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// RUN: %target-swift-frontend -O %s -emit-sil | %FileCheck %s
// Make sure that we can dig all the way through the class hierarchy and
// protocol conformances.
// CHECK-LABEL: sil @$s28devirt_inherited_conformance6driveryyF : $@convention(thin) () -> () {
// CHECK: bb0
// CHECK: [[UNKNOWN2a:%.*]] = function_ref @unknown2a : $@convention(thin) () -> ()
// CHECK: apply [[UNKNOWN2a]]
// CHECK: apply [[UNKNOWN2a]]
// CHECK: [[UNKNOWN3a:%.*]] = function_ref @unknown3a : $@convention(thin) () -> ()
// CHECK: apply [[UNKNOWN3a]]
// CHECK: apply [[UNKNOWN3a]]
// CHECK: return
@_silgen_name("unknown1a")
func unknown1a() -> ()
@_silgen_name("unknown1b")
func unknown1b() -> ()
@_silgen_name("unknown2a")
func unknown2a() -> ()
@_silgen_name("unknown2b")
func unknown2b() -> ()
@_silgen_name("unknown3a")
func unknown3a() -> ()
@_silgen_name("unknown3b")
func unknown3b() -> ()
struct Int32 {}
protocol P {
// We do not specialize typealias's correctly now.
//typealias X
func doSomething(_ x : Int32)
// This exposes a SILGen bug. FIXME: Fix up this test in the future.
// class func doSomethingMeta()
}
class B : P {
// We do not specialize typealias's correctly now.
//typealias X = B
func doSomething(_ x : Int32) {
unknown1a()
}
// See comment in protocol P
//class func doSomethingMeta() {
// unknown1b()
//}
}
class B2 : B {
// When we have covariance in protocols, change this to B2.
// We do not specialize typealias correctly now.
//typealias X = B
override func doSomething(_ x : Int32) {
unknown2a()
}
// See comment in protocol P
//override class func doSomethingMeta() {
// unknown2b()
//}
}
class B3 : B {
// When we have covariance in protocols, change this to B3.
// We do not specialize typealias correctly now.
//typealias X = B
override func doSomething(_ x : Int32) {
unknown3a()
}
// See comment in protocol P
//override class func doSomethingMeta() {
// unknown3b()
//}
}
func WhatShouldIDo<T : P>(_ t : T, _ x : Int32) {
t.doSomething(x)
}
func WhatShouldIDo2(_ p : P, _ x : Int32) {
p.doSomething(x)
}
public func driver() -> () {
let b2 = B2()
let b3 = B3()
let x = Int32()
WhatShouldIDo(b2, x)
WhatShouldIDo2(b2, x)
WhatShouldIDo(b3, x)
WhatShouldIDo2(b3, x)
}
// Test that inherited conformances work properly with
// standard operators like == and custom operators like ---
// Comparable is similar to Equatable, but uses a usual method
// instead of an operator.
public protocol Comparable {
func compare(_: Self, _: Self) -> Bool
}
// Define a custom operator to be used instead of ==
infix operator ---
// Simple is a protocol that simply defines an operator and
// a few methods with different number of arguments.
public protocol Simple {
func foo(_: Self) -> Bool
func boo(_: Self, _: Self) -> Bool
static func ---(_: Self, _: Self) -> Bool
}
public class C: Equatable, Comparable, Simple {
public func compare(_ c1:C, _ c2:C) -> Bool {
return c1 == c2
}
public func foo(_ c:C) -> Bool {
return true
}
public func boo(_ c1:C, _ c2:C) -> Bool {
return false
}
}
// D inherits a bunch of conformances from C.
// We want to check that compiler can handle
// them properly and is able to devirtualize
// them.
public class D: C {
}
public func ==(lhs: C, rhs: C) -> Bool {
return true
}
public func ---(lhs: C, rhs: C) -> Bool {
return true
}
public func compareEquals<T:Equatable>(_ x: T, _ y:T) -> Bool {
return x == y
}
public func compareMinMinMin<T:Simple>(_ x: T, _ y:T) -> Bool {
return x --- y
}
public func compareComparable<T:Comparable>(_ x: T, _ y:T) -> Bool {
return x.compare(x, y)
}
// Check that a call of inherited Equatable.== can be devirtualized.
// CHECK-LABEL: sil @$s28devirt_inherited_conformance17testCompareEqualsSbyF : $@convention(thin) () -> Bool {
// CHECK: bb0
// CHECK-NEXT: integer_literal $Builtin.Int1, -1
// CHECK-NEXT: struct $Bool
// CHECK: return
// CHECK: }
public func testCompareEquals() -> Bool {
return compareEquals(D(), D())
}
// Check that a call of inherited Simple.== can be devirtualized.
// CHECK-LABEL: sil @$s28devirt_inherited_conformance014testCompareMinfF0SbyF : $@convention(thin) () -> Bool {
// CHECK: bb0
// CHECK-NEXT: integer_literal $Builtin.Int1, -1
// CHECK-NEXT: struct $Bool
// CHECK: return
public func testCompareMinMinMin() -> Bool {
return compareMinMinMin(D(), D())
}
// Check that a call of inherited Comparable.== can be devirtualized.
// CHECK-LABEL: sil @$s28devirt_inherited_conformance21testCompareComparableSbyF : $@convention(thin) () -> Bool {
// CHECK: bb0
// CHECK-NEXT: integer_literal $Builtin.Int1, -1
// CHECK-NEXT: struct $Bool
// CHECK: return
public func testCompareComparable() -> Bool {
return compareComparable(D(), D())
}
public func BooCall<T:Simple>(_ x:T, _ y:T) -> Bool {
return x.boo(y, y)
}
// Check that a call of inherited Simple.boo can be devirtualized.
// CHECK-LABEL: sil @$s28devirt_inherited_conformance11testBooCallSbyF : $@convention(thin) () -> Bool {
// CHECK: bb0
// CHECK-NEXT: integer_literal $Builtin.Int1, 0
// CHECK-NEXT: struct $Bool
// CHECK: return
public func testBooCall() -> Bool {
return BooCall(D(), D())
}
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