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cmd/compile: remove isUintXPowerOfTwo functions

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And use the generic version instead.

While at it, also correct the corresponding rules to use logXu variants
instead of logXu, following discussion in CL 689815.

Change-Id: Iba85d14ff0e26d45a126764e7bd5702586358d23
Reviewed-on: https://go-review.googlesource.com/c/go/+/692917
Reviewed-by: Keith Randall <khr@golang.org>
Reviewed-by: Keith Randall <khr@google.com>
LUCI-TryBot-Result: Go LUCI <golang-scoped@luci-project-accounts.iam.gserviceaccount.com>
Auto-Submit: Cuong Manh Le <cuong.manhle.vn@gmail.com>
Reviewed-by: Dmitri Shuralyov <dmitshur@google.com>
This commit is contained in:
Cuong Manh Le 2025-08-04 19:17:10 +07:00 committed by Gopher Robot
parent 72147ffa75
commit 2b622b05a9
3 changed files with 104 additions and 110 deletions
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40
src/cmd/compile/internal/ssa/_gen/AMD64.rules
View file

@ -606,31 +606,31 @@
// mutandis, for UGE and SETAE, and CC and SETCC.
((NE|EQ) (TESTL (SHLL (MOVLconst [1]) x) y)) => ((ULT|UGE) (BTL x y))
((NE|EQ) (TESTQ (SHLQ (MOVQconst [1]) x) y)) => ((ULT|UGE) (BTQ x y))
((NE|EQ) (TESTLconst [c] x)) && isUint32PowerOfTwo(int64(c))
=> ((ULT|UGE) (BTLconst [int8(log32(c))] x))
((NE|EQ) (TESTQconst [c] x)) && isUint64PowerOfTwo(int64(c))
=> ((ULT|UGE) (BTQconst [int8(log32(c))] x))
((NE|EQ) (TESTQ (MOVQconst [c]) x)) && isUint64PowerOfTwo(c)
=> ((ULT|UGE) (BTQconst [int8(log64(c))] x))
((NE|EQ) (TESTLconst [c] x)) && isUnsignedPowerOfTwo(uint32(c))
=> ((ULT|UGE) (BTLconst [int8(log32u(uint32(c)))] x))
((NE|EQ) (TESTQconst [c] x)) && isUnsignedPowerOfTwo(uint64(c))
=> ((ULT|UGE) (BTQconst [int8(log32u(uint32(c)))] x))
((NE|EQ) (TESTQ (MOVQconst [c]) x)) && isUnsignedPowerOfTwo(uint64(c))
=> ((ULT|UGE) (BTQconst [int8(log64u(uint64(c)))] x))
(SET(NE|EQ) (TESTL (SHLL (MOVLconst [1]) x) y)) => (SET(B|AE) (BTL x y))
(SET(NE|EQ) (TESTQ (SHLQ (MOVQconst [1]) x) y)) => (SET(B|AE) (BTQ x y))
(SET(NE|EQ) (TESTLconst [c] x)) && isUint32PowerOfTwo(int64(c))
=> (SET(B|AE) (BTLconst [int8(log32(c))] x))
(SET(NE|EQ) (TESTQconst [c] x)) && isUint64PowerOfTwo(int64(c))
=> (SET(B|AE) (BTQconst [int8(log32(c))] x))
(SET(NE|EQ) (TESTQ (MOVQconst [c]) x)) && isUint64PowerOfTwo(c)
=> (SET(B|AE) (BTQconst [int8(log64(c))] x))
(SET(NE|EQ) (TESTLconst [c] x)) && isUnsignedPowerOfTwo(uint32(c))
=> (SET(B|AE) (BTLconst [int8(log32u(uint32(c)))] x))
(SET(NE|EQ) (TESTQconst [c] x)) && isUnsignedPowerOfTwo(uint64(c))
