| // 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. |
| |
| // Lowering arithmetic |
| (Add(Ptr|32|16|8) ...) => (ADDL ...) |
| (Add(32|64)F ...) => (ADDS(S|D) ...) |
| (Add32carry ...) => (ADDLcarry ...) |
| (Add32withcarry ...) => (ADCL ...) |
| |
| (Sub(Ptr|32|16|8) ...) => (SUBL ...) |
| (Sub(32|64)F ...) => (SUBS(S|D) ...) |
| (Sub32carry ...) => (SUBLcarry ...) |
| (Sub32withcarry ...) => (SBBL ...) |
| |
| (Mul(32|16|8) ...) => (MULL ...) |
| (Mul(32|64)F ...) => (MULS(S|D) ...) |
| (Mul32uhilo ...) => (MULLQU ...) |
| |
| (Select0 (Mul32uover x y)) => (Select0 <typ.UInt32> (MULLU x y)) |
| (Select1 (Mul32uover x y)) => (SETO (Select1 <types.TypeFlags> (MULLU x y))) |
| |
| (Avg32u ...) => (AVGLU ...) |
| |
| (Div(32|64)F ...) => (DIVS(S|D) ...) |
| (Div(32|32u|16|16u) ...) => (DIV(L|LU|W|WU) ...) |
| (Div8 x y) => (DIVW (SignExt8to16 x) (SignExt8to16 y)) |
| (Div8u x y) => (DIVWU (ZeroExt8to16 x) (ZeroExt8to16 y)) |
| |
| (Hmul(32|32u) ...) => (HMUL(L|LU) ...) |
| |
| (Mod(32|32u|16|16u) ...) => (MOD(L|LU|W|WU) ...) |
| (Mod8 x y) => (MODW (SignExt8to16 x) (SignExt8to16 y)) |
| (Mod8u x y) => (MODWU (ZeroExt8to16 x) (ZeroExt8to16 y)) |
| |
| (And(32|16|8) ...) => (ANDL ...) |
| (Or(32|16|8) ...) => (ORL ...) |
| (Xor(32|16|8) ...) => (XORL ...) |
| |
| (Neg(32|16|8) ...) => (NEGL ...) |
| (Neg32F x) => (PXOR x (MOVSSconst <typ.Float32> [float32(math.Copysign(0, -1))])) |
| (Neg64F x) => (PXOR x (MOVSDconst <typ.Float64> [math.Copysign(0, -1)])) |
| |
| (Com(32|16|8) ...) => (NOTL ...) |
| |
| // Lowering boolean ops |
| (AndB ...) => (ANDL ...) |
| (OrB ...) => (ORL ...) |
| (Not x) => (XORLconst [1] x) |
| |
| // Lowering pointer arithmetic |
| (OffPtr [off] ptr) => (ADDLconst [int32(off)] ptr) |
| |
| (Bswap32 ...) => (BSWAPL ...) |
| (Bswap16 x) => (ROLWconst [8] x) |
| |
| (Sqrt ...) => (SQRTSD ...) |
| (Sqrt32 ...) => (SQRTSS ...) |
| |
| (Ctz8 x) => (BSFL (ORLconst <typ.UInt32> [0x100] x)) |
| (Ctz8NonZero ...) => (BSFL ...) |
| (Ctz16 x) => (BSFL (ORLconst <typ.UInt32> [0x10000] x)) |
| (Ctz16NonZero ...) => (BSFL ...) |
| (Ctz32 ...) => (LoweredCtz32 ...) |
| (Ctz32NonZero ...) => (BSFL ...) |
| |
| // Lowering extension |
| (SignExt8to16 ...) => (MOVBLSX ...) |
| (SignExt8to32 ...) => (MOVBLSX ...) |
| (SignExt16to32 ...) => (MOVWLSX ...) |
| |
| (ZeroExt8to16 ...) => (MOVBLZX ...) |
| (ZeroExt8to32 ...) => (MOVBLZX ...) |
| (ZeroExt16to32 ...) => (MOVWLZX ...) |
| |
| (Signmask x) => (SARLconst x [31]) |
| (Zeromask <t> x) => (XORLconst [-1] (SBBLcarrymask <t> (CMPLconst x [1]))) |
| (Slicemask <t> x) => (SARLconst (NEGL <t> x) [31]) |
| |
| // Lowering truncation |
| // Because we ignore high parts of registers, truncates are just copies. |
| (Trunc16to8 ...) => (Copy ...) |
| (Trunc32to8 ...) => (Copy ...) |
| (Trunc32to16 ...) => (Copy ...) |
| |
| // Lowering float-int conversions |
| (Cvt32to32F ...) => (CVTSL2SS ...) |
| (Cvt32to64F ...) => (CVTSL2SD ...) |
| |
| (Cvt32Fto32 ...) => (CVTTSS2SL ...) |
| (Cvt64Fto32 ...) => (CVTTSD2SL ...) |
| |
| (Cvt32Fto64F ...) => (CVTSS2SD ...) |
| (Cvt64Fto32F ...) => (CVTSD2SS ...) |
| |
| (Round32F ...) => (Copy ...) |
| (Round64F ...) => (Copy ...) |
| |
| (CvtBoolToUint8 ...) => (Copy ...) |
| |
| // Lowering shifts |
| // Unsigned shifts need to return 0 if shift amount is >= width of shifted value. |
| // result = (arg << shift) & (shift >= argbits ? 0 : 0xffffffffffffffff) |
| (Lsh32x(32|16|8) <t> x y) && !shiftIsBounded(v) => (ANDL (SHLL <t> x y) (SBBLcarrymask <t> (CMP(L|W|B)const y [32]))) |
| (Lsh16x(32|16|8) <t> x y) && !shiftIsBounded(v) => (ANDL (SHLL <t> x y) (SBBLcarrymask <t> (CMP(L|W|B)const y [32]))) |
| (Lsh8x(32|16|8) <t> x y) && !shiftIsBounded(v) => (ANDL (SHLL <t> x y) (SBBLcarrymask <t> (CMP(L|W|B)const y [32]))) |
| |
| (Lsh32x(32|16|8) <t> x y) && shiftIsBounded(v) => (SHLL <t> x y) |
| (Lsh16x(32|16|8) <t> x y) && shiftIsBounded(v) => (SHLL <t> x y) |
| (Lsh8x(32|16|8) <t> x y) && shiftIsBounded(v) => (SHLL <t> x y) |
| |
| (Rsh32Ux(32|16|8) <t> x y) && !shiftIsBounded(v) => (ANDL (SHRL <t> x y) (SBBLcarrymask <t> (CMP(L|W|B)const y [32]))) |
| (Rsh16Ux(32|16|8) <t> x y) && !shiftIsBounded(v) => (ANDL (SHRW <t> x y) (SBBLcarrymask <t> (CMP(L|W|B)const y [16]))) |
| (Rsh8Ux(32|16|8) <t> x y) && !shiftIsBounded(v) => (ANDL (SHRB <t> x y) (SBBLcarrymask <t> (CMP(L|W|B)const y [8]))) |
| |
| (Rsh32Ux(32|16|8) <t> x y) && shiftIsBounded(v) => (SHRL <t> x y) |
| (Rsh16Ux(32|16|8) <t> x y) && shiftIsBounded(v) => (SHRW <t> x y) |
| (Rsh8Ux(32|16|8) <t> x y) && shiftIsBounded(v) => (SHRB <t> x y) |
| |
| // Signed right shift needs to return 0/-1 if shift amount is >= width of shifted value. |
| // We implement this by setting the shift value to -1 (all ones) if the shift value is >= width. |
| |
| (Rsh32x(32|16|8) <t> x y) && !shiftIsBounded(v) => (SARL <t> x (ORL <y.Type> y (NOTL <y.Type> (SBBLcarrymask <y.Type> (CMP(L|W|B)const y [32]))))) |
| (Rsh16x(32|16|8) <t> x y) && !shiftIsBounded(v) => (SARW <t> x (ORL <y.Type> y (NOTL <y.Type> (SBBLcarrymask <y.Type> (CMP(L|W|B)const y [16]))))) |
| (Rsh8x(32|16|8) <t> x y) && !shiftIsBounded(v) => (SARB <t> x (ORL <y.Type> y (NOTL <y.Type> (SBBLcarrymask <y.Type> (CMP(L|W|B)const y [8]))))) |
| |
| (Rsh32x(32|16|8) <t> x y) && shiftIsBounded(v) => (SARL x y) |
| (Rsh16x(32|16|8) <t> x y) && shiftIsBounded(v) => (SARW x y) |
| (Rsh8x(32|16|8) <t> x y) && shiftIsBounded(v) => (SARB x y) |
| |
| // constant shifts |
| // generic opt rewrites all constant shifts to shift by Const64 |
| (Lsh32x64 x (Const64 [c])) && uint64(c) < 32 => (SHLLconst x [int32(c)]) |
| (Rsh32x64 x (Const64 [c])) && uint64(c) < 32 => (SARLconst x [int32(c)]) |
| (Rsh32Ux64 x (Const64 [c])) && uint64(c) < 32 => (SHRLconst x [int32(c)]) |
