internal/apidiff/testdata/tests.go - tools - Git at Google

 // This file is split into two packages, old and new.
 // It is syntactically valid Go so that gofmt can process it.
 //
 // If a comment begins with:   Then:
 //  old                        write subsequent lines to the "old" package
 //  new                        write subsequent lines to the "new" package
 //  both                       write subsequent lines to both packages
 //  c                          expect a compatible error with the following text
 //  i                          expect an incompatible error with the following text
 package ignore

 // both
 import "io"

 //////////////// Basics

 //// Same type in both: OK.
 // both
 type A int

 //// Changing the type is an incompatible change.
 // old
 type B int

 // new
 // i B: changed from int to string
 type B string

 //// Adding a new type, whether alias or not, is a compatible change.
 // new
 // c AA: added
 type AA = A

 // c B1: added
 type B1 bool

 //// Change of type for an unexported name doesn't matter...
 // old
 type t int

 // new
 type t string // OK: t isn't part of the API

 //// ...unless it is exposed.
 // both
 var V2 u

 // old
 type u string

 // new
 // i u: changed from string to int
 type u int

 //// An exposed, unexported type can be renamed.
 // both
 type u2 int

 // old
 type u1 int

 var V5 u1

 // new
 var V5 u2 // OK: V5 has changed type, but old u1 corresopnds to new u2

 //// Splitting a single type into two is an incompatible change.
 // both
 type u3 int

 // old
 type (
 	Split1 = u1
 	Split2 = u1
 )

 // new
 type (
 	Split1 = u2 // OK, since old u1 corresponds to new u2

 	// This tries to make u1 correspond to u3
 	// i Split2: changed from u1 to u3
 	Split2 = u3
 )

 //// Merging two types into one is OK.
 // old
 type (
 	GoodMerge1 = u2
 	GoodMerge2 = u3
 )

 // new
 type (
 	GoodMerge1 = u3
 	GoodMerge2 = u3
 )

 //// Merging isn't OK here because a method is lost.
 // both
 type u4 int

 func (u4) M() {}

 // old
 type (
 	BadMerge1 = u3
 	BadMerge2 = u4
 )

 // new
 type (
 	BadMerge1 = u3
 	// i u4.M: removed
 	// What's really happening here is that old u4 corresponds to new u3,
 	// and new u3's method set is not a superset of old u4's.
 	BadMerge2 = u3
 )

 // old
 type Rem int

 // new
 // i Rem: removed

 //////////////// Constants

 //// type changes
 // old
 const (
 	C1     = 1
 	C2 int = 2
 	C3     = 3
 	C4 u1  = 4
 )

 var V8 int

 // new
 const (
 	// i C1: changed from untyped int to untyped string
 	C1 = "1"
 	// i C2: changed from int to untyped int
 	C2 = -1
 	// i C3: changed from untyped int to int
 	C3 int = 3
 	// i V8: changed from var to const
 	V8 int = 1
 	C4 u2  = 4 // OK: u1 corresponds to u2
 )

 // value change
 // old
 const (
 	Cr1 = 1
 	Cr2 = "2"
 	Cr3 = 3.5
 	Cr4 = complex(0, 4.1)
 )

 // new
 const (
 	// i Cr1: value changed from 1 to -1
 	Cr1 = -1
 	// i Cr2: value changed from "2" to "3"
 	Cr2 = "3"
 	// i Cr3: value changed from 3.5 to 3.8
 	Cr3 = 3.8
 	// i Cr4: value changed from (0 + 4.1i) to (4.1 + 0i)
 	Cr4 = complex(4.1, 0)
 )

 //////////////// Variables

 //// simple type changes
 // old
 var (
 	V1 string
 	V3 A
 	V7 <-chan int
 )

 // new
 var (
 	// i V1: changed from string to []string
 	V1 []string
 	V3 A // OK: same
 	// i V7: changed from <-chan int to chan int
 	V7 chan int
 )

 //// interface type  changes
 // old
 var (
 	V9  interface{ M() }
 	V10 interface{ M() }
 	V11 interface{ M() }
 )

 // new
 var (
 	// i V9: changed from interface{M()} to interface{}
 	V9 interface{}
 	// i V10: changed from interface{M()} to interface{M(); M2()}
 	V10 interface {
 		M2()
 		M()
 	}
 	// i V11: changed from interface{M()} to interface{M(int)}
 	V11 interface{ M(int) }
 )

 //// struct type changes
 // old
 var (
 	VS1 struct{ A, B int }
 	VS2 struct{ A, B int }
 	VS3 struct{ A, B int }
 	VS4 struct {
 		A int
 		u1
 	}
 )