=> (SET(B|AE) (BTQconst [int8(log32u(uint32(c)))] x))
(SET(NE|EQ) (TESTQ (MOVQconst [c]) x)) && isUnsignedPowerOfTwo(uint64(c))
=> (SET(B|AE) (BTQconst [int8(log64u(uint64(c)))] x))
// SET..store variant
(SET(NE|EQ)store [off] {sym} ptr (TESTL (SHLL (MOVLconst [1]) x) y) mem)
=> (SET(B|AE)store [off] {sym} ptr (BTL x y) mem)
(SET(NE|EQ)store [off] {sym} ptr (TESTQ (SHLQ (MOVQconst [1]) x) y) mem)
=> (SET(B|AE)store [off] {sym} ptr (BTQ x y) mem)
(SET(NE|EQ)store [off] {sym} ptr (TESTLconst [c] x) mem) && isUint32PowerOfTwo(int64(c))
=> (SET(B|AE)store [off] {sym} ptr (BTLconst [int8(log32(c))] x) mem)
(SET(NE|EQ)store [off] {sym} ptr (TESTQconst [c] x) mem) && isUint64PowerOfTwo(int64(c))
=> (SET(B|AE)store [off] {sym} ptr (BTQconst [int8(log32(c))] x) mem)
(SET(NE|EQ)store [off] {sym} ptr (TESTQ (MOVQconst [c]) x) mem) && isUint64PowerOfTwo(c)
=> (SET(B|AE)store [off] {sym} ptr (BTQconst [int8(log64(c))] x) mem)
(SET(NE|EQ)store [off] {sym} ptr (TESTLconst [c] x) mem) && isUnsignedPowerOfTwo(uint32(c))
=> (SET(B|AE)store [off] {sym} ptr (BTLconst [int8(log32u(uint32(c)))] x) mem)
(SET(NE|EQ)store [off] {sym} ptr (TESTQconst [c] x) mem) && isUnsignedPowerOfTwo(uint64(c))
=> (SET(B|AE)store [off] {sym} ptr (BTQconst [int8(log32u(uint32(c)))] x) mem)
(SET(NE|EQ)store [off] {sym} ptr (TESTQ (MOVQconst [c]) x) mem) && isUnsignedPowerOfTwo(uint64(c))
=> (SET(B|AE)store [off] {sym} ptr (BTQconst [int8(log64u(uint64(c)))] x) mem)
// Handle bit-testing in the form (a>>b)&1 != 0 by building the above rules
// and further combining shifts.
@ -655,14 +655,14 @@
(XOR(Q|L) (SHL(Q|L) (MOV(Q|L)const [1]) y) x) => (BTC(Q|L) x y)
// Note: only convert OR/XOR to BTS/BTC if the constant wouldn't fit in
// the constant field of the OR/XOR instruction. See issue 61694.
((OR|XOR)Q (MOVQconst [c]) x) && isUint64PowerOfTwo(c) && uint64(c) >= 1<<31 => (BT(S|C)Qconst [int8(log64(c))] x)
((OR|XOR)Q (MOVQconst [c]) x) && isUnsignedPowerOfTwo(uint64(c)) && uint64(c) >= 1<<31 => (BT(S|C)Qconst [int8(log64u(uint64(c)))] x)
// Recognize bit clearing: a &^= 1<<b
(AND(Q|L) (NOT(Q|L) (SHL(Q|L) (MOV(Q|L)const [1]) y)) x) => (BTR(Q|L) x y)
(ANDN(Q|L) x (SHL(Q|L) (MOV(Q|L)const [1]) y)) => (BTR(Q|L) x y)
// Note: only convert AND to BTR if the constant wouldn't fit in
// the constant field of the AND instruction. See issue 61694.
(ANDQ (MOVQconst [c]) x) && isUint64PowerOfTwo(^c) && uint64(^c) >= 1<<31 => (BTRQconst [int8(log64(^c))] x)
(ANDQ (MOVQconst [c]) x) && isUnsignedPowerOfTwo(uint64(^c)) && uint64(^c) >= 1<<31 => (BTRQconst [int8(log64u(uint64(^c)))] x)
// Special-case bit patterns on first/last bit.