| (Lsh16x64 x (Const64 [c])) && uint64(c) < 16 => (SHLLconst x [int32(c)]) |
| (Rsh16x64 x (Const64 [c])) && uint64(c) < 16 => (SARWconst x [int16(c)]) |
| (Rsh16Ux64 x (Const64 [c])) && uint64(c) < 16 => (SHRWconst x [int16(c)]) |
| (Lsh8x64 x (Const64 [c])) && uint64(c) < 8 => (SHLLconst x [int32(c)]) |
| (Rsh8x64 x (Const64 [c])) && uint64(c) < 8 => (SARBconst x [int8(c)]) |
| (Rsh8Ux64 x (Const64 [c])) && uint64(c) < 8 => (SHRBconst x [int8(c)]) |
| |
| // large constant shifts |
| (Lsh32x64 _ (Const64 [c])) && uint64(c) >= 32 => (Const32 [0]) |
| (Rsh32Ux64 _ (Const64 [c])) && uint64(c) >= 32 => (Const32 [0]) |
| (Lsh16x64 _ (Const64 [c])) && uint64(c) >= 16 => (Const16 [0]) |
| (Rsh16Ux64 _ (Const64 [c])) && uint64(c) >= 16 => (Const16 [0]) |
| (Lsh8x64 _ (Const64 [c])) && uint64(c) >= 8 => (Const8 [0]) |
| (Rsh8Ux64 _ (Const64 [c])) && uint64(c) >= 8 => (Const8 [0]) |
| |
| // large constant signed right shift, we leave the sign bit |
| (Rsh32x64 x (Const64 [c])) && uint64(c) >= 32 => (SARLconst x [31]) |
| (Rsh16x64 x (Const64 [c])) && uint64(c) >= 16 => (SARWconst x [15]) |
| (Rsh8x64 x (Const64 [c])) && uint64(c) >= 8 => (SARBconst x [7]) |
| |
| // rotates |
| (RotateLeft32 ...) => (ROLL ...) |
| (RotateLeft16 ...) => (ROLW ...) |
| (RotateLeft8 ...) => (ROLB ...) |
| // constant rotates |
| (ROLL x (MOVLconst [c])) => (ROLLconst [c&31] x) |
| (ROLW x (MOVLconst [c])) => (ROLWconst [int16(c&15)] x) |
| (ROLB x (MOVLconst [c])) => (ROLBconst [int8(c&7)] x) |
| |
| // Lowering comparisons |
| (Less32 x y) => (SETL (CMPL x y)) |
| (Less16 x y) => (SETL (CMPW x y)) |
| (Less8 x y) => (SETL (CMPB x y)) |
| (Less32U x y) => (SETB (CMPL x y)) |
| (Less16U x y) => (SETB (CMPW x y)) |
| (Less8U x y) => (SETB (CMPB x y)) |
| // Use SETGF with reversed operands to dodge NaN case |
| (Less64F x y) => (SETGF (UCOMISD y x)) |
| (Less32F x y) => (SETGF (UCOMISS y x)) |
| |
| (Leq32 x y) => (SETLE (CMPL x y)) |
| (Leq16 x y) => (SETLE (CMPW x y)) |
| (Leq8 x y) => (SETLE (CMPB x y)) |
| (Leq32U x y) => (SETBE (CMPL x y)) |
| (Leq16U x y) => (SETBE (CMPW x y)) |
| (Leq8U x y) => (SETBE (CMPB x y)) |
| // Use SETGEF with reversed operands to dodge NaN case |
| (Leq64F x y) => (SETGEF (UCOMISD y x)) |
| (Leq32F x y) => (SETGEF (UCOMISS y x)) |
| |
| (Eq32 x y) => (SETEQ (CMPL x y)) |
| (Eq16 x y) => (SETEQ (CMPW x y)) |
| (Eq8 x y) => (SETEQ (CMPB x y)) |
| (EqB x y) => (SETEQ (CMPB x y)) |
| (EqPtr x y) => (SETEQ (CMPL x y)) |
| (Eq64F x y) => (SETEQF (UCOMISD x y)) |
| (Eq32F x y) => (SETEQF (UCOMISS x y)) |
| |
| (Neq32 x y) => (SETNE (CMPL x y)) |
| (Neq16 x y) => (SETNE (CMPW x y)) |
| (Neq8 x y) => (SETNE (CMPB x y)) |
| (NeqB x y) => (SETNE (CMPB x y)) |
| (NeqPtr x y) => (SETNE (CMPL x y)) |
| (Neq64F x y) => (SETNEF (UCOMISD x y)) |
| (Neq32F x y) => (SETNEF (UCOMISS x y)) |
| |
| // Lowering loads |
| (Load <t> ptr mem) && (is32BitInt(t) || isPtr(t)) => (MOVLload ptr mem) |
| (Load <t> ptr mem) && is16BitInt(t) => (MOVWload ptr mem) |
| (Load <t> ptr mem) && (t.IsBoolean() || is8BitInt(t)) => (MOVBload ptr mem) |
| (Load <t> ptr mem) && is32BitFloat(t) => (MOVSSload ptr mem) |
| (Load <t> ptr mem) && is64BitFloat(t) => (MOVSDload ptr mem) |
| |
| // Lowering stores |
| (Store {t} ptr val mem) && t.Size() == 8 && t.IsFloat() => (MOVSDstore ptr val mem) |
| (Store {t} ptr val mem) && t.Size() == 4 && t.IsFloat() => (MOVSSstore ptr val mem) |
| (Store {t} ptr val mem) && t.Size() == 4 && !t.IsFloat() => (MOVLstore ptr val mem) |
| (Store {t} ptr val mem) && t.Size() == 2 => (MOVWstore ptr val mem) |
| (Store {t} ptr val mem) && t.Size() == 1 => (MOVBstore ptr val mem) |
| |
| // Lowering moves |
| (Move [0] _ _ mem) => mem |
| (Move [1] dst src mem) => (MOVBstore dst (MOVBload src mem) mem) |
| (Move [2] dst src mem) => (MOVWstore dst (MOVWload src mem) mem) |
| (Move [4] dst src mem) => (MOVLstore dst (MOVLload src mem) mem) |
| (Move [3] dst src mem) => |
| (MOVBstore [2] dst (MOVBload [2] src mem) |
| (MOVWstore dst (MOVWload src mem) mem)) |
| (Move [5] dst src mem) => |
| (MOVBstore [4] dst (MOVBload [4] src mem) |
| (MOVLstore dst (MOVLload src mem) mem)) |
| (Move [6] dst src mem) => |
| (MOVWstore [4] dst (MOVWload [4] src mem) |
| (MOVLstore dst (MOVLload src mem) mem)) |
| (Move [7] dst src mem) => |
| (MOVLstore [3] dst (MOVLload [3] src mem) |
| (MOVLstore dst (MOVLload src mem) mem)) |
| (Move [8] dst src mem) => |
| (MOVLstore [4] dst (MOVLload [4] src mem) |
| (MOVLstore dst (MOVLload src mem) mem)) |
| |
| // Adjust moves to be a multiple of 4 bytes. |
| (Move [s] dst src mem) |
| && s > 8 && s%4 != 0 => |
| (Move [s-s%4] |
| (ADDLconst <dst.Type> dst [int32(s%4)]) |
| (ADDLconst <src.Type> src [int32(s%4)]) |
| (MOVLstore dst (MOVLload src mem) mem)) |
| |
| // Medium copying uses a duff device. |
| (Move [s] dst src mem) |
| && s > 8 && s <= 4*128 && s%4 == 0 |
| && !config.noDuffDevice && logLargeCopy(v, s) => |
| (DUFFCOPY [10*(128-s/4)] dst src mem) |
| // 10 and 128 are magic constants. 10 is the number of bytes to encode: |
| // MOVL (SI), CX |
| // ADDL $4, SI |
| // MOVL CX, (DI) |
| // ADDL $4, DI |
| // and 128 is the number of such blocks. See src/runtime/duff_386.s:duffcopy. |
| |
| // Large copying uses REP MOVSL. |
| (Move [s] dst src mem) && (s > 4*128 || config.noDuffDevice) && s%4 == 0 && logLargeCopy(v, s) => |
| (REPMOVSL dst src (MOVLconst [int32(s/4)]) mem) |
| |
| // Lowering Zero instructions |
| (Zero [0] _ mem) => mem |
| (Zero [1] destptr mem) => (MOVBstoreconst [0] destptr mem) |
| (Zero [2] destptr mem) => (MOVWstoreconst [0] destptr mem) |
| (Zero [4] destptr mem) => (MOVLstoreconst [0] destptr mem) |
| |
| (Zero [3] destptr mem) => |
| (MOVBstoreconst [makeValAndOff(0,2)] destptr |
