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v8/test/torque/test-torque.tq
Sigurd Schneider 4d05884e7f [torque] Introduce @abstract annotation for Torque classes 
This annotation indicates that the class itself is not instantiated,
and does not have its own instance type: The instance types that
logically belong to the class are the instance types of the derived
classes.

Currently, we need the indication @dirtyInstantiatedAbstractClass
for several classes that are used as both, abstract base classes
and concrete classes. The prime example is JSObject which is the
base for many other classes, and also serves as the class to allocate
plain JSObjects. The annotation is purposefully ugly because in the
future we should refactor code to make it unnecessary.

Another annotation we introduce is @hasSameInstanceTypeAsParent,
which indicates another design pattern that currently occurs in the
code-base: Some Torque classes have the same instance types as their
parent class, but rename some fields, or possibly have a different map.
In such cases, the parent class is not abstract and the derived classes
can be seen as refinements of this class (that, for example, narrows the
type of a field). In the future, Torque should accomodate this pattern
better, but at moment we are content with just indicating where it is
used.

Bug: v8:7793
Change-Id: I1892dcc7325250df75d80308bf3d767d6d43bcc2
Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/1607761
Commit-Queue: Sigurd Schneider <sigurds@chromium.org>
Reviewed-by: Tobias Tebbi <tebbi@chromium.org>
Cr-Commit-Position: refs/heads/master@{#61495}
2019-05-14 16:58:53 +00:00

916 lines
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// Copyright 2018 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
namespace test {
macro ElementsKindTestHelper1(kind: constexpr ElementsKind): bool {
if constexpr ((kind == UINT8_ELEMENTS) || (kind == UINT16_ELEMENTS)) {
return true;
} else {
return false;
}
}
macro ElementsKindTestHelper2(kind: constexpr ElementsKind): bool {
return ((kind == UINT8_ELEMENTS) || (kind == UINT16_ELEMENTS));
}
macro ElementsKindTestHelper3(kind: constexpr ElementsKind): constexpr bool {
return ((kind == UINT8_ELEMENTS) || (kind == UINT16_ELEMENTS));
}
macro LabelTestHelper1(): never
labels Label1 {
goto Label1;
}
macro LabelTestHelper2(): never
labels Label2(Smi) {
goto Label2(42);
}
macro LabelTestHelper3(): never
labels Label3(Oddball, Smi) {
goto Label3(Null, 7);
}
macro TestConstexpr1() {
check(FromConstexpr<bool>(IsFastElementsKind(PACKED_SMI_ELEMENTS)));
}
macro TestConstexprIf() {
check(ElementsKindTestHelper1(UINT8_ELEMENTS));
check(ElementsKindTestHelper1(UINT16_ELEMENTS));
check(!ElementsKindTestHelper1(UINT32_ELEMENTS));
}
macro TestConstexprReturn() {
check(FromConstexpr<bool>(ElementsKindTestHelper3(UINT8_ELEMENTS)));
check(FromConstexpr<bool>(ElementsKindTestHelper3(UINT16_ELEMENTS)));
check(!FromConstexpr<bool>(ElementsKindTestHelper3(UINT32_ELEMENTS)));
check(FromConstexpr<bool>(!ElementsKindTestHelper3(UINT32_ELEMENTS)));
}
macro TestGotoLabel(): Boolean {
try {
LabelTestHelper1() otherwise Label1;
}
label Label1 {
return True;
}
}
macro TestGotoLabelWithOneParameter(): Boolean {
try {
LabelTestHelper2() otherwise Label2;
}
label Label2(smi: Smi) {
check(smi == 42);
return True;
}
}
macro TestGotoLabelWithTwoParameters(): Boolean {
