// Copyright 2017 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. // Check correctness of various closure corner cases // that are expected to be inlined package main var ok bool var sink int func main() { { if x := func() int { // ERROR "can inline main.func1" return 1 }(); x != 1 { // ERROR "inlining call to main.func1" ppanic("x != 1") } if x := func() int { // ERROR "can inline main.func2" "func literal does not escape" return 1 }; x() != 1 { // ERROR "inlining call to main.func2" ppanic("x() != 1") } } { if y := func(x int) int { // ERROR "can inline main.func3" return x + 2 }(40); y != 42 { // ERROR "inlining call to main.func3" ppanic("y != 42") } if y := func(x int) int { // ERROR "can inline main.func4" "func literal does not escape" return x + 2 }; y(40) != 42 { // ERROR "inlining call to main.func4" ppanic("y(40) != 42") } } { y := func(x int) int { // ERROR "can inline main.func5" "func literal does not escape" return x + 2 } y = func(x int) int { // ERROR "can inline main.func6" "func literal does not escape" return x + 1 } if y(40) != 41 { ppanic("y(40) != 41") } } { func() { // ERROR "func literal does not escape" y := func(x int) int { // ERROR "can inline main.func7.1" "func literal does not escape" return x + 2 } y = func(x int) int { // ERROR "can inline main.func7.2" "func literal does not escape" return x + 1 } if y(40) != 41 { ppanic("y(40) != 41") } }() } { y := func(x int) int { // ERROR "can inline main.func8" "func literal does not escape" return x + 2 } y, sink = func(x int) int { // ERROR "can inline main.func9" "func literal does not escape" return x + 1 }, 42 if y(40) != 41 { ppanic("y(40) != 41") } } { func() { // ERROR "func literal does not escape" y := func(x int) int { // ERROR "can inline main.func10.1" "func literal does not escape" return x + 2 } y, sink = func(x int) int { // ERROR "can inline main.func10.2" "func literal does not escape" return x + 1 }, 42 if y(40) != 41 { ppanic("y(40) != 41") } }() } { y := func(x int) int { // ERROR "can inline main.func11" "func literal does not escape" return x + 2 } y, sink = func() (func(int) int, int) { // ERROR "can inline main.func12" return func(x int) int { // ERROR "can inline main.func12" "func literal escapes to heap" return x + 1 }, 42 }() // ERROR "func literal does not escape" "inlining call to main.func12" if y(40) != 41 { ppanic("y(40) != 41") } } { func() { // ERROR "func literal does not escape" y := func(x int) int { // ERROR "func literal does not escape" "can inline main.func13.1" return x + 2 } y, sink = func() (func(int) int, int) { // ERROR "can inline main.func13.2" return func(x int) int { // ERROR "can inline main.func13.2" "func literal escapes to heap" return x + 1 }, 42 }() // ERROR "func literal does not escape" "inlining call to main.func13.2" if y(40) != 41 { ppanic("y(40) != 41") } }() } { y := func(x int) int { // ERROR "can inline main.func14" "func literal does not escape" return x + 2 } y, ok = map[int]func(int) int{ // ERROR "does not escape" 0: func(x int) int { return x + 1 }, // ERROR "can inline main.func15" "func literal escapes" }[0] if y(40) != 41 { ppanic("y(40) != 41") } } { func() { // ERROR "func literal does not escape" y := func(x int) int { // ERROR "can inline main.func16.1" "func literal does not escape" return x + 2 } y, ok = map[int]func(int) int{ // ERROR "does not escape" 0: func(x int) int { return x + 1 }, // ERROR "can inline main.func16.2" "func literal escapes" }[0] if y(40) != 41 { ppanic("y(40) != 41") } }() } { y := func(x int) int { // ERROR "can inline main.func17" "func literal does not escape" return x + 2 } y, ok = interface{}(func(x int) int { // ERROR "can inline main.func18" "does not escape" return x + 1 }).(func(int) int) if y(40) != 41 { ppanic("y(40) != 41") } } { func() { // ERROR "func literal does not escape" y := func(x int) int { // ERROR "can inline main.func19.1" "func literal does not escape" return x + 2 } y, ok = interface{}(func(x int) int { // ERROR "can inline main.func19.2" "does not escape" return x + 1 }).