 // new
 var (
 	// i VS1: changed from struct{A int; B int} to struct{B int; A int}
 	VS1 struct{ B, A int }
 	// i VS2: changed from struct{A int; B int} to struct{A int}
 	VS2 struct{ A int }
 	// i VS3: changed from struct{A int; B int} to struct{A int; B int; C int}
 	VS3 struct{ A, B, C int }
 	VS4 struct {
 		A int
 		u2
 	}
 )

 //////////////// Types

 // old
 const C5 = 3

 type (
 	A1 [1]int
 	A2 [2]int
 	A3 [C5]int
 )

 // new
 // i C5: value changed from 3 to 4
 const C5 = 4

 type (
 	A1 [1]int
 	// i A2: changed from [2]int to [2]bool
 	A2 [2]bool
 	// i A3: changed from [3]int to [4]int
 	A3 [C5]int
 )

 // old
 type (
 	Sl []int
 	P1 *int
 	P2 *u1
 )

 // new
 type (
 	// i Sl: changed from []int to []string
 	Sl []string
 	// i P1: changed from *int to **bool
 	P1 **bool
 	P2 *u2 // OK: u1 corresponds to u2
 )

 // old
 type Bc1 int32
 type Bc2 uint
 type Bc3 float32
 type Bc4 complex64

 // new
 // c Bc1: changed from int32 to int
 type Bc1 int

 // c Bc2: changed from uint to uint64
 type Bc2 uint64

 // c Bc3: changed from float32 to float64
 type Bc3 float64

 // c Bc4: changed from complex64 to complex128
 type Bc4 complex128

 // old
 type Bi1 int32
 type Bi2 uint
 type Bi3 float64
 type Bi4 complex128

 // new
 // i Bi1: changed from int32 to int16
 type Bi1 int16

 // i Bi2: changed from uint to uint32
 type Bi2 uint32

 // i Bi3: changed from float64 to float32
 type Bi3 float32

 // i Bi4: changed from complex128 to complex64
 type Bi4 complex64

 // old
 type (
 	M1 map[string]int
 	M2 map[string]int
 	M3 map[string]int
 )

 // new
 type (
 	M1 map[string]int
 	// i M2: changed from map[string]int to map[int]int
 	M2 map[int]int
 	// i M3: changed from map[string]int to map[string]string
 	M3 map[string]string
 )

 // old
 type (
 	Ch1 chan int
 	Ch2 <-chan int
 	Ch3 chan int
 	Ch4 <-chan int
 )

 // new
 type (
 	// i Ch1, element type: changed from int to bool
 	Ch1 chan bool
 	// i Ch2: changed direction
 	Ch2 chan<- int
 	// i Ch3: changed direction
 	Ch3 <-chan int
 	// c Ch4: removed direction
 	Ch4 chan int
 )

 // old
 type I1 interface {
 	M1()
 	M2()
 }

 // new
 type I1 interface {
 	// M1()
 	// i I1.M1: removed
 	M2(int)
 	// i I1.M2: changed from func() to func(int)
 	M3()
 	// i I1.M3: added
 	m()
 	// i I1.m: added unexported method
 }

 // old
 type I2 interface {
 	M1()
 	m()
 }

 // new
 type I2 interface {
 	M1()
 	// m() Removing an unexported method is OK.
 	m2() // OK, because old already had an unexported method
 	// c I2.M2: added
 	M2()
 }

 // old
 type I3 interface {
 	io.Reader
 	M()
 }

 // new
 // OK: what matters is the method set; the name of the embedded
 // interface isn't important.
 type I3 interface {
 	M()
 	Read([]byte) (int, error)
 }

 // old
 type I4 io.Writer

 // new
 // OK: in both, I4 is a distinct type from io.Writer, and
 // the old and new I4s have the same method set.
 type I4 interface {
 	Write([]byte) (int, error)
 }

 // old
 type I5 = io.Writer

 // new
 // i I5: changed from io.Writer to I5
 // In old, I5 and io.Writer are the same type; in new,
 // they are different. That can break something like:
 //   var _ func(io.Writer) = func(pkg.I6) {}
 type I5 io.Writer

 // old
 type I6 interface{ Write([]byte) (int, error) }

 // new
 // i I6: changed from I6 to io.Writer
 // Similar to the above.
 type I6 = io.Writer

 //// correspondence with a basic type
 // Basic types are technically defined types, but they aren't
 // represented that way in go/types, so the cases below are special.

