package main type Thing struct { name string } type ThingOption func(*Thing) func WithName(name string) ThingOption { return func(t *Thing) { t.name = name } } func NewThing(opts ...ThingOption) *Thing { t := &Thing{} for _, opt := range opts { opt(t) } return t } func (t Thing) String() string { return t.name } func (t Thing) Print(arg string) { println("Thing.Print:", t.name, "arg:", arg) } type Printer interface { Print(string) } func main() { thing := &Thing{"foo"} // function pointers runFunc(hello, 5) // must be indirect to avoid obvious inlining // deferred functions testDefer() // defers in loop testDeferLoop() //defer func variable call testDeferFuncVar() //More complicated func variable call testMultiFuncVar() // Take a bound method and use it as a function pointer. // This function pointer needs a context pointer. testBound(thing.String) // closures func() { println("thing inside closure:", thing.String()) }() runFunc(func(i int) { println("inside fp closure:", thing.String(), i) }, 3) // functional arguments thingFunctionalArgs1 := NewThing() thingFunctionalArgs1.Print("functional args 1") thingFunctionalArgs2 := NewThing(WithName("named thing")) thingFunctionalArgs2.Print("functional args 2") // regression testing regression1033() //Test deferred builtins testDeferBuiltinClose() testDeferBuiltinDelete() // Check for issue 1304. // There are two fields in this struct, one of which is zero-length so the // other covers the entire struct. This led to a verification error for // debug info, which used DW_OP_LLVM_fragment for a field that practically // covered the entire variable. var x issue1304 x.call() } func runFunc(f func(int), arg int) { f(arg) } func hello(n int) { println("hello from function pointer:", n) } func testDefer() { defer exportedDefer() i := 1 defer deferred("...run as defer", i) i++ defer func() { println("...run closure deferred:", i) }() i++ defer deferred("...run as defer", i) i++ var t Printer = &Thing{"foo"} defer t.Print("bar") println("deferring...") d := dumb{} defer d.Value(0) } func testDeferLoop() { for j := 0; j < 4; j++ { defer deferred("loop", j) } } func testDeferFuncVar() { dummy, f := deferFunc() dummy++ defer f(1) } func testMultiFuncVar() { f := multiFuncDefer() defer f(1) } func testDeferBuiltinClose() { i := make(chan int) func() { defer close(i) }() if n, ok := <-i; n != 0 || ok { println("expected to read 0 from closed channel") } } func testDeferBuiltinDelete() { m := map[int]int{3: 30, 5: 50} func() { defer delete(m, 3) if m[3] != 30 { println("expected m[3] to be 30") } }() if m[3] != 0 { println("expected m[3] to be 0") } } type dumb struct { } func (*dumb) Value(key interface{}) interface{} { return nil } func deferred(msg string, i int) { println(msg, i) } //export __exportedDefer func exportedDefer() { println("...exported defer") } func deferFunc() (int, func(int)) { return 0, func(i int) { println("...extracted defer func ", i) } } func multiFuncDefer() func(int) { i := 0 if i > 0 { return func(i int) { println("Should not have gotten here. i = ", i) } } return func(i int) { println("Called the correct function. i = ", i) } } func testBound(f func() string) { println("bound method:", f()) } // regression1033 is a regression test for https://github.com/tinygo-org/tinygo/issues/1033. // In previous versions of the compiler, a deferred call to an interface would create an instruction that did not dominate its uses. func regression1033() { foo(&Bar{}) } type Bar struct { empty bool } func (b *Bar) Close() error { return nil } type Closer interface { Close() error } func foo(bar *Bar) error { var a int if !bar.empty { a = 10 if a != 5 { return nil } } var c Closer = bar defer c.Close() return nil } type issue1304 struct { a [0]int // zero-length field b int // field 'b' covers entire struct } func (x issue1304) call() { // nothing to do } type recursiveFuncType func(recursiveFuncType) var recursiveFunction recursiveFuncType