// 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. // Optimizations TODO: // * Use SLTI and SLTIU for comparisons to constants, instead of SLT/SLTU with constants in registers // * Use the zero register instead of moving 0 into a register. // * Add rules to avoid generating a temp bool value for (If (SLT[U] ...) ...). // * Arrange for non-trivial Zero and Move lowerings to use aligned loads and stores. // * Avoid using Neq32 for writeBarrier.enabled checks. // Lowering arithmetic (Add64 ...) => (ADD ...) (AddPtr ...) => (ADD ...) (Add32 ...) => (ADD ...) (Add16 ...) => (ADD ...) (Add8 ...) => (ADD ...) (Add32F ...) => (FADDS ...) (Add64F ...) => (FADDD ...) (Sub64 ...) => (SUB ...) (SubPtr ...) => (SUB ...) (Sub32 ...) => (SUB ...) (Sub16 ...) => (SUB ...) (Sub8 ...) => (SUB ...) (Sub32F ...) => (FSUBS ...) (Sub64F ...) => (FSUBD ...) (Mul64 ...) => (MUL ...) (Mul64uhilo ...) => (LoweredMuluhilo ...) (Mul64uover ...) => (LoweredMuluover ...) (Mul32 ...) => (MULW ...) (Mul16 x y) => (MULW (SignExt16to32 x) (SignExt16to32 y)) (Mul8 x y) => (MULW (SignExt8to32 x) (SignExt8to32 y)) (Mul32F ...) => (FMULS ...) (Mul64F ...) => (FMULD ...) (Div32F ...) => (FDIVS ...) (Div64F ...) => (FDIVD ...) (Div64 x y [false]) => (DIV x y) (Div64u ...) => (DIVU ...) (Div32 x y [false]) => (DIVW x y) (Div32u ...) => (DIVUW ...) (Div16 x y [false]) => (DIVW (SignExt16to32 x) (SignExt16to32 y)) (Div16u x y) => (DIVUW (ZeroExt16to32 x) (ZeroExt16to32 y)) (Div8 x y) => (DIVW (SignExt8to32 x) (SignExt8to32 y)) (Div8u x y) => (DIVUW (ZeroExt8to32 x) (ZeroExt8to32 y)) (Hmul64 ...) => (MULH ...) (Hmul64u ...) => (MULHU ...) (Hmul32 x y) => (SRAI [32] (MUL (SignExt32to64 x) (SignExt32to64 y))) (Hmul32u x y) => (SRLI [32] (MUL (ZeroExt32to64 x) (ZeroExt32to64 y))) // (x + y) / 2 => (x / 2) + (y / 2) + (x & y & 1) (Avg64u x y) => (ADD (ADD (SRLI [1] x) (SRLI [1] y)) (ANDI [1] (AND x y))) (Mod64 x y [false]) => (REM x y) (Mod64u ...) => (REMU ...) (Mod32 x y [false]) => (REMW x y) (Mod32u ...) => (REMUW ...) (Mod16 x y [false]) => (REMW (SignExt16to32 x) (SignExt16to32 y)) (Mod16u x y) => (REMUW (ZeroExt16to32 x) (ZeroExt16to32 y)) (Mod8 x y) => (REMW (SignExt8to32 x) (SignExt8to32 y)) (Mod8u x y) => (REMUW (ZeroExt8to32 x) (ZeroExt8to32 y)) (And64 ...) => (AND ...) (And32 ...) => (AND ...) (And16 ...) => (AND ...) (And8 ...) => (AND ...) (Or64 ...) => (OR ...) (Or32 ...) => (OR ...) (Or16 ...) => (OR ...) (Or8 ...) => (OR ...) (Xor64 ...) => (XOR ...) (Xor32 ...) => (XOR ...) (Xor16 ...) => (XOR ...) (Xor8 ...) => (XOR ...) (Neg64 ...) => (NEG ...) (Neg32 ...) => (NEG ...) (Neg16 ...) => (NEG ...) (Neg8 ...) => (NEG ...) (Neg32F ...) => (FNEGS ...) (Neg64F ...) => (FNEGD ...) (Com64 ...) => (NOT ...) (Com32 ...) => (NOT ...) (Com16 ...) => (NOT ...) (Com8 ...) => (NOT ...) (Sqrt ...) => (FSQRTD ...) (Sqrt32 ...) => (FSQRTS ...) (Copysign ...) => (FSGNJD ...) (Abs ...) => (FABSD ...) (FMA ...) => (FMADDD ...) // Sign and zero extension. (SignExt8to16 ...) => (MOVBreg ...) (SignExt8to32 ...) => (MOVBreg ...) (SignExt8to64 ...) => (MOVBreg ...) (SignExt16to32 ...) => (MOVHreg ...) (SignExt16to64 ...) => (MOVHreg ...) (SignExt32to64 ...) => (MOVWreg ...) (ZeroExt8to16 ...) => (MOVBUreg ...) (ZeroExt8to32 ...) => (MOVBUreg ...) (ZeroExt8to64 ...) => (MOVBUreg ...) (ZeroExt16to32 ...) => (MOVHUreg ...) (ZeroExt16to64 ...) => (MOVHUreg ...) (ZeroExt32to64 ...) => (MOVWUreg ...) (Cvt32to32F ...) => (FCVTSW ...) (Cvt32to64F ...) => (FCVTDW ...) (Cvt64to32F ...) => (FCVTSL ...) (Cvt64to64F ...) => (FCVTDL ...) (Cvt32Fto32 ...) => (FCVTWS ...) (Cvt32Fto64 ...) => (FCVTLS ...) (Cvt64Fto32 ...) => (FCVTWD ...) (Cvt64Fto64 ...) => (FCVTLD ...) (Cvt32Fto64F ...) => (FCVTDS ...) (Cvt64Fto32F ...) => (FCVTSD ...) (CvtBoolToUint8 ...) => (Copy ...) (Round32F ...) => (Copy ...) (Round64F ...) => (Copy ...) // From genericOps.go: // "0 if arg0 == 0, -1 if arg0 > 0, undef if arg0<0" // // Like other arches, we compute ~((x-1) >> 63), with arithmetic right shift. // For positive x, bit 63 of x-1 is always 0, so the result is -1. // For zero x, bit 63 of x-1 is 1, so the result is 0. // (Slicemask x) => (NOT (SRAI [63] (ADDI [-1] x))) // Truncations // We ignore the unused high parts of registers, so truncates are just copies. (Trunc16to8 ...) => (Copy ...) (Trunc32to8 ...) => (Copy ...) (Trunc32to16 ...) => (Copy ...) (Trunc64to8 ...) => (Copy ...) (Trunc64to16 ...) => (Copy ...) (Trunc64to32 ...) => (Copy ...) // Shifts // SLL only considers the bottom 6 bits of y. If y > 64, the result should // always be 0. // // Breaking down the operation: // // (SLL x y) generates x << (y & 63). // // If y < 64, this is the value we want. Otherwise, we want zero. // // So, we AND with -1 * uint64(y < 64), which is 0xfffff... if y < 64 and 0 otherwise. (Lsh8x8 x y) => (AND (SLL x y) (Neg8 (SLTIU [64] (ZeroExt8to64 y)))) (Lsh8x16 x y) => (AND (SLL x y) (Neg8 (SLTIU [64] (ZeroExt16to64 y)))) (Lsh8x32 x y) => (AND (SLL x y) (Neg8 (SLTIU [64] (ZeroExt32to64 y)))) (Lsh8x64 x y) => (AND (SLL x y) (Neg8 (SLTIU [64] y))) (Lsh16x8 x y) => (AND (SLL x y) (Neg16 (SLTIU [64] (ZeroExt8to64 y)))) (Lsh16x16 x y) => (AND (SLL x y) (Neg16 (SLTIU [64] (ZeroExt16to64 y)))) (Lsh16x32 x y) => (AND (SLL x y) (Neg16 (SLTIU [64] (ZeroExt32to64 y)))) (Lsh16x64 x y) => (AND (SLL x y) (Neg16 (SLTIU [64] y))) (Lsh32x8 x y) => (AND (SLL x y) (Neg32 (SLTIU [64] (ZeroExt8to64 y)))) (Lsh32x16 x y) => (AND (SLL x y) (Neg32 (SLTIU [64] (ZeroExt16to64 y)))) (Lsh32x32 x y) => (AND (SLL x y) (Neg32 (SLTIU [64] (ZeroExt32to64 y)))) (Lsh32x64 x y) => (AND (SLL x y) (Neg32 (SLTIU [64] y))) (Lsh64x8 x y) => (AND (SLL x y) (Neg64 (SLTIU [64] (ZeroExt8to64 y)))) (Lsh64x16 x y) => (AND (SLL x y) (Neg64 (SLTIU [64] (ZeroExt16to64 y)))) (Lsh64x32 x y) => (AND (SLL x y) (Neg64 (SLTIU [64] (ZeroExt32to64 y)))) (Lsh64x64 x y) => (AND (SLL x y) (Neg64 (SLTIU [64] y))) // SRL only considers the bottom 6 bits of y. If y > 64, the result should // always be 0. See Lsh above for a detailed description. (Rsh8Ux8 x y) => (AND (SRL (ZeroExt8to64 x) y) (Neg8 (SLTIU [64] (ZeroExt8to64 y)))) (Rsh8Ux16 x y) => (AND (SRL (ZeroExt8to64 x) y) (Neg8 (SLTIU [64] (ZeroExt16to64 y)))) (Rsh8Ux32 x y) => (AND (SRL (ZeroExt8to64 x) y) (Neg8 (SLTIU [64] (ZeroExt32to64 y)))) (Rsh8Ux64 x y) => (AND (SRL (ZeroExt8to64 x) y) (Neg8 (SLTIU [64] y))) (Rsh16Ux8 x y) => (AND (SRL (ZeroExt16to64 x) y) (Neg16 (SLTIU [64] (ZeroExt8to64 y)))) (Rsh16Ux16 x y) => (AND (SRL (ZeroExt16to64 x) y) (Neg16 (SLTIU [64] (ZeroExt16to64 y)))) (Rsh16Ux32 x y) => (AND (SRL (ZeroExt16to64 x) y) (Neg16 (SLTIU [64] (ZeroExt32to64 y)))) (Rsh16Ux64 x y) => (AND (SRL (ZeroExt16to64 x) y) (Neg16 (SLTIU [64] y))) (Rsh32Ux8 x y) => (AND (SRL (ZeroExt32to64 x) y) (Neg32 (SLTIU [64] (ZeroExt8to64 y)))) (Rsh32Ux16 x y) => (AND (SRL (ZeroExt32to64 x) y) (Neg32 (SLTIU [64] (ZeroExt16to64 y)))) (Rsh32Ux32 x y) => (AND (SRL (ZeroExt32to64 x) y) (Neg32 (SLTIU [64] (ZeroExt32to64 y)))) (Rsh32Ux64 x y) => (AND (SRL (ZeroExt32to64 x) y) (Neg32 (SLTIU [64] y))) (Rsh64Ux8 x y) => (AND (SRL x y) (Neg64 (SLTIU [64] (ZeroExt8to64 y)))) (Rsh64Ux16 x y) => (AND (SRL x y) (Neg64 (SLTIU [64] (ZeroExt16to64 y)))) (Rsh64Ux32 x y) => (AND (SRL x y) (Neg64 (SLTIU [64] (ZeroExt32to64 y)))) (Rsh64Ux64 x y) => (AND (SRL x y) (Neg64 (SLTIU [64] y))) // SRA only considers the bottom 6 bits of y. If y > 64, the result should // be either 0 or -1 based on the sign bit. // // We implement this by performing the max shift (-1) if y >= 64. // // We OR (uint64(y < 64) - 1) into y before passing it to SRA. This leaves // us with -1 (0xffff...) if y >= 64. // // We don't need to sign-extend the OR result, as it will be at minimum 8 bits, // more than the 6 bits SRA cares about. (Rsh8x8 x y) => (SRA (SignExt8to64 x) (OR y (ADDI [-1] (SLTIU [64] (ZeroExt8to64 y))))) (Rsh8x16 x y) => (SRA (SignExt8to64 x) (OR y (ADDI [-1] (SLTIU [64] (ZeroExt16to64 y))))) (Rsh8x32 x y) => (SRA (SignExt8to64 x) (OR y (ADDI [-1] (SLTIU [64] (ZeroExt32to64 y))))) (Rsh8x64 x y) => (SRA (SignExt8to64 x) (OR y (ADDI [-1] (SLTIU [64] y)))) (Rsh16x8 x y) => (SRA (SignExt16to64 x) (OR y (ADDI [-1] (SLTIU [64] (ZeroExt8to64 y))))) (Rsh16x16 x y) => (SRA (SignExt16to64 x) (OR y (ADDI [-1] (SLTIU [64] (ZeroExt16to64 y))))) (Rsh16x32 x y) => (SRA (SignExt16to64 x) (OR y (ADDI [-1] (SLTIU [64] (ZeroExt32to64 y))))) (Rsh16x64 x y) => (SRA (SignExt16to64 x) (OR y (ADDI [-1] (SLTIU [64] y)))) (Rsh32x8 x y) => (SRA (SignExt32to64 x) (OR y (ADDI [-1] (SLTIU [64] (ZeroExt8to64 y))))) (Rsh32x16 x y) => (SRA (SignExt32to64 x) (OR y (ADDI [-1] (SLTIU [64] (ZeroExt16to64 y))))) (Rsh32x32 x y) => (SRA (SignExt32to64 x) (OR y (ADDI [-1] (SLTIU [64] (ZeroExt32to64 y))))) (Rsh32x64 x y) => (SRA (SignExt32to64 x) (OR y (ADDI [-1] (SLTIU [64] y)))) (Rsh64x8 x y) => (SRA x (OR y (ADDI [-1] (SLTIU [64] (ZeroExt8to64 y))))) (Rsh64x16 x y) => (SRA x (OR y (ADDI [-1] (SLTIU [64] (ZeroExt16to64 y))))) (Rsh64x32 x y) => (SRA x (OR y (ADDI [-1] (SLTIU [64] (ZeroExt32to64 y))))) (Rsh64x64 x y) => (SRA x (OR y (ADDI [-1] (SLTIU [64] y)))) // Rotates. (RotateLeft8 x (MOVDconst [c])) => (Or8 (Lsh8x64 x (MOVDconst [c&7])) (Rsh8Ux64 x (MOVDconst [-c&7]))) (RotateLeft16 x (MOVDconst [c])) => (Or16 (Lsh16x64 x (MOVDconst [c&15])) (Rsh16Ux64 x (MOVDconst [-c&15]))) (RotateLeft32 x (MOVDconst [c])) => (Or32 (Lsh32x64 x (MOVDconst [c&31])) (Rsh32Ux64 x (MOVDconst [-c&31]))) (RotateLeft64 x (MOVDconst [c])) => (Or64 (Lsh64x64 x (MOVDconst [c&63])) (Rsh64Ux64 x (MOVDconst [-c&63]))) (Less64 ...) => (SLT ...) (Less32 x y) => (SLT (SignExt32to64 x) (SignExt32to64 y)) (Less16 x y) => (SLT (SignExt16to64 x) (SignExt16to64 y)) (Less8 x y) => (SLT (SignExt8to64 x) (SignExt8to64 y)) (Less64U ...) => (SLTU ...) (Less32U x y) => (SLTU (ZeroExt32to64 x) (ZeroExt32to64 y)) (Less16U x y) => (SLTU (ZeroExt16to64 x) (ZeroExt16to64 y)) (Less8U x y) => (SLTU (ZeroExt8to64 x) (ZeroExt8to64 y)) (Less64F ...) => (FLTD ...) (Less32F ...) => (FLTS ...) // Convert x <= y to !(y > x). (Leq64 x y) => (Not (Less64 y x)) (Leq32 x y) => (Not (Less32 y x)) (Leq16 x y) => (Not (Less16 y x)) (Leq8 x y) => (Not (Less8 y x)) (Leq64U x y) => (Not (Less64U y x)) (Leq32U x y) => (Not (Less32U y x)) (Leq16U x y) => (Not (Less16U y x)) (Leq8U x y) => (Not (Less8U y x)) (Leq64F ...) => (FLED ...) (Leq32F ...) => (FLES ...) (EqPtr x y) => (SEQZ (SUB x y)) (Eq64 x y) => (SEQZ (SUB x y)) (Eq32 x y) => (SEQZ (SUB (ZeroExt32to64 x) (ZeroExt32to64 y))) (Eq16 x y) => (SEQZ (SUB (ZeroExt16to64 x) (ZeroExt16to64 y))) (Eq8 x y) => (SEQZ (SUB (ZeroExt8to64 x) (ZeroExt8to64 y))) (Eq64F ...) => (FEQD ...) (Eq32F ...) => (FEQS ...) (NeqPtr x y) => (SNEZ (SUB x y)) (Neq64 x y) => (SNEZ (SUB x y)) (Neq32 x y) => (SNEZ (SUB (ZeroExt32to64 x) (ZeroExt32to64 y))) (Neq16 x y) => (SNEZ (SUB (ZeroExt16to64 x) (ZeroExt16to64 y))) (Neq8 x y) => (SNEZ (SUB (ZeroExt8to64 x) (ZeroExt8to64 y))) (Neq64F ...) => (FNED ...) (Neq32F ...) => (FNES ...) // Loads (Load ptr mem) && t.IsBoolean() => (MOVBUload ptr mem) (Load ptr mem) && ( is8BitInt(t) && isSigned(t)) => (MOVBload ptr mem) (Load ptr mem) && ( is8BitInt(t) && !isSigned(t)) => (MOVBUload ptr mem) (Load ptr mem) && (is16BitInt(t) && isSigned(t)) => (MOVHload ptr mem) (Load ptr mem) && (is16BitInt(t) && !isSigned(t)) => (MOVHUload ptr mem) (Load ptr mem) && (is32BitInt(t) && isSigned(t)) => (MOVWload ptr mem) (Load ptr mem) && (is32BitInt(t) && !isSigned(t)) => (MOVWUload ptr mem) (Load ptr mem) && (is64BitInt(t) || isPtr(t)) => (MOVDload ptr mem) (Load ptr mem) && is32BitFloat(t) => (FMOVWload ptr mem) (Load 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 && !is32BitFloat(val.Type) => (MOVWstore ptr val mem) (Store {t} ptr val mem) && t.Size() == 8 && !is64BitFloat(val.Type) => (MOVDstore ptr val mem) (Store {t} ptr val mem) && t.Size() == 4 && is32BitFloat(val.Type) => (FMOVWstore ptr val mem) (Store {t} ptr val mem) && t.Size() == 8 && is64BitFloat(val.Type) => (FMOVDstore ptr val mem) // We need to fold MOVaddr into the LD/MOVDstore ops so that the live variable analysis // knows what variables are being read/written by the ops. (MOVBUload [off1] {sym1} (MOVaddr [off2] {sym2} base) mem) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => (MOVBUload [off1+off2] {mergeSym(sym1,sym2)} base mem) (MOVBload [off1] {sym1} (MOVaddr [off2] {sym2} base) mem) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => (MOVBload [off1+off2] {mergeSym(sym1,sym2)} base mem) (MOVHUload [off1] {sym1} (MOVaddr [off2] {sym2} base) mem) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => (MOVHUload [off1+off2] {mergeSym(sym1,sym2)} base mem) (MOVHload [off1] {sym1} (MOVaddr [off2] {sym2} base) mem) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => (MOVHload [off1+off2] {mergeSym(sym1,sym2)} base mem) (MOVWUload [off1] {sym1} (MOVaddr [off2] {sym2} base) mem) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => (MOVWUload [off1+off2] {mergeSym(sym1,sym2)} base mem) (MOVWload [off1] {sym1} (MOVaddr [off2] {sym2} base) mem) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => (MOVWload [off1+off2] {mergeSym(sym1,sym2)} base mem) (MOVDload [off1] {sym1} (MOVaddr [off2] {sym2} base) mem) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => (MOVDload [off1+off2] {mergeSym(sym1,sym2)} base mem) (MOVBstore [off1] {sym1} (MOVaddr [off2] {sym2} base) val mem) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => (MOVBstore [off1+off2] {mergeSym(sym1,sym2)} base val mem) (MOVHstore [off1] {sym1} (MOVaddr [off2] {sym2} base) val mem) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => (MOVHstore [off1+off2] {mergeSym(sym1,sym2)} base val mem) (MOVWstore [off1] {sym1} (MOVaddr [off2] {sym2} base) val mem) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => (MOVWstore [off1+off2] {mergeSym(sym1,sym2)} base val mem) (MOVDstore [off1] {sym1} (MOVaddr [off2] {sym2} base) val mem) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => (MOVDstore [off1+off2] {mergeSym(sym1,sym2)} base val mem) (MOVBstorezero [off1] {sym1} (MOVaddr [off2] {sym2} ptr) mem) && canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2)) => (MOVBstorezero [off1+off2] {mergeSym(sym1,sym2)} ptr mem) (MOVHstorezero [off1] {sym1} (MOVaddr [off2] {sym2} ptr) mem) && canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2)) => (MOVHstorezero [off1+off2] {mergeSym(sym1,sym2)} ptr mem) (MOVWstorezero [off1] {sym1} (MOVaddr [off2] {sym2} ptr) mem) && canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2)) => (MOVWstorezero [off1+off2] {mergeSym(sym1,sym2)} ptr mem) (MOVDstorezero [off1] {sym1} (MOVaddr [off2] {sym2} ptr) mem) && canMergeSym(sym1,sym2) && is32Bit(int64(off1)+int64(off2)) => (MOVDstorezero [off1+off2] {mergeSym(sym1,sym2)} ptr mem) (MOVBUload [off1] {sym} (ADDI [off2] base) mem) && is32Bit(int64(off1)+off2) => (MOVBUload [off1+int32(off2)] {sym} base mem) (MOVBload [off1] {sym} (ADDI [off2] base) mem) && is32Bit(int64(off1)+off2) => (MOVBload [off1+int32(off2)] {sym} base mem) (MOVHUload [off1] {sym} (ADDI [off2] base) mem) && is32Bit(int64(off1)+off2) => (MOVHUload [off1+int32(off2)] {sym} base mem) (MOVHload [off1] {sym} (ADDI [off2] base) mem) && is32Bit(int64(off1)+off2) => (MOVHload [off1+int32(off2)] {sym} base mem) (MOVWUload [off1] {sym} (ADDI [off2] base) mem) && is32Bit(int64(off1)+off2) => (MOVWUload [off1+int32(off2)] {sym} base mem) (MOVWload [off1] {sym} (ADDI [off2] base) mem) && is32Bit(int64(off1)+off2) => (MOVWload [off1+int32(off2)] {sym} base mem) (MOVDload [off1] {sym} (ADDI [off2] base) mem) && is32Bit(int64(off1)+off2) => (MOVDload [off1+int32(off2)] {sym} base mem) (MOVBstore [off1] {sym} (ADDI [off2] base) val mem) && is32Bit(int64(off1)+off2) => (MOVBstore [off1+int32(off2)] {sym} base val mem) (MOVHstore [off1] {sym} (ADDI [off2] base) val mem) && is32Bit(int64(off1)+off2) => (MOVHstore [off1+int32(off2)] {sym} base val mem) (MOVWstore [off1] {sym} (ADDI [off2] base) val mem) && is32Bit(int64(off1)+off2) => (MOVWstore [off1+int32(off2)] {sym} base val mem) (MOVDstore [off1] {sym} (ADDI [off2] base) val mem) && is32Bit(int64(off1)+off2) => (MOVDstore [off1+int32(off2)] {sym} base val mem) (MOVBstorezero [off1] {sym} (ADDI [off2] ptr) mem) && is32Bit(int64(off1)+off2) => (MOVBstorezero [off1+int32(off2)] {sym} ptr mem) (MOVHstorezero [off1] {sym} (ADDI [off2] ptr) mem) && is32Bit(int64(off1)+off2) => (MOVHstorezero [off1+int32(off2)] {sym} ptr mem) (MOVWstorezero [off1] {sym} (ADDI [off2] ptr) mem) && is32Bit(int64(off1)+off2) => (MOVWstorezero [off1+int32(off2)] {sym} ptr mem) (MOVDstorezero [off1] {sym} (ADDI [off2] ptr) mem) && is32Bit(int64(off1)+off2) => (MOVDstorezero [off1+int32(off2)] {sym} ptr mem) // Similarly, fold ADDI into MOVaddr to avoid confusing live variable analysis // with OffPtr -> ADDI. (ADDI [c] (MOVaddr [d] {s} x)) && is32Bit(c+int64(d)) => (MOVaddr [int32(c)+d] {s} x) // Small zeroing (Zero [0] _ mem) => mem (Zero [1] ptr mem) => (MOVBstore ptr (MOVDconst [0]) mem) (Zero [2] {t} ptr mem) && t.Alignment()%2 == 0 => (MOVHstore ptr (MOVDconst [0]) mem) (Zero [2] ptr mem) => (MOVBstore [1] ptr (MOVDconst [0]) (MOVBstore ptr (MOVDconst [0]) mem)) (Zero [4] {t} ptr mem) && t.Alignment()%4 == 0 => (MOVWstore ptr (MOVDconst [0]) mem) (Zero [4] {t} ptr mem) && t.Alignment()%2 == 0 => (MOVHstore [2] ptr (MOVDconst [0]) (MOVHstore ptr (MOVDconst [0]) mem)) (Zero [4] ptr mem) => (MOVBstore [3] ptr (MOVDconst [0]) (MOVBstore [2] ptr (MOVDconst [0]) (MOVBstore [1] ptr (MOVDconst [0]) (MOVBstore ptr (MOVDconst [0]) mem)))) (Zero [8] {t} ptr mem) && t.Alignment()%8 == 0 => (MOVDstore ptr (MOVDconst [0]) mem) (Zero [8] {t} ptr mem) && t.Alignment()%4 == 0 => (MOVWstore [4] ptr (MOVDconst [0]) (MOVWstore ptr (MOVDconst [0]) mem)) (Zero [8] {t} ptr mem) && t.Alignment()%2 == 0 => (MOVHstore [6] ptr (MOVDconst [0]) (MOVHstore [4] ptr (MOVDconst [0]) (MOVHstore [2] ptr (MOVDconst [0]) (MOVHstore ptr (MOVDconst [0]) mem)))) (Zero [3] ptr mem) => (MOVBstore [2] ptr (MOVDconst [0]) (MOVBstore [1] ptr (MOVDconst [0]) (MOVBstore ptr (MOVDconst [0]) mem))) (Zero [6] {t} ptr mem) && t.Alignment()%2 == 0 => (MOVHstore [4] ptr (MOVDconst [0]) (MOVHstore [2] ptr (MOVDconst [0]) (MOVHstore ptr (MOVDconst [0]) mem))) (Zero [12] {t} ptr mem) && t.Alignment()%4 == 0 => (MOVWstore [8] ptr (MOVDconst [0]) (MOVWstore [4] ptr (MOVDconst [0]) (MOVWstore ptr (MOVDconst [0]) mem))) (Zero [16] {t} ptr mem) && t.Alignment()%8 == 0 => (MOVDstore [8] ptr (MOVDconst [0]) (MOVDstore ptr (MOVDconst [0]) mem)) (Zero [24] {t} ptr mem) && t.Alignment()%8 == 0 => (MOVDstore [16] ptr (MOVDconst [0]) (MOVDstore [8] ptr (MOVDconst [0]) (MOVDstore ptr (MOVDconst [0]) mem))) (Zero [32] {t} ptr mem) && t.Alignment()%8 == 0 => (MOVDstore [24] ptr (MOVDconst [0]) (MOVDstore [16] ptr (MOVDconst [0]) (MOVDstore [8] ptr (MOVDconst [0]) (MOVDstore ptr (MOVDconst [0]) mem)))) // Medium 8-aligned zeroing uses a Duff's device // 8 and 128 are magic constants, see runtime/mkduff.go (Zero [s] {t} ptr mem) && s%8 == 0 && s <= 8*128 && t.Alignment()%8 == 0 && !config.noDuffDevice => (DUFFZERO [8 * (128 - s/8)] ptr mem) // Generic zeroing uses a loop (Zero [s] {t} ptr mem) => (LoweredZero [t.Alignment()] ptr (ADD ptr (MOVDconst [s-moveSize(t.Alignment(), config)])) mem) (Convert ...) => (MOVconvert ...) // Checks (IsNonNil ...) => (SNEZ ...) (IsInBounds ...) => (Less64U ...) (IsSliceInBounds ...) => (Leq64U ...) // Trivial lowering (NilCheck ...) => (LoweredNilCheck ...) (GetClosurePtr ...) => (LoweredGetClosurePtr ...) (GetCallerSP ...) => (LoweredGetCallerSP ...) (GetCallerPC ...) => (LoweredGetCallerPC ...) // Write barrier. (WB ...) => (LoweredWB ...) (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) // Small moves (Move [0] _ _ mem) => mem (Move [1] dst src mem) => (MOVBstore dst (MOVBload src mem) mem) (Move [2] {t} dst src mem) && t.Alignment()%2 == 0 => (MOVHstore dst (MOVHload src mem) mem) (Move [2] dst src mem) => (MOVBstore [1] dst (MOVBload [1] src mem) (MOVBstore dst (MOVBload src mem) mem)) (Move [4] {t} dst src mem) && t.Alignment()%4 == 0 => (MOVWstore dst (MOVWload src mem) mem) (Move [4] {t} dst src mem) && t.Alignment()%2 == 0 => (MOVHstore [2] dst (MOVHload [2] src mem) (MOVHstore dst (MOVHload src mem) mem)) (Move [4] dst src mem) => (MOVBstore [3] dst (MOVBload [3] src mem) (MOVBstore [2] dst (MOVBload [2] src mem) (MOVBstore [1] dst (MOVBload [1] src mem) (MOVBstore dst (MOVBload src mem) mem)))) (Move [8] {t} dst src mem) && t.Alignment()%8 == 0 => (MOVDstore dst (MOVDload src mem) mem) (Move [8] {t} dst src mem) && t.Alignment()%4 == 0 => (MOVWstore [4] dst (MOVWload [4] src mem) (MOVWstore dst (MOVWload src mem) mem)) (Move [8] {t} dst src mem) && t.Alignment()%2 == 0 => (MOVHstore [6] dst (MOVHload [6] src mem) (MOVHstore [4] dst (MOVHload [4] src mem) (MOVHstore [2] dst (MOVHload [2] src mem) (MOVHstore dst (MOVHload src mem) mem)))) (Move [3] dst src mem) => (MOVBstore [2] dst (MOVBload [2] src mem) (MOVBstore [1] dst (MOVBload [1] src mem) (MOVBstore dst (MOVBload src mem) mem))) (Move [6] {t} dst src mem) && t.Alignment()%2 == 0 => (MOVHstore [4] dst (MOVHload [4] src mem) (MOVHstore [2] dst (MOVHload [2] src mem) (MOVHstore dst (MOVHload src mem) mem))) (Move [12] {t} dst src mem) && t.Alignment()%4 == 0 => (MOVWstore [8] dst (MOVWload [8] src mem) (MOVWstore [4] dst (MOVWload [4] src mem) (MOVWstore dst (MOVWload src mem) mem))) (Move [16] {t} dst src mem) && t.Alignment()%8 == 0 => (MOVDstore [8] dst (MOVDload [8] src mem) (MOVDstore dst (MOVDload src mem) mem)) (Move [24] {t} dst src mem) && t.Alignment()%8 == 0 => (MOVDstore [16] dst (MOVDload [16] src mem) (MOVDstore [8] dst (MOVDload [8] src mem) (MOVDstore dst (MOVDload src mem) mem))) (Move [32] {t} dst src mem) && t.Alignment()%8 == 0 => (MOVDstore [24] dst (MOVDload [24] src mem) (MOVDstore [16] dst (MOVDload [16] src mem) (MOVDstore [8] dst (MOVDload [8] src mem) (MOVDstore dst (MOVDload src mem) mem)))) // Medium 8-aligned move uses a Duff's device // 16 and 128 are magic constants, see runtime/mkduff.go (Move [s] {t} dst src mem) && s%8 == 0 && s <= 8*128 && t.Alignment()%8 == 0 && !config.noDuffDevice && logLargeCopy(v, s) => (DUFFCOPY [16 * (128 - s/8)] dst src mem) // Generic move uses a loop (Move [s] {t} dst src mem) && (s <= 16 || logLargeCopy(v, s)) => (LoweredMove [t.Alignment()] dst src (ADDI [s-moveSize(t.Alignment(), config)] src) mem) // Boolean ops; 0=false, 1=true (AndB ...) => (AND ...) (OrB ...) => (OR ...) (EqB x y) => (SEQZ (XOR x y)) (NeqB ...) => (XOR ...) (Not ...) => (SEQZ ...) // Lowering pointer arithmetic // TODO: Special handling for SP offsets, like ARM (OffPtr [off] ptr:(SP)) && is32Bit(off) => (MOVaddr [int32(off)] ptr) (OffPtr [off] ptr) && is32Bit(off) => (ADDI [off] ptr) (OffPtr [off] ptr) => (ADD (MOVDconst [off]) ptr) (Const8 [val]) => (MOVDconst [int64(val)]) (Const16 [val]) => (MOVDconst [int64(val)]) (Const32 [val]) => (MOVDconst [int64(val)]) (Const64 [val]) => (MOVDconst [int64(val)]) (Const32F [val]) => (FMVSX (MOVDconst [int64(math.Float32bits(val))])) (Const64F [val]) => (FMVDX (MOVDconst [int64(math.Float64bits(val))])) (ConstNil) => (MOVDconst [0]) (ConstBool [val]) => (MOVDconst [int64(b2i(val))]) (Addr {sym} base) => (MOVaddr {sym} [0] base) (LocalAddr {sym} base _) => (MOVaddr {sym} base) // Calls (StaticCall ...) => (CALLstatic ...) (ClosureCall ...) => (CALLclosure ...) (InterCall ...) => (CALLinter ...) (TailCall ...) => (CALLtail ...) // Atomic Intrinsics (AtomicLoad8 ...) => (LoweredAtomicLoad8 ...) (AtomicLoad32 ...) => (LoweredAtomicLoad32 ...) (AtomicLoad64 ...) => (LoweredAtomicLoad64 ...) (AtomicLoadPtr ...) => (LoweredAtomicLoad64 ...) (AtomicStore8 ...) => (LoweredAtomicStore8 ...) (AtomicStore32 ...) => (LoweredAtomicStore32 ...) (AtomicStore64 ...) => (LoweredAtomicStore64 ...) (AtomicStorePtrNoWB ...) => (LoweredAtomicStore64 ...) (AtomicAdd32 ...) => (LoweredAtomicAdd32 ...) (AtomicAdd64 ...) => (LoweredAtomicAdd64 ...) // AtomicAnd8(ptr,val) => LoweredAtomicAnd32(ptr&^3, ^((uint8(val) ^ 0xff) << ((ptr & 3) * 8))) (AtomicAnd8 ptr val mem) => (LoweredAtomicAnd32 (ANDI [^3] ptr) (NOT (SLL (XORI [0xff] (ZeroExt8to32 val)) (SLLI [3] (ANDI [3] ptr)))) mem) (AtomicAnd32 ...) => (LoweredAtomicAnd32 ...) (AtomicCompareAndSwap32 ...) => (LoweredAtomicCas32 ...) (AtomicCompareAndSwap64 ...) => (LoweredAtomicCas64 ...) (AtomicExchange32 ...) => (LoweredAtomicExchange32 ...) (AtomicExchange64 ...) => (LoweredAtomicExchange64 ...) // AtomicOr8(ptr,val) => LoweredAtomicOr32(ptr&^3, uint32(val)<<((ptr&3)*8)) (AtomicOr8 ptr val mem) => (LoweredAtomicOr32 (ANDI [^3] ptr) (SLL (ZeroExt8to32 val) (SLLI [3] (ANDI [3] ptr))) mem) (AtomicOr32 ...) => (LoweredAtomicOr32 ...) // Conditional branches (If cond yes no) => (BNEZ cond yes no) // Optimizations // Absorb SEQZ/SNEZ into branch. (BEQZ (SEQZ x) yes no) => (BNEZ x yes no) (BEQZ (SNEZ x) yes no) => (BEQZ x yes no) (BNEZ (SEQZ x) yes no) => (BEQZ x yes no) (BNEZ (SNEZ x) yes no) => (BNEZ x yes no) // Absorb NEG into branch when possible. (BEQZ x:(NEG y) yes no) && x.Uses == 1 => (BEQZ y yes no) (BNEZ x:(NEG y) yes no) && x.Uses == 1 => (BNEZ y yes no) // Convert BEQZ/BNEZ into more optimal branch conditions. (BEQZ (SUB x y) yes no) => (BEQ x y yes no) (BNEZ (SUB x y) yes no) => (BNE x y yes no) (BEQZ (SLT x y) yes no) => (BGE x y yes no) (BNEZ (SLT x y) yes no) => (BLT x y yes no) (BEQZ (SLTU x y) yes no) => (BGEU x y yes no) (BNEZ (SLTU x y) yes no) => (BLTU x y yes no) // Convert branch with zero to more optimal branch zero. (BEQ (MOVDconst [0]) cond yes no) => (BEQZ cond yes no) (BEQ cond (MOVDconst [0]) yes no) => (BEQZ cond yes no) (BNE (MOVDconst [0]) cond yes no) => (BNEZ cond yes no) (BNE cond (MOVDconst [0]) yes no) => (BNEZ cond yes no) (BLT (MOVDconst [0]) cond yes no) => (BGTZ cond yes no) (BLT cond (MOVDconst [0]) yes no) => (BLTZ cond yes no) (BGE (MOVDconst [0]) cond yes no) => (BLEZ cond yes no) (BGE cond (MOVDconst [0]) yes no) => (BGEZ cond yes no) // 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) // Avoid sign/zero extension for consts. (MOVBreg (MOVDconst [c])) => (MOVDconst [int64(int8(c))]) (MOVHreg (MOVDconst [c])) => (MOVDconst [int64(int16(c))]) (MOVWreg (MOVDconst [c])) => (MOVDconst [int64(int32(c))]) (MOVBUreg (MOVDconst [c])) => (MOVDconst [int64(uint8(c))]) (MOVHUreg (MOVDconst [c])) => (MOVDconst [int64(uint16(c))]) (MOVWUreg (MOVDconst [c])) => (MOVDconst [int64(uint32(c))]) // Avoid sign/zero extension after properly typed load. (MOVBreg x:(MOVBload _ _)) => (MOVDreg x) (MOVHreg x:(MOVBload _ _)) => (MOVDreg x) (MOVHreg x:(MOVBUload _ _)) => (MOVDreg x) (MOVHreg x:(MOVHload _ _)) => (MOVDreg x) (MOVWreg x:(MOVBload _ _)) => (MOVDreg x) (MOVWreg x:(MOVBUload _ _)) => (MOVDreg x) (MOVWreg x:(MOVHload _ _)) => (MOVDreg x) (MOVWreg x:(MOVHUload _ _)) => (MOVDreg x) (MOVWreg x:(MOVWload _ _)) => (MOVDreg x) (MOVBUreg x:(MOVBUload _ _)) => (MOVDreg x) (MOVHUreg x:(MOVBUload _ _)) => (MOVDreg x) (MOVHUreg x:(MOVHUload _ _)) => (MOVDreg x) (MOVWUreg x:(MOVBUload _ _)) => (MOVDreg x) (MOVWUreg x:(MOVHUload _ _)) => (MOVDreg x) (MOVWUreg x:(MOVWUload _ _)) => (MOVDreg x) // Fold double extensions. (MOVBreg x:(MOVBreg _)) => (MOVDreg x) (MOVHreg x:(MOVBreg _)) => (MOVDreg x) (MOVHreg x:(MOVBUreg _)) => (MOVDreg x) (MOVHreg x:(MOVHreg _)) => (MOVDreg x) (MOVWreg x:(MOVBreg _)) => (MOVDreg x) (MOVWreg x:(MOVBUreg _)) => (MOVDreg x) (MOVWreg x:(MOVHreg _)) => (MOVDreg x) (MOVWreg x:(MOVWreg _)) => (MOVDreg x) (MOVBUreg x:(MOVBUreg _)) => (MOVDreg x) (MOVHUreg x:(MOVBUreg _)) => (MOVDreg x) (MOVHUreg x:(MOVHUreg _)) => (MOVDreg x) (MOVWUreg x:(MOVBUreg _)) => (MOVDreg x) (MOVWUreg x:(MOVHUreg _)) => (MOVDreg x) (MOVWUreg x:(MOVWUreg _)) => (MOVDreg x) // Do not extend before store. (MOVBstore [off] {sym} ptr (MOVBreg 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 (MOVWreg 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 (MOVHUreg 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 (MOVWreg 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 (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) // Replace extend after load with alternate load where possible. (MOVBreg x:(MOVBUload [off] {sym} ptr mem)) && x.Uses == 1 && clobber(x) => @x.Block (MOVBload [off] {sym} ptr mem) (MOVHreg x:(MOVHUload [off] {sym} ptr mem)) && x.Uses == 1 && clobber(x) => @x.Block (MOVHload [off] {sym} ptr mem) (MOVWreg x:(MOVWUload [off] {sym} ptr mem)) && x.Uses == 1 && clobber(x) => @x.Block (MOVWload [off] {sym} ptr mem) (MOVBUreg x:(MOVBload [off] {sym} ptr mem)) && x.Uses == 1 && clobber(x) => @x.Block (MOVBUload [off] {sym} ptr mem) (MOVHUreg x:(MOVHload [off] {sym} ptr mem)) && x.Uses == 1 && clobber(x) => @x.Block (MOVHUload [off] {sym} ptr mem) (MOVWUreg x:(MOVWload [off] {sym} ptr mem)) && x.Uses == 1 && clobber(x) => @x.Block (MOVWUload [off] {sym} ptr mem) // If a register move has only 1 use, just use the same register without emitting instruction // MOVnop does not emit an 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 immediate instructions where possible. (ADD (MOVDconst [val]) x) && is32Bit(val) => (ADDI [val] x) (AND (MOVDconst [val]) x) && is32Bit(val) => (ANDI [val] x) (OR (MOVDconst [val]) x) && is32Bit(val) => (ORI [val] x) (XOR (MOVDconst [val]) x) && is32Bit(val) => (XORI [val] x) (SLL x (MOVDconst [val])) => (SLLI [int64(val&63)] x) (SRL x (MOVDconst [val])) => (SRLI [int64(val&63)] x) (SRA x (MOVDconst [val])) => (SRAI [int64(val&63)] x) // Convert subtraction of a const into ADDI with negative immediate, where possible. (SUB x (MOVDconst [val])) && is32Bit(-val) => (ADDI [-val] x) // Subtraction of zero. (SUB x (MOVDconst [0])) => x (SUBW x (MOVDconst [0])) => (ADDIW [0] x) // Subtraction from zero. (SUB (MOVDconst [0]) x) => (NEG x) (SUBW (MOVDconst [0]) x) => (NEGW x) // Addition of zero or two constants. (ADDI [0] x) => x (ADDI [x] (MOVDconst [y])) && is32Bit(x + y) => (MOVDconst [x + y]) // ANDI with all zeros, all ones or two constants. (ANDI [0] x) => (MOVDconst [0]) (ANDI [-1] x) => x (ANDI [x] (MOVDconst [y])) => (MOVDconst [x & y]) // ORI with all zeroes, all ones or two constants. (ORI [0] x) => x (ORI [-1] x) => (MOVDconst [-1]) (ORI [x] (MOVDconst [y])) => (MOVDconst [x | y]) // Negation of a constant. (NEG (MOVDconst [x])) => (MOVDconst [-x]) (NEGW (MOVDconst [x])) => (MOVDconst [int64(int32(-x))]) // Shift of a constant. (SLLI [x] (MOVDconst [y])) && is32Bit(y << x) => (MOVDconst [y << x]) (SRLI [x] (MOVDconst [y])) => (MOVDconst [int64(uint64(y) >> x)]) (SRAI [x] (MOVDconst [y])) => (MOVDconst [int64(y) >> x]) // SLTI/SLTIU with constants. (SLTI [x] (MOVDconst [y])) => (MOVDconst [b2i(int64(y) < int64(x))]) (SLTIU [x] (MOVDconst [y])) => (MOVDconst [b2i(uint64(y) < uint64(x))]) // Merge negation into fused multiply-add and multiply-subtract. // // Key: // // [+ -](x * y) [+ -] z. // _ N A S // D U // D B // // Note: multiplication commutativity handled by rule generator. (F(MADD|NMADD|MSUB|NMSUB)D neg:(FNEGD x) y z) && neg.Uses == 1 => (F(NMADD|MADD|NMSUB|MSUB)D x y z) (F(MADD|NMADD|MSUB|NMSUB)D x y neg:(FNEGD z)) && neg.Uses == 1 => (F(MSUB|NMSUB|MADD|NMADD)D x y z)