File: uniqueSymbolsDeclarations.types

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=== tests/cases/conformance/types/uniqueSymbol/uniqueSymbolsDeclarations.ts ===
// declarations with call initializer
const constCall = Symbol();
>constCall : unique symbol
>Symbol() : unique symbol
>Symbol : SymbolConstructor

let letCall = Symbol();
>letCall : symbol
>Symbol() : symbol
>Symbol : SymbolConstructor

var varCall = Symbol();
>varCall : symbol
>Symbol() : symbol
>Symbol : SymbolConstructor

// ambient declaration with type
declare const constType: unique symbol;
>constType : unique symbol

// declaration with type and call initializer
const constTypeAndCall: unique symbol = Symbol();
>constTypeAndCall : unique symbol
>Symbol() : unique symbol
>Symbol : SymbolConstructor

// declaration from initializer
const constInitToConstCall = constCall;
>constInitToConstCall : symbol
>constCall : unique symbol

const constInitToLetCall = letCall;
>constInitToLetCall : symbol
>letCall : symbol

const constInitToVarCall = varCall;
>constInitToVarCall : symbol
>varCall : symbol

const constInitToConstDeclAmbient = constType;
>constInitToConstDeclAmbient : symbol
>constType : unique symbol

let letInitToConstCall = constCall;
>letInitToConstCall : symbol
>constCall : unique symbol

let letInitToLetCall = letCall;
>letInitToLetCall : symbol
>letCall : symbol

let letInitToVarCall = varCall;
>letInitToVarCall : symbol
>varCall : symbol

let letInitToConstDeclAmbient = constType;
>letInitToConstDeclAmbient : symbol
>constType : unique symbol

var varInitToConstCall = constCall;
>varInitToConstCall : symbol
>constCall : unique symbol

var varInitToLetCall = letCall;
>varInitToLetCall : symbol
>letCall : symbol

var varInitToVarCall = varCall;
>varInitToVarCall : symbol
>varCall : symbol

var varInitToConstDeclAmbient = constType;
>varInitToConstDeclAmbient : symbol
>constType : unique symbol

// declaration from initializer with type query
const constInitToConstCallWithTypeQuery: typeof constCall = constCall;
>constInitToConstCallWithTypeQuery : unique symbol
>constCall : unique symbol
>constCall : unique symbol

const constInitToConstDeclAmbientWithTypeQuery: typeof constType = constType;
>constInitToConstDeclAmbientWithTypeQuery : unique symbol
>constType : unique symbol
>constType : unique symbol

// function return inference
function funcReturnConstCall() { return constCall; }
>funcReturnConstCall : () => symbol
>constCall : unique symbol

function funcReturnLetCall() { return letCall; }
>funcReturnLetCall : () => symbol
>letCall : symbol

function funcReturnVarCall() { return varCall; }
>funcReturnVarCall : () => symbol
>varCall : symbol

// function return value with type query
function funcReturnConstCallWithTypeQuery(): typeof constCall { return constCall; }
>funcReturnConstCallWithTypeQuery : () => typeof constCall
>constCall : unique symbol
>constCall : unique symbol

// generator function yield inference
function* genFuncYieldConstCall() { yield constCall; }
>genFuncYieldConstCall : () => Generator<symbol, void, unknown>
>yield constCall : any
>constCall : unique symbol

function* genFuncYieldLetCall() { yield letCall; }
>genFuncYieldLetCall : () => Generator<symbol, void, unknown>
>yield letCall : any
>letCall : symbol

function* genFuncYieldVarCall() { yield varCall; }
>genFuncYieldVarCall : () => Generator<symbol, void, unknown>
>yield varCall : any
>varCall : symbol

// generator function yield with return type query
function* genFuncYieldConstCallWithTypeQuery(): IterableIterator<typeof constCall> { yield constCall; }
>genFuncYieldConstCallWithTypeQuery : () => IterableIterator<typeof constCall>
>constCall : unique symbol
>yield constCall : undefined
>constCall : unique symbol

// async function return inference
async function asyncFuncReturnConstCall() { return constCall; }
>asyncFuncReturnConstCall : () => Promise<symbol>
>constCall : unique symbol

async function asyncFuncReturnLetCall() { return letCall; }
>asyncFuncReturnLetCall : () => Promise<symbol>
>letCall : symbol

async function asyncFuncReturnVarCall() { return varCall; }
>asyncFuncReturnVarCall : () => Promise<symbol>
>varCall : symbol