| (MOVWstoreconst [makeValAndOff(0,0)] destptr mem)) |
| (Zero [5] destptr mem) => |
| (MOVBstoreconst [makeValAndOff(0,4)] destptr |
| (MOVLstoreconst [makeValAndOff(0,0)] destptr mem)) |
| (Zero [6] destptr mem) => |
| (MOVWstoreconst [makeValAndOff(0,4)] destptr |
| (MOVLstoreconst [makeValAndOff(0,0)] destptr mem)) |
| (Zero [7] destptr mem) => |
| (MOVLstoreconst [makeValAndOff(0,3)] destptr |
| (MOVLstoreconst [makeValAndOff(0,0)] destptr mem)) |
| |
| // Strip off any fractional word zeroing. |
| (Zero [s] destptr mem) && s%4 != 0 && s > 4 => |
| (Zero [s-s%4] (ADDLconst destptr [int32(s%4)]) |
| (MOVLstoreconst [0] destptr mem)) |
| |
| // Zero small numbers of words directly. |
| (Zero [8] destptr mem) => |
| (MOVLstoreconst [makeValAndOff(0,4)] destptr |
| (MOVLstoreconst [makeValAndOff(0,0)] destptr mem)) |
| (Zero [12] destptr mem) => |
| (MOVLstoreconst [makeValAndOff(0,8)] destptr |
| (MOVLstoreconst [makeValAndOff(0,4)] destptr |
| (MOVLstoreconst [makeValAndOff(0,0)] destptr mem))) |
| (Zero [16] destptr mem) => |
| (MOVLstoreconst [makeValAndOff(0,12)] destptr |
| (MOVLstoreconst [makeValAndOff(0,8)] destptr |
| (MOVLstoreconst [makeValAndOff(0,4)] destptr |
| (MOVLstoreconst [makeValAndOff(0,0)] destptr mem)))) |
| |
| // Medium zeroing uses a duff device. |
| (Zero [s] destptr mem) |
| && s > 16 && s <= 4*128 && s%4 == 0 |
| && !config.noDuffDevice => |
| (DUFFZERO [1*(128-s/4)] destptr (MOVLconst [0]) mem) |
| // 1 and 128 are magic constants. 1 is the number of bytes to encode STOSL. |
| // 128 is the number of STOSL instructions in duffzero. |
| // See src/runtime/duff_386.s:duffzero. |
| |
| // Large zeroing uses REP STOSQ. |
| (Zero [s] destptr mem) |
| && (s > 4*128 || (config.noDuffDevice && s > 16)) |
| && s%4 == 0 => |
| (REPSTOSL destptr (MOVLconst [int32(s/4)]) (MOVLconst [0]) mem) |
| |
| |
| // Lowering constants |
| (Const8 [c]) => (MOVLconst [int32(c)]) |
| (Const16 [c]) => (MOVLconst [int32(c)]) |
| (Const32 ...) => (MOVLconst ...) |
| (Const(32|64)F ...) => (MOVS(S|D)const ...) |
| (ConstNil) => (MOVLconst [0]) |
| (ConstBool [c]) => (MOVLconst [b2i32(c)]) |
| |
| // Lowering calls |
| (StaticCall ...) => (CALLstatic ...) |
| (ClosureCall ...) => (CALLclosure ...) |
| (InterCall ...) => (CALLinter ...) |
| (TailCall ...) => (CALLtail ...) |
| |
| // Miscellaneous |
| (IsNonNil p) => (SETNE (TESTL p p)) |
| (IsInBounds idx len) => (SETB (CMPL idx len)) |
| (IsSliceInBounds idx len) => (SETBE (CMPL idx len)) |
| (NilCheck ...) => (LoweredNilCheck ...) |
| (GetG ...) => (LoweredGetG ...) |
| (GetClosurePtr ...) => (LoweredGetClosurePtr ...) |
| (GetCallerPC ...) => (LoweredGetCallerPC ...) |
| (GetCallerSP ...) => (LoweredGetCallerSP ...) |
| (Addr {sym} base) => (LEAL {sym} base) |
| (LocalAddr <t> {sym} base mem) && t.Elem().HasPointers() => (LEAL {sym} (SPanchored base mem)) |
| (LocalAddr <t> {sym} base _) && !t.Elem().HasPointers() => (LEAL {sym} base) |
| |
| // block rewrites |
| (If (SETL cmp) yes no) => (LT cmp yes no) |
| (If (SETLE cmp) yes no) => (LE cmp yes no) |
| (If (SETG cmp) yes no) => (GT cmp yes no) |
| (If (SETGE cmp) yes no) => (GE cmp yes no) |
| (If (SETEQ cmp) yes no) => (EQ cmp yes no) |
| (If (SETNE cmp) yes no) => (NE cmp yes no) |
| (If (SETB cmp) yes no) => (ULT cmp yes no) |
| (If (SETBE cmp) yes no) => (ULE cmp yes no) |
| (If (SETA cmp) yes no) => (UGT cmp yes no) |
| (If (SETAE cmp) yes no) => (UGE cmp yes no) |
| (If (SETO cmp) yes no) => (OS cmp yes no) |
| |
| // Special case for floating point - LF/LEF not generated |
| (If (SETGF cmp) yes no) => (UGT cmp yes no) |
| (If (SETGEF cmp) yes no) => (UGE cmp yes no) |
| (If (SETEQF cmp) yes no) => (EQF cmp yes no) |
| (If (SETNEF cmp) yes no) => (NEF cmp yes no) |
| |
| (If cond yes no) => (NE (TESTB cond cond) yes no) |
| |
| // 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) |
| |
| (PanicExtend [kind] hi lo y mem) && boundsABI(kind) == 0 => (LoweredPanicExtendA [kind] hi lo y mem) |
| (PanicExtend [kind] hi lo y mem) && boundsABI(kind) == 1 => (LoweredPanicExtendB [kind] hi lo y mem) |
| (PanicExtend [kind] hi lo y mem) && boundsABI(kind) == 2 => (LoweredPanicExtendC [kind] hi lo y mem) |
| |
| // *************************** |
| // Above: lowering rules |
| // Below: optimizations |
| // *************************** |
| // TODO: Should the optimizations be a separate pass? |
| |
| // Fold boolean tests into blocks |
| (NE (TESTB (SETL cmp) (SETL cmp)) yes no) => (LT cmp yes no) |
| (NE (TESTB (SETLE cmp) (SETLE cmp)) yes no) => (LE cmp yes no) |
| (NE (TESTB (SETG cmp) (SETG cmp)) yes no) => (GT cmp yes no) |
| (NE (TESTB (SETGE cmp) (SETGE cmp)) yes no) => (GE cmp yes no) |
| (NE (TESTB (SETEQ cmp) (SETEQ cmp)) yes no) => (EQ cmp yes no) |
| (NE (TESTB (SETNE cmp) (SETNE cmp)) yes no) => (NE cmp yes no) |
| (NE (TESTB (SETB cmp) (SETB cmp)) yes no) => (ULT cmp yes no) |
| (NE (TESTB (SETBE cmp) (SETBE cmp)) yes no) => (ULE cmp yes no) |
| (NE (TESTB (SETA cmp) (SETA cmp)) yes no) => (UGT cmp yes no) |
| (NE (TESTB (SETAE cmp) (SETAE cmp)) yes no) => (UGE cmp yes no) |
| (NE (TESTB (SETO cmp) (SETO cmp)) yes no) => (OS cmp yes no) |
| |
| // Special case for floating point - LF/LEF not generated |
| (NE (TESTB (SETGF cmp) (SETGF cmp)) yes no) => (UGT cmp yes no) |
| (NE (TESTB (SETGEF cmp) (SETGEF cmp)) yes no) => (UGE cmp yes no) |
| (NE (TESTB (SETEQF cmp) (SETEQF cmp)) yes no) => (EQF cmp yes no) |
| (NE (TESTB (SETNEF cmp) (SETNEF cmp)) yes no) => (NEF cmp yes no) |
| |
| // fold constants into instructions |
| (ADDL x (MOVLconst <t> [c])) && !t.IsPtr() => (ADDLconst [c] x) |
| (ADDLcarry x (MOVLconst [c])) => (ADDLconstcarry [c] x) |
| (ADCL x (MOVLconst [c]) f) => (ADCLconst [c] x f) |
| |