// generic.rules changes ANDs of high-part/low-part masks into a couple of shifts,

6
src/cmd/compile/internal/ssa/rewrite.go
View file

@ -504,12 +504,6 @@ func isUnsignedPowerOfTwo[T uint8 | uint16 | uint32 | uint64](n T) bool {
return n != 0 && n&(n-1) == 0
}
// isUint64PowerOfTwo reports whether uint64(n) is a power of 2.
func isUint64PowerOfTwo(in int64) bool { return isUnsignedPowerOfTwo(uint64(in)) }
// isUint32PowerOfTwo reports whether uint32(n) is a power of 2.
func isUint32PowerOfTwo(in int64) bool { return isUnsignedPowerOfTwo(uint32(in)) }
// is32Bit reports whether n can be represented as a signed 32 bit integer.
func is32Bit(n int64) bool {
return n == int64(int32(n))

168
src/cmd/compile/internal/ssa/rewriteAMD64.go
View file

@ -3108,8 +3108,8 @@ func rewriteValueAMD64_OpAMD64ANDQ(v *Value) bool {
break
}
// match: (ANDQ (MOVQconst [c]) x)
// cond: isUint64PowerOfTwo(^c) && uint64(^c) >= 1<<31
// result: (BTRQconst [int8(log64(^c))] x)
// cond: isUnsignedPowerOfTwo(uint64(^c)) && uint64(^c) >= 1<<31
// result: (BTRQconst [int8(log64u(uint64(^c)))] x)
for {
for _i0 := 0; _i0 <= 1; _i0, v_0, v_1 = _i0+1, v_1, v_0 {
if v_0.Op != OpAMD64MOVQconst {
@ -3117,11 +3117,11 @@ func rewriteValueAMD64_OpAMD64ANDQ(v *Value) bool {
}
c := auxIntToInt64(v_0.AuxInt)
x := v_1
if !(isUint64PowerOfTwo(^c) && uint64(^c) >= 1<<31) {
if !(isUnsignedPowerOfTwo(uint64(^c)) && uint64(^c) >= 1<<31) {
continue
}
v.reset(OpAMD64BTRQconst)
v.AuxInt = int8ToAuxInt(int8(log64(^c)))
v.AuxInt = int8ToAuxInt(int8(log64u(uint64(^c))))
v.AddArg(x)
return true
}
@ -14431,8 +14431,8 @@ func rewriteValueAMD64_OpAMD64ORQ(v *Value) bool {
break
}
// match: (ORQ (MOVQconst [c]) x)
// cond: isUint64PowerOfTwo(c) && uint64(c) >= 1<<31
// result: (BTSQconst [int8(log64(c))] x)
// cond: isUnsignedPowerOfTwo(uint64(c)) && uint64(c) >= 1<<31
// result: (BTSQconst [int8(log64u(uint64(c)))] x)
for {
for _i0 := 0; _i0 <= 1; _i0, v_0, v_1 = _i0+1, v_1, v_0 {
if v_0.Op != OpAMD64MOVQconst {
@ -14440,11 +14440,11 @@ func rewriteValueAMD64_OpAMD64ORQ(v *Value) bool {
}
c := auxIntToInt64(v_0.AuxInt)
x := v_1
if !(isUint64PowerOfTwo(c) && uint64(c) >= 1<<31) {
if !(isUnsignedPowerOfTwo(uint64(c)) && uint64(c) >= 1<<31) {
continue
}
v.reset(OpAMD64BTSQconst)
v.AuxInt = int8ToAuxInt(int8(log64(c)))
v.AuxInt = int8ToAuxInt(int8(log64u(uint64(c))))
v.AddArg(x)
return true
}
@ -17398,46 +17398,46 @@ func rewriteValueAMD64_OpAMD64SETEQ(v *Value) bool {
break
}
// match: (SETEQ (TESTLconst [c] x))
// cond: isUint32PowerOfTwo(int64(c))
// result: (SETAE (BTLconst [int8(log32(c))] x))
// cond: isUnsignedPowerOfTwo(uint32(c))
// result: (SETAE (BTLconst [int8(log32u(uint32(c)))] x))
for {
if v_0.Op != OpAMD64TESTLconst {
break
}
c := auxIntToInt32(v_0.AuxInt)
