// errorcheck -0 -m -d=inlfuncswithclosures=1 // Copyright 2015 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. // Test, using compiler diagnostic flags, that inlining is working. // Compiles but does not run. package foo import ( "runtime" "unsafe" ) func add2(p *byte, n uintptr) *byte { // ERROR "can inline add2" "leaking param: p to result" return (*byte)(add1(unsafe.Pointer(p), n)) // ERROR "inlining call to add1" } func add1(p unsafe.Pointer, x uintptr) unsafe.Pointer { // ERROR "can inline add1" "leaking param: p to result" return unsafe.Pointer(uintptr(p) + x) } func f(x *byte) *byte { // ERROR "can inline f" "leaking param: x to result" return add2(x, 1) // ERROR "inlining call to add2" "inlining call to add1" } //go:noinline func g(x int) int { return x + 1 } func h(x int) int { // ERROR "can inline h" return x + 2 } func i(x int) int { // ERROR "can inline i" const y = 2 return x + y } func j(x int) int { // ERROR "can inline j" switch { case x > 0: return x + 2 default: return x + 1 } } func _() int { // ERROR "can inline _" tmp1 := h tmp2 := tmp1 return tmp2(0) // ERROR "inlining call to h" } var somethingWrong error // local closures can be inlined func l(x, y int) (int, int, error) { e := func(err error) (int, int, error) { // ERROR "can inline l.func1" "func literal does not escape" "leaking param: err to result" return 0, 0, err } if x == y { e(somethingWrong) // ERROR "inlining call to l.func1" } else { f := e f(nil) // ERROR "inlining call to l.func1" } return y, x, nil } // any re-assignment prevents closure inlining func m() int { foo := func() int { return 1 } // ERROR "can inline m.func1" "func literal does not escape" x := foo() foo = func() int { return 2 } // ERROR "can inline m.func2" "func literal does not escape" return x + foo() } // address taking prevents closure inlining func n() int { foo := func() int { return 1 } // ERROR "can inline n.func1" "func literal does not escape" bar := &foo x := (*bar)() + foo() return x } // make sure assignment inside closure is detected func o() int { foo := func() int { return 1 } // ERROR "can inline o.func1" "func literal does not escape" func(x int) { // ERROR "func literal does not escape" if x > 10 { foo = func() int { return 2 } // ERROR "can inline o.func2" "func literal escapes" } }(11) return foo() } func p() int { return func() int { return 42 }() // ERROR "can inline p.func1" "inlining call to p.func1" } func q(x int) int { foo := func() int { return x * 2 } // ERROR "can inline q.func1" "func literal does not escape" return foo() // ERROR "inlining call to q.func1" } func r(z int) int { foo := func(x int) int { // ERROR "can inline r.func1" "func literal does not escape" return x + z } bar := func(x int) int { // ERROR "func literal does not escape" return x + func(y int) int { // ERROR "can inline r.func2.1" return 2*y + x*z }(x) // ERROR "inlining call to r.func2.1" } return foo(42) + bar(42) // ERROR "inlining call to r.func1" } func s0(x int) int { foo := func() { // ERROR "can inline s0.func1" "func literal does not escape" x = x + 1 } foo() // ERROR "inlining call to s0.func1" return x } func s1(x int) int { foo := func() int { // ERROR "can inline s1.func1" "func literal does not escape" return x } x = x + 1 return foo() // ERROR "inlining call to s1.func1" } // can't currently inline functions with a break statement func switchBreak(x, y int) int { var n int switch x { case 0: n = 1 Done: switch y { case 0: n += 10 break Done } n = 2 } return n } func switchType(x interface{}) int { // ERROR "can inline switchType" "x does not escape" switch x.