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|
// Copyright 2016 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
(Add(Ptr|64|32|16|8) ...) => (ADD ...)
(Add(32|64)F ...) => (FADD(S|D) ...)
(Sub(Ptr|64|32|16|8) ...) => (SUB ...)
(Sub(32|64)F ...) => (FSUB(S|D) ...)
(Mul64 ...) => (MUL ...)
(Mul(32|16|8) ...) => (MULW ...)
(Mul(32|64)F ...) => (FMUL(S|D) ...)
(Hmul64 ...) => (MULH ...)
(Hmul64u ...) => (UMULH ...)
(Hmul32 x y) => (SRAconst (MULL <typ.Int64> x y) [32])
(Hmul32u x y) => (SRAconst (UMULL <typ.UInt64> x y) [32])
(Select0 (Mul64uhilo x y)) => (UMULH x y)
(Select1 (Mul64uhilo x y)) => (MUL x y)
(Div64 [false] x y) => (DIV x y)
(Div32 [false] x y) => (DIVW x y)
(Div16 [false] x y) => (DIVW (SignExt16to32 x) (SignExt16to32 y))
(Div16u x y) => (UDIVW (ZeroExt16to32 x) (ZeroExt16to32 y))
(Div8 x y) => (DIVW (SignExt8to32 x) (SignExt8to32 y))
(Div8u x y) => (UDIVW (ZeroExt8to32 x) (ZeroExt8to32 y))
(Div64u ...) => (UDIV ...)
(Div32u ...) => (UDIVW ...)
(Div32F ...) => (FDIVS ...)
(Div64F ...) => (FDIVD ...)
(Mod64 x y) => (MOD x y)
(Mod32 x y) => (MODW x y)
(Mod64u ...) => (UMOD ...)
(Mod32u ...) => (UMODW ...)
(Mod(16|8) x y) => (MODW (SignExt(16|8)to32 x) (SignExt(16|8)to32 y))
(Mod(16|8)u x y) => (UMODW (ZeroExt(16|8)to32 x) (ZeroExt(16|8)to32 y))
// (x + y) / 2 with x>=y => (x - y) / 2 + y
(Avg64u <t> x y) => (ADD (SRLconst <t> (SUB <t> x y) [1]) y)
(And(64|32|16|8) ...) => (AND ...)
(Or(64|32|16|8) ...) => (OR ...)
(Xor(64|32|16|8) ...) => (XOR ...)
// unary ops
(Neg(64|32|16|8) ...) => (NEG ...)
(Neg(32|64)F ...) => (FNEG(S|D) ...)
(Com(64|32|16|8) ...) => (MVN ...)
// math package intrinsics
(Abs ...) => (FABSD ...)
(Sqrt ...) => (FSQRTD ...)
(Ceil ...) => (FRINTPD ...)
(Floor ...) => (FRINTMD ...)
(Round ...) => (FRINTAD ...)
(RoundToEven ...) => (FRINTND ...)
(Trunc ...) => (FRINTZD ...)
(FMA x y z) => (FMADDD z x y)
(Sqrt32 ...) => (FSQRTS ...)
(Min(64|32)F ...) => (FMIN(D|S) ...)
(Max(64|32)F ...) => (FMAX(D|S) ...)
// lowering rotates
// we do rotate detection in generic rules, if the following rules need to be changed, check generic rules first.
(RotateLeft8 <t> x (MOVDconst [c])) => (Or8 (Lsh8x64 <t> x (MOVDconst [c&7])) (Rsh8Ux64 <t> x (MOVDconst [-c&7])))
(RotateLeft8 <t> x y) => (OR <t> (SLL <t> x (ANDconst <typ.Int64> [7] y)) (SRL <t> (ZeroExt8to64 x) (ANDconst <typ.Int64> [7] (NEG <typ.Int64> y))))
(RotateLeft16 <t> x (MOVDconst [c])) => (Or16 (Lsh16x64 <t> x (MOVDconst [c&15])) (Rsh16Ux64 <t> x (MOVDconst [-c&15])))
(RotateLeft16 <t> x y) => (RORW <t> (ORshiftLL <typ.UInt32> (ZeroExt16to32 x) (ZeroExt16to32 x) [16]) (NEG <typ.Int64> y))
(RotateLeft32 x y) => (RORW x (NEG <y.Type> y))
(RotateLeft64 x y) => (ROR x (NEG <y.Type> y))
(Ctz(64|32|16|8)NonZero ...) => (Ctz(64|32|32|32) ...)
(Ctz64 <t> x) => (CLZ (RBIT <t> x))
(Ctz32 <t> x) => (CLZW (RBITW <t> x))
(Ctz16 <t> x) => (CLZW <t> (RBITW <typ.UInt32> (ORconst <typ.UInt32> [0x10000] x)))
(Ctz8 <t> x) => (CLZW <t> (RBITW <typ.UInt32> (ORconst <typ.UInt32> [0x100] x)))
(PopCount64 <t> x) => (FMOVDfpgp <t> (VUADDLV <typ.Float64> (VCNT <typ.Float64> (FMOVDgpfp <typ.Float64> x))))
(PopCount32 <t> x) => (FMOVDfpgp <t> (VUADDLV <typ.Float64> (VCNT <typ.Float64> (FMOVDgpfp <typ.Float64> (ZeroExt32to64 x)))))
(PopCount16 <t> x) => (FMOVDfpgp <t> (VUADDLV <typ.Float64> (VCNT <typ.Float64> (FMOVDgpfp <typ.Float64> (ZeroExt16to64 x)))))
// Load args directly into the register class where it will be used.
(FMOVDgpfp <t> (Arg [off] {sym})) => @b.Func.Entry (Arg <t> [off] {sym})
(FMOVDfpgp <t> (Arg [off] {sym})) => @b.Func.Entry (Arg <t> [off] {sym})
// Similarly for stores, if we see a store after FPR <=> GPR move, then redirect store to use the other register set.
(MOVDstore [off] {sym} ptr (FMOVDfpgp val) mem) => (FMOVDstore [off] {sym} ptr val mem)
(FMOVDstore [off] {sym} ptr (FMOVDgpfp val) mem) => (MOVDstore [off] {sym} ptr val mem)
(MOVWstore [off] {sym} ptr (FMOVSfpgp val) mem) => (FMOVSstore [off] {sym} ptr val mem)
(FMOVSstore [off] {sym} ptr (FMOVSgpfp val) mem) => (MOVWstore [off] {sym} ptr val mem)
// float <=> int register moves, with no conversion.
// These come up when compiling math.{Float64bits, Float64frombits, Float32bits, Float32frombits}.
(MOVDload [off] {sym} ptr (FMOVDstore [off] {sym} ptr val _)) => (FMOVDfpgp val)
(FMOVDload [off] {sym} ptr (MOVDstore [off] {sym} ptr val _)) => (FMOVDgpfp val)
(MOVWUload [off] {sym} ptr (FMOVSstore [off] {sym} ptr val _)) => (FMOVSfpgp val)
(FMOVSload [off] {sym} ptr (MOVWstore [off] {sym} ptr val _)) => (FMOVSgpfp val)
(BitLen64 x) => (SUB (MOVDconst [64]) (CLZ <typ.Int> x))
(BitLen32 x) => (SUB (MOVDconst [32]) (CLZW <typ.Int> x))
(Bswap64 ...) => (REV ...)
(Bswap32 ...) => (REVW ...)
(Bswap16 ...) => (REV16W ...)
(BitRev64 ...) => (RBIT ...)
(BitRev32 ...) => (RBITW ...)
(BitRev16 x) => (SRLconst [48] (RBIT <typ.UInt64> x))
(BitRev8 x) => (SRLconst [56] (RBIT <typ.UInt64> x))
// In fact, UMOD will be translated into UREM instruction, and UREM is originally translated into
// UDIV and MSUB instructions. But if there is already an identical UDIV instruction just before or
// after UREM (case like quo, rem := z/y, z%y), then the second UDIV instruction becomes redundant.
// The purpose of this rule is to have this extra UDIV instruction removed in CSE pass.
(UMOD <typ.UInt64> x y) => (MSUB <typ.UInt64> x y (UDIV <typ.UInt64> x y))
(UMODW <typ.UInt32> x y) => (MSUBW <typ.UInt32> x y (UDIVW <typ.UInt32> x y))
// 64-bit addition with carry.
(Select0 (Add64carry x y c)) => (Select0 <typ.UInt64> (ADCSflags x y (Select1 <types.TypeFlags> (ADDSconstflags [-1] c))))
(Select1 (Add64carry x y c)) => (ADCzerocarry <typ.UInt64> (Select1 <types.TypeFlags> (ADCSflags x y (Select1 <types.TypeFlags> (ADDSconstflags [-1] c)))))
// 64-bit subtraction with borrowing.
(Select0 (Sub64borrow x y bo)) => (Select0 <typ.UInt64> (SBCSflags x y (Select1 <types.TypeFlags> (NEGSflags bo))))
(Select1 (Sub64borrow x y bo)) => (NEG <typ.UInt64> (NGCzerocarry <typ.UInt64> (Select1 <types.TypeFlags> (SBCSflags x y (Select1 <types.TypeFlags> (NEGSflags bo))))))
// boolean ops -- booleans are represented with 0=false, 1=true
(AndB ...) => (AND ...)
(OrB ...) => (OR ...)
(EqB x y) => (XOR (MOVDconst [1]) (XOR <typ.Bool> x y))
(NeqB ...) => (XOR ...)
(Not x) => (XOR (MOVDconst [1]) x)
// shifts
// hardware instruction uses only the low 6 bits of the shift
// we compare to 64 to ensure Go semantics for large shifts
// Rules about rotates with non-const shift are based on the following rules,
// if the following rules change, please also modify the rules based on them.
// check shiftIsBounded first, if shift value is proved to be valid then we
// can do the shift directly.
// left shift
(Lsh(64|32|16|8)x64 <t> x y) && shiftIsBounded(v) => (SLL <t> x y)
(Lsh(64|32|16|8)x32 <t> x y) && shiftIsBounded(v) => (SLL <t> x y)
(Lsh(64|32|16|8)x16 <t> x y) && shiftIsBounded(v) => (SLL <t> x y)
(Lsh(64|32|16|8)x8 <t> x y) && shiftIsBounded(v) => (SLL <t> x y)
// signed right shift
(Rsh64x(64|32|16|8) <t> x y) && shiftIsBounded(v) => (SRA <t> x y)
(Rsh32x(64|32|16|8) <t> x y) && shiftIsBounded(v) => (SRA <t> (SignExt32to64 x) y)
(Rsh16x(64|32|16|8) <t> x y) && shiftIsBounded(v) => (SRA <t> (SignExt16to64 x) y)
(Rsh8x(64|32|16|8) <t> x y) && shiftIsBounded(v) => (SRA <t> (SignExt8to64 x) y)
// unsigned right shift
(Rsh64Ux(64|32|16|8) <t> x y) && shiftIsBounded(v) => (SRL <t> x y)
(Rsh32Ux(64|32|16|8) <t> x y) && shiftIsBounded(v) => (SRL <t> (ZeroExt32to64 x) y)
(Rsh16Ux(64|32|16|8) <t> x y) && shiftIsBounded(v) => (SRL <t> (ZeroExt16to64 x) y)
(Rsh8Ux(64|32|16|8) <t> x y) && shiftIsBounded(v) => (SRL <t> (ZeroExt8to64 x) y)
// shift value may be out of range, use CMP + CSEL instead
(Lsh64x64 <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SLL <t> x y) (Const64 <t> [0]) (CMPconst [64] y))
(Lsh64x(32|16|8) <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SLL <t> x y) (Const64 <t> [0]) (CMPconst [64] ((ZeroExt32to64|ZeroExt16to64|ZeroExt8to64) y)))
(Lsh32x64 <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SLL <t> x y) (Const64 <t> [0]) (CMPconst [64] y))
(Lsh32x(32|16|8) <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SLL <t> x y) (Const64 <t> [0]) (CMPconst [64] ((ZeroExt32to64|ZeroExt16to64|ZeroExt8to64) y)))
(Lsh16x64 <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SLL <t> x y) (Const64 <t> [0]) (CMPconst [64] y))
(Lsh16x(32|16|8) <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SLL <t> x y) (Const64 <t> [0]) (CMPconst [64] ((ZeroExt32to64|ZeroExt16to64|ZeroExt8to64) y)))
(Lsh8x64 <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SLL <t> x y) (Const64 <t> [0]) (CMPconst [64] y))
(Lsh8x(32|16|8) <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SLL <t> x y) (Const64 <t> [0]) (CMPconst [64] ((ZeroExt32to64|ZeroExt16to64|ZeroExt8to64) y)))
(Rsh64Ux64 <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SRL <t> x y) (Const64 <t> [0]) (CMPconst [64] y))
(Rsh64Ux(32|16|8) <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SRL <t> x y) (Const64 <t> [0]) (CMPconst [64] ((ZeroExt32to64|ZeroExt16to64|ZeroExt8to64) y)))
(Rsh32Ux64 <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SRL <t> (ZeroExt32to64 x) y) (Const64 <t> [0]) (CMPconst [64] y))
(Rsh32Ux(32|16|8) <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SRL <t> (ZeroExt32to64 x) y) (Const64 <t> [0]) (CMPconst [64] ((ZeroExt32to64|ZeroExt16to64|ZeroExt8to64) y)))
(Rsh16Ux64 <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SRL <t> (ZeroExt16to64 x) y) (Const64 <t> [0]) (CMPconst [64] y))
(Rsh16Ux(32|16|8) <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SRL <t> (ZeroExt16to64 x) y) (Const64 <t> [0]) (CMPconst [64] ((ZeroExt32to64|ZeroExt16to64|ZeroExt8to64) y)))
(Rsh8Ux64 <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SRL <t> (ZeroExt8to64 x) y) (Const64 <t> [0]) (CMPconst [64] y))
(Rsh8Ux(32|16|8) <t> x y) && !shiftIsBounded(v) => (CSEL [OpARM64LessThanU] (SRL <t> (ZeroExt8to64 x) y) (Const64 <t> [0]) (CMPconst [64] ((ZeroExt32to64|ZeroExt16to64|ZeroExt8to64) y)))
(Rsh64x64 x y) && !shiftIsBounded(v) => (SRA x (CSEL [OpARM64LessThanU] <y.Type> y (Const64 <y.Type> [63]) (CMPconst [64] y)))
(Rsh64x(32|16|8) x y) && !shiftIsBounded(v) => (SRA x (CSEL [OpARM64LessThanU] <y.Type> y (Const64 <y.Type> [63]) (CMPconst [64] ((ZeroExt32to64|ZeroExt16to64|ZeroExt8to64) y))))
(Rsh32x64 x y) && !shiftIsBounded(v) => (SRA (SignExt32to64 x) (CSEL [OpARM64LessThanU] <y.Type> y (Const64 <y.Type> [63]) (CMPconst [64] y)))
(Rsh32x(32|16|8) x y) && !shiftIsBounded(v) => (SRA (SignExt32to64 x) (CSEL [OpARM64LessThanU] <y.Type> y (Const64 <y.Type> [63]) (CMPconst [64] ((ZeroExt32to64|ZeroExt16to64|ZeroExt8to64) y))))
(Rsh16x64 x y) && !shiftIsBounded(v) => (SRA (SignExt16to64 x) (CSEL [OpARM64LessThanU] <y.Type> y (Const64 <y.Type> [63]) (CMPconst [64] y)))
(Rsh16x(32|16|8) x y) && !shiftIsBounded(v) => (SRA (SignExt16to64 x) (CSEL [OpARM64LessThanU] <y.Type> y (Const64 <y.Type> [63]) (CMPconst [64] ((ZeroExt32to64|ZeroExt16to64|ZeroExt8to64) y))))
(Rsh8x64 x y) && !shiftIsBounded(v) => (SRA (SignExt8to64 x) (CSEL [OpARM64LessThanU] <y.Type> y (Const64 <y.Type> [63]) (CMPconst [64] y)))
(Rsh8x(32|16|8) x y) && !shiftIsBounded(v) => (SRA (SignExt8to64 x) (CSEL [OpARM64LessThanU] <y.Type> y (Const64 <y.Type> [63]) (CMPconst [64] ((ZeroExt32to64|ZeroExt16to64|ZeroExt8to64) y))))
// constants
(Const(64|32|16|8) [val]) => (MOVDconst [int64(val)])
(Const(32|64)F [val]) => (FMOV(S|D)const [float64(val)])
(ConstNil) => (MOVDconst [0])
(ConstBool [t]) => (MOVDconst [b2i(t)])
(Slicemask <t> x) => (SRAconst (NEG <t> x) [63])
// truncations
// Because we ignore high parts of registers, truncates are just copies.
(Trunc16to8 ...) => (Copy ...)
(Trunc32to8 ...) => (Copy ...)
(Trunc32to16 ...) => (Copy ...)
(Trunc64to8 ...) => (Copy ...)
(Trunc64to16 ...) => (Copy ...)
(Trunc64to32 ...) => (Copy ...)
// Zero-/Sign-extensions
(ZeroExt8to16 ...) => (MOVBUreg ...)
(ZeroExt8to32 ...) => (MOVBUreg ...)
(ZeroExt16to32 ...) => (MOVHUreg ...)
(ZeroExt8to64 ...) => (MOVBUreg ...)
(ZeroExt16to64 ...) => (MOVHUreg ...)
(ZeroExt32to64 ...) => (MOVWUreg ...)
(SignExt8to16 ...) => (MOVBreg ...)
(SignExt8to32 ...) => (MOVBreg ...)
(SignExt16to32 ...) => (MOVHreg ...)
(SignExt8to64 ...) => (MOVBreg ...)
(SignExt16to64 ...) => (MOVHreg ...)
(SignExt32to64 ...) => (MOVWreg ...)
// float <=> int conversion
(Cvt32to32F ...) => (SCVTFWS ...)
(Cvt32to64F ...) => (SCVTFWD ...)
(Cvt64to32F ...) => (SCVTFS ...)
(Cvt64to64F ...) => (SCVTFD ...)
(Cvt32Uto32F ...) => (UCVTFWS ...)
(Cvt32Uto64F ...) => (UCVTFWD ...)
(Cvt64Uto32F ...) => (UCVTFS ...)
(Cvt64Uto64F ...) => (UCVTFD ...)
(Cvt32Fto32 ...) => (FCVTZSSW ...)
(Cvt64Fto32 ...) => (FCVTZSDW ...)
(Cvt32Fto64 ...) => (FCVTZSS ...)
(Cvt64Fto64 ...) => (FCVTZSD ...)
(Cvt32Fto32U ...) => (FCVTZUSW ...)
(Cvt64Fto32U ...) => (FCVTZUDW ...)
(Cvt32Fto64U ...) => (FCVTZUS ...)
(Cvt64Fto64U ...) => (FCVTZUD ...)
(Cvt32Fto64F ...) => (FCVTSD ...)
(Cvt64Fto32F ...) => (FCVTDS ...)
(CvtBoolToUint8 ...) => (Copy ...)
(Round32F ...) => (LoweredRound32F ...)
(Round64F ...) => (LoweredRound64F ...)
// comparisons
(Eq8 x y) => (Equal (CMPW (ZeroExt8to32 x) (ZeroExt8to32 y)))
(Eq16 x y) => (Equal (CMPW (ZeroExt16to32 x) (ZeroExt16to32 y)))
(Eq32 x y) => (Equal (CMPW x y))
(Eq64 x y) => (Equal (CMP x y))
(EqPtr x y) => (Equal (CMP x y))
(Eq32F x y) => (Equal (FCMPS x y))
(Eq64F x y) => (Equal (FCMPD x y))
(Neq8 x y) => (NotEqual (CMPW (ZeroExt8to32 x) (ZeroExt8to32 y)))
(Neq16 x y) => (NotEqual (CMPW (ZeroExt16to32 x) (ZeroExt16to32 y)))
(Neq32 x y) => (NotEqual (CMPW x y))
(Neq64 x y) => (NotEqual (CMP x y))
(NeqPtr x y) => (NotEqual (CMP x y))
(Neq(32|64)F x y) => (NotEqual (FCMP(S|D) x y))
(Less(8|16) x y) => (LessThan (CMPW (SignExt(8|16)to32 x) (SignExt(8|16)to32 y)))
(Less32 x y) => (LessThan (CMPW x y))
(Less64 x y) => (LessThan (CMP x y))
// Set condition flags for floating-point comparisons "x < y"
// and "x <= y". Because if either or both of the operands are
// NaNs, all three of (x < y), (x == y) and (x > y) are false,
// and ARM Manual says FCMP instruction sets PSTATE.<N,Z,C,V>
// of this case to (0, 0, 1, 1).