| (SUBL x (MOVLconst [c])) => (SUBLconst x [c]) |
| (SUBL (MOVLconst [c]) x) => (NEGL (SUBLconst <v.Type> x [c])) |
| (SUBLcarry x (MOVLconst [c])) => (SUBLconstcarry [c] x) |
| (SBBL x (MOVLconst [c]) f) => (SBBLconst [c] x f) |
| |
| (MULL x (MOVLconst [c])) => (MULLconst [c] x) |
| (ANDL x (MOVLconst [c])) => (ANDLconst [c] x) |
| |
| (ANDLconst [c] (ANDLconst [d] x)) => (ANDLconst [c & d] x) |
| (XORLconst [c] (XORLconst [d] x)) => (XORLconst [c ^ d] x) |
| (MULLconst [c] (MULLconst [d] x)) => (MULLconst [c * d] x) |
| |
| (ORL x (MOVLconst [c])) => (ORLconst [c] x) |
| (XORL x (MOVLconst [c])) => (XORLconst [c] x) |
| |
| (SHLL x (MOVLconst [c])) => (SHLLconst [c&31] x) |
| (SHRL x (MOVLconst [c])) => (SHRLconst [c&31] x) |
| (SHRW x (MOVLconst [c])) && c&31 < 16 => (SHRWconst [int16(c&31)] x) |
| (SHRW _ (MOVLconst [c])) && c&31 >= 16 => (MOVLconst [0]) |
| (SHRB x (MOVLconst [c])) && c&31 < 8 => (SHRBconst [int8(c&31)] x) |
| (SHRB _ (MOVLconst [c])) && c&31 >= 8 => (MOVLconst [0]) |
| |
| (SARL x (MOVLconst [c])) => (SARLconst [c&31] x) |
| (SARW x (MOVLconst [c])) => (SARWconst [int16(min(int64(c&31),15))] x) |
| (SARB x (MOVLconst [c])) => (SARBconst [int8(min(int64(c&31),7))] x) |
| |
| (SARL x (ANDLconst [31] y)) => (SARL x y) |
| (SHLL x (ANDLconst [31] y)) => (SHLL x y) |
| (SHRL x (ANDLconst [31] y)) => (SHRL x y) |
| |
| // Constant shift simplifications |
| |
| (SHLLconst x [0]) => x |
| (SHRLconst x [0]) => x |
| (SARLconst x [0]) => x |
| |
| (SHRWconst x [0]) => x |
| (SARWconst x [0]) => x |
| |
| (SHRBconst x [0]) => x |
| (SARBconst x [0]) => x |
| |
| (ROLLconst [0] x) => x |
| (ROLWconst [0] x) => x |
| (ROLBconst [0] x) => x |
| |
| // Note: the word and byte shifts keep the low 5 bits (not the low 4 or 3 bits) |
| // because the x86 instructions are defined to use all 5 bits of the shift even |
| // for the small shifts. I don't think we'll ever generate a weird shift (e.g. |
| // (SHRW x (MOVLconst [24])), but just in case. |
| |
| (CMPL x (MOVLconst [c])) => (CMPLconst x [c]) |
| (CMPL (MOVLconst [c]) x) => (InvertFlags (CMPLconst x [c])) |
| (CMPW x (MOVLconst [c])) => (CMPWconst x [int16(c)]) |
| (CMPW (MOVLconst [c]) x) => (InvertFlags (CMPWconst x [int16(c)])) |
| (CMPB x (MOVLconst [c])) => (CMPBconst x [int8(c)]) |
| (CMPB (MOVLconst [c]) x) => (InvertFlags (CMPBconst x [int8(c)])) |
| |
| // Canonicalize the order of arguments to comparisons - helps with CSE. |
| (CMP(L|W|B) x y) && canonLessThan(x,y) => (InvertFlags (CMP(L|W|B) y x)) |
| |
| // strength reduction |
| // Assumes that the following costs from https://gmplib.org/~tege/x86-timing.pdf: |
| // 1 - addl, shll, leal, negl, subl |
| // 3 - imull |
| // This limits the rewrites to two instructions. |
| // Note that negl always operates in-place, |
| // which can require a register-register move |
| // to preserve the original value, |
| // so it must be used with care. |
| (MULLconst [-9] x) => (NEGL (LEAL8 <v.Type> x x)) |
| (MULLconst [-5] x) => (NEGL (LEAL4 <v.Type> x x)) |
| (MULLconst [-3] x) => (NEGL (LEAL2 <v.Type> x x)) |
| (MULLconst [-1] x) => (NEGL x) |
| (MULLconst [0] _) => (MOVLconst [0]) |
| (MULLconst [1] x) => x |
| (MULLconst [3] x) => (LEAL2 x x) |
| (MULLconst [5] x) => (LEAL4 x x) |
| (MULLconst [7] x) => (LEAL2 x (LEAL2 <v.Type> x x)) |
| (MULLconst [9] x) => (LEAL8 x x) |
| (MULLconst [11] x) => (LEAL2 x (LEAL4 <v.Type> x x)) |
| (MULLconst [13] x) => (LEAL4 x (LEAL2 <v.Type> x x)) |
| (MULLconst [19] x) => (LEAL2 x (LEAL8 <v.Type> x x)) |
| (MULLconst [21] x) => (LEAL4 x (LEAL4 <v.Type> x x)) |
| (MULLconst [25] x) => (LEAL8 x (LEAL2 <v.Type> x x)) |
| (MULLconst [27] x) => (LEAL8 (LEAL2 <v.Type> x x) (LEAL2 <v.Type> x x)) |
| (MULLconst [37] x) => (LEAL4 x (LEAL8 <v.Type> x x)) |
| (MULLconst [41] x) => (LEAL8 x (LEAL4 <v.Type> x x)) |
| (MULLconst [45] x) => (LEAL8 (LEAL4 <v.Type> x x) (LEAL4 <v.Type> x x)) |
| (MULLconst [73] x) => (LEAL8 x (LEAL8 <v.Type> x x)) |
| (MULLconst [81] x) => (LEAL8 (LEAL8 <v.Type> x x) (LEAL8 <v.Type> x x)) |
| |
| (MULLconst [c] x) && isPowerOfTwo32(c+1) && c >= 15 => (SUBL (SHLLconst <v.Type> [int32(log32(c+1))] x) x) |
| (MULLconst [c] x) && isPowerOfTwo32(c-1) && c >= 17 => (LEAL1 (SHLLconst <v.Type> [int32(log32(c-1))] x) x) |
| (MULLconst [c] x) && isPowerOfTwo32(c-2) && c >= 34 => (LEAL2 (SHLLconst <v.Type> [int32(log32(c-2))] x) x) |
| (MULLconst [c] x) && isPowerOfTwo32(c-4) && c >= 68 => (LEAL4 (SHLLconst <v.Type> [int32(log32(c-4))] x) x) |
| (MULLconst [c] x) && isPowerOfTwo32(c-8) && c >= 136 => (LEAL8 (SHLLconst <v.Type> [int32(log32(c-8))] x) x) |
| (MULLconst [c] x) && c%3 == 0 && isPowerOfTwo32(c/3) => (SHLLconst [int32(log32(c/3))] (LEAL2 <v.Type> x x)) |
| (MULLconst [c] x) && c%5 == 0 && isPowerOfTwo32(c/5) => (SHLLconst [int32(log32(c/5))] (LEAL4 <v.Type> x x)) |
| (MULLconst [c] x) && c%9 == 0 && isPowerOfTwo32(c/9) => (SHLLconst [int32(log32(c/9))] (LEAL8 <v.Type> x x)) |
| |
| // combine add/shift into LEAL |
| (ADDL x (SHLLconst [3] y)) => (LEAL8 x y) |
| (ADDL x (SHLLconst [2] y)) => (LEAL4 x y) |
| (ADDL x (SHLLconst [1] y)) => (LEAL2 x y) |
| (ADDL x (ADDL y y)) => (LEAL2 x y) |
| (ADDL x (ADDL x y)) => (LEAL2 y x) |
| |
| // combine ADDL/ADDLconst into LEAL1 |
| (ADDLconst [c] (ADDL x y)) => (LEAL1 [c] x y) |
| (ADDL (ADDLconst [c] x) y) => (LEAL1 [c] x y) |
| |
| // fold ADDL into LEAL |
| (ADDLconst [c] (LEAL [d] {s} x)) && is32Bit(int64(c)+int64(d)) => (LEAL [c+d] {s} x) |
| (LEAL [c] {s} (ADDLconst [d] x)) && is32Bit(int64(c)+int64(d)) => (LEAL [c+d] {s} x) |
| (ADDLconst [c] x:(SP)) => (LEAL [c] x) // so it is rematerializeable |
| (LEAL [c] {s} (ADDL x y)) && x.Op != OpSB && y.Op != OpSB => (LEAL1 [c] {s} x y) |