 // both
 type T1 int

 // old
 var VT1 T1

 // new
 // i VT1: changed from T1 to int
 // This fails because old T1 corresponds to both int and new T1.
 var VT1 int

 // old
 type t2 int

 var VT2 t2

 // new
 // OK: t2 corresponds to int. It's fine that old t2
 // doesn't exist in new.
 var VT2 int

 // both
 type t3 int

 func (t3) M() {}

 // old
 var VT3 t3

 // new
 // i t3.M: removed
 // Here the change from t3 to int is incompatible
 // because old t3 has an exported method.
 var VT3 int

 // old
 var VT4 int

 // new
 type t4 int

 // i VT4: changed from int to t4
 // This is incompatible because of code like
 //    VT4 + int(1)
 // which works in old but fails in new.
 // The difference from the above cases is that
 // in those, we were merging two types into one;
 // here, we are splitting int into t4 and int.
 var VT4 t4

 //////////////// Functions

 // old
 func F1(a int, b string) map[u1]A { return nil }
 func F2(int)                      {}
 func F3(int)                      {}
 func F4(int) int                  { return 0 }
 func F5(int) int                  { return 0 }
 func F6(int)                      {}
 func F7(interface{})              {}

 // new
 func F1(c int, d string) map[u2]AA { return nil } //OK: same (since u1 corresponds to u2)

 // i F2: changed from func(int) to func(int) bool
 func F2(int) bool { return true }

 // i F3: changed from func(int) to func(int, int)
 func F3(int, int) {}

 // i F4: changed from func(int) int to func(bool) int
 func F4(bool) int { return 0 }

 // i F5: changed from func(int) int to func(int) string
 func F5(int) string { return "" }

 // i F6: changed from func(int) to func(...int)
 func F6(...int) {}

 // i F7: changed from func(interface{}) to func(interface{x()})
 func F7(a interface{ x() }) {}

 // old
 func F8(bool) {}

 // new
 // c F8: changed from func to var
 var F8 func(bool)

 // old
 var F9 func(int)

 // new
 // i F9: changed from var to func
 func F9(int) {}

 // both
 // OK, even though new S1 is incompatible with old S1 (see below)
 func F10(S1) {}

 //////////////// Structs

 // old
 type S1 struct {
 	A int
 	B string
 	C bool
 	d float32
 }

 // new
 type S1 = s1

 type s1 struct {
 	C chan int
 	// i S1.C: changed from bool to chan int
 	A int
 	// i S1.B: removed
 	// i S1: old is comparable, new is not
 	x []int
 	d float32
 	E bool
 	// c S1.E: added
 }

 // old
 type embed struct {
 	E string
 }

 type S2 struct {
 	A int
 	embed
 }

 // new
 type embedx struct {
 	E string
 }

 type S2 struct {
 	embedx // OK: the unexported embedded field changed names, but the exported field didn't
 	A      int
 }

 // both
 type F int

 // old
 type S3 struct {
 	A int
 	embed
 }

 // new
 type embed struct{ F int }

 type S3 struct {
 	// i S3.E: removed
 	embed
 	// c S3.F: added
 	A int
 }

 // old
 type embed2 struct {
 	embed3
 	F // shadows embed3.F
 }

 type embed3 struct {
 	F bool
 }

 type alias = struct{ D bool }

 type S4 struct {
 	int
 	*embed2
 	embed
 	E int // shadows embed.E
 	alias
 	A1
 	*S4
 }

 // new
 type S4 struct {
 	// OK: removed unexported fields
 	// D and F marked as added because they are now part of the immediate fields
 	D bool
 	// c S4.D: added
 	E int // OK: same as in old
 	F F
 	// c S4.F: added
 	A1  // OK: same
 	*S4 // OK: same (recursive embedding)
 }

 //// Difference between exported selectable fields and exported immediate fields.
 // both
 type S5 struct{ A int }

 // old
 // Exported immediate fields: A, S5
 // Exported selectable fields: A int, S5 S5
 type S6 struct {
 	S5 S5
 	A  int
 }

 // new
 // Exported immediate fields: S5
 // Exported selectable fields: A int, S5 S5.