x := v_0.Args[0]
if !(isUint32PowerOfTwo(int64(c))) {
if !(isUnsignedPowerOfTwo(uint32(c))) {
break
}
v.reset(OpAMD64SETAE)
v0 := b.NewValue0(v.Pos, OpAMD64BTLconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log32(c)))
v0.AuxInt = int8ToAuxInt(int8(log32u(uint32(c))))
v0.AddArg(x)
v.AddArg(v0)
return true
}
// match: (SETEQ (TESTQconst [c] x))
// cond: isUint64PowerOfTwo(int64(c))
// result: (SETAE (BTQconst [int8(log32(c))] x))
// cond: isUnsignedPowerOfTwo(uint64(c))
// result: (SETAE (BTQconst [int8(log32u(uint32(c)))] x))
for {
if v_0.Op != OpAMD64TESTQconst {
break
}
c := auxIntToInt32(v_0.AuxInt)
x := v_0.Args[0]
if !(isUint64PowerOfTwo(int64(c))) {
if !(isUnsignedPowerOfTwo(uint64(c))) {
break
}
v.reset(OpAMD64SETAE)
v0 := b.NewValue0(v.Pos, OpAMD64BTQconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log32(c)))
v0.AuxInt = int8ToAuxInt(int8(log32u(uint32(c))))
v0.AddArg(x)
v.AddArg(v0)
return true
}
// match: (SETEQ (TESTQ (MOVQconst [c]) x))
// cond: isUint64PowerOfTwo(c)
// result: (SETAE (BTQconst [int8(log64(c))] x))
// cond: isUnsignedPowerOfTwo(uint64(c))
// result: (SETAE (BTQconst [int8(log64u(uint64(c)))] x))
for {
if v_0.Op != OpAMD64TESTQ {
break
@ -17451,12 +17451,12 @@ func rewriteValueAMD64_OpAMD64SETEQ(v *Value) bool {
}
c := auxIntToInt64(v_0_0.AuxInt)
x := v_0_1
if !(isUint64PowerOfTwo(c)) {
if !(isUnsignedPowerOfTwo(uint64(c))) {
continue
}
v.reset(OpAMD64SETAE)
v0 := b.NewValue0(v.Pos, OpAMD64BTQconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log64(c)))
v0.AuxInt = int8ToAuxInt(int8(log64u(uint64(c))))
v0.AddArg(x)
v.AddArg(v0)
return true
@ -17875,8 +17875,8 @@ func rewriteValueAMD64_OpAMD64SETEQstore(v *Value) bool {
break
}
// match: (SETEQstore [off] {sym} ptr (TESTLconst [c] x) mem)
// cond: isUint32PowerOfTwo(int64(c))
// result: (SETAEstore [off] {sym} ptr (BTLconst [int8(log32(c))] x) mem)
// cond: isUnsignedPowerOfTwo(uint32(c))
// result: (SETAEstore [off] {sym} ptr (BTLconst [int8(log32u(uint32(c)))] x) mem)
for {
off := auxIntToInt32(v.AuxInt)
sym := auxToSym(v.Aux)
@ -17887,21 +17887,21 @@ func rewriteValueAMD64_OpAMD64SETEQstore(v *Value) bool {
c := auxIntToInt32(v_1.AuxInt)
x := v_1.Args[0]
mem := v_2
if !(isUint32PowerOfTwo(int64(c))) {
if !(isUnsignedPowerOfTwo(uint32(c))) {
break
}
v.reset(OpAMD64SETAEstore)
v.AuxInt = int32ToAuxInt(off)
v.Aux = symToAux(sym)
v0 := b.NewValue0(v.Pos, OpAMD64BTLconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log32(c)))
v0.AuxInt = int8ToAuxInt(int8(log32u(uint32(c))))
v0.AddArg(x)
v.AddArg3(ptr, v0, mem)
return true
}
// match: (SETEQstore [off] {sym} ptr (TESTQconst [c] x) mem)
// cond: isUint64PowerOfTwo(int64(c))
// result: (SETAEstore [off] {sym} ptr (BTQconst [int8(log32(c))] x) mem)
// cond: isUnsignedPowerOfTwo(uint64(c))