// async generator function yield inference
async function* asyncGenFuncYieldConstCall() { yield constCall; }
>asyncGenFuncYieldConstCall : () => AsyncGenerator<symbol, void, unknown>
>yield constCall : any
>constCall : unique symbol

async function* asyncGenFuncYieldLetCall() { yield letCall; }
>asyncGenFuncYieldLetCall : () => AsyncGenerator<symbol, void, unknown>
>yield letCall : any
>letCall : symbol

async function* asyncGenFuncYieldVarCall() { yield varCall; }
>asyncGenFuncYieldVarCall : () => AsyncGenerator<symbol, void, unknown>
>yield varCall : any
>varCall : symbol

// classes
class C {
>C : C

    static readonly readonlyStaticCall = Symbol();
>readonlyStaticCall : unique symbol
>Symbol() : unique symbol
>Symbol : SymbolConstructor

    static readonly readonlyStaticType: unique symbol;
>readonlyStaticType : unique symbol

    static readonly readonlyStaticTypeAndCall: unique symbol = Symbol();
>readonlyStaticTypeAndCall : unique symbol
>Symbol() : unique symbol
>Symbol : SymbolConstructor

    static readwriteStaticCall = Symbol();
>readwriteStaticCall : symbol
>Symbol() : symbol
>Symbol : SymbolConstructor

    readonly readonlyCall = Symbol();
>readonlyCall : symbol
>Symbol() : symbol
>Symbol : SymbolConstructor

    readwriteCall = Symbol();
>readwriteCall : symbol
>Symbol() : symbol
>Symbol : SymbolConstructor
}
declare const c: C;
>c : C

const constInitToCReadonlyStaticCall = C.readonlyStaticCall;
>constInitToCReadonlyStaticCall : symbol
>C.readonlyStaticCall : unique symbol
>C : typeof C
>readonlyStaticCall : unique symbol

const constInitToCReadonlyStaticType = C.readonlyStaticType;
>constInitToCReadonlyStaticType : symbol
>C.readonlyStaticType : unique symbol
>C : typeof C
>readonlyStaticType : unique symbol

const constInitToCReadonlyStaticTypeAndCall = C.readonlyStaticTypeAndCall;
>constInitToCReadonlyStaticTypeAndCall : symbol
>C.readonlyStaticTypeAndCall : unique symbol
>C : typeof C
>readonlyStaticTypeAndCall : unique symbol

const constInitToCReadwriteStaticCall = C.readwriteStaticCall;
>constInitToCReadwriteStaticCall : symbol
>C.readwriteStaticCall : symbol
>C : typeof C
>readwriteStaticCall : symbol

const constInitToCReadonlyStaticCallWithTypeQuery: typeof C.readonlyStaticCall = C.readonlyStaticCall;
>constInitToCReadonlyStaticCallWithTypeQuery : unique symbol
>C.readonlyStaticCall : unique symbol
>C : typeof C
>readonlyStaticCall : unique symbol
>C.readonlyStaticCall : unique symbol
>C : typeof C
>readonlyStaticCall : unique symbol

const constInitToCReadonlyStaticTypeWithTypeQuery: typeof C.readonlyStaticType = C.readonlyStaticType;
>constInitToCReadonlyStaticTypeWithTypeQuery : unique symbol
>C.readonlyStaticType : unique symbol
>C : typeof C
>readonlyStaticType : unique symbol
>C.readonlyStaticType : unique symbol
>C : typeof C
>readonlyStaticType : unique symbol

const constInitToCReadonlyStaticTypeAndCallWithTypeQuery: typeof C.readonlyStaticTypeAndCall = C.readonlyStaticTypeAndCall;
>constInitToCReadonlyStaticTypeAndCallWithTypeQuery : unique symbol
>C.readonlyStaticTypeAndCall : unique symbol
>C : typeof C
>readonlyStaticTypeAndCall : unique symbol
>C.readonlyStaticTypeAndCall : unique symbol
>C : typeof C
>readonlyStaticTypeAndCall : unique symbol

const constInitToCReadwriteStaticCallWithTypeQuery: typeof C.readwriteStaticCall = C.readwriteStaticCall;
>constInitToCReadwriteStaticCallWithTypeQuery : symbol
>C.readwriteStaticCall : symbol
>C : typeof C
>readwriteStaticCall : symbol
>C.readwriteStaticCall : symbol
>C : typeof C
>readwriteStaticCall : symbol