(Less32F x y) => (LessThanF (FCMPS x y))
(Less64F x y) => (LessThanF (FCMPD x y))
// For an unsigned integer x, the following rules are useful when combining branch
// 0 < x => x != 0
// x <= 0 => x == 0
// x < 1 => x == 0
// 1 <= x => x != 0
(Less(8U|16U|32U|64U) zero:(MOVDconst [0]) x) => (Neq(8|16|32|64) zero x)
(Leq(8U|16U|32U|64U) x zero:(MOVDconst [0])) => (Eq(8|16|32|64) x zero)
(Less(8U|16U|32U|64U) x (MOVDconst [1])) => (Eq(8|16|32|64) x (MOVDconst [0]))
(Leq(8U|16U|32U|64U) (MOVDconst [1]) x) => (Neq(8|16|32|64) (MOVDconst [0]) x)
(Less8U x y) => (LessThanU (CMPW (ZeroExt8to32 x) (ZeroExt8to32 y)))
(Less16U x y) => (LessThanU (CMPW (ZeroExt16to32 x) (ZeroExt16to32 y)))
(Less32U x y) => (LessThanU (CMPW x y))
(Less64U x y) => (LessThanU (CMP x y))
(Leq8 x y) => (LessEqual (CMPW (SignExt8to32 x) (SignExt8to32 y)))
(Leq16 x y) => (LessEqual (CMPW (SignExt16to32 x) (SignExt16to32 y)))
(Leq32 x y) => (LessEqual (CMPW x y))
(Leq64 x y) => (LessEqual (CMP x y))
// Refer to the comments for op Less64F above.
(Leq32F x y) => (LessEqualF (FCMPS x y))
(Leq64F x y) => (LessEqualF (FCMPD x y))
(Leq8U x y) => (LessEqualU (CMPW (ZeroExt8to32 x) (ZeroExt8to32 y)))
(Leq16U x y) => (LessEqualU (CMPW (ZeroExt16to32 x) (ZeroExt16to32 y)))
(Leq32U x y) => (LessEqualU (CMPW x y))
(Leq64U x y) => (LessEqualU (CMP x y))
// Optimize comparison between a floating-point value and 0.0 with "FCMP $(0.0), Fn"
(FCMPS x (FMOVSconst [0])) => (FCMPS0 x)
(FCMPS (FMOVSconst [0]) x) => (InvertFlags (FCMPS0 x))
(FCMPD x (FMOVDconst [0])) => (FCMPD0 x)
(FCMPD (FMOVDconst [0]) x) => (InvertFlags (FCMPD0 x))
// CSEL needs a flag-generating argument. Synthesize a TSTW if necessary.
(CondSelect x y boolval) && flagArg(boolval) != nil => (CSEL [boolval.Op] x y flagArg(boolval))
(CondSelect x y boolval) && flagArg(boolval) == nil => (CSEL [OpARM64NotEqual] x y (TSTWconst [1] boolval))
(OffPtr [off] ptr:(SP)) && is32Bit(off) => (MOVDaddr [int32(off)] ptr)
(OffPtr [off] ptr) => (ADDconst [off] ptr)
(Addr {sym} base) => (MOVDaddr {sym} base)
(LocalAddr <t> {sym} base mem) && t.Elem().HasPointers() => (MOVDaddr {sym} (SPanchored base mem))
(LocalAddr <t> {sym} base _) && !t.Elem().HasPointers() => (MOVDaddr {sym} base)
// loads
(Load <t> ptr mem) && t.IsBoolean() => (MOVBUload ptr mem)
(Load <t> ptr mem) && (is8BitInt(t) && t.IsSigned()) => (MOVBload ptr mem)
(Load <t> ptr mem) && (is8BitInt(t) && !t.IsSigned()) => (MOVBUload ptr mem)
(Load <t> ptr mem) && (is16BitInt(t) && t.IsSigned()) => (MOVHload ptr mem)
(Load <t> ptr mem) && (is16BitInt(t) && !t.IsSigned()) => (MOVHUload ptr mem)
(Load <t> ptr mem) && (is32BitInt(t) && t.IsSigned()) => (MOVWload ptr mem)
(Load <t> ptr mem) && (is32BitInt(t) && !t.IsSigned()) => (MOVWUload ptr mem)
(Load <t> ptr mem) && (is64BitInt(t) || isPtr(t)) => (MOVDload ptr mem)
(Load <t> ptr mem) && is32BitFloat(t) => (FMOVSload ptr mem)
(Load <t> ptr mem) && is64BitFloat(t) => (FMOVDload ptr mem)
// stores
(Store {t} ptr val mem) && t.Size() == 1 => (MOVBstore ptr val mem)
(Store {t} ptr val mem) && t.Size() == 2 => (MOVHstore ptr val mem)
(Store {t} ptr val mem) && t.Size() == 4 && !t.IsFloat() => (MOVWstore ptr val mem)
(Store {t} ptr val mem) && t.Size() == 8 && !t.IsFloat() => (MOVDstore ptr val mem)
(Store {t} ptr val mem) && t.Size() == 4 && t.IsFloat() => (FMOVSstore ptr val mem)
(Store {t} ptr val mem) && t.Size() == 8 && t.IsFloat() => (FMOVDstore ptr val mem)
// zeroing
(Zero [0] _ mem) => mem
(Zero [1] ptr mem) => (MOVBstore ptr (MOVDconst [0]) mem)
(Zero [2] ptr mem) => (MOVHstore ptr (MOVDconst [0]) mem)
(Zero [4] ptr mem) => (MOVWstore ptr (MOVDconst [0]) mem)
(Zero [3] ptr mem) =>
(MOVBstore [2] ptr (MOVDconst [0])
(MOVHstore ptr (MOVDconst [0]) mem))
(Zero [5] ptr mem) =>
(MOVBstore [4] ptr (MOVDconst [0])
(MOVWstore ptr (MOVDconst [0]) mem))
(Zero [6] ptr mem) =>
(MOVHstore [4] ptr (MOVDconst [0])
(MOVWstore ptr (MOVDconst [0]) mem))
(Zero [7] ptr mem) =>
(MOVWstore [3] ptr (MOVDconst [0])
(MOVWstore ptr (MOVDconst [0]) mem))
(Zero [8] ptr mem) => (MOVDstore ptr (MOVDconst [0]) mem)
(Zero [9] ptr mem) =>
(MOVBstore [8] ptr (MOVDconst [0])
(MOVDstore ptr (MOVDconst [0]) mem))
(Zero [10] ptr mem) =>
(MOVHstore [8] ptr (MOVDconst [0])
(MOVDstore ptr (MOVDconst [0]) mem))
(Zero [11] ptr mem) =>
(MOVDstore [3] ptr (MOVDconst [0])
(MOVDstore ptr (MOVDconst [0]) mem))
(Zero [12] ptr mem) =>
(MOVWstore [8] ptr (MOVDconst [0])
(MOVDstore ptr (MOVDconst [0]) mem))
(Zero [13] ptr mem) =>
(MOVDstore [5] ptr (MOVDconst [0])
(MOVDstore ptr (MOVDconst [0]) mem))
(Zero [14] ptr mem) =>
(MOVDstore [6] ptr (MOVDconst [0])
(MOVDstore ptr (MOVDconst [0]) mem))
(Zero [15] ptr mem) =>
(MOVDstore [7] ptr (MOVDconst [0])
(MOVDstore ptr (MOVDconst [0]) mem))
(Zero [16] ptr mem) =>
(STP [0] ptr (MOVDconst [0]) (MOVDconst [0]) mem)
(Zero [32] ptr mem) =>
(STP [16] ptr (MOVDconst [0]) (MOVDconst [0])
(STP [0] ptr (MOVDconst [0]) (MOVDconst [0]) mem))
(Zero [48] ptr mem) =>
(STP [32] ptr (MOVDconst [0]) (MOVDconst [0])
(STP [16] ptr (MOVDconst [0]) (MOVDconst [0])
(STP [0] ptr (MOVDconst [0]) (MOVDconst [0]) mem)))
(Zero [64] ptr mem) =>
(STP [48] ptr (MOVDconst [0]) (MOVDconst [0])
(STP [32] ptr (MOVDconst [0]) (MOVDconst [0])
(STP [16] ptr (MOVDconst [0]) (MOVDconst [0])
(STP [0] ptr (MOVDconst [0]) (MOVDconst [0]) mem))))
// strip off fractional word zeroing
(Zero [s] ptr mem) && s%16 != 0 && s%16 <= 8 && s > 16 =>
(Zero [8]
(OffPtr <ptr.Type> ptr [s-8])
(Zero [s-s%16] ptr mem))
(Zero [s] ptr mem) && s%16 != 0 && s%16 > 8 && s > 16 =>
(Zero [16]
(OffPtr <ptr.Type> ptr [s-16])
(Zero [s-s%16] ptr mem))
// medium zeroing uses a duff device
// 4, 16, and 64 are magic constants, see runtime/mkduff.go
(Zero [s] ptr mem)
&& s%16 == 0 && s > 64 && s <= 16*64
&& !config.noDuffDevice =>
(DUFFZERO [4 * (64 - s/16)] ptr mem)
// large zeroing uses a loop
(Zero [s] ptr mem)
&& s%16 == 0 && (s > 16*64 || config.noDuffDevice) =>
(LoweredZero
ptr
(ADDconst <ptr.Type> [s-16] ptr)
mem)
// moves
(Move [0] _ _ mem) => mem
(Move [1] dst src mem) => (MOVBstore dst (MOVBUload src mem) mem)
(Move [2] dst src mem) => (MOVHstore dst (MOVHUload src mem) mem)
(Move [3] dst src mem) =>
(MOVBstore [2] dst (MOVBUload [2] src mem)
(MOVHstore dst (MOVHUload src mem) mem))
(Move [4] dst src mem) => (MOVWstore dst (MOVWUload src mem) mem)
(Move [5] dst src mem) =>
(MOVBstore [4] dst (MOVBUload [4] src mem)
(MOVWstore dst (MOVWUload src mem) mem))
(Move [6] dst src mem) =>
(MOVHstore [4] dst (MOVHUload [4] src mem)
(MOVWstore dst (MOVWUload src mem) mem))
(Move [7] dst src mem) =>
(MOVWstore [3] dst (MOVWUload [3] src mem)
(MOVWstore dst (MOVWUload src mem) mem))
(Move [8] dst src mem) => (MOVDstore dst (MOVDload src mem) mem)
(Move [9] dst src mem) =>
(MOVBstore [8] dst (MOVBUload [8] src mem)
(MOVDstore dst (MOVDload src mem) mem))
(Move [10] dst src mem) =>
(MOVHstore [8] dst (MOVHUload [8] src mem)
(MOVDstore dst (MOVDload src mem) mem))
(Move [11] dst src mem) =>
(MOVDstore [3] dst (MOVDload [3] src mem)
(MOVDstore dst (MOVDload src mem) mem))
(Move [12] dst src mem) =>
(MOVWstore [8] dst (MOVWUload [8] src mem)
(MOVDstore dst (MOVDload src mem) mem))
(Move [13] dst src mem) =>
(MOVDstore [5] dst (MOVDload [5] src mem)
(MOVDstore dst (MOVDload src mem) mem))
(Move [14] dst src mem) =>
(MOVDstore [6] dst (MOVDload [6] src mem)
(MOVDstore dst (MOVDload src mem) mem))
(Move [15] dst src mem) =>
(MOVDstore [7] dst (MOVDload [7] src mem)
(MOVDstore dst (MOVDload src mem) mem))
(Move [16] dst src mem) =>
(STP dst (Select0 <typ.UInt64> (LDP src mem)) (Select1 <typ.UInt64> (LDP src mem)) mem)
(Move [32] dst src mem) =>
(STP [16] dst (Select0 <typ.UInt64> (LDP [16] src mem)) (Select1 <typ.UInt64> (LDP [16] src mem))
(STP dst (Select0 <typ.UInt64> (LDP src mem)) (Select1 <typ.UInt64> (LDP src mem)) mem))
(Move [48] dst src mem) =>
(STP [32] dst (Select0 <typ.UInt64> (LDP [32] src mem)) (Select1 <typ.UInt64> (LDP [32] src mem))
(STP [16] dst (Select0 <typ.UInt64> (LDP [16] src mem)) (Select1 <typ.UInt64> (LDP [16] src mem))
(STP dst (Select0 <typ.UInt64> (LDP src mem)) (Select1 <typ.UInt64> (LDP src mem)) mem)))
(Move [64] dst src mem) =>
(STP [48] dst (Select0 <typ.UInt64> (LDP [48] src mem)) (Select1 <typ.UInt64> (LDP [48] src mem))
(STP [32] dst (Select0 <typ.UInt64> (LDP [32] src mem)) (Select1 <typ.UInt64> (LDP [32] src mem))
(STP [16] dst (Select0 <typ.UInt64> (LDP [16] src mem)) (Select1 <typ.UInt64> (LDP [16] src mem))
(STP dst (Select0 <typ.UInt64> (LDP src mem)) (Select1 <typ.UInt64> (LDP src mem)) mem))))
(MOVDstorezero {s} [i] ptr x:(MOVDstorezero {s} [i+8] ptr mem)) && x.Uses == 1 && setPos(v, x.Pos) && clobber(x) => (MOVQstorezero {s} [i] ptr mem)
(MOVDstorezero {s} [i] ptr x:(MOVDstorezero {s} [i-8] ptr mem)) && x.Uses == 1 && setPos(v, x.Pos) && clobber(x) => (MOVQstorezero {s} [i-8] ptr mem)
// strip off fractional word move
(Move [s] dst src mem) && s%16 != 0 && s%16 <= 8 && s > 16 =>
(Move [8]
(OffPtr <dst.Type> dst [s-8])
(OffPtr <src.Type> src [s-8])
(Move [s-s%16] dst src mem))
(Move [s] dst src mem) && s%16 != 0 && s%16 > 8 && s > 16 =>
(Move [16]
(OffPtr <dst.Type> dst [s-16])
(OffPtr <src.Type> src [s-16])
(Move [s-s%16] dst src mem))
// medium move uses a duff device
(Move [s] dst src mem)
&& s > 64 && s <= 16*64 && s%16 == 0
&& !config.noDuffDevice && logLargeCopy(v, s) =>
(DUFFCOPY [8 * (64 - s/16)] dst src mem)
// 8 is the number of bytes to encode:
//
// LDP.P 16(R16), (R26, R27)
// STP.P (R26, R27), 16(R17)
//
// 64 is number of these blocks. See runtime/duff_arm64.s:duffcopy
// large move uses a loop
(Move [s] dst src mem)
&& s%16 == 0 && (s > 16*64 || config.noDuffDevice)
&& logLargeCopy(v, s) =>
(LoweredMove
dst
src
(ADDconst <src.Type> src [s-16])
mem)
// calls
(StaticCall ...) => (CALLstatic ...)
(ClosureCall ...) => (CALLclosure ...)
(InterCall ...) => (CALLinter ...)
(TailCall ...) => (CALLtail ...)
// checks
(NilCheck ...) => (LoweredNilCheck ...)
(IsNonNil ptr) => (NotEqual (CMPconst [0] ptr))
(IsInBounds idx len) => (LessThanU (CMP idx len))
(IsSliceInBounds idx len) => (LessEqualU (CMP idx len))
// pseudo-ops
(GetClosurePtr ...) => (LoweredGetClosurePtr ...)
(GetCallerSP ...) => (LoweredGetCallerSP ...)
(GetCallerPC ...) => (LoweredGetCallerPC ...)
// Absorb pseudo-ops into blocks.
(If (Equal cc) yes no) => (EQ cc yes no)
(If (NotEqual cc) yes no) => (NE cc yes no)
(If (LessThan cc) yes no) => (LT cc yes no)
(If (LessThanU cc) yes no) => (ULT cc yes no)
(If (LessEqual cc) yes no) => (LE cc yes no)
(If (LessEqualU cc) yes no) => (ULE cc yes no)
(If (GreaterThan cc) yes no) => (GT cc yes no)
(If (GreaterThanU cc) yes no) => (UGT cc yes no)
(If (GreaterEqual cc) yes no) => (GE cc yes no)
(If (GreaterEqualU cc) yes no) => (UGE cc yes no)
(If (LessThanF cc) yes no) => (FLT cc yes no)
(If (LessEqualF cc) yes no) => (FLE cc yes no)
(If (GreaterThanF cc) yes no) => (FGT cc yes no)
(If (GreaterEqualF cc) yes no) => (FGE cc yes no)
(If cond yes no) => (TBNZ [0] cond yes no)
(JumpTable idx) => (JUMPTABLE {makeJumpTableSym(b)} idx (MOVDaddr <typ.Uintptr> {makeJumpTableSym(b)} (SB)))
// atomic intrinsics
// Note: these ops do not accept offset.
(AtomicLoad8 ...) => (LDARB ...)
(AtomicLoad32 ...) => (LDARW ...)
(AtomicLoad64 ...) => (LDAR ...)
(AtomicLoadPtr ...) => (LDAR ...)
(AtomicStore8 ...) => (STLRB ...)
(AtomicStore32 ...) => (STLRW ...)
(AtomicStore64 ...) => (STLR ...)
(AtomicStorePtrNoWB ...) => (STLR ...)
(AtomicExchange(32|64) ...) => (LoweredAtomicExchange(32|64) ...)
(AtomicAdd(32|64) ...) => (LoweredAtomicAdd(32|64) ...)
(AtomicCompareAndSwap(32|64) ...) => (LoweredAtomicCas(32|64) ...)
(AtomicAdd(32|64)Variant ...) => (LoweredAtomicAdd(32|64)Variant ...)
(AtomicExchange(32|64)Variant ...) => (LoweredAtomicExchange(32|64)Variant ...)
(AtomicCompareAndSwap(32|64)Variant ...) => (LoweredAtomicCas(32|64)Variant ...)
// Currently the updated value is not used, but we need a register to temporarily hold it.
(AtomicAnd(8|32) ptr val mem) => (Select1 (LoweredAtomicAnd(8|32) ptr val mem))
(AtomicOr(8|32) ptr val mem) => (Select1 (LoweredAtomicOr(8|32) ptr val mem))
(AtomicAnd(8|32)Variant ptr val mem) => (Select1 (LoweredAtomicAnd(8|32)Variant ptr val mem))
(AtomicOr(8|32)Variant ptr val mem) => (Select1 (LoweredAtomicOr(8|32)Variant ptr val mem))
// Write barrier.
(WB ...) => (LoweredWB ...)
// Publication barrier (0xe is ST option)
(PubBarrier mem) => (DMB [0xe] mem)
(PanicBounds [kind] x y mem) && boundsABI(kind) == 0 => (LoweredPanicBoundsA [kind] x y mem)
(PanicBounds [kind] x y mem) && boundsABI(kind) == 1 => (LoweredPanicBoundsB [kind] x y mem)
(PanicBounds [kind] x y mem) && boundsABI(kind) == 2 => (LoweredPanicBoundsC [kind] x y mem)
// Optimizations
// Absorb boolean tests into block
(NZ (Equal cc) yes no) => (EQ cc yes no)
(NZ (NotEqual cc) yes no) => (NE cc yes no)
(NZ (LessThan cc) yes no) => (LT cc yes no)
(NZ (LessThanU cc) yes no) => (ULT cc yes no)
(NZ (LessEqual cc) yes no) => (LE cc yes no)
(NZ (LessEqualU cc) yes no) => (ULE cc yes no)
(NZ (GreaterThan cc) yes no) => (GT cc yes no)
(NZ (GreaterThanU cc) yes no) => (UGT cc yes no)
(NZ (GreaterEqual cc) yes no) => (GE cc yes no)
(NZ (GreaterEqualU cc) yes no) => (UGE cc yes no)
(NZ (LessThanF cc) yes no) => (FLT cc yes no)
(NZ (LessEqualF cc) yes no) => (FLE cc yes no)
(NZ (GreaterThanF cc) yes no) => (FGT cc yes no)
(NZ (GreaterEqualF cc) yes no) => (FGE cc yes no)
(TBNZ [0] (Equal cc) yes no) => (EQ cc yes no)
(TBNZ [0] (NotEqual cc) yes no) => (NE cc yes no)
(TBNZ [0] (LessThan cc) yes no) => (LT cc yes no)
(TBNZ [0] (LessThanU cc) yes no) => (ULT cc yes no)
(TBNZ [0] (LessEqual cc) yes no) => (LE cc yes no)
(TBNZ [0] (LessEqualU cc) yes no) => (ULE cc yes no)
(TBNZ [0] (GreaterThan cc) yes no) => (GT cc yes no)
(TBNZ [0] (GreaterThanU cc) yes no) => (UGT cc yes no)
(TBNZ [0] (GreaterEqual cc) yes no) => (GE cc yes no)
(TBNZ [0] (GreaterEqualU cc) yes no) => (UGE cc yes no)
(TBNZ [0] (LessThanF cc) yes no) => (FLT cc yes no)
(TBNZ [0] (LessEqualF cc) yes no) => (FLE cc yes no)
(TBNZ [0] (GreaterThanF cc) yes no) => (FGT cc yes no)
(TBNZ [0] (GreaterEqualF cc) yes no) => (FGE cc yes no)
((EQ|NE|LT|LE|GT|GE) (CMPconst [0] z:(AND x y)) yes no) && z.Uses == 1 => ((EQ|NE|LT|LE|GT|GE) (TST x y) yes no)
((EQ|NE|LT|LE|GT|GE) (CMPconst [0] x:(ANDconst [c] y)) yes no) && x.Uses == 1 => ((EQ|NE|LT|LE|GT|GE) (TSTconst [c] y) yes no)
((EQ|NE|LT|LE|GT|GE) (CMPWconst [0] z:(AND x y)) yes no) && z.Uses == 1 => ((EQ|NE|LT|LE|GT|GE) (TSTW x y) yes no)
((EQ|NE|LT|LE|GT|GE) (CMPWconst [0] x:(ANDconst [c] y)) yes no) && x.Uses == 1 => ((EQ|NE|LT|LE|GT|GE) (TSTWconst [int32(c)] y) yes no)
// For conditional instructions such as CSET, CSEL.
