4f32 MQPR:$src))), (v16i8 MQPR:$src)>;
7494  def : Pat<(v16i8 (bitconvert (v4i32 MQPR:$src))), (v16i8 MQPR:$src)>;
7495  def : Pat<(v16i8 (bitconvert (v8f16 MQPR:$src))), (v16i8 MQPR:$src)>;
7496  def : Pat<(v16i8 (bitconvert (v8i16 MQPR:$src))), (v16i8 MQPR:$src)>;
7497}
7498
7499let Predicates = [IsBE,HasMVEInt] in {
7500  def : Pat<(v2f64 (bitconvert (v4f32 MQPR:$src))), (v2f64 (MVE_VREV64_32 MQPR:$src))>;
7501  def : Pat<(v2f64 (bitconvert (v4i32 MQPR:$src))), (v2f64 (MVE_VREV64_32 MQPR:$src))>;
7502  def : Pat<(v2f64 (bitconvert (v8f16 MQPR:$src))), (v2f64 (MVE_VREV64_16 MQPR:$src))>;
7503  def : Pat<(v2f64 (bitconvert (v8i16 MQPR:$src))), (v2f64 (MVE_VREV64_16 MQPR:$src))>;
7504  def : Pat<(v2f64 (bitconvert (v16i8 MQPR:$src))), (v2f64 (MVE_VREV64_8 MQPR:$src))>;
7505
7506  def : Pat<(v2i64 (bitconvert (v4f32 MQPR:$src))), (v2i64 (MVE_VREV64_32 MQPR:$src))>;
7507  def : Pat<(v2i64 (bitconvert (v4i32 MQPR:$src))), (v2i64 (MVE_VREV64_32 MQPR:$src))>;
7508  def : Pat<(v2i64 (bitconvert (v8f16 MQPR:$src))), (v2i64 (MVE_VREV64_16 MQPR:$src))>;
7509  def : Pat<(v2i64 (bitconvert (v8i16 MQPR:$src))), (v2i64 (MVE_VREV64_16 MQPR:$src))>;
7510  def : Pat<(v2i64 (bitconvert (v16i8 MQPR:$src))), (v2i64 (MVE_VREV64_8 MQPR:$src))>;
7511
7512  def : Pat<(v4f32 (bitconvert (v2f64 MQPR:$src))), (v4f32 (MVE_VREV64_32 MQPR:$src))>;
7513  def : Pat<(v4f32 (bitconvert (v2i64 MQPR:$src))), (v4f32 (MVE_VREV64_32 MQPR:$src))>;
7514  def : Pat<(v4f32 (bitconvert (v8f16 MQPR:$src))), (v4f32 (MVE_VREV32_16 MQPR:$src))>;
7515  def : Pat<(v4f32 (bitconvert (v8i16 MQPR:$src))), (v4f32 (MVE_VREV32_16 MQPR:$src))>;
7516  def : Pat<(v4f32 (bitconvert (v16i8 MQPR:$src))), (v4f32 (MVE_VREV32_8 MQPR:$src))>;
7517
7518  def : Pat<(v4i32 (bitconvert (v2f64 MQPR:$src))), (v4i32 (MVE_VREV64_32 MQPR:$src))>;
7519  def : Pat<(v4i32 (bitconvert (v2i64 MQPR:$src))), (v4i32 (MVE_VREV64_32 MQPR:$src))>;
7520  def : Pat<(v4i32 (bitconvert (v8f16 MQPR:$src))), (v4i32 (MVE_VREV32_16 MQPR:$src))>;
7521  def : Pat<(v4i32 (bitconvert (v8i16 MQPR:$src))), (v4i32 (MVE_VREV32_16 MQPR:$src))>;
7522  def : Pat<(v4i32 (bitconvert (v16i8 MQPR:$src))), (v4i32 (MVE_VREV32_8 MQPR:$src))>;
7523
7524  def : Pat<(v8f16 (bitconvert (v2f64 MQPR:$src))), (v8f16 (MVE_VREV64_16 MQPR:$src))>;
7525  def : Pat<(v8f16 (bitconvert (v2i64 MQPR:$src))), (v8f16 (MVE_VREV64_16 MQPR:$src))>;
7526  def : Pat<(v8f16 (bitconvert (v4f32 MQPR:$src))), (v8f16 (MVE_VREV32_16 MQPR:$src))>;
7527  def : Pat<(v8f16 (bitconvert (v4i32 MQPR:$src))), (v8f16 (MVE_VREV32_16 MQPR:$src))>;
7528  def : Pat<(v8f16 (bitconvert (v16i8 MQPR:$src))), (v8f16 (MVE_VREV16_8 MQPR:$src))>;
7529
7530  def : Pat<(v8i16 (bitconvert (v2f64 MQPR:$src))), (v8i16 (MVE_VREV64_16 MQPR:$src))>;
7531  def : Pat<(v8i16 (bitconvert (v2i64 MQPR:$src))), (v8i16 (MVE_VREV64_16 MQPR:$src))>;
7532  def : Pat<(v8i16 (bitconvert (v4f32 MQPR:$src))), (v8i16 (MVE_VREV32_16 MQPR:$src))>;
7533  def : Pat<(v8i16 (bitconvert (v4i32 MQPR:$src))), (v8i16 (MVE_VREV32_16 MQPR:$src))>;
7534  def : Pat<(v8i16 (bitconvert (v16i8 MQPR:$src))), (v8i16 (MVE_VREV16_8 MQPR:$src))>;
7535
7536  def : Pat<(v16i8 (bitconvert (v2f64 MQPR:$src))), (v16i8 (MVE_VREV64_8 MQPR:$src))>;
7537  def : Pat<(v16i8 (bitconvert (v2i64 MQPR:$src))), (v16i8 (MVE_VREV64_8 MQPR:$src))>;
7538  def : Pat<(v16i8 (bitconvert (v4f32 MQPR:$src))), (v16i8 (MVE_VREV32_8 MQPR:$src))>;
7539  def : Pat<(v16i8 (bitconvert (v4i32 MQPR:$src))), (v16i8 (MVE_VREV32_8 MQPR:$src))>;
7540  def : Pat<(v16i8 (bitconvert (v8f16 MQPR:$src))), (v16i8 (MVE_VREV16_8 MQPR:$src))>;
7541  def : Pat<(v16i8 (bitconvert (v8i16 MQPR:$src))), (v16i8 (MVE_VREV16_8 MQPR:$src))>;
7542}
7543