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go/test/inline.go
Cherry Mui 409f784bea cmd/compile: simplify closure name 
Currently, a closure in a function is usually named after the
outer function, usually in the form of pkg.outer.funcN. When the
containing function is inlined, we attach the inlined caller's
name to the closure name, so this may become things like
callerpkg.caller.pkg.outer.funcN. With multiple levels of
inlining, this name can get pretty long and clutter.

This CL change the compiler to use the simple, pre-inlining name
for closures. That is, the closure is always named pkg.outer.funcN
where outer is the containing function in the source code. This
name is not changed during inlining. With inlining, there may be
multiple copies of the closure, all with the same name. They are
likely to be compiled identically, although technically it is
possible for the compiler to optimize them differently based on
the context. So we'll use a content hash to distinguish and
deduplicate them.

With the content-addressable symbol mechanism, the linker is
capable of handling multiple symbols with the same name, and use
the content hash to distinguish and deduplicate them. A
complication is that the compiler is not able to handle multiple
symbols with the same name when compiling a package. So we give
them temporarily unique suffixes during the compilation (based
on the inline call stack), and trim the suffix in the object file
and DWARF generation. So their linker symbols remain simple.

One caveat is nested closure (i.e. a closure within a closure).
Previously, a nested closure is named as topLevelFunc.funcN.M where
topLevelFunc.funcN is the outer closure. When the outer closure is
inlined, and the inlined caller is not a closure, it is named as
caller.topLevelFunc.funcN.funcM (note the extra "func"). This is
arguably a bug in the current code, as it decides whether to
include the "func" word based on whether the physical containing
function is a closure or not, not the source-level function. This
CL removes the "caller" part from the name, but does not address
the extra "func" word. So when the outer closure is inlined, the
inner closure will be named topLevelFunc.funcN.funcM, which
differs from the original topLevelFunc.funcN.M. This is not too
bad in that the name won't get too long, and still match the
source.

Fixes #60324.

Change-Id: Ia69c35a8f9b1a3b2c27db1a0959c1316be8b1f81
Reviewed-on: https://go-review.googlesource.com/c/go/+/770200
Reviewed-by: Cuong Manh Le <cuong.manhle.vn@gmail.com>
Commit-Queue: Cherry Mui <cherryyz@google.com>
Reviewed-by: David Chase <drchase@google.com>
TryBot-Bypass: Cherry Mui <cherryyz@google.com>
Reviewed-by: Alessandro Arzilli <alessandro.arzilli@gmail.com>
2026-05-07 14:46:33 -07:00