(func(int) int) if y(40) != 41 { ppanic("y(40) != 41") } }() } { x := 42 if y := func() int { // ERROR "can inline main.func20" return x }(); y != 42 { // ERROR "inlining call to main.func20" ppanic("y != 42") } if y := func() int { // ERROR "can inline main.func21" "func literal does not escape" return x }; y() != 42 { // ERROR "inlining call to main.func21" ppanic("y() != 42") } } { x := 42 if z := func(y int) int { // ERROR "can inline main.func22" return func() int { // ERROR "can inline main.func22.1" "can inline main.main.func22.func30" return x + y }() // ERROR "inlining call to main.func22.1" }(1); z != 43 { // ERROR "inlining call to main.func22" "inlining call to main.main.func22.func30" ppanic("z != 43") } if z := func(y int) int { // ERROR "func literal does not escape" "can inline main.func23" return func() int { // ERROR "can inline main.func23.1" "can inline main.main.func23.func31" return x + y }() // ERROR "inlining call to main.func23.1" }; z(1) != 43 { // ERROR "inlining call to main.func23" "inlining call to main.main.func23.func31" ppanic("z(1) != 43") } } { a := 1 func() { // ERROR "can inline main.func24" func() { // ERROR "can inline main.func24" "can inline main.main.func24.func32" a = 2 }() // ERROR "inlining call to main.func24" }() // ERROR "inlining call to main.func24" "inlining call to main.main.func24.func32" if a != 2 { ppanic("a != 2") } } { b := 2 func(b int) { // ERROR "func literal does not escape" func() { // ERROR "can inline main.func25.1" b = 3 }() // ERROR "inlining call to main.func25.1" if b != 3 { ppanic("b != 3") } }(b) if b != 2 { ppanic("b != 2") } } { c := 3 func() { // ERROR "can inline main.func26" c = 4 func() { if c != 4 { ppanic("c != 4") } recover() // prevent inlining }() }() // ERROR "inlining call to main.func26" "func literal does not escape" if c != 4 { ppanic("c != 4") } } { a := 2 // This has an unfortunate exponential growth, where as we visit each // function, we inline the inner closure, and that constructs a new // function for any closures inside the inner function, and then we // revisit those. E.g., func34 and func36 are constructed by the inliner. if r := func(x int) int { // ERROR "can inline main.func27" b := 3 return func(y int) int { // ERROR "can inline main.func27.1" "can inline main.main.func27.func34" c := 5 return func(z int) int { // ERROR "can inline main.func27.1.1" "can inline main.main.func27.func34.1" "can inline main.func27.main.func27.1.2" "can inline main.main.func27.main.main.func27.func34.func36" return a*x + b*y + c*z }(10) // ERROR "inlining call to main.func27.1.1" }(100) // ERROR "inlining call to main.func27.1" "inlining call to main.func27.main.func27.1.2" }(1000); r != 2350 { // ERROR "inlining call to main.func27" "inlining call to main.main.func27.func34" "inlining call to main.main.func27.main.main.func27.func34.func36" ppanic("r != 2350") } } { a := 2 if r := func(x int) int { // ERROR "can inline main.func28" b := 3 return func(y int) int { // ERROR "can inline main.func28.1" "can inline main.main.func28.func35" c := 5 func(z int) { // ERROR "can inline main.func28.1.1" "can inline main.func28.main.func28.1.2" "can inline main.main.func28.func35.1" "can inline main.main.func28.main.main.func28.func35.func37" a = a * x b = b * y c = c * z }(10) // ERROR "inlining call to main.func28.1.1" return a + c }(100) + b // ERROR "inlining call to main.func28.1" "inlining call to main.func28.main.func28.1.2" }(1000); r != 2350 { // ERROR "inlining call to main.func28" "inlining call to main.main.func28.func35" "inlining call to main.main.func28.main.main.func28.func35.func37" ppanic("r != 2350") } if a != 2000 { ppanic("a != 2000") } } } //go:noinline func ppanic(s string) { // ERROR "leaking param: s" panic(s) // ERROR "s escapes to heap" }