 // i S6.A: removed
 type S6 struct {
 	S5
 }

 //// Ambiguous fields can exist; they just can't be selected.
 // both
 type (
 	embed7a struct{ E int }
 	embed7b struct{ E bool }
 )

 // old
 type S7 struct { // legal, but no selectable fields
 	embed7a
 	embed7b
 }

 // new
 type S7 struct {
 	embed7a
 	embed7b
 	// c S7.E: added
 	E string
 }

 //////////////// Method sets

 // old
 type SM struct {
 	embedm
 	Embedm
 }

 func (SM) V1() {}
 func (SM) V2() {}
 func (SM) V3() {}
 func (SM) V4() {}
 func (SM) v()  {}

 func (*SM) P1() {}
 func (*SM) P2() {}
 func (*SM) P3() {}
 func (*SM) P4() {}
 func (*SM) p()  {}

 type embedm int

 func (embedm) EV1()  {}
 func (embedm) EV2()  {}
 func (embedm) EV3()  {}
 func (*embedm) EP1() {}
 func (*embedm) EP2() {}
 func (*embedm) EP3() {}

 type Embedm struct {
 	A int
 }

 func (Embedm) FV()  {}
 func (*Embedm) FP() {}

 type RepeatEmbedm struct {
 	Embedm
 }

 // new
 type SM struct {
 	embedm2
 	embedm3
 	Embedm
 	// i SM.A: changed from int to bool
 }

 // c SMa: added
 type SMa = SM

 func (SM) V1() {} // OK: same

 // func (SM) V2() {}
 // i SM.V2: removed

 // i SM.V3: changed from func() to func(int)
 func (SM) V3(int) {}

 // c SM.V5: added
 func (SM) V5() {}

 func (SM) v(int) {} // OK: unexported method change
 func (SM) v2()   {} // OK: unexported method added

 func (*SM) P1() {} // OK: same
 //func (*SM) P2() {}
 // i (*SM).P2: removed

 // i (*SM).P3: changed from func() to func(int)
 func (*SMa) P3(int) {}

 // c (*SM).P5: added
 func (*SM) P5() {}

 // func (*SM) p() {}  // OK: unexported method removed

 // Changing from a value to a pointer receiver or vice versa
 // just looks like adding and removing a method.

 // i SM.V4: removed
 // i (*SM).V4: changed from func() to func(int)
 func (*SM) V4(int) {}

 // c SM.P4: added
 // P4 is not removed from (*SM) because value methods
 // are in the pointer method set.
 func (SM) P4() {}

 type embedm2 int

 // i embedm.EV1: changed from func() to func(int)
 func (embedm2) EV1(int) {}

 // i embedm.EV2, method set of SM: removed
 // i embedm.EV2, method set of *SM: removed

 // i (*embedm).EP2, method set of *SM: removed
 func (*embedm2) EP1() {}

 type embedm3 int

 func (embedm3) EV3()  {} // OK: compatible with old embedm.EV3
 func (*embedm3) EP3() {} // OK: compatible with old (*embedm).EP3

 type Embedm struct {
 	// i Embedm.A: changed from int to bool
 	A bool
 }

 // i Embedm.FV: changed from func() to func(int)
 func (Embedm) FV(int) {}
 func (*Embedm) FP()   {}

 type RepeatEmbedm struct {
 	// i RepeatEmbedm.A: changed from int to bool
 	Embedm
 }

 //////////////// Whole-package interface satisfaction

 // old
 type WI1 interface {
 	M1()
 	m1()
 }

 type WI2 interface {
 	M2()
 	m2()
 }

 type WS1 int

 func (WS1) M1() {}
 func (WS1) m1() {}

 type WS2 int

 func (WS2) M2() {}
 func (WS2) m2() {}

 // new
 type WI1 interface {
 	M1()
 	m()
 }

 type WS1 int

 func (WS1) M1() {}

 // i WS1: no longer implements WI1
 //func (WS1) m1() {}

 type WI2 interface {
 	M2()
 	m2()
 	// i WS2: no longer implements WI2
 	m3()
 }

 type WS2 int

 func (WS2) M2() {}
 func (WS2) m2() {}

 //////////////// Miscellany

 // This verifies that the code works even through
 // multiple levels of unexported typed.

 // old
 var Z w

 type w []x
 type x []z
 type z int

 // new
 var Z w

 type w []x
 type x []z

 // i z: changed from int to bool
 type z bool

 // old
 type H struct{}

 func (H) M() {}

 // new
 // i H: changed from struct{} to interface{M()}
 type H interface {
 	M()
 }

 //// Splitting types

 //// OK: in both old and new, {J1, K1, L1} name the same type.
 // old
 type (
 	J1 = K1
 	K1 = L1
 	L1 int
 )

 // new
 type (
 	J1 = K1
 	K1 int
 	L1 = J1
 )

 //// Old has one type, K2; new has J2 and K2.
 // both
 type K2 int

 // old
 type J2 = K2

 // new
 // i K2: changed from K2 to K2
 type J2 K2 // old K2 corresponds with new J2
 // old K2 also corresponds with new K2: problem