((Equal|NotEqual|LessThan|LessEqual|GreaterThan|GreaterEqual) (CMPconst [0] z:(AND x y))) && z.Uses == 1 =>
((Equal|NotEqual|LessThan|LessEqual|GreaterThan|GreaterEqual) (TST x y))
((Equal|NotEqual|LessThan|LessEqual|GreaterThan|GreaterEqual) (CMPWconst [0] x:(ANDconst [c] y))) && x.Uses == 1 =>
((Equal|NotEqual|LessThan|LessEqual|GreaterThan|GreaterEqual) (TSTWconst [int32(c)] y))
((Equal|NotEqual|LessThan|LessEqual|GreaterThan|GreaterEqual) (CMPWconst [0] z:(AND x y))) && z.Uses == 1 =>
((Equal|NotEqual|LessThan|LessEqual|GreaterThan|GreaterEqual) (TSTW x y))
((Equal|NotEqual|LessThan|LessEqual|GreaterThan|GreaterEqual) (CMPconst [0] x:(ANDconst [c] y))) && x.Uses == 1 =>
((Equal|NotEqual|LessThan|LessEqual|GreaterThan|GreaterEqual) (TSTconst [c] y))
((EQ|NE|LT|LE|GT|GE) (CMPconst [0] x:(ADDconst [c] y)) yes no) && x.Uses == 1 => ((EQ|NE|LTnoov|LEnoov|GTnoov|GEnoov) (CMNconst [c] y) yes no)
((EQ|NE|LT|LE|GT|GE) (CMPWconst [0] x:(ADDconst [c] y)) yes no) && x.Uses == 1 => ((EQ|NE|LTnoov|LEnoov|GTnoov|GEnoov) (CMNWconst [int32(c)] y) yes no)
((EQ|NE|LT|LE|GT|GE) (CMPconst [0] z:(ADD x y)) yes no) && z.Uses == 1 => ((EQ|NE|LTnoov|LEnoov|GTnoov|GEnoov) (CMN x y) yes no)
((EQ|NE|LT|LE|GT|GE) (CMPWconst [0] z:(ADD x y)) yes no) && z.Uses == 1 => ((EQ|NE|LTnoov|LEnoov|GTnoov|GEnoov) (CMNW x y) yes no)
// CMP(x,-y) -> CMN(x,y) is only valid for unordered comparison, if y can be -1<<63
((EQ|NE) (CMP x z:(NEG y)) yes no) && z.Uses == 1 => ((EQ|NE) (CMN x y) yes no)
((Equal|NotEqual) (CMP x z:(NEG y))) && z.Uses == 1 => ((Equal|NotEqual) (CMN x y))
// CMPW(x,-y) -> CMNW(x,y) is only valid for unordered comparison, if y can be -1<<31
((EQ|NE) (CMPW x z:(NEG y)) yes no) && z.Uses == 1 => ((EQ|NE) (CMNW x y) yes no)
((Equal|NotEqual) (CMPW x z:(NEG y))) && z.Uses == 1 => ((Equal|NotEqual) (CMNW x y))
// For conditional instructions such as CSET, CSEL.
// TODO: add support for LE, GT, overflow needs to be considered.
((Equal|NotEqual|LessThan|GreaterEqual) (CMPconst [0] x:(ADDconst [c] y))) && x.Uses == 1 => ((Equal|NotEqual|LessThanNoov|GreaterEqualNoov) (CMNconst [c] y))
((Equal|NotEqual|LessThan|GreaterEqual) (CMPWconst [0] x:(ADDconst [c] y))) && x.Uses == 1 => ((Equal|NotEqual|LessThanNoov|GreaterEqualNoov) (CMNWconst [int32(c)] y))
((Equal|NotEqual|LessThan|GreaterEqual) (CMPconst [0] z:(ADD x y))) && z.Uses == 1 => ((Equal|NotEqual|LessThanNoov|GreaterEqualNoov) (CMN x y))
((Equal|NotEqual|LessThan|GreaterEqual) (CMPWconst [0] z:(ADD x y))) && z.Uses == 1 => ((Equal|NotEqual|LessThanNoov|GreaterEqualNoov) (CMNW x y))
((Equal|NotEqual|LessThan|GreaterEqual) (CMPconst [0] z:(MADD a x y))) && z.Uses == 1 => ((Equal|NotEqual|LessThanNoov|GreaterEqualNoov) (CMN a (MUL <x.Type> x y)))
((Equal|NotEqual|LessThan|GreaterEqual) (CMPconst [0] z:(MSUB a x y))) && z.Uses == 1 => ((Equal|NotEqual|LessThanNoov|GreaterEqualNoov) (CMP a (MUL <x.Type> x y)))
((Equal|NotEqual|LessThan|GreaterEqual) (CMPWconst [0] z:(MADDW a x y))) && z.Uses == 1 => ((Equal|NotEqual|LessThanNoov|GreaterEqualNoov) (CMNW a (MULW <x.Type> x y)))
((Equal|NotEqual|LessThan|GreaterEqual) (CMPWconst [0] z:(MSUBW a x y))) && z.Uses == 1 => ((Equal|NotEqual|LessThanNoov|GreaterEqualNoov) (CMPW a (MULW <x.Type> x y)))
((CMPconst|CMNconst) [c] y) && c < 0 && c != -1<<63 => ((CMNconst|CMPconst) [-c] y)
((CMPWconst|CMNWconst) [c] y) && c < 0 && c != -1<<31 => ((CMNWconst|CMPWconst) [-c] y)
((EQ|NE) (CMPconst [0] x) yes no) => ((Z|NZ) x yes no)
((EQ|NE) (CMPWconst [0] x) yes no) => ((ZW|NZW) x yes no)
((EQ|NE|LT|LE|GT|GE) (CMPconst [0] z:(MADD a x y)) yes no) && z.Uses==1 => ((EQ|NE|LTnoov|LEnoov|GTnoov|GEnoov) (CMN a (MUL <x.Type> x y)) yes no)
((EQ|NE|LT|LE|GT|GE) (CMPconst [0] z:(MSUB a x y)) yes no) && z.Uses==1 => ((EQ|NE|LTnoov|LEnoov|GTnoov|GEnoov) (CMP a (MUL <x.Type> x y)) yes no)
((EQ|NE|LT|LE|GT|GE) (CMPWconst [0] z:(MADDW a x y)) yes no) && z.Uses==1 => ((EQ|NE|LTnoov|LEnoov|GTnoov|GEnoov) (CMNW a (MULW <x.Type> x y)) yes no)
((EQ|NE|LT|LE|GT|GE) (CMPWconst [0] z:(MSUBW a x y)) yes no) && z.Uses==1 => ((EQ|NE|LTnoov|LEnoov|GTnoov|GEnoov) (CMPW a (MULW <x.Type> x y)) yes no)
// Absorb bit-tests into block
(Z (ANDconst [c] x) yes no) && oneBit(c) => (TBZ [int64(ntz64(c))] x yes no)
(NZ (ANDconst [c] x) yes no) && oneBit(c) => (TBNZ [int64(ntz64(c))] x yes no)
(ZW (ANDconst [c] x) yes no) && oneBit(int64(uint32(c))) => (TBZ [int64(ntz64(int64(uint32(c))))] x yes no)
(NZW (ANDconst [c] x) yes no) && oneBit(int64(uint32(c))) => (TBNZ [int64(ntz64(int64(uint32(c))))] x yes no)
(EQ (TSTconst [c] x) yes no) && oneBit(c) => (TBZ [int64(ntz64(c))] x yes no)
(NE (TSTconst [c] x) yes no) && oneBit(c) => (TBNZ [int64(ntz64(c))] x yes no)
(EQ (TSTWconst [c] x) yes no) && oneBit(int64(uint32(c))) => (TBZ [int64(ntz64(int64(uint32(c))))] x yes no)
(NE (TSTWconst [c] x) yes no) && oneBit(int64(uint32(c))) => (TBNZ [int64(ntz64(int64(uint32(c))))] x yes no)
// Test sign-bit for signed comparisons against zero
(GE (CMPWconst [0] x) yes no) => (TBZ [31] x yes no)
(GE (CMPconst [0] x) yes no) => (TBZ [63] x yes no)
(LT (CMPWconst [0] x) yes no) => (TBNZ [31] x yes no)
(LT (CMPconst [0] x) yes no) => (TBNZ [63] x yes no)
// fold offset into address
(ADDconst [off1] (MOVDaddr [off2] {sym} ptr)) && is32Bit(off1+int64(off2)) =>
(MOVDaddr [int32(off1)+off2] {sym} ptr)
// fold address into load/store.
// Do not fold global variable access in -dynlink mode, where it will
// be rewritten to use the GOT via REGTMP, which currently cannot handle
// large offset.
(MOVBload [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVBload [off1+int32(off2)] {sym} ptr mem)
(MOVBUload [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVBUload [off1+int32(off2)] {sym} ptr mem)
(MOVHload [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVHload [off1+int32(off2)] {sym} ptr mem)
(MOVHUload [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVHUload [off1+int32(off2)] {sym} ptr mem)
(MOVWload [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVWload [off1+int32(off2)] {sym} ptr mem)
(MOVWUload [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVWUload [off1+int32(off2)] {sym} ptr mem)
(MOVDload [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVDload [off1+int32(off2)] {sym} ptr mem)
(LDP [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(LDP [off1+int32(off2)] {sym} ptr mem)
(FMOVSload [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(FMOVSload [off1+int32(off2)] {sym} ptr mem)
(FMOVDload [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(FMOVDload [off1+int32(off2)] {sym} ptr mem)
// register indexed load
(MOVDload [off] {sym} (ADD ptr idx) mem) && off == 0 && sym == nil => (MOVDloadidx ptr idx mem)
(MOVWUload [off] {sym} (ADD ptr idx) mem) && off == 0 && sym == nil => (MOVWUloadidx ptr idx mem)
(MOVWload [off] {sym} (ADD ptr idx) mem) && off == 0 && sym == nil => (MOVWloadidx ptr idx mem)
(MOVHUload [off] {sym} (ADD ptr idx) mem) && off == 0 && sym == nil => (MOVHUloadidx ptr idx mem)
(MOVHload [off] {sym} (ADD ptr idx) mem) && off == 0 && sym == nil => (MOVHloadidx ptr idx mem)
(MOVBUload [off] {sym} (ADD ptr idx) mem) && off == 0 && sym == nil => (MOVBUloadidx ptr idx mem)
(MOVBload [off] {sym} (ADD ptr idx) mem) && off == 0 && sym == nil => (MOVBloadidx ptr idx mem)
(FMOVSload [off] {sym} (ADD ptr idx) mem) && off == 0 && sym == nil => (FMOVSloadidx ptr idx mem)
(FMOVDload [off] {sym} (ADD ptr idx) mem) && off == 0 && sym == nil => (FMOVDloadidx ptr idx mem)
(MOVDloadidx ptr (MOVDconst [c]) mem) && is32Bit(c) => (MOVDload [int32(c)] ptr mem)
(MOVDloadidx (MOVDconst [c]) ptr mem) && is32Bit(c) => (MOVDload [int32(c)] ptr mem)
(MOVWUloadidx ptr (MOVDconst [c]) mem) && is32Bit(c) => (MOVWUload [int32(c)] ptr mem)
(MOVWUloadidx (MOVDconst [c]) ptr mem) && is32Bit(c) => (MOVWUload [int32(c)] ptr mem)
(MOVWloadidx ptr (MOVDconst [c]) mem) && is32Bit(c) => (MOVWload [int32(c)] ptr mem)
(MOVWloadidx (MOVDconst [c]) ptr mem) && is32Bit(c) => (MOVWload [int32(c)] ptr mem)
(MOVHUloadidx ptr (MOVDconst [c]) mem) && is32Bit(c) => (MOVHUload [int32(c)] ptr mem)
(MOVHUloadidx (MOVDconst [c]) ptr mem) && is32Bit(c) => (MOVHUload [int32(c)] ptr mem)
(MOVHloadidx ptr (MOVDconst [c]) mem) && is32Bit(c) => (MOVHload [int32(c)] ptr mem)
(MOVHloadidx (MOVDconst [c]) ptr mem) && is32Bit(c) => (MOVHload [int32(c)] ptr mem)
(MOVBUloadidx ptr (MOVDconst [c]) mem) && is32Bit(c) => (MOVBUload [int32(c)] ptr mem)
(MOVBUloadidx (MOVDconst [c]) ptr mem) && is32Bit(c) => (MOVBUload [int32(c)] ptr mem)
(MOVBloadidx ptr (MOVDconst [c]) mem) && is32Bit(c) => (MOVBload [int32(c)] ptr mem)
(MOVBloadidx (MOVDconst [c]) ptr mem) && is32Bit(c) => (MOVBload [int32(c)] ptr mem)
(FMOVSloadidx ptr (MOVDconst [c]) mem) && is32Bit(c) => (FMOVSload [int32(c)] ptr mem)
(FMOVSloadidx (MOVDconst [c]) ptr mem) && is32Bit(c) => (FMOVSload [int32(c)] ptr mem)
(FMOVDloadidx ptr (MOVDconst [c]) mem) && is32Bit(c) => (FMOVDload [int32(c)] ptr mem)
(FMOVDloadidx (MOVDconst [c]) ptr mem) && is32Bit(c) => (FMOVDload [int32(c)] ptr mem)
// shifted register indexed load
(MOVDload [off] {sym} (ADDshiftLL [3] ptr idx) mem) && off == 0 && sym == nil => (MOVDloadidx8 ptr idx mem)
(MOVWUload [off] {sym} (ADDshiftLL [2] ptr idx) mem) && off == 0 && sym == nil => (MOVWUloadidx4 ptr idx mem)
(MOVWload [off] {sym} (ADDshiftLL [2] ptr idx) mem) && off == 0 && sym == nil => (MOVWloadidx4 ptr idx mem)
(MOVHUload [off] {sym} (ADDshiftLL [1] ptr idx) mem) && off == 0 && sym == nil => (MOVHUloadidx2 ptr idx mem)
(MOVHload [off] {sym} (ADDshiftLL [1] ptr idx) mem) && off == 0 && sym == nil => (MOVHloadidx2 ptr idx mem)
(MOVDloadidx ptr (SLLconst [3] idx) mem) => (MOVDloadidx8 ptr idx mem)
(MOVWloadidx ptr (SLLconst [2] idx) mem) => (MOVWloadidx4 ptr idx mem)
(MOVWUloadidx ptr (SLLconst [2] idx) mem) => (MOVWUloadidx4 ptr idx mem)
(MOVHloadidx ptr (SLLconst [1] idx) mem) => (MOVHloadidx2 ptr idx mem)
(MOVHUloadidx ptr (SLLconst [1] idx) mem) => (MOVHUloadidx2 ptr idx mem)
(MOVHloadidx ptr (ADD idx idx) mem) => (MOVHloadidx2 ptr idx mem)
(MOVHUloadidx ptr (ADD idx idx) mem) => (MOVHUloadidx2 ptr idx mem)
(MOVDloadidx (SLLconst [3] idx) ptr mem) => (MOVDloadidx8 ptr idx mem)
(MOVWloadidx (SLLconst [2] idx) ptr mem) => (MOVWloadidx4 ptr idx mem)
(MOVWUloadidx (SLLconst [2] idx) ptr mem) => (MOVWUloadidx4 ptr idx mem)
(MOVHloadidx (ADD idx idx) ptr mem) => (MOVHloadidx2 ptr idx mem)
(MOVHUloadidx (ADD idx idx) ptr mem) => (MOVHUloadidx2 ptr idx mem)
(MOVDloadidx8 ptr (MOVDconst [c]) mem) && is32Bit(c<<3) => (MOVDload [int32(c)<<3] ptr mem)
(MOVWUloadidx4 ptr (MOVDconst [c]) mem) && is32Bit(c<<2) => (MOVWUload [int32(c)<<2] ptr mem)
(MOVWloadidx4 ptr (MOVDconst [c]) mem) && is32Bit(c<<2) => (MOVWload [int32(c)<<2] ptr mem)
(MOVHUloadidx2 ptr (MOVDconst [c]) mem) && is32Bit(c<<1) => (MOVHUload [int32(c)<<1] ptr mem)
(MOVHloadidx2 ptr (MOVDconst [c]) mem) && is32Bit(c<<1) => (MOVHload [int32(c)<<1] ptr mem)
(FMOVDload [off] {sym} (ADDshiftLL [3] ptr idx) mem) && off == 0 && sym == nil => (FMOVDloadidx8 ptr idx mem)
(FMOVSload [off] {sym} (ADDshiftLL [2] ptr idx) mem) && off == 0 && sym == nil => (FMOVSloadidx4 ptr idx mem)
(FMOVDloadidx ptr (SLLconst [3] idx) mem) => (FMOVDloadidx8 ptr idx mem)
(FMOVSloadidx ptr (SLLconst [2] idx) mem) => (FMOVSloadidx4 ptr idx mem)
(FMOVDloadidx (SLLconst [3] idx) ptr mem) => (FMOVDloadidx8 ptr idx mem)
(FMOVSloadidx (SLLconst [2] idx) ptr mem) => (FMOVSloadidx4 ptr idx mem)
(FMOVDloadidx8 ptr (MOVDconst [c]) mem) && is32Bit(c<<3) => (FMOVDload ptr [int32(c)<<3] mem)
(FMOVSloadidx4 ptr (MOVDconst [c]) mem) && is32Bit(c<<2) => (FMOVSload ptr [int32(c)<<2] mem)
(MOVBstore [off1] {sym} (ADDconst [off2] ptr) val mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVBstore [off1+int32(off2)] {sym} ptr val mem)
(MOVHstore [off1] {sym} (ADDconst [off2] ptr) val mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVHstore [off1+int32(off2)] {sym} ptr val mem)
(MOVWstore [off1] {sym} (ADDconst [off2] ptr) val mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVWstore [off1+int32(off2)] {sym} ptr val mem)
(MOVDstore [off1] {sym} (ADDconst [off2] ptr) val mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVDstore [off1+int32(off2)] {sym} ptr val mem)
(STP [off1] {sym} (ADDconst [off2] ptr) val1 val2 mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(STP [off1+int32(off2)] {sym} ptr val1 val2 mem)
(FMOVSstore [off1] {sym} (ADDconst [off2] ptr) val mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(FMOVSstore [off1+int32(off2)] {sym} ptr val mem)
(FMOVDstore [off1] {sym} (ADDconst [off2] ptr) val mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(FMOVDstore [off1+int32(off2)] {sym} ptr val mem)
(MOVBstorezero [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVBstorezero [off1+int32(off2)] {sym} ptr mem)
(MOVHstorezero [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVHstorezero [off1+int32(off2)] {sym} ptr mem)
(MOVWstorezero [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVWstorezero [off1+int32(off2)] {sym} ptr mem)
(MOVDstorezero [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVDstorezero [off1+int32(off2)] {sym} ptr mem)
(MOVQstorezero [off1] {sym} (ADDconst [off2] ptr) mem) && is32Bit(int64(off1)+off2)
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVQstorezero [off1+int32(off2)] {sym} ptr mem)
// register indexed store
(MOVDstore [off] {sym} (ADD ptr idx) val mem) && off == 0 && sym == nil => (MOVDstoreidx ptr idx val mem)
(MOVWstore [off] {sym} (ADD ptr idx) val mem) && off == 0 && sym == nil => (MOVWstoreidx ptr idx val mem)
(MOVHstore [off] {sym} (ADD ptr idx) val mem) && off == 0 && sym == nil => (MOVHstoreidx ptr idx val mem)
(MOVBstore [off] {sym} (ADD ptr idx) val mem) && off == 0 && sym == nil => (MOVBstoreidx ptr idx val mem)
(FMOVDstore [off] {sym} (ADD ptr idx) val mem) && off == 0 && sym == nil => (FMOVDstoreidx ptr idx val mem)
(FMOVSstore [off] {sym} (ADD ptr idx) val mem) && off == 0 && sym == nil => (FMOVSstoreidx ptr idx val mem)
(MOVDstoreidx ptr (MOVDconst [c]) val mem) && is32Bit(c) => (MOVDstore [int32(c)] ptr val mem)
(MOVDstoreidx (MOVDconst [c]) idx val mem) && is32Bit(c) => (MOVDstore [int32(c)] idx val mem)
(MOVWstoreidx ptr (MOVDconst [c]) val mem) && is32Bit(c) => (MOVWstore [int32(c)] ptr val mem)
(MOVWstoreidx (MOVDconst [c]) idx val mem) && is32Bit(c) => (MOVWstore [int32(c)] idx val mem)
(MOVHstoreidx ptr (MOVDconst [c]) val mem) && is32Bit(c) => (MOVHstore [int32(c)] ptr val mem)
(MOVHstoreidx (MOVDconst [c]) idx val mem) && is32Bit(c) => (MOVHstore [int32(c)] idx val mem)
(MOVBstoreidx ptr (MOVDconst [c]) val mem) && is32Bit(c) => (MOVBstore [int32(c)] ptr val mem)
(MOVBstoreidx (MOVDconst [c]) idx val mem) && is32Bit(c) => (MOVBstore [int32(c)] idx val mem)
(FMOVDstoreidx ptr (MOVDconst [c]) val mem) && is32Bit(c) => (FMOVDstore [int32(c)] ptr val mem)
(FMOVDstoreidx (MOVDconst [c]) idx val mem) && is32Bit(c) => (FMOVDstore [int32(c)] idx val mem)
(FMOVSstoreidx ptr (MOVDconst [c]) val mem) && is32Bit(c) => (FMOVSstore [int32(c)] ptr val mem)
(FMOVSstoreidx (MOVDconst [c]) idx val mem) && is32Bit(c) => (FMOVSstore [int32(c)] idx val mem)
// shifted register indexed store
(MOVDstore [off] {sym} (ADDshiftLL [3] ptr idx) val mem) && off == 0 && sym == nil => (MOVDstoreidx8 ptr idx val mem)
