go/test/typeparam/cons.go
Dan Scales dca9c11845 cmd/compile: add support for generic channels and type conversion during calls
Add support for channels in subster.typ(). Add new test file chans.go.

To support assignability of bidirectional channel args to directional
channel params, I needed to type check generic calls after they are
instantiated. (Eventually, we will create separate functions to just do
the assignability logic, so we don't need to call the old typechecker in
this case.) So, for generic calls, we now leave the call as OCALL (as a
signal that the call still needs typechecking), and do typecheck.Call()
during stenciling.

Smaller changes:
 - Set the type of an instantiated OCLOSURE node (and not just the associated
   OFUNC node)

 - In instTypeName2, filter out the space that types2.TypeString inserts
   after a common in a typelist. Our standard naming requires no space
   after the comma.

 - With the assignability fix above, I no longer need the explicit
   conversions in cons.go.

Change-Id: I148858bfc6708c0aa3f50bad7debce2b8c8c091f
Reviewed-on: https://go-review.googlesource.com/c/go/+/301669
Trust: Dan Scales <danscales@google.com>
Trust: Robert Griesemer <gri@golang.org>
Reviewed-by: Robert Griesemer <gri@golang.org>
2021-03-15 20:28:10 +00:00

100 lines
2 KiB
Go

// run -gcflags=-G=3
// Copyright 2021 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// lice
package main
import "fmt"
// Overriding the predeclare "any", so it can be used as a type constraint or a type
// argument
type any interface{}
type _Function[a, b any] interface {
Apply(x a) b
}
type incr struct{ n int }
func (this incr) Apply(x int) int {
return x + this.n
}
type pos struct{}
func (this pos) Apply(x int) bool {
return x > 0
}
type compose[a, b, c any] struct {
f _Function[a, b]
g _Function[b, c]
}
func (this compose[a, b, c]) Apply(x a) c {
return this.g.Apply(this.f.Apply(x))
}
type _Eq[a any] interface {
Equal(a) bool
}
type Int int
func (this Int) Equal(that int) bool {
return int(this) == that
}
type _List[a any] interface {
Match(casenil _Function[_Nil[a], any], casecons _Function[_Cons[a], any]) any
}
type _Nil[a any] struct{
}
func (xs _Nil[a]) Match(casenil _Function[_Nil[a], any], casecons _Function[_Cons[a], any]) any {
return casenil.Apply(xs)
}
type _Cons[a any] struct {
Head a
Tail _List[a]
}
func (xs _Cons[a]) Match(casenil _Function[_Nil[a], any], casecons _Function[_Cons[a], any]) any {
return casecons.Apply(xs)
}
type mapNil[a, b any] struct{
}
func (m mapNil[a, b]) Apply(_ _Nil[a]) any {
return _Nil[b]{}
}
type mapCons[a, b any] struct {
f _Function[a, b]
}
func (m mapCons[a, b]) Apply(xs _Cons[a]) any {
return _Cons[b]{m.f.Apply(xs.Head), _Map[a, b](m.f, xs.Tail)}
}
func _Map[a, b any](f _Function[a, b], xs _List[a]) _List[b] {
return xs.Match(mapNil[a, b]{}, mapCons[a, b]{f}).(_List[b])
}
func main() {
var xs _List[int] = _Cons[int]{3, _Cons[int]{6, _Nil[int]{}}}
var ys _List[int] = _Map[int, int](incr{-5}, xs)
var xz _List[bool] = _Map[int, bool](pos{}, ys)
cs1 := xz.(_Cons[bool])
cs2 := cs1.Tail.(_Cons[bool])
_, ok := cs2.Tail.(_Nil[bool])
if cs1.Head != false || cs2.Head != true || !ok {
panic(fmt.Sprintf("got %v, %v, %v, expected false, true, true",
cs1.Head, cs2.Head, ok))
}
}