 // both
 type k3 int

 var Vj3 j3 // expose j3

 // old
 type j3 = k3

 // new
 // OK: k3 isn't exposed
 type j3 k3

 // both
 type k4 int

 var Vj4 j4 // expose j4
 var VK4 k4 // expose k4

 // old
 type j4 = k4

 // new
 // i Vj4: changed from k4 to j4
 // e.g. p.Vj4 = p.Vk4
 type j4 k4
	// This file is split into two packages, old and new.
	// It is syntactically valid Go so that gofmt can process it.
	//
	// If a comment begins with: Then:
	// old write subsequent lines to the "old" package
	// new write subsequent lines to the "new" package
	// both write subsequent lines to both packages
	// c expect a compatible error with the following text
	// i expect an incompatible error with the following text
	package ignore

	// both
	import "io"

	//////////////// Basics

	//// Same type in both: OK.
	// both
	type A int

	//// Changing the type is an incompatible change.
	// old
	type B int

	// new
	// i B: changed from int to string
	type B string

	//// Adding a new type, whether alias or not, is a compatible change.
	// new
	// c AA: added
	type AA = A

	// c B1: added
	type B1 bool

	//// Change of type for an unexported name doesn't matter...
	// old
	type t int

	// new
	type t string // OK: t isn't part of the API

	//// ...unless it is exposed.
	// both
	var V2 u

	// old
	type u string

	// new
	// i u: changed from string to int
	type u int

	//// An exposed, unexported type can be renamed.
	// both
	type u2 int

	// old
	type u1 int

	var V5 u1

	// new
	var V5 u2 // OK: V5 has changed type, but old u1 corresopnds to new u2

	//// Splitting a single type into two is an incompatible change.
	// both
	type u3 int

	// old
	type (
	Split1 = u1
	Split2 = u1
	)

	// new
	type (
	Split1 = u2 // OK, since old u1 corresponds to new u2

	// This tries to make u1 correspond to u3
	// i Split2: changed from u1 to u3
	Split2 = u3
	)

	//// Merging two types into one is OK.
	// old
	type (
	GoodMerge1 = u2
	GoodMerge2 = u3
	)

	// new
	type (
	GoodMerge1 = u3
	GoodMerge2 = u3
	)

	//// Merging isn't OK here because a method is lost.
	// both
	type u4 int

	func (u4) M() {}

	// old
	type (
	BadMerge1 = u3
	BadMerge2 = u4
	)

	// new
	type (
	BadMerge1 = u3
	// i u4.M: removed
	// What's really happening here is that old u4 corresponds to new u3,
	// and new u3's method set is not a superset of old u4's.
	BadMerge2 = u3
	)

	// old
	type Rem int

	// new
	// i Rem: removed

	//////////////// Constants

	//// type changes
	// old
	const (
	C1 = 1
	C2 int = 2
	C3 = 3
	C4 u1 = 4
	)

	var V8 int

	// new
	const (
	// i C1: changed from untyped int to untyped string
	C1 = "1"
	// i C2: changed from int to untyped int
	C2 = -1
	// i C3: changed from untyped int to int
	C3 int = 3
	// i V8: changed from var to const
	V8 int = 1
	C4 u2 = 4 // OK: u1 corresponds to u2
	)

	// value change
	// old
	const (
	Cr1 = 1
	Cr2 = "2"
	Cr3 = 3.5
	Cr4 = complex(0, 4.1)
	)

	// new
	const (
	// i Cr1: value changed from 1 to -1
	Cr1 = -1
	// i Cr2: value changed from "2" to "3"
	Cr2 = "3"
	// i Cr3: value changed from 3.5 to 3.8
	Cr3 = 3.8
	// i Cr4: value changed from (0 + 4.1i) to (4.1 + 0i)
	Cr4 = complex(4.1, 0)
	)

	//////////////// Variables

	//// simple type changes
	// old
	var (
	V1 string
	V3 A
	V7 <-chan int
	)

	// new
	var (
	// i V1: changed from string to []string
	V1 []string
	V3 A // OK: same
	// i V7: changed from <-chan int to chan int
	V7 chan int
	)

	//// interface type changes
	// old
	var (
	V9 interface{ M() }
	V10 interface{ M() }
	V11 interface{ M() }
	)

	// new
	var (
	// i V9: changed from interface{M()} to interface{}
	V9 interface{}
	// i V10: changed from interface{M()} to interface{M(); M2()}
	V10 interface {
	M2()
	M()
	}
	// i V11: changed from interface{M()} to interface{M(int)}
	V11 interface{ M(int) }
	)