(MOVWstore [off] {sym} (ADDshiftLL [2] ptr idx) val mem) && off == 0 && sym == nil => (MOVWstoreidx4 ptr idx val mem)
(MOVHstore [off] {sym} (ADDshiftLL [1] ptr idx) val mem) && off == 0 && sym == nil => (MOVHstoreidx2 ptr idx val mem)
(MOVDstoreidx ptr (SLLconst [3] idx) val mem) => (MOVDstoreidx8 ptr idx val mem)
(MOVWstoreidx ptr (SLLconst [2] idx) val mem) => (MOVWstoreidx4 ptr idx val mem)
(MOVHstoreidx ptr (SLLconst [1] idx) val mem) => (MOVHstoreidx2 ptr idx val mem)
(MOVHstoreidx ptr (ADD idx idx) val mem) => (MOVHstoreidx2 ptr idx val mem)
(MOVDstoreidx (SLLconst [3] idx) ptr val mem) => (MOVDstoreidx8 ptr idx val mem)
(MOVWstoreidx (SLLconst [2] idx) ptr val mem) => (MOVWstoreidx4 ptr idx val mem)
(MOVHstoreidx (SLLconst [1] idx) ptr val mem) => (MOVHstoreidx2 ptr idx val mem)
(MOVHstoreidx (ADD idx idx) ptr val mem) => (MOVHstoreidx2 ptr idx val mem)
(MOVDstoreidx8 ptr (MOVDconst [c]) val mem) && is32Bit(c<<3) => (MOVDstore [int32(c)<<3] ptr val mem)
(MOVWstoreidx4 ptr (MOVDconst [c]) val mem) && is32Bit(c<<2) => (MOVWstore [int32(c)<<2] ptr val mem)
(MOVHstoreidx2 ptr (MOVDconst [c]) val mem) && is32Bit(c<<1) => (MOVHstore [int32(c)<<1] ptr val mem)
(FMOVDstore [off] {sym} (ADDshiftLL [3] ptr idx) val mem) && off == 0 && sym == nil => (FMOVDstoreidx8 ptr idx val mem)
(FMOVSstore [off] {sym} (ADDshiftLL [2] ptr idx) val mem) && off == 0 && sym == nil => (FMOVSstoreidx4 ptr idx val mem)
(FMOVDstoreidx ptr (SLLconst [3] idx) val mem) => (FMOVDstoreidx8 ptr idx val mem)
(FMOVSstoreidx ptr (SLLconst [2] idx) val mem) => (FMOVSstoreidx4 ptr idx val mem)
(FMOVDstoreidx (SLLconst [3] idx) ptr val mem) => (FMOVDstoreidx8 ptr idx val mem)
(FMOVSstoreidx (SLLconst [2] idx) ptr val mem) => (FMOVSstoreidx4 ptr idx val mem)
(FMOVDstoreidx8 ptr (MOVDconst [c]) val mem) && is32Bit(c<<3) => (FMOVDstore [int32(c)<<3] ptr val mem)
(FMOVSstoreidx4 ptr (MOVDconst [c]) val mem) && is32Bit(c<<2) => (FMOVSstore [int32(c)<<2] ptr val mem)
(MOVBload [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVBload [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(MOVBUload [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVBUload [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(MOVHload [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVHload [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(MOVHUload [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVHUload [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(MOVWload [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVWload [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(MOVWUload [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVWUload [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(MOVDload [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVDload [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(LDP [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(LDP [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(FMOVSload [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(FMOVSload [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(FMOVDload [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(FMOVDload [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(MOVBstore [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) val mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVBstore [off1+off2] {mergeSym(sym1,sym2)} ptr val mem)
(MOVHstore [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) val mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVHstore [off1+off2] {mergeSym(sym1,sym2)} ptr val mem)
(MOVWstore [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) val mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVWstore [off1+off2] {mergeSym(sym1,sym2)} ptr val mem)
(MOVDstore [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) val mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVDstore [off1+off2] {mergeSym(sym1,sym2)} ptr val mem)
(STP [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) val1 val2 mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(STP [off1+off2] {mergeSym(sym1,sym2)} ptr val1 val2 mem)
(FMOVSstore [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) val mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(FMOVSstore [off1+off2] {mergeSym(sym1,sym2)} ptr val mem)
(FMOVDstore [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) val mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(FMOVDstore [off1+off2] {mergeSym(sym1,sym2)} ptr val mem)
(MOVBstorezero [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVBstorezero [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(MOVHstorezero [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVHstorezero [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(MOVWstorezero [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVWstorezero [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(MOVDstorezero [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVDstorezero [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
(MOVQstorezero [off1] {sym1} (MOVDaddr [off2] {sym2} ptr) mem)
&& canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2))
&& (ptr.Op != OpSB || !config.ctxt.Flag_dynlink) =>
(MOVQstorezero [off1+off2] {mergeSym(sym1,sym2)} ptr mem)
// store zero
(MOVBstore [off] {sym} ptr (MOVDconst [0]) mem) => (MOVBstorezero [off] {sym} ptr mem)
(MOVHstore [off] {sym} ptr (MOVDconst [0]) mem) => (MOVHstorezero [off] {sym} ptr mem)
(MOVWstore [off] {sym} ptr (MOVDconst [0]) mem) => (MOVWstorezero [off] {sym} ptr mem)
(MOVDstore [off] {sym} ptr (MOVDconst [0]) mem) => (MOVDstorezero [off] {sym} ptr mem)
(STP [off] {sym} ptr (MOVDconst [0]) (MOVDconst [0]) mem) => (MOVQstorezero [off] {sym} ptr mem)
// register indexed store zero
(MOVDstorezero [off] {sym} (ADD ptr idx) mem) && off == 0 && sym == nil => (MOVDstorezeroidx ptr idx mem)
(MOVWstorezero [off] {sym} (ADD ptr idx) mem) && off == 0 && sym == nil => (MOVWstorezeroidx ptr idx mem)
(MOVHstorezero [off] {sym} (ADD ptr idx) mem) && off == 0 && sym == nil => (MOVHstorezeroidx ptr idx mem)
(MOVBstorezero [off] {sym} (ADD ptr idx) mem) && off == 0 && sym == nil => (MOVBstorezeroidx ptr idx mem)
(MOVDstoreidx ptr idx (MOVDconst [0]) mem) => (MOVDstorezeroidx ptr idx mem)
(MOVWstoreidx ptr idx (MOVDconst [0]) mem) => (MOVWstorezeroidx ptr idx mem)
(MOVHstoreidx ptr idx (MOVDconst [0]) mem) => (MOVHstorezeroidx ptr idx mem)
(MOVBstoreidx ptr idx (MOVDconst [0]) mem) => (MOVBstorezeroidx ptr idx mem)
(MOVDstorezeroidx ptr (MOVDconst [c]) mem) && is32Bit(c) => (MOVDstorezero [int32(c)] ptr mem)
(MOVDstorezeroidx (MOVDconst [c]) idx mem) && is32Bit(c) => (MOVDstorezero [int32(c)] idx mem)
(MOVWstorezeroidx ptr (MOVDconst [c]) mem) && is32Bit(c) => (MOVWstorezero [int32(c)] ptr mem)
(MOVWstorezeroidx (MOVDconst [c]) idx mem) && is32Bit(c) => (MOVWstorezero [int32(c)] idx mem)
(MOVHstorezeroidx ptr (MOVDconst [c]) mem) && is32Bit(c) => (MOVHstorezero [int32(c)] ptr mem)
(MOVHstorezeroidx (MOVDconst [c]) idx mem) && is32Bit(c) => (MOVHstorezero [int32(c)] idx mem)
(MOVBstorezeroidx ptr (MOVDconst [c]) mem) && is32Bit(c) => (MOVBstorezero [int32(c)] ptr mem)
(MOVBstorezeroidx (MOVDconst [c]) idx mem) && is32Bit(c) => (MOVBstorezero [int32(c)] idx mem)
// shifted register indexed store zero
(MOVDstorezero [off] {sym} (ADDshiftLL [3] ptr idx) mem) && off == 0 && sym == nil => (MOVDstorezeroidx8 ptr idx mem)
(MOVWstorezero [off] {sym} (ADDshiftLL [2] ptr idx) mem) && off == 0 && sym == nil => (MOVWstorezeroidx4 ptr idx mem)
(MOVHstorezero [off] {sym} (ADDshiftLL [1] ptr idx) mem) && off == 0 && sym == nil => (MOVHstorezeroidx2 ptr idx mem)
(MOVDstorezeroidx ptr (SLLconst [3] idx) mem) => (MOVDstorezeroidx8 ptr idx mem)
(MOVWstorezeroidx ptr (SLLconst [2] idx) mem) => (MOVWstorezeroidx4 ptr idx mem)
(MOVHstorezeroidx ptr (SLLconst [1] idx) mem) => (MOVHstorezeroidx2 ptr idx mem)
(MOVHstorezeroidx ptr (ADD idx idx) mem) => (MOVHstorezeroidx2 ptr idx mem)
(MOVDstorezeroidx (SLLconst [3] idx) ptr mem) => (MOVDstorezeroidx8 ptr idx mem)
(MOVWstorezeroidx (SLLconst [2] idx) ptr mem) => (MOVWstorezeroidx4 ptr idx mem)
(MOVHstorezeroidx (SLLconst [1] idx) ptr mem) => (MOVHstorezeroidx2 ptr idx mem)
(MOVHstorezeroidx (ADD idx idx) ptr mem) => (MOVHstorezeroidx2 ptr idx mem)
(MOVDstoreidx8 ptr idx (MOVDconst [0]) mem) => (MOVDstorezeroidx8 ptr idx mem)
(MOVWstoreidx4 ptr idx (MOVDconst [0]) mem) => (MOVWstorezeroidx4 ptr idx mem)
(MOVHstoreidx2 ptr idx (MOVDconst [0]) mem) => (MOVHstorezeroidx2 ptr idx mem)
(MOVDstorezeroidx8 ptr (MOVDconst [c]) mem) && is32Bit(c<<3) => (MOVDstorezero [int32(c<<3)] ptr mem)
(MOVWstorezeroidx4 ptr (MOVDconst [c]) mem) && is32Bit(c<<2) => (MOVWstorezero [int32(c<<2)] ptr mem)
(MOVHstorezeroidx2 ptr (MOVDconst [c]) mem) && is32Bit(c<<1) => (MOVHstorezero [int32(c<<1)] ptr mem)
// replace load from same location as preceding store with zero/sign extension (or copy in case of full width)
// these seem to have bad interaction with other rules, resulting in slower code
//(MOVBload [off] {sym} ptr (MOVBstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) -> (MOVBreg x)
//(MOVBUload [off] {sym} ptr (MOVBstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) -> (MOVBUreg x)
//(MOVHload [off] {sym} ptr (MOVHstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) -> (MOVHreg x)
//(MOVHUload [off] {sym} ptr (MOVHstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) -> (MOVHUreg x)
//(MOVWload [off] {sym} ptr (MOVWstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) -> (MOVWreg x)
//(MOVWUload [off] {sym} ptr (MOVWstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) -> (MOVWUreg x)
//(MOVDload [off] {sym} ptr (MOVDstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) -> x
//(FMOVSload [off] {sym} ptr (FMOVSstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) -> x
//(FMOVDload [off] {sym} ptr (FMOVDstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) -> x
//(LDP [off] {sym} ptr (STP [off2] {sym2} ptr2 x y _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) -> x y
(MOVBload [off] {sym} ptr (MOVBstorezero [off2] {sym2} ptr2 _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) => (MOVDconst [0])
(MOVBUload [off] {sym} ptr (MOVBstorezero [off2] {sym2} ptr2 _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) => (MOVDconst [0])
(MOVHload [off] {sym} ptr (MOVHstorezero [off2] {sym2} ptr2 _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) => (MOVDconst [0])
(MOVHUload [off] {sym} ptr (MOVHstorezero [off2] {sym2} ptr2 _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) => (MOVDconst [0])
(MOVWload [off] {sym} ptr (MOVWstorezero [off2] {sym2} ptr2 _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) => (MOVDconst [0])
(MOVWUload [off] {sym} ptr (MOVWstorezero [off2] {sym2} ptr2 _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) => (MOVDconst [0])
(MOVDload [off] {sym} ptr (MOVDstorezero [off2] {sym2} ptr2 _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) => (MOVDconst [0])
(MOVBloadidx ptr idx (MOVBstorezeroidx ptr2 idx2 _))
&& (isSamePtr(ptr, ptr2) && isSamePtr(idx, idx2) || isSamePtr(ptr, idx2) && isSamePtr(idx, ptr2)) => (MOVDconst [0])
(MOVBUloadidx ptr idx (MOVBstorezeroidx ptr2 idx2 _))
&& (isSamePtr(ptr, ptr2) && isSamePtr(idx, idx2) || isSamePtr(ptr, idx2) && isSamePtr(idx, ptr2)) => (MOVDconst [0])
(MOVHloadidx ptr idx (MOVHstorezeroidx ptr2 idx2 _))
&& (isSamePtr(ptr, ptr2) && isSamePtr(idx, idx2) || isSamePtr(ptr, idx2) && isSamePtr(idx, ptr2)) => (MOVDconst [0])
(MOVHUloadidx ptr idx (MOVHstorezeroidx ptr2 idx2 _))
&& (isSamePtr(ptr, ptr2) && isSamePtr(idx, idx2) || isSamePtr(ptr, idx2) && isSamePtr(idx, ptr2)) => (MOVDconst [0])
(MOVWloadidx ptr idx (MOVWstorezeroidx ptr2 idx2 _))
&& (isSamePtr(ptr, ptr2) && isSamePtr(idx, idx2) || isSamePtr(ptr, idx2) && isSamePtr(idx, ptr2)) => (MOVDconst [0])
(MOVWUloadidx ptr idx (MOVWstorezeroidx ptr2 idx2 _))
&& (isSamePtr(ptr, ptr2) && isSamePtr(idx, idx2) || isSamePtr(ptr, idx2) && isSamePtr(idx, ptr2)) => (MOVDconst [0])
(MOVDloadidx ptr idx (MOVDstorezeroidx ptr2 idx2 _))
&& (isSamePtr(ptr, ptr2) && isSamePtr(idx, idx2) || isSamePtr(ptr, idx2) && isSamePtr(idx, ptr2)) => (MOVDconst [0])
(MOVHloadidx2 ptr idx (MOVHstorezeroidx2 ptr2 idx2 _)) && isSamePtr(ptr, ptr2) && isSamePtr(idx, idx2) => (MOVDconst [0])
(MOVHUloadidx2 ptr idx (MOVHstorezeroidx2 ptr2 idx2 _)) && isSamePtr(ptr, ptr2) && isSamePtr(idx, idx2) => (MOVDconst [0])
(MOVWloadidx4 ptr idx (MOVWstorezeroidx4 ptr2 idx2 _)) && isSamePtr(ptr, ptr2) && isSamePtr(idx, idx2) => (MOVDconst [0])
(MOVWUloadidx4 ptr idx (MOVWstorezeroidx4 ptr2 idx2 _)) && isSamePtr(ptr, ptr2) && isSamePtr(idx, idx2) => (MOVDconst [0])
(MOVDloadidx8 ptr idx (MOVDstorezeroidx8 ptr2 idx2 _)) && isSamePtr(ptr, ptr2) && isSamePtr(idx, idx2) => (MOVDconst [0])
// don't extend before store
(MOVBstore [off] {sym} ptr (MOVBreg x) mem) => (MOVBstore [off] {sym} ptr x mem)
(MOVBstore [off] {sym} ptr (MOVBUreg x) mem) => (MOVBstore [off] {sym} ptr x mem)
(MOVBstore [off] {sym} ptr (MOVHreg x) mem) => (MOVBstore [off] {sym} ptr x mem)
(MOVBstore [off] {sym} ptr (MOVHUreg x) mem) => (MOVBstore [off] {sym} ptr x mem)
(MOVBstore [off] {sym} ptr (MOVWreg x) mem) => (MOVBstore [off] {sym} ptr x mem)
(MOVBstore [off] {sym} ptr (MOVWUreg x) mem) => (MOVBstore [off] {sym} ptr x mem)
(MOVHstore [off] {sym} ptr (MOVHreg x) mem) => (MOVHstore [off] {sym} ptr x mem)
(MOVHstore [off] {sym} ptr (MOVHUreg x) mem) => (MOVHstore [off] {sym} ptr x mem)
(MOVHstore [off] {sym} ptr (MOVWreg x) mem) => (MOVHstore [off] {sym} ptr x mem)
(MOVHstore [off] {sym} ptr (MOVWUreg x) mem) => (MOVHstore [off] {sym} ptr x mem)
(MOVWstore [off] {sym} ptr (MOVWreg x) mem) => (MOVWstore [off] {sym} ptr x mem)
(MOVWstore [off] {sym} ptr (MOVWUreg x) mem) => (MOVWstore [off] {sym} ptr x mem)
(MOVBstoreidx ptr idx (MOVBreg x) mem) => (MOVBstoreidx ptr idx x mem)
(MOVBstoreidx ptr idx (MOVBUreg x) mem) => (MOVBstoreidx ptr idx x mem)
(MOVBstoreidx ptr idx (MOVHreg x) mem) => (MOVBstoreidx ptr idx x mem)
(MOVBstoreidx ptr idx (MOVHUreg x) mem) => (MOVBstoreidx ptr idx x mem)
(MOVBstoreidx ptr idx (MOVWreg x) mem) => (MOVBstoreidx ptr idx x mem)
(MOVBstoreidx ptr idx (MOVWUreg x) mem) => (MOVBstoreidx ptr idx x mem)
(MOVHstoreidx ptr idx (MOVHreg x) mem) => (MOVHstoreidx ptr idx x mem)
(MOVHstoreidx ptr idx (MOVHUreg x) mem) => (MOVHstoreidx ptr idx x mem)
(MOVHstoreidx ptr idx (MOVWreg x) mem) => (MOVHstoreidx ptr idx x mem)
(MOVHstoreidx ptr idx (MOVWUreg x) mem) => (MOVHstoreidx ptr idx x mem)
(MOVWstoreidx ptr idx (MOVWreg x) mem) => (MOVWstoreidx ptr idx x mem)
(MOVWstoreidx ptr idx (MOVWUreg x) mem) => (MOVWstoreidx ptr idx x mem)
(MOVHstoreidx2 ptr idx (MOVHreg x) mem) => (MOVHstoreidx2 ptr idx x mem)
(MOVHstoreidx2 ptr idx (MOVHUreg x) mem) => (MOVHstoreidx2 ptr idx x mem)
(MOVHstoreidx2 ptr idx (MOVWreg x) mem) => (MOVHstoreidx2 ptr idx x mem)
(MOVHstoreidx2 ptr idx (MOVWUreg x) mem) => (MOVHstoreidx2 ptr idx x mem)
(MOVWstoreidx4 ptr idx (MOVWreg x) mem) => (MOVWstoreidx4 ptr idx x mem)
(MOVWstoreidx4 ptr idx (MOVWUreg x) mem) => (MOVWstoreidx4 ptr idx x mem)
// if a register move has only 1 use, just use the same register without emitting instruction
// MOVDnop doesn't emit instruction, only for ensuring the type.