try {
LabelTestHelper3() otherwise Label3;
}
label Label3(o: Oddball, smi: Smi) {
check(o == Null);
check(smi == 7);
return True;
}
}
builtin GenericBuiltinTest<T: type>(c: Context, param: T): Object {
return Null;
}
GenericBuiltinTest<Object>(c: Context, param: Object): Object {
return param;
}
macro TestBuiltinSpecialization(c: Context) {
check(GenericBuiltinTest<Smi>(c, 0) == Null);
check(GenericBuiltinTest<Smi>(c, 1) == Null);
check(GenericBuiltinTest<Object>(c, Undefined) == Undefined);
check(GenericBuiltinTest<Object>(c, Undefined) == Undefined);
}
macro LabelTestHelper4(flag: constexpr bool): never
labels Label4, Label5 {
if constexpr (flag) {
goto Label4;
} else {
goto Label5;
}
}
macro CallLabelTestHelper4(flag: constexpr bool): bool {
try {
LabelTestHelper4(flag) otherwise Label4, Label5;
}
label Label4 {
return true;
}
label Label5 {
return false;
}
}
macro TestPartiallyUnusedLabel(): Boolean {
let r1: bool = CallLabelTestHelper4(true);
let r2: bool = CallLabelTestHelper4(false);
if (r1 && !r2) {
return True;
} else {
return False;
}
}
macro GenericMacroTest<T: type>(param: T): Object {
return Undefined;
}
GenericMacroTest<Object>(param2: Object): Object {
return param2;
}
macro GenericMacroTestWithLabels<T: type>(param: T): Object
labels X {
return Undefined;
}
GenericMacroTestWithLabels<Object>(param2: Object): Object
labels Y {
return Cast<Smi>(param2) otherwise Y;
}
macro TestMacroSpecialization() {
try {
const smi0: Smi = 0;
check(GenericMacroTest<Smi>(0) == Undefined);
check(GenericMacroTest<Smi>(1) == Undefined);
check(GenericMacroTest<Object>(Null) == Null);
check(GenericMacroTest<Object>(False) == False);
check(GenericMacroTest<Object>(True) == True);
check((GenericMacroTestWithLabels<Smi>(0) otherwise Fail) == Undefined);
check((GenericMacroTestWithLabels<Smi>(0) otherwise Fail) == Undefined);
try {
GenericMacroTestWithLabels<Object>(False) otherwise Expected;
}
label Expected {}
}
label Fail {
unreachable;
}
}
builtin TestHelperPlus1(context: Context, x: Smi): Smi {
return x + 1;
}
builtin TestHelperPlus2(context: Context, x: Smi): Smi {
return x + 2;
}
macro TestFunctionPointers(implicit context: Context)(): Boolean {
let fptr: builtin(Context, Smi) => Smi = TestHelperPlus1;
check(fptr(context, 42) == 43);
fptr = TestHelperPlus2;
check(fptr(context, 42) == 44);
return True;
}
macro TestVariableRedeclaration(implicit context: Context)(): Boolean {
let var1: int31 = FromConstexpr<bool>(42 == 0) ? 0 : 1;
let var2: int31 = FromConstexpr<bool>(42 == 0) ? 1 : 0;
return True;
}
macro TestTernaryOperator(x: Smi): Smi {
let b: bool = x < 0 ? true : false;
return b ? x - 10 : x + 100;
}
macro TestFunctionPointerToGeneric(c: Context) {
let fptr1: builtin(Context, Smi) => Object = GenericBuiltinTest<Smi>;
let fptr2: builtin(Context, Object) => Object = GenericBuiltinTest<Object>;
check(fptr1(c, 0) == Null);
check(fptr1(c, 1) == Null);
check(fptr2(c, Undefined) == Undefined);
check(fptr2(c, Undefined) == Undefined);
}
type ObjectToObject = builtin(Context, Object) => Object;
macro TestTypeAlias(x: ObjectToObject): BuiltinPtr {
return x;
}
macro TestUnsafeCast(implicit context: Context)(n: Number): Boolean {
if (TaggedIsSmi(n)) {
let m: Smi = UnsafeCast<Smi>(n);
check(TestHelperPlus1(context, m) == 11);
return True;
}
return False;
}
macro TestHexLiteral() {
check(Convert<intptr>(0xffff) + 1 == 0x10000);