(type) { case int: return x.(int) default: return 0 } } type T struct{} func (T) meth(int, int) {} // ERROR "can inline T.meth" func k() (T, int, int) { return T{}, 0, 0 } // ERROR "can inline k" func _() { // ERROR "can inline _" T.meth(k()) // ERROR "inlining call to k" "inlining call to T.meth" } func small1() { // ERROR "can inline small1" runtime.GC() } func small2() int { // ERROR "can inline small2" return runtime.GOMAXPROCS(0) } func small3(t T) { // ERROR "can inline small3" t.meth2(3, 5) } func small4(t T) { // not inlineable - has 2 calls. t.meth2(runtime.GOMAXPROCS(0), 5) } func (T) meth2(int, int) { // not inlineable - has 2 calls. runtime.GC() runtime.GC() } // Issue #29737 - make sure we can do inlining for a chain of recursive functions func ee() { // ERROR "can inline ee" ff(100) // ERROR "inlining call to ff" "inlining call to gg" "inlining call to hh" } func ff(x int) { // ERROR "can inline ff" if x < 0 { return } gg(x - 1) } func gg(x int) { // ERROR "can inline gg" hh(x - 1) } func hh(x int) { // ERROR "can inline hh" ff(x - 1) // ERROR "inlining call to ff" // ERROR "inlining call to gg" } // Issue #14768 - make sure we can inline for loops. func for1(fn func() bool) { // ERROR "can inline for1" "fn does not escape" for { if fn() { break } else { continue } } } // BAD: for2 should be inlineable too. func for2(fn func() bool) { // ERROR "fn does not escape" Loop: for { if fn() { break Loop } else { continue Loop } } } // Issue #18493 - make sure we can do inlining of functions with a method value type T1 struct{} func (a T1) meth(val int) int { // ERROR "can inline T1.meth" "inlining call to T1.meth" return val + 5 } func getMeth(t1 T1) func(int) int { // ERROR "can inline getMeth" return t1.meth // ERROR "t1.meth escapes to heap" } func ii() { // ERROR "can inline ii" var t1 T1 f := getMeth(t1) // ERROR "inlining call to getMeth" "t1.meth does not escape" _ = f(3) } // Issue #42194 - make sure that functions evaluated in // go and defer statements can be inlined. func gd1(int) { defer gd1(gd2()) // ERROR "inlining call to gd2" defer gd3()() // ERROR "inlining call to gd3" go gd1(gd2()) // ERROR "inlining call to gd2" go gd3()() // ERROR "inlining call to gd3" } func gd2() int { // ERROR "can inline gd2" return 1 } func gd3() func() { // ERROR "can inline gd3" return ii } // Issue #42788 - ensure ODEREF OCONVNOP* OADDR is low cost. func EncodeQuad(d []uint32, x [6]float32) { // ERROR "can inline EncodeQuad" "d does not escape" _ = d[:6] d[0] = float32bits(x[0]) // ERROR "inlining call to float32bits" d[1] = float32bits(x[1]) // ERROR "inlining call to float32bits" d[2] = float32bits(x[2]) // ERROR "inlining call to float32bits" d[3] = float32bits(x[3]) // ERROR "inlining call to float32bits" d[4] = float32bits(x[4]) // ERROR "inlining call to float32bits" d[5] = float32bits(x[5]) // ERROR "inlining call to float32bits" } // float32bits is a copy of math.Float32bits to ensure that // these tests pass with `-gcflags=-l`. func float32bits(f float32) uint32 { // ERROR "can inline float32bits" return *(*uint32)(unsafe.Pointer(&f)) } // Ensure OCONVNOP is zero cost. func Conv(v uint64) uint64 { // ERROR "can inline Conv" return conv2(conv2(conv2(v))) // ERROR "inlining call to (conv1|conv2)" } func conv2(v uint64) uint64 { // ERROR "can inline conv2" return conv1(conv1(conv1(conv1(v)))) // ERROR "inlining call to conv1" } func conv1(v uint64) uint64 { // ERROR "can inline conv1" return uint64(uint64(uint64(uint64(uint64(uint64(uint64(uint64(uint64(uint64(uint64(v))))))))))) }