// result: (SETAEstore [off] {sym} ptr (BTQconst [int8(log32u(uint32(c)))] x) mem)
for {
off := auxIntToInt32(v.AuxInt)
sym := auxToSym(v.Aux)
@ -17912,21 +17912,21 @@ func rewriteValueAMD64_OpAMD64SETEQstore(v *Value) bool {
c := auxIntToInt32(v_1.AuxInt)
x := v_1.Args[0]
mem := v_2
if !(isUint64PowerOfTwo(int64(c))) {
if !(isUnsignedPowerOfTwo(uint64(c))) {
break
}
v.reset(OpAMD64SETAEstore)
v.AuxInt = int32ToAuxInt(off)
v.Aux = symToAux(sym)
v0 := b.NewValue0(v.Pos, OpAMD64BTQconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log32(c)))
v0.AuxInt = int8ToAuxInt(int8(log32u(uint32(c))))
v0.AddArg(x)
v.AddArg3(ptr, v0, mem)
return true
}
// match: (SETEQstore [off] {sym} ptr (TESTQ (MOVQconst [c]) x) mem)
// cond: isUint64PowerOfTwo(c)
// result: (SETAEstore [off] {sym} ptr (BTQconst [int8(log64(c))] x) mem)
// cond: isUnsignedPowerOfTwo(uint64(c))
// result: (SETAEstore [off] {sym} ptr (BTQconst [int8(log64u(uint64(c)))] x) mem)
for {
off := auxIntToInt32(v.AuxInt)
sym := auxToSym(v.Aux)
@ -17944,14 +17944,14 @@ func rewriteValueAMD64_OpAMD64SETEQstore(v *Value) bool {
c := auxIntToInt64(v_1_0.AuxInt)
x := v_1_1
mem := v_2
if !(isUint64PowerOfTwo(c)) {
if !(isUnsignedPowerOfTwo(uint64(c))) {
continue
}
v.reset(OpAMD64SETAEstore)
v.AuxInt = int32ToAuxInt(off)
v.Aux = symToAux(sym)
v0 := b.NewValue0(v.Pos, OpAMD64BTQconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log64(c)))
v0.AuxInt = int8ToAuxInt(int8(log64u(uint64(c))))
v0.AddArg(x)
v.AddArg3(ptr, v0, mem)
return true
@ -19444,46 +19444,46 @@ func rewriteValueAMD64_OpAMD64SETNE(v *Value) bool {
break
}
// match: (SETNE (TESTLconst [c] x))
// cond: isUint32PowerOfTwo(int64(c))
// result: (SETB (BTLconst [int8(log32(c))] x))
// cond: isUnsignedPowerOfTwo(uint32(c))
// result: (SETB (BTLconst [int8(log32u(uint32(c)))] x))
for {
if v_0.Op != OpAMD64TESTLconst {
break
}
c := auxIntToInt32(v_0.AuxInt)
x := v_0.Args[0]
if !(isUint32PowerOfTwo(int64(c))) {
if !(isUnsignedPowerOfTwo(uint32(c))) {
break
}
v.reset(OpAMD64SETB)
v0 := b.NewValue0(v.Pos, OpAMD64BTLconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log32(c)))
v0.AuxInt = int8ToAuxInt(int8(log32u(uint32(c))))
v0.AddArg(x)
v.AddArg(v0)
return true
}
// match: (SETNE (TESTQconst [c] x))
// cond: isUint64PowerOfTwo(int64(c))
// result: (SETB (BTQconst [int8(log32(c))] x))
// cond: isUnsignedPowerOfTwo(uint64(c))
// result: (SETB (BTQconst [int8(log32u(uint32(c)))] x))
for {
if v_0.Op != OpAMD64TESTQconst {
break
}
c := auxIntToInt32(v_0.AuxInt)
x := v_0.Args[0]
if !(isUint64PowerOfTwo(int64(c))) {
if !(isUnsignedPowerOfTwo(uint64(c))) {
break
}
v.reset(OpAMD64SETB)
v0 := b.NewValue0(v.Pos, OpAMD64BTQconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log32(c)))