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// errorcheckwithauto -0 -m -d=inlfuncswithclosures=1
//go:build !goexperiment.newinliner
// 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 (
"errors"
"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 f2() int { // ERROR "can inline f2"
tmp1 := h
tmp2 := tmp1
return tmp2(0) // ERROR "inlining call to h"
}
var abc = errors.New("abc") // ERROR "inlining call to errors.New"
var somethingWrong error
// local closures can be inlined
func l(x, y int) (int, int, error) { // ERROR "can inline l"
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"
}
_ = e // prevent simple deadcode elimination after inlining
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 "can inline o.func2"
if x > 10 {
foo = func() int { return 2 } // ERROR "can inline o.func2"
}
}(11) // ERROR "func literal does not escape" "inlining call to o.func2"
return foo()
}
func p() int { // ERROR "can inline p"
return func() int { return 42 }() // ERROR "can inline p.func1" "inlining call to p.func1"
}
func q(x int) int { // ERROR "can inline q"
foo := func() int { return x * 2 } // ERROR "can inline q.func1" "func literal does not escape"
_ = foo // prevent simple deadcode elimination after inlining
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" "can inline r.func2"
return x + func(y int) int { // ERROR "can inline r.func2.1" "can inline r.func2.func1"
return 2*y + x*z
}(x) // ERROR "inlining call to r.func2.1"
}
_, _ = foo, bar // prevent simple deadcode elimination after inlining
return foo(42) + bar(42) // ERROR "inlining call to r.func1" "inlining call to r.func2$" "inlining call to r.func2.func1"
}
func s0(x int) int { // ERROR "can inline s0"
foo := func() { // ERROR "can inline s0.func1" "func literal does not escape"
x = x + 1
}
foo() // ERROR "inlining call to s0.func1"
_ = foo // prevent simple deadcode elimination after inlining
return x
}
func s1(x int) int { // ERROR "can inline s1"
foo := func() int { // ERROR "can inline s1.func1" "func literal does not escape"
return x
}
x = x + 1
_ = foo // prevent simple deadcode elimination after inlining
return foo() // ERROR "inlining call to s1.func1"
}
func switchBreak(x, y int) int { // ERROR "can inline switchBreak"
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
}
}
// Test that switches on constant things, with constant cases, only cost anything for
// the case that matches. See issue 50253.
func switchConst1(p func(string)) { // ERROR "can inline switchConst" "p does not escape"
const c = 1
switch c {
case 0:
p("zero")
case 1:
p("one")
case 2:
p("two")
default:
p("other")
}
}
func switchConst2() string { // ERROR "can inline switchConst2"
switch runtime.GOOS {
case "linux":
return "Leenooks"
case "windows":
return "Windoze"
case "darwin":
return "MackBone"
case "1", "2", "3", "4", "5", "6", "7", "8", "9", "10", "11", "12", "13", "14", "15", "16", "17", "18", "19", "20", "21", "22", "23", "24", "25", "26", "27", "28", "29", "30", "31", "32", "33", "34", "35", "36", "37", "38", "39", "40", "41", "42", "43", "44", "45", "46", "47", "48", "49", "50", "51", "52", "53", "54", "55", "56", "57", "58", "59", "60", "61", "62", "63", "64", "65", "66", "67", "68", "69", "70", "71", "72", "73", "74", "75", "76", "77", "78", "79", "80", "81", "82", "83", "84", "85", "86", "87", "88", "89", "90", "91", "92", "93", "94", "95", "96", "97", "98", "99", "100":
return "Numbers"
default:
return "oh nose!"
}
}
func switchConst3() string { // ERROR "can inline switchConst3"
switch runtime.GOOS {
case "Linux":
panic("Linux")
case "Windows":
panic("Windows")
case "Darwin":
panic("Darwin")
case "1", "2", "3", "4", "5", "6", "7", "8", "9", "10", "11", "12", "13", "14", "15", "16", "17", "18", "19", "20", "21", "22", "23", "24", "25", "26", "27", "28", "29", "30", "31", "32", "33", "34", "35", "36", "37", "38", "39", "40", "41", "42", "43", "44", "45", "46", "47", "48", "49", "50", "51", "52", "53", "54", "55", "56", "57", "58", "59", "60", "61", "62", "63", "64", "65", "66", "67", "68", "69", "70", "71", "72", "73", "74", "75", "76", "77", "78", "79", "80", "81", "82", "83", "84", "85", "86", "87", "88", "89", "90", "91", "92", "93", "94", "95", "96", "97", "98", "99", "100":
panic("Numbers")
default:
return "oh nose!"
}
}
func switchConst4() { // ERROR "can inline switchConst4"
const intSize = 32 << (^uint(0) >> 63)
want := func() string { // ERROR "can inline switchConst4.func1"
switch intSize {
case 32:
return "32"
case 64:
return "64"
default:
panic("unreachable")
}
}() // ERROR "inlining call to switchConst4.func1"
_ = want
}
func inlineRangeIntoMe(data []int) { // ERROR "can inline inlineRangeIntoMe" "data does not escape"
rangeFunc(data, 12) // ERROR "inlining call to rangeFunc"
}
func rangeFunc(xs []int, b int) int { // ERROR "can inline rangeFunc" "xs does not escape"
for i, x := range xs {
if x == b {
return i
}
}
return -1
}
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 f3() { // ERROR "can inline f3"
T.meth(k()) // ERROR "inlining call to k" "inlining call to T.meth"
// ERRORAUTO "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) // ERROR "inlining call to gg" "inlining call to hh" "inlining call to ff"
}
func gg(x int) { // ERROR "can inline gg"
hh(x - 1) // ERROR "inlining call to hh" "inlining call to ff" "inlining call to gg"
}
func hh(x int) { // ERROR "can inline hh"
ff(x - 1) // ERROR "inlining call to ff" "inlining call to gg" "inlining call to hh"
}
// 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
}
}
}
func for2(fn func() bool) { // ERROR "can inline for2" "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"
return val + 5
}
func getMeth(t1 T1) func(int) int { // ERROR "can inline getMeth"
return t1.meth // ERROR "t1.meth escapes to heap"
// ERRORAUTO "inlining call to T1.meth"
}
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" "can inline gd1.deferwrap1"
defer gd3()() // ERROR "inlining call to gd3"
go gd1(gd2()) // ERROR "inlining call to gd2" "can inline gd1.gowrap2"
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)))))))))))
}
func select1(x, y chan bool) int { // ERROR "can inline select1" "x does not escape" "y does not escape"
select {
case <-x:
return 1
case <-y:
return 2
}
}
func select2(x, y chan bool) { // ERROR "can inline select2" "x does not escape" "y does not escape"
loop: // test that labeled select can be inlined.
select {
case <-x:
break loop
case <-y:
}
}
func inlineSelect2(x, y chan bool) { // ERROR "can inline inlineSelect2" ERROR "x does not escape" "y does not escape"
loop:
for i := 0; i < 5; i++ {
if i == 3 {
break loop
}
select2(x, y) // ERROR "inlining call to select2"
}
}
// Issue #62211: inlining a function with unreachable "return"
// statements could trip up phi insertion.
func issue62211(x bool) { // ERROR "can inline issue62211"
if issue62211F(x) { // ERROR "inlining call to issue62211F"
}
if issue62211G(x) { // ERROR "inlining call to issue62211G"
}
// Initial fix CL caused a "non-monotonic scope positions" failure
// on code like this.
if z := 0; false {
panic(z)
}
}
func issue62211F(x bool) bool { // ERROR "can inline issue62211F"
if x || true {
return true
}
return true
}
func issue62211G(x bool) bool { // ERROR "can inline issue62211G"
if x || true {
return true
} else {
return true
}
}
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