(MOVDreg x) && x.Uses == 1 => (MOVDnop x)
// TODO: we should be able to get rid of MOVDnop all together.
// But for now, this is enough to get rid of lots of them.
(MOVDnop (MOVDconst [c])) => (MOVDconst [c])
// fold constant into arithmetic ops
(ADD x (MOVDconst <t> [c])) && !t.IsPtr() => (ADDconst [c] x)
(SUB x (MOVDconst [c])) => (SUBconst [c] x)
(AND x (MOVDconst [c])) => (ANDconst [c] x)
(OR x (MOVDconst [c])) => (ORconst [c] x)
(XOR x (MOVDconst [c])) => (XORconst [c] x)
(TST x (MOVDconst [c])) => (TSTconst [c] x)
(TSTW x (MOVDconst [c])) => (TSTWconst [int32(c)] x)
(CMN x (MOVDconst [c])) => (CMNconst [c] x)
(CMNW x (MOVDconst [c])) => (CMNWconst [int32(c)] x)
(BIC x (MOVDconst [c])) => (ANDconst [^c] x)
(EON x (MOVDconst [c])) => (XORconst [^c] x)
(ORN x (MOVDconst [c])) => (ORconst [^c] x)
(SLL x (MOVDconst [c])) => (SLLconst x [c&63])
(SRL x (MOVDconst [c])) => (SRLconst x [c&63])
(SRA x (MOVDconst [c])) => (SRAconst x [c&63])
(SLL x (ANDconst [63] y)) => (SLL x y)
(SRL x (ANDconst [63] y)) => (SRL x y)
(SRA x (ANDconst [63] y)) => (SRA x y)
(CMP x (MOVDconst [c])) => (CMPconst [c] x)
(CMP (MOVDconst [c]) x) => (InvertFlags (CMPconst [c] x))
(CMPW x (MOVDconst [c])) => (CMPWconst [int32(c)] x)
(CMPW (MOVDconst [c]) x) => (InvertFlags (CMPWconst [int32(c)] x))
(ROR x (MOVDconst [c])) => (RORconst x [c&63])
(RORW x (MOVDconst [c])) => (RORWconst x [c&31])
(ADDSflags x (MOVDconst [c])) => (ADDSconstflags [c] x)
(ADDconst [c] y) && c < 0 => (SUBconst [-c] y)
// Canonicalize the order of arguments to comparisons - helps with CSE.
((CMP|CMPW) x y) && canonLessThan(x,y) => (InvertFlags ((CMP|CMPW) y x))
// mul-neg => mneg
(NEG (MUL x y)) => (MNEG x y)
(NEG (MULW x y)) && v.Type.Size() <= 4 => (MNEGW x y)
(MUL (NEG x) y) => (MNEG x y)
(MULW (NEG x) y) => (MNEGW x y)
// madd/msub
(ADD a l:(MUL x y)) && l.Uses==1 && clobber(l) => (MADD a x y)
(SUB a l:(MUL x y)) && l.Uses==1 && clobber(l) => (MSUB a x y)
(ADD a l:(MNEG x y)) && l.Uses==1 && clobber(l) => (MSUB a x y)
(SUB a l:(MNEG x y)) && l.Uses==1 && clobber(l) => (MADD a x y)
(ADD a l:(MULW x y)) && v.Type.Size() <= 4 && l.Uses==1 && clobber(l) => (MADDW a x y)
(SUB a l:(MULW x y)) && v.Type.Size() <= 4 && l.Uses==1 && clobber(l) => (MSUBW a x y)
(ADD a l:(MNEGW x y)) && v.Type.Size() <= 4 && l.Uses==1 && clobber(l) => (MSUBW a x y)
(SUB a l:(MNEGW x y)) && v.Type.Size() <= 4 && l.Uses==1 && clobber(l) => (MADDW a x y)
// optimize ADCSflags, SBCSflags and friends
(ADCSflags x y (Select1 <types.TypeFlags> (ADDSconstflags [-1] (ADCzerocarry <typ.UInt64> c)))) => (ADCSflags x y c)
(ADCSflags x y (Select1 <types.TypeFlags> (ADDSconstflags [-1] (MOVDconst [0])))) => (ADDSflags x y)
(SBCSflags x y (Select1 <types.TypeFlags> (NEGSflags (NEG <typ.UInt64> (NGCzerocarry <typ.UInt64> bo))))) => (SBCSflags x y bo)
(SBCSflags x y (Select1 <types.TypeFlags> (NEGSflags (MOVDconst [0])))) => (SUBSflags x y)
// mul by constant
(MUL x (MOVDconst [-1])) => (NEG x)
(MUL _ (MOVDconst [0])) => (MOVDconst [0])
(MUL x (MOVDconst [1])) => x
(MUL x (MOVDconst [c])) && isPowerOfTwo64(c) => (SLLconst [log64(c)] x)
(MUL x (MOVDconst [c])) && isPowerOfTwo64(c-1) && c >= 3 => (ADDshiftLL x x [log64(c-1)])
(MUL x (MOVDconst [c])) && isPowerOfTwo64(c+1) && c >= 7 => (ADDshiftLL (NEG <x.Type> x) x [log64(c+1)])
(MUL x (MOVDconst [c])) && c%3 == 0 && isPowerOfTwo64(c/3) => (SLLconst [log64(c/3)] (ADDshiftLL <x.Type> x x [1]))
(MUL x (MOVDconst [c])) && c%5 == 0 && isPowerOfTwo64(c/5) => (SLLconst [log64(c/5)] (ADDshiftLL <x.Type> x x [2]))
(MUL x (MOVDconst [c])) && c%7 == 0 && isPowerOfTwo64(c/7) => (SLLconst [log64(c/7)] (ADDshiftLL <x.Type> (NEG <x.Type> x) x [3]))
(MUL x (MOVDconst [c])) && c%9 == 0 && isPowerOfTwo64(c/9) => (SLLconst [log64(c/9)] (ADDshiftLL <x.Type> x x [3]))
(MULW x (MOVDconst [c])) && int32(c)==-1 => (MOVWUreg (NEG <x.Type> x))
(MULW _ (MOVDconst [c])) && int32(c)==0 => (MOVDconst [0])
(MULW x (MOVDconst [c])) && int32(c)==1 => (MOVWUreg x)
(MULW x (MOVDconst [c])) && isPowerOfTwo64(c) => (MOVWUreg (SLLconst <x.Type> [log64(c)] x))
(MULW x (MOVDconst [c])) && isPowerOfTwo64(c-1) && int32(c) >= 3 => (MOVWUreg (ADDshiftLL <x.Type> x x [log64(c-1)]))
(MULW x (MOVDconst [c])) && isPowerOfTwo64(c+1) && int32(c) >= 7 => (MOVWUreg (ADDshiftLL <x.Type> (NEG <x.Type> x) x [log64(c+1)]))
(MULW x (MOVDconst [c])) && c%3 == 0 && isPowerOfTwo64(c/3) && is32Bit(c) => (MOVWUreg (SLLconst <x.Type> [log64(c/3)] (ADDshiftLL <x.Type> x x [1])))
(MULW x (MOVDconst [c])) && c%5 == 0 && isPowerOfTwo64(c/5) && is32Bit(c) => (MOVWUreg (SLLconst <x.Type> [log64(c/5)] (ADDshiftLL <x.Type> x x [2])))
(MULW x (MOVDconst [c])) && c%7 == 0 && isPowerOfTwo64(c/7) && is32Bit(c) => (MOVWUreg (SLLconst <x.Type> [log64(c/7)] (ADDshiftLL <x.Type> (NEG <x.Type> x) x [3])))
(MULW x (MOVDconst [c])) && c%9 == 0 && isPowerOfTwo64(c/9) && is32Bit(c) => (MOVWUreg (SLLconst <x.Type> [log64(c/9)] (ADDshiftLL <x.Type> x x [3])))
// mneg by constant
(MNEG x (MOVDconst [-1])) => x
(MNEG _ (MOVDconst [0])) => (MOVDconst [0])
(MNEG x (MOVDconst [1])) => (NEG x)
(MNEG x (MOVDconst [c])) && isPowerOfTwo64(c) => (NEG (SLLconst <x.Type> [log64(c)] x))
(MNEG x (MOVDconst [c])) && isPowerOfTwo64(c-1) && c >= 3 => (NEG (ADDshiftLL <x.Type> x x [log64(c-1)]))
(MNEG x (MOVDconst [c])) && isPowerOfTwo64(c+1) && c >= 7 => (NEG (ADDshiftLL <x.Type> (NEG <x.Type> x) x [log64(c+1)]))
(MNEG x (MOVDconst [c])) && c%3 == 0 && isPowerOfTwo64(c/3) => (SLLconst <x.Type> [log64(c/3)] (SUBshiftLL <x.Type> x x [2]))
(MNEG x (MOVDconst [c])) && c%5 == 0 && isPowerOfTwo64(c/5) => (NEG (SLLconst <x.Type> [log64(c/5)] (ADDshiftLL <x.Type> x x [2])))
(MNEG x (MOVDconst [c])) && c%7 == 0 && isPowerOfTwo64(c/7) => (SLLconst <x.Type> [log64(c/7)] (SUBshiftLL <x.Type> x x [3]))
(MNEG x (MOVDconst [c])) && c%9 == 0 && isPowerOfTwo64(c/9) => (NEG (SLLconst <x.Type> [log64(c/9)] (ADDshiftLL <x.Type> x x [3])))
(MNEGW x (MOVDconst [c])) && int32(c)==-1 => (MOVWUreg x)
(MNEGW _ (MOVDconst [c])) && int32(c)==0 => (MOVDconst [0])
(MNEGW x (MOVDconst [c])) && int32(c)==1 => (MOVWUreg (NEG <x.Type> x))
(MNEGW x (MOVDconst [c])) && isPowerOfTwo64(c) => (NEG (SLLconst <x.Type> [log64(c)] x))
(MNEGW x (MOVDconst [c])) && isPowerOfTwo64(c-1) && int32(c) >= 3 => (MOVWUreg (NEG <x.Type> (ADDshiftLL <x.Type> x x [log64(c-1)])))
(MNEGW x (MOVDconst [c])) && isPowerOfTwo64(c+1) && int32(c) >= 7 => (MOVWUreg (NEG <x.Type> (ADDshiftLL <x.Type> (NEG <x.Type> x) x [log64(c+1)])))
(MNEGW x (MOVDconst [c])) && c%3 == 0 && isPowerOfTwo64(c/3) && is32Bit(c) => (MOVWUreg (SLLconst <x.Type> [log64(c/3)] (SUBshiftLL <x.Type> x x [2])))
(MNEGW x (MOVDconst [c])) && c%5 == 0 && isPowerOfTwo64(c/5) && is32Bit(c) => (MOVWUreg (NEG <x.Type> (SLLconst <x.Type> [log64(c/5)] (ADDshiftLL <x.Type> x x [2]))))
(MNEGW x (MOVDconst [c])) && c%7 == 0 && isPowerOfTwo64(c/7) && is32Bit(c) => (MOVWUreg (SLLconst <x.Type> [log64(c/7)] (SUBshiftLL <x.Type> x x [3])))
(MNEGW x (MOVDconst [c])) && c%9 == 0 && isPowerOfTwo64(c/9) && is32Bit(c) => (MOVWUreg (NEG <x.Type> (SLLconst <x.Type> [log64(c/9)] (ADDshiftLL <x.Type> x x [3]))))
(MADD a x (MOVDconst [-1])) => (SUB a x)
(MADD a _ (MOVDconst [0])) => a
(MADD a x (MOVDconst [1])) => (ADD a x)
(MADD a x (MOVDconst [c])) && isPowerOfTwo64(c) => (ADDshiftLL a x [log64(c)])
(MADD a x (MOVDconst [c])) && isPowerOfTwo64(c-1) && c>=3 => (ADD a (ADDshiftLL <x.Type> x x [log64(c-1)]))
(MADD a x (MOVDconst [c])) && isPowerOfTwo64(c+1) && c>=7 => (SUB a (SUBshiftLL <x.Type> x x [log64(c+1)]))
(MADD a x (MOVDconst [c])) && c%3 == 0 && isPowerOfTwo64(c/3) => (SUBshiftLL a (SUBshiftLL <x.Type> x x [2]) [log64(c/3)])
(MADD a x (MOVDconst [c])) && c%5 == 0 && isPowerOfTwo64(c/5) => (ADDshiftLL a (ADDshiftLL <x.Type> x x [2]) [log64(c/5)])
(MADD a x (MOVDconst [c])) && c%7 == 0 && isPowerOfTwo64(c/7) => (SUBshiftLL a (SUBshiftLL <x.Type> x x [3]) [log64(c/7)])
(MADD a x (MOVDconst [c])) && c%9 == 0 && isPowerOfTwo64(c/9) => (ADDshiftLL a (ADDshiftLL <x.Type> x x [3]) [log64(c/9)])
(MADD a (MOVDconst [-1]) x) => (SUB a x)
(MADD a (MOVDconst [0]) _) => a
(MADD a (MOVDconst [1]) x) => (ADD a x)
(MADD a (MOVDconst [c]) x) && isPowerOfTwo64(c) => (ADDshiftLL a x [log64(c)])
(MADD a (MOVDconst [c]) x) && isPowerOfTwo64(c-1) && c>=3 => (ADD a (ADDshiftLL <x.Type> x x [log64(c-1)]))
(MADD a (MOVDconst [c]) x) && isPowerOfTwo64(c+1) && c>=7 => (SUB a (SUBshiftLL <x.Type> x x [log64(c+1)]))
(MADD a (MOVDconst [c]) x) && c%3 == 0 && isPowerOfTwo64(c/3) => (SUBshiftLL a (SUBshiftLL <x.Type> x x [2]) [log64(c/3)])
(MADD a (MOVDconst [c]) x) && c%5 == 0 && isPowerOfTwo64(c/5) => (ADDshiftLL a (ADDshiftLL <x.Type> x x [2]) [log64(c/5)])
(MADD a (MOVDconst [c]) x) && c%7 == 0 && isPowerOfTwo64(c/7) => (SUBshiftLL a (SUBshiftLL <x.Type> x x [3]) [log64(c/7)])
(MADD a (MOVDconst [c]) x) && c%9 == 0 && isPowerOfTwo64(c/9) => (ADDshiftLL a (ADDshiftLL <x.Type> x x [3]) [log64(c/9)])
(MADDW a x (MOVDconst [c])) && int32(c)==-1 => (MOVWUreg (SUB <a.Type> a x))
(MADDW a _ (MOVDconst [c])) && int32(c)==0 => (MOVWUreg a)
(MADDW a x (MOVDconst [c])) && int32(c)==1 => (MOVWUreg (ADD <a.Type> a x))
(MADDW a x (MOVDconst [c])) && isPowerOfTwo64(c) => (MOVWUreg (ADDshiftLL <a.Type> a x [log64(c)]))
(MADDW a x (MOVDconst [c])) && isPowerOfTwo64(c-1) && int32(c)>=3 => (MOVWUreg (ADD <a.Type> a (ADDshiftLL <x.Type> x x [log64(c-1)])))
(MADDW a x (MOVDconst [c])) && isPowerOfTwo64(c+1) && int32(c)>=7 => (MOVWUreg (SUB <a.Type> a (SUBshiftLL <x.Type> x x [log64(c+1)])))
(MADDW a x (MOVDconst [c])) && c%3 == 0 && isPowerOfTwo64(c/3) && is32Bit(c) => (MOVWUreg (SUBshiftLL <a.Type> a (SUBshiftLL <x.Type> x x [2]) [log64(c/3)]))
(MADDW a x (MOVDconst [c])) && c%5 == 0 && isPowerOfTwo64(c/5) && is32Bit(c) => (MOVWUreg (ADDshiftLL <a.Type> a (ADDshiftLL <x.Type> x x [2]) [log64(c/5)]))
(MADDW a x (MOVDconst [c])) && c%7 == 0 && isPowerOfTwo64(c/7) && is32Bit(c) => (MOVWUreg (SUBshiftLL <a.Type> a (SUBshiftLL <x.Type> x x [3]) [log64(c/7)]))
(MADDW a x (MOVDconst [c])) && c%9 == 0 && isPowerOfTwo64(c/9) && is32Bit(c) => (MOVWUreg (ADDshiftLL <a.Type> a (ADDshiftLL <x.Type> x x [3]) [log64(c/9)]))
(MADDW a (MOVDconst [c]) x) && int32(c)==-1 => (MOVWUreg (SUB <a.Type> a x))
(MADDW a (MOVDconst [c]) _) && int32(c)==0 => (MOVWUreg a)
(MADDW a (MOVDconst [c]) x) && int32(c)==1 => (MOVWUreg (ADD <a.Type> a x))
(MADDW a (MOVDconst [c]) x) && isPowerOfTwo64(c) => (MOVWUreg (ADDshiftLL <a.Type> a x [log64(c)]))
(MADDW a (MOVDconst [c]) x) && isPowerOfTwo64(c-1) && int32(c)>=3 => (MOVWUreg (ADD <a.Type> a (ADDshiftLL <x.Type> x x [log64(c-1)])))
(MADDW a (MOVDconst [c]) x) && isPowerOfTwo64(c+1) && int32(c)>=7 => (MOVWUreg (SUB <a.Type> a (SUBshiftLL <x.Type> x x [log64(c+1)])))
(MADDW a (MOVDconst [c]) x) && c%3 == 0 && isPowerOfTwo64(c/3) && is32Bit(c) => (MOVWUreg (SUBshiftLL <a.Type> a (SUBshiftLL <x.Type> x x [2]) [log64(c/3)]))
(MADDW a (MOVDconst [c]) x) && c%5 == 0 && isPowerOfTwo64(c/5) && is32Bit(c) => (MOVWUreg (ADDshiftLL <a.Type> a (ADDshiftLL <x.Type> x x [2]) [log64(c/5)]))
(MADDW a (MOVDconst [c]) x) && c%7 == 0 && isPowerOfTwo64(c/7) && is32Bit(c) => (MOVWUreg (SUBshiftLL <a.Type> a (SUBshiftLL <x.Type> x x [3]) [log64(c/7)]))
(MADDW a (MOVDconst [c]) x) && c%9 == 0 && isPowerOfTwo64(c/9) && is32Bit(c) => (MOVWUreg (ADDshiftLL <a.Type> a (ADDshiftLL <x.Type> x x [3]) [log64(c/9)]))
(MSUB a x (MOVDconst [-1])) => (ADD a x)
(MSUB a _ (MOVDconst [0])) => a
(MSUB a x (MOVDconst [1])) => (SUB a x)
(MSUB a x (MOVDconst [c])) && isPowerOfTwo64(c) => (SUBshiftLL a x [log64(c)])
(MSUB a x (MOVDconst [c])) && isPowerOfTwo64(c-1) && c>=3 => (SUB a (ADDshiftLL <x.Type> x x [log64(c-1)]))
(MSUB a x (MOVDconst [c])) && isPowerOfTwo64(c+1) && c>=7 => (ADD a (SUBshiftLL <x.Type> x x [log64(c+1)]))
(MSUB a x (MOVDconst [c])) && c%3 == 0 && isPowerOfTwo64(c/3) => (ADDshiftLL a (SUBshiftLL <x.Type> x x [2]) [log64(c/3)])
(MSUB a x (MOVDconst [c])) && c%5 == 0 && isPowerOfTwo64(c/5) => (SUBshiftLL a (ADDshiftLL <x.Type> x x [2]) [log64(c/5)])
(MSUB a x (MOVDconst [c])) && c%7 == 0 && isPowerOfTwo64(c/7) => (ADDshiftLL a (SUBshiftLL <x.Type> x x [3]) [log64(c/7)])
(MSUB a x (MOVDconst [c])) && c%9 == 0 && isPowerOfTwo64(c/9) => (SUBshiftLL a (ADDshiftLL <x.Type> x x [3]) [log64(c/9)])
(MSUB a (MOVDconst [-1]) x) => (ADD a x)
(MSUB a (MOVDconst [0]) _) => a
(MSUB a (MOVDconst [1]) x) => (SUB a x)
(MSUB a (MOVDconst [c]) x) && isPowerOfTwo64(c) => (SUBshiftLL a x [log64(c)])
(MSUB a (MOVDconst [c]) x) && isPowerOfTwo64(c-1) && c>=3 => (SUB a (ADDshiftLL <x.Type> x x [log64(c-1)]))
(MSUB a (MOVDconst [c]) x) && isPowerOfTwo64(c+1) && c>=7 => (ADD a (SUBshiftLL <x.Type> x x [log64(c+1)]))
(MSUB a (MOVDconst [c]) x) && c%3 == 0 && isPowerOfTwo64(c/3) => (ADDshiftLL a (SUBshiftLL <x.Type> x x [2]) [log64(c/3)])
(MSUB a (MOVDconst [c]) x) && c%5 == 0 && isPowerOfTwo64(c/5) => (SUBshiftLL a (ADDshiftLL <x.Type> x x [2]) [log64(c/5)])
(MSUB a (MOVDconst [c]) x) && c%7 == 0 && isPowerOfTwo64(c/7) => (ADDshiftLL a (SUBshiftLL <x.Type> x x [3]) [log64(c/7)])
(MSUB a (MOVDconst [c]) x) && c%9 == 0 && isPowerOfTwo64(c/9) => (SUBshiftLL a (ADDshiftLL <x.Type> x x [3]) [log64(c/9)])
(MSUBW a x (MOVDconst [c])) && int32(c)==-1 => (MOVWUreg (ADD <a.Type> a x))
(MSUBW a _ (MOVDconst [c])) && int32(c)==0 => (MOVWUreg a)
(MSUBW a x (MOVDconst [c])) && int32(c)==1 => (MOVWUreg (SUB <a.Type> a x))
(MSUBW a x (MOVDconst [c])) && isPowerOfTwo64(c) => (MOVWUreg (SUBshiftLL <a.Type> a x [log64(c)]))
(MSUBW a x (MOVDconst [c])) && isPowerOfTwo64(c-1) && int32(c)>=3 => (MOVWUreg (SUB <a.Type> a (ADDshiftLL <x.Type> x x [log64(c-1)])))