| (ADDL x (LEAL [c] {s} y)) && x.Op != OpSB && y.Op != OpSB => (LEAL1 [c] {s} x y) |
| |
| // fold ADDLconst into LEALx |
| (ADDLconst [c] (LEAL1 [d] {s} x y)) && is32Bit(int64(c)+int64(d)) => (LEAL1 [c+d] {s} x y) |
| (ADDLconst [c] (LEAL2 [d] {s} x y)) && is32Bit(int64(c)+int64(d)) => (LEAL2 [c+d] {s} x y) |
| (ADDLconst [c] (LEAL4 [d] {s} x y)) && is32Bit(int64(c)+int64(d)) => (LEAL4 [c+d] {s} x y) |
| (ADDLconst [c] (LEAL8 [d] {s} x y)) && is32Bit(int64(c)+int64(d)) => (LEAL8 [c+d] {s} x y) |
| (LEAL1 [c] {s} (ADDLconst [d] x) y) && is32Bit(int64(c)+int64(d)) && x.Op != OpSB => (LEAL1 [c+d] {s} x y) |
| (LEAL2 [c] {s} (ADDLconst [d] x) y) && is32Bit(int64(c)+int64(d)) && x.Op != OpSB => (LEAL2 [c+d] {s} x y) |
| (LEAL2 [c] {s} x (ADDLconst [d] y)) && is32Bit(int64(c)+2*int64(d)) && y.Op != OpSB => (LEAL2 [c+2*d] {s} x y) |
| (LEAL4 [c] {s} (ADDLconst [d] x) y) && is32Bit(int64(c)+int64(d)) && x.Op != OpSB => (LEAL4 [c+d] {s} x y) |
| (LEAL4 [c] {s} x (ADDLconst [d] y)) && is32Bit(int64(c)+4*int64(d)) && y.Op != OpSB => (LEAL4 [c+4*d] {s} x y) |
| (LEAL8 [c] {s} (ADDLconst [d] x) y) && is32Bit(int64(c)+int64(d)) && x.Op != OpSB => (LEAL8 [c+d] {s} x y) |
| (LEAL8 [c] {s} x (ADDLconst [d] y)) && is32Bit(int64(c)+8*int64(d)) && y.Op != OpSB => (LEAL8 [c+8*d] {s} x y) |
| |
| // fold shifts into LEALx |
| (LEAL1 [c] {s} x (SHLLconst [1] y)) => (LEAL2 [c] {s} x y) |
| (LEAL1 [c] {s} x (SHLLconst [2] y)) => (LEAL4 [c] {s} x y) |
| (LEAL1 [c] {s} x (SHLLconst [3] y)) => (LEAL8 [c] {s} x y) |
| (LEAL2 [c] {s} x (SHLLconst [1] y)) => (LEAL4 [c] {s} x y) |
| (LEAL2 [c] {s} x (SHLLconst [2] y)) => (LEAL8 [c] {s} x y) |
| (LEAL4 [c] {s} x (SHLLconst [1] y)) => (LEAL8 [c] {s} x y) |
| |
| // reverse ordering of compare instruction |
| (SETL (InvertFlags x)) => (SETG x) |
| (SETG (InvertFlags x)) => (SETL x) |
| (SETB (InvertFlags x)) => (SETA x) |
| (SETA (InvertFlags x)) => (SETB x) |
| (SETLE (InvertFlags x)) => (SETGE x) |
| (SETGE (InvertFlags x)) => (SETLE x) |
| (SETBE (InvertFlags x)) => (SETAE x) |
| (SETAE (InvertFlags x)) => (SETBE x) |
| (SETEQ (InvertFlags x)) => (SETEQ x) |
| (SETNE (InvertFlags x)) => (SETNE x) |
| |
| // sign extended loads |
| // Note: The combined instruction must end up in the same block |
| // as the original load. If not, we end up making a value with |
| // memory type live in two different blocks, which can lead to |
| // multiple memory values alive simultaneously. |
| // Make sure we don't combine these ops if the load has another use. |
| // This prevents a single load from being split into multiple loads |
| // which then might return different values. See test/atomicload.go. |
| (MOVBLSX x:(MOVBload [off] {sym} ptr mem)) && x.Uses == 1 && clobber(x) => @x.Block (MOVBLSXload <v.Type> [off] {sym} ptr mem) |
| (MOVBLZX x:(MOVBload [off] {sym} ptr mem)) && x.Uses == 1 && clobber(x) => @x.Block (MOVBload <v.Type> [off] {sym} ptr mem) |
| (MOVWLSX x:(MOVWload [off] {sym} ptr mem)) && x.Uses == 1 && clobber(x) => @x.Block (MOVWLSXload <v.Type> [off] {sym} ptr mem) |
| (MOVWLZX x:(MOVWload [off] {sym} ptr mem)) && x.Uses == 1 && clobber(x) => @x.Block (MOVWload <v.Type> [off] {sym} ptr mem) |
| |
| // replace load from same location as preceding store with zero/sign extension (or copy in case of full width) |
| (MOVBload [off] {sym} ptr (MOVBstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) => (MOVBLZX x) |
| (MOVWload [off] {sym} ptr (MOVWstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) => (MOVWLZX x) |
| (MOVLload [off] {sym} ptr (MOVLstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) => x |
| (MOVBLSXload [off] {sym} ptr (MOVBstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) => (MOVBLSX x) |
| (MOVWLSXload [off] {sym} ptr (MOVWstore [off2] {sym2} ptr2 x _)) && sym == sym2 && off == off2 && isSamePtr(ptr, ptr2) => (MOVWLSX x) |
| |
| // Fold extensions and ANDs together. |
| (MOVBLZX (ANDLconst [c] x)) => (ANDLconst [c & 0xff] x) |
| (MOVWLZX (ANDLconst [c] x)) => (ANDLconst [c & 0xffff] x) |
| (MOVBLSX (ANDLconst [c] x)) && c & 0x80 == 0 => (ANDLconst [c & 0x7f] x) |
| (MOVWLSX (ANDLconst [c] x)) && c & 0x8000 == 0 => (ANDLconst [c & 0x7fff] x) |
| |
| // Don't extend before storing |
| (MOVWstore [off] {sym} ptr (MOVWL(S|Z)X x) mem) => (MOVWstore [off] {sym} ptr x mem) |
| (MOVBstore [off] {sym} ptr (MOVBL(S|Z)X x) mem) => (MOVBstore [off] {sym} ptr x mem) |
| |
| // fold constants into memory operations |
| // Note that this is not always a good idea because if not all the uses of |
| // the ADDLconst get eliminated, we still have to compute the ADDLconst and we now |
| // have potentially two live values (ptr and (ADDLconst [off] ptr)) instead of one. |
| // Nevertheless, let's do it! |
| (MOV(L|W|B|SS|SD)load [off1] {sym} (ADDLconst [off2] ptr) mem) && is32Bit(int64(off1)+int64(off2)) => |
| (MOV(L|W|B|SS|SD)load [off1+off2] {sym} ptr mem) |
| (MOV(L|W|B|SS|SD)store [off1] {sym} (ADDLconst [off2] ptr) val mem) && is32Bit(int64(off1)+int64(off2)) => |
| (MOV(L|W|B|SS|SD)store [off1+off2] {sym} ptr val mem) |
| |
| ((ADD|SUB|MUL|AND|OR|XOR)Lload [off1] {sym} val (ADDLconst [off2] base) mem) && is32Bit(int64(off1)+int64(off2)) => |
| ((ADD|SUB|MUL|AND|OR|XOR)Lload [off1+off2] {sym} val base mem) |
| ((ADD|SUB|MUL|DIV)SSload [off1] {sym} val (ADDLconst [off2] base) mem) && is32Bit(int64(off1)+int64(off2)) => |
| ((ADD|SUB|MUL|DIV)SSload [off1+off2] {sym} val base mem) |
| ((ADD|SUB|MUL|DIV)SDload [off1] {sym} val (ADDLconst [off2] base) mem) && is32Bit(int64(off1)+int64(off2)) => |
| ((ADD|SUB|MUL|DIV)SDload [off1+off2] {sym} val base mem) |
| ((ADD|SUB|AND|OR|XOR)Lmodify [off1] {sym} (ADDLconst [off2] base) val mem) && is32Bit(int64(off1)+int64(off2)) => |
| ((ADD|SUB|AND|OR|XOR)Lmodify [off1+off2] {sym} base val mem) |