check(Convert<intptr>(-0xffff) == -65535);
}
macro TestLargeIntegerLiterals(implicit c: Context)() {
let x: int32 = 0x40000000;
let y: int32 = 0x7fffffff;
}
macro TestMultilineAssert() {
let someVeryLongVariableNameThatWillCauseLineBreaks: Smi = 5;
check(
someVeryLongVariableNameThatWillCauseLineBreaks > 0 &&
someVeryLongVariableNameThatWillCauseLineBreaks < 10);
}
macro TestNewlineInString() {
Print('Hello, World!\n');
}
const kConstexprConst: constexpr int31 = 5;
const kIntptrConst: intptr = 4;
const kSmiConst: Smi = 3;
macro TestModuleConstBindings() {
check(kConstexprConst == Int32Constant(5));
check(kIntptrConst == 4);
check(kSmiConst == 3);
}
macro TestLocalConstBindings() {
const x: constexpr int31 = 3;
const xSmi: Smi = x;
{
const x: Smi = x + FromConstexpr<Smi>(1);
check(x == xSmi + 1);
const xSmi: Smi = x;
check(x == xSmi);
check(x == 4);
}
check(xSmi == 3);
check(x == xSmi);
}
struct TestStructA {
indexes: FixedArray;
i: Smi;
k: Number;
}
struct TestStructB {
x: TestStructA;
y: Smi;
}
macro TestStruct1(i: TestStructA): Smi {
return i.i;
}
macro TestStruct2(implicit context: Context)(): TestStructA {
return TestStructA{
indexes: UnsafeCast<FixedArray>(kEmptyFixedArray),
i: 27,
k: 31
};
}
macro TestStruct3(implicit context: Context)(): TestStructA {
let a: TestStructA =
TestStructA{indexes: UnsafeCast<FixedArray>(kEmptyFixedArray), i: 13, k: 5};
let b: TestStructA = a;
let c: TestStructA = TestStruct2();
a.i = TestStruct1(c);
a.k = a.i;
let d: TestStructB;
d.x = a;
d = TestStructB{x: a, y: 7};
let e: TestStructA = d.x;
let f: Smi = TestStructA{
indexes: UnsafeCast<FixedArray>(kEmptyFixedArray),
i: 27,
k: 31
}.i;
f = TestStruct2().i;
return a;
}
struct TestStructC {
x: TestStructA;
y: TestStructA;
}
macro TestStruct4(implicit context: Context)(): TestStructC {
return TestStructC{x: TestStruct2(), y: TestStruct2()};
}
macro TestStructInLabel(implicit context: Context)(): never
labels Foo(TestStructA) {
goto Foo(TestStruct2());
}
macro CallTestStructInLabel(implicit context: Context)() {
try {
TestStructInLabel() otherwise Foo;
}
label Foo(s: TestStructA) {}
}
// This macro tests different versions of the for-loop where some parts
// are (not) present.
macro TestForLoop() {
let sum: Smi = 0;
for (let i: Smi = 0; i < 5; ++i) sum += i;
check(sum == 10);
sum = 0;
let j: Smi = 0;
for (; j < 5; ++j) sum += j;
check(sum == 10);
sum = 0;
j = 0;
for (; j < 5;) sum += j++;
check(sum == 10);
// Check that break works. No test expression.
sum = 0;
for (let i: Smi = 0;; ++i) {
if (i == 5) break;
sum += i;
}
check(sum == 10);
sum = 0;
j = 0;
for (;;) {
if (j == 5) break;
sum += j;
j++;
}
check(sum == 10);
// The following tests are the same as above, but use continue to skip
// index 3.
sum = 0;
for (let i: Smi = 0; i < 5; ++i) {
if (i == 3) continue;
sum += i;
}
check(sum == 7);
sum = 0;
j = 0;
for (; j < 5; ++j) {
if (j == 3) continue;
sum += j;
}
check(sum == 7);
sum = 0;
j = 0;
for (; j < 5;) {
if (j == 3) {
j++;
continue;
}
sum += j;
j++;
}
check(sum == 7);
sum = 0;
for (let i: Smi = 0;; ++i) {
if (i == 3) continue;
if (i == 5) break;
sum += i;
}
check(sum == 7);
sum = 0;
j = 0;
for (;;) {
if (j == 3) {
j++;
continue;
}
if (j == 5) break;
sum += j;
j++;
}
check(sum == 7);
j = 0;
try {
for (;;) {
if (++j == 10) goto Exit;
}
}
label Exit {
check(j == 10);
}
// Test if we can handle uninitialized values on the stack.