	//// struct type changes
	// old
	var (
	VS1 struct{ A, B int }
	VS2 struct{ A, B int }
	VS3 struct{ A, B int }
	VS4 struct {
	A int
	u1
	}
	)

	// new
	var (
	// i VS1: changed from struct{A int; B int} to struct{B int; A int}
	VS1 struct{ B, A int }
	// i VS2: changed from struct{A int; B int} to struct{A int}
	VS2 struct{ A int }
	// i VS3: changed from struct{A int; B int} to struct{A int; B int; C int}
	VS3 struct{ A, B, C int }
	VS4 struct {
	A int
	u2
	}
	)

	//////////////// Types

	// old
	const C5 = 3

	type (
	A1 [1]int
	A2 [2]int
	A3 [C5]int
	)

	// new
	// i C5: value changed from 3 to 4
	const C5 = 4

	type (
	A1 [1]int
	// i A2: changed from [2]int to [2]bool
	A2 [2]bool
	// i A3: changed from [3]int to [4]int
	A3 [C5]int
	)

	// old
	type (
	Sl []int
	P1 *int
	P2 *u1
	)

	// new
	type (
	// i Sl: changed from []int to []string
	Sl []string
	// i P1: changed from int to *bool
	P1 **bool
	P2 *u2 // OK: u1 corresponds to u2
	)

	// old
	type Bc1 int32
	type Bc2 uint
	type Bc3 float32
	type Bc4 complex64

	// new
	// c Bc1: changed from int32 to int
	type Bc1 int

	// c Bc2: changed from uint to uint64
	type Bc2 uint64

	// c Bc3: changed from float32 to float64
	type Bc3 float64

	// c Bc4: changed from complex64 to complex128
	type Bc4 complex128

	// old
	type Bi1 int32
	type Bi2 uint
	type Bi3 float64
	type Bi4 complex128

	// new
	// i Bi1: changed from int32 to int16
	type Bi1 int16

	// i Bi2: changed from uint to uint32
	type Bi2 uint32

	// i Bi3: changed from float64 to float32
	type Bi3 float32

	// i Bi4: changed from complex128 to complex64
	type Bi4 complex64

	// old
	type (
	M1 map[string]int
	M2 map[string]int
	M3 map[string]int
	)

	// new
	type (
	M1 map[string]int
	// i M2: changed from map[string]int to map[int]int
	M2 map[int]int
	// i M3: changed from map[string]int to map[string]string
	M3 map[string]string
	)

	// old
	type (
	Ch1 chan int
	Ch2 <-chan int
	Ch3 chan int
	Ch4 <-chan int
	)

	// new
	type (
	// i Ch1, element type: changed from int to bool
	Ch1 chan bool
	// i Ch2: changed direction
	Ch2 chan<- int
	// i Ch3: changed direction
	Ch3 <-chan int
	// c Ch4: removed direction
	Ch4 chan int
	)

	// old
	type I1 interface {
	M1()
	M2()
	}

	// new
	type I1 interface {
	// M1()
	// i I1.M1: removed
	M2(int)
	// i I1.M2: changed from func() to func(int)
	M3()
	// i I1.M3: added
	m()
	// i I1.m: added unexported method
	}

	// old
	type I2 interface {
	M1()
	m()
	}

	// new
	type I2 interface {
	M1()
	// m() Removing an unexported method is OK.
	m2() // OK, because old already had an unexported method
	// c I2.M2: added
	M2()
	}

	// old
	type I3 interface {
	io.Reader
	M()
	}

	// new
	// OK: what matters is the method set; the name of the embedded
	// interface isn't important.
	type I3 interface {
	M()
	Read([]byte) (int, error)
	}

	// old
	type I4 io.Writer

	// new
	// OK: in both, I4 is a distinct type from io.Writer, and
	// the old and new I4s have the same method set.
	type I4 interface {
	Write([]byte) (int, error)
	}

	// old
	type I5 = io.Writer

	// new
	// i I5: changed from io.Writer to I5
	// In old, I5 and io.Writer are the same type; in new,
	// they are different. That can break something like:
	// var _ func(io.Writer) = func(pkg.I6) {}
	type I5 io.Writer

	// old
	type I6 interface{ Write([]byte) (int, error) }

	// new
	// i I6: changed from I6 to io.Writer
	// Similar to the above.
	type I6 = io.Writer

	//// correspondence with a basic type
	// Basic types are technically defined types, but they aren't
	// represented that way in go/types, so the cases below are special.