const constInitToCReadonlyCall = c.readonlyCall;
>constInitToCReadonlyCall : symbol
>c.readonlyCall : symbol
>c : C
>readonlyCall : symbol

const constInitToCReadwriteCall = c.readwriteCall;
>constInitToCReadwriteCall : symbol
>c.readwriteCall : symbol
>c : C
>readwriteCall : symbol

const constInitToCReadonlyCallWithTypeQuery: typeof c.readonlyCall = c.readonlyCall;
>constInitToCReadonlyCallWithTypeQuery : symbol
>c.readonlyCall : symbol
>c : C
>readonlyCall : symbol
>c.readonlyCall : symbol
>c : C
>readonlyCall : symbol

const constInitToCReadwriteCallWithTypeQuery: typeof c.readwriteCall = c.readwriteCall;
>constInitToCReadwriteCallWithTypeQuery : symbol
>c.readwriteCall : symbol
>c : C
>readwriteCall : symbol
>c.readwriteCall : symbol
>c : C
>readwriteCall : symbol

const constInitToCReadonlyCallWithIndexedAccess: C["readonlyCall"] = c.readonlyCall;
>constInitToCReadonlyCallWithIndexedAccess : symbol
>c.readonlyCall : symbol
>c : C
>readonlyCall : symbol

const constInitToCReadwriteCallWithIndexedAccess: C["readwriteCall"] = c.readwriteCall;
>constInitToCReadwriteCallWithIndexedAccess : symbol
>c.readwriteCall : symbol
>c : C
>readwriteCall : symbol

// interfaces
interface I {
    readonly readonlyType: unique symbol;
>readonlyType : unique symbol
}
declare const i: I;
>i : I

const constInitToIReadonlyType = i.readonlyType;
>constInitToIReadonlyType : symbol
>i.readonlyType : unique symbol
>i : I
>readonlyType : unique symbol

const constInitToIReadonlyTypeWithTypeQuery: typeof i.readonlyType = i.readonlyType;
>constInitToIReadonlyTypeWithTypeQuery : unique symbol
>i.readonlyType : unique symbol
>i : I
>readonlyType : unique symbol
>i.readonlyType : unique symbol
>i : I
>readonlyType : unique symbol

const constInitToIReadonlyTypeWithIndexedAccess: I["readonlyType"] = i.readonlyType;
>constInitToIReadonlyTypeWithIndexedAccess : unique symbol
>i.readonlyType : unique symbol
>i : I
>readonlyType : unique symbol

// type literals
type L = {
>L : { readonly readonlyType: unique symbol; nested: {    readonly readonlyNestedType: unique symbol;}; }

    readonly readonlyType: unique symbol;
>readonlyType : unique symbol

    nested: {
>nested : { readonly readonlyNestedType: unique symbol; }

        readonly readonlyNestedType: unique symbol;
>readonlyNestedType : unique symbol
    }
};
declare const l: L;
>l : L

const constInitToLReadonlyType = l.readonlyType;
>constInitToLReadonlyType : symbol
>l.readonlyType : unique symbol
>l : L
>readonlyType : unique symbol

const constInitToLReadonlyNestedType = l.nested.readonlyNestedType;
>constInitToLReadonlyNestedType : symbol
>l.nested.readonlyNestedType : unique symbol
>l.nested : { readonly readonlyNestedType: unique symbol; }
>l : L
>nested : { readonly readonlyNestedType: unique symbol; }
>readonlyNestedType : unique symbol

const constInitToLReadonlyTypeWithTypeQuery: typeof l.readonlyType = l.readonlyType;
>constInitToLReadonlyTypeWithTypeQuery : unique symbol
>l.readonlyType : unique symbol
>l : L
>readonlyType : unique symbol
>l.readonlyType : unique symbol
>l : L
>readonlyType : unique symbol

const constInitToLReadonlyNestedTypeWithTypeQuery: typeof l.nested.readonlyNestedType = l.nested.readonlyNestedType;
>constInitToLReadonlyNestedTypeWithTypeQuery : unique symbol
>l.nested.readonlyNestedType : unique symbol
>l.nested : { readonly readonlyNestedType: unique symbol; }
>l : L
>nested : { readonly readonlyNestedType: unique symbol; }
>readonlyNestedType : unique symbol
>l.nested.readonlyNestedType : unique symbol
>l.nested : { readonly readonlyNestedType: unique symbol; }
>l : L
>nested : { readonly readonlyNestedType: unique symbol; }
>readonlyNestedType : unique symbol