let i: Smi;
for (let j: Smi = 0; j < 10; ++j) {
}
}
macro TestSubtyping(x: Smi) {
const foo: Object = x;
}
macro IncrementIfSmi<A: type>(x: A): A {
typeswitch (x) {
case (x: Smi): {
return x + 1;
}
case (o: A): {
return o;
}
}
}
type NumberOrFixedArray = Number | FixedArray;
macro TypeswitchExample(implicit context: Context)(x: NumberOrFixedArray):
int32 {
let result: int32 = 0;
typeswitch (IncrementIfSmi(x)) {
case (x: FixedArray): {
result = result + 1;
}
case (Number): {
result = result + 2;
}
}
result = result * 10;
typeswitch (IncrementIfSmi(x)) {
case (x: Smi): {
result = result + Convert<int32>(x);
}
case (a: FixedArray): {
result = result + Convert<int32>(a.length);
}
case (x: HeapNumber): {
result = result + 7;
}
}
return result;
}
macro TestTypeswitch(implicit context: Context)() {
check(TypeswitchExample(FromConstexpr<Smi>(5)) == 26);
const a: FixedArray = AllocateZeroedFixedArray(3);
check(TypeswitchExample(a) == 13);
check(TypeswitchExample(FromConstexpr<Number>(0.5)) == 27);
}
macro TestTypeswitchAsanLsanFailure(implicit context: Context)(obj: Object) {
typeswitch (obj) {
case (o: Smi): {
}
case (o: JSTypedArray): {
}
case (o: JSReceiver): {
}
case (o: HeapObject): {
}
}
}
macro ExampleGenericOverload<A: type>(o: Object): A {
return o;
}
macro ExampleGenericOverload<A: type>(o: Smi): A {
return o + 1;
}
macro TestGenericOverload(implicit context: Context)() {
const xSmi: Smi = 5;
const xObject: Object = xSmi;
check(ExampleGenericOverload<Smi>(xSmi) == 6);
check(UnsafeCast<Smi>(ExampleGenericOverload<Object>(xObject)) == 5);
}
macro TestEquality(implicit context: Context)() {
const notEqual: bool =
AllocateHeapNumberWithValue(0.5) != AllocateHeapNumberWithValue(0.5);
check(!notEqual);
const equal: bool =
AllocateHeapNumberWithValue(0.5) == AllocateHeapNumberWithValue(0.5);
check(equal);
}
macro BoolToBranch(x: bool): never
labels Taken, NotTaken {
if (x) {
goto Taken;
} else {
goto NotTaken;
}
}
macro TestOrAnd1(x: bool, y: bool, z: bool): bool {
return BoolToBranch(x) || y && z ? true : false;
}
macro TestOrAnd2(x: bool, y: bool, z: bool): bool {
return x || BoolToBranch(y) && z ? true : false;
}
macro TestOrAnd3(x: bool, y: bool, z: bool): bool {
return x || y && BoolToBranch(z) ? true : false;
}
macro TestAndOr1(x: bool, y: bool, z: bool): bool {
return BoolToBranch(x) && y || z ? true : false;
}
macro TestAndOr2(x: bool, y: bool, z: bool): bool {
return x && BoolToBranch(y) || z ? true : false;
}
macro TestAndOr3(x: bool, y: bool, z: bool): bool {
return x && y || BoolToBranch(z) ? true : false;
}
macro TestLogicalOperators() {
check(TestAndOr1(true, true, true));
check(TestAndOr2(true, true, true));
check(TestAndOr3(true, true, true));
check(TestAndOr1(true, true, false));
check(TestAndOr2(true, true, false));
check(TestAndOr3(true, true, false));
check(TestAndOr1(true, false, true));
check(TestAndOr2(true, false, true));
check(TestAndOr3(true, false, true));
check(!TestAndOr1(true, false, false));
check(!TestAndOr2(true, false, false));
check(!TestAndOr3(true, false, false));