(MSUBW a x (MOVDconst [c])) && isPowerOfTwo64(c+1) && int32(c)>=7 => (MOVWUreg (ADD <a.Type> a (SUBshiftLL <x.Type> x x [log64(c+1)])))
(MSUBW a x (MOVDconst [c])) && c%3 == 0 && isPowerOfTwo64(c/3) && is32Bit(c) => (MOVWUreg (ADDshiftLL <a.Type> a (SUBshiftLL <x.Type> x x [2]) [log64(c/3)]))
(MSUBW a x (MOVDconst [c])) && c%5 == 0 && isPowerOfTwo64(c/5) && is32Bit(c) => (MOVWUreg (SUBshiftLL <a.Type> a (ADDshiftLL <x.Type> x x [2]) [log64(c/5)]))
(MSUBW a x (MOVDconst [c])) && c%7 == 0 && isPowerOfTwo64(c/7) && is32Bit(c) => (MOVWUreg (ADDshiftLL <a.Type> a (SUBshiftLL <x.Type> x x [3]) [log64(c/7)]))
(MSUBW a x (MOVDconst [c])) && c%9 == 0 && isPowerOfTwo64(c/9) && is32Bit(c) => (MOVWUreg (SUBshiftLL <a.Type> a (ADDshiftLL <x.Type> x x [3]) [log64(c/9)]))
(MSUBW a (MOVDconst [c]) x) && int32(c)==-1 => (MOVWUreg (ADD <a.Type> a x))
(MSUBW a (MOVDconst [c]) _) && int32(c)==0 => (MOVWUreg a)
(MSUBW a (MOVDconst [c]) x) && int32(c)==1 => (MOVWUreg (SUB <a.Type> a x))
(MSUBW a (MOVDconst [c]) x) && isPowerOfTwo64(c) => (MOVWUreg (SUBshiftLL <a.Type> a x [log64(c)]))
(MSUBW a (MOVDconst [c]) x) && isPowerOfTwo64(c-1) && int32(c)>=3 => (MOVWUreg (SUB <a.Type> a (ADDshiftLL <x.Type> x x [log64(c-1)])))
(MSUBW a (MOVDconst [c]) x) && isPowerOfTwo64(c+1) && int32(c)>=7 => (MOVWUreg (ADD <a.Type> a (SUBshiftLL <x.Type> x x [log64(c+1)])))
(MSUBW a (MOVDconst [c]) x) && c%3 == 0 && isPowerOfTwo64(c/3) && is32Bit(c) => (MOVWUreg (ADDshiftLL <a.Type> a (SUBshiftLL <x.Type> x x [2]) [log64(c/3)]))
(MSUBW a (MOVDconst [c]) x) && c%5 == 0 && isPowerOfTwo64(c/5) && is32Bit(c) => (MOVWUreg (SUBshiftLL <a.Type> a (ADDshiftLL <x.Type> x x [2]) [log64(c/5)]))
(MSUBW a (MOVDconst [c]) x) && c%7 == 0 && isPowerOfTwo64(c/7) && is32Bit(c) => (MOVWUreg (ADDshiftLL <a.Type> a (SUBshiftLL <x.Type> x x [3]) [log64(c/7)]))
(MSUBW a (MOVDconst [c]) x) && c%9 == 0 && isPowerOfTwo64(c/9) && is32Bit(c) => (MOVWUreg (SUBshiftLL <a.Type> a (ADDshiftLL <x.Type> x x [3]) [log64(c/9)]))
// div by constant
(UDIV x (MOVDconst [1])) => x
(UDIV x (MOVDconst [c])) && isPowerOfTwo64(c) => (SRLconst [log64(c)] x)
(UDIVW x (MOVDconst [c])) && uint32(c)==1 => (MOVWUreg x)
(UDIVW x (MOVDconst [c])) && isPowerOfTwo64(c) && is32Bit(c) => (SRLconst [log64(c)] (MOVWUreg <v.Type> x))
(UMOD _ (MOVDconst [1])) => (MOVDconst [0])
(UMOD x (MOVDconst [c])) && isPowerOfTwo64(c) => (ANDconst [c-1] x)
(UMODW _ (MOVDconst [c])) && uint32(c)==1 => (MOVDconst [0])
(UMODW x (MOVDconst [c])) && isPowerOfTwo64(c) && is32Bit(c) => (ANDconst [c-1] x)
// generic simplifications
(ADD x (NEG y)) => (SUB x y)
(SUB x x) => (MOVDconst [0])
(AND x x) => x
(OR x x) => x
(XOR x x) => (MOVDconst [0])
(BIC x x) => (MOVDconst [0])
(EON x x) => (MOVDconst [-1])
(ORN x x) => (MOVDconst [-1])
(AND x (MVN y)) => (BIC x y)
(XOR x (MVN y)) => (EON x y)
(OR x (MVN y)) => (ORN x y)
(MVN (XOR x y)) => (EON x y)
(NEG (NEG x)) => x
(CSEL [cc] (MOVDconst [-1]) (MOVDconst [0]) flag) => (CSETM [cc] flag)
(CSEL [cc] (MOVDconst [0]) (MOVDconst [-1]) flag) => (CSETM [arm64Negate(cc)] flag)
(CSEL [cc] x (MOVDconst [0]) flag) => (CSEL0 [cc] x flag)
(CSEL [cc] (MOVDconst [0]) y flag) => (CSEL0 [arm64Negate(cc)] y flag)
(CSEL [cc] x (ADDconst [1] a) flag) => (CSINC [cc] x a flag)
(CSEL [cc] (ADDconst [1] a) x flag) => (CSINC [arm64Negate(cc)] x a flag)
(CSEL [cc] x (MVN a) flag) => (CSINV [cc] x a flag)
(CSEL [cc] (MVN a) x flag) => (CSINV [arm64Negate(cc)] x a flag)
(CSEL [cc] x (NEG a) flag) => (CSNEG [cc] x a flag)
(CSEL [cc] (NEG a) x flag) => (CSNEG [arm64Negate(cc)] x a flag)
(SUB x (SUB y z)) => (SUB (ADD <v.Type> x z) y)
(SUB (SUB x y) z) => (SUB x (ADD <y.Type> y z))
// remove redundant *const ops
(ADDconst [0] x) => x
(SUBconst [0] x) => x
(ANDconst [0] _) => (MOVDconst [0])
(ANDconst [-1] x) => x
(ORconst [0] x) => x
(ORconst [-1] _) => (MOVDconst [-1])
(XORconst [0] x) => x
(XORconst [-1] x) => (MVN x)
// generic constant folding
(ADDconst [c] (MOVDconst [d])) => (MOVDconst [c+d])
(ADDconst [c] (ADDconst [d] x)) => (ADDconst [c+d] x)
(ADDconst [c] (SUBconst [d] x)) => (ADDconst [c-d] x)
(SUBconst [c] (MOVDconst [d])) => (MOVDconst [d-c])
(SUBconst [c] (SUBconst [d] x)) => (ADDconst [-c-d] x)
(SUBconst [c] (ADDconst [d] x)) => (ADDconst [-c+d] x)
(SLLconst [c] (MOVDconst [d])) => (MOVDconst [d<<uint64(c)])
(SRLconst [c] (MOVDconst [d])) => (MOVDconst [int64(uint64(d)>>uint64(c))])
(SRAconst [c] (MOVDconst [d])) => (MOVDconst [d>>uint64(c)])
(MUL (MOVDconst [c]) (MOVDconst [d])) => (MOVDconst [c*d])
(MNEG (MOVDconst [c]) (MOVDconst [d])) => (MOVDconst [-c*d])
(MULW (MOVDconst [c]) (MOVDconst [d])) => (MOVDconst [int64(uint32(c*d))])
(MNEGW (MOVDconst [c]) (MOVDconst [d])) => (MOVDconst [int64(uint32(-c*d))])
(MADD (MOVDconst [c]) x y) => (ADDconst [c] (MUL <x.Type> x y))
(MSUB (MOVDconst [c]) x y) => (ADDconst [c] (MNEG <x.Type> x y))
(MADD a (MOVDconst [c]) (MOVDconst [d])) => (ADDconst [c*d] a)
(MSUB a (MOVDconst [c]) (MOVDconst [d])) => (SUBconst [c*d] a)
(MADDW (MOVDconst [c]) x y) => (MOVWUreg (ADDconst <x.Type> [c] (MULW <x.Type> x y)))
(MSUBW (MOVDconst [c]) x y) => (MOVWUreg (ADDconst <x.Type> [c] (MNEGW <x.Type> x y)))
(MADDW a (MOVDconst [c]) (MOVDconst [d])) => (MOVWUreg (ADDconst <a.Type> [c*d] a))
(MSUBW a (MOVDconst [c]) (MOVDconst [d])) => (MOVWUreg (SUBconst <a.Type> [c*d] a))
(DIV (MOVDconst [c]) (MOVDconst [d])) && d != 0 => (MOVDconst [c/d])
(UDIV (MOVDconst [c]) (MOVDconst [d])) && d != 0 => (MOVDconst [int64(uint64(c)/uint64(d))])
(DIVW (MOVDconst [c]) (MOVDconst [d])) && d != 0 => (MOVDconst [int64(uint32(int32(c)/int32(d)))])
(UDIVW (MOVDconst [c]) (MOVDconst [d])) && d != 0 => (MOVDconst [int64(uint32(c)/uint32(d))])
(MOD (MOVDconst [c]) (MOVDconst [d])) && d != 0 => (MOVDconst [c%d])
(UMOD (MOVDconst [c]) (MOVDconst [d])) && d != 0 => (MOVDconst [int64(uint64(c)%uint64(d))])
(MODW (MOVDconst [c]) (MOVDconst [d])) && d != 0 => (MOVDconst [int64(uint32(int32(c)%int32(d)))])
(UMODW (MOVDconst [c]) (MOVDconst [d])) && d != 0 => (MOVDconst [int64(uint32(c)%uint32(d))])
(ANDconst [c] (MOVDconst [d])) => (MOVDconst [c&d])
(ANDconst [c] (ANDconst [d] x)) => (ANDconst [c&d] x)
(ANDconst [c] (MOVWUreg x)) => (ANDconst [c&(1<<32-1)] x)
(ANDconst [c] (MOVHUreg x)) => (ANDconst [c&(1<<16-1)] x)
(ANDconst [c] (MOVBUreg x)) => (ANDconst [c&(1<<8-1)] x)
(MOVWUreg (ANDconst [c] x)) => (ANDconst [c&(1<<32-1)] x)
(MOVHUreg (ANDconst [c] x)) => (ANDconst [c&(1<<16-1)] x)
(MOVBUreg (ANDconst [c] x)) => (ANDconst [c&(1<<8-1)] x)
(ORconst [c] (MOVDconst [d])) => (MOVDconst [c|d])
(ORconst [c] (ORconst [d] x)) => (ORconst [c|d] x)
(XORconst [c] (MOVDconst [d])) => (MOVDconst [c^d])
(XORconst [c] (XORconst [d] x)) => (XORconst [c^d] x)
(MVN (MOVDconst [c])) => (MOVDconst [^c])
(NEG (MOVDconst [c])) => (MOVDconst [-c])
(MOVBreg (MOVDconst [c])) => (MOVDconst [int64(int8(c))])
(MOVBUreg (MOVDconst [c])) => (MOVDconst [int64(uint8(c))])
(MOVHreg (MOVDconst [c])) => (MOVDconst [int64(int16(c))])
(MOVHUreg (MOVDconst [c])) => (MOVDconst [int64(uint16(c))])
(MOVWreg (MOVDconst [c])) => (MOVDconst [int64(int32(c))])
(MOVWUreg (MOVDconst [c])) => (MOVDconst [int64(uint32(c))])
(MOVDreg (MOVDconst [c])) => (MOVDconst [c])
// constant comparisons
(CMPconst (MOVDconst [x]) [y]) => (FlagConstant [subFlags64(x,y)])
(CMPWconst (MOVDconst [x]) [y]) => (FlagConstant [subFlags32(int32(x),y)])
(TSTconst (MOVDconst [x]) [y]) => (FlagConstant [logicFlags64(x&y)])
(TSTWconst (MOVDconst [x]) [y]) => (FlagConstant [logicFlags32(int32(x)&y)])
(CMNconst (MOVDconst [x]) [y]) => (FlagConstant [addFlags64(x,y)])
(CMNWconst (MOVDconst [x]) [y]) => (FlagConstant [addFlags32(int32(x),y)])
// other known comparisons
(CMPconst (MOVBUreg _) [c]) && 0xff < c => (FlagConstant [subFlags64(0,1)])
(CMPconst (MOVHUreg _) [c]) && 0xffff < c => (FlagConstant [subFlags64(0,1)])
(CMPconst (MOVWUreg _) [c]) && 0xffffffff < c => (FlagConstant [subFlags64(0,1)])
(CMPconst (ANDconst _ [m]) [n]) && 0 <= m && m < n => (FlagConstant [subFlags64(0,1)])
(CMPconst (SRLconst _ [c]) [n]) && 0 <= n && 0 < c && c <= 63 && (1<<uint64(64-c)) <= uint64(n) => (FlagConstant [subFlags64(0,1)])
(CMPWconst (MOVBUreg _) [c]) && 0xff < c => (FlagConstant [subFlags64(0,1)])
(CMPWconst (MOVHUreg _) [c]) && 0xffff < c => (FlagConstant [subFlags64(0,1)])
// absorb flag constants into branches
(EQ (FlagConstant [fc]) yes no) && fc.eq() => (First yes no)
(EQ (FlagConstant [fc]) yes no) && !fc.eq() => (First no yes)
(NE (FlagConstant [fc]) yes no) && fc.ne() => (First yes no)
(NE (FlagConstant [fc]) yes no) && !fc.ne() => (First no yes)
(LT (FlagConstant [fc]) yes no) && fc.lt() => (First yes no)
(LT (FlagConstant [fc]) yes no) && !fc.lt() => (First no yes)
(LE (FlagConstant [fc]) yes no) && fc.le() => (First yes no)
(LE (FlagConstant [fc]) yes no) && !fc.le() => (First no yes)
(GT (FlagConstant [fc]) yes no) && fc.gt() => (First yes no)
(GT (FlagConstant [fc]) yes no) && !fc.gt() => (First no yes)
(GE (FlagConstant [fc]) yes no) && fc.ge() => (First yes no)
(GE (FlagConstant [fc]) yes no) && !fc.ge() => (First no yes)
(ULT (FlagConstant [fc]) yes no) && fc.ult() => (First yes no)
(ULT (FlagConstant [fc]) yes no) && !fc.ult() => (First no yes)
(ULE (FlagConstant [fc]) yes no) && fc.ule() => (First yes no)
(ULE (FlagConstant [fc]) yes no) && !fc.ule() => (First no yes)
(UGT (FlagConstant [fc]) yes no) && fc.ugt() => (First yes no)
(UGT (FlagConstant [fc]) yes no) && !fc.ugt() => (First no yes)
(UGE (FlagConstant [fc]) yes no) && fc.uge() => (First yes no)
(UGE (FlagConstant [fc]) yes no) && !fc.uge() => (First no yes)
(LTnoov (FlagConstant [fc]) yes no) && fc.ltNoov() => (First yes no)
(LTnoov (FlagConstant [fc]) yes no) && !fc.ltNoov() => (First no yes)
(LEnoov (FlagConstant [fc]) yes no) && fc.leNoov() => (First yes no)
(LEnoov (FlagConstant [fc]) yes no) && !fc.leNoov() => (First no yes)
(GTnoov (FlagConstant [fc]) yes no) && fc.gtNoov() => (First yes no)
(GTnoov (FlagConstant [fc]) yes no) && !fc.gtNoov() => (First no yes)
(GEnoov (FlagConstant [fc]) yes no) && fc.geNoov() => (First yes no)
(GEnoov (FlagConstant [fc]) yes no) && !fc.geNoov() => (First no yes)
(Z (MOVDconst [0]) yes no) => (First yes no)
(Z (MOVDconst [c]) yes no) && c != 0 => (First no yes)
(NZ (MOVDconst [0]) yes no) => (First no yes)
(NZ (MOVDconst [c]) yes no) && c != 0 => (First yes no)
(ZW (MOVDconst [c]) yes no) && int32(c) == 0 => (First yes no)
(ZW (MOVDconst [c]) yes no) && int32(c) != 0 => (First no yes)
(NZW (MOVDconst [c]) yes no) && int32(c) == 0 => (First no yes)
(NZW (MOVDconst [c]) yes no) && int32(c) != 0 => (First yes no)
// absorb InvertFlags into branches
(LT (InvertFlags cmp) yes no) => (GT cmp yes no)
(GT (InvertFlags cmp) yes no) => (LT cmp yes no)
(LE (InvertFlags cmp) yes no) => (GE cmp yes no)
(GE (InvertFlags cmp) yes no) => (LE cmp yes no)
(ULT (InvertFlags cmp) yes no) => (UGT cmp yes no)
(UGT (InvertFlags cmp) yes no) => (ULT cmp yes no)
(ULE (InvertFlags cmp) yes no) => (UGE cmp yes no)
(UGE (InvertFlags cmp) yes no) => (ULE cmp yes no)
(EQ (InvertFlags cmp) yes no) => (EQ cmp yes no)
(NE (InvertFlags cmp) yes no) => (NE cmp yes no)
(FLT (InvertFlags cmp) yes no) => (FGT cmp yes no)
(FGT (InvertFlags cmp) yes no) => (FLT cmp yes no)
(FLE (InvertFlags cmp) yes no) => (FGE cmp yes no)
(FGE (InvertFlags cmp) yes no) => (FLE cmp yes no)
(LTnoov (InvertFlags cmp) yes no) => (GTnoov cmp yes no)
(GEnoov (InvertFlags cmp) yes no) => (LEnoov cmp yes no)
(LEnoov (InvertFlags cmp) yes no) => (GEnoov cmp yes no)
(GTnoov (InvertFlags cmp) yes no) => (LTnoov cmp yes no)
// absorb InvertFlags into conditional instructions
(CSEL [cc] x y (InvertFlags cmp)) => (CSEL [arm64Invert(cc)] x y cmp)
(CSEL0 [cc] x (InvertFlags cmp)) => (CSEL0 [arm64Invert(cc)] x cmp)
(CSETM [cc] (InvertFlags cmp)) => (CSETM [arm64Invert(cc)] cmp)
(CSINC [cc] x y (InvertFlags cmp)) => (CSINC [arm64Invert(cc)] x y cmp)
(CSINV [cc] x y (InvertFlags cmp)) => (CSINV [arm64Invert(cc)] x y cmp)
(CSNEG [cc] x y (InvertFlags cmp)) => (CSNEG [arm64Invert(cc)] x y cmp)
// absorb flag constants into boolean values
(Equal (FlagConstant [fc])) => (MOVDconst [b2i(fc.eq())])
(NotEqual (FlagConstant [fc])) => (MOVDconst [b2i(fc.ne())])
(LessThan (FlagConstant [fc])) => (MOVDconst [b2i(fc.lt())])
(LessThanU (FlagConstant [fc])) => (MOVDconst [b2i(fc.ult())])
(LessEqual (FlagConstant [fc])) => (MOVDconst [b2i(fc.le())])
(LessEqualU (FlagConstant [fc])) => (MOVDconst [b2i(fc.ule())])
(GreaterThan (FlagConstant [fc])) => (MOVDconst [b2i(fc.gt())])
(GreaterThanU (FlagConstant [fc])) => (MOVDconst [b2i(fc.ugt())])
(GreaterEqual (FlagConstant [fc])) => (MOVDconst [b2i(fc.ge())])
(GreaterEqualU (FlagConstant [fc])) => (MOVDconst [b2i(fc.uge())])
// absorb InvertFlags into boolean values
(Equal (InvertFlags x)) => (Equal x)
(NotEqual (InvertFlags x)) => (NotEqual x)
(LessThan (InvertFlags x)) => (GreaterThan x)
(LessThanU (InvertFlags x)) => (GreaterThanU x)
(GreaterThan (InvertFlags x)) => (LessThan x)
(GreaterThanU (InvertFlags x)) => (LessThanU x)
(LessEqual (InvertFlags x)) => (GreaterEqual x)
(LessEqualU (InvertFlags x)) => (GreaterEqualU x)
(GreaterEqual (InvertFlags x)) => (LessEqual x)
(GreaterEqualU (InvertFlags x)) => (LessEqualU x)
(LessThanF (InvertFlags x)) => (GreaterThanF x)
(LessEqualF (InvertFlags x)) => (GreaterEqualF x)
(GreaterThanF (InvertFlags x)) => (LessThanF x)
(GreaterEqualF (InvertFlags x)) => (LessEqualF x)
(LessThanNoov (InvertFlags x)) => (CSEL0 [OpARM64NotEqual] (GreaterEqualNoov <typ.Bool> x) x)
(GreaterEqualNoov (InvertFlags x)) => (CSINC [OpARM64NotEqual] (LessThanNoov <typ.Bool> x) (MOVDconst [0]) x)
// Don't bother extending if we're not using the higher bits.