const constInitToLReadonlyTypeWithIndexedAccess: L["readonlyType"] = l.readonlyType;
>constInitToLReadonlyTypeWithIndexedAccess : unique symbol
>l.readonlyType : unique symbol
>l : L
>readonlyType : unique symbol

const constInitToLReadonlyNestedTypeWithIndexedAccess: L["nested"]["readonlyNestedType"] = l.nested.readonlyNestedType;
>constInitToLReadonlyNestedTypeWithIndexedAccess : unique symbol
>l.nested.readonlyNestedType : unique symbol
>l.nested : { readonly readonlyNestedType: unique symbol; }
>l : L
>nested : { readonly readonlyNestedType: unique symbol; }
>readonlyNestedType : unique symbol

// type argument inference
const promiseForConstCall = Promise.resolve(constCall);
>promiseForConstCall : Promise<unique symbol>
>Promise.resolve(constCall) : Promise<unique symbol>
>Promise.resolve : { (): Promise<void>; <T>(value: T): Promise<Awaited<T>>; <T>(value: T | PromiseLike<T>): Promise<Awaited<T>>; }
>Promise : PromiseConstructor
>resolve : { (): Promise<void>; <T>(value: T): Promise<Awaited<T>>; <T>(value: T | PromiseLike<T>): Promise<Awaited<T>>; }
>constCall : unique symbol

const arrayOfConstCall = [constCall];
>arrayOfConstCall : symbol[]
>[constCall] : symbol[]
>constCall : unique symbol

// unique symbol widening in expressions
declare const s: unique symbol;
>s : unique symbol

declare namespace N { const s: unique symbol; }
>N : typeof N
>s : unique symbol

declare const o: { [s]: "a", [N.s]: "b" };
>o : { [s]: "a"; [N.s]: "b"; }
>[s] : "a"
>s : unique symbol
>[N.s] : "b"
>N.s : unique symbol
>N : typeof N
>s : unique symbol

declare function f<T>(x: T): T;
>f : <T>(x: T) => T
>x : T

declare function g(x: typeof s): void;
>g : { (x: typeof s): void; (x: unique symbol): void; }
>x : unique symbol
>s : unique symbol

declare function g(x: typeof N.s): void;
>g : { (x: unique symbol): void; (x: typeof N.s): void; }
>x : unique symbol
>N.s : unique symbol
>N : typeof N
>s : unique symbol

// widening positions

// argument inference
f(s);
>f(s) : unique symbol
>f : <T>(x: T) => T
>s : unique symbol

f(N.s);
>f(N.s) : unique symbol
>f : <T>(x: T) => T
>N.s : unique symbol
>N : typeof N
>s : unique symbol

f(N["s"]);
>f(N["s"]) : unique symbol
>f : <T>(x: T) => T
>N["s"] : unique symbol
>N : typeof N
>"s" : "s"

// array literal elements
[s];
>[s] : symbol[]
>s : unique symbol

[N.s];
>[N.s] : symbol[]
>N.s : unique symbol
>N : typeof N
>s : unique symbol

[N["s"]];
>[N["s"]] : symbol[]
>N["s"] : unique symbol
>N : typeof N
>"s" : "s"

// property assignments/methods
const o2 = {
>o2 : { a: symbol; b: symbol; c: symbol; method1(): symbol; method2(): Promise<symbol>; method3(): AsyncGenerator<symbol, void, unknown>; method4(): Generator<symbol, void, unknown>; method5(p?: symbol): symbol; }
>{    a: s,    b: N.s,    c: N["s"],    method1() { return s; },    async method2() { return s; },    async * method3() { yield s; },    * method4() { yield s; },    method5(p = s) { return p; }} : { a: symbol; b: symbol; c: symbol; method1(): symbol; method2(): Promise<symbol>; method3(): AsyncGenerator<symbol, void, unknown>; method4(): Generator<symbol, void, unknown>; method5(p?: symbol): symbol; }

    a: s,
>a : symbol
>s : unique symbol

    b: N.s,
>b : symbol
>N.s : unique symbol
>N : typeof N
>s : unique symbol

    c: N["s"],
>c : symbol
>N["s"] : unique symbol
>N : typeof N
>"s" : "s"

    method1() { return s; },
>method1 : () => symbol
>s : unique symbol

    async method2() { return s; },
>method2 : () => Promise<symbol>
>s : unique symbol

    async * method3() { yield s; },
>method3 : () => AsyncGenerator<symbol, void, unknown>
>yield s : any
>s : unique symbol