v0.AuxInt = int8ToAuxInt(int8(log32u(uint32(c))))
v0.AddArg(x)
v.AddArg(v0)
return true
}
// match: (SETNE (TESTQ (MOVQconst [c]) x))
// cond: isUint64PowerOfTwo(c)
// result: (SETB (BTQconst [int8(log64(c))] x))
// cond: isUnsignedPowerOfTwo(uint64(c))
// result: (SETB (BTQconst [int8(log64u(uint64(c)))] x))
for {
if v_0.Op != OpAMD64TESTQ {
break
@ -19497,12 +19497,12 @@ func rewriteValueAMD64_OpAMD64SETNE(v *Value) bool {
}
c := auxIntToInt64(v_0_0.AuxInt)
x := v_0_1
if !(isUint64PowerOfTwo(c)) {
if !(isUnsignedPowerOfTwo(uint64(c))) {
continue
}
v.reset(OpAMD64SETB)
v0 := b.NewValue0(v.Pos, OpAMD64BTQconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log64(c)))
v0.AuxInt = int8ToAuxInt(int8(log64u(uint64(c))))
v0.AddArg(x)
v.AddArg(v0)
return true
@ -19921,8 +19921,8 @@ func rewriteValueAMD64_OpAMD64SETNEstore(v *Value) bool {
break
}
// match: (SETNEstore [off] {sym} ptr (TESTLconst [c] x) mem)
// cond: isUint32PowerOfTwo(int64(c))
// result: (SETBstore [off] {sym} ptr (BTLconst [int8(log32(c))] x) mem)
// cond: isUnsignedPowerOfTwo(uint32(c))
// result: (SETBstore [off] {sym} ptr (BTLconst [int8(log32u(uint32(c)))] x) mem)
for {
off := auxIntToInt32(v.AuxInt)
sym := auxToSym(v.Aux)
@ -19933,21 +19933,21 @@ func rewriteValueAMD64_OpAMD64SETNEstore(v *Value) bool {
c := auxIntToInt32(v_1.AuxInt)
x := v_1.Args[0]
mem := v_2
if !(isUint32PowerOfTwo(int64(c))) {
if !(isUnsignedPowerOfTwo(uint32(c))) {
break
}
v.reset(OpAMD64SETBstore)
v.AuxInt = int32ToAuxInt(off)
v.Aux = symToAux(sym)
v0 := b.NewValue0(v.Pos, OpAMD64BTLconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log32(c)))
v0.AuxInt = int8ToAuxInt(int8(log32u(uint32(c))))
v0.AddArg(x)
v.AddArg3(ptr, v0, mem)
return true
}
// match: (SETNEstore [off] {sym} ptr (TESTQconst [c] x) mem)
// cond: isUint64PowerOfTwo(int64(c))
// result: (SETBstore [off] {sym} ptr (BTQconst [int8(log32(c))] x) mem)
// cond: isUnsignedPowerOfTwo(uint64(c))
// result: (SETBstore [off] {sym} ptr (BTQconst [int8(log32u(uint32(c)))] x) mem)
for {
off := auxIntToInt32(v.AuxInt)
sym := auxToSym(v.Aux)
@ -19958,21 +19958,21 @@ func rewriteValueAMD64_OpAMD64SETNEstore(v *Value) bool {
c := auxIntToInt32(v_1.AuxInt)
x := v_1.Args[0]
mem := v_2
if !(isUint64PowerOfTwo(int64(c))) {
if !(isUnsignedPowerOfTwo(uint64(c))) {
break
}
v.reset(OpAMD64SETBstore)
v.AuxInt = int32ToAuxInt(off)
v.Aux = symToAux(sym)
v0 := b.NewValue0(v.Pos, OpAMD64BTQconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log32(c)))
v0.AuxInt = int8ToAuxInt(int8(log32u(uint32(c))))
v0.AddArg(x)
v.AddArg3(ptr, v0, mem)
return true
}
// match: (SETNEstore [off] {sym} ptr (TESTQ (MOVQconst [c]) x) mem)
// cond: isUint64PowerOfTwo(c)
// result: (SETBstore [off] {sym} ptr (BTQconst [int8(log64(c))] x) mem)
// cond: isUnsignedPowerOfTwo(uint64(c))