check(TestAndOr1(false, true, true));
check(TestAndOr2(false, true, true));
check(TestAndOr3(false, true, true));
check(!TestAndOr1(false, true, false));
check(!TestAndOr2(false, true, false));
check(!TestAndOr3(false, true, false));
check(TestAndOr1(false, false, true));
check(TestAndOr2(false, false, true));
check(TestAndOr3(false, false, true));
check(!TestAndOr1(false, false, false));
check(!TestAndOr2(false, false, false));
check(!TestAndOr3(false, false, false));
check(TestOrAnd1(true, true, true));
check(TestOrAnd2(true, true, true));
check(TestOrAnd3(true, true, true));
check(TestOrAnd1(true, true, false));
check(TestOrAnd2(true, true, false));
check(TestOrAnd3(true, true, false));
check(TestOrAnd1(true, false, true));
check(TestOrAnd2(true, false, true));
check(TestOrAnd3(true, false, true));
check(TestOrAnd1(true, false, false));
check(TestOrAnd2(true, false, false));
check(TestOrAnd3(true, false, false));
check(TestOrAnd1(false, true, true));
check(TestOrAnd2(false, true, true));
check(TestOrAnd3(false, true, true));
check(!TestOrAnd1(false, true, false));
check(!TestOrAnd2(false, true, false));
check(!TestOrAnd3(false, true, false));
check(!TestOrAnd1(false, false, true));
check(!TestOrAnd2(false, false, true));
check(!TestOrAnd3(false, false, true));
check(!TestOrAnd1(false, false, false));
check(!TestOrAnd2(false, false, false));
check(!TestOrAnd3(false, false, false));
}
macro TestCall(i: Smi): Smi
labels A {
if (i < 5) return i;
goto A;
}
macro TestOtherwiseWithCode1() {
let v: Smi = 0;
let s: Smi = 1;
try {
TestCall(10) otherwise goto B(++s);
}
label B(v1: Smi) {
v = v1;
}
assert(v == 2);
}
macro TestOtherwiseWithCode2() {
let s: Smi = 0;
for (let i: Smi = 0; i < 10; ++i) {
TestCall(i) otherwise break;
++s;
}
assert(s == 5);
}
macro TestOtherwiseWithCode3() {
let s: Smi = 0;
for (let i: Smi = 0; i < 10; ++i) {
s += TestCall(i) otherwise break;
}
assert(s == 10);
}
macro TestForwardLabel() {
try {
goto A;
}
label A {
goto B(5);
}
label B(b: Smi) {
assert(b == 5);
}
}
macro TestQualifiedAccess(implicit context: Context)() {
let s: Smi = 0;
check(!array::IsJSArray(s));
}
macro TestCatch1(implicit context: Context)(): Smi {
let r: Smi = 0;
try {
ThrowTypeError(kInvalidArrayLength);
} catch (e) {
r = 1;
return r;
}
}
macro TestCatch2Wrapper(implicit context: Context)(): never {
ThrowTypeError(kInvalidArrayLength);
}
macro TestCatch2(implicit context: Context)(): Smi {
let r: Smi = 0;
try {
TestCatch2Wrapper();
} catch (e) {
r = 2;
return r;
}
}
macro TestCatch3WrapperWithLabel(implicit context: Context)(): never
labels Abort {
ThrowTypeError(kInvalidArrayLength);
}
macro TestCatch3(implicit context: Context)(): Smi {
let r: Smi = 0;
try {
TestCatch3WrapperWithLabel() otherwise Abort;
}
label Abort {
return -1;
}
catch (e) {
r = 2;
return r;
}
}
// This test doesn't actually test the functionality of iterators,
// it's only purpose is to make sure tha the CSA macros in the
// IteratorBuiltinsAssembler match the signatures provided in
// iterator.tq.