    * method4() { yield s; },
>method4 : () => Generator<symbol, void, unknown>
>yield s : any
>s : unique symbol

    method5(p = s) { return p; }
>method5 : (p?: symbol) => symbol
>p : symbol
>s : unique symbol
>p : symbol

};

// property initializers
class C0 {
>C0 : C0

    static readonly a = s;
>a : symbol
>s : unique symbol

    static readonly b = N.s;
>b : symbol
>N.s : unique symbol
>N : typeof N
>s : unique symbol

    static readonly c = N["s"];
>c : symbol
>N["s"] : unique symbol
>N : typeof N
>"s" : "s"

    static d = s;
>d : symbol
>s : unique symbol

    static e = N.s;
>e : symbol
>N.s : unique symbol
>N : typeof N
>s : unique symbol

    static f = N["s"];
>f : symbol
>N["s"] : unique symbol
>N : typeof N
>"s" : "s"

    readonly a = s;
>a : symbol
>s : unique symbol

    readonly b = N.s;
>b : symbol
>N.s : unique symbol
>N : typeof N
>s : unique symbol

    readonly c = N["s"];
>c : symbol
>N["s"] : unique symbol
>N : typeof N
>"s" : "s"

    d = s;
>d : symbol
>s : unique symbol

    e = N.s;
>e : symbol
>N.s : unique symbol
>N : typeof N
>s : unique symbol

    f = N["s"];
>f : symbol
>N["s"] : unique symbol
>N : typeof N
>"s" : "s"

    method1() { return s; }
>method1 : () => symbol
>s : unique symbol

    async method2() { return s; }
>method2 : () => Promise<symbol>
>s : unique symbol

    async * method3() { yield s; }
>method3 : () => AsyncGenerator<symbol, void, unknown>
>yield s : any
>s : unique symbol

    * method4() { yield s; }
>method4 : () => Generator<symbol, void, unknown>
>yield s : any
>s : unique symbol

    method5(p = s) { return p; }
>method5 : (p?: symbol) => symbol
>p : symbol
>s : unique symbol
>p : symbol
}

// non-widening positions

// element access
o[s];
>o[s] : "a"
>o : { [s]: "a"; [N.s]: "b"; }
>s : unique symbol

o[N.s];
>o[N.s] : "b"
>o : { [s]: "a"; [N.s]: "b"; }
>N.s : unique symbol
>N : typeof N
>s : unique symbol

o[N["s"]];
>o[N["s"]] : "b"
>o : { [s]: "a"; [N.s]: "b"; }
>N["s"] : unique symbol
>N : typeof N
>"s" : "s"

// arguments (no-inference)
f<typeof s>(s);
>f<typeof s>(s) : unique symbol
>f : <T>(x: T) => T
>s : unique symbol
>s : unique symbol

f<typeof N.s>(N.s);
>f<typeof N.s>(N.s) : unique symbol
>f : <T>(x: T) => T
>N.s : unique symbol
>N : typeof N
>s : unique symbol
>N.s : unique symbol
>N : typeof N
>s : unique symbol

f<typeof N.s>(N["s"]);
>f<typeof N.s>(N["s"]) : unique symbol
>f : <T>(x: T) => T
>N.s : unique symbol
>N : typeof N
>s : unique symbol
>N["s"] : unique symbol
>N : typeof N
>"s" : "s"

g(s);
>g(s) : void
>g : { (x: unique symbol): void; (x: unique symbol): void; }
>s : unique symbol

g(N.s);
>g(N.s) : void
>g : { (x: unique symbol): void; (x: unique symbol): void; }
>N.s : unique symbol
>N : typeof N
>s : unique symbol

g(N["s"]);
>g(N["s"]) : void
>g : { (x: unique symbol): void; (x: unique symbol): void; }
>N["s"] : unique symbol
>N : typeof N
>"s" : "s"

// falsy expressions
s || "";
>s || "" : "" | unique symbol
>s : unique symbol
>"" : ""