	// both
	type T1 int

	// old
	var VT1 T1

	// new
	// i VT1: changed from T1 to int
	// This fails because old T1 corresponds to both int and new T1.
	var VT1 int

	// old
	type t2 int

	var VT2 t2

	// new
	// OK: t2 corresponds to int. It's fine that old t2
	// doesn't exist in new.
	var VT2 int

	// both
	type t3 int

	func (t3) M() {}

	// old
	var VT3 t3

	// new
	// i t3.M: removed
	// Here the change from t3 to int is incompatible
	// because old t3 has an exported method.
	var VT3 int

	// old
	var VT4 int

	// new
	type t4 int

	// i VT4: changed from int to t4
	// This is incompatible because of code like
	// VT4 + int(1)
	// which works in old but fails in new.
	// The difference from the above cases is that
	// in those, we were merging two types into one;
	// here, we are splitting int into t4 and int.
	var VT4 t4

	//////////////// Functions

	// old
	func F1(a int, b string) map[u1]A { return nil }
	func F2(int) {}
	func F3(int) {}
	func F4(int) int { return 0 }
	func F5(int) int { return 0 }
	func F6(int) {}
	func F7(interface{}) {}

	// new
	func F1(c int, d string) map[u2]AA { return nil } //OK: same (since u1 corresponds to u2)

	// i F2: changed from func(int) to func(int) bool
	func F2(int) bool { return true }

	// i F3: changed from func(int) to func(int, int)
	func F3(int, int) {}

	// i F4: changed from func(int) int to func(bool) int
	func F4(bool) int { return 0 }

	// i F5: changed from func(int) int to func(int) string
	func F5(int) string { return "" }

	// i F6: changed from func(int) to func(...int)
	func F6(...int) {}

	// i F7: changed from func(interface{}) to func(interface{x()})
	func F7(a interface{ x() }) {}

	// old
	func F8(bool) {}

	// new
	// c F8: changed from func to var
	var F8 func(bool)

	// old
	var F9 func(int)

	// new
	// i F9: changed from var to func
	func F9(int) {}

	// both
	// OK, even though new S1 is incompatible with old S1 (see below)
	func F10(S1) {}

	//////////////// Structs

	// old
	type S1 struct {
	A int
	B string
	C bool
	d float32
	}

	// new
	type S1 = s1

	type s1 struct {
	C chan int
	// i S1.C: changed from bool to chan int
	A int
	// i S1.B: removed
	// i S1: old is comparable, new is not
	x []int
	d float32
	E bool
	// c S1.E: added
	}

	// old
	type embed struct {
	E string
	}

	type S2 struct {
	A int
	embed
	}

	// new
	type embedx struct {
	E string
	}

	type S2 struct {
	embedx // OK: the unexported embedded field changed names, but the exported field didn't
	A int
	}

	// both
	type F int

	// old
	type S3 struct {
	A int
	embed
	}

	// new
	type embed struct{ F int }

	type S3 struct {
	// i S3.E: removed
	embed
	// c S3.F: added
	A int
	}

	// old
	type embed2 struct {
	embed3
	F // shadows embed3.F
	}

	type embed3 struct {
	F bool
	}

	type alias = struct{ D bool }

	type S4 struct {
	int
	*embed2
	embed
	E int // shadows embed.E
	alias
	A1
	*S4
	}

	// new
	type S4 struct {
	// OK: removed unexported fields
	// D and F marked as added because they are now part of the immediate fields
	D bool
	// c S4.D: added
	E int // OK: same as in old
	F F
	// c S4.F: added
	A1 // OK: same
	*S4 // OK: same (recursive embedding)
	}

	//// Difference between exported selectable fields and exported immediate fields.
	// both
	type S5 struct{ A int }

	// old
	// Exported immediate fields: A, S5
	// Exported selectable fields: A int, S5 S5
	type S6 struct {
	S5 S5
	A int
	}

	// new
	// Exported immediate fields: S5
	// Exported selectable fields: A int, S5 S5.

	// i S6.A: removed
	type S6 struct {
	S5
	}

	//// Ambiguous fields can exist; they just can't be selected.
	// both
	type (
	embed7a struct{ E int }
	embed7b struct{ E bool }
	)

	// old
	type S7 struct { // legal, but no selectable fields
	embed7a
	embed7b
	}

	// new
	type S7 struct {
	embed7a
	embed7b
	// c S7.E: added
	E string
	}

	//////////////// Method sets

	// old
	type SM struct {
	embedm
	Embedm
	}

	func (SM) V1() {}
	func (SM) V2() {}
	func (SM) V3() {}
	func (SM) V4() {}
	func (SM) v() {}

	func (*SM) P1() {}
	func (*SM) P2() {}
	func (*SM) P3() {}
	func (*SM) P4() {}
	func (*SM) p() {}

	type embedm int

	func (embedm) EV1() {}
	func (embedm) EV2() {}
	func (embedm) EV3() {}
	func (*embedm) EP1() {}
	func (*embedm) EP2() {}
	func (*embedm) EP3() {}

	type Embedm struct {
	A int
	}

	func (Embedm) FV() {}
	func (*Embedm) FP() {}

	type RepeatEmbedm struct {
	Embedm
	}

	// new
	type SM struct {
	embedm2
	embedm3
	Embedm
	// i SM.A: changed from int to bool
	}