// result: (SETBstore [off] {sym} ptr (BTQconst [int8(log64u(uint64(c)))] x) mem)
for {
off := auxIntToInt32(v.AuxInt)
sym := auxToSym(v.Aux)
@ -19990,14 +19990,14 @@ func rewriteValueAMD64_OpAMD64SETNEstore(v *Value) bool {
c := auxIntToInt64(v_1_0.AuxInt)
x := v_1_1
mem := v_2
if !(isUint64PowerOfTwo(c)) {
if !(isUnsignedPowerOfTwo(uint64(c))) {
continue
}
v.reset(OpAMD64SETBstore)
v.AuxInt = int32ToAuxInt(off)
v.Aux = symToAux(sym)
v0 := b.NewValue0(v.Pos, OpAMD64BTQconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log64(c)))
v0.AuxInt = int8ToAuxInt(int8(log64u(uint64(c))))
v0.AddArg(x)
v.AddArg3(ptr, v0, mem)
return true
@ -23495,8 +23495,8 @@ func rewriteValueAMD64_OpAMD64XORQ(v *Value) bool {
break
}
// match: (XORQ (MOVQconst [c]) x)
// cond: isUint64PowerOfTwo(c) && uint64(c) >= 1<<31
// result: (BTCQconst [int8(log64(c))] x)
// cond: isUnsignedPowerOfTwo(uint64(c)) && uint64(c) >= 1<<31
// result: (BTCQconst [int8(log64u(uint64(c)))] x)
for {
for _i0 := 0; _i0 <= 1; _i0, v_0, v_1 = _i0+1, v_1, v_0 {
if v_0.Op != OpAMD64MOVQconst {
@ -23504,11 +23504,11 @@ func rewriteValueAMD64_OpAMD64XORQ(v *Value) bool {
}
c := auxIntToInt64(v_0.AuxInt)
x := v_1
if !(isUint64PowerOfTwo(c) && uint64(c) >= 1<<31) {
if !(isUnsignedPowerOfTwo(uint64(c)) && uint64(c) >= 1<<31) {
continue
}
v.reset(OpAMD64BTCQconst)
v.AuxInt = int8ToAuxInt(int8(log64(c)))
v.AuxInt = int8ToAuxInt(int8(log64u(uint64(c))))
v.AddArg(x)
return true
}
@ -30148,40 +30148,40 @@ func rewriteBlockAMD64(b *Block) bool {
break
}
// match: (EQ (TESTLconst [c] x))
// cond: isUint32PowerOfTwo(int64(c))
// result: (UGE (BTLconst [int8(log32(c))] x))
// cond: isUnsignedPowerOfTwo(uint32(c))
// result: (UGE (BTLconst [int8(log32u(uint32(c)))] x))
for b.Controls[0].Op == OpAMD64TESTLconst {
v_0 := b.Controls[0]
c := auxIntToInt32(v_0.AuxInt)
x := v_0.Args[0]
if !(isUint32PowerOfTwo(int64(c))) {
if !(isUnsignedPowerOfTwo(uint32(c))) {
break
}
v0 := b.NewValue0(v_0.Pos, OpAMD64BTLconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log32(c)))
v0.AuxInt = int8ToAuxInt(int8(log32u(uint32(c))))
v0.AddArg(x)
b.resetWithControl(BlockAMD64UGE, v0)
return true
}
// match: (EQ (TESTQconst [c] x))
// cond: isUint64PowerOfTwo(int64(c))
// result: (UGE (BTQconst [int8(log32(c))] x))
// cond: isUnsignedPowerOfTwo(uint64(c))
// result: (UGE (BTQconst [int8(log32u(uint32(c)))] x))
for b.Controls[0].Op == OpAMD64TESTQconst {
v_0 := b.Controls[0]
c := auxIntToInt32(v_0.AuxInt)
x := v_0.Args[0]
if !(isUint64PowerOfTwo(int64(c))) {
if !(isUnsignedPowerOfTwo(uint64(c))) {
break
}
v0 := b.NewValue0(v_0.Pos, OpAMD64BTQconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log32(c)))
v0.AuxInt = int8ToAuxInt(int8(log32u(uint32(c))))
v0.AddArg(x)
b.resetWithControl(BlockAMD64UGE, v0)