N.s || "";
>N.s || "" : "" | unique symbol
>N.s : unique symbol
>N : typeof N
>s : unique symbol
>"" : ""

N["s"] || "";
>N["s"] || "" : "" | unique symbol
>N["s"] : unique symbol
>N : typeof N
>"s" : "s"
>"" : ""

// conditionals
Math.random() * 2 ? s : "a";
>Math.random() * 2 ? s : "a" : unique symbol | "a"
>Math.random() * 2 : number
>Math.random() : number
>Math.random : () => number
>Math : Math
>random : () => number
>2 : 2
>s : unique symbol
>"a" : "a"

Math.random() * 2 ? N.s : "a";
>Math.random() * 2 ? N.s : "a" : unique symbol | "a"
>Math.random() * 2 : number
>Math.random() : number
>Math.random : () => number
>Math : Math
>random : () => number
>2 : 2
>N.s : unique symbol
>N : typeof N
>s : unique symbol
>"a" : "a"

Math.random() * 2 ? N["s"] : "a";
>Math.random() * 2 ? N["s"] : "a" : unique symbol | "a"
>Math.random() * 2 : number
>Math.random() : number
>Math.random : () => number
>Math : Math
>random : () => number
>2 : 2
>N["s"] : unique symbol
>N : typeof N
>"s" : "s"
>"a" : "a"

// computed property names
({
>({    [s]: "a",    [N.s]: "b",}) : { [s]: string; [N.s]: string; }
>{    [s]: "a",    [N.s]: "b",} : { [s]: string; [N.s]: string; }

    [s]: "a",
>[s] : string
>s : unique symbol
>"a" : "a"

    [N.s]: "b",
>[N.s] : string
>N.s : unique symbol
>N : typeof N
>s : unique symbol
>"b" : "b"

});

class C1 {
>C1 : C1

    static [s]: "a";
>[s] : "a"
>s : unique symbol

    static [N.s]: "b";
>[N.s] : "b"
>N.s : unique symbol
>N : typeof N
>s : unique symbol

    [s]: "a";
>[s] : "a"
>s : unique symbol

    [N.s]: "b";
>[N.s] : "b"
>N.s : unique symbol
>N : typeof N
>s : unique symbol
}

// contextual types

interface Context {
    method1(): typeof s;
>method1 : () => typeof s
>s : unique symbol

    method2(): Promise<typeof s>;
>method2 : () => Promise<typeof s>
>s : unique symbol

    method3(): AsyncIterableIterator<typeof s>;
>method3 : () => AsyncIterableIterator<typeof s>
>s : unique symbol

    method4(): IterableIterator<typeof s>;
>method4 : () => IterableIterator<typeof s>
>s : unique symbol

    method5(p?: typeof s): typeof s;
>method5 : (p?: typeof s) => typeof s
>p : unique symbol
>s : unique symbol
>s : unique symbol
}

const o4: Context = {
>o4 : Context
>{    method1() {        return s; // return type should not widen due to contextual type    },    async method2() {        return s; // return type should not widen due to contextual type    },    async * method3() {        yield s; // yield type should not widen due to contextual type    },    * method4() {        yield s; // yield type should not widen due to contextual type    },    method5(p = s) { // parameter should not widen due to contextual type        return p;    }} : { method1(): unique symbol; method2(): Promise<unique symbol>; method3(): AsyncGenerator<unique symbol, void, undefined>; method4(): Generator<unique symbol, void, undefined>; method5(p?: unique symbol): unique symbol; }

    method1() {
>method1 : () => unique symbol

        return s; // return type should not widen due to contextual type
>s : unique symbol

    },
    async method2() {
>method2 : () => Promise<unique symbol>

        return s; // return type should not widen due to contextual type
>s : unique symbol

    },
    async * method3() {
>method3 : () => AsyncGenerator<unique symbol, void, undefined>

        yield s; // yield type should not widen due to contextual type
>yield s : undefined
>s : unique symbol

    },
    * method4() {
>method4 : () => Generator<unique symbol, void, undefined>

        yield s; // yield type should not widen due to contextual type
>yield s : undefined
>s : unique symbol

    },
    method5(p = s) { // parameter should not widen due to contextual type
>method5 : (p?: unique symbol) => unique symbol
>p : unique symbol
>s : unique symbol

        return p;
>p : unique symbol
    }
};