	// c SMa: added
	type SMa = SM

	func (SM) V1() {} // OK: same

	// func (SM) V2() {}
	// i SM.V2: removed

	// i SM.V3: changed from func() to func(int)
	func (SM) V3(int) {}

	// c SM.V5: added
	func (SM) V5() {}

	func (SM) v(int) {} // OK: unexported method change
	func (SM) v2() {} // OK: unexported method added

	func (*SM) P1() {} // OK: same
	//func (*SM) P2() {}
	// i (*SM).P2: removed

	// i (*SM).P3: changed from func() to func(int)
	func (*SMa) P3(int) {}

	// c (*SM).P5: added
	func (*SM) P5() {}

	// func (*SM) p() {} // OK: unexported method removed

	// Changing from a value to a pointer receiver or vice versa
	// just looks like adding and removing a method.

	// i SM.V4: removed
	// i (*SM).V4: changed from func() to func(int)
	func (*SM) V4(int) {}

	// c SM.P4: added
	// P4 is not removed from (*SM) because value methods
	// are in the pointer method set.
	func (SM) P4() {}

	type embedm2 int

	// i embedm.EV1: changed from func() to func(int)
	func (embedm2) EV1(int) {}

	// i embedm.EV2, method set of SM: removed
	// i embedm.EV2, method set of *SM: removed

	// i (embedm).EP2, method set of SM: removed
	func (*embedm2) EP1() {}

	type embedm3 int

	func (embedm3) EV3() {} // OK: compatible with old embedm.EV3
	func (embedm3) EP3() {} // OK: compatible with old (embedm).EP3

	type Embedm struct {
	// i Embedm.A: changed from int to bool
	A bool
	}

	// i Embedm.FV: changed from func() to func(int)
	func (Embedm) FV(int) {}
	func (*Embedm) FP() {}

	type RepeatEmbedm struct {
	// i RepeatEmbedm.A: changed from int to bool
	Embedm
	}

	//////////////// Whole-package interface satisfaction

	// old
	type WI1 interface {
	M1()
	m1()
	}

	type WI2 interface {
	M2()
	m2()
	}

	type WS1 int

	func (WS1) M1() {}
	func (WS1) m1() {}

	type WS2 int

	func (WS2) M2() {}
	func (WS2) m2() {}

	// new
	type WI1 interface {
	M1()
	m()
	}

	type WS1 int

	func (WS1) M1() {}

	// i WS1: no longer implements WI1
	//func (WS1) m1() {}

	type WI2 interface {
	M2()
	m2()
	// i WS2: no longer implements WI2
	m3()
	}

	type WS2 int

	func (WS2) M2() {}
	func (WS2) m2() {}

	//////////////// Miscellany

	// This verifies that the code works even through
	// multiple levels of unexported typed.

	// old
	var Z w

	type w []x
	type x []z
	type z int

	// new
	var Z w

	type w []x
	type x []z

	// i z: changed from int to bool
	type z bool

	// old
	type H struct{}

	func (H) M() {}

	// new
	// i H: changed from struct{} to interface{M()}
	type H interface {
	M()
	}

	//// Splitting types

	//// OK: in both old and new, {J1, K1, L1} name the same type.
	// old
	type (
	J1 = K1
	K1 = L1
	L1 int
	)

	// new
	type (
	J1 = K1
	K1 int
	L1 = J1
	)

	//// Old has one type, K2; new has J2 and K2.
	// both
	type K2 int

	// old
	type J2 = K2

	// new
	// i K2: changed from K2 to K2
	type J2 K2 // old K2 corresponds with new J2
	// old K2 also corresponds with new K2: problem

	// both
	type k3 int

	var Vj3 j3 // expose j3

	// old
	type j3 = k3

	// new
	// OK: k3 isn't exposed
	type j3 k3

	// both
	type k4 int

	var Vj4 j4 // expose j4
	var VK4 k4 // expose k4

	// old
	type j4 = k4

	// new
	// i Vj4: changed from k4 to j4
	// e.g. p.Vj4 = p.Vk4
	type j4 k4