| ((ADD|AND|OR|XOR)Lconstmodify [valoff1] {sym} (ADDLconst [off2] base) mem) && valoff1.canAdd32(off2) => |
| ((ADD|AND|OR|XOR)Lconstmodify [valoff1.addOffset32(off2)] {sym} base mem) |
| |
| // Fold constants into stores. |
| (MOVLstore [off] {sym} ptr (MOVLconst [c]) mem) => |
| (MOVLstoreconst [makeValAndOff(c,off)] {sym} ptr mem) |
| (MOVWstore [off] {sym} ptr (MOVLconst [c]) mem) => |
| (MOVWstoreconst [makeValAndOff(c,off)] {sym} ptr mem) |
| (MOVBstore [off] {sym} ptr (MOVLconst [c]) mem) => |
| (MOVBstoreconst [makeValAndOff(c,off)] {sym} ptr mem) |
| |
| // Fold address offsets into constant stores. |
| (MOV(L|W|B)storeconst [sc] {s} (ADDLconst [off] ptr) mem) && sc.canAdd32(off) => |
| (MOV(L|W|B)storeconst [sc.addOffset32(off)] {s} ptr mem) |
| |
| // We need to fold LEAL into the MOVx ops so that the live variable analysis knows |
| // what variables are being read/written by the ops. |
| // Note: we turn off this merging for operations on globals when building |
| // position-independent code (when Flag_shared is set). |
| // PIC needs a spare register to load the PC into. Having the LEAL be |
| // a separate instruction gives us that register. Having the LEAL be |
| // a separate instruction also allows it to be CSEd (which is good because |
| // it compiles to a thunk call). |
| (MOV(L|W|B|SS|SD|BLSX|WLSX)load [off1] {sym1} (LEAL [off2] {sym2} base) mem) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) |
| && (base.Op != OpSB || !config.ctxt.Flag_shared) => |
| (MOV(L|W|B|SS|SD|BLSX|WLSX)load [off1+off2] {mergeSym(sym1,sym2)} base mem) |
| |
| (MOV(L|W|B|SS|SD)store [off1] {sym1} (LEAL [off2] {sym2} base) val mem) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) |
| && (base.Op != OpSB || !config.ctxt.Flag_shared) => |
| (MOV(L|W|B|SS|SD)store [off1+off2] {mergeSym(sym1,sym2)} base val mem) |
| |
| (MOV(L|W|B)storeconst [sc] {sym1} (LEAL [off] {sym2} ptr) mem) && canMergeSym(sym1, sym2) && sc.canAdd32(off) |
| && (ptr.Op != OpSB || !config.ctxt.Flag_shared) => |
| (MOV(L|W|B)storeconst [sc.addOffset32(off)] {mergeSym(sym1, sym2)} ptr mem) |
| |
| ((ADD|SUB|MUL|AND|OR|XOR)Lload [off1] {sym1} val (LEAL [off2] {sym2} base) mem) |
| && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) && (base.Op != OpSB || !config.ctxt.Flag_shared) => |
| ((ADD|SUB|MUL|AND|OR|XOR)Lload [off1+off2] {mergeSym(sym1,sym2)} val base mem) |
| ((ADD|SUB|MUL|DIV)SSload [off1] {sym1} val (LEAL [off2] {sym2} base) mem) |
| && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) && (base.Op != OpSB || !config.ctxt.Flag_shared) => |
| ((ADD|SUB|MUL|DIV)SSload [off1+off2] {mergeSym(sym1,sym2)} val base mem) |
| ((ADD|SUB|MUL|DIV)SDload [off1] {sym1} val (LEAL [off2] {sym2} base) mem) |
| && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) && (base.Op != OpSB || !config.ctxt.Flag_shared) => |
| ((ADD|SUB|MUL|DIV)SDload [off1+off2] {mergeSym(sym1,sym2)} val base mem) |
| ((ADD|SUB|AND|OR|XOR)Lmodify [off1] {sym1} (LEAL [off2] {sym2} base) val mem) |
| && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) && (base.Op != OpSB || !config.ctxt.Flag_shared) => |
| ((ADD|SUB|AND|OR|XOR)Lmodify [off1+off2] {mergeSym(sym1,sym2)} base val mem) |
| ((ADD|AND|OR|XOR)Lconstmodify [valoff1] {sym1} (LEAL [off2] {sym2} base) mem) |
| && valoff1.canAdd32(off2) && canMergeSym(sym1, sym2) && (base.Op != OpSB || !config.ctxt.Flag_shared) => |
| ((ADD|AND|OR|XOR)Lconstmodify [valoff1.addOffset32(off2)] {mergeSym(sym1,sym2)} base mem) |
| |
| // Merge load/store to op |
| ((ADD|AND|OR|XOR|SUB|MUL)L x l:(MOVLload [off] {sym} ptr mem)) && canMergeLoadClobber(v, l, x) && clobber(l) => ((ADD|AND|OR|XOR|SUB|MUL)Lload x [off] {sym} ptr mem) |
| ((ADD|SUB|MUL|DIV)SD x l:(MOVSDload [off] {sym} ptr mem)) && canMergeLoadClobber(v, l, x) && clobber(l) => ((ADD|SUB|MUL|DIV)SDload x [off] {sym} ptr mem) |
| ((ADD|SUB|MUL|DIV)SS x l:(MOVSSload [off] {sym} ptr mem)) && canMergeLoadClobber(v, l, x) && clobber(l) => ((ADD|SUB|MUL|DIV)SSload x [off] {sym} ptr mem) |
| (MOVLstore {sym} [off] ptr y:((ADD|AND|OR|XOR)Lload x [off] {sym} ptr mem) mem) && y.Uses==1 && clobber(y) => ((ADD|AND|OR|XOR)Lmodify [off] {sym} ptr x mem) |
| (MOVLstore {sym} [off] ptr y:((ADD|SUB|AND|OR|XOR)L l:(MOVLload [off] {sym} ptr mem) x) mem) && y.Uses==1 && l.Uses==1 && clobber(y, l) => |
| ((ADD|SUB|AND|OR|XOR)Lmodify [off] {sym} ptr x mem) |
| (MOVLstore {sym} [off] ptr y:((ADD|AND|OR|XOR)Lconst [c] l:(MOVLload [off] {sym} ptr mem)) mem) |
| && y.Uses==1 && l.Uses==1 && clobber(y, l) => |
| ((ADD|AND|OR|XOR)Lconstmodify [makeValAndOff(c,off)] {sym} ptr mem) |
| |
| // fold LEALs together |
| (LEAL [off1] {sym1} (LEAL [off2] {sym2} x)) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => |
| (LEAL [off1+off2] {mergeSym(sym1,sym2)} x) |
| |
| // LEAL into LEAL1 |
| (LEAL1 [off1] {sym1} (LEAL [off2] {sym2} x) y) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) && x.Op != OpSB => |
| (LEAL1 [off1+off2] {mergeSym(sym1,sym2)} x y) |
| |
| // LEAL1 into LEAL |
| (LEAL [off1] {sym1} (LEAL1 [off2] {sym2} x y)) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => |
| (LEAL1 [off1+off2] {mergeSym(sym1,sym2)} x y) |
| |
| // LEAL into LEAL[248] |
| (LEAL2 [off1] {sym1} (LEAL [off2] {sym2} x) y) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) && x.Op != OpSB => |
| (LEAL2 [off1+off2] {mergeSym(sym1,sym2)} x y) |
| (LEAL4 [off1] {sym1} (LEAL [off2] {sym2} x) y) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) && x.Op != OpSB => |
| (LEAL4 [off1+off2] {mergeSym(sym1,sym2)} x y) |
| (LEAL8 [off1] {sym1} (LEAL [off2] {sym2} x) y) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) && x.Op != OpSB => |
| (LEAL8 [off1+off2] {mergeSym(sym1,sym2)} x y) |
| |
| // LEAL[248] into LEAL |