macro TestIterator(implicit context: Context)(o: Object, map: Map) {
try {
const t1: Object = iterator::GetIteratorMethod(o);
const t2: iterator::IteratorRecord = iterator::GetIterator(o);
const t3: Object = iterator::IteratorStep(t2) otherwise Fail;
const t4: Object = iterator::IteratorStep(t2, map) otherwise Fail;
const t5: Object = iterator::IteratorValue(t4);
const t6: Object = iterator::IteratorValue(t4, map);
const t7: JSArray = iterator::IterableToList(t1, t1);
iterator::IteratorCloseOnException(t2, t5);
}
label Fail {}
}
macro TestFrame1(implicit context: Context)() {
const f: Frame = LoadFramePointer();
const frameType: FrameType =
Cast<FrameType>(f.context_or_frame_type) otherwise unreachable;
assert(frameType == STUB_FRAME);
assert(f.caller == LoadParentFramePointer());
typeswitch (f) {
case (f: StandardFrame): {
unreachable;
}
case (f: ArgumentsAdaptorFrame): {
unreachable;
}
case (f: StubFrame): {
}
}
}
macro TestNew(implicit context: Context)() {
const f: JSArray = NewJSArray();
assert(f.IsEmpty());
f.length = 0;
}
struct TestInner {
SetX(newValue: int32) {
this.x = newValue;
}
GetX(): int32 {
return this.x;
}
x: int32;
y: int32;
}
struct TestOuter {
a: int32;
b: TestInner;
c: int32;
}
macro TestStructConstructor(implicit context: Context)() {
// Test default constructor
let a: TestOuter = TestOuter{a: 5, b: TestInner{x: 6, y: 7}, c: 8};
assert(a.a == 5);
assert(a.b.x == 6);
assert(a.b.y == 7);
assert(a.c == 8);
a.b.x = 1;
assert(a.b.x == 1);
a.b.SetX(2);
assert(a.b.x == 2);
assert(a.b.GetX() == 2);
}
@noVerifier
extern class TestClassWithAllTypes extends JSObject {
a: int8;
b: uint8;
b2: uint8;
b3: uint8;
c: int16;
d: uint16;
e: int32;
f: uint32;
g: RawPtr;
h: intptr;
i: uintptr;
}
// This class should throw alignment errors if @ifdef decorators aren't
// working.
@noVerifier
extern class PreprocessingTest extends JSObject {
@ifdef(FALSE_FOR_TESTING) a: int8;
@ifdef(TRUE_FOR_TESTING) a: int16;
b: int16;
d: int32;
}
macro TestClassWithAllTypesLoadsAndStores(
t: TestClassWithAllTypes, r: RawPtr, v1: int8, v2: uint8, v3: int16,
v4: uint16) {
t.a = v1;
t.b = v2;
t.c = v3;
t.d = v4;
t.e = 0;
t.f = 0;
t.g = r;
t.h = 0;
t.i = 0;
t.a = t.a;
t.b = t.b;
t.c = t.c;
t.d = t.d;
t.e = t.e;
t.f = t.f;
t.g = t.g;
t.h = t.h;
t.i = t.i;
}
class InternalClass {
Flip() labels NotASmi {
const tmp = Cast<Smi>(this.b) otherwise NotASmi;
this.b = this.a;
this.a = tmp;
}
a: Smi;
b: Number;
}
macro NewInternalClass(x: Smi): InternalClass {
return new InternalClass{a: x, b: x + 1};
}
macro TestInternalClass(implicit context: Context)() {
const o = NewInternalClass(5);
o.Flip() otherwise unreachable;
check(o.a == 6);
check(o.b == 5);
}
struct StructWithConst {
TestMethod1(): int32 {
return this.b;
}
TestMethod2(): Object {
return this.a;
}
a: Object;
const b: int32;
}
macro TestConstInStructs() {
const x = StructWithConst{a: Null, b: 1};
let y = StructWithConst{a: Null, b: 1};
y.a = Undefined;
const copy = x;
}
struct TestIterator {
Next(): Object labels NoMore {
if (this.count-- == 0) goto NoMore;
return Hole;
}
count: Smi;
}
macro TestNewFixedArrayFromSpread(implicit context: Context)(): Object {
const i = TestIterator{count: 5};
return new FixedArray{map: kFixedArrayMap, length: 5, objects: ...i};
}
class SmiPair {
GetA():&Smi {
return & this.a;
}
a: Smi;
b: Smi;
}
macro Swap<T: type>(a:&T, b:&T) {
const tmp = * a;
* a = * b;
* b = tmp;
}
macro TestReferences() {
const array = new SmiPair{a: 7, b: 2};
const ref:&Smi = & array.a;
* ref = 3 + * ref;
-- * ref;
Swap(& array.b, array.GetA());
check(array.a == 2);
check(array.b == 9);
}
type Baztype = Foo | FooType;
@abstract
@noVerifier
extern class Foo extends JSObject {
fooField: FooType;
}
@noVerifier
extern class Bar extends Foo {
barField: Bartype;
bazfield: Baztype;
}
type Bartype = FooType;
type FooType = Smi | Bar;
}
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