(MOV(B|BU)reg x) && v.Type.Size() <= 1 => x
(MOV(H|HU)reg x) && v.Type.Size() <= 2 => x
(MOV(W|WU)reg x) && v.Type.Size() <= 4 => x
// omit sign extension
(MOVWreg <t> (ANDconst x [c])) && uint64(c) & uint64(0xffffffff80000000) == 0 => (ANDconst <t> x [c])
(MOVHreg <t> (ANDconst x [c])) && uint64(c) & uint64(0xffffffffffff8000) == 0 => (ANDconst <t> x [c])
(MOVBreg <t> (ANDconst x [c])) && uint64(c) & uint64(0xffffffffffffff80) == 0 => (ANDconst <t> x [c])
// absorb flag constants into conditional instructions
(CSEL [cc] x _ flag) && ccARM64Eval(cc, flag) > 0 => x
(CSEL [cc] _ y flag) && ccARM64Eval(cc, flag) < 0 => y
(CSEL0 [cc] x flag) && ccARM64Eval(cc, flag) > 0 => x
(CSEL0 [cc] _ flag) && ccARM64Eval(cc, flag) < 0 => (MOVDconst [0])
(CSNEG [cc] x _ flag) && ccARM64Eval(cc, flag) > 0 => x
(CSNEG [cc] _ y flag) && ccARM64Eval(cc, flag) < 0 => (NEG y)
(CSINV [cc] x _ flag) && ccARM64Eval(cc, flag) > 0 => x
(CSINV [cc] _ y flag) && ccARM64Eval(cc, flag) < 0 => (Not y)
(CSINC [cc] x _ flag) && ccARM64Eval(cc, flag) > 0 => x
(CSINC [cc] _ y flag) && ccARM64Eval(cc, flag) < 0 => (ADDconst [1] y)
(CSETM [cc] flag) && ccARM64Eval(cc, flag) > 0 => (MOVDconst [-1])
(CSETM [cc] flag) && ccARM64Eval(cc, flag) < 0 => (MOVDconst [0])
// absorb flags back into boolean CSEL
(CSEL [cc] x y (CMPWconst [0] boolval)) && cc == OpARM64NotEqual && flagArg(boolval) != nil =>
(CSEL [boolval.Op] x y flagArg(boolval))
(CSEL [cc] x y (CMPWconst [0] boolval)) && cc == OpARM64Equal && flagArg(boolval) != nil =>
(CSEL [arm64Negate(boolval.Op)] x y flagArg(boolval))
(CSEL0 [cc] x (CMPWconst [0] boolval)) && cc == OpARM64NotEqual && flagArg(boolval) != nil =>
(CSEL0 [boolval.Op] x flagArg(boolval))
(CSEL0 [cc] x (CMPWconst [0] boolval)) && cc == OpARM64Equal && flagArg(boolval) != nil =>
(CSEL0 [arm64Negate(boolval.Op)] x flagArg(boolval))
// absorb shifts into ops
(NEG x:(SLLconst [c] y)) && clobberIfDead(x) => (NEGshiftLL [c] y)
(NEG x:(SRLconst [c] y)) && clobberIfDead(x) => (NEGshiftRL [c] y)
(NEG x:(SRAconst [c] y)) && clobberIfDead(x) => (NEGshiftRA [c] y)
(MVN x:(SLLconst [c] y)) && clobberIfDead(x) => (MVNshiftLL [c] y)
(MVN x:(SRLconst [c] y)) && clobberIfDead(x) => (MVNshiftRL [c] y)
(MVN x:(SRAconst [c] y)) && clobberIfDead(x) => (MVNshiftRA [c] y)
(MVN x:(RORconst [c] y)) && clobberIfDead(x) => (MVNshiftRO [c] y)
(ADD x0 x1:(SLLconst [c] y)) && clobberIfDead(x1) => (ADDshiftLL x0 y [c])
(ADD x0 x1:(SRLconst [c] y)) && clobberIfDead(x1) => (ADDshiftRL x0 y [c])
(ADD x0 x1:(SRAconst [c] y)) && clobberIfDead(x1) => (ADDshiftRA x0 y [c])
(SUB x0 x1:(SLLconst [c] y)) && clobberIfDead(x1) => (SUBshiftLL x0 y [c])
(SUB x0 x1:(SRLconst [c] y)) && clobberIfDead(x1) => (SUBshiftRL x0 y [c])
(SUB x0 x1:(SRAconst [c] y)) && clobberIfDead(x1) => (SUBshiftRA x0 y [c])
(AND x0 x1:(SLLconst [c] y)) && clobberIfDead(x1) => (ANDshiftLL x0 y [c])
(AND x0 x1:(SRLconst [c] y)) && clobberIfDead(x1) => (ANDshiftRL x0 y [c])
(AND x0 x1:(SRAconst [c] y)) && clobberIfDead(x1) => (ANDshiftRA x0 y [c])
(AND x0 x1:(RORconst [c] y)) && clobberIfDead(x1) => (ANDshiftRO x0 y [c])
(OR x0 x1:(SLLconst [c] y)) && clobberIfDead(x1) => (ORshiftLL x0 y [c]) // useful for combined load
(OR x0 x1:(SRLconst [c] y)) && clobberIfDead(x1) => (ORshiftRL x0 y [c])
(OR x0 x1:(SRAconst [c] y)) && clobberIfDead(x1) => (ORshiftRA x0 y [c])
(OR x0 x1:(RORconst [c] y)) && clobberIfDead(x1) => (ORshiftRO x0 y [c])
(XOR x0 x1:(SLLconst [c] y)) && clobberIfDead(x1) => (XORshiftLL x0 y [c])
(XOR x0 x1:(SRLconst [c] y)) && clobberIfDead(x1) => (XORshiftRL x0 y [c])
(XOR x0 x1:(SRAconst [c] y)) && clobberIfDead(x1) => (XORshiftRA x0 y [c])
(XOR x0 x1:(RORconst [c] y)) && clobberIfDead(x1) => (XORshiftRO x0 y [c])
(BIC x0 x1:(SLLconst [c] y)) && clobberIfDead(x1) => (BICshiftLL x0 y [c])
(BIC x0 x1:(SRLconst [c] y)) && clobberIfDead(x1) => (BICshiftRL x0 y [c])
(BIC x0 x1:(SRAconst [c] y)) && clobberIfDead(x1) => (BICshiftRA x0 y [c])
(BIC x0 x1:(RORconst [c] y)) && clobberIfDead(x1) => (BICshiftRO x0 y [c])
(ORN x0 x1:(SLLconst [c] y)) && clobberIfDead(x1) => (ORNshiftLL x0 y [c])
(ORN x0 x1:(SRLconst [c] y)) && clobberIfDead(x1) => (ORNshiftRL x0 y [c])
(ORN x0 x1:(SRAconst [c] y)) && clobberIfDead(x1) => (ORNshiftRA x0 y [c])
(ORN x0 x1:(RORconst [c] y)) && clobberIfDead(x1) => (ORNshiftRO x0 y [c])
(EON x0 x1:(SLLconst [c] y)) && clobberIfDead(x1) => (EONshiftLL x0 y [c])
(EON x0 x1:(SRLconst [c] y)) && clobberIfDead(x1) => (EONshiftRL x0 y [c])
(EON x0 x1:(SRAconst [c] y)) && clobberIfDead(x1) => (EONshiftRA x0 y [c])
(EON x0 x1:(RORconst [c] y)) && clobberIfDead(x1) => (EONshiftRO x0 y [c])
(CMP x0 x1:(SLLconst [c] y)) && clobberIfDead(x1) => (CMPshiftLL x0 y [c])
(CMP x0:(SLLconst [c] y) x1) && clobberIfDead(x0) => (InvertFlags (CMPshiftLL x1 y [c]))
(CMP x0 x1:(SRLconst [c] y)) && clobberIfDead(x1) => (CMPshiftRL x0 y [c])
(CMP x0:(SRLconst [c] y) x1) && clobberIfDead(x0) => (InvertFlags (CMPshiftRL x1 y [c]))
(CMP x0 x1:(SRAconst [c] y)) && clobberIfDead(x1) => (CMPshiftRA x0 y [c])
(CMP x0:(SRAconst [c] y) x1) && clobberIfDead(x0) => (InvertFlags (CMPshiftRA x1 y [c]))
(CMN x0 x1:(SLLconst [c] y)) && clobberIfDead(x1) => (CMNshiftLL x0 y [c])
(CMN x0 x1:(SRLconst [c] y)) && clobberIfDead(x1) => (CMNshiftRL x0 y [c])
(CMN x0 x1:(SRAconst [c] y)) && clobberIfDead(x1) => (CMNshiftRA x0 y [c])
(TST x0 x1:(SLLconst [c] y)) && clobberIfDead(x1) => (TSTshiftLL x0 y [c])
(TST x0 x1:(SRLconst [c] y)) && clobberIfDead(x1) => (TSTshiftRL x0 y [c])
(TST x0 x1:(SRAconst [c] y)) && clobberIfDead(x1) => (TSTshiftRA x0 y [c])
(TST x0 x1:(RORconst [c] y)) && clobberIfDead(x1) => (TSTshiftRO x0 y [c])
// prefer *const ops to *shift ops
(ADDshiftLL (MOVDconst [c]) x [d]) => (ADDconst [c] (SLLconst <x.Type> x [d]))
(ADDshiftRL (MOVDconst [c]) x [d]) => (ADDconst [c] (SRLconst <x.Type> x [d]))
(ADDshiftRA (MOVDconst [c]) x [d]) => (ADDconst [c] (SRAconst <x.Type> x [d]))
(ANDshiftLL (MOVDconst [c]) x [d]) => (ANDconst [c] (SLLconst <x.Type> x [d]))
(ANDshiftRL (MOVDconst [c]) x [d]) => (ANDconst [c] (SRLconst <x.Type> x [d]))
(ANDshiftRA (MOVDconst [c]) x [d]) => (ANDconst [c] (SRAconst <x.Type> x [d]))
(ANDshiftRO (MOVDconst [c]) x [d]) => (ANDconst [c] (RORconst <x.Type> x [d]))
(ORshiftLL (MOVDconst [c]) x [d]) => (ORconst [c] (SLLconst <x.Type> x [d]))
(ORshiftRL (MOVDconst [c]) x [d]) => (ORconst [c] (SRLconst <x.Type> x [d]))
(ORshiftRA (MOVDconst [c]) x [d]) => (ORconst [c] (SRAconst <x.Type> x [d]))
(ORshiftRO (MOVDconst [c]) x [d]) => (ORconst [c] (RORconst <x.Type> x [d]))
(XORshiftLL (MOVDconst [c]) x [d]) => (XORconst [c] (SLLconst <x.Type> x [d]))
(XORshiftRL (MOVDconst [c]) x [d]) => (XORconst [c] (SRLconst <x.Type> x [d]))
(XORshiftRA (MOVDconst [c]) x [d]) => (XORconst [c] (SRAconst <x.Type> x [d]))
(XORshiftRO (MOVDconst [c]) x [d]) => (XORconst [c] (RORconst <x.Type> x [d]))
(CMPshiftLL (MOVDconst [c]) x [d]) => (InvertFlags (CMPconst [c] (SLLconst <x.Type> x [d])))
(CMPshiftRL (MOVDconst [c]) x [d]) => (InvertFlags (CMPconst [c] (SRLconst <x.Type> x [d])))
(CMPshiftRA (MOVDconst [c]) x [d]) => (InvertFlags (CMPconst [c] (SRAconst <x.Type> x [d])))
(CMNshiftLL (MOVDconst [c]) x [d]) => (CMNconst [c] (SLLconst <x.Type> x [d]))
(CMNshiftRL (MOVDconst [c]) x [d]) => (CMNconst [c] (SRLconst <x.Type> x [d]))
(CMNshiftRA (MOVDconst [c]) x [d]) => (CMNconst [c] (SRAconst <x.Type> x [d]))
(TSTshiftLL (MOVDconst [c]) x [d]) => (TSTconst [c] (SLLconst <x.Type> x [d]))
(TSTshiftRL (MOVDconst [c]) x [d]) => (TSTconst [c] (SRLconst <x.Type> x [d]))
(TSTshiftRA (MOVDconst [c]) x [d]) => (TSTconst [c] (SRAconst <x.Type> x [d]))
(TSTshiftRO (MOVDconst [c]) x [d]) => (TSTconst [c] (RORconst <x.Type> x [d]))
// constant folding in *shift ops
(MVNshiftLL (MOVDconst [c]) [d]) => (MOVDconst [^int64(uint64(c)<<uint64(d))])
(MVNshiftRL (MOVDconst [c]) [d]) => (MOVDconst [^int64(uint64(c)>>uint64(d))])
(MVNshiftRA (MOVDconst [c]) [d]) => (MOVDconst [^(c>>uint64(d))])
(MVNshiftRO (MOVDconst [c]) [d]) => (MOVDconst [^rotateRight64(c, d)])
(NEGshiftLL (MOVDconst [c]) [d]) => (MOVDconst [-int64(uint64(c)<<uint64(d))])
(NEGshiftRL (MOVDconst [c]) [d]) => (MOVDconst [-int64(uint64(c)>>uint64(d))])
(NEGshiftRA (MOVDconst [c]) [d]) => (MOVDconst [-(c>>uint64(d))])
(ADDshiftLL x (MOVDconst [c]) [d]) => (ADDconst x [int64(uint64(c)<<uint64(d))])
(ADDshiftRL x (MOVDconst [c]) [d]) => (ADDconst x [int64(uint64(c)>>uint64(d))])
(ADDshiftRA x (MOVDconst [c]) [d]) => (ADDconst x [c>>uint64(d)])
(SUBshiftLL x (MOVDconst [c]) [d]) => (SUBconst x [int64(uint64(c)<<uint64(d))])
(SUBshiftRL x (MOVDconst [c]) [d]) => (SUBconst x [int64(uint64(c)>>uint64(d))])
(SUBshiftRA x (MOVDconst [c]) [d]) => (SUBconst x [c>>uint64(d)])
(ANDshiftLL x (MOVDconst [c]) [d]) => (ANDconst x [int64(uint64(c)<<uint64(d))])
(ANDshiftRL x (MOVDconst [c]) [d]) => (ANDconst x [int64(uint64(c)>>uint64(d))])
(ANDshiftRA x (MOVDconst [c]) [d]) => (ANDconst x [c>>uint64(d)])
(ANDshiftRO x (MOVDconst [c]) [d]) => (ANDconst x [rotateRight64(c, d)])
(ORshiftLL x (MOVDconst [c]) [d]) => (ORconst x [int64(uint64(c)<<uint64(d))])
(ORshiftRL x (MOVDconst [c]) [d]) => (ORconst x [int64(uint64(c)>>uint64(d))])
(ORshiftRA x (MOVDconst [c]) [d]) => (ORconst x [c>>uint64(d)])
(ORshiftRO x (MOVDconst [c]) [d]) => (ORconst x [rotateRight64(c, d)])
(XORshiftLL x (MOVDconst [c]) [d]) => (XORconst x [int64(uint64(c)<<uint64(d))])
(XORshiftRL x (MOVDconst [c]) [d]) => (XORconst x [int64(uint64(c)>>uint64(d))])
(XORshiftRA x (MOVDconst [c]) [d]) => (XORconst x [c>>uint64(d)])
(XORshiftRO x (MOVDconst [c]) [d]) => (XORconst x [rotateRight64(c, d)])
(BICshiftLL x (MOVDconst [c]) [d]) => (ANDconst x [^int64(uint64(c)<<uint64(d))])
(BICshiftRL x (MOVDconst [c]) [d]) => (ANDconst x [^int64(uint64(c)>>uint64(d))])
(BICshiftRA x (MOVDconst [c]) [d]) => (ANDconst x [^(c>>uint64(d))])
(BICshiftRO x (MOVDconst [c]) [d]) => (ANDconst x [^rotateRight64(c, d)])
(ORNshiftLL x (MOVDconst [c]) [d]) => (ORconst x [^int64(uint64(c)<<uint64(d))])
(ORNshiftRL x (MOVDconst [c]) [d]) => (ORconst x [^int64(uint64(c)>>uint64(d))])
(ORNshiftRA x (MOVDconst [c]) [d]) => (ORconst x [^(c>>uint64(d))])
(ORNshiftRO x (MOVDconst [c]) [d]) => (ORconst x [^rotateRight64(c, d)])
(EONshiftLL x (MOVDconst [c]) [d]) => (XORconst x [^int64(uint64(c)<<uint64(d))])
(EONshiftRL x (MOVDconst [c]) [d]) => (XORconst x [^int64(uint64(c)>>uint64(d))])
(EONshiftRA x (MOVDconst [c]) [d]) => (XORconst x [^(c>>uint64(d))])
(EONshiftRO x (MOVDconst [c]) [d]) => (XORconst x [^rotateRight64(c, d)])
(CMPshiftLL x (MOVDconst [c]) [d]) => (CMPconst x [int64(uint64(c)<<uint64(d))])
(CMPshiftRL x (MOVDconst [c]) [d]) => (CMPconst x [int64(uint64(c)>>uint64(d))])
(CMPshiftRA x (MOVDconst [c]) [d]) => (CMPconst x [c>>uint64(d)])
(CMNshiftLL x (MOVDconst [c]) [d]) => (CMNconst x [int64(uint64(c)<<uint64(d))])
(CMNshiftRL x (MOVDconst [c]) [d]) => (CMNconst x [int64(uint64(c)>>uint64(d))])
(CMNshiftRA x (MOVDconst [c]) [d]) => (CMNconst x [c>>uint64(d)])
(TSTshiftLL x (MOVDconst [c]) [d]) => (TSTconst x [int64(uint64(c)<<uint64(d))])
(TSTshiftRL x (MOVDconst [c]) [d]) => (TSTconst x [int64(uint64(c)>>uint64(d))])
(TSTshiftRA x (MOVDconst [c]) [d]) => (TSTconst x [c>>uint64(d)])
(TSTshiftRO x (MOVDconst [c]) [d]) => (TSTconst x [rotateRight64(c, d)])
// simplification with *shift ops
(SUBshiftLL (SLLconst x [c]) x [c]) => (MOVDconst [0])
(SUBshiftRL (SRLconst x [c]) x [c]) => (MOVDconst [0])
(SUBshiftRA (SRAconst x [c]) x [c]) => (MOVDconst [0])
(ANDshiftLL y:(SLLconst x [c]) x [c]) => y
(ANDshiftRL y:(SRLconst x [c]) x [c]) => y
(ANDshiftRA y:(SRAconst x [c]) x [c]) => y
(ANDshiftRO y:(RORconst x [c]) x [c]) => y
(ORshiftLL y:(SLLconst x [c]) x [c]) => y
(ORshiftRL y:(SRLconst x [c]) x [c]) => y
(ORshiftRA y:(SRAconst x [c]) x [c]) => y
(ORshiftRO y:(RORconst x [c]) x [c]) => y
(XORshiftLL (SLLconst x [c]) x [c]) => (MOVDconst [0])
(XORshiftRL (SRLconst x [c]) x [c]) => (MOVDconst [0])
(XORshiftRA (SRAconst x [c]) x [c]) => (MOVDconst [0])
(XORshiftRO (RORconst x [c]) x [c]) => (MOVDconst [0])
(BICshiftLL (SLLconst x [c]) x [c]) => (MOVDconst [0])
(BICshiftRL (SRLconst x [c]) x [c]) => (MOVDconst [0])
(BICshiftRA (SRAconst x [c]) x [c]) => (MOVDconst [0])
(BICshiftRO (RORconst x [c]) x [c]) => (MOVDconst [0])
(EONshiftLL (SLLconst x [c]) x [c]) => (MOVDconst [-1])
(EONshiftRL (SRLconst x [c]) x [c]) => (MOVDconst [-1])
(EONshiftRA (SRAconst x [c]) x [c]) => (MOVDconst [-1])
(EONshiftRO (RORconst x [c]) x [c]) => (MOVDconst [-1])
(ORNshiftLL (SLLconst x [c]) x [c]) => (MOVDconst [-1])
(ORNshiftRL (SRLconst x [c]) x [c]) => (MOVDconst [-1])
(ORNshiftRA (SRAconst x [c]) x [c]) => (MOVDconst [-1])
(ORNshiftRO (RORconst x [c]) x [c]) => (MOVDconst [-1])
// rev16w | rev16
// ((x>>8) | (x<<8)) => (REV16W x), the type of x is uint16, "|" can also be "^" or "+".