| (LEAL [off1] {sym1} (LEAL2 [off2] {sym2} x y)) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => |
| (LEAL2 [off1+off2] {mergeSym(sym1,sym2)} x y) |
| (LEAL [off1] {sym1} (LEAL4 [off2] {sym2} x y)) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => |
| (LEAL4 [off1+off2] {mergeSym(sym1,sym2)} x y) |
| (LEAL [off1] {sym1} (LEAL8 [off2] {sym2} x y)) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => |
| (LEAL8 [off1+off2] {mergeSym(sym1,sym2)} x y) |
| |
| // LEAL[1248] into LEAL[1248]. Only some such merges are possible. |
| (LEAL1 [off1] {sym1} x (LEAL1 [off2] {sym2} y y)) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => |
| (LEAL2 [off1+off2] {mergeSym(sym1, sym2)} x y) |
| (LEAL1 [off1] {sym1} x (LEAL1 [off2] {sym2} x y)) && is32Bit(int64(off1)+int64(off2)) && canMergeSym(sym1, sym2) => |
| (LEAL2 [off1+off2] {mergeSym(sym1, sym2)} y x) |
| (LEAL2 [off1] {sym} x (LEAL1 [off2] {nil} y y)) && is32Bit(int64(off1)+2*int64(off2)) => |
| (LEAL4 [off1+2*off2] {sym} x y) |
| (LEAL4 [off1] {sym} x (LEAL1 [off2] {nil} y y)) && is32Bit(int64(off1)+4*int64(off2)) => |
| (LEAL8 [off1+4*off2] {sym} x y) |
| |
| // 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) |
| |
| // Constant comparisons. |
| (CMPLconst (MOVLconst [x]) [y]) && x==y => (FlagEQ) |
| (CMPLconst (MOVLconst [x]) [y]) && x<y && uint32(x)<uint32(y) => (FlagLT_ULT) |
| (CMPLconst (MOVLconst [x]) [y]) && x<y && uint32(x)>uint32(y) => (FlagLT_UGT) |
| (CMPLconst (MOVLconst [x]) [y]) && x>y && uint32(x)<uint32(y) => (FlagGT_ULT) |
| (CMPLconst (MOVLconst [x]) [y]) && x>y && uint32(x)>uint32(y) => (FlagGT_UGT) |
| |
| (CMPWconst (MOVLconst [x]) [y]) && int16(x)==y => (FlagEQ) |
| (CMPWconst (MOVLconst [x]) [y]) && int16(x)<y && uint16(x)<uint16(y) => (FlagLT_ULT) |
| (CMPWconst (MOVLconst [x]) [y]) && int16(x)<y && uint16(x)>uint16(y) => (FlagLT_UGT) |
| (CMPWconst (MOVLconst [x]) [y]) && int16(x)>y && uint16(x)<uint16(y) => (FlagGT_ULT) |
| (CMPWconst (MOVLconst [x]) [y]) && int16(x)>y && uint16(x)>uint16(y) => (FlagGT_UGT) |
| |
| (CMPBconst (MOVLconst [x]) [y]) && int8(x)==y => (FlagEQ) |
| (CMPBconst (MOVLconst [x]) [y]) && int8(x)<y && uint8(x)<uint8(y) => (FlagLT_ULT) |
| (CMPBconst (MOVLconst [x]) [y]) && int8(x)<y && uint8(x)>uint8(y) => (FlagLT_UGT) |
| (CMPBconst (MOVLconst [x]) [y]) && int8(x)>y && uint8(x)<uint8(y) => (FlagGT_ULT) |
| (CMPBconst (MOVLconst [x]) [y]) && int8(x)>y && uint8(x)>uint8(y) => (FlagGT_UGT) |
| |
| // Other known comparisons. |
| (CMPLconst (SHRLconst _ [c]) [n]) && 0 <= n && 0 < c && c <= 32 && (1<<uint64(32-c)) <= uint64(n) => (FlagLT_ULT) |
| (CMPLconst (ANDLconst _ [m]) [n]) && 0 <= m && m < n => (FlagLT_ULT) |
| (CMPWconst (ANDLconst _ [m]) [n]) && 0 <= int16(m) && int16(m) < n => (FlagLT_ULT) |
| (CMPBconst (ANDLconst _ [m]) [n]) && 0 <= int8(m) && int8(m) < n => (FlagLT_ULT) |
| // TODO: DIVxU also. |
| |
| // Absorb flag constants into SBB ops. |
| (SBBLcarrymask (FlagEQ)) => (MOVLconst [0]) |
| (SBBLcarrymask (FlagLT_ULT)) => (MOVLconst [-1]) |
| (SBBLcarrymask (FlagLT_UGT)) => (MOVLconst [0]) |
| (SBBLcarrymask (FlagGT_ULT)) => (MOVLconst [-1]) |
| (SBBLcarrymask (FlagGT_UGT)) => (MOVLconst [0]) |
| |
| // Absorb flag constants into branches. |
| (EQ (FlagEQ) yes no) => (First yes no) |
| (EQ (FlagLT_ULT) yes no) => (First no yes) |
| (EQ (FlagLT_UGT) yes no) => (First no yes) |
| (EQ (FlagGT_ULT) yes no) => (First no yes) |
| (EQ (FlagGT_UGT) yes no) => (First no yes) |
| |
| (NE (FlagEQ) yes no) => (First no yes) |
| (NE (FlagLT_ULT) yes no) => (First yes no) |
| (NE (FlagLT_UGT) yes no) => (First yes no) |
| (NE (FlagGT_ULT) yes no) => (First yes no) |
| (NE (FlagGT_UGT) yes no) => (First yes no) |
| |
| (LT (FlagEQ) yes no) => (First no yes) |
| (LT (FlagLT_ULT) yes no) => (First yes no) |
| (LT (FlagLT_UGT) yes no) => (First yes no) |
| (LT (FlagGT_ULT) yes no) => (First no yes) |
| (LT (FlagGT_UGT) yes no) => (First no yes) |
| |
| (LE (FlagEQ) yes no) => (First yes no) |
| (LE (FlagLT_ULT) yes no) => (First yes no) |
| (LE (FlagLT_UGT) yes no) => (First yes no) |
| (LE (FlagGT_ULT) yes no) => (First no yes) |
| (LE (FlagGT_UGT) yes no) => (First no yes) |
| |
| (GT (FlagEQ) yes no) => (First no yes) |
| (GT (FlagLT_ULT) yes no) => (First no yes) |
| (GT (FlagLT_UGT) yes no) => (First no yes) |
| (GT (FlagGT_ULT) yes no) => (First yes no) |
| (GT (FlagGT_UGT) yes no) => (First yes no) |
| |
| (GE (FlagEQ) yes no) => (First yes no) |
| (GE (FlagLT_ULT) yes no) => (First no yes) |
| (GE (FlagLT_UGT) yes no) => (First no yes) |
| (GE (FlagGT_ULT) yes no) => (First yes no) |
| (GE (FlagGT_UGT) yes no) => (First yes no) |
| |
| (ULT (FlagEQ) yes no) => (First no yes) |
| (ULT (FlagLT_ULT) yes no) => (First yes no) |
| (ULT (FlagLT_UGT) yes no) => (First no yes) |
| (ULT (FlagGT_ULT) yes no) => (First yes no) |
| (ULT (FlagGT_UGT) yes no) => (First no yes) |
| |
| (ULE (FlagEQ) yes no) => (First yes no) |
| (ULE (FlagLT_ULT) yes no) => (First yes no) |
| (ULE (FlagLT_UGT) yes no) => (First no yes) |
| (ULE (FlagGT_ULT) yes no) => (First yes no) |
| (ULE (FlagGT_UGT) yes no) => (First no yes) |
| |
| (UGT (FlagEQ) yes no) => (First no yes) |
| (UGT (FlagLT_ULT) yes no) => (First no yes) |
| (UGT (FlagLT_UGT) yes no) => (First yes no) |
| (UGT (FlagGT_ULT) yes no) => (First no yes) |
| (UGT (FlagGT_UGT) yes no) => (First yes no) |
| |
| (UGE (FlagEQ) yes no) => (First yes no) |
| (UGE (FlagLT_ULT) yes no) => (First no yes) |
| (UGE (FlagLT_UGT) yes no) => (First yes no) |
| (UGE (FlagGT_ULT) yes no) => (First no yes) |
| (UGE (FlagGT_UGT) yes no) => (First yes no) |
| |
| // Absorb flag constants into SETxx ops. |
| (SETEQ (FlagEQ)) => (MOVLconst [1]) |
| (SETEQ (FlagLT_ULT)) => (MOVLconst [0]) |