return true
}
// match: (EQ (TESTQ (MOVQconst [c]) x))
// cond: isUint64PowerOfTwo(c)
// result: (UGE (BTQconst [int8(log64(c))] x))
// cond: isUnsignedPowerOfTwo(uint64(c))
// result: (UGE (BTQconst [int8(log64u(uint64(c)))] x))
for b.Controls[0].Op == OpAMD64TESTQ {
v_0 := b.Controls[0]
_ = v_0.Args[1]
@ -30193,11 +30193,11 @@ func rewriteBlockAMD64(b *Block) bool {
}
c := auxIntToInt64(v_0_0.AuxInt)
x := v_0_1
if !(isUint64PowerOfTwo(c)) {
if !(isUnsignedPowerOfTwo(uint64(c))) {
continue
}
v0 := b.NewValue0(v_0.Pos, OpAMD64BTQconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log64(c)))
v0.AuxInt = int8ToAuxInt(int8(log64u(uint64(c))))
v0.AddArg(x)
b.resetWithControl(BlockAMD64UGE, v0)
return true
@ -31128,40 +31128,40 @@ func rewriteBlockAMD64(b *Block) bool {
break
}
// match: (NE (TESTLconst [c] x))
// cond: isUint32PowerOfTwo(int64(c))
// result: (ULT (BTLconst [int8(log32(c))] x))
// cond: isUnsignedPowerOfTwo(uint32(c))
// result: (ULT (BTLconst [int8(log32u(uint32(c)))] x))
for b.Controls[0].Op == OpAMD64TESTLconst {
v_0 := b.Controls[0]
c := auxIntToInt32(v_0.AuxInt)
x := v_0.Args[0]
if !(isUint32PowerOfTwo(int64(c))) {
if !(isUnsignedPowerOfTwo(uint32(c))) {
break
}
v0 := b.NewValue0(v_0.Pos, OpAMD64BTLconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log32(c)))
v0.AuxInt = int8ToAuxInt(int8(log32u(uint32(c))))
v0.AddArg(x)
b.resetWithControl(BlockAMD64ULT, v0)
return true
}
// match: (NE (TESTQconst [c] x))
// cond: isUint64PowerOfTwo(int64(c))
// result: (ULT (BTQconst [int8(log32(c))] x))
// cond: isUnsignedPowerOfTwo(uint64(c))
// result: (ULT (BTQconst [int8(log32u(uint32(c)))] x))
for b.Controls[0].Op == OpAMD64TESTQconst {
v_0 := b.Controls[0]
c := auxIntToInt32(v_0.AuxInt)
x := v_0.Args[0]
if !(isUint64PowerOfTwo(int64(c))) {
if !(isUnsignedPowerOfTwo(uint64(c))) {
break
}
v0 := b.NewValue0(v_0.Pos, OpAMD64BTQconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log32(c)))
v0.AuxInt = int8ToAuxInt(int8(log32u(uint32(c))))
v0.AddArg(x)
b.resetWithControl(BlockAMD64ULT, v0)
return true
}
// match: (NE (TESTQ (MOVQconst [c]) x))
// cond: isUint64PowerOfTwo(c)
// result: (ULT (BTQconst [int8(log64(c))] x))
// cond: isUnsignedPowerOfTwo(uint64(c))
// result: (ULT (BTQconst [int8(log64u(uint64(c)))] x))
for b.Controls[0].Op == OpAMD64TESTQ {
v_0 := b.Controls[0]
_ = v_0.Args[1]
@ -31173,11 +31173,11 @@ func rewriteBlockAMD64(b *Block) bool {
}
c := auxIntToInt64(v_0_0.AuxInt)
x := v_0_1
if !(isUint64PowerOfTwo(c)) {
if !(isUnsignedPowerOfTwo(uint64(c))) {
continue
}
v0 := b.NewValue0(v_0.Pos, OpAMD64BTQconst, types.TypeFlags)
v0.AuxInt = int8ToAuxInt(int8(log64(c)))
v0.AuxInt = int8ToAuxInt(int8(log64u(uint64(c))))
v0.AddArg(x)
b.resetWithControl(BlockAMD64ULT, v0)
return true