((ADDshiftLL|ORshiftLL|XORshiftLL) <typ.UInt16> [8] (UBFX <typ.UInt16> [armBFAuxInt(8, 8)] x) x) => (REV16W x)
// ((x & 0xff00ff00)>>8) | ((x & 0x00ff00ff)<<8), "|" can also be "^" or "+".
((ADDshiftLL|ORshiftLL|XORshiftLL) [8] (UBFX [armBFAuxInt(8, 24)] (ANDconst [c1] x)) (ANDconst [c2] x))
&& uint32(c1) == 0xff00ff00 && uint32(c2) == 0x00ff00ff
=> (REV16W x)
// ((x & 0xff00ff00ff00ff00)>>8) | ((x & 0x00ff00ff00ff00ff)<<8), "|" can also be "^" or "+".
((ADDshiftLL|ORshiftLL|XORshiftLL) [8] (SRLconst [8] (ANDconst [c1] x)) (ANDconst [c2] x))
&& (uint64(c1) == 0xff00ff00ff00ff00 && uint64(c2) == 0x00ff00ff00ff00ff)
=> (REV16 x)
// ((x & 0xff00ff00)>>8) | ((x & 0x00ff00ff)<<8), "|" can also be "^" or "+".
((ADDshiftLL|ORshiftLL|XORshiftLL) [8] (SRLconst [8] (ANDconst [c1] x)) (ANDconst [c2] x))
&& (uint64(c1) == 0xff00ff00 && uint64(c2) == 0x00ff00ff)
=> (REV16 (ANDconst <x.Type> [0xffffffff] x))
// Extract from reg pair
(ADDshiftLL [c] (SRLconst x [64-c]) x2) => (EXTRconst [64-c] x2 x)
( ORshiftLL [c] (SRLconst x [64-c]) x2) => (EXTRconst [64-c] x2 x)
(XORshiftLL [c] (SRLconst x [64-c]) x2) => (EXTRconst [64-c] x2 x)
(ADDshiftLL <t> [c] (UBFX [bfc] x) x2) && c < 32 && t.Size() == 4 && bfc == armBFAuxInt(32-c, c)
=> (EXTRWconst [32-c] x2 x)
( ORshiftLL <t> [c] (UBFX [bfc] x) x2) && c < 32 && t.Size() == 4 && bfc == armBFAuxInt(32-c, c)
=> (EXTRWconst [32-c] x2 x)
(XORshiftLL <t> [c] (UBFX [bfc] x) x2) && c < 32 && t.Size() == 4 && bfc == armBFAuxInt(32-c, c)
=> (EXTRWconst [32-c] x2 x)
// Rewrite special pairs of shifts to AND.
// On ARM64 the bitmask can fit into an instruction.
(SRLconst [c] (SLLconst [c] x)) && 0 < c && c < 64 => (ANDconst [1<<uint(64-c)-1] x) // mask out high bits
(SLLconst [c] (SRLconst [c] x)) && 0 < c && c < 64 => (ANDconst [^(1<<uint(c)-1)] x) // mask out low bits
// Special case setting bit as 1. An example is math.Copysign(c,-1)
(ORconst [c1] (ANDconst [c2] x)) && c2|c1 == ^0 => (ORconst [c1] x)
// If the shift amount is larger than the datasize(32, 16, 8), we can optimize to constant 0.
(MOVWUreg (SLLconst [lc] x)) && lc >= 32 => (MOVDconst [0])
(MOVHUreg (SLLconst [lc] x)) && lc >= 16 => (MOVDconst [0])
(MOVBUreg (SLLconst [lc] x)) && lc >= 8 => (MOVDconst [0])
// After zero extension, the upper (64-datasize(32|16|8)) bits are zero, we can optimiza to constant 0.
(SRLconst [rc] (MOVWUreg x)) && rc >= 32 => (MOVDconst [0])
(SRLconst [rc] (MOVHUreg x)) && rc >= 16 => (MOVDconst [0])
(SRLconst [rc] (MOVBUreg x)) && rc >= 8 => (MOVDconst [0])
// bitfield ops
// sbfiz
// (x << lc) >> rc
(SRAconst [rc] (SLLconst [lc] x)) && lc > rc => (SBFIZ [armBFAuxInt(lc-rc, 64-lc)] x)
// int64(x << lc)
(MOVWreg (SLLconst [lc] x)) && lc < 32 => (SBFIZ [armBFAuxInt(lc, 32-lc)] x)
(MOVHreg (SLLconst [lc] x)) && lc < 16 => (SBFIZ [armBFAuxInt(lc, 16-lc)] x)
(MOVBreg (SLLconst [lc] x)) && lc < 8 => (SBFIZ [armBFAuxInt(lc, 8-lc)] x)
// int64(x) << lc
(SLLconst [lc] (MOVWreg x)) => (SBFIZ [armBFAuxInt(lc, min(32, 64-lc))] x)
(SLLconst [lc] (MOVHreg x)) => (SBFIZ [armBFAuxInt(lc, min(16, 64-lc))] x)
(SLLconst [lc] (MOVBreg x)) => (SBFIZ [armBFAuxInt(lc, min(8, 64-lc))] x)
// sbfx
// (x << lc) >> rc
(SRAconst [rc] (SLLconst [lc] x)) && lc <= rc => (SBFX [armBFAuxInt(rc-lc, 64-rc)] x)
// int64(x) >> rc
(SRAconst [rc] (MOVWreg x)) && rc < 32 => (SBFX [armBFAuxInt(rc, 32-rc)] x)
(SRAconst [rc] (MOVHreg x)) && rc < 16 => (SBFX [armBFAuxInt(rc, 16-rc)] x)
(SRAconst [rc] (MOVBreg x)) && rc < 8 => (SBFX [armBFAuxInt(rc, 8-rc)] x)
// merge sbfx and sign-extension into sbfx
(MOVWreg (SBFX [bfc] x)) && bfc.getARM64BFwidth() <= 32 => (SBFX [bfc] x)
(MOVHreg (SBFX [bfc] x)) && bfc.getARM64BFwidth() <= 16 => (SBFX [bfc] x)
(MOVBreg (SBFX [bfc] x)) && bfc.getARM64BFwidth() <= 8 => (SBFX [bfc] x)
// sbfiz/sbfx combinations: merge shifts into bitfield ops
(SRAconst [sc] (SBFIZ [bfc] x)) && sc < bfc.getARM64BFlsb()
=> (SBFIZ [armBFAuxInt(bfc.getARM64BFlsb()-sc, bfc.getARM64BFwidth())] x)
(SRAconst [sc] (SBFIZ [bfc] x)) && sc >= bfc.getARM64BFlsb()
&& sc < bfc.getARM64BFlsb()+bfc.getARM64BFwidth()
=> (SBFX [armBFAuxInt(sc-bfc.getARM64BFlsb(), bfc.getARM64BFlsb()+bfc.getARM64BFwidth()-sc)] x)
// ubfiz
// (x << lc) >> rc
(SRLconst [rc] (SLLconst [lc] x)) && lc > rc => (UBFIZ [armBFAuxInt(lc-rc, 64-lc)] x)
// uint64(x) << lc
(SLLconst [lc] (MOVWUreg x)) => (UBFIZ [armBFAuxInt(lc, min(32, 64-lc))] x)
(SLLconst [lc] (MOVHUreg x)) => (UBFIZ [armBFAuxInt(lc, min(16, 64-lc))] x)
(SLLconst [lc] (MOVBUreg x)) => (UBFIZ [armBFAuxInt(lc, min(8, 64-lc))] x)
// uint64(x << lc)
(MOVWUreg (SLLconst [lc] x)) && lc < 32 => (UBFIZ [armBFAuxInt(lc, 32-lc)] x)
(MOVHUreg (SLLconst [lc] x)) && lc < 16 => (UBFIZ [armBFAuxInt(lc, 16-lc)] x)
(MOVBUreg (SLLconst [lc] x)) && lc < 8 => (UBFIZ [armBFAuxInt(lc, 8-lc)] x)
// merge ANDconst into ubfiz
// (x & ac) << sc
(SLLconst [sc] (ANDconst [ac] x)) && isARM64BFMask(sc, ac, 0)
=> (UBFIZ [armBFAuxInt(sc, arm64BFWidth(ac, 0))] x)
// (x << sc) & ac
(ANDconst [ac] (SLLconst [sc] x)) && isARM64BFMask(sc, ac, sc)
=> (UBFIZ [armBFAuxInt(sc, arm64BFWidth(ac, sc))] x)
// ubfx
// (x << lc) >> rc
(SRLconst [rc] (SLLconst [lc] x)) && lc < rc => (UBFX [armBFAuxInt(rc-lc, 64-rc)] x)
// uint64(x) >> rc
(SRLconst [rc] (MOVWUreg x)) && rc < 32 => (UBFX [armBFAuxInt(rc, 32-rc)] x)
(SRLconst [rc] (MOVHUreg x)) && rc < 16 => (UBFX [armBFAuxInt(rc, 16-rc)] x)
(SRLconst [rc] (MOVBUreg x)) && rc < 8 => (UBFX [armBFAuxInt(rc, 8-rc)] x)
// uint64(x >> rc)
(MOVWUreg (SRLconst [rc] x)) && rc < 32 => (UBFX [armBFAuxInt(rc, 32)] x)
(MOVHUreg (SRLconst [rc] x)) && rc < 16 => (UBFX [armBFAuxInt(rc, 16)] x)
(MOVBUreg (SRLconst [rc] x)) && rc < 8 => (UBFX [armBFAuxInt(rc, 8)] x)
// merge ANDconst into ubfx
// (x >> sc) & ac
(ANDconst [ac] (SRLconst [sc] x)) && isARM64BFMask(sc, ac, 0)
=> (UBFX [armBFAuxInt(sc, arm64BFWidth(ac, 0))] x)
// (x & ac) >> sc
(SRLconst [sc] (ANDconst [ac] x)) && isARM64BFMask(sc, ac, sc)
=> (UBFX [armBFAuxInt(sc, arm64BFWidth(ac, sc))] x)
// merge ANDconst and ubfx into ubfx
(ANDconst [c] (UBFX [bfc] x)) && isARM64BFMask(0, c, 0) =>
(UBFX [armBFAuxInt(bfc.getARM64BFlsb(), min(bfc.getARM64BFwidth(), arm64BFWidth(c, 0)))] x)
(UBFX [bfc] (ANDconst [c] x)) && isARM64BFMask(0, c, 0) && bfc.getARM64BFlsb() + bfc.getARM64BFwidth() <= arm64BFWidth(c, 0) =>
(UBFX [bfc] x)
// merge ubfx and zerso-extension into ubfx
(MOVWUreg (UBFX [bfc] x)) && bfc.getARM64BFwidth() <= 32 => (UBFX [bfc] x)
(MOVHUreg (UBFX [bfc] x)) && bfc.getARM64BFwidth() <= 16 => (UBFX [bfc] x)
(MOVBUreg (UBFX [bfc] x)) && bfc.getARM64BFwidth() <= 8 => (UBFX [bfc] x)
// ubfiz/ubfx combinations: merge shifts into bitfield ops
(SRLconst [sc] (UBFX [bfc] x)) && sc < bfc.getARM64BFwidth()
=> (UBFX [armBFAuxInt(bfc.getARM64BFlsb()+sc, bfc.getARM64BFwidth()-sc)] x)
(UBFX [bfc] (SRLconst [sc] x)) && sc+bfc.getARM64BFwidth()+bfc.getARM64BFlsb() < 64
=> (UBFX [armBFAuxInt(bfc.getARM64BFlsb()+sc, bfc.getARM64BFwidth())] x)
(SLLconst [sc] (UBFIZ [bfc] x)) && sc+bfc.getARM64BFwidth()+bfc.getARM64BFlsb() < 64
=> (UBFIZ [armBFAuxInt(bfc.getARM64BFlsb()+sc, bfc.getARM64BFwidth())] x)
(UBFIZ [bfc] (SLLconst [sc] x)) && sc < bfc.getARM64BFwidth()
=> (UBFIZ [armBFAuxInt(bfc.getARM64BFlsb()+sc, bfc.getARM64BFwidth()-sc)] x)
// ((x << c1) >> c2) >> c3
(SRLconst [sc] (UBFIZ [bfc] x)) && sc == bfc.getARM64BFlsb()
=> (ANDconst [1<<uint(bfc.getARM64BFwidth())-1] x)
(SRLconst [sc] (UBFIZ [bfc] x)) && sc < bfc.getARM64BFlsb()
=> (UBFIZ [armBFAuxInt(bfc.getARM64BFlsb()-sc, bfc.getARM64BFwidth())] x)
(SRLconst [sc] (UBFIZ [bfc] x)) && sc > bfc.getARM64BFlsb()
&& sc < bfc.getARM64BFlsb()+bfc.getARM64BFwidth()
=> (UBFX [armBFAuxInt(sc-bfc.getARM64BFlsb(), bfc.getARM64BFlsb()+bfc.getARM64BFwidth()-sc)] x)
// ((x << c1) << c2) >> c3
(UBFX [bfc] (SLLconst [sc] x)) && sc == bfc.getARM64BFlsb()
=> (ANDconst [1<<uint(bfc.getARM64BFwidth())-1] x)
(UBFX [bfc] (SLLconst [sc] x)) && sc < bfc.getARM64BFlsb()
=> (UBFX [armBFAuxInt(bfc.getARM64BFlsb()-sc, bfc.getARM64BFwidth())] x)
(UBFX [bfc] (SLLconst [sc] x)) && sc > bfc.getARM64BFlsb()
&& sc < bfc.getARM64BFlsb()+bfc.getARM64BFwidth()
=> (UBFIZ [armBFAuxInt(sc-bfc.getARM64BFlsb(), bfc.getARM64BFlsb()+bfc.getARM64BFwidth()-sc)] x)
// bfi
(OR (UBFIZ [bfc] x) (ANDconst [ac] y))
&& ac == ^((1<<uint(bfc.getARM64BFwidth())-1) << uint(bfc.getARM64BFlsb()))
=> (BFI [bfc] y x)
(ORshiftRL [rc] (ANDconst [ac] x) (SLLconst [lc] y))
&& lc > rc && ac == ^((1<<uint(64-lc)-1) << uint64(lc-rc))
=> (BFI [armBFAuxInt(lc-rc, 64-lc)] x y)
// bfxil
(OR (UBFX [bfc] x) (ANDconst [ac] y)) && ac == ^(1<<uint(bfc.getARM64BFwidth())-1)
=> (BFXIL [bfc] y x)
(ORshiftLL [sc] (UBFX [bfc] x) (SRLconst [sc] y)) && sc == bfc.getARM64BFwidth()
=> (BFXIL [bfc] y x)
(ORshiftRL [rc] (ANDconst [ac] y) (SLLconst [lc] x)) && lc < rc && ac == ^((1<<uint(64-rc)-1))
=> (BFXIL [armBFAuxInt(rc-lc, 64-rc)] y x)
// FP simplification
(FNEGS (FMULS x y)) => (FNMULS x y)
(FNEGD (FMULD x y)) => (FNMULD x y)
(FMULS (FNEGS x) y) => (FNMULS x y)
(FMULD (FNEGD x) y) => (FNMULD x y)
(FNEGS (FNMULS x y)) => (FMULS x y)
(FNEGD (FNMULD x y)) => (FMULD x y)
(FNMULS (FNEGS x) y) => (FMULS x y)
(FNMULD (FNEGD x) y) => (FMULD x y)
(FADDS a (FMULS x y)) && a.Block.Func.useFMA(v) => (FMADDS a x y)
(FADDD a (FMULD x y)) && a.Block.Func.useFMA(v) => (FMADDD a x y)
(FSUBS a (FMULS x y)) && a.Block.Func.useFMA(v) => (FMSUBS a x y)
(FSUBD a (FMULD x y)) && a.Block.Func.useFMA(v) => (FMSUBD a x y)
(FSUBS (FMULS x y) a) && a.Block.Func.useFMA(v) => (FNMSUBS a x y)
(FSUBD (FMULD x y) a) && a.Block.Func.useFMA(v) => (FNMSUBD a x y)
(FADDS a (FNMULS x y)) && a.Block.Func.useFMA(v) => (FMSUBS a x y)
(FADDD a (FNMULD x y)) && a.Block.Func.useFMA(v) => (FMSUBD a x y)
(FSUBS a (FNMULS x y)) && a.Block.Func.useFMA(v) => (FMADDS a x y)
(FSUBD a (FNMULD x y)) && a.Block.Func.useFMA(v) => (FMADDD a x y)
(FSUBS (FNMULS x y) a) && a.Block.Func.useFMA(v) => (FNMADDS a x y)
(FSUBD (FNMULD x y) a) && a.Block.Func.useFMA(v) => (FNMADDD a x y)
(MOVBUload [off] {sym} (SB) _) && symIsRO(sym) => (MOVDconst [int64(read8(sym, int64(off)))])
(MOVHUload [off] {sym} (SB) _) && symIsRO(sym) => (MOVDconst [int64(read16(sym, int64(off), config.ctxt.Arch.ByteOrder))])
(MOVWUload [off] {sym} (SB) _) && symIsRO(sym) => (MOVDconst [int64(read32(sym, int64(off), config.ctxt.Arch.ByteOrder))])
(MOVDload [off] {sym} (SB) _) && symIsRO(sym) => (MOVDconst [int64(read64(sym, int64(off), config.ctxt.Arch.ByteOrder))])
// Prefetch instructions (aux is option: 0 - PLDL1KEEP; 1 - PLDL1STRM)
(PrefetchCache addr mem) => (PRFM [0] addr mem)
(PrefetchCacheStreamed addr mem) => (PRFM [1] addr mem)
// Arch-specific inlining for small or disjoint runtime.memmove
(SelectN [0] call:(CALLstatic {sym} s1:(MOVDstore _ (MOVDconst [sz]) s2:(MOVDstore _ src s3:(MOVDstore {t} _ dst mem)))))
&& sz >= 0
&& isSameCall(sym, "runtime.memmove")
&& s1.Uses == 1 && s2.Uses == 1 && s3.Uses == 1
&& isInlinableMemmove(dst, src, sz, config)
&& clobber(s1, s2, s3, call)
=> (Move [sz] dst src mem)
// Match post-lowering calls, register version.
(SelectN [0] call:(CALLstatic {sym} dst src (MOVDconst [sz]) mem))
&& sz >= 0
&& isSameCall(sym, "runtime.memmove")
&& call.Uses == 1
&& isInlinableMemmove(dst, src, sz, config)
&& clobber(call)
=> (Move [sz] dst src mem)
((REV|REVW) ((REV|REVW) p)) => p
// runtime/internal/math.MulUintptr intrinsics
(Select0 (Mul64uover x y)) => (MUL x y)
(Select1 (Mul64uover x y)) => (NotEqual (CMPconst (UMULH <typ.UInt64> x y) [0]))
|