| (SETEQ (FlagLT_UGT)) => (MOVLconst [0]) |
| (SETEQ (FlagGT_ULT)) => (MOVLconst [0]) |
| (SETEQ (FlagGT_UGT)) => (MOVLconst [0]) |
| |
| (SETNE (FlagEQ)) => (MOVLconst [0]) |
| (SETNE (FlagLT_ULT)) => (MOVLconst [1]) |
| (SETNE (FlagLT_UGT)) => (MOVLconst [1]) |
| (SETNE (FlagGT_ULT)) => (MOVLconst [1]) |
| (SETNE (FlagGT_UGT)) => (MOVLconst [1]) |
| |
| (SETL (FlagEQ)) => (MOVLconst [0]) |
| (SETL (FlagLT_ULT)) => (MOVLconst [1]) |
| (SETL (FlagLT_UGT)) => (MOVLconst [1]) |
| (SETL (FlagGT_ULT)) => (MOVLconst [0]) |
| (SETL (FlagGT_UGT)) => (MOVLconst [0]) |
| |
| (SETLE (FlagEQ)) => (MOVLconst [1]) |
| (SETLE (FlagLT_ULT)) => (MOVLconst [1]) |
| (SETLE (FlagLT_UGT)) => (MOVLconst [1]) |
| (SETLE (FlagGT_ULT)) => (MOVLconst [0]) |
| (SETLE (FlagGT_UGT)) => (MOVLconst [0]) |
| |
| (SETG (FlagEQ)) => (MOVLconst [0]) |
| (SETG (FlagLT_ULT)) => (MOVLconst [0]) |
| (SETG (FlagLT_UGT)) => (MOVLconst [0]) |
| (SETG (FlagGT_ULT)) => (MOVLconst [1]) |
| (SETG (FlagGT_UGT)) => (MOVLconst [1]) |
| |
| (SETGE (FlagEQ)) => (MOVLconst [1]) |
| (SETGE (FlagLT_ULT)) => (MOVLconst [0]) |
| (SETGE (FlagLT_UGT)) => (MOVLconst [0]) |
| (SETGE (FlagGT_ULT)) => (MOVLconst [1]) |
| (SETGE (FlagGT_UGT)) => (MOVLconst [1]) |
| |
| (SETB (FlagEQ)) => (MOVLconst [0]) |
| (SETB (FlagLT_ULT)) => (MOVLconst [1]) |
| (SETB (FlagLT_UGT)) => (MOVLconst [0]) |
| (SETB (FlagGT_ULT)) => (MOVLconst [1]) |
| (SETB (FlagGT_UGT)) => (MOVLconst [0]) |
| |
| (SETBE (FlagEQ)) => (MOVLconst [1]) |
| (SETBE (FlagLT_ULT)) => (MOVLconst [1]) |
| (SETBE (FlagLT_UGT)) => (MOVLconst [0]) |
| (SETBE (FlagGT_ULT)) => (MOVLconst [1]) |
| (SETBE (FlagGT_UGT)) => (MOVLconst [0]) |
| |
| (SETA (FlagEQ)) => (MOVLconst [0]) |
| (SETA (FlagLT_ULT)) => (MOVLconst [0]) |
| (SETA (FlagLT_UGT)) => (MOVLconst [1]) |
| (SETA (FlagGT_ULT)) => (MOVLconst [0]) |
| (SETA (FlagGT_UGT)) => (MOVLconst [1]) |
| |
| (SETAE (FlagEQ)) => (MOVLconst [1]) |
| (SETAE (FlagLT_ULT)) => (MOVLconst [0]) |
| (SETAE (FlagLT_UGT)) => (MOVLconst [1]) |
| (SETAE (FlagGT_ULT)) => (MOVLconst [0]) |
| (SETAE (FlagGT_UGT)) => (MOVLconst [1]) |
| |
| // Remove redundant *const ops |
| (ADDLconst [c] x) && c==0 => x |
| (SUBLconst [c] x) && c==0 => x |
| (ANDLconst [c] _) && c==0 => (MOVLconst [0]) |
| (ANDLconst [c] x) && c==-1 => x |
| (ORLconst [c] x) && c==0 => x |
| (ORLconst [c] _) && c==-1 => (MOVLconst [-1]) |
| (XORLconst [c] x) && c==0 => x |
| // TODO: since we got rid of the W/B versions, we might miss |
| // things like (ANDLconst [0x100] x) which were formerly |
| // (ANDBconst [0] x). Probably doesn't happen very often. |
| // If we cared, we might do: |
| // (ANDLconst <t> [c] x) && t.Size()==1 && int8(x)==0 => (MOVLconst [0]) |
| |
| // Convert constant subtracts to constant adds |
| (SUBLconst [c] x) => (ADDLconst [-c] x) |
| |
| // generic constant folding |
| // TODO: more of this |
| (ADDLconst [c] (MOVLconst [d])) => (MOVLconst [c+d]) |
| (ADDLconst [c] (ADDLconst [d] x)) => (ADDLconst [c+d] x) |
| (SARLconst [c] (MOVLconst [d])) => (MOVLconst [d>>uint64(c)]) |
| (SARWconst [c] (MOVLconst [d])) => (MOVLconst [d>>uint64(c)]) |
| (SARBconst [c] (MOVLconst [d])) => (MOVLconst [d>>uint64(c)]) |
| (NEGL (MOVLconst [c])) => (MOVLconst [-c]) |
| (MULLconst [c] (MOVLconst [d])) => (MOVLconst [c*d]) |
| (ANDLconst [c] (MOVLconst [d])) => (MOVLconst [c&d]) |
| (ORLconst [c] (MOVLconst [d])) => (MOVLconst [c|d]) |
| (XORLconst [c] (MOVLconst [d])) => (MOVLconst [c^d]) |
| (NOTL (MOVLconst [c])) => (MOVLconst [^c]) |
| |
| // generic simplifications |
| // TODO: more of this |
| (ADDL x (NEGL y)) => (SUBL x y) |
| (SUBL x x) => (MOVLconst [0]) |
| (ANDL x x) => x |
| (ORL x x) => x |
| (XORL x x) => (MOVLconst [0]) |
| |
| // checking AND against 0. |
| (CMP(L|W|B)const l:(ANDL x y) [0]) && l.Uses==1 => (TEST(L|W|B) x y) |
| (CMPLconst l:(ANDLconst [c] x) [0]) && l.Uses==1 => (TESTLconst [c] x) |
| (CMPWconst l:(ANDLconst [c] x) [0]) && l.Uses==1 => (TESTWconst [int16(c)] x) |
| (CMPBconst l:(ANDLconst [c] x) [0]) && l.Uses==1 => (TESTBconst [int8(c)] x) |
| |
| // TEST %reg,%reg is shorter than CMP |
| (CMP(L|W|B)const x [0]) => (TEST(L|W|B) x x) |
| |
| // Convert LEAL1 back to ADDL if we can |
| (LEAL1 [0] {nil} x y) => (ADDL x y) |
| |
| // For PIC, break floating-point constant loading into two instructions so we have |
| // a register to use for holding the address of the constant pool entry. |
| (MOVSSconst [c]) && config.ctxt.Flag_shared => (MOVSSconst2 (MOVSSconst1 [c])) |
| (MOVSDconst [c]) && config.ctxt.Flag_shared => (MOVSDconst2 (MOVSDconst1 [c])) |
| |
| (CMP(L|W|B) l:(MOV(L|W|B)load {sym} [off] ptr mem) x) && canMergeLoad(v, l) && clobber(l) => (CMP(L|W|B)load {sym} [off] ptr x mem) |
| (CMP(L|W|B) x l:(MOV(L|W|B)load {sym} [off] ptr mem)) && canMergeLoad(v, l) && clobber(l) => (InvertFlags (CMP(L|W|B)load {sym} [off] ptr x mem)) |
| |
| (CMP(L|W|B)const l:(MOV(L|W|B)load {sym} [off] ptr mem) [c]) |
| && l.Uses == 1 |
| && clobber(l) => |
| @l.Block (CMP(L|W|B)constload {sym} [makeValAndOff(int32(c),off)] ptr mem) |
| |
| (CMPLload {sym} [off] ptr (MOVLconst [c]) mem) => (CMPLconstload {sym} [makeValAndOff(c,off)] ptr mem) |
| (CMPWload {sym} [off] ptr (MOVLconst [c]) mem) => (CMPWconstload {sym} [makeValAndOff(int32(int16(c)),off)] ptr mem) |
| (CMPBload {sym} [off] ptr (MOVLconst [c]) mem) => (CMPBconstload {sym} [makeValAndOff(int32(int8(c)),off)] ptr mem) |
| |
| (MOVBload [off] {sym} (SB) _) && symIsRO(sym) => (MOVLconst [int32(read8(sym, int64(off)))]) |
| (MOVWload [off] {sym} (SB) _) && symIsRO(sym) => (MOVLconst [int32(read16(sym, int64(off), config.ctxt.Arch.ByteOrder))]) |
| (MOVLload [off] {sym} (SB) _) && symIsRO(sym) => (MOVLconst [int32(read32(sym, int64(off), config.ctxt.Arch.ByteOrder))]) |